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|
#ifndef __BDK_CSRS_BGX_H__
#define __BDK_CSRS_BGX_H__
/* This file is auto-generated. Do not edit */
/***********************license start***************
* Copyright (c) 2003-2017 Cavium Inc. (support@cavium.com). All rights
* reserved.
*
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are
* met:
*
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
*
* * Redistributions in binary form must reproduce the above
* copyright notice, this list of conditions and the following
* disclaimer in the documentation and/or other materials provided
* with the distribution.
* * Neither the name of Cavium Inc. nor the names of
* its contributors may be used to endorse or promote products
* derived from this software without specific prior written
* permission.
* This Software, including technical data, may be subject to U.S. export control
* laws, including the U.S. Export Administration Act and its associated
* regulations, and may be subject to export or import regulations in other
* countries.
* TO THE MAXIMUM EXTENT PERMITTED BY LAW, THE SOFTWARE IS PROVIDED "AS IS"
* AND WITH ALL FAULTS AND CAVIUM NETWORKS MAKES NO PROMISES, REPRESENTATIONS OR
* WARRANTIES, EITHER EXPRESS, IMPLIED, STATUTORY, OR OTHERWISE, WITH RESPECT TO
* THE SOFTWARE, INCLUDING ITS CONDITION, ITS CONFORMITY TO ANY REPRESENTATION OR
* DESCRIPTION, OR THE EXISTENCE OF ANY LATENT OR PATENT DEFECTS, AND CAVIUM
* SPECIFICALLY DISCLAIMS ALL IMPLIED (IF ANY) WARRANTIES OF TITLE,
* MERCHANTABILITY, NONINFRINGEMENT, FITNESS FOR A PARTICULAR PURPOSE, LACK OF
* VIRUSES, ACCURACY OR COMPLETENESS, QUIET ENJOYMENT, QUIET POSSESSION OR
* CORRESPONDENCE TO DESCRIPTION. THE ENTIRE RISK ARISING OUT OF USE OR
* PERFORMANCE OF THE SOFTWARE LIES WITH YOU.
***********************license end**************************************/
/**
* @file
*
* Configuration and status register (CSR) address and type definitions for
* Cavium BGX.
*
* This file is auto generated. Do not edit.
*
*/
/**
* Enumeration bgx_bar_e
*
* BGX Base Address Register Enumeration
* Enumerates the base address registers.
*/
#define BDK_BGX_BAR_E_BGXX_PF_BAR0(a) (0x87e0e0000000ll + 0x1000000ll * (a))
#define BDK_BGX_BAR_E_BGXX_PF_BAR0_SIZE 0x400000ull
#define BDK_BGX_BAR_E_BGXX_PF_BAR4(a) (0x87e0e0400000ll + 0x1000000ll * (a))
#define BDK_BGX_BAR_E_BGXX_PF_BAR4_SIZE 0x400000ull
/**
* Enumeration bgx_int_vec_e
*
* BGX MSI-X Vector Enumeration
* Enumeration the MSI-X interrupt vectors.
*/
#define BDK_BGX_INT_VEC_E_CMRX_INT(a) (0 + 7 * (a))
#define BDK_BGX_INT_VEC_E_CMR_MEM_INT (0x1c)
#define BDK_BGX_INT_VEC_E_GMPX_GMI_RX_INT(a) (5 + 7 * (a))
#define BDK_BGX_INT_VEC_E_GMPX_GMI_TX_INT(a) (6 + 7 * (a))
#define BDK_BGX_INT_VEC_E_GMPX_PCS_INT(a) (4 + 7 * (a))
#define BDK_BGX_INT_VEC_E_SMUX_RX_INT(a) (2 + 7 * (a))
#define BDK_BGX_INT_VEC_E_SMUX_TX_INT(a) (3 + 7 * (a))
#define BDK_BGX_INT_VEC_E_SPUX_INT(a) (1 + 7 * (a))
#define BDK_BGX_INT_VEC_E_SPU_MEM_INT (0x1d)
/**
* Enumeration bgx_lmac_types_e
*
* BGX LMAC Type Enumeration
* Enumerates the LMAC Types that BGX supports.
*/
#define BDK_BGX_LMAC_TYPES_E_FORTYG_R (4)
#define BDK_BGX_LMAC_TYPES_E_QSGMII (6)
#define BDK_BGX_LMAC_TYPES_E_RGMII (5)
#define BDK_BGX_LMAC_TYPES_E_RXAUI (2)
#define BDK_BGX_LMAC_TYPES_E_SGMII (0)
#define BDK_BGX_LMAC_TYPES_E_TENG_R (3)
#define BDK_BGX_LMAC_TYPES_E_XAUI (1)
/**
* Enumeration bgx_opcode_e
*
* INTERNAL: BGX Error Opcode Enumeration
*
* Enumerates the error opcodes created by BGX and presented to NCSI/TNS/NIC.
*/
#define BDK_BGX_OPCODE_E_RE_FCS (7)
#define BDK_BGX_OPCODE_E_RE_FCS_RCV (8)
#define BDK_BGX_OPCODE_E_RE_JABBER (2)
#define BDK_BGX_OPCODE_E_RE_NONE (0)
#define BDK_BGX_OPCODE_E_RE_PARTIAL (1)
#define BDK_BGX_OPCODE_E_RE_RX_CTL (0xb)
#define BDK_BGX_OPCODE_E_RE_SKIP (0xc)
#define BDK_BGX_OPCODE_E_RE_TERMINATE (9)
/**
* Enumeration bgx_spu_br_train_cst_e
*
* BGX Training Coefficient Status Enumeration
* 2-bit status for each coefficient as defined in 802.3-2008, Table 72-5.
*/
#define BDK_BGX_SPU_BR_TRAIN_CST_E_MAXIMUM (3)
#define BDK_BGX_SPU_BR_TRAIN_CST_E_MINIMUM (2)
#define BDK_BGX_SPU_BR_TRAIN_CST_E_NOT_UPDATED (0)
#define BDK_BGX_SPU_BR_TRAIN_CST_E_UPDATED (1)
/**
* Enumeration bgx_spu_br_train_cup_e
*
* BGX Training Coefficient Enumeration
* 2-bit command for each coefficient as defined in 802.3-2008, Table 72-4.
*/
#define BDK_BGX_SPU_BR_TRAIN_CUP_E_DECREMENT (1)
#define BDK_BGX_SPU_BR_TRAIN_CUP_E_HOLD (0)
#define BDK_BGX_SPU_BR_TRAIN_CUP_E_INCREMENT (2)
#define BDK_BGX_SPU_BR_TRAIN_CUP_E_RSV_CMD (3)
/**
* Structure bgx_spu_br_lane_train_status_s
*
* BGX Lane Training Status Structure
* This is the group of lane status bits for a single lane in the BASE-R PMD status register
* (MDIO address 1.151) as defined in 802.3ba-2010, Table 45-55.
*/
union bdk_bgx_spu_br_lane_train_status_s
{
uint32_t u;
struct bdk_bgx_spu_br_lane_train_status_s_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint32_t reserved_4_31 : 28;
uint32_t training_failure : 1; /**< [ 3: 3] Link training failure. */
uint32_t training : 1; /**< [ 2: 2] Link training state.
0 = Training in progress.
1 = Training has completed. */
uint32_t frame_lock : 1; /**< [ 1: 1] Frame lock status. Set when training frame delineation has been detected. */
uint32_t rx_trained : 1; /**< [ 0: 0] Receiver trained status.
0 = Receiver training.
1 = Receiver trained and ready to receive data for the lane. */
#else /* Word 0 - Little Endian */
uint32_t rx_trained : 1; /**< [ 0: 0] Receiver trained status.
0 = Receiver training.
1 = Receiver trained and ready to receive data for the lane. */
uint32_t frame_lock : 1; /**< [ 1: 1] Frame lock status. Set when training frame delineation has been detected. */
uint32_t training : 1; /**< [ 2: 2] Link training state.
0 = Training in progress.
1 = Training has completed. */
uint32_t training_failure : 1; /**< [ 3: 3] Link training failure. */
uint32_t reserved_4_31 : 28;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgx_spu_br_lane_train_status_s_s cn; */
};
/**
* Structure bgx_spu_br_train_cup_s
*
* BGX Lane Training Coeffiecient Structure
* This is the coefficient update field of the BASE-R link training packet as defined in
* 802.3-2008, Table 72-4.
*/
union bdk_bgx_spu_br_train_cup_s
{
uint32_t u;
struct bdk_bgx_spu_br_train_cup_s_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint32_t reserved_14_31 : 18;
uint32_t preset : 1; /**< [ 13: 13] Preset. Set to indicate that all TX coefficients be set to a state where equalization is
turned off, i.e. the precursor (k = -1) and postcursor (k = +1) coefficients should be set
to 0 and the main
(k = 0) coefficient should be set to its maximum value. */
uint32_t init : 1; /**< [ 12: 12] Initialize. Set to indicate that the TX coefficients should be set to meet the conditions
defined in 802.3-2008 sub-clause 72.6.10.4.2. */
uint32_t reserved_6_11 : 6;
uint32_t post_cup : 2; /**< [ 5: 4] Post-cursor (k = +1) coefficient update. Valid when PRESET = INIT = 0. Enumerated by
BGX_SPU_BR_TRAIN_CUP_E. */
uint32_t main_cup : 2; /**< [ 3: 2] Main (k = 0) coefficient update. Valid when PRESET = INIT = 0. Enumerated by
BGX_SPU_BR_TRAIN_CUP_E. */
uint32_t pre_cup : 2; /**< [ 1: 0] Pre-cursor (k = -1) coefficient update. Valid when PRESET = INIT = 0. Enumerated by
BGX_SPU_BR_TRAIN_CUP_E. */
#else /* Word 0 - Little Endian */
uint32_t pre_cup : 2; /**< [ 1: 0] Pre-cursor (k = -1) coefficient update. Valid when PRESET = INIT = 0. Enumerated by
BGX_SPU_BR_TRAIN_CUP_E. */
uint32_t main_cup : 2; /**< [ 3: 2] Main (k = 0) coefficient update. Valid when PRESET = INIT = 0. Enumerated by
BGX_SPU_BR_TRAIN_CUP_E. */
uint32_t post_cup : 2; /**< [ 5: 4] Post-cursor (k = +1) coefficient update. Valid when PRESET = INIT = 0. Enumerated by
BGX_SPU_BR_TRAIN_CUP_E. */
uint32_t reserved_6_11 : 6;
uint32_t init : 1; /**< [ 12: 12] Initialize. Set to indicate that the TX coefficients should be set to meet the conditions
defined in 802.3-2008 sub-clause 72.6.10.4.2. */
uint32_t preset : 1; /**< [ 13: 13] Preset. Set to indicate that all TX coefficients be set to a state where equalization is
turned off, i.e. the precursor (k = -1) and postcursor (k = +1) coefficients should be set
to 0 and the main
(k = 0) coefficient should be set to its maximum value. */
uint32_t reserved_14_31 : 18;
#endif /* Word 0 - End */
} s;
struct bdk_bgx_spu_br_train_cup_s_cn
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint32_t reserved_16_31 : 16;
uint32_t reserved_14_15 : 2;
uint32_t preset : 1; /**< [ 13: 13] Preset. Set to indicate that all TX coefficients be set to a state where equalization is
turned off, i.e. the precursor (k = -1) and postcursor (k = +1) coefficients should be set
to 0 and the main
(k = 0) coefficient should be set to its maximum value. */
uint32_t init : 1; /**< [ 12: 12] Initialize. Set to indicate that the TX coefficients should be set to meet the conditions
defined in 802.3-2008 sub-clause 72.6.10.4.2. */
uint32_t reserved_6_11 : 6;
uint32_t post_cup : 2; /**< [ 5: 4] Post-cursor (k = +1) coefficient update. Valid when PRESET = INIT = 0. Enumerated by
BGX_SPU_BR_TRAIN_CUP_E. */
uint32_t main_cup : 2; /**< [ 3: 2] Main (k = 0) coefficient update. Valid when PRESET = INIT = 0. Enumerated by
BGX_SPU_BR_TRAIN_CUP_E. */
uint32_t pre_cup : 2; /**< [ 1: 0] Pre-cursor (k = -1) coefficient update. Valid when PRESET = INIT = 0. Enumerated by
BGX_SPU_BR_TRAIN_CUP_E. */
#else /* Word 0 - Little Endian */
uint32_t pre_cup : 2; /**< [ 1: 0] Pre-cursor (k = -1) coefficient update. Valid when PRESET = INIT = 0. Enumerated by
BGX_SPU_BR_TRAIN_CUP_E. */
uint32_t main_cup : 2; /**< [ 3: 2] Main (k = 0) coefficient update. Valid when PRESET = INIT = 0. Enumerated by
BGX_SPU_BR_TRAIN_CUP_E. */
uint32_t post_cup : 2; /**< [ 5: 4] Post-cursor (k = +1) coefficient update. Valid when PRESET = INIT = 0. Enumerated by
BGX_SPU_BR_TRAIN_CUP_E. */
uint32_t reserved_6_11 : 6;
uint32_t init : 1; /**< [ 12: 12] Initialize. Set to indicate that the TX coefficients should be set to meet the conditions
defined in 802.3-2008 sub-clause 72.6.10.4.2. */
uint32_t preset : 1; /**< [ 13: 13] Preset. Set to indicate that all TX coefficients be set to a state where equalization is
turned off, i.e. the precursor (k = -1) and postcursor (k = +1) coefficients should be set
to 0 and the main
(k = 0) coefficient should be set to its maximum value. */
uint32_t reserved_14_15 : 2;
uint32_t reserved_16_31 : 16;
#endif /* Word 0 - End */
} cn;
};
/**
* Structure bgx_spu_br_train_rep_s
*
* BGX Training Report Structure
* This is the status report field of the BASE-R link training packet as defined in 802.3-2008,
* Table 72-5.
*/
union bdk_bgx_spu_br_train_rep_s
{
uint32_t u;
struct bdk_bgx_spu_br_train_rep_s_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint32_t reserved_16_31 : 16;
uint32_t rx_ready : 1; /**< [ 15: 15] Receiver ready. Set to indicate that the local receiver has determined that training is
complete and is prepared to receive data. */
uint32_t reserved_6_14 : 9;
uint32_t post_cst : 2; /**< [ 5: 4] Post-cursor (k = +1) coefficient status. Valid when PRESET = INIT = 0. Enumerated by
BGX_SPU_BR_TRAIN_CST_E. */
uint32_t main_cst : 2; /**< [ 3: 2] Main (k = 0) coefficient status. Valid when PRESET = INIT = 0. Enumerated by
BGX_SPU_BR_TRAIN_CST_E. */
uint32_t pre_cst : 2; /**< [ 1: 0] Pre-cursor (k = -1) coefficient status. Valid when PRESET = INIT = 0. Enumerated by
BGX_SPU_BR_TRAIN_CST_E. */
#else /* Word 0 - Little Endian */
uint32_t pre_cst : 2; /**< [ 1: 0] Pre-cursor (k = -1) coefficient status. Valid when PRESET = INIT = 0. Enumerated by
BGX_SPU_BR_TRAIN_CST_E. */
uint32_t main_cst : 2; /**< [ 3: 2] Main (k = 0) coefficient status. Valid when PRESET = INIT = 0. Enumerated by
BGX_SPU_BR_TRAIN_CST_E. */
uint32_t post_cst : 2; /**< [ 5: 4] Post-cursor (k = +1) coefficient status. Valid when PRESET = INIT = 0. Enumerated by
BGX_SPU_BR_TRAIN_CST_E. */
uint32_t reserved_6_14 : 9;
uint32_t rx_ready : 1; /**< [ 15: 15] Receiver ready. Set to indicate that the local receiver has determined that training is
complete and is prepared to receive data. */
uint32_t reserved_16_31 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgx_spu_br_train_rep_s_s cn; */
};
/**
* Structure bgx_spu_sds_cu_s
*
* INTERNAL: BGX Training Coeffiecient Structure
*
* This structure is similar to BGX_SPU_BR_TRAIN_CUP_S format, but with reserved fields removed
* and [RCVR_READY] field added.
*/
union bdk_bgx_spu_sds_cu_s
{
uint32_t u;
struct bdk_bgx_spu_sds_cu_s_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint32_t reserved_9_31 : 23;
uint32_t rcvr_ready : 1; /**< [ 8: 8] See BGX_SPU_BR_TRAIN_REP_S[RX_READY]. */
uint32_t preset : 1; /**< [ 7: 7] See BGX_SPU_BR_TRAIN_CUP_S[PRESET]. */
uint32_t initialize : 1; /**< [ 6: 6] See BGX_SPU_BR_TRAIN_CUP_S[INIT]. */
uint32_t post_cu : 2; /**< [ 5: 4] See BGX_SPU_BR_TRAIN_CUP_S[POST_CUP]. */
uint32_t main_cu : 2; /**< [ 3: 2] See BGX_SPU_BR_TRAIN_CUP_S[MAIN_CUP]. */
uint32_t pre_cu : 2; /**< [ 1: 0] See BGX_SPU_BR_TRAIN_CUP_S[PRE_CUP]. */
#else /* Word 0 - Little Endian */
uint32_t pre_cu : 2; /**< [ 1: 0] See BGX_SPU_BR_TRAIN_CUP_S[PRE_CUP]. */
uint32_t main_cu : 2; /**< [ 3: 2] See BGX_SPU_BR_TRAIN_CUP_S[MAIN_CUP]. */
uint32_t post_cu : 2; /**< [ 5: 4] See BGX_SPU_BR_TRAIN_CUP_S[POST_CUP]. */
uint32_t initialize : 1; /**< [ 6: 6] See BGX_SPU_BR_TRAIN_CUP_S[INIT]. */
uint32_t preset : 1; /**< [ 7: 7] See BGX_SPU_BR_TRAIN_CUP_S[PRESET]. */
uint32_t rcvr_ready : 1; /**< [ 8: 8] See BGX_SPU_BR_TRAIN_REP_S[RX_READY]. */
uint32_t reserved_9_31 : 23;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgx_spu_sds_cu_s_s cn; */
};
/**
* Structure bgx_spu_sds_skew_status_s
*
* BGX Skew Status Structure
* Provides receive skew information detected for a physical SerDes lane when it is assigned to a
* multilane LMAC/LPCS. Contents are valid when RX deskew is done for the associated LMAC/LPCS.
*/
union bdk_bgx_spu_sds_skew_status_s
{
uint32_t u;
struct bdk_bgx_spu_sds_skew_status_s_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint32_t reserved_25_31 : 7;
uint32_t lane_skew : 5; /**< [ 24: 20] Lane skew. The SerDes lane's receive skew/delay in number of code-groups (BASE-X) or
blocks (40GBASE-R) relative to the earliest (least delayed) lane of the LMAC/LPCS. */
uint32_t reserved_18_19 : 2;
uint32_t am_lane_id : 2; /**< [ 17: 16] Alignment Marker ID. Valid for 40GBASE-R only. This is the PCS lane number of the
alignment marker received on the SerDes lane. */
uint32_t reserved_12_15 : 4;
uint32_t am_timestamp : 12; /**< [ 11: 0] Alignment marker PTP timestamp. Valid for 40GBASE-R only. Contains the lower 12 bits of
the PTP timestamp of the alignment marker received on the SerDes lane during align/skew
detection. */
#else /* Word 0 - Little Endian */
uint32_t am_timestamp : 12; /**< [ 11: 0] Alignment marker PTP timestamp. Valid for 40GBASE-R only. Contains the lower 12 bits of
the PTP timestamp of the alignment marker received on the SerDes lane during align/skew
detection. */
uint32_t reserved_12_15 : 4;
uint32_t am_lane_id : 2; /**< [ 17: 16] Alignment Marker ID. Valid for 40GBASE-R only. This is the PCS lane number of the
alignment marker received on the SerDes lane. */
uint32_t reserved_18_19 : 2;
uint32_t lane_skew : 5; /**< [ 24: 20] Lane skew. The SerDes lane's receive skew/delay in number of code-groups (BASE-X) or
blocks (40GBASE-R) relative to the earliest (least delayed) lane of the LMAC/LPCS. */
uint32_t reserved_25_31 : 7;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgx_spu_sds_skew_status_s_s cn; */
};
/**
* Structure bgx_spu_sds_sr_s
*
* INTERNAL: BGX Lane Training Coefficient Structure
*
* Similar to BGX_SPU_BR_TRAIN_REP_S format, but with reserved and RX_READY fields removed.
*/
union bdk_bgx_spu_sds_sr_s
{
uint32_t u;
struct bdk_bgx_spu_sds_sr_s_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint32_t reserved_6_31 : 26;
uint32_t post_status : 2; /**< [ 5: 4] See BGX_SPU_BR_TRAIN_REP_S[POST_CST]. */
uint32_t main_status : 2; /**< [ 3: 2] See BGX_SPU_BR_TRAIN_REP_S[MAIN_CST]. */
uint32_t pre_status : 2; /**< [ 1: 0] See BGX_SPU_BR_TRAIN_REP_S[PRE_CST]. */
#else /* Word 0 - Little Endian */
uint32_t pre_status : 2; /**< [ 1: 0] See BGX_SPU_BR_TRAIN_REP_S[PRE_CST]. */
uint32_t main_status : 2; /**< [ 3: 2] See BGX_SPU_BR_TRAIN_REP_S[MAIN_CST]. */
uint32_t post_status : 2; /**< [ 5: 4] See BGX_SPU_BR_TRAIN_REP_S[POST_CST]. */
uint32_t reserved_6_31 : 26;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgx_spu_sds_sr_s_s cn; */
};
/**
* Register (RSL) bgx#_cmr#_config
*
* BGX CMR Configuration Registers
* Logical MAC/PCS configuration registers; one per LMAC. The maximum number of LMACs (and
* maximum LMAC ID) that can be enabled by these registers is limited by
* BGX()_CMR_RX_LMACS[LMACS] and BGX()_CMR_TX_LMACS[LMACS]. When multiple LMACs are
* enabled, they must be configured with the same [LMAC_TYPE] value.
*
* Internal:
* \<pre\>
* Typical configurations:
* ---------------------------------------------------------------------------
* Configuration LMACS Register [ENABLE] [LMAC_TYPE]
* ---------------------------------------------------------------------------
* 1x40GBASE-R4 1 BGXn_CMR0_CONFIG 1 4
* BGXn_CMR1_CONFIG 0 --
* BGXn_CMR2_CONFIG 0 --
* BGXn_CMR3_CONFIG 0 --
* ---------------------------------------------------------------------------
* 4x10GBASE-R 4 BGXn_CMR0_CONFIG 1 3
* BGXn_CMR1_CONFIG 1 3
* BGXn_CMR2_CONFIG 1 3
* BGXn_CMR3_CONFIG 1 3
* ---------------------------------------------------------------------------
* 2xRXAUI 2 BGXn_CMR0_CONFIG 1 2
* BGXn_CMR1_CONFIG 1 2
* BGXn_CMR2_CONFIG 0 --
* BGXn_CMR3_CONFIG 0 --
* ---------------------------------------------------------------------------
* 1x10GBASE-X/XAUI/DXAUI 1 BGXn_CMR0_CONFIG 1 1
* BGXn_CMR1_CONFIG 0 --
* BGXn_CMR2_CONFIG 0 --
* BGXn_CMR3_CONFIG 0 --
* ---------------------------------------------------------------------------
* 4xSGMII/1000BASE-X 4 BGXn_CMR0_CONFIG 1 0
* BGXn_CMR1_CONFIG 1 0
* BGXn_CMR2_CONFIG 1 0
* BGXn_CMR3_CONFIG 1 0
* ---------------------------------------------------------------------------
* \</pre\>
*/
union bdk_bgxx_cmrx_config
{
uint64_t u;
struct bdk_bgxx_cmrx_config_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_18_63 : 46;
uint64_t p2x_select : 1; /**< [ 17: 17](R/W) Selects interior side P2X interface over which the LMAC will communicate:
\<pre\>
[P2X_SELECT] Name Connected block
-------------------------------------------
0 P2X0 NIC
1 P2X1 PKO
\</pre\> */
uint64_t x2p_select : 1; /**< [ 16: 16](R/W) Selects interior side X2P interface over which the LMAC will communicate:
\<pre\>
[X2P_SELECT] Name Connected block
-------------------------------------------
0 X2P0 NIC
1 X2P1 PKI
\</pre\> */
uint64_t enable : 1; /**< [ 15: 15](R/W) Logical MAC/PCS enable. This is the master enable for the LMAC. When clear, all the
dedicated BGX context state for the LMAC (state machines, FIFOs, counters, etc.) is reset,
and LMAC access to shared BGX resources (data path, SerDes lanes) is disabled.
When set, LMAC operation is enabled, including link bring-up, synchronization, and
transmit/receive of idles and fault sequences. Note that configuration registers for an
LMAC are not reset when this bit is clear, allowing software to program them before
setting this bit to enable the LMAC. This bit together with [LMAC_TYPE] is also used to
enable the clocking to the GMP and/or blocks of the Super path (SMU and SPU). CMR clocking
is enabled when any of the paths are enabled. */
uint64_t data_pkt_rx_en : 1; /**< [ 14: 14](R/W) Data packet receive enable. When [ENABLE] = 1 and [DATA_PKT_RX_EN] = 1, the reception of
data
packets is enabled in the MAC layer. When [ENABLE] = 1 and [DATA_PKT_RX_EN] = 0, the MAC
layer
drops received data and flow-control packets. */
uint64_t data_pkt_tx_en : 1; /**< [ 13: 13](R/W) Data packet transmit enable. When [ENABLE] = 1 and [DATA_PKT_TX_EN] = 1, the transmission
of
data
packets is enabled in the MAC layer. When [ENABLE] = 1 and [DATA_PKT_TX_EN] = 0, the MAC
layer
suppresses the transmission of new data and packets for the LMAC. */
uint64_t int_beat_gen : 1; /**< [ 12: 12](R/W) Internal beat generation. This bit is used for debug/test purposes and should be clear
during normal operation. When set, the LMAC's PCS layer ignores RXVALID and
TXREADY/TXCREDIT from the associated SerDes lanes, internally generates fake (idle)
RXVALID and TXCREDIT pulses, and suppresses transmission to the SerDes. */
uint64_t mix_en : 1; /**< [ 11: 11](R/W) Must be 0. */
uint64_t lmac_type : 3; /**< [ 10: 8](R/W) Logical MAC/PCS/prt type:
\<pre\>
LMAC_TYPE Name Description NUM_PCS_LANES
----------------------------------------------------------
0x0 SGMII SGMII/1000BASE-X 1
0x1 XAUI 10GBASE-X/XAUI or DXAUI 4
0x2 RXAUI Reduced XAUI 2
0x3 10G_R 10GBASE-R 1
0x4 40G_R 40GBASE-R 4
0x5 -- Reserved -
0x6 QSGMII QSGMII 1
Other -- Reserved -
\</pre\>
NUM_PCS_LANES specifies the number of PCS lanes that are valid for
each type. Each valid PCS lane is mapped to a physical SerDes lane
based on the programming of [LANE_TO_SDS].
This field must be programmed to its final value before [ENABLE] is set, and must not
be changed when [ENABLE] = 1. */
uint64_t lane_to_sds : 8; /**< [ 7: 0](R/W) PCS lane-to-SerDes mapping.
This is an array of 2-bit values that map each logical PCS lane to a
physical SerDes lane, as follows:
\<pre\>
Bits Description Reset value
------------------------------------------
\<7:6\> PCS Lane 3 SerDes ID 0x3
\<5:4\> PCS Lane 2 SerDes ID 0x2
\<3:2\> PCS Lane 1 SerDes ID 0x1
\<1:0\> PCS Lane 0 SerDes ID 0x0
\</pre\>
PCS lanes 0 through NUM_PCS_LANES-1 are valid, where NUM_PCS_LANES is a function of the
logical MAC/PCS type (see [LMAC_TYPE]). For example, when [LMAC_TYPE] = SGMII,
then NUM_PCS_LANES = 1, PCS lane 0 is valid and the associated physical SerDes lanes
are selected by bits \<1:0\>.
For 40GBASE-R ([LMAC_TYPE] = 40G_R), all four PCS lanes are valid, and the PCS lane IDs
determine the block distribution order and associated alignment markers on the transmit
side. This is not necessarily the order in which PCS lanes receive data because 802.3
allows multilane BASE-R receive lanes to be reordered. When a lane (called service
interface in 802.3ba-2010) has achieved alignment marker lock on the receive side (i.e.
the associated BGX()_SPU()_BR_ALGN_STATUS[MARKER_LOCK] = 1), then the actual
detected RX PCS lane number is recorded in the corresponding
BGX()_SPU()_BR_LANE_MAP[LNx_MAPPING].
For QSGMII, [LANE_TO_SDS]\<1:0\> for LMAC 0 selects the physical SerDes lane shared by four
LMACs, and [LANE_TO_SDS]\<1:0\> must be unique for each of the four LMACs.
This field must be programmed to its final value before [ENABLE] is set, and
must not be changed when [ENABLE] = 1. */
#else /* Word 0 - Little Endian */
uint64_t lane_to_sds : 8; /**< [ 7: 0](R/W) PCS lane-to-SerDes mapping.
This is an array of 2-bit values that map each logical PCS lane to a
physical SerDes lane, as follows:
\<pre\>
Bits Description Reset value
------------------------------------------
\<7:6\> PCS Lane 3 SerDes ID 0x3
\<5:4\> PCS Lane 2 SerDes ID 0x2
\<3:2\> PCS Lane 1 SerDes ID 0x1
\<1:0\> PCS Lane 0 SerDes ID 0x0
\</pre\>
PCS lanes 0 through NUM_PCS_LANES-1 are valid, where NUM_PCS_LANES is a function of the
logical MAC/PCS type (see [LMAC_TYPE]). For example, when [LMAC_TYPE] = SGMII,
then NUM_PCS_LANES = 1, PCS lane 0 is valid and the associated physical SerDes lanes
are selected by bits \<1:0\>.
For 40GBASE-R ([LMAC_TYPE] = 40G_R), all four PCS lanes are valid, and the PCS lane IDs
determine the block distribution order and associated alignment markers on the transmit
side. This is not necessarily the order in which PCS lanes receive data because 802.3
allows multilane BASE-R receive lanes to be reordered. When a lane (called service
interface in 802.3ba-2010) has achieved alignment marker lock on the receive side (i.e.
the associated BGX()_SPU()_BR_ALGN_STATUS[MARKER_LOCK] = 1), then the actual
detected RX PCS lane number is recorded in the corresponding
BGX()_SPU()_BR_LANE_MAP[LNx_MAPPING].
For QSGMII, [LANE_TO_SDS]\<1:0\> for LMAC 0 selects the physical SerDes lane shared by four
LMACs, and [LANE_TO_SDS]\<1:0\> must be unique for each of the four LMACs.
This field must be programmed to its final value before [ENABLE] is set, and
must not be changed when [ENABLE] = 1. */
uint64_t lmac_type : 3; /**< [ 10: 8](R/W) Logical MAC/PCS/prt type:
\<pre\>
LMAC_TYPE Name Description NUM_PCS_LANES
----------------------------------------------------------
0x0 SGMII SGMII/1000BASE-X 1
0x1 XAUI 10GBASE-X/XAUI or DXAUI 4
0x2 RXAUI Reduced XAUI 2
0x3 10G_R 10GBASE-R 1
0x4 40G_R 40GBASE-R 4
0x5 -- Reserved -
0x6 QSGMII QSGMII 1
Other -- Reserved -
\</pre\>
NUM_PCS_LANES specifies the number of PCS lanes that are valid for
each type. Each valid PCS lane is mapped to a physical SerDes lane
based on the programming of [LANE_TO_SDS].
This field must be programmed to its final value before [ENABLE] is set, and must not
be changed when [ENABLE] = 1. */
uint64_t mix_en : 1; /**< [ 11: 11](R/W) Must be 0. */
uint64_t int_beat_gen : 1; /**< [ 12: 12](R/W) Internal beat generation. This bit is used for debug/test purposes and should be clear
during normal operation. When set, the LMAC's PCS layer ignores RXVALID and
TXREADY/TXCREDIT from the associated SerDes lanes, internally generates fake (idle)
RXVALID and TXCREDIT pulses, and suppresses transmission to the SerDes. */
uint64_t data_pkt_tx_en : 1; /**< [ 13: 13](R/W) Data packet transmit enable. When [ENABLE] = 1 and [DATA_PKT_TX_EN] = 1, the transmission
of
data
packets is enabled in the MAC layer. When [ENABLE] = 1 and [DATA_PKT_TX_EN] = 0, the MAC
layer
suppresses the transmission of new data and packets for the LMAC. */
uint64_t data_pkt_rx_en : 1; /**< [ 14: 14](R/W) Data packet receive enable. When [ENABLE] = 1 and [DATA_PKT_RX_EN] = 1, the reception of
data
packets is enabled in the MAC layer. When [ENABLE] = 1 and [DATA_PKT_RX_EN] = 0, the MAC
layer
drops received data and flow-control packets. */
uint64_t enable : 1; /**< [ 15: 15](R/W) Logical MAC/PCS enable. This is the master enable for the LMAC. When clear, all the
dedicated BGX context state for the LMAC (state machines, FIFOs, counters, etc.) is reset,
and LMAC access to shared BGX resources (data path, SerDes lanes) is disabled.
When set, LMAC operation is enabled, including link bring-up, synchronization, and
transmit/receive of idles and fault sequences. Note that configuration registers for an
LMAC are not reset when this bit is clear, allowing software to program them before
setting this bit to enable the LMAC. This bit together with [LMAC_TYPE] is also used to
enable the clocking to the GMP and/or blocks of the Super path (SMU and SPU). CMR clocking
is enabled when any of the paths are enabled. */
uint64_t x2p_select : 1; /**< [ 16: 16](R/W) Selects interior side X2P interface over which the LMAC will communicate:
\<pre\>
[X2P_SELECT] Name Connected block
-------------------------------------------
0 X2P0 NIC
1 X2P1 PKI
\</pre\> */
uint64_t p2x_select : 1; /**< [ 17: 17](R/W) Selects interior side P2X interface over which the LMAC will communicate:
\<pre\>
[P2X_SELECT] Name Connected block
-------------------------------------------
0 P2X0 NIC
1 P2X1 PKO
\</pre\> */
uint64_t reserved_18_63 : 46;
#endif /* Word 0 - End */
} s;
struct bdk_bgxx_cmrx_config_cn81xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_18_63 : 46;
uint64_t p2x_select : 1; /**< [ 17: 17](R/W) Selects interior side P2X interface over which the LMAC will communicate:
\<pre\>
[P2X_SELECT] Name Connected block
-------------------------------------------
0 P2X0 NIC
1 P2X1 Reserved
\</pre\> */
uint64_t x2p_select : 1; /**< [ 16: 16](R/W) Selects interior side X2P interface over which the LMAC will communicate:
\<pre\>
[X2P_SELECT] Name Connected block
-------------------------------------------
0 X2P0 NIC
1 X2P1 Reserved
\</pre\> */
uint64_t enable : 1; /**< [ 15: 15](R/W) Logical MAC/PCS enable. This is the master enable for the LMAC. When clear, all the
dedicated BGX context state for the LMAC (state machines, FIFOs, counters, etc.) is reset,
and LMAC access to shared BGX resources (data path, SerDes lanes) is disabled.
When set, LMAC operation is enabled, including link bring-up, synchronization, and
transmit/receive of idles and fault sequences. Note that configuration registers for an
LMAC are not reset when this bit is clear, allowing software to program them before
setting this bit to enable the LMAC. This bit together with [LMAC_TYPE] is also used to
enable the clocking to the GMP and/or blocks of the Super path (SMU and SPU). CMR clocking
is enabled when any of the paths are enabled. */
uint64_t data_pkt_rx_en : 1; /**< [ 14: 14](R/W) Data packet receive enable. When [ENABLE] = 1 and [DATA_PKT_RX_EN] = 1, the reception of
data
packets is enabled in the MAC layer. When [ENABLE] = 1 and [DATA_PKT_RX_EN] = 0, the MAC
layer
drops received data and flow-control packets. */
uint64_t data_pkt_tx_en : 1; /**< [ 13: 13](R/W) Data packet transmit enable. When [ENABLE] = 1 and [DATA_PKT_TX_EN] = 1, the transmission
of
data
packets is enabled in the MAC layer. When [ENABLE] = 1 and [DATA_PKT_TX_EN] = 0, the MAC
layer
suppresses the transmission of new data and packets for the LMAC. */
uint64_t int_beat_gen : 1; /**< [ 12: 12](R/W) Internal beat generation. This bit is used for debug/test purposes and should be clear
during normal operation. When set, the LMAC's PCS layer ignores RXVALID and
TXREADY/TXCREDIT from the associated SerDes lanes, internally generates fake (idle)
RXVALID and TXCREDIT pulses, and suppresses transmission to the SerDes. */
uint64_t mix_en : 1; /**< [ 11: 11](R/W) Must be 0. */
uint64_t lmac_type : 3; /**< [ 10: 8](R/W) Logical MAC/PCS/prt type:
\<pre\>
LMAC_TYPE Name Description NUM_PCS_LANES
----------------------------------------------------------
0x0 SGMII SGMII/1000BASE-X 1
0x1 XAUI 10GBASE-X/XAUI or DXAUI 4
0x2 RXAUI Reduced XAUI 2
0x3 10G_R 10GBASE-R 1
0x4 40G_R 40GBASE-R 4
0x5 -- Reserved -
0x6 QSGMII QSGMII 1
Other -- Reserved -
\</pre\>
NUM_PCS_LANES specifies the number of PCS lanes that are valid for
each type. Each valid PCS lane is mapped to a physical SerDes lane
based on the programming of [LANE_TO_SDS].
This field must be programmed to its final value before [ENABLE] is set, and must not
be changed when [ENABLE] = 1. */
uint64_t lane_to_sds : 8; /**< [ 7: 0](R/W) PCS lane-to-SerDes mapping.
This is an array of 2-bit values that map each logical PCS lane to a
physical SerDes lane, as follows:
\<pre\>
Bits Description Reset value
------------------------------------------
\<7:6\> PCS Lane 3 SerDes ID 0x3
\<5:4\> PCS Lane 2 SerDes ID 0x2
\<3:2\> PCS Lane 1 SerDes ID 0x1
\<1:0\> PCS Lane 0 SerDes ID 0x0
\</pre\>
PCS lanes 0 through NUM_PCS_LANES-1 are valid, where NUM_PCS_LANES is a function of the
logical MAC/PCS type (see [LMAC_TYPE]). For example, when [LMAC_TYPE] = SGMII,
then NUM_PCS_LANES = 1, PCS lane 0 is valid and the associated physical SerDes lanes
are selected by bits \<1:0\>.
For 40GBASE-R ([LMAC_TYPE] = 40G_R), all four PCS lanes are valid, and the PCS lane IDs
determine the block distribution order and associated alignment markers on the transmit
side. This is not necessarily the order in which PCS lanes receive data because 802.3
allows multilane BASE-R receive lanes to be reordered. When a lane (called service
interface in 802.3ba-2010) has achieved alignment marker lock on the receive side (i.e.
the associated BGX()_SPU()_BR_ALGN_STATUS[MARKER_LOCK] = 1), then the actual
detected RX PCS lane number is recorded in the corresponding
BGX()_SPU()_BR_LANE_MAP[LNx_MAPPING].
For QSGMII, [LANE_TO_SDS]\<1:0\> for LMAC 0 selects the physical SerDes lane shared by four
LMACs, and [LANE_TO_SDS]\<1:0\> must be unique for each of the four LMACs.
This field must be programmed to its final value before [ENABLE] is set, and
must not be changed when [ENABLE] = 1. */
#else /* Word 0 - Little Endian */
uint64_t lane_to_sds : 8; /**< [ 7: 0](R/W) PCS lane-to-SerDes mapping.
This is an array of 2-bit values that map each logical PCS lane to a
physical SerDes lane, as follows:
\<pre\>
Bits Description Reset value
------------------------------------------
\<7:6\> PCS Lane 3 SerDes ID 0x3
\<5:4\> PCS Lane 2 SerDes ID 0x2
\<3:2\> PCS Lane 1 SerDes ID 0x1
\<1:0\> PCS Lane 0 SerDes ID 0x0
\</pre\>
PCS lanes 0 through NUM_PCS_LANES-1 are valid, where NUM_PCS_LANES is a function of the
logical MAC/PCS type (see [LMAC_TYPE]). For example, when [LMAC_TYPE] = SGMII,
then NUM_PCS_LANES = 1, PCS lane 0 is valid and the associated physical SerDes lanes
are selected by bits \<1:0\>.
For 40GBASE-R ([LMAC_TYPE] = 40G_R), all four PCS lanes are valid, and the PCS lane IDs
determine the block distribution order and associated alignment markers on the transmit
side. This is not necessarily the order in which PCS lanes receive data because 802.3
allows multilane BASE-R receive lanes to be reordered. When a lane (called service
interface in 802.3ba-2010) has achieved alignment marker lock on the receive side (i.e.
the associated BGX()_SPU()_BR_ALGN_STATUS[MARKER_LOCK] = 1), then the actual
detected RX PCS lane number is recorded in the corresponding
BGX()_SPU()_BR_LANE_MAP[LNx_MAPPING].
For QSGMII, [LANE_TO_SDS]\<1:0\> for LMAC 0 selects the physical SerDes lane shared by four
LMACs, and [LANE_TO_SDS]\<1:0\> must be unique for each of the four LMACs.
This field must be programmed to its final value before [ENABLE] is set, and
must not be changed when [ENABLE] = 1. */
uint64_t lmac_type : 3; /**< [ 10: 8](R/W) Logical MAC/PCS/prt type:
\<pre\>
LMAC_TYPE Name Description NUM_PCS_LANES
----------------------------------------------------------
0x0 SGMII SGMII/1000BASE-X 1
0x1 XAUI 10GBASE-X/XAUI or DXAUI 4
0x2 RXAUI Reduced XAUI 2
0x3 10G_R 10GBASE-R 1
0x4 40G_R 40GBASE-R 4
0x5 -- Reserved -
0x6 QSGMII QSGMII 1
Other -- Reserved -
\</pre\>
NUM_PCS_LANES specifies the number of PCS lanes that are valid for
each type. Each valid PCS lane is mapped to a physical SerDes lane
based on the programming of [LANE_TO_SDS].
This field must be programmed to its final value before [ENABLE] is set, and must not
be changed when [ENABLE] = 1. */
uint64_t mix_en : 1; /**< [ 11: 11](R/W) Must be 0. */
uint64_t int_beat_gen : 1; /**< [ 12: 12](R/W) Internal beat generation. This bit is used for debug/test purposes and should be clear
during normal operation. When set, the LMAC's PCS layer ignores RXVALID and
TXREADY/TXCREDIT from the associated SerDes lanes, internally generates fake (idle)
RXVALID and TXCREDIT pulses, and suppresses transmission to the SerDes. */
uint64_t data_pkt_tx_en : 1; /**< [ 13: 13](R/W) Data packet transmit enable. When [ENABLE] = 1 and [DATA_PKT_TX_EN] = 1, the transmission
of
data
packets is enabled in the MAC layer. When [ENABLE] = 1 and [DATA_PKT_TX_EN] = 0, the MAC
layer
suppresses the transmission of new data and packets for the LMAC. */
uint64_t data_pkt_rx_en : 1; /**< [ 14: 14](R/W) Data packet receive enable. When [ENABLE] = 1 and [DATA_PKT_RX_EN] = 1, the reception of
data
packets is enabled in the MAC layer. When [ENABLE] = 1 and [DATA_PKT_RX_EN] = 0, the MAC
layer
drops received data and flow-control packets. */
uint64_t enable : 1; /**< [ 15: 15](R/W) Logical MAC/PCS enable. This is the master enable for the LMAC. When clear, all the
dedicated BGX context state for the LMAC (state machines, FIFOs, counters, etc.) is reset,
and LMAC access to shared BGX resources (data path, SerDes lanes) is disabled.
When set, LMAC operation is enabled, including link bring-up, synchronization, and
transmit/receive of idles and fault sequences. Note that configuration registers for an
LMAC are not reset when this bit is clear, allowing software to program them before
setting this bit to enable the LMAC. This bit together with [LMAC_TYPE] is also used to
enable the clocking to the GMP and/or blocks of the Super path (SMU and SPU). CMR clocking
is enabled when any of the paths are enabled. */
uint64_t x2p_select : 1; /**< [ 16: 16](R/W) Selects interior side X2P interface over which the LMAC will communicate:
\<pre\>
[X2P_SELECT] Name Connected block
-------------------------------------------
0 X2P0 NIC
1 X2P1 Reserved
\</pre\> */
uint64_t p2x_select : 1; /**< [ 17: 17](R/W) Selects interior side P2X interface over which the LMAC will communicate:
\<pre\>
[P2X_SELECT] Name Connected block
-------------------------------------------
0 P2X0 NIC
1 P2X1 Reserved
\</pre\> */
uint64_t reserved_18_63 : 46;
#endif /* Word 0 - End */
} cn81xx;
struct bdk_bgxx_cmrx_config_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t enable : 1; /**< [ 15: 15](R/W) Logical MAC/PCS enable. This is the master enable for the LMAC. When clear, all the
dedicated BGX context state for the LMAC (state machines, FIFOs, counters, etc.) is reset,
and LMAC access to shared BGX resources (SMU/SPU data path, SerDes lanes) is disabled.
When set, LMAC operation is enabled, including link bring-up, synchronization, and
transmit/receive of idles and fault sequences. Note that configuration registers for an
LMAC are not reset when this bit is clear, allowing software to program them before
setting this bit to enable the LMAC. This bit together with [LMAC_TYPE] is also used to
enable the clocking to the GMP and/or blocks of the Super path (SMU and SPU). CMR clocking
is enabled when any of the paths are enabled. */
uint64_t data_pkt_rx_en : 1; /**< [ 14: 14](R/W) Data packet receive enable. When [ENABLE] = 1 and [DATA_PKT_RX_EN] = 1, the reception of
data
packets is enabled in the MAC layer. When [ENABLE] = 1 and [DATA_PKT_RX_EN] = 0, the MAC
layer
drops received data and flow-control packets. */
uint64_t data_pkt_tx_en : 1; /**< [ 13: 13](R/W) Data packet transmit enable. When [ENABLE] = 1 and [DATA_PKT_TX_EN] = 1, the transmission
of
data
packets is enabled in the MAC layer. When [ENABLE] = 1 and [DATA_PKT_TX_EN] = 0, the MAC
layer
suppresses the transmission of new data and packets for the LMAC. */
uint64_t int_beat_gen : 1; /**< [ 12: 12](R/W) Internal beat generation. This bit is used for debug/test purposes and should be clear
during normal operation. When set, the LMAC's PCS layer ignores RXVALID and
TXREADY/TXCREDIT from the associated SerDes lanes, internally generates fake (idle)
RXVALID and TXCREDIT pulses, and suppresses transmission to the SerDes. */
uint64_t mix_en : 1; /**< [ 11: 11](R/W) Must be 0. */
uint64_t lmac_type : 3; /**< [ 10: 8](R/W) Logical MAC/PCS/prt type:
\<pre\>
LMAC_TYPE Name Description NUM_PCS_LANES
----------------------------------------------------------
0x0 SGMII SGMII/1000BASE-X 1
0x1 XAUI 10GBASE-X/XAUI or DXAUI 4
0x2 RXAUI Reduced XAUI 2
0x3 10G_R 10GBASE-R 1
0x4 40G_R 40GBASE-R 4
Other -- Reserved -
\</pre\>
NUM_PCS_LANES specifies the number of PCS lanes that are valid for
each type. Each valid PCS lane is mapped to a physical SerDes lane
based on the programming of [LANE_TO_SDS].
This field must be programmed to its final value before [ENABLE] is set, and must not
be changed when [ENABLE] = 1. */
uint64_t lane_to_sds : 8; /**< [ 7: 0](R/W) PCS lane-to-SerDes mapping.
This is an array of 2-bit values that map each logical PCS lane to a
physical SerDes lane, as follows:
\<pre\>
Bits Description Reset value
------------------------------------------
\<7:6\> PCS Lane 3 SerDes ID 0x3
\<5:4\> PCS Lane 2 SerDes ID 0x2
\<3:2\> PCS Lane 1 SerDes ID 0x1
\<1:0\> PCS Lane 0 SerDes ID 0x0
\</pre\>
PCS lanes 0 through NUM_PCS_LANES-1 are valid, where NUM_PCS_LANES is a function of the
logical MAC/PCS type (see [LMAC_TYPE]). For example, when [LMAC_TYPE] = SGMII,
then NUM_PCS_LANES = 1, PCS lane 0 is valid and the associated physical SerDes lanes
are selected by bits \<1:0\>.
For 40GBASE-R ([LMAC_TYPE] = 40G_R), all four PCS lanes are valid, and the PCS lane IDs
determine the block distribution order and associated alignment markers on the transmit
side. This is not necessarily the order in which PCS lanes receive data because 802.3
allows multilane BASE-R receive lanes to be reordered. When a lane (called service
interface in 802.3ba-2010) has achieved alignment marker lock on the receive side (i.e.
the associated BGX()_SPU()_BR_ALGN_STATUS[MARKER_LOCK] = 1), then the actual
detected RX PCS lane number is recorded in the corresponding
BGX()_SPU()_BR_LANE_MAP[LNx_MAPPING].
This field must be programmed to its final value before [ENABLE] is set, and must not
be changed when [ENABLE] = 1. */
#else /* Word 0 - Little Endian */
uint64_t lane_to_sds : 8; /**< [ 7: 0](R/W) PCS lane-to-SerDes mapping.
This is an array of 2-bit values that map each logical PCS lane to a
physical SerDes lane, as follows:
\<pre\>
Bits Description Reset value
------------------------------------------
\<7:6\> PCS Lane 3 SerDes ID 0x3
\<5:4\> PCS Lane 2 SerDes ID 0x2
\<3:2\> PCS Lane 1 SerDes ID 0x1
\<1:0\> PCS Lane 0 SerDes ID 0x0
\</pre\>
PCS lanes 0 through NUM_PCS_LANES-1 are valid, where NUM_PCS_LANES is a function of the
logical MAC/PCS type (see [LMAC_TYPE]). For example, when [LMAC_TYPE] = SGMII,
then NUM_PCS_LANES = 1, PCS lane 0 is valid and the associated physical SerDes lanes
are selected by bits \<1:0\>.
For 40GBASE-R ([LMAC_TYPE] = 40G_R), all four PCS lanes are valid, and the PCS lane IDs
determine the block distribution order and associated alignment markers on the transmit
side. This is not necessarily the order in which PCS lanes receive data because 802.3
allows multilane BASE-R receive lanes to be reordered. When a lane (called service
interface in 802.3ba-2010) has achieved alignment marker lock on the receive side (i.e.
the associated BGX()_SPU()_BR_ALGN_STATUS[MARKER_LOCK] = 1), then the actual
detected RX PCS lane number is recorded in the corresponding
BGX()_SPU()_BR_LANE_MAP[LNx_MAPPING].
This field must be programmed to its final value before [ENABLE] is set, and must not
be changed when [ENABLE] = 1. */
uint64_t lmac_type : 3; /**< [ 10: 8](R/W) Logical MAC/PCS/prt type:
\<pre\>
LMAC_TYPE Name Description NUM_PCS_LANES
----------------------------------------------------------
0x0 SGMII SGMII/1000BASE-X 1
0x1 XAUI 10GBASE-X/XAUI or DXAUI 4
0x2 RXAUI Reduced XAUI 2
0x3 10G_R 10GBASE-R 1
0x4 40G_R 40GBASE-R 4
Other -- Reserved -
\</pre\>
NUM_PCS_LANES specifies the number of PCS lanes that are valid for
each type. Each valid PCS lane is mapped to a physical SerDes lane
based on the programming of [LANE_TO_SDS].
This field must be programmed to its final value before [ENABLE] is set, and must not
be changed when [ENABLE] = 1. */
uint64_t mix_en : 1; /**< [ 11: 11](R/W) Must be 0. */
uint64_t int_beat_gen : 1; /**< [ 12: 12](R/W) Internal beat generation. This bit is used for debug/test purposes and should be clear
during normal operation. When set, the LMAC's PCS layer ignores RXVALID and
TXREADY/TXCREDIT from the associated SerDes lanes, internally generates fake (idle)
RXVALID and TXCREDIT pulses, and suppresses transmission to the SerDes. */
uint64_t data_pkt_tx_en : 1; /**< [ 13: 13](R/W) Data packet transmit enable. When [ENABLE] = 1 and [DATA_PKT_TX_EN] = 1, the transmission
of
data
packets is enabled in the MAC layer. When [ENABLE] = 1 and [DATA_PKT_TX_EN] = 0, the MAC
layer
suppresses the transmission of new data and packets for the LMAC. */
uint64_t data_pkt_rx_en : 1; /**< [ 14: 14](R/W) Data packet receive enable. When [ENABLE] = 1 and [DATA_PKT_RX_EN] = 1, the reception of
data
packets is enabled in the MAC layer. When [ENABLE] = 1 and [DATA_PKT_RX_EN] = 0, the MAC
layer
drops received data and flow-control packets. */
uint64_t enable : 1; /**< [ 15: 15](R/W) Logical MAC/PCS enable. This is the master enable for the LMAC. When clear, all the
dedicated BGX context state for the LMAC (state machines, FIFOs, counters, etc.) is reset,
and LMAC access to shared BGX resources (SMU/SPU data path, SerDes lanes) is disabled.
When set, LMAC operation is enabled, including link bring-up, synchronization, and
transmit/receive of idles and fault sequences. Note that configuration registers for an
LMAC are not reset when this bit is clear, allowing software to program them before
setting this bit to enable the LMAC. This bit together with [LMAC_TYPE] is also used to
enable the clocking to the GMP and/or blocks of the Super path (SMU and SPU). CMR clocking
is enabled when any of the paths are enabled. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} cn88xx;
/* struct bdk_bgxx_cmrx_config_s cn83xx; */
};
typedef union bdk_bgxx_cmrx_config bdk_bgxx_cmrx_config_t;
static inline uint64_t BDK_BGXX_CMRX_CONFIG(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_CONFIG(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000000ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000000ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000000ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_CONFIG", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_CONFIG(a,b) bdk_bgxx_cmrx_config_t
#define bustype_BDK_BGXX_CMRX_CONFIG(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_CONFIG(a,b) "BGXX_CMRX_CONFIG"
#define device_bar_BDK_BGXX_CMRX_CONFIG(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_CONFIG(a,b) (a)
#define arguments_BDK_BGXX_CMRX_CONFIG(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_int
*
* BGX CMR Interrupt Register
*/
union bdk_bgxx_cmrx_int
{
uint64_t u;
struct bdk_bgxx_cmrx_int_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_4_63 : 60;
uint64_t nic_nxc : 1; /**< [ 3: 3](R/W1C/H) TX channel out-of-range from NIC interface.
Reported on this LMAC for ids in the range of LMAC_ID+4, LMAC_ID+8 and LMAC_ID+12.
Reported regardless of LMAC enable or P2X_SELECT association for this LMAC. */
uint64_t pko_nxc : 1; /**< [ 2: 2](R/W1C/H) Reserved. */
uint64_t overflw : 1; /**< [ 1: 1](R/W1C/H) RX overflow. */
uint64_t pause_drp : 1; /**< [ 0: 0](R/W1C/H) RX PAUSE packet was dropped due to full RXB FIFO or during partner reset. */
#else /* Word 0 - Little Endian */
uint64_t pause_drp : 1; /**< [ 0: 0](R/W1C/H) RX PAUSE packet was dropped due to full RXB FIFO or during partner reset. */
uint64_t overflw : 1; /**< [ 1: 1](R/W1C/H) RX overflow. */
uint64_t pko_nxc : 1; /**< [ 2: 2](R/W1C/H) Reserved. */
uint64_t nic_nxc : 1; /**< [ 3: 3](R/W1C/H) TX channel out-of-range from NIC interface.
Reported on this LMAC for ids in the range of LMAC_ID+4, LMAC_ID+8 and LMAC_ID+12.
Reported regardless of LMAC enable or P2X_SELECT association for this LMAC. */
uint64_t reserved_4_63 : 60;
#endif /* Word 0 - End */
} s;
struct bdk_bgxx_cmrx_int_cn81xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_4_63 : 60;
uint64_t nic_nxc : 1; /**< [ 3: 3](R/W1C/H) TX channel out-of-range from NIC interface. */
uint64_t pko_nxc : 1; /**< [ 2: 2](R/W1C/H) Reserved. */
uint64_t overflw : 1; /**< [ 1: 1](R/W1C/H) RX overflow. */
uint64_t pause_drp : 1; /**< [ 0: 0](R/W1C/H) RX PAUSE packet was dropped due to full RXB FIFO or during partner reset. */
#else /* Word 0 - Little Endian */
uint64_t pause_drp : 1; /**< [ 0: 0](R/W1C/H) RX PAUSE packet was dropped due to full RXB FIFO or during partner reset. */
uint64_t overflw : 1; /**< [ 1: 1](R/W1C/H) RX overflow. */
uint64_t pko_nxc : 1; /**< [ 2: 2](R/W1C/H) Reserved. */
uint64_t nic_nxc : 1; /**< [ 3: 3](R/W1C/H) TX channel out-of-range from NIC interface. */
uint64_t reserved_4_63 : 60;
#endif /* Word 0 - End */
} cn81xx;
struct bdk_bgxx_cmrx_int_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_3_63 : 61;
uint64_t pko_nxc : 1; /**< [ 2: 2](R/W1C/H) TX channel out-of-range from TNS/NIC interface. */
uint64_t overflw : 1; /**< [ 1: 1](R/W1C/H) RX overflow. */
uint64_t pause_drp : 1; /**< [ 0: 0](R/W1C/H) RX PAUSE packet was dropped due to full RXB FIFO or during partner reset. */
#else /* Word 0 - Little Endian */
uint64_t pause_drp : 1; /**< [ 0: 0](R/W1C/H) RX PAUSE packet was dropped due to full RXB FIFO or during partner reset. */
uint64_t overflw : 1; /**< [ 1: 1](R/W1C/H) RX overflow. */
uint64_t pko_nxc : 1; /**< [ 2: 2](R/W1C/H) TX channel out-of-range from TNS/NIC interface. */
uint64_t reserved_3_63 : 61;
#endif /* Word 0 - End */
} cn88xx;
struct bdk_bgxx_cmrx_int_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_4_63 : 60;
uint64_t nic_nxc : 1; /**< [ 3: 3](R/W1C/H) TX channel out-of-range from NIC interface.
Reported on this LMAC for ids in the range of LMAC_ID+4, LMAC_ID+8 and LMAC_ID+12.
Reported regardless of LMAC enable or P2X_SELECT association for this LMAC. */
uint64_t pko_nxc : 1; /**< [ 2: 2](R/W1C/H) TX channel out-of-range from PKO interface.
Reported on this LMAC for ids in the range of LMAC_ID+4, LMAC_ID+8 and LMAC_ID+12.
Reported regardless of LMAC enable or P2X_SELECT association for this LMAC. */
uint64_t overflw : 1; /**< [ 1: 1](R/W1C/H) RX overflow. */
uint64_t pause_drp : 1; /**< [ 0: 0](R/W1C/H) RX PAUSE packet was dropped due to full RXB FIFO or during partner reset. */
#else /* Word 0 - Little Endian */
uint64_t pause_drp : 1; /**< [ 0: 0](R/W1C/H) RX PAUSE packet was dropped due to full RXB FIFO or during partner reset. */
uint64_t overflw : 1; /**< [ 1: 1](R/W1C/H) RX overflow. */
uint64_t pko_nxc : 1; /**< [ 2: 2](R/W1C/H) TX channel out-of-range from PKO interface.
Reported on this LMAC for ids in the range of LMAC_ID+4, LMAC_ID+8 and LMAC_ID+12.
Reported regardless of LMAC enable or P2X_SELECT association for this LMAC. */
uint64_t nic_nxc : 1; /**< [ 3: 3](R/W1C/H) TX channel out-of-range from NIC interface.
Reported on this LMAC for ids in the range of LMAC_ID+4, LMAC_ID+8 and LMAC_ID+12.
Reported regardless of LMAC enable or P2X_SELECT association for this LMAC. */
uint64_t reserved_4_63 : 60;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_cmrx_int bdk_bgxx_cmrx_int_t;
static inline uint64_t BDK_BGXX_CMRX_INT(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_INT(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000040ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000040ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000040ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_INT", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_INT(a,b) bdk_bgxx_cmrx_int_t
#define bustype_BDK_BGXX_CMRX_INT(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_INT(a,b) "BGXX_CMRX_INT"
#define device_bar_BDK_BGXX_CMRX_INT(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_INT(a,b) (a)
#define arguments_BDK_BGXX_CMRX_INT(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_int_ena_w1c
*
* BGX CMR Interrupt Enable Clear Register
* This register clears interrupt enable bits.
*/
union bdk_bgxx_cmrx_int_ena_w1c
{
uint64_t u;
struct bdk_bgxx_cmrx_int_ena_w1c_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_4_63 : 60;
uint64_t nic_nxc : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR(0..3)_INT[NIC_NXC]. */
uint64_t pko_nxc : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR(0..3)_INT[PKO_NXC]. */
uint64_t overflw : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR(0..3)_INT[OVERFLW]. */
uint64_t pause_drp : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR(0..3)_INT[PAUSE_DRP]. */
#else /* Word 0 - Little Endian */
uint64_t pause_drp : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR(0..3)_INT[PAUSE_DRP]. */
uint64_t overflw : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR(0..3)_INT[OVERFLW]. */
uint64_t pko_nxc : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR(0..3)_INT[PKO_NXC]. */
uint64_t nic_nxc : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR(0..3)_INT[NIC_NXC]. */
uint64_t reserved_4_63 : 60;
#endif /* Word 0 - End */
} s;
struct bdk_bgxx_cmrx_int_ena_w1c_cn81xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_4_63 : 60;
uint64_t nic_nxc : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR(0..3)_INT[NIC_NXC]. */
uint64_t pko_nxc : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR(0..3)_INT[PKO_NXC]. */
uint64_t overflw : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR(0..3)_INT[OVERFLW]. */
uint64_t pause_drp : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR(0..3)_INT[PAUSE_DRP]. */
#else /* Word 0 - Little Endian */
uint64_t pause_drp : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR(0..3)_INT[PAUSE_DRP]. */
uint64_t overflw : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR(0..3)_INT[OVERFLW]. */
uint64_t pko_nxc : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR(0..3)_INT[PKO_NXC]. */
uint64_t nic_nxc : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR(0..3)_INT[NIC_NXC]. */
uint64_t reserved_4_63 : 60;
#endif /* Word 0 - End */
} cn81xx;
struct bdk_bgxx_cmrx_int_ena_w1c_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_3_63 : 61;
uint64_t pko_nxc : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR(0..3)_INT[PKO_NXC]. */
uint64_t overflw : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR(0..3)_INT[OVERFLW]. */
uint64_t pause_drp : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR(0..3)_INT[PAUSE_DRP]. */
#else /* Word 0 - Little Endian */
uint64_t pause_drp : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR(0..3)_INT[PAUSE_DRP]. */
uint64_t overflw : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR(0..3)_INT[OVERFLW]. */
uint64_t pko_nxc : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR(0..3)_INT[PKO_NXC]. */
uint64_t reserved_3_63 : 61;
#endif /* Word 0 - End */
} cn88xx;
struct bdk_bgxx_cmrx_int_ena_w1c_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_4_63 : 60;
uint64_t nic_nxc : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR(0..3)_INT[NIC_NXC]. */
uint64_t pko_nxc : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR(0..3)_INT[PKO_NXC]. */
uint64_t overflw : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR(0..3)_INT[OVERFLW]. */
uint64_t pause_drp : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR(0..3)_INT[PAUSE_DRP]. */
#else /* Word 0 - Little Endian */
uint64_t pause_drp : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR(0..3)_INT[PAUSE_DRP]. */
uint64_t overflw : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR(0..3)_INT[OVERFLW]. */
uint64_t pko_nxc : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR(0..3)_INT[PKO_NXC]. */
uint64_t nic_nxc : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR(0..3)_INT[NIC_NXC]. */
uint64_t reserved_4_63 : 60;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_cmrx_int_ena_w1c bdk_bgxx_cmrx_int_ena_w1c_t;
static inline uint64_t BDK_BGXX_CMRX_INT_ENA_W1C(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_INT_ENA_W1C(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000050ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000050ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000050ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_INT_ENA_W1C", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_INT_ENA_W1C(a,b) bdk_bgxx_cmrx_int_ena_w1c_t
#define bustype_BDK_BGXX_CMRX_INT_ENA_W1C(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_INT_ENA_W1C(a,b) "BGXX_CMRX_INT_ENA_W1C"
#define device_bar_BDK_BGXX_CMRX_INT_ENA_W1C(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_INT_ENA_W1C(a,b) (a)
#define arguments_BDK_BGXX_CMRX_INT_ENA_W1C(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_int_ena_w1s
*
* BGX CMR Interrupt Enable Set Register
* This register sets interrupt enable bits.
*/
union bdk_bgxx_cmrx_int_ena_w1s
{
uint64_t u;
struct bdk_bgxx_cmrx_int_ena_w1s_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_4_63 : 60;
uint64_t nic_nxc : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR(0..3)_INT[NIC_NXC]. */
uint64_t pko_nxc : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR(0..3)_INT[PKO_NXC]. */
uint64_t overflw : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR(0..3)_INT[OVERFLW]. */
uint64_t pause_drp : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR(0..3)_INT[PAUSE_DRP]. */
#else /* Word 0 - Little Endian */
uint64_t pause_drp : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR(0..3)_INT[PAUSE_DRP]. */
uint64_t overflw : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR(0..3)_INT[OVERFLW]. */
uint64_t pko_nxc : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR(0..3)_INT[PKO_NXC]. */
uint64_t nic_nxc : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR(0..3)_INT[NIC_NXC]. */
uint64_t reserved_4_63 : 60;
#endif /* Word 0 - End */
} s;
struct bdk_bgxx_cmrx_int_ena_w1s_cn81xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_4_63 : 60;
uint64_t nic_nxc : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR(0..3)_INT[NIC_NXC]. */
uint64_t pko_nxc : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR(0..3)_INT[PKO_NXC]. */
uint64_t overflw : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR(0..3)_INT[OVERFLW]. */
uint64_t pause_drp : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR(0..3)_INT[PAUSE_DRP]. */
#else /* Word 0 - Little Endian */
uint64_t pause_drp : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR(0..3)_INT[PAUSE_DRP]. */
uint64_t overflw : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR(0..3)_INT[OVERFLW]. */
uint64_t pko_nxc : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR(0..3)_INT[PKO_NXC]. */
uint64_t nic_nxc : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR(0..3)_INT[NIC_NXC]. */
uint64_t reserved_4_63 : 60;
#endif /* Word 0 - End */
} cn81xx;
struct bdk_bgxx_cmrx_int_ena_w1s_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_3_63 : 61;
uint64_t pko_nxc : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR(0..3)_INT[PKO_NXC]. */
uint64_t overflw : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR(0..3)_INT[OVERFLW]. */
uint64_t pause_drp : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR(0..3)_INT[PAUSE_DRP]. */
#else /* Word 0 - Little Endian */
uint64_t pause_drp : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR(0..3)_INT[PAUSE_DRP]. */
uint64_t overflw : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR(0..3)_INT[OVERFLW]. */
uint64_t pko_nxc : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR(0..3)_INT[PKO_NXC]. */
uint64_t reserved_3_63 : 61;
#endif /* Word 0 - End */
} cn88xx;
struct bdk_bgxx_cmrx_int_ena_w1s_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_4_63 : 60;
uint64_t nic_nxc : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR(0..3)_INT[NIC_NXC]. */
uint64_t pko_nxc : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR(0..3)_INT[PKO_NXC]. */
uint64_t overflw : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR(0..3)_INT[OVERFLW]. */
uint64_t pause_drp : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR(0..3)_INT[PAUSE_DRP]. */
#else /* Word 0 - Little Endian */
uint64_t pause_drp : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR(0..3)_INT[PAUSE_DRP]. */
uint64_t overflw : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR(0..3)_INT[OVERFLW]. */
uint64_t pko_nxc : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR(0..3)_INT[PKO_NXC]. */
uint64_t nic_nxc : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR(0..3)_INT[NIC_NXC]. */
uint64_t reserved_4_63 : 60;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_cmrx_int_ena_w1s bdk_bgxx_cmrx_int_ena_w1s_t;
static inline uint64_t BDK_BGXX_CMRX_INT_ENA_W1S(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_INT_ENA_W1S(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000058ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000058ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000058ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_INT_ENA_W1S", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_INT_ENA_W1S(a,b) bdk_bgxx_cmrx_int_ena_w1s_t
#define bustype_BDK_BGXX_CMRX_INT_ENA_W1S(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_INT_ENA_W1S(a,b) "BGXX_CMRX_INT_ENA_W1S"
#define device_bar_BDK_BGXX_CMRX_INT_ENA_W1S(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_INT_ENA_W1S(a,b) (a)
#define arguments_BDK_BGXX_CMRX_INT_ENA_W1S(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_int_w1s
*
* BGX CMR Interrupt Set Register
* This register sets interrupt bits.
*/
union bdk_bgxx_cmrx_int_w1s
{
uint64_t u;
struct bdk_bgxx_cmrx_int_w1s_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_4_63 : 60;
uint64_t nic_nxc : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..3)_CMR(0..3)_INT[NIC_NXC]. */
uint64_t pko_nxc : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..1)_CMR(0..3)_INT[PKO_NXC]. */
uint64_t overflw : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..1)_CMR(0..3)_INT[OVERFLW]. */
uint64_t pause_drp : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..1)_CMR(0..3)_INT[PAUSE_DRP]. */
#else /* Word 0 - Little Endian */
uint64_t pause_drp : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..1)_CMR(0..3)_INT[PAUSE_DRP]. */
uint64_t overflw : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..1)_CMR(0..3)_INT[OVERFLW]. */
uint64_t pko_nxc : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..1)_CMR(0..3)_INT[PKO_NXC]. */
uint64_t nic_nxc : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..3)_CMR(0..3)_INT[NIC_NXC]. */
uint64_t reserved_4_63 : 60;
#endif /* Word 0 - End */
} s;
struct bdk_bgxx_cmrx_int_w1s_cn81xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_4_63 : 60;
uint64_t nic_nxc : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..1)_CMR(0..3)_INT[NIC_NXC]. */
uint64_t pko_nxc : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..1)_CMR(0..3)_INT[PKO_NXC]. */
uint64_t overflw : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..1)_CMR(0..3)_INT[OVERFLW]. */
uint64_t pause_drp : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..1)_CMR(0..3)_INT[PAUSE_DRP]. */
#else /* Word 0 - Little Endian */
uint64_t pause_drp : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..1)_CMR(0..3)_INT[PAUSE_DRP]. */
uint64_t overflw : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..1)_CMR(0..3)_INT[OVERFLW]. */
uint64_t pko_nxc : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..1)_CMR(0..3)_INT[PKO_NXC]. */
uint64_t nic_nxc : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..1)_CMR(0..3)_INT[NIC_NXC]. */
uint64_t reserved_4_63 : 60;
#endif /* Word 0 - End */
} cn81xx;
struct bdk_bgxx_cmrx_int_w1s_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_3_63 : 61;
uint64_t pko_nxc : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..1)_CMR(0..3)_INT[PKO_NXC]. */
uint64_t overflw : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..1)_CMR(0..3)_INT[OVERFLW]. */
uint64_t pause_drp : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..1)_CMR(0..3)_INT[PAUSE_DRP]. */
#else /* Word 0 - Little Endian */
uint64_t pause_drp : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..1)_CMR(0..3)_INT[PAUSE_DRP]. */
uint64_t overflw : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..1)_CMR(0..3)_INT[OVERFLW]. */
uint64_t pko_nxc : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..1)_CMR(0..3)_INT[PKO_NXC]. */
uint64_t reserved_3_63 : 61;
#endif /* Word 0 - End */
} cn88xx;
struct bdk_bgxx_cmrx_int_w1s_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_4_63 : 60;
uint64_t nic_nxc : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..3)_CMR(0..3)_INT[NIC_NXC]. */
uint64_t pko_nxc : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..3)_CMR(0..3)_INT[PKO_NXC]. */
uint64_t overflw : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..3)_CMR(0..3)_INT[OVERFLW]. */
uint64_t pause_drp : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..3)_CMR(0..3)_INT[PAUSE_DRP]. */
#else /* Word 0 - Little Endian */
uint64_t pause_drp : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..3)_CMR(0..3)_INT[PAUSE_DRP]. */
uint64_t overflw : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..3)_CMR(0..3)_INT[OVERFLW]. */
uint64_t pko_nxc : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..3)_CMR(0..3)_INT[PKO_NXC]. */
uint64_t nic_nxc : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..3)_CMR(0..3)_INT[NIC_NXC]. */
uint64_t reserved_4_63 : 60;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_cmrx_int_w1s bdk_bgxx_cmrx_int_w1s_t;
static inline uint64_t BDK_BGXX_CMRX_INT_W1S(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_INT_W1S(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000048ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000048ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000048ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_INT_W1S", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_INT_W1S(a,b) bdk_bgxx_cmrx_int_w1s_t
#define bustype_BDK_BGXX_CMRX_INT_W1S(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_INT_W1S(a,b) "BGXX_CMRX_INT_W1S"
#define device_bar_BDK_BGXX_CMRX_INT_W1S(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_INT_W1S(a,b) (a)
#define arguments_BDK_BGXX_CMRX_INT_W1S(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_prt_cbfc_ctl
*
* BGX CMR LMAC PFC Control Registers
* See XOFF definition listed under BGX()_SMU()_CBFC_CTL.
*/
union bdk_bgxx_cmrx_prt_cbfc_ctl
{
uint64_t u;
struct bdk_bgxx_cmrx_prt_cbfc_ctl_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_32_63 : 32;
uint64_t phys_bp : 16; /**< [ 31: 16](R/W) When the hardware is backpressuring any LMACs. (from either DRF or PFC packets or
BGX()_CMR()_TX_OVR_BP[TX_CHAN_BP]) and all channels indicated by [PHYS_BP] are
backpressured,
simulate physical backpressure by deferring all packets on the transmitter.
If LMAC_TYPE != SGMII/QSGMII, BGX()_SMU()_CBFC_CTL[RX_EN] or
BGX()_SMU()_HG2_CONTROL[HG2RX_EN]
additionally need to be set. */
uint64_t reserved_0_15 : 16;
#else /* Word 0 - Little Endian */
uint64_t reserved_0_15 : 16;
uint64_t phys_bp : 16; /**< [ 31: 16](R/W) When the hardware is backpressuring any LMACs. (from either DRF or PFC packets or
BGX()_CMR()_TX_OVR_BP[TX_CHAN_BP]) and all channels indicated by [PHYS_BP] are
backpressured,
simulate physical backpressure by deferring all packets on the transmitter.
If LMAC_TYPE != SGMII/QSGMII, BGX()_SMU()_CBFC_CTL[RX_EN] or
BGX()_SMU()_HG2_CONTROL[HG2RX_EN]
additionally need to be set. */
uint64_t reserved_32_63 : 32;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_prt_cbfc_ctl_s cn81xx; */
struct bdk_bgxx_cmrx_prt_cbfc_ctl_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_32_63 : 32;
uint64_t phys_bp : 16; /**< [ 31: 16](R/W) If LMAC_TYPE != SGMII, and BGX()_SMU()_CBFC_CTL[RX_EN] or
BGX()_SMU()_HG2_CONTROL[HG2RX_EN] is set and the hardware is backpressuring any LMACs.
(from either PFC packets or BGX()_CMR()_TX_OVR_BP[TX_CHAN_BP]) and all
channels indicated by [PHYS_BP] are backpressured, simulate physical backpressure
by deferring all packets on the transmitter. */
uint64_t reserved_0_15 : 16;
#else /* Word 0 - Little Endian */
uint64_t reserved_0_15 : 16;
uint64_t phys_bp : 16; /**< [ 31: 16](R/W) If LMAC_TYPE != SGMII, and BGX()_SMU()_CBFC_CTL[RX_EN] or
BGX()_SMU()_HG2_CONTROL[HG2RX_EN] is set and the hardware is backpressuring any LMACs.
(from either PFC packets or BGX()_CMR()_TX_OVR_BP[TX_CHAN_BP]) and all
channels indicated by [PHYS_BP] are backpressured, simulate physical backpressure
by deferring all packets on the transmitter. */
uint64_t reserved_32_63 : 32;
#endif /* Word 0 - End */
} cn88xx;
struct bdk_bgxx_cmrx_prt_cbfc_ctl_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_32_63 : 32;
uint64_t phys_bp : 16; /**< [ 31: 16](R/W) When the hardware is backpressuring any LMACs. (from either DFC or PFC packets or
BGX()_CMR()_TX_OVR_BP[TX_CHAN_BP]) and all channels indicated by [PHYS_BP] are
backpressured,
simulate physical backpressure by deferring all packets on the transmitter.
(i.e. signal to the mac an assertion of physical backpressure).
If LMAC_TYPE != SGMII/QSGMII, BGX()_SMU()_CBFC_CTL[RX_EN] or
BGX()_SMU()_HG2_CONTROL[HG2RX_EN]
additionally need to be set. */
uint64_t reserved_0_15 : 16;
#else /* Word 0 - Little Endian */
uint64_t reserved_0_15 : 16;
uint64_t phys_bp : 16; /**< [ 31: 16](R/W) When the hardware is backpressuring any LMACs. (from either DFC or PFC packets or
BGX()_CMR()_TX_OVR_BP[TX_CHAN_BP]) and all channels indicated by [PHYS_BP] are
backpressured,
simulate physical backpressure by deferring all packets on the transmitter.
(i.e. signal to the mac an assertion of physical backpressure).
If LMAC_TYPE != SGMII/QSGMII, BGX()_SMU()_CBFC_CTL[RX_EN] or
BGX()_SMU()_HG2_CONTROL[HG2RX_EN]
additionally need to be set. */
uint64_t reserved_32_63 : 32;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_cmrx_prt_cbfc_ctl bdk_bgxx_cmrx_prt_cbfc_ctl_t;
static inline uint64_t BDK_BGXX_CMRX_PRT_CBFC_CTL(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_PRT_CBFC_CTL(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000508ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000508ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000508ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_PRT_CBFC_CTL", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_PRT_CBFC_CTL(a,b) bdk_bgxx_cmrx_prt_cbfc_ctl_t
#define bustype_BDK_BGXX_CMRX_PRT_CBFC_CTL(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_PRT_CBFC_CTL(a,b) "BGXX_CMRX_PRT_CBFC_CTL"
#define device_bar_BDK_BGXX_CMRX_PRT_CBFC_CTL(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_PRT_CBFC_CTL(a,b) (a)
#define arguments_BDK_BGXX_CMRX_PRT_CBFC_CTL(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_rx_bp_drop
*
* BGX Receive Backpressure Drop Register
*/
union bdk_bgxx_cmrx_rx_bp_drop
{
uint64_t u;
struct bdk_bgxx_cmrx_rx_bp_drop_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_7_63 : 57;
uint64_t mark : 7; /**< [ 6: 0](R/W) Number of eight-byte cycles to reserve in the RX FIFO. When the number of free
entries in the RX FIFO is less than or equal to [MARK], incoming packet data is
dropped. [MARK] additionally indicates the number of entries to reserve in the RX FIFO for
closing partially received packets. [MARK] should typically be programmed to its reset
value; failure to program correctly can lead to system instability. */
#else /* Word 0 - Little Endian */
uint64_t mark : 7; /**< [ 6: 0](R/W) Number of eight-byte cycles to reserve in the RX FIFO. When the number of free
entries in the RX FIFO is less than or equal to [MARK], incoming packet data is
dropped. [MARK] additionally indicates the number of entries to reserve in the RX FIFO for
closing partially received packets. [MARK] should typically be programmed to its reset
value; failure to program correctly can lead to system instability. */
uint64_t reserved_7_63 : 57;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_rx_bp_drop_s cn; */
};
typedef union bdk_bgxx_cmrx_rx_bp_drop bdk_bgxx_cmrx_rx_bp_drop_t;
static inline uint64_t BDK_BGXX_CMRX_RX_BP_DROP(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_RX_BP_DROP(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e00000c8ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e00000c8ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e00000c8ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_RX_BP_DROP", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_RX_BP_DROP(a,b) bdk_bgxx_cmrx_rx_bp_drop_t
#define bustype_BDK_BGXX_CMRX_RX_BP_DROP(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_RX_BP_DROP(a,b) "BGXX_CMRX_RX_BP_DROP"
#define device_bar_BDK_BGXX_CMRX_RX_BP_DROP(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_RX_BP_DROP(a,b) (a)
#define arguments_BDK_BGXX_CMRX_RX_BP_DROP(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_rx_bp_off
*
* BGX Receive Backpressure Off Register
*/
union bdk_bgxx_cmrx_rx_bp_off
{
uint64_t u;
struct bdk_bgxx_cmrx_rx_bp_off_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_7_63 : 57;
uint64_t mark : 7; /**< [ 6: 0](R/W) Low watermark (number of eight-byte cycles to deassert backpressure). Level is also used
to exit the overflow dropping state. */
#else /* Word 0 - Little Endian */
uint64_t mark : 7; /**< [ 6: 0](R/W) Low watermark (number of eight-byte cycles to deassert backpressure). Level is also used
to exit the overflow dropping state. */
uint64_t reserved_7_63 : 57;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_rx_bp_off_s cn; */
};
typedef union bdk_bgxx_cmrx_rx_bp_off bdk_bgxx_cmrx_rx_bp_off_t;
static inline uint64_t BDK_BGXX_CMRX_RX_BP_OFF(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_RX_BP_OFF(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e00000d8ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e00000d8ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e00000d8ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_RX_BP_OFF", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_RX_BP_OFF(a,b) bdk_bgxx_cmrx_rx_bp_off_t
#define bustype_BDK_BGXX_CMRX_RX_BP_OFF(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_RX_BP_OFF(a,b) "BGXX_CMRX_RX_BP_OFF"
#define device_bar_BDK_BGXX_CMRX_RX_BP_OFF(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_RX_BP_OFF(a,b) (a)
#define arguments_BDK_BGXX_CMRX_RX_BP_OFF(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_rx_bp_on
*
* BGX Receive Backpressure On Register
*/
union bdk_bgxx_cmrx_rx_bp_on
{
uint64_t u;
struct bdk_bgxx_cmrx_rx_bp_on_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_12_63 : 52;
uint64_t mark : 12; /**< [ 11: 0](R/W) High watermark. Buffer depth in multiple of 16-bytes, at which BGX will
assert backpressure for each individual LMAC. Must satisfy:
BGX()_CMR()_RX_BP_OFF[MARK] \<= BGX()_CMR()_RX_BP_ON[MARK] \<
(FIFO_SIZE - BGX()_CMR()_RX_BP_DROP[MARK]).
A value of 0x0 immediately asserts backpressure.
The recommended value is 1/4th the size of the per-LMAC RX FIFO_SIZE as
determined by BGX()_CMR_RX_LMACS[LMACS]. For example in SGMII mode with
four LMACs of type SGMII, where BGX()_CMR_RX_LMACS[LMACS]=0x4, there is
16 KB of buffering. The recommended 1/4th size of that 16 KB is 4 KB, which
in units of 16 bytes gives [MARK] = 0x100 (the reset value). */
#else /* Word 0 - Little Endian */
uint64_t mark : 12; /**< [ 11: 0](R/W) High watermark. Buffer depth in multiple of 16-bytes, at which BGX will
assert backpressure for each individual LMAC. Must satisfy:
BGX()_CMR()_RX_BP_OFF[MARK] \<= BGX()_CMR()_RX_BP_ON[MARK] \<
(FIFO_SIZE - BGX()_CMR()_RX_BP_DROP[MARK]).
A value of 0x0 immediately asserts backpressure.
The recommended value is 1/4th the size of the per-LMAC RX FIFO_SIZE as
determined by BGX()_CMR_RX_LMACS[LMACS]. For example in SGMII mode with
four LMACs of type SGMII, where BGX()_CMR_RX_LMACS[LMACS]=0x4, there is
16 KB of buffering. The recommended 1/4th size of that 16 KB is 4 KB, which
in units of 16 bytes gives [MARK] = 0x100 (the reset value). */
uint64_t reserved_12_63 : 52;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_rx_bp_on_s cn; */
};
typedef union bdk_bgxx_cmrx_rx_bp_on bdk_bgxx_cmrx_rx_bp_on_t;
static inline uint64_t BDK_BGXX_CMRX_RX_BP_ON(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_RX_BP_ON(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e00000d0ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e00000d0ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e00000d0ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_RX_BP_ON", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_RX_BP_ON(a,b) bdk_bgxx_cmrx_rx_bp_on_t
#define bustype_BDK_BGXX_CMRX_RX_BP_ON(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_RX_BP_ON(a,b) "BGXX_CMRX_RX_BP_ON"
#define device_bar_BDK_BGXX_CMRX_RX_BP_ON(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_RX_BP_ON(a,b) (a)
#define arguments_BDK_BGXX_CMRX_RX_BP_ON(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_rx_bp_status
*
* BGX CMR Receive Backpressure Status Registers
*/
union bdk_bgxx_cmrx_rx_bp_status
{
uint64_t u;
struct bdk_bgxx_cmrx_rx_bp_status_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_1_63 : 63;
uint64_t bp : 1; /**< [ 0: 0](RO/H) Per-LMAC backpressure status.
0 = LMAC is not backpressured.
1 = LMAC is backpressured. */
#else /* Word 0 - Little Endian */
uint64_t bp : 1; /**< [ 0: 0](RO/H) Per-LMAC backpressure status.
0 = LMAC is not backpressured.
1 = LMAC is backpressured. */
uint64_t reserved_1_63 : 63;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_rx_bp_status_s cn; */
};
typedef union bdk_bgxx_cmrx_rx_bp_status bdk_bgxx_cmrx_rx_bp_status_t;
static inline uint64_t BDK_BGXX_CMRX_RX_BP_STATUS(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_RX_BP_STATUS(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e00000f0ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e00000f0ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e00000f0ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_RX_BP_STATUS", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_RX_BP_STATUS(a,b) bdk_bgxx_cmrx_rx_bp_status_t
#define bustype_BDK_BGXX_CMRX_RX_BP_STATUS(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_RX_BP_STATUS(a,b) "BGXX_CMRX_RX_BP_STATUS"
#define device_bar_BDK_BGXX_CMRX_RX_BP_STATUS(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_RX_BP_STATUS(a,b) (a)
#define arguments_BDK_BGXX_CMRX_RX_BP_STATUS(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_rx_dmac_ctl
*
* BGX CMR Receive DMAC Address-Control Register
* Internal:
* "* ALGORITHM
* Here is some pseudo code that represents the address filter behavior.
* dmac_addr_filter(uint8 prt, uint48 dmac) {
* for (lmac=0, lmac\<4, lmac++) {
* if (is_bcst(dmac)) // broadcast accept
* return (BGX()_CMR({lmac})_RX_DMAC_CTL[BCST_ACCEPT] ? ACCEPT : REJECT);
* if (is_mcst(dmac) && BGX()_CMR({lmac})_RX_DMAC_CTL[MCST_MODE] == 0) // multicast reject
* return REJECT;
* if (is_mcst(dmac) && BGX()_CMR({lmac})_RX_DMAC_CTL[MCST_MODE] == 1) // multicast accept
* return ACCEPT;
* else // DMAC CAM filter
* cam_hit = 0;
* for (i=0; i\<32; i++) {
* cam = BGX()_CMR_RX_DMAC({i})_CAM;
* if (cam[EN] && cam[ID] == {lmac} && cam[ADR] == dmac) {
* cam_hit = 1;
* break;
* }
* }
* if (cam_hit) {
* return (BGX()_CMR({lmac})_RX_DMAC_CTL[CAM_ACCEPT] ? ACCEPT : REJECT);
* else
* return (BGX()_CMR({lmac})_RX_DMAC_CTL[CAM_ACCEPT] ? REJECT : ACCEPT);
* }
* }"
*/
union bdk_bgxx_cmrx_rx_dmac_ctl
{
uint64_t u;
struct bdk_bgxx_cmrx_rx_dmac_ctl_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_4_63 : 60;
uint64_t cam_accept : 1; /**< [ 3: 3](R/W) Allow or deny DMAC address filter.
0 = Reject the packet on DMAC CAM address match.
1 = Accept the packet on DMAC CAM address match. */
uint64_t mcst_mode : 2; /**< [ 2: 1](R/W) Multicast mode.
0x0 = Force reject all multicast packets.
0x1 = Force accept all multicast packets.
0x2 = Use the address filter CAM.
0x3 = Reserved. */
uint64_t bcst_accept : 1; /**< [ 0: 0](R/W) Allow or deny broadcast packets.
0 = Reject all broadcast packets.
1 = Accept all broadcast packets. */
#else /* Word 0 - Little Endian */
uint64_t bcst_accept : 1; /**< [ 0: 0](R/W) Allow or deny broadcast packets.
0 = Reject all broadcast packets.
1 = Accept all broadcast packets. */
uint64_t mcst_mode : 2; /**< [ 2: 1](R/W) Multicast mode.
0x0 = Force reject all multicast packets.
0x1 = Force accept all multicast packets.
0x2 = Use the address filter CAM.
0x3 = Reserved. */
uint64_t cam_accept : 1; /**< [ 3: 3](R/W) Allow or deny DMAC address filter.
0 = Reject the packet on DMAC CAM address match.
1 = Accept the packet on DMAC CAM address match. */
uint64_t reserved_4_63 : 60;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_rx_dmac_ctl_s cn; */
};
typedef union bdk_bgxx_cmrx_rx_dmac_ctl bdk_bgxx_cmrx_rx_dmac_ctl_t;
static inline uint64_t BDK_BGXX_CMRX_RX_DMAC_CTL(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_RX_DMAC_CTL(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e00000e8ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e00000e8ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e00000e8ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_RX_DMAC_CTL", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_RX_DMAC_CTL(a,b) bdk_bgxx_cmrx_rx_dmac_ctl_t
#define bustype_BDK_BGXX_CMRX_RX_DMAC_CTL(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_RX_DMAC_CTL(a,b) "BGXX_CMRX_RX_DMAC_CTL"
#define device_bar_BDK_BGXX_CMRX_RX_DMAC_CTL(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_RX_DMAC_CTL(a,b) (a)
#define arguments_BDK_BGXX_CMRX_RX_DMAC_CTL(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_rx_fifo_len
*
* BGX CMR Receive FIFO Length Registers
*/
union bdk_bgxx_cmrx_rx_fifo_len
{
uint64_t u;
struct bdk_bgxx_cmrx_rx_fifo_len_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_14_63 : 50;
uint64_t busy : 1; /**< [ 13: 13](RO/H) Indicates if GMP and CMR are busy processing a packet. Used when bringing an LMAC
down since in low bandwidth cases, as the FIFO length may often appear to be 0x0. */
uint64_t fifo_len : 13; /**< [ 12: 0](RO/H) Per-LMAC FIFO length. Useful for determining if FIFO is empty when bringing an LMAC down. */
#else /* Word 0 - Little Endian */
uint64_t fifo_len : 13; /**< [ 12: 0](RO/H) Per-LMAC FIFO length. Useful for determining if FIFO is empty when bringing an LMAC down. */
uint64_t busy : 1; /**< [ 13: 13](RO/H) Indicates if GMP and CMR are busy processing a packet. Used when bringing an LMAC
down since in low bandwidth cases, as the FIFO length may often appear to be 0x0. */
uint64_t reserved_14_63 : 50;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_rx_fifo_len_s cn81xx; */
struct bdk_bgxx_cmrx_rx_fifo_len_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_13_63 : 51;
uint64_t fifo_len : 13; /**< [ 12: 0](RO/H) Per-LMAC FIFO length. Useful for determining if FIFO is empty when bringing an LMAC down. */
#else /* Word 0 - Little Endian */
uint64_t fifo_len : 13; /**< [ 12: 0](RO/H) Per-LMAC FIFO length. Useful for determining if FIFO is empty when bringing an LMAC down. */
uint64_t reserved_13_63 : 51;
#endif /* Word 0 - End */
} cn88xx;
/* struct bdk_bgxx_cmrx_rx_fifo_len_s cn83xx; */
};
typedef union bdk_bgxx_cmrx_rx_fifo_len bdk_bgxx_cmrx_rx_fifo_len_t;
static inline uint64_t BDK_BGXX_CMRX_RX_FIFO_LEN(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_RX_FIFO_LEN(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000108ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000108ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000108ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_RX_FIFO_LEN", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_RX_FIFO_LEN(a,b) bdk_bgxx_cmrx_rx_fifo_len_t
#define bustype_BDK_BGXX_CMRX_RX_FIFO_LEN(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_RX_FIFO_LEN(a,b) "BGXX_CMRX_RX_FIFO_LEN"
#define device_bar_BDK_BGXX_CMRX_RX_FIFO_LEN(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_RX_FIFO_LEN(a,b) (a)
#define arguments_BDK_BGXX_CMRX_RX_FIFO_LEN(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_rx_id_map
*
* BGX CMR Receive ID Map Register
* These registers set the RX LMAC ID mapping for X2P/NIC.
*/
union bdk_bgxx_cmrx_rx_id_map
{
uint64_t u;
struct bdk_bgxx_cmrx_rx_id_map_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_15_63 : 49;
uint64_t rid : 7; /**< [ 14: 8](R/W) Reserved.
Internal:
Defeatured. Reassembly ID for Octeon PKI; not used in CN8XXX.
Reassembly ID map for this LMAC. A shared pool of 96 reassembly IDs (RIDs) exists for all
MACs.
The RID for this LMAC must be constrained such that it does not overlap with any other MAC
in the system. Its reset value has been chosen such that this condition is satisfied:
_ RID reset value = 4*(BGX_ID + 1) + LMAC_ID
Changes to RID must only occur when the LMAC is quiescent (i.e. the LMAC receive interface
is down and the RX FIFO is empty). */
uint64_t unused : 2; /**< [ 7: 6](RAZ) Reserved. */
uint64_t pknd : 6; /**< [ 5: 0](R/W) Port kind for this LMAC. */
#else /* Word 0 - Little Endian */
uint64_t pknd : 6; /**< [ 5: 0](R/W) Port kind for this LMAC. */
uint64_t unused : 2; /**< [ 7: 6](RAZ) Reserved. */
uint64_t rid : 7; /**< [ 14: 8](R/W) Reserved.
Internal:
Defeatured. Reassembly ID for Octeon PKI; not used in CN8XXX.
Reassembly ID map for this LMAC. A shared pool of 96 reassembly IDs (RIDs) exists for all
MACs.
The RID for this LMAC must be constrained such that it does not overlap with any other MAC
in the system. Its reset value has been chosen such that this condition is satisfied:
_ RID reset value = 4*(BGX_ID + 1) + LMAC_ID
Changes to RID must only occur when the LMAC is quiescent (i.e. the LMAC receive interface
is down and the RX FIFO is empty). */
uint64_t reserved_15_63 : 49;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_rx_id_map_s cn; */
};
typedef union bdk_bgxx_cmrx_rx_id_map bdk_bgxx_cmrx_rx_id_map_t;
static inline uint64_t BDK_BGXX_CMRX_RX_ID_MAP(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_RX_ID_MAP(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000060ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000060ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000060ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_RX_ID_MAP", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_RX_ID_MAP(a,b) bdk_bgxx_cmrx_rx_id_map_t
#define bustype_BDK_BGXX_CMRX_RX_ID_MAP(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_RX_ID_MAP(a,b) "BGXX_CMRX_RX_ID_MAP"
#define device_bar_BDK_BGXX_CMRX_RX_ID_MAP(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_RX_ID_MAP(a,b) (a)
#define arguments_BDK_BGXX_CMRX_RX_ID_MAP(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_rx_logl_xoff
*
* BGX CMR Receive Logical XOFF Registers
*/
union bdk_bgxx_cmrx_rx_logl_xoff
{
uint64_t u;
struct bdk_bgxx_cmrx_rx_logl_xoff_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t xoff : 16; /**< [ 15: 0](R/W1S/H) Together with BGX()_CMR()_RX_LOGL_XON, defines type of channel backpressure to
apply to the MAC. In the case of SMU, Do not write when HiGig2 is
enabled. Writing 1 sets the same physical register as that which is cleared by
BGX()_CMR()_RX_LOGL_XON[XON]. An XOFF value of 1 will cause a backpressure on
the MAC. */
#else /* Word 0 - Little Endian */
uint64_t xoff : 16; /**< [ 15: 0](R/W1S/H) Together with BGX()_CMR()_RX_LOGL_XON, defines type of channel backpressure to
apply to the MAC. In the case of SMU, Do not write when HiGig2 is
enabled. Writing 1 sets the same physical register as that which is cleared by
BGX()_CMR()_RX_LOGL_XON[XON]. An XOFF value of 1 will cause a backpressure on
the MAC. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_rx_logl_xoff_s cn; */
};
typedef union bdk_bgxx_cmrx_rx_logl_xoff bdk_bgxx_cmrx_rx_logl_xoff_t;
static inline uint64_t BDK_BGXX_CMRX_RX_LOGL_XOFF(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_RX_LOGL_XOFF(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e00000f8ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e00000f8ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e00000f8ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_RX_LOGL_XOFF", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_RX_LOGL_XOFF(a,b) bdk_bgxx_cmrx_rx_logl_xoff_t
#define bustype_BDK_BGXX_CMRX_RX_LOGL_XOFF(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_RX_LOGL_XOFF(a,b) "BGXX_CMRX_RX_LOGL_XOFF"
#define device_bar_BDK_BGXX_CMRX_RX_LOGL_XOFF(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_RX_LOGL_XOFF(a,b) (a)
#define arguments_BDK_BGXX_CMRX_RX_LOGL_XOFF(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_rx_logl_xon
*
* BGX CMR Receive Logical XON Registers
*/
union bdk_bgxx_cmrx_rx_logl_xon
{
uint64_t u;
struct bdk_bgxx_cmrx_rx_logl_xon_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t xon : 16; /**< [ 15: 0](R/W1C/H) Together with BGX()_CMR()_RX_LOGL_XOFF, defines type of channel backpressure to
apply. Do not write when HiGig2 is enabled. Writing 1 clears the same physical register as
that which is set by XOFF. An XON value of 1 means only NIC channel BP can cause a
backpressure on the MAC. */
#else /* Word 0 - Little Endian */
uint64_t xon : 16; /**< [ 15: 0](R/W1C/H) Together with BGX()_CMR()_RX_LOGL_XOFF, defines type of channel backpressure to
apply. Do not write when HiGig2 is enabled. Writing 1 clears the same physical register as
that which is set by XOFF. An XON value of 1 means only NIC channel BP can cause a
backpressure on the MAC. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_rx_logl_xon_s cn81xx; */
struct bdk_bgxx_cmrx_rx_logl_xon_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t xon : 16; /**< [ 15: 0](R/W1C/H) Together with BGX()_CMR()_RX_LOGL_XOFF, defines type of channel backpressure to
apply. Do not write when HiGig2 is enabled. Writing 1 clears the same physical register as
that which is set by XOFF. An XON value of 1 means only NIC channel BP can cause a
backpressure on SMU. */
#else /* Word 0 - Little Endian */
uint64_t xon : 16; /**< [ 15: 0](R/W1C/H) Together with BGX()_CMR()_RX_LOGL_XOFF, defines type of channel backpressure to
apply. Do not write when HiGig2 is enabled. Writing 1 clears the same physical register as
that which is set by XOFF. An XON value of 1 means only NIC channel BP can cause a
backpressure on SMU. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} cn88xx;
/* struct bdk_bgxx_cmrx_rx_logl_xon_s cn83xx; */
};
typedef union bdk_bgxx_cmrx_rx_logl_xon bdk_bgxx_cmrx_rx_logl_xon_t;
static inline uint64_t BDK_BGXX_CMRX_RX_LOGL_XON(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_RX_LOGL_XON(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000100ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000100ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000100ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_RX_LOGL_XON", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_RX_LOGL_XON(a,b) bdk_bgxx_cmrx_rx_logl_xon_t
#define bustype_BDK_BGXX_CMRX_RX_LOGL_XON(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_RX_LOGL_XON(a,b) "BGXX_CMRX_RX_LOGL_XON"
#define device_bar_BDK_BGXX_CMRX_RX_LOGL_XON(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_RX_LOGL_XON(a,b) (a)
#define arguments_BDK_BGXX_CMRX_RX_LOGL_XON(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_rx_pause_drop_time
*
* BGX CMR Receive Pause Drop-Time Register
*/
union bdk_bgxx_cmrx_rx_pause_drop_time
{
uint64_t u;
struct bdk_bgxx_cmrx_rx_pause_drop_time_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t pause_time : 16; /**< [ 15: 0](R/W1C/H) Time extracted from the dropped PAUSE packet dropped due to RXB FIFO full or during partner reset. */
#else /* Word 0 - Little Endian */
uint64_t pause_time : 16; /**< [ 15: 0](R/W1C/H) Time extracted from the dropped PAUSE packet dropped due to RXB FIFO full or during partner reset. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_rx_pause_drop_time_s cn; */
};
typedef union bdk_bgxx_cmrx_rx_pause_drop_time bdk_bgxx_cmrx_rx_pause_drop_time_t;
static inline uint64_t BDK_BGXX_CMRX_RX_PAUSE_DROP_TIME(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_RX_PAUSE_DROP_TIME(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000068ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000068ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000068ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_RX_PAUSE_DROP_TIME", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_RX_PAUSE_DROP_TIME(a,b) bdk_bgxx_cmrx_rx_pause_drop_time_t
#define bustype_BDK_BGXX_CMRX_RX_PAUSE_DROP_TIME(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_RX_PAUSE_DROP_TIME(a,b) "BGXX_CMRX_RX_PAUSE_DROP_TIME"
#define device_bar_BDK_BGXX_CMRX_RX_PAUSE_DROP_TIME(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_RX_PAUSE_DROP_TIME(a,b) (a)
#define arguments_BDK_BGXX_CMRX_RX_PAUSE_DROP_TIME(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_rx_stat0
*
* BGX Receive Status Register 0
* These registers provide a count of received packets that meet the following conditions:
* * are not recognized as PAUSE packets.
* * are not dropped due DMAC filtering.
* * are not dropped due FIFO full status.
* * do not have any other OPCODE (FCS, Length, etc).
*/
union bdk_bgxx_cmrx_rx_stat0
{
uint64_t u;
struct bdk_bgxx_cmrx_rx_stat0_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t cnt : 48; /**< [ 47: 0](R/W/H) Count of received packets. [CNT] will wrap and is cleared if LMAC is disabled with
BGX()_CMR()_CONFIG[ENABLE]=0. */
#else /* Word 0 - Little Endian */
uint64_t cnt : 48; /**< [ 47: 0](R/W/H) Count of received packets. [CNT] will wrap and is cleared if LMAC is disabled with
BGX()_CMR()_CONFIG[ENABLE]=0. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_rx_stat0_s cn; */
};
typedef union bdk_bgxx_cmrx_rx_stat0 bdk_bgxx_cmrx_rx_stat0_t;
static inline uint64_t BDK_BGXX_CMRX_RX_STAT0(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_RX_STAT0(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000070ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000070ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000070ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_RX_STAT0", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_RX_STAT0(a,b) bdk_bgxx_cmrx_rx_stat0_t
#define bustype_BDK_BGXX_CMRX_RX_STAT0(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_RX_STAT0(a,b) "BGXX_CMRX_RX_STAT0"
#define device_bar_BDK_BGXX_CMRX_RX_STAT0(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_RX_STAT0(a,b) (a)
#define arguments_BDK_BGXX_CMRX_RX_STAT0(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_rx_stat1
*
* BGX Receive Status Register 1
* These registers provide a count of octets of received packets.
*/
union bdk_bgxx_cmrx_rx_stat1
{
uint64_t u;
struct bdk_bgxx_cmrx_rx_stat1_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t cnt : 48; /**< [ 47: 0](R/W/H) Octet count of received packets. [CNT] will wrap and is cleared if LMAC is disabled with
BGX()_CMR()_CONFIG[ENABLE]=0. */
#else /* Word 0 - Little Endian */
uint64_t cnt : 48; /**< [ 47: 0](R/W/H) Octet count of received packets. [CNT] will wrap and is cleared if LMAC is disabled with
BGX()_CMR()_CONFIG[ENABLE]=0. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_rx_stat1_s cn; */
};
typedef union bdk_bgxx_cmrx_rx_stat1 bdk_bgxx_cmrx_rx_stat1_t;
static inline uint64_t BDK_BGXX_CMRX_RX_STAT1(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_RX_STAT1(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000078ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000078ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000078ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_RX_STAT1", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_RX_STAT1(a,b) bdk_bgxx_cmrx_rx_stat1_t
#define bustype_BDK_BGXX_CMRX_RX_STAT1(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_RX_STAT1(a,b) "BGXX_CMRX_RX_STAT1"
#define device_bar_BDK_BGXX_CMRX_RX_STAT1(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_RX_STAT1(a,b) (a)
#define arguments_BDK_BGXX_CMRX_RX_STAT1(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_rx_stat2
*
* BGX Receive Status Register 2
* These registers provide a count of all packets received that were recognized as flow-control
* or PAUSE packets. PAUSE packets with any kind of error are counted in
* BGX()_CMR()_RX_STAT8 (error stats register). Pause packets can be optionally dropped
* or forwarded based on BGX()_SMU()_RX_FRM_CTL[CTL_DRP]. This count increments
* regardless of whether the packet is dropped. PAUSE packets are never counted in
* BGX()_CMR()_RX_STAT0.
*/
union bdk_bgxx_cmrx_rx_stat2
{
uint64_t u;
struct bdk_bgxx_cmrx_rx_stat2_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t cnt : 48; /**< [ 47: 0](R/W/H) Count of received PAUSE packets. [CNT] will wrap and is cleared if LMAC is disabled with
BGX()_CMR()_CONFIG[ENABLE]=0. */
#else /* Word 0 - Little Endian */
uint64_t cnt : 48; /**< [ 47: 0](R/W/H) Count of received PAUSE packets. [CNT] will wrap and is cleared if LMAC is disabled with
BGX()_CMR()_CONFIG[ENABLE]=0. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_rx_stat2_s cn; */
};
typedef union bdk_bgxx_cmrx_rx_stat2 bdk_bgxx_cmrx_rx_stat2_t;
static inline uint64_t BDK_BGXX_CMRX_RX_STAT2(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_RX_STAT2(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000080ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000080ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000080ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_RX_STAT2", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_RX_STAT2(a,b) bdk_bgxx_cmrx_rx_stat2_t
#define bustype_BDK_BGXX_CMRX_RX_STAT2(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_RX_STAT2(a,b) "BGXX_CMRX_RX_STAT2"
#define device_bar_BDK_BGXX_CMRX_RX_STAT2(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_RX_STAT2(a,b) (a)
#define arguments_BDK_BGXX_CMRX_RX_STAT2(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_rx_stat3
*
* BGX Receive Status Register 3
* These registers provide a count of octets of received PAUSE and control packets.
*/
union bdk_bgxx_cmrx_rx_stat3
{
uint64_t u;
struct bdk_bgxx_cmrx_rx_stat3_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t cnt : 48; /**< [ 47: 0](R/W/H) Octet count of received PAUSE packets. [CNT] will wrap and is cleared if LMAC is disabled
with BGX()_CMR()_CONFIG[ENABLE]=0. */
#else /* Word 0 - Little Endian */
uint64_t cnt : 48; /**< [ 47: 0](R/W/H) Octet count of received PAUSE packets. [CNT] will wrap and is cleared if LMAC is disabled
with BGX()_CMR()_CONFIG[ENABLE]=0. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_rx_stat3_s cn; */
};
typedef union bdk_bgxx_cmrx_rx_stat3 bdk_bgxx_cmrx_rx_stat3_t;
static inline uint64_t BDK_BGXX_CMRX_RX_STAT3(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_RX_STAT3(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000088ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000088ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000088ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_RX_STAT3", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_RX_STAT3(a,b) bdk_bgxx_cmrx_rx_stat3_t
#define bustype_BDK_BGXX_CMRX_RX_STAT3(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_RX_STAT3(a,b) "BGXX_CMRX_RX_STAT3"
#define device_bar_BDK_BGXX_CMRX_RX_STAT3(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_RX_STAT3(a,b) (a)
#define arguments_BDK_BGXX_CMRX_RX_STAT3(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_rx_stat4
*
* BGX Receive Status Register 4
* These registers provide a count of all packets received that were dropped by the DMAC filter.
* Packets that match the DMAC are dropped and counted here regardless of whether they were ERR
* packets, but does not include those reported in BGX()_CMR()_RX_STAT6. These packets
* are never counted in BGX()_CMR()_RX_STAT0. Eight-byte packets as the result of
* truncation or other means are not dropped by CNXXXX and will never appear in this count.
*/
union bdk_bgxx_cmrx_rx_stat4
{
uint64_t u;
struct bdk_bgxx_cmrx_rx_stat4_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t cnt : 48; /**< [ 47: 0](R/W/H) Count of filtered DMAC packets. [CNT] will wrap and is cleared if LMAC is disabled with
BGX()_CMR()_CONFIG[ENABLE]=0. */
#else /* Word 0 - Little Endian */
uint64_t cnt : 48; /**< [ 47: 0](R/W/H) Count of filtered DMAC packets. [CNT] will wrap and is cleared if LMAC is disabled with
BGX()_CMR()_CONFIG[ENABLE]=0. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_rx_stat4_s cn; */
};
typedef union bdk_bgxx_cmrx_rx_stat4 bdk_bgxx_cmrx_rx_stat4_t;
static inline uint64_t BDK_BGXX_CMRX_RX_STAT4(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_RX_STAT4(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000090ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000090ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000090ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_RX_STAT4", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_RX_STAT4(a,b) bdk_bgxx_cmrx_rx_stat4_t
#define bustype_BDK_BGXX_CMRX_RX_STAT4(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_RX_STAT4(a,b) "BGXX_CMRX_RX_STAT4"
#define device_bar_BDK_BGXX_CMRX_RX_STAT4(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_RX_STAT4(a,b) (a)
#define arguments_BDK_BGXX_CMRX_RX_STAT4(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_rx_stat5
*
* BGX Receive Status Register 5
* These registers provide a count of octets of filtered DMAC packets.
*/
union bdk_bgxx_cmrx_rx_stat5
{
uint64_t u;
struct bdk_bgxx_cmrx_rx_stat5_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t cnt : 48; /**< [ 47: 0](R/W/H) Octet count of filtered DMAC packets. [CNT] will wrap and is cleared if LMAC is disabled
with BGX()_CMR()_CONFIG[ENABLE]=0. */
#else /* Word 0 - Little Endian */
uint64_t cnt : 48; /**< [ 47: 0](R/W/H) Octet count of filtered DMAC packets. [CNT] will wrap and is cleared if LMAC is disabled
with BGX()_CMR()_CONFIG[ENABLE]=0. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_rx_stat5_s cn; */
};
typedef union bdk_bgxx_cmrx_rx_stat5 bdk_bgxx_cmrx_rx_stat5_t;
static inline uint64_t BDK_BGXX_CMRX_RX_STAT5(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_RX_STAT5(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000098ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000098ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000098ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_RX_STAT5", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_RX_STAT5(a,b) bdk_bgxx_cmrx_rx_stat5_t
#define bustype_BDK_BGXX_CMRX_RX_STAT5(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_RX_STAT5(a,b) "BGXX_CMRX_RX_STAT5"
#define device_bar_BDK_BGXX_CMRX_RX_STAT5(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_RX_STAT5(a,b) (a)
#define arguments_BDK_BGXX_CMRX_RX_STAT5(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_rx_stat6
*
* BGX Receive Status Register 6
* These registers provide a count of all packets received that were dropped due to a full
* receive FIFO. They do not count any packet that is truncated at the point of overflow and sent
* on to the NIC. These registers count all entire packets dropped by the FIFO for a given LMAC
* regardless of DMAC or PAUSE type.
*/
union bdk_bgxx_cmrx_rx_stat6
{
uint64_t u;
struct bdk_bgxx_cmrx_rx_stat6_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t cnt : 48; /**< [ 47: 0](R/W/H) Count of dropped packets. [CNT] will wrap and is cleared if LMAC is disabled with
BGX()_CMR()_CONFIG[ENABLE]=0. */
#else /* Word 0 - Little Endian */
uint64_t cnt : 48; /**< [ 47: 0](R/W/H) Count of dropped packets. [CNT] will wrap and is cleared if LMAC is disabled with
BGX()_CMR()_CONFIG[ENABLE]=0. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_rx_stat6_s cn; */
};
typedef union bdk_bgxx_cmrx_rx_stat6 bdk_bgxx_cmrx_rx_stat6_t;
static inline uint64_t BDK_BGXX_CMRX_RX_STAT6(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_RX_STAT6(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e00000a0ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e00000a0ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e00000a0ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_RX_STAT6", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_RX_STAT6(a,b) bdk_bgxx_cmrx_rx_stat6_t
#define bustype_BDK_BGXX_CMRX_RX_STAT6(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_RX_STAT6(a,b) "BGXX_CMRX_RX_STAT6"
#define device_bar_BDK_BGXX_CMRX_RX_STAT6(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_RX_STAT6(a,b) (a)
#define arguments_BDK_BGXX_CMRX_RX_STAT6(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_rx_stat7
*
* BGX Receive Status Register 7
* These registers provide a count of octets of received packets that were dropped due to a full
* receive FIFO.
*/
union bdk_bgxx_cmrx_rx_stat7
{
uint64_t u;
struct bdk_bgxx_cmrx_rx_stat7_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t cnt : 48; /**< [ 47: 0](R/W/H) Octet count of dropped packets. [CNT] will wrap and is cleared if LMAC is disabled with
BGX()_CMR()_CONFIG[ENABLE]=0. */
#else /* Word 0 - Little Endian */
uint64_t cnt : 48; /**< [ 47: 0](R/W/H) Octet count of dropped packets. [CNT] will wrap and is cleared if LMAC is disabled with
BGX()_CMR()_CONFIG[ENABLE]=0. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_rx_stat7_s cn; */
};
typedef union bdk_bgxx_cmrx_rx_stat7 bdk_bgxx_cmrx_rx_stat7_t;
static inline uint64_t BDK_BGXX_CMRX_RX_STAT7(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_RX_STAT7(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e00000a8ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e00000a8ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e00000a8ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_RX_STAT7", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_RX_STAT7(a,b) bdk_bgxx_cmrx_rx_stat7_t
#define bustype_BDK_BGXX_CMRX_RX_STAT7(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_RX_STAT7(a,b) "BGXX_CMRX_RX_STAT7"
#define device_bar_BDK_BGXX_CMRX_RX_STAT7(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_RX_STAT7(a,b) (a)
#define arguments_BDK_BGXX_CMRX_RX_STAT7(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_rx_stat8
*
* BGX Receive Status Register 8
* These registers provide a count of all packets received with some error that were not dropped
* either due to the DMAC filter or lack of room in the receive FIFO.
* This does not include packets which were counted in
* BGX()_CMR()_RX_STAT2, BGX()_CMR()_RX_STAT4 nor
* BGX()_CMR()_RX_STAT6.
*
* Which statistics are updated on control packet errors and drops are shown below:
*
* \<pre\>
* if dropped {
* if !errored STAT8
* if overflow STAT6
* else if dmac drop STAT4
* else if filter drop STAT2
* } else {
* if errored STAT2
* else STAT8
* }
* \</pre\>
*/
union bdk_bgxx_cmrx_rx_stat8
{
uint64_t u;
struct bdk_bgxx_cmrx_rx_stat8_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t cnt : 48; /**< [ 47: 0](R/W/H) Count of error packets. [CNT] will wrap and is cleared if LMAC is disabled with
BGX()_CMR()_CONFIG[ENABLE]=0. */
#else /* Word 0 - Little Endian */
uint64_t cnt : 48; /**< [ 47: 0](R/W/H) Count of error packets. [CNT] will wrap and is cleared if LMAC is disabled with
BGX()_CMR()_CONFIG[ENABLE]=0. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_rx_stat8_s cn; */
};
typedef union bdk_bgxx_cmrx_rx_stat8 bdk_bgxx_cmrx_rx_stat8_t;
static inline uint64_t BDK_BGXX_CMRX_RX_STAT8(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_RX_STAT8(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e00000b0ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e00000b0ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e00000b0ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_RX_STAT8", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_RX_STAT8(a,b) bdk_bgxx_cmrx_rx_stat8_t
#define bustype_BDK_BGXX_CMRX_RX_STAT8(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_RX_STAT8(a,b) "BGXX_CMRX_RX_STAT8"
#define device_bar_BDK_BGXX_CMRX_RX_STAT8(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_RX_STAT8(a,b) (a)
#define arguments_BDK_BGXX_CMRX_RX_STAT8(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_rx_weight
*
* BGX CMR Receive-Weight Register
*/
union bdk_bgxx_cmrx_rx_weight
{
uint64_t u;
struct bdk_bgxx_cmrx_rx_weight_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_4_63 : 60;
uint64_t weight : 4; /**< [ 3: 0](R/W) For the weighted round robin algorithm in CMR RXB, weight to assign for this LMAC relative
to other LMAC weights. Defaults to round-robin (non-weighted minimum setting of 0x1). A
setting of 0x0 effectively takes the LMAC out of eligibility. */
#else /* Word 0 - Little Endian */
uint64_t weight : 4; /**< [ 3: 0](R/W) For the weighted round robin algorithm in CMR RXB, weight to assign for this LMAC relative
to other LMAC weights. Defaults to round-robin (non-weighted minimum setting of 0x1). A
setting of 0x0 effectively takes the LMAC out of eligibility. */
uint64_t reserved_4_63 : 60;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_rx_weight_s cn; */
};
typedef union bdk_bgxx_cmrx_rx_weight bdk_bgxx_cmrx_rx_weight_t;
static inline uint64_t BDK_BGXX_CMRX_RX_WEIGHT(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_RX_WEIGHT(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e00000e0ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e00000e0ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e00000e0ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_RX_WEIGHT", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_RX_WEIGHT(a,b) bdk_bgxx_cmrx_rx_weight_t
#define bustype_BDK_BGXX_CMRX_RX_WEIGHT(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_RX_WEIGHT(a,b) "BGXX_CMRX_RX_WEIGHT"
#define device_bar_BDK_BGXX_CMRX_RX_WEIGHT(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_RX_WEIGHT(a,b) (a)
#define arguments_BDK_BGXX_CMRX_RX_WEIGHT(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_tx_channel
*
* BGX CMR Transmit-Channels Registers
*/
union bdk_bgxx_cmrx_tx_channel
{
uint64_t u;
struct bdk_bgxx_cmrx_tx_channel_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_32_63 : 32;
uint64_t msk : 16; /**< [ 31: 16](R/W) Backpressure channel mask. BGX can completely ignore the channel backpressure for channel
specified by this field. Any channel in which MSK\<n\> is set never sends backpressure
information to NIC. */
uint64_t dis : 16; /**< [ 15: 0](R/W) Credit return backpressure disable. BGX stops returning channel credits for any
channel that is backpressured. These bits can be used to override that. If
[DIS]\<n\> is set, channel credits may flow back regardless of the backpressure
for that channel. */
#else /* Word 0 - Little Endian */
uint64_t dis : 16; /**< [ 15: 0](R/W) Credit return backpressure disable. BGX stops returning channel credits for any
channel that is backpressured. These bits can be used to override that. If
[DIS]\<n\> is set, channel credits may flow back regardless of the backpressure
for that channel. */
uint64_t msk : 16; /**< [ 31: 16](R/W) Backpressure channel mask. BGX can completely ignore the channel backpressure for channel
specified by this field. Any channel in which MSK\<n\> is set never sends backpressure
information to NIC. */
uint64_t reserved_32_63 : 32;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_tx_channel_s cn81xx; */
struct bdk_bgxx_cmrx_tx_channel_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_32_63 : 32;
uint64_t msk : 16; /**< [ 31: 16](R/W) Backpressure channel mask. BGX can completely ignore the channel backpressure for channel
specified by this field. Any channel in which MSK\<n\> is set never sends backpressure
information to TNS/NIC. */
uint64_t dis : 16; /**< [ 15: 0](R/W) Credit return backpressure disable. BGX stops returning channel credits for any
channel that is backpressured. These bits can be used to override that. If
[DIS]\<n\> is set, channel credits may flow back regardless of the backpressure
for that channel. */
#else /* Word 0 - Little Endian */
uint64_t dis : 16; /**< [ 15: 0](R/W) Credit return backpressure disable. BGX stops returning channel credits for any
channel that is backpressured. These bits can be used to override that. If
[DIS]\<n\> is set, channel credits may flow back regardless of the backpressure
for that channel. */
uint64_t msk : 16; /**< [ 31: 16](R/W) Backpressure channel mask. BGX can completely ignore the channel backpressure for channel
specified by this field. Any channel in which MSK\<n\> is set never sends backpressure
information to TNS/NIC. */
uint64_t reserved_32_63 : 32;
#endif /* Word 0 - End */
} cn88xx;
struct bdk_bgxx_cmrx_tx_channel_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_32_63 : 32;
uint64_t msk : 16; /**< [ 31: 16](R/W) Backpressure channel mask. BGX can completely ignore the channel backpressure for channel
specified by this field. Any channel in which MSK\<n\> is set never sends backpressure
information to PKO. */
uint64_t dis : 16; /**< [ 15: 0](R/W) Credit return backpressure disable. BGX stops returning channel credits for any
channel that is backpressured. These bits can be used to override that. If
[DIS]\<n\> is set, channel credits may flow back regardless of the backpressure
for that channel. */
#else /* Word 0 - Little Endian */
uint64_t dis : 16; /**< [ 15: 0](R/W) Credit return backpressure disable. BGX stops returning channel credits for any
channel that is backpressured. These bits can be used to override that. If
[DIS]\<n\> is set, channel credits may flow back regardless of the backpressure
for that channel. */
uint64_t msk : 16; /**< [ 31: 16](R/W) Backpressure channel mask. BGX can completely ignore the channel backpressure for channel
specified by this field. Any channel in which MSK\<n\> is set never sends backpressure
information to PKO. */
uint64_t reserved_32_63 : 32;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_cmrx_tx_channel bdk_bgxx_cmrx_tx_channel_t;
static inline uint64_t BDK_BGXX_CMRX_TX_CHANNEL(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_TX_CHANNEL(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000500ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000500ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000500ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_TX_CHANNEL", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_TX_CHANNEL(a,b) bdk_bgxx_cmrx_tx_channel_t
#define bustype_BDK_BGXX_CMRX_TX_CHANNEL(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_TX_CHANNEL(a,b) "BGXX_CMRX_TX_CHANNEL"
#define device_bar_BDK_BGXX_CMRX_TX_CHANNEL(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_TX_CHANNEL(a,b) (a)
#define arguments_BDK_BGXX_CMRX_TX_CHANNEL(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_tx_fifo_len
*
* BGX CMR Transmit FIFO Length Registers
*/
union bdk_bgxx_cmrx_tx_fifo_len
{
uint64_t u;
struct bdk_bgxx_cmrx_tx_fifo_len_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_15_63 : 49;
uint64_t lmac_idle : 1; /**< [ 14: 14](RO/H) Idle signal to identify when all credits and other pipeline buffers are also cleared out
and LMAC can be considered IDLE in the BGX CMR TX. */
uint64_t fifo_len : 14; /**< [ 13: 0](RO/H) Per-LMAC TXB main FIFO length. Useful for determining if main FIFO is empty when bringing
an LMAC down. */
#else /* Word 0 - Little Endian */
uint64_t fifo_len : 14; /**< [ 13: 0](RO/H) Per-LMAC TXB main FIFO length. Useful for determining if main FIFO is empty when bringing
an LMAC down. */
uint64_t lmac_idle : 1; /**< [ 14: 14](RO/H) Idle signal to identify when all credits and other pipeline buffers are also cleared out
and LMAC can be considered IDLE in the BGX CMR TX. */
uint64_t reserved_15_63 : 49;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_tx_fifo_len_s cn; */
};
typedef union bdk_bgxx_cmrx_tx_fifo_len bdk_bgxx_cmrx_tx_fifo_len_t;
static inline uint64_t BDK_BGXX_CMRX_TX_FIFO_LEN(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_TX_FIFO_LEN(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000518ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000518ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000518ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_TX_FIFO_LEN", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_TX_FIFO_LEN(a,b) bdk_bgxx_cmrx_tx_fifo_len_t
#define bustype_BDK_BGXX_CMRX_TX_FIFO_LEN(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_TX_FIFO_LEN(a,b) "BGXX_CMRX_TX_FIFO_LEN"
#define device_bar_BDK_BGXX_CMRX_TX_FIFO_LEN(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_TX_FIFO_LEN(a,b) (a)
#define arguments_BDK_BGXX_CMRX_TX_FIFO_LEN(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_tx_hg2_status
*
* BGX CMR Transmit HiGig2 Status Registers
*/
union bdk_bgxx_cmrx_tx_hg2_status
{
uint64_t u;
struct bdk_bgxx_cmrx_tx_hg2_status_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_32_63 : 32;
uint64_t xof : 16; /**< [ 31: 16](RO/H) 16-bit XOF back pressure vector from HiGig2 message packet or from PFC packets. Non-
zero only when logical back pressure is active. All bits are 0 when [LGTIM2GO] = 0x0. */
uint64_t lgtim2go : 16; /**< [ 15: 0](RO/H) Logical packet flow back pressure time remaining. Initial value set from XOF time field of
HiGig2 message packet received or a function of the enabled and current timers for
PFC packets. Nonzero only when logical back pressure is active. */
#else /* Word 0 - Little Endian */
uint64_t lgtim2go : 16; /**< [ 15: 0](RO/H) Logical packet flow back pressure time remaining. Initial value set from XOF time field of
HiGig2 message packet received or a function of the enabled and current timers for
PFC packets. Nonzero only when logical back pressure is active. */
uint64_t xof : 16; /**< [ 31: 16](RO/H) 16-bit XOF back pressure vector from HiGig2 message packet or from PFC packets. Non-
zero only when logical back pressure is active. All bits are 0 when [LGTIM2GO] = 0x0. */
uint64_t reserved_32_63 : 32;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_tx_hg2_status_s cn; */
};
typedef union bdk_bgxx_cmrx_tx_hg2_status bdk_bgxx_cmrx_tx_hg2_status_t;
static inline uint64_t BDK_BGXX_CMRX_TX_HG2_STATUS(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_TX_HG2_STATUS(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000510ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000510ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000510ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_TX_HG2_STATUS", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_TX_HG2_STATUS(a,b) bdk_bgxx_cmrx_tx_hg2_status_t
#define bustype_BDK_BGXX_CMRX_TX_HG2_STATUS(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_TX_HG2_STATUS(a,b) "BGXX_CMRX_TX_HG2_STATUS"
#define device_bar_BDK_BGXX_CMRX_TX_HG2_STATUS(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_TX_HG2_STATUS(a,b) (a)
#define arguments_BDK_BGXX_CMRX_TX_HG2_STATUS(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_tx_ovr_bp
*
* BGX CMR Transmit-Channels Backpressure Override Registers
*/
union bdk_bgxx_cmrx_tx_ovr_bp
{
uint64_t u;
struct bdk_bgxx_cmrx_tx_ovr_bp_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t tx_chan_bp : 16; /**< [ 15: 0](R/W) Per-channel backpressure status sent to NIC. Also see BGX()_PRT_CBFC_CTL for details on
impact to physical backpressure.
0 = Channel is available.
1 = Channel is backpressured. */
#else /* Word 0 - Little Endian */
uint64_t tx_chan_bp : 16; /**< [ 15: 0](R/W) Per-channel backpressure status sent to NIC. Also see BGX()_PRT_CBFC_CTL for details on
impact to physical backpressure.
0 = Channel is available.
1 = Channel is backpressured. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_tx_ovr_bp_s cn81xx; */
struct bdk_bgxx_cmrx_tx_ovr_bp_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t tx_chan_bp : 16; /**< [ 15: 0](R/W) Per-channel backpressure status sent to TNS/NIC.
0 = Channel is available.
1 = Channel is backpressured. */
#else /* Word 0 - Little Endian */
uint64_t tx_chan_bp : 16; /**< [ 15: 0](R/W) Per-channel backpressure status sent to TNS/NIC.
0 = Channel is available.
1 = Channel is backpressured. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} cn88xx;
struct bdk_bgxx_cmrx_tx_ovr_bp_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t tx_chan_bp : 16; /**< [ 15: 0](R/W) Per-channel backpressure status sent to PKO/NIC. Also see BGX()_PRT_CBFC_CTL for
details on impact to physical backpressure.
0 = Channel is available.
1 = Channel is backpressured. */
#else /* Word 0 - Little Endian */
uint64_t tx_chan_bp : 16; /**< [ 15: 0](R/W) Per-channel backpressure status sent to PKO/NIC. Also see BGX()_PRT_CBFC_CTL for
details on impact to physical backpressure.
0 = Channel is available.
1 = Channel is backpressured. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_cmrx_tx_ovr_bp bdk_bgxx_cmrx_tx_ovr_bp_t;
static inline uint64_t BDK_BGXX_CMRX_TX_OVR_BP(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_TX_OVR_BP(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000520ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000520ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000520ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_TX_OVR_BP", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_TX_OVR_BP(a,b) bdk_bgxx_cmrx_tx_ovr_bp_t
#define bustype_BDK_BGXX_CMRX_TX_OVR_BP(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_TX_OVR_BP(a,b) "BGXX_CMRX_TX_OVR_BP"
#define device_bar_BDK_BGXX_CMRX_TX_OVR_BP(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_TX_OVR_BP(a,b) (a)
#define arguments_BDK_BGXX_CMRX_TX_OVR_BP(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_tx_stat0
*
* BGX CMR Transmit Statistics Registers 0
*/
union bdk_bgxx_cmrx_tx_stat0
{
uint64_t u;
struct bdk_bgxx_cmrx_tx_stat0_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t xscol : 48; /**< [ 47: 0](R/W/H) Number of packets dropped (never successfully sent) due to excessive collision. Defined by
BGX()_GMP_GMI_TX_COL_ATTEMPT[LIMIT]. Half-duplex mode only and does not account for late
collisions.
Not cleared on read; cleared on a write with 0x0. Counters will wrap. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
#else /* Word 0 - Little Endian */
uint64_t xscol : 48; /**< [ 47: 0](R/W/H) Number of packets dropped (never successfully sent) due to excessive collision. Defined by
BGX()_GMP_GMI_TX_COL_ATTEMPT[LIMIT]. Half-duplex mode only and does not account for late
collisions.
Not cleared on read; cleared on a write with 0x0. Counters will wrap. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_tx_stat0_s cn; */
};
typedef union bdk_bgxx_cmrx_tx_stat0 bdk_bgxx_cmrx_tx_stat0_t;
static inline uint64_t BDK_BGXX_CMRX_TX_STAT0(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_TX_STAT0(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000600ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000600ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000600ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_TX_STAT0", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_TX_STAT0(a,b) bdk_bgxx_cmrx_tx_stat0_t
#define bustype_BDK_BGXX_CMRX_TX_STAT0(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_TX_STAT0(a,b) "BGXX_CMRX_TX_STAT0"
#define device_bar_BDK_BGXX_CMRX_TX_STAT0(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_TX_STAT0(a,b) (a)
#define arguments_BDK_BGXX_CMRX_TX_STAT0(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_tx_stat1
*
* BGX CMR Transmit Statistics Registers 1
*/
union bdk_bgxx_cmrx_tx_stat1
{
uint64_t u;
struct bdk_bgxx_cmrx_tx_stat1_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t xsdef : 48; /**< [ 47: 0](R/W/H) A count of the number of times any frame was deferred for an excessive period of time.
See maxDeferTime in the IEEE 802.3 specification. Half-duplex mode only and not updated
for late collisions.
Not cleared on read; cleared on a write with 0x0. Counters will wrap. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
#else /* Word 0 - Little Endian */
uint64_t xsdef : 48; /**< [ 47: 0](R/W/H) A count of the number of times any frame was deferred for an excessive period of time.
See maxDeferTime in the IEEE 802.3 specification. Half-duplex mode only and not updated
for late collisions.
Not cleared on read; cleared on a write with 0x0. Counters will wrap. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_tx_stat1_s cn; */
};
typedef union bdk_bgxx_cmrx_tx_stat1 bdk_bgxx_cmrx_tx_stat1_t;
static inline uint64_t BDK_BGXX_CMRX_TX_STAT1(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_TX_STAT1(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000608ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000608ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000608ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_TX_STAT1", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_TX_STAT1(a,b) bdk_bgxx_cmrx_tx_stat1_t
#define bustype_BDK_BGXX_CMRX_TX_STAT1(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_TX_STAT1(a,b) "BGXX_CMRX_TX_STAT1"
#define device_bar_BDK_BGXX_CMRX_TX_STAT1(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_TX_STAT1(a,b) (a)
#define arguments_BDK_BGXX_CMRX_TX_STAT1(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_tx_stat10
*
* BGX CMR Transmit Statistics Registers 10
*/
union bdk_bgxx_cmrx_tx_stat10
{
uint64_t u;
struct bdk_bgxx_cmrx_tx_stat10_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t hist4 : 48; /**< [ 47: 0](R/W/H) Number of packets sent with an octet count between 256-511. Packet length is the sum of
all data transmitted on the wire for the given packet including packet data, pad bytes,
FCS bytes, and JAM bytes. The octet counts do not include PREAMBLE byte or EXTEND cycles.
Not cleared on read; cleared on a write with 0x0. Counters will wrap. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
#else /* Word 0 - Little Endian */
uint64_t hist4 : 48; /**< [ 47: 0](R/W/H) Number of packets sent with an octet count between 256-511. Packet length is the sum of
all data transmitted on the wire for the given packet including packet data, pad bytes,
FCS bytes, and JAM bytes. The octet counts do not include PREAMBLE byte or EXTEND cycles.
Not cleared on read; cleared on a write with 0x0. Counters will wrap. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_tx_stat10_s cn; */
};
typedef union bdk_bgxx_cmrx_tx_stat10 bdk_bgxx_cmrx_tx_stat10_t;
static inline uint64_t BDK_BGXX_CMRX_TX_STAT10(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_TX_STAT10(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000650ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000650ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000650ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_TX_STAT10", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_TX_STAT10(a,b) bdk_bgxx_cmrx_tx_stat10_t
#define bustype_BDK_BGXX_CMRX_TX_STAT10(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_TX_STAT10(a,b) "BGXX_CMRX_TX_STAT10"
#define device_bar_BDK_BGXX_CMRX_TX_STAT10(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_TX_STAT10(a,b) (a)
#define arguments_BDK_BGXX_CMRX_TX_STAT10(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_tx_stat11
*
* BGX CMR Transmit Statistics Registers 11
*/
union bdk_bgxx_cmrx_tx_stat11
{
uint64_t u;
struct bdk_bgxx_cmrx_tx_stat11_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t hist5 : 48; /**< [ 47: 0](R/W/H) Number of packets sent with an octet count between 512-1023. Packet length is the sum of
all data transmitted on the wire for the given packet including packet data, pad bytes,
FCS bytes, and JAM bytes. The octet counts do not include PREAMBLE byte or EXTEND cycles.
Not cleared on read; cleared on a write with 0x0. Counters will wrap. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
#else /* Word 0 - Little Endian */
uint64_t hist5 : 48; /**< [ 47: 0](R/W/H) Number of packets sent with an octet count between 512-1023. Packet length is the sum of
all data transmitted on the wire for the given packet including packet data, pad bytes,
FCS bytes, and JAM bytes. The octet counts do not include PREAMBLE byte or EXTEND cycles.
Not cleared on read; cleared on a write with 0x0. Counters will wrap. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_tx_stat11_s cn; */
};
typedef union bdk_bgxx_cmrx_tx_stat11 bdk_bgxx_cmrx_tx_stat11_t;
static inline uint64_t BDK_BGXX_CMRX_TX_STAT11(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_TX_STAT11(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000658ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000658ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000658ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_TX_STAT11", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_TX_STAT11(a,b) bdk_bgxx_cmrx_tx_stat11_t
#define bustype_BDK_BGXX_CMRX_TX_STAT11(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_TX_STAT11(a,b) "BGXX_CMRX_TX_STAT11"
#define device_bar_BDK_BGXX_CMRX_TX_STAT11(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_TX_STAT11(a,b) (a)
#define arguments_BDK_BGXX_CMRX_TX_STAT11(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_tx_stat12
*
* BGX CMR Transmit Statistics Registers 12
*/
union bdk_bgxx_cmrx_tx_stat12
{
uint64_t u;
struct bdk_bgxx_cmrx_tx_stat12_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t hist6 : 48; /**< [ 47: 0](R/W/H) Number of packets sent with an octet count between 1024-1518. Packet length is the sum of
all data transmitted on the wire for the given packet including packet data, pad bytes,
FCS bytes, and JAM bytes. The octet counts do not include PREAMBLE byte or EXTEND cycles.
Not cleared on read; cleared on a write with 0x0. Counters will wrap. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
#else /* Word 0 - Little Endian */
uint64_t hist6 : 48; /**< [ 47: 0](R/W/H) Number of packets sent with an octet count between 1024-1518. Packet length is the sum of
all data transmitted on the wire for the given packet including packet data, pad bytes,
FCS bytes, and JAM bytes. The octet counts do not include PREAMBLE byte or EXTEND cycles.
Not cleared on read; cleared on a write with 0x0. Counters will wrap. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_tx_stat12_s cn; */
};
typedef union bdk_bgxx_cmrx_tx_stat12 bdk_bgxx_cmrx_tx_stat12_t;
static inline uint64_t BDK_BGXX_CMRX_TX_STAT12(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_TX_STAT12(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000660ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000660ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000660ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_TX_STAT12", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_TX_STAT12(a,b) bdk_bgxx_cmrx_tx_stat12_t
#define bustype_BDK_BGXX_CMRX_TX_STAT12(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_TX_STAT12(a,b) "BGXX_CMRX_TX_STAT12"
#define device_bar_BDK_BGXX_CMRX_TX_STAT12(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_TX_STAT12(a,b) (a)
#define arguments_BDK_BGXX_CMRX_TX_STAT12(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_tx_stat13
*
* BGX CMR Transmit Statistics Registers 13
*/
union bdk_bgxx_cmrx_tx_stat13
{
uint64_t u;
struct bdk_bgxx_cmrx_tx_stat13_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t hist7 : 48; /**< [ 47: 0](R/W/H) Number of packets sent with an octet count \> 1518. Packet length is the sum of all data
transmitted on the wire for the given packet including packet data, pad bytes, FCS bytes,
and JAM bytes. The octet counts do not include PREAMBLE byte or EXTEND cycles.
Not cleared on read; cleared on a write with 0x0. Counters will wrap. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
#else /* Word 0 - Little Endian */
uint64_t hist7 : 48; /**< [ 47: 0](R/W/H) Number of packets sent with an octet count \> 1518. Packet length is the sum of all data
transmitted on the wire for the given packet including packet data, pad bytes, FCS bytes,
and JAM bytes. The octet counts do not include PREAMBLE byte or EXTEND cycles.
Not cleared on read; cleared on a write with 0x0. Counters will wrap. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_tx_stat13_s cn; */
};
typedef union bdk_bgxx_cmrx_tx_stat13 bdk_bgxx_cmrx_tx_stat13_t;
static inline uint64_t BDK_BGXX_CMRX_TX_STAT13(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_TX_STAT13(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000668ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000668ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000668ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_TX_STAT13", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_TX_STAT13(a,b) bdk_bgxx_cmrx_tx_stat13_t
#define bustype_BDK_BGXX_CMRX_TX_STAT13(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_TX_STAT13(a,b) "BGXX_CMRX_TX_STAT13"
#define device_bar_BDK_BGXX_CMRX_TX_STAT13(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_TX_STAT13(a,b) (a)
#define arguments_BDK_BGXX_CMRX_TX_STAT13(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_tx_stat14
*
* BGX CMR Transmit Statistics Registers 14
*/
union bdk_bgxx_cmrx_tx_stat14
{
uint64_t u;
struct bdk_bgxx_cmrx_tx_stat14_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t bcst : 48; /**< [ 47: 0](R/W/H) Number of packets sent to broadcast DMAC, excluding PAUSE or PFC control packets generated
by BGX. Does not include MCST packets.
Not cleared on read; cleared on a write with 0x0. Counters will wrap.
Note that BGX determines if the packet is MCST or BCST from the DMAC of the packet. BGX
assumes that the DMAC lies in the first six bytes of the packet as per the 802.3 frame
definition. If the system requires additional data before the L2 header, the MCST and BCST
counters may not reflect reality and should be ignored by software. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
#else /* Word 0 - Little Endian */
uint64_t bcst : 48; /**< [ 47: 0](R/W/H) Number of packets sent to broadcast DMAC, excluding PAUSE or PFC control packets generated
by BGX. Does not include MCST packets.
Not cleared on read; cleared on a write with 0x0. Counters will wrap.
Note that BGX determines if the packet is MCST or BCST from the DMAC of the packet. BGX
assumes that the DMAC lies in the first six bytes of the packet as per the 802.3 frame
definition. If the system requires additional data before the L2 header, the MCST and BCST
counters may not reflect reality and should be ignored by software. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_tx_stat14_s cn; */
};
typedef union bdk_bgxx_cmrx_tx_stat14 bdk_bgxx_cmrx_tx_stat14_t;
static inline uint64_t BDK_BGXX_CMRX_TX_STAT14(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_TX_STAT14(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000670ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000670ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000670ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_TX_STAT14", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_TX_STAT14(a,b) bdk_bgxx_cmrx_tx_stat14_t
#define bustype_BDK_BGXX_CMRX_TX_STAT14(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_TX_STAT14(a,b) "BGXX_CMRX_TX_STAT14"
#define device_bar_BDK_BGXX_CMRX_TX_STAT14(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_TX_STAT14(a,b) (a)
#define arguments_BDK_BGXX_CMRX_TX_STAT14(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_tx_stat15
*
* BGX CMR Transmit Statistics Registers 15
*/
union bdk_bgxx_cmrx_tx_stat15
{
uint64_t u;
struct bdk_bgxx_cmrx_tx_stat15_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t mcst : 48; /**< [ 47: 0](R/W/H) Number of packets sent to multicast DMAC, excluding PAUSE or PFC control packets generated
by BGX. Does not include BCST packets.
Not cleared on read; cleared on a write with 0x0. Counters will wrap.
Note that BGX determines if the packet is MCST or BCST from the DMAC of the packet. BGX
assumes that the DMAC lies in the first six bytes of the packet as per the 802.3 frame
definition. If the system requires additional data before the L2 header, then the MCST and
BCST counters may not reflect reality and should be ignored by software. Cleared if LMAC
is disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
#else /* Word 0 - Little Endian */
uint64_t mcst : 48; /**< [ 47: 0](R/W/H) Number of packets sent to multicast DMAC, excluding PAUSE or PFC control packets generated
by BGX. Does not include BCST packets.
Not cleared on read; cleared on a write with 0x0. Counters will wrap.
Note that BGX determines if the packet is MCST or BCST from the DMAC of the packet. BGX
assumes that the DMAC lies in the first six bytes of the packet as per the 802.3 frame
definition. If the system requires additional data before the L2 header, then the MCST and
BCST counters may not reflect reality and should be ignored by software. Cleared if LMAC
is disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_tx_stat15_s cn; */
};
typedef union bdk_bgxx_cmrx_tx_stat15 bdk_bgxx_cmrx_tx_stat15_t;
static inline uint64_t BDK_BGXX_CMRX_TX_STAT15(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_TX_STAT15(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000678ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000678ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000678ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_TX_STAT15", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_TX_STAT15(a,b) bdk_bgxx_cmrx_tx_stat15_t
#define bustype_BDK_BGXX_CMRX_TX_STAT15(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_TX_STAT15(a,b) "BGXX_CMRX_TX_STAT15"
#define device_bar_BDK_BGXX_CMRX_TX_STAT15(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_TX_STAT15(a,b) (a)
#define arguments_BDK_BGXX_CMRX_TX_STAT15(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_tx_stat16
*
* BGX CMR Transmit Statistics Registers 16
*/
union bdk_bgxx_cmrx_tx_stat16
{
uint64_t u;
struct bdk_bgxx_cmrx_tx_stat16_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t undflw : 48; /**< [ 47: 0](R/W/H) Number of underflow packets.
Not cleared on read; cleared on a write with 0x0. Counters will wrap. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
#else /* Word 0 - Little Endian */
uint64_t undflw : 48; /**< [ 47: 0](R/W/H) Number of underflow packets.
Not cleared on read; cleared on a write with 0x0. Counters will wrap. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_tx_stat16_s cn; */
};
typedef union bdk_bgxx_cmrx_tx_stat16 bdk_bgxx_cmrx_tx_stat16_t;
static inline uint64_t BDK_BGXX_CMRX_TX_STAT16(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_TX_STAT16(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000680ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000680ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000680ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_TX_STAT16", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_TX_STAT16(a,b) bdk_bgxx_cmrx_tx_stat16_t
#define bustype_BDK_BGXX_CMRX_TX_STAT16(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_TX_STAT16(a,b) "BGXX_CMRX_TX_STAT16"
#define device_bar_BDK_BGXX_CMRX_TX_STAT16(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_TX_STAT16(a,b) (a)
#define arguments_BDK_BGXX_CMRX_TX_STAT16(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_tx_stat17
*
* BGX CMR Transmit Statistics Registers 17
*/
union bdk_bgxx_cmrx_tx_stat17
{
uint64_t u;
struct bdk_bgxx_cmrx_tx_stat17_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t ctl : 48; /**< [ 47: 0](R/W/H) Number of PAUSE or PFC control packets generated by BGX. It does not include control
packets forwarded or generated by the cores. Does not track the number of generated HG2
messages.
Not cleared on read; cleared on a write with 0x0. Counters will wrap. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
#else /* Word 0 - Little Endian */
uint64_t ctl : 48; /**< [ 47: 0](R/W/H) Number of PAUSE or PFC control packets generated by BGX. It does not include control
packets forwarded or generated by the cores. Does not track the number of generated HG2
messages.
Not cleared on read; cleared on a write with 0x0. Counters will wrap. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_tx_stat17_s cn; */
};
typedef union bdk_bgxx_cmrx_tx_stat17 bdk_bgxx_cmrx_tx_stat17_t;
static inline uint64_t BDK_BGXX_CMRX_TX_STAT17(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_TX_STAT17(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000688ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000688ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000688ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_TX_STAT17", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_TX_STAT17(a,b) bdk_bgxx_cmrx_tx_stat17_t
#define bustype_BDK_BGXX_CMRX_TX_STAT17(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_TX_STAT17(a,b) "BGXX_CMRX_TX_STAT17"
#define device_bar_BDK_BGXX_CMRX_TX_STAT17(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_TX_STAT17(a,b) (a)
#define arguments_BDK_BGXX_CMRX_TX_STAT17(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_tx_stat2
*
* BGX CMR Transmit Statistics Registers 2
*/
union bdk_bgxx_cmrx_tx_stat2
{
uint64_t u;
struct bdk_bgxx_cmrx_tx_stat2_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t mcol : 48; /**< [ 47: 0](R/W/H) Number of packets sent with multiple collisions. Must be less than
BGX()_GMP_GMI_TX_COL_ATTEMPT[LIMIT]. Half-duplex mode only and not updated
for late collisions.
Not cleared on read; cleared on a write with 0x0. Counters will wrap. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
#else /* Word 0 - Little Endian */
uint64_t mcol : 48; /**< [ 47: 0](R/W/H) Number of packets sent with multiple collisions. Must be less than
BGX()_GMP_GMI_TX_COL_ATTEMPT[LIMIT]. Half-duplex mode only and not updated
for late collisions.
Not cleared on read; cleared on a write with 0x0. Counters will wrap. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_tx_stat2_s cn; */
};
typedef union bdk_bgxx_cmrx_tx_stat2 bdk_bgxx_cmrx_tx_stat2_t;
static inline uint64_t BDK_BGXX_CMRX_TX_STAT2(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_TX_STAT2(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000610ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000610ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000610ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_TX_STAT2", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_TX_STAT2(a,b) bdk_bgxx_cmrx_tx_stat2_t
#define bustype_BDK_BGXX_CMRX_TX_STAT2(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_TX_STAT2(a,b) "BGXX_CMRX_TX_STAT2"
#define device_bar_BDK_BGXX_CMRX_TX_STAT2(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_TX_STAT2(a,b) (a)
#define arguments_BDK_BGXX_CMRX_TX_STAT2(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_tx_stat3
*
* BGX CMR Transmit Statistics Registers 3
*/
union bdk_bgxx_cmrx_tx_stat3
{
uint64_t u;
struct bdk_bgxx_cmrx_tx_stat3_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t scol : 48; /**< [ 47: 0](R/W/H) Number of packets sent with a single collision. Half-duplex mode only and not updated
for late collisions.
Not cleared on read; cleared on a write with 0x0. Counters will wrap. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
#else /* Word 0 - Little Endian */
uint64_t scol : 48; /**< [ 47: 0](R/W/H) Number of packets sent with a single collision. Half-duplex mode only and not updated
for late collisions.
Not cleared on read; cleared on a write with 0x0. Counters will wrap. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_tx_stat3_s cn; */
};
typedef union bdk_bgxx_cmrx_tx_stat3 bdk_bgxx_cmrx_tx_stat3_t;
static inline uint64_t BDK_BGXX_CMRX_TX_STAT3(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_TX_STAT3(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000618ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000618ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000618ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_TX_STAT3", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_TX_STAT3(a,b) bdk_bgxx_cmrx_tx_stat3_t
#define bustype_BDK_BGXX_CMRX_TX_STAT3(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_TX_STAT3(a,b) "BGXX_CMRX_TX_STAT3"
#define device_bar_BDK_BGXX_CMRX_TX_STAT3(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_TX_STAT3(a,b) (a)
#define arguments_BDK_BGXX_CMRX_TX_STAT3(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_tx_stat4
*
* BGX CMR Transmit Statistics Registers 4
*/
union bdk_bgxx_cmrx_tx_stat4
{
uint64_t u;
struct bdk_bgxx_cmrx_tx_stat4_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t octs : 48; /**< [ 47: 0](R/W/H) Number of total octets sent on the interface, excluding PAUSE or PFC control packets
generated by BGX. Does not count octets from frames that were truncated due to collisions
in half-duplex mode.
Octet counts are the sum of all data transmitted on the wire including packet data, pad
bytes, FCS bytes, and JAM bytes. The octet counts do not include PREAMBLE byte or EXTEND
cycles.
Not cleared on read; cleared on a write with 0x0. Counters will wrap. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
#else /* Word 0 - Little Endian */
uint64_t octs : 48; /**< [ 47: 0](R/W/H) Number of total octets sent on the interface, excluding PAUSE or PFC control packets
generated by BGX. Does not count octets from frames that were truncated due to collisions
in half-duplex mode.
Octet counts are the sum of all data transmitted on the wire including packet data, pad
bytes, FCS bytes, and JAM bytes. The octet counts do not include PREAMBLE byte or EXTEND
cycles.
Not cleared on read; cleared on a write with 0x0. Counters will wrap. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_tx_stat4_s cn; */
};
typedef union bdk_bgxx_cmrx_tx_stat4 bdk_bgxx_cmrx_tx_stat4_t;
static inline uint64_t BDK_BGXX_CMRX_TX_STAT4(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_TX_STAT4(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000620ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000620ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000620ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_TX_STAT4", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_TX_STAT4(a,b) bdk_bgxx_cmrx_tx_stat4_t
#define bustype_BDK_BGXX_CMRX_TX_STAT4(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_TX_STAT4(a,b) "BGXX_CMRX_TX_STAT4"
#define device_bar_BDK_BGXX_CMRX_TX_STAT4(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_TX_STAT4(a,b) (a)
#define arguments_BDK_BGXX_CMRX_TX_STAT4(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_tx_stat5
*
* BGX CMR Transmit Statistics Registers 5
*/
union bdk_bgxx_cmrx_tx_stat5
{
uint64_t u;
struct bdk_bgxx_cmrx_tx_stat5_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t pkts : 48; /**< [ 47: 0](R/W/H) Number of total frames sent on the interface, excluding PAUSE or PFC control packets
generated by BGX. Does not count octets from frames that were truncated due to collisions
in half-duplex mode.
Not cleared on read; cleared on a write with 0x0. Counters will wrap. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
#else /* Word 0 - Little Endian */
uint64_t pkts : 48; /**< [ 47: 0](R/W/H) Number of total frames sent on the interface, excluding PAUSE or PFC control packets
generated by BGX. Does not count octets from frames that were truncated due to collisions
in half-duplex mode.
Not cleared on read; cleared on a write with 0x0. Counters will wrap. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_tx_stat5_s cn; */
};
typedef union bdk_bgxx_cmrx_tx_stat5 bdk_bgxx_cmrx_tx_stat5_t;
static inline uint64_t BDK_BGXX_CMRX_TX_STAT5(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_TX_STAT5(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000628ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000628ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000628ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_TX_STAT5", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_TX_STAT5(a,b) bdk_bgxx_cmrx_tx_stat5_t
#define bustype_BDK_BGXX_CMRX_TX_STAT5(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_TX_STAT5(a,b) "BGXX_CMRX_TX_STAT5"
#define device_bar_BDK_BGXX_CMRX_TX_STAT5(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_TX_STAT5(a,b) (a)
#define arguments_BDK_BGXX_CMRX_TX_STAT5(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_tx_stat6
*
* BGX CMR Transmit Statistics Registers 6
*/
union bdk_bgxx_cmrx_tx_stat6
{
uint64_t u;
struct bdk_bgxx_cmrx_tx_stat6_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t hist0 : 48; /**< [ 47: 0](R/W/H) Number of packets sent with an octet count \< 64, excluding PAUSE or PFC control packets
generated by BGX. Packet length is the sum of all data transmitted on the wire for the
given packet including packet data, pad bytes, FCS bytes, and JAM bytes. The octet counts
do not include PREAMBLE byte or EXTEND cycles.
Not cleared on read; cleared on a write with 0x0. Counters will wrap. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
#else /* Word 0 - Little Endian */
uint64_t hist0 : 48; /**< [ 47: 0](R/W/H) Number of packets sent with an octet count \< 64, excluding PAUSE or PFC control packets
generated by BGX. Packet length is the sum of all data transmitted on the wire for the
given packet including packet data, pad bytes, FCS bytes, and JAM bytes. The octet counts
do not include PREAMBLE byte or EXTEND cycles.
Not cleared on read; cleared on a write with 0x0. Counters will wrap. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_tx_stat6_s cn; */
};
typedef union bdk_bgxx_cmrx_tx_stat6 bdk_bgxx_cmrx_tx_stat6_t;
static inline uint64_t BDK_BGXX_CMRX_TX_STAT6(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_TX_STAT6(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000630ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000630ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000630ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_TX_STAT6", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_TX_STAT6(a,b) bdk_bgxx_cmrx_tx_stat6_t
#define bustype_BDK_BGXX_CMRX_TX_STAT6(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_TX_STAT6(a,b) "BGXX_CMRX_TX_STAT6"
#define device_bar_BDK_BGXX_CMRX_TX_STAT6(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_TX_STAT6(a,b) (a)
#define arguments_BDK_BGXX_CMRX_TX_STAT6(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_tx_stat7
*
* BGX CMR Transmit Statistics Registers 7
*/
union bdk_bgxx_cmrx_tx_stat7
{
uint64_t u;
struct bdk_bgxx_cmrx_tx_stat7_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t hist1 : 48; /**< [ 47: 0](R/W/H) Number of packets sent with an octet count of 64, excluding PAUSE or PFC control packets
generated by BGX. Packet length is the sum of all data transmitted on the wire for the
given packet including packet data, pad bytes, FCS bytes, and JAM bytes. The octet counts
do not include PREAMBLE byte or EXTEND cycles.
Not cleared on read; cleared on a write with 0x0. Counters will wrap. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
#else /* Word 0 - Little Endian */
uint64_t hist1 : 48; /**< [ 47: 0](R/W/H) Number of packets sent with an octet count of 64, excluding PAUSE or PFC control packets
generated by BGX. Packet length is the sum of all data transmitted on the wire for the
given packet including packet data, pad bytes, FCS bytes, and JAM bytes. The octet counts
do not include PREAMBLE byte or EXTEND cycles.
Not cleared on read; cleared on a write with 0x0. Counters will wrap. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_tx_stat7_s cn; */
};
typedef union bdk_bgxx_cmrx_tx_stat7 bdk_bgxx_cmrx_tx_stat7_t;
static inline uint64_t BDK_BGXX_CMRX_TX_STAT7(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_TX_STAT7(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000638ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000638ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000638ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_TX_STAT7", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_TX_STAT7(a,b) bdk_bgxx_cmrx_tx_stat7_t
#define bustype_BDK_BGXX_CMRX_TX_STAT7(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_TX_STAT7(a,b) "BGXX_CMRX_TX_STAT7"
#define device_bar_BDK_BGXX_CMRX_TX_STAT7(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_TX_STAT7(a,b) (a)
#define arguments_BDK_BGXX_CMRX_TX_STAT7(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_tx_stat8
*
* BGX CMR Transmit Statistics Registers 8
*/
union bdk_bgxx_cmrx_tx_stat8
{
uint64_t u;
struct bdk_bgxx_cmrx_tx_stat8_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t hist2 : 48; /**< [ 47: 0](R/W/H) Number of packets sent with an octet count between 65-127. Packet length is the sum of all
data transmitted on the wire for the given packet including packet data, pad bytes, FCS
bytes, and JAM bytes. The octet counts do not include PREAMBLE byte or EXTEND cycles.
Not cleared on read; cleared on a write with 0x0. Counters will wrap. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
#else /* Word 0 - Little Endian */
uint64_t hist2 : 48; /**< [ 47: 0](R/W/H) Number of packets sent with an octet count between 65-127. Packet length is the sum of all
data transmitted on the wire for the given packet including packet data, pad bytes, FCS
bytes, and JAM bytes. The octet counts do not include PREAMBLE byte or EXTEND cycles.
Not cleared on read; cleared on a write with 0x0. Counters will wrap. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_tx_stat8_s cn; */
};
typedef union bdk_bgxx_cmrx_tx_stat8 bdk_bgxx_cmrx_tx_stat8_t;
static inline uint64_t BDK_BGXX_CMRX_TX_STAT8(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_TX_STAT8(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000640ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000640ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000640ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_TX_STAT8", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_TX_STAT8(a,b) bdk_bgxx_cmrx_tx_stat8_t
#define bustype_BDK_BGXX_CMRX_TX_STAT8(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_TX_STAT8(a,b) "BGXX_CMRX_TX_STAT8"
#define device_bar_BDK_BGXX_CMRX_TX_STAT8(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_TX_STAT8(a,b) (a)
#define arguments_BDK_BGXX_CMRX_TX_STAT8(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr#_tx_stat9
*
* BGX CMR Transmit Statistics Registers 9
*/
union bdk_bgxx_cmrx_tx_stat9
{
uint64_t u;
struct bdk_bgxx_cmrx_tx_stat9_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t hist3 : 48; /**< [ 47: 0](R/W/H) Number of packets sent with an octet count between 128-255. Packet length is the sum of
all data transmitted on the wire for the given packet including packet data, pad bytes,
FCS bytes, and JAM bytes. The octet counts do not include PREAMBLE byte or EXTEND cycles.
Not cleared on read; cleared on a write with 0x0. Counters will wrap. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
#else /* Word 0 - Little Endian */
uint64_t hist3 : 48; /**< [ 47: 0](R/W/H) Number of packets sent with an octet count between 128-255. Packet length is the sum of
all data transmitted on the wire for the given packet including packet data, pad bytes,
FCS bytes, and JAM bytes. The octet counts do not include PREAMBLE byte or EXTEND cycles.
Not cleared on read; cleared on a write with 0x0. Counters will wrap. Cleared if LMAC is
disabled with BGX()_CMR()_CONFIG[ENABLE]=0. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmrx_tx_stat9_s cn; */
};
typedef union bdk_bgxx_cmrx_tx_stat9 bdk_bgxx_cmrx_tx_stat9_t;
static inline uint64_t BDK_BGXX_CMRX_TX_STAT9(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMRX_TX_STAT9(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000648ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0000648ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0000648ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_CMRX_TX_STAT9", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMRX_TX_STAT9(a,b) bdk_bgxx_cmrx_tx_stat9_t
#define bustype_BDK_BGXX_CMRX_TX_STAT9(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMRX_TX_STAT9(a,b) "BGXX_CMRX_TX_STAT9"
#define device_bar_BDK_BGXX_CMRX_TX_STAT9(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMRX_TX_STAT9(a,b) (a)
#define arguments_BDK_BGXX_CMRX_TX_STAT9(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr_bad
*
* BGX CMR Bad Registers
*/
union bdk_bgxx_cmr_bad
{
uint64_t u;
struct bdk_bgxx_cmr_bad_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_1_63 : 63;
uint64_t rxb_nxl : 1; /**< [ 0: 0](R/W1C/H) Receive side LMAC ID \> BGX()_CMR_RX_LMACS. */
#else /* Word 0 - Little Endian */
uint64_t rxb_nxl : 1; /**< [ 0: 0](R/W1C/H) Receive side LMAC ID \> BGX()_CMR_RX_LMACS. */
uint64_t reserved_1_63 : 63;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmr_bad_s cn; */
};
typedef union bdk_bgxx_cmr_bad bdk_bgxx_cmr_bad_t;
static inline uint64_t BDK_BGXX_CMR_BAD(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMR_BAD(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e0001020ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e0001020ll + 0x1000000ll * ((a) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && (a<=1))
return 0x87e0e0001020ll + 0x1000000ll * ((a) & 0x1);
__bdk_csr_fatal("BGXX_CMR_BAD", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_CMR_BAD(a) bdk_bgxx_cmr_bad_t
#define bustype_BDK_BGXX_CMR_BAD(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMR_BAD(a) "BGXX_CMR_BAD"
#define device_bar_BDK_BGXX_CMR_BAD(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMR_BAD(a) (a)
#define arguments_BDK_BGXX_CMR_BAD(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_cmr_bist_status
*
* BGX Built-in Self-Test Registers
*/
union bdk_bgxx_cmr_bist_status
{
uint64_t u;
struct bdk_bgxx_cmr_bist_status_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_27_63 : 37;
uint64_t status : 27; /**< [ 26: 0](RO/H) '"BIST results. Hardware sets a bit to 1 for memory that fails; 0 indicates pass or never
run.'
Internal:
"\<0\> = bgx#.rxb.infif_gmp.
\<1\> = bgx#.rxb.infif_smu.
\<2\> = bgx#.rxb.fif_bnk00.
\<3\> = bgx#.rxb.fif_bnk01.
\<4\> = bgx#.rxb.fif_bnk10.
\<5\> = bgx#.rxb.fif_bnk11.
\<6\> = bgx#.rxb.pki_skd_fif.
\<7\> = bgx#.rxb.nic_skd_fif.
\<8\> = bgx#.rxb_mix0_fif.
\<9\> = bgx#.rxb_mix1_fif.
\<10\> = 0.
\<11\> = bgx#.txb_fif_bnk0.
\<12\> = bgx#.txb_fif_bnk1.
\<13\> = bgx#.txb_skd_m0_pko_fif.
\<14\> = bgx#.txb_skd_m1_pko_fif.
\<15\> = bgx#.txb_skd_m2_pko_fif.
\<16\> = bgx#.txb_skd_m3_pko_fif.
\<17\> = bgx#.txb_skd_m0_nic_fif.
\<18\> = bgx#.txb_skd_m1_nic_fif.
\<19\> = bgx#.txb_skd_m2_nic_fif.
\<20\> = bgx#.txb_skd_m3_nic_fif.
\<21\> = bgx#.txb_mix0_fif.
\<22\> = bgx#.txb_mix1_fif.
\<23\> = bgx#.txb_ncsi_fif.
\<24\> = 0." */
#else /* Word 0 - Little Endian */
uint64_t status : 27; /**< [ 26: 0](RO/H) '"BIST results. Hardware sets a bit to 1 for memory that fails; 0 indicates pass or never
run.'
Internal:
"\<0\> = bgx#.rxb.infif_gmp.
\<1\> = bgx#.rxb.infif_smu.
\<2\> = bgx#.rxb.fif_bnk00.
\<3\> = bgx#.rxb.fif_bnk01.
\<4\> = bgx#.rxb.fif_bnk10.
\<5\> = bgx#.rxb.fif_bnk11.
\<6\> = bgx#.rxb.pki_skd_fif.
\<7\> = bgx#.rxb.nic_skd_fif.
\<8\> = bgx#.rxb_mix0_fif.
\<9\> = bgx#.rxb_mix1_fif.
\<10\> = 0.
\<11\> = bgx#.txb_fif_bnk0.
\<12\> = bgx#.txb_fif_bnk1.
\<13\> = bgx#.txb_skd_m0_pko_fif.
\<14\> = bgx#.txb_skd_m1_pko_fif.
\<15\> = bgx#.txb_skd_m2_pko_fif.
\<16\> = bgx#.txb_skd_m3_pko_fif.
\<17\> = bgx#.txb_skd_m0_nic_fif.
\<18\> = bgx#.txb_skd_m1_nic_fif.
\<19\> = bgx#.txb_skd_m2_nic_fif.
\<20\> = bgx#.txb_skd_m3_nic_fif.
\<21\> = bgx#.txb_mix0_fif.
\<22\> = bgx#.txb_mix1_fif.
\<23\> = bgx#.txb_ncsi_fif.
\<24\> = 0." */
uint64_t reserved_27_63 : 37;
#endif /* Word 0 - End */
} s;
struct bdk_bgxx_cmr_bist_status_cn81xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_25_63 : 39;
uint64_t status : 25; /**< [ 24: 0](RO/H) '"BIST results. Hardware sets a bit to 1 for memory that fails; 0 indicates pass or never
run.'
Internal:
"\<0\> = bgx#.rxb.infif_gmp.
\<1\> = bgx#.rxb.infif_smu.
\<2\> = bgx#.rxb.fif_bnk00.
\<3\> = bgx#.rxb.fif_bnk01.
\<4\> = bgx#.rxb.fif_bnk10.
\<5\> = bgx#.rxb.fif_bnk11.
\<6\> = bgx#.rxb.pki_skd_fif.
\<7\> = bgx#.rxb.nic_skd_fif.
\<8\> = bgx#.rxb_mix0_fif.
\<9\> = bgx#.rxb_mix1_fif.
\<10\> = 0.
\<11\> = bgx#.txb_fif_bnk0.
\<12\> = bgx#.txb_fif_bnk1.
\<13\> = bgx#.txb_skd_m0_pko_fif.
\<14\> = bgx#.txb_skd_m1_pko_fif.
\<15\> = bgx#.txb_skd_m2_pko_fif.
\<16\> = bgx#.txb_skd_m3_pko_fif.
\<17\> = bgx#.txb_skd_m0_nic_fif.
\<18\> = bgx#.txb_skd_m1_nic_fif.
\<19\> = bgx#.txb_skd_m2_nic_fif.
\<20\> = bgx#.txb_skd_m3_nic_fif.
\<21\> = bgx#.txb_mix0_fif.
\<22\> = bgx#.txb_mix1_fif.
\<23\> = bgx#.txb_ncsi_fif.
\<24\> = 0." */
#else /* Word 0 - Little Endian */
uint64_t status : 25; /**< [ 24: 0](RO/H) '"BIST results. Hardware sets a bit to 1 for memory that fails; 0 indicates pass or never
run.'
Internal:
"\<0\> = bgx#.rxb.infif_gmp.
\<1\> = bgx#.rxb.infif_smu.
\<2\> = bgx#.rxb.fif_bnk00.
\<3\> = bgx#.rxb.fif_bnk01.
\<4\> = bgx#.rxb.fif_bnk10.
\<5\> = bgx#.rxb.fif_bnk11.
\<6\> = bgx#.rxb.pki_skd_fif.
\<7\> = bgx#.rxb.nic_skd_fif.
\<8\> = bgx#.rxb_mix0_fif.
\<9\> = bgx#.rxb_mix1_fif.
\<10\> = 0.
\<11\> = bgx#.txb_fif_bnk0.
\<12\> = bgx#.txb_fif_bnk1.
\<13\> = bgx#.txb_skd_m0_pko_fif.
\<14\> = bgx#.txb_skd_m1_pko_fif.
\<15\> = bgx#.txb_skd_m2_pko_fif.
\<16\> = bgx#.txb_skd_m3_pko_fif.
\<17\> = bgx#.txb_skd_m0_nic_fif.
\<18\> = bgx#.txb_skd_m1_nic_fif.
\<19\> = bgx#.txb_skd_m2_nic_fif.
\<20\> = bgx#.txb_skd_m3_nic_fif.
\<21\> = bgx#.txb_mix0_fif.
\<22\> = bgx#.txb_mix1_fif.
\<23\> = bgx#.txb_ncsi_fif.
\<24\> = 0." */
uint64_t reserved_25_63 : 39;
#endif /* Word 0 - End */
} cn81xx;
struct bdk_bgxx_cmr_bist_status_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_25_63 : 39;
uint64_t status : 25; /**< [ 24: 0](RO/H) '"BIST results. Hardware sets a bit to 1 for memory that fails; 0 indicates pass or never
run.'
Internal:
"\<0\> = bgx#.rxb.infif_gmp.
\<1\> = bgx#.rxb.infif_smu.
\<2\> = bgx#.rxb.fif_bnk00.
\<3\> = bgx#.rxb.fif_bnk01.
\<4\> = bgx#.rxb.fif_bnk10.
\<5\> = bgx#.rxb.fif_bnk11.
\<6\> = bgx#.rxb.skd_fif.
\<7\> = bgx#.rxb_mix0_fif.
\<8\> = bgx#.rxb_mix1_fif.
\<9\> = 0.
\<10\> = bgx#.txb_fif_bnk0.
\<11\> = bgx#.txb_fif_bnk1.
\<12\> = bgx#.txb_skd_m0_fif.
\<13\> = bgx#.txb_skd_m1_fif.
\<14\> = bgx#.txb_skd_m2_fif.
\<15\> = bgx#.txb_skd_m3_fif.
\<16\> = bgx#.txb_mix0_fif.
\<17\> = bgx#.txb_mix1_fif.
\<18\> = bgx#.txb_ncsi_fif.
\<24:19\> = 0x0." */
#else /* Word 0 - Little Endian */
uint64_t status : 25; /**< [ 24: 0](RO/H) '"BIST results. Hardware sets a bit to 1 for memory that fails; 0 indicates pass or never
run.'
Internal:
"\<0\> = bgx#.rxb.infif_gmp.
\<1\> = bgx#.rxb.infif_smu.
\<2\> = bgx#.rxb.fif_bnk00.
\<3\> = bgx#.rxb.fif_bnk01.
\<4\> = bgx#.rxb.fif_bnk10.
\<5\> = bgx#.rxb.fif_bnk11.
\<6\> = bgx#.rxb.skd_fif.
\<7\> = bgx#.rxb_mix0_fif.
\<8\> = bgx#.rxb_mix1_fif.
\<9\> = 0.
\<10\> = bgx#.txb_fif_bnk0.
\<11\> = bgx#.txb_fif_bnk1.
\<12\> = bgx#.txb_skd_m0_fif.
\<13\> = bgx#.txb_skd_m1_fif.
\<14\> = bgx#.txb_skd_m2_fif.
\<15\> = bgx#.txb_skd_m3_fif.
\<16\> = bgx#.txb_mix0_fif.
\<17\> = bgx#.txb_mix1_fif.
\<18\> = bgx#.txb_ncsi_fif.
\<24:19\> = 0x0." */
uint64_t reserved_25_63 : 39;
#endif /* Word 0 - End */
} cn88xx;
struct bdk_bgxx_cmr_bist_status_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_27_63 : 37;
uint64_t status : 27; /**< [ 26: 0](RO/H) '"BIST results. Hardware sets a bit to 1 for memory that fails; 0 indicates pass or never
run.'
Internal:
"\<0\> = bgx#.rxb.infif_gmp.
\<1\> = bgx#.rxb.infif_smu.
\<2\> = bgx#.rxb.fif_bnk00.
\<3\> = bgx#.rxb.fif_bnk01.
\<4\> = bgx#.rxb.fif_bnk10.
\<5\> = bgx#.rxb.fif_bnk11.
\<6\> = bgx#.rxb.pki_skd_fif.
\<7\> = bgx#.rxb.nic_skd_fif.
\<8\> = bgx#.rxb_mix0_fif.
\<9\> = bgx#.rxb_mix1_fif.
\<10\> = 0.
\<11\> = bgx#.txb_fif_mem0.
\<12\> = bgx#.txb_fif_mem1.
\<13\> = bgx#.txb_fif_mem2.
\<14\> = bgx#.txb_fif_mem3.
\<15\> = bgx#.txb_skd_m0_pko_fif.
\<16\> = bgx#.txb_skd_m1_pko_fif.
\<17\> = bgx#.txb_skd_m2_pko_fif.
\<18\> = bgx#.txb_skd_m3_pko_fif.
\<19\> = bgx#.txb_skd_m0_nic_fif.
\<20\> = bgx#.txb_skd_m1_nic_fif.
\<21\> = bgx#.txb_skd_m2_nic_fif.
\<22\> = bgx#.txb_skd_m3_nic_fif.
\<23\> = bgx#.txb_mix0_fif.
\<24\> = bgx#.txb_mix1_fif.
\<25\> = bgx#.txb_ncsi_fif.
\<26\> = 0." */
#else /* Word 0 - Little Endian */
uint64_t status : 27; /**< [ 26: 0](RO/H) '"BIST results. Hardware sets a bit to 1 for memory that fails; 0 indicates pass or never
run.'
Internal:
"\<0\> = bgx#.rxb.infif_gmp.
\<1\> = bgx#.rxb.infif_smu.
\<2\> = bgx#.rxb.fif_bnk00.
\<3\> = bgx#.rxb.fif_bnk01.
\<4\> = bgx#.rxb.fif_bnk10.
\<5\> = bgx#.rxb.fif_bnk11.
\<6\> = bgx#.rxb.pki_skd_fif.
\<7\> = bgx#.rxb.nic_skd_fif.
\<8\> = bgx#.rxb_mix0_fif.
\<9\> = bgx#.rxb_mix1_fif.
\<10\> = 0.
\<11\> = bgx#.txb_fif_mem0.
\<12\> = bgx#.txb_fif_mem1.
\<13\> = bgx#.txb_fif_mem2.
\<14\> = bgx#.txb_fif_mem3.
\<15\> = bgx#.txb_skd_m0_pko_fif.
\<16\> = bgx#.txb_skd_m1_pko_fif.
\<17\> = bgx#.txb_skd_m2_pko_fif.
\<18\> = bgx#.txb_skd_m3_pko_fif.
\<19\> = bgx#.txb_skd_m0_nic_fif.
\<20\> = bgx#.txb_skd_m1_nic_fif.
\<21\> = bgx#.txb_skd_m2_nic_fif.
\<22\> = bgx#.txb_skd_m3_nic_fif.
\<23\> = bgx#.txb_mix0_fif.
\<24\> = bgx#.txb_mix1_fif.
\<25\> = bgx#.txb_ncsi_fif.
\<26\> = 0." */
uint64_t reserved_27_63 : 37;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_cmr_bist_status bdk_bgxx_cmr_bist_status_t;
static inline uint64_t BDK_BGXX_CMR_BIST_STATUS(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMR_BIST_STATUS(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e0000460ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e0000460ll + 0x1000000ll * ((a) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && (a<=1))
return 0x87e0e0000460ll + 0x1000000ll * ((a) & 0x1);
__bdk_csr_fatal("BGXX_CMR_BIST_STATUS", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_CMR_BIST_STATUS(a) bdk_bgxx_cmr_bist_status_t
#define bustype_BDK_BGXX_CMR_BIST_STATUS(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMR_BIST_STATUS(a) "BGXX_CMR_BIST_STATUS"
#define device_bar_BDK_BGXX_CMR_BIST_STATUS(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMR_BIST_STATUS(a) (a)
#define arguments_BDK_BGXX_CMR_BIST_STATUS(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_cmr_chan_msk_and
*
* BGX CMR Backpressure Channel Mask AND Registers
*/
union bdk_bgxx_cmr_chan_msk_and
{
uint64_t u;
struct bdk_bgxx_cmr_chan_msk_and_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t msk_and : 64; /**< [ 63: 0](R/W) Assert physical backpressure when the backpressure channel vector combined with [MSK_AND]
indicates backpressure as follows:
_ phys_bp_msk_and = [MSK_AND]\<x:y\> != 0 && (chan_vector\<x:y\> & [MSK_AND]\<x:y\>) ==
[MSK_AND]\<x:y\>
_ phys_bp = phys_bp_msk_or || phys_bp_msk_and
x/y are as follows:
_ LMAC 0: \<x:y\> = \<15:0\>.
_ LMAC 1: \<x:y\> = \<31:16\>.
_ LMAC 2: \<x:y\> = \<47:32\>.
_ LMAC 3: \<x:y\> = \<63:48\>. */
#else /* Word 0 - Little Endian */
uint64_t msk_and : 64; /**< [ 63: 0](R/W) Assert physical backpressure when the backpressure channel vector combined with [MSK_AND]
indicates backpressure as follows:
_ phys_bp_msk_and = [MSK_AND]\<x:y\> != 0 && (chan_vector\<x:y\> & [MSK_AND]\<x:y\>) ==
[MSK_AND]\<x:y\>
_ phys_bp = phys_bp_msk_or || phys_bp_msk_and
x/y are as follows:
_ LMAC 0: \<x:y\> = \<15:0\>.
_ LMAC 1: \<x:y\> = \<31:16\>.
_ LMAC 2: \<x:y\> = \<47:32\>.
_ LMAC 3: \<x:y\> = \<63:48\>. */
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmr_chan_msk_and_s cn; */
};
typedef union bdk_bgxx_cmr_chan_msk_and bdk_bgxx_cmr_chan_msk_and_t;
static inline uint64_t BDK_BGXX_CMR_CHAN_MSK_AND(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMR_CHAN_MSK_AND(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e0000450ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e0000450ll + 0x1000000ll * ((a) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && (a<=1))
return 0x87e0e0000450ll + 0x1000000ll * ((a) & 0x1);
__bdk_csr_fatal("BGXX_CMR_CHAN_MSK_AND", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_CMR_CHAN_MSK_AND(a) bdk_bgxx_cmr_chan_msk_and_t
#define bustype_BDK_BGXX_CMR_CHAN_MSK_AND(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMR_CHAN_MSK_AND(a) "BGXX_CMR_CHAN_MSK_AND"
#define device_bar_BDK_BGXX_CMR_CHAN_MSK_AND(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMR_CHAN_MSK_AND(a) (a)
#define arguments_BDK_BGXX_CMR_CHAN_MSK_AND(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_cmr_chan_msk_or
*
* BGX Backpressure Channel Mask OR Registers
*/
union bdk_bgxx_cmr_chan_msk_or
{
uint64_t u;
struct bdk_bgxx_cmr_chan_msk_or_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t msk_or : 64; /**< [ 63: 0](R/W) Assert physical backpressure when the backpressure channel vector combined with [MSK_OR]
indicates backpressure as follows:
_ phys_bp_msk_or = (chan_vector\<x:y\> & [MSK_OR]\<x:y\>) != 0
_ phys_bp = phys_bp_msk_or || phys_bp_msk_and
x/y are as follows:
_ LMAC 0: \<x:y\> = \<15:0\>.
_ LMAC 1: \<x:y\> = \<31:16\>.
_ LMAC 2: \<x:y\> = \<47:32\>.
_ LMAC 3: \<x:y\> = \<63:48\>. */
#else /* Word 0 - Little Endian */
uint64_t msk_or : 64; /**< [ 63: 0](R/W) Assert physical backpressure when the backpressure channel vector combined with [MSK_OR]
indicates backpressure as follows:
_ phys_bp_msk_or = (chan_vector\<x:y\> & [MSK_OR]\<x:y\>) != 0
_ phys_bp = phys_bp_msk_or || phys_bp_msk_and
x/y are as follows:
_ LMAC 0: \<x:y\> = \<15:0\>.
_ LMAC 1: \<x:y\> = \<31:16\>.
_ LMAC 2: \<x:y\> = \<47:32\>.
_ LMAC 3: \<x:y\> = \<63:48\>. */
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmr_chan_msk_or_s cn; */
};
typedef union bdk_bgxx_cmr_chan_msk_or bdk_bgxx_cmr_chan_msk_or_t;
static inline uint64_t BDK_BGXX_CMR_CHAN_MSK_OR(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMR_CHAN_MSK_OR(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e0000458ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e0000458ll + 0x1000000ll * ((a) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && (a<=1))
return 0x87e0e0000458ll + 0x1000000ll * ((a) & 0x1);
__bdk_csr_fatal("BGXX_CMR_CHAN_MSK_OR", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_CMR_CHAN_MSK_OR(a) bdk_bgxx_cmr_chan_msk_or_t
#define bustype_BDK_BGXX_CMR_CHAN_MSK_OR(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMR_CHAN_MSK_OR(a) "BGXX_CMR_CHAN_MSK_OR"
#define device_bar_BDK_BGXX_CMR_CHAN_MSK_OR(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMR_CHAN_MSK_OR(a) (a)
#define arguments_BDK_BGXX_CMR_CHAN_MSK_OR(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_cmr_eco
*
* INTERNAL: BGX ECO Registers
*/
union bdk_bgxx_cmr_eco
{
uint64_t u;
struct bdk_bgxx_cmr_eco_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t eco_ro : 32; /**< [ 63: 32](RO) Internal:
Reserved for ECO usage. */
uint64_t eco_rw : 32; /**< [ 31: 0](R/W) Internal:
Reserved for ECO usage. */
#else /* Word 0 - Little Endian */
uint64_t eco_rw : 32; /**< [ 31: 0](R/W) Internal:
Reserved for ECO usage. */
uint64_t eco_ro : 32; /**< [ 63: 32](RO) Internal:
Reserved for ECO usage. */
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmr_eco_s cn; */
};
typedef union bdk_bgxx_cmr_eco bdk_bgxx_cmr_eco_t;
static inline uint64_t BDK_BGXX_CMR_ECO(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMR_ECO(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e0001028ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e0001028ll + 0x1000000ll * ((a) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX_PASS2_X) && (a<=1))
return 0x87e0e0001028ll + 0x1000000ll * ((a) & 0x1);
__bdk_csr_fatal("BGXX_CMR_ECO", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_CMR_ECO(a) bdk_bgxx_cmr_eco_t
#define bustype_BDK_BGXX_CMR_ECO(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMR_ECO(a) "BGXX_CMR_ECO"
#define device_bar_BDK_BGXX_CMR_ECO(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMR_ECO(a) (a)
#define arguments_BDK_BGXX_CMR_ECO(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_cmr_global_config
*
* BGX CMR Global Configuration Register
* These registers configure the global CMR, PCS, and MAC.
*/
union bdk_bgxx_cmr_global_config
{
uint64_t u;
struct bdk_bgxx_cmr_global_config_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_12_63 : 52;
uint64_t cmr_x2p1_reset : 1; /**< [ 11: 11](R/W) If the master block connected to X2P interface 1 is reset, software also needs
to reset the X2P interface in the BGX by setting this bit. It resets the X2P
interface state in the BGX (skid FIFO and pending requests to the master block)
and prevents the RXB FIFOs for all LMACs from pushing data to the
interface. Because the X2P and NCSI interfaces share the main RXB FIFOs it will
also impact the NCSI interface therefore it is required to set [CMR_NCSI_DROP]
bit first before setting this bit.
Clearing this does not reset the X2P interface nor NCSI interface. After the
master block comes out of reset, software should clear this bit. */
uint64_t cmr_ncsi_reset : 1; /**< [ 10: 10](R/W) Interface reset for the CMR NCSI block.
Upon power up the CMR NCSI is in reset and the companion CNXXXX NCSI block will be
commanded by the
external BMC to enable one of the CNXXXX BGX NCSI interfaces for passing network traffic.
Only one NCSI interface can be enabled in CNXXXX. The BMC/NCSI will then proceed to
configure
the rest of the BGX csr for pass through traffic.
When set, will reset the CMR NCSI interface effectively disabling it at a traffic boundary
should traffic be flowing. This bit will not reset the main RXB fifos. */
uint64_t cmr_ncsi_drop : 1; /**< [ 9: 9](R/W) NCSI drop.
1 = Cleanly drop traffic going into the NCSI block of BGX. Must set asserted
with with [CMR_X2P_RESET]=1 (in the same write operation) to avoid partial packets
to the NCSI interface while performing a X2P partner reset.
0 = Allow traffic to flow through the NCSI block. */
uint64_t ncsi_lmac_id : 2; /**< [ 8: 7](R/W) Logical MAC ID that carries NCSI traffic for both RX and TX side of CMR. On the RX side
is
also the LMAC_ID that is eligible for steering. */
uint64_t fcs_strip : 1; /**< [ 6: 6](R/W) A setting of 1 means the BGX strip the FCS bytes of every packet. For packets less than 4
bytes, the packet will be removed.
A setting of 0 means the BGX will not modify or remove the FCS bytes. */
uint64_t interleave_mode : 1; /**< [ 5: 5](R/W) A setting of 0 means the BGX will operate in non-interleaved mode where there is 1 packet
from a given lmac in flight on the X2P interface to TNS/NIC. A setting of 1 means the BGX
will operate in interleaved mode where each valid consecutive cycle on the X2P interface
may contain words from different lmacs. In other words there will be multiple packets in
flight from different lmacs at the same time. */
uint64_t cmr_mix1_reset : 1; /**< [ 4: 4](R/W) Must be 0. */
uint64_t cmr_mix0_reset : 1; /**< [ 3: 3](R/W) Must be 0. */
uint64_t cmr_x2p_reset : 1; /**< [ 2: 2](R/W) If the NIC block is reset, software also needs to reset the X2P interface in the
BGX by
setting this bit to 1. It resets the X2P interface state in the BGX (skid FIFO and pending
requests to NIC) and prevents the RXB FIFOs for all LMACs from pushing data to the
interface.
Setting this bit to 0 does not reset the X2P interface.
After NIC comes out of reset, software should clear this bit. */
uint64_t bgx_clk_enable : 1; /**< [ 1: 1](R/W) The global clock enable for BGX. Setting this bit overrides clock enables set by
BGX()_CMR()_CONFIG[ENABLE] and BGX()_CMR()_CONFIG[LMAC_TYPE], essentially
turning on clocks for the entire BGX. Setting this bit to 0 results in not overriding
clock enables set by BGX()_CMR()_CONFIG[ENABLE] and
BGX()_CMR()_CONFIG[LMAC_TYPE]. */
uint64_t pmux_sds_sel : 1; /**< [ 0: 0](R/W) SerDes/GSER output select. Must be 0. */
#else /* Word 0 - Little Endian */
uint64_t pmux_sds_sel : 1; /**< [ 0: 0](R/W) SerDes/GSER output select. Must be 0. */
uint64_t bgx_clk_enable : 1; /**< [ 1: 1](R/W) The global clock enable for BGX. Setting this bit overrides clock enables set by
BGX()_CMR()_CONFIG[ENABLE] and BGX()_CMR()_CONFIG[LMAC_TYPE], essentially
turning on clocks for the entire BGX. Setting this bit to 0 results in not overriding
clock enables set by BGX()_CMR()_CONFIG[ENABLE] and
BGX()_CMR()_CONFIG[LMAC_TYPE]. */
uint64_t cmr_x2p_reset : 1; /**< [ 2: 2](R/W) If the NIC block is reset, software also needs to reset the X2P interface in the
BGX by
setting this bit to 1. It resets the X2P interface state in the BGX (skid FIFO and pending
requests to NIC) and prevents the RXB FIFOs for all LMACs from pushing data to the
interface.
Setting this bit to 0 does not reset the X2P interface.
After NIC comes out of reset, software should clear this bit. */
uint64_t cmr_mix0_reset : 1; /**< [ 3: 3](R/W) Must be 0. */
uint64_t cmr_mix1_reset : 1; /**< [ 4: 4](R/W) Must be 0. */
uint64_t interleave_mode : 1; /**< [ 5: 5](R/W) A setting of 0 means the BGX will operate in non-interleaved mode where there is 1 packet
from a given lmac in flight on the X2P interface to TNS/NIC. A setting of 1 means the BGX
will operate in interleaved mode where each valid consecutive cycle on the X2P interface
may contain words from different lmacs. In other words there will be multiple packets in
flight from different lmacs at the same time. */
uint64_t fcs_strip : 1; /**< [ 6: 6](R/W) A setting of 1 means the BGX strip the FCS bytes of every packet. For packets less than 4
bytes, the packet will be removed.
A setting of 0 means the BGX will not modify or remove the FCS bytes. */
uint64_t ncsi_lmac_id : 2; /**< [ 8: 7](R/W) Logical MAC ID that carries NCSI traffic for both RX and TX side of CMR. On the RX side
is
also the LMAC_ID that is eligible for steering. */
uint64_t cmr_ncsi_drop : 1; /**< [ 9: 9](R/W) NCSI drop.
1 = Cleanly drop traffic going into the NCSI block of BGX. Must set asserted
with with [CMR_X2P_RESET]=1 (in the same write operation) to avoid partial packets
to the NCSI interface while performing a X2P partner reset.
0 = Allow traffic to flow through the NCSI block. */
uint64_t cmr_ncsi_reset : 1; /**< [ 10: 10](R/W) Interface reset for the CMR NCSI block.
Upon power up the CMR NCSI is in reset and the companion CNXXXX NCSI block will be
commanded by the
external BMC to enable one of the CNXXXX BGX NCSI interfaces for passing network traffic.
Only one NCSI interface can be enabled in CNXXXX. The BMC/NCSI will then proceed to
configure
the rest of the BGX csr for pass through traffic.
When set, will reset the CMR NCSI interface effectively disabling it at a traffic boundary
should traffic be flowing. This bit will not reset the main RXB fifos. */
uint64_t cmr_x2p1_reset : 1; /**< [ 11: 11](R/W) If the master block connected to X2P interface 1 is reset, software also needs
to reset the X2P interface in the BGX by setting this bit. It resets the X2P
interface state in the BGX (skid FIFO and pending requests to the master block)
and prevents the RXB FIFOs for all LMACs from pushing data to the
interface. Because the X2P and NCSI interfaces share the main RXB FIFOs it will
also impact the NCSI interface therefore it is required to set [CMR_NCSI_DROP]
bit first before setting this bit.
Clearing this does not reset the X2P interface nor NCSI interface. After the
master block comes out of reset, software should clear this bit. */
uint64_t reserved_12_63 : 52;
#endif /* Word 0 - End */
} s;
struct bdk_bgxx_cmr_global_config_cn88xxp1
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_11_63 : 53;
uint64_t cmr_ncsi_reset : 1; /**< [ 10: 10](R/W) Interface reset for the CMR NCSI block.
Upon power up the CMR NCSI is in reset and the companion CNXXXX NCSI block will be
commanded by the
external BMC to enable one of the CNXXXX BGX NCSI interfaces for passing network traffic.
Only one NCSI interface can be enabled in CNXXXX. The BMC/NCSI will then proceed to
configure
the rest of the BGX csr for pass through traffic.
When set, will reset the CMR NCSI interface effectively disabling it at a traffic boundary
should traffic be flowing. This bit will not reset the main RXB fifos. */
uint64_t cmr_ncsi_drop : 1; /**< [ 9: 9](R/W) NCSI drop.
1 = Cleanly drop traffic going into the NCSI block of BGX. Must set asserted
with with [CMR_X2P_RESET]=1 (in the same write operation) to avoid partial packets
to the NCSI interface while performing a X2P partner reset.
0 = Allow traffic to flow through the NCSI block. */
uint64_t ncsi_lmac_id : 2; /**< [ 8: 7](R/W) Logical MAC ID that carries NCSI traffic for both RX and TX side of CMR. On the RX side
is
also the LMAC_ID that is eligible for steering. */
uint64_t fcs_strip : 1; /**< [ 6: 6](R/W) A setting of 1 means the BGX strip the FCS bytes of every packet. For packets less than 4
bytes, the packet will be removed.
A setting of 0 means the BGX will not modify or remove the FCS bytes. */
uint64_t interleave_mode : 1; /**< [ 5: 5](R/W) A setting of 0 means the BGX will operate in non-interleaved mode where there is 1 packet
from a given lmac in flight on the X2P interface to TNS/NIC. A setting of 1 means the BGX
will operate in interleaved mode where each valid consecutive cycle on the X2P interface
may contain words from different lmacs. In other words there will be multiple packets in
flight from different lmacs at the same time. */
uint64_t cmr_mix1_reset : 1; /**< [ 4: 4](R/W) Must be 0. */
uint64_t cmr_mix0_reset : 1; /**< [ 3: 3](R/W) Must be 0. */
uint64_t cmr_x2p_reset : 1; /**< [ 2: 2](R/W) If the NIC or TNS block is reset, software also needs to reset the X2P interface in the
BGX by
setting this bit to 1. It resets the X2P interface state in the BGX (skid FIFO and pending
requests to NIC) and prevents the RXB FIFOs for all LMACs from pushing data to the
interface. Because the X2P and NCSI interfaces share the main RXB fifos it will also
impact the NCSI interface therefore it is required to set [CMR_NCSI_DROP] bit first before
setting this bit.
Setting this bit to 0 does not reset the X2P interface nor NCSI interface.
After NIC/TNS comes out of reset, software should clear this bit. */
uint64_t bgx_clk_enable : 1; /**< [ 1: 1](R/W) The global clock enable for BGX. Setting this bit overrides clock enables set by
BGX()_CMR()_CONFIG[ENABLE] and BGX()_CMR()_CONFIG[LMAC_TYPE], essentially
turning on clocks for the entire BGX. Setting this bit to 0 results in not overriding
clock enables set by BGX()_CMR()_CONFIG[ENABLE] and
BGX()_CMR()_CONFIG[LMAC_TYPE]. */
uint64_t pmux_sds_sel : 1; /**< [ 0: 0](R/W) SerDes/GSER output select. Must be 0. */
#else /* Word 0 - Little Endian */
uint64_t pmux_sds_sel : 1; /**< [ 0: 0](R/W) SerDes/GSER output select. Must be 0. */
uint64_t bgx_clk_enable : 1; /**< [ 1: 1](R/W) The global clock enable for BGX. Setting this bit overrides clock enables set by
BGX()_CMR()_CONFIG[ENABLE] and BGX()_CMR()_CONFIG[LMAC_TYPE], essentially
turning on clocks for the entire BGX. Setting this bit to 0 results in not overriding
clock enables set by BGX()_CMR()_CONFIG[ENABLE] and
BGX()_CMR()_CONFIG[LMAC_TYPE]. */
uint64_t cmr_x2p_reset : 1; /**< [ 2: 2](R/W) If the NIC or TNS block is reset, software also needs to reset the X2P interface in the
BGX by
setting this bit to 1. It resets the X2P interface state in the BGX (skid FIFO and pending
requests to NIC) and prevents the RXB FIFOs for all LMACs from pushing data to the
interface. Because the X2P and NCSI interfaces share the main RXB fifos it will also
impact the NCSI interface therefore it is required to set [CMR_NCSI_DROP] bit first before
setting this bit.
Setting this bit to 0 does not reset the X2P interface nor NCSI interface.
After NIC/TNS comes out of reset, software should clear this bit. */
uint64_t cmr_mix0_reset : 1; /**< [ 3: 3](R/W) Must be 0. */
uint64_t cmr_mix1_reset : 1; /**< [ 4: 4](R/W) Must be 0. */
uint64_t interleave_mode : 1; /**< [ 5: 5](R/W) A setting of 0 means the BGX will operate in non-interleaved mode where there is 1 packet
from a given lmac in flight on the X2P interface to TNS/NIC. A setting of 1 means the BGX
will operate in interleaved mode where each valid consecutive cycle on the X2P interface
may contain words from different lmacs. In other words there will be multiple packets in
flight from different lmacs at the same time. */
uint64_t fcs_strip : 1; /**< [ 6: 6](R/W) A setting of 1 means the BGX strip the FCS bytes of every packet. For packets less than 4
bytes, the packet will be removed.
A setting of 0 means the BGX will not modify or remove the FCS bytes. */
uint64_t ncsi_lmac_id : 2; /**< [ 8: 7](R/W) Logical MAC ID that carries NCSI traffic for both RX and TX side of CMR. On the RX side
is
also the LMAC_ID that is eligible for steering. */
uint64_t cmr_ncsi_drop : 1; /**< [ 9: 9](R/W) NCSI drop.
1 = Cleanly drop traffic going into the NCSI block of BGX. Must set asserted
with with [CMR_X2P_RESET]=1 (in the same write operation) to avoid partial packets
to the NCSI interface while performing a X2P partner reset.
0 = Allow traffic to flow through the NCSI block. */
uint64_t cmr_ncsi_reset : 1; /**< [ 10: 10](R/W) Interface reset for the CMR NCSI block.
Upon power up the CMR NCSI is in reset and the companion CNXXXX NCSI block will be
commanded by the
external BMC to enable one of the CNXXXX BGX NCSI interfaces for passing network traffic.
Only one NCSI interface can be enabled in CNXXXX. The BMC/NCSI will then proceed to
configure
the rest of the BGX csr for pass through traffic.
When set, will reset the CMR NCSI interface effectively disabling it at a traffic boundary
should traffic be flowing. This bit will not reset the main RXB fifos. */
uint64_t reserved_11_63 : 53;
#endif /* Word 0 - End */
} cn88xxp1;
struct bdk_bgxx_cmr_global_config_cn81xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_11_63 : 53;
uint64_t cmr_ncsi_reset : 1; /**< [ 10: 10](R/W) Reserved. */
uint64_t cmr_ncsi_drop : 1; /**< [ 9: 9](R/W) Reserved. */
uint64_t ncsi_lmac_id : 2; /**< [ 8: 7](R/W) Reserved. */
uint64_t fcs_strip : 1; /**< [ 6: 6](R/W) A setting of 1 means the BGX strip the FCS bytes of every packet. For packets less than 4
bytes, the packet will be removed.
A setting of 0 means the BGX will not modify or remove the FCS bytes. */
uint64_t interleave_mode : 1; /**< [ 5: 5](RAZ) Reserved. */
uint64_t cmr_mix1_reset : 1; /**< [ 4: 4](R/W) Must be 0. */
uint64_t cmr_mix0_reset : 1; /**< [ 3: 3](R/W) Must be 0. */
uint64_t cmr_x2p_reset : 1; /**< [ 2: 2](R/W) If the NIC block is reset, software also needs to reset the X2P interface in the
BGX by
setting this bit to 1. It resets the X2P interface state in the BGX (skid FIFO and pending
requests to NIC) and prevents the RXB FIFOs for all LMACs from pushing data to the
interface.
Setting this bit to 0 does not reset the X2P interface.
After NIC comes out of reset, software should clear this bit. */
uint64_t bgx_clk_enable : 1; /**< [ 1: 1](R/W) The global clock enable for BGX. Setting this bit overrides clock enables set by
BGX()_CMR()_CONFIG[ENABLE] and BGX()_CMR()_CONFIG[LMAC_TYPE], essentially
turning on clocks for the entire BGX. Setting this bit to 0 results in not overriding
clock enables set by BGX()_CMR()_CONFIG[ENABLE] and
BGX()_CMR()_CONFIG[LMAC_TYPE]. */
uint64_t pmux_sds_sel : 1; /**< [ 0: 0](R/W) SerDes/GSER output select. Must be 0. */
#else /* Word 0 - Little Endian */
uint64_t pmux_sds_sel : 1; /**< [ 0: 0](R/W) SerDes/GSER output select. Must be 0. */
uint64_t bgx_clk_enable : 1; /**< [ 1: 1](R/W) The global clock enable for BGX. Setting this bit overrides clock enables set by
BGX()_CMR()_CONFIG[ENABLE] and BGX()_CMR()_CONFIG[LMAC_TYPE], essentially
turning on clocks for the entire BGX. Setting this bit to 0 results in not overriding
clock enables set by BGX()_CMR()_CONFIG[ENABLE] and
BGX()_CMR()_CONFIG[LMAC_TYPE]. */
uint64_t cmr_x2p_reset : 1; /**< [ 2: 2](R/W) If the NIC block is reset, software also needs to reset the X2P interface in the
BGX by
setting this bit to 1. It resets the X2P interface state in the BGX (skid FIFO and pending
requests to NIC) and prevents the RXB FIFOs for all LMACs from pushing data to the
interface.
Setting this bit to 0 does not reset the X2P interface.
After NIC comes out of reset, software should clear this bit. */
uint64_t cmr_mix0_reset : 1; /**< [ 3: 3](R/W) Must be 0. */
uint64_t cmr_mix1_reset : 1; /**< [ 4: 4](R/W) Must be 0. */
uint64_t interleave_mode : 1; /**< [ 5: 5](RAZ) Reserved. */
uint64_t fcs_strip : 1; /**< [ 6: 6](R/W) A setting of 1 means the BGX strip the FCS bytes of every packet. For packets less than 4
bytes, the packet will be removed.
A setting of 0 means the BGX will not modify or remove the FCS bytes. */
uint64_t ncsi_lmac_id : 2; /**< [ 8: 7](R/W) Reserved. */
uint64_t cmr_ncsi_drop : 1; /**< [ 9: 9](R/W) Reserved. */
uint64_t cmr_ncsi_reset : 1; /**< [ 10: 10](R/W) Reserved. */
uint64_t reserved_11_63 : 53;
#endif /* Word 0 - End */
} cn81xx;
struct bdk_bgxx_cmr_global_config_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_12_63 : 52;
uint64_t cmr_x2p1_reset : 1; /**< [ 11: 11](R/W) If the master block connected to X2P interface 1 is reset, software also needs
to reset the X2P interface in the BGX by setting this bit. It resets the X2P
interface state in the BGX (skid FIFO and pending requests to the master block)
and prevents the RXB FIFOs for all LMACs from pushing data to the
interface. Because the X2P and NCSI interfaces share the main RXB FIFOs it will
also impact the NCSI interface therefore it is required to set [CMR_NCSI_DROP]
bit first before setting this bit.
Clearing this does not reset the X2P interface nor NCSI interface. After the
master block comes out of reset, software should clear this bit. */
uint64_t cmr_ncsi_reset : 1; /**< [ 10: 10](R/W) Interface reset for the CMR NCSI block.
Upon power up the CMR NCSI is in reset and the companion CNXXXX NCSI block will be
commanded by the
external BMC to enable one of the CNXXXX BGX NCSI interfaces for passing network traffic.
Only one NCSI interface can be enabled in CNXXXX. The BMC/NCSI will then proceed to
configure
the rest of the BGX csr for pass through traffic.
When set, will reset the CMR NCSI interface effectively disabling it at a traffic boundary
should traffic be flowing. This bit will not reset the main RXB fifos. */
uint64_t cmr_ncsi_drop : 1; /**< [ 9: 9](R/W) NCSI drop.
1 = Cleanly drop traffic going into the NCSI block of BGX. Must set asserted
with with [CMR_X2P_RESET]=1 (in the same write operation) to avoid partial packets
to the NCSI interface while performing a X2P partner reset.
0 = Allow traffic to flow through the NCSI block. */
uint64_t ncsi_lmac_id : 2; /**< [ 8: 7](R/W) Logical MAC ID that carries NCSI traffic for both RX and TX side of CMR. On the RX side
is
also the LMAC_ID that is eligible for steering. */
uint64_t fcs_strip : 1; /**< [ 6: 6](R/W) A setting of 1 means the BGX strip the FCS bytes of every packet. For packets less than 4
bytes, the packet will be removed.
A setting of 0 means the BGX will not modify or remove the FCS bytes. */
uint64_t interleave_mode : 1; /**< [ 5: 5](RAZ) Reserved. */
uint64_t cmr_mix1_reset : 1; /**< [ 4: 4](R/W) Must be 0. */
uint64_t cmr_mix0_reset : 1; /**< [ 3: 3](R/W) Must be 0. */
uint64_t cmr_x2p_reset : 1; /**< [ 2: 2](R/W) If the master block connected to X2P interface 0 is reset, software also needs
to reset the X2P interface in the BGX by setting this bit. It resets the X2P
interface state in the BGX (skid FIFO and pending requests to the master block)
and prevents the RXB FIFOs for all LMACs from pushing data to the
interface. Because the X2P and NCSI interfaces share the main RXB FIFOs it will
also impact the NCSI interface therefore it is required to set [CMR_NCSI_DROP]
bit first before setting this bit.
Clearing this does not reset the X2P interface nor NCSI interface. After the
master block comes out of reset, software should clear this bit. */
uint64_t bgx_clk_enable : 1; /**< [ 1: 1](R/W) The global clock enable for BGX. Setting this bit overrides clock enables set by
BGX()_CMR()_CONFIG[ENABLE] and BGX()_CMR()_CONFIG[LMAC_TYPE], essentially
turning on clocks for the entire BGX. Setting this bit to 0 results in not overriding
clock enables set by BGX()_CMR()_CONFIG[ENABLE] and
BGX()_CMR()_CONFIG[LMAC_TYPE]. */
uint64_t pmux_sds_sel : 1; /**< [ 0: 0](R/W) SerDes/GSER output select. Must be 0. */
#else /* Word 0 - Little Endian */
uint64_t pmux_sds_sel : 1; /**< [ 0: 0](R/W) SerDes/GSER output select. Must be 0. */
uint64_t bgx_clk_enable : 1; /**< [ 1: 1](R/W) The global clock enable for BGX. Setting this bit overrides clock enables set by
BGX()_CMR()_CONFIG[ENABLE] and BGX()_CMR()_CONFIG[LMAC_TYPE], essentially
turning on clocks for the entire BGX. Setting this bit to 0 results in not overriding
clock enables set by BGX()_CMR()_CONFIG[ENABLE] and
BGX()_CMR()_CONFIG[LMAC_TYPE]. */
uint64_t cmr_x2p_reset : 1; /**< [ 2: 2](R/W) If the master block connected to X2P interface 0 is reset, software also needs
to reset the X2P interface in the BGX by setting this bit. It resets the X2P
interface state in the BGX (skid FIFO and pending requests to the master block)
and prevents the RXB FIFOs for all LMACs from pushing data to the
interface. Because the X2P and NCSI interfaces share the main RXB FIFOs it will
also impact the NCSI interface therefore it is required to set [CMR_NCSI_DROP]
bit first before setting this bit.
Clearing this does not reset the X2P interface nor NCSI interface. After the
master block comes out of reset, software should clear this bit. */
uint64_t cmr_mix0_reset : 1; /**< [ 3: 3](R/W) Must be 0. */
uint64_t cmr_mix1_reset : 1; /**< [ 4: 4](R/W) Must be 0. */
uint64_t interleave_mode : 1; /**< [ 5: 5](RAZ) Reserved. */
uint64_t fcs_strip : 1; /**< [ 6: 6](R/W) A setting of 1 means the BGX strip the FCS bytes of every packet. For packets less than 4
bytes, the packet will be removed.
A setting of 0 means the BGX will not modify or remove the FCS bytes. */
uint64_t ncsi_lmac_id : 2; /**< [ 8: 7](R/W) Logical MAC ID that carries NCSI traffic for both RX and TX side of CMR. On the RX side
is
also the LMAC_ID that is eligible for steering. */
uint64_t cmr_ncsi_drop : 1; /**< [ 9: 9](R/W) NCSI drop.
1 = Cleanly drop traffic going into the NCSI block of BGX. Must set asserted
with with [CMR_X2P_RESET]=1 (in the same write operation) to avoid partial packets
to the NCSI interface while performing a X2P partner reset.
0 = Allow traffic to flow through the NCSI block. */
uint64_t cmr_ncsi_reset : 1; /**< [ 10: 10](R/W) Interface reset for the CMR NCSI block.
Upon power up the CMR NCSI is in reset and the companion CNXXXX NCSI block will be
commanded by the
external BMC to enable one of the CNXXXX BGX NCSI interfaces for passing network traffic.
Only one NCSI interface can be enabled in CNXXXX. The BMC/NCSI will then proceed to
configure
the rest of the BGX csr for pass through traffic.
When set, will reset the CMR NCSI interface effectively disabling it at a traffic boundary
should traffic be flowing. This bit will not reset the main RXB fifos. */
uint64_t cmr_x2p1_reset : 1; /**< [ 11: 11](R/W) If the master block connected to X2P interface 1 is reset, software also needs
to reset the X2P interface in the BGX by setting this bit. It resets the X2P
interface state in the BGX (skid FIFO and pending requests to the master block)
and prevents the RXB FIFOs for all LMACs from pushing data to the
interface. Because the X2P and NCSI interfaces share the main RXB FIFOs it will
also impact the NCSI interface therefore it is required to set [CMR_NCSI_DROP]
bit first before setting this bit.
Clearing this does not reset the X2P interface nor NCSI interface. After the
master block comes out of reset, software should clear this bit. */
uint64_t reserved_12_63 : 52;
#endif /* Word 0 - End */
} cn83xx;
struct bdk_bgxx_cmr_global_config_cn88xxp2
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_11_63 : 53;
uint64_t cmr_ncsi_reset : 1; /**< [ 10: 10](R/W) Interface reset for the CMR NCSI block.
Upon power up the CMR NCSI is in reset and the companion CNXXXX NCSI block will be
commanded by the
external BMC to enable one of the CNXXXX BGX NCSI interfaces for passing network traffic.
Only one NCSI interface can be enabled in CNXXXX. The BMC/NCSI will then proceed to
configure
the rest of the BGX csr for pass through traffic.
When set, will reset the CMR NCSI interface effectively disabling it at a traffic boundary
should traffic be flowing. This bit will not reset the main RXB fifos. */
uint64_t cmr_ncsi_drop : 1; /**< [ 9: 9](R/W) NCSI drop.
1 = Cleanly drop traffic going into the NCSI block of BGX. Must set asserted
with with [CMR_X2P_RESET]=1 (in the same write operation) to avoid partial packets
to the NCSI interface while performing a X2P partner reset.
0 = Allow traffic to flow through the NCSI block. */
uint64_t ncsi_lmac_id : 2; /**< [ 8: 7](R/W) Logical MAC ID that carries NCSI traffic for both RX and TX side of CMR. On the RX side
is
also the LMAC_ID that is eligible for steering. */
uint64_t fcs_strip : 1; /**< [ 6: 6](R/W) A setting of 1 means the BGX strip the FCS bytes of every packet. For packets less than 4
bytes, the packet will be removed.
A setting of 0 means the BGX will not modify or remove the FCS bytes. */
uint64_t interleave_mode : 1; /**< [ 5: 5](RAZ) Reserved. */
uint64_t cmr_mix1_reset : 1; /**< [ 4: 4](R/W) Must be 0. */
uint64_t cmr_mix0_reset : 1; /**< [ 3: 3](R/W) Must be 0. */
uint64_t cmr_x2p_reset : 1; /**< [ 2: 2](R/W) If the NIC or TNS block is reset, software also needs to reset the X2P interface in the
BGX by
setting this bit to 1. It resets the X2P interface state in the BGX (skid FIFO and pending
requests to NIC) and prevents the RXB FIFOs for all LMACs from pushing data to the
interface. Because the X2P and NCSI interfaces share the main RXB fifos it will also
impact the NCSI interface therefore it is required to set [CMR_NCSI_DROP] bit first before
setting this bit.
Setting this bit to 0 does not reset the X2P interface nor NCSI interface.
After NIC/TNS comes out of reset, software should clear this bit. */
uint64_t bgx_clk_enable : 1; /**< [ 1: 1](R/W) The global clock enable for BGX. Setting this bit overrides clock enables set by
BGX()_CMR()_CONFIG[ENABLE] and BGX()_CMR()_CONFIG[LMAC_TYPE], essentially
turning on clocks for the entire BGX. Setting this bit to 0 results in not overriding
clock enables set by BGX()_CMR()_CONFIG[ENABLE] and
BGX()_CMR()_CONFIG[LMAC_TYPE]. */
uint64_t pmux_sds_sel : 1; /**< [ 0: 0](R/W) SerDes/GSER output select. Must be 0. */
#else /* Word 0 - Little Endian */
uint64_t pmux_sds_sel : 1; /**< [ 0: 0](R/W) SerDes/GSER output select. Must be 0. */
uint64_t bgx_clk_enable : 1; /**< [ 1: 1](R/W) The global clock enable for BGX. Setting this bit overrides clock enables set by
BGX()_CMR()_CONFIG[ENABLE] and BGX()_CMR()_CONFIG[LMAC_TYPE], essentially
turning on clocks for the entire BGX. Setting this bit to 0 results in not overriding
clock enables set by BGX()_CMR()_CONFIG[ENABLE] and
BGX()_CMR()_CONFIG[LMAC_TYPE]. */
uint64_t cmr_x2p_reset : 1; /**< [ 2: 2](R/W) If the NIC or TNS block is reset, software also needs to reset the X2P interface in the
BGX by
setting this bit to 1. It resets the X2P interface state in the BGX (skid FIFO and pending
requests to NIC) and prevents the RXB FIFOs for all LMACs from pushing data to the
interface. Because the X2P and NCSI interfaces share the main RXB fifos it will also
impact the NCSI interface therefore it is required to set [CMR_NCSI_DROP] bit first before
setting this bit.
Setting this bit to 0 does not reset the X2P interface nor NCSI interface.
After NIC/TNS comes out of reset, software should clear this bit. */
uint64_t cmr_mix0_reset : 1; /**< [ 3: 3](R/W) Must be 0. */
uint64_t cmr_mix1_reset : 1; /**< [ 4: 4](R/W) Must be 0. */
uint64_t interleave_mode : 1; /**< [ 5: 5](RAZ) Reserved. */
uint64_t fcs_strip : 1; /**< [ 6: 6](R/W) A setting of 1 means the BGX strip the FCS bytes of every packet. For packets less than 4
bytes, the packet will be removed.
A setting of 0 means the BGX will not modify or remove the FCS bytes. */
uint64_t ncsi_lmac_id : 2; /**< [ 8: 7](R/W) Logical MAC ID that carries NCSI traffic for both RX and TX side of CMR. On the RX side
is
also the LMAC_ID that is eligible for steering. */
uint64_t cmr_ncsi_drop : 1; /**< [ 9: 9](R/W) NCSI drop.
1 = Cleanly drop traffic going into the NCSI block of BGX. Must set asserted
with with [CMR_X2P_RESET]=1 (in the same write operation) to avoid partial packets
to the NCSI interface while performing a X2P partner reset.
0 = Allow traffic to flow through the NCSI block. */
uint64_t cmr_ncsi_reset : 1; /**< [ 10: 10](R/W) Interface reset for the CMR NCSI block.
Upon power up the CMR NCSI is in reset and the companion CNXXXX NCSI block will be
commanded by the
external BMC to enable one of the CNXXXX BGX NCSI interfaces for passing network traffic.
Only one NCSI interface can be enabled in CNXXXX. The BMC/NCSI will then proceed to
configure
the rest of the BGX csr for pass through traffic.
When set, will reset the CMR NCSI interface effectively disabling it at a traffic boundary
should traffic be flowing. This bit will not reset the main RXB fifos. */
uint64_t reserved_11_63 : 53;
#endif /* Word 0 - End */
} cn88xxp2;
};
typedef union bdk_bgxx_cmr_global_config bdk_bgxx_cmr_global_config_t;
static inline uint64_t BDK_BGXX_CMR_GLOBAL_CONFIG(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMR_GLOBAL_CONFIG(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e0000008ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e0000008ll + 0x1000000ll * ((a) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && (a<=1))
return 0x87e0e0000008ll + 0x1000000ll * ((a) & 0x1);
__bdk_csr_fatal("BGXX_CMR_GLOBAL_CONFIG", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_CMR_GLOBAL_CONFIG(a) bdk_bgxx_cmr_global_config_t
#define bustype_BDK_BGXX_CMR_GLOBAL_CONFIG(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMR_GLOBAL_CONFIG(a) "BGXX_CMR_GLOBAL_CONFIG"
#define device_bar_BDK_BGXX_CMR_GLOBAL_CONFIG(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMR_GLOBAL_CONFIG(a) (a)
#define arguments_BDK_BGXX_CMR_GLOBAL_CONFIG(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_cmr_mem_ctrl
*
* BGX CMR Memory Control Register
*/
union bdk_bgxx_cmr_mem_ctrl
{
uint64_t u;
struct bdk_bgxx_cmr_mem_ctrl_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_42_63 : 22;
uint64_t txb_fif_m3_syn : 2; /**< [ 41: 40](R/W) Syndrome to flip and generate single-bit/double-bit error for TXB main mem3. */
uint64_t txb_fif_m3_cdis : 1; /**< [ 39: 39](R/W) ECC-correction disable for the TXB main mem3. */
uint64_t txb_fif_m2_syn : 2; /**< [ 38: 37](R/W) Syndrome to flip and generate single-bit/double-bit error for TXB main mem2. */
uint64_t txb_fif_m2_cdis : 1; /**< [ 36: 36](R/W) ECC-correction disable for the TXB main mem2. */
uint64_t txb_ncsi_synd : 2; /**< [ 35: 34](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO */
uint64_t txb_ncsi_cor_dis : 1; /**< [ 33: 33](R/W) ECC-correction disable for the TXB SKID FIFO */
uint64_t txb_skid_m3_synd : 2; /**< [ 32: 31](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO */
uint64_t txb_skid_m3_cor_dis : 1; /**< [ 30: 30](R/W) ECC-correction disable for the TXB SKID FIFO */
uint64_t txb_skid_m2_synd : 2; /**< [ 29: 28](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO */
uint64_t txb_skid_m2_cor_dis : 1; /**< [ 27: 27](R/W) ECC-correction disable for the TXB SKID FIFO */
uint64_t txb_skid_m1_synd : 2; /**< [ 26: 25](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO */
uint64_t txb_skid_m1_cor_dis : 1; /**< [ 24: 24](R/W) ECC-correction disable for the TXB SKID FIFO */
uint64_t txb_skid_m0_synd : 2; /**< [ 23: 22](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO. */
uint64_t txb_skid_m0_cor_dis : 1; /**< [ 21: 21](R/W) ECC-correction disable for the TXB SKID FIFO. */
uint64_t reserved_15_20 : 6;
uint64_t rxb_skid_synd : 2; /**< [ 14: 13](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB SKID FIFO. */
uint64_t rxb_skid_cor_dis : 1; /**< [ 12: 12](R/W) ECC-correction disable for the RXB SKID FIFO. */
uint64_t rxb_fif_bk1_syn1 : 2; /**< [ 11: 10](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB main bank1 srf1. */
uint64_t rxb_fif_bk1_cdis1 : 1; /**< [ 9: 9](R/W) ECC-correction disable for the RXB main bank1 srf1. */
uint64_t rxb_fif_bk1_syn0 : 2; /**< [ 8: 7](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB main bank1 srf0. */
uint64_t rxb_fif_bk1_cdis0 : 1; /**< [ 6: 6](R/W) ECC-correction disable for the RXB main bank1 srf0. */
uint64_t rxb_fif_bk0_syn1 : 2; /**< [ 5: 4](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB main bank0 srf1. */
uint64_t rxb_fif_bk0_cdis1 : 1; /**< [ 3: 3](R/W) ECC-correction disable for the RXB main bank0 srf1. */
uint64_t rxb_fif_bk0_syn0 : 2; /**< [ 2: 1](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB main bank0 srf0. */
uint64_t rxb_fif_bk0_cdis0 : 1; /**< [ 0: 0](R/W) ECC-correction disable for the RXB main bank0 srf0. */
#else /* Word 0 - Little Endian */
uint64_t rxb_fif_bk0_cdis0 : 1; /**< [ 0: 0](R/W) ECC-correction disable for the RXB main bank0 srf0. */
uint64_t rxb_fif_bk0_syn0 : 2; /**< [ 2: 1](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB main bank0 srf0. */
uint64_t rxb_fif_bk0_cdis1 : 1; /**< [ 3: 3](R/W) ECC-correction disable for the RXB main bank0 srf1. */
uint64_t rxb_fif_bk0_syn1 : 2; /**< [ 5: 4](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB main bank0 srf1. */
uint64_t rxb_fif_bk1_cdis0 : 1; /**< [ 6: 6](R/W) ECC-correction disable for the RXB main bank1 srf0. */
uint64_t rxb_fif_bk1_syn0 : 2; /**< [ 8: 7](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB main bank1 srf0. */
uint64_t rxb_fif_bk1_cdis1 : 1; /**< [ 9: 9](R/W) ECC-correction disable for the RXB main bank1 srf1. */
uint64_t rxb_fif_bk1_syn1 : 2; /**< [ 11: 10](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB main bank1 srf1. */
uint64_t rxb_skid_cor_dis : 1; /**< [ 12: 12](R/W) ECC-correction disable for the RXB SKID FIFO. */
uint64_t rxb_skid_synd : 2; /**< [ 14: 13](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB SKID FIFO. */
uint64_t reserved_15_20 : 6;
uint64_t txb_skid_m0_cor_dis : 1; /**< [ 21: 21](R/W) ECC-correction disable for the TXB SKID FIFO. */
uint64_t txb_skid_m0_synd : 2; /**< [ 23: 22](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO. */
uint64_t txb_skid_m1_cor_dis : 1; /**< [ 24: 24](R/W) ECC-correction disable for the TXB SKID FIFO */
uint64_t txb_skid_m1_synd : 2; /**< [ 26: 25](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO */
uint64_t txb_skid_m2_cor_dis : 1; /**< [ 27: 27](R/W) ECC-correction disable for the TXB SKID FIFO */
uint64_t txb_skid_m2_synd : 2; /**< [ 29: 28](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO */
uint64_t txb_skid_m3_cor_dis : 1; /**< [ 30: 30](R/W) ECC-correction disable for the TXB SKID FIFO */
uint64_t txb_skid_m3_synd : 2; /**< [ 32: 31](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO */
uint64_t txb_ncsi_cor_dis : 1; /**< [ 33: 33](R/W) ECC-correction disable for the TXB SKID FIFO */
uint64_t txb_ncsi_synd : 2; /**< [ 35: 34](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO */
uint64_t txb_fif_m2_cdis : 1; /**< [ 36: 36](R/W) ECC-correction disable for the TXB main mem2. */
uint64_t txb_fif_m2_syn : 2; /**< [ 38: 37](R/W) Syndrome to flip and generate single-bit/double-bit error for TXB main mem2. */
uint64_t txb_fif_m3_cdis : 1; /**< [ 39: 39](R/W) ECC-correction disable for the TXB main mem3. */
uint64_t txb_fif_m3_syn : 2; /**< [ 41: 40](R/W) Syndrome to flip and generate single-bit/double-bit error for TXB main mem3. */
uint64_t reserved_42_63 : 22;
#endif /* Word 0 - End */
} s;
struct bdk_bgxx_cmr_mem_ctrl_cn81xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_36_63 : 28;
uint64_t txb_ncsi_synd : 2; /**< [ 35: 34](R/W) Reserved. */
uint64_t txb_ncsi_cor_dis : 1; /**< [ 33: 33](R/W) Reserved. */
uint64_t txb_skid_m3_synd : 2; /**< [ 32: 31](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO */
uint64_t txb_skid_m3_cor_dis : 1; /**< [ 30: 30](R/W) ECC-correction disable for the TXB SKID FIFO */
uint64_t txb_skid_m2_synd : 2; /**< [ 29: 28](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO */
uint64_t txb_skid_m2_cor_dis : 1; /**< [ 27: 27](R/W) ECC-correction disable for the TXB SKID FIFO */
uint64_t txb_skid_m1_synd : 2; /**< [ 26: 25](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO */
uint64_t txb_skid_m1_cor_dis : 1; /**< [ 24: 24](R/W) ECC-correction disable for the TXB SKID FIFO */
uint64_t txb_skid_m0_synd : 2; /**< [ 23: 22](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO. */
uint64_t txb_skid_m0_cor_dis : 1; /**< [ 21: 21](R/W) ECC-correction disable for the TXB SKID FIFO. */
uint64_t txb_fif_bk1_syn : 2; /**< [ 20: 19](R/W) Syndrome to flip and generate single-bit/double-bit error for TXB main bank1. */
uint64_t txb_fif_bk1_cdis : 1; /**< [ 18: 18](R/W) ECC-correction disable for the TXB main bank1. */
uint64_t txb_fif_bk0_syn : 2; /**< [ 17: 16](R/W) Syndrome to flip and generate single-bit/double-bit error for TXB main bank0. */
uint64_t txb_fif_bk0_cdis : 1; /**< [ 15: 15](R/W) ECC-correction disable for the TXB main bank0. */
uint64_t rxb_skid_synd : 2; /**< [ 14: 13](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB SKID FIFO. */
uint64_t rxb_skid_cor_dis : 1; /**< [ 12: 12](R/W) ECC-correction disable for the RXB SKID FIFO. */
uint64_t rxb_fif_bk1_syn1 : 2; /**< [ 11: 10](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB main bank1 srf1. */
uint64_t rxb_fif_bk1_cdis1 : 1; /**< [ 9: 9](R/W) ECC-correction disable for the RXB main bank1 srf1. */
uint64_t rxb_fif_bk1_syn0 : 2; /**< [ 8: 7](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB main bank1 srf0. */
uint64_t rxb_fif_bk1_cdis0 : 1; /**< [ 6: 6](R/W) ECC-correction disable for the RXB main bank1 srf0. */
uint64_t rxb_fif_bk0_syn1 : 2; /**< [ 5: 4](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB main bank0 srf1. */
uint64_t rxb_fif_bk0_cdis1 : 1; /**< [ 3: 3](R/W) ECC-correction disable for the RXB main bank0 srf1. */
uint64_t rxb_fif_bk0_syn0 : 2; /**< [ 2: 1](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB main bank0 srf0. */
uint64_t rxb_fif_bk0_cdis0 : 1; /**< [ 0: 0](R/W) ECC-correction disable for the RXB main bank0 srf0. */
#else /* Word 0 - Little Endian */
uint64_t rxb_fif_bk0_cdis0 : 1; /**< [ 0: 0](R/W) ECC-correction disable for the RXB main bank0 srf0. */
uint64_t rxb_fif_bk0_syn0 : 2; /**< [ 2: 1](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB main bank0 srf0. */
uint64_t rxb_fif_bk0_cdis1 : 1; /**< [ 3: 3](R/W) ECC-correction disable for the RXB main bank0 srf1. */
uint64_t rxb_fif_bk0_syn1 : 2; /**< [ 5: 4](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB main bank0 srf1. */
uint64_t rxb_fif_bk1_cdis0 : 1; /**< [ 6: 6](R/W) ECC-correction disable for the RXB main bank1 srf0. */
uint64_t rxb_fif_bk1_syn0 : 2; /**< [ 8: 7](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB main bank1 srf0. */
uint64_t rxb_fif_bk1_cdis1 : 1; /**< [ 9: 9](R/W) ECC-correction disable for the RXB main bank1 srf1. */
uint64_t rxb_fif_bk1_syn1 : 2; /**< [ 11: 10](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB main bank1 srf1. */
uint64_t rxb_skid_cor_dis : 1; /**< [ 12: 12](R/W) ECC-correction disable for the RXB SKID FIFO. */
uint64_t rxb_skid_synd : 2; /**< [ 14: 13](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB SKID FIFO. */
uint64_t txb_fif_bk0_cdis : 1; /**< [ 15: 15](R/W) ECC-correction disable for the TXB main bank0. */
uint64_t txb_fif_bk0_syn : 2; /**< [ 17: 16](R/W) Syndrome to flip and generate single-bit/double-bit error for TXB main bank0. */
uint64_t txb_fif_bk1_cdis : 1; /**< [ 18: 18](R/W) ECC-correction disable for the TXB main bank1. */
uint64_t txb_fif_bk1_syn : 2; /**< [ 20: 19](R/W) Syndrome to flip and generate single-bit/double-bit error for TXB main bank1. */
uint64_t txb_skid_m0_cor_dis : 1; /**< [ 21: 21](R/W) ECC-correction disable for the TXB SKID FIFO. */
uint64_t txb_skid_m0_synd : 2; /**< [ 23: 22](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO. */
uint64_t txb_skid_m1_cor_dis : 1; /**< [ 24: 24](R/W) ECC-correction disable for the TXB SKID FIFO */
uint64_t txb_skid_m1_synd : 2; /**< [ 26: 25](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO */
uint64_t txb_skid_m2_cor_dis : 1; /**< [ 27: 27](R/W) ECC-correction disable for the TXB SKID FIFO */
uint64_t txb_skid_m2_synd : 2; /**< [ 29: 28](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO */
uint64_t txb_skid_m3_cor_dis : 1; /**< [ 30: 30](R/W) ECC-correction disable for the TXB SKID FIFO */
uint64_t txb_skid_m3_synd : 2; /**< [ 32: 31](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO */
uint64_t txb_ncsi_cor_dis : 1; /**< [ 33: 33](R/W) Reserved. */
uint64_t txb_ncsi_synd : 2; /**< [ 35: 34](R/W) Reserved. */
uint64_t reserved_36_63 : 28;
#endif /* Word 0 - End */
} cn81xx;
struct bdk_bgxx_cmr_mem_ctrl_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_36_63 : 28;
uint64_t txb_ncsi_synd : 2; /**< [ 35: 34](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO */
uint64_t txb_ncsi_cor_dis : 1; /**< [ 33: 33](R/W) ECC-correction disable for the TXB SKID FIFO */
uint64_t txb_skid_m3_synd : 2; /**< [ 32: 31](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO */
uint64_t txb_skid_m3_cor_dis : 1; /**< [ 30: 30](R/W) ECC-correction disable for the TXB SKID FIFO */
uint64_t txb_skid_m2_synd : 2; /**< [ 29: 28](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO */
uint64_t txb_skid_m2_cor_dis : 1; /**< [ 27: 27](R/W) ECC-correction disable for the TXB SKID FIFO */
uint64_t txb_skid_m1_synd : 2; /**< [ 26: 25](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO */
uint64_t txb_skid_m1_cor_dis : 1; /**< [ 24: 24](R/W) ECC-correction disable for the TXB SKID FIFO */
uint64_t txb_skid_m0_synd : 2; /**< [ 23: 22](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO. */
uint64_t txb_skid_m0_cor_dis : 1; /**< [ 21: 21](R/W) ECC-correction disable for the TXB SKID FIFO. */
uint64_t txb_fif_bk1_syn : 2; /**< [ 20: 19](R/W) Syndrome to flip and generate single-bit/double-bit error for TXB main bank1. */
uint64_t txb_fif_bk1_cdis : 1; /**< [ 18: 18](R/W) ECC-correction disable for the TXB main bank1. */
uint64_t txb_fif_bk0_syn : 2; /**< [ 17: 16](R/W) Syndrome to flip and generate single-bit/double-bit error for TXB main bank0. */
uint64_t txb_fif_bk0_cdis : 1; /**< [ 15: 15](R/W) ECC-correction disable for the TXB main bank0. */
uint64_t rxb_skid_synd : 2; /**< [ 14: 13](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB SKID FIFO. */
uint64_t rxb_skid_cor_dis : 1; /**< [ 12: 12](R/W) ECC-correction disable for the RXB SKID FIFO. */
uint64_t rxb_fif_bk1_syn1 : 2; /**< [ 11: 10](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB main bank1 srf1. */
uint64_t rxb_fif_bk1_cdis1 : 1; /**< [ 9: 9](R/W) ECC-correction disable for the RXB main bank1 srf1. */
uint64_t rxb_fif_bk1_syn0 : 2; /**< [ 8: 7](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB main bank1 srf0. */
uint64_t rxb_fif_bk1_cdis0 : 1; /**< [ 6: 6](R/W) ECC-correction disable for the RXB main bank1 srf0. */
uint64_t rxb_fif_bk0_syn1 : 2; /**< [ 5: 4](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB main bank0 srf1. */
uint64_t rxb_fif_bk0_cdis1 : 1; /**< [ 3: 3](R/W) ECC-correction disable for the RXB main bank0 srf1. */
uint64_t rxb_fif_bk0_syn0 : 2; /**< [ 2: 1](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB main bank0 srf0. */
uint64_t rxb_fif_bk0_cdis0 : 1; /**< [ 0: 0](R/W) ECC-correction disable for the RXB main bank0 srf0. */
#else /* Word 0 - Little Endian */
uint64_t rxb_fif_bk0_cdis0 : 1; /**< [ 0: 0](R/W) ECC-correction disable for the RXB main bank0 srf0. */
uint64_t rxb_fif_bk0_syn0 : 2; /**< [ 2: 1](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB main bank0 srf0. */
uint64_t rxb_fif_bk0_cdis1 : 1; /**< [ 3: 3](R/W) ECC-correction disable for the RXB main bank0 srf1. */
uint64_t rxb_fif_bk0_syn1 : 2; /**< [ 5: 4](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB main bank0 srf1. */
uint64_t rxb_fif_bk1_cdis0 : 1; /**< [ 6: 6](R/W) ECC-correction disable for the RXB main bank1 srf0. */
uint64_t rxb_fif_bk1_syn0 : 2; /**< [ 8: 7](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB main bank1 srf0. */
uint64_t rxb_fif_bk1_cdis1 : 1; /**< [ 9: 9](R/W) ECC-correction disable for the RXB main bank1 srf1. */
uint64_t rxb_fif_bk1_syn1 : 2; /**< [ 11: 10](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB main bank1 srf1. */
uint64_t rxb_skid_cor_dis : 1; /**< [ 12: 12](R/W) ECC-correction disable for the RXB SKID FIFO. */
uint64_t rxb_skid_synd : 2; /**< [ 14: 13](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB SKID FIFO. */
uint64_t txb_fif_bk0_cdis : 1; /**< [ 15: 15](R/W) ECC-correction disable for the TXB main bank0. */
uint64_t txb_fif_bk0_syn : 2; /**< [ 17: 16](R/W) Syndrome to flip and generate single-bit/double-bit error for TXB main bank0. */
uint64_t txb_fif_bk1_cdis : 1; /**< [ 18: 18](R/W) ECC-correction disable for the TXB main bank1. */
uint64_t txb_fif_bk1_syn : 2; /**< [ 20: 19](R/W) Syndrome to flip and generate single-bit/double-bit error for TXB main bank1. */
uint64_t txb_skid_m0_cor_dis : 1; /**< [ 21: 21](R/W) ECC-correction disable for the TXB SKID FIFO. */
uint64_t txb_skid_m0_synd : 2; /**< [ 23: 22](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO. */
uint64_t txb_skid_m1_cor_dis : 1; /**< [ 24: 24](R/W) ECC-correction disable for the TXB SKID FIFO */
uint64_t txb_skid_m1_synd : 2; /**< [ 26: 25](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO */
uint64_t txb_skid_m2_cor_dis : 1; /**< [ 27: 27](R/W) ECC-correction disable for the TXB SKID FIFO */
uint64_t txb_skid_m2_synd : 2; /**< [ 29: 28](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO */
uint64_t txb_skid_m3_cor_dis : 1; /**< [ 30: 30](R/W) ECC-correction disable for the TXB SKID FIFO */
uint64_t txb_skid_m3_synd : 2; /**< [ 32: 31](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO */
uint64_t txb_ncsi_cor_dis : 1; /**< [ 33: 33](R/W) ECC-correction disable for the TXB SKID FIFO */
uint64_t txb_ncsi_synd : 2; /**< [ 35: 34](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO */
uint64_t reserved_36_63 : 28;
#endif /* Word 0 - End */
} cn88xx;
struct bdk_bgxx_cmr_mem_ctrl_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_42_63 : 22;
uint64_t txb_fif_m3_syn : 2; /**< [ 41: 40](R/W) Syndrome to flip and generate single-bit/double-bit error for TXB main mem3. */
uint64_t txb_fif_m3_cdis : 1; /**< [ 39: 39](R/W) ECC-correction disable for the TXB main mem3. */
uint64_t txb_fif_m2_syn : 2; /**< [ 38: 37](R/W) Syndrome to flip and generate single-bit/double-bit error for TXB main mem2. */
uint64_t txb_fif_m2_cdis : 1; /**< [ 36: 36](R/W) ECC-correction disable for the TXB main mem2. */
uint64_t txb_ncsi_synd : 2; /**< [ 35: 34](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO */
uint64_t txb_ncsi_cor_dis : 1; /**< [ 33: 33](R/W) ECC-correction disable for the TXB SKID FIFO */
uint64_t txb_skid_m3_synd : 2; /**< [ 32: 31](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO */
uint64_t txb_skid_m3_cor_dis : 1; /**< [ 30: 30](R/W) ECC-correction disable for the TXB SKID FIFO */
uint64_t txb_skid_m2_synd : 2; /**< [ 29: 28](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO */
uint64_t txb_skid_m2_cor_dis : 1; /**< [ 27: 27](R/W) ECC-correction disable for the TXB SKID FIFO */
uint64_t txb_skid_m1_synd : 2; /**< [ 26: 25](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO */
uint64_t txb_skid_m1_cor_dis : 1; /**< [ 24: 24](R/W) ECC-correction disable for the TXB SKID FIFO */
uint64_t txb_skid_m0_synd : 2; /**< [ 23: 22](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO. */
uint64_t txb_skid_m0_cor_dis : 1; /**< [ 21: 21](R/W) ECC-correction disable for the TXB SKID FIFO. */
uint64_t txb_fif_m1_syn : 2; /**< [ 20: 19](R/W) Syndrome to flip and generate single-bit/double-bit error for TXB main mem1. */
uint64_t txb_fif_m1_cdis : 1; /**< [ 18: 18](R/W) ECC-correction disable for the TXB main mem1. */
uint64_t txb_fif_m0_syn : 2; /**< [ 17: 16](R/W) Syndrome to flip and generate single-bit/double-bit error for TXB main mem0. */
uint64_t txb_fif_m0_cdis : 1; /**< [ 15: 15](R/W) ECC-correction disable for the TXB main mem0. */
uint64_t rxb_skid_synd : 2; /**< [ 14: 13](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB SKID FIFO. */
uint64_t rxb_skid_cor_dis : 1; /**< [ 12: 12](R/W) ECC-correction disable for the RXB SKID FIFO. */
uint64_t rxb_fif_bk1_syn1 : 2; /**< [ 11: 10](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB main bank1 srf1. */
uint64_t rxb_fif_bk1_cdis1 : 1; /**< [ 9: 9](R/W) ECC-correction disable for the RXB main bank1 srf1. */
uint64_t rxb_fif_bk1_syn0 : 2; /**< [ 8: 7](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB main bank1 srf0. */
uint64_t rxb_fif_bk1_cdis0 : 1; /**< [ 6: 6](R/W) ECC-correction disable for the RXB main bank1 srf0. */
uint64_t rxb_fif_bk0_syn1 : 2; /**< [ 5: 4](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB main bank0 srf1. */
uint64_t rxb_fif_bk0_cdis1 : 1; /**< [ 3: 3](R/W) ECC-correction disable for the RXB main bank0 srf1. */
uint64_t rxb_fif_bk0_syn0 : 2; /**< [ 2: 1](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB main bank0 srf0. */
uint64_t rxb_fif_bk0_cdis0 : 1; /**< [ 0: 0](R/W) ECC-correction disable for the RXB main bank0 srf0. */
#else /* Word 0 - Little Endian */
uint64_t rxb_fif_bk0_cdis0 : 1; /**< [ 0: 0](R/W) ECC-correction disable for the RXB main bank0 srf0. */
uint64_t rxb_fif_bk0_syn0 : 2; /**< [ 2: 1](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB main bank0 srf0. */
uint64_t rxb_fif_bk0_cdis1 : 1; /**< [ 3: 3](R/W) ECC-correction disable for the RXB main bank0 srf1. */
uint64_t rxb_fif_bk0_syn1 : 2; /**< [ 5: 4](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB main bank0 srf1. */
uint64_t rxb_fif_bk1_cdis0 : 1; /**< [ 6: 6](R/W) ECC-correction disable for the RXB main bank1 srf0. */
uint64_t rxb_fif_bk1_syn0 : 2; /**< [ 8: 7](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB main bank1 srf0. */
uint64_t rxb_fif_bk1_cdis1 : 1; /**< [ 9: 9](R/W) ECC-correction disable for the RXB main bank1 srf1. */
uint64_t rxb_fif_bk1_syn1 : 2; /**< [ 11: 10](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB main bank1 srf1. */
uint64_t rxb_skid_cor_dis : 1; /**< [ 12: 12](R/W) ECC-correction disable for the RXB SKID FIFO. */
uint64_t rxb_skid_synd : 2; /**< [ 14: 13](R/W) Syndrome to flip and generate single-bit/double-bit error for RXB SKID FIFO. */
uint64_t txb_fif_m0_cdis : 1; /**< [ 15: 15](R/W) ECC-correction disable for the TXB main mem0. */
uint64_t txb_fif_m0_syn : 2; /**< [ 17: 16](R/W) Syndrome to flip and generate single-bit/double-bit error for TXB main mem0. */
uint64_t txb_fif_m1_cdis : 1; /**< [ 18: 18](R/W) ECC-correction disable for the TXB main mem1. */
uint64_t txb_fif_m1_syn : 2; /**< [ 20: 19](R/W) Syndrome to flip and generate single-bit/double-bit error for TXB main mem1. */
uint64_t txb_skid_m0_cor_dis : 1; /**< [ 21: 21](R/W) ECC-correction disable for the TXB SKID FIFO. */
uint64_t txb_skid_m0_synd : 2; /**< [ 23: 22](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO. */
uint64_t txb_skid_m1_cor_dis : 1; /**< [ 24: 24](R/W) ECC-correction disable for the TXB SKID FIFO */
uint64_t txb_skid_m1_synd : 2; /**< [ 26: 25](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO */
uint64_t txb_skid_m2_cor_dis : 1; /**< [ 27: 27](R/W) ECC-correction disable for the TXB SKID FIFO */
uint64_t txb_skid_m2_synd : 2; /**< [ 29: 28](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO */
uint64_t txb_skid_m3_cor_dis : 1; /**< [ 30: 30](R/W) ECC-correction disable for the TXB SKID FIFO */
uint64_t txb_skid_m3_synd : 2; /**< [ 32: 31](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO */
uint64_t txb_ncsi_cor_dis : 1; /**< [ 33: 33](R/W) ECC-correction disable for the TXB SKID FIFO */
uint64_t txb_ncsi_synd : 2; /**< [ 35: 34](R/W) Syndrome to flip and generate single-bit/double-bit for TXB SKID FIFO */
uint64_t txb_fif_m2_cdis : 1; /**< [ 36: 36](R/W) ECC-correction disable for the TXB main mem2. */
uint64_t txb_fif_m2_syn : 2; /**< [ 38: 37](R/W) Syndrome to flip and generate single-bit/double-bit error for TXB main mem2. */
uint64_t txb_fif_m3_cdis : 1; /**< [ 39: 39](R/W) ECC-correction disable for the TXB main mem3. */
uint64_t txb_fif_m3_syn : 2; /**< [ 41: 40](R/W) Syndrome to flip and generate single-bit/double-bit error for TXB main mem3. */
uint64_t reserved_42_63 : 22;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_cmr_mem_ctrl bdk_bgxx_cmr_mem_ctrl_t;
static inline uint64_t BDK_BGXX_CMR_MEM_CTRL(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMR_MEM_CTRL(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e0000030ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e0000030ll + 0x1000000ll * ((a) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && (a<=1))
return 0x87e0e0000030ll + 0x1000000ll * ((a) & 0x1);
__bdk_csr_fatal("BGXX_CMR_MEM_CTRL", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_CMR_MEM_CTRL(a) bdk_bgxx_cmr_mem_ctrl_t
#define bustype_BDK_BGXX_CMR_MEM_CTRL(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMR_MEM_CTRL(a) "BGXX_CMR_MEM_CTRL"
#define device_bar_BDK_BGXX_CMR_MEM_CTRL(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMR_MEM_CTRL(a) (a)
#define arguments_BDK_BGXX_CMR_MEM_CTRL(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_cmr_mem_int
*
* BGX CMR Memory Interrupt Register
*/
union bdk_bgxx_cmr_mem_int
{
uint64_t u;
struct bdk_bgxx_cmr_mem_int_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_40_63 : 24;
uint64_t txb_fif_m3_sbe : 1; /**< [ 39: 39](R/W1C/H) TXB Main FIFO Mem3 single-bit error. */
uint64_t txb_fif_m3_dbe : 1; /**< [ 38: 38](R/W1C/H) TXB Main FIFO Mem3 double-bit error. */
uint64_t txb_fif_m2_sbe : 1; /**< [ 37: 37](R/W1C/H) TXB Main FIFO Mem2 single-bit error. */
uint64_t txb_fif_m2_dbe : 1; /**< [ 36: 36](R/W1C/H) TXB Main FIFO Mem2 double-bit error. */
uint64_t txb_skid_m3_nic_sbe : 1; /**< [ 35: 35](R/W1C/H) TXB SKID NIC FIFO single-bit error */
uint64_t txb_skid_m3_nic_dbe : 1; /**< [ 34: 34](R/W1C/H) TXB SKID NIC FIFO double-bit error */
uint64_t txb_skid_m2_nic_sbe : 1; /**< [ 33: 33](R/W1C/H) TXB SKID FIFO single-bit error */
uint64_t txb_skid_m2_nic_dbe : 1; /**< [ 32: 32](R/W1C/H) TXB SKID NIC FIFO double-bit error */
uint64_t txb_skid_m1_nic_sbe : 1; /**< [ 31: 31](R/W1C/H) TXB SKID NIC FIFO single-bit error */
uint64_t txb_skid_m1_nic_dbe : 1; /**< [ 30: 30](R/W1C/H) TXB SKID NIC FIFO double-bit error */
uint64_t txb_skid_m0_nic_sbe : 1; /**< [ 29: 29](R/W1C/H) TXB SKID NIC FIFO double-bit error */
uint64_t txb_skid_m0_nic_dbe : 1; /**< [ 28: 28](R/W1C/H) TXB SKID NIC FIFO double-bit error */
uint64_t reserved_8_27 : 20;
uint64_t rxb_fif_bk1_sbe1 : 1; /**< [ 7: 7](R/W1C/H) RXB main FIFO bank1 srf1 single-bit error. */
uint64_t rxb_fif_bk1_dbe1 : 1; /**< [ 6: 6](R/W1C/H) RXB main FIFO bank1 srf1 double-bit error. */
uint64_t rxb_fif_bk1_sbe0 : 1; /**< [ 5: 5](R/W1C/H) RXB main FIFO bank1 srf0 single-bit error. */
uint64_t rxb_fif_bk1_dbe0 : 1; /**< [ 4: 4](R/W1C/H) RXB main FIFO bank1 srf0 double-bit error. */
uint64_t rxb_fif_bk0_sbe1 : 1; /**< [ 3: 3](R/W1C/H) RXB main FIFO bank0 srf1 single-bit error. */
uint64_t rxb_fif_bk0_dbe1 : 1; /**< [ 2: 2](R/W1C/H) RXB main FIFO bank0 srf1 double-bit error. */
uint64_t rxb_fif_bk0_sbe0 : 1; /**< [ 1: 1](R/W1C/H) RXB main FIFO bank0 srf0 single-bit error. */
uint64_t rxb_fif_bk0_dbe0 : 1; /**< [ 0: 0](R/W1C/H) RXB main FIFO bank0 srf0 double-bit error. */
#else /* Word 0 - Little Endian */
uint64_t rxb_fif_bk0_dbe0 : 1; /**< [ 0: 0](R/W1C/H) RXB main FIFO bank0 srf0 double-bit error. */
uint64_t rxb_fif_bk0_sbe0 : 1; /**< [ 1: 1](R/W1C/H) RXB main FIFO bank0 srf0 single-bit error. */
uint64_t rxb_fif_bk0_dbe1 : 1; /**< [ 2: 2](R/W1C/H) RXB main FIFO bank0 srf1 double-bit error. */
uint64_t rxb_fif_bk0_sbe1 : 1; /**< [ 3: 3](R/W1C/H) RXB main FIFO bank0 srf1 single-bit error. */
uint64_t rxb_fif_bk1_dbe0 : 1; /**< [ 4: 4](R/W1C/H) RXB main FIFO bank1 srf0 double-bit error. */
uint64_t rxb_fif_bk1_sbe0 : 1; /**< [ 5: 5](R/W1C/H) RXB main FIFO bank1 srf0 single-bit error. */
uint64_t rxb_fif_bk1_dbe1 : 1; /**< [ 6: 6](R/W1C/H) RXB main FIFO bank1 srf1 double-bit error. */
uint64_t rxb_fif_bk1_sbe1 : 1; /**< [ 7: 7](R/W1C/H) RXB main FIFO bank1 srf1 single-bit error. */
uint64_t reserved_8_27 : 20;
uint64_t txb_skid_m0_nic_dbe : 1; /**< [ 28: 28](R/W1C/H) TXB SKID NIC FIFO double-bit error */
uint64_t txb_skid_m0_nic_sbe : 1; /**< [ 29: 29](R/W1C/H) TXB SKID NIC FIFO double-bit error */
uint64_t txb_skid_m1_nic_dbe : 1; /**< [ 30: 30](R/W1C/H) TXB SKID NIC FIFO double-bit error */
uint64_t txb_skid_m1_nic_sbe : 1; /**< [ 31: 31](R/W1C/H) TXB SKID NIC FIFO single-bit error */
uint64_t txb_skid_m2_nic_dbe : 1; /**< [ 32: 32](R/W1C/H) TXB SKID NIC FIFO double-bit error */
uint64_t txb_skid_m2_nic_sbe : 1; /**< [ 33: 33](R/W1C/H) TXB SKID FIFO single-bit error */
uint64_t txb_skid_m3_nic_dbe : 1; /**< [ 34: 34](R/W1C/H) TXB SKID NIC FIFO double-bit error */
uint64_t txb_skid_m3_nic_sbe : 1; /**< [ 35: 35](R/W1C/H) TXB SKID NIC FIFO single-bit error */
uint64_t txb_fif_m2_dbe : 1; /**< [ 36: 36](R/W1C/H) TXB Main FIFO Mem2 double-bit error. */
uint64_t txb_fif_m2_sbe : 1; /**< [ 37: 37](R/W1C/H) TXB Main FIFO Mem2 single-bit error. */
uint64_t txb_fif_m3_dbe : 1; /**< [ 38: 38](R/W1C/H) TXB Main FIFO Mem3 double-bit error. */
uint64_t txb_fif_m3_sbe : 1; /**< [ 39: 39](R/W1C/H) TXB Main FIFO Mem3 single-bit error. */
uint64_t reserved_40_63 : 24;
#endif /* Word 0 - End */
} s;
struct bdk_bgxx_cmr_mem_int_cn81xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_36_63 : 28;
uint64_t txb_skid_m3_nic_sbe : 1; /**< [ 35: 35](R/W1C/H) TXB SKID NIC FIFO single-bit error */
uint64_t txb_skid_m3_nic_dbe : 1; /**< [ 34: 34](R/W1C/H) TXB SKID NIC FIFO double-bit error */
uint64_t txb_skid_m2_nic_sbe : 1; /**< [ 33: 33](R/W1C/H) TXB SKID FIFO single-bit error */
uint64_t txb_skid_m2_nic_dbe : 1; /**< [ 32: 32](R/W1C/H) TXB SKID NIC FIFO double-bit error */
uint64_t txb_skid_m1_nic_sbe : 1; /**< [ 31: 31](R/W1C/H) TXB SKID NIC FIFO single-bit error */
uint64_t txb_skid_m1_nic_dbe : 1; /**< [ 30: 30](R/W1C/H) TXB SKID NIC FIFO double-bit error */
uint64_t txb_skid_m0_nic_sbe : 1; /**< [ 29: 29](R/W1C/H) TXB SKID NIC FIFO double-bit error */
uint64_t txb_skid_m0_nic_dbe : 1; /**< [ 28: 28](R/W1C/H) TXB SKID NIC FIFO double-bit error */
uint64_t txb_ncsi_sbe : 1; /**< [ 27: 27](R/W1C/H) Reserved. */
uint64_t txb_ncsi_dbe : 1; /**< [ 26: 26](R/W1C/H) Reserved. */
uint64_t txb_skid_m3_pko_sbe : 1; /**< [ 25: 25](R/W1C/H) Reserved. */
uint64_t txb_skid_m3_pko_dbe : 1; /**< [ 24: 24](R/W1C/H) Reserved. */
uint64_t txb_skid_m2_pko_sbe : 1; /**< [ 23: 23](R/W1C/H) Reserved. */
uint64_t txb_skid_m2_pko_dbe : 1; /**< [ 22: 22](R/W1C/H) Reserved. */
uint64_t txb_skid_m1_pko_sbe : 1; /**< [ 21: 21](R/W1C/H) Reserved. */
uint64_t txb_skid_m1_pko_dbe : 1; /**< [ 20: 20](R/W1C/H) Reserved. */
uint64_t smu_in_overfl : 1; /**< [ 19: 19](R/W1C/H) RX SMU INFIFO overflow. */
uint64_t gmp_in_overfl : 1; /**< [ 18: 18](R/W1C/H) RX GMP INFIFO overflow. */
uint64_t txb_skid_m0_pko_sbe : 1; /**< [ 17: 17](R/W1C/H) Reserved. */
uint64_t txb_skid_m0_pko_dbe : 1; /**< [ 16: 16](R/W1C/H) Reserved. */
uint64_t txb_fif_bk1_sbe : 1; /**< [ 15: 15](R/W1C/H) TXB Main FIFO Bank1 single-bit error. */
uint64_t txb_fif_bk1_dbe : 1; /**< [ 14: 14](R/W1C/H) TXB Main FIFO Bank1 double-bit error. */
uint64_t txb_fif_bk0_sbe : 1; /**< [ 13: 13](R/W1C/H) TXB Main FIFO Bank0 single-bit error. */
uint64_t txb_fif_bk0_dbe : 1; /**< [ 12: 12](R/W1C/H) TXB Main FIFO Bank0 double-bit error. */
uint64_t rxb_nic_skid_sbe : 1; /**< [ 11: 11](R/W1C/H) RXB NIC SKID FIFO single-bit error. */
uint64_t rxb_nic_skid_dbe : 1; /**< [ 10: 10](R/W1C/H) RXB NIC SKID FIFO double-bit error. */
uint64_t rxb_pki_skid_sbe : 1; /**< [ 9: 9](R/W1C/H) RXB PKI SKID FIFO single-bit error. */
uint64_t rxb_pki_skid_dbe : 1; /**< [ 8: 8](R/W1C/H) RXB PKI SKID FIFO double-bit error. */
uint64_t rxb_fif_bk1_sbe1 : 1; /**< [ 7: 7](R/W1C/H) RXB main FIFO bank1 srf1 single-bit error. */
uint64_t rxb_fif_bk1_dbe1 : 1; /**< [ 6: 6](R/W1C/H) RXB main FIFO bank1 srf1 double-bit error. */
uint64_t rxb_fif_bk1_sbe0 : 1; /**< [ 5: 5](R/W1C/H) RXB main FIFO bank1 srf0 single-bit error. */
uint64_t rxb_fif_bk1_dbe0 : 1; /**< [ 4: 4](R/W1C/H) RXB main FIFO bank1 srf0 double-bit error. */
uint64_t rxb_fif_bk0_sbe1 : 1; /**< [ 3: 3](R/W1C/H) RXB main FIFO bank0 srf1 single-bit error. */
uint64_t rxb_fif_bk0_dbe1 : 1; /**< [ 2: 2](R/W1C/H) RXB main FIFO bank0 srf1 double-bit error. */
uint64_t rxb_fif_bk0_sbe0 : 1; /**< [ 1: 1](R/W1C/H) RXB main FIFO bank0 srf0 single-bit error. */
uint64_t rxb_fif_bk0_dbe0 : 1; /**< [ 0: 0](R/W1C/H) RXB main FIFO bank0 srf0 double-bit error. */
#else /* Word 0 - Little Endian */
uint64_t rxb_fif_bk0_dbe0 : 1; /**< [ 0: 0](R/W1C/H) RXB main FIFO bank0 srf0 double-bit error. */
uint64_t rxb_fif_bk0_sbe0 : 1; /**< [ 1: 1](R/W1C/H) RXB main FIFO bank0 srf0 single-bit error. */
uint64_t rxb_fif_bk0_dbe1 : 1; /**< [ 2: 2](R/W1C/H) RXB main FIFO bank0 srf1 double-bit error. */
uint64_t rxb_fif_bk0_sbe1 : 1; /**< [ 3: 3](R/W1C/H) RXB main FIFO bank0 srf1 single-bit error. */
uint64_t rxb_fif_bk1_dbe0 : 1; /**< [ 4: 4](R/W1C/H) RXB main FIFO bank1 srf0 double-bit error. */
uint64_t rxb_fif_bk1_sbe0 : 1; /**< [ 5: 5](R/W1C/H) RXB main FIFO bank1 srf0 single-bit error. */
uint64_t rxb_fif_bk1_dbe1 : 1; /**< [ 6: 6](R/W1C/H) RXB main FIFO bank1 srf1 double-bit error. */
uint64_t rxb_fif_bk1_sbe1 : 1; /**< [ 7: 7](R/W1C/H) RXB main FIFO bank1 srf1 single-bit error. */
uint64_t rxb_pki_skid_dbe : 1; /**< [ 8: 8](R/W1C/H) RXB PKI SKID FIFO double-bit error. */
uint64_t rxb_pki_skid_sbe : 1; /**< [ 9: 9](R/W1C/H) RXB PKI SKID FIFO single-bit error. */
uint64_t rxb_nic_skid_dbe : 1; /**< [ 10: 10](R/W1C/H) RXB NIC SKID FIFO double-bit error. */
uint64_t rxb_nic_skid_sbe : 1; /**< [ 11: 11](R/W1C/H) RXB NIC SKID FIFO single-bit error. */
uint64_t txb_fif_bk0_dbe : 1; /**< [ 12: 12](R/W1C/H) TXB Main FIFO Bank0 double-bit error. */
uint64_t txb_fif_bk0_sbe : 1; /**< [ 13: 13](R/W1C/H) TXB Main FIFO Bank0 single-bit error. */
uint64_t txb_fif_bk1_dbe : 1; /**< [ 14: 14](R/W1C/H) TXB Main FIFO Bank1 double-bit error. */
uint64_t txb_fif_bk1_sbe : 1; /**< [ 15: 15](R/W1C/H) TXB Main FIFO Bank1 single-bit error. */
uint64_t txb_skid_m0_pko_dbe : 1; /**< [ 16: 16](R/W1C/H) Reserved. */
uint64_t txb_skid_m0_pko_sbe : 1; /**< [ 17: 17](R/W1C/H) Reserved. */
uint64_t gmp_in_overfl : 1; /**< [ 18: 18](R/W1C/H) RX GMP INFIFO overflow. */
uint64_t smu_in_overfl : 1; /**< [ 19: 19](R/W1C/H) RX SMU INFIFO overflow. */
uint64_t txb_skid_m1_pko_dbe : 1; /**< [ 20: 20](R/W1C/H) Reserved. */
uint64_t txb_skid_m1_pko_sbe : 1; /**< [ 21: 21](R/W1C/H) Reserved. */
uint64_t txb_skid_m2_pko_dbe : 1; /**< [ 22: 22](R/W1C/H) Reserved. */
uint64_t txb_skid_m2_pko_sbe : 1; /**< [ 23: 23](R/W1C/H) Reserved. */
uint64_t txb_skid_m3_pko_dbe : 1; /**< [ 24: 24](R/W1C/H) Reserved. */
uint64_t txb_skid_m3_pko_sbe : 1; /**< [ 25: 25](R/W1C/H) Reserved. */
uint64_t txb_ncsi_dbe : 1; /**< [ 26: 26](R/W1C/H) Reserved. */
uint64_t txb_ncsi_sbe : 1; /**< [ 27: 27](R/W1C/H) Reserved. */
uint64_t txb_skid_m0_nic_dbe : 1; /**< [ 28: 28](R/W1C/H) TXB SKID NIC FIFO double-bit error */
uint64_t txb_skid_m0_nic_sbe : 1; /**< [ 29: 29](R/W1C/H) TXB SKID NIC FIFO double-bit error */
uint64_t txb_skid_m1_nic_dbe : 1; /**< [ 30: 30](R/W1C/H) TXB SKID NIC FIFO double-bit error */
uint64_t txb_skid_m1_nic_sbe : 1; /**< [ 31: 31](R/W1C/H) TXB SKID NIC FIFO single-bit error */
uint64_t txb_skid_m2_nic_dbe : 1; /**< [ 32: 32](R/W1C/H) TXB SKID NIC FIFO double-bit error */
uint64_t txb_skid_m2_nic_sbe : 1; /**< [ 33: 33](R/W1C/H) TXB SKID FIFO single-bit error */
uint64_t txb_skid_m3_nic_dbe : 1; /**< [ 34: 34](R/W1C/H) TXB SKID NIC FIFO double-bit error */
uint64_t txb_skid_m3_nic_sbe : 1; /**< [ 35: 35](R/W1C/H) TXB SKID NIC FIFO single-bit error */
uint64_t reserved_36_63 : 28;
#endif /* Word 0 - End */
} cn81xx;
struct bdk_bgxx_cmr_mem_int_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_26_63 : 38;
uint64_t txb_ncsi_sbe : 1; /**< [ 25: 25](R/W1C/H) TXB SKID FIFO single-bit error */
uint64_t txb_ncsi_dbe : 1; /**< [ 24: 24](R/W1C/H) TXB SKID FIFO double-bit error */
uint64_t txb_skid_m3_sbe : 1; /**< [ 23: 23](R/W1C/H) TXB SKID FIFO single-bit error */
uint64_t txb_skid_m3_dbe : 1; /**< [ 22: 22](R/W1C/H) TXB SKID FIFO double-bit error */
uint64_t txb_skid_m2_sbe : 1; /**< [ 21: 21](R/W1C/H) TXB SKID FIFO single-bit error */
uint64_t txb_skid_m2_dbe : 1; /**< [ 20: 20](R/W1C/H) TXB SKID FIFO double-bit error */
uint64_t txb_skid_m1_sbe : 1; /**< [ 19: 19](R/W1C/H) TXB SKID FIFO single-bit error */
uint64_t txb_skid_m1_dbe : 1; /**< [ 18: 18](R/W1C/H) TXB SKID FIFO double-bit error */
uint64_t smu_in_overfl : 1; /**< [ 17: 17](R/W1C/H) RX SMU INFIFO overflow. */
uint64_t gmp_in_overfl : 1; /**< [ 16: 16](R/W1C/H) RX GMP INFIFO overflow. */
uint64_t txb_skid_m0_sbe : 1; /**< [ 15: 15](R/W1C/H) TXB SKID FIFO single-bit error. */
uint64_t txb_skid_m0_dbe : 1; /**< [ 14: 14](R/W1C/H) TXB SKID FIFO double-bit error. */
uint64_t txb_fif_bk1_sbe : 1; /**< [ 13: 13](R/W1C/H) TXB Main FIFO Bank1 single-bit error. */
uint64_t txb_fif_bk1_dbe : 1; /**< [ 12: 12](R/W1C/H) TXB Main FIFO Bank1 double-bit error. */
uint64_t txb_fif_bk0_sbe : 1; /**< [ 11: 11](R/W1C/H) TXB Main FIFO Bank0 single-bit error. */
uint64_t txb_fif_bk0_dbe : 1; /**< [ 10: 10](R/W1C/H) TXB Main FIFO Bank0 double-bit error. */
uint64_t rxb_skid_sbe : 1; /**< [ 9: 9](R/W1C/H) RXB SKID FIFO single-bit error. */
uint64_t rxb_skid_dbe : 1; /**< [ 8: 8](R/W1C/H) RXB SKID FIFO double-bit error. */
uint64_t rxb_fif_bk1_sbe1 : 1; /**< [ 7: 7](R/W1C/H) RXB main FIFO bank1 srf1 single-bit error. */
uint64_t rxb_fif_bk1_dbe1 : 1; /**< [ 6: 6](R/W1C/H) RXB main FIFO bank1 srf1 double-bit error. */
uint64_t rxb_fif_bk1_sbe0 : 1; /**< [ 5: 5](R/W1C/H) RXB main FIFO bank1 srf0 single-bit error. */
uint64_t rxb_fif_bk1_dbe0 : 1; /**< [ 4: 4](R/W1C/H) RXB main FIFO bank1 srf0 double-bit error. */
uint64_t rxb_fif_bk0_sbe1 : 1; /**< [ 3: 3](R/W1C/H) RXB main FIFO bank0 srf1 single-bit error. */
uint64_t rxb_fif_bk0_dbe1 : 1; /**< [ 2: 2](R/W1C/H) RXB main FIFO bank0 srf1 double-bit error. */
uint64_t rxb_fif_bk0_sbe0 : 1; /**< [ 1: 1](R/W1C/H) RXB main FIFO bank0 srf0 single-bit error. */
uint64_t rxb_fif_bk0_dbe0 : 1; /**< [ 0: 0](R/W1C/H) RXB main FIFO bank0 srf0 double-bit error. */
#else /* Word 0 - Little Endian */
uint64_t rxb_fif_bk0_dbe0 : 1; /**< [ 0: 0](R/W1C/H) RXB main FIFO bank0 srf0 double-bit error. */
uint64_t rxb_fif_bk0_sbe0 : 1; /**< [ 1: 1](R/W1C/H) RXB main FIFO bank0 srf0 single-bit error. */
uint64_t rxb_fif_bk0_dbe1 : 1; /**< [ 2: 2](R/W1C/H) RXB main FIFO bank0 srf1 double-bit error. */
uint64_t rxb_fif_bk0_sbe1 : 1; /**< [ 3: 3](R/W1C/H) RXB main FIFO bank0 srf1 single-bit error. */
uint64_t rxb_fif_bk1_dbe0 : 1; /**< [ 4: 4](R/W1C/H) RXB main FIFO bank1 srf0 double-bit error. */
uint64_t rxb_fif_bk1_sbe0 : 1; /**< [ 5: 5](R/W1C/H) RXB main FIFO bank1 srf0 single-bit error. */
uint64_t rxb_fif_bk1_dbe1 : 1; /**< [ 6: 6](R/W1C/H) RXB main FIFO bank1 srf1 double-bit error. */
uint64_t rxb_fif_bk1_sbe1 : 1; /**< [ 7: 7](R/W1C/H) RXB main FIFO bank1 srf1 single-bit error. */
uint64_t rxb_skid_dbe : 1; /**< [ 8: 8](R/W1C/H) RXB SKID FIFO double-bit error. */
uint64_t rxb_skid_sbe : 1; /**< [ 9: 9](R/W1C/H) RXB SKID FIFO single-bit error. */
uint64_t txb_fif_bk0_dbe : 1; /**< [ 10: 10](R/W1C/H) TXB Main FIFO Bank0 double-bit error. */
uint64_t txb_fif_bk0_sbe : 1; /**< [ 11: 11](R/W1C/H) TXB Main FIFO Bank0 single-bit error. */
uint64_t txb_fif_bk1_dbe : 1; /**< [ 12: 12](R/W1C/H) TXB Main FIFO Bank1 double-bit error. */
uint64_t txb_fif_bk1_sbe : 1; /**< [ 13: 13](R/W1C/H) TXB Main FIFO Bank1 single-bit error. */
uint64_t txb_skid_m0_dbe : 1; /**< [ 14: 14](R/W1C/H) TXB SKID FIFO double-bit error. */
uint64_t txb_skid_m0_sbe : 1; /**< [ 15: 15](R/W1C/H) TXB SKID FIFO single-bit error. */
uint64_t gmp_in_overfl : 1; /**< [ 16: 16](R/W1C/H) RX GMP INFIFO overflow. */
uint64_t smu_in_overfl : 1; /**< [ 17: 17](R/W1C/H) RX SMU INFIFO overflow. */
uint64_t txb_skid_m1_dbe : 1; /**< [ 18: 18](R/W1C/H) TXB SKID FIFO double-bit error */
uint64_t txb_skid_m1_sbe : 1; /**< [ 19: 19](R/W1C/H) TXB SKID FIFO single-bit error */
uint64_t txb_skid_m2_dbe : 1; /**< [ 20: 20](R/W1C/H) TXB SKID FIFO double-bit error */
uint64_t txb_skid_m2_sbe : 1; /**< [ 21: 21](R/W1C/H) TXB SKID FIFO single-bit error */
uint64_t txb_skid_m3_dbe : 1; /**< [ 22: 22](R/W1C/H) TXB SKID FIFO double-bit error */
uint64_t txb_skid_m3_sbe : 1; /**< [ 23: 23](R/W1C/H) TXB SKID FIFO single-bit error */
uint64_t txb_ncsi_dbe : 1; /**< [ 24: 24](R/W1C/H) TXB SKID FIFO double-bit error */
uint64_t txb_ncsi_sbe : 1; /**< [ 25: 25](R/W1C/H) TXB SKID FIFO single-bit error */
uint64_t reserved_26_63 : 38;
#endif /* Word 0 - End */
} cn88xx;
struct bdk_bgxx_cmr_mem_int_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_40_63 : 24;
uint64_t txb_fif_m3_sbe : 1; /**< [ 39: 39](R/W1C/H) TXB Main FIFO Mem3 single-bit error. */
uint64_t txb_fif_m3_dbe : 1; /**< [ 38: 38](R/W1C/H) TXB Main FIFO Mem3 double-bit error. */
uint64_t txb_fif_m2_sbe : 1; /**< [ 37: 37](R/W1C/H) TXB Main FIFO Mem2 single-bit error. */
uint64_t txb_fif_m2_dbe : 1; /**< [ 36: 36](R/W1C/H) TXB Main FIFO Mem2 double-bit error. */
uint64_t txb_skid_m3_nic_sbe : 1; /**< [ 35: 35](R/W1C/H) TXB SKID NIC FIFO single-bit error */
uint64_t txb_skid_m3_nic_dbe : 1; /**< [ 34: 34](R/W1C/H) TXB SKID NIC FIFO double-bit error */
uint64_t txb_skid_m2_nic_sbe : 1; /**< [ 33: 33](R/W1C/H) TXB SKID FIFO single-bit error */
uint64_t txb_skid_m2_nic_dbe : 1; /**< [ 32: 32](R/W1C/H) TXB SKID NIC FIFO double-bit error */
uint64_t txb_skid_m1_nic_sbe : 1; /**< [ 31: 31](R/W1C/H) TXB SKID NIC FIFO single-bit error */
uint64_t txb_skid_m1_nic_dbe : 1; /**< [ 30: 30](R/W1C/H) TXB SKID NIC FIFO double-bit error */
uint64_t txb_skid_m0_nic_sbe : 1; /**< [ 29: 29](R/W1C/H) TXB SKID NIC FIFO double-bit error */
uint64_t txb_skid_m0_nic_dbe : 1; /**< [ 28: 28](R/W1C/H) TXB SKID NIC FIFO double-bit error */
uint64_t txb_ncsi_sbe : 1; /**< [ 27: 27](R/W1C/H) TXB SKID NCSI FIFO single-bit error */
uint64_t txb_ncsi_dbe : 1; /**< [ 26: 26](R/W1C/H) TXB SKID NCSI FIFO double-bit error */
uint64_t txb_skid_m3_pko_sbe : 1; /**< [ 25: 25](R/W1C/H) TXB SKID PKO FIFO single-bit error */
uint64_t txb_skid_m3_pko_dbe : 1; /**< [ 24: 24](R/W1C/H) TXB SKID PKO FIFO double-bit error */
uint64_t txb_skid_m2_pko_sbe : 1; /**< [ 23: 23](R/W1C/H) TXB SKID PKO FIFO single-bit error */
uint64_t txb_skid_m2_pko_dbe : 1; /**< [ 22: 22](R/W1C/H) TXB SKID PKO FIFO double-bit error */
uint64_t txb_skid_m1_pko_sbe : 1; /**< [ 21: 21](R/W1C/H) TXB SKID PKO FIFO single-bit error */
uint64_t txb_skid_m1_pko_dbe : 1; /**< [ 20: 20](R/W1C/H) TXB SKID PKO FIFO double-bit error */
uint64_t smu_in_overfl : 1; /**< [ 19: 19](R/W1C/H) RX SMU INFIFO overflow. */
uint64_t gmp_in_overfl : 1; /**< [ 18: 18](R/W1C/H) RX GMP INFIFO overflow. */
uint64_t txb_skid_m0_pko_sbe : 1; /**< [ 17: 17](R/W1C/H) TXB SKID PKO FIFO single-bit error. */
uint64_t txb_skid_m0_pko_dbe : 1; /**< [ 16: 16](R/W1C/H) TXB SKID PKO FIFO double-bit error. */
uint64_t txb_fif_m1_sbe : 1; /**< [ 15: 15](R/W1C/H) TXB Main FIFO Mem1 single-bit error. */
uint64_t txb_fif_m1_dbe : 1; /**< [ 14: 14](R/W1C/H) TXB Main FIFO Mem1 double-bit error. */
uint64_t txb_fif_m0_sbe : 1; /**< [ 13: 13](R/W1C/H) TXB Main FIFO Mem0 single-bit error. */
uint64_t txb_fif_m0_dbe : 1; /**< [ 12: 12](R/W1C/H) TXB Main FIFO Mem0 double-bit error. */
uint64_t rxb_nic_skid_sbe : 1; /**< [ 11: 11](R/W1C/H) RXB NIC SKID FIFO single-bit error. */
uint64_t rxb_nic_skid_dbe : 1; /**< [ 10: 10](R/W1C/H) RXB NIC SKID FIFO double-bit error. */
uint64_t rxb_pki_skid_sbe : 1; /**< [ 9: 9](R/W1C/H) RXB PKI SKID FIFO single-bit error. */
uint64_t rxb_pki_skid_dbe : 1; /**< [ 8: 8](R/W1C/H) RXB PKI SKID FIFO double-bit error. */
uint64_t rxb_fif_bk1_sbe1 : 1; /**< [ 7: 7](R/W1C/H) RXB main FIFO bank1 srf1 single-bit error. */
uint64_t rxb_fif_bk1_dbe1 : 1; /**< [ 6: 6](R/W1C/H) RXB main FIFO bank1 srf1 double-bit error. */
uint64_t rxb_fif_bk1_sbe0 : 1; /**< [ 5: 5](R/W1C/H) RXB main FIFO bank1 srf0 single-bit error. */
uint64_t rxb_fif_bk1_dbe0 : 1; /**< [ 4: 4](R/W1C/H) RXB main FIFO bank1 srf0 double-bit error. */
uint64_t rxb_fif_bk0_sbe1 : 1; /**< [ 3: 3](R/W1C/H) RXB main FIFO bank0 srf1 single-bit error. */
uint64_t rxb_fif_bk0_dbe1 : 1; /**< [ 2: 2](R/W1C/H) RXB main FIFO bank0 srf1 double-bit error. */
uint64_t rxb_fif_bk0_sbe0 : 1; /**< [ 1: 1](R/W1C/H) RXB main FIFO bank0 srf0 single-bit error. */
uint64_t rxb_fif_bk0_dbe0 : 1; /**< [ 0: 0](R/W1C/H) RXB main FIFO bank0 srf0 double-bit error. */
#else /* Word 0 - Little Endian */
uint64_t rxb_fif_bk0_dbe0 : 1; /**< [ 0: 0](R/W1C/H) RXB main FIFO bank0 srf0 double-bit error. */
uint64_t rxb_fif_bk0_sbe0 : 1; /**< [ 1: 1](R/W1C/H) RXB main FIFO bank0 srf0 single-bit error. */
uint64_t rxb_fif_bk0_dbe1 : 1; /**< [ 2: 2](R/W1C/H) RXB main FIFO bank0 srf1 double-bit error. */
uint64_t rxb_fif_bk0_sbe1 : 1; /**< [ 3: 3](R/W1C/H) RXB main FIFO bank0 srf1 single-bit error. */
uint64_t rxb_fif_bk1_dbe0 : 1; /**< [ 4: 4](R/W1C/H) RXB main FIFO bank1 srf0 double-bit error. */
uint64_t rxb_fif_bk1_sbe0 : 1; /**< [ 5: 5](R/W1C/H) RXB main FIFO bank1 srf0 single-bit error. */
uint64_t rxb_fif_bk1_dbe1 : 1; /**< [ 6: 6](R/W1C/H) RXB main FIFO bank1 srf1 double-bit error. */
uint64_t rxb_fif_bk1_sbe1 : 1; /**< [ 7: 7](R/W1C/H) RXB main FIFO bank1 srf1 single-bit error. */
uint64_t rxb_pki_skid_dbe : 1; /**< [ 8: 8](R/W1C/H) RXB PKI SKID FIFO double-bit error. */
uint64_t rxb_pki_skid_sbe : 1; /**< [ 9: 9](R/W1C/H) RXB PKI SKID FIFO single-bit error. */
uint64_t rxb_nic_skid_dbe : 1; /**< [ 10: 10](R/W1C/H) RXB NIC SKID FIFO double-bit error. */
uint64_t rxb_nic_skid_sbe : 1; /**< [ 11: 11](R/W1C/H) RXB NIC SKID FIFO single-bit error. */
uint64_t txb_fif_m0_dbe : 1; /**< [ 12: 12](R/W1C/H) TXB Main FIFO Mem0 double-bit error. */
uint64_t txb_fif_m0_sbe : 1; /**< [ 13: 13](R/W1C/H) TXB Main FIFO Mem0 single-bit error. */
uint64_t txb_fif_m1_dbe : 1; /**< [ 14: 14](R/W1C/H) TXB Main FIFO Mem1 double-bit error. */
uint64_t txb_fif_m1_sbe : 1; /**< [ 15: 15](R/W1C/H) TXB Main FIFO Mem1 single-bit error. */
uint64_t txb_skid_m0_pko_dbe : 1; /**< [ 16: 16](R/W1C/H) TXB SKID PKO FIFO double-bit error. */
uint64_t txb_skid_m0_pko_sbe : 1; /**< [ 17: 17](R/W1C/H) TXB SKID PKO FIFO single-bit error. */
uint64_t gmp_in_overfl : 1; /**< [ 18: 18](R/W1C/H) RX GMP INFIFO overflow. */
uint64_t smu_in_overfl : 1; /**< [ 19: 19](R/W1C/H) RX SMU INFIFO overflow. */
uint64_t txb_skid_m1_pko_dbe : 1; /**< [ 20: 20](R/W1C/H) TXB SKID PKO FIFO double-bit error */
uint64_t txb_skid_m1_pko_sbe : 1; /**< [ 21: 21](R/W1C/H) TXB SKID PKO FIFO single-bit error */
uint64_t txb_skid_m2_pko_dbe : 1; /**< [ 22: 22](R/W1C/H) TXB SKID PKO FIFO double-bit error */
uint64_t txb_skid_m2_pko_sbe : 1; /**< [ 23: 23](R/W1C/H) TXB SKID PKO FIFO single-bit error */
uint64_t txb_skid_m3_pko_dbe : 1; /**< [ 24: 24](R/W1C/H) TXB SKID PKO FIFO double-bit error */
uint64_t txb_skid_m3_pko_sbe : 1; /**< [ 25: 25](R/W1C/H) TXB SKID PKO FIFO single-bit error */
uint64_t txb_ncsi_dbe : 1; /**< [ 26: 26](R/W1C/H) TXB SKID NCSI FIFO double-bit error */
uint64_t txb_ncsi_sbe : 1; /**< [ 27: 27](R/W1C/H) TXB SKID NCSI FIFO single-bit error */
uint64_t txb_skid_m0_nic_dbe : 1; /**< [ 28: 28](R/W1C/H) TXB SKID NIC FIFO double-bit error */
uint64_t txb_skid_m0_nic_sbe : 1; /**< [ 29: 29](R/W1C/H) TXB SKID NIC FIFO double-bit error */
uint64_t txb_skid_m1_nic_dbe : 1; /**< [ 30: 30](R/W1C/H) TXB SKID NIC FIFO double-bit error */
uint64_t txb_skid_m1_nic_sbe : 1; /**< [ 31: 31](R/W1C/H) TXB SKID NIC FIFO single-bit error */
uint64_t txb_skid_m2_nic_dbe : 1; /**< [ 32: 32](R/W1C/H) TXB SKID NIC FIFO double-bit error */
uint64_t txb_skid_m2_nic_sbe : 1; /**< [ 33: 33](R/W1C/H) TXB SKID FIFO single-bit error */
uint64_t txb_skid_m3_nic_dbe : 1; /**< [ 34: 34](R/W1C/H) TXB SKID NIC FIFO double-bit error */
uint64_t txb_skid_m3_nic_sbe : 1; /**< [ 35: 35](R/W1C/H) TXB SKID NIC FIFO single-bit error */
uint64_t txb_fif_m2_dbe : 1; /**< [ 36: 36](R/W1C/H) TXB Main FIFO Mem2 double-bit error. */
uint64_t txb_fif_m2_sbe : 1; /**< [ 37: 37](R/W1C/H) TXB Main FIFO Mem2 single-bit error. */
uint64_t txb_fif_m3_dbe : 1; /**< [ 38: 38](R/W1C/H) TXB Main FIFO Mem3 double-bit error. */
uint64_t txb_fif_m3_sbe : 1; /**< [ 39: 39](R/W1C/H) TXB Main FIFO Mem3 single-bit error. */
uint64_t reserved_40_63 : 24;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_cmr_mem_int bdk_bgxx_cmr_mem_int_t;
static inline uint64_t BDK_BGXX_CMR_MEM_INT(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMR_MEM_INT(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e0000010ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e0000010ll + 0x1000000ll * ((a) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && (a<=1))
return 0x87e0e0000010ll + 0x1000000ll * ((a) & 0x1);
__bdk_csr_fatal("BGXX_CMR_MEM_INT", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_CMR_MEM_INT(a) bdk_bgxx_cmr_mem_int_t
#define bustype_BDK_BGXX_CMR_MEM_INT(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMR_MEM_INT(a) "BGXX_CMR_MEM_INT"
#define device_bar_BDK_BGXX_CMR_MEM_INT(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMR_MEM_INT(a) (a)
#define arguments_BDK_BGXX_CMR_MEM_INT(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_cmr_mem_int_ena_w1c
*
* BGX CMR Memory Interrupt Enable Clear Register
* This register clears interrupt enable bits.
*/
union bdk_bgxx_cmr_mem_int_ena_w1c
{
uint64_t u;
struct bdk_bgxx_cmr_mem_int_ena_w1c_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_40_63 : 24;
uint64_t txb_fif_m3_sbe : 1; /**< [ 39: 39](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M3_SBE]. */
uint64_t txb_fif_m3_dbe : 1; /**< [ 38: 38](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M3_DBE]. */
uint64_t txb_fif_m2_sbe : 1; /**< [ 37: 37](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M2_SBE]. */
uint64_t txb_fif_m2_dbe : 1; /**< [ 36: 36](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M2_DBE]. */
uint64_t txb_skid_m3_nic_sbe : 1; /**< [ 35: 35](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_NIC_SBE]. */
uint64_t txb_skid_m3_nic_dbe : 1; /**< [ 34: 34](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_NIC_DBE]. */
uint64_t txb_skid_m2_nic_sbe : 1; /**< [ 33: 33](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_NIC_SBE]. */
uint64_t txb_skid_m2_nic_dbe : 1; /**< [ 32: 32](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_NIC_DBE]. */
uint64_t txb_skid_m1_nic_sbe : 1; /**< [ 31: 31](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_NIC_SBE]. */
uint64_t txb_skid_m1_nic_dbe : 1; /**< [ 30: 30](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_NIC_DBE]. */
uint64_t txb_skid_m0_nic_sbe : 1; /**< [ 29: 29](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_NIC_SBE]. */
uint64_t txb_skid_m0_nic_dbe : 1; /**< [ 28: 28](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_NIC_DBE]. */
uint64_t reserved_20_27 : 8;
uint64_t txb_skid_m1_sbe : 1; /**< [ 19: 19](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_SBE]. */
uint64_t txb_skid_m1_dbe : 1; /**< [ 18: 18](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_DBE]. */
uint64_t reserved_8_17 : 10;
uint64_t rxb_fif_bk1_sbe1 : 1; /**< [ 7: 7](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE1]. */
uint64_t rxb_fif_bk1_dbe1 : 1; /**< [ 6: 6](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE1]. */
uint64_t rxb_fif_bk1_sbe0 : 1; /**< [ 5: 5](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE0]. */
uint64_t rxb_fif_bk1_dbe0 : 1; /**< [ 4: 4](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE0]. */
uint64_t rxb_fif_bk0_sbe1 : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE1]. */
uint64_t rxb_fif_bk0_dbe1 : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE1]. */
uint64_t rxb_fif_bk0_sbe0 : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE0]. */
uint64_t rxb_fif_bk0_dbe0 : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE0]. */
#else /* Word 0 - Little Endian */
uint64_t rxb_fif_bk0_dbe0 : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE0]. */
uint64_t rxb_fif_bk0_sbe0 : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE0]. */
uint64_t rxb_fif_bk0_dbe1 : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE1]. */
uint64_t rxb_fif_bk0_sbe1 : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE1]. */
uint64_t rxb_fif_bk1_dbe0 : 1; /**< [ 4: 4](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE0]. */
uint64_t rxb_fif_bk1_sbe0 : 1; /**< [ 5: 5](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE0]. */
uint64_t rxb_fif_bk1_dbe1 : 1; /**< [ 6: 6](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE1]. */
uint64_t rxb_fif_bk1_sbe1 : 1; /**< [ 7: 7](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE1]. */
uint64_t reserved_8_17 : 10;
uint64_t txb_skid_m1_dbe : 1; /**< [ 18: 18](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_DBE]. */
uint64_t txb_skid_m1_sbe : 1; /**< [ 19: 19](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_SBE]. */
uint64_t reserved_20_27 : 8;
uint64_t txb_skid_m0_nic_dbe : 1; /**< [ 28: 28](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_NIC_DBE]. */
uint64_t txb_skid_m0_nic_sbe : 1; /**< [ 29: 29](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_NIC_SBE]. */
uint64_t txb_skid_m1_nic_dbe : 1; /**< [ 30: 30](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_NIC_DBE]. */
uint64_t txb_skid_m1_nic_sbe : 1; /**< [ 31: 31](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_NIC_SBE]. */
uint64_t txb_skid_m2_nic_dbe : 1; /**< [ 32: 32](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_NIC_DBE]. */
uint64_t txb_skid_m2_nic_sbe : 1; /**< [ 33: 33](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_NIC_SBE]. */
uint64_t txb_skid_m3_nic_dbe : 1; /**< [ 34: 34](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_NIC_DBE]. */
uint64_t txb_skid_m3_nic_sbe : 1; /**< [ 35: 35](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_NIC_SBE]. */
uint64_t txb_fif_m2_dbe : 1; /**< [ 36: 36](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M2_DBE]. */
uint64_t txb_fif_m2_sbe : 1; /**< [ 37: 37](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M2_SBE]. */
uint64_t txb_fif_m3_dbe : 1; /**< [ 38: 38](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M3_DBE]. */
uint64_t txb_fif_m3_sbe : 1; /**< [ 39: 39](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M3_SBE]. */
uint64_t reserved_40_63 : 24;
#endif /* Word 0 - End */
} s;
struct bdk_bgxx_cmr_mem_int_ena_w1c_cn81xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_36_63 : 28;
uint64_t txb_skid_m3_nic_sbe : 1; /**< [ 35: 35](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_NIC_SBE]. */
uint64_t txb_skid_m3_nic_dbe : 1; /**< [ 34: 34](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_NIC_DBE]. */
uint64_t txb_skid_m2_nic_sbe : 1; /**< [ 33: 33](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_NIC_SBE]. */
uint64_t txb_skid_m2_nic_dbe : 1; /**< [ 32: 32](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_NIC_DBE]. */
uint64_t txb_skid_m1_nic_sbe : 1; /**< [ 31: 31](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_NIC_SBE]. */
uint64_t txb_skid_m1_nic_dbe : 1; /**< [ 30: 30](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_NIC_DBE]. */
uint64_t txb_skid_m0_nic_sbe : 1; /**< [ 29: 29](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_NIC_SBE]. */
uint64_t txb_skid_m0_nic_dbe : 1; /**< [ 28: 28](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_NIC_DBE]. */
uint64_t txb_ncsi_sbe : 1; /**< [ 27: 27](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_NCSI_SBE]. */
uint64_t txb_ncsi_dbe : 1; /**< [ 26: 26](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_NCSI_DBE]. */
uint64_t txb_skid_m3_pko_sbe : 1; /**< [ 25: 25](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_PKO_SBE]. */
uint64_t txb_skid_m3_pko_dbe : 1; /**< [ 24: 24](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_PKO_DBE]. */
uint64_t txb_skid_m2_pko_sbe : 1; /**< [ 23: 23](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_PKO_SBE]. */
uint64_t txb_skid_m2_pko_dbe : 1; /**< [ 22: 22](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_PKO_DBE]. */
uint64_t txb_skid_m1_pko_sbe : 1; /**< [ 21: 21](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_PKO_SBE]. */
uint64_t txb_skid_m1_pko_dbe : 1; /**< [ 20: 20](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_PKO_DBE]. */
uint64_t smu_in_overfl : 1; /**< [ 19: 19](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[SMU_IN_OVERFL]. */
uint64_t gmp_in_overfl : 1; /**< [ 18: 18](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[GMP_IN_OVERFL]. */
uint64_t txb_skid_m0_pko_sbe : 1; /**< [ 17: 17](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_PKO_SBE]. */
uint64_t txb_skid_m0_pko_dbe : 1; /**< [ 16: 16](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_PKO_DBE]. */
uint64_t txb_fif_bk1_sbe : 1; /**< [ 15: 15](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK1_SBE]. */
uint64_t txb_fif_bk1_dbe : 1; /**< [ 14: 14](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK1_DBE]. */
uint64_t txb_fif_bk0_sbe : 1; /**< [ 13: 13](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK0_SBE]. */
uint64_t txb_fif_bk0_dbe : 1; /**< [ 12: 12](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK0_DBE]. */
uint64_t rxb_nic_skid_sbe : 1; /**< [ 11: 11](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_NIC_SKID_SBE]. */
uint64_t rxb_nic_skid_dbe : 1; /**< [ 10: 10](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_NIC_SKID_DBE]. */
uint64_t rxb_pki_skid_sbe : 1; /**< [ 9: 9](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_PKI_SKID_SBE]. */
uint64_t rxb_pki_skid_dbe : 1; /**< [ 8: 8](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_PKI_SKID_DBE]. */
uint64_t rxb_fif_bk1_sbe1 : 1; /**< [ 7: 7](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE1]. */
uint64_t rxb_fif_bk1_dbe1 : 1; /**< [ 6: 6](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE1]. */
uint64_t rxb_fif_bk1_sbe0 : 1; /**< [ 5: 5](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE0]. */
uint64_t rxb_fif_bk1_dbe0 : 1; /**< [ 4: 4](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE0]. */
uint64_t rxb_fif_bk0_sbe1 : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE1]. */
uint64_t rxb_fif_bk0_dbe1 : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE1]. */
uint64_t rxb_fif_bk0_sbe0 : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE0]. */
uint64_t rxb_fif_bk0_dbe0 : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE0]. */
#else /* Word 0 - Little Endian */
uint64_t rxb_fif_bk0_dbe0 : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE0]. */
uint64_t rxb_fif_bk0_sbe0 : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE0]. */
uint64_t rxb_fif_bk0_dbe1 : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE1]. */
uint64_t rxb_fif_bk0_sbe1 : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE1]. */
uint64_t rxb_fif_bk1_dbe0 : 1; /**< [ 4: 4](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE0]. */
uint64_t rxb_fif_bk1_sbe0 : 1; /**< [ 5: 5](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE0]. */
uint64_t rxb_fif_bk1_dbe1 : 1; /**< [ 6: 6](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE1]. */
uint64_t rxb_fif_bk1_sbe1 : 1; /**< [ 7: 7](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE1]. */
uint64_t rxb_pki_skid_dbe : 1; /**< [ 8: 8](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_PKI_SKID_DBE]. */
uint64_t rxb_pki_skid_sbe : 1; /**< [ 9: 9](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_PKI_SKID_SBE]. */
uint64_t rxb_nic_skid_dbe : 1; /**< [ 10: 10](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_NIC_SKID_DBE]. */
uint64_t rxb_nic_skid_sbe : 1; /**< [ 11: 11](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_NIC_SKID_SBE]. */
uint64_t txb_fif_bk0_dbe : 1; /**< [ 12: 12](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK0_DBE]. */
uint64_t txb_fif_bk0_sbe : 1; /**< [ 13: 13](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK0_SBE]. */
uint64_t txb_fif_bk1_dbe : 1; /**< [ 14: 14](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK1_DBE]. */
uint64_t txb_fif_bk1_sbe : 1; /**< [ 15: 15](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK1_SBE]. */
uint64_t txb_skid_m0_pko_dbe : 1; /**< [ 16: 16](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_PKO_DBE]. */
uint64_t txb_skid_m0_pko_sbe : 1; /**< [ 17: 17](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_PKO_SBE]. */
uint64_t gmp_in_overfl : 1; /**< [ 18: 18](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[GMP_IN_OVERFL]. */
uint64_t smu_in_overfl : 1; /**< [ 19: 19](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[SMU_IN_OVERFL]. */
uint64_t txb_skid_m1_pko_dbe : 1; /**< [ 20: 20](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_PKO_DBE]. */
uint64_t txb_skid_m1_pko_sbe : 1; /**< [ 21: 21](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_PKO_SBE]. */
uint64_t txb_skid_m2_pko_dbe : 1; /**< [ 22: 22](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_PKO_DBE]. */
uint64_t txb_skid_m2_pko_sbe : 1; /**< [ 23: 23](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_PKO_SBE]. */
uint64_t txb_skid_m3_pko_dbe : 1; /**< [ 24: 24](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_PKO_DBE]. */
uint64_t txb_skid_m3_pko_sbe : 1; /**< [ 25: 25](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_PKO_SBE]. */
uint64_t txb_ncsi_dbe : 1; /**< [ 26: 26](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_NCSI_DBE]. */
uint64_t txb_ncsi_sbe : 1; /**< [ 27: 27](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_NCSI_SBE]. */
uint64_t txb_skid_m0_nic_dbe : 1; /**< [ 28: 28](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_NIC_DBE]. */
uint64_t txb_skid_m0_nic_sbe : 1; /**< [ 29: 29](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_NIC_SBE]. */
uint64_t txb_skid_m1_nic_dbe : 1; /**< [ 30: 30](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_NIC_DBE]. */
uint64_t txb_skid_m1_nic_sbe : 1; /**< [ 31: 31](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_NIC_SBE]. */
uint64_t txb_skid_m2_nic_dbe : 1; /**< [ 32: 32](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_NIC_DBE]. */
uint64_t txb_skid_m2_nic_sbe : 1; /**< [ 33: 33](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_NIC_SBE]. */
uint64_t txb_skid_m3_nic_dbe : 1; /**< [ 34: 34](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_NIC_DBE]. */
uint64_t txb_skid_m3_nic_sbe : 1; /**< [ 35: 35](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_NIC_SBE]. */
uint64_t reserved_36_63 : 28;
#endif /* Word 0 - End */
} cn81xx;
struct bdk_bgxx_cmr_mem_int_ena_w1c_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_26_63 : 38;
uint64_t txb_ncsi_sbe : 1; /**< [ 25: 25](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_NCSI_SBE]. */
uint64_t txb_ncsi_dbe : 1; /**< [ 24: 24](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_NCSI_DBE]. */
uint64_t txb_skid_m3_sbe : 1; /**< [ 23: 23](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_SBE]. */
uint64_t txb_skid_m3_dbe : 1; /**< [ 22: 22](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_DBE]. */
uint64_t txb_skid_m2_sbe : 1; /**< [ 21: 21](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_SBE]. */
uint64_t txb_skid_m2_dbe : 1; /**< [ 20: 20](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_DBE]. */
uint64_t txb_skid_m1_sbe : 1; /**< [ 19: 19](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_SBE]. */
uint64_t txb_skid_m1_dbe : 1; /**< [ 18: 18](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_DBE]. */
uint64_t smu_in_overfl : 1; /**< [ 17: 17](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[SMU_IN_OVERFL]. */
uint64_t gmp_in_overfl : 1; /**< [ 16: 16](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[GMP_IN_OVERFL]. */
uint64_t txb_skid_m0_sbe : 1; /**< [ 15: 15](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_SBE]. */
uint64_t txb_skid_m0_dbe : 1; /**< [ 14: 14](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_DBE]. */
uint64_t txb_fif_bk1_sbe : 1; /**< [ 13: 13](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK1_SBE]. */
uint64_t txb_fif_bk1_dbe : 1; /**< [ 12: 12](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK1_DBE]. */
uint64_t txb_fif_bk0_sbe : 1; /**< [ 11: 11](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK0_SBE]. */
uint64_t txb_fif_bk0_dbe : 1; /**< [ 10: 10](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK0_DBE]. */
uint64_t rxb_skid_sbe : 1; /**< [ 9: 9](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_SKID_SBE]. */
uint64_t rxb_skid_dbe : 1; /**< [ 8: 8](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_SKID_DBE]. */
uint64_t rxb_fif_bk1_sbe1 : 1; /**< [ 7: 7](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE1]. */
uint64_t rxb_fif_bk1_dbe1 : 1; /**< [ 6: 6](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE1]. */
uint64_t rxb_fif_bk1_sbe0 : 1; /**< [ 5: 5](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE0]. */
uint64_t rxb_fif_bk1_dbe0 : 1; /**< [ 4: 4](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE0]. */
uint64_t rxb_fif_bk0_sbe1 : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE1]. */
uint64_t rxb_fif_bk0_dbe1 : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE1]. */
uint64_t rxb_fif_bk0_sbe0 : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE0]. */
uint64_t rxb_fif_bk0_dbe0 : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE0]. */
#else /* Word 0 - Little Endian */
uint64_t rxb_fif_bk0_dbe0 : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE0]. */
uint64_t rxb_fif_bk0_sbe0 : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE0]. */
uint64_t rxb_fif_bk0_dbe1 : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE1]. */
uint64_t rxb_fif_bk0_sbe1 : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE1]. */
uint64_t rxb_fif_bk1_dbe0 : 1; /**< [ 4: 4](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE0]. */
uint64_t rxb_fif_bk1_sbe0 : 1; /**< [ 5: 5](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE0]. */
uint64_t rxb_fif_bk1_dbe1 : 1; /**< [ 6: 6](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE1]. */
uint64_t rxb_fif_bk1_sbe1 : 1; /**< [ 7: 7](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE1]. */
uint64_t rxb_skid_dbe : 1; /**< [ 8: 8](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_SKID_DBE]. */
uint64_t rxb_skid_sbe : 1; /**< [ 9: 9](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[RXB_SKID_SBE]. */
uint64_t txb_fif_bk0_dbe : 1; /**< [ 10: 10](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK0_DBE]. */
uint64_t txb_fif_bk0_sbe : 1; /**< [ 11: 11](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK0_SBE]. */
uint64_t txb_fif_bk1_dbe : 1; /**< [ 12: 12](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK1_DBE]. */
uint64_t txb_fif_bk1_sbe : 1; /**< [ 13: 13](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK1_SBE]. */
uint64_t txb_skid_m0_dbe : 1; /**< [ 14: 14](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_DBE]. */
uint64_t txb_skid_m0_sbe : 1; /**< [ 15: 15](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_SBE]. */
uint64_t gmp_in_overfl : 1; /**< [ 16: 16](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[GMP_IN_OVERFL]. */
uint64_t smu_in_overfl : 1; /**< [ 17: 17](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[SMU_IN_OVERFL]. */
uint64_t txb_skid_m1_dbe : 1; /**< [ 18: 18](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_DBE]. */
uint64_t txb_skid_m1_sbe : 1; /**< [ 19: 19](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_SBE]. */
uint64_t txb_skid_m2_dbe : 1; /**< [ 20: 20](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_DBE]. */
uint64_t txb_skid_m2_sbe : 1; /**< [ 21: 21](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_SBE]. */
uint64_t txb_skid_m3_dbe : 1; /**< [ 22: 22](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_DBE]. */
uint64_t txb_skid_m3_sbe : 1; /**< [ 23: 23](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_SBE]. */
uint64_t txb_ncsi_dbe : 1; /**< [ 24: 24](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_NCSI_DBE]. */
uint64_t txb_ncsi_sbe : 1; /**< [ 25: 25](R/W1C/H) Reads or clears enable for BGX(0..1)_CMR_MEM_INT[TXB_NCSI_SBE]. */
uint64_t reserved_26_63 : 38;
#endif /* Word 0 - End */
} cn88xx;
struct bdk_bgxx_cmr_mem_int_ena_w1c_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_40_63 : 24;
uint64_t txb_fif_m3_sbe : 1; /**< [ 39: 39](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M3_SBE]. */
uint64_t txb_fif_m3_dbe : 1; /**< [ 38: 38](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M3_DBE]. */
uint64_t txb_fif_m2_sbe : 1; /**< [ 37: 37](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M2_SBE]. */
uint64_t txb_fif_m2_dbe : 1; /**< [ 36: 36](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M2_DBE]. */
uint64_t txb_skid_m3_nic_sbe : 1; /**< [ 35: 35](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_NIC_SBE]. */
uint64_t txb_skid_m3_nic_dbe : 1; /**< [ 34: 34](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_NIC_DBE]. */
uint64_t txb_skid_m2_nic_sbe : 1; /**< [ 33: 33](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_NIC_SBE]. */
uint64_t txb_skid_m2_nic_dbe : 1; /**< [ 32: 32](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_NIC_DBE]. */
uint64_t txb_skid_m1_nic_sbe : 1; /**< [ 31: 31](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_NIC_SBE]. */
uint64_t txb_skid_m1_nic_dbe : 1; /**< [ 30: 30](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_NIC_DBE]. */
uint64_t txb_skid_m0_nic_sbe : 1; /**< [ 29: 29](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_NIC_SBE]. */
uint64_t txb_skid_m0_nic_dbe : 1; /**< [ 28: 28](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_NIC_DBE]. */
uint64_t txb_ncsi_sbe : 1; /**< [ 27: 27](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_NCSI_SBE]. */
uint64_t txb_ncsi_dbe : 1; /**< [ 26: 26](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_NCSI_DBE]. */
uint64_t txb_skid_m3_pko_sbe : 1; /**< [ 25: 25](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_PKO_SBE]. */
uint64_t txb_skid_m3_pko_dbe : 1; /**< [ 24: 24](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_PKO_DBE]. */
uint64_t txb_skid_m2_pko_sbe : 1; /**< [ 23: 23](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_PKO_SBE]. */
uint64_t txb_skid_m2_pko_dbe : 1; /**< [ 22: 22](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_PKO_DBE]. */
uint64_t txb_skid_m1_pko_sbe : 1; /**< [ 21: 21](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_PKO_SBE]. */
uint64_t txb_skid_m1_pko_dbe : 1; /**< [ 20: 20](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_PKO_DBE]. */
uint64_t smu_in_overfl : 1; /**< [ 19: 19](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[SMU_IN_OVERFL]. */
uint64_t gmp_in_overfl : 1; /**< [ 18: 18](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[GMP_IN_OVERFL]. */
uint64_t txb_skid_m0_pko_sbe : 1; /**< [ 17: 17](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_PKO_SBE]. */
uint64_t txb_skid_m0_pko_dbe : 1; /**< [ 16: 16](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_PKO_DBE]. */
uint64_t txb_fif_m1_sbe : 1; /**< [ 15: 15](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M1_SBE]. */
uint64_t txb_fif_m1_dbe : 1; /**< [ 14: 14](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M1_DBE]. */
uint64_t txb_fif_m0_sbe : 1; /**< [ 13: 13](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M0_SBE]. */
uint64_t txb_fif_m0_dbe : 1; /**< [ 12: 12](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M0_DBE]. */
uint64_t rxb_nic_skid_sbe : 1; /**< [ 11: 11](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[RXB_NIC_SKID_SBE]. */
uint64_t rxb_nic_skid_dbe : 1; /**< [ 10: 10](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[RXB_NIC_SKID_DBE]. */
uint64_t rxb_pki_skid_sbe : 1; /**< [ 9: 9](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[RXB_PKI_SKID_SBE]. */
uint64_t rxb_pki_skid_dbe : 1; /**< [ 8: 8](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[RXB_PKI_SKID_DBE]. */
uint64_t rxb_fif_bk1_sbe1 : 1; /**< [ 7: 7](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK1_SBE1]. */
uint64_t rxb_fif_bk1_dbe1 : 1; /**< [ 6: 6](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK1_DBE1]. */
uint64_t rxb_fif_bk1_sbe0 : 1; /**< [ 5: 5](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK1_SBE0]. */
uint64_t rxb_fif_bk1_dbe0 : 1; /**< [ 4: 4](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK1_DBE0]. */
uint64_t rxb_fif_bk0_sbe1 : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK0_SBE1]. */
uint64_t rxb_fif_bk0_dbe1 : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK0_DBE1]. */
uint64_t rxb_fif_bk0_sbe0 : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK0_SBE0]. */
uint64_t rxb_fif_bk0_dbe0 : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK0_DBE0]. */
#else /* Word 0 - Little Endian */
uint64_t rxb_fif_bk0_dbe0 : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK0_DBE0]. */
uint64_t rxb_fif_bk0_sbe0 : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK0_SBE0]. */
uint64_t rxb_fif_bk0_dbe1 : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK0_DBE1]. */
uint64_t rxb_fif_bk0_sbe1 : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK0_SBE1]. */
uint64_t rxb_fif_bk1_dbe0 : 1; /**< [ 4: 4](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK1_DBE0]. */
uint64_t rxb_fif_bk1_sbe0 : 1; /**< [ 5: 5](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK1_SBE0]. */
uint64_t rxb_fif_bk1_dbe1 : 1; /**< [ 6: 6](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK1_DBE1]. */
uint64_t rxb_fif_bk1_sbe1 : 1; /**< [ 7: 7](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK1_SBE1]. */
uint64_t rxb_pki_skid_dbe : 1; /**< [ 8: 8](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[RXB_PKI_SKID_DBE]. */
uint64_t rxb_pki_skid_sbe : 1; /**< [ 9: 9](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[RXB_PKI_SKID_SBE]. */
uint64_t rxb_nic_skid_dbe : 1; /**< [ 10: 10](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[RXB_NIC_SKID_DBE]. */
uint64_t rxb_nic_skid_sbe : 1; /**< [ 11: 11](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[RXB_NIC_SKID_SBE]. */
uint64_t txb_fif_m0_dbe : 1; /**< [ 12: 12](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M0_DBE]. */
uint64_t txb_fif_m0_sbe : 1; /**< [ 13: 13](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M0_SBE]. */
uint64_t txb_fif_m1_dbe : 1; /**< [ 14: 14](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M1_DBE]. */
uint64_t txb_fif_m1_sbe : 1; /**< [ 15: 15](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M1_SBE]. */
uint64_t txb_skid_m0_pko_dbe : 1; /**< [ 16: 16](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_PKO_DBE]. */
uint64_t txb_skid_m0_pko_sbe : 1; /**< [ 17: 17](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_PKO_SBE]. */
uint64_t gmp_in_overfl : 1; /**< [ 18: 18](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[GMP_IN_OVERFL]. */
uint64_t smu_in_overfl : 1; /**< [ 19: 19](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[SMU_IN_OVERFL]. */
uint64_t txb_skid_m1_pko_dbe : 1; /**< [ 20: 20](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_PKO_DBE]. */
uint64_t txb_skid_m1_pko_sbe : 1; /**< [ 21: 21](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_PKO_SBE]. */
uint64_t txb_skid_m2_pko_dbe : 1; /**< [ 22: 22](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_PKO_DBE]. */
uint64_t txb_skid_m2_pko_sbe : 1; /**< [ 23: 23](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_PKO_SBE]. */
uint64_t txb_skid_m3_pko_dbe : 1; /**< [ 24: 24](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_PKO_DBE]. */
uint64_t txb_skid_m3_pko_sbe : 1; /**< [ 25: 25](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_PKO_SBE]. */
uint64_t txb_ncsi_dbe : 1; /**< [ 26: 26](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_NCSI_DBE]. */
uint64_t txb_ncsi_sbe : 1; /**< [ 27: 27](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_NCSI_SBE]. */
uint64_t txb_skid_m0_nic_dbe : 1; /**< [ 28: 28](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_NIC_DBE]. */
uint64_t txb_skid_m0_nic_sbe : 1; /**< [ 29: 29](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_NIC_SBE]. */
uint64_t txb_skid_m1_nic_dbe : 1; /**< [ 30: 30](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_NIC_DBE]. */
uint64_t txb_skid_m1_nic_sbe : 1; /**< [ 31: 31](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_NIC_SBE]. */
uint64_t txb_skid_m2_nic_dbe : 1; /**< [ 32: 32](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_NIC_DBE]. */
uint64_t txb_skid_m2_nic_sbe : 1; /**< [ 33: 33](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_NIC_SBE]. */
uint64_t txb_skid_m3_nic_dbe : 1; /**< [ 34: 34](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_NIC_DBE]. */
uint64_t txb_skid_m3_nic_sbe : 1; /**< [ 35: 35](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_NIC_SBE]. */
uint64_t txb_fif_m2_dbe : 1; /**< [ 36: 36](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M2_DBE]. */
uint64_t txb_fif_m2_sbe : 1; /**< [ 37: 37](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M2_SBE]. */
uint64_t txb_fif_m3_dbe : 1; /**< [ 38: 38](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M3_DBE]. */
uint64_t txb_fif_m3_sbe : 1; /**< [ 39: 39](R/W1C/H) Reads or clears enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M3_SBE]. */
uint64_t reserved_40_63 : 24;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_cmr_mem_int_ena_w1c bdk_bgxx_cmr_mem_int_ena_w1c_t;
static inline uint64_t BDK_BGXX_CMR_MEM_INT_ENA_W1C(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMR_MEM_INT_ENA_W1C(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e0000020ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e0000020ll + 0x1000000ll * ((a) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && (a<=1))
return 0x87e0e0000020ll + 0x1000000ll * ((a) & 0x1);
__bdk_csr_fatal("BGXX_CMR_MEM_INT_ENA_W1C", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_CMR_MEM_INT_ENA_W1C(a) bdk_bgxx_cmr_mem_int_ena_w1c_t
#define bustype_BDK_BGXX_CMR_MEM_INT_ENA_W1C(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMR_MEM_INT_ENA_W1C(a) "BGXX_CMR_MEM_INT_ENA_W1C"
#define device_bar_BDK_BGXX_CMR_MEM_INT_ENA_W1C(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMR_MEM_INT_ENA_W1C(a) (a)
#define arguments_BDK_BGXX_CMR_MEM_INT_ENA_W1C(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_cmr_mem_int_ena_w1s
*
* BGX CMR Memory Interrupt Enable Set Register
* This register sets interrupt enable bits.
*/
union bdk_bgxx_cmr_mem_int_ena_w1s
{
uint64_t u;
struct bdk_bgxx_cmr_mem_int_ena_w1s_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_40_63 : 24;
uint64_t txb_fif_m3_sbe : 1; /**< [ 39: 39](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M3_SBE]. */
uint64_t txb_fif_m3_dbe : 1; /**< [ 38: 38](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M3_DBE]. */
uint64_t txb_fif_m2_sbe : 1; /**< [ 37: 37](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M2_SBE]. */
uint64_t txb_fif_m2_dbe : 1; /**< [ 36: 36](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M2_DBE]. */
uint64_t txb_skid_m3_nic_sbe : 1; /**< [ 35: 35](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_NIC_SBE]. */
uint64_t txb_skid_m3_nic_dbe : 1; /**< [ 34: 34](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_NIC_DBE]. */
uint64_t txb_skid_m2_nic_sbe : 1; /**< [ 33: 33](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_NIC_SBE]. */
uint64_t txb_skid_m2_nic_dbe : 1; /**< [ 32: 32](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_NIC_DBE]. */
uint64_t txb_skid_m1_nic_sbe : 1; /**< [ 31: 31](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_NIC_SBE]. */
uint64_t txb_skid_m1_nic_dbe : 1; /**< [ 30: 30](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_NIC_DBE]. */
uint64_t txb_skid_m0_nic_sbe : 1; /**< [ 29: 29](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_NIC_SBE]. */
uint64_t txb_skid_m0_nic_dbe : 1; /**< [ 28: 28](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_NIC_DBE]. */
uint64_t reserved_20_27 : 8;
uint64_t txb_skid_m1_sbe : 1; /**< [ 19: 19](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_SBE]. */
uint64_t txb_skid_m1_dbe : 1; /**< [ 18: 18](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_DBE]. */
uint64_t reserved_8_17 : 10;
uint64_t rxb_fif_bk1_sbe1 : 1; /**< [ 7: 7](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE1]. */
uint64_t rxb_fif_bk1_dbe1 : 1; /**< [ 6: 6](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE1]. */
uint64_t rxb_fif_bk1_sbe0 : 1; /**< [ 5: 5](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE0]. */
uint64_t rxb_fif_bk1_dbe0 : 1; /**< [ 4: 4](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE0]. */
uint64_t rxb_fif_bk0_sbe1 : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE1]. */
uint64_t rxb_fif_bk0_dbe1 : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE1]. */
uint64_t rxb_fif_bk0_sbe0 : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE0]. */
uint64_t rxb_fif_bk0_dbe0 : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE0]. */
#else /* Word 0 - Little Endian */
uint64_t rxb_fif_bk0_dbe0 : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE0]. */
uint64_t rxb_fif_bk0_sbe0 : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE0]. */
uint64_t rxb_fif_bk0_dbe1 : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE1]. */
uint64_t rxb_fif_bk0_sbe1 : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE1]. */
uint64_t rxb_fif_bk1_dbe0 : 1; /**< [ 4: 4](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE0]. */
uint64_t rxb_fif_bk1_sbe0 : 1; /**< [ 5: 5](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE0]. */
uint64_t rxb_fif_bk1_dbe1 : 1; /**< [ 6: 6](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE1]. */
uint64_t rxb_fif_bk1_sbe1 : 1; /**< [ 7: 7](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE1]. */
uint64_t reserved_8_17 : 10;
uint64_t txb_skid_m1_dbe : 1; /**< [ 18: 18](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_DBE]. */
uint64_t txb_skid_m1_sbe : 1; /**< [ 19: 19](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_SBE]. */
uint64_t reserved_20_27 : 8;
uint64_t txb_skid_m0_nic_dbe : 1; /**< [ 28: 28](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_NIC_DBE]. */
uint64_t txb_skid_m0_nic_sbe : 1; /**< [ 29: 29](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_NIC_SBE]. */
uint64_t txb_skid_m1_nic_dbe : 1; /**< [ 30: 30](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_NIC_DBE]. */
uint64_t txb_skid_m1_nic_sbe : 1; /**< [ 31: 31](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_NIC_SBE]. */
uint64_t txb_skid_m2_nic_dbe : 1; /**< [ 32: 32](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_NIC_DBE]. */
uint64_t txb_skid_m2_nic_sbe : 1; /**< [ 33: 33](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_NIC_SBE]. */
uint64_t txb_skid_m3_nic_dbe : 1; /**< [ 34: 34](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_NIC_DBE]. */
uint64_t txb_skid_m3_nic_sbe : 1; /**< [ 35: 35](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_NIC_SBE]. */
uint64_t txb_fif_m2_dbe : 1; /**< [ 36: 36](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M2_DBE]. */
uint64_t txb_fif_m2_sbe : 1; /**< [ 37: 37](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M2_SBE]. */
uint64_t txb_fif_m3_dbe : 1; /**< [ 38: 38](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M3_DBE]. */
uint64_t txb_fif_m3_sbe : 1; /**< [ 39: 39](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M3_SBE]. */
uint64_t reserved_40_63 : 24;
#endif /* Word 0 - End */
} s;
struct bdk_bgxx_cmr_mem_int_ena_w1s_cn81xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_36_63 : 28;
uint64_t txb_skid_m3_nic_sbe : 1; /**< [ 35: 35](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_NIC_SBE]. */
uint64_t txb_skid_m3_nic_dbe : 1; /**< [ 34: 34](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_NIC_DBE]. */
uint64_t txb_skid_m2_nic_sbe : 1; /**< [ 33: 33](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_NIC_SBE]. */
uint64_t txb_skid_m2_nic_dbe : 1; /**< [ 32: 32](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_NIC_DBE]. */
uint64_t txb_skid_m1_nic_sbe : 1; /**< [ 31: 31](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_NIC_SBE]. */
uint64_t txb_skid_m1_nic_dbe : 1; /**< [ 30: 30](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_NIC_DBE]. */
uint64_t txb_skid_m0_nic_sbe : 1; /**< [ 29: 29](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_NIC_SBE]. */
uint64_t txb_skid_m0_nic_dbe : 1; /**< [ 28: 28](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_NIC_DBE]. */
uint64_t txb_ncsi_sbe : 1; /**< [ 27: 27](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_NCSI_SBE]. */
uint64_t txb_ncsi_dbe : 1; /**< [ 26: 26](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_NCSI_DBE]. */
uint64_t txb_skid_m3_pko_sbe : 1; /**< [ 25: 25](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_PKO_SBE]. */
uint64_t txb_skid_m3_pko_dbe : 1; /**< [ 24: 24](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_PKO_DBE]. */
uint64_t txb_skid_m2_pko_sbe : 1; /**< [ 23: 23](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_PKO_SBE]. */
uint64_t txb_skid_m2_pko_dbe : 1; /**< [ 22: 22](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_PKO_DBE]. */
uint64_t txb_skid_m1_pko_sbe : 1; /**< [ 21: 21](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_PKO_SBE]. */
uint64_t txb_skid_m1_pko_dbe : 1; /**< [ 20: 20](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_PKO_DBE]. */
uint64_t smu_in_overfl : 1; /**< [ 19: 19](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[SMU_IN_OVERFL]. */
uint64_t gmp_in_overfl : 1; /**< [ 18: 18](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[GMP_IN_OVERFL]. */
uint64_t txb_skid_m0_pko_sbe : 1; /**< [ 17: 17](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_PKO_SBE]. */
uint64_t txb_skid_m0_pko_dbe : 1; /**< [ 16: 16](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_PKO_DBE]. */
uint64_t txb_fif_bk1_sbe : 1; /**< [ 15: 15](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK1_SBE]. */
uint64_t txb_fif_bk1_dbe : 1; /**< [ 14: 14](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK1_DBE]. */
uint64_t txb_fif_bk0_sbe : 1; /**< [ 13: 13](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK0_SBE]. */
uint64_t txb_fif_bk0_dbe : 1; /**< [ 12: 12](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK0_DBE]. */
uint64_t rxb_nic_skid_sbe : 1; /**< [ 11: 11](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_NIC_SKID_SBE]. */
uint64_t rxb_nic_skid_dbe : 1; /**< [ 10: 10](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_NIC_SKID_DBE]. */
uint64_t rxb_pki_skid_sbe : 1; /**< [ 9: 9](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_PKI_SKID_SBE]. */
uint64_t rxb_pki_skid_dbe : 1; /**< [ 8: 8](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_PKI_SKID_DBE]. */
uint64_t rxb_fif_bk1_sbe1 : 1; /**< [ 7: 7](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE1]. */
uint64_t rxb_fif_bk1_dbe1 : 1; /**< [ 6: 6](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE1]. */
uint64_t rxb_fif_bk1_sbe0 : 1; /**< [ 5: 5](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE0]. */
uint64_t rxb_fif_bk1_dbe0 : 1; /**< [ 4: 4](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE0]. */
uint64_t rxb_fif_bk0_sbe1 : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE1]. */
uint64_t rxb_fif_bk0_dbe1 : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE1]. */
uint64_t rxb_fif_bk0_sbe0 : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE0]. */
uint64_t rxb_fif_bk0_dbe0 : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE0]. */
#else /* Word 0 - Little Endian */
uint64_t rxb_fif_bk0_dbe0 : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE0]. */
uint64_t rxb_fif_bk0_sbe0 : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE0]. */
uint64_t rxb_fif_bk0_dbe1 : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE1]. */
uint64_t rxb_fif_bk0_sbe1 : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE1]. */
uint64_t rxb_fif_bk1_dbe0 : 1; /**< [ 4: 4](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE0]. */
uint64_t rxb_fif_bk1_sbe0 : 1; /**< [ 5: 5](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE0]. */
uint64_t rxb_fif_bk1_dbe1 : 1; /**< [ 6: 6](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE1]. */
uint64_t rxb_fif_bk1_sbe1 : 1; /**< [ 7: 7](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE1]. */
uint64_t rxb_pki_skid_dbe : 1; /**< [ 8: 8](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_PKI_SKID_DBE]. */
uint64_t rxb_pki_skid_sbe : 1; /**< [ 9: 9](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_PKI_SKID_SBE]. */
uint64_t rxb_nic_skid_dbe : 1; /**< [ 10: 10](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_NIC_SKID_DBE]. */
uint64_t rxb_nic_skid_sbe : 1; /**< [ 11: 11](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_NIC_SKID_SBE]. */
uint64_t txb_fif_bk0_dbe : 1; /**< [ 12: 12](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK0_DBE]. */
uint64_t txb_fif_bk0_sbe : 1; /**< [ 13: 13](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK0_SBE]. */
uint64_t txb_fif_bk1_dbe : 1; /**< [ 14: 14](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK1_DBE]. */
uint64_t txb_fif_bk1_sbe : 1; /**< [ 15: 15](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK1_SBE]. */
uint64_t txb_skid_m0_pko_dbe : 1; /**< [ 16: 16](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_PKO_DBE]. */
uint64_t txb_skid_m0_pko_sbe : 1; /**< [ 17: 17](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_PKO_SBE]. */
uint64_t gmp_in_overfl : 1; /**< [ 18: 18](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[GMP_IN_OVERFL]. */
uint64_t smu_in_overfl : 1; /**< [ 19: 19](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[SMU_IN_OVERFL]. */
uint64_t txb_skid_m1_pko_dbe : 1; /**< [ 20: 20](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_PKO_DBE]. */
uint64_t txb_skid_m1_pko_sbe : 1; /**< [ 21: 21](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_PKO_SBE]. */
uint64_t txb_skid_m2_pko_dbe : 1; /**< [ 22: 22](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_PKO_DBE]. */
uint64_t txb_skid_m2_pko_sbe : 1; /**< [ 23: 23](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_PKO_SBE]. */
uint64_t txb_skid_m3_pko_dbe : 1; /**< [ 24: 24](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_PKO_DBE]. */
uint64_t txb_skid_m3_pko_sbe : 1; /**< [ 25: 25](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_PKO_SBE]. */
uint64_t txb_ncsi_dbe : 1; /**< [ 26: 26](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_NCSI_DBE]. */
uint64_t txb_ncsi_sbe : 1; /**< [ 27: 27](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_NCSI_SBE]. */
uint64_t txb_skid_m0_nic_dbe : 1; /**< [ 28: 28](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_NIC_DBE]. */
uint64_t txb_skid_m0_nic_sbe : 1; /**< [ 29: 29](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_NIC_SBE]. */
uint64_t txb_skid_m1_nic_dbe : 1; /**< [ 30: 30](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_NIC_DBE]. */
uint64_t txb_skid_m1_nic_sbe : 1; /**< [ 31: 31](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_NIC_SBE]. */
uint64_t txb_skid_m2_nic_dbe : 1; /**< [ 32: 32](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_NIC_DBE]. */
uint64_t txb_skid_m2_nic_sbe : 1; /**< [ 33: 33](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_NIC_SBE]. */
uint64_t txb_skid_m3_nic_dbe : 1; /**< [ 34: 34](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_NIC_DBE]. */
uint64_t txb_skid_m3_nic_sbe : 1; /**< [ 35: 35](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_NIC_SBE]. */
uint64_t reserved_36_63 : 28;
#endif /* Word 0 - End */
} cn81xx;
struct bdk_bgxx_cmr_mem_int_ena_w1s_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_26_63 : 38;
uint64_t txb_ncsi_sbe : 1; /**< [ 25: 25](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_NCSI_SBE]. */
uint64_t txb_ncsi_dbe : 1; /**< [ 24: 24](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_NCSI_DBE]. */
uint64_t txb_skid_m3_sbe : 1; /**< [ 23: 23](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_SBE]. */
uint64_t txb_skid_m3_dbe : 1; /**< [ 22: 22](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_DBE]. */
uint64_t txb_skid_m2_sbe : 1; /**< [ 21: 21](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_SBE]. */
uint64_t txb_skid_m2_dbe : 1; /**< [ 20: 20](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_DBE]. */
uint64_t txb_skid_m1_sbe : 1; /**< [ 19: 19](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_SBE]. */
uint64_t txb_skid_m1_dbe : 1; /**< [ 18: 18](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_DBE]. */
uint64_t smu_in_overfl : 1; /**< [ 17: 17](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[SMU_IN_OVERFL]. */
uint64_t gmp_in_overfl : 1; /**< [ 16: 16](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[GMP_IN_OVERFL]. */
uint64_t txb_skid_m0_sbe : 1; /**< [ 15: 15](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_SBE]. */
uint64_t txb_skid_m0_dbe : 1; /**< [ 14: 14](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_DBE]. */
uint64_t txb_fif_bk1_sbe : 1; /**< [ 13: 13](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK1_SBE]. */
uint64_t txb_fif_bk1_dbe : 1; /**< [ 12: 12](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK1_DBE]. */
uint64_t txb_fif_bk0_sbe : 1; /**< [ 11: 11](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK0_SBE]. */
uint64_t txb_fif_bk0_dbe : 1; /**< [ 10: 10](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK0_DBE]. */
uint64_t rxb_skid_sbe : 1; /**< [ 9: 9](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_SKID_SBE]. */
uint64_t rxb_skid_dbe : 1; /**< [ 8: 8](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_SKID_DBE]. */
uint64_t rxb_fif_bk1_sbe1 : 1; /**< [ 7: 7](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE1]. */
uint64_t rxb_fif_bk1_dbe1 : 1; /**< [ 6: 6](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE1]. */
uint64_t rxb_fif_bk1_sbe0 : 1; /**< [ 5: 5](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE0]. */
uint64_t rxb_fif_bk1_dbe0 : 1; /**< [ 4: 4](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE0]. */
uint64_t rxb_fif_bk0_sbe1 : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE1]. */
uint64_t rxb_fif_bk0_dbe1 : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE1]. */
uint64_t rxb_fif_bk0_sbe0 : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE0]. */
uint64_t rxb_fif_bk0_dbe0 : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE0]. */
#else /* Word 0 - Little Endian */
uint64_t rxb_fif_bk0_dbe0 : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE0]. */
uint64_t rxb_fif_bk0_sbe0 : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE0]. */
uint64_t rxb_fif_bk0_dbe1 : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE1]. */
uint64_t rxb_fif_bk0_sbe1 : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE1]. */
uint64_t rxb_fif_bk1_dbe0 : 1; /**< [ 4: 4](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE0]. */
uint64_t rxb_fif_bk1_sbe0 : 1; /**< [ 5: 5](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE0]. */
uint64_t rxb_fif_bk1_dbe1 : 1; /**< [ 6: 6](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE1]. */
uint64_t rxb_fif_bk1_sbe1 : 1; /**< [ 7: 7](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE1]. */
uint64_t rxb_skid_dbe : 1; /**< [ 8: 8](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_SKID_DBE]. */
uint64_t rxb_skid_sbe : 1; /**< [ 9: 9](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[RXB_SKID_SBE]. */
uint64_t txb_fif_bk0_dbe : 1; /**< [ 10: 10](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK0_DBE]. */
uint64_t txb_fif_bk0_sbe : 1; /**< [ 11: 11](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK0_SBE]. */
uint64_t txb_fif_bk1_dbe : 1; /**< [ 12: 12](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK1_DBE]. */
uint64_t txb_fif_bk1_sbe : 1; /**< [ 13: 13](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK1_SBE]. */
uint64_t txb_skid_m0_dbe : 1; /**< [ 14: 14](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_DBE]. */
uint64_t txb_skid_m0_sbe : 1; /**< [ 15: 15](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_SBE]. */
uint64_t gmp_in_overfl : 1; /**< [ 16: 16](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[GMP_IN_OVERFL]. */
uint64_t smu_in_overfl : 1; /**< [ 17: 17](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[SMU_IN_OVERFL]. */
uint64_t txb_skid_m1_dbe : 1; /**< [ 18: 18](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_DBE]. */
uint64_t txb_skid_m1_sbe : 1; /**< [ 19: 19](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_SBE]. */
uint64_t txb_skid_m2_dbe : 1; /**< [ 20: 20](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_DBE]. */
uint64_t txb_skid_m2_sbe : 1; /**< [ 21: 21](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_SBE]. */
uint64_t txb_skid_m3_dbe : 1; /**< [ 22: 22](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_DBE]. */
uint64_t txb_skid_m3_sbe : 1; /**< [ 23: 23](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_SBE]. */
uint64_t txb_ncsi_dbe : 1; /**< [ 24: 24](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_NCSI_DBE]. */
uint64_t txb_ncsi_sbe : 1; /**< [ 25: 25](R/W1S/H) Reads or sets enable for BGX(0..1)_CMR_MEM_INT[TXB_NCSI_SBE]. */
uint64_t reserved_26_63 : 38;
#endif /* Word 0 - End */
} cn88xx;
struct bdk_bgxx_cmr_mem_int_ena_w1s_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_40_63 : 24;
uint64_t txb_fif_m3_sbe : 1; /**< [ 39: 39](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M3_SBE]. */
uint64_t txb_fif_m3_dbe : 1; /**< [ 38: 38](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M3_DBE]. */
uint64_t txb_fif_m2_sbe : 1; /**< [ 37: 37](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M2_SBE]. */
uint64_t txb_fif_m2_dbe : 1; /**< [ 36: 36](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M2_DBE]. */
uint64_t txb_skid_m3_nic_sbe : 1; /**< [ 35: 35](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_NIC_SBE]. */
uint64_t txb_skid_m3_nic_dbe : 1; /**< [ 34: 34](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_NIC_DBE]. */
uint64_t txb_skid_m2_nic_sbe : 1; /**< [ 33: 33](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_NIC_SBE]. */
uint64_t txb_skid_m2_nic_dbe : 1; /**< [ 32: 32](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_NIC_DBE]. */
uint64_t txb_skid_m1_nic_sbe : 1; /**< [ 31: 31](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_NIC_SBE]. */
uint64_t txb_skid_m1_nic_dbe : 1; /**< [ 30: 30](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_NIC_DBE]. */
uint64_t txb_skid_m0_nic_sbe : 1; /**< [ 29: 29](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_NIC_SBE]. */
uint64_t txb_skid_m0_nic_dbe : 1; /**< [ 28: 28](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_NIC_DBE]. */
uint64_t txb_ncsi_sbe : 1; /**< [ 27: 27](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_NCSI_SBE]. */
uint64_t txb_ncsi_dbe : 1; /**< [ 26: 26](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_NCSI_DBE]. */
uint64_t txb_skid_m3_pko_sbe : 1; /**< [ 25: 25](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_PKO_SBE]. */
uint64_t txb_skid_m3_pko_dbe : 1; /**< [ 24: 24](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_PKO_DBE]. */
uint64_t txb_skid_m2_pko_sbe : 1; /**< [ 23: 23](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_PKO_SBE]. */
uint64_t txb_skid_m2_pko_dbe : 1; /**< [ 22: 22](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_PKO_DBE]. */
uint64_t txb_skid_m1_pko_sbe : 1; /**< [ 21: 21](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_PKO_SBE]. */
uint64_t txb_skid_m1_pko_dbe : 1; /**< [ 20: 20](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_PKO_DBE]. */
uint64_t smu_in_overfl : 1; /**< [ 19: 19](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[SMU_IN_OVERFL]. */
uint64_t gmp_in_overfl : 1; /**< [ 18: 18](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[GMP_IN_OVERFL]. */
uint64_t txb_skid_m0_pko_sbe : 1; /**< [ 17: 17](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_PKO_SBE]. */
uint64_t txb_skid_m0_pko_dbe : 1; /**< [ 16: 16](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_PKO_DBE]. */
uint64_t txb_fif_m1_sbe : 1; /**< [ 15: 15](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M1_SBE]. */
uint64_t txb_fif_m1_dbe : 1; /**< [ 14: 14](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M1_DBE]. */
uint64_t txb_fif_m0_sbe : 1; /**< [ 13: 13](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M0_SBE]. */
uint64_t txb_fif_m0_dbe : 1; /**< [ 12: 12](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M0_DBE]. */
uint64_t rxb_nic_skid_sbe : 1; /**< [ 11: 11](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[RXB_NIC_SKID_SBE]. */
uint64_t rxb_nic_skid_dbe : 1; /**< [ 10: 10](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[RXB_NIC_SKID_DBE]. */
uint64_t rxb_pki_skid_sbe : 1; /**< [ 9: 9](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[RXB_PKI_SKID_SBE]. */
uint64_t rxb_pki_skid_dbe : 1; /**< [ 8: 8](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[RXB_PKI_SKID_DBE]. */
uint64_t rxb_fif_bk1_sbe1 : 1; /**< [ 7: 7](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK1_SBE1]. */
uint64_t rxb_fif_bk1_dbe1 : 1; /**< [ 6: 6](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK1_DBE1]. */
uint64_t rxb_fif_bk1_sbe0 : 1; /**< [ 5: 5](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK1_SBE0]. */
uint64_t rxb_fif_bk1_dbe0 : 1; /**< [ 4: 4](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK1_DBE0]. */
uint64_t rxb_fif_bk0_sbe1 : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK0_SBE1]. */
uint64_t rxb_fif_bk0_dbe1 : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK0_DBE1]. */
uint64_t rxb_fif_bk0_sbe0 : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK0_SBE0]. */
uint64_t rxb_fif_bk0_dbe0 : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK0_DBE0]. */
#else /* Word 0 - Little Endian */
uint64_t rxb_fif_bk0_dbe0 : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK0_DBE0]. */
uint64_t rxb_fif_bk0_sbe0 : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK0_SBE0]. */
uint64_t rxb_fif_bk0_dbe1 : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK0_DBE1]. */
uint64_t rxb_fif_bk0_sbe1 : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK0_SBE1]. */
uint64_t rxb_fif_bk1_dbe0 : 1; /**< [ 4: 4](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK1_DBE0]. */
uint64_t rxb_fif_bk1_sbe0 : 1; /**< [ 5: 5](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK1_SBE0]. */
uint64_t rxb_fif_bk1_dbe1 : 1; /**< [ 6: 6](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK1_DBE1]. */
uint64_t rxb_fif_bk1_sbe1 : 1; /**< [ 7: 7](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK1_SBE1]. */
uint64_t rxb_pki_skid_dbe : 1; /**< [ 8: 8](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[RXB_PKI_SKID_DBE]. */
uint64_t rxb_pki_skid_sbe : 1; /**< [ 9: 9](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[RXB_PKI_SKID_SBE]. */
uint64_t rxb_nic_skid_dbe : 1; /**< [ 10: 10](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[RXB_NIC_SKID_DBE]. */
uint64_t rxb_nic_skid_sbe : 1; /**< [ 11: 11](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[RXB_NIC_SKID_SBE]. */
uint64_t txb_fif_m0_dbe : 1; /**< [ 12: 12](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M0_DBE]. */
uint64_t txb_fif_m0_sbe : 1; /**< [ 13: 13](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M0_SBE]. */
uint64_t txb_fif_m1_dbe : 1; /**< [ 14: 14](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M1_DBE]. */
uint64_t txb_fif_m1_sbe : 1; /**< [ 15: 15](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M1_SBE]. */
uint64_t txb_skid_m0_pko_dbe : 1; /**< [ 16: 16](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_PKO_DBE]. */
uint64_t txb_skid_m0_pko_sbe : 1; /**< [ 17: 17](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_PKO_SBE]. */
uint64_t gmp_in_overfl : 1; /**< [ 18: 18](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[GMP_IN_OVERFL]. */
uint64_t smu_in_overfl : 1; /**< [ 19: 19](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[SMU_IN_OVERFL]. */
uint64_t txb_skid_m1_pko_dbe : 1; /**< [ 20: 20](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_PKO_DBE]. */
uint64_t txb_skid_m1_pko_sbe : 1; /**< [ 21: 21](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_PKO_SBE]. */
uint64_t txb_skid_m2_pko_dbe : 1; /**< [ 22: 22](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_PKO_DBE]. */
uint64_t txb_skid_m2_pko_sbe : 1; /**< [ 23: 23](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_PKO_SBE]. */
uint64_t txb_skid_m3_pko_dbe : 1; /**< [ 24: 24](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_PKO_DBE]. */
uint64_t txb_skid_m3_pko_sbe : 1; /**< [ 25: 25](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_PKO_SBE]. */
uint64_t txb_ncsi_dbe : 1; /**< [ 26: 26](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_NCSI_DBE]. */
uint64_t txb_ncsi_sbe : 1; /**< [ 27: 27](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_NCSI_SBE]. */
uint64_t txb_skid_m0_nic_dbe : 1; /**< [ 28: 28](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_NIC_DBE]. */
uint64_t txb_skid_m0_nic_sbe : 1; /**< [ 29: 29](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_NIC_SBE]. */
uint64_t txb_skid_m1_nic_dbe : 1; /**< [ 30: 30](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_NIC_DBE]. */
uint64_t txb_skid_m1_nic_sbe : 1; /**< [ 31: 31](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_NIC_SBE]. */
uint64_t txb_skid_m2_nic_dbe : 1; /**< [ 32: 32](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_NIC_DBE]. */
uint64_t txb_skid_m2_nic_sbe : 1; /**< [ 33: 33](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_NIC_SBE]. */
uint64_t txb_skid_m3_nic_dbe : 1; /**< [ 34: 34](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_NIC_DBE]. */
uint64_t txb_skid_m3_nic_sbe : 1; /**< [ 35: 35](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_NIC_SBE]. */
uint64_t txb_fif_m2_dbe : 1; /**< [ 36: 36](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M2_DBE]. */
uint64_t txb_fif_m2_sbe : 1; /**< [ 37: 37](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M2_SBE]. */
uint64_t txb_fif_m3_dbe : 1; /**< [ 38: 38](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M3_DBE]. */
uint64_t txb_fif_m3_sbe : 1; /**< [ 39: 39](R/W1S/H) Reads or sets enable for BGX(0..3)_CMR_MEM_INT[TXB_FIF_M3_SBE]. */
uint64_t reserved_40_63 : 24;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_cmr_mem_int_ena_w1s bdk_bgxx_cmr_mem_int_ena_w1s_t;
static inline uint64_t BDK_BGXX_CMR_MEM_INT_ENA_W1S(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMR_MEM_INT_ENA_W1S(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e0000028ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e0000028ll + 0x1000000ll * ((a) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && (a<=1))
return 0x87e0e0000028ll + 0x1000000ll * ((a) & 0x1);
__bdk_csr_fatal("BGXX_CMR_MEM_INT_ENA_W1S", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_CMR_MEM_INT_ENA_W1S(a) bdk_bgxx_cmr_mem_int_ena_w1s_t
#define bustype_BDK_BGXX_CMR_MEM_INT_ENA_W1S(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMR_MEM_INT_ENA_W1S(a) "BGXX_CMR_MEM_INT_ENA_W1S"
#define device_bar_BDK_BGXX_CMR_MEM_INT_ENA_W1S(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMR_MEM_INT_ENA_W1S(a) (a)
#define arguments_BDK_BGXX_CMR_MEM_INT_ENA_W1S(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_cmr_mem_int_w1s
*
* BGX CMR Memory Interrupt Set Register
* This register sets interrupt bits.
*/
union bdk_bgxx_cmr_mem_int_w1s
{
uint64_t u;
struct bdk_bgxx_cmr_mem_int_w1s_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_40_63 : 24;
uint64_t txb_fif_m3_sbe : 1; /**< [ 39: 39](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_FIF_M3_SBE]. */
uint64_t txb_fif_m3_dbe : 1; /**< [ 38: 38](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_FIF_M3_DBE]. */
uint64_t txb_fif_m2_sbe : 1; /**< [ 37: 37](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_FIF_M2_SBE]. */
uint64_t txb_fif_m2_dbe : 1; /**< [ 36: 36](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_FIF_M2_DBE]. */
uint64_t txb_skid_m3_nic_sbe : 1; /**< [ 35: 35](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_NIC_SBE]. */
uint64_t txb_skid_m3_nic_dbe : 1; /**< [ 34: 34](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_NIC_DBE]. */
uint64_t txb_skid_m2_nic_sbe : 1; /**< [ 33: 33](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_NIC_SBE]. */
uint64_t txb_skid_m2_nic_dbe : 1; /**< [ 32: 32](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_NIC_DBE]. */
uint64_t txb_skid_m1_nic_sbe : 1; /**< [ 31: 31](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_NIC_SBE]. */
uint64_t txb_skid_m1_nic_dbe : 1; /**< [ 30: 30](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_NIC_DBE]. */
uint64_t txb_skid_m0_nic_sbe : 1; /**< [ 29: 29](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_NIC_SBE]. */
uint64_t txb_skid_m0_nic_dbe : 1; /**< [ 28: 28](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_NIC_DBE]. */
uint64_t reserved_20_27 : 8;
uint64_t txb_skid_m1_sbe : 1; /**< [ 19: 19](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_SBE]. */
uint64_t txb_skid_m1_dbe : 1; /**< [ 18: 18](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_DBE]. */
uint64_t reserved_8_17 : 10;
uint64_t rxb_fif_bk1_sbe1 : 1; /**< [ 7: 7](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE1]. */
uint64_t rxb_fif_bk1_dbe1 : 1; /**< [ 6: 6](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE1]. */
uint64_t rxb_fif_bk1_sbe0 : 1; /**< [ 5: 5](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE0]. */
uint64_t rxb_fif_bk1_dbe0 : 1; /**< [ 4: 4](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE0]. */
uint64_t rxb_fif_bk0_sbe1 : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE1]. */
uint64_t rxb_fif_bk0_dbe1 : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE1]. */
uint64_t rxb_fif_bk0_sbe0 : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE0]. */
uint64_t rxb_fif_bk0_dbe0 : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE0]. */
#else /* Word 0 - Little Endian */
uint64_t rxb_fif_bk0_dbe0 : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE0]. */
uint64_t rxb_fif_bk0_sbe0 : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE0]. */
uint64_t rxb_fif_bk0_dbe1 : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE1]. */
uint64_t rxb_fif_bk0_sbe1 : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE1]. */
uint64_t rxb_fif_bk1_dbe0 : 1; /**< [ 4: 4](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE0]. */
uint64_t rxb_fif_bk1_sbe0 : 1; /**< [ 5: 5](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE0]. */
uint64_t rxb_fif_bk1_dbe1 : 1; /**< [ 6: 6](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE1]. */
uint64_t rxb_fif_bk1_sbe1 : 1; /**< [ 7: 7](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE1]. */
uint64_t reserved_8_17 : 10;
uint64_t txb_skid_m1_dbe : 1; /**< [ 18: 18](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_DBE]. */
uint64_t txb_skid_m1_sbe : 1; /**< [ 19: 19](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_SBE]. */
uint64_t reserved_20_27 : 8;
uint64_t txb_skid_m0_nic_dbe : 1; /**< [ 28: 28](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_NIC_DBE]. */
uint64_t txb_skid_m0_nic_sbe : 1; /**< [ 29: 29](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_NIC_SBE]. */
uint64_t txb_skid_m1_nic_dbe : 1; /**< [ 30: 30](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_NIC_DBE]. */
uint64_t txb_skid_m1_nic_sbe : 1; /**< [ 31: 31](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_NIC_SBE]. */
uint64_t txb_skid_m2_nic_dbe : 1; /**< [ 32: 32](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_NIC_DBE]. */
uint64_t txb_skid_m2_nic_sbe : 1; /**< [ 33: 33](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_NIC_SBE]. */
uint64_t txb_skid_m3_nic_dbe : 1; /**< [ 34: 34](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_NIC_DBE]. */
uint64_t txb_skid_m3_nic_sbe : 1; /**< [ 35: 35](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_NIC_SBE]. */
uint64_t txb_fif_m2_dbe : 1; /**< [ 36: 36](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_FIF_M2_DBE]. */
uint64_t txb_fif_m2_sbe : 1; /**< [ 37: 37](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_FIF_M2_SBE]. */
uint64_t txb_fif_m3_dbe : 1; /**< [ 38: 38](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_FIF_M3_DBE]. */
uint64_t txb_fif_m3_sbe : 1; /**< [ 39: 39](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_FIF_M3_SBE]. */
uint64_t reserved_40_63 : 24;
#endif /* Word 0 - End */
} s;
struct bdk_bgxx_cmr_mem_int_w1s_cn81xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_36_63 : 28;
uint64_t txb_skid_m3_nic_sbe : 1; /**< [ 35: 35](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_NIC_SBE]. */
uint64_t txb_skid_m3_nic_dbe : 1; /**< [ 34: 34](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_NIC_DBE]. */
uint64_t txb_skid_m2_nic_sbe : 1; /**< [ 33: 33](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_NIC_SBE]. */
uint64_t txb_skid_m2_nic_dbe : 1; /**< [ 32: 32](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_NIC_DBE]. */
uint64_t txb_skid_m1_nic_sbe : 1; /**< [ 31: 31](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_NIC_SBE]. */
uint64_t txb_skid_m1_nic_dbe : 1; /**< [ 30: 30](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_NIC_DBE]. */
uint64_t txb_skid_m0_nic_sbe : 1; /**< [ 29: 29](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_NIC_SBE]. */
uint64_t txb_skid_m0_nic_dbe : 1; /**< [ 28: 28](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_NIC_DBE]. */
uint64_t txb_ncsi_sbe : 1; /**< [ 27: 27](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_NCSI_SBE]. */
uint64_t txb_ncsi_dbe : 1; /**< [ 26: 26](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_NCSI_DBE]. */
uint64_t txb_skid_m3_pko_sbe : 1; /**< [ 25: 25](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_PKO_SBE]. */
uint64_t txb_skid_m3_pko_dbe : 1; /**< [ 24: 24](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_PKO_DBE]. */
uint64_t txb_skid_m2_pko_sbe : 1; /**< [ 23: 23](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_PKO_SBE]. */
uint64_t txb_skid_m2_pko_dbe : 1; /**< [ 22: 22](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_PKO_DBE]. */
uint64_t txb_skid_m1_pko_sbe : 1; /**< [ 21: 21](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_PKO_SBE]. */
uint64_t txb_skid_m1_pko_dbe : 1; /**< [ 20: 20](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_PKO_DBE]. */
uint64_t smu_in_overfl : 1; /**< [ 19: 19](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[SMU_IN_OVERFL]. */
uint64_t gmp_in_overfl : 1; /**< [ 18: 18](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[GMP_IN_OVERFL]. */
uint64_t txb_skid_m0_pko_sbe : 1; /**< [ 17: 17](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_PKO_SBE]. */
uint64_t txb_skid_m0_pko_dbe : 1; /**< [ 16: 16](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_PKO_DBE]. */
uint64_t txb_fif_bk1_sbe : 1; /**< [ 15: 15](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK1_SBE]. */
uint64_t txb_fif_bk1_dbe : 1; /**< [ 14: 14](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK1_DBE]. */
uint64_t txb_fif_bk0_sbe : 1; /**< [ 13: 13](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK0_SBE]. */
uint64_t txb_fif_bk0_dbe : 1; /**< [ 12: 12](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK0_DBE]. */
uint64_t rxb_nic_skid_sbe : 1; /**< [ 11: 11](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_NIC_SKID_SBE]. */
uint64_t rxb_nic_skid_dbe : 1; /**< [ 10: 10](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_NIC_SKID_DBE]. */
uint64_t rxb_pki_skid_sbe : 1; /**< [ 9: 9](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_PKI_SKID_SBE]. */
uint64_t rxb_pki_skid_dbe : 1; /**< [ 8: 8](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_PKI_SKID_DBE]. */
uint64_t rxb_fif_bk1_sbe1 : 1; /**< [ 7: 7](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE1]. */
uint64_t rxb_fif_bk1_dbe1 : 1; /**< [ 6: 6](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE1]. */
uint64_t rxb_fif_bk1_sbe0 : 1; /**< [ 5: 5](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE0]. */
uint64_t rxb_fif_bk1_dbe0 : 1; /**< [ 4: 4](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE0]. */
uint64_t rxb_fif_bk0_sbe1 : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE1]. */
uint64_t rxb_fif_bk0_dbe1 : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE1]. */
uint64_t rxb_fif_bk0_sbe0 : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE0]. */
uint64_t rxb_fif_bk0_dbe0 : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE0]. */
#else /* Word 0 - Little Endian */
uint64_t rxb_fif_bk0_dbe0 : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE0]. */
uint64_t rxb_fif_bk0_sbe0 : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE0]. */
uint64_t rxb_fif_bk0_dbe1 : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE1]. */
uint64_t rxb_fif_bk0_sbe1 : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE1]. */
uint64_t rxb_fif_bk1_dbe0 : 1; /**< [ 4: 4](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE0]. */
uint64_t rxb_fif_bk1_sbe0 : 1; /**< [ 5: 5](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE0]. */
uint64_t rxb_fif_bk1_dbe1 : 1; /**< [ 6: 6](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE1]. */
uint64_t rxb_fif_bk1_sbe1 : 1; /**< [ 7: 7](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE1]. */
uint64_t rxb_pki_skid_dbe : 1; /**< [ 8: 8](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_PKI_SKID_DBE]. */
uint64_t rxb_pki_skid_sbe : 1; /**< [ 9: 9](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_PKI_SKID_SBE]. */
uint64_t rxb_nic_skid_dbe : 1; /**< [ 10: 10](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_NIC_SKID_DBE]. */
uint64_t rxb_nic_skid_sbe : 1; /**< [ 11: 11](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_NIC_SKID_SBE]. */
uint64_t txb_fif_bk0_dbe : 1; /**< [ 12: 12](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK0_DBE]. */
uint64_t txb_fif_bk0_sbe : 1; /**< [ 13: 13](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK0_SBE]. */
uint64_t txb_fif_bk1_dbe : 1; /**< [ 14: 14](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK1_DBE]. */
uint64_t txb_fif_bk1_sbe : 1; /**< [ 15: 15](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK1_SBE]. */
uint64_t txb_skid_m0_pko_dbe : 1; /**< [ 16: 16](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_PKO_DBE]. */
uint64_t txb_skid_m0_pko_sbe : 1; /**< [ 17: 17](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_PKO_SBE]. */
uint64_t gmp_in_overfl : 1; /**< [ 18: 18](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[GMP_IN_OVERFL]. */
uint64_t smu_in_overfl : 1; /**< [ 19: 19](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[SMU_IN_OVERFL]. */
uint64_t txb_skid_m1_pko_dbe : 1; /**< [ 20: 20](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_PKO_DBE]. */
uint64_t txb_skid_m1_pko_sbe : 1; /**< [ 21: 21](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_PKO_SBE]. */
uint64_t txb_skid_m2_pko_dbe : 1; /**< [ 22: 22](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_PKO_DBE]. */
uint64_t txb_skid_m2_pko_sbe : 1; /**< [ 23: 23](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_PKO_SBE]. */
uint64_t txb_skid_m3_pko_dbe : 1; /**< [ 24: 24](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_PKO_DBE]. */
uint64_t txb_skid_m3_pko_sbe : 1; /**< [ 25: 25](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_PKO_SBE]. */
uint64_t txb_ncsi_dbe : 1; /**< [ 26: 26](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_NCSI_DBE]. */
uint64_t txb_ncsi_sbe : 1; /**< [ 27: 27](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_NCSI_SBE]. */
uint64_t txb_skid_m0_nic_dbe : 1; /**< [ 28: 28](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_NIC_DBE]. */
uint64_t txb_skid_m0_nic_sbe : 1; /**< [ 29: 29](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_NIC_SBE]. */
uint64_t txb_skid_m1_nic_dbe : 1; /**< [ 30: 30](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_NIC_DBE]. */
uint64_t txb_skid_m1_nic_sbe : 1; /**< [ 31: 31](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_NIC_SBE]. */
uint64_t txb_skid_m2_nic_dbe : 1; /**< [ 32: 32](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_NIC_DBE]. */
uint64_t txb_skid_m2_nic_sbe : 1; /**< [ 33: 33](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_NIC_SBE]. */
uint64_t txb_skid_m3_nic_dbe : 1; /**< [ 34: 34](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_NIC_DBE]. */
uint64_t txb_skid_m3_nic_sbe : 1; /**< [ 35: 35](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_NIC_SBE]. */
uint64_t reserved_36_63 : 28;
#endif /* Word 0 - End */
} cn81xx;
struct bdk_bgxx_cmr_mem_int_w1s_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_26_63 : 38;
uint64_t txb_ncsi_sbe : 1; /**< [ 25: 25](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_NCSI_SBE]. */
uint64_t txb_ncsi_dbe : 1; /**< [ 24: 24](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_NCSI_DBE]. */
uint64_t txb_skid_m3_sbe : 1; /**< [ 23: 23](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_SBE]. */
uint64_t txb_skid_m3_dbe : 1; /**< [ 22: 22](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_DBE]. */
uint64_t txb_skid_m2_sbe : 1; /**< [ 21: 21](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_SBE]. */
uint64_t txb_skid_m2_dbe : 1; /**< [ 20: 20](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_DBE]. */
uint64_t txb_skid_m1_sbe : 1; /**< [ 19: 19](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_SBE]. */
uint64_t txb_skid_m1_dbe : 1; /**< [ 18: 18](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_DBE]. */
uint64_t smu_in_overfl : 1; /**< [ 17: 17](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[SMU_IN_OVERFL]. */
uint64_t gmp_in_overfl : 1; /**< [ 16: 16](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[GMP_IN_OVERFL]. */
uint64_t txb_skid_m0_sbe : 1; /**< [ 15: 15](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_SBE]. */
uint64_t txb_skid_m0_dbe : 1; /**< [ 14: 14](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_DBE]. */
uint64_t txb_fif_bk1_sbe : 1; /**< [ 13: 13](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK1_SBE]. */
uint64_t txb_fif_bk1_dbe : 1; /**< [ 12: 12](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK1_DBE]. */
uint64_t txb_fif_bk0_sbe : 1; /**< [ 11: 11](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK0_SBE]. */
uint64_t txb_fif_bk0_dbe : 1; /**< [ 10: 10](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK0_DBE]. */
uint64_t rxb_skid_sbe : 1; /**< [ 9: 9](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_SKID_SBE]. */
uint64_t rxb_skid_dbe : 1; /**< [ 8: 8](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_SKID_DBE]. */
uint64_t rxb_fif_bk1_sbe1 : 1; /**< [ 7: 7](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE1]. */
uint64_t rxb_fif_bk1_dbe1 : 1; /**< [ 6: 6](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE1]. */
uint64_t rxb_fif_bk1_sbe0 : 1; /**< [ 5: 5](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE0]. */
uint64_t rxb_fif_bk1_dbe0 : 1; /**< [ 4: 4](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE0]. */
uint64_t rxb_fif_bk0_sbe1 : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE1]. */
uint64_t rxb_fif_bk0_dbe1 : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE1]. */
uint64_t rxb_fif_bk0_sbe0 : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE0]. */
uint64_t rxb_fif_bk0_dbe0 : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE0]. */
#else /* Word 0 - Little Endian */
uint64_t rxb_fif_bk0_dbe0 : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE0]. */
uint64_t rxb_fif_bk0_sbe0 : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE0]. */
uint64_t rxb_fif_bk0_dbe1 : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_DBE1]. */
uint64_t rxb_fif_bk0_sbe1 : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK0_SBE1]. */
uint64_t rxb_fif_bk1_dbe0 : 1; /**< [ 4: 4](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE0]. */
uint64_t rxb_fif_bk1_sbe0 : 1; /**< [ 5: 5](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE0]. */
uint64_t rxb_fif_bk1_dbe1 : 1; /**< [ 6: 6](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_DBE1]. */
uint64_t rxb_fif_bk1_sbe1 : 1; /**< [ 7: 7](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_FIF_BK1_SBE1]. */
uint64_t rxb_skid_dbe : 1; /**< [ 8: 8](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_SKID_DBE]. */
uint64_t rxb_skid_sbe : 1; /**< [ 9: 9](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[RXB_SKID_SBE]. */
uint64_t txb_fif_bk0_dbe : 1; /**< [ 10: 10](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK0_DBE]. */
uint64_t txb_fif_bk0_sbe : 1; /**< [ 11: 11](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK0_SBE]. */
uint64_t txb_fif_bk1_dbe : 1; /**< [ 12: 12](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK1_DBE]. */
uint64_t txb_fif_bk1_sbe : 1; /**< [ 13: 13](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_FIF_BK1_SBE]. */
uint64_t txb_skid_m0_dbe : 1; /**< [ 14: 14](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_DBE]. */
uint64_t txb_skid_m0_sbe : 1; /**< [ 15: 15](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M0_SBE]. */
uint64_t gmp_in_overfl : 1; /**< [ 16: 16](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[GMP_IN_OVERFL]. */
uint64_t smu_in_overfl : 1; /**< [ 17: 17](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[SMU_IN_OVERFL]. */
uint64_t txb_skid_m1_dbe : 1; /**< [ 18: 18](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_DBE]. */
uint64_t txb_skid_m1_sbe : 1; /**< [ 19: 19](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M1_SBE]. */
uint64_t txb_skid_m2_dbe : 1; /**< [ 20: 20](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_DBE]. */
uint64_t txb_skid_m2_sbe : 1; /**< [ 21: 21](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M2_SBE]. */
uint64_t txb_skid_m3_dbe : 1; /**< [ 22: 22](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_DBE]. */
uint64_t txb_skid_m3_sbe : 1; /**< [ 23: 23](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_SKID_M3_SBE]. */
uint64_t txb_ncsi_dbe : 1; /**< [ 24: 24](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_NCSI_DBE]. */
uint64_t txb_ncsi_sbe : 1; /**< [ 25: 25](R/W1S/H) Reads or sets BGX(0..1)_CMR_MEM_INT[TXB_NCSI_SBE]. */
uint64_t reserved_26_63 : 38;
#endif /* Word 0 - End */
} cn88xx;
struct bdk_bgxx_cmr_mem_int_w1s_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_40_63 : 24;
uint64_t txb_fif_m3_sbe : 1; /**< [ 39: 39](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_FIF_M3_SBE]. */
uint64_t txb_fif_m3_dbe : 1; /**< [ 38: 38](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_FIF_M3_DBE]. */
uint64_t txb_fif_m2_sbe : 1; /**< [ 37: 37](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_FIF_M2_SBE]. */
uint64_t txb_fif_m2_dbe : 1; /**< [ 36: 36](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_FIF_M2_DBE]. */
uint64_t txb_skid_m3_nic_sbe : 1; /**< [ 35: 35](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_NIC_SBE]. */
uint64_t txb_skid_m3_nic_dbe : 1; /**< [ 34: 34](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_NIC_DBE]. */
uint64_t txb_skid_m2_nic_sbe : 1; /**< [ 33: 33](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_NIC_SBE]. */
uint64_t txb_skid_m2_nic_dbe : 1; /**< [ 32: 32](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_NIC_DBE]. */
uint64_t txb_skid_m1_nic_sbe : 1; /**< [ 31: 31](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_NIC_SBE]. */
uint64_t txb_skid_m1_nic_dbe : 1; /**< [ 30: 30](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_NIC_DBE]. */
uint64_t txb_skid_m0_nic_sbe : 1; /**< [ 29: 29](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_NIC_SBE]. */
uint64_t txb_skid_m0_nic_dbe : 1; /**< [ 28: 28](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_NIC_DBE]. */
uint64_t txb_ncsi_sbe : 1; /**< [ 27: 27](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_NCSI_SBE]. */
uint64_t txb_ncsi_dbe : 1; /**< [ 26: 26](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_NCSI_DBE]. */
uint64_t txb_skid_m3_pko_sbe : 1; /**< [ 25: 25](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_PKO_SBE]. */
uint64_t txb_skid_m3_pko_dbe : 1; /**< [ 24: 24](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_PKO_DBE]. */
uint64_t txb_skid_m2_pko_sbe : 1; /**< [ 23: 23](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_PKO_SBE]. */
uint64_t txb_skid_m2_pko_dbe : 1; /**< [ 22: 22](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_PKO_DBE]. */
uint64_t txb_skid_m1_pko_sbe : 1; /**< [ 21: 21](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_PKO_SBE]. */
uint64_t txb_skid_m1_pko_dbe : 1; /**< [ 20: 20](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_PKO_DBE]. */
uint64_t smu_in_overfl : 1; /**< [ 19: 19](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[SMU_IN_OVERFL]. */
uint64_t gmp_in_overfl : 1; /**< [ 18: 18](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[GMP_IN_OVERFL]. */
uint64_t txb_skid_m0_pko_sbe : 1; /**< [ 17: 17](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_PKO_SBE]. */
uint64_t txb_skid_m0_pko_dbe : 1; /**< [ 16: 16](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_PKO_DBE]. */
uint64_t txb_fif_m1_sbe : 1; /**< [ 15: 15](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_FIF_M1_SBE]. */
uint64_t txb_fif_m1_dbe : 1; /**< [ 14: 14](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_FIF_M1_DBE]. */
uint64_t txb_fif_m0_sbe : 1; /**< [ 13: 13](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_FIF_M0_SBE]. */
uint64_t txb_fif_m0_dbe : 1; /**< [ 12: 12](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_FIF_M0_DBE]. */
uint64_t rxb_nic_skid_sbe : 1; /**< [ 11: 11](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[RXB_NIC_SKID_SBE]. */
uint64_t rxb_nic_skid_dbe : 1; /**< [ 10: 10](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[RXB_NIC_SKID_DBE]. */
uint64_t rxb_pki_skid_sbe : 1; /**< [ 9: 9](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[RXB_PKI_SKID_SBE]. */
uint64_t rxb_pki_skid_dbe : 1; /**< [ 8: 8](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[RXB_PKI_SKID_DBE]. */
uint64_t rxb_fif_bk1_sbe1 : 1; /**< [ 7: 7](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK1_SBE1]. */
uint64_t rxb_fif_bk1_dbe1 : 1; /**< [ 6: 6](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK1_DBE1]. */
uint64_t rxb_fif_bk1_sbe0 : 1; /**< [ 5: 5](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK1_SBE0]. */
uint64_t rxb_fif_bk1_dbe0 : 1; /**< [ 4: 4](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK1_DBE0]. */
uint64_t rxb_fif_bk0_sbe1 : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK0_SBE1]. */
uint64_t rxb_fif_bk0_dbe1 : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK0_DBE1]. */
uint64_t rxb_fif_bk0_sbe0 : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK0_SBE0]. */
uint64_t rxb_fif_bk0_dbe0 : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK0_DBE0]. */
#else /* Word 0 - Little Endian */
uint64_t rxb_fif_bk0_dbe0 : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK0_DBE0]. */
uint64_t rxb_fif_bk0_sbe0 : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK0_SBE0]. */
uint64_t rxb_fif_bk0_dbe1 : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK0_DBE1]. */
uint64_t rxb_fif_bk0_sbe1 : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK0_SBE1]. */
uint64_t rxb_fif_bk1_dbe0 : 1; /**< [ 4: 4](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK1_DBE0]. */
uint64_t rxb_fif_bk1_sbe0 : 1; /**< [ 5: 5](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK1_SBE0]. */
uint64_t rxb_fif_bk1_dbe1 : 1; /**< [ 6: 6](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK1_DBE1]. */
uint64_t rxb_fif_bk1_sbe1 : 1; /**< [ 7: 7](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[RXB_FIF_BK1_SBE1]. */
uint64_t rxb_pki_skid_dbe : 1; /**< [ 8: 8](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[RXB_PKI_SKID_DBE]. */
uint64_t rxb_pki_skid_sbe : 1; /**< [ 9: 9](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[RXB_PKI_SKID_SBE]. */
uint64_t rxb_nic_skid_dbe : 1; /**< [ 10: 10](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[RXB_NIC_SKID_DBE]. */
uint64_t rxb_nic_skid_sbe : 1; /**< [ 11: 11](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[RXB_NIC_SKID_SBE]. */
uint64_t txb_fif_m0_dbe : 1; /**< [ 12: 12](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_FIF_M0_DBE]. */
uint64_t txb_fif_m0_sbe : 1; /**< [ 13: 13](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_FIF_M0_SBE]. */
uint64_t txb_fif_m1_dbe : 1; /**< [ 14: 14](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_FIF_M1_DBE]. */
uint64_t txb_fif_m1_sbe : 1; /**< [ 15: 15](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_FIF_M1_SBE]. */
uint64_t txb_skid_m0_pko_dbe : 1; /**< [ 16: 16](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_PKO_DBE]. */
uint64_t txb_skid_m0_pko_sbe : 1; /**< [ 17: 17](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_PKO_SBE]. */
uint64_t gmp_in_overfl : 1; /**< [ 18: 18](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[GMP_IN_OVERFL]. */
uint64_t smu_in_overfl : 1; /**< [ 19: 19](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[SMU_IN_OVERFL]. */
uint64_t txb_skid_m1_pko_dbe : 1; /**< [ 20: 20](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_PKO_DBE]. */
uint64_t txb_skid_m1_pko_sbe : 1; /**< [ 21: 21](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_PKO_SBE]. */
uint64_t txb_skid_m2_pko_dbe : 1; /**< [ 22: 22](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_PKO_DBE]. */
uint64_t txb_skid_m2_pko_sbe : 1; /**< [ 23: 23](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_PKO_SBE]. */
uint64_t txb_skid_m3_pko_dbe : 1; /**< [ 24: 24](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_PKO_DBE]. */
uint64_t txb_skid_m3_pko_sbe : 1; /**< [ 25: 25](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_PKO_SBE]. */
uint64_t txb_ncsi_dbe : 1; /**< [ 26: 26](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_NCSI_DBE]. */
uint64_t txb_ncsi_sbe : 1; /**< [ 27: 27](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_NCSI_SBE]. */
uint64_t txb_skid_m0_nic_dbe : 1; /**< [ 28: 28](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_NIC_DBE]. */
uint64_t txb_skid_m0_nic_sbe : 1; /**< [ 29: 29](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M0_NIC_SBE]. */
uint64_t txb_skid_m1_nic_dbe : 1; /**< [ 30: 30](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_NIC_DBE]. */
uint64_t txb_skid_m1_nic_sbe : 1; /**< [ 31: 31](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M1_NIC_SBE]. */
uint64_t txb_skid_m2_nic_dbe : 1; /**< [ 32: 32](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_NIC_DBE]. */
uint64_t txb_skid_m2_nic_sbe : 1; /**< [ 33: 33](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M2_NIC_SBE]. */
uint64_t txb_skid_m3_nic_dbe : 1; /**< [ 34: 34](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_NIC_DBE]. */
uint64_t txb_skid_m3_nic_sbe : 1; /**< [ 35: 35](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_SKID_M3_NIC_SBE]. */
uint64_t txb_fif_m2_dbe : 1; /**< [ 36: 36](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_FIF_M2_DBE]. */
uint64_t txb_fif_m2_sbe : 1; /**< [ 37: 37](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_FIF_M2_SBE]. */
uint64_t txb_fif_m3_dbe : 1; /**< [ 38: 38](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_FIF_M3_DBE]. */
uint64_t txb_fif_m3_sbe : 1; /**< [ 39: 39](R/W1S/H) Reads or sets BGX(0..3)_CMR_MEM_INT[TXB_FIF_M3_SBE]. */
uint64_t reserved_40_63 : 24;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_cmr_mem_int_w1s bdk_bgxx_cmr_mem_int_w1s_t;
static inline uint64_t BDK_BGXX_CMR_MEM_INT_W1S(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMR_MEM_INT_W1S(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e0000018ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e0000018ll + 0x1000000ll * ((a) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && (a<=1))
return 0x87e0e0000018ll + 0x1000000ll * ((a) & 0x1);
__bdk_csr_fatal("BGXX_CMR_MEM_INT_W1S", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_CMR_MEM_INT_W1S(a) bdk_bgxx_cmr_mem_int_w1s_t
#define bustype_BDK_BGXX_CMR_MEM_INT_W1S(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMR_MEM_INT_W1S(a) "BGXX_CMR_MEM_INT_W1S"
#define device_bar_BDK_BGXX_CMR_MEM_INT_W1S(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMR_MEM_INT_W1S(a) (a)
#define arguments_BDK_BGXX_CMR_MEM_INT_W1S(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_cmr_nic_nxc_adr
*
* BGX CMR NIC NXC Exception Registers
*/
union bdk_bgxx_cmr_nic_nxc_adr
{
uint64_t u;
struct bdk_bgxx_cmr_nic_nxc_adr_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t lmac_id : 4; /**< [ 15: 12](RO/H) Logged LMAC ID associated with NXC exceptions associated with NIC. */
uint64_t channel : 12; /**< [ 11: 0](RO/H) Logged channel for NXC exceptions associated with NIC. */
#else /* Word 0 - Little Endian */
uint64_t channel : 12; /**< [ 11: 0](RO/H) Logged channel for NXC exceptions associated with NIC. */
uint64_t lmac_id : 4; /**< [ 15: 12](RO/H) Logged LMAC ID associated with NXC exceptions associated with NIC. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmr_nic_nxc_adr_s cn; */
};
typedef union bdk_bgxx_cmr_nic_nxc_adr bdk_bgxx_cmr_nic_nxc_adr_t;
static inline uint64_t BDK_BGXX_CMR_NIC_NXC_ADR(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMR_NIC_NXC_ADR(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e0001030ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e0001030ll + 0x1000000ll * ((a) & 0x3);
__bdk_csr_fatal("BGXX_CMR_NIC_NXC_ADR", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_CMR_NIC_NXC_ADR(a) bdk_bgxx_cmr_nic_nxc_adr_t
#define bustype_BDK_BGXX_CMR_NIC_NXC_ADR(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMR_NIC_NXC_ADR(a) "BGXX_CMR_NIC_NXC_ADR"
#define device_bar_BDK_BGXX_CMR_NIC_NXC_ADR(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMR_NIC_NXC_ADR(a) (a)
#define arguments_BDK_BGXX_CMR_NIC_NXC_ADR(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_cmr_nxc_adr
*
* BGX CMR NCX Exception Registers
*/
union bdk_bgxx_cmr_nxc_adr
{
uint64_t u;
struct bdk_bgxx_cmr_nxc_adr_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t lmac_id : 4; /**< [ 15: 12](RO/H) Logged LMAC ID associated with NXC exceptions. */
uint64_t channel : 12; /**< [ 11: 0](RO/H) Logged channel for NXC exceptions. */
#else /* Word 0 - Little Endian */
uint64_t channel : 12; /**< [ 11: 0](RO/H) Logged channel for NXC exceptions. */
uint64_t lmac_id : 4; /**< [ 15: 12](RO/H) Logged LMAC ID associated with NXC exceptions. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmr_nxc_adr_s cn; */
};
typedef union bdk_bgxx_cmr_nxc_adr bdk_bgxx_cmr_nxc_adr_t;
static inline uint64_t BDK_BGXX_CMR_NXC_ADR(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMR_NXC_ADR(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && (a<=1))
return 0x87e0e0001018ll + 0x1000000ll * ((a) & 0x1);
__bdk_csr_fatal("BGXX_CMR_NXC_ADR", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_CMR_NXC_ADR(a) bdk_bgxx_cmr_nxc_adr_t
#define bustype_BDK_BGXX_CMR_NXC_ADR(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMR_NXC_ADR(a) "BGXX_CMR_NXC_ADR"
#define device_bar_BDK_BGXX_CMR_NXC_ADR(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMR_NXC_ADR(a) (a)
#define arguments_BDK_BGXX_CMR_NXC_ADR(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_cmr_pko_nxc_adr
*
* BGX CMR PKO NXC Exception Registers
*/
union bdk_bgxx_cmr_pko_nxc_adr
{
uint64_t u;
struct bdk_bgxx_cmr_pko_nxc_adr_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t lmac_id : 4; /**< [ 15: 12](RO/H) Logged LMAC ID associated with NXC exceptions associated with PKO. */
uint64_t channel : 12; /**< [ 11: 0](RO/H) Logged channel for NXC exceptions associated with PKO. */
#else /* Word 0 - Little Endian */
uint64_t channel : 12; /**< [ 11: 0](RO/H) Logged channel for NXC exceptions associated with PKO. */
uint64_t lmac_id : 4; /**< [ 15: 12](RO/H) Logged LMAC ID associated with NXC exceptions associated with PKO. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmr_pko_nxc_adr_s cn; */
};
typedef union bdk_bgxx_cmr_pko_nxc_adr bdk_bgxx_cmr_pko_nxc_adr_t;
static inline uint64_t BDK_BGXX_CMR_PKO_NXC_ADR(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMR_PKO_NXC_ADR(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e0001018ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e0001018ll + 0x1000000ll * ((a) & 0x3);
__bdk_csr_fatal("BGXX_CMR_PKO_NXC_ADR", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_CMR_PKO_NXC_ADR(a) bdk_bgxx_cmr_pko_nxc_adr_t
#define bustype_BDK_BGXX_CMR_PKO_NXC_ADR(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMR_PKO_NXC_ADR(a) "BGXX_CMR_PKO_NXC_ADR"
#define device_bar_BDK_BGXX_CMR_PKO_NXC_ADR(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMR_PKO_NXC_ADR(a) (a)
#define arguments_BDK_BGXX_CMR_PKO_NXC_ADR(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_cmr_rx_dmac#_cam
*
* BGX CMR Receive CAM Registers
* These registers provide access to the 32 DMAC CAM entries in BGX.
*/
union bdk_bgxx_cmr_rx_dmacx_cam
{
uint64_t u;
struct bdk_bgxx_cmr_rx_dmacx_cam_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_51_63 : 13;
uint64_t id : 2; /**< [ 50: 49](R/W) Logical MAC ID that this DMAC CAM address applies to. BGX has 32 DMAC CAM entries that can
be accessed with the BGX()_CMR_RX_DMAC()_CAM CSRs. These 32 DMAC entries can be used by
any of the four SGMII MACs or the 10G/40G MACs using these register bits.
A typical configuration is to provide eight CAM entries per LMAC ID, which is configured
using the following settings:
* LMAC interface 0: BGX()_CMR_RX_DMAC(0..7)_CAM[ID] = 0x0.
* LMAC interface 1: BGX()_CMR_RX_DMAC(8..15)_CAM[ID] = 0x1.
* LMAC interface 2: BGX()_CMR_RX_DMAC(16..23)_CAM[ID] = 0x2.
* LMAC interface 3: BGX()_CMR_RX_DMAC(24..31)_CAM[ID] = 0x3. */
uint64_t en : 1; /**< [ 48: 48](R/W) CAM entry enable for this DMAC address.
1 = Include this address in the matching algorithm.
0 = Don't include this address in the matching algorithm. */
uint64_t adr : 48; /**< [ 47: 0](R/W) DMAC address in the CAM used for matching. Specified in network byte order, i.e.
ADR\<47:40\> is for the first DMAC byte on the wire. The CAM matches against unicast or
multicast DMAC addresses. All BGX()_CMR_RX_DMAC()_CAM CSRs can be used in any of the LMAC
combinations such that any BGX MAC can use any of the 32 common DMAC entries. */
#else /* Word 0 - Little Endian */
uint64_t adr : 48; /**< [ 47: 0](R/W) DMAC address in the CAM used for matching. Specified in network byte order, i.e.
ADR\<47:40\> is for the first DMAC byte on the wire. The CAM matches against unicast or
multicast DMAC addresses. All BGX()_CMR_RX_DMAC()_CAM CSRs can be used in any of the LMAC
combinations such that any BGX MAC can use any of the 32 common DMAC entries. */
uint64_t en : 1; /**< [ 48: 48](R/W) CAM entry enable for this DMAC address.
1 = Include this address in the matching algorithm.
0 = Don't include this address in the matching algorithm. */
uint64_t id : 2; /**< [ 50: 49](R/W) Logical MAC ID that this DMAC CAM address applies to. BGX has 32 DMAC CAM entries that can
be accessed with the BGX()_CMR_RX_DMAC()_CAM CSRs. These 32 DMAC entries can be used by
any of the four SGMII MACs or the 10G/40G MACs using these register bits.
A typical configuration is to provide eight CAM entries per LMAC ID, which is configured
using the following settings:
* LMAC interface 0: BGX()_CMR_RX_DMAC(0..7)_CAM[ID] = 0x0.
* LMAC interface 1: BGX()_CMR_RX_DMAC(8..15)_CAM[ID] = 0x1.
* LMAC interface 2: BGX()_CMR_RX_DMAC(16..23)_CAM[ID] = 0x2.
* LMAC interface 3: BGX()_CMR_RX_DMAC(24..31)_CAM[ID] = 0x3. */
uint64_t reserved_51_63 : 13;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmr_rx_dmacx_cam_s cn; */
};
typedef union bdk_bgxx_cmr_rx_dmacx_cam bdk_bgxx_cmr_rx_dmacx_cam_t;
static inline uint64_t BDK_BGXX_CMR_RX_DMACX_CAM(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMR_RX_DMACX_CAM(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=31)))
return 0x87e0e0000200ll + 0x1000000ll * ((a) & 0x1) + 8ll * ((b) & 0x1f);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=31)))
return 0x87e0e0000200ll + 0x1000000ll * ((a) & 0x3) + 8ll * ((b) & 0x1f);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=31)))
return 0x87e0e0000200ll + 0x1000000ll * ((a) & 0x1) + 8ll * ((b) & 0x1f);
__bdk_csr_fatal("BGXX_CMR_RX_DMACX_CAM", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMR_RX_DMACX_CAM(a,b) bdk_bgxx_cmr_rx_dmacx_cam_t
#define bustype_BDK_BGXX_CMR_RX_DMACX_CAM(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMR_RX_DMACX_CAM(a,b) "BGXX_CMR_RX_DMACX_CAM"
#define device_bar_BDK_BGXX_CMR_RX_DMACX_CAM(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMR_RX_DMACX_CAM(a,b) (a)
#define arguments_BDK_BGXX_CMR_RX_DMACX_CAM(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr_rx_lmacs
*
* BGX CMR Receive Logical MACs Registers
*/
union bdk_bgxx_cmr_rx_lmacs
{
uint64_t u;
struct bdk_bgxx_cmr_rx_lmacs_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_3_63 : 61;
uint64_t lmacs : 3; /**< [ 2: 0](R/W) Number of LMACS. Specifies the number of LMACs that can be enabled.
This determines the logical RX buffer size per LMAC and the maximum
LMAC ID that can be used:
0x0 = Reserved.
0x1 = BGX()_CONST[TX_FIFOSZ] bytes per LMAC, maximum LMAC ID is 0.
0x2 = BGX()_CONST[TX_FIFOSZ]/2 bytes per LMAC, maximum LMAC ID is 1.
0x3 = BGX()_CONST[TX_FIFOSZ]/4 bytes per LMAC, maximum LMAC ID is 2.
0x4 = BGX()_CONST[TX_FIFOSZ]/4 bytes per LMAC, maximum LMAC ID is 3.
0x5-0x7 = Reserved.
Note the maximum LMAC ID is determined by the smaller of
BGX()_CMR_RX_LMACS[LMACS] and BGX()_CMR_TX_LMACS[LMACS]. The two fields
should be set to the same value for normal operation. */
#else /* Word 0 - Little Endian */
uint64_t lmacs : 3; /**< [ 2: 0](R/W) Number of LMACS. Specifies the number of LMACs that can be enabled.
This determines the logical RX buffer size per LMAC and the maximum
LMAC ID that can be used:
0x0 = Reserved.
0x1 = BGX()_CONST[TX_FIFOSZ] bytes per LMAC, maximum LMAC ID is 0.
0x2 = BGX()_CONST[TX_FIFOSZ]/2 bytes per LMAC, maximum LMAC ID is 1.
0x3 = BGX()_CONST[TX_FIFOSZ]/4 bytes per LMAC, maximum LMAC ID is 2.
0x4 = BGX()_CONST[TX_FIFOSZ]/4 bytes per LMAC, maximum LMAC ID is 3.
0x5-0x7 = Reserved.
Note the maximum LMAC ID is determined by the smaller of
BGX()_CMR_RX_LMACS[LMACS] and BGX()_CMR_TX_LMACS[LMACS]. The two fields
should be set to the same value for normal operation. */
uint64_t reserved_3_63 : 61;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmr_rx_lmacs_s cn81xx; */
struct bdk_bgxx_cmr_rx_lmacs_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_3_63 : 61;
uint64_t lmacs : 3; /**< [ 2: 0](R/W) Number of LMACS. Specifies the number of LMACs that can be enabled.
This determines the logical RX buffer size per LMAC and the maximum
LMAC ID that can be used:
0x0 = Reserved.
0x1 = 64 KB per LMAC, maximum LMAC ID is 0.
0x2 = 32 KB per LMAC, maximum LMAC ID is 1.
0x3 = 16 KB per LMAC, maximum LMAC ID is 2.
0x4 = 16 KB per LMAC, maximum LMAC ID is 3.
0x5-0x7 = Reserved.
Note the maximum LMAC ID is determined by the smaller of
BGX()_CMR_RX_LMACS[LMACS] and BGX()_CMR_TX_LMACS[LMACS]. The two fields
should be set to the same value for normal operation. */
#else /* Word 0 - Little Endian */
uint64_t lmacs : 3; /**< [ 2: 0](R/W) Number of LMACS. Specifies the number of LMACs that can be enabled.
This determines the logical RX buffer size per LMAC and the maximum
LMAC ID that can be used:
0x0 = Reserved.
0x1 = 64 KB per LMAC, maximum LMAC ID is 0.
0x2 = 32 KB per LMAC, maximum LMAC ID is 1.
0x3 = 16 KB per LMAC, maximum LMAC ID is 2.
0x4 = 16 KB per LMAC, maximum LMAC ID is 3.
0x5-0x7 = Reserved.
Note the maximum LMAC ID is determined by the smaller of
BGX()_CMR_RX_LMACS[LMACS] and BGX()_CMR_TX_LMACS[LMACS]. The two fields
should be set to the same value for normal operation. */
uint64_t reserved_3_63 : 61;
#endif /* Word 0 - End */
} cn88xx;
/* struct bdk_bgxx_cmr_rx_lmacs_s cn83xx; */
};
typedef union bdk_bgxx_cmr_rx_lmacs bdk_bgxx_cmr_rx_lmacs_t;
static inline uint64_t BDK_BGXX_CMR_RX_LMACS(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMR_RX_LMACS(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e0000468ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e0000468ll + 0x1000000ll * ((a) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && (a<=1))
return 0x87e0e0000468ll + 0x1000000ll * ((a) & 0x1);
__bdk_csr_fatal("BGXX_CMR_RX_LMACS", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_CMR_RX_LMACS(a) bdk_bgxx_cmr_rx_lmacs_t
#define bustype_BDK_BGXX_CMR_RX_LMACS(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMR_RX_LMACS(a) "BGXX_CMR_RX_LMACS"
#define device_bar_BDK_BGXX_CMR_RX_LMACS(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMR_RX_LMACS(a) (a)
#define arguments_BDK_BGXX_CMR_RX_LMACS(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_cmr_rx_ovr_bp
*
* BGX CMR Receive-Ports Backpressure Override Registers
* BGX()_CMR_RX_OVR_BP[EN\<0\>] must be set to one and BGX()_CMR_RX_OVR_BP[BP\<0\>] must be
* cleared to zero (to forcibly disable hardware-automatic 802.3 PAUSE packet generation) with
* the HiGig2 Protocol when BGX()_SMU()_HG2_CONTROL[HG2TX_EN]=0. (The HiGig2 protocol is
* indicated by BGX()_SMU()_TX_CTL[HG_EN]=1 and BGX()_SMU()_RX_UDD_SKP[LEN]=16).
* Hardware can only auto-generate backpressure through HiGig2 messages (optionally, when
* BGX()_SMU()_HG2_CONTROL[HG2TX_EN]=1) with the HiGig2 protocol.
*/
union bdk_bgxx_cmr_rx_ovr_bp
{
uint64_t u;
struct bdk_bgxx_cmr_rx_ovr_bp_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_12_63 : 52;
uint64_t en : 4; /**< [ 11: 8](R/W) Per-LMAC enable backpressure override.
0 = Don't enable.
1 = Enable override.
Bit\<8\> represents LMAC 0, ..., bit\<11\> represents LMAC 3. */
uint64_t bp : 4; /**< [ 7: 4](R/W) Per-LMAC backpressure status to use:
0 = LMAC is available.
1 = LMAC should be backpressured.
Bit\<4\> represents LMAC 0, ..., bit\<7\> represents LMAC 3. */
uint64_t ign_fifo_bp : 4; /**< [ 3: 0](R/W) Ignore BGX()_CMR()_RX_BP_ON[MARK] when computing backpressure. CMR does not backpressure
the
MAC due to the FIFO length passing BGX()_CMR()_RX_BP_ON[MARK]. */
#else /* Word 0 - Little Endian */
uint64_t ign_fifo_bp : 4; /**< [ 3: 0](R/W) Ignore BGX()_CMR()_RX_BP_ON[MARK] when computing backpressure. CMR does not backpressure
the
MAC due to the FIFO length passing BGX()_CMR()_RX_BP_ON[MARK]. */
uint64_t bp : 4; /**< [ 7: 4](R/W) Per-LMAC backpressure status to use:
0 = LMAC is available.
1 = LMAC should be backpressured.
Bit\<4\> represents LMAC 0, ..., bit\<7\> represents LMAC 3. */
uint64_t en : 4; /**< [ 11: 8](R/W) Per-LMAC enable backpressure override.
0 = Don't enable.
1 = Enable override.
Bit\<8\> represents LMAC 0, ..., bit\<11\> represents LMAC 3. */
uint64_t reserved_12_63 : 52;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmr_rx_ovr_bp_s cn; */
};
typedef union bdk_bgxx_cmr_rx_ovr_bp bdk_bgxx_cmr_rx_ovr_bp_t;
static inline uint64_t BDK_BGXX_CMR_RX_OVR_BP(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMR_RX_OVR_BP(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e0000470ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e0000470ll + 0x1000000ll * ((a) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && (a<=1))
return 0x87e0e0000470ll + 0x1000000ll * ((a) & 0x1);
__bdk_csr_fatal("BGXX_CMR_RX_OVR_BP", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_CMR_RX_OVR_BP(a) bdk_bgxx_cmr_rx_ovr_bp_t
#define bustype_BDK_BGXX_CMR_RX_OVR_BP(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMR_RX_OVR_BP(a) "BGXX_CMR_RX_OVR_BP"
#define device_bar_BDK_BGXX_CMR_RX_OVR_BP(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMR_RX_OVR_BP(a) (a)
#define arguments_BDK_BGXX_CMR_RX_OVR_BP(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_cmr_rx_stat10
*
* BGX Receive Status Register 10
* This register provide a count of octets of dropped at the NCSI interface.
*/
union bdk_bgxx_cmr_rx_stat10
{
uint64_t u;
struct bdk_bgxx_cmr_rx_stat10_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t cnt : 48; /**< [ 47: 0](R/W/H) Octet count of dropped NCSI packets. CNT will wrap and is cleared if the NCSI interface is
reset with BGX()_CMR_GLOBAL_CONFIG[CMR_NCSI_RESET]. */
#else /* Word 0 - Little Endian */
uint64_t cnt : 48; /**< [ 47: 0](R/W/H) Octet count of dropped NCSI packets. CNT will wrap and is cleared if the NCSI interface is
reset with BGX()_CMR_GLOBAL_CONFIG[CMR_NCSI_RESET]. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
struct bdk_bgxx_cmr_rx_stat10_cn81xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t cnt : 48; /**< [ 47: 0](R/W/H) Octet count of dropped NCSI packets. [CNT] will wrap and is cleared if NCSI is reset with
BGX()_CMR_GLOBAL_CONFIG[CMR_NCSI_RESET]. */
#else /* Word 0 - Little Endian */
uint64_t cnt : 48; /**< [ 47: 0](R/W/H) Octet count of dropped NCSI packets. [CNT] will wrap and is cleared if NCSI is reset with
BGX()_CMR_GLOBAL_CONFIG[CMR_NCSI_RESET]. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} cn81xx;
/* struct bdk_bgxx_cmr_rx_stat10_s cn88xx; */
/* struct bdk_bgxx_cmr_rx_stat10_cn81xx cn83xx; */
};
typedef union bdk_bgxx_cmr_rx_stat10 bdk_bgxx_cmr_rx_stat10_t;
static inline uint64_t BDK_BGXX_CMR_RX_STAT10(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMR_RX_STAT10(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e00000c0ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e00000c0ll + 0x1000000ll * ((a) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && (a<=1))
return 0x87e0e00000c0ll + 0x1000000ll * ((a) & 0x1);
__bdk_csr_fatal("BGXX_CMR_RX_STAT10", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_CMR_RX_STAT10(a) bdk_bgxx_cmr_rx_stat10_t
#define bustype_BDK_BGXX_CMR_RX_STAT10(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMR_RX_STAT10(a) "BGXX_CMR_RX_STAT10"
#define device_bar_BDK_BGXX_CMR_RX_STAT10(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMR_RX_STAT10(a) (a)
#define arguments_BDK_BGXX_CMR_RX_STAT10(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_cmr_rx_stat9
*
* BGX Receive Status Register 9
* This registers provides a count of packets dropped at the NCSI interface.
* The count of dropped NCSI packets is not accounted for in any other stats
* registers.
*/
union bdk_bgxx_cmr_rx_stat9
{
uint64_t u;
struct bdk_bgxx_cmr_rx_stat9_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t cnt : 48; /**< [ 47: 0](R/W/H) Count of dropped packets. CNT will wrap and is cleared if the NCSI interface is reset with
BGX()_CMR_GLOBAL_CONFIG[CMR_NCSI_RESET]. */
#else /* Word 0 - Little Endian */
uint64_t cnt : 48; /**< [ 47: 0](R/W/H) Count of dropped packets. CNT will wrap and is cleared if the NCSI interface is reset with
BGX()_CMR_GLOBAL_CONFIG[CMR_NCSI_RESET]. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
struct bdk_bgxx_cmr_rx_stat9_cn81xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t cnt : 48; /**< [ 47: 0](R/W/H) Count of dropped packets. [CNT] will wrap and is cleared if NCSI is reset with
BGX()_CMR_GLOBAL_CONFIG[CMR_NCSI_RESET]. */
#else /* Word 0 - Little Endian */
uint64_t cnt : 48; /**< [ 47: 0](R/W/H) Count of dropped packets. [CNT] will wrap and is cleared if NCSI is reset with
BGX()_CMR_GLOBAL_CONFIG[CMR_NCSI_RESET]. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} cn81xx;
/* struct bdk_bgxx_cmr_rx_stat9_s cn88xx; */
/* struct bdk_bgxx_cmr_rx_stat9_cn81xx cn83xx; */
};
typedef union bdk_bgxx_cmr_rx_stat9 bdk_bgxx_cmr_rx_stat9_t;
static inline uint64_t BDK_BGXX_CMR_RX_STAT9(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMR_RX_STAT9(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e00000b8ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e00000b8ll + 0x1000000ll * ((a) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && (a<=1))
return 0x87e0e00000b8ll + 0x1000000ll * ((a) & 0x1);
__bdk_csr_fatal("BGXX_CMR_RX_STAT9", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_CMR_RX_STAT9(a) bdk_bgxx_cmr_rx_stat9_t
#define bustype_BDK_BGXX_CMR_RX_STAT9(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMR_RX_STAT9(a) "BGXX_CMR_RX_STAT9"
#define device_bar_BDK_BGXX_CMR_RX_STAT9(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMR_RX_STAT9(a) (a)
#define arguments_BDK_BGXX_CMR_RX_STAT9(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_cmr_rx_steering#
*
* BGX CMR Receive Steering Registers
* These registers, along with BGX()_CMR_RX_STEERING_VETYPE(), provide eight filters for
* identifying and steering NCSI receive traffic.
*
* Steering is done for the designated LMAC specified by BGX()_CMR_GLOBAL_CONFIG[NCSI_LMAC_ID].
* The steering algorithm is applied after the RX DMAC filter specified by
* BGX()_CMR()_RX_DMAC_CTL and BGX()_CMR_RX_DMAC()_CAM. As such, the DMAC filter and steering
* filters should be set in a consistent manner.
*
* Internal:
* "* ALGORITHM
* // Steering of RX packets for LMAC identified by BGX()_CMR_GLOBAL_CONFIG[NCSI_LMAC_ID].
* rx_steering(uint48 pkt_dmac, uint16 pkt_etype, uint16 pkt_vlan_id) {
* for (int i = 0; i \< 8; i++) {
* steer = BGX()_CMR_RX_STEERING(i);
* vetype = BGX()_CMR_RX_STEERING_VETYPE(i);
* if (steer[MCST_EN] || steer[DMAC_EN] || vetype[VLAN_EN] || vetype[VLAN_TAG_EN]) {
* // Filter is enabled.
* if ( (!steer[MCST_EN] || is_mcst(pkt_dmac))
* && (!steer[DMAC_EN] || pkt_dmac == steer[DMAC])
* && (!vetype[VLAN_EN] || pkt_vlan_id == vetype[VLAN_ID])
* && (!vetype[VLAN_TAG_EN] || pkt_etype == vetype[VLAN_ETYPE]) )
* {
* // Filter match (all enabled matching criteria are met).
* return steer[DEST];
* }
* }
* }
* return BGX()_CMR_RX_STEERING_DEFAULT[DEST]; // No match
* }"
*/
union bdk_bgxx_cmr_rx_steeringx
{
uint64_t u;
struct bdk_bgxx_cmr_rx_steeringx_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_52_63 : 12;
uint64_t dest : 2; /**< [ 51: 50](R/W) Destination for traffic that meets all criteria of the matching algorithm:
0x0 = Steer this traffic exclusively to NCSI.
0x1 = Steer this traffic exclusively to TNS/NIC.
0x2 = Steer this traffic to BOTH TNS/NIC and NCSI.
0x3 = Steer this traffic to the bit bucket (drop). */
uint64_t mcst_en : 1; /**< [ 49: 49](R/W) Enable for identifying multicast packets:
1 = Include multicast packets in the matching algorithm.
0 = Do not include multicast packets in the matching algorithm. */
uint64_t dmac_en : 1; /**< [ 48: 48](R/W) Enable DMAC address check:
1 = Include DMAC address checking in the matching algorithm.
0 = Do not include DMAC address checking in the matching algorithm. */
uint64_t dmac : 48; /**< [ 47: 0](R/W) DMAC address used for the matching algorithm when [DMAC_EN] is set. Broadcast can be
specified with value 0xFFFF_FFFFFFFF. */
#else /* Word 0 - Little Endian */
uint64_t dmac : 48; /**< [ 47: 0](R/W) DMAC address used for the matching algorithm when [DMAC_EN] is set. Broadcast can be
specified with value 0xFFFF_FFFFFFFF. */
uint64_t dmac_en : 1; /**< [ 48: 48](R/W) Enable DMAC address check:
1 = Include DMAC address checking in the matching algorithm.
0 = Do not include DMAC address checking in the matching algorithm. */
uint64_t mcst_en : 1; /**< [ 49: 49](R/W) Enable for identifying multicast packets:
1 = Include multicast packets in the matching algorithm.
0 = Do not include multicast packets in the matching algorithm. */
uint64_t dest : 2; /**< [ 51: 50](R/W) Destination for traffic that meets all criteria of the matching algorithm:
0x0 = Steer this traffic exclusively to NCSI.
0x1 = Steer this traffic exclusively to TNS/NIC.
0x2 = Steer this traffic to BOTH TNS/NIC and NCSI.
0x3 = Steer this traffic to the bit bucket (drop). */
uint64_t reserved_52_63 : 12;
#endif /* Word 0 - End */
} s;
struct bdk_bgxx_cmr_rx_steeringx_cn81xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_52_63 : 12;
uint64_t dest : 2; /**< [ 51: 50](R/W) Destination for traffic that meets all criteria of the matching algorithm:
0x0 = Steer this traffic exclusively to NCSI.
0x1 = Steer this traffic exclusively to NIC.
0x2 = Steer this traffic to BOTH NIC and NCSI.
0x3 = Steer this traffic to the bit bucket (drop). */
uint64_t mcst_en : 1; /**< [ 49: 49](R/W) Enable for identifying multicast packets:
1 = Include multicast packets in the matching algorithm.
0 = Do not include multicast packets in the matching algorithm. */
uint64_t dmac_en : 1; /**< [ 48: 48](R/W) Enable DMAC address check:
1 = Include DMAC address checking in the matching algorithm.
0 = Do not include DMAC address checking in the matching algorithm. */
uint64_t dmac : 48; /**< [ 47: 0](R/W) DMAC address used for the matching algorithm when [DMAC_EN] is set. Broadcast can be
specified with value 0xFFFF_FFFFFFFF. */
#else /* Word 0 - Little Endian */
uint64_t dmac : 48; /**< [ 47: 0](R/W) DMAC address used for the matching algorithm when [DMAC_EN] is set. Broadcast can be
specified with value 0xFFFF_FFFFFFFF. */
uint64_t dmac_en : 1; /**< [ 48: 48](R/W) Enable DMAC address check:
1 = Include DMAC address checking in the matching algorithm.
0 = Do not include DMAC address checking in the matching algorithm. */
uint64_t mcst_en : 1; /**< [ 49: 49](R/W) Enable for identifying multicast packets:
1 = Include multicast packets in the matching algorithm.
0 = Do not include multicast packets in the matching algorithm. */
uint64_t dest : 2; /**< [ 51: 50](R/W) Destination for traffic that meets all criteria of the matching algorithm:
0x0 = Steer this traffic exclusively to NCSI.
0x1 = Steer this traffic exclusively to NIC.
0x2 = Steer this traffic to BOTH NIC and NCSI.
0x3 = Steer this traffic to the bit bucket (drop). */
uint64_t reserved_52_63 : 12;
#endif /* Word 0 - End */
} cn81xx;
/* struct bdk_bgxx_cmr_rx_steeringx_s cn88xx; */
struct bdk_bgxx_cmr_rx_steeringx_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_52_63 : 12;
uint64_t dest : 2; /**< [ 51: 50](R/W) Destination for traffic that meets all criteria of the matching algorithm:
0x0 = Steer this traffic exclusively to NCSI.
0x1 = Steer this traffic exclusively to PKO/NIC.
0x2 = Steer this traffic to BOTH PKO/NIC and NCSI.
0x3 = Steer this traffic to the bit bucket (drop). */
uint64_t mcst_en : 1; /**< [ 49: 49](R/W) Enable for identifying multicast packets:
1 = Include multicast packets in the matching algorithm.
0 = Do not include multicast packets in the matching algorithm. */
uint64_t dmac_en : 1; /**< [ 48: 48](R/W) Enable DMAC address check:
1 = Include DMAC address checking in the matching algorithm.
0 = Do not include DMAC address checking in the matching algorithm. */
uint64_t dmac : 48; /**< [ 47: 0](R/W) DMAC address used for the matching algorithm when [DMAC_EN] is set. Broadcast can be
specified with value 0xFFFF_FFFFFFFF. */
#else /* Word 0 - Little Endian */
uint64_t dmac : 48; /**< [ 47: 0](R/W) DMAC address used for the matching algorithm when [DMAC_EN] is set. Broadcast can be
specified with value 0xFFFF_FFFFFFFF. */
uint64_t dmac_en : 1; /**< [ 48: 48](R/W) Enable DMAC address check:
1 = Include DMAC address checking in the matching algorithm.
0 = Do not include DMAC address checking in the matching algorithm. */
uint64_t mcst_en : 1; /**< [ 49: 49](R/W) Enable for identifying multicast packets:
1 = Include multicast packets in the matching algorithm.
0 = Do not include multicast packets in the matching algorithm. */
uint64_t dest : 2; /**< [ 51: 50](R/W) Destination for traffic that meets all criteria of the matching algorithm:
0x0 = Steer this traffic exclusively to NCSI.
0x1 = Steer this traffic exclusively to PKO/NIC.
0x2 = Steer this traffic to BOTH PKO/NIC and NCSI.
0x3 = Steer this traffic to the bit bucket (drop). */
uint64_t reserved_52_63 : 12;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_cmr_rx_steeringx bdk_bgxx_cmr_rx_steeringx_t;
static inline uint64_t BDK_BGXX_CMR_RX_STEERINGX(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMR_RX_STEERINGX(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=7)))
return 0x87e0e0000300ll + 0x1000000ll * ((a) & 0x1) + 8ll * ((b) & 0x7);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=7)))
return 0x87e0e0000300ll + 0x1000000ll * ((a) & 0x3) + 8ll * ((b) & 0x7);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=7)))
return 0x87e0e0000300ll + 0x1000000ll * ((a) & 0x1) + 8ll * ((b) & 0x7);
__bdk_csr_fatal("BGXX_CMR_RX_STEERINGX", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMR_RX_STEERINGX(a,b) bdk_bgxx_cmr_rx_steeringx_t
#define bustype_BDK_BGXX_CMR_RX_STEERINGX(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMR_RX_STEERINGX(a,b) "BGXX_CMR_RX_STEERINGX"
#define device_bar_BDK_BGXX_CMR_RX_STEERINGX(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMR_RX_STEERINGX(a,b) (a)
#define arguments_BDK_BGXX_CMR_RX_STEERINGX(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr_rx_steering_default
*
* BGX CMR Receive Steering Default Destination Register
*/
union bdk_bgxx_cmr_rx_steering_default
{
uint64_t u;
struct bdk_bgxx_cmr_rx_steering_default_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_2_63 : 62;
uint64_t dest : 2; /**< [ 1: 0](R/W) Destination for traffic that does not match any of the steering filters specified by
BGX()_CMR_RX_STEERING() and and BGX()_CMR_RX_STEERING_VETYPE():
0x0 = Steer traffic exclusively to NCSI.
0x1 = Steer traffic exclusively to TNS/NIC.
0x2 = Steer traffic to BOTH TNS/NIC and NCSI.
0x3 = Steer traffic to the bit bucket (drop). */
#else /* Word 0 - Little Endian */
uint64_t dest : 2; /**< [ 1: 0](R/W) Destination for traffic that does not match any of the steering filters specified by
BGX()_CMR_RX_STEERING() and and BGX()_CMR_RX_STEERING_VETYPE():
0x0 = Steer traffic exclusively to NCSI.
0x1 = Steer traffic exclusively to TNS/NIC.
0x2 = Steer traffic to BOTH TNS/NIC and NCSI.
0x3 = Steer traffic to the bit bucket (drop). */
uint64_t reserved_2_63 : 62;
#endif /* Word 0 - End */
} s;
struct bdk_bgxx_cmr_rx_steering_default_cn81xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_2_63 : 62;
uint64_t dest : 2; /**< [ 1: 0](R/W) Destination for traffic that does not match any of the steering filters specified by
BGX()_CMR_RX_STEERING() and and BGX()_CMR_RX_STEERING_VETYPE():
0x0 = Steer traffic exclusively to NCSI.
0x1 = Steer traffic exclusively to NIC.
0x2 = Steer traffic to BOTH NIC and NCSI.
0x3 = Steer traffic to the bit bucket (drop). */
#else /* Word 0 - Little Endian */
uint64_t dest : 2; /**< [ 1: 0](R/W) Destination for traffic that does not match any of the steering filters specified by
BGX()_CMR_RX_STEERING() and and BGX()_CMR_RX_STEERING_VETYPE():
0x0 = Steer traffic exclusively to NCSI.
0x1 = Steer traffic exclusively to NIC.
0x2 = Steer traffic to BOTH NIC and NCSI.
0x3 = Steer traffic to the bit bucket (drop). */
uint64_t reserved_2_63 : 62;
#endif /* Word 0 - End */
} cn81xx;
/* struct bdk_bgxx_cmr_rx_steering_default_s cn88xx; */
struct bdk_bgxx_cmr_rx_steering_default_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_2_63 : 62;
uint64_t dest : 2; /**< [ 1: 0](R/W) Destination for traffic that does not match any of the steering filters specified by
BGX()_CMR_RX_STEERING() and and BGX()_CMR_RX_STEERING_VETYPE():
0x0 = Steer traffic exclusively to NCSI.
0x1 = Steer traffic exclusively to PKO/NIC.
0x2 = Steer traffic to BOTH PKO/NIC and NCSI.
0x3 = Steer traffic to the bit bucket (drop). */
#else /* Word 0 - Little Endian */
uint64_t dest : 2; /**< [ 1: 0](R/W) Destination for traffic that does not match any of the steering filters specified by
BGX()_CMR_RX_STEERING() and and BGX()_CMR_RX_STEERING_VETYPE():
0x0 = Steer traffic exclusively to NCSI.
0x1 = Steer traffic exclusively to PKO/NIC.
0x2 = Steer traffic to BOTH PKO/NIC and NCSI.
0x3 = Steer traffic to the bit bucket (drop). */
uint64_t reserved_2_63 : 62;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_cmr_rx_steering_default bdk_bgxx_cmr_rx_steering_default_t;
static inline uint64_t BDK_BGXX_CMR_RX_STEERING_DEFAULT(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMR_RX_STEERING_DEFAULT(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e0000448ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e0000448ll + 0x1000000ll * ((a) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && (a<=1))
return 0x87e0e0000448ll + 0x1000000ll * ((a) & 0x1);
__bdk_csr_fatal("BGXX_CMR_RX_STEERING_DEFAULT", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_CMR_RX_STEERING_DEFAULT(a) bdk_bgxx_cmr_rx_steering_default_t
#define bustype_BDK_BGXX_CMR_RX_STEERING_DEFAULT(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMR_RX_STEERING_DEFAULT(a) "BGXX_CMR_RX_STEERING_DEFAULT"
#define device_bar_BDK_BGXX_CMR_RX_STEERING_DEFAULT(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMR_RX_STEERING_DEFAULT(a) (a)
#define arguments_BDK_BGXX_CMR_RX_STEERING_DEFAULT(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_cmr_rx_steering_vetype#
*
* BGX CMR Receive VLAN Ethertype Register
* These registers, along with BGX()_CMR_RX_STEERING(), provide eight filters for identifying and
* steering NCSI receive traffic.
*/
union bdk_bgxx_cmr_rx_steering_vetypex
{
uint64_t u;
struct bdk_bgxx_cmr_rx_steering_vetypex_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_30_63 : 34;
uint64_t vlan_en : 1; /**< [ 29: 29](R/W) Enable VLAN ID check:
1 = Include VLAN ID checking in the matching algorithm.
0 = Do not include VLAN ID checking in the matching algorithm. */
uint64_t vlan_id : 12; /**< [ 28: 17](R/W) VLAN ID used for the matching algorithm when [VLAN_EN] is set. */
uint64_t vlan_tag_en : 1; /**< [ 16: 16](R/W) Enable VLAN tag Ethertype check:
1 = Include VLAN tag Ethertype checking in the matching algorithm.
0 = Do not include VLAN tag Ethertype checking in the matching algorithm. */
uint64_t vlan_etype : 16; /**< [ 15: 0](R/W) VLAN Ethertype for the matching algorithm when [VLAN_TAG_EN] is set.
802.1Q and 802.1ad specify several Ethertypes used to identify VLAN tagged and VLAN double
tagged packets. BGX will always match against the tag immediately following the SMAC
address of the L2 header. */
#else /* Word 0 - Little Endian */
uint64_t vlan_etype : 16; /**< [ 15: 0](R/W) VLAN Ethertype for the matching algorithm when [VLAN_TAG_EN] is set.
802.1Q and 802.1ad specify several Ethertypes used to identify VLAN tagged and VLAN double
tagged packets. BGX will always match against the tag immediately following the SMAC
address of the L2 header. */
uint64_t vlan_tag_en : 1; /**< [ 16: 16](R/W) Enable VLAN tag Ethertype check:
1 = Include VLAN tag Ethertype checking in the matching algorithm.
0 = Do not include VLAN tag Ethertype checking in the matching algorithm. */
uint64_t vlan_id : 12; /**< [ 28: 17](R/W) VLAN ID used for the matching algorithm when [VLAN_EN] is set. */
uint64_t vlan_en : 1; /**< [ 29: 29](R/W) Enable VLAN ID check:
1 = Include VLAN ID checking in the matching algorithm.
0 = Do not include VLAN ID checking in the matching algorithm. */
uint64_t reserved_30_63 : 34;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmr_rx_steering_vetypex_s cn; */
};
typedef union bdk_bgxx_cmr_rx_steering_vetypex bdk_bgxx_cmr_rx_steering_vetypex_t;
static inline uint64_t BDK_BGXX_CMR_RX_STEERING_VETYPEX(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMR_RX_STEERING_VETYPEX(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=7)))
return 0x87e0e0000400ll + 0x1000000ll * ((a) & 0x1) + 8ll * ((b) & 0x7);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=7)))
return 0x87e0e0000400ll + 0x1000000ll * ((a) & 0x3) + 8ll * ((b) & 0x7);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=7)))
return 0x87e0e0000400ll + 0x1000000ll * ((a) & 0x1) + 8ll * ((b) & 0x7);
__bdk_csr_fatal("BGXX_CMR_RX_STEERING_VETYPEX", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_CMR_RX_STEERING_VETYPEX(a,b) bdk_bgxx_cmr_rx_steering_vetypex_t
#define bustype_BDK_BGXX_CMR_RX_STEERING_VETYPEX(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMR_RX_STEERING_VETYPEX(a,b) "BGXX_CMR_RX_STEERING_VETYPEX"
#define device_bar_BDK_BGXX_CMR_RX_STEERING_VETYPEX(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMR_RX_STEERING_VETYPEX(a,b) (a)
#define arguments_BDK_BGXX_CMR_RX_STEERING_VETYPEX(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_cmr_tx_lmacs
*
* BGX CMR Transmit Logical MACs Registers
* This register sets the number of LMACs allowed on the TX interface. The value is important for
* defining the partitioning of the transmit FIFO.
*/
union bdk_bgxx_cmr_tx_lmacs
{
uint64_t u;
struct bdk_bgxx_cmr_tx_lmacs_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_3_63 : 61;
uint64_t lmacs : 3; /**< [ 2: 0](R/W) Number of LMACS: Specifies the number of LMACs that can be enabled.
This determines the logical TX buffer size per LMAC and the maximum
LMAC ID that can be used:
0x0 = Reserved.
0x1 = 48 KB per LMAC, maximum LMAC ID is 0.
0x2 = 24 KB per LMAC, maximum LMAC ID is 1.
0x3 = 12 KB per LMAC, maximum LMAC ID is 2.
0x4 = 12 KB per LMAC, maximum LMAC ID is 3.
0x5-0x7 = Reserved.
The maximum LMAC ID is determined by the smaller of BGX()_CMR_RX_LMACS[LMACS]
and BGX()_CMR_TX_LMACS[LMACS]. The two fields should be set to the same value for
normal operation.' */
#else /* Word 0 - Little Endian */
uint64_t lmacs : 3; /**< [ 2: 0](R/W) Number of LMACS: Specifies the number of LMACs that can be enabled.
This determines the logical TX buffer size per LMAC and the maximum
LMAC ID that can be used:
0x0 = Reserved.
0x1 = 48 KB per LMAC, maximum LMAC ID is 0.
0x2 = 24 KB per LMAC, maximum LMAC ID is 1.
0x3 = 12 KB per LMAC, maximum LMAC ID is 2.
0x4 = 12 KB per LMAC, maximum LMAC ID is 3.
0x5-0x7 = Reserved.
The maximum LMAC ID is determined by the smaller of BGX()_CMR_RX_LMACS[LMACS]
and BGX()_CMR_TX_LMACS[LMACS]. The two fields should be set to the same value for
normal operation.' */
uint64_t reserved_3_63 : 61;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_cmr_tx_lmacs_s cn; */
};
typedef union bdk_bgxx_cmr_tx_lmacs bdk_bgxx_cmr_tx_lmacs_t;
static inline uint64_t BDK_BGXX_CMR_TX_LMACS(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CMR_TX_LMACS(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e0001000ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e0001000ll + 0x1000000ll * ((a) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && (a<=1))
return 0x87e0e0001000ll + 0x1000000ll * ((a) & 0x1);
__bdk_csr_fatal("BGXX_CMR_TX_LMACS", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_CMR_TX_LMACS(a) bdk_bgxx_cmr_tx_lmacs_t
#define bustype_BDK_BGXX_CMR_TX_LMACS(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CMR_TX_LMACS(a) "BGXX_CMR_TX_LMACS"
#define device_bar_BDK_BGXX_CMR_TX_LMACS(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CMR_TX_LMACS(a) (a)
#define arguments_BDK_BGXX_CMR_TX_LMACS(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_const
*
* BGX CONST Registers
* This register contains constants for software discovery.
*/
union bdk_bgxx_const
{
uint64_t u;
struct bdk_bgxx_const_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_32_63 : 32;
uint64_t lmacs : 8; /**< [ 31: 24](RO) Number of LMACs. */
uint64_t tx_fifosz : 24; /**< [ 23: 0](RO) Number of bytes of transmit buffering in entire BGX. This buffering may be split
between LMACs; see BGX()_CMR_TX_LMACS[LMACS]. */
#else /* Word 0 - Little Endian */
uint64_t tx_fifosz : 24; /**< [ 23: 0](RO) Number of bytes of transmit buffering in entire BGX. This buffering may be split
between LMACs; see BGX()_CMR_TX_LMACS[LMACS]. */
uint64_t lmacs : 8; /**< [ 31: 24](RO) Number of LMACs. */
uint64_t reserved_32_63 : 32;
#endif /* Word 0 - End */
} s;
struct bdk_bgxx_const_cn81xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_32_63 : 32;
uint64_t lmacs : 8; /**< [ 31: 24](RO) Number of LMACs.
If 0x0, indicates 4 LMACs, otherwise, the number of LMACs. */
uint64_t tx_fifosz : 24; /**< [ 23: 0](RO) Number of bytes of transmit buffering in entire BGX. This buffering may be split
between LMACs; see BGX()_CMR_TX_LMACS[LMACS]. If 0x0, indicates size of 0xC000. */
#else /* Word 0 - Little Endian */
uint64_t tx_fifosz : 24; /**< [ 23: 0](RO) Number of bytes of transmit buffering in entire BGX. This buffering may be split
between LMACs; see BGX()_CMR_TX_LMACS[LMACS]. If 0x0, indicates size of 0xC000. */
uint64_t lmacs : 8; /**< [ 31: 24](RO) Number of LMACs.
If 0x0, indicates 4 LMACs, otherwise, the number of LMACs. */
uint64_t reserved_32_63 : 32;
#endif /* Word 0 - End */
} cn81xx;
/* struct bdk_bgxx_const_s cn83xx; */
};
typedef union bdk_bgxx_const bdk_bgxx_const_t;
static inline uint64_t BDK_BGXX_CONST(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CONST(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e0040000ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e0040000ll + 0x1000000ll * ((a) & 0x3);
__bdk_csr_fatal("BGXX_CONST", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_CONST(a) bdk_bgxx_const_t
#define bustype_BDK_BGXX_CONST(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CONST(a) "BGXX_CONST"
#define device_bar_BDK_BGXX_CONST(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CONST(a) (a)
#define arguments_BDK_BGXX_CONST(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_const1
*
* BGX CONST1 Registers
* This register contains constants for software discovery.
*/
union bdk_bgxx_const1
{
uint64_t u;
struct bdk_bgxx_const1_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_32_63 : 32;
uint64_t res_types : 24; /**< [ 31: 8](RO) Reserved for more LMAC TYPES. */
uint64_t types : 8; /**< [ 7: 0](RO) LMAC types supported. Each bit if set corresponds to that value of BGX_LMAC_TYPES_E being
supported.
E.g. TYPES\<0\> if set indicates BGX_LMAC_TYPES_E::SGMII is supported. */
#else /* Word 0 - Little Endian */
uint64_t types : 8; /**< [ 7: 0](RO) LMAC types supported. Each bit if set corresponds to that value of BGX_LMAC_TYPES_E being
supported.
E.g. TYPES\<0\> if set indicates BGX_LMAC_TYPES_E::SGMII is supported. */
uint64_t res_types : 24; /**< [ 31: 8](RO) Reserved for more LMAC TYPES. */
uint64_t reserved_32_63 : 32;
#endif /* Word 0 - End */
} s;
struct bdk_bgxx_const1_cn81xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_32_63 : 32;
uint64_t res_types : 24; /**< [ 31: 8](RO) Reserved for more LMAC TYPES. */
uint64_t types : 8; /**< [ 7: 0](RO) LMAC types supported. Each bit if set corresponds to that value of
BGX_LMAC_TYPES_E being supported. E.g. TYPES\<5\> if set indicates
BGX_LMAC_TYPES_E::RGMII is supported. If 0x0, [TYPES] should be treated by
software as if the read value was 0x5F (all but RGMII). */
#else /* Word 0 - Little Endian */
uint64_t types : 8; /**< [ 7: 0](RO) LMAC types supported. Each bit if set corresponds to that value of
BGX_LMAC_TYPES_E being supported. E.g. TYPES\<5\> if set indicates
BGX_LMAC_TYPES_E::RGMII is supported. If 0x0, [TYPES] should be treated by
software as if the read value was 0x5F (all but RGMII). */
uint64_t res_types : 24; /**< [ 31: 8](RO) Reserved for more LMAC TYPES. */
uint64_t reserved_32_63 : 32;
#endif /* Word 0 - End */
} cn81xx;
/* struct bdk_bgxx_const1_s cn83xx; */
};
typedef union bdk_bgxx_const1 bdk_bgxx_const1_t;
static inline uint64_t BDK_BGXX_CONST1(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_CONST1(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e0040008ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e0040008ll + 0x1000000ll * ((a) & 0x3);
__bdk_csr_fatal("BGXX_CONST1", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_CONST1(a) bdk_bgxx_const1_t
#define bustype_BDK_BGXX_CONST1(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_CONST1(a) "BGXX_CONST1"
#define device_bar_BDK_BGXX_CONST1(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_CONST1(a) (a)
#define arguments_BDK_BGXX_CONST1(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_prt#_cfg
*
* BGX GMP GMI LMAC Configuration Registers
* This register controls the configuration of the LMAC.
*/
union bdk_bgxx_gmp_gmi_prtx_cfg
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_prtx_cfg_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_14_63 : 50;
uint64_t tx_idle : 1; /**< [ 13: 13](RO/H) TX machine is idle. */
uint64_t rx_idle : 1; /**< [ 12: 12](RO/H) RX machine is idle. */
uint64_t reserved_9_11 : 3;
uint64_t speed_msb : 1; /**< [ 8: 8](R/W) Link speed MSB (SGMII/QSGMII/1000Base-X only). See [SPEED]. */
uint64_t reserved_4_7 : 4;
uint64_t slottime : 1; /**< [ 3: 3](R/W) Slot time for half-duplex operation
(SGMII/QSGMII/1000Base-X only):
0 = 512 bit times (10/100 Mb/s operation).
1 = 4096 bit times (1000 Mb/s operation). */
uint64_t duplex : 1; /**< [ 2: 2](R/W) Duplex mode
(SGMII/QSGMII/1000Base-X only):
0 = half-duplex (collisions/extensions/bursts):
1 = full-duplex. */
uint64_t speed : 1; /**< [ 1: 1](R/W) Link Speed LSB (SGMII/QSGMII/1000Base-X only):
_ [SPEED_MSB,SPEED] = 0x0: 100 Mb/s operation.
_ [SPEED_MSB,SPEED] = 0x1: 1000 Mb/s operation.
_ [SPEED_MSB,SPEED] = 0x2: 10 Mb/s operation.
_ [SPEED_MSB,SPEED] = 0x3: Reserved. */
uint64_t reserved_0 : 1;
#else /* Word 0 - Little Endian */
uint64_t reserved_0 : 1;
uint64_t speed : 1; /**< [ 1: 1](R/W) Link Speed LSB (SGMII/QSGMII/1000Base-X only):
_ [SPEED_MSB,SPEED] = 0x0: 100 Mb/s operation.
_ [SPEED_MSB,SPEED] = 0x1: 1000 Mb/s operation.
_ [SPEED_MSB,SPEED] = 0x2: 10 Mb/s operation.
_ [SPEED_MSB,SPEED] = 0x3: Reserved. */
uint64_t duplex : 1; /**< [ 2: 2](R/W) Duplex mode
(SGMII/QSGMII/1000Base-X only):
0 = half-duplex (collisions/extensions/bursts):
1 = full-duplex. */
uint64_t slottime : 1; /**< [ 3: 3](R/W) Slot time for half-duplex operation
(SGMII/QSGMII/1000Base-X only):
0 = 512 bit times (10/100 Mb/s operation).
1 = 4096 bit times (1000 Mb/s operation). */
uint64_t reserved_4_7 : 4;
uint64_t speed_msb : 1; /**< [ 8: 8](R/W) Link speed MSB (SGMII/QSGMII/1000Base-X only). See [SPEED]. */
uint64_t reserved_9_11 : 3;
uint64_t rx_idle : 1; /**< [ 12: 12](RO/H) RX machine is idle. */
uint64_t tx_idle : 1; /**< [ 13: 13](RO/H) TX machine is idle. */
uint64_t reserved_14_63 : 50;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_gmi_prtx_cfg_s cn81xx; */
struct bdk_bgxx_gmp_gmi_prtx_cfg_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_14_63 : 50;
uint64_t tx_idle : 1; /**< [ 13: 13](RO/H) TX machine is idle. */
uint64_t rx_idle : 1; /**< [ 12: 12](RO/H) RX machine is idle. */
uint64_t reserved_9_11 : 3;
uint64_t speed_msb : 1; /**< [ 8: 8](R/W) Link speed MSB (SGMII/1000Base-X only). See [SPEED]. */
uint64_t reserved_4_7 : 4;
uint64_t slottime : 1; /**< [ 3: 3](R/W) Slot time for half-duplex operation
(SGMII/1000Base-X only):
0 = 512 bit times (10/100 Mb/s operation).
1 = 4096 bit times (1000 Mb/s operation). */
uint64_t duplex : 1; /**< [ 2: 2](R/W) Duplex mode
(SGMII/1000Base-X only):
0 = half-duplex (collisions/extensions/bursts).
1 = full-duplex. */
uint64_t speed : 1; /**< [ 1: 1](R/W) Link Speed LSB (SGMII/1000Base-X only):
_ [SPEED_MSB,SPEED] = 0x0: 100 Mb/s operation.
_ [SPEED_MSB,SPEED] = 0x1: 1000 Mb/s operation.
_ [SPEED_MSB,SPEED] = 0x2: 10 Mb/s operation.
_ [SPEED_MSB,SPEED] = 0x3: Reserved. */
uint64_t reserved_0 : 1;
#else /* Word 0 - Little Endian */
uint64_t reserved_0 : 1;
uint64_t speed : 1; /**< [ 1: 1](R/W) Link Speed LSB (SGMII/1000Base-X only):
_ [SPEED_MSB,SPEED] = 0x0: 100 Mb/s operation.
_ [SPEED_MSB,SPEED] = 0x1: 1000 Mb/s operation.
_ [SPEED_MSB,SPEED] = 0x2: 10 Mb/s operation.
_ [SPEED_MSB,SPEED] = 0x3: Reserved. */
uint64_t duplex : 1; /**< [ 2: 2](R/W) Duplex mode
(SGMII/1000Base-X only):
0 = half-duplex (collisions/extensions/bursts).
1 = full-duplex. */
uint64_t slottime : 1; /**< [ 3: 3](R/W) Slot time for half-duplex operation
(SGMII/1000Base-X only):
0 = 512 bit times (10/100 Mb/s operation).
1 = 4096 bit times (1000 Mb/s operation). */
uint64_t reserved_4_7 : 4;
uint64_t speed_msb : 1; /**< [ 8: 8](R/W) Link speed MSB (SGMII/1000Base-X only). See [SPEED]. */
uint64_t reserved_9_11 : 3;
uint64_t rx_idle : 1; /**< [ 12: 12](RO/H) RX machine is idle. */
uint64_t tx_idle : 1; /**< [ 13: 13](RO/H) TX machine is idle. */
uint64_t reserved_14_63 : 50;
#endif /* Word 0 - End */
} cn88xx;
/* struct bdk_bgxx_gmp_gmi_prtx_cfg_s cn83xx; */
};
typedef union bdk_bgxx_gmp_gmi_prtx_cfg bdk_bgxx_gmp_gmi_prtx_cfg_t;
static inline uint64_t BDK_BGXX_GMP_GMI_PRTX_CFG(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_PRTX_CFG(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038020ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0038020ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038020ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_GMI_PRTX_CFG", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_PRTX_CFG(a,b) bdk_bgxx_gmp_gmi_prtx_cfg_t
#define bustype_BDK_BGXX_GMP_GMI_PRTX_CFG(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_PRTX_CFG(a,b) "BGXX_GMP_GMI_PRTX_CFG"
#define device_bar_BDK_BGXX_GMP_GMI_PRTX_CFG(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_PRTX_CFG(a,b) (a)
#define arguments_BDK_BGXX_GMP_GMI_PRTX_CFG(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_rx#_decision
*
* BGX GMP Packet-Decision Registers
* This register specifies the byte count used to determine when to accept or to filter a packet.
* As each byte in a packet is received by GMI, the L2 byte count is compared against
* [CNT]. In normal operation, the L2 header begins after the
* PREAMBLE + SFD (BGX()_GMP_GMI_RX()_FRM_CTL[PRE_CHK] = 1) and any optional UDD skip
* data (BGX()_GMP_GMI_RX()_UDD_SKP[LEN]).
*
* Internal:
* Notes:
* As each byte in a packet is received by GMI, the L2 byte count is compared
* against the [CNT]. The L2 byte count is the number of bytes
* from the beginning of the L2 header (DMAC). In normal operation, the L2
* header begins after the PREAMBLE+SFD (BGX()_GMP_GMI_RX()_FRM_CTL[PRE_CHK]=1) and any
* optional UDD skip data (BGX()_GMP_GMI_RX()_UDD_SKP[LEN]).
* When BGX()_GMP_GMI_RX()_FRM_CTL[PRE_CHK] is clear, PREAMBLE+SFD are prepended to the
* packet and would require UDD skip length to account for them.
*
* Full Duplex:
* _ L2 Size \< [CNT] - Accept packet. No filtering is applied.
* _ L2 Size \>= [CNT] - Apply filter. Accept packet based on PAUSE packet filter.
*
* Half Duplex:
* _ L2 Size \< [CNT] - Drop packet. Packet is unconditionally dropped.
* _ L2 Size \>= [CNT] - Accept packet.
*
* where L2_size = MAX(0, total_packet_size - BGX()_GMP_GMI_RX()_UDD_SKP[LEN] -
* ((BGX()_GMP_GMI_RX()_FRM_CTL[PRE_CHK]==1)*8))
*/
union bdk_bgxx_gmp_gmi_rxx_decision
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_rxx_decision_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_5_63 : 59;
uint64_t cnt : 5; /**< [ 4: 0](R/W) The byte count used to decide when to accept or filter a packet. */
#else /* Word 0 - Little Endian */
uint64_t cnt : 5; /**< [ 4: 0](R/W) The byte count used to decide when to accept or filter a packet. */
uint64_t reserved_5_63 : 59;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_gmi_rxx_decision_s cn; */
};
typedef union bdk_bgxx_gmp_gmi_rxx_decision bdk_bgxx_gmp_gmi_rxx_decision_t;
static inline uint64_t BDK_BGXX_GMP_GMI_RXX_DECISION(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_RXX_DECISION(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038040ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0038040ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038040ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_GMI_RXX_DECISION", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_RXX_DECISION(a,b) bdk_bgxx_gmp_gmi_rxx_decision_t
#define bustype_BDK_BGXX_GMP_GMI_RXX_DECISION(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_RXX_DECISION(a,b) "BGXX_GMP_GMI_RXX_DECISION"
#define device_bar_BDK_BGXX_GMP_GMI_RXX_DECISION(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_RXX_DECISION(a,b) (a)
#define arguments_BDK_BGXX_GMP_GMI_RXX_DECISION(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_rx#_frm_chk
*
* BGX GMP Frame Check Registers
*/
union bdk_bgxx_gmp_gmi_rxx_frm_chk
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_rxx_frm_chk_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_9_63 : 55;
uint64_t skperr : 1; /**< [ 8: 8](R/W) Skipper error. */
uint64_t rcverr : 1; /**< [ 7: 7](R/W) Frame was received with data-reception error. */
uint64_t reserved_5_6 : 2;
uint64_t fcserr : 1; /**< [ 4: 4](R/W) Frame was received with FCS/CRC error. */
uint64_t jabber : 1; /**< [ 3: 3](R/W) Frame was received with length \> sys_length. */
uint64_t reserved_2 : 1;
uint64_t carext : 1; /**< [ 1: 1](R/W) Carrier extend error. SGMII/QSGMII/1000Base-X only. */
uint64_t minerr : 1; /**< [ 0: 0](R/W) PAUSE frame was received with length \< minFrameSize. */
#else /* Word 0 - Little Endian */
uint64_t minerr : 1; /**< [ 0: 0](R/W) PAUSE frame was received with length \< minFrameSize. */
uint64_t carext : 1; /**< [ 1: 1](R/W) Carrier extend error. SGMII/QSGMII/1000Base-X only. */
uint64_t reserved_2 : 1;
uint64_t jabber : 1; /**< [ 3: 3](R/W) Frame was received with length \> sys_length. */
uint64_t fcserr : 1; /**< [ 4: 4](R/W) Frame was received with FCS/CRC error. */
uint64_t reserved_5_6 : 2;
uint64_t rcverr : 1; /**< [ 7: 7](R/W) Frame was received with data-reception error. */
uint64_t skperr : 1; /**< [ 8: 8](R/W) Skipper error. */
uint64_t reserved_9_63 : 55;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_gmi_rxx_frm_chk_s cn81xx; */
struct bdk_bgxx_gmp_gmi_rxx_frm_chk_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_9_63 : 55;
uint64_t skperr : 1; /**< [ 8: 8](R/W) Skipper error. */
uint64_t rcverr : 1; /**< [ 7: 7](R/W) Frame was received with data-reception error. */
uint64_t reserved_5_6 : 2;
uint64_t fcserr : 1; /**< [ 4: 4](R/W) Frame was received with FCS/CRC error. */
uint64_t jabber : 1; /**< [ 3: 3](R/W) Frame was received with length \> sys_length. */
uint64_t reserved_2 : 1;
uint64_t carext : 1; /**< [ 1: 1](R/W) Carrier extend error. SGMII/1000Base-X only. */
uint64_t minerr : 1; /**< [ 0: 0](R/W) PAUSE frame was received with length \< minFrameSize. */
#else /* Word 0 - Little Endian */
uint64_t minerr : 1; /**< [ 0: 0](R/W) PAUSE frame was received with length \< minFrameSize. */
uint64_t carext : 1; /**< [ 1: 1](R/W) Carrier extend error. SGMII/1000Base-X only. */
uint64_t reserved_2 : 1;
uint64_t jabber : 1; /**< [ 3: 3](R/W) Frame was received with length \> sys_length. */
uint64_t fcserr : 1; /**< [ 4: 4](R/W) Frame was received with FCS/CRC error. */
uint64_t reserved_5_6 : 2;
uint64_t rcverr : 1; /**< [ 7: 7](R/W) Frame was received with data-reception error. */
uint64_t skperr : 1; /**< [ 8: 8](R/W) Skipper error. */
uint64_t reserved_9_63 : 55;
#endif /* Word 0 - End */
} cn88xx;
/* struct bdk_bgxx_gmp_gmi_rxx_frm_chk_s cn83xx; */
};
typedef union bdk_bgxx_gmp_gmi_rxx_frm_chk bdk_bgxx_gmp_gmi_rxx_frm_chk_t;
static inline uint64_t BDK_BGXX_GMP_GMI_RXX_FRM_CHK(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_RXX_FRM_CHK(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038030ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0038030ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038030ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_GMI_RXX_FRM_CHK", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_RXX_FRM_CHK(a,b) bdk_bgxx_gmp_gmi_rxx_frm_chk_t
#define bustype_BDK_BGXX_GMP_GMI_RXX_FRM_CHK(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_RXX_FRM_CHK(a,b) "BGXX_GMP_GMI_RXX_FRM_CHK"
#define device_bar_BDK_BGXX_GMP_GMI_RXX_FRM_CHK(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_RXX_FRM_CHK(a,b) (a)
#define arguments_BDK_BGXX_GMP_GMI_RXX_FRM_CHK(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_rx#_frm_ctl
*
* BGX GMP Frame Control Registers
* This register controls the handling of the frames.
* The [CTL_BCK] and [CTL_DRP] bits control how the hardware handles incoming PAUSE packets. The
* most
* common modes of operation:
* _ [CTL_BCK] = 1, [CTL_DRP] = 1: hardware handles everything.
* _ [CTL_BCK] = 0, [CTL_DRP] = 0: software sees all PAUSE frames.
* _ [CTL_BCK] = 0, [CTL_DRP] = 1: all PAUSE frames are completely ignored.
*
* These control bits should be set to [CTL_BCK] = 0, [CTL_DRP] = 0 in half-duplex mode. Since
* PAUSE
* packets only apply to full duplex operation, any PAUSE packet would constitute an exception
* which should be handled by the processing cores. PAUSE packets should not be forwarded.
*
* Internal:
* Notes:
* [PRE_STRP]:
* When [PRE_CHK] is set (indicating that the PREAMBLE will be sent), [PRE_STRP]
* determines if the PREAMBLE+SFD bytes are thrown away or sent to the Octane
* core as part of the packet.
* In either mode, the PREAMBLE+SFD bytes are not counted toward the packet
* size when checking against the MIN and MAX bounds. Furthermore, the bytes
* are skipped when locating the start of the L2 header for DMAC and Control
* frame recognition.
*/
union bdk_bgxx_gmp_gmi_rxx_frm_ctl
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_rxx_frm_ctl_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_14_63 : 50;
uint64_t rx_fc_type : 1; /**< [ 13: 13](R/W) Receive side flow control type select.
0 = GMI MAC receives and processes ITU G.999.1 pause frames.
1 = GMI MAC receives and processes 802.3 pause frames. */
uint64_t ptp_mode : 1; /**< [ 12: 12](R/W) Timestamp mode. When [PTP_MODE] is set, a 64-bit timestamp is prepended to every incoming
packet.
The timestamp bytes are added to the packet in such a way as to not modify the packet's
receive byte count. This implies that the BGX()_GMP_GMI_RX()_JABBER,
BGX()_GMP_GMI_RX()_DECISION, BGX()_GMP_GMI_RX()_UDD_SKP, and
BGX()_CMR()_RX_STAT0..BGX()_CMR()_RX_STAT8
do not require any adjustment as they operate on the received
packet size. When the packet reaches NIC, its size reflects the additional bytes. */
uint64_t reserved_11 : 1;
uint64_t null_dis : 1; /**< [ 10: 10](R/W) When set, do not modify the MOD bits on NULL ticks due to partial packets. */
uint64_t pre_align : 1; /**< [ 9: 9](R/W) When set, PREAMBLE parser aligns the SFD byte regardless of the number of previous
PREAMBLE nibbles. In this mode, [PRE_STRP] should be set to account for the variable
nature of the PREAMBLE. [PRE_CHK] must be set to enable this and all PREAMBLE features.
SGMII at 10/100Mbs only. */
uint64_t reserved_7_8 : 2;
uint64_t pre_free : 1; /**< [ 6: 6](RO/H) When set, PREAMBLE checking is less strict. GMI will begin the frame at the first SFD.
[PRE_CHK] must be set to enable this and all PREAMBLE features. SGMII/QSGMII/1000Base-X
only. */
uint64_t ctl_smac : 1; /**< [ 5: 5](R/W) Control PAUSE frames can match station SMAC. */
uint64_t ctl_mcst : 1; /**< [ 4: 4](R/W) Control PAUSE frames can match globally assigned multicast address. */
uint64_t ctl_bck : 1; /**< [ 3: 3](R/W) Forward PAUSE information to TX block. */
uint64_t ctl_drp : 1; /**< [ 2: 2](R/W) Drop control-PAUSE frames. */
uint64_t pre_strp : 1; /**< [ 1: 1](R/W) Strip off the preamble (when present).
0 = PREAMBLE + SFD is sent to core as part of frame.
1 = PREAMBLE + SFD is dropped.
[PRE_CHK] must be set to enable this and all PREAMBLE features.
If [PTP_MODE]=1 and [PRE_CHK]=1, [PRE_STRP] must be 1.
When [PRE_CHK] is set (indicating that the PREAMBLE will be sent), [PRE_STRP] determines
if
the PREAMBLE+SFD bytes are thrown away or sent to the core as part of the packet. In
either mode, the PREAMBLE+SFD bytes are not counted toward the packet size when checking
against the MIN and MAX bounds. Furthermore, the bytes are skipped when locating the start
of the L2 header for DMAC and control frame recognition. */
uint64_t pre_chk : 1; /**< [ 0: 0](R/W) Check the preamble for correctness. This port is configured to send a valid 802.3 PREAMBLE
to begin every frame. GMI checks that a valid PREAMBLE is received (based on [PRE_FREE]).
When a problem does occur within the PREAMBLE sequence, the frame is marked as bad and not
sent into the core. The BGX()_GMP()_RX_INT[PCTERR] interrupt is also raised. */
#else /* Word 0 - Little Endian */
uint64_t pre_chk : 1; /**< [ 0: 0](R/W) Check the preamble for correctness. This port is configured to send a valid 802.3 PREAMBLE
to begin every frame. GMI checks that a valid PREAMBLE is received (based on [PRE_FREE]).
When a problem does occur within the PREAMBLE sequence, the frame is marked as bad and not
sent into the core. The BGX()_GMP()_RX_INT[PCTERR] interrupt is also raised. */
uint64_t pre_strp : 1; /**< [ 1: 1](R/W) Strip off the preamble (when present).
0 = PREAMBLE + SFD is sent to core as part of frame.
1 = PREAMBLE + SFD is dropped.
[PRE_CHK] must be set to enable this and all PREAMBLE features.
If [PTP_MODE]=1 and [PRE_CHK]=1, [PRE_STRP] must be 1.
When [PRE_CHK] is set (indicating that the PREAMBLE will be sent), [PRE_STRP] determines
if
the PREAMBLE+SFD bytes are thrown away or sent to the core as part of the packet. In
either mode, the PREAMBLE+SFD bytes are not counted toward the packet size when checking
against the MIN and MAX bounds. Furthermore, the bytes are skipped when locating the start
of the L2 header for DMAC and control frame recognition. */
uint64_t ctl_drp : 1; /**< [ 2: 2](R/W) Drop control-PAUSE frames. */
uint64_t ctl_bck : 1; /**< [ 3: 3](R/W) Forward PAUSE information to TX block. */
uint64_t ctl_mcst : 1; /**< [ 4: 4](R/W) Control PAUSE frames can match globally assigned multicast address. */
uint64_t ctl_smac : 1; /**< [ 5: 5](R/W) Control PAUSE frames can match station SMAC. */
uint64_t pre_free : 1; /**< [ 6: 6](RO/H) When set, PREAMBLE checking is less strict. GMI will begin the frame at the first SFD.
[PRE_CHK] must be set to enable this and all PREAMBLE features. SGMII/QSGMII/1000Base-X
only. */
uint64_t reserved_7_8 : 2;
uint64_t pre_align : 1; /**< [ 9: 9](R/W) When set, PREAMBLE parser aligns the SFD byte regardless of the number of previous
PREAMBLE nibbles. In this mode, [PRE_STRP] should be set to account for the variable
nature of the PREAMBLE. [PRE_CHK] must be set to enable this and all PREAMBLE features.
SGMII at 10/100Mbs only. */
uint64_t null_dis : 1; /**< [ 10: 10](R/W) When set, do not modify the MOD bits on NULL ticks due to partial packets. */
uint64_t reserved_11 : 1;
uint64_t ptp_mode : 1; /**< [ 12: 12](R/W) Timestamp mode. When [PTP_MODE] is set, a 64-bit timestamp is prepended to every incoming
packet.
The timestamp bytes are added to the packet in such a way as to not modify the packet's
receive byte count. This implies that the BGX()_GMP_GMI_RX()_JABBER,
BGX()_GMP_GMI_RX()_DECISION, BGX()_GMP_GMI_RX()_UDD_SKP, and
BGX()_CMR()_RX_STAT0..BGX()_CMR()_RX_STAT8
do not require any adjustment as they operate on the received
packet size. When the packet reaches NIC, its size reflects the additional bytes. */
uint64_t rx_fc_type : 1; /**< [ 13: 13](R/W) Receive side flow control type select.
0 = GMI MAC receives and processes ITU G.999.1 pause frames.
1 = GMI MAC receives and processes 802.3 pause frames. */
uint64_t reserved_14_63 : 50;
#endif /* Word 0 - End */
} s;
struct bdk_bgxx_gmp_gmi_rxx_frm_ctl_cn81xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_14_63 : 50;
uint64_t rx_fc_type : 1; /**< [ 13: 13](R/W) Receive side flow control type select.
0 = GMI MAC receives and processes ITU G.999.1 pause frames.
1 = GMI MAC receives and processes 802.3 pause frames. */
uint64_t ptp_mode : 1; /**< [ 12: 12](R/W) Timestamp mode. When [PTP_MODE] is set, a 64-bit timestamp is prepended to every incoming
packet.
The timestamp bytes are added to the packet in such a way as to not modify the packet's
receive byte count. This implies that the BGX()_GMP_GMI_RX()_JABBER,
BGX()_GMP_GMI_RX()_DECISION, BGX()_GMP_GMI_RX()_UDD_SKP, and
BGX()_CMR()_RX_STAT0..BGX()_CMR()_RX_STAT8
do not require any adjustment as they operate on the received
packet size. When the packet reaches NIC, its size reflects the additional bytes. */
uint64_t reserved_11 : 1;
uint64_t null_dis : 1; /**< [ 10: 10](R/W) When set, do not modify the MOD bits on NULL ticks due to partial packets. */
uint64_t pre_align : 1; /**< [ 9: 9](R/W) When set, PREAMBLE parser aligns the SFD byte regardless of the number of previous
PREAMBLE nibbles. In this mode, [PRE_STRP] should be set to account for the variable
nature of the PREAMBLE. [PRE_CHK] must be set to enable this and all PREAMBLE features.
SGMII at 10/100Mbs only. */
uint64_t reserved_8 : 1;
uint64_t reserved_7 : 1;
uint64_t pre_free : 1; /**< [ 6: 6](RO/H) When set, PREAMBLE checking is less strict. GMI will begin the frame at the first SFD.
[PRE_CHK] must be set to enable this and all PREAMBLE features. SGMII/QSGMII/1000Base-X
only. */
uint64_t ctl_smac : 1; /**< [ 5: 5](R/W) Control PAUSE frames can match station SMAC. */
uint64_t ctl_mcst : 1; /**< [ 4: 4](R/W) Control PAUSE frames can match globally assigned multicast address. */
uint64_t ctl_bck : 1; /**< [ 3: 3](R/W) Forward PAUSE information to TX block. */
uint64_t ctl_drp : 1; /**< [ 2: 2](R/W) Drop control-PAUSE frames. */
uint64_t pre_strp : 1; /**< [ 1: 1](R/W) Strip off the preamble (when present).
0 = PREAMBLE + SFD is sent to core as part of frame.
1 = PREAMBLE + SFD is dropped.
[PRE_CHK] must be set to enable this and all PREAMBLE features.
If [PTP_MODE]=1 and [PRE_CHK]=1, [PRE_STRP] must be 1.
When [PRE_CHK] is set (indicating that the PREAMBLE will be sent), [PRE_STRP] determines
if
the PREAMBLE+SFD bytes are thrown away or sent to the core as part of the packet. In
either mode, the PREAMBLE+SFD bytes are not counted toward the packet size when checking
against the MIN and MAX bounds. Furthermore, the bytes are skipped when locating the start
of the L2 header for DMAC and control frame recognition. */
uint64_t pre_chk : 1; /**< [ 0: 0](R/W) Check the preamble for correctness. This port is configured to send a valid 802.3 PREAMBLE
to begin every frame. GMI checks that a valid PREAMBLE is received (based on [PRE_FREE]).
When a problem does occur within the PREAMBLE sequence, the frame is marked as bad and not
sent into the core. The BGX()_GMP()_RX_INT[PCTERR] interrupt is also raised. */
#else /* Word 0 - Little Endian */
uint64_t pre_chk : 1; /**< [ 0: 0](R/W) Check the preamble for correctness. This port is configured to send a valid 802.3 PREAMBLE
to begin every frame. GMI checks that a valid PREAMBLE is received (based on [PRE_FREE]).
When a problem does occur within the PREAMBLE sequence, the frame is marked as bad and not
sent into the core. The BGX()_GMP()_RX_INT[PCTERR] interrupt is also raised. */
uint64_t pre_strp : 1; /**< [ 1: 1](R/W) Strip off the preamble (when present).
0 = PREAMBLE + SFD is sent to core as part of frame.
1 = PREAMBLE + SFD is dropped.
[PRE_CHK] must be set to enable this and all PREAMBLE features.
If [PTP_MODE]=1 and [PRE_CHK]=1, [PRE_STRP] must be 1.
When [PRE_CHK] is set (indicating that the PREAMBLE will be sent), [PRE_STRP] determines
if
the PREAMBLE+SFD bytes are thrown away or sent to the core as part of the packet. In
either mode, the PREAMBLE+SFD bytes are not counted toward the packet size when checking
against the MIN and MAX bounds. Furthermore, the bytes are skipped when locating the start
of the L2 header for DMAC and control frame recognition. */
uint64_t ctl_drp : 1; /**< [ 2: 2](R/W) Drop control-PAUSE frames. */
uint64_t ctl_bck : 1; /**< [ 3: 3](R/W) Forward PAUSE information to TX block. */
uint64_t ctl_mcst : 1; /**< [ 4: 4](R/W) Control PAUSE frames can match globally assigned multicast address. */
uint64_t ctl_smac : 1; /**< [ 5: 5](R/W) Control PAUSE frames can match station SMAC. */
uint64_t pre_free : 1; /**< [ 6: 6](RO/H) When set, PREAMBLE checking is less strict. GMI will begin the frame at the first SFD.
[PRE_CHK] must be set to enable this and all PREAMBLE features. SGMII/QSGMII/1000Base-X
only. */
uint64_t reserved_7 : 1;
uint64_t reserved_8 : 1;
uint64_t pre_align : 1; /**< [ 9: 9](R/W) When set, PREAMBLE parser aligns the SFD byte regardless of the number of previous
PREAMBLE nibbles. In this mode, [PRE_STRP] should be set to account for the variable
nature of the PREAMBLE. [PRE_CHK] must be set to enable this and all PREAMBLE features.
SGMII at 10/100Mbs only. */
uint64_t null_dis : 1; /**< [ 10: 10](R/W) When set, do not modify the MOD bits on NULL ticks due to partial packets. */
uint64_t reserved_11 : 1;
uint64_t ptp_mode : 1; /**< [ 12: 12](R/W) Timestamp mode. When [PTP_MODE] is set, a 64-bit timestamp is prepended to every incoming
packet.
The timestamp bytes are added to the packet in such a way as to not modify the packet's
receive byte count. This implies that the BGX()_GMP_GMI_RX()_JABBER,
BGX()_GMP_GMI_RX()_DECISION, BGX()_GMP_GMI_RX()_UDD_SKP, and
BGX()_CMR()_RX_STAT0..BGX()_CMR()_RX_STAT8
do not require any adjustment as they operate on the received
packet size. When the packet reaches NIC, its size reflects the additional bytes. */
uint64_t rx_fc_type : 1; /**< [ 13: 13](R/W) Receive side flow control type select.
0 = GMI MAC receives and processes ITU G.999.1 pause frames.
1 = GMI MAC receives and processes 802.3 pause frames. */
uint64_t reserved_14_63 : 50;
#endif /* Word 0 - End */
} cn81xx;
struct bdk_bgxx_gmp_gmi_rxx_frm_ctl_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_13_63 : 51;
uint64_t ptp_mode : 1; /**< [ 12: 12](R/W) Timestamp mode. When [PTP_MODE] is set, a 64-bit timestamp is prepended to every incoming
packet.
The timestamp bytes are added to the packet in such a way as to not modify the packet's
receive byte count. This implies that the BGX()_GMP_GMI_RX()_JABBER,
BGX()_GMP_GMI_RX()_DECISION, BGX()_GMP_GMI_RX()_UDD_SKP, and
BGX()_CMR()_RX_STAT0..BGX()_CMR()_RX_STAT8
do not require any adjustment as they operate on the received
packet size. When the packet reaches NIC, its size reflects the additional bytes. */
uint64_t reserved_11 : 1;
uint64_t null_dis : 1; /**< [ 10: 10](R/W) When set, do not modify the MOD bits on NULL ticks due to partial packets. */
uint64_t pre_align : 1; /**< [ 9: 9](R/W) When set, PREAMBLE parser aligns the SFD byte regardless of the number of previous
PREAMBLE nibbles. In this mode, [PRE_STRP] should be set to account for the variable
nature of the PREAMBLE. [PRE_CHK] must be set to enable this and all PREAMBLE features.
SGMII at 10/100Mbs only. */
uint64_t reserved_8 : 1;
uint64_t reserved_7 : 1;
uint64_t pre_free : 1; /**< [ 6: 6](RO/H) When set, PREAMBLE checking is less strict. GMI will begin the frame at the first SFD.
[PRE_CHK] must be set to enable this and all PREAMBLE features. SGMII/1000Base-X only. */
uint64_t ctl_smac : 1; /**< [ 5: 5](R/W) Control PAUSE frames can match station SMAC. */
uint64_t ctl_mcst : 1; /**< [ 4: 4](R/W) Control PAUSE frames can match globally assigned multicast address. */
uint64_t ctl_bck : 1; /**< [ 3: 3](R/W) Forward PAUSE information to TX block. */
uint64_t ctl_drp : 1; /**< [ 2: 2](R/W) Drop control-PAUSE frames. */
uint64_t pre_strp : 1; /**< [ 1: 1](R/W) Strip off the preamble (when present).
0 = PREAMBLE + SFD is sent to core as part of frame.
1 = PREAMBLE + SFD is dropped.
[PRE_CHK] must be set to enable this and all PREAMBLE features.
If [PTP_MODE]=1 and [PRE_CHK]=1, [PRE_STRP] must be 1.
When [PRE_CHK] is set (indicating that the PREAMBLE will be sent), [PRE_STRP] determines
if
the PREAMBLE+SFD bytes are thrown away or sent to the core as part of the packet. In
either mode, the PREAMBLE+SFD bytes are not counted toward the packet size when checking
against the MIN and MAX bounds. Furthermore, the bytes are skipped when locating the start
of the L2 header for DMAC and control frame recognition. */
uint64_t pre_chk : 1; /**< [ 0: 0](R/W) Check the preamble for correctness. This port is configured to send a valid 802.3 PREAMBLE
to begin every frame. GMI checks that a valid PREAMBLE is received (based on [PRE_FREE]).
When a problem does occur within the PREAMBLE sequence, the frame is marked as bad and not
sent into the core. The BGX()_SMU()_RX_INT[PCTERR] interrupt is also raised.
When BGX()_SMU()_TX_CTL[HG_EN] is set, [PRE_CHK] must be 0. If [PTP_MODE] = 1 and
[PRE_CHK] = 1, [PRE_STRP] must be 1. */
#else /* Word 0 - Little Endian */
uint64_t pre_chk : 1; /**< [ 0: 0](R/W) Check the preamble for correctness. This port is configured to send a valid 802.3 PREAMBLE
to begin every frame. GMI checks that a valid PREAMBLE is received (based on [PRE_FREE]).
When a problem does occur within the PREAMBLE sequence, the frame is marked as bad and not
sent into the core. The BGX()_SMU()_RX_INT[PCTERR] interrupt is also raised.
When BGX()_SMU()_TX_CTL[HG_EN] is set, [PRE_CHK] must be 0. If [PTP_MODE] = 1 and
[PRE_CHK] = 1, [PRE_STRP] must be 1. */
uint64_t pre_strp : 1; /**< [ 1: 1](R/W) Strip off the preamble (when present).
0 = PREAMBLE + SFD is sent to core as part of frame.
1 = PREAMBLE + SFD is dropped.
[PRE_CHK] must be set to enable this and all PREAMBLE features.
If [PTP_MODE]=1 and [PRE_CHK]=1, [PRE_STRP] must be 1.
When [PRE_CHK] is set (indicating that the PREAMBLE will be sent), [PRE_STRP] determines
if
the PREAMBLE+SFD bytes are thrown away or sent to the core as part of the packet. In
either mode, the PREAMBLE+SFD bytes are not counted toward the packet size when checking
against the MIN and MAX bounds. Furthermore, the bytes are skipped when locating the start
of the L2 header for DMAC and control frame recognition. */
uint64_t ctl_drp : 1; /**< [ 2: 2](R/W) Drop control-PAUSE frames. */
uint64_t ctl_bck : 1; /**< [ 3: 3](R/W) Forward PAUSE information to TX block. */
uint64_t ctl_mcst : 1; /**< [ 4: 4](R/W) Control PAUSE frames can match globally assigned multicast address. */
uint64_t ctl_smac : 1; /**< [ 5: 5](R/W) Control PAUSE frames can match station SMAC. */
uint64_t pre_free : 1; /**< [ 6: 6](RO/H) When set, PREAMBLE checking is less strict. GMI will begin the frame at the first SFD.
[PRE_CHK] must be set to enable this and all PREAMBLE features. SGMII/1000Base-X only. */
uint64_t reserved_7 : 1;
uint64_t reserved_8 : 1;
uint64_t pre_align : 1; /**< [ 9: 9](R/W) When set, PREAMBLE parser aligns the SFD byte regardless of the number of previous
PREAMBLE nibbles. In this mode, [PRE_STRP] should be set to account for the variable
nature of the PREAMBLE. [PRE_CHK] must be set to enable this and all PREAMBLE features.
SGMII at 10/100Mbs only. */
uint64_t null_dis : 1; /**< [ 10: 10](R/W) When set, do not modify the MOD bits on NULL ticks due to partial packets. */
uint64_t reserved_11 : 1;
uint64_t ptp_mode : 1; /**< [ 12: 12](R/W) Timestamp mode. When [PTP_MODE] is set, a 64-bit timestamp is prepended to every incoming
packet.
The timestamp bytes are added to the packet in such a way as to not modify the packet's
receive byte count. This implies that the BGX()_GMP_GMI_RX()_JABBER,
BGX()_GMP_GMI_RX()_DECISION, BGX()_GMP_GMI_RX()_UDD_SKP, and
BGX()_CMR()_RX_STAT0..BGX()_CMR()_RX_STAT8
do not require any adjustment as they operate on the received
packet size. When the packet reaches NIC, its size reflects the additional bytes. */
uint64_t reserved_13_63 : 51;
#endif /* Word 0 - End */
} cn88xx;
/* struct bdk_bgxx_gmp_gmi_rxx_frm_ctl_cn81xx cn83xx; */
};
typedef union bdk_bgxx_gmp_gmi_rxx_frm_ctl bdk_bgxx_gmp_gmi_rxx_frm_ctl_t;
static inline uint64_t BDK_BGXX_GMP_GMI_RXX_FRM_CTL(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_RXX_FRM_CTL(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038028ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0038028ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038028ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_GMI_RXX_FRM_CTL", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_RXX_FRM_CTL(a,b) bdk_bgxx_gmp_gmi_rxx_frm_ctl_t
#define bustype_BDK_BGXX_GMP_GMI_RXX_FRM_CTL(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_RXX_FRM_CTL(a,b) "BGXX_GMP_GMI_RXX_FRM_CTL"
#define device_bar_BDK_BGXX_GMP_GMI_RXX_FRM_CTL(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_RXX_FRM_CTL(a,b) (a)
#define arguments_BDK_BGXX_GMP_GMI_RXX_FRM_CTL(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_rx#_ifg
*
* BGX GMI Minimum Interframe-Gap Cycles Registers
* This register specifies the minimum number of interframe-gap (IFG) cycles between packets.
*/
union bdk_bgxx_gmp_gmi_rxx_ifg
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_rxx_ifg_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_4_63 : 60;
uint64_t ifg : 4; /**< [ 3: 0](R/W) Min IFG (in IFG * 8 bits) between packets used to determine IFGERR. Normally IFG is 96
bits. Values 0x1 or smaller are illegal.
Note that in some operating modes, IFG cycles can be inserted or removed in order to
achieve clock rate adaptation. For these reasons, the default value is slightly
conservative and does not check up to the full 96 bits of IFG.
(SGMII/QSGMII/1000Base-X only) */
#else /* Word 0 - Little Endian */
uint64_t ifg : 4; /**< [ 3: 0](R/W) Min IFG (in IFG * 8 bits) between packets used to determine IFGERR. Normally IFG is 96
bits. Values 0x1 or smaller are illegal.
Note that in some operating modes, IFG cycles can be inserted or removed in order to
achieve clock rate adaptation. For these reasons, the default value is slightly
conservative and does not check up to the full 96 bits of IFG.
(SGMII/QSGMII/1000Base-X only) */
uint64_t reserved_4_63 : 60;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_gmi_rxx_ifg_s cn81xx; */
struct bdk_bgxx_gmp_gmi_rxx_ifg_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_4_63 : 60;
uint64_t ifg : 4; /**< [ 3: 0](R/W) Min IFG (in IFG * 8 bits) between packets used to determine IFGERR. Normally IFG is 96
bits. Values 0x1 or smaller are illegal.
Note that in some operating modes, IFG cycles can be inserted or removed in order to
achieve clock rate adaptation. For these reasons, the default value is slightly
conservative and does not check up to the full 96 bits of IFG.
(SGMII/1000Base-X only) */
#else /* Word 0 - Little Endian */
uint64_t ifg : 4; /**< [ 3: 0](R/W) Min IFG (in IFG * 8 bits) between packets used to determine IFGERR. Normally IFG is 96
bits. Values 0x1 or smaller are illegal.
Note that in some operating modes, IFG cycles can be inserted or removed in order to
achieve clock rate adaptation. For these reasons, the default value is slightly
conservative and does not check up to the full 96 bits of IFG.
(SGMII/1000Base-X only) */
uint64_t reserved_4_63 : 60;
#endif /* Word 0 - End */
} cn88xx;
/* struct bdk_bgxx_gmp_gmi_rxx_ifg_s cn83xx; */
};
typedef union bdk_bgxx_gmp_gmi_rxx_ifg bdk_bgxx_gmp_gmi_rxx_ifg_t;
static inline uint64_t BDK_BGXX_GMP_GMI_RXX_IFG(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_RXX_IFG(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038058ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0038058ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038058ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_GMI_RXX_IFG", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_RXX_IFG(a,b) bdk_bgxx_gmp_gmi_rxx_ifg_t
#define bustype_BDK_BGXX_GMP_GMI_RXX_IFG(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_RXX_IFG(a,b) "BGXX_GMP_GMI_RXX_IFG"
#define device_bar_BDK_BGXX_GMP_GMI_RXX_IFG(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_RXX_IFG(a,b) (a)
#define arguments_BDK_BGXX_GMP_GMI_RXX_IFG(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_rx#_int
*
* BGX GMP GMI RX Interrupt Registers
* '"These registers allow interrupts to be sent to the control processor.
* * Exception conditions \<10:0\> can also set the rcv/opcode in the received packet's work-queue
* entry. BGX()_GMP_GMI_RX()_FRM_CHK provides a bit mask for configuring which conditions
* set the error.
* In half duplex operation, the expectation is that collisions will appear as either MINERR or
* CAREXT errors.'
*
* Internal:
* Notes:
* (1) exception conditions 10:0 can also set the rcv/opcode in the received
* packet's workQ entry. The BGX()_GMP_GMI_RX()_FRM_CHK register provides a bit mask
* for configuring which conditions set the error.
*
* (2) in half duplex operation, the expectation is that collisions will appear
* as either MINERR o r CAREXT errors.
*
* (3) JABBER An RX jabber error indicates that a packet was received which
* is longer than the maximum allowed packet as defined by the
* system. GMI will truncate the packet at the JABBER count.
* Failure to do so could lead to system instabilty.
*
* (4) NIBERR This error is illegal at 1000Mbs speeds
* (BGX()_GMP_GMI_PRT()_CFG[SPEED]==0) and will never assert.
*
* (5) MINERR total frame DA+SA+TL+DATA+PAD+FCS \< 64
*
* (6) ALNERR Indicates that the packet received was not an integer number of
* bytes. If FCS checking is enabled, ALNERR will only assert if
* the FCS is bad. If FCS checking is disabled, ALNERR will
* assert in all non-integer frame cases.
*
* (7) Collisions Collisions can only occur in half-duplex mode. A collision
* is assumed by the receiver when the slottime
* (BGX()_GMP_GMI_PRT()_CFG[SLOTTIME]) is not satisfied. In 10/100 mode,
* this will result in a frame \< SLOTTIME. In 1000 mode, it
* could result either in frame \< SLOTTIME or a carrier extend
* error with the SLOTTIME. These conditions are visible by...
* . transfer ended before slottime COLDET
* . carrier extend error CAREXT
*
* (A) LENERR Length errors occur when the received packet does not match the
* length field. LENERR is only checked for packets between 64
* and 1500 bytes. For untagged frames, the length must exact
* match. For tagged frames the length or length+4 must match.
*
* (B) PCTERR checks that the frame begins with a valid PREAMBLE sequence.
* Does not check the number of PREAMBLE cycles.
*
* (C) OVRERR *DON'T PUT IN HRM*
* OVRERR is an architectural assertion check internal to GMI to
* make sure no assumption was violated. In a correctly operating
* system, this interrupt can never fire.
* GMI has an internal arbiter which selects which of four ports to
* buffer in the main RX FIFO. If we normally buffer eight bytes,
* then each port will typically push a tick every eight cycles if
* the packet interface is going as fast as possible. If there
* are four ports, they push every two cycles. So that's the
* assumption. That the inbound module will always be able to
* consume the tick before another is produced. If that doesn't
* happen that's when OVRERR will assert."
*/
union bdk_bgxx_gmp_gmi_rxx_int
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_rxx_int_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_12_63 : 52;
uint64_t ifgerr : 1; /**< [ 11: 11](R/W1C/H) Interframe gap violation. Does not necessarily indicate a failure. SGMII/QSGMII/1000Base-X only. */
uint64_t coldet : 1; /**< [ 10: 10](R/W1C/H) Collision detection. Collisions can only occur in half-duplex mode. A collision is assumed
by the receiver when the slottime (BGX()_GMP_GMI_PRT()_CFG[SLOTTIME]) is not
satisfied. In 10/100 mode, this will result in a frame \< SLOTTIME. In 1000 mode, it could
result either in frame \< SLOTTIME or a carrier extend error with the SLOTTIME. These
conditions are visible by 1) transfer ended before slottime - COLDET or 2) carrier extend
error - CAREXT. */
uint64_t falerr : 1; /**< [ 9: 9](R/W1C/H) False-carrier error, or carrier-extend error after slottime is satisfied.
SGMII/QSGMII/1000Base-X only. */
uint64_t rsverr : 1; /**< [ 8: 8](R/W1C/H) Detected reserved opcode. */
uint64_t pcterr : 1; /**< [ 7: 7](R/W1C/H) Bad preamble/protocol error. Checks that the frame begins with a valid PREAMBLE sequence.
Does not check the number of PREAMBLE cycles. */
uint64_t ovrerr : 1; /**< [ 6: 6](R/W1C/H) Internal data aggregation overflow. This interrupt should never assert.
SGMII/QSGMII/1000Base-X only. */
uint64_t skperr : 1; /**< [ 5: 5](R/W1C/H) Skipper error. */
uint64_t rcverr : 1; /**< [ 4: 4](R/W1C/H) Data-reception error. Frame was received with data-reception error. */
uint64_t fcserr : 1; /**< [ 3: 3](R/W1C/H) FCS/CRC error. Frame was received with FCS/CRC error. */
uint64_t jabber : 1; /**< [ 2: 2](R/W1C/H) System-length error: frame was received with length \> sys_length.
An RX Jabber error indicates that a packet was received which is longer than the maximum
allowed packet as defined by the system. GMI truncates the packet at the JABBER count.
Failure to do so could lead to system instability. */
uint64_t carext : 1; /**< [ 1: 1](R/W1C/H) Carrier-extend error. (SGMII/QSGMII/1000Base-X only) */
uint64_t minerr : 1; /**< [ 0: 0](R/W1C/H) PAUSE frame was received with length \< minFrameSize. Frame length checks are typically
handled in NIC, but PAUSE frames are normally discarded before being inspected by NIC.
Total frame DA+SA+TL+DATA+PAD+FCS \< 64. */
#else /* Word 0 - Little Endian */
uint64_t minerr : 1; /**< [ 0: 0](R/W1C/H) PAUSE frame was received with length \< minFrameSize. Frame length checks are typically
handled in NIC, but PAUSE frames are normally discarded before being inspected by NIC.
Total frame DA+SA+TL+DATA+PAD+FCS \< 64. */
uint64_t carext : 1; /**< [ 1: 1](R/W1C/H) Carrier-extend error. (SGMII/QSGMII/1000Base-X only) */
uint64_t jabber : 1; /**< [ 2: 2](R/W1C/H) System-length error: frame was received with length \> sys_length.
An RX Jabber error indicates that a packet was received which is longer than the maximum
allowed packet as defined by the system. GMI truncates the packet at the JABBER count.
Failure to do so could lead to system instability. */
uint64_t fcserr : 1; /**< [ 3: 3](R/W1C/H) FCS/CRC error. Frame was received with FCS/CRC error. */
uint64_t rcverr : 1; /**< [ 4: 4](R/W1C/H) Data-reception error. Frame was received with data-reception error. */
uint64_t skperr : 1; /**< [ 5: 5](R/W1C/H) Skipper error. */
uint64_t ovrerr : 1; /**< [ 6: 6](R/W1C/H) Internal data aggregation overflow. This interrupt should never assert.
SGMII/QSGMII/1000Base-X only. */
uint64_t pcterr : 1; /**< [ 7: 7](R/W1C/H) Bad preamble/protocol error. Checks that the frame begins with a valid PREAMBLE sequence.
Does not check the number of PREAMBLE cycles. */
uint64_t rsverr : 1; /**< [ 8: 8](R/W1C/H) Detected reserved opcode. */
uint64_t falerr : 1; /**< [ 9: 9](R/W1C/H) False-carrier error, or carrier-extend error after slottime is satisfied.
SGMII/QSGMII/1000Base-X only. */
uint64_t coldet : 1; /**< [ 10: 10](R/W1C/H) Collision detection. Collisions can only occur in half-duplex mode. A collision is assumed
by the receiver when the slottime (BGX()_GMP_GMI_PRT()_CFG[SLOTTIME]) is not
satisfied. In 10/100 mode, this will result in a frame \< SLOTTIME. In 1000 mode, it could
result either in frame \< SLOTTIME or a carrier extend error with the SLOTTIME. These
conditions are visible by 1) transfer ended before slottime - COLDET or 2) carrier extend
error - CAREXT. */
uint64_t ifgerr : 1; /**< [ 11: 11](R/W1C/H) Interframe gap violation. Does not necessarily indicate a failure. SGMII/QSGMII/1000Base-X only. */
uint64_t reserved_12_63 : 52;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_gmi_rxx_int_s cn81xx; */
struct bdk_bgxx_gmp_gmi_rxx_int_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_12_63 : 52;
uint64_t ifgerr : 1; /**< [ 11: 11](R/W1C/H) Interframe gap violation. Does not necessarily indicate a failure. SGMII/1000Base-X only. */
uint64_t coldet : 1; /**< [ 10: 10](R/W1C/H) Collision detection. Collisions can only occur in half-duplex mode. A collision is assumed
by the receiver when the slottime (BGX()_GMP_GMI_PRT()_CFG[SLOTTIME]) is not
satisfied. In 10/100 mode, this will result in a frame \< SLOTTIME. In 1000 mode, it could
result either in frame \< SLOTTIME or a carrier extend error with the SLOTTIME. These
conditions are visible by 1) transfer ended before slottime - COLDET or 2) carrier extend
error - CAREXT. */
uint64_t falerr : 1; /**< [ 9: 9](R/W1C/H) False-carrier error, or carrier-extend error after slottime is satisfied. SGMII/1000Base-X only. */
uint64_t rsverr : 1; /**< [ 8: 8](R/W1C/H) Detected reserved opcode. */
uint64_t pcterr : 1; /**< [ 7: 7](R/W1C/H) Bad preamble/protocol error. Checks that the frame begins with a valid PREAMBLE sequence.
Does not check the number of PREAMBLE cycles. */
uint64_t ovrerr : 1; /**< [ 6: 6](R/W1C/H) Internal data aggregation overflow. This interrupt should never assert. SGMII/1000Base-X only. */
uint64_t skperr : 1; /**< [ 5: 5](R/W1C/H) Skipper error. */
uint64_t rcverr : 1; /**< [ 4: 4](R/W1C/H) Data-reception error. Frame was received with data-reception error. */
uint64_t fcserr : 1; /**< [ 3: 3](R/W1C/H) FCS/CRC error. Frame was received with FCS/CRC error. */
uint64_t jabber : 1; /**< [ 2: 2](R/W1C/H) System-length error: frame was received with length \> sys_length.
An RX Jabber error indicates that a packet was received which is longer than the maximum
allowed packet as defined by the system. GMI truncates the packet at the JABBER count.
Failure to do so could lead to system instability. */
uint64_t carext : 1; /**< [ 1: 1](R/W1C/H) Carrier-extend error. (SGMII/1000Base-X only) */
uint64_t minerr : 1; /**< [ 0: 0](R/W1C/H) PAUSE frame was received with length \< minFrameSize. Frame length checks are typically
handled in NIC, but PAUSE frames are normally discarded before being inspected by NIC.
Total frame DA+SA+TL+DATA+PAD+FCS \< 64. */
#else /* Word 0 - Little Endian */
uint64_t minerr : 1; /**< [ 0: 0](R/W1C/H) PAUSE frame was received with length \< minFrameSize. Frame length checks are typically
handled in NIC, but PAUSE frames are normally discarded before being inspected by NIC.
Total frame DA+SA+TL+DATA+PAD+FCS \< 64. */
uint64_t carext : 1; /**< [ 1: 1](R/W1C/H) Carrier-extend error. (SGMII/1000Base-X only) */
uint64_t jabber : 1; /**< [ 2: 2](R/W1C/H) System-length error: frame was received with length \> sys_length.
An RX Jabber error indicates that a packet was received which is longer than the maximum
allowed packet as defined by the system. GMI truncates the packet at the JABBER count.
Failure to do so could lead to system instability. */
uint64_t fcserr : 1; /**< [ 3: 3](R/W1C/H) FCS/CRC error. Frame was received with FCS/CRC error. */
uint64_t rcverr : 1; /**< [ 4: 4](R/W1C/H) Data-reception error. Frame was received with data-reception error. */
uint64_t skperr : 1; /**< [ 5: 5](R/W1C/H) Skipper error. */
uint64_t ovrerr : 1; /**< [ 6: 6](R/W1C/H) Internal data aggregation overflow. This interrupt should never assert. SGMII/1000Base-X only. */
uint64_t pcterr : 1; /**< [ 7: 7](R/W1C/H) Bad preamble/protocol error. Checks that the frame begins with a valid PREAMBLE sequence.
Does not check the number of PREAMBLE cycles. */
uint64_t rsverr : 1; /**< [ 8: 8](R/W1C/H) Detected reserved opcode. */
uint64_t falerr : 1; /**< [ 9: 9](R/W1C/H) False-carrier error, or carrier-extend error after slottime is satisfied. SGMII/1000Base-X only. */
uint64_t coldet : 1; /**< [ 10: 10](R/W1C/H) Collision detection. Collisions can only occur in half-duplex mode. A collision is assumed
by the receiver when the slottime (BGX()_GMP_GMI_PRT()_CFG[SLOTTIME]) is not
satisfied. In 10/100 mode, this will result in a frame \< SLOTTIME. In 1000 mode, it could
result either in frame \< SLOTTIME or a carrier extend error with the SLOTTIME. These
conditions are visible by 1) transfer ended before slottime - COLDET or 2) carrier extend
error - CAREXT. */
uint64_t ifgerr : 1; /**< [ 11: 11](R/W1C/H) Interframe gap violation. Does not necessarily indicate a failure. SGMII/1000Base-X only. */
uint64_t reserved_12_63 : 52;
#endif /* Word 0 - End */
} cn88xx;
/* struct bdk_bgxx_gmp_gmi_rxx_int_s cn83xx; */
};
typedef union bdk_bgxx_gmp_gmi_rxx_int bdk_bgxx_gmp_gmi_rxx_int_t;
static inline uint64_t BDK_BGXX_GMP_GMI_RXX_INT(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_RXX_INT(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038000ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0038000ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038000ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_GMI_RXX_INT", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_RXX_INT(a,b) bdk_bgxx_gmp_gmi_rxx_int_t
#define bustype_BDK_BGXX_GMP_GMI_RXX_INT(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_RXX_INT(a,b) "BGXX_GMP_GMI_RXX_INT"
#define device_bar_BDK_BGXX_GMP_GMI_RXX_INT(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_RXX_INT(a,b) (a)
#define arguments_BDK_BGXX_GMP_GMI_RXX_INT(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_rx#_int_ena_w1c
*
* BGX GMP GMI RX Interrupt Enable Clear Registers
* This register clears interrupt enable bits.
*/
union bdk_bgxx_gmp_gmi_rxx_int_ena_w1c
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_rxx_int_ena_w1c_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_12_63 : 52;
uint64_t ifgerr : 1; /**< [ 11: 11](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[IFGERR]. */
uint64_t coldet : 1; /**< [ 10: 10](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[COLDET]. */
uint64_t falerr : 1; /**< [ 9: 9](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[FALERR]. */
uint64_t rsverr : 1; /**< [ 8: 8](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[RSVERR]. */
uint64_t pcterr : 1; /**< [ 7: 7](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[PCTERR]. */
uint64_t ovrerr : 1; /**< [ 6: 6](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[OVRERR]. */
uint64_t skperr : 1; /**< [ 5: 5](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[SKPERR]. */
uint64_t rcverr : 1; /**< [ 4: 4](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[RCVERR]. */
uint64_t fcserr : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[FCSERR]. */
uint64_t jabber : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[JABBER]. */
uint64_t carext : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[CAREXT]. */
uint64_t minerr : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[MINERR]. */
#else /* Word 0 - Little Endian */
uint64_t minerr : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[MINERR]. */
uint64_t carext : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[CAREXT]. */
uint64_t jabber : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[JABBER]. */
uint64_t fcserr : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[FCSERR]. */
uint64_t rcverr : 1; /**< [ 4: 4](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[RCVERR]. */
uint64_t skperr : 1; /**< [ 5: 5](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[SKPERR]. */
uint64_t ovrerr : 1; /**< [ 6: 6](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[OVRERR]. */
uint64_t pcterr : 1; /**< [ 7: 7](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[PCTERR]. */
uint64_t rsverr : 1; /**< [ 8: 8](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[RSVERR]. */
uint64_t falerr : 1; /**< [ 9: 9](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[FALERR]. */
uint64_t coldet : 1; /**< [ 10: 10](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[COLDET]. */
uint64_t ifgerr : 1; /**< [ 11: 11](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[IFGERR]. */
uint64_t reserved_12_63 : 52;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_gmi_rxx_int_ena_w1c_s cn81xx; */
/* struct bdk_bgxx_gmp_gmi_rxx_int_ena_w1c_s cn88xx; */
struct bdk_bgxx_gmp_gmi_rxx_int_ena_w1c_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_12_63 : 52;
uint64_t ifgerr : 1; /**< [ 11: 11](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[IFGERR]. */
uint64_t coldet : 1; /**< [ 10: 10](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[COLDET]. */
uint64_t falerr : 1; /**< [ 9: 9](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[FALERR]. */
uint64_t rsverr : 1; /**< [ 8: 8](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[RSVERR]. */
uint64_t pcterr : 1; /**< [ 7: 7](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[PCTERR]. */
uint64_t ovrerr : 1; /**< [ 6: 6](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[OVRERR]. */
uint64_t skperr : 1; /**< [ 5: 5](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[SKPERR]. */
uint64_t rcverr : 1; /**< [ 4: 4](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[RCVERR]. */
uint64_t fcserr : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[FCSERR]. */
uint64_t jabber : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[JABBER]. */
uint64_t carext : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[CAREXT]. */
uint64_t minerr : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[MINERR]. */
#else /* Word 0 - Little Endian */
uint64_t minerr : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[MINERR]. */
uint64_t carext : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[CAREXT]. */
uint64_t jabber : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[JABBER]. */
uint64_t fcserr : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[FCSERR]. */
uint64_t rcverr : 1; /**< [ 4: 4](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[RCVERR]. */
uint64_t skperr : 1; /**< [ 5: 5](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[SKPERR]. */
uint64_t ovrerr : 1; /**< [ 6: 6](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[OVRERR]. */
uint64_t pcterr : 1; /**< [ 7: 7](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[PCTERR]. */
uint64_t rsverr : 1; /**< [ 8: 8](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[RSVERR]. */
uint64_t falerr : 1; /**< [ 9: 9](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[FALERR]. */
uint64_t coldet : 1; /**< [ 10: 10](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[COLDET]. */
uint64_t ifgerr : 1; /**< [ 11: 11](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[IFGERR]. */
uint64_t reserved_12_63 : 52;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_gmp_gmi_rxx_int_ena_w1c bdk_bgxx_gmp_gmi_rxx_int_ena_w1c_t;
static inline uint64_t BDK_BGXX_GMP_GMI_RXX_INT_ENA_W1C(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_RXX_INT_ENA_W1C(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038010ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0038010ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038010ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_GMI_RXX_INT_ENA_W1C", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_RXX_INT_ENA_W1C(a,b) bdk_bgxx_gmp_gmi_rxx_int_ena_w1c_t
#define bustype_BDK_BGXX_GMP_GMI_RXX_INT_ENA_W1C(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_RXX_INT_ENA_W1C(a,b) "BGXX_GMP_GMI_RXX_INT_ENA_W1C"
#define device_bar_BDK_BGXX_GMP_GMI_RXX_INT_ENA_W1C(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_RXX_INT_ENA_W1C(a,b) (a)
#define arguments_BDK_BGXX_GMP_GMI_RXX_INT_ENA_W1C(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_rx#_int_ena_w1s
*
* BGX GMP GMI RX Interrupt Enable Set Registers
* This register sets interrupt enable bits.
*/
union bdk_bgxx_gmp_gmi_rxx_int_ena_w1s
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_rxx_int_ena_w1s_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_12_63 : 52;
uint64_t ifgerr : 1; /**< [ 11: 11](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[IFGERR]. */
uint64_t coldet : 1; /**< [ 10: 10](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[COLDET]. */
uint64_t falerr : 1; /**< [ 9: 9](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[FALERR]. */
uint64_t rsverr : 1; /**< [ 8: 8](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[RSVERR]. */
uint64_t pcterr : 1; /**< [ 7: 7](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[PCTERR]. */
uint64_t ovrerr : 1; /**< [ 6: 6](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[OVRERR]. */
uint64_t skperr : 1; /**< [ 5: 5](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[SKPERR]. */
uint64_t rcverr : 1; /**< [ 4: 4](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[RCVERR]. */
uint64_t fcserr : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[FCSERR]. */
uint64_t jabber : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[JABBER]. */
uint64_t carext : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[CAREXT]. */
uint64_t minerr : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[MINERR]. */
#else /* Word 0 - Little Endian */
uint64_t minerr : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[MINERR]. */
uint64_t carext : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[CAREXT]. */
uint64_t jabber : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[JABBER]. */
uint64_t fcserr : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[FCSERR]. */
uint64_t rcverr : 1; /**< [ 4: 4](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[RCVERR]. */
uint64_t skperr : 1; /**< [ 5: 5](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[SKPERR]. */
uint64_t ovrerr : 1; /**< [ 6: 6](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[OVRERR]. */
uint64_t pcterr : 1; /**< [ 7: 7](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[PCTERR]. */
uint64_t rsverr : 1; /**< [ 8: 8](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[RSVERR]. */
uint64_t falerr : 1; /**< [ 9: 9](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[FALERR]. */
uint64_t coldet : 1; /**< [ 10: 10](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[COLDET]. */
uint64_t ifgerr : 1; /**< [ 11: 11](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_RX(0..3)_INT[IFGERR]. */
uint64_t reserved_12_63 : 52;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_gmi_rxx_int_ena_w1s_s cn81xx; */
/* struct bdk_bgxx_gmp_gmi_rxx_int_ena_w1s_s cn88xx; */
struct bdk_bgxx_gmp_gmi_rxx_int_ena_w1s_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_12_63 : 52;
uint64_t ifgerr : 1; /**< [ 11: 11](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[IFGERR]. */
uint64_t coldet : 1; /**< [ 10: 10](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[COLDET]. */
uint64_t falerr : 1; /**< [ 9: 9](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[FALERR]. */
uint64_t rsverr : 1; /**< [ 8: 8](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[RSVERR]. */
uint64_t pcterr : 1; /**< [ 7: 7](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[PCTERR]. */
uint64_t ovrerr : 1; /**< [ 6: 6](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[OVRERR]. */
uint64_t skperr : 1; /**< [ 5: 5](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[SKPERR]. */
uint64_t rcverr : 1; /**< [ 4: 4](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[RCVERR]. */
uint64_t fcserr : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[FCSERR]. */
uint64_t jabber : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[JABBER]. */
uint64_t carext : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[CAREXT]. */
uint64_t minerr : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[MINERR]. */
#else /* Word 0 - Little Endian */
uint64_t minerr : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[MINERR]. */
uint64_t carext : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[CAREXT]. */
uint64_t jabber : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[JABBER]. */
uint64_t fcserr : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[FCSERR]. */
uint64_t rcverr : 1; /**< [ 4: 4](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[RCVERR]. */
uint64_t skperr : 1; /**< [ 5: 5](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[SKPERR]. */
uint64_t ovrerr : 1; /**< [ 6: 6](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[OVRERR]. */
uint64_t pcterr : 1; /**< [ 7: 7](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[PCTERR]. */
uint64_t rsverr : 1; /**< [ 8: 8](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[RSVERR]. */
uint64_t falerr : 1; /**< [ 9: 9](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[FALERR]. */
uint64_t coldet : 1; /**< [ 10: 10](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[COLDET]. */
uint64_t ifgerr : 1; /**< [ 11: 11](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_RX(0..3)_INT[IFGERR]. */
uint64_t reserved_12_63 : 52;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_gmp_gmi_rxx_int_ena_w1s bdk_bgxx_gmp_gmi_rxx_int_ena_w1s_t;
static inline uint64_t BDK_BGXX_GMP_GMI_RXX_INT_ENA_W1S(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_RXX_INT_ENA_W1S(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038018ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0038018ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038018ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_GMI_RXX_INT_ENA_W1S", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_RXX_INT_ENA_W1S(a,b) bdk_bgxx_gmp_gmi_rxx_int_ena_w1s_t
#define bustype_BDK_BGXX_GMP_GMI_RXX_INT_ENA_W1S(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_RXX_INT_ENA_W1S(a,b) "BGXX_GMP_GMI_RXX_INT_ENA_W1S"
#define device_bar_BDK_BGXX_GMP_GMI_RXX_INT_ENA_W1S(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_RXX_INT_ENA_W1S(a,b) (a)
#define arguments_BDK_BGXX_GMP_GMI_RXX_INT_ENA_W1S(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_rx#_int_w1s
*
* BGX GMP GMI RX Interrupt Set Registers
* This register sets interrupt bits.
*/
union bdk_bgxx_gmp_gmi_rxx_int_w1s
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_rxx_int_w1s_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_12_63 : 52;
uint64_t ifgerr : 1; /**< [ 11: 11](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_RX(0..3)_INT[IFGERR]. */
uint64_t coldet : 1; /**< [ 10: 10](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_RX(0..3)_INT[COLDET]. */
uint64_t falerr : 1; /**< [ 9: 9](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_RX(0..3)_INT[FALERR]. */
uint64_t rsverr : 1; /**< [ 8: 8](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_RX(0..3)_INT[RSVERR]. */
uint64_t pcterr : 1; /**< [ 7: 7](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_RX(0..3)_INT[PCTERR]. */
uint64_t ovrerr : 1; /**< [ 6: 6](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_RX(0..3)_INT[OVRERR]. */
uint64_t skperr : 1; /**< [ 5: 5](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_RX(0..3)_INT[SKPERR]. */
uint64_t rcverr : 1; /**< [ 4: 4](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_RX(0..3)_INT[RCVERR]. */
uint64_t fcserr : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_RX(0..3)_INT[FCSERR]. */
uint64_t jabber : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_RX(0..3)_INT[JABBER]. */
uint64_t carext : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_RX(0..3)_INT[CAREXT]. */
uint64_t minerr : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_RX(0..3)_INT[MINERR]. */
#else /* Word 0 - Little Endian */
uint64_t minerr : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_RX(0..3)_INT[MINERR]. */
uint64_t carext : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_RX(0..3)_INT[CAREXT]. */
uint64_t jabber : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_RX(0..3)_INT[JABBER]. */
uint64_t fcserr : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_RX(0..3)_INT[FCSERR]. */
uint64_t rcverr : 1; /**< [ 4: 4](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_RX(0..3)_INT[RCVERR]. */
uint64_t skperr : 1; /**< [ 5: 5](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_RX(0..3)_INT[SKPERR]. */
uint64_t ovrerr : 1; /**< [ 6: 6](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_RX(0..3)_INT[OVRERR]. */
uint64_t pcterr : 1; /**< [ 7: 7](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_RX(0..3)_INT[PCTERR]. */
uint64_t rsverr : 1; /**< [ 8: 8](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_RX(0..3)_INT[RSVERR]. */
uint64_t falerr : 1; /**< [ 9: 9](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_RX(0..3)_INT[FALERR]. */
uint64_t coldet : 1; /**< [ 10: 10](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_RX(0..3)_INT[COLDET]. */
uint64_t ifgerr : 1; /**< [ 11: 11](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_RX(0..3)_INT[IFGERR]. */
uint64_t reserved_12_63 : 52;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_gmi_rxx_int_w1s_s cn81xx; */
/* struct bdk_bgxx_gmp_gmi_rxx_int_w1s_s cn88xx; */
struct bdk_bgxx_gmp_gmi_rxx_int_w1s_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_12_63 : 52;
uint64_t ifgerr : 1; /**< [ 11: 11](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_RX(0..3)_INT[IFGERR]. */
uint64_t coldet : 1; /**< [ 10: 10](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_RX(0..3)_INT[COLDET]. */
uint64_t falerr : 1; /**< [ 9: 9](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_RX(0..3)_INT[FALERR]. */
uint64_t rsverr : 1; /**< [ 8: 8](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_RX(0..3)_INT[RSVERR]. */
uint64_t pcterr : 1; /**< [ 7: 7](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_RX(0..3)_INT[PCTERR]. */
uint64_t ovrerr : 1; /**< [ 6: 6](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_RX(0..3)_INT[OVRERR]. */
uint64_t skperr : 1; /**< [ 5: 5](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_RX(0..3)_INT[SKPERR]. */
uint64_t rcverr : 1; /**< [ 4: 4](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_RX(0..3)_INT[RCVERR]. */
uint64_t fcserr : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_RX(0..3)_INT[FCSERR]. */
uint64_t jabber : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_RX(0..3)_INT[JABBER]. */
uint64_t carext : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_RX(0..3)_INT[CAREXT]. */
uint64_t minerr : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_RX(0..3)_INT[MINERR]. */
#else /* Word 0 - Little Endian */
uint64_t minerr : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_RX(0..3)_INT[MINERR]. */
uint64_t carext : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_RX(0..3)_INT[CAREXT]. */
uint64_t jabber : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_RX(0..3)_INT[JABBER]. */
uint64_t fcserr : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_RX(0..3)_INT[FCSERR]. */
uint64_t rcverr : 1; /**< [ 4: 4](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_RX(0..3)_INT[RCVERR]. */
uint64_t skperr : 1; /**< [ 5: 5](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_RX(0..3)_INT[SKPERR]. */
uint64_t ovrerr : 1; /**< [ 6: 6](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_RX(0..3)_INT[OVRERR]. */
uint64_t pcterr : 1; /**< [ 7: 7](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_RX(0..3)_INT[PCTERR]. */
uint64_t rsverr : 1; /**< [ 8: 8](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_RX(0..3)_INT[RSVERR]. */
uint64_t falerr : 1; /**< [ 9: 9](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_RX(0..3)_INT[FALERR]. */
uint64_t coldet : 1; /**< [ 10: 10](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_RX(0..3)_INT[COLDET]. */
uint64_t ifgerr : 1; /**< [ 11: 11](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_RX(0..3)_INT[IFGERR]. */
uint64_t reserved_12_63 : 52;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_gmp_gmi_rxx_int_w1s bdk_bgxx_gmp_gmi_rxx_int_w1s_t;
static inline uint64_t BDK_BGXX_GMP_GMI_RXX_INT_W1S(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_RXX_INT_W1S(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038008ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0038008ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038008ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_GMI_RXX_INT_W1S", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_RXX_INT_W1S(a,b) bdk_bgxx_gmp_gmi_rxx_int_w1s_t
#define bustype_BDK_BGXX_GMP_GMI_RXX_INT_W1S(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_RXX_INT_W1S(a,b) "BGXX_GMP_GMI_RXX_INT_W1S"
#define device_bar_BDK_BGXX_GMP_GMI_RXX_INT_W1S(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_RXX_INT_W1S(a,b) (a)
#define arguments_BDK_BGXX_GMP_GMI_RXX_INT_W1S(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_rx#_jabber
*
* BGX GMP Maximum Packet-Size Registers
* This register specifies the maximum size for packets, beyond which the GMI truncates.
*/
union bdk_bgxx_gmp_gmi_rxx_jabber
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_rxx_jabber_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t cnt : 16; /**< [ 15: 0](R/W) Byte count for jabber check. Failing packets set the JABBER interrupt and are optionally
sent with opcode = JABBER. GMI truncates the packet to [CNT] bytes.
[CNT] must be 8-byte aligned such that CNT\<2:0\> = 000. */
#else /* Word 0 - Little Endian */
uint64_t cnt : 16; /**< [ 15: 0](R/W) Byte count for jabber check. Failing packets set the JABBER interrupt and are optionally
sent with opcode = JABBER. GMI truncates the packet to [CNT] bytes.
[CNT] must be 8-byte aligned such that CNT\<2:0\> = 000. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_gmi_rxx_jabber_s cn; */
};
typedef union bdk_bgxx_gmp_gmi_rxx_jabber bdk_bgxx_gmp_gmi_rxx_jabber_t;
static inline uint64_t BDK_BGXX_GMP_GMI_RXX_JABBER(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_RXX_JABBER(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038038ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0038038ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038038ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_GMI_RXX_JABBER", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_RXX_JABBER(a,b) bdk_bgxx_gmp_gmi_rxx_jabber_t
#define bustype_BDK_BGXX_GMP_GMI_RXX_JABBER(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_RXX_JABBER(a,b) "BGXX_GMP_GMI_RXX_JABBER"
#define device_bar_BDK_BGXX_GMP_GMI_RXX_JABBER(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_RXX_JABBER(a,b) (a)
#define arguments_BDK_BGXX_GMP_GMI_RXX_JABBER(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_rx#_udd_skp
*
* BGX GMP GMI User-Defined Data Skip Registers
* This register specifies the amount of user-defined data (UDD) added before the start of the
* L2C data.
*
* Internal:
* Notes:
* (1) The skip bytes are part of the packet and will be handled by NIC.
*
* (2) The system can determine if the UDD bytes are included in the FCS check
* by using the FCSSEL field - if the FCS check is enabled.
*
* (3) Assume that the preamble/sfd is always at the start of the frame - even
* before UDD bytes. In most cases, there will be no preamble in these
* cases since it will be packet interface in direct communication to
* another packet interface (MAC to MAC) without a PHY involved.
*
* (4) We can still do address filtering and control packet filtering is the
* user desires.
*
* (5) BGX()_GMP_GMI_RX()_UDD_SKP[LEN] must be 0 in half-duplex operation unless
* BGX()_GMP_GMI_RX()_FRM_CTL[PRE_CHK] is clear. If BGX()_GMP_GMI_RX()_FRM_CTL[PRE_CHK] is
* clear,
* then BGX()_GMP_GMI_RX()_UDD_SKP[LEN] will normally be 8.
*
* (6) In all cases, the UDD bytes will be sent down the packet interface as
* part of the packet. The UDD bytes are never stripped from the actual
* packet.
*/
union bdk_bgxx_gmp_gmi_rxx_udd_skp
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_rxx_udd_skp_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_9_63 : 55;
uint64_t fcssel : 1; /**< [ 8: 8](R/W) Include the skip bytes in the FCS calculation.
0 = All skip bytes are included in FCS.
1 = The skip bytes are not included in FCS.
The skip bytes are part of the packet and are
handled by NIC. The system can determine if the UDD bytes are included in the FCS check by
using [FCSSEL], if the FCS check is enabled. */
uint64_t reserved_7 : 1;
uint64_t len : 7; /**< [ 6: 0](R/W) Amount of user-defined data before the start of the L2C data, in bytes.
Setting to 0 means L2C comes first; maximum value is 64.
LEN must be 0x0 in half-duplex operation.
If LEN != 0, then BGX()_GMP_GMI_RX()_FRM_CHK[MINERR] will be disabled and
BGX()_GMP_GMI_RX()_INT[MINERR] will be zero. */
#else /* Word 0 - Little Endian */
uint64_t len : 7; /**< [ 6: 0](R/W) Amount of user-defined data before the start of the L2C data, in bytes.
Setting to 0 means L2C comes first; maximum value is 64.
LEN must be 0x0 in half-duplex operation.
If LEN != 0, then BGX()_GMP_GMI_RX()_FRM_CHK[MINERR] will be disabled and
BGX()_GMP_GMI_RX()_INT[MINERR] will be zero. */
uint64_t reserved_7 : 1;
uint64_t fcssel : 1; /**< [ 8: 8](R/W) Include the skip bytes in the FCS calculation.
0 = All skip bytes are included in FCS.
1 = The skip bytes are not included in FCS.
The skip bytes are part of the packet and are
handled by NIC. The system can determine if the UDD bytes are included in the FCS check by
using [FCSSEL], if the FCS check is enabled. */
uint64_t reserved_9_63 : 55;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_gmi_rxx_udd_skp_s cn; */
};
typedef union bdk_bgxx_gmp_gmi_rxx_udd_skp bdk_bgxx_gmp_gmi_rxx_udd_skp_t;
static inline uint64_t BDK_BGXX_GMP_GMI_RXX_UDD_SKP(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_RXX_UDD_SKP(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038048ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0038048ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038048ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_GMI_RXX_UDD_SKP", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_RXX_UDD_SKP(a,b) bdk_bgxx_gmp_gmi_rxx_udd_skp_t
#define bustype_BDK_BGXX_GMP_GMI_RXX_UDD_SKP(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_RXX_UDD_SKP(a,b) "BGXX_GMP_GMI_RXX_UDD_SKP"
#define device_bar_BDK_BGXX_GMP_GMI_RXX_UDD_SKP(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_RXX_UDD_SKP(a,b) (a)
#define arguments_BDK_BGXX_GMP_GMI_RXX_UDD_SKP(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_smac#
*
* BGX GMI SMAC Registers
*/
union bdk_bgxx_gmp_gmi_smacx
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_smacx_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t smac : 48; /**< [ 47: 0](R/W) The SMAC field is used for generating and accepting control PAUSE packets. */
#else /* Word 0 - Little Endian */
uint64_t smac : 48; /**< [ 47: 0](R/W) The SMAC field is used for generating and accepting control PAUSE packets. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_gmi_smacx_s cn; */
};
typedef union bdk_bgxx_gmp_gmi_smacx bdk_bgxx_gmp_gmi_smacx_t;
static inline uint64_t BDK_BGXX_GMP_GMI_SMACX(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_SMACX(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038230ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0038230ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038230ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_GMI_SMACX", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_SMACX(a,b) bdk_bgxx_gmp_gmi_smacx_t
#define bustype_BDK_BGXX_GMP_GMI_SMACX(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_SMACX(a,b) "BGXX_GMP_GMI_SMACX"
#define device_bar_BDK_BGXX_GMP_GMI_SMACX(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_SMACX(a,b) (a)
#define arguments_BDK_BGXX_GMP_GMI_SMACX(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_tx#_append
*
* BGX GMI TX Append Control Registers
*/
union bdk_bgxx_gmp_gmi_txx_append
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_txx_append_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_4_63 : 60;
uint64_t force_fcs : 1; /**< [ 3: 3](R/W) Append the Ethernet FCS on each PAUSE packet. */
uint64_t fcs : 1; /**< [ 2: 2](R/W) Append the Ethernet FCS on each packet. */
uint64_t pad : 1; /**< [ 1: 1](R/W) Append PAD bytes such that minimum-sized packet is transmitted. */
uint64_t preamble : 1; /**< [ 0: 0](R/W) Prepend the Ethernet preamble on each transfer. */
#else /* Word 0 - Little Endian */
uint64_t preamble : 1; /**< [ 0: 0](R/W) Prepend the Ethernet preamble on each transfer. */
uint64_t pad : 1; /**< [ 1: 1](R/W) Append PAD bytes such that minimum-sized packet is transmitted. */
uint64_t fcs : 1; /**< [ 2: 2](R/W) Append the Ethernet FCS on each packet. */
uint64_t force_fcs : 1; /**< [ 3: 3](R/W) Append the Ethernet FCS on each PAUSE packet. */
uint64_t reserved_4_63 : 60;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_gmi_txx_append_s cn; */
};
typedef union bdk_bgxx_gmp_gmi_txx_append bdk_bgxx_gmp_gmi_txx_append_t;
static inline uint64_t BDK_BGXX_GMP_GMI_TXX_APPEND(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_TXX_APPEND(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038218ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0038218ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038218ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_GMI_TXX_APPEND", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_TXX_APPEND(a,b) bdk_bgxx_gmp_gmi_txx_append_t
#define bustype_BDK_BGXX_GMP_GMI_TXX_APPEND(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_TXX_APPEND(a,b) "BGXX_GMP_GMI_TXX_APPEND"
#define device_bar_BDK_BGXX_GMP_GMI_TXX_APPEND(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_TXX_APPEND(a,b) (a)
#define arguments_BDK_BGXX_GMP_GMI_TXX_APPEND(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_tx#_burst
*
* BGX GMI TX Burst-Counter Registers
*/
union bdk_bgxx_gmp_gmi_txx_burst
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_txx_burst_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t burst : 16; /**< [ 15: 0](R/W) Burst (refer to 802.3 to set correctly). Only valid for 1000Mb/s half-duplex operation as
follows:
half duplex/1000Mb/s: 0x2000
all other modes: 0x0
SGMII/QSGMII/1000Base-X only. */
#else /* Word 0 - Little Endian */
uint64_t burst : 16; /**< [ 15: 0](R/W) Burst (refer to 802.3 to set correctly). Only valid for 1000Mb/s half-duplex operation as
follows:
half duplex/1000Mb/s: 0x2000
all other modes: 0x0
SGMII/QSGMII/1000Base-X only. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_gmi_txx_burst_s cn81xx; */
struct bdk_bgxx_gmp_gmi_txx_burst_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t burst : 16; /**< [ 15: 0](R/W) Burst (refer to 802.3 to set correctly). Only valid for 1000Mb/s half-duplex operation as
follows:
half duplex/1000Mb/s: 0x2000
all other modes: 0x0
SGMII/1000Base-X only. */
#else /* Word 0 - Little Endian */
uint64_t burst : 16; /**< [ 15: 0](R/W) Burst (refer to 802.3 to set correctly). Only valid for 1000Mb/s half-duplex operation as
follows:
half duplex/1000Mb/s: 0x2000
all other modes: 0x0
SGMII/1000Base-X only. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} cn88xx;
/* struct bdk_bgxx_gmp_gmi_txx_burst_s cn83xx; */
};
typedef union bdk_bgxx_gmp_gmi_txx_burst bdk_bgxx_gmp_gmi_txx_burst_t;
static inline uint64_t BDK_BGXX_GMP_GMI_TXX_BURST(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_TXX_BURST(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038228ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0038228ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038228ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_GMI_TXX_BURST", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_TXX_BURST(a,b) bdk_bgxx_gmp_gmi_txx_burst_t
#define bustype_BDK_BGXX_GMP_GMI_TXX_BURST(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_TXX_BURST(a,b) "BGXX_GMP_GMI_TXX_BURST"
#define device_bar_BDK_BGXX_GMP_GMI_TXX_BURST(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_TXX_BURST(a,b) (a)
#define arguments_BDK_BGXX_GMP_GMI_TXX_BURST(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_tx#_ctl
*
* BGX GMI Transmit Control Registers
*/
union bdk_bgxx_gmp_gmi_txx_ctl
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_txx_ctl_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_4_63 : 60;
uint64_t link_drain : 1; /**< [ 3: 3](R/W) Enable dropping of full packets to allow BGX and PKO/NIC to drain their FIFOs.
For diagnostic use only. */
uint64_t tx_fc_type : 1; /**< [ 2: 2](R/W) Transmit side flow control type select.
0 = GMI MAC transmits ITU G.999.1 pause frames.
1 = GMI MAC transmits 802.3 pause frames. */
uint64_t xsdef_en : 1; /**< [ 1: 1](R/W) Enables the excessive-deferral check for statistics and interrupts. SGMII/1000Base-X half-
duplex only. */
uint64_t xscol_en : 1; /**< [ 0: 0](R/W) Enables the excessive-collision check for statistics and interrupts. SGMII/1000Base-X
half-duplex only. */
#else /* Word 0 - Little Endian */
uint64_t xscol_en : 1; /**< [ 0: 0](R/W) Enables the excessive-collision check for statistics and interrupts. SGMII/1000Base-X
half-duplex only. */
uint64_t xsdef_en : 1; /**< [ 1: 1](R/W) Enables the excessive-deferral check for statistics and interrupts. SGMII/1000Base-X half-
duplex only. */
uint64_t tx_fc_type : 1; /**< [ 2: 2](R/W) Transmit side flow control type select.
0 = GMI MAC transmits ITU G.999.1 pause frames.
1 = GMI MAC transmits 802.3 pause frames. */
uint64_t link_drain : 1; /**< [ 3: 3](R/W) Enable dropping of full packets to allow BGX and PKO/NIC to drain their FIFOs.
For diagnostic use only. */
uint64_t reserved_4_63 : 60;
#endif /* Word 0 - End */
} s;
struct bdk_bgxx_gmp_gmi_txx_ctl_cn81xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_3_63 : 61;
uint64_t tx_fc_type : 1; /**< [ 2: 2](R/W) Transmit side flow control type select.
0 = GMI MAC transmits ITU G.999.1 pause frames.
1 = GMI MAC transmits 802.3 pause frames. */
uint64_t xsdef_en : 1; /**< [ 1: 1](R/W) Enables the excessive-deferral check for statistics and interrupts. SGMII/1000Base-X half-
duplex only. */
uint64_t xscol_en : 1; /**< [ 0: 0](R/W) Enables the excessive-collision check for statistics and interrupts. SGMII/1000Base-X
half-duplex only. */
#else /* Word 0 - Little Endian */
uint64_t xscol_en : 1; /**< [ 0: 0](R/W) Enables the excessive-collision check for statistics and interrupts. SGMII/1000Base-X
half-duplex only. */
uint64_t xsdef_en : 1; /**< [ 1: 1](R/W) Enables the excessive-deferral check for statistics and interrupts. SGMII/1000Base-X half-
duplex only. */
uint64_t tx_fc_type : 1; /**< [ 2: 2](R/W) Transmit side flow control type select.
0 = GMI MAC transmits ITU G.999.1 pause frames.
1 = GMI MAC transmits 802.3 pause frames. */
uint64_t reserved_3_63 : 61;
#endif /* Word 0 - End */
} cn81xx;
struct bdk_bgxx_gmp_gmi_txx_ctl_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_2_63 : 62;
uint64_t xsdef_en : 1; /**< [ 1: 1](R/W) Enables the excessive-deferral check for statistics and interrupts. SGMII/1000Base-X half-
duplex only. */
uint64_t xscol_en : 1; /**< [ 0: 0](R/W) Enables the excessive-collision check for statistics and interrupts. SGMII/1000Base-X
half-duplex only. */
#else /* Word 0 - Little Endian */
uint64_t xscol_en : 1; /**< [ 0: 0](R/W) Enables the excessive-collision check for statistics and interrupts. SGMII/1000Base-X
half-duplex only. */
uint64_t xsdef_en : 1; /**< [ 1: 1](R/W) Enables the excessive-deferral check for statistics and interrupts. SGMII/1000Base-X half-
duplex only. */
uint64_t reserved_2_63 : 62;
#endif /* Word 0 - End */
} cn88xx;
/* struct bdk_bgxx_gmp_gmi_txx_ctl_s cn83xx; */
};
typedef union bdk_bgxx_gmp_gmi_txx_ctl bdk_bgxx_gmp_gmi_txx_ctl_t;
static inline uint64_t BDK_BGXX_GMP_GMI_TXX_CTL(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_TXX_CTL(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038270ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0038270ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038270ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_GMI_TXX_CTL", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_TXX_CTL(a,b) bdk_bgxx_gmp_gmi_txx_ctl_t
#define bustype_BDK_BGXX_GMP_GMI_TXX_CTL(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_TXX_CTL(a,b) "BGXX_GMP_GMI_TXX_CTL"
#define device_bar_BDK_BGXX_GMP_GMI_TXX_CTL(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_TXX_CTL(a,b) (a)
#define arguments_BDK_BGXX_GMP_GMI_TXX_CTL(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_tx#_int
*
* BGX GMI TX Interrupt Registers
*/
union bdk_bgxx_gmp_gmi_txx_int
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_txx_int_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_5_63 : 59;
uint64_t ptp_lost : 1; /**< [ 4: 4](R/W1C/H) A packet with a PTP request was not able to be sent due to XSCOL. */
uint64_t late_col : 1; /**< [ 3: 3](R/W1C/H) TX late collision. (SGMII/1000BASE-X half-duplex only) */
uint64_t xsdef : 1; /**< [ 2: 2](R/W1C/H) TX excessive deferral. (SGMII/1000BASE-X half-duplex only) */
uint64_t xscol : 1; /**< [ 1: 1](R/W1C/H) TX excessive collisions. (SGMII/1000BASE-X half-duplex only) */
uint64_t undflw : 1; /**< [ 0: 0](R/W1C/H) TX underflow. */
#else /* Word 0 - Little Endian */
uint64_t undflw : 1; /**< [ 0: 0](R/W1C/H) TX underflow. */
uint64_t xscol : 1; /**< [ 1: 1](R/W1C/H) TX excessive collisions. (SGMII/1000BASE-X half-duplex only) */
uint64_t xsdef : 1; /**< [ 2: 2](R/W1C/H) TX excessive deferral. (SGMII/1000BASE-X half-duplex only) */
uint64_t late_col : 1; /**< [ 3: 3](R/W1C/H) TX late collision. (SGMII/1000BASE-X half-duplex only) */
uint64_t ptp_lost : 1; /**< [ 4: 4](R/W1C/H) A packet with a PTP request was not able to be sent due to XSCOL. */
uint64_t reserved_5_63 : 59;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_gmi_txx_int_s cn; */
};
typedef union bdk_bgxx_gmp_gmi_txx_int bdk_bgxx_gmp_gmi_txx_int_t;
static inline uint64_t BDK_BGXX_GMP_GMI_TXX_INT(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_TXX_INT(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038500ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0038500ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038500ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_GMI_TXX_INT", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_TXX_INT(a,b) bdk_bgxx_gmp_gmi_txx_int_t
#define bustype_BDK_BGXX_GMP_GMI_TXX_INT(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_TXX_INT(a,b) "BGXX_GMP_GMI_TXX_INT"
#define device_bar_BDK_BGXX_GMP_GMI_TXX_INT(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_TXX_INT(a,b) (a)
#define arguments_BDK_BGXX_GMP_GMI_TXX_INT(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_tx#_int_ena_w1c
*
* BGX GMI TX Interrupt Enable Clear Registers
* This register clears interrupt enable bits.
*/
union bdk_bgxx_gmp_gmi_txx_int_ena_w1c
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_txx_int_ena_w1c_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_5_63 : 59;
uint64_t ptp_lost : 1; /**< [ 4: 4](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_TX(0..3)_INT[PTP_LOST]. */
uint64_t late_col : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_TX(0..3)_INT[LATE_COL]. */
uint64_t xsdef : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_TX(0..3)_INT[XSDEF]. */
uint64_t xscol : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_TX(0..3)_INT[XSCOL]. */
uint64_t undflw : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_TX(0..3)_INT[UNDFLW]. */
#else /* Word 0 - Little Endian */
uint64_t undflw : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_TX(0..3)_INT[UNDFLW]. */
uint64_t xscol : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_TX(0..3)_INT[XSCOL]. */
uint64_t xsdef : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_TX(0..3)_INT[XSDEF]. */
uint64_t late_col : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_TX(0..3)_INT[LATE_COL]. */
uint64_t ptp_lost : 1; /**< [ 4: 4](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_GMI_TX(0..3)_INT[PTP_LOST]. */
uint64_t reserved_5_63 : 59;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_gmi_txx_int_ena_w1c_s cn81xx; */
/* struct bdk_bgxx_gmp_gmi_txx_int_ena_w1c_s cn88xx; */
struct bdk_bgxx_gmp_gmi_txx_int_ena_w1c_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_5_63 : 59;
uint64_t ptp_lost : 1; /**< [ 4: 4](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_TX(0..3)_INT[PTP_LOST]. */
uint64_t late_col : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_TX(0..3)_INT[LATE_COL]. */
uint64_t xsdef : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_TX(0..3)_INT[XSDEF]. */
uint64_t xscol : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_TX(0..3)_INT[XSCOL]. */
uint64_t undflw : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_TX(0..3)_INT[UNDFLW]. */
#else /* Word 0 - Little Endian */
uint64_t undflw : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_TX(0..3)_INT[UNDFLW]. */
uint64_t xscol : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_TX(0..3)_INT[XSCOL]. */
uint64_t xsdef : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_TX(0..3)_INT[XSDEF]. */
uint64_t late_col : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_TX(0..3)_INT[LATE_COL]. */
uint64_t ptp_lost : 1; /**< [ 4: 4](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_GMI_TX(0..3)_INT[PTP_LOST]. */
uint64_t reserved_5_63 : 59;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_gmp_gmi_txx_int_ena_w1c bdk_bgxx_gmp_gmi_txx_int_ena_w1c_t;
static inline uint64_t BDK_BGXX_GMP_GMI_TXX_INT_ENA_W1C(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_TXX_INT_ENA_W1C(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038510ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0038510ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038510ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_GMI_TXX_INT_ENA_W1C", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_TXX_INT_ENA_W1C(a,b) bdk_bgxx_gmp_gmi_txx_int_ena_w1c_t
#define bustype_BDK_BGXX_GMP_GMI_TXX_INT_ENA_W1C(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_TXX_INT_ENA_W1C(a,b) "BGXX_GMP_GMI_TXX_INT_ENA_W1C"
#define device_bar_BDK_BGXX_GMP_GMI_TXX_INT_ENA_W1C(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_TXX_INT_ENA_W1C(a,b) (a)
#define arguments_BDK_BGXX_GMP_GMI_TXX_INT_ENA_W1C(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_tx#_int_ena_w1s
*
* BGX GMI TX Interrupt Enable Set Registers
* This register sets interrupt enable bits.
*/
union bdk_bgxx_gmp_gmi_txx_int_ena_w1s
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_txx_int_ena_w1s_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_5_63 : 59;
uint64_t ptp_lost : 1; /**< [ 4: 4](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_TX(0..3)_INT[PTP_LOST]. */
uint64_t late_col : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_TX(0..3)_INT[LATE_COL]. */
uint64_t xsdef : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_TX(0..3)_INT[XSDEF]. */
uint64_t xscol : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_TX(0..3)_INT[XSCOL]. */
uint64_t undflw : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_TX(0..3)_INT[UNDFLW]. */
#else /* Word 0 - Little Endian */
uint64_t undflw : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_TX(0..3)_INT[UNDFLW]. */
uint64_t xscol : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_TX(0..3)_INT[XSCOL]. */
uint64_t xsdef : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_TX(0..3)_INT[XSDEF]. */
uint64_t late_col : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_TX(0..3)_INT[LATE_COL]. */
uint64_t ptp_lost : 1; /**< [ 4: 4](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_GMI_TX(0..3)_INT[PTP_LOST]. */
uint64_t reserved_5_63 : 59;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_gmi_txx_int_ena_w1s_s cn81xx; */
/* struct bdk_bgxx_gmp_gmi_txx_int_ena_w1s_s cn88xx; */
struct bdk_bgxx_gmp_gmi_txx_int_ena_w1s_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_5_63 : 59;
uint64_t ptp_lost : 1; /**< [ 4: 4](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_TX(0..3)_INT[PTP_LOST]. */
uint64_t late_col : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_TX(0..3)_INT[LATE_COL]. */
uint64_t xsdef : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_TX(0..3)_INT[XSDEF]. */
uint64_t xscol : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_TX(0..3)_INT[XSCOL]. */
uint64_t undflw : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_TX(0..3)_INT[UNDFLW]. */
#else /* Word 0 - Little Endian */
uint64_t undflw : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_TX(0..3)_INT[UNDFLW]. */
uint64_t xscol : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_TX(0..3)_INT[XSCOL]. */
uint64_t xsdef : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_TX(0..3)_INT[XSDEF]. */
uint64_t late_col : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_TX(0..3)_INT[LATE_COL]. */
uint64_t ptp_lost : 1; /**< [ 4: 4](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_GMI_TX(0..3)_INT[PTP_LOST]. */
uint64_t reserved_5_63 : 59;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_gmp_gmi_txx_int_ena_w1s bdk_bgxx_gmp_gmi_txx_int_ena_w1s_t;
static inline uint64_t BDK_BGXX_GMP_GMI_TXX_INT_ENA_W1S(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_TXX_INT_ENA_W1S(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038518ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0038518ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038518ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_GMI_TXX_INT_ENA_W1S", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_TXX_INT_ENA_W1S(a,b) bdk_bgxx_gmp_gmi_txx_int_ena_w1s_t
#define bustype_BDK_BGXX_GMP_GMI_TXX_INT_ENA_W1S(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_TXX_INT_ENA_W1S(a,b) "BGXX_GMP_GMI_TXX_INT_ENA_W1S"
#define device_bar_BDK_BGXX_GMP_GMI_TXX_INT_ENA_W1S(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_TXX_INT_ENA_W1S(a,b) (a)
#define arguments_BDK_BGXX_GMP_GMI_TXX_INT_ENA_W1S(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_tx#_int_w1s
*
* BGX GMI TX Interrupt Set Registers
* This register sets interrupt bits.
*/
union bdk_bgxx_gmp_gmi_txx_int_w1s
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_txx_int_w1s_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_5_63 : 59;
uint64_t ptp_lost : 1; /**< [ 4: 4](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_TX(0..3)_INT[PTP_LOST]. */
uint64_t late_col : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_TX(0..3)_INT[LATE_COL]. */
uint64_t xsdef : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_TX(0..3)_INT[XSDEF]. */
uint64_t xscol : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_TX(0..3)_INT[XSCOL]. */
uint64_t undflw : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_TX(0..3)_INT[UNDFLW]. */
#else /* Word 0 - Little Endian */
uint64_t undflw : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_TX(0..3)_INT[UNDFLW]. */
uint64_t xscol : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_TX(0..3)_INT[XSCOL]. */
uint64_t xsdef : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_TX(0..3)_INT[XSDEF]. */
uint64_t late_col : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_TX(0..3)_INT[LATE_COL]. */
uint64_t ptp_lost : 1; /**< [ 4: 4](R/W1S/H) Reads or sets BGX(0..1)_GMP_GMI_TX(0..3)_INT[PTP_LOST]. */
uint64_t reserved_5_63 : 59;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_gmi_txx_int_w1s_s cn81xx; */
/* struct bdk_bgxx_gmp_gmi_txx_int_w1s_s cn88xx; */
struct bdk_bgxx_gmp_gmi_txx_int_w1s_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_5_63 : 59;
uint64_t ptp_lost : 1; /**< [ 4: 4](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_TX(0..3)_INT[PTP_LOST]. */
uint64_t late_col : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_TX(0..3)_INT[LATE_COL]. */
uint64_t xsdef : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_TX(0..3)_INT[XSDEF]. */
uint64_t xscol : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_TX(0..3)_INT[XSCOL]. */
uint64_t undflw : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_TX(0..3)_INT[UNDFLW]. */
#else /* Word 0 - Little Endian */
uint64_t undflw : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_TX(0..3)_INT[UNDFLW]. */
uint64_t xscol : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_TX(0..3)_INT[XSCOL]. */
uint64_t xsdef : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_TX(0..3)_INT[XSDEF]. */
uint64_t late_col : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_TX(0..3)_INT[LATE_COL]. */
uint64_t ptp_lost : 1; /**< [ 4: 4](R/W1S/H) Reads or sets BGX(0..3)_GMP_GMI_TX(0..3)_INT[PTP_LOST]. */
uint64_t reserved_5_63 : 59;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_gmp_gmi_txx_int_w1s bdk_bgxx_gmp_gmi_txx_int_w1s_t;
static inline uint64_t BDK_BGXX_GMP_GMI_TXX_INT_W1S(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_TXX_INT_W1S(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038508ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0038508ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038508ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_GMI_TXX_INT_W1S", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_TXX_INT_W1S(a,b) bdk_bgxx_gmp_gmi_txx_int_w1s_t
#define bustype_BDK_BGXX_GMP_GMI_TXX_INT_W1S(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_TXX_INT_W1S(a,b) "BGXX_GMP_GMI_TXX_INT_W1S"
#define device_bar_BDK_BGXX_GMP_GMI_TXX_INT_W1S(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_TXX_INT_W1S(a,b) (a)
#define arguments_BDK_BGXX_GMP_GMI_TXX_INT_W1S(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_tx#_min_pkt
*
* BGX GMI TX Minimum-Size-Packet Registers
*/
union bdk_bgxx_gmp_gmi_txx_min_pkt
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_txx_min_pkt_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_8_63 : 56;
uint64_t min_size : 8; /**< [ 7: 0](R/W) Minimum frame size in bytes before the FCS is applied.
Padding is only appended when BGX()_GMP_GMI_TX()_APPEND[PAD] for the corresponding
LMAC is set.
When LMAC_TYPE=SGMII/QSGMII, packets are padded to [MIN_SIZE]+1. The reset value pads to
60
bytes. */
#else /* Word 0 - Little Endian */
uint64_t min_size : 8; /**< [ 7: 0](R/W) Minimum frame size in bytes before the FCS is applied.
Padding is only appended when BGX()_GMP_GMI_TX()_APPEND[PAD] for the corresponding
LMAC is set.
When LMAC_TYPE=SGMII/QSGMII, packets are padded to [MIN_SIZE]+1. The reset value pads to
60
bytes. */
uint64_t reserved_8_63 : 56;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_gmi_txx_min_pkt_s cn81xx; */
struct bdk_bgxx_gmp_gmi_txx_min_pkt_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_8_63 : 56;
uint64_t min_size : 8; /**< [ 7: 0](R/W) Minimum frame size in bytes before the FCS is applied.
Padding is only appended when BGX()_GMP_GMI_TX()_APPEND[PAD] for the corresponding
LMAC is set.
In SGMII mode, packets are padded to [MIN_SIZE]+1. The reset value pads to 60 bytes. */
#else /* Word 0 - Little Endian */
uint64_t min_size : 8; /**< [ 7: 0](R/W) Minimum frame size in bytes before the FCS is applied.
Padding is only appended when BGX()_GMP_GMI_TX()_APPEND[PAD] for the corresponding
LMAC is set.
In SGMII mode, packets are padded to [MIN_SIZE]+1. The reset value pads to 60 bytes. */
uint64_t reserved_8_63 : 56;
#endif /* Word 0 - End */
} cn88xx;
/* struct bdk_bgxx_gmp_gmi_txx_min_pkt_s cn83xx; */
};
typedef union bdk_bgxx_gmp_gmi_txx_min_pkt bdk_bgxx_gmp_gmi_txx_min_pkt_t;
static inline uint64_t BDK_BGXX_GMP_GMI_TXX_MIN_PKT(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_TXX_MIN_PKT(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038240ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0038240ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038240ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_GMI_TXX_MIN_PKT", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_TXX_MIN_PKT(a,b) bdk_bgxx_gmp_gmi_txx_min_pkt_t
#define bustype_BDK_BGXX_GMP_GMI_TXX_MIN_PKT(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_TXX_MIN_PKT(a,b) "BGXX_GMP_GMI_TXX_MIN_PKT"
#define device_bar_BDK_BGXX_GMP_GMI_TXX_MIN_PKT(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_TXX_MIN_PKT(a,b) (a)
#define arguments_BDK_BGXX_GMP_GMI_TXX_MIN_PKT(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_tx#_pause_pkt_interval
*
* BGX GMI TX PAUSE-Packet Transmission-Interval Registers
* This register specifies how often PAUSE packets are sent.
* Internal:
* Notes:
* Choosing proper values of BGX()_GMP_GMI_TX()_PAUSE_PKT_TIME[PTIME] and
* BGX()_GMP_GMI_TX()_PAUSE_PKT_INTERVAL[INTERVAL] can be challenging to the system
* designer. It is suggested that TIME be much greater than INTERVAL and
* BGX()_GMP_GMI_TX()_PAUSE_ZERO[SEND] be set. This allows a periodic refresh of the PAUSE
* count and then when the backpressure condition is lifted, a PAUSE packet
* with TIME==0 will be sent indicating that Octane is ready for additional
* data.
*
* If the system chooses to not set BGX()_GMP_GMI_TX()_PAUSE_ZERO[SEND], then it is
* suggested that TIME and INTERVAL are programmed such that they satisify the
* following rule:
*
* _ INTERVAL \<= TIME - (largest_pkt_size + IFG + pause_pkt_size)
*
* where largest_pkt_size is that largest packet that the system can send
* (normally 1518B), IFG is the interframe gap and pause_pkt_size is the size
* of the PAUSE packet (normally 64B).
*/
union bdk_bgxx_gmp_gmi_txx_pause_pkt_interval
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_txx_pause_pkt_interval_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t interval : 16; /**< [ 15: 0](R/W) Arbitrate for a 802.3 PAUSE packet every ([INTERVAL] * 512)
bit-times. Normally, 0 \< [INTERVAL] \< BGX()_GMP_GMI_TX()_PAUSE_PKT_TIME[PTIME].
[INTERVAL] = 0 only sends a single PAUSE packet for each backpressure event.
BGX()_GMP_GMI_TX()_PAUSE_ZERO[SEND] must be 1 when [INTERVAL] = 0.
[INTERVAL] should be 0x0 if BGX()_GMP_GMI_TX()_CTL[TX_FC_TYPE] is clear (G.999.1). */
#else /* Word 0 - Little Endian */
uint64_t interval : 16; /**< [ 15: 0](R/W) Arbitrate for a 802.3 PAUSE packet every ([INTERVAL] * 512)
bit-times. Normally, 0 \< [INTERVAL] \< BGX()_GMP_GMI_TX()_PAUSE_PKT_TIME[PTIME].
[INTERVAL] = 0 only sends a single PAUSE packet for each backpressure event.
BGX()_GMP_GMI_TX()_PAUSE_ZERO[SEND] must be 1 when [INTERVAL] = 0.
[INTERVAL] should be 0x0 if BGX()_GMP_GMI_TX()_CTL[TX_FC_TYPE] is clear (G.999.1). */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_gmi_txx_pause_pkt_interval_s cn81xx; */
struct bdk_bgxx_gmp_gmi_txx_pause_pkt_interval_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t interval : 16; /**< [ 15: 0](R/W) Arbitrate for a 802.3 PAUSE packet every ([INTERVAL] * 512)
bit-times. Normally, 0 \< [INTERVAL] \< BGX()_GMP_GMI_TX()_PAUSE_PKT_TIME[PTIME].
[INTERVAL] = 0 only sends a single PAUSE packet for each backpressure event.
BGX()_GMP_GMI_TX()_PAUSE_ZERO[SEND] must be 1 when [INTERVAL] = 0. */
#else /* Word 0 - Little Endian */
uint64_t interval : 16; /**< [ 15: 0](R/W) Arbitrate for a 802.3 PAUSE packet every ([INTERVAL] * 512)
bit-times. Normally, 0 \< [INTERVAL] \< BGX()_GMP_GMI_TX()_PAUSE_PKT_TIME[PTIME].
[INTERVAL] = 0 only sends a single PAUSE packet for each backpressure event.
BGX()_GMP_GMI_TX()_PAUSE_ZERO[SEND] must be 1 when [INTERVAL] = 0. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} cn88xx;
/* struct bdk_bgxx_gmp_gmi_txx_pause_pkt_interval_s cn83xx; */
};
typedef union bdk_bgxx_gmp_gmi_txx_pause_pkt_interval bdk_bgxx_gmp_gmi_txx_pause_pkt_interval_t;
static inline uint64_t BDK_BGXX_GMP_GMI_TXX_PAUSE_PKT_INTERVAL(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_TXX_PAUSE_PKT_INTERVAL(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038248ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0038248ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038248ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_GMI_TXX_PAUSE_PKT_INTERVAL", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_TXX_PAUSE_PKT_INTERVAL(a,b) bdk_bgxx_gmp_gmi_txx_pause_pkt_interval_t
#define bustype_BDK_BGXX_GMP_GMI_TXX_PAUSE_PKT_INTERVAL(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_TXX_PAUSE_PKT_INTERVAL(a,b) "BGXX_GMP_GMI_TXX_PAUSE_PKT_INTERVAL"
#define device_bar_BDK_BGXX_GMP_GMI_TXX_PAUSE_PKT_INTERVAL(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_TXX_PAUSE_PKT_INTERVAL(a,b) (a)
#define arguments_BDK_BGXX_GMP_GMI_TXX_PAUSE_PKT_INTERVAL(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_tx#_pause_pkt_time
*
* BGX GMI TX PAUSE Packet PAUSE-Time Registers
*/
union bdk_bgxx_gmp_gmi_txx_pause_pkt_time
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_txx_pause_pkt_time_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t ptime : 16; /**< [ 15: 0](R/W) Provides the pause_time field placed in outbound 802.3 PAUSE packets
in 512 bit-times. Normally, [PTIME] \>
BGX()_GMP_GMI_TX()_PAUSE_PKT_INTERVAL[INTERVAL]. For programming information see
BGX()_GMP_GMI_TX()_PAUSE_PKT_INTERVAL.
[PTIME] should be 0x0 if BGX()_GMP_GMI_TX()_CTL[TX_FC_TYPE] is clear (G.999.1). */
#else /* Word 0 - Little Endian */
uint64_t ptime : 16; /**< [ 15: 0](R/W) Provides the pause_time field placed in outbound 802.3 PAUSE packets
in 512 bit-times. Normally, [PTIME] \>
BGX()_GMP_GMI_TX()_PAUSE_PKT_INTERVAL[INTERVAL]. For programming information see
BGX()_GMP_GMI_TX()_PAUSE_PKT_INTERVAL.
[PTIME] should be 0x0 if BGX()_GMP_GMI_TX()_CTL[TX_FC_TYPE] is clear (G.999.1). */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_gmi_txx_pause_pkt_time_s cn81xx; */
struct bdk_bgxx_gmp_gmi_txx_pause_pkt_time_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t ptime : 16; /**< [ 15: 0](R/W) Provides the pause_time field placed in outbound 802.3 PAUSE packets
in 512 bit-times. Normally, [PTIME] \>
BGX()_GMP_GMI_TX()_PAUSE_PKT_INTERVAL[INTERVAL]. For programming information see
BGX()_GMP_GMI_TX()_PAUSE_PKT_INTERVAL. */
#else /* Word 0 - Little Endian */
uint64_t ptime : 16; /**< [ 15: 0](R/W) Provides the pause_time field placed in outbound 802.3 PAUSE packets
in 512 bit-times. Normally, [PTIME] \>
BGX()_GMP_GMI_TX()_PAUSE_PKT_INTERVAL[INTERVAL]. For programming information see
BGX()_GMP_GMI_TX()_PAUSE_PKT_INTERVAL. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} cn88xx;
/* struct bdk_bgxx_gmp_gmi_txx_pause_pkt_time_s cn83xx; */
};
typedef union bdk_bgxx_gmp_gmi_txx_pause_pkt_time bdk_bgxx_gmp_gmi_txx_pause_pkt_time_t;
static inline uint64_t BDK_BGXX_GMP_GMI_TXX_PAUSE_PKT_TIME(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_TXX_PAUSE_PKT_TIME(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038238ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0038238ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038238ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_GMI_TXX_PAUSE_PKT_TIME", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_TXX_PAUSE_PKT_TIME(a,b) bdk_bgxx_gmp_gmi_txx_pause_pkt_time_t
#define bustype_BDK_BGXX_GMP_GMI_TXX_PAUSE_PKT_TIME(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_TXX_PAUSE_PKT_TIME(a,b) "BGXX_GMP_GMI_TXX_PAUSE_PKT_TIME"
#define device_bar_BDK_BGXX_GMP_GMI_TXX_PAUSE_PKT_TIME(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_TXX_PAUSE_PKT_TIME(a,b) (a)
#define arguments_BDK_BGXX_GMP_GMI_TXX_PAUSE_PKT_TIME(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_tx#_pause_togo
*
* BGX GMI TX Time-to-Backpressure Registers
*/
union bdk_bgxx_gmp_gmi_txx_pause_togo
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_txx_pause_togo_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t ptime : 16; /**< [ 15: 0](RO/H) Amount of time remaining to backpressure, from the standard 802.3 PAUSE timer. */
#else /* Word 0 - Little Endian */
uint64_t ptime : 16; /**< [ 15: 0](RO/H) Amount of time remaining to backpressure, from the standard 802.3 PAUSE timer. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_gmi_txx_pause_togo_s cn; */
};
typedef union bdk_bgxx_gmp_gmi_txx_pause_togo bdk_bgxx_gmp_gmi_txx_pause_togo_t;
static inline uint64_t BDK_BGXX_GMP_GMI_TXX_PAUSE_TOGO(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_TXX_PAUSE_TOGO(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038258ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0038258ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038258ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_GMI_TXX_PAUSE_TOGO", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_TXX_PAUSE_TOGO(a,b) bdk_bgxx_gmp_gmi_txx_pause_togo_t
#define bustype_BDK_BGXX_GMP_GMI_TXX_PAUSE_TOGO(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_TXX_PAUSE_TOGO(a,b) "BGXX_GMP_GMI_TXX_PAUSE_TOGO"
#define device_bar_BDK_BGXX_GMP_GMI_TXX_PAUSE_TOGO(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_TXX_PAUSE_TOGO(a,b) (a)
#define arguments_BDK_BGXX_GMP_GMI_TXX_PAUSE_TOGO(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_tx#_pause_zero
*
* BGX GMI TX PAUSE-Zero-Enable Registers
*/
union bdk_bgxx_gmp_gmi_txx_pause_zero
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_txx_pause_zero_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_1_63 : 63;
uint64_t send : 1; /**< [ 0: 0](R/W) Send PAUSE-zero enable. When this bit is set, and the backpressure condition is clear, it
allows sending a PAUSE packet with pause_time of 0 to enable the channel.
[SEND] should be set if BGX()_GMP_GMI_TX()_CTL[TX_FC_TYPE] is clear (G.999.1). */
#else /* Word 0 - Little Endian */
uint64_t send : 1; /**< [ 0: 0](R/W) Send PAUSE-zero enable. When this bit is set, and the backpressure condition is clear, it
allows sending a PAUSE packet with pause_time of 0 to enable the channel.
[SEND] should be set if BGX()_GMP_GMI_TX()_CTL[TX_FC_TYPE] is clear (G.999.1). */
uint64_t reserved_1_63 : 63;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_gmi_txx_pause_zero_s cn81xx; */
struct bdk_bgxx_gmp_gmi_txx_pause_zero_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_1_63 : 63;
uint64_t send : 1; /**< [ 0: 0](R/W) Send PAUSE-zero enable.When this bit is set, and the backpressure condition is clear, it
allows sending a PAUSE packet with pause_time of 0 to enable the channel. */
#else /* Word 0 - Little Endian */
uint64_t send : 1; /**< [ 0: 0](R/W) Send PAUSE-zero enable.When this bit is set, and the backpressure condition is clear, it
allows sending a PAUSE packet with pause_time of 0 to enable the channel. */
uint64_t reserved_1_63 : 63;
#endif /* Word 0 - End */
} cn88xx;
/* struct bdk_bgxx_gmp_gmi_txx_pause_zero_s cn83xx; */
};
typedef union bdk_bgxx_gmp_gmi_txx_pause_zero bdk_bgxx_gmp_gmi_txx_pause_zero_t;
static inline uint64_t BDK_BGXX_GMP_GMI_TXX_PAUSE_ZERO(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_TXX_PAUSE_ZERO(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038260ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0038260ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038260ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_GMI_TXX_PAUSE_ZERO", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_TXX_PAUSE_ZERO(a,b) bdk_bgxx_gmp_gmi_txx_pause_zero_t
#define bustype_BDK_BGXX_GMP_GMI_TXX_PAUSE_ZERO(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_TXX_PAUSE_ZERO(a,b) "BGXX_GMP_GMI_TXX_PAUSE_ZERO"
#define device_bar_BDK_BGXX_GMP_GMI_TXX_PAUSE_ZERO(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_TXX_PAUSE_ZERO(a,b) (a)
#define arguments_BDK_BGXX_GMP_GMI_TXX_PAUSE_ZERO(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_tx#_sgmii_ctl
*
* BGX SGMII Control Registers
*/
union bdk_bgxx_gmp_gmi_txx_sgmii_ctl
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_txx_sgmii_ctl_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_1_63 : 63;
uint64_t align : 1; /**< [ 0: 0](R/W) Align the transmission to even cycles: (SGMII/1000BASE-X half-duplex only)
Recommended value is: ALIGN = !BGX()_GMP_GMI_TX()_APPEND[PREAMBLE].
(See Transmit Conversion to Code groups, Transmit Conversion to Code Groups for a complete
discussion.)
_ 0 = Data can be sent on any cycle. In this mode, the interface functions at maximum
bandwidth. It is possible for the TX PCS machine to drop the first byte of the TX frame.
When BGX()_GMP_GMI_TX()_APPEND[PREAMBLE] is set, the first byte is a preamble
byte, which can be dropped to compensate for an extended IPG.
_ 1 = Data is only sent on even cycles. In this mode, there can be bandwidth implications
when sending odd-byte packets as the IPG can extend an extra cycle. There will be no loss
of data. */
#else /* Word 0 - Little Endian */
uint64_t align : 1; /**< [ 0: 0](R/W) Align the transmission to even cycles: (SGMII/1000BASE-X half-duplex only)
Recommended value is: ALIGN = !BGX()_GMP_GMI_TX()_APPEND[PREAMBLE].
(See Transmit Conversion to Code groups, Transmit Conversion to Code Groups for a complete
discussion.)
_ 0 = Data can be sent on any cycle. In this mode, the interface functions at maximum
bandwidth. It is possible for the TX PCS machine to drop the first byte of the TX frame.
When BGX()_GMP_GMI_TX()_APPEND[PREAMBLE] is set, the first byte is a preamble
byte, which can be dropped to compensate for an extended IPG.
_ 1 = Data is only sent on even cycles. In this mode, there can be bandwidth implications
when sending odd-byte packets as the IPG can extend an extra cycle. There will be no loss
of data. */
uint64_t reserved_1_63 : 63;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_gmi_txx_sgmii_ctl_s cn; */
};
typedef union bdk_bgxx_gmp_gmi_txx_sgmii_ctl bdk_bgxx_gmp_gmi_txx_sgmii_ctl_t;
static inline uint64_t BDK_BGXX_GMP_GMI_TXX_SGMII_CTL(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_TXX_SGMII_CTL(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038300ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0038300ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038300ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_GMI_TXX_SGMII_CTL", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_TXX_SGMII_CTL(a,b) bdk_bgxx_gmp_gmi_txx_sgmii_ctl_t
#define bustype_BDK_BGXX_GMP_GMI_TXX_SGMII_CTL(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_TXX_SGMII_CTL(a,b) "BGXX_GMP_GMI_TXX_SGMII_CTL"
#define device_bar_BDK_BGXX_GMP_GMI_TXX_SGMII_CTL(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_TXX_SGMII_CTL(a,b) (a)
#define arguments_BDK_BGXX_GMP_GMI_TXX_SGMII_CTL(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_tx#_slot
*
* BGX GMI TX Slottime Counter Registers
*/
union bdk_bgxx_gmp_gmi_txx_slot
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_txx_slot_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_10_63 : 54;
uint64_t slot : 10; /**< [ 9: 0](R/W) Slottime (refer to IEEE 802.3 to set correctly):
10/100 Mbs: Set SLOT to 0x40.
1000 Mbs: Set SLOT to 0x200.
SGMII/QSGMII/1000Base-X only. */
#else /* Word 0 - Little Endian */
uint64_t slot : 10; /**< [ 9: 0](R/W) Slottime (refer to IEEE 802.3 to set correctly):
10/100 Mbs: Set SLOT to 0x40.
1000 Mbs: Set SLOT to 0x200.
SGMII/QSGMII/1000Base-X only. */
uint64_t reserved_10_63 : 54;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_gmi_txx_slot_s cn81xx; */
struct bdk_bgxx_gmp_gmi_txx_slot_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_10_63 : 54;
uint64_t slot : 10; /**< [ 9: 0](R/W) Slottime (refer to IEEE 802.3 to set correctly):
10/100 Mbs: Set SLOT to 0x40.
1000 Mbs: Set SLOT to 0x200.
SGMII/1000Base-X only. */
#else /* Word 0 - Little Endian */
uint64_t slot : 10; /**< [ 9: 0](R/W) Slottime (refer to IEEE 802.3 to set correctly):
10/100 Mbs: Set SLOT to 0x40.
1000 Mbs: Set SLOT to 0x200.
SGMII/1000Base-X only. */
uint64_t reserved_10_63 : 54;
#endif /* Word 0 - End */
} cn88xx;
/* struct bdk_bgxx_gmp_gmi_txx_slot_s cn83xx; */
};
typedef union bdk_bgxx_gmp_gmi_txx_slot bdk_bgxx_gmp_gmi_txx_slot_t;
static inline uint64_t BDK_BGXX_GMP_GMI_TXX_SLOT(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_TXX_SLOT(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038220ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0038220ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038220ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_GMI_TXX_SLOT", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_TXX_SLOT(a,b) bdk_bgxx_gmp_gmi_txx_slot_t
#define bustype_BDK_BGXX_GMP_GMI_TXX_SLOT(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_TXX_SLOT(a,b) "BGXX_GMP_GMI_TXX_SLOT"
#define device_bar_BDK_BGXX_GMP_GMI_TXX_SLOT(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_TXX_SLOT(a,b) (a)
#define arguments_BDK_BGXX_GMP_GMI_TXX_SLOT(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_tx#_soft_pause
*
* BGX GMI TX Software PAUSE Registers
*/
union bdk_bgxx_gmp_gmi_txx_soft_pause
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_txx_soft_pause_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t ptime : 16; /**< [ 15: 0](R/W) Back off the TX bus for ([PTIME] * 512) bit-times.
[PTIME] should be 0x0 if BGX()_GMP_GMI_TX()_CTL[TX_FC_TYPE] is clear (G.999.1). */
#else /* Word 0 - Little Endian */
uint64_t ptime : 16; /**< [ 15: 0](R/W) Back off the TX bus for ([PTIME] * 512) bit-times.
[PTIME] should be 0x0 if BGX()_GMP_GMI_TX()_CTL[TX_FC_TYPE] is clear (G.999.1). */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_gmi_txx_soft_pause_s cn81xx; */
struct bdk_bgxx_gmp_gmi_txx_soft_pause_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t ptime : 16; /**< [ 15: 0](R/W) Back off the TX bus for ([PTIME] * 512) bit-times. */
#else /* Word 0 - Little Endian */
uint64_t ptime : 16; /**< [ 15: 0](R/W) Back off the TX bus for ([PTIME] * 512) bit-times. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} cn88xx;
/* struct bdk_bgxx_gmp_gmi_txx_soft_pause_s cn83xx; */
};
typedef union bdk_bgxx_gmp_gmi_txx_soft_pause bdk_bgxx_gmp_gmi_txx_soft_pause_t;
static inline uint64_t BDK_BGXX_GMP_GMI_TXX_SOFT_PAUSE(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_TXX_SOFT_PAUSE(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038250ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0038250ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038250ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_GMI_TXX_SOFT_PAUSE", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_TXX_SOFT_PAUSE(a,b) bdk_bgxx_gmp_gmi_txx_soft_pause_t
#define bustype_BDK_BGXX_GMP_GMI_TXX_SOFT_PAUSE(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_TXX_SOFT_PAUSE(a,b) "BGXX_GMP_GMI_TXX_SOFT_PAUSE"
#define device_bar_BDK_BGXX_GMP_GMI_TXX_SOFT_PAUSE(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_TXX_SOFT_PAUSE(a,b) (a)
#define arguments_BDK_BGXX_GMP_GMI_TXX_SOFT_PAUSE(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_tx#_thresh
*
* BGX GMI TX Threshold Registers
*/
union bdk_bgxx_gmp_gmi_txx_thresh
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_txx_thresh_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_11_63 : 53;
uint64_t cnt : 11; /**< [ 10: 0](R/W) Number of 128-bit words to accumulate in the TX FIFO before sending on the packet
interface. This field should be large enough to prevent underflow on the packet interface
and must never be set to 0x0. The recommended setting for
In all modes, this register cannot exceed the TX FIFO depth configured by
BGX()_CMR_TX_LMACS[LMACS]. */
#else /* Word 0 - Little Endian */
uint64_t cnt : 11; /**< [ 10: 0](R/W) Number of 128-bit words to accumulate in the TX FIFO before sending on the packet
interface. This field should be large enough to prevent underflow on the packet interface
and must never be set to 0x0. The recommended setting for
In all modes, this register cannot exceed the TX FIFO depth configured by
BGX()_CMR_TX_LMACS[LMACS]. */
uint64_t reserved_11_63 : 53;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_gmi_txx_thresh_s cn; */
};
typedef union bdk_bgxx_gmp_gmi_txx_thresh bdk_bgxx_gmp_gmi_txx_thresh_t;
static inline uint64_t BDK_BGXX_GMP_GMI_TXX_THRESH(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_TXX_THRESH(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038210ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0038210ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0038210ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_GMI_TXX_THRESH", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_TXX_THRESH(a,b) bdk_bgxx_gmp_gmi_txx_thresh_t
#define bustype_BDK_BGXX_GMP_GMI_TXX_THRESH(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_TXX_THRESH(a,b) "BGXX_GMP_GMI_TXX_THRESH"
#define device_bar_BDK_BGXX_GMP_GMI_TXX_THRESH(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_TXX_THRESH(a,b) (a)
#define arguments_BDK_BGXX_GMP_GMI_TXX_THRESH(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_tx_col_attempt
*
* BGX TX Collision Attempts Before Dropping Frame Registers
*/
union bdk_bgxx_gmp_gmi_tx_col_attempt
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_tx_col_attempt_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_5_63 : 59;
uint64_t limit : 5; /**< [ 4: 0](R/W) Number of collision attempts allowed. (SGMII/1000BASE-X half-duplex only.) */
#else /* Word 0 - Little Endian */
uint64_t limit : 5; /**< [ 4: 0](R/W) Number of collision attempts allowed. (SGMII/1000BASE-X half-duplex only.) */
uint64_t reserved_5_63 : 59;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_gmi_tx_col_attempt_s cn; */
};
typedef union bdk_bgxx_gmp_gmi_tx_col_attempt bdk_bgxx_gmp_gmi_tx_col_attempt_t;
static inline uint64_t BDK_BGXX_GMP_GMI_TX_COL_ATTEMPT(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_TX_COL_ATTEMPT(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e0039010ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e0039010ll + 0x1000000ll * ((a) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && (a<=1))
return 0x87e0e0039010ll + 0x1000000ll * ((a) & 0x1);
__bdk_csr_fatal("BGXX_GMP_GMI_TX_COL_ATTEMPT", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_TX_COL_ATTEMPT(a) bdk_bgxx_gmp_gmi_tx_col_attempt_t
#define bustype_BDK_BGXX_GMP_GMI_TX_COL_ATTEMPT(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_TX_COL_ATTEMPT(a) "BGXX_GMP_GMI_TX_COL_ATTEMPT"
#define device_bar_BDK_BGXX_GMP_GMI_TX_COL_ATTEMPT(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_TX_COL_ATTEMPT(a) (a)
#define arguments_BDK_BGXX_GMP_GMI_TX_COL_ATTEMPT(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_tx_ifg
*
* BGX GMI TX Interframe-Gap Cycles Registers
* Consider the following when programming IFG1 and IFG2:
* * For 10/100/1000 Mb/s half-duplex systems that require IEEE 802.3 compatibility, IFG1 must be
* in the range of 1-8, IFG2 must be in the range of 4-12, and the IFG1 + IFG2 sum must be 12.
* * For 10/100/1000 Mb/s full-duplex systems that require IEEE 802.3 compatibility, IFG1 must be
* in the range of 1-11, IFG2 must be in the range of 1-11, and the IFG1 + IFG2 sum must be 12.
* For all other systems, IFG1 and IFG2 can be any value in the range of 1-15, allowing for a
* total possible IFG sum of 2-30.
*/
union bdk_bgxx_gmp_gmi_tx_ifg
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_tx_ifg_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_8_63 : 56;
uint64_t ifg2 : 4; /**< [ 7: 4](R/W) Remainder of interFrameGap timing, equal to interFrameGap - IFG1 (in IFG2 * 8 bits). If
CRS is detected during IFG2, the interFrameSpacing timer is not reset and a frame is
transmitted once the timer expires. */
uint64_t ifg1 : 4; /**< [ 3: 0](R/W) First portion of interFrameGap timing, in the range of 0 to 2/3 (in IFG2 * 8 bits). If CRS
is detected during IFG1, the interFrameSpacing timer is reset and a frame is not
transmitted. */
#else /* Word 0 - Little Endian */
uint64_t ifg1 : 4; /**< [ 3: 0](R/W) First portion of interFrameGap timing, in the range of 0 to 2/3 (in IFG2 * 8 bits). If CRS
is detected during IFG1, the interFrameSpacing timer is reset and a frame is not
transmitted. */
uint64_t ifg2 : 4; /**< [ 7: 4](R/W) Remainder of interFrameGap timing, equal to interFrameGap - IFG1 (in IFG2 * 8 bits). If
CRS is detected during IFG2, the interFrameSpacing timer is not reset and a frame is
transmitted once the timer expires. */
uint64_t reserved_8_63 : 56;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_gmi_tx_ifg_s cn; */
};
typedef union bdk_bgxx_gmp_gmi_tx_ifg bdk_bgxx_gmp_gmi_tx_ifg_t;
static inline uint64_t BDK_BGXX_GMP_GMI_TX_IFG(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_TX_IFG(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e0039000ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e0039000ll + 0x1000000ll * ((a) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && (a<=1))
return 0x87e0e0039000ll + 0x1000000ll * ((a) & 0x1);
__bdk_csr_fatal("BGXX_GMP_GMI_TX_IFG", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_TX_IFG(a) bdk_bgxx_gmp_gmi_tx_ifg_t
#define bustype_BDK_BGXX_GMP_GMI_TX_IFG(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_TX_IFG(a) "BGXX_GMP_GMI_TX_IFG"
#define device_bar_BDK_BGXX_GMP_GMI_TX_IFG(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_TX_IFG(a) (a)
#define arguments_BDK_BGXX_GMP_GMI_TX_IFG(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_tx_jam
*
* BGX GMI TX JAM Pattern Registers
* This register provides the pattern used in JAM bytes.
*/
union bdk_bgxx_gmp_gmi_tx_jam
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_tx_jam_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_8_63 : 56;
uint64_t jam : 8; /**< [ 7: 0](R/W) JAM pattern. (SGMII/1000BASE-X half-duplex only.) */
#else /* Word 0 - Little Endian */
uint64_t jam : 8; /**< [ 7: 0](R/W) JAM pattern. (SGMII/1000BASE-X half-duplex only.) */
uint64_t reserved_8_63 : 56;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_gmi_tx_jam_s cn; */
};
typedef union bdk_bgxx_gmp_gmi_tx_jam bdk_bgxx_gmp_gmi_tx_jam_t;
static inline uint64_t BDK_BGXX_GMP_GMI_TX_JAM(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_TX_JAM(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e0039008ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e0039008ll + 0x1000000ll * ((a) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && (a<=1))
return 0x87e0e0039008ll + 0x1000000ll * ((a) & 0x1);
__bdk_csr_fatal("BGXX_GMP_GMI_TX_JAM", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_TX_JAM(a) bdk_bgxx_gmp_gmi_tx_jam_t
#define bustype_BDK_BGXX_GMP_GMI_TX_JAM(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_TX_JAM(a) "BGXX_GMP_GMI_TX_JAM"
#define device_bar_BDK_BGXX_GMP_GMI_TX_JAM(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_TX_JAM(a) (a)
#define arguments_BDK_BGXX_GMP_GMI_TX_JAM(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_tx_lfsr
*
* BGX GMI TX LFSR Registers
* This register shows the contents of the linear feedback shift register (LFSR), which is used
* to implement truncated binary exponential backoff.
*/
union bdk_bgxx_gmp_gmi_tx_lfsr
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_tx_lfsr_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t lfsr : 16; /**< [ 15: 0](R/W/H) Contains the current state of the LFSR, which is used to feed random numbers to compute
truncated binary exponential backoff. (SGMII/1000Base-X half-duplex only.) */
#else /* Word 0 - Little Endian */
uint64_t lfsr : 16; /**< [ 15: 0](R/W/H) Contains the current state of the LFSR, which is used to feed random numbers to compute
truncated binary exponential backoff. (SGMII/1000Base-X half-duplex only.) */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_gmi_tx_lfsr_s cn; */
};
typedef union bdk_bgxx_gmp_gmi_tx_lfsr bdk_bgxx_gmp_gmi_tx_lfsr_t;
static inline uint64_t BDK_BGXX_GMP_GMI_TX_LFSR(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_TX_LFSR(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e0039028ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e0039028ll + 0x1000000ll * ((a) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && (a<=1))
return 0x87e0e0039028ll + 0x1000000ll * ((a) & 0x1);
__bdk_csr_fatal("BGXX_GMP_GMI_TX_LFSR", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_TX_LFSR(a) bdk_bgxx_gmp_gmi_tx_lfsr_t
#define bustype_BDK_BGXX_GMP_GMI_TX_LFSR(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_TX_LFSR(a) "BGXX_GMP_GMI_TX_LFSR"
#define device_bar_BDK_BGXX_GMP_GMI_TX_LFSR(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_TX_LFSR(a) (a)
#define arguments_BDK_BGXX_GMP_GMI_TX_LFSR(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_tx_pause_pkt_dmac
*
* BGX TX PAUSE-Packet DMAC-Field Registers
*/
union bdk_bgxx_gmp_gmi_tx_pause_pkt_dmac
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_tx_pause_pkt_dmac_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t dmac : 48; /**< [ 47: 0](R/W) The DMAC field, which is placed in outbound PAUSE packets. */
#else /* Word 0 - Little Endian */
uint64_t dmac : 48; /**< [ 47: 0](R/W) The DMAC field, which is placed in outbound PAUSE packets. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_gmi_tx_pause_pkt_dmac_s cn; */
};
typedef union bdk_bgxx_gmp_gmi_tx_pause_pkt_dmac bdk_bgxx_gmp_gmi_tx_pause_pkt_dmac_t;
static inline uint64_t BDK_BGXX_GMP_GMI_TX_PAUSE_PKT_DMAC(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_TX_PAUSE_PKT_DMAC(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e0039018ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e0039018ll + 0x1000000ll * ((a) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && (a<=1))
return 0x87e0e0039018ll + 0x1000000ll * ((a) & 0x1);
__bdk_csr_fatal("BGXX_GMP_GMI_TX_PAUSE_PKT_DMAC", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_TX_PAUSE_PKT_DMAC(a) bdk_bgxx_gmp_gmi_tx_pause_pkt_dmac_t
#define bustype_BDK_BGXX_GMP_GMI_TX_PAUSE_PKT_DMAC(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_TX_PAUSE_PKT_DMAC(a) "BGXX_GMP_GMI_TX_PAUSE_PKT_DMAC"
#define device_bar_BDK_BGXX_GMP_GMI_TX_PAUSE_PKT_DMAC(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_TX_PAUSE_PKT_DMAC(a) (a)
#define arguments_BDK_BGXX_GMP_GMI_TX_PAUSE_PKT_DMAC(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_gmp_gmi_tx_pause_pkt_type
*
* BGX GMI TX PAUSE-Packet-PTYPE Field Registers
* This register provides the PTYPE field that is placed in outbound PAUSE packets.
*/
union bdk_bgxx_gmp_gmi_tx_pause_pkt_type
{
uint64_t u;
struct bdk_bgxx_gmp_gmi_tx_pause_pkt_type_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t ptype : 16; /**< [ 15: 0](R/W) The PTYPE field placed in outbound PAUSE packets. */
#else /* Word 0 - Little Endian */
uint64_t ptype : 16; /**< [ 15: 0](R/W) The PTYPE field placed in outbound PAUSE packets. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_gmi_tx_pause_pkt_type_s cn; */
};
typedef union bdk_bgxx_gmp_gmi_tx_pause_pkt_type bdk_bgxx_gmp_gmi_tx_pause_pkt_type_t;
static inline uint64_t BDK_BGXX_GMP_GMI_TX_PAUSE_PKT_TYPE(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_GMI_TX_PAUSE_PKT_TYPE(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e0039020ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e0039020ll + 0x1000000ll * ((a) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && (a<=1))
return 0x87e0e0039020ll + 0x1000000ll * ((a) & 0x1);
__bdk_csr_fatal("BGXX_GMP_GMI_TX_PAUSE_PKT_TYPE", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_GMP_GMI_TX_PAUSE_PKT_TYPE(a) bdk_bgxx_gmp_gmi_tx_pause_pkt_type_t
#define bustype_BDK_BGXX_GMP_GMI_TX_PAUSE_PKT_TYPE(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_GMI_TX_PAUSE_PKT_TYPE(a) "BGXX_GMP_GMI_TX_PAUSE_PKT_TYPE"
#define device_bar_BDK_BGXX_GMP_GMI_TX_PAUSE_PKT_TYPE(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_GMI_TX_PAUSE_PKT_TYPE(a) (a)
#define arguments_BDK_BGXX_GMP_GMI_TX_PAUSE_PKT_TYPE(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_gmp_pcs_an#_adv
*
* BGX GMP PCS Autonegotiation Advertisement Registers
*/
union bdk_bgxx_gmp_pcs_anx_adv
{
uint64_t u;
struct bdk_bgxx_gmp_pcs_anx_adv_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t np : 1; /**< [ 15: 15](RO/H) Next page capable. This feature is not supported; this field is always 0. */
uint64_t reserved_14 : 1;
uint64_t rem_flt : 2; /**< [ 13: 12](R/W/H) Remote fault.
0x0 = Link OK, XMIT = DATA.
0x1 = Link failure (loss of sync, XMIT !=DATA).
0x2 = Local device offline.
0x3 = Autonegotiation error; failure to complete autonegotiation. AN error is set if
resolution function precludes operation with link partner. */
uint64_t reserved_9_11 : 3;
uint64_t pause : 2; /**< [ 8: 7](R/W) PAUSE frame flow capability across link, exchanged during autonegotiation as follows:
0x0 = No PAUSE.
0x1 = Symmetric PAUSE.
0x2 = Asymmetric PAUSE.
0x3 = Both symmetric and asymmetric PAUSE to local device. */
uint64_t hfd : 1; /**< [ 6: 6](R/W) Half-duplex. When set, local device is half-duplex capable. */
uint64_t fd : 1; /**< [ 5: 5](R/W) Full-duplex. When set, local device is full-duplex capable. */
uint64_t reserved_0_4 : 5;
#else /* Word 0 - Little Endian */
uint64_t reserved_0_4 : 5;
uint64_t fd : 1; /**< [ 5: 5](R/W) Full-duplex. When set, local device is full-duplex capable. */
uint64_t hfd : 1; /**< [ 6: 6](R/W) Half-duplex. When set, local device is half-duplex capable. */
uint64_t pause : 2; /**< [ 8: 7](R/W) PAUSE frame flow capability across link, exchanged during autonegotiation as follows:
0x0 = No PAUSE.
0x1 = Symmetric PAUSE.
0x2 = Asymmetric PAUSE.
0x3 = Both symmetric and asymmetric PAUSE to local device. */
uint64_t reserved_9_11 : 3;
uint64_t rem_flt : 2; /**< [ 13: 12](R/W/H) Remote fault.
0x0 = Link OK, XMIT = DATA.
0x1 = Link failure (loss of sync, XMIT !=DATA).
0x2 = Local device offline.
0x3 = Autonegotiation error; failure to complete autonegotiation. AN error is set if
resolution function precludes operation with link partner. */
uint64_t reserved_14 : 1;
uint64_t np : 1; /**< [ 15: 15](RO/H) Next page capable. This feature is not supported; this field is always 0. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_pcs_anx_adv_s cn; */
};
typedef union bdk_bgxx_gmp_pcs_anx_adv bdk_bgxx_gmp_pcs_anx_adv_t;
static inline uint64_t BDK_BGXX_GMP_PCS_ANX_ADV(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_PCS_ANX_ADV(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030010ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0030010ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030010ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_PCS_ANX_ADV", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_PCS_ANX_ADV(a,b) bdk_bgxx_gmp_pcs_anx_adv_t
#define bustype_BDK_BGXX_GMP_PCS_ANX_ADV(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_PCS_ANX_ADV(a,b) "BGXX_GMP_PCS_ANX_ADV"
#define device_bar_BDK_BGXX_GMP_PCS_ANX_ADV(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_PCS_ANX_ADV(a,b) (a)
#define arguments_BDK_BGXX_GMP_PCS_ANX_ADV(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_pcs_an#_ext_st
*
* BGX GMO PCS Autonegotiation Extended Status Registers
*/
union bdk_bgxx_gmp_pcs_anx_ext_st
{
uint64_t u;
struct bdk_bgxx_gmp_pcs_anx_ext_st_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t thou_xfd : 1; /**< [ 15: 15](RO/H) When set, PHY is 1000 BASE-X full duplex capable. */
uint64_t thou_xhd : 1; /**< [ 14: 14](RO/H) When set, PHY is 1000 BASE-X half duplex capable. */
uint64_t thou_tfd : 1; /**< [ 13: 13](RO/H) When set, PHY is 1000 BASE-T full duplex capable. */
uint64_t thou_thd : 1; /**< [ 12: 12](RO/H) When set, PHY is 1000 BASE-T half duplex capable. */
uint64_t reserved_0_11 : 12;
#else /* Word 0 - Little Endian */
uint64_t reserved_0_11 : 12;
uint64_t thou_thd : 1; /**< [ 12: 12](RO/H) When set, PHY is 1000 BASE-T half duplex capable. */
uint64_t thou_tfd : 1; /**< [ 13: 13](RO/H) When set, PHY is 1000 BASE-T full duplex capable. */
uint64_t thou_xhd : 1; /**< [ 14: 14](RO/H) When set, PHY is 1000 BASE-X half duplex capable. */
uint64_t thou_xfd : 1; /**< [ 15: 15](RO/H) When set, PHY is 1000 BASE-X full duplex capable. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_pcs_anx_ext_st_s cn; */
};
typedef union bdk_bgxx_gmp_pcs_anx_ext_st bdk_bgxx_gmp_pcs_anx_ext_st_t;
static inline uint64_t BDK_BGXX_GMP_PCS_ANX_EXT_ST(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_PCS_ANX_EXT_ST(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030028ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0030028ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030028ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_PCS_ANX_EXT_ST", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_PCS_ANX_EXT_ST(a,b) bdk_bgxx_gmp_pcs_anx_ext_st_t
#define bustype_BDK_BGXX_GMP_PCS_ANX_EXT_ST(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_PCS_ANX_EXT_ST(a,b) "BGXX_GMP_PCS_ANX_EXT_ST"
#define device_bar_BDK_BGXX_GMP_PCS_ANX_EXT_ST(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_PCS_ANX_EXT_ST(a,b) (a)
#define arguments_BDK_BGXX_GMP_PCS_ANX_EXT_ST(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_pcs_an#_lp_abil
*
* BGX GMP PCS Autonegotiation Link Partner Ability Registers
* This is the autonegotiation link partner ability register 5 as per IEEE 802.3, Clause 37.
*/
union bdk_bgxx_gmp_pcs_anx_lp_abil
{
uint64_t u;
struct bdk_bgxx_gmp_pcs_anx_lp_abil_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t np : 1; /**< [ 15: 15](RO/H) Next page capable:
0 = Link partner not next page capable.
1 = Link partner next page capable. */
uint64_t ack : 1; /**< [ 14: 14](RO/H) When set, indicates acknowledgement received. */
uint64_t rem_flt : 2; /**< [ 13: 12](RO/H) Link partner's link status as follows:
0x0 = Link OK.
0x1 = Offline.
0x2 = Link failure.
0x3 = Autonegotiation error. */
uint64_t reserved_9_11 : 3;
uint64_t pause : 2; /**< [ 8: 7](RO/H) Link partner PAUSE setting as follows:
0x0 = No PAUSE.
0x1 = Symmetric PAUSE.
0x2 = Asymmetric PAUSE.
0x3 = Both symmetric and asymmetric PAUSE to local device. */
uint64_t hfd : 1; /**< [ 6: 6](RO/H) Half-duplex. When set, link partner is half-duplex capable. */
uint64_t fd : 1; /**< [ 5: 5](RO/H) Full-duplex. When set, link partner is full-duplex capable. */
uint64_t reserved_0_4 : 5;
#else /* Word 0 - Little Endian */
uint64_t reserved_0_4 : 5;
uint64_t fd : 1; /**< [ 5: 5](RO/H) Full-duplex. When set, link partner is full-duplex capable. */
uint64_t hfd : 1; /**< [ 6: 6](RO/H) Half-duplex. When set, link partner is half-duplex capable. */
uint64_t pause : 2; /**< [ 8: 7](RO/H) Link partner PAUSE setting as follows:
0x0 = No PAUSE.
0x1 = Symmetric PAUSE.
0x2 = Asymmetric PAUSE.
0x3 = Both symmetric and asymmetric PAUSE to local device. */
uint64_t reserved_9_11 : 3;
uint64_t rem_flt : 2; /**< [ 13: 12](RO/H) Link partner's link status as follows:
0x0 = Link OK.
0x1 = Offline.
0x2 = Link failure.
0x3 = Autonegotiation error. */
uint64_t ack : 1; /**< [ 14: 14](RO/H) When set, indicates acknowledgement received. */
uint64_t np : 1; /**< [ 15: 15](RO/H) Next page capable:
0 = Link partner not next page capable.
1 = Link partner next page capable. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_pcs_anx_lp_abil_s cn; */
};
typedef union bdk_bgxx_gmp_pcs_anx_lp_abil bdk_bgxx_gmp_pcs_anx_lp_abil_t;
static inline uint64_t BDK_BGXX_GMP_PCS_ANX_LP_ABIL(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_PCS_ANX_LP_ABIL(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030018ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0030018ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030018ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_PCS_ANX_LP_ABIL", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_PCS_ANX_LP_ABIL(a,b) bdk_bgxx_gmp_pcs_anx_lp_abil_t
#define bustype_BDK_BGXX_GMP_PCS_ANX_LP_ABIL(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_PCS_ANX_LP_ABIL(a,b) "BGXX_GMP_PCS_ANX_LP_ABIL"
#define device_bar_BDK_BGXX_GMP_PCS_ANX_LP_ABIL(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_PCS_ANX_LP_ABIL(a,b) (a)
#define arguments_BDK_BGXX_GMP_PCS_ANX_LP_ABIL(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_pcs_an#_results
*
* BGX GMP PCS Autonegotiation Results Registers
* This register is not valid when BGX()_GMP_PCS_MISC()_CTL[AN_OVRD] is set to 1. If
* BGX()_GMP_PCS_MISC()_CTL[AN_OVRD] is set to 0 and
* BGX()_GMP_PCS_AN()_RESULTS[AN_CPT] is set to 1, this register is valid.
*/
union bdk_bgxx_gmp_pcs_anx_results
{
uint64_t u;
struct bdk_bgxx_gmp_pcs_anx_results_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_7_63 : 57;
uint64_t pause : 2; /**< [ 6: 5](RO/H) PAUSE selection ('don't care' for SGMII/QSGMII) as follows:
0x0 = Disable PAUSE, TX and RX.
0x1 = Enable PAUSE frames, RX only.
0x2 = Enable PAUSE frames, TX only.
0x3 = Enable PAUSE frames, TX and RX. */
uint64_t spd : 2; /**< [ 4: 3](RO/H) Link speed selection as follows:
0x0 = 10 Mb/s.
0x1 = 100 Mb/s.
0x2 = 1000 Mb/s.
0x3 = Reserved. */
uint64_t an_cpt : 1; /**< [ 2: 2](RO/H) Autonegotiation completed.
1 = Autonegotiation completed.
0 = Autonegotiation not completed or failed. */
uint64_t dup : 1; /**< [ 1: 1](RO/H) Duplex mode. 1 = full duplex, 0 = half duplex. */
uint64_t link_ok : 1; /**< [ 0: 0](RO/H) Link status: 1 = link up (OK), 1 = link down. */
#else /* Word 0 - Little Endian */
uint64_t link_ok : 1; /**< [ 0: 0](RO/H) Link status: 1 = link up (OK), 1 = link down. */
uint64_t dup : 1; /**< [ 1: 1](RO/H) Duplex mode. 1 = full duplex, 0 = half duplex. */
uint64_t an_cpt : 1; /**< [ 2: 2](RO/H) Autonegotiation completed.
1 = Autonegotiation completed.
0 = Autonegotiation not completed or failed. */
uint64_t spd : 2; /**< [ 4: 3](RO/H) Link speed selection as follows:
0x0 = 10 Mb/s.
0x1 = 100 Mb/s.
0x2 = 1000 Mb/s.
0x3 = Reserved. */
uint64_t pause : 2; /**< [ 6: 5](RO/H) PAUSE selection ('don't care' for SGMII/QSGMII) as follows:
0x0 = Disable PAUSE, TX and RX.
0x1 = Enable PAUSE frames, RX only.
0x2 = Enable PAUSE frames, TX only.
0x3 = Enable PAUSE frames, TX and RX. */
uint64_t reserved_7_63 : 57;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_pcs_anx_results_s cn81xx; */
struct bdk_bgxx_gmp_pcs_anx_results_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_7_63 : 57;
uint64_t pause : 2; /**< [ 6: 5](RO/H) PAUSE selection ('don't care' for SGMII) as follows:
0x0 = Disable PAUSE, TX and RX.
0x1 = Enable PAUSE frames, RX only.
0x2 = Enable PAUSE frames, TX only.
0x3 = Enable PAUSE frames, TX and RX. */
uint64_t spd : 2; /**< [ 4: 3](RO/H) Link speed selection as follows:
0x0 = 10 Mb/s.
0x1 = 100 Mb/s.
0x2 = 1000 Mb/s.
0x3 = Reserved. */
uint64_t an_cpt : 1; /**< [ 2: 2](RO/H) Autonegotiation completed.
1 = Autonegotiation completed.
0 = Autonegotiation not completed or failed. */
uint64_t dup : 1; /**< [ 1: 1](RO/H) Duplex mode. 1 = full duplex, 0 = half duplex. */
uint64_t link_ok : 1; /**< [ 0: 0](RO/H) Link status: 1 = link up (OK), 1 = link down. */
#else /* Word 0 - Little Endian */
uint64_t link_ok : 1; /**< [ 0: 0](RO/H) Link status: 1 = link up (OK), 1 = link down. */
uint64_t dup : 1; /**< [ 1: 1](RO/H) Duplex mode. 1 = full duplex, 0 = half duplex. */
uint64_t an_cpt : 1; /**< [ 2: 2](RO/H) Autonegotiation completed.
1 = Autonegotiation completed.
0 = Autonegotiation not completed or failed. */
uint64_t spd : 2; /**< [ 4: 3](RO/H) Link speed selection as follows:
0x0 = 10 Mb/s.
0x1 = 100 Mb/s.
0x2 = 1000 Mb/s.
0x3 = Reserved. */
uint64_t pause : 2; /**< [ 6: 5](RO/H) PAUSE selection ('don't care' for SGMII) as follows:
0x0 = Disable PAUSE, TX and RX.
0x1 = Enable PAUSE frames, RX only.
0x2 = Enable PAUSE frames, TX only.
0x3 = Enable PAUSE frames, TX and RX. */
uint64_t reserved_7_63 : 57;
#endif /* Word 0 - End */
} cn88xx;
/* struct bdk_bgxx_gmp_pcs_anx_results_s cn83xx; */
};
typedef union bdk_bgxx_gmp_pcs_anx_results bdk_bgxx_gmp_pcs_anx_results_t;
static inline uint64_t BDK_BGXX_GMP_PCS_ANX_RESULTS(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_PCS_ANX_RESULTS(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030020ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0030020ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030020ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_PCS_ANX_RESULTS", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_PCS_ANX_RESULTS(a,b) bdk_bgxx_gmp_pcs_anx_results_t
#define bustype_BDK_BGXX_GMP_PCS_ANX_RESULTS(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_PCS_ANX_RESULTS(a,b) "BGXX_GMP_PCS_ANX_RESULTS"
#define device_bar_BDK_BGXX_GMP_PCS_ANX_RESULTS(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_PCS_ANX_RESULTS(a,b) (a)
#define arguments_BDK_BGXX_GMP_PCS_ANX_RESULTS(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_pcs_int#
*
* BGX GMP PCS Interrupt Registers
*/
union bdk_bgxx_gmp_pcs_intx
{
uint64_t u;
struct bdk_bgxx_gmp_pcs_intx_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_13_63 : 51;
uint64_t dbg_sync : 1; /**< [ 12: 12](R/W1C/H) Code group sync failure debug help. BGX()_GMP_PCS_INT()[DBG_SYNC] interrupt fires when
code group
synchronization state machine makes a transition from SYNC_ACQUIRED_1 state to
SYNC_ACQUIRED_2 state. (See IEEE 802.3-2005, figure 37-9). It indicates that a bad code
group was received after code group synchronization was achieved. This interrupt should be
disabled during normal link operation. Use it as a debug help feature only. */
uint64_t dup : 1; /**< [ 11: 11](R/W1C/H) Set whenever duplex mode changes on the link. */
uint64_t sync_bad : 1; /**< [ 10: 10](R/W1C/H) Set by hardware whenever RX sync state machine reaches a bad state. Should never be set
during normal operation. */
uint64_t an_bad : 1; /**< [ 9: 9](R/W1C/H) Set by hardware whenever autonegotiation state machine reaches a bad state. Should never
be set during normal operation. */
uint64_t rxlock : 1; /**< [ 8: 8](R/W1C/H) Set by hardware whenever code group sync or bit lock failure occurs. Cannot fire in loopback1 mode. */
uint64_t rxbad : 1; /**< [ 7: 7](R/W1C/H) Set by hardware whenever RX state machine reaches a bad state. Should never be set during
normal operation. */
uint64_t rxerr : 1; /**< [ 6: 6](R/W1C/H) Set whenever RX receives a code group error in 10-bit to 8-bit decode logic. Cannot fire
in loopback1 mode. */
uint64_t txbad : 1; /**< [ 5: 5](R/W1C/H) Set by hardware whenever TX state machine reaches a bad state. Should never be set during
normal operation. */
uint64_t txfifo : 1; /**< [ 4: 4](R/W1C/H) Set whenever hardware detects a TX FIFO overflow condition. */
uint64_t txfifu : 1; /**< [ 3: 3](R/W1C/H) Set whenever hardware detects a TX FIFO underflow condition. */
uint64_t an_err : 1; /**< [ 2: 2](R/W1C/H) Autonegotiation error; AN resolution function failed. */
uint64_t xmit : 1; /**< [ 1: 1](R/W1C/H) Set whenever hardware detects a change in the XMIT variable. XMIT variable states are
IDLE, CONFIG and DATA. */
uint64_t lnkspd : 1; /**< [ 0: 0](R/W1C/H) Set by hardware whenever link speed has changed. */
#else /* Word 0 - Little Endian */
uint64_t lnkspd : 1; /**< [ 0: 0](R/W1C/H) Set by hardware whenever link speed has changed. */
uint64_t xmit : 1; /**< [ 1: 1](R/W1C/H) Set whenever hardware detects a change in the XMIT variable. XMIT variable states are
IDLE, CONFIG and DATA. */
uint64_t an_err : 1; /**< [ 2: 2](R/W1C/H) Autonegotiation error; AN resolution function failed. */
uint64_t txfifu : 1; /**< [ 3: 3](R/W1C/H) Set whenever hardware detects a TX FIFO underflow condition. */
uint64_t txfifo : 1; /**< [ 4: 4](R/W1C/H) Set whenever hardware detects a TX FIFO overflow condition. */
uint64_t txbad : 1; /**< [ 5: 5](R/W1C/H) Set by hardware whenever TX state machine reaches a bad state. Should never be set during
normal operation. */
uint64_t rxerr : 1; /**< [ 6: 6](R/W1C/H) Set whenever RX receives a code group error in 10-bit to 8-bit decode logic. Cannot fire
in loopback1 mode. */
uint64_t rxbad : 1; /**< [ 7: 7](R/W1C/H) Set by hardware whenever RX state machine reaches a bad state. Should never be set during
normal operation. */
uint64_t rxlock : 1; /**< [ 8: 8](R/W1C/H) Set by hardware whenever code group sync or bit lock failure occurs. Cannot fire in loopback1 mode. */
uint64_t an_bad : 1; /**< [ 9: 9](R/W1C/H) Set by hardware whenever autonegotiation state machine reaches a bad state. Should never
be set during normal operation. */
uint64_t sync_bad : 1; /**< [ 10: 10](R/W1C/H) Set by hardware whenever RX sync state machine reaches a bad state. Should never be set
during normal operation. */
uint64_t dup : 1; /**< [ 11: 11](R/W1C/H) Set whenever duplex mode changes on the link. */
uint64_t dbg_sync : 1; /**< [ 12: 12](R/W1C/H) Code group sync failure debug help. BGX()_GMP_PCS_INT()[DBG_SYNC] interrupt fires when
code group
synchronization state machine makes a transition from SYNC_ACQUIRED_1 state to
SYNC_ACQUIRED_2 state. (See IEEE 802.3-2005, figure 37-9). It indicates that a bad code
group was received after code group synchronization was achieved. This interrupt should be
disabled during normal link operation. Use it as a debug help feature only. */
uint64_t reserved_13_63 : 51;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_pcs_intx_s cn; */
};
typedef union bdk_bgxx_gmp_pcs_intx bdk_bgxx_gmp_pcs_intx_t;
static inline uint64_t BDK_BGXX_GMP_PCS_INTX(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_PCS_INTX(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030080ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0030080ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030080ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_PCS_INTX", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_PCS_INTX(a,b) bdk_bgxx_gmp_pcs_intx_t
#define bustype_BDK_BGXX_GMP_PCS_INTX(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_PCS_INTX(a,b) "BGXX_GMP_PCS_INTX"
#define device_bar_BDK_BGXX_GMP_PCS_INTX(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_PCS_INTX(a,b) (a)
#define arguments_BDK_BGXX_GMP_PCS_INTX(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_pcs_int#_ena_w1c
*
* BGX GMP PCS Interrupt Enable Clear Registers
* This register clears interrupt enable bits.
*/
union bdk_bgxx_gmp_pcs_intx_ena_w1c
{
uint64_t u;
struct bdk_bgxx_gmp_pcs_intx_ena_w1c_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_13_63 : 51;
uint64_t dbg_sync : 1; /**< [ 12: 12](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_PCS_INT(0..3)[DBG_SYNC]. */
uint64_t dup : 1; /**< [ 11: 11](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_PCS_INT(0..3)[DUP]. */
uint64_t sync_bad : 1; /**< [ 10: 10](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_PCS_INT(0..3)[SYNC_BAD]. */
uint64_t an_bad : 1; /**< [ 9: 9](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_PCS_INT(0..3)[AN_BAD]. */
uint64_t rxlock : 1; /**< [ 8: 8](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_PCS_INT(0..3)[RXLOCK]. */
uint64_t rxbad : 1; /**< [ 7: 7](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_PCS_INT(0..3)[RXBAD]. */
uint64_t rxerr : 1; /**< [ 6: 6](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_PCS_INT(0..3)[RXERR]. */
uint64_t txbad : 1; /**< [ 5: 5](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_PCS_INT(0..3)[TXBAD]. */
uint64_t txfifo : 1; /**< [ 4: 4](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_PCS_INT(0..3)[TXFIFO]. */
uint64_t txfifu : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_PCS_INT(0..3)[TXFIFU]. */
uint64_t an_err : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_PCS_INT(0..3)[AN_ERR]. */
uint64_t xmit : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_PCS_INT(0..3)[XMIT]. */
uint64_t lnkspd : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_PCS_INT(0..3)[LNKSPD]. */
#else /* Word 0 - Little Endian */
uint64_t lnkspd : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_PCS_INT(0..3)[LNKSPD]. */
uint64_t xmit : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_PCS_INT(0..3)[XMIT]. */
uint64_t an_err : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_PCS_INT(0..3)[AN_ERR]. */
uint64_t txfifu : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_PCS_INT(0..3)[TXFIFU]. */
uint64_t txfifo : 1; /**< [ 4: 4](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_PCS_INT(0..3)[TXFIFO]. */
uint64_t txbad : 1; /**< [ 5: 5](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_PCS_INT(0..3)[TXBAD]. */
uint64_t rxerr : 1; /**< [ 6: 6](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_PCS_INT(0..3)[RXERR]. */
uint64_t rxbad : 1; /**< [ 7: 7](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_PCS_INT(0..3)[RXBAD]. */
uint64_t rxlock : 1; /**< [ 8: 8](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_PCS_INT(0..3)[RXLOCK]. */
uint64_t an_bad : 1; /**< [ 9: 9](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_PCS_INT(0..3)[AN_BAD]. */
uint64_t sync_bad : 1; /**< [ 10: 10](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_PCS_INT(0..3)[SYNC_BAD]. */
uint64_t dup : 1; /**< [ 11: 11](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_PCS_INT(0..3)[DUP]. */
uint64_t dbg_sync : 1; /**< [ 12: 12](R/W1C/H) Reads or clears enable for BGX(0..1)_GMP_PCS_INT(0..3)[DBG_SYNC]. */
uint64_t reserved_13_63 : 51;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_pcs_intx_ena_w1c_s cn81xx; */
/* struct bdk_bgxx_gmp_pcs_intx_ena_w1c_s cn88xx; */
struct bdk_bgxx_gmp_pcs_intx_ena_w1c_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_13_63 : 51;
uint64_t dbg_sync : 1; /**< [ 12: 12](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_PCS_INT(0..3)[DBG_SYNC]. */
uint64_t dup : 1; /**< [ 11: 11](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_PCS_INT(0..3)[DUP]. */
uint64_t sync_bad : 1; /**< [ 10: 10](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_PCS_INT(0..3)[SYNC_BAD]. */
uint64_t an_bad : 1; /**< [ 9: 9](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_PCS_INT(0..3)[AN_BAD]. */
uint64_t rxlock : 1; /**< [ 8: 8](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_PCS_INT(0..3)[RXLOCK]. */
uint64_t rxbad : 1; /**< [ 7: 7](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_PCS_INT(0..3)[RXBAD]. */
uint64_t rxerr : 1; /**< [ 6: 6](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_PCS_INT(0..3)[RXERR]. */
uint64_t txbad : 1; /**< [ 5: 5](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_PCS_INT(0..3)[TXBAD]. */
uint64_t txfifo : 1; /**< [ 4: 4](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_PCS_INT(0..3)[TXFIFO]. */
uint64_t txfifu : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_PCS_INT(0..3)[TXFIFU]. */
uint64_t an_err : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_PCS_INT(0..3)[AN_ERR]. */
uint64_t xmit : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_PCS_INT(0..3)[XMIT]. */
uint64_t lnkspd : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_PCS_INT(0..3)[LNKSPD]. */
#else /* Word 0 - Little Endian */
uint64_t lnkspd : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_PCS_INT(0..3)[LNKSPD]. */
uint64_t xmit : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_PCS_INT(0..3)[XMIT]. */
uint64_t an_err : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_PCS_INT(0..3)[AN_ERR]. */
uint64_t txfifu : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_PCS_INT(0..3)[TXFIFU]. */
uint64_t txfifo : 1; /**< [ 4: 4](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_PCS_INT(0..3)[TXFIFO]. */
uint64_t txbad : 1; /**< [ 5: 5](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_PCS_INT(0..3)[TXBAD]. */
uint64_t rxerr : 1; /**< [ 6: 6](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_PCS_INT(0..3)[RXERR]. */
uint64_t rxbad : 1; /**< [ 7: 7](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_PCS_INT(0..3)[RXBAD]. */
uint64_t rxlock : 1; /**< [ 8: 8](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_PCS_INT(0..3)[RXLOCK]. */
uint64_t an_bad : 1; /**< [ 9: 9](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_PCS_INT(0..3)[AN_BAD]. */
uint64_t sync_bad : 1; /**< [ 10: 10](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_PCS_INT(0..3)[SYNC_BAD]. */
uint64_t dup : 1; /**< [ 11: 11](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_PCS_INT(0..3)[DUP]. */
uint64_t dbg_sync : 1; /**< [ 12: 12](R/W1C/H) Reads or clears enable for BGX(0..3)_GMP_PCS_INT(0..3)[DBG_SYNC]. */
uint64_t reserved_13_63 : 51;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_gmp_pcs_intx_ena_w1c bdk_bgxx_gmp_pcs_intx_ena_w1c_t;
static inline uint64_t BDK_BGXX_GMP_PCS_INTX_ENA_W1C(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_PCS_INTX_ENA_W1C(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030090ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0030090ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030090ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_PCS_INTX_ENA_W1C", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_PCS_INTX_ENA_W1C(a,b) bdk_bgxx_gmp_pcs_intx_ena_w1c_t
#define bustype_BDK_BGXX_GMP_PCS_INTX_ENA_W1C(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_PCS_INTX_ENA_W1C(a,b) "BGXX_GMP_PCS_INTX_ENA_W1C"
#define device_bar_BDK_BGXX_GMP_PCS_INTX_ENA_W1C(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_PCS_INTX_ENA_W1C(a,b) (a)
#define arguments_BDK_BGXX_GMP_PCS_INTX_ENA_W1C(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_pcs_int#_ena_w1s
*
* BGX GMP PCS Interrupt Enable Set Registers
* This register sets interrupt enable bits.
*/
union bdk_bgxx_gmp_pcs_intx_ena_w1s
{
uint64_t u;
struct bdk_bgxx_gmp_pcs_intx_ena_w1s_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_13_63 : 51;
uint64_t dbg_sync : 1; /**< [ 12: 12](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_PCS_INT(0..3)[DBG_SYNC]. */
uint64_t dup : 1; /**< [ 11: 11](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_PCS_INT(0..3)[DUP]. */
uint64_t sync_bad : 1; /**< [ 10: 10](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_PCS_INT(0..3)[SYNC_BAD]. */
uint64_t an_bad : 1; /**< [ 9: 9](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_PCS_INT(0..3)[AN_BAD]. */
uint64_t rxlock : 1; /**< [ 8: 8](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_PCS_INT(0..3)[RXLOCK]. */
uint64_t rxbad : 1; /**< [ 7: 7](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_PCS_INT(0..3)[RXBAD]. */
uint64_t rxerr : 1; /**< [ 6: 6](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_PCS_INT(0..3)[RXERR]. */
uint64_t txbad : 1; /**< [ 5: 5](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_PCS_INT(0..3)[TXBAD]. */
uint64_t txfifo : 1; /**< [ 4: 4](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_PCS_INT(0..3)[TXFIFO]. */
uint64_t txfifu : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_PCS_INT(0..3)[TXFIFU]. */
uint64_t an_err : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_PCS_INT(0..3)[AN_ERR]. */
uint64_t xmit : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_PCS_INT(0..3)[XMIT]. */
uint64_t lnkspd : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_PCS_INT(0..3)[LNKSPD]. */
#else /* Word 0 - Little Endian */
uint64_t lnkspd : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_PCS_INT(0..3)[LNKSPD]. */
uint64_t xmit : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_PCS_INT(0..3)[XMIT]. */
uint64_t an_err : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_PCS_INT(0..3)[AN_ERR]. */
uint64_t txfifu : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_PCS_INT(0..3)[TXFIFU]. */
uint64_t txfifo : 1; /**< [ 4: 4](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_PCS_INT(0..3)[TXFIFO]. */
uint64_t txbad : 1; /**< [ 5: 5](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_PCS_INT(0..3)[TXBAD]. */
uint64_t rxerr : 1; /**< [ 6: 6](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_PCS_INT(0..3)[RXERR]. */
uint64_t rxbad : 1; /**< [ 7: 7](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_PCS_INT(0..3)[RXBAD]. */
uint64_t rxlock : 1; /**< [ 8: 8](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_PCS_INT(0..3)[RXLOCK]. */
uint64_t an_bad : 1; /**< [ 9: 9](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_PCS_INT(0..3)[AN_BAD]. */
uint64_t sync_bad : 1; /**< [ 10: 10](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_PCS_INT(0..3)[SYNC_BAD]. */
uint64_t dup : 1; /**< [ 11: 11](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_PCS_INT(0..3)[DUP]. */
uint64_t dbg_sync : 1; /**< [ 12: 12](R/W1S/H) Reads or sets enable for BGX(0..1)_GMP_PCS_INT(0..3)[DBG_SYNC]. */
uint64_t reserved_13_63 : 51;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_pcs_intx_ena_w1s_s cn81xx; */
/* struct bdk_bgxx_gmp_pcs_intx_ena_w1s_s cn88xx; */
struct bdk_bgxx_gmp_pcs_intx_ena_w1s_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_13_63 : 51;
uint64_t dbg_sync : 1; /**< [ 12: 12](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_PCS_INT(0..3)[DBG_SYNC]. */
uint64_t dup : 1; /**< [ 11: 11](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_PCS_INT(0..3)[DUP]. */
uint64_t sync_bad : 1; /**< [ 10: 10](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_PCS_INT(0..3)[SYNC_BAD]. */
uint64_t an_bad : 1; /**< [ 9: 9](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_PCS_INT(0..3)[AN_BAD]. */
uint64_t rxlock : 1; /**< [ 8: 8](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_PCS_INT(0..3)[RXLOCK]. */
uint64_t rxbad : 1; /**< [ 7: 7](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_PCS_INT(0..3)[RXBAD]. */
uint64_t rxerr : 1; /**< [ 6: 6](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_PCS_INT(0..3)[RXERR]. */
uint64_t txbad : 1; /**< [ 5: 5](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_PCS_INT(0..3)[TXBAD]. */
uint64_t txfifo : 1; /**< [ 4: 4](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_PCS_INT(0..3)[TXFIFO]. */
uint64_t txfifu : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_PCS_INT(0..3)[TXFIFU]. */
uint64_t an_err : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_PCS_INT(0..3)[AN_ERR]. */
uint64_t xmit : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_PCS_INT(0..3)[XMIT]. */
uint64_t lnkspd : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_PCS_INT(0..3)[LNKSPD]. */
#else /* Word 0 - Little Endian */
uint64_t lnkspd : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_PCS_INT(0..3)[LNKSPD]. */
uint64_t xmit : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_PCS_INT(0..3)[XMIT]. */
uint64_t an_err : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_PCS_INT(0..3)[AN_ERR]. */
uint64_t txfifu : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_PCS_INT(0..3)[TXFIFU]. */
uint64_t txfifo : 1; /**< [ 4: 4](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_PCS_INT(0..3)[TXFIFO]. */
uint64_t txbad : 1; /**< [ 5: 5](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_PCS_INT(0..3)[TXBAD]. */
uint64_t rxerr : 1; /**< [ 6: 6](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_PCS_INT(0..3)[RXERR]. */
uint64_t rxbad : 1; /**< [ 7: 7](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_PCS_INT(0..3)[RXBAD]. */
uint64_t rxlock : 1; /**< [ 8: 8](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_PCS_INT(0..3)[RXLOCK]. */
uint64_t an_bad : 1; /**< [ 9: 9](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_PCS_INT(0..3)[AN_BAD]. */
uint64_t sync_bad : 1; /**< [ 10: 10](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_PCS_INT(0..3)[SYNC_BAD]. */
uint64_t dup : 1; /**< [ 11: 11](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_PCS_INT(0..3)[DUP]. */
uint64_t dbg_sync : 1; /**< [ 12: 12](R/W1S/H) Reads or sets enable for BGX(0..3)_GMP_PCS_INT(0..3)[DBG_SYNC]. */
uint64_t reserved_13_63 : 51;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_gmp_pcs_intx_ena_w1s bdk_bgxx_gmp_pcs_intx_ena_w1s_t;
static inline uint64_t BDK_BGXX_GMP_PCS_INTX_ENA_W1S(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_PCS_INTX_ENA_W1S(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030098ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0030098ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030098ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_PCS_INTX_ENA_W1S", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_PCS_INTX_ENA_W1S(a,b) bdk_bgxx_gmp_pcs_intx_ena_w1s_t
#define bustype_BDK_BGXX_GMP_PCS_INTX_ENA_W1S(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_PCS_INTX_ENA_W1S(a,b) "BGXX_GMP_PCS_INTX_ENA_W1S"
#define device_bar_BDK_BGXX_GMP_PCS_INTX_ENA_W1S(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_PCS_INTX_ENA_W1S(a,b) (a)
#define arguments_BDK_BGXX_GMP_PCS_INTX_ENA_W1S(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_pcs_int#_w1s
*
* BGX GMP PCS Interrupt Set Registers
* This register sets interrupt bits.
*/
union bdk_bgxx_gmp_pcs_intx_w1s
{
uint64_t u;
struct bdk_bgxx_gmp_pcs_intx_w1s_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_13_63 : 51;
uint64_t dbg_sync : 1; /**< [ 12: 12](R/W1S/H) Reads or sets BGX(0..1)_GMP_PCS_INT(0..3)[DBG_SYNC]. */
uint64_t dup : 1; /**< [ 11: 11](R/W1S/H) Reads or sets BGX(0..1)_GMP_PCS_INT(0..3)[DUP]. */
uint64_t sync_bad : 1; /**< [ 10: 10](R/W1S/H) Reads or sets BGX(0..1)_GMP_PCS_INT(0..3)[SYNC_BAD]. */
uint64_t an_bad : 1; /**< [ 9: 9](R/W1S/H) Reads or sets BGX(0..1)_GMP_PCS_INT(0..3)[AN_BAD]. */
uint64_t rxlock : 1; /**< [ 8: 8](R/W1S/H) Reads or sets BGX(0..1)_GMP_PCS_INT(0..3)[RXLOCK]. */
uint64_t rxbad : 1; /**< [ 7: 7](R/W1S/H) Reads or sets BGX(0..1)_GMP_PCS_INT(0..3)[RXBAD]. */
uint64_t rxerr : 1; /**< [ 6: 6](R/W1S/H) Reads or sets BGX(0..1)_GMP_PCS_INT(0..3)[RXERR]. */
uint64_t txbad : 1; /**< [ 5: 5](R/W1S/H) Reads or sets BGX(0..1)_GMP_PCS_INT(0..3)[TXBAD]. */
uint64_t txfifo : 1; /**< [ 4: 4](R/W1S/H) Reads or sets BGX(0..1)_GMP_PCS_INT(0..3)[TXFIFO]. */
uint64_t txfifu : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..1)_GMP_PCS_INT(0..3)[TXFIFU]. */
uint64_t an_err : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..1)_GMP_PCS_INT(0..3)[AN_ERR]. */
uint64_t xmit : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..1)_GMP_PCS_INT(0..3)[XMIT]. */
uint64_t lnkspd : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..1)_GMP_PCS_INT(0..3)[LNKSPD]. */
#else /* Word 0 - Little Endian */
uint64_t lnkspd : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..1)_GMP_PCS_INT(0..3)[LNKSPD]. */
uint64_t xmit : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..1)_GMP_PCS_INT(0..3)[XMIT]. */
uint64_t an_err : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..1)_GMP_PCS_INT(0..3)[AN_ERR]. */
uint64_t txfifu : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..1)_GMP_PCS_INT(0..3)[TXFIFU]. */
uint64_t txfifo : 1; /**< [ 4: 4](R/W1S/H) Reads or sets BGX(0..1)_GMP_PCS_INT(0..3)[TXFIFO]. */
uint64_t txbad : 1; /**< [ 5: 5](R/W1S/H) Reads or sets BGX(0..1)_GMP_PCS_INT(0..3)[TXBAD]. */
uint64_t rxerr : 1; /**< [ 6: 6](R/W1S/H) Reads or sets BGX(0..1)_GMP_PCS_INT(0..3)[RXERR]. */
uint64_t rxbad : 1; /**< [ 7: 7](R/W1S/H) Reads or sets BGX(0..1)_GMP_PCS_INT(0..3)[RXBAD]. */
uint64_t rxlock : 1; /**< [ 8: 8](R/W1S/H) Reads or sets BGX(0..1)_GMP_PCS_INT(0..3)[RXLOCK]. */
uint64_t an_bad : 1; /**< [ 9: 9](R/W1S/H) Reads or sets BGX(0..1)_GMP_PCS_INT(0..3)[AN_BAD]. */
uint64_t sync_bad : 1; /**< [ 10: 10](R/W1S/H) Reads or sets BGX(0..1)_GMP_PCS_INT(0..3)[SYNC_BAD]. */
uint64_t dup : 1; /**< [ 11: 11](R/W1S/H) Reads or sets BGX(0..1)_GMP_PCS_INT(0..3)[DUP]. */
uint64_t dbg_sync : 1; /**< [ 12: 12](R/W1S/H) Reads or sets BGX(0..1)_GMP_PCS_INT(0..3)[DBG_SYNC]. */
uint64_t reserved_13_63 : 51;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_pcs_intx_w1s_s cn81xx; */
/* struct bdk_bgxx_gmp_pcs_intx_w1s_s cn88xx; */
struct bdk_bgxx_gmp_pcs_intx_w1s_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_13_63 : 51;
uint64_t dbg_sync : 1; /**< [ 12: 12](R/W1S/H) Reads or sets BGX(0..3)_GMP_PCS_INT(0..3)[DBG_SYNC]. */
uint64_t dup : 1; /**< [ 11: 11](R/W1S/H) Reads or sets BGX(0..3)_GMP_PCS_INT(0..3)[DUP]. */
uint64_t sync_bad : 1; /**< [ 10: 10](R/W1S/H) Reads or sets BGX(0..3)_GMP_PCS_INT(0..3)[SYNC_BAD]. */
uint64_t an_bad : 1; /**< [ 9: 9](R/W1S/H) Reads or sets BGX(0..3)_GMP_PCS_INT(0..3)[AN_BAD]. */
uint64_t rxlock : 1; /**< [ 8: 8](R/W1S/H) Reads or sets BGX(0..3)_GMP_PCS_INT(0..3)[RXLOCK]. */
uint64_t rxbad : 1; /**< [ 7: 7](R/W1S/H) Reads or sets BGX(0..3)_GMP_PCS_INT(0..3)[RXBAD]. */
uint64_t rxerr : 1; /**< [ 6: 6](R/W1S/H) Reads or sets BGX(0..3)_GMP_PCS_INT(0..3)[RXERR]. */
uint64_t txbad : 1; /**< [ 5: 5](R/W1S/H) Reads or sets BGX(0..3)_GMP_PCS_INT(0..3)[TXBAD]. */
uint64_t txfifo : 1; /**< [ 4: 4](R/W1S/H) Reads or sets BGX(0..3)_GMP_PCS_INT(0..3)[TXFIFO]. */
uint64_t txfifu : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..3)_GMP_PCS_INT(0..3)[TXFIFU]. */
uint64_t an_err : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..3)_GMP_PCS_INT(0..3)[AN_ERR]. */
uint64_t xmit : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..3)_GMP_PCS_INT(0..3)[XMIT]. */
uint64_t lnkspd : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..3)_GMP_PCS_INT(0..3)[LNKSPD]. */
#else /* Word 0 - Little Endian */
uint64_t lnkspd : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..3)_GMP_PCS_INT(0..3)[LNKSPD]. */
uint64_t xmit : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..3)_GMP_PCS_INT(0..3)[XMIT]. */
uint64_t an_err : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..3)_GMP_PCS_INT(0..3)[AN_ERR]. */
uint64_t txfifu : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..3)_GMP_PCS_INT(0..3)[TXFIFU]. */
uint64_t txfifo : 1; /**< [ 4: 4](R/W1S/H) Reads or sets BGX(0..3)_GMP_PCS_INT(0..3)[TXFIFO]. */
uint64_t txbad : 1; /**< [ 5: 5](R/W1S/H) Reads or sets BGX(0..3)_GMP_PCS_INT(0..3)[TXBAD]. */
uint64_t rxerr : 1; /**< [ 6: 6](R/W1S/H) Reads or sets BGX(0..3)_GMP_PCS_INT(0..3)[RXERR]. */
uint64_t rxbad : 1; /**< [ 7: 7](R/W1S/H) Reads or sets BGX(0..3)_GMP_PCS_INT(0..3)[RXBAD]. */
uint64_t rxlock : 1; /**< [ 8: 8](R/W1S/H) Reads or sets BGX(0..3)_GMP_PCS_INT(0..3)[RXLOCK]. */
uint64_t an_bad : 1; /**< [ 9: 9](R/W1S/H) Reads or sets BGX(0..3)_GMP_PCS_INT(0..3)[AN_BAD]. */
uint64_t sync_bad : 1; /**< [ 10: 10](R/W1S/H) Reads or sets BGX(0..3)_GMP_PCS_INT(0..3)[SYNC_BAD]. */
uint64_t dup : 1; /**< [ 11: 11](R/W1S/H) Reads or sets BGX(0..3)_GMP_PCS_INT(0..3)[DUP]. */
uint64_t dbg_sync : 1; /**< [ 12: 12](R/W1S/H) Reads or sets BGX(0..3)_GMP_PCS_INT(0..3)[DBG_SYNC]. */
uint64_t reserved_13_63 : 51;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_gmp_pcs_intx_w1s bdk_bgxx_gmp_pcs_intx_w1s_t;
static inline uint64_t BDK_BGXX_GMP_PCS_INTX_W1S(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_PCS_INTX_W1S(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030088ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0030088ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030088ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_PCS_INTX_W1S", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_PCS_INTX_W1S(a,b) bdk_bgxx_gmp_pcs_intx_w1s_t
#define bustype_BDK_BGXX_GMP_PCS_INTX_W1S(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_PCS_INTX_W1S(a,b) "BGXX_GMP_PCS_INTX_W1S"
#define device_bar_BDK_BGXX_GMP_PCS_INTX_W1S(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_PCS_INTX_W1S(a,b) (a)
#define arguments_BDK_BGXX_GMP_PCS_INTX_W1S(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_pcs_link#_timer
*
* BGX GMP PCS Link Timer Registers
* This is the 1.6 ms nominal link timer register.
*/
union bdk_bgxx_gmp_pcs_linkx_timer
{
uint64_t u;
struct bdk_bgxx_gmp_pcs_linkx_timer_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t count : 16; /**< [ 15: 0](R/W) (Coprocessor clock period * 1024) * [COUNT] should be 1.6 ms for SGMII/QSGMII and 10 ms
otherwise,
which is the link timer used in autonegotiation. Reset assumes a 700 MHz coprocessor
clock for 1.6 ms link timer. */
#else /* Word 0 - Little Endian */
uint64_t count : 16; /**< [ 15: 0](R/W) (Coprocessor clock period * 1024) * [COUNT] should be 1.6 ms for SGMII/QSGMII and 10 ms
otherwise,
which is the link timer used in autonegotiation. Reset assumes a 700 MHz coprocessor
clock for 1.6 ms link timer. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_pcs_linkx_timer_s cn81xx; */
struct bdk_bgxx_gmp_pcs_linkx_timer_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t count : 16; /**< [ 15: 0](R/W) (Coprocessor clock period * 1024) * COUNT should be 1.6 ms for SGMII and 10 ms otherwise,
which is the link timer used in autonegotiation. Reset assumes a 700 MHz coprocessor
clock for 1.6 ms link timer. */
#else /* Word 0 - Little Endian */
uint64_t count : 16; /**< [ 15: 0](R/W) (Coprocessor clock period * 1024) * COUNT should be 1.6 ms for SGMII and 10 ms otherwise,
which is the link timer used in autonegotiation. Reset assumes a 700 MHz coprocessor
clock for 1.6 ms link timer. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} cn88xx;
/* struct bdk_bgxx_gmp_pcs_linkx_timer_s cn83xx; */
};
typedef union bdk_bgxx_gmp_pcs_linkx_timer bdk_bgxx_gmp_pcs_linkx_timer_t;
static inline uint64_t BDK_BGXX_GMP_PCS_LINKX_TIMER(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_PCS_LINKX_TIMER(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030040ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0030040ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030040ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_PCS_LINKX_TIMER", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_PCS_LINKX_TIMER(a,b) bdk_bgxx_gmp_pcs_linkx_timer_t
#define bustype_BDK_BGXX_GMP_PCS_LINKX_TIMER(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_PCS_LINKX_TIMER(a,b) "BGXX_GMP_PCS_LINKX_TIMER"
#define device_bar_BDK_BGXX_GMP_PCS_LINKX_TIMER(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_PCS_LINKX_TIMER(a,b) (a)
#define arguments_BDK_BGXX_GMP_PCS_LINKX_TIMER(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_pcs_misc#_ctl
*
* BGX GMP SGMII Miscellaneous Control Registers
* Internal:
* SGMII bit [12] is really a misnomer, it is a decode of pi_qlm_cfg pins to indicate SGMII or
* 1000Base-X modes.
*
* Note: The SGMII AN Advertisement Register above will be sent during Auto Negotiation if
* [MAC_PHY] is set (1=PHY mode). If the bit is not set (0=MAC mode), the
* tx_Config_Reg\<14\> becomes ACK bit and tx_Config_Reg\<0\> is always 1.
* All other bits in tx_Config_Reg sent will be 0. The PHY dictates the Auto Negotiation results.
*/
union bdk_bgxx_gmp_pcs_miscx_ctl
{
uint64_t u;
struct bdk_bgxx_gmp_pcs_miscx_ctl_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_33_63 : 31;
uint64_t qsgmii_comma_wd_en : 1; /**< [ 32: 32](R/W) QSGMII comma watchdog byte counter enable. */
uint64_t qsgmii_comma_wd : 16; /**< [ 31: 16](R/W) QSGMII comma watchdog byte counter. This counter is used in QSGMII mode and
counts incoming bytes to ensure state transitions in the PCS receive side state
machine when disparity enable is turned off and bad code groups and commas are
not communicated from the code group processor after code group lock. */
uint64_t reserved_14_15 : 2;
uint64_t disp_en : 1; /**< [ 13: 13](R/W) Disparity check enable. When LMAC_TYPE=QSGMII the running disparity check should be
disabled
to
prevent propogation across ports.
0 = disable disparity check
1 = enable disparity checking
See GSER()_LANE_MODE[LMODE]. */
uint64_t sgmii : 1; /**< [ 12: 12](RO/H) Reserved. Always 1. */
uint64_t gmxeno : 1; /**< [ 11: 11](R/W) GMI enable override. When set, forces GMI to appear disabled. The enable/disable status of
GMI is checked only at SOP of every packet. */
uint64_t loopbck2 : 1; /**< [ 10: 10](R/W) Sets external loopback mode to return RX data back out via the TX data path. 0 = No
loopback. 1 = Loopback.
LOOPBCK1 and LOOPBCK2 modes may not be supported simultaneously. */
uint64_t mac_phy : 1; /**< [ 9: 9](R/W) MAC/PHY.
0 = MAC.
1 = PHY decides the tx_Config_Reg value to be sent during autonegotiation. */
uint64_t mode : 1; /**< [ 8: 8](R/W) Mode bit.
_ 0 = SGMII mode is selected and the following note applies.
The SGMII AN advertisement register (BGX()_GMP_PCS_SGM()_AN_ADV) is sent during
autonegotiation if BGX()_GMP_PCS_MISC()_CTL[MAC_PHY] = 1 (PHY mode). If [MAC_PHY]
= 0 (MAC mode), the tx_Config_Reg\<14\> becomes ACK bit and \<0\> is always 1. All other bits
in tx_Config_Reg sent are 0. The PHY dictates the autonegotiation results.
_ 1 = 1000Base-X mode is selected. Autonegotiation follows IEEE 802.3 clause 37. */
uint64_t an_ovrd : 1; /**< [ 7: 7](R/W) Autonegotiation results override:
0 = Disable.
1 = Enable override. Autonegotiation is allowed to happen but the results are ignored
when this bit is set. Duplex and Link speed values are set from BGX()_GMP_PCS_MISC()_CTL. */
uint64_t samp_pt : 7; /**< [ 6: 0](R/W) Byte number in elongated frames for 10/100 Mb/s operation for data sampling on RX side in
PCS. Recommended values are 0x5 for 100 Mb/s operation and 0x32 for 10 Mb/s operation.
For 10 Mb/s operation, this field should be set to a value less than 99 and greater than
0.
If set out of this range, a value of 50 is used for actual sampling internally without
affecting the CSR field.
For 100 Mb/s operation this field should be set to a value less than 9 and greater than 0.
If set out of this range, a value of 5 is used for actual sampling internally without
affecting the CSR field. */
#else /* Word 0 - Little Endian */
uint64_t samp_pt : 7; /**< [ 6: 0](R/W) Byte number in elongated frames for 10/100 Mb/s operation for data sampling on RX side in
PCS. Recommended values are 0x5 for 100 Mb/s operation and 0x32 for 10 Mb/s operation.
For 10 Mb/s operation, this field should be set to a value less than 99 and greater than
0.
If set out of this range, a value of 50 is used for actual sampling internally without
affecting the CSR field.
For 100 Mb/s operation this field should be set to a value less than 9 and greater than 0.
If set out of this range, a value of 5 is used for actual sampling internally without
affecting the CSR field. */
uint64_t an_ovrd : 1; /**< [ 7: 7](R/W) Autonegotiation results override:
0 = Disable.
1 = Enable override. Autonegotiation is allowed to happen but the results are ignored
when this bit is set. Duplex and Link speed values are set from BGX()_GMP_PCS_MISC()_CTL. */
uint64_t mode : 1; /**< [ 8: 8](R/W) Mode bit.
_ 0 = SGMII mode is selected and the following note applies.
The SGMII AN advertisement register (BGX()_GMP_PCS_SGM()_AN_ADV) is sent during
autonegotiation if BGX()_GMP_PCS_MISC()_CTL[MAC_PHY] = 1 (PHY mode). If [MAC_PHY]
= 0 (MAC mode), the tx_Config_Reg\<14\> becomes ACK bit and \<0\> is always 1. All other bits
in tx_Config_Reg sent are 0. The PHY dictates the autonegotiation results.
_ 1 = 1000Base-X mode is selected. Autonegotiation follows IEEE 802.3 clause 37. */
uint64_t mac_phy : 1; /**< [ 9: 9](R/W) MAC/PHY.
0 = MAC.
1 = PHY decides the tx_Config_Reg value to be sent during autonegotiation. */
uint64_t loopbck2 : 1; /**< [ 10: 10](R/W) Sets external loopback mode to return RX data back out via the TX data path. 0 = No
loopback. 1 = Loopback.
LOOPBCK1 and LOOPBCK2 modes may not be supported simultaneously. */
uint64_t gmxeno : 1; /**< [ 11: 11](R/W) GMI enable override. When set, forces GMI to appear disabled. The enable/disable status of
GMI is checked only at SOP of every packet. */
uint64_t sgmii : 1; /**< [ 12: 12](RO/H) Reserved. Always 1. */
uint64_t disp_en : 1; /**< [ 13: 13](R/W) Disparity check enable. When LMAC_TYPE=QSGMII the running disparity check should be
disabled
to
prevent propogation across ports.
0 = disable disparity check
1 = enable disparity checking
See GSER()_LANE_MODE[LMODE]. */
uint64_t reserved_14_15 : 2;
uint64_t qsgmii_comma_wd : 16; /**< [ 31: 16](R/W) QSGMII comma watchdog byte counter. This counter is used in QSGMII mode and
counts incoming bytes to ensure state transitions in the PCS receive side state
machine when disparity enable is turned off and bad code groups and commas are
not communicated from the code group processor after code group lock. */
uint64_t qsgmii_comma_wd_en : 1; /**< [ 32: 32](R/W) QSGMII comma watchdog byte counter enable. */
uint64_t reserved_33_63 : 31;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_pcs_miscx_ctl_s cn81xx; */
struct bdk_bgxx_gmp_pcs_miscx_ctl_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_13_63 : 51;
uint64_t sgmii : 1; /**< [ 12: 12](RO/H) Reserved. Always 1. */
uint64_t gmxeno : 1; /**< [ 11: 11](R/W) GMI enable override. When set, forces GMI to appear disabled. The enable/disable status of
GMI is checked only at SOP of every packet. */
uint64_t loopbck2 : 1; /**< [ 10: 10](R/W) Sets external loopback mode to return RX data back out via the TX data path. 0 = No
loopback. 1 = Loopback.
LOOPBCK1 and LOOPBCK2 modes may not be supported simultaneously. */
uint64_t mac_phy : 1; /**< [ 9: 9](R/W) MAC/PHY.
0 = MAC.
1 = PHY decides the tx_Config_Reg value to be sent during autonegotiation. */
uint64_t mode : 1; /**< [ 8: 8](R/W) Mode bit.
_ 0 = SGMII mode is selected and the following note applies.
The SGMII AN advertisement register (BGX()_GMP_PCS_SGM()_AN_ADV) is sent during
autonegotiation if BGX()_GMP_PCS_MISC()_CTL[MAC_PHY] = 1 (PHY mode). If [MAC_PHY]
= 0 (MAC mode), the tx_Config_Reg\<14\> becomes ACK bit and \<0\> is always 1. All other bits
in tx_Config_Reg sent are 0. The PHY dictates the autonegotiation results.
_ 1 = 1000Base-X mode is selected. Autonegotiation follows IEEE 802.3 clause 37. */
uint64_t an_ovrd : 1; /**< [ 7: 7](R/W) Autonegotiation results override:
0 = Disable.
1 = Enable override. Autonegotiation is allowed to happen but the results are ignored
when this bit is set. Duplex and Link speed values are set from BGX()_GMP_PCS_MISC()_CTL. */
uint64_t samp_pt : 7; /**< [ 6: 0](R/W) Byte number in elongated frames for 10/100 Mb/s operation for data sampling on RX side in
PCS. Recommended values are 0x5 for 100 Mb/s operation and 0x32 for 10 Mb/s operation.
For 10 Mb/s operation, this field should be set to a value less than 99 and greater than
0.
If set out of this range, a value of 50 is used for actual sampling internally without
affecting the CSR field.
For 100 Mb/s operation this field should be set to a value less than 9 and greater than 0.
If set out of this range, a value of 5 is used for actual sampling internally without
affecting the CSR field. */
#else /* Word 0 - Little Endian */
uint64_t samp_pt : 7; /**< [ 6: 0](R/W) Byte number in elongated frames for 10/100 Mb/s operation for data sampling on RX side in
PCS. Recommended values are 0x5 for 100 Mb/s operation and 0x32 for 10 Mb/s operation.
For 10 Mb/s operation, this field should be set to a value less than 99 and greater than
0.
If set out of this range, a value of 50 is used for actual sampling internally without
affecting the CSR field.
For 100 Mb/s operation this field should be set to a value less than 9 and greater than 0.
If set out of this range, a value of 5 is used for actual sampling internally without
affecting the CSR field. */
uint64_t an_ovrd : 1; /**< [ 7: 7](R/W) Autonegotiation results override:
0 = Disable.
1 = Enable override. Autonegotiation is allowed to happen but the results are ignored
when this bit is set. Duplex and Link speed values are set from BGX()_GMP_PCS_MISC()_CTL. */
uint64_t mode : 1; /**< [ 8: 8](R/W) Mode bit.
_ 0 = SGMII mode is selected and the following note applies.
The SGMII AN advertisement register (BGX()_GMP_PCS_SGM()_AN_ADV) is sent during
autonegotiation if BGX()_GMP_PCS_MISC()_CTL[MAC_PHY] = 1 (PHY mode). If [MAC_PHY]
= 0 (MAC mode), the tx_Config_Reg\<14\> becomes ACK bit and \<0\> is always 1. All other bits
in tx_Config_Reg sent are 0. The PHY dictates the autonegotiation results.
_ 1 = 1000Base-X mode is selected. Autonegotiation follows IEEE 802.3 clause 37. */
uint64_t mac_phy : 1; /**< [ 9: 9](R/W) MAC/PHY.
0 = MAC.
1 = PHY decides the tx_Config_Reg value to be sent during autonegotiation. */
uint64_t loopbck2 : 1; /**< [ 10: 10](R/W) Sets external loopback mode to return RX data back out via the TX data path. 0 = No
loopback. 1 = Loopback.
LOOPBCK1 and LOOPBCK2 modes may not be supported simultaneously. */
uint64_t gmxeno : 1; /**< [ 11: 11](R/W) GMI enable override. When set, forces GMI to appear disabled. The enable/disable status of
GMI is checked only at SOP of every packet. */
uint64_t sgmii : 1; /**< [ 12: 12](RO/H) Reserved. Always 1. */
uint64_t reserved_13_63 : 51;
#endif /* Word 0 - End */
} cn88xx;
/* struct bdk_bgxx_gmp_pcs_miscx_ctl_s cn83xx; */
};
typedef union bdk_bgxx_gmp_pcs_miscx_ctl bdk_bgxx_gmp_pcs_miscx_ctl_t;
static inline uint64_t BDK_BGXX_GMP_PCS_MISCX_CTL(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_PCS_MISCX_CTL(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030078ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0030078ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030078ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_PCS_MISCX_CTL", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_PCS_MISCX_CTL(a,b) bdk_bgxx_gmp_pcs_miscx_ctl_t
#define bustype_BDK_BGXX_GMP_PCS_MISCX_CTL(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_PCS_MISCX_CTL(a,b) "BGXX_GMP_PCS_MISCX_CTL"
#define device_bar_BDK_BGXX_GMP_PCS_MISCX_CTL(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_PCS_MISCX_CTL(a,b) (a)
#define arguments_BDK_BGXX_GMP_PCS_MISCX_CTL(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_pcs_mr#_control
*
* BGX GMP PCS Control Registers
*/
union bdk_bgxx_gmp_pcs_mrx_control
{
uint64_t u;
struct bdk_bgxx_gmp_pcs_mrx_control_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t reset : 1; /**< [ 15: 15](R/W/H) Set to reset.
0 = Normal operation.
1 = Software PCS reset.
The bit returns to 0 after PCS has been reset. Takes 32 coprocessor-clock cycles to reset
PCS. This bit, when set, also drains the tx gmi fifo and can be used as a fifo draining
mechanism for both SerDes reset conditions and for XCV reset conditions. */
uint64_t loopbck1 : 1; /**< [ 14: 14](R/W) Enable loopback:
0 = Normal operation.
1 = Internal loopback mode.
The loopback mode returns loopback TX data from GMII TX back to GMII RX interface. The
loopback happens in the PCS module. Autonegotiation is disabled even if [AN_EN] is set
during loopback. */
uint64_t spdlsb : 1; /**< [ 13: 13](R/W) Least-significant bit of the link-speed field, i.e. SPD\<0\>. Refer to SPDMSB. */
uint64_t an_en : 1; /**< [ 12: 12](R/W) Autonegotiation enable. */
uint64_t pwr_dn : 1; /**< [ 11: 11](R/W) Power down:
0 = Normal operation.
1 = Power down (hardware reset). */
uint64_t reserved_10 : 1;
uint64_t rst_an : 1; /**< [ 9: 9](R/W/H) Reset autonegotiation. When set, if [AN_EN] = 1 and
BGX()_GMP_PCS_MR()_STATUS[AN_ABIL] = 1, autonegotiation begins. Otherwise,
software write requests are ignored and this bit remains at 0. This bit clears itself to
0, when autonegotiation starts. */
uint64_t dup : 1; /**< [ 8: 8](R/W) Duplex mode:
0 = half duplex; effective only if autonegotiation is disabled.
1 = full duplex.
If BGX()_GMP_PCS_MR()_STATUS \<15:9\> and
BGX()_GMP_PCS_AN()_ADV\<15:12\> allow only one duplex mode, this bit corresponds to
that value and any attempts to write are ignored. */
uint64_t coltst : 1; /**< [ 7: 7](R/W) Enable COL signal test.
During COL test, the COL signal reflects the GMII TX_EN signal with less than 16BT delay. */
uint64_t spdmsb : 1; /**< [ 6: 6](R/W) Link speed most-significant bit, i.e SPD\<1\>; effective only if autonegotiation is
disabled.
\<pre\>
[SPDMSB] [SPDLSB] Link Speed
0 0 10 Mb/s
0 1 100 Mb/s
1 0 1000 Mb/s
1 1 reserved
\</pre\> */
uint64_t uni : 1; /**< [ 5: 5](R/W) Unidirectional (IEEE 802.3-2005, Clause 66.2). When set to 1, this bit overrides [AN_EN]
and
disables the autonegotiation variable mr_an_enable. Used in both 1000BASE-X and
SGMII/QSGMII
modes. */
uint64_t reserved_0_4 : 5;
#else /* Word 0 - Little Endian */
uint64_t reserved_0_4 : 5;
uint64_t uni : 1; /**< [ 5: 5](R/W) Unidirectional (IEEE 802.3-2005, Clause 66.2). When set to 1, this bit overrides [AN_EN]
and
disables the autonegotiation variable mr_an_enable. Used in both 1000BASE-X and
SGMII/QSGMII
modes. */
uint64_t spdmsb : 1; /**< [ 6: 6](R/W) Link speed most-significant bit, i.e SPD\<1\>; effective only if autonegotiation is
disabled.
\<pre\>
[SPDMSB] [SPDLSB] Link Speed
0 0 10 Mb/s
0 1 100 Mb/s
1 0 1000 Mb/s
1 1 reserved
\</pre\> */
uint64_t coltst : 1; /**< [ 7: 7](R/W) Enable COL signal test.
During COL test, the COL signal reflects the GMII TX_EN signal with less than 16BT delay. */
uint64_t dup : 1; /**< [ 8: 8](R/W) Duplex mode:
0 = half duplex; effective only if autonegotiation is disabled.
1 = full duplex.
If BGX()_GMP_PCS_MR()_STATUS \<15:9\> and
BGX()_GMP_PCS_AN()_ADV\<15:12\> allow only one duplex mode, this bit corresponds to
that value and any attempts to write are ignored. */
uint64_t rst_an : 1; /**< [ 9: 9](R/W/H) Reset autonegotiation. When set, if [AN_EN] = 1 and
BGX()_GMP_PCS_MR()_STATUS[AN_ABIL] = 1, autonegotiation begins. Otherwise,
software write requests are ignored and this bit remains at 0. This bit clears itself to
0, when autonegotiation starts. */
uint64_t reserved_10 : 1;
uint64_t pwr_dn : 1; /**< [ 11: 11](R/W) Power down:
0 = Normal operation.
1 = Power down (hardware reset). */
uint64_t an_en : 1; /**< [ 12: 12](R/W) Autonegotiation enable. */
uint64_t spdlsb : 1; /**< [ 13: 13](R/W) Least-significant bit of the link-speed field, i.e. SPD\<0\>. Refer to SPDMSB. */
uint64_t loopbck1 : 1; /**< [ 14: 14](R/W) Enable loopback:
0 = Normal operation.
1 = Internal loopback mode.
The loopback mode returns loopback TX data from GMII TX back to GMII RX interface. The
loopback happens in the PCS module. Autonegotiation is disabled even if [AN_EN] is set
during loopback. */
uint64_t reset : 1; /**< [ 15: 15](R/W/H) Set to reset.
0 = Normal operation.
1 = Software PCS reset.
The bit returns to 0 after PCS has been reset. Takes 32 coprocessor-clock cycles to reset
PCS. This bit, when set, also drains the tx gmi fifo and can be used as a fifo draining
mechanism for both SerDes reset conditions and for XCV reset conditions. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_pcs_mrx_control_s cn81xx; */
struct bdk_bgxx_gmp_pcs_mrx_control_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t reset : 1; /**< [ 15: 15](R/W/H) Set to reset.
0 = Normal operation.
1 = Software PCS reset.
The bit returns to 0 after PCS has been reset. Takes 32 coprocessor-clock cycles to reset
PCS. This bit, when set, also drains the tx gmi fifo and can be used as a fifo draining
mechanism for both SerDes reset conditions and for XCV reset conditions. */
uint64_t loopbck1 : 1; /**< [ 14: 14](R/W) Enable loopback:
0 = Normal operation.
1 = Internal loopback mode.
The loopback mode returns loopback TX data from GMII TX back to GMII RX interface. The
loopback happens in the PCS module. Autonegotiation is disabled even if [AN_EN] is set
during loopback. */
uint64_t spdlsb : 1; /**< [ 13: 13](R/W) Least-significant bit of the link-speed field, i.e. SPD\<0\>. Refer to SPDMSB. */
uint64_t an_en : 1; /**< [ 12: 12](R/W) Autonegotiation enable. */
uint64_t pwr_dn : 1; /**< [ 11: 11](R/W) Power down:
0 = Normal operation.
1 = Power down (hardware reset). */
uint64_t reserved_10 : 1;
uint64_t rst_an : 1; /**< [ 9: 9](R/W/H) Reset autonegotiation. When set, if [AN_EN] = 1 and
BGX()_GMP_PCS_MR()_STATUS[AN_ABIL] = 1, autonegotiation begins. Otherwise,
software write requests are ignored and this bit remains at 0. This bit clears itself to
0, when autonegotiation starts. */
uint64_t dup : 1; /**< [ 8: 8](R/W) Duplex mode:
0 = half duplex; effective only if autonegotiation is disabled.
1 = full duplex.
If BGX()_GMP_PCS_MR()_STATUS \<15:9\> and
BGX()_GMP_PCS_AN()_ADV\<15:12\> allow only one duplex mode, this bit corresponds to
that value and any attempts to write are ignored. */
uint64_t coltst : 1; /**< [ 7: 7](R/W) Enable COL signal test.
During COL test, the COL signal reflects the GMII TX_EN signal with less than 16BT delay. */
uint64_t spdmsb : 1; /**< [ 6: 6](R/W) Link speed most-significant bit, i.e SPD\<1\>; effective only if autonegotiation is
disabled.
\<pre\>
[SPDMSB] [SPDLSB] Link Speed
0 0 10 Mb/s
0 1 100 Mb/s
1 0 1000 Mb/s
1 1 reserved
\</pre\> */
uint64_t uni : 1; /**< [ 5: 5](R/W) Unidirectional (IEEE 802.3-2005, Clause 66.2). When set to 1, this bit overrides [AN_EN]
and
disables the autonegotiation variable mr_an_enable. Used in both 1000BASE-X and SGMII
modes. */
uint64_t reserved_0_4 : 5;
#else /* Word 0 - Little Endian */
uint64_t reserved_0_4 : 5;
uint64_t uni : 1; /**< [ 5: 5](R/W) Unidirectional (IEEE 802.3-2005, Clause 66.2). When set to 1, this bit overrides [AN_EN]
and
disables the autonegotiation variable mr_an_enable. Used in both 1000BASE-X and SGMII
modes. */
uint64_t spdmsb : 1; /**< [ 6: 6](R/W) Link speed most-significant bit, i.e SPD\<1\>; effective only if autonegotiation is
disabled.
\<pre\>
[SPDMSB] [SPDLSB] Link Speed
0 0 10 Mb/s
0 1 100 Mb/s
1 0 1000 Mb/s
1 1 reserved
\</pre\> */
uint64_t coltst : 1; /**< [ 7: 7](R/W) Enable COL signal test.
During COL test, the COL signal reflects the GMII TX_EN signal with less than 16BT delay. */
uint64_t dup : 1; /**< [ 8: 8](R/W) Duplex mode:
0 = half duplex; effective only if autonegotiation is disabled.
1 = full duplex.
If BGX()_GMP_PCS_MR()_STATUS \<15:9\> and
BGX()_GMP_PCS_AN()_ADV\<15:12\> allow only one duplex mode, this bit corresponds to
that value and any attempts to write are ignored. */
uint64_t rst_an : 1; /**< [ 9: 9](R/W/H) Reset autonegotiation. When set, if [AN_EN] = 1 and
BGX()_GMP_PCS_MR()_STATUS[AN_ABIL] = 1, autonegotiation begins. Otherwise,
software write requests are ignored and this bit remains at 0. This bit clears itself to
0, when autonegotiation starts. */
uint64_t reserved_10 : 1;
uint64_t pwr_dn : 1; /**< [ 11: 11](R/W) Power down:
0 = Normal operation.
1 = Power down (hardware reset). */
uint64_t an_en : 1; /**< [ 12: 12](R/W) Autonegotiation enable. */
uint64_t spdlsb : 1; /**< [ 13: 13](R/W) Least-significant bit of the link-speed field, i.e. SPD\<0\>. Refer to SPDMSB. */
uint64_t loopbck1 : 1; /**< [ 14: 14](R/W) Enable loopback:
0 = Normal operation.
1 = Internal loopback mode.
The loopback mode returns loopback TX data from GMII TX back to GMII RX interface. The
loopback happens in the PCS module. Autonegotiation is disabled even if [AN_EN] is set
during loopback. */
uint64_t reset : 1; /**< [ 15: 15](R/W/H) Set to reset.
0 = Normal operation.
1 = Software PCS reset.
The bit returns to 0 after PCS has been reset. Takes 32 coprocessor-clock cycles to reset
PCS. This bit, when set, also drains the tx gmi fifo and can be used as a fifo draining
mechanism for both SerDes reset conditions and for XCV reset conditions. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} cn88xx;
/* struct bdk_bgxx_gmp_pcs_mrx_control_s cn83xx; */
};
typedef union bdk_bgxx_gmp_pcs_mrx_control bdk_bgxx_gmp_pcs_mrx_control_t;
static inline uint64_t BDK_BGXX_GMP_PCS_MRX_CONTROL(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_PCS_MRX_CONTROL(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030000ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0030000ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030000ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_PCS_MRX_CONTROL", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_PCS_MRX_CONTROL(a,b) bdk_bgxx_gmp_pcs_mrx_control_t
#define bustype_BDK_BGXX_GMP_PCS_MRX_CONTROL(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_PCS_MRX_CONTROL(a,b) "BGXX_GMP_PCS_MRX_CONTROL"
#define device_bar_BDK_BGXX_GMP_PCS_MRX_CONTROL(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_PCS_MRX_CONTROL(a,b) (a)
#define arguments_BDK_BGXX_GMP_PCS_MRX_CONTROL(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_pcs_mr#_status
*
* BGX GMP PCS Status Registers
* Bits \<15:9\> in this register indicate the ability to operate when
* BGX()_GMP_PCS_MISC()_CTL[MAC_PHY] is set to MAC mode. Bits \<15:9\> are always read as
* 0, indicating that the chip cannot operate in the corresponding modes. The field [RM_FLT] is a
* 'don't care' when the selected mode is SGMII.
*/
union bdk_bgxx_gmp_pcs_mrx_status
{
uint64_t u;
struct bdk_bgxx_gmp_pcs_mrx_status_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t hun_t4 : 1; /**< [ 15: 15](RO/H) Indicates 100BASE-T4 capable. */
uint64_t hun_xfd : 1; /**< [ 14: 14](RO/H) Indicates 100BASE-X full duplex. */
uint64_t hun_xhd : 1; /**< [ 13: 13](RO/H) Indicates 100BASE-X half duplex. */
uint64_t ten_fd : 1; /**< [ 12: 12](RO/H) Indicates 10Mb/s full duplex. */
uint64_t ten_hd : 1; /**< [ 11: 11](RO/H) Indicates 10Mb/s half duplex. */
uint64_t hun_t2fd : 1; /**< [ 10: 10](RO/H) Indicates 100BASE-T2 full duplex. */
uint64_t hun_t2hd : 1; /**< [ 9: 9](RO/H) Indicates 100BASE-T2 half duplex. */
uint64_t ext_st : 1; /**< [ 8: 8](RO/H) Extended status information. When set to 1, indicates that additional status data is
available in BGX()_GMP_PCS_AN()_EXT_ST. */
uint64_t reserved_7 : 1;
uint64_t prb_sup : 1; /**< [ 6: 6](RO/H) Preamble not needed.
0 = Cannot accept frames without preamble bytes.
1 = Can work without preamble bytes at the beginning of frames. */
uint64_t an_cpt : 1; /**< [ 5: 5](RO/H) Indicates autonegotiation is complete; the contents of the
BGX()_GMP_PCS_AN()_RESULTS are valid. */
uint64_t rm_flt : 1; /**< [ 4: 4](RO/H) Indicates remote fault condition occurred. This bit implements a latching-high behavior.
It is cleared when software reads this register or when
BGX()_GMP_PCS_MR()_CONTROL[RESET] is asserted.
See BGX()_GMP_PCS_AN()_ADV[REM_FLT] for fault conditions. */
uint64_t an_abil : 1; /**< [ 3: 3](RO/H) Indicates autonegotiation capable. */
uint64_t lnk_st : 1; /**< [ 2: 2](RO/H) Link state:
0 = link down.
1 = link up.
Set during autonegotiation process. Set whenever XMIT = DATA. Latching-low behavior when
link goes down. Link down value of the bit stays low until software reads the register. */
uint64_t reserved_1 : 1;
uint64_t extnd : 1; /**< [ 0: 0](RO/H) This field is always 0, extended capability registers not present. */
#else /* Word 0 - Little Endian */
uint64_t extnd : 1; /**< [ 0: 0](RO/H) This field is always 0, extended capability registers not present. */
uint64_t reserved_1 : 1;
uint64_t lnk_st : 1; /**< [ 2: 2](RO/H) Link state:
0 = link down.
1 = link up.
Set during autonegotiation process. Set whenever XMIT = DATA. Latching-low behavior when
link goes down. Link down value of the bit stays low until software reads the register. */
uint64_t an_abil : 1; /**< [ 3: 3](RO/H) Indicates autonegotiation capable. */
uint64_t rm_flt : 1; /**< [ 4: 4](RO/H) Indicates remote fault condition occurred. This bit implements a latching-high behavior.
It is cleared when software reads this register or when
BGX()_GMP_PCS_MR()_CONTROL[RESET] is asserted.
See BGX()_GMP_PCS_AN()_ADV[REM_FLT] for fault conditions. */
uint64_t an_cpt : 1; /**< [ 5: 5](RO/H) Indicates autonegotiation is complete; the contents of the
BGX()_GMP_PCS_AN()_RESULTS are valid. */
uint64_t prb_sup : 1; /**< [ 6: 6](RO/H) Preamble not needed.
0 = Cannot accept frames without preamble bytes.
1 = Can work without preamble bytes at the beginning of frames. */
uint64_t reserved_7 : 1;
uint64_t ext_st : 1; /**< [ 8: 8](RO/H) Extended status information. When set to 1, indicates that additional status data is
available in BGX()_GMP_PCS_AN()_EXT_ST. */
uint64_t hun_t2hd : 1; /**< [ 9: 9](RO/H) Indicates 100BASE-T2 half duplex. */
uint64_t hun_t2fd : 1; /**< [ 10: 10](RO/H) Indicates 100BASE-T2 full duplex. */
uint64_t ten_hd : 1; /**< [ 11: 11](RO/H) Indicates 10Mb/s half duplex. */
uint64_t ten_fd : 1; /**< [ 12: 12](RO/H) Indicates 10Mb/s full duplex. */
uint64_t hun_xhd : 1; /**< [ 13: 13](RO/H) Indicates 100BASE-X half duplex. */
uint64_t hun_xfd : 1; /**< [ 14: 14](RO/H) Indicates 100BASE-X full duplex. */
uint64_t hun_t4 : 1; /**< [ 15: 15](RO/H) Indicates 100BASE-T4 capable. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_pcs_mrx_status_s cn; */
};
typedef union bdk_bgxx_gmp_pcs_mrx_status bdk_bgxx_gmp_pcs_mrx_status_t;
static inline uint64_t BDK_BGXX_GMP_PCS_MRX_STATUS(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_PCS_MRX_STATUS(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030008ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0030008ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030008ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_PCS_MRX_STATUS", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_PCS_MRX_STATUS(a,b) bdk_bgxx_gmp_pcs_mrx_status_t
#define bustype_BDK_BGXX_GMP_PCS_MRX_STATUS(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_PCS_MRX_STATUS(a,b) "BGXX_GMP_PCS_MRX_STATUS"
#define device_bar_BDK_BGXX_GMP_PCS_MRX_STATUS(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_PCS_MRX_STATUS(a,b) (a)
#define arguments_BDK_BGXX_GMP_PCS_MRX_STATUS(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_pcs_rx#_states
*
* BGX GMP PCS RX State-Machines States Registers
*/
union bdk_bgxx_gmp_pcs_rxx_states
{
uint64_t u;
struct bdk_bgxx_gmp_pcs_rxx_states_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t rx_bad : 1; /**< [ 15: 15](RO/H) Receive state machine is in an illegal state. */
uint64_t rx_st : 5; /**< [ 14: 10](RO/H) Receive state-machine state. */
uint64_t sync_bad : 1; /**< [ 9: 9](RO/H) Receive synchronization state machine is in an illegal state. */
uint64_t sync : 4; /**< [ 8: 5](RO/H) Receive synchronization state-machine state. */
uint64_t an_bad : 1; /**< [ 4: 4](RO/H) Autonegotiation state machine is in an illegal state. */
uint64_t an_st : 4; /**< [ 3: 0](RO/H) Autonegotiation state-machine state. */
#else /* Word 0 - Little Endian */
uint64_t an_st : 4; /**< [ 3: 0](RO/H) Autonegotiation state-machine state. */
uint64_t an_bad : 1; /**< [ 4: 4](RO/H) Autonegotiation state machine is in an illegal state. */
uint64_t sync : 4; /**< [ 8: 5](RO/H) Receive synchronization state-machine state. */
uint64_t sync_bad : 1; /**< [ 9: 9](RO/H) Receive synchronization state machine is in an illegal state. */
uint64_t rx_st : 5; /**< [ 14: 10](RO/H) Receive state-machine state. */
uint64_t rx_bad : 1; /**< [ 15: 15](RO/H) Receive state machine is in an illegal state. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_pcs_rxx_states_s cn; */
};
typedef union bdk_bgxx_gmp_pcs_rxx_states bdk_bgxx_gmp_pcs_rxx_states_t;
static inline uint64_t BDK_BGXX_GMP_PCS_RXX_STATES(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_PCS_RXX_STATES(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030058ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0030058ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030058ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_PCS_RXX_STATES", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_PCS_RXX_STATES(a,b) bdk_bgxx_gmp_pcs_rxx_states_t
#define bustype_BDK_BGXX_GMP_PCS_RXX_STATES(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_PCS_RXX_STATES(a,b) "BGXX_GMP_PCS_RXX_STATES"
#define device_bar_BDK_BGXX_GMP_PCS_RXX_STATES(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_PCS_RXX_STATES(a,b) (a)
#define arguments_BDK_BGXX_GMP_PCS_RXX_STATES(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_pcs_rx#_sync
*
* BGX GMP PCS Code Group Synchronization Registers
*/
union bdk_bgxx_gmp_pcs_rxx_sync
{
uint64_t u;
struct bdk_bgxx_gmp_pcs_rxx_sync_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_2_63 : 62;
uint64_t sync : 1; /**< [ 1: 1](RO/H) When set, code group synchronization achieved. */
uint64_t bit_lock : 1; /**< [ 0: 0](RO/H) When set, bit lock achieved. */
#else /* Word 0 - Little Endian */
uint64_t bit_lock : 1; /**< [ 0: 0](RO/H) When set, bit lock achieved. */
uint64_t sync : 1; /**< [ 1: 1](RO/H) When set, code group synchronization achieved. */
uint64_t reserved_2_63 : 62;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_pcs_rxx_sync_s cn; */
};
typedef union bdk_bgxx_gmp_pcs_rxx_sync bdk_bgxx_gmp_pcs_rxx_sync_t;
static inline uint64_t BDK_BGXX_GMP_PCS_RXX_SYNC(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_PCS_RXX_SYNC(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030050ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0030050ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030050ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_PCS_RXX_SYNC", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_PCS_RXX_SYNC(a,b) bdk_bgxx_gmp_pcs_rxx_sync_t
#define bustype_BDK_BGXX_GMP_PCS_RXX_SYNC(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_PCS_RXX_SYNC(a,b) "BGXX_GMP_PCS_RXX_SYNC"
#define device_bar_BDK_BGXX_GMP_PCS_RXX_SYNC(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_PCS_RXX_SYNC(a,b) (a)
#define arguments_BDK_BGXX_GMP_PCS_RXX_SYNC(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_pcs_sgm#_an_adv
*
* BGX GMP PCS SGMII Autonegotiation Advertisement Registers
* This is the SGMII autonegotiation advertisement register (sent out as tx_Config_Reg\<15:0\> as
* defined in IEEE 802.3 clause 37). This register is sent during autonegotiation if
* BGX()_GMP_PCS_MISC()_CTL[MAC_PHY] is set (1 = PHY mode). If the bit is not set (0 =
* MAC mode), then tx_Config_Reg\<14\> becomes ACK bit and tx_Config_Reg\<0\> is always 1. All other
* bits in tx_Config_Reg sent will be 0. The PHY dictates the autonegotiation results.
*/
union bdk_bgxx_gmp_pcs_sgmx_an_adv
{
uint64_t u;
struct bdk_bgxx_gmp_pcs_sgmx_an_adv_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t link : 1; /**< [ 15: 15](R/W) Link status: 1 = Link up. 0 = Link down. */
uint64_t ack : 1; /**< [ 14: 14](RO/H) Autonegotiation acknowledgement. */
uint64_t reserved_13 : 1;
uint64_t dup : 1; /**< [ 12: 12](R/W) Duplex mode: 1 = full duplex, 0 = half duplex. */
uint64_t speed : 2; /**< [ 11: 10](R/W) Link speed:
0x0 = 10 Mb/s.
0x1 = 100 Mb/s.
0x2 = 1000 Mb/s.
0x3 = Reserved. */
uint64_t reserved_1_9 : 9;
uint64_t one : 1; /**< [ 0: 0](RO/H) Always set to match tx_Config_Reg\<0\>. */
#else /* Word 0 - Little Endian */
uint64_t one : 1; /**< [ 0: 0](RO/H) Always set to match tx_Config_Reg\<0\>. */
uint64_t reserved_1_9 : 9;
uint64_t speed : 2; /**< [ 11: 10](R/W) Link speed:
0x0 = 10 Mb/s.
0x1 = 100 Mb/s.
0x2 = 1000 Mb/s.
0x3 = Reserved. */
uint64_t dup : 1; /**< [ 12: 12](R/W) Duplex mode: 1 = full duplex, 0 = half duplex. */
uint64_t reserved_13 : 1;
uint64_t ack : 1; /**< [ 14: 14](RO/H) Autonegotiation acknowledgement. */
uint64_t link : 1; /**< [ 15: 15](R/W) Link status: 1 = Link up. 0 = Link down. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_pcs_sgmx_an_adv_s cn; */
};
typedef union bdk_bgxx_gmp_pcs_sgmx_an_adv bdk_bgxx_gmp_pcs_sgmx_an_adv_t;
static inline uint64_t BDK_BGXX_GMP_PCS_SGMX_AN_ADV(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_PCS_SGMX_AN_ADV(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030068ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0030068ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030068ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_PCS_SGMX_AN_ADV", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_PCS_SGMX_AN_ADV(a,b) bdk_bgxx_gmp_pcs_sgmx_an_adv_t
#define bustype_BDK_BGXX_GMP_PCS_SGMX_AN_ADV(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_PCS_SGMX_AN_ADV(a,b) "BGXX_GMP_PCS_SGMX_AN_ADV"
#define device_bar_BDK_BGXX_GMP_PCS_SGMX_AN_ADV(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_PCS_SGMX_AN_ADV(a,b) (a)
#define arguments_BDK_BGXX_GMP_PCS_SGMX_AN_ADV(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_pcs_sgm#_lp_adv
*
* BGX GMP PCS SGMII Link-Partner-Advertisement Registers
* This is the SGMII link partner advertisement register (received as rx_Config_Reg\<15:0\> as
* defined in IEEE 802.3 clause 37).
*/
union bdk_bgxx_gmp_pcs_sgmx_lp_adv
{
uint64_t u;
struct bdk_bgxx_gmp_pcs_sgmx_lp_adv_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t link : 1; /**< [ 15: 15](RO/H) Link status: 1 = Link up. 0 = Link down. */
uint64_t reserved_13_14 : 2;
uint64_t dup : 1; /**< [ 12: 12](RO/H) Duplex mode: 1 = Full duplex, 0 = Half duplex. */
uint64_t speed : 2; /**< [ 11: 10](RO/H) Link speed:
0x0 = 10 Mb/s.
0x1 = 100 Mb/s.
0x2 = 1000 Mb/s.
0x3 = Reserved. */
uint64_t reserved_1_9 : 9;
uint64_t one : 1; /**< [ 0: 0](RO/H) Always set to match tx_Config_Reg\<0\> */
#else /* Word 0 - Little Endian */
uint64_t one : 1; /**< [ 0: 0](RO/H) Always set to match tx_Config_Reg\<0\> */
uint64_t reserved_1_9 : 9;
uint64_t speed : 2; /**< [ 11: 10](RO/H) Link speed:
0x0 = 10 Mb/s.
0x1 = 100 Mb/s.
0x2 = 1000 Mb/s.
0x3 = Reserved. */
uint64_t dup : 1; /**< [ 12: 12](RO/H) Duplex mode: 1 = Full duplex, 0 = Half duplex. */
uint64_t reserved_13_14 : 2;
uint64_t link : 1; /**< [ 15: 15](RO/H) Link status: 1 = Link up. 0 = Link down. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
struct bdk_bgxx_gmp_pcs_sgmx_lp_adv_cn
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t link : 1; /**< [ 15: 15](RO/H) Link status: 1 = Link up. 0 = Link down. */
uint64_t reserved_14 : 1;
uint64_t reserved_13 : 1;
uint64_t dup : 1; /**< [ 12: 12](RO/H) Duplex mode: 1 = Full duplex, 0 = Half duplex. */
uint64_t speed : 2; /**< [ 11: 10](RO/H) Link speed:
0x0 = 10 Mb/s.
0x1 = 100 Mb/s.
0x2 = 1000 Mb/s.
0x3 = Reserved. */
uint64_t reserved_1_9 : 9;
uint64_t one : 1; /**< [ 0: 0](RO/H) Always set to match tx_Config_Reg\<0\> */
#else /* Word 0 - Little Endian */
uint64_t one : 1; /**< [ 0: 0](RO/H) Always set to match tx_Config_Reg\<0\> */
uint64_t reserved_1_9 : 9;
uint64_t speed : 2; /**< [ 11: 10](RO/H) Link speed:
0x0 = 10 Mb/s.
0x1 = 100 Mb/s.
0x2 = 1000 Mb/s.
0x3 = Reserved. */
uint64_t dup : 1; /**< [ 12: 12](RO/H) Duplex mode: 1 = Full duplex, 0 = Half duplex. */
uint64_t reserved_13 : 1;
uint64_t reserved_14 : 1;
uint64_t link : 1; /**< [ 15: 15](RO/H) Link status: 1 = Link up. 0 = Link down. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} cn;
};
typedef union bdk_bgxx_gmp_pcs_sgmx_lp_adv bdk_bgxx_gmp_pcs_sgmx_lp_adv_t;
static inline uint64_t BDK_BGXX_GMP_PCS_SGMX_LP_ADV(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_PCS_SGMX_LP_ADV(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030070ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0030070ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030070ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_PCS_SGMX_LP_ADV", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_PCS_SGMX_LP_ADV(a,b) bdk_bgxx_gmp_pcs_sgmx_lp_adv_t
#define bustype_BDK_BGXX_GMP_PCS_SGMX_LP_ADV(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_PCS_SGMX_LP_ADV(a,b) "BGXX_GMP_PCS_SGMX_LP_ADV"
#define device_bar_BDK_BGXX_GMP_PCS_SGMX_LP_ADV(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_PCS_SGMX_LP_ADV(a,b) (a)
#define arguments_BDK_BGXX_GMP_PCS_SGMX_LP_ADV(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_pcs_tx#_states
*
* BGX GMP PCS TX State-Machines States Registers
*/
union bdk_bgxx_gmp_pcs_txx_states
{
uint64_t u;
struct bdk_bgxx_gmp_pcs_txx_states_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_7_63 : 57;
uint64_t xmit : 2; /**< [ 6: 5](RO/H) 0x0 = Undefined.
0x1 = Config.
0x2 = Idle.
0x3 = Data. */
uint64_t tx_bad : 1; /**< [ 4: 4](RO/H) Transmit state machine in an illegal state. */
uint64_t ord_st : 4; /**< [ 3: 0](RO/H) Transmit ordered set state-machine state. */
#else /* Word 0 - Little Endian */
uint64_t ord_st : 4; /**< [ 3: 0](RO/H) Transmit ordered set state-machine state. */
uint64_t tx_bad : 1; /**< [ 4: 4](RO/H) Transmit state machine in an illegal state. */
uint64_t xmit : 2; /**< [ 6: 5](RO/H) 0x0 = Undefined.
0x1 = Config.
0x2 = Idle.
0x3 = Data. */
uint64_t reserved_7_63 : 57;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_pcs_txx_states_s cn; */
};
typedef union bdk_bgxx_gmp_pcs_txx_states bdk_bgxx_gmp_pcs_txx_states_t;
static inline uint64_t BDK_BGXX_GMP_PCS_TXX_STATES(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_PCS_TXX_STATES(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030060ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0030060ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030060ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_PCS_TXX_STATES", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_PCS_TXX_STATES(a,b) bdk_bgxx_gmp_pcs_txx_states_t
#define bustype_BDK_BGXX_GMP_PCS_TXX_STATES(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_PCS_TXX_STATES(a,b) "BGXX_GMP_PCS_TXX_STATES"
#define device_bar_BDK_BGXX_GMP_PCS_TXX_STATES(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_PCS_TXX_STATES(a,b) (a)
#define arguments_BDK_BGXX_GMP_PCS_TXX_STATES(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_gmp_pcs_tx_rx#_polarity
*
* BGX GMP PCS TX/RX Polarity Registers
* BGX()_GMP_PCS_TX_RX()_POLARITY[AUTORXPL] shows correct polarity needed on the link
* receive path after code group synchronization is achieved.
*/
union bdk_bgxx_gmp_pcs_tx_rxx_polarity
{
uint64_t u;
struct bdk_bgxx_gmp_pcs_tx_rxx_polarity_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_4_63 : 60;
uint64_t rxovrd : 1; /**< [ 3: 3](R/W) RX polarity override.
0 = AUTORXPL determines polarity.
1 = [RXPLRT] determines polarity. */
uint64_t autorxpl : 1; /**< [ 2: 2](RO/H) Auto RX polarity detected:
0 = Normal polarity.
1 = Inverted polarity.
This bit always represents the correct RX polarity setting needed for successful RX path
operation, once a successful code group sync is obtained. */
uint64_t rxplrt : 1; /**< [ 1: 1](R/W) RX polarity: 0 = Normal polarity, 1 = Inverted polarity. */
uint64_t txplrt : 1; /**< [ 0: 0](R/W) TX polarity: 0 = Normal polarity, 1 = Inverted polarity. */
#else /* Word 0 - Little Endian */
uint64_t txplrt : 1; /**< [ 0: 0](R/W) TX polarity: 0 = Normal polarity, 1 = Inverted polarity. */
uint64_t rxplrt : 1; /**< [ 1: 1](R/W) RX polarity: 0 = Normal polarity, 1 = Inverted polarity. */
uint64_t autorxpl : 1; /**< [ 2: 2](RO/H) Auto RX polarity detected:
0 = Normal polarity.
1 = Inverted polarity.
This bit always represents the correct RX polarity setting needed for successful RX path
operation, once a successful code group sync is obtained. */
uint64_t rxovrd : 1; /**< [ 3: 3](R/W) RX polarity override.
0 = AUTORXPL determines polarity.
1 = [RXPLRT] determines polarity. */
uint64_t reserved_4_63 : 60;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_gmp_pcs_tx_rxx_polarity_s cn; */
};
typedef union bdk_bgxx_gmp_pcs_tx_rxx_polarity bdk_bgxx_gmp_pcs_tx_rxx_polarity_t;
static inline uint64_t BDK_BGXX_GMP_PCS_TX_RXX_POLARITY(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_GMP_PCS_TX_RXX_POLARITY(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030048ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0030048ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0030048ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_GMP_PCS_TX_RXX_POLARITY", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_GMP_PCS_TX_RXX_POLARITY(a,b) bdk_bgxx_gmp_pcs_tx_rxx_polarity_t
#define bustype_BDK_BGXX_GMP_PCS_TX_RXX_POLARITY(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_GMP_PCS_TX_RXX_POLARITY(a,b) "BGXX_GMP_PCS_TX_RXX_POLARITY"
#define device_bar_BDK_BGXX_GMP_PCS_TX_RXX_POLARITY(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_GMP_PCS_TX_RXX_POLARITY(a,b) (a)
#define arguments_BDK_BGXX_GMP_PCS_TX_RXX_POLARITY(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_msix_pba#
*
* BGX MSI-X Pending Bit Array Registers
* This register is the MSI-X PBA table, the bit number is indexed by the BGX_INT_VEC_E
* enumeration.
*/
union bdk_bgxx_msix_pbax
{
uint64_t u;
struct bdk_bgxx_msix_pbax_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t pend : 64; /**< [ 63: 0](RO/H) Pending message for the associated BGX()_MSIX_VEC()_CTL, enumerated by BGX_INT_VEC_E.
Bits that have no associated BGX_INT_VEC_E are zero. */
#else /* Word 0 - Little Endian */
uint64_t pend : 64; /**< [ 63: 0](RO/H) Pending message for the associated BGX()_MSIX_VEC()_CTL, enumerated by BGX_INT_VEC_E.
Bits that have no associated BGX_INT_VEC_E are zero. */
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_msix_pbax_s cn; */
};
typedef union bdk_bgxx_msix_pbax bdk_bgxx_msix_pbax_t;
static inline uint64_t BDK_BGXX_MSIX_PBAX(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_MSIX_PBAX(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b==0)))
return 0x87e0e04f0000ll + 0x1000000ll * ((a) & 0x1) + 8ll * ((b) & 0x0);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b==0)))
return 0x87e0e04f0000ll + 0x1000000ll * ((a) & 0x3) + 8ll * ((b) & 0x0);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b==0)))
return 0x87e0e04f0000ll + 0x1000000ll * ((a) & 0x1) + 8ll * ((b) & 0x0);
__bdk_csr_fatal("BGXX_MSIX_PBAX", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_MSIX_PBAX(a,b) bdk_bgxx_msix_pbax_t
#define bustype_BDK_BGXX_MSIX_PBAX(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_MSIX_PBAX(a,b) "BGXX_MSIX_PBAX"
#define device_bar_BDK_BGXX_MSIX_PBAX(a,b) 0x4 /* PF_BAR4 */
#define busnum_BDK_BGXX_MSIX_PBAX(a,b) (a)
#define arguments_BDK_BGXX_MSIX_PBAX(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_msix_vec#_addr
*
* BGX MSI-X Vector Table Address Registers
* This register is the MSI-X vector table, indexed by the BGX_INT_VEC_E enumeration.
*/
union bdk_bgxx_msix_vecx_addr
{
uint64_t u;
struct bdk_bgxx_msix_vecx_addr_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_49_63 : 15;
uint64_t addr : 47; /**< [ 48: 2](R/W) IOVA to use for MSI-X delivery of this vector. */
uint64_t reserved_1 : 1;
uint64_t secvec : 1; /**< [ 0: 0](SR/W) Secure vector.
0 = This vector may be read or written by either secure or nonsecure states.
1 = This vector's BGX()_MSIX_VEC()_ADDR, BGX()_MSIX_VEC()_CTL, and corresponding
bit of BGX()_MSIX_PBA() are RAZ/WI and does not cause a fault when accessed
by the nonsecure world.
If PCCPF_BGX()_VSEC_SCTL[MSIX_SEC] (for documentation, see PCCPF_XXX_VSEC_SCTL[MSIX_SEC])
is set, all vectors are secure and function as if [SECVEC] was set. */
#else /* Word 0 - Little Endian */
uint64_t secvec : 1; /**< [ 0: 0](SR/W) Secure vector.
0 = This vector may be read or written by either secure or nonsecure states.
1 = This vector's BGX()_MSIX_VEC()_ADDR, BGX()_MSIX_VEC()_CTL, and corresponding
bit of BGX()_MSIX_PBA() are RAZ/WI and does not cause a fault when accessed
by the nonsecure world.
If PCCPF_BGX()_VSEC_SCTL[MSIX_SEC] (for documentation, see PCCPF_XXX_VSEC_SCTL[MSIX_SEC])
is set, all vectors are secure and function as if [SECVEC] was set. */
uint64_t reserved_1 : 1;
uint64_t addr : 47; /**< [ 48: 2](R/W) IOVA to use for MSI-X delivery of this vector. */
uint64_t reserved_49_63 : 15;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_msix_vecx_addr_s cn; */
};
typedef union bdk_bgxx_msix_vecx_addr bdk_bgxx_msix_vecx_addr_t;
static inline uint64_t BDK_BGXX_MSIX_VECX_ADDR(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_MSIX_VECX_ADDR(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=29)))
return 0x87e0e0400000ll + 0x1000000ll * ((a) & 0x1) + 0x10ll * ((b) & 0x1f);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=29)))
return 0x87e0e0400000ll + 0x1000000ll * ((a) & 0x3) + 0x10ll * ((b) & 0x1f);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=29)))
return 0x87e0e0400000ll + 0x1000000ll * ((a) & 0x1) + 0x10ll * ((b) & 0x1f);
__bdk_csr_fatal("BGXX_MSIX_VECX_ADDR", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_MSIX_VECX_ADDR(a,b) bdk_bgxx_msix_vecx_addr_t
#define bustype_BDK_BGXX_MSIX_VECX_ADDR(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_MSIX_VECX_ADDR(a,b) "BGXX_MSIX_VECX_ADDR"
#define device_bar_BDK_BGXX_MSIX_VECX_ADDR(a,b) 0x4 /* PF_BAR4 */
#define busnum_BDK_BGXX_MSIX_VECX_ADDR(a,b) (a)
#define arguments_BDK_BGXX_MSIX_VECX_ADDR(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_msix_vec#_ctl
*
* BGX MSI-X Vector Table Control and Data Registers
* This register is the MSI-X vector table, indexed by the BGX_INT_VEC_E enumeration.
*/
union bdk_bgxx_msix_vecx_ctl
{
uint64_t u;
struct bdk_bgxx_msix_vecx_ctl_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_33_63 : 31;
uint64_t mask : 1; /**< [ 32: 32](R/W) When set, no MSI-X interrupts will be sent to this vector. */
uint64_t reserved_20_31 : 12;
uint64_t data : 20; /**< [ 19: 0](R/W) Data to use for MSI-X delivery of this vector. */
#else /* Word 0 - Little Endian */
uint64_t data : 20; /**< [ 19: 0](R/W) Data to use for MSI-X delivery of this vector. */
uint64_t reserved_20_31 : 12;
uint64_t mask : 1; /**< [ 32: 32](R/W) When set, no MSI-X interrupts will be sent to this vector. */
uint64_t reserved_33_63 : 31;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_msix_vecx_ctl_s cn; */
};
typedef union bdk_bgxx_msix_vecx_ctl bdk_bgxx_msix_vecx_ctl_t;
static inline uint64_t BDK_BGXX_MSIX_VECX_CTL(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_MSIX_VECX_CTL(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=29)))
return 0x87e0e0400008ll + 0x1000000ll * ((a) & 0x1) + 0x10ll * ((b) & 0x1f);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=29)))
return 0x87e0e0400008ll + 0x1000000ll * ((a) & 0x3) + 0x10ll * ((b) & 0x1f);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=29)))
return 0x87e0e0400008ll + 0x1000000ll * ((a) & 0x1) + 0x10ll * ((b) & 0x1f);
__bdk_csr_fatal("BGXX_MSIX_VECX_CTL", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_MSIX_VECX_CTL(a,b) bdk_bgxx_msix_vecx_ctl_t
#define bustype_BDK_BGXX_MSIX_VECX_CTL(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_MSIX_VECX_CTL(a,b) "BGXX_MSIX_VECX_CTL"
#define device_bar_BDK_BGXX_MSIX_VECX_CTL(a,b) 0x4 /* PF_BAR4 */
#define busnum_BDK_BGXX_MSIX_VECX_CTL(a,b) (a)
#define arguments_BDK_BGXX_MSIX_VECX_CTL(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_cbfc_ctl
*
* BGX SMU PFC Control Registers
* Internal:
* INTERNAL: XOFF for a specific class/channel \<i\> is XOFF\<i\> = ([PHYS_EN]\<i\> & cmr_rx_phys_bp) |
* ([LOGL_EN]\<i\> & cmr_rx_logl_xoff\<i\>).
*/
union bdk_bgxx_smux_cbfc_ctl
{
uint64_t u;
struct bdk_bgxx_smux_cbfc_ctl_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t phys_en : 16; /**< [ 63: 48](R/W) Physical backpressure enable. Determines which classes/channels in the class enable vector
field of a transmitted PFC packet can be asserted due to RX physical backpressure. */
uint64_t logl_en : 16; /**< [ 47: 32](R/W) Logical backpressure enable. Determines which classes/channels in the class enable vector
field of a transmitted PFC packet can be asserted due to RX logical backpressure. */
uint64_t reserved_4_31 : 28;
uint64_t bck_en : 1; /**< [ 3: 3](R/W) Forward PFC information to the backpressure block. */
uint64_t drp_en : 1; /**< [ 2: 2](R/W) Drop-control enable. When set, drop PFC frames. */
uint64_t tx_en : 1; /**< [ 1: 1](R/W) Transmit enable. When set, allow for PFC packets. Must be clear in HiGig2 mode
i.e. when BGX()_SMU()_TX_CTL[HG_EN] = 1 and BGX()_SMU()_RX_UDD_SKP[LEN] =
16. */
uint64_t rx_en : 1; /**< [ 0: 0](R/W) Receive enable. When set, allow for PFC packets. Must be clear in HiGig2 mode
i.e. when BGX()_SMU()_TX_CTL[HG_EN] = 1 and BGX()_SMU()_RX_UDD_SKP[LEN] =
16. */
#else /* Word 0 - Little Endian */
uint64_t rx_en : 1; /**< [ 0: 0](R/W) Receive enable. When set, allow for PFC packets. Must be clear in HiGig2 mode
i.e. when BGX()_SMU()_TX_CTL[HG_EN] = 1 and BGX()_SMU()_RX_UDD_SKP[LEN] =
16. */
uint64_t tx_en : 1; /**< [ 1: 1](R/W) Transmit enable. When set, allow for PFC packets. Must be clear in HiGig2 mode
i.e. when BGX()_SMU()_TX_CTL[HG_EN] = 1 and BGX()_SMU()_RX_UDD_SKP[LEN] =
16. */
uint64_t drp_en : 1; /**< [ 2: 2](R/W) Drop-control enable. When set, drop PFC frames. */
uint64_t bck_en : 1; /**< [ 3: 3](R/W) Forward PFC information to the backpressure block. */
uint64_t reserved_4_31 : 28;
uint64_t logl_en : 16; /**< [ 47: 32](R/W) Logical backpressure enable. Determines which classes/channels in the class enable vector
field of a transmitted PFC packet can be asserted due to RX logical backpressure. */
uint64_t phys_en : 16; /**< [ 63: 48](R/W) Physical backpressure enable. Determines which classes/channels in the class enable vector
field of a transmitted PFC packet can be asserted due to RX physical backpressure. */
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_smux_cbfc_ctl_s cn; */
};
typedef union bdk_bgxx_smux_cbfc_ctl bdk_bgxx_smux_cbfc_ctl_t;
static inline uint64_t BDK_BGXX_SMUX_CBFC_CTL(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_CBFC_CTL(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020218ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020218ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020218ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_CBFC_CTL", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_CBFC_CTL(a,b) bdk_bgxx_smux_cbfc_ctl_t
#define bustype_BDK_BGXX_SMUX_CBFC_CTL(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_CBFC_CTL(a,b) "BGXX_SMUX_CBFC_CTL"
#define device_bar_BDK_BGXX_SMUX_CBFC_CTL(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_CBFC_CTL(a,b) (a)
#define arguments_BDK_BGXX_SMUX_CBFC_CTL(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_ctrl
*
* BGX SMU Control Registers
*/
union bdk_bgxx_smux_ctrl
{
uint64_t u;
struct bdk_bgxx_smux_ctrl_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_2_63 : 62;
uint64_t tx_idle : 1; /**< [ 1: 1](RO/H) TX machine is idle. This indication pertains to the framer FSM and ignores the effects on
the data-path controls or values which occur when BGX()_SMU()_TX_CTL[LS_BYP] is
set. */
uint64_t rx_idle : 1; /**< [ 0: 0](RO/H) RX machine is idle. */
#else /* Word 0 - Little Endian */
uint64_t rx_idle : 1; /**< [ 0: 0](RO/H) RX machine is idle. */
uint64_t tx_idle : 1; /**< [ 1: 1](RO/H) TX machine is idle. This indication pertains to the framer FSM and ignores the effects on
the data-path controls or values which occur when BGX()_SMU()_TX_CTL[LS_BYP] is
set. */
uint64_t reserved_2_63 : 62;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_smux_ctrl_s cn; */
};
typedef union bdk_bgxx_smux_ctrl bdk_bgxx_smux_ctrl_t;
static inline uint64_t BDK_BGXX_SMUX_CTRL(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_CTRL(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020200ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020200ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020200ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_CTRL", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_CTRL(a,b) bdk_bgxx_smux_ctrl_t
#define bustype_BDK_BGXX_SMUX_CTRL(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_CTRL(a,b) "BGXX_SMUX_CTRL"
#define device_bar_BDK_BGXX_SMUX_CTRL(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_CTRL(a,b) (a)
#define arguments_BDK_BGXX_SMUX_CTRL(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_ext_loopback
*
* BGX SMU External Loopback Registers
* In loopback mode, the IFG1+IFG2 of local and remote parties must match exactly; otherwise one
* of the two sides' loopback FIFO will overrun: BGX()_SMU()_TX_INT[LB_OVRFLW].
*/
union bdk_bgxx_smux_ext_loopback
{
uint64_t u;
struct bdk_bgxx_smux_ext_loopback_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_5_63 : 59;
uint64_t en : 1; /**< [ 4: 4](R/W) Loopback enable. Puts the packet interface in external loopback mode where the RX lines
are reflected on the TX lines. */
uint64_t thresh : 4; /**< [ 3: 0](R/W) Threshold on the TX FIFO. Software must only write the typical value. Any other value
causes loopback mode not to function correctly. */
#else /* Word 0 - Little Endian */
uint64_t thresh : 4; /**< [ 3: 0](R/W) Threshold on the TX FIFO. Software must only write the typical value. Any other value
causes loopback mode not to function correctly. */
uint64_t en : 1; /**< [ 4: 4](R/W) Loopback enable. Puts the packet interface in external loopback mode where the RX lines
are reflected on the TX lines. */
uint64_t reserved_5_63 : 59;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_smux_ext_loopback_s cn; */
};
typedef union bdk_bgxx_smux_ext_loopback bdk_bgxx_smux_ext_loopback_t;
static inline uint64_t BDK_BGXX_SMUX_EXT_LOOPBACK(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_EXT_LOOPBACK(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020208ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020208ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020208ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_EXT_LOOPBACK", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_EXT_LOOPBACK(a,b) bdk_bgxx_smux_ext_loopback_t
#define bustype_BDK_BGXX_SMUX_EXT_LOOPBACK(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_EXT_LOOPBACK(a,b) "BGXX_SMUX_EXT_LOOPBACK"
#define device_bar_BDK_BGXX_SMUX_EXT_LOOPBACK(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_EXT_LOOPBACK(a,b) (a)
#define arguments_BDK_BGXX_SMUX_EXT_LOOPBACK(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_hg2_control
*
* BGX SMU HiGig2 Control Registers
* HiGig2 TX- and RX-enable are normally set together for HiGig2 messaging. Setting just the TX
* or RX bit results in only the HG2 message transmit or receive capability.
*
* Setting [PHYS_EN] and [LOGL_EN] to 1 allows link PAUSE or backpressure to TNS/NIC as per the
* received HiGig2 message. Setting these fields to 0 disables link PAUSE and backpressure to
* TNS/NIC
* in response to received messages.
*
* BGX()_SMU()_TX_CTL[HG_EN] must be set (to enable HiGig) whenever either [HG2TX_EN] or
* [HG2RX_EN] are set. BGX()_SMU()_RX_UDD_SKP[LEN] must be set to 16 (to select HiGig2)
* whenever either [HG2TX_EN] or [HG2RX_EN] are set.
*
* BGX()_CMR_RX_OVR_BP[EN]\<0\> must be set and BGX()_CMR_RX_OVR_BP[BP]\<0\> must be cleared
* to 0 (to forcibly disable hardware-automatic 802.3 PAUSE packet generation) with the HiGig2
* Protocol when [HG2TX_EN] = 0. (The HiGig2 protocol is indicated
* by BGX()_SMU()_TX_CTL[HG_EN] = 1 and BGX()_SMU()_RX_UDD_SKP[LEN]=16.) Hardware
* can only autogenerate backpressure via HiGig2 messages (optionally, when [HG2TX_EN] = 1) with
* the HiGig2 protocol.
*/
union bdk_bgxx_smux_hg2_control
{
uint64_t u;
struct bdk_bgxx_smux_hg2_control_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_19_63 : 45;
uint64_t hg2tx_en : 1; /**< [ 18: 18](R/W) Enable transmission of HG2 physical and logical messages. When set, also disables hardware
autogenerated 802.3 PAUSE and PFC frames. (CNXXXX cannot generate proper 802.3 or
PFC frames in HiGig2 mode.) */
uint64_t hg2rx_en : 1; /**< [ 17: 17](R/W) Enable extraction and processing of HG2 message packet from RX flow. Physical and logical
PAUSE information is used to PAUSE physical-link, backpressure PKO. This field must be set
when HiGig2 messages are present in the receive stream. This bit is also forwarded to CMR
so it can generate the required deferring signals to SMU TX and backpressure signals to
PKO. */
uint64_t phys_en : 1; /**< [ 16: 16](R/W) Physical-link backpressure enable for received physical HiGig2 messages. This bit enables
the SMU TX to CMR HG2 deferring counter to be set every time SMU RX receives and filters
out a valid physical HG2 message. */
uint64_t logl_en : 16; /**< [ 15: 0](R/W) 16-bit logical-link backpressure enables for received HiGig2 messages or PFC packets. */
#else /* Word 0 - Little Endian */
uint64_t logl_en : 16; /**< [ 15: 0](R/W) 16-bit logical-link backpressure enables for received HiGig2 messages or PFC packets. */
uint64_t phys_en : 1; /**< [ 16: 16](R/W) Physical-link backpressure enable for received physical HiGig2 messages. This bit enables
the SMU TX to CMR HG2 deferring counter to be set every time SMU RX receives and filters
out a valid physical HG2 message. */
uint64_t hg2rx_en : 1; /**< [ 17: 17](R/W) Enable extraction and processing of HG2 message packet from RX flow. Physical and logical
PAUSE information is used to PAUSE physical-link, backpressure PKO. This field must be set
when HiGig2 messages are present in the receive stream. This bit is also forwarded to CMR
so it can generate the required deferring signals to SMU TX and backpressure signals to
PKO. */
uint64_t hg2tx_en : 1; /**< [ 18: 18](R/W) Enable transmission of HG2 physical and logical messages. When set, also disables hardware
autogenerated 802.3 PAUSE and PFC frames. (CNXXXX cannot generate proper 802.3 or
PFC frames in HiGig2 mode.) */
uint64_t reserved_19_63 : 45;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_smux_hg2_control_s cn81xx; */
struct bdk_bgxx_smux_hg2_control_cn88xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_19_63 : 45;
uint64_t hg2tx_en : 1; /**< [ 18: 18](R/W) Enable transmission of HG2 physical and logical messages. When set, also disables hardware
autogenerated 802.3 PAUSE and PFC frames. (CNXXXX cannot generate proper 802.3 or
PFC frames in HiGig2 mode.) */
uint64_t hg2rx_en : 1; /**< [ 17: 17](R/W) Enable extraction and processing of HG2 message packet from RX flow. Physical and logical
PAUSE information is used to PAUSE physical-link, backpressure TNS/NIC. This field must be
set
when HiGig2 messages are present in the receive stream. This bit is also forwarded to CMR
so it can generate the required deferring signals to SMU TX and backpressure signals to
TNS/NIC. */
uint64_t phys_en : 1; /**< [ 16: 16](R/W) Physical-link backpressure enable for received physical HiGig2 messages. This bit enables
the SMU TX to CMR HG2 deferring counter to be set every time SMU RX receives and filters
out a valid physical HG2 message. */
uint64_t logl_en : 16; /**< [ 15: 0](R/W) 16-bit logical-link backpressure enables for received HiGig2 messages or PFC packets. */
#else /* Word 0 - Little Endian */
uint64_t logl_en : 16; /**< [ 15: 0](R/W) 16-bit logical-link backpressure enables for received HiGig2 messages or PFC packets. */
uint64_t phys_en : 1; /**< [ 16: 16](R/W) Physical-link backpressure enable for received physical HiGig2 messages. This bit enables
the SMU TX to CMR HG2 deferring counter to be set every time SMU RX receives and filters
out a valid physical HG2 message. */
uint64_t hg2rx_en : 1; /**< [ 17: 17](R/W) Enable extraction and processing of HG2 message packet from RX flow. Physical and logical
PAUSE information is used to PAUSE physical-link, backpressure TNS/NIC. This field must be
set
when HiGig2 messages are present in the receive stream. This bit is also forwarded to CMR
so it can generate the required deferring signals to SMU TX and backpressure signals to
TNS/NIC. */
uint64_t hg2tx_en : 1; /**< [ 18: 18](R/W) Enable transmission of HG2 physical and logical messages. When set, also disables hardware
autogenerated 802.3 PAUSE and PFC frames. (CNXXXX cannot generate proper 802.3 or
PFC frames in HiGig2 mode.) */
uint64_t reserved_19_63 : 45;
#endif /* Word 0 - End */
} cn88xx;
/* struct bdk_bgxx_smux_hg2_control_s cn83xx; */
};
typedef union bdk_bgxx_smux_hg2_control bdk_bgxx_smux_hg2_control_t;
static inline uint64_t BDK_BGXX_SMUX_HG2_CONTROL(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_HG2_CONTROL(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020210ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020210ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020210ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_HG2_CONTROL", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_HG2_CONTROL(a,b) bdk_bgxx_smux_hg2_control_t
#define bustype_BDK_BGXX_SMUX_HG2_CONTROL(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_HG2_CONTROL(a,b) "BGXX_SMUX_HG2_CONTROL"
#define device_bar_BDK_BGXX_SMUX_HG2_CONTROL(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_HG2_CONTROL(a,b) (a)
#define arguments_BDK_BGXX_SMUX_HG2_CONTROL(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_rx_bad_col_hi
*
* BGX SMU RX Bad Column High Registers
*/
union bdk_bgxx_smux_rx_bad_col_hi
{
uint64_t u;
struct bdk_bgxx_smux_rx_bad_col_hi_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_17_63 : 47;
uint64_t val : 1; /**< [ 16: 16](R/W1C/H) Set when BGX()_SMU()_RX_INT[PCTERR] is set. */
uint64_t state : 8; /**< [ 15: 8](RO/H) When BGX()_SMU()_RX_INT[PCTERR] is set, contains the receive state at the time of
the error. */
uint64_t lane_rxc : 8; /**< [ 7: 0](RO/H) When BGX()_SMU()_RX_INT[PCTERR] is set, contains the column at the time of the error. */
#else /* Word 0 - Little Endian */
uint64_t lane_rxc : 8; /**< [ 7: 0](RO/H) When BGX()_SMU()_RX_INT[PCTERR] is set, contains the column at the time of the error. */
uint64_t state : 8; /**< [ 15: 8](RO/H) When BGX()_SMU()_RX_INT[PCTERR] is set, contains the receive state at the time of
the error. */
uint64_t val : 1; /**< [ 16: 16](R/W1C/H) Set when BGX()_SMU()_RX_INT[PCTERR] is set. */
uint64_t reserved_17_63 : 47;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_smux_rx_bad_col_hi_s cn; */
};
typedef union bdk_bgxx_smux_rx_bad_col_hi bdk_bgxx_smux_rx_bad_col_hi_t;
static inline uint64_t BDK_BGXX_SMUX_RX_BAD_COL_HI(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_RX_BAD_COL_HI(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020058ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020058ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020058ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_RX_BAD_COL_HI", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_RX_BAD_COL_HI(a,b) bdk_bgxx_smux_rx_bad_col_hi_t
#define bustype_BDK_BGXX_SMUX_RX_BAD_COL_HI(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_RX_BAD_COL_HI(a,b) "BGXX_SMUX_RX_BAD_COL_HI"
#define device_bar_BDK_BGXX_SMUX_RX_BAD_COL_HI(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_RX_BAD_COL_HI(a,b) (a)
#define arguments_BDK_BGXX_SMUX_RX_BAD_COL_HI(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_rx_bad_col_lo
*
* BGX SMU RX Bad Column Low Registers
*/
union bdk_bgxx_smux_rx_bad_col_lo
{
uint64_t u;
struct bdk_bgxx_smux_rx_bad_col_lo_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t lane_rxd : 64; /**< [ 63: 0](RO/H) When BGX()_SMU()_RX_INT[PCTERR] is set, [LANE_RXD] contains the XAUI/RXAUI column at
the time of the error. */
#else /* Word 0 - Little Endian */
uint64_t lane_rxd : 64; /**< [ 63: 0](RO/H) When BGX()_SMU()_RX_INT[PCTERR] is set, [LANE_RXD] contains the XAUI/RXAUI column at
the time of the error. */
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_smux_rx_bad_col_lo_s cn; */
};
typedef union bdk_bgxx_smux_rx_bad_col_lo bdk_bgxx_smux_rx_bad_col_lo_t;
static inline uint64_t BDK_BGXX_SMUX_RX_BAD_COL_LO(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_RX_BAD_COL_LO(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020050ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020050ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020050ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_RX_BAD_COL_LO", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_RX_BAD_COL_LO(a,b) bdk_bgxx_smux_rx_bad_col_lo_t
#define bustype_BDK_BGXX_SMUX_RX_BAD_COL_LO(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_RX_BAD_COL_LO(a,b) "BGXX_SMUX_RX_BAD_COL_LO"
#define device_bar_BDK_BGXX_SMUX_RX_BAD_COL_LO(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_RX_BAD_COL_LO(a,b) (a)
#define arguments_BDK_BGXX_SMUX_RX_BAD_COL_LO(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_rx_ctl
*
* BGX SMU RX Control Registers
*/
union bdk_bgxx_smux_rx_ctl
{
uint64_t u;
struct bdk_bgxx_smux_rx_ctl_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_2_63 : 62;
uint64_t status : 2; /**< [ 1: 0](RO/H) Link status.
0x0 = Link OK.
0x1 = Local fault.
0x2 = Remote fault.
0x3 = Reserved. */
#else /* Word 0 - Little Endian */
uint64_t status : 2; /**< [ 1: 0](RO/H) Link status.
0x0 = Link OK.
0x1 = Local fault.
0x2 = Remote fault.
0x3 = Reserved. */
uint64_t reserved_2_63 : 62;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_smux_rx_ctl_s cn; */
};
typedef union bdk_bgxx_smux_rx_ctl bdk_bgxx_smux_rx_ctl_t;
static inline uint64_t BDK_BGXX_SMUX_RX_CTL(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_RX_CTL(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020048ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020048ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020048ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_RX_CTL", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_RX_CTL(a,b) bdk_bgxx_smux_rx_ctl_t
#define bustype_BDK_BGXX_SMUX_RX_CTL(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_RX_CTL(a,b) "BGXX_SMUX_RX_CTL"
#define device_bar_BDK_BGXX_SMUX_RX_CTL(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_RX_CTL(a,b) (a)
#define arguments_BDK_BGXX_SMUX_RX_CTL(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_rx_decision
*
* BGX SMU Packet Decision Registers
* This register specifies the byte count used to determine when to accept or to filter a packet.
* As each byte in a packet is received by BGX, the L2 byte count (i.e. the number of bytes from
* the beginning of the L2 header (DMAC)) is compared against CNT. In normal operation, the L2
* header begins after the PREAMBLE + SFD (BGX()_SMU()_RX_FRM_CTL[PRE_CHK] = 1) and any
* optional UDD skip data (BGX()_SMU()_RX_UDD_SKP[LEN]).
*/
union bdk_bgxx_smux_rx_decision
{
uint64_t u;
struct bdk_bgxx_smux_rx_decision_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_5_63 : 59;
uint64_t cnt : 5; /**< [ 4: 0](R/W) The byte count to decide when to accept or filter a packet. */
#else /* Word 0 - Little Endian */
uint64_t cnt : 5; /**< [ 4: 0](R/W) The byte count to decide when to accept or filter a packet. */
uint64_t reserved_5_63 : 59;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_smux_rx_decision_s cn; */
};
typedef union bdk_bgxx_smux_rx_decision bdk_bgxx_smux_rx_decision_t;
static inline uint64_t BDK_BGXX_SMUX_RX_DECISION(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_RX_DECISION(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020038ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020038ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020038ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_RX_DECISION", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_RX_DECISION(a,b) bdk_bgxx_smux_rx_decision_t
#define bustype_BDK_BGXX_SMUX_RX_DECISION(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_RX_DECISION(a,b) "BGXX_SMUX_RX_DECISION"
#define device_bar_BDK_BGXX_SMUX_RX_DECISION(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_RX_DECISION(a,b) (a)
#define arguments_BDK_BGXX_SMUX_RX_DECISION(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_rx_frm_chk
*
* BGX SMU RX Frame Check Registers
* The CSRs provide the enable bits for a subset of errors passed to CMR encoded.
*/
union bdk_bgxx_smux_rx_frm_chk
{
uint64_t u;
struct bdk_bgxx_smux_rx_frm_chk_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_9_63 : 55;
uint64_t skperr : 1; /**< [ 8: 8](R/W) Skipper error. */
uint64_t rcverr : 1; /**< [ 7: 7](R/W) Frame was received with data-reception error. */
uint64_t reserved_6 : 1;
uint64_t fcserr_c : 1; /**< [ 5: 5](R/W) Control frame was received with FCS/CRC error. */
uint64_t fcserr_d : 1; /**< [ 4: 4](R/W) Data frame was received with FCS/CRC error. */
uint64_t jabber : 1; /**< [ 3: 3](R/W) Frame was received with length \> sys_length. */
uint64_t reserved_0_2 : 3;
#else /* Word 0 - Little Endian */
uint64_t reserved_0_2 : 3;
uint64_t jabber : 1; /**< [ 3: 3](R/W) Frame was received with length \> sys_length. */
uint64_t fcserr_d : 1; /**< [ 4: 4](R/W) Data frame was received with FCS/CRC error. */
uint64_t fcserr_c : 1; /**< [ 5: 5](R/W) Control frame was received with FCS/CRC error. */
uint64_t reserved_6 : 1;
uint64_t rcverr : 1; /**< [ 7: 7](R/W) Frame was received with data-reception error. */
uint64_t skperr : 1; /**< [ 8: 8](R/W) Skipper error. */
uint64_t reserved_9_63 : 55;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_smux_rx_frm_chk_s cn; */
};
typedef union bdk_bgxx_smux_rx_frm_chk bdk_bgxx_smux_rx_frm_chk_t;
static inline uint64_t BDK_BGXX_SMUX_RX_FRM_CHK(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_RX_FRM_CHK(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020028ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020028ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020028ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_RX_FRM_CHK", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_RX_FRM_CHK(a,b) bdk_bgxx_smux_rx_frm_chk_t
#define bustype_BDK_BGXX_SMUX_RX_FRM_CHK(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_RX_FRM_CHK(a,b) "BGXX_SMUX_RX_FRM_CHK"
#define device_bar_BDK_BGXX_SMUX_RX_FRM_CHK(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_RX_FRM_CHK(a,b) (a)
#define arguments_BDK_BGXX_SMUX_RX_FRM_CHK(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_rx_frm_ctl
*
* BGX SMU RX Frame Control Registers
* This register controls the handling of the frames.
* The [CTL_BCK] and [CTL_DRP] bits control how the hardware handles incoming PAUSE packets. The
* most
* common modes of operation:
* _ [CTL_BCK] = 1, [CTL_DRP] = 1: hardware handles everything
* _ [CTL_BCK] = 0, [CTL_DRP] = 0: software sees all PAUSE frames
* _ [CTL_BCK] = 0, [CTL_DRP] = 1: all PAUSE frames are completely ignored
*
* These control bits should be set to [CTL_BCK] = 0, [CTL_DRP] = 0 in half-duplex mode. Since
* PAUSE
* packets only apply to full duplex operation, any PAUSE packet would constitute an exception
* which should be handled by the processing cores. PAUSE packets should not be forwarded.
*/
union bdk_bgxx_smux_rx_frm_ctl
{
uint64_t u;
struct bdk_bgxx_smux_rx_frm_ctl_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_13_63 : 51;
uint64_t ptp_mode : 1; /**< [ 12: 12](R/W) Timestamp mode. When [PTP_MODE] is set, a 64-bit timestamp is prepended to every incoming
packet.
The timestamp bytes are added to the packet in such a way as to not modify the packet's
receive byte count. This implies that the BGX()_SMU()_RX_JABBER,
BGX()_SMU()_RX_DECISION, and BGX()_SMU()_RX_UDD_SKP do not require any
adjustment as they operate on the received packet size. When the packet reaches NIC, its
size reflects the additional bytes. */
uint64_t reserved_6_11 : 6;
uint64_t ctl_smac : 1; /**< [ 5: 5](R/W) Control PAUSE frames can match station SMAC. */
uint64_t ctl_mcst : 1; /**< [ 4: 4](R/W) Control PAUSE frames can match globally assigned multicast address. */
uint64_t ctl_bck : 1; /**< [ 3: 3](R/W) Forward PAUSE information to TX block. */
uint64_t ctl_drp : 1; /**< [ 2: 2](R/W) Drop control PAUSE frames. */
uint64_t pre_strp : 1; /**< [ 1: 1](R/W) Strip off the preamble (when present).
0 = PREAMBLE + SFD is sent to core as part of frame.
1 = PREAMBLE + SFD is dropped.
[PRE_CHK] must be set to enable this and all PREAMBLE features.
If [PTP_MODE] = 1 and [PRE_CHK] = 1, [PRE_STRP] must be 1.
When [PRE_CHK] is set (indicating that the PREAMBLE will be sent), [PRE_STRP] determines
if
the PREAMBLE+SFD bytes are thrown away or sent to the core as part of the packet. In
either mode, the PREAMBLE+SFD bytes are not counted toward the packet size when checking
against the MIN and MAX bounds. Furthermore, the bytes are skipped when locating the start
of the L2 header for DMAC and control frame recognition. */
uint64_t pre_chk : 1; /**< [ 0: 0](R/W) Check the preamble for correctness.
This port is configured to send a valid 802.3 PREAMBLE to begin every frame. BGX checks
that a valid PREAMBLE is received. When a problem does occur within
the PREAMBLE sequence, the frame is marked as bad and not sent into the core. The
BGX()_SMU()_RX_INT[PCTERR] interrupt is also raised.
When BGX()_SMU()_TX_CTL[HG_EN] is set, [PRE_CHK] must be 0.
If [PTP_MODE] = 1 and [PRE_CHK] = 1, [PRE_STRP] must be 1. */
#else /* Word 0 - Little Endian */
uint64_t pre_chk : 1; /**< [ 0: 0](R/W) Check the preamble for correctness.
This port is configured to send a valid 802.3 PREAMBLE to begin every frame. BGX checks
that a valid PREAMBLE is received. When a problem does occur within
the PREAMBLE sequence, the frame is marked as bad and not sent into the core. The
BGX()_SMU()_RX_INT[PCTERR] interrupt is also raised.
When BGX()_SMU()_TX_CTL[HG_EN] is set, [PRE_CHK] must be 0.
If [PTP_MODE] = 1 and [PRE_CHK] = 1, [PRE_STRP] must be 1. */
uint64_t pre_strp : 1; /**< [ 1: 1](R/W) Strip off the preamble (when present).
0 = PREAMBLE + SFD is sent to core as part of frame.
1 = PREAMBLE + SFD is dropped.
[PRE_CHK] must be set to enable this and all PREAMBLE features.
If [PTP_MODE] = 1 and [PRE_CHK] = 1, [PRE_STRP] must be 1.
When [PRE_CHK] is set (indicating that the PREAMBLE will be sent), [PRE_STRP] determines
if
the PREAMBLE+SFD bytes are thrown away or sent to the core as part of the packet. In
either mode, the PREAMBLE+SFD bytes are not counted toward the packet size when checking
against the MIN and MAX bounds. Furthermore, the bytes are skipped when locating the start
of the L2 header for DMAC and control frame recognition. */
uint64_t ctl_drp : 1; /**< [ 2: 2](R/W) Drop control PAUSE frames. */
uint64_t ctl_bck : 1; /**< [ 3: 3](R/W) Forward PAUSE information to TX block. */
uint64_t ctl_mcst : 1; /**< [ 4: 4](R/W) Control PAUSE frames can match globally assigned multicast address. */
uint64_t ctl_smac : 1; /**< [ 5: 5](R/W) Control PAUSE frames can match station SMAC. */
uint64_t reserved_6_11 : 6;
uint64_t ptp_mode : 1; /**< [ 12: 12](R/W) Timestamp mode. When [PTP_MODE] is set, a 64-bit timestamp is prepended to every incoming
packet.
The timestamp bytes are added to the packet in such a way as to not modify the packet's
receive byte count. This implies that the BGX()_SMU()_RX_JABBER,
BGX()_SMU()_RX_DECISION, and BGX()_SMU()_RX_UDD_SKP do not require any
adjustment as they operate on the received packet size. When the packet reaches NIC, its
size reflects the additional bytes. */
uint64_t reserved_13_63 : 51;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_smux_rx_frm_ctl_s cn; */
};
typedef union bdk_bgxx_smux_rx_frm_ctl bdk_bgxx_smux_rx_frm_ctl_t;
static inline uint64_t BDK_BGXX_SMUX_RX_FRM_CTL(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_RX_FRM_CTL(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020020ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020020ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020020ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_RX_FRM_CTL", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_RX_FRM_CTL(a,b) bdk_bgxx_smux_rx_frm_ctl_t
#define bustype_BDK_BGXX_SMUX_RX_FRM_CTL(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_RX_FRM_CTL(a,b) "BGXX_SMUX_RX_FRM_CTL"
#define device_bar_BDK_BGXX_SMUX_RX_FRM_CTL(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_RX_FRM_CTL(a,b) (a)
#define arguments_BDK_BGXX_SMUX_RX_FRM_CTL(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_rx_int
*
* BGX SMU Receive Interrupt Registers
* SMU Interrupt Register.
* Internal:
* Exception conditions \<9\> and \<4:0\> can also set the rcv/opcode in the received packet's work
* queue entry. BGX()_SMU()_RX_FRM_CHK provides a bit mask for configuring which
* conditions set the error.
*/
union bdk_bgxx_smux_rx_int
{
uint64_t u;
struct bdk_bgxx_smux_rx_int_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_12_63 : 52;
uint64_t hg2cc : 1; /**< [ 11: 11](R/W1C/H) HiGig2 received message CRC or control-character error. Set when either a CRC8 error is
detected, or when a control character is found in the message bytes after the K.SOM.
HG2CC has higher priority than HG2FLD, which means that a HiGig2 message that results in
HG2CC getting set never sets HG2FLD. */
uint64_t hg2fld : 1; /**< [ 10: 10](R/W1C/H) HiGig2 received message field error:
MSG_TYPE field not 0x0, i.e. it is not a flow-control message, which is the only defined
type for HiGig2.
FWD_TYPE field not 0x0, i.e. it is not a link-level message, which is the only defined
type for HiGig2.
FC_OBJECT field is neither 0x0 for physical link, nor 0x2 for logical link. Those are the
only two defined types in HiGig2 */
uint64_t bad_term : 1; /**< [ 9: 9](R/W1C/H) Frame is terminated by control character other than /T/. The error
propagation control character /E/ will be included as part of the frame and does not cause
a frame termination. */
uint64_t bad_seq : 1; /**< [ 8: 8](R/W1C/H) Detected reserved sequence. */
uint64_t rem_fault : 1; /**< [ 7: 7](R/W1C/H) Remote-fault sequence detected. */
uint64_t loc_fault : 1; /**< [ 6: 6](R/W1C/H) Local-fault sequence detected. */
uint64_t rsverr : 1; /**< [ 5: 5](R/W1C/H) Detected reserved opcode. */
uint64_t pcterr : 1; /**< [ 4: 4](R/W1C/H) Bad preamble/protocol. In XAUI/RXAUI mode, the column of data that was bad is logged in
BGX()_SMU()_RX_BAD_COL_LO and BGX()_SMU()_RX_BAD_COL_HI.
PCTERR checks that the frame begins with a valid
PREAMBLE sequence. Does not check the number of PREAMBLE cycles. */
uint64_t skperr : 1; /**< [ 3: 3](R/W1C/H) Skipper error. */
uint64_t rcverr : 1; /**< [ 2: 2](R/W1C/H) Frame was received with data-reception error. */
uint64_t fcserr : 1; /**< [ 1: 1](R/W1C/H) Frame was received with FCS/CRC error */
uint64_t jabber : 1; /**< [ 0: 0](R/W1C/H) Frame was received with length \> sys_length. An RX Jabber error indicates that a packet
was received which is longer than the maximum allowed packet as defined by the system. BGX
terminates the packet with an EOP on the beat on which JABBER was exceeded. The beat on
which JABBER was exceeded is left unchanged and all subsequent data beats are dropped.
Failure to truncate could lead to system instability. */
#else /* Word 0 - Little Endian */
uint64_t jabber : 1; /**< [ 0: 0](R/W1C/H) Frame was received with length \> sys_length. An RX Jabber error indicates that a packet
was received which is longer than the maximum allowed packet as defined by the system. BGX
terminates the packet with an EOP on the beat on which JABBER was exceeded. The beat on
which JABBER was exceeded is left unchanged and all subsequent data beats are dropped.
Failure to truncate could lead to system instability. */
uint64_t fcserr : 1; /**< [ 1: 1](R/W1C/H) Frame was received with FCS/CRC error */
uint64_t rcverr : 1; /**< [ 2: 2](R/W1C/H) Frame was received with data-reception error. */
uint64_t skperr : 1; /**< [ 3: 3](R/W1C/H) Skipper error. */
uint64_t pcterr : 1; /**< [ 4: 4](R/W1C/H) Bad preamble/protocol. In XAUI/RXAUI mode, the column of data that was bad is logged in
BGX()_SMU()_RX_BAD_COL_LO and BGX()_SMU()_RX_BAD_COL_HI.
PCTERR checks that the frame begins with a valid
PREAMBLE sequence. Does not check the number of PREAMBLE cycles. */
uint64_t rsverr : 1; /**< [ 5: 5](R/W1C/H) Detected reserved opcode. */
uint64_t loc_fault : 1; /**< [ 6: 6](R/W1C/H) Local-fault sequence detected. */
uint64_t rem_fault : 1; /**< [ 7: 7](R/W1C/H) Remote-fault sequence detected. */
uint64_t bad_seq : 1; /**< [ 8: 8](R/W1C/H) Detected reserved sequence. */
uint64_t bad_term : 1; /**< [ 9: 9](R/W1C/H) Frame is terminated by control character other than /T/. The error
propagation control character /E/ will be included as part of the frame and does not cause
a frame termination. */
uint64_t hg2fld : 1; /**< [ 10: 10](R/W1C/H) HiGig2 received message field error:
MSG_TYPE field not 0x0, i.e. it is not a flow-control message, which is the only defined
type for HiGig2.
FWD_TYPE field not 0x0, i.e. it is not a link-level message, which is the only defined
type for HiGig2.
FC_OBJECT field is neither 0x0 for physical link, nor 0x2 for logical link. Those are the
only two defined types in HiGig2 */
uint64_t hg2cc : 1; /**< [ 11: 11](R/W1C/H) HiGig2 received message CRC or control-character error. Set when either a CRC8 error is
detected, or when a control character is found in the message bytes after the K.SOM.
HG2CC has higher priority than HG2FLD, which means that a HiGig2 message that results in
HG2CC getting set never sets HG2FLD. */
uint64_t reserved_12_63 : 52;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_smux_rx_int_s cn; */
};
typedef union bdk_bgxx_smux_rx_int bdk_bgxx_smux_rx_int_t;
static inline uint64_t BDK_BGXX_SMUX_RX_INT(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_RX_INT(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020000ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020000ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020000ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_RX_INT", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_RX_INT(a,b) bdk_bgxx_smux_rx_int_t
#define bustype_BDK_BGXX_SMUX_RX_INT(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_RX_INT(a,b) "BGXX_SMUX_RX_INT"
#define device_bar_BDK_BGXX_SMUX_RX_INT(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_RX_INT(a,b) (a)
#define arguments_BDK_BGXX_SMUX_RX_INT(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_rx_int_ena_w1c
*
* BGX SMU Receive Interrupt Enable Clear Registers
* This register clears interrupt enable bits.
*/
union bdk_bgxx_smux_rx_int_ena_w1c
{
uint64_t u;
struct bdk_bgxx_smux_rx_int_ena_w1c_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_12_63 : 52;
uint64_t hg2cc : 1; /**< [ 11: 11](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_RX_INT[HG2CC]. */
uint64_t hg2fld : 1; /**< [ 10: 10](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_RX_INT[HG2FLD]. */
uint64_t bad_term : 1; /**< [ 9: 9](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_RX_INT[BAD_TERM]. */
uint64_t bad_seq : 1; /**< [ 8: 8](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_RX_INT[BAD_SEQ]. */
uint64_t rem_fault : 1; /**< [ 7: 7](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_RX_INT[REM_FAULT]. */
uint64_t loc_fault : 1; /**< [ 6: 6](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_RX_INT[LOC_FAULT]. */
uint64_t rsverr : 1; /**< [ 5: 5](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_RX_INT[RSVERR]. */
uint64_t pcterr : 1; /**< [ 4: 4](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_RX_INT[PCTERR]. */
uint64_t skperr : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_RX_INT[SKPERR]. */
uint64_t rcverr : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_RX_INT[RCVERR]. */
uint64_t fcserr : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_RX_INT[FCSERR]. */
uint64_t jabber : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_RX_INT[JABBER]. */
#else /* Word 0 - Little Endian */
uint64_t jabber : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_RX_INT[JABBER]. */
uint64_t fcserr : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_RX_INT[FCSERR]. */
uint64_t rcverr : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_RX_INT[RCVERR]. */
uint64_t skperr : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_RX_INT[SKPERR]. */
uint64_t pcterr : 1; /**< [ 4: 4](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_RX_INT[PCTERR]. */
uint64_t rsverr : 1; /**< [ 5: 5](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_RX_INT[RSVERR]. */
uint64_t loc_fault : 1; /**< [ 6: 6](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_RX_INT[LOC_FAULT]. */
uint64_t rem_fault : 1; /**< [ 7: 7](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_RX_INT[REM_FAULT]. */
uint64_t bad_seq : 1; /**< [ 8: 8](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_RX_INT[BAD_SEQ]. */
uint64_t bad_term : 1; /**< [ 9: 9](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_RX_INT[BAD_TERM]. */
uint64_t hg2fld : 1; /**< [ 10: 10](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_RX_INT[HG2FLD]. */
uint64_t hg2cc : 1; /**< [ 11: 11](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_RX_INT[HG2CC]. */
uint64_t reserved_12_63 : 52;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_smux_rx_int_ena_w1c_s cn81xx; */
/* struct bdk_bgxx_smux_rx_int_ena_w1c_s cn88xx; */
struct bdk_bgxx_smux_rx_int_ena_w1c_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_12_63 : 52;
uint64_t hg2cc : 1; /**< [ 11: 11](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_RX_INT[HG2CC]. */
uint64_t hg2fld : 1; /**< [ 10: 10](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_RX_INT[HG2FLD]. */
uint64_t bad_term : 1; /**< [ 9: 9](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_RX_INT[BAD_TERM]. */
uint64_t bad_seq : 1; /**< [ 8: 8](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_RX_INT[BAD_SEQ]. */
uint64_t rem_fault : 1; /**< [ 7: 7](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_RX_INT[REM_FAULT]. */
uint64_t loc_fault : 1; /**< [ 6: 6](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_RX_INT[LOC_FAULT]. */
uint64_t rsverr : 1; /**< [ 5: 5](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_RX_INT[RSVERR]. */
uint64_t pcterr : 1; /**< [ 4: 4](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_RX_INT[PCTERR]. */
uint64_t skperr : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_RX_INT[SKPERR]. */
uint64_t rcverr : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_RX_INT[RCVERR]. */
uint64_t fcserr : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_RX_INT[FCSERR]. */
uint64_t jabber : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_RX_INT[JABBER]. */
#else /* Word 0 - Little Endian */
uint64_t jabber : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_RX_INT[JABBER]. */
uint64_t fcserr : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_RX_INT[FCSERR]. */
uint64_t rcverr : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_RX_INT[RCVERR]. */
uint64_t skperr : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_RX_INT[SKPERR]. */
uint64_t pcterr : 1; /**< [ 4: 4](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_RX_INT[PCTERR]. */
uint64_t rsverr : 1; /**< [ 5: 5](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_RX_INT[RSVERR]. */
uint64_t loc_fault : 1; /**< [ 6: 6](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_RX_INT[LOC_FAULT]. */
uint64_t rem_fault : 1; /**< [ 7: 7](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_RX_INT[REM_FAULT]. */
uint64_t bad_seq : 1; /**< [ 8: 8](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_RX_INT[BAD_SEQ]. */
uint64_t bad_term : 1; /**< [ 9: 9](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_RX_INT[BAD_TERM]. */
uint64_t hg2fld : 1; /**< [ 10: 10](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_RX_INT[HG2FLD]. */
uint64_t hg2cc : 1; /**< [ 11: 11](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_RX_INT[HG2CC]. */
uint64_t reserved_12_63 : 52;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_smux_rx_int_ena_w1c bdk_bgxx_smux_rx_int_ena_w1c_t;
static inline uint64_t BDK_BGXX_SMUX_RX_INT_ENA_W1C(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_RX_INT_ENA_W1C(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020010ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020010ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020010ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_RX_INT_ENA_W1C", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_RX_INT_ENA_W1C(a,b) bdk_bgxx_smux_rx_int_ena_w1c_t
#define bustype_BDK_BGXX_SMUX_RX_INT_ENA_W1C(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_RX_INT_ENA_W1C(a,b) "BGXX_SMUX_RX_INT_ENA_W1C"
#define device_bar_BDK_BGXX_SMUX_RX_INT_ENA_W1C(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_RX_INT_ENA_W1C(a,b) (a)
#define arguments_BDK_BGXX_SMUX_RX_INT_ENA_W1C(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_rx_int_ena_w1s
*
* BGX SMU Receive Interrupt Enable Set Registers
* This register sets interrupt enable bits.
*/
union bdk_bgxx_smux_rx_int_ena_w1s
{
uint64_t u;
struct bdk_bgxx_smux_rx_int_ena_w1s_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_12_63 : 52;
uint64_t hg2cc : 1; /**< [ 11: 11](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_RX_INT[HG2CC]. */
uint64_t hg2fld : 1; /**< [ 10: 10](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_RX_INT[HG2FLD]. */
uint64_t bad_term : 1; /**< [ 9: 9](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_RX_INT[BAD_TERM]. */
uint64_t bad_seq : 1; /**< [ 8: 8](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_RX_INT[BAD_SEQ]. */
uint64_t rem_fault : 1; /**< [ 7: 7](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_RX_INT[REM_FAULT]. */
uint64_t loc_fault : 1; /**< [ 6: 6](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_RX_INT[LOC_FAULT]. */
uint64_t rsverr : 1; /**< [ 5: 5](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_RX_INT[RSVERR]. */
uint64_t pcterr : 1; /**< [ 4: 4](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_RX_INT[PCTERR]. */
uint64_t skperr : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_RX_INT[SKPERR]. */
uint64_t rcverr : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_RX_INT[RCVERR]. */
uint64_t fcserr : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_RX_INT[FCSERR]. */
uint64_t jabber : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_RX_INT[JABBER]. */
#else /* Word 0 - Little Endian */
uint64_t jabber : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_RX_INT[JABBER]. */
uint64_t fcserr : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_RX_INT[FCSERR]. */
uint64_t rcverr : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_RX_INT[RCVERR]. */
uint64_t skperr : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_RX_INT[SKPERR]. */
uint64_t pcterr : 1; /**< [ 4: 4](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_RX_INT[PCTERR]. */
uint64_t rsverr : 1; /**< [ 5: 5](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_RX_INT[RSVERR]. */
uint64_t loc_fault : 1; /**< [ 6: 6](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_RX_INT[LOC_FAULT]. */
uint64_t rem_fault : 1; /**< [ 7: 7](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_RX_INT[REM_FAULT]. */
uint64_t bad_seq : 1; /**< [ 8: 8](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_RX_INT[BAD_SEQ]. */
uint64_t bad_term : 1; /**< [ 9: 9](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_RX_INT[BAD_TERM]. */
uint64_t hg2fld : 1; /**< [ 10: 10](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_RX_INT[HG2FLD]. */
uint64_t hg2cc : 1; /**< [ 11: 11](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_RX_INT[HG2CC]. */
uint64_t reserved_12_63 : 52;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_smux_rx_int_ena_w1s_s cn81xx; */
/* struct bdk_bgxx_smux_rx_int_ena_w1s_s cn88xx; */
struct bdk_bgxx_smux_rx_int_ena_w1s_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_12_63 : 52;
uint64_t hg2cc : 1; /**< [ 11: 11](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_RX_INT[HG2CC]. */
uint64_t hg2fld : 1; /**< [ 10: 10](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_RX_INT[HG2FLD]. */
uint64_t bad_term : 1; /**< [ 9: 9](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_RX_INT[BAD_TERM]. */
uint64_t bad_seq : 1; /**< [ 8: 8](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_RX_INT[BAD_SEQ]. */
uint64_t rem_fault : 1; /**< [ 7: 7](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_RX_INT[REM_FAULT]. */
uint64_t loc_fault : 1; /**< [ 6: 6](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_RX_INT[LOC_FAULT]. */
uint64_t rsverr : 1; /**< [ 5: 5](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_RX_INT[RSVERR]. */
uint64_t pcterr : 1; /**< [ 4: 4](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_RX_INT[PCTERR]. */
uint64_t skperr : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_RX_INT[SKPERR]. */
uint64_t rcverr : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_RX_INT[RCVERR]. */
uint64_t fcserr : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_RX_INT[FCSERR]. */
uint64_t jabber : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_RX_INT[JABBER]. */
#else /* Word 0 - Little Endian */
uint64_t jabber : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_RX_INT[JABBER]. */
uint64_t fcserr : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_RX_INT[FCSERR]. */
uint64_t rcverr : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_RX_INT[RCVERR]. */
uint64_t skperr : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_RX_INT[SKPERR]. */
uint64_t pcterr : 1; /**< [ 4: 4](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_RX_INT[PCTERR]. */
uint64_t rsverr : 1; /**< [ 5: 5](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_RX_INT[RSVERR]. */
uint64_t loc_fault : 1; /**< [ 6: 6](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_RX_INT[LOC_FAULT]. */
uint64_t rem_fault : 1; /**< [ 7: 7](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_RX_INT[REM_FAULT]. */
uint64_t bad_seq : 1; /**< [ 8: 8](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_RX_INT[BAD_SEQ]. */
uint64_t bad_term : 1; /**< [ 9: 9](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_RX_INT[BAD_TERM]. */
uint64_t hg2fld : 1; /**< [ 10: 10](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_RX_INT[HG2FLD]. */
uint64_t hg2cc : 1; /**< [ 11: 11](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_RX_INT[HG2CC]. */
uint64_t reserved_12_63 : 52;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_smux_rx_int_ena_w1s bdk_bgxx_smux_rx_int_ena_w1s_t;
static inline uint64_t BDK_BGXX_SMUX_RX_INT_ENA_W1S(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_RX_INT_ENA_W1S(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020018ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020018ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020018ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_RX_INT_ENA_W1S", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_RX_INT_ENA_W1S(a,b) bdk_bgxx_smux_rx_int_ena_w1s_t
#define bustype_BDK_BGXX_SMUX_RX_INT_ENA_W1S(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_RX_INT_ENA_W1S(a,b) "BGXX_SMUX_RX_INT_ENA_W1S"
#define device_bar_BDK_BGXX_SMUX_RX_INT_ENA_W1S(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_RX_INT_ENA_W1S(a,b) (a)
#define arguments_BDK_BGXX_SMUX_RX_INT_ENA_W1S(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_rx_int_w1s
*
* BGX SMU Receive Interrupt Set Registers
* This register sets interrupt bits.
*/
union bdk_bgxx_smux_rx_int_w1s
{
uint64_t u;
struct bdk_bgxx_smux_rx_int_w1s_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_12_63 : 52;
uint64_t hg2cc : 1; /**< [ 11: 11](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_RX_INT[HG2CC]. */
uint64_t hg2fld : 1; /**< [ 10: 10](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_RX_INT[HG2FLD]. */
uint64_t bad_term : 1; /**< [ 9: 9](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_RX_INT[BAD_TERM]. */
uint64_t bad_seq : 1; /**< [ 8: 8](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_RX_INT[BAD_SEQ]. */
uint64_t rem_fault : 1; /**< [ 7: 7](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_RX_INT[REM_FAULT]. */
uint64_t loc_fault : 1; /**< [ 6: 6](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_RX_INT[LOC_FAULT]. */
uint64_t rsverr : 1; /**< [ 5: 5](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_RX_INT[RSVERR]. */
uint64_t pcterr : 1; /**< [ 4: 4](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_RX_INT[PCTERR]. */
uint64_t skperr : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_RX_INT[SKPERR]. */
uint64_t rcverr : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_RX_INT[RCVERR]. */
uint64_t fcserr : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_RX_INT[FCSERR]. */
uint64_t jabber : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_RX_INT[JABBER]. */
#else /* Word 0 - Little Endian */
uint64_t jabber : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_RX_INT[JABBER]. */
uint64_t fcserr : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_RX_INT[FCSERR]. */
uint64_t rcverr : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_RX_INT[RCVERR]. */
uint64_t skperr : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_RX_INT[SKPERR]. */
uint64_t pcterr : 1; /**< [ 4: 4](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_RX_INT[PCTERR]. */
uint64_t rsverr : 1; /**< [ 5: 5](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_RX_INT[RSVERR]. */
uint64_t loc_fault : 1; /**< [ 6: 6](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_RX_INT[LOC_FAULT]. */
uint64_t rem_fault : 1; /**< [ 7: 7](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_RX_INT[REM_FAULT]. */
uint64_t bad_seq : 1; /**< [ 8: 8](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_RX_INT[BAD_SEQ]. */
uint64_t bad_term : 1; /**< [ 9: 9](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_RX_INT[BAD_TERM]. */
uint64_t hg2fld : 1; /**< [ 10: 10](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_RX_INT[HG2FLD]. */
uint64_t hg2cc : 1; /**< [ 11: 11](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_RX_INT[HG2CC]. */
uint64_t reserved_12_63 : 52;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_smux_rx_int_w1s_s cn81xx; */
/* struct bdk_bgxx_smux_rx_int_w1s_s cn88xx; */
struct bdk_bgxx_smux_rx_int_w1s_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_12_63 : 52;
uint64_t hg2cc : 1; /**< [ 11: 11](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_RX_INT[HG2CC]. */
uint64_t hg2fld : 1; /**< [ 10: 10](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_RX_INT[HG2FLD]. */
uint64_t bad_term : 1; /**< [ 9: 9](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_RX_INT[BAD_TERM]. */
uint64_t bad_seq : 1; /**< [ 8: 8](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_RX_INT[BAD_SEQ]. */
uint64_t rem_fault : 1; /**< [ 7: 7](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_RX_INT[REM_FAULT]. */
uint64_t loc_fault : 1; /**< [ 6: 6](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_RX_INT[LOC_FAULT]. */
uint64_t rsverr : 1; /**< [ 5: 5](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_RX_INT[RSVERR]. */
uint64_t pcterr : 1; /**< [ 4: 4](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_RX_INT[PCTERR]. */
uint64_t skperr : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_RX_INT[SKPERR]. */
uint64_t rcverr : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_RX_INT[RCVERR]. */
uint64_t fcserr : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_RX_INT[FCSERR]. */
uint64_t jabber : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_RX_INT[JABBER]. */
#else /* Word 0 - Little Endian */
uint64_t jabber : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_RX_INT[JABBER]. */
uint64_t fcserr : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_RX_INT[FCSERR]. */
uint64_t rcverr : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_RX_INT[RCVERR]. */
uint64_t skperr : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_RX_INT[SKPERR]. */
uint64_t pcterr : 1; /**< [ 4: 4](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_RX_INT[PCTERR]. */
uint64_t rsverr : 1; /**< [ 5: 5](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_RX_INT[RSVERR]. */
uint64_t loc_fault : 1; /**< [ 6: 6](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_RX_INT[LOC_FAULT]. */
uint64_t rem_fault : 1; /**< [ 7: 7](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_RX_INT[REM_FAULT]. */
uint64_t bad_seq : 1; /**< [ 8: 8](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_RX_INT[BAD_SEQ]. */
uint64_t bad_term : 1; /**< [ 9: 9](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_RX_INT[BAD_TERM]. */
uint64_t hg2fld : 1; /**< [ 10: 10](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_RX_INT[HG2FLD]. */
uint64_t hg2cc : 1; /**< [ 11: 11](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_RX_INT[HG2CC]. */
uint64_t reserved_12_63 : 52;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_smux_rx_int_w1s bdk_bgxx_smux_rx_int_w1s_t;
static inline uint64_t BDK_BGXX_SMUX_RX_INT_W1S(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_RX_INT_W1S(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020008ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020008ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020008ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_RX_INT_W1S", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_RX_INT_W1S(a,b) bdk_bgxx_smux_rx_int_w1s_t
#define bustype_BDK_BGXX_SMUX_RX_INT_W1S(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_RX_INT_W1S(a,b) "BGXX_SMUX_RX_INT_W1S"
#define device_bar_BDK_BGXX_SMUX_RX_INT_W1S(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_RX_INT_W1S(a,b) (a)
#define arguments_BDK_BGXX_SMUX_RX_INT_W1S(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_rx_jabber
*
* BGX SMU Maximum Packet-Size Registers
* This register specifies the maximum size for packets, beyond which the SMU truncates. In
* XAUI/RXAUI mode, port 0 is used for checking.
*
* Internal:
* The packet that will be sent to the packet input logic will have an
* additionl 8 bytes if BGX()_SMU()_RX_FRM_CTL[PRE_CHK] is set and
* BGX()_SMU()_RX_FRM_CTL[PRE_STRP] is clear. The max packet that will be sent is
* defined as:
*
* _ max_sized_packet = BGX()_SMU()_RX_JABBER[CNT]+((BGX()_SMU()_RX_FRM_CTL[PRE_CHK] &
* !BGX()_SMU()_RX_FRM_CTL[PRE_STRP])*8)
*/
union bdk_bgxx_smux_rx_jabber
{
uint64_t u;
struct bdk_bgxx_smux_rx_jabber_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t cnt : 16; /**< [ 15: 0](R/W) Byte count for jabber check. Failing packets set the JABBER interrupt and are optionally
sent with opcode = JABBER. BGX truncates the packet to CNT+1 to CNT+8 bytes.
CNT must be 8-byte aligned such that CNT\<2:0\> = 000. */
#else /* Word 0 - Little Endian */
uint64_t cnt : 16; /**< [ 15: 0](R/W) Byte count for jabber check. Failing packets set the JABBER interrupt and are optionally
sent with opcode = JABBER. BGX truncates the packet to CNT+1 to CNT+8 bytes.
CNT must be 8-byte aligned such that CNT\<2:0\> = 000. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_smux_rx_jabber_s cn; */
};
typedef union bdk_bgxx_smux_rx_jabber bdk_bgxx_smux_rx_jabber_t;
static inline uint64_t BDK_BGXX_SMUX_RX_JABBER(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_RX_JABBER(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020030ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020030ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020030ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_RX_JABBER", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_RX_JABBER(a,b) bdk_bgxx_smux_rx_jabber_t
#define bustype_BDK_BGXX_SMUX_RX_JABBER(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_RX_JABBER(a,b) "BGXX_SMUX_RX_JABBER"
#define device_bar_BDK_BGXX_SMUX_RX_JABBER(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_RX_JABBER(a,b) (a)
#define arguments_BDK_BGXX_SMUX_RX_JABBER(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_rx_udd_skp
*
* BGX SMU User-Defined Data Skip Registers
* Internal:
* (1) The skip bytes are part of the packet and will be sent down the NCB
* packet interface and will be handled by NIC.
* (2) The system can determine if the UDD bytes are included in the FCS check
* by using the FCSSEL field if the FCS check is enabled.
*
* (3) Assume that the preamble/sfd is always at the start of the frame even
* before UDD bytes. In most cases, there will be no preamble in these
* cases since it will be packet interface in direct communication to
* another packet interface (MAC to MAC) without a PHY involved.
*
* (4) We can still do address filtering and control packet filtering if the
* user desires.
*
* (6) In all cases, the UDD bytes will be sent down the packet interface as
* part of the packet. The UDD bytes are never stripped from the actual
* packet.
*/
union bdk_bgxx_smux_rx_udd_skp
{
uint64_t u;
struct bdk_bgxx_smux_rx_udd_skp_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_9_63 : 55;
uint64_t fcssel : 1; /**< [ 8: 8](R/W) Include the skip bytes in the FCS calculation.
0 = All skip bytes are included in FCS.
1 = The skip bytes are not included in FCS.
When BGX()_SMU()_TX_CTL[HG_EN] is set, this field must be 0.
The skip bytes are part of the packet and are sent through the NCB packet interface and
are handled by NIC. The system can determine if the UDD bytes are included in the FCS
check by using the FCSSEL field, if the FCS check is enabled. */
uint64_t reserved_7 : 1;
uint64_t len : 7; /**< [ 6: 0](R/W) Amount of user-defined data before the start of the L2C data, in bytes.
Setting to 0 means L2C comes first; maximum value is 64.
LEN must be 0x0 in half-duplex operation.
When BGX()_SMU()_TX_CTL[HG_EN] is set, this field must be set to 12 or 16
(depending on HiGig header size) to account for the HiGig header.
LEN = 12 selects HiGig/HiGig+; LEN = 16 selects HiGig2. */
#else /* Word 0 - Little Endian */
uint64_t len : 7; /**< [ 6: 0](R/W) Amount of user-defined data before the start of the L2C data, in bytes.
Setting to 0 means L2C comes first; maximum value is 64.
LEN must be 0x0 in half-duplex operation.
When BGX()_SMU()_TX_CTL[HG_EN] is set, this field must be set to 12 or 16
(depending on HiGig header size) to account for the HiGig header.
LEN = 12 selects HiGig/HiGig+; LEN = 16 selects HiGig2. */
uint64_t reserved_7 : 1;
uint64_t fcssel : 1; /**< [ 8: 8](R/W) Include the skip bytes in the FCS calculation.
0 = All skip bytes are included in FCS.
1 = The skip bytes are not included in FCS.
When BGX()_SMU()_TX_CTL[HG_EN] is set, this field must be 0.
The skip bytes are part of the packet and are sent through the NCB packet interface and
are handled by NIC. The system can determine if the UDD bytes are included in the FCS
check by using the FCSSEL field, if the FCS check is enabled. */
uint64_t reserved_9_63 : 55;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_smux_rx_udd_skp_s cn; */
};
typedef union bdk_bgxx_smux_rx_udd_skp bdk_bgxx_smux_rx_udd_skp_t;
static inline uint64_t BDK_BGXX_SMUX_RX_UDD_SKP(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_RX_UDD_SKP(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020040ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020040ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020040ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_RX_UDD_SKP", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_RX_UDD_SKP(a,b) bdk_bgxx_smux_rx_udd_skp_t
#define bustype_BDK_BGXX_SMUX_RX_UDD_SKP(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_RX_UDD_SKP(a,b) "BGXX_SMUX_RX_UDD_SKP"
#define device_bar_BDK_BGXX_SMUX_RX_UDD_SKP(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_RX_UDD_SKP(a,b) (a)
#define arguments_BDK_BGXX_SMUX_RX_UDD_SKP(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_smac
*
* BGX SMU SMAC Registers
*/
union bdk_bgxx_smux_smac
{
uint64_t u;
struct bdk_bgxx_smux_smac_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t smac : 48; /**< [ 47: 0](R/W) The SMAC field is used for generating and accepting control PAUSE packets. */
#else /* Word 0 - Little Endian */
uint64_t smac : 48; /**< [ 47: 0](R/W) The SMAC field is used for generating and accepting control PAUSE packets. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_smux_smac_s cn; */
};
typedef union bdk_bgxx_smux_smac bdk_bgxx_smux_smac_t;
static inline uint64_t BDK_BGXX_SMUX_SMAC(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_SMAC(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020108ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020108ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020108ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_SMAC", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_SMAC(a,b) bdk_bgxx_smux_smac_t
#define bustype_BDK_BGXX_SMUX_SMAC(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_SMAC(a,b) "BGXX_SMUX_SMAC"
#define device_bar_BDK_BGXX_SMUX_SMAC(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_SMAC(a,b) (a)
#define arguments_BDK_BGXX_SMUX_SMAC(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_tx_append
*
* BGX SMU TX Append Control Registers
* For more details on the interactions between FCS and PAD, see also the description of
* BGX()_SMU()_TX_MIN_PKT[MIN_SIZE].
*/
union bdk_bgxx_smux_tx_append
{
uint64_t u;
struct bdk_bgxx_smux_tx_append_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_4_63 : 60;
uint64_t fcs_c : 1; /**< [ 3: 3](R/W) Append the Ethernet FCS on each PAUSE packet. PAUSE packets are normally padded to 60
bytes. If BGX()_SMU()_TX_MIN_PKT[MIN_SIZE] exceeds 59, then [FCS_C] is not used. */
uint64_t fcs_d : 1; /**< [ 2: 2](R/W) Append the Ethernet FCS on each data packet. */
uint64_t pad : 1; /**< [ 1: 1](R/W) Append PAD bytes such that minimum-sized packet is transmitted. */
uint64_t preamble : 1; /**< [ 0: 0](R/W) Prepend the Ethernet preamble on each transfer. When BGX()_SMU()_TX_CTL[HG_EN] is
set, PREAMBLE must be 0. */
#else /* Word 0 - Little Endian */
uint64_t preamble : 1; /**< [ 0: 0](R/W) Prepend the Ethernet preamble on each transfer. When BGX()_SMU()_TX_CTL[HG_EN] is
set, PREAMBLE must be 0. */
uint64_t pad : 1; /**< [ 1: 1](R/W) Append PAD bytes such that minimum-sized packet is transmitted. */
uint64_t fcs_d : 1; /**< [ 2: 2](R/W) Append the Ethernet FCS on each data packet. */
uint64_t fcs_c : 1; /**< [ 3: 3](R/W) Append the Ethernet FCS on each PAUSE packet. PAUSE packets are normally padded to 60
bytes. If BGX()_SMU()_TX_MIN_PKT[MIN_SIZE] exceeds 59, then [FCS_C] is not used. */
uint64_t reserved_4_63 : 60;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_smux_tx_append_s cn; */
};
typedef union bdk_bgxx_smux_tx_append bdk_bgxx_smux_tx_append_t;
static inline uint64_t BDK_BGXX_SMUX_TX_APPEND(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_TX_APPEND(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020100ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020100ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020100ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_TX_APPEND", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_TX_APPEND(a,b) bdk_bgxx_smux_tx_append_t
#define bustype_BDK_BGXX_SMUX_TX_APPEND(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_TX_APPEND(a,b) "BGXX_SMUX_TX_APPEND"
#define device_bar_BDK_BGXX_SMUX_TX_APPEND(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_TX_APPEND(a,b) (a)
#define arguments_BDK_BGXX_SMUX_TX_APPEND(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_tx_ctl
*
* BGX SMU Transmit Control Registers
*/
union bdk_bgxx_smux_tx_ctl
{
uint64_t u;
struct bdk_bgxx_smux_tx_ctl_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_31_63 : 33;
uint64_t spu_mrk_cnt : 20; /**< [ 30: 11](R/W) 40GBASE-R transmit marker interval count. Specifies the interval (number of 66-bit BASE-R
blocks) at which the LMAC transmit logic inserts 40GBASE-R alignment markers. An internal
counter in SMU is initialized to this value, counts down for each BASE-R block transmitted
by the LMAC, and wraps back to the initial value from 0. The LMAC transmit logic inserts
alignment markers for lanes 0, 1, 2 and 3, respectively, in the last four BASE-R blocks
before the counter wraps (3, 2, 1, 0). The default value corresponds to an alignment
marker period of 16363 blocks (exclusive) per lane, as specified in 802.3ba-2010. The
default value should always be used for normal operation. */
uint64_t hg_pause_hgi : 2; /**< [ 10: 9](R/W) HGI field for hardware-generated HiGig PAUSE packets. */
uint64_t hg_en : 1; /**< [ 8: 8](R/W) Enable HiGig mode.
When this field is set and BGX()_SMU()_RX_UDD_SKP[LEN] = 12, the interface is in
HiGig/HiGig+ mode and the following must be set:
* BGX()_SMU()_RX_FRM_CTL[PRE_CHK] = 0.
* BGX()_SMU()_RX_UDD_SKP[FCSSEL] = 0.
* BGX()_SMU()_RX_UDD_SKP[LEN] = 12.
* BGX()_SMU()_TX_APPEND[PREAMBLE] = 0.
When this field is set and BGX()_SMU()_RX_UDD_SKP[LEN] = 16, the interface is in
HiGig2 mode and the following must be set:
* BGX()_SMU()_RX_FRM_CTL[PRE_CHK] = 0.
* BGX()_SMU()_RX_UDD_SKP[FCSSEL] = 0.
* BGX()_SMU()_RX_UDD_SKP[LEN] = 16.
* BGX()_SMU()_TX_APPEND[PREAMBLE] = 0.
* BGX()_SMU()_CBFC_CTL[RX_EN] = 0.
* BGX()_SMU()_CBFC_CTL[TX_EN] = 0. */
uint64_t l2p_bp_conv : 1; /**< [ 7: 7](R/W) If set, causes TX to generate 802.3 pause packets when CMR applies logical backpressure
(XOFF), if and only if BGX()_SMU()_CBFC_CTL[TX_EN] is clear and
BGX()_SMU()_HG2_CONTROL[HG2TX_EN] is clear. */
uint64_t ls_byp : 1; /**< [ 6: 6](R/W) Bypass the link status, as determined by the XGMII receiver, and set the link status of
the transmitter to LS. */
uint64_t ls : 2; /**< [ 5: 4](R/W) Link status.
0 = Link OK; link runs normally. RS passes MAC data to PCS.
1 = Local fault. RS layer sends continuous remote fault sequences.
2 = Remote fault. RS layer sends continuous idle sequences.
3 = Link drain. RS layer drops full packets to allow BGX and PKO to drain their FIFOs. */
uint64_t reserved_3 : 1;
uint64_t x4a_dis : 1; /**< [ 2: 2](R/W) Disable 4-byte SOP align (effectively force 8-byte SOP align) for all 10G variants
(XAUI, RXAUI, 10G). */
uint64_t uni_en : 1; /**< [ 1: 1](R/W) Enable unidirectional mode (IEEE Clause 66). */
uint64_t dic_en : 1; /**< [ 0: 0](R/W) Enable the deficit idle counter for IFG averaging. */
#else /* Word 0 - Little Endian */
uint64_t dic_en : 1; /**< [ 0: 0](R/W) Enable the deficit idle counter for IFG averaging. */
uint64_t uni_en : 1; /**< [ 1: 1](R/W) Enable unidirectional mode (IEEE Clause 66). */
uint64_t x4a_dis : 1; /**< [ 2: 2](R/W) Disable 4-byte SOP align (effectively force 8-byte SOP align) for all 10G variants
(XAUI, RXAUI, 10G). */
uint64_t reserved_3 : 1;
uint64_t ls : 2; /**< [ 5: 4](R/W) Link status.
0 = Link OK; link runs normally. RS passes MAC data to PCS.
1 = Local fault. RS layer sends continuous remote fault sequences.
2 = Remote fault. RS layer sends continuous idle sequences.
3 = Link drain. RS layer drops full packets to allow BGX and PKO to drain their FIFOs. */
uint64_t ls_byp : 1; /**< [ 6: 6](R/W) Bypass the link status, as determined by the XGMII receiver, and set the link status of
the transmitter to LS. */
uint64_t l2p_bp_conv : 1; /**< [ 7: 7](R/W) If set, causes TX to generate 802.3 pause packets when CMR applies logical backpressure
(XOFF), if and only if BGX()_SMU()_CBFC_CTL[TX_EN] is clear and
BGX()_SMU()_HG2_CONTROL[HG2TX_EN] is clear. */
uint64_t hg_en : 1; /**< [ 8: 8](R/W) Enable HiGig mode.
When this field is set and BGX()_SMU()_RX_UDD_SKP[LEN] = 12, the interface is in
HiGig/HiGig+ mode and the following must be set:
* BGX()_SMU()_RX_FRM_CTL[PRE_CHK] = 0.
* BGX()_SMU()_RX_UDD_SKP[FCSSEL] = 0.
* BGX()_SMU()_RX_UDD_SKP[LEN] = 12.
* BGX()_SMU()_TX_APPEND[PREAMBLE] = 0.
When this field is set and BGX()_SMU()_RX_UDD_SKP[LEN] = 16, the interface is in
HiGig2 mode and the following must be set:
* BGX()_SMU()_RX_FRM_CTL[PRE_CHK] = 0.
* BGX()_SMU()_RX_UDD_SKP[FCSSEL] = 0.
* BGX()_SMU()_RX_UDD_SKP[LEN] = 16.
* BGX()_SMU()_TX_APPEND[PREAMBLE] = 0.
* BGX()_SMU()_CBFC_CTL[RX_EN] = 0.
* BGX()_SMU()_CBFC_CTL[TX_EN] = 0. */
uint64_t hg_pause_hgi : 2; /**< [ 10: 9](R/W) HGI field for hardware-generated HiGig PAUSE packets. */
uint64_t spu_mrk_cnt : 20; /**< [ 30: 11](R/W) 40GBASE-R transmit marker interval count. Specifies the interval (number of 66-bit BASE-R
blocks) at which the LMAC transmit logic inserts 40GBASE-R alignment markers. An internal
counter in SMU is initialized to this value, counts down for each BASE-R block transmitted
by the LMAC, and wraps back to the initial value from 0. The LMAC transmit logic inserts
alignment markers for lanes 0, 1, 2 and 3, respectively, in the last four BASE-R blocks
before the counter wraps (3, 2, 1, 0). The default value corresponds to an alignment
marker period of 16363 blocks (exclusive) per lane, as specified in 802.3ba-2010. The
default value should always be used for normal operation. */
uint64_t reserved_31_63 : 33;
#endif /* Word 0 - End */
} s;
struct bdk_bgxx_smux_tx_ctl_cn88xxp1
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_31_63 : 33;
uint64_t spu_mrk_cnt : 20; /**< [ 30: 11](R/W) 40GBASE-R transmit marker interval count. Specifies the interval (number of 66-bit BASE-R
blocks) at which the LMAC transmit logic inserts 40GBASE-R alignment markers. An internal
counter in SMU is initialized to this value, counts down for each BASE-R block transmitted
by the LMAC, and wraps back to the initial value from 0. The LMAC transmit logic inserts
alignment markers for lanes 0, 1, 2 and 3, respectively, in the last four BASE-R blocks
before the counter wraps (3, 2, 1, 0). The default value corresponds to an alignment
marker period of 16363 blocks (exclusive) per lane, as specified in 802.3ba-2010. The
default value should always be used for normal operation. */
uint64_t hg_pause_hgi : 2; /**< [ 10: 9](R/W) HGI field for hardware-generated HiGig PAUSE packets. */
uint64_t hg_en : 1; /**< [ 8: 8](R/W) Enable HiGig mode.
When this field is set and BGX()_SMU()_RX_UDD_SKP[LEN] = 12, the interface is in
HiGig/HiGig+ mode and the following must be set:
* BGX()_SMU()_RX_FRM_CTL[PRE_CHK] = 0.
* BGX()_SMU()_RX_UDD_SKP[FCSSEL] = 0.
* BGX()_SMU()_RX_UDD_SKP[LEN] = 12.
* BGX()_SMU()_TX_APPEND[PREAMBLE] = 0.
When this field is set and BGX()_SMU()_RX_UDD_SKP[LEN] = 16, the interface is in
HiGig2 mode and the following must be set:
* BGX()_SMU()_RX_FRM_CTL[PRE_CHK] = 0.
* BGX()_SMU()_RX_UDD_SKP[FCSSEL] = 0.
* BGX()_SMU()_RX_UDD_SKP[LEN] = 16.
* BGX()_SMU()_TX_APPEND[PREAMBLE] = 0.
* BGX()_SMU()_CBFC_CTL[RX_EN] = 0.
* BGX()_SMU()_CBFC_CTL[TX_EN] = 0. */
uint64_t l2p_bp_conv : 1; /**< [ 7: 7](R/W) If set, causes TX to generate 802.3 pause packets when CMR applies logical backpressure
(XOFF), if and only if BGX()_SMU()_CBFC_CTL[TX_EN] is clear and
BGX()_SMU()_HG2_CONTROL[HG2TX_EN] is clear. */
uint64_t ls_byp : 1; /**< [ 6: 6](R/W) Bypass the link status, as determined by the XGMII receiver, and set the link status of
the transmitter to LS. */
uint64_t ls : 2; /**< [ 5: 4](R/W) Link status.
0 = Link OK; link runs normally. RS passes MAC data to PCS.
1 = Local fault. RS layer sends continuous remote fault sequences.
2 = Remote fault. RS layer sends continuous idle sequences.
3 = Link drain. RS layer drops full packets to allow BGX and TNS/NIC to drain their FIFOs. */
uint64_t reserved_3 : 1;
uint64_t x4a_dis : 1; /**< [ 2: 2](RAZ) Reserved. */
uint64_t uni_en : 1; /**< [ 1: 1](R/W) Enable unidirectional mode (IEEE Clause 66). */
uint64_t dic_en : 1; /**< [ 0: 0](R/W) Enable the deficit idle counter for IFG averaging. */
#else /* Word 0 - Little Endian */
uint64_t dic_en : 1; /**< [ 0: 0](R/W) Enable the deficit idle counter for IFG averaging. */
uint64_t uni_en : 1; /**< [ 1: 1](R/W) Enable unidirectional mode (IEEE Clause 66). */
uint64_t x4a_dis : 1; /**< [ 2: 2](RAZ) Reserved. */
uint64_t reserved_3 : 1;
uint64_t ls : 2; /**< [ 5: 4](R/W) Link status.
0 = Link OK; link runs normally. RS passes MAC data to PCS.
1 = Local fault. RS layer sends continuous remote fault sequences.
2 = Remote fault. RS layer sends continuous idle sequences.
3 = Link drain. RS layer drops full packets to allow BGX and TNS/NIC to drain their FIFOs. */
uint64_t ls_byp : 1; /**< [ 6: 6](R/W) Bypass the link status, as determined by the XGMII receiver, and set the link status of
the transmitter to LS. */
uint64_t l2p_bp_conv : 1; /**< [ 7: 7](R/W) If set, causes TX to generate 802.3 pause packets when CMR applies logical backpressure
(XOFF), if and only if BGX()_SMU()_CBFC_CTL[TX_EN] is clear and
BGX()_SMU()_HG2_CONTROL[HG2TX_EN] is clear. */
uint64_t hg_en : 1; /**< [ 8: 8](R/W) Enable HiGig mode.
When this field is set and BGX()_SMU()_RX_UDD_SKP[LEN] = 12, the interface is in
HiGig/HiGig+ mode and the following must be set:
* BGX()_SMU()_RX_FRM_CTL[PRE_CHK] = 0.
* BGX()_SMU()_RX_UDD_SKP[FCSSEL] = 0.
* BGX()_SMU()_RX_UDD_SKP[LEN] = 12.
* BGX()_SMU()_TX_APPEND[PREAMBLE] = 0.
When this field is set and BGX()_SMU()_RX_UDD_SKP[LEN] = 16, the interface is in
HiGig2 mode and the following must be set:
* BGX()_SMU()_RX_FRM_CTL[PRE_CHK] = 0.
* BGX()_SMU()_RX_UDD_SKP[FCSSEL] = 0.
* BGX()_SMU()_RX_UDD_SKP[LEN] = 16.
* BGX()_SMU()_TX_APPEND[PREAMBLE] = 0.
* BGX()_SMU()_CBFC_CTL[RX_EN] = 0.
* BGX()_SMU()_CBFC_CTL[TX_EN] = 0. */
uint64_t hg_pause_hgi : 2; /**< [ 10: 9](R/W) HGI field for hardware-generated HiGig PAUSE packets. */
uint64_t spu_mrk_cnt : 20; /**< [ 30: 11](R/W) 40GBASE-R transmit marker interval count. Specifies the interval (number of 66-bit BASE-R
blocks) at which the LMAC transmit logic inserts 40GBASE-R alignment markers. An internal
counter in SMU is initialized to this value, counts down for each BASE-R block transmitted
by the LMAC, and wraps back to the initial value from 0. The LMAC transmit logic inserts
alignment markers for lanes 0, 1, 2 and 3, respectively, in the last four BASE-R blocks
before the counter wraps (3, 2, 1, 0). The default value corresponds to an alignment
marker period of 16363 blocks (exclusive) per lane, as specified in 802.3ba-2010. The
default value should always be used for normal operation. */
uint64_t reserved_31_63 : 33;
#endif /* Word 0 - End */
} cn88xxp1;
/* struct bdk_bgxx_smux_tx_ctl_s cn81xx; */
/* struct bdk_bgxx_smux_tx_ctl_s cn83xx; */
struct bdk_bgxx_smux_tx_ctl_cn88xxp2
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_31_63 : 33;
uint64_t spu_mrk_cnt : 20; /**< [ 30: 11](R/W) 40GBASE-R transmit marker interval count. Specifies the interval (number of 66-bit BASE-R
blocks) at which the LMAC transmit logic inserts 40GBASE-R alignment markers. An internal
counter in SMU is initialized to this value, counts down for each BASE-R block transmitted
by the LMAC, and wraps back to the initial value from 0. The LMAC transmit logic inserts
alignment markers for lanes 0, 1, 2 and 3, respectively, in the last four BASE-R blocks
before the counter wraps (3, 2, 1, 0). The default value corresponds to an alignment
marker period of 16363 blocks (exclusive) per lane, as specified in 802.3ba-2010. The
default value should always be used for normal operation. */
uint64_t hg_pause_hgi : 2; /**< [ 10: 9](R/W) HGI field for hardware-generated HiGig PAUSE packets. */
uint64_t hg_en : 1; /**< [ 8: 8](R/W) Enable HiGig mode.
When this field is set and BGX()_SMU()_RX_UDD_SKP[LEN] = 12, the interface is in
HiGig/HiGig+ mode and the following must be set:
* BGX()_SMU()_RX_FRM_CTL[PRE_CHK] = 0.
* BGX()_SMU()_RX_UDD_SKP[FCSSEL] = 0.
* BGX()_SMU()_RX_UDD_SKP[LEN] = 12.
* BGX()_SMU()_TX_APPEND[PREAMBLE] = 0.
When this field is set and BGX()_SMU()_RX_UDD_SKP[LEN] = 16, the interface is in
HiGig2 mode and the following must be set:
* BGX()_SMU()_RX_FRM_CTL[PRE_CHK] = 0.
* BGX()_SMU()_RX_UDD_SKP[FCSSEL] = 0.
* BGX()_SMU()_RX_UDD_SKP[LEN] = 16.
* BGX()_SMU()_TX_APPEND[PREAMBLE] = 0.
* BGX()_SMU()_CBFC_CTL[RX_EN] = 0.
* BGX()_SMU()_CBFC_CTL[TX_EN] = 0. */
uint64_t l2p_bp_conv : 1; /**< [ 7: 7](R/W) If set, causes TX to generate 802.3 pause packets when CMR applies logical backpressure
(XOFF), if and only if BGX()_SMU()_CBFC_CTL[TX_EN] is clear and
BGX()_SMU()_HG2_CONTROL[HG2TX_EN] is clear. */
uint64_t ls_byp : 1; /**< [ 6: 6](R/W) Bypass the link status, as determined by the XGMII receiver, and set the link status of
the transmitter to LS. */
uint64_t ls : 2; /**< [ 5: 4](R/W) Link status.
0 = Link OK; link runs normally. RS passes MAC data to PCS.
1 = Local fault. RS layer sends continuous remote fault sequences.
2 = Remote fault. RS layer sends continuous idle sequences.
3 = Link drain. RS layer drops full packets to allow BGX and TNS/NIC to drain their FIFOs. */
uint64_t reserved_3 : 1;
uint64_t x4a_dis : 1; /**< [ 2: 2](R/W) Disable 4-byte SOP align (effectively force 8-byte SOP align) for all 10G variants
(XAUI, RXAUI, 10G). */
uint64_t uni_en : 1; /**< [ 1: 1](R/W) Enable unidirectional mode (IEEE Clause 66). */
uint64_t dic_en : 1; /**< [ 0: 0](R/W) Enable the deficit idle counter for IFG averaging. */
#else /* Word 0 - Little Endian */
uint64_t dic_en : 1; /**< [ 0: 0](R/W) Enable the deficit idle counter for IFG averaging. */
uint64_t uni_en : 1; /**< [ 1: 1](R/W) Enable unidirectional mode (IEEE Clause 66). */
uint64_t x4a_dis : 1; /**< [ 2: 2](R/W) Disable 4-byte SOP align (effectively force 8-byte SOP align) for all 10G variants
(XAUI, RXAUI, 10G). */
uint64_t reserved_3 : 1;
uint64_t ls : 2; /**< [ 5: 4](R/W) Link status.
0 = Link OK; link runs normally. RS passes MAC data to PCS.
1 = Local fault. RS layer sends continuous remote fault sequences.
2 = Remote fault. RS layer sends continuous idle sequences.
3 = Link drain. RS layer drops full packets to allow BGX and TNS/NIC to drain their FIFOs. */
uint64_t ls_byp : 1; /**< [ 6: 6](R/W) Bypass the link status, as determined by the XGMII receiver, and set the link status of
the transmitter to LS. */
uint64_t l2p_bp_conv : 1; /**< [ 7: 7](R/W) If set, causes TX to generate 802.3 pause packets when CMR applies logical backpressure
(XOFF), if and only if BGX()_SMU()_CBFC_CTL[TX_EN] is clear and
BGX()_SMU()_HG2_CONTROL[HG2TX_EN] is clear. */
uint64_t hg_en : 1; /**< [ 8: 8](R/W) Enable HiGig mode.
When this field is set and BGX()_SMU()_RX_UDD_SKP[LEN] = 12, the interface is in
HiGig/HiGig+ mode and the following must be set:
* BGX()_SMU()_RX_FRM_CTL[PRE_CHK] = 0.
* BGX()_SMU()_RX_UDD_SKP[FCSSEL] = 0.
* BGX()_SMU()_RX_UDD_SKP[LEN] = 12.
* BGX()_SMU()_TX_APPEND[PREAMBLE] = 0.
When this field is set and BGX()_SMU()_RX_UDD_SKP[LEN] = 16, the interface is in
HiGig2 mode and the following must be set:
* BGX()_SMU()_RX_FRM_CTL[PRE_CHK] = 0.
* BGX()_SMU()_RX_UDD_SKP[FCSSEL] = 0.
* BGX()_SMU()_RX_UDD_SKP[LEN] = 16.
* BGX()_SMU()_TX_APPEND[PREAMBLE] = 0.
* BGX()_SMU()_CBFC_CTL[RX_EN] = 0.
* BGX()_SMU()_CBFC_CTL[TX_EN] = 0. */
uint64_t hg_pause_hgi : 2; /**< [ 10: 9](R/W) HGI field for hardware-generated HiGig PAUSE packets. */
uint64_t spu_mrk_cnt : 20; /**< [ 30: 11](R/W) 40GBASE-R transmit marker interval count. Specifies the interval (number of 66-bit BASE-R
blocks) at which the LMAC transmit logic inserts 40GBASE-R alignment markers. An internal
counter in SMU is initialized to this value, counts down for each BASE-R block transmitted
by the LMAC, and wraps back to the initial value from 0. The LMAC transmit logic inserts
alignment markers for lanes 0, 1, 2 and 3, respectively, in the last four BASE-R blocks
before the counter wraps (3, 2, 1, 0). The default value corresponds to an alignment
marker period of 16363 blocks (exclusive) per lane, as specified in 802.3ba-2010. The
default value should always be used for normal operation. */
uint64_t reserved_31_63 : 33;
#endif /* Word 0 - End */
} cn88xxp2;
};
typedef union bdk_bgxx_smux_tx_ctl bdk_bgxx_smux_tx_ctl_t;
static inline uint64_t BDK_BGXX_SMUX_TX_CTL(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_TX_CTL(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020178ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020178ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020178ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_TX_CTL", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_TX_CTL(a,b) bdk_bgxx_smux_tx_ctl_t
#define bustype_BDK_BGXX_SMUX_TX_CTL(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_TX_CTL(a,b) "BGXX_SMUX_TX_CTL"
#define device_bar_BDK_BGXX_SMUX_TX_CTL(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_TX_CTL(a,b) (a)
#define arguments_BDK_BGXX_SMUX_TX_CTL(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_tx_ifg
*
* BGX SMU TX Interframe-Gap Cycles Registers
* Programming IFG1 and IFG2:
* * For XAUI/RXAUI/10Gbs/40Gbs systems that require IEEE 802.3 compatibility, the IFG1+IFG2 sum
* must be 12.
* * In loopback mode, the IFG1+IFG2 of local and remote parties must match exactly; otherwise
* one of the two sides' loopback FIFO will overrun: BGX()_SMU()_TX_INT[LB_OVRFLW].
*/
union bdk_bgxx_smux_tx_ifg
{
uint64_t u;
struct bdk_bgxx_smux_tx_ifg_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_8_63 : 56;
uint64_t ifg2 : 4; /**< [ 7: 4](R/W) 1/2 of the interframe gap timing (in IFG2*8 bits). */
uint64_t ifg1 : 4; /**< [ 3: 0](R/W) 1/2 of the interframe gap timing (in IFG1*8 bits). */
#else /* Word 0 - Little Endian */
uint64_t ifg1 : 4; /**< [ 3: 0](R/W) 1/2 of the interframe gap timing (in IFG1*8 bits). */
uint64_t ifg2 : 4; /**< [ 7: 4](R/W) 1/2 of the interframe gap timing (in IFG2*8 bits). */
uint64_t reserved_8_63 : 56;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_smux_tx_ifg_s cn; */
};
typedef union bdk_bgxx_smux_tx_ifg bdk_bgxx_smux_tx_ifg_t;
static inline uint64_t BDK_BGXX_SMUX_TX_IFG(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_TX_IFG(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020160ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020160ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020160ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_TX_IFG", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_TX_IFG(a,b) bdk_bgxx_smux_tx_ifg_t
#define bustype_BDK_BGXX_SMUX_TX_IFG(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_TX_IFG(a,b) "BGXX_SMUX_TX_IFG"
#define device_bar_BDK_BGXX_SMUX_TX_IFG(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_TX_IFG(a,b) (a)
#define arguments_BDK_BGXX_SMUX_TX_IFG(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_tx_int
*
* BGX SMU TX Interrupt Registers
*/
union bdk_bgxx_smux_tx_int
{
uint64_t u;
struct bdk_bgxx_smux_tx_int_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_5_63 : 59;
uint64_t lb_ovrflw : 1; /**< [ 4: 4](R/W1C/H) TX loopback overflow. */
uint64_t lb_undflw : 1; /**< [ 3: 3](R/W1C/H) TX loopback underflow. */
uint64_t fake_commit : 1; /**< [ 2: 2](R/W1C/H) TX SMU started a packet with PTP on SOP and has not seen a commit for it from TX SPU after
256 cycles so it faked a commit to CMR. */
uint64_t xchange : 1; /**< [ 1: 1](R/W1C/H) Link status changed. This denotes a change to BGX()_SMU()_RX_CTL[STATUS]. */
uint64_t undflw : 1; /**< [ 0: 0](R/W1C/H) TX underflow. */
#else /* Word 0 - Little Endian */
uint64_t undflw : 1; /**< [ 0: 0](R/W1C/H) TX underflow. */
uint64_t xchange : 1; /**< [ 1: 1](R/W1C/H) Link status changed. This denotes a change to BGX()_SMU()_RX_CTL[STATUS]. */
uint64_t fake_commit : 1; /**< [ 2: 2](R/W1C/H) TX SMU started a packet with PTP on SOP and has not seen a commit for it from TX SPU after
256 cycles so it faked a commit to CMR. */
uint64_t lb_undflw : 1; /**< [ 3: 3](R/W1C/H) TX loopback underflow. */
uint64_t lb_ovrflw : 1; /**< [ 4: 4](R/W1C/H) TX loopback overflow. */
uint64_t reserved_5_63 : 59;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_smux_tx_int_s cn; */
};
typedef union bdk_bgxx_smux_tx_int bdk_bgxx_smux_tx_int_t;
static inline uint64_t BDK_BGXX_SMUX_TX_INT(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_TX_INT(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020140ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020140ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020140ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_TX_INT", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_TX_INT(a,b) bdk_bgxx_smux_tx_int_t
#define bustype_BDK_BGXX_SMUX_TX_INT(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_TX_INT(a,b) "BGXX_SMUX_TX_INT"
#define device_bar_BDK_BGXX_SMUX_TX_INT(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_TX_INT(a,b) (a)
#define arguments_BDK_BGXX_SMUX_TX_INT(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_tx_int_ena_w1c
*
* BGX SMU TX Interrupt Enable Clear Registers
* This register clears interrupt enable bits.
*/
union bdk_bgxx_smux_tx_int_ena_w1c
{
uint64_t u;
struct bdk_bgxx_smux_tx_int_ena_w1c_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_5_63 : 59;
uint64_t lb_ovrflw : 1; /**< [ 4: 4](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_TX_INT[LB_OVRFLW]. */
uint64_t lb_undflw : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_TX_INT[LB_UNDFLW]. */
uint64_t fake_commit : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_TX_INT[FAKE_COMMIT]. */
uint64_t xchange : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_TX_INT[XCHANGE]. */
uint64_t undflw : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_TX_INT[UNDFLW]. */
#else /* Word 0 - Little Endian */
uint64_t undflw : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_TX_INT[UNDFLW]. */
uint64_t xchange : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_TX_INT[XCHANGE]. */
uint64_t fake_commit : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_TX_INT[FAKE_COMMIT]. */
uint64_t lb_undflw : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_TX_INT[LB_UNDFLW]. */
uint64_t lb_ovrflw : 1; /**< [ 4: 4](R/W1C/H) Reads or clears enable for BGX(0..1)_SMU(0..3)_TX_INT[LB_OVRFLW]. */
uint64_t reserved_5_63 : 59;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_smux_tx_int_ena_w1c_s cn81xx; */
/* struct bdk_bgxx_smux_tx_int_ena_w1c_s cn88xx; */
struct bdk_bgxx_smux_tx_int_ena_w1c_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_5_63 : 59;
uint64_t lb_ovrflw : 1; /**< [ 4: 4](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_TX_INT[LB_OVRFLW]. */
uint64_t lb_undflw : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_TX_INT[LB_UNDFLW]. */
uint64_t fake_commit : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_TX_INT[FAKE_COMMIT]. */
uint64_t xchange : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_TX_INT[XCHANGE]. */
uint64_t undflw : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_TX_INT[UNDFLW]. */
#else /* Word 0 - Little Endian */
uint64_t undflw : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_TX_INT[UNDFLW]. */
uint64_t xchange : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_TX_INT[XCHANGE]. */
uint64_t fake_commit : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_TX_INT[FAKE_COMMIT]. */
uint64_t lb_undflw : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_TX_INT[LB_UNDFLW]. */
uint64_t lb_ovrflw : 1; /**< [ 4: 4](R/W1C/H) Reads or clears enable for BGX(0..3)_SMU(0..3)_TX_INT[LB_OVRFLW]. */
uint64_t reserved_5_63 : 59;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_smux_tx_int_ena_w1c bdk_bgxx_smux_tx_int_ena_w1c_t;
static inline uint64_t BDK_BGXX_SMUX_TX_INT_ENA_W1C(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_TX_INT_ENA_W1C(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020150ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020150ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020150ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_TX_INT_ENA_W1C", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_TX_INT_ENA_W1C(a,b) bdk_bgxx_smux_tx_int_ena_w1c_t
#define bustype_BDK_BGXX_SMUX_TX_INT_ENA_W1C(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_TX_INT_ENA_W1C(a,b) "BGXX_SMUX_TX_INT_ENA_W1C"
#define device_bar_BDK_BGXX_SMUX_TX_INT_ENA_W1C(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_TX_INT_ENA_W1C(a,b) (a)
#define arguments_BDK_BGXX_SMUX_TX_INT_ENA_W1C(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_tx_int_ena_w1s
*
* BGX SMU TX Interrupt Enable Set Registers
* This register sets interrupt enable bits.
*/
union bdk_bgxx_smux_tx_int_ena_w1s
{
uint64_t u;
struct bdk_bgxx_smux_tx_int_ena_w1s_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_5_63 : 59;
uint64_t lb_ovrflw : 1; /**< [ 4: 4](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_TX_INT[LB_OVRFLW]. */
uint64_t lb_undflw : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_TX_INT[LB_UNDFLW]. */
uint64_t fake_commit : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_TX_INT[FAKE_COMMIT]. */
uint64_t xchange : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_TX_INT[XCHANGE]. */
uint64_t undflw : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_TX_INT[UNDFLW]. */
#else /* Word 0 - Little Endian */
uint64_t undflw : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_TX_INT[UNDFLW]. */
uint64_t xchange : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_TX_INT[XCHANGE]. */
uint64_t fake_commit : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_TX_INT[FAKE_COMMIT]. */
uint64_t lb_undflw : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_TX_INT[LB_UNDFLW]. */
uint64_t lb_ovrflw : 1; /**< [ 4: 4](R/W1S/H) Reads or sets enable for BGX(0..1)_SMU(0..3)_TX_INT[LB_OVRFLW]. */
uint64_t reserved_5_63 : 59;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_smux_tx_int_ena_w1s_s cn81xx; */
/* struct bdk_bgxx_smux_tx_int_ena_w1s_s cn88xx; */
struct bdk_bgxx_smux_tx_int_ena_w1s_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_5_63 : 59;
uint64_t lb_ovrflw : 1; /**< [ 4: 4](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_TX_INT[LB_OVRFLW]. */
uint64_t lb_undflw : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_TX_INT[LB_UNDFLW]. */
uint64_t fake_commit : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_TX_INT[FAKE_COMMIT]. */
uint64_t xchange : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_TX_INT[XCHANGE]. */
uint64_t undflw : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_TX_INT[UNDFLW]. */
#else /* Word 0 - Little Endian */
uint64_t undflw : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_TX_INT[UNDFLW]. */
uint64_t xchange : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_TX_INT[XCHANGE]. */
uint64_t fake_commit : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_TX_INT[FAKE_COMMIT]. */
uint64_t lb_undflw : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_TX_INT[LB_UNDFLW]. */
uint64_t lb_ovrflw : 1; /**< [ 4: 4](R/W1S/H) Reads or sets enable for BGX(0..3)_SMU(0..3)_TX_INT[LB_OVRFLW]. */
uint64_t reserved_5_63 : 59;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_smux_tx_int_ena_w1s bdk_bgxx_smux_tx_int_ena_w1s_t;
static inline uint64_t BDK_BGXX_SMUX_TX_INT_ENA_W1S(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_TX_INT_ENA_W1S(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020158ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020158ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020158ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_TX_INT_ENA_W1S", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_TX_INT_ENA_W1S(a,b) bdk_bgxx_smux_tx_int_ena_w1s_t
#define bustype_BDK_BGXX_SMUX_TX_INT_ENA_W1S(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_TX_INT_ENA_W1S(a,b) "BGXX_SMUX_TX_INT_ENA_W1S"
#define device_bar_BDK_BGXX_SMUX_TX_INT_ENA_W1S(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_TX_INT_ENA_W1S(a,b) (a)
#define arguments_BDK_BGXX_SMUX_TX_INT_ENA_W1S(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_tx_int_w1s
*
* BGX SMU TX Interrupt Set Registers
* This register sets interrupt bits.
*/
union bdk_bgxx_smux_tx_int_w1s
{
uint64_t u;
struct bdk_bgxx_smux_tx_int_w1s_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_5_63 : 59;
uint64_t lb_ovrflw : 1; /**< [ 4: 4](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_TX_INT[LB_OVRFLW]. */
uint64_t lb_undflw : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_TX_INT[LB_UNDFLW]. */
uint64_t fake_commit : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_TX_INT[FAKE_COMMIT]. */
uint64_t xchange : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_TX_INT[XCHANGE]. */
uint64_t undflw : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_TX_INT[UNDFLW]. */
#else /* Word 0 - Little Endian */
uint64_t undflw : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_TX_INT[UNDFLW]. */
uint64_t xchange : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_TX_INT[XCHANGE]. */
uint64_t fake_commit : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_TX_INT[FAKE_COMMIT]. */
uint64_t lb_undflw : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_TX_INT[LB_UNDFLW]. */
uint64_t lb_ovrflw : 1; /**< [ 4: 4](R/W1S/H) Reads or sets BGX(0..1)_SMU(0..3)_TX_INT[LB_OVRFLW]. */
uint64_t reserved_5_63 : 59;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_smux_tx_int_w1s_s cn81xx; */
/* struct bdk_bgxx_smux_tx_int_w1s_s cn88xx; */
struct bdk_bgxx_smux_tx_int_w1s_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_5_63 : 59;
uint64_t lb_ovrflw : 1; /**< [ 4: 4](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_TX_INT[LB_OVRFLW]. */
uint64_t lb_undflw : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_TX_INT[LB_UNDFLW]. */
uint64_t fake_commit : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_TX_INT[FAKE_COMMIT]. */
uint64_t xchange : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_TX_INT[XCHANGE]. */
uint64_t undflw : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_TX_INT[UNDFLW]. */
#else /* Word 0 - Little Endian */
uint64_t undflw : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_TX_INT[UNDFLW]. */
uint64_t xchange : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_TX_INT[XCHANGE]. */
uint64_t fake_commit : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_TX_INT[FAKE_COMMIT]. */
uint64_t lb_undflw : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_TX_INT[LB_UNDFLW]. */
uint64_t lb_ovrflw : 1; /**< [ 4: 4](R/W1S/H) Reads or sets BGX(0..3)_SMU(0..3)_TX_INT[LB_OVRFLW]. */
uint64_t reserved_5_63 : 59;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_smux_tx_int_w1s bdk_bgxx_smux_tx_int_w1s_t;
static inline uint64_t BDK_BGXX_SMUX_TX_INT_W1S(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_TX_INT_W1S(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020148ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020148ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020148ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_TX_INT_W1S", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_TX_INT_W1S(a,b) bdk_bgxx_smux_tx_int_w1s_t
#define bustype_BDK_BGXX_SMUX_TX_INT_W1S(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_TX_INT_W1S(a,b) "BGXX_SMUX_TX_INT_W1S"
#define device_bar_BDK_BGXX_SMUX_TX_INT_W1S(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_TX_INT_W1S(a,b) (a)
#define arguments_BDK_BGXX_SMUX_TX_INT_W1S(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_tx_min_pkt
*
* BGX SMU TX Minimum-Size-Packet Registers
*/
union bdk_bgxx_smux_tx_min_pkt
{
uint64_t u;
struct bdk_bgxx_smux_tx_min_pkt_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_8_63 : 56;
uint64_t min_size : 8; /**< [ 7: 0](R/W) Min frame in bytes inclusive of FCS, if applied. Padding is only appended when
BGX()_SMU()_TX_APPEND[PAD] for the corresponding port is set. When FCS is added to
a packet which was padded, the FCS always appears in the four octets preceding /T/ or /E/. */
#else /* Word 0 - Little Endian */
uint64_t min_size : 8; /**< [ 7: 0](R/W) Min frame in bytes inclusive of FCS, if applied. Padding is only appended when
BGX()_SMU()_TX_APPEND[PAD] for the corresponding port is set. When FCS is added to
a packet which was padded, the FCS always appears in the four octets preceding /T/ or /E/. */
uint64_t reserved_8_63 : 56;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_smux_tx_min_pkt_s cn; */
};
typedef union bdk_bgxx_smux_tx_min_pkt bdk_bgxx_smux_tx_min_pkt_t;
static inline uint64_t BDK_BGXX_SMUX_TX_MIN_PKT(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_TX_MIN_PKT(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020118ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020118ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020118ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_TX_MIN_PKT", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_TX_MIN_PKT(a,b) bdk_bgxx_smux_tx_min_pkt_t
#define bustype_BDK_BGXX_SMUX_TX_MIN_PKT(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_TX_MIN_PKT(a,b) "BGXX_SMUX_TX_MIN_PKT"
#define device_bar_BDK_BGXX_SMUX_TX_MIN_PKT(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_TX_MIN_PKT(a,b) (a)
#define arguments_BDK_BGXX_SMUX_TX_MIN_PKT(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_tx_pause_pkt_dmac
*
* BGX SMU TX PAUSE-Packet DMAC-Field Registers
* This register provides the DMAC value that is placed in outbound PAUSE packets.
*/
union bdk_bgxx_smux_tx_pause_pkt_dmac
{
uint64_t u;
struct bdk_bgxx_smux_tx_pause_pkt_dmac_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t dmac : 48; /**< [ 47: 0](R/W) The DMAC field that is placed in outbound PAUSE packets. */
#else /* Word 0 - Little Endian */
uint64_t dmac : 48; /**< [ 47: 0](R/W) The DMAC field that is placed in outbound PAUSE packets. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_smux_tx_pause_pkt_dmac_s cn; */
};
typedef union bdk_bgxx_smux_tx_pause_pkt_dmac bdk_bgxx_smux_tx_pause_pkt_dmac_t;
static inline uint64_t BDK_BGXX_SMUX_TX_PAUSE_PKT_DMAC(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_TX_PAUSE_PKT_DMAC(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020168ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020168ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020168ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_TX_PAUSE_PKT_DMAC", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_TX_PAUSE_PKT_DMAC(a,b) bdk_bgxx_smux_tx_pause_pkt_dmac_t
#define bustype_BDK_BGXX_SMUX_TX_PAUSE_PKT_DMAC(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_TX_PAUSE_PKT_DMAC(a,b) "BGXX_SMUX_TX_PAUSE_PKT_DMAC"
#define device_bar_BDK_BGXX_SMUX_TX_PAUSE_PKT_DMAC(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_TX_PAUSE_PKT_DMAC(a,b) (a)
#define arguments_BDK_BGXX_SMUX_TX_PAUSE_PKT_DMAC(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_tx_pause_pkt_interval
*
* BGX SMU TX PAUSE-Packet Transmission-Interval Registers
* This register specifies how often PAUSE packets are sent.
*/
union bdk_bgxx_smux_tx_pause_pkt_interval
{
uint64_t u;
struct bdk_bgxx_smux_tx_pause_pkt_interval_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_33_63 : 31;
uint64_t hg2_intra_en : 1; /**< [ 32: 32](R/W) Allow intrapacket HiGig2 message generation. Relevant only if HiGig2 message generation is enabled. */
uint64_t hg2_intra_interval : 16; /**< [ 31: 16](R/W) Arbitrate for a HiGig2 message, every (INTERVAL*512) bit-times whilst sending regular
packet data. Relevant only if HiGig2 message generation and [HG2_INTRA_EN] are both set.
Normally, 0 \< INTERVAL \< BGX()_SMU()_TX_PAUSE_PKT_TIME.
INTERVAL = 0 only sends a single PAUSE packet for each backpressure event. */
uint64_t interval : 16; /**< [ 15: 0](R/W) Arbitrate for a 802.3 PAUSE packet, HiGig2 message, or PFC packet every
(INTERVAL * 512) bit-times.
Normally, 0 \< INTERVAL \< BGX()_SMU()_TX_PAUSE_PKT_TIME[P_TIME].
INTERVAL = 0 only sends a single PAUSE packet for each backpressure event. */
#else /* Word 0 - Little Endian */
uint64_t interval : 16; /**< [ 15: 0](R/W) Arbitrate for a 802.3 PAUSE packet, HiGig2 message, or PFC packet every
(INTERVAL * 512) bit-times.
Normally, 0 \< INTERVAL \< BGX()_SMU()_TX_PAUSE_PKT_TIME[P_TIME].
INTERVAL = 0 only sends a single PAUSE packet for each backpressure event. */
uint64_t hg2_intra_interval : 16; /**< [ 31: 16](R/W) Arbitrate for a HiGig2 message, every (INTERVAL*512) bit-times whilst sending regular
packet data. Relevant only if HiGig2 message generation and [HG2_INTRA_EN] are both set.
Normally, 0 \< INTERVAL \< BGX()_SMU()_TX_PAUSE_PKT_TIME.
INTERVAL = 0 only sends a single PAUSE packet for each backpressure event. */
uint64_t hg2_intra_en : 1; /**< [ 32: 32](R/W) Allow intrapacket HiGig2 message generation. Relevant only if HiGig2 message generation is enabled. */
uint64_t reserved_33_63 : 31;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_smux_tx_pause_pkt_interval_s cn; */
};
typedef union bdk_bgxx_smux_tx_pause_pkt_interval bdk_bgxx_smux_tx_pause_pkt_interval_t;
static inline uint64_t BDK_BGXX_SMUX_TX_PAUSE_PKT_INTERVAL(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_TX_PAUSE_PKT_INTERVAL(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020120ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020120ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020120ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_TX_PAUSE_PKT_INTERVAL", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_TX_PAUSE_PKT_INTERVAL(a,b) bdk_bgxx_smux_tx_pause_pkt_interval_t
#define bustype_BDK_BGXX_SMUX_TX_PAUSE_PKT_INTERVAL(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_TX_PAUSE_PKT_INTERVAL(a,b) "BGXX_SMUX_TX_PAUSE_PKT_INTERVAL"
#define device_bar_BDK_BGXX_SMUX_TX_PAUSE_PKT_INTERVAL(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_TX_PAUSE_PKT_INTERVAL(a,b) (a)
#define arguments_BDK_BGXX_SMUX_TX_PAUSE_PKT_INTERVAL(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_tx_pause_pkt_time
*
* BGX SMU TX PAUSE Packet Time Registers
*/
union bdk_bgxx_smux_tx_pause_pkt_time
{
uint64_t u;
struct bdk_bgxx_smux_tx_pause_pkt_time_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t p_time : 16; /**< [ 15: 0](R/W) Provides the pause_time field placed in outbound 802.3 PAUSE packets, HiGig2 messages, or
PFC packets in 512 bit-times. Normally, [P_TIME] \>
BGX()_SMU()_TX_PAUSE_PKT_INTERVAL[INTERVAL]. See programming notes in
BGX()_SMU()_TX_PAUSE_PKT_INTERVAL. */
#else /* Word 0 - Little Endian */
uint64_t p_time : 16; /**< [ 15: 0](R/W) Provides the pause_time field placed in outbound 802.3 PAUSE packets, HiGig2 messages, or
PFC packets in 512 bit-times. Normally, [P_TIME] \>
BGX()_SMU()_TX_PAUSE_PKT_INTERVAL[INTERVAL]. See programming notes in
BGX()_SMU()_TX_PAUSE_PKT_INTERVAL. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_smux_tx_pause_pkt_time_s cn; */
};
typedef union bdk_bgxx_smux_tx_pause_pkt_time bdk_bgxx_smux_tx_pause_pkt_time_t;
static inline uint64_t BDK_BGXX_SMUX_TX_PAUSE_PKT_TIME(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_TX_PAUSE_PKT_TIME(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020110ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020110ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020110ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_TX_PAUSE_PKT_TIME", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_TX_PAUSE_PKT_TIME(a,b) bdk_bgxx_smux_tx_pause_pkt_time_t
#define bustype_BDK_BGXX_SMUX_TX_PAUSE_PKT_TIME(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_TX_PAUSE_PKT_TIME(a,b) "BGXX_SMUX_TX_PAUSE_PKT_TIME"
#define device_bar_BDK_BGXX_SMUX_TX_PAUSE_PKT_TIME(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_TX_PAUSE_PKT_TIME(a,b) (a)
#define arguments_BDK_BGXX_SMUX_TX_PAUSE_PKT_TIME(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_tx_pause_pkt_type
*
* BGX SMU TX PAUSE-Packet P_TYPE-Field Registers
* This register provides the P_TYPE field that is placed in outbound PAUSE packets.
*/
union bdk_bgxx_smux_tx_pause_pkt_type
{
uint64_t u;
struct bdk_bgxx_smux_tx_pause_pkt_type_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t p_type : 16; /**< [ 15: 0](R/W) The P_TYPE field that is placed in outbound PAUSE packets. */
#else /* Word 0 - Little Endian */
uint64_t p_type : 16; /**< [ 15: 0](R/W) The P_TYPE field that is placed in outbound PAUSE packets. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_smux_tx_pause_pkt_type_s cn; */
};
typedef union bdk_bgxx_smux_tx_pause_pkt_type bdk_bgxx_smux_tx_pause_pkt_type_t;
static inline uint64_t BDK_BGXX_SMUX_TX_PAUSE_PKT_TYPE(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_TX_PAUSE_PKT_TYPE(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020170ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020170ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020170ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_TX_PAUSE_PKT_TYPE", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_TX_PAUSE_PKT_TYPE(a,b) bdk_bgxx_smux_tx_pause_pkt_type_t
#define bustype_BDK_BGXX_SMUX_TX_PAUSE_PKT_TYPE(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_TX_PAUSE_PKT_TYPE(a,b) "BGXX_SMUX_TX_PAUSE_PKT_TYPE"
#define device_bar_BDK_BGXX_SMUX_TX_PAUSE_PKT_TYPE(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_TX_PAUSE_PKT_TYPE(a,b) (a)
#define arguments_BDK_BGXX_SMUX_TX_PAUSE_PKT_TYPE(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_tx_pause_togo
*
* BGX SMU TX Time-to-Backpressure Registers
*/
union bdk_bgxx_smux_tx_pause_togo
{
uint64_t u;
struct bdk_bgxx_smux_tx_pause_togo_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_32_63 : 32;
uint64_t msg_time : 16; /**< [ 31: 16](RO/H) Amount of time remaining to backpressure, from the HiGig2 physical message PAUSE timer
(only valid on port0). */
uint64_t p_time : 16; /**< [ 15: 0](RO/H) Amount of time remaining to backpressure, from the standard 802.3 PAUSE timer. */
#else /* Word 0 - Little Endian */
uint64_t p_time : 16; /**< [ 15: 0](RO/H) Amount of time remaining to backpressure, from the standard 802.3 PAUSE timer. */
uint64_t msg_time : 16; /**< [ 31: 16](RO/H) Amount of time remaining to backpressure, from the HiGig2 physical message PAUSE timer
(only valid on port0). */
uint64_t reserved_32_63 : 32;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_smux_tx_pause_togo_s cn; */
};
typedef union bdk_bgxx_smux_tx_pause_togo bdk_bgxx_smux_tx_pause_togo_t;
static inline uint64_t BDK_BGXX_SMUX_TX_PAUSE_TOGO(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_TX_PAUSE_TOGO(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020130ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020130ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020130ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_TX_PAUSE_TOGO", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_TX_PAUSE_TOGO(a,b) bdk_bgxx_smux_tx_pause_togo_t
#define bustype_BDK_BGXX_SMUX_TX_PAUSE_TOGO(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_TX_PAUSE_TOGO(a,b) "BGXX_SMUX_TX_PAUSE_TOGO"
#define device_bar_BDK_BGXX_SMUX_TX_PAUSE_TOGO(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_TX_PAUSE_TOGO(a,b) (a)
#define arguments_BDK_BGXX_SMUX_TX_PAUSE_TOGO(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_tx_pause_zero
*
* BGX SMU TX PAUSE Zero Registers
*/
union bdk_bgxx_smux_tx_pause_zero
{
uint64_t u;
struct bdk_bgxx_smux_tx_pause_zero_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_1_63 : 63;
uint64_t send : 1; /**< [ 0: 0](R/W) Send PAUSE-zero enable. When this bit is set, and the backpressure condition is clear, it
allows sending a PAUSE packet with pause_time of 0 to enable the channel. */
#else /* Word 0 - Little Endian */
uint64_t send : 1; /**< [ 0: 0](R/W) Send PAUSE-zero enable. When this bit is set, and the backpressure condition is clear, it
allows sending a PAUSE packet with pause_time of 0 to enable the channel. */
uint64_t reserved_1_63 : 63;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_smux_tx_pause_zero_s cn; */
};
typedef union bdk_bgxx_smux_tx_pause_zero bdk_bgxx_smux_tx_pause_zero_t;
static inline uint64_t BDK_BGXX_SMUX_TX_PAUSE_ZERO(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_TX_PAUSE_ZERO(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020138ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020138ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020138ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_TX_PAUSE_ZERO", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_TX_PAUSE_ZERO(a,b) bdk_bgxx_smux_tx_pause_zero_t
#define bustype_BDK_BGXX_SMUX_TX_PAUSE_ZERO(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_TX_PAUSE_ZERO(a,b) "BGXX_SMUX_TX_PAUSE_ZERO"
#define device_bar_BDK_BGXX_SMUX_TX_PAUSE_ZERO(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_TX_PAUSE_ZERO(a,b) (a)
#define arguments_BDK_BGXX_SMUX_TX_PAUSE_ZERO(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_tx_soft_pause
*
* BGX SMU TX Soft PAUSE Registers
*/
union bdk_bgxx_smux_tx_soft_pause
{
uint64_t u;
struct bdk_bgxx_smux_tx_soft_pause_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t p_time : 16; /**< [ 15: 0](R/W) Back off the TX bus for ([P_TIME] * 512) bit-times */
#else /* Word 0 - Little Endian */
uint64_t p_time : 16; /**< [ 15: 0](R/W) Back off the TX bus for ([P_TIME] * 512) bit-times */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_smux_tx_soft_pause_s cn; */
};
typedef union bdk_bgxx_smux_tx_soft_pause bdk_bgxx_smux_tx_soft_pause_t;
static inline uint64_t BDK_BGXX_SMUX_TX_SOFT_PAUSE(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_TX_SOFT_PAUSE(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020128ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020128ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020128ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_TX_SOFT_PAUSE", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_TX_SOFT_PAUSE(a,b) bdk_bgxx_smux_tx_soft_pause_t
#define bustype_BDK_BGXX_SMUX_TX_SOFT_PAUSE(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_TX_SOFT_PAUSE(a,b) "BGXX_SMUX_TX_SOFT_PAUSE"
#define device_bar_BDK_BGXX_SMUX_TX_SOFT_PAUSE(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_TX_SOFT_PAUSE(a,b) (a)
#define arguments_BDK_BGXX_SMUX_TX_SOFT_PAUSE(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_smu#_tx_thresh
*
* BGX SMU TX Threshold Registers
*/
union bdk_bgxx_smux_tx_thresh
{
uint64_t u;
struct bdk_bgxx_smux_tx_thresh_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_11_63 : 53;
uint64_t cnt : 11; /**< [ 10: 0](R/W) Number of 128-bit words to accumulate in the TX FIFO before sending on the packet
interface. This field should be large enough to prevent underflow on the packet interface
and must never be set to 0x0.
In all modes, this register cannot exceed the TX FIFO depth configured by
BGX()_CMR_TX_LMACS[LMACS]. */
#else /* Word 0 - Little Endian */
uint64_t cnt : 11; /**< [ 10: 0](R/W) Number of 128-bit words to accumulate in the TX FIFO before sending on the packet
interface. This field should be large enough to prevent underflow on the packet interface
and must never be set to 0x0.
In all modes, this register cannot exceed the TX FIFO depth configured by
BGX()_CMR_TX_LMACS[LMACS]. */
uint64_t reserved_11_63 : 53;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_smux_tx_thresh_s cn; */
};
typedef union bdk_bgxx_smux_tx_thresh bdk_bgxx_smux_tx_thresh_t;
static inline uint64_t BDK_BGXX_SMUX_TX_THRESH(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SMUX_TX_THRESH(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020180ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0020180ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0020180ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SMUX_TX_THRESH", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SMUX_TX_THRESH(a,b) bdk_bgxx_smux_tx_thresh_t
#define bustype_BDK_BGXX_SMUX_TX_THRESH(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SMUX_TX_THRESH(a,b) "BGXX_SMUX_TX_THRESH"
#define device_bar_BDK_BGXX_SMUX_TX_THRESH(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SMUX_TX_THRESH(a,b) (a)
#define arguments_BDK_BGXX_SMUX_TX_THRESH(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_an_adv
*
* BGX SPU Autonegotiation Advertisement Registers
* Software programs this register with the contents of the AN-link code word base page to be
* transmitted during autonegotiation. (See IEEE 802.3 section 73.6 for details.) Any write
* operations to this register prior to completion of autonegotiation, as indicated by
* BGX()_SPU()_AN_STATUS[AN_COMPLETE], should be followed by a renegotiation in order for
* the new values to take effect. Renegotiation is initiated by setting
* BGX()_SPU()_AN_CONTROL[AN_RESTART]. Once autonegotiation has completed, software can
* examine this register along with BGX()_SPU()_AN_LP_BASE to determine the highest
* common denominator technology.
*/
union bdk_bgxx_spux_an_adv
{
uint64_t u;
struct bdk_bgxx_spux_an_adv_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t fec_req : 1; /**< [ 47: 47](R/W) FEC requested. */
uint64_t fec_able : 1; /**< [ 46: 46](R/W) FEC ability. */
uint64_t arsv : 19; /**< [ 45: 27](R/W) Technology ability. Reserved bits, should always be 0. */
uint64_t a100g_cr10 : 1; /**< [ 26: 26](R/W) 100GBASE-CR10 ability. Should always be 0; 100GBASE-R is not supported. */
uint64_t a40g_cr4 : 1; /**< [ 25: 25](R/W) 40GBASE-CR4 ability. */
uint64_t a40g_kr4 : 1; /**< [ 24: 24](R/W) 40GBASE-KR4 ability. */
uint64_t a10g_kr : 1; /**< [ 23: 23](R/W) 10GBASE-KR ability. */
uint64_t a10g_kx4 : 1; /**< [ 22: 22](R/W) 10GBASE-KX4 ability. */
uint64_t a1g_kx : 1; /**< [ 21: 21](R/W) 1000BASE-KX ability. Should always be 0; autonegotiation is not supported for 1000Base-KX. */
uint64_t t : 5; /**< [ 20: 16](R/W/H) Transmitted nonce. This field is automatically updated with a pseudo-random value on entry
to the AN ability detect state. */
uint64_t np : 1; /**< [ 15: 15](R/W) Next page. Always 0; extended next pages are not used for 10G+ autonegotiation. */
uint64_t ack : 1; /**< [ 14: 14](RO/H) Acknowledge. Always 0 in this register. */
uint64_t rf : 1; /**< [ 13: 13](R/W) Remote fault. */
uint64_t xnp_able : 1; /**< [ 12: 12](R/W) Extended next page ability. */
uint64_t asm_dir : 1; /**< [ 11: 11](R/W) Asymmetric PAUSE. */
uint64_t pause : 1; /**< [ 10: 10](R/W) PAUSE ability. */
uint64_t e : 5; /**< [ 9: 5](R/W) Echoed nonce. Provides the echoed-nonce value to use when ACK = 0 in transmitted DME page.
Should always be 0x0. */
uint64_t s : 5; /**< [ 4: 0](R/W) Selector. Should be 0x1 (encoding for IEEE 802.3). */
#else /* Word 0 - Little Endian */
uint64_t s : 5; /**< [ 4: 0](R/W) Selector. Should be 0x1 (encoding for IEEE 802.3). */
uint64_t e : 5; /**< [ 9: 5](R/W) Echoed nonce. Provides the echoed-nonce value to use when ACK = 0 in transmitted DME page.
Should always be 0x0. */
uint64_t pause : 1; /**< [ 10: 10](R/W) PAUSE ability. */
uint64_t asm_dir : 1; /**< [ 11: 11](R/W) Asymmetric PAUSE. */
uint64_t xnp_able : 1; /**< [ 12: 12](R/W) Extended next page ability. */
uint64_t rf : 1; /**< [ 13: 13](R/W) Remote fault. */
uint64_t ack : 1; /**< [ 14: 14](RO/H) Acknowledge. Always 0 in this register. */
uint64_t np : 1; /**< [ 15: 15](R/W) Next page. Always 0; extended next pages are not used for 10G+ autonegotiation. */
uint64_t t : 5; /**< [ 20: 16](R/W/H) Transmitted nonce. This field is automatically updated with a pseudo-random value on entry
to the AN ability detect state. */
uint64_t a1g_kx : 1; /**< [ 21: 21](R/W) 1000BASE-KX ability. Should always be 0; autonegotiation is not supported for 1000Base-KX. */
uint64_t a10g_kx4 : 1; /**< [ 22: 22](R/W) 10GBASE-KX4 ability. */
uint64_t a10g_kr : 1; /**< [ 23: 23](R/W) 10GBASE-KR ability. */
uint64_t a40g_kr4 : 1; /**< [ 24: 24](R/W) 40GBASE-KR4 ability. */
uint64_t a40g_cr4 : 1; /**< [ 25: 25](R/W) 40GBASE-CR4 ability. */
uint64_t a100g_cr10 : 1; /**< [ 26: 26](R/W) 100GBASE-CR10 ability. Should always be 0; 100GBASE-R is not supported. */
uint64_t arsv : 19; /**< [ 45: 27](R/W) Technology ability. Reserved bits, should always be 0. */
uint64_t fec_able : 1; /**< [ 46: 46](R/W) FEC ability. */
uint64_t fec_req : 1; /**< [ 47: 47](R/W) FEC requested. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_an_adv_s cn; */
};
typedef union bdk_bgxx_spux_an_adv bdk_bgxx_spux_an_adv_t;
static inline uint64_t BDK_BGXX_SPUX_AN_ADV(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_AN_ADV(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e00100d8ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e00100d8ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e00100d8ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_AN_ADV", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_AN_ADV(a,b) bdk_bgxx_spux_an_adv_t
#define bustype_BDK_BGXX_SPUX_AN_ADV(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_AN_ADV(a,b) "BGXX_SPUX_AN_ADV"
#define device_bar_BDK_BGXX_SPUX_AN_ADV(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_AN_ADV(a,b) (a)
#define arguments_BDK_BGXX_SPUX_AN_ADV(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_an_bp_status
*
* BGX SPU Autonegotiation Backplane Ethernet & BASE-R Copper Status Registers
* The contents of this register are updated
* during autonegotiation and are valid when BGX()_SPU()_AN_STATUS[AN_COMPLETE] is set.
* At that time, one of the port type bits ([N100G_CR10], [N40G_CR4], [N40G_KR4], [N10G_KR],
* [N10G_KX4],
* [N1G_KX]) will be set depending on the AN priority resolution. If a BASE-R type is negotiated,
* then [FEC] will be set to indicate that FEC operation has been negotiated, and will be
* clear otherwise.
*/
union bdk_bgxx_spux_an_bp_status
{
uint64_t u;
struct bdk_bgxx_spux_an_bp_status_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_9_63 : 55;
uint64_t n100g_cr10 : 1; /**< [ 8: 8](RO/H) 100GBASE-CR10 negotiated; expected to always be 0; 100GBASE-R is not supported. */
uint64_t reserved_7 : 1;
uint64_t n40g_cr4 : 1; /**< [ 6: 6](RO/H) 40GBASE-CR4 negotiated. */
uint64_t n40g_kr4 : 1; /**< [ 5: 5](RO/H) 40GBASE-KR4 negotiated. */
uint64_t fec : 1; /**< [ 4: 4](RO/H) BASE-R FEC negotiated. */
uint64_t n10g_kr : 1; /**< [ 3: 3](RO/H) 10GBASE-KR negotiated. */
uint64_t n10g_kx4 : 1; /**< [ 2: 2](RO/H) 10GBASE-KX4 or CX4 negotiated (XAUI). */
uint64_t n1g_kx : 1; /**< [ 1: 1](RO/H) 1000BASE-KX negotiated. */
uint64_t bp_an_able : 1; /**< [ 0: 0](RO) Backplane or BASE-R copper AN Ability; always 1. */
#else /* Word 0 - Little Endian */
uint64_t bp_an_able : 1; /**< [ 0: 0](RO) Backplane or BASE-R copper AN Ability; always 1. */
uint64_t n1g_kx : 1; /**< [ 1: 1](RO/H) 1000BASE-KX negotiated. */
uint64_t n10g_kx4 : 1; /**< [ 2: 2](RO/H) 10GBASE-KX4 or CX4 negotiated (XAUI). */
uint64_t n10g_kr : 1; /**< [ 3: 3](RO/H) 10GBASE-KR negotiated. */
uint64_t fec : 1; /**< [ 4: 4](RO/H) BASE-R FEC negotiated. */
uint64_t n40g_kr4 : 1; /**< [ 5: 5](RO/H) 40GBASE-KR4 negotiated. */
uint64_t n40g_cr4 : 1; /**< [ 6: 6](RO/H) 40GBASE-CR4 negotiated. */
uint64_t reserved_7 : 1;
uint64_t n100g_cr10 : 1; /**< [ 8: 8](RO/H) 100GBASE-CR10 negotiated; expected to always be 0; 100GBASE-R is not supported. */
uint64_t reserved_9_63 : 55;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_an_bp_status_s cn; */
};
typedef union bdk_bgxx_spux_an_bp_status bdk_bgxx_spux_an_bp_status_t;
static inline uint64_t BDK_BGXX_SPUX_AN_BP_STATUS(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_AN_BP_STATUS(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e00100f8ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e00100f8ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e00100f8ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_AN_BP_STATUS", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_AN_BP_STATUS(a,b) bdk_bgxx_spux_an_bp_status_t
#define bustype_BDK_BGXX_SPUX_AN_BP_STATUS(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_AN_BP_STATUS(a,b) "BGXX_SPUX_AN_BP_STATUS"
#define device_bar_BDK_BGXX_SPUX_AN_BP_STATUS(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_AN_BP_STATUS(a,b) (a)
#define arguments_BDK_BGXX_SPUX_AN_BP_STATUS(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_an_control
*
* BGX SPU Autonegotiation Control Registers
*/
union bdk_bgxx_spux_an_control
{
uint64_t u;
struct bdk_bgxx_spux_an_control_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t an_reset : 1; /**< [ 15: 15](R/W1S/H) Autonegotiation reset. Setting this bit or BGX()_SPU()_CONTROL1[RESET] to 1
causes the following to happen:
* Resets the logical PCS (LPCS)
* Sets the IEEE 802.3 PCS, FEC and AN registers for the LPCS to their default states
* Resets the associated SerDes lanes.
It takes up to 32 coprocessor-clock cycles to reset the LPCS, after which RESET is
automatically cleared. */
uint64_t reserved_14 : 1;
uint64_t xnp_en : 1; /**< [ 13: 13](R/W) Extended next-page enable. */
uint64_t an_en : 1; /**< [ 12: 12](R/W) Autonegotiation enable. This bit should not be set when
BGX()_CMR()_CONFIG[LMAC_TYPE] is set to RXAUI; autonegotiation is not supported
in RXAUI mode. */
uint64_t reserved_10_11 : 2;
uint64_t an_restart : 1; /**< [ 9: 9](R/W1S/H) Autonegotiation restart. Writing a 1 to this bit restarts the autonegotiation process if
[AN_EN] is also set. This is a self-clearing bit. */
uint64_t reserved_0_8 : 9;
#else /* Word 0 - Little Endian */
uint64_t reserved_0_8 : 9;
uint64_t an_restart : 1; /**< [ 9: 9](R/W1S/H) Autonegotiation restart. Writing a 1 to this bit restarts the autonegotiation process if
[AN_EN] is also set. This is a self-clearing bit. */
uint64_t reserved_10_11 : 2;
uint64_t an_en : 1; /**< [ 12: 12](R/W) Autonegotiation enable. This bit should not be set when
BGX()_CMR()_CONFIG[LMAC_TYPE] is set to RXAUI; autonegotiation is not supported
in RXAUI mode. */
uint64_t xnp_en : 1; /**< [ 13: 13](R/W) Extended next-page enable. */
uint64_t reserved_14 : 1;
uint64_t an_reset : 1; /**< [ 15: 15](R/W1S/H) Autonegotiation reset. Setting this bit or BGX()_SPU()_CONTROL1[RESET] to 1
causes the following to happen:
* Resets the logical PCS (LPCS)
* Sets the IEEE 802.3 PCS, FEC and AN registers for the LPCS to their default states
* Resets the associated SerDes lanes.
It takes up to 32 coprocessor-clock cycles to reset the LPCS, after which RESET is
automatically cleared. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_an_control_s cn; */
};
typedef union bdk_bgxx_spux_an_control bdk_bgxx_spux_an_control_t;
static inline uint64_t BDK_BGXX_SPUX_AN_CONTROL(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_AN_CONTROL(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e00100c8ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e00100c8ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e00100c8ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_AN_CONTROL", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_AN_CONTROL(a,b) bdk_bgxx_spux_an_control_t
#define bustype_BDK_BGXX_SPUX_AN_CONTROL(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_AN_CONTROL(a,b) "BGXX_SPUX_AN_CONTROL"
#define device_bar_BDK_BGXX_SPUX_AN_CONTROL(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_AN_CONTROL(a,b) (a)
#define arguments_BDK_BGXX_SPUX_AN_CONTROL(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_an_lp_base
*
* BGX SPU Autonegotiation Link-Partner Base-Page Ability Registers
* This register captures the contents of the latest AN link code word base page received from
* the link partner during autonegotiation. (See IEEE 802.3 section 73.6 for details.)
* BGX()_SPU()_AN_STATUS[PAGE_RX] is set when this register is updated by hardware.
*/
union bdk_bgxx_spux_an_lp_base
{
uint64_t u;
struct bdk_bgxx_spux_an_lp_base_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t fec_req : 1; /**< [ 47: 47](RO/H) FEC requested. */
uint64_t fec_able : 1; /**< [ 46: 46](RO/H) FEC ability. */
uint64_t arsv : 19; /**< [ 45: 27](RO/H) Technology ability. Reserved bits, should always be 0. */
uint64_t a100g_cr10 : 1; /**< [ 26: 26](RO/H) 100GBASE-CR10 ability. */
uint64_t a40g_cr4 : 1; /**< [ 25: 25](RO/H) 40GBASE-CR4 ability. */
uint64_t a40g_kr4 : 1; /**< [ 24: 24](RO/H) 40GBASE-KR4 ability. */
uint64_t a10g_kr : 1; /**< [ 23: 23](RO/H) 10GBASE-KR ability. */
uint64_t a10g_kx4 : 1; /**< [ 22: 22](RO/H) 10GBASE-KX4 ability. */
uint64_t a1g_kx : 1; /**< [ 21: 21](RO/H) 1000BASE-KX ability. */
uint64_t t : 5; /**< [ 20: 16](RO/H) Transmitted nonce. */
uint64_t np : 1; /**< [ 15: 15](RO/H) Next page. */
uint64_t ack : 1; /**< [ 14: 14](RO/H) Acknowledge. */
uint64_t rf : 1; /**< [ 13: 13](RO/H) Remote fault. */
uint64_t xnp_able : 1; /**< [ 12: 12](RO/H) Extended next page ability. */
uint64_t asm_dir : 1; /**< [ 11: 11](RO/H) Asymmetric PAUSE. */
uint64_t pause : 1; /**< [ 10: 10](RO/H) PAUSE ability. */
uint64_t e : 5; /**< [ 9: 5](RO/H) Echoed nonce. */
uint64_t s : 5; /**< [ 4: 0](RO/H) Selector. */
#else /* Word 0 - Little Endian */
uint64_t s : 5; /**< [ 4: 0](RO/H) Selector. */
uint64_t e : 5; /**< [ 9: 5](RO/H) Echoed nonce. */
uint64_t pause : 1; /**< [ 10: 10](RO/H) PAUSE ability. */
uint64_t asm_dir : 1; /**< [ 11: 11](RO/H) Asymmetric PAUSE. */
uint64_t xnp_able : 1; /**< [ 12: 12](RO/H) Extended next page ability. */
uint64_t rf : 1; /**< [ 13: 13](RO/H) Remote fault. */
uint64_t ack : 1; /**< [ 14: 14](RO/H) Acknowledge. */
uint64_t np : 1; /**< [ 15: 15](RO/H) Next page. */
uint64_t t : 5; /**< [ 20: 16](RO/H) Transmitted nonce. */
uint64_t a1g_kx : 1; /**< [ 21: 21](RO/H) 1000BASE-KX ability. */
uint64_t a10g_kx4 : 1; /**< [ 22: 22](RO/H) 10GBASE-KX4 ability. */
uint64_t a10g_kr : 1; /**< [ 23: 23](RO/H) 10GBASE-KR ability. */
uint64_t a40g_kr4 : 1; /**< [ 24: 24](RO/H) 40GBASE-KR4 ability. */
uint64_t a40g_cr4 : 1; /**< [ 25: 25](RO/H) 40GBASE-CR4 ability. */
uint64_t a100g_cr10 : 1; /**< [ 26: 26](RO/H) 100GBASE-CR10 ability. */
uint64_t arsv : 19; /**< [ 45: 27](RO/H) Technology ability. Reserved bits, should always be 0. */
uint64_t fec_able : 1; /**< [ 46: 46](RO/H) FEC ability. */
uint64_t fec_req : 1; /**< [ 47: 47](RO/H) FEC requested. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_an_lp_base_s cn; */
};
typedef union bdk_bgxx_spux_an_lp_base bdk_bgxx_spux_an_lp_base_t;
static inline uint64_t BDK_BGXX_SPUX_AN_LP_BASE(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_AN_LP_BASE(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e00100e0ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e00100e0ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e00100e0ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_AN_LP_BASE", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_AN_LP_BASE(a,b) bdk_bgxx_spux_an_lp_base_t
#define bustype_BDK_BGXX_SPUX_AN_LP_BASE(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_AN_LP_BASE(a,b) "BGXX_SPUX_AN_LP_BASE"
#define device_bar_BDK_BGXX_SPUX_AN_LP_BASE(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_AN_LP_BASE(a,b) (a)
#define arguments_BDK_BGXX_SPUX_AN_LP_BASE(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_an_lp_xnp
*
* BGX SPU Autonegotiation Link Partner Extended Next Page Ability Registers
* This register captures the contents of the latest next page code word received from the link
* partner during autonegotiation, if any. See section 802.3 section 73.7.7 for details.
*/
union bdk_bgxx_spux_an_lp_xnp
{
uint64_t u;
struct bdk_bgxx_spux_an_lp_xnp_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t u : 32; /**< [ 47: 16](RO/H) Unformatted code field. */
uint64_t np : 1; /**< [ 15: 15](RO/H) Next page. */
uint64_t ack : 1; /**< [ 14: 14](RO/H) Acknowledge. */
uint64_t mp : 1; /**< [ 13: 13](RO/H) Message page. */
uint64_t ack2 : 1; /**< [ 12: 12](RO/H) Acknowledge 2. */
uint64_t toggle : 1; /**< [ 11: 11](RO/H) Toggle. */
uint64_t m_u : 11; /**< [ 10: 0](RO/H) Message/unformatted code field. */
#else /* Word 0 - Little Endian */
uint64_t m_u : 11; /**< [ 10: 0](RO/H) Message/unformatted code field. */
uint64_t toggle : 1; /**< [ 11: 11](RO/H) Toggle. */
uint64_t ack2 : 1; /**< [ 12: 12](RO/H) Acknowledge 2. */
uint64_t mp : 1; /**< [ 13: 13](RO/H) Message page. */
uint64_t ack : 1; /**< [ 14: 14](RO/H) Acknowledge. */
uint64_t np : 1; /**< [ 15: 15](RO/H) Next page. */
uint64_t u : 32; /**< [ 47: 16](RO/H) Unformatted code field. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_an_lp_xnp_s cn; */
};
typedef union bdk_bgxx_spux_an_lp_xnp bdk_bgxx_spux_an_lp_xnp_t;
static inline uint64_t BDK_BGXX_SPUX_AN_LP_XNP(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_AN_LP_XNP(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e00100f0ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e00100f0ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e00100f0ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_AN_LP_XNP", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_AN_LP_XNP(a,b) bdk_bgxx_spux_an_lp_xnp_t
#define bustype_BDK_BGXX_SPUX_AN_LP_XNP(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_AN_LP_XNP(a,b) "BGXX_SPUX_AN_LP_XNP"
#define device_bar_BDK_BGXX_SPUX_AN_LP_XNP(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_AN_LP_XNP(a,b) (a)
#define arguments_BDK_BGXX_SPUX_AN_LP_XNP(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_an_status
*
* BGX SPU Autonegotiation Status Registers
*/
union bdk_bgxx_spux_an_status
{
uint64_t u;
struct bdk_bgxx_spux_an_status_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_10_63 : 54;
uint64_t prl_flt : 1; /**< [ 9: 9](RO) Parallel detection fault. Always 0; SPU does not support parallel detection as part of the
autonegotiation protocol. */
uint64_t reserved_8 : 1;
uint64_t xnp_stat : 1; /**< [ 7: 7](RO/H) Extended next-page status. */
uint64_t page_rx : 1; /**< [ 6: 6](R/W1C/H) Page received. This latching-high bit is set when a new page has been received and stored
in BGX()_SPU()_AN_LP_BASE or BGX()_SPU()_AN_LP_XNP; stays set until a 1 is
written by software, autonegotiation is disabled or restarted, or next page exchange is
initiated. Note that in order to avoid read side effects, this is implemented as a
write-1-to-clear bit, rather than latching high read-only as specified in 802.3. */
uint64_t an_complete : 1; /**< [ 5: 5](RO/H) Autonegotiation complete. Set when the autonegotiation process has been completed and
the link is up and running using the negotiated highest common denominator (HCD)
technology. If AN is enabled (BGX()_SPU()_AN_CONTROL[AN_EN] = 1) and this bit is
read as a zero, it indicates that the AN process has not been completed, and the contents
of BGX()_SPU()_AN_LP_BASE, BGX()_SPU()_AN_XNP_TX, and
BGX()_SPU()_AN_LP_XNP are as defined by the current state of the autonegotiation
protocol, or as written for manual configuration. This bit is always zero when AN is
disabled (BGX()_SPU()_AN_CONTROL[AN_EN] = 0). */
uint64_t rmt_flt : 1; /**< [ 4: 4](RO) Remote fault: Always 0. */
uint64_t an_able : 1; /**< [ 3: 3](RO) Autonegotiation ability: Always 1. */
uint64_t link_status : 1; /**< [ 2: 2](R/W1S/H) Link status. This bit captures the state of the link_status variable as defined in 802.3
section 73.9.1. When set, indicates that a valid link has been established. When clear,
indicates that the link has been invalid after this bit was last set by software. Latching
low bit; stays clear until a 1 is written by software. Note that in order to avoid read
side effects, this is implemented as a write-1-to-set bit, rather than latching low read-
only as specified in 802.3. */
uint64_t reserved_1 : 1;
uint64_t lp_an_able : 1; /**< [ 0: 0](RO/H) Link partner autonegotiation ability. Set to indicate that the link partner is able to
participate in the autonegotiation function, and cleared otherwise. */
#else /* Word 0 - Little Endian */
uint64_t lp_an_able : 1; /**< [ 0: 0](RO/H) Link partner autonegotiation ability. Set to indicate that the link partner is able to
participate in the autonegotiation function, and cleared otherwise. */
uint64_t reserved_1 : 1;
uint64_t link_status : 1; /**< [ 2: 2](R/W1S/H) Link status. This bit captures the state of the link_status variable as defined in 802.3
section 73.9.1. When set, indicates that a valid link has been established. When clear,
indicates that the link has been invalid after this bit was last set by software. Latching
low bit; stays clear until a 1 is written by software. Note that in order to avoid read
side effects, this is implemented as a write-1-to-set bit, rather than latching low read-
only as specified in 802.3. */
uint64_t an_able : 1; /**< [ 3: 3](RO) Autonegotiation ability: Always 1. */
uint64_t rmt_flt : 1; /**< [ 4: 4](RO) Remote fault: Always 0. */
uint64_t an_complete : 1; /**< [ 5: 5](RO/H) Autonegotiation complete. Set when the autonegotiation process has been completed and
the link is up and running using the negotiated highest common denominator (HCD)
technology. If AN is enabled (BGX()_SPU()_AN_CONTROL[AN_EN] = 1) and this bit is
read as a zero, it indicates that the AN process has not been completed, and the contents
of BGX()_SPU()_AN_LP_BASE, BGX()_SPU()_AN_XNP_TX, and
BGX()_SPU()_AN_LP_XNP are as defined by the current state of the autonegotiation
protocol, or as written for manual configuration. This bit is always zero when AN is
disabled (BGX()_SPU()_AN_CONTROL[AN_EN] = 0). */
uint64_t page_rx : 1; /**< [ 6: 6](R/W1C/H) Page received. This latching-high bit is set when a new page has been received and stored
in BGX()_SPU()_AN_LP_BASE or BGX()_SPU()_AN_LP_XNP; stays set until a 1 is
written by software, autonegotiation is disabled or restarted, or next page exchange is
initiated. Note that in order to avoid read side effects, this is implemented as a
write-1-to-clear bit, rather than latching high read-only as specified in 802.3. */
uint64_t xnp_stat : 1; /**< [ 7: 7](RO/H) Extended next-page status. */
uint64_t reserved_8 : 1;
uint64_t prl_flt : 1; /**< [ 9: 9](RO) Parallel detection fault. Always 0; SPU does not support parallel detection as part of the
autonegotiation protocol. */
uint64_t reserved_10_63 : 54;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_an_status_s cn; */
};
typedef union bdk_bgxx_spux_an_status bdk_bgxx_spux_an_status_t;
static inline uint64_t BDK_BGXX_SPUX_AN_STATUS(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_AN_STATUS(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e00100d0ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e00100d0ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e00100d0ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_AN_STATUS", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_AN_STATUS(a,b) bdk_bgxx_spux_an_status_t
#define bustype_BDK_BGXX_SPUX_AN_STATUS(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_AN_STATUS(a,b) "BGXX_SPUX_AN_STATUS"
#define device_bar_BDK_BGXX_SPUX_AN_STATUS(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_AN_STATUS(a,b) (a)
#define arguments_BDK_BGXX_SPUX_AN_STATUS(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_an_xnp_tx
*
* BGX SPU Autonegotiation Extended Next Page Transmit Registers
* Software programs this register with the contents of the AN message next page or unformatted
* next page link code word to be transmitted during autonegotiation. Next page exchange occurs
* after the base link code words have been exchanged if either end of the link segment sets the
* NP bit to 1, indicating that it has at least one next page to send. Once initiated, next page
* exchange continues until both ends of the link segment set their NP bits to 0. See section
* 802.3 section 73.7.7 for details.
*/
union bdk_bgxx_spux_an_xnp_tx
{
uint64_t u;
struct bdk_bgxx_spux_an_xnp_tx_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_48_63 : 16;
uint64_t u : 32; /**< [ 47: 16](R/W) Unformatted code field. When the MP bit is set, this field contains the 32-bit unformatted
code field of the message next page. When MP is clear, this field contains the upper 32
bits of the 43-bit unformatted code field of the unformatted next page. */
uint64_t np : 1; /**< [ 15: 15](R/W) Next page. */
uint64_t ack : 1; /**< [ 14: 14](RO/H) Acknowledge: Always 0 in this register. */
uint64_t mp : 1; /**< [ 13: 13](R/W) Message page. Set to indicate that this register contains a message next page. Clear to
indicate that the register contains an unformatted next page. */
uint64_t ack2 : 1; /**< [ 12: 12](R/W) Acknowledge 2. Indicates that the receiver is able to act on the information (or perform
the task) defined in the message. */
uint64_t toggle : 1; /**< [ 11: 11](R/W) This bit is ignored by hardware. The value of the TOGGLE bit in transmitted next pages is
automatically generated by hardware. */
uint64_t m_u : 11; /**< [ 10: 0](R/W) Message/unformatted code field: When the MP bit is set, this field contains the message
code field (M) of the message next page. When MP is clear, this field contains the lower
11 bits of the 43-bit unformatted code field of the unformatted next page. */
#else /* Word 0 - Little Endian */
uint64_t m_u : 11; /**< [ 10: 0](R/W) Message/unformatted code field: When the MP bit is set, this field contains the message
code field (M) of the message next page. When MP is clear, this field contains the lower
11 bits of the 43-bit unformatted code field of the unformatted next page. */
uint64_t toggle : 1; /**< [ 11: 11](R/W) This bit is ignored by hardware. The value of the TOGGLE bit in transmitted next pages is
automatically generated by hardware. */
uint64_t ack2 : 1; /**< [ 12: 12](R/W) Acknowledge 2. Indicates that the receiver is able to act on the information (or perform
the task) defined in the message. */
uint64_t mp : 1; /**< [ 13: 13](R/W) Message page. Set to indicate that this register contains a message next page. Clear to
indicate that the register contains an unformatted next page. */
uint64_t ack : 1; /**< [ 14: 14](RO/H) Acknowledge: Always 0 in this register. */
uint64_t np : 1; /**< [ 15: 15](R/W) Next page. */
uint64_t u : 32; /**< [ 47: 16](R/W) Unformatted code field. When the MP bit is set, this field contains the 32-bit unformatted
code field of the message next page. When MP is clear, this field contains the upper 32
bits of the 43-bit unformatted code field of the unformatted next page. */
uint64_t reserved_48_63 : 16;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_an_xnp_tx_s cn; */
};
typedef union bdk_bgxx_spux_an_xnp_tx bdk_bgxx_spux_an_xnp_tx_t;
static inline uint64_t BDK_BGXX_SPUX_AN_XNP_TX(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_AN_XNP_TX(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e00100e8ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e00100e8ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e00100e8ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_AN_XNP_TX", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_AN_XNP_TX(a,b) bdk_bgxx_spux_an_xnp_tx_t
#define bustype_BDK_BGXX_SPUX_AN_XNP_TX(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_AN_XNP_TX(a,b) "BGXX_SPUX_AN_XNP_TX"
#define device_bar_BDK_BGXX_SPUX_AN_XNP_TX(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_AN_XNP_TX(a,b) (a)
#define arguments_BDK_BGXX_SPUX_AN_XNP_TX(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_br_algn_status
*
* BGX SPU Multilane BASE-R PCS Alignment-Status Registers
* This register implements the IEEE 802.3 multilane BASE-R PCS alignment status 1-4 registers
* (3.50-3.53). It is valid only when the LPCS type is 40GBASE-R
* (BGX()_CMR()_CONFIG[LMAC_TYPE] = 0x4), and always returns 0x0 for all other LPCS
* types. IEEE 802.3 bits that are not applicable to 40GBASE-R (e.g. status bits for PCS lanes
* 19-4) are not implemented and marked as reserved. PCS lanes 3-0 are valid and are mapped to
* physical SerDes lanes based on the programming of BGX()_CMR()_CONFIG[LANE_TO_SDS].
*/
union bdk_bgxx_spux_br_algn_status
{
uint64_t u;
struct bdk_bgxx_spux_br_algn_status_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_36_63 : 28;
uint64_t marker_lock : 4; /**< [ 35: 32](RO/H) Marker-locked status for PCS lanes 3-0.
0 = Not locked.
1 = Locked. */
uint64_t reserved_13_31 : 19;
uint64_t alignd : 1; /**< [ 12: 12](RO/H) All lanes are locked and aligned. This bit returns 1 when the logical PCS has locked and
aligned all associated receive lanes; returns 0 otherwise. For all other PCS types, this
bit always returns 0. */
uint64_t reserved_4_11 : 8;
uint64_t block_lock : 4; /**< [ 3: 0](RO/H) Block-lock status for PCS lanes 3-0:
0 = Not locked.
1 = Locked. */
#else /* Word 0 - Little Endian */
uint64_t block_lock : 4; /**< [ 3: 0](RO/H) Block-lock status for PCS lanes 3-0:
0 = Not locked.
1 = Locked. */
uint64_t reserved_4_11 : 8;
uint64_t alignd : 1; /**< [ 12: 12](RO/H) All lanes are locked and aligned. This bit returns 1 when the logical PCS has locked and
aligned all associated receive lanes; returns 0 otherwise. For all other PCS types, this
bit always returns 0. */
uint64_t reserved_13_31 : 19;
uint64_t marker_lock : 4; /**< [ 35: 32](RO/H) Marker-locked status for PCS lanes 3-0.
0 = Not locked.
1 = Locked. */
uint64_t reserved_36_63 : 28;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_br_algn_status_s cn; */
};
typedef union bdk_bgxx_spux_br_algn_status bdk_bgxx_spux_br_algn_status_t;
static inline uint64_t BDK_BGXX_SPUX_BR_ALGN_STATUS(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_BR_ALGN_STATUS(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010050ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0010050ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010050ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_BR_ALGN_STATUS", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_BR_ALGN_STATUS(a,b) bdk_bgxx_spux_br_algn_status_t
#define bustype_BDK_BGXX_SPUX_BR_ALGN_STATUS(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_BR_ALGN_STATUS(a,b) "BGXX_SPUX_BR_ALGN_STATUS"
#define device_bar_BDK_BGXX_SPUX_BR_ALGN_STATUS(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_BR_ALGN_STATUS(a,b) (a)
#define arguments_BDK_BGXX_SPUX_BR_ALGN_STATUS(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_br_bip_err_cnt
*
* BGX SPU 40GBASE-R BIP Error-Counter Registers
* This register implements the IEEE 802.3 BIP error-counter registers for PCS lanes 0-3
* (3.200-3.203). It is valid only when the LPCS type is 40GBASE-R
* (BGX()_CMR()_CONFIG[LMAC_TYPE] = 0x4), and always returns 0x0 for all other LPCS
* types. The counters are indexed by the RX PCS lane number based on the Alignment Marker
* detected on each lane and captured in BGX()_SPU()_BR_LANE_MAP. Each counter counts the
* BIP errors for its PCS lane, and is held at all ones in case of overflow. The counters are
* reset to all 0s when this register is read by software.
*
* The reset operation takes precedence over the increment operation; if the register is read on
* the same clock cycle as an increment operation, the counter is reset to all 0s and the
* increment operation is lost. The counters are writable for test purposes, rather than read-
* only as specified in IEEE 802.3.
*/
union bdk_bgxx_spux_br_bip_err_cnt
{
uint64_t u;
struct bdk_bgxx_spux_br_bip_err_cnt_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t bip_err_cnt_ln3 : 16; /**< [ 63: 48](RC/W/H) BIP error counter for lane on which PCS lane 3 markers are received. */
uint64_t bip_err_cnt_ln2 : 16; /**< [ 47: 32](RC/W/H) BIP error counter for lane on which PCS lane 2 markers are received. */
uint64_t bip_err_cnt_ln1 : 16; /**< [ 31: 16](RC/W/H) BIP error counter for lane on which PCS lane 1 markers are received. */
uint64_t bip_err_cnt_ln0 : 16; /**< [ 15: 0](RC/W/H) BIP error counter for lane on which PCS lane 0 markers are received. */
#else /* Word 0 - Little Endian */
uint64_t bip_err_cnt_ln0 : 16; /**< [ 15: 0](RC/W/H) BIP error counter for lane on which PCS lane 0 markers are received. */
uint64_t bip_err_cnt_ln1 : 16; /**< [ 31: 16](RC/W/H) BIP error counter for lane on which PCS lane 1 markers are received. */
uint64_t bip_err_cnt_ln2 : 16; /**< [ 47: 32](RC/W/H) BIP error counter for lane on which PCS lane 2 markers are received. */
uint64_t bip_err_cnt_ln3 : 16; /**< [ 63: 48](RC/W/H) BIP error counter for lane on which PCS lane 3 markers are received. */
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_br_bip_err_cnt_s cn; */
};
typedef union bdk_bgxx_spux_br_bip_err_cnt bdk_bgxx_spux_br_bip_err_cnt_t;
static inline uint64_t BDK_BGXX_SPUX_BR_BIP_ERR_CNT(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_BR_BIP_ERR_CNT(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010058ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0010058ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010058ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_BR_BIP_ERR_CNT", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_BR_BIP_ERR_CNT(a,b) bdk_bgxx_spux_br_bip_err_cnt_t
#define bustype_BDK_BGXX_SPUX_BR_BIP_ERR_CNT(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_BR_BIP_ERR_CNT(a,b) "BGXX_SPUX_BR_BIP_ERR_CNT"
#define device_bar_BDK_BGXX_SPUX_BR_BIP_ERR_CNT(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_BR_BIP_ERR_CNT(a,b) (a)
#define arguments_BDK_BGXX_SPUX_BR_BIP_ERR_CNT(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_br_lane_map
*
* BGX SPU 40GBASE-R Lane-Mapping Registers
* This register implements the IEEE 802.3 lane 0-3 mapping registers (3.400-3.403). It is valid
* only when the LPCS type is 40GBASE-R (BGX()_CMR()_CONFIG[LMAC_TYPE] = 0x4), and always
* returns 0x0 for all other LPCS types. The LNx_MAPPING field for each programmed PCS lane
* (called service interface in 802.3ba-2010) is valid when that lane has achieved alignment
* marker lock on the receive side (i.e. the associated
* BGX()_SPU()_BR_ALGN_STATUS[MARKER_LOCK] = 1), and is invalid otherwise. When valid, it
* returns the actual detected receive PCS lane number based on the received alignment marker
* contents received on that service interface.
*
* The mapping is flexible because IEEE 802.3 allows multilane BASE-R receive lanes to be re-
* ordered. Note that for the transmit side, each PCS lane is mapped to a physical SerDes lane
* based on the programming of BGX()_CMR()_CONFIG[LANE_TO_SDS]. For the receive side,
* BGX()_CMR()_CONFIG[LANE_TO_SDS] specifies the service interface to physical SerDes
* lane mapping, and this register specifies the service interface to PCS lane mapping.
*/
union bdk_bgxx_spux_br_lane_map
{
uint64_t u;
struct bdk_bgxx_spux_br_lane_map_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_54_63 : 10;
uint64_t ln3_mapping : 6; /**< [ 53: 48](RO/H) PCS lane number received on service interface 3 */
uint64_t reserved_38_47 : 10;
uint64_t ln2_mapping : 6; /**< [ 37: 32](RO/H) PCS lane number received on service interface 2 */
uint64_t reserved_22_31 : 10;
uint64_t ln1_mapping : 6; /**< [ 21: 16](RO/H) PCS lane number received on service interface 1 */
uint64_t reserved_6_15 : 10;
uint64_t ln0_mapping : 6; /**< [ 5: 0](RO/H) PCS lane number received on service interface 0 */
#else /* Word 0 - Little Endian */
uint64_t ln0_mapping : 6; /**< [ 5: 0](RO/H) PCS lane number received on service interface 0 */
uint64_t reserved_6_15 : 10;
uint64_t ln1_mapping : 6; /**< [ 21: 16](RO/H) PCS lane number received on service interface 1 */
uint64_t reserved_22_31 : 10;
uint64_t ln2_mapping : 6; /**< [ 37: 32](RO/H) PCS lane number received on service interface 2 */
uint64_t reserved_38_47 : 10;
uint64_t ln3_mapping : 6; /**< [ 53: 48](RO/H) PCS lane number received on service interface 3 */
uint64_t reserved_54_63 : 10;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_br_lane_map_s cn; */
};
typedef union bdk_bgxx_spux_br_lane_map bdk_bgxx_spux_br_lane_map_t;
static inline uint64_t BDK_BGXX_SPUX_BR_LANE_MAP(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_BR_LANE_MAP(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010060ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0010060ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010060ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_BR_LANE_MAP", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_BR_LANE_MAP(a,b) bdk_bgxx_spux_br_lane_map_t
#define bustype_BDK_BGXX_SPUX_BR_LANE_MAP(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_BR_LANE_MAP(a,b) "BGXX_SPUX_BR_LANE_MAP"
#define device_bar_BDK_BGXX_SPUX_BR_LANE_MAP(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_BR_LANE_MAP(a,b) (a)
#define arguments_BDK_BGXX_SPUX_BR_LANE_MAP(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_br_pmd_control
*
* BGX SPU 40GBASE-R PMD Control Registers
*/
union bdk_bgxx_spux_br_pmd_control
{
uint64_t u;
struct bdk_bgxx_spux_br_pmd_control_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_2_63 : 62;
uint64_t train_en : 1; /**< [ 1: 1](R/W) BASE-R training enable. */
uint64_t train_restart : 1; /**< [ 0: 0](R/W1S/H) BASE-R training restart. Writing a 1 to this bit restarts the training process if
[TRAIN_EN] is also set. This is a self-clearing bit. Software should
wait a minimum of 1.7ms after BGX()_SPU()_INT[TRAINING_FAILURE] is set before
restarting the training process. */
#else /* Word 0 - Little Endian */
uint64_t train_restart : 1; /**< [ 0: 0](R/W1S/H) BASE-R training restart. Writing a 1 to this bit restarts the training process if
[TRAIN_EN] is also set. This is a self-clearing bit. Software should
wait a minimum of 1.7ms after BGX()_SPU()_INT[TRAINING_FAILURE] is set before
restarting the training process. */
uint64_t train_en : 1; /**< [ 1: 1](R/W) BASE-R training enable. */
uint64_t reserved_2_63 : 62;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_br_pmd_control_s cn; */
};
typedef union bdk_bgxx_spux_br_pmd_control bdk_bgxx_spux_br_pmd_control_t;
static inline uint64_t BDK_BGXX_SPUX_BR_PMD_CONTROL(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_BR_PMD_CONTROL(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010068ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0010068ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010068ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_BR_PMD_CONTROL", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_BR_PMD_CONTROL(a,b) bdk_bgxx_spux_br_pmd_control_t
#define bustype_BDK_BGXX_SPUX_BR_PMD_CONTROL(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_BR_PMD_CONTROL(a,b) "BGXX_SPUX_BR_PMD_CONTROL"
#define device_bar_BDK_BGXX_SPUX_BR_PMD_CONTROL(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_BR_PMD_CONTROL(a,b) (a)
#define arguments_BDK_BGXX_SPUX_BR_PMD_CONTROL(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_br_pmd_ld_cup
*
* BGX SPU 40GBASE-R PMD Local Device Coefficient Update Registers
* This register implements 802.3 MDIO register 1.153 for 10GBASE-R (when
* BGX()_CMR()_CONFIG[LMAC_TYPE] = 10G_R)
* and MDIO registers 1.1300-1.1303 for 40GBASE-R (when
* BGX()_CMR()_CONFIG[LMAC_TYPE] = 40G_R). It is automatically cleared at the start of training.
* When link training
* is in progress, each field reflects the contents of the coefficient update field in the
* associated lane's outgoing training frame. The fields in this register are read/write even
* though they are specified as read-only in 802.3.
*
* If BGX()_SPU_DBG_CONTROL[BR_PMD_TRAIN_SOFT_EN] is set, then this register must be updated
* by software during link training and hardware updates are disabled. If
* BGX()_SPU_DBG_CONTROL[BR_PMD_TRAIN_SOFT_EN] is clear, this register is automatically
* updated by hardware, and it should not be written by software. The lane fields in this
* register are indexed by logical PCS lane ID.
*
* The lane 0 field (LN0_*) is valid for both
* 10GBASE-R and 40GBASE-R. The remaining fields (LN1_*, LN2_*, LN3_*) are only valid for
* 40GBASE-R.
*/
union bdk_bgxx_spux_br_pmd_ld_cup
{
uint64_t u;
struct bdk_bgxx_spux_br_pmd_ld_cup_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t ln3_cup : 16; /**< [ 63: 48](R/W/H) PCS lane 3 coefficient update: format defined by BGX_SPU_BR_TRAIN_CUP_S. Not valid for
10GBASE-R. */
uint64_t ln2_cup : 16; /**< [ 47: 32](R/W/H) PCS lane 2 coefficient update: format defined by BGX_SPU_BR_TRAIN_CUP_S. Not valid for
10GBASE-R. */
uint64_t ln1_cup : 16; /**< [ 31: 16](R/W/H) PCS lane 1 coefficient update: format defined by BGX_SPU_BR_TRAIN_CUP_S. Not valid for
10GBASE-R. */
uint64_t ln0_cup : 16; /**< [ 15: 0](R/W/H) PCS lane 0 coefficient update: format defined by BGX_SPU_BR_TRAIN_CUP_S. */
#else /* Word 0 - Little Endian */
uint64_t ln0_cup : 16; /**< [ 15: 0](R/W/H) PCS lane 0 coefficient update: format defined by BGX_SPU_BR_TRAIN_CUP_S. */
uint64_t ln1_cup : 16; /**< [ 31: 16](R/W/H) PCS lane 1 coefficient update: format defined by BGX_SPU_BR_TRAIN_CUP_S. Not valid for
10GBASE-R. */
uint64_t ln2_cup : 16; /**< [ 47: 32](R/W/H) PCS lane 2 coefficient update: format defined by BGX_SPU_BR_TRAIN_CUP_S. Not valid for
10GBASE-R. */
uint64_t ln3_cup : 16; /**< [ 63: 48](R/W/H) PCS lane 3 coefficient update: format defined by BGX_SPU_BR_TRAIN_CUP_S. Not valid for
10GBASE-R. */
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_br_pmd_ld_cup_s cn; */
};
typedef union bdk_bgxx_spux_br_pmd_ld_cup bdk_bgxx_spux_br_pmd_ld_cup_t;
static inline uint64_t BDK_BGXX_SPUX_BR_PMD_LD_CUP(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_BR_PMD_LD_CUP(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010088ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0010088ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010088ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_BR_PMD_LD_CUP", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_BR_PMD_LD_CUP(a,b) bdk_bgxx_spux_br_pmd_ld_cup_t
#define bustype_BDK_BGXX_SPUX_BR_PMD_LD_CUP(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_BR_PMD_LD_CUP(a,b) "BGXX_SPUX_BR_PMD_LD_CUP"
#define device_bar_BDK_BGXX_SPUX_BR_PMD_LD_CUP(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_BR_PMD_LD_CUP(a,b) (a)
#define arguments_BDK_BGXX_SPUX_BR_PMD_LD_CUP(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_br_pmd_ld_rep
*
* BGX SPU 40GBASE-R PMD Local Device Status Report Registers
* This register implements 802.3 MDIO register 1.154 for 10GBASE-R (when
* BGX()_CMR()_CONFIG[LMAC_TYPE] = 10G_R) and MDIO registers 1.1400-1.1403 for 40GBASE-R
* (when BGX()_CMR()_CONFIG[LMAC_TYPE] = 40G_R). It is automatically cleared at the start of
* training. Each field
* reflects the contents of the status report field in the associated lane's outgoing training
* frame. The fields in this register are read/write even though they are specified as read-only
* in 802.3. If BGX()_SPU_DBG_CONTROL[BR_PMD_TRAIN_SOFT_EN] is set, then this register must
* be updated by software during link training and hardware updates are disabled. If
* BGX()_SPU_DBG_CONTROL[BR_PMD_TRAIN_SOFT_EN] is clear, this register is automatically
* updated by hardware, and it should not be written by software. The lane fields in this
* register are indexed by logical PCS lane ID.
*
* The lane 0 field (LN0_*) is valid for both
* 10GBASE-R and 40GBASE-R. The remaining fields (LN1_*, LN2_*, LN3_*) are only valid for
* 40GBASE-R.
*/
union bdk_bgxx_spux_br_pmd_ld_rep
{
uint64_t u;
struct bdk_bgxx_spux_br_pmd_ld_rep_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t ln3_rep : 16; /**< [ 63: 48](R/W/H) PCS lane 3 status report: format defined by BGX_SPU_BR_TRAIN_REP_S. Not valid for
10GBASE-R. */
uint64_t ln2_rep : 16; /**< [ 47: 32](R/W/H) PCS lane 2 status report: format defined by BGX_SPU_BR_TRAIN_REP_S. Not valid for
10GBASE-R. */
uint64_t ln1_rep : 16; /**< [ 31: 16](R/W/H) PCS lane 1 status report: format defined by BGX_SPU_BR_TRAIN_REP_S. Not valid for
10GBASE-R. */
uint64_t ln0_rep : 16; /**< [ 15: 0](R/W/H) PCS lane 0 status report: format defined by BGX_SPU_BR_TRAIN_REP_S. */
#else /* Word 0 - Little Endian */
uint64_t ln0_rep : 16; /**< [ 15: 0](R/W/H) PCS lane 0 status report: format defined by BGX_SPU_BR_TRAIN_REP_S. */
uint64_t ln1_rep : 16; /**< [ 31: 16](R/W/H) PCS lane 1 status report: format defined by BGX_SPU_BR_TRAIN_REP_S. Not valid for
10GBASE-R. */
uint64_t ln2_rep : 16; /**< [ 47: 32](R/W/H) PCS lane 2 status report: format defined by BGX_SPU_BR_TRAIN_REP_S. Not valid for
10GBASE-R. */
uint64_t ln3_rep : 16; /**< [ 63: 48](R/W/H) PCS lane 3 status report: format defined by BGX_SPU_BR_TRAIN_REP_S. Not valid for
10GBASE-R. */
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_br_pmd_ld_rep_s cn; */
};
typedef union bdk_bgxx_spux_br_pmd_ld_rep bdk_bgxx_spux_br_pmd_ld_rep_t;
static inline uint64_t BDK_BGXX_SPUX_BR_PMD_LD_REP(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_BR_PMD_LD_REP(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010090ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0010090ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010090ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_BR_PMD_LD_REP", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_BR_PMD_LD_REP(a,b) bdk_bgxx_spux_br_pmd_ld_rep_t
#define bustype_BDK_BGXX_SPUX_BR_PMD_LD_REP(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_BR_PMD_LD_REP(a,b) "BGXX_SPUX_BR_PMD_LD_REP"
#define device_bar_BDK_BGXX_SPUX_BR_PMD_LD_REP(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_BR_PMD_LD_REP(a,b) (a)
#define arguments_BDK_BGXX_SPUX_BR_PMD_LD_REP(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_br_pmd_lp_cup
*
* BGX SPU 40GBASE-R PMD Link Partner Coefficient Update Registers
* This register implements 802.3 MDIO register 1.152 for 10GBASE-R (when
* BGX()_CMR()_CONFIG[LMAC_TYPE] = 10G_R)
* and MDIO registers 1.1100-1.1103 for 40GBASE-R (when
* BGX()_CMR()_CONFIG[LMAC_TYPE] = 40G_R). It is automatically cleared at the start of training.
* Each field reflects
* the contents of the coefficient update field in the lane's most recently received training
* frame. This register should not be written when link training is enabled, i.e. when
* BGX()_SPU()_BR_PMD_CONTROL[TRAIN_EN] is set. The lane fields in this register are indexed by
* logical PCS lane ID.
*
* The lane 0 field (LN0_*) is valid for both 10GBASE-R and 40GBASE-R. The remaining fields
* (LN1_*, LN2_*, LN3_*) are only valid for 40GBASE-R.
*/
union bdk_bgxx_spux_br_pmd_lp_cup
{
uint64_t u;
struct bdk_bgxx_spux_br_pmd_lp_cup_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t ln3_cup : 16; /**< [ 63: 48](R/W/H) PCS lane 3 coefficient update: format defined by BGX_SPU_BR_TRAIN_CUP_S. Not valid for
10GBASE-R. */
uint64_t ln2_cup : 16; /**< [ 47: 32](R/W/H) PCS lane 2 coefficient update: format defined by BGX_SPU_BR_TRAIN_CUP_S. Not valid for
10GBASE-R. */
uint64_t ln1_cup : 16; /**< [ 31: 16](R/W/H) PCS lane 1 coefficient update: format defined by BGX_SPU_BR_TRAIN_CUP_S. Not valid for
10GBASE-R. */
uint64_t ln0_cup : 16; /**< [ 15: 0](R/W/H) PCS lane 0 coefficient update: format defined by BGX_SPU_BR_TRAIN_CUP_S. */
#else /* Word 0 - Little Endian */
uint64_t ln0_cup : 16; /**< [ 15: 0](R/W/H) PCS lane 0 coefficient update: format defined by BGX_SPU_BR_TRAIN_CUP_S. */
uint64_t ln1_cup : 16; /**< [ 31: 16](R/W/H) PCS lane 1 coefficient update: format defined by BGX_SPU_BR_TRAIN_CUP_S. Not valid for
10GBASE-R. */
uint64_t ln2_cup : 16; /**< [ 47: 32](R/W/H) PCS lane 2 coefficient update: format defined by BGX_SPU_BR_TRAIN_CUP_S. Not valid for
10GBASE-R. */
uint64_t ln3_cup : 16; /**< [ 63: 48](R/W/H) PCS lane 3 coefficient update: format defined by BGX_SPU_BR_TRAIN_CUP_S. Not valid for
10GBASE-R. */
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_br_pmd_lp_cup_s cn; */
};
typedef union bdk_bgxx_spux_br_pmd_lp_cup bdk_bgxx_spux_br_pmd_lp_cup_t;
static inline uint64_t BDK_BGXX_SPUX_BR_PMD_LP_CUP(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_BR_PMD_LP_CUP(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010078ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0010078ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010078ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_BR_PMD_LP_CUP", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_BR_PMD_LP_CUP(a,b) bdk_bgxx_spux_br_pmd_lp_cup_t
#define bustype_BDK_BGXX_SPUX_BR_PMD_LP_CUP(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_BR_PMD_LP_CUP(a,b) "BGXX_SPUX_BR_PMD_LP_CUP"
#define device_bar_BDK_BGXX_SPUX_BR_PMD_LP_CUP(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_BR_PMD_LP_CUP(a,b) (a)
#define arguments_BDK_BGXX_SPUX_BR_PMD_LP_CUP(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_br_pmd_lp_rep
*
* BGX SPU 40GBASE-R PMD Link Partner Status Report Registers
* This register implements 802.3 MDIO register 1.153 for 10GBASE-R (when
* BGX()_CMR()_CONFIG[LMAC_TYPE] = 10G_R)
* and MDIO registers 1.1200-1.1203 for 40GBASE-R (when
* BGX()_CMR()_CONFIG[LMAC_TYPE] = 40G_R). It is automatically cleared at the start of training.
* Each field reflects
* the contents of the status report field in the associated lane's most recently received
* training frame. The lane fields in this register are indexed by logical PCS lane ID.
*
* The lane
* 0 field (LN0_*) is valid for both 10GBASE-R and 40GBASE-R. The remaining fields (LN1_*, LN2_*,
* LN3_*) are only valid for 40GBASE-R.
*/
union bdk_bgxx_spux_br_pmd_lp_rep
{
uint64_t u;
struct bdk_bgxx_spux_br_pmd_lp_rep_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t ln3_rep : 16; /**< [ 63: 48](RO/H) PCS lane 3 status report: format defined by BGX_SPU_BR_TRAIN_REP_S. Not valid for
10GBASE-R. */
uint64_t ln2_rep : 16; /**< [ 47: 32](RO/H) PCS lane 2 status report: format defined by BGX_SPU_BR_TRAIN_REP_S. Not valid for
10GBASE-R. */
uint64_t ln1_rep : 16; /**< [ 31: 16](RO/H) PCS lane 1 status report: format defined by BGX_SPU_BR_TRAIN_REP_S. Not valid for
10GBASE-R. */
uint64_t ln0_rep : 16; /**< [ 15: 0](RO/H) PCS lane 0 status report: format defined by BGX_SPU_BR_TRAIN_REP_S. */
#else /* Word 0 - Little Endian */
uint64_t ln0_rep : 16; /**< [ 15: 0](RO/H) PCS lane 0 status report: format defined by BGX_SPU_BR_TRAIN_REP_S. */
uint64_t ln1_rep : 16; /**< [ 31: 16](RO/H) PCS lane 1 status report: format defined by BGX_SPU_BR_TRAIN_REP_S. Not valid for
10GBASE-R. */
uint64_t ln2_rep : 16; /**< [ 47: 32](RO/H) PCS lane 2 status report: format defined by BGX_SPU_BR_TRAIN_REP_S. Not valid for
10GBASE-R. */
uint64_t ln3_rep : 16; /**< [ 63: 48](RO/H) PCS lane 3 status report: format defined by BGX_SPU_BR_TRAIN_REP_S. Not valid for
10GBASE-R. */
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_br_pmd_lp_rep_s cn; */
};
typedef union bdk_bgxx_spux_br_pmd_lp_rep bdk_bgxx_spux_br_pmd_lp_rep_t;
static inline uint64_t BDK_BGXX_SPUX_BR_PMD_LP_REP(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_BR_PMD_LP_REP(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010080ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0010080ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010080ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_BR_PMD_LP_REP", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_BR_PMD_LP_REP(a,b) bdk_bgxx_spux_br_pmd_lp_rep_t
#define bustype_BDK_BGXX_SPUX_BR_PMD_LP_REP(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_BR_PMD_LP_REP(a,b) "BGXX_SPUX_BR_PMD_LP_REP"
#define device_bar_BDK_BGXX_SPUX_BR_PMD_LP_REP(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_BR_PMD_LP_REP(a,b) (a)
#define arguments_BDK_BGXX_SPUX_BR_PMD_LP_REP(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_br_pmd_status
*
* BGX SPU 40GBASE-R PMD Status Registers
* The lane fields in this register are indexed by logical PCS lane ID. The lane 0 field (LN0_*)
* is valid for both 10GBASE-R and 40GBASE-R. The remaining fields (LN1_*, LN2_*, LN3_*) are only
* valid for 40GBASE-R.
*/
union bdk_bgxx_spux_br_pmd_status
{
uint64_t u;
struct bdk_bgxx_spux_br_pmd_status_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t ln3_train_status : 4; /**< [ 15: 12](RO/H) PCS lane 3 link training status. Format defined by BGX_SPU_BR_LANE_TRAIN_STATUS_S. Not
valid for 10GBASE-R. */
uint64_t ln2_train_status : 4; /**< [ 11: 8](RO/H) PCS lane 2 link training status. Format defined by BGX_SPU_BR_LANE_TRAIN_STATUS_S. Not
valid for 10GBASE-R. */
uint64_t ln1_train_status : 4; /**< [ 7: 4](RO/H) PCS lane 1 link training status. Format defined by BGX_SPU_BR_LANE_TRAIN_STATUS_S. Not
valid for 10GBASE-R. */
uint64_t ln0_train_status : 4; /**< [ 3: 0](RO/H) PCS lane 0 link training status. Format defined by BGX_SPU_BR_LANE_TRAIN_STATUS_S. */
#else /* Word 0 - Little Endian */
uint64_t ln0_train_status : 4; /**< [ 3: 0](RO/H) PCS lane 0 link training status. Format defined by BGX_SPU_BR_LANE_TRAIN_STATUS_S. */
uint64_t ln1_train_status : 4; /**< [ 7: 4](RO/H) PCS lane 1 link training status. Format defined by BGX_SPU_BR_LANE_TRAIN_STATUS_S. Not
valid for 10GBASE-R. */
uint64_t ln2_train_status : 4; /**< [ 11: 8](RO/H) PCS lane 2 link training status. Format defined by BGX_SPU_BR_LANE_TRAIN_STATUS_S. Not
valid for 10GBASE-R. */
uint64_t ln3_train_status : 4; /**< [ 15: 12](RO/H) PCS lane 3 link training status. Format defined by BGX_SPU_BR_LANE_TRAIN_STATUS_S. Not
valid for 10GBASE-R. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_br_pmd_status_s cn; */
};
typedef union bdk_bgxx_spux_br_pmd_status bdk_bgxx_spux_br_pmd_status_t;
static inline uint64_t BDK_BGXX_SPUX_BR_PMD_STATUS(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_BR_PMD_STATUS(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010070ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0010070ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010070ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_BR_PMD_STATUS", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_BR_PMD_STATUS(a,b) bdk_bgxx_spux_br_pmd_status_t
#define bustype_BDK_BGXX_SPUX_BR_PMD_STATUS(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_BR_PMD_STATUS(a,b) "BGXX_SPUX_BR_PMD_STATUS"
#define device_bar_BDK_BGXX_SPUX_BR_PMD_STATUS(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_BR_PMD_STATUS(a,b) (a)
#define arguments_BDK_BGXX_SPUX_BR_PMD_STATUS(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_br_status1
*
* BGX SPU BASE-R Status 1 Registers
*/
union bdk_bgxx_spux_br_status1
{
uint64_t u;
struct bdk_bgxx_spux_br_status1_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_13_63 : 51;
uint64_t rcv_lnk : 1; /**< [ 12: 12](RO/H) BASE-R receive link status.
0 = BASE-R PCS receive-link down.
1 = BASE-R PCS receive-link up.
This bit is a reflection of the PCS_status variable defined in IEEE 802.3 sections
49.2.14.1 and 82.3.1. */
uint64_t reserved_4_11 : 8;
uint64_t prbs9 : 1; /**< [ 3: 3](RO) 10GBASE-R PRBS9 pattern testing ability. Always 0; PRBS9 pattern testing is not supported. */
uint64_t prbs31 : 1; /**< [ 2: 2](RO) 10GBASE-R PRBS31 pattern testing ability. Always 0; PRBS31 pattern testing is not supported. */
uint64_t hi_ber : 1; /**< [ 1: 1](RO/H) BASE-R PCS high bit-error rate.
0 = 64/66 bit receiver is detecting a bit-error rate of \< 10.4.
1 = 64/66 bit receiver is detecting a bit-error rate of \>= 10.4.
This bit is a direct reflection of the state of the HI_BER variable in the 64 B/66 B state
diagram and is defined in IEEE 802.3 sections 49.2.13.2.2 and 82.2.18.2.2. */
uint64_t blk_lock : 1; /**< [ 0: 0](RO/H) BASE-R PCS block lock.
0 = No block lock.
1 = 64/66 bit receiver for BASE-R has block lock.
This bit is a direct reflection of the state of the BLOCK_LOCK variable in the 64 B/66 B
state diagram and is defined in IEEE 802.3 sections 49.2.13.2.2 and 82.2.18.2.2.
For a multilane logical PCS (i.e. 40GBASE-R), this bit indicates that the receiver has
both block lock and alignment for all lanes and is identical to
BGX()_SPU()_BR_ALGN_STATUS[ALIGND]. */
#else /* Word 0 - Little Endian */
uint64_t blk_lock : 1; /**< [ 0: 0](RO/H) BASE-R PCS block lock.
0 = No block lock.
1 = 64/66 bit receiver for BASE-R has block lock.
This bit is a direct reflection of the state of the BLOCK_LOCK variable in the 64 B/66 B
state diagram and is defined in IEEE 802.3 sections 49.2.13.2.2 and 82.2.18.2.2.
For a multilane logical PCS (i.e. 40GBASE-R), this bit indicates that the receiver has
both block lock and alignment for all lanes and is identical to
BGX()_SPU()_BR_ALGN_STATUS[ALIGND]. */
uint64_t hi_ber : 1; /**< [ 1: 1](RO/H) BASE-R PCS high bit-error rate.
0 = 64/66 bit receiver is detecting a bit-error rate of \< 10.4.
1 = 64/66 bit receiver is detecting a bit-error rate of \>= 10.4.
This bit is a direct reflection of the state of the HI_BER variable in the 64 B/66 B state
diagram and is defined in IEEE 802.3 sections 49.2.13.2.2 and 82.2.18.2.2. */
uint64_t prbs31 : 1; /**< [ 2: 2](RO) 10GBASE-R PRBS31 pattern testing ability. Always 0; PRBS31 pattern testing is not supported. */
uint64_t prbs9 : 1; /**< [ 3: 3](RO) 10GBASE-R PRBS9 pattern testing ability. Always 0; PRBS9 pattern testing is not supported. */
uint64_t reserved_4_11 : 8;
uint64_t rcv_lnk : 1; /**< [ 12: 12](RO/H) BASE-R receive link status.
0 = BASE-R PCS receive-link down.
1 = BASE-R PCS receive-link up.
This bit is a reflection of the PCS_status variable defined in IEEE 802.3 sections
49.2.14.1 and 82.3.1. */
uint64_t reserved_13_63 : 51;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_br_status1_s cn; */
};
typedef union bdk_bgxx_spux_br_status1 bdk_bgxx_spux_br_status1_t;
static inline uint64_t BDK_BGXX_SPUX_BR_STATUS1(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_BR_STATUS1(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010030ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0010030ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010030ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_BR_STATUS1", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_BR_STATUS1(a,b) bdk_bgxx_spux_br_status1_t
#define bustype_BDK_BGXX_SPUX_BR_STATUS1(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_BR_STATUS1(a,b) "BGXX_SPUX_BR_STATUS1"
#define device_bar_BDK_BGXX_SPUX_BR_STATUS1(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_BR_STATUS1(a,b) (a)
#define arguments_BDK_BGXX_SPUX_BR_STATUS1(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_br_status2
*
* BGX SPU BASE-R Status 2 Registers
* This register implements a combination of the following IEEE 802.3 registers:
* * BASE-R PCS status 2 (MDIO address 3.33).
* * BASE-R BER high-order counter (MDIO address 3.44).
* * Errored-blocks high-order counter (MDIO address 3.45).
*
* Note that the relative locations of some fields have been moved from IEEE 802.3 in order to
* make the register layout more software friendly: the BER counter high-order and low-order bits
* from sections 3.44 and 3.33 have been combined into the contiguous, 22-bit [BER_CNT] field;
* likewise, the errored-blocks counter high-order and low-order bits from section 3.45 have been
* combined into the contiguous, 22-bit [ERR_BLKS] field.
*/
union bdk_bgxx_spux_br_status2
{
uint64_t u;
struct bdk_bgxx_spux_br_status2_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_62_63 : 2;
uint64_t err_blks : 22; /**< [ 61: 40](RC/W/H) Errored-blocks counter. This is the BASE-R errored-blocks counter as defined by the
errored_block_count variable specified in IEEE 802.3 sections 49.2.14.2 and 82.2.18.2.4.
It
increments by one on each block for which the BASE-R receive state machine, specified in Std
802.3 diagrams 49-15 and 82-15, enters the RX_E state.
Back-to-back blocks in the RX_E state are counted as transitions from RX_E to RX_E and
keep incrementing the counter. The counter is reset to all zeros after this register is read
by software.
The reset operation takes precedence over the increment operation: if the register is read
on the same clock cycle as an increment operation, the counter is reset to all zeros and the
increment operation is lost.
This field is writable for test purposes, rather than read-only as specified in IEEE
802.3. */
uint64_t reserved_38_39 : 2;
uint64_t ber_cnt : 22; /**< [ 37: 16](RC/W/H) Bit-error-rate counter. This is the BASE-R BER counter as defined by the BER_COUNT
variable in IEEE 802.3 sections 49.2.14.2 and 82.2.18.2.4. The counter is reset to all zeros
after this register is read by software, and is held at all ones in case of overflow.
The reset operation takes precedence over the increment operation: if the register is read
on the same clock cycle an increment operation, the counter is reset to all zeros and the
increment operation is lost.
This field is writable for test purposes, rather than read-only as specified in IEEE
802.3. */
uint64_t latched_lock : 1; /**< [ 15: 15](R/W1S/H) Latched-block lock.
0 = No block.
1 = 64/66 bit receiver for BASE-R has block lock.
This is a latching-low version of BGX()_SPU()_BR_STATUS1[BLK_LOCK]; it stays clear
until a write-1-to-set by software. */
uint64_t latched_ber : 1; /**< [ 14: 14](R/W1C/H) Latched-high bit-error rate.
0 = Not a high BER.
1 = 64/66 bit receiver is detecting a high BER.
This is a latching-high version of BGX()_SPU()_BR_STATUS1[HI_BER]; it stays set until
a write-1-to-clear by software. */
uint64_t reserved_0_13 : 14;
#else /* Word 0 - Little Endian */
uint64_t reserved_0_13 : 14;
uint64_t latched_ber : 1; /**< [ 14: 14](R/W1C/H) Latched-high bit-error rate.
0 = Not a high BER.
1 = 64/66 bit receiver is detecting a high BER.
This is a latching-high version of BGX()_SPU()_BR_STATUS1[HI_BER]; it stays set until
a write-1-to-clear by software. */
uint64_t latched_lock : 1; /**< [ 15: 15](R/W1S/H) Latched-block lock.
0 = No block.
1 = 64/66 bit receiver for BASE-R has block lock.
This is a latching-low version of BGX()_SPU()_BR_STATUS1[BLK_LOCK]; it stays clear
until a write-1-to-set by software. */
uint64_t ber_cnt : 22; /**< [ 37: 16](RC/W/H) Bit-error-rate counter. This is the BASE-R BER counter as defined by the BER_COUNT
variable in IEEE 802.3 sections 49.2.14.2 and 82.2.18.2.4. The counter is reset to all zeros
after this register is read by software, and is held at all ones in case of overflow.
The reset operation takes precedence over the increment operation: if the register is read
on the same clock cycle an increment operation, the counter is reset to all zeros and the
increment operation is lost.
This field is writable for test purposes, rather than read-only as specified in IEEE
802.3. */
uint64_t reserved_38_39 : 2;
uint64_t err_blks : 22; /**< [ 61: 40](RC/W/H) Errored-blocks counter. This is the BASE-R errored-blocks counter as defined by the
errored_block_count variable specified in IEEE 802.3 sections 49.2.14.2 and 82.2.18.2.4.
It
increments by one on each block for which the BASE-R receive state machine, specified in Std
802.3 diagrams 49-15 and 82-15, enters the RX_E state.
Back-to-back blocks in the RX_E state are counted as transitions from RX_E to RX_E and
keep incrementing the counter. The counter is reset to all zeros after this register is read
by software.
The reset operation takes precedence over the increment operation: if the register is read
on the same clock cycle as an increment operation, the counter is reset to all zeros and the
increment operation is lost.
This field is writable for test purposes, rather than read-only as specified in IEEE
802.3. */
uint64_t reserved_62_63 : 2;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_br_status2_s cn; */
};
typedef union bdk_bgxx_spux_br_status2 bdk_bgxx_spux_br_status2_t;
static inline uint64_t BDK_BGXX_SPUX_BR_STATUS2(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_BR_STATUS2(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010038ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0010038ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010038ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_BR_STATUS2", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_BR_STATUS2(a,b) bdk_bgxx_spux_br_status2_t
#define bustype_BDK_BGXX_SPUX_BR_STATUS2(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_BR_STATUS2(a,b) "BGXX_SPUX_BR_STATUS2"
#define device_bar_BDK_BGXX_SPUX_BR_STATUS2(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_BR_STATUS2(a,b) (a)
#define arguments_BDK_BGXX_SPUX_BR_STATUS2(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_br_tp_control
*
* BGX SPU BASE-R Test-Pattern Control Registers
* Refer to the test pattern methodology described in 802.3 sections 49.2.8 and 82.2.10.
*/
union bdk_bgxx_spux_br_tp_control
{
uint64_t u;
struct bdk_bgxx_spux_br_tp_control_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_8_63 : 56;
uint64_t scramble_tp : 1; /**< [ 7: 7](R/W) Select scrambled idle test pattern. This bit selects the transmit test pattern used when
[TX_TP_EN] is set:
0 = Square wave test pattern.
1 = Scrambled idle test pattern. */
uint64_t prbs9_tx : 1; /**< [ 6: 6](RO) 10GBASE-R PRBS9 TP transmit enable. Always 0; PRBS9 pattern testing is not supported. */
uint64_t prbs31_rx : 1; /**< [ 5: 5](RO) 10GBASE-R PRBS31 TP receive enable. Always 0; PRBS31 pattern testing is not supported. */
uint64_t prbs31_tx : 1; /**< [ 4: 4](RO) 10GBASE-R PRBS31 TP transmit enable. Always 0; PRBS31 pattern is not supported. */
uint64_t tx_tp_en : 1; /**< [ 3: 3](R/W) Transmit-test-pattern enable. */
uint64_t rx_tp_en : 1; /**< [ 2: 2](R/W) Receive-test-pattern enable. The only supported receive test pattern is the scrambled idle
test pattern. Setting this bit enables checking of that receive pattern. */
uint64_t tp_sel : 1; /**< [ 1: 1](RO/H) Square/PRBS test pattern select. Always 1 to select square wave test pattern; PRBS test
patterns are not supported. */
uint64_t dp_sel : 1; /**< [ 0: 0](RO) Data pattern select. Always 0; PRBS test patterns are not supported. */
#else /* Word 0 - Little Endian */
uint64_t dp_sel : 1; /**< [ 0: 0](RO) Data pattern select. Always 0; PRBS test patterns are not supported. */
uint64_t tp_sel : 1; /**< [ 1: 1](RO/H) Square/PRBS test pattern select. Always 1 to select square wave test pattern; PRBS test
patterns are not supported. */
uint64_t rx_tp_en : 1; /**< [ 2: 2](R/W) Receive-test-pattern enable. The only supported receive test pattern is the scrambled idle
test pattern. Setting this bit enables checking of that receive pattern. */
uint64_t tx_tp_en : 1; /**< [ 3: 3](R/W) Transmit-test-pattern enable. */
uint64_t prbs31_tx : 1; /**< [ 4: 4](RO) 10GBASE-R PRBS31 TP transmit enable. Always 0; PRBS31 pattern is not supported. */
uint64_t prbs31_rx : 1; /**< [ 5: 5](RO) 10GBASE-R PRBS31 TP receive enable. Always 0; PRBS31 pattern testing is not supported. */
uint64_t prbs9_tx : 1; /**< [ 6: 6](RO) 10GBASE-R PRBS9 TP transmit enable. Always 0; PRBS9 pattern testing is not supported. */
uint64_t scramble_tp : 1; /**< [ 7: 7](R/W) Select scrambled idle test pattern. This bit selects the transmit test pattern used when
[TX_TP_EN] is set:
0 = Square wave test pattern.
1 = Scrambled idle test pattern. */
uint64_t reserved_8_63 : 56;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_br_tp_control_s cn; */
};
typedef union bdk_bgxx_spux_br_tp_control bdk_bgxx_spux_br_tp_control_t;
static inline uint64_t BDK_BGXX_SPUX_BR_TP_CONTROL(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_BR_TP_CONTROL(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010040ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0010040ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010040ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_BR_TP_CONTROL", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_BR_TP_CONTROL(a,b) bdk_bgxx_spux_br_tp_control_t
#define bustype_BDK_BGXX_SPUX_BR_TP_CONTROL(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_BR_TP_CONTROL(a,b) "BGXX_SPUX_BR_TP_CONTROL"
#define device_bar_BDK_BGXX_SPUX_BR_TP_CONTROL(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_BR_TP_CONTROL(a,b) (a)
#define arguments_BDK_BGXX_SPUX_BR_TP_CONTROL(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_br_tp_err_cnt
*
* BGX SPU BASE-R Test-Pattern Error-Count Registers
* This register provides the BASE-R PCS test-pattern error counter.
*/
union bdk_bgxx_spux_br_tp_err_cnt
{
uint64_t u;
struct bdk_bgxx_spux_br_tp_err_cnt_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t err_cnt : 16; /**< [ 15: 0](RC/W/H) Error counter. This 16-bit counter contains the number of errors received during a pattern
test. These bits are reset to all zeros when this register is read by software, and they are
held at all ones in the case of overflow.
The test pattern methodology is described in IEEE 802.3, Sections 49.2.12 and 82.2.10.
This
counter counts either block errors or bit errors dependent on the test mode (see Section
49.2.12). The reset operation takes precedence over the increment operation; if the
register is read on the same clock cycle as an increment operation, the counter is reset
to all zeros and the increment operation is lost. This field is writable for test purposes,
rather than read-only as specified in IEEE 802.3. */
#else /* Word 0 - Little Endian */
uint64_t err_cnt : 16; /**< [ 15: 0](RC/W/H) Error counter. This 16-bit counter contains the number of errors received during a pattern
test. These bits are reset to all zeros when this register is read by software, and they are
held at all ones in the case of overflow.
The test pattern methodology is described in IEEE 802.3, Sections 49.2.12 and 82.2.10.
This
counter counts either block errors or bit errors dependent on the test mode (see Section
49.2.12). The reset operation takes precedence over the increment operation; if the
register is read on the same clock cycle as an increment operation, the counter is reset
to all zeros and the increment operation is lost. This field is writable for test purposes,
rather than read-only as specified in IEEE 802.3. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_br_tp_err_cnt_s cn; */
};
typedef union bdk_bgxx_spux_br_tp_err_cnt bdk_bgxx_spux_br_tp_err_cnt_t;
static inline uint64_t BDK_BGXX_SPUX_BR_TP_ERR_CNT(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_BR_TP_ERR_CNT(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010048ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0010048ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010048ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_BR_TP_ERR_CNT", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_BR_TP_ERR_CNT(a,b) bdk_bgxx_spux_br_tp_err_cnt_t
#define bustype_BDK_BGXX_SPUX_BR_TP_ERR_CNT(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_BR_TP_ERR_CNT(a,b) "BGXX_SPUX_BR_TP_ERR_CNT"
#define device_bar_BDK_BGXX_SPUX_BR_TP_ERR_CNT(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_BR_TP_ERR_CNT(a,b) (a)
#define arguments_BDK_BGXX_SPUX_BR_TP_ERR_CNT(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_bx_status
*
* BGX SPU BASE-X Status Registers
*/
union bdk_bgxx_spux_bx_status
{
uint64_t u;
struct bdk_bgxx_spux_bx_status_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_13_63 : 51;
uint64_t alignd : 1; /**< [ 12: 12](RO/H) 10GBASE-X lane-alignment status.
0 = receive lanes not aligned.
1 = receive lanes aligned. */
uint64_t pattst : 1; /**< [ 11: 11](RO) Pattern-testing ability. Always 0; 10GBASE-X pattern is testing not supported. */
uint64_t reserved_4_10 : 7;
uint64_t lsync : 4; /**< [ 3: 0](RO/H) Lane synchronization. BASE-X lane synchronization status for PCS lanes 3-0. Each bit is
set when the associated lane is code-group synchronized, and clear otherwise. If the PCS
type is RXAUI (i.e. the associated BGX()_CMR()_CONFIG[LMAC_TYPE] = RXAUI), then
only lanes 1-0 are valid. */
#else /* Word 0 - Little Endian */
uint64_t lsync : 4; /**< [ 3: 0](RO/H) Lane synchronization. BASE-X lane synchronization status for PCS lanes 3-0. Each bit is
set when the associated lane is code-group synchronized, and clear otherwise. If the PCS
type is RXAUI (i.e. the associated BGX()_CMR()_CONFIG[LMAC_TYPE] = RXAUI), then
only lanes 1-0 are valid. */
uint64_t reserved_4_10 : 7;
uint64_t pattst : 1; /**< [ 11: 11](RO) Pattern-testing ability. Always 0; 10GBASE-X pattern is testing not supported. */
uint64_t alignd : 1; /**< [ 12: 12](RO/H) 10GBASE-X lane-alignment status.
0 = receive lanes not aligned.
1 = receive lanes aligned. */
uint64_t reserved_13_63 : 51;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_bx_status_s cn; */
};
typedef union bdk_bgxx_spux_bx_status bdk_bgxx_spux_bx_status_t;
static inline uint64_t BDK_BGXX_SPUX_BX_STATUS(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_BX_STATUS(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010028ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0010028ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010028ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_BX_STATUS", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_BX_STATUS(a,b) bdk_bgxx_spux_bx_status_t
#define bustype_BDK_BGXX_SPUX_BX_STATUS(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_BX_STATUS(a,b) "BGXX_SPUX_BX_STATUS"
#define device_bar_BDK_BGXX_SPUX_BX_STATUS(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_BX_STATUS(a,b) (a)
#define arguments_BDK_BGXX_SPUX_BX_STATUS(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_control1
*
* BGX SPU Control 1 Registers
*/
union bdk_bgxx_spux_control1
{
uint64_t u;
struct bdk_bgxx_spux_control1_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t reset : 1; /**< [ 15: 15](R/W1S/H) Reset. Setting this bit or BGX()_SPU()_AN_CONTROL[AN_RESET] to 1 causes the
following to happen:
* Resets the logical PCS (LPCS)
* Sets the IEEE 802.3 PCS, FEC and AN registers for the LPCS to their default states
* Resets the associated SerDes lanes.
It takes up to 32 coprocessor-clock cycles to reset the LPCS, after which RESET is
automatically cleared. */
uint64_t loopbck : 1; /**< [ 14: 14](R/W) TX-to-RX loopback enable. When set, transmit data for each SerDes lane is looped back as
receive data. */
uint64_t spdsel1 : 1; /**< [ 13: 13](RO/H) Speed select 1: always 1. */
uint64_t reserved_12 : 1;
uint64_t lo_pwr : 1; /**< [ 11: 11](R/W) Low power enable. When set, the LPCS is disabled (overriding the associated
BGX()_CMR()_CONFIG[ENABLE]), and the SerDes lanes associated with the LPCS are
reset. */
uint64_t reserved_7_10 : 4;
uint64_t spdsel0 : 1; /**< [ 6: 6](RO/H) Speed select 0: always 1. */
uint64_t spd : 4; /**< [ 5: 2](RO/H) '"Speed selection.
Note that this is a read-only field rather than read/write as
specified in 802.3.
The LPCS speed is instead configured by the associated
BGX()_CMR()_CONFIG[LMAC_TYPE]. The read values returned by this field are as
follows:
\<pre\>
LMAC_TYPE Speed SPD Read Value Comment
------------------------------------------------------
XAUI 10G/20G 0x0 20G if DXAUI
RXAUI 10G 0x0
10G_R 10G 0x0
40G_R 40G 0x3
Other - X
\</pre\>' */
uint64_t reserved_0_1 : 2;
#else /* Word 0 - Little Endian */
uint64_t reserved_0_1 : 2;
uint64_t spd : 4; /**< [ 5: 2](RO/H) '"Speed selection.
Note that this is a read-only field rather than read/write as
specified in 802.3.
The LPCS speed is instead configured by the associated
BGX()_CMR()_CONFIG[LMAC_TYPE]. The read values returned by this field are as
follows:
\<pre\>
LMAC_TYPE Speed SPD Read Value Comment
------------------------------------------------------
XAUI 10G/20G 0x0 20G if DXAUI
RXAUI 10G 0x0
10G_R 10G 0x0
40G_R 40G 0x3
Other - X
\</pre\>' */
uint64_t spdsel0 : 1; /**< [ 6: 6](RO/H) Speed select 0: always 1. */
uint64_t reserved_7_10 : 4;
uint64_t lo_pwr : 1; /**< [ 11: 11](R/W) Low power enable. When set, the LPCS is disabled (overriding the associated
BGX()_CMR()_CONFIG[ENABLE]), and the SerDes lanes associated with the LPCS are
reset. */
uint64_t reserved_12 : 1;
uint64_t spdsel1 : 1; /**< [ 13: 13](RO/H) Speed select 1: always 1. */
uint64_t loopbck : 1; /**< [ 14: 14](R/W) TX-to-RX loopback enable. When set, transmit data for each SerDes lane is looped back as
receive data. */
uint64_t reset : 1; /**< [ 15: 15](R/W1S/H) Reset. Setting this bit or BGX()_SPU()_AN_CONTROL[AN_RESET] to 1 causes the
following to happen:
* Resets the logical PCS (LPCS)
* Sets the IEEE 802.3 PCS, FEC and AN registers for the LPCS to their default states
* Resets the associated SerDes lanes.
It takes up to 32 coprocessor-clock cycles to reset the LPCS, after which RESET is
automatically cleared. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_control1_s cn; */
};
typedef union bdk_bgxx_spux_control1 bdk_bgxx_spux_control1_t;
static inline uint64_t BDK_BGXX_SPUX_CONTROL1(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_CONTROL1(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010000ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0010000ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010000ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_CONTROL1", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_CONTROL1(a,b) bdk_bgxx_spux_control1_t
#define bustype_BDK_BGXX_SPUX_CONTROL1(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_CONTROL1(a,b) "BGXX_SPUX_CONTROL1"
#define device_bar_BDK_BGXX_SPUX_CONTROL1(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_CONTROL1(a,b) (a)
#define arguments_BDK_BGXX_SPUX_CONTROL1(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_control2
*
* BGX SPU Control 2 Registers
*/
union bdk_bgxx_spux_control2
{
uint64_t u;
struct bdk_bgxx_spux_control2_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_3_63 : 61;
uint64_t pcs_type : 3; /**< [ 2: 0](RO/H) PCS type selection.
Note that this is a read-only field rather than read/write as
specified in 802.3.
The LPCS speed is instead configured by the associated
BGX()_CMR()_CONFIG[LMAC_TYPE]. The read values returned by this field are as
follows:
\<pre\>
[PCS_TYPE]
LMAC_TYPE Read Value Comment
-------------------------------------------------
XAUI 0x1 10GBASE-X PCS type
RXAUI 0x1 10GBASE-X PCS type
10G_R 0x0 10GBASE-R PCS type
40G_R 0x4 40GBASE-R PCS type
Other Undefined Reserved
\</pre\> */
#else /* Word 0 - Little Endian */
uint64_t pcs_type : 3; /**< [ 2: 0](RO/H) PCS type selection.
Note that this is a read-only field rather than read/write as
specified in 802.3.
The LPCS speed is instead configured by the associated
BGX()_CMR()_CONFIG[LMAC_TYPE]. The read values returned by this field are as
follows:
\<pre\>
[PCS_TYPE]
LMAC_TYPE Read Value Comment
-------------------------------------------------
XAUI 0x1 10GBASE-X PCS type
RXAUI 0x1 10GBASE-X PCS type
10G_R 0x0 10GBASE-R PCS type
40G_R 0x4 40GBASE-R PCS type
Other Undefined Reserved
\</pre\> */
uint64_t reserved_3_63 : 61;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_control2_s cn; */
};
typedef union bdk_bgxx_spux_control2 bdk_bgxx_spux_control2_t;
static inline uint64_t BDK_BGXX_SPUX_CONTROL2(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_CONTROL2(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010018ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0010018ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010018ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_CONTROL2", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_CONTROL2(a,b) bdk_bgxx_spux_control2_t
#define bustype_BDK_BGXX_SPUX_CONTROL2(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_CONTROL2(a,b) "BGXX_SPUX_CONTROL2"
#define device_bar_BDK_BGXX_SPUX_CONTROL2(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_CONTROL2(a,b) (a)
#define arguments_BDK_BGXX_SPUX_CONTROL2(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_fec_abil
*
* BGX SPU Forward Error Correction Ability Registers
*/
union bdk_bgxx_spux_fec_abil
{
uint64_t u;
struct bdk_bgxx_spux_fec_abil_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_2_63 : 62;
uint64_t err_abil : 1; /**< [ 1: 1](RO/H) BASE-R FEC error-indication ability. Always 1 when the LPCS type is BASE-R,
i.e. BGX()_CMR()_CONFIG[LMAC_TYPE] = 0x3 or 0x4. Always 0 otherwise. */
uint64_t fec_abil : 1; /**< [ 0: 0](RO/H) BASE-R FEC ability. Always 1 when the LPCS type is BASE-R,
i.e. BGX()_CMR()_CONFIG[LMAC_TYPE] = 0x3 or 0x4. Always 0 otherwise. */
#else /* Word 0 - Little Endian */
uint64_t fec_abil : 1; /**< [ 0: 0](RO/H) BASE-R FEC ability. Always 1 when the LPCS type is BASE-R,
i.e. BGX()_CMR()_CONFIG[LMAC_TYPE] = 0x3 or 0x4. Always 0 otherwise. */
uint64_t err_abil : 1; /**< [ 1: 1](RO/H) BASE-R FEC error-indication ability. Always 1 when the LPCS type is BASE-R,
i.e. BGX()_CMR()_CONFIG[LMAC_TYPE] = 0x3 or 0x4. Always 0 otherwise. */
uint64_t reserved_2_63 : 62;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_fec_abil_s cn; */
};
typedef union bdk_bgxx_spux_fec_abil bdk_bgxx_spux_fec_abil_t;
static inline uint64_t BDK_BGXX_SPUX_FEC_ABIL(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_FEC_ABIL(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010098ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0010098ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010098ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_FEC_ABIL", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_FEC_ABIL(a,b) bdk_bgxx_spux_fec_abil_t
#define bustype_BDK_BGXX_SPUX_FEC_ABIL(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_FEC_ABIL(a,b) "BGXX_SPUX_FEC_ABIL"
#define device_bar_BDK_BGXX_SPUX_FEC_ABIL(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_FEC_ABIL(a,b) (a)
#define arguments_BDK_BGXX_SPUX_FEC_ABIL(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_fec_control
*
* BGX SPU Forward Error Correction Control Registers
*/
union bdk_bgxx_spux_fec_control
{
uint64_t u;
struct bdk_bgxx_spux_fec_control_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_2_63 : 62;
uint64_t err_en : 1; /**< [ 1: 1](R/W) BASE-R FEC error-indication enable. This bit corresponds to FEC_Enable_Error_to_PCS
variable for BASE-R as defined in 802.3 Clause 74. When FEC is enabled ([FEC_EN] is set)
and this bit is set, the FEC decoder on the receive side signals an
uncorrectable FEC error to the BASE-R decoder by driving a value of 2'b11 on the sync bits
for some of the 32 64/66 bit blocks belonging to the uncorrectable FEC block. See
802.3-2008/802.3ba-2010 section 74.7.4.5.1 for more details. */
uint64_t fec_en : 1; /**< [ 0: 0](R/W) BASE-R FEC enable. When this bit is set and the LPCS type is BASE-R
(BGX()_CMR()_CONFIG[LMAC_TYPE] = 0x4), forward error correction is enabled. FEC is
disabled otherwise. Forward error correction is defined in IEEE Std
802.3-2008/802.3ba-2010 Clause 74. */
#else /* Word 0 - Little Endian */
uint64_t fec_en : 1; /**< [ 0: 0](R/W) BASE-R FEC enable. When this bit is set and the LPCS type is BASE-R
(BGX()_CMR()_CONFIG[LMAC_TYPE] = 0x4), forward error correction is enabled. FEC is
disabled otherwise. Forward error correction is defined in IEEE Std
802.3-2008/802.3ba-2010 Clause 74. */
uint64_t err_en : 1; /**< [ 1: 1](R/W) BASE-R FEC error-indication enable. This bit corresponds to FEC_Enable_Error_to_PCS
variable for BASE-R as defined in 802.3 Clause 74. When FEC is enabled ([FEC_EN] is set)
and this bit is set, the FEC decoder on the receive side signals an
uncorrectable FEC error to the BASE-R decoder by driving a value of 2'b11 on the sync bits
for some of the 32 64/66 bit blocks belonging to the uncorrectable FEC block. See
802.3-2008/802.3ba-2010 section 74.7.4.5.1 for more details. */
uint64_t reserved_2_63 : 62;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_fec_control_s cn; */
};
typedef union bdk_bgxx_spux_fec_control bdk_bgxx_spux_fec_control_t;
static inline uint64_t BDK_BGXX_SPUX_FEC_CONTROL(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_FEC_CONTROL(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e00100a0ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e00100a0ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e00100a0ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_FEC_CONTROL", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_FEC_CONTROL(a,b) bdk_bgxx_spux_fec_control_t
#define bustype_BDK_BGXX_SPUX_FEC_CONTROL(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_FEC_CONTROL(a,b) "BGXX_SPUX_FEC_CONTROL"
#define device_bar_BDK_BGXX_SPUX_FEC_CONTROL(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_FEC_CONTROL(a,b) (a)
#define arguments_BDK_BGXX_SPUX_FEC_CONTROL(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_fec_corr_blks01
*
* BGX SPU FEC Corrected-Blocks Counters 0/1 Registers
* This register is valid only when the LPCS type is BASE-R
* (BGX()_CMR()_CONFIG[LMAC_TYPE] = 0x3 or 0x4). The FEC corrected-block counters are
* defined in IEEE 802.3 section 74.8.4.1. Each corrected-blocks counter increments by 1 for a
* corrected FEC block, i.e. an FEC block that has been received with invalid parity on the
* associated PCS lane and has been corrected by the FEC decoder. The counter is reset to all 0s
* when the register is read, and held at all 1s in case of overflow.
*
* The reset operation takes precedence over the increment operation; if the register is read on
* the same clock cycle as an increment operation, the counter is reset to all 0s and the
* increment operation is lost. The counters are writable for test purposes, rather than read-
* only as specified in IEEE 802.3.
*/
union bdk_bgxx_spux_fec_corr_blks01
{
uint64_t u;
struct bdk_bgxx_spux_fec_corr_blks01_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t ln1_corr_blks : 32; /**< [ 63: 32](RC/W/H) PCS Lane 1 FEC corrected blocks.
* For 10GBASE-R, reserved.
* For 40GBASE-R, correspond to the IEEE 802.3 FEC_corrected_blocks_counter_1 variable
(registers 1.302-1.303). */
uint64_t ln0_corr_blks : 32; /**< [ 31: 0](RC/W/H) PCS Lane 0 FEC corrected blocks.
* For 10GBASE-R, corresponds to the IEEE 802.3 FEC_corrected_blocks_counter variable
(registers 1.172-1.173).
* For 40GBASE-R, correspond to the IEEE 802.3 FEC_corrected_blocks_counter_0 variable
(registers 1.300-1.301). */
#else /* Word 0 - Little Endian */
uint64_t ln0_corr_blks : 32; /**< [ 31: 0](RC/W/H) PCS Lane 0 FEC corrected blocks.
* For 10GBASE-R, corresponds to the IEEE 802.3 FEC_corrected_blocks_counter variable
(registers 1.172-1.173).
* For 40GBASE-R, correspond to the IEEE 802.3 FEC_corrected_blocks_counter_0 variable
(registers 1.300-1.301). */
uint64_t ln1_corr_blks : 32; /**< [ 63: 32](RC/W/H) PCS Lane 1 FEC corrected blocks.
* For 10GBASE-R, reserved.
* For 40GBASE-R, correspond to the IEEE 802.3 FEC_corrected_blocks_counter_1 variable
(registers 1.302-1.303). */
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_fec_corr_blks01_s cn; */
};
typedef union bdk_bgxx_spux_fec_corr_blks01 bdk_bgxx_spux_fec_corr_blks01_t;
static inline uint64_t BDK_BGXX_SPUX_FEC_CORR_BLKS01(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_FEC_CORR_BLKS01(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e00100a8ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e00100a8ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e00100a8ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_FEC_CORR_BLKS01", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_FEC_CORR_BLKS01(a,b) bdk_bgxx_spux_fec_corr_blks01_t
#define bustype_BDK_BGXX_SPUX_FEC_CORR_BLKS01(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_FEC_CORR_BLKS01(a,b) "BGXX_SPUX_FEC_CORR_BLKS01"
#define device_bar_BDK_BGXX_SPUX_FEC_CORR_BLKS01(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_FEC_CORR_BLKS01(a,b) (a)
#define arguments_BDK_BGXX_SPUX_FEC_CORR_BLKS01(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_fec_corr_blks23
*
* BGX SPU FEC Corrected-Blocks Counters 2/3 Registers
* This register is valid only when the LPCS type is 40GBASE-R
* (BGX()_CMR()_CONFIG[LMAC_TYPE] = 0x4). The FEC corrected-block counters are defined in
* IEEE 802.3 section 74.8.4.1. Each corrected-blocks counter increments by 1 for a corrected FEC
* block, i.e. an FEC block that has been received with invalid parity on the associated PCS lane
* and has been corrected by the FEC decoder. The counter is reset to all 0s when the register is
* read, and held at all 1s in case of overflow.
*
* The reset operation takes precedence over the increment operation; if the register is read on
* the same clock cycle as an increment operation, the counter is reset to all 0s and the
* increment operation is lost. The counters are writable for test purposes, rather than read-
* only as specified in IEEE 802.3.
*/
union bdk_bgxx_spux_fec_corr_blks23
{
uint64_t u;
struct bdk_bgxx_spux_fec_corr_blks23_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t ln3_corr_blks : 32; /**< [ 63: 32](RC/W/H) PCS Lane 3 FEC corrected blocks. Correspond to the IEEE 802.3
FEC_corrected_blocks_counter_3 variable (registers 1.306-1.307). */
uint64_t ln2_corr_blks : 32; /**< [ 31: 0](RC/W/H) PCS Lane 2 FEC corrected blocks. Correspond to the IEEE 802.3
FEC_corrected_blocks_counter_3 variable (registers 1.304-1.305). */
#else /* Word 0 - Little Endian */
uint64_t ln2_corr_blks : 32; /**< [ 31: 0](RC/W/H) PCS Lane 2 FEC corrected blocks. Correspond to the IEEE 802.3
FEC_corrected_blocks_counter_3 variable (registers 1.304-1.305). */
uint64_t ln3_corr_blks : 32; /**< [ 63: 32](RC/W/H) PCS Lane 3 FEC corrected blocks. Correspond to the IEEE 802.3
FEC_corrected_blocks_counter_3 variable (registers 1.306-1.307). */
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_fec_corr_blks23_s cn; */
};
typedef union bdk_bgxx_spux_fec_corr_blks23 bdk_bgxx_spux_fec_corr_blks23_t;
static inline uint64_t BDK_BGXX_SPUX_FEC_CORR_BLKS23(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_FEC_CORR_BLKS23(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e00100b0ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e00100b0ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e00100b0ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_FEC_CORR_BLKS23", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_FEC_CORR_BLKS23(a,b) bdk_bgxx_spux_fec_corr_blks23_t
#define bustype_BDK_BGXX_SPUX_FEC_CORR_BLKS23(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_FEC_CORR_BLKS23(a,b) "BGXX_SPUX_FEC_CORR_BLKS23"
#define device_bar_BDK_BGXX_SPUX_FEC_CORR_BLKS23(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_FEC_CORR_BLKS23(a,b) (a)
#define arguments_BDK_BGXX_SPUX_FEC_CORR_BLKS23(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_fec_uncorr_blks01
*
* BGX SPU FEC Uncorrected-Blocks Counters 0/1 Registers
* This register is valid only when the LPCS type is BASE-R
* (BGX()_CMR()_CONFIG[LMAC_TYPE] = 0x3 or 0x4). The FEC corrected-block counters are
* defined in IEEE 802.3 section 74.8.4.2. Each uncorrected-blocks counter increments by 1 for an
* uncorrected FEC block, i.e. an FEC block that has been received with invalid parity on the
* associated PCS lane and has not been corrected by the FEC decoder. The counter is reset to all
* 0s when the register is read, and held at all 1s in case of overflow.
*
* The reset operation takes precedence over the increment operation; if the register is read on
* the same clock cycle as an increment operation, the counter is reset to all 0s and the
* increment operation is lost. The counters are writable for test purposes, rather than read-
* only as specified in IEEE 802.3.
*/
union bdk_bgxx_spux_fec_uncorr_blks01
{
uint64_t u;
struct bdk_bgxx_spux_fec_uncorr_blks01_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t ln1_uncorr_blks : 32; /**< [ 63: 32](RC/W/H) PCS Lane 1 FEC corrected blocks.
* For 10GBASE-R, reserved.
* For 40GBASE-R, corresponds to the IEEE 802.3 FEC_uncorrected_blocks_counter_1 variable
(registers 1.702-1.703). */
uint64_t ln0_uncorr_blks : 32; /**< [ 31: 0](RC/W/H) PCS Lane 0 FEC uncorrected blocks.
* For 10GBASE-R, corresponds to the IEEE 802.3 FEC_uncorrected_blocks_counter variable
(registers 1.174-1.175).
* For 40GBASE-R, correspond to the IEEE 802.3 FEC_uncorrected_blocks_counter_0 variable
(registers 1.700-1.701). */
#else /* Word 0 - Little Endian */
uint64_t ln0_uncorr_blks : 32; /**< [ 31: 0](RC/W/H) PCS Lane 0 FEC uncorrected blocks.
* For 10GBASE-R, corresponds to the IEEE 802.3 FEC_uncorrected_blocks_counter variable
(registers 1.174-1.175).
* For 40GBASE-R, correspond to the IEEE 802.3 FEC_uncorrected_blocks_counter_0 variable
(registers 1.700-1.701). */
uint64_t ln1_uncorr_blks : 32; /**< [ 63: 32](RC/W/H) PCS Lane 1 FEC corrected blocks.
* For 10GBASE-R, reserved.
* For 40GBASE-R, corresponds to the IEEE 802.3 FEC_uncorrected_blocks_counter_1 variable
(registers 1.702-1.703). */
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_fec_uncorr_blks01_s cn; */
};
typedef union bdk_bgxx_spux_fec_uncorr_blks01 bdk_bgxx_spux_fec_uncorr_blks01_t;
static inline uint64_t BDK_BGXX_SPUX_FEC_UNCORR_BLKS01(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_FEC_UNCORR_BLKS01(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e00100b8ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e00100b8ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e00100b8ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_FEC_UNCORR_BLKS01", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_FEC_UNCORR_BLKS01(a,b) bdk_bgxx_spux_fec_uncorr_blks01_t
#define bustype_BDK_BGXX_SPUX_FEC_UNCORR_BLKS01(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_FEC_UNCORR_BLKS01(a,b) "BGXX_SPUX_FEC_UNCORR_BLKS01"
#define device_bar_BDK_BGXX_SPUX_FEC_UNCORR_BLKS01(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_FEC_UNCORR_BLKS01(a,b) (a)
#define arguments_BDK_BGXX_SPUX_FEC_UNCORR_BLKS01(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_fec_uncorr_blks23
*
* BGX SPU FEC Uncorrected-Blocks Counters 2/3 Registers
* This register is valid only when the LPCS type is 40GBASE-R
* (BGX()_CMR()_CONFIG[LMAC_TYPE] = 0x4). The FEC uncorrected-block counters are defined
* in IEEE 802.3 section 74.8.4.2. Each corrected-blocks counter increments by 1 for an
* uncorrected FEC block, i.e. an FEC block that has been received with invalid parity on the
* associated PCS lane and has not been corrected by the FEC decoder. The counter is reset to all
* 0s when the register is read, and held at all 1s in case of overflow.
*
* The reset operation takes precedence over the increment operation; if the register is read on
* the same clock cycle as an increment operation, the counter is reset to all 0s and the
* increment operation is lost. The counters are writable for test purposes, rather than read-
* only as specified in IEEE 802.3.
*/
union bdk_bgxx_spux_fec_uncorr_blks23
{
uint64_t u;
struct bdk_bgxx_spux_fec_uncorr_blks23_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t ln3_uncorr_blks : 32; /**< [ 63: 32](RC/W/H) PCS Lane 3 FEC uncorrected blocks. Corresponds to the IEEE 802.3
FEC_uncorrected_blocks_counter_3 variable (registers 1.706-1.707). */
uint64_t ln2_uncorr_blks : 32; /**< [ 31: 0](RC/W/H) PCS Lane 2 FEC uncorrected blocks. Corresponds to the IEEE 802.3
FEC_uncorrected_blocks_counter_3 variable (registers 1.704-1.705). */
#else /* Word 0 - Little Endian */
uint64_t ln2_uncorr_blks : 32; /**< [ 31: 0](RC/W/H) PCS Lane 2 FEC uncorrected blocks. Corresponds to the IEEE 802.3
FEC_uncorrected_blocks_counter_3 variable (registers 1.704-1.705). */
uint64_t ln3_uncorr_blks : 32; /**< [ 63: 32](RC/W/H) PCS Lane 3 FEC uncorrected blocks. Corresponds to the IEEE 802.3
FEC_uncorrected_blocks_counter_3 variable (registers 1.706-1.707). */
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_fec_uncorr_blks23_s cn; */
};
typedef union bdk_bgxx_spux_fec_uncorr_blks23 bdk_bgxx_spux_fec_uncorr_blks23_t;
static inline uint64_t BDK_BGXX_SPUX_FEC_UNCORR_BLKS23(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_FEC_UNCORR_BLKS23(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e00100c0ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e00100c0ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e00100c0ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_FEC_UNCORR_BLKS23", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_FEC_UNCORR_BLKS23(a,b) bdk_bgxx_spux_fec_uncorr_blks23_t
#define bustype_BDK_BGXX_SPUX_FEC_UNCORR_BLKS23(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_FEC_UNCORR_BLKS23(a,b) "BGXX_SPUX_FEC_UNCORR_BLKS23"
#define device_bar_BDK_BGXX_SPUX_FEC_UNCORR_BLKS23(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_FEC_UNCORR_BLKS23(a,b) (a)
#define arguments_BDK_BGXX_SPUX_FEC_UNCORR_BLKS23(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_int
*
* BGX SPU Interrupt Registers
*/
union bdk_bgxx_spux_int
{
uint64_t u;
struct bdk_bgxx_spux_int_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_15_63 : 49;
uint64_t training_failure : 1; /**< [ 14: 14](R/W1C/H) BASE-R PMD training failure. Set when BASE-R PMD link training has failed on the 10GBASE-R
lane or any 40GBASE-R lane. Valid if the LPCS type selected by
BGX()_CMR()_CONFIG[LMAC_TYPE] is 10GBASE-R or 40GBASE-R and
BGX()_SPU()_BR_PMD_CONTROL[TRAIN_EN] is 1, and never set otherwise. */
uint64_t training_done : 1; /**< [ 13: 13](R/W1C/H) BASE-R PMD training done. Set when the 10GBASE-R lane or all 40GBASE-R lanes have
successfully completed BASE-R PMD link training. Valid if the LPCS type selected by
BGX()_CMR()_CONFIG[LMAC_TYPE] is 10GBASE-R or 40GBASE-R and
BGX()_SPU()_BR_PMD_CONTROL[TRAIN_EN] is 1, and never set otherwise. */
uint64_t an_complete : 1; /**< [ 12: 12](R/W1C/H) Autonegotiation complete. Set when BGX()_SPU()_AN_STATUS[AN_COMPLETE] is set,
indicating that the autonegotiation process has been completed and the link is up and
running using the negotiated highest common denominator (HCD) technology. */
uint64_t an_link_good : 1; /**< [ 11: 11](R/W1C/H) Autonegotiation link good. Set when the an_link_good variable is set as defined in
802.3-2008 Figure 73-11, indicating that autonegotiation has completed. */
uint64_t an_page_rx : 1; /**< [ 10: 10](R/W1C/H) Autonegotiation page received. This bit is set along with
BGX()_SPU()_AN_STATUS[PAGE_RX] when a new page has been received and stored in
BGX()_SPU()_AN_LP_BASE or BGX()_SPU()_AN_LP_XNP. */
uint64_t fec_uncorr : 1; /**< [ 9: 9](R/W1C/H) Uncorrectable FEC error. Set when an FEC block with an uncorrectable error is received on
the 10GBASE-R lane or any 40GBASE-R lane. Valid if the LPCS type selected by
BGX()_CMR()_CONFIG[LMAC_TYPE] is 10GBASE-R or 40GBASE-R, and never set otherwise. */
uint64_t fec_corr : 1; /**< [ 8: 8](R/W1C/H) Correctable FEC error. Set when an FEC block with a correctable error is received on the
10GBASE-R lane or any 40GBASE-R lane. Valid if the LPCS type selected by
BGX()_CMR()_CONFIG[LMAC_TYPE] is 10GBASE-R or 40GBASE-R, and never set otherwise. */
uint64_t bip_err : 1; /**< [ 7: 7](R/W1C/H) 40GBASE-R bit interleaved parity error. Set when a BIP error is detected on any lane.
Valid if the LPCS type selected by BGX()_CMR()_CONFIG[LMAC_TYPE] is 40GBASE-R, and
never set otherwise. */
uint64_t dbg_sync : 1; /**< [ 6: 6](R/W1C/H) Sync failure debug. This interrupt is provided for link problem debugging help. It is set
as follows based on the LPCS type selected by BGX()_CMR()_CONFIG[LMAC_TYPE], and
whether FEC is enabled or disabled by BGX()_SPU()_FEC_CONTROL[FEC_EN]:
* XAUI or RXAUI: Set when any lane's PCS synchronization state transitions from
SYNC_ACQUIRED_1 to SYNC_ACQUIRED_2 (see 802.3-2008 Figure 48-7).
* 10GBASE-R or 40GBASE-R with FEC disabled: Set when sh_invalid_cnt increments to 1 while
BLOCK_LOCK is 1 (see 802.3-2008 Figure 49-12 and 802.3ba-2010 Figure 82-20).
* 10GBASE-R or 40GBASE-R with FEC enabled: Set when parity_invalid_cnt increments to 1
while fec_block_lock is 1 (see 802.3-2008 Figure 74-8). */
uint64_t algnlos : 1; /**< [ 5: 5](R/W1C/H) Loss of lane alignment. Set when lane-to-lane alignment is lost. This is only valid if the
logical PCS is a multilane type (i.e. XAUI, RXAUI or 40GBASE-R is selected by
BGX()_CMR()_CONFIG[LMAC_TYPE]), and is never set otherwise. */
uint64_t synlos : 1; /**< [ 4: 4](R/W1C/H) Loss of lane sync. Lane code-group or block synchronization is lost on one or more lanes
associated with the LMAC/LPCS. Set as follows based on the LPCS type selected by
BGX()_CMR()_CONFIG[LMAC_TYPE], and whether FEC is enabled or disabled by
BGX()_SPU()_FEC_CONTROL[FEC_EN]:
* XAUI or RXAUI: Set when any lane's PCS synchronization state transitions to LOSS_OF_SYNC
(see 802.3-2008 Figure 48-7)
* 10GBASE-R or 40GBASE-R with FEC disabled: set when the BLOCK_LOCK variable is cleared on
the 10G lane or any 40G lane (see 802.3-2008 Figure 49-12 and 802.3ba-2010 Figure 82-20).
* 10GBASE-R or 40GBASE-R with FEC enabled: set when the fec_block_lock variable is cleared
on the 10G lane or any 40G lane (see 802.3-2008 Figure 74-8). */
uint64_t bitlckls : 1; /**< [ 3: 3](R/W1C/H) Bit lock lost on one or more lanes associated with the LMAC/LPCS. */
uint64_t err_blk : 1; /**< [ 2: 2](R/W1C/H) Errored block received. Set when an errored BASE-R block is received as described for
BGX()_SPU()_BR_STATUS2[ERR_BLKS]. Valid if the LPCS type selected by
BGX()_CMR()_CONFIG[LMAC_TYPE] is 10GBASE-R or 40GBASE-R, and never set otherwise. */
uint64_t rx_link_down : 1; /**< [ 1: 1](R/W1C/H) Set when the receive link goes down, which is the same condition that sets
BGX()_SPU()_STATUS2[RCVFLT]. */
uint64_t rx_link_up : 1; /**< [ 0: 0](R/W1C/H) Set when the receive link comes up, which is the same condition that allows the setting of
BGX()_SPU()_STATUS1[RCV_LNK]. */
#else /* Word 0 - Little Endian */
uint64_t rx_link_up : 1; /**< [ 0: 0](R/W1C/H) Set when the receive link comes up, which is the same condition that allows the setting of
BGX()_SPU()_STATUS1[RCV_LNK]. */
uint64_t rx_link_down : 1; /**< [ 1: 1](R/W1C/H) Set when the receive link goes down, which is the same condition that sets
BGX()_SPU()_STATUS2[RCVFLT]. */
uint64_t err_blk : 1; /**< [ 2: 2](R/W1C/H) Errored block received. Set when an errored BASE-R block is received as described for
BGX()_SPU()_BR_STATUS2[ERR_BLKS]. Valid if the LPCS type selected by
BGX()_CMR()_CONFIG[LMAC_TYPE] is 10GBASE-R or 40GBASE-R, and never set otherwise. */
uint64_t bitlckls : 1; /**< [ 3: 3](R/W1C/H) Bit lock lost on one or more lanes associated with the LMAC/LPCS. */
uint64_t synlos : 1; /**< [ 4: 4](R/W1C/H) Loss of lane sync. Lane code-group or block synchronization is lost on one or more lanes
associated with the LMAC/LPCS. Set as follows based on the LPCS type selected by
BGX()_CMR()_CONFIG[LMAC_TYPE], and whether FEC is enabled or disabled by
BGX()_SPU()_FEC_CONTROL[FEC_EN]:
* XAUI or RXAUI: Set when any lane's PCS synchronization state transitions to LOSS_OF_SYNC
(see 802.3-2008 Figure 48-7)
* 10GBASE-R or 40GBASE-R with FEC disabled: set when the BLOCK_LOCK variable is cleared on
the 10G lane or any 40G lane (see 802.3-2008 Figure 49-12 and 802.3ba-2010 Figure 82-20).
* 10GBASE-R or 40GBASE-R with FEC enabled: set when the fec_block_lock variable is cleared
on the 10G lane or any 40G lane (see 802.3-2008 Figure 74-8). */
uint64_t algnlos : 1; /**< [ 5: 5](R/W1C/H) Loss of lane alignment. Set when lane-to-lane alignment is lost. This is only valid if the
logical PCS is a multilane type (i.e. XAUI, RXAUI or 40GBASE-R is selected by
BGX()_CMR()_CONFIG[LMAC_TYPE]), and is never set otherwise. */
uint64_t dbg_sync : 1; /**< [ 6: 6](R/W1C/H) Sync failure debug. This interrupt is provided for link problem debugging help. It is set
as follows based on the LPCS type selected by BGX()_CMR()_CONFIG[LMAC_TYPE], and
whether FEC is enabled or disabled by BGX()_SPU()_FEC_CONTROL[FEC_EN]:
* XAUI or RXAUI: Set when any lane's PCS synchronization state transitions from
SYNC_ACQUIRED_1 to SYNC_ACQUIRED_2 (see 802.3-2008 Figure 48-7).
* 10GBASE-R or 40GBASE-R with FEC disabled: Set when sh_invalid_cnt increments to 1 while
BLOCK_LOCK is 1 (see 802.3-2008 Figure 49-12 and 802.3ba-2010 Figure 82-20).
* 10GBASE-R or 40GBASE-R with FEC enabled: Set when parity_invalid_cnt increments to 1
while fec_block_lock is 1 (see 802.3-2008 Figure 74-8). */
uint64_t bip_err : 1; /**< [ 7: 7](R/W1C/H) 40GBASE-R bit interleaved parity error. Set when a BIP error is detected on any lane.
Valid if the LPCS type selected by BGX()_CMR()_CONFIG[LMAC_TYPE] is 40GBASE-R, and
never set otherwise. */
uint64_t fec_corr : 1; /**< [ 8: 8](R/W1C/H) Correctable FEC error. Set when an FEC block with a correctable error is received on the
10GBASE-R lane or any 40GBASE-R lane. Valid if the LPCS type selected by
BGX()_CMR()_CONFIG[LMAC_TYPE] is 10GBASE-R or 40GBASE-R, and never set otherwise. */
uint64_t fec_uncorr : 1; /**< [ 9: 9](R/W1C/H) Uncorrectable FEC error. Set when an FEC block with an uncorrectable error is received on
the 10GBASE-R lane or any 40GBASE-R lane. Valid if the LPCS type selected by
BGX()_CMR()_CONFIG[LMAC_TYPE] is 10GBASE-R or 40GBASE-R, and never set otherwise. */
uint64_t an_page_rx : 1; /**< [ 10: 10](R/W1C/H) Autonegotiation page received. This bit is set along with
BGX()_SPU()_AN_STATUS[PAGE_RX] when a new page has been received and stored in
BGX()_SPU()_AN_LP_BASE or BGX()_SPU()_AN_LP_XNP. */
uint64_t an_link_good : 1; /**< [ 11: 11](R/W1C/H) Autonegotiation link good. Set when the an_link_good variable is set as defined in
802.3-2008 Figure 73-11, indicating that autonegotiation has completed. */
uint64_t an_complete : 1; /**< [ 12: 12](R/W1C/H) Autonegotiation complete. Set when BGX()_SPU()_AN_STATUS[AN_COMPLETE] is set,
indicating that the autonegotiation process has been completed and the link is up and
running using the negotiated highest common denominator (HCD) technology. */
uint64_t training_done : 1; /**< [ 13: 13](R/W1C/H) BASE-R PMD training done. Set when the 10GBASE-R lane or all 40GBASE-R lanes have
successfully completed BASE-R PMD link training. Valid if the LPCS type selected by
BGX()_CMR()_CONFIG[LMAC_TYPE] is 10GBASE-R or 40GBASE-R and
BGX()_SPU()_BR_PMD_CONTROL[TRAIN_EN] is 1, and never set otherwise. */
uint64_t training_failure : 1; /**< [ 14: 14](R/W1C/H) BASE-R PMD training failure. Set when BASE-R PMD link training has failed on the 10GBASE-R
lane or any 40GBASE-R lane. Valid if the LPCS type selected by
BGX()_CMR()_CONFIG[LMAC_TYPE] is 10GBASE-R or 40GBASE-R and
BGX()_SPU()_BR_PMD_CONTROL[TRAIN_EN] is 1, and never set otherwise. */
uint64_t reserved_15_63 : 49;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_int_s cn; */
};
typedef union bdk_bgxx_spux_int bdk_bgxx_spux_int_t;
static inline uint64_t BDK_BGXX_SPUX_INT(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_INT(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010220ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0010220ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010220ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_INT", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_INT(a,b) bdk_bgxx_spux_int_t
#define bustype_BDK_BGXX_SPUX_INT(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_INT(a,b) "BGXX_SPUX_INT"
#define device_bar_BDK_BGXX_SPUX_INT(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_INT(a,b) (a)
#define arguments_BDK_BGXX_SPUX_INT(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_int_ena_w1c
*
* BGX SPU Interrupt Enable Clear Registers
* This register clears interrupt enable bits.
*/
union bdk_bgxx_spux_int_ena_w1c
{
uint64_t u;
struct bdk_bgxx_spux_int_ena_w1c_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_15_63 : 49;
uint64_t training_failure : 1; /**< [ 14: 14](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU(0..3)_INT[TRAINING_FAILURE]. */
uint64_t training_done : 1; /**< [ 13: 13](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU(0..3)_INT[TRAINING_DONE]. */
uint64_t an_complete : 1; /**< [ 12: 12](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU(0..3)_INT[AN_COMPLETE]. */
uint64_t an_link_good : 1; /**< [ 11: 11](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU(0..3)_INT[AN_LINK_GOOD]. */
uint64_t an_page_rx : 1; /**< [ 10: 10](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU(0..3)_INT[AN_PAGE_RX]. */
uint64_t fec_uncorr : 1; /**< [ 9: 9](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU(0..3)_INT[FEC_UNCORR]. */
uint64_t fec_corr : 1; /**< [ 8: 8](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU(0..3)_INT[FEC_CORR]. */
uint64_t bip_err : 1; /**< [ 7: 7](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU(0..3)_INT[BIP_ERR]. */
uint64_t dbg_sync : 1; /**< [ 6: 6](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU(0..3)_INT[DBG_SYNC]. */
uint64_t algnlos : 1; /**< [ 5: 5](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU(0..3)_INT[ALGNLOS]. */
uint64_t synlos : 1; /**< [ 4: 4](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU(0..3)_INT[SYNLOS]. */
uint64_t bitlckls : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU(0..3)_INT[BITLCKLS]. */
uint64_t err_blk : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU(0..3)_INT[ERR_BLK]. */
uint64_t rx_link_down : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU(0..3)_INT[RX_LINK_DOWN]. */
uint64_t rx_link_up : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU(0..3)_INT[RX_LINK_UP]. */
#else /* Word 0 - Little Endian */
uint64_t rx_link_up : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU(0..3)_INT[RX_LINK_UP]. */
uint64_t rx_link_down : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU(0..3)_INT[RX_LINK_DOWN]. */
uint64_t err_blk : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU(0..3)_INT[ERR_BLK]. */
uint64_t bitlckls : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU(0..3)_INT[BITLCKLS]. */
uint64_t synlos : 1; /**< [ 4: 4](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU(0..3)_INT[SYNLOS]. */
uint64_t algnlos : 1; /**< [ 5: 5](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU(0..3)_INT[ALGNLOS]. */
uint64_t dbg_sync : 1; /**< [ 6: 6](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU(0..3)_INT[DBG_SYNC]. */
uint64_t bip_err : 1; /**< [ 7: 7](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU(0..3)_INT[BIP_ERR]. */
uint64_t fec_corr : 1; /**< [ 8: 8](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU(0..3)_INT[FEC_CORR]. */
uint64_t fec_uncorr : 1; /**< [ 9: 9](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU(0..3)_INT[FEC_UNCORR]. */
uint64_t an_page_rx : 1; /**< [ 10: 10](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU(0..3)_INT[AN_PAGE_RX]. */
uint64_t an_link_good : 1; /**< [ 11: 11](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU(0..3)_INT[AN_LINK_GOOD]. */
uint64_t an_complete : 1; /**< [ 12: 12](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU(0..3)_INT[AN_COMPLETE]. */
uint64_t training_done : 1; /**< [ 13: 13](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU(0..3)_INT[TRAINING_DONE]. */
uint64_t training_failure : 1; /**< [ 14: 14](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU(0..3)_INT[TRAINING_FAILURE]. */
uint64_t reserved_15_63 : 49;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_int_ena_w1c_s cn81xx; */
/* struct bdk_bgxx_spux_int_ena_w1c_s cn88xx; */
struct bdk_bgxx_spux_int_ena_w1c_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_15_63 : 49;
uint64_t training_failure : 1; /**< [ 14: 14](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU(0..3)_INT[TRAINING_FAILURE]. */
uint64_t training_done : 1; /**< [ 13: 13](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU(0..3)_INT[TRAINING_DONE]. */
uint64_t an_complete : 1; /**< [ 12: 12](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU(0..3)_INT[AN_COMPLETE]. */
uint64_t an_link_good : 1; /**< [ 11: 11](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU(0..3)_INT[AN_LINK_GOOD]. */
uint64_t an_page_rx : 1; /**< [ 10: 10](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU(0..3)_INT[AN_PAGE_RX]. */
uint64_t fec_uncorr : 1; /**< [ 9: 9](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU(0..3)_INT[FEC_UNCORR]. */
uint64_t fec_corr : 1; /**< [ 8: 8](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU(0..3)_INT[FEC_CORR]. */
uint64_t bip_err : 1; /**< [ 7: 7](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU(0..3)_INT[BIP_ERR]. */
uint64_t dbg_sync : 1; /**< [ 6: 6](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU(0..3)_INT[DBG_SYNC]. */
uint64_t algnlos : 1; /**< [ 5: 5](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU(0..3)_INT[ALGNLOS]. */
uint64_t synlos : 1; /**< [ 4: 4](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU(0..3)_INT[SYNLOS]. */
uint64_t bitlckls : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU(0..3)_INT[BITLCKLS]. */
uint64_t err_blk : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU(0..3)_INT[ERR_BLK]. */
uint64_t rx_link_down : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU(0..3)_INT[RX_LINK_DOWN]. */
uint64_t rx_link_up : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU(0..3)_INT[RX_LINK_UP]. */
#else /* Word 0 - Little Endian */
uint64_t rx_link_up : 1; /**< [ 0: 0](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU(0..3)_INT[RX_LINK_UP]. */
uint64_t rx_link_down : 1; /**< [ 1: 1](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU(0..3)_INT[RX_LINK_DOWN]. */
uint64_t err_blk : 1; /**< [ 2: 2](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU(0..3)_INT[ERR_BLK]. */
uint64_t bitlckls : 1; /**< [ 3: 3](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU(0..3)_INT[BITLCKLS]. */
uint64_t synlos : 1; /**< [ 4: 4](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU(0..3)_INT[SYNLOS]. */
uint64_t algnlos : 1; /**< [ 5: 5](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU(0..3)_INT[ALGNLOS]. */
uint64_t dbg_sync : 1; /**< [ 6: 6](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU(0..3)_INT[DBG_SYNC]. */
uint64_t bip_err : 1; /**< [ 7: 7](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU(0..3)_INT[BIP_ERR]. */
uint64_t fec_corr : 1; /**< [ 8: 8](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU(0..3)_INT[FEC_CORR]. */
uint64_t fec_uncorr : 1; /**< [ 9: 9](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU(0..3)_INT[FEC_UNCORR]. */
uint64_t an_page_rx : 1; /**< [ 10: 10](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU(0..3)_INT[AN_PAGE_RX]. */
uint64_t an_link_good : 1; /**< [ 11: 11](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU(0..3)_INT[AN_LINK_GOOD]. */
uint64_t an_complete : 1; /**< [ 12: 12](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU(0..3)_INT[AN_COMPLETE]. */
uint64_t training_done : 1; /**< [ 13: 13](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU(0..3)_INT[TRAINING_DONE]. */
uint64_t training_failure : 1; /**< [ 14: 14](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU(0..3)_INT[TRAINING_FAILURE]. */
uint64_t reserved_15_63 : 49;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_spux_int_ena_w1c bdk_bgxx_spux_int_ena_w1c_t;
static inline uint64_t BDK_BGXX_SPUX_INT_ENA_W1C(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_INT_ENA_W1C(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010230ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0010230ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010230ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_INT_ENA_W1C", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_INT_ENA_W1C(a,b) bdk_bgxx_spux_int_ena_w1c_t
#define bustype_BDK_BGXX_SPUX_INT_ENA_W1C(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_INT_ENA_W1C(a,b) "BGXX_SPUX_INT_ENA_W1C"
#define device_bar_BDK_BGXX_SPUX_INT_ENA_W1C(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_INT_ENA_W1C(a,b) (a)
#define arguments_BDK_BGXX_SPUX_INT_ENA_W1C(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_int_ena_w1s
*
* BGX SPU Interrupt Enable Set Registers
* This register sets interrupt enable bits.
*/
union bdk_bgxx_spux_int_ena_w1s
{
uint64_t u;
struct bdk_bgxx_spux_int_ena_w1s_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_15_63 : 49;
uint64_t training_failure : 1; /**< [ 14: 14](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU(0..3)_INT[TRAINING_FAILURE]. */
uint64_t training_done : 1; /**< [ 13: 13](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU(0..3)_INT[TRAINING_DONE]. */
uint64_t an_complete : 1; /**< [ 12: 12](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU(0..3)_INT[AN_COMPLETE]. */
uint64_t an_link_good : 1; /**< [ 11: 11](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU(0..3)_INT[AN_LINK_GOOD]. */
uint64_t an_page_rx : 1; /**< [ 10: 10](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU(0..3)_INT[AN_PAGE_RX]. */
uint64_t fec_uncorr : 1; /**< [ 9: 9](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU(0..3)_INT[FEC_UNCORR]. */
uint64_t fec_corr : 1; /**< [ 8: 8](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU(0..3)_INT[FEC_CORR]. */
uint64_t bip_err : 1; /**< [ 7: 7](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU(0..3)_INT[BIP_ERR]. */
uint64_t dbg_sync : 1; /**< [ 6: 6](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU(0..3)_INT[DBG_SYNC]. */
uint64_t algnlos : 1; /**< [ 5: 5](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU(0..3)_INT[ALGNLOS]. */
uint64_t synlos : 1; /**< [ 4: 4](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU(0..3)_INT[SYNLOS]. */
uint64_t bitlckls : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU(0..3)_INT[BITLCKLS]. */
uint64_t err_blk : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU(0..3)_INT[ERR_BLK]. */
uint64_t rx_link_down : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU(0..3)_INT[RX_LINK_DOWN]. */
uint64_t rx_link_up : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU(0..3)_INT[RX_LINK_UP]. */
#else /* Word 0 - Little Endian */
uint64_t rx_link_up : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU(0..3)_INT[RX_LINK_UP]. */
uint64_t rx_link_down : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU(0..3)_INT[RX_LINK_DOWN]. */
uint64_t err_blk : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU(0..3)_INT[ERR_BLK]. */
uint64_t bitlckls : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU(0..3)_INT[BITLCKLS]. */
uint64_t synlos : 1; /**< [ 4: 4](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU(0..3)_INT[SYNLOS]. */
uint64_t algnlos : 1; /**< [ 5: 5](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU(0..3)_INT[ALGNLOS]. */
uint64_t dbg_sync : 1; /**< [ 6: 6](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU(0..3)_INT[DBG_SYNC]. */
uint64_t bip_err : 1; /**< [ 7: 7](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU(0..3)_INT[BIP_ERR]. */
uint64_t fec_corr : 1; /**< [ 8: 8](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU(0..3)_INT[FEC_CORR]. */
uint64_t fec_uncorr : 1; /**< [ 9: 9](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU(0..3)_INT[FEC_UNCORR]. */
uint64_t an_page_rx : 1; /**< [ 10: 10](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU(0..3)_INT[AN_PAGE_RX]. */
uint64_t an_link_good : 1; /**< [ 11: 11](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU(0..3)_INT[AN_LINK_GOOD]. */
uint64_t an_complete : 1; /**< [ 12: 12](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU(0..3)_INT[AN_COMPLETE]. */
uint64_t training_done : 1; /**< [ 13: 13](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU(0..3)_INT[TRAINING_DONE]. */
uint64_t training_failure : 1; /**< [ 14: 14](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU(0..3)_INT[TRAINING_FAILURE]. */
uint64_t reserved_15_63 : 49;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_int_ena_w1s_s cn81xx; */
/* struct bdk_bgxx_spux_int_ena_w1s_s cn88xx; */
struct bdk_bgxx_spux_int_ena_w1s_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_15_63 : 49;
uint64_t training_failure : 1; /**< [ 14: 14](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU(0..3)_INT[TRAINING_FAILURE]. */
uint64_t training_done : 1; /**< [ 13: 13](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU(0..3)_INT[TRAINING_DONE]. */
uint64_t an_complete : 1; /**< [ 12: 12](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU(0..3)_INT[AN_COMPLETE]. */
uint64_t an_link_good : 1; /**< [ 11: 11](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU(0..3)_INT[AN_LINK_GOOD]. */
uint64_t an_page_rx : 1; /**< [ 10: 10](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU(0..3)_INT[AN_PAGE_RX]. */
uint64_t fec_uncorr : 1; /**< [ 9: 9](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU(0..3)_INT[FEC_UNCORR]. */
uint64_t fec_corr : 1; /**< [ 8: 8](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU(0..3)_INT[FEC_CORR]. */
uint64_t bip_err : 1; /**< [ 7: 7](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU(0..3)_INT[BIP_ERR]. */
uint64_t dbg_sync : 1; /**< [ 6: 6](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU(0..3)_INT[DBG_SYNC]. */
uint64_t algnlos : 1; /**< [ 5: 5](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU(0..3)_INT[ALGNLOS]. */
uint64_t synlos : 1; /**< [ 4: 4](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU(0..3)_INT[SYNLOS]. */
uint64_t bitlckls : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU(0..3)_INT[BITLCKLS]. */
uint64_t err_blk : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU(0..3)_INT[ERR_BLK]. */
uint64_t rx_link_down : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU(0..3)_INT[RX_LINK_DOWN]. */
uint64_t rx_link_up : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU(0..3)_INT[RX_LINK_UP]. */
#else /* Word 0 - Little Endian */
uint64_t rx_link_up : 1; /**< [ 0: 0](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU(0..3)_INT[RX_LINK_UP]. */
uint64_t rx_link_down : 1; /**< [ 1: 1](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU(0..3)_INT[RX_LINK_DOWN]. */
uint64_t err_blk : 1; /**< [ 2: 2](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU(0..3)_INT[ERR_BLK]. */
uint64_t bitlckls : 1; /**< [ 3: 3](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU(0..3)_INT[BITLCKLS]. */
uint64_t synlos : 1; /**< [ 4: 4](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU(0..3)_INT[SYNLOS]. */
uint64_t algnlos : 1; /**< [ 5: 5](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU(0..3)_INT[ALGNLOS]. */
uint64_t dbg_sync : 1; /**< [ 6: 6](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU(0..3)_INT[DBG_SYNC]. */
uint64_t bip_err : 1; /**< [ 7: 7](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU(0..3)_INT[BIP_ERR]. */
uint64_t fec_corr : 1; /**< [ 8: 8](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU(0..3)_INT[FEC_CORR]. */
uint64_t fec_uncorr : 1; /**< [ 9: 9](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU(0..3)_INT[FEC_UNCORR]. */
uint64_t an_page_rx : 1; /**< [ 10: 10](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU(0..3)_INT[AN_PAGE_RX]. */
uint64_t an_link_good : 1; /**< [ 11: 11](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU(0..3)_INT[AN_LINK_GOOD]. */
uint64_t an_complete : 1; /**< [ 12: 12](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU(0..3)_INT[AN_COMPLETE]. */
uint64_t training_done : 1; /**< [ 13: 13](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU(0..3)_INT[TRAINING_DONE]. */
uint64_t training_failure : 1; /**< [ 14: 14](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU(0..3)_INT[TRAINING_FAILURE]. */
uint64_t reserved_15_63 : 49;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_spux_int_ena_w1s bdk_bgxx_spux_int_ena_w1s_t;
static inline uint64_t BDK_BGXX_SPUX_INT_ENA_W1S(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_INT_ENA_W1S(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010238ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0010238ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010238ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_INT_ENA_W1S", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_INT_ENA_W1S(a,b) bdk_bgxx_spux_int_ena_w1s_t
#define bustype_BDK_BGXX_SPUX_INT_ENA_W1S(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_INT_ENA_W1S(a,b) "BGXX_SPUX_INT_ENA_W1S"
#define device_bar_BDK_BGXX_SPUX_INT_ENA_W1S(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_INT_ENA_W1S(a,b) (a)
#define arguments_BDK_BGXX_SPUX_INT_ENA_W1S(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_int_w1s
*
* BGX SPU Interrupt Set Registers
* This register sets interrupt bits.
*/
union bdk_bgxx_spux_int_w1s
{
uint64_t u;
struct bdk_bgxx_spux_int_w1s_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_15_63 : 49;
uint64_t training_failure : 1; /**< [ 14: 14](R/W1S/H) Reads or sets BGX(0..1)_SPU(0..3)_INT[TRAINING_FAILURE]. */
uint64_t training_done : 1; /**< [ 13: 13](R/W1S/H) Reads or sets BGX(0..1)_SPU(0..3)_INT[TRAINING_DONE]. */
uint64_t an_complete : 1; /**< [ 12: 12](R/W1S/H) Reads or sets BGX(0..1)_SPU(0..3)_INT[AN_COMPLETE]. */
uint64_t an_link_good : 1; /**< [ 11: 11](R/W1S/H) Reads or sets BGX(0..1)_SPU(0..3)_INT[AN_LINK_GOOD]. */
uint64_t an_page_rx : 1; /**< [ 10: 10](R/W1S/H) Reads or sets BGX(0..1)_SPU(0..3)_INT[AN_PAGE_RX]. */
uint64_t fec_uncorr : 1; /**< [ 9: 9](R/W1S/H) Reads or sets BGX(0..1)_SPU(0..3)_INT[FEC_UNCORR]. */
uint64_t fec_corr : 1; /**< [ 8: 8](R/W1S/H) Reads or sets BGX(0..1)_SPU(0..3)_INT[FEC_CORR]. */
uint64_t bip_err : 1; /**< [ 7: 7](R/W1S/H) Reads or sets BGX(0..1)_SPU(0..3)_INT[BIP_ERR]. */
uint64_t dbg_sync : 1; /**< [ 6: 6](R/W1S/H) Reads or sets BGX(0..1)_SPU(0..3)_INT[DBG_SYNC]. */
uint64_t algnlos : 1; /**< [ 5: 5](R/W1S/H) Reads or sets BGX(0..1)_SPU(0..3)_INT[ALGNLOS]. */
uint64_t synlos : 1; /**< [ 4: 4](R/W1S/H) Reads or sets BGX(0..1)_SPU(0..3)_INT[SYNLOS]. */
uint64_t bitlckls : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..1)_SPU(0..3)_INT[BITLCKLS]. */
uint64_t err_blk : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..1)_SPU(0..3)_INT[ERR_BLK]. */
uint64_t rx_link_down : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..1)_SPU(0..3)_INT[RX_LINK_DOWN]. */
uint64_t rx_link_up : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..1)_SPU(0..3)_INT[RX_LINK_UP]. */
#else /* Word 0 - Little Endian */
uint64_t rx_link_up : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..1)_SPU(0..3)_INT[RX_LINK_UP]. */
uint64_t rx_link_down : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..1)_SPU(0..3)_INT[RX_LINK_DOWN]. */
uint64_t err_blk : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..1)_SPU(0..3)_INT[ERR_BLK]. */
uint64_t bitlckls : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..1)_SPU(0..3)_INT[BITLCKLS]. */
uint64_t synlos : 1; /**< [ 4: 4](R/W1S/H) Reads or sets BGX(0..1)_SPU(0..3)_INT[SYNLOS]. */
uint64_t algnlos : 1; /**< [ 5: 5](R/W1S/H) Reads or sets BGX(0..1)_SPU(0..3)_INT[ALGNLOS]. */
uint64_t dbg_sync : 1; /**< [ 6: 6](R/W1S/H) Reads or sets BGX(0..1)_SPU(0..3)_INT[DBG_SYNC]. */
uint64_t bip_err : 1; /**< [ 7: 7](R/W1S/H) Reads or sets BGX(0..1)_SPU(0..3)_INT[BIP_ERR]. */
uint64_t fec_corr : 1; /**< [ 8: 8](R/W1S/H) Reads or sets BGX(0..1)_SPU(0..3)_INT[FEC_CORR]. */
uint64_t fec_uncorr : 1; /**< [ 9: 9](R/W1S/H) Reads or sets BGX(0..1)_SPU(0..3)_INT[FEC_UNCORR]. */
uint64_t an_page_rx : 1; /**< [ 10: 10](R/W1S/H) Reads or sets BGX(0..1)_SPU(0..3)_INT[AN_PAGE_RX]. */
uint64_t an_link_good : 1; /**< [ 11: 11](R/W1S/H) Reads or sets BGX(0..1)_SPU(0..3)_INT[AN_LINK_GOOD]. */
uint64_t an_complete : 1; /**< [ 12: 12](R/W1S/H) Reads or sets BGX(0..1)_SPU(0..3)_INT[AN_COMPLETE]. */
uint64_t training_done : 1; /**< [ 13: 13](R/W1S/H) Reads or sets BGX(0..1)_SPU(0..3)_INT[TRAINING_DONE]. */
uint64_t training_failure : 1; /**< [ 14: 14](R/W1S/H) Reads or sets BGX(0..1)_SPU(0..3)_INT[TRAINING_FAILURE]. */
uint64_t reserved_15_63 : 49;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_int_w1s_s cn81xx; */
/* struct bdk_bgxx_spux_int_w1s_s cn88xx; */
struct bdk_bgxx_spux_int_w1s_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_15_63 : 49;
uint64_t training_failure : 1; /**< [ 14: 14](R/W1S/H) Reads or sets BGX(0..3)_SPU(0..3)_INT[TRAINING_FAILURE]. */
uint64_t training_done : 1; /**< [ 13: 13](R/W1S/H) Reads or sets BGX(0..3)_SPU(0..3)_INT[TRAINING_DONE]. */
uint64_t an_complete : 1; /**< [ 12: 12](R/W1S/H) Reads or sets BGX(0..3)_SPU(0..3)_INT[AN_COMPLETE]. */
uint64_t an_link_good : 1; /**< [ 11: 11](R/W1S/H) Reads or sets BGX(0..3)_SPU(0..3)_INT[AN_LINK_GOOD]. */
uint64_t an_page_rx : 1; /**< [ 10: 10](R/W1S/H) Reads or sets BGX(0..3)_SPU(0..3)_INT[AN_PAGE_RX]. */
uint64_t fec_uncorr : 1; /**< [ 9: 9](R/W1S/H) Reads or sets BGX(0..3)_SPU(0..3)_INT[FEC_UNCORR]. */
uint64_t fec_corr : 1; /**< [ 8: 8](R/W1S/H) Reads or sets BGX(0..3)_SPU(0..3)_INT[FEC_CORR]. */
uint64_t bip_err : 1; /**< [ 7: 7](R/W1S/H) Reads or sets BGX(0..3)_SPU(0..3)_INT[BIP_ERR]. */
uint64_t dbg_sync : 1; /**< [ 6: 6](R/W1S/H) Reads or sets BGX(0..3)_SPU(0..3)_INT[DBG_SYNC]. */
uint64_t algnlos : 1; /**< [ 5: 5](R/W1S/H) Reads or sets BGX(0..3)_SPU(0..3)_INT[ALGNLOS]. */
uint64_t synlos : 1; /**< [ 4: 4](R/W1S/H) Reads or sets BGX(0..3)_SPU(0..3)_INT[SYNLOS]. */
uint64_t bitlckls : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..3)_SPU(0..3)_INT[BITLCKLS]. */
uint64_t err_blk : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..3)_SPU(0..3)_INT[ERR_BLK]. */
uint64_t rx_link_down : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..3)_SPU(0..3)_INT[RX_LINK_DOWN]. */
uint64_t rx_link_up : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..3)_SPU(0..3)_INT[RX_LINK_UP]. */
#else /* Word 0 - Little Endian */
uint64_t rx_link_up : 1; /**< [ 0: 0](R/W1S/H) Reads or sets BGX(0..3)_SPU(0..3)_INT[RX_LINK_UP]. */
uint64_t rx_link_down : 1; /**< [ 1: 1](R/W1S/H) Reads or sets BGX(0..3)_SPU(0..3)_INT[RX_LINK_DOWN]. */
uint64_t err_blk : 1; /**< [ 2: 2](R/W1S/H) Reads or sets BGX(0..3)_SPU(0..3)_INT[ERR_BLK]. */
uint64_t bitlckls : 1; /**< [ 3: 3](R/W1S/H) Reads or sets BGX(0..3)_SPU(0..3)_INT[BITLCKLS]. */
uint64_t synlos : 1; /**< [ 4: 4](R/W1S/H) Reads or sets BGX(0..3)_SPU(0..3)_INT[SYNLOS]. */
uint64_t algnlos : 1; /**< [ 5: 5](R/W1S/H) Reads or sets BGX(0..3)_SPU(0..3)_INT[ALGNLOS]. */
uint64_t dbg_sync : 1; /**< [ 6: 6](R/W1S/H) Reads or sets BGX(0..3)_SPU(0..3)_INT[DBG_SYNC]. */
uint64_t bip_err : 1; /**< [ 7: 7](R/W1S/H) Reads or sets BGX(0..3)_SPU(0..3)_INT[BIP_ERR]. */
uint64_t fec_corr : 1; /**< [ 8: 8](R/W1S/H) Reads or sets BGX(0..3)_SPU(0..3)_INT[FEC_CORR]. */
uint64_t fec_uncorr : 1; /**< [ 9: 9](R/W1S/H) Reads or sets BGX(0..3)_SPU(0..3)_INT[FEC_UNCORR]. */
uint64_t an_page_rx : 1; /**< [ 10: 10](R/W1S/H) Reads or sets BGX(0..3)_SPU(0..3)_INT[AN_PAGE_RX]. */
uint64_t an_link_good : 1; /**< [ 11: 11](R/W1S/H) Reads or sets BGX(0..3)_SPU(0..3)_INT[AN_LINK_GOOD]. */
uint64_t an_complete : 1; /**< [ 12: 12](R/W1S/H) Reads or sets BGX(0..3)_SPU(0..3)_INT[AN_COMPLETE]. */
uint64_t training_done : 1; /**< [ 13: 13](R/W1S/H) Reads or sets BGX(0..3)_SPU(0..3)_INT[TRAINING_DONE]. */
uint64_t training_failure : 1; /**< [ 14: 14](R/W1S/H) Reads or sets BGX(0..3)_SPU(0..3)_INT[TRAINING_FAILURE]. */
uint64_t reserved_15_63 : 49;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_spux_int_w1s bdk_bgxx_spux_int_w1s_t;
static inline uint64_t BDK_BGXX_SPUX_INT_W1S(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_INT_W1S(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010228ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0010228ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010228ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_INT_W1S", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_INT_W1S(a,b) bdk_bgxx_spux_int_w1s_t
#define bustype_BDK_BGXX_SPUX_INT_W1S(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_INT_W1S(a,b) "BGXX_SPUX_INT_W1S"
#define device_bar_BDK_BGXX_SPUX_INT_W1S(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_INT_W1S(a,b) (a)
#define arguments_BDK_BGXX_SPUX_INT_W1S(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_lpcs_states
*
* BGX SPU BASE-X Transmit/Receive States Registers
*/
union bdk_bgxx_spux_lpcs_states
{
uint64_t u;
struct bdk_bgxx_spux_lpcs_states_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_15_63 : 49;
uint64_t br_rx_sm : 3; /**< [ 14: 12](RO/H) BASE-R receive state machine state */
uint64_t reserved_10_11 : 2;
uint64_t bx_rx_sm : 2; /**< [ 9: 8](RO/H) BASE-X receive state machine state */
uint64_t deskew_am_found : 4; /**< [ 7: 4](RO/H) 40GBASE-R deskew state machine alignment marker found flag per logical PCS lane ID. */
uint64_t reserved_3 : 1;
uint64_t deskew_sm : 3; /**< [ 2: 0](RO/H) BASE-X and 40GBASE-R deskew state machine state */
#else /* Word 0 - Little Endian */
uint64_t deskew_sm : 3; /**< [ 2: 0](RO/H) BASE-X and 40GBASE-R deskew state machine state */
uint64_t reserved_3 : 1;
uint64_t deskew_am_found : 4; /**< [ 7: 4](RO/H) 40GBASE-R deskew state machine alignment marker found flag per logical PCS lane ID. */
uint64_t bx_rx_sm : 2; /**< [ 9: 8](RO/H) BASE-X receive state machine state */
uint64_t reserved_10_11 : 2;
uint64_t br_rx_sm : 3; /**< [ 14: 12](RO/H) BASE-R receive state machine state */
uint64_t reserved_15_63 : 49;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_lpcs_states_s cn; */
};
typedef union bdk_bgxx_spux_lpcs_states bdk_bgxx_spux_lpcs_states_t;
static inline uint64_t BDK_BGXX_SPUX_LPCS_STATES(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_LPCS_STATES(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010208ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0010208ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010208ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_LPCS_STATES", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_LPCS_STATES(a,b) bdk_bgxx_spux_lpcs_states_t
#define bustype_BDK_BGXX_SPUX_LPCS_STATES(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_LPCS_STATES(a,b) "BGXX_SPUX_LPCS_STATES"
#define device_bar_BDK_BGXX_SPUX_LPCS_STATES(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_LPCS_STATES(a,b) (a)
#define arguments_BDK_BGXX_SPUX_LPCS_STATES(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_misc_control
*
* BGX SPU Miscellaneous Control Registers
* "* RX logical PCS lane polarity vector \<3:0\> = [XOR_RXPLRT]\<3:0\> ^ {4{[RXPLRT]}}.
* * TX logical PCS lane polarity vector \<3:0\> = [XOR_TXPLRT]\<3:0\> ^ {4{[TXPLRT]}}.
*
* In short, keep [RXPLRT] and [TXPLRT] cleared, and use [XOR_RXPLRT] and [XOR_TXPLRT] fields to
* define
* the polarity per logical PCS lane. Only bit 0 of vector is used for 10GBASE-R, and only bits
* 1:0 of vector are used for RXAUI."
*/
union bdk_bgxx_spux_misc_control
{
uint64_t u;
struct bdk_bgxx_spux_misc_control_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_13_63 : 51;
uint64_t rx_packet_dis : 1; /**< [ 12: 12](R/W) Receive packet disable. Software can set or clear this bit at any time to gracefully
disable or re-enable packet reception by the LPCS. If this bit is set while a packet is
being received, the packet is completed and all subsequent received packets are discarded
by the LPCS. Similarly, if this bit is cleared while a received packet is being discarded,
packet reception resumes after the current packet is fully discarded. When set for a
40GBASE-R or 10GBASE-R LMAC/LPCS type (selected by BGX()_CMR()_CONFIG[LMAC_TYPE]),
received errors and faults will be ignored while receive packets are discarded; idles will
be sent to the MAC layer (SMU) and the errored blocks counter
(BGX()_SPU()_BR_STATUS2[ERR_BLKS]) will not increment. */
uint64_t skip_after_term : 1; /**< [ 11: 11](R/W) Enable sending of idle skip after terminate. This bit is meaningful when the logical PCS
type is XAUI or RXAUI (selected by BGX()_CMR()_CONFIG[LMAC_TYPE]), and has no
effect otherwise. When set, the LMAC/LPCS transmits more idle skip columns for clock
compensation. Typically set in HiGig/HiGig2 modes; clear otherwise. This field can be set
to ensure sufficient density of XAUI idle skip (||R||) columns with a small transmit
inter-frame gap (IFG) in order to allow the link partner's receiver to delete ||R||
columns as needed for clock rate compensation. It is usually set when the LMAC's transmit
IFG is set to eight bytes in HiGig/HiGig2 modes (i.e. BGX()_SMU()_TX_IFG[IFG1] +
BGX()_SMU()_TX_IFG[IFG2] = 8), and should be cleared when the transmit IFG is
greater than eight bytes. When this bit is set, the SPU will send an ||R|| column after a
||T0|| column (terminate in lane 0) if no ||R|| was sent in the previous IFG. This is a
minor deviation from the functionality specified in 802.3-2008 Figure 48-6 (PCS transmit
source state diagram), whereby the state will transition directly from SEND_DATA to
SEND_RANDOM_R after ||T0|| if no ||R|| was transmitted in the previous IFG. Sending ||R||
after ||T0|| only (and not ||T1||, |T2|| or ||T3||) ensures that the check_end function at
the receiving end, as defined in 802.3-2008 sub-clause 48.2.6.1.4, does not detect an
error due to this functional change. When this bit is clear, the LMAC will fully conform
to the functionality specified in Figure 48-6. */
uint64_t intlv_rdisp : 1; /**< [ 10: 10](R/W) RXAUI interleaved running disparity. This bit is meaningful when the logical PCS type is
RXAUI (BGX()_CMR()_CONFIG[LMAC_TYPE] = RXAUI), and has no effect otherwise. It
selects which disparity calculation to use when combining or splitting the RXAUI lanes, as
follows:
_ 0 = Common running disparity. Common running disparity is computed for even and odd
code-
groups of an RXAUI lane, i.e. interleave lanes before PCS layer as described in the Dune
Networks/Broadcom RXAUI v2.1 specification. This obeys 6.25GHz SerDes disparity.
_ 1 = Interleaved running disparity: Running disparity is computed separately for even and
odd code-groups of an RXAUI lane, i.e. interleave lanes after PCS layer as described in
the Marvell RXAUI Interface specification. This does not obey 6.25GHz SerDes disparity. */
uint64_t xor_rxplrt : 4; /**< [ 9: 6](R/W) RX polarity control per logical PCS lane */
uint64_t xor_txplrt : 4; /**< [ 5: 2](R/W) TX polarity control per logical PCS lane */
uint64_t rxplrt : 1; /**< [ 1: 1](R/W) Receive polarity. 1 = inverted polarity. 0 = normal polarity. */
uint64_t txplrt : 1; /**< [ 0: 0](R/W) Transmit polarity. 1 = inverted polarity. 0 = normal polarity. */
#else /* Word 0 - Little Endian */
uint64_t txplrt : 1; /**< [ 0: 0](R/W) Transmit polarity. 1 = inverted polarity. 0 = normal polarity. */
uint64_t rxplrt : 1; /**< [ 1: 1](R/W) Receive polarity. 1 = inverted polarity. 0 = normal polarity. */
uint64_t xor_txplrt : 4; /**< [ 5: 2](R/W) TX polarity control per logical PCS lane */
uint64_t xor_rxplrt : 4; /**< [ 9: 6](R/W) RX polarity control per logical PCS lane */
uint64_t intlv_rdisp : 1; /**< [ 10: 10](R/W) RXAUI interleaved running disparity. This bit is meaningful when the logical PCS type is
RXAUI (BGX()_CMR()_CONFIG[LMAC_TYPE] = RXAUI), and has no effect otherwise. It
selects which disparity calculation to use when combining or splitting the RXAUI lanes, as
follows:
_ 0 = Common running disparity. Common running disparity is computed for even and odd
code-
groups of an RXAUI lane, i.e. interleave lanes before PCS layer as described in the Dune
Networks/Broadcom RXAUI v2.1 specification. This obeys 6.25GHz SerDes disparity.
_ 1 = Interleaved running disparity: Running disparity is computed separately for even and
odd code-groups of an RXAUI lane, i.e. interleave lanes after PCS layer as described in
the Marvell RXAUI Interface specification. This does not obey 6.25GHz SerDes disparity. */
uint64_t skip_after_term : 1; /**< [ 11: 11](R/W) Enable sending of idle skip after terminate. This bit is meaningful when the logical PCS
type is XAUI or RXAUI (selected by BGX()_CMR()_CONFIG[LMAC_TYPE]), and has no
effect otherwise. When set, the LMAC/LPCS transmits more idle skip columns for clock
compensation. Typically set in HiGig/HiGig2 modes; clear otherwise. This field can be set
to ensure sufficient density of XAUI idle skip (||R||) columns with a small transmit
inter-frame gap (IFG) in order to allow the link partner's receiver to delete ||R||
columns as needed for clock rate compensation. It is usually set when the LMAC's transmit
IFG is set to eight bytes in HiGig/HiGig2 modes (i.e. BGX()_SMU()_TX_IFG[IFG1] +
BGX()_SMU()_TX_IFG[IFG2] = 8), and should be cleared when the transmit IFG is
greater than eight bytes. When this bit is set, the SPU will send an ||R|| column after a
||T0|| column (terminate in lane 0) if no ||R|| was sent in the previous IFG. This is a
minor deviation from the functionality specified in 802.3-2008 Figure 48-6 (PCS transmit
source state diagram), whereby the state will transition directly from SEND_DATA to
SEND_RANDOM_R after ||T0|| if no ||R|| was transmitted in the previous IFG. Sending ||R||
after ||T0|| only (and not ||T1||, |T2|| or ||T3||) ensures that the check_end function at
the receiving end, as defined in 802.3-2008 sub-clause 48.2.6.1.4, does not detect an
error due to this functional change. When this bit is clear, the LMAC will fully conform
to the functionality specified in Figure 48-6. */
uint64_t rx_packet_dis : 1; /**< [ 12: 12](R/W) Receive packet disable. Software can set or clear this bit at any time to gracefully
disable or re-enable packet reception by the LPCS. If this bit is set while a packet is
being received, the packet is completed and all subsequent received packets are discarded
by the LPCS. Similarly, if this bit is cleared while a received packet is being discarded,
packet reception resumes after the current packet is fully discarded. When set for a
40GBASE-R or 10GBASE-R LMAC/LPCS type (selected by BGX()_CMR()_CONFIG[LMAC_TYPE]),
received errors and faults will be ignored while receive packets are discarded; idles will
be sent to the MAC layer (SMU) and the errored blocks counter
(BGX()_SPU()_BR_STATUS2[ERR_BLKS]) will not increment. */
uint64_t reserved_13_63 : 51;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_misc_control_s cn; */
};
typedef union bdk_bgxx_spux_misc_control bdk_bgxx_spux_misc_control_t;
static inline uint64_t BDK_BGXX_SPUX_MISC_CONTROL(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_MISC_CONTROL(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010218ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0010218ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010218ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_MISC_CONTROL", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_MISC_CONTROL(a,b) bdk_bgxx_spux_misc_control_t
#define bustype_BDK_BGXX_SPUX_MISC_CONTROL(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_MISC_CONTROL(a,b) "BGXX_SPUX_MISC_CONTROL"
#define device_bar_BDK_BGXX_SPUX_MISC_CONTROL(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_MISC_CONTROL(a,b) (a)
#define arguments_BDK_BGXX_SPUX_MISC_CONTROL(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_spd_abil
*
* BGX SPU PCS Speed Ability Registers
*/
union bdk_bgxx_spux_spd_abil
{
uint64_t u;
struct bdk_bgxx_spux_spd_abil_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_4_63 : 60;
uint64_t hundredgb : 1; /**< [ 3: 3](RO) 100G capable. Always 0. */
uint64_t fortygb : 1; /**< [ 2: 2](RO/H) 40G capable. Always 1. */
uint64_t tenpasst : 1; /**< [ 1: 1](RO) 10PASS-TS/2BASE-TL capable. Always 0. */
uint64_t tengb : 1; /**< [ 0: 0](RO/H) 10G capable. Always 1. */
#else /* Word 0 - Little Endian */
uint64_t tengb : 1; /**< [ 0: 0](RO/H) 10G capable. Always 1. */
uint64_t tenpasst : 1; /**< [ 1: 1](RO) 10PASS-TS/2BASE-TL capable. Always 0. */
uint64_t fortygb : 1; /**< [ 2: 2](RO/H) 40G capable. Always 1. */
uint64_t hundredgb : 1; /**< [ 3: 3](RO) 100G capable. Always 0. */
uint64_t reserved_4_63 : 60;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_spd_abil_s cn; */
};
typedef union bdk_bgxx_spux_spd_abil bdk_bgxx_spux_spd_abil_t;
static inline uint64_t BDK_BGXX_SPUX_SPD_ABIL(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_SPD_ABIL(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010010ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0010010ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010010ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_SPD_ABIL", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_SPD_ABIL(a,b) bdk_bgxx_spux_spd_abil_t
#define bustype_BDK_BGXX_SPUX_SPD_ABIL(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_SPD_ABIL(a,b) "BGXX_SPUX_SPD_ABIL"
#define device_bar_BDK_BGXX_SPUX_SPD_ABIL(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_SPD_ABIL(a,b) (a)
#define arguments_BDK_BGXX_SPUX_SPD_ABIL(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_status1
*
* BGX SPU Status 1 Registers
*/
union bdk_bgxx_spux_status1
{
uint64_t u;
struct bdk_bgxx_spux_status1_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_8_63 : 56;
uint64_t flt : 1; /**< [ 7: 7](RO/H) Fault condition detected.
This bit is a logical OR of BGX()_SPU()_STATUS2[XMTFLT, RCVFLT]. */
uint64_t reserved_3_6 : 4;
uint64_t rcv_lnk : 1; /**< [ 2: 2](R/W1S/H) PCS receive link status:
0 = receive link down.
1 = receive link up.
This is a latching-low bit; it stays clear until a write-1-to-set by software.
For a BASE-X logical PCS type (in the associated BGX()_CMR()_CONFIG[LMAC_TYPE] =
XAUI or RXAUI), this is a latching-low version of BGX()_SPU()_BX_STATUS[ALIGND].
For a BASE-R logical PCS type (in the associated BGX()_CMR()_CONFIG[LMAC_TYPE] =
10G_R or 40G_R), this is a latching-low version of
BGX()_SPU()_BR_STATUS1[RCV_LNK]. */
uint64_t lpable : 1; /**< [ 1: 1](RO) Low-power ability. Always returns 1 to indicate that the LPCS supports low-power mode. */
uint64_t reserved_0 : 1;
#else /* Word 0 - Little Endian */
uint64_t reserved_0 : 1;
uint64_t lpable : 1; /**< [ 1: 1](RO) Low-power ability. Always returns 1 to indicate that the LPCS supports low-power mode. */
uint64_t rcv_lnk : 1; /**< [ 2: 2](R/W1S/H) PCS receive link status:
0 = receive link down.
1 = receive link up.
This is a latching-low bit; it stays clear until a write-1-to-set by software.
For a BASE-X logical PCS type (in the associated BGX()_CMR()_CONFIG[LMAC_TYPE] =
XAUI or RXAUI), this is a latching-low version of BGX()_SPU()_BX_STATUS[ALIGND].
For a BASE-R logical PCS type (in the associated BGX()_CMR()_CONFIG[LMAC_TYPE] =
10G_R or 40G_R), this is a latching-low version of
BGX()_SPU()_BR_STATUS1[RCV_LNK]. */
uint64_t reserved_3_6 : 4;
uint64_t flt : 1; /**< [ 7: 7](RO/H) Fault condition detected.
This bit is a logical OR of BGX()_SPU()_STATUS2[XMTFLT, RCVFLT]. */
uint64_t reserved_8_63 : 56;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_status1_s cn; */
};
typedef union bdk_bgxx_spux_status1 bdk_bgxx_spux_status1_t;
static inline uint64_t BDK_BGXX_SPUX_STATUS1(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_STATUS1(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010008ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0010008ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010008ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_STATUS1", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_STATUS1(a,b) bdk_bgxx_spux_status1_t
#define bustype_BDK_BGXX_SPUX_STATUS1(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_STATUS1(a,b) "BGXX_SPUX_STATUS1"
#define device_bar_BDK_BGXX_SPUX_STATUS1(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_STATUS1(a,b) (a)
#define arguments_BDK_BGXX_SPUX_STATUS1(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu#_status2
*
* BGX SPU Status 2 Registers
*/
union bdk_bgxx_spux_status2
{
uint64_t u;
struct bdk_bgxx_spux_status2_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_16_63 : 48;
uint64_t dev : 2; /**< [ 15: 14](RO/H) Device present. Always returns 0x2 to indicate a device is present at this address. */
uint64_t reserved_12_13 : 2;
uint64_t xmtflt : 1; /**< [ 11: 11](RO/H) Transmit fault. Always returns 0. */
uint64_t rcvflt : 1; /**< [ 10: 10](R/W1C/H) Receive fault: 1 = receive fault. 0 = no receive fault. Latching high bit; stays set until
a write-1-to-clear by software. */
uint64_t reserved_6_9 : 4;
uint64_t hundredgb_r : 1; /**< [ 5: 5](RO) 100GBASE-R capable. Always 0. */
uint64_t fortygb_r : 1; /**< [ 4: 4](RO/H) 40GBASE-R capable. Always 1. */
uint64_t tengb_t : 1; /**< [ 3: 3](RO) 10GBASE-T capable. Always 0. */
uint64_t tengb_w : 1; /**< [ 2: 2](RO) 10GBASE-W capable. Always 0. */
uint64_t tengb_x : 1; /**< [ 1: 1](RO/H) 10GBASE-X capable. Always 1. */
uint64_t tengb_r : 1; /**< [ 0: 0](RO/H) 10GBASE-R capable. Always 1. */
#else /* Word 0 - Little Endian */
uint64_t tengb_r : 1; /**< [ 0: 0](RO/H) 10GBASE-R capable. Always 1. */
uint64_t tengb_x : 1; /**< [ 1: 1](RO/H) 10GBASE-X capable. Always 1. */
uint64_t tengb_w : 1; /**< [ 2: 2](RO) 10GBASE-W capable. Always 0. */
uint64_t tengb_t : 1; /**< [ 3: 3](RO) 10GBASE-T capable. Always 0. */
uint64_t fortygb_r : 1; /**< [ 4: 4](RO/H) 40GBASE-R capable. Always 1. */
uint64_t hundredgb_r : 1; /**< [ 5: 5](RO) 100GBASE-R capable. Always 0. */
uint64_t reserved_6_9 : 4;
uint64_t rcvflt : 1; /**< [ 10: 10](R/W1C/H) Receive fault: 1 = receive fault. 0 = no receive fault. Latching high bit; stays set until
a write-1-to-clear by software. */
uint64_t xmtflt : 1; /**< [ 11: 11](RO/H) Transmit fault. Always returns 0. */
uint64_t reserved_12_13 : 2;
uint64_t dev : 2; /**< [ 15: 14](RO/H) Device present. Always returns 0x2 to indicate a device is present at this address. */
uint64_t reserved_16_63 : 48;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spux_status2_s cn; */
};
typedef union bdk_bgxx_spux_status2 bdk_bgxx_spux_status2_t;
static inline uint64_t BDK_BGXX_SPUX_STATUS2(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPUX_STATUS2(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010020ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0010020ll + 0x1000000ll * ((a) & 0x3) + 0x100000ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010020ll + 0x1000000ll * ((a) & 0x1) + 0x100000ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPUX_STATUS2", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPUX_STATUS2(a,b) bdk_bgxx_spux_status2_t
#define bustype_BDK_BGXX_SPUX_STATUS2(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPUX_STATUS2(a,b) "BGXX_SPUX_STATUS2"
#define device_bar_BDK_BGXX_SPUX_STATUS2(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPUX_STATUS2(a,b) (a)
#define arguments_BDK_BGXX_SPUX_STATUS2(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu_bist_status
*
* BGX SPU BIST Status Registers
* This register provides memory BIST status from the SPU receive buffer lane FIFOs.
*/
union bdk_bgxx_spu_bist_status
{
uint64_t u;
struct bdk_bgxx_spu_bist_status_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_4_63 : 60;
uint64_t rx_buf_bist_status : 4; /**< [ 3: 0](RO/H) SPU receive buffer BIST status for lanes 3-0. One bit per SerDes lane, set to indicate
BIST
failure for the associated receive buffer lane FIFO. */
#else /* Word 0 - Little Endian */
uint64_t rx_buf_bist_status : 4; /**< [ 3: 0](RO/H) SPU receive buffer BIST status for lanes 3-0. One bit per SerDes lane, set to indicate
BIST
failure for the associated receive buffer lane FIFO. */
uint64_t reserved_4_63 : 60;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spu_bist_status_s cn; */
};
typedef union bdk_bgxx_spu_bist_status bdk_bgxx_spu_bist_status_t;
static inline uint64_t BDK_BGXX_SPU_BIST_STATUS(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPU_BIST_STATUS(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e0010330ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e0010330ll + 0x1000000ll * ((a) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && (a<=1))
return 0x87e0e0010330ll + 0x1000000ll * ((a) & 0x1);
__bdk_csr_fatal("BGXX_SPU_BIST_STATUS", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_SPU_BIST_STATUS(a) bdk_bgxx_spu_bist_status_t
#define bustype_BDK_BGXX_SPU_BIST_STATUS(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPU_BIST_STATUS(a) "BGXX_SPU_BIST_STATUS"
#define device_bar_BDK_BGXX_SPU_BIST_STATUS(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPU_BIST_STATUS(a) (a)
#define arguments_BDK_BGXX_SPU_BIST_STATUS(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_spu_dbg_control
*
* BGX SPU Debug Control Registers
*/
union bdk_bgxx_spu_dbg_control
{
uint64_t u;
struct bdk_bgxx_spu_dbg_control_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_56_63 : 8;
uint64_t ms_clk_period : 12; /**< [ 55: 44](R/W) Millisecond clock period. Specifies the number of microsecond clock ticks per millisecond,
minus one. The default value of 999 (0x3E7) should be used during normal operation; other
values may be used for test/debug purposes. */
uint64_t us_clk_period : 12; /**< [ 43: 32](R/W) Microsecond clock period. Specifies the number of SCLK cycles per microseconds, minus one.
For example, if SCLK runs at 1.3 GHz, the number of SCLK cycles per microsecond is 1,300
so the value of this field should be 1,299 (0x513). This is used by the BASE-R BER monitor
timers. */
uint64_t reserved_31 : 1;
uint64_t br_ber_mon_dis : 1; /**< [ 30: 30](R/W) BASE-R bit error rate monitor disable. This bit should be clear for normal operation.
Setting it disables the BASE-R BER monitor state machine defined in 802.3-2008 Figure
49-13 for 10GBASE-R and 802.3ba-2010 Figure 82-13 for 40GBASE-R. */
uint64_t an_nonce_match_dis : 1; /**< [ 29: 29](R/W) Autonegotiation nonce match disable. This bit should be clear for normal operation.
Setting it disables Nonce Match check by forcing nonce_match variable to 0 in the
autonegotiation arbitration state diagram, as defined in 802.3-2008 Figure 73-11. This bit
can
be set by software for test purposes, e.g. for running autonegotiation in loopback mode. */
uint64_t timestamp_norm_dis : 1; /**< [ 28: 28](R/W) 40GBASE-R RX timestamp normalization disable. This bit controls the generation of the
receive SOP timestamp passed to the SMU sub-block for a 40GBASE-R LMAC/LPCS. When this bit
is clear, SPU normalizes the receive SOP timestamp in order to compensate for lane-to-lane
skew on a 40GBASE-R link, as described below. When this bit is set, timestamp
normalization is disabled and SPU directly passes the captured SOP timestamp values to
SMU.
In 40GBASE-R mode, a packet's SOP block can be transferred on any of the LMAC's lanes. In
the presence of lane-to-lane skew, the SOP delay from transmit (by the link partner) to
receive by SPU varies depending on which lane is used by the SOP block. This variation
reduces the accuracy of the received SOP timestamp relative to when it was transmitted by
the link partner.
SPU captures the timestamp of the alignment marker received on each SerDes lane during
align/skew detection; the captured value can be read from the SerDes lane's
BGX()_SPU_SDS()_SKEW_STATUS[SKEW_STATUS] field (BGX_SPU_SDS_SKEW_STATUS_S[AM_TIMESTAMP]
sub-field). If
alignment markers are transmitted at about the same time on all lanes by the link partner,
then the difference between the BGX_SPU_SDS_SKEW_STATUS_S[AM_TIMESTAMP] values for a pair
of lanes represents the
approximate skew between those lanes.
SPU uses the 40GBASE-R LMAC's programmed PCS lane 0 as a reference and computes the
BGX_SPU_SDS_SKEW_STATUS_S[AM_TIMESTAMP] delta of every other lane relative to PCS lane 0.
When normalization is
enabled, SPU adjusts the timestamp of a received SOP by subtracting the receiving lane's
BGX_SPU_SDS_SKEW_STATUS_S[AM_TIMESTAMP] delta from the captured timestamp value. The
adjusted/normalized timestamp
value is then passed to SMU along with the SOP.
Software can determine the actual maximum skew of a 40GBASE-R link by examining the
BGX_SPU_SDS_SKEW_STATUS_S[AM_TIMESTAMP] values in the BGX()_SPU_SDS()_SKEW_STATUS
registers, and decide if
timestamp normalization should be enabled or disabled to improve PTP accuracy.
Normalization improves accuracy for larger skew values but reduces the accuracy (due to
timestamp measurement errors) for small skew values. */
uint64_t rx_buf_flip_synd : 8; /**< [ 27: 20](R/W) Flip SPU receive buffer FIFO ECC bits. Two bits per SerDes lane; used to inject single-bit
and
double-bit errors into the ECC field on writes to the associated SPU receive buffer lane
FIFO, as
follows:
0x0 = Normal operation.
0x1 = SBE on ECC bit 0.
0x2 = SBE on ECC bit 1.
0x3 = DBE on ECC bits 1:0. */
uint64_t br_pmd_train_soft_en : 1; /**< [ 19: 19](R/W) Enable BASE-R PMD software controlled link training. This bit configures the operation
mode for BASE-R link training for all LMACs and lanes. When this bit is set along with
BGX()_SPU()_BR_PMD_CONTROL[TRAIN_EN] for a given LMAC, the BASE-R link training
protocol for that LMAC is executed under software control, whereby the contents the
BGX()_SPU()_BR_PMD_LD_CUP and BGX()_SPU()_BR_PMD_LD_REP registers are
updated by software. When this bit is clear and
BGX()_SPU()_BR_PMD_CONTROL[TRAIN_EN] is set, the link training protocol is fully
automated in hardware, whereby the contents BGX()_SPU()_BR_PMD_LD_CUP and
BGX()_SPU()_BR_PMD_LD_REP registers are automatically updated by hardware. */
uint64_t an_arb_link_chk_en : 1; /**< [ 18: 18](R/W) Enable link status checking by autonegotiation arbitration state machine. When
autonegotiation is enabled (BGX()_SPU()_AN_CONTROL[AN_EN] is set), this bit controls
the behavior of the autonegotiation arbitration state machine when it reaches the AN GOOD
CHECK state after DME pages are successfully exchanged, as defined in Figure 73-11 in
802.3-2008.
When this bit is set and the negotiated highest common denominator (HCD) technology
matches BGX()_CMR()_CONFIG[LMAC_TYPE], the autonegotiation arbitration SM
performs the actions defined for the AN GOOD CHECK state in Figure 73-11, i.e. run the
link_fail_inhibit timer and eventually transition to the AN GOOD or TRANSMIT DISABLE
state.
When this bit is clear or the HCD technology does not match BGX()_CMR()_CONFIG[LMAC_TYPE],
the AN arbitration
SM stays in the AN GOOD CHECK state, with the expectation that software will perform the
appropriate actions to complete the autonegotiation protocol, as follows:
* If this bit is clear and the HCD technology matches BGX()_CMR()_CONFIG[LMAC_TYPE], clear
BGX()_SPU()_AN_CONTROL[AN_EN].
* Otherwise, disable the LPCS by clearing the BGX()_CMR()_CONFIG[ENABLE], clear
BGX()_SPU()_AN_CONTROL[AN_EN], reconfigure the LPCS with the correct
BGX()_CMR()_CONFIG[LMAC_TYPE],
and re-enable the LPCS by setting BGX()_CMR()_CONFIG[ENABLE].
In both cases, software should implement the link_fail_inhibit timer and verify the link
status as specified for the AN GOOD CHECK state. */
uint64_t rx_buf_cor_dis : 1; /**< [ 17: 17](R/W) When set, disables ECC correction on all SPU receive buffer FIFOs. */
uint64_t scramble_dis : 1; /**< [ 16: 16](R/W) BASE-R scrambler/descrambler disable. Setting this bit to 1 disables the BASE-R scrambler
& descrambler functions and FEC PN-2112 scrambler & descrambler functions for debug
purposes. */
uint64_t reserved_15 : 1;
uint64_t marker_rxp : 15; /**< [ 14: 0](R/W) BASE-R alignment marker receive period. For a multilane BASE-R logical PCS (i.e.
40GBASE-R), this field specifies the expected alignment marker receive period per lane,
i.e. the expected number of received 66b non-marker blocks between consecutive markers on
the same lane. The default value corresponds to a period of 16363 blocks (exclusive) as
specified in 802.3ba-2010. Must be greater than 64. */
#else /* Word 0 - Little Endian */
uint64_t marker_rxp : 15; /**< [ 14: 0](R/W) BASE-R alignment marker receive period. For a multilane BASE-R logical PCS (i.e.
40GBASE-R), this field specifies the expected alignment marker receive period per lane,
i.e. the expected number of received 66b non-marker blocks between consecutive markers on
the same lane. The default value corresponds to a period of 16363 blocks (exclusive) as
specified in 802.3ba-2010. Must be greater than 64. */
uint64_t reserved_15 : 1;
uint64_t scramble_dis : 1; /**< [ 16: 16](R/W) BASE-R scrambler/descrambler disable. Setting this bit to 1 disables the BASE-R scrambler
& descrambler functions and FEC PN-2112 scrambler & descrambler functions for debug
purposes. */
uint64_t rx_buf_cor_dis : 1; /**< [ 17: 17](R/W) When set, disables ECC correction on all SPU receive buffer FIFOs. */
uint64_t an_arb_link_chk_en : 1; /**< [ 18: 18](R/W) Enable link status checking by autonegotiation arbitration state machine. When
autonegotiation is enabled (BGX()_SPU()_AN_CONTROL[AN_EN] is set), this bit controls
the behavior of the autonegotiation arbitration state machine when it reaches the AN GOOD
CHECK state after DME pages are successfully exchanged, as defined in Figure 73-11 in
802.3-2008.
When this bit is set and the negotiated highest common denominator (HCD) technology
matches BGX()_CMR()_CONFIG[LMAC_TYPE], the autonegotiation arbitration SM
performs the actions defined for the AN GOOD CHECK state in Figure 73-11, i.e. run the
link_fail_inhibit timer and eventually transition to the AN GOOD or TRANSMIT DISABLE
state.
When this bit is clear or the HCD technology does not match BGX()_CMR()_CONFIG[LMAC_TYPE],
the AN arbitration
SM stays in the AN GOOD CHECK state, with the expectation that software will perform the
appropriate actions to complete the autonegotiation protocol, as follows:
* If this bit is clear and the HCD technology matches BGX()_CMR()_CONFIG[LMAC_TYPE], clear
BGX()_SPU()_AN_CONTROL[AN_EN].
* Otherwise, disable the LPCS by clearing the BGX()_CMR()_CONFIG[ENABLE], clear
BGX()_SPU()_AN_CONTROL[AN_EN], reconfigure the LPCS with the correct
BGX()_CMR()_CONFIG[LMAC_TYPE],
and re-enable the LPCS by setting BGX()_CMR()_CONFIG[ENABLE].
In both cases, software should implement the link_fail_inhibit timer and verify the link
status as specified for the AN GOOD CHECK state. */
uint64_t br_pmd_train_soft_en : 1; /**< [ 19: 19](R/W) Enable BASE-R PMD software controlled link training. This bit configures the operation
mode for BASE-R link training for all LMACs and lanes. When this bit is set along with
BGX()_SPU()_BR_PMD_CONTROL[TRAIN_EN] for a given LMAC, the BASE-R link training
protocol for that LMAC is executed under software control, whereby the contents the
BGX()_SPU()_BR_PMD_LD_CUP and BGX()_SPU()_BR_PMD_LD_REP registers are
updated by software. When this bit is clear and
BGX()_SPU()_BR_PMD_CONTROL[TRAIN_EN] is set, the link training protocol is fully
automated in hardware, whereby the contents BGX()_SPU()_BR_PMD_LD_CUP and
BGX()_SPU()_BR_PMD_LD_REP registers are automatically updated by hardware. */
uint64_t rx_buf_flip_synd : 8; /**< [ 27: 20](R/W) Flip SPU receive buffer FIFO ECC bits. Two bits per SerDes lane; used to inject single-bit
and
double-bit errors into the ECC field on writes to the associated SPU receive buffer lane
FIFO, as
follows:
0x0 = Normal operation.
0x1 = SBE on ECC bit 0.
0x2 = SBE on ECC bit 1.
0x3 = DBE on ECC bits 1:0. */
uint64_t timestamp_norm_dis : 1; /**< [ 28: 28](R/W) 40GBASE-R RX timestamp normalization disable. This bit controls the generation of the
receive SOP timestamp passed to the SMU sub-block for a 40GBASE-R LMAC/LPCS. When this bit
is clear, SPU normalizes the receive SOP timestamp in order to compensate for lane-to-lane
skew on a 40GBASE-R link, as described below. When this bit is set, timestamp
normalization is disabled and SPU directly passes the captured SOP timestamp values to
SMU.
In 40GBASE-R mode, a packet's SOP block can be transferred on any of the LMAC's lanes. In
the presence of lane-to-lane skew, the SOP delay from transmit (by the link partner) to
receive by SPU varies depending on which lane is used by the SOP block. This variation
reduces the accuracy of the received SOP timestamp relative to when it was transmitted by
the link partner.
SPU captures the timestamp of the alignment marker received on each SerDes lane during
align/skew detection; the captured value can be read from the SerDes lane's
BGX()_SPU_SDS()_SKEW_STATUS[SKEW_STATUS] field (BGX_SPU_SDS_SKEW_STATUS_S[AM_TIMESTAMP]
sub-field). If
alignment markers are transmitted at about the same time on all lanes by the link partner,
then the difference between the BGX_SPU_SDS_SKEW_STATUS_S[AM_TIMESTAMP] values for a pair
of lanes represents the
approximate skew between those lanes.
SPU uses the 40GBASE-R LMAC's programmed PCS lane 0 as a reference and computes the
BGX_SPU_SDS_SKEW_STATUS_S[AM_TIMESTAMP] delta of every other lane relative to PCS lane 0.
When normalization is
enabled, SPU adjusts the timestamp of a received SOP by subtracting the receiving lane's
BGX_SPU_SDS_SKEW_STATUS_S[AM_TIMESTAMP] delta from the captured timestamp value. The
adjusted/normalized timestamp
value is then passed to SMU along with the SOP.
Software can determine the actual maximum skew of a 40GBASE-R link by examining the
BGX_SPU_SDS_SKEW_STATUS_S[AM_TIMESTAMP] values in the BGX()_SPU_SDS()_SKEW_STATUS
registers, and decide if
timestamp normalization should be enabled or disabled to improve PTP accuracy.
Normalization improves accuracy for larger skew values but reduces the accuracy (due to
timestamp measurement errors) for small skew values. */
uint64_t an_nonce_match_dis : 1; /**< [ 29: 29](R/W) Autonegotiation nonce match disable. This bit should be clear for normal operation.
Setting it disables Nonce Match check by forcing nonce_match variable to 0 in the
autonegotiation arbitration state diagram, as defined in 802.3-2008 Figure 73-11. This bit
can
be set by software for test purposes, e.g. for running autonegotiation in loopback mode. */
uint64_t br_ber_mon_dis : 1; /**< [ 30: 30](R/W) BASE-R bit error rate monitor disable. This bit should be clear for normal operation.
Setting it disables the BASE-R BER monitor state machine defined in 802.3-2008 Figure
49-13 for 10GBASE-R and 802.3ba-2010 Figure 82-13 for 40GBASE-R. */
uint64_t reserved_31 : 1;
uint64_t us_clk_period : 12; /**< [ 43: 32](R/W) Microsecond clock period. Specifies the number of SCLK cycles per microseconds, minus one.
For example, if SCLK runs at 1.3 GHz, the number of SCLK cycles per microsecond is 1,300
so the value of this field should be 1,299 (0x513). This is used by the BASE-R BER monitor
timers. */
uint64_t ms_clk_period : 12; /**< [ 55: 44](R/W) Millisecond clock period. Specifies the number of microsecond clock ticks per millisecond,
minus one. The default value of 999 (0x3E7) should be used during normal operation; other
values may be used for test/debug purposes. */
uint64_t reserved_56_63 : 8;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spu_dbg_control_s cn; */
};
typedef union bdk_bgxx_spu_dbg_control bdk_bgxx_spu_dbg_control_t;
static inline uint64_t BDK_BGXX_SPU_DBG_CONTROL(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPU_DBG_CONTROL(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e0010300ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e0010300ll + 0x1000000ll * ((a) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && (a<=1))
return 0x87e0e0010300ll + 0x1000000ll * ((a) & 0x1);
__bdk_csr_fatal("BGXX_SPU_DBG_CONTROL", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_SPU_DBG_CONTROL(a) bdk_bgxx_spu_dbg_control_t
#define bustype_BDK_BGXX_SPU_DBG_CONTROL(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPU_DBG_CONTROL(a) "BGXX_SPU_DBG_CONTROL"
#define device_bar_BDK_BGXX_SPU_DBG_CONTROL(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPU_DBG_CONTROL(a) (a)
#define arguments_BDK_BGXX_SPU_DBG_CONTROL(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_spu_mem_int
*
* BGX SPU Memory Interrupt Registers
*/
union bdk_bgxx_spu_mem_int
{
uint64_t u;
struct bdk_bgxx_spu_mem_int_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_8_63 : 56;
uint64_t rx_buf_sbe : 4; /**< [ 7: 4](R/W1C/H) SPU receive buffer single-bit error for lanes 3-0. One bit per physical SerDes lane. Each
bit is set when the associated receive buffer lane FIFO detects a single-bit ECC error. */
uint64_t rx_buf_dbe : 4; /**< [ 3: 0](R/W1C/H) SPU receive buffer double-bit error for lanes 3-0. One bit per physical SerDes lane. Each
bit is set when the associated receive buffer lane FIFO detects a double-bit ECC error. */
#else /* Word 0 - Little Endian */
uint64_t rx_buf_dbe : 4; /**< [ 3: 0](R/W1C/H) SPU receive buffer double-bit error for lanes 3-0. One bit per physical SerDes lane. Each
bit is set when the associated receive buffer lane FIFO detects a double-bit ECC error. */
uint64_t rx_buf_sbe : 4; /**< [ 7: 4](R/W1C/H) SPU receive buffer single-bit error for lanes 3-0. One bit per physical SerDes lane. Each
bit is set when the associated receive buffer lane FIFO detects a single-bit ECC error. */
uint64_t reserved_8_63 : 56;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spu_mem_int_s cn; */
};
typedef union bdk_bgxx_spu_mem_int bdk_bgxx_spu_mem_int_t;
static inline uint64_t BDK_BGXX_SPU_MEM_INT(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPU_MEM_INT(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e0010310ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e0010310ll + 0x1000000ll * ((a) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && (a<=1))
return 0x87e0e0010310ll + 0x1000000ll * ((a) & 0x1);
__bdk_csr_fatal("BGXX_SPU_MEM_INT", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_SPU_MEM_INT(a) bdk_bgxx_spu_mem_int_t
#define bustype_BDK_BGXX_SPU_MEM_INT(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPU_MEM_INT(a) "BGXX_SPU_MEM_INT"
#define device_bar_BDK_BGXX_SPU_MEM_INT(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPU_MEM_INT(a) (a)
#define arguments_BDK_BGXX_SPU_MEM_INT(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_spu_mem_int_ena_w1c
*
* BGX SPU Memory Interrupt Enable Clear Registers
* This register clears interrupt enable bits.
*/
union bdk_bgxx_spu_mem_int_ena_w1c
{
uint64_t u;
struct bdk_bgxx_spu_mem_int_ena_w1c_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_8_63 : 56;
uint64_t rx_buf_sbe : 4; /**< [ 7: 4](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU_MEM_INT[RX_BUF_SBE]. */
uint64_t rx_buf_dbe : 4; /**< [ 3: 0](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU_MEM_INT[RX_BUF_DBE]. */
#else /* Word 0 - Little Endian */
uint64_t rx_buf_dbe : 4; /**< [ 3: 0](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU_MEM_INT[RX_BUF_DBE]. */
uint64_t rx_buf_sbe : 4; /**< [ 7: 4](R/W1C/H) Reads or clears enable for BGX(0..1)_SPU_MEM_INT[RX_BUF_SBE]. */
uint64_t reserved_8_63 : 56;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spu_mem_int_ena_w1c_s cn81xx; */
/* struct bdk_bgxx_spu_mem_int_ena_w1c_s cn88xx; */
struct bdk_bgxx_spu_mem_int_ena_w1c_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_8_63 : 56;
uint64_t rx_buf_sbe : 4; /**< [ 7: 4](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU_MEM_INT[RX_BUF_SBE]. */
uint64_t rx_buf_dbe : 4; /**< [ 3: 0](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU_MEM_INT[RX_BUF_DBE]. */
#else /* Word 0 - Little Endian */
uint64_t rx_buf_dbe : 4; /**< [ 3: 0](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU_MEM_INT[RX_BUF_DBE]. */
uint64_t rx_buf_sbe : 4; /**< [ 7: 4](R/W1C/H) Reads or clears enable for BGX(0..3)_SPU_MEM_INT[RX_BUF_SBE]. */
uint64_t reserved_8_63 : 56;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_spu_mem_int_ena_w1c bdk_bgxx_spu_mem_int_ena_w1c_t;
static inline uint64_t BDK_BGXX_SPU_MEM_INT_ENA_W1C(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPU_MEM_INT_ENA_W1C(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e0010320ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e0010320ll + 0x1000000ll * ((a) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && (a<=1))
return 0x87e0e0010320ll + 0x1000000ll * ((a) & 0x1);
__bdk_csr_fatal("BGXX_SPU_MEM_INT_ENA_W1C", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_SPU_MEM_INT_ENA_W1C(a) bdk_bgxx_spu_mem_int_ena_w1c_t
#define bustype_BDK_BGXX_SPU_MEM_INT_ENA_W1C(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPU_MEM_INT_ENA_W1C(a) "BGXX_SPU_MEM_INT_ENA_W1C"
#define device_bar_BDK_BGXX_SPU_MEM_INT_ENA_W1C(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPU_MEM_INT_ENA_W1C(a) (a)
#define arguments_BDK_BGXX_SPU_MEM_INT_ENA_W1C(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_spu_mem_int_ena_w1s
*
* BGX SPU Memory Interrupt Enable Set Registers
* This register sets interrupt enable bits.
*/
union bdk_bgxx_spu_mem_int_ena_w1s
{
uint64_t u;
struct bdk_bgxx_spu_mem_int_ena_w1s_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_8_63 : 56;
uint64_t rx_buf_sbe : 4; /**< [ 7: 4](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU_MEM_INT[RX_BUF_SBE]. */
uint64_t rx_buf_dbe : 4; /**< [ 3: 0](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU_MEM_INT[RX_BUF_DBE]. */
#else /* Word 0 - Little Endian */
uint64_t rx_buf_dbe : 4; /**< [ 3: 0](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU_MEM_INT[RX_BUF_DBE]. */
uint64_t rx_buf_sbe : 4; /**< [ 7: 4](R/W1S/H) Reads or sets enable for BGX(0..1)_SPU_MEM_INT[RX_BUF_SBE]. */
uint64_t reserved_8_63 : 56;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spu_mem_int_ena_w1s_s cn81xx; */
/* struct bdk_bgxx_spu_mem_int_ena_w1s_s cn88xx; */
struct bdk_bgxx_spu_mem_int_ena_w1s_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_8_63 : 56;
uint64_t rx_buf_sbe : 4; /**< [ 7: 4](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU_MEM_INT[RX_BUF_SBE]. */
uint64_t rx_buf_dbe : 4; /**< [ 3: 0](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU_MEM_INT[RX_BUF_DBE]. */
#else /* Word 0 - Little Endian */
uint64_t rx_buf_dbe : 4; /**< [ 3: 0](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU_MEM_INT[RX_BUF_DBE]. */
uint64_t rx_buf_sbe : 4; /**< [ 7: 4](R/W1S/H) Reads or sets enable for BGX(0..3)_SPU_MEM_INT[RX_BUF_SBE]. */
uint64_t reserved_8_63 : 56;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_spu_mem_int_ena_w1s bdk_bgxx_spu_mem_int_ena_w1s_t;
static inline uint64_t BDK_BGXX_SPU_MEM_INT_ENA_W1S(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPU_MEM_INT_ENA_W1S(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e0010328ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e0010328ll + 0x1000000ll * ((a) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && (a<=1))
return 0x87e0e0010328ll + 0x1000000ll * ((a) & 0x1);
__bdk_csr_fatal("BGXX_SPU_MEM_INT_ENA_W1S", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_SPU_MEM_INT_ENA_W1S(a) bdk_bgxx_spu_mem_int_ena_w1s_t
#define bustype_BDK_BGXX_SPU_MEM_INT_ENA_W1S(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPU_MEM_INT_ENA_W1S(a) "BGXX_SPU_MEM_INT_ENA_W1S"
#define device_bar_BDK_BGXX_SPU_MEM_INT_ENA_W1S(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPU_MEM_INT_ENA_W1S(a) (a)
#define arguments_BDK_BGXX_SPU_MEM_INT_ENA_W1S(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_spu_mem_int_w1s
*
* BGX SPU Memory Interrupt Set Registers
* This register sets interrupt bits.
*/
union bdk_bgxx_spu_mem_int_w1s
{
uint64_t u;
struct bdk_bgxx_spu_mem_int_w1s_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_8_63 : 56;
uint64_t rx_buf_sbe : 4; /**< [ 7: 4](R/W1S/H) Reads or sets BGX(0..1)_SPU_MEM_INT[RX_BUF_SBE]. */
uint64_t rx_buf_dbe : 4; /**< [ 3: 0](R/W1S/H) Reads or sets BGX(0..1)_SPU_MEM_INT[RX_BUF_DBE]. */
#else /* Word 0 - Little Endian */
uint64_t rx_buf_dbe : 4; /**< [ 3: 0](R/W1S/H) Reads or sets BGX(0..1)_SPU_MEM_INT[RX_BUF_DBE]. */
uint64_t rx_buf_sbe : 4; /**< [ 7: 4](R/W1S/H) Reads or sets BGX(0..1)_SPU_MEM_INT[RX_BUF_SBE]. */
uint64_t reserved_8_63 : 56;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spu_mem_int_w1s_s cn81xx; */
/* struct bdk_bgxx_spu_mem_int_w1s_s cn88xx; */
struct bdk_bgxx_spu_mem_int_w1s_cn83xx
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_8_63 : 56;
uint64_t rx_buf_sbe : 4; /**< [ 7: 4](R/W1S/H) Reads or sets BGX(0..3)_SPU_MEM_INT[RX_BUF_SBE]. */
uint64_t rx_buf_dbe : 4; /**< [ 3: 0](R/W1S/H) Reads or sets BGX(0..3)_SPU_MEM_INT[RX_BUF_DBE]. */
#else /* Word 0 - Little Endian */
uint64_t rx_buf_dbe : 4; /**< [ 3: 0](R/W1S/H) Reads or sets BGX(0..3)_SPU_MEM_INT[RX_BUF_DBE]. */
uint64_t rx_buf_sbe : 4; /**< [ 7: 4](R/W1S/H) Reads or sets BGX(0..3)_SPU_MEM_INT[RX_BUF_SBE]. */
uint64_t reserved_8_63 : 56;
#endif /* Word 0 - End */
} cn83xx;
};
typedef union bdk_bgxx_spu_mem_int_w1s bdk_bgxx_spu_mem_int_w1s_t;
static inline uint64_t BDK_BGXX_SPU_MEM_INT_W1S(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPU_MEM_INT_W1S(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e0010318ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e0010318ll + 0x1000000ll * ((a) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && (a<=1))
return 0x87e0e0010318ll + 0x1000000ll * ((a) & 0x1);
__bdk_csr_fatal("BGXX_SPU_MEM_INT_W1S", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_SPU_MEM_INT_W1S(a) bdk_bgxx_spu_mem_int_w1s_t
#define bustype_BDK_BGXX_SPU_MEM_INT_W1S(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPU_MEM_INT_W1S(a) "BGXX_SPU_MEM_INT_W1S"
#define device_bar_BDK_BGXX_SPU_MEM_INT_W1S(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPU_MEM_INT_W1S(a) (a)
#define arguments_BDK_BGXX_SPU_MEM_INT_W1S(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_spu_mem_status
*
* BGX SPU Memory Status Registers
* This register provides memory ECC status from the SPU receive buffer lane FIFOs.
*/
union bdk_bgxx_spu_mem_status
{
uint64_t u;
struct bdk_bgxx_spu_mem_status_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_32_63 : 32;
uint64_t rx_buf_ecc_synd : 32; /**< [ 31: 0](RO/H) SPU receive buffer ECC syndromes for lanes 3-0. 8-bit syndrome sub-field per SerDes lane.
Each
8-bit sub-field contains the syndrome of the latest single-bit or double-bit ECC error
detected by the associated receive buffer lane FIFO, i.e. it is loaded when the
corresponding
BGX()_SPU_MEM_INT[RX_BUF_SBE] or BGX()_SPU_MEM_INT[RX_BUF_DBE] bit is set. */
#else /* Word 0 - Little Endian */
uint64_t rx_buf_ecc_synd : 32; /**< [ 31: 0](RO/H) SPU receive buffer ECC syndromes for lanes 3-0. 8-bit syndrome sub-field per SerDes lane.
Each
8-bit sub-field contains the syndrome of the latest single-bit or double-bit ECC error
detected by the associated receive buffer lane FIFO, i.e. it is loaded when the
corresponding
BGX()_SPU_MEM_INT[RX_BUF_SBE] or BGX()_SPU_MEM_INT[RX_BUF_DBE] bit is set. */
uint64_t reserved_32_63 : 32;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spu_mem_status_s cn; */
};
typedef union bdk_bgxx_spu_mem_status bdk_bgxx_spu_mem_status_t;
static inline uint64_t BDK_BGXX_SPU_MEM_STATUS(unsigned long a) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPU_MEM_STATUS(unsigned long a)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && (a<=1))
return 0x87e0e0010308ll + 0x1000000ll * ((a) & 0x1);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && (a<=3))
return 0x87e0e0010308ll + 0x1000000ll * ((a) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && (a<=1))
return 0x87e0e0010308ll + 0x1000000ll * ((a) & 0x1);
__bdk_csr_fatal("BGXX_SPU_MEM_STATUS", 1, a, 0, 0, 0);
}
#define typedef_BDK_BGXX_SPU_MEM_STATUS(a) bdk_bgxx_spu_mem_status_t
#define bustype_BDK_BGXX_SPU_MEM_STATUS(a) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPU_MEM_STATUS(a) "BGXX_SPU_MEM_STATUS"
#define device_bar_BDK_BGXX_SPU_MEM_STATUS(a) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPU_MEM_STATUS(a) (a)
#define arguments_BDK_BGXX_SPU_MEM_STATUS(a) (a),-1,-1,-1
/**
* Register (RSL) bgx#_spu_sds#_skew_status
*
* BGX SPU SerDes Lane Skew Status Registers
* This register provides SerDes lane skew status. One register per physical SerDes lane.
*/
union bdk_bgxx_spu_sdsx_skew_status
{
uint64_t u;
struct bdk_bgxx_spu_sdsx_skew_status_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_32_63 : 32;
uint64_t skew_status : 32; /**< [ 31: 0](RO/H) Format defined by BGX_SPU_SDS_SKEW_STATUS_S. */
#else /* Word 0 - Little Endian */
uint64_t skew_status : 32; /**< [ 31: 0](RO/H) Format defined by BGX_SPU_SDS_SKEW_STATUS_S. */
uint64_t reserved_32_63 : 32;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spu_sdsx_skew_status_s cn; */
};
typedef union bdk_bgxx_spu_sdsx_skew_status bdk_bgxx_spu_sdsx_skew_status_t;
static inline uint64_t BDK_BGXX_SPU_SDSX_SKEW_STATUS(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPU_SDSX_SKEW_STATUS(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010340ll + 0x1000000ll * ((a) & 0x1) + 8ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0010340ll + 0x1000000ll * ((a) & 0x3) + 8ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010340ll + 0x1000000ll * ((a) & 0x1) + 8ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPU_SDSX_SKEW_STATUS", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPU_SDSX_SKEW_STATUS(a,b) bdk_bgxx_spu_sdsx_skew_status_t
#define bustype_BDK_BGXX_SPU_SDSX_SKEW_STATUS(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPU_SDSX_SKEW_STATUS(a,b) "BGXX_SPU_SDSX_SKEW_STATUS"
#define device_bar_BDK_BGXX_SPU_SDSX_SKEW_STATUS(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPU_SDSX_SKEW_STATUS(a,b) (a)
#define arguments_BDK_BGXX_SPU_SDSX_SKEW_STATUS(a,b) (a),(b),-1,-1
/**
* Register (RSL) bgx#_spu_sds#_states
*
* BGX SPU SerDes States Registers
* This register provides SerDes lane states. One register per physical SerDes lane.
*/
union bdk_bgxx_spu_sdsx_states
{
uint64_t u;
struct bdk_bgxx_spu_sdsx_states_s
{
#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
uint64_t reserved_52_63 : 12;
uint64_t am_lock_invld_cnt : 2; /**< [ 51: 50](RO/H) 40GBASE-R alignment marker lock state machine invalid AM counter. */
uint64_t am_lock_sm : 2; /**< [ 49: 48](RO/H) 40GBASE-R alignment marker lock state machine state. */
uint64_t reserved_45_47 : 3;
uint64_t train_sm : 3; /**< [ 44: 42](RO/H) Link training state machine state. */
uint64_t train_code_viol : 1; /**< [ 41: 41](RO/H) Link training code violation in received control channel. */
uint64_t train_frame_lock : 1; /**< [ 40: 40](RO/H) Link training frame lock status. */
uint64_t train_lock_found_1st_marker : 1;/**< [ 39: 39](RO/H) Link training lock state machine found first marker flag. */
uint64_t train_lock_bad_markers : 3; /**< [ 38: 36](RO/H) Link training lock state machine bad markers counter. */
uint64_t reserved_35 : 1;
uint64_t an_arb_sm : 3; /**< [ 34: 32](RO/H) Autonegotiation arbitration state machine state. */
uint64_t an_rx_sm : 2; /**< [ 31: 30](RO/H) Autonegotiation receive state machine state. */
uint64_t reserved_29 : 1;
uint64_t fec_block_sync : 1; /**< [ 28: 28](RO/H) FEC block sync status. */
uint64_t fec_sync_cnt : 4; /**< [ 27: 24](RO/H) FEC block sync state machine good/bad parity block counter. */
uint64_t reserved_23 : 1;
uint64_t br_sh_invld_cnt : 7; /**< [ 22: 16](RO/H) BASE-R lock state machine invalid sync header counter. */
uint64_t br_block_lock : 1; /**< [ 15: 15](RO/H) BASE-R block lock status. */
uint64_t br_sh_cnt : 11; /**< [ 14: 4](RO/H) BASE-R lock state machine sync header counter */
uint64_t bx_sync_sm : 4; /**< [ 3: 0](RO/H) BASE-X PCS synchronization state machine state */
#else /* Word 0 - Little Endian */
uint64_t bx_sync_sm : 4; /**< [ 3: 0](RO/H) BASE-X PCS synchronization state machine state */
uint64_t br_sh_cnt : 11; /**< [ 14: 4](RO/H) BASE-R lock state machine sync header counter */
uint64_t br_block_lock : 1; /**< [ 15: 15](RO/H) BASE-R block lock status. */
uint64_t br_sh_invld_cnt : 7; /**< [ 22: 16](RO/H) BASE-R lock state machine invalid sync header counter. */
uint64_t reserved_23 : 1;
uint64_t fec_sync_cnt : 4; /**< [ 27: 24](RO/H) FEC block sync state machine good/bad parity block counter. */
uint64_t fec_block_sync : 1; /**< [ 28: 28](RO/H) FEC block sync status. */
uint64_t reserved_29 : 1;
uint64_t an_rx_sm : 2; /**< [ 31: 30](RO/H) Autonegotiation receive state machine state. */
uint64_t an_arb_sm : 3; /**< [ 34: 32](RO/H) Autonegotiation arbitration state machine state. */
uint64_t reserved_35 : 1;
uint64_t train_lock_bad_markers : 3; /**< [ 38: 36](RO/H) Link training lock state machine bad markers counter. */
uint64_t train_lock_found_1st_marker : 1;/**< [ 39: 39](RO/H) Link training lock state machine found first marker flag. */
uint64_t train_frame_lock : 1; /**< [ 40: 40](RO/H) Link training frame lock status. */
uint64_t train_code_viol : 1; /**< [ 41: 41](RO/H) Link training code violation in received control channel. */
uint64_t train_sm : 3; /**< [ 44: 42](RO/H) Link training state machine state. */
uint64_t reserved_45_47 : 3;
uint64_t am_lock_sm : 2; /**< [ 49: 48](RO/H) 40GBASE-R alignment marker lock state machine state. */
uint64_t am_lock_invld_cnt : 2; /**< [ 51: 50](RO/H) 40GBASE-R alignment marker lock state machine invalid AM counter. */
uint64_t reserved_52_63 : 12;
#endif /* Word 0 - End */
} s;
/* struct bdk_bgxx_spu_sdsx_states_s cn; */
};
typedef union bdk_bgxx_spu_sdsx_states bdk_bgxx_spu_sdsx_states_t;
static inline uint64_t BDK_BGXX_SPU_SDSX_STATES(unsigned long a, unsigned long b) __attribute__ ((pure, always_inline));
static inline uint64_t BDK_BGXX_SPU_SDSX_STATES(unsigned long a, unsigned long b)
{
if (CAVIUM_IS_MODEL(CAVIUM_CN81XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010360ll + 0x1000000ll * ((a) & 0x1) + 8ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN83XX) && ((a<=3) && (b<=3)))
return 0x87e0e0010360ll + 0x1000000ll * ((a) & 0x3) + 8ll * ((b) & 0x3);
if (CAVIUM_IS_MODEL(CAVIUM_CN88XX) && ((a<=1) && (b<=3)))
return 0x87e0e0010360ll + 0x1000000ll * ((a) & 0x1) + 8ll * ((b) & 0x3);
__bdk_csr_fatal("BGXX_SPU_SDSX_STATES", 2, a, b, 0, 0);
}
#define typedef_BDK_BGXX_SPU_SDSX_STATES(a,b) bdk_bgxx_spu_sdsx_states_t
#define bustype_BDK_BGXX_SPU_SDSX_STATES(a,b) BDK_CSR_TYPE_RSL
#define basename_BDK_BGXX_SPU_SDSX_STATES(a,b) "BGXX_SPU_SDSX_STATES"
#define device_bar_BDK_BGXX_SPU_SDSX_STATES(a,b) 0x0 /* PF_BAR0 */
#define busnum_BDK_BGXX_SPU_SDSX_STATES(a,b) (a)
#define arguments_BDK_BGXX_SPU_SDSX_STATES(a,b) (a),(b),-1,-1
#endif /* __BDK_CSRS_BGX_H__ */
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