diff options
Diffstat (limited to 'src/vendorcode/cavium/bdk/libdram/dram-init-ddr3.c')
-rw-r--r-- | src/vendorcode/cavium/bdk/libdram/dram-init-ddr3.c | 8535 |
1 files changed, 8535 insertions, 0 deletions
diff --git a/src/vendorcode/cavium/bdk/libdram/dram-init-ddr3.c b/src/vendorcode/cavium/bdk/libdram/dram-init-ddr3.c new file mode 100644 index 0000000000..edb42312f1 --- /dev/null +++ b/src/vendorcode/cavium/bdk/libdram/dram-init-ddr3.c @@ -0,0 +1,8535 @@ +/***********************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 INC. 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**************************************/ +#include <bdk.h> +#include "libbdk-arch/bdk-csrs-l2c_tad.h" +#include "libbdk-arch/bdk-csrs-mio_fus.h" +#include "dram-internal.h" + +#define WODT_MASK_2R_1S 1 // FIXME: did not seem to make much difference with #152 1-slot? + +#define DESKEW_RODT_CTL 1 + +// Set to 1 to use the feature whenever possible automatically. +// When 0, however, the feature is still available, and it can +// be enabled via envvar override "ddr_enable_write_deskew=1". +#define ENABLE_WRITE_DESKEW_DEFAULT 0 + +#define ENABLE_COMPUTED_VREF_ADJUSTMENT 1 + +#define RLEXTRAS_PATCH 1 // write to unused RL rank entries +#define WLEXTRAS_PATCH 1 // write to unused WL rank entries +#define ADD_48_OHM_SKIP 1 +#define NOSKIP_40_48_OHM 1 +#define NOSKIP_48_STACKED 1 +#define NOSKIP_FOR_MINI 1 +#define NOSKIP_FOR_2S_1R 1 +#define MAJORITY_OVER_AVG 1 +#define RANK_MAJORITY MAJORITY_OVER_AVG && 1 +#define SW_WL_CHECK_PATCH 1 // check validity after SW adjust +#define HW_WL_MAJORITY 1 +#define SWL_TRY_HWL_ALT HW_WL_MAJORITY && 1 // try HW WL base alternate if available when SW WL fails +#define DISABLE_SW_WL_PASS_2 1 + +#define HWL_BY_BYTE 0 // FIXME? set to 1 to do HWL a byte at a time (seemed to work better earlier?) + +#define USE_ORIG_TEST_DRAM_BYTE 1 + +// collect and print LMC utilization using SWL software algorithm +#define ENABLE_SW_WLEVEL_UTILIZATION 0 + +#define COUNT_RL_CANDIDATES 1 + +#define LOOK_FOR_STUCK_BYTE 0 +#define ENABLE_STUCK_BYTE_RESET 0 + +#define FAILSAFE_CHECK 1 + +#define PERFECT_BITMASK_COUNTING 1 + +#define DAC_OVERRIDE_EARLY 1 + +#define SWL_WITH_HW_ALTS_CHOOSE_SW 0 // FIXME: allow override? + +#define DEBUG_VALIDATE_BITMASK 0 +#if DEBUG_VALIDATE_BITMASK +#define debug_bitmask_print ddr_print +#else +#define debug_bitmask_print(...) +#endif + +#define ENABLE_SLOT_CTL_ACCESS 0 +#undef ENABLE_CUSTOM_RLEVEL_TABLE + +#define ENABLE_DISPLAY_MPR_PAGE 0 +#if ENABLE_DISPLAY_MPR_PAGE +static void Display_MPR_Page_Location(bdk_node_t node, int rank, + int ddr_interface_num, int dimm_count, + int page, int location, uint64_t *mpr_data); +#endif + +#define USE_L2_WAYS_LIMIT 1 + +/* Read out Deskew Settings for DDR */ + +typedef struct { + uint16_t bits[8]; +} deskew_bytes_t; +typedef struct { + deskew_bytes_t bytes[9]; +} deskew_data_t; + +static void +Get_Deskew_Settings(bdk_node_t node, int ddr_interface_num, deskew_data_t *dskdat) +{ + bdk_lmcx_phy_ctl_t phy_ctl; + bdk_lmcx_config_t lmc_config; + int bit_num, bit_index; + int byte_lane, byte_limit; + // NOTE: these are for pass 2.x + int is_t88p2 = !CAVIUM_IS_MODEL(CAVIUM_CN88XX_PASS1_X); // added 81xx and 83xx + int bit_end = (is_t88p2) ? 9 : 8; + + lmc_config.u = BDK_CSR_READ(node, BDK_LMCX_CONFIG(ddr_interface_num)); + byte_limit = ((lmc_config.s.mode32b) ? 4 : 8) + lmc_config.s.ecc_ena; + + memset(dskdat, 0, sizeof(*dskdat)); + + BDK_CSR_MODIFY(phy_ctl, node, BDK_LMCX_PHY_CTL(ddr_interface_num), + phy_ctl.s.dsk_dbg_clk_scaler = 3); + + for (byte_lane = 0; byte_lane < byte_limit; byte_lane++) { + bit_index = 0; + for (bit_num = 0; bit_num <= bit_end; ++bit_num) { // NOTE: this is for pass 2.x + + if (bit_num == 4) continue; + if ((bit_num == 5) && is_t88p2) continue; // NOTE: this is for pass 2.x + + // set byte lane and bit to read + BDK_CSR_MODIFY(phy_ctl, node, BDK_LMCX_PHY_CTL(ddr_interface_num), + (phy_ctl.s.dsk_dbg_bit_sel = bit_num, + phy_ctl.s.dsk_dbg_byte_sel = byte_lane)); + + // start read sequence + BDK_CSR_MODIFY(phy_ctl, node, BDK_LMCX_PHY_CTL(ddr_interface_num), + phy_ctl.s.dsk_dbg_rd_start = 1); + + // poll for read sequence to complete + do { + phy_ctl.u = BDK_CSR_READ(node, BDK_LMCX_PHY_CTL(ddr_interface_num)); + } while (phy_ctl.s.dsk_dbg_rd_complete != 1); + + // record the data + dskdat->bytes[byte_lane].bits[bit_index] = phy_ctl.s.dsk_dbg_rd_data & 0x3ff; + bit_index++; + + } /* for (bit_num = 0; bit_num <= bit_end; ++bit_num) */ + } /* for (byte_lane = 0; byte_lane < byte_limit; byte_lane++) */ + + return; +} + +static void +Display_Deskew_Data(bdk_node_t node, int ddr_interface_num, + deskew_data_t *dskdat, int print_enable) +{ + int byte_lane; + int bit_num; + uint16_t flags, deskew; + bdk_lmcx_config_t lmc_config; + int byte_limit; + const char *fc = " ?-=+*#&"; + + lmc_config.u = BDK_CSR_READ(node, BDK_LMCX_CONFIG(ddr_interface_num)); + byte_limit = ((lmc_config.s.mode32b) ? 4 : 8) + lmc_config.s.ecc_ena; + + if (print_enable) { + VB_PRT(print_enable, "N%d.LMC%d: Deskew Data: Bit => :", + node, ddr_interface_num); + for (bit_num = 7; bit_num >= 0; --bit_num) + VB_PRT(print_enable, " %3d ", bit_num); + VB_PRT(print_enable, "\n"); + } + + for (byte_lane = 0; byte_lane < byte_limit; byte_lane++) { + if (print_enable) + VB_PRT(print_enable, "N%d.LMC%d: Bit Deskew Byte %d %s :", + node, ddr_interface_num, byte_lane, + (print_enable >= VBL_TME) ? "FINAL" : " "); + + for (bit_num = 7; bit_num >= 0; --bit_num) { + + flags = dskdat->bytes[byte_lane].bits[bit_num] & 7; + deskew = dskdat->bytes[byte_lane].bits[bit_num] >> 3; + + if (print_enable) + VB_PRT(print_enable, " %3d %c", deskew, fc[flags^1]); + + } /* for (bit_num = 7; bit_num >= 0; --bit_num) */ + + if (print_enable) + VB_PRT(print_enable, "\n"); + + } /* for (byte_lane = 0; byte_lane < byte_limit; byte_lane++) */ + + return; +} + +static int +change_wr_deskew_ena(bdk_node_t node, int ddr_interface_num, int new_state) +{ + bdk_lmcx_dll_ctl3_t ddr_dll_ctl3; + int saved_wr_deskew_ena; + + // return original WR_DESKEW_ENA setting + ddr_dll_ctl3.u = BDK_CSR_READ(node, BDK_LMCX_DLL_CTL3(ddr_interface_num)); + saved_wr_deskew_ena = !!GET_DDR_DLL_CTL3(wr_deskew_ena); + if (saved_wr_deskew_ena != !!new_state) { // write it only when changing it + SET_DDR_DLL_CTL3(wr_deskew_ena, !!new_state); + DRAM_CSR_WRITE(node, BDK_LMCX_DLL_CTL3(ddr_interface_num), ddr_dll_ctl3.u); + } + return saved_wr_deskew_ena; +} + +typedef struct { + int saturated; // number saturated + int unlocked; // number unlocked + int nibrng_errs; // nibble range errors + int nibunl_errs; // nibble unlocked errors + //int nibsat_errs; // nibble saturation errors + int bitval_errs; // bit value errors +#if LOOK_FOR_STUCK_BYTE + int bytes_stuck; // byte(s) stuck +#endif +} deskew_counts_t; + +#define MIN_BITVAL 17 +#define MAX_BITVAL 110 + +static deskew_counts_t deskew_training_results; +static int deskew_validation_delay = 10000; // FIXME: make this a var for overriding + +static void +Validate_Read_Deskew_Training(bdk_node_t node, int rank_mask, int ddr_interface_num, + deskew_counts_t *counts, int print_enable) +{ + int byte_lane, bit_num, nib_num; + int nibrng_errs, nibunl_errs, bitval_errs; + //int nibsat_errs; + bdk_lmcx_config_t lmc_config; + int16_t nib_min[2], nib_max[2], nib_unl[2]/*, nib_sat[2]*/; + // NOTE: these are for pass 2.x + int is_t88p2 = !CAVIUM_IS_MODEL(CAVIUM_CN88XX_PASS1_X); // added 81xx and 83xx + int bit_start = (is_t88p2) ? 9 : 8; + int byte_limit; +#if LOOK_FOR_STUCK_BYTE + uint64_t bl_mask[2]; // enough for 128 values + int bit_values; +#endif + deskew_data_t dskdat; + int bit_index; + int16_t flags, deskew; + const char *fc = " ?-=+*#&"; + int saved_wr_deskew_ena; + int bit_last; + + // save original WR_DESKEW_ENA setting, and disable it for read deskew + saved_wr_deskew_ena = change_wr_deskew_ena(node, ddr_interface_num, 0); + + lmc_config.u = BDK_CSR_READ(node, BDK_LMCX_CONFIG(ddr_interface_num)); + byte_limit = ((!lmc_config.s.mode32b) ? 8 : 4) + lmc_config.s.ecc_ena; + + memset(counts, 0, sizeof(deskew_counts_t)); + + Get_Deskew_Settings(node, ddr_interface_num, &dskdat); + + if (print_enable) { + VB_PRT(print_enable, "N%d.LMC%d: Deskew Settings: Bit => :", + node, ddr_interface_num); + for (bit_num = 7; bit_num >= 0; --bit_num) + VB_PRT(print_enable, " %3d ", bit_num); + VB_PRT(print_enable, "\n"); + } + + for (byte_lane = 0; byte_lane < byte_limit; byte_lane++) { + if (print_enable) + VB_PRT(print_enable, "N%d.LMC%d: Bit Deskew Byte %d %s :", + node, ddr_interface_num, byte_lane, + (print_enable >= VBL_TME) ? "FINAL" : " "); + + nib_min[0] = 127; nib_min[1] = 127; + nib_max[0] = 0; nib_max[1] = 0; + nib_unl[0] = 0; nib_unl[1] = 0; + //nib_sat[0] = 0; nib_sat[1] = 0; + +#if LOOK_FOR_STUCK_BYTE + bl_mask[0] = bl_mask[1] = 0; +#endif + + if ((lmc_config.s.mode32b == 1) && (byte_lane == 4)) { + bit_index = 3; + bit_last = 3; + if (print_enable) + VB_PRT(print_enable, " "); + } else { + bit_index = 7; + bit_last = bit_start; + } + + for (bit_num = bit_last; bit_num >= 0; --bit_num) { // NOTE: this is for pass 2.x + if (bit_num == 4) continue; + if ((bit_num == 5) && is_t88p2) continue; // NOTE: this is for pass 2.x + + nib_num = (bit_num > 4) ? 1 : 0; + + flags = dskdat.bytes[byte_lane].bits[bit_index] & 7; + deskew = dskdat.bytes[byte_lane].bits[bit_index] >> 3; + bit_index--; + + counts->saturated += !!(flags & 6); + counts->unlocked += !(flags & 1); + + nib_unl[nib_num] += !(flags & 1); + //nib_sat[nib_num] += !!(flags & 6); + + if (flags & 1) { // FIXME? only do range when locked + nib_min[nib_num] = min(nib_min[nib_num], deskew); + nib_max[nib_num] = max(nib_max[nib_num], deskew); + } + +#if LOOK_FOR_STUCK_BYTE + bl_mask[(deskew >> 6) & 1] |= 1UL << (deskew & 0x3f); +#endif + + if (print_enable) + VB_PRT(print_enable, " %3d %c", deskew, fc[flags^1]); + + } /* for (bit_num = bit_last; bit_num >= 0; --bit_num) */ + + /* + Now look for nibble errors: + + For bit 55, it looks like a bit deskew problem. When the upper nibble of byte 6 + needs to go to saturation, bit 7 of byte 6 locks prematurely at 64. + For DIMMs with raw card A and B, can we reset the deskew training when we encounter this case? + The reset criteria should be looking at one nibble at a time for raw card A and B; + if the bit-deskew setting within a nibble is different by > 33, we'll issue a reset + to the bit deskew training. + + LMC0 Bit Deskew Byte(6): 64 0 - 0 - 0 - 26 61 35 64 + */ + // upper nibble range, then lower nibble range + nibrng_errs = ((nib_max[1] - nib_min[1]) > 33) ? 1 : 0; + nibrng_errs |= ((nib_max[0] - nib_min[0]) > 33) ? 1 : 0; + + // check for nibble all unlocked + nibunl_errs = ((nib_unl[0] == 4) || (nib_unl[1] == 4)) ? 1 : 0; + + // check for nibble all saturated + //nibsat_errs = ((nib_sat[0] == 4) || (nib_sat[1] == 4)) ? 1 : 0; + + // check for bit value errors, ie < 17 or > 110 + // FIXME? assume max always > MIN_BITVAL and min < MAX_BITVAL + bitval_errs = ((nib_max[1] > MAX_BITVAL) || (nib_max[0] > MAX_BITVAL)) ? 1 : 0; + bitval_errs |= ((nib_min[1] < MIN_BITVAL) || (nib_min[0] < MIN_BITVAL)) ? 1 : 0; + + if (((nibrng_errs != 0) || (nibunl_errs != 0) /*|| (nibsat_errs != 0)*/ || (bitval_errs != 0)) + && print_enable) + { + VB_PRT(print_enable, " %c%c%c%c", + (nibrng_errs)?'R':' ', + (nibunl_errs)?'U':' ', + (bitval_errs)?'V':' ', + /*(nibsat_errs)?'S':*/' '); + } + +#if LOOK_FOR_STUCK_BYTE + bit_values = __builtin_popcountl(bl_mask[0]) + __builtin_popcountl(bl_mask[1]); + if (bit_values < 3) { + counts->bytes_stuck |= (1 << byte_lane); + if (print_enable) + VB_PRT(print_enable, "X"); + } +#endif + if (print_enable) + VB_PRT(print_enable, "\n"); + + counts->nibrng_errs |= (nibrng_errs << byte_lane); + counts->nibunl_errs |= (nibunl_errs << byte_lane); + //counts->nibsat_errs |= (nibsat_errs << byte_lane); + counts->bitval_errs |= (bitval_errs << byte_lane); + +#if LOOK_FOR_STUCK_BYTE + // just for completeness, allow print of the stuck values bitmask after the bytelane print + if ((bit_values < 3) && print_enable) { + VB_PRT(VBL_DEV, "N%d.LMC%d: Deskew byte %d STUCK on value 0x%016lx.%016lx\n", + node, ddr_interface_num, byte_lane, + bl_mask[1], bl_mask[0]); + } +#endif + + } /* for (byte_lane = 0; byte_lane < byte_limit; byte_lane++) */ + + // restore original WR_DESKEW_ENA setting + change_wr_deskew_ena(node, ddr_interface_num, saved_wr_deskew_ena); + + return; +} + +unsigned short load_dac_override(int node, int ddr_interface_num, + int dac_value, int byte) +{ + bdk_lmcx_dll_ctl3_t ddr_dll_ctl3; + int bytex = (byte == 0x0A) ? byte : byte + 1; // single bytelanes incr by 1; A is for ALL + + ddr_dll_ctl3.u = BDK_CSR_READ(node, BDK_LMCX_DLL_CTL3(ddr_interface_num)); + + SET_DDR_DLL_CTL3(byte_sel, bytex); + SET_DDR_DLL_CTL3(offset, dac_value >> 1); // only 7-bit field, use MS bits + + ddr_dll_ctl3.s.bit_select = 0x9; /* No-op */ + DRAM_CSR_WRITE(node, BDK_LMCX_DLL_CTL3(ddr_interface_num), ddr_dll_ctl3.u); + + ddr_dll_ctl3.s.bit_select = 0xC; /* Vref bypass setting load */ + DRAM_CSR_WRITE(node, BDK_LMCX_DLL_CTL3(ddr_interface_num), ddr_dll_ctl3.u); + + ddr_dll_ctl3.s.bit_select = 0xD; /* Vref bypass on. */ + DRAM_CSR_WRITE(node, BDK_LMCX_DLL_CTL3(ddr_interface_num), ddr_dll_ctl3.u); + + ddr_dll_ctl3.s.bit_select = 0x9; /* No-op */ + DRAM_CSR_WRITE(node, BDK_LMCX_DLL_CTL3(ddr_interface_num), ddr_dll_ctl3.u); + + return ((unsigned short) GET_DDR_DLL_CTL3(offset)); +} + +// arg dac_or_dbi is 1 for DAC, 0 for DBI +// returns 9 entries (bytelanes 0 through 8) in settings[] +// returns 0 if OK, -1 if a problem +int read_DAC_DBI_settings(int node, int ddr_interface_num, + int dac_or_dbi, int *settings) +{ + bdk_lmcx_phy_ctl_t phy_ctl; + int byte_lane, bit_num; + int deskew; + int dac_value; + int is_t88p2 = !CAVIUM_IS_MODEL(CAVIUM_CN88XX_PASS1_X); // added 81xx and 83xx + + phy_ctl.u = BDK_CSR_READ(node, BDK_LMCX_PHY_CTL(ddr_interface_num)); + phy_ctl.s.dsk_dbg_clk_scaler = 3; + DRAM_CSR_WRITE(node, BDK_LMCX_PHY_CTL(ddr_interface_num), phy_ctl.u); + + bit_num = (dac_or_dbi) ? 4 : 5; + if ((bit_num == 5) && !is_t88p2) { // NOTE: this is for pass 1.x + return -1; + } + + for (byte_lane = 8; byte_lane >= 0 ; --byte_lane) { // FIXME: always assume ECC is available + + //set byte lane and bit to read + phy_ctl.s.dsk_dbg_bit_sel = bit_num; + phy_ctl.s.dsk_dbg_byte_sel = byte_lane; + DRAM_CSR_WRITE(node, BDK_LMCX_PHY_CTL(ddr_interface_num), phy_ctl.u); + + //start read sequence + phy_ctl.u = BDK_CSR_READ(node, BDK_LMCX_PHY_CTL(ddr_interface_num)); + phy_ctl.s.dsk_dbg_rd_start = 1; + DRAM_CSR_WRITE(node, BDK_LMCX_PHY_CTL(ddr_interface_num), phy_ctl.u); + + //poll for read sequence to complete + do { + phy_ctl.u = BDK_CSR_READ(node, BDK_LMCX_PHY_CTL(ddr_interface_num)); + } while (phy_ctl.s.dsk_dbg_rd_complete != 1); + + deskew = phy_ctl.s.dsk_dbg_rd_data /*>> 3*/; // leave the flag bits for DBI + dac_value = phy_ctl.s.dsk_dbg_rd_data & 0xff; + + settings[byte_lane] = (dac_or_dbi) ? dac_value : deskew; + + } /* for (byte_lane = 8; byte_lane >= 0 ; --byte_lane) { */ + + return 0; +} + +// print out the DBI settings array +// arg dac_or_dbi is 1 for DAC, 0 for DBI +void +display_DAC_DBI_settings(int node, int lmc, int dac_or_dbi, + int ecc_ena, int *settings, char *title) +{ + int byte; + int flags; + int deskew; + const char *fc = " ?-=+*#&"; + + ddr_print("N%d.LMC%d: %s %s Deskew Settings %d:0 :", + node, lmc, title, (dac_or_dbi)?"DAC":"DBI", 7+ecc_ena); + for (byte = (7+ecc_ena); byte >= 0; --byte) { // FIXME: what about 32-bit mode? + if (dac_or_dbi) { // DAC + flags = 1; // say its locked to get blank + deskew = settings[byte] & 0xff; + } else { // DBI + flags = settings[byte] & 7; + deskew = (settings[byte] >> 3) & 0x7f; + } + ddr_print(" %3d %c", deskew, fc[flags^1]); + } + ddr_print("\n"); +} + +// Evaluate the DAC settings array +static int +evaluate_DAC_settings(int ddr_interface_64b, int ecc_ena, int *settings) +{ + int byte, dac; + int last = (ddr_interface_64b) ? 7 : 3; + + // this looks only for DAC values that are EVEN + for (byte = (last+ecc_ena); byte >= 0; --byte) { + dac = settings[byte] & 0xff; + if ((dac & 1) == 0) + return 1; + } + return 0; +} + +static void +Perform_Offset_Training(bdk_node_t node, int rank_mask, int ddr_interface_num) +{ + bdk_lmcx_phy_ctl_t lmc_phy_ctl; + uint64_t orig_phy_ctl; + const char *s; + + /* + * 6.9.8 LMC Offset Training + * + * LMC requires input-receiver offset training. + * + * 1. Write LMC(0)_PHY_CTL[DAC_ON] = 1 + */ + lmc_phy_ctl.u = BDK_CSR_READ(node, BDK_LMCX_PHY_CTL(ddr_interface_num)); + orig_phy_ctl = lmc_phy_ctl.u; + lmc_phy_ctl.s.dac_on = 1; + + // allow full CSR override + if ((s = lookup_env_parameter_ull("ddr_phy_ctl")) != NULL) { + lmc_phy_ctl.u = strtoull(s, NULL, 0); + } + + // do not print or write if CSR does not change... + if (lmc_phy_ctl.u != orig_phy_ctl) { + ddr_print("PHY_CTL : 0x%016lx\n", lmc_phy_ctl.u); + DRAM_CSR_WRITE(node, BDK_LMCX_PHY_CTL(ddr_interface_num), lmc_phy_ctl.u); + } + +#if 0 + // FIXME? do we really need to show RODT here? + bdk_lmcx_comp_ctl2_t lmc_comp_ctl2; + lmc_comp_ctl2.u = BDK_CSR_READ(node, BDK_LMCX_COMP_CTL2(ddr_interface_num)); + ddr_print("Read ODT_CTL : 0x%x (%d ohms)\n", + lmc_comp_ctl2.s.rodt_ctl, imp_values->rodt_ohms[lmc_comp_ctl2.s.rodt_ctl]); +#endif + + /* + * 2. Write LMC(0)_SEQ_CTL[SEQ_SEL] = 0x0B and + * LMC(0)_SEQ_CTL[INIT_START] = 1. + * + * 3. Wait for LMC(0)_SEQ_CTL[SEQ_COMPLETE] to be set to 1. + */ + perform_octeon3_ddr3_sequence(node, rank_mask, ddr_interface_num, 0x0B); /* Offset training sequence */ + +} + +static void +Perform_Internal_VREF_Training(bdk_node_t node, int rank_mask, int ddr_interface_num) +{ + bdk_lmcx_ext_config_t ext_config; + + /* + * 6.9.9 LMC Internal Vref Training + * + * LMC requires input-reference-voltage training. + * + * 1. Write LMC(0)_EXT_CONFIG[VREFINT_SEQ_DESKEW] = 0. + */ + ext_config.u = BDK_CSR_READ(node, BDK_LMCX_EXT_CONFIG(ddr_interface_num)); + ext_config.s.vrefint_seq_deskew = 0; + + VB_PRT(VBL_SEQ, "N%d.LMC%d: Performing LMC sequence: vrefint_seq_deskew = %d\n", + node, ddr_interface_num, ext_config.s.vrefint_seq_deskew); + + DRAM_CSR_WRITE(node, BDK_LMCX_EXT_CONFIG(ddr_interface_num), ext_config.u); + + /* + * 2. Write LMC(0)_SEQ_CTL[SEQ_SEL] = 0x0a and + * LMC(0)_SEQ_CTL[INIT_START] = 1. + * + * 3. Wait for LMC(0)_SEQ_CTL[SEQ_COMPLETE] to be set to 1. + */ + perform_octeon3_ddr3_sequence(node, rank_mask, ddr_interface_num, 0x0A); /* LMC Internal Vref Training */ +} + +#define dbg_avg(format, ...) VB_PRT(VBL_DEV, format, ##__VA_ARGS__) +static int +process_samples_average(int16_t *bytes, int num_samples, int lmc, int lane_no) +{ + int i, savg, sadj, sum = 0, rng, ret, asum, trunc; + int16_t smin = 32767, smax = -32768; + + dbg_avg("DBG_AVG%d.%d: ", lmc, lane_no); + + for (i = 0; i < num_samples; i++) { + sum += bytes[i]; + if (bytes[i] < smin) smin = bytes[i]; + if (bytes[i] > smax) smax = bytes[i]; + dbg_avg(" %3d", bytes[i]); + } + rng = smax - smin + 1; + + dbg_avg(" (%3d, %3d, %2d)", smin, smax, rng); + + asum = sum - smin - smax; + + savg = divide_nint(sum * 10, num_samples); + + sadj = divide_nint(asum * 10, (num_samples - 2)); + + trunc = asum / (num_samples - 2); + + dbg_avg(" [%3d.%d, %3d.%d, %3d]", savg/10, savg%10, sadj/10, sadj%10, trunc); + + sadj = divide_nint(sadj, 10); + if (trunc & 1) + ret = trunc; + else if (sadj & 1) + ret = sadj; + else + ret = trunc + 1; + + dbg_avg(" -> %3d\n", ret); + + return ret; +} + + +#define DEFAULT_SAT_RETRY_LIMIT 11 // 1 + 10 retries +static int default_lock_retry_limit = 20; // 20 retries // FIXME: make a var for overriding + +static int +Perform_Read_Deskew_Training(bdk_node_t node, int rank_mask, int ddr_interface_num, + int spd_rawcard_AorB, int print_flags, int ddr_interface_64b) +{ + int unsaturated, locked; + //int nibble_sat; + int sat_retries, lock_retries, lock_retries_total, lock_retries_limit; + int print_first; + int print_them_all; + deskew_counts_t dsk_counts; + uint64_t saved_wr_deskew_ena; +#if DESKEW_RODT_CTL + bdk_lmcx_comp_ctl2_t comp_ctl2; + int save_deskew_rodt_ctl = -1; +#endif + int is_t88p2 = !CAVIUM_IS_MODEL(CAVIUM_CN88XX_PASS1_X); // added 81xx and 83xx + + VB_PRT(VBL_FAE, "N%d.LMC%d: Performing Read Deskew Training.\n", node, ddr_interface_num); + + // save original WR_DESKEW_ENA setting, and disable it for read deskew + saved_wr_deskew_ena = change_wr_deskew_ena(node, ddr_interface_num, 0); + + sat_retries = 0; + lock_retries_total = 0; + unsaturated = 0; + print_first = VBL_FAE; // print the first one, FAE and above + print_them_all = dram_is_verbose(VBL_DEV4); // set to true for printing all normal deskew attempts + + int loops, normal_loops = 1; // default to 1 NORMAL deskew training op... + const char *s; + if ((s = getenv("ddr_deskew_normal_loops")) != NULL) { + normal_loops = strtoul(s, NULL, 0); + } + +#if LOOK_FOR_STUCK_BYTE + // provide override for STUCK BYTE RESETS + int do_stuck_reset = ENABLE_STUCK_BYTE_RESET; + if ((s = getenv("ddr_enable_stuck_byte_reset")) != NULL) { + do_stuck_reset = !!strtoul(s, NULL, 0); + } +#endif + +#if DESKEW_RODT_CTL + if ((s = getenv("ddr_deskew_rodt_ctl")) != NULL) { + int deskew_rodt_ctl = strtoul(s, NULL, 0); + comp_ctl2.u = BDK_CSR_READ(node, BDK_LMCX_COMP_CTL2(ddr_interface_num)); + save_deskew_rodt_ctl = comp_ctl2.s.rodt_ctl; + comp_ctl2.s.rodt_ctl = deskew_rodt_ctl; + DRAM_CSR_WRITE(node, BDK_LMCX_COMP_CTL2(ddr_interface_num), comp_ctl2.u); + } +#endif + + lock_retries_limit = default_lock_retry_limit; + if (! CAVIUM_IS_MODEL(CAVIUM_CN88XX_PASS1_X)) // added 81xx and 83xx + lock_retries_limit *= 2; // give pass 2.0 twice as many + + do { /* while (sat_retries < sat_retry_limit) */ + + /* + * 6.9.10 LMC Deskew Training + * + * LMC requires input-read-data deskew training. + * + * 1. Write LMC(0)_EXT_CONFIG[VREFINT_SEQ_DESKEW] = 1. + */ + VB_PRT(VBL_SEQ, "N%d.LMC%d: Performing LMC sequence: Set vrefint_seq_deskew = 1\n", + node, ddr_interface_num); + DRAM_CSR_MODIFY(ext_config, node, BDK_LMCX_EXT_CONFIG(ddr_interface_num), + ext_config.s.vrefint_seq_deskew = 1); /* Set Deskew sequence */ + + /* + * 2. Write LMC(0)_SEQ_CTL[SEQ_SEL] = 0x0A and + * LMC(0)_SEQ_CTL[INIT_START] = 1. + * + * 3. Wait for LMC(0)_SEQ_CTL[SEQ_COMPLETE] to be set to 1. + */ + DRAM_CSR_MODIFY(phy_ctl, node, BDK_LMCX_PHY_CTL(ddr_interface_num), + phy_ctl.s.phy_dsk_reset = 1); /* RESET Deskew sequence */ + perform_octeon3_ddr3_sequence(node, rank_mask, ddr_interface_num, 0x0A); /* LMC Deskew Training */ + + lock_retries = 0; + + perform_read_deskew_training: + // maybe perform the NORMAL deskew training sequence multiple times before looking at lock status + for (loops = 0; loops < normal_loops; loops++) { + DRAM_CSR_MODIFY(phy_ctl, node, BDK_LMCX_PHY_CTL(ddr_interface_num), + phy_ctl.s.phy_dsk_reset = 0); /* Normal Deskew sequence */ + perform_octeon3_ddr3_sequence(node, rank_mask, ddr_interface_num, 0x0A); /* LMC Deskew Training */ + } + // Moved this from Validate_Read_Deskew_Training + /* Allow deskew results to stabilize before evaluating them. */ + bdk_wait_usec(deskew_validation_delay); + + // Now go look at lock and saturation status... + Validate_Read_Deskew_Training(node, rank_mask, ddr_interface_num, &dsk_counts, print_first); + if (print_first && !print_them_all) // after printing the first and not doing them all, no more + print_first = 0; + + unsaturated = (dsk_counts.saturated == 0); + locked = (dsk_counts.unlocked == 0); + //nibble_sat = (dsk_counts.nibsat_errs != 0); + + // only do locking retries if unsaturated or rawcard A or B, otherwise full SAT retry + if (unsaturated || (spd_rawcard_AorB && !is_t88p2 /*&& !nibble_sat*/)) { + if (!locked) { // and not locked + lock_retries++; + lock_retries_total++; + if (lock_retries <= lock_retries_limit) { + goto perform_read_deskew_training; + } else { + VB_PRT(VBL_TME, "N%d.LMC%d: LOCK RETRIES failed after %d retries\n", + node, ddr_interface_num, lock_retries_limit); + } + } else { + if (lock_retries_total > 0) // only print if we did try + VB_PRT(VBL_TME, "N%d.LMC%d: LOCK RETRIES successful after %d retries\n", + node, ddr_interface_num, lock_retries); + } + } /* if (unsaturated || spd_rawcard_AorB) */ + + ++sat_retries; + +#if LOOK_FOR_STUCK_BYTE + // FIXME: this is a bit of a hack at the moment... + // We want to force a Deskew RESET hopefully to unstick the bytes values + // and then resume normal deskew training as usual. + // For now, do only if it is all locked... + if (locked && (dsk_counts.bytes_stuck != 0)) { + BDK_CSR_INIT(lmc_config, node, BDK_LMCX_CONFIG(ddr_interface_num)); + if (do_stuck_reset && lmc_config.s.mode_x4dev) { // FIXME: only when x4!! + unsaturated = 0; // to always make sure the while continues + VB_PRT(VBL_TME, "N%d.LMC%d: STUCK BYTE (0x%x), forcing deskew RESET\n", + node, ddr_interface_num, dsk_counts.bytes_stuck); + continue; // bypass the rest to get back to the RESET + } else { + VB_PRT(VBL_TME, "N%d.LMC%d: STUCK BYTE (0x%x), ignoring deskew RESET\n", + node, ddr_interface_num, dsk_counts.bytes_stuck); + } + } +#endif + /* + * At this point, check for a DDR4 RDIMM that will not benefit from SAT retries; if so, no retries + */ + if (spd_rawcard_AorB && !is_t88p2 /*&& !nibble_sat*/) { + VB_PRT(VBL_TME, "N%d.LMC%d: Read Deskew Training Loop: Exiting for RAWCARD == A or B.\n", + node, ddr_interface_num); + break; // no sat or lock retries + } + + } while (!unsaturated && (sat_retries < DEFAULT_SAT_RETRY_LIMIT)); + +#if DESKEW_RODT_CTL + if (save_deskew_rodt_ctl != -1) { + comp_ctl2.u = BDK_CSR_READ(node, BDK_LMCX_COMP_CTL2(ddr_interface_num)); + comp_ctl2.s.rodt_ctl = save_deskew_rodt_ctl; + DRAM_CSR_WRITE(node, BDK_LMCX_COMP_CTL2(ddr_interface_num), comp_ctl2.u); + } +#endif + + VB_PRT(VBL_FAE, "N%d.LMC%d: Read Deskew Training %s. %d sat-retries, %d lock-retries\n", + node, ddr_interface_num, + (sat_retries >= DEFAULT_SAT_RETRY_LIMIT) ? "Timed Out" : "Completed", + sat_retries-1, lock_retries_total); + + // restore original WR_DESKEW_ENA setting + change_wr_deskew_ena(node, ddr_interface_num, saved_wr_deskew_ena); + + if ((dsk_counts.nibrng_errs != 0) || (dsk_counts.nibunl_errs != 0)) { + debug_print("N%d.LMC%d: NIBBLE ERROR(S) found, returning FAULT\n", + node, ddr_interface_num); + return -1; // we did retry locally, they did not help + } + + // NOTE: we (currently) always print one last training validation before starting Read Leveling... + + return 0; +} + +static void +do_write_deskew_op(bdk_node_t node, int ddr_interface_num, + int bit_sel, int byte_sel, int ena) +{ + bdk_lmcx_dll_ctl3_t ddr_dll_ctl3; + + ddr_dll_ctl3.u = BDK_CSR_READ(node, BDK_LMCX_DLL_CTL3(ddr_interface_num)); + SET_DDR_DLL_CTL3(bit_select, bit_sel); + SET_DDR_DLL_CTL3(byte_sel, byte_sel); + SET_DDR_DLL_CTL3(wr_deskew_ena, ena); + DRAM_CSR_WRITE(node, BDK_LMCX_DLL_CTL3(ddr_interface_num), ddr_dll_ctl3.u); + + ddr_dll_ctl3.u = BDK_CSR_READ(node, BDK_LMCX_DLL_CTL3(ddr_interface_num)); +} + +static void +set_write_deskew_offset(bdk_node_t node, int ddr_interface_num, + int bit_sel, int byte_sel, int offset) +{ + bdk_lmcx_dll_ctl3_t ddr_dll_ctl3; + + ddr_dll_ctl3.u = BDK_CSR_READ(node, BDK_LMCX_DLL_CTL3(ddr_interface_num)); + SET_DDR_DLL_CTL3(bit_select, bit_sel); + SET_DDR_DLL_CTL3(byte_sel, byte_sel); + SET_DDR_DLL_CTL3(offset, offset); + DRAM_CSR_WRITE(node, BDK_LMCX_DLL_CTL3(ddr_interface_num), ddr_dll_ctl3.u); + + ddr_dll_ctl3.u = BDK_CSR_READ(node, BDK_LMCX_DLL_CTL3(ddr_interface_num)); + SET_DDR_DLL_CTL3(wr_deskew_ld, 1); + DRAM_CSR_WRITE(node, BDK_LMCX_DLL_CTL3(ddr_interface_num), ddr_dll_ctl3.u); + + ddr_dll_ctl3.u = BDK_CSR_READ(node, BDK_LMCX_DLL_CTL3(ddr_interface_num)); +} + +static void +Update_Write_Deskew_Settings(bdk_node_t node, int ddr_interface_num, deskew_data_t *dskdat) +{ + bdk_lmcx_config_t lmc_config; + int bit_num; + int byte_lane, byte_limit; + + lmc_config.u = BDK_CSR_READ(node, BDK_LMCX_CONFIG(ddr_interface_num)); + byte_limit = ((lmc_config.s.mode32b) ? 4 : 8) + lmc_config.s.ecc_ena; + + for (byte_lane = 0; byte_lane < byte_limit; byte_lane++) { + for (bit_num = 0; bit_num <= 7; ++bit_num) { + + set_write_deskew_offset(node, ddr_interface_num, bit_num, byte_lane + 1, + dskdat->bytes[byte_lane].bits[bit_num]); + + } /* for (bit_num = 0; bit_num <= 7; ++bit_num) */ + } /* for (byte_lane = 0; byte_lane < byte_limit; byte_lane++) */ + + return; +} + +#define ALL_BYTES 0x0A +#define BS_NOOP 0x09 +#define BS_RESET 0x0F +#define BS_REUSE 0x0A + +// set all entries to the same value (used during training) +static void +Set_Write_Deskew_Settings(bdk_node_t node, int ddr_interface_num, int value) +{ + bdk_lmcx_dll_ctl3_t ddr_dll_ctl3; + int bit_num; + + VB_PRT(VBL_DEV2, "N%d.LMC%d: SetWriteDeskew: WRITE %d\n", node, ddr_interface_num, value); + + for (bit_num = 0; bit_num <= 7; ++bit_num) { + + // write a bit-deskew value to all bit-lanes of all bytes + ddr_dll_ctl3.u = BDK_CSR_READ(node, BDK_LMCX_DLL_CTL3(ddr_interface_num)); + SET_DDR_DLL_CTL3(bit_select, bit_num); + SET_DDR_DLL_CTL3(byte_sel, ALL_BYTES); // FIXME? will this work in 32-bit mode? + SET_DDR_DLL_CTL3(offset, value); + DRAM_CSR_WRITE(node, BDK_LMCX_DLL_CTL3(ddr_interface_num), ddr_dll_ctl3.u); + + ddr_dll_ctl3.u = BDK_CSR_READ(node, BDK_LMCX_DLL_CTL3(ddr_interface_num)); + SET_DDR_DLL_CTL3(wr_deskew_ld, 1); + DRAM_CSR_WRITE(node, BDK_LMCX_DLL_CTL3(ddr_interface_num), ddr_dll_ctl3.u); + + } /* for (bit_num = 0; bit_num <= 7; ++bit_num) */ + +#if 0 + // FIXME: for debug use only + Get_Deskew_Settings(node, ddr_interface_num, &dskdat); + Display_Deskew_Data(node, ddr_interface_num, &dskdat, VBL_NORM); +#endif + + return; +} + +typedef struct { + uint8_t count[8]; + uint8_t start[8]; + uint8_t best_count[8]; + uint8_t best_start[8]; +} deskew_bytelane_t; +typedef struct { + deskew_bytelane_t bytes[9]; +} deskew_rank_t; + +deskew_rank_t deskew_history[4]; + +#define DSKVAL_INCR 4 + +static void +Neutral_Write_Deskew_Setup(bdk_node_t node, int ddr_interface_num) +{ + // first: NO-OP, Select all bytes, Disable write bit-deskew + ddr_print("N%d.LMC%d: NEUTRAL Write Deskew Setup: first: NOOP\n", node, ddr_interface_num); + do_write_deskew_op(node, ddr_interface_num, BS_NOOP, ALL_BYTES, 0); + //Get_Deskew_Settings(node, ddr_interface_num, &dskdat); + //Display_Deskew_Data(node, ddr_interface_num, &dskdat, VBL_NORM); + + // enable write bit-deskew and RESET the settings + ddr_print("N%d.LMC%d: NEUTRAL Write Deskew Setup: wr_ena: RESET\n", node, ddr_interface_num); + do_write_deskew_op(node, ddr_interface_num, BS_RESET, ALL_BYTES, 1); + //Get_Deskew_Settings(node, ddr_interface_num, &dskdat); + //Display_Deskew_Data(node, ddr_interface_num, &dskdat, VBL_NORM); +} + +static void +Perform_Write_Deskew_Training(bdk_node_t node, int ddr_interface_num) +{ + deskew_data_t dskdat; + int byte, bit_num; + int dskval, rankx, rank_mask, active_ranks, errors, bit_errs; + uint64_t hw_rank_offset; + uint64_t bad_bits[2]; + uint64_t phys_addr; + deskew_rank_t *dhp; + int num_lmcs = __bdk_dram_get_num_lmc(node); + + BDK_CSR_INIT(lmcx_config, node, BDK_LMCX_CONFIG(ddr_interface_num)); + rank_mask = lmcx_config.s.init_status; // FIXME: is this right when we run? + + // this should be correct for 1 or 2 ranks, 1 or 2 DIMMs + hw_rank_offset = 1ull << (28 + lmcx_config.s.pbank_lsb - lmcx_config.s.rank_ena + (num_lmcs/2)); + + VB_PRT(VBL_FAE, "N%d.LMC%d: Performing Write Deskew Training.\n", node, ddr_interface_num); + + // first: NO-OP, Select all bytes, Disable write bit-deskew + ddr_print("N%d.LMC%d: WriteDeskewConfig: first: NOOP\n", node, ddr_interface_num); + do_write_deskew_op(node, ddr_interface_num, BS_NOOP, ALL_BYTES, 0); + //Get_Deskew_Settings(node, ddr_interface_num, &dskdat); + //Display_Deskew_Data(node, ddr_interface_num, &dskdat, VBL_NORM); + + // enable write bit-deskew and RESET the settings + ddr_print("N%d.LMC%d: WriteDeskewConfig: wr_ena: RESET\n", node, ddr_interface_num); + do_write_deskew_op(node, ddr_interface_num, BS_RESET, ALL_BYTES, 1); + //Get_Deskew_Settings(node, ddr_interface_num, &dskdat); + //Display_Deskew_Data(node, ddr_interface_num, &dskdat, VBL_NORM); + +#if 0 + // enable write bit-deskew and REUSE read bit-deskew settings + ddr_print("N%d.LMC%d: WriteDeskewConfig: wr_ena: REUSE\n", node, ddr_interface_num); + do_write_deskew_op(node, ddr_interface_num, BS_REUSE, ALL_BYTES, 1); + Get_Deskew_Settings(node, ddr_interface_num, &dskdat); + Display_Deskew_Data(node, ddr_interface_num, &dskdat, VBL_NORM); +#endif + +#if 1 + memset(deskew_history, 0, sizeof(deskew_history)); + + for (dskval = 0; dskval < 128; dskval += DSKVAL_INCR) { + + Set_Write_Deskew_Settings(node, ddr_interface_num, dskval); + + active_ranks = 0; + for (rankx = 0; rankx < 4; rankx++) { + if (!(rank_mask & (1 << rankx))) + continue; + dhp = &deskew_history[rankx]; + phys_addr = hw_rank_offset * active_ranks; + active_ranks++; + + errors = test_dram_byte_hw(node, ddr_interface_num, phys_addr, 0, bad_bits); + + for (byte = 0; byte <= 8; byte++) { // do bytelane(s) + + // check errors + if (errors & (1 << byte)) { // yes, error(s) in the byte lane in this rank + bit_errs = ((byte == 8) ? bad_bits[1] : bad_bits[0] >> (8 * byte)) & 0xFFULL; + + VB_PRT(VBL_DEV2, "N%d.LMC%d.R%d: Byte %d Value %d: Address 0x%012lx errors 0x%x/0x%x\n", + node, ddr_interface_num, rankx, byte, + dskval, phys_addr, errors, bit_errs); + + for (bit_num = 0; bit_num <= 7; bit_num++) { + if (!(bit_errs & (1 << bit_num))) + continue; + if (dhp->bytes[byte].count[bit_num] > 0) { // had started run + VB_PRT(VBL_DEV2, "N%d.LMC%d.R%d: Byte %d Bit %d Value %d: stopping a run here\n", + node, ddr_interface_num, rankx, byte, bit_num, dskval); + dhp->bytes[byte].count[bit_num] = 0; // stop now + } + } /* for (bit_num = 0; bit_num <= 7; bit_num++) */ + + // FIXME: else had not started run - nothing else to do? + } else { // no error in the byte lane + for (bit_num = 0; bit_num <= 7; bit_num++) { + if (dhp->bytes[byte].count[bit_num] == 0) { // first success, set run start + VB_PRT(VBL_DEV2, "N%d.LMC%d.R%d: Byte %d Bit %d Value %d: starting a run here\n", + node, ddr_interface_num, rankx, byte, bit_num, dskval); + dhp->bytes[byte].start[bit_num] = dskval; + } + dhp->bytes[byte].count[bit_num] += DSKVAL_INCR; // bump run length + + // is this now the biggest window? + if (dhp->bytes[byte].count[bit_num] > dhp->bytes[byte].best_count[bit_num]) { + dhp->bytes[byte].best_count[bit_num] = dhp->bytes[byte].count[bit_num]; + dhp->bytes[byte].best_start[bit_num] = dhp->bytes[byte].start[bit_num]; + VB_PRT(VBL_DEV2, "N%d.LMC%d.R%d: Byte %d Bit %d Value %d: updating best to %d/%d\n", + node, ddr_interface_num, rankx, byte, bit_num, dskval, + dhp->bytes[byte].best_start[bit_num], + dhp->bytes[byte].best_count[bit_num]); + } + } /* for (bit_num = 0; bit_num <= 7; bit_num++) */ + } /* error in the byte lane */ + } /* for (byte = 0; byte <= 8; byte++) */ + } /* for (rankx = 0; rankx < 4; rankx++) */ + } /* for (dskval = 0; dskval < 128; dskval++) */ + + + for (byte = 0; byte <= 8; byte++) { // do bytelane(s) + + for (bit_num = 0; bit_num <= 7; bit_num++) { // do bits + int bit_beg, bit_end; + + bit_beg = 0; + bit_end = 128; + + for (rankx = 0; rankx < 4; rankx++) { // merge ranks + int rank_beg, rank_end, rank_count; + if (!(rank_mask & (1 << rankx))) + continue; + + dhp = &deskew_history[rankx]; + rank_beg = dhp->bytes[byte].best_start[bit_num]; + rank_count = dhp->bytes[byte].best_count[bit_num]; + + if (!rank_count) { + VB_PRT(VBL_DEV, "N%d.LMC%d.R%d: Byte %d Bit %d: EMPTY\n", + node, ddr_interface_num, rankx, byte, bit_num); + continue; + } + + bit_beg = max(bit_beg, rank_beg); + rank_end = rank_beg + rank_count - DSKVAL_INCR; + bit_end = min(bit_end, rank_end); + + } /* for (rankx = 0; rankx < 4; rankx++) */ + + dskdat.bytes[byte].bits[bit_num] = (bit_end + bit_beg) / 2; + + } /* for (bit_num = 0; bit_num <= 7; bit_num++) */ + } /* for (byte = 0; byte <= 8; byte++) */ + +#endif + + // update the write bit-deskew settings with final settings + ddr_print("N%d.LMC%d: WriteDeskewConfig: wr_ena: UPDATE\n", node, ddr_interface_num); + Update_Write_Deskew_Settings(node, ddr_interface_num, &dskdat); + Get_Deskew_Settings(node, ddr_interface_num, &dskdat); + Display_Deskew_Data(node, ddr_interface_num, &dskdat, VBL_NORM); + + // last: NO-OP, Select all bytes, MUST leave write bit-deskew enabled + ddr_print("N%d.LMC%d: WriteDeskewConfig: last: wr_ena: NOOP\n", node, ddr_interface_num); + do_write_deskew_op(node, ddr_interface_num, BS_NOOP, ALL_BYTES, 1); + //Get_Deskew_Settings(node, ddr_interface_num, &dskdat); + //Display_Deskew_Data(node, ddr_interface_num, &dskdat, VBL_NORM); + +#if 0 + // FIXME: disable/delete this when write bit-deskew works... + // final: NO-OP, Select all bytes, do NOT leave write bit-deskew enabled + ddr_print("N%d.LMC%d: WriteDeskewConfig: final: read: NOOP\n", node, ddr_interface_num); + do_write_deskew_op(node, ddr_interface_num, BS_NOOP, ALL_BYTES, 0); + Get_Deskew_Settings(node, ddr_interface_num, &dskdat); + Display_Deskew_Data(node, ddr_interface_num, &dskdat, VBL_NORM); +#endif +} + +#define SCALING_FACTOR (1000) +#define Dprintf debug_print // make this "ddr_print" for extra debug output below +static int compute_Vref_1slot_2rank(int rtt_wr, int rtt_park, int dqx_ctl, int rank_count) +{ + uint64_t Reff_s; + uint64_t Rser_s = 15; + uint64_t Vdd = 1200; + uint64_t Vref; + //uint64_t Vl; + uint64_t rtt_wr_s = (((rtt_wr == 0) || (rtt_wr == 99)) ? 1*1024*1024 : rtt_wr); // 99 == HiZ + uint64_t rtt_park_s = (((rtt_park == 0) || ((rank_count == 1) && (rtt_wr != 0))) ? 1*1024*1024 : rtt_park); + uint64_t dqx_ctl_s = (dqx_ctl == 0 ? 1*1024*1024 : dqx_ctl); + int Vref_value; + uint64_t Rangepc = 6000; // range1 base is 60% + uint64_t Vrefpc; + int Vref_range = 0; + + Dprintf("rtt_wr = %d, rtt_park = %d, dqx_ctl = %d\n", rtt_wr, rtt_park, dqx_ctl); + Dprintf("rtt_wr_s = %d, rtt_park_s = %d, dqx_ctl_s = %d\n", rtt_wr_s, rtt_park_s, dqx_ctl_s); + + Reff_s = divide_nint((rtt_wr_s * rtt_park_s) , (rtt_wr_s + rtt_park_s)); + Dprintf("Reff_s = %d\n", Reff_s); + + //Vl = (((Rser_s + dqx_ctl_s) * SCALING_FACTOR) / (Rser_s + dqx_ctl_s + Reff_s)) * Vdd / SCALING_FACTOR; + //printf("Vl = %d\n", Vl); + + Vref = (((Rser_s + dqx_ctl_s) * SCALING_FACTOR) / (Rser_s + dqx_ctl_s + Reff_s)) + SCALING_FACTOR; + Dprintf("Vref = %d\n", Vref); + + Vref = (Vref * Vdd) / 2 / SCALING_FACTOR; + Dprintf("Vref = %d\n", Vref); + + Vrefpc = (Vref * 100 * 100) / Vdd; + Dprintf("Vrefpc = %d\n", Vrefpc); + + if (Vrefpc < Rangepc) { // < range1 base, use range2 + Vref_range = 1 << 6; // set bit A6 for range2 + Rangepc = 4500; // range2 base is 45% + } + + Vref_value = divide_nint(Vrefpc - Rangepc, 65); + if (Vref_value < 0) + Vref_value = Vref_range; // set to base of range as lowest value + else + Vref_value |= Vref_range; + Dprintf("Vref_value = %d (0x%02x)\n", Vref_value, Vref_value); + + debug_print("rtt_wr:%d, rtt_park:%d, dqx_ctl:%d, Vref_value:%d (0x%x)\n", + rtt_wr, rtt_park, dqx_ctl, Vref_value, Vref_value); + + return Vref_value; +} +static int compute_Vref_2slot_2rank(int rtt_wr, int rtt_park_00, int rtt_park_01, int dqx_ctl, int rtt_nom) +{ + //uint64_t Rser = 15; + uint64_t Vdd = 1200; + //uint64_t Vref; + uint64_t Vl, Vlp, Vcm; + uint64_t Rd0, Rd1, Rpullup; + uint64_t rtt_wr_s = (((rtt_wr == 0) || (rtt_wr == 99)) ? 1*1024*1024 : rtt_wr); // 99 == HiZ + uint64_t rtt_park_00_s = (rtt_park_00 == 0 ? 1*1024*1024 : rtt_park_00); + uint64_t rtt_park_01_s = (rtt_park_01 == 0 ? 1*1024*1024 : rtt_park_01); + uint64_t dqx_ctl_s = (dqx_ctl == 0 ? 1*1024*1024 : dqx_ctl); + uint64_t rtt_nom_s = (rtt_nom == 0 ? 1*1024*1024 : rtt_nom); + int Vref_value; + uint64_t Rangepc = 6000; // range1 base is 60% + uint64_t Vrefpc; + int Vref_range = 0; + + // Rd0 = (RTT_NOM /*parallel*/ RTT_WR) + 15 = ((RTT_NOM * RTT_WR) / (RTT_NOM + RTT_WR)) + 15 + Rd0 = divide_nint((rtt_nom_s * rtt_wr_s), (rtt_nom_s + rtt_wr_s)) + 15; + //printf("Rd0 = %ld\n", Rd0); + + // Rd1 = (RTT_PARK_00 /*parallel*/ RTT_PARK_01) + 15 = ((RTT_PARK_00 * RTT_PARK_01) / (RTT_PARK_00 + RTT_PARK_01)) + 15 + Rd1 = divide_nint((rtt_park_00_s * rtt_park_01_s), (rtt_park_00_s + rtt_park_01_s)) + 15; + //printf("Rd1 = %ld\n", Rd1); + + // Rpullup = Rd0 /*parallel*/ Rd1 = (Rd0 * Rd1) / (Rd0 + Rd1) + Rpullup = divide_nint((Rd0 * Rd1), (Rd0 + Rd1)); + //printf("Rpullup = %ld\n", Rpullup); + + // Vl = (DQX_CTL / (DQX_CTL + Rpullup)) * 1.2 + Vl = divide_nint((dqx_ctl_s * Vdd), (dqx_ctl_s + Rpullup)); + //printf("Vl = %ld\n", Vl); + + // Vlp = ((15 / Rd0) * (1.2 - Vl)) + Vl + Vlp = divide_nint((15 * (Vdd - Vl)), Rd0) + Vl; + //printf("Vlp = %ld\n", Vlp); + + // Vcm = (Vlp + 1.2) / 2 + Vcm = divide_nint((Vlp + Vdd), 2); + //printf("Vcm = %ld\n", Vcm); + + // Vrefpc = (Vcm / 1.2) * 100 + Vrefpc = divide_nint((Vcm * 100 * 100), Vdd); + //printf("Vrefpc = %ld\n", Vrefpc); + + if (Vrefpc < Rangepc) { // < range1 base, use range2 + Vref_range = 1 << 6; // set bit A6 for range2 + Rangepc = 4500; // range2 base is 45% + } + + Vref_value = divide_nint(Vrefpc - Rangepc, 65); + if (Vref_value < 0) + Vref_value = Vref_range; // set to base of range as lowest value + else + Vref_value |= Vref_range; + //printf("Vref_value = %d (0x%02x)\n", Vref_value, Vref_value); + + debug_print("rtt_wr:%d, rtt_park_00:%d, rtt_park_01:%d, dqx_ctl:%d, rtt_nom:%d, Vref_value:%d (0x%x)\n", + rtt_wr, rtt_park_00, rtt_park_01, dqx_ctl, rtt_nom, Vref_value, Vref_value); + + return Vref_value; +} + +// NOTE: only call this for DIMMs with 1 or 2 ranks, not 4. +int +compute_vref_value(bdk_node_t node, int ddr_interface_num, + int rankx, int dimm_count, int rank_count, + impedence_values_t *imp_values, int is_stacked_die) +{ + int computed_final_vref_value = 0; + + /* Calculate an override of the measured Vref value + but only for configurations we know how to...*/ + // we have code for 2-rank DIMMs in both 1-slot or 2-slot configs, + // and can use the 2-rank 1-slot code for 1-rank DIMMs in 1-slot configs + // and can use the 2-rank 2-slot code for 1-rank DIMMs in 2-slot configs + + int rtt_wr, dqx_ctl, rtt_nom, index; + bdk_lmcx_modereg_params1_t lmc_modereg_params1; + bdk_lmcx_modereg_params2_t lmc_modereg_params2; + bdk_lmcx_comp_ctl2_t comp_ctl2; + + lmc_modereg_params1.u = BDK_CSR_READ(node, BDK_LMCX_MODEREG_PARAMS1(ddr_interface_num)); + lmc_modereg_params2.u = BDK_CSR_READ(node, BDK_LMCX_MODEREG_PARAMS2(ddr_interface_num)); + comp_ctl2.u = BDK_CSR_READ(node, BDK_LMCX_COMP_CTL2(ddr_interface_num)); + dqx_ctl = imp_values->dqx_strength[comp_ctl2.s.dqx_ctl]; + + // WR always comes from the current rank + index = (lmc_modereg_params1.u >> (rankx * 12 + 5)) & 0x03; + if (!CAVIUM_IS_MODEL(CAVIUM_CN88XX_PASS1_X)) { + index |= lmc_modereg_params1.u >> (51+rankx-2) & 0x04; + } + rtt_wr = imp_values->rtt_wr_ohms [index]; + + // separate calculations for 1 vs 2 DIMMs per LMC + if (dimm_count == 1) { + // PARK comes from this rank if 1-rank, otherwise other rank + index = (lmc_modereg_params2.u >> ((rankx ^ (rank_count - 1)) * 10 + 0)) & 0x07; + int rtt_park = imp_values->rtt_nom_ohms[index]; + computed_final_vref_value = compute_Vref_1slot_2rank(rtt_wr, rtt_park, dqx_ctl, rank_count); + } else { + // get both PARK values from the other DIMM + index = (lmc_modereg_params2.u >> ((rankx ^ 0x02) * 10 + 0)) & 0x07; + int rtt_park_00 = imp_values->rtt_nom_ohms[index]; + index = (lmc_modereg_params2.u >> ((rankx ^ 0x03) * 10 + 0)) & 0x07; + int rtt_park_01 = imp_values->rtt_nom_ohms[index]; + // NOM comes from this rank if 1-rank, otherwise other rank + index = (lmc_modereg_params1.u >> ((rankx ^ (rank_count - 1)) * 12 + 9)) & 0x07; + rtt_nom = imp_values->rtt_nom_ohms[index]; + computed_final_vref_value = compute_Vref_2slot_2rank(rtt_wr, rtt_park_00, rtt_park_01, dqx_ctl, rtt_nom); + } + +#if ENABLE_COMPUTED_VREF_ADJUSTMENT + { + int saved_final_vref_value = computed_final_vref_value; + BDK_CSR_INIT(lmc_config, node, BDK_LMCX_CONFIG(ddr_interface_num)); + /* + New computed Vref = existing computed Vref – X + + The value of X is depending on different conditions. Both #122 and #139 are 2Rx4 RDIMM, + while #124 is stacked die 2Rx4, so I conclude the results into two conditions: + + 1. Stacked Die: 2Rx4 + 1-slot: offset = 7. i, e New computed Vref = existing computed Vref – 7 + 2-slot: offset = 6 + + 2. Regular: 2Rx4 + 1-slot: offset = 3 + 2-slot: offset = 2 + */ + // we know we never get called unless DDR4, so test just the other conditions + if((!!__bdk_dram_is_rdimm(node, 0)) && + (rank_count == 2) && + (lmc_config.s.mode_x4dev)) + { // it must first be RDIMM and 2-rank and x4 + if (is_stacked_die) { // now do according to stacked die or not... + computed_final_vref_value -= (dimm_count == 1) ? 7 : 6; + } else { + computed_final_vref_value -= (dimm_count == 1) ? 3 : 2; + } + // we have adjusted it, so print it out if verbosity is right + VB_PRT(VBL_TME, "N%d.LMC%d.R%d: adjusting computed vref from %2d (0x%02x) to %2d (0x%02x)\n", + node, ddr_interface_num, rankx, + saved_final_vref_value, saved_final_vref_value, + computed_final_vref_value, computed_final_vref_value); + } + } +#endif + return computed_final_vref_value; +} + +static unsigned int EXTR_WR(uint64_t u, int x) +{ + return (unsigned int)(((u >> (x*12+5)) & 0x3UL) | ((u >> (51+x-2)) & 0x4UL)); +} +static void INSRT_WR(uint64_t *up, int x, int v) +{ + uint64_t u = *up; + u &= ~(((0x3UL) << (x*12+5)) | ((0x1UL) << (51+x))); + *up = (u | ((v & 0x3UL) << (x*12+5)) | ((v & 0x4UL) << (51+x-2))); + return; +} + +static int encode_row_lsb_ddr3(int row_lsb, int ddr_interface_wide) +{ + int encoded_row_lsb; + int row_lsb_start = 14; + + /* Decoding for row_lsb */ + /* 000: row_lsb = mem_adr[14] */ + /* 001: row_lsb = mem_adr[15] */ + /* 010: row_lsb = mem_adr[16] */ + /* 011: row_lsb = mem_adr[17] */ + /* 100: row_lsb = mem_adr[18] */ + /* 101: row_lsb = mem_adr[19] */ + /* 110: row_lsb = mem_adr[20] */ + /* 111: RESERVED */ + + row_lsb_start = 14; + + encoded_row_lsb = row_lsb - row_lsb_start ; + + return encoded_row_lsb; +} + +static int encode_pbank_lsb_ddr3(int pbank_lsb, int ddr_interface_wide) +{ + int encoded_pbank_lsb; + + /* Decoding for pbank_lsb */ + /* 0000:DIMM = mem_adr[28] / rank = mem_adr[27] (if RANK_ENA) */ + /* 0001:DIMM = mem_adr[29] / rank = mem_adr[28] " */ + /* 0010:DIMM = mem_adr[30] / rank = mem_adr[29] " */ + /* 0011:DIMM = mem_adr[31] / rank = mem_adr[30] " */ + /* 0100:DIMM = mem_adr[32] / rank = mem_adr[31] " */ + /* 0101:DIMM = mem_adr[33] / rank = mem_adr[32] " */ + /* 0110:DIMM = mem_adr[34] / rank = mem_adr[33] " */ + /* 0111:DIMM = 0 / rank = mem_adr[34] " */ + /* 1000-1111: RESERVED */ + + int pbank_lsb_start = 0; + + pbank_lsb_start = 28; + + encoded_pbank_lsb = pbank_lsb - pbank_lsb_start; + + return encoded_pbank_lsb; +} + +static uint64_t octeon_read_lmcx_ddr3_rlevel_dbg(bdk_node_t node, int ddr_interface_num, int idx) +{ + DRAM_CSR_MODIFY(c, node, BDK_LMCX_RLEVEL_CTL(ddr_interface_num), + c.s.byte = idx); + BDK_CSR_READ(node, BDK_LMCX_RLEVEL_CTL(ddr_interface_num)); + BDK_CSR_INIT(rlevel_dbg, node, BDK_LMCX_RLEVEL_DBG(ddr_interface_num)); + return rlevel_dbg.s.bitmask; +} + +static uint64_t octeon_read_lmcx_ddr3_wlevel_dbg(bdk_node_t node, int ddr_interface_num, int idx) +{ + bdk_lmcx_wlevel_dbg_t wlevel_dbg; + + wlevel_dbg.u = 0; + wlevel_dbg.s.byte = idx; + + DRAM_CSR_WRITE(node, BDK_LMCX_WLEVEL_DBG(ddr_interface_num), wlevel_dbg.u); + BDK_CSR_READ(node, BDK_LMCX_WLEVEL_DBG(ddr_interface_num)); + + wlevel_dbg.u = BDK_CSR_READ(node, BDK_LMCX_WLEVEL_DBG(ddr_interface_num)); + return wlevel_dbg.s.bitmask; +} + + +/* + * Apply a filter to the BITMASK results returned from Octeon + * read-leveling to determine the most likely delay result. This + * computed delay may be used to qualify the delay result returned by + * Octeon. Accumulate an error penalty for invalid characteristics of + * the bitmask so that they can be used to select the most reliable + * results. + * + * The algorithm searches for the largest contiguous MASK within a + * maximum RANGE of bits beginning with the MSB. + * + * 1. a MASK with a WIDTH less than 4 will be penalized + * 2. Bubbles in the bitmask that occur before or after the MASK + * will be penalized + * 3. If there are no trailing bubbles then extra bits that occur + * beyond the maximum RANGE will be penalized. + * + * +++++++++++++++++++++++++++++++++++++++++++++++++++ + * + + + * + e.g. bitmask = 27B00 + + * + + + * + 63 +--- mstart 0 + + * + | | | + + * + | +---------+ +--- fb | + + * + | | range | | | + + * + V V V V V + + * + + + * + 0 0 ... 1 0 0 1 1 1 1 0 1 1 0 0 0 0 0 0 0 0 + + * + + + * + ^ ^ ^ + + * + | | mask| + + * + lb ---+ +-----+ + + * + width + + * + + + * +++++++++++++++++++++++++++++++++++++++++++++++++++ + */ +#define RLEVEL_BITMASK_TRAILING_BITS_ERROR 5 +#define RLEVEL_BITMASK_BUBBLE_BITS_ERROR 11 // FIXME? now less than TOOLONG +#define RLEVEL_BITMASK_NARROW_ERROR 6 +#define RLEVEL_BITMASK_BLANK_ERROR 100 +#define RLEVEL_BITMASK_TOOLONG_ERROR 12 + +#define MASKRANGE_BITS 6 +#define MASKRANGE ((1 << MASKRANGE_BITS) - 1) + +static int +validate_ddr3_rlevel_bitmask(rlevel_bitmask_t *rlevel_bitmask_p, int ddr_type) +{ + int i; + int errors = 0; + uint64_t mask = 0; /* Used in 64-bit comparisons */ + int8_t mstart = 0; + uint8_t width = 0; + uint8_t firstbit = 0; + uint8_t lastbit = 0; + uint8_t bubble = 0; + uint8_t tbubble = 0; + uint8_t blank = 0; + uint8_t narrow = 0; + uint8_t trailing = 0; + uint64_t bitmask = rlevel_bitmask_p->bm; + uint8_t extras = 0; + uint8_t toolong = 0; + uint64_t temp; + + if (bitmask == 0) { + blank += RLEVEL_BITMASK_BLANK_ERROR; + } else { + + /* Look for fb, the first bit */ + temp = bitmask; + while (!(temp & 1)) { + firstbit++; + temp >>= 1; + } + + /* Look for lb, the last bit */ + lastbit = firstbit; + while ((temp >>= 1)) + lastbit++; + + /* Start with the max range to try to find the largest mask within the bitmask data */ + width = MASKRANGE_BITS; + for (mask = MASKRANGE; mask > 0; mask >>= 1, --width) { + for (mstart = lastbit - width + 1; mstart >= firstbit; --mstart) { + temp = mask << mstart; + if ((bitmask & temp) == temp) + goto done_now; + } + } + done_now: + /* look for any more contiguous 1's to the right of mstart */ + if (width == MASKRANGE_BITS) { // only when maximum mask + while ((bitmask >> (mstart - 1)) & 1) { // slide right over more 1's + --mstart; + if (ddr_type == DDR4_DRAM) // only for DDR4 + extras++; // count the number of extra bits + } + } + + /* Penalize any extra 1's beyond the maximum desired mask */ + if (extras > 0) + toolong = RLEVEL_BITMASK_TOOLONG_ERROR * ((1 << extras) - 1); + + /* Detect if bitmask is too narrow. */ + if (width < 4) + narrow = (4 - width) * RLEVEL_BITMASK_NARROW_ERROR; + + /* detect leading bubble bits, that is, any 0's between first and mstart */ + temp = bitmask >> (firstbit + 1); + i = mstart - firstbit - 1; + while (--i >= 0) { + if ((temp & 1) == 0) + bubble += RLEVEL_BITMASK_BUBBLE_BITS_ERROR; + temp >>= 1; + } + + temp = bitmask >> (mstart + width + extras); + i = lastbit - (mstart + width + extras - 1); + while (--i >= 0) { + if (temp & 1) { /* Detect 1 bits after the trailing end of the mask, including last. */ + trailing += RLEVEL_BITMASK_TRAILING_BITS_ERROR; + } else { /* Detect trailing bubble bits, that is, any 0's between end-of-mask and last */ + tbubble += RLEVEL_BITMASK_BUBBLE_BITS_ERROR; + } + temp >>= 1; + } + } + + errors = bubble + tbubble + blank + narrow + trailing + toolong; + + /* Pass out useful statistics */ + rlevel_bitmask_p->mstart = mstart; + rlevel_bitmask_p->width = width; + + VB_PRT(VBL_DEV2, "bm:%08lx mask:%02lx, width:%2u, mstart:%2d, fb:%2u, lb:%2u" + " (bu:%2d, tb:%2d, bl:%2d, n:%2d, t:%2d, x:%2d) errors:%3d %s\n", + (unsigned long) bitmask, mask, width, mstart, + firstbit, lastbit, bubble, tbubble, blank, narrow, + trailing, toolong, errors, (errors) ? "=> invalid" : ""); + + return errors; +} + +static int compute_ddr3_rlevel_delay(uint8_t mstart, uint8_t width, bdk_lmcx_rlevel_ctl_t rlevel_ctl) +{ + int delay; + + debug_bitmask_print(" offset_en:%d", rlevel_ctl.cn8.offset_en); + + if (rlevel_ctl.s.offset_en) { + delay = max(mstart, mstart + width - 1 - rlevel_ctl.s.offset); + } else { + /* if (rlevel_ctl.s.offset) { */ /* Experimental */ + if (0) { + delay = max(mstart + rlevel_ctl.s.offset, mstart + 1); + /* Insure that the offset delay falls within the bitmask */ + delay = min(delay, mstart + width-1); + } else { + delay = (width - 1) / 2 + mstart; /* Round down */ + /* delay = (width/2) + mstart; */ /* Round up */ + } + } + + return delay; +} + +#define WLEVEL_BYTE_BITS 5 +#define WLEVEL_BYTE_MSK ((1UL << 5) - 1) + +static void update_wlevel_rank_struct(bdk_lmcx_wlevel_rankx_t *lmc_wlevel_rank, + int byte, int delay) +{ + bdk_lmcx_wlevel_rankx_t temp_wlevel_rank; + if (byte >= 0 && byte <= 8) { + temp_wlevel_rank.u = lmc_wlevel_rank->u; + temp_wlevel_rank.u &= ~(WLEVEL_BYTE_MSK << (WLEVEL_BYTE_BITS * byte)); + temp_wlevel_rank.u |= ((delay & WLEVEL_BYTE_MSK) << (WLEVEL_BYTE_BITS * byte)); + lmc_wlevel_rank->u = temp_wlevel_rank.u; + } +} + +static int get_wlevel_rank_struct(bdk_lmcx_wlevel_rankx_t *lmc_wlevel_rank, + int byte) +{ + int delay = 0; + if (byte >= 0 && byte <= 8) { + delay = ((lmc_wlevel_rank->u) >> (WLEVEL_BYTE_BITS * byte)) & WLEVEL_BYTE_MSK; + } + return delay; +} + +#if 0 +// entry = 1 is valid, entry = 0 is invalid +static int +validity_matrix[4][4] = {[0] {1,1,1,0}, // valid pairs when cv == 0: 0,0 + 0,1 + 0,2 == "7" + [1] {0,1,1,1}, // valid pairs when cv == 1: 1,1 + 1,2 + 1,3 == "E" + [2] {1,0,1,1}, // valid pairs when cv == 2: 2,2 + 2,3 + 2,0 == "D" + [3] {1,1,0,1}}; // valid pairs when cv == 3: 3,3 + 3,0 + 3,1 == "B" +#endif +static int +validate_seq(int *wl, int *seq) +{ + int seqx; // sequence index, step through the sequence array + int bitnum; + seqx = 0; + while (seq[seqx+1] >= 0) { // stop on next seq entry == -1 + // but now, check current versus next +#if 0 + if ( !validity_matrix [wl[seq[seqx]]] [wl[seq[seqx+1]]] ) + return 1; +#else + bitnum = (wl[seq[seqx]] << 2) | wl[seq[seqx+1]]; + if (!((1 << bitnum) & 0xBDE7)) // magic validity number (see matrix above) + return 1; +#endif + seqx++; + } + return 0; +} + +static int +Validate_HW_WL_Settings(bdk_node_t node, int ddr_interface_num, + bdk_lmcx_wlevel_rankx_t *lmc_wlevel_rank, + int ecc_ena) +{ + int wl[9], byte, errors; + + // arrange the sequences so + int useq[] = { 0,1,2,3,8,4,5,6,7,-1 }; // index 0 has byte 0, etc, ECC in middle + int rseq1[] = { 8,3,2,1,0,-1 }; // index 0 is ECC, then go down + int rseq2[] = { 4,5,6,7,-1 }; // index 0 has byte 4, then go up + int useqno[] = { 0,1,2,3,4,5,6,7,-1 }; // index 0 has byte 0, etc, no ECC + int rseq1no[] = { 3,2,1,0,-1 }; // index 0 is byte 3, then go down, no ECC + + // in the CSR, bytes 0-7 are always data, byte 8 is ECC + for (byte = 0; byte < 8+ecc_ena; byte++) { + wl[byte] = (get_wlevel_rank_struct(lmc_wlevel_rank, byte) >> 1) & 3; // preprocess :-) + } + + errors = 0; + if (__bdk_dram_is_rdimm(node, 0) != 0) { // RDIMM order + errors = validate_seq(wl, (ecc_ena) ? rseq1 : rseq1no); + errors += validate_seq(wl, rseq2); + } else { // UDIMM order + errors = validate_seq(wl, (ecc_ena) ? useq : useqno); + } + + return errors; +} + +#define RLEVEL_BYTE_BITS 6 +#define RLEVEL_BYTE_MSK ((1UL << 6) - 1) + +static void update_rlevel_rank_struct(bdk_lmcx_rlevel_rankx_t *lmc_rlevel_rank, + int byte, int delay) +{ + bdk_lmcx_rlevel_rankx_t temp_rlevel_rank; + if (byte >= 0 && byte <= 8) { + temp_rlevel_rank.u = lmc_rlevel_rank->u & ~(RLEVEL_BYTE_MSK << (RLEVEL_BYTE_BITS * byte)); + temp_rlevel_rank.u |= ((delay & RLEVEL_BYTE_MSK) << (RLEVEL_BYTE_BITS * byte)); + lmc_rlevel_rank->u = temp_rlevel_rank.u; + } +} + +#if RLEXTRAS_PATCH || !DISABLE_SW_WL_PASS_2 +static int get_rlevel_rank_struct(bdk_lmcx_rlevel_rankx_t *lmc_rlevel_rank, + int byte) +{ + int delay = 0; + if (byte >= 0 && byte <= 8) { + delay = ((lmc_rlevel_rank->u) >> (RLEVEL_BYTE_BITS * byte)) & RLEVEL_BYTE_MSK; + } + return delay; +} +#endif + +static void unpack_rlevel_settings(int ddr_interface_bytemask, int ecc_ena, + rlevel_byte_data_t *rlevel_byte, + bdk_lmcx_rlevel_rankx_t lmc_rlevel_rank) +{ + if ((ddr_interface_bytemask & 0xff) == 0xff) { + if (ecc_ena) { + rlevel_byte[8].delay = lmc_rlevel_rank.cn83xx.byte7; + rlevel_byte[7].delay = lmc_rlevel_rank.cn83xx.byte6; + rlevel_byte[6].delay = lmc_rlevel_rank.cn83xx.byte5; + rlevel_byte[5].delay = lmc_rlevel_rank.cn83xx.byte4; + rlevel_byte[4].delay = lmc_rlevel_rank.cn83xx.byte8; /* ECC */ + } else { + rlevel_byte[7].delay = lmc_rlevel_rank.cn83xx.byte7; + rlevel_byte[6].delay = lmc_rlevel_rank.cn83xx.byte6; + rlevel_byte[5].delay = lmc_rlevel_rank.cn83xx.byte5; + rlevel_byte[4].delay = lmc_rlevel_rank.cn83xx.byte4; + } + } else { + rlevel_byte[8].delay = lmc_rlevel_rank.cn83xx.byte8; /* unused */ + rlevel_byte[7].delay = lmc_rlevel_rank.cn83xx.byte7; /* unused */ + rlevel_byte[6].delay = lmc_rlevel_rank.cn83xx.byte6; /* unused */ + rlevel_byte[5].delay = lmc_rlevel_rank.cn83xx.byte5; /* unused */ + rlevel_byte[4].delay = lmc_rlevel_rank.cn83xx.byte4; /* ECC */ + } + rlevel_byte[3].delay = lmc_rlevel_rank.cn83xx.byte3; + rlevel_byte[2].delay = lmc_rlevel_rank.cn83xx.byte2; + rlevel_byte[1].delay = lmc_rlevel_rank.cn83xx.byte1; + rlevel_byte[0].delay = lmc_rlevel_rank.cn83xx.byte0; +} + +static void pack_rlevel_settings(int ddr_interface_bytemask, int ecc_ena, + rlevel_byte_data_t *rlevel_byte, + bdk_lmcx_rlevel_rankx_t *final_rlevel_rank) +{ + bdk_lmcx_rlevel_rankx_t lmc_rlevel_rank = *final_rlevel_rank; + + if ((ddr_interface_bytemask & 0xff) == 0xff) { + if (ecc_ena) { + lmc_rlevel_rank.cn83xx.byte7 = rlevel_byte[8].delay; + lmc_rlevel_rank.cn83xx.byte6 = rlevel_byte[7].delay; + lmc_rlevel_rank.cn83xx.byte5 = rlevel_byte[6].delay; + lmc_rlevel_rank.cn83xx.byte4 = rlevel_byte[5].delay; + lmc_rlevel_rank.cn83xx.byte8 = rlevel_byte[4].delay; /* ECC */ + } else { + lmc_rlevel_rank.cn83xx.byte7 = rlevel_byte[7].delay; + lmc_rlevel_rank.cn83xx.byte6 = rlevel_byte[6].delay; + lmc_rlevel_rank.cn83xx.byte5 = rlevel_byte[5].delay; + lmc_rlevel_rank.cn83xx.byte4 = rlevel_byte[4].delay; + } + } else { + lmc_rlevel_rank.cn83xx.byte8 = rlevel_byte[8].delay; + lmc_rlevel_rank.cn83xx.byte7 = rlevel_byte[7].delay; + lmc_rlevel_rank.cn83xx.byte6 = rlevel_byte[6].delay; + lmc_rlevel_rank.cn83xx.byte5 = rlevel_byte[5].delay; + lmc_rlevel_rank.cn83xx.byte4 = rlevel_byte[4].delay; + } + lmc_rlevel_rank.cn83xx.byte3 = rlevel_byte[3].delay; + lmc_rlevel_rank.cn83xx.byte2 = rlevel_byte[2].delay; + lmc_rlevel_rank.cn83xx.byte1 = rlevel_byte[1].delay; + lmc_rlevel_rank.cn83xx.byte0 = rlevel_byte[0].delay; + + *final_rlevel_rank = lmc_rlevel_rank; +} + +#if !DISABLE_SW_WL_PASS_2 +static void rlevel_to_wlevel(bdk_lmcx_rlevel_rankx_t *lmc_rlevel_rank, + bdk_lmcx_wlevel_rankx_t *lmc_wlevel_rank, int byte) +{ + int byte_delay = get_rlevel_rank_struct(lmc_rlevel_rank, byte); + + debug_print("Estimating Wlevel delay byte %d: ", byte); + debug_print("Rlevel=%d => ", byte_delay); + byte_delay = divide_roundup(byte_delay,2) & 0x1e; + debug_print("Wlevel=%d\n", byte_delay); + update_wlevel_rank_struct(lmc_wlevel_rank, byte, byte_delay); +} +#endif /* !DISABLE_SW_WL_PASS_2 */ + +/* Delay trend: constant=0, decreasing=-1, increasing=1 */ +static int calc_delay_trend(int v) +{ + if (v == 0) + return (0); + if (v < 0) + return (-1); + return 1; +} + +/* Evaluate delay sequence across the whole range of byte delays while +** keeping track of the overall delay trend, increasing or decreasing. +** If the trend changes charge an error amount to the score. +*/ + +// NOTE: "max_adj_delay_inc" argument is, by default, 1 for DDR3 and 2 for DDR4 + +static int nonsequential_delays(rlevel_byte_data_t *rlevel_byte, + int start, int end, int max_adj_delay_inc) +{ + int error = 0; + int delay_trend, prev_trend = 0; + int byte_idx; + int delay_inc; + int delay_diff; + int byte_err; + + for (byte_idx = start; byte_idx < end; ++byte_idx) { + byte_err = 0; + + delay_diff = rlevel_byte[byte_idx+1].delay - rlevel_byte[byte_idx].delay; + delay_trend = calc_delay_trend(delay_diff); + + debug_bitmask_print("Byte %d: %2d, Byte %d: %2d, delay_trend: %2d, prev_trend: %2d", + byte_idx+0, rlevel_byte[byte_idx+0].delay, + byte_idx+1, rlevel_byte[byte_idx+1].delay, + delay_trend, prev_trend); + + /* Increment error each time the trend changes to the opposite direction. + */ + if ((prev_trend != 0) && (delay_trend != 0) && (prev_trend != delay_trend)) { + byte_err += RLEVEL_NONSEQUENTIAL_DELAY_ERROR; + prev_trend = delay_trend; + debug_bitmask_print(" => Nonsequential byte delay"); + } + + delay_inc = _abs(delay_diff); // how big was the delay change, if any + + /* Even if the trend did not change to the opposite direction, check for + the magnitude of the change, and scale the penalty by the amount that + the size is larger than the provided limit. + */ + if ((max_adj_delay_inc != 0) && (delay_inc > max_adj_delay_inc)) { + byte_err += (delay_inc - max_adj_delay_inc) * RLEVEL_ADJACENT_DELAY_ERROR; + debug_bitmask_print(" => Adjacent delay error"); + } + + debug_bitmask_print("\n"); + if (delay_trend != 0) + prev_trend = delay_trend; + + rlevel_byte[byte_idx+1].sqerrs = byte_err; + error += byte_err; + } + return error; +} + +static int roundup_ddr3_wlevel_bitmask(int bitmask) +{ + int shifted_bitmask; + int leader; + int delay; + + for (leader=0; leader<8; ++leader) { + shifted_bitmask = (bitmask>>leader); + if ((shifted_bitmask&1) == 0) + break; + } + + for (/*leader=leader*/; leader<16; ++leader) { + shifted_bitmask = (bitmask>>(leader%8)); + if (shifted_bitmask&1) + break; + } + + delay = (leader & 1) ? leader + 1 : leader; + delay = delay % 8; + + return delay; +} + +/* Check to see if any custom offset values are provided */ +static int is_dll_offset_provided(const int8_t *dll_offset_table) +{ + int i; + if (dll_offset_table != NULL) { + for (i=0; i<9; ++i) { + if (dll_offset_table[i] != 0) + return (1); + } + } + return (0); +} + +/////////////////// These are the RLEVEL settings display routines + +// flags +#define WITH_NOTHING 0 +#define WITH_SCORE 1 +#define WITH_AVERAGE 2 +#define WITH_FINAL 4 +#define WITH_COMPUTE 8 +static void do_display_RL(bdk_node_t node, int ddr_interface_num, + bdk_lmcx_rlevel_rankx_t lmc_rlevel_rank, + int rank, int flags, int score) +{ + char score_buf[16]; + if (flags & WITH_SCORE) + snprintf(score_buf, sizeof(score_buf), "(%d)", score); + else { + score_buf[0] = ' '; score_buf[1] = 0; + } + + char *msg_buf; + char hex_buf[20]; + if (flags & WITH_AVERAGE) { + msg_buf = " DELAY AVERAGES "; + } else if (flags & WITH_FINAL) { + msg_buf = " FINAL SETTINGS "; + } else if (flags & WITH_COMPUTE) { + msg_buf = " COMPUTED DELAYS "; + } else { + snprintf(hex_buf, sizeof(hex_buf), "0x%016lX", lmc_rlevel_rank.u); + msg_buf = hex_buf; + } + + ddr_print("N%d.LMC%d.R%d: Rlevel Rank %#4x, %s : %5d %5d %5d %5d %5d %5d %5d %5d %5d %s\n", + node, ddr_interface_num, rank, + lmc_rlevel_rank.s.status, + msg_buf, + lmc_rlevel_rank.cn83xx.byte8, + lmc_rlevel_rank.cn83xx.byte7, + lmc_rlevel_rank.cn83xx.byte6, + lmc_rlevel_rank.cn83xx.byte5, + lmc_rlevel_rank.cn83xx.byte4, + lmc_rlevel_rank.cn83xx.byte3, + lmc_rlevel_rank.cn83xx.byte2, + lmc_rlevel_rank.cn83xx.byte1, + lmc_rlevel_rank.cn83xx.byte0, + score_buf + ); +} + +static inline void +display_RL(bdk_node_t node, int ddr_interface_num, bdk_lmcx_rlevel_rankx_t lmc_rlevel_rank, int rank) +{ + do_display_RL(node, ddr_interface_num, lmc_rlevel_rank, rank, 0, 0); +} + +static inline void +display_RL_with_score(bdk_node_t node, int ddr_interface_num, bdk_lmcx_rlevel_rankx_t lmc_rlevel_rank, int rank, int score) +{ + do_display_RL(node, ddr_interface_num, lmc_rlevel_rank, rank, 1, score); +} + +#if !PICK_BEST_RANK_SCORE_NOT_AVG +static inline void +display_RL_with_average(bdk_node_t node, int ddr_interface_num, bdk_lmcx_rlevel_rankx_t lmc_rlevel_rank, int rank, int score) +{ + do_display_RL(node, ddr_interface_num, lmc_rlevel_rank, rank, 3, score); +} +#endif + +static inline void +display_RL_with_final(bdk_node_t node, int ddr_interface_num, bdk_lmcx_rlevel_rankx_t lmc_rlevel_rank, int rank) +{ + do_display_RL(node, ddr_interface_num, lmc_rlevel_rank, rank, 4, 0); +} + +static inline void +display_RL_with_computed(bdk_node_t node, int ddr_interface_num, bdk_lmcx_rlevel_rankx_t lmc_rlevel_rank, int rank, int score) +{ + do_display_RL(node, ddr_interface_num, lmc_rlevel_rank, rank, 9, score); +} + +// flag values +#define WITH_RODT_BLANK 0 +#define WITH_RODT_SKIPPING 1 +#define WITH_RODT_BESTROW 2 +#define WITH_RODT_BESTSCORE 3 +// control +#define SKIP_SKIPPING 1 + +static const char *with_rodt_canned_msgs[4] = { " ", "SKIPPING ", "BEST ROW ", "BEST SCORE" }; + +static void display_RL_with_RODT(bdk_node_t node, int ddr_interface_num, + bdk_lmcx_rlevel_rankx_t lmc_rlevel_rank, int rank, int score, + int nom_ohms, int rodt_ohms, int flag) +{ + const char *msg_buf; + char set_buf[20]; +#if SKIP_SKIPPING + if (flag == WITH_RODT_SKIPPING) return; +#endif + msg_buf = with_rodt_canned_msgs[flag]; + if (nom_ohms < 0) { + snprintf(set_buf, sizeof(set_buf), " RODT %3d ", rodt_ohms); + } else { + snprintf(set_buf, sizeof(set_buf), "NOM %3d RODT %3d", nom_ohms, rodt_ohms); + } + + VB_PRT(VBL_TME, "N%d.LMC%d.R%d: Rlevel %s %s : %5d %5d %5d %5d %5d %5d %5d %5d %5d (%d)\n", + node, ddr_interface_num, rank, + set_buf, msg_buf, + lmc_rlevel_rank.cn83xx.byte8, + lmc_rlevel_rank.cn83xx.byte7, + lmc_rlevel_rank.cn83xx.byte6, + lmc_rlevel_rank.cn83xx.byte5, + lmc_rlevel_rank.cn83xx.byte4, + lmc_rlevel_rank.cn83xx.byte3, + lmc_rlevel_rank.cn83xx.byte2, + lmc_rlevel_rank.cn83xx.byte1, + lmc_rlevel_rank.cn83xx.byte0, + score + ); + + // FIXME: does this help make the output a little easier to focus? + if (flag == WITH_RODT_BESTSCORE) { + VB_PRT(VBL_DEV, "-----------\n"); + } +} + +static void +do_display_WL(bdk_node_t node, int ddr_interface_num, bdk_lmcx_wlevel_rankx_t lmc_wlevel_rank, int rank, int flags) +{ + char *msg_buf; + char hex_buf[20]; + int vbl; + if (flags & WITH_FINAL) { + msg_buf = " FINAL SETTINGS "; + vbl = VBL_NORM; + } else { + snprintf(hex_buf, sizeof(hex_buf), "0x%016lX", lmc_wlevel_rank.u); + msg_buf = hex_buf; + vbl = VBL_FAE; + } + + VB_PRT(vbl, "N%d.LMC%d.R%d: Wlevel Rank %#4x, %s : %5d %5d %5d %5d %5d %5d %5d %5d %5d\n", + node, ddr_interface_num, rank, + lmc_wlevel_rank.s.status, + msg_buf, + lmc_wlevel_rank.s.byte8, + lmc_wlevel_rank.s.byte7, + lmc_wlevel_rank.s.byte6, + lmc_wlevel_rank.s.byte5, + lmc_wlevel_rank.s.byte4, + lmc_wlevel_rank.s.byte3, + lmc_wlevel_rank.s.byte2, + lmc_wlevel_rank.s.byte1, + lmc_wlevel_rank.s.byte0 + ); +} + +static inline void +display_WL(bdk_node_t node, int ddr_interface_num, bdk_lmcx_wlevel_rankx_t lmc_wlevel_rank, int rank) +{ + do_display_WL(node, ddr_interface_num, lmc_wlevel_rank, rank, WITH_NOTHING); +} + +static inline void +display_WL_with_final(bdk_node_t node, int ddr_interface_num, bdk_lmcx_wlevel_rankx_t lmc_wlevel_rank, int rank) +{ + do_display_WL(node, ddr_interface_num, lmc_wlevel_rank, rank, WITH_FINAL); +} + +// pretty-print bitmask adjuster +static uint64_t +PPBM(uint64_t bm) +{ + if (bm != 0ul) { + while ((bm & 0x0fful) == 0ul) + bm >>= 4; + } + return bm; +} + +// xlate PACKED index to UNPACKED index to use with rlevel_byte +#define XPU(i,e) (((i) < 4)?(i):((i)<8)?(i)+(e):4) +// xlate UNPACKED index to PACKED index to use with rlevel_bitmask +#define XUP(i,e) (((i) < 4)?(i):((i)>4)?(i)-(e):8) + +// flag values +#define WITH_WL_BITMASKS 0 +#define WITH_RL_BITMASKS 1 +#define WITH_RL_MASK_SCORES 2 +#define WITH_RL_SEQ_SCORES 3 +static void +do_display_BM(bdk_node_t node, int ddr_interface_num, int rank, void *bm, int flags, int ecc_ena) +{ + int ecc = !!ecc_ena; + if (flags == WITH_WL_BITMASKS) { // wlevel_bitmask array in PACKED index order, so just print them + int *bitmasks = (int *)bm; + + ddr_print("N%d.LMC%d.R%d: Wlevel Debug Results : %05x %05x %05x %05x %05x %05x %05x %05x %05x\n", + node, ddr_interface_num, rank, + bitmasks[8], + bitmasks[7], + bitmasks[6], + bitmasks[5], + bitmasks[4], + bitmasks[3], + bitmasks[2], + bitmasks[1], + bitmasks[0] + ); + } else + if (flags == WITH_RL_BITMASKS) { // rlevel_bitmask array in PACKED index order, so just print them + rlevel_bitmask_t *rlevel_bitmask = (rlevel_bitmask_t *)bm; + ddr_print("N%d.LMC%d.R%d: Rlevel Debug Bitmasks 8:0 : %05lx %05lx %05lx %05lx %05lx %05lx %05lx %05lx %05lx\n", + node, ddr_interface_num, rank, + PPBM(rlevel_bitmask[8].bm), + PPBM(rlevel_bitmask[7].bm), + PPBM(rlevel_bitmask[6].bm), + PPBM(rlevel_bitmask[5].bm), + PPBM(rlevel_bitmask[4].bm), + PPBM(rlevel_bitmask[3].bm), + PPBM(rlevel_bitmask[2].bm), + PPBM(rlevel_bitmask[1].bm), + PPBM(rlevel_bitmask[0].bm) + ); + } else + if (flags == WITH_RL_MASK_SCORES) { // rlevel_bitmask array in PACKED index order, so just print them + rlevel_bitmask_t *rlevel_bitmask = (rlevel_bitmask_t *)bm; + ddr_print("N%d.LMC%d.R%d: Rlevel Debug Bitmask Scores 8:0 : %5d %5d %5d %5d %5d %5d %5d %5d %5d\n", + node, ddr_interface_num, rank, + rlevel_bitmask[8].errs, + rlevel_bitmask[7].errs, + rlevel_bitmask[6].errs, + rlevel_bitmask[5].errs, + rlevel_bitmask[4].errs, + rlevel_bitmask[3].errs, + rlevel_bitmask[2].errs, + rlevel_bitmask[1].errs, + rlevel_bitmask[0].errs + ); + } else + if (flags == WITH_RL_SEQ_SCORES) { // rlevel_byte array in UNPACKED index order, so xlate and print them + rlevel_byte_data_t *rlevel_byte = (rlevel_byte_data_t *)bm; + ddr_print("N%d.LMC%d.R%d: Rlevel Debug Non-seq Scores 8:0 : %5d %5d %5d %5d %5d %5d %5d %5d %5d\n", + node, ddr_interface_num, rank, + rlevel_byte[XPU(8,ecc)].sqerrs, + rlevel_byte[XPU(7,ecc)].sqerrs, + rlevel_byte[XPU(6,ecc)].sqerrs, + rlevel_byte[XPU(5,ecc)].sqerrs, + rlevel_byte[XPU(4,ecc)].sqerrs, + rlevel_byte[XPU(3,ecc)].sqerrs, + rlevel_byte[XPU(2,ecc)].sqerrs, + rlevel_byte[XPU(1,ecc)].sqerrs, + rlevel_byte[XPU(0,ecc)].sqerrs + ); + } +} + +static inline void +display_WL_BM(bdk_node_t node, int ddr_interface_num, int rank, int *bitmasks) +{ + do_display_BM(node, ddr_interface_num, rank, (void *)bitmasks, WITH_WL_BITMASKS, 0); +} + +static inline void +display_RL_BM(bdk_node_t node, int ddr_interface_num, int rank, rlevel_bitmask_t *bitmasks, int ecc_ena) +{ + do_display_BM(node, ddr_interface_num, rank, (void *)bitmasks, WITH_RL_BITMASKS, ecc_ena); +} + +static inline void +display_RL_BM_scores(bdk_node_t node, int ddr_interface_num, int rank, rlevel_bitmask_t *bitmasks, int ecc_ena) +{ + do_display_BM(node, ddr_interface_num, rank, (void *)bitmasks, WITH_RL_MASK_SCORES, ecc_ena); +} + +static inline void +display_RL_SEQ_scores(bdk_node_t node, int ddr_interface_num, int rank, rlevel_byte_data_t *bytes, int ecc_ena) +{ + do_display_BM(node, ddr_interface_num, rank, (void *)bytes, WITH_RL_SEQ_SCORES, ecc_ena); +} + +unsigned short load_dll_offset(bdk_node_t node, int ddr_interface_num, + int dll_offset_mode, int byte_offset, int byte) +{ + bdk_lmcx_dll_ctl3_t ddr_dll_ctl3; + /* byte_sel: + 0x1 = byte 0, ..., 0x9 = byte 8 + 0xA = all bytes */ + int byte_sel = (byte == 10) ? byte : byte + 1; + + ddr_dll_ctl3.u = BDK_CSR_READ(node, BDK_LMCX_DLL_CTL3(ddr_interface_num)); + SET_DDR_DLL_CTL3(load_offset, 0); + DRAM_CSR_WRITE(node, BDK_LMCX_DLL_CTL3(ddr_interface_num), ddr_dll_ctl3.u); + ddr_dll_ctl3.u = BDK_CSR_READ(node, BDK_LMCX_DLL_CTL3(ddr_interface_num)); + + SET_DDR_DLL_CTL3(mode_sel, dll_offset_mode); + SET_DDR_DLL_CTL3(offset, (_abs(byte_offset)&0x3f) | (_sign(byte_offset) << 6)); /* Always 6-bit field? */ + SET_DDR_DLL_CTL3(byte_sel, byte_sel); + DRAM_CSR_WRITE(node, BDK_LMCX_DLL_CTL3(ddr_interface_num), ddr_dll_ctl3.u); + ddr_dll_ctl3.u = BDK_CSR_READ(node, BDK_LMCX_DLL_CTL3(ddr_interface_num)); + + SET_DDR_DLL_CTL3(load_offset, 1); + DRAM_CSR_WRITE(node, BDK_LMCX_DLL_CTL3(ddr_interface_num), ddr_dll_ctl3.u); + ddr_dll_ctl3.u = BDK_CSR_READ(node, BDK_LMCX_DLL_CTL3(ddr_interface_num)); + + return ((unsigned short) GET_DDR_DLL_CTL3(offset)); +} + +void change_dll_offset_enable(bdk_node_t node, int ddr_interface_num, int change) +{ + bdk_lmcx_dll_ctl3_t ddr_dll_ctl3; + + ddr_dll_ctl3.u = BDK_CSR_READ(node, BDK_LMCX_DLL_CTL3(ddr_interface_num)); + SET_DDR_DLL_CTL3(offset_ena, !!change); + DRAM_CSR_WRITE(node, BDK_LMCX_DLL_CTL3(ddr_interface_num), ddr_dll_ctl3.u); + ddr_dll_ctl3.u = BDK_CSR_READ(node, BDK_LMCX_DLL_CTL3(ddr_interface_num)); +} + +static void process_custom_dll_offsets(bdk_node_t node, int ddr_interface_num, const char *enable_str, + const int8_t *offsets, const char *byte_str, int mode) +{ + const char *s; + int enabled; + int provided; + + if ((s = lookup_env_parameter("%s", enable_str)) != NULL) { + enabled = !!strtol(s, NULL, 0); + } else + enabled = -1; + + // enabled == -1: no override, do only configured offsets if provided + // enabled == 0: override OFF, do NOT do it even if configured offsets provided + // enabled == 1: override ON, do it for overrides plus configured offsets + + if (enabled == 0) + return; + + provided = is_dll_offset_provided(offsets); + + if (enabled < 0 && !provided) + return; + + int byte_offset; + unsigned short offset[9] = {0}; + int byte; + + // offsets need to be disabled while loading + change_dll_offset_enable(node, ddr_interface_num, 0); + + for (byte = 0; byte < 9; ++byte) { + + // always take the provided, if available + byte_offset = (provided) ? offsets[byte] : 0; + + // then, if enabled, use any overrides present + if (enabled > 0) { + if ((s = lookup_env_parameter(byte_str, ddr_interface_num, byte)) != NULL) { + byte_offset = strtol(s, NULL, 0); + } + } + + offset[byte] = load_dll_offset(node, ddr_interface_num, mode, byte_offset, byte); + } + + // re-enable offsets after loading + change_dll_offset_enable(node, ddr_interface_num, 1); + + ddr_print("N%d.LMC%d: DLL %s Offset 8:0 :" + " 0x%02x 0x%02x 0x%02x 0x%02x 0x%02x 0x%02x 0x%02x 0x%02x 0x%02x\n", + node, ddr_interface_num, (mode == 2) ? "Read " : "Write", + offset[8], offset[7], offset[6], offset[5], offset[4], + offset[3], offset[2], offset[1], offset[0]); +} + +void perform_octeon3_ddr3_sequence(bdk_node_t node, int rank_mask, int ddr_interface_num, int sequence) +{ + /* + * 3. Without changing any other fields in LMC(0)_CONFIG, write + * LMC(0)_CONFIG[RANKMASK] then write both + * LMC(0)_SEQ_CTL[SEQ_SEL,INIT_START] = 1 with a single CSR write + * operation. LMC(0)_CONFIG[RANKMASK] bits should be set to indicate + * the ranks that will participate in the sequence. + * + * The LMC(0)_SEQ_CTL[SEQ_SEL] value should select power-up/init or + * selfrefresh exit, depending on whether the DRAM parts are in + * self-refresh and whether their contents should be preserved. While + * LMC performs these sequences, it will not perform any other DDR3 + * transactions. When the sequence is complete, hardware sets the + * LMC(0)_CONFIG[INIT_STATUS] bits for the ranks that have been + * initialized. + * + * If power-up/init is selected immediately following a DRESET + * assertion, LMC executes the sequence described in the "Reset and + * Initialization Procedure" section of the JEDEC DDR3 + * specification. This includes activating CKE, writing all four DDR3 + * mode registers on all selected ranks, and issuing the required ZQCL + * command. The LMC(0)_CONFIG[RANKMASK] value should select all ranks + * with attached DRAM in this case. If LMC(0)_CONTROL[RDIMM_ENA] = 1, + * LMC writes the JEDEC standard SSTE32882 control words selected by + * LMC(0)_DIMM_CTL[DIMM*_WMASK] between DDR_CKE* signal assertion and + * the first DDR3 mode register write operation. + * LMC(0)_DIMM_CTL[DIMM*_WMASK] should be cleared to 0 if the + * corresponding DIMM is not present. + * + * If self-refresh exit is selected, LMC executes the required SRX + * command followed by a refresh and ZQ calibration. Section 4.5 + * describes behavior of a REF + ZQCS. LMC does not write the DDR3 + * mode registers as part of this sequence, and the mode register + * parameters must match at self-refresh entry and exit times. + * + * 4. Read LMC(0)_SEQ_CTL and wait for LMC(0)_SEQ_CTL[SEQ_COMPLETE] to be + * set. + * + * 5. Read LMC(0)_CONFIG[INIT_STATUS] and confirm that all ranks have + * been initialized. + */ + + const char *s; + static const char *sequence_str[] = { + "Power-up/init", + "Read-leveling", + "Self-refresh entry", + "Self-refresh exit", + "Illegal", + "Illegal", + "Write-leveling", + "Init Register Control Words", + "Mode Register Write", + "MPR Register Access", + "LMC Deskew/Internal Vref training", + "Offset Training" + }; + + bdk_lmcx_seq_ctl_t seq_ctl; + bdk_lmcx_config_t lmc_config; + + lmc_config.u = BDK_CSR_READ(node, BDK_LMCX_CONFIG(ddr_interface_num)); + lmc_config.s.rankmask = rank_mask; + DRAM_CSR_WRITE(node, BDK_LMCX_CONFIG(ddr_interface_num), lmc_config.u); + + seq_ctl.u = 0; + + seq_ctl.s.init_start = 1; + seq_ctl.s.seq_sel = sequence; + + VB_PRT(VBL_SEQ, "N%d.LMC%d: Performing LMC sequence=%x: rank_mask=0x%02x, %s\n", + node, ddr_interface_num, sequence, rank_mask, sequence_str[sequence]); + + if ((s = lookup_env_parameter("ddr_trigger_sequence%d", sequence)) != NULL) { + int trigger = strtoul(s, NULL, 0); + if (trigger) + pulse_gpio_pin(node, 1, 2); + } + + DRAM_CSR_WRITE(node, BDK_LMCX_SEQ_CTL(ddr_interface_num), seq_ctl.u); + BDK_CSR_READ(node, BDK_LMCX_SEQ_CTL(ddr_interface_num)); + + /* Wait 100us minimum before checking for sequence complete */ + bdk_wait_usec(100); + if (!bdk_is_platform(BDK_PLATFORM_ASIM) && + BDK_CSR_WAIT_FOR_FIELD(node, BDK_LMCX_SEQ_CTL(ddr_interface_num), seq_complete, ==, 1, 1000000)) + { + error_print("N%d.LMC%d: Timeout waiting for LMC sequence=%x, rank_mask=0x%02x, ignoring...\n", + node, ddr_interface_num, sequence, rank_mask); + } + else { + VB_PRT(VBL_SEQ, "N%d.LMC%d: LMC sequence=%x: Completed.\n", node, ddr_interface_num, sequence); + } +} + +void ddr4_mrw(bdk_node_t node, int ddr_interface_num, int rank, + int mr_wr_addr, int mr_wr_sel, int mr_wr_bg1) +{ + bdk_lmcx_mr_mpr_ctl_t lmc_mr_mpr_ctl; + + lmc_mr_mpr_ctl.u = 0; + lmc_mr_mpr_ctl.s.mr_wr_addr = (mr_wr_addr == -1) ? 0 : mr_wr_addr; + lmc_mr_mpr_ctl.s.mr_wr_sel = mr_wr_sel; + lmc_mr_mpr_ctl.s.mr_wr_rank = rank; + //lmc_mr_mpr_ctl.s.mr_wr_pda_mask = + //lmc_mr_mpr_ctl.s.mr_wr_pda_enable = + //lmc_mr_mpr_ctl.s.mpr_loc = + //lmc_mr_mpr_ctl.s.mpr_wr = + //lmc_mr_mpr_ctl.s.mpr_bit_select = + //lmc_mr_mpr_ctl.s.mpr_byte_select = + //lmc_mr_mpr_ctl.s.mpr_whole_byte_enable = + lmc_mr_mpr_ctl.s.mr_wr_use_default_value = (mr_wr_addr == -1) ? 1 : 0; + lmc_mr_mpr_ctl.s.mr_wr_bg1 = mr_wr_bg1; + DRAM_CSR_WRITE(node, BDK_LMCX_MR_MPR_CTL(ddr_interface_num), lmc_mr_mpr_ctl.u); + + /* Mode Register Write */ + perform_octeon3_ddr3_sequence(node, 1 << rank, ddr_interface_num, 0x8); +} + +#define InvA0_17(x) (x ^ 0x22bf8) +static void set_mpr_mode (bdk_node_t node, int rank_mask, + int ddr_interface_num, int dimm_count, int mpr, int bg1) +{ + int rankx; + + ddr_print("All Ranks: Set mpr mode = %x %c-side\n", + mpr, (bg1==0) ? 'A' : 'B'); + + for (rankx = 0; rankx < dimm_count*4; rankx++) { + if (!(rank_mask & (1 << rankx))) + continue; + if (bg1 == 0) + ddr4_mrw(node, ddr_interface_num, rankx, mpr<<2, 3, bg1); /* MR3 A-side */ + else + ddr4_mrw(node, ddr_interface_num, rankx, InvA0_17(mpr<<2), ~3, bg1); /* MR3 B-side */ + } +} + +#if ENABLE_DISPLAY_MPR_PAGE +static void do_ddr4_mpr_read(bdk_node_t node, int ddr_interface_num, int rank, + int page, int location) +{ + bdk_lmcx_mr_mpr_ctl_t lmc_mr_mpr_ctl; + + lmc_mr_mpr_ctl.u = BDK_CSR_READ(node, BDK_LMCX_MR_MPR_CTL(ddr_interface_num)); + + lmc_mr_mpr_ctl.s.mr_wr_addr = 0; + lmc_mr_mpr_ctl.s.mr_wr_sel = page; /* Page */ + lmc_mr_mpr_ctl.s.mr_wr_rank = rank; + //lmc_mr_mpr_ctl.s.mr_wr_pda_mask = + //lmc_mr_mpr_ctl.s.mr_wr_pda_enable = + lmc_mr_mpr_ctl.s.mpr_loc = location; + lmc_mr_mpr_ctl.s.mpr_wr = 0; /* Read=0, Write=1 */ + //lmc_mr_mpr_ctl.s.mpr_bit_select = + //lmc_mr_mpr_ctl.s.mpr_byte_select = + //lmc_mr_mpr_ctl.s.mpr_whole_byte_enable = + //lmc_mr_mpr_ctl.s.mr_wr_use_default_value = + //lmc_mr_mpr_ctl.s.mr_wr_bg1 = + + DRAM_CSR_WRITE(node, BDK_LMCX_MR_MPR_CTL(ddr_interface_num), lmc_mr_mpr_ctl.u); + + /* MPR register access sequence */ + perform_octeon3_ddr3_sequence(node, 1 << rank, ddr_interface_num, 0x9); + + debug_print("LMC_MR_MPR_CTL : 0x%016lx\n", lmc_mr_mpr_ctl.u); + debug_print("lmc_mr_mpr_ctl.s.mr_wr_addr: 0x%02x\n", lmc_mr_mpr_ctl.s.mr_wr_addr); + debug_print("lmc_mr_mpr_ctl.s.mr_wr_sel : 0x%02x\n", lmc_mr_mpr_ctl.s.mr_wr_sel); + debug_print("lmc_mr_mpr_ctl.s.mpr_loc : 0x%02x\n", lmc_mr_mpr_ctl.s.mpr_loc); + debug_print("lmc_mr_mpr_ctl.s.mpr_wr : 0x%02x\n", lmc_mr_mpr_ctl.s.mpr_wr); + +} +#endif + +int set_rdimm_mode(bdk_node_t node, int ddr_interface_num, int enable) +{ + bdk_lmcx_control_t lmc_control; + int save_rdimm_mode; + + lmc_control.u = BDK_CSR_READ(node, BDK_LMCX_CONTROL(ddr_interface_num)); + save_rdimm_mode = lmc_control.s.rdimm_ena; + lmc_control.s.rdimm_ena = enable; + VB_PRT(VBL_FAE, "Setting RDIMM_ENA = %x\n", enable); + DRAM_CSR_WRITE(node, BDK_LMCX_CONTROL(ddr_interface_num), lmc_control.u); + + return (save_rdimm_mode); +} + +#if ENABLE_DISPLAY_MPR_PAGE +static void ddr4_mpr_read(bdk_node_t node, int ddr_interface_num, int rank, + int page, int location, uint64_t *mpr_data) +{ + do_ddr4_mpr_read(node, ddr_interface_num, rank, page, location); + + mpr_data[0] = BDK_CSR_READ(node, BDK_LMCX_MPR_DATA0(ddr_interface_num)); + mpr_data[1] = BDK_CSR_READ(node, BDK_LMCX_MPR_DATA1(ddr_interface_num)); + mpr_data[2] = BDK_CSR_READ(node, BDK_LMCX_MPR_DATA2(ddr_interface_num)); + + debug_print("MPR Read %016lx.%016lx.%016lx\n", mpr_data[2], mpr_data[1], mpr_data[0]); +} + +/* Display MPR values for Page Location */ +static void Display_MPR_Page_Location(bdk_node_t node, int rank, + int ddr_interface_num, int dimm_count, + int page, int location, uint64_t *mpr_data) +{ + ddr4_mpr_read(node, ddr_interface_num, rank, page, location, mpr_data); + ddr_print("MPR Page %d, Loc %d %016lx.%016lx.%016lx\n", + page, location, mpr_data[2], mpr_data[1], mpr_data[0]); +} + +/* Display MPR values for Page */ +static void Display_MPR_Page(bdk_node_t node, int rank_mask, + int ddr_interface_num, int dimm_count, int page) +{ + int rankx; + uint64_t mpr_data[3]; + + for (rankx = 0; rankx < dimm_count * 4;rankx++) { + if (!(rank_mask & (1 << rankx))) + continue; + + ddr_print("Rank %d: MPR values for Page %d\n", rankx, page); + for (int location = 0; location < 4; location++) { + Display_MPR_Page_Location(node, rankx, ddr_interface_num, dimm_count, + page, location, &mpr_data[0]); + } + + } /* for (rankx = 0; rankx < dimm_count * 4; rankx++) */ +} +#endif + +void ddr4_mpr_write(bdk_node_t node, int ddr_interface_num, int rank, + int page, int location, uint8_t mpr_data) +{ + bdk_lmcx_mr_mpr_ctl_t lmc_mr_mpr_ctl; + + lmc_mr_mpr_ctl.u = 0; + lmc_mr_mpr_ctl.s.mr_wr_addr = mpr_data; + lmc_mr_mpr_ctl.s.mr_wr_sel = page; /* Page */ + lmc_mr_mpr_ctl.s.mr_wr_rank = rank; + //lmc_mr_mpr_ctl.s.mr_wr_pda_mask = + //lmc_mr_mpr_ctl.s.mr_wr_pda_enable = + lmc_mr_mpr_ctl.s.mpr_loc = location; + lmc_mr_mpr_ctl.s.mpr_wr = 1; /* Read=0, Write=1 */ + //lmc_mr_mpr_ctl.s.mpr_bit_select = + //lmc_mr_mpr_ctl.s.mpr_byte_select = + //lmc_mr_mpr_ctl.s.mpr_whole_byte_enable = + //lmc_mr_mpr_ctl.s.mr_wr_use_default_value = + //lmc_mr_mpr_ctl.s.mr_wr_bg1 = + DRAM_CSR_WRITE(node, BDK_LMCX_MR_MPR_CTL(ddr_interface_num), lmc_mr_mpr_ctl.u); + + /* MPR register access sequence */ + perform_octeon3_ddr3_sequence(node, (1 << rank), ddr_interface_num, 0x9); + + debug_print("LMC_MR_MPR_CTL : 0x%016lx\n", lmc_mr_mpr_ctl.u); + debug_print("lmc_mr_mpr_ctl.s.mr_wr_addr: 0x%02x\n", lmc_mr_mpr_ctl.s.mr_wr_addr); + debug_print("lmc_mr_mpr_ctl.s.mr_wr_sel : 0x%02x\n", lmc_mr_mpr_ctl.s.mr_wr_sel); + debug_print("lmc_mr_mpr_ctl.s.mpr_loc : 0x%02x\n", lmc_mr_mpr_ctl.s.mpr_loc); + debug_print("lmc_mr_mpr_ctl.s.mpr_wr : 0x%02x\n", lmc_mr_mpr_ctl.s.mpr_wr); +} + +void set_vref(bdk_node_t node, int ddr_interface_num, int rank, + int range, int value) +{ + bdk_lmcx_mr_mpr_ctl_t lmc_mr_mpr_ctl; + bdk_lmcx_modereg_params3_t lmc_modereg_params3; + int mr_wr_addr = 0; + + lmc_mr_mpr_ctl.u = 0; + lmc_modereg_params3.u = BDK_CSR_READ(node, BDK_LMCX_MODEREG_PARAMS3(ddr_interface_num)); + + mr_wr_addr |= lmc_modereg_params3.s.tccd_l<<10; /* A12:A10 tCCD_L */ + mr_wr_addr |= 1<<7; /* A7 1 = Enable(Training Mode) */ + mr_wr_addr |= range<<6; /* A6 VrefDQ Training Range */ + mr_wr_addr |= value<<0; /* A5:A0 VrefDQ Training Value */ + + lmc_mr_mpr_ctl.s.mr_wr_addr = mr_wr_addr; + lmc_mr_mpr_ctl.s.mr_wr_sel = 6; /* Write MR6 */ + lmc_mr_mpr_ctl.s.mr_wr_rank = rank; + //lmc_mr_mpr_ctl.s.mr_wr_pda_mask = + //lmc_mr_mpr_ctl.s.mr_wr_pda_enable = + //lmc_mr_mpr_ctl.s.mpr_loc = location; + //lmc_mr_mpr_ctl.s.mpr_wr = 0; /* Read=0, Write=1 */ + //lmc_mr_mpr_ctl.s.mpr_bit_select = + //lmc_mr_mpr_ctl.s.mpr_byte_select = + //lmc_mr_mpr_ctl.s.mpr_whole_byte_enable = + //lmc_mr_mpr_ctl.s.mr_wr_use_default_value = + //lmc_mr_mpr_ctl.s.mr_wr_bg1 = + DRAM_CSR_WRITE(node, BDK_LMCX_MR_MPR_CTL(ddr_interface_num), lmc_mr_mpr_ctl.u); + + /* 0x8 = Mode Register Write */ + perform_octeon3_ddr3_sequence(node, 1<<rank, ddr_interface_num, 0x8); + + /* It is vendor specific whether Vref_value is captured with A7=1. + A subsequent MRS might be necessary. */ + perform_octeon3_ddr3_sequence(node, 1<<rank, ddr_interface_num, 0x8); + + mr_wr_addr &= ~(1<<7); /* A7 0 = Disable(Training Mode) */ + lmc_mr_mpr_ctl.s.mr_wr_addr = mr_wr_addr; + DRAM_CSR_WRITE(node, BDK_LMCX_MR_MPR_CTL(ddr_interface_num), lmc_mr_mpr_ctl.u); +} + +static void set_DRAM_output_inversion (bdk_node_t node, + int ddr_interface_num, + int dimm_count, + int rank_mask, + int inversion) +{ + bdk_lmcx_ddr4_dimm_ctl_t lmc_ddr4_dimm_ctl; + bdk_lmcx_dimmx_params_t lmc_dimmx_params; + bdk_lmcx_dimm_ctl_t lmc_dimm_ctl; + int dimm_no; + + lmc_ddr4_dimm_ctl.u = 0; /* Don't touch extended register control words */ + DRAM_CSR_WRITE(node, BDK_LMCX_DDR4_DIMM_CTL(ddr_interface_num), lmc_ddr4_dimm_ctl.u); + + ddr_print("All DIMMs: Register Control Word RC0 : %x\n", (inversion & 1)); + + for (dimm_no = 0; dimm_no < dimm_count; ++dimm_no) { + lmc_dimmx_params.u = BDK_CSR_READ(node, BDK_LMCX_DIMMX_PARAMS(ddr_interface_num, dimm_no)); + lmc_dimmx_params.s.rc0 = (lmc_dimmx_params.s.rc0 & ~1) | (inversion & 1); + DRAM_CSR_WRITE(node, BDK_LMCX_DIMMX_PARAMS(ddr_interface_num, dimm_no), lmc_dimmx_params.u); + } + + /* LMC0_DIMM_CTL */ + lmc_dimm_ctl.u = BDK_CSR_READ(node, BDK_LMCX_DIMM_CTL(ddr_interface_num)); + lmc_dimm_ctl.s.dimm0_wmask = 0x1; + lmc_dimm_ctl.s.dimm1_wmask = (dimm_count > 1) ? 0x0001 : 0x0000; + + ddr_print("LMC DIMM_CTL : 0x%016lx\n", + lmc_dimm_ctl.u); + DRAM_CSR_WRITE(node, BDK_LMCX_DIMM_CTL(ddr_interface_num), lmc_dimm_ctl.u); + + perform_octeon3_ddr3_sequence(node, rank_mask, ddr_interface_num, 0x7 ); /* Init RCW */ +} + +static void write_mpr_page0_pattern (bdk_node_t node, int rank_mask, + int ddr_interface_num, int dimm_count, int pattern, int location_mask) +{ + int rankx; + int location; + + for (rankx = 0; rankx < dimm_count*4; rankx++) { + if (!(rank_mask & (1 << rankx))) + continue; + for (location = 0; location < 4; ++location) { + if (!(location_mask & (1 << location))) + continue; + + ddr4_mpr_write(node, ddr_interface_num, rankx, + /* page */ 0, /* location */ location, pattern); + } + } +} + +static void change_rdimm_mpr_pattern (bdk_node_t node, int rank_mask, + int ddr_interface_num, int dimm_count) +{ + int save_ref_zqcs_int; + bdk_lmcx_config_t lmc_config; + + /* + Okay, here is the latest sequence. This should work for all + chips and passes (78,88,73,etc). This sequence should be run + immediately after DRAM INIT. The basic idea is to write the + same pattern into each of the 4 MPR locations in the DRAM, so + that the same value is returned when doing MPR reads regardless + of the inversion state. My advice is to put this into a + function, change_rdimm_mpr_pattern or something like that, so + that it can be called multiple times, as I think David wants a + clock-like pattern for OFFSET training, but does not want a + clock pattern for Bit-Deskew. You should then be able to call + this at any point in the init sequence (after DRAM init) to + change the pattern to a new value. + Mike + + A correction: PHY doesn't need any pattern during offset + training, but needs clock like pattern for internal vref and + bit-dskew training. So for that reason, these steps below have + to be conducted before those trainings to pre-condition + the pattern. David + + Note: Step 3, 4, 8 and 9 have to be done through RDIMM + sequence. If you issue MRW sequence to do RCW write (in o78 pass + 1 at least), LMC will still do two commands because + CONTROL[RDIMM_ENA] is still set high. We don't want it to have + any unintentional mode register write so it's best to do what + Mike is doing here. + Andrew + */ + + + /* 1) Disable refresh (REF_ZQCS_INT = 0) */ + + debug_print("1) Disable refresh (REF_ZQCS_INT = 0)\n"); + + lmc_config.u = BDK_CSR_READ(node, BDK_LMCX_CONFIG(ddr_interface_num)); + save_ref_zqcs_int = lmc_config.s.ref_zqcs_int; + lmc_config.s.ref_zqcs_int = 0; + DRAM_CSR_WRITE(node, BDK_LMCX_CONFIG(ddr_interface_num), lmc_config.u); + + + /* 2) Put all devices in MPR mode (Run MRW sequence (sequence=8) + with MODEREG_PARAMS0[MPRLOC]=0, + MODEREG_PARAMS0[MPR]=1, MR_MPR_CTL[MR_WR_SEL]=3, and + MR_MPR_CTL[MR_WR_USE_DEFAULT_VALUE]=1) */ + + debug_print("2) Put all devices in MPR mode (Run MRW sequence (sequence=8)\n"); + + set_mpr_mode(node, rank_mask, ddr_interface_num, dimm_count, /* mpr */ 1, /* bg1 */ 0); /* A-side */ + set_mpr_mode(node, rank_mask, ddr_interface_num, dimm_count, /* mpr */ 1, /* bg1 */ 1); /* B-side */ + + /* a. Or you can set MR_MPR_CTL[MR_WR_USE_DEFAULT_VALUE]=0 and set + the value you would like directly into + MR_MPR_CTL[MR_WR_ADDR] */ + + /* 3) Disable RCD Parity (if previously enabled) - parity does not + work if inversion disabled */ + + debug_print("3) Disable RCD Parity\n"); + + /* 4) Disable Inversion in the RCD. */ + /* a. I did (3&4) via the RDIMM sequence (seq_sel=7), but it + may be easier to use the MRW sequence (seq_sel=8). Just set + MR_MPR_CTL[MR_WR_SEL]=7, MR_MPR_CTL[MR_WR_ADDR][3:0]=data, + MR_MPR_CTL[MR_WR_ADDR][7:4]=RCD reg */ + + debug_print("4) Disable Inversion in the RCD.\n"); + + set_DRAM_output_inversion(node, ddr_interface_num, dimm_count, rank_mask, + 1 /* 1=disable output inversion*/); + + /* 5) Disable CONTROL[RDIMM_ENA] so that MR sequence goes out + non-inverted. */ + + debug_print("5) Disable CONTROL[RDIMM_ENA]\n"); + + set_rdimm_mode(node, ddr_interface_num, 0); + + /* 6) Write all 4 MPR registers with the desired pattern (have to + do this for all enabled ranks) */ + /* a. MR_MPR_CTL.MPR_WR=1, MR_MPR_CTL.MPR_LOC=0..3, + MR_MPR_CTL.MR_WR_SEL=0, MR_MPR_CTL.MR_WR_ADDR[7:0]=pattern */ + + debug_print("6) Write all 4 MPR page 0 Training Patterns\n"); + + write_mpr_page0_pattern(node, rank_mask, + ddr_interface_num, dimm_count, 0x55, 0x8); + + /* 7) Re-enable RDIMM_ENA */ + + debug_print("7) Re-enable RDIMM_ENA\n"); + + set_rdimm_mode(node, ddr_interface_num, 1); + + /* 8) Re-enable RDIMM inversion */ + + debug_print("8) Re-enable RDIMM inversion\n"); + + set_DRAM_output_inversion(node, ddr_interface_num, dimm_count, rank_mask, + 0 /* 0=re-enable output inversion*/); + + /* 9) Re-enable RDIMM parity (if desired) */ + + debug_print("9) Re-enable RDIMM parity (if desired)\n"); + + /* 10)Take B-side devices out of MPR mode (Run MRW sequence + (sequence=8) with MODEREG_PARAMS0[MPRLOC]=0, + MODEREG_PARAMS0[MPR]=0, MR_MPR_CTL[MR_WR_SEL]=3, and + MR_MPR_CTL[MR_WR_USE_DEFAULT_VALUE]=1) */ + + debug_print("10)Take B-side devices out of MPR mode\n"); + + set_mpr_mode(node, rank_mask, ddr_interface_num, dimm_count, /* mpr */ 0, /* bg1 */ 1); + + /* a. Or you can set MR_MPR_CTL[MR_WR_USE_DEFAULT_VALUE]=0 and + set the value you would like directly into + MR_MPR_CTL[MR_WR_ADDR] */ + + /* 11)Re-enable refresh (REF_ZQCS_INT=previous value) */ + + debug_print("11)Re-enable refresh (REF_ZQCS_INT=previous value)\n"); + + lmc_config.u = BDK_CSR_READ(node, BDK_LMCX_CONFIG(ddr_interface_num)); + lmc_config.s.ref_zqcs_int = save_ref_zqcs_int; + DRAM_CSR_WRITE(node, BDK_LMCX_CONFIG(ddr_interface_num), lmc_config.u); + +} + +static unsigned char ddr4_rodt_ohms [RODT_OHMS_COUNT ] = { 0, 40, 60, 80, 120, 240, 34, 48 }; +static unsigned char ddr4_rtt_nom_ohms [RTT_NOM_OHMS_COUNT ] = { 0, 60, 120, 40, 240, 48, 80, 34 }; +static unsigned char ddr4_rtt_nom_table [RTT_NOM_TABLE_COUNT ] = { 0, 4, 2, 6, 1, 5, 3, 7 }; +static unsigned char ddr4_rtt_wr_ohms [RTT_WR_OHMS_COUNT ] = { 0, 120, 240, 99, 80 }; // setting HiZ ohms to 99 for computed vref +static unsigned char ddr4_dic_ohms [DIC_OHMS_COUNT ] = { 34, 48 }; +static short ddr4_drive_strength[DRIVE_STRENGTH_COUNT] = { 0, 0, 26, 30, 34, 40, 48, 68, 0,0,0,0,0,0,0 }; +static short ddr4_dqx_strength [DRIVE_STRENGTH_COUNT] = { 0, 24, 27, 30, 34, 40, 48, 60, 0,0,0,0,0,0,0 }; + +impedence_values_t ddr4_impedence_values = { + .rodt_ohms = ddr4_rodt_ohms , + .rtt_nom_ohms = ddr4_rtt_nom_ohms , + .rtt_nom_table = ddr4_rtt_nom_table , + .rtt_wr_ohms = ddr4_rtt_wr_ohms , + .dic_ohms = ddr4_dic_ohms , + .drive_strength = ddr4_drive_strength, + .dqx_strength = ddr4_dqx_strength , +}; + +static unsigned char ddr3_rodt_ohms [RODT_OHMS_COUNT ] = { 0, 20, 30, 40, 60, 120, 0, 0 }; +static unsigned char ddr3_rtt_nom_ohms [RTT_NOM_OHMS_COUNT ] = { 0, 60, 120, 40, 20, 30, 0, 0 }; +static unsigned char ddr3_rtt_nom_table [RTT_NOM_TABLE_COUNT ] = { 0, 2, 1, 3, 5, 4, 0, 0 }; +static unsigned char ddr3_rtt_wr_ohms [RTT_WR_OHMS_COUNT ] = { 0, 60, 120 }; +static unsigned char ddr3_dic_ohms [DIC_OHMS_COUNT ] = { 40, 34 }; +static short ddr3_drive_strength[DRIVE_STRENGTH_COUNT] = { 0, 24, 27, 30, 34, 40, 48, 60, 0,0,0,0,0,0,0 }; +static impedence_values_t ddr3_impedence_values = { + .rodt_ohms = ddr3_rodt_ohms , + .rtt_nom_ohms = ddr3_rtt_nom_ohms , + .rtt_nom_table = ddr3_rtt_nom_table , + .rtt_wr_ohms = ddr3_rtt_wr_ohms , + .dic_ohms = ddr3_dic_ohms , + .drive_strength = ddr3_drive_strength, + .dqx_strength = ddr3_drive_strength, +}; + + +uint64_t +hertz_to_psecs(uint64_t hertz) +{ + return divide_nint((uint64_t) 1000*1000*1000*1000, hertz); /* Clock in psecs */ +} + +#define DIVIDEND_SCALE 1000 /* Scale to avoid rounding error. */ +uint64_t +psecs_to_mts(uint64_t psecs) +{ + //ddr_print("psecs %ld, divisor %ld\n", psecs, divide_nint((uint64_t)(2 * 1000000 * DIVIDEND_SCALE), psecs)); + return divide_nint(divide_nint((uint64_t)(2 * 1000000 * DIVIDEND_SCALE), psecs), DIVIDEND_SCALE); +} + +#define WITHIN(v,b,m) (((v)>=((b)-(m)))&&((v)<=((b)+(m)))) + +// pretty-print version, only works with what comes from the SPD: tCKmin or tCKAVGmin +unsigned long +pretty_psecs_to_mts(uint64_t psecs) +{ + uint64_t ret = 0; // default to error + if (WITHIN(psecs, 1250, 1)) + ret = 1600; + else if (WITHIN(psecs, 1071, 1)) + ret = 1866; + else if (WITHIN(psecs, 937, 1)) + ret = 2133; + else if (WITHIN(psecs, 833, 1)) + ret = 2400; + else if (WITHIN(psecs, 750, 1)) + ret = 2666; + return ret; +} + +uint64_t +mts_to_hertz(uint64_t mts) +{ + return ((mts * 1000 * 1000) / 2); +} + +#define DEBUG_RC3X_COMPUTE 0 +#define rc3x_print(...) \ + do { if (DEBUG_RC3X_COMPUTE) printf(__VA_ARGS__); } while (0) + +static int compute_rc3x (int64_t tclk_psecs) +{ + long speed; + long tclk_psecs_min, tclk_psecs_max; + long data_rate_mhz, data_rate_mhz_min, data_rate_mhz_max; + int rc3x; + +#define ENCODING_BASE 1240 + + data_rate_mhz = psecs_to_mts(tclk_psecs); + + /* 2400 MT/s is a special case. Using integer arithmetic it rounds + from 833 psecs to 2401 MT/s. Force it to 2400 to pick the + proper setting from the table. */ + if (tclk_psecs == 833) + data_rate_mhz = 2400; + + for (speed = ENCODING_BASE; speed < 3200; speed += 20) { + int error = 0; + + tclk_psecs_min = hertz_to_psecs(mts_to_hertz(speed + 00)); /* Clock in psecs */ + tclk_psecs_max = hertz_to_psecs(mts_to_hertz(speed + 18)); /* Clock in psecs */ + + data_rate_mhz_min = psecs_to_mts(tclk_psecs_min); + data_rate_mhz_max = psecs_to_mts(tclk_psecs_max); + + /* Force alingment to multiple to avound rounding errors. */ + data_rate_mhz_min = ((data_rate_mhz_min + 18) / 20) * 20; + data_rate_mhz_max = ((data_rate_mhz_max + 18) / 20) * 20; + + error += (speed + 00 != data_rate_mhz_min); + error += (speed + 20 != data_rate_mhz_max); + + rc3x = (speed - ENCODING_BASE) / 20; + + rc3x_print("rc3x: %02x speed: %4ld MT/s < f <= %4ld MT/s, psec: %3ld:%3ld %4ld:%4ld %s\n", + rc3x, + speed, speed + 20, + tclk_psecs_min, tclk_psecs_max, + data_rate_mhz_min, data_rate_mhz_max, + error ? "****" : ""); + + if (data_rate_mhz <= (speed + 20)) { + rc3x_print("rc3x: %4ld MT/s <= %4ld MT/s\n", data_rate_mhz, speed + 20); + break; + } + } + return rc3x; +} + +static const int rlevel_separate_ab = 1; + +int init_octeon3_ddr3_interface(bdk_node_t node, + const ddr_configuration_t *ddr_configuration, + uint32_t ddr_hertz, + uint32_t cpu_hertz, + uint32_t ddr_ref_hertz, + int board_type, + int board_rev_maj, + int board_rev_min, + int ddr_interface_num, + uint32_t ddr_interface_mask + ) +{ + const char *s; + + const dimm_odt_config_t *odt_1rank_config = ddr_configuration->odt_1rank_config; + const dimm_odt_config_t *odt_2rank_config = ddr_configuration->odt_2rank_config; + const dimm_odt_config_t *odt_4rank_config = ddr_configuration->odt_4rank_config; + const dimm_config_t *dimm_config_table = ddr_configuration->dimm_config_table; + const dimm_odt_config_t *odt_config; + const ddr3_custom_config_t *custom_lmc_config = &ddr_configuration->custom_lmc_config; + int odt_idx; + + /* + ** Compute clock rates to the nearest picosecond. + */ + uint64_t tclk_psecs = hertz_to_psecs(ddr_hertz); /* Clock in psecs */ + uint64_t eclk_psecs = hertz_to_psecs(cpu_hertz); /* Clock in psecs */ + + int row_bits, col_bits, num_banks, num_ranks, dram_width; + int dimm_count = 0; + int fatal_error = 0; /* Accumulate and report all the errors before giving up */ + + int safe_ddr_flag = 0; /* Flag that indicates safe DDR settings should be used */ + int ddr_interface_64b = 1; /* THUNDER Default: 64bit interface width */ + int ddr_interface_bytemask; + uint32_t mem_size_mbytes = 0; + unsigned int didx; + int bank_bits = 0; + int bunk_enable; + int rank_mask; + int column_bits_start = 1; + int row_lsb; + int pbank_lsb; + int use_ecc = 1; + int mtb_psec = 0; /* quiet */ + short ftb_Dividend; + short ftb_Divisor; + int tAAmin; + int tCKmin; + int CL, min_cas_latency = 0, max_cas_latency = 0, override_cas_latency = 0; + int ddr_rtt_nom_auto, ddr_rodt_ctl_auto; + int i; + + int spd_addr; + int spd_org; + int spd_banks; + int spd_rdimm; + int spd_dimm_type; + int spd_ecc; + uint32_t spd_cas_latency; + int spd_mtb_dividend; + int spd_mtb_divisor; + int spd_tck_min; + int spd_taa_min; + int spd_twr; + int spd_trcd; + int spd_trrd; + int spd_trp; + int spd_tras; + int spd_trc; + int spd_trfc; + int spd_twtr; + int spd_trtp; + int spd_tfaw; + int spd_addr_mirror; + int spd_package = 0; + int spd_rawcard = 0; + int spd_rawcard_AorB = 0; + int is_stacked_die = 0; + int disable_stacked_die = 0; + int is_3ds_dimm = 0; // 3DS + int lranks_per_prank = 1; // 3DS: logical ranks per package rank + int lranks_bits = 0; // 3DS: logical ranks bits + int die_capacity = 0; // in Mbits; only used for 3DS + + /* FTB values are two's complement ranging from +127 to -128. */ + typedef signed char SC_t; + + int twr; + int trcd; + int trrd; + int trp; + int tras; + int trc; + int trfc; + int twtr; + int trtp = 0; /* quiet */ + int tfaw; + + int wlevel_bitmask_errors = 0; + int wlevel_loops; + int default_rtt_nom[4]; + int dyn_rtt_nom_mask = 0; + + ddr_type_t ddr_type; + int ddr4_tCKAVGmin = 0; /* quiet */ + int ddr4_tCKAVGmax = 0; /* quiet */ + int ddr4_tRCDmin = 0; /* quiet */ + int ddr4_tRPmin = 0; /* quiet */ + int ddr4_tRASmin = 0; /* quiet */ + int ddr4_tRCmin = 0; /* quiet */ + int ddr4_tRFC1min = 0; /* quiet */ + int ddr4_tRFC2min = 0; /* quiet */ + int ddr4_tRFC4min = 0; /* quiet */ + int ddr4_tFAWmin = 0; /* quiet */ + int ddr4_tRRD_Smin = 0; /* quiet */ + int ddr4_tRRD_Lmin; + int ddr4_tCCD_Lmin; + impedence_values_t *imp_values; + int default_rodt_ctl; + // default to disabled (ie, LMC restart, not chip reset) + int ddr_disable_chip_reset = 1; + int disable_deskew_training = 0; + const char *dimm_type_name; + + /* Allow the Write bit-deskew feature to be enabled when desired. */ + // NOTE: THUNDER pass 2.x only, 81xx, 83xx + int enable_write_deskew = ENABLE_WRITE_DESKEW_DEFAULT; + +#if SWL_TRY_HWL_ALT + typedef struct { + uint16_t hwl_alt_mask; // mask of bytelanes with alternate + uint16_t hwl_alt_delay[9]; // bytelane alternate avail if mask=1 + } hwl_alt_by_rank_t; + hwl_alt_by_rank_t hwl_alts[4]; + memset(hwl_alts, 0, sizeof(hwl_alts)); +#endif /* SWL_TRY_HWL_ALT */ + + bdk_lmcx_config_t lmc_config; + + /* Initialize these to shut up the compiler. They are configured + and used only for DDR4 */ + ddr4_tRRD_Lmin = 6000; + ddr4_tCCD_Lmin = 6000; + + ddr_print("\nInitializing node %d DDR interface %d, DDR Clock %d, DDR Reference Clock %d\n", + node, ddr_interface_num, ddr_hertz, ddr_ref_hertz); + + if (dimm_config_table[0].spd_addr == 0 && !dimm_config_table[0].spd_ptr) { + error_print("ERROR: No dimms specified in the dimm_config_table.\n"); + return (-1); + } + + // allow some overrides to be done + + // this one controls whether chip RESET is done, or LMC init restarted from step 6.9.6 + if ((s = lookup_env_parameter("ddr_disable_chip_reset")) != NULL) { + ddr_disable_chip_reset = !!strtoul(s, NULL, 0); + } + // this one controls whether Deskew Training is performed + if ((s = lookup_env_parameter("ddr_disable_deskew_training")) != NULL) { + disable_deskew_training = !!strtoul(s, NULL, 0); + } + // this one is in Validate_Read_Deskew_Training and controls a preliminary delay + if ((s = lookup_env_parameter("ddr_deskew_validation_delay")) != NULL) { + deskew_validation_delay = strtoul(s, NULL, 0); + } + // this one is in Perform_Read_Deskew_Training and controls lock retries + if ((s = lookup_env_parameter("ddr_lock_retries")) != NULL) { + default_lock_retry_limit = strtoul(s, NULL, 0); + } + // this one controls whether stacked die status can affect processing + // disabling it will affect computed vref adjustment, and rodt_row_skip_mask + if ((s = lookup_env_parameter("ddr_disable_stacked_die")) != NULL) { + disable_stacked_die = !!strtoul(s, NULL, 0); + } + + // setup/override for write bit-deskew feature + if (! CAVIUM_IS_MODEL(CAVIUM_CN88XX_PASS1_X)) { // added 81xx and 83xx + // FIXME: allow override + if ((s = lookup_env_parameter("ddr_enable_write_deskew")) != NULL) { + enable_write_deskew = !!strtoul(s, NULL, 0); + } // else take default setting + } else { // not pass 2.x + enable_write_deskew = 0; // force disabled + } + +#if 0 // FIXME: do we really need this anymore? + if (dram_is_verbose(VBL_NORM)) { + printf("DDR SPD Table:"); + for (didx = 0; didx < DDR_CFG_T_MAX_DIMMS; ++didx) { + if (dimm_config_table[didx].spd_addr == 0) break; + printf(" --ddr%dspd=0x%02x", ddr_interface_num, dimm_config_table[didx].spd_addr); + } + printf("\n"); + } +#endif + + /* + ** Walk the DRAM Socket Configuration Table to see what is installed. + */ + for (didx = 0; didx < DDR_CFG_T_MAX_DIMMS; ++didx) + { + /* Check for lower DIMM socket populated */ + if (validate_dimm(node, &dimm_config_table[didx]) == 1) { + // NOTE: DIMM info printing is now done later when more details are available + ++dimm_count; + } else { break; } /* Finished when there is no lower DIMM */ + } + + + initialize_ddr_clock(node, + ddr_configuration, + cpu_hertz, + ddr_hertz, + ddr_ref_hertz, + ddr_interface_num, + ddr_interface_mask); + + if (!odt_1rank_config) + odt_1rank_config = disable_odt_config; + if (!odt_2rank_config) + odt_2rank_config = disable_odt_config; + if (!odt_4rank_config) + odt_4rank_config = disable_odt_config; + + if ((s = lookup_env_parameter("ddr_safe")) != NULL) { + safe_ddr_flag = !!strtoul(s, NULL, 0); + } + + + if (dimm_count == 0) { + error_print("ERROR: DIMM 0 not detected.\n"); + return(-1); + } + + // look for 32-bit mode specified in the config + if (custom_lmc_config->mode32b) { + ddr_interface_64b = 0; + } + + if (ddr_interface_64b == 0) { // check if 32-bit mode is bad + if (!CAVIUM_IS_MODEL(CAVIUM_CN81XX)) { + error_print("32-bit interface width is NOT supported for this Thunder model\n"); + ddr_interface_64b = 1; // force to 64-bit + } + } else { // check if 64-bit mode is bad + if (CAVIUM_IS_MODEL(CAVIUM_CN81XX)) { // check the fuses on 81XX for forced 32-bit mode + BDK_CSR_INIT(mio_fus_dat2, node, BDK_MIO_FUS_DAT2); + if (mio_fus_dat2.s.lmc_mode32) { + error_print("32-bit interface width is ONLY supported for this Thunder model\n"); + ddr_interface_64b = 0; // force to 32-bit + } + } + } + + // finally, say we are in 32-bit mode when it has been validated + if (ddr_interface_64b == 0) { + ddr_print("N%d.LMC%d: Setting 32-bit data width\n", + node, ddr_interface_num); + } + + /* ddr_type only indicates DDR4 or DDR3 */ + ddr_type = get_ddr_type(node, &dimm_config_table[0]); + debug_print("DRAM Device Type: DDR%d\n", ddr_type); + + spd_dimm_type = get_dimm_module_type(node, &dimm_config_table[0], ddr_type); + + if (ddr_type == DDR4_DRAM) { + int spd_module_type; + int asymmetric; + const char *signal_load[4] = {"", "MLS", "3DS", "RSV"}; + + imp_values = &ddr4_impedence_values; + dimm_type_name = ddr4_dimm_types[spd_dimm_type]; + + spd_addr = read_spd(node, &dimm_config_table[0], DDR4_SPD_ADDRESSING_ROW_COL_BITS); + spd_org = read_spd(node, &dimm_config_table[0], DDR4_SPD_MODULE_ORGANIZATION); + spd_banks = 0xFF & read_spd(node, &dimm_config_table[0], DDR4_SPD_DENSITY_BANKS); + + bank_bits = (2 + ((spd_banks >> 4) & 0x3)) + ((spd_banks >> 6) & 0x3); + bank_bits = min((int)bank_bits, 4); /* Controller can only address 4 bits. */ + + spd_package = 0XFF & read_spd(node, &dimm_config_table[0], DDR4_SPD_PACKAGE_TYPE); + if (spd_package & 0x80) { // non-monolithic device + is_stacked_die = (!disable_stacked_die) ? ((spd_package & 0x73) == 0x11) : 0; + ddr_print("DDR4: Package Type 0x%x (%s), %d die\n", spd_package, + signal_load[(spd_package & 3)], ((spd_package >> 4) & 7) + 1); + is_3ds_dimm = ((spd_package & 3) == 2); // is it 3DS? + if (is_3ds_dimm) { // is it 3DS? + lranks_per_prank = ((spd_package >> 4) & 7) + 1; + // FIXME: should make sure it is only 2H or 4H or 8H? + lranks_bits = lranks_per_prank >> 1; + if (lranks_bits == 4) lranks_bits = 3; + } + } else if (spd_package != 0) { + // FIXME: print non-zero monolithic device definition + ddr_print("DDR4: Package Type MONOLITHIC: %d die, signal load %d\n", + ((spd_package >> 4) & 7) + 1, (spd_package & 3)); + } + + asymmetric = (spd_org >> 6) & 1; + if (asymmetric) { + int spd_secondary_pkg = read_spd(node, &dimm_config_table[0], + DDR4_SPD_SECONDARY_PACKAGE_TYPE); + ddr_print("DDR4: Module Organization: ASYMMETRICAL: Secondary Package Type 0x%x\n", + spd_secondary_pkg); + } else { + uint64_t bus_width = 8 << (0x07 & read_spd(node, &dimm_config_table[0], + DDR4_SPD_MODULE_MEMORY_BUS_WIDTH)); + uint64_t ddr_width = 4 << ((spd_org >> 0) & 0x7); + uint64_t module_cap; + int shift = (spd_banks & 0x0F); + die_capacity = (shift < 8) ? (256UL << shift) : ((12UL << (shift & 1)) << 10); + ddr_print("DDR4: Module Organization: SYMMETRICAL: capacity per die %d %cbit\n", + (die_capacity > 512) ? (die_capacity >> 10) : die_capacity, + (die_capacity > 512) ? 'G' : 'M'); + module_cap = ((uint64_t)die_capacity << 20) / 8UL * bus_width / ddr_width * + /* no. pkg ranks*/(1UL + ((spd_org >> 3) & 0x7)); + if (is_3ds_dimm) // is it 3DS? + module_cap *= /* die_count */(uint64_t)(((spd_package >> 4) & 7) + 1); + ddr_print("DDR4: Module Organization: SYMMETRICAL: capacity per module %ld GB\n", + module_cap >> 30); + } + + spd_rawcard = 0xFF & read_spd(node, &dimm_config_table[0], DDR4_SPD_REFERENCE_RAW_CARD); + ddr_print("DDR4: Reference Raw Card 0x%x \n", spd_rawcard); + + spd_module_type = read_spd(node, &dimm_config_table[0], DDR4_SPD_KEY_BYTE_MODULE_TYPE); + if (spd_module_type & 0x80) { // HYBRID module + ddr_print("DDR4: HYBRID module, type %s\n", + ((spd_module_type & 0x70) == 0x10) ? "NVDIMM" : "UNKNOWN"); + } + + spd_dimm_type = spd_module_type & 0x0F; + spd_rdimm = (spd_dimm_type == 1) || (spd_dimm_type == 5) || (spd_dimm_type == 8); + if (spd_rdimm) { + int spd_mfgr_id = read_spd(node, &dimm_config_table[0], DDR4_SPD_REGISTER_MANUFACTURER_ID_LSB) | + (read_spd(node, &dimm_config_table[0], DDR4_SPD_REGISTER_MANUFACTURER_ID_MSB) << 8); + int spd_register_rev = read_spd(node, &dimm_config_table[0], DDR4_SPD_REGISTER_REVISION_NUMBER); + ddr_print("DDR4: RDIMM Register Manufacturer ID 0x%x Revision 0x%x\n", + spd_mfgr_id, spd_register_rev); + + // RAWCARD A or B must be bit 7=0 and bits 4-0 either 00000(A) or 00001(B) + spd_rawcard_AorB = ((spd_rawcard & 0x9fUL) <= 1); + } + } else { + imp_values = &ddr3_impedence_values; + dimm_type_name = ddr3_dimm_types[spd_dimm_type]; + + spd_addr = read_spd(node, &dimm_config_table[0], DDR3_SPD_ADDRESSING_ROW_COL_BITS); + spd_org = read_spd(node, &dimm_config_table[0], DDR3_SPD_MODULE_ORGANIZATION); + spd_banks = read_spd(node, &dimm_config_table[0], DDR3_SPD_DENSITY_BANKS) & 0xff; + + bank_bits = 3 + ((spd_banks >> 4) & 0x7); + bank_bits = min((int)bank_bits, 3); /* Controller can only address 3 bits. */ + + spd_rdimm = (spd_dimm_type == 1) || (spd_dimm_type == 5) || (spd_dimm_type == 9); + } + +#if 0 // FIXME: why should this be possible OR needed? + if ((s = lookup_env_parameter("ddr_rdimm_ena")) != NULL) { + spd_rdimm = !!strtoul(s, NULL, 0); + } +#endif + + debug_print("spd_addr : %#06x\n", spd_addr ); + debug_print("spd_org : %#06x\n", spd_org ); + debug_print("spd_banks : %#06x\n", spd_banks ); + + row_bits = 12 + ((spd_addr >> 3) & 0x7); + col_bits = 9 + ((spd_addr >> 0) & 0x7); + + num_ranks = 1 + ((spd_org >> 3) & 0x7); + dram_width = 4 << ((spd_org >> 0) & 0x7); + num_banks = 1 << bank_bits; + + if ((s = lookup_env_parameter("ddr_num_ranks")) != NULL) { + num_ranks = strtoul(s, NULL, 0); + } + + /* FIX + ** Check that values are within some theoretical limits. + ** col_bits(min) = row_lsb(min) - bank_bits(max) - bus_bits(max) = 14 - 3 - 4 = 7 + ** col_bits(max) = row_lsb(max) - bank_bits(min) - bus_bits(min) = 18 - 2 - 3 = 13 + */ + if ((col_bits > 13) || (col_bits < 7)) { + error_print("Unsupported number of Col Bits: %d\n", col_bits); + ++fatal_error; + } + + /* FIX + ** Check that values are within some theoretical limits. + ** row_bits(min) = pbank_lsb(min) - row_lsb(max) - rank_bits = 26 - 18 - 1 = 7 + ** row_bits(max) = pbank_lsb(max) - row_lsb(min) - rank_bits = 33 - 14 - 1 = 18 + */ + if ((row_bits > 18) || (row_bits < 7)) { + error_print("Unsupported number of Row Bits: %d\n", row_bits); + ++fatal_error; + } + + if (bdk_is_platform(BDK_PLATFORM_ASIM)) + wlevel_loops = 0; + else { + wlevel_loops = WLEVEL_LOOPS_DEFAULT; + // accept generic or interface-specific override but not for ASIM... + if ((s = lookup_env_parameter("ddr_wlevel_loops")) == NULL) + s = lookup_env_parameter("ddr%d_wlevel_loops", ddr_interface_num); + if (s != NULL) { + wlevel_loops = strtoul(s, NULL, 0); + } + } + + bunk_enable = (num_ranks > 1); + + column_bits_start = 3; + + row_lsb = column_bits_start + col_bits + bank_bits - (! ddr_interface_64b); + debug_print("row_lsb = column_bits_start + col_bits + bank_bits = %d\n", row_lsb); + + pbank_lsb = row_lsb + row_bits + bunk_enable; + debug_print("pbank_lsb = row_lsb + row_bits + bunk_enable = %d\n", pbank_lsb); + + if (lranks_per_prank > 1) { + pbank_lsb = row_lsb + row_bits + lranks_bits + bunk_enable; + ddr_print("DDR4: 3DS: pbank_lsb = (%d row_lsb) + (%d row_bits) + (%d lranks_bits) + (%d bunk_enable) = %d\n", + row_lsb, row_bits, lranks_bits, bunk_enable, pbank_lsb); + } + + mem_size_mbytes = dimm_count * ((1ull << pbank_lsb) >> 20); + if (num_ranks == 4) { + /* Quad rank dimm capacity is equivalent to two dual-rank dimms. */ + mem_size_mbytes *= 2; + } + + /* Mask with 1 bits set for for each active rank, allowing 2 bits per dimm. + ** This makes later calculations simpler, as a variety of CSRs use this layout. + ** This init needs to be updated for dual configs (ie non-identical DIMMs). + ** Bit 0 = dimm0, rank 0 + ** Bit 1 = dimm0, rank 1 + ** Bit 2 = dimm1, rank 0 + ** Bit 3 = dimm1, rank 1 + ** ... + */ + rank_mask = 0x1; + if (num_ranks > 1) + rank_mask = 0x3; + if (num_ranks > 2) + rank_mask = 0xf; + + for (i = 1; i < dimm_count; i++) + rank_mask |= ((rank_mask & 0x3) << (2*i)); + + +#ifdef CAVIUM_ONLY + /* Special request: mismatched DIMM support. Slot 0: 2-Rank, Slot 1: 1-Rank */ + if (0) + { + /* + ** Calculate the total memory size in terms of the total + ** number of ranks instead of the number of dimms. The usual + ** requirement is for both dimms to be identical. This check + ** works around that requirement to allow one exception. The + ** dimm in the second slot may now have fewer ranks than the + ** first slot. + */ + int spd_org_dimm1; + int num_ranks_dimm1; + int rank_count; + int rank_mask_dimm1; + + if (dimm_count > 1) { + spd_org_dimm1 = read_spd(node, &dimm_config_table[1] /* dimm 1*/, + DDR3_SPD_MODULE_ORGANIZATION); + num_ranks_dimm1 = 1 + ((spd_org_dimm1 >> 3) & 0x7); + rank_count = num_ranks/* dimm 0 */ + num_ranks_dimm1 /* dimm 1 */; + + if (num_ranks != num_ranks_dimm1) { + mem_size_mbytes = rank_count * ((1ull << (pbank_lsb-bunk_enable)) >> 20); + rank_mask = 1 | ((num_ranks > 1) << 1); + rank_mask_dimm1 = 1 | ((num_ranks_dimm1 > 1) << 1); + rank_mask |= ((rank_mask_dimm1 & 0x3) << 2); + ddr_print("DIMM 1 - ranks: %d, size: %d MB\n", + num_ranks_dimm1, num_ranks_dimm1 * ((1ull << (pbank_lsb-bunk_enable)) >> 20)); + } + } + } +#endif /* CAVIUM_ONLY */ + + spd_ecc = get_dimm_ecc(node, &dimm_config_table[0], ddr_type); + + VB_PRT(VBL_DEV, "Summary: - %d %s%s %dRx%d %s, row bits=%d, col bits=%d, bank bits=%d\n", + dimm_count, dimm_type_name, (dimm_count > 1) ? "s" : "", + num_ranks, dram_width, (spd_ecc) ? "ECC" : "non-ECC", + row_bits, col_bits, bank_bits); + + // always print out the useful DIMM information... + for (i = 0; i < DDR_CFG_T_MAX_DIMMS; i++) { + if (i < dimm_count) + report_dimm(node, &dimm_config_table[i], i, ddr_interface_num, + num_ranks, dram_width, mem_size_mbytes / dimm_count); + else + if (validate_dimm(node, &dimm_config_table[i]) == 0) // only if there is a slot + printf("N%d.LMC%d.DIMM%d: Not Present\n", node, ddr_interface_num, i); + } + + if (ddr_type == DDR4_DRAM) { + spd_cas_latency = ((0xff & read_spd(node, &dimm_config_table[0], DDR4_SPD_CAS_LATENCIES_BYTE0)) << 0); + spd_cas_latency |= ((0xff & read_spd(node, &dimm_config_table[0], DDR4_SPD_CAS_LATENCIES_BYTE1)) << 8); + spd_cas_latency |= ((0xff & read_spd(node, &dimm_config_table[0], DDR4_SPD_CAS_LATENCIES_BYTE2)) << 16); + spd_cas_latency |= ((0xff & read_spd(node, &dimm_config_table[0], DDR4_SPD_CAS_LATENCIES_BYTE3)) << 24); + } else { + spd_cas_latency = 0xff & read_spd(node, &dimm_config_table[0], DDR3_SPD_CAS_LATENCIES_LSB); + spd_cas_latency |= ((0xff & read_spd(node, &dimm_config_table[0], DDR3_SPD_CAS_LATENCIES_MSB)) << 8); + } + debug_print("spd_cas_latency : %#06x\n", spd_cas_latency ); + + if (ddr_type == DDR4_DRAM) { + + /* No other values for DDR4 MTB and FTB are specified at the + * current time so don't bother reading them. Can't speculate how + * new values will be represented. + */ + int spdMTB = 125; + int spdFTB = 1; + + tAAmin + = spdMTB * read_spd(node, &dimm_config_table[0], DDR4_SPD_MIN_CAS_LATENCY_TAAMIN) + + spdFTB * (SC_t) read_spd(node, &dimm_config_table[0], DDR4_SPD_MIN_CAS_LATENCY_FINE_TAAMIN); + + ddr4_tCKAVGmin + = spdMTB * read_spd(node, &dimm_config_table[0], DDR4_SPD_MINIMUM_CYCLE_TIME_TCKAVGMIN) + + spdFTB * (SC_t) read_spd(node, &dimm_config_table[0], DDR4_SPD_MIN_CYCLE_TIME_FINE_TCKAVGMIN); + + ddr4_tCKAVGmax + = spdMTB * read_spd(node, &dimm_config_table[0], DDR4_SPD_MAXIMUM_CYCLE_TIME_TCKAVGMAX) + + spdFTB * (SC_t) read_spd(node, &dimm_config_table[0], DDR4_SPD_MAX_CYCLE_TIME_FINE_TCKAVGMAX); + + ddr4_tRCDmin + = spdMTB * read_spd(node, &dimm_config_table[0], DDR4_SPD_MIN_RAS_CAS_DELAY_TRCDMIN) + + spdFTB * (SC_t) read_spd(node, &dimm_config_table[0], DDR4_SPD_MIN_RAS_TO_CAS_DELAY_FINE_TRCDMIN); + + ddr4_tRPmin + = spdMTB * read_spd(node, &dimm_config_table[0], DDR4_SPD_MIN_ROW_PRECHARGE_DELAY_TRPMIN) + + spdFTB * (SC_t) read_spd(node, &dimm_config_table[0], DDR4_SPD_MIN_ROW_PRECHARGE_DELAY_FINE_TRPMIN); + + ddr4_tRASmin + = spdMTB * (((read_spd(node, &dimm_config_table[0], DDR4_SPD_UPPER_NIBBLES_TRAS_TRC) & 0xf) << 8) + + ( read_spd(node, &dimm_config_table[0], DDR4_SPD_MIN_ACTIVE_PRECHARGE_LSB_TRASMIN) & 0xff)); + + ddr4_tRCmin + = spdMTB * ((((read_spd(node, &dimm_config_table[0], DDR4_SPD_UPPER_NIBBLES_TRAS_TRC) >> 4) & 0xf) << 8) + + ( read_spd(node, &dimm_config_table[0], DDR4_SPD_MIN_ACTIVE_REFRESH_LSB_TRCMIN) & 0xff)) + + spdFTB * (SC_t) read_spd(node, &dimm_config_table[0], DDR4_SPD_MIN_ACT_TO_ACT_REFRESH_DELAY_FINE_TRCMIN); + + ddr4_tRFC1min + = spdMTB * (((read_spd(node, &dimm_config_table[0], DDR4_SPD_MIN_REFRESH_RECOVERY_MSB_TRFC1MIN) & 0xff) << 8) + + ( read_spd(node, &dimm_config_table[0], DDR4_SPD_MIN_REFRESH_RECOVERY_LSB_TRFC1MIN) & 0xff)); + + ddr4_tRFC2min + = spdMTB * (((read_spd(node, &dimm_config_table[0], DDR4_SPD_MIN_REFRESH_RECOVERY_MSB_TRFC2MIN) & 0xff) << 8) + + ( read_spd(node, &dimm_config_table[0], DDR4_SPD_MIN_REFRESH_RECOVERY_LSB_TRFC2MIN) & 0xff)); + + ddr4_tRFC4min + = spdMTB * (((read_spd(node, &dimm_config_table[0], DDR4_SPD_MIN_REFRESH_RECOVERY_MSB_TRFC4MIN) & 0xff) << 8) + + ( read_spd(node, &dimm_config_table[0], DDR4_SPD_MIN_REFRESH_RECOVERY_LSB_TRFC4MIN) & 0xff)); + + ddr4_tFAWmin + = spdMTB * (((read_spd(node, &dimm_config_table[0], DDR4_SPD_MIN_FOUR_ACTIVE_WINDOW_MSN_TFAWMIN) & 0xf) << 8) + + ( read_spd(node, &dimm_config_table[0], DDR4_SPD_MIN_FOUR_ACTIVE_WINDOW_LSB_TFAWMIN) & 0xff)); + + ddr4_tRRD_Smin + = spdMTB * read_spd(node, &dimm_config_table[0], DDR4_SPD_MIN_ROW_ACTIVE_DELAY_SAME_TRRD_SMIN) + + spdFTB * (SC_t) read_spd(node, &dimm_config_table[0], DDR4_SPD_MIN_ACT_TO_ACT_DELAY_DIFF_FINE_TRRD_SMIN); + + ddr4_tRRD_Lmin + = spdMTB * read_spd(node, &dimm_config_table[0], DDR4_SPD_MIN_ROW_ACTIVE_DELAY_DIFF_TRRD_LMIN) + + spdFTB * (SC_t) read_spd(node, &dimm_config_table[0], DDR4_SPD_MIN_ACT_TO_ACT_DELAY_SAME_FINE_TRRD_LMIN); + + ddr4_tCCD_Lmin + = spdMTB * read_spd(node, &dimm_config_table[0], DDR4_SPD_MIN_CAS_TO_CAS_DELAY_TCCD_LMIN) + + spdFTB * (SC_t) read_spd(node, &dimm_config_table[0], DDR4_SPD_MIN_CAS_TO_CAS_DELAY_FINE_TCCD_LMIN); + + ddr_print("%-45s : %6d ps\n", "Medium Timebase (MTB)", spdMTB); + ddr_print("%-45s : %6d ps\n", "Fine Timebase (FTB)", spdFTB); + + #define DDR4_TWR 15000 + #define DDR4_TWTR_S 2500 + + + tCKmin = ddr4_tCKAVGmin; + twr = DDR4_TWR; + trcd = ddr4_tRCDmin; + trrd = ddr4_tRRD_Smin; + trp = ddr4_tRPmin; + tras = ddr4_tRASmin; + trc = ddr4_tRCmin; + trfc = ddr4_tRFC1min; + twtr = DDR4_TWTR_S; + tfaw = ddr4_tFAWmin; + + if (spd_rdimm) { + spd_addr_mirror = read_spd(node, &dimm_config_table[0], DDR4_SPD_RDIMM_ADDR_MAPPING_FROM_REGISTER_TO_DRAM) & 0x1; + } else { + spd_addr_mirror = read_spd(node, &dimm_config_table[0], DDR4_SPD_UDIMM_ADDR_MAPPING_FROM_EDGE) & 0x1; + } + debug_print("spd_addr_mirror : %#06x\n", spd_addr_mirror ); + + } else { /* if (ddr_type == DDR4_DRAM) */ + spd_mtb_dividend = 0xff & read_spd(node, &dimm_config_table[0], DDR3_SPD_MEDIUM_TIMEBASE_DIVIDEND); + spd_mtb_divisor = 0xff & read_spd(node, &dimm_config_table[0], DDR3_SPD_MEDIUM_TIMEBASE_DIVISOR); + spd_tck_min = 0xff & read_spd(node, &dimm_config_table[0], DDR3_SPD_MINIMUM_CYCLE_TIME_TCKMIN); + spd_taa_min = 0xff & read_spd(node, &dimm_config_table[0], DDR3_SPD_MIN_CAS_LATENCY_TAAMIN); + + spd_twr = 0xff & read_spd(node, &dimm_config_table[0], DDR3_SPD_MIN_WRITE_RECOVERY_TWRMIN); + spd_trcd = 0xff & read_spd(node, &dimm_config_table[0], DDR3_SPD_MIN_RAS_CAS_DELAY_TRCDMIN); + spd_trrd = 0xff & read_spd(node, &dimm_config_table[0], DDR3_SPD_MIN_ROW_ACTIVE_DELAY_TRRDMIN); + spd_trp = 0xff & read_spd(node, &dimm_config_table[0], DDR3_SPD_MIN_ROW_PRECHARGE_DELAY_TRPMIN); + spd_tras = 0xff & read_spd(node, &dimm_config_table[0], DDR3_SPD_MIN_ACTIVE_PRECHARGE_LSB_TRASMIN); + spd_tras |= ((0xff & read_spd(node, &dimm_config_table[0], DDR3_SPD_UPPER_NIBBLES_TRAS_TRC)&0xf) << 8); + spd_trc = 0xff & read_spd(node, &dimm_config_table[0], DDR3_SPD_MIN_ACTIVE_REFRESH_LSB_TRCMIN); + spd_trc |= ((0xff & read_spd(node, &dimm_config_table[0], DDR3_SPD_UPPER_NIBBLES_TRAS_TRC)&0xf0) << 4); + spd_trfc = 0xff & read_spd(node, &dimm_config_table[0], DDR3_SPD_MIN_REFRESH_RECOVERY_LSB_TRFCMIN); + spd_trfc |= ((0xff & read_spd(node, &dimm_config_table[0], DDR3_SPD_MIN_REFRESH_RECOVERY_MSB_TRFCMIN)) << 8); + spd_twtr = 0xff & read_spd(node, &dimm_config_table[0], DDR3_SPD_MIN_INTERNAL_WRITE_READ_CMD_TWTRMIN); + spd_trtp = 0xff & read_spd(node, &dimm_config_table[0], DDR3_SPD_MIN_INTERNAL_READ_PRECHARGE_CMD_TRTPMIN); + spd_tfaw = 0xff & read_spd(node, &dimm_config_table[0], DDR3_SPD_MIN_FOUR_ACTIVE_WINDOW_TFAWMIN); + spd_tfaw |= ((0xff & read_spd(node, &dimm_config_table[0], DDR3_SPD_UPPER_NIBBLE_TFAW)&0xf) << 8); + spd_addr_mirror = 0xff & read_spd(node, &dimm_config_table[0], DDR3_SPD_ADDRESS_MAPPING) & 0x1; + spd_addr_mirror = spd_addr_mirror && !spd_rdimm; /* Only address mirror unbuffered dimms. */ + ftb_Dividend = read_spd(node, &dimm_config_table[0], DDR3_SPD_FINE_TIMEBASE_DIVIDEND_DIVISOR) >> 4; + ftb_Divisor = read_spd(node, &dimm_config_table[0], DDR3_SPD_FINE_TIMEBASE_DIVIDEND_DIVISOR) & 0xf; + ftb_Divisor = (ftb_Divisor == 0) ? 1 : ftb_Divisor; /* Make sure that it is not 0 */ + + debug_print("spd_twr : %#06x\n", spd_twr ); + debug_print("spd_trcd : %#06x\n", spd_trcd); + debug_print("spd_trrd : %#06x\n", spd_trrd); + debug_print("spd_trp : %#06x\n", spd_trp ); + debug_print("spd_tras : %#06x\n", spd_tras); + debug_print("spd_trc : %#06x\n", spd_trc ); + debug_print("spd_trfc : %#06x\n", spd_trfc); + debug_print("spd_twtr : %#06x\n", spd_twtr); + debug_print("spd_trtp : %#06x\n", spd_trtp); + debug_print("spd_tfaw : %#06x\n", spd_tfaw); + debug_print("spd_addr_mirror : %#06x\n", spd_addr_mirror); + + mtb_psec = spd_mtb_dividend * 1000 / spd_mtb_divisor; + tAAmin = mtb_psec * spd_taa_min; + tAAmin += ftb_Dividend * (SC_t) read_spd(node, &dimm_config_table[0], DDR3_SPD_MIN_CAS_LATENCY_FINE_TAAMIN) / ftb_Divisor; + tCKmin = mtb_psec * spd_tck_min; + tCKmin += ftb_Dividend * (SC_t) read_spd(node, &dimm_config_table[0], DDR3_SPD_MINIMUM_CYCLE_TIME_FINE_TCKMIN) / ftb_Divisor; + + twr = spd_twr * mtb_psec; + trcd = spd_trcd * mtb_psec; + trrd = spd_trrd * mtb_psec; + trp = spd_trp * mtb_psec; + tras = spd_tras * mtb_psec; + trc = spd_trc * mtb_psec; + trfc = spd_trfc * mtb_psec; + twtr = spd_twtr * mtb_psec; + trtp = spd_trtp * mtb_psec; + tfaw = spd_tfaw * mtb_psec; + + } /* if (ddr_type == DDR4_DRAM) */ + + if (ddr_type == DDR4_DRAM) { + ddr_print("%-45s : %6d ps (%ld MT/s)\n", "SDRAM Minimum Cycle Time (tCKAVGmin)",ddr4_tCKAVGmin, + pretty_psecs_to_mts(ddr4_tCKAVGmin)); + ddr_print("%-45s : %6d ps\n", "SDRAM Maximum Cycle Time (tCKAVGmax)", ddr4_tCKAVGmax); + ddr_print("%-45s : %6d ps\n", "Minimum CAS Latency Time (tAAmin)", tAAmin); + ddr_print("%-45s : %6d ps\n", "Minimum RAS to CAS Delay Time (tRCDmin)", ddr4_tRCDmin); + ddr_print("%-45s : %6d ps\n", "Minimum Row Precharge Delay Time (tRPmin)", ddr4_tRPmin); + ddr_print("%-45s : %6d ps\n", "Minimum Active to Precharge Delay (tRASmin)", ddr4_tRASmin); + ddr_print("%-45s : %6d ps\n", "Minimum Active to Active/Refr. Delay (tRCmin)", ddr4_tRCmin); + ddr_print("%-45s : %6d ps\n", "Minimum Refresh Recovery Delay (tRFC1min)", ddr4_tRFC1min); + ddr_print("%-45s : %6d ps\n", "Minimum Refresh Recovery Delay (tRFC2min)", ddr4_tRFC2min); + ddr_print("%-45s : %6d ps\n", "Minimum Refresh Recovery Delay (tRFC4min)", ddr4_tRFC4min); + ddr_print("%-45s : %6d ps\n", "Minimum Four Activate Window Time (tFAWmin)", ddr4_tFAWmin); + ddr_print("%-45s : %6d ps\n", "Minimum Act. to Act. Delay (tRRD_Smin)", ddr4_tRRD_Smin); + ddr_print("%-45s : %6d ps\n", "Minimum Act. to Act. Delay (tRRD_Lmin)", ddr4_tRRD_Lmin); + ddr_print("%-45s : %6d ps\n", "Minimum CAS to CAS Delay Time (tCCD_Lmin)", ddr4_tCCD_Lmin); + } else { + ddr_print("Medium Timebase (MTB) : %6d ps\n", mtb_psec); + ddr_print("Minimum Cycle Time (tCKmin) : %6d ps (%ld MT/s)\n", tCKmin, + pretty_psecs_to_mts(tCKmin)); + ddr_print("Minimum CAS Latency Time (tAAmin) : %6d ps\n", tAAmin); + ddr_print("Write Recovery Time (tWR) : %6d ps\n", twr); + ddr_print("Minimum RAS to CAS delay (tRCD) : %6d ps\n", trcd); + ddr_print("Minimum Row Active to Row Active delay (tRRD) : %6d ps\n", trrd); + ddr_print("Minimum Row Precharge Delay (tRP) : %6d ps\n", trp); + ddr_print("Minimum Active to Precharge (tRAS) : %6d ps\n", tras); + ddr_print("Minimum Active to Active/Refresh Delay (tRC) : %6d ps\n", trc); + ddr_print("Minimum Refresh Recovery Delay (tRFC) : %6d ps\n", trfc); + ddr_print("Internal write to read command delay (tWTR) : %6d ps\n", twtr); + ddr_print("Min Internal Rd to Precharge Cmd Delay (tRTP) : %6d ps\n", trtp); + ddr_print("Minimum Four Activate Window Delay (tFAW) : %6d ps\n", tfaw); + } + + + /* When the cycle time is within 1 psec of the minimum accept it + as a slight rounding error and adjust it to exactly the minimum + cycle time. This avoids an unnecessary warning. */ + if (_abs(tclk_psecs - tCKmin) < 2) + tclk_psecs = tCKmin; + + if (tclk_psecs < (uint64_t)tCKmin) { + ddr_print("WARNING!!!!: DDR Clock Rate (tCLK: %ld) exceeds DIMM specifications (tCKmin: %ld)!!!!\n", + tclk_psecs, (uint64_t)tCKmin); + } + + + ddr_print("DDR Clock Rate (tCLK) : %6lu ps\n", tclk_psecs); + ddr_print("Core Clock Rate (eCLK) : %6lu ps\n", eclk_psecs); + + if ((s = lookup_env_parameter("ddr_use_ecc")) != NULL) { + use_ecc = !!strtoul(s, NULL, 0); + } + use_ecc = use_ecc && spd_ecc; + + ddr_interface_bytemask = ddr_interface_64b + ? (use_ecc ? 0x1ff : 0xff) + : (use_ecc ? 0x01f : 0x0f); // FIXME? 81xx does diff from 70xx + + ddr_print("DRAM Interface width: %d bits %s bytemask 0x%x\n", + ddr_interface_64b ? 64 : 32, use_ecc ? "+ECC" : "", + ddr_interface_bytemask); + + ddr_print("\n------ Board Custom Configuration Settings ------\n"); + ddr_print("%-45s : %d\n", "MIN_RTT_NOM_IDX ", custom_lmc_config->min_rtt_nom_idx); + ddr_print("%-45s : %d\n", "MAX_RTT_NOM_IDX ", custom_lmc_config->max_rtt_nom_idx); + ddr_print("%-45s : %d\n", "MIN_RODT_CTL ", custom_lmc_config->min_rodt_ctl); + ddr_print("%-45s : %d\n", "MAX_RODT_CTL ", custom_lmc_config->max_rodt_ctl); + ddr_print("%-45s : %d\n", "MIN_CAS_LATENCY ", custom_lmc_config->min_cas_latency); + ddr_print("%-45s : %d\n", "OFFSET_EN ", custom_lmc_config->offset_en); + ddr_print("%-45s : %d\n", "OFFSET_UDIMM ", custom_lmc_config->offset_udimm); + ddr_print("%-45s : %d\n", "OFFSET_RDIMM ", custom_lmc_config->offset_rdimm); + ddr_print("%-45s : %d\n", "DDR_RTT_NOM_AUTO ", custom_lmc_config->ddr_rtt_nom_auto); + ddr_print("%-45s : %d\n", "DDR_RODT_CTL_AUTO ", custom_lmc_config->ddr_rodt_ctl_auto); + if (spd_rdimm) + ddr_print("%-45s : %d\n", "RLEVEL_COMP_OFFSET", custom_lmc_config->rlevel_comp_offset_rdimm); + else + ddr_print("%-45s : %d\n", "RLEVEL_COMP_OFFSET", custom_lmc_config->rlevel_comp_offset_udimm); + ddr_print("%-45s : %d\n", "RLEVEL_COMPUTE ", custom_lmc_config->rlevel_compute); + ddr_print("%-45s : %d\n", "DDR2T_UDIMM ", custom_lmc_config->ddr2t_udimm); + ddr_print("%-45s : %d\n", "DDR2T_RDIMM ", custom_lmc_config->ddr2t_rdimm); + ddr_print("%-45s : %d\n", "FPRCH2 ", custom_lmc_config->fprch2); + ddr_print("-------------------------------------------------\n"); + + + CL = divide_roundup(tAAmin, tclk_psecs); + + ddr_print("Desired CAS Latency : %6d\n", CL); + + min_cas_latency = custom_lmc_config->min_cas_latency; + + + if ((s = lookup_env_parameter("ddr_min_cas_latency")) != NULL) { + min_cas_latency = strtoul(s, NULL, 0); + } + + { + int base_CL; + ddr_print("CAS Latencies supported in DIMM :"); + base_CL = (ddr_type == DDR4_DRAM) ? 7 : 4; + for (i=0; i<32; ++i) { + if ((spd_cas_latency >> i) & 1) { + ddr_print(" %d", i+base_CL); + max_cas_latency = i+base_CL; + if (min_cas_latency == 0) + min_cas_latency = i+base_CL; + } + } + ddr_print("\n"); + + /* Use relaxed timing when running slower than the minimum + supported speed. Adjust timing to match the smallest supported + CAS Latency. */ + if (CL < min_cas_latency) { + uint64_t adjusted_tclk = tAAmin / min_cas_latency; + CL = min_cas_latency; + ddr_print("Slow clock speed. Adjusting timing: tClk = %lu, Adjusted tClk = %ld\n", + tclk_psecs, adjusted_tclk); + tclk_psecs = adjusted_tclk; + } + + if ((s = lookup_env_parameter("ddr_cas_latency")) != NULL) { + override_cas_latency = strtoul(s, NULL, 0); + } + + /* Make sure that the selected cas latency is legal */ + for (i=(CL-base_CL); i<32; ++i) { + if ((spd_cas_latency >> i) & 1) { + CL = i+base_CL; + break; + } + } + } + + if (CL > max_cas_latency) + CL = max_cas_latency; + + if (override_cas_latency != 0) { + CL = override_cas_latency; + } + + ddr_print("CAS Latency : %6d\n", CL); + + if ((CL * tCKmin) > 20000) + { + ddr_print("(CLactual * tCKmin) = %d exceeds 20 ns\n", (CL * tCKmin)); + } + + if ((num_banks != 4) && (num_banks != 8) && (num_banks != 16)) + { + error_print("Unsupported number of banks %d. Must be 4 or 8 or 16.\n", num_banks); + ++fatal_error; + } + + if ((num_ranks != 1) && (num_ranks != 2) && (num_ranks != 4)) + { + error_print("Unsupported number of ranks: %d\n", num_ranks); + ++fatal_error; + } + + if (! CAVIUM_IS_MODEL(CAVIUM_CN81XX)) { // 88XX or 83XX, but not 81XX + if ((dram_width != 8) && (dram_width != 16) && (dram_width != 4)) { + error_print("Unsupported SDRAM Width, x%d. Must be x4, x8 or x16.\n", dram_width); + ++fatal_error; + } + } else if ((dram_width != 8) && (dram_width != 16)) { // 81XX can only do x8 or x16 + error_print("Unsupported SDRAM Width, x%d. Must be x8 or x16.\n", dram_width); + ++fatal_error; + } + + + /* + ** Bail out here if things are not copasetic. + */ + if (fatal_error) + return(-1); + + /* + * 6.9.6 LMC RESET Initialization + * + * The purpose of this step is to assert/deassert the RESET# pin at the + * DDR3/DDR4 parts. + * + * This LMC RESET step is done for all enabled LMCs. + */ + perform_lmc_reset(node, ddr_interface_num); + + // Make sure scrambling is disabled during init... + { + bdk_lmcx_control_t lmc_control; + + lmc_control.u = BDK_CSR_READ(node, BDK_LMCX_CONTROL(ddr_interface_num)); + lmc_control.s.scramble_ena = 0; + DRAM_CSR_WRITE(node, BDK_LMCX_CONTROL(ddr_interface_num), lmc_control.u); + + DRAM_CSR_WRITE(node, BDK_LMCX_SCRAMBLE_CFG0(ddr_interface_num), 0); + DRAM_CSR_WRITE(node, BDK_LMCX_SCRAMBLE_CFG1(ddr_interface_num), 0); + DRAM_CSR_WRITE(node, BDK_LMCX_SCRAMBLE_CFG2(ddr_interface_num), 0); + } + + + odt_idx = dimm_count - 1; + + switch (num_ranks) { + case 1: + odt_config = odt_1rank_config; + break; + case 2: + odt_config = odt_2rank_config; + break; + case 4: + odt_config = odt_4rank_config; + break; + default: + odt_config = disable_odt_config; + error_print("Unsupported number of ranks: %d\n", num_ranks); + ++fatal_error; + } + + + /* Parameters from DDR3 Specifications */ +#define DDR3_tREFI 7800000 /* 7.8 us */ +#define DDR3_ZQCS 80000ull /* 80 ns */ +#define DDR3_ZQCS_Interval 1280000000 /* 128ms/100 */ +#define DDR3_tCKE 5000 /* 5 ns */ +#define DDR3_tMRD 4 /* 4 nCK */ +#define DDR3_tDLLK 512 /* 512 nCK */ +#define DDR3_tMPRR 1 /* 1 nCK */ +#define DDR3_tWLMRD 40 /* 40 nCK */ +#define DDR3_tWLDQSEN 25 /* 25 nCK */ + + /* Parameters from DDR4 Specifications */ +#define DDR4_tMRD 8 /* 8 nCK */ +#define DDR4_tDLLK 768 /* 768 nCK */ + + /* + * 6.9.7 Early LMC Initialization + * + * All of DDR PLL, LMC CK, and LMC DRESET initializations must be + * completed prior to starting this LMC initialization sequence. + * + * Perform the following five substeps for early LMC initialization: + * + * 1. Software must ensure there are no pending DRAM transactions. + * + * 2. Write LMC(0)_CONFIG, LMC(0)_CONTROL, LMC(0)_TIMING_PARAMS0, + * LMC(0)_TIMING_PARAMS1, LMC(0)_MODEREG_PARAMS0, + * LMC(0)_MODEREG_PARAMS1, LMC(0)_DUAL_MEMCFG, LMC(0)_NXM, + * LMC(0)_WODT_MASK, LMC(0)_RODT_MASK, LMC(0)_COMP_CTL2, + * LMC(0)_PHY_CTL, LMC(0)_DIMM0/1_PARAMS, and LMC(0)_DIMM_CTL with + * appropriate values. All sections in this chapter can be used to + * derive proper register settings. + */ + + /* LMC(0)_CONFIG */ + { + lmc_config.u = 0; + + lmc_config.s.ecc_ena = use_ecc; + lmc_config.s.row_lsb = encode_row_lsb_ddr3(row_lsb, ddr_interface_64b); + lmc_config.s.pbank_lsb = encode_pbank_lsb_ddr3(pbank_lsb, ddr_interface_64b); + + lmc_config.s.idlepower = 0; /* Disabled */ + + if ((s = lookup_env_parameter("ddr_idlepower")) != NULL) { + lmc_config.s.idlepower = strtoul(s, NULL, 0); + } + + lmc_config.s.forcewrite = 0; /* Disabled */ + lmc_config.s.ecc_adr = 1; /* Include memory reference address in the ECC */ + + if ((s = lookup_env_parameter("ddr_ecc_adr")) != NULL) { + lmc_config.s.ecc_adr = strtoul(s, NULL, 0); + } + + lmc_config.s.reset = 0; + + /* + * Program LMC0_CONFIG[24:18], ref_zqcs_int(6:0) to + * RND-DN(tREFI/clkPeriod/512) Program LMC0_CONFIG[36:25], + * ref_zqcs_int(18:7) to + * RND-DN(ZQCS_Interval/clkPeriod/(512*128)). Note that this + * value should always be greater than 32, to account for + * resistor calibration delays. + */ + + lmc_config.s.ref_zqcs_int = ((DDR3_tREFI/tclk_psecs/512) & 0x7f); + lmc_config.s.ref_zqcs_int |= ((max(33ull, (DDR3_ZQCS_Interval/(tclk_psecs/100)/(512*128))) & 0xfff) << 7); + + + lmc_config.s.early_dqx = 1; /* Default to enabled */ + + if ((s = lookup_env_parameter("ddr_early_dqx")) == NULL) + s = lookup_env_parameter("ddr%d_early_dqx", ddr_interface_num); + if (s != NULL) { + lmc_config.s.early_dqx = strtoul(s, NULL, 0); + } + + lmc_config.s.sref_with_dll = 0; + + lmc_config.s.rank_ena = bunk_enable; + lmc_config.s.rankmask = rank_mask; /* Set later */ + lmc_config.s.mirrmask = (spd_addr_mirror << 1 | spd_addr_mirror << 3) & rank_mask; + lmc_config.s.init_status = rank_mask; /* Set once and don't change it. */ + lmc_config.s.early_unload_d0_r0 = 0; + lmc_config.s.early_unload_d0_r1 = 0; + lmc_config.s.early_unload_d1_r0 = 0; + lmc_config.s.early_unload_d1_r1 = 0; + lmc_config.s.scrz = 0; + // set 32-bit mode for real only when selected AND 81xx... + if (!ddr_interface_64b && CAVIUM_IS_MODEL(CAVIUM_CN81XX)) { + lmc_config.s.mode32b = 1; + } + VB_PRT(VBL_DEV, "%-45s : %d\n", "MODE32B (init)", lmc_config.s.mode32b); + lmc_config.s.mode_x4dev = (dram_width == 4) ? 1 : 0; + lmc_config.s.bg2_enable = ((ddr_type == DDR4_DRAM) && (dram_width == 16)) ? 0 : 1; + + if ((s = lookup_env_parameter_ull("ddr_config")) != NULL) { + lmc_config.u = strtoull(s, NULL, 0); + } + ddr_print("LMC_CONFIG : 0x%016lx\n", lmc_config.u); + DRAM_CSR_WRITE(node, BDK_LMCX_CONFIG(ddr_interface_num), lmc_config.u); + } + + /* LMC(0)_CONTROL */ + { + bdk_lmcx_control_t lmc_control; + lmc_control.u = BDK_CSR_READ(node, BDK_LMCX_CONTROL(ddr_interface_num)); + lmc_control.s.rdimm_ena = spd_rdimm; + lmc_control.s.bwcnt = 0; /* Clear counter later */ + if (spd_rdimm) + lmc_control.s.ddr2t = (safe_ddr_flag ? 1 : custom_lmc_config->ddr2t_rdimm ); + else + lmc_control.s.ddr2t = (safe_ddr_flag ? 1 : custom_lmc_config->ddr2t_udimm ); + lmc_control.s.pocas = 0; + lmc_control.s.fprch2 = (safe_ddr_flag ? 2 : custom_lmc_config->fprch2 ); + lmc_control.s.throttle_rd = safe_ddr_flag ? 1 : 0; + lmc_control.s.throttle_wr = safe_ddr_flag ? 1 : 0; + lmc_control.s.inorder_rd = safe_ddr_flag ? 1 : 0; + lmc_control.s.inorder_wr = safe_ddr_flag ? 1 : 0; + lmc_control.cn81xx.elev_prio_dis = safe_ddr_flag ? 1 : 0; + lmc_control.s.nxm_write_en = 0; /* discards writes to + addresses that don't exist + in the DRAM */ + lmc_control.s.max_write_batch = 8; + lmc_control.s.xor_bank = 1; + lmc_control.s.auto_dclkdis = 1; + lmc_control.s.int_zqcs_dis = 0; + lmc_control.s.ext_zqcs_dis = 0; + lmc_control.s.bprch = 1; + lmc_control.s.wodt_bprch = 1; + lmc_control.s.rodt_bprch = 1; + + if ((s = lookup_env_parameter("ddr_xor_bank")) != NULL) { + lmc_control.s.xor_bank = strtoul(s, NULL, 0); + } + + if ((s = lookup_env_parameter("ddr_2t")) != NULL) { + lmc_control.s.ddr2t = strtoul(s, NULL, 0); + } + + if ((s = lookup_env_parameter("ddr_fprch2")) != NULL) { + lmc_control.s.fprch2 = strtoul(s, NULL, 0); + } + + if ((s = lookup_env_parameter("ddr_bprch")) != NULL) { + lmc_control.s.bprch = strtoul(s, NULL, 0); + } + + if ((s = lookup_env_parameter("ddr_wodt_bprch")) != NULL) { + lmc_control.s.wodt_bprch = strtoul(s, NULL, 0); + } + + if ((s = lookup_env_parameter("ddr_rodt_bprch")) != NULL) { + lmc_control.s.rodt_bprch = strtoul(s, NULL, 0); + } + + if ((s = lookup_env_parameter("ddr_int_zqcs_dis")) != NULL) { + lmc_control.s.int_zqcs_dis = strtoul(s, NULL, 0); + } + + if ((s = lookup_env_parameter("ddr_ext_zqcs_dis")) != NULL) { + lmc_control.s.ext_zqcs_dis = strtoul(s, NULL, 0); + } + + if ((s = lookup_env_parameter_ull("ddr_control")) != NULL) { + lmc_control.u = strtoull(s, NULL, 0); + } + ddr_print("LMC_CONTROL : 0x%016lx\n", lmc_control.u); + DRAM_CSR_WRITE(node, BDK_LMCX_CONTROL(ddr_interface_num), lmc_control.u); + } + + /* LMC(0)_TIMING_PARAMS0 */ + { + unsigned trp_value; + bdk_lmcx_timing_params0_t lmc_timing_params0; + lmc_timing_params0.u = BDK_CSR_READ(node, BDK_LMCX_TIMING_PARAMS0(ddr_interface_num)); + + trp_value = divide_roundup(trp, tclk_psecs) - 1; + ddr_print("TIMING_PARAMS0[TRP]: NEW 0x%x, OLD 0x%x\n", trp_value, + trp_value + (unsigned)(divide_roundup(max(4*tclk_psecs, 7500ull), tclk_psecs)) - 4); +#if 1 + if ((s = lookup_env_parameter_ull("ddr_use_old_trp")) != NULL) { + if (!!strtoull(s, NULL, 0)) { + trp_value += divide_roundup(max(4*tclk_psecs, 7500ull), tclk_psecs) - 4; + ddr_print("TIMING_PARAMS0[trp]: USING OLD 0x%x\n", trp_value); + } + } +#endif + + lmc_timing_params0.s.txpr = divide_roundup(max(5*tclk_psecs, trfc+10000ull), 16*tclk_psecs); + lmc_timing_params0.s.tzqinit = divide_roundup(max(512*tclk_psecs, 640000ull), (256*tclk_psecs)); + lmc_timing_params0.s.trp = trp_value & 0x1f; + lmc_timing_params0.s.tcksre = divide_roundup(max(5*tclk_psecs, 10000ull), tclk_psecs) - 1; + + if (ddr_type == DDR4_DRAM) { + lmc_timing_params0.s.tzqcs = divide_roundup(128*tclk_psecs, (16*tclk_psecs)); /* Always 8. */ + lmc_timing_params0.s.tcke = divide_roundup(max(3*tclk_psecs, (uint64_t) DDR3_tCKE), tclk_psecs) - 1; + lmc_timing_params0.s.tmrd = divide_roundup((DDR4_tMRD*tclk_psecs), tclk_psecs) - 1; + //lmc_timing_params0.s.tmod = divide_roundup(max(24*tclk_psecs, 15000ull), tclk_psecs) - 1; + lmc_timing_params0.s.tmod = 25; /* 25 is the max allowed */ + lmc_timing_params0.s.tdllk = divide_roundup(DDR4_tDLLK, 256); + } else { + lmc_timing_params0.s.tzqcs = divide_roundup(max(64*tclk_psecs, DDR3_ZQCS), (16*tclk_psecs)); + lmc_timing_params0.s.tcke = divide_roundup(DDR3_tCKE, tclk_psecs) - 1; + lmc_timing_params0.s.tmrd = divide_roundup((DDR3_tMRD*tclk_psecs), tclk_psecs) - 1; + lmc_timing_params0.s.tmod = divide_roundup(max(12*tclk_psecs, 15000ull), tclk_psecs) - 1; + lmc_timing_params0.s.tdllk = divide_roundup(DDR3_tDLLK, 256); + } + + if ((s = lookup_env_parameter_ull("ddr_timing_params0")) != NULL) { + lmc_timing_params0.u = strtoull(s, NULL, 0); + } + ddr_print("TIMING_PARAMS0 : 0x%016lx\n", lmc_timing_params0.u); + DRAM_CSR_WRITE(node, BDK_LMCX_TIMING_PARAMS0(ddr_interface_num), lmc_timing_params0.u); + } + + /* LMC(0)_TIMING_PARAMS1 */ + { + int txp, temp_trcd, trfc_dlr; + bdk_lmcx_timing_params1_t lmc_timing_params1; + lmc_timing_params1.u = BDK_CSR_READ(node, BDK_LMCX_TIMING_PARAMS1(ddr_interface_num)); + + lmc_timing_params1.s.tmprr = divide_roundup(DDR3_tMPRR*tclk_psecs, tclk_psecs) - 1; + + lmc_timing_params1.s.tras = divide_roundup(tras, tclk_psecs) - 1; + + // NOTE: this is reworked for pass 2.x + temp_trcd = divide_roundup(trcd, tclk_psecs); +#if 1 + if (temp_trcd > 15) + ddr_print("TIMING_PARAMS1[trcd]: need extension bit for 0x%x\n", temp_trcd); +#endif + if (CAVIUM_IS_MODEL(CAVIUM_CN88XX_PASS1_X) && (temp_trcd > 15)) { + /* Let .trcd=0 serve as a flag that the field has + overflowed. Must use Additive Latency mode as a + workaround. */ + temp_trcd = 0; + } + lmc_timing_params1.s.trcd = temp_trcd & 0x0f; + lmc_timing_params1.s.trcd_ext = (temp_trcd >> 4) & 1; + + lmc_timing_params1.s.twtr = divide_roundup(twtr, tclk_psecs) - 1; + lmc_timing_params1.s.trfc = divide_roundup(trfc, 8*tclk_psecs); + + // workaround needed for all THUNDER chips thru T88 Pass 2.0, + // but not 81xx and 83xx... + if ((ddr_type == DDR4_DRAM) && CAVIUM_IS_MODEL(CAVIUM_CN88XX)) { + /* Workaround bug 24006. Use Trrd_l. */ + lmc_timing_params1.s.trrd = divide_roundup(ddr4_tRRD_Lmin, tclk_psecs) - 2; + } else + lmc_timing_params1.s.trrd = divide_roundup(trrd, tclk_psecs) - 2; + + /* + ** tXP = max( 3nCK, 7.5 ns) DDR3-800 tCLK = 2500 psec + ** tXP = max( 3nCK, 7.5 ns) DDR3-1066 tCLK = 1875 psec + ** tXP = max( 3nCK, 6.0 ns) DDR3-1333 tCLK = 1500 psec + ** tXP = max( 3nCK, 6.0 ns) DDR3-1600 tCLK = 1250 psec + ** tXP = max( 3nCK, 6.0 ns) DDR3-1866 tCLK = 1071 psec + ** tXP = max( 3nCK, 6.0 ns) DDR3-2133 tCLK = 937 psec + */ + txp = (tclk_psecs < 1875) ? 6000 : 7500; + // NOTE: this is reworked for pass 2.x + int temp_txp = divide_roundup(max(3*tclk_psecs, (unsigned)txp), tclk_psecs) - 1; +#if 1 + if (temp_txp > 7) + ddr_print("TIMING_PARAMS1[txp]: need extension bit for 0x%x\n", temp_txp); +#endif + if (CAVIUM_IS_MODEL(CAVIUM_CN88XX_PASS1_X) && (temp_txp > 7)) { + temp_txp = 7; // max it out + } + lmc_timing_params1.s.txp = temp_txp & 7; + lmc_timing_params1.s.txp_ext = (temp_txp >> 3) & 1; + + lmc_timing_params1.s.twlmrd = divide_roundup(DDR3_tWLMRD*tclk_psecs, 4*tclk_psecs); + lmc_timing_params1.s.twldqsen = divide_roundup(DDR3_tWLDQSEN*tclk_psecs, 4*tclk_psecs); + lmc_timing_params1.s.tfaw = divide_roundup(tfaw, 4*tclk_psecs); + lmc_timing_params1.s.txpdll = divide_roundup(max(10*tclk_psecs, 24000ull), tclk_psecs) - 1; + + if ((ddr_type == DDR4_DRAM) && is_3ds_dimm) { + /* + 4 Gb: tRFC_DLR = 90 ns + 8 Gb: tRFC_DLR = 120 ns + 16 Gb: tRFC_DLR = 190 ns FIXME? + */ + // RNDUP[tRFC_DLR(ns) / (8 * TCYC(ns))] + if (die_capacity == 0x1000) // 4 Gbit + trfc_dlr = 90; + else if (die_capacity == 0x2000) // 8 Gbit + trfc_dlr = 120; + else if (die_capacity == 0x4000) // 16 Gbit + trfc_dlr = 190; + else + trfc_dlr = 0; + + if (trfc_dlr == 0) { + ddr_print("N%d.LMC%d: ERROR: tRFC_DLR: die_capacity %u Mbit is illegal\n", + node, ddr_interface_num, die_capacity); + } else { + lmc_timing_params1.s.trfc_dlr = divide_roundup(trfc_dlr * 1000UL, 8*tclk_psecs); + ddr_print("N%d.LMC%d: TIMING_PARAMS1[trfc_dlr] set to %u\n", + node, ddr_interface_num, lmc_timing_params1.s.trfc_dlr); + } + } + + if ((s = lookup_env_parameter_ull("ddr_timing_params1")) != NULL) { + lmc_timing_params1.u = strtoull(s, NULL, 0); + } + ddr_print("TIMING_PARAMS1 : 0x%016lx\n", lmc_timing_params1.u); + DRAM_CSR_WRITE(node, BDK_LMCX_TIMING_PARAMS1(ddr_interface_num), lmc_timing_params1.u); + } + + /* LMC(0)_TIMING_PARAMS2 */ + if (ddr_type == DDR4_DRAM) { + bdk_lmcx_timing_params1_t lmc_timing_params1; + bdk_lmcx_timing_params2_t lmc_timing_params2; + lmc_timing_params1.u = BDK_CSR_READ(node, BDK_LMCX_TIMING_PARAMS1(ddr_interface_num)); + lmc_timing_params2.u = BDK_CSR_READ(node, BDK_LMCX_TIMING_PARAMS2(ddr_interface_num)); + ddr_print("TIMING_PARAMS2 : 0x%016lx\n", lmc_timing_params2.u); + + //lmc_timing_params2.s.trrd_l = divide_roundup(ddr4_tRRD_Lmin, tclk_psecs) - 1; + // NOTE: this is reworked for pass 2.x + int temp_trrd_l = divide_roundup(ddr4_tRRD_Lmin, tclk_psecs) - 2; +#if 1 + if (temp_trrd_l > 7) + ddr_print("TIMING_PARAMS2[trrd_l]: need extension bit for 0x%x\n", temp_trrd_l); +#endif + if (CAVIUM_IS_MODEL(CAVIUM_CN88XX_PASS1_X) && (temp_trrd_l > 7)) { + temp_trrd_l = 7; // max it out + } + lmc_timing_params2.s.trrd_l = temp_trrd_l & 7; + lmc_timing_params2.s.trrd_l_ext = (temp_trrd_l >> 3) & 1; + + lmc_timing_params2.s.twtr_l = divide_nint(max(4*tclk_psecs, 7500ull), tclk_psecs) - 1; // correct for 1600-2400 + lmc_timing_params2.s.t_rw_op_max = 7; + lmc_timing_params2.s.trtp = divide_roundup(max(4*tclk_psecs, 7500ull), tclk_psecs) - 1; + + ddr_print("TIMING_PARAMS2 : 0x%016lx\n", lmc_timing_params2.u); + DRAM_CSR_WRITE(node, BDK_LMCX_TIMING_PARAMS2(ddr_interface_num), lmc_timing_params2.u); + + /* Workaround Errata 25823 - LMC: Possible DDR4 tWTR_L not met + for Write-to-Read operations to the same Bank Group */ + if (lmc_timing_params1.s.twtr < (lmc_timing_params2.s.twtr_l - 4)) { + lmc_timing_params1.s.twtr = lmc_timing_params2.s.twtr_l - 4; + ddr_print("ERRATA 25823: NEW: TWTR: %d, TWTR_L: %d\n", lmc_timing_params1.s.twtr, lmc_timing_params2.s.twtr_l); + ddr_print("TIMING_PARAMS1 : 0x%016lx\n", lmc_timing_params1.u); + DRAM_CSR_WRITE(node, BDK_LMCX_TIMING_PARAMS1(ddr_interface_num), lmc_timing_params1.u); + } + } + + /* LMC(0)_MODEREG_PARAMS0 */ + { + bdk_lmcx_modereg_params0_t lmc_modereg_params0; + int param; + + lmc_modereg_params0.u = BDK_CSR_READ(node, BDK_LMCX_MODEREG_PARAMS0(ddr_interface_num)); + + if (ddr_type == DDR4_DRAM) { + lmc_modereg_params0.s.cwl = 0; /* 1600 (1250ps) */ + if (tclk_psecs < 1250) + lmc_modereg_params0.s.cwl = 1; /* 1866 (1072ps) */ + if (tclk_psecs < 1072) + lmc_modereg_params0.s.cwl = 2; /* 2133 (938ps) */ + if (tclk_psecs < 938) + lmc_modereg_params0.s.cwl = 3; /* 2400 (833ps) */ + if (tclk_psecs < 833) + lmc_modereg_params0.s.cwl = 4; /* 2666 (750ps) */ + if (tclk_psecs < 750) + lmc_modereg_params0.s.cwl = 5; /* 3200 (625ps) */ + } else { + /* + ** CSR CWL CAS write Latency + ** === === ================================= + ** 0 5 ( tCK(avg) >= 2.5 ns) + ** 1 6 (2.5 ns > tCK(avg) >= 1.875 ns) + ** 2 7 (1.875 ns > tCK(avg) >= 1.5 ns) + ** 3 8 (1.5 ns > tCK(avg) >= 1.25 ns) + ** 4 9 (1.25 ns > tCK(avg) >= 1.07 ns) + ** 5 10 (1.07 ns > tCK(avg) >= 0.935 ns) + ** 6 11 (0.935 ns > tCK(avg) >= 0.833 ns) + ** 7 12 (0.833 ns > tCK(avg) >= 0.75 ns) + */ + + lmc_modereg_params0.s.cwl = 0; + if (tclk_psecs < 2500) + lmc_modereg_params0.s.cwl = 1; + if (tclk_psecs < 1875) + lmc_modereg_params0.s.cwl = 2; + if (tclk_psecs < 1500) + lmc_modereg_params0.s.cwl = 3; + if (tclk_psecs < 1250) + lmc_modereg_params0.s.cwl = 4; + if (tclk_psecs < 1070) + lmc_modereg_params0.s.cwl = 5; + if (tclk_psecs < 935) + lmc_modereg_params0.s.cwl = 6; + if (tclk_psecs < 833) + lmc_modereg_params0.s.cwl = 7; + } + + if ((s = lookup_env_parameter("ddr_cwl")) != NULL) { + lmc_modereg_params0.s.cwl = strtoul(s, NULL, 0) - 5; + } + + if (ddr_type == DDR4_DRAM) { + ddr_print("%-45s : %d, [0x%x]\n", "CAS Write Latency CWL, [CSR]", + lmc_modereg_params0.s.cwl + 9 + + ((lmc_modereg_params0.s.cwl>2) ? (lmc_modereg_params0.s.cwl-3) * 2 : 0), + lmc_modereg_params0.s.cwl); + } else { + ddr_print("%-45s : %d, [0x%x]\n", "CAS Write Latency CWL, [CSR]", + lmc_modereg_params0.s.cwl + 5, + lmc_modereg_params0.s.cwl); + } + + lmc_modereg_params0.s.mprloc = 0; + lmc_modereg_params0.s.mpr = 0; + lmc_modereg_params0.s.dll = (ddr_type == DDR4_DRAM)?1:0; /* disable(0) for DDR3 and enable(1) for DDR4 */ + lmc_modereg_params0.s.al = 0; + lmc_modereg_params0.s.wlev = 0; /* Read Only */ + lmc_modereg_params0.s.tdqs = ((ddr_type == DDR4_DRAM) || (dram_width != 8))?0:1; /* disable(0) for DDR4 and x4/x16 DDR3 */ + lmc_modereg_params0.s.qoff = 0; + //lmc_modereg_params0.s.bl = 0; /* Don't touch block dirty logic */ + + if ((s = lookup_env_parameter("ddr_cl")) != NULL) { + CL = strtoul(s, NULL, 0); + ddr_print("CAS Latency : %6d\n", CL); + } + + if (ddr_type == DDR4_DRAM) { + lmc_modereg_params0.s.cl = 0x0; + if (CL > 9) + lmc_modereg_params0.s.cl = 0x1; + if (CL > 10) + lmc_modereg_params0.s.cl = 0x2; + if (CL > 11) + lmc_modereg_params0.s.cl = 0x3; + if (CL > 12) + lmc_modereg_params0.s.cl = 0x4; + if (CL > 13) + lmc_modereg_params0.s.cl = 0x5; + if (CL > 14) + lmc_modereg_params0.s.cl = 0x6; + if (CL > 15) + lmc_modereg_params0.s.cl = 0x7; + if (CL > 16) + lmc_modereg_params0.s.cl = 0x8; + if (CL > 18) + lmc_modereg_params0.s.cl = 0x9; + if (CL > 20) + lmc_modereg_params0.s.cl = 0xA; + if (CL > 24) + lmc_modereg_params0.s.cl = 0xB; + } else { + lmc_modereg_params0.s.cl = 0x2; + if (CL > 5) + lmc_modereg_params0.s.cl = 0x4; + if (CL > 6) + lmc_modereg_params0.s.cl = 0x6; + if (CL > 7) + lmc_modereg_params0.s.cl = 0x8; + if (CL > 8) + lmc_modereg_params0.s.cl = 0xA; + if (CL > 9) + lmc_modereg_params0.s.cl = 0xC; + if (CL > 10) + lmc_modereg_params0.s.cl = 0xE; + if (CL > 11) + lmc_modereg_params0.s.cl = 0x1; + if (CL > 12) + lmc_modereg_params0.s.cl = 0x3; + if (CL > 13) + lmc_modereg_params0.s.cl = 0x5; + if (CL > 14) + lmc_modereg_params0.s.cl = 0x7; + if (CL > 15) + lmc_modereg_params0.s.cl = 0x9; + } + + lmc_modereg_params0.s.rbt = 0; /* Read Only. */ + lmc_modereg_params0.s.tm = 0; + lmc_modereg_params0.s.dllr = 0; + + param = divide_roundup(twr, tclk_psecs); + + if (ddr_type == DDR4_DRAM) { /* DDR4 */ + lmc_modereg_params0.s.wrp = 1; + if (param > 12) + lmc_modereg_params0.s.wrp = 2; + if (param > 14) + lmc_modereg_params0.s.wrp = 3; + if (param > 16) + lmc_modereg_params0.s.wrp = 4; + if (param > 18) + lmc_modereg_params0.s.wrp = 5; + if (param > 20) + lmc_modereg_params0.s.wrp = 6; + if (param > 24) /* RESERVED in DDR4 spec */ + lmc_modereg_params0.s.wrp = 7; + } else { /* DDR3 */ + lmc_modereg_params0.s.wrp = 1; + if (param > 5) + lmc_modereg_params0.s.wrp = 2; + if (param > 6) + lmc_modereg_params0.s.wrp = 3; + if (param > 7) + lmc_modereg_params0.s.wrp = 4; + if (param > 8) + lmc_modereg_params0.s.wrp = 5; + if (param > 10) + lmc_modereg_params0.s.wrp = 6; + if (param > 12) + lmc_modereg_params0.s.wrp = 7; + } + + lmc_modereg_params0.s.ppd = 0; + + if ((s = lookup_env_parameter("ddr_wrp")) != NULL) { + lmc_modereg_params0.s.wrp = strtoul(s, NULL, 0); + } + + ddr_print("%-45s : %d, [0x%x]\n", "Write recovery for auto precharge WRP, [CSR]", + param, lmc_modereg_params0.s.wrp); + + if ((s = lookup_env_parameter_ull("ddr_modereg_params0")) != NULL) { + lmc_modereg_params0.u = strtoull(s, NULL, 0); + } + ddr_print("MODEREG_PARAMS0 : 0x%016lx\n", lmc_modereg_params0.u); + DRAM_CSR_WRITE(node, BDK_LMCX_MODEREG_PARAMS0(ddr_interface_num), lmc_modereg_params0.u); + } + + /* LMC(0)_MODEREG_PARAMS1 */ + { + bdk_lmcx_modereg_params1_t lmc_modereg_params1; + + lmc_modereg_params1.u = odt_config[odt_idx].odt_mask1.u; + +#ifdef CAVIUM_ONLY + /* Special request: mismatched DIMM support. Slot 0: 2-Rank, Slot 1: 1-Rank */ + if (rank_mask == 0x7) { /* 2-Rank, 1-Rank */ + lmc_modereg_params1.s.rtt_nom_00 = 0; + lmc_modereg_params1.s.rtt_nom_01 = 3; /* rttnom_40ohm */ + lmc_modereg_params1.s.rtt_nom_10 = 3; /* rttnom_40ohm */ + lmc_modereg_params1.s.rtt_nom_11 = 0; + dyn_rtt_nom_mask = 0x6; + } +#endif /* CAVIUM_ONLY */ + + if ((s = lookup_env_parameter("ddr_rtt_nom_mask")) != NULL) { + dyn_rtt_nom_mask = strtoul(s, NULL, 0); + } + + + /* Save the original rtt_nom settings before sweeping through settings. */ + default_rtt_nom[0] = lmc_modereg_params1.s.rtt_nom_00; + default_rtt_nom[1] = lmc_modereg_params1.s.rtt_nom_01; + default_rtt_nom[2] = lmc_modereg_params1.s.rtt_nom_10; + default_rtt_nom[3] = lmc_modereg_params1.s.rtt_nom_11; + + ddr_rtt_nom_auto = custom_lmc_config->ddr_rtt_nom_auto; + + for (i=0; i<4; ++i) { + uint64_t value; + if ((s = lookup_env_parameter("ddr_rtt_nom_%1d%1d", !!(i&2), !!(i&1))) == NULL) + s = lookup_env_parameter("ddr%d_rtt_nom_%1d%1d", ddr_interface_num, !!(i&2), !!(i&1)); + if (s != NULL) { + value = strtoul(s, NULL, 0); + lmc_modereg_params1.u &= ~((uint64_t)0x7 << (i*12+9)); + lmc_modereg_params1.u |= ( (value & 0x7) << (i*12+9)); + default_rtt_nom[i] = value; + ddr_rtt_nom_auto = 0; + } + } + + if ((s = lookup_env_parameter("ddr_rtt_nom")) == NULL) + s = lookup_env_parameter("ddr%d_rtt_nom", ddr_interface_num); + if (s != NULL) { + uint64_t value; + value = strtoul(s, NULL, 0); + + if (dyn_rtt_nom_mask & 1) + default_rtt_nom[0] = lmc_modereg_params1.s.rtt_nom_00 = value; + if (dyn_rtt_nom_mask & 2) + default_rtt_nom[1] = lmc_modereg_params1.s.rtt_nom_01 = value; + if (dyn_rtt_nom_mask & 4) + default_rtt_nom[2] = lmc_modereg_params1.s.rtt_nom_10 = value; + if (dyn_rtt_nom_mask & 8) + default_rtt_nom[3] = lmc_modereg_params1.s.rtt_nom_11 = value; + + ddr_rtt_nom_auto = 0; + } + + if ((s = lookup_env_parameter("ddr_rtt_wr")) != NULL) { + uint64_t value = strtoul(s, NULL, 0); + for (i=0; i<4; ++i) { + INSRT_WR(&lmc_modereg_params1.u, i, value); + } + } + + for (i = 0; i < 4; ++i) { + uint64_t value; + if ((s = lookup_env_parameter("ddr_rtt_wr_%1d%1d", !!(i&2), !!(i&1))) == NULL) + s = lookup_env_parameter("ddr%d_rtt_wr_%1d%1d", ddr_interface_num, !!(i&2), !!(i&1)); + if (s != NULL) { + value = strtoul(s, NULL, 0); + INSRT_WR(&lmc_modereg_params1.u, i, value); + } + } + + // Make sure pass 1 has valid RTT_WR settings, because + // configuration files may be set-up for pass 2, and + // pass 1 supports no RTT_WR extension bits + if (CAVIUM_IS_MODEL(CAVIUM_CN88XX_PASS1_X)) { + for (i = 0; i < 4; ++i) { + if (EXTR_WR(lmc_modereg_params1.u, i) > 3) { // if 80 or undefined + INSRT_WR(&lmc_modereg_params1.u, i, 1); // FIXME? always insert 120 + ddr_print("RTT_WR_%d%d set to 120 for CN88XX pass 1\n", !!(i&2), i&1); + } + } + } + if ((s = lookup_env_parameter("ddr_dic")) != NULL) { + uint64_t value = strtoul(s, NULL, 0); + for (i=0; i<4; ++i) { + lmc_modereg_params1.u &= ~((uint64_t)0x3 << (i*12+7)); + lmc_modereg_params1.u |= ( (value & 0x3) << (i*12+7)); + } + } + + for (i=0; i<4; ++i) { + uint64_t value; + if ((s = lookup_env_parameter("ddr_dic_%1d%1d", !!(i&2), !!(i&1))) != NULL) { + value = strtoul(s, NULL, 0); + lmc_modereg_params1.u &= ~((uint64_t)0x3 << (i*12+7)); + lmc_modereg_params1.u |= ( (value & 0x3) << (i*12+7)); + } + } + + if ((s = lookup_env_parameter_ull("ddr_modereg_params1")) != NULL) { + lmc_modereg_params1.u = strtoull(s, NULL, 0); + } + + ddr_print("RTT_NOM %3d, %3d, %3d, %3d ohms : %x,%x,%x,%x\n", + imp_values->rtt_nom_ohms[lmc_modereg_params1.s.rtt_nom_11], + imp_values->rtt_nom_ohms[lmc_modereg_params1.s.rtt_nom_10], + imp_values->rtt_nom_ohms[lmc_modereg_params1.s.rtt_nom_01], + imp_values->rtt_nom_ohms[lmc_modereg_params1.s.rtt_nom_00], + lmc_modereg_params1.s.rtt_nom_11, + lmc_modereg_params1.s.rtt_nom_10, + lmc_modereg_params1.s.rtt_nom_01, + lmc_modereg_params1.s.rtt_nom_00); + + ddr_print("RTT_WR %3d, %3d, %3d, %3d ohms : %x,%x,%x,%x\n", + imp_values->rtt_wr_ohms[EXTR_WR(lmc_modereg_params1.u, 3)], + imp_values->rtt_wr_ohms[EXTR_WR(lmc_modereg_params1.u, 2)], + imp_values->rtt_wr_ohms[EXTR_WR(lmc_modereg_params1.u, 1)], + imp_values->rtt_wr_ohms[EXTR_WR(lmc_modereg_params1.u, 0)], + EXTR_WR(lmc_modereg_params1.u, 3), + EXTR_WR(lmc_modereg_params1.u, 2), + EXTR_WR(lmc_modereg_params1.u, 1), + EXTR_WR(lmc_modereg_params1.u, 0)); + + ddr_print("DIC %3d, %3d, %3d, %3d ohms : %x,%x,%x,%x\n", + imp_values->dic_ohms[lmc_modereg_params1.s.dic_11], + imp_values->dic_ohms[lmc_modereg_params1.s.dic_10], + imp_values->dic_ohms[lmc_modereg_params1.s.dic_01], + imp_values->dic_ohms[lmc_modereg_params1.s.dic_00], + lmc_modereg_params1.s.dic_11, + lmc_modereg_params1.s.dic_10, + lmc_modereg_params1.s.dic_01, + lmc_modereg_params1.s.dic_00); + + ddr_print("MODEREG_PARAMS1 : 0x%016lx\n", lmc_modereg_params1.u); + DRAM_CSR_WRITE(node, BDK_LMCX_MODEREG_PARAMS1(ddr_interface_num), lmc_modereg_params1.u); + + } /* LMC(0)_MODEREG_PARAMS1 */ + + /* LMC(0)_MODEREG_PARAMS2 */ + if (ddr_type == DDR4_DRAM) { + bdk_lmcx_modereg_params2_t lmc_modereg_params2; + lmc_modereg_params2.u = odt_config[odt_idx].odt_mask2.u; + + for (i=0; i<4; ++i) { + uint64_t value; + if ((s = lookup_env_parameter("ddr_rtt_park_%1d%1d", !!(i&2), !!(i&1))) != NULL) { + value = strtoul(s, NULL, 0); + lmc_modereg_params2.u &= ~((uint64_t)0x7 << (i*10+0)); + lmc_modereg_params2.u |= ( (value & 0x7) << (i*10+0)); + } + } + + if ((s = lookup_env_parameter("ddr_rtt_park")) != NULL) { + uint64_t value = strtoul(s, NULL, 0); + for (i=0; i<4; ++i) { + lmc_modereg_params2.u &= ~((uint64_t)0x7 << (i*10+0)); + lmc_modereg_params2.u |= ( (value & 0x7) << (i*10+0)); + } + } + + if ((s = lookup_env_parameter_ull("ddr_modereg_params2")) != NULL) { + lmc_modereg_params2.u = strtoull(s, NULL, 0); + } + + ddr_print("RTT_PARK %3d, %3d, %3d, %3d ohms : %x,%x,%x,%x\n", + imp_values->rtt_nom_ohms[lmc_modereg_params2.s.rtt_park_11], + imp_values->rtt_nom_ohms[lmc_modereg_params2.s.rtt_park_10], + imp_values->rtt_nom_ohms[lmc_modereg_params2.s.rtt_park_01], + imp_values->rtt_nom_ohms[lmc_modereg_params2.s.rtt_park_00], + lmc_modereg_params2.s.rtt_park_11, + lmc_modereg_params2.s.rtt_park_10, + lmc_modereg_params2.s.rtt_park_01, + lmc_modereg_params2.s.rtt_park_00); + + ddr_print("%-45s : 0x%x,0x%x,0x%x,0x%x\n", "VREF_RANGE", + lmc_modereg_params2.s.vref_range_11, + lmc_modereg_params2.s.vref_range_10, + lmc_modereg_params2.s.vref_range_01, + lmc_modereg_params2.s.vref_range_00); + + ddr_print("%-45s : 0x%x,0x%x,0x%x,0x%x\n", "VREF_VALUE", + lmc_modereg_params2.s.vref_value_11, + lmc_modereg_params2.s.vref_value_10, + lmc_modereg_params2.s.vref_value_01, + lmc_modereg_params2.s.vref_value_00); + + ddr_print("MODEREG_PARAMS2 : 0x%016lx\n", lmc_modereg_params2.u); + DRAM_CSR_WRITE(node, BDK_LMCX_MODEREG_PARAMS2(ddr_interface_num), lmc_modereg_params2.u); + + } /* LMC(0)_MODEREG_PARAMS2 */ + + /* LMC(0)_MODEREG_PARAMS3 */ + if (ddr_type == DDR4_DRAM) { + bdk_lmcx_modereg_params3_t lmc_modereg_params3; + + lmc_modereg_params3.u = BDK_CSR_READ(node, BDK_LMCX_MODEREG_PARAMS3(ddr_interface_num)); + + //lmc_modereg_params3.s.max_pd = + //lmc_modereg_params3.s.tc_ref = + //lmc_modereg_params3.s.vref_mon = + //lmc_modereg_params3.s.cal = + //lmc_modereg_params3.s.sre_abort = + //lmc_modereg_params3.s.rd_preamble = + //lmc_modereg_params3.s.wr_preamble = + //lmc_modereg_params3.s.par_lat_mode = + //lmc_modereg_params3.s.odt_pd = + //lmc_modereg_params3.s.ca_par_pers = + //lmc_modereg_params3.s.dm = + //lmc_modereg_params3.s.wr_dbi = + //lmc_modereg_params3.s.rd_dbi = + lmc_modereg_params3.s.tccd_l = max(divide_roundup(ddr4_tCCD_Lmin, tclk_psecs), 5ull) - 4; + //lmc_modereg_params3.s.lpasr = + //lmc_modereg_params3.s.crc = + //lmc_modereg_params3.s.gd = + //lmc_modereg_params3.s.pda = + //lmc_modereg_params3.s.temp_sense = + //lmc_modereg_params3.s.fgrm = + //lmc_modereg_params3.s.wr_cmd_lat = + //lmc_modereg_params3.s.mpr_fmt = + + if (!CAVIUM_IS_MODEL(CAVIUM_CN88XX_PASS1_X)) { + int delay = 0; + if ((lranks_per_prank == 4) && (ddr_hertz >= 1000000000)) + delay = 1; + lmc_modereg_params3.s.xrank_add_tccd_l = delay; + lmc_modereg_params3.s.xrank_add_tccd_s = delay; + } + + ddr_print("MODEREG_PARAMS3 : 0x%016lx\n", lmc_modereg_params3.u); + DRAM_CSR_WRITE(node, BDK_LMCX_MODEREG_PARAMS3(ddr_interface_num), lmc_modereg_params3.u); + } /* LMC(0)_MODEREG_PARAMS3 */ + + /* LMC(0)_NXM */ + { + bdk_lmcx_nxm_t lmc_nxm; + int num_bits = row_lsb + row_bits + lranks_bits - 26; + lmc_nxm.u = BDK_CSR_READ(node, BDK_LMCX_NXM(ddr_interface_num)); + + if (rank_mask & 0x1) + lmc_nxm.s.mem_msb_d0_r0 = num_bits; + if (rank_mask & 0x2) + lmc_nxm.s.mem_msb_d0_r1 = num_bits; + if (rank_mask & 0x4) + lmc_nxm.s.mem_msb_d1_r0 = num_bits; + if (rank_mask & 0x8) + lmc_nxm.s.mem_msb_d1_r1 = num_bits; + + lmc_nxm.s.cs_mask = ~rank_mask & 0xff; /* Set the mask for non-existant ranks. */ + + if ((s = lookup_env_parameter_ull("ddr_nxm")) != NULL) { + lmc_nxm.u = strtoull(s, NULL, 0); + } + ddr_print("LMC_NXM : 0x%016lx\n", lmc_nxm.u); + DRAM_CSR_WRITE(node, BDK_LMCX_NXM(ddr_interface_num), lmc_nxm.u); + } + + /* LMC(0)_WODT_MASK */ + { + bdk_lmcx_wodt_mask_t lmc_wodt_mask; + lmc_wodt_mask.u = odt_config[odt_idx].odt_mask; + + if ((s = lookup_env_parameter_ull("ddr_wodt_mask")) != NULL) { + lmc_wodt_mask.u = strtoull(s, NULL, 0); + } + + ddr_print("WODT_MASK : 0x%016lx\n", lmc_wodt_mask.u); + DRAM_CSR_WRITE(node, BDK_LMCX_WODT_MASK(ddr_interface_num), lmc_wodt_mask.u); + } + + /* LMC(0)_RODT_MASK */ + { + int rankx; + bdk_lmcx_rodt_mask_t lmc_rodt_mask; + lmc_rodt_mask.u = odt_config[odt_idx].rodt_ctl; + + if ((s = lookup_env_parameter_ull("ddr_rodt_mask")) != NULL) { + lmc_rodt_mask.u = strtoull(s, NULL, 0); + } + + ddr_print("%-45s : 0x%016lx\n", "RODT_MASK", lmc_rodt_mask.u); + DRAM_CSR_WRITE(node, BDK_LMCX_RODT_MASK(ddr_interface_num), lmc_rodt_mask.u); + + dyn_rtt_nom_mask = 0; + for (rankx = 0; rankx < dimm_count * 4;rankx++) { + if (!(rank_mask & (1 << rankx))) + continue; + dyn_rtt_nom_mask |= ((lmc_rodt_mask.u >> (8*rankx)) & 0xff); + } + if (num_ranks == 4) { + /* Normally ODT1 is wired to rank 1. For quad-ranked DIMMs + ODT1 is wired to the third rank (rank 2). The mask, + dyn_rtt_nom_mask, is used to indicate for which ranks + to sweep RTT_NOM during read-leveling. Shift the bit + from the ODT1 position over to the "ODT2" position so + that the read-leveling analysis comes out right. */ + int odt1_bit = dyn_rtt_nom_mask & 2; + dyn_rtt_nom_mask &= ~2; + dyn_rtt_nom_mask |= odt1_bit<<1; + } + ddr_print("%-45s : 0x%02x\n", "DYN_RTT_NOM_MASK", dyn_rtt_nom_mask); + } + + /* LMC(0)_COMP_CTL2 */ + { + bdk_lmcx_comp_ctl2_t comp_ctl2; + + comp_ctl2.u = BDK_CSR_READ(node, BDK_LMCX_COMP_CTL2(ddr_interface_num)); + + comp_ctl2.s.dqx_ctl = odt_config[odt_idx].odt_ena; + comp_ctl2.s.ck_ctl = (custom_lmc_config->ck_ctl == 0) ? 4 : custom_lmc_config->ck_ctl; /* Default 4=34.3 ohm */ + comp_ctl2.s.cmd_ctl = (custom_lmc_config->cmd_ctl == 0) ? 4 : custom_lmc_config->cmd_ctl; /* Default 4=34.3 ohm */ + comp_ctl2.s.control_ctl = (custom_lmc_config->ctl_ctl == 0) ? 4 : custom_lmc_config->ctl_ctl; /* Default 4=34.3 ohm */ + + // NOTE: these are now done earlier, in Step 6.9.3 + // comp_ctl2.s.ntune_offset = 0; + // comp_ctl2.s.ptune_offset = 0; + + ddr_rodt_ctl_auto = custom_lmc_config->ddr_rodt_ctl_auto; + if ((s = lookup_env_parameter("ddr_rodt_ctl_auto")) != NULL) { + ddr_rodt_ctl_auto = !!strtoul(s, NULL, 0); + } + + default_rodt_ctl = odt_config[odt_idx].qs_dic; + if ((s = lookup_env_parameter("ddr_rodt_ctl")) == NULL) + s = lookup_env_parameter("ddr%d_rodt_ctl", ddr_interface_num); + if (s != NULL) { + default_rodt_ctl = strtoul(s, NULL, 0); + ddr_rodt_ctl_auto = 0; + } + + comp_ctl2.s.rodt_ctl = default_rodt_ctl; + + // if DDR4, force CK_CTL to 26 ohms if it is currently 34 ohms, and DCLK speed is 1 GHz or more... + if ((ddr_type == DDR4_DRAM) && (comp_ctl2.s.ck_ctl == ddr4_driver_34_ohm) && (ddr_hertz >= 1000000000)) { + comp_ctl2.s.ck_ctl = ddr4_driver_26_ohm; // lowest for DDR4 is 26 ohms + ddr_print("Forcing DDR4 COMP_CTL2[CK_CTL] to %d, %d ohms\n", comp_ctl2.s.ck_ctl, + imp_values->drive_strength[comp_ctl2.s.ck_ctl]); + } + + if ((s = lookup_env_parameter("ddr_ck_ctl")) != NULL) { + comp_ctl2.s.ck_ctl = strtoul(s, NULL, 0); + } + + if ((s = lookup_env_parameter("ddr_cmd_ctl")) != NULL) { + comp_ctl2.s.cmd_ctl = strtoul(s, NULL, 0); + } + + if ((s = lookup_env_parameter("ddr_control_ctl")) != NULL) { + comp_ctl2.s.control_ctl = strtoul(s, NULL, 0); + } + + if ((s = lookup_env_parameter("ddr_dqx_ctl")) != NULL) { + comp_ctl2.s.dqx_ctl = strtoul(s, NULL, 0); + } + + ddr_print("%-45s : %d, %d ohms\n", "DQX_CTL ", comp_ctl2.s.dqx_ctl, + imp_values->dqx_strength [comp_ctl2.s.dqx_ctl ]); + ddr_print("%-45s : %d, %d ohms\n", "CK_CTL ", comp_ctl2.s.ck_ctl, + imp_values->drive_strength[comp_ctl2.s.ck_ctl ]); + ddr_print("%-45s : %d, %d ohms\n", "CMD_CTL ", comp_ctl2.s.cmd_ctl, + imp_values->drive_strength[comp_ctl2.s.cmd_ctl ]); + ddr_print("%-45s : %d, %d ohms\n", "CONTROL_CTL ", comp_ctl2.s.control_ctl, + imp_values->drive_strength[comp_ctl2.s.control_ctl]); + ddr_print("Read ODT_CTL : 0x%x (%d ohms)\n", + comp_ctl2.s.rodt_ctl, imp_values->rodt_ohms[comp_ctl2.s.rodt_ctl]); + + DRAM_CSR_WRITE(node, BDK_LMCX_COMP_CTL2(ddr_interface_num), comp_ctl2.u); + } + + /* LMC(0)_PHY_CTL */ + { + bdk_lmcx_phy_ctl_t lmc_phy_ctl; + lmc_phy_ctl.u = BDK_CSR_READ(node, BDK_LMCX_PHY_CTL(ddr_interface_num)); + lmc_phy_ctl.s.ts_stagger = 0; + + if (!CAVIUM_IS_MODEL(CAVIUM_CN88XX_PASS1_X) && (lranks_per_prank > 1)) { + lmc_phy_ctl.cn81xx.c0_sel = lmc_phy_ctl.cn81xx.c1_sel = 2; // C0 is TEN, C1 is A17 + ddr_print("N%d.LMC%d: 3DS: setting PHY_CTL[cx_csel] = %d\n", + node, ddr_interface_num, lmc_phy_ctl.cn81xx.c1_sel); + } + + ddr_print("PHY_CTL : 0x%016lx\n", lmc_phy_ctl.u); + DRAM_CSR_WRITE(node, BDK_LMCX_PHY_CTL(ddr_interface_num), lmc_phy_ctl.u); + } + + /* LMC(0)_DIMM0/1_PARAMS */ + if (spd_rdimm) { + bdk_lmcx_dimm_ctl_t lmc_dimm_ctl; + + for (didx = 0; didx < (unsigned)dimm_count; ++didx) { + bdk_lmcx_dimmx_params_t lmc_dimmx_params; + int dimm = didx; + int rc; + + lmc_dimmx_params.u = BDK_CSR_READ(node, BDK_LMCX_DIMMX_PARAMS(ddr_interface_num, dimm)); + + + if (ddr_type == DDR4_DRAM) { + + bdk_lmcx_dimmx_ddr4_params0_t lmc_dimmx_ddr4_params0; + bdk_lmcx_dimmx_ddr4_params1_t lmc_dimmx_ddr4_params1; + bdk_lmcx_ddr4_dimm_ctl_t lmc_ddr4_dimm_ctl; + + lmc_dimmx_params.s.rc0 = 0; + lmc_dimmx_params.s.rc1 = 0; + lmc_dimmx_params.s.rc2 = 0; + + rc = read_spd(node, &dimm_config_table[didx], DDR4_SPD_RDIMM_REGISTER_DRIVE_STRENGTH_CTL); + lmc_dimmx_params.s.rc3 = (rc >> 4) & 0xf; + lmc_dimmx_params.s.rc4 = ((rc >> 0) & 0x3) << 2; + lmc_dimmx_params.s.rc4 |= ((rc >> 2) & 0x3) << 0; + + rc = read_spd(node, &dimm_config_table[didx], DDR4_SPD_RDIMM_REGISTER_DRIVE_STRENGTH_CK); + lmc_dimmx_params.s.rc5 = ((rc >> 0) & 0x3) << 2; + lmc_dimmx_params.s.rc5 |= ((rc >> 2) & 0x3) << 0; + + lmc_dimmx_params.s.rc6 = 0; + lmc_dimmx_params.s.rc7 = 0; + lmc_dimmx_params.s.rc8 = 0; + lmc_dimmx_params.s.rc9 = 0; + + /* + ** rc10 DDR4 RDIMM Operating Speed + ** ==== ========================================================= + ** 0 tclk_psecs >= 1250 psec DDR4-1600 (1250 ps) + ** 1 1250 psec > tclk_psecs >= 1071 psec DDR4-1866 (1071 ps) + ** 2 1071 psec > tclk_psecs >= 938 psec DDR4-2133 ( 938 ps) + ** 3 938 psec > tclk_psecs >= 833 psec DDR4-2400 ( 833 ps) + ** 4 833 psec > tclk_psecs >= 750 psec DDR4-2666 ( 750 ps) + ** 5 750 psec > tclk_psecs >= 625 psec DDR4-3200 ( 625 ps) + */ + lmc_dimmx_params.s.rc10 = 0; + if (1250 > tclk_psecs) + lmc_dimmx_params.s.rc10 = 1; + if (1071 > tclk_psecs) + lmc_dimmx_params.s.rc10 = 2; + if (938 > tclk_psecs) + lmc_dimmx_params.s.rc10 = 3; + if (833 > tclk_psecs) + lmc_dimmx_params.s.rc10 = 4; + if (750 > tclk_psecs) + lmc_dimmx_params.s.rc10 = 5; + + lmc_dimmx_params.s.rc11 = 0; + lmc_dimmx_params.s.rc12 = 0; + lmc_dimmx_params.s.rc13 = (spd_dimm_type == 4) ? 0 : 4; /* 0=LRDIMM, 1=RDIMM */ + lmc_dimmx_params.s.rc13 |= (ddr_type == DDR4_DRAM) ? (spd_addr_mirror << 3) : 0; + lmc_dimmx_params.s.rc14 = 0; + //lmc_dimmx_params.s.rc15 = 4; /* 0 nCK latency adder */ + lmc_dimmx_params.s.rc15 = 0; /* 1 nCK latency adder */ + + lmc_dimmx_ddr4_params0.u = 0; + + lmc_dimmx_ddr4_params0.s.rc8x = 0; + lmc_dimmx_ddr4_params0.s.rc7x = 0; + lmc_dimmx_ddr4_params0.s.rc6x = 0; + lmc_dimmx_ddr4_params0.s.rc5x = 0; + lmc_dimmx_ddr4_params0.s.rc4x = 0; + + lmc_dimmx_ddr4_params0.s.rc3x = compute_rc3x(tclk_psecs); + + lmc_dimmx_ddr4_params0.s.rc2x = 0; + lmc_dimmx_ddr4_params0.s.rc1x = 0; + + lmc_dimmx_ddr4_params1.u = 0; + + lmc_dimmx_ddr4_params1.s.rcbx = 0; + lmc_dimmx_ddr4_params1.s.rcax = 0; + lmc_dimmx_ddr4_params1.s.rc9x = 0; + + lmc_ddr4_dimm_ctl.u = 0; + lmc_ddr4_dimm_ctl.s.ddr4_dimm0_wmask = 0x004; + lmc_ddr4_dimm_ctl.s.ddr4_dimm1_wmask = (dimm_count > 1) ? 0x004 : 0x0000; + + /* + * Handle any overrides from envvars here... + */ + if ((s = lookup_env_parameter("ddr_ddr4_params0")) != NULL) { + lmc_dimmx_ddr4_params0.u = strtoul(s, NULL, 0); + } + + if ((s = lookup_env_parameter("ddr_ddr4_params1")) != NULL) { + lmc_dimmx_ddr4_params1.u = strtoul(s, NULL, 0); + } + + if ((s = lookup_env_parameter("ddr_ddr4_dimm_ctl")) != NULL) { + lmc_ddr4_dimm_ctl.u = strtoul(s, NULL, 0); + } + + for (i=0; i<11; ++i) { + uint64_t value; + if ((s = lookup_env_parameter("ddr_ddr4_rc%1xx", i+1)) != NULL) { + value = strtoul(s, NULL, 0); + if (i < 8) { + lmc_dimmx_ddr4_params0.u &= ~((uint64_t)0xff << (i*8)); + lmc_dimmx_ddr4_params0.u |= (value << (i*8)); + } else { + lmc_dimmx_ddr4_params1.u &= ~((uint64_t)0xff << ((i-8)*8)); + lmc_dimmx_ddr4_params1.u |= (value << ((i-8)*8)); + } + } + } + + /* + * write the final CSR values + */ + DRAM_CSR_WRITE(node, BDK_LMCX_DIMMX_DDR4_PARAMS0(ddr_interface_num, dimm), lmc_dimmx_ddr4_params0.u); + + DRAM_CSR_WRITE(node, BDK_LMCX_DDR4_DIMM_CTL(ddr_interface_num), lmc_ddr4_dimm_ctl.u); + + DRAM_CSR_WRITE(node, BDK_LMCX_DIMMX_DDR4_PARAMS1(ddr_interface_num, dimm), lmc_dimmx_ddr4_params1.u); + + ddr_print("DIMM%d Register Control Words RCBx:RC1x : %x %x %x %x %x %x %x %x %x %x %x\n", + dimm, + lmc_dimmx_ddr4_params1.s.rcbx, + lmc_dimmx_ddr4_params1.s.rcax, + lmc_dimmx_ddr4_params1.s.rc9x, + lmc_dimmx_ddr4_params0.s.rc8x, + lmc_dimmx_ddr4_params0.s.rc7x, + lmc_dimmx_ddr4_params0.s.rc6x, + lmc_dimmx_ddr4_params0.s.rc5x, + lmc_dimmx_ddr4_params0.s.rc4x, + lmc_dimmx_ddr4_params0.s.rc3x, + lmc_dimmx_ddr4_params0.s.rc2x, + lmc_dimmx_ddr4_params0.s.rc1x ); + + } else { /* if (ddr_type == DDR4_DRAM) */ + rc = read_spd(node, &dimm_config_table[didx], 69); + lmc_dimmx_params.s.rc0 = (rc >> 0) & 0xf; + lmc_dimmx_params.s.rc1 = (rc >> 4) & 0xf; + + rc = read_spd(node, &dimm_config_table[didx], 70); + lmc_dimmx_params.s.rc2 = (rc >> 0) & 0xf; + lmc_dimmx_params.s.rc3 = (rc >> 4) & 0xf; + + rc = read_spd(node, &dimm_config_table[didx], 71); + lmc_dimmx_params.s.rc4 = (rc >> 0) & 0xf; + lmc_dimmx_params.s.rc5 = (rc >> 4) & 0xf; + + rc = read_spd(node, &dimm_config_table[didx], 72); + lmc_dimmx_params.s.rc6 = (rc >> 0) & 0xf; + lmc_dimmx_params.s.rc7 = (rc >> 4) & 0xf; + + rc = read_spd(node, &dimm_config_table[didx], 73); + lmc_dimmx_params.s.rc8 = (rc >> 0) & 0xf; + lmc_dimmx_params.s.rc9 = (rc >> 4) & 0xf; + + rc = read_spd(node, &dimm_config_table[didx], 74); + lmc_dimmx_params.s.rc10 = (rc >> 0) & 0xf; + lmc_dimmx_params.s.rc11 = (rc >> 4) & 0xf; + + rc = read_spd(node, &dimm_config_table[didx], 75); + lmc_dimmx_params.s.rc12 = (rc >> 0) & 0xf; + lmc_dimmx_params.s.rc13 = (rc >> 4) & 0xf; + + rc = read_spd(node, &dimm_config_table[didx], 76); + lmc_dimmx_params.s.rc14 = (rc >> 0) & 0xf; + lmc_dimmx_params.s.rc15 = (rc >> 4) & 0xf; + + + if ((s = lookup_env_parameter("ddr_clk_drive")) != NULL) { + if (strcmp(s,"light") == 0) { + lmc_dimmx_params.s.rc5 = 0x0; /* Light Drive */ + } + if (strcmp(s,"moderate") == 0) { + lmc_dimmx_params.s.rc5 = 0x5; /* Moderate Drive */ + } + if (strcmp(s,"strong") == 0) { + lmc_dimmx_params.s.rc5 = 0xA; /* Strong Drive */ + } + } + + if ((s = lookup_env_parameter("ddr_cmd_drive")) != NULL) { + if (strcmp(s,"light") == 0) { + lmc_dimmx_params.s.rc3 = 0x0; /* Light Drive */ + } + if (strcmp(s,"moderate") == 0) { + lmc_dimmx_params.s.rc3 = 0x5; /* Moderate Drive */ + } + if (strcmp(s,"strong") == 0) { + lmc_dimmx_params.s.rc3 = 0xA; /* Strong Drive */ + } + } + + if ((s = lookup_env_parameter("ddr_ctl_drive")) != NULL) { + if (strcmp(s,"light") == 0) { + lmc_dimmx_params.s.rc4 = 0x0; /* Light Drive */ + } + if (strcmp(s,"moderate") == 0) { + lmc_dimmx_params.s.rc4 = 0x5; /* Moderate Drive */ + } + } + + + /* + ** rc10 DDR3 RDIMM Operating Speed + ** ==== ========================================================= + ** 0 tclk_psecs >= 2500 psec DDR3/DDR3L-800 (default) + ** 1 2500 psec > tclk_psecs >= 1875 psec DDR3/DDR3L-1066 + ** 2 1875 psec > tclk_psecs >= 1500 psec DDR3/DDR3L-1333 + ** 3 1500 psec > tclk_psecs >= 1250 psec DDR3/DDR3L-1600 + ** 4 1250 psec > tclk_psecs >= 1071 psec DDR3-1866 + */ + lmc_dimmx_params.s.rc10 = 0; + if (2500 > tclk_psecs) + lmc_dimmx_params.s.rc10 = 1; + if (1875 > tclk_psecs) + lmc_dimmx_params.s.rc10 = 2; + if (1500 > tclk_psecs) + lmc_dimmx_params.s.rc10 = 3; + if (1250 > tclk_psecs) + lmc_dimmx_params.s.rc10 = 4; + + } /* if (ddr_type == DDR4_DRAM) */ + + if ((s = lookup_env_parameter("ddr_dimmx_params")) != NULL) { + lmc_dimmx_params.u = strtoul(s, NULL, 0); + } + + for (i=0; i<16; ++i) { + uint64_t value; + if ((s = lookup_env_parameter("ddr_rc%d", i)) != NULL) { + value = strtoul(s, NULL, 0); + lmc_dimmx_params.u &= ~((uint64_t)0xf << (i*4)); + lmc_dimmx_params.u |= ( value << (i*4)); + } + } + + DRAM_CSR_WRITE(node, BDK_LMCX_DIMMX_PARAMS(ddr_interface_num, dimm), lmc_dimmx_params.u); + + ddr_print("DIMM%d Register Control Words RC15:RC0 : %x %x %x %x %x %x %x %x %x %x %x %x %x %x %x %x\n", + dimm, + lmc_dimmx_params.s.rc15, + lmc_dimmx_params.s.rc14, + lmc_dimmx_params.s.rc13, + lmc_dimmx_params.s.rc12, + lmc_dimmx_params.s.rc11, + lmc_dimmx_params.s.rc10, + lmc_dimmx_params.s.rc9 , + lmc_dimmx_params.s.rc8 , + lmc_dimmx_params.s.rc7 , + lmc_dimmx_params.s.rc6 , + lmc_dimmx_params.s.rc5 , + lmc_dimmx_params.s.rc4 , + lmc_dimmx_params.s.rc3 , + lmc_dimmx_params.s.rc2 , + lmc_dimmx_params.s.rc1 , + lmc_dimmx_params.s.rc0 ); + } /* for didx */ + + if (ddr_type == DDR4_DRAM) { + + /* LMC0_DIMM_CTL */ + lmc_dimm_ctl.u = BDK_CSR_READ(node, BDK_LMCX_DIMM_CTL(ddr_interface_num)); + lmc_dimm_ctl.s.dimm0_wmask = 0xdf3f; + lmc_dimm_ctl.s.dimm1_wmask = (dimm_count > 1) ? 0xdf3f : 0x0000; + lmc_dimm_ctl.s.tcws = 0x4e0; + lmc_dimm_ctl.cn88xx.parity = custom_lmc_config->parity; + + if ((s = lookup_env_parameter("ddr_dimm0_wmask")) != NULL) { + lmc_dimm_ctl.s.dimm0_wmask = strtoul(s, NULL, 0); + } + + if ((s = lookup_env_parameter("ddr_dimm1_wmask")) != NULL) { + lmc_dimm_ctl.s.dimm1_wmask = strtoul(s, NULL, 0); + } + + if ((s = lookup_env_parameter("ddr_dimm_ctl_parity")) != NULL) { + lmc_dimm_ctl.cn88xx.parity = strtoul(s, NULL, 0); + } + + if ((s = lookup_env_parameter("ddr_dimm_ctl_tcws")) != NULL) { + lmc_dimm_ctl.s.tcws = strtoul(s, NULL, 0); + } + + ddr_print("LMC DIMM_CTL : 0x%016lx\n", lmc_dimm_ctl.u); + DRAM_CSR_WRITE(node, BDK_LMCX_DIMM_CTL(ddr_interface_num), lmc_dimm_ctl.u); + + perform_octeon3_ddr3_sequence(node, rank_mask, + ddr_interface_num, 0x7 ); /* Init RCW */ + + /* Write RC0D last */ + lmc_dimm_ctl.s.dimm0_wmask = 0x2000; + lmc_dimm_ctl.s.dimm1_wmask = (dimm_count > 1) ? 0x2000 : 0x0000; + ddr_print("LMC DIMM_CTL : 0x%016lx\n", lmc_dimm_ctl.u); + DRAM_CSR_WRITE(node, BDK_LMCX_DIMM_CTL(ddr_interface_num), lmc_dimm_ctl.u); + + /* Don't write any extended registers the second time */ + DRAM_CSR_WRITE(node, BDK_LMCX_DDR4_DIMM_CTL(ddr_interface_num), 0); + + perform_octeon3_ddr3_sequence(node, rank_mask, + ddr_interface_num, 0x7 ); /* Init RCW */ + } else { + + /* LMC0_DIMM_CTL */ + lmc_dimm_ctl.u = BDK_CSR_READ(node, BDK_LMCX_DIMM_CTL(ddr_interface_num)); + lmc_dimm_ctl.s.dimm0_wmask = 0xffff; + lmc_dimm_ctl.s.dimm1_wmask = (dimm_count > 1) ? 0xffff : 0x0000; + lmc_dimm_ctl.s.tcws = 0x4e0; + lmc_dimm_ctl.cn88xx.parity = custom_lmc_config->parity; + + if ((s = lookup_env_parameter("ddr_dimm0_wmask")) != NULL) { + lmc_dimm_ctl.s.dimm0_wmask = strtoul(s, NULL, 0); + } + + if ((s = lookup_env_parameter("ddr_dimm1_wmask")) != NULL) { + lmc_dimm_ctl.s.dimm1_wmask = strtoul(s, NULL, 0); + } + + if ((s = lookup_env_parameter("ddr_dimm_ctl_parity")) != NULL) { + lmc_dimm_ctl.cn88xx.parity = strtoul(s, NULL, 0); + } + + if ((s = lookup_env_parameter("ddr_dimm_ctl_tcws")) != NULL) { + lmc_dimm_ctl.s.tcws = strtoul(s, NULL, 0); + } + + ddr_print("LMC DIMM_CTL : 0x%016lx\n", lmc_dimm_ctl.u); + DRAM_CSR_WRITE(node, BDK_LMCX_DIMM_CTL(ddr_interface_num), lmc_dimm_ctl.u); + + perform_octeon3_ddr3_sequence(node, rank_mask, + ddr_interface_num, 0x7 ); /* Init RCW */ + } + } else { /* if (spd_rdimm) */ + /* Disable register control writes for unbuffered */ + bdk_lmcx_dimm_ctl_t lmc_dimm_ctl; + lmc_dimm_ctl.u = BDK_CSR_READ(node, BDK_LMCX_DIMM_CTL(ddr_interface_num)); + lmc_dimm_ctl.s.dimm0_wmask = 0; + lmc_dimm_ctl.s.dimm1_wmask = 0; + DRAM_CSR_WRITE(node, BDK_LMCX_DIMM_CTL(ddr_interface_num), lmc_dimm_ctl.u); + } /* if (spd_rdimm) */ + + /* + * Comments (steps 3 through 5) continue in perform_octeon3_ddr3_sequence() + */ + { + bdk_lmcx_modereg_params0_t lmc_modereg_params0; + + if (ddr_memory_preserved(node)) { + /* Contents are being preserved. Take DRAM out of + self-refresh first. Then init steps can procede + normally */ + perform_octeon3_ddr3_sequence(node, rank_mask, + ddr_interface_num, 3); /* self-refresh exit */ + } + + lmc_modereg_params0.u = BDK_CSR_READ(node, BDK_LMCX_MODEREG_PARAMS0(ddr_interface_num)); + + lmc_modereg_params0.s.dllr = 1; /* Set during first init sequence */ + DRAM_CSR_WRITE(node, BDK_LMCX_MODEREG_PARAMS0(ddr_interface_num), lmc_modereg_params0.u); + + perform_ddr_init_sequence(node, rank_mask, ddr_interface_num); + + lmc_modereg_params0.s.dllr = 0; /* Clear for normal operation */ + DRAM_CSR_WRITE(node, BDK_LMCX_MODEREG_PARAMS0(ddr_interface_num), lmc_modereg_params0.u); + } + + // NOTE: this must be done for pass 2.x and pass 1.x + if ((spd_rdimm) && (ddr_type == DDR4_DRAM)) { + VB_PRT(VBL_FAE, "Running init sequence 1\n"); + change_rdimm_mpr_pattern(node, rank_mask, ddr_interface_num, dimm_count); + } + +#define DEFAULT_INTERNAL_VREF_TRAINING_LIMIT 5 + int internal_retries = 0; + int deskew_training_errors; + int dac_eval_retries; + int dac_settings[9]; + int num_samples; + int sample, lane; + int last_lane = ((ddr_interface_64b) ? 8 : 4) + use_ecc; + +#define DEFAULT_DAC_SAMPLES 7 // originally was 5 +#define DAC_RETRIES_LIMIT 2 + + typedef struct { + int16_t bytes[DEFAULT_DAC_SAMPLES]; + } bytelane_sample_t; + bytelane_sample_t lanes[9]; + + memset(lanes, 0, sizeof(lanes)); + + if ((ddr_type == DDR4_DRAM) && !CAVIUM_IS_MODEL(CAVIUM_CN88XX_PASS1_X)) { + num_samples = DEFAULT_DAC_SAMPLES; + } else { + num_samples = 1; // if DDR3 or no ability to write DAC values + } + + perform_internal_vref_training: + + for (sample = 0; sample < num_samples; sample++) { + + dac_eval_retries = 0; + + do { // make offset and internal vref training repeatable + + /* 6.9.8 LMC Offset Training + LMC requires input-receiver offset training. */ + Perform_Offset_Training(node, rank_mask, ddr_interface_num); + + /* 6.9.9 LMC Internal Vref Training + LMC requires input-reference-voltage training. */ + Perform_Internal_VREF_Training(node, rank_mask, ddr_interface_num); + + // read and maybe display the DAC values for a sample + read_DAC_DBI_settings(node, ddr_interface_num, /*DAC*/1, dac_settings); + if ((num_samples == 1) || dram_is_verbose(VBL_DEV)) { + display_DAC_DBI_settings(node, ddr_interface_num, /*DAC*/1, use_ecc, + dac_settings, "Internal VREF"); + } + + // for DDR4, evaluate the DAC settings and retry if any issues + if (ddr_type == DDR4_DRAM) { + if (evaluate_DAC_settings(ddr_interface_64b, use_ecc, dac_settings)) { + if (++dac_eval_retries > DAC_RETRIES_LIMIT) { + ddr_print("N%d.LMC%d: DDR4 internal VREF DAC settings: retries exhausted; continuing...\n", + node, ddr_interface_num); + } else { + ddr_print("N%d.LMC%d: DDR4 internal VREF DAC settings inconsistent; retrying....\n", + node, ddr_interface_num); // FIXME? verbosity!!! + continue; + } + } + if (num_samples > 1) { // taking multiple samples, otherwise do nothing + // good sample or exhausted retries, record it + for (lane = 0; lane < last_lane; lane++) { + lanes[lane].bytes[sample] = dac_settings[lane]; + } + } + } + break; // done if DDR3, or good sample, or exhausted retries + + } while (1); + + } /* for (sample = 0; sample < num_samples; sample++) */ + + if (num_samples > 1) { + debug_print("N%d.LMC%d: DDR4 internal VREF DAC settings: processing multiple samples...\n", + node, ddr_interface_num); + + for (lane = 0; lane < last_lane; lane++) { + dac_settings[lane] = process_samples_average(&lanes[lane].bytes[0], num_samples, + ddr_interface_num, lane); + } + display_DAC_DBI_settings(node, ddr_interface_num, /*DAC*/1, use_ecc, dac_settings, "Averaged VREF"); + + // finally, write the final DAC values + for (lane = 0; lane < last_lane; lane++) { + load_dac_override(node, ddr_interface_num, dac_settings[lane], lane); + } + } + +#if DAC_OVERRIDE_EARLY + // as a second step, after internal VREF training, before starting deskew training: + // for DDR3 and THUNDER pass 2.x, override the DAC setting to 127 + if ((ddr_type == DDR3_DRAM) && !CAVIUM_IS_MODEL(CAVIUM_CN88XX_PASS1_X)) { // added 81xx and 83xx + load_dac_override(node, ddr_interface_num, 127, /* all */0x0A); + ddr_print("N%d.LMC%d: Overriding DDR3 internal VREF DAC settings to 127 (early).\n", + node, ddr_interface_num); + } +#endif + + /* + * 6.9.10 LMC Read Deskew Training + * LMC requires input-read-data deskew training. + */ + if (! disable_deskew_training) { + + deskew_training_errors = Perform_Read_Deskew_Training(node, rank_mask, ddr_interface_num, + spd_rawcard_AorB, 0, ddr_interface_64b); + + // All the Deskew lock and saturation retries (may) have been done, + // but we ended up with nibble errors; so, as a last ditch effort, + // enable retries of the Internal Vref Training... + if (deskew_training_errors) { + if (internal_retries < DEFAULT_INTERNAL_VREF_TRAINING_LIMIT) { + internal_retries++; + VB_PRT(VBL_FAE, "N%d.LMC%d: Deskew training results still unsettled - retrying internal Vref training (%d)\n", + node, ddr_interface_num, internal_retries); + goto perform_internal_vref_training; + } else { + VB_PRT(VBL_FAE, "N%d.LMC%d: Deskew training incomplete - %d retries exhausted, but continuing...\n", + node, ddr_interface_num, internal_retries); + } + } + + // FIXME: treat this as the final DSK print from now on, and print if VBL_NORM or above + // also, save the results of the original training + Validate_Read_Deskew_Training(node, rank_mask, ddr_interface_num, &deskew_training_results, VBL_NORM); + + // setup write bit-deskew if enabled... + if (enable_write_deskew) { + ddr_print("N%d.LMC%d: WRITE BIT-DESKEW feature enabled- going NEUTRAL.\n", + node, ddr_interface_num); + Neutral_Write_Deskew_Setup(node, ddr_interface_num); + } /* if (enable_write_deskew) */ + + } /* if (! disable_deskew_training) */ + +#if !DAC_OVERRIDE_EARLY + // as a final step in internal VREF training, after deskew training but before HW WL: + // for DDR3 and THUNDER pass 2.x, override the DAC setting to 127 + if ((ddr_type == DDR3_DRAM) && !CAVIUM_IS_MODEL(CAVIUM_CN88XX_PASS1_X)) { // added 81xx and 83xx + load_dac_override(node, ddr_interface_num, 127, /* all */0x0A); + ddr_print("N%d.LMC%d, Overriding DDR3 internal VREF DAC settings to 127 (late).\n", + node, ddr_interface_num); + } +#endif + + + /* LMC(0)_EXT_CONFIG */ + { + bdk_lmcx_ext_config_t ext_config; + ext_config.u = BDK_CSR_READ(node, BDK_LMCX_EXT_CONFIG(ddr_interface_num)); + ext_config.s.vrefint_seq_deskew = 0; + ext_config.s.read_ena_bprch = 1; + ext_config.s.read_ena_fprch = 1; + ext_config.s.drive_ena_fprch = 1; + ext_config.s.drive_ena_bprch = 1; + ext_config.s.invert_data = 0; // make sure this is OFF for all current chips + + if ((s = lookup_env_parameter("ddr_read_fprch")) != NULL) { + ext_config.s.read_ena_fprch = strtoul(s, NULL, 0); + } + if ((s = lookup_env_parameter("ddr_read_bprch")) != NULL) { + ext_config.s.read_ena_bprch = strtoul(s, NULL, 0); + } + if ((s = lookup_env_parameter("ddr_drive_fprch")) != NULL) { + ext_config.s.drive_ena_fprch = strtoul(s, NULL, 0); + } + if ((s = lookup_env_parameter("ddr_drive_bprch")) != NULL) { + ext_config.s.drive_ena_bprch = strtoul(s, NULL, 0); + } + + if (!CAVIUM_IS_MODEL(CAVIUM_CN88XX_PASS1_X) && (lranks_per_prank > 1)) { + ext_config.s.dimm0_cid = ext_config.s.dimm1_cid = lranks_bits; + ddr_print("N%d.LMC%d: 3DS: setting EXT_CONFIG[dimmx_cid] = %d\n", + node, ddr_interface_num, ext_config.s.dimm0_cid); + } + + DRAM_CSR_WRITE(node, BDK_LMCX_EXT_CONFIG(ddr_interface_num), ext_config.u); + ddr_print("%-45s : 0x%016lx\n", "EXT_CONFIG", ext_config.u); + } + + + { + int save_ref_zqcs_int; + uint64_t temp_delay_usecs; + + lmc_config.u = BDK_CSR_READ(node, BDK_LMCX_CONFIG(ddr_interface_num)); + + /* Temporarily select the minimum ZQCS interval and wait + long enough for a few ZQCS calibrations to occur. This + should ensure that the calibration circuitry is + stabilized before read/write leveling occurs. */ + save_ref_zqcs_int = lmc_config.s.ref_zqcs_int; + lmc_config.s.ref_zqcs_int = 1 | (32<<7); /* set smallest interval */ + + DRAM_CSR_WRITE(node, BDK_LMCX_CONFIG(ddr_interface_num), lmc_config.u); + BDK_CSR_READ(node, BDK_LMCX_CONFIG(ddr_interface_num)); + + /* Compute an appropriate delay based on the current ZQCS + interval. The delay should be long enough for the + current ZQCS delay counter to expire plus ten of the + minimum intarvals to ensure that some calibrations + occur. */ + temp_delay_usecs = (((uint64_t)save_ref_zqcs_int >> 7) + * tclk_psecs * 100 * 512 * 128) / (10000*10000) + + 10 * ((uint64_t)32 * tclk_psecs * 100 * 512 * 128) / (10000*10000); + + VB_PRT(VBL_FAE, "N%d.LMC%d: Waiting %ld usecs for ZQCS calibrations to start\n", + node, ddr_interface_num, temp_delay_usecs); + bdk_wait_usec(temp_delay_usecs); + + lmc_config.s.ref_zqcs_int = save_ref_zqcs_int; /* Restore computed interval */ + + DRAM_CSR_WRITE(node, BDK_LMCX_CONFIG(ddr_interface_num), lmc_config.u); + BDK_CSR_READ(node, BDK_LMCX_CONFIG(ddr_interface_num)); + } + + /* + * 6.9.11 LMC Write Leveling + * + * LMC supports an automatic write leveling like that described in the + * JEDEC DDR3 specifications separately per byte-lane. + * + * All of DDR PLL, LMC CK, LMC DRESET, and early LMC initializations must + * be completed prior to starting this LMC write-leveling sequence. + * + * There are many possible procedures that will write-level all the + * attached DDR3 DRAM parts. One possibility is for software to simply + * write the desired values into LMC(0)_WLEVEL_RANK(0..3). This section + * describes one possible sequence that uses LMC's autowrite-leveling + * capabilities. + * + * 1. If the DQS/DQ delays on the board may be more than the ADD/CMD + * delays, then ensure that LMC(0)_CONFIG[EARLY_DQX] is set at this + * point. + * + * Do the remaining steps 2-7 separately for each rank i with attached + * DRAM. + * + * 2. Write LMC(0)_WLEVEL_RANKi = 0. + * + * 3. For ×8 parts: + * + * Without changing any other fields in LMC(0)_WLEVEL_CTL, write + * LMC(0)_WLEVEL_CTL[LANEMASK] to select all byte lanes with attached + * DRAM. + * + * For ×16 parts: + * + * Without changing any other fields in LMC(0)_WLEVEL_CTL, write + * LMC(0)_WLEVEL_CTL[LANEMASK] to select all even byte lanes with + * attached DRAM. + * + * 4. Without changing any other fields in LMC(0)_CONFIG, + * + * o write LMC(0)_SEQ_CTL[SEQ_SEL] to select write-leveling + * + * o write LMC(0)_CONFIG[RANKMASK] = (1 << i) + * + * o write LMC(0)_SEQ_CTL[INIT_START] = 1 + * + * LMC will initiate write-leveling at this point. Assuming + * LMC(0)_WLEVEL_CTL [SSET] = 0, LMC first enables write-leveling on + * the selected DRAM rank via a DDR3 MR1 write, then sequences through + * and accumulates write-leveling results for eight different delay + * settings twice, starting at a delay of zero in this case since + * LMC(0)_WLEVEL_RANKi[BYTE*<4:3>] = 0, increasing by 1/8 CK each + * setting, covering a total distance of one CK, then disables the + * write-leveling via another DDR3 MR1 write. + * + * After the sequence through 16 delay settings is complete: + * + * o LMC sets LMC(0)_WLEVEL_RANKi[STATUS] = 3 + * + * o LMC sets LMC(0)_WLEVEL_RANKi[BYTE*<2:0>] (for all ranks selected + * by LMC(0)_WLEVEL_CTL[LANEMASK]) to indicate the first write + * leveling result of 1 that followed result of 0 during the + * sequence, except that the LMC always writes + * LMC(0)_WLEVEL_RANKi[BYTE*<0>]=0. + * + * o Software can read the eight write-leveling results from the first + * pass through the delay settings by reading + * LMC(0)_WLEVEL_DBG[BITMASK] (after writing + * LMC(0)_WLEVEL_DBG[BYTE]). (LMC does not retain the writeleveling + * results from the second pass through the eight delay + * settings. They should often be identical to the + * LMC(0)_WLEVEL_DBG[BITMASK] results, though.) + * + * 5. Wait until LMC(0)_WLEVEL_RANKi[STATUS] != 2. + * + * LMC will have updated LMC(0)_WLEVEL_RANKi[BYTE*<2:0>] for all byte + * lanes selected by LMC(0)_WLEVEL_CTL[LANEMASK] at this point. + * LMC(0)_WLEVEL_RANKi[BYTE*<4:3>] will still be the value that + * software wrote in substep 2 above, which is 0. + * + * 6. For ×16 parts: + * + * Without changing any other fields in LMC(0)_WLEVEL_CTL, write + * LMC(0)_WLEVEL_CTL[LANEMASK] to select all odd byte lanes with + * attached DRAM. + * + * Repeat substeps 4 and 5 with this new LMC(0)_WLEVEL_CTL[LANEMASK] + * setting. Skip to substep 7 if this has already been done. + * + * For ×8 parts: + * + * Skip this substep. Go to substep 7. + * + * 7. Calculate LMC(0)_WLEVEL_RANKi[BYTE*<4:3>] settings for all byte + * lanes on all ranks with attached DRAM. + * + * At this point, all byte lanes on rank i with attached DRAM should + * have been write-leveled, and LMC(0)_WLEVEL_RANKi[BYTE*<2:0>] has + * the result for each byte lane. + * + * But note that the DDR3 write-leveling sequence will only determine + * the delay modulo the CK cycle time, and cannot determine how many + * additional CK cycles of delay are present. Software must calculate + * the number of CK cycles, or equivalently, the + * LMC(0)_WLEVEL_RANKi[BYTE*<4:3>] settings. + * + * This BYTE*<4:3> calculation is system/board specific. + * + * Many techniques can be used to calculate write-leveling BYTE*<4:3> values, + * including: + * + * o Known values for some byte lanes. + * + * o Relative values for some byte lanes relative to others. + * + * For example, suppose lane X is likely to require a larger + * write-leveling delay than lane Y. A BYTEX<2:0> value that is much + * smaller than the BYTEY<2:0> value may then indicate that the + * required lane X delay wrapped into the next CK, so BYTEX<4:3> + * should be set to BYTEY<4:3>+1. + * + * When ECC DRAM is not present (i.e. when DRAM is not attached to the + * DDR_CBS_0_* and DDR_CB<7:0> chip signals, or the DDR_DQS_<4>_* and + * DDR_DQ<35:32> chip signals), write LMC(0)_WLEVEL_RANK*[BYTE8] = + * LMC(0)_WLEVEL_RANK*[BYTE0], using the final calculated BYTE0 value. + * Write LMC(0)_WLEVEL_RANK*[BYTE4] = LMC(0)_WLEVEL_RANK*[BYTE0], + * using the final calculated BYTE0 value. + * + * 8. Initialize LMC(0)_WLEVEL_RANK* values for all unused ranks. + * + * Let rank i be a rank with attached DRAM. + * + * For all ranks j that do not have attached DRAM, set + * LMC(0)_WLEVEL_RANKj = LMC(0)_WLEVEL_RANKi. + */ + { // Start HW write-leveling block +#pragma pack(push,1) + bdk_lmcx_wlevel_ctl_t wlevel_ctl; + bdk_lmcx_wlevel_rankx_t lmc_wlevel_rank; + int rankx = 0; + int wlevel_bitmask[9]; + int byte_idx; + int ecc_ena; + int ddr_wlevel_roundup = 0; + int ddr_wlevel_printall = (dram_is_verbose(VBL_FAE)); // or default to 1 to print all HW WL samples + int disable_hwl_validity = 0; + int default_wlevel_rtt_nom; +#if WODT_MASK_2R_1S + uint64_t saved_wodt_mask = 0; +#endif +#pragma pack(pop) + + if (wlevel_loops) + ddr_print("N%d.LMC%d: Performing Hardware Write-Leveling\n", node, ddr_interface_num); + else { + wlevel_bitmask_errors = 1; /* Force software write-leveling to run */ + ddr_print("N%d.LMC%d: Forcing software Write-Leveling\n", node, ddr_interface_num); + } + + default_wlevel_rtt_nom = (ddr_type == DDR3_DRAM) ? rttnom_20ohm : ddr4_rttnom_40ohm ; /* FIXME? */ + +#if WODT_MASK_2R_1S + if ((ddr_type == DDR4_DRAM) && (num_ranks == 2) && (dimm_count == 1)) { + /* LMC(0)_WODT_MASK */ + bdk_lmcx_wodt_mask_t lmc_wodt_mask; + // always save original so we can always restore later + saved_wodt_mask = BDK_CSR_READ(node, BDK_LMCX_WODT_MASK(ddr_interface_num)); + if ((s = lookup_env_parameter_ull("ddr_hwl_wodt_mask")) != NULL) { + lmc_wodt_mask.u = strtoull(s, NULL, 0); + if (lmc_wodt_mask.u != saved_wodt_mask) { // print/store only when diff + ddr_print("WODT_MASK : 0x%016lx\n", lmc_wodt_mask.u); + DRAM_CSR_WRITE(node, BDK_LMCX_WODT_MASK(ddr_interface_num), lmc_wodt_mask.u); + } + } + } +#endif /* WODT_MASK_2R_1S */ + + lmc_config.u = BDK_CSR_READ(node, BDK_LMCX_CONFIG(ddr_interface_num)); + ecc_ena = lmc_config.s.ecc_ena; + + if ((s = lookup_env_parameter("ddr_wlevel_roundup")) != NULL) { + ddr_wlevel_roundup = strtoul(s, NULL, 0); + } + if ((s = lookup_env_parameter("ddr_wlevel_printall")) != NULL) { + ddr_wlevel_printall = strtoul(s, NULL, 0); + } + + if ((s = lookup_env_parameter("ddr_disable_hwl_validity")) != NULL) { + disable_hwl_validity = !!strtoul(s, NULL, 0); + } + + if ((s = lookup_env_parameter("ddr_wlevel_rtt_nom")) != NULL) { + default_wlevel_rtt_nom = strtoul(s, NULL, 0); + } + + // For DDR3, we leave the WLEVEL_CTL fields at default settings + // For DDR4, we touch WLEVEL_CTL fields OR_DIS or BITMASK here + if (ddr_type == DDR4_DRAM) { + int default_or_dis = 1; + int default_bitmask = 0xFF; + + // when x4, use only the lower nibble bits + if (dram_width == 4) { + default_bitmask = 0x0F; + VB_PRT(VBL_DEV, "N%d.LMC%d: WLEVEL_CTL: default bitmask is 0x%2x for DDR4 x4\n", + node, ddr_interface_num, default_bitmask); + } + + wlevel_ctl.u = BDK_CSR_READ(node, BDK_LMCX_WLEVEL_CTL(ddr_interface_num)); + wlevel_ctl.s.or_dis = default_or_dis; + wlevel_ctl.s.bitmask = default_bitmask; + + // allow overrides + if ((s = lookup_env_parameter("ddr_wlevel_ctl_or_dis")) != NULL) { + wlevel_ctl.s.or_dis = !!strtoul(s, NULL, 0); + } + if ((s = lookup_env_parameter("ddr_wlevel_ctl_bitmask")) != NULL) { + wlevel_ctl.s.bitmask = strtoul(s, NULL, 0); + } + + // print only if not defaults + if ((wlevel_ctl.s.or_dis != default_or_dis) || (wlevel_ctl.s.bitmask != default_bitmask)) { + ddr_print("N%d.LMC%d: WLEVEL_CTL: or_dis=%d, bitmask=0x%02x\n", + node, ddr_interface_num, wlevel_ctl.s.or_dis, wlevel_ctl.s.bitmask); + } + // always write + DRAM_CSR_WRITE(node, BDK_LMCX_WLEVEL_CTL(ddr_interface_num), wlevel_ctl.u); + } + + // Start the hardware write-leveling loop per rank + for (rankx = 0; rankx < dimm_count * 4; rankx++) { + + if (!(rank_mask & (1 << rankx))) + continue; + +#if HW_WL_MAJORITY + // array to collect counts of byte-lane values + // assume low-order 3 bits and even, so really only 2 bit values + int wlevel_bytes[9][4]; + memset(wlevel_bytes, 0, sizeof(wlevel_bytes)); +#endif + + // restructure the looping so we can keep trying until we get the samples we want + //for (int wloop = 0; wloop < wlevel_loops; wloop++) { + int wloop = 0; + int wloop_retries = 0; // retries per sample for HW-related issues with bitmasks or values + int wloop_retries_total = 0; + int wloop_retries_exhausted = 0; +#define WLOOP_RETRIES_DEFAULT 5 + int wlevel_validity_errors; + int wlevel_bitmask_errors_rank = 0; + int wlevel_validity_errors_rank = 0; + + while (wloop < wlevel_loops) { + + wlevel_ctl.u = BDK_CSR_READ(node, BDK_LMCX_WLEVEL_CTL(ddr_interface_num)); + + wlevel_ctl.s.rtt_nom = (default_wlevel_rtt_nom > 0) ? (default_wlevel_rtt_nom - 1) : 7; + + + DRAM_CSR_WRITE(node, BDK_LMCX_WLEVEL_RANKX(ddr_interface_num, rankx), 0); /* Clear write-level delays */ + + wlevel_bitmask_errors = 0; /* Reset error counters */ + wlevel_validity_errors = 0; + + for (byte_idx=0; byte_idx<9; ++byte_idx) { + wlevel_bitmask[byte_idx] = 0; /* Reset bitmasks */ + } + +#if HWL_BY_BYTE // FIXME??? + /* Make a separate pass for each byte to reduce power. */ + for (byte_idx=0; byte_idx<(8+ecc_ena); ++byte_idx) { + + if (!(ddr_interface_bytemask&(1<<byte_idx))) + continue; + + wlevel_ctl.s.lanemask = (1<<byte_idx); + + DRAM_CSR_WRITE(node, BDK_LMCX_WLEVEL_CTL(ddr_interface_num), wlevel_ctl.u); + + /* Read and write values back in order to update the + status field. This insures that we read the updated + values after write-leveling has completed. */ + DRAM_CSR_WRITE(node, BDK_LMCX_WLEVEL_RANKX(ddr_interface_num, rankx), + BDK_CSR_READ(node, BDK_LMCX_WLEVEL_RANKX(ddr_interface_num, rankx))); + + perform_octeon3_ddr3_sequence(node, 1 << rankx, ddr_interface_num, 6); /* write-leveling */ + + if (!bdk_is_platform(BDK_PLATFORM_ASIM) && + BDK_CSR_WAIT_FOR_FIELD(node, BDK_LMCX_WLEVEL_RANKX(ddr_interface_num, rankx), + status, ==, 3, 1000000)) + { + error_print("ERROR: Timeout waiting for WLEVEL\n"); + } + lmc_wlevel_rank.u = BDK_CSR_READ(node, BDK_LMCX_WLEVEL_RANKX(ddr_interface_num, rankx)); + + wlevel_bitmask[byte_idx] = octeon_read_lmcx_ddr3_wlevel_dbg(node, ddr_interface_num, byte_idx); + if (wlevel_bitmask[byte_idx] == 0) + ++wlevel_bitmask_errors; + } /* for (byte_idx=0; byte_idx<(8+ecc_ena); ++byte_idx) */ + + wlevel_ctl.s.lanemask = /*0x1ff*/ddr_interface_bytemask; // restore for RL + DRAM_CSR_WRITE(node, BDK_LMCX_WLEVEL_CTL(ddr_interface_num), wlevel_ctl.u); +#else + // do all the byte-lanes at the same time + wlevel_ctl.s.lanemask = /*0x1ff*/ddr_interface_bytemask; // FIXME? + + DRAM_CSR_WRITE(node, BDK_LMCX_WLEVEL_CTL(ddr_interface_num), wlevel_ctl.u); + + /* Read and write values back in order to update the + status field. This insures that we read the updated + values after write-leveling has completed. */ + DRAM_CSR_WRITE(node, BDK_LMCX_WLEVEL_RANKX(ddr_interface_num, rankx), + BDK_CSR_READ(node, BDK_LMCX_WLEVEL_RANKX(ddr_interface_num, rankx))); + + perform_octeon3_ddr3_sequence(node, 1 << rankx, ddr_interface_num, 6); /* write-leveling */ + + if (!bdk_is_platform(BDK_PLATFORM_ASIM) && + BDK_CSR_WAIT_FOR_FIELD(node, BDK_LMCX_WLEVEL_RANKX(ddr_interface_num, rankx), + status, ==, 3, 1000000)) + { + error_print("ERROR: Timeout waiting for WLEVEL\n"); + } + + lmc_wlevel_rank.u = BDK_CSR_READ(node, BDK_LMCX_WLEVEL_RANKX(ddr_interface_num, rankx)); + + for (byte_idx=0; byte_idx<(8+ecc_ena); ++byte_idx) { + if (!(ddr_interface_bytemask&(1<<byte_idx))) + continue; + wlevel_bitmask[byte_idx] = octeon_read_lmcx_ddr3_wlevel_dbg(node, ddr_interface_num, byte_idx); + if (wlevel_bitmask[byte_idx] == 0) + ++wlevel_bitmask_errors; + } /* for (byte_idx=0; byte_idx<(8+ecc_ena); ++byte_idx) */ +#endif + + // check validity only if no bitmask errors + if (wlevel_bitmask_errors == 0) { + if ((spd_dimm_type != 5) && + (spd_dimm_type != 6) && + (spd_dimm_type != 8) && + (spd_dimm_type != 9) && + (dram_width != 16) && + (ddr_interface_64b) && + !(disable_hwl_validity)) + { // bypass if mini-[RU]DIMM or x16 or 32-bit or SO-[RU]DIMM + wlevel_validity_errors = + Validate_HW_WL_Settings(node, ddr_interface_num, + &lmc_wlevel_rank, ecc_ena); + wlevel_validity_errors_rank += (wlevel_validity_errors != 0); + } + } else + wlevel_bitmask_errors_rank++; + + // before we print, if we had bitmask or validity errors, do a retry... + if ((wlevel_bitmask_errors != 0) || (wlevel_validity_errors != 0)) { + // VBL must be high to show the bad bitmaps or delays here also + if (dram_is_verbose(VBL_DEV2)) { + display_WL_BM(node, ddr_interface_num, rankx, wlevel_bitmask); + display_WL(node, ddr_interface_num, lmc_wlevel_rank, rankx); + } + if (wloop_retries < WLOOP_RETRIES_DEFAULT) { + wloop_retries++; + wloop_retries_total++; + // this printout is per-retry: only when VBL is high enough (DEV2?) + VB_PRT(VBL_DEV2, "N%d.LMC%d.R%d: H/W Write-Leveling had %s errors - retrying...\n", + node, ddr_interface_num, rankx, + (wlevel_bitmask_errors) ? "Bitmask" : "Validity"); + continue; // this takes us back to the top without counting a sample + } else { // ran out of retries for this sample + // retries exhausted, do not print at normal VBL + VB_PRT(VBL_DEV2, "N%d.LMC%d.R%d: H/W Write-Leveling issues: %s errors\n", + node, ddr_interface_num, rankx, + (wlevel_bitmask_errors) ? "Bitmask" : "Validity"); + wloop_retries_exhausted++; + } + } + // no errors or exhausted retries, use this sample + wloop_retries = 0; //reset for next sample + + // when only 1 sample or forced, print the bitmasks first and current HW WL + if ((wlevel_loops == 1) || ddr_wlevel_printall) { + display_WL_BM(node, ddr_interface_num, rankx, wlevel_bitmask); + display_WL(node, ddr_interface_num, lmc_wlevel_rank, rankx); + } + + if (ddr_wlevel_roundup) { /* Round up odd bitmask delays */ + for (byte_idx=0; byte_idx<(8+ecc_ena); ++byte_idx) { + if (!(ddr_interface_bytemask&(1<<byte_idx))) + continue; + update_wlevel_rank_struct(&lmc_wlevel_rank, + byte_idx, + roundup_ddr3_wlevel_bitmask(wlevel_bitmask[byte_idx])); + } /* for (byte_idx=0; byte_idx<(8+ecc_ena); ++byte_idx) */ + DRAM_CSR_WRITE(node, BDK_LMCX_WLEVEL_RANKX(ddr_interface_num, rankx), lmc_wlevel_rank.u); + display_WL(node, ddr_interface_num, lmc_wlevel_rank, rankx); + } + +#if HW_WL_MAJORITY + // OK, we have a decent sample, no bitmask or validity errors + for (byte_idx=0; byte_idx<(8+ecc_ena); ++byte_idx) { + if (!(ddr_interface_bytemask&(1<<byte_idx))) + continue; + // increment count of byte-lane value + int ix = (get_wlevel_rank_struct(&lmc_wlevel_rank, byte_idx) >> 1) & 3; // only 4 values + wlevel_bytes[byte_idx][ix]++; + } /* for (byte_idx=0; byte_idx<(8+ecc_ena); ++byte_idx) */ +#endif + + wloop++; // if we get here, we have taken a decent sample + + } /* while (wloop < wlevel_loops) */ + +#if HW_WL_MAJORITY + // if we did sample more than once, try to pick a majority vote + if (wlevel_loops > 1) { + // look for the majority in each byte-lane + for (byte_idx = 0; byte_idx < (8+ecc_ena); ++byte_idx) { + int mx = -1, mc = 0, xc = 0, cc = 0; + int ix, ic; + if (!(ddr_interface_bytemask&(1<<byte_idx))) + continue; + for (ix = 0; ix < 4; ix++) { + ic = wlevel_bytes[byte_idx][ix]; + // make a bitmask of the ones with a count + if (ic > 0) { + mc |= (1 << ix); + cc++; // count how many had non-zero counts + } + // find the majority + if (ic > xc) { // new max? + xc = ic; // yes + mx = ix; // set its index + } + } +#if SWL_TRY_HWL_ALT + // see if there was an alternate + int alts = (mc & ~(1 << mx)); // take out the majority choice + if (alts != 0) { + for (ix = 0; ix < 4; ix++) { + if (alts & (1 << ix)) { // FIXME: could be done multiple times? bad if so + hwl_alts[rankx].hwl_alt_mask |= (1 << byte_idx); // set the mask + hwl_alts[rankx].hwl_alt_delay[byte_idx] = ix << 1; // record the value + VB_PRT(VBL_DEV, "N%d.LMC%d.R%d: SWL_TRY_HWL_ALT: Byte %d maj %d (%d) alt %d (%d).\n", + node, ddr_interface_num, rankx, byte_idx, mx << 1, xc, + ix << 1, wlevel_bytes[byte_idx][ix]); + } + } + } else { + debug_print("N%d.LMC%d.R%d: SWL_TRY_HWL_ALT: Byte %d maj %d alt NONE.\n", + node, ddr_interface_num, rankx, byte_idx, mx << 1); + } +#endif /* SWL_TRY_HWL_ALT */ + if (cc > 2) { // unlikely, but... + // assume: counts for 3 indices are all 1 + // possiblities are: 0/2/4, 2/4/6, 0/4/6, 0/2/6 + // and the desired?: 2 , 4 , 6, 0 + // we choose the middle, assuming one of the outliers is bad + // NOTE: this is an ugly hack at the moment; there must be a better way + switch (mc) { + case 0x7: mx = 1; break; // was 0/2/4, choose 2 + case 0xb: mx = 0; break; // was 0/2/6, choose 0 + case 0xd: mx = 3; break; // was 0/4/6, choose 6 + case 0xe: mx = 2; break; // was 2/4/6, choose 4 + default: + case 0xf: mx = 1; break; // was 0/2/4/6, choose 2? + } + error_print("N%d.LMC%d.R%d: HW WL MAJORITY: bad byte-lane %d (0x%x), using %d.\n", + node, ddr_interface_num, rankx, byte_idx, mc, mx << 1); + } + update_wlevel_rank_struct(&lmc_wlevel_rank, byte_idx, mx << 1); + } /* for (byte_idx=0; byte_idx<(8+ecc_ena); ++byte_idx) */ + + DRAM_CSR_WRITE(node, BDK_LMCX_WLEVEL_RANKX(ddr_interface_num, rankx), lmc_wlevel_rank.u); + display_WL_with_final(node, ddr_interface_num, lmc_wlevel_rank, rankx); + } /* if (wlevel_loops > 1) */ +#endif /* HW_WL_MAJORITY */ + // maybe print an error summary for the rank + if ((wlevel_bitmask_errors_rank != 0) || (wlevel_validity_errors_rank != 0)) { + VB_PRT(VBL_FAE, "N%d.LMC%d.R%d: H/W Write-Leveling errors - %d bitmask, %d validity, %d retries, %d exhausted\n", + node, ddr_interface_num, rankx, + wlevel_bitmask_errors_rank, wlevel_validity_errors_rank, + wloop_retries_total, wloop_retries_exhausted); + } + + } /* for (rankx = 0; rankx < dimm_count * 4;rankx++) */ + +#if WODT_MASK_2R_1S + if ((ddr_type == DDR4_DRAM) && (num_ranks == 2) && (dimm_count == 1)) { + /* LMC(0)_WODT_MASK */ + bdk_lmcx_wodt_mask_t lmc_wodt_mask; + // always read current so we can see if its different from saved + lmc_wodt_mask.u = BDK_CSR_READ(node, BDK_LMCX_WODT_MASK(ddr_interface_num)); + if (lmc_wodt_mask.u != saved_wodt_mask) { // always restore what was saved if diff + lmc_wodt_mask.u = saved_wodt_mask; + ddr_print("WODT_MASK : 0x%016lx\n", lmc_wodt_mask.u); + DRAM_CSR_WRITE(node, BDK_LMCX_WODT_MASK(ddr_interface_num), lmc_wodt_mask.u); + } + } +#endif /* WODT_MASK_2R_1S */ + + } // End HW write-leveling block + + // At the end of HW Write Leveling, check on some things... + if (! disable_deskew_training) { + + deskew_counts_t dsk_counts; + int retry_count = 0; + + VB_PRT(VBL_FAE, "N%d.LMC%d: Check Deskew Settings before Read-Leveling.\n", node, ddr_interface_num); + + do { + Validate_Read_Deskew_Training(node, rank_mask, ddr_interface_num, &dsk_counts, VBL_FAE); + + // only RAWCARD A or B will not benefit from retraining if there's only saturation + // or any rawcard if there is a nibble error + if ((!spd_rawcard_AorB && dsk_counts.saturated > 0) || + ((dsk_counts.nibrng_errs != 0) || (dsk_counts.nibunl_errs != 0))) + { + retry_count++; + VB_PRT(VBL_FAE, "N%d.LMC%d: Deskew Status indicates saturation or nibble errors - retry %d Training.\n", + node, ddr_interface_num, retry_count); + Perform_Read_Deskew_Training(node, rank_mask, ddr_interface_num, + spd_rawcard_AorB, 0, ddr_interface_64b); + } else + break; + } while (retry_count < 5); + + // print the last setting only if we had to do retries here + if (retry_count > 0) + Validate_Read_Deskew_Training(node, rank_mask, ddr_interface_num, &dsk_counts, VBL_NORM); + } + + /* + * 6.9.12 LMC Read Leveling + * + * LMC supports an automatic read-leveling separately per byte-lane using + * the DDR3 multipurpose register predefined pattern for system + * calibration defined in the JEDEC DDR3 specifications. + * + * All of DDR PLL, LMC CK, and LMC DRESET, and early LMC initializations + * must be completed prior to starting this LMC read-leveling sequence. + * + * Software could simply write the desired read-leveling values into + * LMC(0)_RLEVEL_RANK(0..3). This section describes a sequence that uses + * LMC's autoread-leveling capabilities. + * + * When LMC does the read-leveling sequence for a rank, it first enables + * the DDR3 multipurpose register predefined pattern for system + * calibration on the selected DRAM rank via a DDR3 MR3 write, then + * executes 64 RD operations at different internal delay settings, then + * disables the predefined pattern via another DDR3 MR3 write + * operation. LMC determines the pass or fail of each of the 64 settings + * independently for each byte lane, then writes appropriate + * LMC(0)_RLEVEL_RANK(0..3)[BYTE*] values for the rank. + * + * After read-leveling for a rank, software can read the 64 pass/fail + * indications for one byte lane via LMC(0)_RLEVEL_DBG[BITMASK]. Software + * can observe all pass/fail results for all byte lanes in a rank via + * separate read-leveling sequences on the rank with different + * LMC(0)_RLEVEL_CTL[BYTE] values. + * + * The 64 pass/fail results will typically have failures for the low + * delays, followed by a run of some passing settings, followed by more + * failures in the remaining high delays. LMC sets + * LMC(0)_RLEVEL_RANK(0..3)[BYTE*] to one of the passing settings. + * First, LMC selects the longest run of successes in the 64 results. (In + * the unlikely event that there is more than one longest run, LMC + * selects the first one.) Then if LMC(0)_RLEVEL_CTL[OFFSET_EN] = 1 and + * the selected run has more than LMC(0)_RLEVEL_CTL[OFFSET] successes, + * LMC selects the last passing setting in the run minus + * LMC(0)_RLEVEL_CTL[OFFSET]. Otherwise LMC selects the middle setting in + * the run (rounding earlier when necessary). We expect the read-leveling + * sequence to produce good results with the reset values + * LMC(0)_RLEVEL_CTL [OFFSET_EN]=1, LMC(0)_RLEVEL_CTL[OFFSET] = 2. + * + * The read-leveling sequence has the following steps: + * + * 1. Select desired LMC(0)_RLEVEL_CTL[OFFSET_EN,OFFSET,BYTE] settings. + * Do the remaining substeps 2-4 separately for each rank i with + * attached DRAM. + * + * 2. Without changing any other fields in LMC(0)_CONFIG, + * + * o write LMC(0)_SEQ_CTL[SEQ_SEL] to select read-leveling + * + * o write LMC(0)_CONFIG[RANKMASK] = (1 << i) + * + * o write LMC(0)_SEQ_CTL[INIT_START] = 1 + * + * This initiates the previously-described read-leveling. + * + * 3. Wait until LMC(0)_RLEVEL_RANKi[STATUS] != 2 + * + * LMC will have updated LMC(0)_RLEVEL_RANKi[BYTE*] for all byte lanes + * at this point. + * + * If ECC DRAM is not present (i.e. when DRAM is not attached to the + * DDR_CBS_0_* and DDR_CB<7:0> chip signals, or the DDR_DQS_<4>_* and + * DDR_DQ<35:32> chip signals), write LMC(0)_RLEVEL_RANK*[BYTE8] = + * LMC(0)_RLEVEL_RANK*[BYTE0]. Write LMC(0)_RLEVEL_RANK*[BYTE4] = + * LMC(0)_RLEVEL_RANK*[BYTE0]. + * + * 4. If desired, consult LMC(0)_RLEVEL_DBG[BITMASK] and compare to + * LMC(0)_RLEVEL_RANKi[BYTE*] for the lane selected by + * LMC(0)_RLEVEL_CTL[BYTE]. If desired, modify LMC(0)_RLEVEL_CTL[BYTE] + * to a new value and repeat so that all BITMASKs can be observed. + * + * 5. Initialize LMC(0)_RLEVEL_RANK* values for all unused ranks. + * + * Let rank i be a rank with attached DRAM. + * + * For all ranks j that do not have attached DRAM, set + * LMC(0)_RLEVEL_RANKj = LMC(0)_RLEVEL_RANKi. + * + * This read-leveling sequence can help select the proper CN70XX ODT + * resistance value (LMC(0)_COMP_CTL2[RODT_CTL]). A hardware-generated + * LMC(0)_RLEVEL_RANKi[BYTEj] value (for a used byte lane j) that is + * drastically different from a neighboring LMC(0)_RLEVEL_RANKi[BYTEk] + * (for a used byte lane k) can indicate that the CN70XX ODT value is + * bad. It is possible to simultaneously optimize both + * LMC(0)_COMP_CTL2[RODT_CTL] and LMC(0)_RLEVEL_RANKn[BYTE*] values by + * performing this read-leveling sequence for several + * LMC(0)_COMP_CTL2[RODT_CTL] values and selecting the one with the best + * LMC(0)_RLEVEL_RANKn[BYTE*] profile for the ranks. + */ + + { +#pragma pack(push,4) + bdk_lmcx_rlevel_rankx_t lmc_rlevel_rank; + bdk_lmcx_comp_ctl2_t lmc_comp_ctl2; + bdk_lmcx_rlevel_ctl_t rlevel_ctl; + bdk_lmcx_control_t lmc_control; + bdk_lmcx_modereg_params1_t lmc_modereg_params1; + unsigned char rodt_ctl; + unsigned char rankx = 0; + int rlevel_rodt_errors = 0; + unsigned char ecc_ena; + unsigned char rtt_nom; + unsigned char rtt_idx; + int min_rtt_nom_idx; + int max_rtt_nom_idx; + int min_rodt_ctl; + int max_rodt_ctl; + int rlevel_debug_loops = 1; + unsigned char save_ddr2t; + int rlevel_avg_loops; + int ddr_rlevel_compute; + int saved_ddr__ptune, saved_ddr__ntune, rlevel_comp_offset; + int saved_int_zqcs_dis = 0; + int disable_sequential_delay_check = 0; + int maximum_adjacent_rlevel_delay_increment = 0; + struct { + uint64_t setting; + int score; + } rlevel_scoreboard[RTT_NOM_OHMS_COUNT][RODT_OHMS_COUNT][4]; + int print_nom_ohms; +#if PERFECT_BITMASK_COUNTING + typedef struct { + uint8_t count[9][32]; // 8+ECC by 32 values + uint8_t total[9]; // 8+ECC + } rank_perfect_t; + rank_perfect_t rank_perfect_counts[4]; +#endif + +#pragma pack(pop) + +#if PERFECT_BITMASK_COUNTING + memset(rank_perfect_counts, 0, sizeof(rank_perfect_counts)); +#endif /* PERFECT_BITMASK_COUNTING */ + + lmc_control.u = BDK_CSR_READ(node, BDK_LMCX_CONTROL(ddr_interface_num)); + save_ddr2t = lmc_control.s.ddr2t; + + lmc_config.u = BDK_CSR_READ(node, BDK_LMCX_CONFIG(ddr_interface_num)); + ecc_ena = lmc_config.s.ecc_ena; + +#if 0 + { + int save_ref_zqcs_int; + uint64_t temp_delay_usecs; + + /* Temporarily select the minimum ZQCS interval and wait + long enough for a few ZQCS calibrations to occur. This + should ensure that the calibration circuitry is + stabilized before read-leveling occurs. */ + save_ref_zqcs_int = lmc_config.s.ref_zqcs_int; + lmc_config.s.ref_zqcs_int = 1 | (32<<7); /* set smallest interval */ + DRAM_CSR_WRITE(node, BDK_LMCX_CONFIG(ddr_interface_num), lmc_config.u); + BDK_CSR_READ(node, BDK_LMCX_CONFIG(ddr_interface_num)); + + /* Compute an appropriate delay based on the current ZQCS + interval. The delay should be long enough for the + current ZQCS delay counter to expire plus ten of the + minimum intarvals to ensure that some calibrations + occur. */ + temp_delay_usecs = (((uint64_t)save_ref_zqcs_int >> 7) + * tclk_psecs * 100 * 512 * 128) / (10000*10000) + + 10 * ((uint64_t)32 * tclk_psecs * 100 * 512 * 128) / (10000*10000); + + ddr_print ("Waiting %lu usecs for ZQCS calibrations to start\n", + temp_delay_usecs); + bdk_wait_usec(temp_delay_usecs); + + lmc_config.s.ref_zqcs_int = save_ref_zqcs_int; /* Restore computed interval */ + DRAM_CSR_WRITE(node, BDK_LMCX_CONFIG(ddr_interface_num), lmc_config.u); + BDK_CSR_READ(node, BDK_LMCX_CONFIG(ddr_interface_num)); + } +#endif + + if ((s = lookup_env_parameter("ddr_rlevel_2t")) != NULL) { + lmc_control.s.ddr2t = strtoul(s, NULL, 0); + } + + DRAM_CSR_WRITE(node, BDK_LMCX_CONTROL(ddr_interface_num), lmc_control.u); + + ddr_print("N%d.LMC%d: Performing Read-Leveling\n", node, ddr_interface_num); + + rlevel_ctl.u = BDK_CSR_READ(node, BDK_LMCX_RLEVEL_CTL(ddr_interface_num)); + + rlevel_avg_loops = custom_lmc_config->rlevel_average_loops; + if (rlevel_avg_loops == 0) { + rlevel_avg_loops = RLEVEL_AVG_LOOPS_DEFAULT; + if ((dimm_count == 1) || (num_ranks == 1)) // up the samples for these cases + rlevel_avg_loops = rlevel_avg_loops * 2 + 1; + } + + ddr_rlevel_compute = custom_lmc_config->rlevel_compute; + rlevel_ctl.s.offset_en = custom_lmc_config->offset_en; + rlevel_ctl.s.offset = spd_rdimm + ? custom_lmc_config->offset_rdimm + : custom_lmc_config->offset_udimm; + + rlevel_ctl.s.delay_unload_0 = 1; /* should normally be set */ + rlevel_ctl.s.delay_unload_1 = 1; /* should normally be set */ + rlevel_ctl.s.delay_unload_2 = 1; /* should normally be set */ + rlevel_ctl.s.delay_unload_3 = 1; /* should normally be set */ + + rlevel_ctl.s.or_dis = 1; // default to get best bitmasks + if ((s = lookup_env_parameter("ddr_rlevel_or_dis")) != NULL) { + rlevel_ctl.s.or_dis = !!strtoul(s, NULL, 0); + } + rlevel_ctl.s.bitmask = 0xff; // should work in 32b mode also + if ((s = lookup_env_parameter("ddr_rlevel_ctl_bitmask")) != NULL) { + rlevel_ctl.s.bitmask = strtoul(s, NULL, 0); + } + debug_print("N%d.LMC%d: RLEVEL_CTL: or_dis=%d, bitmask=0x%02x\n", + node, ddr_interface_num, + rlevel_ctl.s.or_dis, rlevel_ctl.s.bitmask); + + rlevel_comp_offset = spd_rdimm + ? custom_lmc_config->rlevel_comp_offset_rdimm + : custom_lmc_config->rlevel_comp_offset_udimm; + + if ((s = lookup_env_parameter("ddr_rlevel_offset")) != NULL) { + rlevel_ctl.s.offset = strtoul(s, NULL, 0); + } + + if ((s = lookup_env_parameter("ddr_rlevel_offset_en")) != NULL) { + rlevel_ctl.s.offset_en = strtoul(s, NULL, 0); + } + if ((s = lookup_env_parameter("ddr_rlevel_ctl")) != NULL) { + rlevel_ctl.u = strtoul(s, NULL, 0); + } + + DRAM_CSR_WRITE(node, BDK_LMCX_RLEVEL_CTL(ddr_interface_num), rlevel_ctl.u); + + if (bdk_is_platform(BDK_PLATFORM_ASIM)) + rlevel_debug_loops = 0; + + if ((s = lookup_env_parameter("ddr%d_rlevel_debug_loops", ddr_interface_num)) != NULL) { + rlevel_debug_loops = strtoul(s, NULL, 0); + } + + if ((s = lookup_env_parameter("ddr_rtt_nom_auto")) != NULL) { + ddr_rtt_nom_auto = !!strtoul(s, NULL, 0); + } + + if ((s = lookup_env_parameter("ddr_rlevel_average")) != NULL) { + rlevel_avg_loops = strtoul(s, NULL, 0); + } + + if ((s = lookup_env_parameter("ddr_rlevel_compute")) != NULL) { + ddr_rlevel_compute = strtoul(s, NULL, 0); + } + + ddr_print("RLEVEL_CTL : 0x%016lx\n", rlevel_ctl.u); + ddr_print("RLEVEL_OFFSET : %6d\n", rlevel_ctl.s.offset); + ddr_print("RLEVEL_OFFSET_EN : %6d\n", rlevel_ctl.s.offset_en); + + /* The purpose for the indexed table is to sort the settings + ** by the ohm value to simplify the testing when incrementing + ** through the settings. (index => ohms) 1=120, 2=60, 3=40, + ** 4=30, 5=20 */ + min_rtt_nom_idx = (custom_lmc_config->min_rtt_nom_idx == 0) ? 1 : custom_lmc_config->min_rtt_nom_idx; + max_rtt_nom_idx = (custom_lmc_config->max_rtt_nom_idx == 0) ? 5 : custom_lmc_config->max_rtt_nom_idx; + + min_rodt_ctl = (custom_lmc_config->min_rodt_ctl == 0) ? 1 : custom_lmc_config->min_rodt_ctl; + max_rodt_ctl = (custom_lmc_config->max_rodt_ctl == 0) ? 5 : custom_lmc_config->max_rodt_ctl; + + if ((s = lookup_env_parameter("ddr_min_rodt_ctl")) != NULL) { + min_rodt_ctl = strtoul(s, NULL, 0); + } + if ((s = lookup_env_parameter("ddr_max_rodt_ctl")) != NULL) { + max_rodt_ctl = strtoul(s, NULL, 0); + } + if ((s = lookup_env_parameter("ddr_min_rtt_nom_idx")) != NULL) { + min_rtt_nom_idx = strtoul(s, NULL, 0); + } + if ((s = lookup_env_parameter("ddr_max_rtt_nom_idx")) != NULL) { + max_rtt_nom_idx = strtoul(s, NULL, 0); + } + +#ifdef ENABLE_CUSTOM_RLEVEL_TABLE + if (custom_lmc_config->rlevel_table != NULL) { + char part_number[21]; + /* Check for hard-coded read-leveling settings */ + get_dimm_part_number(part_number, node, &dimm_config_table[0], 0, ddr_type); + for (rankx = 0; rankx < dimm_count * 4;rankx++) { + if (!(rank_mask & (1 << rankx))) + continue; + + lmc_rlevel_rank.u = BDK_CSR_READ(node, BDK_LMCX_RLEVEL_RANKX(ddr_interface_num, rankx)); + + i = 0; + while (custom_lmc_config->rlevel_table[i].part != NULL) { + debug_print("DIMM part number:\"%s\", SPD: \"%s\"\n", custom_lmc_config->rlevel_table[i].part, part_number); + if ((strcmp(part_number, custom_lmc_config->rlevel_table[i].part) == 0) + && (_abs(custom_lmc_config->rlevel_table[i].speed - 2*ddr_hertz/(1000*1000)) < 10 )) + { + ddr_print("Using hard-coded read leveling for DIMM part number: \"%s\"\n", part_number); + lmc_rlevel_rank.u = custom_lmc_config->rlevel_table[i].rlevel_rank[ddr_interface_num][rankx]; + DRAM_CSR_WRITE(node, BDK_LMCX_RLEVEL_RANKX(ddr_interface_num, rankx), lmc_rlevel_rank.u); + lmc_rlevel_rank.u = BDK_CSR_READ(node, BDK_LMCX_RLEVEL_RANKX(ddr_interface_num, rankx)); + display_RL(node, ddr_interface_num, lmc_rlevel_rank, rankx); + rlevel_debug_loops = 0; /* Disable h/w read-leveling */ + break; + } + ++i; + } + } + } +#endif /* ENABLE_CUSTOM_RLEVEL_TABLE */ + + while(rlevel_debug_loops--) { + /* Initialize the error scoreboard */ + memset(rlevel_scoreboard, 0, sizeof(rlevel_scoreboard)); + + if ((s = lookup_env_parameter("ddr_rlevel_comp_offset")) != NULL) { + rlevel_comp_offset = strtoul(s, NULL, 0); + } + + disable_sequential_delay_check = custom_lmc_config->disable_sequential_delay_check; + + if ((s = lookup_env_parameter("ddr_disable_sequential_delay_check")) != NULL) { + disable_sequential_delay_check = strtoul(s, NULL, 0); + } + + maximum_adjacent_rlevel_delay_increment = custom_lmc_config->maximum_adjacent_rlevel_delay_increment; + + if ((s = lookup_env_parameter("ddr_maximum_adjacent_rlevel_delay_increment")) != NULL) { + maximum_adjacent_rlevel_delay_increment = strtoul(s, NULL, 0); + } + + lmc_comp_ctl2.u = BDK_CSR_READ(node, BDK_LMCX_COMP_CTL2(ddr_interface_num)); + saved_ddr__ptune = lmc_comp_ctl2.s.ddr__ptune; + saved_ddr__ntune = lmc_comp_ctl2.s.ddr__ntune; + + /* Disable dynamic compensation settings */ + if (rlevel_comp_offset != 0) { + lmc_comp_ctl2.s.ptune = saved_ddr__ptune; + lmc_comp_ctl2.s.ntune = saved_ddr__ntune; + + /* Round up the ptune calculation to bias the odd cases toward ptune */ + lmc_comp_ctl2.s.ptune += divide_roundup(rlevel_comp_offset, 2); + lmc_comp_ctl2.s.ntune -= rlevel_comp_offset/2; + + lmc_control.u = BDK_CSR_READ(node, BDK_LMCX_CONTROL(ddr_interface_num)); + saved_int_zqcs_dis = lmc_control.s.int_zqcs_dis; + lmc_control.s.int_zqcs_dis = 1; /* Disable ZQCS while in bypass. */ + DRAM_CSR_WRITE(node, BDK_LMCX_CONTROL(ddr_interface_num), lmc_control.u); + + lmc_comp_ctl2.s.byp = 1; /* Enable bypass mode */ + DRAM_CSR_WRITE(node, BDK_LMCX_COMP_CTL2(ddr_interface_num), lmc_comp_ctl2.u); + BDK_CSR_READ(node, BDK_LMCX_COMP_CTL2(ddr_interface_num)); + lmc_comp_ctl2.u = BDK_CSR_READ(node, BDK_LMCX_COMP_CTL2(ddr_interface_num)); /* Read again */ + ddr_print("DDR__PTUNE/DDR__NTUNE : %d/%d\n", + lmc_comp_ctl2.s.ddr__ptune, lmc_comp_ctl2.s.ddr__ntune); + } + + lmc_modereg_params1.u = BDK_CSR_READ(node, BDK_LMCX_MODEREG_PARAMS1(ddr_interface_num)); + + for (rtt_idx = min_rtt_nom_idx; rtt_idx <= max_rtt_nom_idx; ++rtt_idx) { + rtt_nom = imp_values->rtt_nom_table[rtt_idx]; + + /* When the read ODT mask is zero the dyn_rtt_nom_mask is + zero than RTT_NOM will not be changing during + read-leveling. Since the value is fixed we only need + to test it once. */ + if (dyn_rtt_nom_mask == 0) { + print_nom_ohms = -1; // flag not to print NOM ohms + if (rtt_idx != min_rtt_nom_idx) + continue; + } else { + if (dyn_rtt_nom_mask & 1) lmc_modereg_params1.s.rtt_nom_00 = rtt_nom; + if (dyn_rtt_nom_mask & 2) lmc_modereg_params1.s.rtt_nom_01 = rtt_nom; + if (dyn_rtt_nom_mask & 4) lmc_modereg_params1.s.rtt_nom_10 = rtt_nom; + if (dyn_rtt_nom_mask & 8) lmc_modereg_params1.s.rtt_nom_11 = rtt_nom; + // FIXME? rank 0 ohms always for the printout? + print_nom_ohms = imp_values->rtt_nom_ohms[lmc_modereg_params1.s.rtt_nom_00]; + } + + DRAM_CSR_WRITE(node, BDK_LMCX_MODEREG_PARAMS1(ddr_interface_num), lmc_modereg_params1.u); + VB_PRT(VBL_TME, "\n"); + VB_PRT(VBL_TME, "RTT_NOM %3d, %3d, %3d, %3d ohms : %x,%x,%x,%x\n", + imp_values->rtt_nom_ohms[lmc_modereg_params1.s.rtt_nom_11], + imp_values->rtt_nom_ohms[lmc_modereg_params1.s.rtt_nom_10], + imp_values->rtt_nom_ohms[lmc_modereg_params1.s.rtt_nom_01], + imp_values->rtt_nom_ohms[lmc_modereg_params1.s.rtt_nom_00], + lmc_modereg_params1.s.rtt_nom_11, + lmc_modereg_params1.s.rtt_nom_10, + lmc_modereg_params1.s.rtt_nom_01, + lmc_modereg_params1.s.rtt_nom_00); + + perform_ddr_init_sequence(node, rank_mask, ddr_interface_num); + + // Try RANK outside RODT to rearrange the output... + for (rankx = 0; rankx < dimm_count * 4; rankx++) { + int byte_idx; + rlevel_byte_data_t rlevel_byte[9]; + int average_loops; + int rlevel_rank_errors, rlevel_bitmask_errors, rlevel_nonseq_errors; + rlevel_bitmask_t rlevel_bitmask[9]; +#if PICK_BEST_RANK_SCORE_NOT_AVG + int rlevel_best_rank_score; +#endif + + if (!(rank_mask & (1 << rankx))) + continue; + + for (rodt_ctl = max_rodt_ctl; rodt_ctl >= min_rodt_ctl; --rodt_ctl) { +#if PICK_BEST_RANK_SCORE_NOT_AVG + rlevel_best_rank_score = DEFAULT_BEST_RANK_SCORE; +#endif + rlevel_rodt_errors = 0; + lmc_comp_ctl2.u = BDK_CSR_READ(node, BDK_LMCX_COMP_CTL2(ddr_interface_num)); + lmc_comp_ctl2.s.rodt_ctl = rodt_ctl; + DRAM_CSR_WRITE(node, BDK_LMCX_COMP_CTL2(ddr_interface_num), lmc_comp_ctl2.u); + lmc_comp_ctl2.u = BDK_CSR_READ(node, BDK_LMCX_COMP_CTL2(ddr_interface_num)); + bdk_wait_usec(1); /* Give it a little time to take affect */ + VB_PRT(VBL_DEV, "Read ODT_CTL : 0x%x (%d ohms)\n", + lmc_comp_ctl2.s.rodt_ctl, imp_values->rodt_ohms[lmc_comp_ctl2.s.rodt_ctl]); + + memset(rlevel_byte, 0, sizeof(rlevel_byte)); + + for (average_loops = 0; average_loops < rlevel_avg_loops; average_loops++) { + rlevel_bitmask_errors = 0; + + if (! (rlevel_separate_ab && spd_rdimm && (ddr_type == DDR4_DRAM))) { + /* Clear read-level delays */ + DRAM_CSR_WRITE(node, BDK_LMCX_RLEVEL_RANKX(ddr_interface_num, rankx), 0); + + /* read-leveling */ + perform_octeon3_ddr3_sequence(node, 1 << rankx, ddr_interface_num, 1); + + if (!bdk_is_platform(BDK_PLATFORM_ASIM) && + BDK_CSR_WAIT_FOR_FIELD(node, BDK_LMCX_RLEVEL_RANKX(ddr_interface_num, rankx), + status, ==, 3, 1000000)) + { + error_print("ERROR: Timeout waiting for RLEVEL\n"); + } + } + + lmc_rlevel_rank.u = BDK_CSR_READ(node, BDK_LMCX_RLEVEL_RANKX(ddr_interface_num, rankx)); + + { // start bitmask interpretation block + int redoing_nonseq_errs = 0; + + memset(rlevel_bitmask, 0, sizeof(rlevel_bitmask)); + + if (rlevel_separate_ab && spd_rdimm && (ddr_type == DDR4_DRAM)) { + bdk_lmcx_rlevel_rankx_t lmc_rlevel_rank_aside; + bdk_lmcx_modereg_params0_t lmc_modereg_params0; + + /* A-side */ + lmc_modereg_params0.u = BDK_CSR_READ(node, BDK_LMCX_MODEREG_PARAMS0(ddr_interface_num)); + lmc_modereg_params0.s.mprloc = 0; /* MPR Page 0 Location 0 */ + DRAM_CSR_WRITE(node, BDK_LMCX_MODEREG_PARAMS0(ddr_interface_num), lmc_modereg_params0.u); + + /* Clear read-level delays */ + DRAM_CSR_WRITE(node, BDK_LMCX_RLEVEL_RANKX(ddr_interface_num, rankx), 0); + + perform_octeon3_ddr3_sequence(node, 1 << rankx, ddr_interface_num, 1); /* read-leveling */ + + if (!bdk_is_platform(BDK_PLATFORM_ASIM) && + BDK_CSR_WAIT_FOR_FIELD(node, BDK_LMCX_RLEVEL_RANKX(ddr_interface_num, rankx), + status, ==, 3, 1000000)) + { + error_print("ERROR: Timeout waiting for RLEVEL\n"); + + } + lmc_rlevel_rank.u = BDK_CSR_READ(node, BDK_LMCX_RLEVEL_RANKX(ddr_interface_num, rankx)); + + lmc_rlevel_rank_aside.u = lmc_rlevel_rank.u; + + rlevel_bitmask[0].bm = octeon_read_lmcx_ddr3_rlevel_dbg(node, ddr_interface_num, 0); + rlevel_bitmask[1].bm = octeon_read_lmcx_ddr3_rlevel_dbg(node, ddr_interface_num, 1); + rlevel_bitmask[2].bm = octeon_read_lmcx_ddr3_rlevel_dbg(node, ddr_interface_num, 2); + rlevel_bitmask[3].bm = octeon_read_lmcx_ddr3_rlevel_dbg(node, ddr_interface_num, 3); + rlevel_bitmask[8].bm = octeon_read_lmcx_ddr3_rlevel_dbg(node, ddr_interface_num, 8); + /* A-side complete */ + + + /* B-side */ + lmc_modereg_params0.u = BDK_CSR_READ(node, BDK_LMCX_MODEREG_PARAMS0(ddr_interface_num)); + lmc_modereg_params0.s.mprloc = 3; /* MPR Page 0 Location 3 */ + DRAM_CSR_WRITE(node, BDK_LMCX_MODEREG_PARAMS0(ddr_interface_num), lmc_modereg_params0.u); + + /* Clear read-level delays */ + DRAM_CSR_WRITE(node, BDK_LMCX_RLEVEL_RANKX(ddr_interface_num, rankx), 0); + + perform_octeon3_ddr3_sequence(node, 1 << rankx, ddr_interface_num, 1); /* read-leveling */ + + if (!bdk_is_platform(BDK_PLATFORM_ASIM) && + BDK_CSR_WAIT_FOR_FIELD(node, BDK_LMCX_RLEVEL_RANKX(ddr_interface_num, rankx), + status, ==, 3, 1000000)) + { + error_print("ERROR: Timeout waiting for RLEVEL\n"); + } + lmc_rlevel_rank.u = BDK_CSR_READ(node, BDK_LMCX_RLEVEL_RANKX(ddr_interface_num, rankx)); + + rlevel_bitmask[4].bm = octeon_read_lmcx_ddr3_rlevel_dbg(node, ddr_interface_num, 4); + rlevel_bitmask[5].bm = octeon_read_lmcx_ddr3_rlevel_dbg(node, ddr_interface_num, 5); + rlevel_bitmask[6].bm = octeon_read_lmcx_ddr3_rlevel_dbg(node, ddr_interface_num, 6); + rlevel_bitmask[7].bm = octeon_read_lmcx_ddr3_rlevel_dbg(node, ddr_interface_num, 7); + /* B-side complete */ + + + update_rlevel_rank_struct(&lmc_rlevel_rank, 0, lmc_rlevel_rank_aside.cn83xx.byte0); + update_rlevel_rank_struct(&lmc_rlevel_rank, 1, lmc_rlevel_rank_aside.cn83xx.byte1); + update_rlevel_rank_struct(&lmc_rlevel_rank, 2, lmc_rlevel_rank_aside.cn83xx.byte2); + update_rlevel_rank_struct(&lmc_rlevel_rank, 3, lmc_rlevel_rank_aside.cn83xx.byte3); + update_rlevel_rank_struct(&lmc_rlevel_rank, 8, lmc_rlevel_rank_aside.cn83xx.byte8); /* ECC A-side */ + + lmc_modereg_params0.u = BDK_CSR_READ(node, BDK_LMCX_MODEREG_PARAMS0(ddr_interface_num)); + lmc_modereg_params0.s.mprloc = 0; /* MPR Page 0 Location 0 */ + DRAM_CSR_WRITE(node, BDK_LMCX_MODEREG_PARAMS0(ddr_interface_num), lmc_modereg_params0.u); + + } /* if (rlevel_separate_ab && spd_rdimm && (ddr_type == DDR4_DRAM)) */ + + /* + * Evaluate the quality of the read-leveling delays from the bitmasks. + * Also save off a software computed read-leveling mask that may be + * used later to qualify the delay results from Octeon. + */ + for (byte_idx = 0; byte_idx < (8+ecc_ena); ++byte_idx) { + int bmerr; + if (!(ddr_interface_bytemask&(1<<byte_idx))) + continue; + if (! (rlevel_separate_ab && spd_rdimm && (ddr_type == DDR4_DRAM))) { + rlevel_bitmask[byte_idx].bm = + octeon_read_lmcx_ddr3_rlevel_dbg(node, ddr_interface_num, byte_idx); + } + bmerr = validate_ddr3_rlevel_bitmask(&rlevel_bitmask[byte_idx], ddr_type); + rlevel_bitmask[byte_idx].errs = bmerr; + rlevel_bitmask_errors += bmerr; +#if PERFECT_BITMASK_COUNTING + if ((ddr_type == DDR4_DRAM) && !bmerr) { // count only the "perfect" bitmasks + // FIXME: could optimize this a bit? + int delay = get_rlevel_rank_struct(&lmc_rlevel_rank, byte_idx); + rank_perfect_counts[rankx].count[byte_idx][delay] += 1; + rank_perfect_counts[rankx].total[byte_idx] += 1; + } +#endif /* PERFECT_BITMASK_COUNTING */ + } + + /* Set delays for unused bytes to match byte 0. */ + for (byte_idx = 0; byte_idx < 9; ++byte_idx) { + if (ddr_interface_bytemask & (1 << byte_idx)) + continue; + update_rlevel_rank_struct(&lmc_rlevel_rank, byte_idx, lmc_rlevel_rank.cn83xx.byte0); + } + + /* Save a copy of the byte delays in physical + order for sequential evaluation. */ + unpack_rlevel_settings(ddr_interface_bytemask, ecc_ena, rlevel_byte, lmc_rlevel_rank); + redo_nonseq_errs: + + rlevel_nonseq_errors = 0; + + if (! disable_sequential_delay_check) { + if ((ddr_interface_bytemask & 0xff) == 0xff) { + /* Evaluate delay sequence across the whole range of bytes for standard dimms. */ + if ((spd_dimm_type == 1) || (spd_dimm_type == 5)) { /* 1=RDIMM, 5=Mini-RDIMM */ + int register_adjacent_delay = _abs(rlevel_byte[4].delay - rlevel_byte[5].delay); + /* Registered dimm topology routes from the center. */ + rlevel_nonseq_errors += nonsequential_delays(rlevel_byte, 0, 3+ecc_ena, + maximum_adjacent_rlevel_delay_increment); + rlevel_nonseq_errors += nonsequential_delays(rlevel_byte, 5, 7+ecc_ena, + maximum_adjacent_rlevel_delay_increment); + // byte 5 sqerrs never gets cleared for RDIMMs + rlevel_byte[5].sqerrs = 0; + if (register_adjacent_delay > 1) { + /* Assess proximity of bytes on opposite sides of register */ + rlevel_nonseq_errors += (register_adjacent_delay-1) * RLEVEL_ADJACENT_DELAY_ERROR; + // update byte 5 error + rlevel_byte[5].sqerrs += (register_adjacent_delay-1) * RLEVEL_ADJACENT_DELAY_ERROR; + } + } + if ((spd_dimm_type == 2) || (spd_dimm_type == 6)) { /* 2=UDIMM, 6=Mini-UDIMM */ + /* Unbuffered dimm topology routes from end to end. */ + rlevel_nonseq_errors += nonsequential_delays(rlevel_byte, 0, 7+ecc_ena, + maximum_adjacent_rlevel_delay_increment); + } + } else { + rlevel_nonseq_errors += nonsequential_delays(rlevel_byte, 0, 3+ecc_ena, + maximum_adjacent_rlevel_delay_increment); + } + } /* if (! disable_sequential_delay_check) */ + +#if 0 + // FIXME FIXME: disabled for now, it was too much... + + // Calculate total errors for the rank: + // we do NOT add nonsequential errors if mini-[RU]DIMM or x16; + // mini-DIMMs and x16 devices have unusual sequence geometries. + // Make the final scores for them depend only on the bitmasks... + rlevel_rank_errors = rlevel_bitmask_errors; + if ((spd_dimm_type != 5) && + (spd_dimm_type != 6) && + (dram_width != 16)) + { + rlevel_rank_errors += rlevel_nonseq_errors; + } +#else + rlevel_rank_errors = rlevel_bitmask_errors + rlevel_nonseq_errors; +#endif + + // print original sample here only if we are not really averaging or picking best + // also do not print if we were redoing the NONSEQ score for using COMPUTED + if (!redoing_nonseq_errs && ((rlevel_avg_loops < 2) || dram_is_verbose(VBL_DEV2))) { + display_RL_BM(node, ddr_interface_num, rankx, rlevel_bitmask, ecc_ena); + display_RL_BM_scores(node, ddr_interface_num, rankx, rlevel_bitmask, ecc_ena); + display_RL_SEQ_scores(node, ddr_interface_num, rankx, rlevel_byte, ecc_ena); + display_RL_with_score(node, ddr_interface_num, lmc_rlevel_rank, rankx, rlevel_rank_errors); + } + + if (ddr_rlevel_compute) { + if (!redoing_nonseq_errs) { + /* Recompute the delays based on the bitmask */ + for (byte_idx = 0; byte_idx < (8+ecc_ena); ++byte_idx) { + if (!(ddr_interface_bytemask & (1 << byte_idx))) + continue; + update_rlevel_rank_struct(&lmc_rlevel_rank, byte_idx, + compute_ddr3_rlevel_delay(rlevel_bitmask[byte_idx].mstart, + rlevel_bitmask[byte_idx].width, + rlevel_ctl)); + } + + /* Override the copy of byte delays with the computed results. */ + unpack_rlevel_settings(ddr_interface_bytemask, ecc_ena, rlevel_byte, lmc_rlevel_rank); + + redoing_nonseq_errs = 1; + goto redo_nonseq_errs; + + } else { + /* now print this if already printed the original sample */ + if ((rlevel_avg_loops < 2) || dram_is_verbose(VBL_DEV2)) { + display_RL_with_computed(node, ddr_interface_num, + lmc_rlevel_rank, rankx, + rlevel_rank_errors); + } + } + } /* if (ddr_rlevel_compute) */ + + } // end bitmask interpretation block + +#if PICK_BEST_RANK_SCORE_NOT_AVG + + // if it is a better (lower) score, then keep it + if (rlevel_rank_errors < rlevel_best_rank_score) { + rlevel_best_rank_score = rlevel_rank_errors; + + // save the new best delays and best errors + for (byte_idx = 0; byte_idx < 9; ++byte_idx) { + rlevel_byte[byte_idx].best = rlevel_byte[byte_idx].delay; + rlevel_byte[byte_idx].bestsq = rlevel_byte[byte_idx].sqerrs; + // save bitmasks and their scores as well + // xlate UNPACKED index to PACKED index to get from rlevel_bitmask + rlevel_byte[byte_idx].bm = rlevel_bitmask[XUP(byte_idx, !!ecc_ena)].bm; + rlevel_byte[byte_idx].bmerrs = rlevel_bitmask[XUP(byte_idx, !!ecc_ena)].errs; + } + } +#else /* PICK_BEST_RANK_SCORE_NOT_AVG */ + + /* Accumulate the total score across averaging loops for this setting */ + debug_print("rlevel_scoreboard[rtt_nom=%d][rodt_ctl=%d][rankx=%d].score: %d [%d]\n", + rtt_nom, rodt_ctl, rankx, rlevel_rank_errors, average_loops); + rlevel_scoreboard[rtt_nom][rodt_ctl][rankx].score += rlevel_rank_errors; + + /* Accumulate the delay totals and loop counts + necessary to compute average delay results */ + for (byte_idx = 0; byte_idx < 9; ++byte_idx) { + if (rlevel_byte[byte_idx].delay != 0) { /* Don't include delay=0 in the average */ + ++rlevel_byte[byte_idx].loop_count; + rlevel_byte[byte_idx].loop_total += rlevel_byte[byte_idx].delay; + } + } /* for (byte_idx = 0; byte_idx < 9; ++byte_idx) */ +#endif /* PICK_BEST_RANK_SCORE_NOT_AVG */ + + rlevel_rodt_errors += rlevel_rank_errors; + + } /* for (average_loops = 0; average_loops < rlevel_avg_loops; average_loops++) */ + +#if PICK_BEST_RANK_SCORE_NOT_AVG + + /* We recorded the best score across the averaging loops */ + rlevel_scoreboard[rtt_nom][rodt_ctl][rankx].score = rlevel_best_rank_score; + + /* Restore the delays from the best fields that go with the best score */ + for (byte_idx = 0; byte_idx < 9; ++byte_idx) { + rlevel_byte[byte_idx].delay = rlevel_byte[byte_idx].best; + rlevel_byte[byte_idx].sqerrs = rlevel_byte[byte_idx].bestsq; + } +#else /* PICK_BEST_RANK_SCORE_NOT_AVG */ + + /* Compute the average score across averaging loops */ + rlevel_scoreboard[rtt_nom][rodt_ctl][rankx].score = + divide_nint(rlevel_scoreboard[rtt_nom][rodt_ctl][rankx].score, rlevel_avg_loops); + + /* Compute the average delay results */ + for (byte_idx=0; byte_idx < 9; ++byte_idx) { + if (rlevel_byte[byte_idx].loop_count == 0) + rlevel_byte[byte_idx].loop_count = 1; + rlevel_byte[byte_idx].delay = divide_nint(rlevel_byte[byte_idx].loop_total, + rlevel_byte[byte_idx].loop_count); + } +#endif /* PICK_BEST_RANK_SCORE_NOT_AVG */ + + lmc_rlevel_rank.u = BDK_CSR_READ(node, BDK_LMCX_RLEVEL_RANKX(ddr_interface_num, rankx)); + + pack_rlevel_settings(ddr_interface_bytemask, ecc_ena, rlevel_byte, &lmc_rlevel_rank); + + if (rlevel_avg_loops > 1) { +#if PICK_BEST_RANK_SCORE_NOT_AVG + // restore the "best" bitmasks and their scores for printing + for (byte_idx = 0; byte_idx < 9; ++byte_idx) { + if ((ddr_interface_bytemask & (1 << byte_idx)) == 0) + continue; + // xlate PACKED index to UNPACKED index to get from rlevel_byte + rlevel_bitmask[byte_idx].bm = rlevel_byte[XPU(byte_idx, !!ecc_ena)].bm; + rlevel_bitmask[byte_idx].errs = rlevel_byte[XPU(byte_idx, !!ecc_ena)].bmerrs; + } + // print bitmasks/scores here only for DEV // FIXME? lower VBL? + if (dram_is_verbose(VBL_DEV)) { + display_RL_BM(node, ddr_interface_num, rankx, rlevel_bitmask, ecc_ena); + display_RL_BM_scores(node, ddr_interface_num, rankx, rlevel_bitmask, ecc_ena); + display_RL_SEQ_scores(node, ddr_interface_num, rankx, rlevel_byte, ecc_ena); + } + + display_RL_with_RODT(node, ddr_interface_num, lmc_rlevel_rank, rankx, + rlevel_scoreboard[rtt_nom][rodt_ctl][rankx].score, + print_nom_ohms, imp_values->rodt_ohms[rodt_ctl], + WITH_RODT_BESTSCORE); + +#else /* PICK_BEST_RANK_SCORE_NOT_AVG */ + display_RL_with_average(node, ddr_interface_num, lmc_rlevel_rank, rankx, + rlevel_scoreboard[rtt_nom][rodt_ctl][rankx].score); +#endif /* PICK_BEST_RANK_SCORE_NOT_AVG */ + + } /* if (rlevel_avg_loops > 1) */ + + rlevel_scoreboard[rtt_nom][rodt_ctl][rankx].setting = lmc_rlevel_rank.u; + + } /* for (rodt_ctl = max_rodt_ctl; rodt_ctl >= min_rodt_ctl; --rodt_ctl) */ + } /* for (rankx = 0; rankx < dimm_count*4; rankx++) */ + } /* for (rtt_idx=min_rtt_nom_idx; rtt_idx<max_rtt_nom_idx; ++rtt_idx) */ + + + /* Re-enable dynamic compensation settings. */ + if (rlevel_comp_offset != 0) { + lmc_comp_ctl2.u = BDK_CSR_READ(node, BDK_LMCX_COMP_CTL2(ddr_interface_num)); + + lmc_comp_ctl2.s.ptune = 0; + lmc_comp_ctl2.s.ntune = 0; + lmc_comp_ctl2.s.byp = 0; /* Disable bypass mode */ + DRAM_CSR_WRITE(node, BDK_LMCX_COMP_CTL2(ddr_interface_num), lmc_comp_ctl2.u); + BDK_CSR_READ(node, BDK_LMCX_COMP_CTL2(ddr_interface_num)); /* Read once */ + + lmc_comp_ctl2.u = BDK_CSR_READ(node, BDK_LMCX_COMP_CTL2(ddr_interface_num)); /* Read again */ + ddr_print("DDR__PTUNE/DDR__NTUNE : %d/%d\n", + lmc_comp_ctl2.s.ddr__ptune, lmc_comp_ctl2.s.ddr__ntune); + + lmc_control.u = BDK_CSR_READ(node, BDK_LMCX_CONTROL(ddr_interface_num)); + lmc_control.s.int_zqcs_dis = saved_int_zqcs_dis; /* Restore original setting */ + DRAM_CSR_WRITE(node, BDK_LMCX_CONTROL(ddr_interface_num), lmc_control.u); + + } + + + { + int override_compensation = 0; + if ((s = lookup_env_parameter("ddr__ptune")) != NULL) { + saved_ddr__ptune = strtoul(s, NULL, 0); + override_compensation = 1; + } + if ((s = lookup_env_parameter("ddr__ntune")) != NULL) { + saved_ddr__ntune = strtoul(s, NULL, 0); + override_compensation = 1; + } + if (override_compensation) { + lmc_comp_ctl2.s.ptune = saved_ddr__ptune; + lmc_comp_ctl2.s.ntune = saved_ddr__ntune; + + lmc_control.u = BDK_CSR_READ(node, BDK_LMCX_CONTROL(ddr_interface_num)); + saved_int_zqcs_dis = lmc_control.s.int_zqcs_dis; + lmc_control.s.int_zqcs_dis = 1; /* Disable ZQCS while in bypass. */ + DRAM_CSR_WRITE(node, BDK_LMCX_CONTROL(ddr_interface_num), lmc_control.u); + + lmc_comp_ctl2.s.byp = 1; /* Enable bypass mode */ + DRAM_CSR_WRITE(node, BDK_LMCX_COMP_CTL2(ddr_interface_num), lmc_comp_ctl2.u); + lmc_comp_ctl2.u = BDK_CSR_READ(node, BDK_LMCX_COMP_CTL2(ddr_interface_num)); /* Read again */ + + ddr_print("DDR__PTUNE/DDR__NTUNE : %d/%d\n", + lmc_comp_ctl2.s.ptune, lmc_comp_ctl2.s.ntune); + } + } + { /* Evaluation block */ + int best_rodt_score = DEFAULT_BEST_RANK_SCORE; /* Start with an arbitrarily high score */ + int auto_rodt_ctl = 0; + int auto_rtt_nom = 0; + int rodt_score; + int rodt_row_skip_mask = 0; + + // just add specific RODT rows to the skip mask for DDR4 at this time... + if (ddr_type == DDR4_DRAM) { + rodt_row_skip_mask |= (1 << ddr4_rodt_ctl_34_ohm); // skip RODT row 34 ohms for all DDR4 types + rodt_row_skip_mask |= (1 << ddr4_rodt_ctl_40_ohm); // skip RODT row 40 ohms for all DDR4 types +#if ADD_48_OHM_SKIP + rodt_row_skip_mask |= (1 << ddr4_rodt_ctl_48_ohm); // skip RODT row 48 ohms for all DDR4 types +#endif /* ADD_48OHM_SKIP */ +#if NOSKIP_40_48_OHM + // For now, do not skip RODT row 40 or 48 ohm when ddr_hertz is above 1075 MHz + if (ddr_hertz > 1075000000) { + rodt_row_skip_mask &= ~(1 << ddr4_rodt_ctl_40_ohm); // noskip RODT row 40 ohms + rodt_row_skip_mask &= ~(1 << ddr4_rodt_ctl_48_ohm); // noskip RODT row 48 ohms + } +#endif /* NOSKIP_40_48_OHM */ +#if NOSKIP_48_STACKED + // For now, do not skip RODT row 48 ohm for 2Rx4 stacked die DIMMs + if ((is_stacked_die) && (num_ranks == 2) && (dram_width == 4)) { + rodt_row_skip_mask &= ~(1 << ddr4_rodt_ctl_48_ohm); // noskip RODT row 48 ohms + } +#endif /* NOSKIP_48_STACKED */ +#if NOSKIP_FOR_MINI + // for now, leave all rows eligible when we have mini-DIMMs... + if ((spd_dimm_type == 5) || (spd_dimm_type == 6)) { + rodt_row_skip_mask = 0; + } +#endif /* NOSKIP_FOR_MINI */ +#if NOSKIP_FOR_2S_1R + // for now, leave all rows eligible when we have a 2-slot 1-rank config + if ((dimm_count == 2) && (num_ranks == 1)) { + rodt_row_skip_mask = 0; + } +#endif /* NOSKIP_FOR_2S_1R */ + } + + VB_PRT(VBL_DEV, "Evaluating Read-Leveling Scoreboard for AUTO settings.\n"); + for (rtt_idx=min_rtt_nom_idx; rtt_idx<=max_rtt_nom_idx; ++rtt_idx) { + rtt_nom = imp_values->rtt_nom_table[rtt_idx]; + + /* When the read ODT mask is zero the dyn_rtt_nom_mask is + zero than RTT_NOM will not be changing during + read-leveling. Since the value is fixed we only need + to test it once. */ + if ((dyn_rtt_nom_mask == 0) && (rtt_idx != min_rtt_nom_idx)) + continue; + + for (rodt_ctl=max_rodt_ctl; rodt_ctl>=min_rodt_ctl; --rodt_ctl) { + rodt_score = 0; + for (rankx = 0; rankx < dimm_count * 4;rankx++) { + if (!(rank_mask & (1 << rankx))) + continue; + debug_print("rlevel_scoreboard[rtt_nom=%d][rodt_ctl=%d][rankx=%d].score:%d\n", + rtt_nom, rodt_ctl, rankx, rlevel_scoreboard[rtt_nom][rodt_ctl][rankx].score); + rodt_score += rlevel_scoreboard[rtt_nom][rodt_ctl][rankx].score; + } + // FIXME: do we need to skip RODT rows here, like we do below in the by-RANK settings? + + /* When using automatic ODT settings use the ODT + settings associated with the best score for + all of the tested ODT combinations. */ + + if ((rodt_score < best_rodt_score) || // always take lower score, OR + ((rodt_score == best_rodt_score) && // take same score if RODT ohms are higher + (imp_values->rodt_ohms[rodt_ctl] > imp_values->rodt_ohms[auto_rodt_ctl]))) + { + debug_print("AUTO: new best score for rodt:%d (%3d), new score:%d, previous score:%d\n", + rodt_ctl, imp_values->rodt_ohms[rodt_ctl], rodt_score, best_rodt_score); + best_rodt_score = rodt_score; + auto_rodt_ctl = rodt_ctl; + auto_rtt_nom = rtt_nom; + } + } /* for (rodt_ctl=max_rodt_ctl; rodt_ctl>=min_rodt_ctl; --rodt_ctl) */ + } /* for (rtt_idx=min_rtt_nom_idx; rtt_idx<=max_rtt_nom_idx; ++rtt_idx) */ + + lmc_modereg_params1.u = BDK_CSR_READ(node, BDK_LMCX_MODEREG_PARAMS1(ddr_interface_num)); + + if (ddr_rtt_nom_auto) { + /* Store the automatically set RTT_NOM value */ + if (dyn_rtt_nom_mask & 1) lmc_modereg_params1.s.rtt_nom_00 = auto_rtt_nom; + if (dyn_rtt_nom_mask & 2) lmc_modereg_params1.s.rtt_nom_01 = auto_rtt_nom; + if (dyn_rtt_nom_mask & 4) lmc_modereg_params1.s.rtt_nom_10 = auto_rtt_nom; + if (dyn_rtt_nom_mask & 8) lmc_modereg_params1.s.rtt_nom_11 = auto_rtt_nom; + } else { + /* restore the manual settings to the register */ + lmc_modereg_params1.s.rtt_nom_00 = default_rtt_nom[0]; + lmc_modereg_params1.s.rtt_nom_01 = default_rtt_nom[1]; + lmc_modereg_params1.s.rtt_nom_10 = default_rtt_nom[2]; + lmc_modereg_params1.s.rtt_nom_11 = default_rtt_nom[3]; + } + + DRAM_CSR_WRITE(node, BDK_LMCX_MODEREG_PARAMS1(ddr_interface_num), lmc_modereg_params1.u); + VB_PRT(VBL_DEV, "RTT_NOM %3d, %3d, %3d, %3d ohms : %x,%x,%x,%x\n", + imp_values->rtt_nom_ohms[lmc_modereg_params1.s.rtt_nom_11], + imp_values->rtt_nom_ohms[lmc_modereg_params1.s.rtt_nom_10], + imp_values->rtt_nom_ohms[lmc_modereg_params1.s.rtt_nom_01], + imp_values->rtt_nom_ohms[lmc_modereg_params1.s.rtt_nom_00], + lmc_modereg_params1.s.rtt_nom_11, + lmc_modereg_params1.s.rtt_nom_10, + lmc_modereg_params1.s.rtt_nom_01, + lmc_modereg_params1.s.rtt_nom_00); + + VB_PRT(VBL_DEV, "RTT_WR %3d, %3d, %3d, %3d ohms : %x,%x,%x,%x\n", + imp_values->rtt_wr_ohms[EXTR_WR(lmc_modereg_params1.u, 3)], + imp_values->rtt_wr_ohms[EXTR_WR(lmc_modereg_params1.u, 2)], + imp_values->rtt_wr_ohms[EXTR_WR(lmc_modereg_params1.u, 1)], + imp_values->rtt_wr_ohms[EXTR_WR(lmc_modereg_params1.u, 0)], + EXTR_WR(lmc_modereg_params1.u, 3), + EXTR_WR(lmc_modereg_params1.u, 2), + EXTR_WR(lmc_modereg_params1.u, 1), + EXTR_WR(lmc_modereg_params1.u, 0)); + + VB_PRT(VBL_DEV, "DIC %3d, %3d, %3d, %3d ohms : %x,%x,%x,%x\n", + imp_values->dic_ohms[lmc_modereg_params1.s.dic_11], + imp_values->dic_ohms[lmc_modereg_params1.s.dic_10], + imp_values->dic_ohms[lmc_modereg_params1.s.dic_01], + imp_values->dic_ohms[lmc_modereg_params1.s.dic_00], + lmc_modereg_params1.s.dic_11, + lmc_modereg_params1.s.dic_10, + lmc_modereg_params1.s.dic_01, + lmc_modereg_params1.s.dic_00); + + if (ddr_type == DDR4_DRAM) { + bdk_lmcx_modereg_params2_t lmc_modereg_params2; + /* + * We must read the CSR, and not depend on odt_config[odt_idx].odt_mask2, + * since we could have overridden values with envvars. + * NOTE: this corrects the printout, since the CSR is not written with the old values... + */ + lmc_modereg_params2.u = BDK_CSR_READ(node, BDK_LMCX_MODEREG_PARAMS2(ddr_interface_num)); + + VB_PRT(VBL_DEV, "RTT_PARK %3d, %3d, %3d, %3d ohms : %x,%x,%x,%x\n", + imp_values->rtt_nom_ohms[lmc_modereg_params2.s.rtt_park_11], + imp_values->rtt_nom_ohms[lmc_modereg_params2.s.rtt_park_10], + imp_values->rtt_nom_ohms[lmc_modereg_params2.s.rtt_park_01], + imp_values->rtt_nom_ohms[lmc_modereg_params2.s.rtt_park_00], + lmc_modereg_params2.s.rtt_park_11, + lmc_modereg_params2.s.rtt_park_10, + lmc_modereg_params2.s.rtt_park_01, + lmc_modereg_params2.s.rtt_park_00); + + VB_PRT(VBL_DEV, "%-45s : 0x%x,0x%x,0x%x,0x%x\n", "VREF_RANGE", + lmc_modereg_params2.s.vref_range_11, + lmc_modereg_params2.s.vref_range_10, + lmc_modereg_params2.s.vref_range_01, + lmc_modereg_params2.s.vref_range_00); + + VB_PRT(VBL_DEV, "%-45s : 0x%x,0x%x,0x%x,0x%x\n", "VREF_VALUE", + lmc_modereg_params2.s.vref_value_11, + lmc_modereg_params2.s.vref_value_10, + lmc_modereg_params2.s.vref_value_01, + lmc_modereg_params2.s.vref_value_00); + } + + lmc_comp_ctl2.u = BDK_CSR_READ(node, BDK_LMCX_COMP_CTL2(ddr_interface_num)); + if (ddr_rodt_ctl_auto) + lmc_comp_ctl2.s.rodt_ctl = auto_rodt_ctl; + else + lmc_comp_ctl2.s.rodt_ctl = default_rodt_ctl; // back to the original setting + DRAM_CSR_WRITE(node, BDK_LMCX_COMP_CTL2(ddr_interface_num), lmc_comp_ctl2.u); + lmc_comp_ctl2.u = BDK_CSR_READ(node, BDK_LMCX_COMP_CTL2(ddr_interface_num)); + VB_PRT(VBL_DEV, "Read ODT_CTL : 0x%x (%d ohms)\n", + lmc_comp_ctl2.s.rodt_ctl, imp_values->rodt_ohms[lmc_comp_ctl2.s.rodt_ctl]); + + ////////////////// this is the start of the RANK MAJOR LOOP + + for (rankx = 0; rankx < dimm_count * 4; rankx++) { + int best_rank_score = DEFAULT_BEST_RANK_SCORE; /* Start with an arbitrarily high score */ + int best_rank_rtt_nom = 0; + //int best_rank_nom_ohms = 0; + int best_rank_ctl = 0; + int best_rank_ohms = 0; + int best_rankx = 0; + + if (!(rank_mask & (1 << rankx))) + continue; + + /* Use the delays associated with the best score for each individual rank */ + VB_PRT(VBL_TME, "Evaluating Read-Leveling Scoreboard for Rank %d settings.\n", rankx); + + // some of the rank-related loops below need to operate only on the ranks of a single DIMM, + // so create a mask for their use here + int dimm_rank_mask; + if (num_ranks == 4) + dimm_rank_mask = rank_mask; // should be 1111 + else { + dimm_rank_mask = rank_mask & 3; // should be 01 or 11 + if (rankx >= 2) + dimm_rank_mask <<= 2; // doing a rank on the second DIMM, should be 0100 or 1100 + } + debug_print("DIMM rank mask: 0x%x, rank mask: 0x%x, rankx: %d\n", dimm_rank_mask, rank_mask, rankx); + + ////////////////// this is the start of the BEST ROW SCORE LOOP + + for (rtt_idx = min_rtt_nom_idx; rtt_idx <= max_rtt_nom_idx; ++rtt_idx) { + //int rtt_nom_ohms; + rtt_nom = imp_values->rtt_nom_table[rtt_idx]; + //rtt_nom_ohms = imp_values->rtt_nom_ohms[rtt_nom]; + + /* When the read ODT mask is zero the dyn_rtt_nom_mask is + zero than RTT_NOM will not be changing during + read-leveling. Since the value is fixed we only need + to test it once. */ + if ((dyn_rtt_nom_mask == 0) && (rtt_idx != min_rtt_nom_idx)) + continue; + + debug_print("N%d.LMC%d.R%d: starting RTT_NOM %d (%d)\n", + node, ddr_interface_num, rankx, rtt_nom, rtt_nom_ohms); + + for (rodt_ctl = max_rodt_ctl; rodt_ctl >= min_rodt_ctl; --rodt_ctl) { + int next_ohms = imp_values->rodt_ohms[rodt_ctl]; + + // skip RODT rows in mask, but *NOT* rows with too high a score; + // we will not use the skipped ones for printing or evaluating, but + // we need to allow all the non-skipped ones to be candidates for "best" + if (((1 << rodt_ctl) & rodt_row_skip_mask) != 0) { + debug_print("N%d.LMC%d.R%d: SKIPPING rodt:%d (%d) with rank_score:%d\n", + node, ddr_interface_num, rankx, rodt_ctl, next_ohms, next_score); + continue; + } + for (int orankx = 0; orankx < dimm_count * 4; orankx++) { // this is ROFFIX-0528 + if (!(dimm_rank_mask & (1 << orankx))) // stay on the same DIMM + continue; + + int next_score = rlevel_scoreboard[rtt_nom][rodt_ctl][orankx].score; + + if (next_score > best_rank_score) // always skip a higher score + continue; + if (next_score == best_rank_score) { // if scores are equal + if (next_ohms < best_rank_ohms) // always skip lower ohms + continue; + if (next_ohms == best_rank_ohms) { // if same ohms + if (orankx != rankx) // always skip the other rank(s) + continue; + } + // else next_ohms are greater, always choose it + } + // else next_score is less than current best, so always choose it + VB_PRT(VBL_DEV2, "N%d.LMC%d.R%d: new best score: rank %d, rodt %d(%3d), new best %d, previous best %d(%d)\n", + node, ddr_interface_num, rankx, orankx, rodt_ctl, next_ohms, next_score, + best_rank_score, best_rank_ohms); + best_rank_score = next_score; + best_rank_rtt_nom = rtt_nom; + //best_rank_nom_ohms = rtt_nom_ohms; + best_rank_ctl = rodt_ctl; + best_rank_ohms = next_ohms; + best_rankx = orankx; + lmc_rlevel_rank.u = rlevel_scoreboard[rtt_nom][rodt_ctl][orankx].setting; + + } /* for (int orankx = 0; orankx < dimm_count * 4; orankx++) */ + } /* for (rodt_ctl = max_rodt_ctl; rodt_ctl >= min_rodt_ctl; --rodt_ctl) */ + } /* for (rtt_idx = min_rtt_nom_idx; rtt_idx <= max_rtt_nom_idx; ++rtt_idx) */ + + ////////////////// this is the end of the BEST ROW SCORE LOOP + + // DANGER, Will Robinson!! Abort now if we did not find a best score at all... + if (best_rank_score == DEFAULT_BEST_RANK_SCORE) { + error_print("WARNING: no best rank score found for N%d.LMC%d.R%d - resetting node...\n", + node, ddr_interface_num, rankx); + bdk_wait_usec(500000); + bdk_reset_chip(node); + } + + // FIXME: relative now, but still arbitrary... + // halve the range if 2 DIMMs unless they are single rank... + int MAX_RANK_SCORE = best_rank_score; + MAX_RANK_SCORE += (MAX_RANK_SCORE_LIMIT / ((num_ranks > 1) ? dimm_count : 1)); + + if (!ecc_ena){ + lmc_rlevel_rank.cn83xx.byte8 = lmc_rlevel_rank.cn83xx.byte0; /* ECC is not used */ + } + + // at the end, write the best row settings to the current rank + DRAM_CSR_WRITE(node, BDK_LMCX_RLEVEL_RANKX(ddr_interface_num, rankx), lmc_rlevel_rank.u); + lmc_rlevel_rank.u = BDK_CSR_READ(node, BDK_LMCX_RLEVEL_RANKX(ddr_interface_num, rankx)); + + bdk_lmcx_rlevel_rankx_t saved_rlevel_rank; + saved_rlevel_rank.u = lmc_rlevel_rank.u; + + ////////////////// this is the start of the PRINT LOOP + + // for pass==0, print current rank, pass==1 print other rank(s) + // this is done because we want to show each ranks RODT values together, not interlaced +#if COUNT_RL_CANDIDATES + // keep separates for ranks - pass=0 target rank, pass=1 other rank on DIMM + int mask_skipped[2] = {0,0}; + int score_skipped[2] = {0,0}; + int selected_rows[2] = {0,0}; + int zero_scores[2] = {0,0}; +#endif /* COUNT_RL_CANDIDATES */ + for (int pass = 0; pass < 2; pass++ ) { + for (int orankx = 0; orankx < dimm_count * 4; orankx++) { + if (!(dimm_rank_mask & (1 << orankx))) // stay on the same DIMM + continue; + + if (((pass == 0) && (orankx != rankx)) || ((pass != 0) && (orankx == rankx))) + continue; + + for (rtt_idx = min_rtt_nom_idx; rtt_idx <= max_rtt_nom_idx; ++rtt_idx) { + rtt_nom = imp_values->rtt_nom_table[rtt_idx]; + if (dyn_rtt_nom_mask == 0) { + print_nom_ohms = -1; + if (rtt_idx != min_rtt_nom_idx) + continue; + } else { + print_nom_ohms = imp_values->rtt_nom_ohms[rtt_nom]; + } + + // cycle through all the RODT values... + for (rodt_ctl = max_rodt_ctl; rodt_ctl >= min_rodt_ctl; --rodt_ctl) { + bdk_lmcx_rlevel_rankx_t temp_rlevel_rank; + int temp_score = rlevel_scoreboard[rtt_nom][rodt_ctl][orankx].score; + temp_rlevel_rank.u = rlevel_scoreboard[rtt_nom][rodt_ctl][orankx].setting; + + // skip RODT rows in mask, or rows with too high a score; + // we will not use them for printing or evaluating... +#if COUNT_RL_CANDIDATES + int skip_row; + if ((1 << rodt_ctl) & rodt_row_skip_mask) { + skip_row = WITH_RODT_SKIPPING; + ++mask_skipped[pass]; + } else if (temp_score > MAX_RANK_SCORE) { + skip_row = WITH_RODT_SKIPPING; + ++score_skipped[pass]; + } else { + skip_row = WITH_RODT_BLANK; + ++selected_rows[pass]; + if (temp_score == 0) + ++zero_scores[pass]; + } + +#else /* COUNT_RL_CANDIDATES */ + int skip_row = (((1 << rodt_ctl) & rodt_row_skip_mask) || (temp_score > MAX_RANK_SCORE)) + ? WITH_RODT_SKIPPING: WITH_RODT_BLANK; +#endif /* COUNT_RL_CANDIDATES */ + + // identify and print the BEST ROW when it comes up + if ((skip_row == WITH_RODT_BLANK) && + (best_rankx == orankx) && + (best_rank_rtt_nom == rtt_nom) && + (best_rank_ctl == rodt_ctl)) + { + skip_row = WITH_RODT_BESTROW; + } + + display_RL_with_RODT(node, ddr_interface_num, + temp_rlevel_rank, orankx, temp_score, + print_nom_ohms, + imp_values->rodt_ohms[rodt_ctl], + skip_row); + + } /* for (rodt_ctl = max_rodt_ctl; rodt_ctl >= min_rodt_ctl; --rodt_ctl) */ + } /* for (rtt_idx=min_rtt_nom_idx; rtt_idx<=max_rtt_nom_idx; ++rtt_idx) */ + } /* for (int orankx = 0; orankx < dimm_count * 4; orankx++) { */ + } /* for (int pass = 0; pass < 2; pass++ ) */ +#if COUNT_RL_CANDIDATES + VB_PRT(VBL_TME, "N%d.LMC%d.R%d: RLROWS: selected %d+%d, zero_scores %d+%d, mask_skipped %d+%d, score_skipped %d+%d\n", + node, ddr_interface_num, rankx, + selected_rows[0], selected_rows[1], + zero_scores[0], zero_scores[1], + mask_skipped[0], mask_skipped[1], + score_skipped[0], score_skipped[1]); +#endif /* COUNT_RL_CANDIDATES */ + + ////////////////// this is the end of the PRINT LOOP + + // now evaluate which bytes need adjusting + uint64_t byte_msk = 0x3f; // 6-bit fields + uint64_t best_byte, new_byte, temp_byte, orig_best_byte; + + uint64_t rank_best_bytes[9]; // collect the new byte values; first init with current best for neighbor use + for (int byte_idx = 0, byte_sh = 0; byte_idx < 8+ecc_ena; byte_idx++, byte_sh += 6) { + rank_best_bytes[byte_idx] = (lmc_rlevel_rank.u >> byte_sh) & byte_msk; + } + + ////////////////// this is the start of the BEST BYTE LOOP + + for (int byte_idx = 0, byte_sh = 0; byte_idx < 8+ecc_ena; byte_idx++, byte_sh += 6) { + best_byte = orig_best_byte = rank_best_bytes[byte_idx]; + + ////////////////// this is the start of the BEST BYTE AVERAGING LOOP + + // validate the initial "best" byte by looking at the average of the unskipped byte-column entries + // we want to do this before we go further, so we can try to start with a better initial value + // this is the so-called "BESTBUY" patch set + int sum = 0, count = 0; + + for (rtt_idx = min_rtt_nom_idx; rtt_idx <= max_rtt_nom_idx; ++rtt_idx) { + rtt_nom = imp_values->rtt_nom_table[rtt_idx]; + if ((dyn_rtt_nom_mask == 0) && (rtt_idx != min_rtt_nom_idx)) + continue; + + for (rodt_ctl = max_rodt_ctl; rodt_ctl >= min_rodt_ctl; --rodt_ctl) { + bdk_lmcx_rlevel_rankx_t temp_rlevel_rank; + int temp_score; + for (int orankx = 0; orankx < dimm_count * 4; orankx++) { // average over all the ranks + if (!(dimm_rank_mask & (1 << orankx))) // stay on the same DIMM + continue; + temp_score = rlevel_scoreboard[rtt_nom][rodt_ctl][orankx].score; + // skip RODT rows in mask, or rows with too high a score; + // we will not use them for printing or evaluating... + + if (!((1 << rodt_ctl) & rodt_row_skip_mask) && + (temp_score <= MAX_RANK_SCORE)) + { + temp_rlevel_rank.u = rlevel_scoreboard[rtt_nom][rodt_ctl][orankx].setting; + temp_byte = (temp_rlevel_rank.u >> byte_sh) & byte_msk; + sum += temp_byte; + count++; + } + } /* for (int orankx = 0; orankx < dimm_count * 4; orankx++) */ + } /* for (rodt_ctl = max_rodt_ctl; rodt_ctl >= min_rodt_ctl; --rodt_ctl) */ + } /* for (rtt_idx=min_rtt_nom_idx; rtt_idx<=max_rtt_nom_idx; ++rtt_idx) */ + + ////////////////// this is the end of the BEST BYTE AVERAGING LOOP + + + uint64_t avg_byte = divide_nint(sum, count); // FIXME: validate count and sum?? + int avg_diff = (int)best_byte - (int)avg_byte; + new_byte = best_byte; + if (avg_diff != 0) { + // bump best up/dn by 1, not necessarily all the way to avg + new_byte = best_byte + ((avg_diff > 0) ? -1: 1); + } + + VB_PRT(VBL_DEV, "N%d.LMC%d.R%d: START: Byte %d: best %d is different by %d from average %d, using %d.\n", + node, ddr_interface_num, rankx, + byte_idx, (int)best_byte, avg_diff, (int)avg_byte, (int)new_byte); + best_byte = new_byte; + + // At this point best_byte is either: + // 1. the original byte-column value from the best scoring RODT row, OR + // 2. that value bumped toward the average of all the byte-column values + // + // best_byte will not change from here on... + + ////////////////// this is the start of the BEST BYTE COUNTING LOOP + + // NOTE: we do this next loop separately from above, because we count relative to "best_byte" + // which may have been modified by the above averaging operation... + // + // Also, the above only moves toward the average by +- 1, so that we will always have a count + // of at least 1 for the original best byte, even if all the others are further away and not counted; + // this ensures we will go back to the original if no others are counted... + // FIXME: this could cause issue if the range of values for a byte-lane are too disparate... + int count_less = 0, count_same = 0, count_more = 0; +#if FAILSAFE_CHECK + uint64_t count_byte = new_byte; // save the value we will count around +#endif /* FAILSAFE_CHECK */ +#if RANK_MAJORITY + int rank_less = 0, rank_same = 0, rank_more = 0; +#endif /* RANK_MAJORITY */ + + for (rtt_idx = min_rtt_nom_idx; rtt_idx <= max_rtt_nom_idx; ++rtt_idx) { + rtt_nom = imp_values->rtt_nom_table[rtt_idx]; + if ((dyn_rtt_nom_mask == 0) && (rtt_idx != min_rtt_nom_idx)) + continue; + + for (rodt_ctl = max_rodt_ctl; rodt_ctl >= min_rodt_ctl; --rodt_ctl) { + bdk_lmcx_rlevel_rankx_t temp_rlevel_rank; + int temp_score; + for (int orankx = 0; orankx < dimm_count * 4; orankx++) { // count over all the ranks + if (!(dimm_rank_mask & (1 << orankx))) // stay on the same DIMM + continue; + temp_score = rlevel_scoreboard[rtt_nom][rodt_ctl][orankx].score; + // skip RODT rows in mask, or rows with too high a score; + // we will not use them for printing or evaluating... + if (((1 << rodt_ctl) & rodt_row_skip_mask) || + (temp_score > MAX_RANK_SCORE)) + { + continue; + } + temp_rlevel_rank.u = rlevel_scoreboard[rtt_nom][rodt_ctl][orankx].setting; + temp_byte = (temp_rlevel_rank.u >> byte_sh) & byte_msk; + + if (temp_byte == 0) // do not count it if illegal + continue; + else if (temp_byte == best_byte) + count_same++; + else if (temp_byte == best_byte - 1) + count_less++; + else if (temp_byte == best_byte + 1) + count_more++; + // else do not count anything more than 1 away from the best +#if RANK_MAJORITY + // FIXME? count is relative to best_byte; should it be rank-based? + if (orankx != rankx) // rank counts only on main rank + continue; + else if (temp_byte == best_byte) + rank_same++; + else if (temp_byte == best_byte - 1) + rank_less++; + else if (temp_byte == best_byte + 1) + rank_more++; +#endif /* RANK_MAJORITY */ + } /* for (int orankx = 0; orankx < dimm_count * 4; orankx++) */ + } /* for (rodt_ctl = max_rodt_ctl; rodt_ctl >= min_rodt_ctl; --rodt_ctl) */ + } /* for (rtt_idx=min_rtt_nom_idx; rtt_idx<=max_rtt_nom_idx; ++rtt_idx) */ + +#if RANK_MAJORITY + VB_PRT(VBL_DEV, "N%d.LMC%d.R%d: COUNT: Byte %d: orig %d now %d, more %d same %d less %d (%d/%d/%d)\n", + node, ddr_interface_num, rankx, + byte_idx, (int)orig_best_byte, (int)best_byte, + count_more, count_same, count_less, + rank_more, rank_same, rank_less); +#else /* RANK_MAJORITY */ + VB_PRT(VBL_DEV, "N%d.LMC%d.R%d: COUNT: Byte %d: orig %d now %d, more %d same %d less %d\n", + node, ddr_interface_num, rankx, + byte_idx, (int)orig_best_byte, (int)best_byte, + count_more, count_same, count_less); +#endif /* RANK_MAJORITY */ + ////////////////// this is the end of the BEST BYTE COUNTING LOOP + + // choose the new byte value + // we need to check that there is no gap greater than 2 between adjacent bytes + // (adjacency depends on DIMM type) + // use the neighbor value to help decide + // initially, the rank_best_bytes[] will contain values from the chosen lowest score rank + new_byte = 0; + + // neighbor is index-1 unless we are index 0 or index 8 (ECC) + int neighbor = (byte_idx == 8) ? 3 : ((byte_idx == 0) ? 1 : byte_idx - 1); + uint64_t neigh_byte = rank_best_bytes[neighbor]; + + + // can go up or down or stay the same, so look at a numeric average to help + new_byte = divide_nint(((count_more * (best_byte + 1)) + + (count_same * (best_byte + 0)) + + (count_less * (best_byte - 1))), + max(1, (count_more + count_same + count_less))); + + // use neighbor to help choose with average + if ((byte_idx > 0) && (_abs(neigh_byte - new_byte) > 2)) // but not for byte 0 + { + uint64_t avg_pick = new_byte; + if ((new_byte - best_byte) != 0) + new_byte = best_byte; // back to best, average did not get better + else // avg was the same, still too far, now move it towards the neighbor + new_byte += (neigh_byte > new_byte) ? 1 : -1; + + VB_PRT(VBL_DEV, "N%d.LMC%d.R%d: AVERAGE: Byte %d: neighbor %d too different %d from average %d, picking %d.\n", + node, ddr_interface_num, rankx, + byte_idx, neighbor, (int)neigh_byte, (int)avg_pick, (int)new_byte); + } +#if MAJORITY_OVER_AVG + // NOTE: + // For now, we let the neighbor processing above trump the new simple majority processing here. + // This is mostly because we have seen no smoking gun for a neighbor bad choice (yet?). + // Also note that we will ALWAYS be using byte 0 majority, because of the if clause above. + else { + // majority is dependent on the counts, which are relative to best_byte, so start there + uint64_t maj_byte = best_byte; + if ((count_more > count_same) && (count_more > count_less)) { + maj_byte++; + } else if ((count_less > count_same) && (count_less > count_more)) { + maj_byte--; + } + if (maj_byte != new_byte) { + // print only when majority choice is different from average + VB_PRT(VBL_DEV, "N%d.LMC%d.R%d: MAJORTY: Byte %d: picking majority of %d over average %d.\n", + node, ddr_interface_num, rankx, + byte_idx, (int)maj_byte, (int)new_byte); + new_byte = maj_byte; + } else { + VB_PRT(VBL_DEV, "N%d.LMC%d.R%d: AVERAGE: Byte %d: picking average of %d.\n", + node, ddr_interface_num, rankx, + byte_idx, (int)new_byte); + } +#if RANK_MAJORITY + // rank majority is dependent on the rank counts, which are relative to best_byte, + // so start there, and adjust according to the rank counts majority + uint64_t rank_maj = best_byte; + if ((rank_more > rank_same) && (rank_more > rank_less)) { + rank_maj++; + } else if ((rank_less > rank_same) && (rank_less > rank_more)) { + rank_maj--; + } + int rank_sum = rank_more + rank_same + rank_less; + + // now, let rank majority possibly rule over the current new_byte however we got it + if (rank_maj != new_byte) { // only if different + // Here is where we decide whether to completely apply RANK_MAJORITY or not + // FIXME: For the moment, we do it ONLY when running 2-slot configs + // FIXME? or when rank_sum is big enough? + if ((dimm_count > 1) || (rank_sum > 2)) { + // print only when rank majority choice is selected + VB_PRT(VBL_DEV, "N%d.LMC%d.R%d: RANKMAJ: Byte %d: picking %d over %d.\n", + node, ddr_interface_num, rankx, + byte_idx, (int)rank_maj, (int)new_byte); + new_byte = rank_maj; + } else { // FIXME: print some info when we could have chosen RANKMAJ but did not + VB_PRT(VBL_DEV, "N%d.LMC%d.R%d: RANKMAJ: Byte %d: NOT using %d over %d (best=%d,sum=%d).\n", + node, ddr_interface_num, rankx, + byte_idx, (int)rank_maj, (int)new_byte, + (int)best_byte, rank_sum); + } + } +#endif /* RANK_MAJORITY */ + } +#else + else { + VB_PRT(VBL_DEV, "N%d.LMC%d.R%d: AVERAGE: Byte %d: picking average of %d.\n", + node, ddr_interface_num, rankx, + byte_idx, (int)new_byte); + } +#endif +#if FAILSAFE_CHECK + // one last check: + // if new_byte is still count_byte, BUT there was no count for that value, DO SOMETHING!!! + // FIXME: go back to original best byte from the best row + if ((new_byte == count_byte) && (count_same == 0)) { + new_byte = orig_best_byte; + VB_PRT(VBL_DEV, "N%d.LMC%d.R%d: FAILSAF: Byte %d: going back to original %d.\n", + node, ddr_interface_num, rankx, + byte_idx, (int)new_byte); + } +#endif /* FAILSAFE_CHECK */ +#if PERFECT_BITMASK_COUNTING + // Look at counts for "perfect" bitmasks if we had any for this byte-lane. + // Remember, we only counted for DDR4, so zero means none or DDR3, and we bypass this... + if (rank_perfect_counts[rankx].total[byte_idx] > 0) { + // FIXME: should be more error checking, look for ties, etc... + int i, delay_count, delay_value, delay_max; + uint32_t ties; + delay_value = -1; + delay_max = 0; + ties = 0; + + for (i = 0; i < 32; i++) { + delay_count = rank_perfect_counts[rankx].count[byte_idx][i]; + if (delay_count > 0) { // only look closer if there are any,,, + if (delay_count > delay_max) { + delay_max = delay_count; + delay_value = i; + ties = 0; // reset ties to none + } else if (delay_count == delay_max) { + if (ties == 0) + ties = 1UL << delay_value; // put in original value + ties |= 1UL << i; // add new value + } + } + } /* for (i = 0; i < 32; i++) */ + + if (delay_value >= 0) { + if (ties != 0) { + if (ties & (1UL << (int)new_byte)) { + // leave choice as new_byte if any tied one is the same... + + + delay_value = (int)new_byte; + VB_PRT(VBL_DEV, "N%d.LMC%d.R%d: PERFECT: Byte %d: TIES (0x%x) INCLUDED %d (%d)\n", + node, ddr_interface_num, rankx, byte_idx, ties, (int)new_byte, delay_max); + } else { + // FIXME: should choose a perfect one!!! + // FIXME: for now, leave the choice as new_byte + delay_value = (int)new_byte; + VB_PRT(VBL_DEV, "N%d.LMC%d.R%d: PERFECT: Byte %d: TIES (0x%x) OMITTED %d (%d)\n", + node, ddr_interface_num, rankx, byte_idx, ties, (int)new_byte, delay_max); + } + } /* if (ties != 0) */ + + if (delay_value != (int)new_byte) { + delay_count = rank_perfect_counts[rankx].count[byte_idx][(int)new_byte]; + VB_PRT(VBL_DEV, "N%d.LMC%d.R%d: PERFECT: Byte %d: DIFF from %d (%d), USING %d (%d)\n", + node, ddr_interface_num, rankx, byte_idx, (int)new_byte, + delay_count, delay_value, delay_max); + new_byte = (uint64_t)delay_value; // FIXME: make this optional via envvar? + } else { + debug_print("N%d.LMC%d.R%d: PERFECT: Byte %d: SAME as %d (%d)\n", + node, ddr_interface_num, rankx, byte_idx, new_byte, delay_max); + } + } + } /* if (rank_perfect_counts[rankx].total[byte_idx] > 0) */ + else { + if (ddr_type == DDR4_DRAM) { // only report when DDR4 + // FIXME: remove or increase VBL for this output... + VB_PRT(VBL_DEV, "N%d.LMC%d.R%d: PERFECT: Byte %d: ZERO perfect bitmasks\n", + node, ddr_interface_num, rankx, byte_idx); + } + } /* if (rank_perfect_counts[rankx].total[byte_idx] > 0) */ +#endif /* PERFECT_BITMASK_COUNTING */ + + VB_PRT(VBL_DEV, "N%d.LMC%d.R%d: SUMMARY: Byte %d: %s: orig %d now %d, more %d same %d less %d, using %d\n", + node, ddr_interface_num, rankx, + byte_idx, "AVG", (int)orig_best_byte, + (int)best_byte, count_more, count_same, count_less, (int)new_byte); + + // update the byte with the new value (NOTE: orig value in the CSR may not be current "best") + lmc_rlevel_rank.u &= ~(byte_msk << byte_sh); + lmc_rlevel_rank.u |= (new_byte << byte_sh); + + rank_best_bytes[byte_idx] = new_byte; // save new best for neighbor use + + } /* for (byte_idx = 0; byte_idx < 8+ecc_ena; byte_idx++) */ + + ////////////////// this is the end of the BEST BYTE LOOP + + if (saved_rlevel_rank.u != lmc_rlevel_rank.u) { + DRAM_CSR_WRITE(node, BDK_LMCX_RLEVEL_RANKX(ddr_interface_num, rankx), lmc_rlevel_rank.u); + lmc_rlevel_rank.u = BDK_CSR_READ(node, BDK_LMCX_RLEVEL_RANKX(ddr_interface_num, rankx)); + debug_print("Adjusting Read-Leveling per-RANK settings.\n"); + } else { + debug_print("Not Adjusting Read-Leveling per-RANK settings.\n"); + } + display_RL_with_final(node, ddr_interface_num, lmc_rlevel_rank, rankx); + +#if RLEXTRAS_PATCH +#define RLEVEL_RANKX_EXTRAS_INCR 4 + if ((rank_mask & 0x0F) != 0x0F) { // if there are unused entries to be filled + bdk_lmcx_rlevel_rankx_t temp_rlevel_rank = lmc_rlevel_rank; // copy the current rank + int byte, delay; + if (rankx < 3) { + debug_print("N%d.LMC%d.R%d: checking for RLEVEL_RANK unused entries.\n", + node, ddr_interface_num, rankx); + for (byte = 0; byte < 9; byte++) { // modify the copy in prep for writing to empty slot(s) + delay = get_rlevel_rank_struct(&temp_rlevel_rank, byte) + RLEVEL_RANKX_EXTRAS_INCR; + if (delay > (int)RLEVEL_BYTE_MSK) delay = RLEVEL_BYTE_MSK; + update_rlevel_rank_struct(&temp_rlevel_rank, byte, delay); + } + if (rankx == 0) { // if rank 0, write rank 1 and rank 2 here if empty + if (!(rank_mask & (1<<1))) { // check that rank 1 is empty + VB_PRT(VBL_DEV, "N%d.LMC%d.R%d: writing RLEVEL_RANK unused entry R%d.\n", + node, ddr_interface_num, rankx, 1); + DRAM_CSR_WRITE(node, BDK_LMCX_RLEVEL_RANKX(ddr_interface_num, 1), temp_rlevel_rank.u); + } + if (!(rank_mask & (1<<2))) { // check that rank 2 is empty + VB_PRT(VBL_DEV, "N%d.LMC%d.R%d: writing RLEVEL_RANK unused entry R%d.\n", + node, ddr_interface_num, rankx, 2); + DRAM_CSR_WRITE(node, BDK_LMCX_RLEVEL_RANKX(ddr_interface_num, 2), temp_rlevel_rank.u); + } + } + // if ranks 0, 1 or 2, write rank 3 here if empty + if (!(rank_mask & (1<<3))) { // check that rank 3 is empty + VB_PRT(VBL_DEV, "N%d.LMC%d.R%d: writing RLEVEL_RANK unused entry R%d.\n", + node, ddr_interface_num, rankx, 3); + DRAM_CSR_WRITE(node, BDK_LMCX_RLEVEL_RANKX(ddr_interface_num, 3), temp_rlevel_rank.u); + } + } + } +#endif /* RLEXTRAS_PATCH */ + } /* for (rankx = 0; rankx < dimm_count * 4; rankx++) */ + + ////////////////// this is the end of the RANK MAJOR LOOP + + } /* Evaluation block */ + } /* while(rlevel_debug_loops--) */ + + lmc_control.s.ddr2t = save_ddr2t; + DRAM_CSR_WRITE(node, BDK_LMCX_CONTROL(ddr_interface_num), lmc_control.u); + lmc_control.u = BDK_CSR_READ(node, BDK_LMCX_CONTROL(ddr_interface_num)); + ddr_print("%-45s : %6d\n", "DDR2T", lmc_control.s.ddr2t); /* Display final 2T value */ + + + perform_ddr_init_sequence(node, rank_mask, ddr_interface_num); + + for (rankx = 0; rankx < dimm_count * 4;rankx++) { + uint64_t value; + int parameter_set = 0; + if (!(rank_mask & (1 << rankx))) + continue; + + lmc_rlevel_rank.u = BDK_CSR_READ(node, BDK_LMCX_RLEVEL_RANKX(ddr_interface_num, rankx)); + + for (i=0; i<9; ++i) { + if ((s = lookup_env_parameter("ddr%d_rlevel_rank%d_byte%d", ddr_interface_num, rankx, i)) != NULL) { + parameter_set |= 1; + value = strtoul(s, NULL, 0); + + update_rlevel_rank_struct(&lmc_rlevel_rank, i, value); + } + } + + if ((s = lookup_env_parameter_ull("ddr%d_rlevel_rank%d", ddr_interface_num, rankx)) != NULL) { + parameter_set |= 1; + value = strtoull(s, NULL, 0); + lmc_rlevel_rank.u = value; + } + + + if (bdk_is_platform(BDK_PLATFORM_ASIM)) { + parameter_set |= 1; + + lmc_rlevel_rank.cn83xx.byte8 = 3; + lmc_rlevel_rank.cn83xx.byte7 = 3; + lmc_rlevel_rank.cn83xx.byte6 = 3; + lmc_rlevel_rank.cn83xx.byte5 = 3; + lmc_rlevel_rank.cn83xx.byte4 = 3; + lmc_rlevel_rank.cn83xx.byte3 = 3; + lmc_rlevel_rank.cn83xx.byte2 = 3; + lmc_rlevel_rank.cn83xx.byte1 = 3; + lmc_rlevel_rank.cn83xx.byte0 = 3; + } + + if (parameter_set) { + DRAM_CSR_WRITE(node, BDK_LMCX_RLEVEL_RANKX(ddr_interface_num, rankx), lmc_rlevel_rank.u); + display_RL(node, ddr_interface_num, lmc_rlevel_rank, rankx); + } + } + } + + /* Workaround Trcd overflow by using Additive latency. */ + if (CAVIUM_IS_MODEL(CAVIUM_CN88XX_PASS1_X)) + { + bdk_lmcx_modereg_params0_t lmc_modereg_params0; + bdk_lmcx_timing_params1_t lmc_timing_params1; + bdk_lmcx_control_t lmc_control; + int rankx; + + lmc_timing_params1.u = BDK_CSR_READ(node, BDK_LMCX_TIMING_PARAMS1(ddr_interface_num)); + lmc_modereg_params0.u = BDK_CSR_READ(node, BDK_LMCX_MODEREG_PARAMS0(ddr_interface_num)); + lmc_control.u = BDK_CSR_READ(node, BDK_LMCX_CONTROL(ddr_interface_num)); + + if (lmc_timing_params1.s.trcd == 0) { + ddr_print("Workaround Trcd overflow by using Additive latency.\n"); + lmc_timing_params1.s.trcd = 12; /* Hard code this to 12 and enable additive latency */ + lmc_modereg_params0.s.al = 2; /* CL-2 */ + lmc_control.s.pocas = 1; + + ddr_print("MODEREG_PARAMS0 : 0x%016lx\n", lmc_modereg_params0.u); + DRAM_CSR_WRITE(node, BDK_LMCX_MODEREG_PARAMS0(ddr_interface_num), lmc_modereg_params0.u); + ddr_print("TIMING_PARAMS1 : 0x%016lx\n", lmc_timing_params1.u); + DRAM_CSR_WRITE(node, BDK_LMCX_TIMING_PARAMS1(ddr_interface_num), lmc_timing_params1.u); + + ddr_print("LMC_CONTROL : 0x%016lx\n", lmc_control.u); + DRAM_CSR_WRITE(node, BDK_LMCX_CONTROL(ddr_interface_num), lmc_control.u); + + for (rankx = 0; rankx < dimm_count * 4; rankx++) { + if (!(rank_mask & (1 << rankx))) + continue; + + ddr4_mrw(node, ddr_interface_num, rankx, -1, 1, 0); /* MR1 */ + } + } + } + + // this is here just for output, to allow check of the Deskew settings one last time... + if (! disable_deskew_training) { + deskew_counts_t dsk_counts; + VB_PRT(VBL_TME, "N%d.LMC%d: Check Deskew Settings before software Write-Leveling.\n", + node, ddr_interface_num); + Validate_Read_Deskew_Training(node, rank_mask, ddr_interface_num, &dsk_counts, VBL_TME); // TME for FINAL + } + + + /* Workaround Errata 26304 (T88@2.0) + + When the CSRs LMCX_DLL_CTL3[WR_DESKEW_ENA] = 1 AND + LMCX_PHY_CTL2[DQS[0..8]_DSK_ADJ] > 4, set + LMCX_EXT_CONFIG[DRIVE_ENA_BPRCH] = 1. + */ + if (CAVIUM_IS_MODEL(CAVIUM_CN88XX_PASS2_X)) { // only for 88XX pass 2, not 81xx or 83xx + bdk_lmcx_dll_ctl3_t dll_ctl3; + bdk_lmcx_phy_ctl2_t phy_ctl2; + bdk_lmcx_ext_config_t ext_config; + int increased_dsk_adj = 0; + int byte; + + phy_ctl2.u = BDK_CSR_READ(node, BDK_LMCX_PHY_CTL2(ddr_interface_num)); + ext_config.u = BDK_CSR_READ(node, BDK_LMCX_EXT_CONFIG(ddr_interface_num)); + dll_ctl3.u = BDK_CSR_READ(node, BDK_LMCX_DLL_CTL3(ddr_interface_num)); + + for (byte = 0; byte < 8; ++byte) { + if (!(ddr_interface_bytemask&(1<<byte))) + continue; + increased_dsk_adj |= (((phy_ctl2.u >> (byte*3)) & 0x7) > 4); + } + + if ((dll_ctl3.s.wr_deskew_ena == 1) && increased_dsk_adj) { + ext_config.s.drive_ena_bprch = 1; + DRAM_CSR_WRITE(node, BDK_LMCX_EXT_CONFIG(ddr_interface_num), + ext_config.u); + } + } + + /* + * 6.9.13 DRAM Vref Training for DDR4 + * + * This includes software write-leveling + */ + + { // Software Write-Leveling block + + /* Try to determine/optimize write-level delays experimentally. */ +#pragma pack(push,1) + bdk_lmcx_wlevel_rankx_t lmc_wlevel_rank; + bdk_lmcx_wlevel_rankx_t lmc_wlevel_rank_hw_results; + int byte; + int delay; + int rankx = 0; + int active_rank; +#if !DISABLE_SW_WL_PASS_2 + bdk_lmcx_rlevel_rankx_t lmc_rlevel_rank; + int sw_wlevel_offset = 1; +#endif + int sw_wlevel_enable = 1; /* FIX... Should be customizable. */ + int interfaces; + int measured_vref_flag; + typedef enum { + WL_ESTIMATED = 0, /* HW/SW wleveling failed. Results + estimated. */ + WL_HARDWARE = 1, /* H/W wleveling succeeded */ + WL_SOFTWARE = 2, /* S/W wleveling passed 2 contiguous + settings. */ + WL_SOFTWARE1 = 3, /* S/W wleveling passed 1 marginal + setting. */ + } sw_wl_status_t; + + static const char *wl_status_strings[] = { + "(e)", + " ", + " ", + "(1)" + }; + int sw_wlevel_hw_default = 1; // FIXME: make H/W assist the default now +#pragma pack(pop) + + if ((s = lookup_env_parameter("ddr_sw_wlevel_hw")) != NULL) { + sw_wlevel_hw_default = !!strtoul(s, NULL, 0); + } + + // cannot use hw-assist when doing 32-bit + if (! ddr_interface_64b) { + sw_wlevel_hw_default = 0; + } + + if ((s = lookup_env_parameter("ddr_software_wlevel")) != NULL) { + sw_wlevel_enable = strtoul(s, NULL, 0); + } + +#if SWL_WITH_HW_ALTS_CHOOSE_SW + // Choose the SW algo for SWL if any HWL alternates were found + // NOTE: we have to do this here, and for all, since HW-assist including ECC requires ECC enable + for (rankx = 0; rankx < dimm_count * 4; rankx++) { + if (!sw_wlevel_enable) + break; + if (!(rank_mask & (1 << rankx))) + continue; + + // if we are doing HW-assist, and there are alternates, switch to SW-algorithm for all + if (sw_wlevel_hw && hwl_alts[rankx].hwl_alt_mask) { + ddr_print("N%d.LMC%d.R%d: Using SW algorithm for write-leveling this rank\n", + node, ddr_interface_num, rankx); + sw_wlevel_hw_default = 0; + break; + } + } /* for (rankx = 0; rankx < dimm_count * 4; rankx++) */ +#endif + + /* Get the measured_vref setting from the config, check for an override... */ + /* NOTE: measured_vref=1 (ON) means force use of MEASURED Vref... */ + // NOTE: measured VREF can only be done for DDR4 + if (ddr_type == DDR4_DRAM) { + measured_vref_flag = custom_lmc_config->measured_vref; + if ((s = lookup_env_parameter("ddr_measured_vref")) != NULL) { + measured_vref_flag = !!strtoul(s, NULL, 0); + } + } else { + measured_vref_flag = 0; // OFF for DDR3 + } + + /* Ensure disabled ECC for DRAM tests using the SW algo, else leave it untouched */ + if (!sw_wlevel_hw_default) { + lmc_config.u = BDK_CSR_READ(node, BDK_LMCX_CONFIG(ddr_interface_num)); + lmc_config.s.ecc_ena = 0; + DRAM_CSR_WRITE(node, BDK_LMCX_CONFIG(ddr_interface_num), lmc_config.u); + } + +#if USE_L2_WAYS_LIMIT + limit_l2_ways(node, 0, 0); /* Disable l2 sets for DRAM testing */ +#endif + + /* We need to track absolute rank number, as well as how many + ** active ranks we have. Two single rank DIMMs show up as + ** ranks 0 and 2, but only 2 ranks are active. */ + active_rank = 0; + + interfaces = __builtin_popcount(ddr_interface_mask); + +#define VREF_RANGE1_LIMIT 0x33 // range1 is valid for 0x00 - 0x32 +#define VREF_RANGE2_LIMIT 0x18 // range2 is valid for 0x00 - 0x17 +// full window is valid for 0x00 to 0x4A +// let 0x00 - 0x17 be range2, 0x18 - 0x4a be range 1 +#define VREF_LIMIT (VREF_RANGE1_LIMIT + VREF_RANGE2_LIMIT) +#define VREF_FINAL (VREF_LIMIT - 1) + + for (rankx = 0; rankx < dimm_count * 4; rankx++) { + uint64_t rank_addr; + int vref_value, final_vref_value, final_vref_range = 0; + int start_vref_value = 0, computed_final_vref_value = -1; + char best_vref_values_count, vref_values_count; + char best_vref_values_start, vref_values_start; + + int bytes_failed; + sw_wl_status_t byte_test_status[9]; + sw_wl_status_t sw_wl_rank_status = WL_HARDWARE; + int sw_wl_failed = 0; + int sw_wlevel_hw = sw_wlevel_hw_default; + + if (!sw_wlevel_enable) + break; + + if (!(rank_mask & (1 << rankx))) + continue; + + ddr_print("N%d.LMC%d.R%d: Performing Software Write-Leveling %s\n", + node, ddr_interface_num, rankx, + (sw_wlevel_hw) ? "with H/W assist" : "with S/W algorithm"); + + if ((ddr_type == DDR4_DRAM) && (num_ranks != 4)) { + // always compute when we can... + computed_final_vref_value = compute_vref_value(node, ddr_interface_num, rankx, + dimm_count, num_ranks, imp_values, + is_stacked_die); + if (!measured_vref_flag) // but only use it if allowed + start_vref_value = VREF_FINAL; // skip all the measured Vref processing, just the final setting + } + + /* Save off the h/w wl results */ + lmc_wlevel_rank_hw_results.u = BDK_CSR_READ(node, BDK_LMCX_WLEVEL_RANKX(ddr_interface_num, rankx)); + + vref_values_count = 0; + vref_values_start = 0; + best_vref_values_count = 0; + best_vref_values_start = 0; + + /* Loop one extra time using the Final Vref value. */ + for (vref_value = start_vref_value; vref_value < VREF_LIMIT; ++vref_value) { + if (ddr_type == DDR4_DRAM) { + if (vref_value < VREF_FINAL) { + int vrange, vvalue; + if (vref_value < VREF_RANGE2_LIMIT) { + vrange = 1; vvalue = vref_value; + } else { + vrange = 0; vvalue = vref_value - VREF_RANGE2_LIMIT; + } + set_vref(node, ddr_interface_num, rankx, + vrange, vvalue); + } else { /* if (vref_value < VREF_FINAL) */ + /* Print the final Vref value first. */ + + /* Always print the computed first if its valid */ + if (computed_final_vref_value >= 0) { + ddr_print("N%d.LMC%d.R%d: Vref Computed Summary :" + " %2d (0x%02x)\n", + node, ddr_interface_num, + rankx, computed_final_vref_value, + computed_final_vref_value); + } + if (!measured_vref_flag) { // setup to use the computed + best_vref_values_count = 1; + final_vref_value = computed_final_vref_value; + } else { // setup to use the measured + if (best_vref_values_count > 0) { + best_vref_values_count = max(best_vref_values_count, 2); +#if 0 + // NOTE: this already adjusts VREF via calculating 40% rather than 50% + final_vref_value = best_vref_values_start + divide_roundup((best_vref_values_count-1)*4,10); + ddr_print("N%d.LMC%d.R%d: Vref Training Summary :" + " %2d <----- %2d (0x%02x) -----> %2d range: %2d\n", + node, ddr_interface_num, rankx, best_vref_values_start, + final_vref_value, final_vref_value, + best_vref_values_start+best_vref_values_count-1, + best_vref_values_count-1); +#else + final_vref_value = best_vref_values_start + divide_nint(best_vref_values_count - 1, 2); + if (final_vref_value < VREF_RANGE2_LIMIT) { + final_vref_range = 1; + } else { + final_vref_range = 0; final_vref_value -= VREF_RANGE2_LIMIT; + } + { + int vvlo = best_vref_values_start; + int vrlo; + if (vvlo < VREF_RANGE2_LIMIT) { + vrlo = 2; + } else { + vrlo = 1; vvlo -= VREF_RANGE2_LIMIT; + } + + int vvhi = best_vref_values_start + best_vref_values_count - 1; + int vrhi; + if (vvhi < VREF_RANGE2_LIMIT) { + vrhi = 2; + } else { + vrhi = 1; vvhi -= VREF_RANGE2_LIMIT; + } + ddr_print("N%d.LMC%d.R%d: Vref Training Summary :" + " 0x%02x/%1d <----- 0x%02x/%1d -----> 0x%02x/%1d, range: %2d\n", + node, ddr_interface_num, rankx, + vvlo, vrlo, + final_vref_value, final_vref_range + 1, + vvhi, vrhi, + best_vref_values_count-1); + } +#endif + + } else { + /* If nothing passed use the default Vref value for this rank */ + bdk_lmcx_modereg_params2_t lmc_modereg_params2; + lmc_modereg_params2.u = BDK_CSR_READ(node, BDK_LMCX_MODEREG_PARAMS2(ddr_interface_num)); + final_vref_value = (lmc_modereg_params2.u >> (rankx * 10 + 3)) & 0x3f; + final_vref_range = (lmc_modereg_params2.u >> (rankx * 10 + 9)) & 0x01; + + ddr_print("N%d.LMC%d.R%d: Vref Using Default :" + " %2d <----- %2d (0x%02x) -----> %2d, range%1d\n", + node, ddr_interface_num, rankx, + final_vref_value, final_vref_value, + final_vref_value, final_vref_value, final_vref_range+1); + } + } + + // allow override + if ((s = lookup_env_parameter("ddr%d_vref_value_%1d%1d", + ddr_interface_num, !!(rankx&2), !!(rankx&1))) != NULL) { + final_vref_value = strtoul(s, NULL, 0); + } + + set_vref(node, ddr_interface_num, rankx, final_vref_range, final_vref_value); + + } /* if (vref_value < VREF_FINAL) */ + } /* if (ddr_type == DDR4_DRAM) */ + + lmc_wlevel_rank.u = lmc_wlevel_rank_hw_results.u; /* Restore the saved value */ + + for (byte = 0; byte < 9; ++byte) + byte_test_status[byte] = WL_ESTIMATED; + + if (wlevel_bitmask_errors == 0) { + + /* Determine address of DRAM to test for pass 1 of software write leveling. */ + rank_addr = active_rank * (1ull << (pbank_lsb - bunk_enable + (interfaces/2))); + // FIXME: these now put in by test_dram_byte() + //rank_addr |= (ddr_interface_num<<7); /* Map address into proper interface */ + //rank_addr = bdk_numa_get_address(node, rank_addr); + VB_PRT(VBL_DEV, "N%d.LMC%d.R%d: Active Rank %d Address: 0x%lx\n", + node, ddr_interface_num, rankx, active_rank, rank_addr); + + { // start parallel write-leveling block for delay high-order bits + int errors = 0; + int byte_delay[9]; + uint64_t bytemask; + int bytes_todo; + + if (ddr_interface_64b) { + bytes_todo = (sw_wlevel_hw) ? ddr_interface_bytemask : 0xFF; + bytemask = ~0ULL; + } else { // 32-bit, must be using SW algo, only data bytes + bytes_todo = 0x0f; + bytemask = 0x00000000ffffffffULL; + } + + for (byte = 0; byte < 9; ++byte) { + if (!(bytes_todo & (1 << byte))) { + byte_delay[byte] = 0; + } else { + byte_delay[byte] = get_wlevel_rank_struct(&lmc_wlevel_rank, byte); + } + } /* for (byte = 0; byte < 9; ++byte) */ + +#define WL_MIN_NO_ERRORS_COUNT 3 // FIXME? three passes without errors + int no_errors_count = 0; + + // Change verbosity if using measured vs computed VREF or DDR3 + // measured goes many times through SWL, computed and DDR3 only once + // so we want the EXHAUSTED messages at NORM for computed and DDR3, + // and at DEV2 for measured, just for completeness + int vbl_local = (measured_vref_flag) ? VBL_DEV2 : VBL_NORM; + uint64_t bad_bits[2]; +#if ENABLE_SW_WLEVEL_UTILIZATION + uint64_t sum_dram_dclk = 0, sum_dram_ops = 0; + uint64_t start_dram_dclk, stop_dram_dclk; + uint64_t start_dram_ops, stop_dram_ops; +#endif + do { + // write the current set of WL delays + DRAM_CSR_WRITE(node, BDK_LMCX_WLEVEL_RANKX(ddr_interface_num, rankx), lmc_wlevel_rank.u); + lmc_wlevel_rank.u = BDK_CSR_READ(node, BDK_LMCX_WLEVEL_RANKX(ddr_interface_num, rankx)); + + bdk_watchdog_poke(); + + // do the test + if (sw_wlevel_hw) { + errors = run_best_hw_patterns(node, ddr_interface_num, rank_addr, + DBTRAIN_TEST, bad_bits); + errors &= bytes_todo; // keep only the ones we are still doing + } else { +#if ENABLE_SW_WLEVEL_UTILIZATION + start_dram_dclk = BDK_CSR_READ(node, BDK_LMCX_DCLK_CNT(ddr_interface_num)); + start_dram_ops = BDK_CSR_READ(node, BDK_LMCX_OPS_CNT(ddr_interface_num)); +#endif +#if USE_ORIG_TEST_DRAM_BYTE + errors = test_dram_byte(node, ddr_interface_num, rank_addr, bytemask, bad_bits); +#else + errors = dram_tuning_mem_xor(node, ddr_interface_num, rank_addr, bytemask, bad_bits); +#endif +#if ENABLE_SW_WLEVEL_UTILIZATION + stop_dram_dclk = BDK_CSR_READ(node, BDK_LMCX_DCLK_CNT(ddr_interface_num)); + stop_dram_ops = BDK_CSR_READ(node, BDK_LMCX_OPS_CNT(ddr_interface_num)); + sum_dram_dclk += stop_dram_dclk - start_dram_dclk; + sum_dram_ops += stop_dram_ops - start_dram_ops; +#endif + } + + VB_PRT(VBL_DEV2, "N%d.LMC%d.R%d: S/W write-leveling TEST: returned 0x%x\n", + node, ddr_interface_num, rankx, errors); + + // remember, errors will not be returned for byte-lanes that have maxxed out... + if (errors == 0) { + no_errors_count++; // bump + if (no_errors_count > 1) // bypass check/update completely + continue; // to end of do-while + } else + no_errors_count = 0; // reset + + // check errors by byte + for (byte = 0; byte < 9; ++byte) { + if (!(bytes_todo & (1 << byte))) + continue; + + delay = byte_delay[byte]; + if (errors & (1 << byte)) { // yes, an error in this byte lane + debug_print(" byte %d delay %2d Errors\n", byte, delay); + // since this byte had an error, we move to the next delay value, unless maxxed out + delay += 8; // incr by 8 to do only delay high-order bits + if (delay < 32) { + update_wlevel_rank_struct(&lmc_wlevel_rank, byte, delay); + debug_print(" byte %d delay %2d New\n", byte, delay); + byte_delay[byte] = delay; + } else { // reached max delay, maybe really done with this byte +#if SWL_TRY_HWL_ALT + if (!measured_vref_flag && // consider an alt only for computed VREF and + (hwl_alts[rankx].hwl_alt_mask & (1 << byte))) // if an alt exists... + { + int bad_delay = delay & 0x6; // just orig low-3 bits + delay = hwl_alts[rankx].hwl_alt_delay[byte]; // yes, use it + hwl_alts[rankx].hwl_alt_mask &= ~(1 << byte); // clear that flag + update_wlevel_rank_struct(&lmc_wlevel_rank, byte, delay); + byte_delay[byte] = delay; + debug_print(" byte %d delay %2d ALTERNATE\n", byte, delay); + VB_PRT(VBL_DEV, "N%d.LMC%d.R%d: SWL: Byte %d: %d FAIL, trying ALTERNATE %d\n", + node, ddr_interface_num, rankx, byte, bad_delay, delay); + + } else +#endif /* SWL_TRY_HWL_ALT */ + { + unsigned bits_bad; + if (byte < 8) { + bytemask &= ~(0xffULL << (8*byte)); // test no longer, remove from byte mask + bits_bad = (unsigned)((bad_bits[0] >> (8 * byte)) & 0xffUL); + } else { + bits_bad = (unsigned)(bad_bits[1] & 0xffUL); + } + bytes_todo &= ~(1 << byte); // remove from bytes to do + byte_test_status[byte] = WL_ESTIMATED; // make sure this is set for this case + debug_print(" byte %d delay %2d Exhausted\n", byte, delay); + VB_PRT(vbl_local, "N%d.LMC%d.R%d: SWL: Byte %d (0x%02x): delay %d EXHAUSTED \n", + node, ddr_interface_num, rankx, byte, bits_bad, delay); + } + } + } else { // no error, stay with current delay, but keep testing it... + debug_print(" byte %d delay %2d Passed\n", byte, delay); + byte_test_status[byte] = WL_HARDWARE; // change status + } + + } /* for (byte = 0; byte < 9; ++byte) */ + + } while (no_errors_count < WL_MIN_NO_ERRORS_COUNT); + +#if ENABLE_SW_WLEVEL_UTILIZATION + if (! sw_wlevel_hw) { + uint64_t percent_x10; + if (sum_dram_dclk == 0) + sum_dram_dclk = 1; + percent_x10 = sum_dram_ops * 1000 / sum_dram_dclk; + ddr_print("N%d.LMC%d.R%d: ops %lu, cycles %lu, used %lu.%lu%%\n", + node, ddr_interface_num, rankx, sum_dram_ops, sum_dram_dclk, + percent_x10 / 10, percent_x10 % 10); + } +#endif + if (errors) { + debug_print("End WLEV_64 while loop: vref_value %d(0x%x), errors 0x%02x\n", + vref_value, vref_value, errors); + } + } // end parallel write-leveling block for delay high-order bits + + if (sw_wlevel_hw) { // if we used HW-assist, we did the ECC byte when approp. + VB_PRT(VBL_DEV, "N%d.LMC%d.R%d: HW-assist SWL - no ECC estimate!!!\n", + node, ddr_interface_num, rankx); + goto no_ecc_estimate; + } + + if ((ddr_interface_bytemask & 0xff) == 0xff) { + if (use_ecc) { + int save_byte8 = lmc_wlevel_rank.s.byte8; // save original HW delay + byte_test_status[8] = WL_HARDWARE; /* say it is H/W delay value */ + + if ((save_byte8 != lmc_wlevel_rank.s.byte3) && + (save_byte8 != lmc_wlevel_rank.s.byte4)) + { + // try to calculate a workable delay using SW bytes 3 and 4 and HW byte 8 + int test_byte8 = save_byte8; + int test_byte8_error; + int byte8_error = 0x1f; + int adder; + int avg_bytes = divide_nint(lmc_wlevel_rank.s.byte3+lmc_wlevel_rank.s.byte4, 2); + for (adder = 0; adder<= 32; adder+=8) { + test_byte8_error = _abs((adder+save_byte8) - avg_bytes); + if (test_byte8_error < byte8_error) { + byte8_error = test_byte8_error; + test_byte8 = save_byte8 + adder; + } + } + +#if SW_WL_CHECK_PATCH + // only do the check if we are not using measured VREF + if (!measured_vref_flag) { + test_byte8 &= ~1; /* Use only even settings, rounding down... */ + + // do validity check on the calculated ECC delay value + // this depends on the DIMM type + if (spd_rdimm) { // RDIMM + if (spd_dimm_type != 5) { // but not mini-RDIMM + // it can be > byte4, but should never be > byte3 + if (test_byte8 > lmc_wlevel_rank.s.byte3) { + byte_test_status[8] = WL_ESTIMATED; /* say it is still estimated */ + } + } + } else { // UDIMM + if ((test_byte8 < lmc_wlevel_rank.s.byte3) || + (test_byte8 > lmc_wlevel_rank.s.byte4)) + { // should never be outside the byte 3-4 range + byte_test_status[8] = WL_ESTIMATED; /* say it is still estimated */ + } + } + /* + * Report whenever the calculation appears bad. + * This happens if some of the original values were off, or unexpected geometry + * from DIMM type, or custom circuitry (NIC225E, I am looking at you!). + * We will trust the calculated value, and depend on later testing to catch + * any instances when that value is truly bad. + */ + if (byte_test_status[8] == WL_ESTIMATED) { // ESTIMATED means there may be an issue + ddr_print("N%d.LMC%d.R%d: SWL: (%cDIMM): calculated ECC delay unexpected (%d/%d/%d)\n", + node, ddr_interface_num, rankx, (spd_rdimm?'R':'U'), + lmc_wlevel_rank.s.byte4, test_byte8, lmc_wlevel_rank.s.byte3); + byte_test_status[8] = WL_HARDWARE; + } + } +#endif /* SW_WL_CHECK_PATCH */ + lmc_wlevel_rank.s.byte8 = test_byte8 & ~1; /* Use only even settings */ + } + + if (lmc_wlevel_rank.s.byte8 != save_byte8) { + /* Change the status if s/w adjusted the delay */ + byte_test_status[8] = WL_SOFTWARE; /* Estimated delay */ + } + } else { + byte_test_status[8] = WL_HARDWARE; /* H/W delay value */ + lmc_wlevel_rank.s.byte8 = lmc_wlevel_rank.s.byte0; /* ECC is not used */ + } + } else { /* if ((ddr_interface_bytemask & 0xff) == 0xff) */ + if (use_ecc) { + /* Estimate the ECC byte delay */ + lmc_wlevel_rank.s.byte4 |= (lmc_wlevel_rank.s.byte3 & 0x38); // add hi-order to b4 + if ((lmc_wlevel_rank.s.byte4 & 0x06) < (lmc_wlevel_rank.s.byte3 & 0x06)) // orig b4 < orig b3 + lmc_wlevel_rank.s.byte4 += 8; // must be next clock + } else { + lmc_wlevel_rank.s.byte4 = lmc_wlevel_rank.s.byte0; /* ECC is not used */ + } + /* Change the status if s/w adjusted the delay */ + byte_test_status[4] = WL_SOFTWARE; /* Estimated delay */ + } /* if ((ddr_interface_bytemask & 0xff) == 0xff) */ + } /* if (wlevel_bitmask_errors == 0) */ + + no_ecc_estimate: + + bytes_failed = 0; + for (byte = 0; byte < 9; ++byte) { + /* Don't accumulate errors for untested bytes. */ + if (!(ddr_interface_bytemask & (1 << byte))) + continue; + bytes_failed += (byte_test_status[byte] == WL_ESTIMATED); + } + + /* Vref training loop is only used for DDR4 */ + if (ddr_type != DDR4_DRAM) + break; + + if (bytes_failed == 0) { + if (vref_values_count == 0) { + vref_values_start = vref_value; + } + ++vref_values_count; + if (vref_values_count > best_vref_values_count) { + best_vref_values_count = vref_values_count; + best_vref_values_start = vref_values_start; + debug_print("N%d.LMC%d.R%d: Vref Training (%2d) : 0x%02x <----- ???? -----> 0x%02x\n", + node, ddr_interface_num, + rankx, vref_value, best_vref_values_start, + best_vref_values_start+best_vref_values_count-1); + } + } else { + vref_values_count = 0; + debug_print("N%d.LMC%d.R%d: Vref Training (%2d) : failed\n", + node, ddr_interface_num, + rankx, vref_value); + } + } /* for (vref_value=0; vref_value<VREF_LIMIT; ++vref_value) */ + + /* Determine address of DRAM to test for pass 2 and final test of software write leveling. */ + rank_addr = active_rank * (1ull << (pbank_lsb - bunk_enable + (interfaces/2))); + rank_addr |= (ddr_interface_num<<7); /* Map address into proper interface */ + rank_addr = bdk_numa_get_address(node, rank_addr); + debug_print("N%d.LMC%d.R%d: Active Rank %d Address: 0x%lx\n", + node, ddr_interface_num, rankx, active_rank, rank_addr); + + int errors; + + if (bytes_failed) { + +#if !DISABLE_SW_WL_PASS_2 + + ddr_print("N%d.LMC%d.R%d: Starting SW Write-leveling pass 2\n", + node, ddr_interface_num, rankx); + sw_wl_rank_status = WL_SOFTWARE; + + /* If previous s/w fixups failed then retry using s/w write-leveling. */ + if (wlevel_bitmask_errors == 0) { + /* h/w succeeded but previous s/w fixups failed. So retry s/w. */ + debug_print("N%d.LMC%d.R%d: Retrying software Write-Leveling.\n", + node, ddr_interface_num, rankx); + } + + { // start parallel write-leveling block for delay low-order bits + int byte_delay[8]; + int byte_passed[8]; + uint64_t bytemask; + uint64_t bitmask; + int wl_offset; + int bytes_todo; + + for (byte = 0; byte < 8; ++byte) { + byte_passed[byte] = 0; + } + + bytes_todo = ddr_interface_bytemask; + + for (wl_offset = sw_wlevel_offset; wl_offset >= 0; --wl_offset) { + debug_print("Starting wl_offset for-loop: %d\n", wl_offset); + + bytemask = 0; + + for (byte = 0; byte < 8; ++byte) { + byte_delay[byte] = 0; + if (!(bytes_todo & (1 << byte))) // this does not contain fully passed bytes + continue; + + byte_passed[byte] = 0; // reset across passes if not fully passed + update_wlevel_rank_struct(&lmc_wlevel_rank, byte, 0); // all delays start at 0 + bitmask = ((!ddr_interface_64b) && (byte == 4)) ? 0x0f: 0xff; + bytemask |= bitmask << (8*byte); // set the bytes bits in the bytemask + } /* for (byte = 0; byte < 8; ++byte) */ + + while (bytemask != 0) { // start a pass if there is any byte lane to test + + debug_print("Starting bytemask while-loop: 0x%lx\n", bytemask); + + // write this set of WL delays + DRAM_CSR_WRITE(node, BDK_LMCX_WLEVEL_RANKX(ddr_interface_num, rankx), lmc_wlevel_rank.u); + lmc_wlevel_rank.u = BDK_CSR_READ(node, BDK_LMCX_WLEVEL_RANKX(ddr_interface_num, rankx)); + + bdk_watchdog_poke(); + + // do the test + if (sw_wlevel_hw) + errors = run_best_hw_patterns(node, ddr_interface_num, rank_addr, + DBTRAIN_TEST, NULL); + else + errors = test_dram_byte(node, ddr_interface_num, rank_addr, bytemask, NULL); + + debug_print("SWL pass 2: test_dram_byte returned 0x%x\n", errors); + + // check errors by byte + for (byte = 0; byte < 8; ++byte) { + if (!(bytes_todo & (1 << byte))) + continue; + + delay = byte_delay[byte]; + if (errors & (1 << byte)) { // yes, an error + debug_print(" byte %d delay %2d Errors\n", byte, delay); + byte_passed[byte] = 0; + } else { // no error + byte_passed[byte] += 1; + if (byte_passed[byte] == (1 + wl_offset)) { /* Look for consecutive working settings */ + debug_print(" byte %d delay %2d FULLY Passed\n", byte, delay); + if (wl_offset == 1) { + byte_test_status[byte] = WL_SOFTWARE; + } else if (wl_offset == 0) { + byte_test_status[byte] = WL_SOFTWARE1; + } + bytemask &= ~(0xffULL << (8*byte)); // test no longer, remove from byte mask this pass + bytes_todo &= ~(1 << byte); // remove completely from concern + continue; // on to the next byte, bypass delay updating!! + } else { + debug_print(" byte %d delay %2d Passed\n", byte, delay); + } + } + // error or no, here we move to the next delay value for this byte, unless done all delays + // only a byte that has "fully passed" will bypass around this, + delay += 2; + if (delay < 32) { + update_wlevel_rank_struct(&lmc_wlevel_rank, byte, delay); + debug_print(" byte %d delay %2d New\n", byte, delay); + byte_delay[byte] = delay; + } else { + // reached max delay, done with this byte + debug_print(" byte %d delay %2d Exhausted\n", byte, delay); + bytemask &= ~(0xffULL << (8*byte)); // test no longer, remove from byte mask this pass + } + } /* for (byte = 0; byte < 8; ++byte) */ + debug_print("End of for-loop: bytemask 0x%lx\n", bytemask); + + } /* while (bytemask != 0) */ + } /* for (wl_offset = sw_wlevel_offset; wl_offset >= 0; --wl_offset) */ + + for (byte = 0; byte < 8; ++byte) { + // any bytes left in bytes_todo did not pass + if (bytes_todo & (1 << byte)) { + /* Last resort. Use Rlevel settings to estimate + Wlevel if software write-leveling fails */ + debug_print("Using RLEVEL as WLEVEL estimate for byte %d\n", byte); + lmc_rlevel_rank.u = BDK_CSR_READ(node, BDK_LMCX_RLEVEL_RANKX(ddr_interface_num, rankx)); + rlevel_to_wlevel(&lmc_rlevel_rank, &lmc_wlevel_rank, byte); + } + } /* for (byte = 0; byte < 8; ++byte) */ + + sw_wl_failed = (bytes_todo != 0); + + } // end parallel write-leveling block for delay low-order bits + + if (use_ecc) { + /* ECC byte has to be estimated. Take the average of the two surrounding bytes. */ + int test_byte8 = divide_nint(lmc_wlevel_rank.s.byte3 + + lmc_wlevel_rank.s.byte4 + + 2 /* round-up*/ , 2); + lmc_wlevel_rank.s.byte8 = test_byte8 & ~1; /* Use only even settings */ + byte_test_status[8] = WL_ESTIMATED; /* Estimated delay */ + } else { + byte_test_status[8] = WL_HARDWARE; /* H/W delay value */ + lmc_wlevel_rank.s.byte8 = lmc_wlevel_rank.s.byte0; /* ECC is not used */ + } + + /* Set delays for unused bytes to match byte 0. */ + for (byte=0; byte<8; ++byte) { + if ((ddr_interface_bytemask & (1 << byte))) + continue; + update_wlevel_rank_struct(&lmc_wlevel_rank, byte, + lmc_wlevel_rank.s.byte0); + byte_test_status[byte] = WL_SOFTWARE; + } +#else /* !DISABLE_SW_WL_PASS_2 */ + // FIXME? the big hammer, did not even try SW WL pass2, assume only chip reset will help + ddr_print("N%d.LMC%d.R%d: S/W write-leveling pass 1 failed\n", + node, ddr_interface_num, rankx); + sw_wl_failed = 1; +#endif /* !DISABLE_SW_WL_PASS_2 */ + + } else { /* if (bytes_failed) */ + + // SW WL pass 1 was OK, write the settings + DRAM_CSR_WRITE(node, BDK_LMCX_WLEVEL_RANKX(ddr_interface_num, rankx), lmc_wlevel_rank.u); + lmc_wlevel_rank.u = BDK_CSR_READ(node, BDK_LMCX_WLEVEL_RANKX(ddr_interface_num, rankx)); + +#if SW_WL_CHECK_PATCH + // do validity check on the delay values by running the test 1 more time... + // FIXME: we really need to check the ECC byte setting here as well, + // so we need to enable ECC for this test!!! + // if there are any errors, claim SW WL failure + { + uint64_t datamask = (ddr_interface_64b) ? 0xffffffffffffffffULL : 0x00000000ffffffffULL; + + // do the test + if (sw_wlevel_hw) { + errors = run_best_hw_patterns(node, ddr_interface_num, rank_addr, + DBTRAIN_TEST, NULL) & 0x0ff; + } else { +#if USE_ORIG_TEST_DRAM_BYTE + errors = test_dram_byte(node, ddr_interface_num, rank_addr, datamask, NULL); +#else + errors = dram_tuning_mem_xor(node, ddr_interface_num, rank_addr, datamask, NULL); +#endif + } + + if (errors) { + ddr_print("N%d.LMC%d.R%d: Wlevel Rank Final Test errors 0x%x\n", + node, ddr_interface_num, rankx, errors); + sw_wl_failed = 1; + } + } +#endif /* SW_WL_CHECK_PATCH */ + + } /* if (bytes_failed) */ + + // FIXME? dump the WL settings, so we get more of a clue as to what happened where + ddr_print("N%d.LMC%d.R%d: Wlevel Rank %#4x, 0x%016lX : %2d%3s %2d%3s %2d%3s %2d%3s %2d%3s %2d%3s %2d%3s %2d%3s %2d%3s %s\n", + node, ddr_interface_num, rankx, + lmc_wlevel_rank.s.status, + lmc_wlevel_rank.u, + lmc_wlevel_rank.s.byte8, wl_status_strings[byte_test_status[8]], + lmc_wlevel_rank.s.byte7, wl_status_strings[byte_test_status[7]], + lmc_wlevel_rank.s.byte6, wl_status_strings[byte_test_status[6]], + lmc_wlevel_rank.s.byte5, wl_status_strings[byte_test_status[5]], + lmc_wlevel_rank.s.byte4, wl_status_strings[byte_test_status[4]], + lmc_wlevel_rank.s.byte3, wl_status_strings[byte_test_status[3]], + lmc_wlevel_rank.s.byte2, wl_status_strings[byte_test_status[2]], + lmc_wlevel_rank.s.byte1, wl_status_strings[byte_test_status[1]], + lmc_wlevel_rank.s.byte0, wl_status_strings[byte_test_status[0]], + (sw_wl_rank_status == WL_HARDWARE) ? "" : "(s)" + ); + + // finally, check for fatal conditions: either chip reset right here, or return error flag + if (((ddr_type == DDR4_DRAM) && (best_vref_values_count == 0)) || sw_wl_failed) { + if (!ddr_disable_chip_reset) { // do chip RESET + error_print("INFO: Short memory test indicates a retry is needed on N%d.LMC%d.R%d. Resetting node...\n", + node, ddr_interface_num, rankx); + bdk_wait_usec(500000); + bdk_reset_chip(node); + } else { // return error flag so LMC init can be retried... + ddr_print("INFO: Short memory test indicates a retry is needed on N%d.LMC%d.R%d. Restarting LMC init...\n", + node, ddr_interface_num, rankx); + return 0; // 0 indicates restart possible... + } + } + + active_rank++; + } /* for (rankx = 0; rankx < dimm_count * 4; rankx++) */ + + // Finalize the write-leveling settings + for (rankx = 0; rankx < dimm_count * 4;rankx++) { + uint64_t value; + int parameter_set = 0; + if (!(rank_mask & (1 << rankx))) + continue; + + lmc_wlevel_rank.u = BDK_CSR_READ(node, BDK_LMCX_WLEVEL_RANKX(ddr_interface_num, rankx)); + + if (bdk_is_platform(BDK_PLATFORM_ASIM)) { + parameter_set |= 1; + + lmc_wlevel_rank.s.byte8 = 0; + lmc_wlevel_rank.s.byte7 = 0; + lmc_wlevel_rank.s.byte6 = 0; + lmc_wlevel_rank.s.byte5 = 0; + lmc_wlevel_rank.s.byte4 = 0; + lmc_wlevel_rank.s.byte3 = 0; + lmc_wlevel_rank.s.byte2 = 0; + lmc_wlevel_rank.s.byte1 = 0; + lmc_wlevel_rank.s.byte0 = 0; + } + + for (i=0; i<9; ++i) { + if ((s = lookup_env_parameter("ddr%d_wlevel_rank%d_byte%d", ddr_interface_num, rankx, i)) != NULL) { + parameter_set |= 1; + value = strtoul(s, NULL, 0); + + update_wlevel_rank_struct(&lmc_wlevel_rank, i, value); + } + } + + if ((s = lookup_env_parameter_ull("ddr%d_wlevel_rank%d", ddr_interface_num, rankx)) != NULL) { + parameter_set |= 1; + value = strtoull(s, NULL, 0); + lmc_wlevel_rank.u = value; + } + + if (parameter_set) { + DRAM_CSR_WRITE(node, BDK_LMCX_WLEVEL_RANKX(ddr_interface_num, rankx), lmc_wlevel_rank.u); + lmc_wlevel_rank.u = BDK_CSR_READ(node, BDK_LMCX_WLEVEL_RANKX(ddr_interface_num, rankx)); + display_WL(node, ddr_interface_num, lmc_wlevel_rank, rankx); + } +#if WLEXTRAS_PATCH + if ((rank_mask & 0x0F) != 0x0F) { // if there are unused entries to be filled + if (rankx < 3) { + debug_print("N%d.LMC%d.R%d: checking for WLEVEL_RANK unused entries.\n", + node, ddr_interface_num, rankx); + if (rankx == 0) { // if rank 0, write ranks 1 and 2 here if empty + if (!(rank_mask & (1<<1))) { // check that rank 1 is empty + DRAM_CSR_WRITE(node, BDK_LMCX_WLEVEL_RANKX(ddr_interface_num, 1), lmc_wlevel_rank.u); + VB_PRT(VBL_DEV, "N%d.LMC%d.R%d: writing WLEVEL_RANK unused entry R%d.\n", + node, ddr_interface_num, rankx, 1); + } + if (!(rank_mask & (1<<2))) { // check that rank 2 is empty + VB_PRT(VBL_DEV, "N%d.LMC%d.R%d: writing WLEVEL_RANK unused entry R%d.\n", + node, ddr_interface_num, rankx, 2); + DRAM_CSR_WRITE(node, BDK_LMCX_WLEVEL_RANKX(ddr_interface_num, 2), lmc_wlevel_rank.u); + } + } + // if rank 0, 1 or 2, write rank 3 here if empty + if (!(rank_mask & (1<<3))) { // check that rank 3 is empty + VB_PRT(VBL_DEV, "N%d.LMC%d.R%d: writing WLEVEL_RANK unused entry R%d.\n", + node, ddr_interface_num, rankx, 3); + DRAM_CSR_WRITE(node, BDK_LMCX_WLEVEL_RANKX(ddr_interface_num, 3), lmc_wlevel_rank.u); + } + } + } +#endif /* WLEXTRAS_PATCH */ + + } /* for (rankx = 0; rankx < dimm_count * 4;rankx++) */ + + /* Restore the ECC configuration */ + if (!sw_wlevel_hw_default) { + lmc_config.s.ecc_ena = use_ecc; + DRAM_CSR_WRITE(node, BDK_LMCX_CONFIG(ddr_interface_num), lmc_config.u); + } + +#if USE_L2_WAYS_LIMIT + /* Restore the l2 set configuration */ + if ((s = lookup_env_parameter("limit_l2_ways")) != NULL) { + int ways = strtoul(s, NULL, 10); + limit_l2_ways(node, ways, 1); + } else { + limit_l2_ways(node, bdk_l2c_get_num_assoc(node), 0); + } +#endif + + } // End Software Write-Leveling block + +#if ENABLE_DISPLAY_MPR_PAGE + if (ddr_type == DDR4_DRAM) { + Display_MPR_Page(node, rank_mask, ddr_interface_num, dimm_count, 2); + Display_MPR_Page(node, rank_mask, ddr_interface_num, dimm_count, 0); + } +#endif + +#if 1 // was #ifdef CAVIUM_ONLY + { + int i; + int setting[9]; + bdk_lmcx_dll_ctl3_t ddr_dll_ctl3; + ddr_dll_ctl3.u = BDK_CSR_READ(node, BDK_LMCX_DLL_CTL3(ddr_interface_num)); + + for (i=0; i<9; ++i) { + SET_DDR_DLL_CTL3(dll90_byte_sel, ENCODE_DLL90_BYTE_SEL(i)); + DRAM_CSR_WRITE(node, BDK_LMCX_DLL_CTL3(ddr_interface_num), ddr_dll_ctl3.u); + BDK_CSR_READ(node, BDK_LMCX_DLL_CTL3(ddr_interface_num)); + ddr_dll_ctl3.u = BDK_CSR_READ(node, BDK_LMCX_DLL_CTL3(ddr_interface_num)); + setting[i] = GET_DDR_DLL_CTL3(dll90_setting); + debug_print("%d. LMC%d_DLL_CTL3[%d] = %016lx %d\n", i, ddr_interface_num, + GET_DDR_DLL_CTL3(dll90_byte_sel), ddr_dll_ctl3.u, setting[i]); + } + + VB_PRT(VBL_DEV, "N%d.LMC%d: %-36s : %5d %5d %5d %5d %5d %5d %5d %5d %5d\n", + node, ddr_interface_num, "DLL90 Setting 8:0", + setting[8], setting[7], setting[6], setting[5], setting[4], + setting[3], setting[2], setting[1], setting[0]); + + //BDK_CSR_WRITE(node, BDK_LMCX_DLL_CTL3(ddr_interface_num), save_ddr_dll_ctl3.u); + } +#endif /* CAVIUM_ONLY */ + + // any custom DLL read or write offsets, install them + // FIXME: no need to do these if we are going to auto-tune... ??? + + process_custom_dll_offsets(node, ddr_interface_num, "ddr_dll_write_offset", + custom_lmc_config->dll_write_offset, "ddr%d_dll_write_offset_byte%d", 1); + process_custom_dll_offsets(node, ddr_interface_num, "ddr_dll_read_offset", + custom_lmc_config->dll_read_offset, "ddr%d_dll_read_offset_byte%d", 2); + + // we want to train write bit-deskew here... + if (! disable_deskew_training) { + if (enable_write_deskew) { + ddr_print("N%d.LMC%d: WRITE BIT-DESKEW feature training begins.\n", + node, ddr_interface_num); + Perform_Write_Deskew_Training(node, ddr_interface_num); + } /* if (enable_write_deskew) */ + } /* if (! disable_deskew_training) */ + + /* + * 6.9.14 Final LMC Initialization + * + * Early LMC initialization, LMC write-leveling, and LMC read-leveling + * must be completed prior to starting this final LMC initialization. + * + * LMC hardware updates the LMC(0)_SLOT_CTL0, LMC(0)_SLOT_CTL1, + * LMC(0)_SLOT_CTL2 CSRs with minimum values based on the selected + * readleveling and write-leveling settings. Software should not write + * the final LMC(0)_SLOT_CTL0, LMC(0)_SLOT_CTL1, and LMC(0)_SLOT_CTL2 + * values until after the final read-leveling and write-leveling settings + * are written. + * + * Software must ensure the LMC(0)_SLOT_CTL0, LMC(0)_SLOT_CTL1, and + * LMC(0)_SLOT_CTL2 CSR values are appropriate for this step. These CSRs + * select the minimum gaps between read operations and write operations + * of various types. + * + * Software must not reduce the values in these CSR fields below the + * values previously selected by the LMC hardware (during write-leveling + * and read-leveling steps above). + * + * All sections in this chapter may be used to derive proper settings for + * these registers. + * + * For minimal read latency, L2C_CTL[EF_ENA,EF_CNT] should be programmed + * properly. This should be done prior to the first read. + */ + +#if ENABLE_SLOT_CTL_ACCESS + { + bdk_lmcx_slot_ctl0_t lmc_slot_ctl0; + bdk_lmcx_slot_ctl1_t lmc_slot_ctl1; + bdk_lmcx_slot_ctl2_t lmc_slot_ctl2; + bdk_lmcx_slot_ctl3_t lmc_slot_ctl3; + + lmc_slot_ctl0.u = BDK_CSR_READ(node, BDK_LMCX_SLOT_CTL0(ddr_interface_num)); + lmc_slot_ctl1.u = BDK_CSR_READ(node, BDK_LMCX_SLOT_CTL1(ddr_interface_num)); + lmc_slot_ctl2.u = BDK_CSR_READ(node, BDK_LMCX_SLOT_CTL2(ddr_interface_num)); + lmc_slot_ctl3.u = BDK_CSR_READ(node, BDK_LMCX_SLOT_CTL3(ddr_interface_num)); + + ddr_print("%-45s : 0x%016lx\n", "LMC_SLOT_CTL0", lmc_slot_ctl0.u); + ddr_print("%-45s : 0x%016lx\n", "LMC_SLOT_CTL1", lmc_slot_ctl1.u); + ddr_print("%-45s : 0x%016lx\n", "LMC_SLOT_CTL2", lmc_slot_ctl2.u); + ddr_print("%-45s : 0x%016lx\n", "LMC_SLOT_CTL3", lmc_slot_ctl3.u); + + // for now, look only for SLOT_CTL1 envvar for override of contents + if ((s = lookup_env_parameter("ddr%d_slot_ctl1", ddr_interface_num)) != NULL) { + int slot_ctl1_incr = strtoul(s, NULL, 0); + // validate the value + if ((slot_ctl1_incr < 0) || (slot_ctl1_incr > 3)) { // allow 0 for printing only + error_print("ddr%d_slot_ctl1 illegal value (%d); must be 0-3\n", + ddr_interface_num, slot_ctl1_incr); + } else { + +#define INCR(csr, chip, field, incr) \ + csr.chip.field = (csr.chip.field < (64 - incr)) ? (csr.chip.field + incr) : 63 + + // only print original when we are changing it! + if (slot_ctl1_incr) + ddr_print("%-45s : 0x%016lx\n", "LMC_SLOT_CTL1", lmc_slot_ctl1.u); + + // modify all the SLOT_CTL1 fields by the increment, for now... + // but make sure the value will not overflow!!! + INCR(lmc_slot_ctl1, s, r2r_xrank_init, slot_ctl1_incr); + INCR(lmc_slot_ctl1, s, r2w_xrank_init, slot_ctl1_incr); + INCR(lmc_slot_ctl1, s, w2r_xrank_init, slot_ctl1_incr); + INCR(lmc_slot_ctl1, s, w2w_xrank_init, slot_ctl1_incr); + DRAM_CSR_WRITE(node, BDK_LMCX_SLOT_CTL1(ddr_interface_num), lmc_slot_ctl1.u); + lmc_slot_ctl1.u = BDK_CSR_READ(node, BDK_LMCX_SLOT_CTL1(ddr_interface_num)); + + // always print when we are changing it! + printf("%-45s : 0x%016lx\n", "LMC_SLOT_CTL1", lmc_slot_ctl1.u); + } + } + } +#endif /* ENABLE_SLOT_CTL_ACCESS */ + { + /* Clear any residual ECC errors */ + int num_tads = 1; + int tad; + + DRAM_CSR_WRITE(node, BDK_LMCX_INT(ddr_interface_num), -1ULL); + BDK_CSR_READ(node, BDK_LMCX_INT(ddr_interface_num)); + + for (tad=0; tad<num_tads; tad++) + DRAM_CSR_WRITE(node, BDK_L2C_TADX_INT_W1C(tad), BDK_CSR_READ(node, BDK_L2C_TADX_INT_W1C(tad))); + + ddr_print("%-45s : 0x%08lx\n", "LMC_INT", + BDK_CSR_READ(node, BDK_LMCX_INT(ddr_interface_num))); + +#if 0 + // NOTE: this must be done for pass 2.x + // must enable ECC interrupts to get ECC error info in LMCX_INT + if (! CAVIUM_IS_MODEL(CAVIUM_CN88XX_PASS1_X)) { // added 81xx and 83xx + DRAM_CSR_WRITE(node, BDK_LMCX_INT_ENA_W1S(ddr_interface_num), -1ULL); + BDK_CSR_INIT(lmc_int_ena_w1s, node, BDK_LMCX_INT_ENA_W1S(ddr_interface_num)); + ddr_print("%-45s : 0x%08lx\n", "LMC_INT_ENA_W1S", lmc_int_ena_w1s.u); + } +#endif + } + + // Now we can enable scrambling if desired... + { + bdk_lmcx_control_t lmc_control; + bdk_lmcx_scramble_cfg0_t lmc_scramble_cfg0; + bdk_lmcx_scramble_cfg1_t lmc_scramble_cfg1; + bdk_lmcx_scramble_cfg2_t lmc_scramble_cfg2; + bdk_lmcx_ns_ctl_t lmc_ns_ctl; + + lmc_control.u = BDK_CSR_READ(node, BDK_LMCX_CONTROL(ddr_interface_num)); + lmc_scramble_cfg0.u = BDK_CSR_READ(node, BDK_LMCX_SCRAMBLE_CFG0(ddr_interface_num)); + lmc_scramble_cfg1.u = BDK_CSR_READ(node, BDK_LMCX_SCRAMBLE_CFG1(ddr_interface_num)); + lmc_scramble_cfg2.u = BDK_CSR_READ(node, BDK_LMCX_SCRAMBLE_CFG2(ddr_interface_num)); + lmc_ns_ctl.u = BDK_CSR_READ(node, BDK_LMCX_NS_CTL(ddr_interface_num)); + + /* Read the scramble setting from the config and see if we + need scrambling */ + int use_scramble = bdk_config_get_int(BDK_CONFIG_DRAM_SCRAMBLE); + if (use_scramble == 2) + { + if (bdk_trust_get_level() >= BDK_TRUST_LEVEL_SIGNED) + use_scramble = 1; + else + use_scramble = 0; + } + + /* Generate random values if scrambling is needed */ + if (use_scramble) + { + lmc_scramble_cfg0.u = bdk_rng_get_random64(); + lmc_scramble_cfg1.u = bdk_rng_get_random64(); + lmc_scramble_cfg2.u = bdk_rng_get_random64(); + lmc_ns_ctl.s.ns_scramble_dis = 0; + lmc_ns_ctl.s.adr_offset = 0; + lmc_control.s.scramble_ena = 1; + } + + if ((s = lookup_env_parameter_ull("ddr_scramble_cfg0")) != NULL) { + lmc_scramble_cfg0.u = strtoull(s, NULL, 0); + lmc_control.s.scramble_ena = 1; + } + ddr_print("%-45s : 0x%016lx\n", "LMC_SCRAMBLE_CFG0", lmc_scramble_cfg0.u); + + DRAM_CSR_WRITE(node, BDK_LMCX_SCRAMBLE_CFG0(ddr_interface_num), lmc_scramble_cfg0.u); + + if ((s = lookup_env_parameter_ull("ddr_scramble_cfg1")) != NULL) { + lmc_scramble_cfg1.u = strtoull(s, NULL, 0); + lmc_control.s.scramble_ena = 1; + } + ddr_print("%-45s : 0x%016lx\n", "LMC_SCRAMBLE_CFG1", lmc_scramble_cfg1.u); + DRAM_CSR_WRITE(node, BDK_LMCX_SCRAMBLE_CFG1(ddr_interface_num), lmc_scramble_cfg1.u); + + if ((s = lookup_env_parameter_ull("ddr_scramble_cfg2")) != NULL) { + lmc_scramble_cfg2.u = strtoull(s, NULL, 0); + lmc_control.s.scramble_ena = 1; + } + ddr_print("%-45s : 0x%016lx\n", "LMC_SCRAMBLE_CFG2", lmc_scramble_cfg2.u); + DRAM_CSR_WRITE(node, BDK_LMCX_SCRAMBLE_CFG2(ddr_interface_num), lmc_scramble_cfg2.u); + + if ((s = lookup_env_parameter_ull("ddr_ns_ctl")) != NULL) { + lmc_ns_ctl.u = strtoull(s, NULL, 0); + } + ddr_print("%-45s : 0x%016lx\n", "LMC_NS_CTL", lmc_ns_ctl.u); + DRAM_CSR_WRITE(node, BDK_LMCX_NS_CTL(ddr_interface_num), lmc_ns_ctl.u); + + DRAM_CSR_WRITE(node, BDK_LMCX_CONTROL(ddr_interface_num), lmc_control.u); + + } + + return(mem_size_mbytes); +} |