/* SPDX-License-Identifier: GPL-2.0-only */ /* * JEDEC Standard No. 21-C * Annex L: Serial Presence Detect (SPD) for DDR4 SDRAM Modules */ #ifndef DEVICE_DRAM_DDR4L_H #define DEVICE_DRAM_DDR4L_H /** * @file ddr4.h * * \brief Utilities for decoding DDR4 SPDs */ #include #include #include /** Maximum SPD size supported */ #define SPD_SIZE_MAX_DDR4 512 #define SPD_DDR4_PART_OFF 329 #define SPD_DDR4_PART_LEN 20 /* * Module type (byte 3, bits 3:0) of SPD * This definition is specific to DDR4. DDR2/3 SPDs have a different structure. */ enum spd_dimm_type_ddr4 { SPD_DDR4_DIMM_TYPE_EXTENDED = 0x0, SPD_DDR4_DIMM_TYPE_RDIMM = 0x1, SPD_DDR4_DIMM_TYPE_UDIMM = 0x2, SPD_DDR4_DIMM_TYPE_SO_DIMM = 0x3, SPD_DDR4_DIMM_TYPE_LRDIMM = 0x4, SPD_DDR4_DIMM_TYPE_MINI_RDIMM = 0x5, SPD_DDR4_DIMM_TYPE_MINI_UDIMM = 0x6, SPD_DDR4_DIMM_TYPE_72B_SO_RDIMM = 0x8, SPD_DDR4_DIMM_TYPE_72B_SO_UDIMM = 0x9, SPD_DDR4_DIMM_TYPE_16B_SO_DIMM = 0xc, SPD_DDR4_DIMM_TYPE_32B_SO_DIMM = 0xd, /* Masks to bits 3:0 to give the dimm type */ SPD_DDR4_DIMM_TYPE_MASK = 0xf }; /** * \brief DIMM characteristics * * The characteristics of each DIMM, as presented by the SPD */ struct dimm_attr_ddr4_st { enum spd_memory_type dram_type; enum spd_dimm_type_ddr4 dimm_type; char part_number[SPD_DDR4_PART_LEN + 1]; u8 serial_number[4]; u8 bus_width; u8 ranks; u8 sdram_width; u16 cap_per_die_mbit; u16 size_mb; u16 manufacturer_id; u16 vdd_voltage; bool ecc_extension; }; typedef u8 spd_ddr4_raw_data[SPD_SIZE_MAX_DDR4]; int spd_decode_ddr4(struct dimm_attr_ddr4_st *dimm, spd_ddr4_raw_data spd); enum cb_err spd_add_smbios17_ddr4(const u8 channel, const u8 slot, const u16 selected_freq, const struct dimm_attr_ddr4_st *info); /** * Converts DDR4 clock speed in MHz to the standard reported speed in MT/s */ uint16_t ddr4_speed_mhz_to_reported_mts(uint16_t speed_mhz); /** * \brief Representation of an MRS command * * This represents an MRS command as seen by the DIMM. This is not a memory * address that can be read to generate an MRS command. The mapping of CPU * to memory pins is hardware-dependent. * \n * The idea is to generalize the MRS code, and only need a hardware-specific * function to map the MRS bits to CPU address bits. An MRS command can be * sent like: * @code{.c} * uint32_t addr; * uint32_t mrs; * chipset_enable_mrs_command_mode(); * mrs = ddr4_get_mr0(rtt_wr, srt, cas, asr, cwl) * if (rank_has_mirrorred_pins) * mrs = ddr4_mrs_mirror_pins(mrs); * addr = chipset_specific_get_mrs_addr(mrs); * volatile_read(addr); * @endcode * * The MRS representation has the following structure: * - cmd[17:0] = Address pins A[13:0] * - cmd[21:20] = Bank address BA[1:0] * - cmd[23:22] = Bank group BG[1:0] * * Address pins A[16:14] are always low for MRS commands. A17 is reserved for * future use, cmd[19:18] is left as a placeholder in case it is needed. */ /* Swap A3<->A4, A5<->A6, A7<->A8, A11<->A13, BA0<->BA1, BG0<->BG1 */ static inline uint32_t ddr4_mrs_mirror_pins(uint32_t mrs_cmd) { mrs_cmd = (mrs_cmd & 0x5000A8) << 1 | (mrs_cmd & 0xA00150) >> 1 | (mrs_cmd & ~0xF001F8); mrs_cmd = (mrs_cmd & 0x000800) << 2 | (mrs_cmd & 0x002000) >> 2 | (mrs_cmd & ~0x002800); return mrs_cmd; } enum ddr4_mr0_mode { DDR4_MR0_MODE_NORMAL = 0, DDR4_MR0_MODE_TEST = 1, }; enum ddr4_mr0_dll_reset { DDR4_MR0_DLL_RESET_NO = 0, DDR4_MR0_DLL_RESET_YES = 1, }; enum ddr4_mr0_burst_type { DDR4_MR0_BURST_TYPE_SEQUENTIAL = 0, DDR4_MR0_BURST_TYPE_INTERLEAVED = 1, }; enum ddr4_mr0_burst_length { DDR4_MR0_BURST_LENGTH_FIXED_8 = 0, DDR4_MR0_BURST_LENGTH_ON_THE_FLY = 1, DDR4_MR0_BURST_LENGTH_FIXED_4 = 2, }; /* Returns MRS command */ uint32_t ddr4_get_mr0(u8 write_recovery, enum ddr4_mr0_dll_reset dll_reset, u8 cas, enum ddr4_mr0_burst_type burst_type, enum ddr4_mr0_burst_length burst_length); enum ddr4_mr1_qoff { DDR4_MR1_QOFF_ENABLE = 0, DDR4_MR1_QOFF_DISABLE = 1, }; enum ddr4_mr1_tdqs { DDR4_MR1_TDQS_DISABLE = 0, DDR4_MR1_TDQS_ENABLE = 1, }; enum ddr4_mr1_rtt_nom { DDR4_MR1_RTT_NOM_OFF = 0, DDR4_MR1_RTT_NOM_RZQ_4 = 1, DDR4_MR1_RTT_NOM_RZQ_2 = 2, DDR4_MR1_RTT_NOM_RZQ_6 = 3, DDR4_MR1_RTT_NOM_RZQ_1 = 4, DDR4_MR1_RTT_NOM_RZQ_5 = 5, DDR4_MR1_RTT_NOM_RZQ_3 = 6, DDR4_MR1_RTT_NOM_RZQ_7 = 7, }; enum ddr4_mr1_write_leveling { DDR4_MR1_WRLVL_DISABLE = 0, DDR4_MR1_WRLVL_ENABLE = 1, }; enum ddr4_mr1_additive_latency { DDR4_MR1_AL_DISABLE = 0, DDR4_MR1_AL_CL_MINUS_1 = 1, DDR4_MR1_AL_CL_MINUS_2 = 2, }; enum ddr4_mr1_odimp { DDR4_MR1_ODIMP_RZQ_7 = 0, DDR4_MR1_ODIMP_RZQ_5 = 1, }; enum ddr4_mr1_dll { DDR4_MR1_DLL_DISABLE = 0, DDR4_MR1_DLL_ENABLE = 1, }; /* Returns MRS command */ uint32_t ddr4_get_mr1(enum ddr4_mr1_qoff qoff, enum ddr4_mr1_tdqs tdqs, enum ddr4_mr1_rtt_nom rtt_nom, enum ddr4_mr1_write_leveling write_leveling, enum ddr4_mr1_odimp output_drive_impedance, enum ddr4_mr1_additive_latency additive_latency, enum ddr4_mr1_dll dll_enable); enum ddr4_mr2_wr_crc { DDR4_MR2_WR_CRC_DISABLE = 0, DDR4_MR2_WR_CRC_ENABLE = 1, }; enum ddr4_mr2_rtt_wr { DDR4_MR2_RTT_WR_OFF = 0, DDR4_MR2_RTT_WR_RZQ_2 = 1, DDR4_MR2_RTT_WR_RZQ_1 = 2, DDR4_MR2_RTT_WR_HI_Z = 3, DDR4_MR2_RTT_WR_RZQ_3 = 4, }; enum ddr4_mr2_lp_asr { DDR4_MR2_ASR_MANUAL_NORMAL_RANGE = 0, DDR4_MR2_ASR_MANUAL_REDUCED_RANGE = 1, DDR4_MR2_ASR_MANUAL_EXTENDED_RANGE = 2, DDR4_MR2_ASR_AUTO = 3, }; /* Returns MRS command */ uint32_t ddr4_get_mr2(enum ddr4_mr2_wr_crc wr_crc, enum ddr4_mr2_rtt_wr rtt_wr, enum ddr4_mr2_lp_asr self_refresh, u8 cwl); enum ddr4_mr3_mpr_read_format { DDR4_MR3_MPR_SERIAL = 0, DDR4_MR3_MPR_PARALLEL = 1, DDR4_MR3_MPR_STAGGERED = 2, }; enum ddr4_mr3_wr_cmd_lat_crc_dm { DDR4_MR3_CRC_DM_4 = 0, DDR4_MR3_CRC_DM_5 = 1, DDR4_MR3_CRC_DM_6 = 2, }; enum ddr4_mr3_fine_gran_ref { DDR4_MR3_FINE_GRAN_REF_NORMAL = 0, DDR4_MR3_FINE_GRAN_REF_FIXED_2 = 1, DDR4_MR3_FINE_GRAN_REF_FIXED_4 = 2, /* Two reserved values */ DDR4_MR3_FINE_GRAN_REF_ON_THE_FLY_2 = 5, DDR4_MR3_FINE_GRAN_REF_ON_THE_FLY_4 = 6, }; enum ddr4_mr3_temp_sensor_readout { DDR4_MR3_TEMP_SENSOR_DISABLE = 0, DDR4_MR3_TEMP_SENSOR_ENABLE = 1, }; enum ddr4_mr3_pda { DDR4_MR3_PDA_DISABLE = 0, DDR4_MR3_PDA_ENABLE = 1, }; enum ddr4_mr3_geardown_mode { DDR4_MR3_GEARDOWN_1_2_RATE = 0, DDR4_MR3_GEARDOWN_1_4_RATE = 1, }; enum ddr4_mr3_mpr_operation { DDR4_MR3_MPR_NORMAL = 0, DDR4_MR3_MPR_MPR = 1, }; /* Returns MRS command */ uint32_t ddr4_get_mr3(enum ddr4_mr3_mpr_read_format mpr_read_format, enum ddr4_mr3_wr_cmd_lat_crc_dm command_latency_crc_dm, enum ddr4_mr3_fine_gran_ref fine_refresh, enum ddr4_mr3_temp_sensor_readout temp_sensor, enum ddr4_mr3_pda pda, enum ddr4_mr3_geardown_mode geardown, enum ddr4_mr3_mpr_operation mpr_operation, u8 mpr_page); enum ddr4_mr4_hppr { DDR4_MR4_HPPR_DISABLE = 0, DDR4_MR4_HPPR_ENABLE = 1, }; enum ddr4_mr4_wr_preamble { DDR4_MR4_WR_PREAMBLE_1 = 0, DDR4_MR4_WR_PREAMBLE_2 = 1, }; enum ddr4_mr4_rd_preamble { DDR4_MR4_RD_PREAMBLE_1 = 0, DDR4_MR4_RD_PREAMBLE_2 = 1, }; enum ddr4_mr4_rd_preamble_training { DDR4_MR4_RD_PREAMBLE_TRAINING_DISABLE = 0, DDR4_MR4_RD_PREAMBLE_TRAINING_ENABLE = 1, }; enum ddr4_mr4_self_refr_abort { DDR4_MR4_SELF_REFRESH_ABORT_DISABLE = 0, DDR4_MR4_SELF_REFRESH_ABORT_ENABLE = 1, }; enum ddr4_mr4_cs_to_cmd_latency { DDR4_MR4_CS_TO_CMD_LAT_DISABLE = 0, DDR4_MR4_CS_TO_CMD_LAT_3 = 1, DDR4_MR4_CS_TO_CMD_LAT_4 = 2, DDR4_MR4_CS_TO_CMD_LAT_5 = 3, DDR4_MR4_CS_TO_CMD_LAT_6 = 4, DDR4_MR4_CS_TO_CMD_LAT_8 = 5, }; enum ddr4_mr4_sppr { DDR4_MR4_SPPR_DISABLE = 0, DDR4_MR4_SPPR_ENABLE = 1, }; enum ddr4_mr4_internal_vref_mon { DDR4_MR4_INTERNAL_VREF_MON_DISABLE = 0, DDR4_MR4_INTERNAL_VREF_MON_ENABLE = 1, }; enum ddr4_mr4_temp_controlled_refr { DDR4_MR4_TEMP_CONTROLLED_REFR_DISABLE = 0, DDR4_MR4_TEMP_CONTROLLED_REFR_NORMAL = 2, DDR4_MR4_TEMP_CONTROLLED_REFR_EXTENDED = 3, }; enum ddr4_mr4_max_pd_mode { DDR4_MR4_MAX_PD_MODE_DISABLE = 0, DDR4_MR4_MAX_PD_MODE_ENABLE = 1, }; /* Returns MRS command */ uint32_t ddr4_get_mr4(enum ddr4_mr4_hppr hppr, enum ddr4_mr4_wr_preamble wr_preamble, enum ddr4_mr4_rd_preamble rd_preamble, enum ddr4_mr4_rd_preamble_training rd_preamble_train, enum ddr4_mr4_self_refr_abort self_ref_abrt, enum ddr4_mr4_cs_to_cmd_latency cs2cmd_lat, enum ddr4_mr4_sppr sppr, enum ddr4_mr4_internal_vref_mon int_vref_mon, enum ddr4_mr4_temp_controlled_refr temp_ctrl_ref, enum ddr4_mr4_max_pd_mode max_pd); enum ddr4_mr5_rd_dbi { DDR4_MR5_RD_DBI_DISABLE = 0, DDR4_MR5_RD_DBI_ENABLE = 1, }; enum ddr4_mr5_wr_dbi { DDR4_MR5_WR_DBI_DISABLE = 0, DDR4_MR5_WR_DBI_ENABLE = 1, }; enum ddr4_mr5_data_mask { DDR4_MR5_DATA_MASK_DISABLE = 0, DDR4_MR5_DATA_MASK_ENABLE = 1, }; enum ddr4_mr5_rtt_park { DDR4_MR5_RTT_PARK_OFF = 0, DDR4_MR5_RTT_PARK_RZQ_4 = 1, DDR4_MR5_RTT_PARK_RZQ_2 = 2, DDR4_MR5_RTT_PARK_RZQ_6 = 3, DDR4_MR5_RTT_PARK_RZQ_1 = 4, DDR4_MR5_RTT_PARK_RZQ_5 = 5, DDR4_MR5_RTT_PARK_RZQ_3 = 6, DDR4_MR5_RTT_PARK_RZQ_7 = 7, }; enum ddr4_mr5_odt_pd { DDR4_MR5_ODT_PD_ACTIVADED = 0, DDR4_MR5_ODT_PD_DEACTIVADED = 1, }; enum ddr4_mr5_ca_parity_lat { DDR4_MR5_CA_PARITY_LAT_DISABLE = 0, DDR4_MR5_CA_PARITY_LAT_4 = 1, /* 1600-2133 MT/s */ DDR4_MR5_CA_PARITY_LAT_5 = 2, /* 2400-2666 MT/s */ DDR4_MR5_CA_PARITY_LAT_6 = 3, /* 2933-3200 MT/s */ DDR4_MR5_CA_PARITY_LAT_8 = 4, /* RFU */ }; /* Returns MRS command */ uint32_t ddr4_get_mr5(enum ddr4_mr5_rd_dbi rd_dbi, enum ddr4_mr5_wr_dbi wr_dbi, enum ddr4_mr5_data_mask dm, enum ddr4_mr5_rtt_park rtt_park, enum ddr4_mr5_odt_pd odt_pd, enum ddr4_mr5_ca_parity_lat pl); enum ddr4_mr6_vrefdq_training { DDR4_MR6_VREFDQ_TRAINING_DISABLE = 0, DDR4_MR6_VREFDQ_TRAINING_ENABLE = 1, }; enum ddr4_mr6_vrefdq_training_range { DDR4_MR6_VREFDQ_TRAINING_RANGE_1 = 0, /* 60% to 92.50% in 0.65% steps */ DDR4_MR6_VREFDQ_TRAINING_RANGE_2 = 1, /* 40% to 77.50% in 0.65% steps */ }; /* Returns MRS command */ uint32_t ddr4_get_mr6(u8 tccd_l, enum ddr4_mr6_vrefdq_training vrefdq_training, enum ddr4_mr6_vrefdq_training_range range, u8 vrefdq_value); enum ddr4_zqcal_ls { DDR4_ZQCAL_SHORT = 0, DDR4_ZQCAL_LONG = 1, }; /* Returns MRS command */ uint32_t ddr4_get_zqcal_cmd(enum ddr4_zqcal_ls long_short); #endif /* DEVICE_DRAM_DDR4L_H */