/* SPDX-License-Identifier: GPL-2.0-only */ #include #include #include #include #include #include #include #include enum ddr4_speed_grade { DDR4_1600, DDR4_1866, DDR4_2133, DDR4_2400, DDR4_2666, DDR4_2933, DDR4_3200 }; struct ddr4_speed_attr { uint32_t min_clock_mhz; // inclusive uint32_t max_clock_mhz; // inclusive uint32_t reported_mts; }; /** * DDR4 speed attributes derived from JEDEC 79-4C tables 169 & 170 * * min_clock_mhz = 1000/max_tCk_avg(ns) + 1 * Adding 1 to make minimum inclusive * max_clock_mhz = 1000/min_tCk_avg(ns) * reported_mts = Standard reported DDR4 speed in MT/s * May be 1 less than the actual max MT/s */ static const struct ddr4_speed_attr ddr4_speeds[] = { [DDR4_1600] = {.min_clock_mhz = 668, .max_clock_mhz = 800, .reported_mts = 1600}, [DDR4_1866] = {.min_clock_mhz = 801, .max_clock_mhz = 934, .reported_mts = 1866}, [DDR4_2133] = {.min_clock_mhz = 935, .max_clock_mhz = 1067, .reported_mts = 2133}, [DDR4_2400] = {.min_clock_mhz = 1068, .max_clock_mhz = 1200, .reported_mts = 2400}, [DDR4_2666] = {.min_clock_mhz = 1201, .max_clock_mhz = 1333, .reported_mts = 2666}, [DDR4_2933] = {.min_clock_mhz = 1334, .max_clock_mhz = 1466, .reported_mts = 2933}, [DDR4_3200] = {.min_clock_mhz = 1467, .max_clock_mhz = 1600, .reported_mts = 3200} }; typedef enum { BLOCK_0, /* Base Configuration and DRAM Parameters */ BLOCK_1, BLOCK_1_L, /* Standard Module Parameters */ BLOCK_1_H, /* Hybrid Module Parameters */ BLOCK_2, BLOCK_2_L, /* Hybrid Module Extended Function Parameters */ BLOCK_2_H, /* Manufacturing Information */ BLOCK_3 /* End user programmable */ } spd_block_type; typedef struct { spd_block_type type; uint16_t start; /* starting offset from beginning of the spd */ uint16_t len; /* size of the block */ uint16_t crc_start; /* offset from start of crc bytes, 0 if none */ } spd_block; /* 'SPD contents architecture' as per datasheet */ const spd_block spd_blocks[] = { {.type = BLOCK_0, 0, 128, 126}, {.type = BLOCK_1, 128, 128, 126}, {.type = BLOCK_1_L, 128, 64, 0}, {.type = BLOCK_1_H, 192, 64, 0}, {.type = BLOCK_2_L, 256, 64, 62}, {.type = BLOCK_2_H, 320, 64, 0}, {.type = BLOCK_3, 384, 128, 0} }; static bool verify_block(const spd_block *block, spd_ddr4_raw_data spd) { uint16_t crc, spd_crc; spd_crc = (spd[block->start + block->crc_start + 1] << 8) | spd[block->start + block->crc_start]; crc = ddr_crc16(&spd[block->start], block->len - 2); return spd_crc == crc; } /* Check if given block is 'reserved' for a given module type */ static bool block_exists(spd_block_type type, u8 dimm_type) { bool is_hybrid; switch (type) { case BLOCK_0: /* fall-through */ case BLOCK_1: /* fall-through */ case BLOCK_1_L: /* fall-through */ case BLOCK_1_H: /* fall-through */ case BLOCK_2_H: /* fall-through */ case BLOCK_3: /* fall-through */ return true; case BLOCK_2_L: is_hybrid = (dimm_type >> 4) & ((1 << 3) - 1); if (is_hybrid) return true; return false; default: /* fall-through */ return false; } } /** * 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) { for (enum ddr4_speed_grade speed = 0; speed < ARRAY_SIZE(ddr4_speeds); speed++) { const struct ddr4_speed_attr *speed_attr = &ddr4_speeds[speed]; if (speed_mhz >= speed_attr->min_clock_mhz && speed_mhz <= speed_attr->max_clock_mhz) { return speed_attr->reported_mts; } } printk(BIOS_ERR, "DDR4 speed of %d MHz is out of range\n", speed_mhz); return 0; } /** * \brief Decode the raw SPD data * * Decodes a raw SPD data from a DDR4 DIMM, and organizes it into a * @ref dimm_attr structure. The SPD data must first be read in a contiguous * array, and passed to this function. * * @param dimm pointer to @ref dimm_attr structure where the decoded data is to * be stored * @param spd array of raw data previously read from the SPD. * * @return @ref spd_status enumerator * SPD_STATUS_OK -- decoding was successful * SPD_STATUS_INVALID -- invalid SPD or not a DDR4 SPD * SPD_STATUS_CRC_ERROR -- checksum mismatch */ int spd_decode_ddr4(struct dimm_attr_ddr4_st *dimm, spd_ddr4_raw_data spd) { u8 reg8; u8 bus_width, sdram_width; u16 cap_per_die_mbit; u16 spd_bytes_total, spd_bytes_used; const uint16_t spd_bytes_used_table[] = {0, 128, 256, 384, 512}; /* Make sure that the SPD dump is indeed from a DDR4 module */ if (spd[2] != SPD_MEMORY_TYPE_DDR4_SDRAM) { printk(BIOS_ERR, "Not a DDR4 SPD!\n"); dimm->dram_type = SPD_MEMORY_TYPE_UNDEFINED; return SPD_STATUS_INVALID; } spd_bytes_total = (spd[0] >> 4) & 0x7; spd_bytes_used = spd[0] & 0xf; if (!spd_bytes_total || !spd_bytes_used) { printk(BIOS_ERR, "SPD failed basic sanity checks\n"); return SPD_STATUS_INVALID; } if (spd_bytes_total >= 3) printk(BIOS_WARNING, "SPD Bytes Total value is reserved\n"); spd_bytes_total = 256 << (spd_bytes_total - 1); if (spd_bytes_used > 4) { printk(BIOS_ERR, "SPD Bytes Used value is reserved\n"); return SPD_STATUS_INVALID; } spd_bytes_used = spd_bytes_used_table[spd_bytes_used]; if (spd_bytes_used > spd_bytes_total) { printk(BIOS_ERR, "SPD Bytes Used is greater than SPD Bytes Total\n"); return SPD_STATUS_INVALID; } /* Verify CRC of blocks that have them, do not step over 'used' length */ for (int i = 0; i < ARRAY_SIZE(spd_blocks); i++) { /* this block is not checksummed */ if (spd_blocks[i].crc_start == 0) continue; /* we shouldn't have this block */ if (spd_blocks[i].start + spd_blocks[i].len > spd_bytes_used) continue; /* check if block exists in the current schema */ if (!block_exists(spd_blocks[i].type, spd[3])) continue; if (!verify_block(&spd_blocks[i], spd)) { printk(BIOS_ERR, "CRC failed for block %d\n", i); return SPD_STATUS_CRC_ERROR; } } dimm->dram_type = SPD_MEMORY_TYPE_DDR4_SDRAM; dimm->dimm_type = spd[3] & ((1 << 4) - 1); reg8 = spd[13] & ((1 << 4) - 1); dimm->bus_width = reg8; bus_width = 8 << (reg8 & ((1 << 3) - 1)); reg8 = spd[12] & ((1 << 3) - 1); dimm->sdram_width = reg8; sdram_width = 4 << reg8; reg8 = spd[4] & ((1 << 4) - 1); dimm->cap_per_die_mbit = reg8; cap_per_die_mbit = (1 << reg8) * 256; reg8 = (spd[12] >> 3) & ((1 << 3) - 1); dimm->ranks = reg8 + 1; if (!bus_width || !sdram_width) { printk(BIOS_ERR, "SPD information is invalid"); dimm->size_mb = 0; return SPD_STATUS_INVALID; } /* seems to be only one, in mV */ dimm->vdd_voltage = 1200; /* calculate size */ /* FIXME: this is wrong for 3DS devices */ dimm->size_mb = cap_per_die_mbit / 8 * bus_width / sdram_width * dimm->ranks; dimm->ecc_extension = spd[SPD_PRIMARY_SDRAM_WIDTH] & SPD_ECC_8BIT; /* make sure we have the manufacturing information block */ if (spd_bytes_used > 320) { dimm->manufacturer_id = (spd[351] << 8) | spd[350]; memcpy(dimm->part_number, &spd[329], SPD_DDR4_PART_LEN); dimm->part_number[SPD_DDR4_PART_LEN] = 0; memcpy(dimm->serial_number, &spd[325], sizeof(dimm->serial_number)); } return SPD_STATUS_OK; } enum cb_err spd_add_smbios17_ddr4(const u8 channel, const u8 slot, const u16 selected_freq, const struct dimm_attr_ddr4_st *info) { struct memory_info *mem_info; struct dimm_info *dimm; /* * Allocate CBMEM area for DIMM information used to populate SMBIOS * table 17 */ mem_info = cbmem_find(CBMEM_ID_MEMINFO); if (!mem_info) { mem_info = cbmem_add(CBMEM_ID_MEMINFO, sizeof(*mem_info)); printk(BIOS_DEBUG, "CBMEM entry for DIMM info: %p\n", mem_info); if (!mem_info) return CB_ERR; memset(mem_info, 0, sizeof(*mem_info)); } if (mem_info->dimm_cnt >= ARRAY_SIZE(mem_info->dimm)) { printk(BIOS_WARNING, "BUG: Too many DIMM infos for %s.\n", __func__); return CB_ERR; } dimm = &mem_info->dimm[mem_info->dimm_cnt]; if (info->size_mb) { dimm->ddr_type = MEMORY_TYPE_DDR4; dimm->ddr_frequency = selected_freq; dimm->dimm_size = info->size_mb; dimm->channel_num = channel; dimm->rank_per_dimm = info->ranks; dimm->dimm_num = slot; memcpy(dimm->module_part_number, info->part_number, SPD_DDR4_PART_LEN); dimm->mod_id = info->manufacturer_id; dimm->mod_type = info->dimm_type; dimm->bus_width = info->bus_width; memcpy(dimm->serial, info->serial_number, MIN(sizeof(dimm->serial), sizeof(info->serial_number))); dimm->vdd_voltage = info->vdd_voltage; mem_info->dimm_cnt++; } return CB_SUCCESS; } /* Returns MRS command */ static uint32_t ddr4_wr_to_mr0_map(u8 wr) { static const unsigned int enc[] = {0, 1, 2, 3, 4, 5, 7, 6, 8}; int wr_idx = wr/2 - 5; if (wr_idx < 0 || wr_idx >= ARRAY_SIZE(enc)) die("WR index out of bounds: %d (derived from %d)\n", wr_idx, wr); return enc[wr_idx] << 9; } /* Returns MRS command */ static uint32_t ddr4_cas_to_mr0_map(u8 cas) { static const unsigned int enc[] = { /* * The only non-zero bits are at positions (LSB0): 12, 6, 5, 4, 2. */ 0x0000, /* CL = 9 */ 0x0004, /* CL = 10 */ 0x0010, /* CL = 11 */ 0x0014, /* CL = 12 */ 0x0020, /* CL = 13 */ 0x0024, /* CL = 14 */ 0x0030, /* CL = 15 */ 0x0034, /* CL = 16 */ 0x0064, /* CL = 17 */ 0x0040, /* CL = 18 */ 0x0070, /* CL = 19 */ 0x0044, /* CL = 20 */ 0x0074, /* CL = 21 */ 0x0050, /* CL = 22 */ 0x0060, /* CL = 23 */ 0x0054, /* CL = 24 */ 0x1000, /* CL = 25 */ 0x1004, /* CL = 26 */ 0x1010, /* CL = 27 (only 3DS) */ 0x1014, /* CL = 28 */ 0x1020, /* reserved for CL = 29 */ 0x1024, /* CL = 30 */ 0x1030, /* reserved for CL = 31 */ 0x1034, /* CL = 32 */ }; int cas_idx = cas - 9; if (cas_idx < 0 || cas_idx >= ARRAY_SIZE(enc)) die("CAS index out of bounds: %d (derived from %d)\n", cas_idx, cas); return enc[cas_idx]; } 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) { uint32_t cmd = 0 << 20; cmd |= ddr4_wr_to_mr0_map(write_recovery); cmd |= dll_reset << 8; cmd |= DDR4_MR0_MODE_NORMAL << 7; cmd |= ddr4_cas_to_mr0_map(cas); cmd |= burst_type << 3; cmd |= burst_length << 0; return cmd; } 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) { uint32_t cmd = 1 << 20; cmd |= qoff << 12; cmd |= tdqs << 11; cmd |= rtt_nom << 8; cmd |= write_leveling << 7; cmd |= output_drive_impedance << 1; cmd |= additive_latency << 3; cmd |= dll_enable << 0; return cmd; } /* Returns MRS command */ static uint32_t ddr4_cwl_to_mr2_map(u8 cwl) { /* Encoding is (starting with 0): 9, 10, 11, 12, 14, 16, 18, 20 */ if (cwl < 14) cwl -= 9; else cwl = (cwl - 14) / 2 + 4; return cwl << 3; } 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) { uint32_t cmd = 2 << 20; cmd |= wr_crc << 12; cmd |= rtt_wr << 9; cmd |= self_refresh << 6; cmd |= ddr4_cwl_to_mr2_map(cwl); return cmd; } 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) { uint32_t cmd = 3 << 20; cmd |= mpr_read_format << 11; cmd |= command_latency_crc_dm << 9; cmd |= fine_refresh << 6; cmd |= temp_sensor << 5; cmd |= pda << 4; cmd |= geardown << 3; cmd |= mpr_operation << 2; cmd |= (mpr_page & 3) << 0; return cmd; } 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) { uint32_t cmd = 4 << 20; cmd |= hppr << 13; cmd |= wr_preamble << 12; cmd |= rd_preamble << 11; cmd |= rd_preamble_train << 10; cmd |= self_ref_abrt << 9; cmd |= cs2cmd_lat << 6; cmd |= sppr << 5; cmd |= int_vref_mon << 4; cmd |= temp_ctrl_ref << 2; cmd |= max_pd << 1; return cmd; } 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) { uint32_t cmd = 5 << 20; cmd |= rd_dbi << 12; cmd |= wr_dbi << 11; cmd |= dm << 10; cmd |= rtt_park << 6; cmd |= odt_pd << 5; cmd |= pl << 0; return cmd; } /* Returns MRS command */ static uint32_t ddr4_tccd_l_to_mr6_map(u8 tccd_l) { if (tccd_l < 4 || tccd_l > 8) die("tCCD_l out of range: %d\n", tccd_l); return (tccd_l - 4) << 10; } 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) { uint32_t cmd = 6 << 20; cmd |= ddr4_tccd_l_to_mr6_map(tccd_l); cmd |= vrefdq_training << 7; cmd |= range << 6; cmd |= vrefdq_value & 0x3F; return cmd; } /* * ZQCL: A16 = H, A15 = H, A14 = L, A10 = H, rest either L or H * ZQCS: A16 = H, A15 = H, A14 = L, A10 = L, rest either L or H */ uint32_t ddr4_get_zqcal_cmd(enum ddr4_zqcal_ls long_short) { uint32_t cmd = 1 << 16 | 1 << 15; cmd |= long_short << 10; return cmd; }