/* * This file and its contents are supplied under the terms of the * Common Development and Distribution License ("CDDL"), version 1.0. * You may only use this file in accordance with the terms of version * 1.0 of the CDDL. * * A full copy of the text of the CDDL should have accompanied this * source. A copy of the CDDL is also available via the Internet at * http://www.illumos.org/license/CDDL. */ /* * Copyright 2022 Oxide Computer Company */ #ifndef _SYS_UMC_H #define _SYS_UMC_H #include #include /* * Various register definitions for accessing the AMD Unified Memory Controller * (UMC) over SMN (the system management network). Note, that the SMN exists * independently in each die and must be accessed through the appropriate * IOHC. * * There are effectively four different revisions of the UMC that we know about * and support querying: * * o DDR4 capable APUs * o DDR4 capable CPUs * o DDR5 capable APUs * o DDR5 capable CPUs * * In general for a given revision and generation of a controller (DDR4 vs. * DDR5), all of the address layouts are the same whether it is for an APU or a * CPU. The main difference is generally in the number of features. For example, * most APUs may not support the same rank multiplication bits and related in a * device. However, unlike the DF where everything changes, the main difference * within a generation is just which bits are implemented. This makes it much * easier to define UMC information. * * Between DDR4 and DDR5 based devices, the register locations have shifted; * however, generally speaking, the registers themselves are actually the same. * Registers here, similar to the DF, have a common form: * * UMC__ * * Here, would be something like 'BASE', for the UMC * UMC::CH::BaseAddr register. is one of DDR4 or DDR5. When the same * register is supported at the same address between versions, then is * elided. * * For fields inside of these registers, everything follows the same pattern in * which is: * * UMC___GET_ * * Note, will be elided if the register is the same between the DDR4 and * DDR5 versions. * * Finally, a cautionary note. While the DF provided a way for us to determine * what version something is, we have not determined a way to programmatically * determine what something supports outside of making notes based on the * family, model, and stepping CPUID information. Unfortunately, you must look * towards the documentation and find what you need in the PPR (processor * programming reference). */ #ifdef __cplusplus extern "C" { #endif /* * UMC Channel registers. These are in SMN Space. DDR4 and DDR5 based UMCs share * the same base address, somewhat surprisingly. This constructs the appropriate * offset and ensures that a caller doesn't exceed the number of known instances * of the register. See smn.h for additional details on SMN addressing. */ static inline smn_reg_t amdzen_umc_smn_reg(const uint8_t umcno, const smn_reg_def_t def, const uint16_t reginst) { const uint32_t APERTURE_BASE = 0x50000; const uint32_t APERTURE_MASK = 0xffffe000; const uint32_t umc32 = (const uint32_t)umcno; const uint32_t reginst32 = (const uint32_t)reginst; const uint32_t stride = (def.srd_stride == 0) ? 4 : def.srd_stride; const uint32_t nents = (def.srd_nents == 0) ? 1 : (const uint32_t)def.srd_nents; ASSERT3S(def.srd_unit, ==, SMN_UNIT_UMC); ASSERT0(def.srd_reg & APERTURE_MASK); ASSERT3U(umc32, <, 12); ASSERT3U(nents, >, reginst32); const uint32_t aperture_off = umc32 << 20; ASSERT3U(aperture_off, <=, UINT32_MAX - APERTURE_BASE); const uint32_t aperture = APERTURE_BASE + aperture_off; ASSERT0(aperture & ~APERTURE_MASK); const uint32_t reg = def.srd_reg + reginst32 * stride; ASSERT0(reg & APERTURE_MASK); return (SMN_MAKE_REG(aperture + reg)); } /* * UMC::CH::BaseAddr, UMC::CH::BaseAddrSec -- determines the base address used * to match a chip select. Instances 0/1 always refer to DIMM 0, while * instances 2/3 always refer to DIMM 1. */ /*CSTYLED*/ #define D_UMC_BASE (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0x00, \ .srd_nents = 4 \ } /*CSTYLED*/ #define D_UMC_BASE_SEC (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0x10, \ .srd_nents = 4 \ } #define UMC_BASE(u, i) amdzen_umc_smn_reg(u, D_UMC_BASE, i) #define UMC_BASE_SEC(u, i) amdzen_umc_smn_reg(u, D_UMC_BASE_SEC, i) #define UMC_BASE_GET_ADDR(r) bitx32(r, 31, 1) #define UMC_BASE_ADDR_SHIFT 9 #define UMC_BASE_GET_EN(r) bitx32(r, 0, 0) /* * UMC::BaseAddrExt, UMC::BaseAddrSecExt -- The first of several extensions to * registers that allow more address bits. Note, only present in some DDR5 * capable SoCs. */ /*CSTYLED*/ #define D_UMC_BASE_EXT_DDR5 (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0xb00, \ .srd_nents = 4 \ } /*CSTYLED*/ #define D_UMC_BASE_EXT_SEC_DDR5 (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0xb10, \ .srd_nents = 4 \ } #define UMC_BASE_EXT_DDR5(u, i) amdzen_umc_smn_reg(u, D_UMC_BASE_EXT_DDR5, i) #define UMC_BASE_EXT_SEC_DDR5(u, i) \ amdzen_umc_smn_reg(u, D_UMC_BASE_EXT_SEC_DDR5, i) #define UMC_BASE_EXT_GET_ADDR(r) bitx32(r, 7, 0) #define UMC_BASE_EXT_ADDR_SHIFT 40 /* * UMC::CH::AddrMask, UMC::CH::AddrMaskSec -- This register is used to compare * the incoming address to see it matches the base. Tweaking what is used for * match is often part of the interleaving strategy. */ /*CSTYLED*/ #define D_UMC_MASK_DDR4 (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0x20, \ .srd_nents = 2 \ } /*CSTYLED*/ #define D_UMC_MASK_SEC_DDR4 (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0x28, \ .srd_nents = 2 \ } /*CSTYLED*/ #define D_UMC_MASK_DDR5 (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0x20, \ .srd_nents = 4 \ } /*CSTYLED*/ #define D_UMC_MASK_SEC_DDR5 (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0x30, \ .srd_nents = 4 \ } #define UMC_MASK_DDR4(u, i) amdzen_umc_smn_reg(u, D_UMC_MASK_DDR4, i) #define UMC_MASK_SEC_DDR4(u, i) amdzen_umc_smn_reg(u, D_UMC_MASK_SEC_DDR4, i) #define UMC_MASK_DDR5(u, i) amdzen_umc_smn_reg(u, D_UMC_MASK_DDR5, i) #define UMC_MASK_SEC_DDR5(u, i) amdzen_umc_smn_reg(u, D_UMC_MASK_SEC_DDR5, i) #define UMC_MASK_GET_ADDR(r) bitx32(r, 31, 1) #define UMC_MASK_ADDR_SHIFT 9 /* * UMC::AddrMaskExt, UMC::AddrMaskSecExt -- Extended mask addresses. */ /*CSTYLED*/ #define D_UMC_MASK_EXT_DDR5 (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0xb20, \ .srd_nents = 4 \ } /*CSTYLED*/ #define D_UMC_MASK_EXT_SEC_DDR5 (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0xb30, \ .srd_nents = 4 \ } #define UMC_MASK_EXT_DDR5(u, i) amdzen_umc_smn_reg(u, D_UMC_MASK_EXT_DDR5, i) #define UMC_MASK_EXT_SEC_DDR5(u, i) \ amdzen_umc_smn_reg(u, D_UMC_MASK_EXT_SEC_DDR5, i) #define UMC_MASK_EXT_GET_ADDR(r) bitx32(r, 7, 0) #define UMC_MASK_EXT_ADDR_SHIFT 40 /* * UMC::CH::AddrCfg -- This register contains a number of bits that describe how * the address is actually used, one per DIMM. Note, not all members are valid * for all classes of DIMMs. It's worth calling out that the total number of * banks value here describes the total number of banks on the entire chip, e.g. * it is bank groups * banks/groups. Therefore to determine the number of * banks/group you must subtract the number of bank group bits from the total * number of bank bits. */ /*CSTYLED*/ #define D_UMC_ADDRCFG_DDR4 (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0x30, \ .srd_nents = 2 \ } /*CSTYLED*/ #define D_UMC_ADDRCFG_DDR5 (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0x40, \ .srd_nents = 4 \ } #define UMC_ADDRCFG_DDR4(u, i) amdzen_umc_smn_reg(u, D_UMC_ADDRCFG_DDR4, i) #define UMC_ADDRCFG_DDR5(u, i) amdzen_umc_smn_reg(u, D_UMC_ADDRCFG_DDR5, i) #define UMC_ADDRCFG_GET_NBANK_BITS(r) bitx32(r, 21, 20) #define UMC_ADDRCFG_NBANK_BITS_BASE 3 #define UMC_ADDRCFG_GET_NCOL_BITS(r) bitx32(r, 19, 16) #define UMC_ADDRCFG_NCOL_BITS_BASE 5 #define UMC_ADDRCFG_GET_NROW_BITS_LO(r) bitx32(r, 11, 8) #define UMC_ADDRCFG_NROW_BITS_LO_BASE 10 #define UMC_ADDRCFG_GET_NBANKGRP_BITS(r) bitx32(r, 3, 2) #define UMC_ADDRCFG_DDR4_GET_NROW_BITS_HI(r) bitx32(r, 15, 12) #define UMC_ADDRCFG_DDR4_GET_NRM_BITS(r) bitx32(r, 5, 4) #define UMC_ADDRCFG_DDR5_GET_CSXOR(r) bitx32(r, 31, 30) #define UMC_ADDRCFG_DDR5_GET_NRM_BITS(r) bitx32(r, 6, 4) /* * UMC::CH::AddrSel -- This register is used to program how the actual bits in * the normalized address map to the row and bank. While the bank can select * which bits in the normalized address are used to construct the bank number, * row bits are contiguous from the starting number. */ /*CSTYLED*/ #define D_UMC_ADDRSEL_DDR4 (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0x40, \ .srd_nents = 2 \ } /*CSTYLED*/ #define D_UMC_ADDRSEL_DDR5 (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0x50, \ .srd_nents = 4 \ } #define UMC_ADDRSEL_DDR4(u, i) amdzen_umc_smn_reg(u, D_UMC_ADDRSEL_DDR4, i) #define UMC_ADDRSEL_DDR5(u, i) amdzen_umc_smn_reg(u, D_UMC_ADDRSEL_DDR5, i) #define UMC_ADDRSEL_GET_ROW_LO(r) bitx32(r, 27, 24) #define UMC_ADDRSEL_ROW_LO_BASE 12 #define UMC_ADDRSEL_GET_BANK4(r) bitx32(r, 19, 16) #define UMC_ADDRSEL_GET_BANK3(r) bitx32(r, 15, 12) #define UMC_ADDRSEL_GET_BANK2(r) bitx32(r, 11, 8) #define UMC_ADDRSEL_GET_BANK1(r) bitx32(r, 7, 4) #define UMC_ADDRSEL_GET_BANK0(r) bitx32(r, 3, 0) #define UMC_ADDRSEL_BANK_BASE 5 #define UMC_ADDRSEL_DDR4_GET_ROW_HI(r) bitx32(r, 31, 28) #define UMC_ADDRSEL_DDR4_ROW_HI_BASE 24 /* * UMC::CH::ColSelLo, UMC::CH::ColSelHi -- This register selects which address * bits map to the various column select bits. These registers interleave so in * the case of DDR4, it's 0x50, 0x54 for DIMM 0 lo, hi. Then 0x58, 0x5c for * DIMM1. DDR5 based entries do something similar; however, instead of being * per-DIMM, there is one of these for each CS. */ /*CSTYLED*/ #define D_UMC_COLSEL_LO_DDR4 (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0x50, \ .srd_nents = 2, \ .srd_stride = 8 \ } /*CSTYLED*/ #define D_UMC_COLSEL_HI_DDR4 (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0x54, \ .srd_nents = 2, \ .srd_stride = 8 \ } /*CSTYLED*/ #define D_UMC_COLSEL_LO_DDR5 (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0x60, \ .srd_nents = 4, \ .srd_stride = 8 \ } /*CSTYLED*/ #define D_UMC_COLSEL_HI_DDR5 (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0x64, \ .srd_nents = 4, \ .srd_stride = 8 \ } #define UMC_COLSEL_LO_DDR4(u, i) \ amdzen_umc_smn_reg(u, D_UMC_COLSEL_LO_DDR4, i) #define UMC_COLSEL_HI_DDR4(u, i) \ amdzen_umc_smn_reg(u, D_UMC_COLSEL_HI_DDR4, i) #define UMC_COLSEL_LO_DDR5(u, i) \ amdzen_umc_smn_reg(u, D_UMC_COLSEL_LO_DDR5, i) #define UMC_COLSEL_HI_DDR5(u, i) \ amdzen_umc_smn_reg(u, D_UMC_COLSEL_HI_DDR5, i) #define UMC_COLSEL_REMAP_GET_COL(r, x) bitx32(r, (3 + (4 * (x))), (4 * ((x)))) #define UMC_COLSEL_LO_BASE 2 #define UMC_COLSEL_HI_BASE 8 /* * UMC::CH::RmSel -- This register contains the bits that determine how the rank * is determined. Which fields of this are valid vary a lot in the different * parts. The DDR4 and DDR5 versions are different enough that we use totally * disjoint definitions. It's also worth noting that DDR5 doesn't have a * secondary version of this as it is included in the main register. * * In general, APUs have some of the MSBS (most significant bit swap) related * fields; however, they do not have rank multiplication bits. */ /*CSTYLED*/ #define D_UMC_RMSEL_DDR4 (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0x70, \ .srd_nents = 2 \ } /*CSTYLED*/ #define D_UMC_RMSEL_SEC_DDR4 (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0x78, \ .srd_nents = 2 \ } #define UMC_RMSEL_DDR4(u, i) amdzen_umc_smn_reg(u, D_UMC_RMSEL_DDR4, i) #define UMC_RMSEL_SEC_DDR4(u, i) \ amdzen_umc_smn_reg(u, D_UMC_RMSEL_SEC_DDR4, i) #define UMC_RMSEL_DDR4_GET_INV_MSBO(r) bitx32(r, 19, 18) #define UMC_RMSEL_DDR4_GET_INV_MSBE(r) bitx32(r, 17, 16) #define UMC_RMSEL_DDR4_GET_RM2(r) bitx32(r, 11, 8) #define UMC_RMSEL_DDR4_GET_RM1(r) bitx32(r, 7, 4) #define UMC_RMSEL_DDR4_GET_RM0(r) bitx32(r, 3, 0) #define UMC_RMSEL_BASE 12 /*CSTYLED*/ #define D_UMC_RMSEL_DDR5 (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0x80, \ .srd_nents = 4 \ } #define UMC_RMSEL_DDR5(u, i) amdzen_umc_smn_reg(u, D_UMC_RMSEL_DDR5, i) #define UMC_RMSEL_DDR5_GET_INV_MSBS_SEC(r) bitx32(r, 31, 30) #define UMC_RMSEL_DDR5_GET_INV_MSBS(r) bitx32(r, 29, 28) #define UMC_RMSEL_DDR5_GET_SUBCHAN(r) bitx32(r, 19, 16) #define UMC_RMSEL_DDR5_SUBCHAN_BASE 5 #define UMC_RMSEL_DDR5_GET_RM3(r) bitx32(r, 15, 12) #define UMC_RMSEL_DDR5_GET_RM2(r) bitx32(r, 11, 8) #define UMC_RMSEL_DDR5_GET_RM1(r) bitx32(r, 7, 4) #define UMC_RMSEL_DDR5_GET_RM0(r) bitx32(r, 3, 0) /* * UMC::CH::DimmCfg -- This describes several properties of the DIMM that is * installed, such as its overall width or type. */ /*CSTYLED*/ #define D_UMC_DIMMCFG_DDR4 (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0x80, \ .srd_nents = 2 \ } /*CSTYLED*/ #define D_UMC_DIMMCFG_DDR5 (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0x90, \ .srd_nents = 2 \ } #define UMC_DIMMCFG_DDR4(u, i) amdzen_umc_smn_reg(u, D_UMC_DIMMCFG_DDR4, i) #define UMC_DIMMCFG_DDR5(u, i) amdzen_umc_smn_reg(u, D_UMC_DIMMCFG_DDR5, i) #define UMC_DIMMCFG_GET_PKG_RALIGN(r) bitx32(r, 10, 10) #define UMC_DIMMCFG_GET_REFRESH_DIS(r) bitx32(r, 9, 9) #define UMC_DIMMCFG_GET_DQ_SWAP_DIS(r) bitx32(r, 8, 8) #define UMC_DIMMCFG_GET_X16(r) bitx32(r, 7, 7) #define UMC_DIMMCFG_GET_X4(r) bitx32(r, 6, 6) #define UMC_DIMMCFG_GET_LRDIMM(r) bitx32(r, 5, 5) #define UMC_DIMMCFG_GET_RDIMM(r) bitx32(r, 4, 4) #define UMC_DIMMCFG_GET_CISCS(r) bitx32(r, 3, 3) #define UMC_DIMMCFG_GET_3DS(r) bitx32(r, 2, 2) #define UMC_DIMMCFG_DDR4_GET_NVDIMMP(r) bitx32(r, 12, 12) #define UMC_DIMMCFG_DDR4_GET_DDR4e(r) bitx32(r, 11, 11) #define UMC_DIMMCFG_DDR5_GET_RALIGN(r) bitx32(r, 13, 12) #define UMC_DIMMCFG_DDR5_GET_ASYM(r) bitx32(r, 11, 11) #define UMC_DIMMCFG_DDR4_GET_OUTPUT_INV(r) bitx32(r, 1, 1) #define UMC_DIMMCFG_DDR4_GET_MRS_MIRROR(r) bitx32(r, 0, 0) /* * UMC::CH::AddrHashBank -- These registers contain various instructions about * how to hash an address across a bank to influence which bank is used. */ /*CSTYLED*/ #define D_UMC_BANK_HASH_DDR4 (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0xc8, \ .srd_nents = 5 \ } /*CSTYLED*/ #define D_UMC_BANK_HASH_DDR5 (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0x98, \ .srd_nents = 5 \ } #define UMC_BANK_HASH_DDR4(u, i) \ amdzen_umc_smn_reg(u, D_UMC_BANK_HASH_DDR4, i) #define UMC_BANK_HASH_DDR5(u, i) \ amdzen_umc_smn_reg(u, D_UMC_BANK_HASH_DDR5, i) #define UMC_BANK_HASH_GET_ROW(r) bitx32(r, 31, 14) #define UMC_BANK_HASH_GET_COL(r) bitx32(r, 13, 1) #define UMC_BANK_HASH_GET_EN(r) bitx32(r, 0, 0) /* * UMC::CH::AddrHashRM -- This hash register describes how to transform a UMC * address when trying to do rank hashing. Note, instance 3 is is reserved in * DDR5 modes. */ /*CSTYLED*/ #define D_UMC_RANK_HASH_DDR4 (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0xdc, \ .srd_nents = 3 \ } /*CSTYLED*/ #define D_UMC_RANK_HASH_DDR5 (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0xb0, \ .srd_nents = 4 \ } #define UMC_RANK_HASH_DDR4(u, i) \ amdzen_umc_smn_reg(u, D_UMC_RANK_HASH_DDR4, i) #define UMC_RANK_HASH_DDR5(u, i) \ amdzen_umc_smn_reg(u, D_UMC_RANK_HASH_DDR5, i) #define UMC_RANK_HASH_GET_ADDR(r) bitx32(r, 31, 1) #define UMC_RANK_HASH_SHIFT 9 #define UMC_RANK_HASH_GET_EN(r) bitx32(r, 0, 0) /* * UMC::AddrHashRMExt -- Extended rank hash addresses. */ /*CSTYLED*/ #define D_UMC_RANK_HASH_EXT_DDR5 (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0xbb0, \ .srd_nents = 4 \ } #define UMC_RANK_HASH_EXT_DDR5(u, i) \ amdzen_umc_smn_reg(u, D_UMC_RANK_HASH_EXT_DDR5, i) #define UMC_RANK_HASH_EXT_GET_ADDR(r) bitx32(r, 7, 0) #define UMC_RANK_HASH_EXT_ADDR_SHIFT 40 /* * UMC::CH::AddrHashPC, UMC::CH::AddrHashPC2 -- These registers describe a hash * to use for the DDR5 sub-channel. Note, in the DDR4 case this is actually the * upper two rank hash registers defined above because on the systems where this * occurs for DDR4, they only have up to one rank hash. */ /*CSTYLED*/ #define D_UMC_PC_HASH_DDR5 (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0xc0 \ } /*CSTYLED*/ #define D_UMC_PC_HASH2_DDR5 (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0xc4 \ } #define UMC_PC_HASH_DDR4(u) UMC_RANK_HASH_DDR4(u, 1) #define UMC_PC_HASH2_DDR4(u) UMC_RANK_HASH_DDR4(u, 2) #define UMC_PC_HASH_DDR5(u) amdzen_umc_smn_reg(u, D_UMC_PC_HASH_DDR5, 0) #define UMC_PC_HASH2_DDR5(u) amdzen_umc_smn_reg(u, D_UMC_PC_HASH2_DDR5, 0) #define UMC_PC_HASH_GET_ROW(r) bitx32(r, 31, 14) #define UMC_PC_HASH_GET_COL(r) bitx32(r, 13, 1) #define UMC_PC_HASH_GET_EN(r) bitx32(r, 0, 0) #define UMC_PC_HASH2_GET_BANK(r) bitx32(r, 4, 0) /* * UMC::CH::AddrHashCS -- Hashing: chip-select edition. Note, these can * ultimately cause you to change which DIMM is being actually accessed. */ /*CSTYLED*/ #define D_UMC_CS_HASH_DDR4 (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0xe8, \ .srd_nents = 2 \ } /*CSTYLED*/ #define D_UMC_CS_HASH_DDR5 (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0xc8, \ .srd_nents = 2 \ } #define UMC_CS_HASH_DDR4(u, i) amdzen_umc_smn_reg(u, D_UMC_CS_HASH_DDR4, i) #define UMC_CS_HASH_DDR5(u, i) amdzen_umc_smn_reg(u, D_UMC_CS_HASH_DDR5, i) #define UMC_CS_HASH_GET_ADDR(r) bitx32(r, 31, 1) #define UMC_CS_HASH_SHIFT 9 #define UMC_CS_HASH_GET_EN(r) bitx32(r, 0, 0) /* * UMC::AddrHashExtCS -- Extended chip-select hash addresses. */ /*CSTYLED*/ #define D_UMC_CS_HASH_EXT_DDR5 (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0xbc8, \ .srd_nents = 2 \ } #define UMC_CS_HASH_EXT_DDR5(u, i) \ amdzen_umc_smn_reg(u, D_UMC_CS_HASH_EXT_DDR5, i) #define UMC_CS_HASH_EXT_GET_ADDR(r) bitx32(r, 7, 0) #define UMC_CS_HASH_EXT_ADDR_SHIFT 40 /* * UMC::CH::UmcConfig -- This register controls various features of the device. * For our purposes we mostly care about seeing if ECC is enabled and a DIMM * type. */ /*CSTYLED*/ #define D_UMC_UMCCFG (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0x100 \ } #define UMC_UMCCFG(u) amdzen_umc_smn_reg(u, D_UMC_UMCCFG, 0) #define UMC_UMCCFG_GET_READY(r) bitx32(r, 31, 31) #define UMC_UMCCFG_GET_ECC_EN(r) bitx32(r, 12, 12) #define UMC_UMCCFG_GET_BURST_CTL(r) bitx32(r, 11, 10) #define UMC_UMCCFG_GET_BURST_LEN(r) bitx32(r, 9, 8) #define UMC_UMCCFG_GET_DDR_TYPE(r) bitx32(r, 2, 0) #define UMC_UMCCFG_DDR4_T_DDR4 0 #define UMC_UMCCFG_DDR4_T_LPDDR4 5 #define UMC_UMCCFG_DDR5_T_DDR4 0 #define UMC_UMCCFG_DDR5_T_DDR5 1 #define UMC_UMCCFG_DDR5_T_LPDDR4 5 #define UMC_UMCCFG_DDR5_T_LPDDR5 6 /* * UMC::CH::DataCtrl -- Various settings around whether data encryption or * scrambling is enabled. Note, this register really changes a bunch from family * to family. */ /*CSTYLED*/ #define D_UMC_DATACTL (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0x144 \ } #define UMC_DATACTL(u) amdzen_umc_smn_reg(u, D_UMC_DATACTL, 0) #define UMC_DATACTL_GET_ENCR_EN(r) bitx32(r, 8, 8) #define UMC_DATACTL_GET_SCRAM_EN(r) bitx32(r, 0, 0) #define UMC_DATACTL_DDR4_GET_TWEAK(r) bitx32(r, 19, 16) #define UMC_DATACTL_DDR4_GET_VMG2M(r) bitx32(r, 12, 12) #define UMC_DATACTL_DDR4_GET_FORCE_ENCR(r) bitx32(r, 11, 11) #define UMC_DATACTL_DDR5_GET_TWEAK(r) bitx32(r, 16, 16) #define UMC_DATACTL_DDR5_GET_XTS(r) bitx32(r, 14, 14) #define UMC_DATACTL_DDR5_GET_AES256(r) bitx32(r, 13, 13) /* * UMC::CH:EccCtrl -- Various settings around how ECC operates. */ /*CSTYLED*/ #define D_UMC_ECCCTL (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0x14c \ } #define UMC_ECCCTL(u) amdzen_umc_smn_reg(u, D_UMC_ECCCTL, 0) #define UMC_ECCCTL_GET_RD_EN(r) bitx32(x, 10, 10) #define UMC_ECCCTL_GET_X16(r) bitx32(x, 9, 9) #define UMC_ECCCTL_GET_UC_FATAL(r) bitx32(x, 8, 8) #define UMC_ECCCTL_GET_SYM_SIZE(r) bitx32(x, 7, 7) #define UMC_ECCCTL_GET_BIT_IL(r) bitx32(x, 6, 6) #define UMC_ECCCTL_GET_HIST_EN(r) bitx32(x, 5, 5) #define UMC_ECCCTL_GET_SW_SYM_EN(r) bitx32(x, 4, 4) #define UMC_ECCCTL_GET_WR_EN(r) bitx32(x, 0, 0) /* * Note, while this group appears generic and is the same in both DDR4/DDR5 * systems, this is not always present on every SoC and seems to depend on * something else inside the chip. */ #define UMC_ECCCTL_DDR_GET_PI(r) bitx32(r, 13, 13) #define UMC_ECCCTL_DDR_GET_PF_DIS(r) bitx32(r, 12, 12) #define UMC_ECCCTL_DDR_GET_SDP_OVR(r) bitx32(x, 11, 11) #define UMC_ECCCTL_DDR_GET_REPLAY_EN(r) bitx32(x, 1, 1) #define UMC_ECCCTL_DDR5_GET_PIN_RED(r) bitx32(r, 14, 14) /* * UMC::Ch::UmcCap, UMC::CH::UmcCapHi -- Various capability registers and * feature disables. We mostly just record these for future us for debugging * purposes. They aren't used as part of memory decoding. */ /*CSTYLED*/ #define D_UMC_UMCCAP (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0xdf0 \ } /*CSTYLED*/ #define D_UMC_UMCCAP_HI (const smn_reg_def_t){ \ .srd_unit = SMN_UNIT_UMC, \ .srd_reg = 0xdf4 \ } #define UMC_UMCCAP(u) amdzen_umc_smn_reg(u, D_UMC_UMCCAP, 0) #define UMC_UMCCAP_HI(u) amdzen_umc_smn_reg(u, D_UMC_UMCCAP_HI, 0) #ifdef __cplusplus } #endif #endif /* _SYS_UMC_H */