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// SPDX-License-Identifier: GPL-2.0-or-later
/*
* AMD Address Translation Library
*
* umc.c : Unified Memory Controller (UMC) topology helpers
*
* Copyright (c) 2023, Advanced Micro Devices, Inc.
* All Rights Reserved.
*
* Author: Yazen Ghannam <Yazen.Ghannam@amd.com>
*/
#include "internal.h"
/*
* MI300 has a fixed, model-specific mapping between a UMC instance and
* its related Data Fabric Coherent Station instance.
*
* The MCA_IPID_UMC[InstanceId] field holds a unique identifier for the
* UMC instance within a Node. Use this to find the appropriate Coherent
* Station ID.
*
* Redundant bits were removed from the map below.
*/
static const u16 umc_coh_st_map[32] = {
0x393, 0x293, 0x193, 0x093,
0x392, 0x292, 0x192, 0x092,
0x391, 0x291, 0x191, 0x091,
0x390, 0x290, 0x190, 0x090,
0x793, 0x693, 0x593, 0x493,
0x792, 0x692, 0x592, 0x492,
0x791, 0x691, 0x591, 0x491,
0x790, 0x690, 0x590, 0x490,
};
#define UMC_ID_MI300 GENMASK(23, 12)
static u8 get_coh_st_inst_id_mi300(struct atl_err *err)
{
u16 umc_id = FIELD_GET(UMC_ID_MI300, err->ipid);
u8 i;
for (i = 0; i < ARRAY_SIZE(umc_coh_st_map); i++) {
if (umc_id == umc_coh_st_map[i])
break;
}
WARN_ON_ONCE(i >= ARRAY_SIZE(umc_coh_st_map));
return i;
}
/* XOR the bits in @val. */
static u16 bitwise_xor_bits(u16 val)
{
u16 tmp = 0;
u8 i;
for (i = 0; i < 16; i++)
tmp ^= (val >> i) & 0x1;
return tmp;
}
struct xor_bits {
bool xor_enable;
u16 col_xor;
u32 row_xor;
};
#define NUM_BANK_BITS 4
#define NUM_COL_BITS 5
#define NUM_SID_BITS 2
static struct {
/* UMC::CH::AddrHashBank */
struct xor_bits bank[NUM_BANK_BITS];
/* UMC::CH::AddrHashPC */
struct xor_bits pc;
/* UMC::CH::AddrHashPC2 */
u8 bank_xor;
} addr_hash;
static struct {
u8 bank[NUM_BANK_BITS];
u8 col[NUM_COL_BITS];
u8 sid[NUM_SID_BITS];
u8 num_row_lo;
u8 num_row_hi;
u8 row_lo;
u8 row_hi;
u8 pc;
} bit_shifts;
#define MI300_UMC_CH_BASE 0x90000
#define MI300_ADDR_CFG (MI300_UMC_CH_BASE + 0x30)
#define MI300_ADDR_SEL (MI300_UMC_CH_BASE + 0x40)
#define MI300_COL_SEL_LO (MI300_UMC_CH_BASE + 0x50)
#define MI300_ADDR_SEL_2 (MI300_UMC_CH_BASE + 0xA4)
#define MI300_ADDR_HASH_BANK0 (MI300_UMC_CH_BASE + 0xC8)
#define MI300_ADDR_HASH_PC (MI300_UMC_CH_BASE + 0xE0)
#define MI300_ADDR_HASH_PC2 (MI300_UMC_CH_BASE + 0xE4)
#define ADDR_HASH_XOR_EN BIT(0)
#define ADDR_HASH_COL_XOR GENMASK(13, 1)
#define ADDR_HASH_ROW_XOR GENMASK(31, 14)
#define ADDR_HASH_BANK_XOR GENMASK(5, 0)
#define ADDR_CFG_NUM_ROW_LO GENMASK(11, 8)
#define ADDR_CFG_NUM_ROW_HI GENMASK(15, 12)
#define ADDR_SEL_BANK0 GENMASK(3, 0)
#define ADDR_SEL_BANK1 GENMASK(7, 4)
#define ADDR_SEL_BANK2 GENMASK(11, 8)
#define ADDR_SEL_BANK3 GENMASK(15, 12)
#define ADDR_SEL_BANK4 GENMASK(20, 16)
#define ADDR_SEL_ROW_LO GENMASK(27, 24)
#define ADDR_SEL_ROW_HI GENMASK(31, 28)
#define COL_SEL_LO_COL0 GENMASK(3, 0)
#define COL_SEL_LO_COL1 GENMASK(7, 4)
#define COL_SEL_LO_COL2 GENMASK(11, 8)
#define COL_SEL_LO_COL3 GENMASK(15, 12)
#define COL_SEL_LO_COL4 GENMASK(19, 16)
#define ADDR_SEL_2_BANK5 GENMASK(4, 0)
#define ADDR_SEL_2_CHAN GENMASK(15, 12)
/*
* Read UMC::CH::AddrHash{Bank,PC,PC2} registers to get XOR bits used
* for hashing.
*
* Also, read UMC::CH::Addr{Cfg,Sel,Sel2} and UMC::CH:ColSelLo registers to
* get the values needed to reconstruct the normalized address. Apply additional
* offsets to the raw register values, as needed.
*
* Do this during module init, since the values will not change during run time.
*
* These registers are instantiated for each UMC across each AMD Node.
* However, they should be identically programmed due to the fixed hardware
* design of MI300 systems. So read the values from Node 0 UMC 0 and keep a
* single global structure for simplicity.
*/
int get_umc_info_mi300(void)
{
u32 temp;
int ret;
u8 i;
for (i = 0; i < NUM_BANK_BITS; i++) {
ret = amd_smn_read(0, MI300_ADDR_HASH_BANK0 + (i * 4), &temp);
if (ret)
return ret;
addr_hash.bank[i].xor_enable = FIELD_GET(ADDR_HASH_XOR_EN, temp);
addr_hash.bank[i].col_xor = FIELD_GET(ADDR_HASH_COL_XOR, temp);
addr_hash.bank[i].row_xor = FIELD_GET(ADDR_HASH_ROW_XOR, temp);
}
ret = amd_smn_read(0, MI300_ADDR_HASH_PC, &temp);
if (ret)
return ret;
addr_hash.pc.xor_enable = FIELD_GET(ADDR_HASH_XOR_EN, temp);
addr_hash.pc.col_xor = FIELD_GET(ADDR_HASH_COL_XOR, temp);
addr_hash.pc.row_xor = FIELD_GET(ADDR_HASH_ROW_XOR, temp);
ret = amd_smn_read(0, MI300_ADDR_HASH_PC2, &temp);
if (ret)
return ret;
addr_hash.bank_xor = FIELD_GET(ADDR_HASH_BANK_XOR, temp);
ret = amd_smn_read(0, MI300_ADDR_CFG, &temp);
if (ret)
return ret;
bit_shifts.num_row_hi = FIELD_GET(ADDR_CFG_NUM_ROW_HI, temp);
bit_shifts.num_row_lo = 10 + FIELD_GET(ADDR_CFG_NUM_ROW_LO, temp);
ret = amd_smn_read(0, MI300_ADDR_SEL, &temp);
if (ret)
return ret;
bit_shifts.bank[0] = 5 + FIELD_GET(ADDR_SEL_BANK0, temp);
bit_shifts.bank[1] = 5 + FIELD_GET(ADDR_SEL_BANK1, temp);
bit_shifts.bank[2] = 5 + FIELD_GET(ADDR_SEL_BANK2, temp);
bit_shifts.bank[3] = 5 + FIELD_GET(ADDR_SEL_BANK3, temp);
/* Use BankBit4 for the SID0 position. */
bit_shifts.sid[0] = 5 + FIELD_GET(ADDR_SEL_BANK4, temp);
bit_shifts.row_lo = 12 + FIELD_GET(ADDR_SEL_ROW_LO, temp);
bit_shifts.row_hi = 24 + FIELD_GET(ADDR_SEL_ROW_HI, temp);
ret = amd_smn_read(0, MI300_COL_SEL_LO, &temp);
if (ret)
return ret;
bit_shifts.col[0] = 2 + FIELD_GET(COL_SEL_LO_COL0, temp);
bit_shifts.col[1] = 2 + FIELD_GET(COL_SEL_LO_COL1, temp);
bit_shifts.col[2] = 2 + FIELD_GET(COL_SEL_LO_COL2, temp);
bit_shifts.col[3] = 2 + FIELD_GET(COL_SEL_LO_COL3, temp);
bit_shifts.col[4] = 2 + FIELD_GET(COL_SEL_LO_COL4, temp);
ret = amd_smn_read(0, MI300_ADDR_SEL_2, &temp);
if (ret)
return ret;
/* Use BankBit5 for the SID1 position. */
bit_shifts.sid[1] = 5 + FIELD_GET(ADDR_SEL_2_BANK5, temp);
bit_shifts.pc = 5 + FIELD_GET(ADDR_SEL_2_CHAN, temp);
return 0;
}
/*
* MI300 systems report a DRAM address in MCA_ADDR for DRAM ECC errors. This must
* be converted to the intermediate normalized address (NA) before translating to a
* system physical address.
*
* The DRAM address includes bank, row, and column. Also included are bits for
* pseudochannel (PC) and stack ID (SID).
*
* Abbreviations: (S)tack ID, (P)seudochannel, (R)ow, (B)ank, (C)olumn, (Z)ero
*
* The MCA address format is as follows:
* MCA_ADDR[27:0] = {S[1:0], P[0], R[14:0], B[3:0], C[4:0], Z[0]}
*
* Additionally, the PC and Bank bits may be hashed. This must be accounted for before
* reconstructing the normalized address.
*/
#define MI300_UMC_MCA_COL GENMASK(5, 1)
#define MI300_UMC_MCA_BANK GENMASK(9, 6)
#define MI300_UMC_MCA_ROW GENMASK(24, 10)
#define MI300_UMC_MCA_PC BIT(25)
#define MI300_UMC_MCA_SID GENMASK(27, 26)
static unsigned long convert_dram_to_norm_addr_mi300(unsigned long addr)
{
u16 i, col, row, bank, pc, sid;
u32 temp;
col = FIELD_GET(MI300_UMC_MCA_COL, addr);
bank = FIELD_GET(MI300_UMC_MCA_BANK, addr);
row = FIELD_GET(MI300_UMC_MCA_ROW, addr);
pc = FIELD_GET(MI300_UMC_MCA_PC, addr);
sid = FIELD_GET(MI300_UMC_MCA_SID, addr);
/* Calculate hash for each Bank bit. */
for (i = 0; i < NUM_BANK_BITS; i++) {
if (!addr_hash.bank[i].xor_enable)
continue;
temp = bitwise_xor_bits(col & addr_hash.bank[i].col_xor);
temp ^= bitwise_xor_bits(row & addr_hash.bank[i].row_xor);
bank ^= temp << i;
}
/* Calculate hash for PC bit. */
if (addr_hash.pc.xor_enable) {
temp = bitwise_xor_bits(col & addr_hash.pc.col_xor);
temp ^= bitwise_xor_bits(row & addr_hash.pc.row_xor);
/* Bits SID[1:0] act as Bank[5:4] for PC hash, so apply them here. */
temp ^= bitwise_xor_bits((bank | sid << NUM_BANK_BITS) & addr_hash.bank_xor);
pc ^= temp;
}
/* Reconstruct the normalized address starting with NA[4:0] = 0 */
addr = 0;
/* Column bits */
for (i = 0; i < NUM_COL_BITS; i++) {
temp = (col >> i) & 0x1;
addr |= temp << bit_shifts.col[i];
}
/* Bank bits */
for (i = 0; i < NUM_BANK_BITS; i++) {
temp = (bank >> i) & 0x1;
addr |= temp << bit_shifts.bank[i];
}
/* Row lo bits */
for (i = 0; i < bit_shifts.num_row_lo; i++) {
temp = (row >> i) & 0x1;
addr |= temp << (i + bit_shifts.row_lo);
}
/* Row hi bits */
for (i = 0; i < bit_shifts.num_row_hi; i++) {
temp = (row >> (i + bit_shifts.num_row_lo)) & 0x1;
addr |= temp << (i + bit_shifts.row_hi);
}
/* PC bit */
addr |= pc << bit_shifts.pc;
/* SID bits */
for (i = 0; i < NUM_SID_BITS; i++) {
temp = (sid >> i) & 0x1;
addr |= temp << bit_shifts.sid[i];
}
pr_debug("Addr=0x%016lx", addr);
pr_debug("Bank=%u Row=%u Column=%u PC=%u SID=%u", bank, row, col, pc, sid);
return addr;
}
/*
* When a DRAM ECC error occurs on MI300 systems, it is recommended to retire
* all memory within that DRAM row. This applies to the memory with a DRAM
* bank.
*
* To find the memory addresses, loop through permutations of the DRAM column
* bits and find the System Physical address of each. The column bits are used
* to calculate the intermediate Normalized address, so all permutations should
* be checked.
*
* See amd_atl::convert_dram_to_norm_addr_mi300() for MI300 address formats.
*/
#define MI300_NUM_COL BIT(HWEIGHT(MI300_UMC_MCA_COL))
static void retire_row_mi300(struct atl_err *a_err)
{
unsigned long addr;
struct page *p;
u8 col;
for (col = 0; col < MI300_NUM_COL; col++) {
a_err->addr &= ~MI300_UMC_MCA_COL;
a_err->addr |= FIELD_PREP(MI300_UMC_MCA_COL, col);
addr = amd_convert_umc_mca_addr_to_sys_addr(a_err);
if (IS_ERR_VALUE(addr))
continue;
addr = PHYS_PFN(addr);
/*
* Skip invalid or already poisoned pages to avoid unnecessary
* error messages from memory_failure().
*/
p = pfn_to_online_page(addr);
if (!p)
continue;
if (PageHWPoison(p))
continue;
memory_failure(addr, 0);
}
}
void amd_retire_dram_row(struct atl_err *a_err)
{
if (df_cfg.rev == DF4p5 && df_cfg.flags.heterogeneous)
return retire_row_mi300(a_err);
}
EXPORT_SYMBOL_GPL(amd_retire_dram_row);
static unsigned long get_addr(unsigned long addr)
{
if (df_cfg.rev == DF4p5 && df_cfg.flags.heterogeneous)
return convert_dram_to_norm_addr_mi300(addr);
return addr;
}
#define MCA_IPID_INST_ID_HI GENMASK_ULL(47, 44)
static u8 get_die_id(struct atl_err *err)
{
/*
* AMD Node ID is provided in MCA_IPID[InstanceIdHi], and this
* needs to be divided by 4 to get the internal Die ID.
*/
if (df_cfg.rev == DF4p5 && df_cfg.flags.heterogeneous) {
u8 node_id = FIELD_GET(MCA_IPID_INST_ID_HI, err->ipid);
return node_id >> 2;
}
/*
* For CPUs, this is the AMD Node ID modulo the number
* of AMD Nodes per socket.
*/
return topology_amd_node_id(err->cpu) % topology_amd_nodes_per_pkg();
}
#define UMC_CHANNEL_NUM GENMASK(31, 20)
static u8 get_coh_st_inst_id(struct atl_err *err)
{
if (df_cfg.rev == DF4p5 && df_cfg.flags.heterogeneous)
return get_coh_st_inst_id_mi300(err);
return FIELD_GET(UMC_CHANNEL_NUM, err->ipid);
}
unsigned long convert_umc_mca_addr_to_sys_addr(struct atl_err *err)
{
u8 socket_id = topology_physical_package_id(err->cpu);
u8 coh_st_inst_id = get_coh_st_inst_id(err);
unsigned long addr = get_addr(err->addr);
u8 die_id = get_die_id(err);
pr_debug("socket_id=0x%x die_id=0x%x coh_st_inst_id=0x%x addr=0x%016lx",
socket_id, die_id, coh_st_inst_id, addr);
return norm_to_sys_addr(socket_id, die_id, coh_st_inst_id, addr);
}
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