OpenCloudOS-Kernel/drivers/edac/pnd2_edac.c

1608 lines
43 KiB
C

/*
* Driver for Pondicherry2 memory controller.
*
* Copyright (c) 2016, Intel Corporation.
*
* This program is free software; you can redistribute it and/or modify it
* under the terms and conditions of the GNU General Public License,
* version 2, as published by the Free Software Foundation.
*
* This program is distributed in the hope it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
* more details.
*
* [Derived from sb_edac.c]
*
* Translation of system physical addresses to DIMM addresses
* is a two stage process:
*
* First the Pondicherry 2 memory controller handles slice and channel interleaving
* in "sys2pmi()". This is (almost) completley common between platforms.
*
* Then a platform specific dunit (DIMM unit) completes the process to provide DIMM,
* rank, bank, row and column using the appropriate "dunit_ops" functions/parameters.
*/
#include <linux/module.h>
#include <linux/init.h>
#include <linux/pci.h>
#include <linux/pci_ids.h>
#include <linux/slab.h>
#include <linux/delay.h>
#include <linux/edac.h>
#include <linux/mmzone.h>
#include <linux/smp.h>
#include <linux/bitmap.h>
#include <linux/math64.h>
#include <linux/mod_devicetable.h>
#include <asm/cpu_device_id.h>
#include <asm/intel-family.h>
#include <asm/processor.h>
#include <asm/mce.h>
#include "edac_mc.h"
#include "edac_module.h"
#include "pnd2_edac.h"
#define EDAC_MOD_STR "pnd2_edac"
#define APL_NUM_CHANNELS 4
#define DNV_NUM_CHANNELS 2
#define DNV_MAX_DIMMS 2 /* Max DIMMs per channel */
enum type {
APL,
DNV, /* All requests go to PMI CH0 on each slice (CH1 disabled) */
};
struct dram_addr {
int chan;
int dimm;
int rank;
int bank;
int row;
int col;
};
struct pnd2_pvt {
int dimm_geom[APL_NUM_CHANNELS];
u64 tolm, tohm;
};
/*
* System address space is divided into multiple regions with
* different interleave rules in each. The as0/as1 regions
* have no interleaving at all. The as2 region is interleaved
* between two channels. The mot region is magic and may overlap
* other regions, with its interleave rules taking precedence.
* Addresses not in any of these regions are interleaved across
* all four channels.
*/
static struct region {
u64 base;
u64 limit;
u8 enabled;
} mot, as0, as1, as2;
static struct dunit_ops {
char *name;
enum type type;
int pmiaddr_shift;
int pmiidx_shift;
int channels;
int dimms_per_channel;
int (*rd_reg)(int port, int off, int op, void *data, size_t sz, char *name);
int (*get_registers)(void);
int (*check_ecc)(void);
void (*mk_region)(char *name, struct region *rp, void *asym);
void (*get_dimm_config)(struct mem_ctl_info *mci);
int (*pmi2mem)(struct mem_ctl_info *mci, u64 pmiaddr, u32 pmiidx,
struct dram_addr *daddr, char *msg);
} *ops;
static struct mem_ctl_info *pnd2_mci;
#define PND2_MSG_SIZE 256
/* Debug macros */
#define pnd2_printk(level, fmt, arg...) \
edac_printk(level, "pnd2", fmt, ##arg)
#define pnd2_mc_printk(mci, level, fmt, arg...) \
edac_mc_chipset_printk(mci, level, "pnd2", fmt, ##arg)
#define MOT_CHAN_INTLV_BIT_1SLC_2CH 12
#define MOT_CHAN_INTLV_BIT_2SLC_2CH 13
#define SELECTOR_DISABLED (-1)
#define _4GB (1ul << 32)
#define PMI_ADDRESS_WIDTH 31
#define PND_MAX_PHYS_BIT 39
#define APL_ASYMSHIFT 28
#define DNV_ASYMSHIFT 31
#define CH_HASH_MASK_LSB 6
#define SLICE_HASH_MASK_LSB 6
#define MOT_SLC_INTLV_BIT 12
#define LOG2_PMI_ADDR_GRANULARITY 5
#define MOT_SHIFT 24
#define GET_BITFIELD(v, lo, hi) (((v) & GENMASK_ULL(hi, lo)) >> (lo))
#define U64_LSHIFT(val, s) ((u64)(val) << (s))
/*
* On Apollo Lake we access memory controller registers via a
* side-band mailbox style interface in a hidden PCI device
* configuration space.
*/
static struct pci_bus *p2sb_bus;
#define P2SB_DEVFN PCI_DEVFN(0xd, 0)
#define P2SB_ADDR_OFF 0xd0
#define P2SB_DATA_OFF 0xd4
#define P2SB_STAT_OFF 0xd8
#define P2SB_ROUT_OFF 0xda
#define P2SB_EADD_OFF 0xdc
#define P2SB_HIDE_OFF 0xe1
#define P2SB_BUSY 1
#define P2SB_READ(size, off, ptr) \
pci_bus_read_config_##size(p2sb_bus, P2SB_DEVFN, off, ptr)
#define P2SB_WRITE(size, off, val) \
pci_bus_write_config_##size(p2sb_bus, P2SB_DEVFN, off, val)
static bool p2sb_is_busy(u16 *status)
{
P2SB_READ(word, P2SB_STAT_OFF, status);
return !!(*status & P2SB_BUSY);
}
static int _apl_rd_reg(int port, int off, int op, u32 *data)
{
int retries = 0xff, ret;
u16 status;
u8 hidden;
/* Unhide the P2SB device, if it's hidden */
P2SB_READ(byte, P2SB_HIDE_OFF, &hidden);
if (hidden)
P2SB_WRITE(byte, P2SB_HIDE_OFF, 0);
if (p2sb_is_busy(&status)) {
ret = -EAGAIN;
goto out;
}
P2SB_WRITE(dword, P2SB_ADDR_OFF, (port << 24) | off);
P2SB_WRITE(dword, P2SB_DATA_OFF, 0);
P2SB_WRITE(dword, P2SB_EADD_OFF, 0);
P2SB_WRITE(word, P2SB_ROUT_OFF, 0);
P2SB_WRITE(word, P2SB_STAT_OFF, (op << 8) | P2SB_BUSY);
while (p2sb_is_busy(&status)) {
if (retries-- == 0) {
ret = -EBUSY;
goto out;
}
}
P2SB_READ(dword, P2SB_DATA_OFF, data);
ret = (status >> 1) & 0x3;
out:
/* Hide the P2SB device, if it was hidden before */
if (hidden)
P2SB_WRITE(byte, P2SB_HIDE_OFF, hidden);
return ret;
}
static int apl_rd_reg(int port, int off, int op, void *data, size_t sz, char *name)
{
int ret = 0;
edac_dbg(2, "Read %s port=%x off=%x op=%x\n", name, port, off, op);
switch (sz) {
case 8:
ret = _apl_rd_reg(port, off + 4, op, (u32 *)(data + 4));
/* fall through */
case 4:
ret |= _apl_rd_reg(port, off, op, (u32 *)data);
pnd2_printk(KERN_DEBUG, "%s=%x%08x ret=%d\n", name,
sz == 8 ? *((u32 *)(data + 4)) : 0, *((u32 *)data), ret);
break;
}
return ret;
}
static u64 get_mem_ctrl_hub_base_addr(void)
{
struct b_cr_mchbar_lo_pci lo;
struct b_cr_mchbar_hi_pci hi;
struct pci_dev *pdev;
pdev = pci_get_device(PCI_VENDOR_ID_INTEL, 0x1980, NULL);
if (pdev) {
pci_read_config_dword(pdev, 0x48, (u32 *)&lo);
pci_read_config_dword(pdev, 0x4c, (u32 *)&hi);
pci_dev_put(pdev);
} else {
return 0;
}
if (!lo.enable) {
edac_dbg(2, "MMIO via memory controller hub base address is disabled!\n");
return 0;
}
return U64_LSHIFT(hi.base, 32) | U64_LSHIFT(lo.base, 15);
}
static u64 get_sideband_reg_base_addr(void)
{
struct pci_dev *pdev;
u32 hi, lo;
u8 hidden;
pdev = pci_get_device(PCI_VENDOR_ID_INTEL, 0x19dd, NULL);
if (pdev) {
/* Unhide the P2SB device, if it's hidden */
pci_read_config_byte(pdev, 0xe1, &hidden);
if (hidden)
pci_write_config_byte(pdev, 0xe1, 0);
pci_read_config_dword(pdev, 0x10, &lo);
pci_read_config_dword(pdev, 0x14, &hi);
lo &= 0xfffffff0;
/* Hide the P2SB device, if it was hidden before */
if (hidden)
pci_write_config_byte(pdev, 0xe1, hidden);
pci_dev_put(pdev);
return (U64_LSHIFT(hi, 32) | U64_LSHIFT(lo, 0));
} else {
return 0xfd000000;
}
}
static int dnv_rd_reg(int port, int off, int op, void *data, size_t sz, char *name)
{
struct pci_dev *pdev;
char *base;
u64 addr;
if (op == 4) {
pdev = pci_get_device(PCI_VENDOR_ID_INTEL, 0x1980, NULL);
if (!pdev)
return -ENODEV;
pci_read_config_dword(pdev, off, data);
pci_dev_put(pdev);
} else {
/* MMIO via memory controller hub base address */
if (op == 0 && port == 0x4c) {
addr = get_mem_ctrl_hub_base_addr();
if (!addr)
return -ENODEV;
} else {
/* MMIO via sideband register base address */
addr = get_sideband_reg_base_addr();
if (!addr)
return -ENODEV;
addr += (port << 16);
}
base = ioremap((resource_size_t)addr, 0x10000);
if (!base)
return -ENODEV;
if (sz == 8)
*(u32 *)(data + 4) = *(u32 *)(base + off + 4);
*(u32 *)data = *(u32 *)(base + off);
iounmap(base);
}
edac_dbg(2, "Read %s=%.8x_%.8x\n", name,
(sz == 8) ? *(u32 *)(data + 4) : 0, *(u32 *)data);
return 0;
}
#define RD_REGP(regp, regname, port) \
ops->rd_reg(port, \
regname##_offset, \
regname##_r_opcode, \
regp, sizeof(struct regname), \
#regname)
#define RD_REG(regp, regname) \
ops->rd_reg(regname ## _port, \
regname##_offset, \
regname##_r_opcode, \
regp, sizeof(struct regname), \
#regname)
static u64 top_lm, top_hm;
static bool two_slices;
static bool two_channels; /* Both PMI channels in one slice enabled */
static u8 sym_chan_mask;
static u8 asym_chan_mask;
static u8 chan_mask;
static int slice_selector = -1;
static int chan_selector = -1;
static u64 slice_hash_mask;
static u64 chan_hash_mask;
static void mk_region(char *name, struct region *rp, u64 base, u64 limit)
{
rp->enabled = 1;
rp->base = base;
rp->limit = limit;
edac_dbg(2, "Region:%s [%llx, %llx]\n", name, base, limit);
}
static void mk_region_mask(char *name, struct region *rp, u64 base, u64 mask)
{
if (mask == 0) {
pr_info(FW_BUG "MOT mask cannot be zero\n");
return;
}
if (mask != GENMASK_ULL(PND_MAX_PHYS_BIT, __ffs(mask))) {
pr_info(FW_BUG "MOT mask not power of two\n");
return;
}
if (base & ~mask) {
pr_info(FW_BUG "MOT region base/mask alignment error\n");
return;
}
rp->base = base;
rp->limit = (base | ~mask) & GENMASK_ULL(PND_MAX_PHYS_BIT, 0);
rp->enabled = 1;
edac_dbg(2, "Region:%s [%llx, %llx]\n", name, base, rp->limit);
}
static bool in_region(struct region *rp, u64 addr)
{
if (!rp->enabled)
return false;
return rp->base <= addr && addr <= rp->limit;
}
static int gen_sym_mask(struct b_cr_slice_channel_hash *p)
{
int mask = 0;
if (!p->slice_0_mem_disabled)
mask |= p->sym_slice0_channel_enabled;
if (!p->slice_1_disabled)
mask |= p->sym_slice1_channel_enabled << 2;
if (p->ch_1_disabled || p->enable_pmi_dual_data_mode)
mask &= 0x5;
return mask;
}
static int gen_asym_mask(struct b_cr_slice_channel_hash *p,
struct b_cr_asym_mem_region0_mchbar *as0,
struct b_cr_asym_mem_region1_mchbar *as1,
struct b_cr_asym_2way_mem_region_mchbar *as2way)
{
const int intlv[] = { 0x5, 0xA, 0x3, 0xC };
int mask = 0;
if (as2way->asym_2way_interleave_enable)
mask = intlv[as2way->asym_2way_intlv_mode];
if (as0->slice0_asym_enable)
mask |= (1 << as0->slice0_asym_channel_select);
if (as1->slice1_asym_enable)
mask |= (4 << as1->slice1_asym_channel_select);
if (p->slice_0_mem_disabled)
mask &= 0xc;
if (p->slice_1_disabled)
mask &= 0x3;
if (p->ch_1_disabled || p->enable_pmi_dual_data_mode)
mask &= 0x5;
return mask;
}
static struct b_cr_tolud_pci tolud;
static struct b_cr_touud_lo_pci touud_lo;
static struct b_cr_touud_hi_pci touud_hi;
static struct b_cr_asym_mem_region0_mchbar asym0;
static struct b_cr_asym_mem_region1_mchbar asym1;
static struct b_cr_asym_2way_mem_region_mchbar asym_2way;
static struct b_cr_mot_out_base_mchbar mot_base;
static struct b_cr_mot_out_mask_mchbar mot_mask;
static struct b_cr_slice_channel_hash chash;
/* Apollo Lake dunit */
/*
* Validated on board with just two DIMMs in the [0] and [2] positions
* in this array. Other port number matches documentation, but caution
* advised.
*/
static const int apl_dports[APL_NUM_CHANNELS] = { 0x18, 0x10, 0x11, 0x19 };
static struct d_cr_drp0 drp0[APL_NUM_CHANNELS];
/* Denverton dunit */
static const int dnv_dports[DNV_NUM_CHANNELS] = { 0x10, 0x12 };
static struct d_cr_dsch dsch;
static struct d_cr_ecc_ctrl ecc_ctrl[DNV_NUM_CHANNELS];
static struct d_cr_drp drp[DNV_NUM_CHANNELS];
static struct d_cr_dmap dmap[DNV_NUM_CHANNELS];
static struct d_cr_dmap1 dmap1[DNV_NUM_CHANNELS];
static struct d_cr_dmap2 dmap2[DNV_NUM_CHANNELS];
static struct d_cr_dmap3 dmap3[DNV_NUM_CHANNELS];
static struct d_cr_dmap4 dmap4[DNV_NUM_CHANNELS];
static struct d_cr_dmap5 dmap5[DNV_NUM_CHANNELS];
static void apl_mk_region(char *name, struct region *rp, void *asym)
{
struct b_cr_asym_mem_region0_mchbar *a = asym;
mk_region(name, rp,
U64_LSHIFT(a->slice0_asym_base, APL_ASYMSHIFT),
U64_LSHIFT(a->slice0_asym_limit, APL_ASYMSHIFT) +
GENMASK_ULL(APL_ASYMSHIFT - 1, 0));
}
static void dnv_mk_region(char *name, struct region *rp, void *asym)
{
struct b_cr_asym_mem_region_denverton *a = asym;
mk_region(name, rp,
U64_LSHIFT(a->slice_asym_base, DNV_ASYMSHIFT),
U64_LSHIFT(a->slice_asym_limit, DNV_ASYMSHIFT) +
GENMASK_ULL(DNV_ASYMSHIFT - 1, 0));
}
static int apl_get_registers(void)
{
int ret = -ENODEV;
int i;
if (RD_REG(&asym_2way, b_cr_asym_2way_mem_region_mchbar))
return -ENODEV;
/*
* RD_REGP() will fail for unpopulated or non-existent
* DIMM slots. Return success if we find at least one DIMM.
*/
for (i = 0; i < APL_NUM_CHANNELS; i++)
if (!RD_REGP(&drp0[i], d_cr_drp0, apl_dports[i]))
ret = 0;
return ret;
}
static int dnv_get_registers(void)
{
int i;
if (RD_REG(&dsch, d_cr_dsch))
return -ENODEV;
for (i = 0; i < DNV_NUM_CHANNELS; i++)
if (RD_REGP(&ecc_ctrl[i], d_cr_ecc_ctrl, dnv_dports[i]) ||
RD_REGP(&drp[i], d_cr_drp, dnv_dports[i]) ||
RD_REGP(&dmap[i], d_cr_dmap, dnv_dports[i]) ||
RD_REGP(&dmap1[i], d_cr_dmap1, dnv_dports[i]) ||
RD_REGP(&dmap2[i], d_cr_dmap2, dnv_dports[i]) ||
RD_REGP(&dmap3[i], d_cr_dmap3, dnv_dports[i]) ||
RD_REGP(&dmap4[i], d_cr_dmap4, dnv_dports[i]) ||
RD_REGP(&dmap5[i], d_cr_dmap5, dnv_dports[i]))
return -ENODEV;
return 0;
}
/*
* Read all the h/w config registers once here (they don't
* change at run time. Figure out which address ranges have
* which interleave characteristics.
*/
static int get_registers(void)
{
const int intlv[] = { 10, 11, 12, 12 };
if (RD_REG(&tolud, b_cr_tolud_pci) ||
RD_REG(&touud_lo, b_cr_touud_lo_pci) ||
RD_REG(&touud_hi, b_cr_touud_hi_pci) ||
RD_REG(&asym0, b_cr_asym_mem_region0_mchbar) ||
RD_REG(&asym1, b_cr_asym_mem_region1_mchbar) ||
RD_REG(&mot_base, b_cr_mot_out_base_mchbar) ||
RD_REG(&mot_mask, b_cr_mot_out_mask_mchbar) ||
RD_REG(&chash, b_cr_slice_channel_hash))
return -ENODEV;
if (ops->get_registers())
return -ENODEV;
if (ops->type == DNV) {
/* PMI channel idx (always 0) for asymmetric region */
asym0.slice0_asym_channel_select = 0;
asym1.slice1_asym_channel_select = 0;
/* PMI channel bitmap (always 1) for symmetric region */
chash.sym_slice0_channel_enabled = 0x1;
chash.sym_slice1_channel_enabled = 0x1;
}
if (asym0.slice0_asym_enable)
ops->mk_region("as0", &as0, &asym0);
if (asym1.slice1_asym_enable)
ops->mk_region("as1", &as1, &asym1);
if (asym_2way.asym_2way_interleave_enable) {
mk_region("as2way", &as2,
U64_LSHIFT(asym_2way.asym_2way_base, APL_ASYMSHIFT),
U64_LSHIFT(asym_2way.asym_2way_limit, APL_ASYMSHIFT) +
GENMASK_ULL(APL_ASYMSHIFT - 1, 0));
}
if (mot_base.imr_en) {
mk_region_mask("mot", &mot,
U64_LSHIFT(mot_base.mot_out_base, MOT_SHIFT),
U64_LSHIFT(mot_mask.mot_out_mask, MOT_SHIFT));
}
top_lm = U64_LSHIFT(tolud.tolud, 20);
top_hm = U64_LSHIFT(touud_hi.touud, 32) | U64_LSHIFT(touud_lo.touud, 20);
two_slices = !chash.slice_1_disabled &&
!chash.slice_0_mem_disabled &&
(chash.sym_slice0_channel_enabled != 0) &&
(chash.sym_slice1_channel_enabled != 0);
two_channels = !chash.ch_1_disabled &&
!chash.enable_pmi_dual_data_mode &&
((chash.sym_slice0_channel_enabled == 3) ||
(chash.sym_slice1_channel_enabled == 3));
sym_chan_mask = gen_sym_mask(&chash);
asym_chan_mask = gen_asym_mask(&chash, &asym0, &asym1, &asym_2way);
chan_mask = sym_chan_mask | asym_chan_mask;
if (two_slices && !two_channels) {
if (chash.hvm_mode)
slice_selector = 29;
else
slice_selector = intlv[chash.interleave_mode];
} else if (!two_slices && two_channels) {
if (chash.hvm_mode)
chan_selector = 29;
else
chan_selector = intlv[chash.interleave_mode];
} else if (two_slices && two_channels) {
if (chash.hvm_mode) {
slice_selector = 29;
chan_selector = 30;
} else {
slice_selector = intlv[chash.interleave_mode];
chan_selector = intlv[chash.interleave_mode] + 1;
}
}
if (two_slices) {
if (!chash.hvm_mode)
slice_hash_mask = chash.slice_hash_mask << SLICE_HASH_MASK_LSB;
if (!two_channels)
slice_hash_mask |= BIT_ULL(slice_selector);
}
if (two_channels) {
if (!chash.hvm_mode)
chan_hash_mask = chash.ch_hash_mask << CH_HASH_MASK_LSB;
if (!two_slices)
chan_hash_mask |= BIT_ULL(chan_selector);
}
return 0;
}
/* Get a contiguous memory address (remove the MMIO gap) */
static u64 remove_mmio_gap(u64 sys)
{
return (sys < _4GB) ? sys : sys - (_4GB - top_lm);
}
/* Squeeze out one address bit, shift upper part down to fill gap */
static void remove_addr_bit(u64 *addr, int bitidx)
{
u64 mask;
if (bitidx == -1)
return;
mask = (1ull << bitidx) - 1;
*addr = ((*addr >> 1) & ~mask) | (*addr & mask);
}
/* XOR all the bits from addr specified in mask */
static int hash_by_mask(u64 addr, u64 mask)
{
u64 result = addr & mask;
result = (result >> 32) ^ result;
result = (result >> 16) ^ result;
result = (result >> 8) ^ result;
result = (result >> 4) ^ result;
result = (result >> 2) ^ result;
result = (result >> 1) ^ result;
return (int)result & 1;
}
/*
* First stage decode. Take the system address and figure out which
* second stage will deal with it based on interleave modes.
*/
static int sys2pmi(const u64 addr, u32 *pmiidx, u64 *pmiaddr, char *msg)
{
u64 contig_addr, contig_base, contig_offset, contig_base_adj;
int mot_intlv_bit = two_slices ? MOT_CHAN_INTLV_BIT_2SLC_2CH :
MOT_CHAN_INTLV_BIT_1SLC_2CH;
int slice_intlv_bit_rm = SELECTOR_DISABLED;
int chan_intlv_bit_rm = SELECTOR_DISABLED;
/* Determine if address is in the MOT region. */
bool mot_hit = in_region(&mot, addr);
/* Calculate the number of symmetric regions enabled. */
int sym_channels = hweight8(sym_chan_mask);
/*
* The amount we need to shift the asym base can be determined by the
* number of enabled symmetric channels.
* NOTE: This can only work because symmetric memory is not supposed
* to do a 3-way interleave.
*/
int sym_chan_shift = sym_channels >> 1;
/* Give up if address is out of range, or in MMIO gap */
if (addr >= (1ul << PND_MAX_PHYS_BIT) ||
(addr >= top_lm && addr < _4GB) || addr >= top_hm) {
snprintf(msg, PND2_MSG_SIZE, "Error address 0x%llx is not DRAM", addr);
return -EINVAL;
}
/* Get a contiguous memory address (remove the MMIO gap) */
contig_addr = remove_mmio_gap(addr);
if (in_region(&as0, addr)) {
*pmiidx = asym0.slice0_asym_channel_select;
contig_base = remove_mmio_gap(as0.base);
contig_offset = contig_addr - contig_base;
contig_base_adj = (contig_base >> sym_chan_shift) *
((chash.sym_slice0_channel_enabled >> (*pmiidx & 1)) & 1);
contig_addr = contig_offset + ((sym_channels > 0) ? contig_base_adj : 0ull);
} else if (in_region(&as1, addr)) {
*pmiidx = 2u + asym1.slice1_asym_channel_select;
contig_base = remove_mmio_gap(as1.base);
contig_offset = contig_addr - contig_base;
contig_base_adj = (contig_base >> sym_chan_shift) *
((chash.sym_slice1_channel_enabled >> (*pmiidx & 1)) & 1);
contig_addr = contig_offset + ((sym_channels > 0) ? contig_base_adj : 0ull);
} else if (in_region(&as2, addr) && (asym_2way.asym_2way_intlv_mode == 0x3ul)) {
bool channel1;
mot_intlv_bit = MOT_CHAN_INTLV_BIT_1SLC_2CH;
*pmiidx = (asym_2way.asym_2way_intlv_mode & 1) << 1;
channel1 = mot_hit ? ((bool)((addr >> mot_intlv_bit) & 1)) :
hash_by_mask(contig_addr, chan_hash_mask);
*pmiidx |= (u32)channel1;
contig_base = remove_mmio_gap(as2.base);
chan_intlv_bit_rm = mot_hit ? mot_intlv_bit : chan_selector;
contig_offset = contig_addr - contig_base;
remove_addr_bit(&contig_offset, chan_intlv_bit_rm);
contig_addr = (contig_base >> sym_chan_shift) + contig_offset;
} else {
/* Otherwise we're in normal, boring symmetric mode. */
*pmiidx = 0u;
if (two_slices) {
bool slice1;
if (mot_hit) {
slice_intlv_bit_rm = MOT_SLC_INTLV_BIT;
slice1 = (addr >> MOT_SLC_INTLV_BIT) & 1;
} else {
slice_intlv_bit_rm = slice_selector;
slice1 = hash_by_mask(addr, slice_hash_mask);
}
*pmiidx = (u32)slice1 << 1;
}
if (two_channels) {
bool channel1;
mot_intlv_bit = two_slices ? MOT_CHAN_INTLV_BIT_2SLC_2CH :
MOT_CHAN_INTLV_BIT_1SLC_2CH;
if (mot_hit) {
chan_intlv_bit_rm = mot_intlv_bit;
channel1 = (addr >> mot_intlv_bit) & 1;
} else {
chan_intlv_bit_rm = chan_selector;
channel1 = hash_by_mask(contig_addr, chan_hash_mask);
}
*pmiidx |= (u32)channel1;
}
}
/* Remove the chan_selector bit first */
remove_addr_bit(&contig_addr, chan_intlv_bit_rm);
/* Remove the slice bit (we remove it second because it must be lower */
remove_addr_bit(&contig_addr, slice_intlv_bit_rm);
*pmiaddr = contig_addr;
return 0;
}
/* Translate PMI address to memory (rank, row, bank, column) */
#define C(n) (0x10 | (n)) /* column */
#define B(n) (0x20 | (n)) /* bank */
#define R(n) (0x40 | (n)) /* row */
#define RS (0x80) /* rank */
/* addrdec values */
#define AMAP_1KB 0
#define AMAP_2KB 1
#define AMAP_4KB 2
#define AMAP_RSVD 3
/* dden values */
#define DEN_4Gb 0
#define DEN_8Gb 2
/* dwid values */
#define X8 0
#define X16 1
static struct dimm_geometry {
u8 addrdec;
u8 dden;
u8 dwid;
u8 rowbits, colbits;
u16 bits[PMI_ADDRESS_WIDTH];
} dimms[] = {
{
.addrdec = AMAP_1KB, .dden = DEN_4Gb, .dwid = X16,
.rowbits = 15, .colbits = 10,
.bits = {
C(2), C(3), C(4), C(5), C(6), B(0), B(1), B(2), R(0),
R(1), R(2), R(3), R(4), R(5), R(6), R(7), R(8), R(9),
R(10), C(7), C(8), C(9), R(11), RS, R(12), R(13), R(14),
0, 0, 0, 0
}
},
{
.addrdec = AMAP_1KB, .dden = DEN_4Gb, .dwid = X8,
.rowbits = 16, .colbits = 10,
.bits = {
C(2), C(3), C(4), C(5), C(6), B(0), B(1), B(2), R(0),
R(1), R(2), R(3), R(4), R(5), R(6), R(7), R(8), R(9),
R(10), C(7), C(8), C(9), R(11), RS, R(12), R(13), R(14),
R(15), 0, 0, 0
}
},
{
.addrdec = AMAP_1KB, .dden = DEN_8Gb, .dwid = X16,
.rowbits = 16, .colbits = 10,
.bits = {
C(2), C(3), C(4), C(5), C(6), B(0), B(1), B(2), R(0),
R(1), R(2), R(3), R(4), R(5), R(6), R(7), R(8), R(9),
R(10), C(7), C(8), C(9), R(11), RS, R(12), R(13), R(14),
R(15), 0, 0, 0
}
},
{
.addrdec = AMAP_1KB, .dden = DEN_8Gb, .dwid = X8,
.rowbits = 16, .colbits = 11,
.bits = {
C(2), C(3), C(4), C(5), C(6), B(0), B(1), B(2), R(0),
R(1), R(2), R(3), R(4), R(5), R(6), R(7), R(8), R(9),
R(10), C(7), C(8), C(9), R(11), RS, C(11), R(12), R(13),
R(14), R(15), 0, 0
}
},
{
.addrdec = AMAP_2KB, .dden = DEN_4Gb, .dwid = X16,
.rowbits = 15, .colbits = 10,
.bits = {
C(2), C(3), C(4), C(5), C(6), C(7), B(0), B(1), B(2),
R(0), R(1), R(2), R(3), R(4), R(5), R(6), R(7), R(8),
R(9), R(10), C(8), C(9), R(11), RS, R(12), R(13), R(14),
0, 0, 0, 0
}
},
{
.addrdec = AMAP_2KB, .dden = DEN_4Gb, .dwid = X8,
.rowbits = 16, .colbits = 10,
.bits = {
C(2), C(3), C(4), C(5), C(6), C(7), B(0), B(1), B(2),
R(0), R(1), R(2), R(3), R(4), R(5), R(6), R(7), R(8),
R(9), R(10), C(8), C(9), R(11), RS, R(12), R(13), R(14),
R(15), 0, 0, 0
}
},
{
.addrdec = AMAP_2KB, .dden = DEN_8Gb, .dwid = X16,
.rowbits = 16, .colbits = 10,
.bits = {
C(2), C(3), C(4), C(5), C(6), C(7), B(0), B(1), B(2),
R(0), R(1), R(2), R(3), R(4), R(5), R(6), R(7), R(8),
R(9), R(10), C(8), C(9), R(11), RS, R(12), R(13), R(14),
R(15), 0, 0, 0
}
},
{
.addrdec = AMAP_2KB, .dden = DEN_8Gb, .dwid = X8,
.rowbits = 16, .colbits = 11,
.bits = {
C(2), C(3), C(4), C(5), C(6), C(7), B(0), B(1), B(2),
R(0), R(1), R(2), R(3), R(4), R(5), R(6), R(7), R(8),
R(9), R(10), C(8), C(9), R(11), RS, C(11), R(12), R(13),
R(14), R(15), 0, 0
}
},
{
.addrdec = AMAP_4KB, .dden = DEN_4Gb, .dwid = X16,
.rowbits = 15, .colbits = 10,
.bits = {
C(2), C(3), C(4), C(5), C(6), C(7), C(8), B(0), B(1),
B(2), R(0), R(1), R(2), R(3), R(4), R(5), R(6), R(7),
R(8), R(9), R(10), C(9), R(11), RS, R(12), R(13), R(14),
0, 0, 0, 0
}
},
{
.addrdec = AMAP_4KB, .dden = DEN_4Gb, .dwid = X8,
.rowbits = 16, .colbits = 10,
.bits = {
C(2), C(3), C(4), C(5), C(6), C(7), C(8), B(0), B(1),
B(2), R(0), R(1), R(2), R(3), R(4), R(5), R(6), R(7),
R(8), R(9), R(10), C(9), R(11), RS, R(12), R(13), R(14),
R(15), 0, 0, 0
}
},
{
.addrdec = AMAP_4KB, .dden = DEN_8Gb, .dwid = X16,
.rowbits = 16, .colbits = 10,
.bits = {
C(2), C(3), C(4), C(5), C(6), C(7), C(8), B(0), B(1),
B(2), R(0), R(1), R(2), R(3), R(4), R(5), R(6), R(7),
R(8), R(9), R(10), C(9), R(11), RS, R(12), R(13), R(14),
R(15), 0, 0, 0
}
},
{
.addrdec = AMAP_4KB, .dden = DEN_8Gb, .dwid = X8,
.rowbits = 16, .colbits = 11,
.bits = {
C(2), C(3), C(4), C(5), C(6), C(7), C(8), B(0), B(1),
B(2), R(0), R(1), R(2), R(3), R(4), R(5), R(6), R(7),
R(8), R(9), R(10), C(9), R(11), RS, C(11), R(12), R(13),
R(14), R(15), 0, 0
}
}
};
static int bank_hash(u64 pmiaddr, int idx, int shft)
{
int bhash = 0;
switch (idx) {
case 0:
bhash ^= ((pmiaddr >> (12 + shft)) ^ (pmiaddr >> (9 + shft))) & 1;
break;
case 1:
bhash ^= (((pmiaddr >> (10 + shft)) ^ (pmiaddr >> (8 + shft))) & 1) << 1;
bhash ^= ((pmiaddr >> 22) & 1) << 1;
break;
case 2:
bhash ^= (((pmiaddr >> (13 + shft)) ^ (pmiaddr >> (11 + shft))) & 1) << 2;
break;
}
return bhash;
}
static int rank_hash(u64 pmiaddr)
{
return ((pmiaddr >> 16) ^ (pmiaddr >> 10)) & 1;
}
/* Second stage decode. Compute rank, bank, row & column. */
static int apl_pmi2mem(struct mem_ctl_info *mci, u64 pmiaddr, u32 pmiidx,
struct dram_addr *daddr, char *msg)
{
struct d_cr_drp0 *cr_drp0 = &drp0[pmiidx];
struct pnd2_pvt *pvt = mci->pvt_info;
int g = pvt->dimm_geom[pmiidx];
struct dimm_geometry *d = &dimms[g];
int column = 0, bank = 0, row = 0, rank = 0;
int i, idx, type, skiprs = 0;
for (i = 0; i < PMI_ADDRESS_WIDTH; i++) {
int bit = (pmiaddr >> i) & 1;
if (i + skiprs >= PMI_ADDRESS_WIDTH) {
snprintf(msg, PND2_MSG_SIZE, "Bad dimm_geometry[] table\n");
return -EINVAL;
}
type = d->bits[i + skiprs] & ~0xf;
idx = d->bits[i + skiprs] & 0xf;
/*
* On single rank DIMMs ignore the rank select bit
* and shift remainder of "bits[]" down one place.
*/
if (type == RS && (cr_drp0->rken0 + cr_drp0->rken1) == 1) {
skiprs = 1;
type = d->bits[i + skiprs] & ~0xf;
idx = d->bits[i + skiprs] & 0xf;
}
switch (type) {
case C(0):
column |= (bit << idx);
break;
case B(0):
bank |= (bit << idx);
if (cr_drp0->bahen)
bank ^= bank_hash(pmiaddr, idx, d->addrdec);
break;
case R(0):
row |= (bit << idx);
break;
case RS:
rank = bit;
if (cr_drp0->rsien)
rank ^= rank_hash(pmiaddr);
break;
default:
if (bit) {
snprintf(msg, PND2_MSG_SIZE, "Bad translation\n");
return -EINVAL;
}
goto done;
}
}
done:
daddr->col = column;
daddr->bank = bank;
daddr->row = row;
daddr->rank = rank;
daddr->dimm = 0;
return 0;
}
/* Pluck bit "in" from pmiaddr and return value shifted to bit "out" */
#define dnv_get_bit(pmi, in, out) ((int)(((pmi) >> (in)) & 1u) << (out))
static int dnv_pmi2mem(struct mem_ctl_info *mci, u64 pmiaddr, u32 pmiidx,
struct dram_addr *daddr, char *msg)
{
/* Rank 0 or 1 */
daddr->rank = dnv_get_bit(pmiaddr, dmap[pmiidx].rs0 + 13, 0);
/* Rank 2 or 3 */
daddr->rank |= dnv_get_bit(pmiaddr, dmap[pmiidx].rs1 + 13, 1);
/*
* Normally ranks 0,1 are DIMM0, and 2,3 are DIMM1, but we
* flip them if DIMM1 is larger than DIMM0.
*/
daddr->dimm = (daddr->rank >= 2) ^ drp[pmiidx].dimmflip;
daddr->bank = dnv_get_bit(pmiaddr, dmap[pmiidx].ba0 + 6, 0);
daddr->bank |= dnv_get_bit(pmiaddr, dmap[pmiidx].ba1 + 6, 1);
daddr->bank |= dnv_get_bit(pmiaddr, dmap[pmiidx].bg0 + 6, 2);
if (dsch.ddr4en)
daddr->bank |= dnv_get_bit(pmiaddr, dmap[pmiidx].bg1 + 6, 3);
if (dmap1[pmiidx].bxor) {
if (dsch.ddr4en) {
daddr->bank ^= dnv_get_bit(pmiaddr, dmap3[pmiidx].row6 + 6, 0);
daddr->bank ^= dnv_get_bit(pmiaddr, dmap3[pmiidx].row7 + 6, 1);
if (dsch.chan_width == 0)
/* 64/72 bit dram channel width */
daddr->bank ^= dnv_get_bit(pmiaddr, dmap5[pmiidx].ca3 + 6, 2);
else
/* 32/40 bit dram channel width */
daddr->bank ^= dnv_get_bit(pmiaddr, dmap5[pmiidx].ca4 + 6, 2);
daddr->bank ^= dnv_get_bit(pmiaddr, dmap2[pmiidx].row2 + 6, 3);
} else {
daddr->bank ^= dnv_get_bit(pmiaddr, dmap2[pmiidx].row2 + 6, 0);
daddr->bank ^= dnv_get_bit(pmiaddr, dmap3[pmiidx].row6 + 6, 1);
if (dsch.chan_width == 0)
daddr->bank ^= dnv_get_bit(pmiaddr, dmap5[pmiidx].ca3 + 6, 2);
else
daddr->bank ^= dnv_get_bit(pmiaddr, dmap5[pmiidx].ca4 + 6, 2);
}
}
daddr->row = dnv_get_bit(pmiaddr, dmap2[pmiidx].row0 + 6, 0);
daddr->row |= dnv_get_bit(pmiaddr, dmap2[pmiidx].row1 + 6, 1);
daddr->row |= dnv_get_bit(pmiaddr, dmap2[pmiidx].row2 + 6, 2);
daddr->row |= dnv_get_bit(pmiaddr, dmap2[pmiidx].row3 + 6, 3);
daddr->row |= dnv_get_bit(pmiaddr, dmap2[pmiidx].row4 + 6, 4);
daddr->row |= dnv_get_bit(pmiaddr, dmap2[pmiidx].row5 + 6, 5);
daddr->row |= dnv_get_bit(pmiaddr, dmap3[pmiidx].row6 + 6, 6);
daddr->row |= dnv_get_bit(pmiaddr, dmap3[pmiidx].row7 + 6, 7);
daddr->row |= dnv_get_bit(pmiaddr, dmap3[pmiidx].row8 + 6, 8);
daddr->row |= dnv_get_bit(pmiaddr, dmap3[pmiidx].row9 + 6, 9);
daddr->row |= dnv_get_bit(pmiaddr, dmap3[pmiidx].row10 + 6, 10);
daddr->row |= dnv_get_bit(pmiaddr, dmap3[pmiidx].row11 + 6, 11);
daddr->row |= dnv_get_bit(pmiaddr, dmap4[pmiidx].row12 + 6, 12);
daddr->row |= dnv_get_bit(pmiaddr, dmap4[pmiidx].row13 + 6, 13);
if (dmap4[pmiidx].row14 != 31)
daddr->row |= dnv_get_bit(pmiaddr, dmap4[pmiidx].row14 + 6, 14);
if (dmap4[pmiidx].row15 != 31)
daddr->row |= dnv_get_bit(pmiaddr, dmap4[pmiidx].row15 + 6, 15);
if (dmap4[pmiidx].row16 != 31)
daddr->row |= dnv_get_bit(pmiaddr, dmap4[pmiidx].row16 + 6, 16);
if (dmap4[pmiidx].row17 != 31)
daddr->row |= dnv_get_bit(pmiaddr, dmap4[pmiidx].row17 + 6, 17);
daddr->col = dnv_get_bit(pmiaddr, dmap5[pmiidx].ca3 + 6, 3);
daddr->col |= dnv_get_bit(pmiaddr, dmap5[pmiidx].ca4 + 6, 4);
daddr->col |= dnv_get_bit(pmiaddr, dmap5[pmiidx].ca5 + 6, 5);
daddr->col |= dnv_get_bit(pmiaddr, dmap5[pmiidx].ca6 + 6, 6);
daddr->col |= dnv_get_bit(pmiaddr, dmap5[pmiidx].ca7 + 6, 7);
daddr->col |= dnv_get_bit(pmiaddr, dmap5[pmiidx].ca8 + 6, 8);
daddr->col |= dnv_get_bit(pmiaddr, dmap5[pmiidx].ca9 + 6, 9);
if (!dsch.ddr4en && dmap1[pmiidx].ca11 != 0x3f)
daddr->col |= dnv_get_bit(pmiaddr, dmap1[pmiidx].ca11 + 13, 11);
return 0;
}
static int check_channel(int ch)
{
if (drp0[ch].dramtype != 0) {
pnd2_printk(KERN_INFO, "Unsupported DIMM in channel %d\n", ch);
return 1;
} else if (drp0[ch].eccen == 0) {
pnd2_printk(KERN_INFO, "ECC disabled on channel %d\n", ch);
return 1;
}
return 0;
}
static int apl_check_ecc_active(void)
{
int i, ret = 0;
/* Check dramtype and ECC mode for each present DIMM */
for (i = 0; i < APL_NUM_CHANNELS; i++)
if (chan_mask & BIT(i))
ret += check_channel(i);
return ret ? -EINVAL : 0;
}
#define DIMMS_PRESENT(d) ((d)->rken0 + (d)->rken1 + (d)->rken2 + (d)->rken3)
static int check_unit(int ch)
{
struct d_cr_drp *d = &drp[ch];
if (DIMMS_PRESENT(d) && !ecc_ctrl[ch].eccen) {
pnd2_printk(KERN_INFO, "ECC disabled on channel %d\n", ch);
return 1;
}
return 0;
}
static int dnv_check_ecc_active(void)
{
int i, ret = 0;
for (i = 0; i < DNV_NUM_CHANNELS; i++)
ret += check_unit(i);
return ret ? -EINVAL : 0;
}
static int get_memory_error_data(struct mem_ctl_info *mci, u64 addr,
struct dram_addr *daddr, char *msg)
{
u64 pmiaddr;
u32 pmiidx;
int ret;
ret = sys2pmi(addr, &pmiidx, &pmiaddr, msg);
if (ret)
return ret;
pmiaddr >>= ops->pmiaddr_shift;
/* pmi channel idx to dimm channel idx */
pmiidx >>= ops->pmiidx_shift;
daddr->chan = pmiidx;
ret = ops->pmi2mem(mci, pmiaddr, pmiidx, daddr, msg);
if (ret)
return ret;
edac_dbg(0, "SysAddr=%llx PmiAddr=%llx Channel=%d DIMM=%d Rank=%d Bank=%d Row=%d Column=%d\n",
addr, pmiaddr, daddr->chan, daddr->dimm, daddr->rank, daddr->bank, daddr->row, daddr->col);
return 0;
}
static void pnd2_mce_output_error(struct mem_ctl_info *mci, const struct mce *m,
struct dram_addr *daddr)
{
enum hw_event_mc_err_type tp_event;
char *optype, msg[PND2_MSG_SIZE];
bool ripv = m->mcgstatus & MCG_STATUS_RIPV;
bool overflow = m->status & MCI_STATUS_OVER;
bool uc_err = m->status & MCI_STATUS_UC;
bool recov = m->status & MCI_STATUS_S;
u32 core_err_cnt = GET_BITFIELD(m->status, 38, 52);
u32 mscod = GET_BITFIELD(m->status, 16, 31);
u32 errcode = GET_BITFIELD(m->status, 0, 15);
u32 optypenum = GET_BITFIELD(m->status, 4, 6);
int rc;
tp_event = uc_err ? (ripv ? HW_EVENT_ERR_FATAL : HW_EVENT_ERR_UNCORRECTED) :
HW_EVENT_ERR_CORRECTED;
/*
* According with Table 15-9 of the Intel Architecture spec vol 3A,
* memory errors should fit in this mask:
* 000f 0000 1mmm cccc (binary)
* where:
* f = Correction Report Filtering Bit. If 1, subsequent errors
* won't be shown
* mmm = error type
* cccc = channel
* If the mask doesn't match, report an error to the parsing logic
*/
if (!((errcode & 0xef80) == 0x80)) {
optype = "Can't parse: it is not a mem";
} else {
switch (optypenum) {
case 0:
optype = "generic undef request error";
break;
case 1:
optype = "memory read error";
break;
case 2:
optype = "memory write error";
break;
case 3:
optype = "addr/cmd error";
break;
case 4:
optype = "memory scrubbing error";
break;
default:
optype = "reserved";
break;
}
}
/* Only decode errors with an valid address (ADDRV) */
if (!(m->status & MCI_STATUS_ADDRV))
return;
rc = get_memory_error_data(mci, m->addr, daddr, msg);
if (rc)
goto address_error;
snprintf(msg, sizeof(msg),
"%s%s err_code:%04x:%04x channel:%d DIMM:%d rank:%d row:%d bank:%d col:%d",
overflow ? " OVERFLOW" : "", (uc_err && recov) ? " recoverable" : "", mscod,
errcode, daddr->chan, daddr->dimm, daddr->rank, daddr->row, daddr->bank, daddr->col);
edac_dbg(0, "%s\n", msg);
/* Call the helper to output message */
edac_mc_handle_error(tp_event, mci, core_err_cnt, m->addr >> PAGE_SHIFT,
m->addr & ~PAGE_MASK, 0, daddr->chan, daddr->dimm, -1, optype, msg);
return;
address_error:
edac_mc_handle_error(tp_event, mci, core_err_cnt, 0, 0, 0, -1, -1, -1, msg, "");
}
static void apl_get_dimm_config(struct mem_ctl_info *mci)
{
struct pnd2_pvt *pvt = mci->pvt_info;
struct dimm_info *dimm;
struct d_cr_drp0 *d;
u64 capacity;
int i, g;
for (i = 0; i < APL_NUM_CHANNELS; i++) {
if (!(chan_mask & BIT(i)))
continue;
dimm = EDAC_DIMM_PTR(mci->layers, mci->dimms, mci->n_layers, i, 0, 0);
if (!dimm) {
edac_dbg(0, "No allocated DIMM for channel %d\n", i);
continue;
}
d = &drp0[i];
for (g = 0; g < ARRAY_SIZE(dimms); g++)
if (dimms[g].addrdec == d->addrdec &&
dimms[g].dden == d->dden &&
dimms[g].dwid == d->dwid)
break;
if (g == ARRAY_SIZE(dimms)) {
edac_dbg(0, "Channel %d: unrecognized DIMM\n", i);
continue;
}
pvt->dimm_geom[i] = g;
capacity = (d->rken0 + d->rken1) * 8 * (1ul << dimms[g].rowbits) *
(1ul << dimms[g].colbits);
edac_dbg(0, "Channel %d: %lld MByte DIMM\n", i, capacity >> (20 - 3));
dimm->nr_pages = MiB_TO_PAGES(capacity >> (20 - 3));
dimm->grain = 32;
dimm->dtype = (d->dwid == 0) ? DEV_X8 : DEV_X16;
dimm->mtype = MEM_DDR3;
dimm->edac_mode = EDAC_SECDED;
snprintf(dimm->label, sizeof(dimm->label), "Slice#%d_Chan#%d", i / 2, i % 2);
}
}
static const int dnv_dtypes[] = {
DEV_X8, DEV_X4, DEV_X16, DEV_UNKNOWN
};
static void dnv_get_dimm_config(struct mem_ctl_info *mci)
{
int i, j, ranks_of_dimm[DNV_MAX_DIMMS], banks, rowbits, colbits, memtype;
struct dimm_info *dimm;
struct d_cr_drp *d;
u64 capacity;
if (dsch.ddr4en) {
memtype = MEM_DDR4;
banks = 16;
colbits = 10;
} else {
memtype = MEM_DDR3;
banks = 8;
}
for (i = 0; i < DNV_NUM_CHANNELS; i++) {
if (dmap4[i].row14 == 31)
rowbits = 14;
else if (dmap4[i].row15 == 31)
rowbits = 15;
else if (dmap4[i].row16 == 31)
rowbits = 16;
else if (dmap4[i].row17 == 31)
rowbits = 17;
else
rowbits = 18;
if (memtype == MEM_DDR3) {
if (dmap1[i].ca11 != 0x3f)
colbits = 12;
else
colbits = 10;
}
d = &drp[i];
/* DIMM0 is present if rank0 and/or rank1 is enabled */
ranks_of_dimm[0] = d->rken0 + d->rken1;
/* DIMM1 is present if rank2 and/or rank3 is enabled */
ranks_of_dimm[1] = d->rken2 + d->rken3;
for (j = 0; j < DNV_MAX_DIMMS; j++) {
if (!ranks_of_dimm[j])
continue;
dimm = EDAC_DIMM_PTR(mci->layers, mci->dimms, mci->n_layers, i, j, 0);
if (!dimm) {
edac_dbg(0, "No allocated DIMM for channel %d DIMM %d\n", i, j);
continue;
}
capacity = ranks_of_dimm[j] * banks * (1ul << rowbits) * (1ul << colbits);
edac_dbg(0, "Channel %d DIMM %d: %lld MByte DIMM\n", i, j, capacity >> (20 - 3));
dimm->nr_pages = MiB_TO_PAGES(capacity >> (20 - 3));
dimm->grain = 32;
dimm->dtype = dnv_dtypes[j ? d->dimmdwid0 : d->dimmdwid1];
dimm->mtype = memtype;
dimm->edac_mode = EDAC_SECDED;
snprintf(dimm->label, sizeof(dimm->label), "Chan#%d_DIMM#%d", i, j);
}
}
}
static int pnd2_register_mci(struct mem_ctl_info **ppmci)
{
struct edac_mc_layer layers[2];
struct mem_ctl_info *mci;
struct pnd2_pvt *pvt;
int rc;
rc = ops->check_ecc();
if (rc < 0)
return rc;
/* Allocate a new MC control structure */
layers[0].type = EDAC_MC_LAYER_CHANNEL;
layers[0].size = ops->channels;
layers[0].is_virt_csrow = false;
layers[1].type = EDAC_MC_LAYER_SLOT;
layers[1].size = ops->dimms_per_channel;
layers[1].is_virt_csrow = true;
mci = edac_mc_alloc(0, ARRAY_SIZE(layers), layers, sizeof(*pvt));
if (!mci)
return -ENOMEM;
pvt = mci->pvt_info;
memset(pvt, 0, sizeof(*pvt));
mci->mod_name = EDAC_MOD_STR;
mci->dev_name = ops->name;
mci->ctl_name = "Pondicherry2";
/* Get dimm basic config and the memory layout */
ops->get_dimm_config(mci);
if (edac_mc_add_mc(mci)) {
edac_dbg(0, "MC: failed edac_mc_add_mc()\n");
edac_mc_free(mci);
return -EINVAL;
}
*ppmci = mci;
return 0;
}
static void pnd2_unregister_mci(struct mem_ctl_info *mci)
{
if (unlikely(!mci || !mci->pvt_info)) {
pnd2_printk(KERN_ERR, "Couldn't find mci handler\n");
return;
}
/* Remove MC sysfs nodes */
edac_mc_del_mc(NULL);
edac_dbg(1, "%s: free mci struct\n", mci->ctl_name);
edac_mc_free(mci);
}
/*
* Callback function registered with core kernel mce code.
* Called once for each logged error.
*/
static int pnd2_mce_check_error(struct notifier_block *nb, unsigned long val, void *data)
{
struct mce *mce = (struct mce *)data;
struct mem_ctl_info *mci;
struct dram_addr daddr;
char *type;
if (edac_get_report_status() == EDAC_REPORTING_DISABLED)
return NOTIFY_DONE;
mci = pnd2_mci;
if (!mci)
return NOTIFY_DONE;
/*
* Just let mcelog handle it if the error is
* outside the memory controller. A memory error
* is indicated by bit 7 = 1 and bits = 8-11,13-15 = 0.
* bit 12 has an special meaning.
*/
if ((mce->status & 0xefff) >> 7 != 1)
return NOTIFY_DONE;
if (mce->mcgstatus & MCG_STATUS_MCIP)
type = "Exception";
else
type = "Event";
pnd2_mc_printk(mci, KERN_INFO, "HANDLING MCE MEMORY ERROR\n");
pnd2_mc_printk(mci, KERN_INFO, "CPU %u: Machine Check %s: %llx Bank %u: %llx\n",
mce->extcpu, type, mce->mcgstatus, mce->bank, mce->status);
pnd2_mc_printk(mci, KERN_INFO, "TSC %llx ", mce->tsc);
pnd2_mc_printk(mci, KERN_INFO, "ADDR %llx ", mce->addr);
pnd2_mc_printk(mci, KERN_INFO, "MISC %llx ", mce->misc);
pnd2_mc_printk(mci, KERN_INFO, "PROCESSOR %u:%x TIME %llu SOCKET %u APIC %x\n",
mce->cpuvendor, mce->cpuid, mce->time, mce->socketid, mce->apicid);
pnd2_mce_output_error(mci, mce, &daddr);
/* Advice mcelog that the error were handled */
return NOTIFY_STOP;
}
static struct notifier_block pnd2_mce_dec = {
.notifier_call = pnd2_mce_check_error,
};
#ifdef CONFIG_EDAC_DEBUG
/*
* Write an address to this file to exercise the address decode
* logic in this driver.
*/
static u64 pnd2_fake_addr;
#define PND2_BLOB_SIZE 1024
static char pnd2_result[PND2_BLOB_SIZE];
static struct dentry *pnd2_test;
static struct debugfs_blob_wrapper pnd2_blob = {
.data = pnd2_result,
.size = 0
};
static int debugfs_u64_set(void *data, u64 val)
{
struct dram_addr daddr;
struct mce m;
*(u64 *)data = val;
m.mcgstatus = 0;
/* ADDRV + MemRd + Unknown channel */
m.status = MCI_STATUS_ADDRV + 0x9f;
m.addr = val;
pnd2_mce_output_error(pnd2_mci, &m, &daddr);
snprintf(pnd2_blob.data, PND2_BLOB_SIZE,
"SysAddr=%llx Channel=%d DIMM=%d Rank=%d Bank=%d Row=%d Column=%d\n",
m.addr, daddr.chan, daddr.dimm, daddr.rank, daddr.bank, daddr.row, daddr.col);
pnd2_blob.size = strlen(pnd2_blob.data);
return 0;
}
DEFINE_DEBUGFS_ATTRIBUTE(fops_u64_wo, NULL, debugfs_u64_set, "%llu\n");
static void setup_pnd2_debug(void)
{
pnd2_test = edac_debugfs_create_dir("pnd2_test");
edac_debugfs_create_file("pnd2_debug_addr", 0200, pnd2_test,
&pnd2_fake_addr, &fops_u64_wo);
debugfs_create_blob("pnd2_debug_results", 0400, pnd2_test, &pnd2_blob);
}
static void teardown_pnd2_debug(void)
{
debugfs_remove_recursive(pnd2_test);
}
#else
static void setup_pnd2_debug(void) {}
static void teardown_pnd2_debug(void) {}
#endif /* CONFIG_EDAC_DEBUG */
static int pnd2_probe(void)
{
int rc;
edac_dbg(2, "\n");
rc = get_registers();
if (rc)
return rc;
return pnd2_register_mci(&pnd2_mci);
}
static void pnd2_remove(void)
{
edac_dbg(0, "\n");
pnd2_unregister_mci(pnd2_mci);
}
static struct dunit_ops apl_ops = {
.name = "pnd2/apl",
.type = APL,
.pmiaddr_shift = LOG2_PMI_ADDR_GRANULARITY,
.pmiidx_shift = 0,
.channels = APL_NUM_CHANNELS,
.dimms_per_channel = 1,
.rd_reg = apl_rd_reg,
.get_registers = apl_get_registers,
.check_ecc = apl_check_ecc_active,
.mk_region = apl_mk_region,
.get_dimm_config = apl_get_dimm_config,
.pmi2mem = apl_pmi2mem,
};
static struct dunit_ops dnv_ops = {
.name = "pnd2/dnv",
.type = DNV,
.pmiaddr_shift = 0,
.pmiidx_shift = 1,
.channels = DNV_NUM_CHANNELS,
.dimms_per_channel = 2,
.rd_reg = dnv_rd_reg,
.get_registers = dnv_get_registers,
.check_ecc = dnv_check_ecc_active,
.mk_region = dnv_mk_region,
.get_dimm_config = dnv_get_dimm_config,
.pmi2mem = dnv_pmi2mem,
};
static const struct x86_cpu_id pnd2_cpuids[] = {
{ X86_VENDOR_INTEL, 6, INTEL_FAM6_ATOM_GOLDMONT, 0, (kernel_ulong_t)&apl_ops },
{ X86_VENDOR_INTEL, 6, INTEL_FAM6_ATOM_DENVERTON, 0, (kernel_ulong_t)&dnv_ops },
{ }
};
MODULE_DEVICE_TABLE(x86cpu, pnd2_cpuids);
static int __init pnd2_init(void)
{
const struct x86_cpu_id *id;
const char *owner;
int rc;
edac_dbg(2, "\n");
owner = edac_get_owner();
if (owner && strncmp(owner, EDAC_MOD_STR, sizeof(EDAC_MOD_STR)))
return -EBUSY;
id = x86_match_cpu(pnd2_cpuids);
if (!id)
return -ENODEV;
ops = (struct dunit_ops *)id->driver_data;
if (ops->type == APL) {
p2sb_bus = pci_find_bus(0, 0);
if (!p2sb_bus)
return -ENODEV;
}
/* Ensure that the OPSTATE is set correctly for POLL or NMI */
opstate_init();
rc = pnd2_probe();
if (rc < 0) {
pnd2_printk(KERN_ERR, "Failed to register device with error %d.\n", rc);
return rc;
}
if (!pnd2_mci)
return -ENODEV;
mce_register_decode_chain(&pnd2_mce_dec);
setup_pnd2_debug();
return 0;
}
static void __exit pnd2_exit(void)
{
edac_dbg(2, "\n");
teardown_pnd2_debug();
mce_unregister_decode_chain(&pnd2_mce_dec);
pnd2_remove();
}
module_init(pnd2_init);
module_exit(pnd2_exit);
module_param(edac_op_state, int, 0444);
MODULE_PARM_DESC(edac_op_state, "EDAC Error Reporting state: 0=Poll,1=NMI");
MODULE_LICENSE("GPL v2");
MODULE_AUTHOR("Tony Luck");
MODULE_DESCRIPTION("MC Driver for Intel SoC using Pondicherry memory controller");