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linux-next/drivers/edac/pnd2_edac.c
Thomas Gleixner 2025cf9e19 treewide: Replace GPLv2 boilerplate/reference with SPDX - rule 288
Based on 1 normalized pattern(s):

  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

extracted by the scancode license scanner the SPDX license identifier

  GPL-2.0-only

has been chosen to replace the boilerplate/reference in 263 file(s).

Signed-off-by: Thomas Gleixner <tglx@linutronix.de>
Reviewed-by: Allison Randal <allison@lohutok.net>
Reviewed-by: Alexios Zavras <alexios.zavras@intel.com>
Cc: linux-spdx@vger.kernel.org
Link: https://lkml.kernel.org/r/20190529141901.208660670@linutronix.de
Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2019-06-05 17:36:37 +02:00

1600 lines
43 KiB
C

// SPDX-License-Identifier: GPL-2.0-only
/*
* Driver for Pondicherry2 memory controller.
*
* Copyright (c) 2016, Intel Corporation.
*
* [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_GOLDMONT_X, 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");