Merge branch 'linus' of git://git.kernel.org/pub/scm/linux/kernel/git/evalenti/linux...

[platform/kernel/linux-rpi.git] / drivers / edac / i5000_edac.c

/*
 * Intel 5000(P/V/X) class Memory Controllers kernel module
 *
 * This file may be distributed under the terms of the
 * GNU General Public License.
 *
 * Written by Douglas Thompson Linux Networx (http://lnxi.com)
 *      norsk5@xmission.com
 *
 * This module is based on the following document:
 *
 * Intel 5000X Chipset Memory Controller Hub (MCH) - Datasheet
 *      http://developer.intel.com/design/chipsets/datashts/313070.htm
 *
 */

#include <linux/module.h>
#include <linux/init.h>
#include <linux/pci.h>
#include <linux/pci_ids.h>
#include <linux/slab.h>
#include <linux/edac.h>
#include <asm/mmzone.h>

#include "edac_module.h"

/*
 * Alter this version for the I5000 module when modifications are made
 */
#define I5000_REVISION    " Ver: 2.0.12"
#define EDAC_MOD_STR      "i5000_edac"

#define i5000_printk(level, fmt, arg...) \
        edac_printk(level, "i5000", fmt, ##arg)

#define i5000_mc_printk(mci, level, fmt, arg...) \
        edac_mc_chipset_printk(mci, level, "i5000", fmt, ##arg)

#ifndef PCI_DEVICE_ID_INTEL_FBD_0
#define PCI_DEVICE_ID_INTEL_FBD_0       0x25F5
#endif
#ifndef PCI_DEVICE_ID_INTEL_FBD_1
#define PCI_DEVICE_ID_INTEL_FBD_1       0x25F6
#endif

/* Device 16,
 * Function 0: System Address
 * Function 1: Memory Branch Map, Control, Errors Register
 * Function 2: FSB Error Registers
 *
 * All 3 functions of Device 16 (0,1,2) share the SAME DID
 */
#define PCI_DEVICE_ID_INTEL_I5000_DEV16 0x25F0

/* OFFSETS for Function 0 */

/* OFFSETS for Function 1 */
#define         AMBASE                  0x48
#define         MAXCH                   0x56
#define         MAXDIMMPERCH            0x57
#define         TOLM                    0x6C
#define         REDMEMB                 0x7C
#define                 RED_ECC_LOCATOR(x)      ((x) & 0x3FFFF)
#define                 REC_ECC_LOCATOR_EVEN(x) ((x) & 0x001FF)
#define                 REC_ECC_LOCATOR_ODD(x)  ((x) & 0x3FE00)
#define         MIR0                    0x80
#define         MIR1                    0x84
#define         MIR2                    0x88
#define         AMIR0                   0x8C
#define         AMIR1                   0x90
#define         AMIR2                   0x94

#define         FERR_FAT_FBD            0x98
#define         NERR_FAT_FBD            0x9C
#define                 EXTRACT_FBDCHAN_INDX(x) (((x)>>28) & 0x3)
#define                 FERR_FAT_FBDCHAN 0x30000000
#define                 FERR_FAT_M3ERR  0x00000004
#define                 FERR_FAT_M2ERR  0x00000002
#define                 FERR_FAT_M1ERR  0x00000001
#define                 FERR_FAT_MASK   (FERR_FAT_M1ERR | \
                                                FERR_FAT_M2ERR | \
                                                FERR_FAT_M3ERR)

#define         FERR_NF_FBD             0xA0

/* Thermal and SPD or BFD errors */
#define                 FERR_NF_M28ERR  0x01000000
#define                 FERR_NF_M27ERR  0x00800000
#define                 FERR_NF_M26ERR  0x00400000
#define                 FERR_NF_M25ERR  0x00200000
#define                 FERR_NF_M24ERR  0x00100000
#define                 FERR_NF_M23ERR  0x00080000
#define                 FERR_NF_M22ERR  0x00040000
#define                 FERR_NF_M21ERR  0x00020000

/* Correctable errors */
#define                 FERR_NF_M20ERR  0x00010000
#define                 FERR_NF_M19ERR  0x00008000
#define                 FERR_NF_M18ERR  0x00004000
#define                 FERR_NF_M17ERR  0x00002000

/* Non-Retry or redundant Retry errors */
#define                 FERR_NF_M16ERR  0x00001000
#define                 FERR_NF_M15ERR  0x00000800
#define                 FERR_NF_M14ERR  0x00000400
#define                 FERR_NF_M13ERR  0x00000200

/* Uncorrectable errors */
#define                 FERR_NF_M12ERR  0x00000100
#define                 FERR_NF_M11ERR  0x00000080
#define                 FERR_NF_M10ERR  0x00000040
#define                 FERR_NF_M9ERR   0x00000020
#define                 FERR_NF_M8ERR   0x00000010
#define                 FERR_NF_M7ERR   0x00000008
#define                 FERR_NF_M6ERR   0x00000004
#define                 FERR_NF_M5ERR   0x00000002
#define                 FERR_NF_M4ERR   0x00000001

#define                 FERR_NF_UNCORRECTABLE   (FERR_NF_M12ERR | \
                                                        FERR_NF_M11ERR | \
                                                        FERR_NF_M10ERR | \
                                                        FERR_NF_M9ERR | \
                                                        FERR_NF_M8ERR | \
                                                        FERR_NF_M7ERR | \
                                                        FERR_NF_M6ERR | \
                                                        FERR_NF_M5ERR | \
                                                        FERR_NF_M4ERR)
#define                 FERR_NF_CORRECTABLE     (FERR_NF_M20ERR | \
                                                        FERR_NF_M19ERR | \
                                                        FERR_NF_M18ERR | \
                                                        FERR_NF_M17ERR)
#define                 FERR_NF_DIMM_SPARE      (FERR_NF_M27ERR | \
                                                        FERR_NF_M28ERR)
#define                 FERR_NF_THERMAL         (FERR_NF_M26ERR | \
                                                        FERR_NF_M25ERR | \
                                                        FERR_NF_M24ERR | \
                                                        FERR_NF_M23ERR)
#define                 FERR_NF_SPD_PROTOCOL    (FERR_NF_M22ERR)
#define                 FERR_NF_NORTH_CRC       (FERR_NF_M21ERR)
#define                 FERR_NF_NON_RETRY       (FERR_NF_M13ERR | \
                                                        FERR_NF_M14ERR | \
                                                        FERR_NF_M15ERR)

#define         NERR_NF_FBD             0xA4
#define                 FERR_NF_MASK            (FERR_NF_UNCORRECTABLE | \
                                                        FERR_NF_CORRECTABLE | \
                                                        FERR_NF_DIMM_SPARE | \
                                                        FERR_NF_THERMAL | \
                                                        FERR_NF_SPD_PROTOCOL | \
                                                        FERR_NF_NORTH_CRC | \
                                                        FERR_NF_NON_RETRY)

#define         EMASK_FBD               0xA8
#define                 EMASK_FBD_M28ERR        0x08000000
#define                 EMASK_FBD_M27ERR        0x04000000
#define                 EMASK_FBD_M26ERR        0x02000000
#define                 EMASK_FBD_M25ERR        0x01000000
#define                 EMASK_FBD_M24ERR        0x00800000
#define                 EMASK_FBD_M23ERR        0x00400000
#define                 EMASK_FBD_M22ERR        0x00200000
#define                 EMASK_FBD_M21ERR        0x00100000
#define                 EMASK_FBD_M20ERR        0x00080000
#define                 EMASK_FBD_M19ERR        0x00040000
#define                 EMASK_FBD_M18ERR        0x00020000
#define                 EMASK_FBD_M17ERR        0x00010000

#define                 EMASK_FBD_M15ERR        0x00004000
#define                 EMASK_FBD_M14ERR        0x00002000
#define                 EMASK_FBD_M13ERR        0x00001000
#define                 EMASK_FBD_M12ERR        0x00000800
#define                 EMASK_FBD_M11ERR        0x00000400
#define                 EMASK_FBD_M10ERR        0x00000200
#define                 EMASK_FBD_M9ERR         0x00000100
#define                 EMASK_FBD_M8ERR         0x00000080
#define                 EMASK_FBD_M7ERR         0x00000040
#define                 EMASK_FBD_M6ERR         0x00000020
#define                 EMASK_FBD_M5ERR         0x00000010
#define                 EMASK_FBD_M4ERR         0x00000008
#define                 EMASK_FBD_M3ERR         0x00000004
#define                 EMASK_FBD_M2ERR         0x00000002
#define                 EMASK_FBD_M1ERR         0x00000001

#define                 ENABLE_EMASK_FBD_FATAL_ERRORS   (EMASK_FBD_M1ERR | \
                                                        EMASK_FBD_M2ERR | \
                                                        EMASK_FBD_M3ERR)

#define                 ENABLE_EMASK_FBD_UNCORRECTABLE  (EMASK_FBD_M4ERR | \
                                                        EMASK_FBD_M5ERR | \
                                                        EMASK_FBD_M6ERR | \
                                                        EMASK_FBD_M7ERR | \
                                                        EMASK_FBD_M8ERR | \
                                                        EMASK_FBD_M9ERR | \
                                                        EMASK_FBD_M10ERR | \
                                                        EMASK_FBD_M11ERR | \
                                                        EMASK_FBD_M12ERR)
#define                 ENABLE_EMASK_FBD_CORRECTABLE    (EMASK_FBD_M17ERR | \
                                                        EMASK_FBD_M18ERR | \
                                                        EMASK_FBD_M19ERR | \
                                                        EMASK_FBD_M20ERR)
#define                 ENABLE_EMASK_FBD_DIMM_SPARE     (EMASK_FBD_M27ERR | \
                                                        EMASK_FBD_M28ERR)
#define                 ENABLE_EMASK_FBD_THERMALS       (EMASK_FBD_M26ERR | \
                                                        EMASK_FBD_M25ERR | \
                                                        EMASK_FBD_M24ERR | \
                                                        EMASK_FBD_M23ERR)
#define                 ENABLE_EMASK_FBD_SPD_PROTOCOL   (EMASK_FBD_M22ERR)
#define                 ENABLE_EMASK_FBD_NORTH_CRC      (EMASK_FBD_M21ERR)
#define                 ENABLE_EMASK_FBD_NON_RETRY      (EMASK_FBD_M15ERR | \
                                                        EMASK_FBD_M14ERR | \
                                                        EMASK_FBD_M13ERR)

#define         ENABLE_EMASK_ALL        (ENABLE_EMASK_FBD_NON_RETRY | \
                                        ENABLE_EMASK_FBD_NORTH_CRC | \
                                        ENABLE_EMASK_FBD_SPD_PROTOCOL | \
                                        ENABLE_EMASK_FBD_THERMALS | \
                                        ENABLE_EMASK_FBD_DIMM_SPARE | \
                                        ENABLE_EMASK_FBD_FATAL_ERRORS | \
                                        ENABLE_EMASK_FBD_CORRECTABLE | \
                                        ENABLE_EMASK_FBD_UNCORRECTABLE)

#define         ERR0_FBD                0xAC
#define         ERR1_FBD                0xB0
#define         ERR2_FBD                0xB4
#define         MCERR_FBD               0xB8
#define         NRECMEMA                0xBE
#define                 NREC_BANK(x)            (((x)>>12) & 0x7)
#define                 NREC_RDWR(x)            (((x)>>11) & 1)
#define                 NREC_RANK(x)            (((x)>>8) & 0x7)
#define         NRECMEMB                0xC0
#define                 NREC_CAS(x)             (((x)>>16) & 0xFFF)
#define                 NREC_RAS(x)             ((x) & 0x7FFF)
#define         NRECFGLOG               0xC4
#define         NREEECFBDA              0xC8
#define         NREEECFBDB              0xCC
#define         NREEECFBDC              0xD0
#define         NREEECFBDD              0xD4
#define         NREEECFBDE              0xD8
#define         REDMEMA                 0xDC
#define         RECMEMA                 0xE2
#define                 REC_BANK(x)             (((x)>>12) & 0x7)
#define                 REC_RDWR(x)             (((x)>>11) & 1)
#define                 REC_RANK(x)             (((x)>>8) & 0x7)
#define         RECMEMB                 0xE4
#define                 REC_CAS(x)              (((x)>>16) & 0xFFFFFF)
#define                 REC_RAS(x)              ((x) & 0x7FFF)
#define         RECFGLOG                0xE8
#define         RECFBDA                 0xEC
#define         RECFBDB                 0xF0
#define         RECFBDC                 0xF4
#define         RECFBDD                 0xF8
#define         RECFBDE                 0xFC

/* OFFSETS for Function 2 */

/*
 * Device 21,
 * Function 0: Memory Map Branch 0
 *
 * Device 22,
 * Function 0: Memory Map Branch 1
 */
#define PCI_DEVICE_ID_I5000_BRANCH_0    0x25F5
#define PCI_DEVICE_ID_I5000_BRANCH_1    0x25F6

#define AMB_PRESENT_0   0x64
#define AMB_PRESENT_1   0x66
#define MTR0            0x80
#define MTR1            0x84
#define MTR2            0x88
#define MTR3            0x8C

#define NUM_MTRS                4
#define CHANNELS_PER_BRANCH     2
#define MAX_BRANCHES            2

/* Defines to extract the various fields from the
 *      MTRx - Memory Technology Registers
 */
#define MTR_DIMMS_PRESENT(mtr)          ((mtr) & (0x1 << 8))
#define MTR_DRAM_WIDTH(mtr)             ((((mtr) >> 6) & 0x1) ? 8 : 4)
#define MTR_DRAM_BANKS(mtr)             ((((mtr) >> 5) & 0x1) ? 8 : 4)
#define MTR_DRAM_BANKS_ADDR_BITS(mtr)   ((MTR_DRAM_BANKS(mtr) == 8) ? 3 : 2)
#define MTR_DIMM_RANK(mtr)              (((mtr) >> 4) & 0x1)
#define MTR_DIMM_RANK_ADDR_BITS(mtr)    (MTR_DIMM_RANK(mtr) ? 2 : 1)
#define MTR_DIMM_ROWS(mtr)              (((mtr) >> 2) & 0x3)
#define MTR_DIMM_ROWS_ADDR_BITS(mtr)    (MTR_DIMM_ROWS(mtr) + 13)
#define MTR_DIMM_COLS(mtr)              ((mtr) & 0x3)
#define MTR_DIMM_COLS_ADDR_BITS(mtr)    (MTR_DIMM_COLS(mtr) + 10)

/* enables the report of miscellaneous messages as CE errors - default off */
static int misc_messages;

/* Enumeration of supported devices */
enum i5000_chips {
        I5000P = 0,
        I5000V = 1,             /* future */
        I5000X = 2              /* future */
};

/* Device name and register DID (Device ID) */
struct i5000_dev_info {
        const char *ctl_name;   /* name for this device */
        u16 fsb_mapping_errors; /* DID for the branchmap,control */
};

/* Table of devices attributes supported by this driver */
static const struct i5000_dev_info i5000_devs[] = {
        [I5000P] = {
                .ctl_name = "I5000",
                .fsb_mapping_errors = PCI_DEVICE_ID_INTEL_I5000_DEV16,
        },
};

struct i5000_dimm_info {
        int megabytes;          /* size, 0 means not present  */
        int dual_rank;
};

#define MAX_CHANNELS    6       /* max possible channels */
#define MAX_CSROWS      (8*2)   /* max possible csrows per channel */

/* driver private data structure */
struct i5000_pvt {
        struct pci_dev *system_address; /* 16.0 */
        struct pci_dev *branchmap_werrors;      /* 16.1 */
        struct pci_dev *fsb_error_regs; /* 16.2 */
        struct pci_dev *branch_0;       /* 21.0 */
        struct pci_dev *branch_1;       /* 22.0 */

        u16 tolm;               /* top of low memory */
        union {
                u64 ambase;             /* AMB BAR */
                struct {
                        u32 ambase_bottom;
                        u32 ambase_top;
                } u __packed;
        };

        u16 mir0, mir1, mir2;

        u16 b0_mtr[NUM_MTRS];   /* Memory Technlogy Reg */
        u16 b0_ambpresent0;     /* Branch 0, Channel 0 */
        u16 b0_ambpresent1;     /* Brnach 0, Channel 1 */

        u16 b1_mtr[NUM_MTRS];   /* Memory Technlogy Reg */
        u16 b1_ambpresent0;     /* Branch 1, Channel 8 */
        u16 b1_ambpresent1;     /* Branch 1, Channel 1 */

        /* DIMM information matrix, allocating architecture maximums */
        struct i5000_dimm_info dimm_info[MAX_CSROWS][MAX_CHANNELS];

        /* Actual values for this controller */
        int maxch;              /* Max channels */
        int maxdimmperch;       /* Max DIMMs per channel */
};

/* I5000 MCH error information retrieved from Hardware */
struct i5000_error_info {

        /* These registers are always read from the MC */
        u32 ferr_fat_fbd;       /* First Errors Fatal */
        u32 nerr_fat_fbd;       /* Next Errors Fatal */
        u32 ferr_nf_fbd;        /* First Errors Non-Fatal */
        u32 nerr_nf_fbd;        /* Next Errors Non-Fatal */

        /* These registers are input ONLY if there was a Recoverable  Error */
        u32 redmemb;            /* Recoverable Mem Data Error log B */
        u16 recmema;            /* Recoverable Mem Error log A */
        u32 recmemb;            /* Recoverable Mem Error log B */

        /* These registers are input ONLY if there was a
         * Non-Recoverable Error */
        u16 nrecmema;           /* Non-Recoverable Mem log A */
        u32 nrecmemb;           /* Non-Recoverable Mem log B */

};

static struct edac_pci_ctl_info *i5000_pci;

/*
 *      i5000_get_error_info    Retrieve the hardware error information from
 *                              the hardware and cache it in the 'info'
 *                              structure
 */
static void i5000_get_error_info(struct mem_ctl_info *mci,
                                 struct i5000_error_info *info)
{
        struct i5000_pvt *pvt;
        u32 value;

        pvt = mci->pvt_info;

        /* read in the 1st FATAL error register */
        pci_read_config_dword(pvt->branchmap_werrors, FERR_FAT_FBD, &value);

        /* Mask only the bits that the doc says are valid
         */
        value &= (FERR_FAT_FBDCHAN | FERR_FAT_MASK);

        /* If there is an error, then read in the */
        /* NEXT FATAL error register and the Memory Error Log Register A */
        if (value & FERR_FAT_MASK) {
                info->ferr_fat_fbd = value;

                /* harvest the various error data we need */
                pci_read_config_dword(pvt->branchmap_werrors,
                                NERR_FAT_FBD, &info->nerr_fat_fbd);
                pci_read_config_word(pvt->branchmap_werrors,
                                NRECMEMA, &info->nrecmema);
                pci_read_config_dword(pvt->branchmap_werrors,
                                NRECMEMB, &info->nrecmemb);

                /* Clear the error bits, by writing them back */
                pci_write_config_dword(pvt->branchmap_werrors,
                                FERR_FAT_FBD, value);
        } else {
                info->ferr_fat_fbd = 0;
                info->nerr_fat_fbd = 0;
                info->nrecmema = 0;
                info->nrecmemb = 0;
        }

        /* read in the 1st NON-FATAL error register */
        pci_read_config_dword(pvt->branchmap_werrors, FERR_NF_FBD, &value);

        /* If there is an error, then read in the 1st NON-FATAL error
         * register as well */
        if (value & FERR_NF_MASK) {
                info->ferr_nf_fbd = value;

                /* harvest the various error data we need */
                pci_read_config_dword(pvt->branchmap_werrors,
                                NERR_NF_FBD, &info->nerr_nf_fbd);
                pci_read_config_word(pvt->branchmap_werrors,
                                RECMEMA, &info->recmema);
                pci_read_config_dword(pvt->branchmap_werrors,
                                RECMEMB, &info->recmemb);
                pci_read_config_dword(pvt->branchmap_werrors,
                                REDMEMB, &info->redmemb);

                /* Clear the error bits, by writing them back */
                pci_write_config_dword(pvt->branchmap_werrors,
                                FERR_NF_FBD, value);
        } else {
                info->ferr_nf_fbd = 0;
                info->nerr_nf_fbd = 0;
                info->recmema = 0;
                info->recmemb = 0;
                info->redmemb = 0;
        }
}

/*
 * i5000_process_fatal_error_info(struct mem_ctl_info *mci,
 *                                      struct i5000_error_info *info,
 *                                      int handle_errors);
 *
 *      handle the Intel FATAL errors, if any
 */
static void i5000_process_fatal_error_info(struct mem_ctl_info *mci,
                                        struct i5000_error_info *info,
                                        int handle_errors)
{
        char msg[EDAC_MC_LABEL_LEN + 1 + 160];
        char *specific = NULL;
        u32 allErrors;
        int channel;
        int bank;
        int rank;
        int rdwr;
        int ras, cas;

        /* mask off the Error bits that are possible */
        allErrors = (info->ferr_fat_fbd & FERR_FAT_MASK);
        if (!allErrors)
                return;         /* if no error, return now */

        channel = EXTRACT_FBDCHAN_INDX(info->ferr_fat_fbd);

        /* Use the NON-Recoverable macros to extract data */
        bank = NREC_BANK(info->nrecmema);
        rank = NREC_RANK(info->nrecmema);
        rdwr = NREC_RDWR(info->nrecmema);
        ras = NREC_RAS(info->nrecmemb);
        cas = NREC_CAS(info->nrecmemb);

        edac_dbg(0, "\t\tCSROW= %d  Channel= %d (DRAM Bank= %d rdwr= %s ras= %d cas= %d)\n",
                 rank, channel, bank,
                 rdwr ? "Write" : "Read", ras, cas);

        /* Only 1 bit will be on */
        switch (allErrors) {
        case FERR_FAT_M1ERR:
                specific = "Alert on non-redundant retry or fast "
                                "reset timeout";
                break;
        case FERR_FAT_M2ERR:
                specific = "Northbound CRC error on non-redundant "
                                "retry";
                break;
        case FERR_FAT_M3ERR:
                {
                static int done;

                /*
                 * This error is generated to inform that the intelligent
                 * throttling is disabled and the temperature passed the
                 * specified middle point. Since this is something the BIOS
                 * should take care of, we'll warn only once to avoid
                 * worthlessly flooding the log.
                 */
                if (done)
                        return;
                done++;

                specific = ">Tmid Thermal event with intelligent "
                           "throttling disabled";
                }
                break;
        }

        /* Form out message */
        snprintf(msg, sizeof(msg),
                 "Bank=%d RAS=%d CAS=%d FATAL Err=0x%x (%s)",
                 bank, ras, cas, allErrors, specific);

        /* Call the helper to output message */
        edac_mc_handle_error(HW_EVENT_ERR_FATAL, mci, 1, 0, 0, 0,
                             channel >> 1, channel & 1, rank,
                             rdwr ? "Write error" : "Read error",
                             msg);
}

/*
 * i5000_process_fatal_error_info(struct mem_ctl_info *mci,
 *                              struct i5000_error_info *info,
 *                              int handle_errors);
 *
 *      handle the Intel NON-FATAL errors, if any
 */
static void i5000_process_nonfatal_error_info(struct mem_ctl_info *mci,
                                        struct i5000_error_info *info,
                                        int handle_errors)
{
        char msg[EDAC_MC_LABEL_LEN + 1 + 170];
        char *specific = NULL;
        u32 allErrors;
        u32 ue_errors;
        u32 ce_errors;
        u32 misc_errors;
        int branch;
        int channel;
        int bank;
        int rank;
        int rdwr;
        int ras, cas;

        /* mask off the Error bits that are possible */
        allErrors = (info->ferr_nf_fbd & FERR_NF_MASK);
        if (!allErrors)
                return;         /* if no error, return now */

        /* ONLY ONE of the possible error bits will be set, as per the docs */
        ue_errors = allErrors & FERR_NF_UNCORRECTABLE;
        if (ue_errors) {
                edac_dbg(0, "\tUncorrected bits= 0x%x\n", ue_errors);

                branch = EXTRACT_FBDCHAN_INDX(info->ferr_nf_fbd);

                /*
                 * According with i5000 datasheet, bit 28 has no significance
                 * for errors M4Err-M12Err and M17Err-M21Err, on FERR_NF_FBD
                 */
                channel = branch & 2;

                bank = NREC_BANK(info->nrecmema);
                rank = NREC_RANK(info->nrecmema);
                rdwr = NREC_RDWR(info->nrecmema);
                ras = NREC_RAS(info->nrecmemb);
                cas = NREC_CAS(info->nrecmemb);

                edac_dbg(0, "\t\tCSROW= %d  Channels= %d,%d  (Branch= %d DRAM Bank= %d rdwr= %s ras= %d cas= %d)\n",
                         rank, channel, channel + 1, branch >> 1, bank,
                         rdwr ? "Write" : "Read", ras, cas);

                switch (ue_errors) {
                case FERR_NF_M12ERR:
                        specific = "Non-Aliased Uncorrectable Patrol Data ECC";
                        break;
                case FERR_NF_M11ERR:
                        specific = "Non-Aliased Uncorrectable Spare-Copy "
                                        "Data ECC";
                        break;
                case FERR_NF_M10ERR:
                        specific = "Non-Aliased Uncorrectable Mirrored Demand "
                                        "Data ECC";
                        break;
                case FERR_NF_M9ERR:
                        specific = "Non-Aliased Uncorrectable Non-Mirrored "
                                        "Demand Data ECC";
                        break;
                case FERR_NF_M8ERR:
                        specific = "Aliased Uncorrectable Patrol Data ECC";
                        break;
                case FERR_NF_M7ERR:
                        specific = "Aliased Uncorrectable Spare-Copy Data ECC";
                        break;
                case FERR_NF_M6ERR:
                        specific = "Aliased Uncorrectable Mirrored Demand "
                                        "Data ECC";
                        break;
                case FERR_NF_M5ERR:
                        specific = "Aliased Uncorrectable Non-Mirrored Demand "
                                        "Data ECC";
                        break;
                case FERR_NF_M4ERR:
                        specific = "Uncorrectable Data ECC on Replay";
                        break;
                }

                /* Form out message */
                snprintf(msg, sizeof(msg),
                         "Rank=%d Bank=%d RAS=%d CAS=%d, UE Err=0x%x (%s)",
                         rank, bank, ras, cas, ue_errors, specific);

                /* Call the helper to output message */
                edac_mc_handle_error(HW_EVENT_ERR_UNCORRECTED, mci, 1, 0, 0, 0,
                                channel >> 1, -1, rank,
                                rdwr ? "Write error" : "Read error",
                                msg);
        }

        /* Check correctable errors */
        ce_errors = allErrors & FERR_NF_CORRECTABLE;
        if (ce_errors) {
                edac_dbg(0, "\tCorrected bits= 0x%x\n", ce_errors);

                branch = EXTRACT_FBDCHAN_INDX(info->ferr_nf_fbd);

                channel = 0;
                if (REC_ECC_LOCATOR_ODD(info->redmemb))
                        channel = 1;

                /* Convert channel to be based from zero, instead of
                 * from branch base of 0 */
                channel += branch;

                bank = REC_BANK(info->recmema);
                rank = REC_RANK(info->recmema);
                rdwr = REC_RDWR(info->recmema);
                ras = REC_RAS(info->recmemb);
                cas = REC_CAS(info->recmemb);

                edac_dbg(0, "\t\tCSROW= %d Channel= %d  (Branch %d DRAM Bank= %d rdwr= %s ras= %d cas= %d)\n",
                         rank, channel, branch >> 1, bank,
                         rdwr ? "Write" : "Read", ras, cas);

                switch (ce_errors) {
                case FERR_NF_M17ERR:
                        specific = "Correctable Non-Mirrored Demand Data ECC";
                        break;
                case FERR_NF_M18ERR:
                        specific = "Correctable Mirrored Demand Data ECC";
                        break;
                case FERR_NF_M19ERR:
                        specific = "Correctable Spare-Copy Data ECC";
                        break;
                case FERR_NF_M20ERR:
                        specific = "Correctable Patrol Data ECC";
                        break;
                }

                /* Form out message */
                snprintf(msg, sizeof(msg),
                         "Rank=%d Bank=%d RDWR=%s RAS=%d "
                         "CAS=%d, CE Err=0x%x (%s))", branch >> 1, bank,
                         rdwr ? "Write" : "Read", ras, cas, ce_errors,
                         specific);

                /* Call the helper to output message */
                edac_mc_handle_error(HW_EVENT_ERR_CORRECTED, mci, 1, 0, 0, 0,
                                channel >> 1, channel % 2, rank,
                                rdwr ? "Write error" : "Read error",
                                msg);
        }

        if (!misc_messages)
                return;

        misc_errors = allErrors & (FERR_NF_NON_RETRY | FERR_NF_NORTH_CRC |
                                   FERR_NF_SPD_PROTOCOL | FERR_NF_DIMM_SPARE);
        if (misc_errors) {
                switch (misc_errors) {
                case FERR_NF_M13ERR:
                        specific = "Non-Retry or Redundant Retry FBD Memory "
                                        "Alert or Redundant Fast Reset Timeout";
                        break;
                case FERR_NF_M14ERR:
                        specific = "Non-Retry or Redundant Retry FBD "
                                        "Configuration Alert";
                        break;
                case FERR_NF_M15ERR:
                        specific = "Non-Retry or Redundant Retry FBD "
                                        "Northbound CRC error on read data";
                        break;
                case FERR_NF_M21ERR:
                        specific = "FBD Northbound CRC error on "
                                        "FBD Sync Status";
                        break;
                case FERR_NF_M22ERR:
                        specific = "SPD protocol error";
                        break;
                case FERR_NF_M27ERR:
                        specific = "DIMM-spare copy started";
                        break;
                case FERR_NF_M28ERR:
                        specific = "DIMM-spare copy completed";
                        break;
                }
                branch = EXTRACT_FBDCHAN_INDX(info->ferr_nf_fbd);

                /* Form out message */
                snprintf(msg, sizeof(msg),
                         "Err=%#x (%s)", misc_errors, specific);

                /* Call the helper to output message */
                edac_mc_handle_error(HW_EVENT_ERR_CORRECTED, mci, 1, 0, 0, 0,
                                branch >> 1, -1, -1,
                                "Misc error", msg);
        }
}

/*
 *      i5000_process_error_info        Process the error info that is
 *      in the 'info' structure, previously retrieved from hardware
 */
static void i5000_process_error_info(struct mem_ctl_info *mci,
                                struct i5000_error_info *info,
                                int handle_errors)
{
        /* First handle any fatal errors that occurred */
        i5000_process_fatal_error_info(mci, info, handle_errors);

        /* now handle any non-fatal errors that occurred */
        i5000_process_nonfatal_error_info(mci, info, handle_errors);
}

/*
 *      i5000_clear_error       Retrieve any error from the hardware
 *                              but do NOT process that error.
 *                              Used for 'clearing' out of previous errors
 *                              Called by the Core module.
 */
static void i5000_clear_error(struct mem_ctl_info *mci)
{
        struct i5000_error_info info;

        i5000_get_error_info(mci, &info);
}

/*
 *      i5000_check_error       Retrieve and process errors reported by the
 *                              hardware. Called by the Core module.
 */
static void i5000_check_error(struct mem_ctl_info *mci)
{
        struct i5000_error_info info;
        edac_dbg(4, "MC%d\n", mci->mc_idx);
        i5000_get_error_info(mci, &info);
        i5000_process_error_info(mci, &info, 1);
}

/*
 *      i5000_get_devices       Find and perform 'get' operation on the MCH's
 *                      device/functions we want to reference for this driver
 *
 *                      Need to 'get' device 16 func 1 and func 2
 */
static int i5000_get_devices(struct mem_ctl_info *mci, int dev_idx)
{
        //const struct i5000_dev_info *i5000_dev = &i5000_devs[dev_idx];
        struct i5000_pvt *pvt;
        struct pci_dev *pdev;

        pvt = mci->pvt_info;

        /* Attempt to 'get' the MCH register we want */
        pdev = NULL;
        while (1) {
                pdev = pci_get_device(PCI_VENDOR_ID_INTEL,
                                PCI_DEVICE_ID_INTEL_I5000_DEV16, pdev);

                /* End of list, leave */
                if (pdev == NULL) {
                        i5000_printk(KERN_ERR,
                                "'system address,Process Bus' "
                                "device not found:"
                                "vendor 0x%x device 0x%x FUNC 1 "
                                "(broken BIOS?)\n",
                                PCI_VENDOR_ID_INTEL,
                                PCI_DEVICE_ID_INTEL_I5000_DEV16);

                        return 1;
                }

                /* Scan for device 16 func 1 */
                if (PCI_FUNC(pdev->devfn) == 1)
                        break;
        }

        pvt->branchmap_werrors = pdev;

        /* Attempt to 'get' the MCH register we want */
        pdev = NULL;
        while (1) {
                pdev = pci_get_device(PCI_VENDOR_ID_INTEL,
                                PCI_DEVICE_ID_INTEL_I5000_DEV16, pdev);

                if (pdev == NULL) {
                        i5000_printk(KERN_ERR,
                                "MC: 'branchmap,control,errors' "
                                "device not found:"
                                "vendor 0x%x device 0x%x Func 2 "
                                "(broken BIOS?)\n",
                                PCI_VENDOR_ID_INTEL,
                                PCI_DEVICE_ID_INTEL_I5000_DEV16);

                        pci_dev_put(pvt->branchmap_werrors);
                        return 1;
                }

                /* Scan for device 16 func 1 */
                if (PCI_FUNC(pdev->devfn) == 2)
                        break;
        }

        pvt->fsb_error_regs = pdev;

        edac_dbg(1, "System Address, processor bus- PCI Bus ID: %s  %x:%x\n",
                 pci_name(pvt->system_address),
                 pvt->system_address->vendor, pvt->system_address->device);
        edac_dbg(1, "Branchmap, control and errors - PCI Bus ID: %s  %x:%x\n",
                 pci_name(pvt->branchmap_werrors),
                 pvt->branchmap_werrors->vendor,
                 pvt->branchmap_werrors->device);
        edac_dbg(1, "FSB Error Regs - PCI Bus ID: %s  %x:%x\n",
                 pci_name(pvt->fsb_error_regs),
                 pvt->fsb_error_regs->vendor, pvt->fsb_error_regs->device);

        pdev = NULL;
        pdev = pci_get_device(PCI_VENDOR_ID_INTEL,
                        PCI_DEVICE_ID_I5000_BRANCH_0, pdev);

        if (pdev == NULL) {
                i5000_printk(KERN_ERR,
                        "MC: 'BRANCH 0' device not found:"
                        "vendor 0x%x device 0x%x Func 0 (broken BIOS?)\n",
                        PCI_VENDOR_ID_INTEL, PCI_DEVICE_ID_I5000_BRANCH_0);

                pci_dev_put(pvt->branchmap_werrors);
                pci_dev_put(pvt->fsb_error_regs);
                return 1;
        }

        pvt->branch_0 = pdev;

        /* If this device claims to have more than 2 channels then
         * fetch Branch 1's information
         */
        if (pvt->maxch >= CHANNELS_PER_BRANCH) {
                pdev = NULL;
                pdev = pci_get_device(PCI_VENDOR_ID_INTEL,
                                PCI_DEVICE_ID_I5000_BRANCH_1, pdev);

                if (pdev == NULL) {
                        i5000_printk(KERN_ERR,
                                "MC: 'BRANCH 1' device not found:"
                                "vendor 0x%x device 0x%x Func 0 "
                                "(broken BIOS?)\n",
                                PCI_VENDOR_ID_INTEL,
                                PCI_DEVICE_ID_I5000_BRANCH_1);

                        pci_dev_put(pvt->branchmap_werrors);
                        pci_dev_put(pvt->fsb_error_regs);
                        pci_dev_put(pvt->branch_0);
                        return 1;
                }

                pvt->branch_1 = pdev;
        }

        return 0;
}

/*
 *      i5000_put_devices       'put' all the devices that we have
 *                              reserved via 'get'
 */
static void i5000_put_devices(struct mem_ctl_info *mci)
{
        struct i5000_pvt *pvt;

        pvt = mci->pvt_info;

        pci_dev_put(pvt->branchmap_werrors);    /* FUNC 1 */
        pci_dev_put(pvt->fsb_error_regs);       /* FUNC 2 */
        pci_dev_put(pvt->branch_0);     /* DEV 21 */

        /* Only if more than 2 channels do we release the second branch */
        if (pvt->maxch >= CHANNELS_PER_BRANCH)
                pci_dev_put(pvt->branch_1);     /* DEV 22 */
}

/*
 *      determine_amb_resent
 *
 *              the information is contained in NUM_MTRS different registers
 *              determineing which of the NUM_MTRS requires knowing
 *              which channel is in question
 *
 *      2 branches, each with 2 channels
 *              b0_ambpresent0 for channel '0'
 *              b0_ambpresent1 for channel '1'
 *              b1_ambpresent0 for channel '2'
 *              b1_ambpresent1 for channel '3'
 */
static int determine_amb_present_reg(struct i5000_pvt *pvt, int channel)
{
        int amb_present;

        if (channel < CHANNELS_PER_BRANCH) {
                if (channel & 0x1)
                        amb_present = pvt->b0_ambpresent1;
                else
                        amb_present = pvt->b0_ambpresent0;
        } else {
                if (channel & 0x1)
                        amb_present = pvt->b1_ambpresent1;
                else
                        amb_present = pvt->b1_ambpresent0;
        }

        return amb_present;
}

/*
 * determine_mtr(pvt, csrow, channel)
 *
 *      return the proper MTR register as determine by the csrow and channel desired
 */
static int determine_mtr(struct i5000_pvt *pvt, int slot, int channel)
{
        int mtr;

        if (channel < CHANNELS_PER_BRANCH)
                mtr = pvt->b0_mtr[slot];
        else
                mtr = pvt->b1_mtr[slot];

        return mtr;
}

/*
 */
static void decode_mtr(int slot_row, u16 mtr)
{
        int ans;

        ans = MTR_DIMMS_PRESENT(mtr);

        edac_dbg(2, "\tMTR%d=0x%x:  DIMMs are %sPresent\n",
                 slot_row, mtr, ans ? "" : "NOT ");
        if (!ans)
                return;

        edac_dbg(2, "\t\tWIDTH: x%d\n", MTR_DRAM_WIDTH(mtr));
        edac_dbg(2, "\t\tNUMBANK: %d bank(s)\n", MTR_DRAM_BANKS(mtr));
        edac_dbg(2, "\t\tNUMRANK: %s\n",
                 MTR_DIMM_RANK(mtr) ? "double" : "single");
        edac_dbg(2, "\t\tNUMROW: %s\n",
                 MTR_DIMM_ROWS(mtr) == 0 ? "8,192 - 13 rows" :
                 MTR_DIMM_ROWS(mtr) == 1 ? "16,384 - 14 rows" :
                 MTR_DIMM_ROWS(mtr) == 2 ? "32,768 - 15 rows" :
                 "reserved");
        edac_dbg(2, "\t\tNUMCOL: %s\n",
                 MTR_DIMM_COLS(mtr) == 0 ? "1,024 - 10 columns" :
                 MTR_DIMM_COLS(mtr) == 1 ? "2,048 - 11 columns" :
                 MTR_DIMM_COLS(mtr) == 2 ? "4,096 - 12 columns" :
                 "reserved");
}

static void handle_channel(struct i5000_pvt *pvt, int slot, int channel,
                        struct i5000_dimm_info *dinfo)
{
        int mtr;
        int amb_present_reg;
        int addrBits;

        mtr = determine_mtr(pvt, slot, channel);
        if (MTR_DIMMS_PRESENT(mtr)) {
                amb_present_reg = determine_amb_present_reg(pvt, channel);

                /* Determine if there is a DIMM present in this DIMM slot */
                if (amb_present_reg) {
                        dinfo->dual_rank = MTR_DIMM_RANK(mtr);

                        /* Start with the number of bits for a Bank
                                * on the DRAM */
                        addrBits = MTR_DRAM_BANKS_ADDR_BITS(mtr);
                        /* Add the number of ROW bits */
                        addrBits += MTR_DIMM_ROWS_ADDR_BITS(mtr);
                        /* add the number of COLUMN bits */
                        addrBits += MTR_DIMM_COLS_ADDR_BITS(mtr);

                        /* Dual-rank memories have twice the size */
                        if (dinfo->dual_rank)
                                addrBits++;

                        addrBits += 6;  /* add 64 bits per DIMM */
                        addrBits -= 20; /* divide by 2^^20 */
                        addrBits -= 3;  /* 8 bits per bytes */

                        dinfo->megabytes = 1 << addrBits;
                }
        }
}

/*
 *      calculate_dimm_size
 *
 *      also will output a DIMM matrix map, if debug is enabled, for viewing
 *      how the DIMMs are populated
 */
static void calculate_dimm_size(struct i5000_pvt *pvt)
{
        struct i5000_dimm_info *dinfo;
        int slot, channel, branch;
        char *p, *mem_buffer;
        int space, n;

        /* ================= Generate some debug output ================= */
        space = PAGE_SIZE;
        mem_buffer = p = kmalloc(space, GFP_KERNEL);
        if (p == NULL) {
                i5000_printk(KERN_ERR, "MC: %s:%s() kmalloc() failed\n",
                        __FILE__, __func__);
                return;
        }

        /* Scan all the actual slots
         * and calculate the information for each DIMM
         * Start with the highest slot first, to display it first
         * and work toward the 0th slot
         */
        for (slot = pvt->maxdimmperch - 1; slot >= 0; slot--) {

                /* on an odd slot, first output a 'boundary' marker,
                 * then reset the message buffer  */
                if (slot & 0x1) {
                        n = snprintf(p, space, "--------------------------"
                                "--------------------------------");
                        p += n;
                        space -= n;
                        edac_dbg(2, "%s\n", mem_buffer);
                        p = mem_buffer;
                        space = PAGE_SIZE;
                }
                n = snprintf(p, space, "slot %2d    ", slot);
                p += n;
                space -= n;

                for (channel = 0; channel < pvt->maxch; channel++) {
                        dinfo = &pvt->dimm_info[slot][channel];
                        handle_channel(pvt, slot, channel, dinfo);
                        if (dinfo->megabytes)
                                n = snprintf(p, space, "%4d MB %dR| ",
                                             dinfo->megabytes, dinfo->dual_rank + 1);
                        else
                                n = snprintf(p, space, "%4d MB   | ", 0);
                        p += n;
                        space -= n;
                }
                p += n;
                space -= n;
                edac_dbg(2, "%s\n", mem_buffer);
                p = mem_buffer;
                space = PAGE_SIZE;
        }

        /* Output the last bottom 'boundary' marker */
        n = snprintf(p, space, "--------------------------"
                "--------------------------------");
        p += n;
        space -= n;
        edac_dbg(2, "%s\n", mem_buffer);
        p = mem_buffer;
        space = PAGE_SIZE;

        /* now output the 'channel' labels */
        n = snprintf(p, space, "           ");
        p += n;
        space -= n;
        for (channel = 0; channel < pvt->maxch; channel++) {
                n = snprintf(p, space, "channel %d | ", channel);
                p += n;
                space -= n;
        }
        edac_dbg(2, "%s\n", mem_buffer);
        p = mem_buffer;
        space = PAGE_SIZE;

        n = snprintf(p, space, "           ");
        p += n;
        for (branch = 0; branch < MAX_BRANCHES; branch++) {
                n = snprintf(p, space, "       branch %d       | ", branch);
                p += n;
                space -= n;
        }

        /* output the last message and free buffer */
        edac_dbg(2, "%s\n", mem_buffer);
        kfree(mem_buffer);
}

/*
 *      i5000_get_mc_regs       read in the necessary registers and
 *                              cache locally
 *
 *                      Fills in the private data members
 */
static void i5000_get_mc_regs(struct mem_ctl_info *mci)
{
        struct i5000_pvt *pvt;
        u32 actual_tolm;
        u16 limit;
        int slot_row;
        int way0, way1;

        pvt = mci->pvt_info;

        pci_read_config_dword(pvt->system_address, AMBASE,
                        &pvt->u.ambase_bottom);
        pci_read_config_dword(pvt->system_address, AMBASE + sizeof(u32),
                        &pvt->u.ambase_top);

        edac_dbg(2, "AMBASE= 0x%lx  MAXCH= %d  MAX-DIMM-Per-CH= %d\n",
                 (long unsigned int)pvt->ambase, pvt->maxch, pvt->maxdimmperch);

        /* Get the Branch Map regs */
        pci_read_config_word(pvt->branchmap_werrors, TOLM, &pvt->tolm);
        pvt->tolm >>= 12;
        edac_dbg(2, "TOLM (number of 256M regions) =%u (0x%x)\n",
                 pvt->tolm, pvt->tolm);

        actual_tolm = pvt->tolm << 28;
        edac_dbg(2, "Actual TOLM byte addr=%u (0x%x)\n",
                 actual_tolm, actual_tolm);

        pci_read_config_word(pvt->branchmap_werrors, MIR0, &pvt->mir0);
        pci_read_config_word(pvt->branchmap_werrors, MIR1, &pvt->mir1);
        pci_read_config_word(pvt->branchmap_werrors, MIR2, &pvt->mir2);

        /* Get the MIR[0-2] regs */
        limit = (pvt->mir0 >> 4) & 0x0FFF;
        way0 = pvt->mir0 & 0x1;
        way1 = pvt->mir0 & 0x2;
        edac_dbg(2, "MIR0: limit= 0x%x  WAY1= %u  WAY0= %x\n",
                 limit, way1, way0);
        limit = (pvt->mir1 >> 4) & 0x0FFF;
        way0 = pvt->mir1 & 0x1;
        way1 = pvt->mir1 & 0x2;
        edac_dbg(2, "MIR1: limit= 0x%x  WAY1= %u  WAY0= %x\n",
                 limit, way1, way0);
        limit = (pvt->mir2 >> 4) & 0x0FFF;
        way0 = pvt->mir2 & 0x1;
        way1 = pvt->mir2 & 0x2;
        edac_dbg(2, "MIR2: limit= 0x%x  WAY1= %u  WAY0= %x\n",
                 limit, way1, way0);

        /* Get the MTR[0-3] regs */
        for (slot_row = 0; slot_row < NUM_MTRS; slot_row++) {
                int where = MTR0 + (slot_row * sizeof(u32));

                pci_read_config_word(pvt->branch_0, where,
                                &pvt->b0_mtr[slot_row]);

                edac_dbg(2, "MTR%d where=0x%x B0 value=0x%x\n",
                         slot_row, where, pvt->b0_mtr[slot_row]);

                if (pvt->maxch >= CHANNELS_PER_BRANCH) {
                        pci_read_config_word(pvt->branch_1, where,
                                        &pvt->b1_mtr[slot_row]);
                        edac_dbg(2, "MTR%d where=0x%x B1 value=0x%x\n",
                                 slot_row, where, pvt->b1_mtr[slot_row]);
                } else {
                        pvt->b1_mtr[slot_row] = 0;
                }
        }

        /* Read and dump branch 0's MTRs */
        edac_dbg(2, "Memory Technology Registers:\n");
        edac_dbg(2, "   Branch 0:\n");
        for (slot_row = 0; slot_row < NUM_MTRS; slot_row++) {
                decode_mtr(slot_row, pvt->b0_mtr[slot_row]);
        }
        pci_read_config_word(pvt->branch_0, AMB_PRESENT_0,
                        &pvt->b0_ambpresent0);
        edac_dbg(2, "\t\tAMB-Branch 0-present0 0x%x:\n", pvt->b0_ambpresent0);
        pci_read_config_word(pvt->branch_0, AMB_PRESENT_1,
                        &pvt->b0_ambpresent1);
        edac_dbg(2, "\t\tAMB-Branch 0-present1 0x%x:\n", pvt->b0_ambpresent1);

        /* Only if we have 2 branchs (4 channels) */
        if (pvt->maxch < CHANNELS_PER_BRANCH) {
                pvt->b1_ambpresent0 = 0;
                pvt->b1_ambpresent1 = 0;
        } else {
                /* Read and dump  branch 1's MTRs */
                edac_dbg(2, "   Branch 1:\n");
                for (slot_row = 0; slot_row < NUM_MTRS; slot_row++) {
                        decode_mtr(slot_row, pvt->b1_mtr[slot_row]);
                }
                pci_read_config_word(pvt->branch_1, AMB_PRESENT_0,
                                &pvt->b1_ambpresent0);
                edac_dbg(2, "\t\tAMB-Branch 1-present0 0x%x:\n",
                         pvt->b1_ambpresent0);
                pci_read_config_word(pvt->branch_1, AMB_PRESENT_1,
                                &pvt->b1_ambpresent1);
                edac_dbg(2, "\t\tAMB-Branch 1-present1 0x%x:\n",
                         pvt->b1_ambpresent1);
        }

        /* Go and determine the size of each DIMM and place in an
         * orderly matrix */
        calculate_dimm_size(pvt);
}

/*
 *      i5000_init_csrows       Initialize the 'csrows' table within
 *                              the mci control structure with the
 *                              addressing of memory.
 *
 *      return:
 *              0       success
 *              1       no actual memory found on this MC
 */
static int i5000_init_csrows(struct mem_ctl_info *mci)
{
        struct i5000_pvt *pvt;
        struct dimm_info *dimm;
        int empty;
        int max_csrows;
        int mtr;
        int csrow_megs;
        int channel;
        int slot;

        pvt = mci->pvt_info;
        max_csrows = pvt->maxdimmperch * 2;

        empty = 1;              /* Assume NO memory */

        /*
         * FIXME: The memory layout used to map slot/channel into the
         * real memory architecture is weird: branch+slot are "csrows"
         * and channel is channel. That required an extra array (dimm_info)
         * to map the dimms. A good cleanup would be to remove this array,
         * and do a loop here with branch, channel, slot
         */
        for (slot = 0; slot < max_csrows; slot++) {
                for (channel = 0; channel < pvt->maxch; channel++) {

                        mtr = determine_mtr(pvt, slot, channel);

                        if (!MTR_DIMMS_PRESENT(mtr))
                                continue;

                        dimm = EDAC_DIMM_PTR(mci->layers, mci->dimms, mci->n_layers,
                                       channel / MAX_BRANCHES,
                                       channel % MAX_BRANCHES, slot);

                        csrow_megs = pvt->dimm_info[slot][channel].megabytes;
                        dimm->grain = 8;

                        /* Assume DDR2 for now */
                        dimm->mtype = MEM_FB_DDR2;

                        /* ask what device type on this row */
                        if (MTR_DRAM_WIDTH(mtr) == 8)
                                dimm->dtype = DEV_X8;
                        else
                                dimm->dtype = DEV_X4;

                        dimm->edac_mode = EDAC_S8ECD8ED;
                        dimm->nr_pages = csrow_megs << 8;
                }

                empty = 0;
        }

        return empty;
}

/*
 *      i5000_enable_error_reporting
 *                      Turn on the memory reporting features of the hardware
 */
static void i5000_enable_error_reporting(struct mem_ctl_info *mci)
{
        struct i5000_pvt *pvt;
        u32 fbd_error_mask;

        pvt = mci->pvt_info;

        /* Read the FBD Error Mask Register */
        pci_read_config_dword(pvt->branchmap_werrors, EMASK_FBD,
                        &fbd_error_mask);

        /* Enable with a '0' */
        fbd_error_mask &= ~(ENABLE_EMASK_ALL);

        pci_write_config_dword(pvt->branchmap_werrors, EMASK_FBD,
                        fbd_error_mask);
}

/*
 * i5000_get_dimm_and_channel_counts(pdev, &nr_csrows, &num_channels)
 *
 *      ask the device how many channels are present and how many CSROWS
 *       as well
 */
static void i5000_get_dimm_and_channel_counts(struct pci_dev *pdev,
                                        int *num_dimms_per_channel,
                                        int *num_channels)
{
        u8 value;

        /* Need to retrieve just how many channels and dimms per channel are
         * supported on this memory controller
         */
        pci_read_config_byte(pdev, MAXDIMMPERCH, &value);
        *num_dimms_per_channel = (int)value;

        pci_read_config_byte(pdev, MAXCH, &value);
        *num_channels = (int)value;
}

/*
 *      i5000_probe1    Probe for ONE instance of device to see if it is
 *                      present.
 *      return:
 *              0 for FOUND a device
 *              < 0 for error code
 */
static int i5000_probe1(struct pci_dev *pdev, int dev_idx)
{
        struct mem_ctl_info *mci;
        struct edac_mc_layer layers[3];
        struct i5000_pvt *pvt;
        int num_channels;
        int num_dimms_per_channel;

        edac_dbg(0, "MC: pdev bus %u dev=0x%x fn=0x%x\n",
                 pdev->bus->number,
                 PCI_SLOT(pdev->devfn), PCI_FUNC(pdev->devfn));

        /* We only are looking for func 0 of the set */
        if (PCI_FUNC(pdev->devfn) != 0)
                return -ENODEV;

        /* Ask the devices for the number of CSROWS and CHANNELS so
         * that we can calculate the memory resources, etc
         *
         * The Chipset will report what it can handle which will be greater
         * or equal to what the motherboard manufacturer will implement.
         *
         * As we don't have a motherboard identification routine to determine
         * actual number of slots/dimms per channel, we thus utilize the
         * resource as specified by the chipset. Thus, we might have
         * have more DIMMs per channel than actually on the mobo, but this
         * allows the driver to support up to the chipset max, without
         * some fancy mobo determination.
         */
        i5000_get_dimm_and_channel_counts(pdev, &num_dimms_per_channel,
                                        &num_channels);

        edac_dbg(0, "MC: Number of Branches=2 Channels= %d  DIMMS= %d\n",
                 num_channels, num_dimms_per_channel);

        /* allocate a new MC control structure */

        layers[0].type = EDAC_MC_LAYER_BRANCH;
        layers[0].size = MAX_BRANCHES;
        layers[0].is_virt_csrow = false;
        layers[1].type = EDAC_MC_LAYER_CHANNEL;
        layers[1].size = num_channels / MAX_BRANCHES;
        layers[1].is_virt_csrow = false;
        layers[2].type = EDAC_MC_LAYER_SLOT;
        layers[2].size = num_dimms_per_channel;
        layers[2].is_virt_csrow = true;
        mci = edac_mc_alloc(0, ARRAY_SIZE(layers), layers, sizeof(*pvt));
        if (mci == NULL)
                return -ENOMEM;

        edac_dbg(0, "MC: mci = %p\n", mci);

        mci->pdev = &pdev->dev; /* record ptr  to the generic device */

        pvt = mci->pvt_info;
        pvt->system_address = pdev;     /* Record this device in our private */
        pvt->maxch = num_channels;
        pvt->maxdimmperch = num_dimms_per_channel;

        /* 'get' the pci devices we want to reserve for our use */
        if (i5000_get_devices(mci, dev_idx))
                goto fail0;

        /* Time to get serious */
        i5000_get_mc_regs(mci); /* retrieve the hardware registers */

        mci->mc_idx = 0;
        mci->mtype_cap = MEM_FLAG_FB_DDR2;
        mci->edac_ctl_cap = EDAC_FLAG_NONE;
        mci->edac_cap = EDAC_FLAG_NONE;
        mci->mod_name = "i5000_edac.c";
        mci->ctl_name = i5000_devs[dev_idx].ctl_name;
        mci->dev_name = pci_name(pdev);
        mci->ctl_page_to_phys = NULL;

        /* Set the function pointer to an actual operation function */
        mci->edac_check = i5000_check_error;

        /* initialize the MC control structure 'csrows' table
         * with the mapping and control information */
        if (i5000_init_csrows(mci)) {
                edac_dbg(0, "MC: Setting mci->edac_cap to EDAC_FLAG_NONE because i5000_init_csrows() returned nonzero value\n");
                mci->edac_cap = EDAC_FLAG_NONE; /* no csrows found */
        } else {
                edac_dbg(1, "MC: Enable error reporting now\n");
                i5000_enable_error_reporting(mci);
        }

        /* add this new MC control structure to EDAC's list of MCs */
        if (edac_mc_add_mc(mci)) {
                edac_dbg(0, "MC: failed edac_mc_add_mc()\n");
                /* FIXME: perhaps some code should go here that disables error
                 * reporting if we just enabled it
                 */
                goto fail1;
        }

        i5000_clear_error(mci);

        /* allocating generic PCI control info */
        i5000_pci = edac_pci_create_generic_ctl(&pdev->dev, EDAC_MOD_STR);
        if (!i5000_pci) {
                printk(KERN_WARNING
                        "%s(): Unable to create PCI control\n",
                        __func__);
                printk(KERN_WARNING
                        "%s(): PCI error report via EDAC not setup\n",
                        __func__);
        }

        return 0;

        /* Error exit unwinding stack */
fail1:

        i5000_put_devices(mci);

fail0:
        edac_mc_free(mci);
        return -ENODEV;
}

/*
 *      i5000_init_one  constructor for one instance of device
 *
 *      returns:
 *              negative on error
 *              count (>= 0)
 */
static int i5000_init_one(struct pci_dev *pdev, const struct pci_device_id *id)
{
        int rc;

        edac_dbg(0, "MC:\n");

        /* wake up device */
        rc = pci_enable_device(pdev);
        if (rc)
                return rc;

        /* now probe and enable the device */
        return i5000_probe1(pdev, id->driver_data);
}

/*
 *      i5000_remove_one        destructor for one instance of device
 *
 */
static void i5000_remove_one(struct pci_dev *pdev)
{
        struct mem_ctl_info *mci;

        edac_dbg(0, "\n");

        if (i5000_pci)
                edac_pci_release_generic_ctl(i5000_pci);

        if ((mci = edac_mc_del_mc(&pdev->dev)) == NULL)
                return;

        /* retrieve references to resources, and free those resources */
        i5000_put_devices(mci);
        edac_mc_free(mci);
}

/*
 *      pci_device_id   table for which devices we are looking for
 *
 *      The "E500P" device is the first device supported.
 */
static const struct pci_device_id i5000_pci_tbl[] = {
        {PCI_DEVICE(PCI_VENDOR_ID_INTEL, PCI_DEVICE_ID_INTEL_I5000_DEV16),
         .driver_data = I5000P},

        {0,}                    /* 0 terminated list. */
};

MODULE_DEVICE_TABLE(pci, i5000_pci_tbl);

/*
 *      i5000_driver    pci_driver structure for this module
 *
 */
static struct pci_driver i5000_driver = {
        .name = KBUILD_BASENAME,
        .probe = i5000_init_one,
        .remove = i5000_remove_one,
        .id_table = i5000_pci_tbl,
};

/*
 *      i5000_init              Module entry function
 *                      Try to initialize this module for its devices
 */
static int __init i5000_init(void)
{
        int pci_rc;

        edac_dbg(2, "MC:\n");

        /* Ensure that the OPSTATE is set correctly for POLL or NMI */
        opstate_init();

        pci_rc = pci_register_driver(&i5000_driver);

        return (pci_rc < 0) ? pci_rc : 0;
}

/*
 *      i5000_exit()    Module exit function
 *                      Unregister the driver
 */
static void __exit i5000_exit(void)
{
        edac_dbg(2, "MC:\n");
        pci_unregister_driver(&i5000_driver);
}

module_init(i5000_init);
module_exit(i5000_exit);

MODULE_LICENSE("GPL");
MODULE_AUTHOR
    ("Linux Networx (http://lnxi.com) Doug Thompson <norsk5@xmission.com>");
MODULE_DESCRIPTION("MC Driver for Intel I5000 memory controllers - "
                I5000_REVISION);

module_param(edac_op_state, int, 0444);
MODULE_PARM_DESC(edac_op_state, "EDAC Error Reporting state: 0=Poll,1=NMI");
module_param(misc_messages, int, 0444);
MODULE_PARM_DESC(misc_messages, "Log miscellaneous non fatal messages");