[POWERPC] Fix PCI IRQ fallback code to not map IRQ 0

[deliverable/linux.git] / arch / powerpc / kernel / align.c

/* align.c - handle alignment exceptions for the Power PC.
 *
 * Copyright (c) 1996 Paul Mackerras <paulus@cs.anu.edu.au>
 * Copyright (c) 1998-1999 TiVo, Inc.
 *   PowerPC 403GCX modifications.
 * Copyright (c) 1999 Grant Erickson <grant@lcse.umn.edu>
 *   PowerPC 403GCX/405GP modifications.
 * Copyright (c) 2001-2002 PPC64 team, IBM Corp
 *   64-bit and Power4 support
 * Copyright (c) 2005 Benjamin Herrenschmidt, IBM Corp
 *                    <benh@kernel.crashing.org>
 *   Merge ppc32 and ppc64 implementations
 *
 * This program is free software; you can redistribute it and/or
 * modify it under the terms of the GNU General Public License
 * as published by the Free Software Foundation; either version
 * 2 of the License, or (at your option) any later version.
 */

#include <linux/kernel.h>
#include <linux/mm.h>
#include <asm/processor.h>
#include <asm/uaccess.h>
#include <asm/system.h>
#include <asm/cache.h>
#include <asm/cputable.h>

struct aligninfo {
        unsigned char len;
        unsigned char flags;
};

#define IS_XFORM(inst)  (((inst) >> 26) == 31)
#define IS_DSFORM(inst) (((inst) >> 26) >= 56)

#define INVALID { 0, 0 }

/* Bits in the flags field */
#define LD      0       /* load */
#define ST      1       /* store */
#define SE      2       /* sign-extend value, or FP ld/st as word */
#define F       4       /* to/from fp regs */
#define U       8       /* update index register */
#define M       0x10    /* multiple load/store */
#define SW      0x20    /* byte swap */
#define S       0x40    /* single-precision fp or... */
#define SX      0x40    /* ... byte count in XER */
#define HARD    0x80    /* string, stwcx. */
#define E4      0x40    /* SPE endianness is word */
#define E8      0x80    /* SPE endianness is double word */

/* DSISR bits reported for a DCBZ instruction: */
#define DCBZ    0x5f    /* 8xx/82xx dcbz faults when cache not enabled */

#define SWAP(a, b)      (t = (a), (a) = (b), (b) = t)

/*
 * The PowerPC stores certain bits of the instruction that caused the
 * alignment exception in the DSISR register.  This array maps those
 * bits to information about the operand length and what the
 * instruction would do.
 */
static struct aligninfo aligninfo[128] = {
        { 4, LD },              /* 00 0 0000: lwz / lwarx */
        INVALID,                /* 00 0 0001 */
        { 4, ST },              /* 00 0 0010: stw */
        INVALID,                /* 00 0 0011 */
        { 2, LD },              /* 00 0 0100: lhz */
        { 2, LD+SE },           /* 00 0 0101: lha */
        { 2, ST },              /* 00 0 0110: sth */
        { 4, LD+M },            /* 00 0 0111: lmw */
        { 4, LD+F+S },          /* 00 0 1000: lfs */
        { 8, LD+F },            /* 00 0 1001: lfd */
        { 4, ST+F+S },          /* 00 0 1010: stfs */
        { 8, ST+F },            /* 00 0 1011: stfd */
        INVALID,                /* 00 0 1100 */
        { 8, LD },              /* 00 0 1101: ld/ldu/lwa */
        INVALID,                /* 00 0 1110 */
        { 8, ST },              /* 00 0 1111: std/stdu */
        { 4, LD+U },            /* 00 1 0000: lwzu */
        INVALID,                /* 00 1 0001 */
        { 4, ST+U },            /* 00 1 0010: stwu */
        INVALID,                /* 00 1 0011 */
        { 2, LD+U },            /* 00 1 0100: lhzu */
        { 2, LD+SE+U },         /* 00 1 0101: lhau */
        { 2, ST+U },            /* 00 1 0110: sthu */
        { 4, ST+M },            /* 00 1 0111: stmw */
        { 4, LD+F+S+U },        /* 00 1 1000: lfsu */
        { 8, LD+F+U },          /* 00 1 1001: lfdu */
        { 4, ST+F+S+U },        /* 00 1 1010: stfsu */
        { 8, ST+F+U },          /* 00 1 1011: stfdu */
        { 16, LD+F },           /* 00 1 1100: lfdp */
        INVALID,                /* 00 1 1101 */
        { 16, ST+F },           /* 00 1 1110: stfdp */
        INVALID,                /* 00 1 1111 */
        { 8, LD },              /* 01 0 0000: ldx */
        INVALID,                /* 01 0 0001 */
        { 8, ST },              /* 01 0 0010: stdx */
        INVALID,                /* 01 0 0011 */
        INVALID,                /* 01 0 0100 */
        { 4, LD+SE },           /* 01 0 0101: lwax */
        INVALID,                /* 01 0 0110 */
        INVALID,                /* 01 0 0111 */
        { 4, LD+M+HARD+SX },    /* 01 0 1000: lswx */
        { 4, LD+M+HARD },       /* 01 0 1001: lswi */
        { 4, ST+M+HARD+SX },    /* 01 0 1010: stswx */
        { 4, ST+M+HARD },       /* 01 0 1011: stswi */
        INVALID,                /* 01 0 1100 */
        { 8, LD+U },            /* 01 0 1101: ldu */
        INVALID,                /* 01 0 1110 */
        { 8, ST+U },            /* 01 0 1111: stdu */
        { 8, LD+U },            /* 01 1 0000: ldux */
        INVALID,                /* 01 1 0001 */
        { 8, ST+U },            /* 01 1 0010: stdux */
        INVALID,                /* 01 1 0011 */
        INVALID,                /* 01 1 0100 */
        { 4, LD+SE+U },         /* 01 1 0101: lwaux */
        INVALID,                /* 01 1 0110 */
        INVALID,                /* 01 1 0111 */
        INVALID,                /* 01 1 1000 */
        INVALID,                /* 01 1 1001 */
        INVALID,                /* 01 1 1010 */
        INVALID,                /* 01 1 1011 */
        INVALID,                /* 01 1 1100 */
        INVALID,                /* 01 1 1101 */
        INVALID,                /* 01 1 1110 */
        INVALID,                /* 01 1 1111 */
        INVALID,                /* 10 0 0000 */
        INVALID,                /* 10 0 0001 */
        INVALID,                /* 10 0 0010: stwcx. */
        INVALID,                /* 10 0 0011 */
        INVALID,                /* 10 0 0100 */
        INVALID,                /* 10 0 0101 */
        INVALID,                /* 10 0 0110 */
        INVALID,                /* 10 0 0111 */
        { 4, LD+SW },           /* 10 0 1000: lwbrx */
        INVALID,                /* 10 0 1001 */
        { 4, ST+SW },           /* 10 0 1010: stwbrx */
        INVALID,                /* 10 0 1011 */
        { 2, LD+SW },           /* 10 0 1100: lhbrx */
        { 4, LD+SE },           /* 10 0 1101  lwa */
        { 2, ST+SW },           /* 10 0 1110: sthbrx */
        INVALID,                /* 10 0 1111 */
        INVALID,                /* 10 1 0000 */
        INVALID,                /* 10 1 0001 */
        INVALID,                /* 10 1 0010 */
        INVALID,                /* 10 1 0011 */
        INVALID,                /* 10 1 0100 */
        INVALID,                /* 10 1 0101 */
        INVALID,                /* 10 1 0110 */
        INVALID,                /* 10 1 0111 */
        INVALID,                /* 10 1 1000 */
        INVALID,                /* 10 1 1001 */
        INVALID,                /* 10 1 1010 */
        INVALID,                /* 10 1 1011 */
        INVALID,                /* 10 1 1100 */
        INVALID,                /* 10 1 1101 */
        INVALID,                /* 10 1 1110 */
        { 0, ST+HARD },         /* 10 1 1111: dcbz */
        { 4, LD },              /* 11 0 0000: lwzx */
        INVALID,                /* 11 0 0001 */
        { 4, ST },              /* 11 0 0010: stwx */
        INVALID,                /* 11 0 0011 */
        { 2, LD },              /* 11 0 0100: lhzx */
        { 2, LD+SE },           /* 11 0 0101: lhax */
        { 2, ST },              /* 11 0 0110: sthx */
        INVALID,                /* 11 0 0111 */
        { 4, LD+F+S },          /* 11 0 1000: lfsx */
        { 8, LD+F },            /* 11 0 1001: lfdx */
        { 4, ST+F+S },          /* 11 0 1010: stfsx */
        { 8, ST+F },            /* 11 0 1011: stfdx */
        { 16, LD+F },           /* 11 0 1100: lfdpx */
        { 4, LD+F+SE },         /* 11 0 1101: lfiwax */
        { 16, ST+F },           /* 11 0 1110: stfdpx */
        { 4, ST+F },            /* 11 0 1111: stfiwx */
        { 4, LD+U },            /* 11 1 0000: lwzux */
        INVALID,                /* 11 1 0001 */
        { 4, ST+U },            /* 11 1 0010: stwux */
        INVALID,                /* 11 1 0011 */
        { 2, LD+U },            /* 11 1 0100: lhzux */
        { 2, LD+SE+U },         /* 11 1 0101: lhaux */
        { 2, ST+U },            /* 11 1 0110: sthux */
        INVALID,                /* 11 1 0111 */
        { 4, LD+F+S+U },        /* 11 1 1000: lfsux */
        { 8, LD+F+U },          /* 11 1 1001: lfdux */
        { 4, ST+F+S+U },        /* 11 1 1010: stfsux */
        { 8, ST+F+U },          /* 11 1 1011: stfdux */
        INVALID,                /* 11 1 1100 */
        INVALID,                /* 11 1 1101 */
        INVALID,                /* 11 1 1110 */
        INVALID,                /* 11 1 1111 */
};

/*
 * Create a DSISR value from the instruction
 */
static inline unsigned make_dsisr(unsigned instr)
{
        unsigned dsisr;


        /* bits  6:15 --> 22:31 */
        dsisr = (instr & 0x03ff0000) >> 16;

        if (IS_XFORM(instr)) {
                /* bits 29:30 --> 15:16 */
                dsisr |= (instr & 0x00000006) << 14;
                /* bit     25 -->    17 */
                dsisr |= (instr & 0x00000040) << 8;
                /* bits 21:24 --> 18:21 */
                dsisr |= (instr & 0x00000780) << 3;
        } else {
                /* bit      5 -->    17 */
                dsisr |= (instr & 0x04000000) >> 12;
                /* bits  1: 4 --> 18:21 */
                dsisr |= (instr & 0x78000000) >> 17;
                /* bits 30:31 --> 12:13 */
                if (IS_DSFORM(instr))
                        dsisr |= (instr & 0x00000003) << 18;
        }

        return dsisr;
}

/*
 * The dcbz (data cache block zero) instruction
 * gives an alignment fault if used on non-cacheable
 * memory.  We handle the fault mainly for the
 * case when we are running with the cache disabled
 * for debugging.
 */
static int emulate_dcbz(struct pt_regs *regs, unsigned char __user *addr)
{
        long __user *p;
        int i, size;

#ifdef __powerpc64__
        size = ppc64_caches.dline_size;
#else
        size = L1_CACHE_BYTES;
#endif
        p = (long __user *) (regs->dar & -size);
        if (user_mode(regs) && !access_ok(VERIFY_WRITE, p, size))
                return -EFAULT;
        for (i = 0; i < size / sizeof(long); ++i)
                if (__put_user_inatomic(0, p+i))
                        return -EFAULT;
        return 1;
}

/*
 * Emulate load & store multiple instructions
 * On 64-bit machines, these instructions only affect/use the
 * bottom 4 bytes of each register, and the loads clear the
 * top 4 bytes of the affected register.
 */
#ifdef CONFIG_PPC64
#define REG_BYTE(rp, i)         *((u8 *)((rp) + ((i) >> 2)) + ((i) & 3) + 4)
#else
#define REG_BYTE(rp, i)         *((u8 *)(rp) + (i))
#endif

#define SWIZ_PTR(p)             ((unsigned char __user *)((p) ^ swiz))

static int emulate_multiple(struct pt_regs *regs, unsigned char __user *addr,
                            unsigned int reg, unsigned int nb,
                            unsigned int flags, unsigned int instr,
                            unsigned long swiz)
{
        unsigned long *rptr;
        unsigned int nb0, i, bswiz;
        unsigned long p;

        /*
         * We do not try to emulate 8 bytes multiple as they aren't really
         * available in our operating environments and we don't try to
         * emulate multiples operations in kernel land as they should never
         * be used/generated there at least not on unaligned boundaries
         */
        if (unlikely((nb > 4) || !user_mode(regs)))
                return 0;

        /* lmw, stmw, lswi/x, stswi/x */
        nb0 = 0;
        if (flags & HARD) {
                if (flags & SX) {
                        nb = regs->xer & 127;
                        if (nb == 0)
                                return 1;
                } else {
                        unsigned long pc = regs->nip ^ (swiz & 4);

                        if (__get_user_inatomic(instr,
                                                (unsigned int __user *)pc))
                                return -EFAULT;
                        if (swiz == 0 && (flags & SW))
                                instr = cpu_to_le32(instr);
                        nb = (instr >> 11) & 0x1f;
                        if (nb == 0)
                                nb = 32;
                }
                if (nb + reg * 4 > 128) {
                        nb0 = nb + reg * 4 - 128;
                        nb = 128 - reg * 4;
                }
        } else {
                /* lwm, stmw */
                nb = (32 - reg) * 4;
        }

        if (!access_ok((flags & ST ? VERIFY_WRITE: VERIFY_READ), addr, nb+nb0))
                return -EFAULT; /* bad address */

        rptr = &regs->gpr[reg];
        p = (unsigned long) addr;
        bswiz = (flags & SW)? 3: 0;

        if (!(flags & ST)) {
                /*
                 * This zeroes the top 4 bytes of the affected registers
                 * in 64-bit mode, and also zeroes out any remaining
                 * bytes of the last register for lsw*.
                 */
                memset(rptr, 0, ((nb + 3) / 4) * sizeof(unsigned long));
                if (nb0 > 0)
                        memset(&regs->gpr[0], 0,
                               ((nb0 + 3) / 4) * sizeof(unsigned long));

                for (i = 0; i < nb; ++i, ++p)
                        if (__get_user_inatomic(REG_BYTE(rptr, i ^ bswiz),
                                                SWIZ_PTR(p)))
                                return -EFAULT;
                if (nb0 > 0) {
                        rptr = &regs->gpr[0];
                        addr += nb;
                        for (i = 0; i < nb0; ++i, ++p)
                                if (__get_user_inatomic(REG_BYTE(rptr,
                                                                 i ^ bswiz),
                                                        SWIZ_PTR(p)))
                                        return -EFAULT;
                }

        } else {
                for (i = 0; i < nb; ++i, ++p)
                        if (__put_user_inatomic(REG_BYTE(rptr, i ^ bswiz),
                                                SWIZ_PTR(p)))
                                return -EFAULT;
                if (nb0 > 0) {
                        rptr = &regs->gpr[0];
                        addr += nb;
                        for (i = 0; i < nb0; ++i, ++p)
                                if (__put_user_inatomic(REG_BYTE(rptr,
                                                                 i ^ bswiz),
                                                        SWIZ_PTR(p)))
                                        return -EFAULT;
                }
        }
        return 1;
}

/*
 * Emulate floating-point pair loads and stores.
 * Only POWER6 has these instructions, and it does true little-endian,
 * so we don't need the address swizzling.
 */
static int emulate_fp_pair(struct pt_regs *regs, unsigned char __user *addr,
                           unsigned int reg, unsigned int flags)
{
        char *ptr = (char *) &current->thread.fpr[reg];
        int i, ret;

        if (!(flags & F))
                return 0;
        if (reg & 1)
                return 0;       /* invalid form: FRS/FRT must be even */
        if (!(flags & SW)) {
                /* not byte-swapped - easy */
                if (!(flags & ST))
                        ret = __copy_from_user(ptr, addr, 16);
                else
                        ret = __copy_to_user(addr, ptr, 16);
        } else {
                /* each FPR value is byte-swapped separately */
                ret = 0;
                for (i = 0; i < 16; ++i) {
                        if (!(flags & ST))
                                ret |= __get_user(ptr[i^7], addr + i);
                        else
                                ret |= __put_user(ptr[i^7], addr + i);
                }
        }
        if (ret)
                return -EFAULT;
        return 1;       /* exception handled and fixed up */
}

#ifdef CONFIG_SPE

static struct aligninfo spe_aligninfo[32] = {
        { 8, LD+E8 },           /* 0 00 00: evldd[x] */
        { 8, LD+E4 },           /* 0 00 01: evldw[x] */
        { 8, LD },              /* 0 00 10: evldh[x] */
        INVALID,                /* 0 00 11 */
        { 2, LD },              /* 0 01 00: evlhhesplat[x] */
        INVALID,                /* 0 01 01 */
        { 2, LD },              /* 0 01 10: evlhhousplat[x] */
        { 2, LD+SE },           /* 0 01 11: evlhhossplat[x] */
        { 4, LD },              /* 0 10 00: evlwhe[x] */
        INVALID,                /* 0 10 01 */
        { 4, LD },              /* 0 10 10: evlwhou[x] */
        { 4, LD+SE },           /* 0 10 11: evlwhos[x] */
        { 4, LD+E4 },           /* 0 11 00: evlwwsplat[x] */
        INVALID,                /* 0 11 01 */
        { 4, LD },              /* 0 11 10: evlwhsplat[x] */
        INVALID,                /* 0 11 11 */

        { 8, ST+E8 },           /* 1 00 00: evstdd[x] */
        { 8, ST+E4 },           /* 1 00 01: evstdw[x] */
        { 8, ST },              /* 1 00 10: evstdh[x] */
        INVALID,                /* 1 00 11 */
        INVALID,                /* 1 01 00 */
        INVALID,                /* 1 01 01 */
        INVALID,                /* 1 01 10 */
        INVALID,                /* 1 01 11 */
        { 4, ST },              /* 1 10 00: evstwhe[x] */
        INVALID,                /* 1 10 01 */
        { 4, ST },              /* 1 10 10: evstwho[x] */
        INVALID,                /* 1 10 11 */
        { 4, ST+E4 },           /* 1 11 00: evstwwe[x] */
        INVALID,                /* 1 11 01 */
        { 4, ST+E4 },           /* 1 11 10: evstwwo[x] */
        INVALID,                /* 1 11 11 */
};

#define EVLDD           0x00
#define EVLDW           0x01
#define EVLDH           0x02
#define EVLHHESPLAT     0x04
#define EVLHHOUSPLAT    0x06
#define EVLHHOSSPLAT    0x07
#define EVLWHE          0x08
#define EVLWHOU         0x0A
#define EVLWHOS         0x0B
#define EVLWWSPLAT      0x0C
#define EVLWHSPLAT      0x0E
#define EVSTDD          0x10
#define EVSTDW          0x11
#define EVSTDH          0x12
#define EVSTWHE         0x18
#define EVSTWHO         0x1A
#define EVSTWWE         0x1C
#define EVSTWWO         0x1E

/*
 * Emulate SPE loads and stores.
 * Only Book-E has these instructions, and it does true little-endian,
 * so we don't need the address swizzling.
 */
static int emulate_spe(struct pt_regs *regs, unsigned int reg,
                       unsigned int instr)
{
        int t, ret;
        union {
                u64 ll;
                u32 w[2];
                u16 h[4];
                u8 v[8];
        } data, temp;
        unsigned char __user *p, *addr;
        unsigned long *evr = &current->thread.evr[reg];
        unsigned int nb, flags;

        instr = (instr >> 1) & 0x1f;

        /* DAR has the operand effective address */
        addr = (unsigned char __user *)regs->dar;

        nb = spe_aligninfo[instr].len;
        flags = spe_aligninfo[instr].flags;

        /* Verify the address of the operand */
        if (unlikely(user_mode(regs) &&
                     !access_ok((flags & ST ? VERIFY_WRITE : VERIFY_READ),
                                addr, nb)))
                return -EFAULT;

        /* userland only */
        if (unlikely(!user_mode(regs)))
                return 0;

        flush_spe_to_thread(current);

        /* If we are loading, get the data from user space, else
         * get it from register values
         */
        if (flags & ST) {
                data.ll = 0;
                switch (instr) {
                case EVSTDD:
                case EVSTDW:
                case EVSTDH:
                        data.w[0] = *evr;
                        data.w[1] = regs->gpr[reg];
                        break;
                case EVSTWHE:
                        data.h[2] = *evr >> 16;
                        data.h[3] = regs->gpr[reg] >> 16;
                        break;
                case EVSTWHO:
                        data.h[2] = *evr & 0xffff;
                        data.h[3] = regs->gpr[reg] & 0xffff;
                        break;
                case EVSTWWE:
                        data.w[1] = *evr;
                        break;
                case EVSTWWO:
                        data.w[1] = regs->gpr[reg];
                        break;
                default:
                        return -EINVAL;
                }
        } else {
                temp.ll = data.ll = 0;
                ret = 0;
                p = addr;

                switch (nb) {
                case 8:
                        ret |= __get_user_inatomic(temp.v[0], p++);
                        ret |= __get_user_inatomic(temp.v[1], p++);
                        ret |= __get_user_inatomic(temp.v[2], p++);
                        ret |= __get_user_inatomic(temp.v[3], p++);
                case 4:
                        ret |= __get_user_inatomic(temp.v[4], p++);
                        ret |= __get_user_inatomic(temp.v[5], p++);
                case 2:
                        ret |= __get_user_inatomic(temp.v[6], p++);
                        ret |= __get_user_inatomic(temp.v[7], p++);
                        if (unlikely(ret))
                                return -EFAULT;
                }

                switch (instr) {
                case EVLDD:
                case EVLDW:
                case EVLDH:
                        data.ll = temp.ll;
                        break;
                case EVLHHESPLAT:
                        data.h[0] = temp.h[3];
                        data.h[2] = temp.h[3];
                        break;
                case EVLHHOUSPLAT:
                case EVLHHOSSPLAT:
                        data.h[1] = temp.h[3];
                        data.h[3] = temp.h[3];
                        break;
                case EVLWHE:
                        data.h[0] = temp.h[2];
                        data.h[2] = temp.h[3];
                        break;
                case EVLWHOU:
                case EVLWHOS:
                        data.h[1] = temp.h[2];
                        data.h[3] = temp.h[3];
                        break;
                case EVLWWSPLAT:
                        data.w[0] = temp.w[1];
                        data.w[1] = temp.w[1];
                        break;
                case EVLWHSPLAT:
                        data.h[0] = temp.h[2];
                        data.h[1] = temp.h[2];
                        data.h[2] = temp.h[3];
                        data.h[3] = temp.h[3];
                        break;
                default:
                        return -EINVAL;
                }
        }

        if (flags & SW) {
                switch (flags & 0xf0) {
                case E8:
                        SWAP(data.v[0], data.v[7]);
                        SWAP(data.v[1], data.v[6]);
                        SWAP(data.v[2], data.v[5]);
                        SWAP(data.v[3], data.v[4]);
                        break;
                case E4:

                        SWAP(data.v[0], data.v[3]);
                        SWAP(data.v[1], data.v[2]);
                        SWAP(data.v[4], data.v[7]);
                        SWAP(data.v[5], data.v[6]);
                        break;
                /* Its half word endian */
                default:
                        SWAP(data.v[0], data.v[1]);
                        SWAP(data.v[2], data.v[3]);
                        SWAP(data.v[4], data.v[5]);
                        SWAP(data.v[6], data.v[7]);
                        break;
                }
        }

        if (flags & SE) {
                data.w[0] = (s16)data.h[1];
                data.w[1] = (s16)data.h[3];
        }

        /* Store result to memory or update registers */
        if (flags & ST) {
                ret = 0;
                p = addr;
                switch (nb) {
                case 8:
                        ret |= __put_user_inatomic(data.v[0], p++);
                        ret |= __put_user_inatomic(data.v[1], p++);
                        ret |= __put_user_inatomic(data.v[2], p++);
                        ret |= __put_user_inatomic(data.v[3], p++);
                case 4:
                        ret |= __put_user_inatomic(data.v[4], p++);
                        ret |= __put_user_inatomic(data.v[5], p++);
                case 2:
                        ret |= __put_user_inatomic(data.v[6], p++);
                        ret |= __put_user_inatomic(data.v[7], p++);
                }
                if (unlikely(ret))
                        return -EFAULT;
        } else {
                *evr = data.w[0];
                regs->gpr[reg] = data.w[1];
        }

        return 1;
}
#endif /* CONFIG_SPE */

/*
 * Called on alignment exception. Attempts to fixup
 *
 * Return 1 on success
 * Return 0 if unable to handle the interrupt
 * Return -EFAULT if data address is bad
 */

int fix_alignment(struct pt_regs *regs)
{
        unsigned int instr, nb, flags;
        unsigned int reg, areg;
        unsigned int dsisr;
        unsigned char __user *addr;
        unsigned long p, swiz;
        int ret, t;
        union {
                u64 ll;
                double dd;
                unsigned char v[8];
                struct {
                        unsigned hi32;
                        int      low32;
                } x32;
                struct {
                        unsigned char hi48[6];
                        short         low16;
                } x16;
        } data;

        /*
         * We require a complete register set, if not, then our assembly
         * is broken
         */
        CHECK_FULL_REGS(regs);

        dsisr = regs->dsisr;

        /* Some processors don't provide us with a DSISR we can use here,
         * let's make one up from the instruction
         */
        if (cpu_has_feature(CPU_FTR_NODSISRALIGN)) {
                unsigned long pc = regs->nip;

                if (cpu_has_feature(CPU_FTR_PPC_LE) && (regs->msr & MSR_LE))
                        pc ^= 4;
                if (unlikely(__get_user_inatomic(instr,
                                                 (unsigned int __user *)pc)))
                        return -EFAULT;
                if (cpu_has_feature(CPU_FTR_REAL_LE) && (regs->msr & MSR_LE))
                        instr = cpu_to_le32(instr);
                dsisr = make_dsisr(instr);
        }

        /* extract the operation and registers from the dsisr */
        reg = (dsisr >> 5) & 0x1f;      /* source/dest register */
        areg = dsisr & 0x1f;            /* register to update */

#ifdef CONFIG_SPE
        if ((instr >> 26) == 0x4)
                return emulate_spe(regs, reg, instr);
#endif

        instr = (dsisr >> 10) & 0x7f;
        instr |= (dsisr >> 13) & 0x60;

        /* Lookup the operation in our table */
        nb = aligninfo[instr].len;
        flags = aligninfo[instr].flags;

        /* Byteswap little endian loads and stores */
        swiz = 0;
        if (regs->msr & MSR_LE) {
                flags ^= SW;
                /*
                 * So-called "PowerPC little endian" mode works by
                 * swizzling addresses rather than by actually doing
                 * any byte-swapping.  To emulate this, we XOR each
                 * byte address with 7.  We also byte-swap, because
                 * the processor's address swizzling depends on the
                 * operand size (it xors the address with 7 for bytes,
                 * 6 for halfwords, 4 for words, 0 for doublewords) but
                 * we will xor with 7 and load/store each byte separately.
                 */
                if (cpu_has_feature(CPU_FTR_PPC_LE))
                        swiz = 7;
        }

        /* DAR has the operand effective address */
        addr = (unsigned char __user *)regs->dar;

        /* A size of 0 indicates an instruction we don't support, with
         * the exception of DCBZ which is handled as a special case here
         */
        if (instr == DCBZ)
                return emulate_dcbz(regs, addr);
        if (unlikely(nb == 0))
                return 0;

        /* Load/Store Multiple instructions are handled in their own
         * function
         */
        if (flags & M)
                return emulate_multiple(regs, addr, reg, nb,
                                        flags, instr, swiz);

        /* Verify the address of the operand */
        if (unlikely(user_mode(regs) &&
                     !access_ok((flags & ST ? VERIFY_WRITE : VERIFY_READ),
                                addr, nb)))
                return -EFAULT;

        /* Force the fprs into the save area so we can reference them */
        if (flags & F) {
                /* userland only */
                if (unlikely(!user_mode(regs)))
                        return 0;
                flush_fp_to_thread(current);
        }

        /* Special case for 16-byte FP loads and stores */
        if (nb == 16)
                return emulate_fp_pair(regs, addr, reg, flags);

        /* If we are loading, get the data from user space, else
         * get it from register values
         */
        if (!(flags & ST)) {
                data.ll = 0;
                ret = 0;
                p = (unsigned long) addr;
                switch (nb) {
                case 8:
                        ret |= __get_user_inatomic(data.v[0], SWIZ_PTR(p++));
                        ret |= __get_user_inatomic(data.v[1], SWIZ_PTR(p++));
                        ret |= __get_user_inatomic(data.v[2], SWIZ_PTR(p++));
                        ret |= __get_user_inatomic(data.v[3], SWIZ_PTR(p++));
                case 4:
                        ret |= __get_user_inatomic(data.v[4], SWIZ_PTR(p++));
                        ret |= __get_user_inatomic(data.v[5], SWIZ_PTR(p++));
                case 2:
                        ret |= __get_user_inatomic(data.v[6], SWIZ_PTR(p++));
                        ret |= __get_user_inatomic(data.v[7], SWIZ_PTR(p++));
                        if (unlikely(ret))
                                return -EFAULT;
                }
        } else if (flags & F) {
                data.dd = current->thread.fpr[reg];
                if (flags & S) {
                        /* Single-precision FP store requires conversion... */
#ifdef CONFIG_PPC_FPU
                        preempt_disable();
                        enable_kernel_fp();
                        cvt_df(&data.dd, (float *)&data.v[4], &current->thread);
                        preempt_enable();
#else
                        return 0;
#endif
                }
        } else
                data.ll = regs->gpr[reg];

        if (flags & SW) {
                switch (nb) {
                case 8:
                        SWAP(data.v[0], data.v[7]);
                        SWAP(data.v[1], data.v[6]);
                        SWAP(data.v[2], data.v[5]);
                        SWAP(data.v[3], data.v[4]);
                        break;
                case 4:
                        SWAP(data.v[4], data.v[7]);
                        SWAP(data.v[5], data.v[6]);
                        break;
                case 2:
                        SWAP(data.v[6], data.v[7]);
                        break;
                }
        }

        /* Perform other misc operations like sign extension
         * or floating point single precision conversion
         */
        switch (flags & ~(U|SW)) {
        case LD+SE:     /* sign extending integer loads */
        case LD+F+SE:   /* sign extend for lfiwax */
                if ( nb == 2 )
                        data.ll = data.x16.low16;
                else    /* nb must be 4 */
                        data.ll = data.x32.low32;
                break;

        /* Single-precision FP load requires conversion... */
        case LD+F+S:
#ifdef CONFIG_PPC_FPU
                preempt_disable();
                enable_kernel_fp();
                cvt_fd((float *)&data.v[4], &data.dd, &current->thread);
                preempt_enable();
#else
                return 0;
#endif
                break;
        }

        /* Store result to memory or update registers */
        if (flags & ST) {
                ret = 0;
                p = (unsigned long) addr;
                switch (nb) {
                case 8:
                        ret |= __put_user_inatomic(data.v[0], SWIZ_PTR(p++));
                        ret |= __put_user_inatomic(data.v[1], SWIZ_PTR(p++));
                        ret |= __put_user_inatomic(data.v[2], SWIZ_PTR(p++));
                        ret |= __put_user_inatomic(data.v[3], SWIZ_PTR(p++));
                case 4:
                        ret |= __put_user_inatomic(data.v[4], SWIZ_PTR(p++));
                        ret |= __put_user_inatomic(data.v[5], SWIZ_PTR(p++));
                case 2:
                        ret |= __put_user_inatomic(data.v[6], SWIZ_PTR(p++));
                        ret |= __put_user_inatomic(data.v[7], SWIZ_PTR(p++));
                }
                if (unlikely(ret))
                        return -EFAULT;
        } else if (flags & F)
                current->thread.fpr[reg] = data.dd;
        else
                regs->gpr[reg] = data.ll;

        /* Update RA as needed */
        if (flags & U)
                regs->gpr[areg] = regs->dar;

        return 1;
}