Archipelago » qemu

#include "exec.h"

//#define DEBUG_PCALL

//#define DEBUG_MMU

//#define DEBUG_UNALIGNED

//#define DEBUG_UNASSIGNED

void raise_exception(int tt)

{

    env->exception_index = tt;

    cpu_loop_exit();

}

void check_ieee_exceptions()

{

     T0 = get_float_exception_flags(&env->fp_status);

     if (T0)

     {

        /* Copy IEEE 754 flags into FSR */

        if (T0 & float_flag_invalid)

            env->fsr |= FSR_NVC;

        if (T0 & float_flag_overflow)

            env->fsr |= FSR_OFC;

        if (T0 & float_flag_underflow)

            env->fsr |= FSR_UFC;

        if (T0 & float_flag_divbyzero)

            env->fsr |= FSR_DZC;

        if (T0 & float_flag_inexact)

            env->fsr |= FSR_NXC;

        if ((env->fsr & FSR_CEXC_MASK) & ((env->fsr & FSR_TEM_MASK) >> 23))

        {

            /* Unmasked exception, generate a trap */

            env->fsr |= FSR_FTT_IEEE_EXCP;

            raise_exception(TT_FP_EXCP);

        }

        else

        {

            /* Accumulate exceptions */

            env->fsr |= (env->fsr & FSR_CEXC_MASK) << 5;

        }

     }

}

#ifdef USE_INT_TO_FLOAT_HELPERS

void do_fitos(void)

{

    set_float_exception_flags(0, &env->fp_status);

    FT0 = int32_to_float32(*((int32_t *)&FT1), &env->fp_status);

    check_ieee_exceptions();

}

void do_fitod(void)

{

    DT0 = int32_to_float64(*((int32_t *)&FT1), &env->fp_status);

}

#endif

void do_fabss(void)

{

    FT0 = float32_abs(FT1);

}

#ifdef TARGET_SPARC64

void do_fabsd(void)

{

    DT0 = float64_abs(DT1);

}

#endif

void do_fsqrts(void)

{

    set_float_exception_flags(0, &env->fp_status);

    FT0 = float32_sqrt(FT1, &env->fp_status);

    check_ieee_exceptions();

}

void do_fsqrtd(void)

{

    set_float_exception_flags(0, &env->fp_status);

    DT0 = float64_sqrt(DT1, &env->fp_status);

    check_ieee_exceptions();

}

#define GEN_FCMP(name, size, reg1, reg2, FS, TRAP)                      \

    void glue(do_, name) (void)                                         \

    {                                                                   \

        env->fsr &= ~((FSR_FCC1 | FSR_FCC0) << FS);                     \

        switch (glue(size, _compare) (reg1, reg2, &env->fp_status)) {   \

        case float_relation_unordered:                                  \

            T0 = (FSR_FCC1 | FSR_FCC0) << FS;                           \

            if ((env->fsr & FSR_NVM) || TRAP) {                         \

                env->fsr |= T0;                                         \

                env->fsr |= FSR_NVC;                                    \

                env->fsr |= FSR_FTT_IEEE_EXCP;                          \

                raise_exception(TT_FP_EXCP);                            \

            } else {                                                    \

                env->fsr |= FSR_NVA;                                    \

            }                                                           \

            break;                                                      \

        case float_relation_less:                                       \

            T0 = FSR_FCC0 << FS;                                        \

            break;                                                      \

        case float_relation_greater:                                    \

            T0 = FSR_FCC1 << FS;                                        \

            break;                                                      \

        default:                                                        \

            T0 = 0;                                                     \

            break;                                                      \

        }                                                               \

        env->fsr |= T0;                                                 \

    }

GEN_FCMP(fcmps, float32, FT0, FT1, 0, 0);

GEN_FCMP(fcmpd, float64, DT0, DT1, 0, 0);

GEN_FCMP(fcmpes, float32, FT0, FT1, 0, 1);

GEN_FCMP(fcmped, float64, DT0, DT1, 0, 1);

#ifdef TARGET_SPARC64

GEN_FCMP(fcmps_fcc1, float32, FT0, FT1, 22, 0);

GEN_FCMP(fcmpd_fcc1, float64, DT0, DT1, 22, 0);

GEN_FCMP(fcmps_fcc2, float32, FT0, FT1, 24, 0);

GEN_FCMP(fcmpd_fcc2, float64, DT0, DT1, 24, 0);

GEN_FCMP(fcmps_fcc3, float32, FT0, FT1, 26, 0);

GEN_FCMP(fcmpd_fcc3, float64, DT0, DT1, 26, 0);

GEN_FCMP(fcmpes_fcc1, float32, FT0, FT1, 22, 1);

GEN_FCMP(fcmped_fcc1, float64, DT0, DT1, 22, 1);

GEN_FCMP(fcmpes_fcc2, float32, FT0, FT1, 24, 1);

GEN_FCMP(fcmped_fcc2, float64, DT0, DT1, 24, 1);

GEN_FCMP(fcmpes_fcc3, float32, FT0, FT1, 26, 1);

GEN_FCMP(fcmped_fcc3, float64, DT0, DT1, 26, 1);

#endif

#if defined(CONFIG_USER_ONLY)

void helper_ld_asi(int asi, int size, int sign)

{

}

void helper_st_asi(int asi, int size, int sign)

{

}

#else

#ifndef TARGET_SPARC64

void helper_ld_asi(int asi, int size, int sign)

{

    uint32_t ret = 0;

    switch (asi) {

    case 2: /* SuperSparc MXCC registers */

        break;

    case 3: /* MMU probe */

        {

            int mmulev;

            mmulev = (T0 >> 8) & 15;

            if (mmulev > 4)

                ret = 0;

            else {

                ret = mmu_probe(env, T0, mmulev);

                //bswap32s(&ret);

            }

#ifdef DEBUG_MMU

            printf("mmu_probe: 0x%08x (lev %d) -> 0x%08x\n", T0, mmulev, ret);

#endif

        }

        break;

    case 4: /* read MMU regs */

        {

            int reg = (T0 >> 8) & 0xf;

            ret = env->mmuregs[reg];

            if (reg == 3) /* Fault status cleared on read */

                env->mmuregs[reg] = 0;

#ifdef DEBUG_MMU

            printf("mmu_read: reg[%d] = 0x%08x\n", reg, ret);

#endif

        }

        break;

    case 9: /* Supervisor code access */

        switch(size) {

        case 1:

            ret = ldub_code(T0);

            break;

        case 2:

            ret = lduw_code(T0 & ~1);

            break;

        default:

        case 4:

            ret = ldl_code(T0 & ~3);

            break;

        case 8:

            ret = ldl_code(T0 & ~3);

            T0 = ldl_code((T0 + 4) & ~3);

            break;

        }

        break;

    case 0xc: /* I-cache tag */

    case 0xd: /* I-cache data */

    case 0xe: /* D-cache tag */

    case 0xf: /* D-cache data */

        break;

    case 0x20: /* MMU passthrough */

        switch(size) {

        case 1:

            ret = ldub_phys(T0);

            break;

        case 2:

            ret = lduw_phys(T0 & ~1);

            break;

        default:

        case 4:

            ret = ldl_phys(T0 & ~3);

            break;

        case 8:

            ret = ldl_phys(T0 & ~3);

            T0 = ldl_phys((T0 + 4) & ~3);

            break;

        }

        break;

    case 0x2e: /* MMU passthrough, 0xexxxxxxxx */

    case 0x2f: /* MMU passthrough, 0xfxxxxxxxx */

        switch(size) {

        case 1:

            ret = ldub_phys((target_phys_addr_t)T0

                            | ((target_phys_addr_t)(asi & 0xf) << 32));

            break;

        case 2:

            ret = lduw_phys((target_phys_addr_t)(T0 & ~1)

                            | ((target_phys_addr_t)(asi & 0xf) << 32));

            break;

        default:

        case 4:

            ret = ldl_phys((target_phys_addr_t)(T0 & ~3)

                           | ((target_phys_addr_t)(asi & 0xf) << 32));

            break;

        case 8:

            ret = ldl_phys((target_phys_addr_t)(T0 & ~3)

                           | ((target_phys_addr_t)(asi & 0xf) << 32));

            T0 = ldl_phys((target_phys_addr_t)((T0 + 4) & ~3)

                           | ((target_phys_addr_t)(asi & 0xf) << 32));

            break;

        }

        break;

    case 0x21 ... 0x2d: /* MMU passthrough, unassigned */

    default:

        do_unassigned_access(T0, 0, 0, 1);

        ret = 0;

        break;

    }

    T1 = ret;

}

void helper_st_asi(int asi, int size, int sign)

{

    switch(asi) {

    case 2: /* SuperSparc MXCC registers */

        break;

    case 3: /* MMU flush */

        {

            int mmulev;

            mmulev = (T0 >> 8) & 15;

#ifdef DEBUG_MMU

            printf("mmu flush level %d\n", mmulev);

#endif

            switch (mmulev) {

            case 0: // flush page

                tlb_flush_page(env, T0 & 0xfffff000);

                break;

            case 1: // flush segment (256k)

            case 2: // flush region (16M)

            case 3: // flush context (4G)

            case 4: // flush entire

                tlb_flush(env, 1);

                break;

            default:

                break;

            }

#ifdef DEBUG_MMU

            dump_mmu(env);

#endif

            return;

        }

    case 4: /* write MMU regs */

        {

            int reg = (T0 >> 8) & 0xf;

            uint32_t oldreg;

            oldreg = env->mmuregs[reg];

            switch(reg) {

            case 0:

                env->mmuregs[reg] &= ~(MMU_E | MMU_NF);

                env->mmuregs[reg] |= T1 & (MMU_E | MMU_NF);

                // Mappings generated during no-fault mode or MMU

                // disabled mode are invalid in normal mode

                if (oldreg != env->mmuregs[reg])

                    tlb_flush(env, 1);

                break;

            case 2:

                env->mmuregs[reg] = T1;

                if (oldreg != env->mmuregs[reg]) {

                    /* we flush when the MMU context changes because

                       QEMU has no MMU context support */

                    tlb_flush(env, 1);

                }

                break;

            case 3:

            case 4:

                break;

            default:

                env->mmuregs[reg] = T1;

                break;

            }

#ifdef DEBUG_MMU

            if (oldreg != env->mmuregs[reg]) {

                printf("mmu change reg[%d]: 0x%08x -> 0x%08x\n", reg, oldreg, env->mmuregs[reg]);

            }

            dump_mmu(env);

#endif

            return;

        }

    case 0xc: /* I-cache tag */

    case 0xd: /* I-cache data */

    case 0xe: /* D-cache tag */

    case 0xf: /* D-cache data */

    case 0x10: /* I/D-cache flush page */

    case 0x11: /* I/D-cache flush segment */

    case 0x12: /* I/D-cache flush region */

    case 0x13: /* I/D-cache flush context */

    case 0x14: /* I/D-cache flush user */

        break;

    case 0x17: /* Block copy, sta access */

        {

            // value (T1) = src

            // address (T0) = dst

            // copy 32 bytes

            unsigned int i;

            uint32_t src = T1 & ~3, dst = T0 & ~3, temp;

            for (i = 0; i < 32; i += 4, src += 4, dst += 4) {

                temp = ldl_kernel(src);

                stl_kernel(dst, temp);

            }

        }

        return;

    case 0x1f: /* Block fill, stda access */

        {

            // value (T1, T2)

            // address (T0) = dst

            // fill 32 bytes

            unsigned int i;

            uint32_t dst = T0 & 7;

            uint64_t val;

            val = (((uint64_t)T1) << 32) | T2;

            for (i = 0; i < 32; i += 8, dst += 8)

                stq_kernel(dst, val);

        }

        return;

    case 0x20: /* MMU passthrough */

        {

            switch(size) {

            case 1:

                stb_phys(T0, T1);

                break;

            case 2:

                stw_phys(T0 & ~1, T1);

                break;

            case 4:

            default:

                stl_phys(T0 & ~3, T1);

                break;

            case 8:

                stl_phys(T0 & ~3, T1);

                stl_phys((T0 + 4) & ~3, T2);

                break;

            }

        }

        return;

    case 0x2e: /* MMU passthrough, 0xexxxxxxxx */

    case 0x2f: /* MMU passthrough, 0xfxxxxxxxx */

        {

            switch(size) {

            case 1:

                stb_phys((target_phys_addr_t)T0

                         | ((target_phys_addr_t)(asi & 0xf) << 32), T1);

                break;

            case 2:

                stw_phys((target_phys_addr_t)(T0 & ~1)

                            | ((target_phys_addr_t)(asi & 0xf) << 32), T1);

                break;

            case 4:

            default:

                stl_phys((target_phys_addr_t)(T0 & ~3)

                           | ((target_phys_addr_t)(asi & 0xf) << 32), T1);

                break;

            case 8:

                stl_phys((target_phys_addr_t)(T0 & ~3)

                           | ((target_phys_addr_t)(asi & 0xf) << 32), T1);

                stl_phys((target_phys_addr_t)((T0 + 4) & ~3)

                           | ((target_phys_addr_t)(asi & 0xf) << 32), T1);

                break;

            }

        }

        return;

    case 0x31: /* Ross RT620 I-cache flush */

    case 0x36: /* I-cache flash clear */

    case 0x37: /* D-cache flash clear */

        break;

    case 9: /* Supervisor code access, XXX */

    case 0x21 ... 0x2d: /* MMU passthrough, unassigned */

    default:

        do_unassigned_access(T0, 1, 0, 1);

        return;

    }

}

#else

void helper_ld_asi(int asi, int size, int sign)

{

    uint64_t ret = 0;

    if (asi < 0x80 && (env->pstate & PS_PRIV) == 0)

        raise_exception(TT_PRIV_ACT);

    switch (asi) {

    case 0x14: // Bypass

    case 0x15: // Bypass, non-cacheable

        {

            switch(size) {

            case 1:

                ret = ldub_phys(T0);

                break;

            case 2:

                ret = lduw_phys(T0 & ~1);

                break;

            case 4:

                ret = ldl_phys(T0 & ~3);

                break;

            default:

            case 8:

                ret = ldq_phys(T0 & ~7);

                break;

            }

            break;

        }

    case 0x04: // Nucleus

    case 0x0c: // Nucleus Little Endian (LE)

    case 0x10: // As if user primary

    case 0x11: // As if user secondary

    case 0x18: // As if user primary LE

    case 0x19: // As if user secondary LE

    case 0x1c: // Bypass LE

    case 0x1d: // Bypass, non-cacheable LE

    case 0x24: // Nucleus quad LDD 128 bit atomic

    case 0x2c: // Nucleus quad LDD 128 bit atomic

    case 0x4a: // UPA config

    case 0x82: // Primary no-fault

    case 0x83: // Secondary no-fault

    case 0x88: // Primary LE

    case 0x89: // Secondary LE

    case 0x8a: // Primary no-fault LE

    case 0x8b: // Secondary no-fault LE

        // XXX

        break;

    case 0x45: // LSU

        ret = env->lsu;

        break;

    case 0x50: // I-MMU regs

        {

            int reg = (T0 >> 3) & 0xf;

            ret = env->immuregs[reg];

            break;

        }

    case 0x51: // I-MMU 8k TSB pointer

    case 0x52: // I-MMU 64k TSB pointer

    case 0x55: // I-MMU data access

        // XXX

        break;

    case 0x56: // I-MMU tag read

        {

            unsigned int i;

            for (i = 0; i < 64; i++) {

                // Valid, ctx match, vaddr match

                if ((env->itlb_tte[i] & 0x8000000000000000ULL) != 0 &&

                    env->itlb_tag[i] == T0) {

                    ret = env->itlb_tag[i];

                    break;

                }

            }

            break;

        }

    case 0x58: // D-MMU regs

        {

            int reg = (T0 >> 3) & 0xf;

            ret = env->dmmuregs[reg];

            break;

        }

    case 0x5e: // D-MMU tag read

        {

            unsigned int i;

            for (i = 0; i < 64; i++) {

                // Valid, ctx match, vaddr match

                if ((env->dtlb_tte[i] & 0x8000000000000000ULL) != 0 &&

                    env->dtlb_tag[i] == T0) {

                    ret = env->dtlb_tag[i];

                    break;

                }

            }

            break;

        }

    case 0x59: // D-MMU 8k TSB pointer

    case 0x5a: // D-MMU 64k TSB pointer

    case 0x5b: // D-MMU data pointer

    case 0x5d: // D-MMU data access

    case 0x48: // Interrupt dispatch, RO

    case 0x49: // Interrupt data receive

    case 0x7f: // Incoming interrupt vector, RO

        // XXX

        break;

    case 0x54: // I-MMU data in, WO

    case 0x57: // I-MMU demap, WO

    case 0x5c: // D-MMU data in, WO

    case 0x5f: // D-MMU demap, WO

    case 0x77: // Interrupt vector, WO

    default:

        do_unassigned_access(T0, 0, 0, 1);

        ret = 0;

        break;

    }

    T1 = ret;

}

void helper_st_asi(int asi, int size, int sign)

{

    if (asi < 0x80 && (env->pstate & PS_PRIV) == 0)

        raise_exception(TT_PRIV_ACT);

    switch(asi) {

    case 0x14: // Bypass

    case 0x15: // Bypass, non-cacheable

        {

            switch(size) {

            case 1:

                stb_phys(T0, T1);

                break;

            case 2:

                stw_phys(T0 & ~1, T1);

                break;

            case 4:

                stl_phys(T0 & ~3, T1);

                break;

            case 8:

            default:

                stq_phys(T0 & ~7, T1);

                break;

            }

        }

        return;

    case 0x04: // Nucleus

    case 0x0c: // Nucleus Little Endian (LE)

    case 0x10: // As if user primary

    case 0x11: // As if user secondary

    case 0x18: // As if user primary LE

    case 0x19: // As if user secondary LE

    case 0x1c: // Bypass LE

    case 0x1d: // Bypass, non-cacheable LE

    case 0x24: // Nucleus quad LDD 128 bit atomic

    case 0x2c: // Nucleus quad LDD 128 bit atomic

    case 0x4a: // UPA config

    case 0x88: // Primary LE

    case 0x89: // Secondary LE

        // XXX

        return;

    case 0x45: // LSU

        {

            uint64_t oldreg;

            oldreg = env->lsu;

            env->lsu = T1 & (DMMU_E | IMMU_E);

            // Mappings generated during D/I MMU disabled mode are

            // invalid in normal mode

            if (oldreg != env->lsu) {

#ifdef DEBUG_MMU

                printf("LSU change: 0x%" PRIx64 " -> 0x%" PRIx64 "\n", oldreg, env->lsu);

                dump_mmu(env);

#endif

                tlb_flush(env, 1);

            }

            return;

        }

    case 0x50: // I-MMU regs

        {

            int reg = (T0 >> 3) & 0xf;

            uint64_t oldreg;

            oldreg = env->immuregs[reg];

            switch(reg) {

            case 0: // RO

            case 4:

                return;

            case 1: // Not in I-MMU

            case 2:

            case 7:

            case 8:

                return;

            case 3: // SFSR

                if ((T1 & 1) == 0)

                    T1 = 0; // Clear SFSR

                break;

            case 5: // TSB access

            case 6: // Tag access

            default:

                break;

            }

            env->immuregs[reg] = T1;

#ifdef DEBUG_MMU

            if (oldreg != env->immuregs[reg]) {

                printf("mmu change reg[%d]: 0x%08" PRIx64 " -> 0x%08" PRIx64 "\n", reg, oldreg, env->immuregs[reg]);

            }

            dump_mmu(env);

#endif

            return;

        }

    case 0x54: // I-MMU data in

        {

            unsigned int i;

            // Try finding an invalid entry

            for (i = 0; i < 64; i++) {

                if ((env->itlb_tte[i] & 0x8000000000000000ULL) == 0) {

                    env->itlb_tag[i] = env->immuregs[6];

                    env->itlb_tte[i] = T1;

                    return;

                }

            }

            // Try finding an unlocked entry

            for (i = 0; i < 64; i++) {

                if ((env->itlb_tte[i] & 0x40) == 0) {

                    env->itlb_tag[i] = env->immuregs[6];

                    env->itlb_tte[i] = T1;

                    return;

                }

            }

            // error state?

            return;

        }

    case 0x55: // I-MMU data access

        {

            unsigned int i = (T0 >> 3) & 0x3f;

            env->itlb_tag[i] = env->immuregs[6];

            env->itlb_tte[i] = T1;

            return;

        }

    case 0x57: // I-MMU demap

        // XXX

        return;

    case 0x58: // D-MMU regs

        {

            int reg = (T0 >> 3) & 0xf;

            uint64_t oldreg;

            oldreg = env->dmmuregs[reg];

            switch(reg) {

            case 0: // RO

            case 4:

                return;

            case 3: // SFSR

                if ((T1 & 1) == 0) {

                    T1 = 0; // Clear SFSR, Fault address

                    env->dmmuregs[4] = 0;

                }

                env->dmmuregs[reg] = T1;

                break;

            case 1: // Primary context

            case 2: // Secondary context

            case 5: // TSB access

            case 6: // Tag access

            case 7: // Virtual Watchpoint

            case 8: // Physical Watchpoint

            default:

                break;

            }

            env->dmmuregs[reg] = T1;

#ifdef DEBUG_MMU

            if (oldreg != env->dmmuregs[reg]) {

                printf("mmu change reg[%d]: 0x%08" PRIx64 " -> 0x%08" PRIx64 "\n", reg, oldreg, env->dmmuregs[reg]);

            }

            dump_mmu(env);

#endif

            return;

        }

    case 0x5c: // D-MMU data in

        {

            unsigned int i;

            // Try finding an invalid entry

            for (i = 0; i < 64; i++) {

                if ((env->dtlb_tte[i] & 0x8000000000000000ULL) == 0) {

                    env->dtlb_tag[i] = env->dmmuregs[6];

                    env->dtlb_tte[i] = T1;

                    return;

                }

            }

            // Try finding an unlocked entry

            for (i = 0; i < 64; i++) {

                if ((env->dtlb_tte[i] & 0x40) == 0) {

                    env->dtlb_tag[i] = env->dmmuregs[6];

                    env->dtlb_tte[i] = T1;

                    return;

                }

            }

            // error state?

            return;

        }

    case 0x5d: // D-MMU data access

        {

            unsigned int i = (T0 >> 3) & 0x3f;

            env->dtlb_tag[i] = env->dmmuregs[6];

            env->dtlb_tte[i] = T1;

            return;

        }

    case 0x5f: // D-MMU demap

    case 0x49: // Interrupt data receive

        // XXX

        return;

    case 0x51: // I-MMU 8k TSB pointer, RO

    case 0x52: // I-MMU 64k TSB pointer, RO

    case 0x56: // I-MMU tag read, RO

    case 0x59: // D-MMU 8k TSB pointer, RO

    case 0x5a: // D-MMU 64k TSB pointer, RO

    case 0x5b: // D-MMU data pointer, RO

    case 0x5e: // D-MMU tag read, RO

    case 0x48: // Interrupt dispatch, RO

    case 0x7f: // Incoming interrupt vector, RO

    case 0x82: // Primary no-fault, RO

    case 0x83: // Secondary no-fault, RO

    case 0x8a: // Primary no-fault LE, RO

    case 0x8b: // Secondary no-fault LE, RO

    default:

        do_unassigned_access(T0, 1, 0, 1);

        return;

    }

}

#endif

#endif /* !CONFIG_USER_ONLY */

#ifndef TARGET_SPARC64

void helper_rett()

{

    unsigned int cwp;

    if (env->psret == 1)

        raise_exception(TT_ILL_INSN);

    env->psret = 1;

    cwp = (env->cwp + 1) & (NWINDOWS - 1);

    if (env->wim & (1 << cwp)) {

        raise_exception(TT_WIN_UNF);

    }

    set_cwp(cwp);

    env->psrs = env->psrps;

}

#endif

void helper_ldfsr(void)

{

    int rnd_mode;

    switch (env->fsr & FSR_RD_MASK) {

    case FSR_RD_NEAREST:

        rnd_mode = float_round_nearest_even;

        break;

    default:

    case FSR_RD_ZERO:

        rnd_mode = float_round_to_zero;

        break;

    case FSR_RD_POS:

        rnd_mode = float_round_up;

        break;

    case FSR_RD_NEG:

        rnd_mode = float_round_down;

        break;

    }

    set_float_rounding_mode(rnd_mode, &env->fp_status);

}

void helper_debug()

{

    env->exception_index = EXCP_DEBUG;

    cpu_loop_exit();

}

#ifndef TARGET_SPARC64

void do_wrpsr()

{

    if ((T0 & PSR_CWP) >= NWINDOWS)

        raise_exception(TT_ILL_INSN);

    else

        PUT_PSR(env, T0);

}

void do_rdpsr()

{

    T0 = GET_PSR(env);

}

#else

void do_popc()

{

    T0 = (T1 & 0x5555555555555555ULL) + ((T1 >> 1) & 0x5555555555555555ULL);

    T0 = (T0 & 0x3333333333333333ULL) + ((T0 >> 2) & 0x3333333333333333ULL);

    T0 = (T0 & 0x0f0f0f0f0f0f0f0fULL) + ((T0 >> 4) & 0x0f0f0f0f0f0f0f0fULL);

    T0 = (T0 & 0x00ff00ff00ff00ffULL) + ((T0 >> 8) & 0x00ff00ff00ff00ffULL);

    T0 = (T0 & 0x0000ffff0000ffffULL) + ((T0 >> 16) & 0x0000ffff0000ffffULL);

    T0 = (T0 & 0x00000000ffffffffULL) + ((T0 >> 32) & 0x00000000ffffffffULL);

}

static inline uint64_t *get_gregset(uint64_t pstate)

{

    switch (pstate) {

    default:

    case 0:

        return env->bgregs;

    case PS_AG:

        return env->agregs;

    case PS_MG:

        return env->mgregs;

    case PS_IG:

        return env->igregs;

    }

}

static inline void change_pstate(uint64_t new_pstate)

{

    uint64_t pstate_regs, new_pstate_regs;

    uint64_t *src, *dst;

    pstate_regs = env->pstate & 0xc01;

    new_pstate_regs = new_pstate & 0xc01;

    if (new_pstate_regs != pstate_regs) {

        // Switch global register bank

        src = get_gregset(new_pstate_regs);

        dst = get_gregset(pstate_regs);

        memcpy32(dst, env->gregs);

        memcpy32(env->gregs, src);

    }

    env->pstate = new_pstate;

}

void do_wrpstate(void)

{

    change_pstate(T0 & 0xf3f);

}

void do_done(void)

{

    env->tl--;

    env->pc = env->tnpc[env->tl];

    env->npc = env->tnpc[env->tl] + 4;

    PUT_CCR(env, env->tstate[env->tl] >> 32);

    env->asi = (env->tstate[env->tl] >> 24) & 0xff;

    change_pstate((env->tstate[env->tl] >> 8) & 0xf3f);

    PUT_CWP64(env, env->tstate[env->tl] & 0xff);

}

void do_retry(void)

{

    env->tl--;

    env->pc = env->tpc[env->tl];

    env->npc = env->tnpc[env->tl];

    PUT_CCR(env, env->tstate[env->tl] >> 32);

    env->asi = (env->tstate[env->tl] >> 24) & 0xff;

    change_pstate((env->tstate[env->tl] >> 8) & 0xf3f);

    PUT_CWP64(env, env->tstate[env->tl] & 0xff);

}

#endif

void set_cwp(int new_cwp)

{

    /* put the modified wrap registers at their proper location */

    if (env->cwp == (NWINDOWS - 1))

        memcpy32(env->regbase, env->regbase + NWINDOWS * 16);

    env->cwp = new_cwp;

    /* put the wrap registers at their temporary location */

    if (new_cwp == (NWINDOWS - 1))

        memcpy32(env->regbase + NWINDOWS * 16, env->regbase);

    env->regwptr = env->regbase + (new_cwp * 16);

    REGWPTR = env->regwptr;

}

void cpu_set_cwp(CPUState *env1, int new_cwp)

{

    CPUState *saved_env;

#ifdef reg_REGWPTR

    target_ulong *saved_regwptr;

#endif

    saved_env = env;

#ifdef reg_REGWPTR

    saved_regwptr = REGWPTR;

#endif

    env = env1;

    set_cwp(new_cwp);

    env = saved_env;

#ifdef reg_REGWPTR

    REGWPTR = saved_regwptr;

#endif

}

#ifdef TARGET_SPARC64

void do_interrupt(int intno)

{

#ifdef DEBUG_PCALL

    if (loglevel & CPU_LOG_INT) {

        static int count;

        fprintf(logfile, "%6d: v=%04x pc=%016" PRIx64 " npc=%016" PRIx64 " SP=%016" PRIx64 "\n",

                count, intno,

                env->pc,

                env->npc, env->regwptr[6]);

        cpu_dump_state(env, logfile, fprintf, 0);

#if 0

        {

            int i;

            uint8_t *ptr;

            fprintf(logfile, "       code=");

            ptr = (uint8_t *)env->pc;

            for(i = 0; i < 16; i++) {

                fprintf(logfile, " %02x", ldub(ptr + i));

            }

            fprintf(logfile, "\n");

        }

#endif

        count++;

    }

#endif

#if !defined(CONFIG_USER_ONLY)

    if (env->tl == MAXTL) {

        cpu_abort(env, "Trap 0x%04x while trap level is MAXTL, Error state", env->exception_index);

        return;

    }

#endif

    env->tstate[env->tl] = ((uint64_t)GET_CCR(env) << 32) | ((env->asi & 0xff) << 24) |

        ((env->pstate & 0xf3f) << 8) | GET_CWP64(env);

    env->tpc[env->tl] = env->pc;

    env->tnpc[env->tl] = env->npc;

    env->tt[env->tl] = intno;

    change_pstate(PS_PEF | PS_PRIV | PS_AG);

    if (intno == TT_CLRWIN)

        set_cwp((env->cwp - 1) & (NWINDOWS - 1));

    else if ((intno & 0x1c0) == TT_SPILL)

        set_cwp((env->cwp - env->cansave - 2) & (NWINDOWS - 1));

    else if ((intno & 0x1c0) == TT_FILL)

        set_cwp((env->cwp + 1) & (NWINDOWS - 1));

    env->tbr &= ~0x7fffULL;

    env->tbr |= ((env->tl > 1) ? 1 << 14 : 0) | (intno << 5);

    if (env->tl < MAXTL - 1) {

        env->tl++;

    } else {

        env->pstate |= PS_RED;

        if (env->tl != MAXTL)

            env->tl++;

    }

    env->pc = env->tbr;

    env->npc = env->pc + 4;

    env->exception_index = 0;

}

#else

void do_interrupt(int intno)

{

    int cwp;

#ifdef DEBUG_PCALL

    if (loglevel & CPU_LOG_INT) {

        static int count;

        fprintf(logfile, "%6d: v=%02x pc=%08x npc=%08x SP=%08x\n",

                count, intno,

                env->pc,

                env->npc, env->regwptr[6]);

        cpu_dump_state(env, logfile, fprintf, 0);

#if 0

        {

            int i;

            uint8_t *ptr;

            fprintf(logfile, "       code=");

            ptr = (uint8_t *)env->pc;

            for(i = 0; i < 16; i++) {

                fprintf(logfile, " %02x", ldub(ptr + i));

            }

            fprintf(logfile, "\n");

        }

#endif

        count++;

    }

#endif

#if !defined(CONFIG_USER_ONLY)

    if (env->psret == 0) {

        cpu_abort(env, "Trap 0x%02x while interrupts disabled, Error state", env->exception_index);

        return;

    }

#endif

    env->psret = 0;

    cwp = (env->cwp - 1) & (NWINDOWS - 1);

    set_cwp(cwp);

    env->regwptr[9] = env->pc;

    env->regwptr[10] = env->npc;

    env->psrps = env->psrs;

    env->psrs = 1;

    env->tbr = (env->tbr & TBR_BASE_MASK) | (intno << 4);

    env->pc = env->tbr;

    env->npc = env->pc + 4;

    env->exception_index = 0;

}

#endif

#if !defined(CONFIG_USER_ONLY)

static void do_unaligned_access(target_ulong addr, int is_write, int is_user,

                                void *retaddr);

#define MMUSUFFIX _mmu

#define ALIGNED_ONLY

#define GETPC() (__builtin_return_address(0))

#define SHIFT 0

#include "softmmu_template.h"

#define SHIFT 1

#include "softmmu_template.h"

#define SHIFT 2

#include "softmmu_template.h"

#define SHIFT 3

#include "softmmu_template.h"

static void do_unaligned_access(target_ulong addr, int is_write, int is_user,

                                void *retaddr)

{

#ifdef DEBUG_UNALIGNED

    printf("Unaligned access to 0x%x from 0x%x\n", addr, env->pc);

#endif

    raise_exception(TT_UNALIGNED);

}

/* try to fill the TLB and return an exception if error. If retaddr is

   NULL, it means that the function was called in C code (i.e. not

   from generated code or from helper.c) */

/* XXX: fix it to restore all registers */

void tlb_fill(target_ulong addr, int is_write, int is_user, void *retaddr)

{

    TranslationBlock *tb;

    int ret;

    unsigned long pc;

    CPUState *saved_env;

    /* XXX: hack to restore env in all cases, even if not called from

       generated code */

    saved_env = env;

    env = cpu_single_env;

    ret = cpu_sparc_handle_mmu_fault(env, addr, is_write, is_user, 1);

    if (ret) {

        if (retaddr) {

            /* now we have a real cpu fault */

            pc = (unsigned long)retaddr;

            tb = tb_find_pc(pc);

            if (tb) {

                /* the PC is inside the translated code. It means that we have

                   a virtual CPU fault */

                cpu_restore_state(tb, env, pc, (void *)T2);

            }

        }

        cpu_loop_exit();

    }

    env = saved_env;

}

#endif

#ifndef TARGET_SPARC64

void do_unassigned_access(target_phys_addr_t addr, int is_write, int is_exec,

                          int is_asi)

{

    CPUState *saved_env;

    /* XXX: hack to restore env in all cases, even if not called from

       generated code */

    saved_env = env;

    env = cpu_single_env;

    if (env->mmuregs[3]) /* Fault status register */

        env->mmuregs[3] = 1; /* overflow (not read before another fault) */

    if (is_asi)

        env->mmuregs[3] |= 1 << 16;

    if (env->psrs)

        env->mmuregs[3] |= 1 << 5;

    if (is_exec)

        env->mmuregs[3] |= 1 << 6;

    if (is_write)

        env->mmuregs[3] |= 1 << 7;

    env->mmuregs[3] |= (5 << 2) | 2;

    env->mmuregs[4] = addr; /* Fault address register */

    if ((env->mmuregs[0] & MMU_E) && !(env->mmuregs[0] & MMU_NF)) {

#ifdef DEBUG_UNASSIGNED

        printf("Unassigned mem access to " TARGET_FMT_plx " from " TARGET_FMT_lx

               "\n", addr, env->pc);

#endif

        if (is_exec)

            raise_exception(TT_CODE_ACCESS);

        else

            raise_exception(TT_DATA_ACCESS);

    }

    env = saved_env;

}

#else

void do_unassigned_access(target_phys_addr_t addr, int is_write, int is_exec,

                          int is_asi)

{

#ifdef DEBUG_UNASSIGNED

    CPUState *saved_env;

    /* XXX: hack to restore env in all cases, even if not called from

       generated code */

    saved_env = env;

    env = cpu_single_env;

    printf("Unassigned mem access to " TARGET_FMT_plx " from " TARGET_FMT_lx "\n",

           addr, env->pc);

    env = saved_env;

#endif

    if (is_exec)

        raise_exception(TT_CODE_ACCESS);

    else

        raise_exception(TT_DATA_ACCESS);

}

#endif

#ifdef TARGET_SPARC64

void do_tick_set_count(void *opaque, uint64_t count)

{

#if !defined(CONFIG_USER_ONLY)

    ptimer_set_count(opaque, -count);

#endif

}

uint64_t do_tick_get_count(void *opaque)

{

#if !defined(CONFIG_USER_ONLY)

    return -ptimer_get_count(opaque);

#else

    return 0;

#endif

}

void do_tick_set_limit(void *opaque, uint64_t limit)

{

#if !defined(CONFIG_USER_ONLY)

    ptimer_set_limit(opaque, -limit, 0);

#endif

}

#endif