Archipelago » qemu

/*

 * QEMU generic PowerPC hardware System Emulator

 *

 * Copyright (c) 2003-2007 Jocelyn Mayer

 *

 * Permission is hereby granted, free of charge, to any person obtaining a copy

 * of this software and associated documentation files (the "Software"), to deal

 * in the Software without restriction, including without limitation the rights

 * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell

 * copies of the Software, and to permit persons to whom the Software is

 * furnished to do so, subject to the following conditions:

 *

 * The above copyright notice and this permission notice shall be included in

 * all copies or substantial portions of the Software.

 *

 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR

 * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,

 * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL

 * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER

 * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,

 * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN

 * THE SOFTWARE.

 */

#include "hw.h"

#include "ppc.h"

#include "qemu-timer.h"

#include "sysemu.h"

#include "nvram.h"

#include "qemu-log.h"

#include "loader.h"

#include "kvm.h"

#include "kvm_ppc.h"

//#define PPC_DEBUG_IRQ

//#define PPC_DEBUG_TB

#ifdef PPC_DEBUG_IRQ

#  define LOG_IRQ(...) qemu_log_mask(CPU_LOG_INT, ## __VA_ARGS__)

#else

#  define LOG_IRQ(...) do { } while (0)

#endif

#ifdef PPC_DEBUG_TB

#  define LOG_TB(...) qemu_log(__VA_ARGS__)

#else

#  define LOG_TB(...) do { } while (0)

#endif

static void cpu_ppc_tb_stop (CPUState *env);

static void cpu_ppc_tb_start (CPUState *env);

static void ppc_set_irq (CPUState *env, int n_IRQ, int level)

{

    unsigned int old_pending = env->pending_interrupts;

    if (level) {

        env->pending_interrupts |= 1 << n_IRQ;

        cpu_interrupt(env, CPU_INTERRUPT_HARD);

    } else {

        env->pending_interrupts &= ~(1 << n_IRQ);

        if (env->pending_interrupts == 0)

            cpu_reset_interrupt(env, CPU_INTERRUPT_HARD);

    }

    if (old_pending != env->pending_interrupts) {

#ifdef CONFIG_KVM

        kvmppc_set_interrupt(env, n_IRQ, level);

#endif

    }

    LOG_IRQ("%s: %p n_IRQ %d level %d => pending %08" PRIx32

                "req %08x\n", __func__, env, n_IRQ, level,

                env->pending_interrupts, env->interrupt_request);

}

/* PowerPC 6xx / 7xx internal IRQ controller */

static void ppc6xx_set_irq (void *opaque, int pin, int level)

{

    CPUState *env = opaque;

    int cur_level;

    LOG_IRQ("%s: env %p pin %d level %d\n", __func__,

                env, pin, level);

    cur_level = (env->irq_input_state >> pin) & 1;

    /* Don't generate spurious events */

    if ((cur_level == 1 && level == 0) || (cur_level == 0 && level != 0)) {

        switch (pin) {

        case PPC6xx_INPUT_TBEN:

            /* Level sensitive - active high */

            LOG_IRQ("%s: %s the time base\n",

                        __func__, level ? "start" : "stop");

            if (level) {

                cpu_ppc_tb_start(env);

            } else {

                cpu_ppc_tb_stop(env);

            }

        case PPC6xx_INPUT_INT:

            /* Level sensitive - active high */

            LOG_IRQ("%s: set the external IRQ state to %d\n",

                        __func__, level);

            ppc_set_irq(env, PPC_INTERRUPT_EXT, level);

            break;

        case PPC6xx_INPUT_SMI:

            /* Level sensitive - active high */

            LOG_IRQ("%s: set the SMI IRQ state to %d\n",

                        __func__, level);

            ppc_set_irq(env, PPC_INTERRUPT_SMI, level);

            break;

        case PPC6xx_INPUT_MCP:

            /* Negative edge sensitive */

            /* XXX: TODO: actual reaction may depends on HID0 status

             *            603/604/740/750: check HID0[EMCP]

             */

            if (cur_level == 1 && level == 0) {

                LOG_IRQ("%s: raise machine check state\n",

                            __func__);

                ppc_set_irq(env, PPC_INTERRUPT_MCK, 1);

            }

            break;

        case PPC6xx_INPUT_CKSTP_IN:

            /* Level sensitive - active low */

            /* XXX: TODO: relay the signal to CKSTP_OUT pin */

            /* XXX: Note that the only way to restart the CPU is to reset it */

            if (level) {

                LOG_IRQ("%s: stop the CPU\n", __func__);

                env->halted = 1;

            }

            break;

        case PPC6xx_INPUT_HRESET:

            /* Level sensitive - active low */

            if (level) {

                LOG_IRQ("%s: reset the CPU\n", __func__);

                env->interrupt_request |= CPU_INTERRUPT_EXITTB;

                /* XXX: TOFIX */

#if 0

                cpu_reset(env);

#else

                qemu_system_reset_request();

#endif

            }

            break;

        case PPC6xx_INPUT_SRESET:

            LOG_IRQ("%s: set the RESET IRQ state to %d\n",

                        __func__, level);

            ppc_set_irq(env, PPC_INTERRUPT_RESET, level);

            break;

        default:

            /* Unknown pin - do nothing */

            LOG_IRQ("%s: unknown IRQ pin %d\n", __func__, pin);

            return;

        }

        if (level)

            env->irq_input_state |= 1 << pin;

        else

            env->irq_input_state &= ~(1 << pin);

    }

}

void ppc6xx_irq_init (CPUState *env)

{

    env->irq_inputs = (void **)qemu_allocate_irqs(&ppc6xx_set_irq, env,

                                                  PPC6xx_INPUT_NB);

}

#if defined(TARGET_PPC64)

/* PowerPC 970 internal IRQ controller */

static void ppc970_set_irq (void *opaque, int pin, int level)

{

    CPUState *env = opaque;

    int cur_level;

    LOG_IRQ("%s: env %p pin %d level %d\n", __func__,

                env, pin, level);

    cur_level = (env->irq_input_state >> pin) & 1;

    /* Don't generate spurious events */

    if ((cur_level == 1 && level == 0) || (cur_level == 0 && level != 0)) {

        switch (pin) {

        case PPC970_INPUT_INT:

            /* Level sensitive - active high */

            LOG_IRQ("%s: set the external IRQ state to %d\n",

                        __func__, level);

            ppc_set_irq(env, PPC_INTERRUPT_EXT, level);

            break;

        case PPC970_INPUT_THINT:

            /* Level sensitive - active high */

            LOG_IRQ("%s: set the SMI IRQ state to %d\n", __func__,

                        level);

            ppc_set_irq(env, PPC_INTERRUPT_THERM, level);

            break;

        case PPC970_INPUT_MCP:

            /* Negative edge sensitive */

            /* XXX: TODO: actual reaction may depends on HID0 status

             *            603/604/740/750: check HID0[EMCP]

             */

            if (cur_level == 1 && level == 0) {

                LOG_IRQ("%s: raise machine check state\n",

                            __func__);

                ppc_set_irq(env, PPC_INTERRUPT_MCK, 1);

            }

            break;

        case PPC970_INPUT_CKSTP:

            /* Level sensitive - active low */

            /* XXX: TODO: relay the signal to CKSTP_OUT pin */

            if (level) {

                LOG_IRQ("%s: stop the CPU\n", __func__);

                env->halted = 1;

            } else {

                LOG_IRQ("%s: restart the CPU\n", __func__);

                env->halted = 0;

            }

            break;

        case PPC970_INPUT_HRESET:

            /* Level sensitive - active low */

            if (level) {

#if 0 // XXX: TOFIX

                LOG_IRQ("%s: reset the CPU\n", __func__);

                cpu_reset(env);

#endif

            }

            break;

        case PPC970_INPUT_SRESET:

            LOG_IRQ("%s: set the RESET IRQ state to %d\n",

                        __func__, level);

            ppc_set_irq(env, PPC_INTERRUPT_RESET, level);

            break;

        case PPC970_INPUT_TBEN:

            LOG_IRQ("%s: set the TBEN state to %d\n", __func__,

                        level);

            /* XXX: TODO */

            break;

        default:

            /* Unknown pin - do nothing */

            LOG_IRQ("%s: unknown IRQ pin %d\n", __func__, pin);

            return;

        }

        if (level)

            env->irq_input_state |= 1 << pin;

        else

            env->irq_input_state &= ~(1 << pin);

    }

}

void ppc970_irq_init (CPUState *env)

{

    env->irq_inputs = (void **)qemu_allocate_irqs(&ppc970_set_irq, env,

                                                  PPC970_INPUT_NB);

}

#endif /* defined(TARGET_PPC64) */

/* PowerPC 40x internal IRQ controller */

static void ppc40x_set_irq (void *opaque, int pin, int level)

{

    CPUState *env = opaque;

    int cur_level;

    LOG_IRQ("%s: env %p pin %d level %d\n", __func__,

                env, pin, level);

    cur_level = (env->irq_input_state >> pin) & 1;

    /* Don't generate spurious events */

    if ((cur_level == 1 && level == 0) || (cur_level == 0 && level != 0)) {

        switch (pin) {

        case PPC40x_INPUT_RESET_SYS:

            if (level) {

                LOG_IRQ("%s: reset the PowerPC system\n",

                            __func__);

                ppc40x_system_reset(env);

            }

            break;

        case PPC40x_INPUT_RESET_CHIP:

            if (level) {

                LOG_IRQ("%s: reset the PowerPC chip\n", __func__);

                ppc40x_chip_reset(env);

            }

            break;

        case PPC40x_INPUT_RESET_CORE:

            /* XXX: TODO: update DBSR[MRR] */

            if (level) {

                LOG_IRQ("%s: reset the PowerPC core\n", __func__);

                ppc40x_core_reset(env);

            }

            break;

        case PPC40x_INPUT_CINT:

            /* Level sensitive - active high */

            LOG_IRQ("%s: set the critical IRQ state to %d\n",

                        __func__, level);

            ppc_set_irq(env, PPC_INTERRUPT_CEXT, level);

            break;

        case PPC40x_INPUT_INT:

            /* Level sensitive - active high */

            LOG_IRQ("%s: set the external IRQ state to %d\n",

                        __func__, level);

            ppc_set_irq(env, PPC_INTERRUPT_EXT, level);

            break;

        case PPC40x_INPUT_HALT:

            /* Level sensitive - active low */

            if (level) {

                LOG_IRQ("%s: stop the CPU\n", __func__);

                env->halted = 1;

            } else {

                LOG_IRQ("%s: restart the CPU\n", __func__);

                env->halted = 0;

            }

            break;

        case PPC40x_INPUT_DEBUG:

            /* Level sensitive - active high */

            LOG_IRQ("%s: set the debug pin state to %d\n",

                        __func__, level);

            ppc_set_irq(env, PPC_INTERRUPT_DEBUG, level);

            break;

        default:

            /* Unknown pin - do nothing */

            LOG_IRQ("%s: unknown IRQ pin %d\n", __func__, pin);

            return;

        }

        if (level)

            env->irq_input_state |= 1 << pin;

        else

            env->irq_input_state &= ~(1 << pin);

    }

}

void ppc40x_irq_init (CPUState *env)

{

    env->irq_inputs = (void **)qemu_allocate_irqs(&ppc40x_set_irq,

                                                  env, PPC40x_INPUT_NB);

}

/* PowerPC E500 internal IRQ controller */

static void ppce500_set_irq (void *opaque, int pin, int level)

{

    CPUState *env = opaque;

    int cur_level;

    LOG_IRQ("%s: env %p pin %d level %d\n", __func__,

                env, pin, level);

    cur_level = (env->irq_input_state >> pin) & 1;

    /* Don't generate spurious events */

    if ((cur_level == 1 && level == 0) || (cur_level == 0 && level != 0)) {

        switch (pin) {

        case PPCE500_INPUT_MCK:

            if (level) {

                LOG_IRQ("%s: reset the PowerPC system\n",

                            __func__);

                qemu_system_reset_request();

            }

            break;

        case PPCE500_INPUT_RESET_CORE:

            if (level) {

                LOG_IRQ("%s: reset the PowerPC core\n", __func__);

                ppc_set_irq(env, PPC_INTERRUPT_MCK, level);

            }

            break;

        case PPCE500_INPUT_CINT:

            /* Level sensitive - active high */

            LOG_IRQ("%s: set the critical IRQ state to %d\n",

                        __func__, level);

            ppc_set_irq(env, PPC_INTERRUPT_CEXT, level);

            break;

        case PPCE500_INPUT_INT:

            /* Level sensitive - active high */

            LOG_IRQ("%s: set the core IRQ state to %d\n",

                        __func__, level);

            ppc_set_irq(env, PPC_INTERRUPT_EXT, level);

            break;

        case PPCE500_INPUT_DEBUG:

            /* Level sensitive - active high */

            LOG_IRQ("%s: set the debug pin state to %d\n",

                        __func__, level);

            ppc_set_irq(env, PPC_INTERRUPT_DEBUG, level);

            break;

        default:

            /* Unknown pin - do nothing */

            LOG_IRQ("%s: unknown IRQ pin %d\n", __func__, pin);

            return;

        }

        if (level)

            env->irq_input_state |= 1 << pin;

        else

            env->irq_input_state &= ~(1 << pin);

    }

}

void ppce500_irq_init (CPUState *env)

{

    env->irq_inputs = (void **)qemu_allocate_irqs(&ppce500_set_irq,

                                        env, PPCE500_INPUT_NB);

}

/*****************************************************************************/

/* PowerPC time base and decrementer emulation */

struct ppc_tb_t {

    /* Time base management */

    int64_t  tb_offset;    /* Compensation                    */

    int64_t  atb_offset;   /* Compensation                    */

    uint32_t tb_freq;      /* TB frequency                    */

    /* Decrementer management */

    uint64_t decr_next;    /* Tick for next decr interrupt    */

    uint32_t decr_freq;    /* decrementer frequency           */

    struct QEMUTimer *decr_timer;

    /* Hypervisor decrementer management */

    uint64_t hdecr_next;    /* Tick for next hdecr interrupt  */

    struct QEMUTimer *hdecr_timer;

    uint64_t purr_load;

    uint64_t purr_start;

    void *opaque;

};

static inline uint64_t cpu_ppc_get_tb(ppc_tb_t *tb_env, uint64_t vmclk,

                                      int64_t tb_offset)

{

    /* TB time in tb periods */

    return muldiv64(vmclk, tb_env->tb_freq, get_ticks_per_sec()) + tb_offset;

}

uint64_t cpu_ppc_load_tbl (CPUState *env)

{

    ppc_tb_t *tb_env = env->tb_env;

    uint64_t tb;

    tb = cpu_ppc_get_tb(tb_env, qemu_get_clock(vm_clock), tb_env->tb_offset);

    LOG_TB("%s: tb %016" PRIx64 "\n", __func__, tb);

    return tb;

}

static inline uint32_t _cpu_ppc_load_tbu(CPUState *env)

{

    ppc_tb_t *tb_env = env->tb_env;

    uint64_t tb;

    tb = cpu_ppc_get_tb(tb_env, qemu_get_clock(vm_clock), tb_env->tb_offset);

    LOG_TB("%s: tb %016" PRIx64 "\n", __func__, tb);

    return tb >> 32;

}

uint32_t cpu_ppc_load_tbu (CPUState *env)

{

    return _cpu_ppc_load_tbu(env);

}

static inline void cpu_ppc_store_tb(ppc_tb_t *tb_env, uint64_t vmclk,

                                    int64_t *tb_offsetp, uint64_t value)

{

    *tb_offsetp = value - muldiv64(vmclk, tb_env->tb_freq, get_ticks_per_sec());

    LOG_TB("%s: tb %016" PRIx64 " offset %08" PRIx64 "\n",

                __func__, value, *tb_offsetp);

}

void cpu_ppc_store_tbl (CPUState *env, uint32_t value)

{

    ppc_tb_t *tb_env = env->tb_env;

    uint64_t tb;

    tb = cpu_ppc_get_tb(tb_env, qemu_get_clock(vm_clock), tb_env->tb_offset);

    tb &= 0xFFFFFFFF00000000ULL;

    cpu_ppc_store_tb(tb_env, qemu_get_clock(vm_clock),

                     &tb_env->tb_offset, tb | (uint64_t)value);

}

static inline void _cpu_ppc_store_tbu(CPUState *env, uint32_t value)

{

    ppc_tb_t *tb_env = env->tb_env;

    uint64_t tb;

    tb = cpu_ppc_get_tb(tb_env, qemu_get_clock(vm_clock), tb_env->tb_offset);

    tb &= 0x00000000FFFFFFFFULL;

    cpu_ppc_store_tb(tb_env, qemu_get_clock(vm_clock),

                     &tb_env->tb_offset, ((uint64_t)value << 32) | tb);

}

void cpu_ppc_store_tbu (CPUState *env, uint32_t value)

{

    _cpu_ppc_store_tbu(env, value);

}

uint64_t cpu_ppc_load_atbl (CPUState *env)

{

    ppc_tb_t *tb_env = env->tb_env;

    uint64_t tb;

    tb = cpu_ppc_get_tb(tb_env, qemu_get_clock(vm_clock), tb_env->atb_offset);

    LOG_TB("%s: tb %016" PRIx64 "\n", __func__, tb);

    return tb;

}

uint32_t cpu_ppc_load_atbu (CPUState *env)

{

    ppc_tb_t *tb_env = env->tb_env;

    uint64_t tb;

    tb = cpu_ppc_get_tb(tb_env, qemu_get_clock(vm_clock), tb_env->atb_offset);

    LOG_TB("%s: tb %016" PRIx64 "\n", __func__, tb);

    return tb >> 32;

}

void cpu_ppc_store_atbl (CPUState *env, uint32_t value)

{

    ppc_tb_t *tb_env = env->tb_env;

    uint64_t tb;

    tb = cpu_ppc_get_tb(tb_env, qemu_get_clock(vm_clock), tb_env->atb_offset);

    tb &= 0xFFFFFFFF00000000ULL;

    cpu_ppc_store_tb(tb_env, qemu_get_clock(vm_clock),

                     &tb_env->atb_offset, tb | (uint64_t)value);

}

void cpu_ppc_store_atbu (CPUState *env, uint32_t value)

{

    ppc_tb_t *tb_env = env->tb_env;

    uint64_t tb;

    tb = cpu_ppc_get_tb(tb_env, qemu_get_clock(vm_clock), tb_env->atb_offset);

    tb &= 0x00000000FFFFFFFFULL;

    cpu_ppc_store_tb(tb_env, qemu_get_clock(vm_clock),

                     &tb_env->atb_offset, ((uint64_t)value << 32) | tb);

}

static void cpu_ppc_tb_stop (CPUState *env)

{

    ppc_tb_t *tb_env = env->tb_env;

    uint64_t tb, atb, vmclk;

    /* If the time base is already frozen, do nothing */

    if (tb_env->tb_freq != 0) {

        vmclk = qemu_get_clock(vm_clock);

        /* Get the time base */

        tb = cpu_ppc_get_tb(tb_env, vmclk, tb_env->tb_offset);

        /* Get the alternate time base */

        atb = cpu_ppc_get_tb(tb_env, vmclk, tb_env->atb_offset);

        /* Store the time base value (ie compute the current offset) */

        cpu_ppc_store_tb(tb_env, vmclk, &tb_env->tb_offset, tb);

        /* Store the alternate time base value (compute the current offset) */

        cpu_ppc_store_tb(tb_env, vmclk, &tb_env->atb_offset, atb);

        /* Set the time base frequency to zero */

        tb_env->tb_freq = 0;

        /* Now, the time bases are frozen to tb_offset / atb_offset value */

    }

}

static void cpu_ppc_tb_start (CPUState *env)

{

    ppc_tb_t *tb_env = env->tb_env;

    uint64_t tb, atb, vmclk;

    /* If the time base is not frozen, do nothing */

    if (tb_env->tb_freq == 0) {

        vmclk = qemu_get_clock(vm_clock);

        /* Get the time base from tb_offset */

        tb = tb_env->tb_offset;

        /* Get the alternate time base from atb_offset */

        atb = tb_env->atb_offset;

        /* Restore the tb frequency from the decrementer frequency */

        tb_env->tb_freq = tb_env->decr_freq;

        /* Store the time base value */

        cpu_ppc_store_tb(tb_env, vmclk, &tb_env->tb_offset, tb);

        /* Store the alternate time base value */

        cpu_ppc_store_tb(tb_env, vmclk, &tb_env->atb_offset, atb);

    }

}

static inline uint32_t _cpu_ppc_load_decr(CPUState *env, uint64_t next)

{

    ppc_tb_t *tb_env = env->tb_env;

    uint32_t decr;

    int64_t diff;

    diff = next - qemu_get_clock(vm_clock);

    if (diff >= 0)

        decr = muldiv64(diff, tb_env->decr_freq, get_ticks_per_sec());

    else

        decr = -muldiv64(-diff, tb_env->decr_freq, get_ticks_per_sec());

    LOG_TB("%s: %08" PRIx32 "\n", __func__, decr);

    return decr;

}

uint32_t cpu_ppc_load_decr (CPUState *env)

{

    ppc_tb_t *tb_env = env->tb_env;

    return _cpu_ppc_load_decr(env, tb_env->decr_next);

}

uint32_t cpu_ppc_load_hdecr (CPUState *env)

{

    ppc_tb_t *tb_env = env->tb_env;

    return _cpu_ppc_load_decr(env, tb_env->hdecr_next);

}

uint64_t cpu_ppc_load_purr (CPUState *env)

{

    ppc_tb_t *tb_env = env->tb_env;

    uint64_t diff;

    diff = qemu_get_clock(vm_clock) - tb_env->purr_start;

    return tb_env->purr_load + muldiv64(diff, tb_env->tb_freq, get_ticks_per_sec());

}

/* When decrementer expires,

 * all we need to do is generate or queue a CPU exception

 */

static inline void cpu_ppc_decr_excp(CPUState *env)

{

    /* Raise it */

    LOG_TB("raise decrementer exception\n");

    ppc_set_irq(env, PPC_INTERRUPT_DECR, 1);

}

static inline void cpu_ppc_hdecr_excp(CPUState *env)

{

    /* Raise it */

    LOG_TB("raise decrementer exception\n");

    ppc_set_irq(env, PPC_INTERRUPT_HDECR, 1);

}

static void __cpu_ppc_store_decr (CPUState *env, uint64_t *nextp,

                                  struct QEMUTimer *timer,

                                  void (*raise_excp)(CPUState *),

                                  uint32_t decr, uint32_t value,

                                  int is_excp)

{

    ppc_tb_t *tb_env = env->tb_env;

    uint64_t now, next;

    LOG_TB("%s: %08" PRIx32 " => %08" PRIx32 "\n", __func__,

                decr, value);

    now = qemu_get_clock(vm_clock);

    next = now + muldiv64(value, get_ticks_per_sec(), tb_env->decr_freq);

    if (is_excp)

        next += *nextp - now;

    if (next == now)

        next++;

    *nextp = next;

    /* Adjust timer */

    qemu_mod_timer(timer, next);

    /* If we set a negative value and the decrementer was positive,

     * raise an exception.

     */

    if ((value & 0x80000000) && !(decr & 0x80000000))

        (*raise_excp)(env);

}

static inline void _cpu_ppc_store_decr(CPUState *env, uint32_t decr,

                                       uint32_t value, int is_excp)

{

    ppc_tb_t *tb_env = env->tb_env;

    __cpu_ppc_store_decr(env, &tb_env->decr_next, tb_env->decr_timer,

                         &cpu_ppc_decr_excp, decr, value, is_excp);

}

void cpu_ppc_store_decr (CPUState *env, uint32_t value)

{

    _cpu_ppc_store_decr(env, cpu_ppc_load_decr(env), value, 0);

}

static void cpu_ppc_decr_cb (void *opaque)

{

    _cpu_ppc_store_decr(opaque, 0x00000000, 0xFFFFFFFF, 1);

}

static inline void _cpu_ppc_store_hdecr(CPUState *env, uint32_t hdecr,

                                        uint32_t value, int is_excp)

{

    ppc_tb_t *tb_env = env->tb_env;

    if (tb_env->hdecr_timer != NULL) {

        __cpu_ppc_store_decr(env, &tb_env->hdecr_next, tb_env->hdecr_timer,

                             &cpu_ppc_hdecr_excp, hdecr, value, is_excp);

    }

}

void cpu_ppc_store_hdecr (CPUState *env, uint32_t value)

{

    _cpu_ppc_store_hdecr(env, cpu_ppc_load_hdecr(env), value, 0);

}

static void cpu_ppc_hdecr_cb (void *opaque)

{

    _cpu_ppc_store_hdecr(opaque, 0x00000000, 0xFFFFFFFF, 1);

}

void cpu_ppc_store_purr (CPUState *env, uint64_t value)

{

    ppc_tb_t *tb_env = env->tb_env;

    tb_env->purr_load = value;

    tb_env->purr_start = qemu_get_clock(vm_clock);

}

static void cpu_ppc_set_tb_clk (void *opaque, uint32_t freq)

{

    CPUState *env = opaque;

    ppc_tb_t *tb_env = env->tb_env;

    tb_env->tb_freq = freq;

    tb_env->decr_freq = freq;

    /* There is a bug in Linux 2.4 kernels:

     * if a decrementer exception is pending when it enables msr_ee at startup,

     * it's not ready to handle it...

     */

    _cpu_ppc_store_decr(env, 0xFFFFFFFF, 0xFFFFFFFF, 0);

    _cpu_ppc_store_hdecr(env, 0xFFFFFFFF, 0xFFFFFFFF, 0);

    cpu_ppc_store_purr(env, 0x0000000000000000ULL);

}

/* Set up (once) timebase frequency (in Hz) */

clk_setup_cb cpu_ppc_tb_init (CPUState *env, uint32_t freq)

{

    ppc_tb_t *tb_env;

    tb_env = qemu_mallocz(sizeof(ppc_tb_t));

    env->tb_env = tb_env;

    /* Create new timer */

    tb_env->decr_timer = qemu_new_timer(vm_clock, &cpu_ppc_decr_cb, env);

    if (0) {

        /* XXX: find a suitable condition to enable the hypervisor decrementer

         */

        tb_env->hdecr_timer = qemu_new_timer(vm_clock, &cpu_ppc_hdecr_cb, env);

    } else {

        tb_env->hdecr_timer = NULL;

    }

    cpu_ppc_set_tb_clk(env, freq);

    return &cpu_ppc_set_tb_clk;

}

/* Specific helpers for POWER & PowerPC 601 RTC */

#if 0

static clk_setup_cb cpu_ppc601_rtc_init (CPUState *env)

{

    return cpu_ppc_tb_init(env, 7812500);

}

#endif

void cpu_ppc601_store_rtcu (CPUState *env, uint32_t value)

{

    _cpu_ppc_store_tbu(env, value);

}

uint32_t cpu_ppc601_load_rtcu (CPUState *env)

{

    return _cpu_ppc_load_tbu(env);

}

void cpu_ppc601_store_rtcl (CPUState *env, uint32_t value)

{

    cpu_ppc_store_tbl(env, value & 0x3FFFFF80);

}

uint32_t cpu_ppc601_load_rtcl (CPUState *env)

{

    return cpu_ppc_load_tbl(env) & 0x3FFFFF80;

}

/*****************************************************************************/

/* Embedded PowerPC timers */

/* PIT, FIT & WDT */

typedef struct ppcemb_timer_t ppcemb_timer_t;

struct ppcemb_timer_t {

    uint64_t pit_reload;  /* PIT auto-reload value        */

    uint64_t fit_next;    /* Tick for next FIT interrupt  */

    struct QEMUTimer *fit_timer;

    uint64_t wdt_next;    /* Tick for next WDT interrupt  */

    struct QEMUTimer *wdt_timer;

};

/* Fixed interval timer */

static void cpu_4xx_fit_cb (void *opaque)

{

    CPUState *env;

    ppc_tb_t *tb_env;

    ppcemb_timer_t *ppcemb_timer;

    uint64_t now, next;

    env = opaque;

    tb_env = env->tb_env;

    ppcemb_timer = tb_env->opaque;

    now = qemu_get_clock(vm_clock);

    switch ((env->spr[SPR_40x_TCR] >> 24) & 0x3) {

    case 0:

        next = 1 << 9;

        break;

    case 1:

        next = 1 << 13;

        break;

    case 2:

        next = 1 << 17;

        break;

    case 3:

        next = 1 << 21;

        break;

    default:

        /* Cannot occur, but makes gcc happy */

        return;

    }

    next = now + muldiv64(next, get_ticks_per_sec(), tb_env->tb_freq);

    if (next == now)

        next++;

    qemu_mod_timer(ppcemb_timer->fit_timer, next);

    env->spr[SPR_40x_TSR] |= 1 << 26;

    if ((env->spr[SPR_40x_TCR] >> 23) & 0x1)

        ppc_set_irq(env, PPC_INTERRUPT_FIT, 1);

    LOG_TB("%s: ir %d TCR " TARGET_FMT_lx " TSR " TARGET_FMT_lx "\n", __func__,

           (int)((env->spr[SPR_40x_TCR] >> 23) & 0x1),

           env->spr[SPR_40x_TCR], env->spr[SPR_40x_TSR]);

}

/* Programmable interval timer */

static void start_stop_pit (CPUState *env, ppc_tb_t *tb_env, int is_excp)

{

    ppcemb_timer_t *ppcemb_timer;

    uint64_t now, next;

    ppcemb_timer = tb_env->opaque;

    if (ppcemb_timer->pit_reload <= 1 ||

        !((env->spr[SPR_40x_TCR] >> 26) & 0x1) ||

        (is_excp && !((env->spr[SPR_40x_TCR] >> 22) & 0x1))) {

        /* Stop PIT */

        LOG_TB("%s: stop PIT\n", __func__);

        qemu_del_timer(tb_env->decr_timer);

    } else {

        LOG_TB("%s: start PIT %016" PRIx64 "\n",

                    __func__, ppcemb_timer->pit_reload);

        now = qemu_get_clock(vm_clock);

        next = now + muldiv64(ppcemb_timer->pit_reload,

                              get_ticks_per_sec(), tb_env->decr_freq);

        if (is_excp)

            next += tb_env->decr_next - now;

        if (next == now)

            next++;

        qemu_mod_timer(tb_env->decr_timer, next);

        tb_env->decr_next = next;

    }

}

static void cpu_4xx_pit_cb (void *opaque)

{

    CPUState *env;

    ppc_tb_t *tb_env;

    ppcemb_timer_t *ppcemb_timer;

    env = opaque;

    tb_env = env->tb_env;

    ppcemb_timer = tb_env->opaque;

    env->spr[SPR_40x_TSR] |= 1 << 27;

    if ((env->spr[SPR_40x_TCR] >> 26) & 0x1)

        ppc_set_irq(env, PPC_INTERRUPT_PIT, 1);

    start_stop_pit(env, tb_env, 1);

    LOG_TB("%s: ar %d ir %d TCR " TARGET_FMT_lx " TSR " TARGET_FMT_lx " "

           "%016" PRIx64 "\n", __func__,

           (int)((env->spr[SPR_40x_TCR] >> 22) & 0x1),

           (int)((env->spr[SPR_40x_TCR] >> 26) & 0x1),

           env->spr[SPR_40x_TCR], env->spr[SPR_40x_TSR],

           ppcemb_timer->pit_reload);

}

/* Watchdog timer */

static void cpu_4xx_wdt_cb (void *opaque)

{

    CPUState *env;

    ppc_tb_t *tb_env;

    ppcemb_timer_t *ppcemb_timer;

    uint64_t now, next;

    env = opaque;

    tb_env = env->tb_env;

    ppcemb_timer = tb_env->opaque;

    now = qemu_get_clock(vm_clock);

    switch ((env->spr[SPR_40x_TCR] >> 30) & 0x3) {

    case 0:

        next = 1 << 17;

        break;

    case 1:

        next = 1 << 21;

        break;

    case 2:

        next = 1 << 25;

        break;

    case 3:

        next = 1 << 29;

        break;

    default:

        /* Cannot occur, but makes gcc happy */

        return;

    }

    next = now + muldiv64(next, get_ticks_per_sec(), tb_env->decr_freq);

    if (next == now)

        next++;

    LOG_TB("%s: TCR " TARGET_FMT_lx " TSR " TARGET_FMT_lx "\n", __func__,

           env->spr[SPR_40x_TCR], env->spr[SPR_40x_TSR]);

    switch ((env->spr[SPR_40x_TSR] >> 30) & 0x3) {

    case 0x0:

    case 0x1:

        qemu_mod_timer(ppcemb_timer->wdt_timer, next);

        ppcemb_timer->wdt_next = next;

        env->spr[SPR_40x_TSR] |= 1 << 31;

        break;

    case 0x2:

        qemu_mod_timer(ppcemb_timer->wdt_timer, next);

        ppcemb_timer->wdt_next = next;

        env->spr[SPR_40x_TSR] |= 1 << 30;

        if ((env->spr[SPR_40x_TCR] >> 27) & 0x1)

            ppc_set_irq(env, PPC_INTERRUPT_WDT, 1);

        break;

    case 0x3:

        env->spr[SPR_40x_TSR] &= ~0x30000000;

        env->spr[SPR_40x_TSR] |= env->spr[SPR_40x_TCR] & 0x30000000;

        switch ((env->spr[SPR_40x_TCR] >> 28) & 0x3) {

        case 0x0:

            /* No reset */

            break;

        case 0x1: /* Core reset */

            ppc40x_core_reset(env);

            break;

        case 0x2: /* Chip reset */

            ppc40x_chip_reset(env);

            break;

        case 0x3: /* System reset */

            ppc40x_system_reset(env);

            break;

        }

    }

}

void store_40x_pit (CPUState *env, target_ulong val)

{

    ppc_tb_t *tb_env;

    ppcemb_timer_t *ppcemb_timer;

    tb_env = env->tb_env;

    ppcemb_timer = tb_env->opaque;

    LOG_TB("%s val" TARGET_FMT_lx "\n", __func__, val);

    ppcemb_timer->pit_reload = val;

    start_stop_pit(env, tb_env, 0);

}

target_ulong load_40x_pit (CPUState *env)

{

    return cpu_ppc_load_decr(env);

}

void store_booke_tsr (CPUState *env, target_ulong val)

{

    LOG_TB("%s: val " TARGET_FMT_lx "\n", __func__, val);

    env->spr[SPR_40x_TSR] &= ~(val & 0xFC000000);

    if (val & 0x80000000)

        ppc_set_irq(env, PPC_INTERRUPT_PIT, 0);

}

void store_booke_tcr (CPUState *env, target_ulong val)

{

    ppc_tb_t *tb_env;

    tb_env = env->tb_env;

    LOG_TB("%s: val " TARGET_FMT_lx "\n", __func__, val);

    env->spr[SPR_40x_TCR] = val & 0xFFC00000;

    start_stop_pit(env, tb_env, 1);

    cpu_4xx_wdt_cb(env);

}

static void ppc_emb_set_tb_clk (void *opaque, uint32_t freq)

{

    CPUState *env = opaque;

    ppc_tb_t *tb_env = env->tb_env;

    LOG_TB("%s set new frequency to %" PRIu32 "\n", __func__,

                freq);

    tb_env->tb_freq = freq;

    tb_env->decr_freq = freq;

    /* XXX: we should also update all timers */

}

clk_setup_cb ppc_emb_timers_init (CPUState *env, uint32_t freq)

{

    ppc_tb_t *tb_env;

    ppcemb_timer_t *ppcemb_timer;

    tb_env = qemu_mallocz(sizeof(ppc_tb_t));

    env->tb_env = tb_env;

    ppcemb_timer = qemu_mallocz(sizeof(ppcemb_timer_t));

    tb_env->tb_freq = freq;

    tb_env->decr_freq = freq;

    tb_env->opaque = ppcemb_timer;

    LOG_TB("%s freq %" PRIu32 "\n", __func__, freq);

    if (ppcemb_timer != NULL) {

        /* We use decr timer for PIT */

        tb_env->decr_timer = qemu_new_timer(vm_clock, &cpu_4xx_pit_cb, env);

        ppcemb_timer->fit_timer =

            qemu_new_timer(vm_clock, &cpu_4xx_fit_cb, env);

        ppcemb_timer->wdt_timer =

            qemu_new_timer(vm_clock, &cpu_4xx_wdt_cb, env);

    }

    return &ppc_emb_set_tb_clk;

}

/*****************************************************************************/

/* Embedded PowerPC Device Control Registers */

typedef struct ppc_dcrn_t ppc_dcrn_t;

struct ppc_dcrn_t {

    dcr_read_cb dcr_read;

    dcr_write_cb dcr_write;

    void *opaque;

};

/* XXX: on 460, DCR addresses are 32 bits wide,

 *      using DCRIPR to get the 22 upper bits of the DCR address

 */

#define DCRN_NB 1024

struct ppc_dcr_t {

    ppc_dcrn_t dcrn[DCRN_NB];

    int (*read_error)(int dcrn);

    int (*write_error)(int dcrn);

};

int ppc_dcr_read (ppc_dcr_t *dcr_env, int dcrn, uint32_t *valp)

{

    ppc_dcrn_t *dcr;

    if (dcrn < 0 || dcrn >= DCRN_NB)

        goto error;

    dcr = &dcr_env->dcrn[dcrn];

    if (dcr->dcr_read == NULL)

        goto error;

    *valp = (*dcr->dcr_read)(dcr->opaque, dcrn);

    return 0;

 error:

    if (dcr_env->read_error != NULL)

        return (*dcr_env->read_error)(dcrn);

    return -1;

}

int ppc_dcr_write (ppc_dcr_t *dcr_env, int dcrn, uint32_t val)

{

    ppc_dcrn_t *dcr;

    if (dcrn < 0 || dcrn >= DCRN_NB)

        goto error;

    dcr = &dcr_env->dcrn[dcrn];

    if (dcr->dcr_write == NULL)

        goto error;

    (*dcr->dcr_write)(dcr->opaque, dcrn, val);

    return 0;

 error:

    if (dcr_env->write_error != NULL)

        return (*dcr_env->write_error)(dcrn);

    return -1;

}

int ppc_dcr_register (CPUState *env, int dcrn, void *opaque,

                      dcr_read_cb dcr_read, dcr_write_cb dcr_write)

{

    ppc_dcr_t *dcr_env;

    ppc_dcrn_t *dcr;

    dcr_env = env->dcr_env;

    if (dcr_env == NULL)

        return -1;

    if (dcrn < 0 || dcrn >= DCRN_NB)

        return -1;

    dcr = &dcr_env->dcrn[dcrn];

    if (dcr->opaque != NULL ||

        dcr->dcr_read != NULL ||

        dcr->dcr_write != NULL)

        return -1;

    dcr->opaque = opaque;

    dcr->dcr_read = dcr_read;

    dcr->dcr_write = dcr_write;

    return 0;

}

int ppc_dcr_init (CPUState *env, int (*read_error)(int dcrn),

                  int (*write_error)(int dcrn))

{

    ppc_dcr_t *dcr_env;

    dcr_env = qemu_mallocz(sizeof(ppc_dcr_t));

    dcr_env->read_error = read_error;

    dcr_env->write_error = write_error;

    env->dcr_env = dcr_env;

    return 0;

}

/*****************************************************************************/

/* Debug port */

void PPC_debug_write (void *opaque, uint32_t addr, uint32_t val)

{

    addr &= 0xF;

    switch (addr) {

    case 0:

        printf("%c", val);

        break;

    case 1:

        printf("\n");

        fflush(stdout);

        break;

    case 2:

        printf("Set loglevel to %04" PRIx32 "\n", val);

        cpu_set_log(val | 0x100);

        break;

    }

}

/*****************************************************************************/

/* NVRAM helpers */

static inline uint32_t nvram_read (nvram_t *nvram, uint32_t addr)

{

    return (*nvram->read_fn)(nvram->opaque, addr);;

}

static inline void nvram_write (nvram_t *nvram, uint32_t addr, uint32_t val)

{

    (*nvram->write_fn)(nvram->opaque, addr, val);

}

void NVRAM_set_byte (nvram_t *nvram, uint32_t addr, uint8_t value)

{

    nvram_write(nvram, addr, value);

}

uint8_t NVRAM_get_byte (nvram_t *nvram, uint32_t addr)

{

    return nvram_read(nvram, addr);

}

void NVRAM_set_word (nvram_t *nvram, uint32_t addr, uint16_t value)

{

    nvram_write(nvram, addr, value >> 8);

    nvram_write(nvram, addr + 1, value & 0xFF);

}

uint16_t NVRAM_get_word (nvram_t *nvram, uint32_t addr)

{

    uint16_t tmp;

    tmp = nvram_read(nvram, addr) << 8;

    tmp |= nvram_read(nvram, addr + 1);

    return tmp;

}

void NVRAM_set_lword (nvram_t *nvram, uint32_t addr, uint32_t value)

{

    nvram_write(nvram, addr, value >> 24);

    nvram_write(nvram, addr + 1, (value >> 16) & 0xFF);

    nvram_write(nvram, addr + 2, (value >> 8) & 0xFF);

    nvram_write(nvram, addr + 3, value & 0xFF);

}

uint32_t NVRAM_get_lword (nvram_t *nvram, uint32_t addr)

{

    uint32_t tmp;

    tmp = nvram_read(nvram, addr) << 24;

    tmp |= nvram_read(nvram, addr + 1) << 16;

    tmp |= nvram_read(nvram, addr + 2) << 8;

    tmp |= nvram_read(nvram, addr + 3);

    return tmp;

}

void NVRAM_set_string (nvram_t *nvram, uint32_t addr,

                       const char *str, uint32_t max)

{

    int i;

    for (i = 0; i < max && str[i] != '\0'; i++) {

        nvram_write(nvram, addr + i, str[i]);

    }

    nvram_write(nvram, addr + i, str[i]);

    nvram_write(nvram, addr + max - 1, '\0');

}

int NVRAM_get_string (nvram_t *nvram, uint8_t *dst, uint16_t addr, int max)

{

    int i;

    memset(dst, 0, max);

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

        dst[i] = NVRAM_get_byte(nvram, addr + i);

        if (dst[i] == '\0')

            break;

    }

    return i;

}

static uint16_t NVRAM_crc_update (uint16_t prev, uint16_t value)

{

    uint16_t tmp;

    uint16_t pd, pd1, pd2;

    tmp = prev >> 8;

    pd = prev ^ value;

    pd1 = pd & 0x000F;

    pd2 = ((pd >> 4) & 0x000F) ^ pd1;

    tmp ^= (pd1 << 3) | (pd1 << 8);

    tmp ^= pd2 | (pd2 << 7) | (pd2 << 12);

    return tmp;

}

static uint16_t NVRAM_compute_crc (nvram_t *nvram, uint32_t start, uint32_t count)

{

    uint32_t i;

    uint16_t crc = 0xFFFF;

    int odd;

    odd = count & 1;

    count &= ~1;

    for (i = 0; i != count; i++) {

        crc = NVRAM_crc_update(crc, NVRAM_get_word(nvram, start + i));

    }

    if (odd) {

        crc = NVRAM_crc_update(crc, NVRAM_get_byte(nvram, start + i) << 8);

    }

    return crc;

}

#define CMDLINE_ADDR 0x017ff000

int PPC_NVRAM_set_params (nvram_t *nvram, uint16_t NVRAM_size,

                          const char *arch,

                          uint32_t RAM_size, int boot_device,

                          uint32_t kernel_image, uint32_t kernel_size,

                          const char *cmdline,

                          uint32_t initrd_image, uint32_t initrd_size,

                          uint32_t NVRAM_image,

                          int width, int height, int depth)

{

    uint16_t crc;

    /* Set parameters for Open Hack'Ware BIOS */

    NVRAM_set_string(nvram, 0x00, "QEMU_BIOS", 16);

    NVRAM_set_lword(nvram,  0x10, 0x00000002); /* structure v2 */

    NVRAM_set_word(nvram,   0x14, NVRAM_size);

    NVRAM_set_string(nvram, 0x20, arch, 16);

    NVRAM_set_lword(nvram,  0x30, RAM_size);

    NVRAM_set_byte(nvram,   0x34, boot_device);

    NVRAM_set_lword(nvram,  0x38, kernel_image);

    NVRAM_set_lword(nvram,  0x3C, kernel_size);

    if (cmdline) {

        /* XXX: put the cmdline in NVRAM too ? */

        pstrcpy_targphys("cmdline", CMDLINE_ADDR, RAM_size - CMDLINE_ADDR, cmdline);

        NVRAM_set_lword(nvram,  0x40, CMDLINE_ADDR);

        NVRAM_set_lword(nvram,  0x44, strlen(cmdline));

    } else {

        NVRAM_set_lword(nvram,  0x40, 0);

        NVRAM_set_lword(nvram,  0x44, 0);

    }

    NVRAM_set_lword(nvram,  0x48, initrd_image);

    NVRAM_set_lword(nvram,  0x4C, initrd_size);

    NVRAM_set_lword(nvram,  0x50, NVRAM_image);

    NVRAM_set_word(nvram,   0x54, width);

    NVRAM_set_word(nvram,   0x56, height);

    NVRAM_set_word(nvram,   0x58, depth);

    crc = NVRAM_compute_crc(nvram, 0x00, 0xF8);

    NVRAM_set_word(nvram,   0xFC, crc);

    return 0;

}