mesa/src/c11/impl/threads_win32.c

/*
 * SPDX-License-Identifier: BSL-1.0
 * Copyright yohhoy 2012.
 */
#include <assert.h>
#include <limits.h>
#include <errno.h>
#include <process.h>  // MSVCRT
#include <stdlib.h>
#include <stdbool.h>

#include "c11/threads.h"

#include "threads_win32.h"

#include <windows.h>

/*
Configuration macro:
  EMULATED_THREADS_TSS_DTOR_SLOTNUM
    Max registerable TSS dtor number.
*/

#define EMULATED_THREADS_TSS_DTOR_SLOTNUM 64  // see TLS_MINIMUM_AVAILABLE


static_assert(sizeof(cnd_t) == sizeof(CONDITION_VARIABLE), "The size of cnd_t must equal to CONDITION_VARIABLE");
static_assert(sizeof(thrd_t) == sizeof(HANDLE), "The size of thrd_t must equal to HANDLE");
static_assert(sizeof(tss_t) == sizeof(DWORD), "The size of tss_t must equal to DWORD");
static_assert(sizeof(mtx_t) == sizeof(CRITICAL_SECTION), "The size of mtx_t must equal to CRITICAL_SECTION");
static_assert(sizeof(once_flag) == sizeof(INIT_ONCE), "The size of once_flag must equal to INIT_ONCE");

/*
Implementation limits:
  - Emulated `mtx_timelock()' with mtx_trylock() + *busy loop*
*/

struct impl_thrd_param {
    thrd_start_t func;
    void *arg;
    thrd_t thrd;
};

struct thrd_state {
    thrd_t thrd;
    bool handle_need_close;
};

static thread_local struct thrd_state impl_current_thread = { 0 };

static unsigned __stdcall impl_thrd_routine(void *p)
{
    struct impl_thrd_param *pack_p = (struct impl_thrd_param *)p;
    struct impl_thrd_param pack;
    int code;
    impl_current_thread.thrd = pack_p->thrd;
    impl_current_thread.handle_need_close = false;
    memcpy(&pack, pack_p, sizeof(struct impl_thrd_param));
    free(p);
    code = pack.func(pack.arg);
    return (unsigned)code;
}

static time_t impl_timespec2msec(const struct timespec *ts)
{
    return (ts->tv_sec * 1000U) + (ts->tv_nsec / 1000000L);
}

static DWORD impl_abs2relmsec(const struct timespec *abs_time)
{
    const time_t abs_ms = impl_timespec2msec(abs_time);
    struct timespec now;
    timespec_get(&now, TIME_UTC);
    const time_t now_ms = impl_timespec2msec(&now);
    const DWORD rel_ms = (abs_ms > now_ms) ? (DWORD)(abs_ms - now_ms) : 0;
    return rel_ms;
}

struct impl_call_once_param { void (*func)(void); };
static BOOL CALLBACK impl_call_once_callback(PINIT_ONCE InitOnce, PVOID Parameter, PVOID *Context)
{
    struct impl_call_once_param *param = (struct impl_call_once_param*)Parameter;
    (param->func)();
    ((void)InitOnce); ((void)Context);  // suppress warning
    return true;
}

static struct impl_tss_dtor_entry {
    tss_t key;
    tss_dtor_t dtor;
} impl_tss_dtor_tbl[EMULATED_THREADS_TSS_DTOR_SLOTNUM];

static int impl_tss_dtor_register(tss_t key, tss_dtor_t dtor)
{
    int i;
    for (i = 0; i < EMULATED_THREADS_TSS_DTOR_SLOTNUM; i++) {
        if (!impl_tss_dtor_tbl[i].dtor)
            break;
    }
    if (i == EMULATED_THREADS_TSS_DTOR_SLOTNUM)
        return 1;
    impl_tss_dtor_tbl[i].key = key;
    impl_tss_dtor_tbl[i].dtor = dtor;
    return 0;
}

static void impl_tss_dtor_invoke(void)
{
    int i;
    for (i = 0; i < EMULATED_THREADS_TSS_DTOR_SLOTNUM; i++) {
        if (impl_tss_dtor_tbl[i].dtor) {
            void* val = tss_get(impl_tss_dtor_tbl[i].key);
            if (val)
                (impl_tss_dtor_tbl[i].dtor)(val);
        }
    }
}


/*--------------- 7.25.2 Initialization functions ---------------*/
// 7.25.2.1
void
call_once(once_flag *flag, void (*func)(void))
{
    assert(flag && func);
    struct impl_call_once_param param;
    param.func = func;
    InitOnceExecuteOnce((PINIT_ONCE)flag, impl_call_once_callback, (PVOID)&param, NULL);
}


/*------------- 7.25.3 Condition variable functions -------------*/
// 7.25.3.1
int
cnd_broadcast(cnd_t *cond)
{
    assert(cond != NULL);
    WakeAllConditionVariable((PCONDITION_VARIABLE)cond);
    return thrd_success;
}

// 7.25.3.2
void
cnd_destroy(cnd_t *cond)
{
    (void)cond;
    assert(cond != NULL);
    // do nothing
}

// 7.25.3.3
int
cnd_init(cnd_t *cond)
{
    assert(cond != NULL);
    InitializeConditionVariable((PCONDITION_VARIABLE)cond);
    return thrd_success;
}

// 7.25.3.4
int
cnd_signal(cnd_t *cond)
{
    assert(cond != NULL);
    WakeConditionVariable((PCONDITION_VARIABLE)cond);
    return thrd_success;
}

// 7.25.3.5
int
cnd_timedwait(cnd_t *cond, mtx_t *mtx, const struct timespec *abs_time)
{
    assert(cond != NULL);
    assert(mtx != NULL);
    assert(abs_time != NULL);
    const DWORD timeout = impl_abs2relmsec(abs_time);
    if (SleepConditionVariableCS((PCONDITION_VARIABLE)cond, (PCRITICAL_SECTION)mtx, timeout))
        return thrd_success;
    return (GetLastError() == ERROR_TIMEOUT) ? thrd_timedout : thrd_error;
}

// 7.25.3.6
int
cnd_wait(cnd_t *cond, mtx_t *mtx)
{
    assert(cond != NULL);
    assert(mtx != NULL);
    SleepConditionVariableCS((PCONDITION_VARIABLE)cond, (PCRITICAL_SECTION)mtx, INFINITE);
    return thrd_success;
}


/*-------------------- 7.25.4 Mutex functions --------------------*/
// 7.25.4.1
void
mtx_destroy(mtx_t *mtx)
{
    assert(mtx);
    DeleteCriticalSection((PCRITICAL_SECTION)mtx);
}

// 7.25.4.2
int
mtx_init(mtx_t *mtx, int type)
{
    assert(mtx != NULL);
    if (type != mtx_plain && type != mtx_timed
      && type != (mtx_plain|mtx_recursive)
      && type != (mtx_timed|mtx_recursive))
        return thrd_error;
    InitializeCriticalSection((PCRITICAL_SECTION)mtx);
    return thrd_success;
}

// 7.25.4.3
int
mtx_lock(mtx_t *mtx)
{
    assert(mtx != NULL);
    EnterCriticalSection((PCRITICAL_SECTION)mtx);
    return thrd_success;
}

// 7.25.4.4
int
mtx_timedlock(mtx_t *mtx, const struct timespec *ts)
{
    assert(mtx != NULL);
    assert(ts != NULL);
    while (mtx_trylock(mtx) != thrd_success) {
        if (impl_abs2relmsec(ts) == 0)
            return thrd_timedout;
        // busy loop!
        thrd_yield();
    }
    return thrd_success;
}

// 7.25.4.5
int
mtx_trylock(mtx_t *mtx)
{
    assert(mtx != NULL);
    return TryEnterCriticalSection((PCRITICAL_SECTION)mtx) ? thrd_success : thrd_busy;
}

// 7.25.4.6
int
mtx_unlock(mtx_t *mtx)
{
    assert(mtx != NULL);
    LeaveCriticalSection((PCRITICAL_SECTION)mtx);
    return thrd_success;
}

void
__threads_win32_tls_callback(void)
{
    struct thrd_state *state = &impl_current_thread;
    impl_tss_dtor_invoke();
    if (state->handle_need_close) {
        state->handle_need_close = false;
        CloseHandle(state->thrd.handle);
    }
}

/*------------------- 7.25.5 Thread functions -------------------*/
// 7.25.5.1
int
thrd_create(thrd_t *thr, thrd_start_t func, void *arg)
{
    struct impl_thrd_param *pack;
    uintptr_t handle;
    assert(thr != NULL);
    pack = (struct impl_thrd_param *)malloc(sizeof(struct impl_thrd_param));
    if (!pack) return thrd_nomem;
    pack->func = func;
    pack->arg = arg;
    handle = _beginthreadex(NULL, 0, impl_thrd_routine, pack, CREATE_SUSPENDED, NULL);
    if (handle == 0) {
        free(pack);
        if (errno == EAGAIN || errno == EACCES)
            return thrd_nomem;
        return thrd_error;
    }
    thr->handle = (void*)handle;
    pack->thrd = *thr;
    ResumeThread((HANDLE)handle);
    return thrd_success;
}

// 7.25.5.2
thrd_t
thrd_current(void)
{
    /* GetCurrentThread() returns a pseudo-handle, which we need
     * to pass to DuplicateHandle(). Only the resulting handle can be used
     * from other threads.
     *
     * Note that neither handle can be compared to the one by thread_create.
     * Only the thread IDs - as returned by GetThreadId() and GetCurrentThreadId()
     * can be compared directly.
     *
     * Other potential solutions would be:
     * - define thrd_t as a thread Ids, but this would mean we'd need to OpenThread for many operations
     * - use malloc'ed memory for thrd_t. This would imply using TLS for current thread.
     *
     * Neither is particularly nice.
     *
     * Life would be much easier if C11 threads had different abstractions for
     * threads and thread IDs, just like C++11 threads does...
     */
    struct thrd_state *state = &impl_current_thread;
    if (state->thrd.handle == NULL)
    {
        if (!DuplicateHandle(GetCurrentProcess(), GetCurrentThread(), GetCurrentProcess(),
            &(state->thrd.handle), 0, false, DUPLICATE_SAME_ACCESS))
        {
            abort();
        }
        state->handle_need_close = true;
    }
    return state->thrd;
}

// 7.25.5.3
int
thrd_detach(thrd_t thr)
{
    CloseHandle(thr.handle);
    return thrd_success;
}

// 7.25.5.4
int
thrd_equal(thrd_t thr0, thrd_t thr1)
{
    return GetThreadId(thr0.handle) == GetThreadId(thr1.handle);
}

// 7.25.5.5
_Noreturn
void
thrd_exit(int res)
{
    _endthreadex((unsigned)res);
}

// 7.25.5.6
int
thrd_join(thrd_t thr, int *res)
{
    DWORD w, code;
    if (thr.handle == NULL) {
        return thrd_error;
    }
    w = WaitForSingleObject(thr.handle, INFINITE);
    if (w != WAIT_OBJECT_0)
        return thrd_error;
    if (res) {
        if (!GetExitCodeThread(thr.handle, &code)) {
            CloseHandle(thr.handle);
            return thrd_error;
        }
        *res = (int)code;
    }
    CloseHandle(thr.handle);
    return thrd_success;
}

// 7.25.5.7
int
thrd_sleep(const struct timespec *time_point, struct timespec *remaining)
{
    (void)remaining;
    assert(time_point);
    assert(!remaining); /* not implemented */
    Sleep((DWORD)impl_timespec2msec(time_point));
    return 0;
}

// 7.25.5.8
void
thrd_yield(void)
{
    SwitchToThread();
}


/*----------- 7.25.6 Thread-specific storage functions -----------*/
// 7.25.6.1
int
tss_create(tss_t *key, tss_dtor_t dtor)
{
    assert(key != NULL);
    *key = TlsAlloc();
    if (dtor) {
        if (impl_tss_dtor_register(*key, dtor)) {
            TlsFree(*key);
            return thrd_error;
        }
    }
    return (*key != 0xFFFFFFFF) ? thrd_success : thrd_error;
}

// 7.25.6.2
void
tss_delete(tss_t key)
{
    TlsFree(key);
}

// 7.25.6.3
void *
tss_get(tss_t key)
{
    return TlsGetValue(key);
}

// 7.25.6.4
int
tss_set(tss_t key, void *val)
{
    return TlsSetValue(key, val) ? thrd_success : thrd_error;
}