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rpcs3/Utilities/sync.h

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#pragma once
/* For internal use. Don't include. */
#include "types.h"
#include "Atomic.h"
#ifdef _WIN32
#include <Windows.h>
#define DYNAMIC_IMPORT(handle, name) do { name = reinterpret_cast<decltype(name)>(GetProcAddress(handle, #name)); } while (0)
static NTSTATUS(*NtSetTimerResolution)(ULONG DesiredResolution, BOOLEAN SetResolution, PULONG CurrentResolution);
static NTSTATUS(*NtWaitForKeyedEvent)(HANDLE Handle, PVOID Key, BOOLEAN Alertable, PLARGE_INTEGER Timeout);
static NTSTATUS(*NtReleaseKeyedEvent)(HANDLE Handle, PVOID Key, BOOLEAN Alertable, PLARGE_INTEGER Timeout);
namespace util
{
static const bool keyed_init = []
{
const auto handle = LoadLibraryA("ntdll.dll");
DYNAMIC_IMPORT(handle, NtSetTimerResolution);
DYNAMIC_IMPORT(handle, NtWaitForKeyedEvent);
DYNAMIC_IMPORT(handle, NtReleaseKeyedEvent);
FreeLibrary(handle);
ULONG res = 100;
NtSetTimerResolution(100, TRUE, &res);
return NtWaitForKeyedEvent && NtReleaseKeyedEvent;
}();
// Wait for specified condition. func() acknowledges success by value modification.
template<typename F>
inline void keyed_wait(atomic_t<u32>& key, F&& func)
{
while (true)
{
u32 read = key.load();
u32 copy = read;
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while (func(read), read != copy)
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{
read = key.compare_and_swap(copy, read);
if (copy == read)
{
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return;
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}
copy = read;
}
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NtWaitForKeyedEvent(NULL, &key, FALSE, NULL);
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}
}
// Try to wake up a thread.
inline bool keyed_post(atomic_t<u32>& key, u32 acknowledged_value)
{
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LARGE_INTEGER timeout;
timeout.QuadPart = -50;
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while (UNLIKELY(NtReleaseKeyedEvent(NULL, &key, FALSE, &timeout) != ERROR_SUCCESS))
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{
if (key.load() != acknowledged_value)
return false;
}
return true;
}
struct native_rwlock
{
SRWLOCK rwlock = SRWLOCK_INIT;
constexpr native_rwlock() = default;
native_rwlock(const native_rwlock&) = delete;
void lock()
{
AcquireSRWLockExclusive(&rwlock);
}
bool try_lock()
{
return TryAcquireSRWLockExclusive(&rwlock) != 0;
}
void unlock()
{
ReleaseSRWLockExclusive(&rwlock);
}
void lock_shared()
{
AcquireSRWLockShared(&rwlock);
}
bool try_lock_shared()
{
return TryAcquireSRWLockShared(&rwlock) != 0;
}
void unlock_shared()
{
ReleaseSRWLockShared(&rwlock);
}
};
struct native_cond
{
CONDITION_VARIABLE cond = CONDITION_VARIABLE_INIT;
constexpr native_cond() = default;
native_cond(const native_cond&) = delete;
void notify_one()
{
WakeConditionVariable(&cond);
}
void notify_all()
{
WakeAllConditionVariable(&cond);
}
void wait(native_rwlock& rwlock)
{
SleepConditionVariableSRW(&cond, &rwlock.rwlock, INFINITE, 0);
}
void wait_shared(native_rwlock& rwlock)
{
SleepConditionVariableSRW(&cond, &rwlock.rwlock, INFINITE, CONDITION_VARIABLE_LOCKMODE_SHARED);
}
};
class exclusive_lock
{
native_rwlock& m_rwlock;
public:
exclusive_lock(native_rwlock& rwlock)
: m_rwlock(rwlock)
{
m_rwlock.lock();
}
~exclusive_lock()
{
m_rwlock.unlock();
}
};
class shared_lock
{
native_rwlock& m_rwlock;
public:
shared_lock(native_rwlock& rwlock)
: m_rwlock(rwlock)
{
m_rwlock.lock_shared();
}
~shared_lock()
{
m_rwlock.unlock_shared();
}
};
}
#else
namespace util
{
struct native_rwlock;
struct native_cond;
}
#endif
CHECK_SIZE_ALIGN(util::native_rwlock, sizeof(void*), alignof(void*));
CHECK_SIZE_ALIGN(util::native_cond, sizeof(void*), alignof(void*));