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mirror of https://github.com/RPCS3/rpcs3.git synced 2024-11-22 18:53:28 +01:00
rpcs3/Utilities/Thread.h
2015-07-10 04:31:36 +03:00

491 lines
9.5 KiB
C++

#pragma once
const class thread_ctrl_t* get_current_thread_ctrl();
// named thread control class
class thread_ctrl_t final
{
friend class thread_t;
// thread handler
std::thread m_thread;
// name getter
const std::function<std::string()> name;
// true if assigned somewhere in TLS
std::atomic<bool> assigned{ false };
// assign TLS (must be assigned only once)
void set_current();
public:
thread_ctrl_t(std::function<std::string()> name)
: name(std::move(name))
{
}
// get thread name
std::string get_name() const;
};
class thread_t
{
// pointer to managed resource (shared with actual thread)
std::shared_ptr<thread_ctrl_t> m_thread;
public:
// thread mutex for external use
std::mutex mutex;
// thread condition variable for external use
std::condition_variable cv;
public:
// initialize in empty state
thread_t() = default;
// create named thread
thread_t(std::function<std::string()> name, std::function<void()> func);
// destructor, joins automatically (questionable, don't rely on this functionality in derived destructors)
virtual ~thread_t() noexcept(false);
thread_t(const thread_t&) = delete;
thread_t& operator =(const thread_t&) = delete;
public:
// get thread name
std::string get_name() const;
// create named thread (current state must be empty)
void start(std::function<std::string()> name, std::function<void()> func);
// detach thread -> empty state
void detach();
// join thread -> empty state
void join();
// check if not empty
bool joinable() const { return m_thread.operator bool(); }
// check whether it is the current running thread
bool is_current() const;
};
class autojoin_thread_t final : private thread_t
{
public:
using thread_t::mutex;
using thread_t::cv;
public:
autojoin_thread_t() = delete;
autojoin_thread_t(std::function<std::string()> name, std::function<void()> func)
{
start(std::move(name), std::move(func));
}
virtual ~autojoin_thread_t() override
{
join();
}
using thread_t::is_current;
};
struct waiter_map_t
{
static const size_t size = 16;
std::array<std::mutex, size> mutexes;
std::array<std::condition_variable, size> cvs;
const std::string name;
waiter_map_t(const char* name)
: name(name)
{
}
// generate simple "hash" for mutex/cv distribution
u32 get_hash(u32 addr)
{
addr ^= addr >> 16;
addr ^= addr >> 24;
addr ^= addr >> 28;
return addr % size;
}
void check_emu_status(u32 addr);
// wait until pred() returns true, `addr` is an arbitrary number
template<typename F, typename... Args> safe_buffers auto wait_op(u32 addr, F pred, Args&&... args) -> decltype(static_cast<void>(pred(args...)))
{
const u32 hash = get_hash(addr);
// set mutex locker
std::unique_lock<std::mutex> lock(mutexes[hash], std::defer_lock);
while (true)
{
// check the condition
if (pred(args...)) return;
check_emu_status(addr);
if (!lock)
{
lock.lock();
continue;
}
// wait on an appropriate cond var for 1 ms or until a signal arrived
cvs[hash].wait_for(lock, std::chrono::milliseconds(1));
}
}
// signal all threads waiting on wait_op() with the same `addr` (signaling only hints those threads that corresponding conditions are *probably* met)
void notify(u32 addr);
};
extern const std::function<bool()> SQUEUE_ALWAYS_EXIT;
extern const std::function<bool()> SQUEUE_NEVER_EXIT;
bool squeue_test_exit();
template<typename T, u32 sq_size = 256>
class squeue_t
{
struct squeue_sync_var_t
{
struct
{
u32 position : 31;
u32 pop_lock : 1;
};
struct
{
u32 count : 31;
u32 push_lock : 1;
};
};
atomic_t<squeue_sync_var_t> m_sync;
mutable std::mutex m_rcv_mutex;
mutable std::mutex m_wcv_mutex;
mutable std::condition_variable m_rcv;
mutable std::condition_variable m_wcv;
T m_data[sq_size];
enum squeue_sync_var_result : u32
{
SQSVR_OK = 0,
SQSVR_LOCKED = 1,
SQSVR_FAILED = 2,
};
public:
squeue_t()
: m_sync({})
{
}
u32 get_max_size() const
{
return sq_size;
}
bool is_full() const volatile
{
return m_sync.data.count == sq_size;
}
bool push(const T& data, const std::function<bool()>& test_exit)
{
u32 pos = 0;
while (u32 res = m_sync.atomic_op([&pos](squeue_sync_var_t& sync) -> u32
{
assert(sync.count <= sq_size);
assert(sync.position < sq_size);
if (sync.push_lock)
{
return SQSVR_LOCKED;
}
if (sync.count == sq_size)
{
return SQSVR_FAILED;
}
sync.push_lock = 1;
pos = sync.position + sync.count;
return SQSVR_OK;
}))
{
if (res == SQSVR_FAILED && (test_exit() || squeue_test_exit()))
{
return false;
}
std::unique_lock<std::mutex> wcv_lock(m_wcv_mutex);
m_wcv.wait_for(wcv_lock, std::chrono::milliseconds(1));
}
m_data[pos >= sq_size ? pos - sq_size : pos] = data;
m_sync.atomic_op([](squeue_sync_var_t& sync)
{
assert(sync.count <= sq_size);
assert(sync.position < sq_size);
assert(sync.push_lock);
sync.push_lock = 0;
sync.count++;
});
m_rcv.notify_one();
m_wcv.notify_one();
return true;
}
bool push(const T& data, const volatile bool* do_exit)
{
return push(data, [do_exit](){ return do_exit && *do_exit; });
}
force_inline bool push(const T& data)
{
return push(data, SQUEUE_NEVER_EXIT);
}
force_inline bool try_push(const T& data)
{
return push(data, SQUEUE_ALWAYS_EXIT);
}
bool pop(T& data, const std::function<bool()>& test_exit)
{
u32 pos = 0;
while (u32 res = m_sync.atomic_op([&pos](squeue_sync_var_t& sync) -> u32
{
assert(sync.count <= sq_size);
assert(sync.position < sq_size);
if (!sync.count)
{
return SQSVR_FAILED;
}
if (sync.pop_lock)
{
return SQSVR_LOCKED;
}
sync.pop_lock = 1;
pos = sync.position;
return SQSVR_OK;
}))
{
if (res == SQSVR_FAILED && (test_exit() || squeue_test_exit()))
{
return false;
}
std::unique_lock<std::mutex> rcv_lock(m_rcv_mutex);
m_rcv.wait_for(rcv_lock, std::chrono::milliseconds(1));
}
data = m_data[pos];
m_sync.atomic_op([](squeue_sync_var_t& sync)
{
assert(sync.count <= sq_size);
assert(sync.position < sq_size);
assert(sync.pop_lock);
sync.pop_lock = 0;
sync.position++;
sync.count--;
if (sync.position == sq_size)
{
sync.position = 0;
}
});
m_rcv.notify_one();
m_wcv.notify_one();
return true;
}
bool pop(T& data, const volatile bool* do_exit)
{
return pop(data, [do_exit](){ return do_exit && *do_exit; });
}
force_inline bool pop(T& data)
{
return pop(data, SQUEUE_NEVER_EXIT);
}
force_inline bool try_pop(T& data)
{
return pop(data, SQUEUE_ALWAYS_EXIT);
}
bool peek(T& data, u32 start_pos, const std::function<bool()>& test_exit)
{
assert(start_pos < sq_size);
u32 pos = 0;
while (u32 res = m_sync.atomic_op([&pos, start_pos](squeue_sync_var_t& sync) -> u32
{
assert(sync.count <= sq_size);
assert(sync.position < sq_size);
if (sync.count <= start_pos)
{
return SQSVR_FAILED;
}
if (sync.pop_lock)
{
return SQSVR_LOCKED;
}
sync.pop_lock = 1;
pos = sync.position + start_pos;
return SQSVR_OK;
}))
{
if (res == SQSVR_FAILED && (test_exit() || squeue_test_exit()))
{
return false;
}
std::unique_lock<std::mutex> rcv_lock(m_rcv_mutex);
m_rcv.wait_for(rcv_lock, std::chrono::milliseconds(1));
}
data = m_data[pos >= sq_size ? pos - sq_size : pos];
m_sync.atomic_op([](squeue_sync_var_t& sync)
{
assert(sync.count <= sq_size);
assert(sync.position < sq_size);
assert(sync.pop_lock);
sync.pop_lock = 0;
});
m_rcv.notify_one();
return true;
}
bool peek(T& data, u32 start_pos, const volatile bool* do_exit)
{
return peek(data, start_pos, [do_exit](){ return do_exit && *do_exit; });
}
force_inline bool peek(T& data, u32 start_pos = 0)
{
return peek(data, start_pos, SQUEUE_NEVER_EXIT);
}
force_inline bool try_peek(T& data, u32 start_pos = 0)
{
return peek(data, start_pos, SQUEUE_ALWAYS_EXIT);
}
class squeue_data_t
{
T* const m_data;
const u32 m_pos;
const u32 m_count;
squeue_data_t(T* data, u32 pos, u32 count)
: m_data(data)
, m_pos(pos)
, m_count(count)
{
}
public:
T& operator [] (u32 index)
{
assert(index < m_count);
index += m_pos;
index = index < sq_size ? index : index - sq_size;
return m_data[index];
}
};
void process(void(*proc)(squeue_data_t data))
{
u32 pos, count;
while (m_sync.atomic_op([&pos, &count](squeue_sync_var_t& sync) -> u32
{
assert(sync.count <= sq_size);
assert(sync.position < sq_size);
if (sync.pop_lock || sync.push_lock)
{
return SQSVR_LOCKED;
}
pos = sync.position;
count = sync.count;
sync.pop_lock = 1;
sync.push_lock = 1;
return SQSVR_OK;
}))
{
std::unique_lock<std::mutex> rcv_lock(m_rcv_mutex);
m_rcv.wait_for(rcv_lock, std::chrono::milliseconds(1));
}
proc(squeue_data_t(m_data, pos, count));
m_sync.atomic_op([](squeue_sync_var_t& sync)
{
assert(sync.count <= sq_size);
assert(sync.position < sq_size);
assert(sync.pop_lock && sync.push_lock);
sync.pop_lock = 0;
sync.push_lock = 0;
});
m_wcv.notify_one();
m_rcv.notify_one();
}
void clear()
{
while (m_sync.atomic_op([](squeue_sync_var_t& sync) -> u32
{
assert(sync.count <= sq_size);
assert(sync.position < sq_size);
if (sync.pop_lock || sync.push_lock)
{
return SQSVR_LOCKED;
}
sync.pop_lock = 1;
sync.push_lock = 1;
return SQSVR_OK;
}))
{
std::unique_lock<std::mutex> rcv_lock(m_rcv_mutex);
m_rcv.wait_for(rcv_lock, std::chrono::milliseconds(1));
}
m_sync.exchange({});
m_wcv.notify_one();
m_rcv.notify_one();
}
};