rpcs3/Utilities/cond.h
2019-07-01 04:33:23 +03:00

285 lines
5.2 KiB
C++

#pragma once
#include "types.h"
#include "Atomic.h"
#include <shared_mutex>
#include "asm.h"
// Lightweight condition variable
class cond_variable
{
// Internal waiter counter
atomic_t<u32> m_value{0};
friend class notifier;
protected:
// Internal waiting function
bool imp_wait(u32 _old, u64 _timeout) noexcept;
// Try to notify up to _count threads
void imp_wake(u32 _count) noexcept;
public:
constexpr cond_variable() = default;
// Intrusive wait algorithm for lockable objects
template <typename T>
bool wait(T& object, u64 usec_timeout = -1)
{
const u32 _old = m_value.fetch_add(1); // Increment waiter counter
object.unlock();
const bool res = imp_wait(_old, usec_timeout);
object.lock();
return res;
}
// Unlock all specified objects but don't lock them again
template <typename... Locks>
bool wait_unlock(u64 usec_timeout, Locks&&... locks)
{
const u32 _old = m_value.fetch_add(1); // Increment waiter counter
(..., std::forward<Locks>(locks).unlock());
return imp_wait(_old, usec_timeout);
}
// Wake one thread
void notify_one() noexcept
{
if (m_value)
{
imp_wake(1);
}
}
// Wake all threads
void notify_all() noexcept
{
if (m_value)
{
imp_wake(65535);
}
}
static constexpr u64 max_timeout = u64{UINT32_MAX} / 1000 * 1000000;
};
// Pair of a fake shared mutex (only limited shared locking) and a condition variable. Obsolete.
class notifier
{
atomic_t<u32> m_counter{0};
cond_variable m_cond;
bool imp_try_lock(u32 count);
void imp_unlock(u32 count);
u32 imp_notify(u32 count);
public:
constexpr notifier() = default;
bool try_lock()
{
return imp_try_lock(max_readers);
}
void unlock()
{
imp_unlock(max_readers);
}
bool try_lock_shared()
{
return imp_try_lock(1);
}
void unlock_shared()
{
imp_unlock(1);
}
bool wait(u64 usec_timeout = -1);
void notify_all()
{
if (m_counter)
{
imp_notify(-1);
}
// Notify after imaginary "exclusive" lock+unlock
m_cond.notify_all();
}
void notify_one()
{
// TODO
if (m_counter)
{
if (imp_notify(1))
{
return;
}
}
m_cond.notify_one();
}
static constexpr u32 max_readers = 0x7f;
};
// Condition variable fused with a pseudo-mutex which is never supposed to be locked concurrently.
class unique_cond
{
enum : u32
{
c_wait = 1,
c_lock = 2,
c_sig = 3,
};
atomic_t<u32> m_value{0};
bool imp_wait(u64 _timeout) noexcept;
void imp_notify() noexcept;
public:
constexpr unique_cond() = default;
void lock() noexcept
{
// Shouldn't be locked by more than one thread concurrently
while (UNLIKELY(!m_value.compare_and_swap_test(0, c_lock)))
;
}
void unlock() noexcept
{
m_value = 0;
}
bool wait(std::unique_lock<unique_cond>& lock, u64 usec_timeout = -1) noexcept
{
AUDIT(lock.owns_lock());
AUDIT(lock.mutex() == this);
return imp_wait(usec_timeout);
}
void notify() noexcept
{
// Early exit if notification is not required
if (LIKELY(!m_value))
return;
imp_notify();
}
};
// Condition variable fused with a pseudo-mutex supporting only reader locks (up to 32 readers).
class shared_cond
{
// For information, shouldn't modify
enum : u64
{
// Wait bit is aligned for compatibility with 32-bit futex.
c_wait = 1,
c_sig = 1ull << 32,
c_lock = 1ull << 32 | 1,
};
// Split in 32-bit parts for convenient bit combining
atomic_t<u64> m_cvx32{0};
class shared_lock
{
shared_cond* m_this;
u32 m_slot;
friend class shared_cond;
public:
shared_lock(shared_cond* _this) noexcept
: m_this(_this)
{
// Lock and remember obtained slot index
m_slot = m_this->m_cvx32.atomic_op([](u64& cvx32)
{
// Combine used bits and invert to find least significant bit unused
const u32 slot = static_cast<u32>(utils::cnttz64(~((cvx32 & 0xffffffff) | (cvx32 >> 32)), true));
// Set lock bits (does nothing if all slots are used)
const u64 bit = (1ull << slot) & 0xffffffff;
cvx32 |= bit | (bit << 32);
return slot;
});
}
shared_lock(const shared_lock&) = delete;
shared_lock(shared_lock&& rhs)
: m_this(rhs.m_this)
, m_slot(rhs.m_slot)
{
rhs.m_slot = 32;
}
shared_lock& operator=(const shared_lock&) = delete;
~shared_lock()
{
// Clear the slot (does nothing if all slots are used)
const u64 bit = (1ull << m_slot) & 0xffffffff;
m_this->m_cvx32 &= ~(bit | (bit << 32));
}
explicit operator bool() const noexcept
{
// Check success
return m_slot < 32;
}
bool wait(u64 usec_timeout = -1) const noexcept
{
return m_this->wait(*this, usec_timeout);
}
};
bool imp_wait(u32 slot, u64 _timeout) noexcept;
void imp_notify() noexcept;
public:
constexpr shared_cond() = default;
shared_lock try_shared_lock() noexcept
{
return shared_lock(this);
}
u32 count() const noexcept
{
const u64 cvx32 = m_cvx32;
return utils::popcnt32(static_cast<u32>(cvx32 | (cvx32 >> 32)));
}
bool wait(shared_lock const& lock, u64 usec_timeout = -1) noexcept
{
AUDIT(lock.m_this == this);
return imp_wait(lock.m_slot, usec_timeout);
}
void wait_all() noexcept;
bool wait_all(shared_lock& lock) noexcept;
void notify_all() noexcept
{
if (LIKELY(!m_cvx32))
return;
imp_notify();
}
bool notify_all(shared_lock& lock) noexcept;
};