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mirror of https://github.com/RPCS3/rpcs3.git synced 2024-11-22 18:53:28 +01:00
rpcs3/Utilities/cond.cpp
Nekotekina 5d45a3e47d Implement cpu_thread::suspend_all
Remove Accurate PUTLLC option.
Implement fallback path for SPU transactions.
2019-06-19 20:36:12 +03:00

478 lines
8.0 KiB
C++

#include "cond.h"
#include "sync.h"
#include "lockless.h"
#include <limits.h>
#ifndef _WIN32
#include <thread>
#endif
bool cond_variable::imp_wait(u32 _old, u64 _timeout) noexcept
{
verify("cond_variable overflow" HERE), (_old & 0xffff) != 0xffff; // Very unlikely: it requires 65535 distinct threads to wait simultaneously
return balanced_wait_until(m_value, _timeout, [&](u32& value, auto... ret) -> int
{
if (value >> 16)
{
// Success
value -= 0x10001;
return +1;
}
if constexpr (sizeof...(ret))
{
// Retire
value -= 1;
return -1;
}
return 0;
});
#ifdef _WIN32
if (_old >= 0x10000 && !OptWaitOnAddress && m_value)
{
// Workaround possibly stolen signal
imp_wake(1);
}
#endif
}
void cond_variable::imp_wake(u32 _count) noexcept
{
// TODO (notify_one)
balanced_awaken<true>(m_value, m_value.atomic_op([&](u32& value) -> u32
{
// Subtract already signaled number from total amount of waiters
const u32 can_sig = (value & 0xffff) - (value >> 16);
const u32 num_sig = std::min<u32>(can_sig, _count);
value += num_sig << 16;
return num_sig;
}));
}
bool notifier::imp_try_lock(u32 count)
{
return m_counter.atomic_op([&](u32& value)
{
if ((value % (max_readers + 1)) + count <= max_readers)
{
value += count;
return true;
}
return false;
});
}
void notifier::imp_unlock(u32 count)
{
const u32 counter = m_counter.sub_fetch(count);
if (UNLIKELY(counter % (max_readers + 1)))
{
return;
}
if (counter)
{
const u32 _old = m_counter.atomic_op([](u32& value) -> u32
{
if (value % (max_readers + 1))
{
return 0;
}
return std::exchange(value, 0) / (max_readers + 1);
});
const u32 wc = m_cond.m_value;
if (_old && wc)
{
m_cond.imp_wake(_old > wc ? wc : _old);
}
}
}
u32 notifier::imp_notify(u32 count)
{
return m_counter.atomic_op([&](u32& value) -> u32
{
if (const u32 add = value % (max_readers + 1))
{
// Mutex is locked
const u32 result = add > count ? count : add;
value += result * (max_readers + 1);
return result;
}
else
{
// Mutex is unlocked
value = 0;
return count;
}
});
}
bool notifier::wait(u64 usec_timeout)
{
const u32 _old = m_cond.m_value.fetch_add(1);
if (max_readers < m_counter.fetch_op([](u32& value)
{
if (value > max_readers)
{
value -= max_readers;
}
value -= 1;
}))
{
// Return without waiting
m_cond.imp_wait(_old, 0);
return true;
}
const bool res = m_cond.imp_wait(_old, usec_timeout);
while (!try_lock_shared())
{
// TODO
busy_wait();
}
return res;
}
bool unique_cond::imp_wait(u64 _timeout) noexcept
{
// State transition: c_sig -> c_lock \ c_lock -> c_wait
const u32 _old = m_value.fetch_sub(1);
if (LIKELY(_old == c_sig))
return true;
return balanced_wait_until(m_value, _timeout, [&](u32& value, auto... ret) -> int
{
if (value == c_sig)
{
value = c_lock;
return +1;
}
if constexpr (sizeof...(ret))
{
value = c_lock;
return -1;
}
return 0;
});
}
void unique_cond::imp_notify() noexcept
{
auto [old, ok] = m_value.fetch_op([](u32& v)
{
if (UNLIKELY(v > 0 && v < c_sig))
{
v = c_sig;
return true;
}
return false;
});
verify(HERE), old <= c_sig;
if (LIKELY(!ok || old == c_lock))
{
return;
}
balanced_awaken(m_value, 1);
}
bool shared_cond::imp_wait(u32 slot, u64 _timeout) noexcept
{
if (slot >= 32)
{
// Invalid argument, assume notified
return true;
}
const u64 wait_bit = c_wait << slot;
const u64 lock_bit = c_lock << slot;
// Change state from c_lock to c_wait
const u64 old_ = m_cvx32.fetch_op([=](u64& cvx32)
{
if (cvx32 & wait_bit)
{
// c_lock -> c_wait
cvx32 &= ~(lock_bit & ~wait_bit);
}
else
{
// c_sig -> c_lock
cvx32 |= lock_bit;
}
});
if ((old_ & wait_bit) == 0)
{
// Already signaled, return without waiting
return true;
}
return balanced_wait_until(m_cvx32, _timeout, [&](u64& cvx32, auto... ret) -> int
{
if ((cvx32 & wait_bit) == 0)
{
// c_sig -> c_lock
cvx32 |= lock_bit;
return +1;
}
if constexpr (sizeof...(ret))
{
// Retire
cvx32 |= lock_bit;
return -1;
}
return 0;
});
}
void shared_cond::imp_notify() noexcept
{
auto [old, ok] = m_cvx32.fetch_op([](u64& cvx32)
{
if (const u64 sig_mask = cvx32 & 0xffffffff)
{
cvx32 &= 0xffffffffull << 32;
cvx32 |= sig_mask << 32;
return true;
}
return false;
});
// Determine if some waiters need a syscall notification
const u64 wait_mask = old & (~old >> 32);
if (UNLIKELY(!ok || !wait_mask))
{
return;
}
balanced_awaken<true>(m_cvx32, utils::popcnt32(wait_mask));
}
void shared_cond::wait_all() noexcept
{
// Try to acquire waiting state without locking but only if there are other locks
const auto [old_, result] = m_cvx32.fetch_op([](u64& cvx32) -> u64
{
// Check waiting alone
if ((cvx32 & 0xffffffff) == 0)
{
return 0;
}
// Combine used bits and invert to find least significant bit unused
const u32 slot = utils::cnttz64(~((cvx32 & 0xffffffff) | (cvx32 >> 32)), true);
// Set waiting bit (does nothing if all slots are used)
cvx32 |= (1ull << slot) & 0xffffffff;
return 1ull << slot;
});
if (!result)
{
return;
}
if (result > 0xffffffffu)
{
// All slots are used, fallback to spin wait
while (m_cvx32 & 0xffffffff)
{
busy_wait();
}
return;
}
const u64 wait_bit = result;
const u64 lock_bit = wait_bit | (wait_bit << 32);
balanced_wait_until(m_cvx32, -1, [&](u64& cvx32, auto... ret) -> int
{
if ((cvx32 & wait_bit) == 0)
{
// Remove signal and unlock at once
cvx32 &= ~lock_bit;
return +1;
}
if constexpr (sizeof...(ret))
{
cvx32 &= ~lock_bit;
return -1;
}
return 0;
});
}
bool shared_cond::wait_all(shared_cond::shared_lock& lock) noexcept
{
AUDIT(lock.m_this == this);
if (lock.m_slot >= 32)
{
// Invalid argument, assume notified
return true;
}
const u64 wait_bit = c_wait << lock.m_slot;
const u64 lock_bit = c_lock << lock.m_slot;
// Try to acquire waiting state only if there are other locks
const auto [old_, not_alone] = m_cvx32.fetch_op([&](u64& cvx32)
{
// Check locking alone
if (((cvx32 >> 32) & cvx32) == (lock_bit >> 32))
{
return false;
}
// c_lock -> c_wait, c_sig -> unlock
cvx32 &= ~(lock_bit & ~wait_bit);
return true;
});
if (!not_alone)
{
return false;
}
else
{
// Set invalid slot to acknowledge unlocking
lock.m_slot = 33;
}
if ((old_ & wait_bit) == 0)
{
// Already signaled, return without waiting
return true;
}
balanced_wait_until(m_cvx32, -1, [&](u64& cvx32, auto... ret) -> int
{
if ((cvx32 & wait_bit) == 0)
{
// Remove signal and unlock at once
cvx32 &= ~lock_bit;
return +1;
}
if constexpr (sizeof...(ret))
{
cvx32 &= ~lock_bit;
return -1;
}
return 0;
});
return true;
}
bool shared_cond::notify_all(shared_cond::shared_lock& lock) noexcept
{
AUDIT(lock.m_this == this);
if (lock.m_slot >= 32)
{
// Invalid argument
return false;
}
const u64 slot_mask = c_sig << lock.m_slot;
auto [old, ok] = m_cvx32.fetch_op([&](u64& cvx32)
{
if (((cvx32 << 32) & cvx32) != slot_mask)
{
return false;
}
if (const u64 sig_mask = cvx32 & 0xffffffff)
{
cvx32 &= (0xffffffffull << 32) & ~slot_mask;
cvx32 |= (sig_mask << 32) & ~slot_mask;
return true;
}
return false;
});
if (!ok)
{
// Not an exclusive reader
return false;
}
// Set invalid slot to acknowledge unlocking
lock.m_slot = 34;
// Determine if some waiters need a syscall notification
const u64 wait_mask = old & (~old >> 32);
if (UNLIKELY(!wait_mask))
{
return true;
}
balanced_awaken<true>(m_cvx32, utils::popcnt32(wait_mask));
return true;
}
bool lf_queue_base::wait(u64 _timeout)
{
auto _old = m_head.compare_and_swap(0, 1);
if (_old)
{
verify("lf_queue concurrent wait" HERE), _old != 1;
return true;
}
return balanced_wait_until(m_head, _timeout, [](std::uintptr_t& head, auto... ret) -> int
{
if (head != 1)
{
return +1;
}
if constexpr (sizeof...(ret))
{
head = 0;
return -1;
}
return 0;
});
}
void lf_queue_base::imp_notify()
{
balanced_awaken(m_head, 1);
}