ppsspp/Core/HLE/sceKernelMutex.cpp
Henrik Rydgård 5200208a84 Revert "Merge pull request #15930 from sum2012/kernel-minor"
This reverts commit fd863beb96, reversing
changes made to 59813fff6d.
2022-09-01 20:44:00 +02:00

1140 lines
33 KiB
C++

// Copyright (c) 2012- PPSSPP Project.
// This program is free software: you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation, version 2.0 or later versions.
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License 2.0 for more details.
// A copy of the GPL 2.0 should have been included with the program.
// If not, see http://www.gnu.org/licenses/
// Official git repository and contact information can be found at
// https://github.com/hrydgard/ppsspp and http://www.ppsspp.org/.
#include <algorithm>
#include <map>
#include <unordered_map>
#include "Common/Serialize/Serializer.h"
#include "Common/Serialize/SerializeFuncs.h"
#include "Common/Serialize/SerializeMap.h"
#include "Core/MemMapHelpers.h"
#include "Core/HLE/HLE.h"
#include "Core/MIPS/MIPS.h"
#include "Core/CoreTiming.h"
#include "Core/Reporting.h"
#include "Core/HLE/sceKernel.h"
#include "Core/HLE/sceKernelMutex.h"
#include "Core/HLE/sceKernelThread.h"
#include "Core/HLE/KernelWaitHelpers.h"
#define PSP_MUTEX_ATTR_FIFO 0
#define PSP_MUTEX_ATTR_PRIORITY 0x100
#define PSP_MUTEX_ATTR_ALLOW_RECURSIVE 0x200
#define PSP_MUTEX_ATTR_KNOWN (PSP_MUTEX_ATTR_PRIORITY | PSP_MUTEX_ATTR_ALLOW_RECURSIVE)
// Not sure about the names of these
#define PSP_MUTEX_ERROR_NO_SUCH_MUTEX 0x800201C3
#define PSP_MUTEX_ERROR_TRYLOCK_FAILED 0x800201C4
#define PSP_MUTEX_ERROR_NOT_LOCKED 0x800201C5
#define PSP_MUTEX_ERROR_LOCK_OVERFLOW 0x800201C6
#define PSP_MUTEX_ERROR_UNLOCK_UNDERFLOW 0x800201C7
#define PSP_MUTEX_ERROR_ALREADY_LOCKED 0x800201C8
#define PSP_LWMUTEX_ERROR_NO_SUCH_LWMUTEX 0x800201CA
// Note: used only for _600.
#define PSP_LWMUTEX_ERROR_TRYLOCK_FAILED 0x800201CB
#define PSP_LWMUTEX_ERROR_NOT_LOCKED 0x800201CC
#define PSP_LWMUTEX_ERROR_LOCK_OVERFLOW 0x800201CD
#define PSP_LWMUTEX_ERROR_UNLOCK_UNDERFLOW 0x800201CE
#define PSP_LWMUTEX_ERROR_ALREADY_LOCKED 0x800201CF
struct NativeMutex
{
SceSize_le size;
char name[KERNELOBJECT_MAX_NAME_LENGTH + 1];
SceUInt_le attr;
s32_le initialCount;
s32_le lockLevel;
SceUID_le lockThread;
// Not kept up to date.
s32_le numWaitThreads;
};
struct PSPMutex : public KernelObject
{
const char *GetName() override { return nm.name; }
const char *GetTypeName() override { return GetStaticTypeName(); }
static const char *GetStaticTypeName() { return "Mutex"; }
static u32 GetMissingErrorCode() { return PSP_MUTEX_ERROR_NO_SUCH_MUTEX; }
static int GetStaticIDType() { return SCE_KERNEL_TMID_Mutex; }
int GetIDType() const override { return SCE_KERNEL_TMID_Mutex; }
void DoState(PointerWrap &p) override
{
auto s = p.Section("Mutex", 1);
if (!s)
return;
Do(p, nm);
SceUID dv = 0;
Do(p, waitingThreads, dv);
Do(p, pausedWaits);
}
NativeMutex nm;
std::vector<SceUID> waitingThreads;
// Key is the callback id it was for, or if no callback, the thread id.
std::map<SceUID, u64> pausedWaits;
};
struct NativeLwMutexWorkarea
{
s32_le lockLevel;
SceUID_le lockThread;
u32_le attr;
s32_le numWaitThreads;
SceUID_le uid;
s32_le pad[3];
void init()
{
memset(this, 0, sizeof(NativeLwMutexWorkarea));
}
void clear()
{
lockLevel = 0;
lockThread = -1;
uid = -1;
}
};
struct NativeLwMutex
{
SceSize_le size;
char name[KERNELOBJECT_MAX_NAME_LENGTH + 1];
SceUInt_le attr;
SceUID_le uid;
PSPPointer<NativeLwMutexWorkarea> workarea;
s32_le initialCount;
// Not kept up to date.
s32_le currentCount;
// Not kept up to date.
SceUID_le lockThread;
// Not kept up to date.
s32_le numWaitThreads;
};
struct LwMutex : public KernelObject
{
const char *GetName() override { return nm.name; }
const char *GetTypeName() override { return GetStaticTypeName(); }
static const char *GetStaticTypeName() { return "LwMutex"; }
static u32 GetMissingErrorCode() { return PSP_LWMUTEX_ERROR_NO_SUCH_LWMUTEX; }
static int GetStaticIDType() { return SCE_KERNEL_TMID_LwMutex; }
int GetIDType() const override { return SCE_KERNEL_TMID_LwMutex; }
void DoState(PointerWrap &p) override
{
auto s = p.Section("LwMutex", 1);
if (!s)
return;
Do(p, nm);
SceUID dv = 0;
Do(p, waitingThreads, dv);
Do(p, pausedWaits);
}
NativeLwMutex nm;
std::vector<SceUID> waitingThreads;
// Key is the callback id it was for, or if no callback, the thread id.
std::map<SceUID, u64> pausedWaits;
};
static int mutexWaitTimer = -1;
static int lwMutexWaitTimer = -1;
// Thread -> Mutex locks for thread end.
typedef std::unordered_multimap<SceUID, SceUID> MutexMap;
static MutexMap mutexHeldLocks;
void __KernelMutexBeginCallback(SceUID threadID, SceUID prevCallbackId);
void __KernelMutexEndCallback(SceUID threadID, SceUID prevCallbackId);
void __KernelLwMutexBeginCallback(SceUID threadID, SceUID prevCallbackId);
void __KernelLwMutexEndCallback(SceUID threadID, SceUID prevCallbackId);
void __KernelMutexInit()
{
mutexWaitTimer = CoreTiming::RegisterEvent("MutexTimeout", __KernelMutexTimeout);
lwMutexWaitTimer = CoreTiming::RegisterEvent("LwMutexTimeout", __KernelLwMutexTimeout);
__KernelListenThreadEnd(&__KernelMutexThreadEnd);
__KernelRegisterWaitTypeFuncs(WAITTYPE_MUTEX, __KernelMutexBeginCallback, __KernelMutexEndCallback);
__KernelRegisterWaitTypeFuncs(WAITTYPE_LWMUTEX, __KernelLwMutexBeginCallback, __KernelLwMutexEndCallback);
}
void __KernelMutexDoState(PointerWrap &p)
{
auto s = p.Section("sceKernelMutex", 1);
if (!s)
return;
Do(p, mutexWaitTimer);
CoreTiming::RestoreRegisterEvent(mutexWaitTimer, "MutexTimeout", __KernelMutexTimeout);
Do(p, lwMutexWaitTimer);
CoreTiming::RestoreRegisterEvent(lwMutexWaitTimer, "LwMutexTimeout", __KernelLwMutexTimeout);
Do(p, mutexHeldLocks);
}
KernelObject *__KernelMutexObject()
{
return new PSPMutex;
}
KernelObject *__KernelLwMutexObject()
{
return new LwMutex;
}
void __KernelMutexShutdown()
{
mutexHeldLocks.clear();
}
static void __KernelMutexAcquireLock(PSPMutex *mutex, int count, SceUID thread) {
#if defined(_DEBUG)
auto locked = mutexHeldLocks.equal_range(thread);
for (MutexMap::iterator iter = locked.first; iter != locked.second; ++iter)
_dbg_assert_msg_((*iter).second != mutex->GetUID(), "Thread %d / mutex %d wasn't removed from mutexHeldLocks properly.", thread, mutex->GetUID());
#endif
mutexHeldLocks.insert(std::make_pair(thread, mutex->GetUID()));
mutex->nm.lockLevel = count;
mutex->nm.lockThread = thread;
}
static void __KernelMutexAcquireLock(PSPMutex *mutex, int count) {
__KernelMutexAcquireLock(mutex, count, __KernelGetCurThread());
}
static void __KernelMutexEraseLock(PSPMutex *mutex) {
if (mutex->nm.lockThread != -1)
{
SceUID id = mutex->GetUID();
std::pair<MutexMap::iterator, MutexMap::iterator> locked = mutexHeldLocks.equal_range(mutex->nm.lockThread);
for (MutexMap::iterator iter = locked.first; iter != locked.second; ++iter)
{
if ((*iter).second == id)
{
mutexHeldLocks.erase(iter);
break;
}
}
}
mutex->nm.lockThread = -1;
}
static std::vector<SceUID>::iterator __KernelMutexFindPriority(std::vector<SceUID> &waiting)
{
_dbg_assert_msg_(!waiting.empty(), "__KernelMutexFindPriority: Trying to find best of no threads.");
std::vector<SceUID>::iterator iter, end, best = waiting.end();
u32 best_prio = 0xFFFFFFFF;
for (iter = waiting.begin(), end = waiting.end(); iter != end; ++iter)
{
u32 iter_prio = __KernelGetThreadPrio(*iter);
if (iter_prio < best_prio)
{
best = iter;
best_prio = iter_prio;
}
}
_dbg_assert_msg_(best != waiting.end(), "__KernelMutexFindPriority: Returning invalid best thread.");
return best;
}
static bool __KernelUnlockMutexForThread(PSPMutex *mutex, SceUID threadID, u32 &error, int result) {
if (!HLEKernel::VerifyWait(threadID, WAITTYPE_MUTEX, mutex->GetUID()))
return false;
// If result is an error code, we're just letting it go.
if (result == 0)
{
int wVal = (int)__KernelGetWaitValue(threadID, error);
__KernelMutexAcquireLock(mutex, wVal, threadID);
}
u32 timeoutPtr = __KernelGetWaitTimeoutPtr(threadID, error);
if (timeoutPtr != 0 && mutexWaitTimer != -1)
{
// Remove any event for this thread.
s64 cyclesLeft = CoreTiming::UnscheduleEvent(mutexWaitTimer, threadID);
Memory::Write_U32((u32) cyclesToUs(cyclesLeft), timeoutPtr);
}
__KernelResumeThreadFromWait(threadID, result);
return true;
}
static bool __KernelUnlockMutexForThreadCheck(PSPMutex *mutex, SceUID threadID, u32 &error, int result, bool &wokeThreads) {
if (mutex->nm.lockThread == -1 && __KernelUnlockMutexForThread(mutex, threadID, error, 0))
return true;
return false;
}
void __KernelMutexBeginCallback(SceUID threadID, SceUID prevCallbackId)
{
auto result = HLEKernel::WaitBeginCallback<PSPMutex, WAITTYPE_MUTEX, SceUID>(threadID, prevCallbackId, mutexWaitTimer);
if (result == HLEKernel::WAIT_CB_SUCCESS)
DEBUG_LOG(SCEKERNEL, "sceKernelLockMutexCB: Suspending lock wait for callback");
else
WARN_LOG_REPORT(SCEKERNEL, "sceKernelLockMutexCB: beginning callback with bad wait id?");
}
void __KernelMutexEndCallback(SceUID threadID, SceUID prevCallbackId)
{
auto result = HLEKernel::WaitEndCallback<PSPMutex, WAITTYPE_MUTEX, SceUID>(threadID, prevCallbackId, mutexWaitTimer, __KernelUnlockMutexForThreadCheck);
if (result == HLEKernel::WAIT_CB_RESUMED_WAIT)
DEBUG_LOG(SCEKERNEL, "sceKernelLockMutexCB: Resuming lock wait for callback");
}
int sceKernelCreateMutex(const char *name, u32 attr, int initialCount, u32 optionsPtr)
{
if (!name)
{
WARN_LOG_REPORT(SCEKERNEL, "%08x=sceKernelCreateMutex(): invalid name", SCE_KERNEL_ERROR_ERROR);
return SCE_KERNEL_ERROR_ERROR;
}
if (attr & ~0xBFF)
{
WARN_LOG_REPORT(SCEKERNEL, "%08x=sceKernelCreateMutex(): invalid attr parameter: %08x", SCE_KERNEL_ERROR_ILLEGAL_ATTR, attr);
return SCE_KERNEL_ERROR_ILLEGAL_ATTR;
}
if (initialCount < 0)
return SCE_KERNEL_ERROR_ILLEGAL_COUNT;
if ((attr & PSP_MUTEX_ATTR_ALLOW_RECURSIVE) == 0 && initialCount > 1)
return SCE_KERNEL_ERROR_ILLEGAL_COUNT;
PSPMutex *mutex = new PSPMutex();
SceUID id = kernelObjects.Create(mutex);
mutex->nm.size = sizeof(mutex->nm);
strncpy(mutex->nm.name, name, KERNELOBJECT_MAX_NAME_LENGTH);
mutex->nm.name[KERNELOBJECT_MAX_NAME_LENGTH] = 0;
mutex->nm.attr = attr;
mutex->nm.initialCount = initialCount;
if (initialCount == 0)
{
mutex->nm.lockLevel = 0;
mutex->nm.lockThread = -1;
}
else
__KernelMutexAcquireLock(mutex, initialCount);
DEBUG_LOG(SCEKERNEL, "%i=sceKernelCreateMutex(%s, %08x, %d, %08x)", id, name, attr, initialCount, optionsPtr);
if (optionsPtr != 0)
{
u32 size = Memory::Read_U32(optionsPtr);
if (size > 4)
WARN_LOG_REPORT(SCEKERNEL, "sceKernelCreateMutex(%s) unsupported options parameter, size = %d", name, size);
}
if ((attr & ~PSP_MUTEX_ATTR_KNOWN) != 0)
WARN_LOG_REPORT(SCEKERNEL, "sceKernelCreateMutex(%s) unsupported attr parameter: %08x", name, attr);
return id;
}
int sceKernelDeleteMutex(SceUID id)
{
u32 error;
PSPMutex *mutex = kernelObjects.Get<PSPMutex>(id, error);
if (mutex)
{
DEBUG_LOG(SCEKERNEL, "sceKernelDeleteMutex(%i)", id);
bool wokeThreads = false;
std::vector<SceUID>::iterator iter, end;
for (iter = mutex->waitingThreads.begin(), end = mutex->waitingThreads.end(); iter != end; ++iter)
wokeThreads |= __KernelUnlockMutexForThread(mutex, *iter, error, SCE_KERNEL_ERROR_WAIT_DELETE);
if (mutex->nm.lockThread != -1)
__KernelMutexEraseLock(mutex);
mutex->waitingThreads.clear();
if (wokeThreads)
hleReSchedule("mutex deleted");
return kernelObjects.Destroy<PSPMutex>(id);
}
else
{
DEBUG_LOG(SCEKERNEL, "sceKernelDeleteMutex(%i): invalid mutex", id);
return error;
}
}
static bool __KernelLockMutexCheck(PSPMutex *mutex, int count, u32 &error) {
if (error)
return false;
const bool mutexIsRecursive = (mutex->nm.attr & PSP_MUTEX_ATTR_ALLOW_RECURSIVE) != 0;
if (count <= 0)
error = SCE_KERNEL_ERROR_ILLEGAL_COUNT;
else if (count > 1 && !mutexIsRecursive)
error = SCE_KERNEL_ERROR_ILLEGAL_COUNT;
// Two positive ints will always overflow to negative.
else if (count + mutex->nm.lockLevel < 0)
error = PSP_MUTEX_ERROR_LOCK_OVERFLOW;
// Only a recursive mutex can re-lock.
else if (mutex->nm.lockThread == __KernelGetCurThread())
{
if (mutexIsRecursive)
return true;
error = PSP_MUTEX_ERROR_ALREADY_LOCKED;
}
// Otherwise it would lock or wait.
else if (mutex->nm.lockLevel == 0)
return true;
return false;
}
static bool __KernelLockMutex(PSPMutex *mutex, int count, u32 &error) {
if (!__KernelLockMutexCheck(mutex, count, error))
return false;
if (mutex->nm.lockLevel == 0)
{
__KernelMutexAcquireLock(mutex, count);
// Nobody had it locked - no need to block
return true;
}
if (mutex->nm.lockThread == __KernelGetCurThread())
{
// __KernelLockMutexCheck() would've returned an error, so this must be recursive.
mutex->nm.lockLevel += count;
return true;
}
return false;
}
static bool __KernelUnlockMutex(PSPMutex *mutex, u32 &error) {
__KernelMutexEraseLock(mutex);
bool wokeThreads = false;
std::vector<SceUID>::iterator iter;
while (!wokeThreads && !mutex->waitingThreads.empty())
{
if ((mutex->nm.attr & PSP_MUTEX_ATTR_PRIORITY) != 0)
iter = __KernelMutexFindPriority(mutex->waitingThreads);
else
iter = mutex->waitingThreads.begin();
wokeThreads |= __KernelUnlockMutexForThread(mutex, *iter, error, 0);
mutex->waitingThreads.erase(iter);
}
if (!wokeThreads)
mutex->nm.lockThread = -1;
return wokeThreads;
}
void __KernelMutexTimeout(u64 userdata, int cyclesLate)
{
SceUID threadID = (SceUID)userdata;
HLEKernel::WaitExecTimeout<PSPMutex, WAITTYPE_MUTEX>(threadID);
}
void __KernelMutexThreadEnd(SceUID threadID)
{
u32 error;
// If it was waiting on the mutex, it should finish now.
SceUID waitingMutexID = __KernelGetWaitID(threadID, WAITTYPE_MUTEX, error);
if (waitingMutexID)
{
PSPMutex *mutex = kernelObjects.Get<PSPMutex>(waitingMutexID, error);
if (mutex)
HLEKernel::RemoveWaitingThread(mutex->waitingThreads, threadID);
}
// Unlock all mutexes the thread had locked.
std::pair<MutexMap::iterator, MutexMap::iterator> locked = mutexHeldLocks.equal_range(threadID);
for (MutexMap::iterator iter = locked.first; iter != locked.second; )
{
// Need to increment early so erase() doesn't invalidate.
SceUID mutexID = (*iter++).second;
PSPMutex *mutex = kernelObjects.Get<PSPMutex>(mutexID, error);
if (mutex)
{
mutex->nm.lockLevel = 0;
__KernelUnlockMutex(mutex, error);
}
}
}
static void __KernelWaitMutex(PSPMutex *mutex, u32 timeoutPtr) {
if (timeoutPtr == 0 || mutexWaitTimer == -1)
return;
int micro = (int) Memory::Read_U32(timeoutPtr);
// This happens to be how the hardware seems to time things.
if (micro <= 3)
micro = 25;
else if (micro <= 249)
micro = 250;
// This should call __KernelMutexTimeout() later, unless we cancel it.
CoreTiming::ScheduleEvent(usToCycles(micro), mutexWaitTimer, __KernelGetCurThread());
}
int sceKernelCancelMutex(SceUID uid, int count, u32 numWaitThreadsPtr)
{
u32 error;
PSPMutex *mutex = kernelObjects.Get<PSPMutex>(uid, error);
if (mutex)
{
bool lockable = count <= 0 || __KernelLockMutexCheck(mutex, count, error);
if (!lockable)
{
// May still be okay. As long as the count/etc. are valid.
if (error != 0 && error != PSP_MUTEX_ERROR_LOCK_OVERFLOW && error != PSP_MUTEX_ERROR_ALREADY_LOCKED)
{
DEBUG_LOG(SCEKERNEL, "sceKernelCancelMutex(%i, %d, %08x): invalid count", uid, count, numWaitThreadsPtr);
return error;
}
}
DEBUG_LOG(SCEKERNEL, "sceKernelCancelMutex(%i, %d, %08x)", uid, count, numWaitThreadsPtr);
// Remove threads no longer waiting on this first (so the numWaitThreads value is correct.)
HLEKernel::CleanupWaitingThreads(WAITTYPE_MUTEX, uid, mutex->waitingThreads);
if (Memory::IsValidAddress(numWaitThreadsPtr))
Memory::Write_U32((u32)mutex->waitingThreads.size(), numWaitThreadsPtr);
bool wokeThreads = false;
for (auto iter = mutex->waitingThreads.begin(), end = mutex->waitingThreads.end(); iter != end; ++iter)
wokeThreads |= __KernelUnlockMutexForThread(mutex, *iter, error, SCE_KERNEL_ERROR_WAIT_CANCEL);
if (mutex->nm.lockThread != -1)
__KernelMutexEraseLock(mutex);
mutex->waitingThreads.clear();
if (count <= 0)
{
mutex->nm.lockLevel = 0;
mutex->nm.lockThread = -1;
}
else
__KernelMutexAcquireLock(mutex, count);
if (wokeThreads)
hleReSchedule("mutex canceled");
return 0;
}
else
{
DEBUG_LOG(SCEKERNEL, "sceKernelCancelMutex(%i, %d, %08x)", uid, count, numWaitThreadsPtr);
return error;
}
}
// int sceKernelLockMutex(SceUID id, int count, int *timeout)
int sceKernelLockMutex(SceUID id, int count, u32 timeoutPtr)
{
DEBUG_LOG(SCEKERNEL, "sceKernelLockMutex(%i, %i, %08x)", id, count, timeoutPtr);
u32 error;
PSPMutex *mutex = kernelObjects.Get<PSPMutex>(id, error);
if (__KernelLockMutex(mutex, count, error))
return 0;
else if (error)
return error;
else
{
SceUID threadID = __KernelGetCurThread();
// May be in a tight loop timing out (where we don't remove from waitingThreads yet), don't want to add duplicates.
if (std::find(mutex->waitingThreads.begin(), mutex->waitingThreads.end(), threadID) == mutex->waitingThreads.end())
mutex->waitingThreads.push_back(threadID);
__KernelWaitMutex(mutex, timeoutPtr);
__KernelWaitCurThread(WAITTYPE_MUTEX, id, count, timeoutPtr, false, "mutex waited");
// Return value will be overwritten by wait.
return 0;
}
}
// int sceKernelLockMutexCB(SceUID id, int count, int *timeout)
int sceKernelLockMutexCB(SceUID id, int count, u32 timeoutPtr)
{
DEBUG_LOG(SCEKERNEL, "sceKernelLockMutexCB(%i, %i, %08x)", id, count, timeoutPtr);
u32 error;
PSPMutex *mutex = kernelObjects.Get<PSPMutex>(id, error);
if (!__KernelLockMutexCheck(mutex, count, error))
{
if (error)
return error;
SceUID threadID = __KernelGetCurThread();
// May be in a tight loop timing out (where we don't remove from waitingThreads yet), don't want to add duplicates.
if (std::find(mutex->waitingThreads.begin(), mutex->waitingThreads.end(), threadID) == mutex->waitingThreads.end())
mutex->waitingThreads.push_back(threadID);
__KernelWaitMutex(mutex, timeoutPtr);
__KernelWaitCurThread(WAITTYPE_MUTEX, id, count, timeoutPtr, true, "mutex waited");
// Return value will be overwritten by wait.
return 0;
}
else
{
if (__KernelCurHasReadyCallbacks())
{
// Might actually end up having to wait, so set the timeout.
__KernelWaitMutex(mutex, timeoutPtr);
__KernelWaitCallbacksCurThread(WAITTYPE_MUTEX, id, count, timeoutPtr);
// Return value will be written to callback's v0, but... that's probably fine?
}
else
__KernelLockMutex(mutex, count, error);
return 0;
}
}
// int sceKernelTryLockMutex(SceUID id, int count)
int sceKernelTryLockMutex(SceUID id, int count)
{
DEBUG_LOG(SCEKERNEL, "sceKernelTryLockMutex(%i, %i)", id, count);
u32 error;
PSPMutex *mutex = kernelObjects.Get<PSPMutex>(id, error);
if (__KernelLockMutex(mutex, count, error))
return 0;
else if (error)
return error;
else
return PSP_MUTEX_ERROR_TRYLOCK_FAILED;
}
// int sceKernelUnlockMutex(SceUID id, int count)
int sceKernelUnlockMutex(SceUID id, int count)
{
DEBUG_LOG(SCEKERNEL, "sceKernelUnlockMutex(%i, %i)", id, count);
u32 error;
PSPMutex *mutex = kernelObjects.Get<PSPMutex>(id, error);
if (error)
return error;
if (count <= 0)
return SCE_KERNEL_ERROR_ILLEGAL_COUNT;
if ((mutex->nm.attr & PSP_MUTEX_ATTR_ALLOW_RECURSIVE) == 0 && count > 1)
return SCE_KERNEL_ERROR_ILLEGAL_COUNT;
if (mutex->nm.lockLevel == 0 || mutex->nm.lockThread != __KernelGetCurThread())
return PSP_MUTEX_ERROR_NOT_LOCKED;
if (mutex->nm.lockLevel < count)
return PSP_MUTEX_ERROR_UNLOCK_UNDERFLOW;
mutex->nm.lockLevel -= count;
if (mutex->nm.lockLevel == 0)
{
if (__KernelUnlockMutex(mutex, error))
hleReSchedule("mutex unlocked");
}
return 0;
}
int sceKernelReferMutexStatus(SceUID id, u32 infoAddr)
{
u32 error;
PSPMutex *m = kernelObjects.Get<PSPMutex>(id, error);
if (!m)
{
ERROR_LOG(SCEKERNEL, "sceKernelReferMutexStatus(%i, %08x): invalid mutex id", id, infoAddr);
return error;
}
DEBUG_LOG(SCEKERNEL, "sceKernelReferMutexStatus(%08x, %08x)", id, infoAddr);
// Should we crash the thread somehow?
if (!Memory::IsValidAddress(infoAddr))
return -1;
// Don't write if the size is 0. Anything else is A-OK, though, apparently.
if (Memory::Read_U32(infoAddr) != 0)
{
HLEKernel::CleanupWaitingThreads(WAITTYPE_MUTEX, id, m->waitingThreads);
m->nm.numWaitThreads = (int) m->waitingThreads.size();
Memory::WriteStruct(infoAddr, &m->nm);
}
return 0;
}
int sceKernelCreateLwMutex(u32 workareaPtr, const char *name, u32 attr, int initialCount, u32 optionsPtr)
{
if (!name)
{
WARN_LOG_REPORT(SCEKERNEL, "%08x=sceKernelCreateLwMutex(): invalid name", SCE_KERNEL_ERROR_ERROR);
return SCE_KERNEL_ERROR_ERROR;
}
if (attr >= 0x400)
{
WARN_LOG_REPORT(SCEKERNEL, "%08x=sceKernelCreateLwMutex(): invalid attr parameter: %08x", SCE_KERNEL_ERROR_ILLEGAL_ATTR, attr);
return SCE_KERNEL_ERROR_ILLEGAL_ATTR;
}
if (initialCount < 0)
return SCE_KERNEL_ERROR_ILLEGAL_COUNT;
if ((attr & PSP_MUTEX_ATTR_ALLOW_RECURSIVE) == 0 && initialCount > 1)
return SCE_KERNEL_ERROR_ILLEGAL_COUNT;
LwMutex *mutex = new LwMutex();
SceUID id = kernelObjects.Create(mutex);
mutex->nm.size = sizeof(mutex->nm);
strncpy(mutex->nm.name, name, KERNELOBJECT_MAX_NAME_LENGTH);
mutex->nm.name[KERNELOBJECT_MAX_NAME_LENGTH] = 0;
mutex->nm.attr = attr;
mutex->nm.uid = id;
mutex->nm.workarea = workareaPtr;
mutex->nm.initialCount = initialCount;
auto workarea = PSPPointer<NativeLwMutexWorkarea>::Create(workareaPtr);
workarea->init();
workarea->lockLevel = initialCount;
if (initialCount == 0)
workarea->lockThread = 0;
else
workarea->lockThread = __KernelGetCurThread();
workarea->attr = attr;
workarea->uid = id;
DEBUG_LOG(SCEKERNEL, "sceKernelCreateLwMutex(%08x, %s, %08x, %d, %08x)", workareaPtr, name, attr, initialCount, optionsPtr);
if (optionsPtr != 0)
{
u32 size = Memory::Read_U32(optionsPtr);
if (size > 4)
WARN_LOG_REPORT(SCEKERNEL, "sceKernelCreateLwMutex(%s) unsupported options parameter, size = %d", name, size);
}
if ((attr & ~PSP_MUTEX_ATTR_KNOWN) != 0)
WARN_LOG_REPORT(SCEKERNEL, "sceKernelCreateLwMutex(%s) unsupported attr parameter: %08x", name, attr);
return 0;
}
template <typename T>
bool __KernelUnlockLwMutexForThread(LwMutex *mutex, T workarea, SceUID threadID, u32 &error, int result)
{
if (!HLEKernel::VerifyWait(threadID, WAITTYPE_LWMUTEX, mutex->GetUID()))
return false;
// If result is an error code, we're just letting it go.
if (result == 0)
{
workarea->lockLevel = (int) __KernelGetWaitValue(threadID, error);
workarea->lockThread = threadID;
}
u32 timeoutPtr = __KernelGetWaitTimeoutPtr(threadID, error);
if (timeoutPtr != 0 && lwMutexWaitTimer != -1)
{
// Remove any event for this thread.
s64 cyclesLeft = CoreTiming::UnscheduleEvent(lwMutexWaitTimer, threadID);
Memory::Write_U32((u32) cyclesToUs(cyclesLeft), timeoutPtr);
}
__KernelResumeThreadFromWait(threadID, result);
return true;
}
int sceKernelDeleteLwMutex(u32 workareaPtr)
{
DEBUG_LOG(SCEKERNEL, "sceKernelDeleteLwMutex(%08x)", workareaPtr);
if (!workareaPtr || !Memory::IsValidAddress(workareaPtr))
return SCE_KERNEL_ERROR_ILLEGAL_ADDR;
auto workarea = PSPPointer<NativeLwMutexWorkarea>::Create(workareaPtr);
u32 error;
LwMutex *mutex = kernelObjects.Get<LwMutex>(workarea->uid, error);
if (mutex)
{
bool wokeThreads = false;
std::vector<SceUID>::iterator iter, end;
for (iter = mutex->waitingThreads.begin(), end = mutex->waitingThreads.end(); iter != end; ++iter)
wokeThreads |= __KernelUnlockLwMutexForThread(mutex, workarea, *iter, error, SCE_KERNEL_ERROR_WAIT_DELETE);
mutex->waitingThreads.clear();
workarea->clear();
if (wokeThreads)
hleReSchedule("lwmutex deleted");
return kernelObjects.Destroy<LwMutex>(mutex->GetUID());
}
else
return error;
}
static bool __KernelLockLwMutex(NativeLwMutexWorkarea *workarea, int count, u32 &error)
{
if (!error)
{
if (count <= 0)
error = SCE_KERNEL_ERROR_ILLEGAL_COUNT;
else if (count > 1 && !(workarea->attr & PSP_MUTEX_ATTR_ALLOW_RECURSIVE))
error = SCE_KERNEL_ERROR_ILLEGAL_COUNT;
// Two positive ints will always overflow to negative.
else if (count + workarea->lockLevel < 0)
error = PSP_LWMUTEX_ERROR_LOCK_OVERFLOW;
else if (workarea->uid == -1)
error = PSP_LWMUTEX_ERROR_NO_SUCH_LWMUTEX;
}
if (error)
return false;
if (workarea->lockLevel == 0)
{
if (workarea->lockThread != 0)
{
// Validate that it actually exists so we can return an error if not.
kernelObjects.Get<LwMutex>(workarea->uid, error);
if (error)
return false;
}
workarea->lockLevel = count;
workarea->lockThread = __KernelGetCurThread();
return true;
}
if (workarea->lockThread == __KernelGetCurThread())
{
// Recursive mutex, let's just increase the lock count and keep going
if (workarea->attr & PSP_MUTEX_ATTR_ALLOW_RECURSIVE)
{
workarea->lockLevel += count;
return true;
}
else
{
error = PSP_LWMUTEX_ERROR_ALREADY_LOCKED;
return false;
}
}
return false;
}
template <typename T>
bool __KernelUnlockLwMutex(T workarea, u32 &error)
{
LwMutex *mutex = kernelObjects.Get<LwMutex>(workarea->uid, error);
if (error)
{
workarea->lockThread = 0;
return false;
}
bool wokeThreads = false;
std::vector<SceUID>::iterator iter;
while (!wokeThreads && !mutex->waitingThreads.empty())
{
if ((mutex->nm.attr & PSP_MUTEX_ATTR_PRIORITY) != 0)
iter = __KernelMutexFindPriority(mutex->waitingThreads);
else
iter = mutex->waitingThreads.begin();
wokeThreads |= __KernelUnlockLwMutexForThread(mutex, workarea, *iter, error, 0);
mutex->waitingThreads.erase(iter);
}
if (!wokeThreads)
workarea->lockThread = 0;
return wokeThreads;
}
void __KernelLwMutexTimeout(u64 userdata, int cyclesLate)
{
SceUID threadID = (SceUID)userdata;
HLEKernel::WaitExecTimeout<LwMutex, WAITTYPE_LWMUTEX>(threadID);
}
static void __KernelWaitLwMutex(LwMutex *mutex, u32 timeoutPtr)
{
if (timeoutPtr == 0 || lwMutexWaitTimer == -1)
return;
int micro = (int) Memory::Read_U32(timeoutPtr);
// This happens to be how the hardware seems to time things.
if (micro <= 3)
micro = 25;
else if (micro <= 249)
micro = 250;
// This should call __KernelLwMutexTimeout() later, unless we cancel it.
CoreTiming::ScheduleEvent(usToCycles(micro), lwMutexWaitTimer, __KernelGetCurThread());
}
static bool __KernelUnlockLwMutexForThreadCheck(LwMutex *mutex, SceUID threadID, u32 &error, int result, bool &wokeThreads)
{
if (mutex->nm.lockThread == -1 && __KernelUnlockLwMutexForThread(mutex, mutex->nm.workarea, threadID, error, 0))
return true;
return false;
}
void __KernelLwMutexBeginCallback(SceUID threadID, SceUID prevCallbackId)
{
auto result = HLEKernel::WaitBeginCallback<LwMutex, WAITTYPE_LWMUTEX, SceUID>(threadID, prevCallbackId, lwMutexWaitTimer);
if (result == HLEKernel::WAIT_CB_SUCCESS)
DEBUG_LOG(SCEKERNEL, "sceKernelLockLwMutexCB: Suspending lock wait for callback");
else
WARN_LOG_REPORT(SCEKERNEL, "sceKernelLockLwMutexCB: beginning callback with bad wait id?");
}
void __KernelLwMutexEndCallback(SceUID threadID, SceUID prevCallbackId)
{
auto result = HLEKernel::WaitEndCallback<LwMutex, WAITTYPE_LWMUTEX, SceUID>(threadID, prevCallbackId, lwMutexWaitTimer, __KernelUnlockLwMutexForThreadCheck);
if (result == HLEKernel::WAIT_CB_RESUMED_WAIT)
DEBUG_LOG(SCEKERNEL, "sceKernelLockLwMutexCB: Resuming lock wait for callback");
}
int sceKernelTryLockLwMutex(u32 workareaPtr, int count)
{
DEBUG_LOG(SCEKERNEL, "sceKernelTryLockLwMutex(%08x, %i)", workareaPtr, count);
if (!Memory::IsValidAddress(workareaPtr)) {
ERROR_LOG(SCEKERNEL, "Bad workarea pointer for LwMutex");
return SCE_KERNEL_ERROR_ACCESS_ERROR;
}
auto workarea = PSPPointer<NativeLwMutexWorkarea>::Create(workareaPtr);
hleEatCycles(24);
u32 error = 0;
if (__KernelLockLwMutex(workarea, count, error))
return 0;
// Unlike sceKernelTryLockLwMutex_600, this always returns the same error.
else if (error)
return PSP_MUTEX_ERROR_TRYLOCK_FAILED;
else
return PSP_MUTEX_ERROR_TRYLOCK_FAILED;
}
int sceKernelTryLockLwMutex_600(u32 workareaPtr, int count)
{
DEBUG_LOG(SCEKERNEL, "sceKernelTryLockLwMutex_600(%08x, %i)", workareaPtr, count);
if (!Memory::IsValidAddress(workareaPtr)) {
ERROR_LOG(SCEKERNEL, "Bad workarea pointer for LwMutex");
return SCE_KERNEL_ERROR_ACCESS_ERROR;
}
auto workarea = PSPPointer<NativeLwMutexWorkarea>::Create(workareaPtr);
hleEatCycles(24);
u32 error = 0;
if (__KernelLockLwMutex(workarea, count, error))
return 0;
else if (error)
return error;
else
return PSP_LWMUTEX_ERROR_TRYLOCK_FAILED;
}
int sceKernelLockLwMutex(u32 workareaPtr, int count, u32 timeoutPtr)
{
VERBOSE_LOG(SCEKERNEL, "sceKernelLockLwMutex(%08x, %i, %08x)", workareaPtr, count, timeoutPtr);
if (!Memory::IsValidAddress(workareaPtr)) {
ERROR_LOG(SCEKERNEL, "Bad workarea pointer for LwMutex");
return SCE_KERNEL_ERROR_ACCESS_ERROR;
}
auto workarea = PSPPointer<NativeLwMutexWorkarea>::Create(workareaPtr);
hleEatCycles(48);
u32 error = 0;
if (__KernelLockLwMutex(workarea, count, error))
return 0;
else if (error)
return error;
else
{
LwMutex *mutex = kernelObjects.Get<LwMutex>(workarea->uid, error);
if (mutex)
{
SceUID threadID = __KernelGetCurThread();
// May be in a tight loop timing out (where we don't remove from waitingThreads yet), don't want to add duplicates.
if (std::find(mutex->waitingThreads.begin(), mutex->waitingThreads.end(), threadID) == mutex->waitingThreads.end())
mutex->waitingThreads.push_back(threadID);
__KernelWaitLwMutex(mutex, timeoutPtr);
__KernelWaitCurThread(WAITTYPE_LWMUTEX, workarea->uid, count, timeoutPtr, false, "lwmutex waited");
// Return value will be overwritten by wait.
return 0;
}
else
return error;
}
}
int sceKernelLockLwMutexCB(u32 workareaPtr, int count, u32 timeoutPtr)
{
VERBOSE_LOG(SCEKERNEL, "sceKernelLockLwMutexCB(%08x, %i, %08x)", workareaPtr, count, timeoutPtr);
if (!Memory::IsValidAddress(workareaPtr)) {
ERROR_LOG(SCEKERNEL, "Bad workarea pointer for LwMutex");
return SCE_KERNEL_ERROR_ACCESS_ERROR;
}
auto workarea = PSPPointer<NativeLwMutexWorkarea>::Create(workareaPtr);
hleEatCycles(48);
u32 error = 0;
if (__KernelLockLwMutex(workarea, count, error))
return 0;
else if (error)
return error;
else
{
LwMutex *mutex = kernelObjects.Get<LwMutex>(workarea->uid, error);
if (mutex)
{
SceUID threadID = __KernelGetCurThread();
// May be in a tight loop timing out (where we don't remove from waitingThreads yet), don't want to add duplicates.
if (std::find(mutex->waitingThreads.begin(), mutex->waitingThreads.end(), threadID) == mutex->waitingThreads.end())
mutex->waitingThreads.push_back(threadID);
__KernelWaitLwMutex(mutex, timeoutPtr);
__KernelWaitCurThread(WAITTYPE_LWMUTEX, workarea->uid, count, timeoutPtr, true, "lwmutex cb waited");
// Return value will be overwritten by wait.
return 0;
}
else
return error;
}
}
int sceKernelUnlockLwMutex(u32 workareaPtr, int count)
{
VERBOSE_LOG(SCEKERNEL, "sceKernelUnlockLwMutex(%08x, %i)", workareaPtr, count);
if (!Memory::IsValidAddress(workareaPtr)) {
ERROR_LOG(SCEKERNEL, "Bad workarea pointer for LwMutex");
return SCE_KERNEL_ERROR_ACCESS_ERROR;
}
auto workarea = PSPPointer<NativeLwMutexWorkarea>::Create(workareaPtr);
hleEatCycles(28);
if (workarea->uid == -1)
return PSP_LWMUTEX_ERROR_NO_SUCH_LWMUTEX;
else if (count <= 0)
return SCE_KERNEL_ERROR_ILLEGAL_COUNT;
else if ((workarea->attr & PSP_MUTEX_ATTR_ALLOW_RECURSIVE) == 0 && count > 1)
return SCE_KERNEL_ERROR_ILLEGAL_COUNT;
else if (workarea->lockLevel == 0 || workarea->lockThread != __KernelGetCurThread())
return PSP_LWMUTEX_ERROR_NOT_LOCKED;
else if (workarea->lockLevel < count)
return PSP_LWMUTEX_ERROR_UNLOCK_UNDERFLOW;
workarea->lockLevel -= count;
if (workarea->lockLevel == 0)
{
u32 error;
if (__KernelUnlockLwMutex(workarea, error))
hleReSchedule("lwmutex unlocked");
}
return 0;
}
static int __KernelReferLwMutexStatus(SceUID uid, u32 infoPtr)
{
u32 error;
LwMutex *m = kernelObjects.Get<LwMutex>(uid, error);
if (!m)
return error;
// Should we crash the thread somehow?
if (!Memory::IsValidAddress(infoPtr))
return -1;
if (Memory::Read_U32(infoPtr) != 0)
{
auto workarea = m->nm.workarea;
HLEKernel::CleanupWaitingThreads(WAITTYPE_LWMUTEX, uid, m->waitingThreads);
// Refresh and write
m->nm.currentCount = workarea->lockLevel;
m->nm.lockThread = workarea->lockThread == 0 ? SceUID_le(-1) : workarea->lockThread;
m->nm.numWaitThreads = (int) m->waitingThreads.size();
Memory::WriteStruct(infoPtr, &m->nm);
}
return 0;
}
int sceKernelReferLwMutexStatusByID(SceUID uid, u32 infoPtr)
{
int error = __KernelReferLwMutexStatus(uid, infoPtr);
if (error >= 0)
{
DEBUG_LOG(SCEKERNEL, "sceKernelReferLwMutexStatusByID(%08x, %08x)", uid, infoPtr);
return error;
}
else
{
ERROR_LOG(SCEKERNEL, "%08x=sceKernelReferLwMutexStatusByID(%08x, %08x)", error, uid, infoPtr);
return error;
}
}
int sceKernelReferLwMutexStatus(u32 workareaPtr, u32 infoPtr)
{
if (!Memory::IsValidAddress(workareaPtr)) {
ERROR_LOG(SCEKERNEL, "Bad workarea pointer for LwMutex");
return SCE_KERNEL_ERROR_ACCESS_ERROR;
}
auto workarea = PSPPointer<NativeLwMutexWorkarea>::Create(workareaPtr);
int error = __KernelReferLwMutexStatus(workarea->uid, infoPtr);
if (error >= 0)
{
DEBUG_LOG(SCEKERNEL, "sceKernelReferLwMutexStatus(%08x, %08x)", workareaPtr, infoPtr);
return error;
}
else
{
ERROR_LOG(SCEKERNEL, "%08x=sceKernelReferLwMutexStatus(%08x, %08x)", error, workareaPtr, infoPtr);
return error;
}
}