Exemplo n.º 1
0
s32 sys_cond_signal_all(u32 cond_id)
{
	sys_cond.Log("sys_cond_signal_all(cond_id=%d)", cond_id);

	Cond* cond;
	if (!Emu.GetIdManager().GetIDData(cond_id, cond))
	{
		return CELL_ESRCH;
	}

	Mutex* mutex = cond->mutex;

	while (u32 target = (mutex->protocol == SYS_SYNC_PRIORITY ? cond->m_queue.pop_prio() : cond->m_queue.pop()))
	{
		cond->signaler = GetCurrentCPUThread()->GetId();
		//cond->signal_stamp = get_system_time();
		cond->signal.lock(target);
		Emu.GetCPU().NotifyThread(target);

		if (Emu.IsStopped())
		{
			sys_cond.Warning("sys_cond_signal_all(id=%d) aborted", cond_id);
			break;
		}
	}

	cond->signaler = 0;
	return CELL_OK;
}
Exemplo n.º 2
0
__forceinline u32 SM_GetCurrentCPUThreadId()
{
	if (CPUThread* t = GetCurrentCPUThread())
	{
		return t->GetId();
	}
	return 0;
}
Exemplo n.º 3
0
PPCThread* GetCurrentPPCThread()
{
	CPUThread* thread = GetCurrentCPUThread();

	if(!thread || (thread->GetType() != CPU_THREAD_PPU && thread->GetType() != CPU_THREAD_SPU && thread->GetType() != CPU_THREAD_RAW_SPU))
	{
		throw wxString("GetCurrentPPCThread: bad thread");
	}

	return (PPCThread*)thread;
}
Exemplo n.º 4
0
void _se_translator(unsigned int u, EXCEPTION_POINTERS* pExp)
{
	const u64 addr = (u64)pExp->ExceptionRecord->ExceptionInformation[1] - (u64)Memory.GetBaseAddr();
	CPUThread* t = GetCurrentCPUThread();
	if (u == EXCEPTION_ACCESS_VIOLATION && addr < 0x100000000 && t)
	{
		// TODO: allow recovering from a page fault
		throw fmt::Format("Access violation: addr = 0x%x (is_alive=%d, last_syscall=0x%llx (%s))",
			(u32)addr, t->IsAlive() ? 1 : 0, t->m_last_syscall, SysCalls::GetHLEFuncName((u32)t->m_last_syscall).c_str());
	}
	else
	{
		// some fatal error (should crash)
		return;
	}
}
Exemplo n.º 5
0
void CPUThread::Stop()
{
	if(IsStopped()) return;

	SendDbgCommand(DID_STOP_THREAD, this);

	m_status = Stopped;

	if(CPUThread* thr = GetCurrentCPUThread())
	{
		if(thr->GetId() != GetId())
			ThreadBase::Stop();
	}
	else
		ThreadBase::Stop();

	Emu.CheckStatus();

	SendDbgCommand(DID_STOPED_THREAD, this);
}
Exemplo n.º 6
0
void SPUThread::WriteChannel(u32 ch, const u128& r)
{
	const u32 v = r._u32[3];

	switch (ch)
	{
	case SPU_WrOutIntrMbox:
	{
		if (!group) // if RawSPU
		{
			if (Ini.HLELogging.GetValue()) LOG_NOTICE(Log::SPU, "SPU_WrOutIntrMbox: interrupt(v=0x%x)", v);
			while (!SPU.Out_IntrMBox.Push(v))
			{
				std::this_thread::sleep_for(std::chrono::milliseconds(1));
				if (Emu.IsStopped())
				{
					LOG_WARNING(Log::SPU, "%s(%s) aborted", __FUNCTION__, spu_ch_name[ch]);
					return;
				}
			}
			m_intrtag[2].stat |= 1;
			if (CPUThread* t = Emu.GetCPU().GetThread(m_intrtag[2].thread))
			{
				if (t->GetType() == CPU_THREAD_PPU)
				{
					if (t->IsAlive())
					{
						LOG_ERROR(Log::SPU, "%s(%s): interrupt thread was alive", __FUNCTION__, spu_ch_name[ch]);
						Emu.Pause();
						return;
					}
					PPUThread& ppu = *(PPUThread*)t;
					ppu.GPR[3] = ppu.m_interrupt_arg;
					ppu.FastCall2(vm::read32(ppu.entry), vm::read32(ppu.entry + 4));
				}
			}
		}
		else
		{
			const u8 code = v >> 24;
			if (code < 64)
			{
				/* ===== sys_spu_thread_send_event (used by spu_printf) ===== */

				u8 spup = code & 63;

				u32 data;
				if (!SPU.Out_MBox.Pop(data))
				{
					LOG_ERROR(Log::SPU, "sys_spu_thread_send_event(v=0x%x, spup=%d): Out_MBox is empty", v, spup);
					return;
				}

				if (Ini.HLELogging.GetValue())
				{
					LOG_NOTICE(Log::SPU, "sys_spu_thread_send_event(spup=%d, data0=0x%x, data1=0x%x)", spup, v & 0x00ffffff, data);
				}

				EventPort& port = SPUPs[spup];

				std::lock_guard<std::mutex> lock(port.m_mutex);

				if (!port.eq)
				{
					LOG_WARNING(Log::SPU, "sys_spu_thread_send_event(spup=%d, data0=0x%x, data1=0x%x): event queue not connected", spup, (v & 0x00ffffff), data);
					SPU.In_MBox.PushUncond(CELL_ENOTCONN); // TODO: check error passing
					return;
				}

				if (!port.eq->events.push(SYS_SPU_THREAD_EVENT_USER_KEY, GetCurrentCPUThread()->GetId(), ((u64)spup << 32) | (v & 0x00ffffff), data))
				{
					SPU.In_MBox.PushUncond(CELL_EBUSY);
					return;
				}

				SPU.In_MBox.PushUncond(CELL_OK);
				return;
			}
			else if (code < 128)
			{
				/* ===== sys_spu_thread_throw_event ===== */

				const u8 spup = code & 63;

				u32 data;
				if (!SPU.Out_MBox.Pop(data))
				{
					LOG_ERROR(Log::SPU, "sys_spu_thread_throw_event(v=0x%x, spup=%d): Out_MBox is empty", v, spup);
					return;
				}

				//if (Ini.HLELogging.GetValue())
				{
					LOG_WARNING(Log::SPU, "sys_spu_thread_throw_event(spup=%d, data0=0x%x, data1=0x%x)", spup, v & 0x00ffffff, data);
				}

				EventPort& port = SPUPs[spup];

				std::lock_guard<std::mutex> lock(port.m_mutex);

				if (!port.eq)
				{
					LOG_WARNING(Log::SPU, "sys_spu_thread_throw_event(spup=%d, data0=0x%x, data1=0x%x): event queue not connected", spup, (v & 0x00ffffff), data);
					return;
				}

				// TODO: check passing spup value
				if (!port.eq->events.push(SYS_SPU_THREAD_EVENT_USER_KEY, GetCurrentCPUThread()->GetId(), ((u64)spup << 32) | (v & 0x00ffffff), data))
				{
					LOG_WARNING(Log::SPU, "sys_spu_thread_throw_event(spup=%d, data0=0x%x, data1=0x%x) failed (queue is full)", spup, (v & 0x00ffffff), data);
					return;
				}

				return;
			}
			else if (code == 128)
			{
				/* ===== sys_event_flag_set_bit ===== */
				u32 flag = v & 0xffffff;

				u32 data;
				if (!SPU.Out_MBox.Pop(data))
				{
					LOG_ERROR(Log::SPU, "sys_event_flag_set_bit(v=0x%x (flag=%d)): Out_MBox is empty", v, flag);
					return;
				}

				if (flag > 63)
				{
					LOG_ERROR(Log::SPU, "sys_event_flag_set_bit(id=%d, v=0x%x): flag > 63", data, v, flag);
					return;
				}

				//if (Ini.HLELogging.GetValue())
				{
					LOG_WARNING(Log::SPU, "sys_event_flag_set_bit(id=%d, v=0x%x (flag=%d))", data, v, flag);
				}

				EventFlag* ef;
				if (!Emu.GetIdManager().GetIDData(data, ef))
				{
					LOG_ERROR(Log::SPU, "sys_event_flag_set_bit(id=%d, v=0x%x (flag=%d)): EventFlag not found", data, v, flag);
					SPU.In_MBox.PushUncond(CELL_ESRCH);
					return;
				}

				u32 tid = GetCurrentCPUThread()->GetId();

				ef->m_mutex.lock(tid);
				ef->flags |= (u64)1 << flag;
				if (u32 target = ef->check())
				{
					// if signal, leave both mutexes locked...
					ef->signal.lock(target);
					ef->m_mutex.unlock(tid, target);
				}
				else
				{
					ef->m_mutex.unlock(tid);
				}

				SPU.In_MBox.PushUncond(CELL_OK);
				return;
			}
			else if (code == 192)
			{
				/* ===== sys_event_flag_set_bit_impatient ===== */
				u32 flag = v & 0xffffff;

				u32 data;
				if (!SPU.Out_MBox.Pop(data))
				{
					LOG_ERROR(Log::SPU, "sys_event_flag_set_bit_impatient(v=0x%x (flag=%d)): Out_MBox is empty", v, flag);
					return;
				}

				if (flag > 63)
				{
					LOG_ERROR(Log::SPU, "sys_event_flag_set_bit_impatient(id=%d, v=0x%x): flag > 63", data, v, flag);
					return;
				}

				//if (Ini.HLELogging.GetValue())
				{
					LOG_WARNING(Log::SPU, "sys_event_flag_set_bit_impatient(id=%d, v=0x%x (flag=%d))", data, v, flag);
				}

				EventFlag* ef;
				if (!Emu.GetIdManager().GetIDData(data, ef))
				{
					LOG_WARNING(Log::SPU, "sys_event_flag_set_bit_impatient(id=%d, v=0x%x (flag=%d)): EventFlag not found", data, v, flag);
					return;
				}

				u32 tid = GetCurrentCPUThread()->GetId();

				ef->m_mutex.lock(tid);
				ef->flags |= (u64)1 << flag;
				if (u32 target = ef->check())
				{
					// if signal, leave both mutexes locked...
					ef->signal.lock(target);
					ef->m_mutex.unlock(tid, target);
				}
				else
				{
					ef->m_mutex.unlock(tid);
				}

				return;
			}
			else
			{
				u32 data;
				if (SPU.Out_MBox.Pop(data))
				{
					LOG_ERROR(Log::SPU, "SPU_WrOutIntrMbox: unknown data (v=0x%x); Out_MBox = 0x%x", v, data);
				}
				else
				{
					LOG_ERROR(Log::SPU, "SPU_WrOutIntrMbox: unknown data (v=0x%x)", v);
				}
				SPU.In_MBox.PushUncond(CELL_EINVAL); // ???
				return;
			}
		}
		break;
	}

	case SPU_WrOutMbox:
	{
		while (!SPU.Out_MBox.Push(v) && !Emu.IsStopped()) std::this_thread::sleep_for(std::chrono::milliseconds(1));
		break;
	}

	case MFC_WrTagMask:
	{
		MFC1.QueryMask.SetValue(v);
		break;
	}

	case MFC_WrTagUpdate:
	{
		MFC1.TagStatus.PushUncond(MFC1.QueryMask.GetValue());
		break;
	}

	case MFC_LSA:
	{
		MFC1.LSA.SetValue(v);
		break;
	}

	case MFC_EAH:
	{
		MFC1.EAH.SetValue(v);
		break;
	}

	case MFC_EAL:
	{
		MFC1.EAL.SetValue(v);
		break;
	}

	case MFC_Size:
	{
		MFC1.Size_Tag.SetValue((MFC1.Size_Tag.GetValue() & 0xffff) | (v << 16));
		break;
	}

	case MFC_TagID:
	{
		MFC1.Size_Tag.SetValue((MFC1.Size_Tag.GetValue() & ~0xffff) | (v & 0xffff));
		break;
	}


	case MFC_Cmd:
	{
		MFC1.CMDStatus.SetValue(v);
		EnqMfcCmd(MFC1);
		break;
	}

	case MFC_WrListStallAck:
	{
		if (v >= 32)
		{
			LOG_ERROR(Log::SPU, "MFC_WrListStallAck error: invalid tag(%d)", v);
			return;
		}
		StalledList temp = StallList[v];
		if (!temp.MFCArgs)
		{
			LOG_ERROR(Log::SPU, "MFC_WrListStallAck error: empty tag(%d)", v);
			return;
		}
		StallList[v].MFCArgs = nullptr;
		ListCmd(temp.lsa, temp.ea, temp.tag, temp.size, temp.cmd, *temp.MFCArgs);
		break;
	}

	case SPU_WrDec:
	{
		m_dec_start = get_time();
		m_dec_value = v;
		break;
	}

	case SPU_WrEventMask:
	{
		m_event_mask = v;
		if (v & ~(SPU_EVENT_IMPLEMENTED)) LOG_ERROR(Log::SPU, "SPU_WrEventMask: unsupported event masked (0x%x)");
		break;
	}

	case SPU_WrEventAck:
	{
		m_events &= ~v;
		break;
	}

	default:
	{
		LOG_ERROR(Log::SPU, "%s error (v=0x%x): unknown/illegal channel (%d [%s]).", __FUNCTION__, v, ch, spu_ch_name[ch]);
		break;
	}
	}

	if (Emu.IsStopped()) LOG_WARNING(Log::SPU, "%s(%s) aborted", __FUNCTION__, spu_ch_name[ch]);
}