1
0
mirror of https://github.com/RPCS3/rpcs3.git synced 2024-11-25 04:02:42 +01:00

SPU fixes, various fixes

This commit is contained in:
Nekotekina 2015-07-03 19:07:36 +03:00
parent 721ad404d2
commit 8f9e1100c8
33 changed files with 1021 additions and 871 deletions

3
.gitignore vendored
View File

@ -70,3 +70,6 @@ rpcs3/x64/*
.DS_Store
rpcs3/Emu/SysCalls/Modules/prx_*.h
/CMakeFiles/
CMakeCache.txt

View File

@ -807,9 +807,9 @@ bool handle_access_violation(u32 addr, bool is_writing, x64_context* context)
// check if address is RawSPU MMIO register
if (addr - RAW_SPU_BASE_ADDR < (6 * RAW_SPU_OFFSET) && (addr % RAW_SPU_OFFSET) >= RAW_SPU_PROB_OFFSET)
{
auto t = Emu.GetCPU().GetRawSPUThread((addr - RAW_SPU_BASE_ADDR) / RAW_SPU_OFFSET);
auto thread = Emu.GetCPU().GetRawSPUThread((addr - RAW_SPU_BASE_ADDR) / RAW_SPU_OFFSET);
if (!t)
if (!thread)
{
return false;
}
@ -820,14 +820,12 @@ bool handle_access_violation(u32 addr, bool is_writing, x64_context* context)
return false;
}
auto& spu = static_cast<RawSPUThread&>(*t);
switch (op)
{
case X64OP_LOAD:
{
u32 value;
if (is_writing || !spu.ReadReg(addr, value) || !put_x64_reg_value(context, reg, d_size, _byteswap_ulong(value)))
if (is_writing || !thread->ReadReg(addr, value) || !put_x64_reg_value(context, reg, d_size, _byteswap_ulong(value)))
{
return false;
}
@ -837,7 +835,7 @@ bool handle_access_violation(u32 addr, bool is_writing, x64_context* context)
case X64OP_STORE:
{
u64 reg_value;
if (!is_writing || !get_x64_reg_value(context, reg, d_size, i_size, reg_value) || !spu.WriteReg(addr, _byteswap_ulong((u32)reg_value)))
if (!is_writing || !get_x64_reg_value(context, reg, d_size, i_size, reg_value) || !thread->WriteReg(addr, _byteswap_ulong((u32)reg_value)))
{
return false;
}
@ -1251,11 +1249,11 @@ void thread_t::start(std::function<std::string()> name, std::function<void()> fu
throw EXCEPTION("Thread already exists");
}
// create new ctrl and assign it
auto ctrl = std::make_shared<thread_ctrl_t>(std::move(name));
// create new thread control variable
m_thread = std::make_shared<thread_ctrl_t>(std::move(name));
// start thread
ctrl->m_thread = std::thread([ctrl, func]()
m_thread->m_thread = std::thread([](std::shared_ptr<thread_ctrl_t> ctrl, std::function<void()> func)
{
g_thread_count++;
@ -1326,10 +1324,7 @@ void thread_t::start(std::function<std::string()> name, std::function<void()> fu
#if defined(_MSC_VER)
_set_se_translator(old_se_translator);
#endif
});
// set
m_thread = std::move(ctrl);
}, m_thread, std::move(func));
}
void thread_t::detach()
@ -1339,8 +1334,11 @@ void thread_t::detach()
throw EXCEPTION("Invalid thread");
}
// +clear m_thread
const auto ctrl = std::move(m_thread);
cv.notify_all();
ctrl->m_thread.detach();
}
@ -1356,8 +1354,11 @@ void thread_t::join(std::unique_lock<std::mutex>& lock)
throw EXCEPTION("Deadlock");
}
// +clear m_thread
const auto ctrl = std::move(m_thread);
cv.notify_all();
// wait for completion
while (ctrl->joinable)
{
@ -1381,8 +1382,11 @@ void thread_t::join()
throw EXCEPTION("Deadlock");
}
// +clear m_thread
const auto ctrl = std::move(m_thread);
cv.notify_all();
ctrl->m_thread.join();
}

View File

@ -59,7 +59,7 @@ public:
virtual void operator ()(TO* op, u32 code) const
{
(op->*m_func)((T1)m_arg_func_1(code));
(op->*m_func)(static_cast<T1>(m_arg_func_1(code)));
}
};
@ -83,8 +83,8 @@ public:
virtual void operator ()(TO* op, u32 code) const
{
(op->*m_func)(
(T1)m_arg_func_1(code),
(T2)m_arg_func_2(code)
static_cast<T1>(m_arg_func_1(code)),
static_cast<T2>(m_arg_func_2(code))
);
}
};
@ -114,9 +114,9 @@ public:
virtual void operator ()(TO* op, u32 code) const
{
(op->*m_func)(
(T1)m_arg_func_1(code),
(T2)m_arg_func_2(code),
(T3)m_arg_func_3(code)
static_cast<T1>(m_arg_func_1(code)),
static_cast<T2>(m_arg_func_2(code)),
static_cast<T3>(m_arg_func_3(code))
);
}
};
@ -149,10 +149,10 @@ public:
virtual void operator ()(TO* op, u32 code) const
{
(op->*m_func)(
(T1)m_arg_func_1(code),
(T2)m_arg_func_2(code),
(T3)m_arg_func_3(code),
(T4)m_arg_func_4(code)
static_cast<T1>(m_arg_func_1(code)),
static_cast<T2>(m_arg_func_2(code)),
static_cast<T3>(m_arg_func_3(code)),
static_cast<T4>(m_arg_func_4(code))
);
}
};
@ -188,11 +188,11 @@ public:
virtual void operator ()(TO* op, u32 code) const
{
(op->*m_func)(
(T1)m_arg_func_1(code),
(T2)m_arg_func_2(code),
(T3)m_arg_func_3(code),
(T4)m_arg_func_4(code),
(T5)m_arg_func_5(code)
static_cast<T1>(m_arg_func_1(code)),
static_cast<T2>(m_arg_func_2(code)),
static_cast<T3>(m_arg_func_3(code)),
static_cast<T4>(m_arg_func_4(code)),
static_cast<T5>(m_arg_func_5(code))
);
}
};
@ -231,12 +231,12 @@ public:
virtual void operator ()(TO* op, u32 code) const
{
(op->*m_func)(
(T1)m_arg_func_1(code),
(T2)m_arg_func_2(code),
(T3)m_arg_func_3(code),
(T4)m_arg_func_4(code),
(T5)m_arg_func_5(code),
(T6)m_arg_func_6(code)
static_cast<T1>(m_arg_func_1(code)),
static_cast<T2>(m_arg_func_2(code)),
static_cast<T3>(m_arg_func_3(code)),
static_cast<T4>(m_arg_func_4(code)),
static_cast<T5>(m_arg_func_5(code)),
static_cast<T6>(m_arg_func_6(code))
);
}
};

View File

@ -168,14 +168,28 @@ void CPUThread::Step()
void CPUThread::Sleep()
{
m_state ^= CPU_STATE_SLEEP;
m_state += CPU_STATE_MAX;
m_state |= CPU_STATE_SLEEP;
cv.notify_one();
}
void CPUThread::Awake()
{
m_state ^= CPU_STATE_SLEEP;
// must be called after the corresponding Sleep() call
m_state.atomic_op([](u64& state)
{
if (state < CPU_STATE_MAX)
{
throw EXCEPTION("Sleep()/Awake() inconsistency");
}
if ((state -= CPU_STATE_MAX) < CPU_STATE_MAX)
{
state &= ~CPU_STATE_SLEEP;
}
});
cv.notify_one();
}

View File

@ -14,11 +14,13 @@ enum CPUThreadType
enum : u64
{
CPU_STATE_STOPPED = (1ull << 0), // basic execution state (stopped by default), removed by Exec()
CPU_STATE_PAUSED = (1ull << 1), // paused by debugger (manually or after step execution)
CPU_STATE_SLEEP = (1ull << 2),
CPU_STATE_STEP = (1ull << 3),
CPU_STATE_DEAD = (1ull << 4),
CPU_STATE_RETURN = (1ull << 5),
CPU_STATE_PAUSED = (1ull << 1), // pauses thread execution, set by the debugger (manually or after step execution)
CPU_STATE_SLEEP = (1ull << 2), // shouldn't affect thread execution, set by Sleep() call, removed by the latest Awake() call, may possibly indicate waiting state of the thread
CPU_STATE_STEP = (1ull << 3), // forces the thread to pause after executing just one instruction or something appropriate, set by the debugger
CPU_STATE_DEAD = (1ull << 4), // indicates irreversible exit of the thread
CPU_STATE_RETURN = (1ull << 5), // used for callback return
CPU_STATE_MAX = (1ull << 6), // added to (subtracted from) m_state by Sleep()/Awake() calls to trigger status check
};
// "HLE return" exception event
@ -71,16 +73,35 @@ public:
virtual void InitStack() = 0;
virtual void CloseStack() = 0;
// initialize thread
void Run();
// called by the debugger, don't use
void Pause();
// called by the debugger, don't use
void Resume();
// stop thread execution
void Stop();
// start thread execution (removing STOP status)
void Exec();
// exit thread execution
void Exit();
void Step(); // set STEP status, don't use
void Sleep(); // flip SLEEP status, don't use
void Awake(); // flip SLEEP status, don't use
bool CheckStatus(); // process m_state flags, returns true if the checker must return
// called by the debugger, don't use
void Step();
// trigger thread status check
void Sleep();
// untrigger thread status check
void Awake();
// process m_state flags, returns true if the checker must return
bool CheckStatus();
std::string GetFName() const
{

View File

@ -43,7 +43,7 @@ protected:
{
Write(fmt::Format("%s v%d,r%d,r%d", FixOp(op).c_str(), v0, r1, r2));
}
void DisAsm_CR1_F2_RC(const std::string& op, u32 cr0, u32 f0, u32 f1, bool rc)
void DisAsm_CR1_F2_RC(const std::string& op, u32 cr0, u32 f0, u32 f1, u32 rc)
{
Write(fmt::Format("%s%s cr%d,f%d,f%d", FixOp(op).c_str(), (rc ? "." : ""), cr0, f0, f1));
}
@ -59,7 +59,7 @@ protected:
{
Write(fmt::Format("%s %d,r%d,%d #%x", FixOp(op).c_str(), i0, r0, imm0, imm0));
}
void DisAsm_INT1_R1_RC(const std::string& op, u32 i0, u32 r0, bool rc)
void DisAsm_INT1_R1_RC(const std::string& op, u32 i0, u32 r0, u32 rc)
{
Write(fmt::Format("%s%s %d,r%d", FixOp(op).c_str(), (rc ? "." : ""), i0, r0));
}
@ -67,11 +67,11 @@ protected:
{
DisAsm_INT1_R1_RC(op, i0, r0, false);
}
void DisAsm_F4_RC(const std::string& op, u32 f0, u32 f1, u32 f2, u32 f3, bool rc)
void DisAsm_F4_RC(const std::string& op, u32 f0, u32 f1, u32 f2, u32 f3, u32 rc)
{
Write(fmt::Format("%s%s f%d,f%d,f%d,f%d", FixOp(op).c_str(), (rc ? "." : ""), f0, f1, f2, f3));
}
void DisAsm_F3_RC(const std::string& op, u32 f0, u32 f1, u32 f2, bool rc)
void DisAsm_F3_RC(const std::string& op, u32 f0, u32 f1, u32 f2, u32 rc)
{
Write(fmt::Format("%s%s f%d,f%d,f%d", FixOp(op).c_str(), (rc ? "." : ""), f0, f1, f2));
}
@ -79,7 +79,7 @@ protected:
{
DisAsm_F3_RC(op, f0, f1, f2, false);
}
void DisAsm_F2_RC(const std::string& op, u32 f0, u32 f1, bool rc)
void DisAsm_F2_RC(const std::string& op, u32 f0, u32 f1, u32 rc)
{
Write(fmt::Format("%s%s f%d,f%d", FixOp(op).c_str(), (rc ? "." : ""), f0, f1));
}
@ -97,7 +97,7 @@ protected:
Write(fmt::Format("%s f%d,r%d(r%d)", FixOp(op).c_str(), f0, r0, r1));
}
void DisAsm_F1_IMM_R1_RC(const std::string& op, u32 f0, s32 imm0, u32 r0, bool rc)
void DisAsm_F1_IMM_R1_RC(const std::string& op, u32 f0, s32 imm0, u32 r0, u32 rc)
{
if(m_mode == CPUDisAsm_CompilerElfMode)
{
@ -111,11 +111,11 @@ protected:
{
DisAsm_F1_IMM_R1_RC(op, f0, imm0, r0, false);
}
void DisAsm_F1_RC(const std::string& op, u32 f0, bool rc)
void DisAsm_F1_RC(const std::string& op, u32 f0, u32 rc)
{
Write(fmt::Format("%s%s f%d", FixOp(op).c_str(), (rc ? "." : ""), f0));
}
void DisAsm_R1_RC(const std::string& op, u32 r0, bool rc)
void DisAsm_R1_RC(const std::string& op, u32 r0, u32 rc)
{
Write(fmt::Format("%s%s r%d", FixOp(op).c_str(), (rc ? "." : ""), r0));
}
@ -123,11 +123,11 @@ protected:
{
DisAsm_R1_RC(op, r0, false);
}
void DisAsm_R2_OE_RC(const std::string& op, u32 r0, u32 r1, u32 oe, bool rc)
void DisAsm_R2_OE_RC(const std::string& op, u32 r0, u32 r1, u32 oe, u32 rc)
{
Write(fmt::Format("%s%s%s r%d,r%d", FixOp(op).c_str(), (oe ? "o" : ""), (rc ? "." : ""), r0, r1));
}
void DisAsm_R2_RC(const std::string& op, u32 r0, u32 r1, bool rc)
void DisAsm_R2_RC(const std::string& op, u32 r0, u32 r1, u32 rc)
{
DisAsm_R2_OE_RC(op, r0, r1, false, rc);
}
@ -135,15 +135,15 @@ protected:
{
DisAsm_R2_RC(op, r0, r1, false);
}
void DisAsm_R3_OE_RC(const std::string& op, u32 r0, u32 r1, u32 r2, u32 oe, bool rc)
void DisAsm_R3_OE_RC(const std::string& op, u32 r0, u32 r1, u32 r2, u32 oe, u32 rc)
{
Write(fmt::Format("%s%s%s r%d,r%d,r%d", FixOp(op).c_str(), (oe ? "o" : ""), (rc ? "." : ""), r0, r1, r2));
}
void DisAsm_R3_INT2_RC(const std::string& op, u32 r0, u32 r1, u32 r2, s32 i0, s32 i1, bool rc)
void DisAsm_R3_INT2_RC(const std::string& op, u32 r0, u32 r1, u32 r2, s32 i0, s32 i1, u32 rc)
{
Write(fmt::Format("%s%s r%d,r%d,r%d,%d,%d", FixOp(op).c_str(), (rc ? "." : ""), r0, r1, r2, i0, i1));
}
void DisAsm_R3_RC(const std::string& op, u32 r0, u32 r1, u32 r2, bool rc)
void DisAsm_R3_RC(const std::string& op, u32 r0, u32 r1, u32 r2, u32 rc)
{
DisAsm_R3_OE_RC(op, r0, r1, r2, false, rc);
}
@ -151,7 +151,7 @@ protected:
{
DisAsm_R3_RC(op, r0, r1, r2, false);
}
void DisAsm_R2_INT3_RC(const std::string& op, u32 r0, u32 r1, s32 i0, s32 i1, s32 i2, bool rc)
void DisAsm_R2_INT3_RC(const std::string& op, u32 r0, u32 r1, s32 i0, s32 i1, s32 i2, u32 rc)
{
Write(fmt::Format("%s%s r%d,r%d,%d,%d,%d", FixOp(op).c_str(), (rc ? "." : ""), r0, r1, i0, i1, i2));
}
@ -159,7 +159,7 @@ protected:
{
DisAsm_R2_INT3_RC(op, r0, r1, i0, i1, i2, false);
}
void DisAsm_R2_INT2_RC(const std::string& op, u32 r0, u32 r1, s32 i0, s32 i1, bool rc)
void DisAsm_R2_INT2_RC(const std::string& op, u32 r0, u32 r1, s32 i0, s32 i1, u32 rc)
{
Write(fmt::Format("%s%s r%d,r%d,%d,%d", FixOp(op).c_str(), (rc ? "." : ""), r0, r1, i0, i1));
}
@ -167,7 +167,7 @@ protected:
{
DisAsm_R2_INT2_RC(op, r0, r1, i0, i1, false);
}
void DisAsm_R2_INT1_RC(const std::string& op, u32 r0, u32 r1, s32 i0, bool rc)
void DisAsm_R2_INT1_RC(const std::string& op, u32 r0, u32 r1, s32 i0, u32 rc)
{
Write(fmt::Format("%s%s r%d,r%d,%d", FixOp(op).c_str(), (rc ? "." : ""), r0, r1, i0));
}
@ -197,7 +197,7 @@ protected:
{
Write(fmt::Format("%s cr%d,r%d,%d #%x", FixOp(op).c_str(), cr0, r0, imm0, imm0));
}
void DisAsm_CR1_R2_RC(const std::string& op, u32 cr0, u32 r0, u32 r1, bool rc)
void DisAsm_CR1_R2_RC(const std::string& op, u32 cr0, u32 r0, u32 r1, u32 rc)
{
Write(fmt::Format("%s%s cr%d,r%d,r%d", FixOp(op).c_str(), (rc ? "." : ""), cr0, r0, r1));
}

View File

@ -50,7 +50,7 @@ private:
{
Write(fmt::Format("%s v%d,r%d,r%d", FixOp(op).c_str(), v0, r1, r2));
}
void DisAsm_CR1_F2_RC(const std::string& op, u32 cr0, u32 f0, u32 f1, bool rc)
void DisAsm_CR1_F2_RC(const std::string& op, u32 cr0, u32 f0, u32 f1, u32 rc)
{
Write(fmt::Format("%s%s cr%d,f%d,f%d", FixOp(op).c_str(), (rc ? "." : ""), cr0, f0, f1));
}
@ -66,7 +66,7 @@ private:
{
Write(fmt::Format("%s %d,r%d,%d #%x", FixOp(op).c_str(), i0, r0, imm0, imm0));
}
void DisAsm_INT1_R1_RC(const std::string& op, u32 i0, u32 r0, bool rc)
void DisAsm_INT1_R1_RC(const std::string& op, u32 i0, u32 r0, u32 rc)
{
Write(fmt::Format("%s%s %d,r%d", FixOp(op).c_str(), (rc ? "." : ""), i0, r0));
}
@ -74,11 +74,11 @@ private:
{
DisAsm_INT1_R1_RC(op, i0, r0, false);
}
void DisAsm_F4_RC(const std::string& op, u32 f0, u32 f1, u32 f2, u32 f3, bool rc)
void DisAsm_F4_RC(const std::string& op, u32 f0, u32 f1, u32 f2, u32 f3, u32 rc)
{
Write(fmt::Format("%s%s f%d,f%d,f%d,f%d", FixOp(op).c_str(), (rc ? "." : ""), f0, f1, f2, f3));
}
void DisAsm_F3_RC(const std::string& op, u32 f0, u32 f1, u32 f2, bool rc)
void DisAsm_F3_RC(const std::string& op, u32 f0, u32 f1, u32 f2, u32 rc)
{
Write(fmt::Format("%s%s f%d,f%d,f%d", FixOp(op).c_str(), (rc ? "." : ""), f0, f1, f2));
}
@ -86,7 +86,7 @@ private:
{
DisAsm_F3_RC(op, f0, f1, f2, false);
}
void DisAsm_F2_RC(const std::string& op, u32 f0, u32 f1, bool rc)
void DisAsm_F2_RC(const std::string& op, u32 f0, u32 f1, u32 rc)
{
Write(fmt::Format("%s%s f%d,f%d", FixOp(op).c_str(), (rc ? "." : ""), f0, f1));
}
@ -104,7 +104,7 @@ private:
Write(fmt::Format("%s f%d,r%d(r%d)", FixOp(op).c_str(), f0, r0, r1));
}
void DisAsm_F1_IMM_R1_RC(const std::string& op, u32 f0, s32 imm0, u32 r0, bool rc)
void DisAsm_F1_IMM_R1_RC(const std::string& op, u32 f0, s32 imm0, u32 r0, u32 rc)
{
if(m_mode == CPUDisAsm_CompilerElfMode)
{
@ -118,11 +118,11 @@ private:
{
DisAsm_F1_IMM_R1_RC(op, f0, imm0, r0, false);
}
void DisAsm_F1_RC(const std::string& op, u32 f0, bool rc)
void DisAsm_F1_RC(const std::string& op, u32 f0, u32 rc)
{
Write(fmt::Format("%s%s f%d", FixOp(op).c_str(), (rc ? "." : ""), f0));
}
void DisAsm_R1_RC(const std::string& op, u32 r0, bool rc)
void DisAsm_R1_RC(const std::string& op, u32 r0, u32 rc)
{
Write(fmt::Format("%s%s r%d", FixOp(op).c_str(), (rc ? "." : ""), r0));
}
@ -130,11 +130,11 @@ private:
{
DisAsm_R1_RC(op, r0, false);
}
void DisAsm_R2_OE_RC(const std::string& op, u32 r0, u32 r1, u32 oe, bool rc)
void DisAsm_R2_OE_RC(const std::string& op, u32 r0, u32 r1, u32 oe, u32 rc)
{
Write(fmt::Format("%s%s%s r%d,r%d", FixOp(op).c_str(), (oe ? "o" : ""), (rc ? "." : ""), r0, r1));
}
void DisAsm_R2_RC(const std::string& op, u32 r0, u32 r1, bool rc)
void DisAsm_R2_RC(const std::string& op, u32 r0, u32 r1, u32 rc)
{
DisAsm_R2_OE_RC(op, r0, r1, false, rc);
}
@ -142,15 +142,15 @@ private:
{
DisAsm_R2_RC(op, r0, r1, false);
}
void DisAsm_R3_OE_RC(const std::string& op, u32 r0, u32 r1, u32 r2, u32 oe, bool rc)
void DisAsm_R3_OE_RC(const std::string& op, u32 r0, u32 r1, u32 r2, u32 oe, u32 rc)
{
Write(fmt::Format("%s%s%s r%d,r%d,r%d", FixOp(op).c_str(), (oe ? "o" : ""), (rc ? "." : ""), r0, r1, r2));
}
void DisAsm_R3_INT2_RC(const std::string& op, u32 r0, u32 r1, u32 r2, s32 i0, s32 i1, bool rc)
void DisAsm_R3_INT2_RC(const std::string& op, u32 r0, u32 r1, u32 r2, s32 i0, s32 i1, u32 rc)
{
Write(fmt::Format("%s%s r%d,r%d,r%d,%d,%d", FixOp(op).c_str(), (rc ? "." : ""), r0, r1, r2, i0, i1));
}
void DisAsm_R3_RC(const std::string& op, u32 r0, u32 r1, u32 r2, bool rc)
void DisAsm_R3_RC(const std::string& op, u32 r0, u32 r1, u32 r2, u32 rc)
{
DisAsm_R3_OE_RC(op, r0, r1, r2, false, rc);
}
@ -158,7 +158,7 @@ private:
{
DisAsm_R3_RC(op, r0, r1, r2, false);
}
void DisAsm_R2_INT3_RC(const std::string& op, u32 r0, u32 r1, s32 i0, s32 i1, s32 i2, bool rc)
void DisAsm_R2_INT3_RC(const std::string& op, u32 r0, u32 r1, s32 i0, s32 i1, s32 i2, u32 rc)
{
Write(fmt::Format("%s%s r%d,r%d,%d,%d,%d", FixOp(op).c_str(), (rc ? "." : ""), r0, r1, i0, i1, i2));
}
@ -166,7 +166,7 @@ private:
{
DisAsm_R2_INT3_RC(op, r0, r1, i0, i1, i2, false);
}
void DisAsm_R2_INT2_RC(const std::string& op, u32 r0, u32 r1, s32 i0, s32 i1, bool rc)
void DisAsm_R2_INT2_RC(const std::string& op, u32 r0, u32 r1, s32 i0, s32 i1, u32 rc)
{
Write(fmt::Format("%s%s r%d,r%d,%d,%d", FixOp(op).c_str(), (rc ? "." : ""), r0, r1, i0, i1));
}
@ -174,7 +174,7 @@ private:
{
DisAsm_R2_INT2_RC(op, r0, r1, i0, i1, false);
}
void DisAsm_R2_INT1_RC(const std::string& op, u32 r0, u32 r1, s32 i0, bool rc)
void DisAsm_R2_INT1_RC(const std::string& op, u32 r0, u32 r1, s32 i0, u32 rc)
{
Write(fmt::Format("%s%s r%d,r%d,%d", FixOp(op).c_str(), (rc ? "." : ""), r0, r1, i0));
}
@ -204,7 +204,7 @@ private:
{
Write(fmt::Format("%s cr%d,r%d,%d #%x", FixOp(op).c_str(), cr0, r0, imm0, imm0));
}
void DisAsm_CR1_R2_RC(const std::string& op, u32 cr0, u32 r0, u32 r1, bool rc)
void DisAsm_CR1_R2_RC(const std::string& op, u32 cr0, u32 r0, u32 r1, u32 rc)
{
Write(fmt::Format("%s%s cr%d,r%d,r%d", FixOp(op).c_str(), (rc ? "." : ""), cr0, r0, r1));
}
@ -1128,15 +1128,15 @@ private:
case 1: DisAsm_INT3("bcctrl", bo, bi, bh); break;
}
}
void RLWIMI(u32 ra, u32 rs, u32 sh, u32 mb, u32 me, bool rc)
void RLWIMI(u32 ra, u32 rs, u32 sh, u32 mb, u32 me, u32 rc)
{
DisAsm_R2_INT3_RC("rlwimi", ra, rs, sh, mb, me, rc);
}
void RLWINM(u32 ra, u32 rs, u32 sh, u32 mb, u32 me, bool rc)
void RLWINM(u32 ra, u32 rs, u32 sh, u32 mb, u32 me, u32 rc)
{
DisAsm_R2_INT3_RC("rlwinm", ra, rs, sh, mb, me, rc);
}
void RLWNM(u32 ra, u32 rs, u32 rb, u32 MB, u32 ME, bool rc)
void RLWNM(u32 ra, u32 rs, u32 rb, u32 MB, u32 ME, u32 rc)
{
DisAsm_R3_INT2_RC("rlwnm", ra, rs, rb, MB, ME, rc);
}
@ -1174,7 +1174,7 @@ private:
{
DisAsm_R2_IMM("andis.", ra, rs, uimm16);
}
void RLDICL(u32 ra, u32 rs, u32 sh, u32 mb, bool rc)
void RLDICL(u32 ra, u32 rs, u32 sh, u32 mb, u32 rc)
{
if(sh == 0)
{
@ -1193,19 +1193,19 @@ private:
DisAsm_R2_INT2_RC("rldicl", ra, rs, sh, mb, rc);
}
}
void RLDICR(u32 ra, u32 rs, u32 sh, u32 me, bool rc)
void RLDICR(u32 ra, u32 rs, u32 sh, u32 me, u32 rc)
{
DisAsm_R2_INT2_RC("rldicr", ra, rs, sh, me, rc);
}
void RLDIC(u32 ra, u32 rs, u32 sh, u32 mb, bool rc)
void RLDIC(u32 ra, u32 rs, u32 sh, u32 mb, u32 rc)
{
DisAsm_R2_INT2_RC("rldic", ra, rs, sh, mb, rc);
}
void RLDIMI(u32 ra, u32 rs, u32 sh, u32 mb, bool rc)
void RLDIMI(u32 ra, u32 rs, u32 sh, u32 mb, u32 rc)
{
DisAsm_R2_INT2_RC("rldimi", ra, rs, sh, mb, rc);
}
void RLDC_LR(u32 ra, u32 rs, u32 rb, u32 m_eb, bool is_r, bool rc)
void RLDC_LR(u32 ra, u32 rs, u32 rb, u32 m_eb, u32 is_r, u32 rc)
{
if (is_r)
DisAsm_R3_INT2_RC("rldcr", ra, rs, rb, m_eb, 0, rc);
@ -1228,19 +1228,19 @@ private:
{
DisAsm_V1_R2("lvebx", vd, ra, rb);
}
void SUBFC(u32 rd, u32 ra, u32 rb, u32 oe, bool rc)
void SUBFC(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc)
{
DisAsm_R3_OE_RC("subfc", rd, ra, rb, oe, rc);
}
void ADDC(u32 rd, u32 ra, u32 rb, u32 oe, bool rc)
void ADDC(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc)
{
DisAsm_R3_OE_RC("addc", rd, ra, rb, oe, rc);
}
void MULHDU(u32 rd, u32 ra, u32 rb, bool rc)
void MULHDU(u32 rd, u32 ra, u32 rb, u32 rc)
{
DisAsm_R3_RC("mulhdu", rd, ra, rb, rc);
}
void MULHWU(u32 rd, u32 ra, u32 rb, bool rc)
void MULHWU(u32 rd, u32 ra, u32 rb, u32 rc)
{
DisAsm_R3_RC("mulhwu", rd, ra, rb, rc);
}
@ -1267,19 +1267,19 @@ private:
{
DisAsm_R3("lwzx", rd, ra, rb);
}
void SLW(u32 ra, u32 rs, u32 rb, bool rc)
void SLW(u32 ra, u32 rs, u32 rb, u32 rc)
{
DisAsm_R3_RC("slw", ra, rs, rb, rc);
}
void CNTLZW(u32 ra, u32 rs, bool rc)
void CNTLZW(u32 ra, u32 rs, u32 rc)
{
DisAsm_R2_RC("cntlzw", ra, rs, rc);
}
void SLD(u32 ra, u32 rs, u32 rb, bool rc)
void SLD(u32 ra, u32 rs, u32 rb, u32 rc)
{
DisAsm_R3_RC("sld", ra, rs, rb, rc);
}
void AND(u32 ra, u32 rs, u32 rb, bool rc)
void AND(u32 ra, u32 rs, u32 rb, u32 rc)
{
DisAsm_R3_RC("and", ra, rs, rb, rc);
}
@ -1295,7 +1295,7 @@ private:
{
DisAsm_V1_R2("lvehx", vd, ra, rb);
}
void SUBF(u32 rd, u32 ra, u32 rb, u32 oe, bool rc)
void SUBF(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc)
{
DisAsm_R3_OE_RC("subf", rd, ra, rb, oe, rc);
}
@ -1311,11 +1311,11 @@ private:
{
DisAsm_R3("lwzux", rd, ra, rb);
}
void CNTLZD(u32 ra, u32 rs, bool rc)
void CNTLZD(u32 ra, u32 rs, u32 rc)
{
DisAsm_R2_RC("cntlzd", ra, rs, rc);
}
void ANDC(u32 ra, u32 rs, u32 rb, bool rc)
void ANDC(u32 ra, u32 rs, u32 rb, u32 rc)
{
DisAsm_R3_RC("andc", ra, rs, rb, rc);
}
@ -1327,11 +1327,11 @@ private:
{
DisAsm_V1_R2("lvewx", vd, ra, rb);
}
void MULHD(u32 rd, u32 ra, u32 rb, bool rc)
void MULHD(u32 rd, u32 ra, u32 rb, u32 rc)
{
DisAsm_R3_RC("mulhd", rd, ra, rb, rc);
}
void MULHW(u32 rd, u32 ra, u32 rb, bool rc)
void MULHW(u32 rd, u32 ra, u32 rb, u32 rc)
{
DisAsm_R3_RC("mulhw", rd, ra, rb, rc);
}
@ -1351,7 +1351,7 @@ private:
{
DisAsm_V1_R2("lvx", vd, ra, rb);
}
void NEG(u32 rd, u32 ra, u32 oe, bool rc)
void NEG(u32 rd, u32 ra, u32 oe, u32 rc)
{
DisAsm_R2_OE_RC("neg", rd, ra, oe, rc);
}
@ -1359,7 +1359,7 @@ private:
{
DisAsm_R3("lbzux", rd, ra, rb);
}
void NOR(u32 ra, u32 rs, u32 rb, bool rc)
void NOR(u32 ra, u32 rs, u32 rb, u32 rc)
{
if(rs == rb)
{
@ -1374,11 +1374,11 @@ private:
{
DisAsm_V1_R2("stvebx", vs, ra, rb);
}
void SUBFE(u32 rd, u32 ra, u32 rb, u32 oe, bool rc)
void SUBFE(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc)
{
DisAsm_R3_OE_RC("subfe", rd, ra, rb, oe, rc);
}
void ADDE(u32 rd, u32 ra, u32 rb, u32 oe, bool rc)
void ADDE(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc)
{
DisAsm_R3_OE_RC("adde", rd, ra, rb, oe, rc);
}
@ -1421,11 +1421,11 @@ private:
{
DisAsm_V1_R2("stvewx", vs, ra, rb);
}
void SUBFZE(u32 rd, u32 ra, u32 oe, bool rc)
void SUBFZE(u32 rd, u32 ra, u32 oe, u32 rc)
{
DisAsm_R2_OE_RC("subfze", rd, ra, oe, rc);
}
void ADDZE(u32 rd, u32 ra, u32 oe, bool rc)
void ADDZE(u32 rd, u32 ra, u32 oe, u32 rc)
{
DisAsm_R2_OE_RC("addze", rd, ra, oe, rc);
}
@ -1441,19 +1441,19 @@ private:
{
DisAsm_V1_R2("stvx", vd, ra, rb);
}
void SUBFME(u32 rd, u32 ra, u32 oe, bool rc)
void SUBFME(u32 rd, u32 ra, u32 oe, u32 rc)
{
DisAsm_R2_OE_RC("subfme", rd, ra, oe, rc);
}
void MULLD(u32 rd, u32 ra, u32 rb, u32 oe, bool rc)
void MULLD(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc)
{
DisAsm_R3_OE_RC("mulld", rd, ra, rb, oe, rc);
}
void ADDME(u32 rd, u32 ra, u32 oe, bool rc)
void ADDME(u32 rd, u32 ra, u32 oe, u32 rc)
{
DisAsm_R2_OE_RC("addme", rd, ra, oe, rc);
}
void MULLW(u32 rd, u32 ra, u32 rb, u32 oe, bool rc)
void MULLW(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc)
{
DisAsm_R3_OE_RC("mullw", rd, ra, rb, oe, rc);
}
@ -1465,7 +1465,7 @@ private:
{
DisAsm_R3("stbux", rs, ra, rb);
}
void ADD(u32 rd, u32 ra, u32 rb, u32 oe, bool rc)
void ADD(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc)
{
DisAsm_R3_OE_RC("add", rd, ra, rb, oe, rc);
}
@ -1477,7 +1477,7 @@ private:
{
DisAsm_R3("lhzx", rd, ra, rb);
}
void EQV(u32 ra, u32 rs, u32 rb, bool rc)
void EQV(u32 ra, u32 rs, u32 rb, u32 rc)
{
DisAsm_R3_RC("eqv", ra, rs, rb, rc);
}
@ -1489,7 +1489,7 @@ private:
{
DisAsm_R3("lhzux", rd, ra, rb);
}
void XOR(u32 ra, u32 rs, u32 rb, bool rc)
void XOR(u32 ra, u32 rs, u32 rb, u32 rc)
{
DisAsm_R3_RC("xor", ra, rs, rb, rc);
}
@ -1560,7 +1560,7 @@ private:
{
DisAsm_R3("sthx", rs, ra, rb);
}
void ORC(u32 ra, u32 rs, u32 rb, bool rc)
void ORC(u32 ra, u32 rs, u32 rb, u32 rc)
{
DisAsm_R3_RC("orc", ra, rs, rb, rc);
}
@ -1572,7 +1572,7 @@ private:
{
DisAsm_R3("sthux", rs, ra, rb);
}
void OR(u32 ra, u32 rs, u32 rb, bool rc)
void OR(u32 ra, u32 rs, u32 rb, u32 rc)
{
if(rs==rb)
{
@ -1583,11 +1583,11 @@ private:
DisAsm_R3_RC("or", ra, rs, rb, rc);
}
}
void DIVDU(u32 rd, u32 ra, u32 rb, u32 oe, bool rc)
void DIVDU(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc)
{
DisAsm_R3_OE_RC("divdu", rd, ra, rb, oe, rc);
}
void DIVWU(u32 rd, u32 ra, u32 rb, u32 oe, bool rc)
void DIVWU(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc)
{
DisAsm_R3_OE_RC("divwu", rd, ra, rb, oe, rc);
}
@ -1607,7 +1607,7 @@ private:
{
DisAsm_R2("dcbi", ra, rb);
}
void NAND(u32 ra, u32 rs, u32 rb, bool rc)
void NAND(u32 ra, u32 rs, u32 rb, u32 rc)
{
DisAsm_R3_RC("nand", ra, rs, rb, rc);
}
@ -1615,11 +1615,11 @@ private:
{
DisAsm_V1_R2("stvxl", vs, ra, rb);
}
void DIVD(u32 rd, u32 ra, u32 rb, u32 oe, bool rc)
void DIVD(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc)
{
DisAsm_R3_OE_RC("divd", rd, ra, rb, oe, rc);
}
void DIVW(u32 rd, u32 ra, u32 rb, u32 oe, bool rc)
void DIVW(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc)
{
DisAsm_R3_OE_RC("divw", rd, ra, rb, oe, rc);
}
@ -1643,11 +1643,11 @@ private:
{
DisAsm_F1_R2("lfsx", frd, ra, rb);
}
void SRW(u32 ra, u32 rs, u32 rb, bool rc)
void SRW(u32 ra, u32 rs, u32 rb, u32 rc)
{
DisAsm_R3_RC("srw", ra, rs, rb, rc);
}
void SRD(u32 ra, u32 rs, u32 rb, bool rc)
void SRD(u32 ra, u32 rs, u32 rb, u32 rc)
{
DisAsm_R3_RC("srd", ra, rs, rb, rc);
}
@ -1723,11 +1723,11 @@ private:
{
DisAsm_R3("lhbrx", rd, ra, rb);
}
void SRAW(u32 ra, u32 rs, u32 rb, bool rc)
void SRAW(u32 ra, u32 rs, u32 rb, u32 rc)
{
DisAsm_R3_RC("sraw", ra, rs, rb, rc);
}
void SRAD(u32 ra, u32 rs, u32 rb, bool rc)
void SRAD(u32 ra, u32 rs, u32 rb, u32 rc)
{
DisAsm_R3_RC("srad", ra, rs, rb, rc);
}
@ -1746,15 +1746,15 @@ private:
DisAsm_INT1("dss", strm);
}
}
void SRAWI(u32 ra, u32 rs, u32 sh, bool rc)
void SRAWI(u32 ra, u32 rs, u32 sh, u32 rc)
{
DisAsm_R2_INT1_RC("srawi", ra, rs, sh, rc);
}
void SRADI1(u32 ra, u32 rs, u32 sh, bool rc)
void SRADI1(u32 ra, u32 rs, u32 sh, u32 rc)
{
DisAsm_R2_INT1_RC("sradi", ra, rs, sh, rc);
}
void SRADI2(u32 ra, u32 rs, u32 sh, bool rc)
void SRADI2(u32 ra, u32 rs, u32 sh, u32 rc)
{
DisAsm_R2_INT1_RC("sradi", ra, rs, sh, rc);
}
@ -1770,7 +1770,7 @@ private:
{
DisAsm_R3("sthbrx", rs, ra, rb);
}
void EXTSH(u32 ra, u32 rs, bool rc)
void EXTSH(u32 ra, u32 rs, u32 rc)
{
DisAsm_R2_RC("extsh", ra, rs, rc);
}
@ -1778,7 +1778,7 @@ private:
{
DisAsm_V1_R2("stvrxl", sd, ra, rb);
}
void EXTSB(u32 ra, u32 rs, bool rc)
void EXTSB(u32 ra, u32 rs, u32 rc)
{
DisAsm_R2_RC("extsb", ra, rs, rc);
}
@ -1786,7 +1786,7 @@ private:
{
DisAsm_F1_R2("stfiwx", frs, ra, rb);
}
void EXTSW(u32 ra, u32 rs, bool rc)
void EXTSW(u32 ra, u32 rs, u32 rc)
{
DisAsm_R2_RC("extsw", ra, rs, rc);
}
@ -1906,43 +1906,43 @@ private:
{
DisAsm_R2_IMM("lwa", rd, ra, ds);
}
void FDIVS(u32 frd, u32 fra, u32 frb, bool rc)
void FDIVS(u32 frd, u32 fra, u32 frb, u32 rc)
{
DisAsm_F3_RC("fdivs", frd, fra, frb, rc);
}
void FSUBS(u32 frd, u32 fra, u32 frb, bool rc)
void FSUBS(u32 frd, u32 fra, u32 frb, u32 rc)
{
DisAsm_F3_RC("fsubs", frd, fra, frb, rc);
}
void FADDS(u32 frd, u32 fra, u32 frb, bool rc)
void FADDS(u32 frd, u32 fra, u32 frb, u32 rc)
{
DisAsm_F3_RC("fadds", frd, fra, frb, rc);
}
void FSQRTS(u32 frd, u32 frb, bool rc)
void FSQRTS(u32 frd, u32 frb, u32 rc)
{
DisAsm_F2_RC("fsqrts", frd, frb, rc);
}
void FRES(u32 frd, u32 frb, bool rc)
void FRES(u32 frd, u32 frb, u32 rc)
{
DisAsm_F2_RC("fres", frd, frb, rc);
}
void FMULS(u32 frd, u32 fra, u32 frc, bool rc)
void FMULS(u32 frd, u32 fra, u32 frc, u32 rc)
{
DisAsm_F3_RC("fmuls", frd, fra, frc, rc);
}
void FMADDS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc)
void FMADDS(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc)
{
DisAsm_F4_RC("fmadds", frd, fra, frc, frb, rc);
}
void FMSUBS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc)
void FMSUBS(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc)
{
DisAsm_F4_RC("fmsubs", frd, fra, frc, frb, rc);
}
void FNMSUBS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc)
void FNMSUBS(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc)
{
DisAsm_F4_RC("fnmsubs", frd, fra, frc, frb, rc);
}
void FNMADDS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc)
void FNMADDS(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc)
{
DisAsm_F4_RC("fnmadds", frd, fra, frc, frb, rc);
}
@ -1954,7 +1954,7 @@ private:
{
DisAsm_R2_IMM("stdu", rs, ra, ds);
}
void MTFSB1(u32 bt, bool rc)
void MTFSB1(u32 bt, u32 rc)
{
DisAsm_F1_RC("mtfsb1", bt, rc);
}
@ -1962,19 +1962,19 @@ private:
{
DisAsm_F2("mcrfs", bf, bfa);
}
void MTFSB0(u32 bt, bool rc)
void MTFSB0(u32 bt, u32 rc)
{
DisAsm_F1_RC("mtfsb0", bt, rc);
}
void MTFSFI(u32 crfd, u32 i, bool rc)
void MTFSFI(u32 crfd, u32 i, u32 rc)
{
DisAsm_F2_RC("mtfsfi", crfd, i, rc);
}
void MFFS(u32 frd, bool rc)
void MFFS(u32 frd, u32 rc)
{
DisAsm_F1_RC("mffs", frd, rc);
}
void MTFSF(u32 flm, u32 frb, bool rc)
void MTFSF(u32 flm, u32 frb, u32 rc)
{
DisAsm_F2_RC("mtfsf", flm, frb, rc);
}
@ -1982,59 +1982,59 @@ private:
{
DisAsm_CR1_F2("fcmpu", crfd, fra, frb);
}
void FRSP(u32 frd, u32 frb, bool rc)
void FRSP(u32 frd, u32 frb, u32 rc)
{
DisAsm_F2_RC("frsp", frd, frb, rc);
}
void FCTIW(u32 frd, u32 frb, bool rc)
void FCTIW(u32 frd, u32 frb, u32 rc)
{
DisAsm_F2_RC("fctiw", frd, frb, rc);
}
void FCTIWZ(u32 frd, u32 frb, bool rc)
void FCTIWZ(u32 frd, u32 frb, u32 rc)
{
DisAsm_F2_RC("fctiwz", frd, frb, rc);
}
void FDIV(u32 frd, u32 fra, u32 frb, bool rc)
void FDIV(u32 frd, u32 fra, u32 frb, u32 rc)
{
DisAsm_F3_RC("fdiv", frd, fra, frb, rc);
}
void FSUB(u32 frd, u32 fra, u32 frb, bool rc)
void FSUB(u32 frd, u32 fra, u32 frb, u32 rc)
{
DisAsm_F3_RC("fsub", frd, fra, frb, rc);
}
void FADD(u32 frd, u32 fra, u32 frb, bool rc)
void FADD(u32 frd, u32 fra, u32 frb, u32 rc)
{
DisAsm_F3_RC("fadd", frd, fra, frb, rc);
}
void FSQRT(u32 frd, u32 frb, bool rc)
void FSQRT(u32 frd, u32 frb, u32 rc)
{
DisAsm_F2_RC("fsqrt", frd, frb, rc);
}
void FSEL(u32 frd, u32 fra, u32 frc, u32 frb, bool rc)
void FSEL(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc)
{
DisAsm_F4_RC("fsel", frd, fra, frc, frb, rc);
}
void FMUL(u32 frd, u32 fra, u32 frc, bool rc)
void FMUL(u32 frd, u32 fra, u32 frc, u32 rc)
{
DisAsm_F3_RC("fmul", frd, fra, frc, rc);
}
void FRSQRTE(u32 frd, u32 frb, bool rc)
void FRSQRTE(u32 frd, u32 frb, u32 rc)
{
DisAsm_F2_RC("frsqrte", frd, frb, rc);
}
void FMSUB(u32 frd, u32 fra, u32 frc, u32 frb, bool rc)
void FMSUB(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc)
{
DisAsm_F4_RC("fmsub", frd, fra, frc, frb, rc);
}
void FMADD(u32 frd, u32 fra, u32 frc, u32 frb, bool rc)
void FMADD(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc)
{
DisAsm_F4_RC("fmadd", frd, fra, frc, frb, rc);
}
void FNMSUB(u32 frd, u32 fra, u32 frc, u32 frb, bool rc)
void FNMSUB(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc)
{
DisAsm_F4_RC("fnmsub", frd, fra, frc, frb, rc);
}
void FNMADD(u32 frd, u32 fra, u32 frc, u32 frb, bool rc)
void FNMADD(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc)
{
DisAsm_F4_RC("fnmadd", frd, fra, frc, frb, rc);
}
@ -2042,31 +2042,31 @@ private:
{
DisAsm_F3("fcmpo", crfd, fra, frb);
}
void FNEG(u32 frd, u32 frb, bool rc)
void FNEG(u32 frd, u32 frb, u32 rc)
{
DisAsm_F2_RC("fneg", frd, frb, rc);
}
void FMR(u32 frd, u32 frb, bool rc)
void FMR(u32 frd, u32 frb, u32 rc)
{
DisAsm_F2_RC("fmr", frd, frb, rc);
}
void FNABS(u32 frd, u32 frb, bool rc)
void FNABS(u32 frd, u32 frb, u32 rc)
{
DisAsm_F2_RC("fnabs", frd, frb, rc);
}
void FABS(u32 frd, u32 frb, bool rc)
void FABS(u32 frd, u32 frb, u32 rc)
{
DisAsm_F2_RC("fabs", frd, frb, rc);
}
void FCTID(u32 frd, u32 frb, bool rc)
void FCTID(u32 frd, u32 frb, u32 rc)
{
DisAsm_F2_RC("fctid", frd, frb, rc);
}
void FCTIDZ(u32 frd, u32 frb, bool rc)
void FCTIDZ(u32 frd, u32 frb, u32 rc)
{
DisAsm_F2_RC("fctidz", frd, frb, rc);
}
void FCFID(u32 frd, u32 frb, bool rc)
void FCFID(u32 frd, u32 frb, u32 rc)
{
DisAsm_F2_RC("fcfid", frd, frb, rc);
}

View File

@ -466,7 +466,7 @@ private:
CPU.VPR[vd]._f[w] = ((float)CPU.VPR[vb]._u32[w]) / scale;
}
}
void VCMPBFP(u32 vd, u32 va, u32 vb, bool rc)
void VCMPBFP(u32 vd, u32 va, u32 vb, u32 rc)
{
bool allInBounds = true;
@ -495,7 +495,7 @@ private:
}
void VCMPBFP(u32 vd, u32 va, u32 vb) {VCMPBFP(vd, va, vb, false);}
void VCMPBFP_(u32 vd, u32 va, u32 vb) {VCMPBFP(vd, va, vb, true);}
void VCMPEQFP(u32 vd, u32 va, u32 vb, bool rc)
void VCMPEQFP(u32 vd, u32 va, u32 vb, u32 rc)
{
int all_equal = 0x8;
int none_equal = 0x2;
@ -518,7 +518,7 @@ private:
}
void VCMPEQFP(u32 vd, u32 va, u32 vb) {VCMPEQFP(vd, va, vb, false);}
void VCMPEQFP_(u32 vd, u32 va, u32 vb) {VCMPEQFP(vd, va, vb, true);}
void VCMPEQUB(u32 vd, u32 va, u32 vb, bool rc)
void VCMPEQUB(u32 vd, u32 va, u32 vb, u32 rc)
{
int all_equal = 0x8;
int none_equal = 0x2;
@ -541,7 +541,7 @@ private:
}
void VCMPEQUB(u32 vd, u32 va, u32 vb) {VCMPEQUB(vd, va, vb, false);}
void VCMPEQUB_(u32 vd, u32 va, u32 vb) {VCMPEQUB(vd, va, vb, true);}
void VCMPEQUH(u32 vd, u32 va, u32 vb, bool rc) //nf
void VCMPEQUH(u32 vd, u32 va, u32 vb, u32 rc) //nf
{
int all_equal = 0x8;
int none_equal = 0x2;
@ -564,7 +564,7 @@ private:
}
void VCMPEQUH(u32 vd, u32 va, u32 vb) {VCMPEQUH(vd, va, vb, false);}
void VCMPEQUH_(u32 vd, u32 va, u32 vb) {VCMPEQUH(vd, va, vb, true);}
void VCMPEQUW(u32 vd, u32 va, u32 vb, bool rc)
void VCMPEQUW(u32 vd, u32 va, u32 vb, u32 rc)
{
int all_equal = 0x8;
int none_equal = 0x2;
@ -587,7 +587,7 @@ private:
}
void VCMPEQUW(u32 vd, u32 va, u32 vb) {VCMPEQUW(vd, va, vb, false);}
void VCMPEQUW_(u32 vd, u32 va, u32 vb) {VCMPEQUW(vd, va, vb, true);}
void VCMPGEFP(u32 vd, u32 va, u32 vb, bool rc)
void VCMPGEFP(u32 vd, u32 va, u32 vb, u32 rc)
{
int all_ge = 0x8;
int none_ge = 0x2;
@ -610,7 +610,7 @@ private:
}
void VCMPGEFP(u32 vd, u32 va, u32 vb) {VCMPGEFP(vd, va, vb, false);}
void VCMPGEFP_(u32 vd, u32 va, u32 vb) {VCMPGEFP(vd, va, vb, true);}
void VCMPGTFP(u32 vd, u32 va, u32 vb, bool rc)
void VCMPGTFP(u32 vd, u32 va, u32 vb, u32 rc)
{
int all_ge = 0x8;
int none_ge = 0x2;
@ -633,7 +633,7 @@ private:
}
void VCMPGTFP(u32 vd, u32 va, u32 vb) {VCMPGTFP(vd, va, vb, false);}
void VCMPGTFP_(u32 vd, u32 va, u32 vb) {VCMPGTFP(vd, va, vb, true);}
void VCMPGTSB(u32 vd, u32 va, u32 vb, bool rc) //nf
void VCMPGTSB(u32 vd, u32 va, u32 vb, u32 rc) //nf
{
int all_gt = 0x8;
int none_gt = 0x2;
@ -656,7 +656,7 @@ private:
}
void VCMPGTSB(u32 vd, u32 va, u32 vb) {VCMPGTSB(vd, va, vb, false);}
void VCMPGTSB_(u32 vd, u32 va, u32 vb) {VCMPGTSB(vd, va, vb, true);}
void VCMPGTSH(u32 vd, u32 va, u32 vb, bool rc)
void VCMPGTSH(u32 vd, u32 va, u32 vb, u32 rc)
{
int all_gt = 0x8;
int none_gt = 0x2;
@ -679,7 +679,7 @@ private:
}
void VCMPGTSH(u32 vd, u32 va, u32 vb) {VCMPGTSH(vd, va, vb, false);}
void VCMPGTSH_(u32 vd, u32 va, u32 vb) {VCMPGTSH(vd, va, vb, true);}
void VCMPGTSW(u32 vd, u32 va, u32 vb, bool rc)
void VCMPGTSW(u32 vd, u32 va, u32 vb, u32 rc)
{
int all_gt = 0x8;
int none_gt = 0x2;
@ -702,7 +702,7 @@ private:
}
void VCMPGTSW(u32 vd, u32 va, u32 vb) {VCMPGTSW(vd, va, vb, false);}
void VCMPGTSW_(u32 vd, u32 va, u32 vb) {VCMPGTSW(vd, va, vb, true);}
void VCMPGTUB(u32 vd, u32 va, u32 vb, bool rc)
void VCMPGTUB(u32 vd, u32 va, u32 vb, u32 rc)
{
int all_gt = 0x8;
int none_gt = 0x2;
@ -725,7 +725,7 @@ private:
}
void VCMPGTUB(u32 vd, u32 va, u32 vb) {VCMPGTUB(vd, va, vb, false);}
void VCMPGTUB_(u32 vd, u32 va, u32 vb) {VCMPGTUB(vd, va, vb, true);}
void VCMPGTUH(u32 vd, u32 va, u32 vb, bool rc)
void VCMPGTUH(u32 vd, u32 va, u32 vb, u32 rc)
{
int all_gt = 0x8;
int none_gt = 0x2;
@ -748,7 +748,7 @@ private:
}
void VCMPGTUH(u32 vd, u32 va, u32 vb) {VCMPGTUH(vd, va, vb, false);}
void VCMPGTUH_(u32 vd, u32 va, u32 vb) {VCMPGTUH(vd, va, vb, true);}
void VCMPGTUW(u32 vd, u32 va, u32 vb, bool rc)
void VCMPGTUW(u32 vd, u32 va, u32 vb, u32 rc)
{
int all_gt = 0x8;
int none_gt = 0x2;
@ -2316,18 +2316,18 @@ private:
if(lk) CPU.LR = nextLR;
}
}
void RLWIMI(u32 ra, u32 rs, u32 sh, u32 mb, u32 me, bool rc)
void RLWIMI(u32 ra, u32 rs, u32 sh, u32 mb, u32 me, u32 rc)
{
const u64 mask = rotate_mask[32 + mb][32 + me];
CPU.GPR[ra] = (CPU.GPR[ra] & ~mask) | (rotl32(CPU.GPR[rs], sh) & mask);
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[ra]);
}
void RLWINM(u32 ra, u32 rs, u32 sh, u32 mb, u32 me, bool rc)
void RLWINM(u32 ra, u32 rs, u32 sh, u32 mb, u32 me, u32 rc)
{
CPU.GPR[ra] = rotl32(CPU.GPR[rs], sh) & rotate_mask[32 + mb][32 + me];
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[ra]);
}
void RLWNM(u32 ra, u32 rs, u32 rb, u32 mb, u32 me, bool rc)
void RLWNM(u32 ra, u32 rs, u32 rb, u32 mb, u32 me, u32 rc)
{
CPU.GPR[ra] = rotl32(CPU.GPR[rs], CPU.GPR[rb] & 0x1f) & rotate_mask[32 + mb][32 + me];
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[ra]);
@ -2358,28 +2358,28 @@ private:
CPU.GPR[ra] = CPU.GPR[rs] & ((u64)uimm16 << 16);
CPU.UpdateCR0<s64>(CPU.GPR[ra]);
}
void RLDICL(u32 ra, u32 rs, u32 sh, u32 mb, bool rc)
void RLDICL(u32 ra, u32 rs, u32 sh, u32 mb, u32 rc)
{
CPU.GPR[ra] = rotl64(CPU.GPR[rs], sh) & rotate_mask[mb][63];
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[ra]);
}
void RLDICR(u32 ra, u32 rs, u32 sh, u32 me, bool rc)
void RLDICR(u32 ra, u32 rs, u32 sh, u32 me, u32 rc)
{
CPU.GPR[ra] = rotl64(CPU.GPR[rs], sh) & rotate_mask[0][me];
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[ra]);
}
void RLDIC(u32 ra, u32 rs, u32 sh, u32 mb, bool rc)
void RLDIC(u32 ra, u32 rs, u32 sh, u32 mb, u32 rc)
{
CPU.GPR[ra] = rotl64(CPU.GPR[rs], sh) & rotate_mask[mb][63-sh];
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[ra]);
}
void RLDIMI(u32 ra, u32 rs, u32 sh, u32 mb, bool rc)
void RLDIMI(u32 ra, u32 rs, u32 sh, u32 mb, u32 rc)
{
const u64 mask = rotate_mask[mb][63-sh];
CPU.GPR[ra] = (CPU.GPR[ra] & ~mask) | (rotl64(CPU.GPR[rs], sh) & mask);
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[ra]);
}
void RLDC_LR(u32 ra, u32 rs, u32 rb, u32 m_eb, bool is_r, bool rc)
void RLDC_LR(u32 ra, u32 rs, u32 rb, u32 m_eb, u32 is_r, u32 rc)
{
if (is_r) // rldcr
{
@ -2441,7 +2441,7 @@ private:
CPU.VPR[vd]._u8[15 - (addr & 0xf)] = vm::read8(VM_CAST(addr));
// check LVEWX comments
}
void SUBFC(u32 rd, u32 ra, u32 rb, u32 oe, bool rc)
void SUBFC(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc)
{
const u64 RA = CPU.GPR[ra];
const u64 RB = CPU.GPR[rb];
@ -2450,12 +2450,12 @@ private:
if(oe) CPU.SetOV((~RA>>63 == RB>>63) && (~RA>>63 != CPU.GPR[rd]>>63));
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[rd]);
}
void MULHDU(u32 rd, u32 ra, u32 rb, bool rc)
void MULHDU(u32 rd, u32 ra, u32 rb, u32 rc)
{
CPU.GPR[rd] = __umulh(CPU.GPR[ra], CPU.GPR[rb]);
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[rd]);
}
void ADDC(u32 rd, u32 ra, u32 rb, u32 oe, bool rc)
void ADDC(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc)
{
const u64 RA = CPU.GPR[ra];
const u64 RB = CPU.GPR[rb];
@ -2464,7 +2464,7 @@ private:
if(oe) CPU.SetOV((RA>>63 == RB>>63) && (RA>>63 != CPU.GPR[rd]>>63));
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[rd]);
}
void MULHWU(u32 rd, u32 ra, u32 rb, bool rc)
void MULHWU(u32 rd, u32 ra, u32 rb, u32 rc)
{
u32 a = (u32)CPU.GPR[ra];
u32 b = (u32)CPU.GPR[rb];
@ -2494,7 +2494,7 @@ private:
const u64 addr = ra ? CPU.GPR[ra] + CPU.GPR[rb] : CPU.GPR[rb];
CPU.GPR[rd] = vm::read32(VM_CAST(addr));
}
void SLW(u32 ra, u32 rs, u32 rb, bool rc)
void SLW(u32 ra, u32 rs, u32 rb, u32 rc)
{
u32 n = CPU.GPR[rb] & 0x1f;
u32 r = (u32)rotl32((u32)CPU.GPR[rs], n);
@ -2504,7 +2504,7 @@ private:
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[ra]);
}
void CNTLZW(u32 ra, u32 rs, bool rc)
void CNTLZW(u32 ra, u32 rs, u32 rc)
{
u32 i;
for(i=0; i < 32; i++)
@ -2515,7 +2515,7 @@ private:
CPU.GPR[ra] = i;
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[ra]);
}
void SLD(u32 ra, u32 rs, u32 rb, bool rc)
void SLD(u32 ra, u32 rs, u32 rb, u32 rc)
{
u32 n = CPU.GPR[rb] & 0x3f;
u64 r = rotl64(CPU.GPR[rs], n);
@ -2525,7 +2525,7 @@ private:
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[ra]);
}
void AND(u32 ra, u32 rs, u32 rb, bool rc)
void AND(u32 ra, u32 rs, u32 rb, u32 rc)
{
CPU.GPR[ra] = CPU.GPR[rs] & CPU.GPR[rb];
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[ra]);
@ -2567,7 +2567,7 @@ private:
CPU.VPR[vd]._u16[7 - ((addr >> 1) & 0x7)] = vm::read16(VM_CAST(addr));
// check LVEWX comments
}
void SUBF(u32 rd, u32 ra, u32 rb, u32 oe, bool rc)
void SUBF(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc)
{
const u64 RA = CPU.GPR[ra];
const u64 RB = CPU.GPR[rb];
@ -2590,7 +2590,7 @@ private:
CPU.GPR[rd] = vm::read32(VM_CAST(addr));
CPU.GPR[ra] = addr;
}
void CNTLZD(u32 ra, u32 rs, bool rc)
void CNTLZD(u32 ra, u32 rs, u32 rc)
{
u32 i;
for(i=0; i < 64; i++)
@ -2601,7 +2601,7 @@ private:
CPU.GPR[ra] = i;
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[ra]);
}
void ANDC(u32 ra, u32 rs, u32 rb, bool rc)
void ANDC(u32 ra, u32 rs, u32 rb, u32 rc)
{
CPU.GPR[ra] = CPU.GPR[rs] & ~CPU.GPR[rb];
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[ra]);
@ -2618,12 +2618,12 @@ private:
// because it can theoretically read RawSPU 32-bit MMIO register (read128() will fail)
//CPU.VPR[vd] = vm::read128((ra ? CPU.GPR[ra] + CPU.GPR[rb] : CPU.GPR[rb]) & ~0xfULL);
}
void MULHD(u32 rd, u32 ra, u32 rb, bool rc)
void MULHD(u32 rd, u32 ra, u32 rb, u32 rc)
{
CPU.GPR[rd] = __mulh(CPU.GPR[ra], CPU.GPR[rb]);
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[rd]);
}
void MULHW(u32 rd, u32 ra, u32 rb, bool rc)
void MULHW(u32 rd, u32 ra, u32 rb, u32 rc)
{
s32 a = (s32)CPU.GPR[ra];
s32 b = (s32)CPU.GPR[rb];
@ -2652,7 +2652,7 @@ private:
const u64 addr = (ra ? CPU.GPR[ra] + CPU.GPR[rb] : CPU.GPR[rb]) & ~0xfull;
CPU.VPR[vd] = vm::read128(VM_CAST(addr));
}
void NEG(u32 rd, u32 ra, u32 oe, bool rc)
void NEG(u32 rd, u32 ra, u32 oe, u32 rc)
{
const u64 RA = CPU.GPR[ra];
CPU.GPR[rd] = 0 - RA;
@ -2665,7 +2665,7 @@ private:
CPU.GPR[rd] = vm::read8(VM_CAST(addr));
CPU.GPR[ra] = addr;
}
void NOR(u32 ra, u32 rs, u32 rb, bool rc)
void NOR(u32 ra, u32 rs, u32 rb, u32 rc)
{
CPU.GPR[ra] = ~(CPU.GPR[rs] | CPU.GPR[rb]);
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[ra]);
@ -2676,7 +2676,7 @@ private:
const u8 eb = addr & 0xf;
vm::write8(VM_CAST(addr), CPU.VPR[vs]._u8[15 - eb]);
}
void SUBFE(u32 rd, u32 ra, u32 rb, u32 oe, bool rc)
void SUBFE(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc)
{
const u64 RA = CPU.GPR[ra];
const u64 RB = CPU.GPR[rb];
@ -2685,7 +2685,7 @@ private:
if(oe) CPU.SetOV((~RA>>63 == RB>>63) && (~RA>>63 != CPU.GPR[rd]>>63));
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[rd]);
}
void ADDE(u32 rd, u32 ra, u32 rb, u32 oe, bool rc)
void ADDE(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc)
{
const u64 RA = CPU.GPR[ra];
const u64 RB = CPU.GPR[rb];
@ -2784,7 +2784,7 @@ private:
const u8 eb = (addr & 0xf) >> 2;
vm::write32(VM_CAST(addr), CPU.VPR[vs]._u32[3 - eb]);
}
void SUBFZE(u32 rd, u32 ra, u32 oe, bool rc)
void SUBFZE(u32 rd, u32 ra, u32 oe, u32 rc)
{
const u64 RA = CPU.GPR[ra];
CPU.GPR[rd] = ~RA + CPU.XER.CA;
@ -2792,7 +2792,7 @@ private:
if(oe) CPU.SetOV((~RA>>63 == 0) && (~RA>>63 != CPU.GPR[rd]>>63));
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[rd]);
}
void ADDZE(u32 rd, u32 ra, u32 oe, bool rc)
void ADDZE(u32 rd, u32 ra, u32 oe, u32 rc)
{
const u64 RA = CPU.GPR[ra];
CPU.GPR[rd] = RA + CPU.XER.CA;
@ -2817,7 +2817,7 @@ private:
const u64 addr = (ra ? CPU.GPR[ra] + CPU.GPR[rb] : CPU.GPR[rb]) & ~0xfull;
vm::write128(VM_CAST(addr), CPU.VPR[vs]);
}
void MULLD(u32 rd, u32 ra, u32 rb, u32 oe, bool rc)
void MULLD(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc)
{
const s64 RA = CPU.GPR[ra];
const s64 RB = CPU.GPR[rb];
@ -2829,7 +2829,7 @@ private:
}
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[rd]);
}
void SUBFME(u32 rd, u32 ra, u32 oe, bool rc)
void SUBFME(u32 rd, u32 ra, u32 oe, u32 rc)
{
const u64 RA = CPU.GPR[ra];
CPU.GPR[rd] = ~RA + CPU.XER.CA + ~0ULL;
@ -2837,7 +2837,7 @@ private:
if(oe) CPU.SetOV((~RA>>63 == 1) && (~RA>>63 != CPU.GPR[rd]>>63));
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[rd]);
}
void ADDME(u32 rd, u32 ra, u32 oe, bool rc)
void ADDME(u32 rd, u32 ra, u32 oe, u32 rc)
{
const s64 RA = CPU.GPR[ra];
CPU.GPR[rd] = RA + CPU.XER.CA - 1;
@ -2846,7 +2846,7 @@ private:
if(oe) CPU.SetOV((u64(RA)>>63 == 1) && (u64(RA)>>63 != CPU.GPR[rd]>>63));
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[rd]);
}
void MULLW(u32 rd, u32 ra, u32 rb, u32 oe, bool rc)
void MULLW(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc)
{
CPU.GPR[rd] = (s64)((s64)(s32)CPU.GPR[ra] * (s64)(s32)CPU.GPR[rb]);
if(oe) CPU.SetOV(s64(CPU.GPR[rd]) < s64(-1)<<31 || s64(CPU.GPR[rd]) >= s64(1)<<31);
@ -2861,7 +2861,7 @@ private:
vm::write8(VM_CAST(addr), (u8)CPU.GPR[rs]);
CPU.GPR[ra] = addr;
}
void ADD(u32 rd, u32 ra, u32 rb, u32 oe, bool rc)
void ADD(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc)
{
const u64 RA = CPU.GPR[ra];
const u64 RB = CPU.GPR[rb];
@ -2877,7 +2877,7 @@ private:
const u64 addr = ra ? CPU.GPR[ra] + CPU.GPR[rb] : CPU.GPR[rb];
CPU.GPR[rd] = vm::read16(VM_CAST(addr));
}
void EQV(u32 ra, u32 rs, u32 rb, bool rc)
void EQV(u32 ra, u32 rs, u32 rb, u32 rc)
{
CPU.GPR[ra] = ~(CPU.GPR[rs] ^ CPU.GPR[rb]);
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[ra]);
@ -2892,7 +2892,7 @@ private:
CPU.GPR[rd] = vm::read16(VM_CAST(addr));
CPU.GPR[ra] = addr;
}
void XOR(u32 ra, u32 rs, u32 rb, bool rc)
void XOR(u32 ra, u32 rs, u32 rb, u32 rc)
{
CPU.GPR[ra] = CPU.GPR[rs] ^ CPU.GPR[rb];
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[ra]);
@ -2951,7 +2951,7 @@ private:
const u64 addr = ra ? CPU.GPR[ra] + CPU.GPR[rb] : CPU.GPR[rb];
vm::write16(VM_CAST(addr), (u16)CPU.GPR[rs]);
}
void ORC(u32 ra, u32 rs, u32 rb, bool rc)
void ORC(u32 ra, u32 rs, u32 rb, u32 rc)
{
CPU.GPR[ra] = CPU.GPR[rs] | ~CPU.GPR[rb];
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[ra]);
@ -2966,12 +2966,12 @@ private:
vm::write16(VM_CAST(addr), (u16)CPU.GPR[rs]);
CPU.GPR[ra] = addr;
}
void OR(u32 ra, u32 rs, u32 rb, bool rc)
void OR(u32 ra, u32 rs, u32 rb, u32 rc)
{
CPU.GPR[ra] = CPU.GPR[rs] | CPU.GPR[rb];
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[ra]);
}
void DIVDU(u32 rd, u32 ra, u32 rb, u32 oe, bool rc)
void DIVDU(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc)
{
const u64 RA = CPU.GPR[ra];
const u64 RB = CPU.GPR[rb];
@ -2989,7 +2989,7 @@ private:
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[rd]);
}
void DIVWU(u32 rd, u32 ra, u32 rb, u32 oe, bool rc)
void DIVWU(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc)
{
const u32 RA = (u32)CPU.GPR[ra];
const u32 RB = (u32)CPU.GPR[rb];
@ -3014,7 +3014,7 @@ private:
void DCBI(u32 ra, u32 rb)
{
}
void NAND(u32 ra, u32 rs, u32 rb, bool rc)
void NAND(u32 ra, u32 rs, u32 rb, u32 rc)
{
CPU.GPR[ra] = ~(CPU.GPR[rs] & CPU.GPR[rb]);
@ -3025,7 +3025,7 @@ private:
const u64 addr = (ra ? CPU.GPR[ra] + CPU.GPR[rb] : CPU.GPR[rb]) & ~0xfull;
vm::write128(VM_CAST(addr), CPU.VPR[vs]);
}
void DIVD(u32 rd, u32 ra, u32 rb, u32 oe, bool rc)
void DIVD(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc)
{
const s64 RA = CPU.GPR[ra];
const s64 RB = CPU.GPR[rb];
@ -3043,7 +3043,7 @@ private:
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[rd]);
}
void DIVW(u32 rd, u32 ra, u32 rb, u32 oe, bool rc)
void DIVW(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc)
{
const s32 RA = (s32)CPU.GPR[ra];
const s32 RB = (s32)CPU.GPR[rb];
@ -3112,7 +3112,7 @@ private:
(u64&)CPU.FPR[frd] = (bits & 0x80000000) << 32 | 7ULL << 60 | (bits & 0x7fffffff) << 29;
}
}
void SRW(u32 ra, u32 rs, u32 rb, bool rc)
void SRW(u32 ra, u32 rs, u32 rb, u32 rc)
{
u32 n = CPU.GPR[rb] & 0x1f;
u32 r = (u32)rotl32((u32)CPU.GPR[rs], 64 - n);
@ -3121,7 +3121,7 @@ private:
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[ra]);
}
void SRD(u32 ra, u32 rs, u32 rb, bool rc)
void SRD(u32 ra, u32 rs, u32 rb, u32 rc)
{
u32 n = CPU.GPR[rb] & 0x3f;
u64 r = rotl64(CPU.GPR[rs], 64 - n);
@ -3323,7 +3323,7 @@ private:
const u64 addr = ra ? CPU.GPR[ra] + CPU.GPR[rb] : CPU.GPR[rb];
CPU.GPR[rd] = vm::get_ref<u16>(VM_CAST(addr));
}
void SRAW(u32 ra, u32 rs, u32 rb, bool rc)
void SRAW(u32 ra, u32 rs, u32 rb, u32 rc)
{
s32 RS = (s32)CPU.GPR[rs];
u8 shift = CPU.GPR[rb] & 63;
@ -3340,7 +3340,7 @@ private:
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[ra]);
}
void SRAD(u32 ra, u32 rs, u32 rb, bool rc)
void SRAD(u32 ra, u32 rs, u32 rb, u32 rc)
{
s64 RS = CPU.GPR[rs];
u8 shift = CPU.GPR[rb] & 127;
@ -3368,7 +3368,7 @@ private:
void DSS(u32 strm, u32 a)
{
}
void SRAWI(u32 ra, u32 rs, u32 sh, bool rc)
void SRAWI(u32 ra, u32 rs, u32 sh, u32 rc)
{
s32 RS = (u32)CPU.GPR[rs];
CPU.GPR[ra] = RS >> sh;
@ -3376,7 +3376,7 @@ private:
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[ra]);
}
void SRADI1(u32 ra, u32 rs, u32 sh, bool rc)
void SRADI1(u32 ra, u32 rs, u32 sh, u32 rc)
{
s64 RS = CPU.GPR[rs];
CPU.GPR[ra] = RS >> sh;
@ -3384,7 +3384,7 @@ private:
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[ra]);
}
void SRADI2(u32 ra, u32 rs, u32 sh, bool rc)
void SRADI2(u32 ra, u32 rs, u32 sh, u32 rc)
{
SRADI1(ra, rs, sh, rc);
}
@ -3404,7 +3404,7 @@ private:
const u64 addr = ra ? CPU.GPR[ra] + CPU.GPR[rb] : CPU.GPR[rb];
vm::get_ref<u16>(VM_CAST(addr)) = (u16)CPU.GPR[rs];
}
void EXTSH(u32 ra, u32 rs, bool rc)
void EXTSH(u32 ra, u32 rs, u32 rc)
{
CPU.GPR[ra] = (s64)(s16)CPU.GPR[rs];
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[ra]);
@ -3416,7 +3416,7 @@ private:
for (u32 i = 16 - eb; i < 16; ++i) vm::write8(VM_CAST(addr + i - 16), CPU.VPR[vs]._u8[15 - i]);
}
void EXTSB(u32 ra, u32 rs, bool rc)
void EXTSB(u32 ra, u32 rs, u32 rc)
{
CPU.GPR[ra] = (s64)(s8)CPU.GPR[rs];
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[ra]);
@ -3426,7 +3426,7 @@ private:
const u64 addr = ra ? CPU.GPR[ra] + CPU.GPR[rb] : CPU.GPR[rb];
vm::write32(VM_CAST(addr), (u32&)CPU.FPR[frs]);
}
void EXTSW(u32 ra, u32 rs, bool rc)
void EXTSW(u32 ra, u32 rs, u32 rc)
{
CPU.GPR[ra] = (s64)(s32)CPU.GPR[rs];
if(rc) CPU.UpdateCR0<s64>(CPU.GPR[ra]);
@ -3632,11 +3632,11 @@ private:
const u64 addr = ra ? CPU.GPR[ra] + ds : ds;
CPU.GPR[rd] = (s64)(s32)vm::read32(VM_CAST(addr));
}
void FDIVS(u32 frd, u32 fra, u32 frb, bool rc) {FDIV(frd, fra, frb, rc, true);}
void FSUBS(u32 frd, u32 fra, u32 frb, bool rc) {FSUB(frd, fra, frb, rc, true);}
void FADDS(u32 frd, u32 fra, u32 frb, bool rc) {FADD(frd, fra, frb, rc, true);}
void FSQRTS(u32 frd, u32 frb, bool rc) {FSQRT(frd, frb, rc, true);}
void FRES(u32 frd, u32 frb, bool rc)
void FDIVS(u32 frd, u32 fra, u32 frb, u32 rc) {FDIV(frd, fra, frb, rc, true);}
void FSUBS(u32 frd, u32 fra, u32 frb, u32 rc) {FSUB(frd, fra, frb, rc, true);}
void FADDS(u32 frd, u32 fra, u32 frb, u32 rc) {FADD(frd, fra, frb, rc, true);}
void FSQRTS(u32 frd, u32 frb, u32 rc) {FSQRT(frd, frb, rc, true);}
void FRES(u32 frd, u32 frb, u32 rc)
{
SetHostRoundingMode(CPU.FPSCR.RN);
const double b = CPU.FPR[frb];
@ -3676,11 +3676,11 @@ private:
CPU.FPSCR.FPRF = CPU.FPR[frd].GetType();
if(rc) CPU.UpdateCR1();
}
void FMULS(u32 frd, u32 fra, u32 frc, bool rc) {FMUL(frd, fra, frc, rc, true);}
void FMADDS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) {FMADD(frd, fra, frc, frb, rc, false, false, true);}
void FMSUBS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) {FMADD(frd, fra, frc, frb, rc, false, true, true);}
void FNMSUBS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) {FMADD(frd, fra, frc, frb, rc, true, true, true);}
void FNMADDS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) {FMADD(frd, fra, frc, frb, rc, true, false, true);}
void FMULS(u32 frd, u32 fra, u32 frc, u32 rc) {FMUL(frd, fra, frc, rc, true);}
void FMADDS(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) {FMADD(frd, fra, frc, frb, rc, false, false, true);}
void FMSUBS(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) {FMADD(frd, fra, frc, frb, rc, false, true, true);}
void FNMSUBS(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) {FMADD(frd, fra, frc, frb, rc, true, true, true);}
void FNMADDS(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) {FMADD(frd, fra, frc, frb, rc, true, false, true);}
void STD(u32 rs, u32 ra, s32 d)
{
const u64 addr = ra ? CPU.GPR[ra] + d : d;
@ -3692,7 +3692,7 @@ private:
vm::write64(VM_CAST(addr), CPU.GPR[rs]);
CPU.GPR[ra] = addr;
}
void MTFSB1(u32 crbd, bool rc)
void MTFSB1(u32 crbd, u32 rc)
{
u32 mask = 1 << (31 - crbd);
if ((crbd >= 3 && crbd <= 6) && !(CPU.FPSCR.FPSCR & mask)) mask |= 1 << 31; //FPSCR.FX
@ -3707,7 +3707,7 @@ private:
const u32 exceptions_mask = 0x9FF80700;
CPU.SetFPSCR(CPU.FPSCR.FPSCR & ~(exceptions_mask & 0xf << ((7 - crbs) * 4)));
}
void MTFSB0(u32 crbd, bool rc)
void MTFSB0(u32 crbd, u32 rc)
{
u32 mask = 1 << (31 - crbd);
if ((crbd == 29) && !CPU.FPSCR.NI) LOG_WARNING(PPU, "Non-IEEE mode disabled");
@ -3715,7 +3715,7 @@ private:
if(rc) CPU.UpdateCR1();
}
void MTFSFI(u32 crfd, u32 i, bool rc)
void MTFSFI(u32 crfd, u32 i, u32 rc)
{
u32 mask = 0xF0000000 >> (crfd * 4);
u32 val = (i & 0xF) << ((7 - crfd) * 4);
@ -3732,12 +3732,12 @@ private:
if(rc) CPU.UpdateCR1();
}
void MFFS(u32 frd, bool rc)
void MFFS(u32 frd, u32 rc)
{
(u64&)CPU.FPR[frd] = CPU.FPSCR.FPSCR;
if(rc) CPU.UpdateCR1();
}
void MTFSF(u32 flm, u32 frb, bool rc)
void MTFSF(u32 flm, u32 frb, u32 rc)
{
u32 mask = 0;
for(u32 i=0; i<8; ++i)
@ -3772,7 +3772,7 @@ private:
CPU.FPSCR.FPRF = cmp_res;
CPU.SetCR(crfd, cmp_res);
}
void FRSP(u32 frd, u32 frb, bool rc)
void FRSP(u32 frd, u32 frb, u32 rc)
{
SetHostRoundingMode(CPU.FPSCR.RN);
const double b = CPU.FPR[frb];
@ -3811,8 +3811,8 @@ private:
CPU.FPR[frd] = r;
if(rc) CPU.UpdateCR1();
}
void FCTIW(u32 frd, u32 frb, bool rc) {FCTIW(frd, frb, rc, false);}
void FCTIW(u32 frd, u32 frb, bool rc, bool truncate)
void FCTIW(u32 frd, u32 frb, u32 rc) {FCTIW(frd, frb, rc, false);}
void FCTIW(u32 frd, u32 frb, u32 rc, bool truncate)
{
const double b = CPU.FPR[frb];
u32 r;
@ -3878,9 +3878,9 @@ private:
(u64&)CPU.FPR[frd] = r;
if(rc) CPU.UpdateCR1();
}
void FCTIWZ(u32 frd, u32 frb, bool rc) {FCTIW(frd, frb, rc, true);}
void FDIV(u32 frd, u32 fra, u32 frb, bool rc) {FDIV(frd, fra, frb, rc, false);}
void FDIV(u32 frd, u32 fra, u32 frb, bool rc, bool single)
void FCTIWZ(u32 frd, u32 frb, u32 rc) {FCTIW(frd, frb, rc, true);}
void FDIV(u32 frd, u32 fra, u32 frb, u32 rc) {FDIV(frd, fra, frb, rc, false);}
void FDIV(u32 frd, u32 fra, u32 frb, u32 rc, bool single)
{
SetHostRoundingMode(CPU.FPSCR.RN);
const double a = CPU.FPR[fra];
@ -3951,8 +3951,8 @@ private:
CPU.FPSCR.FPRF = CPU.FPR[frd].GetType();
if(rc) CPU.UpdateCR1();
}
void FSUB(u32 frd, u32 fra, u32 frb, bool rc) {FSUB(frd, fra, frb, rc, false);}
void FSUB(u32 frd, u32 fra, u32 frb, bool rc, bool single)
void FSUB(u32 frd, u32 fra, u32 frb, u32 rc) {FSUB(frd, fra, frb, rc, false);}
void FSUB(u32 frd, u32 fra, u32 frb, u32 rc, bool single)
{
SetHostRoundingMode(CPU.FPSCR.RN);
const double a = CPU.FPR[fra];
@ -3999,8 +3999,8 @@ private:
CPU.FPSCR.FPRF = CPU.FPR[frd].GetType();
if(rc) CPU.UpdateCR1();
}
void FADD(u32 frd, u32 fra, u32 frb, bool rc) {FADD(frd, fra, frb, rc, false);}
void FADD(u32 frd, u32 fra, u32 frb, bool rc, bool single)
void FADD(u32 frd, u32 fra, u32 frb, u32 rc) {FADD(frd, fra, frb, rc, false);}
void FADD(u32 frd, u32 fra, u32 frb, u32 rc, bool single)
{
SetHostRoundingMode(CPU.FPSCR.RN);
const double a = CPU.FPR[fra];
@ -4047,8 +4047,8 @@ private:
CPU.FPSCR.FPRF = CPU.FPR[frd].GetType();
if(rc) CPU.UpdateCR1();
}
void FSQRT(u32 frd, u32 frb, bool rc) {FSQRT(frd, frb, rc, false);}
void FSQRT(u32 frd, u32 frb, bool rc, bool single)
void FSQRT(u32 frd, u32 frb, u32 rc) {FSQRT(frd, frb, rc, false);}
void FSQRT(u32 frd, u32 frb, u32 rc, bool single)
{
SetHostRoundingMode(CPU.FPSCR.RN);
const double b = CPU.FPR[frb];
@ -4090,13 +4090,13 @@ private:
CPU.FPSCR.FPRF = CPU.FPR[frd].GetType();
if(rc) CPU.UpdateCR1();
}
void FSEL(u32 frd, u32 fra, u32 frc, u32 frb, bool rc)
void FSEL(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc)
{
CPU.FPR[frd] = CPU.FPR[fra] >= 0.0 ? CPU.FPR[frc] : CPU.FPR[frb];
if(rc) CPU.UpdateCR1();
}
void FMUL(u32 frd, u32 fra, u32 frc, bool rc) {FMUL(frd, fra, frc, rc, false);}
void FMUL(u32 frd, u32 fra, u32 frc, bool rc, bool single)
void FMUL(u32 frd, u32 fra, u32 frc, u32 rc) {FMUL(frd, fra, frc, rc, false);}
void FMUL(u32 frd, u32 fra, u32 frc, u32 rc, bool single)
{
SetHostRoundingMode(CPU.FPSCR.RN);
const double a = CPU.FPR[fra];
@ -4143,7 +4143,7 @@ private:
CPU.FPSCR.FPRF = CPU.FPR[frd].GetType();
if(rc) CPU.UpdateCR1();
}
void FRSQRTE(u32 frd, u32 frb, bool rc)
void FRSQRTE(u32 frd, u32 frb, u32 rc)
{
SetHostRoundingMode(CPU.FPSCR.RN);
const double b = CPU.FPR[frb];
@ -4195,9 +4195,9 @@ private:
CPU.FPSCR.FPRF = CPU.FPR[frd].GetType();
if(rc) CPU.UpdateCR1();
}
void FMSUB(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) {FMADD(frd, fra, frc, frb, rc, false, true, false);}
void FMADD(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) {FMADD(frd, fra, frc, frb, rc, false, false, false);}
void FMADD(u32 frd, u32 fra, u32 frc, u32 frb, bool rc, bool neg, bool sub, bool single)
void FMSUB(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) {FMADD(frd, fra, frc, frb, rc, false, true, false);}
void FMADD(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) {FMADD(frd, fra, frc, frb, rc, false, false, false);}
void FMADD(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc, bool neg, bool sub, bool single)
{
SetHostRoundingMode(CPU.FPSCR.RN);
const double a = CPU.FPR[fra];
@ -4264,8 +4264,8 @@ private:
CPU.FPSCR.FPRF = CPU.FPR[frd].GetType();
if(rc) CPU.UpdateCR1();
}
void FNMSUB(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) {FMADD(frd, fra, frc, frb, rc, true, true, false);}
void FNMADD(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) {FMADD(frd, fra, frc, frb, rc, true, false, false);}
void FNMSUB(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) {FMADD(frd, fra, frc, frb, rc, true, true, false);}
void FNMADD(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) {FMADD(frd, fra, frc, frb, rc, true, false, false);}
void FCMPO(u32 crfd, u32 fra, u32 frb)
{
int cmp_res = FPRdouble::Cmp(CPU.FPR[fra], CPU.FPR[frb]);
@ -4288,28 +4288,28 @@ private:
CPU.FPSCR.FPRF = cmp_res;
CPU.SetCR(crfd, cmp_res);
}
void FNEG(u32 frd, u32 frb, bool rc)
void FNEG(u32 frd, u32 frb, u32 rc)
{
CPU.FPR[frd] = -CPU.FPR[frb];
if(rc) CPU.UpdateCR1();
}
void FMR(u32 frd, u32 frb, bool rc)
void FMR(u32 frd, u32 frb, u32 rc)
{
CPU.FPR[frd] = CPU.FPR[frb];
if(rc) CPU.UpdateCR1();
}
void FNABS(u32 frd, u32 frb, bool rc)
void FNABS(u32 frd, u32 frb, u32 rc)
{
CPU.FPR[frd] = -fabs(CPU.FPR[frb]);
if(rc) CPU.UpdateCR1();
}
void FABS(u32 frd, u32 frb, bool rc)
void FABS(u32 frd, u32 frb, u32 rc)
{
CPU.FPR[frd] = fabs(CPU.FPR[frb]);
if(rc) CPU.UpdateCR1();
}
void FCTID(u32 frd, u32 frb, bool rc) {FCTID(frd, frb, rc, false);}
void FCTID(u32 frd, u32 frb, bool rc, bool truncate)
void FCTID(u32 frd, u32 frb, u32 rc) {FCTID(frd, frb, rc, false);}
void FCTID(u32 frd, u32 frb, u32 rc, bool truncate)
{
const double b = CPU.FPR[frb];
u64 r;
@ -4375,8 +4375,8 @@ private:
(u64&)CPU.FPR[frd] = r;
if(rc) CPU.UpdateCR1();
}
void FCTIDZ(u32 frd, u32 frb, bool rc) {FCTID(frd, frb, rc, true);}
void FCFID(u32 frd, u32 frb, bool rc)
void FCTIDZ(u32 frd, u32 frb, u32 rc) {FCTID(frd, frb, rc, true);}
void FCFID(u32 frd, u32 frb, u32 rc)
{
s64 bi = (s64&)CPU.FPR[frb];
double bf = (double)bi;

View File

@ -736,59 +736,59 @@ public:
virtual void CRORC(u32 bt, u32 ba, u32 bb) { func = ppu_interpreter::CRORC; }
virtual void CROR(u32 bt, u32 ba, u32 bb) { func = ppu_interpreter::CROR; }
virtual void BCCTR(u32 bo, u32 bi, u32 bh, u32 lk) { func = ppu_interpreter::BCCTR; }
virtual void RLWIMI(u32 ra, u32 rs, u32 sh, u32 mb, u32 me, bool rc) { func = ppu_interpreter::RLWIMI; }
virtual void RLWINM(u32 ra, u32 rs, u32 sh, u32 mb, u32 me, bool rc) { func = ppu_interpreter::RLWINM; }
virtual void RLWNM(u32 ra, u32 rs, u32 rb, u32 MB, u32 ME, bool rc) { func = ppu_interpreter::RLWNM; }
virtual void RLWIMI(u32 ra, u32 rs, u32 sh, u32 mb, u32 me, u32 rc) { func = ppu_interpreter::RLWIMI; }
virtual void RLWINM(u32 ra, u32 rs, u32 sh, u32 mb, u32 me, u32 rc) { func = ppu_interpreter::RLWINM; }
virtual void RLWNM(u32 ra, u32 rs, u32 rb, u32 MB, u32 ME, u32 rc) { func = ppu_interpreter::RLWNM; }
virtual void ORI(u32 rs, u32 ra, u32 uimm16) { func = ppu_interpreter::ORI; }
virtual void ORIS(u32 rs, u32 ra, u32 uimm16) { func = ppu_interpreter::ORIS; }
virtual void XORI(u32 ra, u32 rs, u32 uimm16) { func = ppu_interpreter::XORI; }
virtual void XORIS(u32 ra, u32 rs, u32 uimm16) { func = ppu_interpreter::XORIS; }
virtual void ANDI_(u32 ra, u32 rs, u32 uimm16) { func = ppu_interpreter::ANDI_; }
virtual void ANDIS_(u32 ra, u32 rs, u32 uimm16) { func = ppu_interpreter::ANDIS_; }
virtual void RLDICL(u32 ra, u32 rs, u32 sh, u32 mb, bool rc) { func = ppu_interpreter::RLDICL; }
virtual void RLDICR(u32 ra, u32 rs, u32 sh, u32 me, bool rc) { func = ppu_interpreter::RLDICR; }
virtual void RLDIC(u32 ra, u32 rs, u32 sh, u32 mb, bool rc) { func = ppu_interpreter::RLDIC; }
virtual void RLDIMI(u32 ra, u32 rs, u32 sh, u32 mb, bool rc) { func = ppu_interpreter::RLDIMI; }
virtual void RLDC_LR(u32 ra, u32 rs, u32 rb, u32 m_eb, bool is_r, bool rc) { func = ppu_interpreter::RLDC_LR; }
virtual void RLDICL(u32 ra, u32 rs, u32 sh, u32 mb, u32 rc) { func = ppu_interpreter::RLDICL; }
virtual void RLDICR(u32 ra, u32 rs, u32 sh, u32 me, u32 rc) { func = ppu_interpreter::RLDICR; }
virtual void RLDIC(u32 ra, u32 rs, u32 sh, u32 mb, u32 rc) { func = ppu_interpreter::RLDIC; }
virtual void RLDIMI(u32 ra, u32 rs, u32 sh, u32 mb, u32 rc) { func = ppu_interpreter::RLDIMI; }
virtual void RLDC_LR(u32 ra, u32 rs, u32 rb, u32 m_eb, u32 is_r, u32 rc) { func = ppu_interpreter::RLDC_LR; }
virtual void CMP(u32 crfd, u32 l, u32 ra, u32 rb) { func = ppu_interpreter::CMP; }
virtual void TW(u32 to, u32 ra, u32 rb) { func = ppu_interpreter::TW; }
virtual void LVSL(u32 vd, u32 ra, u32 rb) { func = ppu_interpreter::LVSL; }
virtual void LVEBX(u32 vd, u32 ra, u32 rb) { func = ppu_interpreter::LVEBX; }
virtual void SUBFC(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { func = ppu_interpreter::SUBFC; }
virtual void MULHDU(u32 rd, u32 ra, u32 rb, bool rc) { func = ppu_interpreter::MULHDU; }
virtual void ADDC(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { func = ppu_interpreter::ADDC; }
virtual void MULHWU(u32 rd, u32 ra, u32 rb, bool rc) { func = ppu_interpreter::MULHWU; }
virtual void SUBFC(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) { func = ppu_interpreter::SUBFC; }
virtual void MULHDU(u32 rd, u32 ra, u32 rb, u32 rc) { func = ppu_interpreter::MULHDU; }
virtual void ADDC(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) { func = ppu_interpreter::ADDC; }
virtual void MULHWU(u32 rd, u32 ra, u32 rb, u32 rc) { func = ppu_interpreter::MULHWU; }
virtual void MFOCRF(u32 a, u32 rd, u32 crm) { func = ppu_interpreter::MFOCRF; }
virtual void LWARX(u32 rd, u32 ra, u32 rb) { func = ppu_interpreter::LWARX; }
virtual void LDX(u32 ra, u32 rs, u32 rb) { func = ppu_interpreter::LDX; }
virtual void LWZX(u32 rd, u32 ra, u32 rb) { func = ppu_interpreter::LWZX; }
virtual void SLW(u32 ra, u32 rs, u32 rb, bool rc) { func = ppu_interpreter::SLW; }
virtual void CNTLZW(u32 ra, u32 rs, bool rc) { func = ppu_interpreter::CNTLZW; }
virtual void SLD(u32 ra, u32 rs, u32 rb, bool rc) { func = ppu_interpreter::SLD; }
virtual void AND(u32 ra, u32 rs, u32 rb, bool rc) { func = ppu_interpreter::AND; }
virtual void SLW(u32 ra, u32 rs, u32 rb, u32 rc) { func = ppu_interpreter::SLW; }
virtual void CNTLZW(u32 ra, u32 rs, u32 rc) { func = ppu_interpreter::CNTLZW; }
virtual void SLD(u32 ra, u32 rs, u32 rb, u32 rc) { func = ppu_interpreter::SLD; }
virtual void AND(u32 ra, u32 rs, u32 rb, u32 rc) { func = ppu_interpreter::AND; }
virtual void CMPL(u32 bf, u32 l, u32 ra, u32 rb) { func = ppu_interpreter::CMPL; }
virtual void LVSR(u32 vd, u32 ra, u32 rb) { func = ppu_interpreter::LVSR; }
virtual void LVEHX(u32 vd, u32 ra, u32 rb) { func = ppu_interpreter::LVEHX; }
virtual void SUBF(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { func = ppu_interpreter::SUBF; }
virtual void SUBF(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) { func = ppu_interpreter::SUBF; }
virtual void LDUX(u32 rd, u32 ra, u32 rb) { func = ppu_interpreter::LDUX; }
virtual void DCBST(u32 ra, u32 rb) { func = ppu_interpreter::DCBST; }
virtual void LWZUX(u32 rd, u32 ra, u32 rb) { func = ppu_interpreter::LWZUX; }
virtual void CNTLZD(u32 ra, u32 rs, bool rc) { func = ppu_interpreter::CNTLZD; }
virtual void ANDC(u32 ra, u32 rs, u32 rb, bool rc) { func = ppu_interpreter::ANDC; }
virtual void CNTLZD(u32 ra, u32 rs, u32 rc) { func = ppu_interpreter::CNTLZD; }
virtual void ANDC(u32 ra, u32 rs, u32 rb, u32 rc) { func = ppu_interpreter::ANDC; }
virtual void TD(u32 to, u32 ra, u32 rb) { func = ppu_interpreter::TD; }
virtual void LVEWX(u32 vd, u32 ra, u32 rb) { func = ppu_interpreter::LVEWX; }
virtual void MULHD(u32 rd, u32 ra, u32 rb, bool rc) { func = ppu_interpreter::MULHD; }
virtual void MULHW(u32 rd, u32 ra, u32 rb, bool rc) { func = ppu_interpreter::MULHW; }
virtual void MULHD(u32 rd, u32 ra, u32 rb, u32 rc) { func = ppu_interpreter::MULHD; }
virtual void MULHW(u32 rd, u32 ra, u32 rb, u32 rc) { func = ppu_interpreter::MULHW; }
virtual void LDARX(u32 rd, u32 ra, u32 rb) { func = ppu_interpreter::LDARX; }
virtual void DCBF(u32 ra, u32 rb) { func = ppu_interpreter::DCBF; }
virtual void LBZX(u32 rd, u32 ra, u32 rb) { func = ppu_interpreter::LBZX; }
virtual void LVX(u32 vd, u32 ra, u32 rb) { func = ppu_interpreter::LVX; }
virtual void NEG(u32 rd, u32 ra, u32 oe, bool rc) { func = ppu_interpreter::NEG; }
virtual void NEG(u32 rd, u32 ra, u32 oe, u32 rc) { func = ppu_interpreter::NEG; }
virtual void LBZUX(u32 rd, u32 ra, u32 rb) { func = ppu_interpreter::LBZUX; }
virtual void NOR(u32 ra, u32 rs, u32 rb, bool rc) { func = ppu_interpreter::NOR; }
virtual void NOR(u32 ra, u32 rs, u32 rb, u32 rc) { func = ppu_interpreter::NOR; }
virtual void STVEBX(u32 vs, u32 ra, u32 rb) { func = ppu_interpreter::STVEBX; }
virtual void SUBFE(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { func = ppu_interpreter::SUBFE; }
virtual void ADDE(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { func = ppu_interpreter::ADDE; }
virtual void SUBFE(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) { func = ppu_interpreter::SUBFE; }
virtual void ADDE(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) { func = ppu_interpreter::ADDE; }
virtual void MTOCRF(u32 l, u32 crm, u32 rs) { func = ppu_interpreter::MTOCRF; }
virtual void STDX(u32 rs, u32 ra, u32 rb) { func = ppu_interpreter::STDX; }
virtual void STWCX_(u32 rs, u32 ra, u32 rb) { func = ppu_interpreter::STWCX_; }
@ -797,24 +797,24 @@ public:
virtual void STDUX(u32 rs, u32 ra, u32 rb) { func = ppu_interpreter::STDUX; }
virtual void STWUX(u32 rs, u32 ra, u32 rb) { func = ppu_interpreter::STWUX; }
virtual void STVEWX(u32 vs, u32 ra, u32 rb) { func = ppu_interpreter::STVEWX; }
virtual void SUBFZE(u32 rd, u32 ra, u32 oe, bool rc) { func = ppu_interpreter::SUBFZE; }
virtual void ADDZE(u32 rd, u32 ra, u32 oe, bool rc) { func = ppu_interpreter::ADDZE; }
virtual void SUBFZE(u32 rd, u32 ra, u32 oe, u32 rc) { func = ppu_interpreter::SUBFZE; }
virtual void ADDZE(u32 rd, u32 ra, u32 oe, u32 rc) { func = ppu_interpreter::ADDZE; }
virtual void STDCX_(u32 rs, u32 ra, u32 rb) { func = ppu_interpreter::STDCX_; }
virtual void STBX(u32 rs, u32 ra, u32 rb) { func = ppu_interpreter::STBX; }
virtual void STVX(u32 vs, u32 ra, u32 rb) { func = ppu_interpreter::STVX; }
virtual void MULLD(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { func = ppu_interpreter::MULLD; }
virtual void SUBFME(u32 rd, u32 ra, u32 oe, bool rc) { func = ppu_interpreter::SUBFME; }
virtual void ADDME(u32 rd, u32 ra, u32 oe, bool rc) { func = ppu_interpreter::ADDME; }
virtual void MULLW(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { func = ppu_interpreter::MULLW; }
virtual void MULLD(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) { func = ppu_interpreter::MULLD; }
virtual void SUBFME(u32 rd, u32 ra, u32 oe, u32 rc) { func = ppu_interpreter::SUBFME; }
virtual void ADDME(u32 rd, u32 ra, u32 oe, u32 rc) { func = ppu_interpreter::ADDME; }
virtual void MULLW(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) { func = ppu_interpreter::MULLW; }
virtual void DCBTST(u32 ra, u32 rb, u32 th) { func = ppu_interpreter::DCBTST; }
virtual void STBUX(u32 rs, u32 ra, u32 rb) { func = ppu_interpreter::STBUX; }
virtual void ADD(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { func = ppu_interpreter::ADD; }
virtual void ADD(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) { func = ppu_interpreter::ADD; }
virtual void DCBT(u32 ra, u32 rb, u32 th) { func = ppu_interpreter::DCBT; }
virtual void LHZX(u32 rd, u32 ra, u32 rb) { func = ppu_interpreter::LHZX; }
virtual void EQV(u32 ra, u32 rs, u32 rb, bool rc) { func = ppu_interpreter::EQV; }
virtual void EQV(u32 ra, u32 rs, u32 rb, u32 rc) { func = ppu_interpreter::EQV; }
virtual void ECIWX(u32 rd, u32 ra, u32 rb) { func = ppu_interpreter::ECIWX; }
virtual void LHZUX(u32 rd, u32 ra, u32 rb) { func = ppu_interpreter::LHZUX; }
virtual void XOR(u32 rs, u32 ra, u32 rb, bool rc) { func = ppu_interpreter::XOR; }
virtual void XOR(u32 rs, u32 ra, u32 rb, u32 rc) { func = ppu_interpreter::XOR; }
virtual void MFSPR(u32 rd, u32 spr) { func = ppu_interpreter::MFSPR; }
virtual void LWAX(u32 rd, u32 ra, u32 rb) { func = ppu_interpreter::LWAX; }
virtual void DST(u32 ra, u32 rb, u32 strm, u32 t) { func = ppu_interpreter::DST; }
@ -825,25 +825,25 @@ public:
virtual void DSTST(u32 ra, u32 rb, u32 strm, u32 t) { func = ppu_interpreter::DSTST; }
virtual void LHAUX(u32 rd, u32 ra, u32 rb) { func = ppu_interpreter::LHAUX; }
virtual void STHX(u32 rs, u32 ra, u32 rb) { func = ppu_interpreter::STHX; }
virtual void ORC(u32 rs, u32 ra, u32 rb, bool rc) { func = ppu_interpreter::ORC; }
virtual void ORC(u32 rs, u32 ra, u32 rb, u32 rc) { func = ppu_interpreter::ORC; }
virtual void ECOWX(u32 rs, u32 ra, u32 rb) { func = ppu_interpreter::ECOWX; }
virtual void STHUX(u32 rs, u32 ra, u32 rb) { func = ppu_interpreter::STHUX; }
virtual void OR(u32 ra, u32 rs, u32 rb, bool rc) { func = ppu_interpreter::OR; }
virtual void DIVDU(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { func = ppu_interpreter::DIVDU; }
virtual void DIVWU(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { func = ppu_interpreter::DIVWU; }
virtual void OR(u32 ra, u32 rs, u32 rb, u32 rc) { func = ppu_interpreter::OR; }
virtual void DIVDU(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) { func = ppu_interpreter::DIVDU; }
virtual void DIVWU(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) { func = ppu_interpreter::DIVWU; }
virtual void MTSPR(u32 spr, u32 rs) { func = ppu_interpreter::MTSPR; }
virtual void DCBI(u32 ra, u32 rb) { func = ppu_interpreter::DCBI; }
virtual void NAND(u32 ra, u32 rs, u32 rb, bool rc) { func = ppu_interpreter::NAND; }
virtual void NAND(u32 ra, u32 rs, u32 rb, u32 rc) { func = ppu_interpreter::NAND; }
virtual void STVXL(u32 vs, u32 ra, u32 rb) { func = ppu_interpreter::STVXL; }
virtual void DIVD(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { func = ppu_interpreter::DIVD; }
virtual void DIVW(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { func = ppu_interpreter::DIVW; }
virtual void DIVD(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) { func = ppu_interpreter::DIVD; }
virtual void DIVW(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) { func = ppu_interpreter::DIVW; }
virtual void LVLX(u32 vd, u32 ra, u32 rb) { func = ppu_interpreter::LVLX; }
virtual void LDBRX(u32 rd, u32 ra, u32 rb) { func = ppu_interpreter::LDBRX; }
virtual void LSWX(u32 rd, u32 ra, u32 rb) { func = ppu_interpreter::LSWX; }
virtual void LWBRX(u32 rd, u32 ra, u32 rb) { func = ppu_interpreter::LWBRX; }
virtual void LFSX(u32 frd, u32 ra, u32 rb) { func = ppu_interpreter::LFSX; }
virtual void SRW(u32 ra, u32 rs, u32 rb, bool rc) { func = ppu_interpreter::SRW; }
virtual void SRD(u32 ra, u32 rs, u32 rb, bool rc) { func = ppu_interpreter::SRD; }
virtual void SRW(u32 ra, u32 rs, u32 rb, u32 rc) { func = ppu_interpreter::SRW; }
virtual void SRD(u32 ra, u32 rs, u32 rb, u32 rc) { func = ppu_interpreter::SRD; }
virtual void LVRX(u32 vd, u32 ra, u32 rb) { func = ppu_interpreter::LVRX; }
virtual void LSWI(u32 rd, u32 ra, u32 nb) { func = ppu_interpreter::LSWI; }
virtual void LFSUX(u32 frd, u32 ra, u32 rb) { func = ppu_interpreter::LFSUX; }
@ -862,21 +862,21 @@ public:
virtual void STFDUX(u32 frs, u32 ra, u32 rb) { func = ppu_interpreter::STFDUX; }
virtual void LVLXL(u32 vd, u32 ra, u32 rb) { func = ppu_interpreter::LVLXL; }
virtual void LHBRX(u32 rd, u32 ra, u32 rb) { func = ppu_interpreter::LHBRX; }
virtual void SRAW(u32 ra, u32 rs, u32 rb, bool rc) { func = ppu_interpreter::SRAW; }
virtual void SRAD(u32 ra, u32 rs, u32 rb, bool rc) { func = ppu_interpreter::SRAD; }
virtual void SRAW(u32 ra, u32 rs, u32 rb, u32 rc) { func = ppu_interpreter::SRAW; }
virtual void SRAD(u32 ra, u32 rs, u32 rb, u32 rc) { func = ppu_interpreter::SRAD; }
virtual void LVRXL(u32 vd, u32 ra, u32 rb) { func = ppu_interpreter::LVRXL; }
virtual void DSS(u32 strm, u32 a) { func = ppu_interpreter::DSS; }
virtual void SRAWI(u32 ra, u32 rs, u32 sh, bool rc) { func = ppu_interpreter::SRAWI; }
virtual void SRADI1(u32 ra, u32 rs, u32 sh, bool rc) { func = ppu_interpreter::SRADI; }
virtual void SRADI2(u32 ra, u32 rs, u32 sh, bool rc) { func = ppu_interpreter::SRADI; }
virtual void SRAWI(u32 ra, u32 rs, u32 sh, u32 rc) { func = ppu_interpreter::SRAWI; }
virtual void SRADI1(u32 ra, u32 rs, u32 sh, u32 rc) { func = ppu_interpreter::SRADI; }
virtual void SRADI2(u32 ra, u32 rs, u32 sh, u32 rc) { func = ppu_interpreter::SRADI; }
virtual void EIEIO() { func = ppu_interpreter::EIEIO; }
virtual void STVLXL(u32 vs, u32 ra, u32 rb) { func = ppu_interpreter::STVLXL; }
virtual void STHBRX(u32 rs, u32 ra, u32 rb) { func = ppu_interpreter::STHBRX; }
virtual void EXTSH(u32 ra, u32 rs, bool rc) { func = ppu_interpreter::EXTSH; }
virtual void EXTSH(u32 ra, u32 rs, u32 rc) { func = ppu_interpreter::EXTSH; }
virtual void STVRXL(u32 sd, u32 ra, u32 rb) { func = ppu_interpreter::STVRXL; }
virtual void EXTSB(u32 ra, u32 rs, bool rc) { func = ppu_interpreter::EXTSB; }
virtual void EXTSB(u32 ra, u32 rs, u32 rc) { func = ppu_interpreter::EXTSB; }
virtual void STFIWX(u32 frs, u32 ra, u32 rb) { func = ppu_interpreter::STFIWX; }
virtual void EXTSW(u32 ra, u32 rs, bool rc) { func = ppu_interpreter::EXTSW; }
virtual void EXTSW(u32 ra, u32 rs, u32 rc) { func = ppu_interpreter::EXTSW; }
virtual void ICBI(u32 ra, u32 rb) { func = ppu_interpreter::ICBI; }
virtual void DCBZ(u32 ra, u32 rb) { func = ppu_interpreter::DCBZ; }
virtual void LWZ(u32 rd, u32 ra, s32 d) { func = ppu_interpreter::LWZ; }
@ -906,48 +906,48 @@ public:
virtual void LD(u32 rd, u32 ra, s32 ds) { func = ppu_interpreter::LD; }
virtual void LDU(u32 rd, u32 ra, s32 ds) { func = ppu_interpreter::LDU; }
virtual void LWA(u32 rd, u32 ra, s32 ds) { func = ppu_interpreter::LWA; }
virtual void FDIVS(u32 frd, u32 fra, u32 frb, bool rc) { func = ppu_interpreter::FDIVS; }
virtual void FSUBS(u32 frd, u32 fra, u32 frb, bool rc) { func = ppu_interpreter::FSUBS; }
virtual void FADDS(u32 frd, u32 fra, u32 frb, bool rc) { func = ppu_interpreter::FADDS; }
virtual void FSQRTS(u32 frd, u32 frb, bool rc) { func = ppu_interpreter::FSQRTS; }
virtual void FRES(u32 frd, u32 frb, bool rc) { func = ppu_interpreter::FRES; }
virtual void FMULS(u32 frd, u32 fra, u32 frc, bool rc) { func = ppu_interpreter::FMULS; }
virtual void FMADDS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) { func = ppu_interpreter::FMADDS; }
virtual void FMSUBS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) { func = ppu_interpreter::FMSUBS; }
virtual void FNMSUBS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) { func = ppu_interpreter::FNMSUBS; }
virtual void FNMADDS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) { func = ppu_interpreter::FNMADDS; }
virtual void FDIVS(u32 frd, u32 fra, u32 frb, u32 rc) { func = ppu_interpreter::FDIVS; }
virtual void FSUBS(u32 frd, u32 fra, u32 frb, u32 rc) { func = ppu_interpreter::FSUBS; }
virtual void FADDS(u32 frd, u32 fra, u32 frb, u32 rc) { func = ppu_interpreter::FADDS; }
virtual void FSQRTS(u32 frd, u32 frb, u32 rc) { func = ppu_interpreter::FSQRTS; }
virtual void FRES(u32 frd, u32 frb, u32 rc) { func = ppu_interpreter::FRES; }
virtual void FMULS(u32 frd, u32 fra, u32 frc, u32 rc) { func = ppu_interpreter::FMULS; }
virtual void FMADDS(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) { func = ppu_interpreter::FMADDS; }
virtual void FMSUBS(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) { func = ppu_interpreter::FMSUBS; }
virtual void FNMSUBS(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) { func = ppu_interpreter::FNMSUBS; }
virtual void FNMADDS(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) { func = ppu_interpreter::FNMADDS; }
virtual void STD(u32 rs, u32 ra, s32 ds) { func = ppu_interpreter::STD; }
virtual void STDU(u32 rs, u32 ra, s32 ds) { func = ppu_interpreter::STDU; }
virtual void MTFSB1(u32 bt, bool rc) { func = ppu_interpreter::MTFSB1; }
virtual void MTFSB1(u32 bt, u32 rc) { func = ppu_interpreter::MTFSB1; }
virtual void MCRFS(u32 bf, u32 bfa) { func = ppu_interpreter::MCRFS; }
virtual void MTFSB0(u32 bt, bool rc) { func = ppu_interpreter::MTFSB0; }
virtual void MTFSFI(u32 crfd, u32 i, bool rc) { func = ppu_interpreter::MTFSFI; }
virtual void MFFS(u32 frd, bool rc) { func = ppu_interpreter::MFFS; }
virtual void MTFSF(u32 flm, u32 frb, bool rc) { func = ppu_interpreter::MTFSF; }
virtual void MTFSB0(u32 bt, u32 rc) { func = ppu_interpreter::MTFSB0; }
virtual void MTFSFI(u32 crfd, u32 i, u32 rc) { func = ppu_interpreter::MTFSFI; }
virtual void MFFS(u32 frd, u32 rc) { func = ppu_interpreter::MFFS; }
virtual void MTFSF(u32 flm, u32 frb, u32 rc) { func = ppu_interpreter::MTFSF; }
virtual void FCMPU(u32 bf, u32 fra, u32 frb) { func = ppu_interpreter::FCMPU; }
virtual void FRSP(u32 frd, u32 frb, bool rc) { func = ppu_interpreter::FRSP; }
virtual void FCTIW(u32 frd, u32 frb, bool rc) { func = ppu_interpreter::FCTIW; }
virtual void FCTIWZ(u32 frd, u32 frb, bool rc) { func = ppu_interpreter::FCTIWZ; }
virtual void FDIV(u32 frd, u32 fra, u32 frb, bool rc) { func = ppu_interpreter::FDIV; }
virtual void FSUB(u32 frd, u32 fra, u32 frb, bool rc) { func = ppu_interpreter::FSUB; }
virtual void FADD(u32 frd, u32 fra, u32 frb, bool rc) { func = ppu_interpreter::FADD; }
virtual void FSQRT(u32 frd, u32 frb, bool rc) { func = ppu_interpreter::FSQRT; }
virtual void FSEL(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) { func = ppu_interpreter::FSEL; }
virtual void FMUL(u32 frd, u32 fra, u32 frc, bool rc) { func = ppu_interpreter::FMUL; }
virtual void FRSQRTE(u32 frd, u32 frb, bool rc) { func = ppu_interpreter::FRSQRTE; }
virtual void FMSUB(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) { func = ppu_interpreter::FMSUB; }
virtual void FMADD(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) { func = ppu_interpreter::FMADD; }
virtual void FNMSUB(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) { func = ppu_interpreter::FNMSUB; }
virtual void FNMADD(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) { func = ppu_interpreter::FNMADD; }
virtual void FRSP(u32 frd, u32 frb, u32 rc) { func = ppu_interpreter::FRSP; }
virtual void FCTIW(u32 frd, u32 frb, u32 rc) { func = ppu_interpreter::FCTIW; }
virtual void FCTIWZ(u32 frd, u32 frb, u32 rc) { func = ppu_interpreter::FCTIWZ; }
virtual void FDIV(u32 frd, u32 fra, u32 frb, u32 rc) { func = ppu_interpreter::FDIV; }
virtual void FSUB(u32 frd, u32 fra, u32 frb, u32 rc) { func = ppu_interpreter::FSUB; }
virtual void FADD(u32 frd, u32 fra, u32 frb, u32 rc) { func = ppu_interpreter::FADD; }
virtual void FSQRT(u32 frd, u32 frb, u32 rc) { func = ppu_interpreter::FSQRT; }
virtual void FSEL(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) { func = ppu_interpreter::FSEL; }
virtual void FMUL(u32 frd, u32 fra, u32 frc, u32 rc) { func = ppu_interpreter::FMUL; }
virtual void FRSQRTE(u32 frd, u32 frb, u32 rc) { func = ppu_interpreter::FRSQRTE; }
virtual void FMSUB(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) { func = ppu_interpreter::FMSUB; }
virtual void FMADD(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) { func = ppu_interpreter::FMADD; }
virtual void FNMSUB(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) { func = ppu_interpreter::FNMSUB; }
virtual void FNMADD(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) { func = ppu_interpreter::FNMADD; }
virtual void FCMPO(u32 crfd, u32 fra, u32 frb) { func = ppu_interpreter::FCMPO; }
virtual void FNEG(u32 frd, u32 frb, bool rc) { func = ppu_interpreter::FNEG; }
virtual void FMR(u32 frd, u32 frb, bool rc) { func = ppu_interpreter::FMR; }
virtual void FNABS(u32 frd, u32 frb, bool rc) { func = ppu_interpreter::FNABS; }
virtual void FABS(u32 frd, u32 frb, bool rc) { func = ppu_interpreter::FABS; }
virtual void FCTID(u32 frd, u32 frb, bool rc) { func = ppu_interpreter::FCTID; }
virtual void FCTIDZ(u32 frd, u32 frb, bool rc) { func = ppu_interpreter::FCTIDZ; }
virtual void FCFID(u32 frd, u32 frb, bool rc) { func = ppu_interpreter::FCFID; }
virtual void FNEG(u32 frd, u32 frb, u32 rc) { func = ppu_interpreter::FNEG; }
virtual void FMR(u32 frd, u32 frb, u32 rc) { func = ppu_interpreter::FMR; }
virtual void FNABS(u32 frd, u32 frb, u32 rc) { func = ppu_interpreter::FNABS; }
virtual void FABS(u32 frd, u32 frb, u32 rc) { func = ppu_interpreter::FABS; }
virtual void FCTID(u32 frd, u32 frb, u32 rc) { func = ppu_interpreter::FCTID; }
virtual void FCTIDZ(u32 frd, u32 frb, u32 rc) { func = ppu_interpreter::FCTIDZ; }
virtual void FCFID(u32 frd, u32 frb, u32 rc) { func = ppu_interpreter::FCFID; }
virtual void UNK(const u32 code, const u32 opcode, const u32 gcode) { func = ppu_interpreter::UNK; }
};

View File

@ -2158,7 +2158,7 @@ void Compiler::BCCTR(u32 bo, u32 bi, u32 bh, u32 lk) {
CreateBranch(CheckBranchCondition(bo, bi), ctr_i32, lk ? true : false);
}
void Compiler::RLWIMI(u32 ra, u32 rs, u32 sh, u32 mb, u32 me, bool rc) {
void Compiler::RLWIMI(u32 ra, u32 rs, u32 sh, u32 mb, u32 me, u32 rc) {
auto rs_i32 = GetGpr(rs, 32);
auto rs_i64 = m_ir_builder->CreateZExt(rs_i32, m_ir_builder->getInt64Ty());
auto rsh_i64 = m_ir_builder->CreateShl(rs_i64, 32);
@ -2182,7 +2182,7 @@ void Compiler::RLWIMI(u32 ra, u32 rs, u32 sh, u32 mb, u32 me, bool rc) {
}
}
void Compiler::RLWINM(u32 ra, u32 rs, u32 sh, u32 mb, u32 me, bool rc) {
void Compiler::RLWINM(u32 ra, u32 rs, u32 sh, u32 mb, u32 me, u32 rc) {
auto rs_i32 = GetGpr(rs, 32);
auto rs_i64 = m_ir_builder->CreateZExt(rs_i32, m_ir_builder->getInt64Ty());
auto rsh_i64 = m_ir_builder->CreateShl(rs_i64, 32);
@ -2202,7 +2202,7 @@ void Compiler::RLWINM(u32 ra, u32 rs, u32 sh, u32 mb, u32 me, bool rc) {
}
}
void Compiler::RLWNM(u32 ra, u32 rs, u32 rb, u32 mb, u32 me, bool rc) {
void Compiler::RLWNM(u32 ra, u32 rs, u32 rb, u32 mb, u32 me, u32 rc) {
auto rs_i32 = GetGpr(rs, 32);
auto rs_i64 = m_ir_builder->CreateZExt(rs_i32, m_ir_builder->getInt64Ty());
auto rsh_i64 = m_ir_builder->CreateShl(rs_i64, 32);
@ -2259,7 +2259,7 @@ void Compiler::ANDIS_(u32 ra, u32 rs, u32 uimm16) {
SetCrFieldSignedCmp(0, res_i64, m_ir_builder->getInt64(0));
}
void Compiler::RLDICL(u32 ra, u32 rs, u32 sh, u32 mb, bool rc) {
void Compiler::RLDICL(u32 ra, u32 rs, u32 sh, u32 mb, u32 rc) {
auto rs_i64 = GetGpr(rs);
auto res_i64 = rs_i64;
if (sh) {
@ -2276,7 +2276,7 @@ void Compiler::RLDICL(u32 ra, u32 rs, u32 sh, u32 mb, bool rc) {
}
}
void Compiler::RLDICR(u32 ra, u32 rs, u32 sh, u32 me, bool rc) {
void Compiler::RLDICR(u32 ra, u32 rs, u32 sh, u32 me, u32 rc) {
auto rs_i64 = GetGpr(rs);
auto res_i64 = rs_i64;
if (sh) {
@ -2293,7 +2293,7 @@ void Compiler::RLDICR(u32 ra, u32 rs, u32 sh, u32 me, bool rc) {
}
}
void Compiler::RLDIC(u32 ra, u32 rs, u32 sh, u32 mb, bool rc) {
void Compiler::RLDIC(u32 ra, u32 rs, u32 sh, u32 mb, u32 rc) {
auto rs_i64 = GetGpr(rs);
auto res_i64 = rs_i64;
if (sh) {
@ -2310,7 +2310,7 @@ void Compiler::RLDIC(u32 ra, u32 rs, u32 sh, u32 mb, bool rc) {
}
}
void Compiler::RLDIMI(u32 ra, u32 rs, u32 sh, u32 mb, bool rc) {
void Compiler::RLDIMI(u32 ra, u32 rs, u32 sh, u32 mb, u32 rc) {
auto rs_i64 = GetGpr(rs);
auto ra_i64 = GetGpr(ra);
auto res_i64 = rs_i64;
@ -2331,7 +2331,7 @@ void Compiler::RLDIMI(u32 ra, u32 rs, u32 sh, u32 mb, bool rc) {
}
}
void Compiler::RLDC_LR(u32 ra, u32 rs, u32 rb, u32 m_eb, bool is_r, bool rc) {
void Compiler::RLDC_LR(u32 ra, u32 rs, u32 rb, u32 m_eb, u32 is_r, u32 rc) {
auto rs_i64 = GetGpr(rs);
auto rb_i64 = GetGpr(rb);
auto shl_i64 = m_ir_builder->CreateAnd(rb_i64, 0x3F);
@ -2419,7 +2419,7 @@ void Compiler::LVEBX(u32 vd, u32 ra, u32 rb) {
SetVr(vd, vd_v16i8);
}
void Compiler::SUBFC(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) {
void Compiler::SUBFC(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) {
auto ra_i64 = GetGpr(ra);
ra_i64 = m_ir_builder->CreateNeg(ra_i64);
auto rb_i64 = GetGpr(rb);
@ -2439,7 +2439,7 @@ void Compiler::SUBFC(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) {
}
}
void Compiler::ADDC(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) {
void Compiler::ADDC(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) {
auto ra_i64 = GetGpr(ra);
auto rb_i64 = GetGpr(rb);
auto res_s = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::uadd_with_overflow, m_ir_builder->getInt64Ty()), ra_i64, rb_i64);
@ -2457,7 +2457,7 @@ void Compiler::ADDC(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) {
}
}
void Compiler::MULHDU(u32 rd, u32 ra, u32 rb, bool rc) {
void Compiler::MULHDU(u32 rd, u32 ra, u32 rb, u32 rc) {
auto ra_i64 = GetGpr(ra);
auto rb_i64 = GetGpr(rb);
auto ra_i128 = m_ir_builder->CreateZExt(ra_i64, m_ir_builder->getIntNTy(128));
@ -2472,7 +2472,7 @@ void Compiler::MULHDU(u32 rd, u32 ra, u32 rb, bool rc) {
}
}
void Compiler::MULHWU(u32 rd, u32 ra, u32 rb, bool rc) {
void Compiler::MULHWU(u32 rd, u32 ra, u32 rb, u32 rc) {
auto ra_i32 = GetGpr(ra, 32);
auto rb_i32 = GetGpr(rb, 32);
auto ra_i64 = m_ir_builder->CreateZExt(ra_i32, m_ir_builder->getInt64Ty());
@ -2532,7 +2532,7 @@ void Compiler::LWZX(u32 rd, u32 ra, u32 rb) {
SetGpr(rd, mem_i64);
}
void Compiler::SLW(u32 ra, u32 rs, u32 rb, bool rc) {
void Compiler::SLW(u32 ra, u32 rs, u32 rb, u32 rc) {
auto rs_i32 = GetGpr(rs, 32);
auto rs_i64 = m_ir_builder->CreateZExt(rs_i32, m_ir_builder->getInt64Ty());
auto rb_i8 = GetGpr(rb, 8);
@ -2548,7 +2548,7 @@ void Compiler::SLW(u32 ra, u32 rs, u32 rb, bool rc) {
}
}
void Compiler::CNTLZW(u32 ra, u32 rs, bool rc) {
void Compiler::CNTLZW(u32 ra, u32 rs, u32 rc) {
auto rs_i32 = GetGpr(rs, 32);
auto res_i32 = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::ctlz, m_ir_builder->getInt32Ty()), rs_i32, m_ir_builder->getInt1(false));
auto res_i64 = m_ir_builder->CreateZExt(res_i32, m_ir_builder->getInt64Ty());
@ -2559,7 +2559,7 @@ void Compiler::CNTLZW(u32 ra, u32 rs, bool rc) {
}
}
void Compiler::SLD(u32 ra, u32 rs, u32 rb, bool rc) {
void Compiler::SLD(u32 ra, u32 rs, u32 rb, u32 rc) {
auto rs_i64 = GetGpr(rs);
auto rs_i128 = m_ir_builder->CreateZExt(rs_i64, m_ir_builder->getIntNTy(128));
auto rb_i8 = GetGpr(rb, 8);
@ -2574,7 +2574,7 @@ void Compiler::SLD(u32 ra, u32 rs, u32 rb, bool rc) {
}
}
void Compiler::AND(u32 ra, u32 rs, u32 rb, bool rc) {
void Compiler::AND(u32 ra, u32 rs, u32 rb, u32 rc) {
auto rs_i64 = GetGpr(rs);
auto rb_i64 = GetGpr(rb);
auto res_i64 = m_ir_builder->CreateAnd(rs_i64, rb_i64);
@ -2649,7 +2649,7 @@ void Compiler::LVEHX(u32 vd, u32 ra, u32 rb) {
SetVr(vd, vd_v8i16);
}
void Compiler::SUBF(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) {
void Compiler::SUBF(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) {
auto ra_i64 = GetGpr(ra);
auto rb_i64 = GetGpr(rb);
auto diff_i64 = m_ir_builder->CreateSub(rb_i64, ra_i64);
@ -2691,7 +2691,7 @@ void Compiler::LWZUX(u32 rd, u32 ra, u32 rb) {
SetGpr(ra, addr_i64);
}
void Compiler::CNTLZD(u32 ra, u32 rs, bool rc) {
void Compiler::CNTLZD(u32 ra, u32 rs, u32 rc) {
auto rs_i64 = GetGpr(rs);
auto res_i64 = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::ctlz, m_ir_builder->getInt64Ty()), rs_i64, m_ir_builder->getInt1(false));
SetGpr(ra, res_i64);
@ -2701,7 +2701,7 @@ void Compiler::CNTLZD(u32 ra, u32 rs, bool rc) {
}
}
void Compiler::ANDC(u32 ra, u32 rs, u32 rb, bool rc) {
void Compiler::ANDC(u32 ra, u32 rs, u32 rb, u32 rc) {
auto rs_i64 = GetGpr(rs);
auto rb_i64 = GetGpr(rb);
rb_i64 = m_ir_builder->CreateNot(rb_i64);
@ -2734,7 +2734,7 @@ void Compiler::LVEWX(u32 vd, u32 ra, u32 rb) {
SetVr(vd, vd_v4i32);
}
void Compiler::MULHD(u32 rd, u32 ra, u32 rb, bool rc) {
void Compiler::MULHD(u32 rd, u32 ra, u32 rb, u32 rc) {
auto ra_i64 = GetGpr(ra);
auto rb_i64 = GetGpr(rb);
auto ra_i128 = m_ir_builder->CreateSExt(ra_i64, m_ir_builder->getIntNTy(128));
@ -2749,7 +2749,7 @@ void Compiler::MULHD(u32 rd, u32 ra, u32 rb, bool rc) {
}
}
void Compiler::MULHW(u32 rd, u32 ra, u32 rb, bool rc) {
void Compiler::MULHW(u32 rd, u32 ra, u32 rb, u32 rc) {
auto ra_i32 = GetGpr(ra, 32);
auto rb_i32 = GetGpr(rb, 32);
auto ra_i64 = m_ir_builder->CreateSExt(ra_i32, m_ir_builder->getInt64Ty());
@ -2808,7 +2808,7 @@ void Compiler::LVX(u32 vd, u32 ra, u32 rb) {
SetVr(vd, mem_i128);
}
void Compiler::NEG(u32 rd, u32 ra, u32 oe, bool rc) {
void Compiler::NEG(u32 rd, u32 ra, u32 oe, u32 rc) {
auto ra_i64 = GetGpr(ra);
auto diff_i64 = m_ir_builder->CreateSub(m_ir_builder->getInt64(0), ra_i64);
SetGpr(rd, diff_i64);
@ -2834,7 +2834,7 @@ void Compiler::LBZUX(u32 rd, u32 ra, u32 rb) {
SetGpr(ra, addr_i64);
}
void Compiler::NOR(u32 ra, u32 rs, u32 rb, bool rc) {
void Compiler::NOR(u32 ra, u32 rs, u32 rb, u32 rc) {
auto rs_i64 = GetGpr(rs);
auto rb_i64 = GetGpr(rb);
auto res_i64 = m_ir_builder->CreateOr(rs_i64, rb_i64);
@ -2860,7 +2860,7 @@ void Compiler::STVEBX(u32 vs, u32 ra, u32 rb) {
WriteMemory(addr_i64, val_i8);
}
void Compiler::SUBFE(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) {
void Compiler::SUBFE(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) {
auto ca_i64 = GetXerCa();
auto ra_i64 = GetGpr(ra);
auto rb_i64 = GetGpr(rb);
@ -2885,7 +2885,7 @@ void Compiler::SUBFE(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) {
}
}
void Compiler::ADDE(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) {
void Compiler::ADDE(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) {
auto ca_i64 = GetXerCa();
auto ra_i64 = GetGpr(ra);
auto rb_i64 = GetGpr(rb);
@ -3019,7 +3019,7 @@ void Compiler::STVEWX(u32 vs, u32 ra, u32 rb) {
WriteMemory(addr_i64, val_i32, 4);
}
void Compiler::ADDZE(u32 rd, u32 ra, u32 oe, bool rc) {
void Compiler::ADDZE(u32 rd, u32 ra, u32 oe, u32 rc) {
auto ra_i64 = GetGpr(ra);
auto ca_i64 = GetXerCa();
auto res_s = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::uadd_with_overflow, m_ir_builder->getInt64Ty()), ra_i64, ca_i64);
@ -3038,7 +3038,7 @@ void Compiler::ADDZE(u32 rd, u32 ra, u32 oe, bool rc) {
}
}
void Compiler::SUBFZE(u32 rd, u32 ra, u32 oe, bool rc) {
void Compiler::SUBFZE(u32 rd, u32 ra, u32 oe, u32 rc) {
auto ra_i64 = GetGpr(ra);
ra_i64 = m_ir_builder->CreateNot(ra_i64);
auto ca_i64 = GetXerCa();
@ -3099,7 +3099,7 @@ void Compiler::STVX(u32 vs, u32 ra, u32 rb) {
WriteMemory(addr_i64, GetVr(vs), 16);
}
void Compiler::SUBFME(u32 rd, u32 ra, u32 oe, bool rc) {
void Compiler::SUBFME(u32 rd, u32 ra, u32 oe, u32 rc) {
auto ca_i64 = GetXerCa();
auto ra_i64 = GetGpr(ra);
ra_i64 = m_ir_builder->CreateNot(ra_i64);
@ -3123,7 +3123,7 @@ void Compiler::SUBFME(u32 rd, u32 ra, u32 oe, bool rc) {
}
}
void Compiler::MULLD(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) {
void Compiler::MULLD(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) {
auto ra_i64 = GetGpr(ra);
auto rb_i64 = GetGpr(rb);
auto prod_i64 = m_ir_builder->CreateMul(ra_i64, rb_i64);
@ -3139,7 +3139,7 @@ void Compiler::MULLD(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) {
}
}
void Compiler::ADDME(u32 rd, u32 ra, u32 oe, bool rc) {
void Compiler::ADDME(u32 rd, u32 ra, u32 oe, u32 rc) {
auto ca_i64 = GetXerCa();
auto ra_i64 = GetGpr(ra);
auto res_s = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::uadd_with_overflow, m_ir_builder->getInt64Ty()), ra_i64, ca_i64);
@ -3162,7 +3162,7 @@ void Compiler::ADDME(u32 rd, u32 ra, u32 oe, bool rc) {
}
}
void Compiler::MULLW(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) {
void Compiler::MULLW(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) {
auto ra_i32 = GetGpr(ra, 32);
auto rb_i32 = GetGpr(rb, 32);
auto ra_i64 = m_ir_builder->CreateSExt(ra_i32, m_ir_builder->getInt64Ty());
@ -3194,7 +3194,7 @@ void Compiler::STBUX(u32 rs, u32 ra, u32 rb) {
SetGpr(ra, addr_i64);
}
void Compiler::ADD(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) {
void Compiler::ADD(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) {
auto ra_i64 = GetGpr(ra);
auto rb_i64 = GetGpr(rb);
auto sum_i64 = m_ir_builder->CreateAdd(ra_i64, rb_i64);
@ -3227,7 +3227,7 @@ void Compiler::LHZX(u32 rd, u32 ra, u32 rb) {
SetGpr(rd, mem_i64);
}
void Compiler::EQV(u32 ra, u32 rs, u32 rb, bool rc) {
void Compiler::EQV(u32 ra, u32 rs, u32 rb, u32 rc) {
auto rs_i64 = GetGpr(rs);
auto rb_i64 = GetGpr(rb);
auto res_i64 = m_ir_builder->CreateXor(rs_i64, rb_i64);
@ -3263,7 +3263,7 @@ void Compiler::LHZUX(u32 rd, u32 ra, u32 rb) {
SetGpr(ra, addr_i64);
}
void Compiler::XOR(u32 ra, u32 rs, u32 rb, bool rc) {
void Compiler::XOR(u32 ra, u32 rs, u32 rb, u32 rc) {
auto rs_i64 = GetGpr(rs);
auto rb_i64 = GetGpr(rb);
auto res_i64 = m_ir_builder->CreateXor(rs_i64, rb_i64);
@ -3387,7 +3387,7 @@ void Compiler::STHX(u32 rs, u32 ra, u32 rb) {
WriteMemory(addr_i64, GetGpr(rs, 16));
}
void Compiler::ORC(u32 ra, u32 rs, u32 rb, bool rc) {
void Compiler::ORC(u32 ra, u32 rs, u32 rb, u32 rc) {
auto rs_i64 = GetGpr(rs);
auto rb_i64 = GetGpr(rb);
rb_i64 = m_ir_builder->CreateNot(rb_i64);
@ -3419,7 +3419,7 @@ void Compiler::STHUX(u32 rs, u32 ra, u32 rb) {
SetGpr(ra, addr_i64);
}
void Compiler::OR(u32 ra, u32 rs, u32 rb, bool rc) {
void Compiler::OR(u32 ra, u32 rs, u32 rb, u32 rc) {
auto rs_i64 = GetGpr(rs);
auto rb_i64 = GetGpr(rb);
auto res_i64 = m_ir_builder->CreateOr(rs_i64, rb_i64);
@ -3430,7 +3430,7 @@ void Compiler::OR(u32 ra, u32 rs, u32 rb, bool rc) {
}
}
void Compiler::DIVDU(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) {
void Compiler::DIVDU(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) {
auto ra_i64 = GetGpr(ra);
auto rb_i64 = GetGpr(rb);
auto res_i64 = m_ir_builder->CreateUDiv(ra_i64, rb_i64);
@ -3448,7 +3448,7 @@ void Compiler::DIVDU(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) {
// TODO make sure an exception does not occur on divide by 0 and overflow
}
void Compiler::DIVWU(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) {
void Compiler::DIVWU(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) {
auto ra_i32 = GetGpr(ra, 32);
auto rb_i32 = GetGpr(rb, 32);
auto res_i32 = m_ir_builder->CreateUDiv(ra_i32, rb_i32);
@ -3491,7 +3491,7 @@ void Compiler::MTSPR(u32 spr, u32 rs) {
}
void Compiler::NAND(u32 ra, u32 rs, u32 rb, bool rc) {
void Compiler::NAND(u32 ra, u32 rs, u32 rb, u32 rc) {
auto rs_i64 = GetGpr(rs);
auto rb_i64 = GetGpr(rb);
auto res_i64 = m_ir_builder->CreateAnd(rs_i64, rb_i64);
@ -3507,7 +3507,7 @@ void Compiler::STVXL(u32 vs, u32 ra, u32 rb) {
STVX(vs, ra, rb);
}
void Compiler::DIVD(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) {
void Compiler::DIVD(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) {
auto ra_i64 = GetGpr(ra);
auto rb_i64 = GetGpr(rb);
auto res_i64 = m_ir_builder->CreateSDiv(ra_i64, rb_i64);
@ -3525,7 +3525,7 @@ void Compiler::DIVD(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) {
// TODO make sure an exception does not occur on divide by 0 and overflow
}
void Compiler::DIVW(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) {
void Compiler::DIVW(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) {
auto ra_i32 = GetGpr(ra, 32);
auto rb_i32 = GetGpr(rb, 32);
auto res_i32 = m_ir_builder->CreateSDiv(ra_i32, rb_i32);
@ -3598,7 +3598,7 @@ void Compiler::LFSX(u32 frd, u32 ra, u32 rb) {
SetFpr(frd, mem_i32);
}
void Compiler::SRW(u32 ra, u32 rs, u32 rb, bool rc) {
void Compiler::SRW(u32 ra, u32 rs, u32 rb, u32 rc) {
auto rs_i32 = GetGpr(rs, 32);
auto rs_i64 = m_ir_builder->CreateZExt(rs_i32, m_ir_builder->getInt64Ty());
auto rb_i8 = GetGpr(rb, 8);
@ -3612,7 +3612,7 @@ void Compiler::SRW(u32 ra, u32 rs, u32 rb, bool rc) {
}
}
void Compiler::SRD(u32 ra, u32 rs, u32 rb, bool rc) {
void Compiler::SRD(u32 ra, u32 rs, u32 rb, u32 rc) {
auto rs_i64 = GetGpr(rs);
auto rs_i128 = m_ir_builder->CreateZExt(rs_i64, m_ir_builder->getIntNTy(128));
auto rb_i8 = GetGpr(rb, 8);
@ -3866,7 +3866,7 @@ void Compiler::LHBRX(u32 rd, u32 ra, u32 rb) {
SetGpr(rd, mem_i64);
}
void Compiler::SRAW(u32 ra, u32 rs, u32 rb, bool rc) {
void Compiler::SRAW(u32 ra, u32 rs, u32 rb, u32 rc) {
auto rs_i32 = GetGpr(rs, 32);
auto rs_i64 = m_ir_builder->CreateZExt(rs_i32, m_ir_builder->getInt64Ty());
rs_i64 = m_ir_builder->CreateShl(rs_i64, 32);
@ -3888,7 +3888,7 @@ void Compiler::SRAW(u32 ra, u32 rs, u32 rb, bool rc) {
}
}
void Compiler::SRAD(u32 ra, u32 rs, u32 rb, bool rc) {
void Compiler::SRAD(u32 ra, u32 rs, u32 rb, u32 rc) {
auto rs_i64 = GetGpr(rs);
auto rs_i128 = m_ir_builder->CreateZExt(rs_i64, m_ir_builder->getIntNTy(128));
rs_i128 = m_ir_builder->CreateShl(rs_i128, 64);
@ -3920,7 +3920,7 @@ void Compiler::DSS(u32 strm, u32 a) {
m_ir_builder->CreateCall(Intrinsic::getDeclaration(m_module, Intrinsic::donothing));
}
void Compiler::SRAWI(u32 ra, u32 rs, u32 sh, bool rc) {
void Compiler::SRAWI(u32 ra, u32 rs, u32 sh, u32 rc) {
auto rs_i32 = GetGpr(rs, 32);
auto rs_i64 = m_ir_builder->CreateZExt(rs_i32, m_ir_builder->getInt64Ty());
rs_i64 = m_ir_builder->CreateShl(rs_i64, 32);
@ -3939,7 +3939,7 @@ void Compiler::SRAWI(u32 ra, u32 rs, u32 sh, bool rc) {
}
}
void Compiler::SRADI1(u32 ra, u32 rs, u32 sh, bool rc) {
void Compiler::SRADI1(u32 ra, u32 rs, u32 sh, u32 rc) {
auto rs_i64 = GetGpr(rs);
auto rs_i128 = m_ir_builder->CreateZExt(rs_i64, m_ir_builder->getIntNTy(128));
rs_i128 = m_ir_builder->CreateShl(rs_i128, 64);
@ -3959,7 +3959,7 @@ void Compiler::SRADI1(u32 ra, u32 rs, u32 sh, bool rc) {
}
}
void Compiler::SRADI2(u32 ra, u32 rs, u32 sh, bool rc) {
void Compiler::SRADI2(u32 ra, u32 rs, u32 sh, u32 rc) {
SRADI1(ra, rs, sh, rc);
}
@ -3981,7 +3981,7 @@ void Compiler::STHBRX(u32 rs, u32 ra, u32 rb) {
WriteMemory(addr_i64, GetGpr(rs, 16), 0, false);
}
void Compiler::EXTSH(u32 ra, u32 rs, bool rc) {
void Compiler::EXTSH(u32 ra, u32 rs, u32 rc) {
auto rs_i16 = GetGpr(rs, 16);
auto rs_i64 = m_ir_builder->CreateSExt(rs_i16, m_ir_builder->getInt64Ty());
SetGpr(ra, rs_i64);
@ -3995,7 +3995,7 @@ void Compiler::STVRXL(u32 vs, u32 ra, u32 rb) {
STVRX(vs, ra, rb);
}
void Compiler::EXTSB(u32 ra, u32 rs, bool rc) {
void Compiler::EXTSB(u32 ra, u32 rs, u32 rc) {
auto rs_i8 = GetGpr(rs, 8);
auto rs_i64 = m_ir_builder->CreateSExt(rs_i8, m_ir_builder->getInt64Ty());
SetGpr(ra, rs_i64);
@ -4017,7 +4017,7 @@ void Compiler::STFIWX(u32 frs, u32 ra, u32 rb) {
WriteMemory(addr_i64, frs_i32);
}
void Compiler::EXTSW(u32 ra, u32 rs, bool rc) {
void Compiler::EXTSW(u32 ra, u32 rs, u32 rc) {
auto rs_i32 = GetGpr(rs, 32);
auto rs_i64 = m_ir_builder->CreateSExt(rs_i32, m_ir_builder->getInt64Ty());
SetGpr(ra, rs_i64);
@ -4340,7 +4340,7 @@ void Compiler::LWA(u32 rd, u32 ra, s32 ds) {
SetGpr(rd, mem_i64);
}
void Compiler::FDIVS(u32 frd, u32 fra, u32 frb, bool rc) {
void Compiler::FDIVS(u32 frd, u32 fra, u32 frb, u32 rc) {
auto ra_f64 = GetFpr(fra);
auto rb_f64 = GetFpr(frb);
auto res_f64 = m_ir_builder->CreateFDiv(ra_f64, rb_f64);
@ -4355,7 +4355,7 @@ void Compiler::FDIVS(u32 frd, u32 fra, u32 frb, bool rc) {
// TODO: Set flags
}
void Compiler::FSUBS(u32 frd, u32 fra, u32 frb, bool rc) {
void Compiler::FSUBS(u32 frd, u32 fra, u32 frb, u32 rc) {
auto ra_f64 = GetFpr(fra);
auto rb_f64 = GetFpr(frb);
auto res_f64 = m_ir_builder->CreateFSub(ra_f64, rb_f64);
@ -4370,7 +4370,7 @@ void Compiler::FSUBS(u32 frd, u32 fra, u32 frb, bool rc) {
// TODO: Set flags
}
void Compiler::FADDS(u32 frd, u32 fra, u32 frb, bool rc) {
void Compiler::FADDS(u32 frd, u32 fra, u32 frb, u32 rc) {
auto ra_f64 = GetFpr(fra);
auto rb_f64 = GetFpr(frb);
auto res_f64 = m_ir_builder->CreateFAdd(ra_f64, rb_f64);
@ -4385,7 +4385,7 @@ void Compiler::FADDS(u32 frd, u32 fra, u32 frb, bool rc) {
// TODO: Set flags
}
void Compiler::FSQRTS(u32 frd, u32 frb, bool rc) {
void Compiler::FSQRTS(u32 frd, u32 frb, u32 rc) {
auto rb_f64 = GetFpr(frb);
auto res_f64 = (Value *)m_ir_builder->CreateCall(Intrinsic::getDeclaration(m_module, Intrinsic::sqrt, m_ir_builder->getDoubleTy()), rb_f64);
auto res_f32 = m_ir_builder->CreateFPTrunc(res_f64, m_ir_builder->getFloatTy());
@ -4399,7 +4399,7 @@ void Compiler::FSQRTS(u32 frd, u32 frb, bool rc) {
// TODO: Set flags
}
void Compiler::FRES(u32 frd, u32 frb, bool rc) {
void Compiler::FRES(u32 frd, u32 frb, u32 rc) {
auto rb_f64 = GetFpr(frb);
auto res_f64 = m_ir_builder->CreateFDiv(ConstantFP::get(m_ir_builder->getDoubleTy(), 1.0), rb_f64);
auto res_f32 = m_ir_builder->CreateFPTrunc(res_f64, m_ir_builder->getFloatTy());
@ -4413,7 +4413,7 @@ void Compiler::FRES(u32 frd, u32 frb, bool rc) {
// TODO: Set flags
}
void Compiler::FMULS(u32 frd, u32 fra, u32 frc, bool rc) {
void Compiler::FMULS(u32 frd, u32 fra, u32 frc, u32 rc) {
auto ra_f64 = GetFpr(fra);
auto rc_f64 = GetFpr(frc);
auto res_f64 = m_ir_builder->CreateFMul(ra_f64, rc_f64);
@ -4428,7 +4428,7 @@ void Compiler::FMULS(u32 frd, u32 fra, u32 frc, bool rc) {
// TODO: Set flags
}
void Compiler::FMADDS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) {
void Compiler::FMADDS(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) {
auto ra_f64 = GetFpr(fra);
auto rb_f64 = GetFpr(frb);
auto rc_f64 = GetFpr(frc);
@ -4444,7 +4444,7 @@ void Compiler::FMADDS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) {
// TODO: Set flags
}
void Compiler::FMSUBS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) {
void Compiler::FMSUBS(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) {
auto ra_f64 = GetFpr(fra);
auto rb_f64 = GetFpr(frb);
auto rc_f64 = GetFpr(frc);
@ -4461,7 +4461,7 @@ void Compiler::FMSUBS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) {
// TODO: Set flags
}
void Compiler::FNMSUBS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) {
void Compiler::FNMSUBS(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) {
auto ra_f64 = GetFpr(fra);
auto rb_f64 = GetFpr(frb);
auto rc_f64 = GetFpr(frc);
@ -4479,7 +4479,7 @@ void Compiler::FNMSUBS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) {
// TODO: Set flags
}
void Compiler::FNMADDS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) {
void Compiler::FNMADDS(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) {
auto ra_f64 = GetFpr(fra);
auto rb_f64 = GetFpr(frb);
auto rc_f64 = GetFpr(frc);
@ -4515,7 +4515,7 @@ void Compiler::STDU(u32 rs, u32 ra, s32 ds) {
SetGpr(ra, addr_i64);
}
void Compiler::MTFSB1(u32 crbd, bool rc) {
void Compiler::MTFSB1(u32 crbd, u32 rc) {
auto fpscr_i32 = GetFpscr();
fpscr_i32 = SetBit(fpscr_i32, crbd, m_ir_builder->getInt32(1), false);
SetFpscr(fpscr_i32);
@ -4557,7 +4557,7 @@ void Compiler::MCRFS(u32 crbd, u32 crbs) {
SetFpscr(fpscr_i32);
}
void Compiler::MTFSB0(u32 crbd, bool rc) {
void Compiler::MTFSB0(u32 crbd, u32 rc) {
auto fpscr_i32 = GetFpscr();
fpscr_i32 = ClrBit(fpscr_i32, crbd);
SetFpscr(fpscr_i32);
@ -4568,7 +4568,7 @@ void Compiler::MTFSB0(u32 crbd, bool rc) {
}
}
void Compiler::MTFSFI(u32 crfd, u32 i, bool rc) {
void Compiler::MTFSFI(u32 crfd, u32 i, u32 rc) {
auto fpscr_i32 = GetFpscr();
fpscr_i32 = SetNibble(fpscr_i32, crfd, m_ir_builder->getInt32(i & 0xF));
SetFpscr(fpscr_i32);
@ -4579,7 +4579,7 @@ void Compiler::MTFSFI(u32 crfd, u32 i, bool rc) {
}
}
void Compiler::MFFS(u32 frd, bool rc) {
void Compiler::MFFS(u32 frd, u32 rc) {
auto fpscr_i32 = GetFpscr();
auto fpscr_i64 = m_ir_builder->CreateZExt(fpscr_i32, m_ir_builder->getInt64Ty());
SetFpr(frd, fpscr_i64);
@ -4590,7 +4590,7 @@ void Compiler::MFFS(u32 frd, bool rc) {
}
}
void Compiler::MTFSF(u32 flm, u32 frb, bool rc) {
void Compiler::MTFSF(u32 flm, u32 frb, u32 rc) {
u32 mask = 0;
for(u32 i = 0; i < 8; i++) {
if (flm & (1 << i)) {
@ -4624,7 +4624,7 @@ void Compiler::FCMPU(u32 crfd, u32 fra, u32 frb) {
// TODO: Set flags / Handle NaN
}
void Compiler::FRSP(u32 frd, u32 frb, bool rc) {
void Compiler::FRSP(u32 frd, u32 frb, u32 rc) {
auto rb_f64 = GetFpr(frb);
auto res_f32 = m_ir_builder->CreateFPTrunc(rb_f64, m_ir_builder->getFloatTy());
auto res_f64 = m_ir_builder->CreateFPExt(res_f32, m_ir_builder->getDoubleTy());
@ -4639,7 +4639,7 @@ void Compiler::FRSP(u32 frd, u32 frb, bool rc) {
// TODO: Set flags
}
void Compiler::FCTIW(u32 frd, u32 frb, bool rc) {
void Compiler::FCTIW(u32 frd, u32 frb, u32 rc) {
auto rb_f64 = GetFpr(frb);
auto max_i1 = m_ir_builder->CreateFCmpOGT(rb_f64, ConstantFP::get(m_ir_builder->getDoubleTy(), 2147483647.0));
auto min_i1 = m_ir_builder->CreateFCmpULT(rb_f64, ConstantFP::get(m_ir_builder->getDoubleTy(), -2147483648.0));
@ -4657,7 +4657,7 @@ void Compiler::FCTIW(u32 frd, u32 frb, bool rc) {
// TODO: Set flags / Implement rounding modes
}
void Compiler::FCTIWZ(u32 frd, u32 frb, bool rc) {
void Compiler::FCTIWZ(u32 frd, u32 frb, u32 rc) {
auto rb_f64 = GetFpr(frb);
auto max_i1 = m_ir_builder->CreateFCmpOGT(rb_f64, ConstantFP::get(m_ir_builder->getDoubleTy(), 2147483647.0));
auto min_i1 = m_ir_builder->CreateFCmpULT(rb_f64, ConstantFP::get(m_ir_builder->getDoubleTy(), -2147483648.0));
@ -4675,7 +4675,7 @@ void Compiler::FCTIWZ(u32 frd, u32 frb, bool rc) {
// TODO: Set flags
}
void Compiler::FDIV(u32 frd, u32 fra, u32 frb, bool rc) {
void Compiler::FDIV(u32 frd, u32 fra, u32 frb, u32 rc) {
auto ra_f64 = GetFpr(fra);
auto rb_f64 = GetFpr(frb);
auto res_f64 = m_ir_builder->CreateFDiv(ra_f64, rb_f64);
@ -4689,7 +4689,7 @@ void Compiler::FDIV(u32 frd, u32 fra, u32 frb, bool rc) {
// TODO: Set flags
}
void Compiler::FSUB(u32 frd, u32 fra, u32 frb, bool rc) {
void Compiler::FSUB(u32 frd, u32 fra, u32 frb, u32 rc) {
auto ra_f64 = GetFpr(fra);
auto rb_f64 = GetFpr(frb);
auto res_f64 = m_ir_builder->CreateFSub(ra_f64, rb_f64);
@ -4703,7 +4703,7 @@ void Compiler::FSUB(u32 frd, u32 fra, u32 frb, bool rc) {
// TODO: Set flags
}
void Compiler::FADD(u32 frd, u32 fra, u32 frb, bool rc) {
void Compiler::FADD(u32 frd, u32 fra, u32 frb, u32 rc) {
auto ra_f64 = GetFpr(fra);
auto rb_f64 = GetFpr(frb);
auto res_f64 = m_ir_builder->CreateFAdd(ra_f64, rb_f64);
@ -4717,7 +4717,7 @@ void Compiler::FADD(u32 frd, u32 fra, u32 frb, bool rc) {
// TODO: Set flags
}
void Compiler::FSQRT(u32 frd, u32 frb, bool rc) {
void Compiler::FSQRT(u32 frd, u32 frb, u32 rc) {
auto rb_f64 = GetFpr(frb);
auto res_f64 = (Value *)m_ir_builder->CreateCall(Intrinsic::getDeclaration(m_module, Intrinsic::sqrt, m_ir_builder->getDoubleTy()), rb_f64);
SetFpr(frd, res_f64);
@ -4730,7 +4730,7 @@ void Compiler::FSQRT(u32 frd, u32 frb, bool rc) {
// TODO: Set flags
}
void Compiler::FSEL(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) {
void Compiler::FSEL(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) {
auto ra_f64 = GetFpr(fra);
auto rb_f64 = GetFpr(frb);
auto rc_f64 = GetFpr(frc);
@ -4746,7 +4746,7 @@ void Compiler::FSEL(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) {
// TODO: Set flags
}
void Compiler::FMUL(u32 frd, u32 fra, u32 frc, bool rc) {
void Compiler::FMUL(u32 frd, u32 fra, u32 frc, u32 rc) {
auto ra_f64 = GetFpr(fra);
auto rc_f64 = GetFpr(frc);
auto res_f64 = m_ir_builder->CreateFMul(ra_f64, rc_f64);
@ -4760,7 +4760,7 @@ void Compiler::FMUL(u32 frd, u32 fra, u32 frc, bool rc) {
// TODO: Set flags
}
void Compiler::FRSQRTE(u32 frd, u32 frb, bool rc) {
void Compiler::FRSQRTE(u32 frd, u32 frb, u32 rc) {
auto rb_f64 = GetFpr(frb);
auto res_f64 = (Value *)m_ir_builder->CreateCall(Intrinsic::getDeclaration(m_module, Intrinsic::sqrt, m_ir_builder->getDoubleTy()), rb_f64);
res_f64 = m_ir_builder->CreateFDiv(ConstantFP::get(m_ir_builder->getDoubleTy(), 1.0), res_f64);
@ -4772,7 +4772,7 @@ void Compiler::FRSQRTE(u32 frd, u32 frb, bool rc) {
}
}
void Compiler::FMSUB(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) {
void Compiler::FMSUB(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) {
auto ra_f64 = GetFpr(fra);
auto rb_f64 = GetFpr(frb);
auto rc_f64 = GetFpr(frc);
@ -4788,7 +4788,7 @@ void Compiler::FMSUB(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) {
// TODO: Set flags
}
void Compiler::FMADD(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) {
void Compiler::FMADD(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) {
auto ra_f64 = GetFpr(fra);
auto rb_f64 = GetFpr(frb);
auto rc_f64 = GetFpr(frc);
@ -4803,7 +4803,7 @@ void Compiler::FMADD(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) {
// TODO: Set flags
}
void Compiler::FNMSUB(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) {
void Compiler::FNMSUB(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) {
auto ra_f64 = GetFpr(fra);
auto rb_f64 = GetFpr(frb);
auto rc_f64 = GetFpr(frc);
@ -4819,7 +4819,7 @@ void Compiler::FNMSUB(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) {
// TODO: Set flags
}
void Compiler::FNMADD(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) {
void Compiler::FNMADD(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) {
auto ra_f64 = GetFpr(fra);
auto rb_f64 = GetFpr(frb);
auto rc_f64 = GetFpr(frc);
@ -4849,7 +4849,7 @@ void Compiler::FCMPO(u32 crfd, u32 fra, u32 frb) {
// TODO: Set flags / Handle NaN
}
void Compiler::FNEG(u32 frd, u32 frb, bool rc) {
void Compiler::FNEG(u32 frd, u32 frb, u32 rc) {
auto rb_f64 = GetFpr(frb);
rb_f64 = m_ir_builder->CreateFNeg(rb_f64);
SetFpr(frd, rb_f64);
@ -4862,7 +4862,7 @@ void Compiler::FNEG(u32 frd, u32 frb, bool rc) {
// TODO: Set flags
}
void Compiler::FMR(u32 frd, u32 frb, bool rc) {
void Compiler::FMR(u32 frd, u32 frb, u32 rc) {
SetFpr(frd, GetFpr(frb));
if (rc) {
@ -4873,7 +4873,7 @@ void Compiler::FMR(u32 frd, u32 frb, bool rc) {
// TODO: Set flags
}
void Compiler::FNABS(u32 frd, u32 frb, bool rc) {
void Compiler::FNABS(u32 frd, u32 frb, u32 rc) {
auto rb_f64 = GetFpr(frb);
auto res_f64 = (Value *)m_ir_builder->CreateCall(Intrinsic::getDeclaration(m_module, Intrinsic::fabs, m_ir_builder->getDoubleTy()), rb_f64);
res_f64 = m_ir_builder->CreateFNeg(res_f64);
@ -4887,7 +4887,7 @@ void Compiler::FNABS(u32 frd, u32 frb, bool rc) {
// TODO: Set flags
}
void Compiler::FABS(u32 frd, u32 frb, bool rc) {
void Compiler::FABS(u32 frd, u32 frb, u32 rc) {
auto rb_f64 = GetFpr(frb);
auto res_f64 = (Value *)m_ir_builder->CreateCall(Intrinsic::getDeclaration(m_module, Intrinsic::fabs, m_ir_builder->getDoubleTy()), rb_f64);
SetFpr(frd, res_f64);
@ -4900,7 +4900,7 @@ void Compiler::FABS(u32 frd, u32 frb, bool rc) {
// TODO: Set flags
}
void Compiler::FCTID(u32 frd, u32 frb, bool rc) {
void Compiler::FCTID(u32 frd, u32 frb, u32 rc) {
auto rb_f64 = GetFpr(frb);
auto max_i1 = m_ir_builder->CreateFCmpOGT(rb_f64, ConstantFP::get(m_ir_builder->getDoubleTy(), 9223372036854775807.0));
auto min_i1 = m_ir_builder->CreateFCmpULT(rb_f64, ConstantFP::get(m_ir_builder->getDoubleTy(), -9223372036854775808.0));
@ -4917,7 +4917,7 @@ void Compiler::FCTID(u32 frd, u32 frb, bool rc) {
// TODO: Set flags / Implement rounding modes
}
void Compiler::FCTIDZ(u32 frd, u32 frb, bool rc) {
void Compiler::FCTIDZ(u32 frd, u32 frb, u32 rc) {
auto rb_f64 = GetFpr(frb);
auto max_i1 = m_ir_builder->CreateFCmpOGT(rb_f64, ConstantFP::get(m_ir_builder->getDoubleTy(), 9223372036854775807.0));
auto min_i1 = m_ir_builder->CreateFCmpULT(rb_f64, ConstantFP::get(m_ir_builder->getDoubleTy(), -9223372036854775808.0));
@ -4934,7 +4934,7 @@ void Compiler::FCTIDZ(u32 frd, u32 frb, bool rc) {
// TODO: Set flags
}
void Compiler::FCFID(u32 frd, u32 frb, bool rc) {
void Compiler::FCFID(u32 frd, u32 frb, u32 rc) {
auto rb_i64 = GetFpr(frb, 64, true);
auto res_f64 = m_ir_builder->CreateSIToFP(rb_i64, m_ir_builder->getDoubleTy());
SetFpr(frd, res_f64);
@ -5603,7 +5603,6 @@ RecompilationEngine::RecompilationEngine()
}
RecompilationEngine::~RecompilationEngine() {
cv.notify_one();
join();
}

View File

@ -486,59 +486,59 @@ namespace ppu_recompiler_llvm {
void CRORC(u32 bt, u32 ba, u32 bb) override;
void CROR(u32 bt, u32 ba, u32 bb) override;
void BCCTR(u32 bo, u32 bi, u32 bh, u32 lk) override;
void RLWIMI(u32 ra, u32 rs, u32 sh, u32 mb, u32 me, bool rc) override;
void RLWINM(u32 ra, u32 rs, u32 sh, u32 mb, u32 me, bool rc) override;
void RLWNM(u32 ra, u32 rs, u32 rb, u32 MB, u32 ME, bool rc) override;
void RLWIMI(u32 ra, u32 rs, u32 sh, u32 mb, u32 me, u32 rc) override;
void RLWINM(u32 ra, u32 rs, u32 sh, u32 mb, u32 me, u32 rc) override;
void RLWNM(u32 ra, u32 rs, u32 rb, u32 MB, u32 ME, u32 rc) override;
void ORI(u32 rs, u32 ra, u32 uimm16) override;
void ORIS(u32 rs, u32 ra, u32 uimm16) override;
void XORI(u32 ra, u32 rs, u32 uimm16) override;
void XORIS(u32 ra, u32 rs, u32 uimm16) override;
void ANDI_(u32 ra, u32 rs, u32 uimm16) override;
void ANDIS_(u32 ra, u32 rs, u32 uimm16) override;
void RLDICL(u32 ra, u32 rs, u32 sh, u32 mb, bool rc) override;
void RLDICR(u32 ra, u32 rs, u32 sh, u32 me, bool rc) override;
void RLDIC(u32 ra, u32 rs, u32 sh, u32 mb, bool rc) override;
void RLDIMI(u32 ra, u32 rs, u32 sh, u32 mb, bool rc) override;
void RLDC_LR(u32 ra, u32 rs, u32 rb, u32 m_eb, bool is_r, bool rc) override;
void RLDICL(u32 ra, u32 rs, u32 sh, u32 mb, u32 rc) override;
void RLDICR(u32 ra, u32 rs, u32 sh, u32 me, u32 rc) override;
void RLDIC(u32 ra, u32 rs, u32 sh, u32 mb, u32 rc) override;
void RLDIMI(u32 ra, u32 rs, u32 sh, u32 mb, u32 rc) override;
void RLDC_LR(u32 ra, u32 rs, u32 rb, u32 m_eb, u32 is_r, u32 rc) override;
void CMP(u32 crfd, u32 l, u32 ra, u32 rb) override;
void TW(u32 to, u32 ra, u32 rb) override;
void LVSL(u32 vd, u32 ra, u32 rb) override;
void LVEBX(u32 vd, u32 ra, u32 rb) override;
void SUBFC(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) override;
void MULHDU(u32 rd, u32 ra, u32 rb, bool rc) override;
void ADDC(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) override;
void MULHWU(u32 rd, u32 ra, u32 rb, bool rc) override;
void SUBFC(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) override;
void MULHDU(u32 rd, u32 ra, u32 rb, u32 rc) override;
void ADDC(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) override;
void MULHWU(u32 rd, u32 ra, u32 rb, u32 rc) override;
void MFOCRF(u32 a, u32 rd, u32 crm) override;
void LWARX(u32 rd, u32 ra, u32 rb) override;
void LDX(u32 ra, u32 rs, u32 rb) override;
void LWZX(u32 rd, u32 ra, u32 rb) override;
void SLW(u32 ra, u32 rs, u32 rb, bool rc) override;
void CNTLZW(u32 ra, u32 rs, bool rc) override;
void SLD(u32 ra, u32 rs, u32 rb, bool rc) override;
void AND(u32 ra, u32 rs, u32 rb, bool rc) override;
void SLW(u32 ra, u32 rs, u32 rb, u32 rc) override;
void CNTLZW(u32 ra, u32 rs, u32 rc) override;
void SLD(u32 ra, u32 rs, u32 rb, u32 rc) override;
void AND(u32 ra, u32 rs, u32 rb, u32 rc) override;
void CMPL(u32 bf, u32 l, u32 ra, u32 rb) override;
void LVSR(u32 vd, u32 ra, u32 rb) override;
void LVEHX(u32 vd, u32 ra, u32 rb) override;
void SUBF(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) override;
void SUBF(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) override;
void LDUX(u32 rd, u32 ra, u32 rb) override;
void DCBST(u32 ra, u32 rb) override;
void LWZUX(u32 rd, u32 ra, u32 rb) override;
void CNTLZD(u32 ra, u32 rs, bool rc) override;
void ANDC(u32 ra, u32 rs, u32 rb, bool rc) override;
void CNTLZD(u32 ra, u32 rs, u32 rc) override;
void ANDC(u32 ra, u32 rs, u32 rb, u32 rc) override;
void TD(u32 to, u32 ra, u32 rb) override;
void LVEWX(u32 vd, u32 ra, u32 rb) override;
void MULHD(u32 rd, u32 ra, u32 rb, bool rc) override;
void MULHW(u32 rd, u32 ra, u32 rb, bool rc) override;
void MULHD(u32 rd, u32 ra, u32 rb, u32 rc) override;
void MULHW(u32 rd, u32 ra, u32 rb, u32 rc) override;
void LDARX(u32 rd, u32 ra, u32 rb) override;
void DCBF(u32 ra, u32 rb) override;
void LBZX(u32 rd, u32 ra, u32 rb) override;
void LVX(u32 vd, u32 ra, u32 rb) override;
void NEG(u32 rd, u32 ra, u32 oe, bool rc) override;
void NEG(u32 rd, u32 ra, u32 oe, u32 rc) override;
void LBZUX(u32 rd, u32 ra, u32 rb) override;
void NOR(u32 ra, u32 rs, u32 rb, bool rc) override;
void NOR(u32 ra, u32 rs, u32 rb, u32 rc) override;
void STVEBX(u32 vs, u32 ra, u32 rb) override;
void SUBFE(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) override;
void ADDE(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) override;
void SUBFE(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) override;
void ADDE(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) override;
void MTOCRF(u32 l, u32 crm, u32 rs) override;
void STDX(u32 rs, u32 ra, u32 rb) override;
void STWCX_(u32 rs, u32 ra, u32 rb) override;
@ -547,24 +547,24 @@ namespace ppu_recompiler_llvm {
void STDUX(u32 rs, u32 ra, u32 rb) override;
void STWUX(u32 rs, u32 ra, u32 rb) override;
void STVEWX(u32 vs, u32 ra, u32 rb) override;
void SUBFZE(u32 rd, u32 ra, u32 oe, bool rc) override;
void ADDZE(u32 rd, u32 ra, u32 oe, bool rc) override;
void SUBFZE(u32 rd, u32 ra, u32 oe, u32 rc) override;
void ADDZE(u32 rd, u32 ra, u32 oe, u32 rc) override;
void STDCX_(u32 rs, u32 ra, u32 rb) override;
void STBX(u32 rs, u32 ra, u32 rb) override;
void STVX(u32 vs, u32 ra, u32 rb) override;
void MULLD(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) override;
void SUBFME(u32 rd, u32 ra, u32 oe, bool rc) override;
void ADDME(u32 rd, u32 ra, u32 oe, bool rc) override;
void MULLW(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) override;
void MULLD(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) override;
void SUBFME(u32 rd, u32 ra, u32 oe, u32 rc) override;
void ADDME(u32 rd, u32 ra, u32 oe, u32 rc) override;
void MULLW(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) override;
void DCBTST(u32 ra, u32 rb, u32 th) override;
void STBUX(u32 rs, u32 ra, u32 rb) override;
void ADD(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) override;
void ADD(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) override;
void DCBT(u32 ra, u32 rb, u32 th) override;
void LHZX(u32 rd, u32 ra, u32 rb) override;
void EQV(u32 ra, u32 rs, u32 rb, bool rc) override;
void EQV(u32 ra, u32 rs, u32 rb, u32 rc) override;
void ECIWX(u32 rd, u32 ra, u32 rb) override;
void LHZUX(u32 rd, u32 ra, u32 rb) override;
void XOR(u32 rs, u32 ra, u32 rb, bool rc) override;
void XOR(u32 rs, u32 ra, u32 rb, u32 rc) override;
void MFSPR(u32 rd, u32 spr) override;
void LWAX(u32 rd, u32 ra, u32 rb) override;
void DST(u32 ra, u32 rb, u32 strm, u32 t) override;
@ -575,25 +575,25 @@ namespace ppu_recompiler_llvm {
void DSTST(u32 ra, u32 rb, u32 strm, u32 t) override;
void LHAUX(u32 rd, u32 ra, u32 rb) override;
void STHX(u32 rs, u32 ra, u32 rb) override;
void ORC(u32 rs, u32 ra, u32 rb, bool rc) override;
void ORC(u32 rs, u32 ra, u32 rb, u32 rc) override;
void ECOWX(u32 rs, u32 ra, u32 rb) override;
void STHUX(u32 rs, u32 ra, u32 rb) override;
void OR(u32 ra, u32 rs, u32 rb, bool rc) override;
void DIVDU(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) override;
void DIVWU(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) override;
void OR(u32 ra, u32 rs, u32 rb, u32 rc) override;
void DIVDU(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) override;
void DIVWU(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) override;
void MTSPR(u32 spr, u32 rs) override;
void DCBI(u32 ra, u32 rb) override;
void NAND(u32 ra, u32 rs, u32 rb, bool rc) override;
void NAND(u32 ra, u32 rs, u32 rb, u32 rc) override;
void STVXL(u32 vs, u32 ra, u32 rb) override;
void DIVD(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) override;
void DIVW(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) override;
void DIVD(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) override;
void DIVW(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) override;
void LVLX(u32 vd, u32 ra, u32 rb) override;
void LDBRX(u32 rd, u32 ra, u32 rb) override;
void LSWX(u32 rd, u32 ra, u32 rb) override;
void LWBRX(u32 rd, u32 ra, u32 rb) override;
void LFSX(u32 frd, u32 ra, u32 rb) override;
void SRW(u32 ra, u32 rs, u32 rb, bool rc) override;
void SRD(u32 ra, u32 rs, u32 rb, bool rc) override;
void SRW(u32 ra, u32 rs, u32 rb, u32 rc) override;
void SRD(u32 ra, u32 rs, u32 rb, u32 rc) override;
void LVRX(u32 vd, u32 ra, u32 rb) override;
void LSWI(u32 rd, u32 ra, u32 nb) override;
void LFSUX(u32 frd, u32 ra, u32 rb) override;
@ -612,21 +612,21 @@ namespace ppu_recompiler_llvm {
void STFDUX(u32 frs, u32 ra, u32 rb) override;
void LVLXL(u32 vd, u32 ra, u32 rb) override;
void LHBRX(u32 rd, u32 ra, u32 rb) override;
void SRAW(u32 ra, u32 rs, u32 rb, bool rc) override;
void SRAD(u32 ra, u32 rs, u32 rb, bool rc) override;
void SRAW(u32 ra, u32 rs, u32 rb, u32 rc) override;
void SRAD(u32 ra, u32 rs, u32 rb, u32 rc) override;
void LVRXL(u32 vd, u32 ra, u32 rb) override;
void DSS(u32 strm, u32 a) override;
void SRAWI(u32 ra, u32 rs, u32 sh, bool rc) override;
void SRADI1(u32 ra, u32 rs, u32 sh, bool rc) override;
void SRADI2(u32 ra, u32 rs, u32 sh, bool rc) override;
void SRAWI(u32 ra, u32 rs, u32 sh, u32 rc) override;
void SRADI1(u32 ra, u32 rs, u32 sh, u32 rc) override;
void SRADI2(u32 ra, u32 rs, u32 sh, u32 rc) override;
void EIEIO() override;
void STVLXL(u32 vs, u32 ra, u32 rb) override;
void STHBRX(u32 rs, u32 ra, u32 rb) override;
void EXTSH(u32 ra, u32 rs, bool rc) override;
void EXTSH(u32 ra, u32 rs, u32 rc) override;
void STVRXL(u32 sd, u32 ra, u32 rb) override;
void EXTSB(u32 ra, u32 rs, bool rc) override;
void EXTSB(u32 ra, u32 rs, u32 rc) override;
void STFIWX(u32 frs, u32 ra, u32 rb) override;
void EXTSW(u32 ra, u32 rs, bool rc) override;
void EXTSW(u32 ra, u32 rs, u32 rc) override;
void ICBI(u32 ra, u32 rb) override;
void DCBZ(u32 ra, u32 rb) override;
void LWZ(u32 rd, u32 ra, s32 d) override;
@ -656,48 +656,48 @@ namespace ppu_recompiler_llvm {
void LD(u32 rd, u32 ra, s32 ds) override;
void LDU(u32 rd, u32 ra, s32 ds) override;
void LWA(u32 rd, u32 ra, s32 ds) override;
void FDIVS(u32 frd, u32 fra, u32 frb, bool rc) override;
void FSUBS(u32 frd, u32 fra, u32 frb, bool rc) override;
void FADDS(u32 frd, u32 fra, u32 frb, bool rc) override;
void FSQRTS(u32 frd, u32 frb, bool rc) override;
void FRES(u32 frd, u32 frb, bool rc) override;
void FMULS(u32 frd, u32 fra, u32 frc, bool rc) override;
void FMADDS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) override;
void FMSUBS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) override;
void FNMSUBS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) override;
void FNMADDS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) override;
void FDIVS(u32 frd, u32 fra, u32 frb, u32 rc) override;
void FSUBS(u32 frd, u32 fra, u32 frb, u32 rc) override;
void FADDS(u32 frd, u32 fra, u32 frb, u32 rc) override;
void FSQRTS(u32 frd, u32 frb, u32 rc) override;
void FRES(u32 frd, u32 frb, u32 rc) override;
void FMULS(u32 frd, u32 fra, u32 frc, u32 rc) override;
void FMADDS(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) override;
void FMSUBS(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) override;
void FNMSUBS(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) override;
void FNMADDS(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) override;
void STD(u32 rs, u32 ra, s32 ds) override;
void STDU(u32 rs, u32 ra, s32 ds) override;
void MTFSB1(u32 bt, bool rc) override;
void MTFSB1(u32 bt, u32 rc) override;
void MCRFS(u32 bf, u32 bfa) override;
void MTFSB0(u32 bt, bool rc) override;
void MTFSFI(u32 crfd, u32 i, bool rc) override;
void MFFS(u32 frd, bool rc) override;
void MTFSF(u32 flm, u32 frb, bool rc) override;
void MTFSB0(u32 bt, u32 rc) override;
void MTFSFI(u32 crfd, u32 i, u32 rc) override;
void MFFS(u32 frd, u32 rc) override;
void MTFSF(u32 flm, u32 frb, u32 rc) override;
void FCMPU(u32 bf, u32 fra, u32 frb) override;
void FRSP(u32 frd, u32 frb, bool rc) override;
void FCTIW(u32 frd, u32 frb, bool rc) override;
void FCTIWZ(u32 frd, u32 frb, bool rc) override;
void FDIV(u32 frd, u32 fra, u32 frb, bool rc) override;
void FSUB(u32 frd, u32 fra, u32 frb, bool rc) override;
void FADD(u32 frd, u32 fra, u32 frb, bool rc) override;
void FSQRT(u32 frd, u32 frb, bool rc) override;
void FSEL(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) override;
void FMUL(u32 frd, u32 fra, u32 frc, bool rc) override;
void FRSQRTE(u32 frd, u32 frb, bool rc) override;
void FMSUB(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) override;
void FMADD(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) override;
void FNMSUB(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) override;
void FNMADD(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) override;
void FRSP(u32 frd, u32 frb, u32 rc) override;
void FCTIW(u32 frd, u32 frb, u32 rc) override;
void FCTIWZ(u32 frd, u32 frb, u32 rc) override;
void FDIV(u32 frd, u32 fra, u32 frb, u32 rc) override;
void FSUB(u32 frd, u32 fra, u32 frb, u32 rc) override;
void FADD(u32 frd, u32 fra, u32 frb, u32 rc) override;
void FSQRT(u32 frd, u32 frb, u32 rc) override;
void FSEL(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) override;
void FMUL(u32 frd, u32 fra, u32 frc, u32 rc) override;
void FRSQRTE(u32 frd, u32 frb, u32 rc) override;
void FMSUB(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) override;
void FMADD(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) override;
void FNMSUB(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) override;
void FNMADD(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) override;
void FCMPO(u32 crfd, u32 fra, u32 frb) override;
void FNEG(u32 frd, u32 frb, bool rc) override;
void FMR(u32 frd, u32 frb, bool rc) override;
void FNABS(u32 frd, u32 frb, bool rc) override;
void FABS(u32 frd, u32 frb, bool rc) override;
void FCTID(u32 frd, u32 frb, bool rc) override;
void FCTIDZ(u32 frd, u32 frb, bool rc) override;
void FCFID(u32 frd, u32 frb, bool rc) override;
void FNEG(u32 frd, u32 frb, u32 rc) override;
void FMR(u32 frd, u32 frb, u32 rc) override;
void FNABS(u32 frd, u32 frb, u32 rc) override;
void FABS(u32 frd, u32 frb, u32 rc) override;
void FCTID(u32 frd, u32 frb, u32 rc) override;
void FCTIDZ(u32 frd, u32 frb, u32 rc) override;
void FCFID(u32 frd, u32 frb, u32 rc) override;
void UNK(const u32 code, const u32 opcode, const u32 gcode) override;

View File

@ -664,59 +664,59 @@ public:
virtual void CRORC(u32 bt, u32 ba, u32 bb) = 0;
virtual void CROR(u32 bt, u32 ba, u32 bb) = 0;
virtual void BCCTR(u32 bo, u32 bi, u32 bh, u32 lk) = 0;
virtual void RLWIMI(u32 ra, u32 rs, u32 sh, u32 mb, u32 me, bool rc) = 0;
virtual void RLWINM(u32 ra, u32 rs, u32 sh, u32 mb, u32 me, bool rc) = 0;
virtual void RLWNM(u32 ra, u32 rs, u32 rb, u32 MB, u32 ME, bool rc) = 0;
virtual void RLWIMI(u32 ra, u32 rs, u32 sh, u32 mb, u32 me, u32 rc) = 0;
virtual void RLWINM(u32 ra, u32 rs, u32 sh, u32 mb, u32 me, u32 rc) = 0;
virtual void RLWNM(u32 ra, u32 rs, u32 rb, u32 MB, u32 ME, u32 rc) = 0;
virtual void ORI(u32 rs, u32 ra, u32 uimm16) = 0;
virtual void ORIS(u32 rs, u32 ra, u32 uimm16) = 0;
virtual void XORI(u32 ra, u32 rs, u32 uimm16) = 0;
virtual void XORIS(u32 ra, u32 rs, u32 uimm16) = 0;
virtual void ANDI_(u32 ra, u32 rs, u32 uimm16) = 0;
virtual void ANDIS_(u32 ra, u32 rs, u32 uimm16) = 0;
virtual void RLDICL(u32 ra, u32 rs, u32 sh, u32 mb, bool rc) = 0;
virtual void RLDICR(u32 ra, u32 rs, u32 sh, u32 me, bool rc) = 0;
virtual void RLDIC(u32 ra, u32 rs, u32 sh, u32 mb, bool rc) = 0;
virtual void RLDIMI(u32 ra, u32 rs, u32 sh, u32 mb, bool rc) = 0;
virtual void RLDC_LR(u32 ra, u32 rs, u32 rb, u32 m_eb, bool is_r, bool rc) = 0;
virtual void RLDICL(u32 ra, u32 rs, u32 sh, u32 mb, u32 rc) = 0;
virtual void RLDICR(u32 ra, u32 rs, u32 sh, u32 me, u32 rc) = 0;
virtual void RLDIC(u32 ra, u32 rs, u32 sh, u32 mb, u32 rc) = 0;
virtual void RLDIMI(u32 ra, u32 rs, u32 sh, u32 mb, u32 rc) = 0;
virtual void RLDC_LR(u32 ra, u32 rs, u32 rb, u32 m_eb, u32 is_r, u32 rc) = 0;
virtual void CMP(u32 crfd, u32 l, u32 ra, u32 rb) = 0;
virtual void TW(u32 to, u32 ra, u32 rb) = 0;
virtual void LVSL(u32 vd, u32 ra, u32 rb) = 0;
virtual void LVEBX(u32 vd, u32 ra, u32 rb) = 0;
virtual void SUBFC(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) = 0;
virtual void MULHDU(u32 rd, u32 ra, u32 rb, bool rc) = 0;
virtual void ADDC(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) = 0;
virtual void MULHWU(u32 rd, u32 ra, u32 rb, bool rc) = 0;
virtual void SUBFC(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) = 0;
virtual void MULHDU(u32 rd, u32 ra, u32 rb, u32 rc) = 0;
virtual void ADDC(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) = 0;
virtual void MULHWU(u32 rd, u32 ra, u32 rb, u32 rc) = 0;
virtual void MFOCRF(u32 a, u32 rd, u32 crm) = 0;
virtual void LWARX(u32 rd, u32 ra, u32 rb) = 0;
virtual void LDX(u32 ra, u32 rs, u32 rb) = 0;
virtual void LWZX(u32 rd, u32 ra, u32 rb) = 0;
virtual void SLW(u32 ra, u32 rs, u32 rb, bool rc) = 0;
virtual void CNTLZW(u32 ra, u32 rs, bool rc) = 0;
virtual void SLD(u32 ra, u32 rs, u32 rb, bool rc) = 0;
virtual void AND(u32 ra, u32 rs, u32 rb, bool rc) = 0;
virtual void SLW(u32 ra, u32 rs, u32 rb, u32 rc) = 0;
virtual void CNTLZW(u32 ra, u32 rs, u32 rc) = 0;
virtual void SLD(u32 ra, u32 rs, u32 rb, u32 rc) = 0;
virtual void AND(u32 ra, u32 rs, u32 rb, u32 rc) = 0;
virtual void CMPL(u32 bf, u32 l, u32 ra, u32 rb) = 0;
virtual void LVSR(u32 vd, u32 ra, u32 rb) = 0;
virtual void LVEHX(u32 vd, u32 ra, u32 rb) = 0;
virtual void SUBF(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) = 0;
virtual void SUBF(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) = 0;
virtual void LDUX(u32 rd, u32 ra, u32 rb) = 0;
virtual void DCBST(u32 ra, u32 rb) = 0;
virtual void LWZUX(u32 rd, u32 ra, u32 rb) = 0;
virtual void CNTLZD(u32 ra, u32 rs, bool rc) = 0;
virtual void ANDC(u32 ra, u32 rs, u32 rb, bool rc) = 0;
virtual void CNTLZD(u32 ra, u32 rs, u32 rc) = 0;
virtual void ANDC(u32 ra, u32 rs, u32 rb, u32 rc) = 0;
virtual void TD(u32 to, u32 ra, u32 rb) = 0;
virtual void LVEWX(u32 vd, u32 ra, u32 rb) = 0;
virtual void MULHD(u32 rd, u32 ra, u32 rb, bool rc) = 0;
virtual void MULHW(u32 rd, u32 ra, u32 rb, bool rc) = 0;
virtual void MULHD(u32 rd, u32 ra, u32 rb, u32 rc) = 0;
virtual void MULHW(u32 rd, u32 ra, u32 rb, u32 rc) = 0;
virtual void LDARX(u32 rd, u32 ra, u32 rb) = 0;
virtual void DCBF(u32 ra, u32 rb) = 0;
virtual void LBZX(u32 rd, u32 ra, u32 rb) = 0;
virtual void LVX(u32 vd, u32 ra, u32 rb) = 0;
virtual void NEG(u32 rd, u32 ra, u32 oe, bool rc) = 0;
virtual void NEG(u32 rd, u32 ra, u32 oe, u32 rc) = 0;
virtual void LBZUX(u32 rd, u32 ra, u32 rb) = 0;
virtual void NOR(u32 ra, u32 rs, u32 rb, bool rc) = 0;
virtual void NOR(u32 ra, u32 rs, u32 rb, u32 rc) = 0;
virtual void STVEBX(u32 vs, u32 ra, u32 rb) = 0;
virtual void SUBFE(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) = 0;
virtual void ADDE(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) = 0;
virtual void SUBFE(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) = 0;
virtual void ADDE(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) = 0;
virtual void MTOCRF(u32 l, u32 crm, u32 rs) = 0;
virtual void STDX(u32 rs, u32 ra, u32 rb) = 0;
virtual void STWCX_(u32 rs, u32 ra, u32 rb) = 0;
@ -725,24 +725,24 @@ public:
virtual void STDUX(u32 rs, u32 ra, u32 rb) = 0;
virtual void STWUX(u32 rs, u32 ra, u32 rb) = 0;
virtual void STVEWX(u32 vs, u32 ra, u32 rb) = 0;
virtual void SUBFZE(u32 rd, u32 ra, u32 oe, bool rc) = 0;
virtual void ADDZE(u32 rd, u32 ra, u32 oe, bool rc) = 0;
virtual void SUBFZE(u32 rd, u32 ra, u32 oe, u32 rc) = 0;
virtual void ADDZE(u32 rd, u32 ra, u32 oe, u32 rc) = 0;
virtual void STDCX_(u32 rs, u32 ra, u32 rb) = 0;
virtual void STBX(u32 rs, u32 ra, u32 rb) = 0;
virtual void STVX(u32 vs, u32 ra, u32 rb) = 0;
virtual void MULLD(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) = 0;
virtual void SUBFME(u32 rd, u32 ra, u32 oe, bool rc) = 0;
virtual void ADDME(u32 rd, u32 ra, u32 oe, bool rc) = 0;
virtual void MULLW(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) = 0;
virtual void MULLD(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) = 0;
virtual void SUBFME(u32 rd, u32 ra, u32 oe, u32 rc) = 0;
virtual void ADDME(u32 rd, u32 ra, u32 oe, u32 rc) = 0;
virtual void MULLW(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) = 0;
virtual void DCBTST(u32 ra, u32 rb, u32 th) = 0;
virtual void STBUX(u32 rs, u32 ra, u32 rb) = 0;
virtual void ADD(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) = 0;
virtual void ADD(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) = 0;
virtual void DCBT(u32 ra, u32 rb, u32 th) = 0;
virtual void LHZX(u32 rd, u32 ra, u32 rb) = 0;
virtual void EQV(u32 ra, u32 rs, u32 rb, bool rc) = 0;
virtual void EQV(u32 ra, u32 rs, u32 rb, u32 rc) = 0;
virtual void ECIWX(u32 rd, u32 ra, u32 rb) = 0;
virtual void LHZUX(u32 rd, u32 ra, u32 rb) = 0;
virtual void XOR(u32 rs, u32 ra, u32 rb, bool rc) = 0;
virtual void XOR(u32 rs, u32 ra, u32 rb, u32 rc) = 0;
virtual void MFSPR(u32 rd, u32 spr) = 0;
virtual void LWAX(u32 rd, u32 ra, u32 rb) = 0;
virtual void DST(u32 ra, u32 rb, u32 strm, u32 t) = 0;
@ -753,25 +753,25 @@ public:
virtual void DSTST(u32 ra, u32 rb, u32 strm, u32 t) = 0;
virtual void LHAUX(u32 rd, u32 ra, u32 rb) = 0;
virtual void STHX(u32 rs, u32 ra, u32 rb) = 0;
virtual void ORC(u32 rs, u32 ra, u32 rb, bool rc) = 0;
virtual void ORC(u32 rs, u32 ra, u32 rb, u32 rc) = 0;
virtual void ECOWX(u32 rs, u32 ra, u32 rb) = 0;
virtual void STHUX(u32 rs, u32 ra, u32 rb) = 0;
virtual void OR(u32 ra, u32 rs, u32 rb, bool rc) = 0;
virtual void DIVDU(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) = 0;
virtual void DIVWU(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) = 0;
virtual void OR(u32 ra, u32 rs, u32 rb, u32 rc) = 0;
virtual void DIVDU(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) = 0;
virtual void DIVWU(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) = 0;
virtual void MTSPR(u32 spr, u32 rs) = 0;
virtual void DCBI(u32 ra, u32 rb) = 0;
virtual void NAND(u32 ra, u32 rs, u32 rb, bool rc) = 0;
virtual void NAND(u32 ra, u32 rs, u32 rb, u32 rc) = 0;
virtual void STVXL(u32 vs, u32 ra, u32 rb) = 0;
virtual void DIVD(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) = 0;
virtual void DIVW(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) = 0;
virtual void DIVD(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) = 0;
virtual void DIVW(u32 rd, u32 ra, u32 rb, u32 oe, u32 rc) = 0;
virtual void LVLX(u32 vd, u32 ra, u32 rb) = 0;
virtual void LDBRX(u32 rd, u32 ra, u32 rb) = 0;
virtual void LSWX(u32 rd, u32 ra, u32 rb) = 0;
virtual void LWBRX(u32 rd, u32 ra, u32 rb) = 0;
virtual void LFSX(u32 frd, u32 ra, u32 rb) = 0;
virtual void SRW(u32 ra, u32 rs, u32 rb, bool rc) = 0;
virtual void SRD(u32 ra, u32 rs, u32 rb, bool rc) = 0;
virtual void SRW(u32 ra, u32 rs, u32 rb, u32 rc) = 0;
virtual void SRD(u32 ra, u32 rs, u32 rb, u32 rc) = 0;
virtual void LVRX(u32 vd, u32 ra, u32 rb) = 0;
virtual void LSWI(u32 rd, u32 ra, u32 nb) = 0;
virtual void LFSUX(u32 frd, u32 ra, u32 rb) = 0;
@ -790,21 +790,21 @@ public:
virtual void STFDUX(u32 frs, u32 ra, u32 rb) = 0;
virtual void LVLXL(u32 vd, u32 ra, u32 rb) = 0;
virtual void LHBRX(u32 rd, u32 ra, u32 rb) = 0;
virtual void SRAW(u32 ra, u32 rs, u32 rb, bool rc) = 0;
virtual void SRAD(u32 ra, u32 rs, u32 rb, bool rc) = 0;
virtual void SRAW(u32 ra, u32 rs, u32 rb, u32 rc) = 0;
virtual void SRAD(u32 ra, u32 rs, u32 rb, u32 rc) = 0;
virtual void LVRXL(u32 vd, u32 ra, u32 rb) = 0;
virtual void DSS(u32 strm, u32 a) = 0;
virtual void SRAWI(u32 ra, u32 rs, u32 sh, bool rc) = 0;
virtual void SRADI1(u32 ra, u32 rs, u32 sh, bool rc) = 0;
virtual void SRADI2(u32 ra, u32 rs, u32 sh, bool rc) = 0;
virtual void SRAWI(u32 ra, u32 rs, u32 sh, u32 rc) = 0;
virtual void SRADI1(u32 ra, u32 rs, u32 sh, u32 rc) = 0;
virtual void SRADI2(u32 ra, u32 rs, u32 sh, u32 rc) = 0;
virtual void EIEIO() = 0;
virtual void STVLXL(u32 vs, u32 ra, u32 rb) = 0;
virtual void STHBRX(u32 rs, u32 ra, u32 rb) = 0;
virtual void EXTSH(u32 ra, u32 rs, bool rc) = 0;
virtual void EXTSH(u32 ra, u32 rs, u32 rc) = 0;
virtual void STVRXL(u32 sd, u32 ra, u32 rb) = 0;
virtual void EXTSB(u32 ra, u32 rs, bool rc) = 0;
virtual void EXTSB(u32 ra, u32 rs, u32 rc) = 0;
virtual void STFIWX(u32 frs, u32 ra, u32 rb) = 0;
virtual void EXTSW(u32 ra, u32 rs, bool rc) = 0;
virtual void EXTSW(u32 ra, u32 rs, u32 rc) = 0;
virtual void ICBI(u32 ra, u32 rb) = 0;
virtual void DCBZ(u32 ra, u32 rb) = 0;
virtual void LWZ(u32 rd, u32 ra, s32 d) = 0;
@ -834,48 +834,48 @@ public:
virtual void LD(u32 rd, u32 ra, s32 ds) = 0;
virtual void LDU(u32 rd, u32 ra, s32 ds) = 0;
virtual void LWA(u32 rd, u32 ra, s32 ds) = 0;
virtual void FDIVS(u32 frd, u32 fra, u32 frb, bool rc) = 0;
virtual void FSUBS(u32 frd, u32 fra, u32 frb, bool rc) = 0;
virtual void FADDS(u32 frd, u32 fra, u32 frb, bool rc) = 0;
virtual void FSQRTS(u32 frd, u32 frb, bool rc) = 0;
virtual void FRES(u32 frd, u32 frb, bool rc) = 0;
virtual void FMULS(u32 frd, u32 fra, u32 frc, bool rc) = 0;
virtual void FMADDS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) = 0;
virtual void FMSUBS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) = 0;
virtual void FNMSUBS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) = 0;
virtual void FNMADDS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) = 0;
virtual void FDIVS(u32 frd, u32 fra, u32 frb, u32 rc) = 0;
virtual void FSUBS(u32 frd, u32 fra, u32 frb, u32 rc) = 0;
virtual void FADDS(u32 frd, u32 fra, u32 frb, u32 rc) = 0;
virtual void FSQRTS(u32 frd, u32 frb, u32 rc) = 0;
virtual void FRES(u32 frd, u32 frb, u32 rc) = 0;
virtual void FMULS(u32 frd, u32 fra, u32 frc, u32 rc) = 0;
virtual void FMADDS(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) = 0;
virtual void FMSUBS(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) = 0;
virtual void FNMSUBS(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) = 0;
virtual void FNMADDS(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) = 0;
virtual void STD(u32 rs, u32 ra, s32 ds) = 0;
virtual void STDU(u32 rs, u32 ra, s32 ds) = 0;
virtual void MTFSB1(u32 bt, bool rc) = 0;
virtual void MTFSB1(u32 bt, u32 rc) = 0;
virtual void MCRFS(u32 bf, u32 bfa) = 0;
virtual void MTFSB0(u32 bt, bool rc) = 0;
virtual void MTFSFI(u32 crfd, u32 i, bool rc) = 0;
virtual void MFFS(u32 frd, bool rc) = 0;
virtual void MTFSF(u32 flm, u32 frb, bool rc) = 0;
virtual void MTFSB0(u32 bt, u32 rc) = 0;
virtual void MTFSFI(u32 crfd, u32 i, u32 rc) = 0;
virtual void MFFS(u32 frd, u32 rc) = 0;
virtual void MTFSF(u32 flm, u32 frb, u32 rc) = 0;
virtual void FCMPU(u32 bf, u32 fra, u32 frb) = 0;
virtual void FRSP(u32 frd, u32 frb, bool rc) = 0;
virtual void FCTIW(u32 frd, u32 frb, bool rc) = 0;
virtual void FCTIWZ(u32 frd, u32 frb, bool rc) = 0;
virtual void FDIV(u32 frd, u32 fra, u32 frb, bool rc) = 0;
virtual void FSUB(u32 frd, u32 fra, u32 frb, bool rc) = 0;
virtual void FADD(u32 frd, u32 fra, u32 frb, bool rc) = 0;
virtual void FSQRT(u32 frd, u32 frb, bool rc) = 0;
virtual void FSEL(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) = 0;
virtual void FMUL(u32 frd, u32 fra, u32 frc, bool rc) = 0;
virtual void FRSQRTE(u32 frd, u32 frb, bool rc) = 0;
virtual void FMSUB(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) = 0;
virtual void FMADD(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) = 0;
virtual void FNMSUB(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) = 0;
virtual void FNMADD(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) = 0;
virtual void FRSP(u32 frd, u32 frb, u32 rc) = 0;
virtual void FCTIW(u32 frd, u32 frb, u32 rc) = 0;
virtual void FCTIWZ(u32 frd, u32 frb, u32 rc) = 0;
virtual void FDIV(u32 frd, u32 fra, u32 frb, u32 rc) = 0;
virtual void FSUB(u32 frd, u32 fra, u32 frb, u32 rc) = 0;
virtual void FADD(u32 frd, u32 fra, u32 frb, u32 rc) = 0;
virtual void FSQRT(u32 frd, u32 frb, u32 rc) = 0;
virtual void FSEL(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) = 0;
virtual void FMUL(u32 frd, u32 fra, u32 frc, u32 rc) = 0;
virtual void FRSQRTE(u32 frd, u32 frb, u32 rc) = 0;
virtual void FMSUB(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) = 0;
virtual void FMADD(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) = 0;
virtual void FNMSUB(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) = 0;
virtual void FNMADD(u32 frd, u32 fra, u32 frc, u32 frb, u32 rc) = 0;
virtual void FCMPO(u32 crfd, u32 fra, u32 frb) = 0;
virtual void FNEG(u32 frd, u32 frb, bool rc) = 0;
virtual void FMR(u32 frd, u32 frb, bool rc) = 0;
virtual void FNABS(u32 frd, u32 frb, bool rc) = 0;
virtual void FABS(u32 frd, u32 frb, bool rc) = 0;
virtual void FCTID(u32 frd, u32 frb, bool rc) = 0;
virtual void FCTIDZ(u32 frd, u32 frb, bool rc) = 0;
virtual void FCFID(u32 frd, u32 frb, bool rc) = 0;
virtual void FNEG(u32 frd, u32 frb, u32 rc) = 0;
virtual void FMR(u32 frd, u32 frb, u32 rc) = 0;
virtual void FNABS(u32 frd, u32 frb, u32 rc) = 0;
virtual void FABS(u32 frd, u32 frb, u32 rc) = 0;
virtual void FCTID(u32 frd, u32 frb, u32 rc) = 0;
virtual void FCTIDZ(u32 frd, u32 frb, u32 rc) = 0;
virtual void FCFID(u32 frd, u32 frb, u32 rc) = 0;
virtual void UNK(const u32 code, const u32 opcode, const u32 gcode) = 0;
};

View File

@ -498,7 +498,6 @@ PPUThread::PPUThread(const std::string& name)
PPUThread::~PPUThread()
{
cv.notify_one();
join();
CloseStack();
@ -507,7 +506,7 @@ PPUThread::~PPUThread()
void PPUThread::DumpInformation() const
{
if (hle_code < 0)
if (~hle_code < 1024)
{
LOG_SUCCESS(HLE, "Last function: syscall %lld (%s)", ~hle_code, SysCalls::GetFuncName(hle_code));
}

View File

@ -543,7 +543,7 @@ public:
bool is_joinable = true;
bool is_joining = false;
s64 hle_code = 0; // current syscall (inverted value) or function id (positive value)
u64 hle_code = 0; // current syscall (~0..~1023) or function id (1..UINT32_MAX)
std::function<void(PPUThread& CPU)> custom_task;

View File

@ -16,7 +16,6 @@ RawSPUThread::RawSPUThread(const std::string& name, u32 index)
RawSPUThread::~RawSPUThread()
{
cv.notify_one();
join();
Memory.Unmap(offset);

View File

@ -64,10 +64,10 @@ SPUThread::SPUThread(CPUThreadType type, const std::string& name, u32 index, u32
{
}
SPUThread::SPUThread(const std::string& name, u32 index, u32 offset)
SPUThread::SPUThread(const std::string& name, u32 index)
: CPUThread(CPU_THREAD_SPU, name, [this]{ return fmt::format("%s[0x%x] Thread (%s)[0x%08x]", GetTypeString(), GetId(), GetName(), PC); })
, index(index)
, offset(offset)
, offset(Memory.MainMem.AllocAlign(0x40000))
{
}
@ -75,8 +75,9 @@ SPUThread::~SPUThread()
{
if (m_type == CPU_THREAD_SPU)
{
cv.notify_one();
join();
Memory.MainMem.Free(offset);
}
else if (joinable())
{
@ -86,15 +87,20 @@ SPUThread::~SPUThread()
bool SPUThread::IsPaused() const
{
if (CPUThread::IsPaused())
{
return true;
}
if (const auto group = tg.lock())
{
if (group->state == SPU_THREAD_GROUP_STATUS_WAITING || group->state == SPU_THREAD_GROUP_STATUS_SUSPENDED)
if (group->state >= SPU_THREAD_GROUP_STATUS_WAITING && group->state <= SPU_THREAD_GROUP_STATUS_SUSPENDED)
{
return true;
}
}
return CPUThread::IsPaused();
return false;
}
void SPUThread::DumpInformation() const
@ -511,6 +517,26 @@ u32 SPUThread::get_ch_value(u32 ch)
LOG_NOTICE(SPU, "get_ch_value(ch=%d [%s])", ch, ch < 128 ? spu_ch_name[ch] : "???");
}
auto read_channel = [this](spu_channel_t& channel) -> u32
{
std::unique_lock<std::mutex> lock(mutex, std::defer_lock);
u32 result;
while (!channel.try_pop(result))
{
CHECK_EMU_STATUS;
if (IsStopped()) throw CPUThreadStop{};
if (!lock) lock.lock();
cv.wait_for(lock, std::chrono::milliseconds(1));
}
return result;
};
switch (ch)
{
//case SPU_RdSRR0:
@ -518,11 +544,19 @@ u32 SPUThread::get_ch_value(u32 ch)
// break;
case SPU_RdInMbox:
{
std::unique_lock<std::mutex> lock(mutex, std::defer_lock);
u32 result, count;
while (!ch_in_mbox.pop(result, count) && !Emu.IsStopped())
while (!ch_in_mbox.try_pop(result, count))
{
std::this_thread::sleep_for(std::chrono::milliseconds(1)); // hack
CHECK_EMU_STATUS;
if (IsStopped()) throw CPUThreadStop{};
if (!lock) lock.lock();
cv.wait_for(lock, std::chrono::milliseconds(1));
}
if (count + 1 == 4 /* SPU_IN_MBOX_THRESHOLD */) // TODO: check this
@ -535,13 +569,7 @@ u32 SPUThread::get_ch_value(u32 ch)
case MFC_RdTagStat:
{
u32 result;
while (!ch_tag_stat.pop(result) && !Emu.IsStopped())
{
std::this_thread::sleep_for(std::chrono::milliseconds(1)); // hack
}
return result;
return read_channel(ch_tag_stat);
}
case MFC_RdTagMask:
@ -551,46 +579,22 @@ u32 SPUThread::get_ch_value(u32 ch)
case SPU_RdSigNotify1:
{
u32 result;
while (!ch_snr1.pop(result) && !Emu.IsStopped())
{
std::this_thread::sleep_for(std::chrono::milliseconds(1)); // hack
}
return result;
return read_channel(ch_snr1);
}
case SPU_RdSigNotify2:
{
u32 result;
while (!ch_snr2.pop(result) && !Emu.IsStopped())
{
std::this_thread::sleep_for(std::chrono::milliseconds(1)); // hack
}
return result;
return read_channel(ch_snr2);
}
case MFC_RdAtomicStat:
{
u32 result;
while (!ch_atomic_stat.pop(result) && !Emu.IsStopped())
{
std::this_thread::sleep_for(std::chrono::milliseconds(1)); // hack
}
return result;
return read_channel(ch_atomic_stat);
}
case MFC_RdListStallStat:
{
u32 result;
while (!ch_stall_stat.pop(result) && !Emu.IsStopped())
{
std::this_thread::sleep_for(std::chrono::milliseconds(1)); // hack
}
return result;
return read_channel(ch_stall_stat);
}
case SPU_RdDec:
@ -639,9 +643,17 @@ void SPUThread::set_ch_value(u32 ch, u32 value)
{
if (m_type == CPU_THREAD_RAW_SPU)
{
while (!ch_out_intr_mbox.push(value) && !Emu.IsStopped())
std::unique_lock<std::mutex> lock(mutex, std::defer_lock);
while (!ch_out_intr_mbox.try_push(value))
{
std::this_thread::sleep_for(std::chrono::milliseconds(1)); // hack
CHECK_EMU_STATUS;
if (IsStopped()) throw CPUThreadStop{};
if (!lock) lock.lock();
cv.wait_for(lock, std::chrono::milliseconds(1));
}
int2.set(SPU_INT2_STAT_MAILBOX_INT);
@ -657,7 +669,7 @@ void SPUThread::set_ch_value(u32 ch, u32 value)
u8 spup = code & 63;
u32 data;
if (!ch_out_mbox.pop(data))
if (!ch_out_mbox.try_pop(data))
{
throw EXCEPTION("sys_spu_thread_send_event(value=0x%x, spup=%d): Out_MBox is empty", value, spup);
}
@ -693,7 +705,7 @@ void SPUThread::set_ch_value(u32 ch, u32 value)
const u8 spup = code & 63;
u32 data;
if (!ch_out_mbox.pop(data))
if (!ch_out_mbox.try_pop(data))
{
throw EXCEPTION("sys_spu_thread_throw_event(value=0x%x, spup=%d): Out_MBox is empty", value, spup);
}
@ -729,7 +741,7 @@ void SPUThread::set_ch_value(u32 ch, u32 value)
u32 flag = value & 0xffffff;
u32 data;
if (!ch_out_mbox.pop(data))
if (!ch_out_mbox.try_pop(data))
{
throw EXCEPTION("sys_event_flag_set_bit(value=0x%x (flag=%d)): Out_MBox is empty", value, flag);
}
@ -773,7 +785,7 @@ void SPUThread::set_ch_value(u32 ch, u32 value)
u32 flag = value & 0xffffff;
u32 data;
if (!ch_out_mbox.pop(data))
if (!ch_out_mbox.try_pop(data))
{
throw EXCEPTION("sys_event_flag_set_bit_impatient(value=0x%x (flag=%d)): Out_MBox is empty", value, flag);
}
@ -827,9 +839,17 @@ void SPUThread::set_ch_value(u32 ch, u32 value)
case SPU_WrOutMbox:
{
while (!ch_out_mbox.push(value) && !Emu.IsStopped())
std::unique_lock<std::mutex> lock(mutex, std::defer_lock);
while (!ch_out_mbox.try_push(value))
{
std::this_thread::sleep_for(std::chrono::milliseconds(1)); // hack
CHECK_EMU_STATUS;
if (IsStopped()) throw CPUThreadStop{};
if (!lock) lock.lock();
cv.wait_for(lock, std::chrono::milliseconds(1));
}
return;
@ -1015,7 +1035,7 @@ void SPUThread::stop_and_signal(u32 code)
/* ===== sys_spu_thread_receive_event ===== */
u32 spuq = 0;
if (!ch_out_mbox.pop(spuq))
if (!ch_out_mbox.try_pop(spuq))
{
throw EXCEPTION("sys_spu_thread_receive_event(): cannot read Out_MBox");
}
@ -1033,6 +1053,18 @@ void SPUThread::stop_and_signal(u32 code)
LV2_LOCK;
const auto group = tg.lock();
if (!group)
{
throw EXCEPTION("Invalid SPU Thread Group");
}
if (group->type & SYS_SPU_THREAD_GROUP_TYPE_EXCLUSIVE_NON_CONTEXT) // this check may be inaccurate
{
return ch_in_mbox.push_uncond(CELL_EINVAL);
}
std::shared_ptr<lv2_event_queue_t> queue;
for (auto& v : this->spuq)
@ -1053,40 +1085,85 @@ void SPUThread::stop_and_signal(u32 code)
return ch_in_mbox.push_uncond(CELL_EINVAL); // TODO: check error value
}
// check thread group status
while (group->state >= SPU_THREAD_GROUP_STATUS_WAITING && group->state <= SPU_THREAD_GROUP_STATUS_SUSPENDED)
{
CHECK_EMU_STATUS;
if (IsStopped()) throw CPUThreadStop{};
group->cv.wait_for(lv2_lock, std::chrono::milliseconds(1));
}
// change group status
if (group->state == SPU_THREAD_GROUP_STATUS_RUNNING)
{
group->state = SPU_THREAD_GROUP_STATUS_WAITING;
for (auto& t : group->threads)
{
if (t) t->Sleep(); // trigger status check
}
}
else
{
throw EXCEPTION("Unexpected SPU Thread Group state (%d)", group->state);
}
// protocol is ignored in current implementation
queue->waiters++;
while (queue->events.empty())
// wait on the event queue
while (queue->events.empty() && !queue->cancelled)
{
if (queue->cancelled)
{
return ch_in_mbox.push_uncond(CELL_ECANCELED);
}
CHECK_EMU_STATUS;
if (IsStopped())
{
LOG_WARNING(SPU, "sys_spu_thread_receive_event(spuq=0x%x) aborted", spuq);
return;
}
if (IsStopped()) throw CPUThreadStop{};
queue->cv.wait_for(lv2_lock, std::chrono::milliseconds(1));
}
auto& event = queue->events.front();
ch_in_mbox.push_uncond(CELL_OK);
ch_in_mbox.push_uncond((u32)event.data1);
ch_in_mbox.push_uncond((u32)event.data2);
ch_in_mbox.push_uncond((u32)event.data3);
queue->events.pop_front();
queue->waiters--;
if (queue->events.size())
if (queue->cancelled)
{
queue->cv.notify_one();
ch_in_mbox.push_uncond(CELL_ECANCELED);
}
else
{
auto& event = queue->events.front();
ch_in_mbox.push_uncond(CELL_OK);
ch_in_mbox.push_uncond((u32)event.data1);
ch_in_mbox.push_uncond((u32)event.data2);
ch_in_mbox.push_uncond((u32)event.data3);
queue->events.pop_front();
queue->waiters--;
if (queue->events.size())
{
queue->cv.notify_one();
}
}
// restore thread group status
if (group->state == SPU_THREAD_GROUP_STATUS_WAITING)
{
group->state = SPU_THREAD_GROUP_STATUS_RUNNING;
}
else if (group->state == SPU_THREAD_GROUP_STATUS_WAITING_AND_SUSPENDED)
{
group->state = SPU_THREAD_GROUP_STATUS_SUSPENDED;
}
else
{
throw EXCEPTION("Unexpected SPU Thread Group state (%d)", group->state);
}
for (auto& t : group->threads)
{
if (t) t->Awake(); // untrigger status check
}
group->cv.notify_all();
return;
}
@ -1096,7 +1173,7 @@ void SPUThread::stop_and_signal(u32 code)
/* ===== sys_spu_thread_group_exit ===== */
u32 value;
if (!ch_out_mbox.pop(value))
if (!ch_out_mbox.try_pop(value))
{
throw EXCEPTION("sys_spu_thread_group_exit(): cannot read Out_MBox");
}
@ -1112,7 +1189,7 @@ void SPUThread::stop_and_signal(u32 code)
if (!group)
{
throw EXCEPTION("sys_spu_thread_group_exit(status=0x%x): invalid group", value);
throw EXCEPTION("Invalid SPU Thread Group");
}
for (auto t : group->threads)
@ -1126,7 +1203,7 @@ void SPUThread::stop_and_signal(u32 code)
group->state = SPU_THREAD_GROUP_STATUS_INITIALIZED;
group->exit_status = value;
group->join_state |= SPU_TGJSF_GROUP_EXIT;
group->join_cv.notify_one();
group->cv.notify_one();
return Stop();
}
@ -1147,7 +1224,15 @@ void SPUThread::stop_and_signal(u32 code)
LV2_LOCK;
const auto group = tg.lock();
if (!group)
{
throw EXCEPTION("Invalid SPU Thread Group");
}
status |= SPU_STATUS_STOPPED_BY_STOP;
group->cv.notify_one();
return Stop();
}
@ -1189,7 +1274,7 @@ void SPUThread::halt()
spu_thread::spu_thread(u32 entry, const std::string& name, u32 stack_size, u32 prio)
{
auto spu = Emu.GetIdManager().make_ptr<SPUThread>(name, 0, 0x10000);
auto spu = Emu.GetIdManager().make_ptr<SPUThread>(name, 0x13370666);
spu->PC = entry;

View File

@ -140,7 +140,7 @@ union spu_channel_t
atomic<sync_var_t> sync_var; // atomic variable
public:
bool push(u32 value)
bool try_push(u32 value)
{
bool out_result;
@ -166,7 +166,7 @@ public:
sync_var.exchange({ 1, value });
}
bool pop(u32& out_value)
bool try_pop(u32& out_value)
{
bool out_result;
@ -250,7 +250,7 @@ public:
}
// out_count: count after removing first element
bool pop(u32& out_value, u32& out_count)
bool try_pop(u32& out_value, u32& out_count)
{
bool out_result;
@ -633,7 +633,7 @@ protected:
SPUThread(CPUThreadType type, const std::string& name, u32 index, u32 offset);
public:
SPUThread(const std::string& name, u32 index, u32 offset);
SPUThread(const std::string& name, u32 index);
virtual ~SPUThread() override;
virtual bool IsPaused() const override;

View File

@ -208,40 +208,69 @@ public:
}
};
template<typename T, typename T2 = T> using if_integral_le_t = std::enable_if_t<std::is_integral<T>::value && std::is_integral<T2>::value, le_t<T>>;
template<typename T, typename T2 = T> using if_integral_be_t = std::enable_if_t<std::is_integral<T>::value && std::is_integral<T2>::value, be_t<T>>;
template<typename T> using if_integral_t = std::enable_if_t<std::is_integral<T>::value>;
template<typename T> inline if_integral_le_t<T> operator ++(_atomic_base<le_t<T>>& left)
template<typename T, typename = if_integral_t<T>> inline T operator ++(_atomic_base<T>& left)
{
return left.from_subtype(sync_fetch_and_add(&left.sub_data, 1) + 1);
}
template<typename T> inline if_integral_le_t<T> operator --(_atomic_base<le_t<T>>& left)
template<typename T, typename = if_integral_t<T>> inline T operator --(_atomic_base<T>& left)
{
return left.from_subtype(sync_fetch_and_sub(&left.sub_data, 1) - 1);
}
template<typename T> inline if_integral_le_t<T> operator ++(_atomic_base<le_t<T>>& left, int)
template<typename T, typename = if_integral_t<T>> inline T operator ++(_atomic_base<T>& left, int)
{
return left.from_subtype(sync_fetch_and_add(&left.sub_data, 1));
}
template<typename T> inline if_integral_le_t<T> operator --(_atomic_base<le_t<T>>& left, int)
template<typename T, typename = if_integral_t<T>> inline T operator --(_atomic_base<T>& left, int)
{
return left.from_subtype(sync_fetch_and_sub(&left.sub_data, 1));
}
template<typename T, typename T2> inline if_integral_le_t<T, T2> operator +=(_atomic_base<le_t<T>>& left, T2 right)
template<typename T, typename T2, typename = if_integral_t<T>> inline auto operator +=(_atomic_base<T>& left, T2 right) -> decltype(std::declval<T>() + std::declval<T2>())
{
return left.from_subtype(sync_fetch_and_add(&left.sub_data, right) + right);
}
template<typename T, typename T2> inline if_integral_le_t<T, T2> operator -=(_atomic_base<le_t<T>>& left, T2 right)
template<typename T, typename T2, typename = if_integral_t<T>> inline auto operator -=(_atomic_base<T>& left, T2 right) -> decltype(std::declval<T>() - std::declval<T2>())
{
return left.from_subtype(sync_fetch_and_sub(&left.sub_data, right) - right);
}
template<typename T> inline if_integral_be_t<T> operator ++(_atomic_base<be_t<T>>& left)
template<typename T, typename = if_integral_t<T>> inline le_t<T> operator ++(_atomic_base<le_t<T>>& left)
{
return left.from_subtype(sync_fetch_and_add(&left.sub_data, 1) + 1);
}
template<typename T, typename = if_integral_t<T>> inline le_t<T> operator --(_atomic_base<le_t<T>>& left)
{
return left.from_subtype(sync_fetch_and_sub(&left.sub_data, 1) - 1);
}
template<typename T, typename = if_integral_t<T>> inline le_t<T> operator ++(_atomic_base<le_t<T>>& left, int)
{
return left.from_subtype(sync_fetch_and_add(&left.sub_data, 1));
}
template<typename T, typename = if_integral_t<T>> inline le_t<T> operator --(_atomic_base<le_t<T>>& left, int)
{
return left.from_subtype(sync_fetch_and_sub(&left.sub_data, 1));
}
template<typename T, typename T2, typename = if_integral_t<T>> inline auto operator +=(_atomic_base<le_t<T>>& left, T2 right) -> decltype(std::declval<T>() + std::declval<T2>())
{
return left.from_subtype(sync_fetch_and_add(&left.sub_data, right) + right);
}
template<typename T, typename T2, typename = if_integral_t<T>> inline auto operator -=(_atomic_base<le_t<T>>& left, T2 right) -> decltype(std::declval<T>() - std::declval<T2>())
{
return left.from_subtype(sync_fetch_and_sub(&left.sub_data, right) - right);
}
template<typename T, typename = if_integral_t<T>> inline be_t<T> operator ++(_atomic_base<be_t<T>>& left)
{
return left.atomic_op([](be_t<T>& value) -> be_t<T>
{
@ -249,7 +278,7 @@ template<typename T> inline if_integral_be_t<T> operator ++(_atomic_base<be_t<T>
});
}
template<typename T> inline if_integral_be_t<T> operator --(_atomic_base<be_t<T>>& left)
template<typename T, typename = if_integral_t<T>> inline be_t<T> operator --(_atomic_base<be_t<T>>& left)
{
return left.atomic_op([](be_t<T>& value) -> be_t<T>
{
@ -257,7 +286,7 @@ template<typename T> inline if_integral_be_t<T> operator --(_atomic_base<be_t<T>
});
}
template<typename T> inline if_integral_be_t<T> operator ++(_atomic_base<be_t<T>>& left, int)
template<typename T, typename = if_integral_t<T>> inline be_t<T> operator ++(_atomic_base<be_t<T>>& left, int)
{
return left.atomic_op([](be_t<T>& value) -> be_t<T>
{
@ -265,7 +294,7 @@ template<typename T> inline if_integral_be_t<T> operator ++(_atomic_base<be_t<T>
});
}
template<typename T> inline if_integral_be_t<T> operator --(_atomic_base<be_t<T>>& left, int)
template<typename T, typename = if_integral_t<T>> inline be_t<T> operator --(_atomic_base<be_t<T>>& left, int)
{
return left.atomic_op([](be_t<T>& value) -> be_t<T>
{
@ -273,7 +302,7 @@ template<typename T> inline if_integral_be_t<T> operator --(_atomic_base<be_t<T>
});
}
template<typename T, typename T2> inline if_integral_be_t<T, T2> operator +=(_atomic_base<be_t<T>>& left, T2 right)
template<typename T, typename T2, typename = if_integral_t<T>> inline auto operator +=(_atomic_base<be_t<T>>& left, T2 right) -> be_t<decltype(std::declval<T>() + std::declval<T2>())>
{
return left.atomic_op([right](be_t<T>& value) -> be_t<T>
{
@ -281,7 +310,7 @@ template<typename T, typename T2> inline if_integral_be_t<T, T2> operator +=(_at
});
}
template<typename T, typename T2> inline if_integral_be_t<T, T2> operator -=(_atomic_base<be_t<T>>& left, T2 right)
template<typename T, typename T2, typename = if_integral_t<T>> inline auto operator -=(_atomic_base<be_t<T>>& left, T2 right) -> be_t<decltype(std::declval<T>() - std::declval<T2>())>
{
return left.atomic_op([right](be_t<T>& value) -> be_t<T>
{

View File

@ -821,7 +821,6 @@ void GLGSRender::Close()
{
if (joinable())
{
cv.notify_one();
join();
}

View File

@ -11,8 +11,10 @@ public:
virtual ~NullGSRender() override
{
cv.notify_one();
join();
if (joinable())
{
throw EXCEPTION("Thread not joined");
}
}
private:
@ -46,6 +48,10 @@ private:
virtual void Close()
{
if (joinable())
{
join();
}
}
virtual void semaphorePGRAPHTextureReadRelease(u32 offset, u32 value) override

View File

@ -2,7 +2,7 @@
#include "Modules.h"
#include "SysCalls.h"
std::string SysCalls::GetFuncName(const s64 fid)
std::string SysCalls::GetFuncName(const u64 fid)
{
// check syscalls
switch (~fid)

View File

@ -443,7 +443,6 @@ s32 cellAudioQuit()
return CELL_AUDIO_ERROR_NOT_INIT;
}
g_audio.thread.cv.notify_one();
g_audio.thread.join();
g_audio.state.exchange(AUDIO_STATE_NOT_INITIALIZED);
return CELL_OK;

View File

@ -924,7 +924,7 @@ s32 cellFsAioFinish(vm::cptr<char> mount_point)
return CELL_OK;
}
std::atomic<s32> g_fs_aio_id(0);
std::atomic<s32> g_fs_aio_id;
s32 cellFsAioRead(vm::ptr<CellFsAio> aio, vm::ptr<s32> id, fs_aio_cb_t func)
{
@ -984,6 +984,8 @@ s32 cellFsSetIoBufferFromDefaultContainer(u32 fd, u32 buffer_size, u32 page_type
Module cellFs("cellFs", []()
{
g_fs_aio_id = 1;
REG_FUNC(cellFs, cellFsOpen);
REG_FUNC(cellFs, cellFsSdataOpen);
REG_FUNC(cellFs, cellFsSdataOpenByFd);

View File

@ -25,5 +25,5 @@ class SysCalls
{
public:
static void DoSyscall(PPUThread& CPU, u64 code);
static std::string GetFuncName(const s64 fid);
static std::string GetFuncName(const u64 fid);
};

View File

@ -171,6 +171,8 @@ s32 sys_event_queue_receive(PPUThread& CPU, u32 equeue_id, vm::ptr<sys_event_t>
while (queue->events.empty())
{
CHECK_EMU_STATUS;
if (queue->cancelled)
{
return CELL_ECANCELED;
@ -182,12 +184,6 @@ s32 sys_event_queue_receive(PPUThread& CPU, u32 equeue_id, vm::ptr<sys_event_t>
return CELL_ETIMEDOUT;
}
if (Emu.IsStopped())
{
sys_event.Warning("sys_event_queue_receive(equeue_id=0x%x) aborted", equeue_id);
return CELL_OK;
}
queue->cv.wait_for(lv2_lock, std::chrono::milliseconds(1));
}

View File

@ -23,16 +23,14 @@ s32 sys_interrupt_tag_destroy(u32 intrtag)
return CELL_ESRCH;
}
const auto t = Emu.GetCPU().GetRawSPUThread(intrtag & 0xff);
const auto thread = Emu.GetCPU().GetRawSPUThread(intrtag & 0xff);
if (!t)
if (!thread)
{
return CELL_ESRCH;
}
RawSPUThread& spu = static_cast<RawSPUThread&>(*t);
auto& tag = class_id ? spu.int2 : spu.int0;
auto& tag = class_id ? thread->int2 : thread->int0;
if (s32 old = tag.assigned.compare_and_swap(0, -1))
{
@ -58,16 +56,14 @@ s32 sys_interrupt_thread_establish(vm::ptr<u32> ih, u32 intrtag, u32 intrthread,
return CELL_ESRCH;
}
const auto t = Emu.GetCPU().GetRawSPUThread(intrtag & 0xff);
const auto thread = Emu.GetCPU().GetRawSPUThread(intrtag & 0xff);
if (!t)
if (!thread)
{
return CELL_ESRCH;
}
RawSPUThread& spu = static_cast<RawSPUThread&>(*t);
auto& tag = class_id ? spu.int2 : spu.int0;
auto& tag = class_id ? thread->int2 : thread->int0;
// CELL_ESTAT is not returned (can't detect exact condition)
@ -78,12 +74,10 @@ s32 sys_interrupt_thread_establish(vm::ptr<u32> ih, u32 intrtag, u32 intrthread,
return CELL_ESRCH;
}
PPUThread& ppu = static_cast<PPUThread&>(*it);
{
LV2_LOCK;
if (ppu.custom_task)
if (it->custom_task)
{
return CELL_EAGAIN;
}
@ -102,7 +96,7 @@ s32 sys_interrupt_thread_establish(vm::ptr<u32> ih, u32 intrtag, u32 intrthread,
return res;
}
ppu.custom_task = [t, &tag, arg](PPUThread& CPU)
it->custom_task = [thread, &tag, arg](PPUThread& CPU)
{
const auto pc = CPU.PC;
const auto rtoc = CPU.GPR[2];
@ -124,7 +118,7 @@ s32 sys_interrupt_thread_establish(vm::ptr<u32> ih, u32 intrtag, u32 intrthread,
}
*ih = Emu.GetIdManager().make<lv2_int_handler_t>(it);
ppu.Exec();
it->Exec();
return CELL_OK;
}
@ -140,11 +134,9 @@ s32 _sys_interrupt_thread_disestablish(u32 ih, vm::ptr<u64> r13)
return CELL_ESRCH;
}
PPUThread& ppu = static_cast<PPUThread&>(*handler->handler);
// TODO: wait for sys_interrupt_thread_eoi() and destroy interrupt thread
*r13 = ppu.GPR[13];
*r13 = handler->thread->GPR[13];
return CELL_OK;
}
@ -153,8 +145,9 @@ void sys_interrupt_thread_eoi(PPUThread& CPU)
{
sys_interrupt.Log("sys_interrupt_thread_eoi()");
// TODO: maybe it should actually unwind the stack (ensure that all the automatic objects are finalized)?
CPU.GPR[1] = align(CPU.stack_addr + CPU.stack_size, 0x200) - 0x200; // supercrutch (just to hide error messages)
// TODO: maybe it should actually unwind the stack of PPU thread?
CPU.GPR[1] = align(CPU.stack_addr + CPU.stack_size, 0x200) - 0x200; // supercrutch to avoid stack check
CPU.FastStop();
}

View File

@ -6,10 +6,10 @@ class PPUThread;
struct lv2_int_handler_t
{
std::shared_ptr<CPUThread> handler;
const std::shared_ptr<PPUThread> thread;
lv2_int_handler_t(const std::shared_ptr<CPUThread>& handler)
: handler(handler)
lv2_int_handler_t(const std::shared_ptr<PPUThread>& thread)
: thread(thread)
{
}
};

View File

@ -33,8 +33,8 @@ void _sys_ppu_thread_exit(PPUThread& CPU, u64 errorcode)
void sys_ppu_thread_yield()
{
sys_ppu_thread.Log("sys_ppu_thread_yield()");
// Note: Or do we actually want to yield?
std::this_thread::sleep_for(std::chrono::milliseconds(1)); // hack
std::this_thread::yield();
}
s32 sys_ppu_thread_join(PPUThread& CPU, u32 thread_id, vm::ptr<u64> vptr)

View File

@ -102,7 +102,7 @@ s32 prx_load_module(std::string path, u64 flags, vm::ptr<sys_prx_load_module_opt
if (!func)
{
sys_prx.Error("Unimplemented function '%s' in '%s' module (0x%x)", SysCalls::GetFuncName(nid), module_.first);
sys_prx.Error("Unknown function '%s' in '%s' module (0x%x)", SysCalls::GetFuncName(nid), module_.first);
index = add_ppu_func(ModuleFunc(nid, 0, module, nullptr, nullptr));
}

View File

@ -96,10 +96,10 @@ u32 spu_thread_initialize(u32 group_id, u32 spu_num, vm::ptr<sys_spu_image> img,
{
if (option)
{
sys_spu.Todo("Unsupported SPU Thread options (0x%x)", option);
sys_spu.Error("Unsupported SPU Thread options (0x%x)", option);
}
const auto spu = Emu.GetIdManager().make_ptr<SPUThread>(name, spu_num, Memory.MainMem.AllocAlign(0x40000));
const auto spu = Emu.GetIdManager().make_ptr<SPUThread>(name, spu_num);
spu->m_custom_task = task;
@ -120,9 +120,13 @@ u32 spu_thread_initialize(u32 group_id, u32 spu_num, vm::ptr<sys_spu_image> img,
}
}
if (count >= group->num)
if (count > group->num)
{
throw EXCEPTION("Unexpected thread count (%d)", count);
}
if (count == group->num)
{
assert(count == group->num);
group->state = SPU_THREAD_GROUP_STATUS_INITIALIZED;
}
@ -152,7 +156,7 @@ s32 sys_spu_thread_initialize(vm::ptr<u32> thread, u32 group_id, u32 spu_num, vm
return CELL_EBUSY;
}
*thread = spu_thread_initialize(group_id, spu_num, img, attr->name ? std::string(attr->name.get_ptr(), attr->name_len) : "SPUThread", attr->option, arg->arg1, arg->arg2, arg->arg3, arg->arg4);
*thread = spu_thread_initialize(group_id, spu_num, img, attr->name ? std::string(attr->name.get_ptr(), attr->name_len) : "", attr->option, arg->arg1, arg->arg2, arg->arg3, arg->arg4);
return CELL_OK;
}
@ -171,7 +175,15 @@ s32 sys_spu_thread_set_argument(u32 id, vm::ptr<sys_spu_thread_argument> arg)
const auto group = thread->tg.lock();
assert(thread->index < group->threads.size());
if (!group)
{
throw EXCEPTION("Invalid SPU thread group");
}
if (thread->index >= group->threads.size() || group->threads[thread->index] != thread)
{
throw EXCEPTION("Unexpected SPU thread index (%d)", thread->index);
}
group->args[thread->index].arg1 = arg->arg1;
group->args[thread->index].arg2 = arg->arg2;
@ -245,10 +257,7 @@ s32 sys_spu_thread_group_destroy(u32 id)
{
if (t)
{
auto& spu = static_cast<SPUThread&>(*t);
Memory.MainMem.Free(spu.offset);
Emu.GetIdManager().remove<SPUThread>(spu.GetId());
Emu.GetIdManager().remove<SPUThread>(t->GetId());
t.reset();
}
@ -287,24 +296,26 @@ s32 sys_spu_thread_group_start(u32 id)
{
if (t)
{
auto& spu = static_cast<SPUThread&>(*t);
if (t->index >= group->threads.size())
{
throw EXCEPTION("Unexpected SPU thread index (%d)", t->index);
}
assert(spu.index < group->threads.size());
auto& args = group->args[spu.index];
auto& image = group->images[spu.index];
auto& args = group->args[t->index];
auto& image = group->images[t->index];
// Copy SPU image:
// TODO: use segment info
memcpy(vm::get_ptr<void>(spu.offset), vm::get_ptr<void>(image->addr), 256 * 1024);
std::memcpy(vm::get_ptr<void>(t->offset), vm::get_ptr<void>(image->addr), 256 * 1024);
spu.Run();
spu.PC = image->entry_point;
spu.GPR[3] = u128::from64(0, args.arg1);
spu.GPR[4] = u128::from64(0, args.arg2);
spu.GPR[5] = u128::from64(0, args.arg3);
spu.GPR[6] = u128::from64(0, args.arg4);
t->PC = image->entry_point;
t->Run();
t->GPR[3] = u128::from64(0, args.arg1);
t->GPR[4] = u128::from64(0, args.arg2);
t->GPR[5] = u128::from64(0, args.arg3);
t->GPR[6] = u128::from64(0, args.arg4);
spu.status.exchange(SPU_STATUS_RUNNING);
t->status.exchange(SPU_STATUS_RUNNING);
}
}
@ -314,10 +325,7 @@ s32 sys_spu_thread_group_start(u32 id)
for (auto& t : group->threads)
{
if (t)
{
t->Exec();
}
if (t) t->Exec();
}
return CELL_OK;
@ -367,10 +375,7 @@ s32 sys_spu_thread_group_suspend(u32 id)
for (auto& t : group->threads)
{
if (t)
{
t->Sleep(); // trigger m_state check
}
if (t) t->Sleep(); // trigger status check
}
return CELL_OK;
@ -403,7 +408,6 @@ s32 sys_spu_thread_group_resume(u32 id)
else if (group->state == SPU_THREAD_GROUP_STATUS_WAITING_AND_SUSPENDED)
{
group->state = SPU_THREAD_GROUP_STATUS_WAITING;
return CELL_OK; // probably, nothing to do there
}
else
{
@ -412,12 +416,11 @@ s32 sys_spu_thread_group_resume(u32 id)
for (auto& t : group->threads)
{
if (t)
{
t->Awake(); // trigger m_state check
}
if (t) t->Awake(); // untrigger status check
}
group->cv.notify_all();
return CELL_OK;
}
@ -452,19 +455,15 @@ s32 sys_spu_thread_group_terminate(u32 id, s32 value)
// seems the id can be either SPU Thread Group or SPU Thread
const auto thread = Emu.GetIdManager().get<SPUThread>(id);
auto group = Emu.GetIdManager().get<spu_group_t>(id);
const auto group = thread ? thread->tg.lock() : Emu.GetIdManager().get<spu_group_t>(id);
if (!group && !thread)
{
return CELL_ESRCH;
}
auto& spu = static_cast<SPUThread&>(*thread);
if (thread)
{
group = spu.tg.lock();
for (auto& t : group->threads)
{
// find primary (?) thread and compare it with the one specified
@ -482,26 +481,22 @@ s32 sys_spu_thread_group_terminate(u32 id, s32 value)
}
}
if ((group->state <= SPU_THREAD_GROUP_STATUS_INITIALIZED) || (group->state == SPU_THREAD_GROUP_STATUS_WAITING))
if (group->state <= SPU_THREAD_GROUP_STATUS_INITIALIZED ||
group->state == SPU_THREAD_GROUP_STATUS_WAITING ||
group->state == SPU_THREAD_GROUP_STATUS_WAITING_AND_SUSPENDED)
{
return CELL_ESTAT;
}
for (auto& t : group->threads)
{
if (t)
{
auto& spu = static_cast<SPUThread&>(*t);
spu.status.exchange(SPU_STATUS_STOPPED);
spu.Stop();
}
if (t) t->Stop();
}
group->state = SPU_THREAD_GROUP_STATUS_INITIALIZED;
group->exit_status = value;
group->join_state |= SPU_TGJSF_TERMINATED;
group->join_cv.notify_one();
group->cv.notify_one();
return CELL_OK;
}
@ -538,9 +533,7 @@ s32 sys_spu_thread_group_join(u32 id, vm::ptr<u32> cause, vm::ptr<u32> status)
{
if (t)
{
auto& spu = static_cast<SPUThread&>(*t);
if ((spu.status.load() & SPU_STATUS_STOPPED_BY_STOP) == 0)
if ((t->status.load() & SPU_STATUS_STOPPED_BY_STOP) == 0)
{
stopped = false;
break;
@ -559,7 +552,7 @@ s32 sys_spu_thread_group_join(u32 id, vm::ptr<u32> cause, vm::ptr<u32> status)
return CELL_OK;
}
group->join_cv.wait_for(lv2_lock, std::chrono::milliseconds(1));
group->cv.wait_for(lv2_lock, std::chrono::milliseconds(1));
}
switch (group->join_state & ~SPU_TGJSF_IS_JOINING)
@ -615,6 +608,11 @@ s32 sys_spu_thread_write_ls(u32 id, u32 address, u64 value, u32 type)
const auto group = thread->tg.lock();
if (!group)
{
throw EXCEPTION("Invalid SPU thread group");
}
if ((group->state < SPU_THREAD_GROUP_STATUS_WAITING) || (group->state > SPU_THREAD_GROUP_STATUS_RUNNING))
{
return CELL_ESTAT;
@ -652,6 +650,11 @@ s32 sys_spu_thread_read_ls(u32 id, u32 address, vm::ptr<u64> value, u32 type)
const auto group = thread->tg.lock();
if (!group)
{
throw EXCEPTION("Invalid SPU thread group");
}
if ((group->state < SPU_THREAD_GROUP_STATUS_WAITING) || (group->state > SPU_THREAD_GROUP_STATUS_RUNNING))
{
return CELL_ESTAT;
@ -684,6 +687,11 @@ s32 sys_spu_thread_write_spu_mb(u32 id, u32 value)
const auto group = thread->tg.lock();
if (!group)
{
throw EXCEPTION("Invalid SPU thread group");
}
if ((group->state < SPU_THREAD_GROUP_STATUS_WAITING) || (group->state > SPU_THREAD_GROUP_STATUS_RUNNING))
{
return CELL_ESTAT;
@ -755,11 +763,16 @@ s32 sys_spu_thread_write_snr(u32 id, u32 number, u32 value)
const auto group = thread->tg.lock();
if ((group->state < SPU_THREAD_GROUP_STATUS_WAITING) || (group->state > SPU_THREAD_GROUP_STATUS_RUNNING))
if (!group)
{
return CELL_ESTAT;
throw EXCEPTION("Invalid SPU thread group");
}
//if ((group->state < SPU_THREAD_GROUP_STATUS_WAITING) || (group->state > SPU_THREAD_GROUP_STATUS_RUNNING)) // ???
//{
// return CELL_ESTAT;
//}
thread->write_snr(number, value);
return CELL_OK;
@ -1056,9 +1069,7 @@ s32 sys_spu_thread_group_connect_event_all_threads(u32 id, u32 eq, u64 req, vm::
{
if (t)
{
auto& spu = static_cast<SPUThread&>(*t);
if (!spu.spup[port].expired())
if (!t->spup[port].expired())
{
found = false;
break;
@ -1081,9 +1092,7 @@ s32 sys_spu_thread_group_connect_event_all_threads(u32 id, u32 eq, u64 req, vm::
{
if (t)
{
auto& spu = static_cast<SPUThread&>(*t);
spu.spup[port] = queue;
t->spup[port] = queue;
}
}
@ -1114,9 +1123,7 @@ s32 sys_spu_thread_group_disconnect_event_all_threads(u32 id, u8 spup)
{
if (t)
{
auto& spu = static_cast<SPUThread&>(*t);
spu.spup[spup].reset();
t->spup[spup].reset();
}
}
@ -1172,16 +1179,14 @@ s32 sys_raw_spu_create_interrupt_tag(u32 id, u32 class_id, u32 hwthread, vm::ptr
return CELL_EINVAL;
}
const auto t = Emu.GetCPU().GetRawSPUThread(id);
const auto thread = Emu.GetCPU().GetRawSPUThread(id);
if (!t)
if (!thread)
{
return CELL_ESRCH;
}
auto& spu = static_cast<RawSPUThread&>(*t);
auto& tag = class_id ? spu.int2 : spu.int0;
auto& tag = class_id ? thread->int2 : thread->int0;
if (!tag.assigned.compare_and_swap_test(-1, 0))
{
@ -1202,16 +1207,16 @@ s32 sys_raw_spu_set_int_mask(u32 id, u32 class_id, u64 mask)
return CELL_EINVAL;
}
const auto t = Emu.GetCPU().GetRawSPUThread(id);
const auto thread = Emu.GetCPU().GetRawSPUThread(id);
if (!t)
if (!thread)
{
return CELL_ESRCH;
}
auto& spu = static_cast<RawSPUThread&>(*t);
auto& tag = class_id ? thread->int2 : thread->int0;
(class_id ? spu.int2 : spu.int0).mask.exchange(mask);
tag.mask.exchange(mask);
return CELL_OK;
}
@ -1225,16 +1230,16 @@ s32 sys_raw_spu_get_int_mask(u32 id, u32 class_id, vm::ptr<u64> mask)
return CELL_EINVAL;
}
const auto t = Emu.GetCPU().GetRawSPUThread(id);
const auto thread = Emu.GetCPU().GetRawSPUThread(id);
if (!t)
if (!thread)
{
return CELL_ESRCH;
}
auto& spu = static_cast<RawSPUThread&>(*t);
auto& tag = class_id ? thread->int2 : thread->int0;
*mask = (class_id ? spu.int2 : spu.int0).mask.load();
*mask = tag.mask.load();
return CELL_OK;
}
@ -1248,16 +1253,16 @@ s32 sys_raw_spu_set_int_stat(u32 id, u32 class_id, u64 stat)
return CELL_EINVAL;
}
const auto t = Emu.GetCPU().GetRawSPUThread(id);
const auto thread = Emu.GetCPU().GetRawSPUThread(id);
if (!t)
if (!thread)
{
return CELL_ESRCH;
}
auto& spu = static_cast<RawSPUThread&>(*t);
auto& tag = class_id ? thread->int2 : thread->int0;
(class_id ? spu.int2 : spu.int0).clear(stat);
tag.clear(stat);
return CELL_OK;
}
@ -1271,16 +1276,16 @@ s32 sys_raw_spu_get_int_stat(u32 id, u32 class_id, vm::ptr<u64> stat)
return CELL_EINVAL;
}
const auto t = Emu.GetCPU().GetRawSPUThread(id);
const auto thread = Emu.GetCPU().GetRawSPUThread(id);
if (!t)
if (!thread)
{
return CELL_ESRCH;
}
auto& spu = static_cast<RawSPUThread&>(*t);
auto& tag = class_id ? thread->int2 : thread->int0;
*stat = (class_id ? spu.int2 : spu.int0).stat.load();
*stat = tag.stat.load();
return CELL_OK;
}
@ -1289,16 +1294,14 @@ s32 sys_raw_spu_read_puint_mb(u32 id, vm::ptr<u32> value)
{
sys_spu.Log("sys_raw_spu_read_puint_mb(id=%d, value=*0x%x)", id, value);
const auto t = Emu.GetCPU().GetRawSPUThread(id);
const auto thread = Emu.GetCPU().GetRawSPUThread(id);
if (!t)
if (!thread)
{
return CELL_ESRCH;
}
auto& spu = static_cast<RawSPUThread&>(*t);
*value = spu.ch_out_intr_mbox.pop_uncond();
*value = thread->ch_out_intr_mbox.pop_uncond();
return CELL_OK;
}
@ -1312,16 +1315,14 @@ s32 sys_raw_spu_set_spu_cfg(u32 id, u32 value)
sys_spu.Fatal("sys_raw_spu_set_spu_cfg(id=%d, value=0x%x)", id, value);
}
const auto t = Emu.GetCPU().GetRawSPUThread(id);
const auto thread = Emu.GetCPU().GetRawSPUThread(id);
if (!t)
if (!thread)
{
return CELL_ESRCH;
}
auto& spu = static_cast<RawSPUThread&>(*t);
spu.snr_config = value;
thread->snr_config = value;
return CELL_OK;
}
@ -1330,16 +1331,14 @@ s32 sys_raw_spu_get_spu_cfg(u32 id, vm::ptr<u32> value)
{
sys_spu.Log("sys_raw_spu_get_spu_afg(id=%d, value=*0x%x)", id, value);
const auto t = Emu.GetCPU().GetRawSPUThread(id);
const auto thread = Emu.GetCPU().GetRawSPUThread(id);
if (!t)
if (!thread)
{
return CELL_ESRCH;
}
auto& spu = static_cast<RawSPUThread&>(*t);
*value = (u32)spu.snr_config;
*value = (u32)thread->snr_config;
return CELL_OK;
}

View File

@ -141,6 +141,8 @@ enum : u32
SPU_TGJSF_GROUP_EXIT = (1 << 2), // set if SPU Thread Group is terminated by sys_spu_thread_group_exit
};
class SPUThread;
struct spu_group_t
{
const std::string name;
@ -148,16 +150,16 @@ struct spu_group_t
const s32 type; // SPU Thread Group Type
const u32 ct; // Memory Container Id
std::array<std::shared_ptr<CPUThread>, 256> threads; // SPU Threads
std::array<std::shared_ptr<SPUThread>, 256> threads; // SPU Threads
std::array<vm::ptr<sys_spu_image>, 256> images; // SPU Images
std::array<spu_arg_t, 256> args; // SPU Thread Arguments
s32 prio; // SPU Thread Group Priority
u32 state; // SPU Thread Group State
volatile u32 state; // SPU Thread Group State
s32 exit_status; // SPU Thread Group Exit Status
std::atomic<u32> join_state; // flags used to detect exit cause
std::condition_variable join_cv; // used to signal waiting PPU thread
std::condition_variable cv; // used to signal waiting PPU thread
std::weak_ptr<lv2_event_queue_t> ep_run; // port for SYS_SPU_THREAD_GROUP_EVENT_RUN events
std::weak_ptr<lv2_event_queue_t> ep_exception; // TODO: SYS_SPU_THREAD_GROUP_EVENT_EXCEPTION
@ -206,7 +208,6 @@ struct spu_group_t
}
};
class SPUThread;
struct vfsStream;
void LoadSpuImage(vfsStream& stream, u32& spu_ep, u32 addr);

View File

@ -309,7 +309,7 @@ void Emulator::Resume()
for (auto& t : GetCPU().GetAllThreads())
{
t->Awake(); // trigger status check
t->Awake(); // untrigger status check
}
SendDbgCommand(DID_RESUMED_EMU);
@ -327,9 +327,11 @@ void Emulator::Stop()
m_status = Stopped;
LOG_NOTICE(GENERAL, "Stopping emulator...");
for (auto& t : GetCPU().GetAllThreads())
{
t->Pause(); // trigger status check
t->Sleep(); // trigger status check
}
while (g_thread_count)
@ -337,7 +339,7 @@ void Emulator::Stop()
std::this_thread::sleep_for(std::chrono::milliseconds(1));
}
LOG_NOTICE(HLE, "All threads stopped...");
LOG_NOTICE(GENERAL, "All threads stopped...");
finalize_psv_modules();
clear_all_psv_objects();

View File

@ -464,7 +464,7 @@ namespace loader
if (!func)
{
LOG_ERROR(LOADER, "Unimplemented function '%s' (0x%x)", SysCalls::GetFuncName(nid), addr);
LOG_ERROR(LOADER, "Unknown function '%s' (0x%x)", SysCalls::GetFuncName(nid), addr);
index = add_ppu_func(ModuleFunc(nid, 0, module, nullptr, nullptr));
}
@ -695,7 +695,7 @@ namespace loader
if (!func)
{
LOG_ERROR(LOADER, "Unimplemented function '%s' in '%s' module (0x%x)", SysCalls::GetFuncName(nid), module_name, addr);
LOG_ERROR(LOADER, "Unknown function '%s' in '%s' module (0x%x)", SysCalls::GetFuncName(nid), module_name, addr);
index = add_ppu_func(ModuleFunc(nid, 0, module, nullptr, nullptr));
}