qzdoom/src/scripting/vm/jit_move.cpp


#include "jitintern.h"

void JitCompiler::EmitMOVE()
{
	cc.mov(regD[A], regD[B]);
}
void JitCompiler::EmitMOVEF()
{
	cc.movsd(regF[A], regF[B]);
}

void JitCompiler::EmitMOVES()
{
	auto call = cc.call(ToMemAddress(reinterpret_cast<void*>(static_cast<void(*)(FString*, FString*)>(CallAssignString))),
		asmjit::FuncSignature2<void, FString*, FString*>(asmjit::CallConv::kIdHostCDecl));
	call->setArg(0, regS[A]);
	call->setArg(1, regS[B]);
}

void JitCompiler::EmitMOVEA()
{
	cc.mov(regA[A], regA[B]);
}

void JitCompiler::EmitMOVEV2()
{
	cc.movsd(regF[A], regF[B]);
	cc.movsd(regF[A + 1], regF[B + 1]);
}

void JitCompiler::EmitMOVEV3()
{
	cc.movsd(regF[A], regF[B]);
	cc.movsd(regF[A + 1], regF[B + 1]);
	cc.movsd(regF[A + 2], regF[B + 2]);
}

void JitCompiler::EmitCAST()
{
	switch (C)
	{
	case CAST_I2F:
		cc.cvtsi2sd(regF[A], regD[B]);
		break;
	case CAST_U2F:
	{
		auto tmp = cc.newInt64();
		cc.xor_(tmp, tmp);
		cc.mov(tmp.r32(), regD[B]);
		cc.cvtsi2sd(regF[A], tmp);
		break;
	}
	case CAST_F2I:
		cc.cvttsd2si(regD[A], regF[B]);
		break;
	case CAST_F2U:
	{
		auto tmp = cc.newInt64();
		cc.cvttsd2si(tmp, regF[B]);
		cc.mov(regD[A], tmp.r32());
		break;
	}
	/*case CAST_I2S:
		reg.s[A].Format("%d", reg.d[B]);
		break;
	case CAST_U2S:
		reg.s[A].Format("%u", reg.d[B]);
		break;
	case CAST_F2S:
		reg.s[A].Format("%.5f", reg.f[B]);	// keep this small. For more precise conversion there should be a conversion function.
		break;
	case CAST_V22S:
		reg.s[A].Format("(%.5f, %.5f)", reg.f[B], reg.f[b + 1]);
		break;
	case CAST_V32S:
		reg.s[A].Format("(%.5f, %.5f, %.5f)", reg.f[B], reg.f[b + 1], reg.f[b + 2]);
		break;
	case CAST_P2S:
	{
		if (reg.a[B] == nullptr) reg.s[A] = "null";
		else reg.s[A].Format("%p", reg.a[B]);
		break;
	}
	case CAST_S2I:
		reg.d[A] = (VM_SWORD)reg.s[B].ToLong();
		break;
	case CAST_S2F:
		reg.f[A] = reg.s[B].ToDouble();
		break;
	case CAST_S2N:
		reg.d[A] = reg.s[B].Len() == 0 ? FName(NAME_None) : FName(reg.s[B]);
		break;
	case CAST_N2S:
	{
		FName name = FName(ENamedName(reg.d[B]));
		reg.s[A] = name.IsValidName() ? name.GetChars() : "";
		break;
	}
	case CAST_S2Co:
		reg.d[A] = V_GetColor(NULL, reg.s[B]);
		break;
	case CAST_Co2S:
		reg.s[A].Format("%02x %02x %02x", PalEntry(reg.d[B]).r, PalEntry(reg.d[B]).g, PalEntry(reg.d[B]).b);
		break;
	case CAST_S2So:
		reg.d[A] = FSoundID(reg.s[B]);
		break;
	case CAST_So2S:
		reg.s[A] = S_sfx[reg.d[B]].name;
		break;
	case CAST_SID2S:
		reg.s[A] = unsigned(reg.d[B]) >= sprites.Size() ? "TNT1" : sprites[reg.d[B]].name;
		break;
	case CAST_TID2S:
	{
		auto tex = TexMan[*(FTextureID*)&(reg.d[B])];
		reg.s[A] = tex == nullptr ? "(null)" : tex->Name.GetChars();
		break;
	}*/
	default:
		assert(0);
	}
}

void JitCompiler::EmitCASTB()
{
	if (C == CASTB_I)
	{
		cc.mov(regD[A], regD[B]);
		cc.shr(regD[A], 31);
	}
	else if (C == CASTB_F)
	{
		auto zero = cc.newXmm();
		auto one = cc.newInt32();
		cc.xorpd(zero, zero);
		cc.mov(one, 1);
		cc.ucomisd(regF[A], zero);
		cc.setp(regD[A]);
		cc.cmovne(regD[A], one);
	}
	else if (C == CASTB_A)
	{
		cc.test(regA[A], regA[A]);
		cc.setne(regD[A]);
	}
	else
	{
		using namespace asmjit;
		typedef int(*FuncPtr)(FString*);
		auto call = cc.call(ToMemAddress(reinterpret_cast<const void*>(static_cast<FuncPtr>([](FString *s) -> int {
			return s->Len() > 0;
		}))), FuncSignature1<int, void*>());
		call->setRet(0, regD[A]);
		call->setArg(0, regS[B]);
	}
}

void JitCompiler::EmitDYNCAST_R()
{
	using namespace asmjit;
	typedef DObject*(*FuncPtr)(DObject*, PClass*);
	auto call = cc.call(ToMemAddress(reinterpret_cast<const void*>(static_cast<FuncPtr>([](DObject *obj, PClass *cls) -> DObject* {
		return (obj && obj->IsKindOf(cls)) ? obj : nullptr;
	}))), FuncSignature2<void*, void*, void*>());
	call->setRet(0, regA[A]);
	call->setArg(0, regA[B]);
	call->setArg(1, regA[C]);
}

void JitCompiler::EmitDYNCAST_K()
{
	using namespace asmjit;
	auto c = cc.newIntPtr();
	cc.mov(c, ToMemAddress(konsta[C].o));
	typedef DObject*(*FuncPtr)(DObject*, PClass*);
	auto call = cc.call(ToMemAddress(reinterpret_cast<const void*>(static_cast<FuncPtr>([](DObject *obj, PClass *cls) -> DObject* {
		return (obj && obj->IsKindOf(cls)) ? obj : nullptr;
	}))), FuncSignature2<void*, void*, void*>());
	call->setRet(0, regA[A]);
	call->setArg(0, regA[B]);
	call->setArg(1, c);
}

void JitCompiler::EmitDYNCASTC_R()
{
	using namespace asmjit;
	typedef PClass*(*FuncPtr)(PClass*, PClass*);
	auto call = cc.call(ToMemAddress(reinterpret_cast<const void*>(static_cast<FuncPtr>([](PClass *cls1, PClass *cls2) -> PClass* {
		return (cls1 && cls1->IsDescendantOf(cls2)) ? cls1 : nullptr;
	}))), FuncSignature2<void*, void*, void*>());
	call->setRet(0, regA[A]);
	call->setArg(0, regA[B]);
	call->setArg(1, regA[C]);
}

void JitCompiler::EmitDYNCASTC_K()
{
	using namespace asmjit;
	auto c = cc.newIntPtr();
	cc.mov(c, ToMemAddress(konsta[C].o));
	typedef PClass*(*FuncPtr)(PClass*, PClass*);
	auto call = cc.call(ToMemAddress(reinterpret_cast<const void*>(static_cast<FuncPtr>([](PClass *cls1, PClass *cls2) -> PClass* {
		return (cls1 && cls1->IsDescendantOf(cls2)) ? cls1 : nullptr;
	}))), FuncSignature2<void*, void*, void*>());
	call->setRet(0, regA[A]);
	call->setArg(0, regA[B]);
	call->setArg(1, c);
}
- split JitCompiler into multiple files 2018-09-13 00:29:04 +00:00
			`#include "jitintern.h"`

			`void JitCompiler::EmitMOVE()`
			`{`
			`cc.mov(regD[A], regD[B]);`
			`}`
			`void JitCompiler::EmitMOVEF()`
			`{`
			`cc.movsd(regF[A], regF[B]);`
			`}`

			`void JitCompiler::EmitMOVES()`
			`{`
- added string PARAM and RET 2018-09-14 17:20:31 +00:00			`auto call = cc.call(ToMemAddress(reinterpret_cast<void>(static_cast<void()(FString, FString)>(CallAssignString))),`
- added OP_MOVES, OP_CONCAT, OP_LENS, OP_CMPS 2018-09-13 19:31:06 +00:00			`asmjit::FuncSignature2<void, FString, FString>(asmjit::CallConv::kIdHostCDecl));`
			`call->setArg(0, regS[A]);`
			`call->setArg(1, regS[B]);`
- split JitCompiler into multiple files 2018-09-13 00:29:04 +00:00			`}`

			`void JitCompiler::EmitMOVEA()`
			`{`
			`cc.mov(regA[A], regA[B]);`
			`}`

			`void JitCompiler::EmitMOVEV2()`
			`{`
			`cc.movsd(regF[A], regF[B]);`
			`cc.movsd(regF[A + 1], regF[B + 1]);`
			`}`

			`void JitCompiler::EmitMOVEV3()`
			`{`
			`cc.movsd(regF[A], regF[B]);`
			`cc.movsd(regF[A + 1], regF[B + 1]);`
			`cc.movsd(regF[A + 2], regF[B + 2]);`
			`}`

			`void JitCompiler::EmitCAST()`
			`{`
			`switch (C)`
			`{`
			`case CAST_I2F:`
			`cc.cvtsi2sd(regF[A], regD[B]);`
			`break;`
			`case CAST_U2F:`
			`{`
			`auto tmp = cc.newInt64();`
			`cc.xor_(tmp, tmp);`
			`cc.mov(tmp.r32(), regD[B]);`
			`cc.cvtsi2sd(regF[A], tmp);`
			`break;`
			`}`
			`case CAST_F2I:`
			`cc.cvttsd2si(regD[A], regF[B]);`
			`break;`
			`case CAST_F2U:`
			`{`
			`auto tmp = cc.newInt64();`
			`cc.cvttsd2si(tmp, regF[B]);`
			`cc.mov(regD[A], tmp.r32());`
			`break;`
			`}`
			`/*case CAST_I2S:`
			`reg.s[A].Format("%d", reg.d[B]);`
			`break;`
			`case CAST_U2S:`
			`reg.s[A].Format("%u", reg.d[B]);`
			`break;`
			`case CAST_F2S:`
			`reg.s[A].Format("%.5f", reg.f[B]); // keep this small. For more precise conversion there should be a conversion function.`
			`break;`
			`case CAST_V22S:`
			`reg.s[A].Format("(%.5f, %.5f)", reg.f[B], reg.f[b + 1]);`
			`break;`
			`case CAST_V32S:`
			`reg.s[A].Format("(%.5f, %.5f, %.5f)", reg.f[B], reg.f[b + 1], reg.f[b + 2]);`
			`break;`
			`case CAST_P2S:`
			`{`
			`if (reg.a[B] == nullptr) reg.s[A] = "null";`
			`else reg.s[A].Format("%p", reg.a[B]);`
			`break;`
			`}`
			`case CAST_S2I:`
			`reg.d[A] = (VM_SWORD)reg.s[B].ToLong();`
			`break;`
			`case CAST_S2F:`
			`reg.f[A] = reg.s[B].ToDouble();`
			`break;`
			`case CAST_S2N:`
			`reg.d[A] = reg.s[B].Len() == 0 ? FName(NAME_None) : FName(reg.s[B]);`
			`break;`
			`case CAST_N2S:`
			`{`
			`FName name = FName(ENamedName(reg.d[B]));`
			`reg.s[A] = name.IsValidName() ? name.GetChars() : "";`
			`break;`
			`}`
			`case CAST_S2Co:`
			`reg.d[A] = V_GetColor(NULL, reg.s[B]);`
			`break;`
			`case CAST_Co2S:`
			`reg.s[A].Format("%02x %02x %02x", PalEntry(reg.d[B]).r, PalEntry(reg.d[B]).g, PalEntry(reg.d[B]).b);`
			`break;`
			`case CAST_S2So:`
			`reg.d[A] = FSoundID(reg.s[B]);`
			`break;`
			`case CAST_So2S:`
			`reg.s[A] = S_sfx[reg.d[B]].name;`
			`break;`
			`case CAST_SID2S:`
			`reg.s[A] = unsigned(reg.d[B]) >= sprites.Size() ? "TNT1" : sprites[reg.d[B]].name;`
			`break;`
			`case CAST_TID2S:`
			`{`
			`auto tex = TexMan[(FTextureID)&(reg.d[B])];`
			`reg.s[A] = tex == nullptr ? "(null)" : tex->Name.GetChars();`
			`break;`
			`}*/`
			`default:`
			`assert(0);`
			`}`
			`}`

			`void JitCompiler::EmitCASTB()`
			`{`
			`if (C == CASTB_I)`
			`{`
			`cc.mov(regD[A], regD[B]);`
			`cc.shr(regD[A], 31);`
			`}`
			`else if (C == CASTB_F)`
			`{`
			`auto zero = cc.newXmm();`
			`auto one = cc.newInt32();`
			`cc.xorpd(zero, zero);`
			`cc.mov(one, 1);`
			`cc.ucomisd(regF[A], zero);`
			`cc.setp(regD[A]);`
			`cc.cmovne(regD[A], one);`
			`}`
			`else if (C == CASTB_A)`
			`{`
			`cc.test(regA[A], regA[A]);`
			`cc.setne(regD[A]);`
			`}`
			`else`
			`{`
- implement string part of OP_CASTB 2018-09-16 20:39:48 +00:00			`using namespace asmjit;`
			`typedef int(FuncPtr)(FString);`
			`auto call = cc.call(ToMemAddress(reinterpret_cast<const void>(static_cast<FuncPtr>([](FString s) -> int {`
			`return s->Len() > 0;`
			`}))), FuncSignature1<int, void*>());`
			`call->setRet(0, regD[A]);`
			`call->setArg(0, regS[B]);`
- split JitCompiler into multiple files 2018-09-13 00:29:04 +00:00			`}`
			`}`

			`void JitCompiler::EmitDYNCAST_R()`
			`{`
			`using namespace asmjit;`
			`typedef DObject(FuncPtr)(DObject, PClass);`
			`auto call = cc.call(ToMemAddress(reinterpret_cast<const void>(static_cast<FuncPtr>([](DObject obj, PClass cls) -> DObject {`
			`return (obj && obj->IsKindOf(cls)) ? obj : nullptr;`
			`}))), FuncSignature2<void, void, void*>());`
			`call->setRet(0, regA[A]);`
			`call->setArg(0, regA[B]);`
			`call->setArg(1, regA[C]);`
			`}`

			`void JitCompiler::EmitDYNCAST_K()`
			`{`
			`using namespace asmjit;`
			`auto c = cc.newIntPtr();`
			`cc.mov(c, ToMemAddress(konsta[C].o));`
			`typedef DObject(FuncPtr)(DObject, PClass);`
			`auto call = cc.call(ToMemAddress(reinterpret_cast<const void>(static_cast<FuncPtr>([](DObject obj, PClass cls) -> DObject {`
			`return (obj && obj->IsKindOf(cls)) ? obj : nullptr;`
			`}))), FuncSignature2<void, void, void*>());`
			`call->setRet(0, regA[A]);`
			`call->setArg(0, regA[B]);`
			`call->setArg(1, c);`
			`}`

			`void JitCompiler::EmitDYNCASTC_R()`
			`{`
			`using namespace asmjit;`
			`typedef PClass(FuncPtr)(PClass, PClass);`
			`auto call = cc.call(ToMemAddress(reinterpret_cast<const void>(static_cast<FuncPtr>([](PClass cls1, PClass cls2) -> PClass {`
			`return (cls1 && cls1->IsDescendantOf(cls2)) ? cls1 : nullptr;`
			`}))), FuncSignature2<void, void, void*>());`
			`call->setRet(0, regA[A]);`
			`call->setArg(0, regA[B]);`
			`call->setArg(1, regA[C]);`
			`}`

			`void JitCompiler::EmitDYNCASTC_K()`
			`{`
			`using namespace asmjit;`
			`auto c = cc.newIntPtr();`
			`cc.mov(c, ToMemAddress(konsta[C].o));`
			`typedef PClass(FuncPtr)(PClass, PClass);`
			`auto call = cc.call(ToMemAddress(reinterpret_cast<const void>(static_cast<FuncPtr>([](PClass cls1, PClass cls2) -> PClass {`
			`return (cls1 && cls1->IsDescendantOf(cls2)) ? cls1 : nullptr;`
			`}))), FuncSignature2<void, void, void*>());`
			`call->setRet(0, regA[A]);`
			`call->setArg(0, regA[B]);`
			`call->setArg(1, c);`
			`}`