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view gen/tollvm.cpp @ 1138:4c8bb03e4fbc
Update DtoConstFP() to be correct after LLVM r67562, which changed the way the
APFloat constructor expects its i80 APInts to be formatted. (They're now
actually consistent with the x87 format)
| author | Frits van Bommel <fvbommel wxs.nl> |
|---|---|
| date | Tue, 24 Mar 2009 15:24:59 +0100 |
| parents | f0b6549055ab |
| children | 71479f6e2a01 |
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#include "gen/llvm.h" #include "dsymbol.h" #include "aggregate.h" #include "declaration.h" #include "init.h" #include "module.h" #include "gen/tollvm.h" #include "gen/irstate.h" #include "gen/logger.h" #include "gen/runtime.h" #include "gen/arrays.h" #include "gen/dvalue.h" #include "gen/functions.h" #include "gen/structs.h" #include "gen/classes.h" #include "gen/typeinf.h" #include "gen/complex.h" #include "gen/llvmhelpers.h" #include "gen/linkage.h" #include "gen/llvm-version.h" bool DtoIsPassedByRef(Type* type) { Type* typ = type->toBasetype(); TY t = typ->ty; return (t == Tstruct || t == Tsarray); } unsigned DtoShouldExtend(Type* type) { type = type->toBasetype(); if (type->isintegral()) { switch(type->ty) { case Tint8: case Tint16: return llvm::Attribute::SExt; case Tuns8: case Tuns16: return llvm::Attribute::ZExt; } } return llvm::Attribute::None; } const LLType* DtoType(Type* t) { assert(t); switch (t->ty) { // integers case Tint8: case Tuns8: case Tchar: return (const LLType*)LLType::Int8Ty; case Tint16: case Tuns16: case Twchar: return (const LLType*)LLType::Int16Ty; case Tint32: case Tuns32: case Tdchar: return (const LLType*)LLType::Int32Ty; case Tint64: case Tuns64: return (const LLType*)LLType::Int64Ty; case Tbool: return (const LLType*)llvm::ConstantInt::getTrue()->getType(); // floats case Tfloat32: case Timaginary32: return LLType::FloatTy; case Tfloat64: case Timaginary64: return LLType::DoubleTy; case Tfloat80: case Timaginary80: if (global.params.cpu == ARCHx86 || global.params.cpu == ARCHx86_64) return LLType::X86_FP80Ty; else return LLType::DoubleTy; // complex case Tcomplex32: case Tcomplex64: case Tcomplex80: return DtoComplexType(t); // pointers case Tpointer: // getPtrToType checks for void itself return getPtrToType(DtoType(t->nextOf())); // arrays case Tarray: return DtoArrayType(t); case Tsarray: return DtoStaticArrayType(t); // void case Tvoid: return LLType::VoidTy; // aggregates case Tstruct: { #if DMDV2 TypeStruct* ts = (TypeStruct*)t->mutableOf(); #else TypeStruct* ts = (TypeStruct*)t; #endif assert(ts->sym); DtoResolveDsymbol(ts->sym); return ts->ir.type->get(); } case Tclass: { #if DMDV2 TypeClass* tc = (TypeClass*)t->mutableOf(); #else TypeClass* tc = (TypeClass*)t; #endif assert(tc->sym); DtoResolveDsymbol(tc->sym); return getPtrToType(tc->ir.type->get()); } // functions case Tfunction: { if (!t->ir.type || *t->ir.type == NULL) { return DtoFunctionType(t,NULL,NULL); } else { return t->ir.type->get(); } } // delegates case Tdelegate: { if (!t->ir.type || *t->ir.type == NULL) { return DtoDelegateType(t); } else { return t->ir.type->get(); } } // typedefs // enum case Ttypedef: case Tenum: { Type* bt = t->toBasetype(); assert(bt); return DtoType(bt); } // associative arrays case Taarray: #if 1 return getVoidPtrType(); #else { TypeAArray* taa = (TypeAArray*)t; // aa key/val can't be void return getPtrToType(LLStructType::get(DtoType(taa->key), DtoType(taa->next), 0)); } #endif /* Not needed atm as VarDecls for tuples are rewritten as a string of VarDecls for the fields (u -> _u_field_0, ...) case Ttuple: { TypeTuple* ttupl = (TypeTuple*)t; return DtoStructTypeFromArguments(ttupl->arguments); } */ default: printf("trying to convert unknown type '%s' with value %d\n", t->toChars(), t->ty); assert(0); } return 0; } ////////////////////////////////////////////////////////////////////////////////////////// /* const LLType* DtoStructTypeFromArguments(Arguments* arguments) { if (!arguments) return LLType::VoidTy; std::vector<const LLType*> types; for (size_t i = 0; i < arguments->dim; i++) { Argument *arg = (Argument *)arguments->data[i]; assert(arg && arg->type); types.push_back(DtoType(arg->type)); } return LLStructType::get(types); } */ ////////////////////////////////////////////////////////////////////////////////////////// const LLType* DtoTypeNotVoid(Type* t) { const LLType* lt = DtoType(t); if (lt == LLType::VoidTy) return LLType::Int8Ty; return lt; } ////////////////////////////////////////////////////////////////////////////////////////// const LLStructType* DtoDelegateType(Type* t) { assert(t->ty == Tdelegate); const LLType* i8ptr = getVoidPtrType(); const LLType* func = DtoFunctionType(t->nextOf(), NULL, Type::tvoid->pointerTo()); const LLType* funcptr = getPtrToType(func); return LLStructType::get(i8ptr, funcptr, NULL); } ////////////////////////////////////////////////////////////////////////////////////////// LLValue* DtoDelegateEquals(TOK op, LLValue* lhs, LLValue* rhs) { Logger::println("Doing delegate equality"); llvm::Value *b1, *b2; if (rhs == NULL) { rhs = LLConstant::getNullValue(lhs->getType()); } LLValue* l = gIR->ir->CreateExtractValue(lhs, 0); LLValue* r = gIR->ir->CreateExtractValue(rhs, 0); b1 = gIR->ir->CreateICmp(llvm::ICmpInst::ICMP_EQ,l,r,"tmp"); l = gIR->ir->CreateExtractValue(lhs, 1); r = gIR->ir->CreateExtractValue(rhs, 1); b2 = gIR->ir->CreateICmp(llvm::ICmpInst::ICMP_EQ,l,r,"tmp"); LLValue* b = gIR->ir->CreateAnd(b1,b2,"tmp"); if (op == TOKnotequal || op == TOKnotidentity) return gIR->ir->CreateNot(b,"tmp"); return b; } ////////////////////////////////////////////////////////////////////////////////////////// LLGlobalValue::LinkageTypes DtoLinkage(Dsymbol* sym) { // global variable if (VarDeclaration* vd = sym->isVarDeclaration()) { // template if (needsTemplateLinkage(sym)) return TEMPLATE_LINKAGE_TYPE; // local static else if (sym->parent && sym->parent->isFuncDeclaration()) return llvm::GlobalValue::InternalLinkage; } // function else if (FuncDeclaration* fdecl = sym->isFuncDeclaration()) { assert(fdecl->type->ty == Tfunction); TypeFunction* ft = (TypeFunction*)fdecl->type; // array operations are always internal if (fdecl->isArrayOp) return llvm::GlobalValue::InternalLinkage; // intrinsics are always external if (fdecl->llvmInternal == LLVMintrinsic) return llvm::GlobalValue::ExternalLinkage; // template instances should have weak linkage // but only if there's a body, and it's not naked // otherwise we make it external else if (needsTemplateLinkage(fdecl) && fdecl->fbody && !fdecl->naked) return TEMPLATE_LINKAGE_TYPE; // extern(C) functions are always external else if (ft->linkage == LINKc) return llvm::GlobalValue::ExternalLinkage; } // class else if (ClassDeclaration* cd = sym->isClassDeclaration()) { // template if (needsTemplateLinkage(cd)) return TEMPLATE_LINKAGE_TYPE; } else { assert(0 && "not global/function"); } // default to external linkage return llvm::GlobalValue::ExternalLinkage; } llvm::GlobalValue::LinkageTypes DtoInternalLinkage(Dsymbol* sym) { if (needsTemplateLinkage(sym)) return TEMPLATE_LINKAGE_TYPE; else return llvm::GlobalValue::InternalLinkage; } llvm::GlobalValue::LinkageTypes DtoExternalLinkage(Dsymbol* sym) { if (needsTemplateLinkage(sym)) return TEMPLATE_LINKAGE_TYPE; else return llvm::GlobalValue::ExternalLinkage; } ////////////////////////////////////////////////////////////////////////////////////////// LLValue* DtoPointedType(LLValue* ptr, LLValue* val) { const LLType* ptrTy = ptr->getType()->getContainedType(0); const LLType* valTy = val->getType(); // ptr points to val's type if (ptrTy == valTy) { return val; } // ptr is integer pointer else if (ptrTy->isInteger()) { // val is integer assert(valTy->isInteger()); const LLIntegerType* pt = llvm::cast<const LLIntegerType>(ptrTy); const LLIntegerType* vt = llvm::cast<const LLIntegerType>(valTy); if (pt->getBitWidth() < vt->getBitWidth()) { return new llvm::TruncInst(val, pt, "tmp", gIR->scopebb()); } else assert(0); } // something else unsupported else { if (Logger::enabled()) Logger::cout() << *ptrTy << '|' << *valTy << '\n'; assert(0); } return 0; } ////////////////////////////////////////////////////////////////////////////////////////// const LLType* DtoSize_t() { // the type of size_t does not change once set static const LLType* t = NULL; if (t == NULL) t = (global.params.is64bit) ? LLType::Int64Ty : LLType::Int32Ty; return t; } ////////////////////////////////////////////////////////////////////////////////////////// LLValue* DtoGEP1(LLValue* ptr, LLValue* i0, const char* var, llvm::BasicBlock* bb) { return llvm::GetElementPtrInst::Create(ptr, i0, var?var:"tmp", bb?bb:gIR->scopebb()); } ////////////////////////////////////////////////////////////////////////////////////////// LLValue* DtoGEP(LLValue* ptr, LLValue* i0, LLValue* i1, const char* var, llvm::BasicBlock* bb) { LLSmallVector<LLValue*,2> v(2); v[0] = i0; v[1] = i1; return llvm::GetElementPtrInst::Create(ptr, v.begin(), v.end(), var?var:"tmp", bb?bb:gIR->scopebb()); } ////////////////////////////////////////////////////////////////////////////////////////// LLValue* DtoGEPi1(LLValue* ptr, unsigned i, const char* var, llvm::BasicBlock* bb) { return llvm::GetElementPtrInst::Create(ptr, DtoConstUint(i), var?var:"tmp", bb?bb:gIR->scopebb()); } ////////////////////////////////////////////////////////////////////////////////////////// LLValue* DtoGEPi(LLValue* ptr, unsigned i0, unsigned i1, const char* var, llvm::BasicBlock* bb) { LLSmallVector<LLValue*,2> v(2); v[0] = DtoConstUint(i0); v[1] = DtoConstUint(i1); return llvm::GetElementPtrInst::Create(ptr, v.begin(), v.end(), var?var:"tmp", bb?bb:gIR->scopebb()); } ////////////////////////////////////////////////////////////////////////////////////////// void DtoMemSetZero(LLValue* dst, LLValue* nbytes) { dst = DtoBitCast(dst,getVoidPtrType()); const LLType* intTy = DtoSize_t(); llvm::Function* fn = llvm::Intrinsic::getDeclaration(gIR->module, llvm::Intrinsic::memset, &intTy, 1); gIR->ir->CreateCall4(fn, dst, DtoConstUbyte(0), nbytes, DtoConstUint(0), ""); } ////////////////////////////////////////////////////////////////////////////////////////// void DtoMemCpy(LLValue* dst, LLValue* src, LLValue* nbytes) { dst = DtoBitCast(dst,getVoidPtrType()); src = DtoBitCast(src,getVoidPtrType()); const LLType* intTy = DtoSize_t(); llvm::Function* fn = llvm::Intrinsic::getDeclaration(gIR->module, llvm::Intrinsic::memcpy, &intTy, 1); gIR->ir->CreateCall4(fn, dst, src, nbytes, DtoConstUint(0), ""); } ////////////////////////////////////////////////////////////////////////////////////////// LLValue* DtoMemCmp(LLValue* lhs, LLValue* rhs, LLValue* nbytes) { // int memcmp ( const void * ptr1, const void * ptr2, size_t num ); LLFunction* fn = gIR->module->getFunction("memcmp"); if (!fn) { std::vector<const LLType*> params(3); params[0] = getVoidPtrType(); params[1] = getVoidPtrType(); params[2] = DtoSize_t(); const LLFunctionType* fty = LLFunctionType::get(LLType::Int32Ty, params, false); fn = LLFunction::Create(fty, LLGlobalValue::ExternalLinkage, "memcmp", gIR->module); } lhs = DtoBitCast(lhs,getVoidPtrType()); rhs = DtoBitCast(rhs,getVoidPtrType()); return gIR->ir->CreateCall3(fn, lhs, rhs, nbytes, "tmp"); } ////////////////////////////////////////////////////////////////////////////////////////// void DtoAggrZeroInit(LLValue* v) { uint64_t n = getTypeStoreSize(v->getType()->getContainedType(0)); DtoMemSetZero(v, DtoConstSize_t(n)); } ////////////////////////////////////////////////////////////////////////////////////////// void DtoAggrCopy(LLValue* dst, LLValue* src) { uint64_t n = getTypeStoreSize(dst->getType()->getContainedType(0)); DtoMemCpy(dst, src, DtoConstSize_t(n)); } ////////////////////////////////////////////////////////////////////////////////////////// void DtoMemoryBarrier(bool ll, bool ls, bool sl, bool ss, bool device) { llvm::Function* fn = GET_INTRINSIC_DECL(memory_barrier); assert(fn != NULL); LLSmallVector<LLValue*, 5> llargs; llargs.push_back(DtoConstBool(ll)); llargs.push_back(DtoConstBool(ls)); llargs.push_back(DtoConstBool(sl)); llargs.push_back(DtoConstBool(ss)); llargs.push_back(DtoConstBool(device)); llvm::CallInst::Create(fn, llargs.begin(), llargs.end(), "", gIR->scopebb()); } ////////////////////////////////////////////////////////////////////////////////////////// llvm::ConstantInt* DtoConstSize_t(size_t i) { return llvm::ConstantInt::get(DtoSize_t(), i, false); } llvm::ConstantInt* DtoConstUint(unsigned i) { return llvm::ConstantInt::get(LLType::Int32Ty, i, false); } llvm::ConstantInt* DtoConstInt(int i) { return llvm::ConstantInt::get(LLType::Int32Ty, i, true); } LLConstant* DtoConstBool(bool b) { return llvm::ConstantInt::get(LLType::Int1Ty, b, false); } llvm::ConstantInt* DtoConstUbyte(unsigned char i) { return llvm::ConstantInt::get(LLType::Int8Ty, i, false); } llvm::ConstantFP* DtoConstFP(Type* t, long double value) { const LLType* llty = DtoType(t); assert(llty->isFloatingPoint()); if(llty == LLType::FloatTy || llty == LLType::DoubleTy) return LLConstantFP::get(llty, value); else if(llty == LLType::X86_FP80Ty) { uint64_t bits[] = {0, 0}; #if LLVM_REV < 67562 // Prior to r67562, the i80 APInt format expected by the APFloat // constructor was different than the memory layout on the actual // processor. bits[1] = *(uint16_t*)&value; bits[0] = *(uint64_t*)((uint16_t*)&value + 1); #else bits[0] = *(uint64_t*)&value; bits[1] = *(uint16_t*)((uint64_t*)&value + 1); #endif return LLConstantFP::get(APFloat(APInt(80, 2, bits))); } else { assert(0 && "Unknown floating point type encountered"); } } ////////////////////////////////////////////////////////////////////////////////////////// LLConstant* DtoConstString(const char* str) { std::string s(str?str:""); LLConstant* init = llvm::ConstantArray::get(s, true); llvm::GlobalVariable* gvar = new llvm::GlobalVariable( init->getType(), true,llvm::GlobalValue::InternalLinkage, init, ".str", gIR->module); LLConstant* idxs[2] = { DtoConstUint(0), DtoConstUint(0) }; return DtoConstSlice( DtoConstSize_t(s.length()), llvm::ConstantExpr::getGetElementPtr(gvar,idxs,2) ); } LLConstant* DtoConstStringPtr(const char* str, const char* section) { std::string s(str); LLConstant* init = llvm::ConstantArray::get(s, true); llvm::GlobalVariable* gvar = new llvm::GlobalVariable( init->getType(), true,llvm::GlobalValue::InternalLinkage, init, ".str", gIR->module); if (section) gvar->setSection(section); LLConstant* idxs[2] = { DtoConstUint(0), DtoConstUint(0) }; return llvm::ConstantExpr::getGetElementPtr(gvar,idxs,2); } ////////////////////////////////////////////////////////////////////////////////////////// LLValue* DtoLoad(LLValue* src, const char* name) { // if (Logger::enabled()) // Logger::cout() << "loading " << *src << '\n'; LLValue* ld = gIR->ir->CreateLoad(src, name ? name : "tmp"); //ld->setVolatile(gIR->func()->inVolatile); return ld; } void DtoStore(LLValue* src, LLValue* dst) { // if (Logger::enabled()) // Logger::cout() << "storing " << *src << " into " << *dst << '\n'; LLValue* st = gIR->ir->CreateStore(src,dst); //st->setVolatile(gIR->func()->inVolatile); } ////////////////////////////////////////////////////////////////////////////////////////// LLValue* DtoBitCast(LLValue* v, const LLType* t, const char* name) { if (v->getType() == t) return v; assert(!isaStruct(t)); return gIR->ir->CreateBitCast(v, t, name ? name : "tmp"); } LLConstant* DtoBitCast(LLConstant* v, const LLType* t) { if (v->getType() == t) return v; return llvm::ConstantExpr::getBitCast(v, t); } ////////////////////////////////////////////////////////////////////////////////////////// const LLPointerType* isaPointer(LLValue* v) { return llvm::dyn_cast<LLPointerType>(v->getType()); } const LLPointerType* isaPointer(const LLType* t) { return llvm::dyn_cast<LLPointerType>(t); } const LLArrayType* isaArray(LLValue* v) { return llvm::dyn_cast<LLArrayType>(v->getType()); } const LLArrayType* isaArray(const LLType* t) { return llvm::dyn_cast<LLArrayType>(t); } const LLStructType* isaStruct(LLValue* v) { return llvm::dyn_cast<LLStructType>(v->getType()); } const LLStructType* isaStruct(const LLType* t) { return llvm::dyn_cast<LLStructType>(t); } const LLFunctionType* isaFunction(LLValue* v) { return llvm::dyn_cast<LLFunctionType>(v->getType()); } const LLFunctionType* isaFunction(const LLType* t) { return llvm::dyn_cast<LLFunctionType>(t); } LLConstant* isaConstant(LLValue* v) { return llvm::dyn_cast<llvm::Constant>(v); } llvm::ConstantInt* isaConstantInt(LLValue* v) { return llvm::dyn_cast<llvm::ConstantInt>(v); } llvm::Argument* isaArgument(LLValue* v) { return llvm::dyn_cast<llvm::Argument>(v); } llvm::GlobalVariable* isaGlobalVar(LLValue* v) { return llvm::dyn_cast<llvm::GlobalVariable>(v); } ////////////////////////////////////////////////////////////////////////////////////////// const LLPointerType* getPtrToType(const LLType* t) { if (t == LLType::VoidTy) t = LLType::Int8Ty; return LLPointerType::get(t, 0); } const LLPointerType* getVoidPtrType() { return getPtrToType(LLType::Int8Ty); } llvm::ConstantPointerNull* getNullPtr(const LLType* t) { const LLPointerType* pt = llvm::cast<LLPointerType>(t); return llvm::ConstantPointerNull::get(pt); } LLConstant* getNullValue(const LLType* t) { return LLConstant::getNullValue(t); } ////////////////////////////////////////////////////////////////////////////////////////// size_t getTypeBitSize(const LLType* t) { return gTargetData->getTypeSizeInBits(t); } size_t getTypeStoreSize(const LLType* t) { return gTargetData->getTypeStoreSize(t); } size_t getTypePaddedSize(const LLType* t) { size_t sz = gTargetData->getTypePaddedSize(t); //Logger::cout() << "abi type size of: " << *t << " == " << sz << '\n'; return sz; } unsigned char getABITypeAlign(const LLType* t) { return gTargetData->getABITypeAlignment(t); } unsigned char getPrefTypeAlign(const LLType* t) { return gTargetData->getPrefTypeAlignment(t); } const LLType* getBiggestType(const LLType** begin, size_t n) { const LLType* bigTy = 0; size_t bigSize = 0; size_t bigAlign = 0; const LLType** end = begin+n; while (begin != end) { const LLType* T = *begin; size_t sz = getTypePaddedSize(T); size_t ali = getABITypeAlign(T); if (sz > bigSize || (sz == bigSize && ali > bigAlign)) { bigTy = T; bigSize = sz; bigAlign = ali; } ++begin; } // will be null for n==0 return bigTy; } ////////////////////////////////////////////////////////////////////////////////////////// const LLStructType* DtoInterfaceInfoType() { if (gIR->interfaceInfoType) return gIR->interfaceInfoType; // build interface info type std::vector<const LLType*> types; // ClassInfo classinfo ClassDeclaration* cd2 = ClassDeclaration::classinfo; DtoResolveClass(cd2); types.push_back(getPtrToType(cd2->type->ir.type->get())); // void*[] vtbl std::vector<const LLType*> vtbltypes; vtbltypes.push_back(DtoSize_t()); const LLType* byteptrptrty = getPtrToType(getPtrToType(LLType::Int8Ty)); vtbltypes.push_back(byteptrptrty); types.push_back(LLStructType::get(vtbltypes)); // int offset types.push_back(LLType::Int32Ty); // create type gIR->interfaceInfoType = LLStructType::get(types); return gIR->interfaceInfoType; } ////////////////////////////////////////////////////////////////////////////////////////// const LLStructType* DtoMutexType() { if (gIR->mutexType) return gIR->mutexType; // win32 if (global.params.os == OSWindows) { // CRITICAL_SECTION.sizeof == 68 std::vector<const LLType*> types(17, LLType::Int32Ty); return LLStructType::get(types); } // FreeBSD else if (global.params.os == OSFreeBSD) { // Just a pointer return LLStructType::get(DtoSize_t(), NULL); } // pthread_fastlock std::vector<const LLType*> types2; types2.push_back(DtoSize_t()); types2.push_back(LLType::Int32Ty); const LLStructType* fastlock = LLStructType::get(types2); // pthread_mutex std::vector<const LLType*> types1; types1.push_back(LLType::Int32Ty); types1.push_back(LLType::Int32Ty); types1.push_back(getVoidPtrType()); types1.push_back(LLType::Int32Ty); types1.push_back(fastlock); const LLStructType* pmutex = LLStructType::get(types1); // D_CRITICAL_SECTION LLOpaqueType* opaque = LLOpaqueType::get(); std::vector<const LLType*> types; types.push_back(getPtrToType(opaque)); types.push_back(pmutex); // resolve type pmutex = LLStructType::get(types); LLPATypeHolder pa(pmutex); opaque->refineAbstractTypeTo(pa.get()); pmutex = isaStruct(pa.get()); gIR->mutexType = pmutex; gIR->module->addTypeName("D_CRITICAL_SECTION", pmutex); return pmutex; } ////////////////////////////////////////////////////////////////////////////////////////// const LLStructType* DtoModuleReferenceType() { if (gIR->moduleRefType) return gIR->moduleRefType; // this is a recursive type so start out with the opaque LLOpaqueType* opaque = LLOpaqueType::get(); // add members std::vector<const LLType*> types; types.push_back(getPtrToType(opaque)); types.push_back(DtoType(Module::moduleinfo->type)); // resolve type const LLStructType* st = LLStructType::get(types); LLPATypeHolder pa(st); opaque->refineAbstractTypeTo(pa.get()); st = isaStruct(pa.get()); // done gIR->moduleRefType = st; gIR->module->addTypeName("ModuleReference", st); return st; } ////////////////////////////////////////////////////////////////////////////////////////// LLValue* DtoAggrPair(const LLType* type, LLValue* V1, LLValue* V2, const char* name) { LLValue* res = llvm::UndefValue::get(type); res = gIR->ir->CreateInsertValue(res, V1, 0, "tmp"); return gIR->ir->CreateInsertValue(res, V2, 1, name?name:"tmp"); } LLValue* DtoAggrPair(LLValue* V1, LLValue* V2, const char* name) { const LLType* t = LLStructType::get(V1->getType(), V2->getType(), NULL); return DtoAggrPair(t, V1, V2, name); } LLValue* DtoAggrPaint(LLValue* aggr, const LLType* as) { if (aggr->getType() == as) return aggr; LLValue* res = llvm::UndefValue::get(as); LLValue* V = gIR->ir->CreateExtractValue(aggr, 0, "tmp");; V = DtoBitCast(V, as->getContainedType(0)); res = gIR->ir->CreateInsertValue(res, V, 0, "tmp"); V = gIR->ir->CreateExtractValue(aggr, 1, "tmp");; V = DtoBitCast(V, as->getContainedType(1)); return gIR->ir->CreateInsertValue(res, V, 1, "tmp"); } LLValue* DtoAggrPairSwap(LLValue* aggr) { Logger::println("swapping aggr pair"); LLValue* r = gIR->ir->CreateExtractValue(aggr, 0); LLValue* i = gIR->ir->CreateExtractValue(aggr, 1); return DtoAggrPair(i, r, "swapped"); }