Mercurial > projects > ldc
view gen/complex.cpp @ 109:5ab8e92611f9 trunk
[svn r113] Added initial support for associative arrays (AAs).
Fixed some problems with the string runtime support functions.
Fixed initialization of array of structs.
Fixed slice assignment where LHS is slice but RHS is dynamic array.
Fixed problems with result of assignment expressions.
Fixed foreach problems with key type mismatches.
| author | lindquist |
|---|---|
| date | Wed, 21 Nov 2007 04:13:15 +0100 |
| parents | 3efbcc81ba45 |
| children | 44a95ac7368a |
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#include "gen/llvm.h" #include "mtype.h" #include "declaration.h" #include "gen/complex.h" #include "gen/tollvm.h" #include "gen/irstate.h" #include "gen/dvalue.h" ////////////////////////////////////////////////////////////////////////////////////////// const llvm::StructType* DtoComplexType(Type* type) { Type* t = DtoDType(type); const llvm::Type* base = DtoComplexBaseType(t); std::vector<const llvm::Type*> types; types.push_back(base); types.push_back(base); return llvm::StructType::get(types); } const llvm::Type* DtoComplexBaseType(Type* t) { TY ty = DtoDType(t)->ty; const llvm::Type* base; if (ty == Tcomplex32) { return llvm::Type::FloatTy; } else if (ty == Tcomplex64 || ty == Tcomplex80) { return llvm::Type::DoubleTy; } else { assert(0); } } ////////////////////////////////////////////////////////////////////////////////////////// llvm::Constant* DtoConstComplex(Type* ty, llvm::Constant* re, llvm::Constant* im) { assert(0); const llvm::Type* base = DtoComplexBaseType(ty); std::vector<llvm::Constant*> inits; inits.push_back(re); inits.push_back(im); const llvm::VectorType* vt = llvm::VectorType::get(base, 2); return llvm::ConstantVector::get(vt, inits); } llvm::Constant* DtoConstComplex(Type* _ty, long double re, long double im) { TY ty = DtoDType(_ty)->ty; llvm::ConstantFP* fre; llvm::ConstantFP* fim; const llvm::Type* base; if (ty == Tcomplex32) { fre = DtoConstFP(Type::tfloat32, re); fim = DtoConstFP(Type::tfloat32, im); base = llvm::Type::FloatTy; } else if (ty == Tcomplex64 || ty == Tcomplex80) { fre = DtoConstFP(Type::tfloat64, re); fim = DtoConstFP(Type::tfloat64, im); base = llvm::Type::DoubleTy; } else assert(0); std::vector<llvm::Constant*> inits; inits.push_back(fre); inits.push_back(fim); return llvm::ConstantStruct::get(DtoComplexType(_ty), inits); } llvm::Constant* DtoUndefComplex(Type* _ty) { assert(0); TY ty = DtoDType(_ty)->ty; const llvm::Type* base; if (ty == Tcomplex32) { base = llvm::Type::FloatTy; } else if (ty == Tcomplex64 || ty == Tcomplex80) { base = llvm::Type::DoubleTy; } else assert(0); std::vector<llvm::Constant*> inits; inits.push_back(llvm::UndefValue::get(base)); inits.push_back(llvm::UndefValue::get(base)); const llvm::VectorType* vt = llvm::VectorType::get(base, 2); return llvm::ConstantVector::get(vt, inits); } ////////////////////////////////////////////////////////////////////////////////////////// llvm::Value* DtoRealPart(DValue* val) { assert(0); return gIR->ir->CreateExtractElement(val->getRVal(), DtoConstUint(0), "tmp"); } ////////////////////////////////////////////////////////////////////////////////////////// llvm::Value* DtoImagPart(DValue* val) { assert(0); return gIR->ir->CreateExtractElement(val->getRVal(), DtoConstUint(1), "tmp"); } ////////////////////////////////////////////////////////////////////////////////////////// DValue* DtoComplex(Type* to, DValue* val) { Type* t = DtoDType(val->getType()); TY ty = t->ty; if (val->isComplex() || t->iscomplex()) { return DtoCastComplex(val, to); } const llvm::Type* base = DtoComplexBaseType(to); llvm::Constant* undef = llvm::UndefValue::get(base); llvm::Constant* zero; if (ty == Tfloat32 || ty == Timaginary32 || ty == Tcomplex32) zero = llvm::ConstantFP::get(llvm::Type::FloatTy, float(0)); else if (ty == Tfloat64 || ty == Timaginary64 || ty == Tcomplex64 || ty == Tfloat80 || ty == Timaginary80 || ty == Tcomplex80) zero = llvm::ConstantFP::get(llvm::Type::DoubleTy, double(0)); if (t->isimaginary()) { return new DComplexValue(to, zero, val->getRVal()); } else if (t->isfloating()) { return new DComplexValue(to, val->getRVal(), zero); } else assert(0); } ////////////////////////////////////////////////////////////////////////////////////////// void DtoComplexAssign(llvm::Value* l, llvm::Value* r) { DtoStore(DtoLoad(DtoGEPi(r, 0,0, "tmp")), DtoGEPi(l,0,0,"tmp")); DtoStore(DtoLoad(DtoGEPi(r, 0,1, "tmp")), DtoGEPi(l,0,1,"tmp")); } void DtoComplexSet(llvm::Value* c, llvm::Value* re, llvm::Value* im) { DtoStore(re, DtoGEPi(c,0,0,"tmp")); DtoStore(im, DtoGEPi(c,0,1,"tmp")); } ////////////////////////////////////////////////////////////////////////////////////////// void DtoGetComplexParts(DValue* c, llvm::Value*& re, llvm::Value*& im) { // lhs values if (DComplexValue* cx = c->isComplex()) { re = cx->re; im = cx->im; } else { re = DtoLoad(DtoGEPi(c->getRVal(),0,0,"tmp")); im = DtoLoad(DtoGEPi(c->getRVal(),0,1,"tmp")); } } ////////////////////////////////////////////////////////////////////////////////////////// DValue* DtoComplexAdd(Type* type, DValue* lhs, DValue* rhs) { lhs = DtoComplex(type, lhs); rhs = DtoComplex(type, rhs); llvm::Value *a, *b, *c, *d, *re, *im; // lhs values DtoGetComplexParts(lhs, a, b); // rhs values DtoGetComplexParts(rhs, c, d); // add up re = gIR->ir->CreateAdd(a, c, "tmp"); im = gIR->ir->CreateAdd(b, d, "tmp"); return new DComplexValue(type, re, im); } ////////////////////////////////////////////////////////////////////////////////////////// DValue* DtoComplexSub(Type* type, DValue* lhs, DValue* rhs) { lhs = DtoComplex(type, lhs); rhs = DtoComplex(type, rhs); llvm::Value *a, *b, *c, *d, *re, *im; // lhs values DtoGetComplexParts(lhs, a, b); // rhs values DtoGetComplexParts(rhs, c, d); // add up re = gIR->ir->CreateSub(a, c, "tmp"); im = gIR->ir->CreateSub(b, d, "tmp"); return new DComplexValue(type, re, im); } ////////////////////////////////////////////////////////////////////////////////////////// DValue* DtoComplexMul(Type* type, DValue* lhs, DValue* rhs) { lhs = DtoComplex(type, lhs); rhs = DtoComplex(type, rhs); llvm::Value *a, *b, *c, *d; // lhs values DtoGetComplexParts(lhs, a, b); // rhs values DtoGetComplexParts(rhs, c, d); llvm::Value *tmp1, *tmp2, *re, *im; tmp1 = gIR->ir->CreateMul(a, c, "tmp"); tmp2 = gIR->ir->CreateMul(b, d, "tmp"); re = gIR->ir->CreateSub(tmp1, tmp2, "tmp"); tmp1 = gIR->ir->CreateMul(b, c, "tmp"); tmp2 = gIR->ir->CreateMul(a, d, "tmp"); im = gIR->ir->CreateAdd(tmp1, tmp2, "tmp"); return new DComplexValue(type, re, im); } ////////////////////////////////////////////////////////////////////////////////////////// DValue* DtoComplexDiv(Type* type, DValue* lhs, DValue* rhs) { lhs = DtoComplex(type, lhs); rhs = DtoComplex(type, rhs); llvm::Value *a, *b, *c, *d; // lhs values DtoGetComplexParts(lhs, a, b); // rhs values DtoGetComplexParts(rhs, c, d); llvm::Value *tmp1, *tmp2, *denom, *re, *im; tmp1 = gIR->ir->CreateMul(c, c, "tmp"); tmp2 = gIR->ir->CreateMul(d, d, "tmp"); denom = gIR->ir->CreateAdd(tmp1, tmp2, "tmp"); tmp1 = gIR->ir->CreateMul(a, c, "tmp"); tmp2 = gIR->ir->CreateMul(b, d, "tmp"); re = gIR->ir->CreateAdd(tmp1, tmp2, "tmp"); re = gIR->ir->CreateFDiv(re, denom, "tmp"); tmp1 = gIR->ir->CreateMul(b, c, "tmp"); tmp2 = gIR->ir->CreateMul(a, d, "tmp"); im = gIR->ir->CreateSub(tmp1, tmp2, "tmp"); im = gIR->ir->CreateFDiv(im, denom, "tmp"); return new DComplexValue(type, re, im); } ////////////////////////////////////////////////////////////////////////////////////////// llvm::Value* DtoComplexEquals(TOK op, DValue* lhs, DValue* rhs) { Type* type = lhs->getType(); lhs = DtoComplex(type, lhs); rhs = DtoComplex(type, rhs); llvm::Value *a, *b, *c, *d; // lhs values DtoGetComplexParts(lhs, a, b); // rhs values DtoGetComplexParts(rhs, c, d); // select predicate llvm::FCmpInst::Predicate cmpop; if (op == TOKequal) cmpop = llvm::FCmpInst::FCMP_OEQ; else cmpop = llvm::FCmpInst::FCMP_UNE; // (l.re==r.re && l.im==r.im) llvm::Value* b1 = new llvm::FCmpInst(cmpop, a, c, "tmp", gIR->scopebb()); llvm::Value* b2 = new llvm::FCmpInst(cmpop, b, d, "tmp", gIR->scopebb()); return gIR->ir->CreateAnd(b1,b2,"tmp"); }