Mercurial > projects > ldc
view gen/complex.cpp @ 351:f273f5c58a9a trunk
[svn r372] Fixed extern(C++) handling now same as DMD, which is to treat it like extern(C).
Fixed a problem in resolving struct types where the size of elements might not yet be known. Switched to using DMD size() instead
of LLVM ABI size (TargetData).
| author | lindquist |
|---|---|
| date | Mon, 14 Jul 2008 03:23:43 +0200 |
| parents | 4aa2b6753059 |
| children | 926f65e39246 |
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#include "gen/llvm.h" #include "mtype.h" #include "declaration.h" #include "gen/complex.h" #include "gen/tollvm.h" #include "gen/llvmhelpers.h" #include "gen/irstate.h" #include "gen/dvalue.h" ////////////////////////////////////////////////////////////////////////////////////////// const llvm::StructType* DtoComplexType(Type* type) { Type* t = DtoDType(type); const LLType* base = DtoComplexBaseType(t); std::vector<const LLType*> types; types.push_back(base); types.push_back(base); return llvm::StructType::get(types); } const LLType* DtoComplexBaseType(Type* t) { TY ty = DtoDType(t)->ty; const LLType* base; if (ty == Tcomplex32) { return LLType::FloatTy; } else if (ty == Tcomplex64) { return LLType::DoubleTy; } else if (ty == Tcomplex80) { return (global.params.useFP80) ? LLType::X86_FP80Ty : LLType::DoubleTy; } else { assert(0); } } ////////////////////////////////////////////////////////////////////////////////////////// LLConstant* DtoConstComplex(Type* ty, LLConstant* re, LLConstant* im) { assert(0); const LLType* base = DtoComplexBaseType(ty); std::vector<LLConstant*> inits; inits.push_back(re); inits.push_back(im); const llvm::VectorType* vt = llvm::VectorType::get(base, 2); return llvm::ConstantVector::get(vt, inits); } LLConstant* DtoConstComplex(Type* _ty, long double re, long double im) { TY ty = DtoDType(_ty)->ty; llvm::ConstantFP* fre; llvm::ConstantFP* fim; Type* base = 0; if (ty == Tcomplex32) { base = Type::tfloat32; } else if (ty == Tcomplex64) { base = Type::tfloat64; } else if (ty == Tcomplex80) { base = (global.params.useFP80) ? Type::tfloat80 : Type::tfloat64; } std::vector<LLConstant*> inits; inits.push_back(DtoConstFP(base, re)); inits.push_back(DtoConstFP(base, im)); return llvm::ConstantStruct::get(DtoComplexType(_ty), inits); } ////////////////////////////////////////////////////////////////////////////////////////// LLValue* DtoRealPart(DValue* val) { assert(0); return gIR->ir->CreateExtractElement(val->getRVal(), DtoConstUint(0), "tmp"); } ////////////////////////////////////////////////////////////////////////////////////////// LLValue* 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 LLType* base = DtoComplexBaseType(to); LLConstant* undef = llvm::UndefValue::get(base); LLConstant* zero; if (ty == Tfloat32 || ty == Timaginary32 || ty == Tcomplex32) zero = LLConstant::getNullValue(DtoType(Type::tfloat32)); // llvm::ConstantFP::get(llvm::APFloat(0.0f)); else if (ty == Tfloat64 || ty == Timaginary64 || ty == Tcomplex64) zero = LLConstant::getNullValue(DtoType(Type::tfloat64)); else if (ty == Tfloat80 || ty == Timaginary80 || ty == Tcomplex80) zero = LLConstant::getNullValue(DtoType((global.params.useFP80)?Type::tfloat80:Type::tfloat64)); 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(LLValue* l, LLValue* 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(LLValue* c, LLValue* re, LLValue* im) { DtoStore(re, DtoGEPi(c,0,0,"tmp")); DtoStore(im, DtoGEPi(c,0,1,"tmp")); } ////////////////////////////////////////////////////////////////////////////////////////// void DtoGetComplexParts(DValue* c, LLValue*& re, LLValue*& 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); } ////////////////////////////////////////////////////////////////////////////////////////// DValue* DtoComplexNeg(Type* type, DValue* val) { val = DtoComplex(type, val); llvm::Value *a, *b, *re, *im; // values DtoGetComplexParts(val, a, b); // sub up re = gIR->ir->CreateNeg(a, "tmp"); im = gIR->ir->CreateNeg(b, "tmp"); return new DComplexValue(type, re, im); } ////////////////////////////////////////////////////////////////////////////////////////// LLValue* 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) LLValue* b1 = new llvm::FCmpInst(cmpop, a, c, "tmp", gIR->scopebb()); LLValue* b2 = new llvm::FCmpInst(cmpop, b, d, "tmp", gIR->scopebb()); return gIR->ir->CreateAnd(b1,b2,"tmp"); } ////////////////////////////////////////////////////////////////////////////////////////// DValue* DtoCastComplex(DValue* val, Type* _to) { Type* to = DtoDType(_to); Type* vty = val->getType(); if (to->iscomplex()) { if (vty->size() == to->size()) return val; llvm::Value *re, *im; DtoGetComplexParts(val, re, im); const LLType* toty = DtoComplexBaseType(to); if (to->size() < vty->size()) { re = gIR->ir->CreateFPTrunc(re, toty, "tmp"); im = gIR->ir->CreateFPTrunc(im, toty, "tmp"); } else if (to->size() > vty->size()) { re = gIR->ir->CreateFPExt(re, toty, "tmp"); im = gIR->ir->CreateFPExt(im, toty, "tmp"); } else { return val; } if (val->isComplex()) return new DComplexValue(_to, re, im); // unfortunately at this point, the cast value can show up as the lvalue for += and similar expressions. // so we need to give it storage, or fix the system that handles this stuff (DLRValue) LLValue* mem = new llvm::AllocaInst(DtoType(_to), "castcomplextmp", gIR->topallocapoint()); DtoComplexSet(mem, re, im); return new DLRValue(val->getType(), val->getRVal(), _to, mem); } else if (to->isimaginary()) { if (val->isComplex()) return new DImValue(to, val->isComplex()->im); LLValue* v = val->getRVal(); DImValue* im = new DImValue(to, DtoLoad(DtoGEPi(v,0,1,"tmp"))); return DtoCastFloat(im, to); } else if (to->isfloating()) { if (val->isComplex()) return new DImValue(to, val->isComplex()->re); LLValue* v = val->getRVal(); DImValue* re = new DImValue(to, DtoLoad(DtoGEPi(v,0,0,"tmp"))); return DtoCastFloat(re, to); } else assert(0); }