Mercurial > projects > ldc
view gen/toir.cpp @ 144:a27941d00351 trunk
[svn r149] fixed: a bunch of D-style variadics problems.
fixed: GotoDefaultStatement implemented.
fixed: some other minor bugs.
| author | lindquist |
|---|---|
| date | Sat, 26 Jan 2008 17:13:22 +0100 |
| parents | 336ec4f4bbb3 |
| children | 2c336566ffed |
line wrap: on
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// Backend stubs /* DMDFE backend stubs * This file contains the implementations of the backend routines. * For dmdfe these do nothing but print a message saying the module * has been parsed. Substitute your own behaviors for these routimes. */ #include <stdio.h> #include <math.h> #include <sstream> #include <fstream> #include <iostream> #include "gen/llvm.h" #include "attrib.h" #include "total.h" #include "init.h" #include "mtype.h" #include "hdrgen.h" #include "port.h" #include "gen/irstate.h" #include "gen/logger.h" #include "gen/tollvm.h" #include "gen/runtime.h" #include "gen/arrays.h" #include "gen/structs.h" #include "gen/classes.h" #include "gen/typeinf.h" #include "gen/complex.h" #include "gen/dvalue.h" #include "gen/aa.h" #include "gen/functions.h" ////////////////////////////////////////////////////////////////////////////////////////// DValue* DeclarationExp::toElem(IRState* p) { Logger::print("DeclarationExp::toElem: %s | T=%s\n", toChars(), type->toChars()); LOG_SCOPE; // variable declaration if (VarDeclaration* vd = declaration->isVarDeclaration()) { Logger::println("VarDeclaration"); // static if (vd->isDataseg()) { vd->toObjFile(); // TODO } else { if (global.params.llvmAnnotate) DtoAnnotation(toChars()); Logger::println("vdtype = %s", vd->type->toChars()); // referenced by nested delegate? if (vd->nestedref) { Logger::println("has nestedref set"); assert(vd->irLocal); vd->irLocal->value = p->func()->decl->irFunc->nestedVar; assert(vd->irLocal->value); assert(vd->irLocal->nestedIndex >= 0); } // normal stack variable else { // allocate storage on the stack const llvm::Type* lltype = DtoType(vd->type); llvm::AllocaInst* allocainst = new llvm::AllocaInst(lltype, vd->toChars(), p->topallocapoint()); //allocainst->setAlignment(vd->type->alignsize()); // TODO assert(!vd->irLocal); vd->irLocal = new IrLocal(vd); vd->irLocal->value = allocainst; } Logger::cout() << "llvm value for decl: " << *vd->irLocal->value << '\n'; DValue* ie = DtoInitializer(vd->init); } return new DVarValue(vd, vd->getIrValue(), true); } // struct declaration else if (StructDeclaration* s = declaration->isStructDeclaration()) { Logger::println("StructDeclaration"); DtoForceConstInitDsymbol(s); } // function declaration else if (FuncDeclaration* f = declaration->isFuncDeclaration()) { Logger::println("FuncDeclaration"); DtoForceDeclareDsymbol(f); } // alias declaration else if (AliasDeclaration* a = declaration->isAliasDeclaration()) { Logger::println("AliasDeclaration - no work"); // do nothing } // enum else if (EnumDeclaration* e = declaration->isEnumDeclaration()) { Logger::println("EnumDeclaration - no work"); // do nothing } // class else if (ClassDeclaration* e = declaration->isClassDeclaration()) { Logger::println("ClassDeclaration"); DtoForceConstInitDsymbol(e); } // typedef else if (TypedefDeclaration* tdef = declaration->isTypedefDeclaration()) { Logger::println("TypedefDeclaration"); tdef->type->getTypeInfo(NULL); } // attribute declaration else if (AttribDeclaration* a = declaration->isAttribDeclaration()) { Logger::println("AttribDeclaration"); for (int i=0; i < a->decl->dim; ++i) { DtoForceDeclareDsymbol((Dsymbol*)a->decl->data[i]); } } // unsupported declaration else { error("Unimplemented DeclarationExp type. kind: %s", declaration->kind()); assert(0); } return 0; } ////////////////////////////////////////////////////////////////////////////////////////// DValue* VarExp::toElem(IRState* p) { Logger::print("VarExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; assert(var); if (VarDeclaration* vd = var->isVarDeclaration()) { Logger::println("VarDeclaration %s", vd->toChars()); // _arguments if (vd->ident == Id::_arguments) { Logger::println("Id::_arguments"); /*if (!vd->getIrValue()) vd->getIrValue() = p->func()->decl->irFunc->_arguments; assert(vd->getIrValue()); return new DVarValue(vd, vd->getIrValue(), true);*/ llvm::Value* v = p->func()->decl->irFunc->_arguments; assert(v); return new DVarValue(vd, v, true); } // _argptr else if (vd->ident == Id::_argptr) { Logger::println("Id::_argptr"); /*if (!vd->getIrValue()) vd->getIrValue() = p->func()->decl->irFunc->_argptr; assert(vd->getIrValue()); return new DVarValue(vd, vd->getIrValue(), true);*/ llvm::Value* v = p->func()->decl->irFunc->_argptr; assert(v); return new DVarValue(vd, v, true); } // _dollar else if (vd->ident == Id::dollar) { Logger::println("Id::dollar"); assert(!p->arrays.empty()); llvm::Value* tmp = DtoArrayLen(p->arrays.back()); return new DVarValue(vd, tmp, false); } // typeinfo else if (TypeInfoDeclaration* tid = vd->isTypeInfoDeclaration()) { Logger::println("TypeInfoDeclaration"); DtoForceDeclareDsymbol(tid); assert(tid->getIrValue()); const llvm::Type* vartype = DtoType(type); llvm::Value* m; if (tid->getIrValue()->getType() != getPtrToType(vartype)) m = p->ir->CreateBitCast(tid->getIrValue(), vartype, "tmp"); else m = tid->getIrValue(); return new DVarValue(vd, m, true); } // classinfo else if (ClassInfoDeclaration* cid = vd->isClassInfoDeclaration()) { Logger::println("ClassInfoDeclaration: %s", cid->cd->toChars()); DtoDeclareClassInfo(cid->cd); assert(cid->cd->irStruct->classInfo); return new DVarValue(vd, cid->cd->irStruct->classInfo, true); } // nested variable else if (vd->nestedref) { Logger::println("nested variable"); return new DVarValue(vd, DtoNestedVariable(vd), true); } // function parameter else if (vd->isParameter()) { Logger::println("function param"); if (!vd->getIrValue()) { // TODO: determine this properly // this happens when the DMD frontend generates by pointer wrappers for struct opEquals(S) and opCmp(S) vd->getIrValue() = &p->func()->func->getArgumentList().back(); } if (vd->isRef() || vd->isOut() || DtoIsPassedByRef(vd->type) || llvm::isa<llvm::AllocaInst>(vd->getIrValue())) { return new DVarValue(vd, vd->getIrValue(), true); } else if (llvm::isa<llvm::Argument>(vd->getIrValue())) { return new DImValue(type, vd->getIrValue()); } else assert(0); } else { // take care of forward references of global variables if (vd->isDataseg() || (vd->storage_class & STCextern)) { vd->toObjFile(); DtoConstInitGlobal(vd); } if (!vd->getIrValue() || vd->getIrValue()->getType()->isAbstract()) { Logger::println("global variable not resolved :/ %s", vd->toChars()); assert(0); } return new DVarValue(vd, vd->getIrValue(), true); } } else if (FuncDeclaration* fdecl = var->isFuncDeclaration()) { Logger::println("FuncDeclaration"); if (fdecl->llvmInternal != LLVMva_arg) {// && fdecl->llvmValue == 0) DtoForceDeclareDsymbol(fdecl); } return new DFuncValue(fdecl, fdecl->irFunc->func); } else if (SymbolDeclaration* sdecl = var->isSymbolDeclaration()) { // this seems to be the static initialiser for structs Type* sdecltype = DtoDType(sdecl->type); Logger::print("Sym: type=%s\n", sdecltype->toChars()); assert(sdecltype->ty == Tstruct); TypeStruct* ts = (TypeStruct*)sdecltype; assert(ts->sym); assert(ts->sym->irStruct->init); return new DVarValue(type, ts->sym->irStruct->init, true); } else { assert(0 && "Unimplemented VarExp type"); } return 0; } ////////////////////////////////////////////////////////////////////////////////////////// llvm::Constant* VarExp::toConstElem(IRState* p) { Logger::print("VarExp::toConstElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; if (SymbolDeclaration* sdecl = var->isSymbolDeclaration()) { // this seems to be the static initialiser for structs Type* sdecltype = DtoDType(sdecl->type); Logger::print("Sym: type=%s\n", sdecltype->toChars()); assert(sdecltype->ty == Tstruct); TypeStruct* ts = (TypeStruct*)sdecltype; DtoForceConstInitDsymbol(ts->sym); assert(ts->sym->irStruct->constInit); return ts->sym->irStruct->constInit; } else if (TypeInfoDeclaration* ti = var->isTypeInfoDeclaration()) { DtoForceDeclareDsymbol(ti); assert(ti->getIrValue()); const llvm::Type* vartype = DtoType(type); llvm::Constant* m = isaConstant(ti->getIrValue()); assert(m); if (ti->getIrValue()->getType() != getPtrToType(vartype)) m = llvm::ConstantExpr::getBitCast(m, vartype); return m; } assert(0 && "Unsupported const VarExp kind"); return NULL; } ////////////////////////////////////////////////////////////////////////////////////////// DValue* IntegerExp::toElem(IRState* p) { Logger::print("IntegerExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; llvm::Constant* c = toConstElem(p); return new DConstValue(type, c); } ////////////////////////////////////////////////////////////////////////////////////////// llvm::Constant* IntegerExp::toConstElem(IRState* p) { Logger::print("IntegerExp::toConstElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; const llvm::Type* t = DtoType(type); if (isaPointer(t)) { Logger::println("pointer"); llvm::Constant* i = llvm::ConstantInt::get(DtoSize_t(),(uint64_t)value,false); return llvm::ConstantExpr::getIntToPtr(i, t); } assert(llvm::isa<llvm::IntegerType>(t)); llvm::Constant* c = llvm::ConstantInt::get(t,(uint64_t)value,!type->isunsigned()); assert(c); Logger::cout() << "value = " << *c << '\n'; return c; } ////////////////////////////////////////////////////////////////////////////////////////// DValue* RealExp::toElem(IRState* p) { Logger::print("RealExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; llvm::Constant* c = toConstElem(p); return new DConstValue(type, c); } ////////////////////////////////////////////////////////////////////////////////////////// llvm::Constant* RealExp::toConstElem(IRState* p) { Logger::print("RealExp::toConstElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; Type* t = DtoDType(type); return DtoConstFP(t, value); } ////////////////////////////////////////////////////////////////////////////////////////// DValue* NullExp::toElem(IRState* p) { Logger::print("NullExp::toElem(type=%s): %s\n", type->toChars(),toChars()); LOG_SCOPE; llvm::Constant* c = toConstElem(p); return new DNullValue(type, c); } ////////////////////////////////////////////////////////////////////////////////////////// llvm::Constant* NullExp::toConstElem(IRState* p) { Logger::print("NullExp::toConstElem(type=%s): %s\n", type->toChars(),toChars()); LOG_SCOPE; const llvm::Type* t = DtoType(type); if (type->ty == Tarray) { assert(isaStruct(t)); return llvm::ConstantAggregateZero::get(t); } else { return llvm::Constant::getNullValue(t); } assert(0); return NULL; } ////////////////////////////////////////////////////////////////////////////////////////// DValue* ComplexExp::toElem(IRState* p) { Logger::print("ComplexExp::toElem(): %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; llvm::Constant* c = toConstElem(p); if (c->isNullValue()) { Type* t = DtoDType(type); if (t->ty == Tcomplex32) c = DtoConstFP(Type::tfloat32, 0); else c = DtoConstFP(Type::tfloat64, 0); return new DComplexValue(type, c, c); } return new DComplexValue(type, c->getOperand(0), c->getOperand(1)); } ////////////////////////////////////////////////////////////////////////////////////////// llvm::Constant* ComplexExp::toConstElem(IRState* p) { Logger::print("ComplexExp::toConstElem(): %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; return DtoConstComplex(type, value.re, value.im); } ////////////////////////////////////////////////////////////////////////////////////////// DValue* StringExp::toElem(IRState* p) { Logger::print("StringExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; Type* dtype = DtoDType(type); Type* cty = DtoDType(dtype->next); const llvm::Type* ct = DtoType(cty); if (ct == llvm::Type::VoidTy) ct = llvm::Type::Int8Ty; //printf("ct = %s\n", type->next->toChars()); const llvm::ArrayType* at = llvm::ArrayType::get(ct,len+1); llvm::Constant* _init; if (cty->ty == Tchar || cty->ty == Tvoid) { uint8_t* str = (uint8_t*)string; std::string cont((char*)str, len); _init = llvm::ConstantArray::get(cont,true); } else if (cty->ty == Twchar) { uint16_t* str = (uint16_t*)string; std::vector<llvm::Constant*> vals; for(size_t i=0; i<len; ++i) { vals.push_back(llvm::ConstantInt::get(ct, str[i], false));; } vals.push_back(llvm::ConstantInt::get(ct, 0, false)); _init = llvm::ConstantArray::get(at,vals); } else if (cty->ty == Tdchar) { uint32_t* str = (uint32_t*)string; std::vector<llvm::Constant*> vals; for(size_t i=0; i<len; ++i) { vals.push_back(llvm::ConstantInt::get(ct, str[i], false));; } vals.push_back(llvm::ConstantInt::get(ct, 0, false)); _init = llvm::ConstantArray::get(at,vals); } else assert(0); llvm::GlobalValue::LinkageTypes _linkage = llvm::GlobalValue::InternalLinkage;//WeakLinkage; Logger::cout() << "type: " << *at << "\ninit: " << *_init << '\n'; llvm::GlobalVariable* gvar = new llvm::GlobalVariable(at,true,_linkage,_init,"stringliteral",gIR->module); llvm::ConstantInt* zero = llvm::ConstantInt::get(llvm::Type::Int32Ty, 0, false); llvm::Constant* idxs[2] = { zero, zero }; llvm::Constant* arrptr = llvm::ConstantExpr::getGetElementPtr(gvar,idxs,2); if (dtype->ty == Tarray) { llvm::Constant* clen = llvm::ConstantInt::get(DtoSize_t(),len,false); if (!p->topexp() || p->topexp()->e2 != this) { llvm::Value* tmpmem = new llvm::AllocaInst(DtoType(dtype),"tempstring",p->topallocapoint()); DtoSetArray(tmpmem, clen, arrptr); return new DVarValue(type, tmpmem, true); } else if (p->topexp()->e2 == this) { DValue* arr = p->topexp()->v; assert(arr); if (arr->isSlice()) { return new DSliceValue(type, clen, arrptr); } else { DtoSetArray(arr->getRVal(), clen, arrptr); return new DImValue(type, arr->getLVal(), true); } } assert(0); } else if (dtype->ty == Tsarray) { const llvm::Type* dstType = getPtrToType(llvm::ArrayType::get(ct, len)); llvm::Value* emem = (gvar->getType() == dstType) ? gvar : DtoBitCast(gvar, dstType); return new DVarValue(type, emem, true); } else if (dtype->ty == Tpointer) { return new DImValue(type, arrptr); } assert(0); return 0; } ////////////////////////////////////////////////////////////////////////////////////////// llvm::Constant* StringExp::toConstElem(IRState* p) { Logger::print("StringExp::toConstElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; uint8_t* str = (uint8_t*)string; std::string cont((char*)str, len); Type* t = DtoDType(type); if (t->ty == Tsarray) { return llvm::ConstantArray::get(cont,false); } llvm::Constant* _init = llvm::ConstantArray::get(cont,true); llvm::GlobalValue::LinkageTypes _linkage = llvm::GlobalValue::InternalLinkage;//WeakLinkage; llvm::GlobalVariable* gvar = new llvm::GlobalVariable(_init->getType(),true,_linkage,_init,"stringliteral",gIR->module); llvm::ConstantInt* zero = llvm::ConstantInt::get(llvm::Type::Int32Ty, 0, false); llvm::Constant* idxs[2] = { zero, zero }; llvm::Constant* arrptr = llvm::ConstantExpr::getGetElementPtr(gvar,idxs,2); if (t->ty == Tpointer) { return arrptr; } if (t->ty == Tarray) { llvm::Constant* clen = llvm::ConstantInt::get(DtoSize_t(),len,false); return DtoConstSlice(clen, arrptr); } assert(0); return NULL; } ////////////////////////////////////////////////////////////////////////////////////////// DValue* AssignExp::toElem(IRState* p) { Logger::print("AssignExp::toElem: %s | %s = %s\n", toChars(), e1->type->toChars(), e2->type ? e2->type->toChars() : 0); LOG_SCOPE; p->exps.push_back(IRExp(e1,e2,NULL)); DValue* l = e1->toElem(p); p->topexp()->v = l; DValue* r = e2->toElem(p); p->exps.pop_back(); DImValue* im = r->isIm(); if (!im || !im->inPlace()) { Logger::println("assignment not inplace"); if (l->isArrayLen()) DtoResizeDynArray(l->getLVal(), r->getRVal()); else DtoAssign(l, r); } if (l->isSlice() || l->isComplex()) return l; llvm::Value* v; if (l->isVar() && l->isVar()->lval) v = l->getLVal(); else v = l->getRVal(); return new DVarValue(type, v, true); } ////////////////////////////////////////////////////////////////////////////////////////// DValue* AddExp::toElem(IRState* p) { Logger::print("AddExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; DValue* l = e1->toElem(p); DValue* r = e2->toElem(p); Type* t = DtoDType(type); Type* e1type = DtoDType(e1->type); Type* e1next = e1type->next ? DtoDType(e1type->next) : NULL; Type* e2type = DtoDType(e2->type); if (e1type != e2type) { if (llvmFieldIndex) { assert(e1type->ty == Tpointer && e1next && e1next->ty == Tstruct); Logger::println("add to AddrExp of struct"); assert(r->isConst()); llvm::ConstantInt* cofs = llvm::cast<llvm::ConstantInt>(r->isConst()->c); TypeStruct* ts = (TypeStruct*)e1next; std::vector<unsigned> offsets; llvm::Value* v = DtoIndexStruct(l->getRVal(), ts->sym, t->next, cofs->getZExtValue(), offsets); return new DFieldValue(type, v, true); } else if (e1type->ty == Tpointer) { Logger::println("add to pointer"); if (r->isConst()) { llvm::ConstantInt* cofs = llvm::cast<llvm::ConstantInt>(r->isConst()->c); if (cofs->isZero()) { Logger::println("is zero"); return new DImValue(type, l->getRVal()); } } llvm::Value* v = new llvm::GetElementPtrInst(l->getRVal(), r->getRVal(), "tmp", p->scopebb()); return new DImValue(type, v); } else if (t->iscomplex()) { return DtoComplexAdd(type, l, r); } assert(0); } else if (t->iscomplex()) { return DtoComplexAdd(type, l, r); } else { return DtoBinAdd(l,r); } } ////////////////////////////////////////////////////////////////////////////////////////// DValue* AddAssignExp::toElem(IRState* p) { Logger::print("AddAssignExp::toElem: %s\n", toChars()); LOG_SCOPE; p->exps.push_back(IRExp(e1,e2,NULL)); DValue* l = e1->toElem(p); DValue* r = e2->toElem(p); p->exps.pop_back(); Type* t = DtoDType(type); DValue* res; if (DtoDType(e1->type)->ty == Tpointer) { llvm::Value* gep = new llvm::GetElementPtrInst(l->getRVal(),r->getRVal(),"tmp",p->scopebb()); res = new DImValue(type, gep); } else if (t->iscomplex()) { res = DtoComplexAdd(e1->type, l, r); } else { res = DtoBinAdd(l,r); } DtoAssign(l, res); // used as lvalue :/ if (p->topexp() && p->topexp()->e1 == this) { assert(!l->isLRValue()); return l; } else { return res; } } ////////////////////////////////////////////////////////////////////////////////////////// DValue* MinExp::toElem(IRState* p) { Logger::print("MinExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; DValue* l = e1->toElem(p); DValue* r = e2->toElem(p); Type* t = DtoDType(type); if (DtoDType(e1->type)->ty == Tpointer) { llvm::Value* lv = l->getRVal(); llvm::Value* rv = r->getRVal(); Logger::cout() << "lv: " << *lv << " rv: " << *rv << '\n'; if (isaPointer(lv)) lv = p->ir->CreatePtrToInt(lv, DtoSize_t(), "tmp"); if (isaPointer(rv)) rv = p->ir->CreatePtrToInt(rv, DtoSize_t(), "tmp"); llvm::Value* diff = p->ir->CreateSub(lv,rv,"tmp"); if (diff->getType() != DtoType(type)) diff = p->ir->CreateIntToPtr(diff, DtoType(type)); return new DImValue(type, diff); } else if (t->iscomplex()) { return DtoComplexSub(type, l, r); } else { return DtoBinSub(l,r); } } ////////////////////////////////////////////////////////////////////////////////////////// DValue* MinAssignExp::toElem(IRState* p) { Logger::print("MinAssignExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; DValue* l = e1->toElem(p); DValue* r = e2->toElem(p); Type* t = DtoDType(type); DValue* res; if (DtoDType(e1->type)->ty == Tpointer) { Logger::println("ptr"); llvm::Value* tmp = r->getRVal(); llvm::Value* zero = llvm::ConstantInt::get(tmp->getType(),0,false); tmp = llvm::BinaryOperator::createSub(zero,tmp,"tmp",p->scopebb()); tmp = new llvm::GetElementPtrInst(l->getRVal(),tmp,"tmp",p->scopebb()); res = new DImValue(type, tmp); } else if (t->iscomplex()) { Logger::println("complex"); res = DtoComplexSub(type, l, r); } else { Logger::println("basic"); res = DtoBinSub(l,r); } DtoAssign(l, res); return l; } ////////////////////////////////////////////////////////////////////////////////////////// DValue* MulExp::toElem(IRState* p) { Logger::print("MulExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; DValue* l = e1->toElem(p); DValue* r = e2->toElem(p); if (type->iscomplex()) { return DtoComplexMul(type, l, r); } return DtoBinMul(l,r); } ////////////////////////////////////////////////////////////////////////////////////////// DValue* MulAssignExp::toElem(IRState* p) { Logger::print("MulAssignExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; DValue* l = e1->toElem(p); DValue* r = e2->toElem(p); DValue* res; if (type->iscomplex()) { res = DtoComplexMul(type, l, r); } else { res = DtoBinMul(l,r); } DtoAssign(l, res); return l; } ////////////////////////////////////////////////////////////////////////////////////////// DValue* DivExp::toElem(IRState* p) { Logger::print("DivExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; DValue* l = e1->toElem(p); DValue* r = e2->toElem(p); if (type->iscomplex()) { return DtoComplexDiv(type, l, r); } return DtoBinDiv(l, r); } ////////////////////////////////////////////////////////////////////////////////////////// DValue* DivAssignExp::toElem(IRState* p) { Logger::print("DivAssignExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; DValue* l = e1->toElem(p); DValue* r = e2->toElem(p); DValue* res; if (type->iscomplex()) { res = DtoComplexDiv(type, l, r); } else { res = DtoBinDiv(l,r); } DtoAssign(l, res); return l; } ////////////////////////////////////////////////////////////////////////////////////////// DValue* ModExp::toElem(IRState* p) { Logger::print("ModExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; DValue* l = e1->toElem(p); DValue* r = e2->toElem(p); return DtoBinRem(l, r); } ////////////////////////////////////////////////////////////////////////////////////////// DValue* ModAssignExp::toElem(IRState* p) { Logger::print("ModAssignExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; DValue* l = e1->toElem(p); DValue* r = e2->toElem(p); DValue* res = DtoBinRem(l, r); DtoAssign(l, res); return l; } ////////////////////////////////////////////////////////////////////////////////////////// DValue* CallExp::toElem(IRState* p) { Logger::print("CallExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; DValue* fn = e1->toElem(p); TypeFunction* tf = 0; Type* e1type = DtoDType(e1->type); bool delegateCall = false; llvm::Value* zero = llvm::ConstantInt::get(llvm::Type::Int32Ty,0,false); llvm::Value* one = llvm::ConstantInt::get(llvm::Type::Int32Ty,1,false); LINK dlink = LINKd; // hidden struct return parameter handling bool retinptr = false; // regular functions if (e1type->ty == Tfunction) { tf = (TypeFunction*)e1type; if (tf->llvmRetInPtr) { retinptr = true; } dlink = tf->linkage; } // delegates else if (e1type->ty == Tdelegate) { Logger::println("delegateTy = %s\n", e1type->toChars()); assert(e1type->next->ty == Tfunction); tf = (TypeFunction*)e1type->next; if (tf->llvmRetInPtr) { retinptr = true; } dlink = tf->linkage; delegateCall = true; } // invalid else { assert(tf); } // magic stuff bool va_magic = false; bool va_intrinsic = false; DFuncValue* dfv = fn->isFunc(); if (dfv && dfv->func) { FuncDeclaration* fndecl = dfv->func; if (fndecl->llvmInternal == LLVMva_intrinsic) { va_magic = true; va_intrinsic = true; } else if (fndecl->llvmInternal == LLVMva_start) { va_magic = true; } else if (fndecl->llvmInternal == LLVMva_arg) { //Argument* fnarg = Argument::getNth(tf->parameters, 0); Expression* exp = (Expression*)arguments->data[0]; DValue* expelem = exp->toElem(p); Type* t = DtoDType(type); const llvm::Type* llt = DtoType(type); if (DtoIsPassedByRef(t)) llt = getPtrToType(llt); // TODO if (strcmp(global.params.llvmArch, "x86") != 0) { warning("%s: va_arg for C variadic functions is broken for anything but x86", loc.toChars()); } return new DImValue(type, p->ir->CreateVAArg(expelem->getLVal(),llt,"tmp")); } else if (fndecl->llvmInternal == LLVMalloca) { //Argument* fnarg = Argument::getNth(tf->parameters, 0); Expression* exp = (Expression*)arguments->data[0]; DValue* expv = exp->toElem(p); if (expv->getType()->toBasetype()->ty != Tint32) expv = DtoCast(expv, Type::tint32); llvm::Value* alloc = new llvm::AllocaInst(llvm::Type::Int8Ty, expv->getRVal(), "alloca", p->scopebb()); return new DImValue(type, alloc); } } // args size_t n = arguments->dim; DFuncValue* dfn = fn->isFunc(); if (dfn && dfn->func && dfn->func->llvmInternal == LLVMva_start) n = 1; if (delegateCall || (dfn && dfn->vthis)) n++; if (retinptr) n++; if (tf->linkage == LINKd && tf->varargs == 1) n+=2; if (dfn && dfn->func && dfn->func->isNested()) n++; llvm::Value* funcval = fn->getRVal(); assert(funcval != 0); std::vector<llvm::Value*> llargs(n, 0); const llvm::FunctionType* llfnty = 0; // normal function call if (llvm::isa<llvm::FunctionType>(funcval->getType())) { llfnty = llvm::cast<llvm::FunctionType>(funcval->getType()); } // pointer to something else if (isaPointer(funcval->getType())) { // pointer to function pointer - I think this not really supposed to happen, but does :/ // seems like sometimes we get a func* other times a func** if (isaPointer(funcval->getType()->getContainedType(0))) { funcval = new llvm::LoadInst(funcval,"tmp",p->scopebb()); } // function pointer if (llvm::isa<llvm::FunctionType>(funcval->getType()->getContainedType(0))) { //Logger::cout() << "function pointer type:\n" << *funcval << '\n'; llfnty = llvm::cast<llvm::FunctionType>(funcval->getType()->getContainedType(0)); } // struct pointer - delegate else if (isaStruct(funcval->getType()->getContainedType(0))) { funcval = DtoGEP(funcval,zero,one,"tmp",p->scopebb()); funcval = new llvm::LoadInst(funcval,"tmp",p->scopebb()); const llvm::Type* ty = funcval->getType()->getContainedType(0); llfnty = llvm::cast<llvm::FunctionType>(ty); } // unknown else { Logger::cout() << "what kind of pointer are we calling? : " << *funcval->getType() << '\n'; } } else { Logger::cout() << "what are we calling? : " << *funcval << '\n'; } assert(llfnty); //Logger::cout() << "Function LLVM type: " << *llfnty << '\n'; // argument handling llvm::FunctionType::param_iterator argiter = llfnty->param_begin(); int j = 0; IRExp* topexp = p->topexp(); bool isInPlace = false; // hidden struct return arguments if (retinptr) { if (topexp && topexp->e2 == this) { assert(topexp->v); llvm::Value* tlv = topexp->v->getLVal(); assert(isaStruct(tlv->getType()->getContainedType(0))); llargs[j] = tlv; isInPlace = true; /*if (DtoIsPassedByRef(tf->next)) { isInPlace = true; } else assert(0);*/ } else { llargs[j] = new llvm::AllocaInst(argiter->get()->getContainedType(0),"rettmp",p->topallocapoint()); } if (dfn && dfn->func && dfn->func->runTimeHack) { const llvm::Type* rettype = getPtrToType(DtoType(type)); if (llargs[j]->getType() != llfnty->getParamType(j)) { Logger::println("llvmRunTimeHack==true - force casting return value param"); Logger::cout() << "casting: " << *llargs[j] << " to type: " << *llfnty->getParamType(j) << '\n'; llargs[j] = DtoBitCast(llargs[j], llfnty->getParamType(j)); } } ++j; ++argiter; } // this arguments if (dfn && dfn->vthis) { Logger::cout() << "This Call func val:" << *funcval << '\n'; if (dfn->vthis->getType() != argiter->get()) { //Logger::cout() << "value: " << *dfn->vthis << " totype: " << *argiter->get() << '\n'; llargs[j] = DtoBitCast(dfn->vthis, argiter->get()); } else { llargs[j] = dfn->vthis; } ++j; ++argiter; } // delegate context arguments else if (delegateCall) { Logger::println("Delegate Call"); llvm::Value* contextptr = DtoGEP(fn->getRVal(),zero,zero,"tmp",p->scopebb()); llargs[j] = new llvm::LoadInst(contextptr,"tmp",p->scopebb()); ++j; ++argiter; } // nested call else if (dfn && dfn->func && dfn->func->isNested()) { Logger::println("Nested Call"); llvm::Value* contextptr = DtoNestedContext(dfn->func->toParent2()->isFuncDeclaration()); if (!contextptr) contextptr = llvm::ConstantPointerNull::get(getPtrToType(llvm::Type::Int8Ty)); llargs[j] = DtoBitCast(contextptr, getPtrToType(llvm::Type::Int8Ty)); ++j; ++argiter; } // va arg function special argument passing if (va_magic) { size_t n = va_intrinsic ? arguments->dim : 1; for (int i=0; i<n; i++,j++) { Argument* fnarg = Argument::getNth(tf->parameters, i); Expression* exp = (Expression*)arguments->data[i]; DValue* expelem = exp->toElem(p); llargs[j] = DtoBitCast(expelem->getLVal(), getPtrToType(llvm::Type::Int8Ty)); } } // regular arguments else { // d variadic function? if (tf->linkage == LINKd && tf->varargs == 1) { Logger::println("doing d-style variadic arguments"); size_t nimplicit = j; std::vector<const llvm::Type*> vtypes; std::vector<llvm::Value*> vtypeinfos; // number of non variadic args int begin = tf->parameters->dim; Logger::println("num non vararg params = %d", begin); // build struct with argument types for (int i=begin; i<arguments->dim; i++) { Argument* argu = Argument::getNth(tf->parameters, i); Expression* argexp = (Expression*)arguments->data[i]; vtypes.push_back(DtoType(argexp->type)); } const llvm::StructType* vtype = llvm::StructType::get(vtypes); Logger::cout() << "d-variadic argument struct type:\n" << *vtype << '\n'; llvm::Value* mem = new llvm::AllocaInst(vtype,"_argptr_storage",p->topallocapoint()); // store arguments in the struct for (int i=begin,k=0; i<arguments->dim; i++,k++) { Expression* argexp = (Expression*)arguments->data[i]; if (global.params.llvmAnnotate) DtoAnnotation(argexp->toChars()); DtoVariadicArgument(argexp, DtoGEPi(mem,0,k,"tmp")); } // build type info array assert(Type::typeinfo->irStruct->constInit); const llvm::Type* typeinfotype = DtoType(Type::typeinfo->type); const llvm::ArrayType* typeinfoarraytype = llvm::ArrayType::get(typeinfotype,vtype->getNumElements()); llvm::Value* typeinfomem = new llvm::AllocaInst(typeinfoarraytype,"_arguments_storage",p->topallocapoint()); Logger::cout() << "_arguments storage: " << *typeinfomem << '\n'; for (int i=begin,k=0; i<arguments->dim; i++,k++) { Expression* argexp = (Expression*)arguments->data[i]; TypeInfoDeclaration* tidecl = argexp->type->getTypeInfoDeclaration(); DtoForceDeclareDsymbol(tidecl); assert(tidecl->getIrValue()); vtypeinfos.push_back(tidecl->getIrValue()); llvm::Value* v = p->ir->CreateBitCast(vtypeinfos[k], typeinfotype, "tmp"); p->ir->CreateStore(v, DtoGEPi(typeinfomem,0,k,"tmp")); } // put data in d-array llvm::Value* typeinfoarrayparam = new llvm::AllocaInst(llfnty->getParamType(j)->getContainedType(0),"_arguments_array",p->topallocapoint()); p->ir->CreateStore(DtoConstSize_t(vtype->getNumElements()), DtoGEPi(typeinfoarrayparam,0,0,"tmp")); llvm::Value* casttypeinfomem = p->ir->CreateBitCast(typeinfomem, getPtrToType(typeinfotype), "tmp"); p->ir->CreateStore(casttypeinfomem, DtoGEPi(typeinfoarrayparam,0,1,"tmp")); // specify arguments llargs[j] = typeinfoarrayparam;; j++; llargs[j] = p->ir->CreateBitCast(mem, getPtrToType(llvm::Type::Int8Ty), "tmp"); j++; // pass non variadic args for (int i=0; i<begin; i++) { Argument* fnarg = Argument::getNth(tf->parameters, i); DValue* argval = DtoArgument(fnarg, (Expression*)arguments->data[i]); llargs[j] = argval->getRVal(); j++; } // make sure arg vector has the right size llargs.resize(nimplicit+begin+2); } // normal function else { Logger::println("doing normal arguments"); for (int i=0; i<arguments->dim; i++,j++) { Argument* fnarg = Argument::getNth(tf->parameters, i); if (global.params.llvmAnnotate) DtoAnnotation(((Expression*)arguments->data[i])->toChars()); DValue* argval = DtoArgument(fnarg, (Expression*)arguments->data[i]); llargs[j] = argval->getRVal(); if (fnarg && llargs[j]->getType() != llfnty->getParamType(j)) { llargs[j] = DtoBitCast(llargs[j], llfnty->getParamType(j)); } // this hack is necessary :/ if (dfn && dfn->func && dfn->func->runTimeHack) { if (llfnty->getParamType(j) != NULL) { if (llargs[j]->getType() != llfnty->getParamType(j)) { Logger::println("llvmRunTimeHack==true - force casting argument"); Logger::cout() << "casting: " << *llargs[j] << " to type: " << *llfnty->getParamType(j) << '\n'; llargs[j] = DtoBitCast(llargs[j], llfnty->getParamType(j)); } } } } } } #if 1 Logger::println("%d params passed", n); for (int i=0; i<llargs.size(); ++i) { assert(llargs[i]); Logger::cout() << "arg["<<i<<"] = " << *llargs[i] << '\n'; } #endif // void returns cannot not be named const char* varname = ""; if (llfnty->getReturnType() != llvm::Type::VoidTy) varname = "tmp"; Logger::cout() << "Calling: " << *funcval << '\n'; // call the function llvm::CallInst* call = new llvm::CallInst(funcval, llargs.begin(), llargs.end(), varname, p->scopebb()); llvm::Value* retllval = (retinptr) ? llargs[0] : call; if (retinptr && dfn && dfn->func && dfn->func->runTimeHack) { const llvm::Type* rettype = getPtrToType(DtoType(type)); if (retllval->getType() != rettype) { Logger::println("llvmRunTimeHack==true - force casting return value"); Logger::cout() << "from: " << *retllval->getType() << " to: " << *rettype << '\n'; retllval = DtoBitCast(retllval, rettype); } } // set calling convention if (dfn && dfn->func) { int li = dfn->func->llvmInternal; if (li != LLVMintrinsic && li != LLVMva_start && li != LLVMva_intrinsic) { call->setCallingConv(DtoCallingConv(dlink)); } } /*else if (delegateCall) { call->setCallingConv(DtoCallingConv(dlink)); }*/ else if (dfn && dfn->cc != (unsigned)-1) { call->setCallingConv(dfn->cc); } else { call->setCallingConv(DtoCallingConv(dlink)); } return new DImValue(type, retllval, isInPlace); } ////////////////////////////////////////////////////////////////////////////////////////// DValue* CastExp::toElem(IRState* p) { Logger::print("CastExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; DValue* u = e1->toElem(p); DValue* v = DtoCast(u, to); if (v->isSlice()) { assert(!gIR->topexp() || gIR->topexp()->e1 != this); return v; } else if (u->isLRValue() || (u->isVar() && u->isVar()->lval)) return new DLRValue(e1->type, u->getLVal(), to, v->getRVal()); else if (gIR->topexp() && gIR->topexp()->e1 == this) return new DLRValue(e1->type, u->getLVal(), to, v->getRVal()); return v; } ////////////////////////////////////////////////////////////////////////////////////////// DValue* SymOffExp::toElem(IRState* p) { Logger::print("SymOffExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; assert(0 && "SymOffExp::toElem should no longer be called :/"); if (VarDeclaration* vd = var->isVarDeclaration()) { Logger::println("VarDeclaration"); // handle forward reference if (!vd->llvmDeclared && vd->isDataseg()) { vd->toObjFile(); // TODO } assert(vd->getIrValue()); Type* t = DtoDType(type); Type* tnext = DtoDType(t->next); Type* vdtype = DtoDType(vd->type); llvm::Value* llvalue = vd->nestedref ? DtoNestedVariable(vd) : vd->getIrValue(); llvm::Value* varmem = 0; if (vdtype->ty == Tstruct && !(t->ty == Tpointer && t->next == vdtype)) { Logger::println("struct"); TypeStruct* vdt = (TypeStruct*)vdtype; assert(vdt->sym); const llvm::Type* llt = DtoType(t); if (offset == 0) { varmem = p->ir->CreateBitCast(llvalue, llt, "tmp"); } else { std::vector<unsigned> dst; varmem = DtoIndexStruct(llvalue,vdt->sym, tnext, offset, dst); } } else if (vdtype->ty == Tsarray) { Logger::println("sarray"); assert(llvalue); //e->arg = llvalue; // TODO const llvm::Type* llt = DtoType(t); llvm::Value* off = 0; if (offset != 0) { Logger::println("offset = %d\n", offset); } if (offset == 0) { varmem = llvalue; } else { const llvm::Type* elemtype = llvalue->getType()->getContainedType(0)->getContainedType(0); size_t elemsz = getABITypeSize(elemtype); varmem = DtoGEPi(llvalue, 0, offset / elemsz, "tmp"); } } else if (offset == 0) { Logger::println("normal symoff"); assert(llvalue); varmem = llvalue; const llvm::Type* llt = DtoType(t); if (llvalue->getType() != llt) { varmem = p->ir->CreateBitCast(varmem, llt, "tmp"); } } else { assert(0); } return new DFieldValue(type, varmem, true); } assert(0); return 0; } ////////////////////////////////////////////////////////////////////////////////////////// DValue* AddrExp::toElem(IRState* p) { Logger::println("AddrExp::toElem: %s | %s", toChars(), type->toChars()); LOG_SCOPE; DValue* v = e1->toElem(p); if (v->isField()) { Logger::println("is field"); return v; } else if (DFuncValue* fv = v->isFunc()) { Logger::println("is func"); //Logger::println("FuncDeclaration"); FuncDeclaration* fd = fv->func; assert(fd); DtoForceDeclareDsymbol(fd); return new DFuncValue(fd, fd->irFunc->func); } else if (DImValue* im = v->isIm()) { Logger::println("is immediate"); return v; } Logger::println("is nothing special"); return new DFieldValue(type, v->getLVal(), false); } ////////////////////////////////////////////////////////////////////////////////////////// DValue* PtrExp::toElem(IRState* p) { Logger::println("PtrExp::toElem: %s | %s", toChars(), type->toChars()); LOG_SCOPE; DValue* a = e1->toElem(p); if (p->topexp() && p->topexp()->e1 == this) { Logger::println("lval PtrExp"); return new DVarValue(type, a->getRVal(), true); } // this should be deterministic but right now lvalue casts don't propagate lvalueness !?! llvm::Value* lv = a->getRVal(); llvm::Value* v = lv; if (DtoCanLoad(v)) v = DtoLoad(v); return new DLRValue(e1->type, lv, type, v); } ////////////////////////////////////////////////////////////////////////////////////////// DValue* DotVarExp::toElem(IRState* p) { Logger::print("DotVarExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; DValue* l = e1->toElem(p); Type* t = DtoDType(type); Type* e1type = DtoDType(e1->type); //Logger::print("e1type=%s\n", e1type->toChars()); if (VarDeclaration* vd = var->isVarDeclaration()) { llvm::Value* arrptr; if (e1type->ty == Tpointer) { assert(e1type->next->ty == Tstruct); TypeStruct* ts = (TypeStruct*)e1type->next; Logger::println("Struct member offset:%d", vd->offset); llvm::Value* src = l->getRVal(); std::vector<unsigned> vdoffsets; arrptr = DtoIndexStruct(src, ts->sym, vd->type, vd->offset, vdoffsets); } else if (e1type->ty == Tclass) { TypeClass* tc = (TypeClass*)e1type; Logger::println("Class member offset: %d", vd->offset); llvm::Value* src = l->getRVal(); std::vector<unsigned> vdoffsets; arrptr = DtoIndexClass(src, tc->sym, vd->type, vd->offset, vdoffsets); /*std::vector<unsigned> vdoffsets(1,0); tc->sym->offsetToIndex(vd->type, vd->offset, vdoffsets); llvm::Value* src = l->getRVal(); Logger::println("indices:"); for (size_t i=0; i<vdoffsets.size(); ++i) Logger::println("%d", vdoffsets[i]); Logger::cout() << "src: " << *src << '\n'; arrptr = DtoGEP(src,vdoffsets,"tmp",p->scopebb()); Logger::cout() << "dst: " << *arrptr << '\n';*/ } else assert(0); //Logger::cout() << "mem: " << *arrptr << '\n'; return new DVarValue(vd, arrptr, true); } else if (FuncDeclaration* fdecl = var->isFuncDeclaration()) { DtoResolveDsymbol(fdecl); llvm::Value* funcval; llvm::Value* vthis2 = 0; if (e1type->ty == Tclass) { TypeClass* tc = (TypeClass*)e1type; if (tc->sym->isInterfaceDeclaration()) { vthis2 = DtoCastInterfaceToObject(l, NULL)->getRVal(); } } llvm::Value* vthis = l->getRVal(); if (!vthis2) vthis2 = vthis; //unsigned cc = (unsigned)-1; // super call if (e1->op == TOKsuper) { DtoForceDeclareDsymbol(fdecl); funcval = fdecl->irFunc->func; assert(funcval); } // normal virtual call else if (fdecl->isAbstract() || (!fdecl->isFinal() && fdecl->isVirtual())) { assert(fdecl->vtblIndex > 0); assert(e1type->ty == Tclass); llvm::Value* zero = llvm::ConstantInt::get(llvm::Type::Int32Ty, 0, false); llvm::Value* vtblidx = llvm::ConstantInt::get(llvm::Type::Int32Ty, (size_t)fdecl->vtblIndex, false); //Logger::cout() << "vthis: " << *vthis << '\n'; funcval = DtoGEP(vthis, zero, zero, "tmp", p->scopebb()); funcval = new llvm::LoadInst(funcval,"tmp",p->scopebb()); funcval = DtoGEP(funcval, zero, vtblidx, toChars(), p->scopebb()); funcval = new llvm::LoadInst(funcval,"tmp",p->scopebb()); //assert(funcval->getType() == DtoType(fdecl->type)); //cc = DtoCallingConv(fdecl->linkage); } // static call else { DtoForceDeclareDsymbol(fdecl); funcval = fdecl->irFunc->func; assert(funcval); //assert(funcval->getType() == DtoType(fdecl->type)); } return new DFuncValue(fdecl, funcval, vthis2); } else { printf("unsupported dotvarexp: %s\n", var->toChars()); } assert(0); return 0; } ////////////////////////////////////////////////////////////////////////////////////////// DValue* ThisExp::toElem(IRState* p) { Logger::print("ThisExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; if (VarDeclaration* vd = var->isVarDeclaration()) { llvm::Value* v; v = p->func()->decl->irFunc->thisVar; if (llvm::isa<llvm::AllocaInst>(v)) v = new llvm::LoadInst(v, "tmp", p->scopebb()); return new DThisValue(vd, v); } assert(0); return 0; } ////////////////////////////////////////////////////////////////////////////////////////// DValue* IndexExp::toElem(IRState* p) { Logger::print("IndexExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; DValue* l = e1->toElem(p); Type* e1type = DtoDType(e1->type); p->arrays.push_back(l); // if $ is used it must be an array so this is fine. DValue* r = e2->toElem(p); p->arrays.pop_back(); llvm::Value* zero = llvm::ConstantInt::get(llvm::Type::Int32Ty, 0, false); llvm::Value* one = llvm::ConstantInt::get(llvm::Type::Int32Ty, 1, false); llvm::Value* arrptr = 0; if (e1type->ty == Tpointer) { arrptr = new llvm::GetElementPtrInst(l->getRVal(),r->getRVal(),"tmp",p->scopebb()); } else if (e1type->ty == Tsarray) { arrptr = DtoGEP(l->getRVal(), zero, r->getRVal(),"tmp",p->scopebb()); } else if (e1type->ty == Tarray) { arrptr = DtoGEP(l->getLVal(),zero,one,"tmp",p->scopebb()); arrptr = new llvm::LoadInst(arrptr,"tmp",p->scopebb()); arrptr = new llvm::GetElementPtrInst(arrptr,r->getRVal(),"tmp",p->scopebb()); } else if (e1type->ty == Taarray) { return DtoAAIndex(type, l, r); } else { Logger::println("invalid index exp! e1type: %s", e1type->toChars()); assert(0); } return new DVarValue(type, arrptr, true); } ////////////////////////////////////////////////////////////////////////////////////////// DValue* SliceExp::toElem(IRState* p) { Logger::print("SliceExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; Type* t = DtoDType(type); Type* e1type = DtoDType(e1->type); DValue* v = e1->toElem(p); llvm::Value* vmem = v->getRVal(); assert(vmem); llvm::Value* zero = llvm::ConstantInt::get(llvm::Type::Int32Ty, 0, false); llvm::Value* one = llvm::ConstantInt::get(llvm::Type::Int32Ty, 1, false); llvm::Value* emem = 0; llvm::Value* earg = 0; // partial slice if (lwr) { assert(upr); p->arrays.push_back(v); DValue* lo = lwr->toElem(p); bool lwr_is_zero = false; if (DConstValue* cv = lo->isConst()) { assert(llvm::isa<llvm::ConstantInt>(cv->c)); if (e1type->ty == Tpointer) { emem = v->getRVal(); } else if (e1type->ty == Tarray) { llvm::Value* tmp = DtoGEP(vmem,zero,one,"tmp",p->scopebb()); emem = new llvm::LoadInst(tmp,"tmp",p->scopebb()); } else if (e1type->ty == Tsarray) { emem = DtoGEP(vmem,zero,zero,"tmp",p->scopebb()); } else assert(emem); llvm::ConstantInt* c = llvm::cast<llvm::ConstantInt>(cv->c); if (!(lwr_is_zero = c->isZero())) { emem = new llvm::GetElementPtrInst(emem,cv->c,"tmp",p->scopebb()); } } else { if (e1type->ty == Tarray) { llvm::Value* tmp = DtoGEP(vmem,zero,one,"tmp",p->scopebb()); tmp = new llvm::LoadInst(tmp,"tmp",p->scopebb()); emem = new llvm::GetElementPtrInst(tmp,lo->getRVal(),"tmp",p->scopebb()); } else if (e1type->ty == Tsarray) { emem = DtoGEP(vmem,zero,lo->getRVal(),"tmp",p->scopebb()); } else if (e1type->ty == Tpointer) { emem = new llvm::GetElementPtrInst(v->getRVal(),lo->getRVal(),"tmp",p->scopebb()); } else { Logger::println("type = %s", e1type->toChars()); assert(0); } } DValue* up = upr->toElem(p); p->arrays.pop_back(); if (DConstValue* cv = up->isConst()) { assert(llvm::isa<llvm::ConstantInt>(cv->c)); if (lwr_is_zero) { earg = cv->c; } else { if (lo->isConst()) { llvm::Constant* clo = llvm::cast<llvm::Constant>(lo->getRVal()); llvm::Constant* cup = llvm::cast<llvm::Constant>(cv->c); earg = llvm::ConstantExpr::getSub(cup, clo); } else { earg = llvm::BinaryOperator::createSub(cv->c, lo->getRVal(), "tmp", p->scopebb()); } } } else { if (lwr_is_zero) { earg = up->getRVal(); } else { earg = llvm::BinaryOperator::createSub(up->getRVal(), lo->getRVal(), "tmp", p->scopebb()); } } } // full slice else { emem = vmem; } if (earg) Logger::cout() << "slice exp result, length = " << *earg << '\n'; Logger::cout() << "slice exp result, ptr = " << *emem << '\n'; return new DSliceValue(type,earg,emem); } ////////////////////////////////////////////////////////////////////////////////////////// DValue* CmpExp::toElem(IRState* p) { Logger::print("CmpExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; DValue* l = e1->toElem(p); DValue* r = e2->toElem(p); Type* t = DtoDType(e1->type); Type* e2t = DtoDType(e2->type); assert(t == e2t); llvm::Value* eval = 0; if (t->isintegral() || t->ty == Tpointer) { llvm::ICmpInst::Predicate cmpop; bool skip = false; switch(op) { case TOKlt: case TOKul: cmpop = t->isunsigned() ? llvm::ICmpInst::ICMP_ULT : llvm::ICmpInst::ICMP_SLT; break; case TOKle: case TOKule: cmpop = t->isunsigned() ? llvm::ICmpInst::ICMP_ULE : llvm::ICmpInst::ICMP_SLE; break; case TOKgt: case TOKug: cmpop = t->isunsigned() ? llvm::ICmpInst::ICMP_UGT : llvm::ICmpInst::ICMP_SGT; break; case TOKge: case TOKuge: cmpop = t->isunsigned() ? llvm::ICmpInst::ICMP_UGE : llvm::ICmpInst::ICMP_SGE; break; case TOKue: cmpop = llvm::ICmpInst::ICMP_EQ; break; case TOKlg: cmpop = llvm::ICmpInst::ICMP_NE; break; case TOKleg: skip = true; eval = llvm::ConstantInt::getTrue(); break; case TOKunord: skip = true; eval = llvm::ConstantInt::getFalse(); break; default: assert(0); } if (!skip) { llvm::Value* a = l->getRVal(); llvm::Value* b = r->getRVal(); Logger::cout() << "type 1: " << *a << '\n'; Logger::cout() << "type 2: " << *b << '\n'; eval = new llvm::ICmpInst(cmpop, a, b, "tmp", p->scopebb()); } } else if (t->isfloating()) { llvm::FCmpInst::Predicate cmpop; switch(op) { case TOKlt: cmpop = llvm::FCmpInst::FCMP_OLT;break; case TOKle: cmpop = llvm::FCmpInst::FCMP_OLE;break; case TOKgt: cmpop = llvm::FCmpInst::FCMP_OGT;break; case TOKge: cmpop = llvm::FCmpInst::FCMP_OGE;break; case TOKunord: cmpop = llvm::FCmpInst::FCMP_UNO;break; case TOKule: cmpop = llvm::FCmpInst::FCMP_ULE;break; case TOKul: cmpop = llvm::FCmpInst::FCMP_ULT;break; case TOKuge: cmpop = llvm::FCmpInst::FCMP_UGE;break; case TOKug: cmpop = llvm::FCmpInst::FCMP_UGT;break; case TOKue: cmpop = llvm::FCmpInst::FCMP_UEQ;break; case TOKlg: cmpop = llvm::FCmpInst::FCMP_ONE;break; case TOKleg: cmpop = llvm::FCmpInst::FCMP_ORD;break; default: assert(0); } eval = new llvm::FCmpInst(cmpop, l->getRVal(), r->getRVal(), "tmp", p->scopebb()); } else if (t->ty == Tsarray || t->ty == Tarray) { Logger::println("static or dynamic array"); eval = DtoArrayCompare(op,l,r); } else { assert(0 && "Unsupported CmpExp type"); } return new DImValue(type, eval); } ////////////////////////////////////////////////////////////////////////////////////////// DValue* EqualExp::toElem(IRState* p) { Logger::print("EqualExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; DValue* l = e1->toElem(p); DValue* r = e2->toElem(p); Type* t = DtoDType(e1->type); Type* e2t = DtoDType(e2->type); //assert(t == e2t); llvm::Value* eval = 0; if (t->isintegral() || t->ty == Tpointer) { Logger::println("integral or pointer"); llvm::ICmpInst::Predicate cmpop; switch(op) { case TOKequal: cmpop = llvm::ICmpInst::ICMP_EQ; break; case TOKnotequal: cmpop = llvm::ICmpInst::ICMP_NE; break; default: assert(0); } llvm::Value* lv = l->getRVal(); llvm::Value* rv = r->getRVal(); if (rv->getType() != lv->getType()) { rv = DtoBitCast(rv, lv->getType()); } eval = new llvm::ICmpInst(cmpop, lv, rv, "tmp", p->scopebb()); } else if (t->iscomplex()) { Logger::println("complex"); eval = DtoComplexEquals(op, l, r); } else if (t->isfloating()) { Logger::println("floating"); llvm::FCmpInst::Predicate cmpop; switch(op) { case TOKequal: cmpop = llvm::FCmpInst::FCMP_OEQ; break; case TOKnotequal: cmpop = llvm::FCmpInst::FCMP_UNE; break; default: assert(0); } eval = new llvm::FCmpInst(cmpop, l->getRVal(), r->getRVal(), "tmp", p->scopebb()); } else if (t->ty == Tsarray || t->ty == Tarray) { Logger::println("static or dynamic array"); eval = DtoArrayEquals(op,l,r); } else if (t->ty == Tdelegate) { Logger::println("delegate"); eval = DtoCompareDelegate(op,l->getRVal(),r->getRVal()); } else { assert(0 && "Unsupported EqualExp type"); } return new DImValue(type, eval); } ////////////////////////////////////////////////////////////////////////////////////////// DValue* PostExp::toElem(IRState* p) { Logger::print("PostExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; DValue* l = e1->toElem(p); DValue* r = e2->toElem(p); llvm::Value* val = l->getRVal(); llvm::Value* post = 0; Type* e1type = DtoDType(e1->type); Type* e2type = DtoDType(e2->type); if (e1type->isintegral()) { assert(e2type->isintegral()); llvm::Value* one = llvm::ConstantInt::get(val->getType(), 1, !e2type->isunsigned()); if (op == TOKplusplus) { post = llvm::BinaryOperator::createAdd(val,one,"tmp",p->scopebb()); } else if (op == TOKminusminus) { post = llvm::BinaryOperator::createSub(val,one,"tmp",p->scopebb()); } } else if (e1type->ty == Tpointer) { assert(e2type->isintegral()); llvm::Constant* minusone = llvm::ConstantInt::get(DtoSize_t(),(uint64_t)-1,true); llvm::Constant* plusone = llvm::ConstantInt::get(DtoSize_t(),(uint64_t)1,false); llvm::Constant* whichone = (op == TOKplusplus) ? plusone : minusone; post = new llvm::GetElementPtrInst(val, whichone, "tmp", p->scopebb()); } else if (e1type->isfloating()) { assert(e2type->isfloating()); llvm::Value* one = llvm::ConstantFP::get(val->getType(), llvm::APFloat(1.0f)); if (op == TOKplusplus) { post = llvm::BinaryOperator::createAdd(val,one,"tmp",p->scopebb()); } else if (op == TOKminusminus) { post = llvm::BinaryOperator::createSub(val,one,"tmp",p->scopebb()); } } else assert(post); DtoStore(post,l->getLVal()); return new DImValue(type,val,true); } ////////////////////////////////////////////////////////////////////////////////////////// DValue* NewExp::toElem(IRState* p) { Logger::print("NewExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; assert(!newargs && "arguments to new not yet supported"); assert(newtype); assert(!allocator && "custom allocators not yet supported"); Type* ntype = DtoDType(newtype); if (ntype->ty == Tclass) { return DtoNewClass((TypeClass*)ntype, this); } const llvm::Type* t = DtoType(ntype); llvm::Value* emem = 0; bool inplace = false; if (ntype->ty == Tarray) { assert(arguments); if (arguments->dim == 1) { DValue* sz = ((Expression*)arguments->data[0])->toElem(p); llvm::Value* dimval = sz->getRVal(); Type* nnt = DtoDType(ntype->next); if (nnt->ty == Tvoid) nnt = Type::tint8; if (p->topexp() && p->topexp()->e2 == this) { assert(p->topexp()->v); emem = p->topexp()->v->getLVal(); DtoNewDynArray(emem, dimval, nnt); inplace = true; } else { const llvm::Type* restype = DtoType(type); Logger::cout() << "restype = " << *restype << '\n'; emem = new llvm::AllocaInst(restype,"newstorage",p->topallocapoint()); DtoNewDynArray(emem, dimval, nnt); return new DVarValue(newtype, emem, true); } } else { assert(0 && "num args to 'new' != 1"); } } else { emem = new llvm::MallocInst(t,"tmp",p->scopebb()); } if (ntype->ty == Tstruct) { TypeStruct* ts = (TypeStruct*)ntype; if (ts->isZeroInit()) { DtoStructZeroInit(emem); } else { assert(ts->sym); DtoStructCopy(emem,ts->sym->irStruct->init); } } return new DImValue(type, emem, inplace); } ////////////////////////////////////////////////////////////////////////////////////////// DValue* DeleteExp::toElem(IRState* p) { Logger::print("DeleteExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; //assert(e1->type->ty != Tclass); DValue* v = e1->toElem(p); const llvm::Type* t = DtoType(v->getType()); llvm::Value* ldval = 0; llvm::Constant* z = llvm::Constant::getNullValue(t); Type* e1type = DtoDType(e1->type); if (e1type->ty == Tpointer) { llvm::Value* val = v->getRVal(); Logger::cout() << *z << '\n'; Logger::cout() << *val << '\n'; new llvm::FreeInst(val, p->scopebb()); new llvm::StoreInst(z, v->getLVal(), p->scopebb()); } else if (e1type->ty == Tclass) { TypeClass* tc = (TypeClass*)e1type; llvm::Value* val = 0; if (tc->sym->dtors.dim > 0) { val = v->getRVal(); DtoCallClassDtors(tc, val); } if (DVarValue* vv = v->isVar()) { if (vv->var && !vv->var->onstack) { if (!val) val = v->getRVal(); new llvm::FreeInst(val, p->scopebb()); } } new llvm::StoreInst(z, v->getLVal(), p->scopebb()); } else if (e1type->ty == Tarray) { // must be on the heap (correct?) llvm::Value* val = v->getRVal(); llvm::Value* zero = llvm::ConstantInt::get(llvm::Type::Int32Ty, 0, false); llvm::Value* one = llvm::ConstantInt::get(llvm::Type::Int32Ty, 1, false); llvm::Value* ptr = DtoGEP(val,zero,one,"tmp",p->scopebb()); ptr = new llvm::LoadInst(ptr,"tmp",p->scopebb()); new llvm::FreeInst(ptr, p->scopebb()); DtoSetArrayToNull(val); } else { assert(0); } // this expression produces no useful data return 0; } ////////////////////////////////////////////////////////////////////////////////////////// DValue* ArrayLengthExp::toElem(IRState* p) { Logger::print("ArrayLengthExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; DValue* u = e1->toElem(p); if (p->topexp() && p->topexp()->e1 == this) { return new DArrayLenValue(type, u->getLVal()); } else { llvm::Value* zero = llvm::ConstantInt::get(llvm::Type::Int32Ty, 0, false); llvm::Value* ptr = DtoGEP(u->getRVal(),zero,zero,"tmp",p->scopebb()); ptr = new llvm::LoadInst(ptr, "tmp", p->scopebb()); return new DImValue(type, ptr); } } ////////////////////////////////////////////////////////////////////////////////////////// DValue* AssertExp::toElem(IRState* p) { Logger::print("AssertExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; // condition DValue* cond = e1->toElem(p); // create basic blocks llvm::BasicBlock* oldend = p->scopeend(); llvm::BasicBlock* assertbb = new llvm::BasicBlock("assert", p->topfunc(), oldend); llvm::BasicBlock* endbb = new llvm::BasicBlock("endassert", p->topfunc(), oldend); // test condition llvm::Value* condval = cond->getRVal(); condval = DtoBoolean(condval); // branch new llvm::BranchInst(endbb, assertbb, condval, p->scopebb()); // call assert runtime functions p->scope() = IRScope(assertbb,endbb); DtoAssert(&loc, msg ? msg->toElem(p) : NULL); if (!gIR->scopereturned()) new llvm::BranchInst(endbb, p->scopebb()); // rewrite the scope p->scope() = IRScope(endbb,oldend); // no meaningful return value return NULL; } ////////////////////////////////////////////////////////////////////////////////////////// DValue* NotExp::toElem(IRState* p) { Logger::print("NotExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; DValue* u = e1->toElem(p); llvm::Value* b = DtoBoolean(u->getRVal()); llvm::Constant* zero = llvm::ConstantInt::get(llvm::Type::Int1Ty, 0, true); b = p->ir->CreateICmpEQ(b,zero); return new DImValue(type, b); } ////////////////////////////////////////////////////////////////////////////////////////// DValue* AndAndExp::toElem(IRState* p) { Logger::print("AndAndExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; // allocate a temporary for the final result. failed to come up with a better way :/ llvm::Value* resval = 0; llvm::BasicBlock* entryblock = &p->topfunc()->front(); resval = new llvm::AllocaInst(llvm::Type::Int1Ty,"andandtmp",p->topallocapoint()); DValue* u = e1->toElem(p); llvm::BasicBlock* oldend = p->scopeend(); llvm::BasicBlock* andand = new llvm::BasicBlock("andand", gIR->topfunc(), oldend); llvm::BasicBlock* andandend = new llvm::BasicBlock("andandend", gIR->topfunc(), oldend); llvm::Value* ubool = DtoBoolean(u->getRVal()); new llvm::StoreInst(ubool,resval,p->scopebb()); new llvm::BranchInst(andand,andandend,ubool,p->scopebb()); p->scope() = IRScope(andand, andandend); DValue* v = e2->toElem(p); llvm::Value* vbool = DtoBoolean(v->getRVal()); llvm::Value* uandvbool = llvm::BinaryOperator::create(llvm::BinaryOperator::And, ubool, vbool,"tmp",p->scopebb()); new llvm::StoreInst(uandvbool,resval,p->scopebb()); new llvm::BranchInst(andandend,p->scopebb()); p->scope() = IRScope(andandend, oldend); resval = new llvm::LoadInst(resval,"tmp",p->scopebb()); return new DImValue(type, resval); } ////////////////////////////////////////////////////////////////////////////////////////// DValue* OrOrExp::toElem(IRState* p) { Logger::print("OrOrExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; // allocate a temporary for the final result. failed to come up with a better way :/ llvm::Value* resval = 0; llvm::BasicBlock* entryblock = &p->topfunc()->front(); resval = new llvm::AllocaInst(llvm::Type::Int1Ty,"orortmp",p->topallocapoint()); DValue* u = e1->toElem(p); llvm::BasicBlock* oldend = p->scopeend(); llvm::BasicBlock* oror = new llvm::BasicBlock("oror", gIR->topfunc(), oldend); llvm::BasicBlock* ororend = new llvm::BasicBlock("ororend", gIR->topfunc(), oldend); llvm::Value* ubool = DtoBoolean(u->getRVal()); new llvm::StoreInst(ubool,resval,p->scopebb()); new llvm::BranchInst(ororend,oror,ubool,p->scopebb()); p->scope() = IRScope(oror, ororend); DValue* v = e2->toElem(p); llvm::Value* vbool = DtoBoolean(v->getRVal()); new llvm::StoreInst(vbool,resval,p->scopebb()); new llvm::BranchInst(ororend,p->scopebb()); p->scope() = IRScope(ororend, oldend); resval = new llvm::LoadInst(resval,"tmp",p->scopebb()); return new DImValue(type, resval); } ////////////////////////////////////////////////////////////////////////////////////////// #define BinBitExp(X,Y) \ DValue* X##Exp::toElem(IRState* p) \ { \ Logger::print("%sExp::toElem: %s | %s\n", #X, toChars(), type->toChars()); \ LOG_SCOPE; \ DValue* u = e1->toElem(p); \ DValue* v = e2->toElem(p); \ llvm::Value* x = llvm::BinaryOperator::create(llvm::Instruction::Y, u->getRVal(), v->getRVal(), "tmp", p->scopebb()); \ return new DImValue(type, x); \ } \ \ DValue* X##AssignExp::toElem(IRState* p) \ { \ Logger::print("%sAssignExp::toElem: %s | %s\n", #X, toChars(), type->toChars()); \ LOG_SCOPE; \ p->exps.push_back(IRExp(e1,e2,NULL)); \ DValue* u = e1->toElem(p); \ p->topexp()->v = u; \ DValue* v = e2->toElem(p); \ p->exps.pop_back(); \ llvm::Value* uval = u->getRVal(); \ llvm::Value* vval = v->getRVal(); \ llvm::Value* tmp = llvm::BinaryOperator::create(llvm::Instruction::Y, uval, vval, "tmp", p->scopebb()); \ new llvm::StoreInst(DtoPointedType(u->getLVal(), tmp), u->getLVal(), p->scopebb()); \ return u; \ } BinBitExp(And,And); BinBitExp(Or,Or); BinBitExp(Xor,Xor); BinBitExp(Shl,Shl); BinBitExp(Shr,AShr); BinBitExp(Ushr,LShr); ////////////////////////////////////////////////////////////////////////////////////////// DValue* HaltExp::toElem(IRState* p) { Logger::print("HaltExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; DtoAssert(&loc, NULL); new llvm::UnreachableInst(p->scopebb()); return 0; } ////////////////////////////////////////////////////////////////////////////////////////// DValue* DelegateExp::toElem(IRState* p) { Logger::print("DelegateExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; const llvm::PointerType* int8ptrty = getPtrToType(llvm::Type::Int8Ty); llvm::Value* lval; bool inplace = false; if (p->topexp() && p->topexp()->e2 == this) { assert(p->topexp()->v); lval = p->topexp()->v->getLVal(); inplace = true; } else { lval = new llvm::AllocaInst(DtoType(type), "tmpdelegate", p->topallocapoint()); } DValue* u = e1->toElem(p); llvm::Value* uval; if (DFuncValue* f = u->isFunc()) { //assert(f->vthis); //uval = f->vthis; llvm::Value* nestvar = p->func()->decl->irFunc->nestedVar; if (nestvar) uval = nestvar; else uval = llvm::ConstantPointerNull::get(int8ptrty); } else { DValue* src = u; if (ClassDeclaration* cd = u->getType()->isClassHandle()) { Logger::println("context type is class handle"); if (cd->isInterfaceDeclaration()) { Logger::println("context type is interface"); src = DtoCastInterfaceToObject(u, ClassDeclaration::object->type); } } uval = src->getRVal(); } Logger::cout() << "context = " << *uval << '\n'; llvm::Value* context = DtoGEPi(lval,0,0,"tmp"); llvm::Value* castcontext = DtoBitCast(uval, int8ptrty); DtoStore(castcontext, context); llvm::Value* fptr = DtoGEPi(lval,0,1,"tmp"); Logger::println("func: '%s'", func->toPrettyChars()); llvm::Value* castfptr; if (func->isVirtual()) castfptr = DtoVirtualFunctionPointer(u, func); else if (func->isAbstract()) assert(0 && "TODO delegate to abstract method"); else if (func->toParent()->isInterfaceDeclaration()) assert(0 && "TODO delegate to interface method"); else castfptr = func->irFunc->func; castfptr = DtoBitCast(castfptr, fptr->getType()->getContainedType(0)); DtoStore(castfptr, fptr); return new DImValue(type, lval, inplace); } ////////////////////////////////////////////////////////////////////////////////////////// DValue* IdentityExp::toElem(IRState* p) { Logger::print("IdentityExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; DValue* u = e1->toElem(p); DValue* v = e2->toElem(p); llvm::Value* l = u->getRVal(); llvm::Value* r = v->getRVal(); Type* t1 = DtoDType(e1->type); llvm::Value* eval = 0; if (t1->ty == Tarray) { if (v->isNull()) { r = NULL; } else { assert(l->getType() == r->getType()); } eval = DtoDynArrayIs(op,l,r); } else if (t1->isfloating()) { llvm::FCmpInst::Predicate pred = (op == TOKidentity) ? llvm::FCmpInst::FCMP_OEQ : llvm::FCmpInst::FCMP_ONE; eval = new llvm::FCmpInst(pred, l, r, "tmp", p->scopebb()); } else { llvm::ICmpInst::Predicate pred = (op == TOKidentity) ? llvm::ICmpInst::ICMP_EQ : llvm::ICmpInst::ICMP_NE; if (t1->ty == Tpointer && v->isNull() && l->getType() != r->getType()) { r = llvm::ConstantPointerNull::get(isaPointer(l->getType())); } //Logger::cout() << "l = " << *l << " r = " << *r << '\n'; eval = new llvm::ICmpInst(pred, l, r, "tmp", p->scopebb()); } return new DImValue(type, eval); } ////////////////////////////////////////////////////////////////////////////////////////// DValue* CommaExp::toElem(IRState* p) { Logger::print("CommaExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; DValue* u = e1->toElem(p); DValue* v = e2->toElem(p); assert(e2->type == type); return v; } ////////////////////////////////////////////////////////////////////////////////////////// DValue* CondExp::toElem(IRState* p) { Logger::print("CondExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; Type* dtype = DtoDType(type); const llvm::Type* resty = DtoType(dtype); // allocate a temporary for the final result. failed to come up with a better way :/ llvm::BasicBlock* entryblock = &p->topfunc()->front(); llvm::Value* resval = new llvm::AllocaInst(resty,"condtmp",p->topallocapoint()); DVarValue* dvv = new DVarValue(type, resval, true); llvm::BasicBlock* oldend = p->scopeend(); llvm::BasicBlock* condtrue = new llvm::BasicBlock("condtrue", gIR->topfunc(), oldend); llvm::BasicBlock* condfalse = new llvm::BasicBlock("condfalse", gIR->topfunc(), oldend); llvm::BasicBlock* condend = new llvm::BasicBlock("condend", gIR->topfunc(), oldend); DValue* c = econd->toElem(p); llvm::Value* cond_val = DtoBoolean(c->getRVal()); new llvm::BranchInst(condtrue,condfalse,cond_val,p->scopebb()); p->scope() = IRScope(condtrue, condfalse); DValue* u = e1->toElem(p); DtoAssign(dvv, u); new llvm::BranchInst(condend,p->scopebb()); p->scope() = IRScope(condfalse, condend); DValue* v = e2->toElem(p); DtoAssign(dvv, v); new llvm::BranchInst(condend,p->scopebb()); p->scope() = IRScope(condend, oldend); return dvv; } ////////////////////////////////////////////////////////////////////////////////////////// DValue* ComExp::toElem(IRState* p) { Logger::print("ComExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; DValue* u = e1->toElem(p); llvm::Value* value = u->getRVal(); llvm::Value* minusone = llvm::ConstantInt::get(value->getType(), -1, true); value = llvm::BinaryOperator::create(llvm::Instruction::Xor, value, minusone, "tmp", p->scopebb()); return new DImValue(type, value); } ////////////////////////////////////////////////////////////////////////////////////////// DValue* NegExp::toElem(IRState* p) { Logger::print("NegExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; DValue* l = e1->toElem(p); llvm::Value* val = l->getRVal(); Type* t = DtoDType(type); llvm::Value* zero = 0; if (t->isintegral()) zero = llvm::ConstantInt::get(val->getType(), 0, true); else if (t->isfloating()) { if (t->ty == Tfloat32 || t->ty == Timaginary32) zero = llvm::ConstantFP::get(val->getType(), llvm::APFloat(0.0f)); else if (t->ty == Tfloat64 || t->ty == Tfloat80 || t->ty == Timaginary64 || t->ty == Timaginary80) zero = llvm::ConstantFP::get(val->getType(), llvm::APFloat(0.0)); else assert(0); } else assert(0); val = llvm::BinaryOperator::createSub(zero,val,"tmp",p->scopebb()); return new DImValue(type, val); } ////////////////////////////////////////////////////////////////////////////////////////// DValue* CatExp::toElem(IRState* p) { Logger::print("CatExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; Type* t = DtoDType(type); bool arrNarr = DtoDType(e1->type) == DtoDType(e2->type); IRExp* ex = p->topexp(); if (ex && ex->e2 == this) { assert(ex->v); if (arrNarr) DtoCatArrays(ex->v->getLVal(),e1,e2); else DtoCatArrayElement(ex->v->getLVal(),e1,e2); return new DImValue(type, ex->v->getLVal(), true); } else { assert(t->ty == Tarray); const llvm::Type* arrty = DtoType(t); llvm::Value* dst = new llvm::AllocaInst(arrty, "tmpmem", p->topallocapoint()); if (arrNarr) DtoCatArrays(dst,e1,e2); else DtoCatArrayElement(dst,e1,e2); return new DVarValue(type, dst, true); } } ////////////////////////////////////////////////////////////////////////////////////////// DValue* CatAssignExp::toElem(IRState* p) { Logger::print("CatAssignExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; DValue* l = e1->toElem(p); Type* e1type = DtoDType(e1->type); Type* elemtype = DtoDType(e1type->next); Type* e2type = DtoDType(e2->type); if (e2type == elemtype) { DtoCatAssignElement(l->getLVal(),e2); } else if (e1type == e2type) { DtoCatAssignArray(l->getLVal(),e2); } else assert(0 && "only one element at a time right now"); return 0; } ////////////////////////////////////////////////////////////////////////////////////////// DValue* FuncExp::toElem(IRState* p) { Logger::print("FuncExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; assert(fd); if (fd->isNested()) Logger::println("nested"); Logger::println("kind = %s\n", fd->kind()); DtoForceDefineDsymbol(fd); bool temp = false; llvm::Value* lval = NULL; if (p->topexp() && p->topexp()->e2 == this) { assert(p->topexp()->v); lval = p->topexp()->v->getLVal(); } else { const llvm::Type* dgty = DtoType(type); Logger::cout() << "delegate without explicit storage:" << '\n' << *dgty << '\n'; lval = new llvm::AllocaInst(dgty,"dgstorage",p->topallocapoint()); temp = true; } llvm::Value* context = DtoGEPi(lval,0,0,"tmp",p->scopebb()); const llvm::PointerType* pty = isaPointer(context->getType()->getContainedType(0)); llvm::Value* llvmNested = p->func()->decl->irFunc->nestedVar; if (llvmNested == NULL) { llvm::Value* nullcontext = llvm::ConstantPointerNull::get(pty); p->ir->CreateStore(nullcontext, context); } else { llvm::Value* nestedcontext = p->ir->CreateBitCast(llvmNested, pty, "tmp"); p->ir->CreateStore(nestedcontext, context); } llvm::Value* fptr = DtoGEPi(lval,0,1,"tmp",p->scopebb()); assert(fd->irFunc->func); llvm::Value* castfptr = new llvm::BitCastInst(fd->irFunc->func,fptr->getType()->getContainedType(0),"tmp",p->scopebb()); new llvm::StoreInst(castfptr, fptr, p->scopebb()); if (temp) return new DVarValue(type, lval, true); else return new DImValue(type, lval, true); } ////////////////////////////////////////////////////////////////////////////////////////// DValue* ArrayLiteralExp::toElem(IRState* p) { Logger::print("ArrayLiteralExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; Type* ty = DtoDType(type); const llvm::Type* t = DtoType(ty); Logger::cout() << "array literal has llvm type: " << *t << '\n'; llvm::Value* mem = 0; bool inplace_slice = false; if (!p->topexp() || p->topexp()->e2 != this) { assert(DtoDType(type)->ty == Tsarray); mem = new llvm::AllocaInst(t,"arrayliteral",p->topallocapoint()); } else if (p->topexp()->e2 == this) { DValue* tlv = p->topexp()->v; if (DSliceValue* sv = tlv->isSlice()) { assert(sv->len == 0); mem = sv->ptr; inplace_slice = true; } else { mem = p->topexp()->v->getLVal(); } assert(mem); if (!isaPointer(mem->getType()) || !isaArray(mem->getType()->getContainedType(0))) { assert(!inplace_slice); assert(ty->ty == Tarray); // we need to give this array literal storage const llvm::ArrayType* arrty = llvm::ArrayType::get(DtoType(ty->next), elements->dim); mem = new llvm::AllocaInst(arrty, "arrayliteral", p->topallocapoint()); } } else assert(0); Logger::cout() << "array literal mem: " << *mem << '\n'; for (unsigned i=0; i<elements->dim; ++i) { Expression* expr = (Expression*)elements->data[i]; llvm::Value* elemAddr = DtoGEPi(mem,0,i,"tmp",p->scopebb()); DVarValue* vv = new DVarValue(expr->type, elemAddr, true); p->exps.push_back(IRExp(NULL, expr, vv)); DValue* e = expr->toElem(p); p->exps.pop_back(); DImValue* im = e->isIm(); if (!im || !im->inPlace()) { DtoAssign(vv, e); } } if (ty->ty == Tsarray || (ty->ty == Tarray && inplace_slice)) return new DImValue(type, mem, true); else if (ty->ty == Tarray) return new DSliceValue(type, DtoConstSize_t(elements->dim), DtoGEPi(mem,0,0,"tmp")); else { assert(0); return 0; } } ////////////////////////////////////////////////////////////////////////////////////////// llvm::Constant* ArrayLiteralExp::toConstElem(IRState* p) { Logger::print("ArrayLiteralExp::toConstElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; const llvm::Type* t = DtoType(type); Logger::cout() << "array literal has llvm type: " << *t << '\n'; assert(isaArray(t)); const llvm::ArrayType* arrtype = isaArray(t); assert(arrtype->getNumElements() == elements->dim); std::vector<llvm::Constant*> vals(elements->dim, NULL); for (unsigned i=0; i<elements->dim; ++i) { Expression* expr = (Expression*)elements->data[i]; vals[i] = expr->toConstElem(p); } return llvm::ConstantArray::get(arrtype, vals); } ////////////////////////////////////////////////////////////////////////////////////////// DValue* StructLiteralExp::toElem(IRState* p) { Logger::print("StructLiteralExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; llvm::Value* sptr; const llvm::Type* llt = DtoType(type); llvm::Value* mem = 0; // temporary struct literal if (!p->topexp() || p->topexp()->e2 != this) { sptr = new llvm::AllocaInst(llt,"tmpstructliteral",p->topallocapoint()); } // already has memory else { assert(p->topexp()->e2 == this); sptr = p->topexp()->v->getLVal(); } // num elements in literal unsigned n = elements->dim; // unions might have different types for each literal if (sd->irStruct->hasUnions) { // build the type of the literal std::vector<const llvm::Type*> tys; for (unsigned i=0; i<n; ++i) { Expression* vx = (Expression*)elements->data[i]; if (!vx) continue; tys.push_back(DtoType(vx->type)); } const llvm::StructType* t = llvm::StructType::get(tys); if (t != llt) { if (getABITypeSize(t) != getABITypeSize(llt)) { Logger::cout() << "got size " << getABITypeSize(t) << ", expected " << getABITypeSize(llt) << '\n'; assert(0 && "type size mismatch"); } sptr = DtoBitCast(sptr, getPtrToType(t)); Logger::cout() << "sptr type is now: " << *t << '\n'; } } // build unsigned j = 0; for (unsigned i=0; i<n; ++i) { Expression* vx = (Expression*)elements->data[i]; if (!vx) continue; Logger::cout() << "getting index " << j << " of " << *sptr << '\n'; llvm::Value* arrptr = DtoGEPi(sptr,0,j,"tmp",p->scopebb()); DValue* darrptr = new DVarValue(vx->type, arrptr, true); p->exps.push_back(IRExp(NULL,vx,darrptr)); DValue* ve = vx->toElem(p); p->exps.pop_back(); if (!ve->inPlace()) DtoAssign(darrptr, ve); j++; } return new DImValue(type, sptr, true); } ////////////////////////////////////////////////////////////////////////////////////////// llvm::Constant* StructLiteralExp::toConstElem(IRState* p) { Logger::print("StructLiteralExp::toConstElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; unsigned n = elements->dim; std::vector<llvm::Constant*> vals(n, NULL); for (unsigned i=0; i<n; ++i) { Expression* vx = (Expression*)elements->data[i]; vals[i] = vx->toConstElem(p); } assert(DtoDType(type)->ty == Tstruct); const llvm::Type* t = DtoType(type); const llvm::StructType* st = isaStruct(t); return llvm::ConstantStruct::get(st,vals); } ////////////////////////////////////////////////////////////////////////////////////////// DValue* InExp::toElem(IRState* p) { Logger::print("InExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; DValue* key = e1->toElem(p); DValue* aa = e2->toElem(p); return DtoAAIn(type, aa, key); } DValue* RemoveExp::toElem(IRState* p) { Logger::print("RemoveExp::toElem: %s\n", toChars()); LOG_SCOPE; DValue* aa = e1->toElem(p); DValue* key = e2->toElem(p); DtoAARemove(aa, key); return NULL; // does not produce anything useful } ////////////////////////////////////////////////////////////////////////////////////////// DValue* AssocArrayLiteralExp::toElem(IRState* p) { Logger::print("AssocArrayLiteralExp::toElem: %s | %s\n", toChars(), type->toChars()); LOG_SCOPE; assert(keys); assert(values); assert(keys->dim == values->dim); Type* aatype = DtoDType(type); Type* vtype = aatype->next; DValue* aa; if (p->topexp() && p->topexp()->e2 == this) { aa = p->topexp()->v; } else { llvm::Value* tmp = new llvm::AllocaInst(DtoType(type),"aaliteral",p->topallocapoint()); aa = new DVarValue(type, tmp, true); } const size_t n = keys->dim; for (size_t i=0; i<n; ++i) { Expression* ekey = (Expression*)keys->data[i]; Expression* eval = (Expression*)values->data[i]; Logger::println("(%u) aa[%s] = %s", i, ekey->toChars(), eval->toChars()); // index DValue* key = ekey->toElem(p); DValue* mem = DtoAAIndex(vtype, aa, key); // store DValue* val = eval->toElem(p); DtoAssign(mem, val); } return aa; } ////////////////////////////////////////////////////////////////////////////////////////// #define STUB(x) DValue *x::toElem(IRState * p) {error("Exp type "#x" not implemented: %s", toChars()); fatal(); return 0; } //STUB(IdentityExp); //STUB(CondExp); //STUB(EqualExp); //STUB(InExp); //STUB(CmpExp); //STUB(AndAndExp); //STUB(OrOrExp); //STUB(AndExp); //STUB(AndAssignExp); //STUB(OrExp); //STUB(OrAssignExp); //STUB(XorExp); //STUB(XorAssignExp); //STUB(ShrExp); //STUB(ShrAssignExp); //STUB(ShlExp); //STUB(ShlAssignExp); //STUB(UshrExp); //STUB(UshrAssignExp); //STUB(DivExp); //STUB(DivAssignExp); //STUB(MulExp); //STUB(MulAssignExp); //STUB(ModExp); //STUB(ModAssignExp); //STUB(CatExp); //STUB(CatAssignExp); //STUB(AddExp); //STUB(AddAssignExp); STUB(Expression); //STUB(MinExp); //STUB(MinAssignExp); //STUB(PostExp); //STUB(NullExp); //STUB(ThisExp); //STUB(CallExp); STUB(DotTypeExp); STUB(TypeDotIdExp); //STUB(DotVarExp); //STUB(AssertExp); //STUB(FuncExp); //STUB(DelegateExp); //STUB(VarExp); //STUB(DeclarationExp); //STUB(NewExp); //STUB(SymOffExp); STUB(ScopeExp); //STUB(AssignExp); STUB(TypeExp); //STUB(RealExp); //STUB(ComplexExp); //STUB(StringExp); //STUB(IntegerExp); STUB(BoolExp); //STUB(NotExp); //STUB(ComExp); //STUB(NegExp); //STUB(PtrExp); //STUB(AddrExp); //STUB(SliceExp); //STUB(CastExp); //STUB(DeleteExp); //STUB(IndexExp); //STUB(CommaExp); //STUB(ArrayLengthExp); //STUB(HaltExp); //STUB(RemoveExp); //STUB(ArrayLiteralExp); //STUB(AssocArrayLiteralExp); //STUB(StructLiteralExp); STUB(TupleExp); #define CONSTSTUB(x) llvm::Constant* x::toConstElem(IRState * p) {error("const Exp type "#x" not implemented: '%s' type: '%s'", toChars(), type->toChars()); fatal(); return NULL; } CONSTSTUB(Expression); //CONSTSTUB(IntegerExp); //CONSTSTUB(RealExp); //CONSTSTUB(NullExp); //CONSTSTUB(ComplexExp); //CONSTSTUB(StringExp); //CONSTSTUB(VarExp); //CONSTSTUB(ArrayLiteralExp); CONSTSTUB(AssocArrayLiteralExp); //CONSTSTUB(StructLiteralExp); unsigned Type::totym() { return 0; } type * Type::toCtype() { assert(0); return 0; } type * Type::toCParamtype() { assert(0); return 0; } Symbol * Type::toSymbol() { assert(0); return 0; } type * TypeTypedef::toCtype() { assert(0); return 0; } type * TypeTypedef::toCParamtype() { assert(0); return 0; } void TypedefDeclaration::toDebug() { assert(0); } type * TypeEnum::toCtype() { assert(0); return 0; } type * TypeStruct::toCtype() { assert(0); return 0; } void StructDeclaration::toDebug() { assert(0); } Symbol * TypeClass::toSymbol() { assert(0); return 0; } unsigned TypeFunction::totym() { assert(0); return 0; } type * TypeFunction::toCtype() { assert(0); return 0; } type * TypeSArray::toCtype() { assert(0); return 0; } type *TypeSArray::toCParamtype() { assert(0); return 0; } type * TypeDArray::toCtype() { assert(0); return 0; } type * TypeAArray::toCtype() { assert(0); return 0; } type * TypePointer::toCtype() { assert(0); return 0; } type * TypeDelegate::toCtype() { assert(0); return 0; } type * TypeClass::toCtype() { assert(0); return 0; } void ClassDeclaration::toDebug() { assert(0); } ////////////////////////////////////////////////////////////////////////////// void EnumDeclaration::toDebug() { assert(0); } int Dsymbol::cvMember(unsigned char*) { assert(0); return 0; } int EnumDeclaration::cvMember(unsigned char*) { assert(0); return 0; } int FuncDeclaration::cvMember(unsigned char*) { assert(0); return 0; } int VarDeclaration::cvMember(unsigned char*) { assert(0); return 0; } int TypedefDeclaration::cvMember(unsigned char*) { assert(0); return 0; } void obj_includelib(char*){} AsmStatement::AsmStatement(Loc loc, Token *tokens) : Statement(loc) { this->tokens = tokens; } Statement *AsmStatement::syntaxCopy() { /*error("%s: inline asm is not yet implemented", loc.toChars()); fatal(); assert(0);*/ return 0; } Statement *AsmStatement::semantic(Scope *sc) { return Statement::semantic(sc); } void AsmStatement::toCBuffer(OutBuffer *buf, HdrGenState *hgs) { Statement::toCBuffer(buf, hgs); } int AsmStatement::comeFrom() { /*error("%s: inline asm is not yet implemented", loc.toChars()); fatal(); assert(0);*/ return 0; } void backend_init() { // now lazily loaded //LLVM_D_InitRuntime(); } void backend_term() { LLVM_D_FreeRuntime(); }