Mercurial > projects > ldc
view gen/functions.cpp @ 720:e177ae483f8e
Added inreg attribute where appropriate on x86 to follow ABI docs.
Removed now unnecessary temporary variable in StringExp.
| author | Tomas Lindquist Olsen <tomas.l.olsen@gmail.com> |
|---|---|
| date | Thu, 23 Oct 2008 00:34:46 +0200 |
| parents | 7261ff0f95ff |
| children | 55f6c2e454d7 |
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#include "gen/llvm.h" #include "llvm/Support/CFG.h" #include "llvm/Intrinsics.h" #include "mtype.h" #include "aggregate.h" #include "init.h" #include "declaration.h" #include "template.h" #include "module.h" #include "statement.h" #include "gen/irstate.h" #include "gen/tollvm.h" #include "gen/llvmhelpers.h" #include "gen/runtime.h" #include "gen/arrays.h" #include "gen/logger.h" #include "gen/functions.h" #include "gen/todebug.h" #include "gen/classes.h" #include "gen/dvalue.h" const llvm::FunctionType* DtoFunctionType(Type* type, const LLType* thistype, const LLType* nesttype, bool ismain) { assert(type->ty == Tfunction); TypeFunction* f = (TypeFunction*)type; if (type->ir.type != NULL) { return llvm::cast<llvm::FunctionType>(type->ir.type->get()); } bool typesafeVararg = false; bool arrayVararg = false; if (f->linkage == LINKd) { if (f->varargs == 1) typesafeVararg = true; else if (f->varargs == 2) arrayVararg = true; } // return value type const LLType* rettype; const LLType* actualRettype; Type* rt = f->next; bool retinptr = false; bool usesthis = false; bool usesnest = false; // parameter types std::vector<const LLType*> paramvec; if (ismain) { rettype = LLType::Int32Ty; actualRettype = rettype; if (Argument::dim(f->parameters) == 0) { const LLType* arrTy = DtoArrayType(LLType::Int8Ty); const LLType* arrArrTy = DtoArrayType(arrTy); paramvec.push_back(arrArrTy); } } else{ assert(rt); if (DtoIsReturnedInArg(rt)) { rettype = getPtrToType(DtoType(rt)); actualRettype = LLType::VoidTy; f->retInPtr = retinptr = true; } else { rettype = DtoType(rt); actualRettype = rettype; } if (unsigned ea = DtoShouldExtend(rt)) { f->retAttrs |= ea; } } if (retinptr) { //Logger::cout() << "returning through pointer parameter: " << *rettype << '\n'; paramvec.push_back(rettype); } if (thistype) { paramvec.push_back(thistype); usesthis = true; } else if (nesttype) { paramvec.push_back(nesttype); usesnest = true; } if (typesafeVararg) { ClassDeclaration* ti = Type::typeinfo; ti->toObjFile(0); // TODO: multiobj DtoForceConstInitDsymbol(ti); assert(ti->ir.irStruct->constInit); std::vector<const LLType*> types; types.push_back(DtoSize_t()); types.push_back(getPtrToType(getPtrToType(ti->ir.irStruct->constInit->getType()))); const LLType* t1 = llvm::StructType::get(types); paramvec.push_back(t1); paramvec.push_back(getPtrToType(LLType::Int8Ty)); } else if (arrayVararg) { // do nothing? } size_t n = Argument::dim(f->parameters); for (int i=0; i < n; ++i) { Argument* arg = Argument::getNth(f->parameters, i); // ensure scalar Type* argT = arg->type->toBasetype(); assert(argT); bool refOrOut = ((arg->storageClass & STCref) || (arg->storageClass & STCout)); const LLType* at = DtoType(argT); // handle lazy args if (arg->storageClass & STClazy) { Logger::println("lazy param"); TypeFunction *ltf = new TypeFunction(NULL, arg->type, 0, LINKd); TypeDelegate *ltd = new TypeDelegate(ltf); at = DtoType(ltd); paramvec.push_back(at); } // opaque types need special handling else if (llvm::isa<llvm::OpaqueType>(at)) { Logger::println("opaque param"); assert(argT->ty == Tstruct || argT->ty == Tclass); paramvec.push_back(getPtrToType(at)); } // structs are passed as a reference, but by value else if (argT->ty == Tstruct) { Logger::println("struct param"); if (!refOrOut) arg->llvmAttrs |= llvm::Attribute::ByVal; paramvec.push_back(getPtrToType(at)); } // static arrays are passed directly by reference else if (argT->ty == Tsarray) { Logger::println("static array param"); at = getPtrToType(at); paramvec.push_back(at); } // firstclass ' ref/out ' parameter else if (refOrOut) { Logger::println("ref/out param"); at = getPtrToType(at); paramvec.push_back(at); } // firstclass ' in ' parameter else { Logger::println("in param"); if (unsigned ea = DtoShouldExtend(argT)) arg->llvmAttrs |= ea; paramvec.push_back(at); } } // construct function type bool isvararg = !(typesafeVararg || arrayVararg) && f->varargs; llvm::FunctionType* functype = llvm::FunctionType::get(actualRettype, paramvec, isvararg); // tell first param to be passed in a register if we can // ONLY extern(D) functions ! if ((n > 0 || usesthis || usesnest) && f->linkage == LINKd) { // FIXME: Only x86 right now ... if (global.params.cpu == ARCHx86) { // pass first param in EAX if it fits, is not floating point and is not a 3 byte struct. // FIXME: struct are not passed in EAX yet // if there is a implicit context parameter, pass it in EAX if (usesthis || usesnest) { f->thisAttrs |= llvm::Attribute::InReg; } // otherwise check the first formal parameter else { Argument* arg = Argument::getNth(f->parameters, 0); Type* t = arg->type->toBasetype(); // 32bit ints, pointers, classes and static arrays are candidate for being passed in EAX if ((arg->storageClass & STCin) && ((t->isscalar() && !t->isfloating()) || t->ty == Tclass || t->ty == Tsarray) && (t->size() <= PTRSIZE)) { arg->llvmAttrs |= llvm::Attribute::InReg; } } } } // done f->retInPtr = retinptr; f->usesThis = usesthis; f->usesNest = usesnest; f->ir.type = new llvm::PATypeHolder(functype); return functype; } ////////////////////////////////////////////////////////////////////////////////////////// static const llvm::FunctionType* DtoVaFunctionType(FuncDeclaration* fdecl) { // type has already been resolved if (fdecl->type->ir.type != 0) { return llvm::cast<llvm::FunctionType>(fdecl->type->ir.type->get()); } TypeFunction* f = (TypeFunction*)fdecl->type; const llvm::FunctionType* fty = 0; if (fdecl->llvmInternal == LLVMva_start) fty = GET_INTRINSIC_DECL(vastart)->getFunctionType(); else if (fdecl->llvmInternal == LLVMva_copy) fty = GET_INTRINSIC_DECL(vacopy)->getFunctionType(); else if (fdecl->llvmInternal == LLVMva_end) fty = GET_INTRINSIC_DECL(vaend)->getFunctionType(); assert(fty); f->ir.type = new llvm::PATypeHolder(fty); return fty; } ////////////////////////////////////////////////////////////////////////////////////////// const llvm::FunctionType* DtoFunctionType(FuncDeclaration* fdecl) { // handle for C vararg intrinsics if (fdecl->isVaIntrinsic()) return DtoVaFunctionType(fdecl); // type has already been resolved if (fdecl->type->ir.type != 0) return llvm::cast<llvm::FunctionType>(fdecl->type->ir.type->get()); const LLType* thisty = 0; const LLType* nestty = 0; if (fdecl->needThis()) { if (AggregateDeclaration* ad = fdecl->isMember2()) { Logger::println("isMember = this is: %s", ad->type->toChars()); thisty = DtoType(ad->type); //Logger::cout() << "this llvm type: " << *thisty << '\n'; if (isaStruct(thisty) || (!gIR->structs.empty() && thisty == gIR->topstruct()->recty.get())) thisty = getPtrToType(thisty); } else { Logger::println("chars: %s type: %s kind: %s", fdecl->toChars(), fdecl->type->toChars(), fdecl->kind()); assert(0); } } else if (fdecl->isNested()) { nestty = getPtrToType(LLType::Int8Ty); } const llvm::FunctionType* functype = DtoFunctionType(fdecl->type, thisty, nestty, fdecl->isMain()); return functype; } ////////////////////////////////////////////////////////////////////////////////////////// static llvm::Function* DtoDeclareVaFunction(FuncDeclaration* fdecl) { TypeFunction* f = (TypeFunction*)fdecl->type->toBasetype(); const llvm::FunctionType* fty = DtoVaFunctionType(fdecl); llvm::Function* func = 0; if (fdecl->llvmInternal == LLVMva_start) func = GET_INTRINSIC_DECL(vastart); else if (fdecl->llvmInternal == LLVMva_copy) func = GET_INTRINSIC_DECL(vacopy); else if (fdecl->llvmInternal == LLVMva_end) func = GET_INTRINSIC_DECL(vaend); assert(func); fdecl->ir.irFunc->func = func; return func; } ////////////////////////////////////////////////////////////////////////////////////////// void DtoResolveFunction(FuncDeclaration* fdecl) { if (!global.params.useUnitTests && fdecl->isUnitTestDeclaration()) { return; // ignore declaration completely } // is imported and we don't have access? if (fdecl->getModule() != gIR->dmodule) { if (fdecl->prot() == PROTprivate) return; } if (fdecl->ir.resolved) return; fdecl->ir.resolved = true; Logger::println("DtoResolveFunction(%s): %s", fdecl->toPrettyChars(), fdecl->loc.toChars()); LOG_SCOPE; //printf("resolve function: %s\n", fdecl->toPrettyChars()); if (fdecl->parent) if (TemplateInstance* tinst = fdecl->parent->isTemplateInstance()) { TemplateDeclaration* tempdecl = tinst->tempdecl; if (tempdecl->llvmInternal == LLVMva_arg) { Logger::println("magic va_arg found"); fdecl->llvmInternal = LLVMva_arg; fdecl->ir.declared = true; fdecl->ir.initialized = true; fdecl->ir.defined = true; return; // this gets mapped to an instruction so a declaration makes no sence } else if (tempdecl->llvmInternal == LLVMva_start) { Logger::println("magic va_start found"); fdecl->llvmInternal = LLVMva_start; } else if (tempdecl->llvmInternal == LLVMintrinsic) { Logger::println("overloaded intrinsic found"); fdecl->llvmInternal = LLVMintrinsic; DtoOverloadedIntrinsicName(tinst, tempdecl, fdecl->intrinsicName); } } DtoFunctionType(fdecl); // queue declaration if (!fdecl->isAbstract()) gIR->declareList.push_back(fdecl); } ////////////////////////////////////////////////////////////////////////////////////////// static void set_param_attrs(TypeFunction* f, llvm::Function* func, FuncDeclaration* fdecl) { int llidx = 1; if (f->retInPtr) ++llidx; if (f->usesThis) ++llidx; else if (f->usesNest) ++llidx; if (f->linkage == LINKd && f->varargs == 1) llidx += 2; int funcNumArgs = func->getArgumentList().size(); std::vector<llvm::AttributeWithIndex> attrs; int k = 0; llvm::AttributeWithIndex PAWI; // set return value attrs if any if (f->retAttrs) { PAWI.Index = 0; PAWI.Attrs = f->retAttrs; attrs.push_back(PAWI); } // set sret param if (f->retInPtr) { PAWI.Index = 1; PAWI.Attrs = llvm::Attribute::StructRet; attrs.push_back(PAWI); } // set this/nest param attrs if (f->thisAttrs) { PAWI.Index = f->retInPtr ? 2 : 1; PAWI.Attrs = f->thisAttrs; attrs.push_back(PAWI); } // set attrs on the rest of the arguments for (; llidx <= funcNumArgs && Argument::dim(f->parameters) > k; ++llidx,++k) { Argument* fnarg = Argument::getNth(f->parameters, k); assert(fnarg); PAWI.Index = llidx; PAWI.Attrs = fnarg->llvmAttrs; if (PAWI.Attrs) attrs.push_back(PAWI); } llvm::AttrListPtr palist = llvm::AttrListPtr::get(attrs.begin(), attrs.end()); func->setAttributes(palist); } ////////////////////////////////////////////////////////////////////////////////////////// void DtoDeclareFunction(FuncDeclaration* fdecl) { if (fdecl->ir.declared) return; fdecl->ir.declared = true; Logger::println("DtoDeclareFunction(%s): %s", fdecl->toPrettyChars(), fdecl->loc.toChars()); LOG_SCOPE; //printf("declare function: %s\n", fdecl->toPrettyChars()); // intrinsic sanity check if (fdecl->llvmInternal == LLVMintrinsic && fdecl->fbody) { error(fdecl->loc, "intrinsics cannot have function bodies"); fatal(); } // get TypeFunction* Type* t = fdecl->type->toBasetype(); TypeFunction* f = (TypeFunction*)t; bool declareOnly = false; bool templInst = fdecl->parent && DtoIsTemplateInstance(fdecl->parent); if (!templInst && fdecl->getModule() != gIR->dmodule) { Logger::println("not template instance, and not in this module. declare only!"); Logger::println("current module: %s", gIR->dmodule->ident->toChars()); if(fdecl->getModule()) Logger::println("func module: %s", fdecl->getModule()->ident->toChars()); else { Logger::println("func not in a module, is runtime"); } declareOnly = true; } else if (fdecl->llvmInternal == LLVMva_start) declareOnly = true; if (!fdecl->ir.irFunc) { fdecl->ir.irFunc = new IrFunction(fdecl); } // mangled name const char* mangled_name; if (fdecl->llvmInternal == LLVMintrinsic) mangled_name = fdecl->intrinsicName.c_str(); else mangled_name = fdecl->mangle(); llvm::Function* vafunc = 0; if (fdecl->isVaIntrinsic()) vafunc = DtoDeclareVaFunction(fdecl); // construct function const llvm::FunctionType* functype = DtoFunctionType(fdecl); llvm::Function* func = vafunc ? vafunc : gIR->module->getFunction(mangled_name); if (!func) func = llvm::Function::Create(functype, DtoLinkage(fdecl), mangled_name, gIR->module); // add func to IRFunc fdecl->ir.irFunc->func = func; // calling convention if (!vafunc && fdecl->llvmInternal != LLVMintrinsic) func->setCallingConv(DtoCallingConv(f->linkage)); else // fall back to C, it should be the right thing to do func->setCallingConv(llvm::CallingConv::C); fdecl->ir.irFunc->func = func; assert(llvm::isa<llvm::FunctionType>(f->ir.type->get())); // parameter attributes if (!fdecl->isIntrinsic()) { set_param_attrs(f, func, fdecl); } // main if (fdecl->isMain()) { gIR->mainFunc = func; } // static ctor if (fdecl->isStaticCtorDeclaration() && fdecl->getModule() == gIR->dmodule) { gIR->ctors.push_back(fdecl); } // static dtor else if (fdecl->isStaticDtorDeclaration() && fdecl->getModule() == gIR->dmodule) { gIR->dtors.push_back(fdecl); } // we never reference parameters of function prototypes if (!declareOnly) { // name parameters llvm::Function::arg_iterator iarg = func->arg_begin(); int k = 0; if (f->retInPtr) { iarg->setName(".sretarg"); fdecl->ir.irFunc->retArg = iarg; ++iarg; } if (f->usesThis) { iarg->setName("this"); fdecl->ir.irFunc->thisArg = iarg; assert(fdecl->ir.irFunc->thisArg); ++iarg; } else if (f->usesNest) { iarg->setName(".nest"); fdecl->ir.irFunc->nestArg = iarg; assert(fdecl->ir.irFunc->nestArg); ++iarg; } if (f->linkage == LINKd && f->varargs == 1) { iarg->setName("_arguments"); fdecl->ir.irFunc->_arguments = iarg; ++iarg; iarg->setName("_argptr"); fdecl->ir.irFunc->_argptr = iarg; ++iarg; } for (; iarg != func->arg_end(); ++iarg) { if (fdecl->parameters && fdecl->parameters->dim > k) { Dsymbol* argsym = (Dsymbol*)fdecl->parameters->data[k++]; VarDeclaration* argvd = argsym->isVarDeclaration(); assert(argvd); assert(!argvd->ir.irLocal); argvd->ir.irLocal = new IrLocal(argvd); argvd->ir.irLocal->value = iarg; iarg->setName(argvd->ident->toChars()); } else { iarg->setName("unnamed"); } } } if (fdecl->isUnitTestDeclaration()) gIR->unitTests.push_back(fdecl); if (!declareOnly) gIR->defineList.push_back(fdecl); else assert(func->getLinkage() != llvm::GlobalValue::InternalLinkage); if (Logger::enabled()) Logger::cout() << "func decl: " << *func << '\n'; } ////////////////////////////////////////////////////////////////////////////////////////// void DtoDefineFunc(FuncDeclaration* fd) { if (fd->ir.defined) return; fd->ir.defined = true; assert(fd->ir.declared); Logger::println("DtoDefineFunc(%s): %s", fd->toPrettyChars(), fd->loc.toChars()); LOG_SCOPE; // error on naked if (fd->naked) { fd->error("naked is not supported"); fatal(); } // debug info if (global.params.symdebug) { Module* mo = fd->getModule(); fd->ir.irFunc->dwarfSubProg = DtoDwarfSubProgram(fd); } Type* t = fd->type->toBasetype(); TypeFunction* f = (TypeFunction*)t; assert(f->ir.type); llvm::Function* func = fd->ir.irFunc->func; const llvm::FunctionType* functype = func->getFunctionType(); // only members of the current module or template instances maybe be defined if (!(fd->getModule() == gIR->dmodule || DtoIsTemplateInstance(fd->parent))) return; // set module owner fd->ir.DModule = gIR->dmodule; // is there a body? if (fd->fbody == NULL) return; Logger::println("Doing function body for: %s", fd->toChars()); assert(fd->ir.irFunc); IrFunction* irfunction = fd->ir.irFunc; gIR->functions.push_back(irfunction); if (fd->isMain()) gIR->emitMain = true; std::string entryname("entry_"); entryname.append(fd->toPrettyChars()); llvm::BasicBlock* beginbb = llvm::BasicBlock::Create(entryname,func); llvm::BasicBlock* endbb = llvm::BasicBlock::Create("endentry",func); //assert(gIR->scopes.empty()); gIR->scopes.push_back(IRScope(beginbb, endbb)); // create alloca point llvm::Instruction* allocaPoint = new llvm::AllocaInst(LLType::Int32Ty, "alloca point", beginbb); irfunction->allocapoint = allocaPoint; // debug info - after all allocas, but before any llvm.dbg.declare etc if (global.params.symdebug) DtoDwarfFuncStart(fd); // need result variable? if (fd->vresult) { Logger::println("vresult value"); fd->vresult->ir.irLocal = new IrLocal(fd->vresult); fd->vresult->ir.irLocal->value = DtoAlloca(DtoType(fd->vresult->type), "function_vresult"); } // this hack makes sure the frame pointer elimination optimization is disabled. // this this eliminates a bunch of inline asm related issues. // naked must always eliminate the framepointer however... if (fd->inlineAsm && !fd->naked) { // emit a call to llvm_eh_unwind_init LLFunction* hack = GET_INTRINSIC_DECL(eh_unwind_init); gIR->ir->CreateCall(hack, ""); } // give the 'this' argument storage and debug info if (f->usesThis) { LLValue* thisvar = irfunction->thisArg; assert(thisvar); LLValue* thismem = DtoAlloca(thisvar->getType(), ".this"); DtoStore(thisvar, thismem); irfunction->thisArg = thismem; assert(!fd->vthis->ir.irLocal); fd->vthis->ir.irLocal = new IrLocal(fd->vthis); fd->vthis->ir.irLocal->value = thismem; if (global.params.symdebug) DtoDwarfLocalVariable(thismem, fd->vthis); if (fd->vthis->nestedref) fd->nestedVars.insert(fd->vthis); } // give arguments storage // and debug info if (fd->parameters) { size_t n = fd->parameters->dim; for (int i=0; i < n; ++i) { Dsymbol* argsym = (Dsymbol*)fd->parameters->data[i]; VarDeclaration* vd = argsym->isVarDeclaration(); assert(vd); if (vd->nestedref) fd->nestedVars.insert(vd); IrLocal* irloc = vd->ir.irLocal; assert(irloc); bool refout = vd->storage_class & (STCref | STCout); bool lazy = vd->storage_class & STClazy; if (refout) { continue; } else if (!lazy && DtoIsPassedByRef(vd->type)) { LLValue* vdirval = irloc->value; if (global.params.symdebug && !(isaArgument(vdirval) && !isaArgument(vdirval)->hasByValAttr())) DtoDwarfLocalVariable(vdirval, vd); continue; } LLValue* a = irloc->value; LLValue* v = DtoAlloca(a->getType(), "."+a->getName()); DtoStore(a,v); irloc->value = v; } } // need result variable? (nested) if (fd->vresult && fd->vresult->nestedref) { Logger::println("nested vresult value: %s", fd->vresult->toChars()); fd->nestedVars.insert(fd->vresult); } // construct nested variables array if (!fd->nestedVars.empty()) { Logger::println("has nested frame"); // start with add all enclosing parent frames int nparelems = 0; Dsymbol* par = fd->toParent2(); while (par) { if (FuncDeclaration* parfd = par->isFuncDeclaration()) { nparelems += parfd->nestedVars.size(); } else if (ClassDeclaration* parcd = par->isClassDeclaration()) { // nothing needed } else { break; } par = par->toParent2(); } int nelems = fd->nestedVars.size() + nparelems; // make array type for nested vars const LLType* nestedVarsTy = LLArrayType::get(getVoidPtrType(), nelems); // alloca it LLValue* nestedVars = DtoAlloca(nestedVarsTy, ".nested_vars"); // copy parent frame into beginning if (nparelems) { LLValue* src = irfunction->nestArg; if (!src) { assert(irfunction->thisArg); assert(fd->isMember2()); LLValue* thisval = DtoLoad(irfunction->thisArg); ClassDeclaration* cd = fd->isMember2()->isClassDeclaration(); assert(cd); assert(cd->vthis); src = DtoLoad(DtoGEPi(thisval, 0,2+cd->vthis->ir.irField->index, ".vthis")); } DtoMemCpy(nestedVars, src, DtoConstSize_t(nparelems*PTRSIZE)); } // store in IrFunction irfunction->nestedVar = nestedVars; // go through all nested vars and assign indices int idx = nparelems; for (std::set<VarDeclaration*>::iterator i=fd->nestedVars.begin(); i!=fd->nestedVars.end(); ++i) { VarDeclaration* vd = *i; if (!vd->ir.irLocal) vd->ir.irLocal = new IrLocal(vd); if (vd->isParameter()) { Logger::println("nested param: %s", vd->toChars()); LLValue* gep = DtoGEPi(nestedVars, 0, idx); LLValue* val = DtoBitCast(vd->ir.irLocal->value, getVoidPtrType()); DtoStore(val, gep); } else { Logger::println("nested var: %s", vd->toChars()); } vd->ir.irLocal->nestedIndex = idx++; } // fixup nested result variable if (fd->vresult && fd->vresult->nestedref) { Logger::println("nested vresult value: %s", fd->vresult->toChars()); LLValue* gep = DtoGEPi(nestedVars, 0, fd->vresult->ir.irLocal->nestedIndex); LLValue* val = DtoBitCast(fd->vresult->ir.irLocal->value, getVoidPtrType()); DtoStore(val, gep); } } // copy _argptr and _arguments to a memory location if (f->linkage == LINKd && f->varargs == 1) { // _argptr LLValue* argptrmem = DtoAlloca(fd->ir.irFunc->_argptr->getType(), "_argptr_mem"); new llvm::StoreInst(fd->ir.irFunc->_argptr, argptrmem, gIR->scopebb()); fd->ir.irFunc->_argptr = argptrmem; // _arguments LLValue* argumentsmem = DtoAlloca(fd->ir.irFunc->_arguments->getType(), "_arguments_mem"); new llvm::StoreInst(fd->ir.irFunc->_arguments, argumentsmem, gIR->scopebb()); fd->ir.irFunc->_arguments = argumentsmem; } // output function body fd->fbody->toIR(gIR); // llvm requires all basic blocks to end with a TerminatorInst but DMD does not put a return statement // in automatically, so we do it here. if (!gIR->scopereturned()) { // pass the previous block into this block if (global.params.symdebug) DtoDwarfFuncEnd(fd); if (func->getReturnType() == LLType::VoidTy) { llvm::ReturnInst::Create(gIR->scopebb()); } else { if (!fd->isMain()) llvm::ReturnInst::Create(llvm::UndefValue::get(func->getReturnType()), gIR->scopebb()); else llvm::ReturnInst::Create(llvm::Constant::getNullValue(func->getReturnType()), gIR->scopebb()); } } // erase alloca point allocaPoint->eraseFromParent(); allocaPoint = 0; gIR->func()->allocapoint = 0; gIR->scopes.pop_back(); // get rid of the endentry block, it's never used assert(!func->getBasicBlockList().empty()); func->getBasicBlockList().pop_back(); // if the last block is empty now, it must be unreachable or it's a bug somewhere else // would be nice to figure out how to assert that this is correct llvm::BasicBlock* lastbb = &func->getBasicBlockList().back(); if (lastbb->empty()) { new llvm::UnreachableInst(lastbb); } // if the last block is not terminated we return a null value or void // for some unknown reason this is needed when a void main() has a inline asm block ... // this should be harmless for well formed code! lastbb = &func->getBasicBlockList().back(); if (!lastbb->getTerminator()) { Logger::println("adding missing return statement"); if (func->getReturnType() == LLType::VoidTy) llvm::ReturnInst::Create(lastbb); else llvm::ReturnInst::Create(llvm::Constant::getNullValue(func->getReturnType()), lastbb); } gIR->functions.pop_back(); } ////////////////////////////////////////////////////////////////////////////////////////// const llvm::FunctionType* DtoBaseFunctionType(FuncDeclaration* fdecl) { Dsymbol* parent = fdecl->toParent(); ClassDeclaration* cd = parent->isClassDeclaration(); assert(cd); FuncDeclaration* f = fdecl; while (cd) { ClassDeclaration* base = cd->baseClass; if (!base) break; FuncDeclaration* f2 = base->findFunc(fdecl->ident, (TypeFunction*)fdecl->type); if (f2) { f = f2; cd = base; } else break; } DtoResolveDsymbol(f); return llvm::cast<llvm::FunctionType>(DtoType(f->type)); } ////////////////////////////////////////////////////////////////////////////////////////// DValue* DtoArgument(Argument* fnarg, Expression* argexp) { Logger::println("DtoArgument"); LOG_SCOPE; DValue* arg = argexp->toElem(gIR); // ref/out arg if (fnarg && ((fnarg->storageClass & STCref) || (fnarg->storageClass & STCout))) { if (arg->isVar() || arg->isLRValue()) arg = new DImValue(argexp->type, arg->getLVal()); else arg = new DImValue(argexp->type, arg->getRVal()); } // lazy arg else if (fnarg && (fnarg->storageClass & STClazy)) { assert(argexp->type->toBasetype()->ty == Tdelegate); assert(!arg->isLVal()); return arg; } // byval arg, but expr has no storage yet else if (DtoIsPassedByRef(argexp->type) && (arg->isSlice() || arg->isNull())) { LLValue* alloc = DtoAlloca(DtoType(argexp->type), ".tmp_arg"); DVarValue* vv = new DVarValue(argexp->type, alloc); DtoAssign(argexp->loc, vv, arg); arg = vv; } return arg; } ////////////////////////////////////////////////////////////////////////////////////////// void DtoVariadicArgument(Expression* argexp, LLValue* dst) { Logger::println("DtoVariadicArgument"); LOG_SCOPE; DVarValue vv(argexp->type, dst); DtoAssign(argexp->loc, &vv, argexp->toElem(gIR)); } ////////////////////////////////////////////////////////////////////////////////////////// bool FuncDeclaration::isIntrinsic() { return (llvmInternal == LLVMintrinsic || isVaIntrinsic()); } bool FuncDeclaration::isVaIntrinsic() { return (llvmInternal == LLVMva_start || llvmInternal == LLVMva_copy || llvmInternal == LLVMva_end); }