Mercurial > projects > ldc
view gen/typinf.cpp @ 102:027b8d8b71ec trunk
[svn r106] Turns out the last commit wasn't enough, now the D->LLVM process is even more split up.
Basically it tries to do the following in order: Resolve types, Declare symbols, Create constant initializers, Apply initializers, Generate functions bodies.
ClassInfo is now has the most useful(biased?) members working.
Probably other stuf...
| author | lindquist |
|---|---|
| date | Sun, 18 Nov 2007 06:52:57 +0100 |
| parents | 5071469303d4 |
| children | 182b41f56b7f |
line wrap: on
line source
// Copyright (c) 1999-2004 by Digital Mars // All Rights Reserved // written by Walter Bright // www.digitalmars.com // License for redistribution is by either the Artistic License // in artistic.txt, or the GNU General Public License in gnu.txt. // See the included readme.txt for details. // Modifications for LLVMDC: // Copyright (c) 2007 by Tomas Lindquist Olsen // tomas at famolsen dk #include <cstdio> #include <cassert> #include "gen/llvm.h" #include "mars.h" #include "module.h" #include "mtype.h" #include "scope.h" #include "init.h" #include "expression.h" #include "attrib.h" #include "declaration.h" #include "template.h" #include "id.h" #include "enum.h" #include "import.h" #include "aggregate.h" #include "gen/irstate.h" #include "gen/logger.h" #include "gen/runtime.h" #include "gen/tollvm.h" #include "gen/arrays.h" #include "gen/structs.h" /******************************************* * Get a canonicalized form of the TypeInfo for use with the internal * runtime library routines. Canonicalized in that static arrays are * represented as dynamic arrays, enums are represented by their * underlying type, etc. This reduces the number of TypeInfo's needed, * so we can use the custom internal ones more. */ Expression *Type::getInternalTypeInfo(Scope *sc) { TypeInfoDeclaration *tid; Expression *e; Type *t; static TypeInfoDeclaration *internalTI[TMAX]; //printf("Type::getInternalTypeInfo() %s\n", toChars()); t = toBasetype(); switch (t->ty) { case Tsarray: t = t->next->arrayOf(); // convert to corresponding dynamic array type break; case Tclass: if (((TypeClass *)t)->sym->isInterfaceDeclaration()) break; goto Linternal; case Tarray: if (t->next->ty != Tclass) break; goto Linternal; case Tfunction: case Tdelegate: case Tpointer: Linternal: tid = internalTI[t->ty]; if (!tid) { tid = new TypeInfoDeclaration(t, 1); internalTI[t->ty] = tid; } e = new VarExp(0, tid); //e = e->addressOf(sc); e->type = tid->type; // do this so we don't get redundant dereference return e; default: break; } //printf("\tcalling getTypeInfo() %s\n", t->toChars()); return t->getTypeInfo(sc); } /**************************************************** * Get the exact TypeInfo. */ Expression *Type::getTypeInfo(Scope *sc) { Expression *e; Type *t; //printf("Type::getTypeInfo() %p, %s\n", this, toChars()); t = merge(); // do this since not all Type's are merge'd if (!t->vtinfo) { t->vtinfo = t->getTypeInfoDeclaration(); assert(t->vtinfo); /* If this has a custom implementation in std/typeinfo, then * do not generate a COMDAT for it. */ if (!t->builtinTypeInfo()) { // Generate COMDAT if (sc) // if in semantic() pass { // Find module that will go all the way to an object file Module *m = sc->module->importedFrom; m->members->push(t->vtinfo); } else // if in obj generation pass { t->vtinfo->toObjFile(); } } } e = new VarExp(0, t->vtinfo); //e = e->addressOf(sc); e->type = t->vtinfo->type; // do this so we don't get redundant dereference return e; } enum RET TypeFunction::retStyle() { return RETstack; } TypeInfoDeclaration *Type::getTypeInfoDeclaration() { //printf("Type::getTypeInfoDeclaration() %s\n", toChars()); return new TypeInfoDeclaration(this, 0); } TypeInfoDeclaration *TypeTypedef::getTypeInfoDeclaration() { return new TypeInfoTypedefDeclaration(this); } TypeInfoDeclaration *TypePointer::getTypeInfoDeclaration() { return new TypeInfoPointerDeclaration(this); } TypeInfoDeclaration *TypeDArray::getTypeInfoDeclaration() { return new TypeInfoArrayDeclaration(this); } TypeInfoDeclaration *TypeSArray::getTypeInfoDeclaration() { return new TypeInfoStaticArrayDeclaration(this); } TypeInfoDeclaration *TypeAArray::getTypeInfoDeclaration() { return new TypeInfoAssociativeArrayDeclaration(this); } TypeInfoDeclaration *TypeStruct::getTypeInfoDeclaration() { return new TypeInfoStructDeclaration(this); } TypeInfoDeclaration *TypeClass::getTypeInfoDeclaration() { if (sym->isInterfaceDeclaration()) return new TypeInfoInterfaceDeclaration(this); else return new TypeInfoClassDeclaration(this); } TypeInfoDeclaration *TypeEnum::getTypeInfoDeclaration() { return new TypeInfoEnumDeclaration(this); } TypeInfoDeclaration *TypeFunction::getTypeInfoDeclaration() { return new TypeInfoFunctionDeclaration(this); } TypeInfoDeclaration *TypeDelegate::getTypeInfoDeclaration() { return new TypeInfoDelegateDeclaration(this); } TypeInfoDeclaration *TypeTuple::getTypeInfoDeclaration() { return new TypeInfoTupleDeclaration(this); } /* ========================================================================= */ /* These decide if there's an instance for them already in std.typeinfo, * because then the compiler doesn't need to build one. */ int Type::builtinTypeInfo() { return 0; } int TypeBasic::builtinTypeInfo() { return 1; } int TypeDArray::builtinTypeInfo() { return next->isTypeBasic() != NULL; } /* ========================================================================= */ /*************************************** * Create a static array of TypeInfo references * corresponding to an array of Expression's. * Used to supply hidden _arguments[] value for variadic D functions. */ Expression *createTypeInfoArray(Scope *sc, Expression *exps[], int dim) { assert(0); return NULL; } /* ========================================================================= */ ////////////////////////////////////////////////////////////////////////////// // MAGIC PLACE ////////////////////////////////////////////////////////////////////////////// void TypeInfoDeclaration::toObjFile() { gIR->resolveList.push_back(this); } void DtoResolveTypeInfo(TypeInfoDeclaration* tid) { if (tid->llvmResolved) return; tid->llvmResolved = true; Logger::println("* DtoResolveTypeInfo(%s)", tid->toChars()); LOG_SCOPE; tid->llvmIRGlobal = new IRGlobal(tid); gIR->declareList.push_back(tid); } void DtoDeclareTypeInfo(TypeInfoDeclaration* tid) { if (tid->llvmDeclared) return; tid->llvmDeclared = true; Logger::println("* DtoDeclareTypeInfo(%s)", tid->toChars()); LOG_SCOPE; std::string mangled(tid->mangle()); Logger::println("type = '%s'", tid->tinfo->toChars()); Logger::println("typeinfo mangle: %s", mangled.c_str()); // this is a declaration of a builtin __initZ var if (tid->tinfo->builtinTypeInfo()) { tid->llvmValue = LLVM_D_GetRuntimeGlobal(gIR->module, mangled.c_str()); assert(tid->llvmValue); mangled.append("__TYPE"); gIR->module->addTypeName(mangled, tid->llvmValue->getType()->getContainedType(0)); Logger::println("Got typeinfo var: %s", tid->llvmValue->getName().c_str()); tid->llvmInitialized = true; tid->llvmDefined = true; } // custom typedef else { gIR->constInitList.push_back(tid); } } void DtoConstInitTypeInfo(TypeInfoDeclaration* tid) { if (tid->llvmInitialized) return; tid->llvmInitialized = true; Logger::println("* DtoConstInitTypeInfo(%s)", tid->toChars()); LOG_SCOPE; tid->toDt(NULL); tid->llvmDefined = true; //gIR->defineList.push_back(tid); } void DtoDefineTypeInfo(TypeInfoDeclaration* tid) { if (tid->llvmDefined) return; tid->llvmDefined = true; Logger::println("* DtoDefineTypeInfo(%s)", tid->toChars()); LOG_SCOPE; assert(0); } /* ========================================================================= */ void TypeInfoDeclaration::toDt(dt_t **pdt) { assert(0 && "TypeInfoDeclaration"); } /* ========================================================================= */ void TypeInfoTypedefDeclaration::toDt(dt_t **pdt) { Logger::println("TypeInfoTypedefDeclaration::toDt() %s", toChars()); LOG_SCOPE; ClassDeclaration* base = Type::typeinfotypedef; DtoForceConstInitDsymbol(base); const llvm::StructType* stype = isaStruct(base->type->llvmType->get()); Logger::cout() << "got stype: " << *stype << '\n'; std::vector<llvm::Constant*> sinits; sinits.push_back(base->llvmVtbl); assert(tinfo->ty == Ttypedef); TypeTypedef *tc = (TypeTypedef *)tinfo; TypedefDeclaration *sd = tc->sym; // TypeInfo base //const llvm::PointerType* basept = isaPointer(initZ->getOperand(1)->getType()); //sinits.push_back(llvm::ConstantPointerNull::get(basept)); Logger::println("generating base typeinfo"); //sd->basetype = sd->basetype->merge(); sd->basetype->getTypeInfo(NULL); // generate vtinfo assert(sd->basetype->vtinfo); if (!sd->basetype->vtinfo->llvmValue) DtoForceConstInitDsymbol(sd->basetype->vtinfo); assert(sd->basetype->vtinfo->llvmValue); assert(llvm::isa<llvm::Constant>(sd->basetype->vtinfo->llvmValue)); llvm::Constant* castbase = llvm::cast<llvm::Constant>(sd->basetype->vtinfo->llvmValue); castbase = llvm::ConstantExpr::getBitCast(castbase, stype->getElementType(1)); sinits.push_back(castbase); // char[] name char *name = sd->toPrettyChars(); sinits.push_back(DtoConstString(name)); assert(sinits.back()->getType() == stype->getElementType(2)); // void[] init const llvm::PointerType* initpt = llvm::PointerType::get(llvm::Type::Int8Ty); if (tinfo->isZeroInit() || !sd->init) // 0 initializer, or the same as the base type { sinits.push_back(DtoConstSlice(DtoConstSize_t(0), llvm::ConstantPointerNull::get(initpt))); } else { llvm::Constant* ci = DtoConstInitializer(sd->basetype, sd->init); std::string ciname(sd->mangle()); ciname.append("__init"); llvm::GlobalVariable* civar = new llvm::GlobalVariable(DtoType(sd->basetype),true,llvm::GlobalValue::InternalLinkage,ci,ciname,gIR->module); llvm::Constant* cicast = llvm::ConstantExpr::getBitCast(civar, initpt); size_t cisize = gTargetData->getTypeSize(DtoType(sd->basetype)); sinits.push_back(DtoConstSlice(DtoConstSize_t(cisize), cicast)); } // create the symbol llvm::Constant* tiInit = llvm::ConstantStruct::get(stype, sinits); llvm::GlobalVariable* gvar = new llvm::GlobalVariable(stype,true,llvm::GlobalValue::WeakLinkage,tiInit,toChars(),gIR->module); llvmValue = gvar; } /* ========================================================================= */ void TypeInfoEnumDeclaration::toDt(dt_t **pdt) { Logger::println("TypeInfoTypedefDeclaration::toDt() %s", toChars()); LOG_SCOPE; ClassDeclaration* base = Type::typeinfoenum; DtoForceConstInitDsymbol(base); const llvm::StructType* stype = isaStruct(base->type->llvmType->get()); std::vector<llvm::Constant*> sinits; sinits.push_back(base->llvmVtbl); assert(tinfo->ty == Tenum); TypeEnum *tc = (TypeEnum *)tinfo; EnumDeclaration *sd = tc->sym; // TypeInfo base //const llvm::PointerType* basept = isaPointer(initZ->getOperand(1)->getType()); //sinits.push_back(llvm::ConstantPointerNull::get(basept)); Logger::println("generating base typeinfo"); //sd->basetype = sd->basetype->merge(); sd->memtype->getTypeInfo(NULL); // generate vtinfo assert(sd->memtype->vtinfo); if (!sd->memtype->vtinfo->llvmValue) DtoForceConstInitDsymbol(sd->memtype->vtinfo); assert(llvm::isa<llvm::Constant>(sd->memtype->vtinfo->llvmValue)); llvm::Constant* castbase = llvm::cast<llvm::Constant>(sd->memtype->vtinfo->llvmValue); castbase = llvm::ConstantExpr::getBitCast(castbase, stype->getElementType(1)); sinits.push_back(castbase); // char[] name char *name = sd->toPrettyChars(); sinits.push_back(DtoConstString(name)); assert(sinits.back()->getType() == stype->getElementType(2)); // void[] init const llvm::PointerType* initpt = llvm::PointerType::get(llvm::Type::Int8Ty); if (tinfo->isZeroInit() || !sd->defaultval) // 0 initializer, or the same as the base type { sinits.push_back(DtoConstSlice(DtoConstSize_t(0), llvm::ConstantPointerNull::get(initpt))); } else { const llvm::Type* memty = DtoType(sd->memtype); llvm::Constant* ci = llvm::ConstantInt::get(memty, sd->defaultval, !sd->memtype->isunsigned()); std::string ciname(sd->mangle()); ciname.append("__init"); llvm::GlobalVariable* civar = new llvm::GlobalVariable(memty,true,llvm::GlobalValue::InternalLinkage,ci,ciname,gIR->module); llvm::Constant* cicast = llvm::ConstantExpr::getBitCast(civar, initpt); size_t cisize = gTargetData->getTypeSize(memty); sinits.push_back(DtoConstSlice(DtoConstSize_t(cisize), cicast)); } // create the symbol llvm::Constant* tiInit = llvm::ConstantStruct::get(stype, sinits); llvm::GlobalVariable* gvar = new llvm::GlobalVariable(stype,true,llvm::GlobalValue::WeakLinkage,tiInit,toChars(),gIR->module); llvmValue = gvar; } /* ========================================================================= */ static llvm::Constant* LLVM_D_Create_TypeInfoBase(Type* basetype, TypeInfoDeclaration* tid, ClassDeclaration* cd) { ClassDeclaration* base = cd; DtoForceConstInitDsymbol(base); const llvm::StructType* stype = isaStruct(base->type->llvmType->get()); std::vector<llvm::Constant*> sinits; sinits.push_back(base->llvmVtbl); // TypeInfo base Logger::println("generating base typeinfo"); basetype->getTypeInfo(NULL); assert(basetype->vtinfo); if (!basetype->vtinfo->llvmValue) DtoForceConstInitDsymbol(basetype->vtinfo); assert(llvm::isa<llvm::Constant>(basetype->vtinfo->llvmValue)); llvm::Constant* castbase = llvm::cast<llvm::Constant>(basetype->vtinfo->llvmValue); castbase = llvm::ConstantExpr::getBitCast(castbase, stype->getElementType(1)); sinits.push_back(castbase); // create the symbol llvm::Constant* tiInit = llvm::ConstantStruct::get(stype, sinits); llvm::GlobalVariable* gvar = new llvm::GlobalVariable(stype,true,llvm::GlobalValue::WeakLinkage,tiInit,tid->toChars(),gIR->module); tid->llvmValue = gvar; } /* ========================================================================= */ void TypeInfoPointerDeclaration::toDt(dt_t **pdt) { Logger::println("TypeInfoPointerDeclaration::toDt() %s", toChars()); LOG_SCOPE; assert(tinfo->ty == Tpointer); TypePointer *tc = (TypePointer *)tinfo; LLVM_D_Create_TypeInfoBase(tc->next, this, Type::typeinfopointer); } /* ========================================================================= */ void TypeInfoArrayDeclaration::toDt(dt_t **pdt) { Logger::println("TypeInfoArrayDeclaration::toDt() %s", toChars()); LOG_SCOPE; assert(tinfo->ty == Tarray); TypeDArray *tc = (TypeDArray *)tinfo; LLVM_D_Create_TypeInfoBase(tc->next, this, Type::typeinfoarray); } /* ========================================================================= */ void TypeInfoStaticArrayDeclaration::toDt(dt_t **pdt) { assert(0 && "TypeInfoStaticArrayDeclaration"); /* //printf("TypeInfoStaticArrayDeclaration::toDt()\n"); dtxoff(pdt, Type::typeinfostaticarray->toVtblSymbol(), 0, TYnptr); // vtbl for TypeInfo_StaticArray dtdword(pdt, 0); // monitor assert(tinfo->ty == Tsarray); TypeSArray *tc = (TypeSArray *)tinfo; tc->next->getTypeInfo(NULL); dtxoff(pdt, tc->next->vtinfo->toSymbol(), 0, TYnptr); // TypeInfo for array of type dtdword(pdt, tc->dim->toInteger()); // length */ } /* ========================================================================= */ void TypeInfoAssociativeArrayDeclaration::toDt(dt_t **pdt) { assert(0 && "TypeInfoAssociativeArrayDeclaration"); /* //printf("TypeInfoAssociativeArrayDeclaration::toDt()\n"); dtxoff(pdt, Type::typeinfoassociativearray->toVtblSymbol(), 0, TYnptr); // vtbl for TypeInfo_AssociativeArray dtdword(pdt, 0); // monitor assert(tinfo->ty == Taarray); TypeAArray *tc = (TypeAArray *)tinfo; tc->next->getTypeInfo(NULL); dtxoff(pdt, tc->next->vtinfo->toSymbol(), 0, TYnptr); // TypeInfo for array of type tc->index->getTypeInfo(NULL); dtxoff(pdt, tc->index->vtinfo->toSymbol(), 0, TYnptr); // TypeInfo for array of type */ } /* ========================================================================= */ void TypeInfoFunctionDeclaration::toDt(dt_t **pdt) { Logger::println("TypeInfoFunctionDeclaration::toDt() %s", toChars()); LOG_SCOPE; assert(tinfo->ty == Tfunction); TypeFunction *tc = (TypeFunction *)tinfo; LLVM_D_Create_TypeInfoBase(tc->next, this, Type::typeinfofunction); } /* ========================================================================= */ void TypeInfoDelegateDeclaration::toDt(dt_t **pdt) { Logger::println("TypeInfoDelegateDeclaration::toDt() %s", toChars()); LOG_SCOPE; assert(tinfo->ty == Tdelegate); TypeDelegate *tc = (TypeDelegate *)tinfo; LLVM_D_Create_TypeInfoBase(tc->next->next, this, Type::typeinfodelegate); } /* ========================================================================= */ void TypeInfoStructDeclaration::toDt(dt_t **pdt) { Logger::println("TypeInfoStructDeclaration::toDt() %s", toChars()); LOG_SCOPE; assert(tinfo->ty == Tstruct); TypeStruct *tc = (TypeStruct *)tinfo; StructDeclaration *sd = tc->sym; DtoForceConstInitDsymbol(sd); ClassDeclaration* base = Type::typeinfostruct; DtoForceConstInitDsymbol(base); const llvm::StructType* stype = isaStruct(((TypeClass*)base->type)->llvmType->get()); std::vector<llvm::Constant*> sinits; sinits.push_back(base->llvmVtbl); // char[] name char *name = sd->toPrettyChars(); sinits.push_back(DtoConstString(name)); Logger::println("************** A"); assert(sinits.back()->getType() == stype->getElementType(1)); // void[] init const llvm::PointerType* initpt = llvm::PointerType::get(llvm::Type::Int8Ty); if (sd->zeroInit) // 0 initializer, or the same as the base type { sinits.push_back(DtoConstSlice(DtoConstSize_t(0), llvm::ConstantPointerNull::get(initpt))); } else { assert(sd->llvmInitZ); size_t cisize = gTargetData->getTypeSize(tc->llvmType->get()); llvm::Constant* cicast = llvm::ConstantExpr::getBitCast(tc->llvmInit, initpt); sinits.push_back(DtoConstSlice(DtoConstSize_t(cisize), cicast)); } // toX functions ground work FuncDeclaration *fd; FuncDeclaration *fdx; TypeFunction *tf; Type *ta; Dsymbol *s; static TypeFunction *tftohash; static TypeFunction *tftostring; if (!tftohash) { Scope sc; tftohash = new TypeFunction(NULL, Type::thash_t, 0, LINKd); tftohash = (TypeFunction *)tftohash->semantic(0, &sc); tftostring = new TypeFunction(NULL, Type::tchar->arrayOf(), 0, LINKd); tftostring = (TypeFunction *)tftostring->semantic(0, &sc); } TypeFunction *tfeqptr; { Scope sc; Arguments *arguments = new Arguments; Argument *arg = new Argument(STCin, tc->pointerTo(), NULL, NULL); arguments->push(arg); tfeqptr = new TypeFunction(arguments, Type::tint32, 0, LINKd); tfeqptr = (TypeFunction *)tfeqptr->semantic(0, &sc); } #if 0 TypeFunction *tfeq; { Scope sc; Array *arguments = new Array; Argument *arg = new Argument(In, tc, NULL, NULL); arguments->push(arg); tfeq = new TypeFunction(arguments, Type::tint32, 0, LINKd); tfeq = (TypeFunction *)tfeq->semantic(0, &sc); } #endif Logger::println("************** B"); const llvm::PointerType* ptty = isaPointer(stype->getElementType(3)); s = search_function(sd, Id::tohash); fdx = s ? s->isFuncDeclaration() : NULL; if (fdx) { fd = fdx->overloadExactMatch(tftohash); if (fd) { assert(fd->llvmValue != 0); llvm::Constant* c = llvm::cast_or_null<llvm::Constant>(fd->llvmValue); assert(c); c = llvm::ConstantExpr::getBitCast(c, ptty); sinits.push_back(c); } else { //fdx->error("must be declared as extern (D) uint toHash()"); sinits.push_back(llvm::ConstantPointerNull::get(ptty)); } } else { sinits.push_back(llvm::ConstantPointerNull::get(ptty)); } s = search_function(sd, Id::eq); fdx = s ? s->isFuncDeclaration() : NULL; for (int i = 0; i < 2; i++) { Logger::println("************** C %d", i); ptty = isaPointer(stype->getElementType(4+i)); if (fdx) { fd = fdx->overloadExactMatch(tfeqptr); if (fd) { assert(fd->llvmValue != 0); llvm::Constant* c = llvm::cast_or_null<llvm::Constant>(fd->llvmValue); assert(c); c = llvm::ConstantExpr::getBitCast(c, ptty); sinits.push_back(c); } else { //fdx->error("must be declared as extern (D) int %s(%s*)", fdx->toChars(), sd->toChars()); sinits.push_back(llvm::ConstantPointerNull::get(ptty)); } } else { sinits.push_back(llvm::ConstantPointerNull::get(ptty)); } s = search_function(sd, Id::cmp); fdx = s ? s->isFuncDeclaration() : NULL; } Logger::println("************** D"); ptty = isaPointer(stype->getElementType(6)); s = search_function(sd, Id::tostring); fdx = s ? s->isFuncDeclaration() : NULL; if (fdx) { fd = fdx->overloadExactMatch(tftostring); if (fd) { assert(fd->llvmValue != 0); llvm::Constant* c = llvm::cast_or_null<llvm::Constant>(fd->llvmValue); assert(c); c = llvm::ConstantExpr::getBitCast(c, ptty); sinits.push_back(c); } else { //fdx->error("must be declared as extern (D) char[] toString()"); sinits.push_back(llvm::ConstantPointerNull::get(ptty)); } } else { sinits.push_back(llvm::ConstantPointerNull::get(ptty)); } // uint m_flags; sinits.push_back(DtoConstUint(tc->hasPointers())); // create the symbol llvm::Constant* tiInit = llvm::ConstantStruct::get(stype, sinits); llvm::GlobalVariable* gvar = new llvm::GlobalVariable(stype,true,llvm::GlobalValue::WeakLinkage,tiInit,toChars(),gIR->module); llvmValue = gvar; } /* ========================================================================= */ void TypeInfoClassDeclaration::toDt(dt_t **pdt) { assert(0 && "TypeInfoClassDeclaration"); /* //printf("TypeInfoClassDeclaration::toDt() %s\n", tinfo->toChars()); dtxoff(pdt, Type::typeinfoclass->toVtblSymbol(), 0, TYnptr); // vtbl for TypeInfoClass dtdword(pdt, 0); // monitor assert(tinfo->ty == Tclass); TypeClass *tc = (TypeClass *)tinfo; Symbol *s; if (!tc->sym->vclassinfo) tc->sym->vclassinfo = new ClassInfoDeclaration(tc->sym); s = tc->sym->vclassinfo->toSymbol(); dtxoff(pdt, s, 0, TYnptr); // ClassInfo for tinfo */ } /* ========================================================================= */ void TypeInfoInterfaceDeclaration::toDt(dt_t **pdt) { assert(0 && "TypeInfoInterfaceDeclaration"); /* //printf("TypeInfoInterfaceDeclaration::toDt() %s\n", tinfo->toChars()); dtxoff(pdt, Type::typeinfointerface->toVtblSymbol(), 0, TYnptr); // vtbl for TypeInfoInterface dtdword(pdt, 0); // monitor assert(tinfo->ty == Tclass); TypeClass *tc = (TypeClass *)tinfo; Symbol *s; if (!tc->sym->vclassinfo) tc->sym->vclassinfo = new ClassInfoDeclaration(tc->sym); s = tc->sym->vclassinfo->toSymbol(); dtxoff(pdt, s, 0, TYnptr); // ClassInfo for tinfo */ } /* ========================================================================= */ void TypeInfoTupleDeclaration::toDt(dt_t **pdt) { assert(0 && "TypeInfoTupleDeclaration"); /* //printf("TypeInfoTupleDeclaration::toDt() %s\n", tinfo->toChars()); dtxoff(pdt, Type::typeinfotypelist->toVtblSymbol(), 0, TYnptr); // vtbl for TypeInfoInterface dtdword(pdt, 0); // monitor assert(tinfo->ty == Ttuple); TypeTuple *tu = (TypeTuple *)tinfo; size_t dim = tu->arguments->dim; dtdword(pdt, dim); // elements.length dt_t *d = NULL; for (size_t i = 0; i < dim; i++) { Argument *arg = (Argument *)tu->arguments->data[i]; Expression *e = arg->type->getTypeInfo(NULL); e = e->optimize(WANTvalue); e->toDt(&d); } Symbol *s; s = static_sym(); s->Sdt = d; outdata(s); dtxoff(pdt, s, 0, TYnptr); // elements.ptr */ }