// Compiler implementation of the D programming language // Copyright (c) 1999-2012 by Digital Mars // All Rights Reserved // written by Walter Bright // http://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. #include #include #include "init.h" #include "declaration.h" #include "attrib.h" #include "mtype.h" #include "template.h" #include "scope.h" #include "aggregate.h" #include "module.h" #include "id.h" #include "expression.h" #include "statement.h" #include "hdrgen.h" /********************************* Declaration ****************************/ Declaration::Declaration(Identifier *id) : Dsymbol(id) { type = NULL; originalType = NULL; storage_class = STCundefined; protection = PROTundefined; linkage = LINKdefault; inuse = 0; sem = SemanticStart; } void Declaration::semantic(Scope *sc) { } const char *Declaration::kind() { return "declaration"; } unsigned Declaration::size(Loc loc) { assert(type); return type->size(); } int Declaration::isDelete() { return FALSE; } int Declaration::isDataseg() { return FALSE; } int Declaration::isThreadlocal() { return FALSE; } int Declaration::isCodeseg() { return FALSE; } enum PROT Declaration::prot() { return protection; } /************************************* * Check to see if declaration can be modified in this context (sc). * Issue error if not. */ #if DMDV2 void Declaration::checkModify(Loc loc, Scope *sc, Type *t) { if (sc->incontract && isParameter()) error(loc, "cannot modify parameter '%s' in contract", toChars()); if (sc->incontract && isResult()) error(loc, "cannot modify result '%s' in contract", toChars()); if (isCtorinit() && !t->isMutable() || (storage_class & STCnodefaultctor)) { // It's only modifiable if inside the right constructor modifyFieldVar(loc, sc, isVarDeclaration(), NULL); } else { VarDeclaration *v = isVarDeclaration(); if (v && v->canassign == 0) { const char *p = NULL; if (isConst()) p = "const"; else if (isImmutable()) p = "immutable"; else if (isWild()) p = "inout"; else if (storage_class & STCmanifest) p = "enum"; else if (!t->isAssignable()) p = "struct with immutable members"; if (p) { error(loc, "cannot modify %s", p); } } } } #endif Dsymbol *Declaration::search(Loc loc, Identifier *ident, int flags) { Dsymbol *s = Dsymbol::search(loc, ident, flags); if (!s && type) { s = type->toDsymbol(NULL); if (s) s = s->search(loc, ident, flags); } return s; } /********************************* TupleDeclaration ****************************/ TupleDeclaration::TupleDeclaration(Loc loc, Identifier *id, Objects *objects) : Declaration(id) { this->loc = loc; this->type = NULL; this->objects = objects; this->isexp = 0; this->tupletype = NULL; } Dsymbol *TupleDeclaration::syntaxCopy(Dsymbol *s) { assert(0); return NULL; } const char *TupleDeclaration::kind() { return "tuple"; } Type *TupleDeclaration::getType() { /* If this tuple represents a type, return that type */ //printf("TupleDeclaration::getType() %s\n", toChars()); if (isexp) return NULL; if (!tupletype) { /* It's only a type tuple if all the Object's are types */ for (size_t i = 0; i < objects->dim; i++) { Object *o = (*objects)[i]; if (o->dyncast() != DYNCAST_TYPE) { //printf("\tnot[%d], %p, %d\n", i, o, o->dyncast()); return NULL; } } /* We know it's a type tuple, so build the TypeTuple */ Types *types = (Types *)objects; Parameters *args = new Parameters(); args->setDim(objects->dim); OutBuffer buf; int hasdeco = 1; for (size_t i = 0; i < types->dim; i++) { Type *t = (*types)[i]; //printf("type = %s\n", t->toChars()); #if 0 buf.printf("_%s_%d", ident->toChars(), i); char *name = (char *)buf.extractData(); Identifier *id = new Identifier(name, TOKidentifier); Parameter *arg = new Parameter(STCin, t, id, NULL); #else Parameter *arg = new Parameter(0, t, NULL, NULL); #endif (*args)[i] = arg; if (!t->deco) hasdeco = 0; } tupletype = new TypeTuple(args); if (hasdeco) return tupletype->semantic(0, NULL); } return tupletype; } int TupleDeclaration::needThis() { //printf("TupleDeclaration::needThis(%s)\n", toChars()); for (size_t i = 0; i < objects->dim; i++) { Object *o = (*objects)[i]; if (o->dyncast() == DYNCAST_EXPRESSION) { Expression *e = (Expression *)o; if (e->op == TOKdsymbol) { DsymbolExp *ve = (DsymbolExp *)e; Declaration *d = ve->s->isDeclaration(); if (d && d->needThis()) { return 1; } } } } return 0; } #if IN_LLVM void TupleDeclaration::semantic3(Scope *sc) { //printf("TupleDeclaration::semantic3((%s)\n", toChars()); for (size_t i = 0; i < objects->dim; i++) { Object *o = (Object *)objects->data[i]; if (o->dyncast() == DYNCAST_EXPRESSION) { Expression *e = (Expression *)o; if (e->op == TOKdsymbol) { DsymbolExp *ve = (DsymbolExp *)e; Declaration *d = ve->s->isDeclaration(); d->semantic3(sc); } } } } #endif /********************************* TypedefDeclaration ****************************/ TypedefDeclaration::TypedefDeclaration(Loc loc, Identifier *id, Type *basetype, Initializer *init) : Declaration(id) { this->type = new TypeTypedef(this); this->basetype = basetype->toBasetype(); this->init = init; this->htype = NULL; this->hbasetype = NULL; this->loc = loc; #if IN_DMD this->sinit = NULL; #endif } Dsymbol *TypedefDeclaration::syntaxCopy(Dsymbol *s) { Type *basetype = this->basetype->syntaxCopy(); Initializer *init = NULL; if (this->init) init = this->init->syntaxCopy(); assert(!s); TypedefDeclaration *st; st = new TypedefDeclaration(loc, ident, basetype, init); // Syntax copy for header file if (!htype) // Don't overwrite original { if (type) // Make copy for both old and new instances { htype = type->syntaxCopy(); st->htype = type->syntaxCopy(); } } else // Make copy of original for new instance st->htype = htype->syntaxCopy(); if (!hbasetype) { if (basetype) { hbasetype = basetype->syntaxCopy(); st->hbasetype = basetype->syntaxCopy(); } } else st->hbasetype = hbasetype->syntaxCopy(); return st; } void TypedefDeclaration::semantic(Scope *sc) { //printf("TypedefDeclaration::semantic(%s) sem = %d\n", toChars(), sem); if (sem == SemanticStart) { sem = SemanticIn; parent = sc->parent; int errors = global.errors; Type *savedbasetype = basetype; basetype = basetype->semantic(loc, sc); if (errors != global.errors) { basetype = savedbasetype; sem = SemanticStart; return; } sem = SemanticDone; #if DMDV2 type = type->addStorageClass(storage_class); #endif Type *savedtype = type; type = type->semantic(loc, sc); if (sc->parent->isFuncDeclaration() && init) semantic2(sc); if (errors != global.errors) { basetype = savedbasetype; type = savedtype; sem = SemanticStart; return; } storage_class |= sc->stc & STCdeprecated; } else if (sem == SemanticIn) { error("circular definition"); } } void TypedefDeclaration::semantic2(Scope *sc) { //printf("TypedefDeclaration::semantic2(%s) sem = %d\n", toChars(), sem); if (sem == SemanticDone) { sem = Semantic2Done; if (init) { Initializer *savedinit = init; int errors = global.errors; init = init->semantic(sc, basetype, INITinterpret); if (errors != global.errors) { init = savedinit; return; } ExpInitializer *ie = init->isExpInitializer(); if (ie) { if (ie->exp->type == basetype) ie->exp->type = type; } } } } const char *TypedefDeclaration::kind() { return "typedef"; } Type *TypedefDeclaration::getType() { return type; } void TypedefDeclaration::toCBuffer(OutBuffer *buf, HdrGenState *hgs) { buf->writestring("typedef "); basetype->toCBuffer(buf, ident, hgs); if (init) { buf->writestring(" = "); init->toCBuffer(buf, hgs); } buf->writeByte(';'); buf->writenl(); } /********************************* AliasDeclaration ****************************/ AliasDeclaration::AliasDeclaration(Loc loc, Identifier *id, Type *type) : Declaration(id) { //printf("AliasDeclaration(id = '%s', type = %p)\n", id->toChars(), type); //printf("type = '%s'\n", type->toChars()); this->loc = loc; this->type = type; this->aliassym = NULL; this->htype = NULL; this->haliassym = NULL; this->overnext = NULL; this->inSemantic = 0; this->importprot = PROTundefined; assert(type); } AliasDeclaration::AliasDeclaration(Loc loc, Identifier *id, Dsymbol *s) : Declaration(id) { //printf("AliasDeclaration(id = '%s', s = %p)\n", id->toChars(), s); assert(s != this); this->loc = loc; this->type = NULL; this->aliassym = s; this->htype = NULL; this->haliassym = NULL; this->overnext = NULL; this->inSemantic = 0; assert(s); } Dsymbol *AliasDeclaration::syntaxCopy(Dsymbol *s) { //printf("AliasDeclaration::syntaxCopy()\n"); assert(!s); AliasDeclaration *sa; if (type) sa = new AliasDeclaration(loc, ident, type->syntaxCopy()); else sa = new AliasDeclaration(loc, ident, aliassym->syntaxCopy(NULL)); // Syntax copy for header file if (!htype) // Don't overwrite original { if (type) // Make copy for both old and new instances { htype = type->syntaxCopy(); sa->htype = type->syntaxCopy(); } } else // Make copy of original for new instance sa->htype = htype->syntaxCopy(); if (!haliassym) { if (aliassym) { haliassym = aliassym->syntaxCopy(s); sa->haliassym = aliassym->syntaxCopy(s); } } else sa->haliassym = haliassym->syntaxCopy(s); return sa; } void AliasDeclaration::semantic(Scope *sc) { //printf("AliasDeclaration::semantic() %s\n", toChars()); if (aliassym) { if (aliassym->isTemplateInstance()) aliassym->semantic(sc); return; } this->inSemantic = 1; #if DMDV1 // don't really know why this is here if (storage_class & STCconst) error("cannot be const"); #endif storage_class |= sc->stc & STCdeprecated; protection = sc->protection; // Given: // alias foo.bar.abc def; // it is not knowable from the syntax whether this is an alias // for a type or an alias for a symbol. It is up to the semantic() // pass to distinguish. // If it is a type, then type is set and getType() will return that // type. If it is a symbol, then aliassym is set and type is NULL - // toAlias() will return aliasssym. int errors = global.errors; Type *savedtype = type; Dsymbol *s; Type *t; Expression *e; /* This section is needed because resolve() will: * const x = 3; * alias x y; * try to alias y to 3. */ s = type->toDsymbol(sc); if (s #if DMDV2 && ((s->getType() && type->equals(s->getType())) || s->isEnumMember()) #endif ) goto L2; // it's a symbolic alias #if DMDV2 type = type->addStorageClass(storage_class); if (storage_class & (STCref | STCnothrow | STCpure | STCdisable)) { // For 'ref' to be attached to function types, and picked // up by Type::resolve(), it has to go into sc. sc = sc->push(); sc->stc |= storage_class & (STCref | STCnothrow | STCpure | STCshared | STCdisable); type->resolve(loc, sc, &e, &t, &s); sc = sc->pop(); } else #endif type->resolve(loc, sc, &e, &t, &s); if (s) { goto L2; } else if (e) { // Try to convert Expression to Dsymbol s = getDsymbol(e); if (s) goto L2; if (e->op != TOKerror) error("cannot alias an expression %s", e->toChars()); t = e->type; } else if (t) { type = t->semantic(loc, sc); //printf("\talias resolved to type %s\n", type->toChars()); } if (overnext) ScopeDsymbol::multiplyDefined(0, this, overnext); this->inSemantic = 0; if (global.gag && errors != global.errors) type = savedtype; return; L2: //printf("alias is a symbol %s %s\n", s->kind(), s->toChars()); type = NULL; VarDeclaration *v = s->isVarDeclaration(); if (0 && v && v->linkage == LINKdefault) { error("forward reference of %s", v->toChars()); s = NULL; } else { Dsymbol *savedovernext = overnext; FuncDeclaration *f = s->toAlias()->isFuncDeclaration(); if (f) { if (overnext) { FuncAliasDeclaration *fa = new FuncAliasDeclaration(f); #if IN_LLVM fa->importprot = importprot; #endif if (!fa->overloadInsert(overnext)) ScopeDsymbol::multiplyDefined(0, f, overnext); overnext = NULL; s = fa; s->parent = sc->parent; } } OverloadSet *o = s->toAlias()->isOverloadSet(); if (o) { if (overnext) { o->push(overnext); overnext = NULL; s = o; s->parent = sc->parent; } } if (overnext) ScopeDsymbol::multiplyDefined(0, this, overnext); if (s == this) { assert(global.errors); s = NULL; } if (global.gag && errors != global.errors) { type = savedtype; overnext = savedovernext; aliassym = NULL; inSemantic = 0; return; } } //printf("setting aliassym %s to %s %s\n", toChars(), s->kind(), s->toChars()); aliassym = s; this->inSemantic = 0; } int AliasDeclaration::overloadInsert(Dsymbol *s) { /* Don't know yet what the aliased symbol is, so assume it can * be overloaded and check later for correctness. */ //printf("AliasDeclaration::overloadInsert('%s')\n", s->toChars()); if (aliassym) // see test/test56.d { Dsymbol *a = aliassym->toAlias(); FuncDeclaration *f = a->isFuncDeclaration(); if (f) // BUG: what if it's a template? { FuncAliasDeclaration *fa = new FuncAliasDeclaration(f); aliassym = fa; return fa->overloadInsert(s); } } if (overnext == NULL) { if (s == this) { return TRUE; } overnext = s; return TRUE; } else { return overnext->overloadInsert(s); } } const char *AliasDeclaration::kind() { return "alias"; } Type *AliasDeclaration::getType() { if (type) return type; return toAlias()->getType(); } Dsymbol *AliasDeclaration::toAlias() { //printf("AliasDeclaration::toAlias('%s', this = %p, aliassym = %p, kind = '%s')\n", toChars(), this, aliassym, aliassym ? aliassym->kind() : ""); assert(this != aliassym); //static int count; if (++count == 10) *(char*)0=0; if (inSemantic) { error("recursive alias declaration"); aliassym = new AliasDeclaration(loc, ident, Type::terror); type = Type::terror; } else if (aliassym || type->deco) ; // semantic is already done. else if (scope) semantic(scope); Dsymbol *s = aliassym ? aliassym->toAlias() : this; return s; } void AliasDeclaration::toCBuffer(OutBuffer *buf, HdrGenState *hgs) { buf->writestring("alias "); #if 0 if (hgs->hdrgen) { if (haliassym) { buf->writestring(haliassym->toChars()); buf->writeByte(' '); buf->writestring(ident->toChars()); } else htype->toCBuffer(buf, ident, hgs); } else #endif { if (aliassym) { #if !IN_LLVM aliassym->toCBuffer(buf, hgs); #else buf->writestring(aliassym->toChars()); #endif buf->writeByte(' '); buf->writestring(ident->toChars()); } else type->toCBuffer(buf, ident, hgs); } buf->writeByte(';'); buf->writenl(); } /********************************* VarDeclaration ****************************/ VarDeclaration::VarDeclaration(Loc loc, Type *type, Identifier *id, Initializer *init) : Declaration(id) { //printf("VarDeclaration('%s')\n", id->toChars()); #ifdef DEBUG if (!type && !init) { printf("VarDeclaration('%s')\n", id->toChars()); //*(char*)0=0; } #endif assert(type || init); this->type = type; this->init = init; this->htype = NULL; this->hinit = NULL; this->loc = loc; offset = 0; noscope = 0; #if DMDV2 isargptr = FALSE; #endif #if DMDV1 nestedref = 0; #endif alignment = 0; ctorinit = 0; aliassym = NULL; onstack = 0; canassign = 0; ctfeAdrOnStack = (size_t)(-1); #if DMDV2 rundtor = NULL; edtor = NULL; #endif #if IN_LLVM aggrIndex = 0; nakedUse = false; availableExternally = true; // assume this unless proven otherwise #endif } Dsymbol *VarDeclaration::syntaxCopy(Dsymbol *s) { //printf("VarDeclaration::syntaxCopy(%s)\n", toChars()); VarDeclaration *sv; if (s) { sv = (VarDeclaration *)s; } else { Initializer *init = NULL; if (this->init) { init = this->init->syntaxCopy(); //init->isExpInitializer()->exp->print(); //init->isExpInitializer()->exp->dump(0); } sv = new VarDeclaration(loc, type ? type->syntaxCopy() : NULL, ident, init); sv->storage_class = storage_class; } // Syntax copy for header file if (!htype) // Don't overwrite original { if (type) // Make copy for both old and new instances { htype = type->syntaxCopy(); sv->htype = type->syntaxCopy(); } } else // Make copy of original for new instance sv->htype = htype->syntaxCopy(); if (!hinit) { if (init) { hinit = init->syntaxCopy(); sv->hinit = init->syntaxCopy(); } } else sv->hinit = hinit->syntaxCopy(); return sv; } void VarDeclaration::semantic(Scope *sc) { #if 0 printf("VarDeclaration::semantic('%s', parent = '%s')\n", toChars(), sc->parent->toChars()); printf(" type = %s\n", type ? type->toChars() : "null"); printf(" stc = x%x\n", sc->stc); printf(" storage_class = x%llx\n", storage_class); printf("linkage = %d\n", sc->linkage); //if (strcmp(toChars(), "mul") == 0) halt(); #endif // if (sem > SemanticStart) // return; // sem = SemanticIn; if (scope) { sc = scope; scope = NULL; } /* Pick up storage classes from context, but skip synchronized */ storage_class |= (sc->stc & ~STCsynchronized); if (storage_class & STCextern && init) error("extern symbols cannot have initializers"); AggregateDeclaration *ad = isThis(); if (ad) storage_class |= ad->storage_class & STC_TYPECTOR; /* If auto type inference, do the inference */ int inferred = 0; if (!type) { inuse++; //printf("inferring type for %s with init %s\n", toChars(), init->toChars()); ArrayInitializer *ai = init->isArrayInitializer(); if (ai) { Expression *e; if (ai->isAssociativeArray()) e = ai->toAssocArrayLiteral(); else e = init->toExpression(); if (!e) { error("cannot infer type from initializer"); e = new ErrorExp(); } init = new ExpInitializer(e->loc, e); type = init->inferType(sc); if (type->ty == Tsarray) type = type->nextOf()->arrayOf(); } else type = init->inferType(sc); // type = type->semantic(loc, sc); inuse--; inferred = 1; if (init->isArrayInitializer() && type->toBasetype()->ty == Tsarray) { // Prefer array literals to give a T[] type rather than a T[dim] type = type->toBasetype()->nextOf()->arrayOf(); } /* This is a kludge to support the existing syntax for RAII * declarations. */ storage_class &= ~STCauto; originalType = type; } else { if (!originalType) originalType = type; type = type->semantic(loc, sc); } //printf(" semantic type = %s\n", type ? type->toChars() : "null"); type->checkDeprecated(loc, sc); linkage = sc->linkage; this->parent = sc->parent; //printf("this = %p, parent = %p, '%s'\n", this, parent, parent->toChars()); protection = sc->protection; /* If scope's alignment is the default, use the type's alignment, * otherwise the scope overrrides. */ alignment = sc->structalign; if (alignment == STRUCTALIGN_DEFAULT) alignment = type->alignment(); // use type's alignment //printf("sc->stc = %x\n", sc->stc); //printf("storage_class = x%x\n", storage_class); #if DMDV2 // Safety checks if (sc->func && !sc->intypeof) { if (storage_class & STCgshared) { if (sc->func->setUnsafe()) error("__gshared not allowed in safe functions; use shared"); } if (init && init->isVoidInitializer() && type->hasPointers()) { if (sc->func->setUnsafe()) error("void initializers for pointers not allowed in safe functions"); } if (type->hasPointers() && type->toDsymbol(sc)) { Dsymbol *s = type->toDsymbol(sc); if (s) { AggregateDeclaration *ad2 = s->isAggregateDeclaration(); if (ad2 && ad2->hasUnions) { if (sc->func->setUnsafe()) error("unions containing pointers are not allowed in @safe functions"); } } } } #endif Dsymbol *parent = toParent(); FuncDeclaration *fd = parent->isFuncDeclaration(); Type *tb = type->toBasetype(); if (tb->ty == Tvoid && !(storage_class & STClazy)) { if (inferred) { error("type %s is inferred from initializer %s, and variables cannot be of type void", type->toChars(), init->toChars()); } else error("variables cannot be of type void"); type = Type::terror; tb = type; } if (tb->ty == Tfunction) { error("cannot be declared to be a function"); type = Type::terror; tb = type; } if (tb->ty == Tstruct) { TypeStruct *ts = (TypeStruct *)tb; if (!ts->sym->members) { error("no definition of struct %s", ts->toChars()); } } if ((storage_class & STCauto) && !inferred) error("storage class 'auto' has no effect if type is not inferred, did you mean 'scope'?"); if (tb->ty == Ttuple) { /* Instead, declare variables for each of the tuple elements * and add those. */ TypeTuple *tt = (TypeTuple *)tb; size_t nelems = Parameter::dim(tt->arguments); Objects *exps = new Objects(); exps->setDim(nelems); Expression *ie = init ? init->toExpression() : NULL; if (ie) ie = ie->semantic(sc); if (nelems > 0 && ie) { Expressions *iexps = new Expressions(); iexps->push(ie); Expressions *exps = new Expressions(); for (size_t pos = 0; pos < iexps->dim; pos++) { Lexpand1: Expression *e = (*iexps)[pos]; Parameter *arg = Parameter::getNth(tt->arguments, pos); arg->type = arg->type->semantic(loc, sc); //printf("[%d] iexps->dim = %d, ", pos, iexps->dim); //printf("e = (%s %s, %s), ", Token::tochars[e->op], e->toChars(), e->type->toChars()); //printf("arg = (%s, %s)\n", arg->toChars(), arg->type->toChars()); if (e != ie) { if (iexps->dim > nelems) goto Lnomatch; if (e->type->implicitConvTo(arg->type)) continue; } if (e->op == TOKtuple) { TupleExp *te = (TupleExp *)e; if (iexps->dim - 1 + te->exps->dim > nelems) goto Lnomatch; iexps->remove(pos); iexps->insert(pos, te->exps); goto Lexpand1; } else if (isAliasThisTuple(e)) { Identifier *id = Lexer::uniqueId("__tup"); ExpInitializer *ei = new ExpInitializer(e->loc, e); VarDeclaration *v = new VarDeclaration(loc, NULL, id, ei); v->storage_class = STCctfe | STCref | STCforeach; VarExp *ve = new VarExp(loc, v); ve->type = e->type; exps->setDim(1); (*exps)[0] = ve; expandAliasThisTuples(exps, 0); for (size_t u = 0; u < exps->dim ; u++) { Lexpand2: Expression *ee = (*exps)[u]; Parameter *arg = Parameter::getNth(tt->arguments, pos + u); arg->type = arg->type->semantic(loc, sc); //printf("[%d+%d] exps->dim = %d, ", pos, u, exps->dim); //printf("ee = (%s %s, %s), ", Token::tochars[ee->op], ee->toChars(), ee->type->toChars()); //printf("arg = (%s, %s)\n", arg->toChars(), arg->type->toChars()); size_t iexps_dim = iexps->dim - 1 + exps->dim; if (iexps_dim > nelems) goto Lnomatch; if (ee->type->implicitConvTo(arg->type)) continue; if (expandAliasThisTuples(exps, u) != -1) goto Lexpand2; } if ((*exps)[0] != ve) { Expression *e0 = (*exps)[0]; (*exps)[0] = new CommaExp(loc, new DeclarationExp(loc, v), e0); (*exps)[0]->type = e0->type; iexps->remove(pos); iexps->insert(pos, exps); goto Lexpand1; } } } if (iexps->dim < nelems) goto Lnomatch; ie = new TupleExp(init->loc, iexps); } Lnomatch: if (ie && ie->op == TOKtuple) { size_t tedim = ((TupleExp *)ie)->exps->dim; if (tedim != nelems) { ::error(loc, "tuple of %d elements cannot be assigned to tuple of %d elements", (int)tedim, (int)nelems); for (size_t u = tedim; u < nelems; u++) // fill dummy expression ((TupleExp *)ie)->exps->push(new ErrorExp()); } } for (size_t i = 0; i < nelems; i++) { Parameter *arg = Parameter::getNth(tt->arguments, i); OutBuffer buf; buf.printf("_%s_field_%llu", ident->toChars(), (ulonglong)i); buf.writeByte(0); const char *name = (const char *)buf.extractData(); Identifier *id = Lexer::idPool(name); Expression *einit = ie; if (ie && ie->op == TOKtuple) { einit = (*((TupleExp *)ie)->exps)[i]; } Initializer *ti = init; if (einit) { ti = new ExpInitializer(einit->loc, einit); } VarDeclaration *v = new VarDeclaration(loc, arg->type, id, ti); if (arg->storageClass & STCparameter) v->storage_class |= arg->storageClass; //printf("declaring field %s of type %s\n", v->toChars(), v->type->toChars()); v->semantic(sc); #if !IN_LLVM // removed for LDC since TupleDeclaration::toObj already creates the fields; // adding them to the scope again leads to duplicates if (sc->scopesym) { //printf("adding %s to %s\n", v->toChars(), sc->scopesym->toChars()); if (sc->scopesym->members) sc->scopesym->members->push(v); } #endif Expression *e = new DsymbolExp(loc, v); (*exps)[i] = e; } TupleDeclaration *v2 = new TupleDeclaration(loc, ident, exps); v2->isexp = 1; aliassym = v2; return; } /* Storage class can modify the type */ type = type->addStorageClass(storage_class); /* Adjust storage class to reflect type */ if (type->isConst()) { storage_class |= STCconst; if (type->isShared()) storage_class |= STCshared; } else if (type->isImmutable()) storage_class |= STCimmutable; else if (type->isShared()) storage_class |= STCshared; else if (type->isWild()) storage_class |= STCwild; if (isSynchronized()) { error("variable %s cannot be synchronized", toChars()); } else if (isOverride()) { error("override cannot be applied to variable"); } else if (isAbstract()) { error("abstract cannot be applied to variable"); } else if (storage_class & STCfinal) { error("final cannot be applied to variable, perhaps you meant const?"); } if (storage_class & (STCstatic | STCextern | STCmanifest | STCtemplateparameter | STCtls | STCgshared | STCctfe)) { } else { AggregateDeclaration *aad = parent->isAggregateDeclaration(); if (aad) { #if DMDV2 assert(!(storage_class & (STCextern | STCstatic | STCtls | STCgshared))); if (storage_class & (STCconst | STCimmutable) && init) { if (!tb->isTypeBasic()) storage_class |= STCstatic; } else #endif { storage_class |= STCfield; #if DMDV2 if (tb->ty == Tstruct && ((TypeStruct *)tb)->sym->noDefaultCtor || tb->ty == Tclass && ((TypeClass *)tb)->sym->noDefaultCtor) aad->noDefaultCtor = TRUE; #endif } } InterfaceDeclaration *id = parent->isInterfaceDeclaration(); if (id) { error("field not allowed in interface"); } /* Templates cannot add fields to aggregates */ TemplateInstance *ti = parent->isTemplateInstance(); if (ti) { // Take care of nested templates while (1) { TemplateInstance *ti2 = ti->tempdecl->parent->isTemplateInstance(); if (!ti2) break; ti = ti2; } // If it's a member template AggregateDeclaration *ad2 = ti->tempdecl->isMember(); if (ad2 && storage_class != STCundefined) { error("cannot use template to add field to aggregate '%s'", ad2->toChars()); } } } #if DMDV2 if ((storage_class & (STCref | STCparameter | STCforeach)) == STCref && ident != Id::This) { error("only parameters or foreach declarations can be ref"); } if (type->hasWild() && !(type->ty == Tpointer && type->nextOf()->ty == Tfunction || type->ty == Tdelegate)) { if (storage_class & (STCstatic | STCextern | STCtls | STCgshared | STCmanifest | STCfield) || isDataseg() ) { error("only parameters or stack based variables can be inout"); } FuncDeclaration *func = sc->func; if (func) { if (func->fes) func = func->fes->func; if (!((TypeFunction *)func->type)->iswild) { error("inout variables can only be declared inside inout functions"); } } } if (!(storage_class & (STCctfe | STCref)) && tb->ty == Tstruct && ((TypeStruct *)tb)->sym->noDefaultCtor) { if (!init) { if (storage_class & STCfield) /* For fields, we'll check the constructor later to make sure it is initialized */ storage_class |= STCnodefaultctor; else if (storage_class & STCparameter) ; else error("initializer required for type %s", type->toChars()); } } #endif if (type->isscope() && !noscope) { if (storage_class & (STCfield | STCout | STCref | STCstatic | STCmanifest | STCtls | STCgshared) || !fd) { error("globals, statics, fields, manifest constants, ref and out parameters cannot be scope"); } if (!(storage_class & STCscope)) { if (!(storage_class & STCparameter) && ident != Id::withSym) error("reference to scope class must be scope"); } } if (!init && !fd) { // If not mutable, initializable by constructor only storage_class |= STCctorinit; } if (init) storage_class |= STCinit; // remember we had an explicit initializer else if (storage_class & STCmanifest) error("manifest constants must have initializers"); enum TOK op = TOKconstruct; if (!init && !sc->inunion && !isStatic() && fd && (!(storage_class & (STCfield | STCin | STCforeach | STCparameter | STCresult)) || (storage_class & STCout)) && type->size() != 0) { // Provide a default initializer //printf("Providing default initializer for '%s'\n", toChars()); if (type->ty == Tstruct && ((TypeStruct *)type)->sym->zeroInit == 1) { /* If a struct is all zeros, as a special case * set it's initializer to the integer 0. * In AssignExp::toElem(), we check for this and issue * a memset() to initialize the struct. * Must do same check in interpreter. */ Expression *e = new IntegerExp(loc, 0, Type::tint32); Expression *e1; e1 = new VarExp(loc, this); e = new ConstructExp(loc, e1, e); e->type = e1->type; // don't type check this, it would fail init = new ExpInitializer(loc, e); goto Ldtor; } else if (type->ty == Tstruct && (((TypeStruct *)type)->sym->isnested)) { /* Nested struct requires valid enclosing frame pointer. * In StructLiteralExp::toElem(), it's calculated. */ Expression *e = type->defaultInitLiteral(loc); Expression *e1 = new VarExp(loc, this); e = new ConstructExp(loc, e1, e); e = e->semantic(sc); init = new ExpInitializer(loc, e); goto Ldtor; } else if (type->ty == Ttypedef) { TypeTypedef *td = (TypeTypedef *)type; if (td->sym->init) { init = td->sym->init; ExpInitializer *ie = init->isExpInitializer(); if (ie) // Make copy so we can modify it init = new ExpInitializer(ie->loc, ie->exp); } else init = getExpInitializer(); } else { init = getExpInitializer(); } // Default initializer is always a blit op = TOKblit; } if (init) { sc = sc->push(); sc->stc &= ~(STC_TYPECTOR | STCpure | STCnothrow | STCref | STCdisable); ArrayInitializer *ai = init->isArrayInitializer(); if (ai && tb->ty == Taarray) { Expression *e = ai->toAssocArrayLiteral(); init = new ExpInitializer(e->loc, e); } StructInitializer *si = init->isStructInitializer(); ExpInitializer *ei = init->isExpInitializer(); if (ei && isScope()) { // See if initializer is a NewExp that can be allocated on the stack if (ei->exp->op == TOKnew) { NewExp *ne = (NewExp *)ei->exp; if (!(ne->newargs && ne->newargs->dim)) { ne->onstack = 1; onstack = 1; if (type->isBaseOf(ne->newtype->semantic(loc, sc), NULL)) onstack = 2; } } // or a delegate that doesn't escape a reference to the function else if (ei->exp->op == TOKfunction) { FuncDeclaration *f = ((FuncExp *)ei->exp)->fd; f->tookAddressOf--; } } // If inside function, there is no semantic3() call if (sc->func) { // If local variable, use AssignExp to handle all the various // possibilities. if (fd && !(storage_class & (STCmanifest | STCstatic | STCtls | STCgshared | STCextern)) && !init->isVoidInitializer()) { //printf("fd = '%s', var = '%s'\n", fd->toChars(), toChars()); if (!ei) { Expression *e = init->toExpression(); if (!e) { // Run semantic, but don't need to interpret init = init->semantic(sc, type, INITnointerpret); e = init->toExpression(); if (!e) { error("is not a static and cannot have static initializer"); return; } } ei = new ExpInitializer(init->loc, e); init = ei; } Expression *e1 = new VarExp(loc, this); Type *t = type->toBasetype(); if (ei && !inferred) ei->exp = ei->exp->inferType(t); Linit2: if (t->ty == Tsarray && !(storage_class & (STCref | STCout))) { ei->exp = ei->exp->semantic(sc); if (!ei->exp->implicitConvTo(type)) { dinteger_t dim = ((TypeSArray *)t)->dim->toInteger(); // If multidimensional static array, treat as one large array while (1) { t = t->nextOf()->toBasetype(); if (t->ty != Tsarray) break; dim *= ((TypeSArray *)t)->dim->toInteger(); e1->type = new TypeSArray(t->nextOf(), new IntegerExp(0, dim, Type::tindex)); } } e1 = new SliceExp(loc, e1, NULL, NULL); } else if (t->ty == Tstruct) { ei->exp = ei->exp->semantic(sc); ei->exp = resolveProperties(sc, ei->exp); StructDeclaration *sd = ((TypeStruct *)t)->sym; #if DMDV2 Expression** pinit = &ei->exp; while ((*pinit)->op == TOKcomma) { pinit = &((CommaExp *)*pinit)->e2; } /* Look to see if initializer is a call to the constructor */ if (sd->ctor && // there are constructors (*pinit)->type->ty == Tstruct && // rvalue is the same struct ((TypeStruct *)(*pinit)->type)->sym == sd && (*pinit)->op == TOKcall) { /* Look for form of constructor call which is: * *__ctmp.ctor(arguments...) */ if (1) { CallExp *ce = (CallExp *)(*pinit); if (ce->e1->op == TOKdotvar) { DotVarExp *dve = (DotVarExp *)ce->e1; if (dve->var->isCtorDeclaration()) { /* It's a constructor call, currently constructing * a temporary __ctmp. */ /* Before calling the constructor, initialize * variable with a bit copy of the default * initializer */ /* Remove ref if this declaration is ref binding. * ref Type __self = (__ctmp = 0, __ctmp).this(...); * -> Type __self = (__self = 0, __self.this(...)); */ storage_class &= ~(STCref | STCforeach | STCparameter); Expression *e; if (sd->zeroInit == 1) { e = new ConstructExp(loc, new VarExp(loc, this), new IntegerExp(loc, 0, Type::tint32)); } else if (sd->isNested()) { e = new AssignExp(loc, new VarExp(loc, this), t->defaultInitLiteral(loc)); e->op = TOKblit; } else { e = new AssignExp(loc, new VarExp(loc, this), t->defaultInit(loc)); e->op = TOKblit; } e->type = t; /* Replace __ctmp being constructed with e1. * We need to copy constructor call expression, * because it may be used in other place. */ DotVarExp *dvx = (DotVarExp *)dve->copy(); dvx->e1 = e1; CallExp *cx = (CallExp *)ce->copy(); cx->e1 = dvx; (*pinit) = new CommaExp(loc, e, cx); (*pinit) = (*pinit)->semantic(sc); goto Ldtor; } } } } /* Look for ((S tmp = S()),tmp) and replace it with just S() */ Expression *e2 = ei->exp->isTemp(); if (e2) { ei->exp = e2; goto Linit2; } #endif if (!ei->exp->implicitConvTo(type)) { Type *ti = ei->exp->type->toBasetype(); // Look for constructor first if (sd->ctor && /* Initializing with the same type is done differently */ !(ti->ty == Tstruct && t->toDsymbol(sc) == ti->toDsymbol(sc))) { // Rewrite as e1.ctor(arguments) Expression *ector = new DotIdExp(loc, e1, Id::ctor); ei->exp = new CallExp(loc, ector, ei->exp); /* Before calling the constructor, initialize * variable with a bit copy of the default * initializer */ Expression *e = new AssignExp(loc, e1, t->defaultInit(loc)); e->op = TOKblit; e->type = t; ei->exp = new CommaExp(loc, e, ei->exp); } else /* Look for opCall * See bugzilla 2702 for more discussion */ // Don't cast away invariant or mutability in initializer if (search_function(sd, Id::call) && /* Initializing with the same type is done differently */ !(ti->ty == Tstruct && t->toDsymbol(sc) == ti->toDsymbol(sc))) { // Rewrite as e1.call(arguments) Expression * eCall = new DotIdExp(loc, e1, Id::call); ei->exp = new CallExp(loc, eCall, ei->exp); } } } ei->exp = new AssignExp(loc, e1, ei->exp); ei->exp->op = op; canassign++; ei->exp = ei->exp->semantic(sc); canassign--; ei->exp->optimize(WANTvalue); } else { init = init->semantic(sc, type, INITinterpret); } } else if (storage_class & (STCconst | STCimmutable | STCmanifest) || type->isConst() || type->isImmutable() || parent->isAggregateDeclaration()) { /* Because we may need the results of a const declaration in a * subsequent type, such as an array dimension, before semantic2() * gets ordinarily run, try to run semantic2() now. * Ignore failure. */ if (!global.errors && !inferred) { unsigned errors = global.startGagging(); Expression *e; Initializer *i2 = init; inuse++; if (ei) { e = ei->exp->syntaxCopy(); e = e->semantic(sc); e = resolveProperties(sc, e); #if DMDV2 /* The problem is the following code: * struct CopyTest { * double x; * this(double a) { x = a * 10.0;} * this(this) { x += 2.0; } * } * const CopyTest z = CopyTest(5.3); // ok * const CopyTest w = z; // not ok, postblit not run * static assert(w.x == 55.0); * because the postblit doesn't get run on the initialization of w. */ Type *tb2 = e->type->toBasetype(); if (tb2->ty == Tstruct) { StructDeclaration *sd = ((TypeStruct *)tb2)->sym; Type *typeb = type->toBasetype(); /* Look to see if initializer involves a copy constructor * (which implies a postblit) */ if (sd->cpctor && // there is a copy constructor typeb->equals(tb2)) // rvalue is the same struct { // The only allowable initializer is a (non-copy) constructor if (e->op == TOKcall) { CallExp *ce = (CallExp *)e; if (ce->e1->op == TOKdotvar) { DotVarExp *dve = (DotVarExp *)ce->e1; if (dve->var->isCtorDeclaration()) goto LNoCopyConstruction; } } global.gag--; error("of type struct %s uses this(this), which is not allowed in static initialization", typeb->toChars()); global.gag++; LNoCopyConstruction: ; } } #endif e = e->implicitCastTo(sc, type); } else if (si || ai) { i2 = init->syntaxCopy(); i2 = i2->semantic(sc, type, INITinterpret); } inuse--; if (global.endGagging(errors)) // if errors happened { #if DMDV2 /* Save scope for later use, to try again */ scope = new Scope(*sc); scope->setNoFree(); #endif } else if (ei) { if (isDataseg() || (storage_class & STCmanifest)) e = e->ctfeInterpret(); else e = e->optimize(WANTvalue); switch (e->op) { case TOKint64: case TOKfloat64: case TOKstring: case TOKarrayliteral: case TOKassocarrayliteral: case TOKstructliteral: case TOKnull: ei->exp = e; // no errors, keep result break; default: #if DMDV2 /* Save scope for later use, to try again */ scope = new Scope(*sc); scope->setNoFree(); #endif break; } } else init = i2; // no errors, keep result } } sc = sc->pop(); } Ldtor: /* Build code to execute destruction, if necessary */ edtor = callScopeDtor(sc); if (edtor) { edtor = edtor->semantic(sc); #if 0 // currently disabled because of std.stdio.stdin, stdout and stderr if (isDataseg() && !(storage_class & STCextern)) error("static storage variables cannot have destructors"); #endif } sem = SemanticDone; } void VarDeclaration::semantic2(Scope *sc) { //printf("VarDeclaration::semantic2('%s')\n", toChars()); // Inside unions, default to void initializers if (!init && sc->inunion && !toParent()->isFuncDeclaration()) { AggregateDeclaration *aad = parent->isAggregateDeclaration(); if (aad) { if (aad->fields[0] == this) { int hasinit = 0; for (size_t i = 1; i < aad->fields.dim; i++) { if (aad->fields[i]->init && !aad->fields[i]->init->isVoidInitializer()) { hasinit = 1; break; } } if (!hasinit) init = new ExpInitializer(loc, type->defaultInitLiteral(loc)); } else init = new VoidInitializer(loc); } } if (init && !toParent()->isFuncDeclaration()) { inuse++; #if 0 ExpInitializer *ei = init->isExpInitializer(); if (ei) { ei->exp->dump(0); printf("type = %p\n", ei->exp->type); } #endif init = init->semantic(sc, type, INITinterpret); inuse--; } sem = Semantic2Done; } void VarDeclaration::setFieldOffset(AggregateDeclaration *ad, unsigned *poffset, bool isunion) { //printf("VarDeclaration::setFieldOffset(ad = %s) %s\n", ad->toChars(), toChars()); if (aliassym) { // If this variable was really a tuple, set the offsets for the tuple fields TupleDeclaration *v2 = aliassym->isTupleDeclaration(); assert(v2); for (size_t i = 0; i < v2->objects->dim; i++) { Object *o = (*v2->objects)[i]; assert(o->dyncast() == DYNCAST_EXPRESSION); Expression *e = (Expression *)o; assert(e->op == TOKdsymbol); DsymbolExp *se = (DsymbolExp *)e; se->s->setFieldOffset(ad, poffset, isunion); } return; } if (!(storage_class & STCfield)) return; assert(!(storage_class & (STCstatic | STCextern | STCparameter | STCtls))); /* Fields that are tuples appear both as part of TupleDeclarations and * as members. That means ignore them if they are already a field. */ if (offset) return; // already a field for (size_t i = 0; i < ad->fields.dim; i++) { if (ad->fields[i] == this) return; // already a field } // Check for forward referenced types which will fail the size() call Type *t = type->toBasetype(); if (storage_class & STCref) { // References are the size of a pointer t = Type::tvoidptr; } if (t->ty == Tstruct) { TypeStruct *ts = (TypeStruct *)t; #if DMDV2 if (ts->sym == ad) { ad->error("cannot have field %s with same struct type", toChars()); } #endif if (ts->sym->sizeok != SIZEOKdone && ts->sym->scope) ts->sym->semantic(NULL); if (ts->sym->sizeok != SIZEOKdone) { ad->sizeok = SIZEOKfwd; // cannot finish; flag as forward referenced return; } } if (t->ty == Tident) { ad->sizeok = SIZEOKfwd; // cannot finish; flag as forward referenced return; } unsigned memsize = t->size(loc); // size of member unsigned memalignsize = t->alignsize(); // size of member for alignment purposes offset = AggregateDeclaration::placeField(poffset, memsize, memalignsize, alignment, &ad->structsize, &ad->alignsize, isunion); //printf("\t%s: alignsize = %d\n", toChars(), alignsize); //printf(" addField '%s' to '%s' at offset %d, size = %d\n", toChars(), ad->toChars(), offset, memsize); ad->fields.push(this); } void VarDeclaration::semantic3(Scope *sc) { // LDC if (!global.params.useAvailableExternally) availableExternally = false; if (aliassym) aliassym->semantic3(sc); // Preserve call chain Declaration::semantic3(sc); } const char *VarDeclaration::kind() { return "variable"; } Dsymbol *VarDeclaration::toAlias() { //printf("VarDeclaration::toAlias('%s', this = %p, aliassym = %p)\n", toChars(), this, aliassym); assert(this != aliassym); Dsymbol *s = aliassym ? aliassym->toAlias() : this; return s; } void VarDeclaration::toCBuffer(OutBuffer *buf, HdrGenState *hgs) { StorageClassDeclaration::stcToCBuffer(buf, storage_class); /* If changing, be sure and fix CompoundDeclarationStatement::toCBuffer() * too. */ if (type) type->toCBuffer(buf, ident, hgs); else buf->writestring(ident->toChars()); if (init) { buf->writestring(" = "); #if DMDV2 ExpInitializer *ie = init->isExpInitializer(); if (ie && (ie->exp->op == TOKconstruct || ie->exp->op == TOKblit)) ((AssignExp *)ie->exp)->e2->toCBuffer(buf, hgs); else #endif init->toCBuffer(buf, hgs); } buf->writeByte(';'); buf->writenl(); } AggregateDeclaration *VarDeclaration::isThis() { AggregateDeclaration *ad = NULL; if (!(storage_class & (STCstatic | STCextern | STCmanifest | STCtemplateparameter | STCtls | STCgshared | STCctfe))) { if ((storage_class & (STCconst | STCimmutable | STCwild)) && init) return NULL; for (Dsymbol *s = this; s; s = s->parent) { ad = s->isMember(); if (ad) break; if (!s->parent || !s->parent->isTemplateMixin()) break; } } return ad; } int VarDeclaration::needThis() { //printf("VarDeclaration::needThis(%s, x%x)\n", toChars(), storage_class); return storage_class & STCfield; } int VarDeclaration::isImportedSymbol() { if (protection == PROTexport && !init && (storage_class & STCstatic || parent->isModule())) return TRUE; return FALSE; } void VarDeclaration::checkCtorConstInit() { #if 0 /* doesn't work if more than one static ctor */ if (ctorinit == 0 && isCtorinit() && !(storage_class & STCfield)) error("missing initializer in static constructor for const variable"); #endif } /************************************ * Check to see if this variable is actually in an enclosing function * rather than the current one. */ void VarDeclaration::checkNestedReference(Scope *sc, Loc loc) { //printf("VarDeclaration::checkNestedReference() %s\n", toChars()); if (parent && !isDataseg() && parent != sc->parent && !(storage_class & STCmanifest)) { // The function that this variable is in FuncDeclaration *fdv = toParent()->isFuncDeclaration(); // The current function FuncDeclaration *fdthis = sc->parent->isFuncDeclaration(); if (fdv && fdthis && fdv != fdthis) { // Add fdthis to nestedrefs[] if not already there for (size_t i = 0; 1; i++) { if (i == nestedrefs.dim) { nestedrefs.push(fdthis); break; } if (nestedrefs[i] == fdthis) break; } if (fdthis->ident != Id::ensure) { /* __ensure is always called directly, * so it never becomes closure. */ //printf("\tfdv = %s\n", fdv->toChars()); //printf("\tfdthis = %s\n", fdthis->toChars()); if (loc.filename) fdthis->getLevel(loc, sc, fdv); // Function literals from fdthis to fdv must be delegates for (Dsymbol *s = fdthis; s && s != fdv; s = s->toParent2()) { // function literal has reference to enclosing scope is delegate if (FuncLiteralDeclaration *fld = s->isFuncLiteralDeclaration()) { fld->tok = TOKdelegate; } } // Add this to fdv->closureVars[] if not already there for (size_t i = 0; 1; i++) { if (i == fdv->closureVars.dim) { fdv->closureVars.push(this); break; } if (fdv->closureVars[i] == this) break; } //printf("fdthis is %s\n", fdthis->toChars()); //printf("var %s in function %s is nested ref\n", toChars(), fdv->toChars()); // __dollar creates problems because it isn't a real variable Bugzilla 3326 if (ident == Id::dollar) ::error(loc, "cannnot use $ inside a function literal"); } } } } /**************************** * Get ExpInitializer for a variable, if there is one. */ ExpInitializer *VarDeclaration::getExpInitializer() { ExpInitializer *ei; if (init) ei = init->isExpInitializer(); else { Expression *e = type->defaultInit(loc); if (e) ei = new ExpInitializer(loc, e); else ei = NULL; } return ei; } /******************************************* * If variable has a constant expression initializer, get it. * Otherwise, return NULL. */ Expression *VarDeclaration::getConstInitializer() { if ((isConst() || isImmutable() || storage_class & STCmanifest) && storage_class & STCinit) { ExpInitializer *ei = getExpInitializer(); if (ei) return ei->exp; } return NULL; } /************************************* * Return !=0 if we can take the address of this variable. */ int VarDeclaration::canTakeAddressOf() { #if 0 /* Global variables and struct/class fields of the form: * const int x = 3; * are not stored and hence cannot have their address taken. */ if ((isConst() || isImmutable()) && storage_class & STCinit && (!(storage_class & (STCstatic | STCextern)) || (storage_class & STCfield)) && (!parent || toParent()->isModule() || toParent()->isTemplateInstance()) && type->toBasetype()->isTypeBasic() ) { return 0; } #else if (storage_class & STCmanifest) return 0; #endif return 1; } /******************************* * Does symbol go into data segment? * Includes extern variables. */ int VarDeclaration::isDataseg() { #if 0 printf("VarDeclaration::isDataseg(%p, '%s')\n", this, toChars()); printf("%llx, isModule: %p, isTemplateInstance: %p\n", storage_class & (STCstatic | STCconst), parent->isModule(), parent->isTemplateInstance()); printf("parent = '%s'\n", parent->toChars()); #endif if (storage_class & STCmanifest) return 0; Dsymbol *parent = this->toParent(); if (!parent && !(storage_class & STCstatic)) { error("forward referenced"); type = Type::terror; return 0; } return canTakeAddressOf() && (storage_class & (STCstatic | STCextern | STCtls | STCgshared) || toParent()->isModule() || toParent()->isTemplateInstance()); } /************************************ * Does symbol go into thread local storage? */ int VarDeclaration::isThreadlocal() { //printf("VarDeclaration::isThreadlocal(%p, '%s')\n", this, toChars()); #if 0 //|| TARGET_OSX /* To be thread-local, must use the __thread storage class. * BUG: OSX doesn't support thread local yet. */ return isDataseg() && (storage_class & (STCtls | STCconst | STCimmutable | STCshared | STCgshared)) == STCtls; #else /* Data defaults to being thread-local. It is not thread-local * if it is immutable, const or shared. */ int i = isDataseg() && !(storage_class & (STCimmutable | STCconst | STCshared | STCgshared)); //printf("\treturn %d\n", i); return i; #endif } /******************************************** * Can variable be read and written by CTFE? */ int VarDeclaration::isCTFE() { return (storage_class & STCctfe) != 0; // || !isDataseg(); } int VarDeclaration::hasPointers() { //printf("VarDeclaration::hasPointers() %s, ty = %d\n", toChars(), type->ty); return (!isDataseg() && type->hasPointers()); } /****************************************** * Return TRUE if variable needs to call the destructor. */ int VarDeclaration::needsAutoDtor() { //printf("VarDeclaration::needsAutoDtor() %s\n", toChars()); if (noscope || !edtor) return FALSE; return TRUE; } /****************************************** * If a variable has a scope destructor call, return call for it. * Otherwise, return NULL. */ Expression *VarDeclaration::callScopeDtor(Scope *sc) { Expression *e = NULL; //printf("VarDeclaration::callScopeDtor() %s\n", toChars()); // Destruction of STCfield's is handled by buildDtor() if (noscope || storage_class & (STCnodtor | STCref | STCout | STCfield)) { return NULL; } // Destructors for structs and arrays of structs bool array = false; Type *tv = type->toBasetype(); while (tv->ty == Tsarray) { TypeSArray *ta = (TypeSArray *)tv; array = true; tv = tv->nextOf()->toBasetype(); } if (tv->ty == Tstruct) { TypeStruct *ts = (TypeStruct *)tv; StructDeclaration *sd = ts->sym; if (sd->dtor) { if (array) { // Typeinfo.destroy(cast(void*)&v); #if IN_LLVM Expression *ea = new AddrExp(loc, new DsymbolExp(loc, this)); #else Expression *ea = new SymOffExp(loc, this, 0, 0); #endif ea = new CastExp(loc, ea, Type::tvoid->pointerTo()); Expressions *args = new Expressions(); args->push(ea); Expression *et = type->getTypeInfo(sc); et = new DotIdExp(loc, et, Id::destroy); e = new CallExp(loc, et, args); } else { e = new VarExp(loc, this); /* This is a hack so we can call destructors on const/immutable objects. * Need to add things like "const ~this()" and "immutable ~this()" to * fix properly. */ e->type = e->type->mutableOf(); e = new DotVarExp(loc, e, sd->dtor, 0); e = new CallExp(loc, e); } return e; } } // Destructors for classes if (storage_class & (STCauto | STCscope)) { for (ClassDeclaration *cd = type->isClassHandle(); cd; cd = cd->baseClass) { /* We can do better if there's a way with onstack * classes to determine if there's no way the monitor * could be set. */ //if (cd->isInterfaceDeclaration()) //error("interface %s cannot be scope", cd->toChars()); if (1 || onstack || cd->dtors.dim) // if any destructors { // delete this; Expression *ec; ec = new VarExp(loc, this); e = new DeleteExp(loc, ec); e->type = Type::tvoid; break; } } } return e; } /****************************************** */ void ObjectNotFound(Identifier *id) { Type::error(0, "%s not found. object.d may be incorrectly installed or corrupt.", id->toChars()); fatal(); } /********************************* ClassInfoDeclaration ****************************/ ClassInfoDeclaration::ClassInfoDeclaration(ClassDeclaration *cd) : VarDeclaration(0, ClassDeclaration::classinfo->type, cd->ident, NULL) { this->cd = cd; storage_class = STCstatic | STCgshared; } Dsymbol *ClassInfoDeclaration::syntaxCopy(Dsymbol *s) { assert(0); // should never be produced by syntax return NULL; } void ClassInfoDeclaration::semantic(Scope *sc) { } /********************************* ModuleInfoDeclaration ****************************/ ModuleInfoDeclaration::ModuleInfoDeclaration(Module *mod) : VarDeclaration(0, Module::moduleinfo->type, mod->ident, NULL) { this->mod = mod; storage_class = STCstatic | STCgshared; } Dsymbol *ModuleInfoDeclaration::syntaxCopy(Dsymbol *s) { assert(0); // should never be produced by syntax return NULL; } void ModuleInfoDeclaration::semantic(Scope *sc) { } /********************************* TypeInfoDeclaration ****************************/ TypeInfoDeclaration::TypeInfoDeclaration(Type *tinfo, int internal) : VarDeclaration(0, Type::typeinfo->type, tinfo->getTypeInfoIdent(internal), NULL) { this->tinfo = tinfo; storage_class = STCstatic | STCgshared; protection = PROTpublic; linkage = LINKc; } Dsymbol *TypeInfoDeclaration::syntaxCopy(Dsymbol *s) { assert(0); // should never be produced by syntax return NULL; } void TypeInfoDeclaration::semantic(Scope *sc) { assert(linkage == LINKc); #if IN_LLVM if (!global.params.useAvailableExternally) availableExternally = false; #endif } /***************************** TypeInfoConstDeclaration **********************/ #if DMDV2 TypeInfoConstDeclaration::TypeInfoConstDeclaration(Type *tinfo) : TypeInfoDeclaration(tinfo, 0) { if (!Type::typeinfoconst) { ObjectNotFound(Id::TypeInfo_Const); } type = Type::typeinfoconst->type; } #endif /***************************** TypeInfoInvariantDeclaration **********************/ #if DMDV2 TypeInfoInvariantDeclaration::TypeInfoInvariantDeclaration(Type *tinfo) : TypeInfoDeclaration(tinfo, 0) { if (!Type::typeinfoinvariant) { ObjectNotFound(Id::TypeInfo_Invariant); } type = Type::typeinfoinvariant->type; } #endif /***************************** TypeInfoSharedDeclaration **********************/ #if DMDV2 TypeInfoSharedDeclaration::TypeInfoSharedDeclaration(Type *tinfo) : TypeInfoDeclaration(tinfo, 0) { if (!Type::typeinfoshared) { ObjectNotFound(Id::TypeInfo_Shared); } type = Type::typeinfoshared->type; } #endif /***************************** TypeInfoWildDeclaration **********************/ #if DMDV2 TypeInfoWildDeclaration::TypeInfoWildDeclaration(Type *tinfo) : TypeInfoDeclaration(tinfo, 0) { if (!Type::typeinfowild) { ObjectNotFound(Id::TypeInfo_Wild); } type = Type::typeinfowild->type; } #endif /***************************** TypeInfoStructDeclaration **********************/ TypeInfoStructDeclaration::TypeInfoStructDeclaration(Type *tinfo) : TypeInfoDeclaration(tinfo, 0) { if (!Type::typeinfostruct) { ObjectNotFound(Id::TypeInfo_Struct); } type = Type::typeinfostruct->type; } /***************************** TypeInfoClassDeclaration ***********************/ TypeInfoClassDeclaration::TypeInfoClassDeclaration(Type *tinfo) : TypeInfoDeclaration(tinfo, 0) { if (!Type::typeinfoclass) { ObjectNotFound(Id::TypeInfo_Class); } type = Type::typeinfoclass->type; } /***************************** TypeInfoInterfaceDeclaration *******************/ TypeInfoInterfaceDeclaration::TypeInfoInterfaceDeclaration(Type *tinfo) : TypeInfoDeclaration(tinfo, 0) { if (!Type::typeinfointerface) { ObjectNotFound(Id::TypeInfo_Interface); } type = Type::typeinfointerface->type; } /***************************** TypeInfoTypedefDeclaration *********************/ TypeInfoTypedefDeclaration::TypeInfoTypedefDeclaration(Type *tinfo) : TypeInfoDeclaration(tinfo, 0) { if (!Type::typeinfotypedef) { ObjectNotFound(Id::TypeInfo_Typedef); } type = Type::typeinfotypedef->type; } /***************************** TypeInfoPointerDeclaration *********************/ TypeInfoPointerDeclaration::TypeInfoPointerDeclaration(Type *tinfo) : TypeInfoDeclaration(tinfo, 0) { if (!Type::typeinfopointer) { ObjectNotFound(Id::TypeInfo_Pointer); } type = Type::typeinfopointer->type; } /***************************** TypeInfoArrayDeclaration ***********************/ TypeInfoArrayDeclaration::TypeInfoArrayDeclaration(Type *tinfo) : TypeInfoDeclaration(tinfo, 0) { if (!Type::typeinfoarray) { ObjectNotFound(Id::TypeInfo_Array); } type = Type::typeinfoarray->type; } /***************************** TypeInfoStaticArrayDeclaration *****************/ TypeInfoStaticArrayDeclaration::TypeInfoStaticArrayDeclaration(Type *tinfo) : TypeInfoDeclaration(tinfo, 0) { if (!Type::typeinfostaticarray) { ObjectNotFound(Id::TypeInfo_StaticArray); } type = Type::typeinfostaticarray->type; } /***************************** TypeInfoAssociativeArrayDeclaration ************/ TypeInfoAssociativeArrayDeclaration::TypeInfoAssociativeArrayDeclaration(Type *tinfo) : TypeInfoDeclaration(tinfo, 0) { if (!Type::typeinfoassociativearray) { ObjectNotFound(Id::TypeInfo_AssociativeArray); } type = Type::typeinfoassociativearray->type; } /***************************** TypeInfoVectorDeclaration ***********************/ TypeInfoVectorDeclaration::TypeInfoVectorDeclaration(Type *tinfo) : TypeInfoDeclaration(tinfo, 0) { if (!Type::typeinfovector) { ObjectNotFound(Id::TypeInfo_Vector); } type = Type::typeinfovector->type; } /***************************** TypeInfoEnumDeclaration ***********************/ TypeInfoEnumDeclaration::TypeInfoEnumDeclaration(Type *tinfo) : TypeInfoDeclaration(tinfo, 0) { if (!Type::typeinfoenum) { ObjectNotFound(Id::TypeInfo_Enum); } type = Type::typeinfoenum->type; } /***************************** TypeInfoFunctionDeclaration ********************/ TypeInfoFunctionDeclaration::TypeInfoFunctionDeclaration(Type *tinfo) : TypeInfoDeclaration(tinfo, 0) { if (!Type::typeinfofunction) { ObjectNotFound(Id::TypeInfo_Function); } type = Type::typeinfofunction->type; } /***************************** TypeInfoDelegateDeclaration ********************/ TypeInfoDelegateDeclaration::TypeInfoDelegateDeclaration(Type *tinfo) : TypeInfoDeclaration(tinfo, 0) { if (!Type::typeinfodelegate) { ObjectNotFound(Id::TypeInfo_Delegate); } type = Type::typeinfodelegate->type; } /***************************** TypeInfoTupleDeclaration **********************/ TypeInfoTupleDeclaration::TypeInfoTupleDeclaration(Type *tinfo) : TypeInfoDeclaration(tinfo, 0) { if (!Type::typeinfotypelist) { ObjectNotFound(Id::TypeInfo_Tuple); } type = Type::typeinfotypelist->type; } /********************************* ThisDeclaration ****************************/ // For the "this" parameter to member functions ThisDeclaration::ThisDeclaration(Loc loc, Type *t) : VarDeclaration(loc, t, Id::This, NULL) { noscope = 1; } Dsymbol *ThisDeclaration::syntaxCopy(Dsymbol *s) { assert(0); // should never be produced by syntax return NULL; } /********************** StaticStructInitDeclaration ***************************/ StaticStructInitDeclaration::StaticStructInitDeclaration(Loc loc, StructDeclaration *dsym) : Declaration(new Identifier("", TOKidentifier)) { this->loc = loc; this->dsym = dsym; storage_class |= STCconst; }