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view dmd2/dsymbol.c @ 843:880b7aa29aa4
Automated merge with http://hg.dsource.org/projects/ldc
| author | Christian Kamm <kamm incasoftware de> |
|---|---|
| date | Fri, 12 Dec 2008 08:18:30 +0100 |
| parents | f04dde6e882c |
| children | 356e65836fb5 |
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// Compiler implementation of the D programming language // Copyright (c) 1999-2008 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 <stdio.h> #include <string.h> #include <assert.h> #include "mem.h" #include "mars.h" #include "dsymbol.h" #include "aggregate.h" #include "identifier.h" #include "module.h" #include "mtype.h" #include "expression.h" #include "statement.h" #include "declaration.h" #include "id.h" #include "scope.h" #include "init.h" #include "import.h" #include "template.h" #include "attrib.h" #include "../gen/enums.h" /****************************** Dsymbol ******************************/ Dsymbol::Dsymbol() { //printf("Dsymbol::Dsymbol(%p)\n", this); this->ident = NULL; this->c_ident = NULL; this->parent = NULL; this->csym = NULL; this->isym = NULL; this->loc = 0; this->comment = NULL; this->llvmInternal = LLVMnone; } Dsymbol::Dsymbol(Identifier *ident) { //printf("Dsymbol::Dsymbol(%p, ident)\n", this); this->ident = ident; this->c_ident = NULL; this->parent = NULL; this->csym = NULL; this->isym = NULL; this->loc = 0; this->comment = NULL; this->llvmInternal = LLVMnone; } int Dsymbol::equals(Object *o) { Dsymbol *s; if (this == o) return TRUE; s = (Dsymbol *)(o); if (s && ident->equals(s->ident)) return TRUE; return FALSE; } /************************************** * Copy the syntax. * Used for template instantiations. * If s is NULL, allocate the new object, otherwise fill it in. */ Dsymbol *Dsymbol::syntaxCopy(Dsymbol *s) { print(); printf("%s %s\n", kind(), toChars()); assert(0); return NULL; } /************************************** * Determine if this symbol is only one. * Returns: * FALSE, *ps = NULL: There are 2 or more symbols * TRUE, *ps = NULL: There are zero symbols * TRUE, *ps = symbol: The one and only one symbol */ int Dsymbol::oneMember(Dsymbol **ps) { //printf("Dsymbol::oneMember()\n"); *ps = this; return TRUE; } /***************************************** * Same as Dsymbol::oneMember(), but look at an array of Dsymbols. */ int Dsymbol::oneMembers(Array *members, Dsymbol **ps) { //printf("Dsymbol::oneMembers() %d\n", members ? members->dim : 0); Dsymbol *s = NULL; if (members) { for (int i = 0; i < members->dim; i++) { Dsymbol *sx = (Dsymbol *)members->data[i]; int x = sx->oneMember(ps); //printf("\t[%d] kind %s = %d, s = %p\n", i, sx->kind(), x, *ps); if (!x) { //printf("\tfalse 1\n"); assert(*ps == NULL); return FALSE; } if (*ps) { if (s) // more than one symbol { *ps = NULL; //printf("\tfalse 2\n"); return FALSE; } s = *ps; } } } *ps = s; // s is the one symbol, NULL if none //printf("\ttrue\n"); return TRUE; } /***************************************** * Is Dsymbol a variable that contains pointers? */ int Dsymbol::hasPointers() { //printf("Dsymbol::hasPointers() %s\n", toChars()); return 0; } char *Dsymbol::toChars() { return ident ? ident->toChars() : (char *)"__anonymous"; } char *Dsymbol::toPrettyChars() { Dsymbol *p; char *s; char *q; size_t len; //printf("Dsymbol::toPrettyChars() '%s'\n", toChars()); if (!parent) return toChars(); len = 0; for (p = this; p; p = p->parent) len += strlen(p->toChars()) + 1; s = (char *)mem.malloc(len); q = s + len - 1; *q = 0; for (p = this; p; p = p->parent) { char *t = p->toChars(); len = strlen(t); q -= len; memcpy(q, t, len); if (q == s) break; q--; *q = '.'; } return s; } char *Dsymbol::locToChars() { OutBuffer buf; char *p; Module *m = getModule(); if (m && m->srcfile) loc.filename = m->srcfile->toChars(); return loc.toChars(); } const char *Dsymbol::kind() { return "symbol"; } /********************************* * If this symbol is really an alias for another, * return that other. */ Dsymbol *Dsymbol::toAlias() { return this; } Dsymbol *Dsymbol::toParent() { return parent ? parent->pastMixin() : NULL; } Dsymbol *Dsymbol::pastMixin() { Dsymbol *s = this; //printf("Dsymbol::pastMixin() %s\n", toChars()); while (s && s->isTemplateMixin()) s = s->parent; return s; } /********************************** * Use this instead of toParent() when looking for the * 'this' pointer of the enclosing function/class. */ Dsymbol *Dsymbol::toParent2() { Dsymbol *s = parent; while (s && s->isTemplateInstance()) s = s->parent; return s; } TemplateInstance *Dsymbol::inTemplateInstance() { for (Dsymbol *parent = this->parent; parent; parent = parent->parent) { TemplateInstance *ti = parent->isTemplateInstance(); if (ti) return ti; } return NULL; } int Dsymbol::isAnonymous() { return ident ? 0 : 1; } void Dsymbol::semantic(Scope *sc) { error("%p has no semantic routine", this); } void Dsymbol::semantic2(Scope *sc) { // Most Dsymbols have no further semantic analysis needed } void Dsymbol::semantic3(Scope *sc) { // Most Dsymbols have no further semantic analysis needed } void Dsymbol::inlineScan() { // Most Dsymbols have no further semantic analysis needed } /********************************************* * Search for ident as member of s. * Input: * flags: 1 don't find private members * 2 don't give error messages * 4 return NULL if ambiguous * Returns: * NULL if not found */ Dsymbol *Dsymbol::search(Loc loc, Identifier *ident, int flags) { //printf("Dsymbol::search(this=%p,%s, ident='%s')\n", this, toChars(), ident->toChars()); return NULL; } /*************************************** * Search for identifier id as a member of 'this'. * id may be a template instance. * Returns: * symbol found, NULL if not */ Dsymbol *Dsymbol::searchX(Loc loc, Scope *sc, Identifier *id) { //printf("Dsymbol::searchX(this=%p,%s, ident='%s')\n", this, toChars(), ident->toChars()); Dsymbol *s = toAlias(); Dsymbol *sm; switch (id->dyncast()) { case DYNCAST_IDENTIFIER: sm = s->search(loc, id, 0); break; case DYNCAST_DSYMBOL: { // It's a template instance //printf("\ttemplate instance id\n"); Dsymbol *st = (Dsymbol *)id; TemplateInstance *ti = st->isTemplateInstance(); id = ti->name; sm = s->search(loc, id, 0); if (!sm) { error("template identifier %s is not a member of %s %s", id->toChars(), s->kind(), s->toChars()); return NULL; } sm = sm->toAlias(); TemplateDeclaration *td = sm->isTemplateDeclaration(); if (!td) { error("%s is not a template, it is a %s", id->toChars(), sm->kind()); return NULL; } ti->tempdecl = td; if (!ti->semanticdone) ti->semantic(sc); sm = ti->toAlias(); break; } default: assert(0); } return sm; } int Dsymbol::overloadInsert(Dsymbol *s) { //printf("Dsymbol::overloadInsert('%s')\n", s->toChars()); return FALSE; } void Dsymbol::toCBuffer(OutBuffer *buf, HdrGenState *hgs) { buf->writestring(toChars()); } unsigned Dsymbol::size(Loc loc) { error("Dsymbol '%s' has no size\n", toChars()); return 0; } int Dsymbol::isforwardRef() { return FALSE; } AggregateDeclaration *Dsymbol::isThis() { return NULL; } ClassDeclaration *Dsymbol::isClassMember() // are we a member of a class? { Dsymbol *parent = toParent(); if (parent && parent->isClassDeclaration()) return (ClassDeclaration *)parent; return NULL; } void Dsymbol::defineRef(Dsymbol *s) { assert(0); } int Dsymbol::isExport() { return FALSE; } int Dsymbol::isImportedSymbol() { return FALSE; } int Dsymbol::isDeprecated() { return FALSE; } int Dsymbol::isOverloadable() { return 0; } LabelDsymbol *Dsymbol::isLabel() // is this a LabelDsymbol()? { return NULL; } AggregateDeclaration *Dsymbol::isMember() // is this a member of an AggregateDeclaration? { //printf("Dsymbol::isMember() %s\n", toChars()); Dsymbol *parent = toParent(); //printf("parent is %s %s\n", parent->kind(), parent->toChars()); return parent ? parent->isAggregateDeclaration() : NULL; } Type *Dsymbol::getType() { return NULL; } int Dsymbol::needThis() { return FALSE; } int Dsymbol::addMember(Scope *sc, ScopeDsymbol *sd, int memnum) { //printf("Dsymbol::addMember('%s')\n", toChars()); //printf("Dsymbol::addMember(this = %p, '%s' scopesym = '%s')\n", this, toChars(), sd->toChars()); //printf("Dsymbol::addMember(this = %p, '%s' sd = %p, sd->symtab = %p)\n", this, toChars(), sd, sd->symtab); parent = sd; if (!isAnonymous()) // no name, so can't add it to symbol table { if (!sd->symtab->insert(this)) // if name is already defined { Dsymbol *s2; s2 = sd->symtab->lookup(ident); if (!s2->overloadInsert(this)) { sd->multiplyDefined(0, this, s2); } } if (sd->isAggregateDeclaration() || sd->isEnumDeclaration()) { if (ident == Id::__sizeof || ident == Id::alignof || ident == Id::mangleof) error(".%s property cannot be redefined", ident->toChars()); } return 1; } return 0; } void Dsymbol::error(const char *format, ...) { //printf("Dsymbol::error()\n"); if (!global.gag) { char *p = locToChars(); if (*p) fprintf(stdmsg, "%s: ", p); mem.free(p); fprintf(stdmsg, "Error: "); if (isAnonymous()) fprintf(stdmsg, "%s ", kind()); else fprintf(stdmsg, "%s %s ", kind(), toPrettyChars()); va_list ap; va_start(ap, format); vfprintf(stdmsg, format, ap); va_end(ap); fprintf(stdmsg, "\n"); fflush(stdmsg); } global.errors++; //fatal(); } void Dsymbol::error(Loc loc, const char *format, ...) { if (!global.gag) { char *p = loc.toChars(); if (!*p) p = locToChars(); if (*p) fprintf(stdmsg, "%s: ", p); mem.free(p); fprintf(stdmsg, "Error: "); fprintf(stdmsg, "%s %s ", kind(), toPrettyChars()); va_list ap; va_start(ap, format); vfprintf(stdmsg, format, ap); va_end(ap); fprintf(stdmsg, "\n"); fflush(stdmsg); } global.errors++; //fatal(); } void Dsymbol::checkDeprecated(Loc loc, Scope *sc) { if (!global.params.useDeprecated && isDeprecated()) { // Don't complain if we're inside a deprecated symbol's scope for (Dsymbol *sp = sc->parent; sp; sp = sp->parent) { if (sp->isDeprecated()) return; } for (; sc; sc = sc->enclosing) { if (sc->scopesym && sc->scopesym->isDeprecated()) return; // If inside a StorageClassDeclaration that is deprecated if (sc->stc & STCdeprecated) return; } error(loc, "is deprecated"); } } /********************************** * Determine which Module a Dsymbol is in. */ Module *Dsymbol::getModule() { Module *m; Dsymbol *s; //printf("Dsymbol::getModule()\n"); s = this; while (s) { //printf("\ts = '%s'\n", s->toChars()); m = s->isModule(); if (m) return m; s = s->parent; } return NULL; } /************************************* */ enum PROT Dsymbol::prot() { return PROTpublic; } /************************************* * Do syntax copy of an array of Dsymbol's. */ Array *Dsymbol::arraySyntaxCopy(Array *a) { Array *b = NULL; if (a) { b = a->copy(); for (int i = 0; i < b->dim; i++) { Dsymbol *s = (Dsymbol *)b->data[i]; s = s->syntaxCopy(NULL); b->data[i] = (void *)s; } } return b; } /**************************************** * Add documentation comment to Dsymbol. * Ignore NULL comments. */ void Dsymbol::addComment(unsigned char *comment) { //if (comment) //printf("adding comment '%s' to symbol %p '%s'\n", comment, this, toChars()); if (!this->comment) this->comment = comment; #if 1 else if (comment && strcmp((char *)comment, (char *)this->comment)) { // Concatenate the two this->comment = Lexer::combineComments(this->comment, comment); } #endif } /********************************* OverloadSet ****************************/ OverloadSet::OverloadSet() : Dsymbol() { } void OverloadSet::push(Dsymbol *s) { a.push(s); } const char *OverloadSet::kind() { return "overloadset"; } /********************************* ScopeDsymbol ****************************/ ScopeDsymbol::ScopeDsymbol() : Dsymbol() { members = NULL; symtab = NULL; imports = NULL; prots = NULL; } ScopeDsymbol::ScopeDsymbol(Identifier *id) : Dsymbol(id) { members = NULL; symtab = NULL; imports = NULL; prots = NULL; } Dsymbol *ScopeDsymbol::syntaxCopy(Dsymbol *s) { //printf("ScopeDsymbol::syntaxCopy('%s')\n", toChars()); ScopeDsymbol *sd; if (s) sd = (ScopeDsymbol *)s; else sd = new ScopeDsymbol(ident); sd->members = arraySyntaxCopy(members); return sd; } Dsymbol *ScopeDsymbol::search(Loc loc, Identifier *ident, int flags) { //printf("%s->ScopeDsymbol::search(ident='%s', flags=x%x)\n", toChars(), ident->toChars(), flags); // Look in symbols declared in this module Dsymbol *s = symtab ? symtab->lookup(ident) : NULL; // hide private nonlocal symbols if (flags & 1 && s && s->prot() == PROTprivate) s = NULL; if (s) { //printf("\ts = '%s.%s'\n",toChars(),s->toChars()); } else if (imports) { OverloadSet *a = NULL; // Look in imported modules for (int i = 0; i < imports->dim; i++) { ScopeDsymbol *ss = (ScopeDsymbol *)imports->data[i]; Dsymbol *s2; // If private import, don't search it if (flags & 1 && prots[i] == PROTprivate) continue; //printf("\tscanning import '%s', prots = %d, isModule = %p, isImport = %p\n", ss->toChars(), prots[i], ss->isModule(), ss->isImport()); /* Don't find private members if ss is a module */ s2 = ss->search(loc, ident, ss->isModule() ? 1 : 0); if (!s) s = s2; else if (s2 && s != s2) { if (s->toAlias() == s2->toAlias()) { /* After following aliases, we found the same symbol, * so it's not an ambiguity. * But if one alias is deprecated, prefer the other. */ if (s->isDeprecated()) s = s2; } else { /* Two imports of the same module should be regarded as * the same. */ Import *i1 = s->isImport(); Import *i2 = s2->isImport(); if (!(i1 && i2 && (i1->mod == i2->mod || (!i1->parent->isImport() && !i2->parent->isImport() && i1->ident->equals(i2->ident)) ) ) ) { /* If both s2 and s are overloadable (though we only * need to check s once) */ if (s2->isOverloadable() && (a || s->isOverloadable())) { if (!a) a = new OverloadSet(); /* Don't add to a[] if s2 is alias of previous sym */ for (int j = 0; j < a->a.dim; j++) { Dsymbol *s3 = (Dsymbol *)a->a.data[j]; if (s2->toAlias() == s3->toAlias()) { if (s3->isDeprecated()) a->a.data[j] = (void *)s2; goto Lcontinue; } } a->push(s2); Lcontinue: continue; } if (flags & 4) // if return NULL on ambiguity return NULL; if (!(flags & 2)) ss->multiplyDefined(loc, s, s2); break; } } } } /* Build special symbol if we had multiple finds */ if (a) { assert(s); a->push(s); s = a; } if (s) { Declaration *d = s->isDeclaration(); if (d && d->protection == PROTprivate && !d->parent->isTemplateMixin() && !(flags & 2)) error("%s is private", d->toPrettyChars()); } } return s; } void ScopeDsymbol::importScope(ScopeDsymbol *s, enum PROT protection) { //printf("%s->ScopeDsymbol::importScope(%s, %d)\n", toChars(), s->toChars(), protection); // No circular or redundant import's if (s != this) { if (!imports) imports = new Array(); else { for (int i = 0; i < imports->dim; i++) { ScopeDsymbol *ss; ss = (ScopeDsymbol *) imports->data[i]; if (ss == s) { if (protection > prots[i]) prots[i] = protection; // upgrade access return; } } } imports->push(s); prots = (unsigned char *)mem.realloc(prots, imports->dim * sizeof(prots[0])); prots[imports->dim - 1] = protection; } } int ScopeDsymbol::isforwardRef() { return (members == NULL); } void ScopeDsymbol::defineRef(Dsymbol *s) { ScopeDsymbol *ss; ss = s->isScopeDsymbol(); members = ss->members; ss->members = NULL; } void ScopeDsymbol::multiplyDefined(Loc loc, Dsymbol *s1, Dsymbol *s2) { #if 0 printf("ScopeDsymbol::multiplyDefined()\n"); printf("s1 = %p, '%s' kind = '%s', parent = %s\n", s1, s1->toChars(), s1->kind(), s1->parent ? s1->parent->toChars() : ""); printf("s2 = %p, '%s' kind = '%s', parent = %s\n", s2, s2->toChars(), s2->kind(), s2->parent ? s2->parent->toChars() : ""); #endif if (loc.filename) { ::error(loc, "%s at %s conflicts with %s at %s", s1->toPrettyChars(), s1->locToChars(), s2->toPrettyChars(), s2->locToChars()); } else { s1->error(loc, "conflicts with %s %s at %s", s2->kind(), s2->toPrettyChars(), s2->locToChars()); } halt(); } Dsymbol *ScopeDsymbol::nameCollision(Dsymbol *s) { Dsymbol *sprev; // Look to see if we are defining a forward referenced symbol sprev = symtab->lookup(s->ident); assert(sprev); if (s->equals(sprev)) // if the same symbol { if (s->isforwardRef()) // if second declaration is a forward reference return sprev; if (sprev->isforwardRef()) { sprev->defineRef(s); // copy data from s into sprev return sprev; } } multiplyDefined(0, s, sprev); return sprev; } const char *ScopeDsymbol::kind() { return "ScopeDsymbol"; } /*************************************** * Determine number of Dsymbols, folding in AttribDeclaration members. */ size_t ScopeDsymbol::dim(Array *members) { size_t n = 0; if (members) { for (size_t i = 0; i < members->dim; i++) { Dsymbol *s = (Dsymbol *)members->data[i]; AttribDeclaration *a = s->isAttribDeclaration(); if (a) { n += dim(a->decl); } else n++; } } return n; } /*************************************** * Get nth Dsymbol, folding in AttribDeclaration members. * Returns: * Dsymbol* nth Dsymbol * NULL not found, *pn gets incremented by the number * of Dsymbols */ Dsymbol *ScopeDsymbol::getNth(Array *members, size_t nth, size_t *pn) { if (!members) return NULL; size_t n = 0; for (size_t i = 0; i < members->dim; i++) { Dsymbol *s = (Dsymbol *)members->data[i]; AttribDeclaration *a = s->isAttribDeclaration(); if (a) { s = getNth(a->decl, nth - n, &n); if (s) return s; } else if (n == nth) return s; else n++; } if (pn) *pn += n; return NULL; } /******************************************* * Look for member of the form: * const(MemberInfo)[] getMembers(string); * Returns NULL if not found */ #if DMDV2 FuncDeclaration *ScopeDsymbol::findGetMembers() { Dsymbol *s = search_function(this, Id::getmembers); FuncDeclaration *fdx = s ? s->isFuncDeclaration() : NULL; #if 0 // Finish static TypeFunction *tfgetmembers; if (!tfgetmembers) { Scope sc; Arguments *arguments = new Arguments; Arguments *arg = new Argument(STCin, Type::tchar->constOf()->arrayOf(), NULL, NULL); arguments->push(arg); Type *tret = NULL; tfgetmembers = new TypeFunction(arguments, tret, 0, LINKd); tfgetmembers = (TypeFunction *)tfgetmembers->semantic(0, &sc); } if (fdx) fdx = fdx->overloadExactMatch(tfgetmembers); #endif if (fdx && fdx->isVirtual()) fdx = NULL; return fdx; } #endif /****************************** WithScopeSymbol ******************************/ WithScopeSymbol::WithScopeSymbol(WithStatement *withstate) : ScopeDsymbol() { this->withstate = withstate; } Dsymbol *WithScopeSymbol::search(Loc loc, Identifier *ident, int flags) { // Acts as proxy to the with class declaration return withstate->exp->type->toDsymbol(NULL)->search(loc, ident, 0); } /****************************** ArrayScopeSymbol ******************************/ ArrayScopeSymbol::ArrayScopeSymbol(Scope *sc, Expression *e) : ScopeDsymbol() { assert(e->op == TOKindex || e->op == TOKslice); exp = e; type = NULL; td = NULL; this->sc = sc; } ArrayScopeSymbol::ArrayScopeSymbol(Scope *sc, TypeTuple *t) : ScopeDsymbol() { exp = NULL; type = t; td = NULL; this->sc = sc; } ArrayScopeSymbol::ArrayScopeSymbol(Scope *sc, TupleDeclaration *s) : ScopeDsymbol() { exp = NULL; type = NULL; td = s; this->sc = sc; } Dsymbol *ArrayScopeSymbol::search(Loc loc, Identifier *ident, int flags) { //printf("ArrayScopeSymbol::search('%s', flags = %d)\n", ident->toChars(), flags); if (ident == Id::length || ident == Id::dollar) { VarDeclaration **pvar; Expression *ce; L1: if (td) { VarDeclaration *v = new VarDeclaration(loc, Type::tsize_t, Id::dollar, NULL); Expression *e = new IntegerExp(0, td->objects->dim, Type::tsize_t); v->init = new ExpInitializer(0, e); v->storage_class |= STCstatic | STCconst; v->semantic(sc); return v; } if (type) { VarDeclaration *v = new VarDeclaration(loc, Type::tsize_t, Id::dollar, NULL); Expression *e = new IntegerExp(0, type->arguments->dim, Type::tsize_t); v->init = new ExpInitializer(0, e); v->storage_class |= STCstatic | STCconst; v->semantic(sc); return v; } if (exp->op == TOKindex) { IndexExp *ie = (IndexExp *)exp; pvar = &ie->lengthVar; ce = ie->e1; } else if (exp->op == TOKslice) { SliceExp *se = (SliceExp *)exp; pvar = &se->lengthVar; ce = se->e1; } else return NULL; if (ce->op == TOKtype) { Type *t = ((TypeExp *)ce)->type; if (t->ty == Ttuple) { type = (TypeTuple *)t; goto L1; } } if (!*pvar) { VarDeclaration *v = new VarDeclaration(loc, Type::tsize_t, Id::dollar, NULL); if (ce->op == TOKvar) { // if ce is const, get its initializer ce = fromConstInitializer(WANTvalue | WANTinterpret, ce); } if (ce->op == TOKstring) { /* It is for a string literal, so the * length will be a const. */ Expression *e = new IntegerExp(0, ((StringExp *)ce)->len, Type::tsize_t); v->init = new ExpInitializer(0, e); v->storage_class |= STCstatic | STCconst; } else if (ce->op == TOKarrayliteral) { /* It is for an array literal, so the * length will be a const. */ Expression *e = new IntegerExp(0, ((ArrayLiteralExp *)ce)->elements->dim, Type::tsize_t); v->init = new ExpInitializer(0, e); v->storage_class |= STCstatic | STCconst; } else if (ce->op == TOKtuple) { /* It is for an expression tuple, so the * length will be a const. */ Expression *e = new IntegerExp(0, ((TupleExp *)ce)->exps->dim, Type::tsize_t); v->init = new ExpInitializer(0, e); v->storage_class |= STCstatic | STCconst; } *pvar = v; } (*pvar)->semantic(sc); return (*pvar); } return NULL; } /****************************** DsymbolTable ******************************/ DsymbolTable::DsymbolTable() { tab = new StringTable; } DsymbolTable::~DsymbolTable() { delete tab; } Dsymbol *DsymbolTable::lookup(Identifier *ident) { StringValue *sv; #ifdef DEBUG assert(ident); assert(tab); #endif sv = tab->lookup((char*)ident->string, ident->len); return (Dsymbol *)(sv ? sv->ptrvalue : NULL); } Dsymbol *DsymbolTable::insert(Dsymbol *s) { StringValue *sv; Identifier *ident; //printf("DsymbolTable::insert(this = %p, '%s')\n", this, s->ident->toChars()); ident = s->ident; #ifdef DEBUG assert(ident); assert(tab); #endif sv = tab->insert(ident->toChars(), ident->len); if (!sv) return NULL; // already in table sv->ptrvalue = s; return s; } Dsymbol *DsymbolTable::insert(Identifier *ident, Dsymbol *s) { StringValue *sv; //printf("DsymbolTable::insert()\n"); sv = tab->insert(ident->toChars(), ident->len); if (!sv) return NULL; // already in table sv->ptrvalue = s; return s; } Dsymbol *DsymbolTable::update(Dsymbol *s) { StringValue *sv; Identifier *ident; ident = s->ident; sv = tab->update(ident->toChars(), ident->len); sv->ptrvalue = s; return s; }