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view gcc/d/dmd/denum.c @ 158:494b0b89df80 default tip
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| author | Shinji KONO <kono@ie.u-ryukyu.ac.jp> |
|---|---|
| date | Mon, 25 May 2020 18:13:55 +0900 |
| parents | 1830386684a0 |
| children |
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/* Compiler implementation of the D programming language * Copyright (C) 1999-2019 by The D Language Foundation, All Rights Reserved * written by Walter Bright * http://www.digitalmars.com * Distributed under the Boost Software License, Version 1.0. * http://www.boost.org/LICENSE_1_0.txt * https://github.com/D-Programming-Language/dmd/blob/master/src/enum.c */ #include "root/dsystem.h" #include "root/root.h" #include "errors.h" #include "enum.h" #include "mtype.h" #include "scope.h" #include "id.h" #include "expression.h" #include "module.h" #include "declaration.h" #include "init.h" Expression *semantic(Expression *e, Scope *sc); /********************************* EnumDeclaration ****************************/ EnumDeclaration::EnumDeclaration(Loc loc, Identifier *id, Type *memtype) : ScopeDsymbol(id) { //printf("EnumDeclaration() %s\n", toChars()); this->loc = loc; type = new TypeEnum(this); this->memtype = memtype; maxval = NULL; minval = NULL; defaultval = NULL; sinit = NULL; isdeprecated = false; protection = Prot(PROTundefined); parent = NULL; added = false; inuse = 0; } Dsymbol *EnumDeclaration::syntaxCopy(Dsymbol *s) { assert(!s); EnumDeclaration *ed = new EnumDeclaration(loc, ident, memtype ? memtype->syntaxCopy() : NULL); return ScopeDsymbol::syntaxCopy(ed); } void EnumDeclaration::setScope(Scope *sc) { if (semanticRun > PASSinit) return; ScopeDsymbol::setScope(sc); } void EnumDeclaration::addMember(Scope *sc, ScopeDsymbol *sds) { /* Anonymous enum members get added to enclosing scope. */ ScopeDsymbol *scopesym = isAnonymous() ? sds : this; if (!isAnonymous()) { ScopeDsymbol::addMember(sc, sds); if (!symtab) symtab = new DsymbolTable(); } if (members) { for (size_t i = 0; i < members->dim; i++) { EnumMember *em = (*members)[i]->isEnumMember(); em->ed = this; //printf("add %s to scope %s\n", em->toChars(), scopesym->toChars()); em->addMember(sc, isAnonymous() ? scopesym : this); } } added = true; } void EnumDeclaration::semantic(Scope *sc) { //printf("EnumDeclaration::semantic(sd = %p, '%s') %s\n", sc->scopesym, sc->scopesym->toChars(), toChars()); //printf("EnumDeclaration::semantic() %p %s\n", this, toChars()); if (semanticRun >= PASSsemanticdone) return; // semantic() already completed if (semanticRun == PASSsemantic) { assert(memtype); ::error(loc, "circular reference to enum base type %s", memtype->toChars()); errors = true; semanticRun = PASSsemanticdone; return; } unsigned dprogress_save = Module::dprogress; Scope *scx = NULL; if (_scope) { sc = _scope; scx = _scope; // save so we don't make redundant copies _scope = NULL; } if (!sc) return; parent = sc->parent; type = type->semantic(loc, sc); protection = sc->protection; if (sc->stc & STCdeprecated) isdeprecated = true; userAttribDecl = sc->userAttribDecl; semanticRun = PASSsemantic; if (!members && !memtype) // enum ident; { semanticRun = PASSsemanticdone; return; } if (!symtab) symtab = new DsymbolTable(); /* The separate, and distinct, cases are: * 1. enum { ... } * 2. enum : memtype { ... } * 3. enum ident { ... } * 4. enum ident : memtype { ... } * 5. enum ident : memtype; * 6. enum ident; */ if (memtype) { memtype = memtype->semantic(loc, sc); /* Check to see if memtype is forward referenced */ if (memtype->ty == Tenum) { EnumDeclaration *sym = (EnumDeclaration *)memtype->toDsymbol(sc); if (!sym->memtype || !sym->members || !sym->symtab || sym->_scope) { // memtype is forward referenced, so try again later _scope = scx ? scx : sc->copy(); _scope->setNoFree(); _scope->_module->addDeferredSemantic(this); Module::dprogress = dprogress_save; //printf("\tdeferring %s\n", toChars()); semanticRun = PASSinit; return; } } if (memtype->ty == Tvoid) { error("base type must not be void"); memtype = Type::terror; } if (memtype->ty == Terror) { errors = true; if (members) { for (size_t i = 0; i < members->dim; i++) { Dsymbol *s = (*members)[i]; s->errors = true; // poison all the members } } semanticRun = PASSsemanticdone; return; } } semanticRun = PASSsemanticdone; if (!members) // enum ident : memtype; return; if (members->dim == 0) { error("enum %s must have at least one member", toChars()); errors = true; return; } Module::dprogress++; Scope *sce; if (isAnonymous()) sce = sc; else { sce = sc->push(this); sce->parent = this; } sce = sce->startCTFE(); sce->setNoFree(); // needed for getMaxMinValue() /* Each enum member gets the sce scope */ for (size_t i = 0; i < members->dim; i++) { EnumMember *em = (*members)[i]->isEnumMember(); if (em) em->_scope = sce; } if (!added) { /* addMember() is not called when the EnumDeclaration appears as a function statement, * so we have to do what addMember() does and install the enum members in the right symbol * table */ ScopeDsymbol *scopesym = NULL; if (isAnonymous()) { /* Anonymous enum members get added to enclosing scope. */ for (Scope *sct = sce; 1; sct = sct->enclosing) { assert(sct); if (sct->scopesym) { scopesym = sct->scopesym; if (!sct->scopesym->symtab) sct->scopesym->symtab = new DsymbolTable(); break; } } } else { // Otherwise enum members are in the EnumDeclaration's symbol table scopesym = this; } for (size_t i = 0; i < members->dim; i++) { EnumMember *em = (*members)[i]->isEnumMember(); if (em) { em->ed = this; em->addMember(sc, scopesym); } } } for (size_t i = 0; i < members->dim; i++) { EnumMember *em = (*members)[i]->isEnumMember(); if (em) em->semantic(em->_scope); } //printf("defaultval = %lld\n", defaultval); //if (defaultval) printf("defaultval: %s %s\n", defaultval->toChars(), defaultval->type->toChars()); //printf("members = %s\n", members->toChars()); } /****************************** * Get the value of the .max/.min property as an Expression * Input: * id Id::max or Id::min */ Expression *EnumDeclaration::getMaxMinValue(Loc loc, Identifier *id) { //printf("EnumDeclaration::getMaxValue()\n"); bool first = true; Expression **pval = (id == Id::max) ? &maxval : &minval; if (inuse) { error(loc, "recursive definition of .%s property", id->toChars()); goto Lerrors; } if (*pval) goto Ldone; if (_scope) semantic(_scope); if (errors) goto Lerrors; if (semanticRun == PASSinit || !members) { if (isSpecial()) { /* Allow these special enums to not need a member list */ return memtype->getProperty(loc, id, 0); } error("is forward referenced looking for .%s", id->toChars()); goto Lerrors; } if (!(memtype && memtype->isintegral())) { error(loc, "has no .%s property because base type %s is not an integral type", id->toChars(), memtype ? memtype->toChars() : ""); goto Lerrors; } for (size_t i = 0; i < members->dim; i++) { EnumMember *em = (*members)[i]->isEnumMember(); if (!em) continue; if (em->errors) goto Lerrors; Expression *e = em->value(); if (first) { *pval = e; first = false; } else { /* In order to work successfully with UDTs, * build expressions to do the comparisons, * and let the semantic analyzer and constant * folder give us the result. */ /* Compute: * if (e > maxval) * maxval = e; */ Expression *ec = new CmpExp(id == Id::max ? TOKgt : TOKlt, em->loc, e, *pval); inuse++; ec = ::semantic(ec, em->_scope); inuse--; ec = ec->ctfeInterpret(); if (ec->toInteger()) *pval = e; } } Ldone: { Expression *e = *pval; if (e->op != TOKerror) { e = e->copy(); e->loc = loc; } return e; } Lerrors: *pval = new ErrorExp(); return *pval; } /**************** * Determine if enum is a 'special' one. * Returns: * true if special */ bool EnumDeclaration::isSpecial() const { return (ident == Id::__c_long || ident == Id::__c_ulong || ident == Id::__c_longlong || ident == Id::__c_ulonglong || ident == Id::__c_long_double) && memtype; } Expression *EnumDeclaration::getDefaultValue(Loc loc) { //printf("EnumDeclaration::getDefaultValue() %p %s\n", this, toChars()); if (defaultval) return defaultval; if (_scope) semantic(_scope); if (errors) goto Lerrors; if (semanticRun == PASSinit || !members) { if (isSpecial()) { /* Allow these special enums to not need a member list */ return memtype->defaultInit(loc); } error(loc, "forward reference of %s.init", toChars()); goto Lerrors; } for (size_t i = 0; i < members->dim; i++) { EnumMember *em = (*members)[i]->isEnumMember(); if (em) { defaultval = em->value(); return defaultval; } } Lerrors: defaultval = new ErrorExp(); return defaultval; } Type *EnumDeclaration::getMemtype(Loc loc) { if (loc.linnum == 0) loc = this->loc; if (_scope) { /* Enum is forward referenced. We don't need to resolve the whole thing, * just the base type */ if (memtype) memtype = memtype->semantic(loc, _scope); else { if (!isAnonymous() && members) memtype = Type::tint32; } } if (!memtype) { if (!isAnonymous() && members) memtype = Type::tint32; else { error(loc, "is forward referenced looking for base type"); return Type::terror; } } return memtype; } bool EnumDeclaration::oneMember(Dsymbol **ps, Identifier *ident) { if (isAnonymous()) return Dsymbol::oneMembers(members, ps, ident); return Dsymbol::oneMember(ps, ident); } Type *EnumDeclaration::getType() { return type; } const char *EnumDeclaration::kind() const { return "enum"; } bool EnumDeclaration::isDeprecated() { return isdeprecated; } Prot EnumDeclaration::prot() { return protection; } Dsymbol *EnumDeclaration::search(const Loc &loc, Identifier *ident, int flags) { //printf("%s.EnumDeclaration::search('%s')\n", toChars(), ident->toChars()); if (_scope) { // Try one last time to resolve this enum semantic(_scope); } if (!members || !symtab || _scope) { error("is forward referenced when looking for '%s'", ident->toChars()); //*(char*)0=0; return NULL; } Dsymbol *s = ScopeDsymbol::search(loc, ident, flags); return s; } /********************************* EnumMember ****************************/ EnumMember::EnumMember(Loc loc, Identifier *id, Expression *value, Type *origType) : VarDeclaration(loc, NULL, id ? id : Id::empty, new ExpInitializer(loc, value)) { this->ed = NULL; this->origValue = value; this->origType = origType; } Expression *&EnumMember::value() { return ((ExpInitializer*)_init)->exp; } Dsymbol *EnumMember::syntaxCopy(Dsymbol *s) { assert(!s); return new EnumMember(loc, ident, value() ? value()->syntaxCopy() : NULL, origType ? origType->syntaxCopy() : NULL); } const char *EnumMember::kind() const { return "enum member"; } void EnumMember::semantic(Scope *sc) { //printf("EnumMember::semantic() %s\n", toChars()); if (errors || semanticRun >= PASSsemanticdone) return; if (semanticRun == PASSsemantic) { error("circular reference to enum member"); Lerrors: errors = true; semanticRun = PASSsemanticdone; return; } assert(ed); ed->semantic(sc); if (ed->errors) goto Lerrors; if (errors || semanticRun >= PASSsemanticdone) return; if (_scope) sc = _scope; if (!sc) return; semanticRun = PASSsemantic; protection = ed->isAnonymous() ? ed->protection : Prot(PROTpublic); linkage = LINKd; storage_class = STCmanifest; userAttribDecl = ed->isAnonymous() ? ed->userAttribDecl : NULL; // The first enum member is special bool first = (this == (*ed->members)[0]); if (origType) { origType = origType->semantic(loc, sc); type = origType; assert(value()); // "type id;" is not a valid enum member declaration } if (value()) { Expression *e = value(); assert(e->dyncast() == DYNCAST_EXPRESSION); e = ::semantic(e, sc); e = resolveProperties(sc, e); e = e->ctfeInterpret(); if (e->op == TOKerror) goto Lerrors; if (first && !ed->memtype && !ed->isAnonymous()) { ed->memtype = e->type; if (ed->memtype->ty == Terror) { ed->errors = true; goto Lerrors; } if (ed->memtype->ty != Terror) { /* Bugzilla 11746: All of named enum members should have same type * with the first member. If the following members were referenced * during the first member semantic, their types should be unified. */ for (size_t i = 0; i < ed->members->dim; i++) { EnumMember *em = (*ed->members)[i]->isEnumMember(); if (!em || em == this || em->semanticRun < PASSsemanticdone || em->origType) continue; //printf("[%d] em = %s, em->semanticRun = %d\n", i, toChars(), em->semanticRun); Expression *ev = em->value(); ev = ev->implicitCastTo(sc, ed->memtype); ev = ev->ctfeInterpret(); ev = ev->castTo(sc, ed->type); if (ev->op == TOKerror) ed->errors = true; em->value() = ev; } if (ed->errors) { ed->memtype = Type::terror; goto Lerrors; } } } if (ed->memtype && !origType) { e = e->implicitCastTo(sc, ed->memtype); e = e->ctfeInterpret(); // save origValue for better json output origValue = e; if (!ed->isAnonymous()) { e = e->castTo(sc, ed->type); e = e->ctfeInterpret(); } } else if (origType) { e = e->implicitCastTo(sc, origType); e = e->ctfeInterpret(); assert(ed->isAnonymous()); // save origValue for better json output origValue = e; } value() = e; } else if (first) { Type *t; if (ed->memtype) t = ed->memtype; else { t = Type::tint32; if (!ed->isAnonymous()) ed->memtype = t; } Expression *e = new IntegerExp(loc, 0, Type::tint32); e = e->implicitCastTo(sc, t); e = e->ctfeInterpret(); // save origValue for better json output origValue = e; if (!ed->isAnonymous()) { e = e->castTo(sc, ed->type); e = e->ctfeInterpret(); } value() = e; } else { /* Find the previous enum member, * and set this to be the previous value + 1 */ EnumMember *emprev = NULL; for (size_t i = 0; i < ed->members->dim; i++) { EnumMember *em = (*ed->members)[i]->isEnumMember(); if (em) { if (em == this) break; emprev = em; } } assert(emprev); if (emprev->semanticRun < PASSsemanticdone) // if forward reference emprev->semantic(emprev->_scope); // resolve it if (emprev->errors) goto Lerrors; Expression *eprev = emprev->value(); Type *tprev = eprev->type->equals(ed->type) ? ed->memtype : eprev->type; Expression *emax = tprev->getProperty(ed->loc, Id::max, 0); emax = ::semantic(emax, sc); emax = emax->ctfeInterpret(); // Set value to (eprev + 1). // But first check that (eprev != emax) assert(eprev); Expression *e = new EqualExp(TOKequal, loc, eprev, emax); e = ::semantic(e, sc); e = e->ctfeInterpret(); if (e->toInteger()) { error("initialization with (%s.%s + 1) causes overflow for type '%s'", emprev->ed->toChars(), emprev->toChars(), ed->type->toBasetype()->toChars()); goto Lerrors; } // Now set e to (eprev + 1) e = new AddExp(loc, eprev, new IntegerExp(loc, 1, Type::tint32)); e = ::semantic(e, sc); e = e->castTo(sc, eprev->type); e = e->ctfeInterpret(); // save origValue (without cast) for better json output if (e->op != TOKerror) // avoid duplicate diagnostics { assert(emprev->origValue); origValue = new AddExp(loc, emprev->origValue, new IntegerExp(loc, 1, Type::tint32)); origValue = ::semantic(origValue, sc); origValue = origValue->ctfeInterpret(); } if (e->op == TOKerror) goto Lerrors; if (e->type->isfloating()) { // Check that e != eprev (not always true for floats) Expression *etest = new EqualExp(TOKequal, loc, e, eprev); etest = ::semantic(etest, sc); etest = etest->ctfeInterpret(); if (etest->toInteger()) { error("has inexact value, due to loss of precision"); goto Lerrors; } } value() = e; } if (!origType) type = value()->type; assert(origValue); semanticRun = PASSsemanticdone; } Expression *EnumMember::getVarExp(Loc loc, Scope *sc) { semantic(sc); if (errors) return new ErrorExp(); Expression *e = new VarExp(loc, this); return ::semantic(e, sc); }