Ejemplo n.º 1
0
Archivo: module.c Proyecto: smunix/ldc
void Module::importAll(Scope *prevsc)
{
    //printf("+Module::importAll(this = %p, '%s'): parent = %p\n", this, toChars(), parent);

    if (scope)
        return;                 // already done

    /* Note that modules get their own scope, from scratch.
     * This is so regardless of where in the syntax a module
     * gets imported, it is unaffected by context.
     * Ignore prevsc.
     */
    Scope *sc = Scope::createGlobal(this);      // create root scope

    // Add import of "object" if this module isn't "object"
    if (ident != Id::object)
    {
        if (members->dim == 0 || ((Dsymbol *)members->data[0])->ident != Id::object)
        {
            Import *im = new Import(0, NULL, Id::object, NULL, 0);
            members->shift(im);
        }
    }

    if (!symtab)
    {
        // Add all symbols into module's symbol table
        symtab = new DsymbolTable();
        for (int i = 0; i < members->dim; i++)
        {
            Dsymbol *s = (Dsymbol *)members->data[i];
            s->addMember(NULL, sc->scopesym, 1);
        }
    }
    // anything else should be run after addMember, so version/debug symbols are defined

    /* Set scope for the symbols so that if we forward reference
     * a symbol, it can possibly be resolved on the spot.
     * If this works out well, it can be extended to all modules
     * before any semantic() on any of them.
     */
    setScope(sc);               // remember module scope for semantic
    for (int i = 0; i < members->dim; i++)
    {   Dsymbol *s = (Dsymbol *)members->data[i];
        s->setScope(sc);
    }

    for (int i = 0; i < members->dim; i++)
    {
        Dsymbol *s = (Dsymbol *)members->data[i];
        s->importAll(sc);
    }

    sc = sc->pop();
    sc->pop();          // 2 pops because Scope::createGlobal() created 2
}
Ejemplo n.º 2
0
Archivo: attrib.c Proyecto: smunix/ldc
void ConditionalDeclaration::importAll(Scope *sc)
{
    Array *d = include(sc, NULL);

    //printf("\tConditionalDeclaration::importAll '%s', d = %p\n",toChars(), d);
    if (d)
    {
       for (unsigned i = 0; i < d->dim; i++)
       {
           Dsymbol *s = (Dsymbol *)d->data[i];

           s->importAll(sc);
       }
    }
}
Ejemplo n.º 3
0
void ConditionalDeclaration::importAll(Scope *sc)
{
    Dsymbols *d = include(sc, NULL);

    //printf("\tConditionalDeclaration::importAll '%s', d = %p\n",toChars(), d);
    if (d)
    {
       for (size_t i = 0; i < d->dim; i++)
       {
           Dsymbol *s = (*d)[i];

           s->importAll(sc);
       }
    }
}
Ejemplo n.º 4
0
void AttribDeclaration::importAll(Scope *sc)
{
    Dsymbols *d = include(sc, NULL);

    //printf("\tAttribDeclaration::importAll '%s', d = %p\n", toChars(), d);
    if (d)
    {
        Scope *sc2 = newScope(sc);

        for (size_t i = 0; i < d->dim; i++)
        {
            Dsymbol *s = (*d)[i];
            s->importAll(sc2);
        }

        if (sc2 != sc)
            sc2->pop();
    }
}
Ejemplo n.º 5
0
void ProtDeclaration::importAll(Scope *sc)
{
    Scope *newsc = sc;
    if (sc->protection != protection ||
       sc->explicitProtection != 1)
    {
       // create new one for changes
       newsc = new Scope(*sc);
       newsc->flags &= ~SCOPEfree;
       newsc->protection = protection;
       newsc->explicitProtection = 1;
    }

    for (size_t i = 0; i < decl->dim; i++)
    {
       Dsymbol *s = (*decl)[i];
       s->importAll(newsc);
    }

    if (newsc != sc)
       newsc->pop();
}
Ejemplo n.º 6
0
void Nspace::semantic(Scope *sc)
{
    if (semanticRun != PASSinit)
        return;
    if (_scope)
    {
        sc = _scope;
        _scope = NULL;
    }
    if (!sc)
        return;

    semanticRun = PASSsemantic;
    parent = sc->parent;
    if (members)
    {
        assert(sc);
        sc = sc->push(this);
        sc->linkage = LINKcpp;          // note that namespaces imply C++ linkage
        sc->parent = this;

        for (size_t i = 0; i < members->dim; i++)
        {
            Dsymbol *s = (*members)[i];
            s->importAll(sc);
        }

        for (size_t i = 0; i < members->dim; i++)
        {
            Dsymbol *s = (*members)[i];
            s->semantic(sc);
        }
        sc->pop();
    }
    semanticRun = PASSsemanticdone;
}
Ejemplo n.º 7
0
void ClassDeclaration::semantic(Scope *sc)
{
    //printf("ClassDeclaration::semantic(%s), type = %p, sizeok = %d, this = %p\n", toChars(), type, sizeok, this);
    //printf("\tparent = %p, '%s'\n", sc->parent, sc->parent ? sc->parent->toChars() : "");
    //printf("sc->stc = %x\n", sc->stc);

    //{ static int n;  if (++n == 20) *(char*)0=0; }

    if (!ident)         // if anonymous class
    {   const char *id = "__anonclass";

        ident = Identifier::generateId(id);
    }

    if (!sc)
        sc = scope;
    if (!parent && sc->parent && !sc->parent->isModule())
        parent = sc->parent;

    type = type->semantic(loc, sc);

    if (type->ty == Tclass && ((TypeClass *)type)->sym != this)
    {
        TemplateInstance *ti = ((TypeClass *)type)->sym->isInstantiated();
        if (ti && ti->errors)
            ((TypeClass *)type)->sym = this;
    }

    if (!members)               // if opaque declaration
    {   //printf("\tclass '%s' is forward referenced\n", toChars());
        return;
    }
    if (symtab)
    {   if (sizeok == SIZEOKdone || !scope)
        {   //printf("\tsemantic for '%s' is already completed\n", toChars());
            return;             // semantic() already completed
        }
    }
    else
        symtab = new DsymbolTable();

    Scope *scx = NULL;
    if (scope)
    {
        sc = scope;
        scx = scope;            // save so we don't make redundant copies
        scope = NULL;
    }
    unsigned dprogress_save = Module::dprogress;
    int errors = global.errors;

    if (sc->stc & STCdeprecated)
    {
        isdeprecated = true;
    }
    userAttribDecl = sc->userAttribDecl;

    if (sc->linkage == LINKcpp)
        cpp = 1;

    // Expand any tuples in baseclasses[]
    for (size_t i = 0; i < baseclasses->dim; )
    {
        // Ungag errors when not speculative
        Ungag ungag = ungagSpeculative();

        BaseClass *b = (*baseclasses)[i];
        b->type = b->type->semantic(loc, sc);

        Type *tb = b->type->toBasetype();
        if (tb->ty == Ttuple)
        {   TypeTuple *tup = (TypeTuple *)tb;
            PROT protection = b->protection;
            baseclasses->remove(i);
            size_t dim = Parameter::dim(tup->arguments);
            for (size_t j = 0; j < dim; j++)
            {   Parameter *arg = Parameter::getNth(tup->arguments, j);
                b = new BaseClass(arg->type, protection);
                baseclasses->insert(i + j, b);
            }
        }
        else
            i++;
    }

    // See if there's a base class as first in baseclasses[]
    if (baseclasses->dim)
    {
        // Ungag errors when not speculative
        Ungag ungag = ungagSpeculative();

        BaseClass *b = (*baseclasses)[0];
        //b->type = b->type->semantic(loc, sc);

        Type *tb = b->type->toBasetype();
        if (tb->ty != Tclass)
        {
            if (b->type != Type::terror)
                error("base type must be class or interface, not %s", b->type->toChars());
            baseclasses->remove(0);
        }
        else
        {
            TypeClass *tc = (TypeClass *)(tb);

            if (tc->sym->isDeprecated())
            {
                if (!isDeprecated())
                {
                    // Deriving from deprecated class makes this one deprecated too
                    isdeprecated = true;

                    tc->checkDeprecated(loc, sc);
                }
            }

            if (tc->sym->isInterfaceDeclaration())
                ;
            else
            {
                for (ClassDeclaration *cdb = tc->sym; cdb; cdb = cdb->baseClass)
                {
                    if (cdb == this)
                    {
                        error("circular inheritance");
                        baseclasses->remove(0);
                        goto L7;
                    }
                }
                if (tc->sym->scope)
                {
                    // Try to resolve forward reference
                    tc->sym->semantic(NULL);
                }

                if (tc->sym->symtab && tc->sym->scope == NULL)
                {
                    /* Bugzilla 11034: Essentailly, class inheritance hierarchy
                     * and instance size of each classes are orthogonal information.
                     * Therefore, even if tc->sym->sizeof == SIZEOKnone,
                     * we need to set baseClass field for class covariance check.
                     */
                    baseClass = tc->sym;
                    b->base = baseClass;
                }
                if (!tc->sym->symtab || tc->sym->scope || tc->sym->sizeok == SIZEOKnone)
                {
                    //printf("%s: forward reference of base class %s\n", toChars(), tc->sym->toChars());
                    //error("forward reference of base class %s", baseClass->toChars());
                    // Forward reference of base class, try again later
                    //printf("\ttry later, forward reference of base class %s\n", tc->sym->toChars());
                    scope = scx ? scx : sc->copy();
                    scope->setNoFree();
                    if (tc->sym->scope)
                        tc->sym->scope->module->addDeferredSemantic(tc->sym);
                    scope->module->addDeferredSemantic(this);
                    return;
                }
             L7: ;
            }
        }
    }

    // Treat the remaining entries in baseclasses as interfaces
    // Check for errors, handle forward references
    for (size_t i = (baseClass ? 1 : 0); i < baseclasses->dim; )
    {
        // Ungag errors when not speculative
        Ungag ungag = ungagSpeculative();

        BaseClass *b = (*baseclasses)[i];
        b->type = b->type->semantic(loc, sc);

        Type *tb = b->type->toBasetype();
        TypeClass *tc = (tb->ty == Tclass) ? (TypeClass *)tb : NULL;
        if (!tc || !tc->sym->isInterfaceDeclaration())
        {
            if (b->type != Type::terror)
                error("base type must be interface, not %s", b->type->toChars());
            baseclasses->remove(i);
            continue;
        }
        else
        {
            if (tc->sym->isDeprecated())
            {
                if (!isDeprecated())
                {
                    // Deriving from deprecated class makes this one deprecated too
                    isdeprecated = true;

                    tc->checkDeprecated(loc, sc);
                }
            }

            // Check for duplicate interfaces
            for (size_t j = (baseClass ? 1 : 0); j < i; j++)
            {
                BaseClass *b2 = (*baseclasses)[j];
                if (b2->base == tc->sym)
                    error("inherits from duplicate interface %s", b2->base->toChars());
            }

            if (tc->sym->scope)
            {
                // Try to resolve forward reference
                tc->sym->semantic(NULL);
            }

            b->base = tc->sym;
            if (!b->base->symtab || b->base->scope)
            {
                //error("forward reference of base class %s", baseClass->toChars());
                // Forward reference of base, try again later
                //printf("\ttry later, forward reference of base %s\n", baseClass->toChars());
                scope = scx ? scx : sc->copy();
                scope->setNoFree();
                if (tc->sym->scope)
                    tc->sym->scope->module->addDeferredSemantic(tc->sym);
                scope->module->addDeferredSemantic(this);
                return;
            }
        }
        i++;
    }
    if (doAncestorsSemantic == SemanticIn)
        doAncestorsSemantic = SemanticDone;


    if (sizeok == SIZEOKnone)
    {
        // If no base class, and this is not an Object, use Object as base class
        if (!baseClass && ident != Id::Object && !cpp)
        {
            if (!object)
            {
                error("missing or corrupt object.d");
                fatal();
            }

            Type *t = object->type;
            t = t->semantic(loc, sc)->toBasetype();
            assert(t->ty == Tclass);
            TypeClass *tc = (TypeClass *)t;

            BaseClass *b = new BaseClass(tc, PROTpublic);
            baseclasses->shift(b);

            baseClass = tc->sym;
            assert(!baseClass->isInterfaceDeclaration());
            b->base = baseClass;
        }

        interfaces_dim = baseclasses->dim;
        interfaces = baseclasses->tdata();

        if (baseClass)
        {
            if (baseClass->storage_class & STCfinal)
                error("cannot inherit from final class %s", baseClass->toChars());

            interfaces_dim--;
            interfaces++;

            // Copy vtbl[] from base class
            vtbl.setDim(baseClass->vtbl.dim);
            memcpy(vtbl.tdata(), baseClass->vtbl.tdata(), sizeof(void *) * vtbl.dim);

            // Inherit properties from base class
            com = baseClass->isCOMclass();
            if (baseClass->isCPPclass())
                cpp = 1;
            isscope = baseClass->isscope;
            vthis = baseClass->vthis;
            enclosing = baseClass->enclosing;
            storage_class |= baseClass->storage_class & STC_TYPECTOR;
        }
        else
        {
            // No base class, so this is the root of the class hierarchy
            vtbl.setDim(0);
            if (vtblOffset())
                vtbl.push(this);            // leave room for classinfo as first member
        }

        protection = sc->protection;
        storage_class |= sc->stc;

        interfaceSemantic(sc);

        for (size_t i = 0; i < members->dim; i++)
        {
            Dsymbol *s = (*members)[i];
            s->addMember(sc, this, 1);
        }

        /* If this is a nested class, add the hidden 'this'
         * member which is a pointer to the enclosing scope.
         */
        if (vthis)              // if inheriting from nested class
        {
            // Use the base class's 'this' member
            if (storage_class & STCstatic)
                error("static class cannot inherit from nested class %s", baseClass->toChars());
            if (toParent2() != baseClass->toParent2() &&
                (!toParent2() ||
                 !baseClass->toParent2()->getType() ||
                 !baseClass->toParent2()->getType()->isBaseOf(toParent2()->getType(), NULL)))
            {
                if (toParent2())
                {
                    error("is nested within %s, but super class %s is nested within %s",
                        toParent2()->toChars(),
                        baseClass->toChars(),
                        baseClass->toParent2()->toChars());
                }
                else
                {
                    error("is not nested, but super class %s is nested within %s",
                        baseClass->toChars(),
                        baseClass->toParent2()->toChars());
                }
                enclosing = NULL;
            }
        }
        else
            makeNested();

        if (storage_class & STCauto)
            error("storage class 'auto' is invalid when declaring a class, did you mean to use 'scope'?");
        if (storage_class & STCscope)
            isscope = true;
        if (storage_class & STCabstract)
            isabstract = 1;
    }

    sc = sc->push(this);
    //sc->stc &= ~(STCfinal | STCauto | STCscope | STCstatic | STCabstract | STCdeprecated | STC_TYPECTOR | STCtls | STCgshared);
    //sc->stc |= storage_class & STC_TYPECTOR;
    sc->stc &= STCsafe | STCtrusted | STCsystem;
    sc->parent = this;
    sc->inunion = 0;
    if (isCOMclass())
    {
        if (global.params.isWindows)
            sc->linkage = LINKwindows;
        else
            /* This enables us to use COM objects under Linux and
             * work with things like XPCOM
             */
            sc->linkage = LINKc;
    }
    sc->protection = PROTpublic;
    sc->explicitProtection = 0;
    sc->structalign = STRUCTALIGN_DEFAULT;
    if (baseClass)
    {
        sc->offset = baseClass->structsize;
        alignsize = baseClass->alignsize;
        sc->offset = (sc->offset + alignsize - 1) & ~(alignsize - 1);
//      if (enclosing)
//          sc->offset += Target::ptrsize;      // room for uplevel context pointer
    }
    else
    {
        if (cpp)
            sc->offset = Target::ptrsize;       // allow room for __vptr
        else
            sc->offset = Target::ptrsize * 2;   // allow room for __vptr and __monitor
        alignsize = Target::ptrsize;
    }
    sc->userAttribDecl = NULL;
    structsize = sc->offset;
    Scope scsave = *sc;
    size_t members_dim = members->dim;
    sizeok = SIZEOKnone;

    /* Set scope so if there are forward references, we still might be able to
     * resolve individual members like enums.
     */
    for (size_t i = 0; i < members_dim; i++)
    {
        Dsymbol *s = (*members)[i];
        //printf("[%d] setScope %s %s, sc = %p\n", i, s->kind(), s->toChars(), sc);
        s->setScope(sc);
    }

    for (size_t i = 0; i < members->dim; i++)
    {
        Dsymbol *s = (*members)[i];
        s->importAll(sc);
    }

    for (size_t i = 0; i < members_dim; i++)
    {
        Dsymbol *s = (*members)[i];

        // Ungag errors when not speculative
        Ungag ungag = ungagSpeculative();
        s->semantic(sc);
    }

    // Set the offsets of the fields and determine the size of the class

    unsigned offset = structsize;
    for (size_t i = 0; i < members->dim; i++)
    {
        Dsymbol *s = (*members)[i];
        s->setFieldOffset(this, &offset, false);
    }
    sc->offset = structsize;

    if (global.errors != errors)
    {
        // The type is no good.
        type = Type::terror;
    }

    if (sizeok == SIZEOKfwd)            // failed due to forward references
    {
        // semantic() failed due to forward references
        // Unwind what we did, and defer it for later
        for (size_t i = 0; i < fields.dim; i++)
        {
            VarDeclaration *v = fields[i];
            v->offset = 0;
        }
        fields.setDim(0);
        structsize = 0;
        alignsize = 0;
//        structalign = 0;

        sc = sc->pop();

        scope = scx ? scx : sc->copy();
        scope->setNoFree();
        scope->module->addDeferredSemantic(this);

        Module::dprogress = dprogress_save;

        //printf("\tsemantic('%s') failed due to forward references\n", toChars());
        return;
    }

    //printf("\tsemantic('%s') successful\n", toChars());

    //members->print();

    /* Look for special member functions.
     * They must be in this class, not in a base class.
     */
    searchCtor();
    if (ctor && (ctor->toParent() != this || !(ctor->isCtorDeclaration() || ctor->isTemplateDeclaration())))
        ctor = NULL;    // search() looks through ancestor classes
    if (!ctor && noDefaultCtor)
    {
        // A class object is always created by constructor, so this check is legitimate.
        for (size_t i = 0; i < fields.dim; i++)
        {
            VarDeclaration *v = fields[i];
            if (v->storage_class & STCnodefaultctor)
                ::error(v->loc, "field %s must be initialized in constructor", v->toChars());
        }
    }

    inv = buildInv(this, sc);

    // Can be in base class
    aggNew    =    (NewDeclaration *)search(Loc(), Id::classNew);
    aggDelete = (DeleteDeclaration *)search(Loc(), Id::classDelete);

    // If this class has no constructor, but base class has a default
    // ctor, create a constructor:
    //    this() { }
    if (!ctor && baseClass && baseClass->ctor)
    {
        FuncDeclaration *fd = resolveFuncCall(loc, sc, baseClass->ctor, NULL, NULL, NULL, 1);
        if (fd && !fd->errors)
        {
            //printf("Creating default this(){} for class %s\n", toChars());
            TypeFunction *btf = (TypeFunction *)fd->type;
            TypeFunction *tf = new TypeFunction(NULL, NULL, 0, LINKd, fd->storage_class);
            tf->purity = btf->purity;
            tf->isnothrow = btf->isnothrow;
            tf->trust = btf->trust;
            CtorDeclaration *ctor = new CtorDeclaration(loc, Loc(), 0, tf);
            ctor->fbody = new CompoundStatement(Loc(), new Statements());
            members->push(ctor);
            ctor->addMember(sc, this, 1);
            *sc = scsave;   // why? What about sc->nofree?
            ctor->semantic(sc);
            this->ctor = ctor;
            defaultCtor = ctor;
        }
        else
        {
            error("Cannot implicitly generate a default ctor when base class %s is missing a default ctor", baseClass->toPrettyChars());
        }
    }

#if 0
    if (baseClass)
    {   if (!aggDelete)
            aggDelete = baseClass->aggDelete;
        if (!aggNew)
            aggNew = baseClass->aggNew;
    }
#endif

    // Allocate instance of each new interface
    sc->offset = structsize;
    for (size_t i = 0; i < vtblInterfaces->dim; i++)
    {
        BaseClass *b = (*vtblInterfaces)[i];
        unsigned thissize = Target::ptrsize;

        alignmember(STRUCTALIGN_DEFAULT, thissize, &sc->offset);
        assert(b->offset == 0);
        b->offset = sc->offset;

        // Take care of single inheritance offsets
        while (b->baseInterfaces_dim)
        {
            b = &b->baseInterfaces[0];
            b->offset = sc->offset;
        }

        sc->offset += thissize;
        if (alignsize < thissize)
            alignsize = thissize;
    }
    structsize = sc->offset;
    sizeok = SIZEOKdone;
    Module::dprogress++;

    dtor = buildDtor(this, sc);
    if (FuncDeclaration *f = hasIdentityOpAssign(this, sc))
    {
        if (!(f->storage_class & STCdisable))
            error(f->loc, "identity assignment operator overload is illegal");
    }
    sc->pop();

#if 0 // Do not call until toObjfile() because of forward references
    // Fill in base class vtbl[]s
    for (i = 0; i < vtblInterfaces->dim; i++)
    {
        BaseClass *b = (*vtblInterfaces)[i];

        //b->fillVtbl(this, &b->vtbl, 1);
    }
#endif
    //printf("-ClassDeclaration::semantic(%s), type = %p\n", toChars(), type);

    if (deferred && !global.gag)
    {
        deferred->semantic2(sc);
        deferred->semantic3(sc);
    }

#if 0
    if (type->ty == Tclass && ((TypeClass *)type)->sym != this)
    {
        printf("this = %p %s\n", this, this->toChars());
        printf("type = %d sym = %p\n", type->ty, ((TypeClass *)type)->sym);
      }
#endif
    assert(type->ty != Tclass || ((TypeClass *)type)->sym == this);
}
Ejemplo n.º 8
0
void InterfaceDeclaration::semantic(Scope *sc)
{
    //printf("InterfaceDeclaration::semantic(%s), type = %p\n", toChars(), type);
    if (inuse)
        return;

    if (!sc)
        sc = scope;
    if (!parent && sc->parent && !sc->parent->isModule())
        parent = sc->parent;

    type = type->semantic(loc, sc);

    if (type->ty == Tclass && ((TypeClass *)type)->sym != this)
    {
        TemplateInstance *ti = ((TypeClass *)type)->sym->isInstantiated();
        if (ti && ti->errors)
            ((TypeClass *)type)->sym = this;
    }

    if (!members)                       // if forward reference
    {   //printf("\tinterface '%s' is forward referenced\n", toChars());
        return;
    }
    if (symtab)                 // if already done
    {   if (!scope)
            return;
    }
    else
        symtab = new DsymbolTable();

    Scope *scx = NULL;
    if (scope)
    {
        sc = scope;
        scx = scope;            // save so we don't make redundant copies
        scope = NULL;
    }

    int errors = global.errors;

    if (sc->stc & STCdeprecated)
    {
        isdeprecated = true;
    }
    userAttribDecl = sc->userAttribDecl;

    // Expand any tuples in baseclasses[]
    for (size_t i = 0; i < baseclasses->dim; )
    {
        // Ungag errors when not speculative
        Ungag ungag = ungagSpeculative();

        BaseClass *b = (*baseclasses)[i];
        b->type = b->type->semantic(loc, sc);

        Type *tb = b->type->toBasetype();
        if (tb->ty == Ttuple)
        {   TypeTuple *tup = (TypeTuple *)tb;
            PROT protection = b->protection;
            baseclasses->remove(i);
            size_t dim = Parameter::dim(tup->arguments);
            for (size_t j = 0; j < dim; j++)
            {   Parameter *arg = Parameter::getNth(tup->arguments, j);
                b = new BaseClass(arg->type, protection);
                baseclasses->insert(i + j, b);
            }
        }
        else
            i++;
    }

    if (!baseclasses->dim && sc->linkage == LINKcpp)
        cpp = 1;

    // Check for errors, handle forward references
    for (size_t i = 0; i < baseclasses->dim; )
    {
        // Ungag errors when not speculative
        Ungag ungag = ungagSpeculative();

        BaseClass *b = (*baseclasses)[i];
        b->type = b->type->semantic(loc, sc);

        Type *tb = b->type->toBasetype();
        TypeClass *tc = (tb->ty == Tclass) ? (TypeClass *)tb : NULL;
        if (!tc || !tc->sym->isInterfaceDeclaration())
        {
            if (b->type != Type::terror)
                error("base type must be interface, not %s", b->type->toChars());
            baseclasses->remove(i);
            continue;
        }
        else
        {
            // Check for duplicate interfaces
            for (size_t j = 0; j < i; j++)
            {
                BaseClass *b2 = (*baseclasses)[j];
                if (b2->base == tc->sym)
                    error("inherits from duplicate interface %s", b2->base->toChars());
            }

            b->base = tc->sym;
            if (b->base == this || isBaseOf2(b->base))
            {
                error("circular inheritance of interface");
                baseclasses->remove(i);
                continue;
            }
            if (b->base->scope)
            {
                // Try to resolve forward reference
                b->base->semantic(NULL);
            }
            if (!b->base->symtab || b->base->scope || b->base->inuse)
            {
                //error("forward reference of base class %s", baseClass->toChars());
                // Forward reference of base, try again later
                //printf("\ttry later, forward reference of base %s\n", b->base->toChars());
                scope = scx ? scx : sc->copy();
                scope->setNoFree();
                scope->module->addDeferredSemantic(this);
                return;
            }
        }
#if 0
        // Inherit const/invariant from base class
        storage_class |= b->base->storage_class & STC_TYPECTOR;
#endif
        i++;
    }
    if (doAncestorsSemantic == SemanticIn)
        doAncestorsSemantic = SemanticDone;

    interfaces_dim = baseclasses->dim;
    interfaces = baseclasses->tdata();

    interfaceSemantic(sc);

    if (vtblOffset())
        vtbl.push(this);                // leave room at vtbl[0] for classinfo

    // Cat together the vtbl[]'s from base interfaces
    for (size_t i = 0; i < interfaces_dim; i++)
    {   BaseClass *b = interfaces[i];

        // Skip if b has already appeared
        for (size_t k = 0; k < i; k++)
        {
            if (b == interfaces[k])
                goto Lcontinue;
        }

        // Copy vtbl[] from base class
        if (b->base->vtblOffset())
        {   size_t d = b->base->vtbl.dim;
            if (d > 1)
            {
                vtbl.reserve(d - 1);
                for (size_t j = 1; j < d; j++)
                    vtbl.push(b->base->vtbl[j]);
            }
        }
        else
        {
            vtbl.append(&b->base->vtbl);
        }

      Lcontinue:
        ;
    }

    protection = sc->protection;
    storage_class |= sc->stc & STC_TYPECTOR;

    for (size_t i = 0; i < members->dim; i++)
    {
        Dsymbol *s = (*members)[i];
        s->addMember(sc, this, 1);
    }

    sc = sc->push(this);
    sc->stc &= STCsafe | STCtrusted | STCsystem;
    sc->parent = this;
    if (com)
        sc->linkage = LINKwindows;
    else if (cpp)
        sc->linkage = LINKcpp;
    sc->structalign = STRUCTALIGN_DEFAULT;
    sc->protection = PROTpublic;
    sc->explicitProtection = 0;
//    structalign = sc->structalign;
    sc->offset = Target::ptrsize * 2;
    sc->userAttribDecl = NULL;
    structsize = sc->offset;
    inuse++;

    /* Set scope so if there are forward references, we still might be able to
     * resolve individual members like enums.
     */
    for (size_t i = 0; i < members->dim; i++)
    {   Dsymbol *s = (*members)[i];
        /* There are problems doing this in the general case because
         * Scope keeps track of things like 'offset'
         */
        if (s->isEnumDeclaration() || (s->isAggregateDeclaration() && s->ident))
        {
            //printf("setScope %s %s\n", s->kind(), s->toChars());
            s->setScope(sc);
        }
    }

    for (size_t i = 0; i < members->dim; i++)
    {
        Dsymbol *s = (*members)[i];
        s->importAll(sc);
    }

    for (size_t i = 0; i < members->dim; i++)
    {
        Dsymbol *s = (*members)[i];

        // Ungag errors when not speculative
        Ungag ungag = ungagSpeculative();
        s->semantic(sc);
    }

    if (global.errors != errors)
    {   // The type is no good.
        type = Type::terror;
    }

    inuse--;
    //members->print();
    sc->pop();
    //printf("-InterfaceDeclaration::semantic(%s), type = %p\n", toChars(), type);

#if 0
    if (type->ty == Tclass && ((TypeClass *)type)->sym != this)
    {
        printf("this = %p %s\n", this, this->toChars());
        printf("type = %d sym = %p\n", type->ty, ((TypeClass *)type)->sym);
      }
#endif
    assert(type->ty != Tclass || ((TypeClass *)type)->sym == this);
}
Ejemplo n.º 9
0
void Module::importAll(Scope *prevsc)
{
    //printf("+Module::importAll(this = %p, '%s'): parent = %p\n", this, toChars(), parent);

    if (scope)
        return;                 // already done

    if (isDocFile)
    {
        error("is a Ddoc file, cannot import it");
        return;
    }

    /* Note that modules get their own scope, from scratch.
     * This is so regardless of where in the syntax a module
     * gets imported, it is unaffected by context.
     * Ignore prevsc.
     */
    Scope *sc = Scope::createGlobal(this);      // create root scope

    // Add import of "object", even for the "object" module.
    // If it isn't there, some compiler rewrites, like
    //    classinst == classinst -> .object.opEquals(classinst, classinst)
    // would fail inside object.d.
    if (members->dim == 0 || ((*members)[0])->ident != Id::object)
    {
        Import *im = new Import(Loc(), NULL, Id::object, NULL, 0);
        members->shift(im);
    }

    if (!symtab)
    {
        // Add all symbols into module's symbol table
        symtab = new DsymbolTable();
        for (size_t i = 0; i < members->dim; i++)
        {
            Dsymbol *s = (*members)[i];
            s->addMember(NULL, sc->scopesym, 1);
        }
    }
    // anything else should be run after addMember, so version/debug symbols are defined

    /* Set scope for the symbols so that if we forward reference
     * a symbol, it can possibly be resolved on the spot.
     * If this works out well, it can be extended to all modules
     * before any semantic() on any of them.
     */
    setScope(sc);               // remember module scope for semantic
    for (size_t i = 0; i < members->dim; i++)
    {
        Dsymbol *s = (*members)[i];
        s->setScope(sc);
    }

    for (size_t i = 0; i < members->dim; i++)
    {
        Dsymbol *s = (*members)[i];
        s->importAll(sc);
    }

    sc = sc->pop();
    sc->pop();          // 2 pops because Scope::createGlobal() created 2
}
Ejemplo n.º 10
0
void Nspace::semantic(Scope *sc)
{
    if (semanticRun >= PASSsemantic)
        return;
    semanticRun = PASSsemantic;
#if LOG
    printf("+Nspace::semantic('%s')\n", toChars());
#endif
    if (scope)
    {
        sc = scope;
        scope = NULL;
    }
    parent = sc->parent;
    if (members)
    {
        if (!symtab)
            symtab = new DsymbolTable();

        // The namespace becomes 'imported' into the enclosing scope
        for (Scope *sce = sc; 1; sce = sce->enclosing)
        {
            ScopeDsymbol *sds = (ScopeDsymbol *)sce->scopesym;
            if (sds)
            {
                sds->importScope(this, Prot(PROTpublic));
                break;
            }
        }

        assert(sc);
        sc = sc->push(this);
        sc->linkage = LINKcpp;          // note that namespaces imply C++ linkage
        sc->parent = this;

        for (size_t i = 0; i < members->dim; i++)
        {
            Dsymbol *s = (*members)[i];
            //printf("add %s to scope %s\n", s->toChars(), toChars());
            s->addMember(sc, this);
        }

        for (size_t i = 0; i < members->dim; i++)
        {
            Dsymbol *s = (*members)[i];
            s->setScope(sc);
        }

        for (size_t i = 0; i < members->dim; i++)
        {
            Dsymbol *s = (*members)[i];
            s->importAll(sc);
        }

        for (size_t i = 0; i < members->dim; i++)
        {
            Dsymbol *s = (*members)[i];
#if LOG
            printf("\tmember '%s', kind = '%s'\n", s->toChars(), s->kind());
#endif
            s->semantic(sc);
        }
        sc->pop();
    }
#if LOG
    printf("-Nspace::semantic('%s')\n", toChars());
#endif
}
Ejemplo n.º 11
0
void StructDeclaration::semantic(Scope *sc)
{
    //printf("+StructDeclaration::semantic(this=%p, %s '%s', sizeok = %d)\n", this, parent->toChars(), toChars(), sizeok);

    //static int count; if (++count == 20) halt();

    if (semanticRun >= PASSsemanticdone)
        return;
    unsigned dprogress_save = Module::dprogress;
    int errors = global.errors;

    Scope *scx = NULL;
    if (scope)
    {
        sc = scope;
        scx = scope;            // save so we don't make redundant copies
        scope = NULL;
    }

    if (!parent)
    {
        assert(sc->parent && sc->func);
        parent = sc->parent;
    }
    assert(parent && !isAnonymous());
    type = type->semantic(loc, sc);

    if (type->ty == Tstruct && ((TypeStruct *)type)->sym != this)
    {
        TemplateInstance *ti = ((TypeStruct *)type)->sym->isInstantiated();
        if (ti && isError(ti))
            ((TypeStruct *)type)->sym = this;
    }

    // Ungag errors when not speculative
    Ungag ungag = ungagSpeculative();

    if (semanticRun == PASSinit)
    {
        protection = sc->protection;

        alignment = sc->structalign;

        storage_class |= sc->stc;
        if (storage_class & STCdeprecated)
            isdeprecated = true;
        if (storage_class & STCabstract)
            error("structs, unions cannot be abstract");
        userAttribDecl = sc->userAttribDecl;
    }
    else if (symtab)
    {
        if (sizeok == SIZEOKdone || !scx)
        {
            semanticRun = PASSsemanticdone;
            return;
        }
    }
    semanticRun = PASSsemantic;

    if (!members)               // if opaque declaration
    {
        semanticRun = PASSsemanticdone;
        return;
    }
    if (!symtab)
        symtab = new DsymbolTable();

    if (sizeok == SIZEOKnone)            // if not already done the addMember step
    {
        for (size_t i = 0; i < members->dim; i++)
        {
            Dsymbol *s = (*members)[i];
            //printf("adding member '%s' to '%s'\n", s->toChars(), this->toChars());
            s->addMember(sc, this, 1);
        }
    }

    sizeok = SIZEOKnone;
    Scope *sc2 = sc->push(this);
    sc2->stc &= STCsafe | STCtrusted | STCsystem;
    sc2->parent = this;
    if (isUnionDeclaration())
        sc2->inunion = 1;
    sc2->protection = Prot(PROTpublic);
    sc2->explicitProtection = 0;
    sc2->structalign = STRUCTALIGN_DEFAULT;
    sc2->userAttribDecl = NULL;

    /* Set scope so if there are forward references, we still might be able to
     * resolve individual members like enums.
     */
    for (size_t i = 0; i < members->dim; i++)
    {
        Dsymbol *s = (*members)[i];
        //printf("struct: setScope %s %s\n", s->kind(), s->toChars());
        s->setScope(sc2);
    }

    for (size_t i = 0; i < members->dim; i++)
    {
        Dsymbol *s = (*members)[i];
        s->importAll(sc2);
    }

    for (size_t i = 0; i < members->dim; i++)
    {
        Dsymbol *s = (*members)[i];

        /* If this is the last member, see if we can finish setting the size.
         * This could be much better - finish setting the size after the last
         * field was processed. The problem is the chicken-and-egg determination
         * of when that is. See Bugzilla 7426 for more info.
         */
        if (i + 1 == members->dim)
        {
            if (sizeok == SIZEOKnone && s->isAliasDeclaration())
                finalizeSize(sc2);
        }
        s->semantic(sc2);
    }
    finalizeSize(sc2);

    if (sizeok == SIZEOKfwd)
    {
        // semantic() failed because of forward references.
        // Unwind what we did, and defer it for later
        for (size_t i = 0; i < fields.dim; i++)
        {
            VarDeclaration *vd = fields[i];
            vd->offset = 0;
        }
        fields.setDim(0);
        structsize = 0;
        alignsize = 0;

        scope = scx ? scx : sc->copy();
        scope->setNoFree();
        scope->module->addDeferredSemantic(this);

        Module::dprogress = dprogress_save;
        //printf("\tdeferring %s\n", toChars());
        return;
    }

    Module::dprogress++;
    semanticRun = PASSsemanticdone;

    //printf("-StructDeclaration::semantic(this=%p, '%s')\n", this, toChars());

    // Determine if struct is all zeros or not
    zeroInit = 1;
    for (size_t i = 0; i < fields.dim; i++)
    {
        VarDeclaration *vd = fields[i];
        if (!vd->isDataseg())
        {
            if (vd->init)
            {
                // Should examine init to see if it is really all 0's
                zeroInit = 0;
                break;
            }
            else
            {
                if (!vd->type->isZeroInit(loc))
                {
                    zeroInit = 0;
                    break;
                }
            }
        }
    }

    dtor = buildDtor(this, sc2);
    postblit = buildPostBlit(this, sc2);
    cpctor = buildCpCtor(this, sc2);

    buildOpAssign(this, sc2);
    buildOpEquals(this, sc2);

    xeq = buildXopEquals(this, sc2);
    xcmp = buildXopCmp(this, sc2);
    xhash = buildXtoHash(this, sc2);

    /* Even if the struct is merely imported and its semantic3 is not run,
     * the TypeInfo object would be speculatively stored in each object
     * files. To set correct function pointer, run semantic3 for xeq and xcmp.
     */
    //if ((xeq && xeq != xerreq || xcmp && xcmp != xerrcmp) && isImportedSym(this))
    //    Module::addDeferredSemantic3(this);
    /* Defer requesting semantic3 until TypeInfo generation is actually invoked.
     * See semanticTypeInfo().
     */
    inv = buildInv(this, sc2);

    sc2->pop();

    /* Look for special member functions.
     */
    ctor = searchCtor();
    aggNew =       (NewDeclaration *)search(Loc(), Id::classNew);
    aggDelete = (DeleteDeclaration *)search(Loc(), Id::classDelete);

    if (ctor)
    {
        Dsymbol *scall = search(Loc(), Id::call);
        if (scall)
        {
            unsigned xerrors = global.startGagging();
            sc = sc->push();
            sc->speculative = true;
            FuncDeclaration *fcall = resolveFuncCall(loc, sc, scall, NULL, NULL, NULL, 1);
            sc = sc->pop();
            global.endGagging(xerrors);

            if (fcall && fcall->isStatic())
            {
                error(fcall->loc, "static opCall is hidden by constructors and can never be called");
                errorSupplemental(fcall->loc, "Please use a factory method instead, or replace all constructors with static opCall.");
            }
        }
    }

    TypeTuple *tup = toArgTypes(type);
    size_t dim = tup->arguments->dim;
    if (dim >= 1)
    {
        assert(dim <= 2);
        arg1type = (*tup->arguments)[0]->type;
        if (dim == 2)
            arg2type = (*tup->arguments)[1]->type;
    }

    if (sc->func)
        semantic2(sc);

    if (global.errors != errors)
    {
        // The type is no good.
        type = Type::terror;
        this->errors = true;
        if (deferred)
            deferred->errors = true;
    }

    if (deferred && !global.gag)
    {
        deferred->semantic2(sc);
        deferred->semantic3(sc);
    }

#if 0
    if (type->ty == Tstruct && ((TypeStruct *)type)->sym != this)
    {
        printf("this = %p %s\n", this, this->toChars());
        printf("type = %d sym = %p\n", type->ty, ((TypeStruct *)type)->sym);
    }
#endif
    assert(type->ty != Tstruct || ((TypeStruct *)type)->sym == this);
}