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Allocate objects on the stack if they (a) don't have a destructor, and (b) don't override the delete operator (on top of the regular conditions for stack allocation that also apply to arrays, structs, etc.). The "no destructor" clause is not strictly necessary, but calling them at the right time would be tricky to say the least; it would involve, among other things, "manually" inserting a try-finally block around anything that might throw exceptions not caught in the current function. Note: objects with custom new operators are automatically ignored because they don't use the regular allocation runtime call, so there's no need to pay special attention to them.
author Frits van Bommel <fvbommel wxs.nl>
date Sat, 09 May 2009 00:50:15 +0200
parents f99a3b393c03
children def7a1d494fd
line wrap: on
line source


// Copyright (c) 1999-2005 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 <assert.h>

#include "root.h"

#include "mars.h"
#include "init.h"
#include "identifier.h"
#include "attrib.h"
#include "dsymbol.h"
#include "scope.h"
#include "declaration.h"
#include "aggregate.h"
#include "module.h"
#include "id.h"

Scope *Scope::freelist = NULL;

void *Scope::operator new(size_t size)
{
    if (freelist)
    {
	Scope *s = freelist;
	freelist = s->enclosing;
	//printf("freelist %p\n", s);
	assert(s->flags & SCOPEfree);
	s->flags &= ~SCOPEfree;
	return s;
    }

    void *p = ::operator new(size);
    //printf("new %p\n", p);
    return p;
}

Scope::Scope()
{   // Create root scope

    //printf("Scope::Scope() %p\n", this);
    this->module = NULL;
    this->scopesym = NULL;
    this->sd = NULL;
    this->enclosing = NULL;
    this->parent = NULL;
    this->sw = NULL;
    this->enclosingFinally = NULL;
    this->enclosingScopeExit = NULL;
    this->tinst = NULL;
    this->sbreak = NULL;
    this->scontinue = NULL;
    this->fes = NULL;
    this->structalign = global.structalign;
    this->func = NULL;
    this->slabel = NULL;
    this->linkage = LINKd;
    this->protection = PROTpublic;
    this->explicitProtection = 0;
    this->stc = 0;
    this->offset = 0;
    this->inunion = 0;
    this->incontract = 0;
    this->nofree = 0;
    this->noctor = 0;
    this->noaccesscheck = 0;
    this->intypeof = 0;
    this->parameterSpecialization = 0;
    this->callSuper = 0;
    this->flags = 0;
    this->anonAgg = NULL;
    this->lastdc = NULL;
    this->lastoffset = 0;
    this->docbuf = NULL;
}

Scope::Scope(Scope *enclosing)
{
    //printf("Scope::Scope(enclosing = %p) %p\n", enclosing, this);
    assert(!(enclosing->flags & SCOPEfree));
    this->module = enclosing->module;
    this->func   = enclosing->func;
    this->parent = enclosing->parent;
    this->scopesym = NULL;
    this->sd = NULL;
    this->sw = enclosing->sw;
    this->enclosingFinally = enclosing->enclosingFinally;
    this->enclosingScopeExit = enclosing->enclosingScopeExit;
    this->tinst = enclosing->tinst;
    this->sbreak = enclosing->sbreak;
    this->scontinue = enclosing->scontinue;
    this->fes = enclosing->fes;
    this->structalign = enclosing->structalign;
    this->enclosing = enclosing;
#ifdef DEBUG
    if (enclosing->enclosing)
	assert(!(enclosing->enclosing->flags & SCOPEfree));
    if (this == enclosing->enclosing)
    {
	printf("this = %p, enclosing = %p, enclosing->enclosing = %p\n", this, enclosing, enclosing->enclosing);
    }
    assert(this != enclosing->enclosing);
#endif
    this->slabel = NULL;
    this->linkage = enclosing->linkage;
    this->protection = enclosing->protection;
    this->explicitProtection = enclosing->explicitProtection;
    this->stc = enclosing->stc;
    this->offset = 0;
    this->inunion = enclosing->inunion;
    this->incontract = enclosing->incontract;
    this->nofree = 0;
    this->noctor = enclosing->noctor;
    this->noaccesscheck = enclosing->noaccesscheck;
    this->intypeof = enclosing->intypeof;
    this->parameterSpecialization = enclosing->parameterSpecialization;
    this->callSuper = enclosing->callSuper;
    this->flags = 0;
    this->anonAgg = NULL;
    this->lastdc = NULL;
    this->lastoffset = 0;
    this->docbuf = enclosing->docbuf;
    assert(this != enclosing);
}

Scope *Scope::createGlobal(Module *module)
{
    Scope *sc;

    sc = new Scope();
    sc->module = module;
    sc->scopesym = new ScopeDsymbol();
    sc->scopesym->symtab = new DsymbolTable();

    // Add top level package as member of this global scope
    Dsymbol *m = module;
    while (m->parent)
	m = m->parent;
    m->addMember(NULL, sc->scopesym, 1);
    m->parent = NULL;			// got changed by addMember()

    // Create the module scope underneath the global scope
    sc = sc->push(module);
    sc->parent = module;
    return sc;
}

Scope *Scope::push()
{
    //printf("Scope::push()\n");
    Scope *s = new Scope(this);
    assert(this != s);
    return s;
}

Scope *Scope::push(ScopeDsymbol *ss)
{
    //printf("Scope::push(%s)\n", ss->toChars());
    Scope *s = push();
    s->scopesym = ss;
    return s;
}

Scope *Scope::pop()
{
    //printf("Scope::pop() %p nofree = %d\n", this, nofree);
    Scope *enc = enclosing;

    if (enclosing)
	enclosing->callSuper |= callSuper;

    if (!nofree)
    {	enclosing = freelist;
	freelist = this;
	flags |= SCOPEfree;
    }

    return enc;
}

void Scope::mergeCallSuper(Loc loc, unsigned cs)
{
    // This does a primitive flow analysis to support the restrictions
    // regarding when and how constructors can appear.
    // It merges the results of two paths.
    // The two paths are callSuper and cs; the result is merged into callSuper.

    if (cs != callSuper)
    {	int a;
	int b;

	callSuper |= cs & (CSXany_ctor | CSXlabel);
	if (cs & CSXreturn)
	{
	}
	else if (callSuper & CSXreturn)
	{
	    callSuper = cs | (callSuper & (CSXany_ctor | CSXlabel));
	}
	else
	{
	    a = (cs        & (CSXthis_ctor | CSXsuper_ctor)) != 0;
	    b = (callSuper & (CSXthis_ctor | CSXsuper_ctor)) != 0;
	    if (a != b)
		error(loc, "one path skips constructor");
	    callSuper |= cs;
	}
    }
}

Dsymbol *Scope::search(Loc loc, Identifier *ident, Dsymbol **pscopesym)
{   Dsymbol *s;
    Scope *sc;

    //printf("Scope::search(%p, '%s')\n", this, ident->toChars());
    if (ident == Id::empty)
    {
	// Look for module scope
	for (sc = this; sc; sc = sc->enclosing)
	{
	    assert(sc != sc->enclosing);
	    if (sc->scopesym)
	    {
		s = sc->scopesym->isModule();
		if (s)
		{
		    //printf("\tfound %s.%s\n", s->parent ? s->parent->toChars() : "", s->toChars());
		    if (pscopesym)
			*pscopesym = sc->scopesym;
		    return s;
		}
	    }
	}
	return NULL;
    }

    for (sc = this; sc; sc = sc->enclosing)
    {
	assert(sc != sc->enclosing);
	if (sc->scopesym)
	{
	    //printf("\tlooking in scopesym '%s', kind = '%s'\n", sc->scopesym->toChars(), sc->scopesym->kind());
	    s = sc->scopesym->search(loc, ident, 0);
	    if (s)
	    {
		if ((global.params.warnings ||
		    global.params.Dversion > 1) &&
		    ident == Id::length &&
		    sc->scopesym->isArrayScopeSymbol() &&
		    sc->enclosing &&
		    sc->enclosing->search(loc, ident, NULL))
		{
		    warning(s->loc, "array 'length' hides other 'length' name in outer scope");
		}

		//printf("\tfound %s.%s, kind = '%s'\n", s->parent ? s->parent->toChars() : "", s->toChars(), s->kind());
		if (pscopesym)
		    *pscopesym = sc->scopesym;
		return s;
	    }
	}
    }

    return NULL;
}

Dsymbol *Scope::insert(Dsymbol *s)
{   Scope *sc;

    for (sc = this; sc; sc = sc->enclosing)
    {
	//printf("\tsc = %p\n", sc);
	if (sc->scopesym)
	{
	    //printf("\t\tsc->scopesym = %p\n", sc->scopesym);
	    if (!sc->scopesym->symtab)
		sc->scopesym->symtab = new DsymbolTable();
	    return sc->scopesym->symtab->insert(s);
	}
    }
    assert(0);
    return NULL;
}

/********************************************
 * Search enclosing scopes for ClassDeclaration.
 */

ClassDeclaration *Scope::getClassScope()
{   Scope *sc;

    for (sc = this; sc; sc = sc->enclosing)
    {
	ClassDeclaration *cd;
	
	if (sc->scopesym)
	{
	    cd = sc->scopesym->isClassDeclaration();
	    if (cd)
		return cd;
	}
    }
    return NULL;
}

/********************************************
 * Search enclosing scopes for ClassDeclaration.
 */

AggregateDeclaration *Scope::getStructClassScope()
{   Scope *sc;

    for (sc = this; sc; sc = sc->enclosing)
    {
	AggregateDeclaration *ad;
	
	if (sc->scopesym)
	{
	    ad = sc->scopesym->isClassDeclaration();
	    if (ad)
		return ad;
	    else
	    {	ad = sc->scopesym->isStructDeclaration();
		if (ad)
		    return ad;
	    }
	}
    }
    return NULL;
}

/*******************************************
 * For TemplateDeclarations, we need to remember the Scope
 * where it was declared. So mark the Scope as not
 * to be free'd.
 */

void Scope::setNoFree()
{   Scope *sc;
    //int i = 0;

    //printf("Scope::setNoFree(this = %p)\n", this);
    for (sc = this; sc; sc = sc->enclosing)
    {
	//printf("\tsc = %p\n", sc);
	sc->nofree = 1;

	assert(!(flags & SCOPEfree));
	//assert(sc != sc->enclosing);
	//assert(!sc->enclosing || sc != sc->enclosing->enclosing);
	//if (++i == 10)
	    //assert(0);
    }
}