src/third_party/mozjs/js/src/jspropertytree.cpp - cobalt - Git at Google

 /* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*-
  * vim: set ts=8 sts=4 et sw=4 tw=99:
  * This Source Code Form is subject to the terms of the Mozilla Public
  * License, v. 2.0. If a copy of the MPL was not distributed with this
  * file, You can obtain one at http://mozilla.org/MPL/2.0/. */

 #include "jspropertytree.h"

 #include "jstypes.h"
 #include "jsapi.h"
 #include "jscntxt.h"
 #include "jsgc.h"

 #include "vm/Shape.h"

 #include "jsgcinlines.h"

 #include "vm/Shape-inl.h"

 using namespace js;

 inline HashNumber
 ShapeHasher::hash(const Lookup &l)
 {
     return l.hash();
 }

 inline bool
 ShapeHasher::match(const Key k, const Lookup &l)
 {
     return k->matches(l);
 }

 Shape *
 PropertyTree::newShape(JSContext *cx)
 {
     Shape *shape = js_NewGCShape(cx);
     if (!shape)
         JS_ReportOutOfMemory(cx);
     return shape;
 }

 static KidsHash *
 HashChildren(Shape *kid1, Shape *kid2)
 {
     KidsHash *hash = js_new<KidsHash>();
     if (!hash || !hash->init(2)) {
         js_delete(hash);
         return NULL;
     }

     JS_ALWAYS_TRUE(hash->putNew(kid1, kid1));
     JS_ALWAYS_TRUE(hash->putNew(kid2, kid2));
     return hash;
 }

 bool
 PropertyTree::insertChild(JSContext *cx, Shape *parent, Shape *child)
 {
     JS_ASSERT(!parent->inDictionary());
     JS_ASSERT(!child->parent);
     JS_ASSERT(!child->inDictionary());
     JS_ASSERT(cx->compartment() == compartment);
     JS_ASSERT(child->compartment() == parent->compartment());

     KidsPointer *kidp = &parent->kids;

     if (kidp->isNull()) {
         child->setParent(parent);
         kidp->setShape(child);
         return true;
     }

     if (kidp->isShape()) {
         Shape *shape = kidp->toShape();
         JS_ASSERT(shape != child);
         JS_ASSERT(!shape->matches(child));

         KidsHash *hash = HashChildren(shape, child);
         if (!hash) {
             JS_ReportOutOfMemory(cx);
             return false;
         }
         kidp->setHash(hash);
         child->setParent(parent);
         return true;
     }

     if (!kidp->toHash()->putNew(child, child)) {
         JS_ReportOutOfMemory(cx);
         return false;
     }

     child->setParent(parent);
     return true;
 }

 void
 Shape::removeChild(Shape *child)
 {
     JS_ASSERT(!child->inDictionary());
     JS_ASSERT(child->parent == this);

     KidsPointer *kidp = &kids;

     if (kidp->isShape()) {
         JS_ASSERT(kidp->toShape() == child);
         kidp->setNull();
         child->parent = NULL;
         return;
     }

     KidsHash *hash = kidp->toHash();
     JS_ASSERT(hash->count() >= 2);      /* otherwise kidp->isShape() should be true */

     hash->remove(child);
     child->parent = NULL;

     if (hash->count() == 1) {
         /* Convert from HASH form back to SHAPE form. */
         KidsHash::Range r = hash->all();
         Shape *otherChild = r.front();
         JS_ASSERT((r.popFront(), r.empty()));    /* No more elements! */
         kidp->setShape(otherChild);
         js_delete(hash);
     }
 }

 Shape *
 PropertyTree::getChild(JSContext *cx, Shape *parent_, uint32_t nfixed, const StackShape &child)
 {
     {
         Shape *shape = NULL;

         JS_ASSERT(parent_);

         /*
          * The property tree has extremely low fan-out below its root in
          * popular embeddings with real-world workloads. Patterns such as
          * defining closures that capture a constructor's environment as
          * getters or setters on the new object that is passed in as
          * |this| can significantly increase fan-out below the property
          * tree root -- see bug 335700 for details.
          */
         KidsPointer *kidp = &parent_->kids;
         if (kidp->isShape()) {
             Shape *kid = kidp->toShape();
             if (kid->matches(child))
                 shape = kid;
         } else if (kidp->isHash()) {
             if (KidsHash::Ptr p = kidp->toHash()->lookup(child))
                 shape = *p;
         } else {
             /* If kidp->isNull(), we always insert. */
         }

 #ifdef JSGC_INCREMENTAL
         if (shape) {
             JS::Zone *zone = shape->zone();
             if (zone->needsBarrier()) {
                 /*
                  * We need a read barrier for the shape tree, since these are weak
                  * pointers.
                  */
                 Shape *tmp = shape;
                 MarkShapeUnbarriered(zone->barrierTracer(), &tmp, "read barrier");
                 JS_ASSERT(tmp == shape);
             } else if (zone->isGCSweeping() && !shape->isMarked() &&
                        !shape->arenaHeader()->allocatedDuringIncremental)
             {
                 /*
                  * The shape we've found is unreachable and due to be finalized, so
                  * remove our weak reference to it and don't use it.
                  */
                 JS_ASSERT(parent_->isMarked());
                 parent_->removeChild(shape);
                 shape = NULL;
             }
         }
 #endif

         if (shape)
             return shape;
     }

     StackShape::AutoRooter childRoot(cx, &child);
     RootedShape parent(cx, parent_);

     Shape *shape = newShape(cx);
     if (!shape)
         return NULL;

     new (shape) Shape(child, nfixed);

     if (!insertChild(cx, parent, shape))
         return NULL;

     return shape;
 }

 void
 Shape::sweep()
 {
     if (inDictionary())
         return;

     /*
      * We detach the child from the parent if the parent is reachable.
      *
      * Note that due to incremental sweeping, the parent pointer may point
      * to the original reachable parent, or it may point to a new live
      * object allocated in the same cell that used to hold the parent.
      *
      * There are three cases:
      *
      * Case 1: parent is not marked - parent is unreachable, may have been
      *         finalized, and the cell may subsequently have been
      *         reallocated to a compartment that is not being marked (cells
      *         are marked when allocated in a compartment that is currenly
      *         being marked by the collector).
      *
      * Case 2: parent is marked and is in a different compartment - parent
      *         has been freed and reallocated to compartment that was being
      *         marked.
      *
      * Case 3: parent is marked and is in the same compartment - parent is
      *         stil reachable and we need to detach from it.
      */
     if (parent && parent->isMarked() && parent->compartment() == compartment())
         parent->removeChild(this);
 }

 void
 Shape::finalize(FreeOp *fop)
 {
     if (!inDictionary() && kids.isHash())
         fop->delete_(kids.toHash());
 }

 #ifdef DEBUG

 void
 KidsPointer::checkConsistency(Shape *aKid) const
 {
     if (isShape()) {
         JS_ASSERT(toShape() == aKid);
     } else {
         JS_ASSERT(isHash());
         KidsHash *hash = toHash();
         KidsHash::Ptr ptr = hash->lookup(aKid);
         JS_ASSERT(*ptr == aKid);
     }
 }

 void
 Shape::dump(JSContext *cx, FILE *fp) const
 {
     jsid propid = this->propid();

     JS_ASSERT(!JSID_IS_VOID(propid));

     if (JSID_IS_INT(propid)) {
         fprintf(fp, "[%ld]", (long) JSID_TO_INT(propid));
     } else {
         JSLinearString *str;
         if (JSID_IS_ATOM(propid)) {
             str = JSID_TO_ATOM(propid);
         } else {
             JS_ASSERT(JSID_IS_OBJECT(propid));
             RootedValue v(cx, IdToValue(propid));
             JSString *s = ToStringSlow<CanGC>(cx, v);
             fputs("object ", fp);
             str = s ? s->ensureLinear(cx) : NULL;
         }
         if (!str)
             fputs("<error>", fp);
         else
             FileEscapedString(fp, str, '"');
     }

     fprintf(fp, " g/s %p/%p slot %d attrs %x ",
             JS_FUNC_TO_DATA_PTR(void *, base()->rawGetter),
             JS_FUNC_TO_DATA_PTR(void *, base()->rawSetter),
             hasSlot() ? slot() : -1, attrs);

     if (attrs) {
         int first = 1;
         fputs("(", fp);
 #define DUMP_ATTR(name, display) if (attrs & JSPROP_##name) fputs(&(" " #display)[first], fp), first = 0
         DUMP_ATTR(ENUMERATE, enumerate);
         DUMP_ATTR(READONLY, readonly);
         DUMP_ATTR(PERMANENT, permanent);
         DUMP_ATTR(GETTER, getter);
         DUMP_ATTR(SETTER, setter);
         DUMP_ATTR(SHARED, shared);
 #undef  DUMP_ATTR
         fputs(") ", fp);
     }

     fprintf(fp, "flags %x ", flags);
     if (flags) {
         int first = 1;
         fputs("(", fp);
 #define DUMP_FLAG(name, display) if (flags & name) fputs(&(" " #display)[first], fp), first = 0
         DUMP_FLAG(HAS_SHORTID, has_shortid);
         DUMP_FLAG(IN_DICTIONARY, in_dictionary);
 #undef  DUMP_FLAG
         fputs(") ", fp);
     }

     fprintf(fp, "shortid %d\n", maybeShortid());
 }

 void
 Shape::dumpSubtree(JSContext *cx, int level, FILE *fp) const
 {
     if (!parent) {
         JS_ASSERT(level == 0);
         JS_ASSERT(JSID_IS_EMPTY(propid_));
         fprintf(fp, "class %s emptyShape\n", getObjectClass()->name);
     } else {
         fprintf(fp, "%*sid ", level, "");
         dump(cx, fp);
     }

     if (!kids.isNull()) {
         ++level;
         if (kids.isShape()) {
             Shape *kid = kids.toShape();
             JS_ASSERT(kid->parent == this);
             kid->dumpSubtree(cx, level, fp);
         } else {
             const KidsHash &hash = *kids.toHash();
             for (KidsHash::Range range = hash.all(); !range.empty(); range.popFront()) {
                 Shape *kid = range.front();

                 JS_ASSERT(kid->parent == this);
                 kid->dumpSubtree(cx, level, fp);
             }
         }
     }
 }

 void
 js::PropertyTree::dumpShapes(JSRuntime *rt)
 {
 #if defined(STARBOARD)
     return;
 #else
     static bool init = false;
     static FILE *dumpfp = NULL;
     if (!init) {
         init = true;
         const char *name = getenv("JS_DUMP_SHAPES_FILE");
         if (!name)
             return;
         dumpfp = fopen(name, "a");
     }

     if (!dumpfp)
         return;

     fprintf(dumpfp, "rt->gcNumber = %lu", (unsigned long)rt->gcNumber);

     for (gc::GCCompartmentsIter c(rt); !c.done(); c.next()) {
         fprintf(dumpfp, "*** Compartment %p ***\n", (void *)c.get());

         /*
         typedef JSCompartment::EmptyShapeSet HS;
         HS &h = c->emptyShapes;
         for (HS::Range r = h.all(); !r.empty(); r.popFront()) {
             Shape *empty = r.front();
             empty->dumpSubtree(rt, 0, dumpfp);
             putc('\n', dumpfp);
         }
         */
     }
 #endif
 }
 #endif
	/* -- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 --
	* vim: set ts=8 sts=4 et sw=4 tw=99:
	* This Source Code Form is subject to the terms of the Mozilla Public
	* License, v. 2.0. If a copy of the MPL was not distributed with this
	* file, You can obtain one at http://mozilla.org/MPL/2.0/. */

	#include "jspropertytree.h"

	#include "jstypes.h"
	#include "jsapi.h"
	#include "jscntxt.h"
	#include "jsgc.h"

	#include "vm/Shape.h"

	#include "jsgcinlines.h"

	#include "vm/Shape-inl.h"

	using namespace js;

	inline HashNumber
	ShapeHasher::hash(const Lookup &l)
	{
	return l.hash();
	}

	inline bool
	ShapeHasher::match(const Key k, const Lookup &l)
	{
	return k->matches(l);
	}

	Shape *
	PropertyTree::newShape(JSContext *cx)
	{
	Shape *shape = js_NewGCShape(cx);
	if (!shape)
	JS_ReportOutOfMemory(cx);
	return shape;
	}

	static KidsHash *
	HashChildren(Shape kid1, Shape kid2)
	{
	KidsHash *hash = js_new<KidsHash>();
	if (!hash \|\| !hash->init(2)) {
	js_delete(hash);
	return NULL;
	}

	JS_ALWAYS_TRUE(hash->putNew(kid1, kid1));
	JS_ALWAYS_TRUE(hash->putNew(kid2, kid2));
	return hash;
	}

	bool
	PropertyTree::insertChild(JSContext cx, Shape parent, Shape *child)
	{
	JS_ASSERT(!parent->inDictionary());
	JS_ASSERT(!child->parent);
	JS_ASSERT(!child->inDictionary());
	JS_ASSERT(cx->compartment() == compartment);
	JS_ASSERT(child->compartment() == parent->compartment());

	KidsPointer *kidp = &parent->kids;

	if (kidp->isNull()) {
	child->setParent(parent);
	kidp->setShape(child);
	return true;
	}

	if (kidp->isShape()) {
	Shape *shape = kidp->toShape();
	JS_ASSERT(shape != child);
	JS_ASSERT(!shape->matches(child));

	KidsHash *hash = HashChildren(shape, child);
	if (!hash) {
	JS_ReportOutOfMemory(cx);
	return false;
	}
	kidp->setHash(hash);
	child->setParent(parent);
	return true;
	}

	if (!kidp->toHash()->putNew(child, child)) {
	JS_ReportOutOfMemory(cx);
	return false;
	}

	child->setParent(parent);
	return true;
	}

	void
	Shape::removeChild(Shape *child)
	{
	JS_ASSERT(!child->inDictionary());
	JS_ASSERT(child->parent == this);

	KidsPointer *kidp = &kids;

	if (kidp->isShape()) {
	JS_ASSERT(kidp->toShape() == child);
	kidp->setNull();
	child->parent = NULL;
	return;
	}

	KidsHash *hash = kidp->toHash();
	JS_ASSERT(hash->count() >= 2); /* otherwise kidp->isShape() should be true */

	hash->remove(child);
	child->parent = NULL;

	if (hash->count() == 1) {
	/* Convert from HASH form back to SHAPE form. */
	KidsHash::Range r = hash->all();
	Shape *otherChild = r.front();
	JS_ASSERT((r.popFront(), r.empty())); /* No more elements! */
	kidp->setShape(otherChild);
	js_delete(hash);
	}
	}

	Shape *
	PropertyTree::getChild(JSContext cx, Shape parent_, uint32_t nfixed, const StackShape &child)
	{
	{
	Shape *shape = NULL;

	JS_ASSERT(parent_);

	/*
	* The property tree has extremely low fan-out below its root in
	* popular embeddings with real-world workloads. Patterns such as
	* defining closures that capture a constructor's environment as
	* getters or setters on the new object that is passed in as
	* \|this\| can significantly increase fan-out below the property
	* tree root -- see bug 335700 for details.
	*/
	KidsPointer *kidp = &parent_->kids;
	if (kidp->isShape()) {
	Shape *kid = kidp->toShape();
	if (kid->matches(child))
	shape = kid;
	} else if (kidp->isHash()) {
	if (KidsHash::Ptr p = kidp->toHash()->lookup(child))
	shape = *p;
	} else {
	/* If kidp->isNull(), we always insert. */
	}

	#ifdef JSGC_INCREMENTAL
	if (shape) {
	JS::Zone *zone = shape->zone();
	if (zone->needsBarrier()) {
	/*
	* We need a read barrier for the shape tree, since these are weak
	* pointers.
	*/
	Shape *tmp = shape;
	MarkShapeUnbarriered(zone->barrierTracer(), &tmp, "read barrier");
	JS_ASSERT(tmp == shape);
	} else if (zone->isGCSweeping() && !shape->isMarked() &&
	!shape->arenaHeader()->allocatedDuringIncremental)
	{
	/*
	* The shape we've found is unreachable and due to be finalized, so
	* remove our weak reference to it and don't use it.
	*/
	JS_ASSERT(parent_->isMarked());
	parent_->removeChild(shape);
	shape = NULL;
	}
	}
	#endif

	if (shape)
	return shape;
	}

	StackShape::AutoRooter childRoot(cx, &child);
	RootedShape parent(cx, parent_);

	Shape *shape = newShape(cx);
	if (!shape)
	return NULL;

	new (shape) Shape(child, nfixed);

	if (!insertChild(cx, parent, shape))
	return NULL;

	return shape;
	}

	void
	Shape::sweep()
	{
	if (inDictionary())
	return;

	/*
	* We detach the child from the parent if the parent is reachable.
	*
	* Note that due to incremental sweeping, the parent pointer may point
	* to the original reachable parent, or it may point to a new live
	* object allocated in the same cell that used to hold the parent.
	*
	* There are three cases:
	*
	* Case 1: parent is not marked - parent is unreachable, may have been
	* finalized, and the cell may subsequently have been
	* reallocated to a compartment that is not being marked (cells
	* are marked when allocated in a compartment that is currenly
	* being marked by the collector).
	*
	* Case 2: parent is marked and is in a different compartment - parent
	* has been freed and reallocated to compartment that was being
	* marked.
	*
	* Case 3: parent is marked and is in the same compartment - parent is
	* stil reachable and we need to detach from it.
	*/
	if (parent && parent->isMarked() && parent->compartment() == compartment())
	parent->removeChild(this);
	}

	void
	Shape::finalize(FreeOp *fop)
	{
	if (!inDictionary() && kids.isHash())
	fop->delete_(kids.toHash());
	}

	#ifdef DEBUG

	void
	KidsPointer::checkConsistency(Shape *aKid) const
	{
	if (isShape()) {
	JS_ASSERT(toShape() == aKid);
	} else {
	JS_ASSERT(isHash());
	KidsHash *hash = toHash();
	KidsHash::Ptr ptr = hash->lookup(aKid);
	JS_ASSERT(*ptr == aKid);
	}
	}

	void
	Shape::dump(JSContext cx, FILE fp) const
	{
	jsid propid = this->propid();

	JS_ASSERT(!JSID_IS_VOID(propid));

	if (JSID_IS_INT(propid)) {
	fprintf(fp, "[%ld]", (long) JSID_TO_INT(propid));
	} else {
	JSLinearString *str;
	if (JSID_IS_ATOM(propid)) {
	str = JSID_TO_ATOM(propid);
	} else {
	JS_ASSERT(JSID_IS_OBJECT(propid));
	RootedValue v(cx, IdToValue(propid));
	JSString *s = ToStringSlow<CanGC>(cx, v);
	fputs("object ", fp);
	str = s ? s->ensureLinear(cx) : NULL;
	}
	if (!str)
	fputs("<error>", fp);
	else
	FileEscapedString(fp, str, '"');
	}

	fprintf(fp, " g/s %p/%p slot %d attrs %x ",
	JS_FUNC_TO_DATA_PTR(void *, base()->rawGetter),
	JS_FUNC_TO_DATA_PTR(void *, base()->rawSetter),
	hasSlot() ? slot() : -1, attrs);

	if (attrs) {
	int first = 1;
	fputs("(", fp);
	#define DUMP_ATTR(name, display) if (attrs & JSPROP_##name) fputs(&(" " #display)[first], fp), first = 0
	DUMP_ATTR(ENUMERATE, enumerate);
	DUMP_ATTR(READONLY, readonly);
	DUMP_ATTR(PERMANENT, permanent);
	DUMP_ATTR(GETTER, getter);
	DUMP_ATTR(SETTER, setter);
	DUMP_ATTR(SHARED, shared);
	#undef DUMP_ATTR
	fputs(") ", fp);
	}

	fprintf(fp, "flags %x ", flags);
	if (flags) {
	int first = 1;
	fputs("(", fp);
	#define DUMP_FLAG(name, display) if (flags & name) fputs(&(" " #display)[first], fp), first = 0
	DUMP_FLAG(HAS_SHORTID, has_shortid);
	DUMP_FLAG(IN_DICTIONARY, in_dictionary);
	#undef DUMP_FLAG
	fputs(") ", fp);
	}

	fprintf(fp, "shortid %d\n", maybeShortid());
	}

	void
	Shape::dumpSubtree(JSContext cx, int level, FILE fp) const
	{
	if (!parent) {
	JS_ASSERT(level == 0);
	JS_ASSERT(JSID_IS_EMPTY(propid_));
	fprintf(fp, "class %s emptyShape\n", getObjectClass()->name);
	} else {
	fprintf(fp, "%*sid ", level, "");
	dump(cx, fp);
	}

	if (!kids.isNull()) {
	++level;
	if (kids.isShape()) {
	Shape *kid = kids.toShape();
	JS_ASSERT(kid->parent == this);
	kid->dumpSubtree(cx, level, fp);
	} else {
	const KidsHash &hash = *kids.toHash();
	for (KidsHash::Range range = hash.all(); !range.empty(); range.popFront()) {
	Shape *kid = range.front();

	JS_ASSERT(kid->parent == this);
	kid->dumpSubtree(cx, level, fp);
	}
	}
	}
	}

	void
	js::PropertyTree::dumpShapes(JSRuntime *rt)
	{
	#if defined(STARBOARD)
	return;
	#else
	static bool init = false;
	static FILE *dumpfp = NULL;
	if (!init) {
	init = true;
	const char *name = getenv("JS_DUMP_SHAPES_FILE");
	if (!name)
	return;
	dumpfp = fopen(name, "a");
	}

	if (!dumpfp)
	return;

	fprintf(dumpfp, "rt->gcNumber = %lu", (unsigned long)rt->gcNumber);

	for (gc::GCCompartmentsIter c(rt); !c.done(); c.next()) {
	fprintf(dumpfp, "* Compartment %p \n", (void )c.get());

	/*
	typedef JSCompartment::EmptyShapeSet HS;
	HS &h = c->emptyShapes;
	for (HS::Range r = h.all(); !r.empty(); r.popFront()) {
	Shape *empty = r.front();
	empty->dumpSubtree(rt, 0, dumpfp);
	putc('\n', dumpfp);
	}
	*/
	}
	#endif
	}
	#endif