src/third_party/skia/src/gpu/gl/GrGLNameAllocator.cpp - cobalt - Git at Google


 /*
  * Copyright 2014 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "GrGLNameAllocator.h"

 /**
  * This is the abstract base class for a nonempty AVL tree that tracks allocated
  * names within the half-open range [fFirst, fEnd). The inner nodes can be
  * sparse (meaning not every name within the range is necessarily allocated),
  * but the bounds are tight, so fFirst *is* guaranteed to be allocated, and so
  * is fEnd - 1.
  */
 class GrGLNameAllocator::SparseNameRange : public SkRefCnt {
 public:
     virtual ~SparseNameRange() {}

     /**
      * Return the beginning of the range. first() is guaranteed to be allocated.
      *
      * @return The first name in the range.
      */
     GrGLuint first() const { return fFirst; }

     /**
      * Return the end of the range. end() - 1 is guaranteed to be allocated.
      *
      * @return One plus the final name in the range.
      */
     GrGLuint end() const { return fEnd; }

     /**
      * Return the height of the tree. This can only be nonzero at an inner node.
      *
      * @return 0 if the implementation is a leaf node,
      *         The nonzero height of the tree otherwise.
      */
     GrGLuint height() const { return fHeight; }

     /**
      * Allocate a name from strictly inside this range. The call will fail if
      * there is not a free name within.
      *
      * @param outName A pointer that receives the allocated name. outName will
      *                be set to zero if there were no free names within the
      *                range [fFirst, fEnd).
      * @return The resulting SparseNameRange after the allocation. Note that
      *         this call is destructive, so the original SparseNameRange will no
      *         longer be valid afterward. The caller must always update its
      *         pointer with the new SparseNameRange.
      */
     virtual SparseNameRange* SK_WARN_UNUSED_RESULT internalAllocate(GrGLuint* outName) = 0;

     /**
      * Remove the leftmost leaf node from this range (or the entire thing if it
      * *is* a leaf node). This is an internal helper method that is used after
      * an allocation if one contiguous range became adjacent to another. (The
      * range gets removed so the one immediately before can be extended,
      * collapsing the two into one.)
      *
      * @param removedCount A pointer that receives the size of the contiguous
                            range that was removed.
      * @return The resulting SparseNameRange after the removal (or NULL if it
      *         became empty). Note that this call is destructive, so the
      *         original SparseNameRange will no longer be valid afterward. The
      *         caller must always update its pointer with the new
      *         SparseNameRange.
      */
     virtual SparseNameRange* SK_WARN_UNUSED_RESULT removeLeftmostContiguousRange(GrGLuint* removedCount) = 0;

     /**
      * Append adjacent allocated names to the end of this range. This operation
      * does not affect the structure of the tree. The caller is responsible for
      * ensuring the new names won't overlap sibling ranges, if any.
      *
      * @param count The number of adjacent names to append.
      * @return The first name appended.
      */
     virtual GrGLuint appendNames(GrGLuint count) = 0;

     /**
      * Prepend adjacent allocated names behind the beginning of this range. This
      * operation does not affect the structure of the tree. The caller is
      * responsible for ensuring the new names won't overlap sibling ranges, if
      * any.
      *
      * @param count The number of adjacent names to prepend.
      * @return The final name prepended (the one with the lowest value).
      */
     virtual GrGLuint prependNames(GrGLuint count) = 0;

     /**
      * Free a name so it is no longer tracked as allocated. If the name is at
      * the very beginning or very end of the range, the boundaries [fFirst, fEnd)
      * will be tightened.
      *
      * @param name The name to free. Not-allocated names are silently ignored
      *             the same way they are in the OpenGL spec.
      * @return The resulting SparseNameRange after the free (or NULL if it
      *         became empty). Note that this call is destructive, so the
      *         original SparseNameRange will no longer be valid afterward. The
      *         caller must always update its pointer with the new
      *         SparseNameRange.
      */
     virtual SparseNameRange* SK_WARN_UNUSED_RESULT free(GrGLuint name) = 0;

 protected:
     SparseNameRange* takeRef() {
       this->ref();
       return this;
     }

     GrGLuint fFirst;
     GrGLuint fEnd;
     GrGLuint fHeight;
 };

 /**
  * This class is the SparseNameRange implementation for an inner node. It is an
  * AVL tree with non-null, non-adjacent left and right children.
  */
 class GrGLNameAllocator::SparseNameTree : public SparseNameRange {
 public:
     SparseNameTree(SparseNameRange* left, SparseNameRange* right)
         : fLeft(left),
           fRight(right) {
         SkASSERT(fLeft.get());
         SkASSERT(fRight.get());
         this->updateStats();
     }

     virtual SparseNameRange* SK_WARN_UNUSED_RESULT internalAllocate(GrGLuint* outName) SK_OVERRIDE {
         // Try allocating the range inside fLeft's internal gaps.
         fLeft.reset(fLeft->internalAllocate(outName));
         if (0 != *outName) {
             this->updateStats();
             return this->rebalance();
         }

         if (fLeft->end() + 1 == fRight->first()) {
             // It closed the gap between fLeft and fRight; merge.
             GrGLuint removedCount;
             fRight.reset(fRight->removeLeftmostContiguousRange(&removedCount));
             *outName = fLeft->appendNames(1 + removedCount);
             if (NULL == fRight.get()) {
                 return fLeft.detach();
             }
             this->updateStats();
             return this->rebalance();
         }

         // There is guaranteed to be a gap between fLeft and fRight, and the
         // "size 1" case has already been covered.
         SkASSERT(fLeft->end() + 1 < fRight->first());
         *outName = fLeft->appendNames(1);
         return this->takeRef();
     }

     virtual SparseNameRange* SK_WARN_UNUSED_RESULT removeLeftmostContiguousRange(GrGLuint* removedCount) SK_OVERRIDE {
         fLeft.reset(fLeft->removeLeftmostContiguousRange(removedCount));
         if (NULL == fLeft) {
             return fRight.detach();
         }
         this->updateStats();
         return this->rebalance();
     }

     virtual GrGLuint appendNames(GrGLuint count) SK_OVERRIDE {
         SkASSERT(fEnd + count > fEnd); // Check for integer wrap.
         GrGLuint name = fRight->appendNames(count);
         SkASSERT(fRight->end() == fEnd + count);
         this->updateStats();
         return name;
     }

     virtual GrGLuint prependNames(GrGLuint count) SK_OVERRIDE {
         SkASSERT(fFirst > count); // We can't allocate at or below 0.
         GrGLuint name = fLeft->prependNames(count);
         SkASSERT(fLeft->first() == fFirst - count);
         this->updateStats();
         return name;
     }

     virtual SparseNameRange* SK_WARN_UNUSED_RESULT free(GrGLuint name) SK_OVERRIDE {
         if (name < fLeft->end()) {
             fLeft.reset(fLeft->free(name));
             if (NULL == fLeft) {
                 // fLeft became empty after the free.
                 return fRight.detach();
             }
             this->updateStats();
             return this->rebalance();
         } else {
             fRight.reset(fRight->free(name));
             if (NULL == fRight) {
                 // fRight became empty after the free.
                 return fLeft.detach();
             }
             this->updateStats();
             return this->rebalance();
         }
     }

 private:
     typedef SkAutoTUnref<SparseNameRange> SparseNameTree::* ChildRange;

     SparseNameRange* SK_WARN_UNUSED_RESULT rebalance() {
         if (fLeft->height() > fRight->height() + 1) {
             return this->rebalanceImpl<&SparseNameTree::fLeft, &SparseNameTree::fRight>();
         }
         if (fRight->height() > fLeft->height() + 1) {
             return this->rebalanceImpl<&SparseNameTree::fRight, &SparseNameTree::fLeft>();
         }
         return this->takeRef();
     }

     /**
      * Rebalance the tree using rotations, as described in the AVL algorithm:
      * http://en.wikipedia.org/wiki/AVL_tree#Insertion
      */
     template<ChildRange Tall, ChildRange Short>
     SparseNameRange* SK_WARN_UNUSED_RESULT rebalanceImpl() {
         // We should be calling rebalance() enough that the tree never gets more
         // than one rotation off balance.
         SkASSERT(2 == (this->*Tall)->height() - (this->*Short)->height());

         // Ensure we are in the 'Left Left' or 'Right Right' case:
         // http://en.wikipedia.org/wiki/AVL_tree#Insertion
         SparseNameTree* tallChild = static_cast<SparseNameTree*>((this->*Tall).get());
         if ((tallChild->*Tall)->height() < (tallChild->*Short)->height()) {
             (this->*Tall).reset(tallChild->rotate<Short, Tall>());
         }

         // Perform a rotation to balance the tree.
         return this->rotate<Tall, Short>();
     }

     /**
      * Perform a node rotation, as described in the AVL algorithm:
      * http://en.wikipedia.org/wiki/AVL_tree#Insertion
      */
     template<ChildRange Tall, ChildRange Short>
     SparseNameRange* SK_WARN_UNUSED_RESULT rotate() {
         SparseNameTree* newRoot = static_cast<SparseNameTree*>((this->*Tall).detach());

         (this->*Tall).reset((newRoot->*Short).detach());
         this->updateStats();

         (newRoot->*Short).reset(this->takeRef());
         newRoot->updateStats();

         return newRoot;
     }

     void updateStats() {
         SkASSERT(fLeft->end() < fRight->first()); // There must be a gap between left and right.
         fFirst = fLeft->first();
         fEnd = fRight->end();
         fHeight = 1 + SkMax32(fLeft->height(), fRight->height());
     }

     SkAutoTUnref<SparseNameRange> fLeft;
     SkAutoTUnref<SparseNameRange> fRight;
 };

 /**
  * This class is the SparseNameRange implementation for a leaf node. It just a
  * contiguous range of allocated names.
  */
 class GrGLNameAllocator::ContiguousNameRange : public SparseNameRange {
 public:
     ContiguousNameRange(GrGLuint first, GrGLuint end) {
         SkASSERT(first < end);
         fFirst = first;
         fEnd = end;
         fHeight = 0;
     }

     virtual SparseNameRange* SK_WARN_UNUSED_RESULT internalAllocate(GrGLuint* outName) SK_OVERRIDE {
         *outName = 0; // No internal gaps, we are contiguous.
         return this->takeRef();
     }

     virtual SparseNameRange* SK_WARN_UNUSED_RESULT removeLeftmostContiguousRange(GrGLuint* removedCount) SK_OVERRIDE {
         *removedCount = fEnd - fFirst;
         return NULL;
     }

     virtual GrGLuint appendNames(GrGLuint count) SK_OVERRIDE {
         SkASSERT(fEnd + count > fEnd); // Check for integer wrap.
         GrGLuint name = fEnd;
         fEnd += count;
         return name;
     }

     virtual GrGLuint prependNames(GrGLuint count) SK_OVERRIDE {
         SkASSERT(fFirst > count); // We can't allocate at or below 0.
         fFirst -= count;
         return fFirst;
     }

     virtual SparseNameRange* SK_WARN_UNUSED_RESULT free(GrGLuint name) SK_OVERRIDE {
         if (name < fFirst || name >= fEnd) {
           // Not-allocated names are silently ignored.
           return this->takeRef();
         }

         if (fFirst == name) {
             ++fFirst;
             return (fEnd == fFirst) ? NULL : this->takeRef();
         }

         if (fEnd == name + 1) {
             --fEnd;
             return this->takeRef();
         }

         SparseNameRange* left = SkNEW_ARGS(ContiguousNameRange, (fFirst, name));
         SparseNameRange* right = this->takeRef();
         fFirst = name + 1;
         return SkNEW_ARGS(SparseNameTree, (left, right));
     }
 };

 GrGLNameAllocator::GrGLNameAllocator(GrGLuint firstName, GrGLuint endName)
     : fFirstName(firstName),
       fEndName(endName) {
     SkASSERT(firstName > 0);
     SkASSERT(endName > firstName);
 }

 GrGLNameAllocator::~GrGLNameAllocator() {
 }

 GrGLuint GrGLNameAllocator::allocateName() {
     if (NULL == fAllocatedNames.get()) {
         fAllocatedNames.reset(SkNEW_ARGS(ContiguousNameRange, (fFirstName, fFirstName + 1)));
         return fFirstName;
     }

     if (fAllocatedNames->first() > fFirstName) {
         return fAllocatedNames->prependNames(1);
     }

     GrGLuint name;
     fAllocatedNames.reset(fAllocatedNames->internalAllocate(&name));
     if (0 != name) {
         return name;
     }

     if (fAllocatedNames->end() < fEndName) {
         return fAllocatedNames->appendNames(1);
     }

     // Out of names.
     return 0;
 }

 void GrGLNameAllocator::free(GrGLuint name) {
     if (!fAllocatedNames.get()) {
       // Not-allocated names are silently ignored.
       return;
     }

     fAllocatedNames.reset(fAllocatedNames->free(name));
 }

	/*
	* Copyright 2014 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "GrGLNameAllocator.h"

	/**
	* This is the abstract base class for a nonempty AVL tree that tracks allocated
	* names within the half-open range [fFirst, fEnd). The inner nodes can be
	* sparse (meaning not every name within the range is necessarily allocated),
	* but the bounds are tight, so fFirst is guaranteed to be allocated, and so
	* is fEnd - 1.
	*/
	class GrGLNameAllocator::SparseNameRange : public SkRefCnt {
	public:
	virtual ~SparseNameRange() {}

	/**
	* Return the beginning of the range. first() is guaranteed to be allocated.
	*
	* @return The first name in the range.
	*/
	GrGLuint first() const { return fFirst; }

	/**
	* Return the end of the range. end() - 1 is guaranteed to be allocated.
	*
	* @return One plus the final name in the range.
	*/
	GrGLuint end() const { return fEnd; }

	/**
	* Return the height of the tree. This can only be nonzero at an inner node.
	*
	* @return 0 if the implementation is a leaf node,
	* The nonzero height of the tree otherwise.
	*/
	GrGLuint height() const { return fHeight; }

	/**
	* Allocate a name from strictly inside this range. The call will fail if
	* there is not a free name within.
	*
	* @param outName A pointer that receives the allocated name. outName will
	* be set to zero if there were no free names within the
	* range [fFirst, fEnd).
	* @return The resulting SparseNameRange after the allocation. Note that
	* this call is destructive, so the original SparseNameRange will no
	* longer be valid afterward. The caller must always update its
	* pointer with the new SparseNameRange.
	*/
	virtual SparseNameRange* SK_WARN_UNUSED_RESULT internalAllocate(GrGLuint* outName) = 0;

	/**
	* Remove the leftmost leaf node from this range (or the entire thing if it
	* is a leaf node). This is an internal helper method that is used after
	* an allocation if one contiguous range became adjacent to another. (The
	* range gets removed so the one immediately before can be extended,
	* collapsing the two into one.)
	*
	* @param removedCount A pointer that receives the size of the contiguous
	range that was removed.
	* @return The resulting SparseNameRange after the removal (or NULL if it
	* became empty). Note that this call is destructive, so the
	* original SparseNameRange will no longer be valid afterward. The
	* caller must always update its pointer with the new
	* SparseNameRange.
	*/
	virtual SparseNameRange* SK_WARN_UNUSED_RESULT removeLeftmostContiguousRange(GrGLuint* removedCount) = 0;

	/**
	* Append adjacent allocated names to the end of this range. This operation
	* does not affect the structure of the tree. The caller is responsible for
	* ensuring the new names won't overlap sibling ranges, if any.
	*
	* @param count The number of adjacent names to append.
	* @return The first name appended.
	*/
	virtual GrGLuint appendNames(GrGLuint count) = 0;

	/**
	* Prepend adjacent allocated names behind the beginning of this range. This
	* operation does not affect the structure of the tree. The caller is
	* responsible for ensuring the new names won't overlap sibling ranges, if
	* any.
	*
	* @param count The number of adjacent names to prepend.
	* @return The final name prepended (the one with the lowest value).
	*/
	virtual GrGLuint prependNames(GrGLuint count) = 0;

	/**
	* Free a name so it is no longer tracked as allocated. If the name is at
	* the very beginning or very end of the range, the boundaries [fFirst, fEnd)
	* will be tightened.
	*
	* @param name The name to free. Not-allocated names are silently ignored
	* the same way they are in the OpenGL spec.
	* @return The resulting SparseNameRange after the free (or NULL if it
	* became empty). Note that this call is destructive, so the
	* original SparseNameRange will no longer be valid afterward. The
	* caller must always update its pointer with the new
	* SparseNameRange.
	*/
	virtual SparseNameRange* SK_WARN_UNUSED_RESULT free(GrGLuint name) = 0;

	protected:
	SparseNameRange* takeRef() {
	this->ref();
	return this;
	}

	GrGLuint fFirst;
	GrGLuint fEnd;
	GrGLuint fHeight;
	};

	/**
	* This class is the SparseNameRange implementation for an inner node. It is an
	* AVL tree with non-null, non-adjacent left and right children.
	*/
	class GrGLNameAllocator::SparseNameTree : public SparseNameRange {
	public:
	SparseNameTree(SparseNameRange* left, SparseNameRange* right)
	: fLeft(left),
	fRight(right) {
	SkASSERT(fLeft.get());
	SkASSERT(fRight.get());
	this->updateStats();
	}

	virtual SparseNameRange* SK_WARN_UNUSED_RESULT internalAllocate(GrGLuint* outName) SK_OVERRIDE {
	// Try allocating the range inside fLeft's internal gaps.
	fLeft.reset(fLeft->internalAllocate(outName));
	if (0 != *outName) {
	this->updateStats();
	return this->rebalance();
	}

	if (fLeft->end() + 1 == fRight->first()) {
	// It closed the gap between fLeft and fRight; merge.
	GrGLuint removedCount;
	fRight.reset(fRight->removeLeftmostContiguousRange(&removedCount));
	*outName = fLeft->appendNames(1 + removedCount);
	if (NULL == fRight.get()) {
	return fLeft.detach();
	}
	this->updateStats();
	return this->rebalance();
	}

	// There is guaranteed to be a gap between fLeft and fRight, and the
	// "size 1" case has already been covered.
	SkASSERT(fLeft->end() + 1 < fRight->first());
	*outName = fLeft->appendNames(1);
	return this->takeRef();
	}

	virtual SparseNameRange* SK_WARN_UNUSED_RESULT removeLeftmostContiguousRange(GrGLuint* removedCount) SK_OVERRIDE {
	fLeft.reset(fLeft->removeLeftmostContiguousRange(removedCount));
	if (NULL == fLeft) {
	return fRight.detach();
	}
	this->updateStats();
	return this->rebalance();
	}

	virtual GrGLuint appendNames(GrGLuint count) SK_OVERRIDE {
	SkASSERT(fEnd + count > fEnd); // Check for integer wrap.
	GrGLuint name = fRight->appendNames(count);
	SkASSERT(fRight->end() == fEnd + count);
	this->updateStats();
	return name;
	}

	virtual GrGLuint prependNames(GrGLuint count) SK_OVERRIDE {
	SkASSERT(fFirst > count); // We can't allocate at or below 0.
	GrGLuint name = fLeft->prependNames(count);
	SkASSERT(fLeft->first() == fFirst - count);
	this->updateStats();
	return name;
	}

	virtual SparseNameRange* SK_WARN_UNUSED_RESULT free(GrGLuint name) SK_OVERRIDE {
	if (name < fLeft->end()) {
	fLeft.reset(fLeft->free(name));
	if (NULL == fLeft) {
	// fLeft became empty after the free.
	return fRight.detach();
	}
	this->updateStats();
	return this->rebalance();
	} else {
	fRight.reset(fRight->free(name));
	if (NULL == fRight) {
	// fRight became empty after the free.
	return fLeft.detach();
	}
	this->updateStats();
	return this->rebalance();
	}
	}

	private:
	typedef SkAutoTUnref<SparseNameRange> SparseNameTree::* ChildRange;

	SparseNameRange* SK_WARN_UNUSED_RESULT rebalance() {
	if (fLeft->height() > fRight->height() + 1) {
	return this->rebalanceImpl<&SparseNameTree::fLeft, &SparseNameTree::fRight>();
	}
	if (fRight->height() > fLeft->height() + 1) {
	return this->rebalanceImpl<&SparseNameTree::fRight, &SparseNameTree::fLeft>();
	}
	return this->takeRef();
	}

	/**
	* Rebalance the tree using rotations, as described in the AVL algorithm:
	* http://en.wikipedia.org/wiki/AVL_tree#Insertion
	*/
	template<ChildRange Tall, ChildRange Short>
	SparseNameRange* SK_WARN_UNUSED_RESULT rebalanceImpl() {
	// We should be calling rebalance() enough that the tree never gets more
	// than one rotation off balance.
	SkASSERT(2 == (this->Tall)->height() - (this->Short)->height());

	// Ensure we are in the 'Left Left' or 'Right Right' case:
	// http://en.wikipedia.org/wiki/AVL_tree#Insertion
	SparseNameTree* tallChild = static_cast<SparseNameTree>((this->Tall).get());
	if ((tallChild->Tall)->height() < (tallChild->Short)->height()) {
	(this->*Tall).reset(tallChild->rotate<Short, Tall>());
	}

	// Perform a rotation to balance the tree.
	return this->rotate<Tall, Short>();
	}

	/**
	* Perform a node rotation, as described in the AVL algorithm:
	* http://en.wikipedia.org/wiki/AVL_tree#Insertion
	*/
	template<ChildRange Tall, ChildRange Short>
	SparseNameRange* SK_WARN_UNUSED_RESULT rotate() {
	SparseNameTree* newRoot = static_cast<SparseNameTree>((this->Tall).detach());

	(this->Tall).reset((newRoot->Short).detach());
	this->updateStats();

	(newRoot->*Short).reset(this->takeRef());
	newRoot->updateStats();

	return newRoot;
	}

	void updateStats() {
	SkASSERT(fLeft->end() < fRight->first()); // There must be a gap between left and right.
	fFirst = fLeft->first();
	fEnd = fRight->end();
	fHeight = 1 + SkMax32(fLeft->height(), fRight->height());
	}

	SkAutoTUnref<SparseNameRange> fLeft;
	SkAutoTUnref<SparseNameRange> fRight;
	};

	/**
	* This class is the SparseNameRange implementation for a leaf node. It just a
	* contiguous range of allocated names.
	*/
	class GrGLNameAllocator::ContiguousNameRange : public SparseNameRange {
	public:
	ContiguousNameRange(GrGLuint first, GrGLuint end) {
	SkASSERT(first < end);
	fFirst = first;
	fEnd = end;
	fHeight = 0;
	}

	virtual SparseNameRange* SK_WARN_UNUSED_RESULT internalAllocate(GrGLuint* outName) SK_OVERRIDE {
	*outName = 0; // No internal gaps, we are contiguous.
	return this->takeRef();
	}

	virtual SparseNameRange* SK_WARN_UNUSED_RESULT removeLeftmostContiguousRange(GrGLuint* removedCount) SK_OVERRIDE {
	*removedCount = fEnd - fFirst;
	return NULL;
	}

	virtual GrGLuint appendNames(GrGLuint count) SK_OVERRIDE {
	SkASSERT(fEnd + count > fEnd); // Check for integer wrap.
	GrGLuint name = fEnd;
	fEnd += count;
	return name;
	}

	virtual GrGLuint prependNames(GrGLuint count) SK_OVERRIDE {
	SkASSERT(fFirst > count); // We can't allocate at or below 0.
	fFirst -= count;
	return fFirst;
	}

	virtual SparseNameRange* SK_WARN_UNUSED_RESULT free(GrGLuint name) SK_OVERRIDE {
	if (name < fFirst \|\| name >= fEnd) {
	// Not-allocated names are silently ignored.
	return this->takeRef();
	}

	if (fFirst == name) {
	++fFirst;
	return (fEnd == fFirst) ? NULL : this->takeRef();
	}

	if (fEnd == name + 1) {
	--fEnd;
	return this->takeRef();
	}

	SparseNameRange* left = SkNEW_ARGS(ContiguousNameRange, (fFirst, name));
	SparseNameRange* right = this->takeRef();
	fFirst = name + 1;
	return SkNEW_ARGS(SparseNameTree, (left, right));
	}
	};

	GrGLNameAllocator::GrGLNameAllocator(GrGLuint firstName, GrGLuint endName)
	: fFirstName(firstName),
	fEndName(endName) {
	SkASSERT(firstName > 0);
	SkASSERT(endName > firstName);
	}

	GrGLNameAllocator::~GrGLNameAllocator() {
	}

	GrGLuint GrGLNameAllocator::allocateName() {
	if (NULL == fAllocatedNames.get()) {
	fAllocatedNames.reset(SkNEW_ARGS(ContiguousNameRange, (fFirstName, fFirstName + 1)));
	return fFirstName;
	}

	if (fAllocatedNames->first() > fFirstName) {
	return fAllocatedNames->prependNames(1);
	}

	GrGLuint name;
	fAllocatedNames.reset(fAllocatedNames->internalAllocate(&name));
	if (0 != name) {
	return name;
	}

	if (fAllocatedNames->end() < fEndName) {
	return fAllocatedNames->appendNames(1);
	}

	// Out of names.
	return 0;
	}

	void GrGLNameAllocator::free(GrGLuint name) {
	if (!fAllocatedNames.get()) {
	// Not-allocated names are silently ignored.
	return;
	}

	fAllocatedNames.reset(fAllocatedNames->free(name));
	}