src/gpu/GrAllocator.h - skia - Git at Google

 /*
  * Copyright 2010 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef GrAllocator_DEFINED
 #define GrAllocator_DEFINED

 #include "GrConfig.h"
 #include "GrTypes.h"
 #include "SkTArray.h"
 #include "SkTypes.h"

 class GrAllocator : SkNoncopyable {
 public:
     ~GrAllocator() { this->reset(); }

     /**
      * Create an allocator
      *
      * @param   itemSize        the size of each item to allocate
      * @param   itemsPerBlock   the number of items to allocate at once
      * @param   initialBlock    optional memory to use for the first block.
      *                          Must be at least itemSize*itemsPerBlock sized.
      *                          Caller is responsible for freeing this memory.
      */
     GrAllocator(size_t itemSize, int itemsPerBlock, void* initialBlock)
         : fItemSize(itemSize)
         , fItemsPerBlock(itemsPerBlock)
         , fOwnFirstBlock(nullptr == initialBlock)
         , fCount(0)
         , fInsertionIndexInBlock(0) {
         SkASSERT(itemsPerBlock > 0);
         fBlockSize = fItemSize * fItemsPerBlock;
         if (fOwnFirstBlock) {
             // This force us to allocate a new block on push_back().
             fInsertionIndexInBlock = fItemsPerBlock;
         } else {
             fBlocks.push_back() = initialBlock;
             fInsertionIndexInBlock = 0;
         }
     }

     /**
      * Adds an item and returns pointer to it.
      *
      * @return pointer to the added item.
      */
     void* push_back() {
         // we always have at least one block
         if (fItemsPerBlock == fInsertionIndexInBlock) {
             fBlocks.push_back() = sk_malloc_throw(fBlockSize);
             fInsertionIndexInBlock = 0;
         }
         void* ret = (char*)fBlocks.back() + fItemSize * fInsertionIndexInBlock;
         ++fCount;
         ++fInsertionIndexInBlock;
         return ret;
     }

     /**
      * Remove the last item, only call if count() != 0
      */
     void pop_back() {
         SkASSERT(fCount);
         SkASSERT(fInsertionIndexInBlock > 0);
         --fInsertionIndexInBlock;
         --fCount;
         if (0 == fInsertionIndexInBlock) {
             // Never delete the first block
             if (fBlocks.count() > 1) {
                 sk_free(fBlocks.back());
                 fBlocks.pop_back();
                 fInsertionIndexInBlock = fItemsPerBlock;
             }
         }
     }

     /**
      * Removes all added items.
      */
     void reset() {
         int firstBlockToFree = fOwnFirstBlock ? 0 : 1;
         for (int i = firstBlockToFree; i < fBlocks.count(); ++i) {
             sk_free(fBlocks[i]);
         }
         if (fOwnFirstBlock) {
             fBlocks.reset();
             // This force us to allocate a new block on push_back().
             fInsertionIndexInBlock = fItemsPerBlock;
         } else {
             fBlocks.pop_back_n(fBlocks.count() - 1);
             fInsertionIndexInBlock = 0;
         }
         fCount = 0;
     }

     /**
      * Returns the item count.
      */
     int count() const {
         return fCount;
     }

     /**
      * Is the count 0?
      */
     bool empty() const { return 0 == fCount; }

     /**
      * Access last item, only call if count() != 0
      */
     void* back() {
         SkASSERT(fCount);
         SkASSERT(fInsertionIndexInBlock > 0);
         return (char*)(fBlocks.back()) + (fInsertionIndexInBlock - 1) * fItemSize;
     }

     /**
      * Access last item, only call if count() != 0
      */
     const void* back() const {
         SkASSERT(fCount);
         SkASSERT(fInsertionIndexInBlock > 0);
         return (const char*)(fBlocks.back()) + (fInsertionIndexInBlock - 1) * fItemSize;
     }

     /**
      * Iterates through the allocator. This is faster than using operator[] when walking linearly
      * through the allocator.
      */
     class Iter {
     public:
         /**
          * Initializes the iterator. next() must be called before get().
          */
         Iter(const GrAllocator* allocator)
             : fAllocator(allocator)
             , fBlockIndex(-1)
             , fIndexInBlock(allocator->fItemsPerBlock - 1)
             , fItemIndex(-1) {}

         /**
          * Advances the iterator. Iteration is finished when next() returns false.
          */
         bool next() {
             ++fIndexInBlock;
             ++fItemIndex;
             if (fIndexInBlock == fAllocator->fItemsPerBlock) {
                 ++fBlockIndex;
                 fIndexInBlock = 0;
             }
             return fItemIndex < fAllocator->fCount;
         }

         /**
          * Gets the current iterator value. Call next() at least once before calling. Don't call
          * after next() returns false.
          */
         void* get() const {
             SkASSERT(fItemIndex >= 0 && fItemIndex < fAllocator->fCount);
             return (char*) fAllocator->fBlocks[fBlockIndex] + fIndexInBlock * fAllocator->fItemSize;
         }

     private:
         const GrAllocator* fAllocator;
         int                fBlockIndex;
         int                fIndexInBlock;
         int                fItemIndex;
     };

     /**
      * Access item by index.
      */
     void* operator[] (int i) {
         SkASSERT(i >= 0 && i < fCount);
         return (char*)fBlocks[i / fItemsPerBlock] +
                fItemSize * (i % fItemsPerBlock);
     }

     /**
      * Access item by index.
      */
     const void* operator[] (int i) const {
         SkASSERT(i >= 0 && i < fCount);
         return (const char*)fBlocks[i / fItemsPerBlock] +
                fItemSize * (i % fItemsPerBlock);
     }

 protected:
     /**
      * Set first block of memory to write into.  Must be called before any other methods.
      * This requires that you have passed nullptr in the constructor.
      *
      * @param   initialBlock    optional memory to use for the first block.
      *                          Must be at least itemSize*itemsPerBlock sized.
      *                          Caller is responsible for freeing this memory.
      */
     void setInitialBlock(void* initialBlock) {
         SkASSERT(0 == fCount);
         SkASSERT(0 == fBlocks.count());
         SkASSERT(fItemsPerBlock == fInsertionIndexInBlock);
         fOwnFirstBlock = false;
         fBlocks.push_back() = initialBlock;
         fInsertionIndexInBlock = 0;
     }

     // For access to above function.
     template <typename T> friend class GrTAllocator;

 private:
     static const int NUM_INIT_BLOCK_PTRS = 8;

     SkSTArray<NUM_INIT_BLOCK_PTRS, void*, true>   fBlocks;
     size_t                                        fBlockSize;
     size_t                                        fItemSize;
     int                                           fItemsPerBlock;
     bool                                          fOwnFirstBlock;
     int                                           fCount;
     int                                           fInsertionIndexInBlock;

     typedef SkNoncopyable INHERITED;
 };

 template <typename T> class GrTAllocator;
 template <typename T> void* operator new(size_t, GrTAllocator<T>*);

 template <typename T> class GrTAllocator : SkNoncopyable {
 public:
     virtual ~GrTAllocator() { this->reset(); };

     /**
      * Create an allocator
      *
      * @param   itemsPerBlock   the number of items to allocate at once
      */
     explicit GrTAllocator(int itemsPerBlock)
         : fAllocator(sizeof(T), itemsPerBlock, nullptr) {}

     /**
      * Adds an item and returns it.
      *
      * @return the added item.
      */
     T& push_back() {
         void* item = fAllocator.push_back();
         SkASSERT(item);
         new (item) T;
         return *(T*)item;
     }

     T& push_back(const T& t) {
         void* item = fAllocator.push_back();
         SkASSERT(item);
         new (item) T(t);
         return *(T*)item;
     }

     /**
      * Remove the last item, only call if count() != 0
      */
     void pop_back() {
         this->back().~T();
         fAllocator.pop_back();
     }

     /**
      * Removes all added items.
      */
     void reset() {
         int c = fAllocator.count();
         for (int i = 0; i < c; ++i) {
             ((T*)fAllocator[i])->~T();
         }
         fAllocator.reset();
     }

     /**
      * Returns the item count.
      */
     int count() const {
         return fAllocator.count();
     }

     /**
      * Is the count 0?
      */
     bool empty() const { return fAllocator.empty(); }

     /**
      * Access last item, only call if count() != 0
      */
     T& back() {
         return *(T*)fAllocator.back();
     }

     /**
      * Access last item, only call if count() != 0
      */
     const T& back() const {
         return *(const T*)fAllocator.back();
     }

     /**
      * Iterates through the allocator. This is faster than using operator[] when walking linearly
      * through the allocator.
      */
     class Iter {
     public:
         /**
          * Initializes the iterator. next() must be called before get() or ops * and ->.
          */
         Iter(const GrTAllocator* allocator) : fImpl(&allocator->fAllocator) {}

         /**
          * Advances the iterator. Iteration is finished when next() returns false.
          */
         bool next() { return fImpl.next(); }

         /**
          * Gets the current iterator value. Call next() at least once before calling. Don't call
          * after next() returns false.
          */
         T* get() const { return (T*) fImpl.get(); }

         /**
          * Convenience operators. Same rules for calling apply as get().
          */
         T& operator*() const { return *this->get(); }
         T* operator->() const { return this->get(); }

     private:
         GrAllocator::Iter fImpl;
     };

     /**
      * Access item by index.
      */
     T& operator[] (int i) {
         return *(T*)(fAllocator[i]);
     }

     /**
      * Access item by index.
      */
     const T& operator[] (int i) const {
         return *(const T*)(fAllocator[i]);
     }

 protected:
     /*
      * Set first block of memory to write into.  Must be called before any other methods.
      *
      * @param   initialBlock    optional memory to use for the first block.
      *                          Must be at least size(T)*itemsPerBlock sized.
      *                          Caller is responsible for freeing this memory.
      */
     void setInitialBlock(void* initialBlock) {
         fAllocator.setInitialBlock(initialBlock);
     }

 private:
     friend void* operator new<T>(size_t, GrTAllocator*);

     GrAllocator fAllocator;
     typedef SkNoncopyable INHERITED;
 };

 template <int N, typename T> class GrSTAllocator : public GrTAllocator<T> {
 private:
     typedef GrTAllocator<T> INHERITED;

 public:
     GrSTAllocator() : INHERITED(N) {
         this->setInitialBlock(fStorage.get());
     }

 private:
     SkAlignedSTStorage<N, T> fStorage;
 };

 template <typename T> void* operator new(size_t size, GrTAllocator<T>* allocator) {
     return allocator->fAllocator.push_back();
 }

 // Skia doesn't use C++ exceptions but it may be compiled with them enabled. Having an op delete
 // to match the op new silences warnings about missing op delete when a constructor throws an
 // exception.
 template <typename T> void operator delete(void*, GrTAllocator<T>*) {
     SK_ABORT("Invalid Operation");
 }

 #define GrNEW_APPEND_TO_ALLOCATOR(allocator_ptr, type_name, args) \
     new (allocator_ptr) type_name args

 #endif
	/*
	* Copyright 2010 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef GrAllocator_DEFINED
	#define GrAllocator_DEFINED

	#include "GrConfig.h"
	#include "GrTypes.h"
	#include "SkTArray.h"
	#include "SkTypes.h"

	class GrAllocator : SkNoncopyable {
	public:
	~GrAllocator() { this->reset(); }

	/**
	* Create an allocator
	*
	* @param itemSize the size of each item to allocate
	* @param itemsPerBlock the number of items to allocate at once
	* @param initialBlock optional memory to use for the first block.
	* Must be at least itemSize*itemsPerBlock sized.
	* Caller is responsible for freeing this memory.
	*/
	GrAllocator(size_t itemSize, int itemsPerBlock, void* initialBlock)
	: fItemSize(itemSize)
	, fItemsPerBlock(itemsPerBlock)
	, fOwnFirstBlock(nullptr == initialBlock)
	, fCount(0)
	, fInsertionIndexInBlock(0) {
	SkASSERT(itemsPerBlock > 0);
	fBlockSize = fItemSize * fItemsPerBlock;
	if (fOwnFirstBlock) {
	// This force us to allocate a new block on push_back().
	fInsertionIndexInBlock = fItemsPerBlock;
	} else {
	fBlocks.push_back() = initialBlock;
	fInsertionIndexInBlock = 0;
	}
	}

	/**
	* Adds an item and returns pointer to it.
	*
	* @return pointer to the added item.
	*/
	void* push_back() {
	// we always have at least one block
	if (fItemsPerBlock == fInsertionIndexInBlock) {
	fBlocks.push_back() = sk_malloc_throw(fBlockSize);
	fInsertionIndexInBlock = 0;
	}
	void* ret = (char)fBlocks.back() + fItemSize fInsertionIndexInBlock;
	++fCount;
	++fInsertionIndexInBlock;
	return ret;
	}

	/**
	* Remove the last item, only call if count() != 0
	*/
	void pop_back() {
	SkASSERT(fCount);
	SkASSERT(fInsertionIndexInBlock > 0);
	--fInsertionIndexInBlock;
	--fCount;
	if (0 == fInsertionIndexInBlock) {
	// Never delete the first block
	if (fBlocks.count() > 1) {
	sk_free(fBlocks.back());
	fBlocks.pop_back();
	fInsertionIndexInBlock = fItemsPerBlock;
	}
	}
	}

	/**
	* Removes all added items.
	*/
	void reset() {
	int firstBlockToFree = fOwnFirstBlock ? 0 : 1;
	for (int i = firstBlockToFree; i < fBlocks.count(); ++i) {
	sk_free(fBlocks[i]);
	}
	if (fOwnFirstBlock) {
	fBlocks.reset();
	// This force us to allocate a new block on push_back().
	fInsertionIndexInBlock = fItemsPerBlock;
	} else {
	fBlocks.pop_back_n(fBlocks.count() - 1);
	fInsertionIndexInBlock = 0;
	}
	fCount = 0;
	}

	/**
	* Returns the item count.
	*/
	int count() const {
	return fCount;
	}

	/**
	* Is the count 0?
	*/
	bool empty() const { return 0 == fCount; }

	/**
	* Access last item, only call if count() != 0
	*/
	void* back() {
	SkASSERT(fCount);
	SkASSERT(fInsertionIndexInBlock > 0);
	return (char)(fBlocks.back()) + (fInsertionIndexInBlock - 1) fItemSize;
	}

	/**
	* Access last item, only call if count() != 0
	*/
	const void* back() const {
	SkASSERT(fCount);
	SkASSERT(fInsertionIndexInBlock > 0);
	return (const char)(fBlocks.back()) + (fInsertionIndexInBlock - 1) fItemSize;
	}

	/**
	* Iterates through the allocator. This is faster than using operator[] when walking linearly
	* through the allocator.
	*/
	class Iter {
	public:
	/**
	* Initializes the iterator. next() must be called before get().
	*/
	Iter(const GrAllocator* allocator)
	: fAllocator(allocator)
	, fBlockIndex(-1)
	, fIndexInBlock(allocator->fItemsPerBlock - 1)
	, fItemIndex(-1) {}

	/**
	* Advances the iterator. Iteration is finished when next() returns false.
	*/
	bool next() {
	++fIndexInBlock;
	++fItemIndex;
	if (fIndexInBlock == fAllocator->fItemsPerBlock) {
	++fBlockIndex;
	fIndexInBlock = 0;
	}
	return fItemIndex < fAllocator->fCount;
	}

	/**
	* Gets the current iterator value. Call next() at least once before calling. Don't call
	* after next() returns false.
	*/
	void* get() const {
	SkASSERT(fItemIndex >= 0 && fItemIndex < fAllocator->fCount);
	return (char) fAllocator->fBlocks[fBlockIndex] + fIndexInBlock fAllocator->fItemSize;
	}

	private:
	const GrAllocator* fAllocator;
	int fBlockIndex;
	int fIndexInBlock;
	int fItemIndex;
	};

	/**
	* Access item by index.
	*/
	void* operator[] (int i) {
	SkASSERT(i >= 0 && i < fCount);
	return (char*)fBlocks[i / fItemsPerBlock] +
	fItemSize * (i % fItemsPerBlock);
	}

	/**
	* Access item by index.
	*/
	const void* operator[] (int i) const {
	SkASSERT(i >= 0 && i < fCount);
	return (const char*)fBlocks[i / fItemsPerBlock] +
	fItemSize * (i % fItemsPerBlock);
	}

	protected:
	/**
	* Set first block of memory to write into. Must be called before any other methods.
	* This requires that you have passed nullptr in the constructor.
	*
	* @param initialBlock optional memory to use for the first block.
	* Must be at least itemSize*itemsPerBlock sized.
	* Caller is responsible for freeing this memory.
	*/
	void setInitialBlock(void* initialBlock) {
	SkASSERT(0 == fCount);
	SkASSERT(0 == fBlocks.count());
	SkASSERT(fItemsPerBlock == fInsertionIndexInBlock);
	fOwnFirstBlock = false;
	fBlocks.push_back() = initialBlock;
	fInsertionIndexInBlock = 0;
	}

	// For access to above function.
	template <typename T> friend class GrTAllocator;

	private:
	static const int NUM_INIT_BLOCK_PTRS = 8;

	SkSTArray<NUM_INIT_BLOCK_PTRS, void*, true> fBlocks;
	size_t fBlockSize;
	size_t fItemSize;
	int fItemsPerBlock;
	bool fOwnFirstBlock;
	int fCount;
	int fInsertionIndexInBlock;

	typedef SkNoncopyable INHERITED;
	};

	template <typename T> class GrTAllocator;
	template <typename T> void* operator new(size_t, GrTAllocator<T>*);

	template <typename T> class GrTAllocator : SkNoncopyable {
	public:
	virtual ~GrTAllocator() { this->reset(); };

	/**
	* Create an allocator
	*
	* @param itemsPerBlock the number of items to allocate at once
	*/
	explicit GrTAllocator(int itemsPerBlock)
	: fAllocator(sizeof(T), itemsPerBlock, nullptr) {}

	/**
	* Adds an item and returns it.
	*
	* @return the added item.
	*/
	T& push_back() {
	void* item = fAllocator.push_back();
	SkASSERT(item);
	new (item) T;
	return (T)item;
	}

	T& push_back(const T& t) {
	void* item = fAllocator.push_back();
	SkASSERT(item);
	new (item) T(t);
	return (T)item;
	}

	/**
	* Remove the last item, only call if count() != 0
	*/
	void pop_back() {
	this->back().~T();
	fAllocator.pop_back();
	}

	/**
	* Removes all added items.
	*/
	void reset() {
	int c = fAllocator.count();
	for (int i = 0; i < c; ++i) {
	((T*)fAllocator[i])->~T();
	}
	fAllocator.reset();
	}

	/**
	* Returns the item count.
	*/
	int count() const {
	return fAllocator.count();
	}

	/**
	* Is the count 0?
	*/
	bool empty() const { return fAllocator.empty(); }

	/**
	* Access last item, only call if count() != 0
	*/
	T& back() {
	return (T)fAllocator.back();
	}

	/**
	* Access last item, only call if count() != 0
	*/
	const T& back() const {
	return (const T)fAllocator.back();
	}

	/**
	* Iterates through the allocator. This is faster than using operator[] when walking linearly
	* through the allocator.
	*/
	class Iter {
	public:
	/**
	* Initializes the iterator. next() must be called before get() or ops * and ->.
	*/
	Iter(const GrTAllocator* allocator) : fImpl(&allocator->fAllocator) {}

	/**
	* Advances the iterator. Iteration is finished when next() returns false.
	*/
	bool next() { return fImpl.next(); }

	/**
	* Gets the current iterator value. Call next() at least once before calling. Don't call
	* after next() returns false.
	*/
	T* get() const { return (T*) fImpl.get(); }

	/**
	* Convenience operators. Same rules for calling apply as get().
	*/
	T& operator() const { return this->get(); }
	T* operator->() const { return this->get(); }

	private:
	GrAllocator::Iter fImpl;
	};

	/**
	* Access item by index.
	*/
	T& operator[] (int i) {
	return (T)(fAllocator[i]);
	}

	/**
	* Access item by index.
	*/
	const T& operator[] (int i) const {
	return (const T)(fAllocator[i]);
	}

	protected:
	/*
	* Set first block of memory to write into. Must be called before any other methods.
	*
	* @param initialBlock optional memory to use for the first block.
	* Must be at least size(T)*itemsPerBlock sized.
	* Caller is responsible for freeing this memory.
	*/
	void setInitialBlock(void* initialBlock) {
	fAllocator.setInitialBlock(initialBlock);
	}

	private:
	friend void* operator new<T>(size_t, GrTAllocator*);

	GrAllocator fAllocator;
	typedef SkNoncopyable INHERITED;
	};

	template <int N, typename T> class GrSTAllocator : public GrTAllocator<T> {
	private:
	typedef GrTAllocator<T> INHERITED;

	public:
	GrSTAllocator() : INHERITED(N) {
	this->setInitialBlock(fStorage.get());
	}

	private:
	SkAlignedSTStorage<N, T> fStorage;
	};

	template <typename T> void* operator new(size_t size, GrTAllocator<T>* allocator) {
	return allocator->fAllocator.push_back();
	}

	// Skia doesn't use C++ exceptions but it may be compiled with them enabled. Having an op delete
	// to match the op new silences warnings about missing op delete when a constructor throws an
	// exception.
	template <typename T> void operator delete(void, GrTAllocator<T>) {
	SK_ABORT("Invalid Operation");
	}

	#define GrNEW_APPEND_TO_ALLOCATOR(allocator_ptr, type_name, args) \
	new (allocator_ptr) type_name args

	#endif