src/gpu/GrTDArray.h - platform/external/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 GrTDArray_DEFINED
 #define GrTDArray_DEFINED

 #include "GrTypes.h"
 #include "GrRefCnt.h"

 static int GrInitialArrayAllocationCount() {
     return 4;
 }

 static int GrNextArrayAllocationCount(int count) {
     return count + ((count + 1) >> 1);
 }

 template <typename T> class GrTDArray {
 public:
     GrTDArray() : fArray(NULL), fAllocated(0), fCount(0) {}
     GrTDArray(const GrTDArray& src) {
         fCount = fAllocated = src.fCount;
         fArray = (T*)GrMalloc(fAllocated * sizeof(T));
         memcpy(fArray, src.fArray, fCount * sizeof(T));
     }
     ~GrTDArray() {
         if (fArray) {
             GrFree(fArray);
         }
     }

     bool isEmpty() const { return 0 == fCount; }
     int count() const { return fCount; }

     const T& at(int index) const {
         GrAssert((unsigned)index < (unsigned)fCount);
         return fArray[index];
     }
     T& at(int index) {
         GrAssert((unsigned)index < (unsigned)fCount);
         return fArray[index];
     }

     const T& operator[](int index) const { return this->at(index); }
     T& operator[](int index) { return this->at(index); }

     GrTDArray& operator=(const GrTDArray& src) {
         if (fAllocated < src.fCount) {
             fAllocated = src.fCount;
             GrFree(fArray);
             fArray = (T*)GrMalloc(fAllocated * sizeof(T));
         }
         fCount = src.fCount;
         memcpy(fArray, src.fArray, fCount * sizeof(T));
         return *this;
     }

     void reset() {
         if (fArray) {
             GrFree(fArray);
             fArray = NULL;
         }
         fAllocated = fCount = 0;
     }

     T* begin() const { return fArray; }
     T* end() const { return fArray + fCount; }
     T* back() const { GrAssert(fCount); return fArray + (fCount - 1); }

     T* prepend() {
         this->growAt(0);
         return fArray;
     }

     T* append() {
         this->growAt(fCount);
         return fArray + fCount - 1;
     }

     /**
      *  index may be [0..count], so that you can insert at the end (like append)
      */
     T* insert(int index) {
         GrAssert((unsigned)index <= (unsigned)fCount);
         this->growAt(index);
         return fArray + index;
     }

     void remove(int index) {
         GrAssert((unsigned)index < (unsigned)fCount);
         fCount -= 1;
         if (index < fCount) {
             int remaining = fCount - index;
             memmove(fArray + index, fArray + index + 1, remaining * sizeof(T));
         }
     }

     void removeShuffle(int index) {
         GrAssert((unsigned)index < (unsigned)fCount);
         fCount -= 1;
         if (index < fCount) {
             memmove(fArray + index, fArray + fCount, sizeof(T));
         }
     }

     // Utility iterators

     /**
      *  Calls GrFree() on each element. Assumes each is NULL or was allocated
      *  with GrMalloc().
      */
     void freeAll() {
         T* stop = this->end();
         for (T* curr = this->begin(); curr < stop; curr++) {
             GrFree(*curr);
         }
         this->reset();
     }

     /**
      *  Calls delete on each element. Assumes each is NULL or was allocated
      *  with new.
      */
     void deleteAll() {
         T* stop = this->end();
         for (T* curr = this->begin(); curr < stop; curr++) {
             delete *curr;
         }
         this->reset();
     }

     /**
      *  Calls GrSafeUnref() on each element. Assumes each is NULL or is a
      *  subclass of GrRefCnt.
      */
     void unrefAll() {
         T* stop = this->end();
         for (T* curr = this->begin(); curr < stop; curr++) {
             GrSafeUnref(*curr);
         }
         this->reset();
     }

     void visit(void visitor(T&)) const {
         T* stop = this->end();
         for (T* curr = this->begin(); curr < stop; curr++) {
             if (*curr) {
                 visitor(*curr);
             }
         }
     }

     int find(const T& elem) const {
         int count = this->count();
         T* curr = this->begin();
         for (int i = 0; i < count; i++) {
             if (elem == curr[i]) {
                 return i;
             }
         }
         return -1;
     }

     friend bool operator==(const GrTDArray<T>& a, const GrTDArray<T>& b) {
         return a.count() == b.count() &&
                (0 == a.count() ||
                 0 == memcmp(a.begin(), b.begin(), a.count() * sizeof(T)));
     }
     friend bool operator!=(const GrTDArray<T>& a, const GrTDArray<T>& b) {
         return !(a == b);
     }

 private:
     T*  fArray;
     int fAllocated, fCount;

     // growAt will increment fCount, reallocate fArray (as needed), and slide
     // the contents of fArray to make a hole for new data at index.
     void growAt(int index) {
         GrAssert(fCount <= fAllocated);
         if (0 == fAllocated) {
             fAllocated = GrInitialArrayAllocationCount();
             fArray = (T*)GrMalloc(fAllocated * sizeof(T));
         } else if (fCount == fAllocated) {
             fAllocated = GrNextArrayAllocationCount(fAllocated);
             T* newArray = (T*)GrMalloc(fAllocated * sizeof(T));
             memcpy(newArray, fArray, index * sizeof(T));
             memcpy(newArray + index + 1, fArray + index,
                    (fCount - index) * sizeof(T));
             GrFree(fArray);
             fArray = newArray;
         } else {
             // check that we're not just appending
             if (index < fCount) {
                 memmove(fArray + index + 1, fArray + index,
                         (fCount - index) * sizeof(T));
             }
         }
         GrAssert(fCount < fAllocated);
         fCount += 1;
     }
 };

 extern void* GrTDArray_growAt(void*, int* allocated, int& count, int index,
                               size_t);


 #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 GrTDArray_DEFINED
	#define GrTDArray_DEFINED

	#include "GrTypes.h"
	#include "GrRefCnt.h"

	static int GrInitialArrayAllocationCount() {
	return 4;
	}

	static int GrNextArrayAllocationCount(int count) {
	return count + ((count + 1) >> 1);
	}

	template <typename T> class GrTDArray {
	public:
	GrTDArray() : fArray(NULL), fAllocated(0), fCount(0) {}
	GrTDArray(const GrTDArray& src) {
	fCount = fAllocated = src.fCount;
	fArray = (T)GrMalloc(fAllocated sizeof(T));
	memcpy(fArray, src.fArray, fCount * sizeof(T));
	}
	~GrTDArray() {
	if (fArray) {
	GrFree(fArray);
	}
	}

	bool isEmpty() const { return 0 == fCount; }
	int count() const { return fCount; }

	const T& at(int index) const {
	GrAssert((unsigned)index < (unsigned)fCount);
	return fArray[index];
	}
	T& at(int index) {
	GrAssert((unsigned)index < (unsigned)fCount);
	return fArray[index];
	}

	const T& operator[](int index) const { return this->at(index); }
	T& operator[](int index) { return this->at(index); }

	GrTDArray& operator=(const GrTDArray& src) {
	if (fAllocated < src.fCount) {
	fAllocated = src.fCount;
	GrFree(fArray);
	fArray = (T)GrMalloc(fAllocated sizeof(T));
	}
	fCount = src.fCount;
	memcpy(fArray, src.fArray, fCount * sizeof(T));
	return *this;
	}

	void reset() {
	if (fArray) {
	GrFree(fArray);
	fArray = NULL;
	}
	fAllocated = fCount = 0;
	}

	T* begin() const { return fArray; }
	T* end() const { return fArray + fCount; }
	T* back() const { GrAssert(fCount); return fArray + (fCount - 1); }

	T* prepend() {
	this->growAt(0);
	return fArray;
	}

	T* append() {
	this->growAt(fCount);
	return fArray + fCount - 1;
	}

	/**
	* index may be [0..count], so that you can insert at the end (like append)
	*/
	T* insert(int index) {
	GrAssert((unsigned)index <= (unsigned)fCount);
	this->growAt(index);
	return fArray + index;
	}

	void remove(int index) {
	GrAssert((unsigned)index < (unsigned)fCount);
	fCount -= 1;
	if (index < fCount) {
	int remaining = fCount - index;
	memmove(fArray + index, fArray + index + 1, remaining * sizeof(T));
	}
	}

	void removeShuffle(int index) {
	GrAssert((unsigned)index < (unsigned)fCount);
	fCount -= 1;
	if (index < fCount) {
	memmove(fArray + index, fArray + fCount, sizeof(T));
	}
	}

	// Utility iterators

	/**
	* Calls GrFree() on each element. Assumes each is NULL or was allocated
	* with GrMalloc().
	*/
	void freeAll() {
	T* stop = this->end();
	for (T* curr = this->begin(); curr < stop; curr++) {
	GrFree(*curr);
	}
	this->reset();
	}

	/**
	* Calls delete on each element. Assumes each is NULL or was allocated
	* with new.
	*/
	void deleteAll() {
	T* stop = this->end();
	for (T* curr = this->begin(); curr < stop; curr++) {
	delete *curr;
	}
	this->reset();
	}

	/**
	* Calls GrSafeUnref() on each element. Assumes each is NULL or is a
	* subclass of GrRefCnt.
	*/
	void unrefAll() {
	T* stop = this->end();
	for (T* curr = this->begin(); curr < stop; curr++) {
	GrSafeUnref(*curr);
	}
	this->reset();
	}

	void visit(void visitor(T&)) const {
	T* stop = this->end();
	for (T* curr = this->begin(); curr < stop; curr++) {
	if (*curr) {
	visitor(*curr);
	}
	}
	}

	int find(const T& elem) const {
	int count = this->count();
	T* curr = this->begin();
	for (int i = 0; i < count; i++) {
	if (elem == curr[i]) {
	return i;
	}
	}
	return -1;
	}

	friend bool operator==(const GrTDArray<T>& a, const GrTDArray<T>& b) {
	return a.count() == b.count() &&
	(0 == a.count() \|\|
	0 == memcmp(a.begin(), b.begin(), a.count() * sizeof(T)));
	}
	friend bool operator!=(const GrTDArray<T>& a, const GrTDArray<T>& b) {
	return !(a == b);
	}

	private:
	T* fArray;
	int fAllocated, fCount;

	// growAt will increment fCount, reallocate fArray (as needed), and slide
	// the contents of fArray to make a hole for new data at index.
	void growAt(int index) {
	GrAssert(fCount <= fAllocated);
	if (0 == fAllocated) {
	fAllocated = GrInitialArrayAllocationCount();
	fArray = (T)GrMalloc(fAllocated sizeof(T));
	} else if (fCount == fAllocated) {
	fAllocated = GrNextArrayAllocationCount(fAllocated);
	T* newArray = (T)GrMalloc(fAllocated sizeof(T));
	memcpy(newArray, fArray, index * sizeof(T));
	memcpy(newArray + index + 1, fArray + index,
	(fCount - index) * sizeof(T));
	GrFree(fArray);
	fArray = newArray;
	} else {
	// check that we're not just appending
	if (index < fCount) {
	memmove(fArray + index + 1, fArray + index,
	(fCount - index) * sizeof(T));
	}
	}
	GrAssert(fCount < fAllocated);
	fCount += 1;
	}
	};

	extern void* GrTDArray_growAt(void, int allocated, int& count, int index,
	size_t);


	#endif