include/core/SkTArray.h - platform/external/skia - Git at Google

 /*
  * Copyright 2011 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef SkTArray_DEFINED
 #define SkTArray_DEFINED

 #include <new>
 #include "SkTypes.h"
 #include "SkTemplates.h"

 template <typename T, bool MEM_COPY = false> class SkTArray;

 namespace SkTArrayExt {

 template<typename T>
 inline void copy(SkTArray<T, true>* self, const T* array) {
     memcpy(self->fMemArray, array, self->fCount * sizeof(T));
 }
 template<typename T>
 inline void copyAndDelete(SkTArray<T, true>* self, char* newMemArray) {
     memcpy(newMemArray, self->fMemArray, self->fCount * sizeof(T));
 }

 template<typename T>
 inline void copy(SkTArray<T, false>* self, const T* array) {
     for (int i = 0; i < self->fCount; ++i) {
         new (self->fItemArray + i) T(array[i]);
     }
 }
 template<typename T>
 inline void copyAndDelete(SkTArray<T, false>* self, char* newMemArray) {
     for (int i = 0; i < self->fCount; ++i) {
         new (newMemArray + sizeof(T) * i) T(self->fItemArray[i]);
         self->fItemArray[i].~T();
     }
 }

 }

 /** When MEM_COPY is true T will be bit copied when moved.
     When MEM_COPY is false, T will be copy constructed / destructed.
     In all cases T's constructor will be called on allocation,
     and its destructor will be called from this object's destructor.
 */
 template <typename T, bool MEM_COPY> class SkTArray {
 public:
     /**
      * Creates an empty array with no initial storage
      */
     SkTArray() {
         fCount = 0;
         fReserveCount = gMIN_ALLOC_COUNT;
         fAllocCount = 0;
         fMemArray = NULL;
         fPreAllocMemArray = NULL;
     }

     /**
      * Creates an empty array that will preallocate space for reserveCount
      * elements.
      */
     explicit SkTArray(int reserveCount) {
         this->init(NULL, 0, NULL, reserveCount);
     }

     /**
      * Copies one array to another. The new array will be heap allocated.
      */
     explicit SkTArray(const SkTArray& array) {
         this->init(array.fItemArray, array.fCount, NULL, 0);
     }

     /**
      * Creates a SkTArray by copying contents of a standard C array. The new
      * array will be heap allocated. Be careful not to use this constructor
      * when you really want the (void*, int) version.
      */
     SkTArray(const T* array, int count) {
         this->init(array, count, NULL, 0);
     }

     /**
      * assign copy of array to this
      */
     SkTArray& operator =(const SkTArray& array) {
         for (int i = 0; i < fCount; ++i) {
             fItemArray[i].~T();
         }
         fCount = 0;
         checkRealloc((int)array.count());
         fCount = array.count();
         SkTArrayExt::copy(this, static_cast<const T*>(array.fMemArray));
         return *this;
     }

     virtual ~SkTArray() {
         for (int i = 0; i < fCount; ++i) {
             fItemArray[i].~T();
         }
         if (fMemArray != fPreAllocMemArray) {
             sk_free(fMemArray);
         }
     }

     /**
      * Resets to count() == 0
      */
     void reset() { this->pop_back_n(fCount); }

     /**
      * Number of elements in the array.
      */
     int count() const { return fCount; }

     /**
      * Is the array empty.
      */
     bool empty() const { return !fCount; }

     /**
      * Adds 1 new default-constructed T value and returns in by reference. Note
      * the reference only remains valid until the next call that adds or removes
      * elements.
      */
     T& push_back() {
         checkRealloc(1);
         new ((char*)fMemArray+sizeof(T)*fCount) T;
         ++fCount;
         return fItemArray[fCount-1];
     }

     /**
      * Version of above that uses a copy constructor to initialize the new item
      */
     T& push_back(const T& t) {
         checkRealloc(1);
         new ((char*)fMemArray+sizeof(T)*fCount) T(t);
         ++fCount;
         return fItemArray[fCount-1];
     }

     /**
      * Allocates n more default T values, and returns the address of the start
      * of that new range. Note: this address is only valid until the next API
      * call made on the array that might add or remove elements.
      */
     T* push_back_n(int n) {
         SkASSERT(n >= 0);
         checkRealloc(n);
         for (int i = 0; i < n; ++i) {
             new (fItemArray + fCount + i) T;
         }
         fCount += n;
         return fItemArray + fCount - n;
     }

     /**
      * Version of above that uses a copy constructor to initialize all n items
      * to the same T.
      */
     T* push_back_n(int n, const T& t) {
         SkASSERT(n >= 0);
         checkRealloc(n);
         for (int i = 0; i < n; ++i) {
             new (fItemArray + fCount + i) T(t);
         }
         fCount += n;
         return fItemArray + fCount - n;
     }

     /**
      * Version of above that uses a copy constructor to initialize the n items
      * to separate T values.
      */
     T* push_back_n(int n, const T t[]) {
         SkASSERT(n >= 0);
         checkRealloc(n);
         for (int i = 0; i < n; ++i) {
             new (fItemArray + fCount + i) T(t[i]);
         }
         fCount += n;
         return fItemArray + fCount - n;
     }

     /**
      * Removes the last element. Not safe to call when count() == 0.
      */
     void pop_back() {
         SkASSERT(fCount > 0);
         --fCount;
         fItemArray[fCount].~T();
         checkRealloc(0);
     }

     /**
      * Removes the last n elements. Not safe to call when count() < n.
      */
     void pop_back_n(int n) {
         SkASSERT(n >= 0);
         SkASSERT(fCount >= n);
         fCount -= n;
         for (int i = 0; i < n; ++i) {
             fItemArray[i].~T();
         }
         checkRealloc(0);
     }

     /**
      * Pushes or pops from the back to resize. Pushes will be default
      * initialized.
      */
     void resize_back(int newCount) {
         SkASSERT(newCount >= 0);

         if (newCount > fCount) {
             push_back_n(newCount - fCount);
         } else if (newCount < fCount) {
             pop_back_n(fCount - newCount);
         }
     }

     /**
      * Get the i^th element.
      */
     T& operator[] (int i) {
         SkASSERT(i < fCount);
         SkASSERT(i >= 0);
         return fItemArray[i];
     }

     const T& operator[] (int i) const {
         SkASSERT(i < fCount);
         SkASSERT(i >= 0);
         return fItemArray[i];
     }

     /**
      * equivalent to operator[](0)
      */
     T& front() { SkASSERT(fCount > 0); return fItemArray[0];}

     const T& front() const { SkASSERT(fCount > 0); return fItemArray[0];}

     /**
      * equivalent to operator[](count() - 1)
      */
     T& back() { SkASSERT(fCount); return fItemArray[fCount - 1];}

     const T& back() const { SkASSERT(fCount > 0); return fItemArray[fCount - 1];}

     /**
      * equivalent to operator[](count()-1-i)
      */
     T& fromBack(int i) {
         SkASSERT(i >= 0);
         SkASSERT(i < fCount);
         return fItemArray[fCount - i - 1];
     }

     const T& fromBack(int i) const {
         SkASSERT(i >= 0);
         SkASSERT(i < fCount);
         return fItemArray[fCount - i - 1];
     }

 protected:
     /**
      * Creates an empty array that will use the passed storage block until it
      * is insufficiently large to hold the entire array.
      */
     template <int N>
     SkTArray(SkAlignedSTStorage<N,T>* storage) {
         this->init(NULL, 0, storage->get(), N);
     }

     /**
      * Copy another array, using preallocated storage if preAllocCount >=
      * array.count(). Otherwise storage will only be used when array shrinks
      * to fit.
      */
     template <int N>
     SkTArray(const SkTArray& array, SkAlignedSTStorage<N,T>* storage) {
         this->init(array.fItemArray, array.fCount, storage->get(), N);
     }

     /**
      * Copy a C array, using preallocated storage if preAllocCount >=
      * count. Otherwise storage will only be used when array shrinks
      * to fit.
      */
     template <int N>
     SkTArray(const T* array, int count, SkAlignedSTStorage<N,T>* storage) {
         this->init(array, count, storage->get(), N);
     }

     void init(const T* array, int count,
                void* preAllocStorage, int preAllocOrReserveCount) {
         SkASSERT(count >= 0);
         SkASSERT(preAllocOrReserveCount >= 0);
         fCount              = count;
         fReserveCount       = (preAllocOrReserveCount > 0) ?
                                     preAllocOrReserveCount :
                                     gMIN_ALLOC_COUNT;
         fPreAllocMemArray   = preAllocStorage;
         if (fReserveCount >= fCount &&
             NULL != preAllocStorage) {
             fAllocCount = fReserveCount;
             fMemArray = preAllocStorage;
         } else {
             fAllocCount = SkMax32(fCount, fReserveCount);
             fMemArray = sk_malloc_throw(fAllocCount * sizeof(T));
         }

         SkTArrayExt::copy(this, array);
     }

 private:

     static const int gMIN_ALLOC_COUNT = 8;

     inline void checkRealloc(int delta) {
         SkASSERT(fCount >= 0);
         SkASSERT(fAllocCount >= 0);

         SkASSERT(-delta <= fCount);

         int newCount = fCount + delta;
         int newAllocCount = fAllocCount;

         if (newCount > fAllocCount) {
             newAllocCount = SkMax32(newCount + ((newCount + 1) >> 1),
                                    fReserveCount);
         } else if (newCount < fAllocCount / 3) {
             newAllocCount = SkMax32(fAllocCount / 2, fReserveCount);
         }

         if (newAllocCount != fAllocCount) {

             fAllocCount = newAllocCount;
             char* newMemArray;

             if (fAllocCount == fReserveCount && NULL != fPreAllocMemArray) {
                 newMemArray = (char*) fPreAllocMemArray;
             } else {
                 newMemArray = (char*) sk_malloc_throw(fAllocCount*sizeof(T));
             }

             SkTArrayExt::copyAndDelete<T>(this, newMemArray);

             if (fMemArray != fPreAllocMemArray) {
                 sk_free(fMemArray);
             }
             fMemArray = newMemArray;
         }
     }

     template<typename X> friend void SkTArrayExt::copy(SkTArray<X, true>* that, const X*);
     template<typename X> friend void SkTArrayExt::copyAndDelete(SkTArray<X, true>* that, char*);

     template<typename X> friend void SkTArrayExt::copy(SkTArray<X, false>* that, const X*);
     template<typename X> friend void SkTArrayExt::copyAndDelete(SkTArray<X, false>* that, char*);

     int fReserveCount;
     int fCount;
     int fAllocCount;
     void*    fPreAllocMemArray;
     union {
         T*       fItemArray;
         void*    fMemArray;
     };
 };

 /**
  * Subclass of SkTArray that contains a preallocated memory block for the array.
  */
 template <int N, typename T, bool DATA_TYPE = false>
 class SkSTArray : public SkTArray<T, DATA_TYPE> {
 private:
     typedef SkTArray<T, DATA_TYPE> INHERITED;

 public:
     SkSTArray() : INHERITED(&fStorage) {
     }

     SkSTArray(const SkSTArray& array)
         : INHERITED(array, &fStorage) {
     }

     explicit SkSTArray(const INHERITED& array)
         : INHERITED(array, &fStorage) {
     }

     SkSTArray(const T* array, int count)
         : INHERITED(array, count, &fStorage) {
     }

     SkSTArray& operator= (const SkSTArray& array) {
         return *this = *(const INHERITED*)&array;
     }

     SkSTArray& operator= (const INHERITED& array) {
         INHERITED::operator=(array);
         return *this;
     }

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

 #endif
	/*
	* Copyright 2011 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef SkTArray_DEFINED
	#define SkTArray_DEFINED

	#include <new>
	#include "SkTypes.h"
	#include "SkTemplates.h"

	template <typename T, bool MEM_COPY = false> class SkTArray;

	namespace SkTArrayExt {

	template<typename T>
	inline void copy(SkTArray<T, true>* self, const T* array) {
	memcpy(self->fMemArray, array, self->fCount * sizeof(T));
	}
	template<typename T>
	inline void copyAndDelete(SkTArray<T, true>* self, char* newMemArray) {
	memcpy(newMemArray, self->fMemArray, self->fCount * sizeof(T));
	}

	template<typename T>
	inline void copy(SkTArray<T, false>* self, const T* array) {
	for (int i = 0; i < self->fCount; ++i) {
	new (self->fItemArray + i) T(array[i]);
	}
	}
	template<typename T>
	inline void copyAndDelete(SkTArray<T, false>* self, char* newMemArray) {
	for (int i = 0; i < self->fCount; ++i) {
	new (newMemArray + sizeof(T) * i) T(self->fItemArray[i]);
	self->fItemArray[i].~T();
	}
	}

	}

	/** When MEM_COPY is true T will be bit copied when moved.
	When MEM_COPY is false, T will be copy constructed / destructed.
	In all cases T's constructor will be called on allocation,
	and its destructor will be called from this object's destructor.
	*/
	template <typename T, bool MEM_COPY> class SkTArray {
	public:
	/**
	* Creates an empty array with no initial storage
	*/
	SkTArray() {
	fCount = 0;
	fReserveCount = gMIN_ALLOC_COUNT;
	fAllocCount = 0;
	fMemArray = NULL;
	fPreAllocMemArray = NULL;
	}

	/**
	* Creates an empty array that will preallocate space for reserveCount
	* elements.
	*/
	explicit SkTArray(int reserveCount) {
	this->init(NULL, 0, NULL, reserveCount);
	}

	/**
	* Copies one array to another. The new array will be heap allocated.
	*/
	explicit SkTArray(const SkTArray& array) {
	this->init(array.fItemArray, array.fCount, NULL, 0);
	}

	/**
	* Creates a SkTArray by copying contents of a standard C array. The new
	* array will be heap allocated. Be careful not to use this constructor
	* when you really want the (void*, int) version.
	*/
	SkTArray(const T* array, int count) {
	this->init(array, count, NULL, 0);
	}

	/**
	* assign copy of array to this
	*/
	SkTArray& operator =(const SkTArray& array) {
	for (int i = 0; i < fCount; ++i) {
	fItemArray[i].~T();
	}
	fCount = 0;
	checkRealloc((int)array.count());
	fCount = array.count();
	SkTArrayExt::copy(this, static_cast<const T*>(array.fMemArray));
	return *this;
	}

	virtual ~SkTArray() {
	for (int i = 0; i < fCount; ++i) {
	fItemArray[i].~T();
	}
	if (fMemArray != fPreAllocMemArray) {
	sk_free(fMemArray);
	}
	}

	/**
	* Resets to count() == 0
	*/
	void reset() { this->pop_back_n(fCount); }

	/**
	* Number of elements in the array.
	*/
	int count() const { return fCount; }

	/**
	* Is the array empty.
	*/
	bool empty() const { return !fCount; }

	/**
	* Adds 1 new default-constructed T value and returns in by reference. Note
	* the reference only remains valid until the next call that adds or removes
	* elements.
	*/
	T& push_back() {
	checkRealloc(1);
	new ((char)fMemArray+sizeof(T)fCount) T;
	++fCount;
	return fItemArray[fCount-1];
	}

	/**
	* Version of above that uses a copy constructor to initialize the new item
	*/
	T& push_back(const T& t) {
	checkRealloc(1);
	new ((char)fMemArray+sizeof(T)fCount) T(t);
	++fCount;
	return fItemArray[fCount-1];
	}

	/**
	* Allocates n more default T values, and returns the address of the start
	* of that new range. Note: this address is only valid until the next API
	* call made on the array that might add or remove elements.
	*/
	T* push_back_n(int n) {
	SkASSERT(n >= 0);
	checkRealloc(n);
	for (int i = 0; i < n; ++i) {
	new (fItemArray + fCount + i) T;
	}
	fCount += n;
	return fItemArray + fCount - n;
	}

	/**
	* Version of above that uses a copy constructor to initialize all n items
	* to the same T.
	*/
	T* push_back_n(int n, const T& t) {
	SkASSERT(n >= 0);
	checkRealloc(n);
	for (int i = 0; i < n; ++i) {
	new (fItemArray + fCount + i) T(t);
	}
	fCount += n;
	return fItemArray + fCount - n;
	}

	/**
	* Version of above that uses a copy constructor to initialize the n items
	* to separate T values.
	*/
	T* push_back_n(int n, const T t[]) {
	SkASSERT(n >= 0);
	checkRealloc(n);
	for (int i = 0; i < n; ++i) {
	new (fItemArray + fCount + i) T(t[i]);
	}
	fCount += n;
	return fItemArray + fCount - n;
	}

	/**
	* Removes the last element. Not safe to call when count() == 0.
	*/
	void pop_back() {
	SkASSERT(fCount > 0);
	--fCount;
	fItemArray[fCount].~T();
	checkRealloc(0);
	}

	/**
	* Removes the last n elements. Not safe to call when count() < n.
	*/
	void pop_back_n(int n) {
	SkASSERT(n >= 0);
	SkASSERT(fCount >= n);
	fCount -= n;
	for (int i = 0; i < n; ++i) {
	fItemArray[i].~T();
	}
	checkRealloc(0);
	}

	/**
	* Pushes or pops from the back to resize. Pushes will be default
	* initialized.
	*/
	void resize_back(int newCount) {
	SkASSERT(newCount >= 0);

	if (newCount > fCount) {
	push_back_n(newCount - fCount);
	} else if (newCount < fCount) {
	pop_back_n(fCount - newCount);
	}
	}

	/**
	* Get the i^th element.
	*/
	T& operator[] (int i) {
	SkASSERT(i < fCount);
	SkASSERT(i >= 0);
	return fItemArray[i];
	}

	const T& operator[] (int i) const {
	SkASSERT(i < fCount);
	SkASSERT(i >= 0);
	return fItemArray[i];
	}

	/**
	* equivalent to operator[](0)
	*/
	T& front() { SkASSERT(fCount > 0); return fItemArray[0];}

	const T& front() const { SkASSERT(fCount > 0); return fItemArray[0];}

	/**
	* equivalent to operator[](count() - 1)
	*/
	T& back() { SkASSERT(fCount); return fItemArray[fCount - 1];}

	const T& back() const { SkASSERT(fCount > 0); return fItemArray[fCount - 1];}

	/**
	* equivalent to operator[](count()-1-i)
	*/
	T& fromBack(int i) {
	SkASSERT(i >= 0);
	SkASSERT(i < fCount);
	return fItemArray[fCount - i - 1];
	}

	const T& fromBack(int i) const {
	SkASSERT(i >= 0);
	SkASSERT(i < fCount);
	return fItemArray[fCount - i - 1];
	}

	protected:
	/**
	* Creates an empty array that will use the passed storage block until it
	* is insufficiently large to hold the entire array.
	*/
	template <int N>
	SkTArray(SkAlignedSTStorage<N,T>* storage) {
	this->init(NULL, 0, storage->get(), N);
	}

	/**
	* Copy another array, using preallocated storage if preAllocCount >=
	* array.count(). Otherwise storage will only be used when array shrinks
	* to fit.
	*/
	template <int N>
	SkTArray(const SkTArray& array, SkAlignedSTStorage<N,T>* storage) {
	this->init(array.fItemArray, array.fCount, storage->get(), N);
	}

	/**
	* Copy a C array, using preallocated storage if preAllocCount >=
	* count. Otherwise storage will only be used when array shrinks
	* to fit.
	*/
	template <int N>
	SkTArray(const T* array, int count, SkAlignedSTStorage<N,T>* storage) {
	this->init(array, count, storage->get(), N);
	}

	void init(const T* array, int count,
	void* preAllocStorage, int preAllocOrReserveCount) {
	SkASSERT(count >= 0);
	SkASSERT(preAllocOrReserveCount >= 0);
	fCount = count;
	fReserveCount = (preAllocOrReserveCount > 0) ?
	preAllocOrReserveCount :
	gMIN_ALLOC_COUNT;
	fPreAllocMemArray = preAllocStorage;
	if (fReserveCount >= fCount &&
	NULL != preAllocStorage) {
	fAllocCount = fReserveCount;
	fMemArray = preAllocStorage;
	} else {
	fAllocCount = SkMax32(fCount, fReserveCount);
	fMemArray = sk_malloc_throw(fAllocCount * sizeof(T));
	}

	SkTArrayExt::copy(this, array);
	}

	private:

	static const int gMIN_ALLOC_COUNT = 8;

	inline void checkRealloc(int delta) {
	SkASSERT(fCount >= 0);
	SkASSERT(fAllocCount >= 0);

	SkASSERT(-delta <= fCount);

	int newCount = fCount + delta;
	int newAllocCount = fAllocCount;

	if (newCount > fAllocCount) {
	newAllocCount = SkMax32(newCount + ((newCount + 1) >> 1),
	fReserveCount);
	} else if (newCount < fAllocCount / 3) {
	newAllocCount = SkMax32(fAllocCount / 2, fReserveCount);
	}

	if (newAllocCount != fAllocCount) {

	fAllocCount = newAllocCount;
	char* newMemArray;

	if (fAllocCount == fReserveCount && NULL != fPreAllocMemArray) {
	newMemArray = (char*) fPreAllocMemArray;
	} else {
	newMemArray = (char) sk_malloc_throw(fAllocCountsizeof(T));
	}

	SkTArrayExt::copyAndDelete<T>(this, newMemArray);

	if (fMemArray != fPreAllocMemArray) {
	sk_free(fMemArray);
	}
	fMemArray = newMemArray;
	}
	}

	template<typename X> friend void SkTArrayExt::copy(SkTArray<X, true>* that, const X*);
	template<typename X> friend void SkTArrayExt::copyAndDelete(SkTArray<X, true>* that, char*);

	template<typename X> friend void SkTArrayExt::copy(SkTArray<X, false>* that, const X*);
	template<typename X> friend void SkTArrayExt::copyAndDelete(SkTArray<X, false>* that, char*);

	int fReserveCount;
	int fCount;
	int fAllocCount;
	void* fPreAllocMemArray;
	union {
	T* fItemArray;
	void* fMemArray;
	};
	};

	/**
	* Subclass of SkTArray that contains a preallocated memory block for the array.
	*/
	template <int N, typename T, bool DATA_TYPE = false>
	class SkSTArray : public SkTArray<T, DATA_TYPE> {
	private:
	typedef SkTArray<T, DATA_TYPE> INHERITED;

	public:
	SkSTArray() : INHERITED(&fStorage) {
	}

	SkSTArray(const SkSTArray& array)
	: INHERITED(array, &fStorage) {
	}

	explicit SkSTArray(const INHERITED& array)
	: INHERITED(array, &fStorage) {
	}

	SkSTArray(const T* array, int count)
	: INHERITED(array, count, &fStorage) {
	}

	SkSTArray& operator= (const SkSTArray& array) {
	return this = (const INHERITED*)&array;
	}

	SkSTArray& operator= (const INHERITED& array) {
	INHERITED::operator=(array);
	return *this;
	}

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

	#endif