skia2/include/core/SkDeque.h
Ben Wagner d5148e3314 Move SkNoncopyable to include/private.
Change-Id: I62f60ea52faeebddecacf03d9429ac3f7c516b8e
Reviewed-on: https://skia-review.googlesource.com/141823
Commit-Queue: Ben Wagner <bungeman@google.com>
Reviewed-by: Ben Wagner <bungeman@google.com>
2018-07-17 21:39:51 +00:00

140 lines
3.7 KiB
C++

/*
* Copyright 2006 The Android Open Source Project
*
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#ifndef SkDeque_DEFINED
#define SkDeque_DEFINED
#include "../private/SkNoncopyable.h"
#include "SkTypes.h"
/*
* The deque class works by blindly creating memory space of a specified element
* size. It manages the memory as a doubly linked list of blocks each of which
* can contain multiple elements. Pushes and pops add/remove blocks from the
* beginning/end of the list as necessary while each block tracks the used
* portion of its memory.
* One behavior to be aware of is that the pops do not immediately remove an
* empty block from the beginning/end of the list (Presumably so push/pop pairs
* on the block boundaries don't cause thrashing). This can result in the first/
* last element not residing in the first/last block.
*/
class SK_API SkDeque : SkNoncopyable {
public:
/**
* elemSize specifies the size of each individual element in the deque
* allocCount specifies how many elements are to be allocated as a block
*/
explicit SkDeque(size_t elemSize, int allocCount = 1);
SkDeque(size_t elemSize, void* storage, size_t storageSize, int allocCount = 1);
~SkDeque();
bool empty() const { return 0 == fCount; }
int count() const { return fCount; }
size_t elemSize() const { return fElemSize; }
const void* front() const { return fFront; }
const void* back() const { return fBack; }
void* front() {
return (void*)((const SkDeque*)this)->front();
}
void* back() {
return (void*)((const SkDeque*)this)->back();
}
/**
* push_front and push_back return a pointer to the memory space
* for the new element
*/
void* push_front();
void* push_back();
void pop_front();
void pop_back();
private:
struct Block;
public:
class Iter {
public:
enum IterStart {
kFront_IterStart,
kBack_IterStart,
};
/**
* Creates an uninitialized iterator. Must be reset()
*/
Iter();
Iter(const SkDeque& d, IterStart startLoc);
void* next();
void* prev();
void reset(const SkDeque& d, IterStart startLoc);
private:
SkDeque::Block* fCurBlock;
char* fPos;
size_t fElemSize;
};
// Inherit privately from Iter to prevent access to reverse iteration
class F2BIter : private Iter {
public:
F2BIter() {}
/**
* Wrap Iter's 2 parameter ctor to force initialization to the
* beginning of the deque
*/
F2BIter(const SkDeque& d) : INHERITED(d, kFront_IterStart) {}
using Iter::next;
/**
* Wrap Iter::reset to force initialization to the beginning of the
* deque
*/
void reset(const SkDeque& d) {
this->INHERITED::reset(d, kFront_IterStart);
}
private:
typedef Iter INHERITED;
};
private:
// allow unit test to call numBlocksAllocated
friend class DequeUnitTestHelper;
void* fFront;
void* fBack;
Block* fFrontBlock;
Block* fBackBlock;
size_t fElemSize;
void* fInitialStorage;
int fCount; // number of elements in the deque
int fAllocCount; // number of elements to allocate per block
Block* allocateBlock(int allocCount);
void freeBlock(Block* block);
/**
* This returns the number of chunk blocks allocated by the deque. It
* can be used to gauge the effectiveness of the selected allocCount.
*/
int numBlocksAllocated() const;
};
#endif