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/*
* 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 SkPictureFlat_DEFINED
#define SkPictureFlat_DEFINED
//#define SK_DEBUG_SIZE
#include "SkChunkAlloc.h"
#include "SkBitmap.h"
#include "SkOrderedReadBuffer.h"
#include "SkOrderedWriteBuffer.h"
#include "SkPicture.h"
#include "SkMatrix.h"
#include "SkPaint.h"
#include "SkPath.h"
#include "SkRegion.h"
#include "SkTRefArray.h"
#include "SkTSearch.h"
enum DrawType {
UNUSED,
CLIP_PATH,
CLIP_REGION,
CLIP_RECT,
CONCAT,
DRAW_BITMAP,
DRAW_BITMAP_MATRIX,
DRAW_BITMAP_NINE,
DRAW_BITMAP_RECT,
DRAW_CLEAR,
DRAW_DATA,
DRAW_PAINT,
DRAW_PATH,
DRAW_PICTURE,
DRAW_POINTS,
DRAW_POS_TEXT,
DRAW_POS_TEXT_TOP_BOTTOM, // fast variant of DRAW_POS_TEXT
DRAW_POS_TEXT_H,
DRAW_POS_TEXT_H_TOP_BOTTOM, // fast variant of DRAW_POS_TEXT_H
DRAW_RECT,
DRAW_SPRITE,
DRAW_TEXT,
DRAW_TEXT_ON_PATH,
DRAW_TEXT_TOP_BOTTOM, // fast variant of DRAW_TEXT
DRAW_VERTICES,
RESTORE,
ROTATE,
SAVE,
SAVE_LAYER,
SCALE,
SET_MATRIX,
SKEW,
TRANSLATE
};
enum DrawVertexFlags {
DRAW_VERTICES_HAS_TEXS = 0x01,
DRAW_VERTICES_HAS_COLORS = 0x02,
DRAW_VERTICES_HAS_INDICES = 0x04
};
///////////////////////////////////////////////////////////////////////////////
// clipparams are packed in 5 bits
// doAA:1 | regionOp:4
static inline uint32_t ClipParams_pack(SkRegion::Op op, bool doAA) {
unsigned doAABit = doAA ? 1 : 0;
return (doAABit << 4) | op;
}
static inline SkRegion::Op ClipParams_unpackRegionOp(uint32_t packed) {
return (SkRegion::Op)(packed & 0xF);
}
static inline bool ClipParams_unpackDoAA(uint32_t packed) {
return SkToBool((packed >> 4) & 1);
}
///////////////////////////////////////////////////////////////////////////////
class SkRefCntPlayback {
public:
SkRefCntPlayback();
virtual ~SkRefCntPlayback();
int count() const { return fCount; }
void reset(const SkRefCntSet*);
void setCount(int count);
SkRefCnt* set(int index, SkRefCnt*);
virtual void setupBuffer(SkFlattenableReadBuffer& buffer) const {
buffer.setRefCntArray(fArray, fCount);
}
protected:
int fCount;
SkRefCnt** fArray;
};
class SkTypefacePlayback : public SkRefCntPlayback {
public:
virtual void setupBuffer(SkFlattenableReadBuffer& buffer) const {
buffer.setTypefaceArray((SkTypeface**)fArray, fCount);
}
};
class SkFactoryPlayback {
public:
SkFactoryPlayback(int count) : fCount(count) {
fArray = SkNEW_ARRAY(SkFlattenable::Factory, count);
}
~SkFactoryPlayback() {
SkDELETE_ARRAY(fArray);
}
SkFlattenable::Factory* base() const { return fArray; }
void setupBuffer(SkFlattenableReadBuffer& buffer) const {
buffer.setFactoryPlayback(fArray, fCount);
}
private:
int fCount;
SkFlattenable::Factory* fArray;
};
///////////////////////////////////////////////////////////////////////////////
//
//
// The following templated classes provide an efficient way to store and compare
// objects that have been flattened (i.e. serialized in an ordered binary
// format).
//
// SkFlatData: is a simple indexable container for the flattened data
// which is agnostic to the type of data is is indexing. It is
// also responsible for flattening/unflattening objects but
// details of that operation are hidden in the provided procs
// SkFlatDictionary: is an abstract templated dictionary that maintains a
// searchable set of SkFlataData objects of type T.
// SkFlatController: is an interface provided to SkFlatDictionary which handles
// allocation and unallocation in some cases
//
// NOTE: any class that wishes to be used in conjunction with SkFlatDictionary
// must subclass the dictionary and provide the necessary flattening procs.
// The end of this header contains dictionary subclasses for some common classes
// like SkBitmap, SkMatrix, SkPaint, and SkRegion. SkFlatController must also
// be implemented, or SkChunkFlatController can be used to use an
// SkChunkAllocator and never do replacements.
//
//
///////////////////////////////////////////////////////////////////////////////
class SkFlatData;
class SkFlatController : public SkRefCnt {
public:
/**
* Provide a new block of memory for the SkFlatDictionary to use.
*/
virtual void* allocThrow(size_t bytes) = 0;
/**
* Unallocate a previously allocated block, returned by allocThrow.
* Implementation should at least perform an unallocation if passed the last
* pointer returned by allocThrow. If findAndReplace() is intended to be
* used, unalloc should also be able to unallocate the SkFlatData that is
* provided.
*/
virtual void unalloc(void* ptr) = 0;
};
class SkFlatData {
public:
/**
* Compare two SkFlatData ptrs, returning -1, 0, 1 to allow them to be
* sorted.
*
* Note: this assumes that a and b have different sentinel values, either
* InCache or AsCandidate, otherwise the loop will go beyond the end of
* the buffers.
*
* dataToCompare() returns 2 fields before the flattened data:
* - checksum
* - size
* This ensures that if we see two blocks of different length, we will
* notice that right away, and not read any further. It also ensures that
* we see the checksum right away, so that most of the time it is enough
* to short-circuit our comparison.
*/
static int Compare(const SkFlatData* a, const SkFlatData* b) {
const uint32_t* stop = a->dataStop();
const uint32_t* a_ptr = a->dataToCompare() - 1;
const uint32_t* b_ptr = b->dataToCompare() - 1;
// We use -1 above, so we can pre-increment our pointers in the loop
while (*++a_ptr == *++b_ptr) {}
if (a_ptr == stop) { // sentinel
SkASSERT(b->dataStop() == b_ptr);
return 0;
}
SkASSERT(a_ptr < a->dataStop());
SkASSERT(b_ptr < b->dataStop());
return (*a_ptr < *b_ptr) ? -1 : 1;
}
int index() const { return fIndex; }
const void* data() const { return (const char*)this + sizeof(*this); }
void* data() { return (char*)this + sizeof(*this); }
// Our data is always 32bit aligned, so we can offer this accessor
uint32_t* data32() { return (uint32_t*)this->data(); }
// Returns the size of the flattened data.
size_t flatSize() const { return fFlatSize; }
void setSentinelInCache() {
this->setSentinel(kInCache_Sentinel);
}
void setSentinelAsCandidate() {
this->setSentinel(kCandidate_Sentinel);
}
uint32_t checksum() const { return fChecksum; }
#ifdef SK_DEBUG_SIZE
// returns the logical size of our data. Does not return any sentinel or
// padding we might have.
size_t size() const {
return sizeof(SkFlatData) + fFlatSize;
}
#endif
static SkFlatData* Create(SkFlatController* controller, const void* obj, int index,
void (*flattenProc)(SkOrderedWriteBuffer&, const void*),
SkRefCntSet* refCntRecorder = NULL,
SkRefCntSet* faceRecorder = NULL,
uint32_t writeBufferflags = 0,
SkFactorySet* fset = NULL);
void unflatten(void* result,
void (*unflattenProc)(SkOrderedReadBuffer&, void*),
SkRefCntPlayback* refCntPlayback = NULL,
SkTypefacePlayback* facePlayback = NULL) const;
// When we purge an entry, we want to reuse an old index for the new entry,
// so we expose this setter.
void setIndex(int index) { fIndex = index; }
// for unittesting
friend bool operator==(const SkFlatData& a, const SkFlatData& b) {
size_t N = (const char*)a.dataStop() - (const char*)a.dataToCompare();
return !memcmp(a.dataToCompare(), b.dataToCompare(), N);
}
private:
int fIndex;
// From here down is the data we look at in the search/sort. We always begin
// with the checksum and then length.
uint32_t fChecksum;
int32_t fFlatSize; // size of flattened data
// uint32_t flattenedData[]
// uint32_t sentinelValue
const uint32_t* dataToCompare() const {
return (const uint32_t*)&fChecksum;
}
const uint32_t* dataStop() const {
SkASSERT(SkIsAlign4(fFlatSize));
return (const uint32_t*)((const char*)this->data() + fFlatSize);
}
enum {
kInCache_Sentinel = 0,
kCandidate_Sentinel = ~0U,
};
void setSentinel(uint32_t value) {
SkASSERT(SkIsAlign4(fFlatSize));
this->data32()[fFlatSize >> 2] = value;
}
};
template <class T>
class SkFlatDictionary {
public:
SkFlatDictionary(SkFlatController* controller, SkRefCntSet* refSet = NULL,
SkRefCntSet* typeFaceSet = NULL,
SkFactorySet* factorySet = NULL)
: fController(controller), fRefSet(refSet), fTypefaceSet(typeFaceSet)
, fFactorySet(factorySet) {
fFlattenProc = NULL;
fUnflattenProc = NULL;
SkASSERT(controller);
fController->ref();
SkSafeRef(refSet);
SkSafeRef(typeFaceSet);
SkSafeRef(factorySet);
// set to 1 since returning a zero from find() indicates failure
fNextIndex = 1;
sk_bzero(fHash, sizeof(fHash));
}
virtual ~SkFlatDictionary() {
fController->unref();
SkSafeUnref(fRefSet);
SkSafeUnref(fTypefaceSet);
SkSafeUnref(fFactorySet);
}
int count() const { return fData.count(); }
const SkFlatData* operator[](int index) const {
SkASSERT(index >= 0 && index < fData.count());
return fData[index];
}
/**
* Clears the dictionary of all entries. However, it does NOT free the
* memory that was allocated for each entry.
*/
void reset() {
fData.reset();
fNextIndex = 1;
sk_bzero(fHash, sizeof(fHash));
}
/**
* Similar to find. Allows the caller to specify an SkFlatData to replace in
* the case of an add. Also tells the caller whether a new SkFlatData was
* added and whether the old one was replaced. The parameters added and
* replaced are required to be non-NULL. Rather than returning the index of
* the entry in the dictionary, it returns the actual SkFlatData.
*/
const SkFlatData* findAndReplace(const T& element,
uint32_t writeBufferFlags,
const SkFlatData* toReplace, bool* added,
bool* replaced) {
SkASSERT(added != NULL && replaced != NULL);
int oldCount = fData.count();
const SkFlatData* flat = this->findAndReturnFlat(element,
writeBufferFlags);
*added = fData.count() == oldCount + 1;
*replaced = false;
if (*added && toReplace != NULL) {
// First, find the index of the one to replace
int indexToReplace = fData.find(toReplace);
if (indexToReplace >= 0) {
// findAndReturnFlat set the index to fNextIndex and increased
// fNextIndex by one. Reuse the index from the one being
// replaced and reset fNextIndex to the proper value.
const_cast<SkFlatData*>(flat)->setIndex(toReplace->index());
fNextIndex--;
// Remove from the array.
fData.remove(indexToReplace);
// Remove from the hash table.
int oldHash = ChecksumToHashIndex(toReplace->checksum());
if (fHash[oldHash] == toReplace) {
fHash[oldHash] = NULL;
}
// Delete the actual object.
fController->unalloc((void*)toReplace);
*replaced = true;
}
}
return flat;
}
/**
* Given an element of type T return its 1-based index in the dictionary. If
* the element wasn't previously in the dictionary it is automatically
* added.
*
* To make the Compare function fast, we write a sentinel value at the end
* of each block. The blocks in our fData[] all have a 0 sentinel. The
* newly created block we're comparing against has a -1 in the sentinel.
*
* This trick allows Compare to always loop until failure. If it fails on
* the sentinal value, we know the blocks are equal.
*/
int find(const T& element, uint32_t writeBufferflags = 0) {
return this->findAndReturnFlat(element, writeBufferflags)->index();
}
/**
* Given a pointer to an array of type T we allocate the array and fill it
* with the unflattened dictionary contents. The return value is the size of
* the allocated array.
*/
int unflattenDictionary(T*& array,
SkRefCntPlayback* refCntPlayback = NULL,
SkTypefacePlayback* facePlayback = NULL) const {
int elementCount = fData.count();
if (elementCount > 0) {
array = SkNEW_ARRAY(T, elementCount);
this->unflattenIntoArray(array, refCntPlayback, facePlayback);
}
return elementCount;
}
/**
* Unflatten the objects and return them in SkTRefArray, or return NULL
* if there no objects (instead of an empty array).
*/
SkTRefArray<T>* unflattenToArray(SkRefCntPlayback* refCntPlayback,
SkTypefacePlayback* facePlayback) const {
int count = fData.count();
SkTRefArray<T>* array = NULL;
if (count > 0) {
array = SkTRefArray<T>::Create(count);
this->unflattenIntoArray(&array->writableAt(0),
refCntPlayback, facePlayback);
}
return array;
}
protected:
void (*fFlattenProc)(SkOrderedWriteBuffer&, const void*);
void (*fUnflattenProc)(SkOrderedReadBuffer&, void*);
private:
void unflattenIntoArray(T* array,
SkRefCntPlayback* refCntPlayback,
SkTypefacePlayback* facePlayback) const {
const int count = fData.count();
const SkFlatData** iter = fData.begin();
for (int i = 0; i < count; ++i) {
const SkFlatData* element = iter[i];
int index = element->index() - 1;
SkASSERT((unsigned)index < (unsigned)count);
element->unflatten(&array[index], fUnflattenProc,
refCntPlayback, facePlayback);
}
}
SkFlatController * const fController;
int fNextIndex;
SkTDArray<const SkFlatData*> fData;
SkRefCntSet* fRefSet;
SkRefCntSet* fTypefaceSet;
SkFactorySet* fFactorySet;
const SkFlatData* findAndReturnFlat(const T& element,
uint32_t writeBufferflags) {
SkFlatData* flat = SkFlatData::Create(fController, &element, fNextIndex,
fFlattenProc, fRefSet,
fTypefaceSet, writeBufferflags,
fFactorySet);
int hashIndex = ChecksumToHashIndex(flat->checksum());
const SkFlatData* candidate = fHash[hashIndex];
if (candidate && !SkFlatData::Compare(flat, candidate)) {
fController->unalloc(flat);
return candidate;
}
int index = SkTSearch<SkFlatData>((const SkFlatData**) fData.begin(),
fData.count(), flat, sizeof(flat),
&SkFlatData::Compare);
if (index >= 0) {
fController->unalloc(flat);
fHash[hashIndex] = fData[index];
return fData[index];
}
index = ~index;
*fData.insert(index) = flat;
SkASSERT(fData.count() == fNextIndex);
fNextIndex++;
flat->setSentinelInCache();
fHash[hashIndex] = flat;
return flat;
}
enum {
// Determined by trying diff values on picture-recording benchmarks
// (e.g. PictureRecordBench.cpp), choosing the smallest value that
// showed a big improvement. Even better would be to benchmark diff
// values on recording representative web-pages or other "real" content.
HASH_BITS = 7,
HASH_MASK = (1 << HASH_BITS) - 1,
HASH_COUNT = 1 << HASH_BITS
};
const SkFlatData* fHash[HASH_COUNT];
static int ChecksumToHashIndex(uint32_t checksum) {
int n = checksum;
if (HASH_BITS < 32) {
n ^= n >> 16;
}
if (HASH_BITS < 16) {
n ^= n >> 8;
}
if (HASH_BITS < 8) {
n ^= n >> 4;
}
return n & HASH_MASK;
}
};
///////////////////////////////////////////////////////////////////////////////
// Some common dictionaries are defined here for both reference and convenience
///////////////////////////////////////////////////////////////////////////////
template <class T>
static void SkFlattenObjectProc(SkOrderedWriteBuffer& buffer, const void* obj) {
((T*)obj)->flatten(buffer);
}
template <class T>
static void SkUnflattenObjectProc(SkOrderedReadBuffer& buffer, void* obj) {
((T*)obj)->unflatten(buffer);
}
class SkChunkFlatController : public SkFlatController {
public:
SkChunkFlatController(size_t minSize)
: fHeap(minSize) {}
virtual void* allocThrow(size_t bytes) {
return fHeap.allocThrow(bytes);
}
virtual void unalloc(void* ptr) {
(void) fHeap.unalloc(ptr);
}
void reset() { fHeap.reset(); }
private:
SkChunkAlloc fHeap;
};
class SkBitmapDictionary : public SkFlatDictionary<SkBitmap> {
public:
SkBitmapDictionary(SkFlatController* controller, SkRefCntSet* refSet = NULL,
SkRefCntSet* typefaceSet = NULL,
SkFactorySet* factorySet = NULL)
: SkFlatDictionary<SkBitmap>(controller, refSet, typefaceSet, factorySet) {
fFlattenProc = &SkFlattenObjectProc<SkBitmap>;
fUnflattenProc = &SkUnflattenObjectProc<SkBitmap>;
}
};
class SkMatrixDictionary : public SkFlatDictionary<SkMatrix> {
public:
SkMatrixDictionary(SkFlatController* controller)
: SkFlatDictionary<SkMatrix>(controller) {
fFlattenProc = &flattenMatrix;
fUnflattenProc = &unflattenMatrix;
}
static void flattenMatrix(SkOrderedWriteBuffer& buffer, const void* obj) {
buffer.getWriter32()->writeMatrix(*(SkMatrix*)obj);
}
static void unflattenMatrix(SkOrderedReadBuffer& buffer, void* obj) {
buffer.getReader32()->readMatrix((SkMatrix*)obj);
}
};
class SkPaintDictionary : public SkFlatDictionary<SkPaint> {
public:
SkPaintDictionary(SkFlatController* controller, SkRefCntSet* refSet,
SkRefCntSet* typefaceSet)
: SkFlatDictionary<SkPaint>(controller, refSet, typefaceSet) {
fFlattenProc = &SkFlattenObjectProc<SkPaint>;
fUnflattenProc = &SkUnflattenObjectProc<SkPaint>;
}
};
class SkRegionDictionary : public SkFlatDictionary<SkRegion> {
public:
SkRegionDictionary(SkFlatController* controller)
: SkFlatDictionary<SkRegion>(controller) {
fFlattenProc = &flattenRegion;
fUnflattenProc = &unflattenRegion;
}
static void flattenRegion(SkOrderedWriteBuffer& buffer, const void* obj) {
buffer.getWriter32()->writeRegion(*(SkRegion*)obj);
}
static void unflattenRegion(SkOrderedReadBuffer& buffer, void* obj) {
buffer.getReader32()->readRegion((SkRegion*)obj);
}
};
#endif
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