core/SkOrderedReadBuffer.cpp - platform/external/chromium_org/third_party/skia/src - Git at Google


 /*
  * Copyright 2012 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "SkBitmap.h"
 #include "SkErrorInternals.h"
 #include "SkOrderedReadBuffer.h"
 #include "SkStream.h"
 #include "SkTypeface.h"

 SkOrderedReadBuffer::SkOrderedReadBuffer() : INHERITED() {
     fMemoryPtr = NULL;

     fBitmapStorage = NULL;
     fTFArray = NULL;
     fTFCount = 0;

     fFactoryTDArray = NULL;
     fFactoryArray = NULL;
     fFactoryCount = 0;
     fBitmapDecoder = NULL;
 #ifdef DEBUG_NON_DETERMINISTIC_ASSERT
     fDecodedBitmapIndex = -1;
 #endif // DEBUG_NON_DETERMINISTIC_ASSERT
 }

 SkOrderedReadBuffer::SkOrderedReadBuffer(const void* data, size_t size) : INHERITED()  {
     fReader.setMemory(data, size);
     fMemoryPtr = NULL;

     fBitmapStorage = NULL;
     fTFArray = NULL;
     fTFCount = 0;

     fFactoryTDArray = NULL;
     fFactoryArray = NULL;
     fFactoryCount = 0;
     fBitmapDecoder = NULL;
 #ifdef DEBUG_NON_DETERMINISTIC_ASSERT
     fDecodedBitmapIndex = -1;
 #endif // DEBUG_NON_DETERMINISTIC_ASSERT
 }

 SkOrderedReadBuffer::SkOrderedReadBuffer(SkStream* stream) {
     const size_t length = stream->getLength();
     fMemoryPtr = sk_malloc_throw(length);
     stream->read(fMemoryPtr, length);
     fReader.setMemory(fMemoryPtr, length);

     fBitmapStorage = NULL;
     fTFArray = NULL;
     fTFCount = 0;

     fFactoryTDArray = NULL;
     fFactoryArray = NULL;
     fFactoryCount = 0;
     fBitmapDecoder = NULL;
 #ifdef DEBUG_NON_DETERMINISTIC_ASSERT
     fDecodedBitmapIndex = -1;
 #endif // DEBUG_NON_DETERMINISTIC_ASSERT
 }

 SkOrderedReadBuffer::~SkOrderedReadBuffer() {
     sk_free(fMemoryPtr);
     SkSafeUnref(fBitmapStorage);
 }

 bool SkOrderedReadBuffer::readBool() {
     return fReader.readBool();
 }

 SkColor SkOrderedReadBuffer::readColor() {
     return fReader.readInt();
 }

 SkFixed SkOrderedReadBuffer::readFixed() {
     return fReader.readS32();
 }

 int32_t SkOrderedReadBuffer::readInt() {
     return fReader.readInt();
 }

 SkScalar SkOrderedReadBuffer::readScalar() {
     return fReader.readScalar();
 }

 uint32_t SkOrderedReadBuffer::readUInt() {
     return fReader.readU32();
 }

 int32_t SkOrderedReadBuffer::read32() {
     return fReader.readInt();
 }

 void SkOrderedReadBuffer::readString(SkString* string) {
     size_t len;
     const char* strContents = fReader.readString(&len);
     string->set(strContents, len);
 }

 void* SkOrderedReadBuffer::readEncodedString(size_t* length, SkPaint::TextEncoding encoding) {
     SkDEBUGCODE(int32_t encodingType = ) fReader.readInt();
     SkASSERT(encodingType == encoding);
     *length =  fReader.readInt();
     void* data = sk_malloc_throw(*length);
     memcpy(data, fReader.skip(SkAlign4(*length)), *length);
     return data;
 }

 void SkOrderedReadBuffer::readPoint(SkPoint* point) {
     point->fX = fReader.readScalar();
     point->fY = fReader.readScalar();
 }

 void SkOrderedReadBuffer::readMatrix(SkMatrix* matrix) {
     fReader.readMatrix(matrix);
 }

 void SkOrderedReadBuffer::readIRect(SkIRect* rect) {
     memcpy(rect, fReader.skip(sizeof(SkIRect)), sizeof(SkIRect));
 }

 void SkOrderedReadBuffer::readRect(SkRect* rect) {
     memcpy(rect, fReader.skip(sizeof(SkRect)), sizeof(SkRect));
 }

 void SkOrderedReadBuffer::readRegion(SkRegion* region) {
     fReader.readRegion(region);
 }

 void SkOrderedReadBuffer::readPath(SkPath* path) {
     fReader.readPath(path);
 }

 uint32_t SkOrderedReadBuffer::readByteArray(void* value) {
     const uint32_t length = fReader.readU32();
     memcpy(value, fReader.skip(SkAlign4(length)), length);
     return length;
 }

 uint32_t SkOrderedReadBuffer::readColorArray(SkColor* colors) {
     const uint32_t count = fReader.readU32();
     const uint32_t byteLength = count * sizeof(SkColor);
     memcpy(colors, fReader.skip(SkAlign4(byteLength)), byteLength);
     return count;
 }

 uint32_t SkOrderedReadBuffer::readIntArray(int32_t* values) {
     const uint32_t count = fReader.readU32();
     const uint32_t byteLength = count * sizeof(int32_t);
     memcpy(values, fReader.skip(SkAlign4(byteLength)), byteLength);
     return count;
 }

 uint32_t SkOrderedReadBuffer::readPointArray(SkPoint* points) {
     const uint32_t count = fReader.readU32();
     const uint32_t byteLength = count * sizeof(SkPoint);
     memcpy(points, fReader.skip(SkAlign4(byteLength)), byteLength);
     return count;
 }

 uint32_t SkOrderedReadBuffer::readScalarArray(SkScalar* values) {
     const uint32_t count = fReader.readU32();
     const uint32_t byteLength = count * sizeof(SkScalar);
     memcpy(values, fReader.skip(SkAlign4(byteLength)), byteLength);
     return count;
 }

 uint32_t SkOrderedReadBuffer::getArrayCount() {
     return *(uint32_t*)fReader.peek();
 }

 void SkOrderedReadBuffer::readBitmap(SkBitmap* bitmap) {
     const int width = this->readInt();
     const int height = this->readInt();
     // The writer stored a boolean value to determine whether an SkBitmapHeap was used during
     // writing.
     if (this->readBool()) {
         // An SkBitmapHeap was used for writing. Read the index from the stream and find the
         // corresponding SkBitmap in fBitmapStorage.
         const uint32_t index = fReader.readU32();
         fReader.readU32(); // bitmap generation ID (see SkOrderedWriteBuffer::writeBitmap)
         if (fBitmapStorage) {
             *bitmap = *fBitmapStorage->getBitmap(index);
             fBitmapStorage->releaseRef(index);
             return;
         } else {
             // The bitmap was stored in a heap, but there is no way to access it. Set an error and
             // fall through to use a place holder bitmap.
             SkErrorInternals::SetError(kParseError_SkError, "SkOrderedWriteBuffer::writeBitmap "
                                        "stored the SkBitmap in an SkBitmapHeap, but "
                                        "SkOrderedReadBuffer has no SkBitmapHeapReader to "
                                        "retrieve the SkBitmap.");
         }
     } else {
         // The writer stored false, meaning the SkBitmap was not stored in an SkBitmapHeap.
         const size_t length = this->readUInt();
         if (length > 0) {
 #ifdef DEBUG_NON_DETERMINISTIC_ASSERT
             fDecodedBitmapIndex++;
 #endif // DEBUG_NON_DETERMINISTIC_ASSERT
             // A non-zero size means the SkBitmap was encoded. Read the data and pixel
             // offset.
             const void* data = this->skip(length);
             const int32_t xOffset = fReader.readS32();
             const int32_t yOffset = fReader.readS32();
             if (fBitmapDecoder != NULL && fBitmapDecoder(data, length, bitmap)) {
                 if (bitmap->width() == width && bitmap->height() == height) {
 #ifdef DEBUG_NON_DETERMINISTIC_ASSERT
                     if (0 != xOffset || 0 != yOffset) {
                         SkDebugf("SkOrderedReadBuffer::readBitmap: heights match,"
                                  " but offset is not zero. \nInfo about the bitmap:"
                                  "\n\tIndex: %d\n\tDimensions: [%d %d]\n\tEncoded"
                                  " data size: %d\n\tOffset: (%d, %d)\n",
                                  fDecodedBitmapIndex, width, height, length, xOffset,
                                  yOffset);
                     }
 #endif // DEBUG_NON_DETERMINISTIC_ASSERT
                     // If the width and height match, there should be no offset.
                     SkASSERT(0 == xOffset && 0 == yOffset);
                     return;
                 }

                 // This case can only be reached if extractSubset was called, so
                 // the recorded width and height must be smaller than (or equal to
                 // the encoded width and height.
                 SkASSERT(width <= bitmap->width() && height <= bitmap->height());

                 SkBitmap subsetBm;
                 SkIRect subset = SkIRect::MakeXYWH(xOffset, yOffset, width, height);
                 if (bitmap->extractSubset(&subsetBm, subset)) {
                     bitmap->swap(subsetBm);
                     return;
                 }
             }
             // This bitmap was encoded when written, but we are unable to decode, possibly due to
             // not having a decoder.
             SkErrorInternals::SetError(kParseError_SkError,
                                        "Could not decode bitmap. Resulting bitmap will be red.");
         } else {
             // A size of zero means the SkBitmap was simply flattened.
             bitmap->unflatten(*this);
             return;
         }
     }
     // Could not read the SkBitmap. Use a placeholder bitmap.
     bitmap->setConfig(SkBitmap::kARGB_8888_Config, width, height);
     bitmap->allocPixels();
     bitmap->eraseColor(SK_ColorRED);
 }

 SkTypeface* SkOrderedReadBuffer::readTypeface() {

     uint32_t index = fReader.readU32();
     if (0 == index || index > (unsigned)fTFCount) {
         if (index) {
             SkDebugf("====== typeface index %d\n", index);
         }
         return NULL;
     } else {
         SkASSERT(fTFArray);
         return fTFArray[index - 1];
     }
 }

 SkFlattenable* SkOrderedReadBuffer::readFlattenable() {
     SkFlattenable::Factory factory = NULL;

     if (fFactoryCount > 0) {
         int32_t index = fReader.readU32();
         if (0 == index) {
             return NULL; // writer failed to give us the flattenable
         }
         index -= 1;     // we stored the index-base-1
         SkASSERT(index < fFactoryCount);
         factory = fFactoryArray[index];
     } else if (fFactoryTDArray) {
         int32_t index = fReader.readU32();
         if (0 == index) {
             return NULL; // writer failed to give us the flattenable
         }
         index -= 1;     // we stored the index-base-1
         factory = (*fFactoryTDArray)[index];
     } else {
         factory = (SkFlattenable::Factory)readFunctionPtr();
         if (NULL == factory) {
             return NULL; // writer failed to give us the flattenable
         }
     }

     // if we get here, factory may still be null, but if that is the case, the
     // failure was ours, not the writer.
     SkFlattenable* obj = NULL;
     uint32_t sizeRecorded = fReader.readU32();
     if (factory) {
         uint32_t offset = fReader.offset();
         obj = (*factory)(*this);
         // check that we read the amount we expected
         uint32_t sizeRead = fReader.offset() - offset;
         if (sizeRecorded != sizeRead) {
             // we could try to fix up the offset...
             sk_throw();
         }
     } else {
         // we must skip the remaining data
         fReader.skip(sizeRecorded);
     }
     return obj;
 }

	/*
	* Copyright 2012 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "SkBitmap.h"
	#include "SkErrorInternals.h"
	#include "SkOrderedReadBuffer.h"
	#include "SkStream.h"
	#include "SkTypeface.h"

	SkOrderedReadBuffer::SkOrderedReadBuffer() : INHERITED() {
	fMemoryPtr = NULL;

	fBitmapStorage = NULL;
	fTFArray = NULL;
	fTFCount = 0;

	fFactoryTDArray = NULL;
	fFactoryArray = NULL;
	fFactoryCount = 0;
	fBitmapDecoder = NULL;
	#ifdef DEBUG_NON_DETERMINISTIC_ASSERT
	fDecodedBitmapIndex = -1;
	#endif // DEBUG_NON_DETERMINISTIC_ASSERT
	}

	SkOrderedReadBuffer::SkOrderedReadBuffer(const void* data, size_t size) : INHERITED() {
	fReader.setMemory(data, size);
	fMemoryPtr = NULL;

	fBitmapStorage = NULL;
	fTFArray = NULL;
	fTFCount = 0;

	fFactoryTDArray = NULL;
	fFactoryArray = NULL;
	fFactoryCount = 0;
	fBitmapDecoder = NULL;
	#ifdef DEBUG_NON_DETERMINISTIC_ASSERT
	fDecodedBitmapIndex = -1;
	#endif // DEBUG_NON_DETERMINISTIC_ASSERT
	}

	SkOrderedReadBuffer::SkOrderedReadBuffer(SkStream* stream) {
	const size_t length = stream->getLength();
	fMemoryPtr = sk_malloc_throw(length);
	stream->read(fMemoryPtr, length);
	fReader.setMemory(fMemoryPtr, length);

	fBitmapStorage = NULL;
	fTFArray = NULL;
	fTFCount = 0;

	fFactoryTDArray = NULL;
	fFactoryArray = NULL;
	fFactoryCount = 0;
	fBitmapDecoder = NULL;
	#ifdef DEBUG_NON_DETERMINISTIC_ASSERT
	fDecodedBitmapIndex = -1;
	#endif // DEBUG_NON_DETERMINISTIC_ASSERT
	}

	SkOrderedReadBuffer::~SkOrderedReadBuffer() {
	sk_free(fMemoryPtr);
	SkSafeUnref(fBitmapStorage);
	}

	bool SkOrderedReadBuffer::readBool() {
	return fReader.readBool();
	}

	SkColor SkOrderedReadBuffer::readColor() {
	return fReader.readInt();
	}

	SkFixed SkOrderedReadBuffer::readFixed() {
	return fReader.readS32();
	}

	int32_t SkOrderedReadBuffer::readInt() {
	return fReader.readInt();
	}

	SkScalar SkOrderedReadBuffer::readScalar() {
	return fReader.readScalar();
	}

	uint32_t SkOrderedReadBuffer::readUInt() {
	return fReader.readU32();
	}

	int32_t SkOrderedReadBuffer::read32() {
	return fReader.readInt();
	}

	void SkOrderedReadBuffer::readString(SkString* string) {
	size_t len;
	const char* strContents = fReader.readString(&len);
	string->set(strContents, len);
	}

	void* SkOrderedReadBuffer::readEncodedString(size_t* length, SkPaint::TextEncoding encoding) {
	SkDEBUGCODE(int32_t encodingType = ) fReader.readInt();
	SkASSERT(encodingType == encoding);
	*length = fReader.readInt();
	void* data = sk_malloc_throw(*length);
	memcpy(data, fReader.skip(SkAlign4(length)), length);
	return data;
	}

	void SkOrderedReadBuffer::readPoint(SkPoint* point) {
	point->fX = fReader.readScalar();
	point->fY = fReader.readScalar();
	}

	void SkOrderedReadBuffer::readMatrix(SkMatrix* matrix) {
	fReader.readMatrix(matrix);
	}

	void SkOrderedReadBuffer::readIRect(SkIRect* rect) {
	memcpy(rect, fReader.skip(sizeof(SkIRect)), sizeof(SkIRect));
	}

	void SkOrderedReadBuffer::readRect(SkRect* rect) {
	memcpy(rect, fReader.skip(sizeof(SkRect)), sizeof(SkRect));
	}

	void SkOrderedReadBuffer::readRegion(SkRegion* region) {
	fReader.readRegion(region);
	}

	void SkOrderedReadBuffer::readPath(SkPath* path) {
	fReader.readPath(path);
	}

	uint32_t SkOrderedReadBuffer::readByteArray(void* value) {
	const uint32_t length = fReader.readU32();
	memcpy(value, fReader.skip(SkAlign4(length)), length);
	return length;
	}

	uint32_t SkOrderedReadBuffer::readColorArray(SkColor* colors) {
	const uint32_t count = fReader.readU32();
	const uint32_t byteLength = count * sizeof(SkColor);
	memcpy(colors, fReader.skip(SkAlign4(byteLength)), byteLength);
	return count;
	}

	uint32_t SkOrderedReadBuffer::readIntArray(int32_t* values) {
	const uint32_t count = fReader.readU32();
	const uint32_t byteLength = count * sizeof(int32_t);
	memcpy(values, fReader.skip(SkAlign4(byteLength)), byteLength);
	return count;
	}

	uint32_t SkOrderedReadBuffer::readPointArray(SkPoint* points) {
	const uint32_t count = fReader.readU32();
	const uint32_t byteLength = count * sizeof(SkPoint);
	memcpy(points, fReader.skip(SkAlign4(byteLength)), byteLength);
	return count;
	}

	uint32_t SkOrderedReadBuffer::readScalarArray(SkScalar* values) {
	const uint32_t count = fReader.readU32();
	const uint32_t byteLength = count * sizeof(SkScalar);
	memcpy(values, fReader.skip(SkAlign4(byteLength)), byteLength);
	return count;
	}

	uint32_t SkOrderedReadBuffer::getArrayCount() {
	return (uint32_t)fReader.peek();
	}

	void SkOrderedReadBuffer::readBitmap(SkBitmap* bitmap) {
	const int width = this->readInt();
	const int height = this->readInt();
	// The writer stored a boolean value to determine whether an SkBitmapHeap was used during
	// writing.
	if (this->readBool()) {
	// An SkBitmapHeap was used for writing. Read the index from the stream and find the
	// corresponding SkBitmap in fBitmapStorage.
	const uint32_t index = fReader.readU32();
	fReader.readU32(); // bitmap generation ID (see SkOrderedWriteBuffer::writeBitmap)
	if (fBitmapStorage) {
	bitmap = fBitmapStorage->getBitmap(index);
	fBitmapStorage->releaseRef(index);
	return;
	} else {
	// The bitmap was stored in a heap, but there is no way to access it. Set an error and
	// fall through to use a place holder bitmap.
	SkErrorInternals::SetError(kParseError_SkError, "SkOrderedWriteBuffer::writeBitmap "
	"stored the SkBitmap in an SkBitmapHeap, but "
	"SkOrderedReadBuffer has no SkBitmapHeapReader to "
	"retrieve the SkBitmap.");
	}
	} else {
	// The writer stored false, meaning the SkBitmap was not stored in an SkBitmapHeap.
	const size_t length = this->readUInt();
	if (length > 0) {
	#ifdef DEBUG_NON_DETERMINISTIC_ASSERT
	fDecodedBitmapIndex++;
	#endif // DEBUG_NON_DETERMINISTIC_ASSERT
	// A non-zero size means the SkBitmap was encoded. Read the data and pixel
	// offset.
	const void* data = this->skip(length);
	const int32_t xOffset = fReader.readS32();
	const int32_t yOffset = fReader.readS32();
	if (fBitmapDecoder != NULL && fBitmapDecoder(data, length, bitmap)) {
	if (bitmap->width() == width && bitmap->height() == height) {
	#ifdef DEBUG_NON_DETERMINISTIC_ASSERT
	if (0 != xOffset \|\| 0 != yOffset) {
	SkDebugf("SkOrderedReadBuffer::readBitmap: heights match,"
	" but offset is not zero. \nInfo about the bitmap:"
	"\n\tIndex: %d\n\tDimensions: [%d %d]\n\tEncoded"
	" data size: %d\n\tOffset: (%d, %d)\n",
	fDecodedBitmapIndex, width, height, length, xOffset,
	yOffset);
	}
	#endif // DEBUG_NON_DETERMINISTIC_ASSERT
	// If the width and height match, there should be no offset.
	SkASSERT(0 == xOffset && 0 == yOffset);
	return;
	}

	// This case can only be reached if extractSubset was called, so
	// the recorded width and height must be smaller than (or equal to
	// the encoded width and height.
	SkASSERT(width <= bitmap->width() && height <= bitmap->height());

	SkBitmap subsetBm;
	SkIRect subset = SkIRect::MakeXYWH(xOffset, yOffset, width, height);
	if (bitmap->extractSubset(&subsetBm, subset)) {
	bitmap->swap(subsetBm);
	return;
	}
	}
	// This bitmap was encoded when written, but we are unable to decode, possibly due to
	// not having a decoder.
	SkErrorInternals::SetError(kParseError_SkError,
	"Could not decode bitmap. Resulting bitmap will be red.");
	} else {
	// A size of zero means the SkBitmap was simply flattened.
	bitmap->unflatten(*this);
	return;
	}
	}
	// Could not read the SkBitmap. Use a placeholder bitmap.
	bitmap->setConfig(SkBitmap::kARGB_8888_Config, width, height);
	bitmap->allocPixels();
	bitmap->eraseColor(SK_ColorRED);
	}

	SkTypeface* SkOrderedReadBuffer::readTypeface() {

	uint32_t index = fReader.readU32();
	if (0 == index \|\| index > (unsigned)fTFCount) {
	if (index) {
	SkDebugf("====== typeface index %d\n", index);
	}
	return NULL;
	} else {
	SkASSERT(fTFArray);
	return fTFArray[index - 1];
	}
	}

	SkFlattenable* SkOrderedReadBuffer::readFlattenable() {
	SkFlattenable::Factory factory = NULL;

	if (fFactoryCount > 0) {
	int32_t index = fReader.readU32();
	if (0 == index) {
	return NULL; // writer failed to give us the flattenable
	}
	index -= 1; // we stored the index-base-1
	SkASSERT(index < fFactoryCount);
	factory = fFactoryArray[index];
	} else if (fFactoryTDArray) {
	int32_t index = fReader.readU32();
	if (0 == index) {
	return NULL; // writer failed to give us the flattenable
	}
	index -= 1; // we stored the index-base-1
	factory = (*fFactoryTDArray)[index];
	} else {
	factory = (SkFlattenable::Factory)readFunctionPtr();
	if (NULL == factory) {
	return NULL; // writer failed to give us the flattenable
	}
	}

	// if we get here, factory may still be null, but if that is the case, the
	// failure was ours, not the writer.
	SkFlattenable* obj = NULL;
	uint32_t sizeRecorded = fReader.readU32();
	if (factory) {
	uint32_t offset = fReader.offset();
	obj = (factory)(this);
	// check that we read the amount we expected
	uint32_t sizeRead = fReader.offset() - offset;
	if (sizeRecorded != sizeRead) {
	// we could try to fix up the offset...
	sk_throw();
	}
	} else {
	// we must skip the remaining data
	fReader.skip(sizeRecorded);
	}
	return obj;
	}