src/core/SkWriteBuffer.cpp - skia - 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 "src/core/SkWriteBuffer.h"

 #include "include/core/SkBitmap.h"
 #include "include/core/SkData.h"
 #include "include/core/SkM44.h"
 #include "include/core/SkStream.h"
 #include "include/core/SkTypeface.h"
 #include "include/private/SkTo.h"
 #include "src/core/SkImagePriv.h"
 #include "src/core/SkMatrixPriv.h"
 #include "src/core/SkPaintPriv.h"
 #include "src/core/SkPtrRecorder.h"

 ///////////////////////////////////////////////////////////////////////////////////////////////////

 SkBinaryWriteBuffer::SkBinaryWriteBuffer()
     : fFactorySet(nullptr)
     , fTFSet(nullptr) {
 }

 SkBinaryWriteBuffer::SkBinaryWriteBuffer(void* storage, size_t storageSize)
     : fFactorySet(nullptr)
     , fTFSet(nullptr)
     , fWriter(storage, storageSize)
 {}

 SkBinaryWriteBuffer::~SkBinaryWriteBuffer() {}

 bool SkBinaryWriteBuffer::usingInitialStorage() const {
     return fWriter.usingInitialStorage();
 }

 void SkBinaryWriteBuffer::writeByteArray(const void* data, size_t size) {
     fWriter.write32(SkToU32(size));
     fWriter.writePad(data, size);
 }

 void SkBinaryWriteBuffer::writeBool(bool value) {
     fWriter.writeBool(value);
 }

 void SkBinaryWriteBuffer::writeScalar(SkScalar value) {
     fWriter.writeScalar(value);
 }

 void SkBinaryWriteBuffer::writeScalarArray(const SkScalar* value, uint32_t count) {
     fWriter.write32(count);
     fWriter.write(value, count * sizeof(SkScalar));
 }

 void SkBinaryWriteBuffer::writeInt(int32_t value) {
     fWriter.write32(value);
 }

 void SkBinaryWriteBuffer::writeIntArray(const int32_t* value, uint32_t count) {
     fWriter.write32(count);
     fWriter.write(value, count * sizeof(int32_t));
 }

 void SkBinaryWriteBuffer::writeUInt(uint32_t value) {
     fWriter.write32(value);
 }

 void SkBinaryWriteBuffer::writeString(const char* value) {
     fWriter.writeString(value);
 }

 void SkBinaryWriteBuffer::writeColor(SkColor color) {
     fWriter.write32(color);
 }

 void SkBinaryWriteBuffer::writeColorArray(const SkColor* color, uint32_t count) {
     fWriter.write32(count);
     fWriter.write(color, count * sizeof(SkColor));
 }

 void SkBinaryWriteBuffer::writeColor4f(const SkColor4f& color) {
     fWriter.write(&color, sizeof(SkColor4f));
 }

 void SkBinaryWriteBuffer::writeColor4fArray(const SkColor4f* color, uint32_t count) {
     fWriter.write32(count);
     fWriter.write(color, count * sizeof(SkColor4f));
 }

 void SkBinaryWriteBuffer::writePoint(const SkPoint& point) {
     fWriter.writeScalar(point.fX);
     fWriter.writeScalar(point.fY);
 }

 void SkBinaryWriteBuffer::writePoint3(const SkPoint3& point) {
     this->writePad32(&point, sizeof(SkPoint3));
 }

 void SkBinaryWriteBuffer::writePointArray(const SkPoint* point, uint32_t count) {
     fWriter.write32(count);
     fWriter.write(point, count * sizeof(SkPoint));
 }

 void SkBinaryWriteBuffer::write(const SkM44& matrix) {
     fWriter.write(SkMatrixPriv::M44ColMajor(matrix), sizeof(float) * 16);
 }

 void SkBinaryWriteBuffer::writeMatrix(const SkMatrix& matrix) {
     fWriter.writeMatrix(matrix);
 }

 void SkBinaryWriteBuffer::writeIRect(const SkIRect& rect) {
     fWriter.write(&rect, sizeof(SkIRect));
 }

 void SkBinaryWriteBuffer::writeRect(const SkRect& rect) {
     fWriter.writeRect(rect);
 }

 void SkBinaryWriteBuffer::writeRegion(const SkRegion& region) {
     fWriter.writeRegion(region);
 }

 void SkBinaryWriteBuffer::writePath(const SkPath& path) {
     fWriter.writePath(path);
 }

 size_t SkBinaryWriteBuffer::writeStream(SkStream* stream, size_t length) {
     fWriter.write32(SkToU32(length));
     size_t bytesWritten = fWriter.readFromStream(stream, length);
     if (bytesWritten < length) {
         fWriter.reservePad(length - bytesWritten);
     }
     return bytesWritten;
 }

 bool SkBinaryWriteBuffer::writeToStream(SkWStream* stream) const {
     return fWriter.writeToStream(stream);
 }

 #include "src/image/SkImage_Base.h"

 /*  Format:
  *      flags: U32
  *      encoded : size_32 + data[]
  *      [subset: IRect]
  *      [mips]  : size_32 + data[]
  */
 void SkBinaryWriteBuffer::writeImage(const SkImage* image) {
     uint32_t flags = 0;
     const SkMipmap* mips = as_IB(image)->onPeekMips();
     if (mips) {
         flags |= SkWriteBufferImageFlags::kHasMipmap;
     }
     if (image->alphaType() == kUnpremul_SkAlphaType) {
         flags |= SkWriteBufferImageFlags::kUnpremul;
     }

     this->write32(flags);

     sk_sp<SkData> data;
     if (fProcs.fImageProc) {
         data = fProcs.fImageProc(const_cast<SkImage*>(image), fProcs.fImageCtx);
     }
     if (!data) {
         data = image->encodeToData();
     }
     this->writeDataAsByteArray(data.get());

     if (flags & SkWriteBufferImageFlags::kHasMipmap) {
         this->writeDataAsByteArray(mips->serialize().get());
     }
 }

 void SkBinaryWriteBuffer::writeTypeface(SkTypeface* obj) {
     // Write 32 bits (signed)
     //   0 -- default font
     //  >0 -- index
     //  <0 -- custom (serial procs)

     if (obj == nullptr) {
         fWriter.write32(0);
     } else if (fProcs.fTypefaceProc) {
         auto data = fProcs.fTypefaceProc(obj, fProcs.fTypefaceCtx);
         if (data) {
             size_t size = data->size();
             if (!SkTFitsIn<int32_t>(size)) {
                 size = 0;               // fall back to default font
             }
             int32_t ssize = SkToS32(size);
             fWriter.write32(-ssize);    // negative to signal custom
             if (size) {
                 this->writePad32(data->data(), size);
             }
             return;
         }
         // no data means fall through for std behavior
     }
     fWriter.write32(fTFSet ? fTFSet->add(obj) : 0);
 }

 void SkBinaryWriteBuffer::writePaint(const SkPaint& paint) {
     SkPaintPriv::Flatten(paint, *this);
 }

 void SkBinaryWriteBuffer::setFactoryRecorder(sk_sp<SkFactorySet> rec) {
     fFactorySet = std::move(rec);
 }

 void SkBinaryWriteBuffer::setTypefaceRecorder(sk_sp<SkRefCntSet> rec) {
     fTFSet = std::move(rec);
 }

 void SkBinaryWriteBuffer::writeFlattenable(const SkFlattenable* flattenable) {
     if (nullptr == flattenable) {
         this->write32(0);
         return;
     }

     /*
      *  We can write 1 of 2 versions of the flattenable:
      *
      *  1. index into fFactorySet: This assumes the writer will later resolve the function-ptrs
      *     into strings for its reader. SkPicture does exactly this, by writing a table of names
      *     (matching the indices) up front in its serialized form.
      *
      *  2. string name of the flattenable or index into fFlattenableDict:  We store the string to
      *     allow the reader to specify its own factories after write time. In order to improve
      *     compression, if we have already written the string, we write its index instead.
      */

     if (SkFlattenable::Factory factory = flattenable->getFactory(); factory && fFactorySet) {
         this->write32(fFactorySet->add(factory));
     } else {
         const char* name = flattenable->getTypeName();
         SkASSERT(name);
         SkASSERT(0 != strcmp("", name));

         if (uint32_t* indexPtr = fFlattenableDict.find(name)) {
             // We will write the index as a 32-bit int.  We want the first byte
             // that we send to be zero - this will act as a sentinel that we
             // have an index (not a string).  This means that we will send the
             // the index shifted left by 8.  The remaining 24-bits should be
             // plenty to store the index.  Note that this strategy depends on
             // being little endian, and type names being non-empty.
             SkASSERT(0 == *indexPtr >> 24);
             this->write32(*indexPtr << 8);
         } else {
             this->writeString(name);
             fFlattenableDict.set(name, fFlattenableDict.count() + 1);
         }
     }

     // make room for the size of the flattened object
     (void)fWriter.reserve(sizeof(uint32_t));
     // record the current size, so we can subtract after the object writes.
     size_t offset = fWriter.bytesWritten();
     // now flatten the object
     flattenable->flatten(*this);
     size_t objSize = fWriter.bytesWritten() - offset;
     // record the obj's size
     fWriter.overwriteTAt(offset - sizeof(uint32_t), SkToU32(objSize));
 }
	/*
	* 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 "src/core/SkWriteBuffer.h"

	#include "include/core/SkBitmap.h"
	#include "include/core/SkData.h"
	#include "include/core/SkM44.h"
	#include "include/core/SkStream.h"
	#include "include/core/SkTypeface.h"
	#include "include/private/SkTo.h"
	#include "src/core/SkImagePriv.h"
	#include "src/core/SkMatrixPriv.h"
	#include "src/core/SkPaintPriv.h"
	#include "src/core/SkPtrRecorder.h"

	///////////////////////////////////////////////////////////////////////////////////////////////////

	SkBinaryWriteBuffer::SkBinaryWriteBuffer()
	: fFactorySet(nullptr)
	, fTFSet(nullptr) {
	}

	SkBinaryWriteBuffer::SkBinaryWriteBuffer(void* storage, size_t storageSize)
	: fFactorySet(nullptr)
	, fTFSet(nullptr)
	, fWriter(storage, storageSize)
	{}

	SkBinaryWriteBuffer::~SkBinaryWriteBuffer() {}

	bool SkBinaryWriteBuffer::usingInitialStorage() const {
	return fWriter.usingInitialStorage();
	}

	void SkBinaryWriteBuffer::writeByteArray(const void* data, size_t size) {
	fWriter.write32(SkToU32(size));
	fWriter.writePad(data, size);
	}

	void SkBinaryWriteBuffer::writeBool(bool value) {
	fWriter.writeBool(value);
	}

	void SkBinaryWriteBuffer::writeScalar(SkScalar value) {
	fWriter.writeScalar(value);
	}

	void SkBinaryWriteBuffer::writeScalarArray(const SkScalar* value, uint32_t count) {
	fWriter.write32(count);
	fWriter.write(value, count * sizeof(SkScalar));
	}

	void SkBinaryWriteBuffer::writeInt(int32_t value) {
	fWriter.write32(value);
	}

	void SkBinaryWriteBuffer::writeIntArray(const int32_t* value, uint32_t count) {
	fWriter.write32(count);
	fWriter.write(value, count * sizeof(int32_t));
	}

	void SkBinaryWriteBuffer::writeUInt(uint32_t value) {
	fWriter.write32(value);
	}

	void SkBinaryWriteBuffer::writeString(const char* value) {
	fWriter.writeString(value);
	}

	void SkBinaryWriteBuffer::writeColor(SkColor color) {
	fWriter.write32(color);
	}

	void SkBinaryWriteBuffer::writeColorArray(const SkColor* color, uint32_t count) {
	fWriter.write32(count);
	fWriter.write(color, count * sizeof(SkColor));
	}

	void SkBinaryWriteBuffer::writeColor4f(const SkColor4f& color) {
	fWriter.write(&color, sizeof(SkColor4f));
	}

	void SkBinaryWriteBuffer::writeColor4fArray(const SkColor4f* color, uint32_t count) {
	fWriter.write32(count);
	fWriter.write(color, count * sizeof(SkColor4f));
	}

	void SkBinaryWriteBuffer::writePoint(const SkPoint& point) {
	fWriter.writeScalar(point.fX);
	fWriter.writeScalar(point.fY);
	}

	void SkBinaryWriteBuffer::writePoint3(const SkPoint3& point) {
	this->writePad32(&point, sizeof(SkPoint3));
	}

	void SkBinaryWriteBuffer::writePointArray(const SkPoint* point, uint32_t count) {
	fWriter.write32(count);
	fWriter.write(point, count * sizeof(SkPoint));
	}

	void SkBinaryWriteBuffer::write(const SkM44& matrix) {
	fWriter.write(SkMatrixPriv::M44ColMajor(matrix), sizeof(float) * 16);
	}

	void SkBinaryWriteBuffer::writeMatrix(const SkMatrix& matrix) {
	fWriter.writeMatrix(matrix);
	}

	void SkBinaryWriteBuffer::writeIRect(const SkIRect& rect) {
	fWriter.write(&rect, sizeof(SkIRect));
	}

	void SkBinaryWriteBuffer::writeRect(const SkRect& rect) {
	fWriter.writeRect(rect);
	}

	void SkBinaryWriteBuffer::writeRegion(const SkRegion& region) {
	fWriter.writeRegion(region);
	}

	void SkBinaryWriteBuffer::writePath(const SkPath& path) {
	fWriter.writePath(path);
	}

	size_t SkBinaryWriteBuffer::writeStream(SkStream* stream, size_t length) {
	fWriter.write32(SkToU32(length));
	size_t bytesWritten = fWriter.readFromStream(stream, length);
	if (bytesWritten < length) {
	fWriter.reservePad(length - bytesWritten);
	}
	return bytesWritten;
	}

	bool SkBinaryWriteBuffer::writeToStream(SkWStream* stream) const {
	return fWriter.writeToStream(stream);
	}

	#include "src/image/SkImage_Base.h"

	/* Format:
	* flags: U32
	* encoded : size_32 + data[]
	* [subset: IRect]
	* [mips] : size_32 + data[]
	*/
	void SkBinaryWriteBuffer::writeImage(const SkImage* image) {
	uint32_t flags = 0;
	const SkMipmap* mips = as_IB(image)->onPeekMips();
	if (mips) {
	flags \|= SkWriteBufferImageFlags::kHasMipmap;
	}
	if (image->alphaType() == kUnpremul_SkAlphaType) {
	flags \|= SkWriteBufferImageFlags::kUnpremul;
	}

	this->write32(flags);

	sk_sp<SkData> data;
	if (fProcs.fImageProc) {
	data = fProcs.fImageProc(const_cast<SkImage*>(image), fProcs.fImageCtx);
	}
	if (!data) {
	data = image->encodeToData();
	}
	this->writeDataAsByteArray(data.get());

	if (flags & SkWriteBufferImageFlags::kHasMipmap) {
	this->writeDataAsByteArray(mips->serialize().get());
	}
	}

	void SkBinaryWriteBuffer::writeTypeface(SkTypeface* obj) {
	// Write 32 bits (signed)
	// 0 -- default font
	// >0 -- index
	// <0 -- custom (serial procs)

	if (obj == nullptr) {
	fWriter.write32(0);
	} else if (fProcs.fTypefaceProc) {
	auto data = fProcs.fTypefaceProc(obj, fProcs.fTypefaceCtx);
	if (data) {
	size_t size = data->size();
	if (!SkTFitsIn<int32_t>(size)) {
	size = 0; // fall back to default font
	}
	int32_t ssize = SkToS32(size);
	fWriter.write32(-ssize); // negative to signal custom
	if (size) {
	this->writePad32(data->data(), size);
	}
	return;
	}
	// no data means fall through for std behavior
	}
	fWriter.write32(fTFSet ? fTFSet->add(obj) : 0);
	}

	void SkBinaryWriteBuffer::writePaint(const SkPaint& paint) {
	SkPaintPriv::Flatten(paint, *this);
	}

	void SkBinaryWriteBuffer::setFactoryRecorder(sk_sp<SkFactorySet> rec) {
	fFactorySet = std::move(rec);
	}

	void SkBinaryWriteBuffer::setTypefaceRecorder(sk_sp<SkRefCntSet> rec) {
	fTFSet = std::move(rec);
	}

	void SkBinaryWriteBuffer::writeFlattenable(const SkFlattenable* flattenable) {
	if (nullptr == flattenable) {
	this->write32(0);
	return;
	}

	/*
	* We can write 1 of 2 versions of the flattenable:
	*
	* 1. index into fFactorySet: This assumes the writer will later resolve the function-ptrs
	* into strings for its reader. SkPicture does exactly this, by writing a table of names
	* (matching the indices) up front in its serialized form.
	*
	* 2. string name of the flattenable or index into fFlattenableDict: We store the string to
	* allow the reader to specify its own factories after write time. In order to improve
	* compression, if we have already written the string, we write its index instead.
	*/

	if (SkFlattenable::Factory factory = flattenable->getFactory(); factory && fFactorySet) {
	this->write32(fFactorySet->add(factory));
	} else {
	const char* name = flattenable->getTypeName();
	SkASSERT(name);
	SkASSERT(0 != strcmp("", name));

	if (uint32_t* indexPtr = fFlattenableDict.find(name)) {
	// We will write the index as a 32-bit int. We want the first byte
	// that we send to be zero - this will act as a sentinel that we
	// have an index (not a string). This means that we will send the
	// the index shifted left by 8. The remaining 24-bits should be
	// plenty to store the index. Note that this strategy depends on
	// being little endian, and type names being non-empty.
	SkASSERT(0 == *indexPtr >> 24);
	this->write32(*indexPtr << 8);
	} else {
	this->writeString(name);
	fFlattenableDict.set(name, fFlattenableDict.count() + 1);
	}
	}

	// make room for the size of the flattened object
	(void)fWriter.reserve(sizeof(uint32_t));
	// record the current size, so we can subtract after the object writes.
	size_t offset = fWriter.bytesWritten();
	// now flatten the object
	flattenable->flatten(*this);
	size_t objSize = fWriter.bytesWritten() - offset;
	// record the obj's size
	fWriter.overwriteTAt(offset - sizeof(uint32_t), SkToU32(objSize));
	}