src/core/SkReadBuffer.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 "include/core/SkBitmap.h"
 #include "include/core/SkData.h"
 #include "include/core/SkImage.h"
 #include "include/core/SkImageGenerator.h"
 #include "include/core/SkStream.h"
 #include "include/core/SkTypeface.h"
 #include "src/core/SkAutoMalloc.h"
 #include "src/core/SkMathPriv.h"
 #include "src/core/SkMatrixPriv.h"
 #include "src/core/SkMipmapBuilder.h"
 #include "src/core/SkReadBuffer.h"
 #include "src/core/SkSafeMath.h"

 namespace {
     // This generator intentionally should always fail on all attempts to get its pixels,
     // simulating a bad or empty codec stream.
     class EmptyImageGenerator final : public SkImageGenerator {
     public:
         EmptyImageGenerator(const SkImageInfo& info) : INHERITED(info) { }

     private:
         using INHERITED = SkImageGenerator;
     };

     static sk_sp<SkImage> MakeEmptyImage(int width, int height) {
         return SkImage::MakeFromGenerator(
               std::make_unique<EmptyImageGenerator>(SkImageInfo::MakeN32Premul(width, height)));
     }

 } // anonymous namespace

 void SkReadBuffer::setMemory(const void* data, size_t size) {
     this->validate(IsPtrAlign4(data) && (SkAlign4(size) == size));
     if (!fError) {
         fBase = fCurr = (const char*)data;
         fStop = fBase + size;
     }
 }

 void SkReadBuffer::setInvalid() {
     if (!fError) {
         // When an error is found, send the read cursor to the end of the stream
         fCurr = fStop;
         fError = true;
     }
 }

 const void* SkReadBuffer::skip(size_t size) {
     size_t inc = SkAlign4(size);
     this->validate(inc >= size);
     const void* addr = fCurr;
     this->validate(IsPtrAlign4(addr) && this->isAvailable(inc));
     if (fError) {
         return nullptr;
     }

     fCurr += inc;
     return addr;
 }

 const void* SkReadBuffer::skip(size_t count, size_t size) {
     return this->skip(SkSafeMath::Mul(count, size));
 }

 void SkReadBuffer::setDeserialProcs(const SkDeserialProcs& procs) {
     fProcs = procs;
 }

 bool SkReadBuffer::readBool() {
     uint32_t value = this->readUInt();
     // Boolean value should be either 0 or 1
     this->validate(!(value & ~1));
     return value != 0;
 }

 SkColor SkReadBuffer::readColor() {
     return this->readUInt();
 }

 int32_t SkReadBuffer::readInt() {
     const size_t inc = sizeof(int32_t);
     if (!this->validate(IsPtrAlign4(fCurr) && this->isAvailable(inc))) {
         return 0;
     }
     int32_t value = *((const int32_t*)fCurr);
     fCurr += inc;
     return value;
 }

 SkScalar SkReadBuffer::readScalar() {
     const size_t inc = sizeof(SkScalar);
     if (!this->validate(IsPtrAlign4(fCurr) && this->isAvailable(inc))) {
         return 0;
     }
     SkScalar value = *((const SkScalar*)fCurr);
     fCurr += inc;
     return value;
 }

 uint32_t SkReadBuffer::readUInt() {
     return this->readInt();
 }

 int32_t SkReadBuffer::read32() {
     return this->readInt();
 }

 uint8_t SkReadBuffer::peekByte() {
     if (this->available() <= 0) {
         fError = true;
         return 0;
     }
     return *((uint8_t*)fCurr);
 }

 bool SkReadBuffer::readPad32(void* buffer, size_t bytes) {
     if (const void* src = this->skip(bytes)) {
         // buffer might be null if bytes is zero (see SkAutoMalloc), hence we call
         // the careful version of memcpy.
         sk_careful_memcpy(buffer, src, bytes);
         return true;
     }
     return false;
 }

 const char* SkReadBuffer::readString(size_t* len) {
     *len = this->readUInt();

     // The string is len characters and a terminating \0.
     const char* c_str = this->skipT<char>(*len+1);

     if (this->validate(c_str && c_str[*len] == '\0')) {
         return c_str;
     }
     return nullptr;
 }

 void SkReadBuffer::readString(SkString* string) {
     size_t len;
     if (const char* c_str = this->readString(&len)) {
         string->set(c_str, len);
         return;
     }
     string->reset();
 }

 void SkReadBuffer::readColor4f(SkColor4f* color) {
     if (!this->readPad32(color, sizeof(SkColor4f))) {
         *color = {0, 0, 0, 0};
     }
 }

 void SkReadBuffer::readPoint(SkPoint* point) {
     point->fX = this->readScalar();
     point->fY = this->readScalar();
 }

 void SkReadBuffer::readPoint3(SkPoint3* point) {
     this->readPad32(point, sizeof(SkPoint3));
 }

 void SkReadBuffer::read(SkM44* matrix) {
     if (this->isValid()) {
         if (const float* m = (const float*)this->skip(sizeof(float) * 16)) {
             *matrix = SkM44::ColMajor(m);
         }
     }
     if (!this->isValid()) {
         *matrix = SkM44();
     }
 }

 void SkReadBuffer::readMatrix(SkMatrix* matrix) {
     size_t size = 0;
     if (this->isValid()) {
         size = SkMatrixPriv::ReadFromMemory(matrix, fCurr, this->available());
         (void)this->validate((SkAlign4(size) == size) && (0 != size));
     }
     if (!this->isValid()) {
         matrix->reset();
     }
     (void)this->skip(size);
 }

 void SkReadBuffer::readIRect(SkIRect* rect) {
     if (!this->readPad32(rect, sizeof(SkIRect))) {
         rect->setEmpty();
     }
 }

 void SkReadBuffer::readRect(SkRect* rect) {
     if (!this->readPad32(rect, sizeof(SkRect))) {
         rect->setEmpty();
     }
 }

 SkRect SkReadBuffer::readRect() {
     SkRect r;
     if (!this->readPad32(&r, sizeof(SkRect))) {
         r.setEmpty();
     }
     return r;
 }

 SkSamplingOptions SkReadBuffer::readSampling() {
     if (!this->isVersionLT(SkPicturePriv::kAnisotropicFilter)) {
         int maxAniso = this->readInt();
         if (maxAniso != 0) {
             return SkSamplingOptions::Aniso(maxAniso);
         }
     }
     if (this->readBool()) {
         float B = this->readScalar();
         float C = this->readScalar();
         return SkSamplingOptions({B, C});
     } else {
         SkFilterMode filter = this->read32LE(SkFilterMode::kLinear);
         SkMipmapMode mipmap = this->read32LE(SkMipmapMode::kLinear);
         return SkSamplingOptions(filter, mipmap);
     }
 }

 void SkReadBuffer::readRRect(SkRRect* rrect) {
     size_t size = 0;
     if (!fError) {
         size = rrect->readFromMemory(fCurr, this->available());
         if (!this->validate((SkAlign4(size) == size) && (0 != size))) {
             rrect->setEmpty();
         }
     }
     (void)this->skip(size);
 }

 void SkReadBuffer::readRegion(SkRegion* region) {
     size_t size = 0;
     if (!fError) {
         size = region->readFromMemory(fCurr, this->available());
         if (!this->validate((SkAlign4(size) == size) && (0 != size))) {
             region->setEmpty();
         }
     }
     (void)this->skip(size);
 }

 void SkReadBuffer::readPath(SkPath* path) {
     size_t size = 0;
     if (!fError) {
         size = path->readFromMemory(fCurr, this->available());
         if (!this->validate((SkAlign4(size) == size) && (0 != size))) {
             path->reset();
         }
     }
     (void)this->skip(size);
 }

 bool SkReadBuffer::readArray(void* value, size_t size, size_t elementSize) {
     const uint32_t count = this->readUInt();
     return this->validate(size == count) &&
            this->readPad32(value, SkSafeMath::Mul(size, elementSize));
 }

 bool SkReadBuffer::readByteArray(void* value, size_t size) {
     return this->readArray(value, size, sizeof(uint8_t));
 }

 bool SkReadBuffer::readColorArray(SkColor* colors, size_t size) {
     return this->readArray(colors, size, sizeof(SkColor));
 }

 bool SkReadBuffer::readColor4fArray(SkColor4f* colors, size_t size) {
     return this->readArray(colors, size, sizeof(SkColor4f));
 }

 bool SkReadBuffer::readIntArray(int32_t* values, size_t size) {
     return this->readArray(values, size, sizeof(int32_t));
 }

 bool SkReadBuffer::readPointArray(SkPoint* points, size_t size) {
     return this->readArray(points, size, sizeof(SkPoint));
 }

 bool SkReadBuffer::readScalarArray(SkScalar* values, size_t size) {
     return this->readArray(values, size, sizeof(SkScalar));
 }

 const void* SkReadBuffer::skipByteArray(size_t* size) {
     const uint32_t count = this->readUInt();
     const void* buf = this->skip(count);
     if (size) {
         *size = this->isValid() ? count : 0;
     }
     return buf;
 }

 sk_sp<SkData> SkReadBuffer::readByteArrayAsData() {
     size_t numBytes = this->getArrayCount();
     if (!this->validate(this->isAvailable(numBytes))) {
         return nullptr;
     }

     SkAutoMalloc buffer(numBytes);
     if (!this->readByteArray(buffer.get(), numBytes)) {
         return nullptr;
     }
     return SkData::MakeFromMalloc(buffer.release(), numBytes);
 }

 uint32_t SkReadBuffer::getArrayCount() {
     const size_t inc = sizeof(uint32_t);
     if (!this->validate(IsPtrAlign4(fCurr) && this->isAvailable(inc))) {
         return 0;
     }
     return *((uint32_t*)fCurr);
 }

 #include "src/core/SkMipmap.h"

 // If we see a corrupt stream, we return null (fail). If we just fail trying to decode
 // the image, we don't fail, but return a 1x1 empty image.
 sk_sp<SkImage> SkReadBuffer::readImage() {
     uint32_t flags = this->read32();

     sk_sp<SkImage> image;
     {
         sk_sp<SkData> data = this->readByteArrayAsData();
         if (!data) {
             this->validate(false);
             return nullptr;
         }
         if (fProcs.fImageProc) {
             image = fProcs.fImageProc(data->data(), data->size(), fProcs.fImageCtx);
         }
         if (!image) {
             std::optional<SkAlphaType> alphaType = std::nullopt;
             if (flags & SkWriteBufferImageFlags::kUnpremul) {
                 alphaType = kUnpremul_SkAlphaType;
             }
             image = SkImage::MakeFromEncoded(std::move(data), alphaType);
         }
     }

     if (flags & SkWriteBufferImageFlags::kHasSubsetRect) {
         SkIRect subset;
         this->readIRect(&subset);
         if (image) {
             image = image->makeSubset(subset);
         }
     }

     if (flags & SkWriteBufferImageFlags::kHasMipmap) {
         sk_sp<SkData> data = this->readByteArrayAsData();
         if (!data) {
             this->validate(false);
             return nullptr;
         }
         if (image) {
             SkMipmapBuilder builder(image->imageInfo());
             if (SkMipmap::Deserialize(&builder, data->data(), data->size())) {
                 // TODO: need to make lazy images support mips
                 if (auto ri = image->makeRasterImage()) {
                     image = ri;
                 }
                 image = builder.attachTo(image);
                 SkASSERT(image);    // withMipmaps should never return null
             }
         }
     }
     return image ? image : MakeEmptyImage(1, 1);
 }

 sk_sp<SkTypeface> SkReadBuffer::readTypeface() {
     // Read 32 bits (signed)
     //   0 -- return null (default font)
     //  >0 -- index
     //  <0 -- custom (serial procs) : negative size in bytes

     int32_t index = this->read32();
     if (index == 0) {
         return nullptr;
     } else if (index > 0) {
         if (!this->validate(index <= fTFCount)) {
             return nullptr;
         }
         return fTFArray[index - 1];
     } else {    // custom
         size_t size = sk_negate_to_size_t(index);
         const void* data = this->skip(size);
         if (!this->validate(data != nullptr && fProcs.fTypefaceProc)) {
             return nullptr;
         }
         return fProcs.fTypefaceProc(data, size, fProcs.fTypefaceCtx);
     }
 }

 SkFlattenable* SkReadBuffer::readRawFlattenable() {
     SkFlattenable::Factory factory = nullptr;

     if (fFactoryCount > 0) {
         int32_t index = this->read32();
         if (0 == index || !this->isValid()) {
             return nullptr; // writer failed to give us the flattenable
         }
         if (index < 0) {
             this->validate(false);
             return nullptr;
         }
         index -= 1;     // we stored the index-base-1
         if ((unsigned)index >= (unsigned)fFactoryCount) {
             this->validate(false);
             return nullptr;
         }
         factory = fFactoryArray[index];
     } else {
         if (this->peekByte() != 0) {
             // If the first byte is non-zero, the flattenable is specified by a string.
             size_t ignored_length;
             if (const char* name = this->readString(&ignored_length)) {
                 factory = SkFlattenable::NameToFactory(name);
                 fFlattenableDict.set(fFlattenableDict.count() + 1, factory);
             }
         } else {
             // Read the index.  We are guaranteed that the first byte
             // is zeroed, so we must shift down a byte.
             uint32_t index = this->readUInt() >> 8;
             if (index == 0) {
                 return nullptr; // writer failed to give us the flattenable
             }

             if (SkFlattenable::Factory* found = fFlattenableDict.find(index)) {
                 factory = *found;
             }
         }

         if (!this->validate(factory != nullptr)) {
             return nullptr;
         }
     }

     // if we get here, factory may still be null, but if that is the case, the
     // failure was ours, not the writer.
     sk_sp<SkFlattenable> obj;
     uint32_t sizeRecorded = this->read32();
     if (factory) {
         size_t offset = this->offset();
         obj = (*factory)(*this);
         // check that we read the amount we expected
         size_t sizeRead = this->offset() - offset;
         if (sizeRecorded != sizeRead) {
             this->validate(false);
             return nullptr;
         }
     } else {
         // we must skip the remaining data
         this->skip(sizeRecorded);
     }
     if (!this->isValid()) {
         return nullptr;
     }
     return obj.release();
 }

 SkFlattenable* SkReadBuffer::readFlattenable(SkFlattenable::Type ft) {
     SkFlattenable* obj = this->readRawFlattenable();
     if (obj && obj->getFlattenableType() != ft) {
         this->validate(false);
         obj->unref();
         return nullptr;
     }
     return obj;
 }

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

 int32_t SkReadBuffer::checkInt(int32_t min, int32_t max) {
     SkASSERT(min <= max);
     int32_t value = this->read32();
     if (value < min || value > max) {
         this->validate(false);
         value = min;
     }
     return value;
 }

 SkLegacyFQ SkReadBuffer::checkFilterQuality() {
     return this->checkRange<SkLegacyFQ>(kNone_SkLegacyFQ, kLast_SkLegacyFQ);
 }
	/*
	* 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 "include/core/SkBitmap.h"
	#include "include/core/SkData.h"
	#include "include/core/SkImage.h"
	#include "include/core/SkImageGenerator.h"
	#include "include/core/SkStream.h"
	#include "include/core/SkTypeface.h"
	#include "src/core/SkAutoMalloc.h"
	#include "src/core/SkMathPriv.h"
	#include "src/core/SkMatrixPriv.h"
	#include "src/core/SkMipmapBuilder.h"
	#include "src/core/SkReadBuffer.h"
	#include "src/core/SkSafeMath.h"

	namespace {
	// This generator intentionally should always fail on all attempts to get its pixels,
	// simulating a bad or empty codec stream.
	class EmptyImageGenerator final : public SkImageGenerator {
	public:
	EmptyImageGenerator(const SkImageInfo& info) : INHERITED(info) { }

	private:
	using INHERITED = SkImageGenerator;
	};

	static sk_sp<SkImage> MakeEmptyImage(int width, int height) {
	return SkImage::MakeFromGenerator(
	std::make_unique<EmptyImageGenerator>(SkImageInfo::MakeN32Premul(width, height)));
	}

	} // anonymous namespace

	void SkReadBuffer::setMemory(const void* data, size_t size) {
	this->validate(IsPtrAlign4(data) && (SkAlign4(size) == size));
	if (!fError) {
	fBase = fCurr = (const char*)data;
	fStop = fBase + size;
	}
	}

	void SkReadBuffer::setInvalid() {
	if (!fError) {
	// When an error is found, send the read cursor to the end of the stream
	fCurr = fStop;
	fError = true;
	}
	}

	const void* SkReadBuffer::skip(size_t size) {
	size_t inc = SkAlign4(size);
	this->validate(inc >= size);
	const void* addr = fCurr;
	this->validate(IsPtrAlign4(addr) && this->isAvailable(inc));
	if (fError) {
	return nullptr;
	}

	fCurr += inc;
	return addr;
	}

	const void* SkReadBuffer::skip(size_t count, size_t size) {
	return this->skip(SkSafeMath::Mul(count, size));
	}

	void SkReadBuffer::setDeserialProcs(const SkDeserialProcs& procs) {
	fProcs = procs;
	}

	bool SkReadBuffer::readBool() {
	uint32_t value = this->readUInt();
	// Boolean value should be either 0 or 1
	this->validate(!(value & ~1));
	return value != 0;
	}

	SkColor SkReadBuffer::readColor() {
	return this->readUInt();
	}

	int32_t SkReadBuffer::readInt() {
	const size_t inc = sizeof(int32_t);
	if (!this->validate(IsPtrAlign4(fCurr) && this->isAvailable(inc))) {
	return 0;
	}
	int32_t value = ((const int32_t)fCurr);
	fCurr += inc;
	return value;
	}

	SkScalar SkReadBuffer::readScalar() {
	const size_t inc = sizeof(SkScalar);
	if (!this->validate(IsPtrAlign4(fCurr) && this->isAvailable(inc))) {
	return 0;
	}
	SkScalar value = ((const SkScalar)fCurr);
	fCurr += inc;
	return value;
	}

	uint32_t SkReadBuffer::readUInt() {
	return this->readInt();
	}

	int32_t SkReadBuffer::read32() {
	return this->readInt();
	}

	uint8_t SkReadBuffer::peekByte() {
	if (this->available() <= 0) {
	fError = true;
	return 0;
	}
	return ((uint8_t)fCurr);
	}

	bool SkReadBuffer::readPad32(void* buffer, size_t bytes) {
	if (const void* src = this->skip(bytes)) {
	// buffer might be null if bytes is zero (see SkAutoMalloc), hence we call
	// the careful version of memcpy.
	sk_careful_memcpy(buffer, src, bytes);
	return true;
	}
	return false;
	}

	const char* SkReadBuffer::readString(size_t* len) {
	*len = this->readUInt();

	// The string is len characters and a terminating \0.
	const char* c_str = this->skipT<char>(*len+1);

	if (this->validate(c_str && c_str[*len] == '\0')) {
	return c_str;
	}
	return nullptr;
	}

	void SkReadBuffer::readString(SkString* string) {
	size_t len;
	if (const char* c_str = this->readString(&len)) {
	string->set(c_str, len);
	return;
	}
	string->reset();
	}

	void SkReadBuffer::readColor4f(SkColor4f* color) {
	if (!this->readPad32(color, sizeof(SkColor4f))) {
	*color = {0, 0, 0, 0};
	}
	}

	void SkReadBuffer::readPoint(SkPoint* point) {
	point->fX = this->readScalar();
	point->fY = this->readScalar();
	}

	void SkReadBuffer::readPoint3(SkPoint3* point) {
	this->readPad32(point, sizeof(SkPoint3));
	}

	void SkReadBuffer::read(SkM44* matrix) {
	if (this->isValid()) {
	if (const float* m = (const float)this->skip(sizeof(float) 16)) {
	*matrix = SkM44::ColMajor(m);
	}
	}
	if (!this->isValid()) {
	*matrix = SkM44();
	}
	}

	void SkReadBuffer::readMatrix(SkMatrix* matrix) {
	size_t size = 0;
	if (this->isValid()) {
	size = SkMatrixPriv::ReadFromMemory(matrix, fCurr, this->available());
	(void)this->validate((SkAlign4(size) == size) && (0 != size));
	}
	if (!this->isValid()) {
	matrix->reset();
	}
	(void)this->skip(size);
	}

	void SkReadBuffer::readIRect(SkIRect* rect) {
	if (!this->readPad32(rect, sizeof(SkIRect))) {
	rect->setEmpty();
	}
	}

	void SkReadBuffer::readRect(SkRect* rect) {
	if (!this->readPad32(rect, sizeof(SkRect))) {
	rect->setEmpty();
	}
	}

	SkRect SkReadBuffer::readRect() {
	SkRect r;
	if (!this->readPad32(&r, sizeof(SkRect))) {
	r.setEmpty();
	}
	return r;
	}

	SkSamplingOptions SkReadBuffer::readSampling() {
	if (!this->isVersionLT(SkPicturePriv::kAnisotropicFilter)) {
	int maxAniso = this->readInt();
	if (maxAniso != 0) {
	return SkSamplingOptions::Aniso(maxAniso);
	}
	}
	if (this->readBool()) {
	float B = this->readScalar();
	float C = this->readScalar();
	return SkSamplingOptions({B, C});
	} else {
	SkFilterMode filter = this->read32LE(SkFilterMode::kLinear);
	SkMipmapMode mipmap = this->read32LE(SkMipmapMode::kLinear);
	return SkSamplingOptions(filter, mipmap);
	}
	}

	void SkReadBuffer::readRRect(SkRRect* rrect) {
	size_t size = 0;
	if (!fError) {
	size = rrect->readFromMemory(fCurr, this->available());
	if (!this->validate((SkAlign4(size) == size) && (0 != size))) {
	rrect->setEmpty();
	}
	}
	(void)this->skip(size);
	}

	void SkReadBuffer::readRegion(SkRegion* region) {
	size_t size = 0;
	if (!fError) {
	size = region->readFromMemory(fCurr, this->available());
	if (!this->validate((SkAlign4(size) == size) && (0 != size))) {
	region->setEmpty();
	}
	}
	(void)this->skip(size);
	}

	void SkReadBuffer::readPath(SkPath* path) {
	size_t size = 0;
	if (!fError) {
	size = path->readFromMemory(fCurr, this->available());
	if (!this->validate((SkAlign4(size) == size) && (0 != size))) {
	path->reset();
	}
	}
	(void)this->skip(size);
	}

	bool SkReadBuffer::readArray(void* value, size_t size, size_t elementSize) {
	const uint32_t count = this->readUInt();
	return this->validate(size == count) &&
	this->readPad32(value, SkSafeMath::Mul(size, elementSize));
	}

	bool SkReadBuffer::readByteArray(void* value, size_t size) {
	return this->readArray(value, size, sizeof(uint8_t));
	}

	bool SkReadBuffer::readColorArray(SkColor* colors, size_t size) {
	return this->readArray(colors, size, sizeof(SkColor));
	}

	bool SkReadBuffer::readColor4fArray(SkColor4f* colors, size_t size) {
	return this->readArray(colors, size, sizeof(SkColor4f));
	}

	bool SkReadBuffer::readIntArray(int32_t* values, size_t size) {
	return this->readArray(values, size, sizeof(int32_t));
	}

	bool SkReadBuffer::readPointArray(SkPoint* points, size_t size) {
	return this->readArray(points, size, sizeof(SkPoint));
	}

	bool SkReadBuffer::readScalarArray(SkScalar* values, size_t size) {
	return this->readArray(values, size, sizeof(SkScalar));
	}

	const void* SkReadBuffer::skipByteArray(size_t* size) {
	const uint32_t count = this->readUInt();
	const void* buf = this->skip(count);
	if (size) {
	*size = this->isValid() ? count : 0;
	}
	return buf;
	}

	sk_sp<SkData> SkReadBuffer::readByteArrayAsData() {
	size_t numBytes = this->getArrayCount();
	if (!this->validate(this->isAvailable(numBytes))) {
	return nullptr;
	}

	SkAutoMalloc buffer(numBytes);
	if (!this->readByteArray(buffer.get(), numBytes)) {
	return nullptr;
	}
	return SkData::MakeFromMalloc(buffer.release(), numBytes);
	}

	uint32_t SkReadBuffer::getArrayCount() {
	const size_t inc = sizeof(uint32_t);
	if (!this->validate(IsPtrAlign4(fCurr) && this->isAvailable(inc))) {
	return 0;
	}
	return ((uint32_t)fCurr);
	}

	#include "src/core/SkMipmap.h"

	// If we see a corrupt stream, we return null (fail). If we just fail trying to decode
	// the image, we don't fail, but return a 1x1 empty image.
	sk_sp<SkImage> SkReadBuffer::readImage() {
	uint32_t flags = this->read32();

	sk_sp<SkImage> image;
	{
	sk_sp<SkData> data = this->readByteArrayAsData();
	if (!data) {
	this->validate(false);
	return nullptr;
	}
	if (fProcs.fImageProc) {
	image = fProcs.fImageProc(data->data(), data->size(), fProcs.fImageCtx);
	}
	if (!image) {
	std::optional<SkAlphaType> alphaType = std::nullopt;
	if (flags & SkWriteBufferImageFlags::kUnpremul) {
	alphaType = kUnpremul_SkAlphaType;
	}
	image = SkImage::MakeFromEncoded(std::move(data), alphaType);
	}
	}

	if (flags & SkWriteBufferImageFlags::kHasSubsetRect) {
	SkIRect subset;
	this->readIRect(&subset);
	if (image) {
	image = image->makeSubset(subset);
	}
	}

	if (flags & SkWriteBufferImageFlags::kHasMipmap) {
	sk_sp<SkData> data = this->readByteArrayAsData();
	if (!data) {
	this->validate(false);
	return nullptr;
	}
	if (image) {
	SkMipmapBuilder builder(image->imageInfo());
	if (SkMipmap::Deserialize(&builder, data->data(), data->size())) {
	// TODO: need to make lazy images support mips
	if (auto ri = image->makeRasterImage()) {
	image = ri;
	}
	image = builder.attachTo(image);
	SkASSERT(image); // withMipmaps should never return null
	}
	}
	}
	return image ? image : MakeEmptyImage(1, 1);
	}

	sk_sp<SkTypeface> SkReadBuffer::readTypeface() {
	// Read 32 bits (signed)
	// 0 -- return null (default font)
	// >0 -- index
	// <0 -- custom (serial procs) : negative size in bytes

	int32_t index = this->read32();
	if (index == 0) {
	return nullptr;
	} else if (index > 0) {
	if (!this->validate(index <= fTFCount)) {
	return nullptr;
	}
	return fTFArray[index - 1];
	} else { // custom
	size_t size = sk_negate_to_size_t(index);
	const void* data = this->skip(size);
	if (!this->validate(data != nullptr && fProcs.fTypefaceProc)) {
	return nullptr;
	}
	return fProcs.fTypefaceProc(data, size, fProcs.fTypefaceCtx);
	}
	}

	SkFlattenable* SkReadBuffer::readRawFlattenable() {
	SkFlattenable::Factory factory = nullptr;

	if (fFactoryCount > 0) {
	int32_t index = this->read32();
	if (0 == index \|\| !this->isValid()) {
	return nullptr; // writer failed to give us the flattenable
	}
	if (index < 0) {
	this->validate(false);
	return nullptr;
	}
	index -= 1; // we stored the index-base-1
	if ((unsigned)index >= (unsigned)fFactoryCount) {
	this->validate(false);
	return nullptr;
	}
	factory = fFactoryArray[index];
	} else {
	if (this->peekByte() != 0) {
	// If the first byte is non-zero, the flattenable is specified by a string.
	size_t ignored_length;
	if (const char* name = this->readString(&ignored_length)) {
	factory = SkFlattenable::NameToFactory(name);
	fFlattenableDict.set(fFlattenableDict.count() + 1, factory);
	}
	} else {
	// Read the index. We are guaranteed that the first byte
	// is zeroed, so we must shift down a byte.
	uint32_t index = this->readUInt() >> 8;
	if (index == 0) {
	return nullptr; // writer failed to give us the flattenable
	}

	if (SkFlattenable::Factory* found = fFlattenableDict.find(index)) {
	factory = *found;
	}
	}

	if (!this->validate(factory != nullptr)) {
	return nullptr;
	}
	}

	// if we get here, factory may still be null, but if that is the case, the
	// failure was ours, not the writer.
	sk_sp<SkFlattenable> obj;
	uint32_t sizeRecorded = this->read32();
	if (factory) {
	size_t offset = this->offset();
	obj = (factory)(this);
	// check that we read the amount we expected
	size_t sizeRead = this->offset() - offset;
	if (sizeRecorded != sizeRead) {
	this->validate(false);
	return nullptr;
	}
	} else {
	// we must skip the remaining data
	this->skip(sizeRecorded);
	}
	if (!this->isValid()) {
	return nullptr;
	}
	return obj.release();
	}

	SkFlattenable* SkReadBuffer::readFlattenable(SkFlattenable::Type ft) {
	SkFlattenable* obj = this->readRawFlattenable();
	if (obj && obj->getFlattenableType() != ft) {
	this->validate(false);
	obj->unref();
	return nullptr;
	}
	return obj;
	}

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

	int32_t SkReadBuffer::checkInt(int32_t min, int32_t max) {
	SkASSERT(min <= max);
	int32_t value = this->read32();
	if (value < min \|\| value > max) {
	this->validate(false);
	value = min;
	}
	return value;
	}

	SkLegacyFQ SkReadBuffer::checkFilterQuality() {
	return this->checkRange<SkLegacyFQ>(kNone_SkLegacyFQ, kLast_SkLegacyFQ);
	}