/* * 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. */ #include "SkStream.h" #include "SkStreamPriv.h" #include "SkData.h" #include "SkFixed.h" #include "SkString.h" #include "SkOSFile.h" #include "SkTypes.h" /////////////////////////////////////////////////////////////////////////////// int8_t SkStream::readS8() { int8_t value; SkDEBUGCODE(size_t len =) this->read(&value, 1); SkASSERT(1 == len); return value; } int16_t SkStream::readS16() { int16_t value; SkDEBUGCODE(size_t len =) this->read(&value, 2); SkASSERT(2 == len); return value; } int32_t SkStream::readS32() { int32_t value; SkDEBUGCODE(size_t len =) this->read(&value, 4); SkASSERT(4 == len); return value; } SkScalar SkStream::readScalar() { SkScalar value; SkDEBUGCODE(size_t len =) this->read(&value, sizeof(SkScalar)); SkASSERT(sizeof(SkScalar) == len); return value; } #define SK_MAX_BYTE_FOR_U8 0xFD #define SK_BYTE_SENTINEL_FOR_U16 0xFE #define SK_BYTE_SENTINEL_FOR_U32 0xFF size_t SkStream::readPackedUInt() { uint8_t byte; if (!this->read(&byte, 1)) { return 0; } if (SK_BYTE_SENTINEL_FOR_U16 == byte) { return this->readU16(); } else if (SK_BYTE_SENTINEL_FOR_U32 == byte) { return this->readU32(); } else { return byte; } } SkData* SkStream::readData() { size_t size = this->readU32(); if (0 == size) { return SkData::NewEmpty(); } else { void* buffer = sk_malloc_throw(size); this->read(buffer, size); return SkData::NewFromMalloc(buffer, size); } } ////////////////////////////////////////////////////////////////////////////////////// SkWStream::~SkWStream() { } void SkWStream::newline() { this->write("\n", 1); } void SkWStream::flush() { } bool SkWStream::writeText(const char text[]) { SkASSERT(text); return this->write(text, strlen(text)); } bool SkWStream::writeDecAsText(int32_t dec) { SkString tmp; tmp.appendS32(dec); return this->write(tmp.c_str(), tmp.size()); } bool SkWStream::writeBigDecAsText(int64_t dec, int minDigits) { SkString tmp; tmp.appendS64(dec, minDigits); return this->write(tmp.c_str(), tmp.size()); } bool SkWStream::writeHexAsText(uint32_t hex, int digits) { SkString tmp; tmp.appendHex(hex, digits); return this->write(tmp.c_str(), tmp.size()); } bool SkWStream::writeScalarAsText(SkScalar value) { SkString tmp; tmp.appendScalar(value); return this->write(tmp.c_str(), tmp.size()); } bool SkWStream::write8(U8CPU value) { uint8_t v = SkToU8(value); return this->write(&v, 1); } bool SkWStream::write16(U16CPU value) { uint16_t v = SkToU16(value); return this->write(&v, 2); } bool SkWStream::write32(uint32_t value) { return this->write(&value, 4); } bool SkWStream::writeScalar(SkScalar value) { return this->write(&value, sizeof(value)); } int SkWStream::SizeOfPackedUInt(size_t value) { if (value <= SK_MAX_BYTE_FOR_U8) { return 1; } else if (value <= 0xFFFF) { return 3; } return 5; } bool SkWStream::writePackedUInt(size_t value) { uint8_t data[5]; size_t len = 1; if (value <= SK_MAX_BYTE_FOR_U8) { data[0] = value; len = 1; } else if (value <= 0xFFFF) { uint16_t value16 = value; data[0] = SK_BYTE_SENTINEL_FOR_U16; memcpy(&data[1], &value16, 2); len = 3; } else { uint32_t value32 = SkToU32(value); data[0] = SK_BYTE_SENTINEL_FOR_U32; memcpy(&data[1], &value32, 4); len = 5; } return this->write(data, len); } bool SkWStream::writeStream(SkStream* stream, size_t length) { char scratch[1024]; const size_t MAX = sizeof(scratch); while (length != 0) { size_t n = length; if (n > MAX) { n = MAX; } stream->read(scratch, n); if (!this->write(scratch, n)) { return false; } length -= n; } return true; } bool SkWStream::writeData(const SkData* data) { if (data) { this->write32(SkToU32(data->size())); this->write(data->data(), data->size()); } else { this->write32(0); } return true; } /////////////////////////////////////////////////////////////////////////////// SkFILEStream::SkFILEStream(const char file[]) : fName(file), fOwnership(kCallerPasses_Ownership) { fFILE = file ? sk_fopen(fName.c_str(), kRead_SkFILE_Flag) : NULL; } SkFILEStream::SkFILEStream(FILE* file, Ownership ownership) : fFILE((SkFILE*)file) , fOwnership(ownership) { } SkFILEStream::~SkFILEStream() { if (fFILE && fOwnership != kCallerRetains_Ownership) { sk_fclose(fFILE); } } void SkFILEStream::setPath(const char path[]) { fName.set(path); if (fFILE) { sk_fclose(fFILE); fFILE = NULL; } if (path) { fFILE = sk_fopen(fName.c_str(), kRead_SkFILE_Flag); } } size_t SkFILEStream::read(void* buffer, size_t size) { if (fFILE) { return sk_fread(buffer, size, fFILE); } return 0; } bool SkFILEStream::isAtEnd() const { return sk_feof(fFILE); } bool SkFILEStream::rewind() { if (fFILE) { if (sk_frewind(fFILE)) { return true; } // we hit an error sk_fclose(fFILE); fFILE = NULL; } return false; } SkStreamAsset* SkFILEStream::duplicate() const { if (NULL == fFILE) { return new SkMemoryStream(); } if (NULL != fData.get()) { return new SkMemoryStream(fData); } if (!fName.isEmpty()) { SkAutoTUnref that(new SkFILEStream(fName.c_str())); if (sk_fidentical(that->fFILE, this->fFILE)) { return that.detach(); } } fData.reset(SkData::NewFromFILE(fFILE)); if (NULL == fData.get()) { return NULL; } return new SkMemoryStream(fData); } size_t SkFILEStream::getPosition() const { return sk_ftell(fFILE); } bool SkFILEStream::seek(size_t position) { return sk_fseek(fFILE, position); } bool SkFILEStream::move(long offset) { return sk_fmove(fFILE, offset); } SkStreamAsset* SkFILEStream::fork() const { SkAutoTUnref that(this->duplicate()); that->seek(this->getPosition()); return that.detach(); } size_t SkFILEStream::getLength() const { return sk_fgetsize(fFILE); } const void* SkFILEStream::getMemoryBase() { if (NULL == fData.get()) { return NULL; } return fData->data(); } /////////////////////////////////////////////////////////////////////////////// static SkData* newFromParams(const void* src, size_t size, bool copyData) { if (copyData) { return SkData::NewWithCopy(src, size); } else { return SkData::NewWithProc(src, size, NULL, NULL); } } SkMemoryStream::SkMemoryStream() { fData = SkData::NewEmpty(); fOffset = 0; } SkMemoryStream::SkMemoryStream(size_t size) { fData = SkData::NewFromMalloc(sk_malloc_throw(size), size); fOffset = 0; } SkMemoryStream::SkMemoryStream(const void* src, size_t size, bool copyData) { fData = newFromParams(src, size, copyData); fOffset = 0; } SkMemoryStream::SkMemoryStream(SkData* data) { if (NULL == data) { fData = SkData::NewEmpty(); } else { fData = data; fData->ref(); } fOffset = 0; } SkMemoryStream::~SkMemoryStream() { fData->unref(); } void SkMemoryStream::setMemoryOwned(const void* src, size_t size) { fData->unref(); fData = SkData::NewFromMalloc(src, size); fOffset = 0; } void SkMemoryStream::setMemory(const void* src, size_t size, bool copyData) { fData->unref(); fData = newFromParams(src, size, copyData); fOffset = 0; } SkData* SkMemoryStream::copyToData() const { fData->ref(); return fData; } SkData* SkMemoryStream::setData(SkData* data) { fData->unref(); if (NULL == data) { fData = SkData::NewEmpty(); } else { fData = data; fData->ref(); } fOffset = 0; return data; } void SkMemoryStream::skipToAlign4() { // cast to remove unary-minus warning fOffset += -(int)fOffset & 0x03; } size_t SkMemoryStream::read(void* buffer, size_t size) { size_t dataSize = fData->size(); if (size > dataSize - fOffset) { size = dataSize - fOffset; } if (buffer) { memcpy(buffer, fData->bytes() + fOffset, size); } fOffset += size; return size; } bool SkMemoryStream::isAtEnd() const { return fOffset == fData->size(); } bool SkMemoryStream::rewind() { fOffset = 0; return true; } SkMemoryStream* SkMemoryStream::duplicate() const { return SkNEW_ARGS(SkMemoryStream, (fData)); } size_t SkMemoryStream::getPosition() const { return fOffset; } bool SkMemoryStream::seek(size_t position) { fOffset = position > fData->size() ? fData->size() : position; return true; } bool SkMemoryStream::move(long offset) { return this->seek(fOffset + offset); } SkMemoryStream* SkMemoryStream::fork() const { SkAutoTUnref that(this->duplicate()); that->seek(fOffset); return that.detach(); } size_t SkMemoryStream::getLength() const { return fData->size(); } const void* SkMemoryStream::getMemoryBase() { return fData->data(); } const void* SkMemoryStream::getAtPos() { return fData->bytes() + fOffset; } ///////////////////////////////////////////////////////////////////////////////////////////////////////// ///////////////////////////////////////////////////////////////////////////////////////////////////////// SkFILEWStream::SkFILEWStream(const char path[]) { fFILE = sk_fopen(path, kWrite_SkFILE_Flag); } SkFILEWStream::~SkFILEWStream() { if (fFILE) { sk_fclose(fFILE); } } size_t SkFILEWStream::bytesWritten() const { return sk_ftell(fFILE); } bool SkFILEWStream::write(const void* buffer, size_t size) { if (fFILE == NULL) { return false; } if (sk_fwrite(buffer, size, fFILE) != size) { SkDEBUGCODE(SkDebugf("SkFILEWStream failed writing %d bytes\n", size);) sk_fclose(fFILE); fFILE = NULL; return false; } return true; } void SkFILEWStream::flush() { if (fFILE) { sk_fflush(fFILE); } } //////////////////////////////////////////////////////////////////////// SkMemoryWStream::SkMemoryWStream(void* buffer, size_t size) : fBuffer((char*)buffer), fMaxLength(size), fBytesWritten(0) { } bool SkMemoryWStream::write(const void* buffer, size_t size) { size = SkTMin(size, fMaxLength - fBytesWritten); if (size > 0) { memcpy(fBuffer + fBytesWritten, buffer, size); fBytesWritten += size; return true; } return false; } //////////////////////////////////////////////////////////////////////// #define SkDynamicMemoryWStream_MinBlockSize 256 struct SkDynamicMemoryWStream::Block { Block* fNext; char* fCurr; char* fStop; const char* start() const { return (const char*)(this + 1); } char* start() { return (char*)(this + 1); } size_t avail() const { return fStop - fCurr; } size_t written() const { return fCurr - this->start(); } void init(size_t size) { fNext = NULL; fCurr = this->start(); fStop = this->start() + size; } const void* append(const void* data, size_t size) { SkASSERT((size_t)(fStop - fCurr) >= size); memcpy(fCurr, data, size); fCurr += size; return (const void*)((const char*)data + size); } }; SkDynamicMemoryWStream::SkDynamicMemoryWStream() : fHead(NULL), fTail(NULL), fBytesWritten(0), fCopy(NULL) { } SkDynamicMemoryWStream::~SkDynamicMemoryWStream() { reset(); } void SkDynamicMemoryWStream::reset() { this->invalidateCopy(); Block* block = fHead; while (block != NULL) { Block* next = block->fNext; sk_free(block); block = next; } fHead = fTail = NULL; fBytesWritten = 0; } bool SkDynamicMemoryWStream::write(const void* buffer, size_t count) { if (count > 0) { this->invalidateCopy(); fBytesWritten += count; size_t size; if (fTail != NULL && fTail->avail() > 0) { size = SkTMin(fTail->avail(), count); buffer = fTail->append(buffer, size); SkASSERT(count >= size); count -= size; if (count == 0) return true; } size = SkTMax(count, SkDynamicMemoryWStream_MinBlockSize); Block* block = (Block*)sk_malloc_throw(sizeof(Block) + size); block->init(size); block->append(buffer, count); if (fTail != NULL) fTail->fNext = block; else fHead = fTail = block; fTail = block; } return true; } bool SkDynamicMemoryWStream::write(const void* buffer, size_t offset, size_t count) { if (offset + count > fBytesWritten) { return false; // test does not partially modify } this->invalidateCopy(); Block* block = fHead; while (block != NULL) { size_t size = block->written(); if (offset < size) { size_t part = offset + count > size ? size - offset : count; memcpy(block->start() + offset, buffer, part); if (count <= part) return true; count -= part; buffer = (const void*) ((char* ) buffer + part); } offset = offset > size ? offset - size : 0; block = block->fNext; } return false; } bool SkDynamicMemoryWStream::read(void* buffer, size_t offset, size_t count) { if (offset + count > fBytesWritten) return false; // test does not partially modify Block* block = fHead; while (block != NULL) { size_t size = block->written(); if (offset < size) { size_t part = offset + count > size ? size - offset : count; memcpy(buffer, block->start() + offset, part); if (count <= part) return true; count -= part; buffer = (void*) ((char* ) buffer + part); } offset = offset > size ? offset - size : 0; block = block->fNext; } return false; } void SkDynamicMemoryWStream::copyTo(void* dst) const { if (fCopy) { memcpy(dst, fCopy->data(), fBytesWritten); } else { Block* block = fHead; while (block != NULL) { size_t size = block->written(); memcpy(dst, block->start(), size); dst = (void*)((char*)dst + size); block = block->fNext; } } } void SkDynamicMemoryWStream::padToAlign4() { // cast to remove unary-minus warning int padBytes = -(int)fBytesWritten & 0x03; if (padBytes == 0) return; int zero = 0; write(&zero, padBytes); } SkData* SkDynamicMemoryWStream::copyToData() const { if (NULL == fCopy) { void* buffer = sk_malloc_throw(fBytesWritten); this->copyTo(buffer); fCopy = SkData::NewFromMalloc(buffer, fBytesWritten); } fCopy->ref(); return fCopy; } void SkDynamicMemoryWStream::invalidateCopy() { if (fCopy) { fCopy->unref(); fCopy = NULL; } } class SkBlockMemoryRefCnt : public SkRefCnt { public: explicit SkBlockMemoryRefCnt(SkDynamicMemoryWStream::Block* head) : fHead(head) { } virtual ~SkBlockMemoryRefCnt() { SkDynamicMemoryWStream::Block* block = fHead; while (block != NULL) { SkDynamicMemoryWStream::Block* next = block->fNext; sk_free(block); block = next; } } SkDynamicMemoryWStream::Block* const fHead; }; class SkBlockMemoryStream : public SkStreamAsset { public: SkBlockMemoryStream(SkDynamicMemoryWStream::Block* head, size_t size) : fBlockMemory(SkNEW_ARGS(SkBlockMemoryRefCnt, (head))), fCurrent(head) , fSize(size) , fOffset(0), fCurrentOffset(0) { } SkBlockMemoryStream(SkBlockMemoryRefCnt* headRef, size_t size) : fBlockMemory(SkRef(headRef)), fCurrent(fBlockMemory->fHead) , fSize(size) , fOffset(0), fCurrentOffset(0) { } virtual size_t read(void* buffer, size_t rawCount) SK_OVERRIDE { size_t count = rawCount; if (fOffset + count > fSize) { count = fSize - fOffset; } size_t bytesLeftToRead = count; while (fCurrent != NULL) { size_t bytesLeftInCurrent = fCurrent->written() - fCurrentOffset; size_t bytesFromCurrent = SkTMin(bytesLeftToRead, bytesLeftInCurrent); if (buffer) { memcpy(buffer, fCurrent->start() + fCurrentOffset, bytesFromCurrent); buffer = SkTAddOffset(buffer, bytesFromCurrent); } if (bytesLeftToRead <= bytesFromCurrent) { fCurrentOffset += bytesFromCurrent; fOffset += count; return count; } bytesLeftToRead -= bytesFromCurrent; fCurrent = fCurrent->fNext; fCurrentOffset = 0; } SkASSERT(false); return 0; } virtual bool isAtEnd() const SK_OVERRIDE { return fOffset == fSize; } virtual bool rewind() SK_OVERRIDE { fCurrent = fBlockMemory->fHead; fOffset = 0; fCurrentOffset = 0; return true; } virtual SkBlockMemoryStream* duplicate() const SK_OVERRIDE { return SkNEW_ARGS(SkBlockMemoryStream, (fBlockMemory.get(), fSize)); } virtual size_t getPosition() const SK_OVERRIDE { return fOffset; } virtual bool seek(size_t position) SK_OVERRIDE { // If possible, skip forward. if (position >= fOffset) { size_t skipAmount = position - fOffset; return this->skip(skipAmount) == skipAmount; } // If possible, move backward within the current block. size_t moveBackAmount = fOffset - position; if (moveBackAmount <= fCurrentOffset) { fCurrentOffset -= moveBackAmount; fOffset -= moveBackAmount; return true; } // Otherwise rewind and move forward. return this->rewind() && this->skip(position) == position; } virtual bool move(long offset) SK_OVERRIDE { return seek(fOffset + offset); } virtual SkBlockMemoryStream* fork() const SK_OVERRIDE { SkAutoTUnref that(this->duplicate()); that->fCurrent = this->fCurrent; that->fOffset = this->fOffset; that->fCurrentOffset = this->fCurrentOffset; return that.detach(); } virtual size_t getLength() const SK_OVERRIDE { return fSize; } virtual const void* getMemoryBase() SK_OVERRIDE { if (NULL == fBlockMemory->fHead->fNext) { return fBlockMemory->fHead->start(); } return NULL; } private: SkAutoTUnref const fBlockMemory; SkDynamicMemoryWStream::Block const * fCurrent; size_t const fSize; size_t fOffset; size_t fCurrentOffset; }; SkStreamAsset* SkDynamicMemoryWStream::detachAsStream() { if (fCopy) { SkMemoryStream* stream = SkNEW_ARGS(SkMemoryStream, (fCopy)); this->reset(); return stream; } SkBlockMemoryStream* stream = SkNEW_ARGS(SkBlockMemoryStream, (fHead, fBytesWritten)); fHead = 0; this->reset(); return stream; } /////////////////////////////////////////////////////////////////////////////// void SkDebugWStream::newline() { #if defined(SK_DEBUG) || defined(SK_DEVELOPER) SkDebugf("\n"); fBytesWritten++; #endif } bool SkDebugWStream::write(const void* buffer, size_t size) { #if defined(SK_DEBUG) || defined(SK_DEVELOPER) char* s = new char[size+1]; memcpy(s, buffer, size); s[size] = 0; SkDebugf("%s", s); delete[] s; fBytesWritten += size; #endif return true; } /////////////////////////////////////////////////////////////////////////////// /////////////////////////////////////////////////////////////////////////////// static SkData* mmap_filename(const char path[]) { SkFILE* file = sk_fopen(path, kRead_SkFILE_Flag); if (NULL == file) { return NULL; } SkData* data = SkData::NewFromFILE(file); sk_fclose(file); return data; } SkStreamAsset* SkStream::NewFromFile(const char path[]) { SkAutoTUnref data(mmap_filename(path)); if (data.get()) { return SkNEW_ARGS(SkMemoryStream, (data.get())); } // If we get here, then our attempt at using mmap failed, so try normal // file access. SkFILEStream* stream = SkNEW_ARGS(SkFILEStream, (path)); if (!stream->isValid()) { stream->unref(); stream = NULL; } return stream; } // Declared in SkStreamPriv.h: size_t SkCopyStreamToStorage(SkAutoMalloc* storage, SkStream* stream) { SkASSERT(storage != NULL); SkASSERT(stream != NULL); if (stream->hasLength()) { const size_t length = stream->getLength(); void* dst = storage->reset(length); if (stream->read(dst, length) != length) { return 0; } return length; } SkDynamicMemoryWStream tempStream; // Arbitrary buffer size. const size_t bufferSize = 256 * 1024; // 256KB char buffer[bufferSize]; SkDEBUGCODE(size_t debugLength = 0;) do { size_t bytesRead = stream->read(buffer, bufferSize); tempStream.write(buffer, bytesRead); SkDEBUGCODE(debugLength += bytesRead); SkASSERT(tempStream.bytesWritten() == debugLength); } while (!stream->isAtEnd()); const size_t length = tempStream.bytesWritten(); void* dst = storage->reset(length); tempStream.copyTo(dst); return length; } // Declared in SkStreamPriv.h: SkData* SkCopyStreamToData(SkStream* stream) { SkASSERT(stream != NULL); if (stream->hasLength()) { const size_t length = stream->getLength(); SkAutoMalloc dst(length); if (stream->read(dst.get(), length) != length) { return NULL; } return SkData::NewFromMalloc(dst.detach(), length); } SkDynamicMemoryWStream tempStream; const size_t bufferSize = 4096; char buffer[bufferSize]; do { size_t bytesRead = stream->read(buffer, bufferSize); tempStream.write(buffer, bytesRead); } while (!stream->isAtEnd()); return tempStream.copyToData(); } SkStreamRewindable* SkStreamRewindableFromSkStream(SkStream* stream) { if (!stream) { return NULL; } SkAutoTUnref dupStream(stream->duplicate()); if (dupStream) { return dupStream.detach(); } stream->rewind(); if (stream->hasLength()) { size_t length = stream->getLength(); if (stream->hasPosition()) { // If stream has length, but can't rewind. length -= stream->getPosition(); } SkAutoMalloc allocMemory(length); SkDEBUGCODE(size_t read =) stream->read(allocMemory.get(), length); SkASSERT(length == read); SkAutoTUnref data( SkData::NewFromMalloc(allocMemory.detach(), length)); return SkNEW_ARGS(SkMemoryStream, (data.get())); } SkDynamicMemoryWStream tempStream; const size_t bufferSize = 4096; char buffer[bufferSize]; do { size_t bytesRead = stream->read(buffer, bufferSize); tempStream.write(buffer, bytesRead); } while (!stream->isAtEnd()); return tempStream.detachAsStream(); // returns a SkBlockMemoryStream, // cheaper than copying to SkData }