src/core/SkFlattenable.cpp - platform/external/skia - Git at Google


 /*
  * Copyright 2011 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */
 #include "SkFlattenable.h"
 #include "SkTypeface.h"

 #include "SkMatrix.h"
 #include "SkRegion.h"

 void SkReadMatrix(SkReader32* reader, SkMatrix* matrix) {
     size_t size = matrix->unflatten(reader->peek());
     SkASSERT(SkAlign4(size) == size);
     (void)reader->skip(size);
 }

 void SkWriteMatrix(SkWriter32* writer, const SkMatrix& matrix) {
     size_t size = matrix.flatten(NULL);
     SkASSERT(SkAlign4(size) == size);
     matrix.flatten(writer->reserve(size));
 }

 void SkReadRegion(SkReader32* reader, SkRegion* rgn) {
     size_t size = rgn->unflatten(reader->peek());
     SkASSERT(SkAlign4(size) == size);
     (void)reader->skip(size);
 }

 void SkWriteRegion(SkWriter32* writer, const SkRegion& rgn) {
     size_t size = rgn.flatten(NULL);
     SkASSERT(SkAlign4(size) == size);
     rgn.flatten(writer->reserve(size));
 }

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

 void SkFlattenable::flatten(SkFlattenableWriteBuffer&)
 {
     /*  we don't write anything at the moment, but this allows our subclasses
         to not know that, since we want them to always call INHERITED::flatten()
         in their code.
     */
 }

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

 SkFlattenableReadBuffer::SkFlattenableReadBuffer() {
     fRCArray = NULL;
     fRCCount = 0;

     fTFArray = NULL;
     fTFCount = 0;

     fFactoryTDArray = NULL;
     fFactoryArray = NULL;
     fFactoryCount = 0;
     fPictureVersion = PICTURE_VERSION_JB;
 }

 SkFlattenableReadBuffer::SkFlattenableReadBuffer(const void* data) :
         INHERITED(data, 1024 * 1024) {
     fRCArray = NULL;
     fRCCount = 0;

     fTFArray = NULL;
     fTFCount = 0;

     fFactoryTDArray = NULL;
     fFactoryArray = NULL;
     fFactoryCount = 0;
     fPictureVersion = PICTURE_VERSION_JB;
 }

 SkFlattenableReadBuffer::SkFlattenableReadBuffer(const void* data, size_t size)
         : INHERITED(data, size) {
     fRCArray = NULL;
     fRCCount = 0;

     fTFArray = NULL;
     fTFCount = 0;

     fFactoryTDArray = NULL;
     fFactoryArray = NULL;
     fFactoryCount = 0;
     fPictureVersion = PICTURE_VERSION_JB;
 }

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

 SkRefCnt* SkFlattenableReadBuffer::readRefCnt() {
     uint32_t index = this->readU32();
     if (0 == index || index > (unsigned)fRCCount) {
         return NULL;
     } else {
         SkASSERT(fRCArray);
         return fRCArray[index - 1];
     }
 }

 SkFlattenable* SkFlattenableReadBuffer::readFlattenable() {

     if(fPictureVersion == PICTURE_VERSION_ICS) {
         SkFlattenable::Factory factory = NULL;

         if (fFactoryCount > 0) {
             uint32_t index = this->readU32();
             if (index > 0) {
                 index -= 1;
                 SkASSERT(index < (unsigned)fFactoryCount);
                 factory = fFactoryArray[index];
                 // if we recorded an index, but failed to get a factory, we need
                 // to skip the flattened data in the buffer
                 if (NULL == factory) {
                     uint32_t size = this->readU32();
                     this->skip(size);
                     // fall through and return NULL for the object
                 }
             }
         } else {
             factory = (SkFlattenable::Factory)readFunctionPtr();
         }

         SkFlattenable* obj = NULL;
         if (factory) {
             uint32_t sizeRecorded = this->readU32();
             uint32_t offset = this->offset();
             obj = (*factory)(*this);
             // check that we read the amount we expected
             uint32_t sizeRead = this->offset() - offset;
             if (sizeRecorded != sizeRead) {
                 // we could try to fix up the offset...
                 sk_throw();
             }
         }
         return obj;
     }

     SkFlattenable::Factory factory = NULL;

     if (fFactoryCount > 0) {
         int32_t index = this->readU32();
         if (0 == index) {
             return NULL; // writer failed to give us the flattenable
         }
         index = -index; // we stored the negative of the index
         index -= 1;     // we stored the index-base-1
         SkASSERT(index < fFactoryCount);
         factory = fFactoryArray[index];
     } else if (fFactoryTDArray) {
         const int32_t* peek = (const int32_t*)this->peek();
         if (*peek <= 0) {
             int32_t index = this->readU32();
             if (0 == index) {
                 return NULL; // writer failed to give us the flattenable
             }
             index = -index; // we stored the negative of the index
             index -= 1;     // we stored the index-base-1
             factory = (*fFactoryTDArray)[index];
         } else {
             const char* name = this->readString();
             factory = SkFlattenable::NameToFactory(name);
             if (factory) {
                 SkASSERT(fFactoryTDArray->find(factory) < 0);
                 *fFactoryTDArray->append() = factory;
             } else {
 //                SkDebugf("can't find factory for [%s]\n", name);
             }
             // if we didn't find a factory, that's our failure, not the writer's,
             // so we fall through, so we can skip the sizeRecorded data.
         }
     } 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 = this->readU32();
     if (factory) {
         uint32_t offset = this->offset();
         obj = (*factory)(*this);
         // check that we read the amount we expected
         uint32_t sizeRead = this->offset() - offset;
         if (sizeRecorded != sizeRead) {
             // we could try to fix up the offset...
             sk_throw();
         }
     } else {
         // we must skip the remaining data
         this->skip(sizeRecorded);
     }
     return obj;
 }

 void* SkFlattenableReadBuffer::readFunctionPtr() {
     void* proc;
     this->read(&proc, sizeof(proc));
     return proc;
 }

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

 SkFlattenableWriteBuffer::SkFlattenableWriteBuffer(size_t minSize) :
         INHERITED(minSize) {
     fFlags = (Flags)0;
     fRCSet = NULL;
     fTFSet = NULL;
     fFactorySet = NULL;
 }

 SkFlattenableWriteBuffer::~SkFlattenableWriteBuffer() {
     SkSafeUnref(fRCSet);
     SkSafeUnref(fTFSet);
     SkSafeUnref(fFactorySet);
 }

 SkRefCntSet* SkFlattenableWriteBuffer::setRefCntRecorder(SkRefCntSet* rec) {
     SkRefCnt_SafeAssign(fRCSet, rec);
     return rec;
 }

 SkRefCntSet* SkFlattenableWriteBuffer::setTypefaceRecorder(SkRefCntSet* rec) {
     SkRefCnt_SafeAssign(fTFSet, rec);
     return rec;
 }

 SkFactorySet* SkFlattenableWriteBuffer::setFactoryRecorder(SkFactorySet* rec) {
     SkRefCnt_SafeAssign(fFactorySet, rec);
     return rec;
 }

 void SkFlattenableWriteBuffer::writeTypeface(SkTypeface* obj) {
     if (NULL == obj || NULL == fTFSet) {
         this->write32(0);
     } else {
         this->write32(fTFSet->add(obj));
     }
 }

 void SkFlattenableWriteBuffer::writeRefCnt(SkRefCnt* obj) {
     if (NULL == obj || NULL == fRCSet) {
         this->write32(0);
     } else {
         this->write32(fRCSet->add(obj));
     }
 }

 void SkFlattenableWriteBuffer::writeFlattenable(SkFlattenable* flattenable) {
     /*
      *  If we have a factoryset, then the first 32bits tell us...
      *       0: failure to write the flattenable
      *      <0: we store the negative of the (1-based) index
      *      >0: the length of the name
      *  If we don't have a factoryset, then the first "ptr" is either the
      *  factory, or null for failure.
      *
      *  The distinction is important, since 0-index is 32bits (always), but a
      *  0-functionptr might be 32 or 64 bits.
      */

     SkFlattenable::Factory factory = NULL;
     if (flattenable) {
         factory = flattenable->getFactory();
     }
     if (NULL == factory) {
         if (fFactorySet) {
             this->write32(0);
         } else {
             this->writeFunctionPtr(NULL);
         }
         return;
     }

     /*
      *  We can write 1 of 3 versions of the flattenable:
      *  1.  function-ptr : this is the fastest for the reader, but assumes that
      *      the writer and reader are in the same process.
      *  2.  index into fFactorySet : This is 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.
      *  3.  names : Reuse fFactorySet to store indices, but only after we've
      *      written the name the first time. SkGPipe uses this technique, as it
      *      doesn't require the reader to be told to know the table of names
      *      up front.
      */
     if (fFactorySet) {
         if (this->inlineFactoryNames()) {
             int index = fFactorySet->find(factory);
             if (index) {
                 // we write the negative of the index, to distinguish it from
                 // the length of a string
                 this->write32(-index);
             } else {
                 const char* name = SkFlattenable::FactoryToName(factory);
                 if (NULL == name) {
                     this->write32(0);
                     return;
                 }
                 this->writeString(name);
                 index = fFactorySet->add(factory);
             }
         } else {
             // we write the negative of the index, to distinguish it from
             // the length of a string
             this->write32(-(int)fFactorySet->add(factory));
         }
     } else {
         this->writeFunctionPtr((void*)factory);
     }

     // make room for the size of the flatttened object
     (void)this->reserve(sizeof(uint32_t));
     // record the current size, so we can subtract after the object writes.
     uint32_t offset = this->size();
     // now flatten the object
     flattenable->flatten(*this);
     uint32_t objSize = this->size() - offset;
     // record the obj's size
     *this->peek32(offset - sizeof(uint32_t)) = objSize;
 }

 void SkFlattenableWriteBuffer::writeFunctionPtr(void* proc) {
     *(void**)this->reserve(sizeof(void*)) = proc;
 }

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

 SkRefCntSet::~SkRefCntSet() {
     // call this now, while our decPtr() is sill in scope
     this->reset();
 }

 void SkRefCntSet::incPtr(void* ptr) {
     ((SkRefCnt*)ptr)->ref();
 }

 void SkRefCntSet::decPtr(void* ptr) {
     ((SkRefCnt*)ptr)->unref();
 }

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

 #define MAX_PAIR_COUNT  64

 struct Pair {
     const char*             fName;
     SkFlattenable::Factory  fFactory;
 };

 static int gCount;
 static Pair gPairs[MAX_PAIR_COUNT];

 void SkFlattenable::Register(const char name[], Factory factory) {
     SkASSERT(name);
     SkASSERT(factory);

     static bool gOnce;
     if (!gOnce) {
         gCount = 0;
         gOnce = true;
     }

     SkASSERT(gCount < MAX_PAIR_COUNT);

     gPairs[gCount].fName = name;
     gPairs[gCount].fFactory = factory;
     gCount += 1;
 }

 #if !SK_ALLOW_STATIC_GLOBAL_INITIALIZERS && defined(SK_DEBUG)
 static void report_no_entries(const char* functionName) {
     if (!gCount) {
         SkDebugf("%s has no registered name/factory pairs."
                  " Call SkGraphics::Init() at process initialization time.",
                  functionName);
     }
 }
 #endif

 SkFlattenable::Factory SkFlattenable::NameToFactory(const char name[]) {
 #if !SK_ALLOW_STATIC_GLOBAL_INITIALIZERS && defined(SK_DEBUG)
     report_no_entries(__FUNCTION__);
 #endif
     const Pair* pairs = gPairs;
     for (int i = gCount - 1; i >= 0; --i) {
         if (strcmp(pairs[i].fName, name) == 0) {
             return pairs[i].fFactory;
         }
     }
     return NULL;
 }

 const char* SkFlattenable::FactoryToName(Factory fact) {
 #if !SK_ALLOW_STATIC_GLOBAL_INITIALIZERS && defined(SK_DEBUG)
     report_no_entries(__FUNCTION__);
 #endif
     const Pair* pairs = gPairs;
     for (int i = gCount - 1; i >= 0; --i) {
         if (pairs[i].fFactory == fact) {
             return pairs[i].fName;
         }
     }
     return NULL;
 }

 bool SkFlattenable::toDumpString(SkString* str) const {
     return false;
 }

	/*
	* Copyright 2011 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/
	#include "SkFlattenable.h"
	#include "SkTypeface.h"

	#include "SkMatrix.h"
	#include "SkRegion.h"

	void SkReadMatrix(SkReader32* reader, SkMatrix* matrix) {
	size_t size = matrix->unflatten(reader->peek());
	SkASSERT(SkAlign4(size) == size);
	(void)reader->skip(size);
	}

	void SkWriteMatrix(SkWriter32* writer, const SkMatrix& matrix) {
	size_t size = matrix.flatten(NULL);
	SkASSERT(SkAlign4(size) == size);
	matrix.flatten(writer->reserve(size));
	}

	void SkReadRegion(SkReader32* reader, SkRegion* rgn) {
	size_t size = rgn->unflatten(reader->peek());
	SkASSERT(SkAlign4(size) == size);
	(void)reader->skip(size);
	}

	void SkWriteRegion(SkWriter32* writer, const SkRegion& rgn) {
	size_t size = rgn.flatten(NULL);
	SkASSERT(SkAlign4(size) == size);
	rgn.flatten(writer->reserve(size));
	}

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

	void SkFlattenable::flatten(SkFlattenableWriteBuffer&)
	{
	/* we don't write anything at the moment, but this allows our subclasses
	to not know that, since we want them to always call INHERITED::flatten()
	in their code.
	*/
	}

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

	SkFlattenableReadBuffer::SkFlattenableReadBuffer() {
	fRCArray = NULL;
	fRCCount = 0;

	fTFArray = NULL;
	fTFCount = 0;

	fFactoryTDArray = NULL;
	fFactoryArray = NULL;
	fFactoryCount = 0;
	fPictureVersion = PICTURE_VERSION_JB;
	}

	SkFlattenableReadBuffer::SkFlattenableReadBuffer(const void* data) :
	INHERITED(data, 1024 * 1024) {
	fRCArray = NULL;
	fRCCount = 0;

	fTFArray = NULL;
	fTFCount = 0;

	fFactoryTDArray = NULL;
	fFactoryArray = NULL;
	fFactoryCount = 0;
	fPictureVersion = PICTURE_VERSION_JB;
	}

	SkFlattenableReadBuffer::SkFlattenableReadBuffer(const void* data, size_t size)
	: INHERITED(data, size) {
	fRCArray = NULL;
	fRCCount = 0;

	fTFArray = NULL;
	fTFCount = 0;

	fFactoryTDArray = NULL;
	fFactoryArray = NULL;
	fFactoryCount = 0;
	fPictureVersion = PICTURE_VERSION_JB;
	}

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

	SkRefCnt* SkFlattenableReadBuffer::readRefCnt() {
	uint32_t index = this->readU32();
	if (0 == index \|\| index > (unsigned)fRCCount) {
	return NULL;
	} else {
	SkASSERT(fRCArray);
	return fRCArray[index - 1];
	}
	}

	SkFlattenable* SkFlattenableReadBuffer::readFlattenable() {

	if(fPictureVersion == PICTURE_VERSION_ICS) {
	SkFlattenable::Factory factory = NULL;

	if (fFactoryCount > 0) {
	uint32_t index = this->readU32();
	if (index > 0) {
	index -= 1;
	SkASSERT(index < (unsigned)fFactoryCount);
	factory = fFactoryArray[index];
	// if we recorded an index, but failed to get a factory, we need
	// to skip the flattened data in the buffer
	if (NULL == factory) {
	uint32_t size = this->readU32();
	this->skip(size);
	// fall through and return NULL for the object
	}
	}
	} else {
	factory = (SkFlattenable::Factory)readFunctionPtr();
	}

	SkFlattenable* obj = NULL;
	if (factory) {
	uint32_t sizeRecorded = this->readU32();
	uint32_t offset = this->offset();
	obj = (factory)(this);
	// check that we read the amount we expected
	uint32_t sizeRead = this->offset() - offset;
	if (sizeRecorded != sizeRead) {
	// we could try to fix up the offset...
	sk_throw();
	}
	}
	return obj;
	}

	SkFlattenable::Factory factory = NULL;

	if (fFactoryCount > 0) {
	int32_t index = this->readU32();
	if (0 == index) {
	return NULL; // writer failed to give us the flattenable
	}
	index = -index; // we stored the negative of the index
	index -= 1; // we stored the index-base-1
	SkASSERT(index < fFactoryCount);
	factory = fFactoryArray[index];
	} else if (fFactoryTDArray) {
	const int32_t* peek = (const int32_t*)this->peek();
	if (*peek <= 0) {
	int32_t index = this->readU32();
	if (0 == index) {
	return NULL; // writer failed to give us the flattenable
	}
	index = -index; // we stored the negative of the index
	index -= 1; // we stored the index-base-1
	factory = (*fFactoryTDArray)[index];
	} else {
	const char* name = this->readString();
	factory = SkFlattenable::NameToFactory(name);
	if (factory) {
	SkASSERT(fFactoryTDArray->find(factory) < 0);
	*fFactoryTDArray->append() = factory;
	} else {
	// SkDebugf("can't find factory for [%s]\n", name);
	}
	// if we didn't find a factory, that's our failure, not the writer's,
	// so we fall through, so we can skip the sizeRecorded data.
	}
	} 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 = this->readU32();
	if (factory) {
	uint32_t offset = this->offset();
	obj = (factory)(this);
	// check that we read the amount we expected
	uint32_t sizeRead = this->offset() - offset;
	if (sizeRecorded != sizeRead) {
	// we could try to fix up the offset...
	sk_throw();
	}
	} else {
	// we must skip the remaining data
	this->skip(sizeRecorded);
	}
	return obj;
	}

	void* SkFlattenableReadBuffer::readFunctionPtr() {
	void* proc;
	this->read(&proc, sizeof(proc));
	return proc;
	}

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

	SkFlattenableWriteBuffer::SkFlattenableWriteBuffer(size_t minSize) :
	INHERITED(minSize) {
	fFlags = (Flags)0;
	fRCSet = NULL;
	fTFSet = NULL;
	fFactorySet = NULL;
	}

	SkFlattenableWriteBuffer::~SkFlattenableWriteBuffer() {
	SkSafeUnref(fRCSet);
	SkSafeUnref(fTFSet);
	SkSafeUnref(fFactorySet);
	}

	SkRefCntSet* SkFlattenableWriteBuffer::setRefCntRecorder(SkRefCntSet* rec) {
	SkRefCnt_SafeAssign(fRCSet, rec);
	return rec;
	}

	SkRefCntSet* SkFlattenableWriteBuffer::setTypefaceRecorder(SkRefCntSet* rec) {
	SkRefCnt_SafeAssign(fTFSet, rec);
	return rec;
	}

	SkFactorySet* SkFlattenableWriteBuffer::setFactoryRecorder(SkFactorySet* rec) {
	SkRefCnt_SafeAssign(fFactorySet, rec);
	return rec;
	}

	void SkFlattenableWriteBuffer::writeTypeface(SkTypeface* obj) {
	if (NULL == obj \|\| NULL == fTFSet) {
	this->write32(0);
	} else {
	this->write32(fTFSet->add(obj));
	}
	}

	void SkFlattenableWriteBuffer::writeRefCnt(SkRefCnt* obj) {
	if (NULL == obj \|\| NULL == fRCSet) {
	this->write32(0);
	} else {
	this->write32(fRCSet->add(obj));
	}
	}

	void SkFlattenableWriteBuffer::writeFlattenable(SkFlattenable* flattenable) {
	/*
	* If we have a factoryset, then the first 32bits tell us...
	* 0: failure to write the flattenable
	* <0: we store the negative of the (1-based) index
	* >0: the length of the name
	* If we don't have a factoryset, then the first "ptr" is either the
	* factory, or null for failure.
	*
	* The distinction is important, since 0-index is 32bits (always), but a
	* 0-functionptr might be 32 or 64 bits.
	*/

	SkFlattenable::Factory factory = NULL;
	if (flattenable) {
	factory = flattenable->getFactory();
	}
	if (NULL == factory) {
	if (fFactorySet) {
	this->write32(0);
	} else {
	this->writeFunctionPtr(NULL);
	}
	return;
	}

	/*
	* We can write 1 of 3 versions of the flattenable:
	* 1. function-ptr : this is the fastest for the reader, but assumes that
	* the writer and reader are in the same process.
	* 2. index into fFactorySet : This is 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.
	* 3. names : Reuse fFactorySet to store indices, but only after we've
	* written the name the first time. SkGPipe uses this technique, as it
	* doesn't require the reader to be told to know the table of names
	* up front.
	*/
	if (fFactorySet) {
	if (this->inlineFactoryNames()) {
	int index = fFactorySet->find(factory);
	if (index) {
	// we write the negative of the index, to distinguish it from
	// the length of a string
	this->write32(-index);
	} else {
	const char* name = SkFlattenable::FactoryToName(factory);
	if (NULL == name) {
	this->write32(0);
	return;
	}
	this->writeString(name);
	index = fFactorySet->add(factory);
	}
	} else {
	// we write the negative of the index, to distinguish it from
	// the length of a string
	this->write32(-(int)fFactorySet->add(factory));
	}
	} else {
	this->writeFunctionPtr((void*)factory);
	}

	// make room for the size of the flatttened object
	(void)this->reserve(sizeof(uint32_t));
	// record the current size, so we can subtract after the object writes.
	uint32_t offset = this->size();
	// now flatten the object
	flattenable->flatten(*this);
	uint32_t objSize = this->size() - offset;
	// record the obj's size
	*this->peek32(offset - sizeof(uint32_t)) = objSize;
	}

	void SkFlattenableWriteBuffer::writeFunctionPtr(void* proc) {
	(void)this->reserve(sizeof(void)) = proc;
	}

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

	SkRefCntSet::~SkRefCntSet() {
	// call this now, while our decPtr() is sill in scope
	this->reset();
	}

	void SkRefCntSet::incPtr(void* ptr) {
	((SkRefCnt*)ptr)->ref();
	}

	void SkRefCntSet::decPtr(void* ptr) {
	((SkRefCnt*)ptr)->unref();
	}

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

	#define MAX_PAIR_COUNT 64

	struct Pair {
	const char* fName;
	SkFlattenable::Factory fFactory;
	};

	static int gCount;
	static Pair gPairs[MAX_PAIR_COUNT];

	void SkFlattenable::Register(const char name[], Factory factory) {
	SkASSERT(name);
	SkASSERT(factory);

	static bool gOnce;
	if (!gOnce) {
	gCount = 0;
	gOnce = true;
	}

	SkASSERT(gCount < MAX_PAIR_COUNT);

	gPairs[gCount].fName = name;
	gPairs[gCount].fFactory = factory;
	gCount += 1;
	}

	#if !SK_ALLOW_STATIC_GLOBAL_INITIALIZERS && defined(SK_DEBUG)
	static void report_no_entries(const char* functionName) {
	if (!gCount) {
	SkDebugf("%s has no registered name/factory pairs."
	" Call SkGraphics::Init() at process initialization time.",
	functionName);
	}
	}
	#endif

	SkFlattenable::Factory SkFlattenable::NameToFactory(const char name[]) {
	#if !SK_ALLOW_STATIC_GLOBAL_INITIALIZERS && defined(SK_DEBUG)
	report_no_entries(__FUNCTION__);
	#endif
	const Pair* pairs = gPairs;
	for (int i = gCount - 1; i >= 0; --i) {
	if (strcmp(pairs[i].fName, name) == 0) {
	return pairs[i].fFactory;
	}
	}
	return NULL;
	}

	const char* SkFlattenable::FactoryToName(Factory fact) {
	#if !SK_ALLOW_STATIC_GLOBAL_INITIALIZERS && defined(SK_DEBUG)
	report_no_entries(__FUNCTION__);
	#endif
	const Pair* pairs = gPairs;
	for (int i = gCount - 1; i >= 0; --i) {
	if (pairs[i].fFactory == fact) {
	return pairs[i].fName;
	}
	}
	return NULL;
	}

	bool SkFlattenable::toDumpString(SkString* str) const {
	return false;
	}