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


 /*
  * 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 "SkGlyphCache.h"
 #include "SkGraphics.h"
 #include "SkPaint.h"
 #include "SkTemplates.h"

 //#define SPEW_PURGE_STATUS
 //#define USE_CACHE_HASH
 //#define RECORD_HASH_EFFICIENCY

 bool gSkSuppressFontCachePurgeSpew;

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

 #ifdef RECORD_HASH_EFFICIENCY
     static uint32_t gHashSuccess;
     static uint32_t gHashCollision;

     static void RecordHashSuccess() {
         gHashSuccess += 1;
     }

     static void RecordHashCollisionIf(bool pred) {
         if (pred) {
             gHashCollision += 1;

             uint32_t total = gHashSuccess + gHashCollision;
             SkDebugf("Font Cache Hash success rate: %d%%\n",
                      100 * gHashSuccess / total);
         }
     }
 #else
     #define RecordHashSuccess() (void)0
     #define RecordHashCollisionIf(pred) (void)0
 #endif
 #define RecordHashCollision() RecordHashCollisionIf(true)

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

 #define kMinGlphAlloc       (sizeof(SkGlyph) * 64)
 #define kMinImageAlloc      (24 * 64)   // should be pointsize-dependent

 #define METRICS_RESERVE_COUNT  128  // so we don't grow this array a lot

 SkGlyphCache::SkGlyphCache(const SkDescriptor* desc)
         : fGlyphAlloc(kMinGlphAlloc), fImageAlloc(kMinImageAlloc) {
     fPrev = fNext = NULL;

     fDesc = desc->copy();
     fScalerContext = SkScalerContext::Create(desc);
     fScalerContext->getFontMetrics(NULL, &fFontMetricsY);

     // init to 0 so that all of the pointers will be null
     memset(fGlyphHash, 0, sizeof(fGlyphHash));
     // init with 0xFF so that the charCode field will be -1, which is invalid
     memset(fCharToGlyphHash, 0xFF, sizeof(fCharToGlyphHash));

     fMemoryUsed = sizeof(*this) + kMinGlphAlloc + kMinImageAlloc;

     fGlyphArray.setReserve(METRICS_RESERVE_COUNT);

     fMetricsCount = 0;
     fAdvanceCount = 0;
     fAuxProcList = NULL;
 }

 SkGlyphCache::~SkGlyphCache() {
     SkGlyph**   gptr = fGlyphArray.begin();
     SkGlyph**   stop = fGlyphArray.end();
     while (gptr < stop) {
         SkPath* path = (*gptr)->fPath;
         if (path) {
             SkDELETE(path);
         }
         gptr += 1;
     }
     SkDescriptor::Free(fDesc);
     SkDELETE(fScalerContext);
     this->invokeAndRemoveAuxProcs();
 }

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

 #ifdef SK_DEBUG
 #define VALIDATE()  AutoValidate av(this)
 #else
 #define VALIDATE()
 #endif

 uint16_t SkGlyphCache::unicharToGlyph(SkUnichar charCode) {
     VALIDATE();
     uint32_t id = SkGlyph::MakeID(charCode);
     const CharGlyphRec& rec = fCharToGlyphHash[ID2HashIndex(id)];

     if (rec.fID == id) {
         return rec.fGlyph->getGlyphID();
     } else {
         return fScalerContext->charToGlyphID(charCode);
     }
 }

 SkUnichar SkGlyphCache::glyphToUnichar(uint16_t glyphID) {
     return fScalerContext->glyphIDToChar(glyphID);
 }

 unsigned SkGlyphCache::getGlyphCount() {
     return fScalerContext->getGlyphCount();
 }

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

 const SkGlyph& SkGlyphCache::getUnicharAdvance(SkUnichar charCode) {
     VALIDATE();
     uint32_t id = SkGlyph::MakeID(charCode);
     CharGlyphRec* rec = &fCharToGlyphHash[ID2HashIndex(id)];

     if (rec->fID != id) {
         // this ID is based on the UniChar
         rec->fID = id;
         // this ID is based on the glyph index
         id = SkGlyph::MakeID(fScalerContext->charToGlyphID(charCode));
         rec->fGlyph = this->lookupMetrics(id, kJustAdvance_MetricsType);
     }
     return *rec->fGlyph;
 }

 const SkGlyph& SkGlyphCache::getGlyphIDAdvance(uint16_t glyphID) {
     VALIDATE();
     uint32_t id = SkGlyph::MakeID(glyphID);
     unsigned index = ID2HashIndex(id);
     SkGlyph* glyph = fGlyphHash[index];

     if (NULL == glyph || glyph->fID != id) {
         glyph = this->lookupMetrics(glyphID, kJustAdvance_MetricsType);
         fGlyphHash[index] = glyph;
     }
     return *glyph;
 }

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

 const SkGlyph& SkGlyphCache::getUnicharMetrics(SkUnichar charCode) {
     VALIDATE();
     uint32_t id = SkGlyph::MakeID(charCode);
     CharGlyphRec* rec = &fCharToGlyphHash[ID2HashIndex(id)];

     if (rec->fID != id) {
         RecordHashCollisionIf(rec->fGlyph != NULL);
         // this ID is based on the UniChar
         rec->fID = id;
         // this ID is based on the glyph index
         id = SkGlyph::MakeID(fScalerContext->charToGlyphID(charCode));
         rec->fGlyph = this->lookupMetrics(id, kFull_MetricsType);
     } else {
         RecordHashSuccess();
         if (rec->fGlyph->isJustAdvance()) {
             fScalerContext->getMetrics(rec->fGlyph);
         }
     }
     SkASSERT(rec->fGlyph->isFullMetrics());
     return *rec->fGlyph;
 }

 const SkGlyph& SkGlyphCache::getUnicharMetrics(SkUnichar charCode,
                                                SkFixed x, SkFixed y) {
     VALIDATE();
     uint32_t id = SkGlyph::MakeID(charCode, x, y);
     CharGlyphRec* rec = &fCharToGlyphHash[ID2HashIndex(id)];

     if (rec->fID != id) {
         RecordHashCollisionIf(rec->fGlyph != NULL);
         // this ID is based on the UniChar
         rec->fID = id;
         // this ID is based on the glyph index
         id = SkGlyph::MakeID(fScalerContext->charToGlyphID(charCode), x, y);
         rec->fGlyph = this->lookupMetrics(id, kFull_MetricsType);
     } else {
         RecordHashSuccess();
         if (rec->fGlyph->isJustAdvance()) {
             fScalerContext->getMetrics(rec->fGlyph);
         }
     }
     SkASSERT(rec->fGlyph->isFullMetrics());
     return *rec->fGlyph;
 }

 const SkGlyph& SkGlyphCache::getGlyphIDMetrics(uint16_t glyphID) {
     VALIDATE();
     uint32_t id = SkGlyph::MakeID(glyphID);
     unsigned index = ID2HashIndex(id);
     SkGlyph* glyph = fGlyphHash[index];

     if (NULL == glyph || glyph->fID != id) {
         RecordHashCollisionIf(glyph != NULL);
         glyph = this->lookupMetrics(glyphID, kFull_MetricsType);
         fGlyphHash[index] = glyph;
     } else {
         RecordHashSuccess();
         if (glyph->isJustAdvance()) {
             fScalerContext->getMetrics(glyph);
         }
     }
     SkASSERT(glyph->isFullMetrics());
     return *glyph;
 }

 const SkGlyph& SkGlyphCache::getGlyphIDMetrics(uint16_t glyphID,
                                                SkFixed x, SkFixed y) {
     VALIDATE();
     uint32_t id = SkGlyph::MakeID(glyphID, x, y);
     unsigned index = ID2HashIndex(id);
     SkGlyph* glyph = fGlyphHash[index];

     if (NULL == glyph || glyph->fID != id) {
         RecordHashCollisionIf(glyph != NULL);
         glyph = this->lookupMetrics(id, kFull_MetricsType);
         fGlyphHash[index] = glyph;
     } else {
         RecordHashSuccess();
         if (glyph->isJustAdvance()) {
             fScalerContext->getMetrics(glyph);
         }
     }
     SkASSERT(glyph->isFullMetrics());
     return *glyph;
 }

 SkGlyph* SkGlyphCache::lookupMetrics(uint32_t id, MetricsType mtype) {
     SkGlyph* glyph;

     int     hi = 0;
     int     count = fGlyphArray.count();

     if (count) {
         SkGlyph**   gptr = fGlyphArray.begin();
         int     lo = 0;

         hi = count - 1;
         while (lo < hi) {
             int mid = (hi + lo) >> 1;
             if (gptr[mid]->fID < id) {
                 lo = mid + 1;
             } else {
                 hi = mid;
             }
         }
         glyph = gptr[hi];
         if (glyph->fID == id) {
             if (kFull_MetricsType == mtype && glyph->isJustAdvance()) {
                 fScalerContext->getMetrics(glyph);
             }
             return glyph;
         }

         // check if we need to bump hi before falling though to the allocator
         if (glyph->fID < id) {
             hi += 1;
         }
     }

     // not found, but hi tells us where to inser the new glyph
     fMemoryUsed += sizeof(SkGlyph);

     glyph = (SkGlyph*)fGlyphAlloc.alloc(sizeof(SkGlyph),
                                         SkChunkAlloc::kThrow_AllocFailType);
     glyph->init(id);
     *fGlyphArray.insert(hi) = glyph;

     if (kJustAdvance_MetricsType == mtype) {
         fScalerContext->getAdvance(glyph);
         fAdvanceCount += 1;
     } else {
         SkASSERT(kFull_MetricsType == mtype);
         fScalerContext->getMetrics(glyph);
         fMetricsCount += 1;
     }

     return glyph;
 }

 const void* SkGlyphCache::findImage(const SkGlyph& glyph) {
     if (glyph.fWidth > 0 && glyph.fWidth < kMaxGlyphWidth) {
         if (glyph.fImage == NULL) {
             size_t  size = glyph.computeImageSize();
             const_cast<SkGlyph&>(glyph).fImage = fImageAlloc.alloc(size,
                                         SkChunkAlloc::kReturnNil_AllocFailType);
             // check that alloc() actually succeeded
             if (glyph.fImage) {
                 fScalerContext->getImage(glyph);
                 // TODO: the scaler may have changed the maskformat during
                 // getImage (e.g. from AA or LCD to BW) which means we may have
                 // overallocated the buffer. Check if the new computedImageSize
                 // is smaller, and if so, strink the alloc size in fImageAlloc.
                 fMemoryUsed += size;
             }
         }
     }
     return glyph.fImage;
 }

 const SkPath* SkGlyphCache::findPath(const SkGlyph& glyph) {
     if (glyph.fWidth) {
         if (glyph.fPath == NULL) {
             const_cast<SkGlyph&>(glyph).fPath = SkNEW(SkPath);
             fScalerContext->getPath(glyph, glyph.fPath);
             fMemoryUsed += sizeof(SkPath) +
                     glyph.fPath->getPoints(NULL, 0x7FFFFFFF) * sizeof(SkPoint);
         }
     }
     return glyph.fPath;
 }

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

 bool SkGlyphCache::getAuxProcData(void (*proc)(void*), void** dataPtr) const {
     const AuxProcRec* rec = fAuxProcList;
     while (rec) {
         if (rec->fProc == proc) {
             if (dataPtr) {
                 *dataPtr = rec->fData;
             }
             return true;
         }
         rec = rec->fNext;
     }
     return false;
 }

 void SkGlyphCache::setAuxProc(void (*proc)(void*), void* data) {
     if (proc == NULL) {
         return;
     }

     AuxProcRec* rec = fAuxProcList;
     while (rec) {
         if (rec->fProc == proc) {
             rec->fData = data;
             return;
         }
         rec = rec->fNext;
     }
     // not found, create a new rec
     rec = SkNEW(AuxProcRec);
     rec->fProc = proc;
     rec->fData = data;
     rec->fNext = fAuxProcList;
     fAuxProcList = rec;
 }

 void SkGlyphCache::removeAuxProc(void (*proc)(void*)) {
     AuxProcRec* rec = fAuxProcList;
     AuxProcRec* prev = NULL;
     while (rec) {
         AuxProcRec* next = rec->fNext;
         if (rec->fProc == proc) {
             if (prev) {
                 prev->fNext = next;
             } else {
                 fAuxProcList = next;
             }
             SkDELETE(rec);
             return;
         }
         prev = rec;
         rec = next;
     }
 }

 void SkGlyphCache::invokeAndRemoveAuxProcs() {
     AuxProcRec* rec = fAuxProcList;
     while (rec) {
         rec->fProc(rec->fData);
         AuxProcRec* next = rec->fNext;
         SkDELETE(rec);
         rec = next;
     }
 }

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

 #ifdef USE_CACHE_HASH
     #define HASH_BITCOUNT   6
     #define HASH_COUNT      (1 << HASH_BITCOUNT)
     #define HASH_MASK       (HASH_COUNT - 1)

     static unsigned desc_to_hashindex(const SkDescriptor* desc)
     {
         SkASSERT(HASH_MASK < 256);  // since our munging reduces to 8 bits

         uint32_t n = *(const uint32_t*)desc;    //desc->getChecksum();
         SkASSERT(n == desc->getChecksum());

         // don't trust that the low bits of checksum vary enough, so...
         n ^= (n >> 24) ^ (n >> 16) ^ (n >> 8) ^ (n >> 30);

         return n & HASH_MASK;
     }
 #endif

 #include "SkThread.h"

 class SkGlyphCache_Globals {
 public:
     SkGlyphCache_Globals() {
         fHead = NULL;
         fTotalMemoryUsed = 0;
 #ifdef USE_CACHE_HASH
         sk_bzero(fHash, sizeof(fHash));
 #endif
     }

     SkMutex         fMutex;
     SkGlyphCache*   fHead;
     size_t          fTotalMemoryUsed;
 #ifdef USE_CACHE_HASH
     SkGlyphCache*   fHash[HASH_COUNT];
 #endif

 #ifdef SK_DEBUG
     void validate() const;
 #else
     void validate() const {}
 #endif
 };

 static SkGlyphCache_Globals& getGlobals() {
     // we leak this, so we don't incur any shutdown cost of the destructor
     static SkGlyphCache_Globals* gGlobals = new SkGlyphCache_Globals;
     return *gGlobals;
 }

 void SkGlyphCache::VisitAllCaches(bool (*proc)(SkGlyphCache*, void*),
                                   void* context) {
     SkGlyphCache_Globals& globals = getGlobals();
     SkAutoMutexAcquire    ac(globals.fMutex);
     SkGlyphCache*         cache;

     globals.validate();

     for (cache = globals.fHead; cache != NULL; cache = cache->fNext) {
         if (proc(cache, context)) {
             break;
         }
     }

     globals.validate();
 }

 /*  This guy calls the visitor from within the mutext lock, so the visitor
     cannot:
     - take too much time
     - try to acquire the mutext again
     - call a fontscaler (which might call into the cache)
 */
 SkGlyphCache* SkGlyphCache::VisitCache(const SkDescriptor* desc,
                               bool (*proc)(const SkGlyphCache*, void*),
                               void* context) {
     SkASSERT(desc);

     SkGlyphCache_Globals& globals = getGlobals();
     SkAutoMutexAcquire    ac(globals.fMutex);
     SkGlyphCache*         cache;
     bool                  insideMutex = true;

     globals.validate();

 #ifdef USE_CACHE_HASH
     SkGlyphCache** hash = globals.fHash;
     unsigned index = desc_to_hashindex(desc);
     cache = hash[index];
     if (cache && *cache->fDesc == *desc) {
         cache->detach(&globals.fHead);
         goto FOUND_IT;
     }
 #endif

     for (cache = globals.fHead; cache != NULL; cache = cache->fNext) {
         if (cache->fDesc->equals(*desc)) {
             cache->detach(&globals.fHead);
             goto FOUND_IT;
         }
     }

     /* Release the mutex now, before we create a new entry (which might have
         side-effects like trying to access the cache/mutex (yikes!)
     */
     ac.release();           // release the mutex now
     insideMutex = false;    // can't use globals anymore

     cache = SkNEW_ARGS(SkGlyphCache, (desc));

 FOUND_IT:

     AutoValidate av(cache);

     if (proc(cache, context)) {   // stay detached
         if (insideMutex) {
             SkASSERT(globals.fTotalMemoryUsed >= cache->fMemoryUsed);
             globals.fTotalMemoryUsed -= cache->fMemoryUsed;
 #ifdef USE_CACHE_HASH
             hash[index] = NULL;
 #endif
         }
     } else {                        // reattach
         if (insideMutex) {
             cache->attachToHead(&globals.fHead);
 #ifdef USE_CACHE_HASH
             hash[index] = cache;
 #endif
         } else {
             AttachCache(cache);
         }
         cache = NULL;
     }
     return cache;
 }

 void SkGlyphCache::AttachCache(SkGlyphCache* cache) {
     SkASSERT(cache);
     SkASSERT(cache->fNext == NULL);

     SkGlyphCache_Globals& globals = getGlobals();
     SkAutoMutexAcquire    ac(globals.fMutex);

     globals.validate();
     cache->validate();

     // if we have a fixed budget for our cache, do a purge here
     {
         size_t allocated = globals.fTotalMemoryUsed + cache->fMemoryUsed;
         size_t budgeted = SkGraphics::GetFontCacheLimit();
         if (allocated > budgeted) {
             (void)InternalFreeCache(&globals, allocated - budgeted);
         }
     }

     cache->attachToHead(&globals.fHead);
     globals.fTotalMemoryUsed += cache->fMemoryUsed;

 #ifdef USE_CACHE_HASH
     unsigned index = desc_to_hashindex(cache->fDesc);
     SkASSERT(globals.fHash[index] != cache);
     globals.fHash[index] = cache;
 #endif

     globals.validate();
 }

 size_t SkGlyphCache::GetCacheUsed() {
     SkGlyphCache_Globals& globals = getGlobals();
     SkAutoMutexAcquire  ac(globals.fMutex);

     return SkGlyphCache::ComputeMemoryUsed(globals.fHead);
 }

 bool SkGlyphCache::SetCacheUsed(size_t bytesUsed) {
     size_t curr = SkGlyphCache::GetCacheUsed();

     if (curr > bytesUsed) {
         SkGlyphCache_Globals& globals = getGlobals();
         SkAutoMutexAcquire  ac(globals.fMutex);

         return InternalFreeCache(&globals, curr - bytesUsed) > 0;
     }
     return false;
 }

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

 SkGlyphCache* SkGlyphCache::FindTail(SkGlyphCache* cache) {
     if (cache) {
         while (cache->fNext) {
             cache = cache->fNext;
         }
     }
     return cache;
 }

 size_t SkGlyphCache::ComputeMemoryUsed(const SkGlyphCache* head) {
     size_t size = 0;

     while (head != NULL) {
         size += head->fMemoryUsed;
         head = head->fNext;
     }
     return size;
 }

 #ifdef SK_DEBUG
 void SkGlyphCache_Globals::validate() const {
     size_t computed = SkGlyphCache::ComputeMemoryUsed(fHead);
     if (fTotalMemoryUsed != computed) {
         printf("total %d, computed %d\n", (int)fTotalMemoryUsed, (int)computed);
     }
     SkASSERT(fTotalMemoryUsed == computed);
 }
 #endif

 size_t SkGlyphCache::InternalFreeCache(SkGlyphCache_Globals* globals,
                                        size_t bytesNeeded) {
     globals->validate();

     size_t  bytesFreed = 0;
     int     count = 0;

     // don't do any "small" purges
     size_t minToPurge = globals->fTotalMemoryUsed >> 2;
     if (bytesNeeded < minToPurge)
         bytesNeeded = minToPurge;

     SkGlyphCache* cache = FindTail(globals->fHead);
     while (cache != NULL && bytesFreed < bytesNeeded) {
         SkGlyphCache* prev = cache->fPrev;
         bytesFreed += cache->fMemoryUsed;

 #ifdef USE_CACHE_HASH
         unsigned index = desc_to_hashindex(cache->fDesc);
         if (cache == globals->fHash[index]) {
             globals->fHash[index] = NULL;
         }
 #endif

         cache->detach(&globals->fHead);
         SkDELETE(cache);
         cache = prev;
         count += 1;
     }

     SkASSERT(bytesFreed <= globals->fTotalMemoryUsed);
     globals->fTotalMemoryUsed -= bytesFreed;
     globals->validate();

 #ifdef SPEW_PURGE_STATUS
     if (count && !gSkSuppressFontCachePurgeSpew) {
         SkDebugf("purging %dK from font cache [%d entries]\n",
                  (int)(bytesFreed >> 10), count);
     }
 #endif

     return bytesFreed;
 }

 ///////////////////////////////////////////////////////////////////////////////
 #ifdef SK_DEBUG

 void SkGlyphCache::validate() const {
     int count = fGlyphArray.count();
     for (int i = 0; i < count; i++) {
         const SkGlyph* glyph = fGlyphArray[i];
         SkASSERT(glyph);
         SkASSERT(fGlyphAlloc.contains(glyph));
         if (glyph->fImage) {
             SkASSERT(fImageAlloc.contains(glyph->fImage));
         }
     }
 }

 #endif

	/*
	* 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 "SkGlyphCache.h"
	#include "SkGraphics.h"
	#include "SkPaint.h"
	#include "SkTemplates.h"

	//#define SPEW_PURGE_STATUS
	//#define USE_CACHE_HASH
	//#define RECORD_HASH_EFFICIENCY

	bool gSkSuppressFontCachePurgeSpew;

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

	#ifdef RECORD_HASH_EFFICIENCY
	static uint32_t gHashSuccess;
	static uint32_t gHashCollision;

	static void RecordHashSuccess() {
	gHashSuccess += 1;
	}

	static void RecordHashCollisionIf(bool pred) {
	if (pred) {
	gHashCollision += 1;

	uint32_t total = gHashSuccess + gHashCollision;
	SkDebugf("Font Cache Hash success rate: %d%%\n",
	100 * gHashSuccess / total);
	}
	}
	#else
	#define RecordHashSuccess() (void)0
	#define RecordHashCollisionIf(pred) (void)0
	#endif
	#define RecordHashCollision() RecordHashCollisionIf(true)

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

	#define kMinGlphAlloc (sizeof(SkGlyph) * 64)
	#define kMinImageAlloc (24 * 64) // should be pointsize-dependent

	#define METRICS_RESERVE_COUNT 128 // so we don't grow this array a lot

	SkGlyphCache::SkGlyphCache(const SkDescriptor* desc)
	: fGlyphAlloc(kMinGlphAlloc), fImageAlloc(kMinImageAlloc) {
	fPrev = fNext = NULL;

	fDesc = desc->copy();
	fScalerContext = SkScalerContext::Create(desc);
	fScalerContext->getFontMetrics(NULL, &fFontMetricsY);

	// init to 0 so that all of the pointers will be null
	memset(fGlyphHash, 0, sizeof(fGlyphHash));
	// init with 0xFF so that the charCode field will be -1, which is invalid
	memset(fCharToGlyphHash, 0xFF, sizeof(fCharToGlyphHash));

	fMemoryUsed = sizeof(*this) + kMinGlphAlloc + kMinImageAlloc;

	fGlyphArray.setReserve(METRICS_RESERVE_COUNT);

	fMetricsCount = 0;
	fAdvanceCount = 0;
	fAuxProcList = NULL;
	}

	SkGlyphCache::~SkGlyphCache() {
	SkGlyph** gptr = fGlyphArray.begin();
	SkGlyph** stop = fGlyphArray.end();
	while (gptr < stop) {
	SkPath* path = (*gptr)->fPath;
	if (path) {
	SkDELETE(path);
	}
	gptr += 1;
	}
	SkDescriptor::Free(fDesc);
	SkDELETE(fScalerContext);
	this->invokeAndRemoveAuxProcs();
	}

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

	#ifdef SK_DEBUG
	#define VALIDATE() AutoValidate av(this)
	#else
	#define VALIDATE()
	#endif

	uint16_t SkGlyphCache::unicharToGlyph(SkUnichar charCode) {
	VALIDATE();
	uint32_t id = SkGlyph::MakeID(charCode);
	const CharGlyphRec& rec = fCharToGlyphHash[ID2HashIndex(id)];

	if (rec.fID == id) {
	return rec.fGlyph->getGlyphID();
	} else {
	return fScalerContext->charToGlyphID(charCode);
	}
	}

	SkUnichar SkGlyphCache::glyphToUnichar(uint16_t glyphID) {
	return fScalerContext->glyphIDToChar(glyphID);
	}

	unsigned SkGlyphCache::getGlyphCount() {
	return fScalerContext->getGlyphCount();
	}

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

	const SkGlyph& SkGlyphCache::getUnicharAdvance(SkUnichar charCode) {
	VALIDATE();
	uint32_t id = SkGlyph::MakeID(charCode);
	CharGlyphRec* rec = &fCharToGlyphHash[ID2HashIndex(id)];

	if (rec->fID != id) {
	// this ID is based on the UniChar
	rec->fID = id;
	// this ID is based on the glyph index
	id = SkGlyph::MakeID(fScalerContext->charToGlyphID(charCode));
	rec->fGlyph = this->lookupMetrics(id, kJustAdvance_MetricsType);
	}
	return *rec->fGlyph;
	}

	const SkGlyph& SkGlyphCache::getGlyphIDAdvance(uint16_t glyphID) {
	VALIDATE();
	uint32_t id = SkGlyph::MakeID(glyphID);
	unsigned index = ID2HashIndex(id);
	SkGlyph* glyph = fGlyphHash[index];

	if (NULL == glyph \|\| glyph->fID != id) {
	glyph = this->lookupMetrics(glyphID, kJustAdvance_MetricsType);
	fGlyphHash[index] = glyph;
	}
	return *glyph;
	}

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

	const SkGlyph& SkGlyphCache::getUnicharMetrics(SkUnichar charCode) {
	VALIDATE();
	uint32_t id = SkGlyph::MakeID(charCode);
	CharGlyphRec* rec = &fCharToGlyphHash[ID2HashIndex(id)];

	if (rec->fID != id) {
	RecordHashCollisionIf(rec->fGlyph != NULL);
	// this ID is based on the UniChar
	rec->fID = id;
	// this ID is based on the glyph index
	id = SkGlyph::MakeID(fScalerContext->charToGlyphID(charCode));
	rec->fGlyph = this->lookupMetrics(id, kFull_MetricsType);
	} else {
	RecordHashSuccess();
	if (rec->fGlyph->isJustAdvance()) {
	fScalerContext->getMetrics(rec->fGlyph);
	}
	}
	SkASSERT(rec->fGlyph->isFullMetrics());
	return *rec->fGlyph;
	}

	const SkGlyph& SkGlyphCache::getUnicharMetrics(SkUnichar charCode,
	SkFixed x, SkFixed y) {
	VALIDATE();
	uint32_t id = SkGlyph::MakeID(charCode, x, y);
	CharGlyphRec* rec = &fCharToGlyphHash[ID2HashIndex(id)];

	if (rec->fID != id) {
	RecordHashCollisionIf(rec->fGlyph != NULL);
	// this ID is based on the UniChar
	rec->fID = id;
	// this ID is based on the glyph index
	id = SkGlyph::MakeID(fScalerContext->charToGlyphID(charCode), x, y);
	rec->fGlyph = this->lookupMetrics(id, kFull_MetricsType);
	} else {
	RecordHashSuccess();
	if (rec->fGlyph->isJustAdvance()) {
	fScalerContext->getMetrics(rec->fGlyph);
	}
	}
	SkASSERT(rec->fGlyph->isFullMetrics());
	return *rec->fGlyph;
	}

	const SkGlyph& SkGlyphCache::getGlyphIDMetrics(uint16_t glyphID) {
	VALIDATE();
	uint32_t id = SkGlyph::MakeID(glyphID);
	unsigned index = ID2HashIndex(id);
	SkGlyph* glyph = fGlyphHash[index];

	if (NULL == glyph \|\| glyph->fID != id) {
	RecordHashCollisionIf(glyph != NULL);
	glyph = this->lookupMetrics(glyphID, kFull_MetricsType);
	fGlyphHash[index] = glyph;
	} else {
	RecordHashSuccess();
	if (glyph->isJustAdvance()) {
	fScalerContext->getMetrics(glyph);
	}
	}
	SkASSERT(glyph->isFullMetrics());
	return *glyph;
	}

	const SkGlyph& SkGlyphCache::getGlyphIDMetrics(uint16_t glyphID,
	SkFixed x, SkFixed y) {
	VALIDATE();
	uint32_t id = SkGlyph::MakeID(glyphID, x, y);
	unsigned index = ID2HashIndex(id);
	SkGlyph* glyph = fGlyphHash[index];

	if (NULL == glyph \|\| glyph->fID != id) {
	RecordHashCollisionIf(glyph != NULL);
	glyph = this->lookupMetrics(id, kFull_MetricsType);
	fGlyphHash[index] = glyph;
	} else {
	RecordHashSuccess();
	if (glyph->isJustAdvance()) {
	fScalerContext->getMetrics(glyph);
	}
	}
	SkASSERT(glyph->isFullMetrics());
	return *glyph;
	}

	SkGlyph* SkGlyphCache::lookupMetrics(uint32_t id, MetricsType mtype) {
	SkGlyph* glyph;

	int hi = 0;
	int count = fGlyphArray.count();

	if (count) {
	SkGlyph** gptr = fGlyphArray.begin();
	int lo = 0;

	hi = count - 1;
	while (lo < hi) {
	int mid = (hi + lo) >> 1;
	if (gptr[mid]->fID < id) {
	lo = mid + 1;
	} else {
	hi = mid;
	}
	}
	glyph = gptr[hi];
	if (glyph->fID == id) {
	if (kFull_MetricsType == mtype && glyph->isJustAdvance()) {
	fScalerContext->getMetrics(glyph);
	}
	return glyph;
	}

	// check if we need to bump hi before falling though to the allocator
	if (glyph->fID < id) {
	hi += 1;
	}
	}

	// not found, but hi tells us where to inser the new glyph
	fMemoryUsed += sizeof(SkGlyph);

	glyph = (SkGlyph*)fGlyphAlloc.alloc(sizeof(SkGlyph),
	SkChunkAlloc::kThrow_AllocFailType);
	glyph->init(id);
	*fGlyphArray.insert(hi) = glyph;

	if (kJustAdvance_MetricsType == mtype) {
	fScalerContext->getAdvance(glyph);
	fAdvanceCount += 1;
	} else {
	SkASSERT(kFull_MetricsType == mtype);
	fScalerContext->getMetrics(glyph);
	fMetricsCount += 1;
	}

	return glyph;
	}

	const void* SkGlyphCache::findImage(const SkGlyph& glyph) {
	if (glyph.fWidth > 0 && glyph.fWidth < kMaxGlyphWidth) {
	if (glyph.fImage == NULL) {
	size_t size = glyph.computeImageSize();
	const_cast<SkGlyph&>(glyph).fImage = fImageAlloc.alloc(size,
	SkChunkAlloc::kReturnNil_AllocFailType);
	// check that alloc() actually succeeded
	if (glyph.fImage) {
	fScalerContext->getImage(glyph);
	// TODO: the scaler may have changed the maskformat during
	// getImage (e.g. from AA or LCD to BW) which means we may have
	// overallocated the buffer. Check if the new computedImageSize
	// is smaller, and if so, strink the alloc size in fImageAlloc.
	fMemoryUsed += size;
	}
	}
	}
	return glyph.fImage;
	}

	const SkPath* SkGlyphCache::findPath(const SkGlyph& glyph) {
	if (glyph.fWidth) {
	if (glyph.fPath == NULL) {
	const_cast<SkGlyph&>(glyph).fPath = SkNEW(SkPath);
	fScalerContext->getPath(glyph, glyph.fPath);
	fMemoryUsed += sizeof(SkPath) +
	glyph.fPath->getPoints(NULL, 0x7FFFFFFF) * sizeof(SkPoint);
	}
	}
	return glyph.fPath;
	}

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

	bool SkGlyphCache::getAuxProcData(void (proc)(void), void** dataPtr) const {
	const AuxProcRec* rec = fAuxProcList;
	while (rec) {
	if (rec->fProc == proc) {
	if (dataPtr) {
	*dataPtr = rec->fData;
	}
	return true;
	}
	rec = rec->fNext;
	}
	return false;
	}

	void SkGlyphCache::setAuxProc(void (proc)(void), void* data) {
	if (proc == NULL) {
	return;
	}

	AuxProcRec* rec = fAuxProcList;
	while (rec) {
	if (rec->fProc == proc) {
	rec->fData = data;
	return;
	}
	rec = rec->fNext;
	}
	// not found, create a new rec
	rec = SkNEW(AuxProcRec);
	rec->fProc = proc;
	rec->fData = data;
	rec->fNext = fAuxProcList;
	fAuxProcList = rec;
	}

	void SkGlyphCache::removeAuxProc(void (proc)(void)) {
	AuxProcRec* rec = fAuxProcList;
	AuxProcRec* prev = NULL;
	while (rec) {
	AuxProcRec* next = rec->fNext;
	if (rec->fProc == proc) {
	if (prev) {
	prev->fNext = next;
	} else {
	fAuxProcList = next;
	}
	SkDELETE(rec);
	return;
	}
	prev = rec;
	rec = next;
	}
	}

	void SkGlyphCache::invokeAndRemoveAuxProcs() {
	AuxProcRec* rec = fAuxProcList;
	while (rec) {
	rec->fProc(rec->fData);
	AuxProcRec* next = rec->fNext;
	SkDELETE(rec);
	rec = next;
	}
	}

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

	#ifdef USE_CACHE_HASH
	#define HASH_BITCOUNT 6
	#define HASH_COUNT (1 << HASH_BITCOUNT)
	#define HASH_MASK (HASH_COUNT - 1)

	static unsigned desc_to_hashindex(const SkDescriptor* desc)
	{
	SkASSERT(HASH_MASK < 256); // since our munging reduces to 8 bits

	uint32_t n = (const uint32_t)desc; //desc->getChecksum();
	SkASSERT(n == desc->getChecksum());

	// don't trust that the low bits of checksum vary enough, so...
	n ^= (n >> 24) ^ (n >> 16) ^ (n >> 8) ^ (n >> 30);

	return n & HASH_MASK;
	}
	#endif

	#include "SkThread.h"

	class SkGlyphCache_Globals {
	public:
	SkGlyphCache_Globals() {
	fHead = NULL;
	fTotalMemoryUsed = 0;
	#ifdef USE_CACHE_HASH
	sk_bzero(fHash, sizeof(fHash));
	#endif
	}

	SkMutex fMutex;
	SkGlyphCache* fHead;
	size_t fTotalMemoryUsed;
	#ifdef USE_CACHE_HASH
	SkGlyphCache* fHash[HASH_COUNT];
	#endif

	#ifdef SK_DEBUG
	void validate() const;
	#else
	void validate() const {}
	#endif
	};

	static SkGlyphCache_Globals& getGlobals() {
	// we leak this, so we don't incur any shutdown cost of the destructor
	static SkGlyphCache_Globals* gGlobals = new SkGlyphCache_Globals;
	return *gGlobals;
	}

	void SkGlyphCache::VisitAllCaches(bool (proc)(SkGlyphCache, void*),
	void* context) {
	SkGlyphCache_Globals& globals = getGlobals();
	SkAutoMutexAcquire ac(globals.fMutex);
	SkGlyphCache* cache;

	globals.validate();

	for (cache = globals.fHead; cache != NULL; cache = cache->fNext) {
	if (proc(cache, context)) {
	break;
	}
	}

	globals.validate();
	}

	/* This guy calls the visitor from within the mutext lock, so the visitor
	cannot:
	- take too much time
	- try to acquire the mutext again
	- call a fontscaler (which might call into the cache)
	*/
	SkGlyphCache* SkGlyphCache::VisitCache(const SkDescriptor* desc,
	bool (proc)(const SkGlyphCache, void*),
	void* context) {
	SkASSERT(desc);

	SkGlyphCache_Globals& globals = getGlobals();
	SkAutoMutexAcquire ac(globals.fMutex);
	SkGlyphCache* cache;
	bool insideMutex = true;

	globals.validate();

	#ifdef USE_CACHE_HASH
	SkGlyphCache** hash = globals.fHash;
	unsigned index = desc_to_hashindex(desc);
	cache = hash[index];
	if (cache && cache->fDesc == desc) {
	cache->detach(&globals.fHead);
	goto FOUND_IT;
	}
	#endif

	for (cache = globals.fHead; cache != NULL; cache = cache->fNext) {
	if (cache->fDesc->equals(*desc)) {
	cache->detach(&globals.fHead);
	goto FOUND_IT;
	}
	}

	/* Release the mutex now, before we create a new entry (which might have
	side-effects like trying to access the cache/mutex (yikes!)
	*/
	ac.release(); // release the mutex now
	insideMutex = false; // can't use globals anymore

	cache = SkNEW_ARGS(SkGlyphCache, (desc));

	FOUND_IT:

	AutoValidate av(cache);

	if (proc(cache, context)) { // stay detached
	if (insideMutex) {
	SkASSERT(globals.fTotalMemoryUsed >= cache->fMemoryUsed);
	globals.fTotalMemoryUsed -= cache->fMemoryUsed;
	#ifdef USE_CACHE_HASH
	hash[index] = NULL;
	#endif
	}
	} else { // reattach
	if (insideMutex) {
	cache->attachToHead(&globals.fHead);
	#ifdef USE_CACHE_HASH
	hash[index] = cache;
	#endif
	} else {
	AttachCache(cache);
	}
	cache = NULL;
	}
	return cache;
	}

	void SkGlyphCache::AttachCache(SkGlyphCache* cache) {
	SkASSERT(cache);
	SkASSERT(cache->fNext == NULL);

	SkGlyphCache_Globals& globals = getGlobals();
	SkAutoMutexAcquire ac(globals.fMutex);

	globals.validate();
	cache->validate();

	// if we have a fixed budget for our cache, do a purge here
	{
	size_t allocated = globals.fTotalMemoryUsed + cache->fMemoryUsed;
	size_t budgeted = SkGraphics::GetFontCacheLimit();
	if (allocated > budgeted) {
	(void)InternalFreeCache(&globals, allocated - budgeted);
	}
	}

	cache->attachToHead(&globals.fHead);
	globals.fTotalMemoryUsed += cache->fMemoryUsed;

	#ifdef USE_CACHE_HASH
	unsigned index = desc_to_hashindex(cache->fDesc);
	SkASSERT(globals.fHash[index] != cache);
	globals.fHash[index] = cache;
	#endif

	globals.validate();
	}

	size_t SkGlyphCache::GetCacheUsed() {
	SkGlyphCache_Globals& globals = getGlobals();
	SkAutoMutexAcquire ac(globals.fMutex);

	return SkGlyphCache::ComputeMemoryUsed(globals.fHead);
	}

	bool SkGlyphCache::SetCacheUsed(size_t bytesUsed) {
	size_t curr = SkGlyphCache::GetCacheUsed();

	if (curr > bytesUsed) {
	SkGlyphCache_Globals& globals = getGlobals();
	SkAutoMutexAcquire ac(globals.fMutex);

	return InternalFreeCache(&globals, curr - bytesUsed) > 0;
	}
	return false;
	}

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

	SkGlyphCache* SkGlyphCache::FindTail(SkGlyphCache* cache) {
	if (cache) {
	while (cache->fNext) {
	cache = cache->fNext;
	}
	}
	return cache;
	}

	size_t SkGlyphCache::ComputeMemoryUsed(const SkGlyphCache* head) {
	size_t size = 0;

	while (head != NULL) {
	size += head->fMemoryUsed;
	head = head->fNext;
	}
	return size;
	}

	#ifdef SK_DEBUG
	void SkGlyphCache_Globals::validate() const {
	size_t computed = SkGlyphCache::ComputeMemoryUsed(fHead);
	if (fTotalMemoryUsed != computed) {
	printf("total %d, computed %d\n", (int)fTotalMemoryUsed, (int)computed);
	}
	SkASSERT(fTotalMemoryUsed == computed);
	}
	#endif

	size_t SkGlyphCache::InternalFreeCache(SkGlyphCache_Globals* globals,
	size_t bytesNeeded) {
	globals->validate();

	size_t bytesFreed = 0;
	int count = 0;

	// don't do any "small" purges
	size_t minToPurge = globals->fTotalMemoryUsed >> 2;
	if (bytesNeeded < minToPurge)
	bytesNeeded = minToPurge;

	SkGlyphCache* cache = FindTail(globals->fHead);
	while (cache != NULL && bytesFreed < bytesNeeded) {
	SkGlyphCache* prev = cache->fPrev;
	bytesFreed += cache->fMemoryUsed;

	#ifdef USE_CACHE_HASH
	unsigned index = desc_to_hashindex(cache->fDesc);
	if (cache == globals->fHash[index]) {
	globals->fHash[index] = NULL;
	}
	#endif

	cache->detach(&globals->fHead);
	SkDELETE(cache);
	cache = prev;
	count += 1;
	}

	SkASSERT(bytesFreed <= globals->fTotalMemoryUsed);
	globals->fTotalMemoryUsed -= bytesFreed;
	globals->validate();

	#ifdef SPEW_PURGE_STATUS
	if (count && !gSkSuppressFontCachePurgeSpew) {
	SkDebugf("purging %dK from font cache [%d entries]\n",
	(int)(bytesFreed >> 10), count);
	}
	#endif

	return bytesFreed;
	}

	///////////////////////////////////////////////////////////////////////////////
	#ifdef SK_DEBUG

	void SkGlyphCache::validate() const {
	int count = fGlyphArray.count();
	for (int i = 0; i < count; i++) {
	const SkGlyph* glyph = fGlyphArray[i];
	SkASSERT(glyph);
	SkASSERT(fGlyphAlloc.contains(glyph));
	if (glyph->fImage) {
	SkASSERT(fImageAlloc.contains(glyph->fImage));
	}
	}
	}

	#endif