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/*
* Copyright 2015 Google Inc.
*
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#ifndef GrDrawOpAtlas_DEFINED
#define GrDrawOpAtlas_DEFINED
#include <cmath>
#include "SkGlyphRunPainter.h"
#include "SkIPoint16.h"
#include "SkSize.h"
#include "SkTDArray.h"
#include "SkTInternalLList.h"
#include "ops/GrDrawOp.h"
class GrOnFlushResourceProvider;
class GrRectanizer;
/**
* This class manages one or more atlas textures on behalf of GrDrawOps. The draw ops that use the
* atlas perform texture uploads when preparing their draws during flush. The class provides
* facilities for using GrDrawOpUploadToken to detect data hazards. Op's uploads are performed in
* "ASAP" mode until it is impossible to add data without overwriting texels read by draws that
* have not yet executed on the gpu. At that point, the atlas will attempt to allocate a new
* atlas texture (or "page") of the same size, up to a maximum number of textures, and upload
* to that texture. If that's not possible, the uploads are performed "inline" between draws. If a
* single draw would use enough subimage space to overflow the atlas texture then the atlas will
* fail to add a subimage. This gives the op the chance to end the draw and begin a new one.
* Additional uploads will then succeed in inline mode.
*
* When the atlas has multiple pages, new uploads are prioritized to the lower index pages, i.e.,
* it will try to upload to page 0 before page 1 or 2. To keep the atlas from continually using
* excess space, periodic garbage collection is needed to shift data from the higher index pages to
* the lower ones, and then eventually remove any pages that are no longer in use. "In use" is
* determined by using the GrDrawUploadToken system: After a flush each subarea of the page
* is checked to see whether it was used in that flush; if it is not, a counter is incremented.
* Once that counter reaches a threshold that subarea is considered to be no longer in use.
*
* Garbage collection is initiated by the GrDrawOpAtlas's client via the compact() method. One
* solution is to make the client a subclass of GrOnFlushCallbackObject, register it with the
* GrContext via addOnFlushCallbackObject(), and the client's postFlush() method calls compact()
* and passes in the given GrDrawUploadToken.
*/
class GrDrawOpAtlas {
private:
static constexpr auto kMaxMultitexturePages = 4;
public:
/** Is the atlas allowed to use more than one texture? */
enum class AllowMultitexturing : bool { kNo, kYes };
static constexpr int kMaxPlots = 32; // restricted by the fPlotAlreadyUpdated bitfield
// in BulkUseTokenUpdater
/**
* An AtlasID is an opaque handle which callers can use to determine if the atlas contains
* a specific piece of data.
*/
typedef uint64_t AtlasID;
static const uint32_t kInvalidAtlasID = 0;
static const uint64_t kInvalidAtlasGeneration = 0;
/**
* A function pointer for use as a callback during eviction. Whenever GrDrawOpAtlas evicts a
* specific AtlasID, it will call all of the registered listeners so they can process the
* eviction.
*/
typedef void (*EvictionFunc)(GrDrawOpAtlas::AtlasID, void*);
/**
* Returns a GrDrawOpAtlas. This function can be called anywhere, but the returned atlas
* should only be used inside of GrMeshDrawOp::onPrepareDraws.
* @param GrPixelConfig The pixel config which this atlas will store
* @param width width in pixels of the atlas
* @param height height in pixels of the atlas
* @param numPlotsX The number of plots the atlas should be broken up into in the X
* direction
* @param numPlotsY The number of plots the atlas should be broken up into in the Y
* direction
* @param allowMultitexturing Can the atlas use more than one texture.
* @param func An eviction function which will be called whenever the atlas has to
* evict data
* @param data User supplied data which will be passed into func whenever an
* eviction occurs
* @return An initialized GrDrawOpAtlas, or nullptr if creation fails
*/
static std::unique_ptr<GrDrawOpAtlas> Make(GrProxyProvider*,
const GrBackendFormat& format,
GrPixelConfig,
int width, int height,
int plotWidth, int plotHeight,
AllowMultitexturing allowMultitexturing,
GrDrawOpAtlas::EvictionFunc func, void* data);
/**
* Adds a width x height subimage to the atlas. Upon success it returns 'kSucceeded' and returns
* the ID and the subimage's coordinates in the backing texture. 'kTryAgain' is returned if
* the subimage cannot fit in the atlas without overwriting texels that will be read in the
* current draw. This indicates that the op should end its current draw and begin another
* before adding more data. Upon success, an upload of the provided image data will have
* been added to the GrDrawOp::Target, in "asap" mode if possible, otherwise in "inline" mode.
* Successive uploads in either mode may be consolidated.
* 'kError' will be returned when some unrecoverable error was encountered while trying to
* add the subimage. In this case the op being created should be discarded.
*
* NOTE: When the GrDrawOp prepares a draw that reads from the atlas, it must immediately call
* 'setUseToken' with the currentToken from the GrDrawOp::Target, otherwise the next call to
* addToAtlas might cause the previous data to be overwritten before it has been read.
*/
enum class ErrorCode {
kError,
kSucceeded,
kTryAgain
};
ErrorCode addToAtlas(GrResourceProvider*, AtlasID*, GrDeferredUploadTarget*,
int width, int height,
const void* image, SkIPoint16* loc);
const sk_sp<GrTextureProxy>* getProxies() const { return fProxies; }
uint64_t atlasGeneration() const { return fAtlasGeneration; }
inline bool hasID(AtlasID id) {
if (kInvalidAtlasID == id) {
return false;
}
uint32_t plot = GetPlotIndexFromID(id);
SkASSERT(plot < fNumPlots);
uint32_t page = GetPageIndexFromID(id);
SkASSERT(page < fNumActivePages);
return fPages[page].fPlotArray[plot]->genID() == GetGenerationFromID(id);
}
/** To ensure the atlas does not evict a given entry, the client must set the last use token. */
inline void setLastUseToken(AtlasID id, GrDeferredUploadToken token) {
SkASSERT(this->hasID(id));
uint32_t plotIdx = GetPlotIndexFromID(id);
SkASSERT(plotIdx < fNumPlots);
uint32_t pageIdx = GetPageIndexFromID(id);
SkASSERT(pageIdx < fNumActivePages);
Plot* plot = fPages[pageIdx].fPlotArray[plotIdx].get();
this->makeMRU(plot, pageIdx);
plot->setLastUseToken(token);
}
inline void registerEvictionCallback(EvictionFunc func, void* userData) {
EvictionData* data = fEvictionCallbacks.append();
data->fFunc = func;
data->fData = userData;
}
uint32_t numActivePages() { return fNumActivePages; }
/**
* A class which can be handed back to GrDrawOpAtlas for updating last use tokens in bulk. The
* current max number of plots per page the GrDrawOpAtlas can handle is 32. If in the future
* this is insufficient then we can move to a 64 bit int.
*/
class BulkUseTokenUpdater {
public:
BulkUseTokenUpdater() {
memset(fPlotAlreadyUpdated, 0, sizeof(fPlotAlreadyUpdated));
}
BulkUseTokenUpdater(const BulkUseTokenUpdater& that)
: fPlotsToUpdate(that.fPlotsToUpdate) {
memcpy(fPlotAlreadyUpdated, that.fPlotAlreadyUpdated, sizeof(fPlotAlreadyUpdated));
}
bool add(AtlasID id) {
int index = GrDrawOpAtlas::GetPlotIndexFromID(id);
int pageIdx = GrDrawOpAtlas::GetPageIndexFromID(id);
if (this->find(pageIdx, index)) {
return false;
}
this->set(pageIdx, index);
return true;
}
void reset() {
fPlotsToUpdate.reset();
memset(fPlotAlreadyUpdated, 0, sizeof(fPlotAlreadyUpdated));
}
struct PlotData {
PlotData(int pageIdx, int plotIdx) : fPageIndex(pageIdx), fPlotIndex(plotIdx) {}
uint32_t fPageIndex;
uint32_t fPlotIndex;
};
private:
bool find(int pageIdx, int index) const {
SkASSERT(index < kMaxPlots);
return (fPlotAlreadyUpdated[pageIdx] >> index) & 1;
}
void set(int pageIdx, int index) {
SkASSERT(!this->find(pageIdx, index));
fPlotAlreadyUpdated[pageIdx] |= (1 << index);
fPlotsToUpdate.push_back(PlotData(pageIdx, index));
}
static constexpr int kMinItems = 4;
SkSTArray<kMinItems, PlotData, true> fPlotsToUpdate;
uint32_t fPlotAlreadyUpdated[kMaxMultitexturePages]; // TODO: increase this to uint64_t
// to allow more plots per page
friend class GrDrawOpAtlas;
};
void setLastUseTokenBulk(const BulkUseTokenUpdater& updater, GrDeferredUploadToken token) {
int count = updater.fPlotsToUpdate.count();
for (int i = 0; i < count; i++) {
const BulkUseTokenUpdater::PlotData& pd = updater.fPlotsToUpdate[i];
// it's possible we've added a plot to the updater and subsequently the plot's page
// was deleted -- so we check to prevent a crash
if (pd.fPageIndex < fNumActivePages) {
Plot* plot = fPages[pd.fPageIndex].fPlotArray[pd.fPlotIndex].get();
this->makeMRU(plot, pd.fPageIndex);
plot->setLastUseToken(token);
}
}
}
void compact(GrDeferredUploadToken startTokenForNextFlush);
static uint32_t GetPageIndexFromID(AtlasID id) {
return id & 0xff;
}
void instantiate(GrOnFlushResourceProvider*);
uint32_t maxPages() const {
return fMaxPages;
}
int numAllocated_TestingOnly() const;
void setMaxPages_TestingOnly(uint32_t maxPages);
private:
GrDrawOpAtlas(GrProxyProvider*, const GrBackendFormat& format, GrPixelConfig, int width,
int height, int plotWidth, int plotHeight,
AllowMultitexturing allowMultitexturing);
/**
* The backing GrTexture for a GrDrawOpAtlas is broken into a spatial grid of Plots. The Plots
* keep track of subimage placement via their GrRectanizer. A Plot manages the lifetime of its
* data using two tokens, a last use token and a last upload token. Once a Plot is "full" (i.e.
* there is no room for the new subimage according to the GrRectanizer), it can no longer be
* used unless the last use of the Plot has already been flushed through to the gpu.
*/
class Plot : public SkRefCnt {
SK_DECLARE_INTERNAL_LLIST_INTERFACE(Plot);
public:
/** index() is a unique id for the plot relative to the owning GrAtlas and page. */
uint32_t index() const { return fPlotIndex; }
/**
* genID() is incremented when the plot is evicted due to a atlas spill. It is used to know
* if a particular subimage is still present in the atlas.
*/
uint64_t genID() const { return fGenID; }
GrDrawOpAtlas::AtlasID id() const {
SkASSERT(GrDrawOpAtlas::kInvalidAtlasID != fID);
return fID;
}
SkDEBUGCODE(size_t bpp() const { return fBytesPerPixel; })
bool addSubImage(int width, int height, const void* image, SkIPoint16* loc);
/**
* To manage the lifetime of a plot, we use two tokens. We use the last upload token to
* know when we can 'piggy back' uploads, i.e. if the last upload hasn't been flushed to
* the gpu, we don't need to issue a new upload even if we update the cpu backing store. We
* use lastUse to determine when we can evict a plot from the cache, i.e. if the last use
* has already flushed through the gpu then we can reuse the plot.
*/
GrDeferredUploadToken lastUploadToken() const { return fLastUpload; }
GrDeferredUploadToken lastUseToken() const { return fLastUse; }
void setLastUploadToken(GrDeferredUploadToken token) { fLastUpload = token; }
void setLastUseToken(GrDeferredUploadToken token) { fLastUse = token; }
void uploadToTexture(GrDeferredTextureUploadWritePixelsFn&, GrTextureProxy*);
void resetRects();
int flushesSinceLastUsed() { return fFlushesSinceLastUse; }
void resetFlushesSinceLastUsed() { fFlushesSinceLastUse = 0; }
void incFlushesSinceLastUsed() { fFlushesSinceLastUse++; }
private:
Plot(int pageIndex, int plotIndex, uint64_t genID, int offX, int offY, int width, int height,
GrPixelConfig config);
~Plot() override;
/**
* Create a clone of this plot. The cloned plot will take the place of the current plot in
* the atlas
*/
Plot* clone() const {
return new Plot(fPageIndex, fPlotIndex, fGenID + 1, fX, fY, fWidth, fHeight, fConfig);
}
static GrDrawOpAtlas::AtlasID CreateId(uint32_t pageIdx, uint32_t plotIdx,
uint64_t generation) {
SkASSERT(pageIdx < (1 << 8));
SkASSERT(pageIdx < kMaxMultitexturePages);
SkASSERT(plotIdx < (1 << 8));
SkASSERT(generation < ((uint64_t)1 << 48));
return generation << 16 | plotIdx << 8 | pageIdx;
}
GrDeferredUploadToken fLastUpload;
GrDeferredUploadToken fLastUse;
// the number of flushes since this plot has been last used
int fFlushesSinceLastUse;
struct {
const uint32_t fPageIndex : 16;
const uint32_t fPlotIndex : 16;
};
uint64_t fGenID;
GrDrawOpAtlas::AtlasID fID;
unsigned char* fData;
const int fWidth;
const int fHeight;
const int fX;
const int fY;
GrRectanizer* fRects;
const SkIPoint16 fOffset; // the offset of the plot in the backing texture
const GrPixelConfig fConfig;
const size_t fBytesPerPixel;
SkIRect fDirtyRect;
SkDEBUGCODE(bool fDirty);
friend class GrDrawOpAtlas;
typedef SkRefCnt INHERITED;
};
typedef SkTInternalLList<Plot> PlotList;
static uint32_t GetPlotIndexFromID(AtlasID id) {
return (id >> 8) & 0xff;
}
// top 48 bits are reserved for the generation ID
static uint64_t GetGenerationFromID(AtlasID id) {
return (id >> 16) & 0xffffffffffff;
}
inline bool updatePlot(GrDeferredUploadTarget*, AtlasID*, Plot*);
inline void makeMRU(Plot* plot, int pageIdx) {
if (fPages[pageIdx].fPlotList.head() == plot) {
return;
}
fPages[pageIdx].fPlotList.remove(plot);
fPages[pageIdx].fPlotList.addToHead(plot);
// No MRU update for pages -- since we will always try to add from
// the front and remove from the back there is no need for MRU.
}
bool uploadToPage(unsigned int pageIdx, AtlasID* id, GrDeferredUploadTarget* target,
int width, int height, const void* image, SkIPoint16* loc);
bool createPages(GrProxyProvider*);
bool activateNewPage(GrResourceProvider*);
void deactivateLastPage();
void processEviction(AtlasID);
inline void processEvictionAndResetRects(Plot* plot) {
this->processEviction(plot->id());
plot->resetRects();
}
GrBackendFormat fFormat;
GrPixelConfig fPixelConfig;
int fTextureWidth;
int fTextureHeight;
int fPlotWidth;
int fPlotHeight;
unsigned int fNumPlots;
uint64_t fAtlasGeneration;
// nextTokenToFlush() value at the end of the previous flush
GrDeferredUploadToken fPrevFlushToken;
struct EvictionData {
EvictionFunc fFunc;
void* fData;
};
SkTDArray<EvictionData> fEvictionCallbacks;
struct Page {
// allocated array of Plots
std::unique_ptr<sk_sp<Plot>[]> fPlotArray;
// LRU list of Plots (MRU at head - LRU at tail)
PlotList fPlotList;
};
// proxies kept separate to make it easier to pass them up to client
sk_sp<GrTextureProxy> fProxies[kMaxMultitexturePages];
Page fPages[kMaxMultitexturePages];
uint32_t fMaxPages;
uint32_t fNumActivePages;
};
// There are three atlases (A8, 565, ARGB) that are kept in relation with one another. In
// general, the A8 dimensions are 2x the 565 and ARGB dimensions with the constraint that an atlas
// size will always contain at least one plot. Since the ARGB atlas takes the most space, its
// dimensions are used to size the other two atlases.
class GrDrawOpAtlasConfig {
public:
// The capabilities of the GPU define maxTextureSize. The client provides maxBytes, and this
// represents the largest they want a single atlas texture to be. Due to multitexturing, we
// may expand temporarily to use more space as needed.
GrDrawOpAtlasConfig(int maxTextureSize, size_t maxBytes);
// For testing only - make minimum sized atlases -- a single plot for ARGB, four for A8
GrDrawOpAtlasConfig() : GrDrawOpAtlasConfig(kMaxAtlasDim, 0) {}
SkISize atlasDimensions(GrMaskFormat type) const;
SkISize plotDimensions(GrMaskFormat type) const;
private:
// On some systems texture coordinates are represented using half-precision floating point,
// which limits the largest atlas dimensions to 2048x2048.
// For simplicity we'll use this constraint for all of our atlas textures.
// This can be revisited later if we need larger atlases.
static constexpr int kMaxAtlasDim = 2048;
SkISize fARGBDimensions;
int fMaxTextureSize;
};
#endif