/*
* Copyright 2015 Google Inc.
*
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#include "GrDrawOpAtlas.h"
#include "GrContext.h"
#include "GrContextPriv.h"
#include "GrOnFlushResourceProvider.h"
#include "GrOpFlushState.h"
#include "GrRectanizer.h"
#include "GrProxyProvider.h"
#include "GrResourceProvider.h"
#include "GrSurfaceProxyPriv.h"
#include "GrTexture.h"
#include "GrTracing.h"
// When proxy allocation is deferred until flush time the proxies acting as atlases require
// special handling. This is because the usage that can be determined from the ops themselves
// isn't sufficient. Independent of the ops there will be ASAP and inline uploads to the
// atlases. Extending the usage interval of any op that uses an atlas to the start of the
// flush (as is done for proxies that are used for sw-generated masks) also won't work because
// the atlas persists even beyond the last use in an op - for a given flush. Given this, atlases
// must explicitly manage the lifetime of their backing proxies via the onFlushCallback system
// (which calls this method).
void GrDrawOpAtlas::instantiate(GrOnFlushResourceProvider* onFlushResourceProvider) {
for (uint32_t i = 0; i < fNumActivePages; ++i) {
// All the atlas pages are now instantiated at flush time in the activeNewPage method.
SkASSERT(fProxies[i] && fProxies[i]->isInstantiated());
}
}
std::unique_ptr<GrDrawOpAtlas> GrDrawOpAtlas::Make(GrProxyProvider* proxyProvider,
const GrBackendFormat& format,
GrPixelConfig config, int width,
int height, int plotWidth, int plotHeight,
AllowMultitexturing allowMultitexturing,
GrDrawOpAtlas::EvictionFunc func, void* data) {
std::unique_ptr<GrDrawOpAtlas> atlas(new GrDrawOpAtlas(proxyProvider, format, config, width,
height, plotWidth, plotHeight,
allowMultitexturing));
if (!atlas->getProxies()[0]) {
return nullptr;
}
atlas->registerEvictionCallback(func, data);
return atlas;
}
#ifdef DUMP_ATLAS_DATA
static bool gDumpAtlasData = false;
#endif
////////////////////////////////////////////////////////////////////////////////
GrDrawOpAtlas::Plot::Plot(int pageIndex, int plotIndex, uint64_t genID, int offX, int offY,
int width, int height, GrPixelConfig config)
: fLastUpload(GrDeferredUploadToken::AlreadyFlushedToken())
, fLastUse(GrDeferredUploadToken::AlreadyFlushedToken())
, fFlushesSinceLastUse(0)
, fPageIndex(pageIndex)
, fPlotIndex(plotIndex)
, fGenID(genID)
, fID(CreateId(fPageIndex, fPlotIndex, fGenID))
, fData(nullptr)
, fWidth(width)
, fHeight(height)
, fX(offX)
, fY(offY)
, fRects(nullptr)
, fOffset(SkIPoint16::Make(fX * fWidth, fY * fHeight))
, fConfig(config)
, fBytesPerPixel(GrBytesPerPixel(config))
#ifdef SK_DEBUG
, fDirty(false)
#endif
{
// We expect the allocated dimensions to be a multiple of 4 bytes
SkASSERT(((width*fBytesPerPixel) & 0x3) == 0);
// The padding for faster uploads only works for 1, 2 and 4 byte texels
SkASSERT(fBytesPerPixel != 3 && fBytesPerPixel <= 4);
fDirtyRect.setEmpty();
}
GrDrawOpAtlas::Plot::~Plot() {
sk_free(fData);
delete fRects;
}
bool GrDrawOpAtlas::Plot::addSubImage(int width, int height, const void* image, SkIPoint16* loc) {
SkASSERT(width <= fWidth && height <= fHeight);
if (!fRects) {
fRects = GrRectanizer::Factory(fWidth, fHeight);
}
if (!fRects->addRect(width, height, loc)) {
return false;
}
if (!fData) {
fData = reinterpret_cast<unsigned char*>(sk_calloc_throw(fBytesPerPixel * fWidth *
fHeight));
}
size_t rowBytes = width * fBytesPerPixel;
const unsigned char* imagePtr = (const unsigned char*)image;
// point ourselves at the right starting spot
unsigned char* dataPtr = fData;
dataPtr += fBytesPerPixel * fWidth * loc->fY;
dataPtr += fBytesPerPixel * loc->fX;
// copy into the data buffer, swizzling as we go if this is ARGB data
if (4 == fBytesPerPixel && kSkia8888_GrPixelConfig == kBGRA_8888_GrPixelConfig) {
for (int i = 0; i < height; ++i) {
SkOpts::RGBA_to_BGRA((uint32_t*)dataPtr, (const uint32_t*)imagePtr, width);
dataPtr += fBytesPerPixel * fWidth;
imagePtr += rowBytes;
}
} else {
for (int i = 0; i < height; ++i) {
memcpy(dataPtr, imagePtr, rowBytes);
dataPtr += fBytesPerPixel * fWidth;
imagePtr += rowBytes;
}
}
fDirtyRect.join(loc->fX, loc->fY, loc->fX + width, loc->fY + height);
loc->fX += fOffset.fX;
loc->fY += fOffset.fY;
SkDEBUGCODE(fDirty = true;)
return true;
}
void GrDrawOpAtlas::Plot::uploadToTexture(GrDeferredTextureUploadWritePixelsFn& writePixels,
GrTextureProxy* proxy) {
// We should only be issuing uploads if we are in fact dirty
SkASSERT(fDirty && fData && proxy && proxy->peekTexture());
TRACE_EVENT0("skia.gpu", TRACE_FUNC);
size_t rowBytes = fBytesPerPixel * fWidth;
const unsigned char* dataPtr = fData;
// Clamp to 4-byte aligned boundaries
unsigned int clearBits = 0x3 / fBytesPerPixel;
fDirtyRect.fLeft &= ~clearBits;
fDirtyRect.fRight += clearBits;
fDirtyRect.fRight &= ~clearBits;
SkASSERT(fDirtyRect.fRight <= fWidth);
// Set up dataPtr
dataPtr += rowBytes * fDirtyRect.fTop;
dataPtr += fBytesPerPixel * fDirtyRect.fLeft;
// TODO: Make GrDrawOpAtlas store a GrColorType rather than GrPixelConfig.
auto colorType = GrPixelConfigToColorType(fConfig);
writePixels(proxy, fOffset.fX + fDirtyRect.fLeft, fOffset.fY + fDirtyRect.fTop,
fDirtyRect.width(), fDirtyRect.height(), colorType, dataPtr, rowBytes);
fDirtyRect.setEmpty();
SkDEBUGCODE(fDirty = false;)
}
void GrDrawOpAtlas::Plot::resetRects() {
if (fRects) {
fRects->reset();
}
fGenID++;
fID = CreateId(fPageIndex, fPlotIndex, fGenID);
fLastUpload = GrDeferredUploadToken::AlreadyFlushedToken();
fLastUse = GrDeferredUploadToken::AlreadyFlushedToken();
// zero out the plot
if (fData) {
sk_bzero(fData, fBytesPerPixel * fWidth * fHeight);
}
fDirtyRect.setEmpty();
SkDEBUGCODE(fDirty = false;)
}
///////////////////////////////////////////////////////////////////////////////
GrDrawOpAtlas::GrDrawOpAtlas(GrProxyProvider* proxyProvider, const GrBackendFormat& format,
GrPixelConfig config, int width, int height,
int plotWidth, int plotHeight, AllowMultitexturing allowMultitexturing)
: fFormat(format)
, fPixelConfig(config)
, fTextureWidth(width)
, fTextureHeight(height)
, fPlotWidth(plotWidth)
, fPlotHeight(plotHeight)
, fAtlasGeneration(kInvalidAtlasGeneration + 1)
, fPrevFlushToken(GrDeferredUploadToken::AlreadyFlushedToken())
, fMaxPages(AllowMultitexturing::kYes == allowMultitexturing ? kMaxMultitexturePages : 1)
, fNumActivePages(0) {
int numPlotsX = width/plotWidth;
int numPlotsY = height/plotHeight;
SkASSERT(numPlotsX * numPlotsY <= GrDrawOpAtlas::kMaxPlots);
SkASSERT(fPlotWidth * numPlotsX == fTextureWidth);
SkASSERT(fPlotHeight * numPlotsY == fTextureHeight);
fNumPlots = numPlotsX * numPlotsY;
this->createPages(proxyProvider);
}
inline void GrDrawOpAtlas::processEviction(AtlasID id) {
for (int i = 0; i < fEvictionCallbacks.count(); i++) {
(*fEvictionCallbacks[i].fFunc)(id, fEvictionCallbacks[i].fData);
}
++fAtlasGeneration;
}
inline bool GrDrawOpAtlas::updatePlot(GrDeferredUploadTarget* target, AtlasID* id, Plot* plot) {
int pageIdx = GetPageIndexFromID(plot->id());
this->makeMRU(plot, pageIdx);
// If our most recent upload has already occurred then we have to insert a new
// upload. Otherwise, we already have a scheduled upload that hasn't yet ocurred.
// This new update will piggy back on that previously scheduled update.
if (plot->lastUploadToken() < target->tokenTracker()->nextTokenToFlush()) {
// With c+14 we could move sk_sp into lamba to only ref once.
sk_sp<Plot> plotsp(SkRef(plot));
GrTextureProxy* proxy = fProxies[pageIdx].get();
SkASSERT(proxy->isInstantiated()); // This is occurring at flush time
GrDeferredUploadToken lastUploadToken = target->addASAPUpload(
[plotsp, proxy](GrDeferredTextureUploadWritePixelsFn& writePixels) {
plotsp->uploadToTexture(writePixels, proxy);
});
plot->setLastUploadToken(lastUploadToken);
}
*id = plot->id();
return true;
}
bool GrDrawOpAtlas::uploadToPage(unsigned int pageIdx, AtlasID* id, GrDeferredUploadTarget* target,
int width, int height, const void* image, SkIPoint16* loc) {
SkASSERT(fProxies[pageIdx] && fProxies[pageIdx]->isInstantiated());
// look through all allocated plots for one we can share, in Most Recently Refed order
PlotList::Iter plotIter;
plotIter.init(fPages[pageIdx].fPlotList, PlotList::Iter::kHead_IterStart);
for (Plot* plot = plotIter.get(); plot; plot = plotIter.next()) {
SkASSERT(GrBytesPerPixel(fProxies[pageIdx]->config()) == plot->bpp());
if (plot->addSubImage(width, height, image, loc)) {
return this->updatePlot(target, id, plot);
}
}
return false;
}
// Number of atlas-related flushes beyond which we consider a plot to no longer be in use.
//
// This value is somewhat arbitrary -- the idea is to keep it low enough that
// a page with unused plots will get removed reasonably quickly, but allow it
// to hang around for a bit in case it's needed. The assumption is that flushes
// are rare; i.e., we are not continually refreshing the frame.
static constexpr auto kRecentlyUsedCount = 256;
GrDrawOpAtlas::ErrorCode GrDrawOpAtlas::addToAtlas(GrResourceProvider* resourceProvider,
AtlasID* id, GrDeferredUploadTarget* target,
int width, int height,
const void* image, SkIPoint16* loc) {
if (width > fPlotWidth || height > fPlotHeight) {
return ErrorCode::kError;
}
// Look through each page to see if we can upload without having to flush
// We prioritize this upload to the first pages, not the most recently used, to make it easier
// to remove unused pages in reverse page order.
for (unsigned int pageIdx = 0; pageIdx < fNumActivePages; ++pageIdx) {
if (this->uploadToPage(pageIdx, id, target, width, height, image, loc)) {
return ErrorCode::kSucceeded;
}
}
// If the above fails, then see if the least recently used plot per page has already been
// flushed to the gpu if we're at max page allocation, or if the plot has aged out otherwise.
// We wait until we've grown to the full number of pages to begin evicting already flushed
// plots so that we can maximize the opportunity for reuse.
// As before we prioritize this upload to the first pages, not the most recently used.
if (fNumActivePages == this->maxPages()) {
for (unsigned int pageIdx = 0; pageIdx < fNumActivePages; ++pageIdx) {
Plot* plot = fPages[pageIdx].fPlotList.tail();
SkASSERT(plot);
if (plot->lastUseToken() < target->tokenTracker()->nextTokenToFlush()) {
this->processEvictionAndResetRects(plot);
SkASSERT(GrBytesPerPixel(fProxies[pageIdx]->config()) == plot->bpp());
SkDEBUGCODE(bool verify = )plot->addSubImage(width, height, image, loc);
SkASSERT(verify);
if (!this->updatePlot(target, id, plot)) {
return ErrorCode::kError;
}
return ErrorCode::kSucceeded;
}
}
} else {
// If we haven't activated all the available pages, try to create a new one and add to it
if (!this->activateNewPage(resourceProvider)) {
return ErrorCode::kError;
}
if (this->uploadToPage(fNumActivePages-1, id, target, width, height, image, loc)) {
return ErrorCode::kSucceeded;
} else {
// If we fail to upload to a newly activated page then something has gone terribly
// wrong - return an error
return ErrorCode::kError;
}
}
if (!fNumActivePages) {
return ErrorCode::kError;
}
// Try to find a plot that we can perform an inline upload to.
// We prioritize this upload in reverse order of pages to counterbalance the order above.
Plot* plot = nullptr;
for (int pageIdx = ((int)fNumActivePages)-1; pageIdx >= 0; --pageIdx) {
Plot* currentPlot = fPages[pageIdx].fPlotList.tail();
if (currentPlot->lastUseToken() != target->tokenTracker()->nextDrawToken()) {
plot = currentPlot;
break;
}
}
// If we can't find a plot that is not used in a draw currently being prepared by an op, then
// we have to fail. This gives the op a chance to enqueue the draw, and call back into this
// function. When that draw is enqueued, the draw token advances, and the subsequent call will
// continue past this branch and prepare an inline upload that will occur after the enqueued
// draw which references the plot's pre-upload content.
if (!plot) {
return ErrorCode::kTryAgain;
}
this->processEviction(plot->id());
int pageIdx = GetPageIndexFromID(plot->id());
fPages[pageIdx].fPlotList.remove(plot);
sk_sp<Plot>& newPlot = fPages[pageIdx].fPlotArray[plot->index()];
newPlot.reset(plot->clone());
fPages[pageIdx].fPlotList.addToHead(newPlot.get());
SkASSERT(GrBytesPerPixel(fProxies[pageIdx]->config()) == newPlot->bpp());
SkDEBUGCODE(bool verify = )newPlot->addSubImage(width, height, image, loc);
SkASSERT(verify);
// Note that this plot will be uploaded inline with the draws whereas the
// one it displaced most likely was uploaded ASAP.
// With c+14 we could move sk_sp into lambda to only ref once.
sk_sp<Plot> plotsp(SkRef(newPlot.get()));
GrTextureProxy* proxy = fProxies[pageIdx].get();
SkASSERT(proxy->isInstantiated());
GrDeferredUploadToken lastUploadToken = target->addInlineUpload(
[plotsp, proxy](GrDeferredTextureUploadWritePixelsFn& writePixels) {
plotsp->uploadToTexture(writePixels, proxy);
});
newPlot->setLastUploadToken(lastUploadToken);
*id = newPlot->id();
return ErrorCode::kSucceeded;
}
void GrDrawOpAtlas::compact(GrDeferredUploadToken startTokenForNextFlush) {
if (fNumActivePages <= 1) {
fPrevFlushToken = startTokenForNextFlush;
return;
}
// For all plots, reset number of flushes since used if used this frame.
PlotList::Iter plotIter;
bool atlasUsedThisFlush = false;
for (uint32_t pageIndex = 0; pageIndex < fNumActivePages; ++pageIndex) {
plotIter.init(fPages[pageIndex].fPlotList, PlotList::Iter::kHead_IterStart);
while (Plot* plot = plotIter.get()) {
// Reset number of flushes since used
if (plot->lastUseToken().inInterval(fPrevFlushToken, startTokenForNextFlush)) {
plot->resetFlushesSinceLastUsed();
atlasUsedThisFlush = true;
}
plotIter.next();
}
}
// We only try to compact if the atlas was used in the recently completed flush.
// This is to handle the case where a lot of text or path rendering has occurred but then just
// a blinking cursor is drawn.
// TODO: consider if we should also do this if it's been a long time since the last atlas use
if (atlasUsedThisFlush) {
SkTArray<Plot*> availablePlots;
uint32_t lastPageIndex = fNumActivePages - 1;
// For all plots but the last one, update number of flushes since used, and check to see
// if there are any in the first pages that the last page can safely upload to.
for (uint32_t pageIndex = 0; pageIndex < lastPageIndex; ++pageIndex) {
#ifdef DUMP_ATLAS_DATA
if (gDumpAtlasData) {
SkDebugf("page %d: ", pageIndex);
}
#endif
plotIter.init(fPages[pageIndex].fPlotList, PlotList::Iter::kHead_IterStart);
while (Plot* plot = plotIter.get()) {
// Update number of flushes since plot was last used
// We only increment the 'sinceLastUsed' count for flushes where the atlas was used
// to avoid deleting everything when we return to text drawing in the blinking
// cursor case
if (!plot->lastUseToken().inInterval(fPrevFlushToken, startTokenForNextFlush)) {
plot->incFlushesSinceLastUsed();
}
#ifdef DUMP_ATLAS_DATA
if (gDumpAtlasData) {
SkDebugf("%d ", plot->flushesSinceLastUsed());
}
#endif
// Count plots we can potentially upload to in all pages except the last one
// (the potential compactee).
if (plot->flushesSinceLastUsed() > kRecentlyUsedCount) {
availablePlots.push_back() = plot;
}
plotIter.next();
}
#ifdef DUMP_ATLAS_DATA
if (gDumpAtlasData) {
SkDebugf("\n");
}
#endif
}
// Count recently used plots in the last page and evict any that are no longer in use.
// Since we prioritize uploading to the first pages, this will eventually
// clear out usage of this page unless we have a large need.
plotIter.init(fPages[lastPageIndex].fPlotList, PlotList::Iter::kHead_IterStart);
unsigned int usedPlots = 0;
#ifdef DUMP_ATLAS_DATA
if (gDumpAtlasData) {
SkDebugf("page %d: ", lastPageIndex);
}
#endif
while (Plot* plot = plotIter.get()) {
// Update number of flushes since plot was last used
if (!plot->lastUseToken().inInterval(fPrevFlushToken, startTokenForNextFlush)) {
plot->incFlushesSinceLastUsed();
}
#ifdef DUMP_ATLAS_DATA
if (gDumpAtlasData) {
SkDebugf("%d ", plot->flushesSinceLastUsed());
}
#endif
// If this plot was used recently
if (plot->flushesSinceLastUsed() <= kRecentlyUsedCount) {
usedPlots++;
} else if (plot->lastUseToken() != GrDeferredUploadToken::AlreadyFlushedToken()) {
// otherwise if aged out just evict it.
this->processEvictionAndResetRects(plot);
}
plotIter.next();
}
#ifdef DUMP_ATLAS_DATA
if (gDumpAtlasData) {
SkDebugf("\n");
}
#endif
// If recently used plots in the last page are using less than a quarter of the page, try
// to evict them if there's available space in earlier pages. Since we prioritize uploading
// to the first pages, this will eventually clear out usage of this page unless we have a
// large need.
if (availablePlots.count() && usedPlots && usedPlots <= fNumPlots / 4) {
plotIter.init(fPages[lastPageIndex].fPlotList, PlotList::Iter::kHead_IterStart);
while (Plot* plot = plotIter.get()) {
// If this plot was used recently
if (plot->flushesSinceLastUsed() <= kRecentlyUsedCount) {
// See if there's room in an earlier page and if so evict.
// We need to be somewhat harsh here so that a handful of plots that are
// consistently in use don't end up locking the page in memory.
if (availablePlots.count() > 0) {
this->processEvictionAndResetRects(plot);
this->processEvictionAndResetRects(availablePlots.back());
availablePlots.pop_back();
--usedPlots;
}
if (!usedPlots || !availablePlots.count()) {
break;
}
}
plotIter.next();
}
}
// If none of the plots in the last page have been used recently, delete it.
if (!usedPlots) {
#ifdef DUMP_ATLAS_DATA
if (gDumpAtlasData) {
SkDebugf("delete %d\n", fNumPages-1);
}
#endif
this->deactivateLastPage();
}
}
fPrevFlushToken = startTokenForNextFlush;
}
bool GrDrawOpAtlas::createPages(GrProxyProvider* proxyProvider) {
SkASSERT(SkIsPow2(fTextureWidth) && SkIsPow2(fTextureHeight));
GrSurfaceDesc desc;
desc.fFlags = kNone_GrSurfaceFlags;
desc.fWidth = fTextureWidth;
desc.fHeight = fTextureHeight;
desc.fConfig = fPixelConfig;
int numPlotsX = fTextureWidth/fPlotWidth;
int numPlotsY = fTextureHeight/fPlotHeight;
for (uint32_t i = 0; i < this->maxPages(); ++i) {
fProxies[i] = proxyProvider->createProxy(fFormat, desc, kTopLeft_GrSurfaceOrigin,
SkBackingFit::kExact, SkBudgeted::kYes, GrInternalSurfaceFlags::kNoPendingIO);
if (!fProxies[i]) {
return false;
}
// set up allocated plots
fPages[i].fPlotArray.reset(new sk_sp<Plot>[ numPlotsX * numPlotsY ]);
sk_sp<Plot>* currPlot = fPages[i].fPlotArray.get();
for (int y = numPlotsY - 1, r = 0; y >= 0; --y, ++r) {
for (int x = numPlotsX - 1, c = 0; x >= 0; --x, ++c) {
uint32_t plotIndex = r * numPlotsX + c;
currPlot->reset(new Plot(i, plotIndex, 1, x, y, fPlotWidth, fPlotHeight,
fPixelConfig));
// build LRU list
fPages[i].fPlotList.addToHead(currPlot->get());
++currPlot;
}
}
}
return true;
}
bool GrDrawOpAtlas::activateNewPage(GrResourceProvider* resourceProvider) {
SkASSERT(fNumActivePages < this->maxPages());
if (!fProxies[fNumActivePages]->instantiate(resourceProvider)) {
return false;
}
#ifdef DUMP_ATLAS_DATA
if (gDumpAtlasData) {
SkDebugf("activated page#: %d\n", fNumActivePages);
}
#endif
++fNumActivePages;
return true;
}
inline void GrDrawOpAtlas::deactivateLastPage() {
SkASSERT(fNumActivePages);
uint32_t lastPageIndex = fNumActivePages - 1;
int numPlotsX = fTextureWidth/fPlotWidth;
int numPlotsY = fTextureHeight/fPlotHeight;
fPages[lastPageIndex].fPlotList.reset();
for (int r = 0; r < numPlotsY; ++r) {
for (int c = 0; c < numPlotsX; ++c) {
uint32_t plotIndex = r * numPlotsX + c;
Plot* currPlot = fPages[lastPageIndex].fPlotArray[plotIndex].get();
currPlot->resetRects();
currPlot->resetFlushesSinceLastUsed();
// rebuild the LRU list
SkDEBUGCODE(currPlot->fPrev = currPlot->fNext = nullptr);
SkDEBUGCODE(currPlot->fList = nullptr);
fPages[lastPageIndex].fPlotList.addToHead(currPlot);
}
}
// remove ref to the backing texture
fProxies[lastPageIndex]->deinstantiate();
--fNumActivePages;
}
GrDrawOpAtlasConfig::GrDrawOpAtlasConfig(int maxTextureSize, size_t maxBytes) {
static const SkISize kARGBDimensions[] = {
{256, 256}, // maxBytes < 2^19
{512, 256}, // 2^19 <= maxBytes < 2^20
{512, 512}, // 2^20 <= maxBytes < 2^21
{1024, 512}, // 2^21 <= maxBytes < 2^22
{1024, 1024}, // 2^22 <= maxBytes < 2^23
{2048, 1024}, // 2^23 <= maxBytes
};
// Index 0 corresponds to maxBytes of 2^18, so start by dividing it by that
maxBytes >>= 18;
// Take the floor of the log to get the index
int index = maxBytes > 0
? SkTPin<int>(SkPrevLog2(maxBytes), 0, SK_ARRAY_COUNT(kARGBDimensions) - 1)
: 0;
SkASSERT(kARGBDimensions[index].width() <= kMaxAtlasDim);
SkASSERT(kARGBDimensions[index].height() <= kMaxAtlasDim);
fARGBDimensions.set(SkTMin<int>(kARGBDimensions[index].width(), maxTextureSize),
SkTMin<int>(kARGBDimensions[index].height(), maxTextureSize));
fMaxTextureSize = SkTMin<int>(maxTextureSize, kMaxAtlasDim);
}
SkISize GrDrawOpAtlasConfig::atlasDimensions(GrMaskFormat type) const {
if (kA8_GrMaskFormat == type) {
// A8 is always 2x the ARGB dimensions, clamped to the max allowed texture size
return { SkTMin<int>(2 * fARGBDimensions.width(), fMaxTextureSize),
SkTMin<int>(2 * fARGBDimensions.height(), fMaxTextureSize) };
} else {
return fARGBDimensions;
}
}
SkISize GrDrawOpAtlasConfig::plotDimensions(GrMaskFormat type) const {
if (kA8_GrMaskFormat == type) {
SkISize atlasDimensions = this->atlasDimensions(type);
// For A8 we want to grow the plots at larger texture sizes to accept more of the
// larger SDF glyphs. Since the largest SDF glyph can be 170x170 with padding, this
// allows us to pack 3 in a 512x256 plot, or 9 in a 512x512 plot.
// This will give us 512x256 plots for 2048x1024, 512x512 plots for 2048x2048,
// and 256x256 plots otherwise.
int plotWidth = atlasDimensions.width() >= 2048 ? 512 : 256;
int plotHeight = atlasDimensions.height() >= 2048 ? 512 : 256;
return { plotWidth, plotHeight };
} else {
// ARGB and LCD always use 256x256 plots -- this has been shown to be faster
return { 256, 256 };
}
}
constexpr int GrDrawOpAtlasConfig::kMaxAtlasDim;