/* * 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 "GrBatchAtlas.h" #include "GrBatchFlushState.h" #include "GrRectanizer.h" #include "GrTracing.h" #include "GrVertexBuffer.h" //////////////////////////////////////////////////////////////////////////////// GrBatchAtlas::BatchPlot::BatchPlot(int index, uint64_t genID, int offX, int offY, int width, int height, GrPixelConfig config) : fLastUpload(0) , fLastUse(0) , fIndex(index) , fGenID(genID) , fID(CreateId(fIndex, 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 { fDirtyRect.setEmpty(); } GrBatchAtlas::BatchPlot::~BatchPlot() { sk_free(fData); delete fRects; } bool GrBatchAtlas::BatchPlot::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(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 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 GrBatchAtlas::BatchPlot::uploadToTexture(GrBatchUploader::TextureUploader* uploader, GrTexture* texture) { // We should only be issuing uploads if we are in fact dirty SkASSERT(fDirty && fData && texture); TRACE_EVENT0(TRACE_DISABLED_BY_DEFAULT("skia.gpu"), "GrBatchPlot::uploadToTexture"); size_t rowBytes = fBytesPerPixel * fWidth; const unsigned char* dataPtr = fData; dataPtr += rowBytes * fDirtyRect.fTop; dataPtr += fBytesPerPixel * fDirtyRect.fLeft; uploader->writeTexturePixels(texture, fOffset.fX + fDirtyRect.fLeft, fOffset.fY + fDirtyRect.fTop, fDirtyRect.width(), fDirtyRect.height(), fConfig, dataPtr, rowBytes); fDirtyRect.setEmpty(); SkDEBUGCODE(fDirty = false;) } void GrBatchAtlas::BatchPlot::resetRects() { if (fRects) { fRects->reset(); } fGenID++; fID = CreateId(fIndex, fGenID); // zero out the plot if (fData) { sk_bzero(fData, fBytesPerPixel * fWidth * fHeight); } fDirtyRect.setEmpty(); SkDEBUGCODE(fDirty = false;) } //////////////////////////////////////////////////////////////////////////////// class GrPlotUploader : public GrBatchUploader { public: GrPlotUploader(GrBatchAtlas::BatchPlot* plot, GrTexture* texture) : INHERITED(plot->lastUploadToken()) , fPlot(SkRef(plot)) , fTexture(texture) { SkASSERT(plot); } void upload(TextureUploader* uploader) override { fPlot->uploadToTexture(uploader, fTexture); } private: SkAutoTUnref fPlot; GrTexture* fTexture; typedef GrBatchUploader INHERITED; }; /////////////////////////////////////////////////////////////////////////////// GrBatchAtlas::GrBatchAtlas(GrTexture* texture, int numPlotsX, int numPlotsY) : fTexture(texture) , fAtlasGeneration(kInvalidAtlasGeneration + 1) { int plotWidth = texture->width() / numPlotsX; int plotHeight = texture->height() / numPlotsY; SkASSERT(numPlotsX * numPlotsY <= BulkUseTokenUpdater::kMaxPlots); SkASSERT(plotWidth * numPlotsX == texture->width()); SkASSERT(plotHeight * numPlotsY == texture->height()); SkDEBUGCODE(fNumPlots = numPlotsX * numPlotsY;) // We currently do not support compressed atlases... SkASSERT(!GrPixelConfigIsCompressed(texture->desc().fConfig)); // set up allocated plots fPlotArray = new SkAutoTUnref[numPlotsX * numPlotsY]; SkAutoTUnref* currPlot = fPlotArray; for (int y = numPlotsY - 1, r = 0; y >= 0; --y, ++r) { for (int x = numPlotsX - 1, c = 0; x >= 0; --x, ++c) { uint32_t index = r * numPlotsX + c; currPlot->reset(new BatchPlot(index, 1, x, y, plotWidth, plotHeight, texture->desc().fConfig)); // build LRU list fPlotList.addToHead(currPlot->get()); ++currPlot; } } } GrBatchAtlas::~GrBatchAtlas() { SkSafeUnref(fTexture); delete[] fPlotArray; } void GrBatchAtlas::processEviction(AtlasID id) { for (int i = 0; i < fEvictionCallbacks.count(); i++) { (*fEvictionCallbacks[i].fFunc)(id, fEvictionCallbacks[i].fData); } } inline void GrBatchAtlas::updatePlot(GrDrawBatch::Target* target, AtlasID* id, BatchPlot* plot) { this->makeMRU(plot); // 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 (target->hasTokenBeenFlushed(plot->lastUploadToken())) { plot->setLastUploadToken(target->asapToken()); SkAutoTUnref uploader(new GrPlotUploader(plot, fTexture)); target->upload(uploader); } *id = plot->id(); } bool GrBatchAtlas::addToAtlas(AtlasID* id, GrDrawBatch::Target* batchTarget, int width, int height, const void* image, SkIPoint16* loc) { // We should already have a texture, TODO clean this up SkASSERT(fTexture); // now look through all allocated plots for one we can share, in Most Recently Refed order GrBatchPlotList::Iter plotIter; plotIter.init(fPlotList, GrBatchPlotList::Iter::kHead_IterStart); BatchPlot* plot; while ((plot = plotIter.get())) { SkASSERT(GrBytesPerPixel(fTexture->desc().fConfig) == plot->bpp()); if (plot->addSubImage(width, height, image, loc)) { this->updatePlot(batchTarget, id, plot); return true; } plotIter.next(); } // If the above fails, then see if the least recently refed plot has already been flushed to the // gpu plot = fPlotList.tail(); SkASSERT(plot); if (batchTarget->hasTokenBeenFlushed(plot->lastUseToken())) { this->processEviction(plot->id()); plot->resetRects(); SkASSERT(GrBytesPerPixel(fTexture->desc().fConfig) == plot->bpp()); SkDEBUGCODE(bool verify = )plot->addSubImage(width, height, image, loc); SkASSERT(verify); this->updatePlot(batchTarget, id, plot); fAtlasGeneration++; return true; } // The least recently used plot hasn't been flushed to the gpu yet, however, if we have flushed // it to the batch target than we can reuse it. Our last use token is guaranteed to be less // than or equal to the current token. If its 'less than' the current token, than we can spin // off the plot (ie let the batch target manage it) and create a new plot in its place in our // array. If it is equal to the currentToken, then the caller has to flush draws to the batch // target so we can spin off the plot if (plot->lastUseToken() == batchTarget->currentToken()) { return false; } SkASSERT(plot->lastUseToken() < batchTarget->currentToken()); SkASSERT(!batchTarget->hasTokenBeenFlushed(batchTarget->currentToken())); SkASSERT(!plot->unique()); // The GrPlotUpdater should have a ref too this->processEviction(plot->id()); fPlotList.remove(plot); SkAutoTUnref& newPlot = fPlotArray[plot->index()]; newPlot.reset(plot->clone()); fPlotList.addToHead(newPlot.get()); SkASSERT(GrBytesPerPixel(fTexture->desc().fConfig) == 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. newPlot->setLastUploadToken(batchTarget->currentToken()); SkAutoTUnref uploader(new GrPlotUploader(newPlot, fTexture)); batchTarget->upload(uploader); *id = newPlot->id(); fAtlasGeneration++; return true; }