Ejemplo n.º 1
0
void SkBaseDevice::LogDrawScaleFactor(const SkMatrix& matrix, SkFilterQuality filterQuality) {
#if SK_HISTOGRAMS_ENABLED
    enum ScaleFactor {
        kUpscale_ScaleFactor,
        kNoScale_ScaleFactor,
        kDownscale_ScaleFactor,
        kLargeDownscale_ScaleFactor,

        kLast_ScaleFactor = kLargeDownscale_ScaleFactor
    };

    float rawScaleFactor = matrix.getMinScale();

    ScaleFactor scaleFactor;
    if (rawScaleFactor < 0.5f) {
        scaleFactor = kLargeDownscale_ScaleFactor;
    } else if (rawScaleFactor < 1.0f) {
        scaleFactor = kDownscale_ScaleFactor;
    } else if (rawScaleFactor > 1.0f) {
        scaleFactor = kUpscale_ScaleFactor;
    } else {
        scaleFactor = kNoScale_ScaleFactor;
    }

    switch (filterQuality) {
        case kNone_SkFilterQuality:
            SK_HISTOGRAM_ENUMERATION("DrawScaleFactor.NoneFilterQuality", scaleFactor,
                                     kLast_ScaleFactor + 1);
            break;
        case kLow_SkFilterQuality:
            SK_HISTOGRAM_ENUMERATION("DrawScaleFactor.LowFilterQuality", scaleFactor,
                                     kLast_ScaleFactor + 1);
            break;
        case kMedium_SkFilterQuality:
            SK_HISTOGRAM_ENUMERATION("DrawScaleFactor.MediumFilterQuality", scaleFactor,
                                     kLast_ScaleFactor + 1);
            break;
        case kHigh_SkFilterQuality:
            SK_HISTOGRAM_ENUMERATION("DrawScaleFactor.HighFilterQuality", scaleFactor,
                                     kLast_ScaleFactor + 1);
            break;
    }

    // Also log filter quality independent scale factor.
    SK_HISTOGRAM_ENUMERATION("DrawScaleFactor.AnyFilterQuality", scaleFactor,
                             kLast_ScaleFactor + 1);

    // Also log an overall histogram of filter quality.
    SK_HISTOGRAM_ENUMERATION("FilterQuality", filterQuality, kLast_SkFilterQuality + 1);
#endif
}
Ejemplo n.º 2
0
/*
 *  We have a 5 ways to try to return a texture (in sorted order)
 *
 *  1. Check the cache for a pre-existing one
 *  2. Ask the generator to natively create one
 *  3. Ask the generator to return a compressed form that the GPU might support
 *  4. Ask the generator to return YUV planes, which the GPU can convert
 *  5. Ask the generator to return RGB(A) data, which the GPU can convert
 */
GrTexture* SkImageCacherator::lockTexture(GrContext* ctx, const GrUniqueKey& key,
                                          const SkImage* client, SkImage::CachingHint chint) {
    // Values representing the various texture lock paths we can take. Used for logging the path
    // taken to a histogram.
    enum LockTexturePath {
        kFailure_LockTexturePath,
        kPreExisting_LockTexturePath,
        kNative_LockTexturePath,
        kCompressed_LockTexturePath,
        kYUV_LockTexturePath,
        kRGBA_LockTexturePath,
    };

    enum { kLockTexturePathCount = kRGBA_LockTexturePath + 1 };

    // 1. Check the cache for a pre-existing one
    if (key.isValid()) {
        if (GrTexture* tex = ctx->textureProvider()->findAndRefTextureByUniqueKey(key)) {
            SK_HISTOGRAM_ENUMERATION("LockTexturePath", kPreExisting_LockTexturePath,
                                     kLockTexturePathCount);
            return tex;
        }
    }

    // 2. Ask the generator to natively create one
    {
        ScopedGenerator generator(this);
        SkIRect subset = SkIRect::MakeXYWH(fOrigin.x(), fOrigin.y(), fInfo.width(), fInfo.height());
        if (GrTexture* tex = generator->generateTexture(ctx, &subset)) {
            SK_HISTOGRAM_ENUMERATION("LockTexturePath", kNative_LockTexturePath,
                                     kLockTexturePathCount);
            return set_key_and_return(tex, key);
        }
    }

    const GrSurfaceDesc desc = GrImageInfoToSurfaceDesc(fInfo);

    // 3. Ask the generator to return a compressed form that the GPU might support
    SkAutoTUnref<SkData> data(this->refEncoded(ctx));
    if (data) {
        GrTexture* tex = load_compressed_into_texture(ctx, data, desc);
        if (tex) {
            SK_HISTOGRAM_ENUMERATION("LockTexturePath", kCompressed_LockTexturePath,
                                     kLockTexturePathCount);
            return set_key_and_return(tex, key);
        }
    }

    // 4. Ask the generator to return YUV planes, which the GPU can convert
    {
        ScopedGenerator generator(this);
        Generator_GrYUVProvider provider(generator);
        GrTexture* tex = provider.refAsTexture(ctx, desc, true);
        if (tex) {
            SK_HISTOGRAM_ENUMERATION("LockTexturePath", kYUV_LockTexturePath,
                                     kLockTexturePathCount);
            return set_key_and_return(tex, key);
        }
    }

    // 5. Ask the generator to return RGB(A) data, which the GPU can convert
    SkBitmap bitmap;
    if (this->tryLockAsBitmap(&bitmap, client, chint)) {
        GrTexture* tex = GrUploadBitmapToTexture(ctx, bitmap);
        if (tex) {
            SK_HISTOGRAM_ENUMERATION("LockTexturePath", kRGBA_LockTexturePath,
                                     kLockTexturePathCount);
            return set_key_and_return(tex, key);
        }
    }
    SK_HISTOGRAM_ENUMERATION("LockTexturePath", kFailure_LockTexturePath,
                             kLockTexturePathCount);
    return nullptr;
}
Ejemplo n.º 3
0
/*
 *  We have 4 ways to try to return a texture (in sorted order)
 *
 *  1. Check the cache for a pre-existing one
 *  2. Ask the generator to natively create one
 *  3. Ask the generator to return YUV planes, which the GPU can convert
 *  4. Ask the generator to return RGB(A) data, which the GPU can convert
 */
sk_sp<GrTextureProxy> SkImage_Lazy::lockTextureProxy(GrContext* ctx,
                                                     const GrUniqueKey& origKey,
                                                     SkImage::CachingHint chint,
                                                     bool willBeMipped,
                                                     SkColorSpace* dstColorSpace,
                                                     GrTextureMaker::AllowedTexGenType genType) {
    // Values representing the various texture lock paths we can take. Used for logging the path
    // taken to a histogram.
    enum LockTexturePath {
        kFailure_LockTexturePath,
        kPreExisting_LockTexturePath,
        kNative_LockTexturePath,
        kCompressed_LockTexturePath, // Deprecated
        kYUV_LockTexturePath,
        kRGBA_LockTexturePath,
    };

    enum { kLockTexturePathCount = kRGBA_LockTexturePath + 1 };

    // Determine which cached format we're going to use (which may involve decoding to a different
    // info than the generator provides).
    CachedFormat format = this->chooseCacheFormat(dstColorSpace, ctx->caps());

    // Fold the cache format into our texture key
    GrUniqueKey key;
    this->makeCacheKeyFromOrigKey(origKey, format, &key);

    GrProxyProvider* proxyProvider = ctx->contextPriv().proxyProvider();
    sk_sp<GrTextureProxy> proxy;

    // 1. Check the cache for a pre-existing one
    if (key.isValid()) {
        proxy = proxyProvider->findOrCreateProxyByUniqueKey(key, kTopLeft_GrSurfaceOrigin);
        if (proxy) {
            SK_HISTOGRAM_ENUMERATION("LockTexturePath", kPreExisting_LockTexturePath,
                                     kLockTexturePathCount);
            if (!willBeMipped || GrMipMapped::kYes == proxy->mipMapped()) {
                return proxy;
            }
        }
    }

    // The CachedFormat is both an index for which cache "slot" we'll use to store this particular
    // decoded variant of the encoded data, and also a recipe for how to transform the original
    // info to get the one that we're going to decode to.
    const SkImageInfo cacheInfo = this->buildCacheInfo(format);
    SkImageInfo genPixelsInfo = cacheInfo;
    SkTransferFunctionBehavior behavior = getGeneratorBehaviorAndInfo(&genPixelsInfo);

    // 2. Ask the generator to natively create one
    if (!proxy) {
        ScopedGenerator generator(fSharedGenerator);
        if (GrTextureMaker::AllowedTexGenType::kCheap == genType &&
                SkImageGenerator::TexGenType::kCheap != generator->onCanGenerateTexture()) {
            return nullptr;
        }
        if ((proxy = generator->generateTexture(ctx, genPixelsInfo, fOrigin, behavior,
                                                willBeMipped))) {
            SK_HISTOGRAM_ENUMERATION("LockTexturePath", kNative_LockTexturePath,
                                     kLockTexturePathCount);
            set_key_on_proxy(proxyProvider, proxy.get(), nullptr, key);
            if (!willBeMipped || GrMipMapped::kYes == proxy->mipMapped()) {
                return proxy;
            }
        }
    }

    // 3. Ask the generator to return YUV planes, which the GPU can convert. If we will be mipping
    //    the texture we fall through here and have the CPU generate the mip maps for us.
    if (!proxy && !willBeMipped && !ctx->contextPriv().disableGpuYUVConversion()) {
        const GrSurfaceDesc desc = GrImageInfoToSurfaceDesc(cacheInfo, *ctx->caps());
        ScopedGenerator generator(fSharedGenerator);
        Generator_GrYUVProvider provider(generator);

        // The pixels in the texture will be in the generator's color space. If onMakeColorSpace
        // has been called then this will not match this image's color space. To correct this, apply
        // a color space conversion from the generator's color space to this image's color space.
        const SkColorSpace* generatorColorSpace =
                fSharedGenerator->fGenerator->getInfo().colorSpace();
        const SkColorSpace* thisColorSpace = fInfo.colorSpace();

        // TODO: Update to create the mipped surface in the YUV generator and draw the base layer
        // directly into the mipped surface.
        proxy = provider.refAsTextureProxy(ctx, desc, generatorColorSpace, thisColorSpace);
        if (proxy) {
            SK_HISTOGRAM_ENUMERATION("LockTexturePath", kYUV_LockTexturePath,
                                     kLockTexturePathCount);
            set_key_on_proxy(proxyProvider, proxy.get(), nullptr, key);
            return proxy;
        }
    }

    // 4. Ask the generator to return RGB(A) data, which the GPU can convert
    SkBitmap bitmap;
    if (!proxy && this->lockAsBitmap(&bitmap, chint, format, genPixelsInfo, behavior)) {
        if (willBeMipped) {
            proxy = proxyProvider->createMipMapProxyFromBitmap(bitmap, dstColorSpace);
        }
        if (!proxy) {
            proxy = GrUploadBitmapToTextureProxy(proxyProvider, bitmap, dstColorSpace);
        }
        if (proxy && (!willBeMipped || GrMipMapped::kYes == proxy->mipMapped())) {
            SK_HISTOGRAM_ENUMERATION("LockTexturePath", kRGBA_LockTexturePath,
                                     kLockTexturePathCount);
            set_key_on_proxy(proxyProvider, proxy.get(), nullptr, key);
            return proxy;
        }
    }

    if (proxy) {
        // We need a mipped proxy, but we either found a proxy earlier that wasn't mipped, generated
        // a native non mipped proxy, or generated a non-mipped yuv proxy. Thus we generate a new
        // mipped surface and copy the original proxy into the base layer. We will then let the gpu
        // generate the rest of the mips.
        SkASSERT(willBeMipped);
        SkASSERT(GrMipMapped::kNo == proxy->mipMapped());
        if (auto mippedProxy = GrCopyBaseMipMapToTextureProxy(ctx, proxy.get())) {
            set_key_on_proxy(proxyProvider, mippedProxy.get(), proxy.get(), key);
            return mippedProxy;
        }
        // We failed to make a mipped proxy with the base copied into it. This could have
        // been from failure to make the proxy or failure to do the copy. Thus we will fall
        // back to just using the non mipped proxy; See skbug.com/7094.
        return proxy;
    }

    SK_HISTOGRAM_ENUMERATION("LockTexturePath", kFailure_LockTexturePath,
                             kLockTexturePathCount);
    return nullptr;
}