зеркало из https://github.com/mozilla/gecko-dev.git
684 строки
24 KiB
C++
684 строки
24 KiB
C++
/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
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/* This Source Code Form is subject to the terms of the Mozilla Public
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* License, v. 2.0. If a copy of the MPL was not distributed with this
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* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
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#include "Common.h"
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#include <cstdlib>
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#include "gfxPrefs.h"
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#include "nsDirectoryServiceDefs.h"
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#include "nsIDirectoryService.h"
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#include "nsIFile.h"
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#include "nsIInputStream.h"
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#include "nsIProperties.h"
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#include "nsNetUtil.h"
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#include "mozilla/RefPtr.h"
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#include "nsStreamUtils.h"
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#include "nsString.h"
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namespace mozilla {
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namespace image {
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using namespace gfx;
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using std::abs;
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using std::vector;
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///////////////////////////////////////////////////////////////////////////////
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// General Helpers
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///////////////////////////////////////////////////////////////////////////////
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// These macros work like gtest's ASSERT_* macros, except that they can be used
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// in functions that return values.
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#define ASSERT_TRUE_OR_RETURN(e, rv) \
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EXPECT_TRUE(e); \
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if (!(e)) { \
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return rv; \
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}
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#define ASSERT_EQ_OR_RETURN(a, b, rv) \
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EXPECT_EQ(a, b); \
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if ((a) != (b)) { \
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return rv; \
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}
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#define ASSERT_GE_OR_RETURN(a, b, rv) \
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EXPECT_GE(a, b); \
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if (!((a) >= (b))) { \
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return rv; \
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}
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#define ASSERT_LE_OR_RETURN(a, b, rv) \
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EXPECT_LE(a, b); \
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if (!((a) <= (b))) { \
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return rv; \
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}
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#define ASSERT_LT_OR_RETURN(a, b, rv) \
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EXPECT_LT(a, b); \
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if (!((a) < (b))) { \
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return rv; \
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}
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already_AddRefed<nsIInputStream>
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LoadFile(const char* aRelativePath)
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{
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nsresult rv;
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nsCOMPtr<nsIProperties> dirService =
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do_GetService(NS_DIRECTORY_SERVICE_CONTRACTID);
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ASSERT_TRUE_OR_RETURN(dirService != nullptr, nullptr);
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// Retrieve the current working directory.
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nsCOMPtr<nsIFile> file;
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rv = dirService->Get(NS_OS_CURRENT_WORKING_DIR,
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NS_GET_IID(nsIFile), getter_AddRefs(file));
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ASSERT_TRUE_OR_RETURN(NS_SUCCEEDED(rv), nullptr);
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// Construct the final path by appending the working path to the current
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// working directory.
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file->AppendNative(nsDependentCString(aRelativePath));
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// Construct an input stream for the requested file.
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nsCOMPtr<nsIInputStream> inputStream;
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rv = NS_NewLocalFileInputStream(getter_AddRefs(inputStream), file);
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ASSERT_TRUE_OR_RETURN(NS_SUCCEEDED(rv), nullptr);
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// Ensure the resulting input stream is buffered.
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if (!NS_InputStreamIsBuffered(inputStream)) {
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nsCOMPtr<nsIInputStream> bufStream;
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rv = NS_NewBufferedInputStream(getter_AddRefs(bufStream),
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inputStream, 1024);
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ASSERT_TRUE_OR_RETURN(NS_SUCCEEDED(rv), nullptr);
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inputStream = bufStream;
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}
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return inputStream.forget();
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}
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bool
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IsSolidColor(SourceSurface* aSurface,
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BGRAColor aColor,
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uint8_t aFuzz /* = 0 */)
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{
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IntSize size = aSurface->GetSize();
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return RectIsSolidColor(aSurface, IntRect(0, 0, size.width, size.height),
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aColor, aFuzz);
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}
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bool
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IsSolidPalettedColor(Decoder* aDecoder, uint8_t aColor)
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{
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RawAccessFrameRef currentFrame = aDecoder->GetCurrentFrameRef();
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return PalettedRectIsSolidColor(aDecoder, currentFrame->GetRect(), aColor);
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}
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bool
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RowsAreSolidColor(SourceSurface* aSurface,
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int32_t aStartRow,
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int32_t aRowCount,
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BGRAColor aColor,
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uint8_t aFuzz /* = 0 */)
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{
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IntSize size = aSurface->GetSize();
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return RectIsSolidColor(aSurface, IntRect(0, aStartRow, size.width, aRowCount),
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aColor, aFuzz);
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}
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bool
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PalettedRowsAreSolidColor(Decoder* aDecoder,
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int32_t aStartRow,
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int32_t aRowCount,
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uint8_t aColor)
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{
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RawAccessFrameRef currentFrame = aDecoder->GetCurrentFrameRef();
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IntRect frameRect = currentFrame->GetRect();
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IntRect solidColorRect(frameRect.x, aStartRow, frameRect.width, aRowCount);
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return PalettedRectIsSolidColor(aDecoder, solidColorRect, aColor);
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}
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bool
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RectIsSolidColor(SourceSurface* aSurface,
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const IntRect& aRect,
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BGRAColor aColor,
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uint8_t aFuzz /* = 0 */)
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{
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IntSize surfaceSize = aSurface->GetSize();
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IntRect rect =
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aRect.Intersect(IntRect(0, 0, surfaceSize.width, surfaceSize.height));
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RefPtr<DataSourceSurface> dataSurface = aSurface->GetDataSurface();
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ASSERT_TRUE_OR_RETURN(dataSurface != nullptr, false);
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ASSERT_EQ_OR_RETURN(dataSurface->Stride(), surfaceSize.width * 4, false);
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DataSourceSurface::ScopedMap mapping(dataSurface,
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DataSourceSurface::MapType::READ);
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ASSERT_TRUE_OR_RETURN(mapping.IsMapped(), false);
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uint8_t* data = dataSurface->GetData();
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ASSERT_TRUE_OR_RETURN(data != nullptr, false);
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int32_t rowLength = dataSurface->Stride();
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for (int32_t row = rect.y; row < rect.YMost(); ++row) {
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for (int32_t col = rect.x; col < rect.XMost(); ++col) {
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int32_t i = row * rowLength + col * 4;
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if (aFuzz != 0) {
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ASSERT_LE_OR_RETURN(abs(aColor.mBlue - data[i + 0]), aFuzz, false);
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ASSERT_LE_OR_RETURN(abs(aColor.mGreen - data[i + 1]), aFuzz, false);
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ASSERT_LE_OR_RETURN(abs(aColor.mRed - data[i + 2]), aFuzz, false);
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ASSERT_LE_OR_RETURN(abs(aColor.mAlpha - data[i + 3]), aFuzz, false);
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} else {
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ASSERT_EQ_OR_RETURN(aColor.mBlue, data[i + 0], false);
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ASSERT_EQ_OR_RETURN(aColor.mGreen, data[i + 1], false);
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ASSERT_EQ_OR_RETURN(aColor.mRed, data[i + 2], false);
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ASSERT_EQ_OR_RETURN(aColor.mAlpha, data[i + 3], false);
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}
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}
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}
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return true;
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}
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bool
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PalettedRectIsSolidColor(Decoder* aDecoder, const IntRect& aRect, uint8_t aColor)
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{
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RawAccessFrameRef currentFrame = aDecoder->GetCurrentFrameRef();
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uint8_t* imageData;
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uint32_t imageLength;
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currentFrame->GetImageData(&imageData, &imageLength);
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ASSERT_TRUE_OR_RETURN(imageData, false);
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// Clamp to the frame rect. If any pixels outside the frame rect are included,
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// we immediately fail, because such pixels don't have any "color" in the
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// sense this function measures - they're transparent, and that doesn't
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// necessarily correspond to any color palette index at all.
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IntRect frameRect = currentFrame->GetRect();
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ASSERT_EQ_OR_RETURN(imageLength, uint32_t(frameRect.Area()), false);
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IntRect rect = aRect.Intersect(frameRect);
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ASSERT_EQ_OR_RETURN(rect.Area(), aRect.Area(), false);
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// Translate |rect| by |frameRect.TopLeft()| to reflect the fact that the
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// frame rect's offset doesn't actually mean anything in terms of the
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// in-memory representation of the surface. The image data starts at the upper
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// left corner of the frame rect, in other words.
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rect -= frameRect.TopLeft();
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// Walk through the image data and make sure that the entire rect has the
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// palette index |aColor|.
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int32_t rowLength = frameRect.width;
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for (int32_t row = rect.y; row < rect.YMost(); ++row) {
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for (int32_t col = rect.x; col < rect.XMost(); ++col) {
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int32_t i = row * rowLength + col;
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ASSERT_EQ_OR_RETURN(aColor, imageData[i], false);
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}
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}
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return true;
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}
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bool
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RowHasPixels(SourceSurface* aSurface,
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int32_t aRow,
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const vector<BGRAColor>& aPixels)
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{
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ASSERT_GE_OR_RETURN(aRow, 0, false);
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IntSize surfaceSize = aSurface->GetSize();
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ASSERT_EQ_OR_RETURN(aPixels.size(), size_t(surfaceSize.width), false);
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ASSERT_LT_OR_RETURN(aRow, surfaceSize.height, false);
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RefPtr<DataSourceSurface> dataSurface = aSurface->GetDataSurface();
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ASSERT_TRUE_OR_RETURN(dataSurface, false);
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ASSERT_EQ_OR_RETURN(dataSurface->Stride(), surfaceSize.width * 4, false);
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DataSourceSurface::ScopedMap mapping(dataSurface,
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DataSourceSurface::MapType::READ);
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ASSERT_TRUE_OR_RETURN(mapping.IsMapped(), false);
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uint8_t* data = dataSurface->GetData();
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ASSERT_TRUE_OR_RETURN(data != nullptr, false);
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int32_t rowLength = dataSurface->Stride();
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for (int32_t col = 0; col < surfaceSize.width; ++col) {
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int32_t i = aRow * rowLength + col * 4;
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ASSERT_EQ_OR_RETURN(aPixels[col].mBlue, data[i + 0], false);
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ASSERT_EQ_OR_RETURN(aPixels[col].mGreen, data[i + 1], false);
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ASSERT_EQ_OR_RETURN(aPixels[col].mRed, data[i + 2], false);
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ASSERT_EQ_OR_RETURN(aPixels[col].mAlpha, data[i + 3], false);
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}
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return true;
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}
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///////////////////////////////////////////////////////////////////////////////
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// SurfacePipe Helpers
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///////////////////////////////////////////////////////////////////////////////
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already_AddRefed<Decoder>
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CreateTrivialDecoder()
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{
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gfxPrefs::GetSingleton();
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DecoderType decoderType = DecoderFactory::GetDecoderType("image/gif");
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NotNull<RefPtr<SourceBuffer>> sourceBuffer = WrapNotNull(new SourceBuffer());
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RefPtr<Decoder> decoder =
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DecoderFactory::CreateAnonymousDecoder(decoderType, sourceBuffer, Nothing(),
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DefaultSurfaceFlags());
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return decoder.forget();
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}
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void
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AssertCorrectPipelineFinalState(SurfaceFilter* aFilter,
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const gfx::IntRect& aInputSpaceRect,
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const gfx::IntRect& aOutputSpaceRect)
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{
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EXPECT_TRUE(aFilter->IsSurfaceFinished());
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Maybe<SurfaceInvalidRect> invalidRect = aFilter->TakeInvalidRect();
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EXPECT_TRUE(invalidRect.isSome());
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EXPECT_EQ(aInputSpaceRect, invalidRect->mInputSpaceRect);
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EXPECT_EQ(aOutputSpaceRect, invalidRect->mOutputSpaceRect);
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}
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void
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CheckGeneratedImage(Decoder* aDecoder,
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const IntRect& aRect,
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uint8_t aFuzz /* = 0 */)
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{
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RawAccessFrameRef currentFrame = aDecoder->GetCurrentFrameRef();
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RefPtr<SourceSurface> surface = currentFrame->GetSourceSurface();
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const IntSize surfaceSize = surface->GetSize();
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// This diagram shows how the surface is divided into regions that the code
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// below tests for the correct content. The output rect is the bounds of the
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// region labeled 'C'.
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//
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// +---------------------------+
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// | A |
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// +---------+--------+--------+
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// | B | C | D |
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// +---------+--------+--------+
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// | E |
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// +---------------------------+
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// Check that the output rect itself is green. (Region 'C'.)
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EXPECT_TRUE(RectIsSolidColor(surface, aRect, BGRAColor::Green(), aFuzz));
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// Check that the area above the output rect is transparent. (Region 'A'.)
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EXPECT_TRUE(RectIsSolidColor(surface,
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IntRect(0, 0, surfaceSize.width, aRect.y),
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BGRAColor::Transparent(), aFuzz));
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// Check that the area to the left of the output rect is transparent. (Region 'B'.)
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EXPECT_TRUE(RectIsSolidColor(surface,
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IntRect(0, aRect.y, aRect.x, aRect.YMost()),
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BGRAColor::Transparent(), aFuzz));
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// Check that the area to the right of the output rect is transparent. (Region 'D'.)
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const int32_t widthOnRight = surfaceSize.width - aRect.XMost();
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EXPECT_TRUE(RectIsSolidColor(surface,
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IntRect(aRect.XMost(), aRect.y, widthOnRight, aRect.YMost()),
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BGRAColor::Transparent(), aFuzz));
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// Check that the area below the output rect is transparent. (Region 'E'.)
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const int32_t heightBelow = surfaceSize.height - aRect.YMost();
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EXPECT_TRUE(RectIsSolidColor(surface,
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IntRect(0, aRect.YMost(), surfaceSize.width, heightBelow),
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BGRAColor::Transparent(), aFuzz));
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}
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void
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CheckGeneratedPalettedImage(Decoder* aDecoder, const IntRect& aRect)
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{
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RawAccessFrameRef currentFrame = aDecoder->GetCurrentFrameRef();
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IntSize imageSize = currentFrame->GetImageSize();
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// This diagram shows how the surface is divided into regions that the code
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// below tests for the correct content. The output rect is the bounds of the
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// region labeled 'C'.
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//
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// +---------------------------+
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// | A |
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// +---------+--------+--------+
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// | B | C | D |
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// +---------+--------+--------+
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// | E |
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// +---------------------------+
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// Check that the output rect itself is all 255's. (Region 'C'.)
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EXPECT_TRUE(PalettedRectIsSolidColor(aDecoder, aRect, 255));
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// Check that the area above the output rect is all 0's. (Region 'A'.)
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EXPECT_TRUE(PalettedRectIsSolidColor(aDecoder,
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IntRect(0, 0, imageSize.width, aRect.y),
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0));
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// Check that the area to the left of the output rect is all 0's. (Region 'B'.)
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EXPECT_TRUE(PalettedRectIsSolidColor(aDecoder,
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IntRect(0, aRect.y, aRect.x, aRect.YMost()),
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0));
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// Check that the area to the right of the output rect is all 0's. (Region 'D'.)
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const int32_t widthOnRight = imageSize.width - aRect.XMost();
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EXPECT_TRUE(PalettedRectIsSolidColor(aDecoder,
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IntRect(aRect.XMost(), aRect.y, widthOnRight, aRect.YMost()),
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0));
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// Check that the area below the output rect is transparent. (Region 'E'.)
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const int32_t heightBelow = imageSize.height - aRect.YMost();
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EXPECT_TRUE(PalettedRectIsSolidColor(aDecoder,
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IntRect(0, aRect.YMost(), imageSize.width, heightBelow),
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0));
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}
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void
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CheckWritePixels(Decoder* aDecoder,
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SurfaceFilter* aFilter,
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const Maybe<IntRect>& aOutputRect /* = Nothing() */,
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const Maybe<IntRect>& aInputRect /* = Nothing() */,
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const Maybe<IntRect>& aInputWriteRect /* = Nothing() */,
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const Maybe<IntRect>& aOutputWriteRect /* = Nothing() */,
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uint8_t aFuzz /* = 0 */)
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{
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IntRect outputRect = aOutputRect.valueOr(IntRect(0, 0, 100, 100));
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IntRect inputRect = aInputRect.valueOr(IntRect(0, 0, 100, 100));
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IntRect inputWriteRect = aInputWriteRect.valueOr(inputRect);
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IntRect outputWriteRect = aOutputWriteRect.valueOr(outputRect);
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// Fill the image.
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int32_t count = 0;
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auto result = aFilter->WritePixels<uint32_t>([&] {
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++count;
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return AsVariant(BGRAColor::Green().AsPixel());
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});
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EXPECT_EQ(WriteState::FINISHED, result);
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EXPECT_EQ(inputWriteRect.width * inputWriteRect.height, count);
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AssertCorrectPipelineFinalState(aFilter, inputRect, outputRect);
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// Attempt to write more data and make sure nothing changes.
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const int32_t oldCount = count;
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result = aFilter->WritePixels<uint32_t>([&] {
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++count;
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return AsVariant(BGRAColor::Green().AsPixel());
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});
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EXPECT_EQ(oldCount, count);
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EXPECT_EQ(WriteState::FINISHED, result);
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EXPECT_TRUE(aFilter->IsSurfaceFinished());
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Maybe<SurfaceInvalidRect> invalidRect = aFilter->TakeInvalidRect();
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EXPECT_TRUE(invalidRect.isNothing());
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// Attempt to advance to the next row and make sure nothing changes.
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aFilter->AdvanceRow();
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EXPECT_TRUE(aFilter->IsSurfaceFinished());
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invalidRect = aFilter->TakeInvalidRect();
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EXPECT_TRUE(invalidRect.isNothing());
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// Check that the generated image is correct.
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CheckGeneratedImage(aDecoder, outputWriteRect, aFuzz);
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}
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void
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CheckPalettedWritePixels(Decoder* aDecoder,
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SurfaceFilter* aFilter,
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const Maybe<IntRect>& aOutputRect /* = Nothing() */,
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const Maybe<IntRect>& aInputRect /* = Nothing() */,
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const Maybe<IntRect>& aInputWriteRect /* = Nothing() */,
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const Maybe<IntRect>& aOutputWriteRect /* = Nothing() */,
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uint8_t aFuzz /* = 0 */)
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{
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IntRect outputRect = aOutputRect.valueOr(IntRect(0, 0, 100, 100));
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IntRect inputRect = aInputRect.valueOr(IntRect(0, 0, 100, 100));
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IntRect inputWriteRect = aInputWriteRect.valueOr(inputRect);
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IntRect outputWriteRect = aOutputWriteRect.valueOr(outputRect);
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// Fill the image.
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int32_t count = 0;
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auto result = aFilter->WritePixels<uint8_t>([&] {
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++count;
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return AsVariant(uint8_t(255));
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});
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EXPECT_EQ(WriteState::FINISHED, result);
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EXPECT_EQ(inputWriteRect.width * inputWriteRect.height, count);
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AssertCorrectPipelineFinalState(aFilter, inputRect, outputRect);
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// Attempt to write more data and make sure nothing changes.
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const int32_t oldCount = count;
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result = aFilter->WritePixels<uint8_t>([&] {
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++count;
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return AsVariant(uint8_t(255));
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});
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EXPECT_EQ(oldCount, count);
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EXPECT_EQ(WriteState::FINISHED, result);
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EXPECT_TRUE(aFilter->IsSurfaceFinished());
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Maybe<SurfaceInvalidRect> invalidRect = aFilter->TakeInvalidRect();
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EXPECT_TRUE(invalidRect.isNothing());
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// Attempt to advance to the next row and make sure nothing changes.
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aFilter->AdvanceRow();
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EXPECT_TRUE(aFilter->IsSurfaceFinished());
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invalidRect = aFilter->TakeInvalidRect();
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EXPECT_TRUE(invalidRect.isNothing());
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// Check that the generated image is correct.
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RawAccessFrameRef currentFrame = aDecoder->GetCurrentFrameRef();
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uint8_t* imageData;
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uint32_t imageLength;
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currentFrame->GetImageData(&imageData, &imageLength);
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ASSERT_TRUE(imageData != nullptr);
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ASSERT_EQ(outputWriteRect.width * outputWriteRect.height, int32_t(imageLength));
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|
for (uint32_t i = 0; i < imageLength; ++i) {
|
|
ASSERT_EQ(uint8_t(255), imageData[i]);
|
|
}
|
|
}
|
|
|
|
|
|
///////////////////////////////////////////////////////////////////////////////
|
|
// Test Data
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|
///////////////////////////////////////////////////////////////////////////////
|
|
|
|
ImageTestCase GreenPNGTestCase()
|
|
{
|
|
return ImageTestCase("green.png", "image/png", IntSize(100, 100));
|
|
}
|
|
|
|
ImageTestCase GreenGIFTestCase()
|
|
{
|
|
return ImageTestCase("green.gif", "image/gif", IntSize(100, 100));
|
|
}
|
|
|
|
ImageTestCase GreenJPGTestCase()
|
|
{
|
|
return ImageTestCase("green.jpg", "image/jpeg", IntSize(100, 100),
|
|
TEST_CASE_IS_FUZZY);
|
|
}
|
|
|
|
ImageTestCase GreenBMPTestCase()
|
|
{
|
|
return ImageTestCase("green.bmp", "image/bmp", IntSize(100, 100));
|
|
}
|
|
|
|
ImageTestCase GreenICOTestCase()
|
|
{
|
|
// This ICO contains a 32-bit BMP, and we use a BMP's alpha data by default
|
|
// when the BMP is embedded in an ICO, so it's transparent.
|
|
return ImageTestCase("green.ico", "image/x-icon", IntSize(100, 100),
|
|
TEST_CASE_IS_TRANSPARENT);
|
|
}
|
|
|
|
ImageTestCase GreenIconTestCase()
|
|
{
|
|
return ImageTestCase("green.icon", "image/icon", IntSize(100, 100),
|
|
TEST_CASE_IS_TRANSPARENT);
|
|
}
|
|
|
|
ImageTestCase GreenFirstFrameAnimatedGIFTestCase()
|
|
{
|
|
return ImageTestCase("first-frame-green.gif", "image/gif", IntSize(100, 100),
|
|
TEST_CASE_IS_ANIMATED);
|
|
}
|
|
|
|
ImageTestCase GreenFirstFrameAnimatedPNGTestCase()
|
|
{
|
|
return ImageTestCase("first-frame-green.png", "image/png", IntSize(100, 100),
|
|
TEST_CASE_IS_TRANSPARENT | TEST_CASE_IS_ANIMATED);
|
|
}
|
|
|
|
ImageTestCase CorruptTestCase()
|
|
{
|
|
return ImageTestCase("corrupt.jpg", "image/jpeg", IntSize(100, 100),
|
|
TEST_CASE_HAS_ERROR);
|
|
}
|
|
|
|
ImageTestCase CorruptBMPWithTruncatedHeader()
|
|
{
|
|
// This BMP has a header which is truncated right between the BIH and the
|
|
// bitfields, which is a particularly error-prone place w.r.t. the BMP decoder
|
|
// state machine.
|
|
return ImageTestCase("invalid-truncated-metadata.bmp", "image/bmp",
|
|
IntSize(100, 100), TEST_CASE_HAS_ERROR);
|
|
}
|
|
|
|
ImageTestCase CorruptICOWithBadBMPWidthTestCase()
|
|
{
|
|
// This ICO contains a BMP icon which has a width that doesn't match the size
|
|
// listed in the corresponding ICO directory entry.
|
|
return ImageTestCase("corrupt-with-bad-bmp-width.ico", "image/x-icon",
|
|
IntSize(100, 100), TEST_CASE_HAS_ERROR);
|
|
}
|
|
|
|
ImageTestCase CorruptICOWithBadBMPHeightTestCase()
|
|
{
|
|
// This ICO contains a BMP icon which has a height that doesn't match the size
|
|
// listed in the corresponding ICO directory entry.
|
|
return ImageTestCase("corrupt-with-bad-bmp-height.ico", "image/x-icon",
|
|
IntSize(100, 100), TEST_CASE_HAS_ERROR);
|
|
}
|
|
|
|
ImageTestCase CorruptICOWithBadBppTestCase()
|
|
{
|
|
// This test case is an ICO with a BPP (15) in the ICO header which differs
|
|
// from that in the BMP header itself (1). It should ignore the ICO BPP when
|
|
// the BMP BPP is available and thus correctly decode the image.
|
|
return ImageTestCase("corrupt-with-bad-ico-bpp.ico", "image/x-icon",
|
|
IntSize(100, 100), TEST_CASE_IS_TRANSPARENT);
|
|
}
|
|
|
|
ImageTestCase TransparentPNGTestCase()
|
|
{
|
|
return ImageTestCase("transparent.png", "image/png", IntSize(32, 32),
|
|
TEST_CASE_IS_TRANSPARENT);
|
|
}
|
|
|
|
ImageTestCase TransparentGIFTestCase()
|
|
{
|
|
return ImageTestCase("transparent.gif", "image/gif", IntSize(16, 16),
|
|
TEST_CASE_IS_TRANSPARENT);
|
|
}
|
|
|
|
ImageTestCase FirstFramePaddingGIFTestCase()
|
|
{
|
|
return ImageTestCase("transparent.gif", "image/gif", IntSize(16, 16),
|
|
TEST_CASE_IS_TRANSPARENT);
|
|
}
|
|
|
|
ImageTestCase TransparentIfWithinICOBMPTestCase(TestCaseFlags aFlags)
|
|
{
|
|
// This is a BMP that is only transparent when decoded as if it is within an
|
|
// ICO file. (Note: aFlags needs to be set to TEST_CASE_DEFAULT_FLAGS or
|
|
// TEST_CASE_IS_TRANSPARENT accordingly.)
|
|
return ImageTestCase("transparent-if-within-ico.bmp", "image/bmp",
|
|
IntSize(32, 32), aFlags);
|
|
}
|
|
|
|
ImageTestCase RLE4BMPTestCase()
|
|
{
|
|
return ImageTestCase("rle4.bmp", "image/bmp", IntSize(320, 240),
|
|
TEST_CASE_IS_TRANSPARENT);
|
|
}
|
|
|
|
ImageTestCase RLE8BMPTestCase()
|
|
{
|
|
return ImageTestCase("rle8.bmp", "image/bmp", IntSize(32, 32),
|
|
TEST_CASE_IS_TRANSPARENT);
|
|
}
|
|
|
|
ImageTestCase NoFrameDelayGIFTestCase()
|
|
{
|
|
// This is an invalid (or at least, questionably valid) GIF that's animated
|
|
// even though it specifies a frame delay of zero. It's animated, but it's not
|
|
// marked TEST_CASE_IS_ANIMATED because the metadata decoder can't detect that
|
|
// it's animated.
|
|
return ImageTestCase("no-frame-delay.gif", "image/gif", IntSize(100, 100));
|
|
}
|
|
|
|
ImageTestCase ExtraImageSubBlocksAnimatedGIFTestCase()
|
|
{
|
|
// This is a corrupt GIF that has extra image sub blocks between the first and
|
|
// second frame.
|
|
return ImageTestCase("animated-with-extra-image-sub-blocks.gif", "image/gif",
|
|
IntSize(100, 100));
|
|
}
|
|
|
|
ImageTestCase DownscaledPNGTestCase()
|
|
{
|
|
// This testcase (and all the other "downscaled") testcases) consists of 25
|
|
// lines of green, followed by 25 lines of red, followed by 25 lines of green,
|
|
// followed by 25 more lines of red. It's intended that tests downscale it
|
|
// from 100x100 to 20x20, so we specify a 20x20 output size.
|
|
return ImageTestCase("downscaled.png", "image/png", IntSize(100, 100),
|
|
IntSize(20, 20));
|
|
}
|
|
|
|
ImageTestCase DownscaledGIFTestCase()
|
|
{
|
|
return ImageTestCase("downscaled.gif", "image/gif", IntSize(100, 100),
|
|
IntSize(20, 20));
|
|
}
|
|
|
|
ImageTestCase DownscaledJPGTestCase()
|
|
{
|
|
return ImageTestCase("downscaled.jpg", "image/jpeg", IntSize(100, 100),
|
|
IntSize(20, 20));
|
|
}
|
|
|
|
ImageTestCase DownscaledBMPTestCase()
|
|
{
|
|
return ImageTestCase("downscaled.bmp", "image/bmp", IntSize(100, 100),
|
|
IntSize(20, 20));
|
|
}
|
|
|
|
ImageTestCase DownscaledICOTestCase()
|
|
{
|
|
return ImageTestCase("downscaled.ico", "image/x-icon", IntSize(100, 100),
|
|
IntSize(20, 20), TEST_CASE_IS_TRANSPARENT);
|
|
}
|
|
|
|
ImageTestCase DownscaledIconTestCase()
|
|
{
|
|
return ImageTestCase("downscaled.icon", "image/icon", IntSize(100, 100),
|
|
IntSize(20, 20), TEST_CASE_IS_TRANSPARENT);
|
|
}
|
|
|
|
ImageTestCase DownscaledTransparentICOWithANDMaskTestCase()
|
|
{
|
|
// This test case is an ICO with AND mask transparency. We want to ensure that
|
|
// we can downscale it without crashing or triggering ASAN failures, but its
|
|
// content isn't simple to verify, so for now we don't check the output.
|
|
return ImageTestCase("transparent-ico-with-and-mask.ico", "image/x-icon",
|
|
IntSize(32, 32), IntSize(20, 20),
|
|
TEST_CASE_IS_TRANSPARENT | TEST_CASE_IGNORE_OUTPUT);
|
|
}
|
|
|
|
ImageTestCase TruncatedSmallGIFTestCase()
|
|
{
|
|
return ImageTestCase("green-1x1-truncated.gif", "image/gif", IntSize(1, 1));
|
|
}
|
|
|
|
} // namespace image
|
|
} // namespace mozilla
|