gecko-dev/image/test/gtest/TestSurfaceSink.cpp

1492 строки
53 KiB
C++

/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* vim: set ts=8 sts=2 et sw=2 tw=80: */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
#include "gtest/gtest.h"
#include "mozilla/gfx/2D.h"
#include "Common.h"
#include "Decoder.h"
#include "DecoderFactory.h"
#include "SourceBuffer.h"
#include "SurfacePipe.h"
using namespace mozilla;
using namespace mozilla::gfx;
using namespace mozilla::image;
enum class Orient
{
NORMAL,
FLIP_VERTICALLY
};
template <Orient Orientation, typename Func> void
WithSurfaceSink(Func aFunc)
{
RefPtr<Decoder> decoder = CreateTrivialDecoder();
ASSERT_TRUE(decoder != nullptr);
const bool flipVertically = Orientation == Orient::FLIP_VERTICALLY;
WithFilterPipeline(decoder, Forward<Func>(aFunc),
SurfaceConfig { decoder, 0, IntSize(100, 100),
SurfaceFormat::B8G8R8A8, flipVertically });
}
template <typename Func> void
WithPalettedSurfaceSink(const IntRect& aFrameRect, Func aFunc)
{
RefPtr<Decoder> decoder = CreateTrivialDecoder();
ASSERT_TRUE(decoder != nullptr);
WithFilterPipeline(decoder, Forward<Func>(aFunc),
PalettedSurfaceConfig { decoder, 0, IntSize(100, 100),
aFrameRect, SurfaceFormat::B8G8R8A8,
8, false });
}
void
ResetForNextPass(SurfaceFilter* aSink)
{
aSink->ResetToFirstRow();
EXPECT_FALSE(aSink->IsSurfaceFinished());
Maybe<SurfaceInvalidRect> invalidRect = aSink->TakeInvalidRect();
EXPECT_TRUE(invalidRect.isNothing());
}
template <typename WriteFunc, typename CheckFunc> void
DoCheckIterativeWrite(SurfaceFilter* aSink,
WriteFunc aWriteFunc,
CheckFunc aCheckFunc)
{
// Write the buffer to successive rows until every row of the surface
// has been written.
uint32_t row = 0;
WriteState result = WriteState::NEED_MORE_DATA;
while (result == WriteState::NEED_MORE_DATA) {
result = aWriteFunc(row);
++row;
}
EXPECT_EQ(WriteState::FINISHED, result);
EXPECT_EQ(100u, row);
AssertCorrectPipelineFinalState(aSink,
IntRect(0, 0, 100, 100),
IntRect(0, 0, 100, 100));
// Check that the generated image is correct.
aCheckFunc();
}
template <typename WriteFunc> void
CheckIterativeWrite(Decoder* aDecoder,
SurfaceSink* aSink,
const IntRect& aOutputRect,
WriteFunc aWriteFunc)
{
// Ignore the row passed to WriteFunc, since no callers use it.
auto writeFunc = [&](uint32_t) {
return aWriteFunc();
};
DoCheckIterativeWrite(aSink, writeFunc, [&]{
CheckGeneratedImage(aDecoder, aOutputRect);
});
}
template <typename WriteFunc> void
CheckPalettedIterativeWrite(Decoder* aDecoder,
PalettedSurfaceSink* aSink,
const IntRect& aOutputRect,
WriteFunc aWriteFunc)
{
// Ignore the row passed to WriteFunc, since no callers use it.
auto writeFunc = [&](uint32_t) {
return aWriteFunc();
};
DoCheckIterativeWrite(aSink, writeFunc, [&]{
CheckGeneratedPalettedImage(aDecoder, aOutputRect);
});
}
TEST(ImageSurfaceSink, NullSurfaceSink)
{
// Create the NullSurfaceSink.
NullSurfaceSink sink;
nsresult rv = sink.Configure(NullSurfaceConfig { });
ASSERT_TRUE(NS_SUCCEEDED(rv));
EXPECT_TRUE(!sink.IsValidPalettedPipe());
// Ensure that we can't write anything.
bool gotCalled = false;
auto result = sink.WritePixels<uint32_t>([&]() {
gotCalled = true;
return AsVariant(BGRAColor::Green().AsPixel());
});
EXPECT_FALSE(gotCalled);
EXPECT_EQ(WriteState::FINISHED, result);
EXPECT_TRUE(sink.IsSurfaceFinished());
Maybe<SurfaceInvalidRect> invalidRect = sink.TakeInvalidRect();
EXPECT_TRUE(invalidRect.isNothing());
uint32_t source = BGRAColor::Red().AsPixel();
result = sink.WriteBuffer(&source);
EXPECT_EQ(WriteState::FINISHED, result);
EXPECT_TRUE(sink.IsSurfaceFinished());
invalidRect = sink.TakeInvalidRect();
EXPECT_TRUE(invalidRect.isNothing());
result = sink.WriteBuffer(&source, 0, 1);
EXPECT_EQ(WriteState::FINISHED, result);
EXPECT_TRUE(sink.IsSurfaceFinished());
invalidRect = sink.TakeInvalidRect();
EXPECT_TRUE(invalidRect.isNothing());
result = sink.WriteEmptyRow();
EXPECT_EQ(WriteState::FINISHED, result);
EXPECT_TRUE(sink.IsSurfaceFinished());
invalidRect = sink.TakeInvalidRect();
EXPECT_TRUE(invalidRect.isNothing());
result = sink.WriteUnsafeComputedRow<uint32_t>([&](uint32_t* aRow,
uint32_t aLength) {
gotCalled = true;
for (uint32_t col = 0; col < aLength; ++col, ++aRow) {
*aRow = BGRAColor::Red().AsPixel();
}
});
EXPECT_FALSE(gotCalled);
EXPECT_EQ(WriteState::FINISHED, result);
EXPECT_TRUE(sink.IsSurfaceFinished());
invalidRect = sink.TakeInvalidRect();
EXPECT_TRUE(invalidRect.isNothing());
// Attempt to advance to the next row and make sure nothing changes.
sink.AdvanceRow();
EXPECT_TRUE(sink.IsSurfaceFinished());
invalidRect = sink.TakeInvalidRect();
EXPECT_TRUE(invalidRect.isNothing());
// Attempt to advance to the next pass and make sure nothing changes.
sink.ResetToFirstRow();
EXPECT_TRUE(sink.IsSurfaceFinished());
invalidRect = sink.TakeInvalidRect();
EXPECT_TRUE(invalidRect.isNothing());
}
TEST(ImageSurfaceSink, SurfaceSinkInitialization)
{
WithSurfaceSink<Orient::NORMAL>([](Decoder* aDecoder, SurfaceSink* aSink) {
// Check initial state.
EXPECT_FALSE(aSink->IsSurfaceFinished());
Maybe<SurfaceInvalidRect> invalidRect = aSink->TakeInvalidRect();
EXPECT_TRUE(invalidRect.isNothing());
// Check that the surface is zero-initialized. We verify this by calling
// CheckGeneratedImage() and telling it that we didn't write to the surface
// anyway (i.e., we wrote to the empty rect); it will then expect the entire
// surface to be transparent, which is what it should be if it was
// zero-initialied.
CheckGeneratedImage(aDecoder, IntRect(0, 0, 0, 0));
});
}
TEST(ImageSurfaceSink, SurfaceSinkWritePixels)
{
WithSurfaceSink<Orient::NORMAL>([](Decoder* aDecoder, SurfaceSink* aSink) {
CheckWritePixels(aDecoder, aSink);
});
}
TEST(ImageSurfaceSink, SurfaceSinkWritePixelsFinish)
{
WithSurfaceSink<Orient::NORMAL>([](Decoder* aDecoder, SurfaceSink* aSink) {
// Write nothing into the surface; just finish immediately.
uint32_t count = 0;
auto result = aSink->WritePixels<uint32_t>([&]() {
count++;
return AsVariant(WriteState::FINISHED);
});
EXPECT_EQ(WriteState::FINISHED, result);
EXPECT_EQ(1u, count);
AssertCorrectPipelineFinalState(aSink,
IntRect(0, 0, 100, 100),
IntRect(0, 0, 100, 100));
// Attempt to write more and make sure that nothing gets written.
count = 0;
result = aSink->WritePixels<uint32_t>([&]() {
count++;
return AsVariant(BGRAColor::Red().AsPixel());
});
EXPECT_EQ(WriteState::FINISHED, result);
EXPECT_EQ(0u, count);
EXPECT_TRUE(aSink->IsSurfaceFinished());
// Check that the generated image is correct.
RawAccessFrameRef currentFrame = aDecoder->GetCurrentFrameRef();
RefPtr<SourceSurface> surface = currentFrame->GetSurface();
EXPECT_TRUE(IsSolidColor(surface, BGRAColor::Transparent()));
});
}
TEST(ImageSurfaceSink, SurfaceSinkWritePixelsEarlyExit)
{
auto checkEarlyExit =
[](Decoder* aDecoder, SurfaceSink* aSink, WriteState aState) {
// Write half a row of green pixels and then exit early with |aState|. If
// the lambda keeps getting called, we'll write red pixels, which will cause
// the test to fail.
uint32_t count = 0;
auto result = aSink->WritePixels<uint32_t>([&]() -> NextPixel<uint32_t> {
if (count == 50) {
return AsVariant(aState);
}
return count++ < 50 ? AsVariant(BGRAColor::Green().AsPixel())
: AsVariant(BGRAColor::Red().AsPixel());
});
EXPECT_EQ(aState, result);
EXPECT_EQ(50u, count);
CheckGeneratedImage(aDecoder, IntRect(0, 0, 50, 1));
if (aState != WriteState::FINISHED) {
// We should still be able to write more at this point.
EXPECT_FALSE(aSink->IsSurfaceFinished());
// Verify that we can resume writing. We'll finish up the same row.
count = 0;
result = aSink->WritePixels<uint32_t>([&]() -> NextPixel<uint32_t> {
if (count == 50) {
return AsVariant(WriteState::NEED_MORE_DATA);
}
++count;
return AsVariant(BGRAColor::Green().AsPixel());
});
EXPECT_EQ(WriteState::NEED_MORE_DATA, result);
EXPECT_EQ(50u, count);
EXPECT_FALSE(aSink->IsSurfaceFinished());
CheckGeneratedImage(aDecoder, IntRect(0, 0, 100, 1));
return;
}
// We should've finished the surface at this point.
AssertCorrectPipelineFinalState(aSink,
IntRect(0, 0, 100, 100),
IntRect(0, 0, 100, 100));
// Attempt to write more and make sure that nothing gets written.
count = 0;
result = aSink->WritePixels<uint32_t>([&]{
count++;
return AsVariant(BGRAColor::Red().AsPixel());
});
EXPECT_EQ(WriteState::FINISHED, result);
EXPECT_EQ(0u, count);
EXPECT_TRUE(aSink->IsSurfaceFinished());
// Check that the generated image is still correct.
CheckGeneratedImage(aDecoder, IntRect(0, 0, 50, 1));
};
WithSurfaceSink<Orient::NORMAL>([&](Decoder* aDecoder, SurfaceSink* aSink) {
checkEarlyExit(aDecoder, aSink, WriteState::NEED_MORE_DATA);
});
WithSurfaceSink<Orient::NORMAL>([&](Decoder* aDecoder, SurfaceSink* aSink) {
checkEarlyExit(aDecoder, aSink, WriteState::FAILURE);
});
WithSurfaceSink<Orient::NORMAL>([&](Decoder* aDecoder, SurfaceSink* aSink) {
checkEarlyExit(aDecoder, aSink, WriteState::FINISHED);
});
}
TEST(ImageSurfaceSink, SurfaceSinkWritePixelsToRow)
{
WithSurfaceSink<Orient::NORMAL>([](Decoder* aDecoder, SurfaceSink* aSink) {
// Write the first 99 rows of our 100x100 surface and verify that even
// though our lambda will yield pixels forever, only one row is written per
// call to WritePixelsToRow().
for (int row = 0; row < 99; ++row) {
uint32_t count = 0;
WriteState result = aSink->WritePixelsToRow<uint32_t>([&]{
++count;
return AsVariant(BGRAColor::Green().AsPixel());
});
EXPECT_EQ(WriteState::NEED_MORE_DATA, result);
EXPECT_EQ(100u, count);
EXPECT_FALSE(aSink->IsSurfaceFinished());
Maybe<SurfaceInvalidRect> invalidRect = aSink->TakeInvalidRect();
EXPECT_TRUE(invalidRect.isSome());
EXPECT_EQ(IntRect(0, row, 100, 1), invalidRect->mInputSpaceRect);
EXPECT_EQ(IntRect(0, row, 100, 1), invalidRect->mOutputSpaceRect);
CheckGeneratedImage(aDecoder, IntRect(0, 0, 100, row + 1));
}
// Write the final line, which should finish the surface.
uint32_t count = 0;
WriteState result = aSink->WritePixelsToRow<uint32_t>([&]{
++count;
return AsVariant(BGRAColor::Green().AsPixel());
});
EXPECT_EQ(WriteState::FINISHED, result);
EXPECT_EQ(100u, count);
// Note that the final invalid rect we expect here is only the last row;
// that's because we called TakeInvalidRect() repeatedly in the loop above.
AssertCorrectPipelineFinalState(aSink,
IntRect(0, 99, 100, 1),
IntRect(0, 99, 100, 1));
// Check that the generated image is correct.
CheckGeneratedImage(aDecoder, IntRect(0, 0, 100, 100));
// Attempt to write more and make sure that nothing gets written.
count = 0;
result = aSink->WritePixelsToRow<uint32_t>([&]{
count++;
return AsVariant(BGRAColor::Red().AsPixel());
});
EXPECT_EQ(WriteState::FINISHED, result);
EXPECT_EQ(0u, count);
EXPECT_TRUE(aSink->IsSurfaceFinished());
// Check that the generated image is still correct.
CheckGeneratedImage(aDecoder, IntRect(0, 0, 100, 100));
});
}
TEST(ImageSurfaceSink, SurfaceSinkWritePixelsToRowEarlyExit)
{
auto checkEarlyExit =
[](Decoder* aDecoder, SurfaceSink* aSink, WriteState aState) {
// Write half a row of green pixels and then exit early with |aState|. If
// the lambda keeps getting called, we'll write red pixels, which will cause
// the test to fail.
uint32_t count = 0;
auto result = aSink->WritePixelsToRow<uint32_t>([&]() -> NextPixel<uint32_t> {
if (count == 50) {
return AsVariant(aState);
}
return count++ < 50 ? AsVariant(BGRAColor::Green().AsPixel())
: AsVariant(BGRAColor::Red().AsPixel());
});
EXPECT_EQ(aState, result);
EXPECT_EQ(50u, count);
CheckGeneratedImage(aDecoder, IntRect(0, 0, 50, 1));
if (aState != WriteState::FINISHED) {
// We should still be able to write more at this point.
EXPECT_FALSE(aSink->IsSurfaceFinished());
// Verify that we can resume the same row and still stop at the end.
count = 0;
WriteState result = aSink->WritePixelsToRow<uint32_t>([&]{
++count;
return AsVariant(BGRAColor::Green().AsPixel());
});
EXPECT_EQ(WriteState::NEED_MORE_DATA, result);
EXPECT_EQ(50u, count);
EXPECT_FALSE(aSink->IsSurfaceFinished());
CheckGeneratedImage(aDecoder, IntRect(0, 0, 100, 1));
return;
}
// We should've finished the surface at this point.
AssertCorrectPipelineFinalState(aSink,
IntRect(0, 0, 100, 100),
IntRect(0, 0, 100, 100));
// Attempt to write more and make sure that nothing gets written.
count = 0;
result = aSink->WritePixelsToRow<uint32_t>([&]{
count++;
return AsVariant(BGRAColor::Red().AsPixel());
});
EXPECT_EQ(WriteState::FINISHED, result);
EXPECT_EQ(0u, count);
EXPECT_TRUE(aSink->IsSurfaceFinished());
// Check that the generated image is still correct.
CheckGeneratedImage(aDecoder, IntRect(0, 0, 50, 1));
};
WithSurfaceSink<Orient::NORMAL>([&](Decoder* aDecoder, SurfaceSink* aSink) {
checkEarlyExit(aDecoder, aSink, WriteState::NEED_MORE_DATA);
});
WithSurfaceSink<Orient::NORMAL>([&](Decoder* aDecoder, SurfaceSink* aSink) {
checkEarlyExit(aDecoder, aSink, WriteState::FAILURE);
});
WithSurfaceSink<Orient::NORMAL>([&](Decoder* aDecoder, SurfaceSink* aSink) {
checkEarlyExit(aDecoder, aSink, WriteState::FINISHED);
});
}
TEST(ImageSurfaceSink, SurfaceSinkWriteBuffer)
{
WithSurfaceSink<Orient::NORMAL>([](Decoder* aDecoder, SurfaceSink* aSink) {
// Create a green buffer the same size as one row of the surface (which is 100x100),
// containing 60 pixels of green in the middle and 20 transparent pixels on
// either side.
uint32_t buffer[100];
for (int i = 0; i < 100; ++i) {
buffer[i] = 20 <= i && i < 80 ? BGRAColor::Green().AsPixel()
: BGRAColor::Transparent().AsPixel();
}
// Write the buffer to every row of the surface and check that the generated
// image is correct.
CheckIterativeWrite(aDecoder, aSink, IntRect(20, 0, 60, 100), [&]{
return aSink->WriteBuffer(buffer);
});
});
}
TEST(ImageSurfaceSink, SurfaceSinkWriteBufferPartialRow)
{
WithSurfaceSink<Orient::NORMAL>([](Decoder* aDecoder, SurfaceSink* aSink) {
// Create a buffer the same size as one row of the surface, containing all
// green pixels.
uint32_t buffer[100];
for (int i = 0; i < 100; ++i) {
buffer[i] = BGRAColor::Green().AsPixel();
}
// Write the buffer to the middle 60 pixels of every row of the surface and
// check that the generated image is correct.
CheckIterativeWrite(aDecoder, aSink, IntRect(20, 0, 60, 100), [&]{
return aSink->WriteBuffer(buffer, 20, 60);
});
});
}
TEST(ImageSurfaceSink, SurfaceSinkWriteBufferPartialRowStartColOverflow)
{
WithSurfaceSink<Orient::NORMAL>([](Decoder* aDecoder, SurfaceSink* aSink) {
// Create a buffer the same size as one row of the surface, containing all
// green pixels.
uint32_t buffer[100];
for (int i = 0; i < 100; ++i) {
buffer[i] = BGRAColor::Green().AsPixel();
}
{
// Write the buffer to successive rows until every row of the surface
// has been written. We place the start column beyond the end of the row,
// which will prevent us from writing anything, so we check that the
// generated image is entirely transparent.
CheckIterativeWrite(aDecoder, aSink, IntRect(0, 0, 0, 0), [&]{
return aSink->WriteBuffer(buffer, 100, 100);
});
}
ResetForNextPass(aSink);
{
// Write the buffer to successive rows until every row of the surface
// has been written. We use column 50 as the start column, but we still
// write the buffer, which means we overflow the right edge of the surface
// by 50 pixels. We check that the left half of the generated image is
// transparent and the right half is green.
CheckIterativeWrite(aDecoder, aSink, IntRect(50, 0, 50, 100), [&]{
return aSink->WriteBuffer(buffer, 50, 100);
});
}
});
}
TEST(ImageSurfaceSink, SurfaceSinkWriteBufferPartialRowBufferOverflow)
{
WithSurfaceSink<Orient::NORMAL>([](Decoder* aDecoder, SurfaceSink* aSink) {
// Create a buffer twice as large as a row of the surface. The first half
// (which is as large as a row of the image) will contain green pixels,
// while the second half will contain red pixels.
uint32_t buffer[200];
for (int i = 0; i < 200; ++i) {
buffer[i] = i < 100 ? BGRAColor::Green().AsPixel()
: BGRAColor::Red().AsPixel();
}
{
// Write the buffer to successive rows until every row of the surface has
// been written. The buffer extends 100 pixels to the right of a row of
// the surface, but bounds checking will prevent us from overflowing the
// buffer. We check that the generated image is entirely green since the
// pixels on the right side of the buffer shouldn't have been written to
// the surface.
CheckIterativeWrite(aDecoder, aSink, IntRect(0, 0, 100, 100), [&]{
return aSink->WriteBuffer(buffer, 0, 200);
});
}
ResetForNextPass(aSink);
{
// Write from the buffer to the middle of each row of the surface. That
// means that the left side of each row should be transparent, since we
// didn't write anything there. A buffer overflow would cause us to write
// buffer contents into the left side of each row. We check that the
// generated image is transparent on the left side and green on the right.
CheckIterativeWrite(aDecoder, aSink, IntRect(50, 0, 50, 100), [&]{
return aSink->WriteBuffer(buffer, 50, 200);
});
}
});
}
TEST(ImageSurfaceSink, SurfaceSinkWriteBufferFromNullSource)
{
WithSurfaceSink<Orient::NORMAL>([](Decoder* aDecoder, SurfaceSink* aSink) {
// Calling WriteBuffer() with a null pointer should fail without making any
// changes to the surface.
uint32_t* nullBuffer = nullptr;
WriteState result = aSink->WriteBuffer(nullBuffer);
EXPECT_EQ(WriteState::FAILURE, result);
EXPECT_FALSE(aSink->IsSurfaceFinished());
Maybe<SurfaceInvalidRect> invalidRect = aSink->TakeInvalidRect();
EXPECT_TRUE(invalidRect.isNothing());
// Check that nothing got written to the surface.
CheckGeneratedImage(aDecoder, IntRect(0, 0, 0, 0));
});
}
TEST(ImageSurfaceSink, SurfaceSinkWriteEmptyRow)
{
WithSurfaceSink<Orient::NORMAL>([](Decoder* aDecoder, SurfaceSink* aSink) {
{
// Write an empty row to each row of the surface. We check that the
// generated image is entirely transparent.
CheckIterativeWrite(aDecoder, aSink, IntRect(0, 0, 0, 0), [&]{
return aSink->WriteEmptyRow();
});
}
ResetForNextPass(aSink);
{
// Write a partial row before we begin calling WriteEmptyRow(). We check
// that the generated image is entirely transparent, which is to be
// expected since WriteEmptyRow() overwrites the current row even if some
// data has already been written to it.
uint32_t count = 0;
auto result = aSink->WritePixels<uint32_t>([&]() -> NextPixel<uint32_t> {
if (count == 50) {
return AsVariant(WriteState::NEED_MORE_DATA);
}
++count;
return AsVariant(BGRAColor::Green().AsPixel());
});
EXPECT_EQ(WriteState::NEED_MORE_DATA, result);
EXPECT_EQ(50u, count);
EXPECT_FALSE(aSink->IsSurfaceFinished());
CheckIterativeWrite(aDecoder, aSink, IntRect(0, 0, 0, 0), [&]{
return aSink->WriteEmptyRow();
});
}
ResetForNextPass(aSink);
{
// Create a buffer the same size as one row of the surface, containing all
// green pixels.
uint32_t buffer[100];
for (int i = 0; i < 100; ++i) {
buffer[i] = BGRAColor::Green().AsPixel();
}
// Write an empty row to the middle 60 rows of the surface. The first 20
// and last 20 rows will be green. (We need to use DoCheckIterativeWrite()
// here because we need a custom function to check the output, since it
// can't be described by a simple rect.)
auto writeFunc = [&](uint32_t aRow) {
if (aRow < 20 || aRow >= 80) {
return aSink->WriteBuffer(buffer);
} else {
return aSink->WriteEmptyRow();
}
};
auto checkFunc = [&]{
RawAccessFrameRef currentFrame = aDecoder->GetCurrentFrameRef();
RefPtr<SourceSurface> surface = currentFrame->GetSurface();
EXPECT_TRUE(RowsAreSolidColor(surface, 0, 20, BGRAColor::Green()));
EXPECT_TRUE(RowsAreSolidColor(surface, 20, 60, BGRAColor::Transparent()));
EXPECT_TRUE(RowsAreSolidColor(surface, 80, 20, BGRAColor::Green()));
};
DoCheckIterativeWrite(aSink, writeFunc, checkFunc);
}
});
}
TEST(ImageSurfaceSink, SurfaceSinkWriteUnsafeComputedRow)
{
WithSurfaceSink<Orient::NORMAL>([](Decoder* aDecoder, SurfaceSink* aSink) {
// Create a green buffer the same size as one row of the surface.
uint32_t buffer[100];
for (int i = 0; i < 100; ++i) {
buffer[i] = BGRAColor::Green().AsPixel();
}
// Write the buffer to successive rows until every row of the surface
// has been written. We only write to the right half of each row, so we
// check that the left side of the generated image is transparent and the
// right side is green.
CheckIterativeWrite(aDecoder, aSink, IntRect(50, 0, 50, 100), [&]{
return aSink->WriteUnsafeComputedRow<uint32_t>([&](uint32_t* aRow,
uint32_t aLength) {
EXPECT_EQ(100u, aLength );
memcpy(aRow + 50, buffer, 50 * sizeof(uint32_t));
});
});
});
}
TEST(ImageSurfaceSink, SurfaceSinkProgressivePasses)
{
WithSurfaceSink<Orient::NORMAL>([](Decoder* aDecoder, SurfaceSink* aSink) {
{
// Fill the image with a first pass of red.
uint32_t count = 0;
auto result = aSink->WritePixels<uint32_t>([&]() {
++count;
return AsVariant(BGRAColor::Red().AsPixel());
});
EXPECT_EQ(WriteState::FINISHED, result);
EXPECT_EQ(100u * 100u, count);
AssertCorrectPipelineFinalState(aSink,
IntRect(0, 0, 100, 100),
IntRect(0, 0, 100, 100));
// Check that the generated image is correct.
RawAccessFrameRef currentFrame = aDecoder->GetCurrentFrameRef();
RefPtr<SourceSurface> surface = currentFrame->GetSurface();
EXPECT_TRUE(IsSolidColor(surface, BGRAColor::Red()));
}
{
ResetForNextPass(aSink);
// Check that the generated image is still the first pass image.
RawAccessFrameRef currentFrame = aDecoder->GetCurrentFrameRef();
RefPtr<SourceSurface> surface = currentFrame->GetSurface();
EXPECT_TRUE(IsSolidColor(surface, BGRAColor::Red()));
}
{
// Fill the image with a second pass of green.
uint32_t count = 0;
auto result = aSink->WritePixels<uint32_t>([&]() {
++count;
return AsVariant(BGRAColor::Green().AsPixel());
});
EXPECT_EQ(WriteState::FINISHED, result);
EXPECT_EQ(100u * 100u, count);
AssertCorrectPipelineFinalState(aSink,
IntRect(0, 0, 100, 100),
IntRect(0, 0, 100, 100));
// Check that the generated image is correct.
RawAccessFrameRef currentFrame = aDecoder->GetCurrentFrameRef();
RefPtr<SourceSurface> surface = currentFrame->GetSurface();
EXPECT_TRUE(IsSolidColor(surface, BGRAColor::Green()));
}
});
}
TEST(ImageSurfaceSink, SurfaceSinkInvalidRect)
{
WithSurfaceSink<Orient::NORMAL>([](Decoder* aDecoder, SurfaceSink* aSink) {
{
// Write one row.
uint32_t count = 0;
auto result = aSink->WritePixels<uint32_t>([&]() -> NextPixel<uint32_t> {
if (count == 100) {
return AsVariant(WriteState::NEED_MORE_DATA);
}
count++;
return AsVariant(BGRAColor::Green().AsPixel());
});
EXPECT_EQ(WriteState::NEED_MORE_DATA, result);
EXPECT_EQ(100u, count);
EXPECT_FALSE(aSink->IsSurfaceFinished());
// Assert that we have the right invalid rect.
Maybe<SurfaceInvalidRect> invalidRect = aSink->TakeInvalidRect();
EXPECT_TRUE(invalidRect.isSome());
EXPECT_EQ(IntRect(0, 0, 100, 1), invalidRect->mInputSpaceRect);
EXPECT_EQ(IntRect(0, 0, 100, 1), invalidRect->mOutputSpaceRect);
}
{
// Write eight rows.
uint32_t count = 0;
auto result = aSink->WritePixels<uint32_t>([&]() -> NextPixel<uint32_t> {
if (count == 100 * 8) {
return AsVariant(WriteState::NEED_MORE_DATA);
}
count++;
return AsVariant(BGRAColor::Green().AsPixel());
});
EXPECT_EQ(WriteState::NEED_MORE_DATA, result);
EXPECT_EQ(100u * 8u, count);
EXPECT_FALSE(aSink->IsSurfaceFinished());
// Assert that we have the right invalid rect.
Maybe<SurfaceInvalidRect> invalidRect = aSink->TakeInvalidRect();
EXPECT_TRUE(invalidRect.isSome());
EXPECT_EQ(IntRect(0, 1, 100, 8), invalidRect->mInputSpaceRect);
EXPECT_EQ(IntRect(0, 1, 100, 8), invalidRect->mOutputSpaceRect);
}
{
// Write the left half of one row.
uint32_t count = 0;
auto result = aSink->WritePixels<uint32_t>([&]() -> NextPixel<uint32_t> {
if (count == 50) {
return AsVariant(WriteState::NEED_MORE_DATA);
}
count++;
return AsVariant(BGRAColor::Green().AsPixel());
});
EXPECT_EQ(WriteState::NEED_MORE_DATA, result);
EXPECT_EQ(50u, count);
EXPECT_FALSE(aSink->IsSurfaceFinished());
// Assert that we don't have an invalid rect, since the invalid rect only
// gets updated when a row gets completed.
Maybe<SurfaceInvalidRect> invalidRect = aSink->TakeInvalidRect();
EXPECT_TRUE(invalidRect.isNothing());
}
{
// Write the right half of the same row.
uint32_t count = 0;
auto result = aSink->WritePixels<uint32_t>([&]() -> NextPixel<uint32_t> {
if (count == 50) {
return AsVariant(WriteState::NEED_MORE_DATA);
}
count++;
return AsVariant(BGRAColor::Green().AsPixel());
});
EXPECT_EQ(WriteState::NEED_MORE_DATA, result);
EXPECT_EQ(50u, count);
EXPECT_FALSE(aSink->IsSurfaceFinished());
// Assert that we have the right invalid rect, which will include both the
// left and right halves of this row now that we've completed it.
Maybe<SurfaceInvalidRect> invalidRect = aSink->TakeInvalidRect();
EXPECT_TRUE(invalidRect.isSome());
EXPECT_EQ(IntRect(0, 9, 100, 1), invalidRect->mInputSpaceRect);
EXPECT_EQ(IntRect(0, 9, 100, 1), invalidRect->mOutputSpaceRect);
}
{
// Write no rows.
auto result = aSink->WritePixels<uint32_t>([&]() {
return AsVariant(WriteState::NEED_MORE_DATA);
});
EXPECT_EQ(WriteState::NEED_MORE_DATA, result);
EXPECT_FALSE(aSink->IsSurfaceFinished());
// Assert that we don't have an invalid rect.
Maybe<SurfaceInvalidRect> invalidRect = aSink->TakeInvalidRect();
EXPECT_TRUE(invalidRect.isNothing());
}
{
// Fill the rest of the image.
uint32_t count = 0;
auto result = aSink->WritePixels<uint32_t>([&]() {
count++;
return AsVariant(BGRAColor::Green().AsPixel());
});
EXPECT_EQ(WriteState::FINISHED, result);
EXPECT_EQ(100u * 90u, count);
EXPECT_TRUE(aSink->IsSurfaceFinished());
// Assert that we have the right invalid rect.
Maybe<SurfaceInvalidRect> invalidRect = aSink->TakeInvalidRect();
EXPECT_TRUE(invalidRect.isSome());
EXPECT_EQ(IntRect(0, 10, 100, 90), invalidRect->mInputSpaceRect);
EXPECT_EQ(IntRect(0, 10, 100, 90), invalidRect->mOutputSpaceRect);
// Check that the generated image is correct.
RawAccessFrameRef currentFrame = aDecoder->GetCurrentFrameRef();
RefPtr<SourceSurface> surface = currentFrame->GetSurface();
EXPECT_TRUE(IsSolidColor(surface, BGRAColor::Green()));
}
});
}
TEST(ImageSurfaceSink, SurfaceSinkFlipVertically)
{
WithSurfaceSink<Orient::FLIP_VERTICALLY>([](Decoder* aDecoder,
SurfaceSink* aSink) {
{
// Fill the image with a first pass of red.
uint32_t count = 0;
auto result = aSink->WritePixels<uint32_t>([&]() {
++count;
return AsVariant(BGRAColor::Red().AsPixel());
});
EXPECT_EQ(WriteState::FINISHED, result);
EXPECT_EQ(100u * 100u, count);
AssertCorrectPipelineFinalState(aSink,
IntRect(0, 0, 100, 100),
IntRect(0, 0, 100, 100));
// Check that the generated image is correct.
RawAccessFrameRef currentFrame = aDecoder->GetCurrentFrameRef();
RefPtr<SourceSurface> surface = currentFrame->GetSurface();
EXPECT_TRUE(IsSolidColor(surface, BGRAColor::Red()));
}
{
ResetForNextPass(aSink);
// Check that the generated image is still the first pass image.
RawAccessFrameRef currentFrame = aDecoder->GetCurrentFrameRef();
RefPtr<SourceSurface> surface = currentFrame->GetSurface();
EXPECT_TRUE(IsSolidColor(surface, BGRAColor::Red()));
}
{
// Fill 25 rows of the image with green and make sure everything is OK.
uint32_t count = 0;
auto result = aSink->WritePixels<uint32_t>([&]() -> NextPixel<uint32_t> {
if (count == 25 * 100) {
return AsVariant(WriteState::NEED_MORE_DATA);
}
count++;
return AsVariant(BGRAColor::Green().AsPixel());
});
EXPECT_EQ(WriteState::NEED_MORE_DATA, result);
EXPECT_EQ(25u * 100u, count);
EXPECT_FALSE(aSink->IsSurfaceFinished());
// Assert that we have the right invalid rect, which should include the
// *bottom* (since we're flipping vertically) 25 rows of the image.
Maybe<SurfaceInvalidRect> invalidRect = aSink->TakeInvalidRect();
EXPECT_TRUE(invalidRect.isSome());
EXPECT_EQ(IntRect(0, 75, 100, 25), invalidRect->mInputSpaceRect);
EXPECT_EQ(IntRect(0, 75, 100, 25), invalidRect->mOutputSpaceRect);
// Check that the generated image is correct.
RawAccessFrameRef currentFrame = aDecoder->GetCurrentFrameRef();
RefPtr<SourceSurface> surface = currentFrame->GetSurface();
EXPECT_TRUE(RowsAreSolidColor(surface, 0, 75, BGRAColor::Red()));
EXPECT_TRUE(RowsAreSolidColor(surface, 75, 25, BGRAColor::Green()));
}
{
// Fill the rest of the image with a second pass of green.
uint32_t count = 0;
auto result = aSink->WritePixels<uint32_t>([&]() {
++count;
return AsVariant(BGRAColor::Green().AsPixel());
});
EXPECT_EQ(WriteState::FINISHED, result);
EXPECT_EQ(75u * 100u, count);
AssertCorrectPipelineFinalState(aSink,
IntRect(0, 0, 100, 75),
IntRect(0, 0, 100, 75));
// Check that the generated image is correct.
RawAccessFrameRef currentFrame = aDecoder->GetCurrentFrameRef();
RefPtr<SourceSurface> surface = currentFrame->GetSurface();
EXPECT_TRUE(IsSolidColor(surface, BGRAColor::Green()));
}
});
}
TEST(ImageSurfaceSink, PalettedSurfaceSinkInitialization)
{
WithPalettedSurfaceSink(IntRect(0, 0, 100, 100),
[](Decoder* aDecoder, PalettedSurfaceSink* aSink) {
// Check initial state.
EXPECT_FALSE(aSink->IsSurfaceFinished());
Maybe<SurfaceInvalidRect> invalidRect = aSink->TakeInvalidRect();
EXPECT_TRUE(invalidRect.isNothing());
// Check that the paletted image data is zero-initialized.
RawAccessFrameRef currentFrame = aDecoder->GetCurrentFrameRef();
uint8_t* imageData = nullptr;
uint32_t imageLength = 0;
currentFrame->GetImageData(&imageData, &imageLength);
ASSERT_TRUE(imageData != nullptr);
ASSERT_EQ(100u * 100u, imageLength);
for (uint32_t i = 0; i < imageLength; ++i) {
ASSERT_EQ(uint8_t(0), imageData[i]);
}
});
}
TEST(ImageSurfaceSink, PalettedSurfaceSinkWritePixelsFor0_0_100_100)
{
WithPalettedSurfaceSink(IntRect(0, 0, 100, 100),
[](Decoder* aDecoder, PalettedSurfaceSink* aSink) {
CheckPalettedWritePixels(aDecoder, aSink);
});
}
TEST(ImageSurfaceSink, PalettedSurfaceSinkWritePixelsFor25_25_50_50)
{
WithPalettedSurfaceSink(IntRect(25, 25, 50, 50),
[](Decoder* aDecoder, PalettedSurfaceSink* aSink) {
CheckPalettedWritePixels(aDecoder, aSink,
/* aOutputRect = */ Some(IntRect(0, 0, 50, 50)),
/* aInputRect = */ Some(IntRect(0, 0, 50, 50)),
/* aInputWriteRect = */ Some(IntRect(25, 25, 50, 50)),
/* aOutputWriteRect = */ Some(IntRect(25, 25, 50, 50)));
});
}
TEST(ImageSurfaceSink, PalettedSurfaceSinkWritePixelsForMinus25_Minus25_50_50)
{
WithPalettedSurfaceSink(IntRect(-25, -25, 50, 50),
[](Decoder* aDecoder, PalettedSurfaceSink* aSink) {
CheckPalettedWritePixels(aDecoder, aSink,
/* aOutputRect = */ Some(IntRect(0, 0, 50, 50)),
/* aInputRect = */ Some(IntRect(0, 0, 50, 50)),
/* aInputWriteRect = */ Some(IntRect(-25, -25, 50, 50)),
/* aOutputWriteRect = */ Some(IntRect(-25, -25, 50, 50)));
});
}
TEST(ImageSurfaceSink, PalettedSurfaceSinkWritePixelsFor75_Minus25_50_50)
{
WithPalettedSurfaceSink(IntRect(75, -25, 50, 50),
[](Decoder* aDecoder, PalettedSurfaceSink* aSink) {
CheckPalettedWritePixels(aDecoder, aSink,
/* aOutputRect = */ Some(IntRect(0, 0, 50, 50)),
/* aInputRect = */ Some(IntRect(0, 0, 50, 50)),
/* aInputWriteRect = */ Some(IntRect(75, -25, 50, 50)),
/* aOutputWriteRect = */ Some(IntRect(75, -25, 50, 50)));
});
}
TEST(ImageSurfaceSink, PalettedSurfaceSinkWritePixelsForMinus25_75_50_50)
{
WithPalettedSurfaceSink(IntRect(-25, 75, 50, 50),
[](Decoder* aDecoder, PalettedSurfaceSink* aSink) {
CheckPalettedWritePixels(aDecoder, aSink,
/* aOutputRect = */ Some(IntRect(0, 0, 50, 50)),
/* aInputRect = */ Some(IntRect(0, 0, 50, 50)),
/* aInputWriteRect = */ Some(IntRect(-25, 75, 50, 50)),
/* aOutputWriteRect = */ Some(IntRect(-25, 75, 50, 50)));
});
}
TEST(ImageSurfaceSink, PalettedSurfaceSinkWritePixelsFor75_75_50_50)
{
WithPalettedSurfaceSink(IntRect(75, 75, 50, 50),
[](Decoder* aDecoder, PalettedSurfaceSink* aSink) {
CheckPalettedWritePixels(aDecoder, aSink,
/* aOutputRect = */ Some(IntRect(0, 0, 50, 50)),
/* aInputRect = */ Some(IntRect(0, 0, 50, 50)),
/* aInputWriteRect = */ Some(IntRect(75, 75, 50, 50)),
/* aOutputWriteRect = */ Some(IntRect(75, 75, 50, 50)));
});
}
TEST(ImageSurfaceSink, PalettedSurfaceSinkWritePixelsFinish)
{
WithPalettedSurfaceSink(IntRect(0, 0, 100, 100),
[](Decoder* aDecoder, PalettedSurfaceSink* aSink) {
// Write nothing into the surface; just finish immediately.
uint32_t count = 0;
auto result = aSink->WritePixels<uint8_t>([&]{
count++;
return AsVariant(WriteState::FINISHED);
});
EXPECT_EQ(WriteState::FINISHED, result);
EXPECT_EQ(1u, count);
AssertCorrectPipelineFinalState(aSink,
IntRect(0, 0, 100, 100),
IntRect(0, 0, 100, 100));
// Attempt to write more and make sure that nothing gets written.
count = 0;
result = aSink->WritePixels<uint8_t>([&]() {
count++;
return AsVariant(uint8_t(128));
});
EXPECT_EQ(WriteState::FINISHED, result);
EXPECT_EQ(0u, count);
EXPECT_TRUE(aSink->IsSurfaceFinished());
// Check that the generated image is correct.
EXPECT_TRUE(IsSolidPalettedColor(aDecoder, 0));
});
}
TEST(ImageSurfaceSink, PalettedSurfaceSinkWritePixelsEarlyExit)
{
auto checkEarlyExit =
[](Decoder* aDecoder, PalettedSurfaceSink* aSink, WriteState aState) {
// Write half a row of green pixels and then exit early with |aState|. If
// the lambda keeps getting called, we'll write red pixels, which will cause
// the test to fail.
uint32_t count = 0;
auto result = aSink->WritePixels<uint8_t>([&]() -> NextPixel<uint8_t> {
if (count == 50) {
return AsVariant(aState);
}
return count++ < 50 ? AsVariant(uint8_t(255)) : AsVariant(uint8_t(128));
});
EXPECT_EQ(aState, result);
EXPECT_EQ(50u, count);
CheckGeneratedPalettedImage(aDecoder, IntRect(0, 0, 50, 1));
if (aState != WriteState::FINISHED) {
// We should still be able to write more at this point.
EXPECT_FALSE(aSink->IsSurfaceFinished());
// Verify that we can resume writing. We'll finish up the same row.
count = 0;
result = aSink->WritePixels<uint8_t>([&]() -> NextPixel<uint8_t> {
if (count == 50) {
return AsVariant(WriteState::NEED_MORE_DATA);
}
++count;
return AsVariant(uint8_t(255));
});
EXPECT_EQ(WriteState::NEED_MORE_DATA, result);
EXPECT_EQ(50u, count);
EXPECT_FALSE(aSink->IsSurfaceFinished());
CheckGeneratedPalettedImage(aDecoder, IntRect(0, 0, 100, 1));
return;
}
// We should've finished the surface at this point.
AssertCorrectPipelineFinalState(aSink,
IntRect(0, 0, 100, 100),
IntRect(0, 0, 100, 100));
// Attempt to write more and make sure that nothing gets written.
count = 0;
result = aSink->WritePixels<uint8_t>([&]{
count++;
return AsVariant(uint8_t(128));
});
EXPECT_EQ(WriteState::FINISHED, result);
EXPECT_EQ(0u, count);
EXPECT_TRUE(aSink->IsSurfaceFinished());
// Check that the generated image is still correct.
CheckGeneratedPalettedImage(aDecoder, IntRect(0, 0, 50, 1));
};
WithPalettedSurfaceSink(IntRect(0, 0, 100, 100),
[&](Decoder* aDecoder, PalettedSurfaceSink* aSink) {
checkEarlyExit(aDecoder, aSink, WriteState::NEED_MORE_DATA);
});
WithPalettedSurfaceSink(IntRect(0, 0, 100, 100),
[&](Decoder* aDecoder, PalettedSurfaceSink* aSink) {
checkEarlyExit(aDecoder, aSink, WriteState::FAILURE);
});
WithPalettedSurfaceSink(IntRect(0, 0, 100, 100),
[&](Decoder* aDecoder, PalettedSurfaceSink* aSink) {
checkEarlyExit(aDecoder, aSink, WriteState::FINISHED);
});
}
TEST(ImageSurfaceSink, PalettedSurfaceSinkWritePixelsToRow)
{
WithPalettedSurfaceSink(IntRect(0, 0, 100, 100),
[](Decoder* aDecoder, PalettedSurfaceSink* aSink) {
// Write the first 99 rows of our 100x100 surface and verify that even
// though our lambda will yield pixels forever, only one row is written per
// call to WritePixelsToRow().
for (int row = 0; row < 99; ++row) {
uint32_t count = 0;
WriteState result = aSink->WritePixelsToRow<uint8_t>([&]{
++count;
return AsVariant(uint8_t(255));
});
EXPECT_EQ(WriteState::NEED_MORE_DATA, result);
EXPECT_EQ(100u, count);
EXPECT_FALSE(aSink->IsSurfaceFinished());
Maybe<SurfaceInvalidRect> invalidRect = aSink->TakeInvalidRect();
EXPECT_TRUE(invalidRect.isSome());
EXPECT_EQ(IntRect(0, row, 100, 1), invalidRect->mInputSpaceRect);
EXPECT_EQ(IntRect(0, row, 100, 1), invalidRect->mOutputSpaceRect);
CheckGeneratedPalettedImage(aDecoder, IntRect(0, 0, 100, row + 1));
}
// Write the final line, which should finish the surface.
uint32_t count = 0;
WriteState result = aSink->WritePixelsToRow<uint8_t>([&]{
++count;
return AsVariant(uint8_t(255));
});
EXPECT_EQ(WriteState::FINISHED, result);
EXPECT_EQ(100u, count);
// Note that the final invalid rect we expect here is only the last row;
// that's because we called TakeInvalidRect() repeatedly in the loop above.
AssertCorrectPipelineFinalState(aSink,
IntRect(0, 99, 100, 1),
IntRect(0, 99, 100, 1));
// Check that the generated image is correct.
CheckGeneratedPalettedImage(aDecoder, IntRect(0, 0, 100, 100));
// Attempt to write more and make sure that nothing gets written.
count = 0;
result = aSink->WritePixelsToRow<uint8_t>([&]{
count++;
return AsVariant(uint8_t(128));
});
EXPECT_EQ(WriteState::FINISHED, result);
EXPECT_EQ(0u, count);
EXPECT_TRUE(aSink->IsSurfaceFinished());
// Check that the generated image is still correct.
CheckGeneratedPalettedImage(aDecoder, IntRect(0, 0, 100, 100));
});
}
TEST(ImageSurfaceSink, PalettedSurfaceSinkWritePixelsToRowEarlyExit)
{
auto checkEarlyExit =
[](Decoder* aDecoder, PalettedSurfaceSink* aSink, WriteState aState) {
// Write half a row of 255s and then exit early with |aState|. If the lambda
// keeps getting called, we'll write 128s, which will cause the test to
// fail.
uint32_t count = 0;
auto result = aSink->WritePixelsToRow<uint8_t>([&]() -> NextPixel<uint8_t> {
if (count == 50) {
return AsVariant(aState);
}
return count++ < 50 ? AsVariant(uint8_t(255))
: AsVariant(uint8_t(128));
});
EXPECT_EQ(aState, result);
EXPECT_EQ(50u, count);
CheckGeneratedPalettedImage(aDecoder, IntRect(0, 0, 50, 1));
if (aState != WriteState::FINISHED) {
// We should still be able to write more at this point.
EXPECT_FALSE(aSink->IsSurfaceFinished());
// Verify that we can resume the same row and still stop at the end.
count = 0;
WriteState result = aSink->WritePixelsToRow<uint8_t>([&]{
++count;
return AsVariant(uint8_t(255));
});
EXPECT_EQ(WriteState::NEED_MORE_DATA, result);
EXPECT_EQ(50u, count);
EXPECT_FALSE(aSink->IsSurfaceFinished());
CheckGeneratedPalettedImage(aDecoder, IntRect(0, 0, 100, 1));
return;
}
// We should've finished the surface at this point.
AssertCorrectPipelineFinalState(aSink,
IntRect(0, 0, 100, 100),
IntRect(0, 0, 100, 100));
// Attempt to write more and make sure that nothing gets written.
count = 0;
result = aSink->WritePixelsToRow<uint8_t>([&]{
count++;
return AsVariant(uint8_t(128));
});
EXPECT_EQ(WriteState::FINISHED, result);
EXPECT_EQ(0u, count);
EXPECT_TRUE(aSink->IsSurfaceFinished());
// Check that the generated image is still correct.
CheckGeneratedPalettedImage(aDecoder, IntRect(0, 0, 50, 1));
};
WithPalettedSurfaceSink(IntRect(0, 0, 100, 100),
[&](Decoder* aDecoder, PalettedSurfaceSink* aSink) {
checkEarlyExit(aDecoder, aSink, WriteState::NEED_MORE_DATA);
});
WithPalettedSurfaceSink(IntRect(0, 0, 100, 100),
[&](Decoder* aDecoder, PalettedSurfaceSink* aSink) {
checkEarlyExit(aDecoder, aSink, WriteState::FAILURE);
});
WithPalettedSurfaceSink(IntRect(0, 0, 100, 100),
[&](Decoder* aDecoder, PalettedSurfaceSink* aSink) {
checkEarlyExit(aDecoder, aSink, WriteState::FINISHED);
});
}
TEST(ImageSurfaceSink, PalettedSurfaceSinkWriteBuffer)
{
WithPalettedSurfaceSink(IntRect(0, 0, 100, 100),
[](Decoder* aDecoder, PalettedSurfaceSink* aSink) {
// Create a buffer the same size as one row of the surface (which is 100x100),
// containing 60 pixels of 255 in the middle and 20 transparent pixels of 0 on
// either side.
uint8_t buffer[100];
for (int i = 0; i < 100; ++i) {
buffer[i] = 20 <= i && i < 80 ? 255 : 0;
}
// Write the buffer to every row of the surface and check that the generated
// image is correct.
CheckPalettedIterativeWrite(aDecoder, aSink, IntRect(20, 0, 60, 100), [&]{
return aSink->WriteBuffer(buffer);
});
});
}
TEST(ImageSurfaceSink, PalettedSurfaceSinkWriteBufferPartialRow)
{
WithPalettedSurfaceSink(IntRect(0, 0, 100, 100),
[](Decoder* aDecoder, PalettedSurfaceSink* aSink) {
// Create a buffer the same size as one row of the surface, containing all
// 255 pixels.
uint8_t buffer[100];
for (int i = 0; i < 100; ++i) {
buffer[i] = 255;
}
// Write the buffer to the middle 60 pixels of every row of the surface and
// check that the generated image is correct.
CheckPalettedIterativeWrite(aDecoder, aSink, IntRect(20, 0, 60, 100), [&]{
return aSink->WriteBuffer(buffer, 20, 60);
});
});
}
TEST(ImageSurfaceSink, PalettedSurfaceSinkWriteBufferPartialRowStartColOverflow)
{
WithPalettedSurfaceSink(IntRect(0, 0, 100, 100),
[](Decoder* aDecoder, PalettedSurfaceSink* aSink) {
// Create a buffer the same size as one row of the surface, containing all
// 255 pixels.
uint8_t buffer[100];
for (int i = 0; i < 100; ++i) {
buffer[i] = 255;
}
{
// Write the buffer to successive rows until every row of the surface
// has been written. We place the start column beyond the end of the row,
// which will prevent us from writing anything, so we check that the
// generated image is entirely 0.
CheckPalettedIterativeWrite(aDecoder, aSink, IntRect(0, 0, 0, 0), [&]{
return aSink->WriteBuffer(buffer, 100, 100);
});
}
ResetForNextPass(aSink);
{
// Write the buffer to successive rows until every row of the surface
// has been written. We use column 50 as the start column, but we still
// write the buffer, which means we overflow the right edge of the surface
// by 50 pixels. We check that the left half of the generated image is
// 0 and the right half is 255.
CheckPalettedIterativeWrite(aDecoder, aSink, IntRect(50, 0, 50, 100), [&]{
return aSink->WriteBuffer(buffer, 50, 100);
});
}
});
}
TEST(ImageSurfaceSink, PalettedSurfaceSinkWriteBufferPartialRowBufferOverflow)
{
WithPalettedSurfaceSink(IntRect(0, 0, 100, 100),
[](Decoder* aDecoder, PalettedSurfaceSink* aSink) {
// Create a buffer twice as large as a row of the surface. The first half
// (which is as large as a row of the image) will contain 255 pixels,
// while the second half will contain 128 pixels.
uint8_t buffer[200];
for (int i = 0; i < 200; ++i) {
buffer[i] = i < 100 ? 255 : 128;
}
{
// Write the buffer to successive rows until every row of the surface has
// been written. The buffer extends 100 pixels to the right of a row of
// the surface, but bounds checking will prevent us from overflowing the
// buffer. We check that the generated image is entirely 255 since the
// pixels on the right side of the buffer shouldn't have been written to
// the surface.
CheckPalettedIterativeWrite(aDecoder, aSink, IntRect(0, 0, 100, 100), [&]{
return aSink->WriteBuffer(buffer, 0, 200);
});
}
ResetForNextPass(aSink);
{
// Write from the buffer to the middle of each row of the surface. That
// means that the left side of each row should be 0, since we didn't write
// anything there. A buffer overflow would cause us to write buffer
// contents into the left side of each row. We check that the generated
// image is 0 on the left side and 255 on the right.
CheckPalettedIterativeWrite(aDecoder, aSink, IntRect(50, 0, 50, 100), [&]{
return aSink->WriteBuffer(buffer, 50, 200);
});
}
});
}
TEST(ImageSurfaceSink, PalettedSurfaceSinkWriteBufferFromNullSource)
{
WithPalettedSurfaceSink(IntRect(0, 0, 100, 100),
[](Decoder* aDecoder, PalettedSurfaceSink* aSink) {
// Calling WriteBuffer() with a null pointer should fail without making any
// changes to the surface.
uint8_t* nullBuffer = nullptr;
WriteState result = aSink->WriteBuffer(nullBuffer);
EXPECT_EQ(WriteState::FAILURE, result);
EXPECT_FALSE(aSink->IsSurfaceFinished());
Maybe<SurfaceInvalidRect> invalidRect = aSink->TakeInvalidRect();
EXPECT_TRUE(invalidRect.isNothing());
// Check that nothing got written to the surface.
CheckGeneratedPalettedImage(aDecoder, IntRect(0, 0, 0, 0));
});
}
TEST(ImageSurfaceSink, PalettedSurfaceSinkWriteEmptyRow)
{
WithPalettedSurfaceSink(IntRect(0, 0, 100, 100),
[](Decoder* aDecoder, PalettedSurfaceSink* aSink) {
{
// Write an empty row to each row of the surface. We check that the
// generated image is entirely 0.
CheckPalettedIterativeWrite(aDecoder, aSink, IntRect(0, 0, 0, 0), [&]{
return aSink->WriteEmptyRow();
});
}
ResetForNextPass(aSink);
{
// Write a partial row before we begin calling WriteEmptyRow(). We check
// that the generated image is entirely 0, which is to be expected since
// WriteEmptyRow() overwrites the current row even if some data has
// already been written to it.
uint32_t count = 0;
auto result = aSink->WritePixels<uint8_t>([&]() -> NextPixel<uint8_t> {
if (count == 50) {
return AsVariant(WriteState::NEED_MORE_DATA);
}
++count;
return AsVariant(uint8_t(255));
});
EXPECT_EQ(WriteState::NEED_MORE_DATA, result);
EXPECT_EQ(50u, count);
EXPECT_FALSE(aSink->IsSurfaceFinished());
CheckPalettedIterativeWrite(aDecoder, aSink, IntRect(0, 0, 0, 0), [&]{
return aSink->WriteEmptyRow();
});
}
ResetForNextPass(aSink);
{
// Create a buffer the same size as one row of the surface, containing all
// 255 pixels.
uint8_t buffer[100];
for (int i = 0; i < 100; ++i) {
buffer[i] = 255;
}
// Write an empty row to the middle 60 rows of the surface. The first 20
// and last 20 rows will be 255. (We need to use DoCheckIterativeWrite()
// here because we need a custom function to check the output, since it
// can't be described by a simple rect.)
auto writeFunc = [&](uint32_t aRow) {
if (aRow < 20 || aRow >= 80) {
return aSink->WriteBuffer(buffer);
} else {
return aSink->WriteEmptyRow();
}
};
auto checkFunc = [&]{
EXPECT_TRUE(PalettedRowsAreSolidColor(aDecoder, 0, 20, 255));
EXPECT_TRUE(PalettedRowsAreSolidColor(aDecoder, 20, 60, 0));
EXPECT_TRUE(PalettedRowsAreSolidColor(aDecoder, 80, 20, 255));
};
DoCheckIterativeWrite(aSink, writeFunc, checkFunc);
}
});
}
TEST(ImageSurfaceSink, PalettedSurfaceSinkWriteUnsafeComputedRow)
{
WithPalettedSurfaceSink(IntRect(0, 0, 100, 100),
[](Decoder* aDecoder, PalettedSurfaceSink* aSink) {
// Create an all-255 buffer the same size as one row of the surface.
uint8_t buffer[100];
for (int i = 0; i < 100; ++i) {
buffer[i] = 255;
}
// Write the buffer to successive rows until every row of the surface has
// been written. We only write to the right half of each row, so we check
// that the left side of the generated image is 0 and the right side is 255.
CheckPalettedIterativeWrite(aDecoder, aSink, IntRect(50, 0, 50, 100), [&]{
return aSink->WriteUnsafeComputedRow<uint8_t>([&](uint8_t* aRow,
uint32_t aLength) {
EXPECT_EQ(100u, aLength );
memcpy(aRow + 50, buffer, 50 * sizeof(uint8_t));
});
});
});
}