/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */ /* * This file is part of the LibreOffice project. * * 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 #include #include #include #include #include #include #include #include namespace { class BitmapScaleTest : public CppUnit::TestFixture { void testScale(); void testScale2(); void testScaleSymmetry(); CPPUNIT_TEST_SUITE(BitmapScaleTest); CPPUNIT_TEST(testScale); CPPUNIT_TEST(testScale2); CPPUNIT_TEST(testScaleSymmetry); CPPUNIT_TEST_SUITE_END(); }; bool checkBitmapColor(Bitmap const& rBitmap, Color const& rExpectedColor) { bool bResult = true; Bitmap aBitmap(rBitmap); Bitmap::ScopedReadAccess pReadAccess(aBitmap); long nHeight = pReadAccess->Height(); long nWidth = pReadAccess->Width(); for (long y = 0; y < nHeight; ++y) { Scanline pScanlineRead = pReadAccess->GetScanline(y); for (long x = 0; x < nWidth; ++x) { Color aColor = pReadAccess->GetPixelFromData(pScanlineRead, x); if (aColor != rExpectedColor) bResult = false; } } return bResult; } void assertColorsAreSimilar(int maxDifference, const std::string& message, const BitmapColor& expected, const BitmapColor& actual) { // Check that the two colors match or are reasonably similar. if (expected == actual) return; if (abs(expected.GetRed() - actual.GetRed()) <= maxDifference && abs(expected.GetGreen() - actual.GetGreen()) <= maxDifference && abs(expected.GetBlue() - actual.GetBlue()) <= maxDifference && abs(expected.GetAlpha() - actual.GetAlpha()) <= maxDifference) { return; } CPPUNIT_ASSERT_EQUAL_MESSAGE(message, expected, actual); } void assertColorsAreSimilar(int maxDifference, int line, const BitmapColor& expected, const BitmapColor& actual) { std::stringstream stream; stream << "Line: " << line; assertColorsAreSimilar(maxDifference, stream.str(), expected, actual); } void BitmapScaleTest::testScale() { const bool bExportBitmap(false); using tools::Rectangle; static const BmpScaleFlag scaleMethods[] = { BmpScaleFlag::Default, BmpScaleFlag::Fast, BmpScaleFlag::BestQuality, BmpScaleFlag::Interpolate, BmpScaleFlag::Lanczos, BmpScaleFlag::BiCubic, BmpScaleFlag::BiLinear }; for (BmpScaleFlag scaleMethod : scaleMethods) { struct ScaleSize { Size srcSize; Size destSize; }; static const ScaleSize scaleSizes[] = { // test no-op { Size(16, 16), Size(16, 16) }, // powers of 2 (OpenGL may use texture atlas) { Size(16, 16), Size(14, 14) }, { Size(14, 14), Size(16, 16) }, // both upscaling and downscaling // "random" sizes { Size(18, 18), Size(14, 14) }, { Size(14, 14), Size(18, 18) }, // different x/y ratios { Size(16, 30), Size(14, 18) }, { Size(14, 18), Size(16, 30) }, // ratio larger than 16 (triggers different paths in some OpenGL algorithms) { Size(18 * 20, 18 * 20), Size(14, 14) }, { Size(14, 14), Size(18 * 20, 18 * 20) }, // Boundary cases. { Size(1, 1), Size(1, 1) }, { Size(16, 1), Size(12, 1) }, { Size(1, 16), Size(1, 12) } }; for (const ScaleSize& scaleSize : scaleSizes) { OString testStr = "Testing scale (" + scaleSize.srcSize.toString() + ")->(" + scaleSize.destSize.toString() + "), method " + OString::number(static_cast(scaleMethod)); fprintf(stderr, "%s\n", testStr.getStr()); Bitmap bitmap(scaleSize.srcSize, 24); { // Fill each quarter of the source bitmap with a different color, // and center with yet another color. BitmapScopedWriteAccess writeAccess(bitmap); const int halfW = scaleSize.srcSize.getWidth() / 2; const int halfH = scaleSize.srcSize.getHeight() / 2; const Size aSize(std::max(halfW, 1), std::max(halfH, 1)); writeAccess->SetFillColor(COL_GREEN); writeAccess->FillRect(Rectangle(Point(0, 0), aSize)); writeAccess->SetFillColor(COL_RED); writeAccess->FillRect(Rectangle(Point(0, halfH), aSize)); writeAccess->SetFillColor(COL_YELLOW); writeAccess->FillRect(Rectangle(Point(halfW, 0), aSize)); writeAccess->SetFillColor(COL_BLACK); writeAccess->FillRect(Rectangle(Point(halfW, halfH), aSize)); writeAccess->SetFillColor(COL_BLUE); writeAccess->FillRect(Rectangle(Point(halfW / 2, halfH / 2), aSize)); } if (bExportBitmap) { SvFileStream aStream("~/scale_before.png", StreamMode::WRITE | StreamMode::TRUNC); GraphicFilter& rFilter = GraphicFilter::GetGraphicFilter(); rFilter.compressAsPNG(bitmap, aStream); } CPPUNIT_ASSERT(bitmap.Scale(scaleSize.destSize, scaleMethod)); if (bExportBitmap) { SvFileStream aStream("~/scale_after.png", StreamMode::WRITE | StreamMode::TRUNC); GraphicFilter& rFilter = GraphicFilter::GetGraphicFilter(); rFilter.compressAsPNG(bitmap, aStream); } CPPUNIT_ASSERT_EQUAL(scaleSize.destSize, bitmap.GetSizePixel()); const int lastW = scaleSize.destSize.getWidth() - 1; const int lastH = scaleSize.destSize.getHeight() - 1; if (scaleSize.srcSize.getWidth() == 1 && scaleSize.srcSize.getHeight() == 1) { BitmapReadAccess readAccess(bitmap); assertColorsAreSimilar(2, __LINE__, COL_BLUE, readAccess.GetColor(0, 0)); assertColorsAreSimilar(2, __LINE__, COL_BLUE, readAccess.GetColor(lastH, 0)); assertColorsAreSimilar(2, __LINE__, COL_BLUE, readAccess.GetColor(0, lastW)); assertColorsAreSimilar(2, __LINE__, COL_BLUE, readAccess.GetColor(lastH, lastW)); assertColorsAreSimilar(2, __LINE__, COL_BLUE, readAccess.GetColor(lastH / 2, lastW / 2)); } else if (lastW && lastH) { // Scaling should keep each quarter of the resulting bitmap have the same color, // so check that color in each corner of the result bitmap is the same color, // or reasonably close (some algorithms may alter the color very slightly). BitmapReadAccess readAccess(bitmap); assertColorsAreSimilar(2, __LINE__, COL_GREEN, readAccess.GetColor(0, 0)); assertColorsAreSimilar(2, __LINE__, COL_RED, readAccess.GetColor(lastH, 0)); assertColorsAreSimilar(2, __LINE__, COL_YELLOW, readAccess.GetColor(0, lastW)); assertColorsAreSimilar(2, __LINE__, COL_BLACK, readAccess.GetColor(lastH, lastW)); assertColorsAreSimilar(2, __LINE__, COL_BLUE, readAccess.GetColor(lastH / 2, lastW / 2)); } else if (lastW) { BitmapReadAccess readAccess(bitmap); assertColorsAreSimilar(2, __LINE__, COL_RED, readAccess.GetColor(0, 0)); assertColorsAreSimilar(2, __LINE__, COL_BLACK, readAccess.GetColor(0, lastW)); assertColorsAreSimilar(2, __LINE__, COL_BLUE, readAccess.GetColor(0, lastW / 2)); } else if (lastH) { BitmapReadAccess readAccess(bitmap); assertColorsAreSimilar(2, __LINE__, COL_YELLOW, readAccess.GetColor(0, 0)); assertColorsAreSimilar(2, __LINE__, COL_BLACK, readAccess.GetColor(lastH, 0)); assertColorsAreSimilar(2, __LINE__, COL_BLUE, readAccess.GetColor(lastH / 2, 0)); } } } } void BitmapScaleTest::testScale2() { const bool bExportBitmap(false); Bitmap aBitmap24Bit(Size(4096, 4096), 24); CPPUNIT_ASSERT_EQUAL(static_cast(24), aBitmap24Bit.GetBitCount()); Color aBitmapColor = COL_YELLOW; { BitmapScopedWriteAccess aWriteAccess(aBitmap24Bit); aWriteAccess->Erase(aBitmapColor); } if (bExportBitmap) { SvFileStream aStream("scale_before.png", StreamMode::WRITE | StreamMode::TRUNC); GraphicFilter& rFilter = GraphicFilter::GetGraphicFilter(); rFilter.compressAsPNG(aBitmap24Bit, aStream); } // Scale - 65x65 CPPUNIT_ASSERT_EQUAL(static_cast(4096), aBitmap24Bit.GetSizePixel().Width()); CPPUNIT_ASSERT_EQUAL(static_cast(4096), aBitmap24Bit.GetSizePixel().Height()); Bitmap aScaledBitmap = aBitmap24Bit; aScaledBitmap.Scale(Size(65, 65)); if (bExportBitmap) { SvFileStream aStream("scale_after_65x65.png", StreamMode::WRITE | StreamMode::TRUNC); GraphicFilter& rFilter = GraphicFilter::GetGraphicFilter(); rFilter.compressAsPNG(aScaledBitmap, aStream); } CPPUNIT_ASSERT_EQUAL(static_cast(65), aScaledBitmap.GetSizePixel().Width()); CPPUNIT_ASSERT_EQUAL(static_cast(65), aScaledBitmap.GetSizePixel().Height()); CPPUNIT_ASSERT(checkBitmapColor(aScaledBitmap, aBitmapColor)); // Scale - 64x64 CPPUNIT_ASSERT_EQUAL(static_cast(4096), aBitmap24Bit.GetSizePixel().Width()); CPPUNIT_ASSERT_EQUAL(static_cast(4096), aBitmap24Bit.GetSizePixel().Height()); aScaledBitmap = aBitmap24Bit; aScaledBitmap.Scale(Size(64, 64)); if (bExportBitmap) { SvFileStream aStream("scale_after_64x64.png", StreamMode::WRITE | StreamMode::TRUNC); GraphicFilter& rFilter = GraphicFilter::GetGraphicFilter(); rFilter.compressAsPNG(aScaledBitmap, aStream); } CPPUNIT_ASSERT_EQUAL(static_cast(64), aScaledBitmap.GetSizePixel().Width()); CPPUNIT_ASSERT_EQUAL(static_cast(64), aScaledBitmap.GetSizePixel().Height()); CPPUNIT_ASSERT(checkBitmapColor(aScaledBitmap, aBitmapColor)); // Scale - 63x63 CPPUNIT_ASSERT_EQUAL(static_cast(4096), aBitmap24Bit.GetSizePixel().Width()); CPPUNIT_ASSERT_EQUAL(static_cast(4096), aBitmap24Bit.GetSizePixel().Height()); aScaledBitmap = aBitmap24Bit; aScaledBitmap.Scale(Size(63, 63)); if (bExportBitmap) { SvFileStream aStream("scale_after_63x63.png", StreamMode::WRITE | StreamMode::TRUNC); GraphicFilter& rFilter = GraphicFilter::GetGraphicFilter(); rFilter.compressAsPNG(aScaledBitmap, aStream); } CPPUNIT_ASSERT_EQUAL(static_cast(63), aScaledBitmap.GetSizePixel().Width()); CPPUNIT_ASSERT_EQUAL(static_cast(63), aScaledBitmap.GetSizePixel().Height()); CPPUNIT_ASSERT(checkBitmapColor(aScaledBitmap, aBitmapColor)); } void BitmapScaleTest::testScaleSymmetry() { const bool bExportBitmap(false); Bitmap aBitmap24Bit(Size(10, 10), 24); CPPUNIT_ASSERT_EQUAL(static_cast(24), aBitmap24Bit.GetBitCount()); { BitmapScopedWriteAccess aWriteAccess(aBitmap24Bit); aWriteAccess->Erase(COL_WHITE); aWriteAccess->SetLineColor(COL_BLACK); aWriteAccess->DrawRect(tools::Rectangle(1, 1, 8, 8)); aWriteAccess->DrawRect(tools::Rectangle(3, 3, 6, 6)); } BitmapSymmetryCheck aBitmapSymmetryCheck; CPPUNIT_ASSERT_EQUAL(static_cast(10), aBitmap24Bit.GetSizePixel().Width()); CPPUNIT_ASSERT_EQUAL(static_cast(10), aBitmap24Bit.GetSizePixel().Height()); // Check symmetry of the bitmap CPPUNIT_ASSERT(BitmapSymmetryCheck::check(aBitmap24Bit)); if (bExportBitmap) { SvFileStream aStream("~/scale_before.png", StreamMode::WRITE | StreamMode::TRUNC); GraphicFilter& rFilter = GraphicFilter::GetGraphicFilter(); rFilter.compressAsPNG(aBitmap24Bit, aStream); } aBitmap24Bit.Scale(2, 2, BmpScaleFlag::Fast); CPPUNIT_ASSERT_EQUAL(static_cast(20), aBitmap24Bit.GetSizePixel().Width()); CPPUNIT_ASSERT_EQUAL(static_cast(20), aBitmap24Bit.GetSizePixel().Height()); // After scaling the bitmap should still be symmetrical. This check guarantees that // scaling doesn't misalign the bitmap. CPPUNIT_ASSERT(BitmapSymmetryCheck::check(aBitmap24Bit)); if (bExportBitmap) { SvFileStream aStream("~/scale_after.png", StreamMode::WRITE | StreamMode::TRUNC); GraphicFilter& rFilter = GraphicFilter::GetGraphicFilter(); rFilter.compressAsPNG(aBitmap24Bit, aStream); } } } // namespace CPPUNIT_TEST_SUITE_REGISTRATION(BitmapScaleTest); /* vim:set shiftwidth=4 softtabstop=4 expandtab: */