/* -*- 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 namespace vcl::test { namespace { int deltaColor(BitmapColor aColor1, BitmapColor aColor2) { int deltaR = std::abs(aColor1.GetRed() - aColor2.GetRed()); int deltaG = std::abs(aColor1.GetGreen() - aColor2.GetGreen()); int deltaB = std::abs(aColor1.GetBlue() - aColor2.GetBlue()); return std::max(std::max(deltaR, deltaG), deltaB); } void checkValue(BitmapScopedWriteAccess& pAccess, int x, int y, Color aExpected, int& nNumberOfQuirks, int& nNumberOfErrors, bool bQuirkMode, int nColorDeltaThresh = 0) { const bool bColorize = false; Color aColor = pAccess->GetPixel(y, x); int nColorDelta = deltaColor(aColor, aExpected); if (nColorDelta <= nColorDeltaThresh) { if (bColorize) pAccess->SetPixel(y, x, COL_LIGHTGREEN); } else if (bQuirkMode) { nNumberOfQuirks++; if (bColorize) pAccess->SetPixel(y, x, COL_YELLOW); } else { nNumberOfErrors++; if (bColorize) pAccess->SetPixel(y, x, COL_LIGHTRED); } } void checkValue(BitmapScopedWriteAccess& pAccess, const Point& point, Color aExpected, int& nNumberOfQuirks, int& nNumberOfErrors, bool bQuirkMode, int nColorDeltaThresh = 0) { checkValue(pAccess, point.getX(), point.getY(), aExpected, nNumberOfQuirks, nNumberOfErrors, bQuirkMode, nColorDeltaThresh); } void checkValue(BitmapScopedWriteAccess& pAccess, int x, int y, Color aExpected, int& nNumberOfQuirks, int& nNumberOfErrors, int nColorDeltaThresh, int nColorDeltaThreshQuirk = 0) { const bool bColorize = false; Color aColor = pAccess->GetPixel(y, x); int nColorDelta = deltaColor(aColor, aExpected); nColorDeltaThreshQuirk = std::max( nColorDeltaThresh, nColorDeltaThreshQuirk); if (nColorDelta <= nColorDeltaThresh) { if (bColorize) pAccess->SetPixel(y, x, COL_LIGHTGREEN); } else if (nColorDelta <= nColorDeltaThreshQuirk) { nNumberOfQuirks++; if (bColorize) pAccess->SetPixel(y, x, COL_YELLOW); } else { nNumberOfErrors++; if (bColorize) pAccess->SetPixel(y, x, COL_LIGHTRED); } } char returnDominantColor(Color aColor) { int aRed = aColor.GetRed(); int aGreen = aColor.GetGreen(); int aBlue = aColor.GetBlue(); if (aRed > aGreen && aRed > aBlue) return 'R'; if (aGreen > aRed && aGreen > aBlue) return 'G'; if(aBlue > aRed && aBlue > aGreen) return 'B'; return 'X'; //No Dominant Color. } void checkValueAA(BitmapScopedWriteAccess& pAccess, int x, int y, Color aExpected, int& nNumberOfQuirks, int& nNumberOfErrors, int nColorDeltaThresh = 64) { const bool bColorize = false; Color aColor = pAccess->GetPixel(y, x); bool aColorResult = returnDominantColor(aExpected) == returnDominantColor(aColor); int nColorDelta = deltaColor(aColor, aExpected); if (nColorDelta <= nColorDeltaThresh && aColorResult) { if (bColorize) pAccess->SetPixel(y, x, COL_LIGHTGREEN); } else if (aColorResult) { nNumberOfQuirks++; if (bColorize) pAccess->SetPixel(y, x, COL_YELLOW); } else { nNumberOfErrors++; if (bColorize) pAccess->SetPixel(y, x, COL_LIGHTRED); } } // Return all colors in the rectangle and their count. std::map collectColors(Bitmap& bitmap, const tools::Rectangle& rectangle) { std::map colors; BitmapScopedWriteAccess pAccess(bitmap); for (tools::Long y = rectangle.Top(); y < rectangle.Bottom(); ++y) for (tools::Long x = rectangle.Left(); x < rectangle.Right(); ++x) ++colors[pAccess->GetPixel(y, x)]; // operator[] initializes to 0 (default ctor) if creating return colors; } bool checkConvexHullProperty(Bitmap& bitmap, Color constLineColor, int nWidthOffset, int nHeightOffset) { BitmapScopedWriteAccess pAccess(bitmap); tools::Long thresholdWidth = pAccess->Width() - nWidthOffset; tools::Long thresholdHeight = pAccess->Height() - nHeightOffset; for (tools::Long y = 0; y < pAccess->Height(); ++y) { for (tools::Long x = 0; x < pAccess->Width(); ++x) { /* If the shape exceeds the threshold limit of height or width or both, this would indicate that the bezier curve is not within its convex polygon and hence is faulty. */ if (pAccess->GetPixel(y, x) == constLineColor && (thresholdHeight < y || thresholdWidth < x)) { return false; } } } return true; } TestResult checkRect(Bitmap& rBitmap, int aLayerNumber, Color aExpectedColor) { BitmapScopedWriteAccess pAccess(rBitmap); tools::Long nHeight = pAccess->Height(); tools::Long nWidth = pAccess->Width(); tools::Long firstX = 0 + aLayerNumber; tools::Long firstY = 0 + aLayerNumber; tools::Long lastX = nWidth - aLayerNumber - 1; tools::Long lastY = nHeight - aLayerNumber - 1; TestResult aResult = TestResult::Passed; int nNumberOfQuirks = 0; int nNumberOfErrors = 0; // check corner quirks checkValue(pAccess, firstX, firstY, aExpectedColor, nNumberOfQuirks, nNumberOfErrors, true); checkValue(pAccess, lastX, firstY, aExpectedColor, nNumberOfQuirks, nNumberOfErrors, true); checkValue(pAccess, firstX, lastY, aExpectedColor, nNumberOfQuirks, nNumberOfErrors, true); checkValue(pAccess, lastX, lastY, aExpectedColor, nNumberOfQuirks, nNumberOfErrors, true); for (tools::Long y = firstY + 1; y <= lastY - 1; y++) { checkValue(pAccess, firstX, y, aExpectedColor, nNumberOfQuirks, nNumberOfErrors, false); checkValue(pAccess, lastX, y, aExpectedColor, nNumberOfQuirks, nNumberOfErrors, false); } for (tools::Long x = firstX + 1; x <= lastX - 1; x++) { checkValue(pAccess, x, firstY, aExpectedColor, nNumberOfQuirks, nNumberOfErrors, false); checkValue(pAccess, x, lastY, aExpectedColor, nNumberOfQuirks, nNumberOfErrors, false); } if (nNumberOfQuirks > 0) aResult = TestResult::PassedWithQuirks; if (nNumberOfErrors > 0) aResult = TestResult::Failed; return aResult; } TestResult checkHorizontalVerticalDiagonalLines(Bitmap& rBitmap, Color aExpectedColor, int nColorThresh) { BitmapScopedWriteAccess pAccess(rBitmap); tools::Long nWidth = pAccess->Width(); tools::Long nHeight = pAccess->Height(); TestResult aResult = TestResult::Passed; int nNumberOfQuirks = 0; int nNumberOfErrors = 0; // check horizontal line { tools::Long startX = 4; tools::Long endX = nWidth - 2; tools::Long y = 1; checkValue(pAccess, startX, y, aExpectedColor, nNumberOfQuirks, nNumberOfErrors, true, nColorThresh); checkValue(pAccess, endX, y, aExpectedColor, nNumberOfQuirks, nNumberOfErrors, true, nColorThresh); for (tools::Long x = startX + 1; x <= endX - 1; x++) { checkValue(pAccess, x, y, aExpectedColor, nNumberOfQuirks, nNumberOfErrors, false, nColorThresh); } } // check vertical line { tools::Long startY = 4; tools::Long endY = nHeight - 2; tools::Long x = 1; checkValue(pAccess, x, startY, aExpectedColor, nNumberOfQuirks, nNumberOfErrors, true, nColorThresh); checkValue(pAccess, x, endY, aExpectedColor, nNumberOfQuirks, nNumberOfErrors, true, nColorThresh); for (tools::Long y = startY + 1; y <= endY - 1; y++) { checkValue(pAccess, x, y, aExpectedColor, nNumberOfQuirks, nNumberOfErrors, false, nColorThresh); } } // check diagonal line { tools::Long startX = 1; tools::Long endX = nWidth - 2; tools::Long startY = 1; tools::Long endY = nHeight - 2; tools::Long x = startX; tools::Long y = startY; checkValue(pAccess, startX, startY, aExpectedColor, nNumberOfQuirks, nNumberOfErrors, true, nColorThresh); checkValue(pAccess, endX, endY, aExpectedColor, nNumberOfQuirks, nNumberOfErrors, true, nColorThresh); x++; y++; while(y <= endY - 1 && x <= endX - 1) { checkValue(pAccess, x, y, aExpectedColor, nNumberOfQuirks, nNumberOfErrors, false, nColorThresh); x++; y++; } } if (nNumberOfQuirks > 0) aResult = TestResult::PassedWithQuirks; if (nNumberOfErrors > 0) aResult = TestResult::Failed; return aResult; } TestResult checkDiamondLine(Bitmap& rBitmap, int aLayerNumber, Color aExpectedColor) { BitmapScopedWriteAccess pAccess(rBitmap); tools::Long nHeight = pAccess->Height(); tools::Long nWidth = pAccess->Width(); tools::Long midX = nWidth / 2; tools::Long midY = nHeight / 2; tools::Long firstX = aLayerNumber; tools::Long lastX = nWidth - aLayerNumber - 1; tools::Long firstY = aLayerNumber; tools::Long lastY = nHeight - aLayerNumber - 1; tools::Long offsetFromMid = 0; TestResult aResult = TestResult::Passed; int nNumberOfQuirks = 0; int nNumberOfErrors = 0; checkValue(pAccess, firstX, midY, aExpectedColor, nNumberOfQuirks, nNumberOfErrors, true); checkValue(pAccess, lastX, midY, aExpectedColor, nNumberOfQuirks, nNumberOfErrors, true); checkValue(pAccess, midX, firstY, aExpectedColor, nNumberOfQuirks, nNumberOfErrors, true); checkValue(pAccess, midX, lastY, aExpectedColor, nNumberOfQuirks, nNumberOfErrors, true); offsetFromMid = 1; for (tools::Long x = firstX + 1; x <= midX - 1; x++) { checkValue(pAccess, x, midY - offsetFromMid, aExpectedColor, nNumberOfQuirks, nNumberOfErrors, false); checkValue(pAccess, x, midY + offsetFromMid, aExpectedColor, nNumberOfQuirks, nNumberOfErrors, false); offsetFromMid++; } offsetFromMid = midY - aLayerNumber - 1; for (tools::Long x = midX + 1; x <= lastX - 1; x++) { checkValue(pAccess, x, midY - offsetFromMid, aExpectedColor, nNumberOfQuirks, nNumberOfErrors, false); checkValue(pAccess, x, midY + offsetFromMid, aExpectedColor, nNumberOfQuirks, nNumberOfErrors, false); offsetFromMid--; } if (nNumberOfQuirks > 0) aResult = TestResult::PassedWithQuirks; if (nNumberOfErrors > 0) aResult = TestResult::Failed; return aResult; } } // end anonymous namespace const Color OutputDeviceTestCommon::constBackgroundColor(COL_LIGHTGRAY); const Color OutputDeviceTestCommon::constLineColor(COL_LIGHTBLUE); const Color OutputDeviceTestCommon::constFillColor(COL_BLUE); OutputDeviceTestCommon::OutputDeviceTestCommon() {} OUString OutputDeviceTestCommon::getRenderBackendName() const { if (mpVirtualDevice && mpVirtualDevice->GetGraphics()) { SalGraphics const * pGraphics = mpVirtualDevice->GetGraphics(); return pGraphics->getRenderBackendName(); } return OUString(); } void OutputDeviceTestCommon::initialSetup(tools::Long nWidth, tools::Long nHeight, Color aColor, bool bEnableAA, bool bAlphaVirtualDevice) { if (bAlphaVirtualDevice) mpVirtualDevice = VclPtr::Create(DeviceFormat::WITH_ALPHA); else mpVirtualDevice = VclPtr::Create(DeviceFormat::WITHOUT_ALPHA); maVDRectangle = tools::Rectangle(Point(), Size (nWidth, nHeight)); mpVirtualDevice->SetOutputSizePixel(maVDRectangle.GetSize()); if (bEnableAA) mpVirtualDevice->SetAntialiasing(AntialiasingFlags::Enable | AntialiasingFlags::PixelSnapHairline); else mpVirtualDevice->SetAntialiasing(AntialiasingFlags::NONE); mpVirtualDevice->SetBackground(Wallpaper(aColor)); mpVirtualDevice->Erase(); } TestResult OutputDeviceTestCommon::checkLines(Bitmap& rBitmap) { return checkHorizontalVerticalDiagonalLines(rBitmap, constLineColor, 0); } TestResult OutputDeviceTestCommon::checkAALines(Bitmap& rBitmap) { return checkHorizontalVerticalDiagonalLines(rBitmap, constLineColor, 30); // 30 color values threshold delta } static void checkResult(TestResult eResult, TestResult & eTotal) { if (eTotal == TestResult::Failed) return; if (eResult == TestResult::Failed) eTotal = TestResult::Failed; if (eResult == TestResult::PassedWithQuirks) eTotal = TestResult::PassedWithQuirks; } TestResult OutputDeviceTestCommon::checkInvertRectangle(Bitmap& aBitmap) { TestResult aReturnValue = TestResult::Passed; TestResult eResult; std::vector aExpected{ COL_WHITE, COL_WHITE }; eResult = checkRectangles(aBitmap, aExpected); checkResult(eResult, aReturnValue); eResult = checkFilled(aBitmap, tools::Rectangle(Point(2, 2), Size(8, 8)), COL_LIGHTCYAN); checkResult(eResult, aReturnValue); eResult = checkFilled(aBitmap, tools::Rectangle(Point(10, 2), Size(8, 8)), COL_LIGHTMAGENTA); checkResult(eResult, aReturnValue); eResult = checkFilled(aBitmap, tools::Rectangle(Point(2, 10), Size(8, 8)), COL_YELLOW); checkResult(eResult, aReturnValue); eResult = checkFilled(aBitmap, tools::Rectangle(Point(10, 10), Size(8, 8)), COL_BLACK); checkResult(eResult, aReturnValue); return aReturnValue; } TestResult OutputDeviceTestCommon::checkChecker(Bitmap& rBitmap, sal_Int32 nStartX, sal_Int32 nEndX, sal_Int32 nStartY, sal_Int32 nEndY, std::vector const & rExpected) { TestResult aReturnValue = TestResult::Passed; int choice = 0; for (sal_Int32 y = nStartY; y <= nEndY; ++y) { for (sal_Int32 x = nStartX; x <= nEndX; ++x) { TestResult eResult = checkFilled(rBitmap, tools::Rectangle(Point(x, y), Size(1, 1)), rExpected[choice % 2]); checkResult(eResult, aReturnValue); choice++; } choice++; } return aReturnValue; } TestResult OutputDeviceTestCommon::checkInvertN50Rectangle(Bitmap& aBitmap) { TestResult aReturnValue = TestResult::Passed; TestResult eResult; std::vector aExpected{ COL_WHITE, COL_WHITE }; eResult = checkRectangles(aBitmap, aExpected); checkResult(eResult, aReturnValue); eResult = checkChecker(aBitmap, 2, 9, 2, 9, { COL_LIGHTCYAN, COL_LIGHTRED }); checkResult(eResult, aReturnValue); eResult = checkChecker(aBitmap, 2, 9, 10, 17, { COL_YELLOW, COL_LIGHTBLUE }); checkResult(eResult, aReturnValue); eResult = checkChecker(aBitmap, 10, 17, 2, 9, { COL_LIGHTMAGENTA, COL_LIGHTGREEN }); checkResult(eResult, aReturnValue); eResult = checkChecker(aBitmap, 10, 17, 10, 17, { COL_BLACK, COL_WHITE }); checkResult(eResult, aReturnValue); return aReturnValue; } TestResult OutputDeviceTestCommon::checkInvertTrackFrameRectangle(Bitmap& aBitmap) { std::vector aExpected { COL_WHITE, COL_WHITE }; return checkRectangles(aBitmap, aExpected); } TestResult OutputDeviceTestCommon::checkRectangle(Bitmap& aBitmap) { std::vector aExpected { constBackgroundColor, constBackgroundColor, constLineColor, constBackgroundColor, constBackgroundColor, constLineColor, constBackgroundColor }; return checkRectangles(aBitmap, aExpected); } TestResult OutputDeviceTestCommon::checkRectangles(Bitmap& rBitmap, bool aEnableAA) { BitmapScopedWriteAccess pAccess(rBitmap); TestResult aResult = TestResult::Passed; int nNumberOfQuirks = 0; int nNumberOfErrors = 0; std::vector aExpected = { constBackgroundColor, constLineColor, constLineColor }; for (size_t aLayerNumber = 0; aLayerNumber < aExpected.size(); aLayerNumber++) { tools::Long startX = aLayerNumber, endX = pAccess->Width() / 2 - aLayerNumber + 1; tools::Long startY = aLayerNumber, endY = pAccess->Height() - aLayerNumber - 1; for (tools::Long ptX = startX; ptX <= endX; ++ptX) { if (aEnableAA) { checkValueAA(pAccess, ptX, startY + (aLayerNumber == 2 ? 2 : 0), aExpected[aLayerNumber], nNumberOfQuirks, nNumberOfErrors); checkValueAA(pAccess, ptX, endY - (aLayerNumber == 2 ? 2 : 0), aExpected[aLayerNumber], nNumberOfQuirks, nNumberOfErrors); } else { checkValue(pAccess, ptX, startY + (aLayerNumber == 2 ? 2 : 0), aExpected[aLayerNumber], nNumberOfQuirks, nNumberOfErrors, true); checkValue(pAccess, ptX, endY - (aLayerNumber == 2 ? 2 : 0), aExpected[aLayerNumber], nNumberOfQuirks, nNumberOfErrors, true); } } for (tools::Long ptY = startY + (aLayerNumber == 2 ? 2 : 0); ptY <= endY - (aLayerNumber == 2 ? 2 : 0); ++ptY) { if (aEnableAA) { checkValueAA(pAccess, startX, ptY, aExpected[aLayerNumber], nNumberOfQuirks, nNumberOfErrors); checkValueAA(pAccess, endX, ptY, aExpected[aLayerNumber], nNumberOfQuirks, nNumberOfErrors); } else { checkValue(pAccess, startX, ptY, aExpected[aLayerNumber], nNumberOfQuirks, nNumberOfErrors, true); checkValue(pAccess, endX, ptY, aExpected[aLayerNumber], nNumberOfQuirks, nNumberOfErrors, true); } } } if (nNumberOfQuirks > 0) aResult = TestResult::PassedWithQuirks; if (nNumberOfErrors > 0) aResult = TestResult::Failed; return aResult; } TestResult OutputDeviceTestCommon::checkRectangleAA(Bitmap& aBitmap) { return checkRectangles(aBitmap, true); } TestResult OutputDeviceTestCommon::checkFilledRectangle(Bitmap& aBitmap, bool useLineColor) { std::vector aExpected{ constBackgroundColor, useLineColor ? constLineColor : constFillColor, constFillColor, constFillColor, constFillColor }; BitmapScopedWriteAccess pAccess(aBitmap); TestResult aResult = TestResult::Passed; int nNumberOfQuirks = 0; int nNumberOfErrors = 0; for (size_t aLayerNumber = 0; aLayerNumber < aExpected.size(); aLayerNumber++) { tools::Long startX = aLayerNumber, endX = pAccess->Width() / 2 - aLayerNumber + 1; tools::Long startY = aLayerNumber, endY = pAccess->Height() - aLayerNumber - 1; for (tools::Long ptX = startX; ptX <= endX; ++ptX) { checkValue(pAccess, ptX, startY, aExpected[aLayerNumber], nNumberOfQuirks, nNumberOfErrors, true); checkValue(pAccess, ptX, endY, aExpected[aLayerNumber], nNumberOfQuirks, nNumberOfErrors, true); } for (tools::Long ptY = startY; ptY <= endY; ++ptY) { checkValue(pAccess, startX, ptY, aExpected[aLayerNumber], nNumberOfQuirks, nNumberOfErrors, true); checkValue(pAccess, endX, ptY, aExpected[aLayerNumber], nNumberOfQuirks, nNumberOfErrors, true); } } if (nNumberOfQuirks > 0) aResult = TestResult::PassedWithQuirks; if (nNumberOfErrors > 0) aResult = TestResult::Failed; return aResult; } TestResult OutputDeviceTestCommon::checkFilled(Bitmap& rBitmap, tools::Rectangle aRectangle, Color aExpectedColor) { BitmapScopedWriteAccess pAccess(rBitmap); TestResult aResult = TestResult::Passed; int nNumberOfQuirks = 0; int nNumberOfErrors = 0; for (tools::Long y = aRectangle.Top(); y < aRectangle.Top() + aRectangle.GetHeight(); y++) { for (tools::Long x = aRectangle.Left(); x < aRectangle.Left() + aRectangle.GetWidth(); x++) { checkValue(pAccess, x, y, aExpectedColor, nNumberOfQuirks, nNumberOfErrors, false); } } if (nNumberOfQuirks > 0) aResult = TestResult::PassedWithQuirks; if (nNumberOfErrors > 0) aResult = TestResult::Failed; return aResult; } TestResult OutputDeviceTestCommon::checkRectangles(Bitmap& aBitmap, std::vector& aExpectedColors) { TestResult aReturnValue = TestResult::Passed; for (size_t i = 0; i < aExpectedColors.size(); i++) { TestResult eResult = checkRect(aBitmap, i, aExpectedColors[i]); if (eResult == TestResult::Failed) aReturnValue = TestResult::Failed; if (eResult == TestResult::PassedWithQuirks && aReturnValue != TestResult::Failed) aReturnValue = TestResult::PassedWithQuirks; } return aReturnValue; } TestResult OutputDeviceTestCommon::checkRectangle(Bitmap& rBitmap, int aLayerNumber, Color aExpectedColor) { return checkRect(rBitmap, aLayerNumber, aExpectedColor); } tools::Rectangle OutputDeviceTestCommon::alignToCenter(tools::Rectangle aRect1, tools::Rectangle aRect2) { Point aPoint((aRect1.GetWidth() / 2.0) - (aRect2.GetWidth() / 2.0), (aRect1.GetHeight() / 2.0) - (aRect2.GetHeight() / 2.0)); return tools::Rectangle(aPoint, aRect2.GetSize()); } TestResult OutputDeviceTestCommon::checkDiamond(Bitmap& rBitmap) { return checkDiamondLine(rBitmap, 1, constLineColor); } void OutputDeviceTestCommon::createDiamondPoints(tools::Rectangle rRect, int nOffset, Point& rPoint1, Point& rPoint2, Point& rPoint3, Point& rPoint4) { tools::Long midPointX = rRect.Left() + (rRect.Right() - rRect.Left()) / 2.0; tools::Long midPointY = rRect.Top() + (rRect.Bottom() - rRect.Top()) / 2.0; rPoint1 = Point(midPointX , midPointY - nOffset); rPoint2 = Point(midPointX + nOffset, midPointY ); rPoint3 = Point(midPointX , midPointY + nOffset); rPoint4 = Point(midPointX - nOffset, midPointY ); } tools::Polygon OutputDeviceTestCommon::createDropShapePolygon() { tools::Polygon aPolygon(15); aPolygon.SetPoint(Point(10, 2), 0); aPolygon.SetFlags(0, PolyFlags::Normal); aPolygon.SetPoint(Point(14, 2), 1); aPolygon.SetFlags(1, PolyFlags::Control); aPolygon.SetPoint(Point(18, 6), 2); aPolygon.SetFlags(2, PolyFlags::Control); aPolygon.SetPoint(Point(18, 10), 3); aPolygon.SetFlags(3, PolyFlags::Normal); aPolygon.SetPoint(Point(18, 10), 4); aPolygon.SetFlags(4, PolyFlags::Normal); aPolygon.SetPoint(Point(18, 14), 5); aPolygon.SetFlags(5, PolyFlags::Control); aPolygon.SetPoint(Point(14, 18), 6); aPolygon.SetFlags(6, PolyFlags::Control); aPolygon.SetPoint(Point(10, 18), 7); aPolygon.SetFlags(7, PolyFlags::Normal); aPolygon.SetPoint(Point(10, 18), 8); aPolygon.SetFlags(8, PolyFlags::Normal); aPolygon.SetPoint(Point(6, 18), 9); aPolygon.SetFlags(9, PolyFlags::Control); aPolygon.SetPoint(Point(2, 14), 10); aPolygon.SetFlags(10, PolyFlags::Control); aPolygon.SetPoint(Point(2, 10), 11); aPolygon.SetFlags(11, PolyFlags::Normal); aPolygon.SetPoint(Point(2, 10), 12); aPolygon.SetFlags(12, PolyFlags::Normal); aPolygon.SetPoint(Point(2, 2), 13); aPolygon.SetFlags(13, PolyFlags::Normal); aPolygon.SetPoint(Point(10, 2), 14); aPolygon.SetFlags(14, PolyFlags::Normal); aPolygon.Optimize(PolyOptimizeFlags::CLOSE); return aPolygon; } basegfx::B2DPolygon OutputDeviceTestCommon::createHalfEllipsePolygon() { basegfx::B2DPolygon aPolygon; aPolygon.append({ 9.0, 1.0 }); aPolygon.append({ 17.0, 10.0 }); aPolygon.append({ 1.0, 10.0 }); aPolygon.setClosed(true); aPolygon.setControlPoints(0, { 1.5, 1.5 }, { 16.5, 1.5 }); return aPolygon; } tools::Polygon OutputDeviceTestCommon::createClosedBezierLoop(const tools::Rectangle& rRect) { tools::Long minX = rRect.Left(); tools::Long maxX = rRect.Right() - 2; tools::Long minY = rRect.Top(); tools::Long maxY = rRect.Bottom() - 2; tools::Polygon aPolygon(4); aPolygon.SetPoint(Point((maxX / 2.0), maxY), 0); aPolygon.SetFlags(0, PolyFlags::Normal); aPolygon.SetPoint(Point(maxX, minY), 1); aPolygon.SetFlags(1, PolyFlags::Control); aPolygon.SetPoint(Point(minX, minY), 2); aPolygon.SetFlags(2, PolyFlags::Control); aPolygon.SetPoint(Point((maxX / 2.0), maxY), 3); aPolygon.SetFlags(3, PolyFlags::Normal); aPolygon.Optimize(PolyOptimizeFlags::CLOSE); return aPolygon; } basegfx::B2DPolygon OutputDeviceTestCommon::createOpenPolygon(const tools::Rectangle& rRect, int nOffset) { int nMidOffset = rRect.GetWidth() / 2; basegfx::B2DPolygon aPolygon{ basegfx::B2DPoint(rRect.Left() + nOffset - (nOffset + 1) / 2, rRect.Top() + nOffset - 1), basegfx::B2DPoint(rRect.Left() + nOffset - (nOffset + 1) / 2, rRect.Bottom() - nOffset + 1), basegfx::B2DPoint(rRect.Right() - nMidOffset - nOffset / 3, rRect.Bottom() - nOffset + 1), basegfx::B2DPoint(rRect.Right() - nMidOffset - nOffset / 3, rRect.Top() + nOffset - 1), }; aPolygon.setClosed(false); return aPolygon; } basegfx::B2DPolygon OutputDeviceTestCommon::createOpenBezier() { basegfx::B2DPolygon aPolygon; aPolygon.append({ 5.0, 2.0 }); aPolygon.append({ 3.0, 14.0 }); aPolygon.setClosed(false); aPolygon.setControlPoints(0, { 15.0, 2.0 }, { 15.0, 15.0 }); return aPolygon; } TestResult OutputDeviceTestCommon::checkDropShape(Bitmap& rBitmap, bool aEnableAA) { BitmapScopedWriteAccess pAccess(rBitmap); TestResult aResult = TestResult::Passed; int nNumberOfQuirks = 0; int nNumberOfErrors = 0; std::map, bool> SetPixels = { { { 2, 2 }, true }, { { 3, 2 }, true }, { { 4, 2 }, true }, { { 5, 2 }, true }, { { 6, 2 }, true }, { { 7, 2 }, true }, { { 8, 2 }, true }, { { 9, 2 }, true }, { { 10, 2 }, true }, { { 11, 2 }, true }, { { 12, 2 }, true }, { { 2, 3 }, true }, { { 13, 3 }, true }, { { 14, 3 }, true }, { { 2, 4 }, true }, { { 15, 4 }, true }, { { 2, 5 }, true }, { { 16, 5 }, true }, { { 2, 6 }, true }, { { 17, 6 }, true }, { { 2, 7 }, true }, { { 17, 7 }, true }, { { 2, 8 }, true }, { { 18, 8 }, true }, { { 2, 9 }, true }, { { 18, 9 }, true }, { { 2, 10 }, true }, { { 18, 10 }, true }, { { 2, 11 }, true }, { { 18, 11 }, true }, { { 2, 12 }, true }, { { 18, 12 }, true }, { { 3, 13 }, true }, { { 17, 13 }, true }, { { 3, 14 }, true }, { { 17, 14 }, true }, { { 4, 15 }, true }, { { 16, 15 }, true }, { { 5, 16 }, true }, { { 15, 16 }, true }, { { 6, 17 }, true }, { { 7, 17 }, true }, { { 13, 17 }, true }, { { 14, 17 }, true }, { { 8, 18 }, true }, { { 9, 18 }, true }, { { 10, 18 }, true }, { { 11, 18 }, true }, { { 12, 18 }, true } }; for (tools::Long x = 0; x < pAccess->Width(); x++) { for (tools::Long y = 0; y < pAccess->Height(); y++) { if (SetPixels[{ x, y }]) { if (aEnableAA) { // coverity[swapped_arguments : FALSE] - this is in the correct order checkValueAA(pAccess, y, x, constLineColor, nNumberOfQuirks, nNumberOfErrors); } else checkValue(pAccess, y, x, constLineColor, nNumberOfQuirks, nNumberOfErrors, true); } else { if (!aEnableAA) checkValue(pAccess, y, x, constBackgroundColor, nNumberOfQuirks, nNumberOfErrors, true); } } } if (nNumberOfQuirks > 0) aResult = TestResult::PassedWithQuirks; if (nNumberOfErrors > 0) aResult = TestResult::Failed; return aResult; } void OutputDeviceTestCommon::createHorizontalVerticalDiagonalLinePoints(tools::Rectangle rRect, Point& rHorizontalLinePoint1, Point& rHorizontalLinePoint2, Point& rVerticalLinePoint1, Point& rVerticalLinePoint2, Point& rDiagonalLinePoint1, Point& rDiagonalLinePoint2) { rHorizontalLinePoint1 = Point(4, 1); rHorizontalLinePoint2 = Point(rRect.Right() - 1, 1); rVerticalLinePoint1 = Point(1, 4); rVerticalLinePoint2 = Point(1,rRect.Bottom() - 1); rDiagonalLinePoint1 = Point(1, 1); rDiagonalLinePoint2 = Point(rRect.Right() - 1, rRect.Bottom() - 1); } TestResult OutputDeviceTestCommon::checkBezier(Bitmap& rBitmap) { std::vector aExpected { constBackgroundColor, constBackgroundColor }; // Check the bezier doesn't go over to the margins first // TODO extend the check with more exact assert return checkRectangles(rBitmap, aExpected); } TestResult OutputDeviceTestCommon::checkHalfEllipse(Bitmap& rBitmap, bool aEnableAA) { BitmapScopedWriteAccess pAccess(rBitmap); TestResult aResult = TestResult::Passed; int nNumberOfQuirks = 0; int nNumberOfErrors = 0; std::map, bool> SetPixels = { { { 8, 1 }, true }, { { 9, 1 }, true }, { { 10, 1 }, true }, { { 6, 2 }, true }, { { 7, 2 }, true }, { { 10, 2 }, true }, { { 4, 3 }, true }, { { 5, 3 }, true }, { { 10, 3 }, true }, { { 3, 4 }, true }, { { 10, 4 }, true }, { { 2, 5 }, true }, { { 10, 5 }, true }, { { 2, 6 }, true }, { { 10, 6 }, true }, { { 1, 7 }, true }, { { 10, 7 }, true }, { { 1, 8 }, true }, { { 10, 8 }, true }, { { 1, 9 }, true }, { { 10, 9 }, true }, { { 1, 10 }, true }, { { 10, 10 }, true }, { { 1, 11 }, true }, { { 10, 11 }, true }, { { 2, 12 }, true }, { { 10, 12 }, true }, { { 2, 13 }, true }, { { 10, 13 }, true }, { { 3, 14 }, true }, { { 10, 14 }, true }, { { 4, 15 }, true }, { { 5, 15 }, true }, { { 10, 15 }, true }, { { 6, 16 }, true }, { { 7, 16 }, true }, { { 10, 16 }, true }, { { 8, 17 }, true }, { { 9, 17 }, true }, { { 10, 17 }, true } }; for (tools::Long x = 0; x < pAccess->Width(); x++) { for (tools::Long y = 0; y < pAccess->Height(); ++y) { // coverity[swapped_arguments : FALSE] - this is in the correct order if (SetPixels[{ y, x }]) { if (aEnableAA) checkValueAA(pAccess, x, y, constLineColor, nNumberOfQuirks, nNumberOfErrors); else checkValue(pAccess, x, y, constLineColor, nNumberOfQuirks, nNumberOfErrors, true); } else { if (!aEnableAA) checkValue(pAccess, x, y, constBackgroundColor, nNumberOfQuirks, nNumberOfErrors, true); } } } if (nNumberOfQuirks > 0) aResult = TestResult::PassedWithQuirks; if (nNumberOfErrors > 0) aResult = TestResult::Failed; return aResult; } TestResult OutputDeviceTestCommon::checkClosedBezier(Bitmap& rBitmap) { BitmapScopedWriteAccess pAccess(rBitmap); TestResult aResult = TestResult::Passed; int nNumberOfQuirks = 0; int nNumberOfErrors = 0; std::map, bool> SetPixels = { { { 3, 8 }, true }, { { 3, 9 }, true }, { { 3, 10 }, true }, { { 4, 7 }, true }, { { 4, 8 }, true }, { { 4, 9 }, true }, { { 4, 10 }, true }, { { 4, 11 }, true }, { { 5, 7 }, true }, { { 5, 11 }, true }, { { 6, 6 }, true }, { { 6, 12 }, true }, { { 7, 6 }, true }, { { 7, 12 }, true }, { { 8, 7 }, true }, { { 8, 11 }, true }, { { 9, 7 }, true }, { { 9, 11 }, true }, { { 10, 7 }, true }, { { 10, 11 }, true }, { { 11, 8 }, true }, { { 11, 9 }, true }, { { 11, 10 }, true }, { { 12, 8 }, true }, { { 12, 9 }, true }, { { 12, 10 }, true }, { { 13, 9 }, true } }; for (tools::Long x = 0; x < pAccess->Width(); x++) { for (tools::Long y = 0; y < pAccess->Height(); ++y) { // coverity[swapped_arguments : FALSE] - this is in the correct order if (SetPixels[{ y, x }]) { checkValue(pAccess, x, y, constLineColor, nNumberOfQuirks, nNumberOfErrors, true); } else { checkValue(pAccess, x, y, constBackgroundColor, nNumberOfQuirks, nNumberOfErrors, true); } } } if (nNumberOfQuirks > 0) aResult = TestResult::PassedWithQuirks; if (nNumberOfErrors > 0 || !checkConvexHullProperty(rBitmap, constLineColor, 2, 2)) aResult = TestResult::Failed; return aResult; } TestResult OutputDeviceTestCommon::checkOpenBezier(Bitmap& rBitmap) { BitmapScopedWriteAccess pAccess(rBitmap); TestResult aResult = TestResult::Passed; int nNumberOfQuirks = 0; int nNumberOfErrors = 0; std::map, bool> SetPixels = { { { 14, 3 }, true }, { { 14, 4 }, true }, { { 14, 5 }, true }, { { 3, 6 }, true }, { { 4, 6 }, true }, { { 14, 6 }, true }, { { 4, 7 }, true }, { { 5, 7 }, true }, { { 13, 7 }, true }, { { 6, 8 }, true }, { { 7, 8 }, true }, { { 12, 8 }, true }, { { 13, 8 }, true }, { { 8, 9 }, true }, { { 9, 9 }, true }, { { 10, 9 }, true }, { { 11, 9 }, true }, { { 12, 9 }, true } }; for (tools::Long x = 0; x < pAccess->Width(); x++) { for (tools::Long y = 0; y < pAccess->Height(); ++y) { // coverity[swapped_arguments : FALSE] - this is in the correct order if (SetPixels[{ y, x }]) { checkValue(pAccess, x, y, constLineColor, nNumberOfQuirks, nNumberOfErrors, true); } else { checkValue(pAccess, x, y, constBackgroundColor, nNumberOfQuirks, nNumberOfErrors, true); } } } if (nNumberOfQuirks > 0) aResult = TestResult::PassedWithQuirks; if (nNumberOfErrors > 0 || !checkConvexHullProperty(rBitmap, constLineColor, 2, 5)) aResult = TestResult::Failed; return aResult; } TestResult OutputDeviceTestCommon::checkFilledAsymmetricalDropShape(Bitmap& rBitmap) { BitmapScopedWriteAccess pAccess(rBitmap); TestResult aResult = TestResult::Passed; int nNumberOfQuirks = 0; int nNumberOfErrors = 0; std::map, bool> SetPixels = { { { 2, 2 }, true }, { { 3, 2 }, true }, { { 4, 2 }, true }, { { 5, 2 }, true }, { { 6, 2 }, true }, { { 7, 2 }, true }, { { 8, 2 }, true }, { { 9, 2 }, true }, { { 10, 2 }, true }, { { 11, 2 }, true }, { { 2, 3 }, true }, { { 3, 3 }, true }, { { 4, 3 }, true }, { { 5, 3 }, true }, { { 6, 3 }, true }, { { 7, 3 }, true }, { { 8, 3 }, true }, { { 9, 3 }, true }, { { 10, 3 }, true }, { { 11, 3 }, true }, { { 12, 3 }, true }, { { 13, 3 }, true }, { { 2, 4 }, true }, { { 3, 4 }, true }, { { 4, 4 }, true }, { { 5, 4 }, true }, { { 6, 4 }, true }, { { 7, 4 }, true }, { { 8, 4 }, true }, { { 9, 4 }, true }, { { 10, 4 }, true }, { { 11, 4 }, true }, { { 12, 4 }, true }, { { 13, 4 }, true }, { { 14, 4 }, true }, { { 15, 4 }, true }, { { 2, 5 }, true }, { { 3, 5 }, true }, { { 4, 5 }, true }, { { 5, 5 }, true }, { { 6, 5 }, true }, { { 7, 5 }, true }, { { 8, 5 }, true }, { { 9, 5 }, true }, { { 10, 5 }, true }, { { 11, 5 }, true }, { { 12, 5 }, true }, { { 13, 5 }, true }, { { 14, 5 }, true }, { { 15, 5 }, true }, { { 2, 6 }, true }, { { 3, 6 }, true }, { { 4, 6 }, true }, { { 5, 6 }, true }, { { 6, 6 }, true }, { { 7, 6 }, true }, { { 8, 6 }, true }, { { 9, 6 }, true }, { { 10, 6 }, true }, { { 11, 6 }, true }, { { 12, 6 }, true }, { { 13, 6 }, true }, { { 14, 6 }, true }, { { 15, 6 }, true }, { { 16, 6 }, true }, { { 2, 7 }, true }, { { 3, 7 }, true }, { { 4, 7 }, true }, { { 5, 7 }, true }, { { 6, 7 }, true }, { { 7, 7 }, true }, { { 8, 7 }, true }, { { 9, 7 }, true }, { { 10, 7 }, true }, { { 11, 7 }, true }, { { 12, 7 }, true }, { { 13, 7 }, true }, { { 14, 7 }, true }, { { 15, 7 }, true }, { { 16, 7 }, true }, { { 2, 8 }, true }, { { 3, 8 }, true }, { { 4, 8 }, true }, { { 5, 8 }, true }, { { 6, 8 }, true }, { { 7, 8 }, true }, { { 8, 8 }, true }, { { 9, 8 }, true }, { { 10, 8 }, true }, { { 11, 8 }, true }, { { 12, 8 }, true }, { { 13, 8 }, true }, { { 14, 8 }, true }, { { 15, 8 }, true }, { { 16, 8 }, true }, { { 17, 8 }, true }, { { 2, 9 }, true }, { { 3, 9 }, true }, { { 4, 9 }, true }, { { 5, 9 }, true }, { { 6, 9 }, true }, { { 7, 9 }, true }, { { 8, 9 }, true }, { { 9, 9 }, true }, { { 10, 9 }, true }, { { 11, 9 }, true }, { { 12, 9 }, true }, { { 13, 9 }, true }, { { 14, 9 }, true }, { { 15, 9 }, true }, { { 16, 9 }, true }, { { 17, 9 }, true }, { { 2, 10 }, true }, { { 3, 10 }, true }, { { 4, 10 }, true }, { { 5, 10 }, true }, { { 6, 10 }, true }, { { 7, 10 }, true }, { { 8, 10 }, true }, { { 9, 10 }, true }, { { 10, 10 }, true }, { { 11, 10 }, true }, { { 12, 10 }, true }, { { 13, 10 }, true }, { { 14, 10 }, true }, { { 15, 10 }, true }, { { 16, 10 }, true }, { { 17, 10 }, true }, { { 2, 11 }, true }, { { 3, 11 }, true }, { { 4, 11 }, true }, { { 5, 11 }, true }, { { 6, 11 }, true }, { { 7, 11 }, true }, { { 8, 11 }, true }, { { 9, 11 }, true }, { { 10, 11 }, true }, { { 11, 11 }, true }, { { 12, 11 }, true }, { { 13, 11 }, true }, { { 14, 11 }, true }, { { 15, 11 }, true }, { { 16, 11 }, true }, { { 17, 11 }, true }, { { 3, 12 }, true }, { { 4, 12 }, true }, { { 5, 12 }, true }, { { 6, 12 }, true }, { { 7, 12 }, true }, { { 8, 12 }, true }, { { 9, 12 }, true }, { { 10, 12 }, true }, { { 11, 12 }, true }, { { 12, 12 }, true }, { { 13, 12 }, true }, { { 14, 12 }, true }, { { 15, 12 }, true }, { { 16, 12 }, true }, { { 3, 13 }, true }, { { 4, 13 }, true }, { { 5, 13 }, true }, { { 6, 13 }, true }, { { 7, 13 }, true }, { { 8, 13 }, true }, { { 9, 13 }, true }, { { 10, 13 }, true }, { { 11, 13 }, true }, { { 12, 13 }, true }, { { 13, 13 }, true }, { { 14, 13 }, true }, { { 15, 13 }, true }, { { 16, 13 }, true }, { { 4, 14 }, true }, { { 5, 14 }, true }, { { 6, 14 }, true }, { { 7, 14 }, true }, { { 8, 14 }, true }, { { 9, 14 }, true }, { { 10, 14 }, true }, { { 11, 14 }, true }, { { 12, 14 }, true }, { { 13, 14 }, true }, { { 14, 14 }, true }, { { 15, 14 }, true }, { { 5, 15 }, true }, { { 6, 15 }, true }, { { 7, 15 }, true }, { { 8, 15 }, true }, { { 9, 15 }, true }, { { 10, 15 }, true }, { { 11, 15 }, true }, { { 12, 15 }, true }, { { 13, 15 }, true }, { { 14, 15 }, true }, { { 15, 15 }, true }, { { 6, 16 }, true }, { { 7, 16 }, true }, { { 8, 16 }, true }, { { 9, 16 }, true }, { { 10, 16 }, true }, { { 11, 16 }, true }, { { 12, 16 }, true }, { { 13, 16 }, true }, { { 8, 17 }, true }, { { 9, 17 }, true }, { { 10, 17 }, true }, { { 11, 17 }, true } }; for (tools::Long x = 0; x < pAccess->Width(); x++) { for (tools::Long y = 0; y < pAccess->Height(); ++y) { if (SetPixels[{ x, y }]) { checkValue(pAccess, y, x, constFillColor, nNumberOfQuirks, nNumberOfErrors, true); } else { checkValue(pAccess, y, x, constBackgroundColor, nNumberOfQuirks, nNumberOfErrors, true); } } } if (nNumberOfQuirks > 0) aResult = TestResult::PassedWithQuirks; if (nNumberOfErrors > 0) aResult = TestResult::Failed; return aResult; } TestResult OutputDeviceTestCommon::checkTextLocation(Bitmap& rBitmap) { BitmapScopedWriteAccess pAccess(rBitmap); TestResult aResult = TestResult::Passed; //The limit to which error would be tolerated. tools::Long textThreshold = 3; tools::Long textWidth = 3, textHeight = 8; tools::Long deviationX = 0, deviationY = 0; tools::Long verticalStart = 0, verticalEnd = 0; tools::Long horizontalStart = 0, horizontalEnd = 0; tools::Long midX = pAccess->Width() / 2.0; tools::Long midY = pAccess->Height() / 2.0; bool insideFlag = false; //Traversing horizontally for (tools::Long x = 0, y = pAccess->Height() / 2.0; x < pAccess->Width(); ++x) { if (pAccess->GetPixel(y, x) != constBackgroundColor) { if (!insideFlag) { horizontalStart = x; insideFlag = true; } else { horizontalEnd = x; } } } deviationX = abs(midX - horizontalStart); midY -= midY / 2.0; midY += 1; insideFlag = false; //Traversing vertically for (tools::Long x = 0, y = pAccess->Height() / 2.0; x < pAccess->Height(); ++x) { if (pAccess->GetPixel(x, y) != constBackgroundColor) { if (!insideFlag) { verticalStart = x; insideFlag = true; } else { verticalEnd = x; } } } deviationY = abs(midY - verticalStart); if (deviationX != 0 || deviationY != 0 || abs(horizontalStart - horizontalEnd) + 1 != textWidth || abs(verticalStart - verticalEnd) + 1 != textHeight) { aResult = TestResult::PassedWithQuirks; } if (deviationX > textThreshold || deviationY > textThreshold || abs((abs(horizontalStart - horizontalEnd) + 1) - textWidth) > textThreshold || abs((abs(verticalStart - verticalEnd) + 1) - textHeight) > textThreshold) { aResult = TestResult::Failed; } return aResult; } TestResult OutputDeviceTestCommon::checkIntersectingRecs(Bitmap& rBitmap, int aLayerNumber, Color aExpected) { BitmapScopedWriteAccess pAccess(rBitmap); TestResult aResult = TestResult::Passed; int nNumberOfQuirks = 0; int nNumberOfErrors = 0; for (int x = 4; x <= 19; ++x) { checkValue(pAccess, x, aLayerNumber, aExpected, nNumberOfQuirks, nNumberOfErrors, true); } if (nNumberOfQuirks > 0) aResult = TestResult::PassedWithQuirks; if (nNumberOfErrors > 0) aResult = TestResult::Failed; return aResult; } TestResult OutputDeviceTestCommon::checkEvenOddRuleInIntersectingRecs(Bitmap& rBitmap) { /* The even-odd rule would be tested via the below pattern as layers both of the constFillColor & constBackgroundColor appears in an even-odd fashion. */ std::vector aExpectedColors = { constBackgroundColor, constBackgroundColor, constLineColor, constFillColor, constFillColor, constLineColor, constBackgroundColor, constBackgroundColor, constLineColor, constFillColor, constFillColor, constLineColor, constBackgroundColor, constBackgroundColor, constLineColor, constFillColor, constFillColor, constLineColor, constBackgroundColor, constBackgroundColor, constLineColor, constFillColor, constLineColor }; TestResult aReturnValue = TestResult::Passed; for (size_t i = 0; i < aExpectedColors.size(); i++) { TestResult eResult = checkIntersectingRecs(rBitmap, i, aExpectedColors[i]); if (eResult == TestResult::Failed) aReturnValue = TestResult::Failed; if (eResult == TestResult::PassedWithQuirks && aReturnValue != TestResult::Failed) aReturnValue = TestResult::PassedWithQuirks; } return aReturnValue; } TestResult OutputDeviceTestCommon::checkOpenPolygon(Bitmap& rBitmap, bool aEnableAA) { std::vector aExpected = { constBackgroundColor, constLineColor, constLineColor }; BitmapScopedWriteAccess pAccess(rBitmap); TestResult aResult = TestResult::Passed; int nNumberOfQuirks = 0; int nNumberOfErrors = 0; for (size_t aLayerNumber = 0; aLayerNumber < aExpected.size(); aLayerNumber++) { tools::Long startX = aLayerNumber + 1, endX = pAccess->Width() / 2 - aLayerNumber; tools::Long startY = aLayerNumber + 2, endY = pAccess->Height() - aLayerNumber - 3; for (tools::Long ptX = startX; ptX <= endX; ++ptX) { if (aEnableAA) { checkValueAA(pAccess, ptX, endY - (aLayerNumber == 2 ? 2 : 0), aExpected[aLayerNumber], nNumberOfQuirks, nNumberOfErrors); } else { checkValue(pAccess, ptX, endY - (aLayerNumber == 2 ? 2 : 0), aExpected[aLayerNumber], nNumberOfQuirks, nNumberOfErrors, true); } } for (tools::Long ptY = startY + (aLayerNumber == 2 ? 2 : 0); ptY <= endY - (aLayerNumber == 2 ? 2 : 0); ++ptY) { if (aEnableAA) { checkValueAA(pAccess, startX, ptY, aExpected[aLayerNumber], nNumberOfQuirks, nNumberOfErrors); checkValueAA(pAccess, endX, ptY, aExpected[aLayerNumber], nNumberOfQuirks, nNumberOfErrors); } else { checkValue(pAccess, startX, ptY, aExpected[aLayerNumber], nNumberOfQuirks, nNumberOfErrors, true); checkValue(pAccess, endX, ptY, aExpected[aLayerNumber], nNumberOfQuirks, nNumberOfErrors, true); } } } if (nNumberOfQuirks > 0) aResult = TestResult::PassedWithQuirks; if (nNumberOfErrors > 0) aResult = TestResult::Failed; return aResult; } // Check 'count' pixels from (x,y) in (addX,addY) direction, the color values must not decrease. static bool checkGradient(BitmapScopedWriteAccess& pAccess, int x, int y, int count, int addX, int addY) { const bool bColorize = false; Color maxColor = COL_BLACK; for( int i = 0; i < count; ++i ) { Color color = pAccess->GetPixel(y, x); if( color.GetRed() < maxColor.GetRed() || color.GetGreen() < maxColor.GetGreen() || color.GetBlue() < maxColor.GetBlue()) { if (bColorize) pAccess->SetPixel(y, x, COL_RED); return false; } maxColor = color; if (bColorize) pAccess->SetPixel(y, x, COL_LIGHTGREEN); x += addX; y += addY; } return true; } TestResult OutputDeviceTestCommon::checkLinearGradient(Bitmap& bitmap) { BitmapScopedWriteAccess pAccess(bitmap); TestResult aResult = TestResult::Passed; int nNumberOfQuirks = 0; int nNumberOfErrors = 0; // The lowest line is missing in the default VCL implementation => quirk. checkValue(pAccess, 1, 10, COL_WHITE, nNumberOfQuirks, nNumberOfErrors, true, 255 / 10); checkValue(pAccess, 10, 10, COL_BLACK, nNumberOfQuirks, nNumberOfErrors, true, 255 / 10); for(int y = 1; y < 10; ++y) { checkValue(pAccess, 1, y, COL_WHITE, nNumberOfQuirks, nNumberOfErrors, 255 / 10); checkValue(pAccess, 10, y, COL_BLACK, nNumberOfQuirks, nNumberOfErrors, 255 / 10); } for(int y = 1; y < 10; ++y) if( !checkGradient( pAccess, 10, y, 10, -1, 0 )) return TestResult::Failed; if (nNumberOfQuirks > 0) checkResult(TestResult::PassedWithQuirks, aResult); if (nNumberOfErrors > 0) checkResult(TestResult::Failed, aResult); return aResult; } TestResult OutputDeviceTestCommon::checkLinearGradientAngled(Bitmap& bitmap) { BitmapScopedWriteAccess pAccess(bitmap); TestResult aResult = TestResult::Passed; int nNumberOfQuirks = 0; int nNumberOfErrors = 0; // The top-left pixel is not white but gray in the default VCL implementation => quirk. checkValue(pAccess, 1, 1, COL_WHITE, nNumberOfQuirks, nNumberOfErrors, 50); checkValue(pAccess, 10, 10, COL_BLACK, nNumberOfQuirks, nNumberOfErrors, 0, 255 / 10); // Bottom-right. // Main diagonal. if( !checkGradient( pAccess, 10, 10, 10, -1, -1 )) return TestResult::Failed; if (nNumberOfQuirks > 0) checkResult(TestResult::PassedWithQuirks, aResult); if (nNumberOfErrors > 0) checkResult(TestResult::Failed, aResult); return TestResult::Passed; } TestResult OutputDeviceTestCommon::checkLinearGradientBorder(Bitmap& bitmap) { TestResult aResult = TestResult::Passed; // Top half is border. checkResult(checkFilled(bitmap, tools::Rectangle(Point(1, 1), Size(10, 5)), COL_WHITE), aResult); BitmapScopedWriteAccess pAccess(bitmap); int nNumberOfQuirks = 0; int nNumberOfErrors = 0; for(int x = 1; x <= 10; ++x) { checkValue(pAccess, x, 10, COL_BLACK, nNumberOfQuirks, nNumberOfErrors, 255 / 10, 255 / 5); if( !checkGradient( pAccess, x, 10, 5, 0, -1 )) return TestResult::Failed; } if (nNumberOfQuirks > 0) checkResult(TestResult::PassedWithQuirks, aResult); if (nNumberOfErrors > 0) checkResult(TestResult::Failed, aResult); return aResult; } TestResult OutputDeviceTestCommon::checkLinearGradientIntensity(Bitmap& bitmap) { BitmapScopedWriteAccess pAccess(bitmap); TestResult aResult = TestResult::Passed; int nNumberOfQuirks = 0; int nNumberOfErrors = 0; for(int x = 1; x <= 10; ++x) { // The gradient starts at half intensity, i.e. white's 255's are halved. checkValue(pAccess, x, 1, Color(128,128,128), nNumberOfQuirks, nNumberOfErrors, false, 10); checkValue(pAccess, x, 10, COL_BLACK, nNumberOfQuirks, nNumberOfErrors, 255 / 10); if( !checkGradient( pAccess, x, 10, 10, 0, -1 )) return TestResult::Failed; } if (nNumberOfQuirks > 0) checkResult(TestResult::PassedWithQuirks, aResult); if (nNumberOfErrors > 0) checkResult(TestResult::Failed, aResult); return aResult; } TestResult OutputDeviceTestCommon::checkLinearGradientSteps(Bitmap& bitmap) { // Reuse the basic linear gradient check. TestResult aResult = checkLinearGradient(bitmap); // Only 4 steps in the gradient, there should be only 4 colors. if( collectColors( bitmap, tools::Rectangle( Point( 1, 1 ), Size( 10, 10 ))).size() != 4 ) return TestResult::Failed; return aResult; } TestResult OutputDeviceTestCommon::checkAxialGradient(Bitmap& bitmap) { BitmapScopedWriteAccess pAccess(bitmap); TestResult aResult = TestResult::Passed; int nNumberOfQuirks = 0; int nNumberOfErrors = 0; for(int y = 1; y <= 11; ++y) { // Middle horizontal line is white, gradients to the sides. checkValue(pAccess, 6, y, COL_WHITE, nNumberOfQuirks, nNumberOfErrors, 255 / 10, 255 / 5); checkValue(pAccess, 1, y, COL_BLACK, nNumberOfQuirks, nNumberOfErrors, 255 / 10, 255 / 5); checkValue(pAccess, 11, y, COL_BLACK, nNumberOfQuirks, nNumberOfErrors, 255 / 10, 255 / 5); if( !checkGradient( pAccess, 1, y, 6, 1, 0 )) return TestResult::Failed; if( !checkGradient( pAccess, 11, y, 6, -1, 0 )) return TestResult::Failed; } if (nNumberOfQuirks > 0) checkResult(TestResult::PassedWithQuirks, aResult); if (nNumberOfErrors > 0) checkResult(TestResult::Failed, aResult); return aResult; } TestResult OutputDeviceTestCommon::checkRadialGradient(Bitmap& bitmap) { BitmapScopedWriteAccess pAccess(bitmap); TestResult aResult = TestResult::Passed; int nNumberOfQuirks = 0; int nNumberOfErrors = 0; // The default VCL implementation is off-center in the direction to the top-left. // This means not all corners will be pure white => quirks. checkValue(pAccess, 1, 1, COL_WHITE, nNumberOfQuirks, nNumberOfErrors, 255 / 10, 255 / 2); checkValue(pAccess, 1, 10, COL_WHITE, nNumberOfQuirks, nNumberOfErrors, 255 / 10, 255 / 5); checkValue(pAccess, 10, 1, COL_WHITE, nNumberOfQuirks, nNumberOfErrors, 255 / 10, 255 / 5); checkValue(pAccess, 10, 10, COL_WHITE, nNumberOfQuirks, nNumberOfErrors, 255 / 10, 255 / 5); // And not all centers will be pure black => quirks. checkValue(pAccess, 5, 5, COL_BLACK, nNumberOfQuirks, nNumberOfErrors, 255 / 10, 255 / 5); checkValue(pAccess, 5, 6, COL_BLACK, nNumberOfQuirks, nNumberOfErrors, 255 / 10, 255 / 3); checkValue(pAccess, 6, 5, COL_BLACK, nNumberOfQuirks, nNumberOfErrors, 255 / 10, 255 / 3); checkValue(pAccess, 6, 6, COL_BLACK, nNumberOfQuirks, nNumberOfErrors, 255 / 10, 255 / 2); // Check diagonals, from the offset center. if(!checkGradient(pAccess, 5, 5, 5, -1, -1)) return TestResult::Failed; if(!checkGradient(pAccess, 5, 5, 6, 1, 1)) return TestResult::Failed; if(!checkGradient(pAccess, 5, 5, 5, 1, -1)) return TestResult::Failed; if(!checkGradient(pAccess, 5, 5, 5, -1, 1)) return TestResult::Failed; if (nNumberOfQuirks > 0) checkResult(TestResult::PassedWithQuirks, aResult); if (nNumberOfErrors > 0) checkResult(TestResult::Failed, aResult); return aResult; } TestResult OutputDeviceTestCommon::checkRadialGradientOfs(Bitmap& bitmap) { BitmapScopedWriteAccess pAccess(bitmap); TestResult aResult = TestResult::Passed; int nNumberOfQuirks = 0; int nNumberOfErrors = 0; checkValue(pAccess, 1, 1, COL_WHITE, nNumberOfQuirks, nNumberOfErrors, 255 / 10, 255 / 5); checkValue(pAccess, 10, 1, COL_WHITE, nNumberOfQuirks, nNumberOfErrors, 255 / 10, 255 / 5); checkValue(pAccess, 1, 10, COL_WHITE, nNumberOfQuirks, nNumberOfErrors, 255 / 10, 255 / 5); checkValue(pAccess, 10, 10, COL_BLACK, nNumberOfQuirks, nNumberOfErrors, 255 / 10, 255 / 5); // Check gradients from the center (=bottom-right corner). if(!checkGradient(pAccess, 10, 10, 10, -1, -1)) return TestResult::Failed; if(!checkGradient(pAccess, 10, 10, 10, -1, 0)) return TestResult::Failed; if(!checkGradient(pAccess, 10, 10, 10, 0, -1)) return TestResult::Failed; if (nNumberOfQuirks > 0) checkResult(TestResult::PassedWithQuirks, aResult); if (nNumberOfErrors > 0) checkResult(TestResult::Failed, aResult); return aResult; } constexpr int CAPSHRINK = 25; constexpr int CAPWIDTH = 20; TestResult OutputDeviceTestCommon::checkLineCap(Bitmap& rBitmap, css::drawing::LineCap lineCap) { BitmapScopedWriteAccess access(rBitmap); tools::Rectangle rectangle( Point( 0, 0 ), Size( 101, 101 )); rectangle.shrink(CAPSHRINK); rectangle = tools::Rectangle( Point(rectangle.LeftCenter().getX(), rectangle.LeftCenter().getY() - CAPWIDTH / 2), Point(rectangle.RightCenter().getX(), rectangle.RightCenter().getY() + CAPWIDTH / 2)); rectangle.shrink(1); TestResult aResult = TestResult::Passed; int nNumberOfQuirks = 0; int nNumberOfErrors = 0; // the line itself checkValue(access, rectangle.TopLeft(), constLineColor, nNumberOfQuirks, nNumberOfErrors, false); checkValue(access, rectangle.TopRight(), constLineColor, nNumberOfQuirks, nNumberOfErrors, false); checkValue(access, rectangle.BottomLeft(), constLineColor, nNumberOfQuirks, nNumberOfErrors, false); checkValue(access, rectangle.BottomRight(), constLineColor, nNumberOfQuirks, nNumberOfErrors, false); // the cap in the middle Color color = ( lineCap == css::drawing::LineCap_BUTT ) ? constBackgroundColor : constLineColor; checkValue(access, rectangle.LeftCenter() - Point(CAPWIDTH/2, 0), color, nNumberOfQuirks, nNumberOfErrors, false); checkValue(access, rectangle.RightCenter() + Point(CAPWIDTH/2, 0), color, nNumberOfQuirks, nNumberOfErrors, false); // the cap corners color = ( lineCap == css::drawing::LineCap_SQUARE ) ? constLineColor : constBackgroundColor; checkValue(access, rectangle.TopLeft() - Point(CAPWIDTH/2, 0), color, nNumberOfQuirks, nNumberOfErrors, false); checkValue(access, rectangle.TopRight() + Point(CAPWIDTH/2, 0), color, nNumberOfQuirks, nNumberOfErrors, false); checkValue(access, rectangle.BottomLeft() - Point(CAPWIDTH/2, 0), color, nNumberOfQuirks, nNumberOfErrors, false); checkValue(access, rectangle.BottomRight() + Point(CAPWIDTH/2, 0), color, nNumberOfQuirks, nNumberOfErrors, false); if (nNumberOfQuirks > 0) checkResult(TestResult::PassedWithQuirks, aResult); if (nNumberOfErrors > 0) checkResult(TestResult::Failed, aResult); return aResult; } TestResult OutputDeviceTestCommon::checkLineJoin(Bitmap& rBitmap, basegfx::B2DLineJoin lineJoin) { BitmapScopedWriteAccess access(rBitmap); tools::Rectangle rectangle( Point( 0, 0 ), Size( 101, 101 )); rectangle.shrink(CAPSHRINK); tools::Rectangle rectangle1( Point(rectangle.TopLeft().getX(), rectangle.TopLeft().getY() - CAPWIDTH / 2), Point(rectangle.TopRight().getX(), rectangle.TopRight().getY() + CAPWIDTH / 2)); tools::Rectangle rectangle2( Point(rectangle.TopRight().getX() - CAPWIDTH / 2, rectangle.TopRight().getY()), Point(rectangle.BottomRight().getX() + CAPWIDTH / 2, rectangle.BottomRight().getY())); rectangle1.shrink(1); rectangle2.shrink(1); TestResult aResult = TestResult::Passed; int nNumberOfQuirks = 0; int nNumberOfErrors = 0; // the lines themselves checkValue(access, rectangle1.TopLeft(), constLineColor, nNumberOfQuirks, nNumberOfErrors, false); checkValue(access, rectangle1.TopRight(), constLineColor, nNumberOfQuirks, nNumberOfErrors, false); checkValue(access, rectangle1.BottomLeft(), constLineColor, nNumberOfQuirks, nNumberOfErrors, false); checkValue(access, rectangle1.BottomRight(), constLineColor, nNumberOfQuirks, nNumberOfErrors, false); checkValue(access, rectangle2.TopLeft(), constLineColor, nNumberOfQuirks, nNumberOfErrors, false); checkValue(access, rectangle2.TopRight(), constLineColor, nNumberOfQuirks, nNumberOfErrors, false); checkValue(access, rectangle2.BottomLeft(), constLineColor, nNumberOfQuirks, nNumberOfErrors, false); checkValue(access, rectangle2.BottomRight(), constLineColor, nNumberOfQuirks, nNumberOfErrors, false); // Only miter has the corner point. Color color = ( lineJoin == basegfx::B2DLineJoin::Miter ) ? constLineColor : constBackgroundColor; checkValue(access, rectangle2.Right(), rectangle1.Top(), color, nNumberOfQuirks, nNumberOfErrors, false); // Round reaches a bit past the diagonal. Point midDiagonal = (Point( rectangle2.Right(), rectangle1.Top()) + rectangle.TopRight()) / 2; if( lineJoin == basegfx::B2DLineJoin::Round) color = constLineColor; checkValue(access, midDiagonal + Point( 2, -2 ), color, nNumberOfQuirks, nNumberOfErrors, false); // Bevel is the diagonal. if( lineJoin == basegfx::B2DLineJoin::Bevel) color = constLineColor; checkValue(access, midDiagonal + Point( -1, 1 ), color, nNumberOfQuirks, nNumberOfErrors, false); // Everything except None has at least some line join. checkValue(access, rectangle.TopRight() + Point( 1, -1 ), color, nNumberOfQuirks, nNumberOfErrors, false); if (nNumberOfQuirks > 0) checkResult(TestResult::PassedWithQuirks, aResult); if (nNumberOfErrors > 0) checkResult(TestResult::Failed, aResult); return aResult; } TestResult OutputDeviceTestAnotherOutDev::checkDrawOutDev(Bitmap& rBitmap) { std::vector aExpected { constBackgroundColor, constBackgroundColor, constFillColor, constFillColor, constFillColor, constFillColor, constFillColor }; return checkRectangles(rBitmap, aExpected); } TestResult OutputDeviceTestAnotherOutDev::checkDrawOutDevScaledClipped(Bitmap& rBitmap) { TestResult aReturnValue = TestResult::Passed; TestResult eResult; eResult = checkRect(rBitmap, 0, constBackgroundColor); // outer line checkResult(eResult, aReturnValue); eResult = checkRect(rBitmap, 1, constBackgroundColor); // next outer line checkResult(eResult, aReturnValue); eResult = checkFilled(rBitmap, tools::Rectangle(Point(2, 2), Size(4, 8)), constBackgroundColor); checkResult(eResult, aReturnValue); eResult = checkFilled(rBitmap, tools::Rectangle(Point(6, 2), Size(4, 8)), constFillColor); checkResult(eResult, aReturnValue); return aReturnValue; } TestResult OutputDeviceTestAnotherOutDev::checkDrawOutDevSelf(Bitmap& rBitmap) { TestResult aReturnValue = TestResult::Passed; TestResult eResult; eResult = checkRect(rBitmap, 0, constBackgroundColor); // outer line checkResult(eResult, aReturnValue); eResult = checkFilled(rBitmap, tools::Rectangle(Point(1, 1), Size(4, 4)), constBackgroundColor); checkResult(eResult, aReturnValue); eResult = checkFilled(rBitmap, tools::Rectangle(Point(8, 8), Size(4, 4)), constBackgroundColor); checkResult(eResult, aReturnValue); eResult = checkFilled(rBitmap, tools::Rectangle(Point(11, 1), Size(1, 1)), COL_YELLOW); checkResult(eResult, aReturnValue); eResult = checkFilled(rBitmap, tools::Rectangle(Point(7, 5), Size(1, 1)), COL_YELLOW); checkResult(eResult, aReturnValue); eResult = checkFilled(rBitmap, tools::Rectangle(Point(1, 11), Size(1, 1)), COL_YELLOW); checkResult(eResult, aReturnValue); eResult = checkFilled(rBitmap, tools::Rectangle(Point(1, 5), Size(6, 6)), constFillColor); checkResult(eResult, aReturnValue); eResult = checkFilled(rBitmap, tools::Rectangle(Point(2, 6), Size(6, 6)), constFillColor); checkResult(eResult, aReturnValue); eResult = checkFilled(rBitmap, tools::Rectangle(Point(5, 1), Size(6, 4)), constFillColor); checkResult(eResult, aReturnValue); eResult = checkFilled(rBitmap, tools::Rectangle(Point(8, 2), Size(4, 6)), constFillColor); checkResult(eResult, aReturnValue); return aReturnValue; } TestResult OutputDeviceTestAnotherOutDev::checkXOR(Bitmap& rBitmap) { Color xorColor( constBackgroundColor.GetRed() ^ constFillColor.GetRed(), constBackgroundColor.GetGreen() ^ constFillColor.GetGreen(), constBackgroundColor.GetBlue() ^ constFillColor.GetBlue()); std::vector aExpected { constBackgroundColor, xorColor, constBackgroundColor, constBackgroundColor, constFillColor, constFillColor, constFillColor }; return checkRectangles(rBitmap, aExpected); } TestResult OutputDeviceTestBitmap::checkTransformedBitmap(Bitmap& rBitmap) { std::vector aExpected { constBackgroundColor, constBackgroundColor, COL_YELLOW, constFillColor, COL_YELLOW, constFillColor, constFillColor }; return checkRectangles(rBitmap, aExpected); } TestResult OutputDeviceTestBitmap::checkComplexTransformedBitmap(Bitmap& rBitmap) { TestResult aReturnValue = TestResult::Passed; TestResult eResult; eResult = checkRectangle(rBitmap, 0, constBackgroundColor); // outer line not affected checkResult(eResult, aReturnValue); // empty "corners" should not be affected eResult = checkFilled(rBitmap, tools::Rectangle(Point(1, 11), Size(2, 2)), constBackgroundColor); checkResult(eResult, aReturnValue); eResult = checkFilled(rBitmap, tools::Rectangle(Point(14, 1), Size(2, 2)), constBackgroundColor); checkResult(eResult, aReturnValue); // check the middle eResult = checkFilled(rBitmap, tools::Rectangle(Point(4, 3), Size(9, 8)), constFillColor); checkResult(eResult, aReturnValue); int nNumberOfQuirks = 0; int nNumberOfErrors = 0; BitmapScopedWriteAccess pAccess(rBitmap); // starting and ending corner, headless draws with AA, so be lenient checkValue(pAccess, 1, 1, constFillColor, nNumberOfQuirks, nNumberOfErrors, 0, 192); checkValue(pAccess, 2, 2, constFillColor, nNumberOfQuirks, nNumberOfErrors, 0, 16); checkValue(pAccess, 14, 11, constFillColor, nNumberOfQuirks, nNumberOfErrors, 0, 16); checkValue(pAccess, 15, 12, constFillColor, nNumberOfQuirks, nNumberOfErrors, 0, 192); if (nNumberOfQuirks > 0) checkResult(TestResult::PassedWithQuirks, aReturnValue); if (nNumberOfErrors > 0) checkResult(TestResult::Failed, aReturnValue); return aReturnValue; } TestResult OutputDeviceTestBitmap::checkTransformedBitmap8bppGreyScale(Bitmap& rBitmap) { std::vector aExpected { Color(0xC0,0xC0,0xC0), Color(0xC0,0xC0,0xC0), Color(0xE2,0xE2,0xE2), Color(0xE,0xE,0xE), Color(0xE2,0xE2,0xE2), Color(0xE,0xE,0xE), Color(0xE,0xE,0xE) }; return checkRectangles(rBitmap, aExpected); } TestResult OutputDeviceTestBitmap::checkBitmapExWithAlpha(Bitmap& rBitmap) { const Color aBlendedColor(0xEE, 0xEE, 0x33); std::vector aExpected { constBackgroundColor, constBackgroundColor, aBlendedColor, constBackgroundColor, constBackgroundColor, aBlendedColor, constBackgroundColor }; return checkRectangles(rBitmap, aExpected); } TestResult OutputDeviceTestBitmap::checkMask(Bitmap& rBitmap) { return checkRectangle(rBitmap); } TestResult OutputDeviceTestBitmap::checkBlend(const BitmapEx& rBitmapEx) { const Color aBlendedColor(0xEE, 0xEE, 0x33); std::vector aExpected { COL_WHITE, COL_WHITE, COL_YELLOW, constBackgroundColor, constBackgroundColor, aBlendedColor, constBackgroundColor }; Bitmap aBitmap(rBitmapEx.GetBitmap()); return checkRectangles(aBitmap, aExpected); } } // end namespace vcl::test /* vim:set shiftwidth=4 softtabstop=4 expandtab: */