// Copyright (C) 2020-2022 Jakub Melka // // This file is part of PDF4QT. // // PDF4QT is free software: you can redistribute it and/or modify // it under the terms of the GNU Lesser General Public License as published by // the Free Software Foundation, either version 3 of the License, or // with the written consent of the copyright owner, any later version. // // PDF4QT is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU Lesser General Public License for more details. // // You should have received a copy of the GNU Lesser General Public License // along with PDF4QT. If not, see . #include "pdftransparencyrenderer.h" #include "pdfdocument.h" #include "pdfcms.h" #include "pdfexecutionpolicy.h" #include "pdfimage.h" #include "pdfpattern.h" #include "pdfdbgheap.h" #include namespace pdf { PDFFloatBitmap::PDFFloatBitmap() : m_width(0), m_height(0), m_pixelSize(0) { } PDFFloatBitmap::PDFFloatBitmap(size_t width, size_t height, PDFPixelFormat format) : m_format(format), m_width(width), m_height(height), m_pixelSize(format.getChannelCount()) { Q_ASSERT(format.isValid()); m_data.resize(format.calculateBitmapDataLength(width, height), static_cast(0.0f)); if (m_format.hasActiveColorMask()) { m_activeColorMask.resize(width * height, 0); } } PDFColorBuffer PDFFloatBitmap::getPixel(size_t x, size_t y) { Q_ASSERT(x < m_width); Q_ASSERT(y < m_height); const size_t index = getPixelIndex(x, y); return PDFColorBuffer(m_data.data() + index, m_pixelSize); } PDFConstColorBuffer PDFFloatBitmap::getPixel(size_t x, size_t y) const { Q_ASSERT(x < m_width); Q_ASSERT(y < m_height); const size_t index = getPixelIndex(x, y); return PDFConstColorBuffer(m_data.data() + index, m_pixelSize); } PDFColorBuffer PDFFloatBitmap::getPixels() { return PDFColorBuffer(m_data.data(), m_data.size()); } PDFColorComponent PDFFloatBitmap::getPixelInkCoverage(size_t x, size_t y) const { PDFConstColorBuffer buffer = getPixel(x, y); const uint8_t colorChannelIndexStart = m_format.getColorChannelIndexStart(); const uint8_t colorChannelIndexEnd = m_format.getColorChannelIndexEnd(); PDFColorComponent inkCoverage = 0.0; for (uint8_t i = colorChannelIndexStart; i < colorChannelIndexEnd; ++i) { inkCoverage += buffer[i]; } return inkCoverage; } PDFFloatBitmap PDFFloatBitmap::getInkCoverageBitmap() const { PDFFloatBitmap result(getWidth(), getHeight(), PDFPixelFormat::createFormat(1, 0, false, true, false)); for (size_t y = 0; y < getHeight(); ++y) { for (size_t x = 0; x < getWidth(); ++x) { PDFColorComponent coverage = getPixelInkCoverage(x, y); PDFColorBuffer targetProcessColorBuffer = result.getPixel(x, y); targetProcessColorBuffer[0] = coverage; } } return result; } const PDFColorComponent* PDFFloatBitmap::begin() const { return m_data.data(); } const PDFColorComponent* PDFFloatBitmap::end() const { return m_data.data() + m_data.size(); } PDFColorComponent* PDFFloatBitmap::begin() { return m_data.data(); } PDFColorComponent* PDFFloatBitmap::end() { return m_data.data() + m_data.size(); } void PDFFloatBitmap::makeTransparent() { if (m_format.hasShapeChannel()) { fillChannel(m_format.getShapeChannelIndex(), 0.0f); } if (m_format.hasOpacityChannel()) { fillChannel(m_format.getOpacityChannelIndex(), 0.0f); } } void PDFFloatBitmap::makeOpaque() { if (m_format.hasShapeChannel()) { fillChannel(m_format.getShapeChannelIndex(), 1.0f); } if (m_format.hasOpacityChannel()) { fillChannel(m_format.getOpacityChannelIndex(), 1.0f); } } void PDFFloatBitmap::makeColorBlack() { fillProcessColorChannels(m_format.hasProcessColorsSubtractive() ? 1.0 : 0.0); } void PDFFloatBitmap::makeColorWhite() { fillProcessColorChannels(m_format.hasProcessColorsSubtractive() ? 0.0 : 1.0); } size_t PDFFloatBitmap::getPixelIndex(size_t x, size_t y) const { return (y * m_width + x) * m_pixelSize; } uint32_t PDFFloatBitmap::getPixelActiveColorMask(size_t x, size_t y) const { Q_ASSERT(hasActiveColorMask()); return m_activeColorMask[y * m_width + x]; } void PDFFloatBitmap::markPixelActiveColorMask(size_t x, size_t y, uint32_t activeColorMask) { Q_ASSERT(hasActiveColorMask()); m_activeColorMask[y * m_width + x] |= activeColorMask; } void PDFFloatBitmap::setPixelActiveColorMask(size_t x, size_t y, uint32_t activeColorMask) { Q_ASSERT(hasActiveColorMask()); m_activeColorMask[y * m_width + x] = activeColorMask; } void PDFFloatBitmap::setAllColorActive() { std::fill(m_activeColorMask.begin(), m_activeColorMask.end(), PDFPixelFormat::getAllColorsMask()); } void PDFFloatBitmap::setAllColorInactive() { std::fill(m_activeColorMask.begin(), m_activeColorMask.end(), 0); } void PDFFloatBitmap::setColorActivity(uint32_t mask) { std::fill(m_activeColorMask.begin(), m_activeColorMask.end(), mask); } QImage PDFFloatBitmap::getChannelImage(uint8_t channelIndex) const { if (channelIndex >= getPixelSize()) { return QImage(); } QImage image(int(getWidth()), int(getHeight()), QImage::Format_Grayscale8); for (int y = 0; y < image.height(); ++y) { uchar* line = image.scanLine(y); for (int x = 0; x < image.width(); ++x) { PDFConstColorBuffer buffer = getPixel(x, y); line[x] = qRound(buffer[channelIndex] * 255); } } return image; } PDFFloatBitmap PDFFloatBitmap::extractProcessColors() const { PDFPixelFormat format = PDFPixelFormat::createFormat(m_format.getProcessColorChannelCount(), 0, false, m_format.hasProcessColorsSubtractive(), false); PDFFloatBitmap result(getWidth(), getHeight(), format); for (size_t x = 0; x < getWidth(); ++x) { for (size_t y = 0; y < getHeight(); ++y) { PDFConstColorBuffer sourceProcessColorBuffer = getPixel(x, y); PDFColorBuffer targetProcessColorBuffer = result.getPixel(x, y); Q_ASSERT(sourceProcessColorBuffer.size() >= targetProcessColorBuffer.size()); std::copy(sourceProcessColorBuffer.cbegin(), std::next(sourceProcessColorBuffer.cbegin(), targetProcessColorBuffer.size()), targetProcessColorBuffer.begin()); } } return result; } PDFFloatBitmap PDFFloatBitmap::extractSpotChannel(uint8_t channel) const { PDFPixelFormat format = PDFPixelFormat::createFormat(0, 1, false, m_format.hasProcessColorsSubtractive(), false); PDFFloatBitmap result(getWidth(), getHeight(), format); Q_ASSERT(m_format.hasSpotColors()); Q_ASSERT(m_format.getSpotColorChannelIndexStart() <= channel); Q_ASSERT(m_format.getSpotColorChannelIndexEnd() > channel); for (size_t x = 0; x < getWidth(); ++x) { for (size_t y = 0; y < getHeight(); ++y) { PDFConstColorBuffer sourceProcessColorBuffer = getPixel(x, y); PDFColorBuffer targetProcessColorBuffer = result.getPixel(x, y); targetProcessColorBuffer[0] = sourceProcessColorBuffer[channel]; } } return result; } PDFFloatBitmap PDFFloatBitmap::extractOpacityChannel() const { PDFFloatBitmap result(getWidth(), getHeight(), PDFPixelFormat::createOpacityMask()); if (m_format.hasOpacityChannel()) { const uint8_t opacityChannel = m_format.getOpacityChannelIndex(); for (size_t x = 0; x < getWidth(); ++x) { for (size_t y = 0; y < getHeight(); ++y) { PDFConstColorBuffer sourceProcessColorBuffer = getPixel(x, y); PDFColorBuffer targetProcessColorBuffer = result.getPixel(x, y); targetProcessColorBuffer[0] = sourceProcessColorBuffer[opacityChannel]; } } } else { result.makeOpaque(); } return result; } PDFFloatBitmap PDFFloatBitmap::extractLuminosityChannel() const { PDFFloatBitmap result(getWidth(), getHeight(), PDFPixelFormat::createOpacityMask()); const uint8_t sourceChannelIndex = m_format.getProcessColorChannelIndexStart(); switch (m_format.getProcessColorChannelCount()) { case 1: { for (size_t x = 0; x < getWidth(); ++x) { for (size_t y = 0; y < getHeight(); ++y) { PDFConstColorBuffer sourceProcessColorBuffer = getPixel(x, y); PDFColorBuffer targetProcessColorBuffer = result.getPixel(x, y); targetProcessColorBuffer[0] = PDFBlendFunction::getLuminosity(PDFGray(sourceProcessColorBuffer[sourceChannelIndex])); } } break; } case 3: { for (size_t x = 0; x < getWidth(); ++x) { for (size_t y = 0; y < getHeight(); ++y) { PDFConstColorBuffer sourceProcessColorBuffer = getPixel(x, y); PDFColorBuffer targetProcessColorBuffer = result.getPixel(x, y); PDFColorComponent r = sourceProcessColorBuffer[sourceChannelIndex + 0]; PDFColorComponent g = sourceProcessColorBuffer[sourceChannelIndex + 1]; PDFColorComponent b = sourceProcessColorBuffer[sourceChannelIndex + 2]; targetProcessColorBuffer[0] = PDFBlendFunction::getLuminosity(PDFRGB{ r, g, b }); } } break; } case 4: { for (size_t x = 0; x < getWidth(); ++x) { for (size_t y = 0; y < getHeight(); ++y) { PDFConstColorBuffer sourceProcessColorBuffer = getPixel(x, y); PDFColorBuffer targetProcessColorBuffer = result.getPixel(x, y); PDFColorComponent _c = sourceProcessColorBuffer[sourceChannelIndex + 0]; PDFColorComponent _m = sourceProcessColorBuffer[sourceChannelIndex + 1]; PDFColorComponent _y = sourceProcessColorBuffer[sourceChannelIndex + 2]; PDFColorComponent _k = sourceProcessColorBuffer[sourceChannelIndex + 3]; targetProcessColorBuffer[0] = PDFBlendFunction::getLuminosity(PDFCMYK{ _c, _m, _y, _k }); } } break; } default: { result.makeOpaque(); break; } } if (m_format.hasOpacityChannel()) { const uint8_t opacityChannel = m_format.getOpacityChannelIndex(); for (size_t x = 0; x < getWidth(); ++x) { for (size_t y = 0; y < getHeight(); ++y) { PDFConstColorBuffer sourceProcessColorBuffer = getPixel(x, y); PDFColorBuffer targetProcessColorBuffer = result.getPixel(x, y); targetProcessColorBuffer[0] = sourceProcessColorBuffer[opacityChannel]; } } } else { result.makeOpaque(); } return result; } void PDFFloatBitmap::copyChannel(const PDFFloatBitmap& sourceBitmap, uint8_t channelFrom, uint8_t channelTo) { Q_ASSERT(getWidth() == sourceBitmap.getWidth()); Q_ASSERT(getHeight() == sourceBitmap.getHeight()); for (size_t x = 0; x < getWidth(); ++x) { for (size_t y = 0; y < getHeight(); ++y) { PDFConstColorBuffer sourceProcessColorBuffer = sourceBitmap.getPixel(x, y); PDFColorBuffer targetProcessColorBuffer = getPixel(x, y); targetProcessColorBuffer[channelTo] = sourceProcessColorBuffer[channelFrom]; } } } PDFFloatBitmap PDFFloatBitmap::resize(size_t width, size_t height, Qt::TransformationMode mode) const { if (width == 0 || height == 0) { return PDFFloatBitmap(); } PDFFloatBitmap bitmap(width, height, getPixelFormat()); const qreal pixelRatioH = qreal(getWidth()) / qreal(width); const qreal pixelRatioV = qreal(getHeight()) / qreal(height); switch (mode) { case Qt::FastTransformation: { for (size_t yDest = 0; yDest < height; ++yDest) { for (size_t xDest = 0; xDest < width; ++xDest) { size_t xSrc = qFloor(pixelRatioH * xDest); size_t ySrc = qFloor(pixelRatioV * yDest); PDFConstColorBuffer srcBuffer = getPixel(xSrc, ySrc); PDFColorBuffer destBuffer = bitmap.getPixel(xDest, yDest); Q_ASSERT(srcBuffer.size() == destBuffer.size()); // Just copy the color std::copy(srcBuffer.cbegin(), srcBuffer.cend(), destBuffer.begin()); } } break; } case Qt::SmoothTransformation: { const size_t pixelCount = getPixelSize(); std::vector buffer(pixelCount, 0.0f); for (size_t yDest = 0; yDest < height; ++yDest) { for (size_t xDest = 0; xDest < width; ++xDest) { const qreal xOrdinateStart = pixelRatioH * xDest; const qreal xOrdinateEnd = xOrdinateStart + pixelRatioH; const qreal yOrdinateStart = pixelRatioV * yDest; const qreal yOrdinateEnd = yOrdinateStart + pixelRatioV; size_t xSrcStart = qFloor(xOrdinateStart); size_t xSrcEnd = qMin(qCeil(xOrdinateEnd), getWidth()); size_t ySrcStart = qFloor(yOrdinateStart); size_t ySrcEnd = qMin(qCeil(yOrdinateEnd), getHeight()); std::fill(buffer.begin(), buffer.end(), 0.0f); qreal sumPortion = 0.0; for (size_t i = xSrcStart; i < xSrcEnd; ++i) { const qreal xSubpixelStart = qMax(qreal(i), xOrdinateStart); const qreal xSubpixelEnd = qMin(qreal(i + 1), xOrdinateEnd); const qreal xPortion = xSubpixelEnd - xSubpixelStart; for (size_t j = ySrcStart; j < ySrcEnd; ++j) { const qreal ySubpixelStart = qMax(qreal(j), yOrdinateStart); const qreal ySubpixelEnd = qMin(qreal(j + 1), yOrdinateEnd); const qreal yPortion = ySubpixelEnd - ySubpixelStart; const qreal pixelPortion = xPortion * yPortion; PDFConstColorBuffer srcBuffer = getPixel(i, j); for (size_t k = 0; k < pixelCount; ++k) { buffer[k] += srcBuffer[k] * pixelPortion; } sumPortion += pixelPortion; } } // Compute weighed sum of pixels const qreal coefficient = qFuzzyIsNull(sumPortion) ? 0.0 : 1.0 / sumPortion; for (size_t k = 0; k < pixelCount; ++k) { buffer[k] *= coefficient; } PDFColorBuffer destBuffer = bitmap.getPixel(xDest, yDest); Q_ASSERT(buffer.size() == destBuffer.size()); std::copy(buffer.cbegin(), buffer.cend(), destBuffer.begin()); } } break; } default: Q_ASSERT(false); break; } return bitmap; } void PDFFloatBitmap::blend(const PDFFloatBitmap& source, PDFFloatBitmap& target, const PDFFloatBitmap& backdrop, const PDFFloatBitmap& initialBackdrop, const PDFFloatBitmap& blendSoftMask, bool alphaIsShape, PDFColorComponent constantAlpha, BlendMode mode, bool knockoutGroup, OverprintMode overprintMode, QRect blendRegion) { Q_ASSERT(source.getWidth() == target.getWidth()); Q_ASSERT(source.getHeight() == target.getHeight()); Q_ASSERT(source.getPixelFormat() == target.getPixelFormat()); Q_ASSERT(source.getWidth() == blendSoftMask.getWidth()); Q_ASSERT(source.getHeight() == blendSoftMask.getHeight()); Q_ASSERT(blendSoftMask.getPixelFormat() == PDFPixelFormat::createOpacityMask()); Q_ASSERT(blendRegion.left() >= 0); Q_ASSERT(blendRegion.top() >= 0); Q_ASSERT(blendRegion.right() < source.getWidth()); Q_ASSERT(blendRegion.bottom() < source.getHeight()); const PDFPixelFormat pixelFormat = source.getPixelFormat(); const uint8_t shapeChannel = pixelFormat.getShapeChannelIndex(); const uint8_t opacityChannel = pixelFormat.getOpacityChannelIndex(); const uint8_t colorChannelStart = pixelFormat.getColorChannelIndexStart(); const uint8_t colorChannelEnd = pixelFormat.getColorChannelIndexEnd(); const uint8_t processColorChannelStart = pixelFormat.getProcessColorChannelIndexStart(); const uint8_t processColorChannelEnd = pixelFormat.getProcessColorChannelIndexEnd(); const uint8_t spotColorChannelStart = pixelFormat.getSpotColorChannelIndexStart(); const uint8_t spotColorChannelEnd = pixelFormat.getSpotColorChannelIndexEnd(); std::vector B_i(source.getPixelSize(), 0.0f); std::vector channelBlendModes(source.getPixelSize(), mode); // For blending spot colors, only white preserving blend modes are possible. // If this is not the case, revert spot color blend mode to normal blending. // See 11.7.4.2 of PDF 2.0 specification. if (pixelFormat.hasSpotColors() && !PDFBlendModeInfo::isWhitePreserving(mode)) { auto itBegin = std::next(channelBlendModes.begin(), spotColorChannelStart); auto itEnd = std::next(channelBlendModes.begin(), spotColorChannelEnd); std::fill(itBegin, itEnd, BlendMode::Normal); } // Handle overprint mode for normal blend mode. We do not support // oveprinting for other blend modes, than normal. auto getBlendModeForPixel = [&source, &channelBlendModes, pixelFormat, overprintMode, mode](size_t x, size_t y, uint8_t channel) { switch (overprintMode) { case OverprintMode::NoOveprint: break; case OverprintMode::Overprint_Mode_0: { // Select source color, if channel is active, // otherwise select backdrop color. const uint32_t activeColorChannels = source.hasActiveColorMask() ? source.getPixelActiveColorMask(x, y) : PDFPixelFormat::getAllColorsMask(); uint32_t flag = (static_cast(1)) << channel; if (channelBlendModes[channel] == BlendMode::Normal && !(activeColorChannels & flag)) { // Color channel is inactive return BlendMode::Overprint_SelectBackdrop; } break; } case OverprintMode::Overprint_Mode_1: { // For process colors, select source color, if it is nonzero, // otherwise select backdrop. If process color channel is inactive, // select backdrop. const uint32_t activeColorChannels = source.hasActiveColorMask() ? source.getPixelActiveColorMask(x, y) : PDFPixelFormat::getAllColorsMask(); if (pixelFormat.hasProcessColors() && mode == BlendMode::Normal && channel >= pixelFormat.getProcessColorChannelIndexStart() && channel < pixelFormat.getProcessColorChannelIndexEnd()) { uint32_t flag = (static_cast(1)) << channel; if (!(activeColorChannels & flag)) { // Color channel is inactive return BlendMode::Overprint_SelectBackdrop; } else { // Color channel is active, but select source color only, if it is nonzero return pixelFormat.hasProcessColorsSubtractive() ? BlendMode::Overprint_SelectNonOneSourceOrBackdrop : BlendMode::Overprint_SelectNonZeroSourceOrBackdrop; } } if (pixelFormat.hasSpotColors() && channel >= pixelFormat.getSpotColorChannelIndexStart() && channel < pixelFormat.getSpotColorChannelIndexEnd()) { // For spot colors, select backdrop, if channel is inactive, // otherwise select source color. uint32_t flag = (static_cast(1)) << channel; if (channelBlendModes[channel] == BlendMode::Normal && !(activeColorChannels & flag)) { // Color channel is inactive return BlendMode::Overprint_SelectBackdrop; } } break; } default: { Q_ASSERT(false); break; } } return channelBlendModes[channel]; }; for (int x = blendRegion.left(); x <= blendRegion.right(); ++x) { for (int y = blendRegion.top(); y <= blendRegion.bottom(); ++y) { PDFConstColorBuffer sourceColor = source.getPixel(x, y); PDFColorBuffer targetColor = target.getPixel(x, y); PDFConstColorBuffer backdropColor = backdrop.getPixel(x, y); PDFConstColorBuffer initialBackdropColor = initialBackdrop.getPixel(x, y); PDFConstColorBuffer alphaColorBuffer = blendSoftMask.getPixel(x, y); const PDFColorComponent softMaskValue = alphaColorBuffer[0]; const PDFColorComponent f_j_i = sourceColor[shapeChannel]; const PDFColorComponent f_m_i = alphaIsShape ? softMaskValue : 1.0f; const PDFColorComponent f_k_i = alphaIsShape ? constantAlpha : 1.0f; const PDFColorComponent q_m_i = !alphaIsShape ? softMaskValue : 1.0f; const PDFColorComponent q_k_i = !alphaIsShape ? constantAlpha : 1.0f; const PDFColorComponent f_s_i = f_j_i * f_m_i * f_k_i; const PDFColorComponent alpha_j_i = sourceColor[opacityChannel]; const PDFColorComponent alpha_s_i = alpha_j_i * (f_m_i * q_m_i) * (f_k_i * q_k_i); // Old alpha (alpha_g_i_1) is stored in target (immediate) buffer const PDFColorComponent alpha_g_i_1 = targetColor[opacityChannel]; // alpha_g_0 == 0.0f according to the specification, otherwise select alpha_g_i_1 from target color const PDFColorComponent alpha_g_b = knockoutGroup ? 0.0f : alpha_g_i_1; // alpha_0 is taken from initial backdrop color buffer const PDFColorComponent alpha_0 = initialBackdropColor[opacityChannel]; // f_g_i_1 is stored in target (immediate) buffer const PDFColorComponent f_g_i_1 = targetColor[shapeChannel]; // Formulas taken from const PDFColorComponent f_g_i = PDFBlendFunction::blend_Union(f_g_i_1, f_s_i); const PDFColorComponent alpha_g_i = (1.0f - f_s_i) * alpha_g_i_1 + (f_s_i - alpha_s_i) * alpha_g_b + alpha_s_i; const PDFColorComponent alpha_i_1 = PDFBlendFunction::blend_Union(alpha_0, alpha_g_i_1); const PDFColorComponent alpha_i = PDFBlendFunction::blend_Union(alpha_0, alpha_g_i); // alpha_b is either alpha_0 (for knockout group) or alpha_i_1 const PDFColorComponent alpha_b = knockoutGroup ? alpha_0 : alpha_i_1; if (qFuzzyIsNull(alpha_g_i)) { // If alpha_i is zero, then color is undefined, just fill shape/opacity targetColor[shapeChannel] = f_g_i; targetColor[opacityChannel] = alpha_g_i; continue; } if (target.hasActiveColorMask()) { const uint32_t activeColorChannels = source.hasActiveColorMask() ? source.getPixelActiveColorMask(x, y) : PDFPixelFormat::getAllColorsMask(); target.markPixelActiveColorMask(x, y, activeColorChannels); } std::fill(B_i.begin(), B_i.end(), 0.0f); // Calculate blended pixel if (PDFBlendModeInfo::isSeparable(mode)) { // Separable blend mode - process each color separately const bool isProcessColorSubtractive = pixelFormat.hasProcessColorsSubtractive(); const bool isSpotColorSubtractive = pixelFormat.hasSpotColorsSubtractive(); if (pixelFormat.hasProcessColors()) { if (!isProcessColorSubtractive) { for (uint8_t i = processColorChannelStart; i < processColorChannelEnd; ++i) { const BlendMode pixelBlendMode = getBlendModeForPixel(x, y, i); B_i[i] = PDFBlendFunction::blend(pixelBlendMode, backdropColor[i], sourceColor[i]); } } else { for (uint8_t i = processColorChannelStart; i < processColorChannelEnd; ++i) { const BlendMode pixelBlendMode = getBlendModeForPixel(x, y, i); B_i[i] = 1.0f - PDFBlendFunction::blend(pixelBlendMode, 1.0f - backdropColor[i], 1.0f - sourceColor[i]); } } } if (pixelFormat.hasSpotColors()) { if (!isSpotColorSubtractive) { for (uint8_t i = spotColorChannelStart; i < spotColorChannelEnd; ++i) { const BlendMode pixelBlendMode = getBlendModeForPixel(x, y, i); B_i[i] = PDFBlendFunction::blend(pixelBlendMode, backdropColor[i], sourceColor[i]); } } else { for (uint8_t i = spotColorChannelStart; i < spotColorChannelEnd; ++i) { const BlendMode pixelBlendMode = getBlendModeForPixel(x, y, i); B_i[i] = 1.0f - PDFBlendFunction::blend(pixelBlendMode, 1.0f - backdropColor[i], 1.0f - sourceColor[i]); } } } } else { // Nonseparable blend mode - process colors together if (pixelFormat.hasProcessColors()) { switch (pixelFormat.getProcessColorChannelCount()) { case 1: { // Gray const PDFGray Cb = backdropColor[processColorChannelStart]; const PDFGray Cs = sourceColor[processColorChannelStart]; const PDFGray blended = PDFBlendFunction::blend_Nonseparable(mode, Cb, Cs); B_i[pixelFormat.getProcessColorChannelIndexStart()] = blended; break; } case 3: { // RGB const PDFRGB Cb = { backdropColor[processColorChannelStart + 0], backdropColor[processColorChannelStart + 1], backdropColor[processColorChannelStart + 2] }; const PDFRGB Cs = { sourceColor[processColorChannelStart + 0], sourceColor[processColorChannelStart + 1], sourceColor[processColorChannelStart + 2] }; const PDFRGB blended = PDFBlendFunction::blend_Nonseparable(mode, Cb, Cs); B_i[processColorChannelStart + 0] = blended[0]; B_i[processColorChannelStart + 1] = blended[1]; B_i[processColorChannelStart + 2] = blended[2]; break; } case 4: { // CMYK const PDFCMYK Cb = { backdropColor[processColorChannelStart + 0], backdropColor[processColorChannelStart + 1], backdropColor[processColorChannelStart + 2], backdropColor[processColorChannelStart + 3] }; const PDFCMYK Cs = { sourceColor[processColorChannelStart + 0], sourceColor[processColorChannelStart + 1], sourceColor[processColorChannelStart + 2], sourceColor[processColorChannelStart + 3] }; const PDFCMYK blended = PDFBlendFunction::blend_Nonseparable(mode, Cb, Cs); B_i[processColorChannelStart + 0] = blended[0]; B_i[processColorChannelStart + 1] = blended[1]; B_i[processColorChannelStart + 2] = blended[2]; B_i[processColorChannelStart + 3] = blended[3]; break; } default: { // This is a serious error. Blended buffer remains unchanged (zero) Q_ASSERT(false); break; } } } if (pixelFormat.hasSpotColors()) { const bool isSpotColorSubtractive = pixelFormat.hasSpotColorsSubtractive(); if (!isSpotColorSubtractive) { for (uint8_t i = spotColorChannelStart; i < spotColorChannelEnd; ++i) { const BlendMode pixelBlendMode = getBlendModeForPixel(x, y, i); B_i[i] = PDFBlendFunction::blend(pixelBlendMode, backdropColor[i], sourceColor[i]); } } else { for (uint8_t i = spotColorChannelStart; i < spotColorChannelEnd; ++i) { const BlendMode pixelBlendMode = getBlendModeForPixel(x, y, i); B_i[i] = 1.0f - PDFBlendFunction::blend(pixelBlendMode, 1.0f - backdropColor[i], 1.0f - sourceColor[i]); } } } } for (uint8_t i = colorChannelStart; i < colorChannelEnd; ++i) { const PDFColorComponent C_s_i = sourceColor[i]; const PDFColorComponent C_b = backdropColor[i]; const PDFColorComponent C_i_1 = targetColor[i]; PDFColorComponent C_t = (f_s_i - alpha_s_i) * alpha_b * C_b + alpha_s_i * ((1.0f - alpha_b) * C_s_i + alpha_b * B_i[i]); PDFColorComponent C_i = ((1.0f - f_s_i) * alpha_i_1 * C_i_1 + C_t) / alpha_i; targetColor[i] = C_i; } targetColor[shapeChannel] = f_g_i; targetColor[opacityChannel] = alpha_g_i; } } } void PDFFloatBitmap::blendConvertedSpots(const PDFFloatBitmap& convertedSpotColors) { Q_ASSERT(convertedSpotColors.getPixelFormat().getProcessColorChannelCount() == m_format.getProcessColorChannelCount()); const uint8_t processColorChannelStart = m_format.getProcessColorChannelIndexStart(); const uint8_t processColorChannelEnd = m_format.getProcessColorChannelIndexEnd(); const PDFColorComponent* sourcePixel = convertedSpotColors.begin(); for (PDFColorComponent* targetPixel = begin(); targetPixel != end(); targetPixel += m_pixelSize, sourcePixel+= convertedSpotColors.getPixelSize()) { for (uint8_t i = processColorChannelStart; i < processColorChannelEnd; ++i) { if (m_format.hasProcessColorsSubtractive()) { targetPixel[i] = PDFBlendFunction::blend_Union(targetPixel[i], sourcePixel[i]); } else { targetPixel[i] = targetPixel[i] * sourcePixel[i]; } } } } void PDFFloatBitmap::fillProcessColorChannels(PDFColorComponent value) { if (!m_format.hasProcessColors()) { // No process colors return; } const uint8_t channelStart = m_format.getProcessColorChannelIndexStart(); const uint8_t channelEnd = m_format.getProcessColorChannelIndexEnd(); for (PDFColorComponent* pixel = begin(); pixel != end(); pixel += m_pixelSize) { std::fill(pixel + channelStart, pixel + channelEnd, value); } } void PDFFloatBitmap::fillChannel(size_t channel, PDFColorComponent value) { // Do we have just one channel? if (m_format.getChannelCount() == 1) { Q_ASSERT(channel == 0); std::fill(m_data.begin(), m_data.end(), value); return; } for (PDFColorComponent* pixel = begin(); pixel != end(); pixel += m_pixelSize) { pixel[channel] = value; } } PDFFloatBitmap PDFFloatBitmap::createOpaqueSoftMask(size_t width, size_t height) { PDFFloatBitmap result(width, height, PDFPixelFormat::createOpacityMask()); result.makeOpaque(); return result; } PDFFloatBitmapWithColorSpace::PDFFloatBitmapWithColorSpace() { } PDFFloatBitmapWithColorSpace::PDFFloatBitmapWithColorSpace(size_t width, size_t height, PDFPixelFormat format) : PDFFloatBitmap(width, height, format) { } PDFFloatBitmapWithColorSpace::PDFFloatBitmapWithColorSpace(size_t width, size_t height, PDFPixelFormat format, PDFColorSpacePointer blendColorSpace) : PDFFloatBitmap(width, height, format), m_colorSpace(blendColorSpace) { } PDFColorSpacePointer PDFFloatBitmapWithColorSpace::getColorSpace() const { return m_colorSpace; } void PDFFloatBitmapWithColorSpace::setColorSpace(const PDFColorSpacePointer& colorSpace) { m_colorSpace = colorSpace; } void PDFFloatBitmapWithColorSpace::convertToColorSpace(const PDFCMS* cms, RenderingIntent intent, const PDFColorSpacePointer& targetColorSpace, PDFRenderErrorReporter* reporter) { Q_ASSERT(m_colorSpace); if (m_colorSpace->equals(targetColorSpace.get())) { return; } const uint8_t targetDeviceColors = static_cast(targetColorSpace->getColorComponentCount()); PDFPixelFormat newFormat = getPixelFormat(); newFormat.setProcessColors(targetDeviceColors); newFormat.setProcessColorsSubtractive(targetDeviceColors == 4); PDFFloatBitmap sourceProcessColors = extractProcessColors(); PDFFloatBitmap targetProcessColors(sourceProcessColors.getWidth(), sourceProcessColors.getHeight(), PDFPixelFormat::createFormat(targetDeviceColors, 0, false, newFormat.hasProcessColorsSubtractive(), newFormat.hasActiveColorMask())); if (!PDFAbstractColorSpace::transform(m_colorSpace.data(), targetColorSpace.data(), cms, intent, sourceProcessColors.getPixels(), targetProcessColors.getPixels(), reporter)) { reporter->reportRenderError(RenderErrorType::Error, PDFTranslationContext::tr("Transformation between blending color space failed.")); } PDFFloatBitmapWithColorSpace temporary(getWidth(), getHeight(), newFormat, targetColorSpace); for (size_t x = 0; x < getWidth(); ++x) { for (size_t y = 0; y < getHeight(); ++y) { PDFColorBuffer sourceProcessColorBuffer = targetProcessColors.getPixel(x, y); PDFColorBuffer sourceSpotColorAndOpacityBuffer = getPixel(x, y); PDFColorBuffer targetBuffer = temporary.getPixel(x, y); Q_ASSERT(sourceProcessColorBuffer.size() <= targetBuffer.size()); // Copy process colors PDFColorComponent* targetIt = targetBuffer.begin(); targetIt = std::copy(sourceProcessColorBuffer.cbegin(), sourceProcessColorBuffer.cend(), targetIt); Q_ASSERT(std::distance(targetIt, targetBuffer.end()) == temporary.getPixelFormat().getSpotColorChannelCount() + temporary.getPixelFormat().getAuxiliaryChannelCount()); const PDFColorComponent* sourceIt = std::next(sourceSpotColorAndOpacityBuffer.cbegin(), getPixelFormat().getProcessColorChannelCount()); targetIt = std::copy(sourceIt, sourceSpotColorAndOpacityBuffer.cend(), targetIt); Q_ASSERT(targetIt == targetBuffer.cend()); } } // Simplification - set all color channels active temporary.setAllColorActive(); *this = qMove(temporary); } PDFTransparencyRenderer::PDFTransparencyRenderer(const PDFPage* page, const PDFDocument* document, const PDFFontCache* fontCache, const PDFCMS* cms, const PDFOptionalContentActivity* optionalContentActivity, const PDFInkMapper* inkMapper, PDFTransparencyRendererSettings settings, QMatrix pagePointToDevicePointMatrix) : BaseClass(page, document, fontCache, cms, optionalContentActivity, pagePointToDevicePointMatrix, PDFMeshQualitySettings()), m_inkMapper(inkMapper), m_active(false), m_settings(settings) { m_deviceColorSpace.reset(new PDFDeviceRGBColorSpace()); m_processColorSpace.reset(new PDFDeviceCMYKColorSpace()); } void PDFTransparencyRenderer::setDeviceColorSpace(PDFColorSpacePointer colorSpace) { if (!colorSpace || colorSpace->isBlendColorSpace()) { // Set device color space only, when it is a blend color space m_deviceColorSpace = colorSpace; } } void PDFTransparencyRenderer::setProcessColorSpace(PDFColorSpacePointer colorSpace) { if (!colorSpace || colorSpace->isBlendColorSpace()) { // Set process color space only, when it is a blend color space m_processColorSpace = colorSpace; } } void PDFTransparencyRenderer::beginPaint(QSize pixelSize) { Q_ASSERT(!m_active); m_active = true; Q_ASSERT(pixelSize.isValid()); Q_ASSERT(m_deviceColorSpace); Q_ASSERT(m_processColorSpace); m_originalProcessBitmap = PDFFloatBitmapWithColorSpace(); m_transparencyGroupDataStack.clear(); m_painterStateStack.push(PDFTransparencyPainterState()); // Initialize initial opaque soft mask PDFFloatBitmap initialSoftMaskBitmap; createOpaqueSoftMask(initialSoftMaskBitmap, pixelSize.width(), pixelSize.height()); m_painterStateStack.top().softMask = PDFTransparencySoftMask(true, qMove(initialSoftMaskBitmap)); PDFPixelFormat pixelFormat = PDFPixelFormat::createFormat(uint8_t(m_deviceColorSpace->getColorComponentCount()), uint8_t(m_inkMapper->getActiveSpotColorCount()), true, m_deviceColorSpace->getColorComponentCount() == 4, true); PDFFloatBitmapWithColorSpace paper = PDFFloatBitmapWithColorSpace(pixelSize.width(), pixelSize.height(), pixelFormat, m_deviceColorSpace); paper.makeColorWhite(); PDFTransparencyGroupPainterData deviceGroup; deviceGroup.alphaIsShape = getGraphicState()->getAlphaIsShape(); deviceGroup.alphaStroke = getGraphicState()->getAlphaStroking(); deviceGroup.alphaFill = getGraphicState()->getAlphaFilling(); deviceGroup.blendMode = getGraphicState()->getBlendMode(); deviceGroup.blackPointCompensationMode = getGraphicState()->getBlackPointCompensationMode(); deviceGroup.renderingIntent = RenderingIntent::RelativeColorimetric; deviceGroup.initialBackdrop = qMove(paper); deviceGroup.immediateBackdrop = deviceGroup.initialBackdrop; deviceGroup.blendColorSpace = m_deviceColorSpace; m_transparencyGroupDataStack.emplace_back(qMove(deviceGroup)); // Create page transparency group PDFObject pageTransparencyGroupObject = getPage()->getTransparencyGroup(&getDocument()->getStorage()); PDFTransparencyGroup transparencyGroup = parseTransparencyGroup(pageTransparencyGroupObject); transparencyGroup.isolated = true; if (!transparencyGroup.colorSpacePointer) { transparencyGroup.colorSpacePointer = m_processColorSpace; } m_pageTransparencyGroupGuard.reset(new PDFTransparencyGroupGuard(this, qMove(transparencyGroup))); m_transparencyGroupDataStack.back().filterColorsUsingMask = (m_settings.flags.testFlag(PDFTransparencyRendererSettings::ActiveColorMask) && m_settings.activeColorMask != PDFPixelFormat::getAllColorsMask()); m_transparencyGroupDataStack.back().activeColorMask = m_settings.activeColorMask; m_transparencyGroupDataStack.back().transformSpotsToDevice = m_settings.flags.testFlag(PDFTransparencyRendererSettings::SeparationSimulation); m_transparencyGroupDataStack.back().saveOriginalImage = m_settings.flags.testFlag(PDFTransparencyRendererSettings::SaveOriginalProcessImage); } const PDFFloatBitmap& PDFTransparencyRenderer::endPaint() { Q_ASSERT(m_active); m_textTransparencyGroupGuard.reset(); // Just safeguard - ET operator may not be present m_pageTransparencyGroupGuard.reset(); m_active = false; m_painterStateStack.pop(); return *getImmediateBackdrop(); } QImage PDFTransparencyRenderer::toImageImpl(const PDFFloatBitmapWithColorSpace& floatImage, bool use16Bit) const { QImage image; Q_ASSERT(floatImage.getPixelFormat().getProcessColorChannelCount() == 3); if (use16Bit) { image = QImage(int(floatImage.getWidth()), int(floatImage.getHeight()), QImage::Format_RGBA64); const PDFPixelFormat pixelFormat = floatImage.getPixelFormat(); const int height = image.height(); const int width = image.width(); const float scale = std::numeric_limits::max(); const uint8_t channelStart = pixelFormat.getProcessColorChannelIndexStart(); const uint8_t channelEnd = pixelFormat.getProcessColorChannelIndexEnd(); const uint8_t opacityChannel = pixelFormat.getOpacityChannelIndex(); for (int y = 0; y < height; ++y) { quint16* pixels = reinterpret_cast(image.bits() + y * image.bytesPerLine()); for (int x = 0; x < width; ++x) { PDFConstColorBuffer colorBuffer = floatImage.getPixel(x, y); for (uint8_t channel = channelStart; channel < channelEnd; ++channel) { *pixels++ = quint16(colorBuffer[channel] * scale); } *pixels++ = quint16(colorBuffer[opacityChannel] * scale); } } } else { image = QImage(int(floatImage.getWidth()), int(floatImage.getHeight()), QImage::Format_RGBA8888); const PDFPixelFormat pixelFormat = floatImage.getPixelFormat(); const int height = image.height(); const int width = image.width(); const float scale = std::numeric_limits::max(); const uint8_t channelStart = pixelFormat.getProcessColorChannelIndexStart(); const uint8_t channelEnd = pixelFormat.getProcessColorChannelIndexEnd(); const uint8_t opacityChannel = pixelFormat.getOpacityChannelIndex(); for (int y = 0; y < height; ++y) { quint8* pixels = reinterpret_cast(image.bits() + y * image.bytesPerLine()); for (int x = 0; x < width; ++x) { PDFConstColorBuffer colorBuffer = floatImage.getPixel(x, y); for (uint8_t channel = channelStart; channel < channelEnd; ++channel) { *pixels++ = quint8(colorBuffer[channel] * scale); } *pixels++ = quint8(colorBuffer[opacityChannel] * scale); } } } return image; } QImage PDFTransparencyRenderer::toImage(bool use16Bit, bool usePaper, const PDFRGB& paperColor) const { QImage image; if (m_transparencyGroupDataStack.size() == 1 && // We have finished the painting getImmediateBackdrop()->getPixelFormat().getProcessColorChannelCount() == 3) // We have exactly three process colors (RGB) { const PDFFloatBitmapWithColorSpace& floatImage = *getImmediateBackdrop(); Q_ASSERT(floatImage.getPixelFormat().hasOpacityChannel()); if (!usePaper) { return toImageImpl(floatImage, use16Bit); } PDFFloatBitmapWithColorSpace paperImage(floatImage.getWidth(), floatImage.getHeight(), floatImage.getPixelFormat(), floatImage.getColorSpace()); createPaperBitmap(paperImage, paperColor); PDFFloatBitmap imageSoftMask; createOpaqueSoftMask(imageSoftMask, paperImage.getWidth(), paperImage.getHeight()); QRect blendRegion(0, 0, int(floatImage.getWidth()), int(floatImage.getHeight())); PDFFloatBitmapWithColorSpace::blend(floatImage, paperImage, paperImage, paperImage, imageSoftMask, false, 1.0f, BlendMode::Normal, false, PDFFloatBitmap::OverprintMode::NoOveprint, blendRegion); return toImageImpl(paperImage, use16Bit); } return image; } void PDFTransparencyRenderer::clearColor(const PDFColor& color) { PDFFloatBitmapWithColorSpace* backdrop = getImmediateBackdrop(); const PDFPixelFormat pixelFormat = backdrop->getPixelFormat(); const uint8_t processColorChannelStart = pixelFormat.getProcessColorChannelIndexStart(); const uint8_t processColorChannelEnd = pixelFormat.getProcessColorChannelIndexEnd(); for (uint8_t i = processColorChannelStart; i < processColorChannelEnd; ++i) { if (i >= color.size()) { reportRenderError(RenderErrorType::Error, PDFTranslationContext::tr("Invalid clear color - process color %1 was not found in clear color.").arg(i)); return; } backdrop->fillChannel(i, color[i]); } if (color.size() > pixelFormat.getProcessColorChannelCount()) { reportRenderError(RenderErrorType::Error, PDFTranslationContext::tr("More colors in clear color (%1) than process color channel count (%2).").arg(color.size()).arg(pixelFormat.getProcessColorChannelCount())); } } bool PDFTransparencyRenderer::isContentKindSuppressed(ContentKind kind) const { switch (kind) { case ContentKind::Shapes: if (!m_settings.flags.testFlag(PDFTransparencyRendererSettings::DisplayVectorGraphics)) { return true; } break; case ContentKind::Text: if (!m_settings.flags.testFlag(PDFTransparencyRendererSettings::DisplayText)) { return true; } break; case ContentKind::Images: if (!m_settings.flags.testFlag(PDFTransparencyRendererSettings::DisplayImages)) { return true; } break; case ContentKind::Shading: if (!m_settings.flags.testFlag(PDFTransparencyRendererSettings::DisplayShadings)) { return true; } break; case ContentKind::Tiling: if (!m_settings.flags.testFlag(PDFTransparencyRendererSettings::DisplayTilingPatterns)) { return true; } break; default: Q_ASSERT(false); break; } return BaseClass::isContentKindSuppressed(kind); } void PDFTransparencyRenderer::performPixelSampling(const PDFReal shape, const PDFReal opacity, const uint8_t shapeChannel, const uint8_t opacityChannel, const uint8_t colorChannelStart, const uint8_t colorChannelEnd, int x, int y, const PDFMappedColor& fillColor, const PDFPainterPathSampler& clipSampler, const PDFPainterPathSampler& pathSampler) { const PDFColorComponent clipValue = clipSampler.sample(QPoint(x, y)); const PDFColorComponent objectShapeValue = pathSampler.sample(QPoint(x, y)); const PDFColorComponent shapeValue = objectShapeValue * clipValue * shape; if (shapeValue > 0.0f) { // We consider old object shape - we use Union function to // set shape channel value. PDFColorBuffer pixel = m_drawBuffer.getPixel(x, y); pixel[shapeChannel] = PDFBlendFunction::blend_Union(shapeValue, pixel[shapeChannel]); pixel[opacityChannel] = pixel[shapeChannel] * opacity; // Copy color for (uint8_t colorChannelIndex = colorChannelStart; colorChannelIndex < colorChannelEnd; ++colorChannelIndex) { pixel[colorChannelIndex] = fillColor.mappedColor[colorChannelIndex]; } m_drawBuffer.markPixelActiveColorMask(x, y, fillColor.activeChannels); } } void PDFTransparencyRenderer::performFillFragmentFromTexture(const PDFReal shape, const PDFReal opacity, const uint8_t shapeChannel, const uint8_t opacityChannel, const uint8_t colorChannelStart, const uint8_t colorChannelEnd, int x, int y, const QMatrix& worldToTextureMatrix, const PDFFloatBitmap& texture, const PDFPainterPathSampler& clipSampler) { // Get pixel buffer from texture QPointF sourcePoint(x, y); QPointF texturePoint = sourcePoint * worldToTextureMatrix; if (texturePoint.x() < 0.0 || texturePoint.x() >= texture.getWidth() || texturePoint.y() < 0.0 || texturePoint.y() >= texture.getHeight()) { // Fragment is outside of the texture return; } const size_t texelCoordinateX = qFloor(texturePoint.x()); const size_t texelCoordinateY = qFloor(texturePoint.y()); PDFConstColorBuffer texel = texture.getPixel(texelCoordinateX, texelCoordinateY); const PDFColorComponent clipValue = clipSampler.sample(QPoint(x, y)); const PDFColorComponent objectShapeValue = texel[shapeChannel]; const PDFColorComponent objectOpacityValue = texel[opacityChannel]; const PDFColorComponent shapeValue = objectShapeValue * clipValue * shape; const PDFColorComponent opacityValue = objectOpacityValue * clipValue * shape * opacity; if (shapeValue > 0.0f) { // We consider old object shape - we use Union function to // set shape channel value. PDFColorBuffer pixel = m_drawBuffer.getPixel(x, y); pixel[shapeChannel] = PDFBlendFunction::blend_Union(shapeValue, pixel[shapeChannel]); pixel[opacityChannel] = opacityValue; // Copy color for (uint8_t colorChannelIndex = colorChannelStart; colorChannelIndex < colorChannelEnd; ++colorChannelIndex) { pixel[colorChannelIndex] = texel[colorChannelIndex]; } m_drawBuffer.markPixelActiveColorMask(x, y, texture.getPixelActiveColorMask(texelCoordinateX, texelCoordinateY)); } } void PDFTransparencyRenderer::collapseSpotColorsToDeviceColors(PDFFloatBitmapWithColorSpace& bitmap) { PDFPixelFormat pixelFormat = bitmap.getPixelFormat(); if (!pixelFormat.hasSpotColors()) { return; } const uint8_t spotColorIndexStart = pixelFormat.getSpotColorChannelIndexStart(); const uint8_t spotColorIndexEnd = pixelFormat.getSpotColorChannelIndexEnd(); for (uint8_t i = spotColorIndexStart; i < spotColorIndexEnd; ++i) { // Collapse spot color const PDFInkMapper::ColorInfo* spotColor = m_inkMapper->getActiveSpotColor(i - spotColorIndexStart); Q_ASSERT(spotColor); switch (spotColor->colorSpace->getColorSpace()) { case PDFAbstractColorSpace::ColorSpace::Separation: { PDFFloatBitmap spotColorBitmap = bitmap.extractSpotChannel(i); PDFFloatBitmap processColorBitmap(spotColorBitmap.getWidth(), spotColorBitmap.getHeight(), PDFPixelFormat::createFormat(pixelFormat.getProcessColorChannelCount(), 0, false, pixelFormat.hasProcessColorsSubtractive(), false)); if (!PDFAbstractColorSpace::transform(spotColor->colorSpace.data(), bitmap.getColorSpace().data(), getCMS(), getGraphicState()->getRenderingIntent(), spotColorBitmap.getPixels(), processColorBitmap.getPixels(), this)) { reportRenderError(RenderErrorType::Error, PDFTranslationContext::tr("Transformation of spot color to blend color space failed.")); } bitmap.blendConvertedSpots(processColorBitmap); break; } case PDFAbstractColorSpace::ColorSpace::DeviceN: { PDFFloatBitmap deviceNBitmap(bitmap.getWidth(), bitmap.getHeight(), PDFPixelFormat::createFormat(uint8_t(spotColor->colorSpace->getColorComponentCount()), 0, false, true, false)); PDFFloatBitmap processColorBitmap(bitmap.getWidth(), bitmap.getHeight(), PDFPixelFormat::createFormat(pixelFormat.getProcessColorChannelCount(), 0, false, pixelFormat.hasProcessColorsSubtractive(), false)); deviceNBitmap.copyChannel(bitmap, i, spotColor->colorSpaceIndex); if (!PDFAbstractColorSpace::transform(spotColor->colorSpace.data(), bitmap.getColorSpace().data(), getCMS(), getGraphicState()->getRenderingIntent(), deviceNBitmap.getPixels(), processColorBitmap.getPixels(), this)) { reportRenderError(RenderErrorType::Error, PDFTranslationContext::tr("Transformation of spot color to blend color space failed.")); } bitmap.blendConvertedSpots(processColorBitmap); break; } default: reportRenderError(RenderErrorType::Error, PDFTranslationContext::tr("Transformation of spot color to blend color space failed.")); break; } } } PDFFloatBitmapWithColorSpace PDFTransparencyRenderer::getImage(const PDFImage& sourceImage) { PDFFloatBitmapWithColorSpace bitmap; const PDFImageData& imageData = sourceImage.getImageData(); if (imageData.isValid()) { const bool isImageMask = imageData.getMaskingType() == PDFImageData::MaskingType::ImageMask; if (sourceImage.getColorSpace() && !isImageMask) { bitmap = getColoredImage(sourceImage); } else if (isImageMask) { if (imageData.getBitsPerComponent() != 1) { throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Invalid number bits of image mask (should be 1 bit instead of %1 bits).").arg(imageData.getBitsPerComponent())); } if (imageData.getWidth() == 0 || imageData.getHeight() == 0) { throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Invalid size of image (%1x%2)").arg(imageData.getWidth()).arg(imageData.getHeight())); } bitmap = PDFFloatBitmapWithColorSpace(imageData.getWidth(), imageData.getHeight(), m_drawBuffer.getPixelFormat(), getBlendColorSpace()); const bool flip01 = !imageData.getDecode().empty() && qFuzzyCompare(imageData.getDecode().front(), 1.0); PDFBitReader reader(&imageData.getData(), imageData.getBitsPerComponent()); PDFPixelFormat pixelFormat = bitmap.getPixelFormat(); const PDFMappedColor& fillColor = getMappedFillColor(); Q_ASSERT(fillColor.mappedColor.size() == pixelFormat.getColorChannelCount()); for (size_t i = pixelFormat.getColorChannelIndexStart(); i < pixelFormat.getColorChannelIndexEnd(); ++i) { bitmap.fillChannel(i, fillColor.mappedColor[i]); } Q_ASSERT(pixelFormat.hasShapeChannel()); Q_ASSERT(pixelFormat.hasOpacityChannel()); const uint8_t shapeChannelIndex = pixelFormat.getShapeChannelIndex(); const uint8_t opacityChannelIndex = pixelFormat.getOpacityChannelIndex(); const bool alphaIsShape = getGraphicState()->getAlphaIsShape(); for (unsigned int i = 0, rowCount = imageData.getHeight(); i < rowCount; ++i) { reader.seek(i * imageData.getStride()); for (unsigned int j = 0, colCount = imageData.getWidth(); j < colCount; ++j) { PDFColorBuffer buffer = bitmap.getPixel(j, i); const bool transparent = flip01 != static_cast(reader.read()); if (alphaIsShape) { const PDFColorComponent shapeValue = transparent ? 0.0f : 1.0f; const PDFColorComponent opacityValue = shapeValue; buffer[shapeChannelIndex] = shapeValue; buffer[opacityChannelIndex] = opacityValue; } else { const PDFColorComponent shapeValue = 1.0f; const PDFColorComponent opacityValue = transparent ? 0.0f : 1.0f; buffer[shapeChannelIndex] = shapeValue; buffer[opacityChannelIndex] = opacityValue; } } } bitmap.setColorActivity(fillColor.activeChannels); } } return bitmap; } PDFFloatBitmapWithColorSpace PDFTransparencyRenderer::convertImageToBlendSpace(const PDFFloatBitmapWithColorSpace& image) { PDFFloatBitmapWithColorSpace convertedImage(image.getWidth(), image.getHeight(), m_drawBuffer.getPixelFormat(), getBlendColorSpace()); auto imageColorSpace = image.getColorSpace(); Q_ASSERT(imageColorSpace); const PDFFloatBitmapWithColorSpace* sourceImage = ℑ PDFFloatBitmapWithColorSpace temporaryImage; PDFInkMapping inkMapping = m_inkMapper->createMapping(imageColorSpace.data(), getBlendColorSpace().data(), m_drawBuffer.getPixelFormat()); if (!inkMapping.isValid()) { temporaryImage = image; temporaryImage.convertToColorSpace(getCMS(), getGraphicState()->getRenderingIntent(), getBlendColorSpace(), this); inkMapping = m_inkMapper->createMapping(getBlendColorSpace().data(), getBlendColorSpace().data(), m_drawBuffer.getPixelFormat()); sourceImage = &temporaryImage; } Q_ASSERT(inkMapping.isValid()); const uint8_t sourceBufferShapeChannelIndex = sourceImage->getPixelFormat().getShapeChannelIndex(); const uint8_t sourceBufferOpacityChannelIndex = sourceImage->getPixelFormat().getOpacityChannelIndex(); const uint8_t targetBufferShapeChannelIndex = convertedImage.getPixelFormat().getShapeChannelIndex(); const uint8_t targetBufferOpacityChannelIndex = convertedImage.getPixelFormat().getOpacityChannelIndex(); for (size_t y = 0; y < sourceImage->getHeight(); ++y) { for (size_t x = 0; x < sourceImage->getWidth(); ++x) { PDFConstColorBuffer sourceBuffer = sourceImage->getPixel(x, y); PDFColorBuffer targetBuffer = convertedImage.getPixel(x, y); for (const PDFInkMapping::Mapping& ink : inkMapping.mapping) { switch (ink.type) { case pdf::PDFInkMapping::Pass: targetBuffer[ink.target] = sourceBuffer[ink.source]; break; default: Q_ASSERT(false); break; } } targetBuffer[targetBufferShapeChannelIndex] = sourceBuffer[sourceBufferShapeChannelIndex]; targetBuffer[targetBufferOpacityChannelIndex] = sourceBuffer[sourceBufferOpacityChannelIndex]; } } convertedImage.setColorActivity(inkMapping.activeChannels); return convertedImage; } PDFFloatBitmapWithColorSpace PDFTransparencyRenderer::getColoredImage(const PDFImage& sourceImage) { PDFFloatBitmapWithColorSpace result; const PDFImageData& imageData = sourceImage.getImageData(); const PDFImageData& imageSoftMask = sourceImage.getSoftMaskData(); PDFColorSpacePointer imageColorSpace = sourceImage.getColorSpace(); size_t colorComponentCount = imageColorSpace->getColorComponentCount(); bool isCMYK = colorComponentCount == 4; const bool useSmoothImageTransformation = m_settings.flags.testFlag(PDFTransparencyRendererSettings::SmoothImageTransformation) && sourceImage.isInterpolated(); if (!imageColorSpace) { throw PDFException(PDFTranslationContext::tr("Invalid image color space.")); } auto setColorSpaceAndMakeOpaque = [&](auto imageColorSpace) { result.setColorSpace(imageColorSpace); result.makeOpaque(); }; Q_ASSERT(imageData.isValid()); if (imageColorSpace->getColorSpace() == PDFAbstractColorSpace::ColorSpace::Indexed) { const PDFIndexedColorSpace* indexedColorSpace = dynamic_cast(imageColorSpace.data()); imageColorSpace = indexedColorSpace->getBaseColorSpace(); if (!imageColorSpace) { throw PDFException(PDFTranslationContext::tr("Invalid base color space of indexed color space.")); } unsigned int componentCount = imageData.getComponents(); PDFBitReader reader(&imageData.getData(), imageData.getBitsPerComponent()); if (componentCount != colorComponentCount) { throw PDFException(PDFTranslationContext::tr("Invalid colors for indexed color space. Color space has %1 colors. Provided color count is %4.").arg(colorComponentCount).arg(componentCount)); } const unsigned int imageWidth = imageData.getWidth(); const unsigned int imageHeight = imageData.getHeight(); Q_ASSERT(componentCount == 1); std::vector colorIndices; colorIndices.reserve(imageData.getWidth() * imageData.getHeight()); for (unsigned int i = 0; i < imageHeight; ++i) { reader.seek(i * imageData.getStride()); for (unsigned int j = 0; j < imageWidth; ++j) { PDFBitReader::Value index = reader.read(); colorIndices.push_back(index); } } PDFColorBuffer indicesBuffer(colorIndices.data(), colorIndices.size()); std::vector transformedColors = indexedColorSpace->transformColorsToBaseColorSpace(indicesBuffer); colorComponentCount = imageColorSpace->getColorComponentCount(); isCMYK = colorComponentCount == 4; if (transformedColors.size() != colorComponentCount * imageWidth * imageHeight) { throw PDFException(PDFTranslationContext::tr("Conversion of indexed image to base color space failed.")); } result = PDFFloatBitmapWithColorSpace(imageWidth, imageHeight, PDFPixelFormat::createFormat(uint8_t(colorComponentCount), 0, true, isCMYK, false)); setColorSpaceAndMakeOpaque(imageColorSpace); for (unsigned int i = 0; i < imageHeight; ++i) { for (unsigned int j = 0; j < imageWidth; ++j) { PDFColorBuffer buffer = result.getPixel(j, i); size_t pixelIndex = (i * imageWidth + j) * colorComponentCount; for (size_t k = 0; k < colorComponentCount; ++k) { Q_ASSERT(pixelIndex + k < transformedColors.size()); buffer[k] = transformedColors[pixelIndex + k]; } } } switch (imageData.getMaskingType()) { case PDFImageData::MaskingType::None: break; case PDFImageData::MaskingType::SoftMask: { PDFFloatBitmap alphaMask = getAlphaMaskFromSoftMask(imageSoftMask); if (alphaMask.getWidth() != result.getWidth() || alphaMask.getHeight() != result.getHeight()) { // Scale the alpha mask, if it is masked alphaMask = alphaMask.resize(result.getWidth(), result.getHeight(), useSmoothImageTransformation ? Qt::SmoothTransformation : Qt::FastTransformation); } Q_ASSERT(alphaMask.getPixelFormat().getChannelCount() == 2); Q_ASSERT(alphaMask.getPixelFormat().hasOpacityChannel()); Q_ASSERT(alphaMask.getPixelFormat().hasShapeChannel()); Q_ASSERT(result.getPixelFormat().hasShapeChannel()); Q_ASSERT(result.getPixelFormat().hasOpacityChannel()); const uint8_t sourceShapeChannelIndex = alphaMask.getPixelFormat().getShapeChannelIndex(); const uint8_t sourceOpacityChannelIndex = alphaMask.getPixelFormat().getOpacityChannelIndex(); const uint8_t targetShapeChannelIndex = result.getPixelFormat().getShapeChannelIndex(); const uint8_t targetOpacityChannelIndex = result.getPixelFormat().getOpacityChannelIndex(); for (size_t i = 0; i < imageHeight; ++i) { for (unsigned int j = 0; j < imageWidth; ++j) { PDFColorBuffer targetBuffer = result.getPixel(j, i); PDFColorBuffer alphaBuffer = alphaMask.getPixel(j, i); targetBuffer[targetShapeChannelIndex] = alphaBuffer[sourceShapeChannelIndex]; targetBuffer[targetOpacityChannelIndex] = alphaBuffer[sourceOpacityChannelIndex]; } } break; } default: throw PDFRendererException(RenderErrorType::NotImplemented, PDFTranslationContext::tr("Image masking not implemented!")); } } else { switch (imageData.getMaskingType()) { case PDFImageData::MaskingType::None: { result = PDFFloatBitmapWithColorSpace(imageData.getWidth(), imageData.getHeight(), PDFPixelFormat::createFormat(uint8_t(colorComponentCount), 0, true, isCMYK, false)); setColorSpaceAndMakeOpaque(imageColorSpace); unsigned int componentCount = imageData.getComponents(); if (componentCount != colorComponentCount) { throw PDFException(PDFTranslationContext::tr("Invalid colors for color space. Color space has %1 colors. Provided color count is %4.").arg(colorComponentCount).arg(componentCount)); } const std::vector& decode = imageData.getDecode(); if (!decode.empty() && decode.size() != componentCount * 2) { throw PDFException(PDFTranslationContext::tr("Invalid size of the decode array. Expected %1, actual %2.").arg(componentCount * 2).arg(decode.size())); } const unsigned int imageWidth = imageData.getWidth(); const unsigned int imageHeight = imageData.getHeight(); PDFBitReader reader(&imageData.getData(), imageData.getBitsPerComponent()); const PDFColorComponent max = reader.max(); const PDFColorComponent coefficient = 1.0 / max; for (size_t i = 0; i < imageHeight; ++i) { reader.seek(i * imageData.getStride()); for (size_t j = 0; j < imageWidth; ++j) { PDFColorBuffer buffer = result.getPixel(j, i); for (size_t k = 0; k < componentCount; ++k) { PDFReal value = reader.read(); // Interpolate value, if it is not empty if (!decode.empty()) { buffer[k] = interpolateColors(value, 0.0, max, decode[2 * k], decode[2 * k + 1]); } else { buffer[k] = value * coefficient; } } } } break; } case PDFImageData::MaskingType::SoftMask: { result = PDFFloatBitmapWithColorSpace(imageData.getWidth(), imageData.getHeight(), PDFPixelFormat::createFormat(uint8_t(colorComponentCount), 0, true, isCMYK, false)); result.setColorSpace(imageColorSpace); const bool hasMatte = !imageSoftMask.getMatte().empty(); std::vector matte = imageSoftMask.getMatte(); if (hasMatte && matte.size() != colorComponentCount) { reportRenderError(RenderErrorType::Warning, PDFTranslationContext::tr("Invalid matte color.")); } matte.resize(colorComponentCount, 0.0f); unsigned int componentCount = imageData.getComponents(); if (componentCount != colorComponentCount) { throw PDFException(PDFTranslationContext::tr("Invalid colors for color space. Color space has %1 colors. Provided color count is %4.").arg(colorComponentCount).arg(componentCount)); } const std::vector& decode = imageData.getDecode(); if (!decode.empty() && decode.size() != componentCount * 2) { throw PDFException(PDFTranslationContext::tr("Invalid size of the decode array. Expected %1, actual %2.").arg(componentCount * 2).arg(decode.size())); } const unsigned int imageWidth = imageData.getWidth(); const unsigned int imageHeight = imageData.getHeight(); PDFFloatBitmap alphaMask = getAlphaMaskFromSoftMask(imageSoftMask); if (alphaMask.getWidth() != result.getWidth() || alphaMask.getHeight() != result.getHeight()) { // Scale the alpha mask, if it is masked alphaMask = alphaMask.resize(result.getWidth(), result.getHeight(), useSmoothImageTransformation ? Qt::SmoothTransformation : Qt::FastTransformation); } Q_ASSERT(alphaMask.getPixelFormat().getChannelCount() == 2); Q_ASSERT(alphaMask.getPixelFormat().hasOpacityChannel()); Q_ASSERT(alphaMask.getPixelFormat().hasShapeChannel()); PDFBitReader reader(&imageData.getData(), imageData.getBitsPerComponent()); const PDFColorComponent max = reader.max(); const PDFColorComponent coefficient = 1.0 / max; Q_ASSERT(result.getPixelFormat().hasShapeChannel()); Q_ASSERT(result.getPixelFormat().hasOpacityChannel()); const uint8_t sourceShapeChannelIndex = alphaMask.getPixelFormat().getShapeChannelIndex(); const uint8_t sourceOpacityChannelIndex = alphaMask.getPixelFormat().getOpacityChannelIndex(); const uint8_t targetShapeChannelIndex = result.getPixelFormat().getShapeChannelIndex(); const uint8_t targetOpacityChannelIndex = result.getPixelFormat().getOpacityChannelIndex(); for (size_t i = 0; i < imageHeight; ++i) { reader.seek(i * imageData.getStride()); for (unsigned int j = 0; j < imageWidth; ++j) { PDFColorBuffer targetBuffer = result.getPixel(j, i); PDFColorBuffer alphaBuffer = alphaMask.getPixel(j, i); for (unsigned int k = 0; k < componentCount; ++k) { PDFReal value = reader.read(); // Interpolate value, if it is not empty if (!decode.empty()) { targetBuffer[k] = interpolateColors(value, 0.0, max, decode[2 * k], decode[2 * k + 1]); } else { targetBuffer[k] = value * coefficient; } } targetBuffer[targetShapeChannelIndex] = alphaBuffer[sourceShapeChannelIndex]; targetBuffer[targetOpacityChannelIndex] = alphaBuffer[sourceOpacityChannelIndex]; const PDFColorComponent alpha = targetBuffer[targetOpacityChannelIndex]; // Un-premultiply with matte color, according to chapter 11.6.5.2 in PDF // 2.0 specification, we use inversion of following formula: // // c' = m + alpha * (c - m) // // So, inversion is: // // c = m + (c' - m) / alpha // if (hasMatte && !qFuzzyIsNull(alpha)) { for (unsigned int k = 0; k < componentCount; ++k) { const PDFColorComponent m = matte[k]; targetBuffer[k] = qBound(0.0f, m + (targetBuffer[k] - m) / alpha, 1.0f); } } } } break; } case PDFImageData::MaskingType::ColorKeyMasking: { result = PDFFloatBitmapWithColorSpace(imageData.getWidth(), imageData.getHeight(), PDFPixelFormat::createFormat(uint8_t(colorComponentCount), 0, true, isCMYK, false)); setColorSpaceAndMakeOpaque(imageColorSpace); unsigned int componentCount = imageData.getComponents(); if (componentCount != colorComponentCount) { throw PDFException(PDFTranslationContext::tr("Invalid colors for color space. Color space has %1 colors. Provided color count is %4.").arg(colorComponentCount).arg(componentCount)); } Q_ASSERT(componentCount > 0); const std::vector& colorKeyMask = imageData.getColorKeyMask(); if (colorKeyMask.size() / 2 != componentCount) { throw PDFException(PDFTranslationContext::tr("Invalid number of color components in color key mask. Expected %1, provided %2.").arg(2 * componentCount).arg(colorKeyMask.size())); } const std::vector& decode = imageData.getDecode(); if (!decode.empty() && decode.size() != componentCount * 2) { throw PDFException(PDFTranslationContext::tr("Invalid size of the decoded array. Expected %1, actual %2.").arg(componentCount * 2).arg(decode.size())); } PDFBitReader reader(&imageData.getData(), imageData.getBitsPerComponent()); PDFColor color; color.resize(componentCount); const PDFColorComponent max = reader.max(); const PDFColorComponent coefficient = 1.0 / max; const bool alphaIsShape = getGraphicState()->getAlphaIsShape(); const uint8_t targetShapeChannelIndex = result.getPixelFormat().getShapeChannelIndex(); const uint8_t targetOpacityChannelIndex = result.getPixelFormat().getOpacityChannelIndex(); for (unsigned int i = 0, rowCount = imageData.getHeight(); i < rowCount; ++i) { reader.seek(i * imageData.getStride()); for (unsigned int j = 0; j < imageData.getWidth(); ++j) { // Number of masked-out colors unsigned int maskedColors = 0; PDFColorBuffer targetBuffer = result.getPixel(j, i); for (unsigned int k = 0; k < componentCount; ++k) { PDFBitReader::Value value = reader.read(); // Interpolate value, if decode is not empty if (!decode.empty()) { targetBuffer[k] = interpolateColors(value, 0.0, max, decode[2 * k], decode[2 * k + 1]); } else { targetBuffer[k] = value * coefficient; } Q_ASSERT(2 * k + 1 < colorKeyMask.size()); if (static_cast::type::value_type>(value) >= colorKeyMask[2 * k] && static_cast::type::value_type>(value) <= colorKeyMask[2 * k + 1]) { ++maskedColors; } } const PDFColorComponent alpha = (maskedColors == componentCount) ? 0.0f : 1.0f; const PDFColorComponent shape = alphaIsShape ? alpha : 1.0f; targetBuffer[targetShapeChannelIndex] = shape; targetBuffer[targetOpacityChannelIndex] = alpha; } } break; } default: { throw PDFRendererException(RenderErrorType::NotImplemented, PDFTranslationContext::tr("Image masking not implemented!")); } } } // Jakub Melka: We are mapping into draw buffer, so we must use draw buffer pixel format return convertImageToBlendSpace(result); } PDFFloatBitmap PDFTransparencyRenderer::getAlphaMaskFromSoftMask(const PDFImageData& imageSoftMask) { if (imageSoftMask.getMaskingType() != PDFImageData::MaskingType::None) { throw PDFException(PDFTranslationContext::tr("Soft mask can't have masking.")); } if (imageSoftMask.getWidth() < 1 || imageSoftMask.getHeight() < 1) { throw PDFException(PDFTranslationContext::tr("Invalid size of soft mask.")); } PDFFloatBitmap result(imageSoftMask.getWidth(), imageSoftMask.getHeight(), PDFPixelFormat::createFormat(0, 0, true, false, false)); unsigned int componentCount = imageSoftMask.getComponents(); if (componentCount != 1) { throw PDFException(PDFTranslationContext::tr("Soft mask should have only 1 color component (alpha) instead of %1.").arg(componentCount)); } const std::vector& decode = imageSoftMask.getDecode(); if (!decode.empty() && decode.size() != componentCount * 2) { throw PDFException(PDFTranslationContext::tr("Invalid size of the decode array. Expected %1, actual %2.").arg(componentCount * 2).arg(decode.size())); } PDFBitReader reader(&imageSoftMask.getData(), imageSoftMask.getBitsPerComponent()); PDFColor color; color.resize(componentCount); const PDFColorComponent max = reader.max(); const PDFColorComponent coefficient = 1.0 / max; const uint8_t targetShapeChannelIndex = result.getPixelFormat().getShapeChannelIndex(); const uint8_t targetOpacityChannelIndex = result.getPixelFormat().getOpacityChannelIndex(); const bool alphaIsShape = getGraphicState()->getAlphaIsShape(); for (unsigned int i = 0, rowCount = imageSoftMask.getHeight(); i < rowCount; ++i) { reader.seek(i * imageSoftMask.getStride()); for (unsigned int j = 0, colCount = imageSoftMask.getWidth(); j < colCount; ++j) { PDFColorComponent alpha = 0.0; PDFReal value = reader.read(); // Interpolate value, if it is not empty if (!decode.empty()) { alpha = interpolate(value, 0.0, max, decode[0], decode[1]); } else { alpha = value * coefficient; } alpha = qBound(0.0f, alpha, 1.0f); const PDFColorComponent shape = alphaIsShape ? alpha : 1.0f; PDFColorBuffer targetBuffer = result.getPixel(j, i); targetBuffer[targetShapeChannelIndex] = shape; targetBuffer[targetOpacityChannelIndex] = alpha; } } return result; } void PDFTransparencyRenderer::processSoftMask(const PDFDictionary* softMask) { if (m_painterStateStack.empty()) { // Jakub Melka: This occurs only in initialization phase. // Just quit, opaque soft mask is initialized when beginPaint is called. return; } if (!softMask) { // Make soft mask opaque getPainterState()->softMask.makeOpaque(); } else { PDFSoftMaskDefinition softMaskDefinition = PDFSoftMaskDefinition::parse(softMask, this); if (!softMaskDefinition.getFormStream()) { reportRenderError(RenderErrorType::Error, PDFTranslationContext::tr("Invalind soft mask.")); getPainterState()->softMask.makeOpaque(); return; } // Jakub Melka: Define blend color space PDFColorSpacePointer blendColorSpace = softMaskDefinition.getTransparencyGroup().colorSpacePointer; if (!blendColorSpace) { blendColorSpace.reset(new PDFDeviceRGBColorSpace()); } if (!blendColorSpace->isBlendColorSpace()) { reportRenderError(RenderErrorType::Error, PDFTranslationContext::tr("Invalid blend color space of soft mask definition.")); getPainterState()->softMask.makeOpaque(); return; } PDFInkMapper inkMapper(nullptr, getDocument()); PDFTransparencyRenderer softMaskRenderer(getPage(), getDocument(), getFontCache(), getCMS(), getOptionalContentActivity(), &inkMapper, m_settings, getPagePointToDevicePointMatrix()); softMaskRenderer.initializeProcessor(); PDFPageContentProcessorState graphicState = *getGraphicState(); graphicState.setSoftMask(nullptr); softMaskRenderer.setDeviceColorSpace(blendColorSpace); softMaskRenderer.setProcessColorSpace(blendColorSpace); softMaskRenderer.beginPaint(QSize(int(m_drawBuffer.getWidth()), int(m_drawBuffer.getHeight()))); softMaskRenderer.clearColor(softMaskDefinition.getBackdropColor()); softMaskRenderer.setGraphicsState(graphicState); softMaskRenderer.processForm(softMaskDefinition.getFormStream()); const PDFFloatBitmap& renderedSoftMask = softMaskRenderer.endPaint(); PDFFloatBitmap softMask; switch (softMaskDefinition.getType()) { case pdf::PDFPageContentProcessor::PDFSoftMaskDefinition::Type::Alpha: softMask = renderedSoftMask.extractOpacityChannel(); break; case pdf::PDFPageContentProcessor::PDFSoftMaskDefinition::Type::Luminosity: softMask = renderedSoftMask.extractLuminosityChannel(); break; default: case pdf::PDFPageContentProcessor::PDFSoftMaskDefinition::Type::Invalid: reportRenderError(RenderErrorType::Error, PDFTranslationContext::tr("Invalid soft mask type.")); softMask = renderedSoftMask.extractOpacityChannel(); break; } if (const PDFFunction* function = softMaskDefinition.getTransferFunction()) { const size_t width = softMask.getWidth(); const size_t height = softMask.getHeight(); for (size_t y = 0; y < height; ++y) { for (size_t x = 0; x < width; ++x) { PDFColorBuffer pixel = softMask.getPixel(x, y); PDFReal sourceValue = pixel[0]; PDFReal targetValue = sourceValue; PDFFunction::FunctionResult result = function->apply(&sourceValue, &sourceValue + 1, &targetValue, &targetValue + 1); if (!result) { reportRenderErrorOnce(RenderErrorType::Error, PDFTranslationContext::tr("Evaulation of soft mask transfer function failed.")); } pixel[0] = targetValue; } } } getPainterState()->softMask = PDFTransparencySoftMask(false, qMove(softMask)); } } void PDFTransparencyRenderer::createOpaqueBitmap(PDFFloatBitmap& bitmap) { bitmap.makeOpaque(); } void PDFTransparencyRenderer::createPaperBitmap(PDFFloatBitmap& bitmap, const PDFRGB& paperColor) { bitmap.makeOpaque(); bitmap.fillChannel(0, paperColor[0]); bitmap.fillChannel(1, paperColor[1]); bitmap.fillChannel(2, paperColor[2]); } void PDFTransparencyRenderer::performPathPainting(const QPainterPath& path, bool stroke, bool fill, bool text, Qt::FillRule fillRule) { Q_UNUSED(text); Q_UNUSED(fillRule); QMatrix worldMatrix = getCurrentWorldMatrix(); const PDFReal shapeStroking = getShapeStroking(); const PDFReal opacityStroking = getOpacityStroking(); const PDFReal shapeFilling = getShapeFilling(); const PDFReal opacityFilling = getOpacityFilling(); PDFPixelFormat format = m_drawBuffer.getPixelFormat(); Q_ASSERT(format.hasShapeChannel()); Q_ASSERT(format.hasOpacityChannel()); const uint8_t shapeChannel = format.getShapeChannelIndex(); const uint8_t opacityChannel = format.getOpacityChannelIndex(); const uint8_t colorChannelStart = format.getColorChannelIndexStart(); const uint8_t colorChannelEnd = format.getColorChannelIndexEnd(); if (fill) { QPainterPath worldPath = worldMatrix.map(path); QRect fillRect = getActualFillRect(worldPath.controlPointRect()); // Fill rect may be, or may not be valid. It depends on the painter path // and world matrix. Path can be translated outside of the paint area. if (fillRect.isValid()) { PDFPainterPathSampler clipSampler(m_painterStateStack.top().clipPath, m_settings.samplesCount, 1.0f, fillRect, m_settings.flags.testFlag(PDFTransparencyRendererSettings::PrecisePathSampler)); PDFPainterPathSampler pathSampler(worldPath, m_settings.samplesCount, 0.0f, fillRect, m_settings.flags.testFlag(PDFTransparencyRendererSettings::PrecisePathSampler)); const PDFMappedColor& fillColor = getMappedFillColor(); if (isMultithreadedPathSamplingUsed(fillRect)) { if (fillRect.width() > fillRect.height()) { // Columns PDFIntegerRange range(fillRect.left(), fillRect.right() + 1); auto processEntry = [&, this](int x) { for (int y = fillRect.top(); y <= fillRect.bottom(); ++y) { performPixelSampling(shapeFilling, opacityFilling, shapeChannel, opacityChannel, colorChannelStart, colorChannelEnd, x, y, fillColor, clipSampler, pathSampler); } }; PDFExecutionPolicy::execute(PDFExecutionPolicy::Scope::Content, range.begin(), range.end(), processEntry); } else { // Rows PDFIntegerRange range(fillRect.top(), fillRect.bottom() + 1); auto processEntry = [&, this](int y) { for (int x = fillRect.left(); x <= fillRect.right(); ++x) { performPixelSampling(shapeFilling, opacityFilling, shapeChannel, opacityChannel, colorChannelStart, colorChannelEnd, x, y, fillColor, clipSampler, pathSampler); } }; PDFExecutionPolicy::execute(PDFExecutionPolicy::Scope::Content, range.begin(), range.end(), processEntry); } } else { for (int x = fillRect.left(); x <= fillRect.right(); ++x) { for (int y = fillRect.top(); y <= fillRect.bottom(); ++y) { performPixelSampling(shapeFilling, opacityFilling, shapeChannel, opacityChannel, colorChannelStart, colorChannelEnd, x, y, fillColor, clipSampler, pathSampler); } } } m_drawBuffer.modify(fillRect, true, false); } } if (stroke) { // We must stroke the path. QPainterPathStroker stroker; stroker.setCapStyle(getGraphicState()->getLineCapStyle()); stroker.setWidth(getGraphicState()->getLineWidth()); stroker.setMiterLimit(getGraphicState()->getMitterLimit()); stroker.setJoinStyle(getGraphicState()->getLineJoinStyle()); const PDFLineDashPattern& lineDashPattern = getGraphicState()->getLineDashPattern(); if (!lineDashPattern.isSolid()) { const auto& dashArray = lineDashPattern.getDashArray(); stroker.setDashPattern(QVector(dashArray.begin(), dashArray.end())); stroker.setDashOffset(lineDashPattern.getDashOffset()); } QPainterPath strokedPath = stroker.createStroke(path); QPainterPath worldPath = worldMatrix.map(strokedPath); QRect strokeRect = getActualFillRect(worldPath.controlPointRect()); // Fill rect may be, or may not be valid. It depends on the painter path // and world matrix. Path can be translated outside of the paint area. if (strokeRect.isValid()) { PDFPainterPathSampler clipSampler(m_painterStateStack.top().clipPath, m_settings.samplesCount, 1.0f, strokeRect, m_settings.flags.testFlag(PDFTransparencyRendererSettings::PrecisePathSampler)); PDFPainterPathSampler pathSampler(worldPath, m_settings.samplesCount, 0.0f, strokeRect, m_settings.flags.testFlag(PDFTransparencyRendererSettings::PrecisePathSampler)); const PDFMappedColor& strokeColor = getMappedStrokeColor(); if (isMultithreadedPathSamplingUsed(strokeRect)) { if (strokeRect.width() > strokeRect.height()) { // Columns PDFIntegerRange range(strokeRect.left(), strokeRect.right() + 1); auto processEntry = [&, this](int x) { for (int y = strokeRect.top(); y <= strokeRect.bottom(); ++y) { performPixelSampling(shapeStroking, opacityStroking, shapeChannel, opacityChannel, colorChannelStart, colorChannelEnd, x, y, strokeColor, clipSampler, pathSampler); } }; PDFExecutionPolicy::execute(PDFExecutionPolicy::Scope::Content, range.begin(), range.end(), processEntry); } else { // Rows PDFIntegerRange range(strokeRect.top(), strokeRect.bottom() + 1); auto processEntry = [&, this](int y) { for (int x = strokeRect.left(); x <= strokeRect.right(); ++x) { performPixelSampling(shapeStroking, opacityStroking, shapeChannel, opacityChannel, colorChannelStart, colorChannelEnd, x, y, strokeColor, clipSampler, pathSampler); } }; PDFExecutionPolicy::execute(PDFExecutionPolicy::Scope::Content, range.begin(), range.end(), processEntry); } } else { for (int x = strokeRect.left(); x <= strokeRect.right(); ++x) { for (int y = strokeRect.top(); y <= strokeRect.bottom(); ++y) { performPixelSampling(shapeStroking, opacityStroking, shapeChannel, opacityChannel, colorChannelStart, colorChannelEnd, x, y, strokeColor, clipSampler, pathSampler); } } } m_drawBuffer.modify(strokeRect, false, true); } } flushDrawBuffer(); } bool PDFTransparencyRenderer::performPathPaintingUsingShading(const QPainterPath& path, bool stroke, bool fill, const PDFShadingPattern* shadingPattern) { if (path.isEmpty()) { // Path is empty return true; } // Exactly one of stroke/fill must be true and other must be false Q_ASSERT(stroke != fill); QMatrix worldMatrix = getCurrentWorldMatrix(); QPainterPath worldPath = worldMatrix.map(path); QRect fillRect = getActualFillRect(worldPath.controlPointRect()); if (fillRect.isEmpty()) { // Jakub Melka: nothing to draw, rectangle is empty return true; } std::unique_ptr sampler(shadingPattern->createSampler(getPatternBaseMatrix())); if (!sampler) { // Can't create sampler - this is error reportRenderError(RenderErrorType::Error, PDFTranslationContext::tr("Cannot create shading sampler.")); return true; } // Now, we have a sampler, so we create a texture, which we will later use // as color source. const PDFAbstractColorSpace* colorSpace = shadingPattern->getColorSpace(); const size_t shadingColorComponentCount = colorSpace->getColorComponentCount(); PDFFloatBitmapWithColorSpace texture(fillRect.width() + 1, fillRect.height() + 1, PDFPixelFormat::createFormat(uint8_t(shadingColorComponentCount), 0, true, shadingColorComponentCount == 4, false), shadingPattern->getColorSpacePtr()); QPointF offset = fillRect.topLeft(); PDFPixelFormat texturePixelFormat = texture.getPixelFormat(); uint8_t textureShapeChannel = texturePixelFormat.getShapeChannelIndex(); uint8_t textureOpacityChannel = texturePixelFormat.getOpacityChannelIndex(); if (fillRect.width() > fillRect.height()) { // Columns PDFIntegerRange range(fillRect.left(), fillRect.right() + 1); auto processEntry = [&, this](int x) { for (int y = fillRect.top(); y <= fillRect.bottom(); ++y) { const int texelCoordinateX = x - fillRect.left(); const int texelCoordinateY = y - fillRect.top(); PDFColorBuffer buffer = texture.getPixel(texelCoordinateX, texelCoordinateY); bool isSampled = sampler->sample(QPointF(x, y) + offset, buffer.resized(shadingColorComponentCount), m_settings.shadingAlgorithmLimit); const PDFColorComponent textureSampleShape = isSampled ? 1.0f : 0.0f; buffer[textureShapeChannel] = textureSampleShape; buffer[textureOpacityChannel] = textureSampleShape; } }; PDFExecutionPolicy::execute(PDFExecutionPolicy::Scope::Content, range.begin(), range.end(), processEntry); } else { // Rows PDFIntegerRange range(fillRect.top(), fillRect.bottom() + 1); auto processEntry = [&, this](int y) { for (int x = fillRect.left(); x <= fillRect.right(); ++x) { const int texelCoordinateX = x - fillRect.left(); const int texelCoordinateY = y - fillRect.top(); PDFColorBuffer buffer = texture.getPixel(texelCoordinateX, texelCoordinateY); bool isSampled = sampler->sample(QPointF(x, y) + offset, buffer.resized(shadingColorComponentCount), m_settings.shadingAlgorithmLimit); const PDFColorComponent textureSampleShape = isSampled ? 1.0f : 0.0f; buffer[textureShapeChannel] = textureSampleShape; buffer[textureOpacityChannel] = textureSampleShape; } }; PDFExecutionPolicy::execute(PDFExecutionPolicy::Scope::Content, range.begin(), range.end(), processEntry); } // Convert image to a blend color space texture = convertImageToBlendSpace(texture); texturePixelFormat = texture.getPixelFormat(); textureShapeChannel = texturePixelFormat.getShapeChannelIndex(); textureOpacityChannel = texturePixelFormat.getOpacityChannelIndex(); PDFPainterPathSampler clipSampler(m_painterStateStack.top().clipPath, m_settings.samplesCount, 1.0f, fillRect, m_settings.flags.testFlag(PDFTransparencyRendererSettings::PrecisePathSampler)); PDFPainterPathSampler pathSampler(worldPath, m_settings.samplesCount, 0.0f, fillRect, m_settings.flags.testFlag(PDFTransparencyRendererSettings::PrecisePathSampler)); const PDFReal constantShape = stroke ? getShapeStroking() : getShapeFilling(); const PDFReal constantOpacity = stroke ? getOpacityStroking() : getOpacityFilling(); Q_ASSERT(m_drawBuffer.getPixelFormat() == texture.getPixelFormat()); const PDFPixelFormat drawBufferPixelFormat = m_drawBuffer.getPixelFormat(); const uint8_t drawBufferShapeChannel = drawBufferPixelFormat.getShapeChannelIndex(); const uint8_t drawBufferOpacityChannel = drawBufferPixelFormat.getOpacityChannelIndex(); const uint32_t colorChannelStart = drawBufferPixelFormat.getColorChannelIndexStart(); const uint32_t colorChannelEnd = drawBufferPixelFormat.getColorChannelIndexEnd(); for (int x = fillRect.left(); x <= fillRect.right(); ++x) { for (int y = fillRect.top(); y <= fillRect.bottom(); ++y) { const int texelCoordinateX = x - fillRect.left(); const int texelCoordinateY = y - fillRect.top(); PDFColorBuffer texel = texture.getPixel(texelCoordinateX, texelCoordinateY); const PDFColorComponent textureShape = texel[drawBufferShapeChannel]; const PDFColorComponent textureOpacity = texel[drawBufferOpacityChannel]; const PDFColorComponent clipValue = clipSampler.sample(QPoint(x, y)); const PDFColorComponent objectShapeValue = pathSampler.sample(QPoint(x, y)); const PDFColorComponent shapeValue = objectShapeValue * clipValue * constantShape * textureShape; const PDFColorComponent opacityValue = shapeValue * constantOpacity * textureOpacity; if (shapeValue > 0.0f) { // We consider old object shape - we use Union function to // set shape channel value. PDFColorBuffer pixel = m_drawBuffer.getPixel(x, y); pixel[drawBufferShapeChannel] = PDFBlendFunction::blend_Union(shapeValue, pixel[drawBufferShapeChannel]); pixel[drawBufferOpacityChannel] = opacityValue; // Copy color for (uint8_t colorChannelIndex = colorChannelStart; colorChannelIndex < colorChannelEnd; ++colorChannelIndex) { pixel[colorChannelIndex] = texel[colorChannelIndex]; } m_drawBuffer.markPixelActiveColorMask(x, y, texture.getPixelActiveColorMask(texelCoordinateX, texelCoordinateY)); } } } m_drawBuffer.modify(fillRect, fill, stroke); return true; } void PDFTransparencyRenderer::performFinishPathPainting() { flushDrawBuffer(); } void PDFTransparencyRenderer::performClipping(const QPainterPath& path, Qt::FillRule fillRule) { Q_UNUSED(fillRule); PDFTransparencyPainterState* painterState = getPainterState(); if (!painterState->clipPath.isEmpty()) { painterState->clipPath = painterState->clipPath.intersected(getCurrentWorldMatrix().map(path)); } else { painterState->clipPath = getCurrentWorldMatrix().map(path); } } void PDFTransparencyRenderer::performUpdateGraphicsState(const PDFPageContentProcessorState& state) { PDFPageContentProcessorState::StateFlags stateFlags = state.getStateFlags(); const bool colorTransformAffected = stateFlags.testFlag(PDFPageContentProcessorState::StateRenderingIntent) || stateFlags.testFlag(PDFPageContentProcessorState::StateBlackPointCompensation); if (colorTransformAffected || stateFlags.testFlag(PDFPageContentProcessorState::StateStrokeColor) || stateFlags.testFlag(PDFPageContentProcessorState::StateStrokeColorSpace)) { m_mappedStrokeColor.dirty(); } if (colorTransformAffected || stateFlags.testFlag(PDFPageContentProcessorState::StateFillColor) || stateFlags.testFlag(PDFPageContentProcessorState::StateFillColorSpace)) { m_mappedFillColor.dirty(); } BaseClass::performUpdateGraphicsState(state); if (stateFlags.testFlag(PDFPageContentProcessorState::StateSoftMask)) { processSoftMask(state.getSoftMask()); } } void PDFTransparencyRenderer::performSaveGraphicState(ProcessOrder order) { if (order == ProcessOrder::AfterOperation) { m_painterStateStack.push(m_painterStateStack.top()); } } void PDFTransparencyRenderer::performRestoreGraphicState(ProcessOrder order) { if (order == ProcessOrder::BeforeOperation) { m_painterStateStack.pop(); } if (order == ProcessOrder::AfterOperation) { invalidateCachedItems(); } } void PDFTransparencyRenderer::performBeginTransparencyGroup(ProcessOrder order, const PDFTransparencyGroup& transparencyGroup) { if (order == ProcessOrder::BeforeOperation) { PDFTransparencyGroupPainterData data; data.group = transparencyGroup; data.alphaIsShape = getGraphicState()->getAlphaIsShape(); data.alphaFill = getGraphicState()->getAlphaFilling(); data.alphaStroke = getGraphicState()->getAlphaStroking(); data.blendMode = getGraphicState()->getBlendMode(); data.blackPointCompensationMode = getGraphicState()->getBlackPointCompensationMode(); data.renderingIntent = getGraphicState()->getRenderingIntent(); data.blendColorSpace = transparencyGroup.colorSpacePointer; if (!data.blendColorSpace) { data.blendColorSpace = getBlendColorSpace(); } // Create initial backdrop, according to 11.4.8 of PDF 2.0 specification. // If group is knockout, use initial backdrop. data.initialBackdrop = *getBackdrop(); if (isTransparencyGroupIsolated()) { // Make initial backdrop transparent data.makeInitialBackdropTransparent(); } else if (!isTransparencyGroupKnockout()) { // We have stored alpha_g_i in immediate buffer. We must mix it with alpha_0 to get alpha_i const PDFFloatBitmapWithColorSpace* initialBackdrop = getInitialBackdrop(); const uint8_t opacityChannelIndex = initialBackdrop->getPixelFormat().getOpacityChannelIndex(); const size_t width = data.initialBackdrop.getWidth(); const size_t height = data.initialBackdrop.getHeight(); for (size_t x = 0; x < width; ++x) { for (size_t y = 0; y < height; ++y) { PDFConstColorBuffer oldPixel = initialBackdrop->getPixel(x, y); PDFColorBuffer newPixel = data.initialBackdrop.getPixel(x, y); newPixel[opacityChannelIndex] = PDFBlendFunction::blend_Union(oldPixel[opacityChannelIndex], newPixel[opacityChannelIndex]); } } } // Prepare soft mask data.softMask = getPainterState()->softMask; data.initialBackdrop.convertToColorSpace(getCMS(), data.renderingIntent, data.blendColorSpace, this); data.immediateBackdrop = data.initialBackdrop; // Jakub Melka: According to 11.4.8 of PDF 2.0 specification, we must // initialize f_g_0 and alpha_g_0 to zero. We store f_g_0 and alpha_g_0 // in the immediate backdrop, so we will make it transparent. data.makeImmediateBackdropTransparent(); // Create draw buffer m_drawBuffer = PDFDrawBuffer(data.immediateBackdrop.getWidth(), data.immediateBackdrop.getHeight(), data.immediateBackdrop.getPixelFormat()); m_transparencyGroupDataStack.emplace_back(qMove(data)); invalidateCachedItems(); } } void PDFTransparencyRenderer::performEndTransparencyGroup(ProcessOrder order, const PDFTransparencyGroup& transparencyGroup) { Q_UNUSED(transparencyGroup); if (order == ProcessOrder::AfterOperation) { // "Unblend" the initial backdrop from immediate backdrop, according to 11.4.8 removeInitialBackdrop(); PDFTransparencyGroupPainterData sourceData = qMove(m_transparencyGroupDataStack.back()); m_transparencyGroupDataStack.pop_back(); // Filter inactive colors - clear all colors in immediate mask, // which are set to inactive. if (sourceData.filterColorsUsingMask) { const PDFPixelFormat pixelFormat = sourceData.immediateBackdrop.getPixelFormat(); const uint32_t colorChannelStart = pixelFormat.getColorChannelIndexStart(); const uint32_t colorChannelEnd = pixelFormat.getColorChannelIndexEnd(); const uint32_t processColorChannelEnd = pixelFormat.getProcessColorChannelIndexEnd(); for (uint32_t colorChannelIndex = colorChannelStart; colorChannelIndex < colorChannelEnd; ++colorChannelIndex) { const uint32_t flag = 1 << colorChannelIndex; if (!(sourceData.activeColorMask & flag)) { const bool isProcessColor = colorChannelIndex < processColorChannelEnd; const bool isSubtractive = isProcessColor ? pixelFormat.hasProcessColorsSubtractive() : pixelFormat.hasSpotColorsSubtractive(); sourceData.immediateBackdrop.fillChannel(colorChannelIndex, isSubtractive ? 0.0f : 1.0f); } } } if (sourceData.saveOriginalImage) { m_originalProcessBitmap = sourceData.immediateBackdrop; } // Collapse spot colors if (sourceData.transformSpotsToDevice) { collapseSpotColorsToDeviceColors(sourceData.immediateBackdrop); } PDFTransparencyGroupPainterData& targetData = m_transparencyGroupDataStack.back(); sourceData.immediateBackdrop.convertToColorSpace(getCMS(), targetData.renderingIntent, targetData.blendColorSpace, this); PDFOverprintMode overprintMode = getGraphicState()->getOverprintMode(); const bool useOverprint = overprintMode.overprintFilling || overprintMode.overprintStroking; PDFFloatBitmap::OverprintMode selectedOverprintMode = PDFFloatBitmap::OverprintMode::NoOveprint; if (useOverprint) { selectedOverprintMode = overprintMode.overprintMode == 0 ? PDFFloatBitmap::OverprintMode::Overprint_Mode_0 : PDFFloatBitmap::OverprintMode::Overprint_Mode_1; } PDFFloatBitmap::blend(sourceData.immediateBackdrop, targetData.immediateBackdrop, *getBackdrop(), *getInitialBackdrop(), *sourceData.softMask.getSoftMask(), sourceData.alphaIsShape, sourceData.alphaFill, sourceData.blendMode, sourceData.group.knockout, selectedOverprintMode, getPaintRect()); // Create draw buffer PDFFloatBitmapWithColorSpace* backdrop = getImmediateBackdrop(); m_drawBuffer = PDFDrawBuffer(backdrop->getWidth(), backdrop->getHeight(), backdrop->getPixelFormat()); invalidateCachedItems(); } } void PDFTransparencyRenderer::performTextBegin(ProcessOrder order) { if (order == ProcessOrder::AfterOperation && getGraphicState()->getTextKnockout()) { // In a case of text knockout, use text transparency group of type knockout PDFTransparencyGroup transparencyGroup; transparencyGroup.knockout = true; m_textTransparencyGroupGuard.reset(new PDFTransparencyGroupGuard(this, qMove(transparencyGroup))); } } void PDFTransparencyRenderer::performTextEnd(ProcessOrder order) { if (order == ProcessOrder::BeforeOperation) { m_textTransparencyGroupGuard.reset(); } } bool PDFTransparencyRenderer::performOriginalImagePainting(const PDFImage& image) { PDFFloatBitmap texture = getImage(image); if (m_settings.flags.testFlag(PDFTransparencyRendererSettings::SmoothImageTransformation) && image.isInterpolated()) { // Test, if we can use smooth images. We can use them under following conditions: // 1) Transformed rectangle is not skewed or deformed (so vectors (0, 1) and (1, 0) are orthogonal) // 2) We are shrinking the image // 3) Aspect ratio of the image is the same QMatrix matrix = getCurrentWorldMatrix(); QLineF mappedWidthVector = matrix.map(QLineF(0, 0, texture.getWidth(), 0)); QLineF mappedHeightVector = matrix.map(QLineF(0, 0, 0, texture.getHeight())); qreal angle = mappedWidthVector.angleTo(mappedHeightVector); if (qFuzzyCompare(angle, 90.0)) { // Image is not skewed, so we if we are shrinking the image const qreal originalWidth = texture.getWidth(); const qreal originalHeight = texture.getHeight(); const qreal originalRatio = originalWidth / originalHeight; const qreal transformedWidth = mappedWidthVector.length(); const qreal transformedHeight = mappedHeightVector.length(); const qreal transformedRatio = transformedWidth / transformedHeight; if (qFuzzyCompare(originalRatio, transformedRatio) && originalWidth > transformedWidth && originalHeight > transformedHeight) { uint32_t activeColorMask = texture.getPixelActiveColorMask(0, 0); texture = texture.resize(qCeil(transformedWidth), qCeil(transformedHeight), Qt::SmoothTransformation); texture.setColorActivity(activeColorMask); } } } QMatrix imageTransform(1.0 / qreal(texture.getWidth()), 0, 0, 1.0 / qreal(texture.getHeight()), 0, 0); QMatrix worldMatrix = imageTransform * getCurrentWorldMatrix(); // Because Qt uses opposite axis direction than PDF, then we must transform the y-axis // to the opposite (so the image is then unchanged) worldMatrix.translate(0.0, texture.getHeight()); worldMatrix.scale(1, -1); QPolygonF imagePolygon; imagePolygon << QPointF(0.0, 0.0); imagePolygon << QPointF(0.0, texture.getHeight()); imagePolygon << QPointF(texture.getWidth(), texture.getHeight()); imagePolygon << QPointF(texture.getWidth(), 0.0); QMatrix worldToTextureMatrix = worldMatrix.inverted(); QRectF boundingRectangle = worldMatrix.map(imagePolygon).boundingRect(); QRect fillRect = getActualFillRect(boundingRectangle); const PDFReal shape = getShapeFilling(); const PDFReal opacity = getOpacityFilling(); PDFPixelFormat format = m_drawBuffer.getPixelFormat(); Q_ASSERT(format.hasShapeChannel()); Q_ASSERT(format.hasOpacityChannel()); Q_ASSERT(format == texture.getPixelFormat()); const uint8_t shapeChannel = format.getShapeChannelIndex(); const uint8_t opacityChannel = format.getOpacityChannelIndex(); const uint8_t colorChannelStart = format.getColorChannelIndexStart(); const uint8_t colorChannelEnd = format.getColorChannelIndexEnd(); // Fill rect may be, or may not be valid. It depends on the painter path // and world matrix. Path can be translated outside of the paint area. if (fillRect.isValid()) { PDFPainterPathSampler clipSampler(m_painterStateStack.top().clipPath, m_settings.samplesCount, 1.0f, fillRect, m_settings.flags.testFlag(PDFTransparencyRendererSettings::PrecisePathSampler)); if (isMultithreadedPathSamplingUsed(fillRect)) { if (fillRect.width() > fillRect.height()) { // Columns PDFIntegerRange range(fillRect.left(), fillRect.right() + 1); auto processEntry = [&, this](int x) { for (int y = fillRect.top(); y <= fillRect.bottom(); ++y) { performFillFragmentFromTexture(shape, opacity, shapeChannel, opacityChannel, colorChannelStart, colorChannelEnd, x, y, worldToTextureMatrix, texture, clipSampler); } }; PDFExecutionPolicy::execute(PDFExecutionPolicy::Scope::Content, range.begin(), range.end(), processEntry); } else { // Rows PDFIntegerRange range(fillRect.top(), fillRect.bottom() + 1); auto processEntry = [&, this](int y) { for (int x = fillRect.left(); x <= fillRect.right(); ++x) { performFillFragmentFromTexture(shape, opacity, shapeChannel, opacityChannel, colorChannelStart, colorChannelEnd, x, y, worldToTextureMatrix, texture, clipSampler); } }; PDFExecutionPolicy::execute(PDFExecutionPolicy::Scope::Content, range.begin(), range.end(), processEntry); } } else { for (int x = fillRect.left(); x <= fillRect.right(); ++x) { for (int y = fillRect.top(); y <= fillRect.bottom(); ++y) { performFillFragmentFromTexture(shape, opacity, shapeChannel, opacityChannel, colorChannelStart, colorChannelEnd, x, y, worldToTextureMatrix, texture, clipSampler); } } } m_drawBuffer.modify(fillRect, true, false); flushDrawBuffer(); } return true; } void PDFTransparencyRenderer::performImagePainting(const QImage& image) { Q_UNUSED(image); reportRenderErrorOnce(RenderErrorType::NotImplemented, PDFTranslationContext::tr("Image painting not implemented.")); } void PDFTransparencyRenderer::performMeshPainting(const PDFMesh& mesh) { Q_UNUSED(mesh); reportRenderErrorOnce(RenderErrorType::NotImplemented, PDFTranslationContext::tr("Mesh painting not implemented.")); } PDFReal PDFTransparencyRenderer::getShapeStroking() const { return getGraphicState()->getAlphaIsShape() ? getGraphicState()->getAlphaStroking() : 1.0; } PDFReal PDFTransparencyRenderer::getOpacityStroking() const { return !getGraphicState()->getAlphaIsShape() ? getGraphicState()->getAlphaStroking() : 1.0; } PDFReal PDFTransparencyRenderer::getShapeFilling() const { return getGraphicState()->getAlphaIsShape() ? getGraphicState()->getAlphaFilling() : 1.0; } PDFReal PDFTransparencyRenderer::getOpacityFilling() const { return !getGraphicState()->getAlphaIsShape() ? getGraphicState()->getAlphaFilling() : 1.0; } void PDFTransparencyRenderer::invalidateCachedItems() { m_mappedStrokeColor.dirty(); m_mappedFillColor.dirty(); } void PDFTransparencyRenderer::removeInitialBackdrop() { PDFFloatBitmapWithColorSpace* immediateBackdrop = getImmediateBackdrop(); PDFFloatBitmapWithColorSpace* initialBackdrop = getInitialBackdrop(); PDFPixelFormat pixelFormat = immediateBackdrop->getPixelFormat(); const uint8_t alphaChannelIndex = pixelFormat.getOpacityChannelIndex(); const uint8_t colorChannelIndexStart = pixelFormat.getColorChannelIndexStart(); const uint8_t colorChannelIndexEnd= pixelFormat.getColorChannelIndexEnd(); Q_ASSERT(alphaChannelIndex != PDFPixelFormat::INVALID_CHANNEL_INDEX); Q_ASSERT(colorChannelIndexStart != PDFPixelFormat::INVALID_CHANNEL_INDEX); Q_ASSERT(colorChannelIndexEnd != PDFPixelFormat::INVALID_CHANNEL_INDEX); for (size_t x = 0; x < immediateBackdrop->getWidth(); ++x) { for (size_t y = 0; y < immediateBackdrop->getHeight(); ++y) { PDFColorBuffer initialBackdropColorBuffer = initialBackdrop->getPixel(x, y); PDFColorBuffer immediateBackdropColorBuffer = immediateBackdrop->getPixel(x, y); const PDFColorComponent alpha_0 = initialBackdropColorBuffer[alphaChannelIndex]; const PDFColorComponent alpha_g_n = immediateBackdropColorBuffer[alphaChannelIndex]; if (!qFuzzyIsNull(alpha_g_n)) { for (uint8_t i = colorChannelIndexStart; i < colorChannelIndexEnd; ++i) { const PDFColorComponent C_0 = initialBackdropColorBuffer[i]; const PDFColorComponent C_n = immediateBackdropColorBuffer[i]; const PDFColorComponent C = C_n + (C_n - C_0) * alpha_0 * (1.0f / alpha_g_n - 1.0f); const PDFColorComponent C_clipped = qBound(0.0f, C, 1.0f); immediateBackdropColorBuffer[i] = C_clipped; } } } } } PDFFloatBitmapWithColorSpace* PDFTransparencyRenderer::getInitialBackdrop() { return &m_transparencyGroupDataStack.back().initialBackdrop; } PDFFloatBitmapWithColorSpace* PDFTransparencyRenderer::getImmediateBackdrop() { return &m_transparencyGroupDataStack.back().immediateBackdrop; } PDFFloatBitmapWithColorSpace* PDFTransparencyRenderer::getBackdrop() { if (isTransparencyGroupKnockout()) { return getInitialBackdrop(); } else { return getImmediateBackdrop(); } } const PDFFloatBitmapWithColorSpace* PDFTransparencyRenderer::getInitialBackdrop() const { return &m_transparencyGroupDataStack.back().initialBackdrop; } const PDFFloatBitmapWithColorSpace* PDFTransparencyRenderer::getImmediateBackdrop() const { return &m_transparencyGroupDataStack.back().immediateBackdrop; } const PDFFloatBitmapWithColorSpace* PDFTransparencyRenderer::getBackdrop() const { if (isTransparencyGroupKnockout()) { return getInitialBackdrop(); } else { return getImmediateBackdrop(); } } const PDFColorSpacePointer& PDFTransparencyRenderer::getBlendColorSpace() const { return m_transparencyGroupDataStack.back().blendColorSpace; } bool PDFTransparencyRenderer::isTransparencyGroupIsolated() const { return m_transparencyGroupDataStack.back().group.isolated; } bool PDFTransparencyRenderer::isTransparencyGroupKnockout() const { return m_transparencyGroupDataStack.back().group.knockout; } const PDFTransparencyRenderer::PDFMappedColor& PDFTransparencyRenderer::getMappedStrokeColor() { return m_mappedStrokeColor.get(this, &PDFTransparencyRenderer::getMappedStrokeColorImpl); } const PDFTransparencyRenderer::PDFMappedColor& PDFTransparencyRenderer::getMappedFillColor() { return m_mappedFillColor.get(this, &PDFTransparencyRenderer::getMappedFillColorImpl); } void PDFTransparencyRenderer::fillMappedColorUsingMapping(const PDFPixelFormat pixelFormat, PDFMappedColor& result, const PDFInkMapping& inkMapping, const PDFColor& sourceColor) { result.mappedColor.resize(pixelFormat.getColorChannelCount()); // Zero the color for (size_t i = 0; i < pixelFormat.getColorChannelCount(); ++i) { result.mappedColor[i] = 0.0f; } for (const PDFInkMapping::Mapping& ink : inkMapping.mapping) { // Sanity check of source color if (ink.source >= sourceColor.size()) { reportRenderError(RenderErrorType::Error, PDFTranslationContext::tr("Invalid source ink index %1.").arg(ink.source)); continue; } // Sanity check of target color if (ink.target >= result.mappedColor.size()) { reportRenderError(RenderErrorType::Error, PDFTranslationContext::tr("Invalid target ink index %1.").arg(ink.target)); continue; } switch (ink.type) { case pdf::PDFInkMapping::Pass: result.mappedColor[ink.target] = sourceColor[ink.source]; break; default: Q_ASSERT(false); break; } } result.activeChannels = inkMapping.activeChannels; } PDFTransparencyRenderer::PDFMappedColor PDFTransparencyRenderer::createMappedColor(const PDFColor& sourceColor, const PDFAbstractColorSpace* sourceColorSpace) { PDFMappedColor result; const PDFAbstractColorSpace* targetColorSpace = getBlendColorSpace().data(); const PDFPixelFormat pixelFormat = getImmediateBackdrop()->getPixelFormat(); Q_ASSERT(targetColorSpace->equals(getImmediateBackdrop()->getColorSpace().data())); PDFInkMapping inkMapping = m_inkMapper->createMapping(sourceColorSpace, targetColorSpace, pixelFormat); if (inkMapping.isValid()) { fillMappedColorUsingMapping(pixelFormat, result, inkMapping, sourceColor); } else { // Jakub Melka: We must convert color form source color space to target color space std::vector sourceColorVector(sourceColor.size(), 0.0f); for (size_t i = 0; i < sourceColorVector.size(); ++i) { sourceColorVector[i] = sourceColor[i]; } PDFColorBuffer sourceColorBuffer(sourceColorVector.data(), sourceColorVector.size()); std::vector targetColorVector(pixelFormat.getProcessColorChannelCount(), 0.0f); PDFColorBuffer targetColorBuffer(targetColorVector.data(), targetColorVector.size()); if (!PDFAbstractColorSpace::transform(sourceColorSpace, targetColorSpace, getCMS(), getGraphicState()->getRenderingIntent(), sourceColorBuffer, targetColorBuffer, this)) { reportRenderError(RenderErrorType::Error, PDFTranslationContext::tr("Transformation from source color space to target blending color space failed.")); } PDFColor adjustedSourceColor; adjustedSourceColor.resize(targetColorBuffer.size()); for (size_t i = 0; i < targetColorBuffer.size(); ++i) { adjustedSourceColor[i] = targetColorBuffer[i]; } inkMapping = m_inkMapper->createMapping(targetColorSpace, targetColorSpace, pixelFormat); Q_ASSERT(inkMapping.isValid()); fillMappedColorUsingMapping(pixelFormat, result, inkMapping, adjustedSourceColor); } return result; } PDFTransparencyRenderer::PDFMappedColor PDFTransparencyRenderer::getMappedStrokeColorImpl() { const PDFAbstractColorSpace* sourceColorSpace = getGraphicState()->getStrokeColorSpace(); const PDFColor& sourceColor = getGraphicState()->getStrokeColorOriginal(); return createMappedColor(sourceColor, sourceColorSpace); } PDFTransparencyRenderer::PDFMappedColor PDFTransparencyRenderer::getMappedFillColorImpl() { const PDFAbstractColorSpace* sourceColorSpace = getGraphicState()->getFillColorSpace(); const PDFColor& sourceColor = getGraphicState()->getFillColorOriginal(); return createMappedColor(sourceColor, sourceColorSpace); } QRect PDFTransparencyRenderer::getPaintRect() const { return QRect(0, 0, int(getBackdrop()->getWidth()), int(getBackdrop()->getHeight())); } QRect PDFTransparencyRenderer::getActualFillRect(const QRectF& fillRect) const { int xLeft = qFloor(fillRect.left()) - 1; int xRight = qCeil(fillRect.right()) + 1; int yTop = qFloor(fillRect.top()) - 1; int yBottom = qCeil(fillRect.bottom()) + 1; QRect drawRect(xLeft, yTop, xRight - xLeft, yBottom - yTop); return getPaintRect().intersected(drawRect); } void PDFTransparencyRenderer::flushDrawBuffer() { if (m_drawBuffer.isModified()) { PDFOverprintMode overprintMode = getGraphicState()->getOverprintMode(); const bool useOverprint = (overprintMode.overprintFilling && m_drawBuffer.isContainsFilling()) || (overprintMode.overprintStroking && m_drawBuffer.isContainsStroking()); PDFFloatBitmap::OverprintMode selectedOverprintMode = PDFFloatBitmap::OverprintMode::NoOveprint; if (useOverprint) { selectedOverprintMode = overprintMode.overprintMode == 0 ? PDFFloatBitmap::OverprintMode::Overprint_Mode_0 : PDFFloatBitmap::OverprintMode::Overprint_Mode_1; } PDFFloatBitmap::blend(m_drawBuffer, *getImmediateBackdrop(), *getBackdrop(), *getInitialBackdrop(), *getPainterState()->softMask.getSoftMask(), getGraphicState()->getAlphaIsShape(), 1.0f, getGraphicState()->getBlendMode(), isTransparencyGroupKnockout(), selectedOverprintMode, m_drawBuffer.getModifiedRect()); m_drawBuffer.clear(); } } bool PDFTransparencyRenderer::isMultithreadedPathSamplingUsed(QRect fillRect) const { if (!m_settings.flags.testFlag(PDFTransparencyRendererSettings::MultithreadedPathSampler)) { return false; } return fillRect.width() * fillRect.height() > m_settings.multithreadingPathSampleThreshold && fillRect.width() > 1; } PDFInkMapper::PDFInkMapper(const PDFCMSManager* manager, const PDFDocument* document) : m_cmsManager(manager), m_document(document) { // Initialize device separations std::vector graySeparations = getSeparations(1, false); std::vector rgbSeparations = getSeparations(3, false); std::vector cmykSeparations = getSeparations(4, false); m_deviceColors.insert(m_deviceColors.end(), std::make_move_iterator(graySeparations.begin()), std::make_move_iterator(graySeparations.end())); m_deviceColors.insert(m_deviceColors.end(), std::make_move_iterator(rgbSeparations.begin()), std::make_move_iterator(rgbSeparations.end())); m_deviceColors.insert(m_deviceColors.end(), std::make_move_iterator(cmykSeparations.begin()), std::make_move_iterator(cmykSeparations.end())); } std::vector PDFInkMapper::getSeparations(uint32_t processColorCount, bool withSpots) const { std::vector result; result.reserve(getActiveSpotColorCount() + processColorCount); PDFRenderErrorReporterDummy renderErrorReporter; PDFCMSPointer cms = m_cmsManager ? m_cmsManager->getCurrentCMS() : nullptr; switch (processColorCount) { case 1: { PDFDeviceGrayColorSpace grayColorSpace; ColorInfo gray; gray.name = "Gray"; gray.textName = PDFTranslationContext::tr("Gray"); gray.canBeActive = true; gray.active = true; gray.isSpot = false; gray.spotColorIndex = 0; gray.colorSpaceType = PDFAbstractColorSpace::ColorSpace::DeviceGray; gray.color = cms ? grayColorSpace.getColor(PDFColor(1.0f), cms.get(), RenderingIntent::Perceptual, &renderErrorReporter, true) : QColor(); result.emplace_back(qMove(gray)); break; } case 3: { PDFDeviceRGBColorSpace rgbColorSpace; ColorInfo red; red.name = "Red"; red.textName = PDFTranslationContext::tr("Red"); red.canBeActive = true; red.active = true; red.isSpot = false; red.spotColorIndex = 0; red.colorSpaceType = PDFAbstractColorSpace::ColorSpace::DeviceRGB; red.color = cms ? rgbColorSpace.getColor(PDFColor(1.0f, 0.0f, 0.0f), cms.get(), RenderingIntent::Perceptual, &renderErrorReporter, true) : QColor(); result.emplace_back(qMove(red)); ColorInfo green; green.name = "Green"; green.textName = PDFTranslationContext::tr("Green"); green.canBeActive = true; green.active = true; green.isSpot = false; green.spotColorIndex = 1; green.colorSpaceType = PDFAbstractColorSpace::ColorSpace::DeviceRGB; green.color = cms ? rgbColorSpace.getColor(PDFColor(0.0f, 1.0f, 0.0f), cms.get(), RenderingIntent::Perceptual, &renderErrorReporter, true) : QColor(); result.emplace_back(qMove(green)); ColorInfo blue; blue.name = "Blue"; blue.textName = PDFTranslationContext::tr("Blue"); blue.canBeActive = true; blue.active = true; blue.isSpot = false; blue.spotColorIndex = 2; blue.colorSpaceType = PDFAbstractColorSpace::ColorSpace::DeviceRGB; blue.color = cms ? rgbColorSpace.getColor(PDFColor(0.0f, 0.0f, 1.0f), cms.get(), RenderingIntent::Perceptual, &renderErrorReporter, true) : QColor(); result.emplace_back(qMove(blue)); break; } case 4: { PDFDeviceCMYKColorSpace cmykColorSpace; ColorInfo cyan; cyan.name = "Cyan"; cyan.textName = PDFTranslationContext::tr("Cyan"); cyan.canBeActive = true; cyan.active = true; cyan.isSpot = false; cyan.spotColorIndex = 0; cyan.colorSpaceType = PDFAbstractColorSpace::ColorSpace::DeviceCMYK; cyan.color = cms ? cmykColorSpace.getColor(PDFColor(1.0f, 0.0f, 0.0f, 0.0f), cms.get(), RenderingIntent::Perceptual, &renderErrorReporter, true) : QColor(); result.emplace_back(qMove(cyan)); ColorInfo magenta; magenta.name = "Magenta"; magenta.textName = PDFTranslationContext::tr("Magenta"); magenta.canBeActive = true; magenta.active = true; magenta.isSpot = false; magenta.spotColorIndex = 1; magenta.colorSpaceType = PDFAbstractColorSpace::ColorSpace::DeviceCMYK; magenta.color = cms ? cmykColorSpace.getColor(PDFColor(0.0f, 1.0f, 0.0f, 0.0f), cms.get(), RenderingIntent::Perceptual, &renderErrorReporter, true) : QColor(); result.emplace_back(qMove(magenta)); ColorInfo yellow; yellow.name = "Yellow"; yellow.textName = PDFTranslationContext::tr("Yellow"); yellow.canBeActive = true; yellow.active = true; yellow.isSpot = false; yellow.spotColorIndex = 2; yellow.colorSpaceType = PDFAbstractColorSpace::ColorSpace::DeviceCMYK; yellow.color = cms ? cmykColorSpace.getColor(PDFColor(0.0f, 0.0f, 1.0f, 0.0f), cms.get(), RenderingIntent::Perceptual, &renderErrorReporter, true) : QColor(); result.emplace_back(qMove(yellow)); ColorInfo black; black.name = "Black"; black.textName = PDFTranslationContext::tr("Black"); black.canBeActive = true; black.active = true; black.isSpot = false; black.spotColorIndex = 3; black.colorSpaceType = PDFAbstractColorSpace::ColorSpace::DeviceCMYK; black.color = cms ? cmykColorSpace.getColor(PDFColor(0.0f, 0.0f, 0.0f, 1.0f), cms.get(), RenderingIntent::Perceptual, &renderErrorReporter, true) : QColor(); result.emplace_back(qMove(black)); break; } default: { for (uint32_t i = 0; i < processColorCount; ++i) { ColorInfo generic; generic.textName = PDFTranslationContext::tr("Process Generic%1").arg(i + 1); generic.name = generic.textName.toLatin1(); generic.canBeActive = true; generic.active = true; generic.isSpot = false; generic.spotColorIndex = i; result.emplace_back(qMove(generic)); } } } if (withSpots) { for (const auto& spotColor : m_spotColors) { if (!spotColor.active) { // Skip inactive spot colors continue; } result.emplace_back(spotColor); } } return result; } void PDFInkMapper::createSpotColors(bool activate) { m_spotColors.clear(); m_activeSpotColors = 0; PDFRenderErrorReporterDummy renderErrorReporter; PDFCMSPointer cms = m_cmsManager ? m_cmsManager->getCurrentCMS() : nullptr; const PDFCatalog* catalog = m_document->getCatalog(); const size_t pageCount = catalog->getPageCount(); for (size_t i = 0; i < pageCount; ++i) { const PDFPage* page = catalog->getPage(i); PDFObject resources = m_document->getObject(page->getResources()); if (resources.isDictionary() && resources.getDictionary()->hasKey("ColorSpace")) { const PDFDictionary* colorSpaceDictionary = m_document->getDictionaryFromObject(resources.getDictionary()->get("ColorSpace")); if (colorSpaceDictionary) { std::size_t colorSpaces = colorSpaceDictionary->getCount(); for (size_t csIndex = 0; csIndex < colorSpaces; ++ csIndex) { PDFColorSpacePointer colorSpacePointer; try { colorSpacePointer = PDFAbstractColorSpace::createColorSpace(colorSpaceDictionary, m_document, m_document->getObject(colorSpaceDictionary->getValue(csIndex))); } catch (const PDFException&) { // Ignore invalid color spaces continue; } if (!colorSpacePointer) { continue; } switch (colorSpacePointer->getColorSpace()) { case PDFAbstractColorSpace::ColorSpace::Separation: { const PDFSeparationColorSpace* separationColorSpace = dynamic_cast(colorSpacePointer.data()); if (!separationColorSpace->isNone() && !separationColorSpace->isAll() && !separationColorSpace->getColorName().isEmpty()) { // Try to add spot color const QByteArray& colorName = separationColorSpace->getColorName(); if (!containsSpotColor(colorName) && !containsProcessColor(colorName)) { ColorInfo info; info.name = colorName; info.textName = PDFEncoding::convertTextString(info.name); info.colorSpace = colorSpacePointer; info.spotColorIndex = uint32_t(m_spotColors.size()); info.color = cms ? separationColorSpace->getColor(pdf::PDFColor(1.0f), cms.get(), pdf::RenderingIntent::Perceptual, &renderErrorReporter, true) : nullptr; m_spotColors.emplace_back(qMove(info)); } } break; } case PDFAbstractColorSpace::ColorSpace::DeviceN: { const PDFDeviceNColorSpace* deviceNColorSpace = dynamic_cast(colorSpacePointer.data()); if (!deviceNColorSpace->isNone()) { const PDFDeviceNColorSpace::Colorants& colorants = deviceNColorSpace->getColorants(); for (size_t i = 0; i < colorants.size(); ++i) { const PDFDeviceNColorSpace::ColorantInfo& colorantInfo = colorants[i]; if (!containsSpotColor(colorantInfo.name) && !containsProcessColor(colorantInfo.name)) { PDFColor color; color.resize(deviceNColorSpace->getColorComponentCount()); color[i] = 1.0f; ColorInfo info; info.name = colorantInfo.name; info.textName = PDFEncoding::convertTextString(info.name); info.colorSpaceIndex = uint32_t(i); info.colorSpace = colorSpacePointer; info.spotColorIndex = uint32_t(m_spotColors.size()); info.color = cms ? deviceNColorSpace->getColor(color, cms.get(), pdf::RenderingIntent::Perceptual, &renderErrorReporter, true) : nullptr; m_spotColors.emplace_back(qMove(info)); } } } break; } default: break; } } } } } size_t minIndex = qMin(uint32_t(m_spotColors.size()), MAX_SPOT_COLOR_COMPONENTS); for (size_t i = 0; i < minIndex; ++i) { m_spotColors[i].canBeActive = true; } setSpotColorsActive(activate); } bool PDFInkMapper::containsSpotColor(const QByteArray& colorName) const { return getSpotColor(colorName) != nullptr; } bool PDFInkMapper::containsProcessColor(const QByteArray& colorName) const { return getProcessColor(colorName) != nullptr; } const PDFInkMapper::ColorInfo* PDFInkMapper::getSpotColor(const QByteArray& colorName) const { auto it = std::find_if(m_spotColors.cbegin(), m_spotColors.cend(), [&colorName](const auto& info) { return info.name == colorName; }); if (it != m_spotColors.cend()) { return &*it; } return nullptr; } const PDFInkMapper::ColorInfo* PDFInkMapper::getProcessColor(const QByteArray& colorName) const { auto it = std::find_if(m_deviceColors.cbegin(), m_deviceColors.cend(), [&colorName](const auto& info) { return info.name == colorName; }); if (it != m_deviceColors.cend()) { return &*it; } return nullptr; } const PDFInkMapper::ColorInfo* PDFInkMapper::getActiveProcessColor(const QByteArray& colorName, PDFAbstractColorSpace::ColorSpace colorSpace) const { auto it = std::find_if(m_deviceColors.cbegin(), m_deviceColors.cend(), [&colorName, colorSpace](const auto& info) { return info.name == colorName && info.active && info.colorSpaceType == colorSpace; }); if (it != m_deviceColors.cend()) { return &*it; } return nullptr; } const PDFInkMapper::ColorInfo* PDFInkMapper::getActiveSpotColor(size_t index) const { for (const ColorInfo& info : m_spotColors) { if (info.active) { if (index == 0) { return &info; } --index; } } return nullptr; } void PDFInkMapper::setSpotColorsActive(bool active) { m_activeSpotColors = 0; if (active) { for (auto& spotColor : m_spotColors) { if (spotColor.canBeActive) { spotColor.active = true; ++m_activeSpotColors; } } } else { for (auto& spotColor : m_spotColors) { spotColor.active = false; } } } PDFInkMapping PDFInkMapper::createMapping(const PDFAbstractColorSpace* sourceColorSpace, const PDFAbstractColorSpace* targetColorSpace, PDFPixelFormat targetPixelFormat) const { PDFInkMapping mapping; const PDFAbstractColorSpace::ColorSpace colorSpaceType = targetColorSpace->getColorSpace(); Q_ASSERT(targetColorSpace->getColorComponentCount() == targetPixelFormat.getProcessColorChannelCount()); if (sourceColorSpace->equals(targetColorSpace)) { Q_ASSERT(sourceColorSpace->getColorComponentCount() == targetColorSpace->getColorComponentCount()); uint8_t colorCount = uint8_t(targetColorSpace->getColorComponentCount()); mapping.mapping.reserve(colorCount); for (uint8_t i = 0; i < colorCount; ++i) { mapping.map(i, i); } } else { switch (sourceColorSpace->getColorSpace()) { case PDFAbstractColorSpace::ColorSpace::Separation: { const PDFSeparationColorSpace* separationColorSpace = dynamic_cast(sourceColorSpace); if (separationColorSpace->isAll()) { // Map this color to all device colors uint32_t colorCount = static_cast(targetColorSpace->getColorComponentCount()); mapping.mapping.reserve(colorCount); for (size_t i = 0; i < colorCount; ++i) { mapping.map(0, uint8_t(i)); } } else if (!separationColorSpace->isNone() && !separationColorSpace->getColorName().isEmpty()) { const QByteArray& colorName = separationColorSpace->getColorName(); // First try to map it as process color, if we do not succeed, then map it as spot color const ColorInfo* processColor = getActiveProcessColor(colorName, colorSpaceType); if (processColor) { if (targetPixelFormat.hasProcessColors() && processColor->spotColorIndex < targetPixelFormat.getProcessColorChannelCount()) { mapping.map(0, uint8_t(targetPixelFormat.getProcessColorChannelIndexStart() + processColor->spotColorIndex)); } } else { const ColorInfo* spotColor = getSpotColor(colorName); if (spotColor && spotColor->active && targetPixelFormat.hasSpotColors() && spotColor->spotColorIndex < targetPixelFormat.getSpotColorChannelCount()) { mapping.map(0, uint8_t(targetPixelFormat.getSpotColorChannelIndexStart() + spotColor->spotColorIndex)); } } } break; } case PDFAbstractColorSpace::ColorSpace::DeviceN: { const PDFDeviceNColorSpace* deviceNColorSpace = dynamic_cast(sourceColorSpace); if (!deviceNColorSpace->isNone()) { const PDFDeviceNColorSpace::Colorants& colorants = deviceNColorSpace->getColorants(); for (size_t i = 0; i < colorants.size(); ++i) { const PDFDeviceNColorSpace::ColorantInfo& colorantInfo = colorants[i]; // First try to map it as process color, if we do not succeed, then map it as spot color const ColorInfo* processColor = getActiveProcessColor(colorantInfo.name, colorSpaceType); if (processColor) { if (targetPixelFormat.hasProcessColors() && processColor->spotColorIndex < targetPixelFormat.getProcessColorChannelCount()) { mapping.map(uint8_t(i), uint8_t(targetPixelFormat.getProcessColorChannelIndexStart() + processColor->spotColorIndex)); } } else { const ColorInfo* info = getSpotColor(colorantInfo.name); if (info && info->active && targetPixelFormat.hasSpotColors() && info->spotColorIndex < targetPixelFormat.getSpotColorChannelCount()) { mapping.map(uint8_t(i), uint8_t(targetColorSpace->getColorComponentCount() + info->spotColorIndex)); } } } } break; } default: break; } } return mapping; } PDFPainterPathSampler::PDFPainterPathSampler(QPainterPath path, int samplesCount, PDFColorComponent defaultShape, QRect fillRect, bool precise) : m_defaultShape(defaultShape), m_samplesCount(qMax(samplesCount, 1)), m_path(qMove(path)), m_fillRect(fillRect), m_precise(precise) { if (!precise) { m_fillPolygon = m_path.toFillPolygon(); prepareScanLines(); } } PDFColorComponent PDFPainterPathSampler::sample(QPoint point) const { if (m_path.isEmpty() || !m_fillRect.contains(point)) { return m_defaultShape; } if (!m_scanLineInfo.empty()) { return sampleByScanLine(point); } const qreal coordX1 = point.x(); const qreal coordX2 = coordX1 + 1.0; const qreal coordY1 = point.y(); const qreal coordY2 = coordY1 + 1.0; const qreal centerX = (coordX1 + coordX2) * 0.5; const qreal centerY = (coordY1 + coordY2) * 0.5; const QPointF topLeft(coordX1, coordY1); const QPointF topRight(coordX2, coordY1); const QPointF bottomLeft(coordX1, coordY2); const QPointF bottomRight(coordX2, coordY2); if (m_samplesCount <= 1) { // Jakub Melka: Just one sample if (m_precise) { return m_path.contains(QPointF(centerX, centerY)) ? 1.0f : 0.0f; } else { return m_fillPolygon.contains(QPointF(centerX, centerY)) ? 1.0f : 0.0f; } } int cornerHits = 0; Qt::FillRule fillRule = m_path.fillRule(); if (m_precise) { cornerHits += m_path.contains(topLeft) ? 1 : 0; cornerHits += m_path.contains(topRight) ? 1 : 0; cornerHits += m_path.contains(bottomLeft) ? 1 : 0; cornerHits += m_path.contains(bottomRight) ? 1 : 0; } else { cornerHits += m_fillPolygon.containsPoint(topLeft, fillRule) ? 1 : 0; cornerHits += m_fillPolygon.containsPoint(topRight, fillRule) ? 1 : 0; cornerHits += m_fillPolygon.containsPoint(bottomLeft, fillRule) ? 1 : 0; cornerHits += m_fillPolygon.containsPoint(bottomRight, fillRule) ? 1 : 0; } if (cornerHits == 4) { // Completely inside return 1.0; } if (cornerHits == 0) { // Completely outside return 0.0; } // Otherwise we must use regular sample grid const qreal offset = 1.0f / PDFColorComponent(m_samplesCount + 1); PDFColorComponent sampleValue = 0.0f; const PDFColorComponent sampleGain = 1.0f / PDFColorComponent(m_samplesCount * m_samplesCount); for (int ix = 0; ix < m_samplesCount; ++ix) { const qreal x = offset * (ix + 1) + coordX1; for (int iy = 0; iy < m_samplesCount; ++iy) { const qreal y = offset * (iy + 1) + coordY1; if (m_precise) { if (m_path.contains(QPointF(x, y))) { sampleValue += sampleGain; } } else { if (m_fillPolygon.containsPoint(QPointF(x, y), fillRule)) { sampleValue += sampleGain; } } } } return sampleValue; } PDFColorComponent PDFPainterPathSampler::sampleByScanLine(QPoint point) const { int scanLinePosition = point.y() - m_fillRect.y(); size_t scanLineCountPerPixel = getScanLineCountPerPixel(); size_t scanLineTopRow = scanLinePosition * scanLineCountPerPixel; size_t scanLineBottomRow = scanLineTopRow + scanLineCountPerPixel - 1; size_t scanLineGridRowTop = scanLineTopRow + 1; Qt::FillRule fillRule = m_path.fillRule(); auto performSampling = [&](size_t scanLineIndex, PDFReal firstOrdinate, int sampleCount, PDFReal step, PDFReal gain) { ScanLineInfo info = m_scanLineInfo[scanLineIndex]; auto it = std::next(m_scanLineSamples.cbegin(), info.indexStart); PDFReal ordinate = firstOrdinate; PDFColorComponent value = 0.0; auto ordinateIt = it; for (int i = 0; i < sampleCount; ++i) { while (std::next(ordinateIt)->x < ordinate) { ++ordinateIt; } int windingNumber = ordinateIt->windingNumber; const bool inside = (fillRule == Qt::WindingFill) ? windingNumber != 0 : windingNumber % 2 != 0; if (inside) { value += gain; } ordinate += step; } return value; }; const qreal coordX1 = point.x(); const PDFReal cornerValue = performSampling(scanLineTopRow, coordX1, 2, 1.0, 1.0) + performSampling(scanLineBottomRow, coordX1, 2, 1.0, 1.0); if (qFuzzyIsNull(4.0 - cornerValue)) { // Whole inside return 1.0; } if (qFuzzyIsNull(cornerValue)) { // Whole outside return 0.0; } const qreal offset = 1.0f / PDFColorComponent(m_samplesCount + 1); PDFColorComponent sampleValue = 0.0f; const PDFColorComponent sampleGain = 1.0f / PDFColorComponent(m_samplesCount * m_samplesCount); for (size_t i = 0; i < m_samplesCount; ++i) { sampleValue += performSampling(scanLineGridRowTop++, coordX1 + offset, m_samplesCount, offset, sampleGain); } return sampleValue; } size_t PDFPainterPathSampler::getScanLineCountPerPixel() const { return m_samplesCount + 2; } void PDFPainterPathSampler::prepareScanLines() { if (m_fillPolygon.isEmpty()) { return; } for (int yOffset = m_fillRect.top(); yOffset <= m_fillRect.bottom(); ++yOffset) { const qreal coordY1 = yOffset; const qreal coordY2 = coordY1 + 1.0; // Top pixel line if (m_scanLineInfo.empty()) { m_scanLineInfo.emplace_back(createScanLine(coordY1)); } else { m_scanLineInfo.emplace_back(m_scanLineInfo.back()); } // Sample grid const qreal offset = 1.0f / PDFColorComponent(m_samplesCount + 1); for (int iy = 0; iy < m_samplesCount; ++iy) { const qreal y = offset * (iy + 1) + coordY1; m_scanLineInfo.emplace_back(createScanLine(y)); } // Bottom pixel line m_scanLineInfo.emplace_back(createScanLine(coordY2)); } } PDFPainterPathSampler::ScanLineInfo PDFPainterPathSampler::createScanLine(qreal y) { ScanLineInfo result; result.indexStart = m_scanLineSamples.size(); // Add start item m_scanLineSamples.emplace_back(-std::numeric_limits::infinity(), 0); // Traverse polygon, add sample for each polygon line, we must // also implicitly close last edge (if polygon is not closed) for (int i = 1; i < m_fillPolygon.size(); ++i) { createScanLineSample(m_fillPolygon[i - 1], m_fillPolygon[i], y); } if (m_fillPolygon.front() != m_fillPolygon.back()) { createScanLineSample(m_fillPolygon.back(), m_fillPolygon.front(), y); } // Add end item m_scanLineSamples.emplace_back(+std::numeric_limits::infinity(), 0); result.indexEnd = m_scanLineSamples.size(); auto it = std::next(m_scanLineSamples.begin(), result.indexStart); auto itEnd = std::next(m_scanLineSamples.begin(), result.indexEnd); // Jakub Melka: now, sort the line samples and compute properly the winding number std::sort(it, itEnd); int currentWindingNumber = 0; for (; it != itEnd; ++it) { currentWindingNumber += it->windingNumber; it->windingNumber = currentWindingNumber; } return result; } void PDFPainterPathSampler::createScanLineSample(const QPointF& p1, const QPointF& p2, qreal y) { PDFReal y1 = p1.y(); PDFReal y2 = p2.y(); if (qFuzzyIsNull(y2 - y1)) { // Ignore horizontal lines return; } PDFReal x1 = p1.x(); PDFReal x2 = p2.x(); int windingNumber = 1; if (y2 < y1) { std::swap(y1, y2); std::swap(x1, x2); windingNumber = -1; } // Do we have intercept? if (y1 <= y && y < y2) { const PDFReal x = interpolate(y, y1, y2, x1, x2); m_scanLineSamples.emplace_back(x, windingNumber); } } void PDFDrawBuffer::clear() { if (!m_modifiedRect.isValid()) { return; } for (int x = m_modifiedRect.left(); x <= m_modifiedRect.right(); ++x) { for (int y = m_modifiedRect.top(); y <= m_modifiedRect.bottom(); ++y) { PDFColorBuffer buffer = getPixel(x, y); std::fill(buffer.begin(), buffer.end(), 0.0f); setPixelActiveColorMask(x, y, 0); } } m_containsFilling = false; m_containsStroking = false; m_modifiedRect = QRect(); } void PDFDrawBuffer::modify(QRect rect, bool containsFilling, bool containsStroking) { m_modifiedRect = m_modifiedRect.united(rect); m_containsFilling |= containsFilling; m_containsStroking |= containsStroking; } void PDFTransparencyRenderer::PDFTransparencyGroupPainterData::makeInitialBackdropTransparent() { initialBackdrop.makeTransparent(); } void PDFTransparencyRenderer::PDFTransparencyGroupPainterData::makeImmediateBackdropTransparent() { immediateBackdrop.makeTransparent(); immediateBackdrop.setAllColorInactive(); } void PDFTransparencyRenderer::PDFTransparencySoftMask::makeOpaque() { if (!isOpaque()) { m_data->isOpaque = true; m_data->softMask.makeOpaque(); } } PDFInkCoverageCalculator::PDFInkCoverageCalculator(const PDFDocument* document, const PDFFontCache* fontCache, const PDFCMSManager* cmsManager, const PDFOptionalContentActivity* optionalContentActivity, const PDFInkMapper* inkMapper, PDFProgress* progress, PDFTransparencyRendererSettings settings) : m_document(document), m_fontCache(fontCache), m_cmsManager(cmsManager), m_optionalContentActivity(optionalContentActivity), m_inkMapper(inkMapper), m_progress(progress), m_settings(settings) { Q_ASSERT(m_document); Q_ASSERT(m_fontCache); Q_ASSERT(m_cmsManager); Q_ASSERT(m_optionalContentActivity); Q_ASSERT(m_inkMapper); } void PDFInkCoverageCalculator::perform(QSize size, const std::vector& pages) { if (pages.empty()) { // Nothing to do return; } if (m_progress) { m_progress->start(pages.size(), ProgressStartupInfo()); } auto calculatePageCoverage = [this, size](PDFInteger pageIndex) { if (pageIndex >= PDFInteger(m_document->getCatalog()->getPageCount())) { return; } const PDFPage* page = m_document->getCatalog()->getPage(pageIndex); if (!page) { return; } QRectF pageRect = page->getRotatedMediaBox(); QSizeF pageSize = pageRect.size(); pageSize.scale(size.width(), size.height(), Qt::KeepAspectRatio); QSize imageSize = pageSize.toSize(); if (!imageSize.isValid()) { return; } pdf::PDFTransparencyRendererSettings settings; settings.flags.setFlag(PDFTransparencyRendererSettings::SaveOriginalProcessImage, true); // Jakub Melka: debug is very slow, use multithreading #ifdef QT_DEBUG settings.flags.setFlag(PDFTransparencyRendererSettings::MultithreadedPathSampler, true); #endif settings.flags.setFlag(PDFTransparencyRendererSettings::ActiveColorMask, false); settings.flags.setFlag(PDFTransparencyRendererSettings::SeparationSimulation, true); settings.activeColorMask = PDFPixelFormat::getAllColorsMask(); QMatrix pagePointToDevicePoint = pdf::PDFRenderer::createPagePointToDevicePointMatrix(page, QRect(QPoint(0, 0), imageSize)); pdf::PDFCMSPointer cms = m_cmsManager->getCurrentCMS(); pdf::PDFTransparencyRenderer renderer(page, m_document, m_fontCache, cms.data(), m_optionalContentActivity, m_inkMapper, settings, pagePointToDevicePoint); renderer.beginPaint(imageSize); renderer.processContents(); renderer.endPaint(); PDFFloatBitmapWithColorSpace originalProcessImage = renderer.getOriginalProcessBitmap(); QSizeF pageSizeMM = page->getRotatedMediaBoxMM().size(); pdf::PDFPixelFormat pixelFormat = originalProcessImage.getPixelFormat(); pdf::PDFColorComponent totalArea = pageSizeMM.width() * pageSizeMM.height(); pdf::PDFColorComponent pixelArea = totalArea / pdf::PDFColorComponent(originalProcessImage.getWidth() * originalProcessImage.getHeight()); std::vector pageCoverage; const uint8_t colorChannelCount = pixelFormat.getColorChannelCount(); pageCoverage.resize(colorChannelCount, 0.0f); for (size_t y = 0; y < originalProcessImage.getHeight(); ++y) { for (size_t x = 0; x < originalProcessImage.getWidth(); ++x) { const pdf::PDFColorBuffer buffer = originalProcessImage.getPixel(x, y); const pdf::PDFColorComponent alpha = pixelFormat.hasOpacityChannel() ? buffer[pixelFormat.getOpacityChannelIndex()] : 1.0f; for (uint8_t i = 0; i < colorChannelCount; ++i) { pageCoverage[i] += buffer[i] * alpha; } } } std::vector pageRatioCoverage = pageCoverage; for (uint8_t i = 0; i < colorChannelCount; ++i) { pageCoverage[i] *= pixelArea; pageRatioCoverage[i] *= pixelArea / totalArea; } std::vector separations = m_inkMapper->getSeparations(pixelFormat.getProcessColorChannelCount()); Q_ASSERT(pixelFormat.getColorChannelCount() == separations.size()); std::vector results; results.reserve(separations.size()); for (size_t i = 0; i < separations.size(); ++i) { const PDFInkMapper::ColorInfo& colorInfo = separations[i]; InkCoverageChannelInfo info; info.color = colorInfo.color; info.name = colorInfo.name; info.textName = colorInfo.textName; info.isSpot = colorInfo.isSpot; info.coveredArea = pageCoverage[i]; info.ratio = pageRatioCoverage[i]; results.emplace_back(qMove(info)); } if (m_progress) { m_progress->step(); } QMutexLocker lock(&m_mutex); m_inkCoverageResults[pageIndex] = qMove(results); }; PDFExecutionPolicy::execute(PDFExecutionPolicy::Scope::Page, pages.begin(), pages.end(), calculatePageCoverage); if (m_progress) { m_progress->finish(); } } void PDFInkCoverageCalculator::clear() { QMutexLocker lock(&m_mutex); m_inkCoverageResults.clear(); } const std::vector* PDFInkCoverageCalculator::getInkCoverage(PDFInteger pageIndex) const { auto it = m_inkCoverageResults.find(pageIndex); if (it != m_inkCoverageResults.end()) { return &it->second; } static const std::vector dummy; return &dummy; } const PDFInkCoverageCalculator::InkCoverageChannelInfo* PDFInkCoverageCalculator::findCoverageInfoByName(const std::vector& infos, const QByteArray& name) { auto it = std::find_if(infos.cbegin(), infos.cend(), [&name](const auto& info) { return info.name == name; }); if (it != infos.cend()) { return &*it; } return nullptr; } PDFInkCoverageCalculator::InkCoverageChannelInfo* PDFInkCoverageCalculator::findCoverageInfoByName(std::vector& infos, const QByteArray& name) { auto it = std::find_if(infos.begin(), infos.end(), [&name](const auto& info) { return info.name == name; }); if (it != infos.cend()) { return &*it; } return nullptr; } } // namespace pdf