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PDF4QT/Pdf4QtLib/sources/pdfpagecontentprocessor.cpp

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// Copyright (C) 2019-2021 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 <https://www.gnu.org/licenses/>.
#include "pdfpagecontentprocessor.h"
#include "pdfdocument.h"
#include "pdfexception.h"
#include "pdfimage.h"
#include "pdfpattern.h"
#include "pdfexecutionpolicy.h"
#include "pdfstreamfilters.h"
#include <QPainterPathStroker>
namespace pdf
{
// Graphic state operators - mapping from PDF name to the enum, splitted into groups.
// Please see Table 4.1 in PDF Reference 1.7, chapter 4.1 - Graphic Objects.
//
// General graphic state: w, J, j, M, d, ri, i, gs
// Special graphic state: q, Q, cm
// Path construction: m, l, c, v, y, h, re
// Path painting: S, s, F, f, f*, B, B*, b, b*, n
// Clipping paths: W, W*
// Text object: BT, ET
// Text state: Tc, Tw, Tz, TL, Tf, Tr, Ts
// Text positioning: Td, TD, Tm, T*
// Text showing: Tj, TJ, ', "
// Type 3 font: d0, d1
// Color: CS, cs, SC, SCN, sc, scn, G, g, RG, rg, K, k
// Shading pattern: sh
// Inline images: BI, ID, EI
// XObject: Do
// Marked content: MP, DP, BMC, BDC, EMC
// Compatibility: BX, EX
static constexpr const std::pair<const char*, PDFPageContentProcessor::Operator> operators[] =
{
// General graphic state w, J, j, M, d, ri, i, gs
{ "w", PDFPageContentProcessor::Operator::SetLineWidth },
{ "J", PDFPageContentProcessor::Operator::SetLineCap },
{ "j", PDFPageContentProcessor::Operator::SetLineJoin },
{ "M", PDFPageContentProcessor::Operator::SetMitterLimit },
{ "d", PDFPageContentProcessor::Operator::SetLineDashPattern },
{ "ri", PDFPageContentProcessor::Operator::SetRenderingIntent },
{ "i", PDFPageContentProcessor::Operator::SetFlatness },
{ "gs", PDFPageContentProcessor::Operator::SetGraphicState },
// Special graphic state: q, Q, cm
{ "q", PDFPageContentProcessor::Operator::SaveGraphicState },
{ "Q", PDFPageContentProcessor::Operator::RestoreGraphicState },
{ "cm", PDFPageContentProcessor::Operator::AdjustCurrentTransformationMatrix },
// Path construction: m, l, c, v, y, h, re
{ "m", PDFPageContentProcessor::Operator::MoveCurrentPoint },
{ "l", PDFPageContentProcessor::Operator::LineTo },
{ "c", PDFPageContentProcessor::Operator::Bezier123To },
{ "v", PDFPageContentProcessor::Operator::Bezier23To },
{ "y", PDFPageContentProcessor::Operator::Bezier13To },
{ "h", PDFPageContentProcessor::Operator::EndSubpath },
{ "re", PDFPageContentProcessor::Operator::Rectangle },
// Path painting: S, s, f, F, f*, B, B*, b, b*, n
{ "S", PDFPageContentProcessor::Operator::PathStroke },
{ "s", PDFPageContentProcessor::Operator::PathCloseStroke },
{ "f", PDFPageContentProcessor::Operator::PathFillWinding },
{ "F", PDFPageContentProcessor::Operator::PathFillWinding2 },
{ "f*", PDFPageContentProcessor::Operator::PathFillEvenOdd },
{ "B", PDFPageContentProcessor::Operator::PathFillStrokeWinding },
{ "B*", PDFPageContentProcessor::Operator::PathFillStrokeEvenOdd },
{ "b", PDFPageContentProcessor::Operator::PathCloseFillStrokeWinding },
{ "b*", PDFPageContentProcessor::Operator::PathCloseFillStrokeEvenOdd },
{ "n", PDFPageContentProcessor::Operator::PathClear },
// Clipping paths: W, W*
{ "W", PDFPageContentProcessor::Operator::ClipWinding },
{ "W*", PDFPageContentProcessor::Operator::ClipEvenOdd },
// Text object: BT, ET
{ "BT", PDFPageContentProcessor::Operator::TextBegin },
{ "ET", PDFPageContentProcessor::Operator::TextEnd },
// Text state: Tc, Tw, Tz, TL, Tf, Tr, Ts
{ "Tc", PDFPageContentProcessor::Operator::TextSetCharacterSpacing },
{ "Tw", PDFPageContentProcessor::Operator::TextSetWordSpacing },
{ "Tz", PDFPageContentProcessor::Operator::TextSetHorizontalScale },
{ "TL", PDFPageContentProcessor::Operator::TextSetLeading },
{ "Tf", PDFPageContentProcessor::Operator::TextSetFontAndFontSize },
{ "Tr", PDFPageContentProcessor::Operator::TextSetRenderMode },
{ "Ts", PDFPageContentProcessor::Operator::TextSetRise },
// Text positioning: Td, TD, Tm, T*
{ "Td", PDFPageContentProcessor::Operator::TextMoveByOffset },
{ "TD", PDFPageContentProcessor::Operator::TextSetLeadingAndMoveByOffset },
{ "Tm", PDFPageContentProcessor::Operator::TextSetMatrix },
{ "T*", PDFPageContentProcessor::Operator::TextMoveByLeading },
// Text showing: Tj, TJ, ', "
{ "Tj", PDFPageContentProcessor::Operator::TextShowTextString },
{ "TJ", PDFPageContentProcessor::Operator::TextShowTextIndividualSpacing },
{ "'", PDFPageContentProcessor::Operator::TextNextLineShowText },
{ "\"", PDFPageContentProcessor::Operator::TextSetSpacingAndShowText },
// Type 3 font: d0, d1
{ "d0", PDFPageContentProcessor::Operator::Type3FontSetOffset },
{ "d1", PDFPageContentProcessor::Operator::Type3FontSetOffsetAndBB },
// Color: CS, cs, SC, SCN, sc, scn, G, g, RG, rg, K, k
{ "CS", PDFPageContentProcessor::Operator::ColorSetStrokingColorSpace },
{ "cs", PDFPageContentProcessor::Operator::ColorSetFillingColorSpace },
{ "SC", PDFPageContentProcessor::Operator::ColorSetStrokingColor },
{ "SCN", PDFPageContentProcessor::Operator::ColorSetStrokingColorN },
{ "sc", PDFPageContentProcessor::Operator::ColorSetFillingColor },
{ "scn", PDFPageContentProcessor::Operator::ColorSetFillingColorN },
{ "G", PDFPageContentProcessor::Operator::ColorSetDeviceGrayStroking },
{ "g", PDFPageContentProcessor::Operator::ColorSetDeviceGrayFilling },
{ "RG", PDFPageContentProcessor::Operator::ColorSetDeviceRGBStroking },
{ "rg", PDFPageContentProcessor::Operator::ColorSetDeviceRGBFilling },
{ "K", PDFPageContentProcessor::Operator::ColorSetDeviceCMYKStroking },
{ "k", PDFPageContentProcessor::Operator::ColorSetDeviceCMYKFilling },
// Shading pattern: sh
{ "sh", PDFPageContentProcessor::Operator::ShadingPaintShape },
// Inline images: BI, ID, EI
{ "BI", PDFPageContentProcessor::Operator::InlineImageBegin },
{ "ID", PDFPageContentProcessor::Operator::InlineImageData },
{ "EI", PDFPageContentProcessor::Operator::InlineImageEnd },
// XObject: Do
{ "Do", PDFPageContentProcessor::Operator::PaintXObject },
// Marked content: MP, DP, BMC, BDC, EMC
{ "MP", PDFPageContentProcessor::Operator::MarkedContentPoint },
{ "DP", PDFPageContentProcessor::Operator::MarkedContentPointWithProperties },
{ "BMC", PDFPageContentProcessor::Operator::MarkedContentBegin },
{ "BDC", PDFPageContentProcessor::Operator::MarkedContentBeginWithProperties },
{ "EMC", PDFPageContentProcessor::Operator::MarkedContentEnd },
// Compatibility: BX, EX
{ "BX", PDFPageContentProcessor::Operator::CompatibilityBegin },
{ "EX", PDFPageContentProcessor::Operator::CompatibilityEnd }
};
void PDFPageContentProcessor::initDictionaries(const PDFObject& resourcesObject)
{
const PDFObject& resources = m_document->getObject(resourcesObject);
auto getDictionary = [this, &resources](const char* resourceName) -> const pdf::PDFDictionary*
{
if (resources.isDictionary() && resources.getDictionary()->hasKey(resourceName))
{
const PDFObject& resourceDictionary = m_document->getObject(resources.getDictionary()->get(resourceName));
if (resourceDictionary.isDictionary())
{
return resourceDictionary.getDictionary();
}
}
return nullptr;
};
m_colorSpaceDictionary = getDictionary(COLOR_SPACE_DICTIONARY);
m_fontDictionary = getDictionary("Font");
m_xobjectDictionary = getDictionary("XObject");
m_extendedGraphicStateDictionary = getDictionary(PDF_RESOURCE_EXTGSTATE);
m_propertiesDictionary = getDictionary("Properties");
m_shadingDictionary = getDictionary("Shading");
m_patternDictionary = getDictionary("Pattern");
m_procedureSets = NoProcSet;
if (resources.isDictionary() && resources.getDictionary()->hasKey("ProcSet"))
{
PDFDocumentDataLoaderDecorator loader(m_document);
std::vector<QByteArray> procedureSetNames = loader.readNameArrayFromDictionary(resources.getDictionary(), "ProcSet");
ProcedureSets newProcSet = EmptyProcSet;
for (const QByteArray& procedureSetName : procedureSetNames)
{
if (procedureSetName == "PDF")
{
newProcSet.setFlag(PDF);
}
else if (procedureSetName == "Text")
{
newProcSet.setFlag(Text);
}
else if (procedureSetName == "ImageB")
{
newProcSet.setFlag(ImageB);
}
else if (procedureSetName == "ImageC")
{
newProcSet.setFlag(ImageC);
}
else if (procedureSetName == "ImageI")
{
newProcSet.setFlag(ImageI);
}
}
if (newProcSet)
{
m_procedureSets = newProcSet;
}
}
}
PDFPageContentProcessor::PDFPageContentProcessor(const PDFPage* page,
const PDFDocument* document,
const PDFFontCache* fontCache,
const PDFCMS* CMS,
const PDFOptionalContentActivity* optionalContentActivity,
QMatrix pagePointToDevicePointMatrix,
const PDFMeshQualitySettings& meshQualitySettings) :
m_page(page),
m_document(document),
m_fontCache(fontCache),
m_CMS(CMS),
m_optionalContentActivity(optionalContentActivity),
m_colorSpaceDictionary(nullptr),
m_fontDictionary(nullptr),
m_xobjectDictionary(nullptr),
m_extendedGraphicStateDictionary(nullptr),
m_propertiesDictionary(nullptr),
m_shadingDictionary(nullptr),
m_patternDictionary(nullptr),
m_procedureSets(NoProcSet),
m_textBeginEndState(0),
m_compatibilityBeginEndState(0),
m_drawingUncoloredTilingPatternState(0),
m_patternBaseMatrix(pagePointToDevicePointMatrix),
m_pagePointToDevicePointMatrix(pagePointToDevicePointMatrix),
m_meshQualitySettings(meshQualitySettings),
m_structuralParentKey(0)
{
Q_ASSERT(page);
Q_ASSERT(document);
m_structuralParentKey = page->getStructureParentKey();
PDFExecutionPolicy::startProcessingContentStream();
QPainterPath pageRectPath;
pageRectPath.addRect(m_page->getMediaBox());
m_pageBoundingRectDeviceSpace = pagePointToDevicePointMatrix.map(pageRectPath).boundingRect();
initDictionaries(m_page->getResources());
}
PDFPageContentProcessor::~PDFPageContentProcessor()
{
PDFExecutionPolicy::endProcessingContentStream();
}
void PDFPageContentProcessor::initializeProcessor()
{
// Clear the old errors
m_errorList.clear();
// Initialize default color spaces (gray, RGB, CMYK)
try
{
m_deviceGrayColorSpace = PDFAbstractColorSpace::createDeviceColorSpaceByName(m_colorSpaceDictionary, m_document, COLOR_SPACE_NAME_DEVICE_GRAY);
m_deviceRGBColorSpace = PDFAbstractColorSpace::createDeviceColorSpaceByName(m_colorSpaceDictionary, m_document, COLOR_SPACE_NAME_DEVICE_RGB);
m_deviceCMYKColorSpace = PDFAbstractColorSpace::createDeviceColorSpaceByName(m_colorSpaceDictionary, m_document, COLOR_SPACE_NAME_DEVICE_CMYK);
}
catch (PDFException exception)
{
m_errorList.append(PDFRenderError(RenderErrorType::Error, exception.getMessage()));
// Create default color spaces anyway, but do not try to load them...
m_deviceGrayColorSpace.reset(new PDFDeviceGrayColorSpace);
m_deviceRGBColorSpace.reset(new PDFDeviceRGBColorSpace);
m_deviceCMYKColorSpace.reset(new PDFDeviceCMYKColorSpace);
}
m_graphicState.setStrokeColorSpace(m_deviceGrayColorSpace);
m_graphicState.setStrokeColor(m_deviceGrayColorSpace->getDefaultColor(m_CMS, m_graphicState.getRenderingIntent(), this), m_deviceGrayColorSpace->getDefaultColorOriginal());
m_graphicState.setFillColorSpace(m_deviceGrayColorSpace);
m_graphicState.setFillColor(m_deviceGrayColorSpace->getDefaultColor(m_CMS, m_graphicState.getRenderingIntent(), this), m_deviceGrayColorSpace->getDefaultColorOriginal());
m_graphicState.setStateFlags(PDFPageContentProcessorState::StateAll);
updateGraphicState();
}
QList<PDFRenderError> PDFPageContentProcessor::processContents()
{
const PDFObject& contents = m_page->getContents();
// Initialize stream processor
initializeProcessor();
if (contents.isArray())
{
const PDFArray* array = contents.getArray();
const size_t count = array->getCount();
for (size_t i = 0; i < count; ++i)
{
const PDFObject& streamObject = m_document->getObject(array->getItem(i));
if (streamObject.isStream())
{
processContentStream(streamObject.getStream());
}
else
{
m_errorList.append(PDFRenderError(RenderErrorType::Error, PDFTranslationContext::tr("Invalid page contents.")));
}
}
}
else if (contents.isStream())
{
processContentStream(contents.getStream());
}
else
{
m_errorList.append(PDFRenderError(RenderErrorType::Error, PDFTranslationContext::tr("Invalid page contents.")));
}
if (!m_stack.empty())
{
// Stack is not empty. There was more saves than restores. This is error.
m_errorList.append(PDFRenderError(RenderErrorType::Error, PDFTranslationContext::tr("Graphic state stack was saved more times, than was restored.")));
while (!m_stack.empty())
{
operatorRestoreGraphicState();
}
}
finishMarkedContent();
return m_errorList;
}
void PDFPageContentProcessor::reportRenderError(RenderErrorType type, QString message)
{
m_errorList.append(PDFRenderError(type, qMove(message)));
}
void PDFPageContentProcessor::performPathPainting(const QPainterPath& path, bool stroke, bool fill, bool text, Qt::FillRule fillRule)
{
Q_UNUSED(path);
Q_UNUSED(stroke);
Q_UNUSED(fill);
Q_UNUSED(text);
Q_UNUSED(fillRule);
}
bool PDFPageContentProcessor::performPathPaintingUsingShading(const QPainterPath& path, bool stroke, bool fill, const PDFShadingPattern* shadingPattern)
{
Q_UNUSED(path);
Q_UNUSED(stroke);
Q_UNUSED(fill);
Q_UNUSED(shadingPattern);
return false;
}
void PDFPageContentProcessor::performFinishPathPainting()
{
}
void PDFPageContentProcessor::performClipping(const QPainterPath& path, Qt::FillRule fillRule)
{
Q_UNUSED(path);
Q_UNUSED(fillRule);
}
bool PDFPageContentProcessor::performOriginalImagePainting(const PDFImage& image)
{
Q_UNUSED(image);
return false;
}
void PDFPageContentProcessor::performImagePainting(const QImage& image)
{
Q_UNUSED(image);
}
void PDFPageContentProcessor::performMeshPainting(const PDFMesh& mesh)
{
Q_UNUSED(mesh);
}
void PDFPageContentProcessor::performUpdateGraphicsState(const PDFPageContentProcessorState& state)
{
if (state.getStateFlags().testFlag(PDFPageContentProcessorState::StateTextFont) ||
state.getStateFlags().testFlag(PDFPageContentProcessorState::StateTextFontSize))
{
m_realizedFont.dirty();
}
}
void PDFPageContentProcessor::performSaveGraphicState(ProcessOrder order)
{
Q_UNUSED(order);
}
void PDFPageContentProcessor::performRestoreGraphicState(ProcessOrder order)
{
Q_UNUSED(order);
}
void PDFPageContentProcessor::performMarkedContentPoint(const QByteArray& tag, const PDFObject& properties)
{
Q_UNUSED(tag);
Q_UNUSED(properties);
}
void PDFPageContentProcessor::performMarkedContentBegin(const QByteArray& tag, const PDFObject& properties)
{
Q_UNUSED(tag);
Q_UNUSED(properties);
}
void PDFPageContentProcessor::performMarkedContentEnd()
{
}
void PDFPageContentProcessor::performSetCharWidth(PDFReal wx, PDFReal wy)
{
Q_UNUSED(wx);
Q_UNUSED(wy);
}
void PDFPageContentProcessor::performSetCacheDevice(PDFReal wx, PDFReal wy, PDFReal llx, PDFReal lly, PDFReal urx, PDFReal ury)
{
Q_UNUSED(wx);
Q_UNUSED(wy);
Q_UNUSED(llx);
Q_UNUSED(lly);
Q_UNUSED(urx);
Q_UNUSED(ury);
}
void PDFPageContentProcessor::performBeginTransparencyGroup(ProcessOrder order, const PDFTransparencyGroup& transparencyGroup)
{
Q_UNUSED(order);
Q_UNUSED(transparencyGroup);
}
void PDFPageContentProcessor::performEndTransparencyGroup(ProcessOrder order, const PDFTransparencyGroup& transparencyGroup)
{
Q_UNUSED(order);
Q_UNUSED(transparencyGroup);
}
void PDFPageContentProcessor::performOutputCharacter(const PDFTextCharacterInfo& info)
{
Q_UNUSED(info);
}
void PDFPageContentProcessor::performTextBegin(ProcessOrder order)
{
Q_UNUSED(order);
}
void PDFPageContentProcessor::performTextEnd(ProcessOrder order)
{
Q_UNUSED(order);
}
bool PDFPageContentProcessor::isContentKindSuppressed(ContentKind kind) const
{
Q_UNUSED(kind);
return false;
}
void PDFPageContentProcessor::setGraphicsState(const PDFPageContentProcessorState& state)
{
m_graphicState = state;
updateGraphicState();
}
bool PDFPageContentProcessor::isContentSuppressed() const
{
return std::any_of(m_markedContentStack.cbegin(), m_markedContentStack.cend(), [](const MarkedContentState& state) { return state.contentSuppressed; });
}
PDFPageContentProcessor::PDFTransparencyGroup PDFPageContentProcessor::parseTransparencyGroup(const PDFObject& object)
{
PDFTransparencyGroup group;
if (const PDFDictionary* transparencyDictionary = m_document->getDictionaryFromObject(object))
{
const PDFObject& colorSpaceObject = m_document->getObject(transparencyDictionary->get("CS"));
if (!colorSpaceObject.isNull())
{
group.colorSpacePointer = PDFAbstractColorSpace::createColorSpace(m_colorSpaceDictionary, m_document, colorSpaceObject);
if (group.colorSpacePointer && !group.colorSpacePointer->isBlendColorSpace())
{
reportRenderError(RenderErrorType::Error, PDFTranslationContext::tr("Transparency group blending color space is invalid."));
group.colorSpacePointer = nullptr;
}
}
PDFDocumentDataLoaderDecorator loader(m_document);
group.isolated = loader.readBooleanFromDictionary(transparencyDictionary, "I", false);
group.knockout = loader.readBooleanFromDictionary(transparencyDictionary, "K", false);
}
return group;
}
void PDFPageContentProcessor::processContent(const QByteArray& content)
{
PDFLexicalAnalyzer parser(content.constBegin(), content.constEnd());
while (!parser.isAtEnd())
{
bool tokenFetched = false;
PDFInteger oldParserPosition = parser.pos();
try
{
PDFLexicalAnalyzer::Token token = parser.fetch();
tokenFetched = true;
switch (token.type)
{
case PDFLexicalAnalyzer::TokenType::Command:
{
QByteArray command = token.data.toByteArray();
if (command == "BI")
{
// Strategy: We will try to find position of BI/ID/EI in the stream. If we can determine
// length of the stream explicitly, then we use explicit length. We also create a PDFObject
// from the inline image dictionary/image content stream and then process it like XObject.
PDFInteger operatorBIPosition = parser.pos();
PDFInteger operatorIDPosition = parser.findSubstring("ID", operatorBIPosition);
PDFInteger operatorEIPosition = parser.findSubstring("EI", operatorIDPosition);
// According the PDF 1.7 specification, single white space characters is after ID, then the byte
// immediately after it is interpreted as first byte of image data.
PDFInteger startDataPosition = operatorIDPosition + 3;
if (operatorIDPosition == -1 || operatorEIPosition == -1)
{
throw PDFException(PDFTranslationContext::tr("Invalid inline image dictionary, ID operator is missing."));
}
Q_ASSERT(operatorBIPosition < content.size());
Q_ASSERT(operatorIDPosition < content.size());
Q_ASSERT(operatorBIPosition <= operatorIDPosition);
PDFLexicalAnalyzer inlineImageLexicalAnalyzer(content.constBegin() + operatorBIPosition, content.constBegin() + operatorIDPosition);
PDFParser inlineImageParser([&inlineImageLexicalAnalyzer]{ return inlineImageLexicalAnalyzer.fetch(); });
constexpr std::pair<const char*, const char*> replacements[] =
{
{ "BPC", "BitsPerComponent" },
{ "CS", "ColorSpace" },
{ "D", "Decode" },
{ "DP", "DecodeParms" },
{ "F", "Filter" },
{ "H", "Height" },
{ "IM", "ImageMask" },
{ "I", "Interpolate" },
{ "W", "Width" },
{ "L", "Length" },
{ "G", "DeviceGray" },
{ "RGB", "DeviceRGB" },
{ "CMYK", "DeviceCMYK" }
};
std::shared_ptr<PDFDictionary> dictionarySharedPointer = std::make_shared<PDFDictionary>();
PDFDictionary* dictionary = dictionarySharedPointer.get();
while (inlineImageParser.lookahead().type != PDFLexicalAnalyzer::TokenType::EndOfFile)
{
PDFObject nameObject = inlineImageParser.getObject();
PDFObject valueObject = inlineImageParser.getObject();
if (!nameObject.isName())
{
throw PDFException(PDFTranslationContext::tr("Expected name in the inline image dictionary stream."));
}
// Replace the name, if neccessary
QByteArray name = nameObject.getString();
for (auto [string, replacement] : replacements)
{
if (name == string)
{
name = replacement;
break;
}
}
dictionary->addEntry(PDFInplaceOrMemoryString(qMove(name)), qMove(valueObject));
}
PDFDocumentDataLoaderDecorator loader(m_document);
PDFInteger dataLength = 0;
if (dictionary->hasKey("Length"))
{
dataLength = loader.readIntegerFromDictionary(dictionary, "Length", 0);
}
else if (dictionary->hasKey("Filter"))
{
dataLength = -1;
// We will try to use stream filter hint
PDFDocumentDataLoaderDecorator loader(m_document);
QByteArray filterName = loader.readNameFromDictionary(dictionary, "Filter");
if (!filterName.isEmpty())
{
dataLength = PDFStreamFilterStorage::getStreamDataLength(content, filterName, startDataPosition);
}
if (dataLength == -1)
{
// We will use EI operator position to determine stream length
dataLength = operatorEIPosition - startDataPosition;
}
}
else
{
// We will calculate stream size from the with/height and bit per component
const PDFInteger width = loader.readIntegerFromDictionary(dictionary, "Width", 0);
const PDFInteger height = loader.readIntegerFromDictionary(dictionary, "Height", 0);
const PDFInteger bpc = loader.readIntegerFromDictionary(dictionary, "BitsPerComponent", 8);
if (width <= 0 || height <= 0 || bpc <= 0)
{
throw PDFException(PDFTranslationContext::tr("Expected name in the inline image dictionary stream."));
}
const PDFInteger stride = (width * bpc + 7) / 8;
dataLength = stride * height;
}
// We will once more find the "EI" operator, due to recomputed dataLength.
operatorEIPosition = parser.findSubstring("EI", startDataPosition + dataLength);
if (operatorEIPosition == -1)
{
throw PDFException(PDFTranslationContext::tr("Invalid inline image stream."));
}
// We must seek after EI operator. Then we will paint the image. Because painting of image can throw exception,
// then we will paint the image AFTER we seek the position.
parser.seek(operatorEIPosition + 2);
QByteArray buffer = content.mid(startDataPosition, dataLength);
PDFStream imageStream(std::move(*dictionary), std::move(buffer));
paintXObjectImage(&imageStream);
}
else
{
// Process the command, then clear the operand stack
processCommand(command);
}
m_operands.clear();
break;
}
case PDFLexicalAnalyzer::TokenType::EndOfFile:
{
// Do nothing, just break, we are at the end
break;
}
default:
{
// Push the operand onto the operand stack
m_operands.push_back(std::move(token));
break;
}
}
}
catch (PDFException exception)
{
// If we get exception when parsing, and parser position is not advanced,
// then we must advance it manually, otherwise we get infinite loop.
if (!tokenFetched && oldParserPosition == parser.pos() && !parser.isAtEnd())
{
parser.seek(parser.pos() + 1);
}
m_operands.clear();
m_errorList.append(PDFRenderError(RenderErrorType::Error, exception.getMessage()));
}
catch (PDFRendererException exception)
{
m_operands.clear();
m_errorList.append(exception.getError());
}
}
}
void PDFPageContentProcessor::processContentStream(const PDFStream* stream)
{
try
{
QByteArray content = m_document->getDecodedStream(stream);
processContent(content);
}
catch (PDFException exception)
{
m_operands.clear();
m_errorList.append(PDFRenderError(RenderErrorType::Error, exception.getMessage()));
}
}
void PDFPageContentProcessor::processForm(const QMatrix& matrix,
const QRectF& boundingBox,
const PDFObject& resources,
const PDFObject& transparencyGroup,
const QByteArray& content,
PDFInteger formStructuralParent)
{
PDFPageContentProcessorStateGuard guard(this);
PDFTemporaryValueChange structuralParentChangeGuard(&m_structuralParentKey, formStructuralParent);
std::unique_ptr<PDFTransparencyGroupGuard> guard2;
if (transparencyGroup.isDictionary())
{
// Parse the transparency group
const PDFDictionary* transparencyDictionary = transparencyGroup.getDictionary();
PDFDocumentDataLoaderDecorator loader(m_document);
PDFTransparencyGroup group;
const PDFObject& colorSpaceObject = m_document->getObject(transparencyDictionary->get("CS"));
if (!colorSpaceObject.isNull())
{
group.colorSpacePointer = PDFAbstractColorSpace::createColorSpace(m_colorSpaceDictionary, m_document, colorSpaceObject);
}
group.isolated = loader.readBooleanFromDictionary(transparencyDictionary, "I", false);
group.knockout = loader.readBooleanFromDictionary(transparencyDictionary, "K", false);
guard2.reset(new PDFTransparencyGroupGuard(this, qMove(group)));
// If we are in transparency group, we must reset transparency settings in the graphic state.
// Graphic state is then updated in the lines below.
m_graphicState.setBlendMode(BlendMode::Normal);
m_graphicState.setAlphaFilling(1.0);
m_graphicState.setAlphaStroking(1.0);
m_graphicState.setSoftMask(nullptr);
}
QMatrix formMatrix = matrix * m_graphicState.getCurrentTransformationMatrix();
m_graphicState.setCurrentTransformationMatrix(formMatrix);
updateGraphicState();
QMatrix patternMatrix = formMatrix * m_pagePointToDevicePointMatrix;
PDFTemporaryValueChange patternMatrixGuard(&m_patternBaseMatrix, patternMatrix);
// If the clipping box is valid, then use clipping. Clipping box is in the form coordinate system
if (boundingBox.isValid())
{
QPainterPath path;
path.addRect(boundingBox);
performClipping(path, path.fillRule());
}
// Initialize the resources, if we have them
if (!resources.isNull())
{
initDictionaries(resources);
}
processContent(content);
}
void PDFPageContentProcessor::processPathPainting(const QPainterPath& path, bool stroke, bool fill, bool text, Qt::FillRule fillRule)
{
if (isContentSuppressed() || (text && isContentKindSuppressed(ContentKind::Text)) || (!text && isContentKindSuppressed(ContentKind::Shapes)))
{
// Content is suppressed, do not paint anything
return;
}
if ((!stroke && !fill) || path.isEmpty())
{
// No operation requested - either path is empty, or neither stroking or filling
return;
}
if (fill)
{
if (const PDFPatternColorSpace* patternColorSpace = getGraphicState()->getFillColorSpace()->asPatternColorSpace())
{
const PDFPattern* pattern = patternColorSpace->getPattern();
switch (pattern->getType())
{
case PatternType::Tiling:
{
if (!isContentKindSuppressed(ContentKind::Tiling))
{
// Tiling is enabled
const PDFTilingPattern* tilingPattern = pattern->getTilingPattern();
processTillingPatternPainting(tilingPattern, path, patternColorSpace->getUncoloredPatternColorSpace(), patternColorSpace->getUncoloredPatternColor());
}
break;
}
case PatternType::Shading:
{
if (!isContentKindSuppressed(ContentKind::Shading))
{
// Shading is enabled
PDFPageContentProcessorGraphicStateSaveRestoreGuard guard(this);
const PDFShadingPattern* shadingPattern = pattern->getShadingPattern();
// Apply pattern graphic state
const PDFObject& patternGraphicState = m_document->getObject(shadingPattern->getPatternGraphicState());
if (!patternGraphicState.isNull())
{
if (patternGraphicState.isDictionary())
{
processApplyGraphicState(patternGraphicState.getDictionary());
}
else
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Shading pattern graphic state is invalid."));
}
}
// We must create a mesh and then draw pattern
PDFMeshQualitySettings settings = m_meshQualitySettings;
settings.deviceSpaceMeshingArea = getPageBoundingRectDeviceSpace();
settings.userSpaceToDeviceSpaceMatrix = getPatternBaseMatrix();
settings.initResolution();
if (!performPathPaintingUsingShading(path, false, true, shadingPattern))
{
PDFMesh mesh = shadingPattern->createMesh(settings, m_CMS, m_graphicState.getRenderingIntent(), this);
// Now, merge the current path to the mesh clipping path
QPainterPath boundingPath = mesh.getBoundingPath();
if (boundingPath.isEmpty())
{
boundingPath = getCurrentWorldMatrix().map(path);
}
else
{
boundingPath = boundingPath.intersected(path);
}
mesh.setBoundingPath(boundingPath);
performMeshPainting(mesh);
}
}
break;
}
case PatternType::Invalid:
{
throw PDFException(PDFTranslationContext::tr("Invalid pattern."));
break;
}
default:
{
Q_ASSERT(false);
break;
}
}
fill = false;
}
}
if (stroke)
{
if (const PDFPatternColorSpace* patternColorSpace = getGraphicState()->getFillColorSpace()->asPatternColorSpace())
{
const PDFPattern* pattern = patternColorSpace->getPattern();
switch (pattern->getType())
{
case PatternType::Tiling:
{
if (!isContentKindSuppressed(ContentKind::Tiling))
{
// Tiling is enabled
const PDFTilingPattern* tilingPattern = pattern->getTilingPattern();
// We must stroke the path.
QPainterPathStroker stroker;
stroker.setCapStyle(m_graphicState.getLineCapStyle());
stroker.setWidth(m_graphicState.getLineWidth());
stroker.setMiterLimit(m_graphicState.getMitterLimit());
stroker.setJoinStyle(m_graphicState.getLineJoinStyle());
const PDFLineDashPattern& lineDashPattern = m_graphicState.getLineDashPattern();
if (!lineDashPattern.isSolid())
{
stroker.setDashPattern(QVector<PDFReal>::fromStdVector(lineDashPattern.getDashArray()));
stroker.setDashOffset(lineDashPattern.getDashOffset());
}
QPainterPath strokedPath = stroker.createStroke(path);
processTillingPatternPainting(tilingPattern, strokedPath, patternColorSpace->getUncoloredPatternColorSpace(), patternColorSpace->getUncoloredPatternColor());
}
break;
}
case PatternType::Shading:
{
if (!isContentKindSuppressed(ContentKind::Shading))
{
// Shading is enabled
PDFPageContentProcessorGraphicStateSaveRestoreGuard guard(this);
const PDFShadingPattern* shadingPattern = pattern->getShadingPattern();
// Apply pattern graphic state
const PDFObject& patternGraphicState = m_document->getObject(shadingPattern->getPatternGraphicState());
if (!patternGraphicState.isNull())
{
if (patternGraphicState.isDictionary())
{
processApplyGraphicState(patternGraphicState.getDictionary());
}
else
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Shading pattern graphic state is invalid."));
}
}
// We must create a mesh and then draw pattern
PDFMeshQualitySettings settings = m_meshQualitySettings;
settings.deviceSpaceMeshingArea = getPageBoundingRectDeviceSpace();
settings.userSpaceToDeviceSpaceMatrix = getPatternBaseMatrix();
settings.initResolution();
// We must stroke the path.
QPainterPathStroker stroker;
stroker.setCapStyle(m_graphicState.getLineCapStyle());
stroker.setWidth(m_graphicState.getLineWidth());
stroker.setMiterLimit(m_graphicState.getMitterLimit());
stroker.setJoinStyle(m_graphicState.getLineJoinStyle());
const PDFLineDashPattern& lineDashPattern = m_graphicState.getLineDashPattern();
if (!lineDashPattern.isSolid())
{
stroker.setDashPattern(QVector<PDFReal>::fromStdVector(lineDashPattern.getDashArray()));
stroker.setDashOffset(lineDashPattern.getDashOffset());
}
QPainterPath strokedPath = stroker.createStroke(path);
if (!performPathPaintingUsingShading(strokedPath, true, false, shadingPattern))
{
PDFMesh mesh = shadingPattern->createMesh(settings, m_CMS, m_graphicState.getRenderingIntent(), this);
QPainterPath boundingPath = mesh.getBoundingPath();
if (boundingPath.isEmpty())
{
boundingPath = getCurrentWorldMatrix().map(strokedPath);
}
else
{
boundingPath = boundingPath.intersected(strokedPath);
}
mesh.setBoundingPath(boundingPath);
performMeshPainting(mesh);
}
}
break;
}
case PatternType::Invalid:
{
throw PDFException(PDFTranslationContext::tr("Invalid pattern."));
break;
}
default:
{
Q_ASSERT(false);
break;
}
}
stroke = false;
}
}
if (stroke || fill)
{
performPathPainting(path, stroke, fill, text, fillRule);
}
performFinishPathPainting();
}
void PDFPageContentProcessor::processTillingPatternPainting(const PDFTilingPattern* tilingPattern,
const QPainterPath& path,
PDFColorSpacePointer uncoloredPatternColorSpace,
PDFColor uncoloredPatternColor)
{
PDFPageContentProcessorStateGuard guard(this);
performClipping(path, path.fillRule());
// Initialize resources
const PDFObject& resources = tilingPattern->getResources();
if (!resources.isNull())
{
initDictionaries(resources);
}
Q_ASSERT(m_pagePointToDevicePointMatrix.isInvertible());
// Initialize rendering matrix
QMatrix patternMatrix = tilingPattern->getMatrix() * getPatternBaseMatrix();
QMatrix matrix = patternMatrix * m_pagePointToDevicePointMatrix.inverted();
QMatrix pathTransformationMatrix = m_graphicState.getCurrentTransformationMatrix() * matrix.inverted();
m_graphicState.setCurrentTransformationMatrix(matrix);
int uncoloredTilingPatternFlag = 0;
// Initialize colors for uncolored color space pattern
if (tilingPattern->getPaintingType() == PDFTilingPattern::PaintType::Uncolored)
{
if (!uncoloredPatternColorSpace)
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Uncolored tiling pattern has not underlying color space."));
}
uncoloredTilingPatternFlag = 1;
m_graphicState.setStrokeColorSpace(uncoloredPatternColorSpace);
m_graphicState.setFillColorSpace(uncoloredPatternColorSpace);
QColor color = uncoloredPatternColorSpace->getCheckedColor(uncoloredPatternColor, m_CMS, m_graphicState.getRenderingIntent(), this);
m_graphicState.setStrokeColor(color, uncoloredPatternColor);
m_graphicState.setFillColor(color, uncoloredPatternColor);
}
else
{
// Jakub Melka: According the specification, we set default color space and default color
m_graphicState.setStrokeColorSpace(m_deviceGrayColorSpace);
m_graphicState.setFillColorSpace(m_deviceGrayColorSpace);
QColor color = m_deviceGrayColorSpace->getDefaultColor(m_CMS, m_graphicState.getRenderingIntent(), this);
m_graphicState.setStrokeColor(color, m_deviceGrayColorSpace->getDefaultColorOriginal());
m_graphicState.setFillColor(color, m_deviceGrayColorSpace->getDefaultColorOriginal());
}
updateGraphicState();
// Mark uncolored flag, if we drawing uncolored color pattern
PDFTemporaryValueChange guard2(&m_drawingUncoloredTilingPatternState, m_drawingUncoloredTilingPatternState + uncoloredTilingPatternFlag);
// Tiling parameters
const QRectF tilingArea = pathTransformationMatrix.map(path).boundingRect();
const QRectF boundingBox = tilingPattern->getBoundingBox();
const PDFReal xStep = qAbs(tilingPattern->getXStep());
const PDFReal yStep = qAbs(tilingPattern->getYStep());
const QByteArray& content = tilingPattern->getContent();
QPainterPath boundingPath;
boundingPath.addRect(boundingBox);
// Draw the tiling
const PDFInteger columns = qMax<PDFInteger>(qCeil(tilingArea.width() / xStep), 1);
const PDFInteger rows = qMax<PDFInteger>(qCeil(tilingArea.height() / yStep), 1);
QMatrix baseTransformationMatrix = m_graphicState.getCurrentTransformationMatrix();
for (PDFInteger column = 0; column < columns; ++column)
{
for (PDFInteger row = 0; row < rows; ++row)
{
PDFPageContentProcessorGraphicStateSaveRestoreGuard guard(this);
QMatrix transformationMatrix = baseTransformationMatrix;
transformationMatrix.translate(tilingArea.left(), tilingArea.top());
transformationMatrix.translate(column * xStep, row * yStep);
QMatrix patternMatrix = transformationMatrix * m_pagePointToDevicePointMatrix;
PDFTemporaryValueChange patternMatrixGuard(&m_patternBaseMatrix, patternMatrix);
m_graphicState.setCurrentTransformationMatrix(transformationMatrix);
updateGraphicState();
performClipping(boundingPath, boundingPath.fillRule());
processContent(content);
}
}
}
void PDFPageContentProcessor::processCommand(const QByteArray& command)
{
Operator op = Operator::Invalid;
// Find the command in the command array
for (const std::pair<const char*, PDFPageContentProcessor::Operator>& operatorDescriptor : operators)
{
if (command == operatorDescriptor.first)
{
op = operatorDescriptor.second;
break;
}
}
switch (op)
{
case Operator::SetLineWidth:
{
invokeOperator(&PDFPageContentProcessor::operatorSetLineWidth);
break;
}
case Operator::SetLineCap:
{
invokeOperator(&PDFPageContentProcessor::operatorSetLineCap);
break;
}
case Operator::SetLineJoin:
{
invokeOperator(&PDFPageContentProcessor::operatorSetLineJoin);
break;
}
case Operator::SetMitterLimit:
{
invokeOperator(&PDFPageContentProcessor::operatorSetMitterLimit);
break;
}
case Operator::SetLineDashPattern:
{
invokeOperator(&PDFPageContentProcessor::operatorSetLineDashPattern);
break;
}
case Operator::SetRenderingIntent:
{
invokeOperator(&PDFPageContentProcessor::operatorSetRenderingIntent);
break;
}
case Operator::SetFlatness:
{
invokeOperator(&PDFPageContentProcessor::operatorSetFlatness);
break;
}
case Operator::SetGraphicState:
{
invokeOperator(&PDFPageContentProcessor::operatorSetGraphicState);
break;
}
case Operator::SaveGraphicState:
{
operatorSaveGraphicState();
break;
}
case Operator::RestoreGraphicState:
{
operatorRestoreGraphicState();
break;
}
case Operator::AdjustCurrentTransformationMatrix:
{
invokeOperator(&PDFPageContentProcessor::operatorAdjustCurrentTransformationMatrix);
break;
}
case Operator::MoveCurrentPoint:
{
invokeOperator(&PDFPageContentProcessor::operatorMoveCurrentPoint);
break;
}
case Operator::LineTo:
{
invokeOperator(&PDFPageContentProcessor::operatorLineTo);
break;
}
case Operator::Bezier123To:
{
invokeOperator(&PDFPageContentProcessor::operatorBezier123To);
break;
}
case Operator::Bezier23To:
{
invokeOperator(&PDFPageContentProcessor::operatorBezier23To);
break;
}
case Operator::Bezier13To:
{
invokeOperator(&PDFPageContentProcessor::operatorBezier13To);
break;
}
case Operator::EndSubpath:
{
// Call directly, no parameters involved
operatorEndSubpath();
break;
}
case Operator::Rectangle:
{
invokeOperator(&PDFPageContentProcessor::operatorRectangle);
break;
}
case Operator::PathStroke:
{
operatorPathStroke();
break;
}
case Operator::PathCloseStroke:
{
operatorPathCloseStroke();
break;
}
case Operator::PathFillWinding:
case Operator::PathFillWinding2:
{
operatorPathFillWinding();
break;
}
case Operator::PathFillEvenOdd:
{
operatorPathFillEvenOdd();
break;
}
case Operator::PathFillStrokeWinding:
{
operatorPathFillStrokeWinding();
break;
}
case Operator::PathFillStrokeEvenOdd:
{
operatorPathFillStrokeEvenOdd();
break;
}
case Operator::PathCloseFillStrokeWinding:
{
operatorPathCloseFillStrokeWinding();
break;
}
case Operator::PathCloseFillStrokeEvenOdd:
{
operatorPathCloseFillStrokeEvenOdd();
break;
}
case Operator::PathClear:
{
operatorPathClear();
break;
}
case Operator::ClipEvenOdd:
{
operatorClipEvenOdd();
break;
}
case Operator::ClipWinding:
{
operatorClipWinding();
break;
}
case Operator::Type3FontSetOffset:
{
// d0, set width information, see PDF 1.7 Reference, Table 5.10
invokeOperator(&PDFPageContentProcessor::operatorType3FontSetOffset);
break;
}
case Operator::Type3FontSetOffsetAndBB:
{
// d1, set offset and glyph bounding box
invokeOperator(&PDFPageContentProcessor::operatorType3FontSetOffsetAndBB);
break;
}
case Operator::ColorSetStrokingColorSpace:
{
// CS, set current color space for stroking operations
invokeOperator(&PDFPageContentProcessor::operatorColorSetStrokingColorSpace);
break;
}
case Operator::ColorSetFillingColorSpace:
{
// cs, set current color space for filling operations
invokeOperator(&PDFPageContentProcessor::operatorColorSetFillingColorSpace);
break;
}
case Operator::ColorSetStrokingColor:
{
// SC, set current stroking color
operatorColorSetStrokingColor();
break;
}
case Operator::ColorSetStrokingColorN:
{
// SCN, same as SC, but also supports Pattern, Separation, DeviceN and ICCBased color spaces
operatorColorSetStrokingColorN();
break;
}
case Operator::ColorSetFillingColor:
{
// sc, set current filling color
operatorColorSetFillingColor();
break;
}
case Operator::ColorSetFillingColorN:
{
// scn, same as sc, but also supports Pattern, Separation, DeviceN and ICCBased color spaces
operatorColorSetFillingColorN();
break;
}
case Operator::ColorSetDeviceGrayStroking:
{
// G, set DeviceGray color space for stroking color and set color
invokeOperator(&PDFPageContentProcessor::operatorColorSetDeviceGrayStroking);
break;
}
case Operator::ColorSetDeviceGrayFilling:
{
// g, set DeviceGray color space for filling color and set color
invokeOperator(&PDFPageContentProcessor::operatorColorSetDeviceGrayFilling);
break;
}
case Operator::ColorSetDeviceRGBStroking:
{
// RG, set DeviceRGB color space for stroking color and set color
invokeOperator(&PDFPageContentProcessor::operatorColorSetDeviceRGBStroking);
break;
}
case Operator::ColorSetDeviceRGBFilling:
{
// rg, set DeviceRGB color space for filling color and set color
invokeOperator(&PDFPageContentProcessor::operatorColorSetDeviceRGBFilling);
break;
}
case Operator::ColorSetDeviceCMYKStroking:
{
// K, set DeviceCMYK color space for stroking color and set color
invokeOperator(&PDFPageContentProcessor::operatorColorSetDeviceCMYKStroking);
break;
}
case Operator::ColorSetDeviceCMYKFilling:
{
// k, set DeviceCMYK color space for filling color and set color
invokeOperator(&PDFPageContentProcessor::operatorColorSetDeviceCMYKFilling);
break;
}
case Operator::TextBegin:
{
// BT, begin text object, initialize text matrices, cannot be nested
operatorTextBegin();
break;
}
case Operator::TextEnd:
{
// ET, end text object, cannot be nested
operatorTextEnd();
break;
}
case Operator::TextSetCharacterSpacing:
{
// Tc, set text character spacing
invokeOperator(&PDFPageContentProcessor::operatorTextSetCharacterSpacing);
break;
}
case Operator::TextSetWordSpacing:
{
// Tw, set text word spacing
invokeOperator(&PDFPageContentProcessor::operatorTextSetWordSpacing);
break;
}
case Operator::TextSetHorizontalScale:
{
// Tz, set text horizontal scaling (in percents, 100% = normal scaling)
invokeOperator(&PDFPageContentProcessor::operatorTextSetHorizontalScale);
break;
}
case Operator::TextSetLeading:
{
// TL, set text leading
invokeOperator(&PDFPageContentProcessor::operatorTextSetLeading);
break;
}
case Operator::TextSetFontAndFontSize:
{
// Tf, set text font (name from dictionary) and its size
invokeOperator(&PDFPageContentProcessor::operatorTextSetFontAndFontSize);
break;
}
case Operator::TextSetRenderMode:
{
// Tr, set text render mode
invokeOperator(&PDFPageContentProcessor::operatorTextSetRenderMode);
break;
}
case Operator::TextSetRise:
{
// Ts, set text rise
invokeOperator(&PDFPageContentProcessor::operatorTextSetRise);
break;
}
case Operator::TextMoveByOffset:
{
// Td, move by offset
invokeOperator(&PDFPageContentProcessor::operatorTextMoveByOffset);
break;
}
case Operator::TextSetLeadingAndMoveByOffset:
{
// TD, sets text leading and moves by offset, x y TD is equivalent to sequence -y TL x y Td
invokeOperator(&PDFPageContentProcessor::operatorTextSetLeadingAndMoveByOffset);
break;
}
case Operator::TextSetMatrix:
{
// Tm, set text matrix
invokeOperator(&PDFPageContentProcessor::operatorTextSetMatrix);
break;
}
case Operator::TextMoveByLeading:
{
// T*, moves text by leading, equivalent to 0 leading Td
operatorTextMoveByLeading();
break;
}
case Operator::TextShowTextString:
{
// Tj, show text string
invokeOperator(&PDFPageContentProcessor::operatorTextShowTextString);
break;
}
case Operator::TextShowTextIndividualSpacing:
{
// TJ, show text, allow individual text spacing
invokeOperator(&PDFPageContentProcessor::operatorTextShowTextIndividualSpacing);
break;
}
case Operator::TextNextLineShowText:
{
// ', move to the next line and show text ("string '" is equivalent to "T* string Tj")
invokeOperator(&PDFPageContentProcessor::operatorTextNextLineShowText);
break;
}
case Operator::TextSetSpacingAndShowText:
{
// ", move to the next line, set spacing and show text (equivalent to sequence "w1 Tw w2 Tc string '")
invokeOperator(&PDFPageContentProcessor::operatorTextSetSpacingAndShowText);
break;
}
case Operator::PaintXObject:
{
// Do, paint the X Object (image, form, ...)
invokeOperator(&PDFPageContentProcessor::operatorPaintXObject);
break;
}
case Operator::ShadingPaintShape:
{
// sh, paint shape
invokeOperator(&PDFPageContentProcessor::operatorShadingPaintShape);
break;
}
case Operator::MarkedContentPoint:
{
// MP, marked content point
invokeOperator(&PDFPageContentProcessor::operatorMarkedContentPoint);
break;
}
case Operator::MarkedContentPointWithProperties:
{
// DP, marked content point with properties
operatorMarkedContentPointWithProperties(readOperand<PDFOperandName>(0), readObjectFromOperandStack(1));
break;
}
case Operator::MarkedContentBegin:
{
// BMC, begin of sequence of marked content
invokeOperator(&PDFPageContentProcessor::operatorMarkedContentBegin);
break;
}
case Operator::MarkedContentBeginWithProperties:
{
// BDC, begin of sequence of marked content with properties
operatorMarkedContentBeginWithProperties(readOperand<PDFOperandName>(0), readObjectFromOperandStack(1));
break;
}
case Operator::MarkedContentEnd:
{
// EMC, end of marked content sequence
operatorMarkedContentEnd();
break;
}
case Operator::CompatibilityBegin:
{
operatorCompatibilityBegin();
break;
}
case Operator::CompatibilityEnd:
{
operatorCompatibilityEnd();
break;
}
case Operator::Invalid:
{
m_errorList.append(PDFRenderError(RenderErrorType::Error, PDFTranslationContext::tr("Unknown operator '%1'.").arg(QString::fromLatin1(command))));
break;
}
default:
{
m_errorList.append(PDFRenderError(RenderErrorType::NotImplemented, PDFTranslationContext::tr("Not implemented operator '%1'.").arg(QString::fromLatin1(command))));
break;
}
}
}
QPointF PDFPageContentProcessor::getCurrentPoint() const
{
const int elementCount = m_currentPath.elementCount();
if (elementCount > 0)
{
QPainterPath::Element element = m_currentPath.elementAt(elementCount - 1);
return QPointF(element.x, element.y);
}
else
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Current point of path is not set. Path is empty."));
}
return QPointF();
}
void PDFPageContentProcessor::updateGraphicState()
{
if (m_graphicState.getStateFlags())
{
performUpdateGraphicsState(m_graphicState);
m_graphicState.setStateFlags(PDFPageContentProcessorState::StateUnchanged);
}
}
void PDFPageContentProcessor::operatorSetLineWidth(PDFReal lineWidth)
{
lineWidth = qMax(0.0, lineWidth);
m_graphicState.setLineWidth(lineWidth);
updateGraphicState();
}
Qt::PenCapStyle PDFPageContentProcessor::convertLineCapToPenCapStyle(PDFInteger lineCap)
{
lineCap = qBound<PDFInteger>(0, lineCap, 2);
Qt::PenCapStyle penCapStyle = Qt::FlatCap;
switch (lineCap)
{
case 0:
{
penCapStyle = Qt::FlatCap;
break;
}
case 1:
{
penCapStyle = Qt::RoundCap;
break;
}
case 2:
{
penCapStyle = Qt::SquareCap;
break;
}
default:
{
// This case can't occur, because we are correcting invalid values above.
Q_ASSERT(false);
break;
}
}
return penCapStyle;
}
PDFInteger PDFPageContentProcessor::convertPenCapStyleToLineCap(Qt::PenCapStyle penCapStyle)
{
switch (penCapStyle)
{
case Qt::FlatCap:
return 0;
case Qt::SquareCap:
return 2;
case Qt::RoundCap:
return 1;
default:
break;
}
// Invalid pen cap style occured
Q_ASSERT(false);
return 0;
}
void PDFPageContentProcessor::operatorSetLineCap(PDFInteger lineCap)
{
const Qt::PenCapStyle penCapStyle = convertLineCapToPenCapStyle(lineCap);
m_graphicState.setLineCapStyle(penCapStyle);
updateGraphicState();
}
Qt::PenJoinStyle PDFPageContentProcessor::convertLineJoinToPenJoinStyle(PDFInteger lineJoin)
{
lineJoin = qBound<PDFInteger>(0, lineJoin, 2);
Qt::PenJoinStyle penJoinStyle = Qt::MiterJoin;
switch (lineJoin)
{
case 0:
{
penJoinStyle = Qt::MiterJoin;
break;
}
case 1:
{
penJoinStyle = Qt::RoundJoin;
break;
}
case 2:
{
penJoinStyle = Qt::BevelJoin;
break;
}
default:
{
// This case can't occur, because we are correcting invalid values above.
Q_ASSERT(false);
break;
}
}
return penJoinStyle;
}
PDFInteger PDFPageContentProcessor::convertPenJoinStyleToLineJoin(Qt::PenJoinStyle penJoinStyle)
{
switch (penJoinStyle)
{
case Qt::MiterJoin:
return 0;
case Qt::BevelJoin:
return 2;
case Qt::RoundJoin:
return 1;
default:
break;
}
// Invalid pen join style occured
Q_ASSERT(false);
return 0;
}
void PDFPageContentProcessor::operatorSetLineJoin(PDFInteger lineJoin)
{
const Qt::PenJoinStyle penJoinStyle = convertLineJoinToPenJoinStyle(lineJoin);
m_graphicState.setLineJoinStyle(penJoinStyle);
updateGraphicState();
}
void PDFPageContentProcessor::operatorSetMitterLimit(PDFReal mitterLimit)
{
mitterLimit = qMax(0.0, mitterLimit);
m_graphicState.setMitterLimit(mitterLimit);
updateGraphicState();
}
void PDFPageContentProcessor::operatorSetLineDashPattern()
{
// Operand stack must be of this form [ ... numbers ... ] offset. We check it.
// Minimal number of operands is [] 0.
if (m_operands.size() < 3)
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Invalid line dash pattern."));
}
// Now, we have at least 3 arguments. Check we have an array
if (m_operands[0].type != PDFLexicalAnalyzer::TokenType::ArrayStart ||
m_operands[m_operands.size() - 2].type != PDFLexicalAnalyzer::TokenType::ArrayEnd)
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Invalid line dash pattern."));
}
const size_t dashArrayStartIndex = 1;
const size_t dashArrayEndIndex = m_operands.size() - 2;
const size_t dashOffsetIndex = m_operands.size() - 1;
std::vector<PDFReal> dashArray;
dashArray.reserve(dashArrayEndIndex - dashArrayStartIndex);
for (size_t i = dashArrayStartIndex; i < dashArrayEndIndex; ++i)
{
dashArray.push_back(readOperand<PDFReal>(i));
}
const PDFReal dashOffset = readOperand<PDFReal>(dashOffsetIndex);
PDFLineDashPattern pattern(std::move(dashArray), dashOffset);
m_graphicState.setLineDashPattern(std::move(pattern));
updateGraphicState();
}
void PDFPageContentProcessor::operatorSetRenderingIntent(PDFOperandName intent)
{
setRenderingIntentByName(intent.name);
updateGraphicState();
}
void PDFPageContentProcessor::operatorSetFlatness(PDFReal flatness)
{
flatness = qBound(0.0, flatness, 100.0);
m_graphicState.setFlatness(flatness);
updateGraphicState();
}
void PDFPageContentProcessor::setRenderingIntentByName(QByteArray renderingIntentName)
{
RenderingIntent renderingIntent = RenderingIntent::Unknown;
if (renderingIntentName == "Perceptual")
{
renderingIntent = RenderingIntent::Perceptual;
}
else if (renderingIntentName == "AbsoluteColorimetric")
{
renderingIntent = RenderingIntent::AbsoluteColorimetric;
}
else if (renderingIntentName == "RelativeColorimetric")
{
renderingIntent = RenderingIntent::RelativeColorimetric;
}
else if (renderingIntentName == "Saturation")
{
renderingIntent = RenderingIntent::Saturation;
}
m_graphicState.setRenderingIntent(renderingIntent);
m_graphicState.setRenderingIntentName(renderingIntentName);
}
void PDFPageContentProcessor::finishMarkedContent()
{
if (!m_markedContentStack.empty())
{
m_errorList.append(PDFRenderError(RenderErrorType::Error, PDFTranslationContext::tr("Marked content is not well formed (not enough EMC operators).")));
}
while (!m_markedContentStack.empty())
{
operatorMarkedContentEnd();
}
}
void PDFPageContentProcessor::reportRenderErrorOnce(RenderErrorType type, QString message)
{
if (!m_onceReportedErrors.count(message))
{
m_onceReportedErrors.insert(message);
reportRenderError(type, message);
}
}
void PDFPageContentProcessor::processApplyGraphicState(const PDFDictionary* graphicStateDictionary)
{
PDFDocumentDataLoaderDecorator loader(m_document);
const PDFReal lineWidth = loader.readNumberFromDictionary(graphicStateDictionary, "LW", m_graphicState.getLineWidth());
const Qt::PenCapStyle penCapStyle = convertLineCapToPenCapStyle(loader.readNumberFromDictionary(graphicStateDictionary, "LC", convertPenCapStyleToLineCap(m_graphicState.getLineCapStyle())));
const Qt::PenJoinStyle penJoinStyle = convertLineJoinToPenJoinStyle(loader.readNumberFromDictionary(graphicStateDictionary, "LJ", convertPenJoinStyleToLineJoin(m_graphicState.getLineJoinStyle())));
const PDFReal mitterLimit = loader.readNumberFromDictionary(graphicStateDictionary, "ML", m_graphicState.getMitterLimit());
const PDFObject& lineDashPatternObject = m_document->getObject(graphicStateDictionary->get("D"));
if (lineDashPatternObject.isArray())
{
const PDFArray* lineDashPatternDefinitionArray = lineDashPatternObject.getArray();
if (lineDashPatternDefinitionArray->getCount() == 2)
{
PDFLineDashPattern pattern(loader.readNumberArray(lineDashPatternDefinitionArray->getItem(0)), loader.readNumber(lineDashPatternDefinitionArray->getItem(1), 0.0));
pattern.fix();
m_graphicState.setLineDashPattern(pattern);
}
}
const PDFReal flatness = loader.readNumberFromDictionary(graphicStateDictionary, "FL", m_graphicState.getFlatness());
const PDFReal smoothness = loader.readNumberFromDictionary(graphicStateDictionary, "SM", m_graphicState.getSmoothness());
const bool textKnockout = loader.readBooleanFromDictionary(graphicStateDictionary, "TK", m_graphicState.getTextKnockout());
const PDFReal strokingAlpha = loader.readNumberFromDictionary(graphicStateDictionary, "CA", m_graphicState.getAlphaStroking());
const PDFReal fillingAlpha = loader.readNumberFromDictionary(graphicStateDictionary, "ca", m_graphicState.getAlphaFilling());
QByteArray blendModeName = loader.readNameFromDictionary(graphicStateDictionary, "BM");
QByteArray renderingIntentName = loader.readNameFromDictionary(graphicStateDictionary, "RI");
const bool alphaIsShape = loader.readBooleanFromDictionary(graphicStateDictionary, "AIS", m_graphicState.getAlphaIsShape());
const bool strokeAdjustment = loader.readBooleanFromDictionary(graphicStateDictionary, "SA", m_graphicState.getStrokeAdjustment());
const PDFDictionary* softMask = graphicStateDictionary->hasKey("SMask") ? m_document->getDictionaryFromObject(graphicStateDictionary->get("SMask")) : m_graphicState.getSoftMask();
// We will try to get blend mode name from the array (if BM is array). First supported blend mode should
// be used. In PDF 2.0, array is deprecated, so for backward compatibility, we extract first blend mode
// name from the array and try to use it.
if (blendModeName.isEmpty())
{
std::vector<QByteArray> blendModeNames = loader.readNameArrayFromDictionary(graphicStateDictionary, "BM");
if (!blendModeNames.empty())
{
blendModeName = qMove(blendModeNames.front());
}
}
if (!blendModeName.isEmpty())
{
BlendMode blendMode = PDFBlendModeInfo::getBlendMode(blendModeName);
if (blendMode == BlendMode::Invalid)
{
blendMode = BlendMode::Normal;
m_errorList.append(PDFRenderError(RenderErrorType::NotImplemented, PDFTranslationContext::tr("Blend mode '%1' is invalid.").arg(QString::fromLatin1(blendModeName))));
}
m_graphicState.setBlendMode(blendMode);
}
if (!renderingIntentName.isEmpty())
{
setRenderingIntentByName(renderingIntentName);
}
PDFOverprintMode overprintMode = m_graphicState.getOverprintMode();
overprintMode.overprintMode = loader.readIntegerFromDictionary(graphicStateDictionary, "OPM", overprintMode.overprintMode);
// Overprint for filling is ruled by overprint for stroking, if "op" is not present, according to the specification
overprintMode.overprintStroking = loader.readBooleanFromDictionary(graphicStateDictionary, "OP", overprintMode.overprintStroking);
overprintMode.overprintFilling = loader.readBooleanFromDictionary(graphicStateDictionary, "op", overprintMode.overprintStroking);
constexpr std::array blackPointCompensationModes = {
std::pair<const char*, BlackPointCompensationMode>{ "Default", BlackPointCompensationMode::Default },
std::pair<const char*, BlackPointCompensationMode>{ "ON", BlackPointCompensationMode::ON },
std::pair<const char*, BlackPointCompensationMode>{ "OFF", BlackPointCompensationMode::OFF },
};
BlackPointCompensationMode blackPointCompensationMode = m_graphicState.getBlackPointCompensationMode();
if (graphicStateDictionary->hasKey("UseBlackPtComp"))
{
blackPointCompensationMode = loader.readEnumByName(graphicStateDictionary->get("UseBlackPtComp"), blackPointCompensationModes.cbegin(), blackPointCompensationModes.cend(), BlackPointCompensationMode::Default);
}
PDFObject blackGenerationFunctionObject = m_graphicState.getBlackGenerationFunction();
if (graphicStateDictionary->hasKey("BG") || graphicStateDictionary->hasKey("BG2"))
{
blackGenerationFunctionObject = m_document->getObject(graphicStateDictionary->get("BG2"));
if (blackGenerationFunctionObject.isNull())
{
blackGenerationFunctionObject = m_document->getObject(graphicStateDictionary->get("BG"));
}
}
PDFObject undercolorRemovalFunctionObject = m_graphicState.getUndercolorRemovalFunction();
if (graphicStateDictionary->hasKey("UCR") || graphicStateDictionary->hasKey("UCR2"))
{
undercolorRemovalFunctionObject = m_document->getObject(graphicStateDictionary->get("UCR2"));
if (undercolorRemovalFunctionObject.isNull())
{
undercolorRemovalFunctionObject = m_document->getObject(graphicStateDictionary->get("UCR"));
}
}
PDFObject transferFunctionObject = m_graphicState.getTransferFunction();
if (graphicStateDictionary->hasKey("TR") || graphicStateDictionary->hasKey("TR2"))
{
transferFunctionObject = m_document->getObject(graphicStateDictionary->get("TR2"));
if (transferFunctionObject.isNull())
{
transferFunctionObject = m_document->getObject(graphicStateDictionary->get("TR"));
}
}
PDFObject halftoneObject = graphicStateDictionary->hasKey("HT") ? m_document->getObject(graphicStateDictionary->get("HT")) : m_graphicState.getHalftone();
QPointF halftoneOrigin = m_graphicState.getHalftoneOrigin();
if (graphicStateDictionary->hasKey("HTO"))
{
std::vector<PDFReal> halftoneOriginArray = loader.readNumberArrayFromDictionary(graphicStateDictionary, "HTO");
if (halftoneOriginArray.size() >= 2)
{
halftoneOrigin = QPointF(halftoneOriginArray[0], halftoneOriginArray[1]);
}
}
m_graphicState.setLineWidth(lineWidth);
m_graphicState.setLineCapStyle(penCapStyle);
m_graphicState.setLineJoinStyle(penJoinStyle);
m_graphicState.setMitterLimit(mitterLimit);
m_graphicState.setFlatness(flatness);
m_graphicState.setSmoothness(smoothness);
m_graphicState.setTextKnockout(textKnockout);
m_graphicState.setAlphaStroking(strokingAlpha);
m_graphicState.setAlphaFilling(fillingAlpha);
m_graphicState.setOverprintMode(overprintMode);
m_graphicState.setAlphaIsShape(alphaIsShape);
m_graphicState.setStrokeAdjustment(strokeAdjustment);
m_graphicState.setSoftMask(softMask);
m_graphicState.setBlackPointCompensationMode(blackPointCompensationMode);
m_graphicState.setBlackGenerationFunction(qMove(blackGenerationFunctionObject));
m_graphicState.setUndercolorRemovalFunction(qMove(undercolorRemovalFunctionObject));
m_graphicState.setTransferFunction(qMove(transferFunctionObject));
m_graphicState.setHalftone(qMove(halftoneObject));
m_graphicState.setHalftoneOrigin(halftoneOrigin);
updateGraphicState();
if (graphicStateDictionary->hasKey("Font"))
{
const PDFObject& fontObject = m_document->getObject(graphicStateDictionary->get("Font"));
if (fontObject.isArray())
{
const PDFArray* fontObjectArray = fontObject.getArray();
if (fontObjectArray->getCount() == 2)
{
PDFOperandName operandName;
operandName.name = loader.readName(fontObjectArray->getItem(0));
operatorTextSetFontAndFontSize(operandName, loader.readNumber(fontObjectArray->getItem(1), 1.0));
}
}
}
}
void PDFPageContentProcessor::operatorSetGraphicState(PDFOperandName dictionaryName)
{
if (m_extendedGraphicStateDictionary)
{
if (m_extendedGraphicStateDictionary->hasKey(dictionaryName.name))
{
const PDFObject& graphicStateObject = m_document->getObject(m_extendedGraphicStateDictionary->get(dictionaryName.name));
if (graphicStateObject.isDictionary())
{
const PDFDictionary* graphicStateDictionary = graphicStateObject.getDictionary();
processApplyGraphicState(graphicStateDictionary);
}
else
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Graphic state '%1' found, but invalid in resource dictionary.").arg(QString::fromLatin1(dictionaryName.name)));
}
}
else
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Graphic state '%1' not found in resource dictionary.").arg(QString::fromLatin1(dictionaryName.name)));
}
}
else
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Invalid graphic state resource dictionary."));
}
}
void PDFPageContentProcessor::operatorSaveGraphicState()
{
performSaveGraphicState(ProcessOrder::BeforeOperation);
m_stack.push(m_graphicState);
m_stack.top().setStateFlags(PDFPageContentProcessorState::StateUnchanged);
performSaveGraphicState(ProcessOrder::AfterOperation);
}
void PDFPageContentProcessor::operatorRestoreGraphicState()
{
if (m_stack.empty())
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Trying to restore graphic state more times than it was saved."));
}
performRestoreGraphicState(ProcessOrder::BeforeOperation);
m_graphicState = m_stack.top();
m_stack.pop();
updateGraphicState();
performRestoreGraphicState(ProcessOrder::AfterOperation);
}
void PDFPageContentProcessor::operatorAdjustCurrentTransformationMatrix(PDFReal a, PDFReal b, PDFReal c, PDFReal d, PDFReal e, PDFReal f)
{
// We will comment following equation:
// Adobe PDF Reference 1.7 says, that we have this transformation using coefficient a, b, c, d, e and f:
// [ a, b, 0 ]
// [x', y', 1] = [ x, y, 1] * [ c, d, 0 ]
// [ e, f, 1 ]
// If we transpose this equation (we want this, because Qt uses transposed matrices (QMatrix).
// So, we will get following result:
//
// [ x' ] [ a, c, e] [ x ]
// [ y' ] = [ b, d, f] * [ y ]
// [ 1 ] [ 0, 0, 1] [ 1 ]
//
// So, it is obvious, than we will have following coefficients:
// m_11 = a, m_21 = c, dx = e
// m_12 = b, m_22 = d, dy = f
//
// We must also check, that matrix is invertible. If it is not, then we will throw exception
// to avoid errors later (for some operations, we assume matrix is invertible).
QMatrix matrix(a, b, c, d, e, f);
QMatrix transformMatrix = matrix * m_graphicState.getCurrentTransformationMatrix();
if (!transformMatrix.isInvertible())
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Transformation matrix is not invertible."));
}
m_graphicState.setCurrentTransformationMatrix(transformMatrix);
updateGraphicState();
}
template<>
PDFReal PDFPageContentProcessor::readOperand<PDFReal>(size_t index) const
{
if (index < m_operands.size())
{
const PDFLexicalAnalyzer::Token& token = m_operands[index];
switch (token.type)
{
case PDFLexicalAnalyzer::TokenType::Real:
case PDFLexicalAnalyzer::TokenType::Integer:
return token.data.value<PDFReal>();
default:
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Can't read operand (real number) on index %1. Operand is of type '%2'.").arg(index + 1).arg(PDFLexicalAnalyzer::getStringFromOperandType(token.type)));
}
}
else
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Can't read operand (real number) on index %1. Only %2 operands provided.").arg(index + 1).arg(m_operands.size()));
}
return 0.0;
}
template<>
PDFInteger PDFPageContentProcessor::readOperand<PDFInteger>(size_t index) const
{
if (index < m_operands.size())
{
const PDFLexicalAnalyzer::Token& token = m_operands[index];
switch (token.type)
{
case PDFLexicalAnalyzer::TokenType::Integer:
return token.data.value<PDFInteger>();
default:
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Can't read operand (integer) on index %1. Operand is of type '%2'.").arg(index + 1).arg(PDFLexicalAnalyzer::getStringFromOperandType(token.type)));
}
}
else
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Can't read operand (integer) on index %1. Only %2 operands provided.").arg(index + 1).arg(m_operands.size()));
}
return 0;
}
template<>
PDFPageContentProcessor::PDFOperandName PDFPageContentProcessor::readOperand<PDFPageContentProcessor::PDFOperandName>(size_t index) const
{
if (index < m_operands.size())
{
const PDFLexicalAnalyzer::Token& token = m_operands[index];
switch (token.type)
{
case PDFLexicalAnalyzer::TokenType::Name:
return PDFOperandName{ token.data.toByteArray() };
default:
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Can't read operand (name) on index %1. Operand is of type '%2'.").arg(index + 1).arg(PDFLexicalAnalyzer::getStringFromOperandType(token.type)));
}
}
else
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Can't read operand (name) on index %1. Only %2 operands provided.").arg(index + 1).arg(m_operands.size()));
}
return PDFOperandName();
}
template<>
PDFPageContentProcessor::PDFOperandString PDFPageContentProcessor::readOperand<PDFPageContentProcessor::PDFOperandString>(size_t index) const
{
if (index < m_operands.size())
{
const PDFLexicalAnalyzer::Token& token = m_operands[index];
switch (token.type)
{
case PDFLexicalAnalyzer::TokenType::String:
return PDFOperandString{ token.data.toByteArray() };
default:
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Can't read operand (string) on index %1. Operand is of type '%2'.").arg(index + 1).arg(PDFLexicalAnalyzer::getStringFromOperandType(token.type)));
}
}
else
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Can't read operand (string) on index %1. Only %2 operands provided.").arg(index + 1).arg(m_operands.size()));
}
return PDFOperandString();
}
void PDFPageContentProcessor::operatorMoveCurrentPoint(PDFReal x, PDFReal y)
{
m_currentPath.moveTo(x, y);;
}
void PDFPageContentProcessor::operatorLineTo(PDFReal x, PDFReal y)
{
m_currentPath.lineTo(x, y);
}
void PDFPageContentProcessor::operatorBezier123To(PDFReal x1, PDFReal y1, PDFReal x2, PDFReal y2, PDFReal x3, PDFReal y3)
{
m_currentPath.cubicTo(x1, y1, x2, y2, x3, y3);
}
void PDFPageContentProcessor::operatorBezier23To(PDFReal x2, PDFReal y2, PDFReal x3, PDFReal y3)
{
QPointF currentPoint = getCurrentPoint();
m_currentPath.cubicTo(currentPoint.x(), currentPoint.y(), x2, y2, x3, y3);
}
void PDFPageContentProcessor::operatorBezier13To(PDFReal x1, PDFReal y1, PDFReal x3, PDFReal y3)
{
m_currentPath.cubicTo(x1, y1, x3, y3, x3, y3);
}
void PDFPageContentProcessor::operatorEndSubpath()
{
m_currentPath.closeSubpath();
}
void PDFPageContentProcessor::operatorRectangle(PDFReal x, PDFReal y, PDFReal width, PDFReal height)
{
const PDFReal xMin = qMin(x, x + width);
const PDFReal xMax = qMax(x, x + width);
const PDFReal yMin = qMin(y, y + height);
const PDFReal yMax = qMax(y, y + height);
const PDFReal correctedWidth = xMax - xMin;
const PDFReal correctedHeight = yMax - yMin;
m_currentPath.addRect(QRectF(xMin, yMin, correctedWidth, correctedHeight));
}
void PDFPageContentProcessor::operatorPathStroke()
{
// Do not close the path
if (!m_currentPath.isEmpty())
{
m_currentPath.setFillRule(Qt::WindingFill);
processPathPainting(m_currentPath, true, false, false, Qt::WindingFill);
m_currentPath = QPainterPath();
}
}
void PDFPageContentProcessor::operatorPathCloseStroke()
{
// Close the path
if (!m_currentPath.isEmpty())
{
m_currentPath.closeSubpath();
m_currentPath.setFillRule(Qt::WindingFill);
processPathPainting(m_currentPath, true, false, false, Qt::WindingFill);
m_currentPath = QPainterPath();
}
}
void PDFPageContentProcessor::operatorPathFillWinding()
{
if (!m_currentPath.isEmpty())
{
m_currentPath.setFillRule(Qt::WindingFill);
processPathPainting(m_currentPath, false, true, false, Qt::WindingFill);
m_currentPath = QPainterPath();
}
}
void PDFPageContentProcessor::operatorPathFillEvenOdd()
{
if (!m_currentPath.isEmpty())
{
m_currentPath.setFillRule(Qt::OddEvenFill);
processPathPainting(m_currentPath, false, true, false, Qt::OddEvenFill);
m_currentPath = QPainterPath();
}
}
void PDFPageContentProcessor::operatorPathFillStrokeWinding()
{
if (!m_currentPath.isEmpty())
{
m_currentPath.setFillRule(Qt::WindingFill);
processPathPainting(m_currentPath, true, true, false, Qt::WindingFill);
m_currentPath = QPainterPath();
}
}
void PDFPageContentProcessor::operatorPathFillStrokeEvenOdd()
{
if (!m_currentPath.isEmpty())
{
m_currentPath.setFillRule(Qt::OddEvenFill);
processPathPainting(m_currentPath, true, true, false, Qt::OddEvenFill);
m_currentPath = QPainterPath();
}
}
void PDFPageContentProcessor::operatorPathCloseFillStrokeWinding()
{
if (!m_currentPath.isEmpty())
{
m_currentPath.closeSubpath();
m_currentPath.setFillRule(Qt::WindingFill);
processPathPainting(m_currentPath, true, true, false, Qt::WindingFill);
m_currentPath = QPainterPath();
}
}
void PDFPageContentProcessor::operatorPathCloseFillStrokeEvenOdd()
{
if (!m_currentPath.isEmpty())
{
m_currentPath.closeSubpath();
m_currentPath.setFillRule(Qt::OddEvenFill);
processPathPainting(m_currentPath, true, true, false, Qt::OddEvenFill);
m_currentPath = QPainterPath();
}
}
void PDFPageContentProcessor::operatorPathClear()
{
m_currentPath = QPainterPath();
}
void PDFPageContentProcessor::operatorClipWinding()
{
if (!m_currentPath.isEmpty())
{
m_currentPath.setFillRule(Qt::WindingFill);
performClipping(m_currentPath, Qt::WindingFill);
}
}
void PDFPageContentProcessor::operatorClipEvenOdd()
{
if (!m_currentPath.isEmpty())
{
m_currentPath.setFillRule(Qt::OddEvenFill);
performClipping(m_currentPath, Qt::OddEvenFill);
}
}
void PDFPageContentProcessor::operatorType3FontSetOffset(PDFReal wx, PDFReal wy)
{
performSetCharWidth(wx, wy);
}
void PDFPageContentProcessor::operatorType3FontSetOffsetAndBB(PDFReal wx, PDFReal wy, PDFReal llx, PDFReal lly, PDFReal urx, PDFReal ury)
{
performSetCacheDevice(wx, wy, llx, lly, urx, ury);
}
void PDFPageContentProcessor::operatorColorSetStrokingColorSpace(PDFPageContentProcessor::PDFOperandName name)
{
if (m_drawingUncoloredTilingPatternState)
{
reportWarningAboutColorOperatorsInUTP();
return;
}
PDFColorSpacePointer colorSpace = PDFAbstractColorSpace::createColorSpace(m_colorSpaceDictionary, m_document, PDFObject::createName(name.name));
if (colorSpace)
{
// We must also set default color (it can depend on the color space)
m_graphicState.setStrokeColorSpace(colorSpace);
m_graphicState.setStrokeColor(colorSpace->getDefaultColor(m_CMS, m_graphicState.getRenderingIntent(), this), colorSpace->getDefaultColorOriginal());
updateGraphicState();
checkStrokingColor();
}
else
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Invalid color space."));
}
}
void PDFPageContentProcessor::operatorColorSetFillingColorSpace(PDFOperandName name)
{
if (m_drawingUncoloredTilingPatternState)
{
reportWarningAboutColorOperatorsInUTP();
return;
}
PDFColorSpacePointer colorSpace = PDFAbstractColorSpace::createColorSpace(m_colorSpaceDictionary, m_document, PDFObject::createName(name.name));
if (colorSpace)
{
// We must also set default color (it can depend on the color space)
m_graphicState.setFillColorSpace(colorSpace);
m_graphicState.setFillColor(colorSpace->getDefaultColor(m_CMS, m_graphicState.getRenderingIntent(), this), colorSpace->getDefaultColorOriginal());
updateGraphicState();
checkFillingColor();
}
else
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Invalid color space."));
}
}
void PDFPageContentProcessor::operatorColorSetStrokingColor()
{
if (m_drawingUncoloredTilingPatternState)
{
reportWarningAboutColorOperatorsInUTP();
return;
}
const PDFAbstractColorSpace* colorSpace = m_graphicState.getStrokeColorSpace();
const size_t colorSpaceComponentCount = colorSpace->getColorComponentCount();
const size_t operandCount = m_operands.size();
if (operandCount == colorSpaceComponentCount)
{
PDFColor color;
for (size_t i = 0; i < operandCount; ++i)
{
color.push_back(readOperand<PDFReal>(i));
}
m_graphicState.setStrokeColor(colorSpace->getColor(color, m_CMS, m_graphicState.getRenderingIntent(), this, true), color);
updateGraphicState();
checkStrokingColor();
}
else
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Invalid color component count. Provided %1, required %2.").arg(operandCount).arg(colorSpaceComponentCount));
}
}
void PDFPageContentProcessor::operatorColorSetStrokingColorN()
{
if (m_drawingUncoloredTilingPatternState)
{
reportWarningAboutColorOperatorsInUTP();
return;
}
// In our implementation, operator 'SC' can also set color using all color spaces
// PDF reference 1.7 allows here Pattern, Separation, DeviceN and ICCBased color spaces here,
// but default operator can use them (with exception of Pattern color space). For pattern color space,
// we treat this differently.
const PDFAbstractColorSpace* colorSpace = m_graphicState.getStrokeColorSpace();
if (const PDFPatternColorSpace* patternColorSpace = colorSpace->asPatternColorSpace())
{
const size_t operandCount = m_operands.size();
if (operandCount > 0)
{
PDFColorSpacePointer uncoloredColorSpace = patternColorSpace->getUncoloredPatternColorSpace();
PDFColor uncoloredPatternColor;
for (size_t i = 0; i < operandCount - 1; ++i)
{
uncoloredPatternColor.push_back(readOperand<PDFReal>(i));
}
PDFOperandName name = readOperand<PDFOperandName>(operandCount - 1);
if (m_patternDictionary && m_patternDictionary->hasKey(name.name))
{
// Create the pattern
PDFPatternPtr pattern = PDFPattern::createPattern(m_colorSpaceDictionary, m_document, m_patternDictionary->get(name.name), m_CMS, m_graphicState.getRenderingIntent(), this);
m_graphicState.setStrokeColorSpace(PDFColorSpacePointer(new PDFPatternColorSpace(qMove(pattern), qMove(uncoloredColorSpace), qMove(uncoloredPatternColor))));
updateGraphicState();
return;
}
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Invalid pattern for Pattern color space."));
}
else
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Invalid pattern for Pattern color space."));
}
}
else
{
operatorColorSetStrokingColor();
}
}
void PDFPageContentProcessor::operatorColorSetFillingColor()
{
if (m_drawingUncoloredTilingPatternState)
{
reportWarningAboutColorOperatorsInUTP();
return;
}
const PDFAbstractColorSpace* colorSpace = m_graphicState.getFillColorSpace();
const size_t colorSpaceComponentCount = colorSpace->getColorComponentCount();
const size_t operandCount = m_operands.size();
if (operandCount == colorSpaceComponentCount)
{
PDFColor color;
for (size_t i = 0; i < operandCount; ++i)
{
color.push_back(readOperand<PDFReal>(i));
}
m_graphicState.setFillColor(colorSpace->getColor(color, m_CMS, m_graphicState.getRenderingIntent(), this, true), color);
updateGraphicState();
checkFillingColor();
}
else
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Invalid color component count. Provided %1, required %2.").arg(operandCount).arg(colorSpaceComponentCount));
}
}
void PDFPageContentProcessor::operatorColorSetFillingColorN()
{
if (m_drawingUncoloredTilingPatternState)
{
reportWarningAboutColorOperatorsInUTP();
return;
}
// In our implementation, operator 'sc' can also set color using all color spaces
// PDF reference 1.7 allows here Pattern, Separation, DeviceN and ICCBased color spaces here,
// but default operator can use them (with exception of Pattern color space). For pattern color space,
// we treat this differently.
const PDFAbstractColorSpace* colorSpace = m_graphicState.getFillColorSpace();
if (const PDFPatternColorSpace* patternColorSpace = colorSpace->asPatternColorSpace())
{
const size_t operandCount = m_operands.size();
if (operandCount > 0)
{
PDFColorSpacePointer uncoloredColorSpace = patternColorSpace->getUncoloredPatternColorSpace();
PDFColor uncoloredPatternColor;
for (size_t i = 0; i < operandCount - 1; ++i)
{
uncoloredPatternColor.push_back(readOperand<PDFReal>(i));
}
PDFOperandName name = readOperand<PDFOperandName>(operandCount - 1);
if (m_patternDictionary && m_patternDictionary->hasKey(name.name))
{
// Create the pattern
PDFPatternPtr pattern = PDFPattern::createPattern(m_colorSpaceDictionary, m_document, m_patternDictionary->get(name.name), m_CMS, m_graphicState.getRenderingIntent(), this);
m_graphicState.setFillColorSpace(QSharedPointer<PDFAbstractColorSpace>(new PDFPatternColorSpace(qMove(pattern), qMove(uncoloredColorSpace), qMove(uncoloredPatternColor))));
updateGraphicState();
return;
}
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Invalid pattern for Pattern color space."));
}
else
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Invalid pattern for Pattern color space."));
}
}
else
{
operatorColorSetFillingColor();
}
}
void PDFPageContentProcessor::operatorColorSetDeviceGrayStroking(PDFReal gray)
{
if (m_drawingUncoloredTilingPatternState)
{
reportWarningAboutColorOperatorsInUTP();
return;
}
m_graphicState.setStrokeColorSpace(m_deviceGrayColorSpace);
m_graphicState.setStrokeColor(getColorFromColorSpace(m_graphicState.getStrokeColorSpace(), gray), PDFColor(PDFColorComponent(gray)));
updateGraphicState();
checkStrokingColor();
}
void PDFPageContentProcessor::operatorColorSetDeviceGrayFilling(PDFReal gray)
{
if (m_drawingUncoloredTilingPatternState)
{
reportWarningAboutColorOperatorsInUTP();
return;
}
m_graphicState.setFillColorSpace(m_deviceGrayColorSpace);
m_graphicState.setFillColor(getColorFromColorSpace(m_graphicState.getFillColorSpace(), gray), PDFColor(PDFColorComponent(gray)));
updateGraphicState();
checkFillingColor();
}
void PDFPageContentProcessor::operatorColorSetDeviceRGBStroking(PDFReal r, PDFReal g, PDFReal b)
{
if (m_drawingUncoloredTilingPatternState)
{
reportWarningAboutColorOperatorsInUTP();
return;
}
m_graphicState.setStrokeColorSpace(m_deviceRGBColorSpace);
m_graphicState.setStrokeColor(getColorFromColorSpace(m_graphicState.getStrokeColorSpace(), r, g, b), PDFColor(PDFColorComponent(r), PDFColorComponent(g), PDFColorComponent(b)));
updateGraphicState();
checkStrokingColor();
}
void PDFPageContentProcessor::operatorColorSetDeviceRGBFilling(PDFReal r, PDFReal g, PDFReal b)
{
if (m_drawingUncoloredTilingPatternState)
{
reportWarningAboutColorOperatorsInUTP();
return;
}
m_graphicState.setFillColorSpace(m_deviceRGBColorSpace);
m_graphicState.setFillColor(getColorFromColorSpace(m_graphicState.getFillColorSpace(), r, g, b), PDFColor(PDFColorComponent(r), PDFColorComponent(g), PDFColorComponent(b)));
updateGraphicState();
checkFillingColor();
}
void PDFPageContentProcessor::operatorColorSetDeviceCMYKStroking(PDFReal c, PDFReal m, PDFReal y, PDFReal k)
{
if (m_drawingUncoloredTilingPatternState)
{
reportWarningAboutColorOperatorsInUTP();
return;
}
m_graphicState.setStrokeColorSpace(m_deviceCMYKColorSpace);
m_graphicState.setStrokeColor(getColorFromColorSpace(m_graphicState.getStrokeColorSpace(), c, m, y, k), PDFColor(PDFColorComponent(c), PDFColorComponent(m), PDFColorComponent(y), PDFColorComponent(k)));
updateGraphicState();
checkStrokingColor();
}
void PDFPageContentProcessor::operatorColorSetDeviceCMYKFilling(PDFReal c, PDFReal m, PDFReal y, PDFReal k)
{
if (m_drawingUncoloredTilingPatternState)
{
reportWarningAboutColorOperatorsInUTP();
return;
}
m_graphicState.setFillColorSpace(m_deviceCMYKColorSpace);
m_graphicState.setFillColor(getColorFromColorSpace(m_graphicState.getFillColorSpace(), c, m, y, k), PDFColor(PDFColorComponent(c), PDFColorComponent(m), PDFColorComponent(y), PDFColorComponent(k)));
updateGraphicState();
checkFillingColor();
}
void PDFPageContentProcessor::operatorTextBegin()
{
performTextBegin(ProcessOrder::BeforeOperation);
m_graphicState.setTextMatrix(QMatrix());
m_graphicState.setTextLineMatrix(QMatrix());
updateGraphicState();
++m_textBeginEndState;
if (m_textBeginEndState > 1)
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Text object already started."));
}
performTextBegin(ProcessOrder::AfterOperation);
}
void PDFPageContentProcessor::operatorTextEnd()
{
if (--m_textBeginEndState < 0)
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Text object ended more than once."));
}
performTextEnd(ProcessOrder::BeforeOperation);
if (!m_textClippingPath.isEmpty())
{
QPainterPath clippingPath = m_graphicState.getCurrentTransformationMatrix().inverted().map(m_textClippingPath);
performClipping(clippingPath, clippingPath.fillRule());
m_textClippingPath = QPainterPath();
}
performTextEnd(ProcessOrder::AfterOperation);
}
void PDFPageContentProcessor::operatorTextSetCharacterSpacing(PDFReal charSpacing)
{
m_graphicState.setTextCharacterSpacing(charSpacing);
updateGraphicState();
}
void PDFPageContentProcessor::operatorTextSetWordSpacing(PDFReal wordSpacing)
{
m_graphicState.setTextWordSpacing(wordSpacing);
updateGraphicState();
}
void PDFPageContentProcessor::operatorTextSetHorizontalScale(PDFReal horizontalScaling)
{
// We disable horizontal scaling to less than 1%
horizontalScaling = qMax(horizontalScaling, 1.0);
m_graphicState.setTextHorizontalScaling(horizontalScaling);
updateGraphicState();
}
void PDFPageContentProcessor::operatorTextSetLeading(PDFReal leading)
{
m_graphicState.setTextLeading(leading);
updateGraphicState();
}
void PDFPageContentProcessor::operatorTextSetFontAndFontSize(PDFOperandName fontName, PDFReal fontSize)
{
if (m_fontDictionary)
{
if (m_fontDictionary->hasKey(fontName.name))
{
try
{
PDFFontPointer font = m_fontCache->getFont(m_fontDictionary->get(fontName.name));
m_graphicState.setTextFont(qMove(font));
m_graphicState.setTextFontSize(fontSize);
updateGraphicState();
}
catch (PDFException)
{
m_graphicState.setTextFont(nullptr);
m_graphicState.setTextFontSize(fontSize);
updateGraphicState();
throw;
}
}
else
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Font '%1' not found in font dictionary.").arg(QString::fromLatin1(fontName.name)));
}
}
else
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Invalid font dictionary."));
}
}
void PDFPageContentProcessor::operatorTextSetRenderMode(PDFInteger mode)
{
mode = qBound<PDFInteger>(0, mode, 7);
m_graphicState.setTextRenderingMode(static_cast<TextRenderingMode>(mode));
updateGraphicState();
}
void PDFPageContentProcessor::operatorTextSetRise(PDFReal rise)
{
m_graphicState.setTextRise(rise);
updateGraphicState();
}
void PDFPageContentProcessor::operatorTextMoveByOffset(PDFReal t_x, PDFReal t_y)
{
const QMatrix& textLineMatrix = m_graphicState.getTextLineMatrix();
QMatrix transformedMatrix = QMatrix(1, 0, 0, 1, t_x, t_y) * textLineMatrix;
m_graphicState.setTextMatrix(transformedMatrix);
m_graphicState.setTextLineMatrix(transformedMatrix);
updateGraphicState();
}
void PDFPageContentProcessor::operatorTextSetLeadingAndMoveByOffset(PDFReal t_x, PDFReal t_y)
{
// Update of graphic state is
m_graphicState.setTextLeading(-t_y);
operatorTextMoveByOffset(t_x, t_y);
}
void PDFPageContentProcessor::operatorTextSetMatrix(PDFReal a, PDFReal b, PDFReal c, PDFReal d, PDFReal e, PDFReal f)
{
// We will comment following equation:
// Adobe PDF Reference 1.7 says, that we have this transformation using coefficient a, b, c, d, e and f:
// [ a, b, 0 ]
// [x', y', 1] = [ x, y, 1] * [ c, d, 0 ]
// [ e, f, 1 ]
// If we transpose this equation (we want this, because Qt uses transposed matrices (QMatrix).
// So, we will get following result:
//
// [ x' ] [ a, c, e] [ x ]
// [ y' ] = [ b, d, f] * [ y ]
// [ 1 ] [ 0, 0, 1] [ 1 ]
//
// So, it is obvious, than we will have following coefficients:
// m_11 = a, m_21 = c, dx = e
// m_12 = b, m_22 = d, dy = f
//
// We must also check, that matrix is invertible. If it is not, then we will throw exception
// to avoid errors later (for some operations, we assume matrix is invertible).
QMatrix matrix(a, b, c, d, e, f);
m_graphicState.setTextMatrix(matrix);
m_graphicState.setTextLineMatrix(matrix);
updateGraphicState();
}
void PDFPageContentProcessor::operatorTextMoveByLeading()
{
operatorTextMoveByOffset(0.0, -m_graphicState.getTextLeading());
}
void PDFPageContentProcessor::operatorTextShowTextString(PDFOperandString text)
{
if (m_graphicState.getTextFont())
{
// Get the realized font
const PDFRealizedFontPointer& realizedFont = getRealizedFont();
if (!realizedFont)
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Invalid font, text can't be printed."));
}
TextSequence textSequence;
// We use simple heuristic to ensure reallocation doesn't occur too often
textSequence.items.reserve(m_operands.size());
realizedFont->fillTextSequence(text.string, textSequence, this);
drawText(textSequence);
}
else
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Invalid font, text can't be printed."));
}
}
void PDFPageContentProcessor::operatorTextShowTextIndividualSpacing()
{
// Operand stack must be of this form [ ... text, number, text, number, number, text ... ]. We check it.
if (m_operands.size() < 2)
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Invalid parameters of text operator with individual character spacing."));
}
// Now, we have at least 2 arguments. Check we have an array
if (m_operands[0].type != PDFLexicalAnalyzer::TokenType::ArrayStart ||
m_operands[m_operands.size() - 1].type != PDFLexicalAnalyzer::TokenType::ArrayEnd)
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Invalid line dash pattern."));
}
if (m_graphicState.getTextFont())
{
TextSequence textSequence;
// We use simple heuristic to ensure reallocation doesn't occur too often
textSequence.items.reserve(m_operands.size() * 4);
// Get the realized font
const PDFRealizedFontPointer& realizedFont = getRealizedFont();
if (!realizedFont)
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Invalid font, text can't be printed."));
}
for (size_t i = 1, lastIndex = m_operands.size() - 1; i < lastIndex; ++i)
{
switch (m_operands[i].type)
{
case PDFLexicalAnalyzer::TokenType::Integer:
{
textSequence.items.push_back(TextSequenceItem(m_operands[i].data.value<PDFInteger>()));
break;
}
case PDFLexicalAnalyzer::TokenType::Real:
{
textSequence.items.push_back(TextSequenceItem(m_operands[i].data.value<PDFReal>()));
break;
}
case PDFLexicalAnalyzer::TokenType::String:
{
realizedFont->fillTextSequence(m_operands[i].data.toByteArray(), textSequence, this);
break;
}
default:
{
// Error - we have operand of different type
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Invalid operand of text show operator."));
}
}
}
drawText(textSequence);
}
else
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Invalid font, text can't be printed."));
}
}
void PDFPageContentProcessor::operatorTextNextLineShowText(PDFOperandString text)
{
operatorTextMoveByLeading();
operatorTextShowTextString(qMove(text));
}
void PDFPageContentProcessor::operatorTextSetSpacingAndShowText(PDFReal t_w, PDFReal t_c, PDFOperandString text)
{
m_graphicState.setTextWordSpacing(t_w);
m_graphicState.setTextCharacterSpacing(t_c);
updateGraphicState();
operatorTextNextLineShowText(qMove(text));
}
void PDFPageContentProcessor::operatorShadingPaintShape(PDFPageContentProcessor::PDFOperandName name)
{
if (isContentKindSuppressed(ContentKind::Shading))
{
// Shadings are suppressed
return;
}
QMatrix matrix = getCurrentWorldMatrix();
PDFPageContentProcessorStateGuard guard(this);
PDFTemporaryValueChange guard2(&m_patternBaseMatrix, matrix);
if (!m_shadingDictionary)
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Shading '%1' not found.").arg(QString::fromLatin1(name.name)));
}
PDFPatternPtr pattern = PDFPattern::createShadingPattern(m_colorSpaceDictionary, m_document, m_shadingDictionary->get(name.name), QMatrix(), PDFObject(), m_CMS, m_graphicState.getRenderingIntent(), this, true);
// We will do a trick: we will set current fill color space, and then paint
// bounding rectangle in the color pattern.
m_graphicState.setFillColorSpace(PDFColorSpacePointer(new PDFPatternColorSpace(qMove(pattern), nullptr, PDFColor())));
updateGraphicState();
Q_ASSERT(matrix.isInvertible());
QMatrix inverted = matrix.inverted();
QPainterPath deviceBoundingRectPath;
deviceBoundingRectPath.addRect(m_pageBoundingRectDeviceSpace);
QPainterPath boundingRectPath = inverted.map(deviceBoundingRectPath);
processPathPainting(boundingRectPath, false, true, false, boundingRectPath.fillRule());
}
void PDFPageContentProcessor::paintXObjectImage(const PDFStream* stream)
{
if (isContentKindSuppressed(ContentKind::Images))
{
// Images are suppressed
return;
}
PDFColorSpacePointer colorSpace;
const PDFDictionary* streamDictionary = stream->getDictionary();
if (streamDictionary->hasKey("ColorSpace"))
{
const PDFObject& colorSpaceObject = m_document->getObject(streamDictionary->get("ColorSpace"));
if (colorSpaceObject.isName() || colorSpaceObject.isArray())
{
colorSpace = PDFAbstractColorSpace::createColorSpace(m_colorSpaceDictionary, m_document, colorSpaceObject);
}
else if (!colorSpaceObject.isNull())
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Invalid color space of the image."));
}
}
PDFImage pdfImage = PDFImage::createImage(m_document, stream, qMove(colorSpace), false, m_graphicState.getRenderingIntent(), this);
if (!performOriginalImagePainting(pdfImage))
{
QImage image = pdfImage.getImage(m_CMS, this);
if (image.format() == QImage::Format_Alpha8)
{
QSize size = image.size();
QImage unmaskedImage(size, QImage::Format_ARGB32_Premultiplied);
unmaskedImage.fill(m_graphicState.getFillColor());
unmaskedImage.setAlphaChannel(image);
image = qMove(unmaskedImage);
}
if (!image.isNull())
{
performImagePainting(image);
}
else
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Can't decode the image."));
}
}
}
void PDFPageContentProcessor::reportWarningAboutColorOperatorsInUTP()
{
reportRenderErrorOnce(RenderErrorType::Warning, PDFTranslationContext::tr("Color operators are not allowed in uncolored tilling pattern."));
}
void PDFPageContentProcessor::processForm(const PDFStream* stream)
{
PDFDocumentDataLoaderDecorator loader(getDocument());
const PDFDictionary* streamDictionary = stream->getDictionary();
// Read the bounding rectangle, if it is present
QRectF boundingBox = loader.readRectangle(streamDictionary->get("BBox"), QRectF());
// Read the transformation matrix, if it is present
QMatrix transformationMatrix = loader.readMatrixFromDictionary(streamDictionary, "Matrix", QMatrix());
// Read the dictionary content
QByteArray content = m_document->getDecodedStream(stream);
// Read resources
PDFObject resources = m_document->getObject(streamDictionary->get("Resources"));
// Transparency group
PDFObject transparencyGroup = m_document->getObject(streamDictionary->get("Group"));
// Form structural parent key
const PDFInteger formStructuralParentKey = loader.readIntegerFromDictionary(streamDictionary, "StructParent", m_structuralParentKey);
processForm(transformationMatrix, boundingBox, resources, transparencyGroup, content, formStructuralParentKey);
}
void PDFPageContentProcessor::operatorPaintXObject(PDFOperandName name)
{
// We want to have empty operands, when we are invoking forms
m_operands.clear();
if (m_xobjectDictionary)
{
const PDFObject& object = m_document->getObject(m_xobjectDictionary->get(name.name));
if (object.isStream())
{
const PDFStream* stream = object.getStream();
const PDFDictionary* streamDictionary = stream->getDictionary();
// According to the specification, XObjects are skipped entirely, as no operator was invoked.
if (streamDictionary->hasKey("OC"))
{
const PDFObject& object = streamDictionary->get("OC");
if (object.isReference())
{
if (isContentSuppressedByOC(object.getReference()))
{
return;
}
}
else
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Reference to optional content expected."));
}
}
PDFDocumentDataLoaderDecorator loader(m_document);
QByteArray subtype = loader.readNameFromDictionary(streamDictionary, "Subtype");
if (subtype == "Image")
{
paintXObjectImage(stream);
}
else if (subtype == "Form")
{
PDFInteger formType = loader.readIntegerFromDictionary(streamDictionary, "FormType", 1);
if (formType != 1)
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Form of type %1 not supported.").arg(formType));
}
processForm(stream);
}
else
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Unknown XObject type '%1'.").arg(QString::fromLatin1(subtype)));
}
}
else
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Invalid format of XObject. Dictionary expected."));
}
}
else
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("XObject resource dictionary not found."));
}
}
void PDFPageContentProcessor::operatorMarkedContentPoint(PDFOperandName name)
{
performMarkedContentPoint(name.name, PDFObject());
}
void PDFPageContentProcessor::operatorMarkedContentPointWithProperties(PDFOperandName name, PDFObject properties)
{
performMarkedContentPoint(name.name, properties);
}
void PDFPageContentProcessor::operatorMarkedContentBegin(PDFOperandName name)
{
operatorMarkedContentBeginWithProperties(qMove(name), PDFObject());
}
void PDFPageContentProcessor::operatorMarkedContentBeginWithProperties(PDFOperandName name, PDFObject properties)
{
// Handle the optional content
if (name.name == "OC")
{
PDFObjectReference ocg;
if (m_propertiesDictionary && properties.isName())
{
const PDFObject& ocgObject = m_propertiesDictionary->get(properties.getString());
if (ocgObject.isReference())
{
ocg = ocgObject.getReference();
}
}
m_markedContentStack.emplace_back(name.name, MarkedContentKind::OptionalContent, isContentSuppressedByOC(ocg));
}
else
{
m_markedContentStack.emplace_back(name.name, MarkedContentKind::Other, false);
}
performMarkedContentBegin(name.name, properties);
}
void PDFPageContentProcessor::operatorMarkedContentEnd()
{
if (m_markedContentStack.empty())
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Mismatched begin/end of marked content."));
}
m_markedContentStack.pop_back();
performMarkedContentEnd();
}
void PDFPageContentProcessor::operatorCompatibilityBegin()
{
++m_compatibilityBeginEndState;
}
void PDFPageContentProcessor::operatorCompatibilityEnd()
{
if (--m_compatibilityBeginEndState < 0)
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Compatibility operator begin/end mismatch."));
}
}
void PDFPageContentProcessor::drawText(const TextSequence& textSequence)
{
if (textSequence.items.empty())
{
// Do not display empty text
return;
}
const PDFRealizedFontPointer& font = getRealizedFont();
if (font)
{
const bool isType3Font = m_graphicState.getTextFont()->getFontType() == FontType::Type3;
const PDFReal fontSize = m_graphicState.getTextFontSize();
const PDFReal horizontalScaling = m_graphicState.getTextHorizontalScaling() * 0.01; // Horizontal scaling is in percents
const PDFReal characterSpacing = m_graphicState.getTextCharacterSpacing();
const PDFReal wordSpacing = m_graphicState.getTextWordSpacing();
const PDFReal textRise = m_graphicState.getTextRise();
const TextRenderingMode textRenderingMode = m_graphicState.getTextRenderingMode();
const bool fill = isTextRenderingModeFilled(textRenderingMode);
const bool stroke = isTextRenderingModeStroked(textRenderingMode);
const bool clipped = isTextRenderingModeClipped(textRenderingMode);
// Detect horizontal writing system
const bool isHorizontalWritingSystem = font->isHorizontalWritingSystem();
// Calculate text rendering matrix
QMatrix adjustMatrix(horizontalScaling, 0.0, 0.0, 1.0, 0.0, textRise);
QMatrix textMatrix = m_graphicState.getTextMatrix();
if (!isType3Font)
{
for (const TextSequenceItem& item : textSequence.items)
{
PDFReal displacementX = 0.0;
PDFReal displacementY = 0.0;
if (item.isCharacter())
{
QChar character = item.character;
QPointF advance = isHorizontalWritingSystem ? QPointF(item.advance, 0) : QPointF(0, item.advance);
// First, compute the advance
const PDFReal additionalAdvance = (character == QChar(QChar::Space)) ? wordSpacing + characterSpacing : characterSpacing;
if (isHorizontalWritingSystem)
{
advance.rx() += additionalAdvance;
}
else
{
advance.ry() += additionalAdvance;
}
advance.rx() *= horizontalScaling;
// Then get the glyph path and paint it
if (item.glyph)
{
const QPainterPath& glyphPath = *item.glyph;
QMatrix textRenderingMatrix = adjustMatrix * textMatrix;
QMatrix toDeviceSpaceTransform = textRenderingMatrix * m_graphicState.getCurrentTransformationMatrix();
if (!glyphPath.isEmpty())
{
QPainterPath transformedGlyph = textRenderingMatrix.map(glyphPath);
processPathPainting(transformedGlyph, stroke, fill, true, transformedGlyph.fillRule());
if (clipped)
{
// Clipping is enabled, we must transform to the device coordinates
m_textClippingPath = m_textClippingPath.united(toDeviceSpaceTransform.map(glyphPath));
}
}
if (!item.character.isNull())
{
// Output character
PDFTextCharacterInfo info;
info.character = item.character;
info.isVerticalWritingSystem = !isHorizontalWritingSystem;
info.advance = item.advance;
info.fontSize = fontSize;
info.outline = glyphPath;
info.matrix = toDeviceSpaceTransform;
performOutputCharacter(info);
}
}
displacementX = advance.x();
displacementY = advance.y();
}
else if (item.isAdvance())
{
if (horizontalScaling)
{
displacementX = -item.advance * 0.001 * fontSize * horizontalScaling;
}
else
{
displacementY = -item.advance * 0.001 * fontSize;
}
}
textMatrix.translate(displacementX, displacementY);
}
}
else
{
// Type 3 Font
Q_ASSERT(dynamic_cast<const PDFType3Font*>(m_graphicState.getTextFont().get()));
const PDFType3Font* parentFont = static_cast<const PDFType3Font*>(m_graphicState.getTextFont().get());
QMatrix fontMatrix = parentFont->getFontMatrix();
if (!fontMatrix.isInvertible())
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Type 3 font matrix is not invertible."));
}
PDFPageContentProcessorStateGuard guard(this);
PDFObject resources = parentFont->getResources();
if (!resources.isNull())
{
initDictionaries(resources);
}
QMatrix scaleMatrix(fontSize, 0.0, 0.0, fontSize, 0.0, 0.0);
adjustMatrix = scaleMatrix * adjustMatrix;
QMatrix fontAdjustedMatrix = fontMatrix * adjustMatrix;
for (const TextSequenceItem& item : textSequence.items)
{
// First, compute horizontal advance
qreal displacementX = 0.0;
if (item.advance != 0.0)
{
qreal ry = 0.0;
fontAdjustedMatrix.map(item.advance, 0.0, &displacementX, &ry);
}
if (item.characterContentStream && (fill || stroke))
{
PDFPageContentProcessorStateGuard guard(this);
// We must clear operands, because we are processing a new content stream
m_operands.clear();
QMatrix worldMatrix = fontAdjustedMatrix * textMatrix * m_graphicState.getCurrentTransformationMatrix();
m_graphicState.setCurrentTransformationMatrix(worldMatrix);
updateGraphicState();
processContent(*item.characterContentStream);
if (!item.character.isNull())
{
// Output character
PDFTextCharacterInfo info;
info.character = item.character;
info.isVerticalWritingSystem = !isHorizontalWritingSystem;
info.advance = item.advance;
info.fontSize = fontSize;
info.matrix = worldMatrix;
performOutputCharacter(info);
}
}
textMatrix.translate(displacementX, 0.0);
}
}
m_graphicState.setTextMatrix(textMatrix);
updateGraphicState();
}
else
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Invalid font, text can't be printed."));
}
}
PDFRealizedFontPointer PDFPageContentProcessor::getRealizedFontImpl()
{
if (m_graphicState.getTextFont())
{
return m_fontCache->getRealizedFont(m_graphicState.getTextFont(), m_graphicState.getTextFontSize(), this);
}
return PDFRealizedFontPointer();
}
void PDFPageContentProcessor::checkStrokingColor()
{
if (!m_graphicState.getStrokeColor().isValid())
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Invalid stroking color."));
}
}
void PDFPageContentProcessor::checkFillingColor()
{
if (!m_graphicState.getFillColor().isValid())
{
throw PDFRendererException(RenderErrorType::Error, PDFTranslationContext::tr("Invalid filling color."));
}
}
PDFObject PDFPageContentProcessor::readObjectFromOperandStack(size_t startPosition) const
{
auto tokenFetcher = [this, &startPosition]()
{
if (startPosition < m_operands.size())
{
return m_operands[startPosition++];
}
return PDFLexicalAnalyzer::Token();
};
PDFParser parser(tokenFetcher);
return parser.getObject();
}
bool PDFPageContentProcessor::isContentSuppressedByOC(PDFObjectReference ocgOrOcmd)
{
if (!m_optionalContentActivity)
{
// Optional content activity control is suppressed, treat all content as not suppressed
return false;
}
if (m_optionalContentActivity->getProperties()->hasOptionalContentGroup(ocgOrOcmd))
{
// Simplest case - we have single optional content group
return m_optionalContentActivity->getState(ocgOrOcmd) == OCState::OFF;
}
PDFOptionalContentMembershipObject ocmd;
try
{
ocmd = PDFOptionalContentMembershipObject::create(m_document, PDFObject::createReference(ocgOrOcmd));
}
catch (PDFException e)
{
m_errorList.push_back(PDFRenderError(RenderErrorType::Error, e.getMessage()));
}
if (ocmd.isValid())
{
return ocmd.evaluate(m_optionalContentActivity) == OCState::OFF;
}
return false;
}
PDFPageContentProcessor::PDFPageContentProcessorState::PDFPageContentProcessorState() :
m_currentTransformationMatrix(),
m_strokeColorSpace(),
m_fillColorSpace(),
m_strokeColor(Qt::black),
m_strokeColorOriginal(),
m_fillColor(Qt::black),
m_fillColorOriginal(),
m_lineWidth(1.0),
m_lineCapStyle(Qt::FlatCap),
m_lineJoinStyle(Qt::MiterJoin),
m_mitterLimit(10.0),
m_renderingIntentName(),
m_flatness(1.0),
m_smoothness(0.01),
m_textCharacterSpacing(0.0),
m_textWordSpacing(0.0),
m_textHorizontalScaling(100.0),
m_textLeading(0.0),
m_textFontSize(0.0),
m_textRenderingMode(TextRenderingMode::Fill),
m_textRise(0.0),
m_textKnockout(true),
m_alphaStroking(1.0),
m_alphaFilling(1.0),
m_blendMode(BlendMode::Normal),
m_renderingIntent(RenderingIntent::Perceptual),
m_overprintMode(),
m_alphaIsShape(false),
m_strokeAdjustment(false),
m_softMask(nullptr),
m_blackPointCompensationMode(BlackPointCompensationMode::Default),
m_stateFlags(StateUnchanged)
{
m_fillColorSpace.reset(new PDFDeviceGrayColorSpace);
m_strokeColorSpace = m_fillColorSpace;
m_fillColorOriginal = m_fillColorSpace->getDefaultColorOriginal();
m_strokeColorOriginal = m_fillColorOriginal;
}
PDFPageContentProcessor::PDFPageContentProcessorState::~PDFPageContentProcessorState()
{
}
PDFPageContentProcessor::PDFPageContentProcessorState& PDFPageContentProcessor::PDFPageContentProcessorState::operator=(const PDFPageContentProcessor::PDFPageContentProcessorState& other)
{
setCurrentTransformationMatrix(other.getCurrentTransformationMatrix());
setStrokeColorSpace(other.m_strokeColorSpace);
setFillColorSpace(other.m_fillColorSpace);
setStrokeColor(other.getStrokeColor(), other.getStrokeColorOriginal());
setFillColor(other.getFillColor(), other.getFillColorOriginal());
setLineWidth(other.getLineWidth());
setLineCapStyle(other.getLineCapStyle());
setLineJoinStyle(other.getLineJoinStyle());
setMitterLimit(other.getMitterLimit());
setLineDashPattern(other.getLineDashPattern());
setRenderingIntentName(other.getRenderingIntentName());
setFlatness(other.getFlatness());
setSmoothness(other.getSmoothness());
setTextCharacterSpacing(other.getTextCharacterSpacing());
setTextWordSpacing(other.getTextWordSpacing());
setTextHorizontalScaling(other.getTextHorizontalScaling());
setTextLeading(other.getTextLeading());
setTextFont(other.getTextFont());
setTextFontSize(other.getTextFontSize());
setTextRenderingMode(other.getTextRenderingMode());
setTextRise(other.getTextRise());
setTextKnockout(other.getTextKnockout());
setTextMatrix(other.getTextMatrix());
setTextLineMatrix(other.getTextLineMatrix());
setAlphaStroking(other.getAlphaStroking());
setAlphaFilling(other.getAlphaFilling());
setBlendMode(other.getBlendMode());
setRenderingIntent(other.getRenderingIntent());
setOverprintMode(other.getOverprintMode());
setAlphaIsShape(other.getAlphaIsShape());
setStrokeAdjustment(other.getStrokeAdjustment());
setSoftMask(other.getSoftMask());
setBlackPointCompensationMode(other.getBlackPointCompensationMode());
setBlackGenerationFunction(other.getBlackGenerationFunction());
setUndercolorRemovalFunction(other.getUndercolorRemovalFunction());
setTransferFunction(other.getTransferFunction());
setHalftone(other.getHalftone());
setHalftoneOrigin(other.getHalftoneOrigin());
return *this;
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setCurrentTransformationMatrix(const QMatrix& currentTransformationMatrix)
{
if (m_currentTransformationMatrix != currentTransformationMatrix)
{
m_currentTransformationMatrix = currentTransformationMatrix;
m_stateFlags |= StateCurrentTransformationMatrix;
}
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setStrokeColorSpace(const QSharedPointer<PDFAbstractColorSpace>& strokeColorSpace)
{
if (m_strokeColorSpace != strokeColorSpace)
{
m_strokeColorSpace = strokeColorSpace;
m_stateFlags |= StateStrokeColorSpace;
}
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setFillColorSpace(const QSharedPointer<PDFAbstractColorSpace>& fillColorSpace)
{
if (m_fillColorSpace != fillColorSpace)
{
m_fillColorSpace = fillColorSpace;
m_stateFlags |= StateFillColorSpace;
}
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setStrokeColor(const QColor& strokeColor, const PDFColor& originalColor)
{
if (m_strokeColor != strokeColor || m_strokeColorOriginal != originalColor)
{
m_strokeColor = strokeColor;
m_strokeColorOriginal = originalColor;
m_stateFlags |= StateStrokeColor;
}
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setFillColor(const QColor& fillColor, const PDFColor& originalColor)
{
if (m_fillColor != fillColor || m_fillColorOriginal != originalColor)
{
m_fillColor = fillColor;
m_fillColorOriginal = originalColor;
m_stateFlags |= StateFillColor;
}
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setLineWidth(PDFReal lineWidth)
{
if (m_lineWidth != lineWidth)
{
m_lineWidth = lineWidth;
m_stateFlags |= StateLineWidth;
}
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setLineCapStyle(Qt::PenCapStyle lineCapStyle)
{
if (m_lineCapStyle != lineCapStyle)
{
m_lineCapStyle = lineCapStyle;
m_stateFlags |= StateLineCapStyle;
}
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setLineJoinStyle(Qt::PenJoinStyle lineJoinStyle)
{
if (m_lineJoinStyle != lineJoinStyle)
{
m_lineJoinStyle = lineJoinStyle;
m_stateFlags |= StateLineJoinStyle;
}
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setMitterLimit(PDFReal mitterLimit)
{
if (m_mitterLimit != mitterLimit)
{
m_mitterLimit = mitterLimit;
m_stateFlags |= StateMitterLimit;
}
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setLineDashPattern(PDFLineDashPattern pattern)
{
if (m_lineDashPattern != pattern)
{
m_lineDashPattern = std::move(pattern);
m_stateFlags |= StateLineDashPattern;
}
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setRenderingIntentName(const QByteArray& renderingIntentName)
{
if (m_renderingIntentName != renderingIntentName)
{
m_renderingIntentName = renderingIntentName;
m_stateFlags |= StateRenderingIntentName;
}
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setFlatness(PDFReal flatness)
{
if (m_flatness != flatness)
{
m_flatness = flatness;
m_stateFlags |= StateFlatness;
}
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setSmoothness(PDFReal smoothness)
{
if (m_smoothness != smoothness)
{
m_smoothness = smoothness;
m_stateFlags |= StateSmoothness;
}
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setTextLeading(PDFReal textLeading)
{
if (m_textLeading != textLeading)
{
m_textLeading = textLeading;
m_stateFlags |= StateTextLeading;
}
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setTextFontSize(PDFReal textFontSize)
{
if (m_textFontSize != textFontSize)
{
m_textFontSize = textFontSize;
m_stateFlags |= StateTextFontSize;
}
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setTextKnockout(bool textKnockout)
{
if (m_textKnockout != textKnockout)
{
m_textKnockout = textKnockout;
m_stateFlags |= StateTextKnockout;
}
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setTextLineMatrix(const QMatrix& textLineMatrix)
{
if (m_textLineMatrix != textLineMatrix)
{
m_textLineMatrix = textLineMatrix;
m_stateFlags |= StateTextLineMatrix;
}
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setAlphaStroking(PDFReal alpha)
{
if (m_alphaStroking != alpha)
{
m_alphaStroking = alpha;
m_stateFlags |= StateAlphaStroking;
}
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setAlphaFilling(PDFReal alpha)
{
if (m_alphaFilling != alpha)
{
m_alphaFilling = alpha;
m_stateFlags |= StateAlphaFilling;
}
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setBlendMode(BlendMode mode)
{
if (m_blendMode != mode)
{
m_blendMode = mode;
m_stateFlags |= StateBlendMode;
}
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setRenderingIntent(RenderingIntent renderingIntent)
{
if (m_renderingIntent != renderingIntent)
{
m_renderingIntent = renderingIntent;
m_stateFlags |= StateRenderingIntent;
}
}
QColor PDFPageContentProcessor::PDFPageContentProcessorState::getStrokeColorWithAlpha() const
{
QColor color = getStrokeColor();
color.setAlphaF(m_alphaStroking);
return color;
}
QColor PDFPageContentProcessor::PDFPageContentProcessorState::getFillColorWithAlpha() const
{
QColor color = getFillColor();
color.setAlphaF(m_alphaFilling);
return color;
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setOverprintMode(PDFOverprintMode overprintMode)
{
if (m_overprintMode != overprintMode)
{
m_overprintMode = overprintMode;
m_stateFlags |= StateOverprint;
}
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setAlphaIsShape(bool alphaIsShape)
{
if (m_alphaIsShape != alphaIsShape)
{
m_alphaIsShape = alphaIsShape;
m_stateFlags |= StateAlphaIsShape;
}
}
bool PDFPageContentProcessor::PDFPageContentProcessorState::getStrokeAdjustment() const
{
return m_strokeAdjustment;
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setStrokeAdjustment(bool strokeAdjustment)
{
if (m_strokeAdjustment != strokeAdjustment)
{
m_strokeAdjustment = strokeAdjustment;
m_stateFlags |= StateStrokeAdjustment;
}
}
const PDFDictionary* PDFPageContentProcessor::PDFPageContentProcessorState::getSoftMask() const
{
return m_softMask;
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setSoftMask(const PDFDictionary* softMask)
{
if (m_softMask != softMask)
{
m_softMask = softMask;
m_stateFlags |= StateSoftMask;
}
}
BlackPointCompensationMode PDFPageContentProcessor::PDFPageContentProcessorState::getBlackPointCompensationMode() const
{
return m_blackPointCompensationMode;
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setBlackPointCompensationMode(BlackPointCompensationMode blackPointCompensationMode)
{
if (m_blackPointCompensationMode != blackPointCompensationMode)
{
m_blackPointCompensationMode = blackPointCompensationMode;
m_stateFlags |= StateBlackPointCompensation;
}
}
PDFObject PDFPageContentProcessor::PDFPageContentProcessorState::getHalftone() const
{
return m_halftone;
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setHalftone(const PDFObject& halftone)
{
if (m_halftone != halftone)
{
m_halftone = halftone;
m_stateFlags |= StateHalftone;
}
}
QPointF PDFPageContentProcessor::PDFPageContentProcessorState::getHalftoneOrigin() const
{
return m_halftoneOrigin;
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setHalftoneOrigin(const QPointF& halftoneOrigin)
{
if (m_halftoneOrigin != halftoneOrigin)
{
m_halftoneOrigin = halftoneOrigin;
m_stateFlags |= StateHalftoneOrigin;
}
}
PDFObject PDFPageContentProcessor::PDFPageContentProcessorState::getTransferFunction() const
{
return m_transferFunction;
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setTransferFunction(const PDFObject& transferFunction)
{
if (m_transferFunction != transferFunction)
{
m_transferFunction = transferFunction;
m_stateFlags |= StateTransferFunction;
}
}
PDFObject PDFPageContentProcessor::PDFPageContentProcessorState::getUndercolorRemovalFunction() const
{
return m_undercolorRemovalFunction;
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setUndercolorRemovalFunction(const PDFObject& undercolorRemovalFunction)
{
if (m_undercolorRemovalFunction != undercolorRemovalFunction)
{
m_undercolorRemovalFunction = undercolorRemovalFunction;
m_stateFlags |= StateUndercolorRemovalFunction;
}
}
PDFObject PDFPageContentProcessor::PDFPageContentProcessorState::getBlackGenerationFunction() const
{
return m_blackGenerationFunction;
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setBlackGenerationFunction(const PDFObject& blackGenerationFunction)
{
if (m_blackGenerationFunction != blackGenerationFunction)
{
m_blackGenerationFunction = blackGenerationFunction;
m_stateFlags |= StateBlackGenerationFunction;
}
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setTextMatrix(const QMatrix& textMatrix)
{
if (m_textMatrix != textMatrix)
{
m_textMatrix = textMatrix;
m_stateFlags |= StateTextMatrix;
}
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setTextRise(PDFReal textRise)
{
if (m_textRise != textRise)
{
m_textRise = textRise;
m_stateFlags |= StateTextRise;
}
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setTextRenderingMode(TextRenderingMode textRenderingMode)
{
if (m_textRenderingMode != textRenderingMode)
{
m_textRenderingMode = textRenderingMode;
m_stateFlags |= StateTextRenderingMode;
}
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setTextFont(const PDFFontPointer& textFont)
{
if (m_textFont != textFont)
{
m_textFont = textFont;
m_stateFlags |= StateTextFont;
}
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setTextHorizontalScaling(PDFReal textHorizontalScaling)
{
if (m_textHorizontalScaling != textHorizontalScaling)
{
m_textHorizontalScaling = textHorizontalScaling;
m_stateFlags |= StateTextHorizontalScaling;
}
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setTextWordSpacing(PDFReal textWordSpacing)
{
if (m_textWordSpacing != textWordSpacing)
{
m_textWordSpacing = textWordSpacing;
m_stateFlags |= StateTextWordSpacing;
}
}
void PDFPageContentProcessor::PDFPageContentProcessorState::setTextCharacterSpacing(PDFReal textCharacterSpacing)
{
if (m_textCharacterSpacing != textCharacterSpacing)
{
m_textCharacterSpacing = textCharacterSpacing;
m_stateFlags |= StateTextCharacterSpacing;
}
}
PDFPageContentProcessor::PDFPageContentProcessorStateGuard::PDFPageContentProcessorStateGuard(PDFPageContentProcessor* processor) :
m_processor(processor),
m_colorSpaceDictionary(processor->m_colorSpaceDictionary),
m_fontDictionary(processor->m_fontDictionary),
m_xobjectDictionary(processor->m_xobjectDictionary),
m_extendedGraphicStateDictionary(processor->m_extendedGraphicStateDictionary),
m_propertiesDictionary(processor->m_propertiesDictionary),
m_shadingDictionary(processor->m_shadingDictionary),
m_patternDictionary(processor->m_patternDictionary),
m_procedureSets(processor->m_procedureSets)
{
m_processor->operatorSaveGraphicState();
}
PDFPageContentProcessor::PDFPageContentProcessorStateGuard::~PDFPageContentProcessorStateGuard()
{
// Restore dictionaries
m_processor->m_colorSpaceDictionary = m_colorSpaceDictionary;
m_processor->m_fontDictionary = m_fontDictionary;
m_processor->m_xobjectDictionary = m_xobjectDictionary;
m_processor->m_extendedGraphicStateDictionary = m_extendedGraphicStateDictionary;
m_processor->m_propertiesDictionary = m_propertiesDictionary;
m_processor->m_shadingDictionary = m_shadingDictionary;
m_processor->m_patternDictionary = m_patternDictionary;
m_processor->m_procedureSets = m_procedureSets;
m_processor->operatorRestoreGraphicState();
}
PDFPageContentProcessor::PDFTransparencyGroupGuard::PDFTransparencyGroupGuard(PDFPageContentProcessor* processor, PDFTransparencyGroup&& group) :
m_processor(processor)
{
m_processor->performBeginTransparencyGroup(ProcessOrder::BeforeOperation, group);
m_processor->m_transparencyGroupStack.push(qMove(group));
m_processor->performBeginTransparencyGroup(ProcessOrder::AfterOperation, m_processor->m_transparencyGroupStack.top());
}
PDFPageContentProcessor::PDFTransparencyGroupGuard::~PDFTransparencyGroupGuard()
{
m_processor->performEndTransparencyGroup(ProcessOrder::BeforeOperation, m_processor->m_transparencyGroupStack.top());
PDFTransparencyGroup group = qMove(m_processor->m_transparencyGroupStack.top());
m_processor->m_transparencyGroupStack.pop();
m_processor->performEndTransparencyGroup(ProcessOrder::AfterOperation, group);
}
PDFLineDashPattern::PDFLineDashPattern(const std::vector<PDFReal>& dashArray, PDFReal dashOffset) :
m_dashArray(dashArray),
m_dashOffset(dashOffset)
{
if (m_dashArray.size() % 2 == 1)
{
m_dashArray.push_back(m_dashArray.back());
}
}
void PDFLineDashPattern::fix()
{
if (m_dashOffset < 0.0)
{
// According to the PDF 2.0 specification, if dash offset is negative,
// then twice of sum of lengths in the dash array should be added
// so dash offset will become positive.
const PDFReal totalLength = 2 * std::accumulate(m_dashArray.cbegin(), m_dashArray.cend(), 0.0);
if (totalLength > 0.0)
{
m_dashOffset += (std::floor(std::abs(m_dashOffset / totalLength)) + 1.0) * totalLength;
}
else
{
// Reset to default solid line, dash pattern is invalid
*this = PDFLineDashPattern();
}
}
}
PDFPageContentProcessor::PDFSoftMaskDefinition PDFPageContentProcessor::PDFSoftMaskDefinition::parse(const PDFDictionary* softMask, PDFPageContentProcessor* processor)
{
PDFSoftMaskDefinition result;
PDFDocumentDataLoaderDecorator loader(processor->getDocument());
constexpr const std::array type = {
std::pair<const char*, Type>{ "Alpha", Type::Alpha },
std::pair<const char*, Type>{ "Luminosity", Type::Luminosity }
};
result.m_type = loader.readEnumByName(softMask->get("S"), type.begin(), type.end(), Type::Invalid);
PDFObject streamObject = processor->getDocument()->getObject(softMask->get("G"));
result.m_formStream = streamObject.isStream() ? streamObject.getStream() : nullptr;
if (result.m_formStream)
{
result.m_transparencyGroup = processor->parseTransparencyGroup(result.m_formStream->getDictionary()->get("Group"));
}
std::vector<PDFReal> backdropColor = loader.readNumberArrayFromDictionary(softMask, "BC");
result.m_backdropColor = PDFAbstractColorSpace::convertToColor(backdropColor);
if (result.m_backdropColor.empty() && result.m_transparencyGroup.colorSpacePointer)
{
result.m_transparencyGroup.colorSpacePointer->getDefaultColorOriginal();
}
if (softMask->hasKey("TR"))
{
try
{
result.m_transferFunction = PDFFunction::createFunction(processor->getDocument(), softMask->get("TR"));
}
catch (PDFException)
{
processor->reportRenderError(RenderErrorType::Error, PDFTranslationContext::tr("Invalid soft mask transfer function."));
}
}
return result;
}
} // namespace pdf
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