Пример #1
0
void ImageImporter::execute() {
    if (mFilename == "")
        throw Exception("No filename was supplied to the ImageImporter");

    uchar* convertedPixelData;
    // Load image from disk using Qt
    QImage image;
    reportInfo() << "Trying to load image..." << Reporter::end();
    if(!image.load(mFilename.c_str())) {
        throw FileNotFoundException(mFilename);
    }
    reportInfo() << "Loaded image with size " << image.width() << " "  << image.height() << Reporter::end();

    QImage::Format format;
    if(mGrayscale) {
        format = QImage::Format_Grayscale8;
    } else {
        format = QImage::Format_RGB888;
    }
    QImage convertedImage = image.convertToFormat(format);

    // Get pixel data
    convertedPixelData = convertedImage.bits();

    Image::pointer output = getOutputData<Image>();
    std::cout << "image info" << std::endl;
    std::cout << convertedImage.width() << std::endl;
    std::cout << convertedImage.depth() << std::endl;
    std::cout << convertedImage.bytesPerLine() << std::endl;
    if(convertedImage.width()*convertedImage.depth()/8 != convertedImage.bytesPerLine()) {
        const int bytesPerPixel = (convertedImage.depth()/8);
        std::unique_ptr<uchar[]> fixedPixelData = std::make_unique<uchar[]>(image.width()*image.height());
        // Misalignment
        for(int scanline = 0; scanline < image.height(); ++scanline) {
            std::memcpy(
                    &fixedPixelData[scanline*image.width()*bytesPerPixel],
                    &convertedPixelData[scanline*convertedImage.bytesPerLine()],
                    image.width()*bytesPerPixel
            );
        }
        output->create(
            image.width(),
            image.height(),
            TYPE_UINT8,
            mGrayscale ? 1 : 3,
            getMainDevice(),
            fixedPixelData.get()
        );
    } else {
        output->create(
            image.width(),
            image.height(),
            TYPE_UINT8,
            mGrayscale ? 1 : 3,
            getMainDevice(),
            convertedPixelData
        );
    }
}
Пример #2
0
void ManualImageStreamer::stop() {
    {
        std::unique_lock<std::mutex> lock(mStopMutex);
        mStop = true;
    }
    mThread->join();
    reportInfo() << "File streamer thread returned" << reportEnd();
}
Пример #3
0
    void setupUi(QDialog *kregularGraphDialog)
    {
    if (kregularGraphDialog->objectName().isEmpty())
        kregularGraphDialog->setObjectName(QString::fromUtf8("kregularGraphDialog"));
    kregularGraphDialog->setWindowModality(Qt::WindowModal);
    kregularGraphDialog->resize(377, 249);
    kregularGraphDialog->setMinimumSize(QSize(377, 249));
    kregularGraphDialog->setMaximumSize(QSize(377, 249));
    kregularGraphDialog->setLayoutDirection(Qt::LeftToRight);
    kregularGraphDialog->setModal(false);
    buttonBox = new QDialogButtonBox(kregularGraphDialog);
    buttonBox->setObjectName(QString::fromUtf8("buttonBox"));
    buttonBox->setGeometry(QRect(30, 190, 331, 32));
    buttonBox->setOrientation(Qt::Horizontal);
    buttonBox->setStandardButtons(QDialogButtonBox::Cancel|QDialogButtonBox::Ok);
    formLayoutWidget = new QWidget(kregularGraphDialog);
    formLayoutWidget->setObjectName(QString::fromUtf8("formLayoutWidget"));
    formLayoutWidget->setGeometry(QRect(39, 70, 291, 101));
    formLayout = new QFormLayout(formLayoutWidget);
    formLayout->setObjectName(QString::fromUtf8("formLayout"));
    formLayout->setHorizontalSpacing(5);
    formLayout->setVerticalSpacing(23);
    formLayout->setContentsMargins(0, 0, 0, 0);
    label = new QLabel(formLayoutWidget);
    label->setObjectName(QString::fromUtf8("label"));

    formLayout->setWidget(0, QFormLayout::LabelRole, label);

    label_2 = new QLabel(formLayoutWidget);
    label_2->setObjectName(QString::fromUtf8("label_2"));

    formLayout->setWidget(1, QFormLayout::LabelRole, label_2);

    spinBox = new QSpinBox(formLayoutWidget);
    spinBox->setObjectName(QString::fromUtf8("spinBox"));
    spinBox->setMinimum(1);
    spinBox->setMaximum(1000);

    formLayout->setWidget(0, QFormLayout::FieldRole, spinBox);

    spinBox_2 = new QSpinBox(formLayoutWidget);
    spinBox_2->setObjectName(QString::fromUtf8("spinBox_2"));

    formLayout->setWidget(1, QFormLayout::FieldRole, spinBox_2);

    label_3 = new QLabel(kregularGraphDialog);
    label_3->setObjectName(QString::fromUtf8("label_3"));
    label_3->setGeometry(QRect(40, 30, 291, 18));

    retranslateUi(kregularGraphDialog);
		QObject::connect(buttonBox,SIGNAL(accepted()), this , SLOT(reportInfo()));
    QObject::connect(buttonBox, SIGNAL(accepted()), kregularGraphDialog, SLOT(accept()));
    QObject::connect(buttonBox, SIGNAL(rejected()), kregularGraphDialog, SLOT(reject()));

    QMetaObject::connectSlotsByName(kregularGraphDialog);
    } // setupUi
Пример #4
0
void getCommand(unsigned long runTime)
{
  int ch;
  unsigned long preTime = getclocks();
  
  do {
    while (cmdWaitAck > 0 && !cmdBuffferNearFull()) {
		response_ack();
		cmdWaitAck--;
	}

    if (commandAvailable() <= 0)
	  break;
	ch = readCommandChr();

	if (ch == '\n' || ch == '\t' || (ch == ':' && !cmdCommentDetected))
	{
	  cmdCommentDetected = false;
	  
	  if (cmdTail == cmdTailOut)
	    continue;
	
	  cmdBuffer[cmdTail] = '\0';
	  cmdTail = (cmdTail + 1) % cmdSize;
	  
	  if (parseCommand() == false)
		request_to_send(cmdLineNumber + 1);
	  else if (reportInfo() == false)
        cmdTailOut = skipUnusedCode();
	  
	  cmdTail = cmdTailOut;
	  if (cmdBuffferNearFull())
	    cmdWaitAck++;
	  else
	    response_ack();
	}
	else if (ch == ';')
	  cmdCommentDetected = true;
	else if (cmdCommentDetected == false)
	{
	  cmdBuffer[cmdTail] = ch;
	  cmdTail = (cmdTail + 1) % cmdSize;
	}
  } while (getclocks() - preTime < runTime);
}
Пример #5
0
void ImageClassifier::execute() {

    run();

    Tensor::pointer tensor = m_engine->getOutputNodes().begin()->second.data;
    TensorAccess::pointer access = tensor->getAccess(ACCESS_READ);

    auto data = access->getData<2>();
    ImageClassification::pointer output = getOutputData<ImageClassification>(0);
    for(int i = 0; i < data.dimension(0); ++i) { // for each input image
        std::map<std::string, float> mapResult;
        for(int j = 0; j < data.dimension(1); ++j) { // for each class
            mapResult[mLabels[j]] = data(i, j);
            reportInfo() << mLabels[j] << ": " << data(i, j) << reportEnd();
        }

        output->create(mapResult);
    }
}
Пример #6
0
/*
 * That is a method which gets called from check_wrapper
 * */
int CppCheckExecutor::check_internal(CppCheck& cppcheck, int /*argc*/, const char* const argv[])
{
    Settings& settings = cppcheck.settings();
    _settings = &settings;
    bool std = tryLoadLibrary(settings.library, argv[0], "std.cfg");
    bool posix = true;
    if (settings.standards.posix)
        posix = tryLoadLibrary(settings.library, argv[0], "posix.cfg");
    bool windows = true;
    if (settings.isWindowsPlatform())
        windows = tryLoadLibrary(settings.library, argv[0], "windows.cfg");

    if (!std || !posix || !windows) {
        const std::list<ErrorLogger::ErrorMessage::FileLocation> callstack;
        const std::string msg("Failed to load " + std::string(!std ? "std.cfg" : !posix ? "posix.cfg" : "windows.cfg") + ". Your Cppcheck installation is broken, please re-install.");
#ifdef CFGDIR
        const std::string details("The Cppcheck binary was compiled with CFGDIR set to \"" +
                                  std::string(CFGDIR) + "\" and will therefore search for "
                                  "std.cfg in that path.");
#else
        const std::string cfgfolder(Path::fromNativeSeparators(Path::getPathFromFilename(argv[0])) + "cfg");
        const std::string details("The Cppcheck binary was compiled without CFGDIR set. Either the "
                                  "std.cfg should be available in " + cfgfolder + " or the CFGDIR "
                                  "should be configured.");
#endif
        ErrorLogger::ErrorMessage errmsg(callstack, Severity::information, msg+" "+details, "failedToLoadCfg", false);
        reportErr(errmsg);
        return EXIT_FAILURE;
    }

    if (settings.reportProgress)
        time1 = std::time(0);

    if (settings._xml) {
        reportErr(ErrorLogger::ErrorMessage::getXMLHeader(settings._xml_version));
    }

    unsigned int returnValue = 0;
    if (settings._jobs == 1) {
        // Single process
        settings.jointSuppressionReport = true;

        std::size_t totalfilesize = 0;
        for (std::map<std::string, std::size_t>::const_iterator i = _files.begin(); i != _files.end(); ++i) {
            totalfilesize += i->second;
        }

        std::size_t processedsize = 0;
        unsigned int c = 0;
        for (std::map<std::string, std::size_t>::const_iterator i = _files.begin(); i != _files.end(); ++i) {
            if (!_settings->library.markupFile(i->first)
                || !_settings->library.processMarkupAfterCode(i->first)) {
                returnValue += cppcheck.check(i->first);
                processedsize += i->second;
                if (!settings.quiet)
                    reportStatus(c + 1, _files.size(), processedsize, totalfilesize);
                c++;
            }
        }

        // second loop to parse all markup files which may not work until all
        // c/cpp files have been parsed and checked
        for (std::map<std::string, std::size_t>::const_iterator i = _files.begin(); i != _files.end(); ++i) {
            if (_settings->library.markupFile(i->first) && _settings->library.processMarkupAfterCode(i->first)) {
                returnValue += cppcheck.check(i->first);
                processedsize += i->second;
                if (!settings.quiet)
                    reportStatus(c + 1, _files.size(), processedsize, totalfilesize);
                c++;
            }
        }
        cppcheck.analyseWholeProgram();
    } else if (!ThreadExecutor::isEnabled()) {
        std::cout << "No thread support yet implemented for this platform." << std::endl;
    } else {
        // Multiple processes
        ThreadExecutor executor(_files, settings, *this);
        returnValue = executor.check();
    }

    if (settings.isEnabled("information") || settings.checkConfiguration) {
        const bool enableUnusedFunctionCheck = cppcheck.unusedFunctionCheckIsEnabled();

        if (settings.jointSuppressionReport) {
            for (std::map<std::string, std::size_t>::const_iterator i = _files.begin(); i != _files.end(); ++i) {
                reportUnmatchedSuppressions(settings.nomsg.getUnmatchedLocalSuppressions(i->first, enableUnusedFunctionCheck));
            }
        }

        reportUnmatchedSuppressions(settings.nomsg.getUnmatchedGlobalSuppressions(enableUnusedFunctionCheck));
    }

    if (!settings.checkConfiguration) {
        cppcheck.tooManyConfigsError("",0U);

        if (settings.isEnabled("missingInclude") && (Preprocessor::missingIncludeFlag || Preprocessor::missingSystemIncludeFlag)) {
            const std::list<ErrorLogger::ErrorMessage::FileLocation> callStack;
            ErrorLogger::ErrorMessage msg(callStack,
                                          Severity::information,
                                          "Cppcheck cannot find all the include files (use --check-config for details)\n"
                                          "Cppcheck cannot find all the include files. Cppcheck can check the code without the "
                                          "include files found. But the results will probably be more accurate if all the include "
                                          "files are found. Please check your project's include directories and add all of them "
                                          "as include directories for Cppcheck. To see what files Cppcheck cannot find use "
                                          "--check-config.",
                                          Preprocessor::missingIncludeFlag ? "missingInclude" : "missingIncludeSystem",
                                          false);
            reportInfo(msg);
        }
    }

    if (settings._xml) {
        reportErr(ErrorLogger::ErrorMessage::getXMLFooter(settings._xml_version));
    }

    _settings = 0;
    if (returnValue)
        return settings._exitCode;
    else
        return 0;
}
Пример #7
0
int CppCheckExecutor::check(int argc, const char* const argv[])
{
    Preprocessor::missingIncludeFlag = false;

    CppCheck cppCheck(*this, true);

    Settings& settings = cppCheck.settings();
    _settings = &settings;

    if (!parseFromArgs(&cppCheck, argc, argv)) {
        return EXIT_FAILURE;
    }

    if (settings.reportProgress)
        time1 = std::time(0);

    if (settings._xml) {
        reportErr(ErrorLogger::ErrorMessage::getXMLHeader(settings._xml_version));
    }

    unsigned int returnValue = 0;
    if (settings._jobs == 1) {
        // Single process

        std::size_t totalfilesize = 0;
        for (std::map<std::string, std::size_t>::const_iterator i = _files.begin(); i != _files.end(); ++i) {
            totalfilesize += i->second;
        }

        std::size_t processedsize = 0;
        unsigned int c = 0;
        for (std::map<std::string, std::size_t>::const_iterator i = _files.begin(); i != _files.end(); ++i) {
            returnValue += cppCheck.check(i->first);
            processedsize += i->second;
            if (!settings._errorsOnly)
                reportStatus(c + 1, _files.size(), processedsize, totalfilesize);
            c++;
        }

        cppCheck.checkFunctionUsage();
    } else if (!ThreadExecutor::isEnabled()) {
        std::cout << "No thread support yet implemented for this platform." << std::endl;
    } else {
        // Multiple processes
        ThreadExecutor executor(_files, settings, *this);
        returnValue = executor.check();
    }

    if (!settings.checkConfiguration) {
        if (!settings._errorsOnly)
            reportUnmatchedSuppressions(settings.nomsg.getUnmatchedGlobalSuppressions());

        cppCheck.tooManyConfigsError("",0U);

        if (settings.isEnabled("missingInclude") && Preprocessor::missingIncludeFlag) {
            const std::list<ErrorLogger::ErrorMessage::FileLocation> callStack;
            ErrorLogger::ErrorMessage msg(callStack,
                                          Severity::information,
                                          "Cppcheck cannot find all the include files (use --check-config for details)\n"
                                          "Cppcheck cannot find all the include files. Cppcheck can check the code without the "
                                          "include files found. But the results will probably be more accurate if all the include "
                                          "files are found. Please check your project's include directories and add all of them "
                                          "as include directories for Cppcheck. To see what files Cppcheck cannot find use "
                                          "--check-config.",
                                          "missingInclude",
                                          false);
            reportInfo(msg);
        }
    }

    if (settings._xml) {
        reportErr(ErrorLogger::ErrorMessage::getXMLFooter(settings._xml_version));
    }

    _settings = 0;
    if (returnValue)
        return settings._exitCode;
    else
        return 0;
}
Пример #8
0
void VTKMeshFileImporter::execute() {
    if(mFilename == "")
        throw Exception("No filename given to the VTKMeshFileImporter");

    // Try to open file and check that it exists
    std::ifstream file(mFilename.c_str());
    std::string line;
    if(!file.is_open()) {
        throw FileNotFoundException(mFilename);
    }

    // Check file header?

    // Read vertices
    std::vector<Vector3f> vertices;
    if(!gotoLineWithString(file, "POINTS")) {
        throw Exception("Found no vertices in the VTK surface file");
    }
    while(getline(file, line)) {
        boost::trim(line);
        if(line.size() == 0)
            break;

        if(!(isdigit(line[0]) || line[0] == '-')) {
            // Has reached end
            break;
        }

        std::vector<std::string> tokens;
        boost::split(tokens, line, boost::is_any_of(" "));

        for(int i = 0; i < tokens.size(); i += 3) {
            Vector3f v;
            v(0) = boost::lexical_cast<float>(tokens[i]);
            v(1) = boost::lexical_cast<float>(tokens[i+1]);
            v(2) = boost::lexical_cast<float>(tokens[i+2]);
            vertices.push_back(v);
        }
    }
    file.seekg(0); // set stream to start

    // Read triangles (other types of polygons not supported yet)
    std::vector<Vector3ui> triangles;
    if(!gotoLineWithString(file, "POLYGONS")) {
        throw Exception("Found no triangles in the VTK surface file");
    }
    while(getline(file, line)) {
        boost::trim(line);
        if(line.size() == 0)
            break;

        if(!isdigit(line[0])) {
            // Has reached end
            break;
        }


        std::vector<std::string> tokens;
        boost::split(tokens, line, boost::is_any_of(" "));

        if(boost::lexical_cast<int>(tokens[0]) != 3) {
            throw Exception("The VTKMeshFileImporter currently only supports reading files with triangles. Encountered a non-triangle. Aborting.");
        }
        if(tokens.size() != 4) {
            throw Exception("Error while reading triangles in VTKMeshFileImporter. Check format.");
        }

        Vector3ui triangle;
        triangle(0) = boost::lexical_cast<uint>(tokens[1]);
        triangle(1) = boost::lexical_cast<uint>(tokens[2]);
        triangle(2) = boost::lexical_cast<uint>(tokens[3]);

        triangles.push_back(triangle);

    }
    file.seekg(0); // set stream to start

    // Read normals (if any)
    std::vector<Vector3f> normals;
    if(!gotoLineWithString(file, "NORMALS")) {
        // Create dummy normals
        for(uint i = 0; i < vertices.size(); i++) {
            Vector3f dummyNormal;
            normals.push_back(dummyNormal);
        }
    } else {
        while(getline(file, line)) {
            boost::trim(line);
            if(line.size() == 0)
                break;

            if(!(isdigit(line[0]) || line[0] == '-')) {
                // Has reached end
                break;
            }

            std::vector<std::string> tokens;
            boost::split(tokens, line, boost::is_any_of(" "));

            for(int i = 0; i < tokens.size(); i += 3) {
                Vector3f v;
                v(0) = boost::lexical_cast<float>(tokens[i]);
                v(1) = boost::lexical_cast<float>(tokens[i+1]);
                v(2) = boost::lexical_cast<float>(tokens[i+2]);
                normals.push_back(v);
            }
        }

        if(normals.size() != vertices.size()) {
            std::string message = "Read different amount of vertices (" + boost::lexical_cast<std::string>(vertices.size()) + ") and normals (" + boost::lexical_cast<std::string>(normals.size()) + ").";
            throw Exception(message);
        }
    }

    Mesh::pointer output = getOutputData<Mesh>(0);

    // Add data to output
    output->create(vertices, normals, triangles);
    reportInfo() << "MESH IMPORTED vertices " << vertices.size() << " normals " << normals.size() << " triangles " << triangles.size() << Reporter::end;
}
Пример #9
0
void ManualImageStreamer::producerStream() {
    uint i = mStartNumber;
    int replays = 0;
    uint64_t previousTimestamp = 0;
    auto previousTimestampTime = std::chrono::high_resolution_clock::time_point::min();
    int currentSequence = 0;
    while(true) {
        {
            std::unique_lock<std::mutex> lock(mStopMutex);
            if(mStop) {
                mStreamIsStarted = false;
                mFirstFrameIsInserted = false;
                mHasReachedEnd = false;
                break;
            }
        }
        try {
            Image::pointer image = mImages[currentSequence].at(i);
            addOutputData(0, image);
            if(image->getCreationTimestamp() != 0) {
                uint64_t timestamp = image->getCreationTimestamp();
                // Wait as long as necessary before adding image
                // Time passed since last frame
                auto timePassed = std::chrono::duration_cast<std::chrono::milliseconds>(
                        std::chrono::high_resolution_clock::now() - previousTimestampTime);
                while (timestamp > previousTimestamp + timePassed.count()) {
                    // Wait
                    int64_t left = (timestamp - previousTimestamp) - timePassed.count();
                    reportInfo() << "Sleeping for " << left << " ms" << reportEnd();
                    std::this_thread::sleep_for(std::chrono::milliseconds(left));
                    timePassed = std::chrono::duration_cast<std::chrono::milliseconds>(
                            std::chrono::high_resolution_clock::now() - previousTimestampTime);
                }
                previousTimestamp = timestamp;
                previousTimestampTime = std::chrono::high_resolution_clock::now();
            }
            if(mSleepTime > 0)
                std::this_thread::sleep_for(std::chrono::milliseconds(mSleepTime));
            if(!mFirstFrameIsInserted) {
                {
                    std::lock_guard<std::mutex> lock(mFirstFrameMutex);
                    mFirstFrameIsInserted = true;
                }
                mFirstFrameCondition.notify_one();
            }
            mNrOfFrames++;
            i += mStepSize;
        } catch(std::out_of_range &e) {
            if(i > 0) {
                reportInfo() << "Reached end of stream" << Reporter::end();
                // If there where no files found at all, we need to release the execute method
                if(!mFirstFrameIsInserted) {
                    {
                        std::lock_guard<std::mutex> lock(mFirstFrameMutex);
                        mFirstFrameIsInserted = true;
                    }
                    mFirstFrameCondition.notify_one();
                }
                if(mLoop || (mNrOfReplays > 0 && replays != mNrOfReplays || (currentSequence < mImages.size()-1))) {
                    // Restart stream
                    previousTimestamp = 0;
                    previousTimestampTime = std::chrono::high_resolution_clock::time_point::min();
                    replays++;
                    i = mStartNumber;
                    currentSequence++;
                    // Go to first sequence if looping is enabled
                    if(mLoop && currentSequence == mImages.size()) {
                        currentSequence = 0;
                    }
                    continue;
                }
                mHasReachedEnd = true;
                // Reached end of stream
                break;
            } else {
                throw e;
            }
        }
    }
}
Пример #10
0
void TensorFlowEngine::run() {
	if(mInputNodes.empty())
		throw Exception("At least one output node has to be given to the NeuralNetwork before execution");
	if(mOutputNodes.empty())
		throw Exception("At least one output node has to be given to the NeuralNetwork before execution");

	// For each input, create a tensorflow tensor:
	std::vector <std::pair<std::string, tensorflow::Tensor>> input_tensors;
	for(auto inputNode : mInputNodes) {
		const std::string name = inputNode.first;
		if(!inputNode.second.data)
			throw Exception("Input node " + name + " has not received any data");
		auto shape = inputNode.second.data->getShape();
		if(shape.getUnknownDimensions() > 0)
		    throw Exception("Input shape must be fully known when executing NN");

		// Construct tensorflow tensor
        tensorflow::TensorShape tensorShape;
        for(auto i : shape.getAll()) {
            tensorShape.AddDim(i);
        }
        tensorflow::Tensor input_tensor(
                tensorflow::DT_FLOAT,
                tensorShape
        );

        // Give tensor data to tensorflow
        // TODO is the data here actually moved?
        TensorAccess::pointer access = inputNode.second.data->getAccess(ACCESS_READ);
        switch(shape.getDimensions()) {
            case 2:
                input_tensor.tensor<float, 2>() = std::move(access->getData<2>());
                break;
            case 3:
                input_tensor.tensor<float, 3>() = std::move(access->getData<3>());
                break;
            case 4:
                input_tensor.tensor<float, 4>() = std::move(access->getData<4>());
                break;
            case 5:
                input_tensor.tensor<float, 5>() = std::move(access->getData<5>());
                break;
			case 6:
				input_tensor.tensor<float, 6>() = std::move(access->getData<6>());
				break;
            default:
                throw Exception("Invalid tensor dimension size");
		}

		// Add tensorflow tensor to list of input tensors
		input_tensors.push_back(std::make_pair(name, input_tensor));
	}

    for(std::string name : mLearningPhaseTensors) {
        // Create a scalar tensor which tells the system we are NOT doing training
        tensorflow::Tensor input_tensor2(
                tensorflow::DT_BOOL,
                tensorflow::TensorShape() // Scalar
        );
        auto input_tensor_mapped2 = input_tensor2.tensor<bool, 0>();
        input_tensor_mapped2(0) = false;
        input_tensors.push_back(std::make_pair(name, input_tensor2));
    }

	std::vector<tensorflow::Tensor> output_tensors;

	reportInfo() << "Running network" << reportEnd();
	tensorflow::Status s;
	//mRuntimeManager->startRegularTimer("network_execution");
	std::vector<std::string> outputNames;
	for(auto node : mOutputNodes)
	    outputNames.push_back(node.first);
	s = mSession->Run(input_tensors, outputNames, {}, &output_tensors);
	//mRuntimeManager->stopRegularTimer("network_execution");

	if (!s.ok()) {
		throw Exception("Error during inference: " + s.ToString());
	}
	reportInfo() << "Finished executing network" << reportEnd();

    // Collect all output data as FAST tensors
    for(int j = 0; j < outputNames.size(); ++j) {
        const std::string outputName = outputNames[j];
        const NetworkNode node = mOutputNodes[outputName];
        auto tensor = TensorflowTensor::New();
        tensor->create(std::move(output_tensors[j]));
        mOutputNodes[outputName].data = tensor;
	}
	reportInfo() << "Finished parsing output" << reportEnd();
}
Пример #11
0
void TensorFlowEngine::load() {
	const auto networkFilename = getFilename();
	tensorflow::SessionOptions options;
	tensorflow::ConfigProto &config = options.config;
	tensorflow::GPUOptions* gpuOptions = config.mutable_gpu_options();
	gpuOptions->set_allow_growth(true); // Set this so that tensorflow will not use up all GPU memory
	//gpuOptions->set_per_process_gpu_memory_fraction(0.5);
	mSession.reset(tensorflow::NewSession(options));
	tensorflow::GraphDef tensorflow_graph;

	{
		reportInfo() << "Loading network file: " << networkFilename << reportEnd();
		tensorflow::Status s = ReadBinaryProto(tensorflow::Env::Default(), networkFilename, &tensorflow_graph);
		if (!s.ok()) {
			throw Exception("Could not read TensorFlow graph file " + networkFilename);
		}
	}

	bool nodesSpecified = true;
    int inputCounter = 0;
	if(mInputNodes.size() == 0) {
		nodesSpecified = false;
	}
    for(int i = 0; i < tensorflow_graph.node_size(); ++i) {
		tensorflow::NodeDef node = tensorflow_graph.node(i);
		if(mInputNodes.count(node.name()) > 0) {
		}
		if(node.op() == "Placeholder") {
			if(node.name().find("keras_learning_phase") != std::string::npos) {
				//mLearningPhaseTensors.insert(node.name());
				mLearningPhaseTensors.push_back(node.name());
			} else {
				// Input node found:
				// Get its shape
				// Input nodes use the Op Placeholder
				reportInfo() << "Found input node: " << i << " with name " << node.name() << reportEnd();
				auto shape = getShape(node);
				reportInfo() << "Node has shape " << shape.toString() << reportEnd();
				if(mInputNodes.count(node.name()) == 0) {
					if(nodesSpecified) {
						throw Exception("Encountered unknown node " + node.name());
					}
					reportInfo() << "Node was not specified by user" << reportEnd();
					// If node has not been specified by user, we need to add it
					// and thus know its type (fast image or tensor)
					// It is assumed to be an image if input shape has at least 4 dimensions
					NodeType type = NodeType::TENSOR;
					if(shape.getKnownDimensions() >= 2) {
						reportInfo() << "Assuming node is an image" << reportEnd();
						type = NodeType::IMAGE;
					} else {
						reportInfo() << "Assuming node is a tensor" << reportEnd();
					}
					addInputNode(inputCounter, tensorflow_graph.node(0).name(), type, shape);
					++inputCounter;
				}

				// Set its shape
				mInputNodes[node.name()].shape = shape;
			}
		}
	}

	reportInfo() << "Creating session." << reportEnd();
	tensorflow::Status s = mSession->Create(tensorflow_graph);
	if (!s.ok()) {
		throw Exception("Could not create TensorFlow Graph");
	}

	//tensorflow::graph::SetDefaultDevice("/gpu:0", &tensorflow_graph);

	// Clear the proto to save memory space.
	tensorflow_graph.Clear();
	reportInfo() << "TensorFlow graph loaded from: " << networkFilename << reportEnd();

	setIsLoaded(true);
}
Пример #12
0
void IterativeClosestPoint::execute() {
    float error = std::numeric_limits<float>::max(), previousError;
    uint iterations = 0;

    // Get access to the two point sets
    PointSetAccess::pointer accessFixedSet = ((PointSet::pointer)getStaticInputData<PointSet>(0))->getAccess(ACCESS_READ);
    PointSetAccess::pointer accessMovingSet = ((PointSet::pointer)getStaticInputData<PointSet>(1))->getAccess(ACCESS_READ);

    // Get transformations of point sets
    AffineTransformation::pointer fixedPointTransform2 = SceneGraph::getAffineTransformationFromData(getStaticInputData<PointSet>(0));
    Eigen::Affine3f fixedPointTransform;
    fixedPointTransform.matrix() = fixedPointTransform2->matrix();
    AffineTransformation::pointer initialMovingTransform2 = SceneGraph::getAffineTransformationFromData(getStaticInputData<PointSet>(1));
    Eigen::Affine3f initialMovingTransform;
    initialMovingTransform.matrix() = initialMovingTransform2->matrix();

    // These matrices are Nx3
    MatrixXf fixedPoints = accessFixedSet->getPointSetAsMatrix();
    MatrixXf movingPoints = accessMovingSet->getPointSetAsMatrix();

    Eigen::Affine3f currentTransformation = Eigen::Affine3f::Identity();

    // Want to choose the smallest one as moving
    bool invertTransform = false;
    if(false && fixedPoints.cols() < movingPoints.cols()) {
        reportInfo() << "switching fixed and moving" << Reporter::end;
        // Switch fixed and moving
        MatrixXf temp = fixedPoints;
        fixedPoints = movingPoints;
        movingPoints = temp;
        invertTransform = true;

        // Apply initial transformations
        //currentTransformation = fixedPointTransform.getTransform();
        movingPoints = fixedPointTransform*movingPoints.colwise().homogeneous();
        fixedPoints = initialMovingTransform*fixedPoints.colwise().homogeneous();
    } else {
        // Apply initial transformations
        //currentTransformation = initialMovingTransform.getTransform();
        movingPoints = initialMovingTransform*movingPoints.colwise().homogeneous();
        fixedPoints = fixedPointTransform*fixedPoints.colwise().homogeneous();
    }
    do {
        previousError = error;
        MatrixXf movedPoints = currentTransformation*(movingPoints.colwise().homogeneous());

        // Match closest points using current transformation
        MatrixXf rearrangedFixedPoints = rearrangeMatrixToClosestPoints(
                fixedPoints, movedPoints);

        // Get centroids
        Vector3f centroidFixed = getCentroid(rearrangedFixedPoints);
        //reportInfo() << "Centroid fixed: " << Reporter::end;
        //reportInfo() << centroidFixed << Reporter::end;
        Vector3f centroidMoving = getCentroid(movedPoints);
        //reportInfo() << "Centroid moving: " << Reporter::end;
        //reportInfo() << centroidMoving << Reporter::end;

        Eigen::Transform<float, 3, Eigen::Affine> updateTransform = Eigen::Transform<float, 3, Eigen::Affine>::Identity();

        if(mTransformationType == IterativeClosestPoint::RIGID) {
            // Create correlation matrix H of the deviations from centroid
            MatrixXf H = (movedPoints.colwise() - centroidMoving)*
                    (rearrangedFixedPoints.colwise() - centroidFixed).transpose();

            // Do SVD on H
            Eigen::JacobiSVD<Eigen::MatrixXf> svd(H, Eigen::ComputeFullU | Eigen::ComputeFullV);

            // Estimate rotation as R=V*U.transpose()
            MatrixXf temp = svd.matrixV()*svd.matrixU().transpose();
            Matrix3f d = Matrix3f::Identity();
            d(2,2) = sign(temp.determinant());
            Matrix3f R = svd.matrixV()*d*svd.matrixU().transpose();

            // Estimate translation
            Vector3f T = centroidFixed - R*centroidMoving;

            updateTransform.linear() = R;
            updateTransform.translation() = T;
        } else {
            // Only translation
            Vector3f T = centroidFixed - centroidMoving;
            updateTransform.translation() = T;
        }

        // Update current transformation
        currentTransformation = updateTransform*currentTransformation;

        // Calculate RMS error
        MatrixXf distance = rearrangedFixedPoints - currentTransformation*(movingPoints.colwise().homogeneous());
        error = 0;
        for(uint i = 0; i < distance.cols(); i++) {
            error += pow(distance.col(i).norm(),2);
        }
        error = sqrt(error / distance.cols());

        iterations++;
        reportInfo() << "Error: " << error << Reporter::end;
        // To continue, change in error has to be above min error change and nr of iterations less than max iterations
    } while(previousError-error > mMinErrorChange && iterations < mMaxIterations);


    if(invertTransform){
        currentTransformation = currentTransformation.inverse();
    }

    mError = error;
    mTransformation->matrix() = currentTransformation.matrix();
}
   void setupUi(QDialog *strangersbanquetGraphDialog)
    {
    if (strangersbanquetGraphDialog->objectName().isEmpty())
        strangersbanquetGraphDialog->setObjectName(QString::fromUtf8("strangersbanquetGraphDialog"));
    strangersbanquetGraphDialog->setWindowModality(Qt::WindowModal);
    strangersbanquetGraphDialog->resize(424, 339);
    strangersbanquetGraphDialog->setMinimumSize(QSize(424, 339));
    strangersbanquetGraphDialog->setMaximumSize(QSize(377, 249));
    strangersbanquetGraphDialog->setLayoutDirection(Qt::LeftToRight);
    strangersbanquetGraphDialog->setModal(false);
    buttonBox = new QDialogButtonBox(strangersbanquetGraphDialog);
    buttonBox->setObjectName(QString::fromUtf8("buttonBox"));
    buttonBox->setGeometry(QRect(40, 290, 371, 32));
    buttonBox->setOrientation(Qt::Horizontal);
    buttonBox->setStandardButtons(QDialogButtonBox::Cancel|QDialogButtonBox::Ok);
    formLayoutWidget = new QWidget(strangersbanquetGraphDialog);
    formLayoutWidget->setObjectName(QString::fromUtf8("formLayoutWidget"));
    formLayoutWidget->setGeometry(QRect(39, 70, 351, 201));
    formLayout = new QFormLayout(formLayoutWidget);
    formLayout->setObjectName(QString::fromUtf8("formLayout"));
    formLayout->setHorizontalSpacing(5);
    formLayout->setVerticalSpacing(23);
    formLayout->setContentsMargins(0, 0, 0, 0);
    label = new QLabel(formLayoutWidget);
    label->setObjectName(QString::fromUtf8("label"));

    formLayout->setWidget(0, QFormLayout::LabelRole, label);

    label_2 = new QLabel(formLayoutWidget);
    label_2->setObjectName(QString::fromUtf8("label_2"));

    formLayout->setWidget(2, QFormLayout::LabelRole, label_2);

    spinBox = new QSpinBox(formLayoutWidget);
    spinBox->setObjectName(QString::fromUtf8("spinBox"));
    spinBox->setMinimum(1);
    spinBox->setMaximum(1000);

    formLayout->setWidget(0, QFormLayout::FieldRole, spinBox);

 label_5 = new QLabel(formLayoutWidget);
    label_5->setObjectName(QString::fromUtf8("label_5"));

    formLayout->setWidget(1, QFormLayout::LabelRole, label_5);

    spinBox_2 = new QSpinBox(formLayoutWidget);
    spinBox_2->setObjectName(QString::fromUtf8("spinBox_2"));
    spinBox_2->setMinimum(1);
    spinBox_2->setMaximum(5);

    formLayout->setWidget(1, QFormLayout::FieldRole, spinBox_2);

    label_4 = new QLabel(formLayoutWidget);
    label_4->setObjectName(QString::fromUtf8("label_4"));

    formLayout->setWidget(3, QFormLayout::LabelRole, label_4);

    doubleSpinBox_2 = new QDoubleSpinBox(formLayoutWidget);
    doubleSpinBox_2->setObjectName(QString::fromUtf8("doubleSpinBox_2"));
    doubleSpinBox_2->setDecimals(3);
    doubleSpinBox_2->setMaximum(1);
    doubleSpinBox_2->setSingleStep(0.01);

    formLayout->setWidget(2, QFormLayout::FieldRole, doubleSpinBox_2);

    doubleSpinBox_3 = new QDoubleSpinBox(formLayoutWidget);
    doubleSpinBox_3->setObjectName(QString::fromUtf8("doubleSpinBox_3"));
    doubleSpinBox_3->setDecimals(3);
    doubleSpinBox_3->setMaximum(1);
    doubleSpinBox_3->setSingleStep(0.01);

    formLayout->setWidget(3, QFormLayout::FieldRole, doubleSpinBox_3);

   

    label_3 = new QLabel(strangersbanquetGraphDialog);
    label_3->setObjectName(QString::fromUtf8("label_3"));
    label_3->setGeometry(QRect(40, 30, 351, 18));

    retranslateUi(strangersbanquetGraphDialog);
	    retranslateUi(strangersbanquetGraphDialog);
		QObject::connect(buttonBox,SIGNAL(accepted()),this , SLOT(reportInfo()));
    QObject::connect(buttonBox, SIGNAL(accepted()), strangersbanquetGraphDialog, SLOT(accept()));
    QObject::connect(buttonBox, SIGNAL(rejected()), strangersbanquetGraphDialog, SLOT(reject()));

    QMetaObject::connectSlotsByName(strangersbanquetGraphDialog);
    } // setupUi
Пример #14
0
unsigned int CppCheck::processFile(const std::string& filename)
{
    exitcode = 0;

    // only show debug warnings for accepted C/C++ source files
    if (!Path::acceptFile(filename))
        _settings.debugwarnings = false;

    if (_settings.terminated())
        return exitcode;

    if (_settings._errorsOnly == false) {
        std::string fixedpath = Path::simplifyPath(filename.c_str());
        fixedpath = Path::toNativeSeparators(fixedpath);
        _errorLogger.reportOut(std::string("Checking ") + fixedpath + std::string("..."));
    }

    try {
        Preprocessor preprocessor(&_settings, this);
        std::list<std::string> configurations;
        std::string filedata = "";

        if (!_fileContent.empty()) {
            // File content was given as a string
            std::istringstream iss(_fileContent);
            preprocessor.preprocess(iss, filedata, configurations, filename, _settings._includePaths);
        } else {
            // Only file name was given, read the content from file
            std::ifstream fin(filename.c_str());
            Timer t("Preprocessor::preprocess", _settings._showtime, &S_timerResults);
            preprocessor.preprocess(fin, filedata, configurations, filename, _settings._includePaths);
        }

        if (_settings.checkConfiguration) {
            return 0;
        }

        if (!_settings.userDefines.empty()) {
            configurations.clear();
            configurations.push_back(_settings.userDefines);
        }

        if (!_settings._force && configurations.size() > _settings._maxConfigs) {
            const std::string fixedpath = Path::toNativeSeparators(filename);
            ErrorLogger::ErrorMessage::FileLocation location;
            location.setfile(fixedpath);
            const std::list<ErrorLogger::ErrorMessage::FileLocation> loclist(1, location);
            std::ostringstream msg;
            msg << "Too many #ifdef configurations - cppcheck will only check " << _settings._maxConfigs << " of " << configurations.size() << ".\n"
                "The checking of the file will be interrupted because there are too many "
                "#ifdef configurations. Checking of all #ifdef configurations can be forced "
                "by --force command line option or from GUI preferences. However that may "
                "increase the checking time.";
            ErrorLogger::ErrorMessage errmsg(loclist,
                                             Severity::information,
                                             msg.str(),
                                             "toomanyconfigs",
                                             false);

            reportErr(errmsg);
        }

        unsigned int checkCount = 0;
        for (std::list<std::string>::const_iterator it = configurations.begin(); it != configurations.end(); ++it) {
            // Check only a few configurations (default 12), after that bail out, unless --force
            // was used.
            if (!_settings._force && checkCount >= _settings._maxConfigs) {

                const std::string fixedpath = Path::toNativeSeparators(filename);
                ErrorLogger::ErrorMessage::FileLocation location;
                location.setfile(fixedpath);
                std::list<ErrorLogger::ErrorMessage::FileLocation> loclist;
                loclist.push_back(location);
                ErrorLogger::ErrorMessage errmsg(loclist,
                                                 Severity::information,
                                                 "Interrupted checking because of too many #ifdef configurations.",
                                                 "toomanyconfigs",
                                                 false);

                reportInfo(errmsg);
                break;
            }

            cfg = *it;

            // If only errors are printed, print filename after the check
            if (_settings._errorsOnly == false && it != configurations.begin()) {
                std::string fixedpath = Path::simplifyPath(filename.c_str());
                fixedpath = Path::toNativeSeparators(fixedpath);
                _errorLogger.reportOut(std::string("Checking ") + fixedpath + ": " + cfg + std::string("..."));
            }

            Timer t("Preprocessor::getcode", _settings._showtime, &S_timerResults);
            const std::string codeWithoutCfg = preprocessor.getcode(filedata, *it, filename, _settings.userDefines.empty());
            t.Stop();

            const std::string &appendCode = _settings.append();

            if (_settings.debugFalsePositive) {
                if (findError(codeWithoutCfg + appendCode, filename.c_str())) {
                    return exitcode;
                }
            } else {
                checkFile(codeWithoutCfg + appendCode, filename.c_str());
            }

            ++checkCount;
        }
    } catch (const std::runtime_error &e) {
        // Exception was thrown when checking this file..
        const std::string fixedpath = Path::toNativeSeparators(filename);
        _errorLogger.reportOut("Bailing out from checking " + fixedpath + ": " + e.what());
    }

    if (!_settings._errorsOnly)
        reportUnmatchedSuppressions(_settings.nomsg.getUnmatchedLocalSuppressions(filename));

    _errorList.clear();
    return exitcode;
}
    // ---------------------
void serialParse(void)
{
    char charCh;
    byte hexRead, oldHexRead;
  
    charCh = getChar();
    if (!charCh) return;

    if (sysStat & ST_DEBUG_MODE)        // Super commands for Monitor
    {
        rs485TransmitEna();
        putChar(charCh);

        switch(charCh)
        {
            case 'd':
                putStr("\tNode ID switch test.\n\r");
                putStr("\tHit any key to quit.\n\r");
                rs485TransmitDisa();
                while(1)
                {                  
                    charCh = getChar();
                    if (charCh) break;
                    hexRead = readNodeSw();
                    if (hexRead != oldHexRead)
                    {
                        rs485TransmitEna();
                        sprintf(ioBfr, "\n\r Node ID: %02Xh", hexRead);
                        putStr(ioBfr);
                        oldHexRead = hexRead;
                        rs485TransmitDisa();
                    }
                }
                break;

            case 'f':
                putStr("\tFlood sensor test: ");
                adcFloodSensor(ADC_LOQUACIOUS);
                break;

            case 'h':
                adcRHumid(ADC_LOQUACIOUS);
                break;

            case 'r':
                reportInfo();             
                break;

            case 't':
                adcTemper(ADC_LOQUACIOUS);
                break;

            case 'T':
                adcTemperSecondary(ADC_LOQUACIOUS);
                break;


            case '1':
                RELAY1 ^= 1;
                if (RELAY1) putStr("\tRelay 1 on");
                else putStr("\tRelay 1 off");
                break;

            case '2':
                RELAY2 ^= 1;
                if (RELAY2) putStr("\tRelay 2 on");
                else putStr("\tRelay 2 off");
                break;

            case '3':
                SwiPwr1 ^= 1;
                if (SwiPwr1) putStr("\tSwi Pwr1 on");
                else putStr("\tSwi Pwr1 off");
                break;

            case '4':
                SwiPwr2 ^= 1;
                if (SwiPwr2) putStr("\tSwi Pwr2 on");
                else putStr("\tSwi Pwr2 off");
                break;

            case '?':
                menuDisplay();                
                break;
        }                       // EO switch
        putPrompt();
        rs485TransmitDisa();
    }       // EO if debug
    else
    {
        childStateMach(charCh);
    }
}