Example #1
0
// -----------------------------------------------------------------------------
//
// -----------------------------------------------------------------------------
void VoxelDataContainer::addEdgeData(const std::string &name, IDataArray::Pointer data)
{
  if (data->GetName().compare(name) != 0)
  {
    std::cout << "Adding Edge array with different array name than key name" << std::endl;
    std::cout << "Key name: " << name << std::endl;
    std::cout << "Array Name:" << data->GetName() << std::endl;
    data->SetName(name);
  }
  m_EdgeData[name] = data;
  m_NumEdgeTuples = data->GetNumberOfTuples();
}
Example #2
0
// -----------------------------------------------------------------------------
//
// -----------------------------------------------------------------------------
void ClearData::execute()
{
  int err = 0;
  setErrorCondition(err);
  VoxelDataContainer* m = getVoxelDataContainer();
  if(NULL == m)
  {
    setErrorCondition(-999);
    notifyErrorMessage("The DataContainer Object was NULL", -999);
    return;
  }

  setErrorCondition(0);
  dataCheck(false, m->getTotalPoints(), m->getNumFieldTuples(), m->getNumEnsembleTuples());
  if(getErrorCondition() < 0)
  {
    return;
  }

  size_t udims[3] =
  { 0, 0, 0 };
  m->getDimensions(udims);
#if (CMP_SIZEOF_SIZE_T == 4)
  typedef int32_t DimType;
#else
  typedef int64_t DimType;
#endif
  DimType dims[3] =
  { static_cast<DimType>(udims[0]), static_cast<DimType>(udims[1]), static_cast<DimType>(udims[2]), };



  int index;
  std::list<std::string> voxelArrayNames = m->getCellArrayNameList();
  for (int k = m_ZMin; k < m_ZMax+1; k++)
  {
    for (int j = m_YMin; j < m_YMax+1; j++)
    {
      for (int i = m_XMin; i < m_XMax+1; i++)
      {
        index = (k * dims[0] * dims[1]) + (j * dims[0]) + i;
        for (std::list<std::string>::iterator iter = voxelArrayNames.begin(); iter != voxelArrayNames.end(); ++iter)
        {
          std::string name = *iter;
          IDataArray::Pointer p = m->getCellData(*iter);
          p->InitializeTuple(index,0);
        }
      }
    }
  }

  notifyStatusMessage("Completed");
}
Example #3
0
 /**
  * @brief deepCopy
  * @param forceNoAllocate
  * @return
  */
 virtual IDataArray::Pointer deepCopy(bool forceNoAllocate = false)
 {
   IDataArray::Pointer daCopy = createNewArray(getNumberOfTuples(), getComponentDimensions(), getName(), m_IsAllocated);
   if(m_IsAllocated == true && forceNoAllocate == false)
   {
     T* src = getPointer(0);
     void* dest = daCopy->getVoidPointer(0);
     size_t totalBytes = (getNumberOfTuples() * getNumberOfComponents() * sizeof(T));
     ::memcpy(dest, src, totalBytes);
   }
   return daCopy;
 }
// -----------------------------------------------------------------------------
//
// -----------------------------------------------------------------------------
void SurfaceMeshDataContainer::addFieldData(const std::string &name, IDataArray::Pointer data)
{
  if (data->GetName().compare(name) != 0)
  {
    std::cout << "Adding Field array with different array name than key name" << std::endl;
    std::cout << "Key name: " << name << std::endl;
    std::cout << "Array Name:" << data->GetName() << std::endl;
    data->SetName(name);
  }
  m_FieldData[name] = data;
  m_NumFieldTuples = data->GetNumberOfTuples();
}
// -----------------------------------------------------------------------------
//
// -----------------------------------------------------------------------------
void VisualizeGBCDPoleFigure::dataCheck()
{
  setErrorCondition(0);

  getDataContainerArray()->getPrereqGeometryFromDataContainer<TriangleGeom, AbstractFilter>(this, getGBCDArrayPath().getDataContainerName());

  if (getOutputFile().isEmpty() == true)
  {
    QString ss = QObject::tr( "The output file must be set");
    setErrorCondition(-1000);
    notifyErrorMessage(getHumanLabel(), ss, getErrorCondition());
  }

  QFileInfo fi(getOutputFile());
  QDir parentPath = fi.path();
  if (parentPath.exists() == false && getInPreflight())
  {
    QString ss = QObject::tr( "The directory path for the output file does not exist. DREAM.3D will attempt to create this path during execution of the filter");
    notifyWarningMessage(getHumanLabel(), ss, -1);
  }

  if (fi.suffix().compare("") == 0)
  {
    setOutputFile(getOutputFile().append(".vtk"));
  }

  QVector<size_t> cDims(1, 1);
  m_CrystalStructuresPtr = getDataContainerArray()->getPrereqArrayFromPath<DataArray<unsigned int>, AbstractFilter>(this, getCrystalStructuresArrayPath(), cDims); /* Assigns the shared_ptr<> to an instance variable that is a weak_ptr<> */
  if (NULL != m_CrystalStructuresPtr.lock().get()) /* Validate the Weak Pointer wraps a non-NULL pointer to a DataArray<T> object */
  {
    m_CrystalStructures = m_CrystalStructuresPtr.lock()->getPointer(0);
  } /* Now assign the raw pointer to data from the DataArray<T> object */

  IDataArray::Pointer tmpGBCDPtr = getDataContainerArray()->getPrereqIDataArrayFromPath<IDataArray, AbstractFilter>(this, getGBCDArrayPath());
  if(getErrorCondition() < 0) { return; }

  if (NULL != tmpGBCDPtr.get())
  {
    QVector<size_t> cDims = tmpGBCDPtr->getComponentDimensions();
    m_GBCDPtr = getDataContainerArray()->getPrereqArrayFromPath<DataArray<double>, AbstractFilter>(this, getGBCDArrayPath(), cDims); /* Assigns the shared_ptr<> to an instance variable that is a weak_ptr<> */
    if( NULL != m_GBCDPtr.lock().get() ) /* Validate the Weak Pointer wraps a non-NULL pointer to a DataArray<T> object */
    { m_GBCD = m_GBCDPtr.lock()->getPointer(0); } /* Now assign the raw pointer to data from the DataArray<T> object */
  }

  if (NULL != m_GBCDPtr.lock().get() && getPhaseOfInterest() >= m_GBCDPtr.lock()->getNumberOfTuples())
  {
    QString ss = QObject::tr("The phase index is larger than the number of Ensembles").arg(ClassName());
    setErrorCondition(-1);
    notifyErrorMessage(getHumanLabel(), ss, getErrorCondition());
  }
}
// -----------------------------------------------------------------------------
//
// -----------------------------------------------------------------------------
int AttributeMatrix::writeAttributeArraysToHDF5(hid_t parentId)
{
    int err;
    for(QMap<QString, IDataArray::Pointer>::iterator iter = m_AttributeArrays.begin(); iter != m_AttributeArrays.end(); ++iter)
    {
        IDataArray::Pointer d = iter.value();
        err = d->writeH5Data(parentId, m_TupleDims);
        if(err < 0)
        {
            return err;
        }
    }
    return 0;
}
// -----------------------------------------------------------------------------
//
// -----------------------------------------------------------------------------
int VoxelDataContainerWriter::writeEnsembleData(hid_t dcGid)
{
  std::stringstream ss;
  int err = 0;
  VoxelDataContainer* m = getVoxelDataContainer();

  // Write the Ensemble data
  err = H5Utilities::createGroupsFromPath(H5_ENSEMBLE_DATA_GROUP_NAME, dcGid);
  if(err < 0)
  {
    ss.str("");
    ss << "Error creating HDF Group " << H5_ENSEMBLE_DATA_GROUP_NAME << std::endl;
    setErrorCondition(-66);
    notifyErrorMessage( ss.str(), err);
    H5Gclose(dcGid); // Close the Data Container Group
    return err;
  }
  err = H5Lite::writeStringAttribute(dcGid, H5_ENSEMBLE_DATA_GROUP_NAME, H5_NAME, H5_ENSEMBLE_DATA_DEFAULT);

  hid_t ensembleGid = H5Gopen(dcGid, H5_ENSEMBLE_DATA_GROUP_NAME, H5P_DEFAULT);
  if(err < 0)
  {
    ss.str("");
    ss << "Error opening ensemble Group " << H5_ENSEMBLE_DATA_GROUP_NAME << std::endl;
    setErrorCondition(-67);
    notifyErrorMessage( ss.str(), err);
    H5Gclose(dcGid); // Close the Data Container Group
    return err;
  }
  NameListType names = m->getEnsembleArrayNameList();
  for (NameListType::iterator iter = names.begin(); iter != names.end(); ++iter)
  {
    IDataArray::Pointer array = m->getEnsembleData(*iter);
    err = array->writeH5Data(ensembleGid);
    if(err < 0)
    {
      ss.str("");
      ss << "Error writing Ensemble array '" << *iter << "' to the HDF5 File";
      notifyErrorMessage( ss.str(), err);
      setErrorCondition(err);
      H5Gclose(ensembleGid); // Close the Cell Group
      H5Gclose(dcGid); // Close the Data Container Group
      return err;
    }
  }

  H5Gclose(ensembleGid);

  return err;
}
Example #8
0
// -----------------------------------------------------------------------------
//
// -----------------------------------------------------------------------------
bool VoxelDataContainer::renameFieldData(const std::string &oldname, const std::string &newname)
{
  std::map<std::string, IDataArray::Pointer>::iterator it;
  it =  m_FieldData.find(oldname);
  if ( it == m_FieldData.end() )
  {
	  return false;
  }
  IDataArray::Pointer p = (*it).second;
  p->SetName(newname);
  removeFieldData(oldname);
  addFieldData(newname, p);
  return true;
}
// -----------------------------------------------------------------------------
//
// -----------------------------------------------------------------------------
int VoxelDataContainerWriter::writeFaceData(hid_t dcGid)
{
  std::stringstream ss;
  int err = 0;
  VoxelDataContainer* m = getVoxelDataContainer();

  // Write the Voxel Data
  err = H5Utilities::createGroupsFromPath(H5_FACE_DATA_GROUP_NAME, dcGid);
  if(err < 0)
  {
    ss.str("");
    ss << "Error creating HDF Group " << H5_FACE_DATA_GROUP_NAME << std::endl;
    setErrorCondition(-63);
    notifyErrorMessage( ss.str(), err);
    H5Gclose(dcGid); // Close the Data Container Group
    return err;
  }
  hid_t FaceGroupId = H5Gopen(dcGid, H5_FACE_DATA_GROUP_NAME, H5P_DEFAULT);
  if(err < 0)
  {
    ss.str("");
    ss << "Error writing string attribute to HDF Group " << H5_FACE_DATA_GROUP_NAME << std::endl;
    setErrorCondition(-64);
    notifyErrorMessage( ss.str(), err);
    H5Gclose(dcGid); // Close the Data Container Group
    return err;
  }
  NameListType names = m->getFaceArrayNameList();
  for (NameListType::iterator iter = names.begin(); iter != names.end(); ++iter)
  {
    ss.str("");
    ss << "Writing Face Data '" << *iter << "' to HDF5 File" << std::endl;
    notifyStatusMessage(ss.str());
    IDataArray::Pointer array = m->getFaceData(*iter);
    err = array->writeH5Data(FaceGroupId);
    if(err < 0)
    {
      ss.str("");
      ss << "Error writing array '" << *iter << "' to the HDF5 File";
      notifyErrorMessage( ss.str(), err);
      setErrorCondition(err);
      H5Gclose(FaceGroupId); // Close the Face Group
      H5Gclose(dcGid); // Close the Data Container Group
      return err;
    }
  }
  H5Gclose(FaceGroupId); // Close the Face Group
  return err;
}
Example #10
0
void writeCellVectorData(DataContainer::Pointer dc, const QString& faceAttributeMatrixName, const QString& dataName, const QString& dataType,
                         bool writeBinaryData, bool writeConformalMesh, const QString& vtkAttributeType,
                         FILE* vtkFile, int nT)
{
  IDataArray::Pointer data = dc->getAttributeMatrix(faceAttributeMatrixName)->getAttributeArray(dataName);
  QString buf;
  QTextStream ss(&buf);
  if (NULL != data.get())
  {
    T* m = reinterpret_cast<T*>(data->getVoidPointer(0));
    fprintf(vtkFile, "\n");
    fprintf(vtkFile, "%s %s %s\n", vtkAttributeType.toLatin1().data(), dataName.toLatin1().data(), dataType.toLatin1().data());
    for(int i = 0; i < nT; ++i)
    {
      T s0 = 0x00;
      T s1 = 0x00;
      T s2 = 0x00;
      if(writeBinaryData == true)
      {
        s0 = static_cast<T>(m[i * 3 + 0]);
        s1 = static_cast<T>(m[i * 3 + 1]);
        s2 = static_cast<T>(m[i * 3 + 2]);
        SIMPLib::Endian::FromSystemToBig::convert(s0);
        SIMPLib::Endian::FromSystemToBig::convert(s1);
        SIMPLib::Endian::FromSystemToBig::convert(s2);
        fwrite(&s0, sizeof(T), 1, vtkFile);
        fwrite(&s1, sizeof(T), 1, vtkFile);
        fwrite(&s2, sizeof(T), 1, vtkFile);
        if(false == writeConformalMesh)
        {
          fwrite(&s0, sizeof(T), 1, vtkFile);
          fwrite(&s1, sizeof(T), 1, vtkFile);
          fwrite(&s2, sizeof(T), 1, vtkFile);
        }
      }
      else
      {
        ss << m[i * 3 + 0] << " " << m[i * 3 + 1] << " " << m[i * 3 + 2] << " ";
        if(false == writeConformalMesh)
        {
          ss << m[i * 3 + 0] << " " << m[i * 3 + 1] << " " << m[i * 3 + 2] << " ";
        }
        fprintf(vtkFile, "%s ",  buf.toLatin1().data());
        buf.clear();
        if (i % 25 == 0) { fprintf(vtkFile, "\n"); }
      }
    }
  }
}
// -----------------------------------------------------------------------------
//
// -----------------------------------------------------------------------------
bool AttributeMatrix::validateAttributeArraySizes()
{
    int64_t arraySize = 0;
    int64_t matrixSize = getNumTuples();
    for(QMap<QString, IDataArray::Pointer>::iterator iter = m_AttributeArrays.begin(); iter != m_AttributeArrays.end(); ++iter)
    {
        IDataArray::Pointer d = iter.value();
        arraySize = d->getNumberOfTuples();
        if(arraySize != matrixSize)
        {
            return false;
        }
    }
    return true;
}
Example #12
0
// -----------------------------------------------------------------------------
//
// -----------------------------------------------------------------------------
void WriteImages::dataCheck()
{
  setErrorCondition(0);

  getDataContainerArray()->getPrereqGeometryFromDataContainer<ImageGeom, AbstractFilter>(this, getColorsArrayPath().getDataContainerName());

  QDir dir(getOutputPath());

  if (getOutputPath().isEmpty() == true)
  {
    setErrorCondition(-1003);
    notifyErrorMessage(getHumanLabel(), "The output directory must be set", getErrorCondition());
  }
  else if (dir.exists() == false)
  {
    QString ss = QObject::tr("The output directory path does not exist. DREAM.3D will attempt to create this path during execution");
    notifyWarningMessage(getHumanLabel(), ss, -1);
  }

  IDataArray::Pointer iDa = getDataContainerArray()->getPrereqIDataArrayFromPath<IDataArray, AbstractFilter>(this, getColorsArrayPath());
  if (getErrorCondition() < 0) { return; }

  QVector<size_t> cDims = iDa->getComponentDimensions();

  if (cDims[0] == 1)
  {
    m_ColorsPtr = getDataContainerArray()->getPrereqArrayFromPath<DataArray<uint8_t>, AbstractFilter>(this, getColorsArrayPath(), cDims); /* Assigns the shared_ptr<> to an instance variable that is a weak_ptr<> */
    if (NULL != m_ColorsPtr.lock().get()) /* Validate the Weak Pointer wraps a non-NULL pointer to a DataArray<T> object */
    { m_Colors = m_ColorsPtr.lock()->getPointer(0); } /* Now assign the raw pointer to data from the DataArray<T> object */
  }
  else if (cDims[0] == 3)
  {
    m_ColorsPtr = getDataContainerArray()->getPrereqArrayFromPath<DataArray<uint8_t>, AbstractFilter>(this, getColorsArrayPath(), cDims); /* Assigns the shared_ptr<> to an instance variable that is a weak_ptr<> */
    if (NULL != m_ColorsPtr.lock().get()) /* Validate the Weak Pointer wraps a non-NULL pointer to a DataArray<T> object */
    { m_Colors = m_ColorsPtr.lock()->getPointer(0); } /* Now assign the raw pointer to data from the DataArray<T> object */
  }
  else if (cDims[0] == 4)
  {
    m_ColorsPtr = getDataContainerArray()->getPrereqArrayFromPath<DataArray<uint8_t>, AbstractFilter>(this, getColorsArrayPath(), cDims); /* Assigns the shared_ptr<> to an instance variable that is a weak_ptr<> */
    if (NULL != m_ColorsPtr.lock().get()) /* Validate the Weak Pointer wraps a non-NULL pointer to a DataArray<T> object */
    { m_Colors = m_ColorsPtr.lock()->getPointer(0); } /* Now assign the raw pointer to data from the DataArray<T> object */
  }
  else
  {
    setErrorCondition(-1006);
    notifyErrorMessage(getHumanLabel(), "Number of components must be 1 (grayscale), 3 (RGB) or 4 (ARGB) arrays", getErrorCondition());
  }
}
Example #13
0
// -----------------------------------------------------------------------------
//
// -----------------------------------------------------------------------------
std::vector<int32_t> TriangleOps::findAdjacentTriangles(SurfaceMeshDataContainer* sm,
                                                        int32_t triangleIndex,
                                                        int32_t label)
{
  std::vector<int32_t> adjacentTris;
  // Get the master list of triangles for the mesh
  DREAM3D::SurfaceMesh::FaceList_t::Pointer facesPtr = sm->getFaces();
//  DREAM3D::SurfaceMesh::Face_t* faces = facesPtr->GetPointer(0);
  IDataArray::Pointer flPtr = sm->getFaceData(DREAM3D::FaceData::SurfaceMeshFaceLabels);
  DataArray<int32_t>* faceLabelsPtr = DataArray<int32_t>::SafePointerDownCast(flPtr.get());
  int32_t* faceLabels = faceLabelsPtr->GetPointer(0);

  // Get the Triangle Neighbor Structure
  MeshFaceNeighbors::Pointer triNeighbors = sm->getMeshFaceNeighborLists();

  // For the specific triangle that was passed, get its neighbor list
  uint16_t count = triNeighbors->getNumberOfFaces(triangleIndex);
  int32_t* nList = triNeighbors->getNeighborListPointer(triangleIndex);

  if (count < 3)
  {
    std::cout << "Triangle Neighbor List had only " << count << " neighbors. Must be at least 3." << std::endl;
    BOOST_ASSERT(false);
  }
  else if (count == 3) // This triangle only has 3 neighbors so we are assuming all three have the same label set.
  {
    for (uint16_t n = 0; n < count; ++n)
    {
      adjacentTris.push_back(nList[n]);
    }
  }
  else
  {
    // Iterate over the indices to find triangles that match the label and are NOT the current triangle index
    for (uint16_t n = 0; n < count; ++n)
    {
      int32_t fl_0 = faceLabels[nList[n]*2];
      int32_t fl_1 = faceLabels[nList[n]*2 + 1];
      if ( (fl_0 == label || fl_1 == label)  && (nList[n] != triangleIndex) )
      {
        //  std::cout << "    Found Adjacent Triangle: " << t->tIndex << std::endl;
        adjacentTris.push_back(nList[n]);
        // ++index;
      }
    }
  }
  return adjacentTris;
}
    /**
     * @brief copyData This method copies all data from the <b>sourceArray</b> into
     * the current array starting at the target destination tuple offset value.
     *
     * For example if the DataArray has 10 tuples and the destTupleOffset = 5 then
     * then source data will be copied into the destination array starting at
     * destination tuple 5. In psuedo code it would be the following:
     * @code
     *  destArray[5] = sourceArray[0];
     *  destArray[6] = sourceArray[1];
     *  .....
     * @endcode
     * @param destTupleOffset
     * @param sourceArray
     * @return
     */
    bool copyData(size_t destTupleOffset, IDataArray::Pointer sourceArray)
    {

      if(destTupleOffset >= m_Array.size()) { return false; }
      if(!sourceArray->isAllocated()) { return false; }
      if(sourceArray->getNumberOfComponents() != getNumberOfComponents()) { return false; }

      Self* source = dynamic_cast<Self*>(sourceArray.get());
      size_t sourceNTuples = source->getNumberOfTuples();

      for(size_t i = 0; i < sourceNTuples; i++)
      {
        m_Array[destTupleOffset + i] = source->getValue(i);
      }
      return true;
    }
// -----------------------------------------------------------------------------
//
// -----------------------------------------------------------------------------
void BoundaryPhaseWidget::extractStatsData(AttributeMatrix::Pointer attrMat, int index)
{

  setPhaseIndex(index);

  IDataArray::Pointer iDataArray = attrMat->getAttributeArray(DREAM3D::EnsembleData::CrystalStructures);
  unsigned int* attributeArray = boost::dynamic_pointer_cast< UInt32ArrayType >(iDataArray)->getPointer(0);
  m_CrystalStructure = attributeArray[index];

  iDataArray = attrMat->getAttributeArray(DREAM3D::EnsembleData::PhaseTypes);
  attributeArray = boost::dynamic_pointer_cast< UInt32ArrayType >(iDataArray)->getPointer(0);
  m_PhaseType = attributeArray[index];

  iDataArray = attrMat->getAttributeArray(DREAM3D::EnsembleData::Statistics);
  StatsDataArray* statsDataArray = StatsDataArray::SafeObjectDownCast<IDataArray*, StatsDataArray*>(iDataArray.get());
  if (statsDataArray == NULL)
  {
    return;
  }
  StatsData::Pointer statsData = statsDataArray->getStatsData(index);
  BoundaryStatsData* boundaryStatsData = BoundaryStatsData::SafePointerDownCast(statsData.get());

  m_PhaseFraction = boundaryStatsData->getPhaseFraction();

}
void findHistogram(IDataArray::Pointer inputData, int32_t* ensembleArray, int32_t* eIds, int NumberOfBins, bool removeBiasedFeatures, bool* biasedFeatures)
{
  DataArray<T>* featureArray = DataArray<T>::SafePointerDownCast(inputData.get());
  if (NULL == featureArray)
  {
    return;
  }

  T* fPtr = featureArray->getPointer(0);
  size_t numfeatures = featureArray->getNumberOfTuples();

  int32_t bin;
  int32_t ensemble;
  float min = 1000000.0f;
  float max = 0.0f;
  float value;
  for (size_t i = 1; i < numfeatures; i++)
  {
    value = fPtr[i];
    if(value > max) { max = value; }
    if(value < min) { min = value; }
  }
  float stepsize = (max - min) / NumberOfBins;

  for (size_t i = 1; i < numfeatures; i++)
  {
    if(removeBiasedFeatures == false || biasedFeatures[i] == false)
    {
      ensemble = eIds[i];
      bin = (fPtr[i] - min) / stepsize;
      if(bin >= NumberOfBins) { bin = NumberOfBins - 1; }
      ensembleArray[(NumberOfBins * ensemble) + bin]++;
    }
  }
}
void InitializeData::initializeArrayWithReals(IDataArray::Pointer p, int64_t dims[3])
{
  T rangeMin;
  T rangeMax;
  if (m_InitType == RandomWithRange)
  {
    rangeMin = static_cast<T>(m_InitRange.first);
    rangeMax = static_cast<T>(m_InitRange.second);
  }
  else
  {
    rangeMin = std::numeric_limits<T>().min();
    rangeMax = std::numeric_limits<T>().max();
  }

  typedef boost::mt19937 RandomNumberGenerator;
  typedef boost::uniform_real<T> RealDistribution;
  typedef boost::variate_generator<RandomNumberGenerator&, RealDistribution> RealGenerator;

  std::shared_ptr<RealDistribution> distribution = std::shared_ptr<RealDistribution>(new RealDistribution(rangeMin, rangeMax));
  std::shared_ptr<RandomNumberGenerator> randomNumberGenerator = std::shared_ptr<RandomNumberGenerator>(new RandomNumberGenerator);
  randomNumberGenerator->seed(static_cast<size_t>(QDateTime::currentMSecsSinceEpoch())); // seed with the current time
  std::shared_ptr<RealGenerator> realGeneratorPtr = std::shared_ptr<RealGenerator>(new RealGenerator(*randomNumberGenerator, *distribution));
  RealGenerator& realGenerator = *realGeneratorPtr;

  for (int32_t k = m_ZMin; k < m_ZMax + 1; k++)
  {
    for (int32_t j = m_YMin; j < m_YMax + 1; j++)
    {
      for (int32_t i = m_XMin; i < m_XMax + 1; i++)
      {
        size_t index = (k * dims[0] * dims[1]) + (j * dims[0]) + i;

        if (m_InitType == Manual)
        {
          T num = static_cast<T>(m_InitValue);
          p->initializeTuple(index, &num);
        }
        else
        {
          T temp = realGenerator();
          p->initializeTuple(index, &temp);
        }
      }
    }
  }
}
// -----------------------------------------------------------------------------
//
// -----------------------------------------------------------------------------
AttributeMatrix::Pointer AttributeMatrix::deepCopy()
{
    AttributeMatrix::Pointer newAttrMat = AttributeMatrix::New(getTupleDimensions(), getName(), getType());

    for(QMap<QString, IDataArray::Pointer>::iterator iter = m_AttributeArrays.begin(); iter != m_AttributeArrays.end(); ++iter)
    {
        IDataArray::Pointer d = iter.value();
        IDataArray::Pointer new_d = d->deepCopy();
        if (new_d.get() == NULL)
        {
            return AttributeMatrix::NullPointer();
        }
        newAttrMat->addAttributeArray(new_d->getName(), new_d);
    }

    return newAttrMat;
}
// -----------------------------------------------------------------------------
//
// -----------------------------------------------------------------------------
void AttributeMatrix::resizeAttributeArrays(QVector<size_t> tDims)
{
    // int success = 0;
    m_TupleDims = tDims;
    size_t numTuples = m_TupleDims[0];
    for(int i = 1; i < m_TupleDims.size(); i++)
    {
        numTuples *= m_TupleDims[i];
    }

    for(QMap<QString, IDataArray::Pointer>::iterator iter = m_AttributeArrays.begin(); iter != m_AttributeArrays.end(); ++iter)
    {
        //std::cout << "Resizing Array '" << (*iter).first << "' : " << success << std::endl;
        IDataArray::Pointer d = iter.value();
        d->resize(numTuples);
    }
}
void writeCellVectorData(DataContainer::Pointer dc, const QString& faceAttributeMatrixName, const QString& dataName, const QString& dataType,
                         bool writeBinaryData, const QString& vtkAttributeType,
                         FILE* vtkFile, QMap<int32_t, int32_t>& featureIds)
{
  TriangleGeom::Pointer triangleGeom = dc->getGeometryAs<TriangleGeom>();

  int64_t numTriangles = triangleGeom->getNumberOfTris();

  IDataArray::Pointer data = dc->getAttributeMatrix(faceAttributeMatrixName)->getAttributeArray(dataName);
  QString ss;
  if (NULL != data.get())
  {
    T* m = reinterpret_cast<T*>(data->getVoidPointer(0));
    fprintf(vtkFile, "\n");
    fprintf(vtkFile, "%s %s %s\n", vtkAttributeType.toLatin1().data(), dataName.toLatin1().data(), dataType.toLatin1().data());
    for(int i = 0; i < numTriangles; ++i)
    {
      T s0 = 0x00;
      T s1 = 0x00;
      T s2 = 0x00;
      if(writeBinaryData == true)
      {
        s0 = static_cast<T>(m[i * 3 + 0]);
        s1 = static_cast<T>(m[i * 3 + 1]);
        s2 = static_cast<T>(m[i * 3 + 2]);
        SIMPLib::Endian::FromSystemToBig::convert(s0);
        SIMPLib::Endian::FromSystemToBig::convert(s1);
        SIMPLib::Endian::FromSystemToBig::convert(s2);
        fwrite(&s0, sizeof(T), 1, vtkFile);
        fwrite(&s1, sizeof(T), 1, vtkFile);
        fwrite(&s2, sizeof(T), 1, vtkFile);

      }
      else
      {

        ss << m[i * 3 + 0] << " " << m[i * 3 + 1] << " " << m[i * 3 + 2] << " ";

        fprintf(vtkFile, "%s ", ss.toLatin1().data());
        if (i % 25 == 0) { fprintf(vtkFile, "\n"); }
      }
    }
  }
}
  IDataArray::Pointer readH5Dataset(hid_t locId,
                                    const QString& datasetPath,
                                    const QVector<size_t>& tDims,
                                    const QVector<size_t>& cDims)
  {
    herr_t err = -1;
    IDataArray::Pointer ptr;

    ptr = DataArray<T>::CreateArray(tDims, cDims, datasetPath);

    T* data = (T*)(ptr->getVoidPointer(0));
    err = QH5Lite::readPointerDataset(locId, datasetPath, data);
    if(err < 0)
    {
      qDebug() << "readH5Data read error: " << __FILE__ << "(" << __LINE__ << ")" ;
      ptr = IDataArray::NullPointer();
    }
    return ptr;
  }
// -----------------------------------------------------------------------------
//
// -----------------------------------------------------------------------------
QString AttributeMatrix::writeXdmfAttributeData(IDataArray::Pointer array, const QString& centering, const QString& dataContainerName, const QString& hdfFileName, const uint8_t gridType)
{
    QString xdmfText;
    QTextStream out(&xdmfText);

    int precision = 0;
    QString xdmfTypeName;
    array->getXdmfTypeAndSize(xdmfTypeName, precision);
    if (0 == precision)
    {
        out << "<!-- " << array->getName() << " has unkown type or unsupported type or precision for XDMF to understand" << " -->" << "\n";
        return xdmfText;
    }
    int numComp = array->getNumberOfComponents();
    QString attrType = "";
    if(numComp == 1)
    {
        attrType = "Scalar";
    }
    //we are assuming a component of 2 is for scalars on either side of a single object (ie faceIds)
    if(numComp == 2)
    {
        attrType = "Scalar";
    }
    if(numComp == 3)
    {
        attrType = "Vector";
    }
    if(numComp == 6)
    {
        attrType = "Vector";
    }
    //  if(numComp == 6) { attrType = "Tensor6"; }
    if(numComp == 9)
    {
        attrType = "Tensor";
    }
    QString block = writeXdmfAttributeDataHelper(numComp, attrType, dataContainerName, array, centering, precision, xdmfTypeName, hdfFileName, gridType);

    out << block;

    return xdmfText;
}
// -----------------------------------------------------------------------------
//
// -----------------------------------------------------------------------------
int AttributeMatrix::addAttributeArray(const QString& name, IDataArray::Pointer data)
{
    if (data->getName().compare(name) != 0)
    {
        qDebug() << "Adding Attribute Array with different array name than key name" << "\n";
        qDebug() << "Key name: " << name << "\n";
        qDebug() << "Array Name:" << data->getName() << "\n";
        data->setName(name);
    }
    if(getNumTuples() != data->getNumberOfTuples())
    {
        qDebug() << "AttributeMatrix::Name: " << getName() << "  dataArray::name:  " << data->getName() << " Type: " << data->getTypeAsString();
        qDebug() << "getNumTuples(): " << getNumTuples() << "  data->getNumberOfTuples(): " << data->getNumberOfTuples();
    }
    Q_ASSERT(getNumTuples() == data->getNumberOfTuples());

    m_AttributeArrays[name] = data;
    return 0;
}
Example #24
0
 virtual IDataArray::Pointer reorderCopy(QVector<size_t> newOrderMap)
 {
   if(newOrderMap.size() != static_cast<QVector<size_t>::size_type>(getNumberOfTuples()))
   {
     return IDataArray::NullPointer();
   }
   IDataArray::Pointer daCopy = createNewArray(getNumberOfTuples(), getComponentDimensions(), getName(), m_IsAllocated);
   if(m_IsAllocated == true)
   {
     daCopy->initializeWithZeros();
     size_t chunkSize = getNumberOfComponents() * sizeof(T);
     for(size_t i = 0; i < getNumberOfTuples(); i++)
     {
       T* src = getPointer(i * getNumberOfComponents());
       void* dest = daCopy->getVoidPointer(newOrderMap[i] * getNumberOfComponents());
       ::memcpy(dest, src, chunkSize);
     }
   }
   return daCopy;
 }
Example #25
0
void writeCellScalarData(DataContainer::Pointer dc, const QString& faceAttributeMatrixName, const QString& dataName, const QString& dataType,
                         bool writeBinaryData, bool writeConformalMesh, FILE* vtkFile, int nT)
{
  // Write the Feature Face ID Data to the file
  IDataArray::Pointer data = dc->getAttributeMatrix(faceAttributeMatrixName)->getAttributeArray(dataName);
  QString buf;
  QTextStream ss(&buf);
  if (NULL != data.get())
  {
    T* m = reinterpret_cast<T*>(data->getVoidPointer(0));
    fprintf(vtkFile, "\n");
    fprintf(vtkFile, "SCALARS %s %s 1\n", dataName.toLatin1().data(), dataType.toLatin1().data());
    fprintf(vtkFile, "LOOKUP_TABLE default\n");
    for(int i = 0; i < nT; ++i)
    {
      T swapped = 0x00;
      if(writeBinaryData == true)
      {
        swapped = static_cast<T>(m[i]);
        SIMPLib::Endian::FromSystemToBig::convert(swapped);
        fwrite(&swapped, sizeof(T), 1, vtkFile);
        if(false == writeConformalMesh)
        {
          fwrite(&swapped, sizeof(T), 1, vtkFile);
        }
      }
      else
      {

        ss << m[i] << " ";
        if(false == writeConformalMesh)
        {
          ss << m[i] << " ";
        }
        fprintf(vtkFile, "%s", buf.toLatin1().data());
        buf.clear();
        if (i % 50 == 0) { fprintf(vtkFile, "\n"); }
      }
    }
  }
}
// -----------------------------------------------------------------------------
//
// -----------------------------------------------------------------------------
bool ModifiedLambertProjectionArray::copyData(size_t destTupleOffset, IDataArray::Pointer sourceArray)
{
  if(!m_IsAllocated) { return false; }
  if(0 == m_ModifiedLambertProjectionArray.size()) { return false; }
  if(destTupleOffset >= m_ModifiedLambertProjectionArray.size()) { return false; }
  if(!sourceArray->isAllocated()) { return false; }
  Self* source = dynamic_cast<Self*>(sourceArray.get());

  if(sourceArray->getNumberOfComponents() != getNumberOfComponents()) { return false; }

  if( sourceArray->getNumberOfTuples()*sourceArray->getNumberOfComponents() + destTupleOffset*getNumberOfComponents() > m_ModifiedLambertProjectionArray.size() ) { return false; }

  size_t sourceNTuples = source->getNumberOfTuples();

  for(size_t i = 0; i < sourceNTuples; i++)
  {
    m_ModifiedLambertProjectionArray[destTupleOffset + i] = (*source)[i];
  }

  return true;
}
Example #27
0
void writePointVectorData(DataContainer::Pointer dc, const QString& vertexAttributeMatrixName, const QString& dataName, const QString& dataType,
                          bool writeBinaryData, bool writeConformalMesh, const QString& vtkAttributeType,
                          FILE* vtkFile, int nT)
{
  IDataArray::Pointer data = dc->getAttributeMatrix(vertexAttributeMatrixName)->getAttributeArray(dataName);
  QString ss;
  if (NULL != data.get())
  {
    T* m = reinterpret_cast<T*>(data->getVoidPointer(0));
    fprintf(vtkFile, "\n");
    fprintf(vtkFile, "%s %s %s\n", vtkAttributeType.toLatin1().data(), dataName.toLatin1().data(), dataType.toLatin1().data());
    for(int i = 0; i < nT; ++i)
    {
      T s0 = 0x00;
      T s1 = 0x00;
      T s2 = 0x00;
      if(writeBinaryData == true)
      {
        s0 = static_cast<T>(m[i * 3 + 0]);
        s1 = static_cast<T>(m[i * 3 + 1]);
        s2 = static_cast<T>(m[i * 3 + 2]);
        SIMPLib::Endian::FromSystemToBig::convert(s0);
        SIMPLib::Endian::FromSystemToBig::convert(s1);
        SIMPLib::Endian::FromSystemToBig::convert(s2);
        fwrite(&s0, sizeof(T), 1, vtkFile);
        fwrite(&s1, sizeof(T), 1, vtkFile);
        fwrite(&s1, sizeof(T), 1, vtkFile);
      }
      else
      {

        ss = QString::number(m[i * 3 + 0]) + " " + QString::number(m[i * 3 + 1]) + " " + QString::number(m[i * 3 + 2]) + " ";
        fprintf(vtkFile, "%s ", ss.toLatin1().data());
        //if (i%50 == 0)
        { fprintf(vtkFile, "\n"); }
      }

    }
  }
}
Example #28
0
// -----------------------------------------------------------------------------
//
// -----------------------------------------------------------------------------
void InitializeData::execute()
{
  setErrorCondition(0);
  dataCheck();
  if(getErrorCondition() < 0) { return; }

  DataContainer::Pointer m = getDataContainerArray()->getDataContainer(m_CellAttributeMatrixPath.getDataContainerName());

  size_t udims[3] =
  { 0, 0, 0 };
  m->getGeometryAs<ImageGeom>()->getDimensions(udims);
#if (CMP_SIZEOF_SIZE_T == 4)
  typedef int32_t DimType;
#else
  typedef int64_t DimType;
#endif
  DimType dims[3] =
  { static_cast<DimType>(udims[0]), static_cast<DimType>(udims[1]), static_cast<DimType>(udims[2]), };

  int index;
  QString attrMatName = m_CellAttributeMatrixPath.getAttributeMatrixName();
  QList<QString> voxelArrayNames = m->getAttributeMatrix(attrMatName)->getAttributeArrayNames();
  for (int32_t k = m_ZMin; k < m_ZMax + 1; k++)
  {
    for (int32_t j = m_YMin; j < m_YMax + 1; j++)
    {
      for (int32_t i = m_XMin; i < m_XMax + 1; i++)
      {
        index = (k * dims[0] * dims[1]) + (j * dims[0]) + i;
        for (QList<QString>::iterator iter = voxelArrayNames.begin(); iter != voxelArrayNames.end(); ++iter)
        {
          IDataArray::Pointer p = m->getAttributeMatrix(attrMatName)->getAttributeArray(*iter);
          p->initializeTuple(index, 0);
        }
      }
    }
  }

  notifyStatusMessage(getHumanLabel(), "Complete");
}
// -----------------------------------------------------------------------------
//
// -----------------------------------------------------------------------------
int AttributeMatrix::addAttributeArrayFromHDF5Path(hid_t gid, QString name, bool preflight)
{
    int err = 0;
    QString classType;
    QH5Lite::readStringAttribute(gid, name, DREAM3D::HDF5::ObjectType, classType);
    //   qDebug() << groupName << " Array: " << *iter << " with C++ ClassType of " << classType << "\n";
    IDataArray::Pointer dPtr = IDataArray::NullPointer();

    if(classType.startsWith("DataArray") == true)
    {
        dPtr = H5DataArrayReader::ReadIDataArray(gid, name, preflight);
        if(preflight == true)
        {
            dPtr->resize(getNumTuples());
        }
    }
    else if(classType.compare("StringDataArray") == 0)
    {
        dPtr = H5DataArrayReader::ReadStringDataArray(gid, name, preflight);
        if (preflight == true)
        {
            dPtr->resize(getNumTuples());
        }
    }
    else if(classType.compare("vector") == 0)
    {

    }
    else if(classType.compare("NeighborList<T>") == 0)
    {
        dPtr = H5DataArrayReader::ReadNeighborListData(gid, name, preflight);
        if (preflight == true)
        {
            dPtr->resize(getNumTuples());
        }
    }
    else if ( name.compare(DREAM3D::EnsembleData::Statistics) == 0)
    {
        StatsDataArray::Pointer statsData = StatsDataArray::New();
        statsData->setName(DREAM3D::EnsembleData::Statistics);
        statsData->readH5Data(gid);
        dPtr = statsData;
        if (preflight == true)
        {
            dPtr->resize(getNumTuples());
        }
    }

    if (NULL != dPtr.get())
    {
        addAttributeArray(dPtr->getName(), dPtr);
    }

    return err;
}
Example #30
0
// -----------------------------------------------------------------------------
//
// -----------------------------------------------------------------------------
void  AddBadData::add_noise()
{
  notifyStatusMessage(getHumanLabel(), "Adding Noise");
  DREAM3D_RANDOMNG_NEW()

  DataContainer::Pointer m = getDataContainerArray()->getDataContainer(getGBEuclideanDistancesArrayPath().getDataContainerName());

  QString attMatName = getGBEuclideanDistancesArrayPath().getAttributeMatrixName();
  QList<QString> voxelArrayNames = m->getAttributeMatrix(attMatName)->getAttributeArrayNames();

  float random = 0.0f;
  size_t totalPoints = m->getGeometryAs<ImageGeom>()->getNumberOfElements();
  for (size_t i = 0; i < totalPoints; ++i)
  {
    if (m_BoundaryNoise == true && m_GBEuclideanDistances[i] < 1)
    {
      random = static_cast<float>( rg.genrand_res53() );
      if (random < m_BoundaryVolFraction)
      {
        for (QList<QString>::iterator iter = voxelArrayNames.begin(); iter != voxelArrayNames.end(); ++iter)
        {
          IDataArray::Pointer p = m->getAttributeMatrix(attMatName)->getAttributeArray(*iter);
          p->initializeTuple(i, 0);
        }
      }
    }
    if (m_PoissonNoise == true)
    {
      random = static_cast<float>( rg.genrand_res53() );
      if (random < m_PoissonVolFraction)
      {
        for (QList<QString>::iterator iter = voxelArrayNames.begin(); iter != voxelArrayNames.end(); ++iter)
        {
          IDataArray::Pointer p = m->getAttributeMatrix(attMatName)->getAttributeArray(*iter);
          p->initializeTuple(i, 0);
        }
      }
    }
  }
}