bool LayeredConstruction_Impl::insertLayer(unsigned layerIndex,
const Material& material)
{
OS_ASSERT(material.model() == model());
layerIndex = mf_clearNullLayers(layerIndex);
unsigned n = numLayers();
MaterialVector layers = this->layers();
MaterialVector::iterator layersBegin = layers.begin();
MaterialVector::iterator layersEnd = layers.end();
MaterialVector::iterator insertAtIt = layersBegin;
while ((static_cast<unsigned>(insertAtIt - layersBegin) < layerIndex) &&
(insertAtIt != layersEnd))
{ ++insertAtIt; }
layers.insert(insertAtIt, material);
OS_ASSERT(layers.size() == ++n);
if ((model().strictnessLevel() < StrictnessLevel::Final) ||
LayeredConstruction::layersAreValid(layers))
{
IdfExtensibleGroup idfGroup = insertExtensibleGroup(layerIndex,StringVector());
OS_ASSERT(!idfGroup.empty());
ModelExtensibleGroup group = idfGroup.cast<ModelExtensibleGroup>();
bool ok = group.setPointer(0,material.handle());
OS_ASSERT(ok);
return true;
}
return false;
}
TEST_F(ModelFixture, ConstructionWithInternalSource_ReverseConstructionWithInternalSource_2)
{
Model model;
// Create some materials
StandardOpaqueMaterial exterior(model);
StandardOpaqueMaterial interior(model);
OpaqueMaterialVector layers;
layers.push_back(exterior);
layers.push_back(interior);
ConstructionWithInternalSource construction(layers);
EXPECT_EQ(1u, model.getModelObjects<ConstructionWithInternalSource>().size());
ConstructionWithInternalSource construction2 = construction.reverseConstructionWithInternalSource();
EXPECT_EQ(2u, model.getModelObjects<ConstructionWithInternalSource>().size());
EXPECT_NE(construction.handle(), construction2.handle());
MaterialVector testLayers = construction2.layers();
ASSERT_EQ(static_cast<unsigned>(2),testLayers.size());
EXPECT_TRUE(testLayers[0] == interior);
EXPECT_TRUE(testLayers[1] == exterior);
ConstructionWithInternalSource construction3 = construction.reverseConstructionWithInternalSource();
EXPECT_EQ(2u, model.getModelObjects<ConstructionWithInternalSource>().size());
EXPECT_NE(construction.handle(), construction3.handle());
EXPECT_EQ(construction2.handle(), construction3.handle());
}
TEST_F(ModelFixture, Construction_InsertLayers)
{
Model model;
// Create some materials
StandardOpaqueMaterial exterior(model);
AirGap air(model);
StandardOpaqueMaterial interior(model);
Construction construction(model);
try{
// these functions should not throw, just return false
EXPECT_TRUE(construction.insertLayer(0, exterior));
EXPECT_TRUE(construction.insertLayer(1, air));
EXPECT_TRUE(construction.insertLayer(2, interior));
}catch(const std::exception&){
}
// Get layers
MaterialVector testLayers = construction.layers();
ASSERT_EQ(static_cast<unsigned>(3),testLayers.size());
EXPECT_TRUE(testLayers[0] == exterior);
EXPECT_TRUE(testLayers[1] == air);
EXPECT_TRUE(testLayers[2] == interior);
}
TEST_F(ModelFixture, Construction_Layers)
{
Model model;
// Create some materials
StandardOpaqueMaterial exterior(model);
AirGap air(model);
StandardOpaqueMaterial interior(model);
OpaqueMaterialVector layers;
layers.push_back(exterior);
layers.push_back(air);
layers.push_back(interior);
Construction construction(layers);
// Get layers
MaterialVector testLayers = construction.layers();
ASSERT_EQ(static_cast<unsigned>(3),testLayers.size());
EXPECT_TRUE(testLayers[0] == exterior);
EXPECT_TRUE(testLayers[1] == air);
EXPECT_TRUE(testLayers[2] == interior);
// construct by clone
Model modelClone = model.clone().cast<Model>();
EXPECT_EQ(static_cast<unsigned>(4),modelClone.objects().size());
ConstructionVector constructions = modelClone.getModelObjects<Construction>();
ASSERT_EQ(static_cast<unsigned>(1),constructions.size());
construction = constructions[0];
EXPECT_FALSE(construction.model() == model);
EXPECT_TRUE(construction.iddObject().type() ==
IddObjectType::OS_Construction);
}
MaterialVector MaterialManager::load(const std::string &filepath)
{
if ( !filepath.empty() )
{
// We must find a MaterialLoader able to load this file.
for ( auto it = iFactory.getLoaders().begin(); it != iFactory.getLoaders().end(); it++ )
{
MaterialLoader* loader = it->second.get();
if ( loader )
{
if ( loader->isLoadable(filepath) )
{
// Found a loader. Load the Materials.
MaterialHolderList materials = loader->load(filepath);
if ( !materials.empty() )
{
// Registers every Loader to the Manager and to the return Vector.
MaterialVector ret;
for ( MaterialHolder& holder : materials )
{
iMaterials.add(holder);
ret.push_back(Material(holder));
}
return ret;
}
else
{
#ifdef GreIsDebugMode
GreDebugPretty() << "File '" << filepath << "' doesn't seem to contain any Material." << std::endl;
#endif
return MaterialVector();
}
}
}
}
#ifdef GreIsDebugMode
GreDebugPretty() << "File '" << filepath << "' is not loadable by any MaterialLoader." << std::endl;
#endif
return MaterialVector();
}
else
{
#ifdef GreIsDebugMode
GreDebugPretty() << "'filepath' is empty." << std::endl;
#endif
return MaterialVector();
}
}
void CSobeyView::ComputerTimeLineLength(MaterialVector& timeLine)
{
m_timeLineLength = 0;
if (timeLine.empty())
return;
for (MaterialVector::iterator it = timeLine.begin(); it != timeLine.end(); ++it)
{
m_timeLineLength += abs(it->endTime - it->beginTime);
}
}
boost::optional<IdfObject> ForwardTranslator::translateConstruction( Construction & modelObject )
{
IdfObject construction( openstudio::IddObjectType::Construction );
m_idfObjects.push_back(construction);
for (LifeCycleCost lifeCycleCost : modelObject.lifeCycleCosts()){
translateAndMapModelObject(lifeCycleCost);
}
construction.setName(modelObject.name().get());
MaterialVector layers = modelObject.layers();
unsigned fieldIndex = 1;
for(unsigned layerIndex = 0; layerIndex < layers.size(); ++layerIndex ) {
Material material = layers[layerIndex];
translateAndMapModelObject(material);
construction.setString(fieldIndex++, material.name().get());
}
return boost::optional<IdfObject>(construction);
}
void CSobeyView::ComputerTimeLineRect(MaterialVector& timeLine)
{
ComputerTimeLineLength(timeLine);
m_timeLineRect.clear();
if (timeLine.empty())
return;
int top = 10;
int left = 10;
int width = 0;
int height = 50;
CRect windowRect;
GetWindowRect(&windowRect);
// 计算出窗体的大小作为比率
int base = windowRect.right - windowRect.left - 20;
for (MaterialVector::iterator it = timeLine.begin(); it != timeLine.end(); ++it)
{
left += width + 1;
// 素材的宽度等于素材时间长度和时间线总长的比值乘以窗体大小
width = abs(it->endTime - it->beginTime) * base / m_timeLineLength;
m_timeLineRect.push_back(CRect(left, top, left + width, top + height));
}
}
TEST_F(ModelFixture, ConstructionWithInternalSource_Layers)
{
Model model;
// Create some materials
StandardOpaqueMaterial exterior(model);
AirGap air(model);
StandardOpaqueMaterial interior(model);
MaterialVector layers;
layers.push_back(exterior);
layers.push_back(air);
layers.push_back(interior);
ConstructionWithInternalSource construction(model);
EXPECT_TRUE(construction.setLayers(layers));
// Get layers
MaterialVector testLayers = construction.layers();
ASSERT_EQ(static_cast<unsigned>(3),testLayers.size());
EXPECT_TRUE(testLayers[0] == exterior);
EXPECT_TRUE(testLayers[1] == air);
EXPECT_TRUE(testLayers[2] == interior);
}
TEST_F(ModelFixture, Material)
{
Model model;
StandardOpaqueMaterial exterior(model);
MaterialVector materials = model.getModelObjects<Material>();
ASSERT_EQ(static_cast<unsigned>(1), materials.size());
StandardsInformationMaterialVector materialInformations = model.getModelObjects<StandardsInformationMaterial>();
ASSERT_EQ(static_cast<unsigned>(0), materialInformations.size());
{
Model testModel;
exterior.clone(testModel);
materials = model.getModelObjects<Material>();
ASSERT_EQ(static_cast<unsigned>(1), materials.size());
materialInformations = model.getModelObjects<StandardsInformationMaterial>();
ASSERT_EQ(static_cast<unsigned>(0), materialInformations.size());
materials = testModel.getModelObjects<Material>();
ASSERT_EQ(static_cast<unsigned>(1), materials.size());
materialInformations = testModel.getModelObjects<StandardsInformationMaterial>();
ASSERT_EQ(static_cast<unsigned>(0), materialInformations.size());
}
StandardsInformationMaterial info = exterior.standardsInformation();
{
Model testModel;
exterior.clone(testModel);
materials = model.getModelObjects<Material>();
ASSERT_EQ(static_cast<unsigned>(1), materials.size());
materialInformations = model.getModelObjects<StandardsInformationMaterial>();
ASSERT_EQ(static_cast<unsigned>(1), materialInformations.size());
materials = testModel.getModelObjects<Material>();
ASSERT_EQ(static_cast<unsigned>(1), materials.size());
materialInformations = testModel.getModelObjects<StandardsInformationMaterial>();
ASSERT_EQ(static_cast<unsigned>(1), materialInformations.size());
}
{
Model testModel;
info.clone(testModel);
materials = model.getModelObjects<Material>();
ASSERT_EQ(static_cast<unsigned>(1), materials.size());
materialInformations = model.getModelObjects<StandardsInformationMaterial>();
ASSERT_EQ(static_cast<unsigned>(1), materialInformations.size());
materials = testModel.getModelObjects<Material>();
ASSERT_EQ(static_cast<unsigned>(0), materials.size());
materialInformations = testModel.getModelObjects<StandardsInformationMaterial>();
ASSERT_EQ(static_cast<unsigned>(1), materialInformations.size());
}
StandardOpaqueMaterial exteriorClone = exterior.clone().cast<StandardOpaqueMaterial>();
materials = model.getModelObjects<Material>();
ASSERT_EQ(static_cast<unsigned>(2), materials.size());
materialInformations = model.getModelObjects<StandardsInformationMaterial>();
ASSERT_EQ(static_cast<unsigned>(2), materialInformations.size());
}
ConstructionWithInternalSource ConstructionWithInternalSource_Impl::reverseConstructionWithInternalSource() const
{
MaterialVector reverseLayers(this->layers());
std::reverse(reverseLayers.begin(), reverseLayers.end());
int numLayers = (int)this->numLayers();
int reverseSourcePresentAfterLayerNumber = numLayers - this->sourcePresentAfterLayerNumber();
int reverseTemperatureCalculationRequestedAfterLayerNumber = numLayers - this->temperatureCalculationRequestedAfterLayerNumber();
int dimensionsForTheCTFCalculation = this->dimensionsForTheCTFCalculation();
double tubeSpacing = this->tubeSpacing();
Model model = this->model();
for (const ConstructionWithInternalSource& other : model.getConcreteModelObjects<ConstructionWithInternalSource>()) {
if (other.sourcePresentAfterLayerNumber() != reverseSourcePresentAfterLayerNumber){
continue;
}
if (other.temperatureCalculationRequestedAfterLayerNumber() != reverseTemperatureCalculationRequestedAfterLayerNumber){
continue;
}
if (other.dimensionsForTheCTFCalculation() != dimensionsForTheCTFCalculation){
continue;
}
if (other.tubeSpacing() != tubeSpacing){
continue;
}
MaterialVector layers = other.layers();
if (layers.size() != reverseLayers.size()){
continue;
}
bool test = true;
for (unsigned i = 0; i < layers.size(); ++i){
if (layers[i].handle() != reverseLayers[i].handle()){
test = false;
break; // break out of loop over layers
}
}
if (test){
return other;
}
}
// TODO: this should also copy (and modify) standards information object
// no match, make one
ConstructionWithInternalSource result(model);
result.setName(this->name().get() + " Reversed");
result.setSourcePresentAfterLayerNumber(reverseSourcePresentAfterLayerNumber);
result.setTemperatureCalculationRequestedAfterLayerNumber(reverseTemperatureCalculationRequestedAfterLayerNumber);
result.setDimensionsForTheCTFCalculation(dimensionsForTheCTFCalculation);
result.setTubeSpacing(tubeSpacing);
result.setLayers(reverseLayers);
return result;
}
TEST_F(ModelFixture, ConstructionWithInternalSource_FromLayers)
{
Model model;
// Create some materials
StandardOpaqueMaterial exterior(model);
StandardOpaqueMaterial interior(model);
OpaqueMaterialVector layers;
EXPECT_EQ(0, model.getModelObjects<ConstructionWithInternalSource>().size());
EXPECT_EQ(0, layers.size());
EXPECT_THROW((ConstructionWithInternalSource(layers)), std::exception);
EXPECT_EQ(0, model.getModelObjects<ConstructionWithInternalSource>().size());
layers.push_back(exterior);
EXPECT_EQ(1u, layers.size());
EXPECT_THROW((ConstructionWithInternalSource(layers)), std::exception);
EXPECT_EQ(0, model.getModelObjects<ConstructionWithInternalSource>().size());
layers.push_back(interior);
EXPECT_EQ(2u, layers.size());
ConstructionWithInternalSource construction(layers);
EXPECT_EQ(2u, construction.numLayers());
EXPECT_EQ(2u, construction.layers().size());
EXPECT_EQ(1, construction.sourcePresentAfterLayerNumber());
EXPECT_EQ(1, construction.temperatureCalculationRequestedAfterLayerNumber());
EXPECT_EQ(1, construction.dimensionsForTheCTFCalculation());
EXPECT_EQ(0.154, construction.tubeSpacing());
// check that we can't mess up the construction
EXPECT_FALSE(construction.setSourcePresentAfterLayerNumber(3));
EXPECT_EQ(1, construction.sourcePresentAfterLayerNumber());
EXPECT_FALSE(construction.setTemperatureCalculationRequestedAfterLayerNumber(3));
EXPECT_EQ(1, construction.temperatureCalculationRequestedAfterLayerNumber());
EXPECT_TRUE(construction.eraseLayer(1));
EXPECT_EQ(1u, construction.numLayers());
EXPECT_FALSE(construction.setLayers(MaterialVector()));
EXPECT_EQ(1u, construction.numLayers());
MaterialVector testLayers = construction.layers();
ASSERT_EQ(static_cast<unsigned>(1),testLayers.size());
EXPECT_TRUE(testLayers[0] == exterior);
testLayers.push_back(interior);
testLayers.push_back(exterior);
EXPECT_TRUE(construction.setLayers(testLayers));
EXPECT_EQ(3u, construction.numLayers());
testLayers = construction.layers();
ASSERT_EQ(static_cast<unsigned>(3),testLayers.size());
EXPECT_TRUE(testLayers[0] == exterior);
EXPECT_TRUE(testLayers[1] == interior);
EXPECT_TRUE(testLayers[2] == exterior);
EXPECT_TRUE(construction.setSourcePresentAfterLayerNumber(3));
EXPECT_EQ(3, construction.sourcePresentAfterLayerNumber());
EXPECT_TRUE(construction.setTemperatureCalculationRequestedAfterLayerNumber(3));
EXPECT_EQ(3, construction.temperatureCalculationRequestedAfterLayerNumber());
testLayers.clear();
testLayers.push_back(interior);
testLayers.push_back(exterior);
EXPECT_TRUE(construction.setLayers(testLayers));
EXPECT_EQ(2u, construction.numLayers());
testLayers = construction.layers();
ASSERT_EQ(static_cast<unsigned>(2),testLayers.size());
EXPECT_TRUE(testLayers[0] == interior);
EXPECT_TRUE(testLayers[1] == exterior);
EXPECT_EQ(1, construction.sourcePresentAfterLayerNumber());
EXPECT_EQ(1, construction.temperatureCalculationRequestedAfterLayerNumber());
EXPECT_FALSE(construction.setSourcePresentAfterLayerNumber(3));
EXPECT_EQ(1, construction.sourcePresentAfterLayerNumber());
EXPECT_FALSE(construction.setTemperatureCalculationRequestedAfterLayerNumber(3));
EXPECT_EQ(1, construction.temperatureCalculationRequestedAfterLayerNumber());
while (layers.size() < 11) {
layers.push_back(exterior);
}
EXPECT_THROW((ConstructionWithInternalSource(layers)), std::exception);
}
