コード例 #1
0
ファイル: GcpListUndo.cpp プロジェクト: Siddharthk/opticks
void SetGcpPoints::executeRedo()
{
   GcpList* pGcpList = dynamic_cast<GcpList*>(getSessionItem());
   if (pGcpList != NULL)
   {
      if (pGcpList->getSelectedPoints() != mNewPoints)
      {
         pGcpList->clearPoints();
         pGcpList->addPoints(mNewPoints);
      }
   }
}
コード例 #2
0
ファイル: GeographicData.cpp プロジェクト: Siddharthk/opticks
 struct Gcp getGcpPoint(DataElement* pList, uint32_t index)
 {
    GcpList* pGcpList = dynamic_cast<GcpList*>(pList);
    if (pGcpList == NULL || index >= static_cast<uint32_t>(pGcpList->getCount()))
    {
       setLastError(SIMPLE_BAD_PARAMS);
       return Gcp();
    }
    const std::list<GcpPoint>& points = pGcpList->getSelectedPoints();
    std::list<GcpPoint>::const_iterator point = points.begin();
    while (index-- > 0) ++point;
    struct Gcp rval;
    memcpy(&rval, &*point, sizeof(struct Gcp));
    setLastError(SIMPLE_NO_ERROR);
    return rval;
 }
コード例 #3
0
ファイル: GeographicData.cpp プロジェクト: Siddharthk/opticks
 uint32_t getGcpPoints(DataElement* pList, struct Gcp* pPoints)
 {
    GcpList* pGcpList = dynamic_cast<GcpList*>(pList);
    if (pGcpList == NULL || pPoints == NULL)
    {
       setLastError(SIMPLE_BAD_PARAMS);
       return 0;
    }
    const std::list<GcpPoint>& points = pGcpList->getSelectedPoints();
    uint32_t index = 0;
    for (std::list<GcpPoint>::const_iterator point = points.begin(); point != points.end(); ++point)
    {
       memcpy(&pPoints[index++], &*point, sizeof(struct Gcp));
    }
    setLastError(SIMPLE_NO_ERROR);
    return points.size();
 }
コード例 #4
0
void Simulation_GUI::CheckModel()
{
   ProgressResource pProgress("ProgressBar");

   RasterDataDescriptor* pDesc = static_cast<RasterDataDescriptor*>(pCube->getDataDescriptor());

   FactoryResource<DataRequest> pRequest;
   DataAccessor pAcc = pCube->getDataAccessor(pRequest.release());

   DataDescriptor* dMeta = pCube->getDataDescriptor();

   DynamicObject* oMetadata = dMeta->getMetadata();

	// RETRIEVE & UPDATE METADATA INFORMATION //

	bool control = Metadata->ReadFile(image_path);

	Metadata->UpdateMetadata(oMetadata); 
  
	// WIDGET SELECT & RETRIEVE GCPs INFORMATION  //
	GcpList * GCPs = NULL;

    Service<ModelServices> pModel;
	std::vector<DataElement*> pGcpLists = pModel->getElements(pCube, TypeConverter::toString<GcpList>());

    if (!pGcpLists.empty())
	{
         QStringList aoiNames("<none>");
         for (std::vector<DataElement*>::iterator it = pGcpLists.begin(); it != pGcpLists.end(); ++it)
         {
            aoiNames << QString::fromStdString((*it)->getName());
         }
         QString aoi = QInputDialog::getItem(Service<DesktopServices>()->getMainWidget(),
            "Select a GCP List", "Select a GCP List for validate the orientation model", aoiNames);
         
         if (aoi != "<none>")
         {
            std::string strAoi = aoi.toStdString();
            for (std::vector<DataElement*>::iterator it = pGcpLists.begin(); it != pGcpLists.end(); ++it)
            {
               if ((*it)->getName() == strAoi)
               {
                  GCPs = static_cast<GcpList*>(*it);
                  break;
               }
            }
            if (GCPs == NULL)
            {
               std::string msg = "Invalid GCPList.";
               pProgress->updateProgress(msg, 0, ERRORS);
               return;
            }
         }
		 else
		 {
			 std::string msg = "A set of GCPs must be specified.";
			 if (pProgress.get() != NULL)
             {
				 pProgress->updateProgress(msg, 0, ERRORS);
             }
			 return;
		 }
	} // End if GcpList
   
  	
	// UPDATE GCPs HEIGHT INFORMATION AND SWITCH Lat&Lon COORDINATE FOR CORRECT VISUALIZAZION IN THE GCPs EDITOR
 
    std::list<GcpPoint> Punti = GCPs->getSelectedPoints();
     
	Punti = Metadata->UpdateGCP(Punti, image_path);

	//SAR_Model ModProva(*Metadata);

	SAR_Model *ModProva;
	//ModProva = new SAR_Ground_Model(Prova_metadata);
	ModProva = new SAR_Slant_Model(*Metadata);

	if(Metadata->Projection == "SGF")
	{
		ModProva = new SAR_Ground_Model(*Metadata);
	}

	P_COORD Punto;
	int N=Punti.size();
	int n=0;
	double Lat, Lon;

	accumulator_set<double, stats<tag::mean, tag::variance> > accX, accY;

	list<GcpPoint>::iterator pList;
	for (pList = Punti.begin(); pList != Punti.end(); pList++)
	{
		if(pList->mPixel.mX<Metadata->Width && pList->mPixel.mY<Metadata->Height)	
		{
			Lon = pList->mCoordinate.mX;
			Lat = pList->mCoordinate.mY;
			
			Punto = ModProva->SAR_GroundToImage(pList->mCoordinate.mX,pList->mCoordinate.mY,pList->mCoordinate.mZ); 
			pList->mRmsError.mX = pList->mPixel.mX -Punto.I;
			pList->mRmsError.mY = pList->mPixel.mY -Punto.J;
			accX(pList->mRmsError.mX);
			accY(pList->mRmsError.mY);

			pList->mCoordinate.mX = Lat;
			pList->mCoordinate.mY = Lon;

		}
		else
		{
			Lon = pList->mCoordinate.mX;
			Lat = pList->mCoordinate.mY;
			pList->mRmsError.mX = -9999;
			pList->mRmsError.mY = -9999;
			pList->mCoordinate.mX = Lat;
			pList->mCoordinate.mY = Lon;
		}


        pProgress->updateProgress("Calculating statistics", int(100*n/N), NORMAL);
		
		n++;
	}

	 double meanX = mean(accX);
	 double meanY = mean(accY);

	 double varX = variance(accX);
	 double varY = variance(accY);
	
     GCPs->clearPoints();
     GCPs->addPoints(Punti);
	

		std::string msg = "Number of Rows : " + StringUtilities::toDisplayString(pDesc->getRowCount()) + "\n"
						  "Number of Columns : " + StringUtilities::toDisplayString(pDesc->getColumnCount()) + "\n\n"
						  "Metadata update completed" + "\n\n"					  
						  "**********     Validation Results     **********" "\n\n"
						  "Number of GCPs: " + StringUtilities::toDisplayString(Punti.size()) + "\n\n"
						  "Mean I : " + StringUtilities::toDisplayString(meanX) + "\n"
						  "Variance I : " + StringUtilities::toDisplayString(varX) + "\n\n"
						  "Mean J : " + StringUtilities::toDisplayString(meanY) + "\n"
						  "Variance J : " + StringUtilities::toDisplayString(varY) + "\n\n" ;
				  						                      
		pProgress->updateProgress(msg, 100, NORMAL);

     //	pStep->finalize(); 
}
コード例 #5
0
bool Test_Update_TerraSAR::execute(PlugInArgList* pInArgList, PlugInArgList* pOutArgList)
{
  StepResource pStep("Tutorial CEO", "app", "0FD3C564-041D-4f8f-BBF8-96A7A165AB61");

   if (pInArgList == NULL || pOutArgList == NULL)
   {
      return false;
   }
   Progress* pProgress = pInArgList->getPlugInArgValue<Progress>(Executable::ProgressArg());
   RasterElement* pCube = pInArgList->getPlugInArgValue<RasterElement>(Executable::DataElementArg());
   
   if (pCube == NULL)
   {
      std::string msg = "A raster cube must be specified.";
      pStep->finalize(Message::Failure, msg);
      if (pProgress != NULL)
      {
         pProgress->updateProgress(msg, 0, ERRORS);
      }

      return false;
   }

   RasterDataDescriptor* pDesc = static_cast<RasterDataDescriptor*>(pCube->getDataDescriptor());
   VERIFY(pDesc != NULL);

   FactoryResource<DataRequest> pRequest;
   DataAccessor pAcc = pCube->getDataAccessor(pRequest.release());

   std::string path = pCube->getFilename();

   DataDescriptor* dMeta = pCube->getDataDescriptor();

   DynamicObject* Metadata = dMeta->getMetadata();

	// RETRIEVE & UPDATE METADATA INFORMATION //
		   
	TerraSAR_Metadata Prova_metadata;

	bool control = Prova_metadata.ReadFile(path);

	if (control == false)
	{
	std::string msg = "This is not a TerraSAR-X SLC Files, Metadata can't be updated";
	pProgress->updateProgress(msg, 100, ERRORS);
	return false;
	}

	Prova_metadata.UpdateMetadata(Metadata); 

	//SAR_Model ModProva(Prova_metadata,1000);

	SAR_Model *ModProva;
	//ModProva = new SAR_Ground_Model(Prova_metadata);
	
	ModProva = new SAR_Slant_Model(Prova_metadata);

	if(Prova_metadata.Projection == "SGF")
	{
		ModProva = new SAR_Ground_Model(Prova_metadata);
	}
	//else
	//{
	//	ModProva = new SAR_Slant_Model(Prova_metadata);
	//}
	
	
	// WIDGET SELECT & RETRIEVE GCPs INFORMATION  //
	GcpList * GCPs = NULL;

    Service<ModelServices> pModel;
	std::vector<DataElement*> pGcpLists = pModel->getElements(pCube, TypeConverter::toString<GcpList>());


	std::list<GcpPoint> Punti;

    if (!pGcpLists.empty())
	{
         QStringList aoiNames("<none>");
         for (std::vector<DataElement*>::iterator it = pGcpLists.begin(); it != pGcpLists.end(); ++it)
         {
            aoiNames << QString::fromStdString((*it)->getName());
         }
         QString aoi = QInputDialog::getItem(Service<DesktopServices>()->getMainWidget(),
            "Select a GCP List", "Select a GCP List for validate the orientation model", aoiNames);
         
         if (aoi != "<none>")
         {
            std::string strAoi = aoi.toStdString();
            for (std::vector<DataElement*>::iterator it = pGcpLists.begin(); it != pGcpLists.end(); ++it)
            {
               if ((*it)->getName() == strAoi)
               {
                  GCPs = static_cast<GcpList*>(*it);
                  break;
               }
            }
            if (GCPs == NULL)
            {
               std::string msg = "Invalid GCPList.";
               pStep->finalize(Message::Failure, msg);
               if (pProgress != NULL)
               {
                  pProgress->updateProgress(msg, 0, ERRORS);
               }

               return false;
            }
         }
		 else
		 {
			 std::string msg = "A set of GCPs must be specified.";
             pStep->finalize(Message::Failure, msg);
             if (pProgress != NULL)
             {
				 pProgress->updateProgress(msg, 0, ERRORS);
             }
			 return false;
		 }


		// UPDATE GCPs HEIGHT INFORMATION AND SWITCH Lat&Lon COORDINATE FOR CORRECT VISUALIZAZION IN THE GCPs EDITOR

		Punti = GCPs->getSelectedPoints();
     
		Punti = Prova_metadata.UpdateGCP(Punti, path, pProgress);



	P_COORD Punto;
	int N=Punti.size();
	int n=0, indexP=0;
	double Lat, Lon;

	accumulator_set<double, stats<tag::mean, tag::variance> > accX, accY;

	list<GcpPoint>::iterator pList;
	for (pList = Punti.begin(); pList != Punti.end(); pList++)
	{
		if(pList->mPixel.mX<Prova_metadata.Width && pList->mPixel.mY<Prova_metadata.Height)	
		{
			Lon = pList->mCoordinate.mX;
			Lat = pList->mCoordinate.mY;
			
			Punto = ModProva->SAR_GroundToImage(pList->mCoordinate.mX,pList->mCoordinate.mY,pList->mCoordinate.mZ); 
			//pList->mRmsError.mX = pList->mPixel.mX -Punto.I;
			//pList->mRmsError.mY = pList->mPixel.mY -Punto.J;

			pList->mPixel.mX = (Prova_metadata.Grid_Range_Time/Prova_metadata.RowSpacing)*(indexP-int(indexP/Prova_metadata.Grid_N_Range)*Prova_metadata.Grid_N_Range);
			pList->mRmsError.mX = (Prova_metadata.Grid_Range_Time/Prova_metadata.RowSpacing)*(indexP-int(indexP/Prova_metadata.Grid_N_Range)*Prova_metadata.Grid_N_Range) -Punto.I;

			pList->mPixel.mY = (Prova_metadata.Grid_Azimuth_Time*Prova_metadata.PRF)*int(indexP/Prova_metadata.Grid_N_Range);
			pList->mRmsError.mY = (Prova_metadata.Grid_Azimuth_Time*Prova_metadata.PRF)*int(indexP/Prova_metadata.Grid_N_Range) - Punto.J;
			
			accX(pList->mRmsError.mX);
			accY(pList->mRmsError.mY);

			pList->mCoordinate.mX = Lat;
			pList->mCoordinate.mY = Lon;

		}
		else
		{
			Lon = pList->mCoordinate.mX;
			Lat = pList->mCoordinate.mY;
			pList->mRmsError.mX = -9999;
			pList->mRmsError.mY = -9999;
			pList->mCoordinate.mX = Lat;
			pList->mCoordinate.mY = Lon;
		}

		if (pProgress != NULL)
		{
         pProgress->updateProgress("Calculating statistics", int(100*n/N), NORMAL);
		}
		n++;
		indexP++;
	}

	double meanX = mean(accX);
	double meanY = mean(accY);

	double varX = variance(accX);
	double varY = variance(accY);
	
    GCPs->clearPoints();
    GCPs->addPoints(Punti);


	if (pProgress != NULL)
	{
		std::string msg = "Number of Rows : " + StringUtilities::toDisplayString(pDesc->getRowCount()) + "\n"
						  "Number of Columns : " + StringUtilities::toDisplayString(pDesc->getColumnCount()) + "\n\n"
						  "Metadata update completed" + "\n\n"					  
						  "**********     Validation Results     **********" "\n\n"
						  "Number of GCPs: " + StringUtilities::toDisplayString(Punti.size()) + "\n\n"
						  "Mean I : " + StringUtilities::toDisplayString(meanX) + "\n"
						  "Variance I : " + StringUtilities::toDisplayString(varX) + "\n\n"
						  "Mean J : " + StringUtilities::toDisplayString(meanY) + "\n"
						  "Variance J : " + StringUtilities::toDisplayString(varY) + "\n\n" ;
				  						                      
		pProgress->updateProgress(msg, 100, NORMAL);
	}

	} // End if GcpList
	else
	{
		Punti.resize(Prova_metadata.Grid_N);
		Punti = Prova_metadata.UpdateGCP(Punti, path);

	}


	pStep->finalize(); 

	return true;
}
コード例 #6
0
bool GcpGeoreference::execute(PlugInArgList* pInArgList, PlugInArgList* pOutArgList)
{
   StepResource pStep("Run GCP Georeference", "app", "296120A0-1CD5-467E-A501-934BCA7775EA");

   Progress* pProgress = pInArgList->getPlugInArgValue<Progress>(Executable::ProgressArg());
   mpProgress = pProgress;

   FAIL_IF(!isBatch(), "Interactive mode is not supported.", return false);

   int numPoints;
   PlugInArg* pArg = NULL;

   mpRaster = pInArgList->getPlugInArgValue<RasterElement>(Executable::DataElementArg());
   FAIL_IF(mpRaster == NULL, "Unable to find raster element input", return false);

   GcpList* pGcpList = NULL;
   if (mpGui != NULL)
   {
      mOrder = mpGui->getOrder();

      string gcpListName = mpGui->getGcpListName();
      if (gcpListName.empty() == false)
      {
         pGcpList = static_cast<GcpList*>(mpDataModel->getElement(gcpListName,
            TypeConverter::toString<GcpList>(), mpRaster));
      }
   }
   else
   {
      pInArgList->getPlugInArgValue<int>("Order", mOrder);
      pGcpList = pInArgList->getPlugInArgValue<GcpList>(Georeference::GcpListArg());
   }

   if (pGcpList != NULL)
   {
      pStep->addProperty("gcpList", pGcpList->getName());
   }
   pStep->addProperty("polynomialOrder", mOrder);

   FAIL_IF(pGcpList == NULL, "Unable to find GCP list.", return false);

   if ((mOrder <= 0) || (mOrder > MAX_ORDER))
   {
      if (mpProgress)
      {
         stringstream buffer;
         buffer << "Invalid polynomial order: " << mOrder << "\nThe order must be between 1 and " <<
            MAX_ORDER << " (inclusive)";
         mpProgress->updateProgress(buffer.str(), 0, ERRORS);
      }
      pStep->addProperty("Max Polynomial Order", MAX_ORDER);
      pStep->finalize(Message::Failure, "Invalid polynomial order");
      return false;
   }

   mReverseOrder = min(MAX_ORDER, mOrder+1);

   int numCoeffs = COEFFS_FOR_ORDER(mOrder);
   numPoints = pGcpList->getSelectedPoints().size();
   if (numPoints < numCoeffs)
   {
      if (mpProgress)
      {
         stringstream buffer;
         buffer << "Too few ground control points.\n" << "A polynomial fit of order " << mOrder <<
            "\nrequires at least " << numCoeffs << " GCPs.";
         mpProgress->updateProgress(buffer.str(), 0, ERRORS);
      }
      pStep->addProperty("Required GCPs", numCoeffs);
      pStep->finalize(Message::Failure, "Too few ground control points");
      return false;
   }

   int numReverseCoeffs = COEFFS_FOR_ORDER(mReverseOrder);
   vector<double> latCoeffs(numCoeffs);
   vector<double> lonCoeffs(numCoeffs);
   vector<double> pXCoeffs(numReverseCoeffs);
   vector<double> pYCoeffs(numReverseCoeffs);
   vector<LocationType> latlonValues(numPoints);
   vector<LocationType> pixelValues(numPoints);
   double maxLonSeparation(0.0);

   list<GcpPoint>::const_iterator it;
   unsigned int i;
   unsigned int j;
   for (i = 0, it = pGcpList->getSelectedPoints().begin(); 
               it != pGcpList->getSelectedPoints().end();
               ++it, ++i)
   {
      pixelValues[i] = it->mPixel;
      latlonValues[i] = it->mCoordinate;
   }

   // Find the maximum separation to determine if it is the antimeridian or the poles
   for (i = 0; i < pGcpList->getSelectedPoints().size(); ++i)
   {
      for (j = i + 1; j < pGcpList->getSelectedPoints().size(); ++j)
      {
         if (fabs(latlonValues[i].mY - latlonValues[j].mY) > maxLonSeparation)
         {
            maxLonSeparation = fabs(latlonValues[i].mY - latlonValues[j].mY);
         }
      }
   }

   bool badValues = true;
   bool badPixelValues = true;
   for (i = 0; i < pGcpList->getSelectedPoints().size(); ++i)
   {
      for (j = i + 1; j < pGcpList->getSelectedPoints().size(); ++j)
      {
         if (fabs(latlonValues[i].mX - latlonValues[j].mX) > 1e-20)
         {
            badValues = false;
            break;
         }
         if (fabs(latlonValues[i].mY - latlonValues[j].mY) > 1e-20)
         {
            badValues = false;
            break;
         }
      }
   }

   #pragma message(__FILE__ "(" STRING(__LINE__) ") : warning : This is a short term solution " \
   "the draw method in LatLonLayer needs to be changed! (mconsidi)")
   // Special lon cases of the Antimeridian and poles
   // A value of more than 180.0 in maxLonSeparation indicates a special condition
   if (maxLonSeparation > 180.0)
   {
      for (i = 0; i < pGcpList->getSelectedPoints().size(); ++i)
      {
         if (latlonValues[i].mY < 0.0)
         {
            latlonValues[i].mY = 360.0 + latlonValues[i].mY;
         }
      }
   }

   if (badValues)
   {
      mMessageText = "All GCPs have the same value.";
      if (mpProgress)
      {
         mpProgress->updateProgress(mMessageText, 0, ERRORS);
      }
      pStep->finalize(Message::Failure, mMessageText);
      return false;
   }

   for (i = 0; i < pGcpList->getSelectedPoints().size(); ++i)
   {
      for (j = i + 1; j < pGcpList->getSelectedPoints().size(); ++j)
      {
         if (fabs(pixelValues[i].mX - pixelValues[j].mX) > 1e-20)
         {
            badPixelValues = false;
            break;
         }
         if (fabs(pixelValues[i].mY - pixelValues[j].mY) > 1e-20)
         {
            badPixelValues = false;
            break;
         }
      }
   }

   if (badPixelValues)
   {
      mMessageText = "All GCPs have the same pixel location value.";
      if (mpProgress)
      {
         mpProgress->updateProgress(mMessageText, 0, ERRORS);
      }
      pStep->finalize(Message::Failure, mMessageText);
      return false;
   }

   mMessageText = "GcpGeoreference started.";
   if (mpProgress)
   {
      mpProgress->updateProgress(mMessageText, 0, NORMAL);
   }

   bool success = computeFit(pixelValues, latlonValues, 0, latCoeffs);
   if (success)
   {
      success = computeFit(pixelValues, latlonValues, 1, lonCoeffs);
   }

   const RasterDataDescriptor* pDescriptor = dynamic_cast<const RasterDataDescriptor*>(mpRaster->getDataDescriptor());
   if (pDescriptor != NULL)
   {
      setCubeSize(pDescriptor->getRowCount(), pDescriptor->getColumnCount());
   }

   copy(latCoeffs.begin(), latCoeffs.end(), mLatCoefficients);
   copy(lonCoeffs.begin(), lonCoeffs.end(), mLonCoefficients);

   // Generate a gridSize x gridSize grid of GCPs calculated from the 
   // frontwards (pixel-to-lat/lon) polynomial. Then generate the reverse 
   // (lat/lon-to-pixel) polynomial from this grid of GCPs.
   const int gridSize = 30;
   pixelValues.clear();
   latlonValues.clear();
   for (i = 0; i < gridSize; ++i)
   {
      for (j = 0; j < gridSize; ++j)
      {
         LocationType pixel;
         LocationType latlon;
         pixel.mX = i * mNumColumns / gridSize;
         pixel.mY = j * mNumRows / gridSize;
         latlon.mX = computePolynomial(pixel, mOrder, latCoeffs);
         latlon.mY = computePolynomial(pixel, mOrder, lonCoeffs);
         pixelValues.push_back(pixel);
         latlonValues.push_back(latlon);
      }
   }

   if (success)
   {
      success = computeFit(latlonValues, pixelValues, 0, pXCoeffs);
   }
   if (success)
   {
      success = computeFit(latlonValues, pixelValues, 1, pYCoeffs);
   }

   copy(pXCoeffs.begin(), pXCoeffs.end(), mXCoefficients);
   copy(pYCoeffs.begin(), pYCoeffs.end(), mYCoefficients);

   list<GcpPoint> newPoints;
   list<GcpPoint>::iterator npIter;
   for (i = 0, it = pGcpList->getSelectedPoints().begin(); it != pGcpList->getSelectedPoints().end(); ++it, ++i)
   {
      GcpPoint newPoint;
      newPoint.mPixel.mX = it->mPixel.mX;
      newPoint.mPixel.mY = it->mPixel.mY;
      newPoint.mCoordinate.mX = it->mCoordinate.mX;
      newPoint.mCoordinate.mY = it->mCoordinate.mY;
      // If maxLonSeparation > 180.0 then this is a special case
      if (maxLonSeparation > 180.0 && newPoint.mCoordinate.mY < 0.0)
      {
         newPoint.mCoordinate.mY = newPoint.mCoordinate.mY + 360.0;
      }
      LocationType newPixel = geoToPixel(newPoint.mCoordinate);
      newPoint.mRmsError.mX = fabs(newPixel.mX - newPoint.mPixel.mX);
      newPoint.mRmsError.mY = fabs(newPixel.mY - newPoint.mPixel.mY);
      newPoints.push_back(newPoint);
   }

   pGcpList->clearPoints();
   pGcpList->addPoints(newPoints);

   mpGui = NULL;

   if (mpRaster != NULL)
   {
      mpRaster->setGeoreferencePlugin(this);
   }

   pStep->finalize(Message::Success);
   if (mpProgress)
   {
      mpProgress->updateProgress("GcpGeoreference finished.", 0, NORMAL);
   }

   return true;
}