/** Calls the algorithm. */
protected void callAlgorithm() {
try {
resultImage =
new ModelImage(imageA.getType(), imageA.getExtents(), (imageA.getImageName() + "_isn"));
resultImage.copyFileTypeInfo(imageA);
// Make algorithm
isnAlgo = new PlugInAlgorithmISN(resultImage, imageA);
// This is very important. Adding this object as a listener allows the algorithm to
// notify this object when it has completed of failed. See algorithm performed event.
// This is made possible by implementing AlgorithmedPerformed interface
isnAlgo.addListener(this);
createProgressBar(imageA.getImageName(), " ...", isnAlgo);
// Hide dialog
setVisible(false);
if (isRunInSeparateThread()) {
// Start the thread as a low priority because we wish to still have user interface work
// fast.
if (isnAlgo.startMethod(Thread.MIN_PRIORITY) == false) {
MipavUtil.displayError("A thread is already running on this object");
}
} else {
isnAlgo.run();
}
} catch (OutOfMemoryError x) {
System.gc();
MipavUtil.displayError("AlgorithmAbsoluteValue: unable to allocate enough memory");
return;
}
}
/** Starts the program. */
public void runAlgorithm() {
if ((srcImage1 == null) || (srcImage2 == null) || (destImage == null)) {
displayError("Source Image(s) is null");
setCompleted(false);
return;
}
if (srcImage1.getType() != srcImage2.getType()) {
displayError("Source Images must be of the same data type.");
setCompleted(false);
return;
}
float[] resols1 = srcImage1.getResolutions(0);
float[] resols2 = srcImage2.getResolutions(0);
if ((srcImage1.getNDims() == 2) && (srcImage2.getNDims() == 2)) {
if (resols1[0] == resols2[0] && resols1[1] == resols2[1]) {
cat2D_2D_3D();
} else {
displayError("Resolutions must match up");
setCompleted(false);
return;
}
} else if (((srcImage1.getNDims() == 2) && (srcImage2.getNDims() == 3))
|| ((srcImage1.getNDims() == 3) && (srcImage2.getNDims() == 2))) {
if (resols1[0] == resols2[0] && resols1[1] == resols2[1]) {
cat2D_3D_3D();
} else {
displayError("Resolutions must match up");
setCompleted(false);
return;
}
} else if ((srcImage1.getNDims() == 3)
&& (srcImage2.getNDims() == 3)
&& (destImage.getNDims() == 3)) {
if (resols1[0] == resols2[0] && resols1[1] == resols2[1] && resols1[2] == resols2[2]) {
cat3D_3D_3D();
} else {
displayError("Resolutions must match up");
setCompleted(false);
return;
}
} else if ((srcImage1.getNDims() == 3)
&& (srcImage2.getNDims() == 3)
&& (destImage.getNDims() == 4)) {
if (resols1[0] == resols2[0] && resols1[1] == resols2[1] && resols1[2] == resols2[2]) {
cat3D_3D_4D();
} else {
displayError("Resolutions must match up");
setCompleted(false);
return;
}
} else if (((srcImage1.getNDims() == 3) && (srcImage2.getNDims() == 4))
|| ((srcImage1.getNDims() == 4) && (srcImage2.getNDims() == 3))) {
if (resols1[0] == resols2[0] && resols1[1] == resols2[1] && resols1[2] == resols2[2]) {
cat3D_4D_4D();
} else {
displayError("Resolutions must match up");
setCompleted(false);
return;
}
} else if ((srcImage1.getNDims() == 4) && (srcImage2.getNDims() == 4)) {
if (resols1[0] == resols2[0]
&& resols1[1] == resols2[1]
&& resols1[2] == resols2[2]
&& resols1[3] == resols2[3]) {
cat4D_4D_4D();
} else {
displayError("Resolutions must match up");
setCompleted(false);
return;
}
} else {
displayError("Source Image(s) dimensionality not supported.");
}
}
/**
* Once all the necessary variables are set, call the Concat algorithm based on what type of image
* this is and whether or not there is a separate destination image.
*/
protected void callAlgorithm() {
int destExtents[] = new int[3];
ModelImage destImage = null;
destExtents[0] = subXDim;
destExtents[1] = subYDim;
destExtents[2] = numberOfImagesInMosaic;
destImage =
new ModelImage(
image.getType(), destExtents, makeImageName(image.getImageName(), "_mosaic_to_slices"));
try {
// Make algorithm
mathAlgo = new AlgorithmMosaicToSlices(image, destImage);
// This is very important. Adding this object as a listener allows the algorithm to
// notify this object when it has completed of failed. See algorithm performed event.
// This is made possible by implementing AlgorithmedPerformed interface
mathAlgo.addListener(this);
createProgressBar(image.getImageName(), mathAlgo);
// Hide dialog
setVisible(false);
if (displayLoc == REPLACE) {
// These next lines set the titles in all frames where the source image is displayed to
// "locked - " image name so as to indicate that the image is now read/write locked!
// The image frames are disabled and then unregisted from the userinterface until the
// algorithm has completed.
Vector<ViewImageUpdateInterface> imageFrames = image.getImageFrameVector();
titles = new String[imageFrames.size()];
for (int i = 0; i < imageFrames.size(); i++) {
titles[i] = ((Frame) (imageFrames.elementAt(i))).getTitle();
((Frame) (imageFrames.elementAt(i))).setTitle("Locked: " + titles[i]);
((Frame) (imageFrames.elementAt(i))).setEnabled(false);
userInterface.unregisterFrame((Frame) (imageFrames.elementAt(i)));
}
}
if (isRunInSeparateThread()) {
// Start the thread as a low priority because we wish to still have user interface work
// fast.
if (mathAlgo.startMethod(Thread.MIN_PRIORITY) == false) {
MipavUtil.displayError("A thread is already running on this object");
}
} else {
mathAlgo.run();
}
} catch (OutOfMemoryError x) {
System.gc();
MipavUtil.displayError("Dialog Concatenation: unable to allocate enough memory");
return;
}
}
