lacan/Export Contiguous Fields.groovy

## Export Contiguous Fields.groovy
// This script was created for Anna Hamacher, as per an internal discussion on the ImageSC forum
// that stemmed from https://forum.image.sc/t/viewing-slide-scans-from-operetta-perkin-elmer-cls-as-overview-montage-images/52942/13?u=oburri
// Code by Olivier Burri, EPFL - SV - PTECH - BIOP
// Edited by Anna Hamacher
// Last edition: July 2022

#@ File dir (label="Images Folder", style="directory")
#@Integer downsample (label="Downsample Factor", value=1)
#@String z_projection_method (label = "Projection Type", choices = {"No Projection", "Average Intensity", "Max Intensity", "Min Intensity", "Sum Slices", "Standard Deviation", "Median"} )
#@File outputDir (label="Output directory", style="directory")

def id = new File( dir, "Index.idx.xml" )
// Minimal example, export everything
opm = new OperettaManager.Builder()
									.setId( id )
									.setSaveFolder(outputDir)
									.setProjectionMethod()
									.setProjectionMethod( z_projection_method )
									.build();


def allWells = opm.getAvailableWells( )

allWells.each{ well ->

    def clusters = getContigiousFields(well, 0.1)


    def fieldsClusters = clusters.collect{ it.collect{ it.field } }

    // Get XY coordinates of top left field from each cluster
    //def coordClusters = clusters.collect{ [x:it.min{it.roi.x}.roi.x, y:it.min{it.roi.y}.roi.y ] }
    //[fieldsClusters, coordClusters].transpose().each{ f, coord -> println f; println coord }
    //return

    fieldsClusters.eachWithIndex() {f, i ->
		println f.size()
		imp = opm.getWellImage( well, f, downsample, opm.getRange(), null )
		def name = opm.getFinalWellImageName( well ) + "_region" + i
		IJ.saveAsTiff(imp, new File( outputDir, name + ".tif" ).getAbsolutePath() )
    }
}

// Basic Flood Fill for finding fields that are next to each other
// overlapRatio should be around 0.1 to find the right fields, especially if they do not overlap much
def getContigiousFields( def well, def overlapRatio ) {

	def fields = opm.getAvailableFields( well )
	def id = 0
    def topleft = opm.getTopLeftCoordinates( fields )

	// Build the rois
	def rois = fields.collect{ field ->
		def sample_id = field.getIndex( ).getValue( )
        def x = ( opm.getUncalibratedPositionX( field ) - topleft.getLongPosition( 0 ) ) / downsample
        def y = ( opm.getUncalibratedPositionY( field ) - topleft.getLongPosition( 1 ) ) / downsample
        def w = ( opm.metadata.getPixelsSizeX( sample_id ).getValue( ) ) / downsample
        def h = ( opm.metadata.getPixelsSizeY( sample_id ).getValue( ) ) / downsample

        def extraW = w * overlapRatio
        def extraH = h * overlapRatio
        x -= extraW/2
        y -= extraH/2
        w += extraW
        h += extraH
        def roi = new Roi( x, y, w, h )
		id++
        return [id:id, field:field, roi:roi]
	}

	// Basic clustering algorithm using flood fill
	// Define candidates that are available
	def candidates = rois.collect()
	// Define a list that will contain the discovered clusters
	def clusters = []

	// While there are available candidates
	while (!candidates.isEmpty() ) {
		// Take the last candidate as seed.
		seed = candidates.pop()

		// Prepare a queue which will contain all the fields to explore
		def Q = [] as Queue
		// Initialize this queue with the seed point
		Q.offer(seed)

		// Initialize this cluster, which contains the seed. This will contain the final list of fields that are part of this cluster
		def cluster = [seed]

		// Explore around the seedpoint, adding to the queue
		while( !Q.isEmpty() ) {
			// Get the first element of the queue, as we will insert new points to visit at the end
			seed = Q.poll()
			// Find all rois that overlap with the current one
			def neighbors = candidates.findAll{ opm.isOverlapping( seed.roi, it.roi ) }

			// If neighbors were found, add them to the queue, so they can be visited as well, remove them from the candidates and add them to the growing cluster list
			if (neighbors.size() > 0) {
				println( "Found ${neighbors.size()} neighbors" )
				Q.addAll( neighbors )
				candidates.removeAll( neighbors )
				cluster.addAll( neighbors )
			}
		}
		// When the queue is empty, we have a cluster ready, this will loop if there are candidates left
		clusters.add( cluster )
	}

	return clusters
}

import ch.epfl.biop.operetta.OperettaManager
import ij.gui.Roi
import java.awt.Color
import ij.IJ
	// This script was created for Anna Hamacher, as per an internal discussion on the ImageSC forum
	// that stemmed from https://forum.image.sc/t/viewing-slide-scans-from-operetta-perkin-elmer-cls-as-overview-montage-images/52942/13?u=oburri
	// Code by Olivier Burri, EPFL - SV - PTECH - BIOP
	// Edited by Anna Hamacher
	// Last edition: July 2022

	#@ File dir (label="Images Folder", style="directory")
	#@Integer downsample (label="Downsample Factor", value=1)
	#@String z_projection_method (label = "Projection Type", choices = {"No Projection", "Average Intensity", "Max Intensity", "Min Intensity", "Sum Slices", "Standard Deviation", "Median"} )
	#@File outputDir (label="Output directory", style="directory")

	def id = new File( dir, "Index.idx.xml" )
	// Minimal example, export everything
	opm = new OperettaManager.Builder()
	.setId( id )
	.setSaveFolder(outputDir)
	.setProjectionMethod()
	.setProjectionMethod( z_projection_method )
	.build();


	def allWells = opm.getAvailableWells( )

	allWells.each{ well ->

	def clusters = getContigiousFields(well, 0.1)


	def fieldsClusters = clusters.collect{ it.collect{ it.field } }

	// Get XY coordinates of top left field from each cluster
	//def coordClusters = clusters.collect{ [x:it.min{it.roi.x}.roi.x, y:it.min{it.roi.y}.roi.y ] }
	//[fieldsClusters, coordClusters].transpose().each{ f, coord -> println f; println coord }
	//return

	fieldsClusters.eachWithIndex() {f, i ->
	println f.size()
	imp = opm.getWellImage( well, f, downsample, opm.getRange(), null )
	def name = opm.getFinalWellImageName( well ) + "_region" + i
	IJ.saveAsTiff(imp, new File( outputDir, name + ".tif" ).getAbsolutePath() )
	}
	}

	// Basic Flood Fill for finding fields that are next to each other
	// overlapRatio should be around 0.1 to find the right fields, especially if they do not overlap much
	def getContigiousFields( def well, def overlapRatio ) {

	def fields = opm.getAvailableFields( well )
	def id = 0
	def topleft = opm.getTopLeftCoordinates( fields )

	// Build the rois
	def rois = fields.collect{ field ->
	def sample_id = field.getIndex( ).getValue( )
	def x = ( opm.getUncalibratedPositionX( field ) - topleft.getLongPosition( 0 ) ) / downsample
	def y = ( opm.getUncalibratedPositionY( field ) - topleft.getLongPosition( 1 ) ) / downsample
	def w = ( opm.metadata.getPixelsSizeX( sample_id ).getValue( ) ) / downsample
	def h = ( opm.metadata.getPixelsSizeY( sample_id ).getValue( ) ) / downsample

	def extraW = w * overlapRatio
	def extraH = h * overlapRatio
	x -= extraW/2
	y -= extraH/2
	w += extraW
	h += extraH
	def roi = new Roi( x, y, w, h )
	id++
	return [id:id, field:field, roi:roi]
	}

	// Basic clustering algorithm using flood fill
	// Define candidates that are available
	def candidates = rois.collect()
	// Define a list that will contain the discovered clusters
	def clusters = []

	// While there are available candidates
	while (!candidates.isEmpty() ) {
	// Take the last candidate as seed.
	seed = candidates.pop()

	// Prepare a queue which will contain all the fields to explore
	def Q = [] as Queue
	// Initialize this queue with the seed point
	Q.offer(seed)

	// Initialize this cluster, which contains the seed. This will contain the final list of fields that are part of this cluster
	def cluster = [seed]

	// Explore around the seedpoint, adding to the queue
	while( !Q.isEmpty() ) {
	// Get the first element of the queue, as we will insert new points to visit at the end
	seed = Q.poll()
	// Find all rois that overlap with the current one
	def neighbors = candidates.findAll{ opm.isOverlapping( seed.roi, it.roi ) }

	// If neighbors were found, add them to the queue, so they can be visited as well, remove them from the candidates and add them to the growing cluster list
	if (neighbors.size() > 0) {
	println( "Found ${neighbors.size()} neighbors" )
	Q.addAll( neighbors )
	candidates.removeAll( neighbors )
	cluster.addAll( neighbors )
	}
	}
	// When the queue is empty, we have a cluster ready, this will loop if there are candidates left
	clusters.add( cluster )
	}

	return clusters
	}

	import ch.epfl.biop.operetta.OperettaManager
	import ij.gui.Roi
	import java.awt.Color
	import ij.IJ