def __isub__(self, intersectWith):
if (isinstance(intersectWith, Area)):
a1 = Area(LineUtils().lineToGeneralPath(self.autoStroke()))
a1.subtract(intersectWith)
self.__dict__["line"] = self.maybeFix(LineUtils().piToCachedLine(
a1.getPathIterator(None)))
return self
def findMergedContour(project): # Find the two bezier Profile instances that define the contour # and merge them into a single Area. lys = project.getRootLayerSet() contour = Area() for profile in lys.getDisplayables(Profile): pt = project.findProjectThing(profile) if pt is None: print "null pt for profile ", profile continue if pt.getParent().getParent().getTitle() == "contour": contour.add(Area(profile.getPerimeter())) # Extract a single Polygon from the Area pols = M.getPolygons(contour) if len(pols) > 1: print "More than one polygon for the contour!" return pols[0]
def scaleContour(pol, scale): # Scale up the polygon relative to its center cx = 0 cy = 0 for i in range(pol.npoints): cx += pol.xpoints[i] cy += pol.ypoints[i] cx /= pol.npoints cy /= pol.npoints aff = AffineTransform(1, 0, 0, 1, -cx, -cy) aff.preConcatenate(AffineTransform(scale, 0, 0, scale, 0, 0)) aff.preConcatenate(AffineTransform(1, 0, 0, 1, cx, cy)) tmp = Area(pol) tmp.transform(aff) return M.getPolygons(tmp)[0]
def fixAreatreeArea(areatree):
# Append a 1-pixel square area for nodes without any area
# this will fix using findZDisplayables for finding areatree,
# including connector.getTargets(), connector.getOrigins() etc.
if not isinstance(areatree, AreaTree):
print "Error: input must be an AreaTree"
return
root = areatree.getRoot()
if root is None:
return
for nd in root.getSubtreeNodes():
a = nd.getArea()
a.add(Area(Rectangle(int(nd.getX()), int(nd.getY()), 1, 1)))
nd.setData(a)
def findLocals(project, pol):
# Test if any node of every treeline is outside the polygon,
# to determine if a neuron is local or not.
lys = project.getRootLayerSet()
trees = [t for t in lys.getZDisplayables(Treeline)]
trees = trees + [t for t in lys.getZDisplayables(AreaTree)]
tags = {}
for tree in trees:
# Make the polygon local to the tree coordinates
a = Area(pol)
a.transform(tree.getAffineTransform().createInverse())
localPol = M.getPolygons(a)[0]
isLocal = False
for node in tree.getRoot().getSubtreeNodes():
if localPol.contains(node.x, node.y):
continue
isLocal = True
break
tags[tree.getId()] = isLocal
return tags
def __isub__(self, intersectWith): if (isinstance(intersectWith, Area)): a1 = Area(LineUtils().lineToGeneralPath(self.autoStroke())) a1.subtract(intersectWith) self.__dict__["line"] = self.maybeFix(LineUtils().piToCachedLine(a1.getPathIterator(None))) return self
layerset = areatree.getLayerSet()
calibration = layerset.getCalibration()
affine = areatree.getAffineTransform()
# outAndInArray = areatree.findConnectors()
for nd in root.getSubtreeNodes():
# get node coordinates, from tut on web
fp = array([nd.getX(), nd.getY()], 'f')
affine.transform(fp, 0, fp, 0, 1)
x = fp[0] * calibration.pixelWidth
y = fp[1] * calibration.pixelHeight
z = nd.getLayer().getZ(
) * calibration.pixelWidth # a TrakEM2 oddity
# get node connections, in/out synapse number, synapse id
# NOTE: this method seems to be affected by display zoom value
area = Area(Rectangle(int(fp[0]), int(fp[1]), 1, 1))
# area.transform(affine)
inAndOuts = layerset.findZDisplayables(Connector, nd.getLayer(),
area, False, False)
outgoing = []
incoming = []
for connector in inAndOuts:
if connector is None:
break
if connector.intersectsOrigin(area, nd.getLayer()):
outgoing.append(connector)
else:
incoming.append(connector)
nInputs = len(incoming)
nOutputs = len(outgoing)
outgoingIds = [oc.getId() for oc in outgoing]
def squarea(
self, offset
): #This is the default area generator. It will be overridden by certain shapes.
return Area(Rectangle2D.Double(-offset.x, -offset.y, 1, 1))
def area(self):
return Area(LineUtils().lineToGeneralPath(self.__dict__["line"]))
def toArea2(self): """Convert this line to a java.geom.Area""" return Area(LineUtils().lineToGeneralPath(self))
