Пример #1
0
    def addingIntersection(self, blobA, blobB, blobC):
        """
        Update the blobA by adding to it the intersection between the blobB and the blobC
        """
        mask_intersect, bbox_intersect = Mask.intersectMask(
            blobB.getMask(), blobB.bbox, blobC.getMask(), blobC.bbox)

        bbox = Mask.jointBox([blobA.bbox, bbox_intersect])
        (mask, bbox) = Mask.jointMask(bbox, bbox)

        Mask.paintMask(mask, bbox, blobA.getMask(), blobA.bbox, 1)
        Mask.paintMask(mask, bbox, mask_intersect, bbox_intersect, 1)

        if mask.any():
            blobA.updateUsingMask(bbox, mask.astype(int))
Пример #2
0
    def union(self, blobs):
        """
        Create a new blob that is the union of the (two) blobs given
        """
        #boxs are in image space, masks invert x and y.
        boxes = []
        for blob in blobs:
            boxes.append(blob.bbox)
        box = Mask.jointBox(boxes)
        (mask, box) = Mask.jointMask(box, box)

        for blob in blobs:
            Mask.paintMask(mask, box, blob.getMask(), blob.bbox, 1)

        if mask.any():
            # measure is brutally slower with non int types (factor 4), while byte&bool would be faster by 25%, conversion is fast.
            blob = blobs[0].copy()
            blob.updateUsingMask(box, mask.astype(int))
            return blob
        return None
Пример #3
0
    def segmentation(self):

        # compute bbox of scribbles (working area)
        bboxes = []
        for i, curve in enumerate(self.scribbles.points):
            bbox = Mask.pointsBox(curve, int(self.scribbles.size[i] / 2))
            bboxes.append(bbox)
        working_area = Mask.jointBox(bboxes)

        if working_area[0] < 0:
            working_area[0] = 0

        if working_area[1] < 0:
            working_area[1] = 0

        if working_area[0] + working_area[3] > self.viewerplus.img_map.height(
        ) - 1:
            working_area[3] = self.viewerplus.img_map.height(
            ) - 1 - working_area[0]

        if working_area[1] + working_area[2] > self.viewerplus.img_map.width(
        ) - 1:
            working_area[2] = self.viewerplus.img_map.width(
            ) - 1 - working_area[1]

        crop_img = utils.cropQImage(self.viewerplus.img_map, working_area)
        crop_imgnp = utils.qimageToNumpyArray(crop_img)

        # create markers
        mask = np.zeros((working_area[3], working_area[2], 3), dtype=np.int32)

        color_codes = dict()
        counter = 1
        for i, curve in enumerate(self.scribbles.points):

            col = self.scribbles.label[i].fill
            b = col[2]
            g = col[1]
            r = col[0]
            color = (b, g, r)

            color_code = b + 256 * g + 65536 * r
            color_key = str(color_code)
            if color_codes.get(color_key) is None:
                name = self.scribbles.label[i].name
                color_codes[color_key] = (counter, name)
                counter = counter + 1

            curve = np.int32(curve)

            curve[:, 0] = curve[:, 0] - working_area[1]
            curve[:, 1] = curve[:, 1] - working_area[0]

            curve = curve.reshape((-1, 1, 2))
            mask = cv2.polylines(mask,
                                 pts=[curve],
                                 isClosed=False,
                                 color=color,
                                 thickness=self.scribbles.size[i],
                                 lineType=cv2.LINE_8)

        mask = np.uint8(mask)

        markers = np.zeros((working_area[3], working_area[2]), dtype='int32')
        for label in self.scribbles.label:
            col = label.fill
            b = col[2]
            g = col[1]
            r = col[0]
            color_code = b + 256 * g + 65536 * r
            color_key = str(color_code)

            idx = np.where((mask[:, :, 0] == b) & (mask[:, :, 1] == g)
                           & (mask[:, :, 2] == r))
            (value, name) = color_codes[color_key]
            markers[idx] = value

        # markers = np.int32(255*rgb2gray(mask))
        # markersprint = 255*rgb2gray(mask)
        markersprint = markers
        cv2.imwrite('mask.png', markersprint)

        # watershed segmentation
        segmentation = cv2.watershed(crop_imgnp, markers)
        segmentation = filters.median(segmentation, disk(5), mode="mirror")
        cv2.imwrite('segmentation.png', segmentation)

        # the result of the segmentation must be converted into labels again
        lbls = measure.label(segmentation)

        blobs = []
        for region in measure.regionprops(lbls):
            blob = Blob(region, working_area[1], working_area[0],
                        self.viewerplus.annotations.getFreeId())
            color_index = segmentation[region.coords[0][0],
                                       region.coords[0][1]]
            data = list(color_codes.items())
            index = 0
            for i in range(len(data)):
                (color_code, t) = data[i]
                if t[0] == color_index:
                    color_code = int(color_code)
                    r = int(color_code / 65536)
                    g = int(int(color_code - r * 65536) / 256)
                    b = int(color_code - r * 65536 - g * 256)
                    color = [r, g, b]
                    name = t[1]
                    break

            blob.class_color = color
            blob.class_name = name

            blobs.append(blob)

        return blobs