opencv/modules/softcascade/misc/sft.py

#!/usr/bin/env python

import cv2, re, glob
import numpy             as np
import matplotlib.pyplot as plt
from itertools import izip

""" Convert numPy matrices with rectangles and confidences to sorted list of detections."""
def convert2detections(rects, confs, crop_factor = 0.125):
    if rects is None:
        return []

    dts = zip(*[rects.tolist(), confs.tolist()])
    dts = zip(dts[0][0], dts[0][1])
    dts = [Detection(r,c) for r, c in dts]

    dts.sort(lambda x, y : -1  if (x.conf - y.conf) > 0 else 1)

    for dt in dts:
        dt.crop(crop_factor)

    return dts

""" Create new instance of soft cascade."""
def cascade(min_scale, max_scale, nscales, f):
    # where we use nms cv::SCascade::DOLLAR == 2
    c = cv2.SCascade(min_scale, max_scale, nscales, 2)
    xml = cv2.FileStorage(f, 0)
    dom = xml.getFirstTopLevelNode()
    assert c.load(dom)
    return c

""" Compute prefix sum for en array."""
def cumsum(n):
    cum = []
    y = 0
    for i in n:
        y += i
        cum.append(y)
    return cum

""" Compute x and y arrays for ROC plot."""
def computeROC(confidenses, tp, nannotated, nframes, ignored):
    confidenses, tp, ignored = zip(*sorted(zip(confidenses, tp, ignored), reverse = True))

    fp = [(1 - x) for x in tp]
    fp = [(x - y) for x, y in izip(fp, ignored)]

    fp = cumsum(fp)
    tp = cumsum(tp)
    miss_rate = [(1 - x / (nannotated + 0.000001)) for x in tp]
    fppi = [x / float(nframes) for x in fp]

    return fppi, miss_rate

""" Crop rectangle by factor."""
def crop_rect(rect, factor):
    val_x = factor * float(rect[2])
    val_y = factor * float(rect[3])
    x = [int(rect[0] + val_x), int(rect[1] + val_y), int(rect[2] - 2.0 * val_x), int(rect[3] - 2.0 * val_y)]
    return x

""" Initialize plot axises."""
def initPlot(name):
    plt.xlabel("fppi")
    plt.ylabel("miss rate")
    plt.title(name)
    plt.grid(True)
    plt.xscale('log')
    plt.yscale('log')

""" Draw plot."""
def plotLogLog(fppi, miss_rate, c):
    plt.loglog(fppi, miss_rate, color = c, linewidth = 2)

""" Show resulted plot."""
def showPlot(file_name, labels):
    plt.axis((pow(10, -3), pow(10, 1), .035, 1))
    plt.yticks( [0.05, 0.1, 0.2, 0.3, 0.4, 0.5, 0.64, 0.8, 1], ['.05', '.10', '.20', '.30', '.40', '.50', '.64', '.80', '1'] )
    plt.legend(labels, loc = "lower left")
    plt.savefig(file_name)
    plt.show()

""" Filter true positives and ignored detections for cascade detector output."""
def match(gts, dts):
    matches_gt     = [0]*len(gts)
    matches_dt     = [0]*len(dts)
    matches_ignore = [0]*len(dts)

    if len(gts) == 0:
        return matches_dt, matches_ignore

    # Cartesian product for each detection BB_dt with each BB_gt
    overlaps = [[dt.overlap(gt) for gt in gts]for dt in dts]

    for idx, row in enumerate(overlaps):
        imax = row.index(max(row))

        # try to match ground truth
        if (matches_gt[imax] == 0 and row[imax] > 0.5):
            matches_gt[imax] = 1
            matches_dt[idx]  = 1

    for idx, dt in enumerate(dts):
        # try to math ignored
        if matches_dt[idx] == 0:
            row = gts
            row = [i for i in row if (i[3] - i[1]) < 53 or (i[3] - i[1]) >  256]
            for each in row:
                if dts[idx].overlapIgnored(each) > 0.5:
                    matches_ignore[idx] = 1
    return matches_dt, matches_ignore


""" Draw detections or ground truth on image."""
def draw_rects(img, rects, color, l = lambda x, y : x + y):
    if rects is not None:
        for x1, y1, x2, y2 in rects:
            cv2.rectangle(img, (x1, y1), (l(x1, x2), l(y1, y2)), color, 2)


def draw_dt(img, dts, color, l = lambda x, y : x + y):
    if dts is not None:
        for dt in dts:
            bb = dt.bb
            x1, y1, x2, y2 = dt.bb[0], dt.bb[1], dt.bb[2], dt.bb[3]

            cv2.rectangle(img, (x1, y1), (l(x1, x2), l(y1, y2)), color, 2)

class Detection:
    def __init__(self, bb, conf):
        self.bb = bb
        self.conf = conf
        self.matched = False

    def crop(self, factor):
        self.bb = crop_rect(self.bb, factor)

    # we use rect-style for dt and box style for gt. ToDo: fix it
    def overlap(self, b):

        a = self.bb
        w = min( a[0] + a[2], b[2]) - max(a[0], b[0]);
        h = min( a[1] + a[3], b[3]) - max(a[1], b[1]);

        cross_area = 0.0 if (w < 0 or h < 0) else float(w * h)
        union_area = (a[2] * a[3]) + ((b[2] - b[0]) * (b[3] - b[1])) - cross_area;

        return cross_area / union_area

        # we use rect-style for dt and box style for gt. ToDo: fix it
    def overlapIgnored(self, b):

        a = self.bb
        w = min( a[0] + a[2], b[2]) - max(a[0], b[0]);
        h = min( a[1] + a[3], b[3]) - max(a[1], b[1]);

        cross_area = 0.0 if (w < 0 or h < 0) else float(w * h)
        self_area = (a[2] * a[3]);

        return cross_area / self_area

    def mark_matched(self):
        self.matched = True

"""Parse INPIA annotation format"""
def parse_inria(ipath, f):
    bbs = []
    path = None
    for l in f:
        box = None
        if l.startswith("Bounding box"):
            b = [x.strip() for x in l.split(":")[1].split("-")]
            c = [x[1:-1].split(",") for x in b]
            d = [int(x) for x in sum(c, [])]
            bbs.append(d)

        if l.startswith("Image filename"):
            path = l.split('"')[-2]

    return Sample(path, bbs)


def glob_set(pattern):
    return [__n for __n in glob.iglob(pattern)]

""" Parse ETH idl file. """
def parse_idl(f):
    map = {}
    for l in open(f):
        l = re.sub(r"^\"left\/", "{\"", l)
        l = re.sub(r"\:", ":[", l)
        l = re.sub(r"(\;|\.)$", "]}", l)
        map.update(eval(l))
    return map

""" Normalize detection box to unified aspect ration."""
def norm_box(box, ratio):
    middle = float(box[0] + box[2]) / 2.0
    new_half_width = float(box[3] - box[1]) * ratio / 2.0
    return (int(round(middle - new_half_width)), box[1], int(round(middle + new_half_width)), box[3])

""" Process array of boxes."""
def norm_acpect_ratio(boxes, ratio):
    return [ norm_box(box, ratio)  for box in boxes]

""" Filter detections out of extended range. """
def filter_for_range(boxes, scale_range, ext_ratio):
    boxes = norm_acpect_ratio(boxes, 0.5)
    boxes = [b for b in boxes if (b[3] - b[1]) > scale_range[0] / ext_ratio]
    boxes = [b for b in boxes if (b[3] - b[1]) < scale_range[1] * ext_ratio]
    return boxes

""" Resize sample for training."""
def resize_sample(image, d_w, d_h):
    h, w, _ = image.shape
    if (d_h < h) or (d_w < w):
        ratio = min(d_h / float(h), d_w / float(w))

        kernel_size = int( 5 / (2 * ratio))
        sigma = 0.5 / ratio
        image_to_resize = cv2.filter2D(image, cv2.CV_8UC3, cv2.getGaussianKernel(kernel_size, sigma))
        interpolation_type = cv2.INTER_AREA
    else:
        image_to_resize = image
        interpolation_type = cv2.INTER_CUBIC

    return cv2.resize(image_to_resize,(d_w, d_h), None, 0, 0, interpolation_type)

newobj = re.compile("^lbl=\'(\w+)\'\s+str=(\d+)\s+end=(\d+)\s+hide=0$")

class caltech:
    @staticmethod
    def extract_objects(f):
        objects = []
        tmp = []
        for l in f:
            if newobj.match(l) is not None:
                objects.append(tmp)
                tmp = []
            tmp.append(l)
        return objects[1:]

    @staticmethod
    def parse_header(f):
        _    = f.readline() # skip first line (version string)
        head = f.readline()
        (nFrame, nSample) = re.search(r'nFrame=(\d+) n=(\d+)', head).groups()
        return (int(nFrame), int(nSample))

    @staticmethod
    def parse_pos(l):
        pos = re.match(r'^posv?\s*=(\[[\d\s\.\;]+\])$', l).group(1)
        pos = re.sub(r"(\[)(\d)", "\\1[\\2", pos)
        pos = re.sub(r"\s", ", ", re.sub(r"\;\s+(?=\])", "]", re.sub(r"\;\s+(?!\])", "],[", pos)))
        return eval(pos)

    @staticmethod
    def parse_occl(l):
        occl = re.match(r'^occl\s*=(\[[\d\s\.\;]+\])$', l).group(1)
        occl = re.sub(r"\s(?!\])", ",", occl)
        return eval(occl)

def parse_caltech(f):
    (nFrame, nSample) = caltech.parse_header(f)
    objects = caltech.extract_objects(f)

    annotations = [[] for i in range(nFrame)]
    for obj in objects:
        (type, start, end) = re.search(r'^lbl=\'(\w+)\'\s+str=(\d+)\s+end=(\d+)\s+hide=0$', obj[0]).groups()
        print type, start, end
        start = int(start) -1
        end   = int(end)
        pos   = caltech.parse_pos(obj[1])
        posv  = caltech.parse_pos(obj[2])
        occl  = caltech.parse_occl(obj[3])

        for idx, (p, pv, oc) in enumerate(zip(*[pos, posv, occl])):
            annotations[start + idx].append((type, p, oc, pv))

    return annotations
caltech ROC test: - parse idl - replase option parser with argument parser 12 years ago			`#!/usr/bin/env python`

			`import cv2, re, glob`
refactor python ROC script and add axis ticks 12 years ago			`import numpy as np`
add plotting function (matplotlib required) 12 years ago			`import matplotlib.pyplot as plt`
improve ROC test script: handle ignored 12 years ago			`from itertools import izip`
add plotting function (matplotlib required) 12 years ago
refactor python ROC script and add axis ticks 12 years ago			`""" Convert numPy matrices with rectangles and confidences to sorted list of detections."""`
add detection to ground truth matching according to Piotr Dollar paper 12 years ago			`def convert2detections(rects, confs, crop_factor = 0.125):`
			`if rects is None:`
			`return []`

			`dts = zip(*[rects.tolist(), confs.tolist()])`
			`dts = zip(dts[0][0], dts[0][1])`
			`dts = [Detection(r,c) for r, c in dts]`

			`dts.sort(lambda x, y : -1 if (x.conf - y.conf) > 0 else 1)`
refactor python ROC script and add axis ticks 12 years ago
add detection to ground truth matching according to Piotr Dollar paper 12 years ago			`for dt in dts:`
			`dt.crop(crop_factor)`

			`return dts`

refactor python ROC script and add axis ticks 12 years ago			`""" Create new instance of soft cascade."""`
add ROC estimation in the same way as Dallar's matlab toolbox does 12 years ago			`def cascade(min_scale, max_scale, nscales, f):`
			`# where we use nms cv::SCascade::DOLLAR == 2`
			`c = cv2.SCascade(min_scale, max_scale, nscales, 2)`
			`xml = cv2.FileStorage(f, 0)`
			`dom = xml.getFirstTopLevelNode()`
			`assert c.load(dom)`
			`return c`

ROC script refactoring 12 years ago			`""" Compute prefix sum for en array."""`
add ROC estimation in the same way as Dallar's matlab toolbox does 12 years ago			`def cumsum(n):`
			`cum = []`
			`y = 0`
			`for i in n:`
			`y += i`
			`cum.append(y)`
			`return cum`

ROC script refactoring 12 years ago			`""" Compute x and y arrays for ROC plot."""`
improve ROC test script: handle ignored 12 years ago			`def computeROC(confidenses, tp, nannotated, nframes, ignored):`
			`confidenses, tp, ignored = zip(*sorted(zip(confidenses, tp, ignored), reverse = True))`
add ROC estimation in the same way as Dallar's matlab toolbox does 12 years ago
			`fp = [(1 - x) for x in tp]`
improve ROC test script: handle ignored 12 years ago			`fp = [(x - y) for x, y in izip(fp, ignored)]`

add ROC estimation in the same way as Dallar's matlab toolbox does 12 years ago			`fp = cumsum(fp)`
			`tp = cumsum(tp)`
			`miss_rate = [(1 - x / (nannotated + 0.000001)) for x in tp]`
			`fppi = [x / float(nframes) for x in fp]`

			`return fppi, miss_rate`

ROC script refactoring 12 years ago			`""" Crop rectangle by factor."""`
add detection to ground truth matching according to Piotr Dollar paper 12 years ago			`def crop_rect(rect, factor):`
			`val_x = factor * float(rect[2])`
			`val_y = factor * float(rect[3])`
			`x = [int(rect[0] + val_x), int(rect[1] + val_y), int(rect[2] - 2.0 * val_x), int(rect[3] - 2.0 * val_y)]`
			`return x`

ROC script refactoring 12 years ago			`""" Initialize plot axises."""`
add legend for ROC plot 12 years ago			`def initPlot(name):`
add plotting function (matplotlib required) 12 years ago			`plt.xlabel("fppi")`
			`plt.ylabel("miss rate")`
refactor python ROC script and add axis ticks 12 years ago			`plt.title(name)`
add plotting function (matplotlib required) 12 years ago			`plt.grid(True)`
			`plt.xscale('log')`
add ROC estimation in the same way as Dallar's matlab toolbox does 12 years ago			`plt.yscale('log')`

add legend for ROC plot 12 years ago			`""" Draw plot."""`
			`def plotLogLog(fppi, miss_rate, c):`
			`plt.loglog(fppi, miss_rate, color = c, linewidth = 2)`

ROC script refactoring 12 years ago			`""" Show resulted plot."""`
add legend for ROC plot 12 years ago			`def showPlot(file_name, labels):`
			`plt.axis((pow(10, -3), pow(10, 1), .035, 1))`
refactor python ROC script and add axis ticks 12 years ago			`plt.yticks( [0.05, 0.1, 0.2, 0.3, 0.4, 0.5, 0.64, 0.8, 1], ['.05', '.10', '.20', '.30', '.40', '.50', '.64', '.80', '1'] )`
add legend for ROC plot 12 years ago			`plt.legend(labels, loc = "lower left")`
			`plt.savefig(file_name)`
add plotting function (matplotlib required) 12 years ago			`plt.show()`

ROC script refactoring 12 years ago			`""" Filter true positives and ignored detections for cascade detector output."""`
refactor python ROC script and add axis ticks 12 years ago			`def match(gts, dts):`
improve ROC test script: handle ignored 12 years ago			`matches_gt = [0]*len(gts)`
			`matches_dt = [0]*len(dts)`
			`matches_ignore = [0]*len(dts)`
refactor python ROC script and add axis ticks 12 years ago
add parameter to control range and extended range for annotations 12 years ago			`if len(gts) == 0:`
			`return matches_dt, matches_ignore`

			`# Cartesian product for each detection BB_dt with each BB_gt`
			`overlaps = [[dt.overlap(gt) for gt in gts]for dt in dts]`

refactor python ROC script and add axis ticks 12 years ago			`for idx, row in enumerate(overlaps):`
			`imax = row.index(max(row))`

ROC script refactoring 12 years ago			`# try to match ground truth`
refactor python ROC script and add axis ticks 12 years ago			`if (matches_gt[imax] == 0 and row[imax] > 0.5):`
			`matches_gt[imax] = 1`
			`matches_dt[idx] = 1`
improve ROC test script: handle ignored 12 years ago
			`for idx, dt in enumerate(dts):`
			`# try to math ignored`
			`if matches_dt[idx] == 0:`
			`row = gts`
			`row = [i for i in row if (i[3] - i[1]) < 53 or (i[3] - i[1]) > 256]`
			`for each in row:`
			`if dts[idx].overlapIgnored(each) > 0.5:`
			`matches_ignore[idx] = 1`
			`return matches_dt, matches_ignore`
refactor python ROC script and add axis ticks 12 years ago
allow multiple detectors 12 years ago
ROC script refactoring 12 years ago			`""" Draw detections or ground truth on image."""`
caltech ROC test: - parse idl - replase option parser with argument parser 12 years ago			`def draw_rects(img, rects, color, l = lambda x, y : x + y):`
			`if rects is not None:`
			`for x1, y1, x2, y2 in rects:`
			`cv2.rectangle(img, (x1, y1), (l(x1, x2), l(y1, y2)), color, 2)`

ROC script refactoring 12 years ago
add cropping and aspect ratio normalization 12 years ago			`def draw_dt(img, dts, color, l = lambda x, y : x + y):`
			`if dts is not None:`
			`for dt in dts:`
			`bb = dt.bb`
			`x1, y1, x2, y2 = dt.bb[0], dt.bb[1], dt.bb[2], dt.bb[3]`

			`cv2.rectangle(img, (x1, y1), (l(x1, x2), l(y1, y2)), color, 2)`

ROC test: add overlap calculation according to Pascal criteria 12 years ago			`class Detection:`
			`def __init__(self, bb, conf):`
			`self.bb = bb`
			`self.conf = conf`
add plotting function (matplotlib required) 12 years ago			`self.matched = False`

add cropping and aspect ratio normalization 12 years ago			`def crop(self, factor):`
			`self.bb = crop_rect(self.bb, factor)`
ROC test: add overlap calculation according to Pascal criteria 12 years ago
refactor python ROC script and add axis ticks 12 years ago			`# we use rect-style for dt and box style for gt. ToDo: fix it`
ROC test: add overlap calculation according to Pascal criteria 12 years ago			`def overlap(self, b):`
add detection to ground truth matching according to Piotr Dollar paper 12 years ago
ROC test: add overlap calculation according to Pascal criteria 12 years ago			`a = self.bb`
add plotting function (matplotlib required) 12 years ago			`w = min( a[0] + a[2], b[2]) - max(a[0], b[0]);`
			`h = min( a[1] + a[3], b[3]) - max(a[1], b[1]);`
ROC test: add overlap calculation according to Pascal criteria 12 years ago
			`cross_area = 0.0 if (w < 0 or h < 0) else float(w * h)`
			`union_area = (a[2] * a[3]) + ((b[2] - b[0]) * (b[3] - b[1])) - cross_area;`

add plotting function (matplotlib required) 12 years ago			`return cross_area / union_area`

improve ROC test script: handle ignored 12 years ago			`# we use rect-style for dt and box style for gt. ToDo: fix it`
			`def overlapIgnored(self, b):`

			`a = self.bb`
			`w = min( a[0] + a[2], b[2]) - max(a[0], b[0]);`
			`h = min( a[1] + a[3], b[3]) - max(a[1], b[1]);`

			`cross_area = 0.0 if (w < 0 or h < 0) else float(w * h)`
			`self_area = (a[2] * a[3]);`

			`return cross_area / self_area`

add plotting function (matplotlib required) 12 years ago			`def mark_matched(self):`
			`self.matched = True`
ROC test: add overlap calculation according to Pascal criteria 12 years ago
ROC script refactoring 12 years ago			`"""Parse INPIA annotation format"""`
caltech ROC test: - parse idl - replase option parser with argument parser 12 years ago			`def parse_inria(ipath, f):`
			`bbs = []`
			`path = None`
			`for l in f:`
			`box = None`
			`if l.startswith("Bounding box"):`
			`b = [x.strip() for x in l.split(":")[1].split("-")]`
			`c = [x[1:-1].split(",") for x in b]`
			`d = [int(x) for x in sum(c, [])]`
			`bbs.append(d)`

			`if l.startswith("Image filename"):`
			`path = l.split('"')[-2]`

			`return Sample(path, bbs)`

ROC script refactoring 12 years ago
caltech ROC test: - parse idl - replase option parser with argument parser 12 years ago			`def glob_set(pattern):`
ROC script refactoring 12 years ago			`return [__n for __n in glob.iglob(pattern)]`
caltech ROC test: - parse idl - replase option parser with argument parser 12 years ago
ROC script refactoring 12 years ago			`""" Parse ETH idl file. """`
caltech ROC test: - parse idl - replase option parser with argument parser 12 years ago			`def parse_idl(f):`
			`map = {}`
			`for l in open(f):`
			`l = re.sub(r"^\"left\/", "{\"", l)`
			`l = re.sub(r"\:", ":[", l)`
			`l = re.sub(r"(\;\|\.)$", "]}", l)`
			`map.update(eval(l))`
ROC test: add overlap calculation according to Pascal criteria 12 years ago			`return map`

ROC script refactoring 12 years ago			`""" Normalize detection box to unified aspect ration."""`
add cropping and aspect ratio normalization 12 years ago			`def norm_box(box, ratio):`
			`middle = float(box[0] + box[2]) / 2.0`
			`new_half_width = float(box[3] - box[1]) * ratio / 2.0`
			`return (int(round(middle - new_half_width)), box[1], int(round(middle + new_half_width)), box[3])`

ROC script refactoring 12 years ago			`""" Process array of boxes."""`
add cropping and aspect ratio normalization 12 years ago			`def norm_acpect_ratio(boxes, ratio):`
ROC script refactoring 12 years ago			`return [ norm_box(box, ratio) for box in boxes]`

			`""" Filter detections out of extended range. """`
			`def filter_for_range(boxes, scale_range, ext_ratio):`
add legend for ROC plot 12 years ago			`boxes = norm_acpect_ratio(boxes, 0.5)`
ROC script refactoring 12 years ago			`boxes = [b for b in boxes if (b[3] - b[1]) > scale_range[0] / ext_ratio]`
			`boxes = [b for b in boxes if (b[3] - b[1]) < scale_range[1] * ext_ratio]`
			`return boxes`

			`""" Resize sample for training."""`
			`def resize_sample(image, d_w, d_h):`
			`h, w, _ = image.shape`
			`if (d_h < h) or (d_w < w):`
			`ratio = min(d_h / float(h), d_w / float(w))`

			`kernel_size = int( 5 / (2 * ratio))`
			`sigma = 0.5 / ratio`
			`image_to_resize = cv2.filter2D(image, cv2.CV_8UC3, cv2.getGaussianKernel(kernel_size, sigma))`
			`interpolation_type = cv2.INTER_AREA`
			`else:`
			`image_to_resize = image`
			`interpolation_type = cv2.INTER_CUBIC`

parse Caltech annotations 12 years ago			`return cv2.resize(image_to_resize,(d_w, d_h), None, 0, 0, interpolation_type)`

			`newobj = re.compile("^lbl=\'(\w+)\'\s+str=(\d+)\s+end=(\d+)\s+hide=0$")`

			`class caltech:`
			`@staticmethod`
			`def extract_objects(f):`
			`objects = []`
			`tmp = []`
			`for l in f:`
			`if newobj.match(l) is not None:`
			`objects.append(tmp)`
			`tmp = []`
			`tmp.append(l)`
			`return objects[1:]`

			`@staticmethod`
			`def parse_header(f):`
			`_ = f.readline() # skip first line (version string)`
			`head = f.readline()`
			`(nFrame, nSample) = re.search(r'nFrame=(\d+) n=(\d+)', head).groups()`
			`return (int(nFrame), int(nSample))`

			`@staticmethod`
			`def parse_pos(l):`
			`pos = re.match(r'^posv?\s*=(\[[\d\s\.\;]+\])$', l).group(1)`
			`pos = re.sub(r"(\[)(\d)", "\\1[\\2", pos)`
			`pos = re.sub(r"\s", ", ", re.sub(r"\;\s+(?=\])", "]", re.sub(r"\;\s+(?!\])", "],[", pos)))`
			`return eval(pos)`

			`@staticmethod`
			`def parse_occl(l):`
			`occl = re.match(r'^occl\s*=(\[[\d\s\.\;]+\])$', l).group(1)`
			`occl = re.sub(r"\s(?!\])", ",", occl)`
refactor python 12 years ago			`return eval(occl)`

			`def parse_caltech(f):`
			`(nFrame, nSample) = caltech.parse_header(f)`
			`objects = caltech.extract_objects(f)`

			`annotations = [[] for i in range(nFrame)]`
			`for obj in objects:`
			`(type, start, end) = re.search(r'^lbl=\'(\w+)\'\s+str=(\d+)\s+end=(\d+)\s+hide=0$', obj[0]).groups()`
			`print type, start, end`
			`start = int(start) -1`
			`end = int(end)`
			`pos = caltech.parse_pos(obj[1])`
			`posv = caltech.parse_pos(obj[2])`
			`occl = caltech.parse_occl(obj[3])`

			`for idx, (p, pv, oc) in enumerate(zip(*[pos, posv, occl])):`
			`annotations[start + idx].append((type, p, oc, pv))`

			`return annotations`