darknet/scripts/voc_eval.py

# --------------------------------------------------------
# Fast/er R-CNN
# Licensed under The MIT License [see LICENSE for details]
# Written by Bharath Hariharan
# --------------------------------------------------------

import xml.etree.ElementTree as ET
import os
import cPickle
import numpy as np

def parse_rec(filename):
    """ Parse a PASCAL VOC xml file """
    tree = ET.parse(filename)
    objects = []
    for obj in tree.findall('object'):
        obj_struct = {}
        obj_struct['name'] = obj.find('name').text
        #obj_struct['pose'] = obj.find('pose').text
        #obj_struct['truncated'] = int(obj.find('truncated').text)
        obj_struct['difficult'] = int(obj.find('difficult').text)
        bbox = obj.find('bndbox')
        obj_struct['bbox'] = [int(bbox.find('xmin').text),
                              int(bbox.find('ymin').text),
                              int(bbox.find('xmax').text),
                              int(bbox.find('ymax').text)]
        objects.append(obj_struct)

    return objects

def voc_ap(rec, prec, use_07_metric=False):
    """ ap = voc_ap(rec, prec, [use_07_metric])
    Compute VOC AP given precision and recall.
    If use_07_metric is true, uses the
    VOC 07 11 point method (default:False).
    """
    if use_07_metric:
        # 11 point metric
        ap = 0.
        for t in np.arange(0., 1.1, 0.1):
            if np.sum(rec >= t) == 0:
                p = 0
            else:
                p = np.max(prec[rec >= t])
            ap = ap + p / 11.
    else:
        # correct AP calculation
        # first append sentinel values at the end
        mrec = np.concatenate(([0.], rec, [1.]))
        mpre = np.concatenate(([0.], prec, [0.]))

        # compute the precision envelope
        for i in range(mpre.size - 1, 0, -1):
            mpre[i - 1] = np.maximum(mpre[i - 1], mpre[i])

        # to calculate area under PR curve, look for points
        # where X axis (recall) changes value
        i = np.where(mrec[1:] != mrec[:-1])[0]

        # and sum (\Delta recall) * prec
        ap = np.sum((mrec[i + 1] - mrec[i]) * mpre[i + 1])
    return ap

def voc_eval(detpath,
             annopath,
             imagesetfile,
             classname,
             cachedir,
             ovthresh=0.5,
             use_07_metric=False):
    """rec, prec, ap = voc_eval(detpath,
                                annopath,
                                imagesetfile,
                                classname,
                                [ovthresh],
                                [use_07_metric])

    Top level function that does the PASCAL VOC evaluation.

    detpath: Path to detections
        detpath.format(classname) should produce the detection results file.
    annopath: Path to annotations
        annopath.format(imagename) should be the xml annotations file.
    imagesetfile: Text file containing the list of images, one image per line.
    classname: Category name (duh)
    cachedir: Directory for caching the annotations
    [ovthresh]: Overlap threshold (default = 0.5)
    [use_07_metric]: Whether to use VOC07's 11 point AP computation
        (default False)
    """
    # assumes detections are in detpath.format(classname)
    # assumes annotations are in annopath.format(imagename)
    # assumes imagesetfile is a text file with each line an image name
    # cachedir caches the annotations in a pickle file

    # first load gt
    if not os.path.isdir(cachedir):
        os.mkdir(cachedir)
    cachefile = os.path.join(cachedir, 'annots.pkl')
    # read list of images
    with open(imagesetfile, 'r') as f:
        lines = f.readlines()
    imagenames = [x.strip() for x in lines]

    if not os.path.isfile(cachefile):
        # load annots
        recs = {}
        for i, imagename in enumerate(imagenames):
            recs[imagename] = parse_rec(annopath.format(imagename))
            if i % 100 == 0:
                print 'Reading annotation for {:d}/{:d}'.format(
                    i + 1, len(imagenames))
        # save
        print 'Saving cached annotations to {:s}'.format(cachefile)
        with open(cachefile, 'w') as f:
            cPickle.dump(recs, f)
    else:
        # load
        with open(cachefile, 'r') as f:
            recs = cPickle.load(f)

    # extract gt objects for this class
    class_recs = {}
    npos = 0
    for imagename in imagenames:
        R = [obj for obj in recs[imagename] if obj['name'] == classname]
        bbox = np.array([x['bbox'] for x in R])
        difficult = np.array([x['difficult'] for x in R]).astype(np.bool)
        det = [False] * len(R)
        npos = npos + sum(~difficult)
        class_recs[imagename] = {'bbox': bbox,
                                 'difficult': difficult,
                                 'det': det}

    # read dets
    detfile = detpath.format(classname)
    with open(detfile, 'r') as f:
        lines = f.readlines()

    splitlines = [x.strip().split(' ') for x in lines]
    image_ids = [x[0] for x in splitlines]
    confidence = np.array([float(x[1]) for x in splitlines])
    BB = np.array([[float(z) for z in x[2:]] for x in splitlines])

    # sort by confidence
    sorted_ind = np.argsort(-confidence)
    sorted_scores = np.sort(-confidence)
    BB = BB[sorted_ind, :]
    image_ids = [image_ids[x] for x in sorted_ind]

    # go down dets and mark TPs and FPs
    nd = len(image_ids)
    tp = np.zeros(nd)
    fp = np.zeros(nd)
    for d in range(nd):
        R = class_recs[image_ids[d]]
        bb = BB[d, :].astype(float)
        ovmax = -np.inf
        BBGT = R['bbox'].astype(float)

        if BBGT.size > 0:
            # compute overlaps
            # intersection
            ixmin = np.maximum(BBGT[:, 0], bb[0])
            iymin = np.maximum(BBGT[:, 1], bb[1])
            ixmax = np.minimum(BBGT[:, 2], bb[2])
            iymax = np.minimum(BBGT[:, 3], bb[3])
            iw = np.maximum(ixmax - ixmin + 1., 0.)
            ih = np.maximum(iymax - iymin + 1., 0.)
            inters = iw * ih

            # union
            uni = ((bb[2] - bb[0] + 1.) * (bb[3] - bb[1] + 1.) +
                   (BBGT[:, 2] - BBGT[:, 0] + 1.) *
                   (BBGT[:, 3] - BBGT[:, 1] + 1.) - inters)

            overlaps = inters / uni
            ovmax = np.max(overlaps)
            jmax = np.argmax(overlaps)

        if ovmax > ovthresh:
            if not R['difficult'][jmax]:
                if not R['det'][jmax]:
                    tp[d] = 1.
                    R['det'][jmax] = 1
                else:
                    fp[d] = 1.
        else:
            fp[d] = 1.

    # compute precision recall
    fp = np.cumsum(fp)
    tp = np.cumsum(tp)
    rec = tp / float(npos)
    # avoid divide by zero in case the first detection matches a difficult
    # ground truth
    prec = tp / np.maximum(tp + fp, np.finfo(np.float64).eps)
    ap = voc_ap(rec, prec, use_07_metric)

    return rec, prec, ap
Fixed yolo_console_dll.cpp 2017-09-13 18:47:19 +08:00			`# --------------------------------------------------------`
			`# Fast/er R-CNN`
			`# Licensed under The MIT License [see LICENSE for details]`
			`# Written by Bharath Hariharan`
			`# --------------------------------------------------------`

			`import xml.etree.ElementTree as ET`
			`import os`
			`import cPickle`
			`import numpy as np`

			`def parse_rec(filename):`
			`""" Parse a PASCAL VOC xml file """`
			`tree = ET.parse(filename)`
			`objects = []`
			`for obj in tree.findall('object'):`
			`obj_struct = {}`
			`obj_struct['name'] = obj.find('name').text`
			`#obj_struct['pose'] = obj.find('pose').text`
			`#obj_struct['truncated'] = int(obj.find('truncated').text)`
			`obj_struct['difficult'] = int(obj.find('difficult').text)`
			`bbox = obj.find('bndbox')`
			`obj_struct['bbox'] = [int(bbox.find('xmin').text),`
			`int(bbox.find('ymin').text),`
			`int(bbox.find('xmax').text),`
			`int(bbox.find('ymax').text)]`
			`objects.append(obj_struct)`

			`return objects`

			`def voc_ap(rec, prec, use_07_metric=False):`
			`""" ap = voc_ap(rec, prec, [use_07_metric])`
			`Compute VOC AP given precision and recall.`
			`If use_07_metric is true, uses the`
			`VOC 07 11 point method (default:False).`
			`"""`
			`if use_07_metric:`
			`# 11 point metric`
			`ap = 0.`
			`for t in np.arange(0., 1.1, 0.1):`
			`if np.sum(rec >= t) == 0:`
			`p = 0`
			`else:`
			`p = np.max(prec[rec >= t])`
			`ap = ap + p / 11.`
			`else:`
			`# correct AP calculation`
			`# first append sentinel values at the end`
			`mrec = np.concatenate(([0.], rec, [1.]))`
			`mpre = np.concatenate(([0.], prec, [0.]))`

			`# compute the precision envelope`
			`for i in range(mpre.size - 1, 0, -1):`
			`mpre[i - 1] = np.maximum(mpre[i - 1], mpre[i])`

			`# to calculate area under PR curve, look for points`
			`# where X axis (recall) changes value`
			`i = np.where(mrec[1:] != mrec[:-1])[0]`

			`# and sum (\Delta recall) * prec`
			`ap = np.sum((mrec[i + 1] - mrec[i]) * mpre[i + 1])`
			`return ap`

			`def voc_eval(detpath,`
			`annopath,`
			`imagesetfile,`
			`classname,`
			`cachedir,`
			`ovthresh=0.5,`
			`use_07_metric=False):`
			`"""rec, prec, ap = voc_eval(detpath,`
			`annopath,`
			`imagesetfile,`
			`classname,`
			`[ovthresh],`
			`[use_07_metric])`

			`Top level function that does the PASCAL VOC evaluation.`

			`detpath: Path to detections`
			`detpath.format(classname) should produce the detection results file.`
			`annopath: Path to annotations`
			`annopath.format(imagename) should be the xml annotations file.`
			`imagesetfile: Text file containing the list of images, one image per line.`
			`classname: Category name (duh)`
			`cachedir: Directory for caching the annotations`
			`[ovthresh]: Overlap threshold (default = 0.5)`
			`[use_07_metric]: Whether to use VOC07's 11 point AP computation`
			`(default False)`
			`"""`
			`# assumes detections are in detpath.format(classname)`
			`# assumes annotations are in annopath.format(imagename)`
			`# assumes imagesetfile is a text file with each line an image name`
			`# cachedir caches the annotations in a pickle file`

			`# first load gt`
			`if not os.path.isdir(cachedir):`
			`os.mkdir(cachedir)`
			`cachefile = os.path.join(cachedir, 'annots.pkl')`
			`# read list of images`
			`with open(imagesetfile, 'r') as f:`
			`lines = f.readlines()`
			`imagenames = [x.strip() for x in lines]`

			`if not os.path.isfile(cachefile):`
			`# load annots`
			`recs = {}`
			`for i, imagename in enumerate(imagenames):`
			`recs[imagename] = parse_rec(annopath.format(imagename))`
			`if i % 100 == 0:`
			`print 'Reading annotation for {:d}/{:d}'.format(`
			`i + 1, len(imagenames))`
			`# save`
			`print 'Saving cached annotations to {:s}'.format(cachefile)`
			`with open(cachefile, 'w') as f:`
			`cPickle.dump(recs, f)`
			`else:`
			`# load`
			`with open(cachefile, 'r') as f:`
			`recs = cPickle.load(f)`

			`# extract gt objects for this class`
			`class_recs = {}`
			`npos = 0`
			`for imagename in imagenames:`
			`R = [obj for obj in recs[imagename] if obj['name'] == classname]`
			`bbox = np.array([x['bbox'] for x in R])`
			`difficult = np.array([x['difficult'] for x in R]).astype(np.bool)`
			`det = [False] * len(R)`
			`npos = npos + sum(~difficult)`
			`class_recs[imagename] = {'bbox': bbox,`
			`'difficult': difficult,`
			`'det': det}`

			`# read dets`
			`detfile = detpath.format(classname)`
			`with open(detfile, 'r') as f:`
			`lines = f.readlines()`

			`splitlines = [x.strip().split(' ') for x in lines]`
			`image_ids = [x[0] for x in splitlines]`
			`confidence = np.array([float(x[1]) for x in splitlines])`
			`BB = np.array([[float(z) for z in x[2:]] for x in splitlines])`

			`# sort by confidence`
			`sorted_ind = np.argsort(-confidence)`
			`sorted_scores = np.sort(-confidence)`
			`BB = BB[sorted_ind, :]`
			`image_ids = [image_ids[x] for x in sorted_ind]`

			`# go down dets and mark TPs and FPs`
			`nd = len(image_ids)`
			`tp = np.zeros(nd)`
			`fp = np.zeros(nd)`
			`for d in range(nd):`
			`R = class_recs[image_ids[d]]`
			`bb = BB[d, :].astype(float)`
			`ovmax = -np.inf`
			`BBGT = R['bbox'].astype(float)`

			`if BBGT.size > 0:`
			`# compute overlaps`
			`# intersection`
			`ixmin = np.maximum(BBGT[:, 0], bb[0])`
			`iymin = np.maximum(BBGT[:, 1], bb[1])`
			`ixmax = np.minimum(BBGT[:, 2], bb[2])`
			`iymax = np.minimum(BBGT[:, 3], bb[3])`
			`iw = np.maximum(ixmax - ixmin + 1., 0.)`
			`ih = np.maximum(iymax - iymin + 1., 0.)`
			`inters = iw * ih`

			`# union`
			`uni = ((bb[2] - bb[0] + 1.) * (bb[3] - bb[1] + 1.) +`
			`(BBGT[:, 2] - BBGT[:, 0] + 1.) *`
			`(BBGT[:, 3] - BBGT[:, 1] + 1.) - inters)`

			`overlaps = inters / uni`
			`ovmax = np.max(overlaps)`
			`jmax = np.argmax(overlaps)`

			`if ovmax > ovthresh:`
			`if not R['difficult'][jmax]:`
			`if not R['det'][jmax]:`
			`tp[d] = 1.`
			`R['det'][jmax] = 1`
			`else:`
			`fp[d] = 1.`
			`else:`
			`fp[d] = 1.`

			`# compute precision recall`
			`fp = np.cumsum(fp)`
			`tp = np.cumsum(tp)`
			`rec = tp / float(npos)`
			`# avoid divide by zero in case the first detection matches a difficult`
			`# ground truth`
			`prec = tp / np.maximum(tp + fp, np.finfo(np.float64).eps)`
			`ap = voc_ap(rec, prec, use_07_metric)`

			`return rec, prec, ap`