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evaluation.py
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evaluation.py
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from __future__ import print_function
import os
import pickle
import numpy
from data import get_test_loader
import time
import numpy as np
from vocab import Vocabulary # NOQA
import torch
from model import VSE, order_sim
from collections import OrderedDict
class AverageMeter(object):
"""Computes and stores the average and current value"""
def __init__(self):
self.reset()
def reset(self):
self.val = 0
self.avg = 0
self.sum = 0
self.count = 0
def update(self, val, n=0):
self.val = val
self.sum += val * n
self.count += n
self.avg = self.sum / (.0001 + self.count)
def __str__(self):
"""String representation for logging
"""
# for values that should be recorded exactly e.g. iteration number
if self.count == 0:
return str(self.val)
# for stats
return '%.4f (%.4f)' % (self.val, self.avg)
class LogCollector(object):
"""A collection of logging objects that can change from train to val"""
def __init__(self):
# to keep the order of logged variables deterministic
self.meters = OrderedDict()
def update(self, k, v, n=0):
# create a new meter if previously not recorded
if k not in self.meters:
self.meters[k] = AverageMeter()
self.meters[k].update(v, n)
def __str__(self):
"""Concatenate the meters in one log line
"""
s = ''
for i, (k, v) in enumerate(self.meters.iteritems()):
if i > 0:
s += ' '
s += k + ' ' + str(v)
return s
def tb_log(self, tb_logger, prefix='', step=None):
"""Log using tensorboard
"""
for k, v in self.meters.iteritems():
tb_logger.log_value(prefix + k, v.val, step=step)
def encode_data(model, data_loader, log_step=10, logging=print):
"""Encode all images and captions loadable by `data_loader`
"""
batch_time = AverageMeter()
val_logger = LogCollector()
# switch to evaluate mode
model.val_start()
end = time.time()
# numpy array to keep all the embeddings
img_embs = None
cap_embs = None
for i, (images, captions, lengths, ids) in enumerate(data_loader):
# make sure val logger is used
model.logger = val_logger
# compute the embeddings
img_emb, cap_emb = model.forward_emb(images, captions, lengths,
volatile=True)
# initialize the numpy arrays given the size of the embeddings
if img_embs is None:
img_embs = np.zeros((len(data_loader.dataset), img_emb.size(1)))
cap_embs = np.zeros((len(data_loader.dataset), cap_emb.size(1)))
# preserve the embeddings by copying from gpu and converting to numpy
img_embs[ids] = img_emb.data.cpu().numpy().copy()
cap_embs[ids] = cap_emb.data.cpu().numpy().copy()
# measure accuracy and record loss
model.forward_loss(img_emb, cap_emb)
# measure elapsed time
batch_time.update(time.time() - end)
end = time.time()
if i % log_step == 0:
logging('Test: [{0}/{1}]\t'
'{e_log}\t'
'Time {batch_time.val:.3f} ({batch_time.avg:.3f})\t'
.format(
i, len(data_loader), batch_time=batch_time,
e_log=str(model.logger)))
del images, captions
return img_embs, cap_embs
def evalrank(model_path, data_path=None, split='dev', fold5=False):
"""
Evaluate a trained model on either dev or test. If `fold5=True`, 5 fold
cross-validation is done (only for MSCOCO). Otherwise, the full data is
used for evaluation.
"""
# load model and options
checkpoint = torch.load(model_path)
opt = checkpoint['opt']
if data_path is not None:
opt.data_path = data_path
# load vocabulary used by the model
with open(os.path.join(opt.vocab_path,
'%s_vocab.pkl' % opt.data_name), 'rb') as f:
vocab = pickle.load(f)
opt.vocab_size = len(vocab)
# construct model
model = VSE(opt)
# load model state
model.load_state_dict(checkpoint['model'])
print('Loading dataset')
data_loader = get_test_loader(split, opt.data_name, vocab, opt.crop_size,
opt.batch_size, opt.workers, opt)
print('Computing results...')
img_embs, cap_embs = encode_data(model, data_loader)
print('Images: %d, Captions: %d' %
(img_embs.shape[0] / 5, cap_embs.shape[0]))
if not fold5:
# no cross-validation, full evaluation
r, rt = i2t(img_embs, cap_embs, measure=opt.measure, return_ranks=True)
ri, rti = t2i(img_embs, cap_embs,
measure=opt.measure, return_ranks=True)
ar = (r[0] + r[1] + r[2]) / 3
ari = (ri[0] + ri[1] + ri[2]) / 3
rsum = r[0] + r[1] + r[2] + ri[0] + ri[1] + ri[2]
print("rsum: %.1f" % rsum)
print("Average i2t Recall: %.1f" % ar)
print("Image to text: %.1f %.1f %.1f %.1f %.1f" % r)
print("Average t2i Recall: %.1f" % ari)
print("Text to image: %.1f %.1f %.1f %.1f %.1f" % ri)
else:
# 5fold cross-validation, only for MSCOCO
results = []
for i in range(5):
r, rt0 = i2t(img_embs[i * 5000:(i + 1) * 5000],
cap_embs[i * 5000:(i + 1) *
5000], measure=opt.measure,
return_ranks=True)
print("Image to text: %.1f, %.1f, %.1f, %.1f, %.1f" % r)
ri, rti0 = t2i(img_embs[i * 5000:(i + 1) * 5000],
cap_embs[i * 5000:(i + 1) *
5000], measure=opt.measure,
return_ranks=True)
if i == 0:
rt, rti = rt0, rti0
print("Text to image: %.1f, %.1f, %.1f, %.1f, %.1f" % ri)
ar = (r[0] + r[1] + r[2]) / 3
ari = (ri[0] + ri[1] + ri[2]) / 3
rsum = r[0] + r[1] + r[2] + ri[0] + ri[1] + ri[2]
print("rsum: %.1f ar: %.1f ari: %.1f" % (rsum, ar, ari))
results += [list(r) + list(ri) + [ar, ari, rsum]]
print("-----------------------------------")
print("Mean metrics: ")
mean_metrics = tuple(np.array(results).mean(axis=0).flatten())
print("rsum: %.1f" % (mean_metrics[10] * 6))
print("Average i2t Recall: %.1f" % mean_metrics[11])
print("Image to text: %.1f %.1f %.1f %.1f %.1f" %
mean_metrics[:5])
print("Average t2i Recall: %.1f" % mean_metrics[12])
print("Text to image: %.1f %.1f %.1f %.1f %.1f" %
mean_metrics[5:10])
torch.save({'rt': rt, 'rti': rti}, 'ranks.pth.tar')
def i2t(images, captions, npts=None, measure='cosine', return_ranks=False):
"""
Images->Text (Image Annotation)
Images: (5N, K) matrix of images
Captions: (5N, K) matrix of captions
"""
if npts is None:
npts = images.shape[0] / 5
index_list = []
ranks = numpy.zeros(npts)
top1 = numpy.zeros(npts)
for index in range(npts):
# Get query image
im = images[5 * index].reshape(1, images.shape[1])
# Compute scores
if measure == 'order':
bs = 100
if index % bs == 0:
mx = min(images.shape[0], 5 * (index + bs))
im2 = images[5 * index:mx:5]
d2 = order_sim(torch.Tensor(im2).cuda(),
torch.Tensor(captions).cuda())
d2 = d2.cpu().numpy()
d = d2[index % bs]
else:
d = numpy.dot(im, captions.T).flatten()
inds = numpy.argsort(d)[::-1]
index_list.append(inds[0])
# Score
rank = 1e20
for i in range(5 * index, 5 * index + 5, 1):
tmp = numpy.where(inds == i)[0][0]
if tmp < rank:
rank = tmp
ranks[index] = rank
top1[index] = inds[0]
# Compute metrics
r1 = 100.0 * len(numpy.where(ranks < 1)[0]) / len(ranks)
r5 = 100.0 * len(numpy.where(ranks < 5)[0]) / len(ranks)
r10 = 100.0 * len(numpy.where(ranks < 10)[0]) / len(ranks)
medr = numpy.floor(numpy.median(ranks)) + 1
meanr = ranks.mean() + 1
if return_ranks:
return (r1, r5, r10, medr, meanr), (ranks, top1)
else:
return (r1, r5, r10, medr, meanr)
def t2i(images, captions, npts=None, measure='cosine', return_ranks=False):
"""
Text->Images (Image Search)
Images: (5N, K) matrix of images
Captions: (5N, K) matrix of captions
"""
if npts is None:
npts = images.shape[0] / 5
ims = numpy.array([images[i] for i in range(0, len(images), 5)])
ranks = numpy.zeros(5 * npts)
top1 = numpy.zeros(5 * npts)
for index in range(npts):
# Get query captions
queries = captions[5 * index:5 * index + 5]
# Compute scores
if measure == 'order':
bs = 100
if 5 * index % bs == 0:
mx = min(captions.shape[0], 5 * index + bs)
q2 = captions[5 * index:mx]
d2 = order_sim(torch.Tensor(ims).cuda(),
torch.Tensor(q2).cuda())
d2 = d2.cpu().numpy()
d = d2[:, (5 * index) % bs:(5 * index) % bs + 5].T
else:
d = numpy.dot(queries, ims.T)
inds = numpy.zeros(d.shape)
for i in range(len(inds)):
inds[i] = numpy.argsort(d[i])[::-1]
ranks[5 * index + i] = numpy.where(inds[i] == index)[0][0]
top1[5 * index + i] = inds[i][0]
# Compute metrics
r1 = 100.0 * len(numpy.where(ranks < 1)[0]) / len(ranks)
r5 = 100.0 * len(numpy.where(ranks < 5)[0]) / len(ranks)
r10 = 100.0 * len(numpy.where(ranks < 10)[0]) / len(ranks)
medr = numpy.floor(numpy.median(ranks)) + 1
meanr = ranks.mean() + 1
if return_ranks:
return (r1, r5, r10, medr, meanr), (ranks, top1)
else:
return (r1, r5, r10, medr, meanr)