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predict_on_images.py
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predict_on_images.py
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import argparse
import json
import time
import datetime
import numpy as np
import code
import os
import cPickle as pickle
import math
import scipy.io
from imagernn.solver import Solver
from imagernn.imagernn_utils import decodeGenerator, eval_split
"""
This script is used to predict sentences for arbitrary images
that are located in a folder we call root_folder. It is assumed that
the root_folder contains:
- the raw images
- a file tasks.txt that lists the images you'd like to use
- a file vgg_feats.mat that contains the CNN features.
You'll need to use the Matlab script I provided and point it at the
root folder and its tasks.txt file to save the features.
Then point this script at the folder and at a checkpoint model you'd
like to evaluate.
"""
def main(params):
# load the checkpoint
checkpoint_path = params['checkpoint_path']
print 'loading checkpoint %s' % (checkpoint_path, )
checkpoint = pickle.load(open(checkpoint_path, 'rb'))
checkpoint_params = checkpoint['params']
dataset = checkpoint_params['dataset']
model = checkpoint['model']
misc = {}
misc['wordtoix'] = checkpoint['wordtoix']
ixtoword = checkpoint['ixtoword']
# output blob which we will dump to JSON for visualizing the results
blob = {}
blob['params'] = params
blob['checkpoint_params'] = checkpoint_params
blob['imgblobs'] = []
# load the tasks.txt file
root_path = params['root_path']
img_names = open(os.path.join(root_path, 'tasks.txt'), 'r').read().splitlines()
# load the features for all images
features_path = os.path.join(root_path, 'vgg_feats.mat')
features_struct = scipy.io.loadmat(features_path)
features = features_struct['feats'] # this is a 4096 x N numpy array of features
D,N = features.shape
# iterate over all images and predict sentences
BatchGenerator = decodeGenerator(checkpoint_params)
for n in xrange(N):
print 'image %d/%d:' % (n, N)
# encode the image
img = {}
img['feat'] = features[:, n]
img['local_file_path'] =img_names[n]
# perform the work. heavy lifting happens inside
kwparams = { 'beam_size' : params['beam_size'] }
Ys = BatchGenerator.predict([{'image':img}], model, checkpoint_params, **kwparams)
# build up the output
img_blob = {}
img_blob['img_path'] = img['local_file_path']
# encode the top prediction
top_predictions = Ys[0] # take predictions for the first (and only) image we passed in
top_prediction = top_predictions[0] # these are sorted with highest on top
candidate = ' '.join([ixtoword[ix] for ix in top_prediction[1] if ix > 0]) # ix 0 is the END token, skip that
print 'PRED: (%f) %s' % (top_prediction[0], candidate)
img_blob['candidate'] = {'text': candidate, 'logprob': top_prediction[0]}
blob['imgblobs'].append(img_blob)
# dump result struct to file
save_file = os.path.join(root_path, 'result_struct.json')
print 'writing predictions to %s...' % (save_file, )
json.dump(blob, open(save_file, 'w'))
# dump output html
html = ''
for img in blob['imgblobs']:
html += '<img src="%s" height="400"><br>' % (img['img_path'], )
html += '(%f) %s <br><br>' % (img['candidate']['logprob'], img['candidate']['text'])
html_file = os.path.join(root_path, 'result.html')
print 'writing html result file to %s...' % (html_file, )
open(html_file, 'w').write(html)
if __name__ == "__main__":
parser = argparse.ArgumentParser()
parser.add_argument('checkpoint_path', type=str, help='the input checkpoint')
parser.add_argument('-r', '--root_path', default='example_images', type=str, help='folder with the images, tasks.txt file, and corresponding vgg_feats.mat file')
parser.add_argument('-b', '--beam_size', type=int, default=1, help='beam size in inference. 1 indicates greedy per-word max procedure. Good value is approx 20 or so, and more = better.')
args = parser.parse_args()
params = vars(args) # convert to ordinary dict
print 'parsed parameters:'
print json.dumps(params, indent = 2)
main(params)