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data.py
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data.py
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"""
Class for managing our data.
"""
import csv
import numpy as np
import random
import glob
import os.path
import sys
import operator
import threading
from processor import process_image
from keras.utils import to_categorical
class threadsafe_iterator:
def __init__(self, iterator):
self.iterator = iterator
self.lock = threading.Lock()
def __iter__(self):
return self
def __next__(self):
with self.lock:
return next(self.iterator)
def threadsafe_generator(func):
"""Decorator"""
def gen(*a, **kw):
return threadsafe_iterator(func(*a, **kw))
return gen
class DataSet():
def __init__(self, seq_length=40, class_limit=None, image_shape=(224, 224, 3)):
"""Constructor.
seq_length = (int) the number of frames to consider
class_limit = (int) number of classes to limit the data to.
None = no limit.
"""
self.seq_length = seq_length
self.class_limit = class_limit
self.sequence_path = os.path.join('data', 'sequences')
self.max_frames = 300 # max number of frames a video can have for us to use it
# Get the data.
self.data = self.get_data()
# Get the classes.
self.classes = self.get_classes()
# Now do some minor data cleaning.
self.data = self.clean_data()
self.image_shape = image_shape
@staticmethod
def get_data():
"""Load our data from file."""
with open(os.path.join('data', 'data_file.csv'), 'r') as fin:
reader = csv.reader(fin)
data = list(reader)
return data
def clean_data(self):
"""Limit samples to greater than the sequence length and fewer
than N frames. Also limit it to classes we want to use."""
data_clean = []
for item in self.data:
if int(item[3]) >= self.seq_length and int(item[3]) <= self.max_frames \
and item[1] in self.classes:
data_clean.append(item)
return data_clean
def get_classes(self):
"""Extract the classes from our data. If we want to limit them,
only return the classes we need."""
classes = []
for item in self.data:
if item[1] not in classes:
classes.append(item[1])
# Sort them.
classes = sorted(classes)
# Return.
if self.class_limit is not None:
return classes[:self.class_limit]
else:
return classes
def get_class_one_hot(self, class_str):
"""Given a class as a string, return its number in the classes
list. This lets us encode and one-hot it for training."""
# Encode it first.
label_encoded = self.classes.index(class_str)
# Now one-hot it.
label_hot = to_categorical(label_encoded, len(self.classes))
assert len(label_hot) == len(self.classes)
return label_hot
def split_train_test(self):
"""Split the data into train and test groups."""
train = []
test = []
for item in self.data:
if item[0] == 'train':
train.append(item)
else:
test.append(item)
return train, test
def get_all_sequences_in_memory(self, train_test, data_type):
"""
This is a mirror of our generator, but attempts to load everything into
memory so we can train way faster.
"""
# Get the right dataset.
train, test = self.split_train_test()
data = train if train_test == 'train' else test
print("Loading %d samples into memory for %sing." % (len(data), train_test))
X, y = [], []
for row in data:
if data_type == 'images':
frames = self.get_frames_for_sample(row)
frames = self.rescale_list(frames, self.seq_length)
# Build the image sequence
sequence = self.build_image_sequence(frames)
else:
sequence = self.get_extracted_sequence(data_type, row)
if sequence is None:
print("Can't find sequence. Did you generate them?")
raise
X.append(sequence)
y.append(self.get_class_one_hot(row[1]))
return np.array(X), np.array(y)
@threadsafe_generator
def frame_generator(self, batch_size, train_test, data_type):
"""Return a generator that we can use to train on. There are
a couple different things we can return:
data_type: 'features', 'images'
"""
# Get the right dataset for the generator.
train, test = self.split_train_test()
data = train if train_test == 'train' else test
print("Creating %s generator with %d samples." % (train_test, len(data)))
while 1:
X, y = [], []
# Generate batch_size samples.
for _ in range(batch_size):
# Reset to be safe.
sequence = None
# Get a random sample.
sample = random.choice(data)
# Check to see if we've already saved this sequence.
if data_type is "images":
# Get and resample frames.
frames = self.get_frames_for_sample(sample)
frames = self.rescale_list(frames, self.seq_length)
# Build the image sequence
sequence = self.build_image_sequence(frames)
else:
# Get the sequence from disk.
sequence = self.get_extracted_sequence(data_type, sample)
if sequence is None:
raise ValueError("Can't find sequence. Did you generate them?")
X.append(sequence)
y.append(self.get_class_one_hot(sample[1]))
yield np.array(X), np.array(y)
def build_image_sequence(self, frames):
"""Given a set of frames (filenames), build our sequence."""
return [process_image(x, self.image_shape) for x in frames]
def get_extracted_sequence(self, data_type, sample):
"""Get the saved extracted features."""
filename = sample[2]
path = os.path.join(self.sequence_path, filename + '-' + str(self.seq_length) + \
'-' + data_type + '.npy')
if os.path.isfile(path):
return np.load(path)
else:
return None
def get_frames_by_filename(self, filename, data_type):
"""Given a filename for one of our samples, return the data
the model needs to make predictions."""
# First, find the sample row.
sample = None
for row in self.data:
if row[2] == filename:
sample = row
break
if sample is None:
raise ValueError("Couldn't find sample: %s" % filename)
if data_type == "images":
# Get and resample frames.
frames = self.get_frames_for_sample(sample)
frames = self.rescale_list(frames, self.seq_length)
# Build the image sequence
sequence = self.build_image_sequence(frames)
else:
# Get the sequence from disk.
sequence = self.get_extracted_sequence(data_type, sample)
if sequence is None:
raise ValueError("Can't find sequence. Did you generate them?")
return sequence
@staticmethod
def get_frames_for_sample(sample):
"""Given a sample row from the data file, get all the corresponding frame
filenames."""
path = os.path.join('data', sample[0], sample[1])
filename = sample[2]
images = sorted(glob.glob(os.path.join(path, filename + '*jpg')))
return images
@staticmethod
def get_filename_from_image(filename):
parts = filename.split(os.path.sep)
return parts[-1].replace('.jpg', '')
@staticmethod
def rescale_list(input_list, size):
"""Given a list and a size, return a rescaled/samples list. For example,
if we want a list of size 5 and we have a list of size 25, return a new
list of size five which is every 5th element of the origina list."""
assert len(input_list) >= size
# Get the number to skip between iterations.
skip = len(input_list) // size
# Build our new output.
output = [input_list[i] for i in range(0, len(input_list), skip)]
# Cut off the last one if needed.
return output[:size]
def print_class_from_prediction(self, predictions, nb_to_return=5):
"""Given a prediction, print the top classes."""
# Get the prediction for each label.
label_predictions = {}
for i, label in enumerate(self.classes):
label_predictions[label] = predictions[i]
# Now sort them.
sorted_lps = sorted(
label_predictions.items(),
key=operator.itemgetter(1),
reverse=True
)
# And return the top N.
for i, class_prediction in enumerate(sorted_lps):
if i > nb_to_return - 1 or class_prediction[1] == 0.0:
break
print("%s: %.2f" % (class_prediction[0], class_prediction[1]))