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helper.py
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helper.py
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# CIFAR - 10
# To decode the files
import pickle
# For array manipulations
import numpy as np
# To make one-hot vectors
from keras.utils import np_utils
# To plot graphs and display images
from matplotlib import pyplot as plt
#constants
path = "data/" # Path to data
# Height or width of the images (32 x 32)
size = 32
# 3 channels: Red, Green, Blue (RGB)
channels = 3
# Number of classes
num_classes = 10
# Each file contains 10000 images
image_batch = 10000
# 5 training files
num_files_train = 5
# Total number of training images
images_train = image_batch * num_files_train
# https://www.cs.toronto.edu/~kriz/cifar.html
def unpickle(file):
# Convert byte stream to object
with open(path + file,'rb') as fo:
print("Decoding file: %s" % (path+file))
dict = pickle.load(fo, encoding='bytes')
# Dictionary with images and labels
return dict
def convert_images(raw_images):
# Convert images to numpy arrays
# Convert raw images to numpy array and normalize it
raw = np.array(raw_images, dtype = float) / 255.0
# Reshape to 4-dimensions - [image_number, channel, height, width]
images = raw.reshape([-1, channels, size, size])
images = images.transpose([0, 2, 3, 1])
# 4D array - [image_number, height, width, channel]
return images
def load_data(file):
# Load file, unpickle it and return images with their labels
data = unpickle(file)
# Get raw images
images_array = data[b'data']
# Convert image
images = convert_images(images_array)
# Convert class number to numpy array
labels = np.array(data[b'labels'])
# Images and labels in np array form
return images, labels
def get_test_data():
# Load all test data
images, labels = load_data(file = "test_batch")
# Images, their labels and
# corresponding one-hot vectors in form of np arrays
return images, labels, np_utils.to_categorical(labels,num_classes)
def get_train_data():
# Load all training data in 5 files
# Pre-allocate arrays
images = np.zeros(shape = [images_train, size, size, channels], dtype = float)
labels = np.zeros(shape=[images_train],dtype = int)
# Starting index of training dataset
start = 0
# For all 5 files
for i in range(num_files_train):
# Load images and labels
images_batch, labels_batch = load_data(file = "data_batch_" + str(i+1))
# Calculate end index for current batch
end = start + image_batch
# Store data to corresponding arrays
images[start:end,:] = images_batch
labels[start:end] = labels_batch
# Update starting index of next batch
start = end
# Images, their labels and
# corresponding one-hot vectors in form of np arrays
return images, labels, np_utils.to_categorical(labels,num_classes)
def get_class_names():
# Load class names
raw = unpickle("batches.meta")[b'label_names']
# Convert from binary strings
names = [x.decode('utf-8') for x in raw]
# Class names
return names
def plot_images(images, labels_true, class_names, labels_pred=None):
assert len(images) == len(labels_true)
# Create a figure with sub-plots
fig, axes = plt.subplots(3, 3, figsize = (8,8))
# Adjust the vertical spacing
if labels_pred is None:
hspace = 0.2
else:
hspace = 0.5
fig.subplots_adjust(hspace=hspace, wspace=0.3)
for i, ax in enumerate(axes.flat):
# Fix crash when less than 9 images
if i < len(images):
# Plot the image
ax.imshow(images[i], interpolation='spline16')
# Name of the true class
labels_true_name = class_names[labels_true[i]]
# Show true and predicted classes
if labels_pred is None:
xlabel = "True: "+labels_true_name
else:
# Name of the predicted class
labels_pred_name = class_names[labels_pred[i]]
xlabel = "True: "+labels_true_name+"\nPredicted: "+ labels_pred_name
# Show the class on the x-axis
ax.set_xlabel(xlabel)
# Remove ticks from the plot
ax.set_xticks([])
ax.set_yticks([])
# Show the plot
plt.show()
def plot_model(model_details):
# Create sub-plots
fig, axs = plt.subplots(1,2,figsize=(15,5))
# Summarize history for accuracy
axs[0].plot(range(1,len(model_details.history['acc'])+1),model_details.history['acc'])
axs[0].plot(range(1,len(model_details.history['val_acc'])+1),model_details.history['val_acc'])
axs[0].set_title('Model Accuracy')
axs[0].set_ylabel('Accuracy')
axs[0].set_xlabel('Epoch')
axs[0].set_xticks(np.arange(1,len(model_details.history['acc'])+1),len(model_details.history['acc'])/10)
axs[0].legend(['train', 'val'], loc='best')
# Summarize history for loss
axs[1].plot(range(1,len(model_details.history['loss'])+1),model_details.history['loss'])
axs[1].plot(range(1,len(model_details.history['val_loss'])+1),model_details.history['val_loss'])
axs[1].set_title('Model Loss')
axs[1].set_ylabel('Loss')
axs[1].set_xlabel('Epoch')
axs[1].set_xticks(np.arange(1,len(model_details.history['loss'])+1),len(model_details.history['loss'])/10)
axs[1].legend(['train', 'val'], loc='best')
# Show the plot
plt.show()
def visualize_errors(images_test, labels_test, class_names, labels_pred, correct):
incorrect = (correct == False)
# Images of the test-set that have been incorrectly classified.
images_error = images_test[incorrect]
# Get predicted classes for those images
labels_error = labels_pred[incorrect]
# Get true classes for those images
labels_true = labels_test[incorrect]
# Plot the first 9 images.
plot_images(images=images_error[0:9],
labels_true=labels_true[0:9],
class_names=class_names,
labels_pred=labels_error[0:9])
def predict_classes(model, images_test, labels_test):
# Predict class of image using model
class_pred = model.predict(images_test, batch_size=32)
# Convert vector to a label
labels_pred = np.argmax(class_pred,axis=1)
# Boolean array that tell if predicted label is the true label
correct = (labels_pred == labels_test)
# Array which tells if the prediction is correct or not
# And predicted labels
return correct, labels_pred