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try_convnet_cc_multirotflip_3x69r45_shareddense.py
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try_convnet_cc_multirotflip_3x69r45_shareddense.py
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import numpy as np
# import pandas as pd
import theano
import theano.tensor as T
import layers
import cc_layers
import custom
import load_data
import realtime_augmentation as ra
import time
import csv
import os
import cPickle as pickle
from datetime import datetime, timedelta
# import matplotlib.pyplot as plt
# plt.ion()
# import utils
BATCH_SIZE = 16
NUM_INPUT_FEATURES = 3
LEARNING_RATE_SCHEDULE = {
0: 0.04,
1800: 0.004,
2300: 0.0004,
}
MOMENTUM = 0.9
WEIGHT_DECAY = 0.0
CHUNK_SIZE = 10000 # 30000 # this should be a multiple of the batch size, ideally.
NUM_CHUNKS = 2500 # 3000 # 1500 # 600 # 600 # 600 # 500
VALIDATE_EVERY = 20 # 12 # 6 # 6 # 6 # 5 # validate only every 5 chunks. MUST BE A DIVISOR OF NUM_CHUNKS!!!
# else computing the analysis data does not work correctly, since it assumes that the validation set is still loaded.
NUM_CHUNKS_NONORM = 1 # train without normalisation for this many chunks, to get the weights in the right 'zone'.
# this should be only a few, just 1 hopefully suffices.
GEN_BUFFER_SIZE = 1
# # need to load the full training data anyway to extract the validation set from it.
# # alternatively we could create separate validation set files.
# DATA_TRAIN_PATH = "data/images_train_color_cropped33_singletf.npy.gz"
# DATA2_TRAIN_PATH = "data/images_train_color_8x_singletf.npy.gz"
# DATA_VALIDONLY_PATH = "data/images_validonly_color_cropped33_singletf.npy.gz"
# DATA2_VALIDONLY_PATH = "data/images_validonly_color_8x_singletf.npy.gz"
# DATA_TEST_PATH = "data/images_test_color_cropped33_singletf.npy.gz"
# DATA2_TEST_PATH = "data/images_test_color_8x_singletf.npy.gz"
TARGET_PATH = "predictions/final/try_convnet_cc_multirotflip_3x69r45_shareddense.csv"
ANALYSIS_PATH = "analysis/final/try_convnet_cc_multirotflip_3x69r45_shareddense.pkl"
# FEATURES_PATTERN = "features/try_convnet_chunked_ra_b3sched.%s.npy"
print "Set up data loading"
# TODO: adapt this so it loads the validation data from JPEGs and does the processing realtime
input_sizes = [(69, 69), (69, 69)]
ds_transforms = [
ra.build_ds_transform(3.0, target_size=input_sizes[0]),
ra.build_ds_transform(3.0, target_size=input_sizes[1]) + ra.build_augmentation_transform(rotation=45)
]
num_input_representations = len(ds_transforms)
augmentation_params = {
'zoom_range': (1.0 / 1.3, 1.3),
'rotation_range': (0, 360),
'shear_range': (0, 0),
'translation_range': (-4, 4),
'do_flip': True,
}
augmented_data_gen = ra.realtime_augmented_data_gen(num_chunks=NUM_CHUNKS, chunk_size=CHUNK_SIZE,
augmentation_params=augmentation_params, ds_transforms=ds_transforms,
target_sizes=input_sizes)
post_augmented_data_gen = ra.post_augment_brightness_gen(augmented_data_gen, std=0.5)
train_gen = load_data.buffered_gen_mp(post_augmented_data_gen, buffer_size=GEN_BUFFER_SIZE)
y_train = np.load("data/solutions_train.npy")
train_ids = load_data.train_ids
test_ids = load_data.test_ids
# split training data into training + a small validation set
num_train = len(train_ids)
num_test = len(test_ids)
num_valid = num_train // 10 # integer division
num_train -= num_valid
y_valid = y_train[num_train:]
y_train = y_train[:num_train]
valid_ids = train_ids[num_train:]
train_ids = train_ids[:num_train]
train_indices = np.arange(num_train)
valid_indices = np.arange(num_train, num_train + num_valid)
test_indices = np.arange(num_test)
def create_train_gen():
"""
this generates the training data in order, for postprocessing. Do not use this for actual training.
"""
data_gen_train = ra.realtime_fixed_augmented_data_gen(train_indices, 'train',
ds_transforms=ds_transforms, chunk_size=CHUNK_SIZE, target_sizes=input_sizes)
return load_data.buffered_gen_mp(data_gen_train, buffer_size=GEN_BUFFER_SIZE)
def create_valid_gen():
data_gen_valid = ra.realtime_fixed_augmented_data_gen(valid_indices, 'train',
ds_transforms=ds_transforms, chunk_size=CHUNK_SIZE, target_sizes=input_sizes)
return load_data.buffered_gen_mp(data_gen_valid, buffer_size=GEN_BUFFER_SIZE)
def create_test_gen():
data_gen_test = ra.realtime_fixed_augmented_data_gen(test_indices, 'test',
ds_transforms=ds_transforms, chunk_size=CHUNK_SIZE, target_sizes=input_sizes)
return load_data.buffered_gen_mp(data_gen_test, buffer_size=GEN_BUFFER_SIZE)
print "Preprocess validation data upfront"
start_time = time.time()
xs_valid = [[] for _ in xrange(num_input_representations)]
for data, length in create_valid_gen():
for x_valid_list, x_chunk in zip(xs_valid, data):
x_valid_list.append(x_chunk[:length])
xs_valid = [np.vstack(x_valid) for x_valid in xs_valid]
xs_valid = [x_valid.transpose(0, 3, 1, 2) for x_valid in xs_valid] # move the colour dimension up
print " took %.2f seconds" % (time.time() - start_time)
print "Build model"
l0 = layers.Input2DLayer(BATCH_SIZE, NUM_INPUT_FEATURES, input_sizes[0][0], input_sizes[0][1])
l0_45 = layers.Input2DLayer(BATCH_SIZE, NUM_INPUT_FEATURES, input_sizes[1][0], input_sizes[1][1])
l0r = layers.MultiRotSliceLayer([l0, l0_45], part_size=45, include_flip=True)
l0s = cc_layers.ShuffleBC01ToC01BLayer(l0r)
l1a = cc_layers.CudaConvnetConv2DLayer(l0s, n_filters=32, filter_size=6, weights_std=0.01, init_bias_value=0.1, dropout=0.0, partial_sum=1, untie_biases=True)
l1 = cc_layers.CudaConvnetPooling2DLayer(l1a, pool_size=2)
l2a = cc_layers.CudaConvnetConv2DLayer(l1, n_filters=64, filter_size=5, weights_std=0.01, init_bias_value=0.1, dropout=0.0, partial_sum=1, untie_biases=True)
l2 = cc_layers.CudaConvnetPooling2DLayer(l2a, pool_size=2)
l3a = cc_layers.CudaConvnetConv2DLayer(l2, n_filters=128, filter_size=3, weights_std=0.01, init_bias_value=0.1, dropout=0.0, partial_sum=1, untie_biases=True)
l3b = cc_layers.CudaConvnetConv2DLayer(l3a, n_filters=128, filter_size=3, pad=0, weights_std=0.1, init_bias_value=0.1, dropout=0.0, partial_sum=1, untie_biases=True)
l3 = cc_layers.CudaConvnetPooling2DLayer(l3b, pool_size=2)
l3s = cc_layers.ShuffleC01BToBC01Layer(l3)
l3f = layers.FlattenLayer(l3s)
l4a = layers.DenseLayer(l3f, n_outputs=512, weights_std=0.01, init_bias_value=0.1, dropout=0.5, nonlinearity=layers.identity)
l4 = layers.FeatureMaxPoolingLayer(l4a, pool_size=2, feature_dim=1, implementation='reshape')
j4 = layers.MultiRotMergeLayer(l4, num_views=4) # 2) # merge convolutional parts
l5a = layers.DenseLayer(j4, n_outputs=4096, weights_std=0.001, init_bias_value=0.01, dropout=0.5, nonlinearity=layers.identity)
l5 = layers.FeatureMaxPoolingLayer(l5a, pool_size=2, feature_dim=1, implementation='reshape')
l6a = layers.DenseLayer(l5, n_outputs=37, weights_std=0.01, init_bias_value=0.1, dropout=0.5, nonlinearity=layers.identity)
# l6 = layers.OutputLayer(l5, error_measure='mse')
l6 = custom.OptimisedDivGalaxyOutputLayer(l6a) # this incorporates the constraints on the output (probabilities sum to one, weighting, etc.)
train_loss_nonorm = l6.error(normalisation=False)
train_loss = l6.error() # but compute and print this!
valid_loss = l6.error(dropout_active=False)
all_parameters = layers.all_parameters(l6)
all_bias_parameters = layers.all_bias_parameters(l6)
xs_shared = [theano.shared(np.zeros((1,1,1,1), dtype=theano.config.floatX)) for _ in xrange(num_input_representations)]
y_shared = theano.shared(np.zeros((1,1), dtype=theano.config.floatX))
learning_rate = theano.shared(np.array(LEARNING_RATE_SCHEDULE[0], dtype=theano.config.floatX))
idx = T.lscalar('idx')
givens = {
l0.input_var: xs_shared[0][idx*BATCH_SIZE:(idx+1)*BATCH_SIZE],
l0_45.input_var: xs_shared[1][idx*BATCH_SIZE:(idx+1)*BATCH_SIZE],
l6.target_var: y_shared[idx*BATCH_SIZE:(idx+1)*BATCH_SIZE],
}
# updates = layers.gen_updates(train_loss, all_parameters, learning_rate=LEARNING_RATE, momentum=MOMENTUM, weight_decay=WEIGHT_DECAY)
updates_nonorm = layers.gen_updates_nesterov_momentum_no_bias_decay(train_loss_nonorm, all_parameters, all_bias_parameters, learning_rate=learning_rate, momentum=MOMENTUM, weight_decay=WEIGHT_DECAY)
updates = layers.gen_updates_nesterov_momentum_no_bias_decay(train_loss, all_parameters, all_bias_parameters, learning_rate=learning_rate, momentum=MOMENTUM, weight_decay=WEIGHT_DECAY)
train_nonorm = theano.function([idx], train_loss_nonorm, givens=givens, updates=updates_nonorm)
train_norm = theano.function([idx], train_loss, givens=givens, updates=updates)
compute_loss = theano.function([idx], valid_loss, givens=givens) # dropout_active=False
compute_output = theano.function([idx], l6.predictions(dropout_active=False), givens=givens, on_unused_input='ignore') # not using the labels, so theano complains
compute_features = theano.function([idx], l4.output(dropout_active=False), givens=givens, on_unused_input='ignore')
print "Train model"
start_time = time.time()
prev_time = start_time
num_batches_valid = x_valid.shape[0] // BATCH_SIZE
losses_train = []
losses_valid = []
param_stds = []
for e in xrange(NUM_CHUNKS):
print "Chunk %d/%d" % (e + 1, NUM_CHUNKS)
chunk_data, chunk_length = train_gen.next()
y_chunk = chunk_data.pop() # last element is labels.
xs_chunk = chunk_data
# need to transpose the chunks to move the 'channels' dimension up
xs_chunk = [x_chunk.transpose(0, 3, 1, 2) for x_chunk in xs_chunk]
if e in LEARNING_RATE_SCHEDULE:
current_lr = LEARNING_RATE_SCHEDULE[e]
learning_rate.set_value(LEARNING_RATE_SCHEDULE[e])
print " setting learning rate to %.6f" % current_lr
# train without normalisation for the first # chunks.
if e >= NUM_CHUNKS_NONORM:
train = train_norm
else:
train = train_nonorm
print " load training data onto GPU"
for x_shared, x_chunk in zip(xs_shared, xs_chunk):
x_shared.set_value(x_chunk)
y_shared.set_value(y_chunk)
num_batches_chunk = x_chunk.shape[0] // BATCH_SIZE
# import pdb; pdb.set_trace()
print " batch SGD"
losses = []
for b in xrange(num_batches_chunk):
# if b % 1000 == 0:
# print " batch %d/%d" % (b + 1, num_batches_chunk)
loss = train(b)
losses.append(loss)
# print " loss: %.6f" % loss
mean_train_loss = np.sqrt(np.mean(losses))
print " mean training loss (RMSE):\t\t%.6f" % mean_train_loss
losses_train.append(mean_train_loss)
# store param stds during training
param_stds.append([p.std() for p in layers.get_param_values(l6)])
if ((e + 1) % VALIDATE_EVERY) == 0:
print
print "VALIDATING"
print " load validation data onto GPU"
for x_shared, x_valid in zip(xs_shared, xs_valid):
x_shared.set_value(x_valid)
y_shared.set_value(y_valid)
print " compute losses"
losses = []
for b in xrange(num_batches_valid):
# if b % 1000 == 0:
# print " batch %d/%d" % (b + 1, num_batches_valid)
loss = compute_loss(b)
losses.append(loss)
mean_valid_loss = np.sqrt(np.mean(losses))
print " mean validation loss (RMSE):\t\t%.6f" % mean_valid_loss
losses_valid.append(mean_valid_loss)
layers.dump_params(l6, e=e)
now = time.time()
time_since_start = now - start_time
time_since_prev = now - prev_time
prev_time = now
est_time_left = time_since_start * (float(NUM_CHUNKS - (e + 1)) / float(e + 1))
eta = datetime.now() + timedelta(seconds=est_time_left)
eta_str = eta.strftime("%c")
print " %s since start (%.2f s)" % (load_data.hms(time_since_start), time_since_prev)
print " estimated %s to go (ETA: %s)" % (load_data.hms(est_time_left), eta_str)
print
del chunk_data, xs_chunk, x_chunk, y_chunk, xs_valid, x_valid # memory cleanup
print "Compute predictions on validation set for analysis in batches"
predictions_list = []
for b in xrange(num_batches_valid):
# if b % 1000 == 0:
# print " batch %d/%d" % (b + 1, num_batches_valid)
predictions = compute_output(b)
predictions_list.append(predictions)
all_predictions = np.vstack(predictions_list)
# postprocessing: clip all predictions to 0-1
all_predictions[all_predictions > 1] = 1.0
all_predictions[all_predictions < 0] = 0.0
print "Write validation set predictions to %s" % ANALYSIS_PATH
with open(ANALYSIS_PATH, 'w') as f:
pickle.dump({
'ids': valid_ids[:num_batches_valid * BATCH_SIZE], # note that we need to truncate the ids to a multiple of the batch size.
'predictions': all_predictions,
'targets': y_valid,
'mean_train_loss': mean_train_loss,
'mean_valid_loss': mean_valid_loss,
'time_since_start': time_since_start,
'losses_train': losses_train,
'losses_valid': losses_valid,
'param_values': layers.get_param_values(l6),
'param_stds': param_stds,
}, f, pickle.HIGHEST_PROTOCOL)
del predictions_list, all_predictions # memory cleanup
# print "Loading test data"
# x_test = load_data.load_gz(DATA_TEST_PATH)
# x2_test = load_data.load_gz(DATA2_TEST_PATH)
# test_ids = np.load("data/test_ids.npy")
# num_test = x_test.shape[0]
# x_test = x_test.transpose(0, 3, 1, 2) # move the colour dimension up.
# x2_test = x2_test.transpose(0, 3, 1, 2)
# create_test_gen = lambda: load_data.array_chunker_gen([x_test, x2_test], chunk_size=CHUNK_SIZE, loop=False, truncate=False, shuffle=False)
print "Computing predictions on test data"
predictions_list = []
for e, (xs_chunk, chunk_length) in enumerate(create_test_gen()):
print "Chunk %d" % (e + 1)
xs_chunk = [x_chunk.transpose(0, 3, 1, 2) for x_chunk in xs_chunk] # move the colour dimension up.
for x_shared, x_chunk in zip(xs_shared, xs_chunk):
x_shared.set_value(x_chunk)
num_batches_chunk = int(np.ceil(chunk_length / float(BATCH_SIZE))) # need to round UP this time to account for all data
# make predictions for testset, don't forget to cute off the zeros at the end
for b in xrange(num_batches_chunk):
# if b % 1000 == 0:
# print " batch %d/%d" % (b + 1, num_batches_chunk)
predictions = compute_output(b)
predictions_list.append(predictions)
all_predictions = np.vstack(predictions_list)
all_predictions = all_predictions[:num_test] # truncate back to the correct length
# postprocessing: clip all predictions to 0-1
all_predictions[all_predictions > 1] = 1.0
all_predictions[all_predictions < 0] = 0.0
print "Write predictions to %s" % TARGET_PATH
# test_ids = np.load("data/test_ids.npy")
with open(TARGET_PATH, 'wb') as csvfile:
writer = csv.writer(csvfile) # , delimiter=',', quoting=csv.QUOTE_MINIMAL)
# write header
writer.writerow(['GalaxyID', 'Class1.1', 'Class1.2', 'Class1.3', 'Class2.1', 'Class2.2', 'Class3.1', 'Class3.2', 'Class4.1', 'Class4.2', 'Class5.1', 'Class5.2', 'Class5.3', 'Class5.4', 'Class6.1', 'Class6.2', 'Class7.1', 'Class7.2', 'Class7.3', 'Class8.1', 'Class8.2', 'Class8.3', 'Class8.4', 'Class8.5', 'Class8.6', 'Class8.7', 'Class9.1', 'Class9.2', 'Class9.3', 'Class10.1', 'Class10.2', 'Class10.3', 'Class11.1', 'Class11.2', 'Class11.3', 'Class11.4', 'Class11.5', 'Class11.6'])
# write data
for k in xrange(test_ids.shape[0]):
row = [test_ids[k]] + all_predictions[k].tolist()
writer.writerow(row)
print "Gzipping..."
os.system("gzip -c %s > %s.gz" % (TARGET_PATH, TARGET_PATH))
del all_predictions, predictions_list, xs_chunk, x_chunk # memory cleanup
# # need to reload training data because it has been split and shuffled.
# # don't need to reload test data
# x_train = load_data.load_gz(DATA_TRAIN_PATH)
# x2_train = load_data.load_gz(DATA2_TRAIN_PATH)
# x_train = x_train.transpose(0, 3, 1, 2) # move the colour dimension up
# x2_train = x2_train.transpose(0, 3, 1, 2)
# train_gen_features = load_data.array_chunker_gen([x_train, x2_train], chunk_size=CHUNK_SIZE, loop=False, truncate=False, shuffle=False)
# test_gen_features = load_data.array_chunker_gen([x_test, x2_test], chunk_size=CHUNK_SIZE, loop=False, truncate=False, shuffle=False)
# for name, gen, num in zip(['train', 'test'], [train_gen_features, test_gen_features], [x_train.shape[0], x_test.shape[0]]):
# print "Extracting feature representations for all galaxies: %s" % name
# features_list = []
# for e, (xs_chunk, chunk_length) in enumerate(gen):
# print "Chunk %d" % (e + 1)
# x_chunk, x2_chunk = xs_chunk
# x_shared.set_value(x_chunk)
# x2_shared.set_value(x2_chunk)
# num_batches_chunk = int(np.ceil(chunk_length / float(BATCH_SIZE))) # need to round UP this time to account for all data
# # compute features for set, don't forget to cute off the zeros at the end
# for b in xrange(num_batches_chunk):
# if b % 1000 == 0:
# print " batch %d/%d" % (b + 1, num_batches_chunk)
# features = compute_features(b)
# features_list.append(features)
# all_features = np.vstack(features_list)
# all_features = all_features[:num] # truncate back to the correct length
# features_path = FEATURES_PATTERN % name
# print " write features to %s" % features_path
# np.save(features_path, all_features)
print "Done!"