def evaluate_lenet5(learning_rate=0.1, n_epochs=200, dataset='mnist.pkl.gz', nkerns=[20, 50], batch_size=500): """ Demonstrates lenet on MNIST dataset :type learning_rate: float :param learning_rate: learning rate used (factor for the stochastic gradient) :type n_epochs: int :param n_epochs: maximal number of epochs to run the optimizer :type dataset: string :param dataset: path to the dataset used for training /testing (MNIST here) :type nkerns: list of ints :param nkerns: number of kernels on each layer """ rng = numpy.random.RandomState(23455) br = BatchReader.inputs() br2 = BatchReader.inputs(testingData = True) X, Y = br.getNPArray(2) train_set_x = theano.shared(X[0:50000*0.6].astype(float)) train_set_y = theano.shared(Y[0:50000*0.6].astype('int32')) valid_set_x = theano.shared(X[50000*0.6:50000*0.9].astype(float)) valid_set_y = theano.shared(Y[50000*0.6:50000*0.9].astype('int32')) test_set_x = theano.shared(X[50000*0.9:50000].astype(float)) test_set_y = theano.shared(Y[50000*0.9:50000].astype('int32')) #datasets = load_data(dataset) #train_set_x, train_set_y = datasets[0] #valid_set_x, valid_set_y = datasets[1] #test_set_x, test_set_y = datasets[2] # compute number of minibatches for training, validation and testing n_train_batches = train_set_x.get_value(borrow=True).shape[0] n_valid_batches = valid_set_x.get_value(borrow=True).shape[0] n_test_batches = test_set_x.get_value(borrow=True).shape[0] n_train_batches /= batch_size n_valid_batches /= batch_size n_test_batches /= batch_size # allocate symbolic variables for the data index = T.lscalar() # index to a [mini]batch # start-snippet-1 x = T.matrix('x') # the data is presented as rasterized images y = T.ivector('y') # the labels are presented as 1D vector of # [int] labels ###################### # BUILD ACTUAL MODEL # ###################### print '... building the model' # Reshape matrix of rasterized images of shape (batch_size, 28 * 28) # to a 4D tensor, compatible with our LeNetConvPoolLayer # (28, 28) is the size of MNIST images. layer0_input = x.reshape((batch_size, 1, 48, 48)) # Construct the first convolutional pooling layer: # filtering reduces the image size to (28-5+1 , 28-5+1) = (24, 24) # maxpooling reduces this further to (24/2, 24/2) = (12, 12) # 4D output tensor is thus of shape (batch_size, nkerns[0], 12, 12) layer0 = LeNetConvPoolLayer( rng, input=layer0_input, image_shape=(batch_size, 1, 48, 48), filter_shape=(nkerns[0], 1, 9, 9), poolsize=(2, 2) ) # Construct the second convolutional pooling layer # filtering reduces the image size to (12-5+1, 12-5+1) = (8, 8) # maxpooling reduces this further to (8/2, 8/2) = (4, 4) # 4D output tensor is thus of shape (batch_size, nkerns[1], 4, 4) layer1 = LeNetConvPoolLayer( rng, input=layer0.output, image_shape=(batch_size, nkerns[0], 20, 20), filter_shape=(nkerns[1], nkerns[0], 8, 8), poolsize=(2, 2) ) # the HiddenLayer being fully-connected, it operates on 2D matrices of # shape (batch_size, num_pixels) (i.e matrix of rasterized images). # This will generate a matrix of shape (batch_size, nkerns[1] * 4 * 4), # or (500, 50 * 4 * 4) = (500, 800) with the default values. layer2_input = layer1.output.flatten(2) # construct a fully-connected sigmoidal layer layer2 = HiddenLayer( rng, input=layer2_input, n_in=nkerns[1] * 6 * 6, n_out=500, activation=T.tanh ) # classify the values of the fully-connected sigmoidal layer layer3 = LogisticRegression(input=layer2.output, n_in=500, n_out=10) # the cost we minimize during training is the NLL of the model cost = layer3.negative_log_likelihood(y) print type(test_set_x) # create a function to compute the mistakes that are made by the model test_model = theano.function( [index], layer3.errors(y), givens={ x: test_set_x[index * batch_size: (index + 1) * batch_size], y: test_set_y[index * batch_size: (index + 1) * batch_size] } ) validate_model = theano.function( [index], layer3.errors(y), givens={ x: valid_set_x[index * batch_size: (index + 1) * batch_size], y: valid_set_y[index * batch_size: (index + 1) * batch_size] } ) # create a list of all model parameters to be fit by gradient descent params = layer3.params + layer2.params + layer1.params + layer0.params # create a list of gradients for all model parameters grads = T.grad(cost, params) # train_model is a function that updates the model parameters by # SGD Since this model has many parameters, it would be tedious to # manually create an update rule for each model parameter. We thus # create the updates list by automatically looping over all # (params[i], grads[i]) pairs. updates = [ (param_i, param_i - learning_rate * grad_i) for param_i, grad_i in zip(params, grads) ] train_model = theano.function( [index], cost, updates=updates, givens={ x: train_set_x[index * batch_size: (index + 1) * batch_size], y: train_set_y[index * batch_size: (index + 1) * batch_size] } ) # end-snippet-1 ############### # TRAIN MODEL # ############### print '... training' # early-stopping parameters patience = 10000 # look as this many examples regardless patience_increase = 2 # wait this much longer when a new best is # found improvement_threshold = 0.995 # a relative improvement of this much is # considered significant validation_frequency = min(n_train_batches, patience / 2) # go through this many # minibatche before checking the network # on the validation set; in this case we # check every epoch best_validation_loss = numpy.inf best_iter = 0 test_score = 0. start_time = timeit.default_timer() epoch = 0 done_looping = False while (epoch < n_epochs) and (not done_looping): epoch = epoch + 1 for minibatch_index in xrange(n_train_batches): iter = (epoch - 1) * n_train_batches + minibatch_index if iter % 100 == 0: print 'training @ iter = ', iter cost_ij = train_model(minibatch_index) if (iter + 1) % validation_frequency == 0: # compute zero-one loss on validation set validation_losses = [validate_model(i) for i in xrange(n_valid_batches)] this_validation_loss = numpy.mean(validation_losses) print('epoch %i, minibatch %i/%i, validation error %f %%' % (epoch, minibatch_index + 1, n_train_batches, this_validation_loss * 100.)) # if we got the best validation score until now if this_validation_loss < best_validation_loss: #improve patience if loss improvement is good enough if this_validation_loss < best_validation_loss * \ improvement_threshold: patience = max(patience, iter * patience_increase) # save best validation score and iteration number best_validation_loss = this_validation_loss best_iter = iter # test it on the test set test_losses = [ test_model(i) for i in xrange(n_test_batches) ] test_score = numpy.mean(test_losses) print((' epoch %i, minibatch %i/%i, test error of ' 'best model %f %%') % (epoch, minibatch_index + 1, n_train_batches, test_score * 100.)) if patience <= iter: done_looping = True break end_time = timeit.default_timer() print('Optimization complete.') print('Best validation score of %f %% obtained at iteration %i, ' 'with test performance %f %%' % (best_validation_loss * 100., best_iter + 1, test_score * 100.)) print >> sys.stderr, ('The code for file ' + os.path.split(__file__)[1] + ' ran for %.2fm' % ((end_time - start_time) / 60.)) print "Dumping parameters to ../data/convnet.pkl" dir = os.getcwd() path = os.path.join(dir,"../data") os.chdir(path) with open( "convnet.pkl" , 'wb') as file: dict = { "layer0" : layer0.param, "layer1" : layer1.param, "layer2" : layer2.param, "layer3" : layer3.param } pickle.dump(dict, file, 2 ) os.chdir(dir)
def evaluate_lenet5(learning_rate=0.1, n_epochs=200, dataset='mnist.pkl.gz', nkerns=[20, 50], batch_size=500): """ Demonstrates lenet on MNIST dataset :type learning_rate: float :param learning_rate: learning rate used (factor for the stochastic gradient) :type n_epochs: int :param n_epochs: maximal number of epochs to run the optimizer :type dataset: string :param dataset: path to the dataset used for training /testing (MNIST here) :type nkerns: list of ints :param nkerns: number of kernels on each layer """ rng = numpy.random.RandomState(23455) br = BatchReader.inputs() br2 = BatchReader.inputs(testingData=True) X, Y = br.getNPArray(2) train_set_x = theano.shared(X[0:50000 * 0.6].astype(float)) train_set_y = theano.shared(Y[0:50000 * 0.6].astype('int32')) valid_set_x = theano.shared(X[50000 * 0.6:50000 * 0.9].astype(float)) valid_set_y = theano.shared(Y[50000 * 0.6:50000 * 0.9].astype('int32')) test_set_x = theano.shared(X[50000 * 0.9:50000].astype(float)) test_set_y = theano.shared(Y[50000 * 0.9:50000].astype('int32')) #datasets = load_data(dataset) #train_set_x, train_set_y = datasets[0] #valid_set_x, valid_set_y = datasets[1] #test_set_x, test_set_y = datasets[2] # compute number of minibatches for training, validation and testing n_train_batches = train_set_x.get_value(borrow=True).shape[0] n_valid_batches = valid_set_x.get_value(borrow=True).shape[0] n_test_batches = test_set_x.get_value(borrow=True).shape[0] n_train_batches /= batch_size n_valid_batches /= batch_size n_test_batches /= batch_size # allocate symbolic variables for the data index = T.lscalar() # index to a [mini]batch # start-snippet-1 x = T.matrix('x') # the data is presented as rasterized images y = T.ivector('y') # the labels are presented as 1D vector of # [int] labels ###################### # BUILD ACTUAL MODEL # ###################### print '... building the model' # Reshape matrix of rasterized images of shape (batch_size, 28 * 28) # to a 4D tensor, compatible with our LeNetConvPoolLayer # (28, 28) is the size of MNIST images. layer0_input = x.reshape((batch_size, 1, 48, 48)) # Construct the first convolutional pooling layer: # filtering reduces the image size to (28-5+1 , 28-5+1) = (24, 24) # maxpooling reduces this further to (24/2, 24/2) = (12, 12) # 4D output tensor is thus of shape (batch_size, nkerns[0], 12, 12) layer0 = LeNetConvPoolLayer(rng, input=layer0_input, image_shape=(batch_size, 1, 48, 48), filter_shape=(nkerns[0], 1, 9, 9), poolsize=(2, 2)) # Construct the second convolutional pooling layer # filtering reduces the image size to (12-5+1, 12-5+1) = (8, 8) # maxpooling reduces this further to (8/2, 8/2) = (4, 4) # 4D output tensor is thus of shape (batch_size, nkerns[1], 4, 4) layer1 = LeNetConvPoolLayer(rng, input=layer0.output, image_shape=(batch_size, nkerns[0], 20, 20), filter_shape=(nkerns[1], nkerns[0], 8, 8), poolsize=(2, 2)) # the HiddenLayer being fully-connected, it operates on 2D matrices of # shape (batch_size, num_pixels) (i.e matrix of rasterized images). # This will generate a matrix of shape (batch_size, nkerns[1] * 4 * 4), # or (500, 50 * 4 * 4) = (500, 800) with the default values. layer2_input = layer1.output.flatten(2) # construct a fully-connected sigmoidal layer layer2 = HiddenLayer(rng, input=layer2_input, n_in=nkerns[1] * 6 * 6, n_out=500, activation=T.tanh) # classify the values of the fully-connected sigmoidal layer layer3 = LogisticRegression(input=layer2.output, n_in=500, n_out=10) # the cost we minimize during training is the NLL of the model cost = layer3.negative_log_likelihood(y) print type(test_set_x) # create a function to compute the mistakes that are made by the model test_model = theano.function( [index], layer3.errors(y), givens={ x: test_set_x[index * batch_size:(index + 1) * batch_size], y: test_set_y[index * batch_size:(index + 1) * batch_size] }) validate_model = theano.function( [index], layer3.errors(y), givens={ x: valid_set_x[index * batch_size:(index + 1) * batch_size], y: valid_set_y[index * batch_size:(index + 1) * batch_size] }) # create a list of all model parameters to be fit by gradient descent params = layer3.params + layer2.params + layer1.params + layer0.params # create a list of gradients for all model parameters grads = T.grad(cost, params) # train_model is a function that updates the model parameters by # SGD Since this model has many parameters, it would be tedious to # manually create an update rule for each model parameter. We thus # create the updates list by automatically looping over all # (params[i], grads[i]) pairs. updates = [(param_i, param_i - learning_rate * grad_i) for param_i, grad_i in zip(params, grads)] train_model = theano.function( [index], cost, updates=updates, givens={ x: train_set_x[index * batch_size:(index + 1) * batch_size], y: train_set_y[index * batch_size:(index + 1) * batch_size] }) # end-snippet-1 ############### # TRAIN MODEL # ############### print '... training' # early-stopping parameters patience = 10000 # look as this many examples regardless patience_increase = 2 # wait this much longer when a new best is # found improvement_threshold = 0.995 # a relative improvement of this much is # considered significant validation_frequency = min(n_train_batches, patience / 2) # go through this many # minibatche before checking the network # on the validation set; in this case we # check every epoch best_validation_loss = numpy.inf best_iter = 0 test_score = 0. start_time = timeit.default_timer() epoch = 0 done_looping = False while (epoch < n_epochs) and (not done_looping): epoch = epoch + 1 for minibatch_index in xrange(n_train_batches): iter = (epoch - 1) * n_train_batches + minibatch_index if iter % 100 == 0: print 'training @ iter = ', iter cost_ij = train_model(minibatch_index) if (iter + 1) % validation_frequency == 0: # compute zero-one loss on validation set validation_losses = [ validate_model(i) for i in xrange(n_valid_batches) ] this_validation_loss = numpy.mean(validation_losses) print('epoch %i, minibatch %i/%i, validation error %f %%' % (epoch, minibatch_index + 1, n_train_batches, this_validation_loss * 100.)) # if we got the best validation score until now if this_validation_loss < best_validation_loss: #improve patience if loss improvement is good enough if this_validation_loss < best_validation_loss * \ improvement_threshold: patience = max(patience, iter * patience_increase) # save best validation score and iteration number best_validation_loss = this_validation_loss best_iter = iter # test it on the test set test_losses = [ test_model(i) for i in xrange(n_test_batches) ] test_score = numpy.mean(test_losses) print((' epoch %i, minibatch %i/%i, test error of ' 'best model %f %%') % (epoch, minibatch_index + 1, n_train_batches, test_score * 100.)) if patience <= iter: done_looping = True break end_time = timeit.default_timer() print('Optimization complete.') print( 'Best validation score of %f %% obtained at iteration %i, ' 'with test performance %f %%' % (best_validation_loss * 100., best_iter + 1, test_score * 100.)) print >> sys.stderr, ('The code for file ' + os.path.split(__file__)[1] + ' ran for %.2fm' % ((end_time - start_time) / 60.)) print "Dumping parameters to ../data/convnet.pkl" dir = os.getcwd() path = os.path.join(dir, "../data") os.chdir(path) with open("convnet.pkl", 'wb') as file: dict = { "layer0": layer0.param, "layer1": layer1.param, "layer2": layer2.param, "layer3": layer3.param } pickle.dump(dict, file, 2) os.chdir(dir)
for angle in range(0,360,60): y_k.append(self.eval_net( self.rotate( x[k*self.batch_size:(k+1)*self.batch_size],angle) ) ) y_i.append(np.float32(y_k).mean(axis=0)) y = np.vstack(y_i) return y if __name__ == '__main__': rng = numpy.random.RandomState(42) br = BatchReader.inputs() br2 = BatchReader.inputs(testingData = True) X, Y = br.getNPArray(2) testX = br2.getNPArray(2) nkerns = [35,70,35] print X.shape, Y.shape print testX.shape n_examples = X.shape[0] fs = foldsize = n_examples/K_FOLD # k folds for k in range(K_FOLD): trainX = np.vstack(
print(__doc__) from sklearn import neighbors, linear_model import BatchReader reader = BatchReader.inputs() array = reader.getNPArray(7809) X_digits = array[0] y_digits = array[1] n_samples = len(X_digits) X_train = X_digits[:.9*n_samples] y_train = y_digits[:.9*n_samples] X_test = X_digits[.9*n_samples:] y_test = y_digits[.9*n_samples:] logistic = linear_model.LogisticRegression() print('LogisticRegression score: %f' % logistic.fit(X_train, y_train).score(X_test,y_test))
y_k = [] for angle in range(0, 360, 60): y_k.append( self.eval_net( self.rotate( x[k * self.batch_size:(k + 1) * self.batch_size], angle))) y_i.append(np.float32(y_k).mean(axis=0)) y = np.vstack(y_i) return y if __name__ == '__main__': rng = numpy.random.RandomState(42) br = BatchReader.inputs() br2 = BatchReader.inputs(testingData=True) X, Y = br.getNPArray(2) testX = br2.getNPArray(2) nkerns = [35, 70, 35] print X.shape, Y.shape print testX.shape n_examples = X.shape[0] fs = foldsize = n_examples / K_FOLD # k folds for k in range(K_FOLD): trainX = np.vstack([X[:k * fs], X[(k + 1) * fs:]])