def init_net_without_loading_data(self, config): """This should be called after loading all required data.""" self.config = config if config.is_output and (not os.path.exists(config.output_dir)): os.makedirs(config.output_dir) [num_total_cases, input_dim] = self.train_data.X.shape self.num_total_cases = num_total_cases self.input_dim = input_dim self.num_minibatches = num_total_cases / config.minibatch_size if self.num_minibatches < 1: self.num_minibatches = 1 # initialize the network self.num_layers = config.num_layers self.layer = [] in_dim = input_dim for i in range(self.num_layers): layer_spec = config.layer[i] self.layer.append(Layer( in_dim, layer_spec.out_dim, layer_spec.act_type, layer_spec.weight_decay, layer_spec.weight_constraint, layer_spec.dropout)) in_dim = layer_spec.out_dim self.output = OutputLayer(in_dim, config.output.out_dim, config.output.output_type, config.output.weight_decay, config.output.weight_constraint, config.output.dropout) # if not linear output (regression) load task loss function if not isinstance(self.output.act_type, act.LinearOutput): if config.task_loss_file != None: self.task_loss = self.read_loss(config.task_loss_file) print 'Loading task loss from %s' % config.task_loss_file else: self.task_loss = 1 - np.eye(self.train_data.K) print 'No task loss specified, using 0-1 loss.' # To use multi-class hinge output, a training loss function is required if isinstance(self.output.act_type, act.MulticlassHingeOutput): if config.train_loss_file != None: self.train_loss = self.read_loss(config.train_loss_file) print 'Loading surrogate loss from %s' % config.train_loss_file else: self.train_loss = 1 - np.eye(self.train_data.K) print 'No surrogate loss specified, using 0-1 loss.' self.output.act_type.set_loss(self.train_loss) # initialize the weights in every layer self._init_weights(config.init_scale, config.random_seed)
def forward_time(self, ix, prev_cell): """Forward in time t given current input and previous hidden cell state.""" # FIXME: There maybe multiple layers here. # Compute the hidden state (hidden, output) = self.create_cell() hidden.forward(self.Wz, self.Wi, self.Wf, self.Wo, self.Rz, self.Ri, self.Rf, self.Ro, self.pi, self.pf, self.po, self.bz, self.bi, self.bf, self.bo, ix, prev_cell[0].c, prev_cell[0].h) # Compute the output output = OutputLayer(self.hidden_size) output.forward(self.V, hidden.h, self.c) return (hidden, output)
class TrainingResultsTest( unittest.TestCase ): def setUp( self ): self.tr = TrainingResults() from opencl import OpenCL from layer import InputLayer, Layer, OutputLayer, ExecutionContext self.ocl = OpenCL( pyopencl.create_some_context() ) self.i = InputLayer( 2, self.ocl ) self.h = Layer( 3, self.ocl ) self.o = OutputLayer( 1, self.ocl ) self.i.link_next( self.h ) self.h.link_next( self.o, 0, 3 ) self.nnc = ExecutionContext( self.i, self.o, allow_training = True ) self.i.set_weights( numpy.array( [ 0.1 ] * self.i.weights_count, numpy.float32 ) ) self.h.set_weights( numpy.array( [ 0.2 ] * self.h.weights_count, numpy.float32 ) ) self.o.set_weights( numpy.array( [ 0.3 ] * self.o.weights_count, numpy.float32 ) ) def assertArrayEqual( self, ar1, ar2 ): self.assertEqual( len( ar1 ), len( ar2 ) ) for x, y in zip( numpy.array( ar1, numpy.float32 ), numpy.array( ar2, numpy.float32 ) ): self.assertAlmostEqual( x, y, places = 5 ) def test_store( self ): self.tr.reset() self.assertEqual( self.tr.iterations, numpy.int32( 0 ) ) self.assertGreater( self.tr.minimal_error, numpy.float32( 1e6 ) ) self.assertIsNone( self.tr.optimal_weights ) self.assertAlmostEqual( self.tr.total_time, 0.0 ) self.assertAlmostEqual( self.tr.opencl_time, 0.0 ) self.i.set_inputs( numpy.array( [1.0, 1.0], numpy.float32 ), is_blocking = True ) self.i.process() initial_result = self.o.get_outputs() self.tr.store_weights( self.nnc ) self.i.set_weights( numpy.array( [ 0.4 ] * self.i.weights_count, numpy.float32 ) ) self.i.process() self.assertNotEqual( initial_result, self.o.get_outputs() ) self.tr.apply_weights( self.nnc ) self.i.process() self.assertArrayEqual( initial_result , self.o.get_outputs() )
def __init__(self, cfg): self.model = cfg["model"] self.cost = cfg["cost"] self.struct = cfg["struct"] self.activation = cfg["activation"] # size is the number of weight matrices self.size = len(cfg["struct"]) - 1 # init of layers self.layers = [] layer_cfg = { "model": cfg["model"], "load_weights": cfg["load_weights"], "activation": cfg["activation"], "cost": cfg["cost"] } for l in range(self.size): layer_cfg["shape"] = [ cfg["struct"][l], # input size cfg["struct"][l + 1] # output size ] layer_cfg["ID"] = l if l == self.size - 1: self.layers.append(OutputLayer(layer_cfg)) else: self.layers.append(Layer(layer_cfg))
def Mininet_test(): from functions import Sigmoid, Quadratic w_h = np.ones((2, 2)) * 0.5 w_o = np.ones((1, 3)) * 0.5 f_activation = Sigmoid f_cost = Quadratic layers = [ Layer(f_activation, weights=w_h), OutputLayer(f_activation, f_cost, weights=w_o) ] net = Network(f_activation, f_cost, layers=layers) input = [1] act, cost = net.train(input=input, target=input, learning_rate=1) print(act, cost) for l in net.layers: print(l.delta_w)
def load(name): with open(name + "/p.pkl", "rb") as file: print(file) params = pickle.load(file) layers = [] for index in range(params["no_of_layers"] - 1): path = name + "/l" + str(index) + ".npy" weights = np.load(path) layers.append( Layer(f_activation=params["f_activation"], weights=weights)) path = name + "/l" + str(params["no_of_layers"] - 1) + ".npy" weights = np.load(path) layers.append( OutputLayer(f_activation=params["f_activation"], f_cost=params["f_cost"], weights=weights)) return Network(f_activation=params["f_activation"], f_cost=params["f_cost"], layers=layers)
def init_net(self, config): """config is an instance of class Config""" import os self.config = config if config.is_output and (not os.path.exists(config.output_dir)): os.makedirs(config.output_dir) self.train_data = self.read_data(config.train_data_file) if config.is_val: self.val_data = self.read_data(config.val_data_file) if config.is_test: self.test_data = self.read_data(config.test_data_file) [num_total_cases, input_dim] = self.train_data.X.shape self.num_total_cases = num_total_cases self.input_dim = input_dim self.num_minibatches = num_total_cases / config.minibatch_size if self.num_minibatches < 1: self.num_minibatches = 1 # initialize the network self.num_layers = config.num_layers self.layer = [] in_dim = input_dim for i in range(0, self.num_layers): self.layer.append( Layer(in_dim, config.layer[i].out_dim, config.layer[i].act_type)) in_dim = config.layer[i].out_dim self.output = OutputLayer(in_dim, config.output.out_dim, config.output.output_type) # To use multi-class hinge output, we need to specify the loss function if isinstance(self.output.act_type, act.MulticlassHingeOutput): if config.loss_file != None: self.output.act_type.set_loss(self.read_loss(config.loss_file)) else: self.output.act_type.set_loss(1 - np.eye(self.train_data.K)) # initialize the weights in every layer self._init_weights(config.init_scale, config.random_seed)
def forward_propagation(self, x): """Forward Progation of a single sample.""" tau = len(x) prev_h = sp.zeros(self.n_hiddens) cells = [None for i in range(tau)] for i in range(tau): # Compute the hidden state time_input = x[i] hidden = HiddenLayer() hidden.forward(self.U, time_input, self.W, prev_h, self.b) # Compute the output prev_h = hidden.h output = OutputLayer() output.forward(self.V, hidden.h, self.c) cells[i] = (hidden, output) return cells
def setUpClass( self ): from opencl import OpenCL from layer import InputLayer, OutputLayer, ExecutionContext self.ocl = OpenCL( pyopencl.create_some_context() ) self.i = InputLayer( 2, self.ocl ) self.o = OutputLayer( 1, self.ocl ) self.i.link_next( self.o ) self.nnc = ExecutionContext( self.i, self.o, allow_training = True ) self.i.set_weights( numpy.array( [ 0.1 ] * self.i.weights_count, numpy.float32 ) ) self.o.set_weights( numpy.array( [ 0.3 ] * self.o.weights_count, numpy.float32 ) ) self.tr = TrainingResults() self._create_method()
def __init_layers(self, layer_spec): self.layers = [] last_index = len(layer_spec) - 1 for i, size in enumerate(layer_spec): if i == 0: self.layers.append(InputLayer(size, self.activation_fn)) elif i == last_index: self.layers.append(OutputLayer(size, self.activation_fn)) else: self.layers.append(HiddenLayer(size, self.activation_fn)) for i in range(len(self.layers) - 1): self.__join_layers(self.layers[i], self.layers[i+1])
def __init__(self, architecture=[784, 100, 10], activation='sigmoid', learning_rate=0.1, momentum=0.5, weight_decay=1e-4, dropout=0.5, early_stopping=True, seed=99): """ Neural network model initializer. """ # Attributes self.architecture = architecture self.activation = activation self.learning_rate = learning_rate self.momentum = momentum self.weight_decay = weight_decay self.dropout = dropout self.early_stopping = early_stopping self.seed = seed # Turn `activation` and `learning_rate` to class instances if not isinstance(self.activation, Activation): self.activation = Activation(self.activation) if not isinstance(self.learning_rate, LearningRate): self.learning_rate = LearningRate(self.learning_rate) # Initialize a list of layers self.layers = [] for i, (n_in, n_out) in enumerate(zip(architecture[:-2], architecture[1:-1])): l = HiddenLayer('layer{}'.format(i), n_in, n_out, self.activation, self.learning_rate, self.momentum, self.weight_decay, self.dropout, self.seed + i) self.layers.append(l) # Output layer n_in, n_out = architecture[-2], architecture[-1] l = OutputLayer('output_layer', n_in, n_out, self.learning_rate, self.momentum, self.weight_decay, self.dropout, self.seed + i + 1) self.layers.append(l) # Training updates self.epoch = 0 self.training_error = [] self.validation_error = [] self.training_loss = [] self.validation_loss = []
def create_layers(f_activation, f_cost, struct): layers = [] for input, output in zip(struct, struct[1:-1]): layer = Layer(f_activation, size=[output, input]) layers.append(layer) layer = OutputLayer(f_activation, f_cost, size=[struct[-1], struct[-2]]) layers.append(layer) return layers
def init_net(self, config): """config is an instance of class Config""" import os self.config = config if config.is_output and (not os.path.exists(config.output_dir)): os.makedirs(config.output_dir) self.train_data = self.read_data(config.train_data_file) if config.is_val: self.val_data = self.read_data(config.val_data_file) if config.is_test: self.test_data = self.read_data(config.test_data_file) [num_total_cases, input_dim] = self.train_data.X.shape self.num_total_cases = num_total_cases self.input_dim = input_dim self.num_minibatches = num_total_cases / config.minibatch_size if self.num_minibatches < 1: self.num_minibatches = 1 # initialize the network self.num_layers = config.num_layers self.layer = [] in_dim = input_dim for i in range(0, self.num_layers): self.layer.append(Layer( in_dim, config.layer[i].out_dim, config.layer[i].act_type)) in_dim = config.layer[i].out_dim self.output = OutputLayer(in_dim, config.output.out_dim, config.output.output_type) # To use multi-class hinge output, we need to specify the loss function if isinstance(self.output.act_type, act.MulticlassHingeOutput): if config.loss_file != None: self.output.act_type.set_loss(self.read_loss(config.loss_file)) else: self.output.act_type.set_loss(1 - np.eye(self.train_data.K)) # initialize the weights in every layer self._init_weights(config.init_scale, config.random_seed)
def __init__(self, model, struct, activation="sigmoid", cost="quadratic", load_weights=False, weight_range=[-1, 1], bias_range=[0.5, 0.95]): self.model = model self.struct = struct self.activation = activation self.cost = cost # size is the number of weight matrices self.size = len(self.struct) - 1 # init of layers self.layers = [] for l in range(self.size): if l == self.size - 1: self.layers.append( OutputLayer(model=self.model, ID=l, activation=self.activation, load_weights=load_weights, in_size=self.struct[l], out_size=self.struct[l + 1], weight_range=weight_range, bias_range=bias_range, cost=self.cost)) else: self.layers.append( Layer(model=self.model, ID=l, activation=self.activation, load_weights=load_weights, in_size=self.struct[l], out_size=self.struct[l + 1], weight_range=weight_range, bias_range=bias_range))
def main(): sess = tf.Session() image = read_image('../data/heart.jpg') image = np.reshape(image, [1, 224, 224, 3]) # type numpy.ndarray image.astype(np.float32) parser = Parser('../data/alexnet.cfg') network_builder = NetworkBuilder("test") # type: NetworkBuilder network_builder.set_parser(parser) network = network_builder.build() # type: Network network.add_input_layer(InputLayer(tf.float32, [None, 224, 224, 3])) network.add_output_layer(OutputLayer()) network.connect_each_layer() sess.run(tf.global_variables_initializer()) fc_layer = sess.run(network.output, feed_dict={network.input: image})
def test(): data = pd.read_csv("train.csv").values x = data[:, 1:] t = np.identity(10, dtype=np.uint8)[data[:, 0]] x = (x - x.min()) / x.max() x = (x - x.mean()) / x.std() validate = int(x.shape[0] * 0.75) x_train, t_train = x[:validate], t[:validate] x_test, t_test = x[validate:], t[validate:] network = NeuralNetwork(784, error="R2error", optimizer="Gradient") network.add(Layer(100, activation="Sigmoid")) network.add(Layer(50, activation="Sigmoid")) network.add(OutputLayer(10, activation="Softmax")) network.fit(x_train, t_train, epoch_time=EPOCH_TIME, batch_size=BATCH_SIZE) network.print_accurate(x_test, t_test)
def build_net_from_copy(self, copy): """ Rebuild the net from a copy made by make_copy. """ nnstore = copy self.num_layers = len(nnstore.layer) self.layer = [] for i in range(self.num_layers): in_dim, out_dim = nnstore.layer[i].W.shape new_layer = Layer(in_dim, out_dim, nnstore.layer[i].act_type) new_layer.load_weight(nnstore.layer[i].W, nnstore.layer[i].b) self.layer.append(new_layer) in_dim, out_dim = nnstore.output.W.shape new_layer = OutputLayer(in_dim, out_dim, nnstore.output.act_type) new_layer.load_weight(nnstore.output.W, nnstore.output.b) self.output = new_layer if self.num_layers > 0: self.input_dim = self.layer[0].W.shape[0] else: self.input_dim = self.output.W.shape[0]
def init_net(self, config): """config is an instance of class Config""" import os self.config = config if config.is_output and (not os.path.exists(config.output_dir)): os.makedirs(config.output_dir) self.train_data = self.read_data(config.train_data_file) if config.is_val: self.val = self.read_data(config.val_data_file) if config.is_test: self.test = self.read_data(config.test_data_file) [num_total_cases, input_dim] = self.train_data.X.shape self.num_total_cases = num_total_cases self.input_dim = input_dim self.num_minibatches = num_total_cases / config.minibatch_size if self.num_minibatches < 1: self.num_minibatches += 1 # initialize the network self.num_layers = config.num_layers self.layer = [] in_dim = input_dim for i in range(0, self.num_layers): self.layer.append(Layer( in_dim, config.layer[i].out_dim, config.layer[i].act_type)) in_dim = config.layer[i].out_dim self.output = OutputLayer(in_dim, config.output.out_dim, config.output.output_type) # initialize the weights in every layer self._init_weights(config.init_scale, config.random_seed)
class NN: """A class for general purpose neural networks, trained with backpropagation. The type of activation functions, number of hidden layers and number of units in each layer, the output function, and other options during training can be configured.""" def __init__(self): pass def init_net(self, config): """config is an instance of class Config""" import os self.config = config if config.is_output and (not os.path.exists(config.output_dir)): os.makedirs(config.output_dir) self.train_data = self.read_data(config.train_data_file) if config.is_val: self.val_data = self.read_data(config.val_data_file) if config.is_test: self.test_data = self.read_data(config.test_data_file) [num_total_cases, input_dim] = self.train_data.X.shape self.num_total_cases = num_total_cases self.input_dim = input_dim self.num_minibatches = num_total_cases / config.minibatch_size if self.num_minibatches < 1: self.num_minibatches = 1 # initialize the network self.num_layers = config.num_layers self.layer = [] in_dim = input_dim for i in range(0, self.num_layers): self.layer.append(Layer( in_dim, config.layer[i].out_dim, config.layer[i].act_type)) in_dim = config.layer[i].out_dim self.output = OutputLayer(in_dim, config.output.out_dim, config.output.output_type) # To use multi-class hinge output, we need to specify the loss function if isinstance(self.output.act_type, act.MulticlassHingeOutput): if config.loss_file != None: self.output.act_type.set_loss(self.read_loss(config.loss_file)) else: self.output.act_type.set_loss(1 - np.eye(self.train_data.K)) # initialize the weights in every layer self._init_weights(config.init_scale, config.random_seed) def _init_weights(self, init_scale, random_seed=None): if random_seed: np.random.seed(random_seed) for i in range(0, self.num_layers): self.layer[i].init_weight(init_scale) self.output.init_weight(init_scale) def train(self): config = self.config # convert t into a matrix in 1-of-K representation if it is a vector t = self.train_data.T if not self.config.is_regression: T_matrix = self.output.act_type.label_vec_to_mat(t, self.train_data.K) else: T_matrix = t layer_config = LayerConfig() layer_config.learn_rate = config.learn_rate layer_config.momentum = config.momentum layer_config.weight_decay = config.weight_decay nnstore = NNStore() nnstore.init_from_net(self) self.display_training_info(-1, 0, 0) t_start = time.time() for epoch in range(0, config.num_epochs): # shuffle the dataset idx = np.random.permutation(self.num_total_cases) train_X = self.train_data.X[idx] train_T = T_matrix[idx] loss = 0 for batch in range(0, self.num_minibatches): i_start = batch * config.minibatch_size if not batch == self.num_minibatches - 1: i_end = i_start + config.minibatch_size else: i_end = self.num_total_cases X = train_X[i_start:i_end] T = train_T[i_start:i_end] Xbelow = X # forward pass for i in range(0, self.num_layers): Xbelow = self.layer[i].forward(Xbelow) self.output.forward(Xbelow) # compute loss loss += self.output.loss(T) # backprop dLdXabove = self.output.backprop(layer_config) for i in range(self.num_layers-1, -1, -1): dLdXabove = self.layer[i].backprop(dLdXabove, layer_config) # statistics avg_loss = 1.0 * loss / self.num_total_cases if (epoch + 1) % config.epoch_to_display == 0: self.display_training_info(epoch, avg_loss, time.time() - t_start) t_start = time.time() if (epoch + 1) % config.epoch_to_save == 0: nnstore.update_from_net(self) nnstore.write(config.output_dir + '/m' + str(epoch + 1) + '.pdata') def display_training_info(self, epoch, loss, time): """Print training information. Use the config information to determine what information to display.""" if self.config.is_val: if self.config.is_test: self._display_training_info(epoch, loss, time, self.train_data.X, self.train_data.T, val_data=self.val_data.X, val_labels=self.val_data.T, test_data=self.test_data.X, test_labels=self.test_data.T) else: self._display_training_info(epoch, loss, time, self.train_data.X, self.train_data.T, val_data=self.val_data.X, val_labels=self.val_data.T) else: if self.config.is_test: self._display_training_info(epoch, loss, time, self.train_data.X, self.train_data.T, test_data=self.test_data.X, test_labels=self.test_data.T) else: self._display_training_info(epoch, loss, time, self.train_data.X, self.train_data.T) def _display_training_info(self, epoch, loss, time, train_data, train_labels, val_data=None, val_labels=None, test_data=None, test_labels=None): """Print training information during training.""" print 'epoch %d, loss %.4f,' % (epoch + 1, loss), # print loss if it is a regression problem if self.config.is_regression: if val_data != None and val_labels != None: self.predict(val_data) avg_loss = self.output.loss(val_labels) / val_labels.shape[0] print 'val_loss %.4f,' % (avg_loss), if test_data != None and test_labels != None: self.predict(test_data) avg_loss = self.output.loss(test_labels) / test_labels.shape[0] print 'test_loss %.4f,' % (avg_loss), else: # print accuracy if it is a classification problem ypred = self.predict(train_data) acc = (ypred == train_labels.squeeze()).mean() print 'acc %.4f,' % acc, if val_data != None and val_labels != None: ypred = self.predict(val_data) acc = (ypred == val_labels.squeeze()).mean() print 'val_acc %.4f,' % acc, if test_data != None and test_labels != None: ypred = self.predict(test_data) acc = (ypred == test_labels.squeeze()).mean() print 'test_acc %.4f,' % acc, if self.config.display_winc: for i in range(0, self.num_layers): print 'winc%d %.5f,' % (i+1, np.abs(self.layer[i].Winc).max()), print 'winc_out %.5f,' % np.abs(self.output.Winc).max(), print 'time %.2f' % time def _forward(self, X): """Do a forward pass without computing the output and predictions. Used as a subroutine for function predict and check_grad.""" Xbelow = X for i in range(0, self.num_layers): Xbelow = self.layer[i].forward(Xbelow) self.output.forward(Xbelow) def predict(self, X): """Make prediction using the current network. X: N*D data matrix ispad: if True, X is padded by an extra dimension of constant 1's Return an N-element vector of predicted labels. """ self._forward(X) return self.output.predict() def read_data(self, data_file_name): """(data_file_name) --> data Read from the specified data file, return a data object, which is an object with three attributes, X, T and K. X and T are the data and target matrices respectively, and K is the dimensionality of the output. Each of X and T is a matrix with N rows, N is the number of data cases.""" f = open(data_file_name) data_dict = pickle.load(f) f.close() data = Data() data.X = data_dict['data'] data.T = data_dict['labels'] data.K = data_dict['K'] return data def read_loss(self, loss_file_name): """(data_file_name) --> loss Read from the specified data file, return a loss matrix. """ f = open(loss_file_name) d = pickle.load(f) f.close() return d['loss'] def display(self): print '%d training cases' % self.train_data.X.shape[0] if self.config.is_val: print '%d validation cases' % self.val_data.X.shape[0] if self.config.is_test: print '%d test cases' % self.test_data.X.shape[0] print '[' + str(self.output) + ']' for i in range(self.num_layers-1, -1, -1): print '[' + str(self.layer[i]) + ']' print '[input ' + str(self.input_dim) + ']' print 'learn_rate : ' + str(self.config.learn_rate) print 'init_scale : ' + str(self.config.init_scale) print 'momentum : ' + str(self.config.momentum) print 'weight_decay : ' + str(self.config.weight_decay) print 'minibatch_size : ' + str(self.config.minibatch_size) print 'num_epochs : ' + str(self.config.num_epochs) print 'epoch_to_save : ' + str(self.config.epoch_to_save) def check_grad(self): # check the gradient of the 1st layer weights import scipy.optimize as opt ncases = 100 def f(w): if self.num_layers == 0: Wtemp = self.output.W self.output.W = w.reshape(Wtemp.shape) else: Wtemp = self.layer[0].W self.layer[0].W = w.reshape(Wtemp.shape) self._forward(self.train_data.X[:ncases,:]) Z = self.train_data.T[:ncases] if not self.config.is_regression: Z = self.output.act_type.label_vec_to_mat(Z, self.train_data.K) L = self.output.loss(Z) / Z.shape[0] if self.num_layers == 0: self.output.W = Wtemp else: self.layer[0].W = Wtemp return L def fgrad(w): if self.num_layers == 0: Wtemp = self.output.W self.output.W = w.reshape(Wtemp.shape) else: Wtemp = self.layer[0].W self.layer[0].W = w.reshape(Wtemp.shape) self._forward(self.train_data.X[:ncases,:]) Z = self.train_data.T[:ncases] if not self.config.is_regression: Z = self.output.act_type.label_vec_to_mat(Z, self.train_data.K) self.output.loss(Z) self.output.gradient() dLdXabove = self.output.dLdXtop[:,:-1] for i in range(self.num_layers-1, -1, -1): self.layer[i].gradient(dLdXabove) dLdXabove = self.layer[i].dLdXbelow[:,:-1] if self.num_layers == 0: grad_w = self.output.dLdW else: grad_w = self.layer[0].dLdW if self.num_layers == 0: self.output.W = Wtemp else: self.layer[0].W = Wtemp return grad_w.reshape(np.prod(grad_w.shape)) / Z.shape[0] if self.num_layers == 0: #W = np.random.randn( # self.output.W.shape[0], self.output.W.shape[1]) * 1e-3 W = self.output.W else: #W = np.random.randn( # self.layer[0].W.shape[0], self.layer[0].W.shape[1]) * 1e-3 W = self.layer[0].W print "wmax: %f" % np.abs(fgrad(W.reshape(np.prod(W.shape)))).max() print "check_grad err: %f" % opt.check_grad( f, fgrad, W.reshape(np.prod(W.shape)))
epoch = 1 batch_size = 8 interval = 1 # 経過の表示間隔 n_sample = 7 # 誤差計測のサンプル数 n_flt = 6 # n_flt:フィルタ数 flt_h = 3 # flt_h:フィルタ高さ flt_w = 3 # flt_w:フィルタ幅 # stride:ストライド幅, pad:パディング幅 # -- 各層の初期化 -- cl_1 = ConvLayer(img_ch, img_h, img_w, n_flt, flt_h, flt_w, 1, 1) pl_1 = PoolingLayer(cl_1.y_ch, cl_1.y_h, cl_1.y_w, 2, 0) n_fc_in = pl_1.y_ch * pl_1.y_h * pl_1.y_w ml_1 = MiddleLayer(n_fc_in, 10) ol_1 = OutputLayer(10, 10) # -- 順伝播 -- def forward_propagation(x): n_bt = x.shape[0] print("forward_propagation()") print(" x.shape", x.shape) images = x.reshape(n_bt, img_ch, img_h, img_w) print(" x.reshape", images.shape) cl_1.forward(images) pl_1.forward(cl_1.y) print(" pl_1.y.shape", pl_1.y.shape, "バッチ数,フィルタ数,img縦,img横")
class NN: """A class for general purpose neural networks, trained with backpropagation. The type of activation functions, number of hidden layers and number of units in each layer, the output function, and other options during training can be configured.""" def __init__(self): pass def init_net(self, config): """config is an instance of class Config""" import os self.config = config if config.is_output and (not os.path.exists(config.output_dir)): os.makedirs(config.output_dir) self.train_data = self.read_data(config.train_data_file) if config.is_val: self.val = self.read_data(config.val_data_file) if config.is_test: self.test = self.read_data(config.test_data_file) [num_total_cases, input_dim] = self.train_data.X.shape self.num_total_cases = num_total_cases self.input_dim = input_dim self.num_minibatches = num_total_cases / config.minibatch_size if self.num_minibatches < 1: self.num_minibatches += 1 # initialize the network self.num_layers = config.num_layers self.layer = [] in_dim = input_dim for i in range(0, self.num_layers): self.layer.append(Layer( in_dim, config.layer[i].out_dim, config.layer[i].act_type)) in_dim = config.layer[i].out_dim self.output = OutputLayer(in_dim, config.output.out_dim, config.output.output_type) # initialize the weights in every layer self._init_weights(config.init_scale, config.random_seed) def _init_weights(self, init_scale, random_seed=None): if random_seed: np.random.seed(random_seed) for i in range(0, self.num_layers): self.layer[i].init_weight(init_scale) self.output.init_weight(init_scale) def train(self): config = self.config layer_config = LayerConfig() layer_config.learn_rate = config.learn_rate layer_config.momentum = config.momentum layer_config.weight_decay = config.weight_decay nnstore = NNStore() nnstore.init_from_net(self) for epoch in range(0, config.num_epochs): # shuffle the data cases idx = np.random.permutation(self.num_total_cases) train_X = self.train_data.X[idx] train_T = self.train_data.T[idx] loss = 0 for batch in range(0, self.num_minibatches): i_start = batch * config.minibatch_size if not batch == self.num_minibatches - 1: i_end = i_start + config.minibatch_size else: i_end = self.num_total_cases X = train_X[i_start:i_end] T = train_T[i_start:i_end] Xbelow = X # forward pass for i in range(0, self.num_layers): Xbelow = self.layer[i].forward(Xbelow) self.output.forward(Xbelow) # compute loss loss += self.output.loss(T) # backprop dLdXabove = self.output.backprop(layer_config) for i in range(self.num_layers-1, -1, -1): dLdXabove = self.layer[i].backprop(dLdXabove, layer_config) # statistics avg_loss = 1.0 * loss / self.num_total_cases if (epoch + 1) % config.epoch_to_display == 0: print 'epoch ' + str(epoch + 1) + ', loss = ' + str(avg_loss) if (epoch + 1) % config.epoch_to_save == 0: nnstore.update_from_net(self) nnstore.write(config.output_dir + '/m' + str(epoch + 1) + '.pdata') def read_data(self, data_file_name): """(data_file_name) --> data Read from the specified data file, return a data object, which is an object with three attributes, X, T and K. X and T are the data and target matrix respectively, and K is the dimensionality of the output. Each of X and T is a matrix with N rows, N is the number of data cases""" f = open(data_file_name) data_dict = pickle.load(f) f.close() X = data_dict['data'] t = data_dict['labels'] K = data_dict['K'] if len(t.shape) == 1 or t.shape[0] == 1 or t.shape[1] == 1: T = util.vec_to_mat(t, K) else: T = t data = Data() data.X = X data.T = T data.K = K return data def save_net(self, model_file_name): """Save the current neural net to a file.""" pass def display(self): print '[' + str(self.output) + ']' for i in range(self.num_layers-1, -1, -1): print '[' + str(self.layer[i]) + ']' print '[input ' + str(self.input_dim) + ']' print 'learn_rate : ' + str(self.config.learn_rate) print 'init_scale : ' + str(self.config.init_scale) print 'momentum : ' + str(self.config.momentum) print 'weight_decay : ' + str(self.config.weight_decay)
def create_cell(self): # FIXME: Should create cells base on network structure hidden = HiddenLayer(self.hidden_size) output = OutputLayer(self.hidden_size) return (hidden, output)
class NN: """A class for general purpose neural networks, trained with backpropagation. The type of activation functions, number of hidden layers and number of units in each layer, the output function, and other options during training can be configured.""" def __init__(self): self.task_loss_fn = None def load_train_data(self, data): self.train_data = data self.train_data.X = gnp.garray(data.X) def load_val_data(self, data): self.val_data = data self.val_data.X = gnp.garray(data.X) def load_test_data(self, data): self.test_data = data self.test_data.X = gnp.garray(data.X) def init_net_without_loading_data(self, config): """This should be called after loading all required data.""" self.config = config if config.is_output and (not os.path.exists(config.output_dir)): os.makedirs(config.output_dir) [num_total_cases, input_dim] = self.train_data.X.shape self.num_total_cases = num_total_cases self.input_dim = input_dim self.num_minibatches = num_total_cases / config.minibatch_size if self.num_minibatches < 1: self.num_minibatches = 1 # initialize the network self.num_layers = config.num_layers self.layer = [] in_dim = input_dim for i in range(self.num_layers): layer_spec = config.layer[i] self.layer.append(Layer( in_dim, layer_spec.out_dim, layer_spec.act_type, layer_spec.weight_decay, layer_spec.weight_constraint, layer_spec.dropout)) in_dim = layer_spec.out_dim self.output = OutputLayer(in_dim, config.output.out_dim, config.output.output_type, config.output.weight_decay, config.output.weight_constraint, config.output.dropout) # if not linear output (regression) load task loss function if not isinstance(self.output.act_type, act.LinearOutput): if config.task_loss_file != None: self.task_loss = self.read_loss(config.task_loss_file) print 'Loading task loss from %s' % config.task_loss_file else: self.task_loss = 1 - np.eye(self.train_data.K) print 'No task loss specified, using 0-1 loss.' # To use multi-class hinge output, a training loss function is required if isinstance(self.output.act_type, act.MulticlassHingeOutput): if config.train_loss_file != None: self.train_loss = self.read_loss(config.train_loss_file) print 'Loading surrogate loss from %s' % config.train_loss_file else: self.train_loss = 1 - np.eye(self.train_data.K) print 'No surrogate loss specified, using 0-1 loss.' self.output.act_type.set_loss(self.train_loss) # initialize the weights in every layer self._init_weights(config.init_scale, config.random_seed) def init_net(self, config): """config is an instance of class Config""" self.train_data = self.read_data(config.train_data_file) print 'Loading training data from %s' % config.train_data_file if config.is_val: self.val_data = self.read_data(config.val_data_file) print 'Loading validation data from %s' % config.val_data_file if config.is_test: self.test_data = self.read_data(config.test_data_file) print 'Loading test data from %s' % config.test_data_file self.init_net_without_loading_data(config) def load_net(self, model_file): """Load a saved model from a specified file.""" nnstore = NNStore() nnstore.load(model_file) self.build_net_from_copy(nnstore) def make_copy(self): """ Make a CPU copy of the net. This copy can be used to recover the net. """ nnstore = NNStore() nnstore.init_from_net(self) return nnstore def build_net_from_copy(self, copy): """ Rebuild the net from a copy made by make_copy. """ nnstore = copy self.num_layers = len(nnstore.layer) self.layer = [] for i in range(self.num_layers): in_dim, out_dim = nnstore.layer[i].W.shape new_layer = Layer(in_dim, out_dim, nnstore.layer[i].act_type) new_layer.load_weight(nnstore.layer[i].W, nnstore.layer[i].b) self.layer.append(new_layer) in_dim, out_dim = nnstore.output.W.shape new_layer = OutputLayer(in_dim, out_dim, nnstore.output.act_type) new_layer.load_weight(nnstore.output.W, nnstore.output.b) self.output = new_layer if self.num_layers > 0: self.input_dim = self.layer[0].W.shape[0] else: self.input_dim = self.output.W.shape[0] def _init_weights(self, init_scale, random_seed=None): if random_seed: np.random.seed(random_seed) for i in range(0, self.num_layers): self.layer[i].init_weight(init_scale) self.output.init_weight(init_scale) def set_task_loss(self, task_loss_fn): """Set the task loss function to be user defined task loss. task_loss_fn should have a signature like this: task_loss_fn(OutputType, Y, Z, A) """ self.task_loss_fn = task_loss_fn def _compute_loss(self, X, T, batch_size=1000): n_total = X.shape[0] n_batches = n_total / batch_size loss = 0 for i in range(n_batches): gnp.free_reuse_cache() i_start = i * batch_size if i < n_batches - 1: i_end = i_start + batch_size else: i_end = n_total Xbatch = X[i_start:i_end] Tbatch = T[i_start:i_end] self._forward(Xbatch) loss += self.output.loss(Tbatch) return loss / n_total def train(self): config = self.config # convert t into a matrix in 1-of-K representation if it is a vector t = self.train_data.T T_matrix = self.output.act_type.label_vec_to_mat(t, self.train_data.K) layer_config = LayerConfig() layer_config.learn_rate = config.learn_rate layer_config.momentum = config.init_momentum layer_config.weight_decay = config.weight_decay nnstore = NNStore() nnstore.init_from_net(self) best_net = NNStore() best_net.init_from_net(self) train_acc, val_acc, test_acc = self.display_training_info( -1, self._compute_loss( self.train_data.X, T_matrix, config.minibatch_size), 0) acc_rec = np.zeros((config.num_epochs / config.epoch_to_display + 1, 4)) acc_rec[0, 0] = 0 acc_rec[0, 1] = train_acc if config.is_val: acc_rec[0, 2] = val_acc if config.is_test: acc_rec[0, 3] = test_acc t_start = time.time() best_acc = val_acc if self.config.is_test: best_test_acc = test_acc best_epoch = -1 for epoch in range(0, config.num_epochs): gnp.free_reuse_cache() # decrease learning rate over time layer_config.learn_rate = config.learn_rate / \ (epoch / config.lr_drop_rate + 1) # TODO [dirty] special for Lnsvm if isinstance(self.output.act_type, act.LnsvmVariantOutput): #self.output.act_type.n = 3.0 - (3.0 - 0.5) / 50 * epoch self.output.act_type.n = 0.5 if self.output.act_type.n < 0.5: self.output.act_type.n = 0.5 if (epoch + 1) % config.epoch_to_display == 0: print 'n %.4f' % self.output.act_type.n, if epoch >= config.switch_epoch: layer_config.momentum = config.final_momentum # shuffle the dataset idx = np.random.permutation(self.num_total_cases) #idx = np.arange(self.num_total_cases) train_X = self.train_data.X[idx] train_T = T_matrix[idx] if config.input_noise > 0: train_X = train_X * (gnp.rand(train_X.shape) > config.input_noise) # train_X = train_X + gnp.randn(train_X.shape) * config.input_noise loss = 0 for batch in range(0, self.num_minibatches): i_start = batch * config.minibatch_size if not batch == self.num_minibatches - 1: i_end = i_start + config.minibatch_size else: i_end = self.num_total_cases X = train_X[i_start:i_end] T = train_T[i_start:i_end] # forward pass self._forward(X) # compute loss loss += self.output.loss(T) if self.output.Y.isnan().any(): import ipdb ipdb.set_trace() print 'batch #%d <-- nan' % batch # backprop dLdXabove = self.output.backprop(layer_config) for i in range(self.num_layers-1, -1, -1): dLdXabove = self.layer[i].backprop(dLdXabove, layer_config) # statistics avg_loss = 1.0 * loss / self.num_total_cases if (epoch + 1) % config.epoch_to_display == 0: train_acc, val_acc, test_acc = self.display_training_info( epoch, avg_loss, time.time() - t_start) if val_acc == None: val_acc = train_acc if (config.show_task_loss and val_acc < best_acc) or \ (not config.show_task_loss and val_acc > best_acc): best_acc = val_acc best_net.update_from_net(self) if config.is_test: best_test_acc = test_acc best_epoch = epoch t_start = time.time() acc_rec[(epoch + 1) / config.epoch_to_display, 0] = epoch + 1 acc_rec[(epoch + 1) / config.epoch_to_display, 1] = train_acc if config.is_val: acc_rec[(epoch + 1) / config.epoch_to_display, 2] = val_acc if config.is_test: acc_rec[(epoch + 1) / config.epoch_to_display, 3] = test_acc if (epoch + 1) % config.epoch_to_save == 0: nnstore.update_from_net(self) nnstore.write(config.output_dir + '/m' + str(epoch + 1) + '.pdata') print '----------------------------------------------------------------' if config.show_task_loss: s = 'loss' else: s = 'acc' if config.is_val: print 'Best val_%s %.4f' % (s, best_acc), else: print 'Best train_%s %.4f' % (s, best_acc), if config.is_test: print '--> test_%s %.4f' % (s, best_test_acc), print 'at epoch %d' % (best_epoch + 1) if config.is_output: f = open('%s/acc_rec.pdata' % config.output_dir, 'w') pickle.dump(acc_rec, f, -1) f.close() self.write_config('%s/cfg.txt' % config.output_dir) # save the best net fname = config.output_dir + '/best_net.pdata' print 'Saving the best model to ' + fname best_net.write(fname) if config.is_test: return (best_acc, best_test_acc) else: return (best_acc) def display_training_info(self, epoch, loss, time): """Print training information. Use the config information to determine what information to display. Return a 3-tuple (train acc, val acc, test acc) val acc and test acc will be 0 if no validation/test data are given """ if self.config.is_val: if self.config.is_test: return self._display_training_info(epoch, loss, time, self.train_data.X, self.train_data.T, val_data=self.val_data.X, val_labels=self.val_data.T, test_data=self.test_data.X, test_labels=self.test_data.T) else: return self._display_training_info(epoch, loss, time, self.train_data.X, self.train_data.T, val_data=self.val_data.X, val_labels=self.val_data.T) else: if self.config.is_test: return self._display_training_info(epoch, loss, time, self.train_data.X, self.train_data.T, test_data=self.test_data.X, test_labels=self.test_data.T) else: return self._display_training_info(epoch, loss, time, self.train_data.X, self.train_data.T) def _display_training_info(self, epoch, loss, time, train_data, train_labels, val_data=None, val_labels=None, test_data=None, test_labels=None): """Print training information during training.""" print 'epoch %d, surrogate loss %.4f,' % (epoch + 1, loss), train_acc = 0 val_acc = None test_acc = None acc = 0 # print loss if it is a regression problem if self.config.is_regression: # TODO [Dirty code] #self.predict(train_data) #avg_loss = self.output.task_loss(train_labels, self.task_loss_fn) avg_loss = np.sqrt(self._compute_loss(train_data, train_labels) * 2) print 'train_loss %.4f,' % avg_loss, if val_data != None and val_labels != None: #self.predict(val_data) #avg_loss = self.output.task_loss(val_labels, self.task_loss_fn) avg_loss = np.sqrt(self._compute_loss(val_data, val_labels) * 2) print 'val_loss %.4f,' % (avg_loss), val_acc = avg_loss if test_data != None and test_labels != None: #self.predict(test_data) #avg_loss = self.output.task_loss(test_labels, self.task_loss_fn) avg_loss = np.sqrt(self._compute_loss(test_data, test_labels) * 2) print 'test_loss %.4f,' % (avg_loss), test_acc = avg_loss else: # print accuracy if it is a classification problem ypred = self.predict(train_data) if self.config.show_accuracy: acc = (ypred == train_labels.squeeze()).mean() print 'acc %.4f,' % acc, if self.config.show_task_loss: acc = self.task_loss[ypred, train_labels].mean() print 'loss %.4f,' % acc, train_acc = acc if val_data != None and val_labels != None: ypred = self.predict(val_data) if self.config.show_accuracy: acc = (ypred == val_labels.squeeze()).mean() print 'val_acc %.4f,' % acc, if self.config.show_task_loss: acc = self.task_loss[ypred, val_labels].mean() print 'val_loss %.4f,' % acc, val_acc = acc if test_data != None and test_labels != None: ypred = self.predict(test_data) if self.config.show_accuracy: acc = (ypred == test_labels.squeeze()).mean() print 'test_acc %.4f,' % acc, if self.config.show_task_loss: acc = self.task_loss[ypred, test_labels].mean() print 'test_loss %.4f,' % acc, test_acc = acc if self.config.display_winc: self.display_winc() print 'time %.2f' % time return (train_acc, val_acc, test_acc) def display_winc(self): """Display scale of weight updates. This can be used by external applications.""" for i in range(0, self.num_layers): print 'winc%d %.5f,' % (i+1, gnp.abs(self.layer[i].Winc).max()), print 'winc_out %.5f,' % gnp.abs(self.output.Winc).max(), def _forward(self, X): """Do a forward pass without computing the output and predictions. Used as a subroutine for function predict and check_grad.""" Xbelow = X for i in range(self.num_layers): Xbelow = self.layer[i].forward(Xbelow) self.output.forward(Xbelow) def predict(self, X): """Make prediction using the current network. X: N*D data matrix Return an N-element vector of predicted labels. """ self._forward(X) return self.output.predict() def forward(self, X): """Compute the activation for each class. X: N*D data matrix Return a N*D activation matrix A. """ self._forward(X) return self.output.A def _backprop(self, config): """Backpropagate through the net from the output layer. This will be used as an external interface for semi-supervised application, and the backprop starts from the `update_weights` method of the output layer, rather than the `backprop` method.""" dLdXabove = self.output.update_weights(config) for i in range(self.num_layers-1, -1, -1): dLdXabove = self.layer[i].backprop(dLdXabove, config) def eval_task_loss(self, X, z, loss): """Evaluate the performance of the net using task specific loss. Classification problems only. X: N*D data matrix z: N-d ground truth matrix. loss: K*K matrix, K is the number of classes. Return the average loss over all datacases. """ y = self.predict(X) return loss[z, y].mean() def read_data(self, data_file_name): """(data_file_name) --> data Read from the specified data file, return a data object, which is an object with three attributes, X, T and K. X and T are the data and target matrices respectively, and K is the dimensionality of the output. Each of X and T is a matrix with N rows, N is the number of data cases.""" f = open(data_file_name) data_dict = pickle.load(f) f.close() data = Data() data.X = gnp.garray(data_dict['data']) #data.T = data_dict['labels'].astype(np.float) data.T = data_dict['labels'] data.K = data_dict['K'] return data def read_loss(self, loss_file_name): """(data_file_name) --> loss Read from the specified data file, return a loss matrix. """ f = open(loss_file_name) d = pickle.load(f) f.close() return d def write_config(self, filename): f = open(filename, 'w') f.write('%d training cases\n' % self.train_data.X.shape[0]) if self.config.is_val: f.write('%d validation cases\n' % self.val_data.X.shape[0]) if self.config.is_test: f.write('%d test cases\n' % self.test_data.X.shape[0]) f.write('[' + str(self.output) + ']\n') for i in range(self.num_layers-1, -1, -1): f.write('[' + str(self.layer[i]) + ']\n') f.write('[input ' + str(self.input_dim) + ']\n') f.write('learn_rate : ' + str(self.config.learn_rate) + '\n') f.write('init_scale : ' + str(self.config.init_scale) + '\n') f.write('init_momentum : ' + str(self.config.init_momentum) + '\n') f.write('switch_epoch : ' + str(self.config.switch_epoch) + '\n') f.write('final_momentum : ' + str(self.config.final_momentum) + '\n') f.write('weight_decay : ' + str(self.config.weight_decay) + '\n') f.write('minibatch_size : ' + str(self.config.minibatch_size) + '\n') f.write('num_epochs : ' + str(self.config.num_epochs) + '\n') f.write('epoch_to_save : ' + str(self.config.epoch_to_save) + '\n') f.close() def display_structure(self): print '[' + str(self.output) + ']' for i in range(self.num_layers-1, -1, -1): print '[' + str(self.layer[i]) + ']' print '[input ' + str(self.input_dim) + ']' def display(self): print '%d training cases' % self.train_data.X.shape[0] if self.config.is_val: print '%d validation cases' % self.val_data.X.shape[0] if self.config.is_test: print '%d test cases' % self.test_data.X.shape[0] self.display_structure() print 'learn_rate : ' + str(self.config.learn_rate) print 'init_scale : ' + str(self.config.init_scale) print 'init_momentum : ' + str(self.config.init_momentum) print 'switch_epoch : ' + str(self.config.switch_epoch) print 'final_momentum : ' + str(self.config.final_momentum) print 'weight_decay : ' + str(self.config.weight_decay) print 'minibatch_size : ' + str(self.config.minibatch_size) print 'num_epochs : ' + str(self.config.num_epochs) print 'epoch_to_save : ' + str(self.config.epoch_to_save) if self.config.is_output: print 'output_dir : ' + self.config.output_dir def check_grad(self): # check the gradient of the 1st layer weights import scipy.optimize as opt ncases = 100 def f(w): if self.num_layers == 0: Wtemp = self.output.W self.output.W = gnp.garray(w.reshape(Wtemp.shape)) else: Wtemp = self.layer[0].W self.layer[0].W = gnp.garray(w.reshape(Wtemp.shape)) self._forward(self.train_data.X[:ncases,:]) Z = self.train_data.T[:ncases] Z = self.output.act_type.label_vec_to_mat(Z, self.train_data.K) L = self.output.loss(Z) / Z.shape[0] if self.num_layers == 0: self.output.W = Wtemp else: self.layer[0].W = Wtemp return L def fgrad(w): if self.num_layers == 0: Wtemp = self.output.W self.output.W = gnp.garray(w.reshape(Wtemp.shape)) else: Wtemp = self.layer[0].W self.layer[0].W = gnp.garray(w.reshape(Wtemp.shape)) self._forward(self.train_data.X[:ncases,:]) Z = self.train_data.T[:ncases] Z = self.output.act_type.label_vec_to_mat(Z, self.train_data.K) self.output.loss(Z) self.output.gradient() dLdXabove = self.output.dLdXtop for i in range(self.num_layers-1, -1, -1): self.layer[i].gradient(dLdXabove) dLdXabove = self.layer[i].dLdXbelow if self.num_layers == 0: grad_w = self.output.dLdW else: grad_w = self.layer[0].dLdW if self.num_layers == 0: self.output.W = Wtemp else: self.layer[0].W = Wtemp return grad_w.reshape(np.prod(grad_w.shape)).asarray() / Z.shape[0] if self.num_layers == 0: W = self.output.W else: W = self.layer[0].W W = W.asarray() def finite_diff_grad(f, x0): eps = 1e-8 approx = np.zeros(len(x0)) for i in xrange(len(x0)): x0plus = x0.copy() x0minus = x0.copy() x0plus[i] += eps x0minus[i] -= eps approx[i] = (f(x0plus) - f(x0minus)) / (2 * eps) return approx net_grad = fgrad(W.reshape(W.size)) fd_grad = finite_diff_grad(f, W.reshape(W.size)) print "wmax: %f" % np.abs(net_grad).max() print "finite difference grad scale: %f" % np.abs(fd_grad).max() print "check_grad err: %f" % np.sqrt(((fd_grad - net_grad)**2).sum())
class TrainingMethodTest( unittest.TestCase ): @classmethod def setUpClass( self ): from opencl import OpenCL from layer import InputLayer, OutputLayer, ExecutionContext self.ocl = OpenCL( pyopencl.create_some_context() ) self.i = InputLayer( 2, self.ocl ) self.o = OutputLayer( 1, self.ocl ) self.i.link_next( self.o ) self.nnc = ExecutionContext( self.i, self.o, allow_training = True ) self.i.set_weights( numpy.array( [ 0.1 ] * self.i.weights_count, numpy.float32 ) ) self.o.set_weights( numpy.array( [ 0.3 ] * self.o.weights_count, numpy.float32 ) ) self.tr = TrainingResults() self._create_method() @classmethod def _create_method( self ): pass def assertArrayEqual( self, ar1, ar2 ): self.assertEqual( len( ar1 ), len( ar2 ) ) for x, y in zip( numpy.array( ar1, numpy.float32 ), numpy.array( ar2, numpy.float32 ) ): self.assertAlmostEqual( x, y, places = 5 ) def test_create( self ): self.setUpClass() if not getattr( self, 'method', None ): return self.assertAlmostEqual( self.method.n, 0.5 ) self.assertAlmostEqual( self.method.alpha, 0.2 ) self.assertAlmostEqual( self.method.kw, 1.03 ) self.assertAlmostEqual( self.method.pd, 0.7 ) self.assertAlmostEqual( self.method.pi, 1.02 ) self.assertAlmostEqual( self.method.last_error, 0.0 ) self.assertEqual( self.method.offline, False ) def test_randomize_weights( self ): if not getattr( self, 'method', None ): return self.i.set_weights( numpy.array( [ 0.1 ] * self.i.weights_count, numpy.float32 ) ) self.assertTrue( all( map( lambda x: abs( x - 0.1 ) < 0.0001, self.i.get_weights() ) ) ) self.method.randomize_weights( self.nnc ) w1 = self.i.get_weights() self.assertFalse( all( map( lambda x: abs( x - 0.1 ) < 0.0001, self.i.get_weights() ) ) ) self.method.randomize_weights( self.nnc ) self.assertFalse( all( map( lambda x: abs( x - 0.1 ) < 0.0001, self.i.get_weights() ) ) ) self.assertNotAlmostEqual( ( w1 - self.i.get_weights() ).sum(), 0.0 ) def test_adjust_weights( self ): if not getattr( self, 'method', None ): return self.method.last_error = numpy.float32( 1.0 ) self.method.n = numpy.float32( 0.5 ) self.method.kw = numpy.float32( 1.03 ) self.method.pd = numpy.float32( 0.5 ) self.method.pi = numpy.float32( 1.5 ) self.method.adjust_training_parameters( 1.2 ) self.assertAlmostEqual( self.method.n, 0.25 ) self.assertAlmostEqual( self.method.last_error, 1.2 ) self.method.adjust_training_parameters( 1.0 ) self.assertAlmostEqual( self.method.n, 0.375 ) self.assertAlmostEqual( self.method.last_error, 1.0 ) self.method.adjust_training_parameters( 1.0 ) self.assertAlmostEqual( self.method.n, 0.5625 ) self.assertAlmostEqual( self.method.last_error, 1.0 ) def test_prepare_training( self ): if not getattr( self, 'method', None ): return self.method.prepare_training( self.nnc ) self.assertIsInstance( self.method._weights_delta_buf, pyopencl.Buffer )
class NN: """A class for general purpose neural networks, trained with backpropagation. The type of activation functions, number of hidden layers and number of units in each layer, the output function, and other options during training can be configured.""" def __init__(self): pass def init_net(self, config): """config is an instance of class Config""" import os self.config = config if config.is_output and (not os.path.exists(config.output_dir)): os.makedirs(config.output_dir) self.train_data = self.read_data(config.train_data_file) if config.is_val: self.val_data = self.read_data(config.val_data_file) if config.is_test: self.test_data = self.read_data(config.test_data_file) [num_total_cases, input_dim] = self.train_data.X.shape self.num_total_cases = num_total_cases self.input_dim = input_dim self.num_minibatches = num_total_cases / config.minibatch_size if self.num_minibatches < 1: self.num_minibatches = 1 # initialize the network self.num_layers = config.num_layers self.layer = [] in_dim = input_dim for i in range(0, self.num_layers): self.layer.append( Layer(in_dim, config.layer[i].out_dim, config.layer[i].act_type)) in_dim = config.layer[i].out_dim self.output = OutputLayer(in_dim, config.output.out_dim, config.output.output_type) # To use multi-class hinge output, we need to specify the loss function if isinstance(self.output.act_type, act.MulticlassHingeOutput): if config.loss_file != None: self.output.act_type.set_loss(self.read_loss(config.loss_file)) else: self.output.act_type.set_loss(1 - np.eye(self.train_data.K)) # initialize the weights in every layer self._init_weights(config.init_scale, config.random_seed) def _init_weights(self, init_scale, random_seed=None): if random_seed: np.random.seed(random_seed) for i in range(0, self.num_layers): self.layer[i].init_weight(init_scale) self.output.init_weight(init_scale) def train(self): config = self.config # convert t into a matrix in 1-of-K representation if it is a vector t = self.train_data.T if not self.config.is_regression: T_matrix = self.output.act_type.label_vec_to_mat( t, self.train_data.K) else: T_matrix = t layer_config = LayerConfig() layer_config.learn_rate = config.learn_rate layer_config.momentum = config.momentum layer_config.weight_decay = config.weight_decay nnstore = NNStore() nnstore.init_from_net(self) self.display_training_info(-1, 0, 0) t_start = time.time() for epoch in range(0, config.num_epochs): # shuffle the dataset idx = np.random.permutation(self.num_total_cases) train_X = self.train_data.X[idx] train_T = T_matrix[idx] loss = 0 for batch in range(0, self.num_minibatches): i_start = batch * config.minibatch_size if not batch == self.num_minibatches - 1: i_end = i_start + config.minibatch_size else: i_end = self.num_total_cases X = train_X[i_start:i_end] T = train_T[i_start:i_end] Xbelow = X # forward pass for i in range(0, self.num_layers): Xbelow = self.layer[i].forward(Xbelow) self.output.forward(Xbelow) # compute loss loss += self.output.loss(T) # backprop dLdXabove = self.output.backprop(layer_config) for i in range(self.num_layers - 1, -1, -1): dLdXabove = self.layer[i].backprop(dLdXabove, layer_config) # statistics avg_loss = 1.0 * loss / self.num_total_cases if (epoch + 1) % config.epoch_to_display == 0: self.display_training_info(epoch, avg_loss, time.time() - t_start) t_start = time.time() if (epoch + 1) % config.epoch_to_save == 0: nnstore.update_from_net(self) nnstore.write(config.output_dir + '/m' + str(epoch + 1) + '.pdata') def display_training_info(self, epoch, loss, time): """Print training information. Use the config information to determine what information to display.""" if self.config.is_val: if self.config.is_test: self._display_training_info(epoch, loss, time, self.train_data.X, self.train_data.T, val_data=self.val_data.X, val_labels=self.val_data.T, test_data=self.test_data.X, test_labels=self.test_data.T) else: self._display_training_info(epoch, loss, time, self.train_data.X, self.train_data.T, val_data=self.val_data.X, val_labels=self.val_data.T) else: if self.config.is_test: self._display_training_info(epoch, loss, time, self.train_data.X, self.train_data.T, test_data=self.test_data.X, test_labels=self.test_data.T) else: self._display_training_info(epoch, loss, time, self.train_data.X, self.train_data.T) def _display_training_info(self, epoch, loss, time, train_data, train_labels, val_data=None, val_labels=None, test_data=None, test_labels=None): """Print training information during training.""" print 'epoch %d, loss %.4f,' % (epoch + 1, loss), # print loss if it is a regression problem if self.config.is_regression: if val_data != None and val_labels != None: self.predict(val_data) avg_loss = self.output.loss(val_labels) / val_labels.shape[0] print 'val_loss %.4f,' % (avg_loss), if test_data != None and test_labels != None: self.predict(test_data) avg_loss = self.output.loss(test_labels) / test_labels.shape[0] print 'test_loss %.4f,' % (avg_loss), else: # print accuracy if it is a classification problem ypred = self.predict(train_data) acc = (ypred == train_labels.squeeze()).mean() print 'acc %.4f,' % acc, if val_data != None and val_labels != None: ypred = self.predict(val_data) acc = (ypred == val_labels.squeeze()).mean() print 'val_acc %.4f,' % acc, if test_data != None and test_labels != None: ypred = self.predict(test_data) acc = (ypred == test_labels.squeeze()).mean() print 'test_acc %.4f,' % acc, if self.config.display_winc: for i in range(0, self.num_layers): print 'winc%d %.5f,' % (i + 1, np.abs( self.layer[i].Winc).max()), print 'winc_out %.5f,' % np.abs(self.output.Winc).max(), print 'time %.2f' % time def _forward(self, X): """Do a forward pass without computing the output and predictions. Used as a subroutine for function predict and check_grad.""" Xbelow = X for i in range(0, self.num_layers): Xbelow = self.layer[i].forward(Xbelow) self.output.forward(Xbelow) def predict(self, X): """Make prediction using the current network. X: N*D data matrix ispad: if True, X is padded by an extra dimension of constant 1's Return an N-element vector of predicted labels. """ self._forward(X) return self.output.predict() def read_data(self, data_file_name): """(data_file_name) --> data Read from the specified data file, return a data object, which is an object with three attributes, X, T and K. X and T are the data and target matrices respectively, and K is the dimensionality of the output. Each of X and T is a matrix with N rows, N is the number of data cases.""" f = open(data_file_name) data_dict = pickle.load(f) f.close() data = Data() data.X = data_dict['data'] data.T = data_dict['labels'] data.K = data_dict['K'] return data def read_loss(self, loss_file_name): """(data_file_name) --> loss Read from the specified data file, return a loss matrix. """ f = open(loss_file_name) d = pickle.load(f) f.close() return d['loss'] def display(self): print '%d training cases' % self.train_data.X.shape[0] if self.config.is_val: print '%d validation cases' % self.val_data.X.shape[0] if self.config.is_test: print '%d test cases' % self.test_data.X.shape[0] print '[' + str(self.output) + ']' for i in range(self.num_layers - 1, -1, -1): print '[' + str(self.layer[i]) + ']' print '[input ' + str(self.input_dim) + ']' print 'learn_rate : ' + str(self.config.learn_rate) print 'init_scale : ' + str(self.config.init_scale) print 'momentum : ' + str(self.config.momentum) print 'weight_decay : ' + str(self.config.weight_decay) print 'minibatch_size : ' + str(self.config.minibatch_size) print 'num_epochs : ' + str(self.config.num_epochs) print 'epoch_to_save : ' + str(self.config.epoch_to_save) def check_grad(self): # check the gradient of the 1st layer weights import scipy.optimize as opt ncases = 100 def f(w): if self.num_layers == 0: Wtemp = self.output.W self.output.W = w.reshape(Wtemp.shape) else: Wtemp = self.layer[0].W self.layer[0].W = w.reshape(Wtemp.shape) self._forward(self.train_data.X[:ncases, :]) Z = self.train_data.T[:ncases] if not self.config.is_regression: Z = self.output.act_type.label_vec_to_mat(Z, self.train_data.K) L = self.output.loss(Z) / Z.shape[0] if self.num_layers == 0: self.output.W = Wtemp else: self.layer[0].W = Wtemp return L def fgrad(w): if self.num_layers == 0: Wtemp = self.output.W self.output.W = w.reshape(Wtemp.shape) else: Wtemp = self.layer[0].W self.layer[0].W = w.reshape(Wtemp.shape) self._forward(self.train_data.X[:ncases, :]) Z = self.train_data.T[:ncases] if not self.config.is_regression: Z = self.output.act_type.label_vec_to_mat(Z, self.train_data.K) self.output.loss(Z) self.output.gradient() dLdXabove = self.output.dLdXtop[:, :-1] for i in range(self.num_layers - 1, -1, -1): self.layer[i].gradient(dLdXabove) dLdXabove = self.layer[i].dLdXbelow[:, :-1] if self.num_layers == 0: grad_w = self.output.dLdW else: grad_w = self.layer[0].dLdW if self.num_layers == 0: self.output.W = Wtemp else: self.layer[0].W = Wtemp return grad_w.reshape(np.prod(grad_w.shape)) / Z.shape[0] if self.num_layers == 0: #W = np.random.randn( # self.output.W.shape[0], self.output.W.shape[1]) * 1e-3 W = self.output.W else: #W = np.random.randn( # self.layer[0].W.shape[0], self.layer[0].W.shape[1]) * 1e-3 W = self.layer[0].W print "wmax: %f" % np.abs(fgrad(W.reshape(np.prod(W.shape)))).max() print "check_grad err: %f" % opt.check_grad( f, fgrad, W.reshape(np.prod(W.shape)))