Mercurial > ift6266
diff deep/rbm/rbm.py @ 347:9685e9d94cc4
base class for an rbm
author | goldfinger |
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date | Mon, 19 Apr 2010 08:16:56 -0400 |
parents | |
children | d81284e13d77 |
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--- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/deep/rbm/rbm.py Mon Apr 19 08:16:56 2010 -0400 @@ -0,0 +1,226 @@ +"""This tutorial introduces restricted boltzmann machines (RBM) using Theano. + +Boltzmann Machines (BMs) are a particular form of energy-based model which +contain hidden variables. Restricted Boltzmann Machines further restrict BMs +to those without visible-visible and hidden-hidden connections. +""" + + +import numpy, time, cPickle, gzip, PIL.Image + +import theano +import theano.tensor as T +import os + +from theano.tensor.shared_randomstreams import RandomStreams + +from utils import tile_raster_images +from logistic_sgd import load_data + + +class RBM(object): + """Restricted Boltzmann Machine (RBM) """ + def __init__(self, input=None, n_visible=784, n_hidden=1000, \ + W = None, hbias = None, vbias = None, numpy_rng = None, + theano_rng = None): + """ + RBM constructor. Defines the parameters of the model along with + basic operations for inferring hidden from visible (and vice-versa), + as well as for performing CD updates. + + :param input: None for standalone RBMs or symbolic variable if RBM is + part of a larger graph. + + :param n_visible: number of visible units + + :param n_hidden: number of hidden units + + :param W: None for standalone RBMs or symbolic variable pointing to a + shared weight matrix in case RBM is part of a DBN network; in a DBN, + the weights are shared between RBMs and layers of a MLP + + :param hbias: None for standalone RBMs or symbolic variable pointing + to a shared hidden units bias vector in case RBM is part of a + different network + + :param vbias: None for standalone RBMs or a symbolic variable + pointing to a shared visible units bias + """ + + self.n_visible = n_visible + self.n_hidden = n_hidden + + + if W is None : + # W is initialized with `initial_W` which is uniformely sampled + # from -6./sqrt(n_visible+n_hidden) and 6./sqrt(n_hidden+n_visible) + # the output of uniform if converted using asarray to dtype + # theano.config.floatX so that the code is runable on GPU + initial_W = numpy.asarray( numpy.random.uniform( + low = -numpy.sqrt(6./(n_hidden+n_visible)), + high = numpy.sqrt(6./(n_hidden+n_visible)), + size = (n_visible, n_hidden)), + dtype = theano.config.floatX) + # theano shared variables for weights and biases + W = theano.shared(value = initial_W, name = 'W') + + if hbias is None : + # create shared variable for hidden units bias + hbias = theano.shared(value = numpy.zeros(n_hidden, + dtype = theano.config.floatX), name='hbias') + + if vbias is None : + # create shared variable for visible units bias + vbias = theano.shared(value =numpy.zeros(n_visible, + dtype = theano.config.floatX),name='vbias') + + if numpy_rng is None: + # create a number generator + numpy_rng = numpy.random.RandomState(1234) + + if theano_rng is None : + theano_rng = RandomStreams(numpy_rng.randint(2**30)) + + + # initialize input layer for standalone RBM or layer0 of DBN + self.input = input if input else T.dmatrix('input') + + self.W = W + self.hbias = hbias + self.vbias = vbias + self.theano_rng = theano_rng + # **** WARNING: It is not a good idea to put things in this list + # other than shared variables created in this function. + self.params = [self.W, self.hbias, self.vbias] + self.batch_size = self.input.shape[0] + + def free_energy(self, v_sample): + ''' Function to compute the free energy ''' + wx_b = T.dot(v_sample, self.W) + self.hbias + vbias_term = T.sum(T.dot(v_sample, self.vbias)) + hidden_term = T.sum(T.log(1+T.exp(wx_b))) + return -hidden_term - vbias_term + + def sample_h_given_v(self, v0_sample): + ''' This function infers state of hidden units given visible units ''' + # compute the activation of the hidden units given a sample of the visibles + h1_mean = T.nnet.sigmoid(T.dot(v0_sample, self.W) + self.hbias) + # get a sample of the hiddens given their activation + h1_sample = self.theano_rng.binomial(size = h1_mean.shape, n = 1, prob = h1_mean) + return [h1_mean, h1_sample] + + def sample_v_given_h(self, h0_sample): + ''' This function infers state of visible units given hidden units ''' + # compute the activation of the visible given the hidden sample + v1_mean = T.nnet.sigmoid(T.dot(h0_sample, self.W.T) + self.vbias) + # get a sample of the visible given their activation + v1_sample = self.theano_rng.binomial(size = v1_mean.shape,n = 1,prob = v1_mean) + return [v1_mean, v1_sample] + + def gibbs_hvh(self, h0_sample): + ''' This function implements one step of Gibbs sampling, + starting from the hidden state''' + v1_mean, v1_sample = self.sample_v_given_h(h0_sample) + h1_mean, h1_sample = self.sample_h_given_v(v1_sample) + return [v1_mean, v1_sample, h1_mean, h1_sample] + + def gibbs_vhv(self, v0_sample): + ''' This function implements one step of Gibbs sampling, + starting from the visible state''' + h1_mean, h1_sample = self.sample_h_given_v(v0_sample) + v1_mean, v1_sample = self.sample_v_given_h(h1_sample) + return [h1_mean, h1_sample, v1_mean, v1_sample] + + def cd(self, lr = 0.1, persistent=None): + """ + This functions implements one step of CD-1 or PCD-1 + + :param lr: learning rate used to train the RBM + :param persistent: None for CD. For PCD, shared variable containing old state + of Gibbs chain. This must be a shared variable of size (batch size, number of + hidden units). + + Returns the updates dictionary. The dictionary contains the update rules for weights + and biases but also an update of the shared variable used to store the persistent + chain, if one is used. + """ + + # compute positive phase + ph_mean, ph_sample = self.sample_h_given_v(self.input) + + # decide how to initialize persistent chain: + # for CD, we use the newly generate hidden sample + # for PCD, we initialize from the old state of the chain + if persistent is None: + chain_start = ph_sample + else: + chain_start = persistent + + # perform actual negative phase + [nv_mean, nv_sample, nh_mean, nh_sample] = self.gibbs_hvh(chain_start) + + # determine gradients on RBM parameters + g_vbias = T.sum( self.input - nv_mean, axis = 0)/self.batch_size + g_hbias = T.sum( ph_mean - nh_mean, axis = 0)/self.batch_size + g_W = T.dot(ph_mean.T, self.input )/ self.batch_size - \ + T.dot(nh_mean.T, nv_mean )/ self.batch_size + + gparams = [g_W.T, g_hbias, g_vbias] + + # constructs the update dictionary + updates = {} + for gparam, param in zip(gparams, self.params): + updates[param] = param + gparam * lr + + if persistent: + # Note that this works only if persistent is a shared variable + updates[persistent] = T.cast(nh_sample, dtype=theano.config.floatX) + # pseudo-likelihood is a better proxy for PCD + cost = self.get_pseudo_likelihood_cost(updates) + else: + # reconstruction cross-entropy is a better proxy for CD + cost = self.get_reconstruction_cost(updates, nv_mean) + + return cost, updates + + def get_pseudo_likelihood_cost(self, updates): + """Stochastic approximation to the pseudo-likelihood""" + + # index of bit i in expression p(x_i | x_{\i}) + bit_i_idx = theano.shared(value=0, name = 'bit_i_idx') + + # binarize the input image by rounding to nearest integer + xi = T.iround(self.input) + + # calculate free energy for the given bit configuration + fe_xi = self.free_energy(xi) + + # flip bit x_i of matrix xi and preserve all other bits x_{\i} + # Equivalent to xi[:,bit_i_idx] = 1-xi[:, bit_i_idx] + # NB: slice(start,stop,step) is the python object used for + # slicing, e.g. to index matrix x as follows: x[start:stop:step] + xi_flip = T.setsubtensor(xi, 1-xi[:, bit_i_idx], + idx_list=(slice(None,None,None),bit_i_idx)) + + # calculate free energy with bit flipped + fe_xi_flip = self.free_energy(xi_flip) + + # equivalent to e^(-FE(x_i)) / (e^(-FE(x_i)) + e^(-FE(x_{\i}))) + cost = self.n_visible * T.log(T.nnet.sigmoid(fe_xi_flip - fe_xi)) + + # increment bit_i_idx % number as part of updates + updates[bit_i_idx] = (bit_i_idx + 1) % self.n_visible + + return cost + + def get_reconstruction_cost(self, updates, nv_mean): + """Approximation to the reconstruction error""" + + cross_entropy = T.mean( + T.sum(self.input*T.log(nv_mean) + + (1 - self.input)*T.log(1-nv_mean), axis = 1)) + + return cross_entropy + + +