modules.py

# -*- coding: utf-8 -*-
#/usr/bin/python2
'''
June 2017 by kyubyong park. 
kbpark.linguist@gmail.com.
https://www.github.com/kyubyong/transformer
'''

import tensorflow as tf
import numpy as np


def normalize(inputs, 
              epsilon = 1e-8,
              scope="ln",
              reuse=None):
    
    with tf.variable_scope(scope, reuse=reuse):
        inputs_shape = inputs.get_shape()
        params_shape = inputs_shape[-1:]
    
        mean, variance = tf.nn.moments(inputs, [-1], keep_dims=True)
        beta= tf.Variable(tf.zeros(params_shape))
        gamma = tf.Variable(tf.ones(params_shape))
        normalized = (inputs - mean) / ( (variance + epsilon) ** (.5) )
        outputs = gamma * normalized + beta
        
    return outputs


def embedding(inputs, 
              vocab_size, 
              num_units, 
              preemb=None, 
              trainable=True, 
              zero_pad=True, 
              scale=True, 
              scope="embedding", 
              reuse=None):
    
    with tf.variable_scope(scope, reuse=reuse):
        if preemb is not None:
            init = tf.constant_initializer(preemb)
        else:
            init = tf.contrib.layers.xavier_initializer()

        lookup_table = tf.get_variable('lookup_table',
                                       dtype=tf.float32,
                                       shape=[vocab_size, num_units],
                                       initializer=init,
                                       trainable=trainable)

        if zero_pad:
            lookup_table = tf.concat((tf.zeros(shape=[1, num_units]),
                                      lookup_table[1:, :]), 0)
        outputs = tf.nn.embedding_lookup(lookup_table, inputs)
        
        if scale:
            outputs = outputs * (num_units ** 0.5) 
            
    return outputs


def positional_encoding(inputs,
                        vocab_size,
                        num_units,
                        zero_pad=True,
                        scale=True,
                        scope="positional_encoding",
                        reuse=None):

    with tf.variable_scope(scope, reuse=reuse):
        # First part of the PE function: sin and cos argument
        position_enc = np.array([
            [pos / np.power(10000, 2.*i/num_units) for i in range(num_units)]
            for pos in range(vocab_size)])

        # Second part, apply the cosine to even columns and sin to odds.
        position_enc[:, 0::2] = np.sin(position_enc[:, 0::2])  # dim 2i
        position_enc[:, 1::2] = np.cos(position_enc[:, 1::2])  # dim 2i+1

        # Convert to a tensor
        lookup_table = tf.convert_to_tensor(position_enc.astype('float32'))

        if zero_pad:
            lookup_table = tf.concat((tf.zeros(shape=[1, num_units]),
                                      lookup_table[1:, :]), 0)
        outputs = tf.nn.embedding_lookup(lookup_table, inputs)

        if scale:
            outputs = outputs * num_units**0.5

        return outputs


def multihead_attention(queries,
                        keys,
                        drop,
                        dropout_rate=0,
                        num_units=None,
                        num_heads=8,
                        causality=False,
                        residual=False,
                        scope="multihead_attention", 
                        reuse=None):
    
    with tf.variable_scope(scope, reuse=reuse):
        # Set the fall back option for num_units
        if num_units is None:
            num_units = queries.get_shape().as_list[-1]
        
        # Linear projections
        Q = tf.layers.dense(queries, num_units, activation=tf.nn.relu) # (N, T_q, C)
        K = tf.layers.dense(keys, num_units, activation=tf.nn.relu) # (N, T_k, C)
        V = tf.layers.dense(keys, num_units, activation=tf.nn.relu) # (N, T_k, C)
        
        # Split and concat
        Q_ = tf.concat(tf.split(Q, num_heads, axis=2), axis=0) # (h*N, T_q, C/h) 
        K_ = tf.concat(tf.split(K, num_heads, axis=2), axis=0) # (h*N, T_k, C/h) 
        V_ = tf.concat(tf.split(V, num_heads, axis=2), axis=0) # (h*N, T_k, C/h) 

        # Multiplication
        outputs = tf.matmul(Q_, tf.transpose(K_, [0, 2, 1])) # (h*N, T_q, T_k)
        
        # Scale
        outputs = outputs / (K_.get_shape().as_list()[-1] ** 0.5)
        
        # Key Masking
        key_masks = tf.sign(tf.abs(tf.reduce_sum(keys, axis=-1))) # (N, T_k)
        key_masks = tf.tile(key_masks, [num_heads, 1]) # (h*N, T_k)
        key_masks = tf.tile(tf.expand_dims(key_masks, 1), [1, tf.shape(queries)[1], 1]) # (h*N, T_q, T_k)
        
        paddings = tf.ones_like(outputs)*(-2**32+1)
        outputs = tf.where(tf.equal(key_masks, 0), paddings, outputs) # (h*N, T_q, T_k)
  
        # Causality = Future blinding
        if causality:
            diag_vals = tf.ones_like(outputs[0, :, :]) # (T_q, T_k)
            #tril = tf.contrib.linalg.LinearOperatorTriL(diag_vals).to_dense() # (T_q, T_k)
            tril = tf.linalg.LinearOperatorLowerTriangular(diag_vals).to_dense()
            masks = tf.tile(tf.expand_dims(tril, 0), [tf.shape(outputs)[0], 1, 1]) # (h*N, T_q, T_k)
   
            paddings = tf.ones_like(masks)*(-2**32+1)
            outputs = tf.where(tf.equal(masks, 0), paddings, outputs) # (h*N, T_q, T_k)
  
        # Activation
        outputs = tf.nn.softmax(outputs) # (h*N, T_q, T_k)
         
        # Query Masking
        query_masks = tf.sign(tf.abs(tf.reduce_sum(queries, axis=-1))) # (N, T_q)
        query_masks = tf.tile(query_masks, [num_heads, 1]) # (h*N, T_q)
        query_masks = tf.tile(tf.expand_dims(query_masks, -1), [1, 1, tf.shape(keys)[1]]) # (h*N, T_q, T_k)
        outputs *= query_masks # broadcasting. (N, T_q, C)
        
        # Dropouts
        outputs = tf.layers.dropout(outputs, rate=dropout_rate, training=drop)
        
        # Weighted sum
        outputs = tf.matmul(outputs, V_) # ( h*N, T_q, C/h)
        
        # Restore shape
        outputs = tf.concat(tf.split(outputs, num_heads, axis=0), axis=2 ) # (N, T_q, C)
              
        # Residual connection
        if residual:
            outputs += queries
        
        # Normalize
        outputs = normalize(outputs) # (N, T_q, C)
 
    return outputs


def feedforward(inputs, 
                num_units=[2048, 512],
                scope="multihead_attention", 
                reuse=None):
    
    with tf.variable_scope(scope, reuse=reuse):
        # Inner layer
        params = {"inputs": inputs, "filters": num_units[0], "kernel_size": 1,
                  "activation": tf.nn.relu, "use_bias": True}
        outputs = tf.layers.conv1d(**params)
        
        # Readout layer
        params = {"inputs": outputs, "filters": num_units[1], "kernel_size": 1,
                  "activation": None, "use_bias": True}
        outputs = tf.layers.conv1d(**params)
        
        # Residual connection
        outputs += inputs
        
        # Normalize
        outputs = normalize(outputs)
    
    return outputs


def label_smoothing(inputs, epsilon=0.1):
    K = inputs.get_shape().as_list()[-1] # number of channels
    return ((1-epsilon) * inputs) + (epsilon / K)