I am currently designing a NoisyNet layer, as proposed here: "Noisy Networks for Exploration", in Tensorflow and get the dimensionality error as indicated in the title, while the dimensions of the two tensors to be multiplied element-wise in line filtered_output = keras.layers.merge.Multiply()([output, actions_input]) should (in principle) be compatible with each other according to the printed output when printing the dimensions of both tensors involved, filtered_output and actions_input, where both tensors seem to be of dimension shape=(1, 4).

I am using Tensorflow 1.12.0 in Python3.

The relevant code looks as follows:

import numpy as np
import tensorflow as tf
import keras

class NoisyLayer(keras.layers.Layer):

    def __init__(self, in_shape=(1,2592), out_units=256, activation=tf.identity): 
        super(NoisyLayer, self).__init__()
        self.in_shape = in_shape
        self.out_units = out_units
        self.mu_interval = 1.0/np.sqrt(float(self.out_units))
        self.sig_0 = 0.5
        self.activation = activation

    def build(self, input_shape):
        # Initializer
        self.mu_initializer = tf.initializers.random_uniform(minval=-self.mu_interval, maxval=self.mu_interval) # Mu-initializer
        self.si_initializer = tf.initializers.constant(self.sig_0/np.sqrt(float(self.out_units)))      # Sigma-initializer

        # Weights
        self.w_mu = tf.Variable(initial_value=self.mu_initializer(shape=(self.in_shape[-1], self.out_units), dtype='float32'), trainable=True) # (1,2592)x(2592,4) = (1,4)
        self.w_si = tf.Variable(initial_value=self.si_initializer(shape=(self.in_shape[-1], self.out_units), dtype='float32'), trainable=True)

        # Biases
        self.b_mu = tf.Variable(initial_value=self.mu_initializer(shape=(self.in_shape[0], self.out_units), dtype='float32'), trainable=True)
        self.b_si = tf.Variable(initial_value=self.si_initializer(shape=(self.in_shape[0], self.out_units), dtype='float32'), trainable=True)

    def call(self, inputs, resample_noise_flag):
        if resample_noise_flag:

        # Putting it all together
        self.w = tf.math.add(self.w_mu, tf.math.multiply(self.w_si, self.w_eps))
        self.b = tf.math.add(self.b_mu, tf.math.multiply(self.b_si, self.q_eps))

        return self.activation(tf.linalg.matmul(inputs, self.w) + self.b)

    def assign_resampling(self):
        self.p_eps = self.f(self.resample_noise([self.in_shape[-1], 1]))
        self.q_eps = self.f(self.resample_noise([1, self.out_units]))
        self.w_eps = self.p_eps * self.q_eps         # Cartesian product of input_noise x output_noise

    def resample_noise(self, shape):
        return tf.random.normal(shape, mean=0.0, stddev=1.0, seed=None, name=None)

    def f(self, x):
        return tf.math.multiply(tf.math.sign(x), tf.math.sqrt(tf.math.abs(x)))

frames_input = tf.ones((1, 84, 84, 4))  # Toy input

conv1 = keras.layers.Conv2D(16, (8, 8), strides=(4, 4), activation="relu")(frames_input)
conv2 = keras.layers.Conv2D(32, (4, 4), strides=(2, 2), activation="relu")(conv1)

flattened = keras.layers.Flatten()(conv2)

actionspace_size = 4  

# NoisyNet        
hidden = NoisyLayer(activation=tf.nn.relu)(inputs=flattened, resample_noise_flag=True)
output = NoisyLayer(in_shape=(1,256), out_units=actionspace_size)(inputs=hidden, resample_noise_flag=True)

actions_input = tf.ones((1,actionspace_size))

print('hidden:\n', hidden)
print('output:\n', output)
print('actions_input:\n', actions_input)

filtered_output = keras.layers.merge.Multiply()([output, actions_input])

The output, when I run the code, looks as follows:

 Tensor("noisy_layer_5/Relu:0", shape=(1, 256), dtype=float32)
 Tensor("noisy_layer_6/Identity:0", shape=(1, 4), dtype=float32)
 Tensor("ones_5:0", shape=(1, 4), dtype=float32)


ValueError                                Traceback (most recent call last)

<ipython-input-4-f6df621eacab> in <module>()
     68 print('actions_input:\n', actions_input)
---> 70 filtered_output = keras.layers.merge.Multiply()([output, actions_input])

2 frames

/usr/local/lib/python3.6/dist-packages/keras/layers/merge.py in _compute_elemwise_op_output_shape(self, shape1, shape2)
     59                     raise ValueError('Operands could not be broadcast '
     60                                      'together with shapes ' +
---> 61                                      str(shape1) + ' ' + str(shape2))
     62                 output_shape.append(i)
     63         return tuple(output_shape)

ValueError: Operands could not be broadcast together with shapes (2592,) (4,)

Particularly, I am wondering where the number 2592 in Operands could not be broadcast together with shapes (2592,) (4,) comes from, since the number coincides with the length of the flattened input tensor flattened to the first noisy layer, but is -as it seems to me- not part of the output dimension of the second noisy layer output anymore, which in turn serves as the input to the erroneous line indicated above.

Does anyone know what's going wrong?

Thanks in advance, Daniel


As stated in the custom layer document, you need to implement compute_output_shape(input_shape) method:

compute_output_shape(input_shape): in case your layer modifies the shape of its input, you should specify here the shape transformation logic. This allows Keras to do automatic shape inference.

Keras can't do shape inference without actually executing the computation when you don't apply this method.


(1, 2592)
(1, 2592)

So you need to add it as follows:

def compute_output_shape(self, input_shape):
    return (input_shape[0], self.out_units)

In addition, build() method must set self.built = True at the end, which can be done by calling super(NoisyLayer, self).build(input_shape) according to the document.

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