# Compute pairwise distance in a batch without replicating tensor in Tensorflow?

I want to compute the pairwise square distance of a batch of feature in Tensorflow. I have a simple implementation using + and * operations by tiling the original tensor :

``````def pairwise_l2_norm2(x, y, scope=None):
with tf.op_scope([x, y], scope, 'pairwise_l2_norm2'):
size_x = tf.shape(x)
size_y = tf.shape(y)
xx = tf.expand_dims(x, -1)
xx = tf.tile(xx, tf.pack([1, 1, size_y]))

yy = tf.expand_dims(y, -1)
yy = tf.tile(yy, tf.pack([1, 1, size_x]))
yy = tf.transpose(yy, perm=[2, 1, 0])

diff = tf.sub(xx, yy)
square_diff = tf.square(diff)

square_dist = tf.reduce_sum(square_diff, 1)

return square_dist
``````

This function takes as input two matrices of size (m,d) and (n,d) and compute the squared distance between each row vector. The output is a matrix of size (m,n) with element 'd_ij = dist(x_i, y_j)'.

The problem is that I have a large batch and high dim features 'm, n, d' replicating the tensor consume a lot of memory. I'm looking for another way to implement this without increasing the memory usage and just only store the final distance tensor. Kind of double looping the original tensor.

• It's not clear that your code is doing 'pairwise distance of a batch of feature`. Can you specify the function you want to do more formally? Also, have you considered tf.squared_difference May 3, 2016 at 22:58
• I update the question to explain this. If you put a batch of features as input of this function it should compute distance between its rows. May 4, 2016 at 1:20

You can use some linear algebra to turn it into matrix ops. Note that what you need matrix `D` where `a[i]` is the `i`th row of your original matrix and

``````D[i,j] = (a[i]-a[j])(a[i]-a[j])'
``````

You can rewrite that into

``````D[i,j] = r[i] - 2 a[i]a[j]' + r[j]
``````

Where `r[i]` is squared norm of `i`th row of the original matrix.

In a system that supports standard broadcasting rules you can treat `r` as a column vector and write `D` as

``````D = r - 2 A A' + r'
``````

In TensorFlow you could write this as

``````A = tf.constant([[1, 1], [2, 2], [3, 3]])
r = tf.reduce_sum(A*A, 1)

# turn r into column vector
r = tf.reshape(r, [-1, 1])
D = r - 2*tf.matmul(A, tf.transpose(A)) + tf.transpose(r)
sess = tf.Session()
sess.run(D)
``````

result

``````array([[0, 2, 8],
[2, 0, 2],
[8, 2, 0]], dtype=int32)
``````
• Thank you. I better understand why broadcasting is interesting. May 5, 2016 at 9:08
• Do you know if this approach is better than using `tf.expand_dims` to exploit broadcasting and then use `tf.squared_difference`? Oct 14, 2016 at 12:02
• I don't know how much of a performance improvement this provides, but `tf.matmul` has arguments for transposing arrays on the fly (`transpose_a` and `transpose_b`). May 2, 2017 at 17:44
• ^ I recently tested this (on GPU, with TF 2.0). `tf.matmul(a, b, transpose_b=True)` was consistently ~40% faster than `tf.matmul(a, tf.transpose(b))`. Nov 21, 2019 at 17:11
• I think it should be noted that this produces the square of the distance and not the distance itself. A simple sqrt at the end gets you the actual distance. I only mention that because of the title of the original Q. May 4, 2021 at 11:52

Using `squared_difference`:

``````def squared_dist(A):
expanded_a = tf.expand_dims(A, 1)
expanded_b = tf.expand_dims(A, 0)
distances = tf.reduce_sum(tf.squared_difference(expanded_a, expanded_b), 2)
return distances
``````

One thing I noticed is that this solution using `tf.squared_difference` gives me out of memory (OOM) for very large vectors, while the approach by @YaroslavBulatov doesn't. So, I think decomposing the operation yields a smaller memory footprint (which I thought `squared_difference` would handle better under the hood).

• thanks for the information that the other solution is less memory intensive. good to know that. +1 for the great answer
– lhk
Nov 16, 2016 at 12:45
• This solution is also less compute efficient. But it is very useful when there is no possibility to use matrix multiplication (e.g. for absolute distance) Dec 18, 2017 at 17:53

Here is a more general solution for two tensors of coordinates `A` and `B`:

``````def squared_dist(A, B):
assert A.shape.as_list() == B.shape.as_list()

row_norms_A = tf.reduce_sum(tf.square(A), axis=1)
row_norms_A = tf.reshape(row_norms_A, [-1, 1])  # Column vector.

row_norms_B = tf.reduce_sum(tf.square(B), axis=1)
row_norms_B = tf.reshape(row_norms_B, [1, -1])  # Row vector.

return row_norms_A - 2 * tf.matmul(A, tf.transpose(B)) + row_norms_B
``````

Note that this is the square distance. If you want to change this to the Euclidean distance, perform a `tf.sqrt` on the result. If you want to do that, don't forget to add a small constant to compensate for the floating point instabilities: `dist = tf.sqrt(squared_dist(A, B) + 1e-6)`.

If you want compute other method , then change the order of the tf modules.

``````def compute_euclidean_distance(x, y):
size_x = x.shape.dims
size_y = y.shape.dims
for i in range(size_x):
tile_one = tf.reshape(tf.tile(x[i], [size_y]), [size_y, -1])
eu_one = tf.expand_dims(tf.sqrt(tf.reduce_sum(tf.pow(tf.subtract(tile_one, y), 2), axis=1)), axis=0)
if i == 0:
d = eu_one
else:
d = tf.concat([d, eu_one], axis=0)
return d
``````