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Tensor contraction over specified indices and outer product.
tf.einsum( equation, *inputs, **kwargs )
Einsum allows defining Tensors by defining their element-wise computation. This computation is defined by equation
, a shorthand form based on Einstein summation. As an example, consider multiplying two matrices A and B to form a matrix C. The elements of C are given by:
or
C[i,k] = sum_j A[i,j] * B[j,k]
The corresponding einsum equation
is:
ij,jk->ik
In general, to convert the element-wise equation into the equation
string, use the following procedure (intermediate strings for matrix multiplication example provided in parentheses):
ik = sum_j ij * jk
)ik = sum_j ij , jk
)ik = ij, jk
)ij,jk->ik
)Note: If the output indices are not specified repeated indices are summed. Soij,jk->ik
can be simplified toij,jk
.
Many common operations can be expressed in this way. For example:
Matrix multiplication
m0 = tf.random.normal(shape=[2, 3]) m1 = tf.random.normal(shape=[3, 5]) e = tf.einsum('ij,jk->ik', m0, m1) # output[i,k] = sum_j m0[i,j] * m1[j, k] print(e.shape) (2, 5)
Repeated indices are summed if the output indices are not specified.
e = tf.einsum('ij,jk', m0, m1) # output[i,k] = sum_j m0[i,j] * m1[j, k] print(e.shape) (2, 5)
Dot product
u = tf.random.normal(shape=[5]) v = tf.random.normal(shape=[5]) e = tf.einsum('i,i->', u, v) # output = sum_i u[i]*v[i] print(e.shape) ()
Outer product
u = tf.random.normal(shape=[3]) v = tf.random.normal(shape=[5]) e = tf.einsum('i,j->ij', u, v) # output[i,j] = u[i]*v[j] print(e.shape) (3, 5)
Transpose
m = tf.ones(2,3) e = tf.einsum('ij->ji', m0) # output[j,i] = m0[i,j] print(e.shape) (3, 2)
Diag
m = tf.reshape(tf.range(9), [3,3]) diag = tf.einsum('ii->i', m) print(diag.shape) (3,)
Trace
# Repeated indices are summed. trace = tf.einsum('ii', m) # output[j,i] = trace(m) = sum_i m[i, i] assert trace == sum(diag) print(trace.shape) ()
Batch matrix multiplication
s = tf.random.normal(shape=[7,5,3]) t = tf.random.normal(shape=[7,3,2]) e = tf.einsum('bij,bjk->bik', s, t) # output[a,i,k] = sum_j s[a,i,j] * t[a, j, k] print(e.shape) (7, 5, 2)
This method does not support broadcasting on named-axes. All axes with matching labels should have the same length. If you have length-1 axes, use tf.squeseze
or tf.reshape
to eliminate them.
To write code that is agnostic to the number of indices in the input use an ellipsis. The ellipsis is a placeholder for "whatever other indices fit here".
For example, to perform a NumPy-style broadcasting-batch-matrix multiplication where the matrix multiply acts on the last two axes of the input, use:
s = tf.random.normal(shape=[11, 7, 5, 3]) t = tf.random.normal(shape=[11, 7, 3, 2]) e = tf.einsum('...ij,...jk->...ik', s, t) print(e.shape) (11, 7, 5, 2)
Einsum will broadcast over axes covered by the ellipsis.
s = tf.random.normal(shape=[11, 1, 5, 3]) t = tf.random.normal(shape=[1, 7, 3, 2]) e = tf.einsum('...ij,...jk->...ik', s, t) print(e.shape) (11, 7, 5, 2)
Args | |
---|---|
equation | a str describing the contraction, in the same format as numpy.einsum . |
*inputs | the inputs to contract (each one a Tensor ), whose shapes should be consistent with equation . |
**kwargs |
|
Returns | |
---|---|
The contracted Tensor , with shape determined by equation . |
Raises | |
---|---|
ValueError | If
|
© 2020 The TensorFlow Authors. All rights reserved.
Licensed under the Creative Commons Attribution License 3.0.
Code samples licensed under the Apache 2.0 License.
https://www.tensorflow.org/versions/r2.4/api_docs/python/tf/einsum