einsum(subscripts, *operands, out=None, dtype=None, order='K', casting='safe', optimize=False)
Using the Einstein summation convention, many common multi-dimensional, linear algebraic array operations can be represented in a simple fashion. In implicit mode einsum
computes these values.
In explicit mode, einsum
provides further flexibility to compute other array operations that might not be considered classical Einstein summation operations, by disabling, or forcing summation over specified subscript labels.
See the notes and examples for clarification.
The Einstein summation convention can be used to compute many multi-dimensional, linear algebraic array operations. einsum
provides a succinct way of representing these.
A non-exhaustive list of these operations, which can be computed by einsum
, is shown below along with examples:
Trace of an array, numpy.trace
.
Return a diagonal, numpy.diag
.
Array axis summations, numpy.sum
.
Transpositions and permutations, numpy.transpose
.
Matrix multiplication and dot product, numpy.matmul
numpy.dot
.
Vector inner and outer products, numpy.inner
numpy.outer
.
Broadcasting, element-wise and scalar multiplication, numpy.multiply
.
Tensor contractions, numpy.tensordot
.
Chained array operations, in efficient calculation order, numpy.einsum_path
.
The subscripts string is a comma-separated list of subscript labels, where each label refers to a dimension of the corresponding operand. Whenever a label is repeated it is summed, so np.einsum('i,i', a, b)
is equivalent to np.inner(a,b) <numpy.inner>
. If a label appears only once, it is not summed, so np.einsum('i', a)
produces a view of a
with no changes. A further example np.einsum('ij,jk', a, b)
describes traditional matrix multiplication and is equivalent to np.matmul(a,b) <numpy.matmul>
. Repeated subscript labels in one operand take the diagonal. For example, np.einsum('ii', a)
is equivalent to np.trace(a) <numpy.trace>
.
In implicit mode, the chosen subscripts are important since the axes of the output are reordered alphabetically. This means that np.einsum('ij', a)
doesn't affect a 2D array, while np.einsum('ji', a)
takes its transpose. Additionally, np.einsum('ij,jk', a, b)
returns a matrix multiplication, while, np.einsum('ij,jh', a, b)
returns the transpose of the multiplication since subscript 'h' precedes subscript 'i'.
In explicit mode the output can be directly controlled by specifying output subscript labels. This requires the identifier '->' as well as the list of output subscript labels. This feature increases the flexibility of the function since summing can be disabled or forced when required. The call np.einsum('i->', a)
is like np.sum(a, axis=-1) <numpy.sum>
, and np.einsum('ii->i', a)
is like np.diag(a) <numpy.diag>
. The difference is that einsum
does not allow broadcasting by default. Additionally np.einsum('ij,jh->ih', a, b)
directly specifies the order of the output subscript labels and therefore returns matrix multiplication, unlike the example above in implicit mode.
To enable and control broadcasting, use an ellipsis. Default NumPy-style broadcasting is done by adding an ellipsis to the left of each term, like np.einsum('...ii->...i', a)
. To take the trace along the first and last axes, you can do np.einsum('i...i', a)
, or to do a matrix-matrix product with the left-most indices instead of rightmost, one can do np.einsum('ij...,jk...->ik...', a, b)
.
When there is only one operand, no axes are summed, and no output parameter is provided, a view into the operand is returned instead of a new array. Thus, taking the diagonal as np.einsum('ii->i', a)
produces a view (changed in version 1.10.0).
einsum
also provides an alternative way to provide the subscripts and operands as einsum(op0, sublist0, op1, sublist1, ..., [sublistout])
. If the output shape is not provided in this format einsum
will be calculated in implicit mode, otherwise it will be performed explicitly. The examples below have corresponding einsum
calls with the two parameter methods.
Views returned from einsum are now writeable whenever the input array is writeable. For example, np.einsum('ijk...->kji...', a)
will now have the same effect as np.swapaxes(a, 0, 2) <numpy.swapaxes>
and np.einsum('ii->i', a)
will return a writeable view of the diagonal of a 2D array.
Added the optimize
argument which will optimize the contraction order of an einsum expression. For a contraction with three or more operands this can greatly increase the computational efficiency at the cost of a larger memory footprint during computation.
Typically a 'greedy' algorithm is applied which empirical tests have shown returns the optimal path in the majority of cases. In some cases 'optimal' will return the superlative path through a more expensive, exhaustive search. For iterative calculations it may be advisable to calculate the optimal path once and reuse that path by supplying it as an argument. An example is given below.
See numpy.einsum_path
for more details.
Specifies the subscripts for summation as comma separated list of subscript labels. An implicit (classical Einstein summation) calculation is performed unless the explicit indicator '->' is included as well as subscript labels of the precise output form.
These are the arrays for the operation.
If provided, the calculation is done into this array.
If provided, forces the calculation to use the data type specified. Note that you may have to also give a more liberal :None:None:`casting`
parameter to allow the conversions. Default is None.
Controls the memory layout of the output. 'C' means it should be C contiguous. 'F' means it should be Fortran contiguous, 'A' means it should be 'F' if the inputs are all 'F', 'C' otherwise. 'K' means it should be as close to the layout as the inputs as is possible, including arbitrarily permuted axes. Default is 'K'.
Controls what kind of data casting may occur. Setting this to 'unsafe' is not recommended, as it can adversely affect accumulations.
'no' means the data types should not be cast at all.
'equiv' means only byte-order changes are allowed.
'safe' means only casts which can preserve values are allowed.
'same_kind' means only safe casts or casts within a kind, like float64 to float32, are allowed.
'unsafe' means any data conversions may be done.
Default is 'safe'.
Controls if intermediate optimization should occur. No optimization will occur if False and True will default to the 'greedy' algorithm. Also accepts an explicit contraction list from the np.einsum_path
function. See np.einsum_path
for more details. Defaults to False.
The calculation based on the Einstein summation convention.
Evaluates the Einstein summation convention on the operands.
einops
similar verbose interface is provided by :None:None:`einops <https://github.com/arogozhnikov/einops>`
package to cover additional operations: transpose, reshape/flatten, repeat/tile, squeeze/unsqueeze and reductions.
opt_einsum
:None:None:`opt_einsum <https://optimized-einsum.readthedocs.io/en/stable/>`
optimizes contraction order for einsum-like expressions in backend-agnostic manner.
>>> a = np.arange(25).reshape(5,5)
... b = np.arange(5)
... c = np.arange(6).reshape(2,3)
Trace of a matrix:
>>> np.einsum('ii', a) 60
>>> np.einsum(a, [0,0]) 60
>>> np.trace(a) 60
Extract the diagonal (requires explicit form):
>>> np.einsum('ii->i', a) array([ 0, 6, 12, 18, 24])
>>> np.einsum(a, [0,0], [0]) array([ 0, 6, 12, 18, 24])
>>> np.diag(a) array([ 0, 6, 12, 18, 24])
Sum over an axis (requires explicit form):
>>> np.einsum('ij->i', a) array([ 10, 35, 60, 85, 110])
>>> np.einsum(a, [0,1], [0]) array([ 10, 35, 60, 85, 110])
>>> np.sum(a, axis=1) array([ 10, 35, 60, 85, 110])
For higher dimensional arrays summing a single axis can be done with ellipsis:
>>> np.einsum('...j->...', a) array([ 10, 35, 60, 85, 110])
>>> np.einsum(a, [Ellipsis,1], [Ellipsis]) array([ 10, 35, 60, 85, 110])
Compute a matrix transpose, or reorder any number of axes:
>>> np.einsum('ji', c) array([[0, 3], [1, 4], [2, 5]])
>>> np.einsum('ij->ji', c) array([[0, 3], [1, 4], [2, 5]])
>>> np.einsum(c, [1,0]) array([[0, 3], [1, 4], [2, 5]])
>>> np.transpose(c) array([[0, 3], [1, 4], [2, 5]])
Vector inner products:
>>> np.einsum('i,i', b, b) 30
>>> np.einsum(b, [0], b, [0]) 30
>>> np.inner(b,b) 30
Matrix vector multiplication:
>>> np.einsum('ij,j', a, b) array([ 30, 80, 130, 180, 230])
>>> np.einsum(a, [0,1], b, [1]) array([ 30, 80, 130, 180, 230])
>>> np.dot(a, b) array([ 30, 80, 130, 180, 230])
>>> np.einsum('...j,j', a, b) array([ 30, 80, 130, 180, 230])
Broadcasting and scalar multiplication:
>>> np.einsum('..., ...', 3, c) array([[ 0, 3, 6], [ 9, 12, 15]])
>>> np.einsum(',ij', 3, c) array([[ 0, 3, 6], [ 9, 12, 15]])
>>> np.einsum(3, [Ellipsis], c, [Ellipsis]) array([[ 0, 3, 6], [ 9, 12, 15]])
>>> np.multiply(3, c) array([[ 0, 3, 6], [ 9, 12, 15]])
Vector outer product:
>>> np.einsum('i,j', np.arange(2)+1, b) array([[0, 1, 2, 3, 4], [0, 2, 4, 6, 8]])
>>> np.einsum(np.arange(2)+1, [0], b, [1]) array([[0, 1, 2, 3, 4], [0, 2, 4, 6, 8]])
>>> np.outer(np.arange(2)+1, b) array([[0, 1, 2, 3, 4], [0, 2, 4, 6, 8]])
Tensor contraction:
>>> a = np.arange(60.).reshape(3,4,5)
... b = np.arange(24.).reshape(4,3,2)
... np.einsum('ijk,jil->kl', a, b) array([[4400., 4730.], [4532., 4874.], [4664., 5018.], [4796., 5162.], [4928., 5306.]])
>>> np.einsum(a, [0,1,2], b, [1,0,3], [2,3]) array([[4400., 4730.], [4532., 4874.], [4664., 5018.], [4796., 5162.], [4928., 5306.]])
>>> np.tensordot(a,b, axes=([1,0],[0,1])) array([[4400., 4730.], [4532., 4874.], [4664., 5018.], [4796., 5162.], [4928., 5306.]])
Writeable returned arrays (since version 1.10.0):
>>> a = np.zeros((3, 3))
... np.einsum('ii->i', a)[:] = 1
... a array([[1., 0., 0.], [0., 1., 0.], [0., 0., 1.]])
Example of ellipsis use:
>>> a = np.arange(6).reshape((3,2))
... b = np.arange(12).reshape((4,3))
... np.einsum('ki,jk->ij', a, b) array([[10, 28, 46, 64], [13, 40, 67, 94]])
>>> np.einsum('ki,...k->i...', a, b) array([[10, 28, 46, 64], [13, 40, 67, 94]])
>>> np.einsum('k...,jk', a, b) array([[10, 28, 46, 64], [13, 40, 67, 94]])
Chained array operations. For more complicated contractions, speed ups might be achieved by repeatedly computing a 'greedy' path or pre-computing the 'optimal' path and repeatedly applying it, using an einsum_path
insertion (since version 1.12.0). Performance improvements can be particularly significant with larger arrays:
>>> a = np.ones(64).reshape(2,4,8)
Basic einsum
: ~1520ms (benchmarked on 3.1GHz Intel i5.)
>>> for iteration in range(500):
... _ = np.einsum('ijk,ilm,njm,nlk,abc->',a,a,a,a,a)
Sub-optimal einsum
(due to repeated path calculation time): ~330ms
>>> for iteration in range(500):
... _ = np.einsum('ijk,ilm,njm,nlk,abc->',a,a,a,a,a, optimize='optimal')
Greedy einsum
(faster optimal path approximation): ~160ms
>>> for iteration in range(500):
... _ = np.einsum('ijk,ilm,njm,nlk,abc->',a,a,a,a,a, optimize='greedy')
Optimal einsum
(best usage pattern in some use cases): ~110ms
>>> path = np.einsum_path('ijk,ilm,njm,nlk,abc->',a,a,a,a,a, optimize='optimal')[0]See :
... for iteration in range(500):
... _ = np.einsum('ijk,ilm,njm,nlk,abc->',a,a,a,a,a, optimize=path)
The following pages refer to to this document either explicitly or contain code examples using this.
numpy.outer
dask.array.einsumfuncs.einsum
numpy.core._multiarray_umath.dot
numpy.einsum_path
numpy.linalg.tensorsolve
numpy.dot
numpy.inner
numpy.ma.core.outer
papyri
numpy.core._multiarray_umath.c_einsum
numpy.ma.core.inner
numpy.core._multiarray_umath.inner
numpy.einsum
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