# Understanding NumPy's einsum

I'm struggling to understand exactly how `einsum` works. I've looked at the documentation and a few examples, but it's not seeming to stick.

Here's an example we went over in class:

``````C = np.einsum("ij,jk->ki", A, B)
``````

for two arrays`A` and `B`

I think this would take `A^T * B`, but I'm not sure (it's taking the transpose of one of them right?). Can anyone walk me through exactly what's happening here (and in general when using `einsum`)?

• Actually it will be `(A * B)^T`, or equivalently `B^T * A^T`. – Tigran Saluev Apr 3 '15 at 10:42
• I wrote a short blog post about the basics of `einsum` here. (I'm happy to transplant the most relevant bits to an answer on Stack Overflow if useful). – Alex Riley Jun 8 '15 at 19:32
• @ajcr - Beautiful link. Thanks. The `numpy` documentation is woefully inadequate when explaining the details. – rayryeng - Reinstate Monica Jun 14 '15 at 1:14
• Thank you for the vote of confidence! Belatedly, I've contributed an answer below. – Alex Riley Nov 10 '15 at 23:11
• Note that in Python the `*` is not matrix multiplication but elementwise multiplication. Watch out! – ComputerScientist Dec 28 '16 at 17:34

(Note: this answer is based on a short blog post about `einsum` I wrote a while ago.)

## What does `einsum` do?

Imagine that we have two multi-dimensional arrays, `A` and `B`. Now let's suppose we want to...

• multiply `A` with `B` in a particular way to create new array of products; and then maybe
• sum this new array along particular axes; and then maybe
• transpose the axes of the new array in a particular order.

There's a good chance that `einsum` will help us do this faster and more memory-efficiently that combinations of the NumPy functions like `multiply`, `sum` and `transpose` will allow.

## How does `einsum` work?

Here's a simple (but not completely trivial) example. Take the following two arrays:

``````A = np.array([0, 1, 2])

B = np.array([[ 0,  1,  2,  3],
[ 4,  5,  6,  7],
[ 8,  9, 10, 11]])
``````

We will multiply `A` and `B` element-wise and then sum along the rows of the new array. In "normal" NumPy we'd write:

``````>>> (A[:, np.newaxis] * B).sum(axis=1)
array([ 0, 22, 76])
``````

So here, the indexing operation on `A` lines up the first axes of the two arrays so that the multiplication can be broadcast. The rows of the array of products is then summed to return the answer.

Now if we wanted to use `einsum` instead, we could write:

``````>>> np.einsum('i,ij->i', A, B)
array([ 0, 22, 76])
``````

The signature string `'i,ij->i'` is the key here and needs a little bit of explaining. You can think of it in two halves. On the left-hand side (left of the `->`) we've labelled the two input arrays. To the right of `->`, we've labelled the array we want to end up with.

Here is what happens next:

• `A` has one axis; we've labelled it `i`. And `B` has two axes; we've labelled axis 0 as `i` and axis 1 as `j`.

• By repeating the label `i` in both input arrays, we are telling `einsum` that these two axes should be multiplied together. In other words, we're multiplying array `A` with each column of array `B`, just like `A[:, np.newaxis] * B` does.

• Notice that `j` does not appear as a label in our desired output; we've just used `i` (we want to end up with a 1D array). By omitting the label, we're telling `einsum` to sum along this axis. In other words, we're summing the rows of the products, just like `.sum(axis=1)` does.

That's basically all you need to know to use `einsum`. It helps to play about a little; if we leave both labels in the output, `'i,ij->ij'`, we get back a 2D array of products (same as `A[:, np.newaxis] * B`). If we say no output labels, `'i,ij->`, we get back a single number (same as doing `(A[:, np.newaxis] * B).sum()`).

The great thing about `einsum` however, is that is does not build a temporary array of products first; it just sums the products as it goes. This can lead to big savings in memory use.

## A slightly bigger example

To explain the dot product, here are two new arrays:

``````A = array([[1, 1, 1],
[2, 2, 2],
[5, 5, 5]])

B = array([[0, 1, 0],
[1, 1, 0],
[1, 1, 1]])
``````

We will compute the dot product using `np.einsum('ij,jk->ik', A, B)`. Here's a picture showing the labelling of the `A` and `B` and the output array that we get from the function:

You can see that label `j` is repeated - this means we're multiplying the rows of `A` with the columns of `B`. Furthermore, the label `j` is not included in the output - we're summing these products. Labels `i` and `k` are kept for the output, so we get back a 2D array.

It might be even clearer to compare this result with the array where the label `j` is not summed. Below, on the left you can see the 3D array that results from writing `np.einsum('ij,jk->ijk', A, B)` (i.e. we've kept label `j`):

Summing axis `j` gives the expected dot product, shown on the right.

## Some exercises

To get more of feel for `einsum`, it can be useful to implement familiar NumPy array operations using the subscript notation. Anything that involves combinations of multiplying and summing axes can be written using `einsum`.

Let A and B be two 1D arrays with the same length. For example, `A = np.arange(10)` and `B = np.arange(5, 15)`.

• The sum of `A` can be written:

``````np.einsum('i->', A)
``````
• Element-wise multiplication, `A * B`, can be written:

``````np.einsum('i,i->i', A, B)
``````
• The inner product or dot product, `np.inner(A, B)` or `np.dot(A, B)`, can be written:

``````np.einsum('i,i->', A, B) # or just use 'i,i'
``````
• The outer product, `np.outer(A, B)`, can be written:

``````np.einsum('i,j->ij', A, B)
``````

For 2D arrays, `C` and `D`, provided that the axes are compatible lengths (both the same length or one of them of has length 1), here are a few examples:

• The trace of `C` (sum of main diagonal), `np.trace(C)`, can be written:

``````np.einsum('ii', C)
``````
• Element-wise multiplication of `C` and the transpose of `D`, `C * D.T`, can be written:

``````np.einsum('ij,ji->ij', C, D)
``````
• Multiplying each element of `C` by the array `D` (to make a 4D array), `C[:, :, None, None] * D`, can be written:

``````np.einsum('ij,kl->ijkl', C, D)
``````
• Very nice explanation, thanks. "Notice that i does not appear as a label in our desired output"-- doesn't it? – Ian Hincks Sep 7 '16 at 20:14
• Thanks @IanHincks! That looks like a typo; I've corrected it now. – Alex Riley Sep 18 '16 at 13:40
• Very good answer. It's also worth noting that `ij,jk` could work by itself (without the arrows) to form the matrix multiplication. But it seems like for clarity it's best to put the arrows and then the output dimensions. It's in the blog post. – ComputerScientist Dec 28 '16 at 17:35
• `In other words, we're multiplying array A with each column of array B`. Did you mean each "row" of B instead? – Peaceful Jan 15 '17 at 7:33
• @Peaceful: this is one of those occasions where it's difficult to choose the right word! I feel "column" fits a bit better here since `A` is of length 3, the same as the length of the columns in `B` (whereas rows of `B` have length 4 and cannot be multiplied element-wise by `A`). – Alex Riley Jan 15 '17 at 10:47

Grasping the idea of `numpy.einsum()` is very easy if you understand it intuitively. As an example, let's start with a simple description involving matrix multiplication.

To use `numpy.einsum()`, all you have to do is to pass the so-called subscripts string as an argument, followed by your input arrays.

Let's say you have two 2D arrays, `A` and `B`, and you want to do matrix multiplication. So, you do:

``````np.einsum("ij, jk -> ik", A, B)
``````

Here the subscript string `ij` corresponds to array `A` while the subscript string `jk` corresponds to array `B`. Also, the most important thing to note here is that the number of characters in each subscript string must match the dimensions of the array. (i.e. two chars for 2D arrays, three chars for 3D arrays, and so on.) And if you repeat the chars between subscript strings (`j` in our case), then that means you want the `ein`sum to happen along those dimensions. Thus, they will be sum-reduced. (i.e. that dimension will be gone)

The subscript string after this `->`, will be our resultant array. If you leave it empty, then everything will be summed and a scalar value is returned as result. Else the resultant array will have dimensions according to the subscript string. In our example, it'll be `ik`. This is intuitive because we know that for matrix multiplication the number of columns in array `A` has to match the number of rows in array `B` which is what is happening here (i.e. we encode this knowledge by repeating the char `j` in the subscript string)

Here are some more examples illustrating the use/power of `np.einsum()` in implementing some common tensor or nd-array operations, succinctly.

Inputs

``````# a vector
In [197]: vec
Out[197]: array([0, 1, 2, 3])

# an array
In [198]: A
Out[198]:
array([[11, 12, 13, 14],
[21, 22, 23, 24],
[31, 32, 33, 34],
[41, 42, 43, 44]])

# another array
In [199]: B
Out[199]:
array([[1, 1, 1, 1],
[2, 2, 2, 2],
[3, 3, 3, 3],
[4, 4, 4, 4]])
``````

1) Matrix multiplication (similar to `np.matmul(arr1, arr2)`)

``````In [200]: np.einsum("ij, jk -> ik", A, B)
Out[200]:
array([[130, 130, 130, 130],
[230, 230, 230, 230],
[330, 330, 330, 330],
[430, 430, 430, 430]])
``````

2) Extract elements along the main-diagonal (similar to `np.diag(arr)`)

``````In [202]: np.einsum("ii -> i", A)
Out[202]: array([11, 22, 33, 44])
``````

3) Hadamard product (i.e. element-wise product of two arrays) (similar to `arr1 * arr2`)

``````In [203]: np.einsum("ij, ij -> ij", A, B)
Out[203]:
array([[ 11,  12,  13,  14],
[ 42,  44,  46,  48],
[ 93,  96,  99, 102],
[164, 168, 172, 176]])
``````

4) Element-wise squaring (similar to `np.square(arr)` or `arr ** 2`)

``````In [210]: np.einsum("ij, ij -> ij", B, B)
Out[210]:
array([[ 1,  1,  1,  1],
[ 4,  4,  4,  4],
[ 9,  9,  9,  9],
[16, 16, 16, 16]])
``````

5) Trace (i.e. sum of main-diagonal elements) (similar to `np.trace(arr)`)

``````In [217]: np.einsum("ii -> ", A)
Out[217]: 110
``````

6) Matrix transpose (similar to `np.transpose(arr)`)

``````In [221]: np.einsum("ij -> ji", A)
Out[221]:
array([[11, 21, 31, 41],
[12, 22, 32, 42],
[13, 23, 33, 43],
[14, 24, 34, 44]])
``````

7) Outer Product (of vectors) (similar to `np.outer(vec1, vec2)`)

``````In [255]: np.einsum("i, j -> ij", vec, vec)
Out[255]:
array([[0, 0, 0, 0],
[0, 1, 2, 3],
[0, 2, 4, 6],
[0, 3, 6, 9]])
``````

8) Inner Product (of vectors) (similar to `np.inner(vec1, vec2)`)

``````In [256]: np.einsum("i, i -> ", vec, vec)
Out[256]: 14
``````

9) Sum along axis 0 (similar to `np.sum(arr, axis=0)`)

``````In [260]: np.einsum("ij -> j", B)
Out[260]: array([10, 10, 10, 10])
``````

10) Sum along axis 1 (similar to `np.sum(arr, axis=1)`)

``````In [261]: np.einsum("ij -> i", B)
Out[261]: array([ 4,  8, 12, 16])
``````

11) Batch Matrix Multiplication

``````In [287]: BM = np.stack((A, B), axis=0)

In [288]: BM
Out[288]:
array([[[11, 12, 13, 14],
[21, 22, 23, 24],
[31, 32, 33, 34],
[41, 42, 43, 44]],

[[ 1,  1,  1,  1],
[ 2,  2,  2,  2],
[ 3,  3,  3,  3],
[ 4,  4,  4,  4]]])

In [289]: BM.shape
Out[289]: (2, 4, 4)

# batch matrix multiply using einsum
In [292]: BMM = np.einsum("bij, bjk -> bik", BM, BM)

In [293]: BMM
Out[293]:
array([[[1350, 1400, 1450, 1500],
[2390, 2480, 2570, 2660],
[3430, 3560, 3690, 3820],
[4470, 4640, 4810, 4980]],

[[  10,   10,   10,   10],
[  20,   20,   20,   20],
[  30,   30,   30,   30],
[  40,   40,   40,   40]]])

In [294]: BMM.shape
Out[294]: (2, 4, 4)
``````

12) Sum along axis 2 (similar to `np.sum(arr, axis=2)`)

``````In [330]: np.einsum("ijk -> ij", BM)
Out[330]:
array([[ 50,  90, 130, 170],
[  4,   8,  12,  16]])
``````

13) Sum all the elements in array (similar to `np.sum(arr)`)

``````In [335]: np.einsum("ijk -> ", BM)
Out[335]: 480
``````

14) Sum over multiple axes (i.e. marginalization)
(similar to `np.sum(arr, axis=(axis0, axis1, axis2, axis3, axis4, axis6, axis7))`)

``````# 8D array
In [354]: R = np.random.standard_normal((3,5,4,6,8,2,7,9))

# marginalize out axis 5 (i.e. "n" here)
In [363]: esum = np.einsum("ijklmnop -> n", R)

# marginalize out axis 5 (i.e. sum over rest of the axes)
In [364]: nsum = np.sum(R, axis=(0,1,2,3,4,6,7))

In [365]: np.allclose(esum, nsum)
Out[365]: True
``````

15) Double Dot Products (similar to np.sum(hadamard-product) cf. 3)

``````In [772]: A
Out[772]:
array([[1, 2, 3],
[4, 2, 2],
[2, 3, 4]])

In [773]: B
Out[773]:
array([[1, 4, 7],
[2, 5, 8],
[3, 6, 9]])

In [774]: np.einsum("ij, ij -> ", A, B)
Out[774]: 124
``````

16) 2D and 3D array multiplication

Such a multiplication could be very useful when solving linear system of equations (Ax = b) where you want to verify the result.

``````# inputs
In [115]: A = np.random.rand(3,3)
In [116]: b = np.random.rand(3, 4, 5)

# solve for x
In [117]: x = np.linalg.solve(A, b.reshape(b.shape[0], -1)).reshape(b.shape)

# 2D and 3D array multiplication :)
In [118]: Ax = np.einsum('ij, jkl', A, x)

# indeed the same!
In [119]: np.allclose(Ax, b)
Out[119]: True
``````

On the contrary, if one has to use `np.matmul()` for this verification, we have to do couple of `reshape` operations to achieve the same result like:

``````# reshape 3D array `x` to 2D, perform matmul
# then reshape the resultant array to 3D
In [123]: Ax_matmul = np.matmul(A, x.reshape(x.shape[0], -1)).reshape(x.shape)

# indeed correct!
In [124]: np.allclose(Ax, Ax_matmul)
Out[124]: True
``````

Bonus: Read more math here : Einstein-Summation and definitely here: Tensor-Notation

Lets make 2 arrays, with different, but compatible dimensions to highlight their interplay

``````In [43]: A=np.arange(6).reshape(2,3)
Out[43]:
array([[0, 1, 2],
[3, 4, 5]])

In [44]: B=np.arange(12).reshape(3,4)
Out[44]:
array([[ 0,  1,  2,  3],
[ 4,  5,  6,  7],
[ 8,  9, 10, 11]])
``````

Your calculation, takes a 'dot' (sum of products) of a (2,3) with a (3,4) to produce a (4,2) array. `i` is the 1st dim of `A`, the last of `C`; `k` the last of `B`, 1st of `C`. `j` is 'consumed' by the summation.

``````In [45]: C=np.einsum('ij,jk->ki',A,B)
Out[45]:
array([[20, 56],
[23, 68],
[26, 80],
[29, 92]])
``````

This is the same as `np.dot(A,B).T` - it's the final output that's transposed.

To see more of what happens to `j`, change the `C` subscripts to `ijk`:

``````In [46]: np.einsum('ij,jk->ijk',A,B)
Out[46]:
array([[[ 0,  0,  0,  0],
[ 4,  5,  6,  7],
[16, 18, 20, 22]],

[[ 0,  3,  6,  9],
[16, 20, 24, 28],
[40, 45, 50, 55]]])
``````

This can also be produced with:

``````A[:,:,None]*B[None,:,:]
``````

That is, add a `k` dimension to the end of `A`, and an `i` to the front of `B`, resulting in a (2,3,4) array.

`0 + 4 + 16 = 20`, `9 + 28 + 55 = 92`, etc; Sum on `j` and transpose to get the earlier result:

``````np.sum(A[:,:,None] * B[None,:,:], axis=1).T

# C[k,i] = sum(j) A[i,j (,k) ] * B[(i,)  j,k]
``````

I found NumPy: The tricks of the trade (Part II) instructive

We use -> to indicate the order of the output array. So think of 'ij, i->j' as having left hand side (LHS) and right hand side (RHS). Any repetition of labels on the LHS computes the product element wise and then sums over. By changing the label on the RHS (output) side, we can define the axis in which we want to proceed with respect to the input array, i.e. summation along axis 0, 1 and so on.

``````import numpy as np

>>> a
array([[1, 1, 1],
[2, 2, 2],
[3, 3, 3]])
>>> b
array([[0, 1, 2],
[3, 4, 5],
[6, 7, 8]])
>>> d = np.einsum('ij, jk->ki', a, b)
``````

Notice there are three axes, i, j, k, and that j is repeated (on the left-hand-side). `i,j` represent rows and columns for `a`. `j,k` for `b`.

In order to calculate the product and align the `j` axis we need to add an axis to `a`. (`b` will be broadcast along(?) the first axis)

``````a[i, j, k]
b[j, k]

>>> c = a[:,:,np.newaxis] * b
>>> c
array([[[ 0,  1,  2],
[ 3,  4,  5],
[ 6,  7,  8]],

[[ 0,  2,  4],
[ 6,  8, 10],
[12, 14, 16]],

[[ 0,  3,  6],
[ 9, 12, 15],
[18, 21, 24]]])
``````

`j` is absent from the right-hand-side so we sum over `j` which is the second axis of the 3x3x3 array

``````>>> c = c.sum(1)
>>> c
array([[ 9, 12, 15],
[18, 24, 30],
[27, 36, 45]])
``````

Finally, the indices are (alphabetically) reversed on the right-hand-side so we transpose.

``````>>> c.T
array([[ 9, 18, 27],
[12, 24, 36],
[15, 30, 45]])

>>> np.einsum('ij, jk->ki', a, b)
array([[ 9, 18, 27],
[12, 24, 36],
[15, 30, 45]])
>>>
``````
• NumPy: The tricks of the trade (Part II) seems to require an invite from the site owner as well as a Wordpress account – Tejas Shetty Nov 24 '19 at 6:47
• ... updated link, luckily I found it with a search. - Thnx. – wwii Nov 24 '19 at 7:03
• @TejasShetty A lot of better answers here now - maybe I should delete this one. – wwii Nov 24 '19 at 7:10

When reading einsum equations, I've found it the most helpful to just be able to mentally boil them down to their imperative versions.

``````C = np.einsum('bhwi,bhwj->bij', A, B)
``````

Working through the punctuation first we see that we have two 4-letter comma-separated blobs - `bhwi` and `bhwj`, before the arrow, and a single 3-letter blob `bij` after it. Therefore, the equation produces a rank-3 tensor result from two rank-4 tensor inputs.

Now, let each letter in each blob be the name of a range variable. The position at which the letter appears in the blob is the index of the axis that it ranges over in that tensor. The imperative summation that produces each element of C, therefore, has to start with three nested for loops, one for each index of C.

``````for b in range(...):
for i in range(...):
for j in range(...):
# the variables b, i and j index C in the order of their appearance in the equation
C[b, i, j] = ...
``````

So, essentially, you have a `for` loop for every output index of C. We'll leave the ranges undetermined for now.

Next we look at the left-hand side - are there any range variables there that don't appear on the right-hand side? In our case - yes, `h` and `w`. Add an inner nested `for` loop for every such variable:

``````for b in range(...):
for i in range(...):
for j in range(...):
C[b, i, j] = 0
for h in range(...):
for w in range(...):
...
``````

Inside the innermost loop we now have all indices defined, so we can write the actual summation and the translation is complete:

``````# three nested for-loops that index the elements of C
for b in range(...):
for i in range(...):
for j in range(...):

# prepare to sum
C[b, i, j] = 0

# two nested for-loops for the two indexes that don't appear on the right-hand side
for h in range(...):
for w in range(...):
# Sum! Compare the statement below with the original einsum formula
# 'bhwi,bhwj->bij'

C[b, i, j] += A[b, h, w, i] * B[b, h, w, j]
``````

If you've been able to follow the code thus far, then congratulations! This is all you need to be able to read einsum equations. Notice in particular how the original einsum formula maps to the final summation statement in the snippet above. The for-loops and range bounds are just fluff and that final statement is all you really need to understand what's going on.

For the sake of completeness, let's see how to determine the ranges for each range variable. Well, the range of each variable is simply the length of the dimension(s) which it indexes. Obviously, if a variable indexes more than one dimension in one or more tensors, then the lengths of each of those dimensions have to be equal. Here's the code above with the complete ranges:

``````# C's shape is determined by the shapes of the inputs
# b indexes both A and B, so its range can come from either A.shape or B.shape
# i indexes only A, so its range can only come from A.shape, the same is true for j and B
assert A.shape[0] == B.shape[0]
assert A.shape[1] == B.shape[1]
assert A.shape[2] == B.shape[2]
C = np.zeros((A.shape[0], A.shape[3], B.shape[3]))
for b in range(A.shape[0]): # b indexes both A and B, or B.shape[0], which must be the same
for i in range(A.shape[3]):
for j in range(B.shape[3]):
# h and w can come from either A or B
for h in range(A.shape[1]):
for w in range(A.shape[2]):
C[b, i, j] += A[b, h, w, i] * B[b, h, w, j]
``````