# Comparing two NumPy arrays for equality, element-wise

What is the simplest way to compare two NumPy arrays for equality (where equality is defined as: A = B iff for all indices i: `A[i] == B[i]`)?

Simply using `==` gives me a boolean array:

`````` >>> numpy.array([1,1,1]) == numpy.array([1,1,1])

array([ True,  True,  True], dtype=bool)
``````

Do I have to `and` the elements of this array to determine if the arrays are equal, or is there a simpler way to compare?

``````(A==B).all()
``````

test if all values of array (A==B) are True.

Note: maybe you also want to test A and B shape, such as `A.shape == B.shape`

Special cases and alternatives (from dbaupp's answer and yoavram's comment)

It should be noted that:

• this solution can have a strange behavior in a particular case: if either `A` or `B` is empty and the other one contains a single element, then it return `True`. For some reason, the comparison `A==B` returns an empty array, for which the `all` operator returns `True`.
• Another risk is if `A` and `B` don't have the same shape and aren't broadcastable, then this approach will raise an error.

In conclusion, if you have a doubt about `A` and `B` shape or simply want to be safe: use one of the specialized functions:

``````np.array_equal(A,B)  # test if same shape, same elements values
np.array_equiv(A,B)  # test if broadcastable shape, same elements values
np.allclose(A,B,...) # test if same shape, elements have close enough values
``````
• You almost always want `np.array_equal` IME. `(A==B).all()` will crash if A and B have different lengths. As of numpy 1.10, == raises a deprecation warning in this case. Jul 1, 2016 at 13:25
• You've got a good point, but in the case I have a doubt on the shape I usually prefer to directly test it, before the value. Then the error is clearly on the shapes which have a completely different meaning than having different values. But that probably depends on each use-case
– Juh_
Aug 6, 2018 at 9:20
• another risk is if the arrays contains nan. In that case you will get False because nan != nan Sep 12, 2018 at 22:45
• Good to point it out. However, I think this is logical because `nan!=nan` implies that `array(nan)!=array(nan)`.
– Juh_
Sep 13, 2018 at 9:29
• I do not understand this behavior: `import numpy as np` `H = 1/np.sqrt(2)*np.array([[1, 1], [1, -1]]) #hadamard matrix` `np.array_equal(H.dot(H.T.conj()), np.eye(len(H))) # checking if H is an unitary matrix or not` H is an unitary matrix, so H x `H.T.conj` is an identity matrix. But `np.array_equal` returns False
– Dex
Feb 25, 2019 at 11:39

The `(A==B).all()` solution is very neat, but there are some built-in functions for this task. Namely `array_equal`, `allclose` and `array_equiv`.

(Although, some quick testing with `timeit` seems to indicate that the `(A==B).all()` method is the fastest, which is a little peculiar, given it has to allocate a whole new array.)

• you're right, except that if one of the compared arrays is empty you'll get the wrong answer with `(A==B).all()`. For example, try: `(np.array()==np.array([])).all()`, it gives `True`, while `np.array_equal(np.array(), np.array([]))` gives `False` Jan 17, 2013 at 12:53
• I just discovered this performance difference too. It's strange because if you have 2 arrays that are completely different `(a==b).all()` is still faster than `np.array_equal(a, b)` (which could have just checked a single element and exited). Jan 16, 2015 at 13:51
• `np.array_equal` also works with `lists of arrays` and `dicts of arrays`. This might be a reason for a slower performance. Jun 22, 2016 at 13:03
• Thanks a lot for the function `allclose`, that is what I needed for numerical calculations. It compares the equality of vectors within a tolerance. :) Sep 25, 2018 at 8:51
• Note that `np.array_equiv([1,1,1], 1) is True`. This is because: Shape consistent means they are either the same shape, or one input array can be broadcasted to create the same shape as the other one. May 26, 2020 at 9:55

If you want to check if two arrays have the same `shape` AND `elements` you should use `np.array_equal` as it is the method recommended in the documentation.

Performance-wise don't expect that any equality check will beat another, as there is not much room to optimize `comparing two elements`. Just for the sake, i still did some tests.

``````import numpy as np
import timeit

A = np.zeros((300, 300, 3))
B = np.zeros((300, 300, 3))
C = np.ones((300, 300, 3))

timeit.timeit(stmt='(A==B).all()', setup='from __main__ import A, B', number=10**5)
timeit.timeit(stmt='np.array_equal(A, B)', setup='from __main__ import A, B, np', number=10**5)
timeit.timeit(stmt='np.array_equiv(A, B)', setup='from __main__ import A, B, np', number=10**5)
> 51.5094
> 52.555
> 52.761
``````

So pretty much equal, no need to talk about the speed.

The `(A==B).all()` behaves pretty much as the following code snippet:

``````x = [1,2,3]
y = [1,2,3]
print all([x[i]==y[i] for i in range(len(x))])
> True
``````

Let's measure the performance by using the following piece of code.

``````import numpy as np
import time

exec_time0 = []
exec_time1 = []
exec_time2 = []

sizeOfArray = 5000
numOfIterations = 200

for i in xrange(numOfIterations):

A = np.random.randint(0,255,(sizeOfArray,sizeOfArray))
B = np.random.randint(0,255,(sizeOfArray,sizeOfArray))

a = time.clock()
res = (A==B).all()
b = time.clock()
exec_time0.append( b - a )

a = time.clock()
res = np.array_equal(A,B)
b = time.clock()
exec_time1.append( b - a )

a = time.clock()
res = np.array_equiv(A,B)
b = time.clock()
exec_time2.append( b - a )

print 'Method: (A==B).all(),       ', np.mean(exec_time0)
print 'Method: np.array_equal(A,B),', np.mean(exec_time1)
print 'Method: np.array_equiv(A,B),', np.mean(exec_time2)
``````

Output

``````Method: (A==B).all(),        0.03031857
Method: np.array_equal(A,B), 0.030025185
Method: np.array_equiv(A,B), 0.030141515
``````

According to the results above, the numpy methods seem to be faster than the combination of the == operator and the all() method and by comparing the numpy methods the fastest one seems to be the numpy.array_equal method.

• You should use a larger array size that takes at least a second to compile to increase the experiment accuracy. Jan 6, 2018 at 17:10
• Does this also reproduce when order of comparison is changed? or reiniting A and B to random each time? This difference might also be explained from memory caching of A and B cells. Feb 6, 2020 at 13:26
• There's no meaningful difference between these timings. Feb 11, 2020 at 3:17

Usually two arrays will have some small numeric errors,

You can use `numpy.allclose(A,B)`, instead of `(A==B).all()`. This returns a bool True/False

Now use `np.array_equal`. From documentation:

``````np.array_equal([1, 2], [1, 2])
True
np.array_equal(np.array([1, 2]), np.array([1, 2]))
True
np.array_equal([1, 2], [1, 2, 3])
False
np.array_equal([1, 2], [1, 4])
False
``````

On top of the other answers, you can now use an assertion:

``````numpy.testing.assert_array_equal(x, y)
``````

You also have similar function such as `numpy.testing.assert_almost_equal()`

https://numpy.org/doc/stable/reference/generated/numpy.testing.assert_array_equal.html

Just for the sake of completeness. I will add the pandas approach for comparing two arrays:

``````import numpy as np
a = np.arange(0.0, 10.2, 0.12)
b = np.arange(0.0, 10.2, 0.12)
ap = pd.DataFrame(a)
bp = pd.DataFrame(b)

ap.equals(bp)
True
``````

FYI: In case you are looking of How to compare Vectors, Arrays or Dataframes in R. You just you can use:

``````identical(iris1, iris2)
# TRUE
all.equal(array1, array2)
#>  TRUE
``````