One solution without using `np.rot90`

to rotate in clockwise direction would be to swap the last two axes and then flip the last one -

```
img.swapaxes(-2,-1)[...,::-1]
```

For counter-clockwise rotation, flip the second last axis -

```
img.swapaxes(-2,-1)[...,::-1,:]
```

With `np.rot90`

, the counter-clockwise rotation would be -

```
np.rot90(img,axes=(-2,-1))
```

Sample run -

```
In [39]: img = np.random.randint(0,255,(7,4,3,5))
In [40]: out_CW = img.swapaxes(-2,-1)[...,::-1] # Clockwise
In [41]: out_CCW = img.swapaxes(-2,-1)[...,::-1,:] # Counter-Clockwise
In [42]: img[0,0,:,:]
Out[42]:
array([[142, 181, 141, 81, 42],
[ 1, 126, 145, 242, 118],
[112, 115, 128, 0, 151]])
In [43]: out_CW[0,0,:,:]
Out[43]:
array([[112, 1, 142],
[115, 126, 181],
[128, 145, 141],
[ 0, 242, 81],
[151, 118, 42]])
In [44]: out_CCW[0,0,:,:]
Out[44]:
array([[ 42, 118, 151],
[ 81, 242, 0],
[141, 145, 128],
[181, 126, 115],
[142, 1, 112]])
```

**Runtime test**

```
In [41]: img = np.random.randint(0,255,(800,600))
# @Manel Fornos's Scipy based rotate func
In [42]: %timeit rotate(img, 90)
10 loops, best of 3: 60.8 ms per loop
In [43]: %timeit np.rot90(img,axes=(-2,-1))
100000 loops, best of 3: 4.19 µs per loop
In [44]: %timeit img.swapaxes(-2,-1)[...,::-1,:]
1000000 loops, best of 3: 480 ns per loop
```

Thus, for rotating by `90`

degrees or multiples of it, `numpy.dot`

or `swapping axes`

based ones seem pretty good in terms of performance and also more importantly do not perform any interpolation that would change the values otherwise as done by Scipy's rotate based function.