### Approach #1 : Using `numexpr`

When working with large data, we can use `numexpr`

module that supports multi-core processing if the intended operations could be expressed as arithmetic ones. Here, one way would be -

```
(X>=0)+0
```

Thus, to solve our case, it would be -

```
import numexpr as ne
ne.evaluate('(X>=0)+0')
```

### Approach #2 : Using NumPy `views`

Another trick would be to use `views`

by viewing the mask of comparisons as an `int`

array, like so -

```
(X>=0).view('i1')
```

On performance, it should be identical to creating `X>=0`

.

**Timings**

Comparing all posted solutions on a random array -

```
In [14]: np.random.seed(0)
...: X = np.random.randn(3072,10000)
In [15]: # OP's soln-1
...: def relu_derivative_v1(x):
...: return (x>0)*np.ones(x.shape)
...:
...: # OP's soln-2
...: def relu_derivative_v2(x):
...: x[x>=0]=1
...: x[x<0]=0
...: return x
In [16]: %timeit ne.evaluate('(X>=0)+0')
10 loops, best of 3: 27.8 ms per loop
In [17]: %timeit (X>=0).view('i1')
100 loops, best of 3: 19.3 ms per loop
In [18]: %timeit relu_derivative_v1(X)
1 loop, best of 3: 269 ms per loop
In [19]: %timeit relu_derivative_v2(X)
1 loop, best of 3: 89.5 ms per loop
```

The `numexpr`

based one was with `8`

threads. Thus, with more number of threads available for compute, it should improve further. `Related post`

on how to control multi-core functionality.

### Approach #3 : Approach #1 + #2 -

Mix both of those for the most optimal one for large arrays -

```
In [27]: np.random.seed(0)
...: X = np.random.randn(3072,10000)
In [28]: %timeit ne.evaluate('X>=0').view('i1')
100 loops, best of 3: 14.7 ms per loop
```