You can let numpy handle the iteration, i.e. vectorize it:

```
def local_maxima(xval, yval):
xval = np.asarray(xval)
yval = np.asarray(yval)
sort_idx = np.argsort(xval)
yval = yval[sort_idx]
gradient = np.diff(yval)
maxima = np.diff((gradient > 0).view(np.int8))
return np.concatenate((([0],) if gradient[0] < 0 else ()) +
(np.where(maxima == -1)[0] + 1,) +
(([len(yval)-1],) if gradient[-1] > 0 else ()))
```

**EDIT** So the code first computes the variation from every point to the nex(`gradient`

). The next step is a little tricky... If you do `np.diff((gradient > 0)`

the resulting boolean array is `True`

where there is a change from growing (`> 0`

) to not growing(`<= 0`

). By making it a signed int of the same size as the boolean array, you can discriminate from transitions from growing to not growing (`-1`

) to the opposite (`+1`

). By taking a `.view(np.int8)`

of a signed integer type of the same dtype size as the boolean array, we avoid copying the data, as would happen if we did the less hacky `.astype(int)`

. All that's left is taking care of the first and last points, and concatenating all points together into a single array. One thing I found out today is that if you include an empty list in the tuple you send to `np.concatenate`

, it comes out as an empty array of dtype `np.float`

, and that ends up being the dtype of the result, hence the more complicated concatenation of empty tuples in the above code.

It works:

```
In [2]: local_maxima(xval, yval)
Out[2]: array([ 1, 6, 10], dtype=int64)
```

And is reasonably fast:

```
In [3]: xval = np.random.rand(10000)
In [4]: yval = np.random.rand(10000)
In [5]: local_maxima(xval, yval)
Out[5]: array([ 0, 2, 4, ..., 9991, 9995, 9998], dtype=int64)
In [6]: %timeit local_maxima(xval, yval)
1000 loops, best of 3: 1.16 ms per loop
```

Also, most of the time is converting your data from lists to arrays and sorting them. If your data is already sorted and kept in arrays, you can probably improve performance over the above by a factor of 5x.