The method you propose does have a python loop, so for large values of `ni`

it is going to get slow. That said, unless you are going to have large `ni`

you shouldn't worry much.

I have created sample input data with the following code:

```
def sample_data(n_i, n_j, z_shape) :
x = np.random.rand(n_i, n_j) * 1000
x.sort()
x[:,0] = 0
x[:, -1] = 1000
y = np.random.rand(n_i, n_j)
z = np.random.rand(*z_shape) * 1000
return x, y, z
```

And have tested them with this two versions of linear interpolation:

```
def interp_1(x, y, z) :
rows, cols = x.shape
out = np.empty((rows,) + z.shape, dtype=y.dtype)
for j in xrange(rows) :
out[j] =interp1d(x[j], y[j], kind='linear', copy=False)(z)
return out
def interp_2(x, y, z) :
rows, cols = x.shape
row_idx = np.arange(rows).reshape((rows,) + (1,) * z.ndim)
col_idx = np.argmax(x.reshape(x.shape + (1,) * z.ndim) > z, axis=1) - 1
ret = y[row_idx, col_idx + 1] - y[row_idx, col_idx]
ret /= x[row_idx, col_idx + 1] - x[row_idx, col_idx]
ret *= z - x[row_idx, col_idx]
ret += y[row_idx, col_idx]
return ret
```

`interp_1`

is an optimized version of your code, following Dave's answer. `interp_2`

is a vectorized implementation of linear interpolation that avoids any python loop whatsoever. Coding something like this requires a sound understanding of broadcasting and indexing in numpy, and some things are going to be less optimized than what `interp1d`

does. A prime example being finding the bin in which to interpolate a value: `interp1d`

will surely break out of loops early once it finds the bin, the above function is comparing the value to all bins.

So the result is going to be very dependent on what `n_i`

and `n_j`

are, and even how long your array `z`

of values to interpolate is. If `n_j`

is small and `n_i`

is large, you should expect an advantage from `interp_2`

, and from `interp_1`

if it is the other way around. Smaller `z`

should be an advantage to `interp_2`

, longer ones to `interp_1`

.

I have actually timed both approaches with a variety of `n_i`

and `n_j`

, for `z`

of shape `(5,)`

and `(50,)`

, here are the graphs:

So it seems that for `z`

of shape `(5,)`

you should go with `interp_2`

whenever `n_j < 1000`

, and with `interp_1`

elsewhere. Not surprisingly, the threshold is different for `z`

of shape `(50,)`

, now being around `n_j < 100`

. It seems tempting to conclude that you should stick with your code if `n_j * len(z) > 5000`

, but change it to something like `interp_2`

above if not, but there is a great deal of extrapolating in that statement! If you want to further experiment yourself, here's the code I used to produce the graphs.

```
n_s = np.logspace(1, 3.3, 25)
int_1 = np.empty((len(n_s),) * 2)
int_2 = np.empty((len(n_s),) * 2)
z_shape = (5,)
for i, n_i in enumerate(n_s) :
print int(n_i)
for j, n_j in enumerate(n_s) :
x, y, z = sample_data(int(n_i), int(n_j), z_shape)
int_1[i, j] = min(timeit.repeat('interp_1(x, y, z)',
'from __main__ import interp_1, x, y, z',
repeat=10, number=1))
int_2[i, j] = min(timeit.repeat('interp_2(x, y, z)',
'from __main__ import interp_2, x, y, z',
repeat=10, number=1))
cs = plt.contour(n_s, n_s, np.transpose(int_1-int_2))
plt.clabel(cs, inline=1, fontsize=10)
plt.xlabel('n_i')
plt.ylabel('n_j')
plt.title('timeit(interp_2) - timeit(interp_1), z.shape=' + str(z_shape))
plt.show()
```