I thought up a rather elegant solution (IMHO), so I can't resist posting it:

```
from bisect import bisect_left
class Interpolate(object):
def __init__(self, x_list, y_list):
if any(y - x <= 0 for x, y in zip(x_list, x_list[1:])):
raise ValueError("x_list must be in strictly ascending order!")
x_list = self.x_list = map(float, x_list)
y_list = self.y_list = map(float, y_list)
intervals = zip(x_list, x_list[1:], y_list, y_list[1:])
self.slopes = [(y2 - y1)/(x2 - x1) for x1, x2, y1, y2 in intervals]
def __getitem__(self, x):
i = bisect_left(self.x_list, x) - 1
return self.y_list[i] + self.slopes[i] * (x - self.x_list[i])
```

I map to `float`

so that integer division (python <= 2.7) won't kick in and ruin things if `x1`

, `x2`

, `y1`

and `y2`

are all integers for some iterval.

In `__getitem__`

I'm taking advantage of the fact that self.x_list is sorted in ascending order by using `bisect_left`

to (very) quickly find the index of the largest element smaller than `x`

in `self.x_list`

.

Use the class like this:

```
i = Interpolate([1, 2.5, 3.4, 5.8, 6], [2, 4, 5.8, 4.3, 4])
# Get the interpolated value at x = 4:
y = i[4]
```

I've not dealt with the border conditions at all here, for simplicity. As it is, `i[x]`

for `x < 1`

will work as if the line from (2.5, 4) to (1, 2) had been extended to minus infinity, while `i[x]`

for `x == 1`

or `x > 6`

will raise an `IndexError`

. Better would be to raise an IndexError in all cases, but this is left as an exercise for the reader. :)

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