# Calculating Integrals: One-liner solution?

I was working on a program to find the integral of a function, where the user specifies the amount of rectangles, the start, and the stop.

NOTE: I am using left-end points of the rectangles.

I have the function working perfectly (at least, it seems to be perfect). However, I wanted to see if I could write a one-liner for it, but not sure how because I'm using `eval()`. Here is my original code:

``````def integral(function, n=1000, start=0, stop=100):
"""Returns integral of function from start to stop with 'n' rectangles"""
increment, rectangles, x = float((stop - start)) / n, [], start
while x <= stop:
num = eval(function)
rectangles.append(num)
if x >= stop: break
x += increment
return increment * sum(rectangles)
``````

This works fine:

``````>>> integral('x**2')
333833.4999999991
``````

The actual answer is `1000000/3`, so my function gives a pretty nice estimate (for only 1000 rectangles).

My attempt at a one-liner:

``````def integral2(function, n=1000, start=0, stop=100): rectangles = [(float(x) / n) for x in range(start*n, (stop*n)+1)]; return (float((stop-start))/n) * sum([eval(function) for x in rectangles])
``````

However, this isn't a truly a one-liner since I'm using a semi-colon. Also, it's a bit slower (takes a few seconds longer, which is pretty significant) and gives the wrong answer:

``````>>> integral2('x**2')
33333833.334999967
``````

So, is it possible to use a one-liner solution for this function? I wasn't sure how to implement `eval()` and `float(x)/n` in the same list comprehension. `float(x)/n` achieves a virtual 'step' in the `range` function.

Thanks!

-
Remember that floating-point numbers are inherently inaccurate. Trying a fixed-point number may help. Also, one-liners are not something to strive for. Right now it is bad. –  Waleed Khan Feb 8 '13 at 3:01
@WaleedKhan I don't want to use the one-liner for my program, as it is slower. I was just wondering if it was possible, and if it is, how. –  Rushy Panchal Feb 8 '13 at 3:05
Incidentally, I would pass to the function a callable object (e.g. a lambda, a function, ...) instead of a string to `eval` - it's cleaner and could speed it up by quite a bit. –  Matteo Italia Feb 8 '13 at 3:09
@MatteoItalia Agreed - `lambda x: x**2` is much nicer than `eval('x**2')` –  Alex L Feb 8 '13 at 3:24

``````def integral2(function, n=1000, start=0, stop=100): return (float(1)/n) * sum([eval(function) for x in [(float(x) / n) for x in range(start*n, (stop*n)+1)]])
``````

Note that there is a big difference between `integral` and `integral2`: `integral2` makes `(stop*n)+1-(start*n)` rectangles, while `integral` only makes `n` rectangles.

``````In [64]: integral('x**2')
Out[64]: 333833.4999999991
In [68]: integral2('x**2')
Out[68]: 333338.33334999956
``````

``````In [69]: %timeit integral2('x**2')
1 loops, best of 3: 704 ms per loop

In [70]: %timeit integral('x**2')
100 loops, best of 3: 7.32 ms per loop
``````

Perhaps a more comparable translation of `integral` would be:

``````def integral3(function, n=1000, start=0, stop=100): return (float(stop-start)/n) * sum([eval(function) for x in [start+(i*float(stop-start)/n) for i in range(n)]])

In [77]: %timeit integral3('x**2')
100 loops, best of 3: 7.1 ms per loop
``````

Of course, it should go with say that there is no purpose for making this a one-liner other than (perverse?) amusement :)

-

You don't need to use `eval` if you receive `function` as a Python `callable` itself You could also make use of `numpy.arange` function to generate a list of float values

### Case 1: `function` is a Python `callable`

``````def integrate(f, n, start, end):
return sum([f(i)*(abs(start-end)/float(n)) for i in np.arange(start, end, abs(start-end)/float(n))])
``````

### Case 2: `function` is not a Python `callable`

``````def integrate(f, n, start, end):
return sum([eval(f)*(abs(start-end)/float(n)) for x in np.arange(start, end, abs(start-end)/float(n))])
``````
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mine is not that accurate though –  Aditya Sriram Feb 8 '13 at 3:22