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i want to find the square root of a number without using the math module,as i need to call the function some 20k times and dont want to slow down the execution by linking to the math module each time the function is called

is there any faster and easier way for finding square root??

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3  
sqrt()s are just slow. Do you really need to find 20k distinct roots, or can you use a lookup table or cache results? –  David Lively Jun 15 '10 at 17:22

6 Answers 6

up vote 19 down vote accepted

Importing the math module only happens once, and you probably won't get much faster than the math module. There is also an older Stackoverflow question regarding Which is faster in Python: x**.5 or math.sqrt(x)?. It is not clear which method is faster.

Maybe take a look at NumPy and SciPy, not necessarily for the sqrt but if you're doing some heavy calculations they could be handy.

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7  
+1 for answering both the question being asked and the question that actually needed answering! –  Skeolan Jun 15 '10 at 16:42
4  
Just so you know, using a Numpy array and just raising the whole array to the .5 power speeds up 20k square roots by a factor of at least 60x in my tests over iterating over the same numpy array. –  Justin Peel Jun 15 '10 at 20:38
    
With Python 2.6.5 on Mac OS X, sqrt() is actually faster (see my answer). The two approaches are actually different, and which one is faster depends on implementation details. –  EOL Jun 16 '10 at 7:28
1  
I've removed the text about which is faster. –  Mad Scientist Jun 16 '10 at 7:47

I'd think the math library would likely be as fast as anything you could write yourself. But if you want to write your own, here's one algorithm. I don't know Python, so I'll just write some pseudo-code.

function sqrt(x)
  lastGuess=x/2
  loop
    guess=(lastGuess+x/lastGuess)/2
    if abs(guess-lastGuess)<.000001 // or whatever threshold you want
      exit loop
    lastGuess=guess
  return guess

and the pseudocode translated to Python:

def sqrt(x):
    last_guess= x/2.0
    while True:
        guess= (last_guess + x/last_guess)/2
        if abs(guess - last_guess) < .000001: # example threshold
            return guess
        last_guess= guess
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+1 for actually answering the question :) –  Lo Sauer Sep 26 '12 at 6:10

Use the power operator, and raise your numbers to the 1/2 power:

>>> 2**0.5
1.4142135623730951

As to whether it's faster:

>>> timeit.timeit(stmt='sqrt(x)', setup='from math import sqrt; x = 2')
0.7182440785071833
>>> timeit.timeit(stmt='x**0.5', setup='from math import sqrt; x = 2')
0.87514279049432275
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I get similar results on my computer, but when I try the benchmark from the accepted answer of the question I linked to, math.sqrt is faster. There is something funny going on here. –  Mad Scientist Jun 15 '10 at 16:42
    
These timing tests are not very representative: you can see my answer, which shows that '**0.5' is actually slower than math.sqrt. The reason is that 2**0.5 is a pre-calculated numerical constant. –  EOL Jun 15 '10 at 17:21
    
@EOL - I get similar results with other numbers (i.e., 0.42521**0.5 is roughly 7 times faster than sqrt(0.42521)). I'm not making any conclusions, but the test seems valid to me. –  Seth Jun 15 '10 at 20:54
2  
You do get the same result because 0.42521**0.5 is pre-compiled by Python (as is any constant to the power 0.5): when you run the code, no mathematical operation is performed; instead, Python just loads a constant number (see the disassembled code in my answer). If computation time matters, it's only when the square root of variables is calculated (not of constants); so, realistic tests should involve taking the square root of a variable. –  EOL Jun 16 '10 at 7:22
    
I'm being dense, I get it now. Thanks :P Fixed the test. –  Seth Jun 16 '10 at 17:45

As Fabian said, it's hard to be faster than math.sqrt. The reason is that it calls the correspond function from the C library, with CPython.

However, you can speed things up by removing the overhead of attribute lookup:

from math import sqrt

Each subsequent call to sqrt will not have to look it up in the math module, which saves execution time:

print sqrt(2)

Here are timing numbers, from the fastest to the slowest (Python 2.6.5, Mac OS X 10.6.3): sqrt is faster than **0.5:

lebigot@weinberg ~ % python -m timeit -s 'from math import sqrt; x = 2' 'sqrt(x)'
1000000 loops, best of 3: 0.207 usec per loop
lebigot@weinberg ~ % python -m timeit -s 'x = 2' 'x**0.5'
1000000 loops, best of 3: 0.226 usec per loop
lebigot@weinberg ~ % python -m timeit -s 'import math; x = 2' 'math.sqrt(x)'
1000000 loops, best of 3: 0.268 usec per loop

Note that the timing tests calculate the square root of a variable. They do not calculate a constant like "2*0.5", because "2*0.5" is pre-calculated, in CPython:

import dis

def f():
    return 2**0.5

print dis.dis(f)

prints

2           0 LOAD_CONST               3 (1.4142135623730951)
            3 RETURN_VALUE        

where you see the constant float sqrt(2) = 1.414…

If you manipulate arrays of numbers, NumPy's sqrt is the way to go, as mentioned in another answer.

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In some special cases you can trade program size for blistering speed. Create a large array and store the pre-calculated result for every square root operation (using the input value as the index). It's pretty limited but you won't get anything faster.

(That's how quake did it)

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If the values are all small integers, this could work. If the values are arbitrary real numbers, this will not work. Also, this only works if you expect to see the same number show up many times. Even at that, rather than calculating the square roots of thousands of numbers that may never show up in the input, I'd build a cache and calculate the square root the first time it's needed, then after that use the value from the cache. –  Jay May 8 at 20:18

You could implement Newton's method but, though it's really fast, it's unlikely to be faster than the C version which I assume is implemented in the math module. See http://en.wikipedia.org/wiki/Methods_of_computing_square_roots .

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