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@ -49,3 +49,39 @@ def roundup(value, unit): |
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return numpy.ceil(float(value) / float(unit)) * unit |
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return numpy.ceil(float(value) / float(unit)) * unit |
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def choose(n,r): |
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"""Computes n! / {r! (n-r)!} . Note that the following condition must |
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always be fulfilled: |
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1 <= n |
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1 <= r <= n |
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Otherwise the result is not predictable! |
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Optimization: To minimize the # of multiplications and divisions, we |
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rewrite the expression as |
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n! n(n-1)...(n-r+1) |
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--------- = ---------------- |
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r!(n-r)! r! |
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To avoid multiplication overflow as much as possible, we will evaluate |
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in the following STRICT order, from left to right: |
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n / 1 * (n-1) / 2 * (n-2) / 3 * ... * (n-r+1) / r |
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We can show that integer arithmatic operated in this order is exact |
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(i.e. no roundoff error). |
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Note: this implementation is based on my C++ cp.inc library. |
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For other implementations, see: |
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http://stackoverflow.com/questions/3025162/statistics-combinations-in-python |
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Published in stack overflow, see URL above. |
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""" |
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assert n >= 0 |
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assert 0 <= r <= n |
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c = 1L |
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denom = 1 |
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for (num,denom) in zip(xrange(n,n-r,-1), xrange(1,r+1,1)): |
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c = (c * num) // denom |
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return c |
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