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numpy.amax() will find the max value in an array, and numpy.amin() does the same for the min value. If I want to find both max and min, I have to call both functions, which requires passing over the (very big) array twice, which seems slow.

Is there a function in the numpy API that finds both max and min with only a single pass through the data?

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How big is very big? If I get some time, I'll run a few tests comparing a fortran implementation to amax and amin –  mgilson Aug 30 '12 at 16:01
    
I'll admit "very big" is subjective. In my case, I'm talking about arrays that are a few GB. –  superbatfish Aug 30 '12 at 17:36
    
that's pretty big. I've coded up an example to calculate it in fortran (even if you don't know fortran, it should be pretty easy to understand the code). It really makes a difference running it from fortran vs. running through numpy. (Presumably, you should be able to get the same performance from C ...) I'm not sure -- I suppose we would need a numpy dev to comment on why my functions perform so much better than theirs ... –  mgilson Aug 30 '12 at 17:39
    
Of course, this is hardly a novel idea. For example, the boost minmax library (C++) provides an implementation of the algorithm I'm looking for. –  superbatfish Aug 30 '12 at 17:46
    
Yeah, the idea isn't novel. I suppose the question that I'm wondering is what extra work is np.min doing to make it so much slower than my naive version? –  mgilson Aug 30 '12 at 17:47

4 Answers 4

I don't think that passing over the array twice is a problem. Consider the following pseudo-code:

minval = array[0]
maxval = array[0]
for i in array:
    if i < minval:
       minval = i
    if i > maxval:
       maxval = i

While there is only 1 loop here, there are still 2 checks. (Instead of having 2 loops with 1 check each). Really the only thing you save is the overhead of 1 loop. If the arrays really are big as you say, that overhead is small compared to the actual loop's work load. (Note that this is all implemented in C, so the loops are more or less free anyway).


EDIT Sorry to the 4 of you who upvoted and had faith in me. You definitely can optimize this.

Here's some fortran code which can be compiled into a python module via f2py (maybe a Cython guru can come along and compare this with an optimized C version ...):

subroutine minmax1(a,n,amin,amax)
  implicit none
  !f2py intent(hidden) :: n
  !f2py intent(out) :: amin,amax
  !f2py intent(in) :: a
  integer n
  real a(n),amin,amax
  integer i

  amin = a(1)
  amax = a(1)
  do i=2, n
     if(a(i) > amax)then
        amax = a(i)
     elseif(a(i) < amin) then
        amin = a(i)
     endif
  enddo
end subroutine minmax1

subroutine minmax2(a,n,amin,amax)
  implicit none
  !f2py intent(hidden) :: n
  !f2py intent(out) :: amin,amax
  !f2py intent(in) :: a
  integer n
  real a(n),amin,amax
  amin = minval(a)
  amax = maxval(a)
end subroutine minmax2

Compile it via:

f2py -m untitled -c fortran_code.f90

And now we're in a place where we can test it:

import timeit

size = 100000
repeat = 10000

print timeit.timeit(
    'np.min(a); np.max(a)',
    setup='import numpy as np; a = np.arange(%d, dtype=np.float32)' % size,
    number=repeat), " # numpy min/max"

print timeit.timeit(
    'untitled.minmax1(a)',
    setup='import numpy as np; import untitled; a = np.arange(%d, dtype=np.float32)' % size,
    number=repeat), '# minmax1'

print timeit.timeit(
    'untitled.minmax2(a)',
    setup='import numpy as np; import untitled; a = np.arange(%d, dtype=np.float32)' % size,
    number=repeat), '# minmax2'

The results are a bit staggering for me:

8.61869883537 # numpy min/max
1.60417699814 # minmax1
2.30169081688 # minmax2

I have to say, I don't completely understand it. Comparing just np.min versus minmax1 and minmax2 is still a losing battle, so it's not just a memory issue ...

notes -- Increasing size by a factor of 10**a and decreasing repeat by a factor of 10**a (keeping the problem size constant) does change the performance, but not in a seemingly consistent way which shows that there is some interplay between memory performance and function call overhead in python. Even comparing a simple min implementation in fortran beats numpy's by a factor of approximately 2 ...

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1  
Indeed, it's still O(n) time and practically as fast. –  progo Aug 30 '12 at 15:45
4  
The advantage of a single pass is memory efficiency. Particularly if your array is large enough to be swapped out, this could be huge. –  Dougal Aug 30 '12 at 15:55
1  
Thats not quite true, its almost half as fast, because with these kind of arrays, the memory speed is usually the limiting factor, so it can be half as fast... –  seberg Aug 30 '12 at 15:57
1  
Small note: I doubt Cython is the way to get the most optimized Python-callable C module. Cython's goal is to be a sort of type-annotated Python, which is then machine-translated to C, whereas f2py just wraps hand-coded Fortran so that it is callable by Python. A "fairer" test is probably hand-coding C and then using f2py (!) to wrap it for Python. If you're allowing C++, then Shed Skin may be the sweet spot for balancing coding ease with performance. –  John Y Aug 30 '12 at 18:19
1  
as of numpy 1.8 min and max are vectorized on amd64 platforms,on my core2duo numpy performs as well as this fortran code. But a single pass would be advantageous if the array exceed the size of the larger cpu caches. –  jtaylor Mar 7 at 13:58

There is a function for finding (max-min) called numpy.ptp if that's useful for you:

>>> import numpy
>>> x = numpy.array([1,2,3,4,5,6])
>>> x.ptp()
5

but I don't think there's a way to find both min and max with one traversal.

EDIT: ptp just calls min and max under the hood

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It's annoying because presumably the way ptp is implemented it has to keep track of max and min! –  Andy Hayden Aug 30 '12 at 16:50
    
Or it might just call max and min, not sure –  jterrace Aug 30 '12 at 17:06
    
@hayden turns out ptp just calls max and min –  jterrace Aug 30 '12 at 20:26

This is an old thread, but anyway, if anyone ever looks at this again...

When looking for the min and max simultaneously, it is possible to reduce the number of comparisons. If it is floats you are comparing (which I guess it is) this might save you some time, although not computational complexity.

Instead of (Python code):

_max = ar[0]
_min=  ar[0]
for ii in xrange(len(ar)):
    if _max > ar[ii]: _max = ar[ii]
    if _min < ar[ii]: _min = ar[ii]

you can first compare two adjacent values in the array, and then only compare the smaller one against current minimum, and the larger one against current maximum:

## for an even-sized array
_max = ar[0]
_min = ar[0]
for ii in xrange(0, len(ar), 2)):  ## iterate over every other value in the array
    f1 = ar[ii]
    f2 = ar[ii+1]
    if (f1 < f2):
        if f1 < _min: _min = f1
        if f2 > _max: _max = f2
    else:
        if f2 < _min: _min = f2
        if f1 > _max: _max = f1

The code here is written in Python, clearly for speed you would use C or Fortran or Cython, but this way you do 3 comparisons per iteration, with len(ar)/2 iterations, giving 3/2 * len(ar) comparisons. As opposed to that, doing the comparison "the obvious way" you do two comparisons per iteration, leading to 2*len(ar) comparisons. Saves you 25% of comparison time.

Maybe someone one day will find this useful.

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1  
have you benchmarked this? on modern x86 hardware you have machine instructions for min and max as used in the first variant, these avoid the need for branches while your code puts in a control dependency which probably does not map as well to the hardware. –  jtaylor Mar 7 at 14:28
    
I haven't actually. Will do if I get a chance. I think it's pretty clear that pure python code will lose hands-down to any sensible compiled implementation, but I wonder if a speedup could be seen in Cython... –  magic Mar 12 at 19:35

At first glance, numpy.histogram appears to do the trick:

count, (amin, amax) = numpy.histogram(a, bins=1)

... but if you look at the source for that function, it simply calls a.min() and a.max() independently, and therefore fails to avoid the performance concerns addressed in this question. :-(

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