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# Python: efficiently check if integer is within *many* ranges

I am working on a postage application which is required to check an integer postcode against a number of postcode ranges, and return a different code based on which range the postcode matches against.

Each code has more than one postcode range. For example, the M code should be returned if the postcode is within the ranges 1000-2429, 2545-2575, 2640-2686 or is equal to 2890.

I could write this as:

if 1000 <= postcode <= 2429 or 2545 <= postcode <= 2575 or 2640 <= postcode <= 2686 or postcode == 2890:
return 'M'

but this seems like a lot of lines of code, given that there are 27 returnable codes and 77 total ranges to check against. Is there a more efficient (and preferably more concise) method of matching an integer to all these ranges using Python?

Edit: There's a lot of excellent solutions flying around, so I have implemented all the ones that I could, and benchmarked their performances.

The environment for this program is a web service (Django-powered actually) which needs to check postcode region codes one-by-one, on the fly. My preferred implementation, then, would be one that can be quickly used for each request, and does not need any process to be kept in memory, or needs to process many postcodes in bulk.

I tested the following solutions using timeit.Timer with default 1000000 repetitions using randomly generated postcodes each time.

### IF solution (my original)

if 1000 <= postcode <= 2249 or 2555 <= postcode <= 2574 or ...:
return 'M'
if 2250 <= postcode <= 2265 or ...:
return 'N'
...

Time for 1m reps: 5.11 seconds.

### Ranges in tuples (Jeff Mercado)

Somewhat more elegant to my mind and certainly easier to enter and read the ranges. Particularly good if they change over time, which is possible. But it did end up four times slower in my implementation.

if any(lower <= postcode <= upper for (lower, upper) in [(1000, 2249), (2555, 2574), ...]):
return 'M'
if any(lower <= postcode <= upper for (lower, upper) in [(2250, 2265), ...]):
return 'N'
...

Time for 1m reps: 19.61 seconds.

### Set membership (gnibbler)

As stated by the author, "it's only better if you are building the set once to check against many postcodes in a loop". But I thought I would test it anyway to see.

if postcode in set(chain(*(xrange(start, end+1) for start, end in ((1000, 2249), (2555, 2574), ...)))):
return 'M'
if postcode in set(chain(*(xrange(start, end+1) for start, end in ((2250, 2265), ...)))):
return 'N'
...

Time for 1m reps: 339.35 seconds.

### Bisect (robert king)

This one may have been a bit above my intellect level. I learnt a lot reading about the bisect module but just couldn't quite work out which parameters to give find_ge() to make a runnable test. I expect that it would be extremely fast with a loop of many postcodes, but not if it had to do the setup each time. So, with 1m repetitions of filling numbers, edgepairs, edgeanswers etc for just one postal region code (the M code with four ranges), but not actually running the fast_solver:

Time for 1m reps: 105.61 seconds.

### Dict (sentinel)

Using one dict per postal region code pre-generated, cPickled in a source file (106 KB), and loaded for each run. I was expecting much better performance from this method, but on my system at least, the IO really destroyed it. The server is a not-quite-blindingly-fast-top-of-the-line Mac Mini.

Time for 1m reps: 5895.18 seconds (extrapolated from a 10,000 run).

## The summary

Well, I was expecting someone to just give a simple 'duh' answer that I hadn't considered, but it turns out this is much more complicated (and even a little controversial).

If every nanosecond of efficiency counted in this case, I would probably keep a separate process running which implemented one of the binary search or dict solutions and kept the result in memory for an extremely fast lookup. However, since the IF tree takes only five seconds to run a million times, which is plenty fast enough for my small business, that's what I'll end up using in my application.

Thank you to everyone for contributing!

-
Ah, so some ranges map to different letters? – John La Rooy May 19 '11 at 5:44
The set answer is good, but all things told, you should test the performance. It might very well be that the if branches are faster than set inclusion (and they definitely take less memory). – Nick Bastin May 19 '11 at 6:40
If your intervals do not overlap a binary search should be plenty efficient. If your intervals overlap and you have lots of them, read up on Interval trees. – samplebias May 19 '11 at 22:03
@tobygriffin: need developer to change code, only a user needed to edit datafile. – John Machin May 20 '11 at 2:40
Regards my solution with the bisect, You need to only do the pre-processing once! once you have edgepairsanswers and edgeanswers sitting in memory, you only need to run fast_solver each time (the whole point is that you are using pre-calculated results rather than recalculating the results each time) – robert king May 20 '11 at 12:15

## 10 Answers

Your benchmarks seem to include setting up the data structure from scratch each for each call. Why? Have you considered a mapping from postcode to region code, loaded from file ONCE at module import time? These look suspiciously like Australian postcodes. If so, there aren't very many of them.

-
Thank you, this exposed a large gap in my knowledge! However I have just done some tests, and it appears that my Django WSGI app imports its modules freshly once per client request, rather than keeping them in memory between requests. This being the case, there would still be the overhead of loading the data structure for each request. There may be another way around this, but I do not know it. – tobygriffin May 20 '11 at 2:17
@tobygriffin: upvotes count more than thanks :-) Perhaps you should ask a separate question to elicit whether this repeated importing is more apparent than real (inside one Python process invokation, 2nd and subsequent imports of the same module are very quick) and if real, how it can be worked around. – John Machin May 20 '11 at 2:39
I am not sure how this is the answer of your question ??? – sapam Jan 27 '14 at 10:04

You can throw your ranges into tuples and put the tuples in a list. Then use any() to help you find if your value is within these ranges.

ranges = [(1000,2429), (2545,2575), (2640,2686), (2890, 2890)]
if any(lower <= postcode <= upper for (lower, upper) in ranges):
print('M')
-
Why an upvote for a solution with same horrible efficiency like the code by the OP? Sorry, not an appropriate solution for the problem! – Andreas Jung May 19 '11 at 5:39
@Sentinel: Not an appropriate solution? How so? Is there some magic hashing function that can turn anything like this into an O(1) solution in a reasonable amount of space? I don't buy it. This is probably the best its gonna get with a reasonable compromise. If there's such a solution that can be more efficient in terms of speed and efficiency, then by all means, be my guest and share it with us. – Jeff Mercado May 19 '11 at 5:51
@jeff: your solution is nothing but code-rewriting in the same horrible but a little more elegant way - nothing more, nothing less. Look at my anwer. A hash-based solution is both efficient and better maintainable than having hard-coded ranges here. Memory does matter, memory is cheap...nobody needs yet another runtime-inefficient solution this yours or the one of the OP. There is a slighly difference between O(1) and O(n)... – Andreas Jung May 19 '11 at 5:56
@Sentinel: Answer me this then, suppose we had the ranges [(-5000000, 5000000), (6000000, 100000000000)], would your solution be a viable one? Not likely. The point is that there is a compromise made here for both of us and I went for memory efficiency. How can you argue with that? – Jeff Mercado May 19 '11 at 6:01
We don't have that large ranges here. Postcodes are usually max 5 chars long! – Andreas Jung May 19 '11 at 6:08

Probably the fastest will be to check the membership of a set

>>> from itertools import chain
>>> ranges = ((1000, 2429), (2545, 2575), (2640, 2686), (2890, 2890))
>>> postcodes = set(chain(*(xrange(start, end+1) for start, end in ranges)))
>>> 1000 in postcodes
True
>>> 2500 in postcodes
False

But it does use more memory this way, and building the set takes time, so it's only better if you are building the set once to check against many postcodes in a loop

EDIT: seems that different ranges need to map to different letters

>>> from itertools import chain
>>> ranges = {'M':((1000,2429), (2545,2575), (2640,2686), (2890, 2890)),
# more ranges
}
>>> postcodemap = dict((k,v) for v in ranges for k in chain(*imap(xrange, *zip(*ranges[v]))))
>>> print postcodemap.get(1000)
M
>>> print postcodemap.get(2500)
None
-
You might want to use the class method chain.from_iterable() instead that way you're not going through the values prematurely in the argument expansion. – Jeff Mercado May 19 '11 at 6:13

you only have to solve for edge cases and for one number between edge cases when doing inequalities.

e.g. if you do the following tests on TEN:

10 < 20, 10 < 15, 10 > 8, 10 >12

It will give True True True False

but note that the closest numbers to 10 are 8 and 12

this means that 9,10,11 will give the answers that ten did.. if you don't have too many initial range numbers and they are sparse then this well help. Otherwise you will need to see if your inequalities are transitive and use a range tree or something.

So what you can do is sort all of your boundaries into intervals. e.g. if your inequalities had the numbers 12, 50, 192,999

you would get the following intervals that ALL have the same answer: less than 12, 12, 13-49, 50, 51-191, 192, 193-998, 999, 999+

as you can see from these intervals we only need to solve for 9 cases and we can then quickly solve for anything.

Here is an example of how I might carry it out for solving for a new number x using these pre-calculated results:

a) is x a boundary? (is it in the set) if yes, then return the answer you found for that boundary previously. otherwise use case b)

b) find the maximum boundary number that is smaller than x, call it maxS find the minimum boundary number that is larger than x call it minL. Now just return any previously found solution that was between maxS and minL.

see Python binary search-like function to find first number in sorted list greater than a specific value for finding closest numbers. bisect module will help (import it in your code) This will help finding maxS and minL

You can use bisect and the function i have included in my sample code:

def find_ge(a, key):
'''Find smallest item greater-than or equal to key.
Raise ValueError if no such item exists.
If multiple keys are equal, return the leftmost.

'''
i = bisect_left(a, key)
if i == len(a):
raise ValueError('No item found with key at or above: %r' % (key,))
return a[i]

ranges=[(1000,2429), (2545,2575), (2640,2686), (2890, 2890)]
numbers=[]
for pair in ranges:
numbers+=list(pair)

numbers+=[-999999,999999] #ensure nothing goes outside the range
numbers.sort()
edges=set(numbers)

edgepairs={}

for i in range(len(numbers)-1):
edgepairs[(numbers[i],numbers[i+1])]=(numbers[i+1]-numbers[i])//2

def slow_solver(x):
return #your answer for postcode x

listedges=list(edges)
edgeanswers=dict(zip(listedges,map(solver,listedges)))
edgepairsanswers=dict(zip(edgepairs.keys(),map(solver,edgepairs.values())))

#now we are ready for fast solving:
def fast_solver(x):
if x in edges:
return edgeanswers[x]
else:
#find minL and maxS using find_ge and your own similar find_le
return edgepairsanswers[(minL,maxS)]
-

Recently I had a similar requirement and I used bit manipulation to test if an integer belongs to said range. It is definitely faster, but I guess not suitable if your ranges involve huge numbers. I liberally copied example methods from here

First we create a binary number which will have all bits in the range set to 1.

#Sets the bits to one between lower and upper range
def setRange(permitRange, lower, upper):
# the range is inclusive of left & right edge. So add 1 upper limit
bUpper = 1 << (upper + 1)
bLower = 1 << lower
mask = bUpper - bLower
return (permitRange | mask)

#For my case the ranges also include single integers. So added method to set single bits
#Set individual bits  to 1
def setBit(permitRange, number):
mask = 1 << vlan
return (permitRange| mask)

Now time to parse the range and populate our binary mask. If the highest number in the range is n, we will be creating integer greater than 2^n in binary

#Example range (10-20, 25, 30-50)
rangeList = "10-20, 25, 30-50"
maxRange = 100
permitRange = 1 << maxRange
for range in rangeList.split(","):
if range.isdigit():
permitRange = setBit(permitRange, int(range))
else:
lower, upper = range.split("-",1)
permitRange = setRange(permitRange, int(lower), int(upper))
return permitRange

To check if a number 'n' belongs to the range, simply test the bit at n'th position

#return a non-zero result, 2**offset, if the bit at 'offset' is one.
def testBit(permitRange, number):
mask = 1 << number
return (permitRange & mask)

if testBit(permitRange,10):
do_something()
-

Here is a fast and short solution, using numpy:

import numpy as np
lows = np.array([1, 10, 100]) # the lower bounds
ups = np.array([3, 15, 130]) # the upper bounds

def in_range(x):
return np.any((lows <= x) & (x <= ups))

Now for instance

in_range(2) # True
in_range(23) # False
-

Warning - This is probably premature optimisation. For a large list of ranges it might be worthwhile, but probably not in your case. Also, although dictionary/set solutions will use more memory, they are still probably a better choice.

You could do a binary-search into your range end-points. This would be easy if all ranges are non-overlapping, but could still be done (with some tweaks) for overlapping ranges.

Do a find-highest-match-less-than binary search. This is the same as a find-lowest-match-greater-than-or-equal (lower bound) binary search, except that you subtract one from the result.

Use half-open items in your list of end points - that is if your range is 1000..2429 inclusive, use the values 1000 and 2430. If you get an end-point and a start-point with the same value (two ranges touching, so there is no gap between) exclude the end-point for the lower range from your list.

If you find a start-of-range end-point, your goal value is within that range. If you find an end-of-range end-point, your goal value isn't in any range.

The binary search algorithm is roughly (don't expect this to run without editing)...

while upperbound > lowerbound :
testpos = lowerbound + ((upperbound-lowerbound) // 2)

if item [testpos] > goal :
#  new best-so-far
upperbound = testpos
else :
lowerbound = testpos + 1

Note - the "//" division operator is necessary for integer division in Python 3. In Python 2, the normal "/" will work, but it's best to be ready for Python 3.

At the end, both upperbound and lowerbound point to the found item - but for the "upper bound" search. Subtract one to get the required search result. If that gives -1, there is no matching range.

There's probably a binary search routine in the library that does the upper-bound search, so prefer that to this if so. To get a better understanding of how the binary search works, see How can I better understand the one-comparison-per-iteration binary search? - no, I'm not above begging for upvotes ;-)

-
A binary search might not be so bad. It will definitely cut-down on the time going through the different ranges. – Jeff Mercado May 19 '11 at 6:07
@Jeff - not necessarily. Python is very good at optimising simple list/generator comprehensions, and the "any" linear search can be very fast for small numbers of ranges. A binary search is a tad more complex, may not optimise so well, and may not use cache so well. Asymptotically faster solutions are only guaranteed faster for sufficiently large n and the n here isn't that large. – Steve314 May 19 '11 at 6:36

The full data isn't there, but I'm assuming the ranges are non-overlapping, so you can express your ranges as a single sorted tuple of ranges, along with their codes:

ranges = (
(1000, 2249, 'M'),
(2250, 2265, 'N'),
(2555, 2574, 'M'),
# ...
)

This means we can binary search over them in one go. This should be O(log(N)) time, which should result in pretty decent performance with very large sets.

def code_lookup(value, ranges):
left, right = 0, len(ranges)

while left != right - 1:
mid = left + (right - left) / 2

if value <= ranges[mid - 1][1]:  # Check left split max
right = mid
elif value >= ranges[mid][0]:    # Check right split min
left = mid
else:                            # We are in a gap
return None

if ranges[left][0] <= value <= ranges[left][1]:
# Return the code
return ranges[left][2]

I don't have your exact values, but for comparison I ran it against some generated ranges (77 ranges with various codes) and compared it to a naive approach:

def get_code_naive(value):
if 1000 < value < 2249:
return 'M'
if 2250 < value < 2265:
return 'N'
# ...

The result for 1,000,000 was that the naive version ran in about 5 sec and the binary search version in 4 sec. So it's a bit faster (20%), the codes are a lot nicer to maintain and the longer the list gets, the more it will out-perform the naive method over time.

-

Python has a range(a, b) function which means the range from (and including) a, to (but excluding) b. You can make a list of these ranges and check to see if a number is in any of them. It may be more efficient to use xrange(a, b) which has the same meaning but doesn't actually make a list in memory.

list_of_ranges = []
list_of_ranges.append(xrange(1000, 2430))
list_of_ranges.append(xrange(2545, 2576))
for x in [999, 1000, 2429, 2430, 2544, 2545]:
result = False
for r in list_of_ranges:
if x in r:
result = True
break
print x, result
-
I think that would be a step in the wrong direction. Why turn a O(1) operation of checking if a value is within a range into a O(n) operation? – Jeff Mercado May 19 '11 at 5:21
Absolutely, my bad. I thought python could know the start/end of the xrange and do something clever. Alas no, at least not in 2.6. – karmakaze May 19 '11 at 5:32
@Jeff, if the code was for Python 3.0 then this becomes a sensible answer (provided you go back to just using range()). In Python 3.0 x in range(lo,hi) is both O(1) and space efficient. – Duncan May 19 '11 at 9:12
@Duncan: Really? That's good to know. If only... :) – Jeff Mercado May 19 '11 at 9:29

Have you really made benchmarks? Does the performance of this piece of code influence the performance of the overall application? So benchmark first!

But you can also use a dict e.g. for storing all keys of the "M" ranges:

mhash = {1000: true, 1001: true,..., 2429: true,...}

if postcode in mhash:
print 'M'

Of course: the hashes require more memory but access time is O(1).

-
Perhaps a set would be more appropriate? – Jeff Mercado May 19 '11 at 5:23
Very bad solution. You're creating a huge waste of memory with no benefit for a small number of ranges being searched. Also who want to write 2000 numbers in a source file? Maybe with set comprehensions but still wasteful. – JBernardo May 19 '11 at 6:07
@JBernado: """ Also who want to write 2000 numbers in a source file? """ - what troll statement is that? Usually you have a database with the related information and you fill your hash tables during the startup phase of your application... – Andreas Jung May 19 '11 at 6:13
The basic idea is still here - though I kind of agree that you'd probably type in the ranges (not every item), and derive the dictionary from that once per run (during initialisation or on first use). You might generate it in a separate script and serialise it, though, and the size of the file would be trivial. – Steve314 May 19 '11 at 6:23
This would be employable with a C++ bitset or some such. Otherwise, the memory consumption is, by all reasonable measures, appalling. Especially considering this is Python we're talking about here. But I do appreciate the sentiment of going with hashing, it's just not realistic for the example. – Steven Lu Nov 24 '14 at 21:05