# Pythonic way to implement three similar integer range operators?

I am working on a circular problem. In this problem, we have objects that are put on a ring of size `MAX`, and are assigned IDs from (0 to MAX-1).

I have three simple functions to test for range inclusions. inRange(i,j,k) tests if i is in the circular interval [j,k[ (Mnemonic is i inRange(j,k)). And I have the same for ranges ]j,k[ and ]j,k].

Code in those three methods look duplicated from one method to another:

``````def inRange(i,j,k):
"""
Returns True if i in [j, k[
* 0 <= i, j, k < MAX
* no order is assumed between j and k: we can have k < j
"""
if j <= k:
return j <= i < k
# j > k :
return j <= i or i < k

def inStrictRange(i,j,k):
"""
Returns True if i in ]j, k[
* 0 <= i, j, k < MAX
* no order is assumed between j and k: we can have k < j
"""
if j <= k:
return j < i < k
# j > k :
return j < i or i < k

def inRange2(i,j,k):
"""
Returns True if i in ]j, k]
* 0 <= i, j, k < MAX
* no order is assumed between j and k: we can have k < j
"""
if j <= k:
return j < i <= k
# j > k :
return j < i or i <= k
``````

Do you know any cleaner way to implement those three methods? After all, only the operators are changing?!

After thinking of a better solution, I came up with:

``````from operator import lt, le
def _compare(i,j,k, op1, op2):
if j <= k:
return op1(j,i) and op2(i,k)
return op1(j,i) or op2(i,k)

def inRange(i,j,k):
return _compare(i,j,k, le, lt)
def inStrictRange(i,j,k):
return _compare(i,j,k, lt, lt)
def inRange2(i,j,k):
return _compare(i,j,k, lt, le)
``````

Is it any better? Can you come up with something more intuitive? In short, what would be the Pythonic way to write these three operators?

Also, I hate the inRange, inStrictRange, inRange2 names, but I can't think of crystal-clear names. Any ideas?

Thanks.

-

Two Zen of Python principles leap to mind:

• Simple is better than complex.
• There should be one—and preferably only one—obvious way to do it.

# `range`

The Python built-in function `range(start, end)` generates a list from `start` to `end`.1 The first element of that list is `start`, and the last element is `end - 1`.

There is no `range_strict` function or `inclusive_range` function. This was very awkward to me when I started in Python. ("I just want a list from `a` to `b` inclusive! How hard is that, Guido?") However, the convention used in calling the `range` function was simple and easy to remember, and the lack of multiple functions made it easy to remember exactly how to generate a range every time.

# Recommendation

As you've probably guessed, my recommendation is to only create a function to test whether i is in the range [j, k). In fact, my recommendation is to keep only your existing `inRange` function.

(Since your question specifically mentions Pythonicity, I would recommend you name the function as `in_range` to better fit with the Python Style Guide.)

# Justification

Why is this a good idea?

• The single function is easy to understand. It is very easy to learn how to use it.

Of course, the same could be said for each of your three starting functions. So far so good.

• There is only one function to learn. There are not three functions with necessarily similar names.

Given the similar names and behaviours of your three functions, it is somewhat possible that you will, at some point, use the wrong function. This is compounded by the fact that the functions return the same value except for edge cases, which could lead to a hard-to-find off-by-one bug. By only making one function available, you know you will not make such a mistake.

• The function is easy to edit.

It is unlikely that you'll need to ever debug or edit such an easy piece of code. However, should you need to do so, you need only edit this one function. With your original three functions, you have to make the same edit in three places. With your revised code in your self-answer, the code is made slightly less intuitive by the operator obfuscation.

• The "size" of the range is obvious.

For a given ring where you would use `inRange(i, j, k)`, it is obvious how many elements would be covered by the range [j, k). Here it is in code.

``````if j <= k:
size = k - j
if j > k:
size = k - j + MAX
``````

So therefore

``````size = (k - j) % MAX
``````

# Caveats

I'm approaching this problem from a completely generic point of view, such as that of a person writing a function for a publicly-released library. Since I don't know your problem domain, I can't say whether this is a practical solution.

Using this solution may mean a fair bit of refactoring of the code that calls these functions. Look through this code to see if editing it is prohibitively difficult or tedious.

1: Actually, it is `range([start], end, [step])`. I trust you get what I mean though.

-
Wow. Thanks for taking the time to write that answer. But afaik, range() generates a list. And I don't really want to generate a list for each generic comparison: we are talking of generating a list of size O(n), and doing a O(n) operation (contains_) instead of my three arithmetic operations. It's a very important overhead :) –  NicDumZ Jun 12 '09 at 10:29
I don't mean to say that you should generate a range for your comparison. I'm saying that you should consider why there is only one `range` function, and then consider only writing one `inRange` function for the same reasons. Your `inRange` function is obviously O(1). However, you should consider omitting the other two functions entirely. If you suddenly need an inclusive `inRange` for x between a and b, you have `inRange(x, a, b+1)`, which is also O(1). –  Wesley Jun 12 '09 at 21:41
Right, sorry for reading too fast through your answer then. I certainly agree with your suggestion then. in_range2(x, lo, hi) can be obtained through `not in_range(x, hi, lo)` –  NicDumZ Jun 13 '09 at 2:39
For clarity's sake, I would rewrite a call to `in_range2(x, lo, hi)` as `in_range(x, lo + 1, hi + 1)`. After all, the goal of being pythonic is being easy to understand. Admittedly, adding one to the bounds is not terribly clear either, but it's a little easier to work out with time and a pencil. –  Wesley Jun 13 '09 at 3:45
If you don't want to generate a list, use xrange() instead. It uses yield stackoverflow.com/questions/231767/…) and generate the values on the fly. –  e-satis Jun 13 '09 at 8:24
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The Pythonic way to do it is to choose readability, and therefor keep the 3 methods as they were at the beginning.

It's not like they are HUGE methods, or there are thousand of them, or you would have to dynamically generate them.

-
+1: Particularly since the docstrings are most of the text –  James Hopkin Jun 12 '09 at 8:11
maybe. But my question sort of begs for another approach, or at least suggestions :) –  NicDumZ Jun 13 '09 at 2:30

No higher-order functions, but it's less code, even with the extraneous `else`.

``````def exclusive(i, j, k):
if j <= k:
return j < i < k
else:
return j < i or i < k

def inclusive_left(i, j, k):
return i==j or exclusive(i, j, k)

def inclusive_right(i, j, k):
return i==k or exclusive(i, j, k)
``````

I actually tried switching the identifiers to `n, a, b`, but the code began to look less cohesive. (My point: perfecting this code may not be a productive use of time.)

-
I like this I guess: concentrate on the Mathematical meaning rather than on code factoring. And /yes/*3 for the productivity remark :) –  NicDumZ Jun 12 '09 at 7:17

Now I am thinking of something such as:

``````def comparator(lop, rop):
def comp(i, j, k):
if j <= k:
return lop(j, i) and rop(i,k)
return lop(j, i) or rop(i,k)

return comp

from operator import le, lt

inRange = comparator(le, lt)
inStrictRange = comparator(lt, lt)
inRange2 = comparator(lt, le)
``````

Which looks better indeed.

-
That's a nice way indeed. I'd recommend the name "comparer" or some such though; "comparator" kind of indicates that the function is a device which compares, rather than just something that compares. Small matter, I know =) –  Blixt Jun 12 '09 at 7:05
Pretty classy indeed. Unfortunately, le and lt don't jump out at you as well as operator literals do. –  Nikhil Chelliah Jun 12 '09 at 7:14

I certainly agree that you need only one function, and that the function should use a (Pythonic) half-open range.

Two suggestions:

1. Use meaningful names for the args: in_range(x, lo, hi) is a big improvement relative to the 2-keystroke cost.

2. Document the fact that the constraint hi < MAX means that it is not possible to express a range that includes all MAX elements. As Wesley remarked, size = (k - j) % MAX i.e. size = (hi - lo) % MAX and thus 0 <= size < MAX.

-
Two very useful points, thanks. For most of the answers, there is also a problem with a range of size 0. But fortunately enough, this is not in my scope today :) –  NicDumZ Jun 13 '09 at 1:59

To make it more familiar to your users, I would have one main in_range function with the same bounds as range(). This makes it much easier to remember, and has other nice properties as Wesley mentioned.

``````def in_range(i, j, k):
return (j <= i < k) if j <= k else (j <= i or i < k)
``````

You can certainly use this one alone for all your use cases by adding 1 to j and/or k. If you find that you're using a specific form frequently, then you can define it in terms of the main one:

``````def exclusive(i, j, k):
"""Excludes both endpoints."""
return in_range(i, j + 1, k)

def inclusive(i, j, k):
"""Includes both endpoints."""
return in_range(i, j, k + 1)

def weird(i, j, k):
"""Excludes the left endpoint but includes the right endpoint."""
return in_range(i, j + 1, k + 1)
``````

This is shorter than mucking around with operators, and is also much less confusing to understand. Also, note that you should use underscores instead of camelCase for function names in Python.

-
+1 for the CamelCase remark, and for reminding me that for naturals "i in [lo, hi[" <=> 'i in [lo, hi+1]". It's however a bit unperfect: you need to include MAX modulos, as my ranges are cyclic :) –  NicDumZ Jun 13 '09 at 2:25

I'd go one step further than Wesley in aping the normal python 'in range' idiom; i'd write a cyclic_range class:

``````import itertools

MAX = 10 # or whatever

class cyclic_range(object):
def __init__(self, start, stop):
# mod so you can be a bit sloppy with indices, plus -1 means the last element, as with list indices
self.start = start % MAX
self.stop = stop % MAX
def __len__(self):
return (self.stop - self.start) % MAX
def __getitem__(self, i):
return (self.start + i) % MAX
def __contains__(self, x):
if (self.start < self.stop):
return (x >= self.start) and (x < self.stop)
else:
return (x >= self.start) or (x < self.stop)
def __iter__(self):
for i in xrange(len(self)):
yield self[i]
def __eq__(self, other):
if (len(self) != len(other)): return False
for a, b in itertools.izip(self, other):
if (a != b): return False
return True
def __hash__(self):
return (self.start << 1) + self.stop
def __str__(self):
return str(list(self))
def __repr__(self):
return "cyclic_range(" + str(self.start) + ", " + str(self.stop) + ")"
# and whatever other list-like methods you fancy
``````

You can then write code like:

``````if (myIndex in cyclic_range(firstNode, stopNode)):
blah
``````

To do the equivalent of inRange. To do inStrictRange, write:

``````if (myIndex in cyclic_range(firstNode + 1, stopNode)):
``````

And to do inRange2:

``````if (myIndex in cyclic_range(firstNode + 1, stopNode + 1)):
``````

``````	def strict(self):
return cyclic_range(self.start + 1, self.stop)
def right_closed(self):
return cyclic_range(self.start + 1, self.stop + 1)
``````

And then doing:

``````if (myIndex in cyclic_range(firstNode, stopNode).strict()): # inStrictRange
if (myIndex in cyclic_range(firstNode, stopNode).closed_right()): # inRange2
``````

Whilst this approach is, IMHO, more readable, it does involve doing an allocation, rather than just a function call, which is more expensive - although still O(1). But then if you really cared about performance, you wouldn't be using python!

-
On a philosophic aspect, I disagree with "if you really cared about performance, you wouldn't be using python!". I like Python for its readability. It's great to prototype implementations and improve algorithms (algorithms, not implementations). Then, if you need something fast, porting it to another language is not so hard. –  NicDumZ Jun 13 '09 at 2:21
Interesting approach too, thanks :) A small remark: hash is fast, but very collusive: ~70% of collisions. That might be unwanted :) –  NicDumZ Jun 13 '09 at 2:28