# Why are slice and range upper-bound exclusive?

Disclaimer: I am not asking if the upper-bound `stop`argument of `slice()`and `range()` is exclusive or how to use these functions.

Calls to the `range`and `slice`functions, as well as the slice notation `[start:stop]` all refer to sets of integers.

``````range([start], stop[, step])
slice([start], stop[, step])
``````

In all these, the `stop` integer is excluded.

I am wondering why the language is designed this way.

Is it to make `stop`equal to the number of elements in the represented integer set when `start` equals 0 or is omitted?

Is it to have:

``````for i in range(start, stop):
``````

look like the following C code?

``````for (i = start ; i < stop; i++) {
``````
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Here's a discussion on why Python uses half-open intervals: groups.google.com/forum/?fromgroups#!msg/comp.lang.python/… –  ecatmur Jul 6 '12 at 15:10
Regardless of why they're that way, you can always write your own similar ones that are inclusive if you need that functionality a lot. –  martineau Jul 6 '12 at 16:49
Here's Edsger Dijkstra's lovely handwritten explanation of why the half-open zero-based interval convention is the best choice for computer programming: cs.utexas.edu/users/EWD/ewd08xx/EWD831.PDF –  Russell Borogove Jul 6 '12 at 18:41
Thanks for this, it's really great! –  wap26 Jul 9 '12 at 9:51

The documentation implies this has a few useful properties:

``````word[:2]    # The first two characters
word[2:]    # Everything except the first two characters
``````

Here’s a useful invariant of slice operations: `s[:i] + s[i:]` equals `s`.

For non-negative indices, the length of a slice is the difference of the indices, if both are within bounds. For example, the length of `word[1:3]` is `2`.

I think we can assume that the range functions act the same for consistency.

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A bit late to this question, nonetheless, this attempts to answer the why-part of your question:

Part of the reason is because we use zero-based indexing/offsets when addressing memory.

The easiest example is an array. Think of an "array of 6 items" as a location to store 6 data items. If this array's start location is at memory address 100, then data, let's say the 6 characters 'apple\0', are stored like this:

``````memory/
array      contains
location   data
100   ->   'a'
101   ->   'p'
102   ->   'p'
103   ->   'l'
104   ->   'e'
105   ->   '0'
``````

So for 6 items, our index goes from 100 to 105. Addresses are generated using base + offset, so the first item is at base memory location 100 + offest 0 (i.e., 100 + 0), the second at 100 + 1, third at 100 + 2 .. until 100 + 5 is the last location.

This is the primary reason we use zero based indexing and leads to language constructs such as for loops in C

``````for (int i = 0; i < LIMIT; i++)
``````

or in Python

``````for i in range(LIMIT):
``````

When you program in a language like C where you deal with pointers more directly, or assembly even more so, this base+offset scheme becomes much more obvious.

Because of the above, many language constructs automatically use this range from start to length-1.

You might find this article on Zero-based numbering on Wikipedia interesting, and also this question from Programmers SE.

Example:

In C for instance if you have an array `ar` and you subscript it as `ar[3]` that really is equivalent to taking the (base) address of array `ar` and adding `3` to it => `*(ar+3)` which can lead to code like this printing the contents of an array, showing the simple base+offset approach:

``````for(i = 0; i < 5; i++)
printf("%c\n", *(ar + i));
``````

really equivalent to

``````for(i = 0; i < 5; i++)
printf("%c\n", ar[i]);
``````
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