# Why prefer start + (end - start) / 2 over (start + end) / 2 when calculating the middle of an array?

I've seen programmers use the formula

``````mid = start + (end - start) / 2
``````

instead of using the simpler formula

``````mid = (start + end) / 2
``````

for finding the middle element in the array or list.

Why do they use the former one?

• Wild guess: `(start + end)` might overflow, while `(end - start)` cannot. – cadaniluk Jul 31 '16 at 20:15
• because latter does not work when `start` and `end` are pointer. – ensc Jul 31 '16 at 20:20
• `start + (end - start) / 2` also carries semantic meaning: `(end - start)` is the length, so this says: `start + half the length`. – njzk2 Aug 1 '16 at 2:16
• @LưuVĩnhPhúc: Doesn't this question have the best answers and the most votes? If so, the other questions should probably be closed as a dup of this one. The age of the posts are irrelevant. – Nisse Engström Aug 2 '16 at 12:08

There are three reasons.

First of all, `start + (end - start) / 2` works even if you are using pointers, as long as `end - start` doesn't overflow1.

``````int *start = ..., *end = ...;
int *mid = start + (end - start) / 2; // works as expected
int *mid = (start + end) / 2;         // type error, won't compile
``````

Second of all, `start + (end - start) / 2` won't overflow if `start` and `end` are large positive numbers. With signed operands, overflow is undefined:

``````int start = 0x7ffffffe, end = 0x7fffffff;
int mid = start + (end - start) / 2; // works as expected
int mid = (start + end) / 2;         // overflow... undefined
``````

(Note that `end - start` may overflow, but only if `start < 0` or `end < 0`.)

Or with unsigned arithmetic, overflow is defined but gives you the wrong answer. However, for unsigned operands, `start + (end - start) / 2` will never overflow as long as `end >= start`.

``````unsigned start = 0xfffffffeu, end = 0xffffffffu;
unsigned mid = start + (end - start) / 2; // works as expected
unsigned mid = (start + end) / 2;         // mid = 0x7ffffffe
``````

Finally, you often want to round towards the `start` element.

``````int start = -3, end = 0;
int mid = start + (end - start) / 2; // -2, closer to start
int mid = (start + end) / 2;         // -1, surprise!
``````

### Footnotes

1 According to the C standard, if the result of pointer subtraction is not representable as a `ptrdiff_t`, then the behavior is undefined. However, in practice, this requires allocating a `char` array using at least half the entire address space.

• result of `(end - start)` in the `signed int` case is undefined when it overflows. – ensc Jul 31 '16 at 20:52
• Can you prove that `end-start` wont overflow? AFAIK if you take a negative `start` it should be possible to make it overflow. Sure, most of the times when you compute the average you know that values are `>= 0` ... – Bakuriu Jul 31 '16 at 21:28
• @Bakuriu: It's impossible to prove something which is not true. – Dietrich Epp Jul 31 '16 at 23:07
• It's of particular interest in C, since pointer subtraction (per the standard) is broken by design. Implementations are permitted to create arrays so big that `end - start` is undefined, because object sizes are unsigned whereas pointer differences are signed. So `end - start` "works even using pointers", provided you also somehow keep the size of the array below `PTRDIFF_MAX`. To be fair to the standard, that's not much of an obstruction on most architectures since that's half the size of the memory map. – Steve Jessop Aug 1 '16 at 11:03
• @Bakuriu: By the way, there is an "edit" button on the post you can use to suggest changes (or make them yourself) if you think I've missed something, or something is unclear. I'm only human, and this post has been seen by over two thousand pairs of eyeballs. The kind of comment, "You should clarify..." really rubs me the wrong way. – Dietrich Epp Aug 1 '16 at 14:02

We can take a simple example to demonstrate this fact. Suppose in a certain large array, we are trying to find the midpoint of the range `[1000, INT_MAX]`. Now, `INT_MAX` is the largest value the `int` data type can store. Even if `1` is added to this, the final value will become negative.

Also, `start = 1000` and `end = INT_MAX`.

Using the formula: `(start + end)/2`,

the mid-point will be

`(1000 + INT_MAX)/2` = `-(INT_MAX+999)/2`, which is negative and may give segmentation fault if we try to index using this value.

But, using the formula, `(start + (end-start)/2)`, we get:

`(1000 + (INT_MAX-1000)/2)` = `(1000 + INT_MAX/2 - 500)` = `(INT_MAX/2 + 500)` which will not overflow.

• If you add 1 to `INT_MAX`, the result will not be negative, but undefined. – celtschk Aug 1 '16 at 21:46
• @celtschk Theoretically, yes. Practically it will wrap-around a lot of the times going from `INT_MAX` to `-INT_MAX`. It's a bad habit to rely upon that though. – Mast Aug 2 '16 at 9:46

To add to what others have already said, the first one explains its meaning clearer to those less mathematically minded:

``````mid = start + (end - start) / 2
``````

mid equals start plus half of the length.

whereas:

``````mid = (start + end) / 2
``````

mid equals half of start plus end

Which does not seem as clear as the first, at least when expressed like that.

as Kos pointed out it can also read:

mid equals the average of start and end

Which is clearer but still not, at least in my opinion, as clear as the first.

• I see your point, but this really is a stretch. If you see "e - s" and think "length" then you almost surely see "(s+e)/2" and think "average" or "mid." – djechlin Aug 1 '16 at 22:57
• @djechlin Programmers are poor at math. They are busy doing their work. They have no time to attend the math classes. – Little Alien Aug 2 '16 at 5:01

start + (end-start) / 2 can avoid possible overflow, for example start = 2^20 and end = 2^30