# The real difference between "int" and "unsigned int"

int:

The 32-bit int data type can hold integer values in the range of −2,147,483,648 to 2,147,483,647. You may also refer to this data type as signed int or signed.

unsigned int :

The 32-bit unsigned int data type can hold integer values in the range of 0 to 4,294,967,295. You may also refer to this data type simply as unsigned.

Ok, but, in practice:

``````int x = 0xFFFFFFFF;
unsigned int y = 0xFFFFFFFF;
printf("%d, %d, %u, %u", x, y, x, y);
// -1, -1, 4294967295, 4294967295
``````

no difference, O.o. I'm a bit confused.

• You need to think about the binary representation of both an `int` and an `unsigned int`.
– Oded
Commented Jan 28, 2012 at 13:08
• The real reason that this can happen is that C is a weakly typed language. But `unsigned int` and `int` are really different. Commented Jan 28, 2012 at 13:13
• stackoverflow.com/questions/247873/… Commented Jan 28, 2012 at 13:18
• possible duplicate of why unsigned int 0xFFFFFFFF is equal to int -1? Commented Jan 28, 2012 at 13:18

Hehe. You have an implicit cast here, because you're telling `printf` what type to expect.

Try this on for size instead:

``````unsigned int x = 0xFFFFFFFF;
int y = 0xFFFFFFFF;

if (x < 0)
printf("one\n");
else
printf("two\n");
if (y < 0)
printf("three\n");
else
printf("four\n");
``````

Yes, because in your case they use the same representation.

The bit pattern `0xFFFFFFFF` happens to look like -1 when interpreted as a 32b signed integer and as 4294967295 when interpreted as a 32b unsigned integer.

It's the same as `char c = 65`. If you interpret it as a signed integer, it's 65. If you interpret it as a character it's `a`.

As R and pmg point out, technically it's undefined behavior to pass arguments that don't match the format specifiers. So the program could do anything (from printing random values to crashing, to printing the "right" thing, etc).

The standard points it out in `7.19.6.1-9`

If a conversion speciﬁcation is invalid, the behavior is undeﬁned. If any argument is not the correct type for the corresponding conversion speciﬁcation, the behavior is undeﬁned.

• The real reason is that he is using %u to print both. Commented Jan 28, 2012 at 13:11
• The real reason is that he invoked undefined behavior by passing a non-type-matching format string to `printf`. I almost want to downvote all the answers that are skipping this and pointing out irrelevant stuff about the representation... Commented Jan 28, 2012 at 13:33
• @R.. That's right, mismatching the format and the arguments is undefined behavior. Feel free to downvote, I won't mind :-) Commented Jan 28, 2012 at 13:33
• @R..: You're wrong, this is not undefined behaviour. See C99 section 6.5.2.2 paragraph 6. Commented Jan 28, 2012 at 13:49
• The documentation of `fprintf` is very explicit: "If any argument is not the correct type for the corresponding conversion specification, the behavior is undefined." Commented Jan 28, 2012 at 22:05

There is no difference between the two in how they are stored in memory and registers, there is no signed and unsigned version of int registers there is no signed info stored with the int, the difference only becomes relevant when you perform maths operations, there are signed and unsigned version of the maths ops built into the CPU and the signedness tell the compiler which version to use.

• This answer is the simplest one Commented Jun 17, 2016 at 20:37

The problem is that you invoked Undefined Behaviour.

When you invoke UB anything can happen.

The assignments are ok; there is an implicit conversion in the first line

``````int x = 0xFFFFFFFF;
unsigned int y = 0xFFFFFFFF;
``````

However, the call to `printf`, is not ok

``````printf("%d, %d, %u, %u", x, y, x, y);
``````

It is UB to mismatch the `%` specifier and the type of the argument.
In your case you specify 2 `int`s and 2 `unsigned int`s in this order by provide 1 `int`, 1 `unsigned int`, 1 `int`, and 1 `unsigned int`.

Don't do UB!

• -1, wrong. This is not undefined behaviour. Check out C99 section 6.5.2.2 paragraph 6. Commented Jan 28, 2012 at 13:47
• @cha0site: I specifically said the assignments are ok: section 6.5.2.2 paragraph 6 does not really apply to my answer. The UB is in the `printf` call: check 7.19.6.1: "If any argument is not the correct type for the corresponding conversion specification, the behavior is undefined". Also notice `printf` is a function taking a variable number of arguments and the conversions according to the prototype are not possible.
– pmg
Commented Jan 28, 2012 at 13:55
• C99 6.5.2.2 takes precedence over that. There's integer promotion afoot. I may have miscounted - it's possibly paragraph 5. Commented Jan 28, 2012 at 14:00
• @cha0site No it doesn't. Arguments can't be promoted to anything when the function takes a variable number of parameters. Commented Jan 28, 2012 at 14:08
• @cnicutar: What? Of course they can. That's exactly what it says there: "If the function is defined with a type that does not include a prototype, and the types of the arguments after promotion are not compatible with those of the parameters after promotion, the behavior is undefined, except for the following cases: one promoted type is a signed integer type, the other promoted type is the corresponding unsigned integer type, and the value is representable in both types;" Commented Jan 28, 2012 at 14:11

He is asking about the real difference. When you are talking about undefined behavior you are on the level of guarantee provided by language specification - it's far from reality. To understand the real difference please check this snippet (of course this is UB but it's perfectly defined on your favorite compiler):

``````#include <stdio.h>

int main()
{
int i1 = ~0;
int i2 = i1 >> 1;
unsigned u1 = ~0;
unsigned u2 = u1 >> 1;
printf("int         : %X -> %X\n", i1, i2);
printf("unsigned int: %X -> %X\n", u1, u2);
}
``````

The binary representation is the key. An Example: Unsigned int in HEX

`````` 0XFFFFFFF = translates to = 1111 1111 1111 1111 1111 1111 1111 1111
``````

Which represents `4,294,967,295` in a base-ten positive number. But we also need a way to represent negative numbers. So the brains decided on twos complement. In short, they took the leftmost bit and decided that when it is a 1 (followed by at least one other bit set to one) the number will be negative. And the leftmost bit is set to 0 the number is positive. Now let's look at what happens

``````0000 0000 0000 0000 0000 0000 0000 0011 = 3
``````

Adding to the number we finally reach.

``````0111 1111 1111 1111 1111 1111 1111 1111 = 2,147,483,645
``````

the highest positive number with a signed integer. Let's add 1 more bit (binary addition carries the overflow to the left, in this case, all bits are set to one, so we land on the leftmost bit)

``````1111 1111 1111 1111 1111 1111 1111 1111 = -1
``````

So I guess in short we could say the difference is the one allows for negative numbers the other does not. Because of the sign bit or leftmost bit or most significant bit.

The internal representation of `int` and `unsigned int` is the same.

Therefore, when you pass the same format string to `printf` it will be printed as the same.

However, there are differences when you compare them. Consider:

``````int x = 0x7FFFFFFF;
int y = 0xFFFFFFFF;
x < y // false
x > y // true
(unsigned int) x < (unsigned int y) // true
(unsigned int) x > (unsigned int y) // false
``````

This can be also a caveat, because when comparing signed and unsigned integer one of them will be implicitly casted to match the types.

The `printf` function interprets the value that you pass it according to the format specifier in a matching position. If you tell `printf` that you pass an `int`, but pass `unsigned` instead, `printf` would re-interpret one as the other, and print the results that you see.

The type just tells you what the bit pattern is supposed to represent. The bits are only what you make of them. The same sequences can be interpreted in different ways.