The problem is that `-2147483648`

is not an integer literal. It's an expression consisting of the unary negation operator `-`

and the integer `2147483648`

, which is too big to be an `int`

if `int`

s are 32 bits. Since the compiler will choose an appropriately-sized signed integer to represent `2147483648`

before applying the negation operator, the type of the result will be larger than an `int`

.

If you know that your `int`

s are 32 bits, and want to avoid the warning without mutilating readability, use an explicit cast:

```
printf("PRINTF(d) \t: %d\n", (int)(-2147483648));
```

That's defined behaviour on a 2's complement machine with 32-bit `int`

s.

For increased theoretical portability, use `INT_MIN`

instead of the number, and let us know where you found a non-2's-complement machine to test it on.

To be clear, that last paragraph was partly a joke. `INT_MIN`

is definitely the way to go if you mean "the smallest `int`

", because `int`

varies in size. There are still lots of 16-bit implementations, for example. Writing out -2^{31} is only useful if you definitely always mean precisely that value, in which case you would probably use a fixed-sized type like `int32_t`

instead of `int`

.

You might want some alternative to writing out the number in decimal to make it clearer for those who might not notice the difference between `2147483648`

and `2174483648`

, but you need to be careful.

As mentioned above, on a 32-bit 2's-complement machine, `(int)(-2147483648)`

will not overflow and is therefore well-defined, because `-2147483648`

will be treate as a wider signed type. However, the same is not true for `(int)(-0x80000000)`

. `0x80000000`

will be treated as an `unsigned int`

(since it fits into the unsigned representation); `-0x80000000`

is well-defined (but the `-`

has no effect if `int`

is 32 bits), and the conversion of the resulting `unsigned int`

`0x80000000`

to `int`

involves an overflow. To avoid the overflow, you would need to cast the hex constant to a signed type: `(int)(-(long long)(0x80000000))`

.

Similarly, you need to take care if you want to use the left shift operator. `1<<31`

is undefined behaviour on 32-bit machines with 32-bit (or smaller) `int`

s; it will only evaluate to 2^{31} if `int`

is at least 33 bits, because left shift by `k`

bits is only well-defined if `k`

is strictly less than the number of non-sign bits of the integer type of the left-hand argument.

`1LL<<31`

is safe, since `long long int`

is required to be able to represent 2^{63}-1, so its bit size must be greater than 32. So the form

```
(int)(-(1LL<<31))
```

is possibly the most readable. YMMV.

For any passing pedants, this question is tagged C, and the latest C draft (n1570.pdf) says, with respect to `E1 << E2`

, where `E1`

has a signed type, that the value is defined only if `E1`

is nonnegative and `E1 × 2`^{E2}

"is representable in the result type". (§6.5.7 para 4).

That's different from C++, in which the application of the left-shift operator is defined if `E1`

is nonnegative and `E1 × 2`^{E2}

"is representable
*in the corresponding unsigned type* of the result type" (§5.8 para. 2, emphasis added).

In C++, according to the most recent draft standard, the conversion of an integer value to a signed integer type is *implementation-defined* if the value cannot be represented in the destination type (§4.7 para. 3). The corresponding paragraph of the C standard -- §6.3.1.3 para. 3 -- says that "either the result is implementation-defined or an implementation-defined signal is raised".)

`va_arg()`

doesn't know what type the argument you try to fetch has. You need to know that and if you try to fetch a different type than what was passed as an argument, that's undefined behaviour. This also applies if you do`printf("%d\n", -2147483648)`

as the argument has type`long`

but`printf`

tries to fetch an`int`

.they specified the literal in hex, which means it's unsigned int rather than signed long.That can be read as "hex constants are always unsigned". Old pre-standard C compilers often made hex constants unsigned, so that might be confusing. Per6.4.4.1 Integer constants, paragraph 5: "The type of an integer constant is the first of the corresponding list in which its value can be represented." In this case,`0x80000000`

is an`unsigned int`

here because it fits in an`unsigned int`

but is too big for`[signed] int`

.