# Why is −1 > sizeof(int)?

Consider the following code:

``````template<bool> class StaticAssert;
template<> class StaticAssert<true> {};
StaticAssert< (-1 < sizeof(int)) > xyz1; // Compile error
StaticAssert< (-1 > sizeof(int)) > xyz2; // OK
``````

Why is `-1 > sizeof(int)` true?

1. Is it true that `-1` is promoted to `unsigned(-1)` and then `unsigned(-1) > sizeof(int)`.
2. Is it true that `-1 > sizeof(int)` is equivalent to `-1 > size_t(4)` if sizeof(int) is 4. If this is so why `-1 > size_t(4)` is false?

Is this C++ standard comformant?

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The following is how standard (ISO 14882) explains abort -1 > sizeof(int)

Relational operator `>' is defined in 5.9 (expr.rel/2)

The usual arithmetic conversions are performed on operands of arithmetic or enumeration type. ...

The usual arithmetic conversions is defined in 5 (expr/9)

... The pattern is called the usual arithmetic conversions, which are defined as following:

• If either operand is of type long double, ...
• Otherwise, if either operand is dobule, ...
• Otherwise, if either operand is float, ...
• Otherwise, the integral promotions shall be performed on both operands.
• ...

The integral promotions is defined in 4.5 (conv.prom/1)

An rvalue of type char, signed char, unsigned char, short int, or unsigned short int can be converted to an rvalue of type int if int can represent all the values of the source type; otherwise, the source rvalue can be converted to an rvalue of type unsigned int.

The result of sizeof is defined in 5.3.3 (expr.sizeof/6)

The result is a constant of type size_t

size_t is defined in C standard (ISO 9899), which is unsigned integer type.

So for `-1 > sizeof(int)`, the > triggers usual arithmetic conversions. The usual arithmetic conversion converts -1 to unsigned int because int cannot represent all the value of `size_t`. `-1` becomes a very large number depend on platform. So `-1 > sizeof(int)` is `true`.

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It could just be a typo but `size_t` is an unsigned integer type and it doesn't have to be the case that `int` can't represent all the values of `size_t` (`size_t` might be `unsigned short`), although it obviously can't on the question asker's platform. –  Charles Bailey Jun 23 '10 at 11:03
`(unsigned T)-1` isn't just a large value, it's the largest value `unsigned T` can hold. –  GManNickG Jun 23 '10 at 23:22
I'm well aware what the standard allows. :) -1 is always the largest, read the conversion rules. Or this stackoverflow.com/questions/809227/… –  GManNickG Jun 25 '10 at 15:29
@GMan Thank for your help. I misunderstood the description in standard. (Remove wrong comment) –  czchen Jul 2 '10 at 1:21

Because unsigned is stronger then signed and -1 converted to unsigned value as of `size_t` , so actually `-1 == 0xFFFFFFFF > 4`

This is how it should work according to C++ standard

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doesn't compilers issue warnings for such cases ? –  kriss Jun 23 '10 at 9:32
this doesn't explain why -1 < (size_t) 4, sizeof should use return type size_t.. –  Anders Westrup Jun 23 '10 at 9:35
@kriss - Different compilers issue different warnings. Also warnings can be supressed via compiler command-line options, and/or by pragmas in the source code; and/or then can be ignored by the programmer. –  ChrisW Jun 23 '10 at 9:36
Is this C++ standard comformant? –  Alexey Malistov Jun 23 '10 at 10:25
@rubenvb: Doesn't matter: `unsigned(-1) == UINT_MAX` per the standard, everywhere. –  MSalters Jun 23 '10 at 14:13

because -1 gets casted to size_t and this is an unsigned datatype - so (size_t)-1 == 4294967295 (on a 32bit system) which is definitly larger than 4

if you add -Wall to the gcc settings for example you get a warning that you are comparing a signed and an unsigned datatype

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It's simple and sad. In C/C++:

1. most of the time, unsigned integer types have the semantic of modular integers (they represent equivalence classes)
2. comparisons of unsigned integer types have the semantic of usual integer ordering, so that `1U < 2U` (IOW `0U` is the smallest `unsigned` value)
3. `sizeof` has type `size_t`
4. `size_t` is an unsigned integer type
5. Point (1) implies that mixed arithmetic computations involving a signed and an unsigned integer are done in unsigned, modular arithmetic: this is the only possibility without violating "unsigned mean modular" rule. It's trivial to convert an integer to the equivalence class of integers equivalent to it. (Whereas going the other way requires the choice of an integer to represent the equivalence class.)
6. Point (5) implies that `-1 < 1U` is interpreted as `unsigned(-1) < 1U`, and `unsigned(-1)` = `- 1U`, and obviously `- 1U < 1U`, so `-1 < 1U` is true.
7. Points (1,3,4) imply that `sizeof something` acts (mostly) as an equivalent class (!!!).
8. All this imply that `-1 < sizeof something`

The conclusion: this is a design error inherited from C.

Rule:

Only use unsigned types for modular arithmetic, bits manipulations (`&`, `|`, `^`, `<<`, `>>`, `~` operators), byte manipulations (`unsigned char` means "byte" in C/C++), and characters (`unsigned char` means character in C/C++).

Do not use unsigned types to do arithmetic.

If a function expects an integer value that should never be negative, take a signed integer, and optionally check in the function that the value is in range.

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It's nothing to do with 64-bit, it only matters which unsigned type `size_t` actually is and which conversion rules for expressions actualy apply. If, as in most implementations, `size_t` is as wide as an `int` (it doesn't need to be wider) then both sides of the expression must be converted to the unsigned type. –  Charles Bailey Jun 23 '10 at 10:00
@Charles: What do you mean it doesn't need to be wider than `int`? It's perfectly feasible that `size_t` is an unsigned 64-bit type on a 64-bit system, because `sizeof(some_really_huge_array)` might easily exceed 4GB on such a system. –  FredOverflow Jun 23 '10 at 10:03
Also, if you are comparing a narrower signed type to a wider unsigned type there are no cases where the signed equivalent of the wider type would be used, both operands would be converted to the wide unsigned type if the wide unsigned type is at least `unsigned int` or to a signed type of even greater size if `int` is actually wider than 64-bits. –  Charles Bailey Jun 23 '10 at 10:05
I mean that if `size_t` is actually `unsigned int` then both operands are converted to `unsigned int` in `-1 > size_t(4)`. Your answer seemed to imply that it matters that `size_t` is strictly wider than `int` for the comparison to return true. –  Charles Bailey Jun 23 '10 at 10:09