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I do not understand why the sizeof operator is producing the following results:

sizeof( 2500000000 ) // => 8 (8 bytes).

... it returns 8, and when I do the following:

sizeof( 1250000000 * 2 ) // => 4 (4 bytes).

... it returns 4, rather than 8 (which is what I expected). Can someone clarify how sizeof determines the size of an expression (or data type) and why in my specific case this is occurring?

My best guess is that the sizeof operator is a compile-time operator.

Bounty Question: Is there a run time operator that can evaluate these expressions and produce my expected output (without casting)?

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10  
sizeof is for types, not literals, and is evaluated at compile time - why do you need to do this? –  Roger Rowland May 30 '13 at 4:35
9  
@RogerRowland what do you mean sizeof is not for literals? –  Luchian Grigore May 30 '13 at 4:37
11  
sizeof can be used on a type or on an expression. The literals are expressions; they are fine. –  Jonathan Leffler May 30 '13 at 4:40
16  
@RogerRowland it's actually common practice, and recommended, to apply sizeof to actual objects rather than classes. –  Luchian Grigore May 30 '13 at 4:40
2  
@JacobPollack: Except for variable-length arrays, every expression's size is determined at compile time. I think what you're asking is, for example, given int x = foo; int y = bar;, how big an integer type (or which integer type) do you need to store the result of multiplying x by y without overflow. There's no straightforward way do to that; C pretty much leaves that up to you. –  Keith Thompson Aug 14 '13 at 19:34

7 Answers 7

up vote 120 down vote accepted

2500000000 doesn't fit in an int, so the compiler correctly interprets it as a long (or long long, or a type where it fits). 1250000000 does, and so does 2. The parameter to sizeof isn't evaluated, so the compiler can't possibly know that the multiplication doesn't fit in an int, and so returns the size of an int.

Also, even if the parameter was evaluated, you'd likely get an overflow (and undefined behavior), but probably still resulting in 4.

Here:

#include <iostream>
int main()
{
    long long x = 1250000000 * 2;
    std::cout << x;
}

can you guess the output? If you think it's 2500000000, you'd be wrong. The type of the expression 1250000000 * 2 is int, because the operands are int and int and multiplication isn't automagically promoted to a larger data type if it doesn't fit.

http://ideone.com/4Adf97

So here, gcc says it's -1794967296, but it's undefined behavior, so that could be any number. This number does fit into an int.

In addition, if you cast one of the operands to the expected type (much like you cast integers when dividing if you're looking for a non-integer result), you'll see this working:

#include <iostream>
int main()
{
    long long x = (long long)1250000000 * 2;
    std::cout << x;
}

yields the correct 2500000000.

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2  
Yes, for VC++, MSDN says that an expression is not evaluated - msdn.microsoft.com/en-us/library/4s7x1k91(v=vs.71).aspx –  Roger Rowland May 30 '13 at 4:40
27  
@RogerRowland most importantly, the standard says the operand of sizeof is not evaluated. –  Luchian Grigore May 30 '13 at 4:41
11  
Instead of casting, better add an LL suffix. –  Oberon May 30 '13 at 7:10
1  
@Oberon ha I see what you did there! –  Luchian Grigore May 30 '13 at 7:10
1  
I am looking for someone to cite the C99 standard for me. This is still a fantastic answer though and if no one does I will re-accept this. If you could cite a C99 standard too then I will give you the bounty and re-accept it. –  Jacob Pollack Aug 14 '13 at 19:14

[Edit: I did not notice, initially, that this was posted as both C and C++. I'm answering only with respect to C.]

Answering your followup question, "Is there anyway to determine the amount of memory allocated to an expression or variable at run time?": well, not exactly. The problem is that this is not a very well formed question.

"Expressions", in C-the-language (as opposed to some specific implementation), don't actually use any memory. (Specific implementations need some code and/or data memory to hold calculations, depending on how many results will fit into CPU registers and so on.) If an expression result is not stashed away in a variable, it simply vanishes (and the compiler can often omit the run-time code to calculate the never-saved result). The language doesn't give you a way to ask about something it doesn't assume exists, i.e., storage space for expressions.

Variables, on the other hand, do occupy storage (memory). The declaration for a variable tells the compiler how much storage to set aside. Except for C99's Variable Length Arrays, though, the storage required is determined purely at compile time, not at run time. This is why sizeof x is generally a constant-expression: the compiler can (and in fact must) determine the value of sizeof x at compile time.

C99's VLAs are a special exception to the rule:

void f(int n) {
    char buf[n];
    ...
}

The storage required for buf is not (in general) something the compiler can find at compile time, so sizeof buf is not a compile-time constant. In this case, buf actually is allocated at run time and its size is only determined then. So sizeof buf is a runtime-computed expression.

For most cases, though, everything is sized up front, at compile time, and if an expression overflows at run-time, the behavior is undefined, implementation-defined, or well-defined depending on the type. Signed integer overflow, as in 2.5 billion multiplied by 2, when INT_MAX is just a little over 2.7 billion, results in "undefined behavior". Unsigned integers do modular arithmetic and thus allow you to calculate in GF(2k).

If you want to make sure some calculation cannot overflow, that's something you have to calculate yourself, at run time. This is a big part of what makes multiprecision libraries (like gmp) hard to write in C—it's usually a lot easier, as well as faster, to code big parts of that in assembly and take advantage of known properties of the CPU (like overflow flags, or double-wide result-register-pairs).

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Interesting, didn't know C99 sizeof evaluates arrays at runtime. +1 –  Luchian Grigore May 30 '13 at 6:42
    
not all arrays, I don't believe, just ones where it can't determine the size at compile time -- where it has a variable length. –  xaxxon May 30 '13 at 7:56
    
@xaxxon: correct, only VLAs result in run-time work for sizeof. –  torek May 30 '13 at 8:03

Luchian answered it already. Just for complete it..

C11 Standard states (C++ standard has similar lines) that the type of an integer literal with no suffix to designating the type is dertermined as follows:

From 6.4.4 Constants (C11 draft):

Semantics

4 The value of a decimal constant is computed base 10; that of an octal constant, base 8; that of a hexadecimal constant, base 16. The lexically first digit is the most significant.

5 The type of an integer constant is the first of the corresponding list in which its value can be represented.

And the table is as follows:

Decimal Constant

int
int long int 
long long int

Octal or Hexadecimal Constant

int
unsigned int
long int
unsigned long int
long long int
unsigned long long int

For Octal and Hexadecimal constants, even unsigned types are possible. So depending on your platform whichever in the above list (int or long int or long long int) fits first (in the order) will be the type of integer literal.

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I really wonder what the compiler did, though, when it saw a keyword it thought it was supposed to handle immediately and replace with a constant value, but then saw an expression inside. I would expect that it would either, 1: fail to compile 2: do the math for some limited subset of expressions or 3: move to a runtime implementation of sizeof (which is apparently used for dynamic array sizes where the size is passed in as a parameter int foo[3*n+1]; sizeof(foo); in which case the multiplication would have been executed. –  xaxxon May 30 '13 at 7:55
    
Except VLAs, compiler has the size information for types. So it can determine whether an integer literal will fit in in one of the types available.As torek said in his answer, compiler is required to evaluate the operand of sizeof in case of C99 VLAs. (Btw, VLAs are made optional in C11). But compile time evaluation of size is more straight forward than that. –  Blue Moon May 30 '13 at 9:08
    
I am not sure how it exactly compiler calculates the type. For example, gcc issues a wanring for sizeof(9999999999999999999): warning: integer constant is too large for long type. I don't know exactly working of compiler how it determines the size for literals. But it checks: 1. Whether the literal has any suffix designating the type. If so, use that type to fit in. For example, sizeof(1L) will be the sizeof(long) even though literal 1 will fit in an int. –  Blue Moon May 30 '13 at 9:08
    
2. If no suffix, then follow the above order starting from int to find the size. 3. If nothing literal is too large to fit any of the types then issue a diagnostic. –  Blue Moon May 30 '13 at 9:11
1  
It's nice to cite from the C11 standard (which is in this case virtually identical to the C99 standard), but since many C programmers use either GCC or a compiler that aims to be compatible with GCC, it should be pointed out that by default, GCC does not use the list of types you cite, but instead the C90 list extended at the end with larger non-standard types: blog.frama-c.com/index.php?post/2012/01/20/Constants-quiz –  Pascal Cuoq Aug 14 '13 at 19:29

Another way to put the answer is to say that what is relevant to sizeof is not the value of the expression but it's type. sizeof returns the memory size for a type that can be provided either explicitely as a type or as an expression. In this case the compiler will compute this type at compile time without actually computing the expression (following known rules, for instance if you call a function, the resulting type is the type of the returned value).

As other poster stated there is an exception for variable length array (whose type size is only known at run time).

In other word you usually write things like sizeof(type) or sizeof expression where expression is an L-Value. Expression is almost never a complex computing (like the stupid example of calling a function above) : it would be useless anyway as it is not evaluated.

#include <stdio.h>

int main(){
    struct Stype {
            int a;
    } svar;
    printf("size=%d\n", sizeof(struct Stype));
    printf("size=%d\n", sizeof svar);
    printf("size=%d\n", sizeof svar.a);
    printf("size=%d\n", sizeof(int));

}

Also notice that as sizeof is a language keyword, not a function parenthesis are not necessary before the trailing expression (we have the same kind of rule for return keyword).

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For your follow-up question, there's no "operator", and there's no difference between the "compile time" size of an expression, and the "run time" size.

If you want to know if a given type can hold the result you're looking for, you can always try something like this:

#include <stdio.h>
#include <limits.h>

int main(void) {
    int a = 1250000000;
    int b = 2;

    if ( (INT_MAX / (double) b) > a ) {
        printf("int is big enough for %d * %d\n", a, b);
    } else {
        printf("int is not big enough for %d * %d\n", a, b);
    }

    if ( (LONG_MAX / (double) b) > a ) {
        printf("long is big enough for %d * %d\n", a, b);
    } else {
        printf("long is not big enough for %d * %d\n", a, b);
    }

    return 0;
}

and a (slightly) more general solution, just for larks:

#include <stdlib.h>
#include <stdio.h>
#include <limits.h>

/* 'gssim' is 'get size of signed integral multiplication */

size_t gssim(long long a, long long b);
int same_sign(long long a, long long b);

int main(void) {
    printf("size required for 127 * 1 is %zu\n", gssim(127, 1));
    printf("size required for 128 * 1 is %zu\n", gssim(128, 1));
    printf("size required for 129 * 1 is %zu\n", gssim(129, 1));
    printf("size required for 127 * -1 is %zu\n", gssim(127, -1));
    printf("size required for 128 * -1 is %zu\n", gssim(128, -1));
    printf("size required for 129 * -1 is %zu\n", gssim(129, -1));
    printf("size required for 32766 * 1 is %zu\n", gssim(32766, 1));
    printf("size required for 32767 * 1 is %zu\n", gssim(32767, 1));
    printf("size required for 32768 * 1 is %zu\n", gssim(32768, 1));
    printf("size required for -32767 * 1 is %zu\n", gssim(-32767, 1));
    printf("size required for -32768 * 1 is %zu\n", gssim(-32768, 1));
    printf("size required for -32769 * 1 is %zu\n", gssim(-32769, 1));
    printf("size required for 1000000000 * 2 is %zu\n", gssim(1000000000, 2));
    printf("size required for 1250000000 * 2 is %zu\n", gssim(1250000000, 2));

    return 0;
}

size_t gssim(long long a, long long b) {
    size_t ret_size;
    if ( same_sign(a, b) ) {
        if ( (CHAR_MAX / (long double) b) >= a ) {
            ret_size = 1;
        } else if ( (SHRT_MAX / (long double) b) >= a ) {
            ret_size = sizeof(short);
        } else if ( (INT_MAX / (long double) b) >= a ) {
            ret_size = sizeof(int);
        } else if ( (LONG_MAX / (long double) b) >= a ) {
            ret_size = sizeof(long);
        } else if ( (LLONG_MAX / (long double) b) >= a ) {
            ret_size = sizeof(long long);
        } else {
            ret_size = 0;
        }
    } else {
        if ( (SCHAR_MIN / (long double) llabs(b)) <= -llabs(a) ) {
            ret_size = 1;
        } else if ( (SHRT_MIN / (long double) llabs(b)) <= -llabs(a) ) {
            ret_size = sizeof(short);
        } else if ( (INT_MIN / (long double) llabs(b)) <= -llabs(a) ) {
            ret_size = sizeof(int);
        } else if ( (LONG_MIN / (long double) llabs(b)) <= -llabs(a) ) {
            ret_size = sizeof(long);
        } else if ( (LLONG_MIN / (long double) llabs(b)) <= -llabs(a) ) {
            ret_size = sizeof(long long);
        } else {
            ret_size = 0;
        }
    }
    return ret_size;
}

int same_sign(long long a, long long b) {
    if ( (a >= 0 && b >= 0) || (a <= 0 && b <= 0) ) {
        return 1;
    } else {
        return 0;
    }
}

which, on my system, outputs:

size required for 127 * 1 is 1
size required for 128 * 1 is 2
size required for 129 * 1 is 2
size required for 127 * -1 is 1
size required for 128 * -1 is 1
size required for 129 * -1 is 2
size required for 32766 * 1 is 2
size required for 32767 * 1 is 2
size required for 32768 * 1 is 4
size required for -32767 * 1 is 2
size required for -32768 * 1 is 2
size required for -32769 * 1 is 4
size required for 1000000000 * 2 is 4
size required for 1250000000 * 2 is 8
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Yes, sizeof() doesn't calculate the memory required for the result of that multiplication.

In the second case both literals : 1250000000 and 2 each requires 4 bytes of memory, hence sizeof() returns 4. If one of the values was above 4294967295 (2^32 - 1), you would have got 8.

But i don't know how sizeof() returned 8 for 2500000000. It returns 4 on my VS2012 compiler

share|improve this answer
    
2,5b is a long that's why. Is there anyway to determine the amount of memory allocated to an expression or variable at run time? –  Jacob Pollack May 30 '13 at 4:51
1  
@JacobPollack I already answered that. The expression 1250000000 * 2 has 4 bytes allocated to it if used in a context where allocation is necessary. And the result of the expression isn't 2500000000. –  Luchian Grigore May 30 '13 at 4:57
    
@LuchianGrigore I know. If 4 bytes is allocated, it will just overflow and give some ambiguous 4 byte integer. Thanks man. –  Jacob Pollack May 30 '13 at 4:58
    
The maximum possible 4 byte value is 4294967295. Then how come 2500000000, which is below that, requires 8 bytes memory??? –  Aravind May 30 '13 at 5:02
4  
@AravindMeppallil The signed Integer range is -2147483648 to 2147483647. The unsigned range is 0 to 4294967295. :) –  Apocalyp5e May 30 '13 at 6:31

The C11 Draft is here: http://www.open-std.org/jtc1/sc22/wg14/www/docs/n1570.pdf You can find the Cx0 draft here: http://c0x.coding-guidelines.com/6.5.3.4.html

In both cases, section 6.5.3.4 is what you are looking for. Basically, your problem boils down to this:

// Example 1:
long long x = 2500000000;
int size = sizeof(x); // returns 8

// Example 2:
int x = 1250000000;
int y = 2;
int size = sizeof(x * y); // returns 4

In example 1, you have a long long (8 bytes), so it returns 8. In example 2, you have an int * int which returns an int, which is 4 bytes (so it returns 4).

To answer your bounty question: Yes and no. sizeof will not calculate the size needed for the operation you are trying to perform, but it will tell you the size of the results if you perform the operation with the proper labels:

long long x = 1250000000;
int y = 2;
int size = sizeof(x * y); // returns 8

// Alternatively
int size = sizeof(1250000000LL * 2); // returns 8

You have to tell it you are dealing with a large number or it will assume it is dealing with the smallest type it can (which in this case is int).

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