Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

In C++, sizeof('a') == sizeof(char) == 1. This makes intuitive sense, since 'a' is a character literal, and sizeof(char) == 1 as defined by the standard.

In C however, sizeof('a') == sizeof(int). That is, it appears that C character literals are actually integers. Does anyone know why? I can find plenty of mentions of this C quirk but no explanation for why it exists.

share|improve this question
    
sizeof would just return the size of a byte wouldn't it? Aren't a char and an int equal in size? –  Josh Smeaton Jan 11 '09 at 23:13
    
This is probably compiler (and architecture) dependent. Care to say what you're using? The standard (at least up to '89) was very loose. –  dmckee Jan 11 '09 at 23:14
1  
no. a char is always 1 byte large, so sizeof('a') == 1 always (in c++), while an int can theoretically be sizeof of 1, but that would require a byte having at least 16bits, which is very unlikely :) so sizeof('a') != sizeof(int) is very likely in C++ in most implementations –  Johannes Schaub - litb Jan 11 '09 at 23:30
2  
... while it's always wrong in C. –  Johannes Schaub - litb Jan 11 '09 at 23:31
14  
'a' is an int in C - period. C got there first - C made the rules. C++ changed the rules. You can argue that the C++ rules make more sense, but changing the C rules would do more damage than good, so the C standard committee wisely hasn't touched this. –  Jonathan Leffler Jan 12 '09 at 1:12

11 Answers 11

up vote 22 down vote accepted

discussion on same subject

"More specifically the integral promotions. In K&R C it was virtually (?) impossible to use a character value without it being promoted to int first, so making character constant int in the first place eliminated that step. There were and still are multi character constants such as 'abcd' or however many will fit in an int."

share|improve this answer
    
Multi-character constants are not portable, even between compilers on a single machine (though GCC seems to be self-consistent across platforms). See: stackoverflow.com/questions/328215 –  Jonathan Leffler Jan 12 '09 at 1:10
3  
I would note that a) This quotation is unattributed; the citation merely says "Would you disagree with this opinion, which was posted in a past thread discussing the issue in question?" ... and b) It is ludicrous, because a char variable is not an int, so making a character constant be one is a special case. And it's easy to use a character value without promoting it: c1 = c2;. OTOH, c1 = 'x' is a downward conversion. Most importantly, sizeof(char) != sizeof('x'), which is serious language botch. As for multibyte character constants: they're the reason, but they're obsolete. –  Jim Balter Mar 16 '11 at 13:02

I don't know the specific reasons why a character literal in C is of type int. But in C++, there is a good reason not to go that way. Consider this:

void print(int);
void print(char);

print('a');

You would expect that the call to print selects the second version taking a char. Having a character literal being an int would make that impossible. Note that in C++ literals having more than one character still have type int, although their value is implementation defined. So, 'ab' has type int, while 'a' has type char.

share|improve this answer
    
Yes, "Design and Evolution of C++" says overloaded input/output routines were the main reason C++ changed the rules. –  Max Lybbert Jan 12 '09 at 8:25
1  
Max, yeah i cheated. i looked in the standard in the compatibility section :) –  Johannes Schaub - litb Jan 12 '09 at 10:55

using gcc on my MacBook, I try:

#include <stdio.h>
#define test(A) do{printf(#A":\t%i\n",sizeof(A));}while(0)
int main(void){
  test('a');
  test("a");
  test("");
  test(char);
  test(short);
  test(int);
  test(long);
  test((char)0x0);
  test((short)0x0);
  test((int)0x0);
  test((long)0x0);
  return 0;
};

which when run gives:

'a':    4
"a":    2
"":     1
char:   1
short:  2
int:    4
long:   4
(char)0x0:      1
(short)0x0:     2
(int)0x0:       4
(long)0x0:      4

which suggests that a character is 8 bits, like you suspect, but a character literal is an int.

share|improve this answer
5  
+1 for being interesting. People often think that sizeof("a") and sizeof("") are char*'s and should give 4 (or 8). But in fact they're char[]'s at that point (sizeof(char[11]) gives 11). A trap for newbies. –  paxdiablo Jan 12 '09 at 1:32
3  
A character literal is not promoted to an int, it is already an int. There is no promotion going on whatsoever if the object is an operand of the sizeof operator. If there was, this would defeat sizeof's purpose. –  Chris Young Jan 12 '09 at 3:40
    
@Chris Young: Ya. Check. Thanks. –  dmckee Jan 12 '09 at 3:50

I remember reading K&R and seeing a code snippet that would read a character at a time until it hit EOF. Since all characters are valid characters to be in a file/input stream, this means that EOF cannot be any char value. What the code did was to put the read character into an int, then test for EOF, then convert to a char if it wasn't.

I realize this doesn't exactly answer your question, but it would make some sense for the rest of the character literals to be sizeof(int) if the EOF literal was.

int r;
char buffer[1024], *p; // don't use in production - buffer overflow likely
p = buffer;

while ((r = getc(file)) != EOF)
{
  *(p++) = (char) r;
}
share|improve this answer
    
I don't think 0 is a valid character though. –  gbjbaanb Jan 11 '09 at 22:56
3  
@gbjbaanb: Sure it is. It's the null character. Think about it. Do you think a file shouldn't be allowed to contain any zero bytes? –  P Daddy Jan 11 '09 at 23:00
1  
Read wikipedia - "The actual value of EOF is a system-dependent negative number, commonly -1, which is guaranteed to be unequal to any valid character code." –  Malx Jan 11 '09 at 23:22
1  
As Malx says - EOF is not a char type - it's an int type. getchar() and friends return an int, which can hold any char as well as EOF without conflict. This would really not require literal chars to have type int. –  Michael Burr Jan 12 '09 at 0:00
1  
EOF == -1 came long after C's character constants, so this is not an answer and not even relevant. –  Jim Balter Mar 16 '11 at 13:04

Back when C was being written, the PDP-11's MACRO-11 assembly language had:

MOV #'A, R0      // 8-bit character encoding for 'A' into 16 bit register

This kind of thing's quite common in assembly language - the low 8 bits will hold the character code, other bits cleared to 0. PDP-11 even had:

MOV #"AB, R0     // 16-bit character encoding for 'A' (low byte) and 'B'

This provided a convenient way to load two characters into the low and high bytes of the 16 bit register. You might then write those elsewhere, updating some textual data or screen memory.

So, the idea of characters being promoted to register size is quite normal and desirable. But, let's say you need to get 'A' into a register not as part of the hard-coded opcode, but from somewhere in main memory containing:

address: value
20: 'X'
21: 'A'
22: 'A'
23: 'X'
24: 0
25: 'A'
26: 'A'
27: 0
28: 'A'

If you want to read just an 'A' from this main memory into a register, which one would you read?

  • Some CPUs may only directly support reading a 16 bit value into a 16 bit register, which would mean a read at 20 or 22 would then require the bits from 'X' be cleared out, and depending on the endianness of the CPU one or other would need shifting into the low order byte.

  • Some CPUs may require a memory-aligned read, which means that the lowest address involved must be a multiple of the data size: you might be able to read from addresses 24 and 25, but not 27 and 28.

So, a compiler generating code to get an 'A' into the register may prefer to waste a little extra memory and encode the value as 0 'A' or 'A' 0 - depending on endianness, and also ensuring it is aligned properly (i.e. not at an odd memory address).

My guess is that C's simply carried this level of CPU-centric behaviour over, thinking of character constants occupying register sizes of memory, bearing out the common assessment of C as a "high level assembler".

(See 6.3.3 on page 6-25 of http://www.dmv.net/dec/pdf/macro.pdf)

share|improve this answer

I haven't seen a rationale for it (C char literals being int types), but here's something Stroustrup had to say about it (from Design and Evolution 11.2.1 - Fine-Grain Resolution):

In C, the type of a character literal such as 'a' is int. Surprisingly, giving 'a' type char in C++ doesn't cause any compatibility problems. Except for the pathological example sizeof('a'), every construct that can be expressed in both C and C++ gives the same result.

So for the most part, it should cause no problems.

share|improve this answer
    
Interesting! Kinda contradicts what others were saying about how the C standards committee "wisely" decided not to remove this quirk from C. –  j_random_hacker Jan 12 '09 at 8:42

The original question is "why?"

The reason is that the definition of a literal character has evolved and changed, while trying to remain backwards compatible with existing code.

In the dark days of early C there were no types at all. By the time I first learnt to program in C, types had been introduced, but functions didn't have prototypes to tell the caller what the argument types were. Instead it was standardised that everything passed as a parameter would either be the size of an int (this included all pointers) or it would be a double.

This meant that when you were writing the function, all the parameters that weren't double were stored on the stack as ints, no matter how you declared them, and the compiler put code in the function to handle this for you.

This made things somewhat inconsistent, so when K&R wrote their famous book, they put in the rule that a character literal would always be promoted to an int in any expression, not just a function parameter.

When the ANSI committee first standardised C, they changed this rule so that a character literal would simply be an int, since this seemed a simpler way of achieving the same thing.

When C++ was being designed, all functions were required to have full prototypes (this is still not required in C, although it is universally accepted as good practice). Because of this, it was decided that a character literal could be stored in a char. The advantage of this in C++ is that a function with a char parameter and a function with an int parameter have different signatures. This advantage is not the case in C.

This is why they are different. Evolution...

share|improve this answer

I don't know, but I'm going to guess it was easier to implement it that way and it didn't really matter. It wasn't until C++ when the type could determine which function would get called that it needed to be fixed.

share|improve this answer

I didn't know this indeed. Before prototypes existed, anything narrower than an int was converted to an int when using it as a function argument. That may be part of the explanation.

share|improve this answer
1  
Another poor "answer". Automatic conversion of char to int would make it quite unnecessary for character constants to be ints. What's relevant is that the language treats character constants differently (by giving them a different type) from char variables, and what's needed is an explanation of that difference. –  Jim Balter Mar 16 '11 at 13:10
    
Thanks for the explanation you gave below. You might want to describe your explanation more fully in an answer, where it belongs, can be up-voted, and easily seen by visitors. Also, I never said I had a good answer here. Therefore your value judgement is of no help. –  Blaisorblade Mar 23 '11 at 22:43

This is the correct behavior, called "integral promotion". It can happen in other cases too (mainly binary operators, if I remember correctly).

EDIT: Just to be sure, I checked my copy of Expert C Programming: Deep Secrets, and I confirmed that a char literal does not start with a type int. It is initially of type char but when it is used in an expression, it is promoted to an int. The following is quoted from the book:

Character literals have type int and they get there by following the rules for promotion from type char. This is too briefly covered in K&R 1, on page 39 where it says:

Every char in an expression is converted into an int....Notice that all float's in an expression are converted to double....Since a function argument is an expression, type conversions also take place when arguments are passed to functions: in particular, char and short become int, float becomes double.

share|improve this answer
    
If the other comments are to be believed, the expression 'a' starts out with type int -- no type promotion is performed inside of a sizeof(). That 'a' has type int is just a quirk of C it seems. –  j_random_hacker Jan 12 '09 at 8:41
2  
A char literal does have type int. The ANSI/ISO 99 standard calls them 'integer character constants' (to differentiate them from 'wide character constants', which have type wchar_t) and specifically says, "An integer character constant has type int." –  Michael Burr Jan 12 '09 at 16:49
    
What I meant was that it does not start with type int, but rather converted to an int from char (answer edited). Of course, this probably does not concern anyone except compiler writers since the conversion is always done. –  PolyThinker Jan 13 '09 at 1:40
2  
No! If you read the ANSI/ISO 99 C standard you will find that in C, the expression 'a' starts with type int. If you have a function void f(int) and a variable char c, then f(c) will perform integral promotion, but f('a') won't as the type of 'a' is already int. Strange but true. –  j_random_hacker Jan 15 '09 at 15:35
1  
"Just to be sure" -- You could be more sure by actually reading the statement: "Character literals have type int". "I can only assume that was one of the silent changes" -- you assume wrongly. Character literals in C have always been of type int. –  Jim Balter Mar 16 '11 at 13:15

This is only tangential to the language spec, but in hardware the CPU usually only has one register size -- 32 bits, let's say -- and so whenever it actually works on a char (by adding, subtracting, or comparing it) there is an implicit conversion to int when it is loaded into the register. The compiler takes care of properly masking and shifting the number after each operation so that if you add, say, 2 to (unsigned char) 254, it'll wrap around to 0 instead of 256, but inside the silicon it is really an int until you save it back to memory.

It's sort of an academic point because the language could have specified an 8-bit literal type anyway, but in this case the language spec happens to reflect more closely what the CPU is really doing.

(x86 wonks may note that there is eg a native addh op that adds the short-wide registers in one step, but inside the RISC core this translates to two steps: add the numbers, then extend sign, like an add/extsh pair on the PowerPC)

share|improve this answer
    
Yet another wrong answer. The issue here is why character literals and char variables have different types. Automatic promotions, which reflect the hardware, aren't relevant -- they're actually anti-relevant, because char variables are automatically promoted so that's no reason for character literals not to be of type char. The real reason is multibyte literals, which are now obsolete. –  Jim Balter Mar 16 '11 at 13:23
    
@Jim Balter Multibyte literals aren't obsolete at all; there's multibyte Unicode and UTF characters. –  Crashworks Mar 16 '11 at 20:51
    
@Crashworks We're talking about multibyte character literals, not multibyte string literals. Do try to pay attention. –  Jim Balter Mar 17 '11 at 3:36
3  
Chrashworks did write characters. You should have written that wide character literals (say L'à') do take more bytes but are not called multibyte char literals. Being less arrogant would help you to be more accurate yourself. –  Blaisorblade Mar 23 '11 at 23:00
    
@Blaisorblade Wide character literals aren't relevant here -- they have nothing to do with what I wrote. I was accurate and you lack comprehension and your bogus attempt to correct me is what's arrogant. –  Jim Balter Mar 26 '11 at 13:33

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.