The code below compiles, but has different behavior for the char type than for the int types.

In particular

   cout << getIsTrue< isX<int8>::ikIsX  >() << endl;
   cout << getIsTrue< isX<uint8>::ikIsX  >() << endl;
   cout << getIsTrue< isX<char>::ikIsX  >() << endl;

result in 3 instantiations of templates for three types: int8, uint8 and char. What gives?

The same is not true for ints: int and uint32 which result in the same template instantiation, and signed int another.

The reason seems to be that C++ sees char, signed char and unsigned char as three different types. Whereas int is the same as a signed int. Is this right or am I missing something?

#include <iostream>

using namespace std;

typedef   signed char       int8;
typedef unsigned char      uint8;
typedef   signed short      int16;
typedef unsigned short     uint16;
typedef   signed int        int32;
typedef unsigned int       uint32;
typedef   signed long long  int64;
typedef unsigned long long uint64;

struct TrueType {};
struct FalseType {};

template <typename T>
struct isX
   typedef typename T::ikIsX ikIsX;

// This  int==int32 is ambiguous
//template <>            struct isX<int  >    { typedef FalseType ikIsX; };  // Fails
template <>            struct isX<int32  >  { typedef FalseType ikIsX; };
template <>            struct isX<uint32 >  { typedef FalseType ikIsX; };

// Whay isn't this ambiguous? char==int8
template <>            struct isX<char  >  { typedef FalseType ikIsX; };
template <>            struct isX<int8  >  { typedef FalseType ikIsX; };
template <>            struct isX<uint8 >  { typedef FalseType ikIsX; };

template <typename T> bool getIsTrue();
template <>           bool getIsTrue<TrueType>() { return true; }
template <>           bool getIsTrue<FalseType>() { return false; }

int main(int, char **t )
   cout << sizeof(int8) << endl;  // 1
   cout << sizeof(uint8) << endl; // 1
   cout << sizeof(char) << endl;  // 1

   cout << getIsTrue< isX<int8>::ikIsX  >() << endl;
   cout << getIsTrue< isX<uint8>::ikIsX  >() << endl;
   cout << getIsTrue< isX<char>::ikIsX  >() << endl;

   cout << getIsTrue< isX<int32>::ikIsX  >() << endl;
   cout << getIsTrue< isX<uint32>::ikIsX  >() << endl;
   cout << getIsTrue< isX<int>::ikIsX  >() << endl;


I'm using g++ 4.something

  • 1
    You should also note that there is no guarantee that int8_t is going to be a signed char and uint8_t is going to be an unsigned char. In particular, on Solaris int8_t is just char if char is signed. In other words, your code will fail to compile there. – Michał Górny Oct 11 '16 at 15:05
  • 1
    "int and uint32 which result in the same template instantiation, and signed int another" this should definitely be the other way around as int is signed. – Felix Dombek Mar 7 '18 at 13:24

Here is your answer from the standard:

3.9.1 Fundamental types [basic.fundamental]

Objects declared as characters (char) shall be large enough to store any member of the implementation's basic character set. If a character from this set is stored in a character object, the integral value of that character object is equal to the value of the single character literal form of that character. It is implementation-defined whether a char object can hold negative values. Characters can be explicitly declared unsigned or signed. Plain char, signed char, and unsigned char are three distinct types. A char, a signed char, and an unsigned char occupy the same amount of storage and have the same alignment requirements (basic.types); that is, they have the same object representation. For character types, all bits of the object representation participate in the value representation. For unsigned character types, all possible bit patterns of the value representation represent numbers. These requirements do not hold for other types. In any particular implementation, a plain char object can take on either the same values as a signed char or an unsigned char; which one is implementation-defined.

| improve this answer | |

While most integral types like short and int default to being signed, char does not have a default signage in C++.

It is neither the type signed char nor unsigned char, so implementations may decide whether it is signed.

It's a common mistake that C++ programmers run into when they use char as an 8 bit integer type.

| improve this answer | |
  • 2
    +1 because you very succinctly explain the differences in the data types and imply how they should be used by comparison. – Joshua Detwiler Jun 23 '17 at 13:31
  • 1
    Historical footnote: I heard this was because early versions of C didn't specify the signedness of char, so different compilers did different things, and then the standard preserved this behavior so that old code would keep working on their same compilers. – Mooing Duck Sep 29 at 18:31

For questions such as this, i like to look into the Rationale document for C, which often provides answers to C++ mysteries as well, that sometimes arise for me when reading the Standard. It has this to say about it:

Three types of char are specified: signed, plain, and unsigned. A plain char may be represented as either signed or unsigned, depending upon the implementation, as in prior practice. The type signed char was introduced to make available a one-byte signed integer type on those systems which implement plain char as unsigned. For reasons of symmetry, the keyword signed is allowed as part of the type name of other integral types.

Rationale for C

| improve this answer | |
  • So, why do we need signed char? Just in order to use it to represent a one-byte signed integer? – Alcott Aug 16 '12 at 1:46
  • 3
    @Alcott i think char might be signed, or might be unsigned, which is implementation defined, but signed char is always signed, and unsigned char is always unsigned, if you want to be sure/explicit of the type – hanshenrik Aug 8 '17 at 16:15

that's correct, char, unsigned char and signed char are separate types. It probably would have been nice if char was just a synonym for either signed char or unsigned char depending on your compilers implementation, but the standard says they are separate types.

| improve this answer | |

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