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A common question that comes up from time to time in the world of C++ programming is compile-time determination of endianness. Usually this is done with barely portable #ifdefs. But does the C++11 constexpr keyword along with template specialization offer us a better solution to this?

Would it be legal C++11 to do something like:

constexpr bool little_endian()
   const static unsigned num = 0xAABBCCDD;
   return reinterpret_cast<const unsigned char*> (&num)[0] == 0xDD;

And then specialize a template for both endian types:

template <bool LittleEndian>
struct Foo 
  // .... specialization for little endian

template <>
struct Foo<false>
  // .... specialization for big endian

And then do:

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6 Answers 6

up vote 12 down vote accepted

Assuming N2116 is the wording that gets incorporated, then your example is ill-formed (notice that there is no concept of "legal/illegal" in C++). The proposed text for [decl.constexpr]/3 says

  • its function-body shall be a compound-statement of the form { return expression; } where expression is a potential constant expression (5.19);

Your function violates the requirement in that it also declares a local variable.

Edit: This restriction could be overcome by moving num outside of the function. The function still wouldn't be well-formed, then, because expression needs to be a potential constant expression, which is defined as

An expression is a potential constant expression if it is a constant expression when all occurrences of function parameters are replaced by arbitrary constant expressions of the appropriate type.

IOW, reinterpret_cast<const unsigned char*> (&num)[0] == 0xDD would have to be a constant expression. However, it is not: &num would be a address constant-expression (5.19/4). Accessing the value of such a pointer is, however, not allowed for a constant expression:

The subscripting operator [] and the class member access . and operators, the & and * unary operators, and pointer casts (except dynamic_casts, 5.2.7) can be used in the creation of an address constant expression, but the value of an object shall not be accessed by the use of these operators.

Edit: The above text is from C++98. Apparently, C++0x is more permissive what it allows for constant expressions. The expression involves an lvalue-to-rvalue conversion of the array reference, which is banned from constant expressions unless

it is applied to an lvalue of effective integral type that refers to a non-volatile const variable or static data member initialized with constant expressions

It's not clear to me whether (&num)[0] "refers to" a const variable, or whether only a literal num "refers to" such a variable. If (&num)[0] refers to that variable, it is then unclear whether reinterpret_cast<const unsigned char*> (&num)[0] still "refers to" num.

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I don't feel it applies, here. The static variable is constant itself. –  GManNickG Oct 18 '09 at 5:30
The wording in 4.1 of N2116 states that the body of the function must only have one statement (that being the return statement). Mind you, from my quick glance over the text, I don't see anything prohibiting the above code if num is defined globally. –  GRB Oct 18 '09 at 5:49
The last quoted paragraph does not seem to be part of the latest c++0x draft (n2960). The draft says that &num is a constant expression if num is not a variable or data-member of thread or automatic storage duration (read: if num is a local static or namespace scope variable without the "thread_local" specifier, then &num is a constant expression). However the reinterpret_cast makes it a non-constant expression, because it constitutes a conversion of pointer type to a literal type (notice that pointer types are itself literal types). –  Johannes Schaub - litb Oct 18 '09 at 15:52
No, that is not questionable. It's certain that it's not allowed. The wording is clear. –  Johannes Schaub - litb Oct 19 '09 at 2:59
And pointer types are scalar types. :) BTW i think you are being confused by the above (&num)[0] too: In the code, he never does (&num)[0]. He is doing (reinterpret_cast<...>(&num))[0]. So you have to first consider the reinterpret_cast, and then it is result_of_reinterpret_cast[0]. Your last paragraph indicates that you get the binding of it wrong, which is quite confusing to readers. –  Johannes Schaub - litb Oct 19 '09 at 13:42

That is a very interesting question.

I am not Language Lawyer, but you might be able to replace the reinterpret_cast with a union.

const union {
    int int_value;
    char char_value[4];
} Endian = { 0xAABBCCDD };

constexpr bool little_endian()
   return Endian[0] == 0xDD;
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Placing a value in a union then accessing the union via another member is not valid. –  GManNickG Oct 18 '09 at 20:41
@GMan: It is well-formed, but invokes undefined behavior. "valid" is not a property defined in the C++ standard. –  Martin v. Löwis Oct 18 '09 at 21:02
Yea, threw my own terminology in there. Thanks for pointing out the correct terms. –  GManNickG Oct 19 '09 at 8:45
@Martin: Exactly what § of the standard says it invokes undefined behaviour? A char lvalue may certainly alias (part of) an int object. Also, all possible bit patterns represent valid char and unsigned char values as far as I can tell. This leads me to believe this is just invokes implementation-defined behaviour and not UB. –  sellibitze Oct 19 '09 at 17:08
@sellibitze: aliasing pointers with char* would be fine, but not via a union. –  Mooing Duck May 21 '12 at 19:11

It is not possible to determine endianness at compile time using constexpr. reinterpret_cast is explicitly forbidden by [expr.const]p2, as is iain's suggestion of reading from a non-active member of a union.

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++ .. I came to this after looking at this question. –  Shafik Yaghmour Nov 21 at 3:58

This may seem like cheating, but you can always include endian.h... BYTE_ORDER == BIG_ENDIAN is a valid constexpr...

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I was able to write this:

#include <cstdint>

class Endian
    static constexpr uint32_t uint32_ = 0x01020304;
    static constexpr uint8_t magic_ = (const uint8_t&)uint32_;
    static constexpr bool little = magic_ == 0x04;
    static constexpr bool middle = magic_ == 0x02;
    static constexpr bool big = magic_ == 0x01;
    static_assert(little || middle || big, "Cannot determine endianness!");
    Endian() = delete;

g++ compiles it without error. It seems to work on my x64. Can anyone verify this code on any big-endian processor?

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If your goal is to insure that the compiler optimizes little_endian() into a constant true or false at compile-time, without any of its contents winding up in the executable or being executed at runtime, and only generating code from the "correct" one of your two Foo templates, I fear you're in for a disappointment.

I also am not a language lawyer, but it looks to me like constexpr is like inline or register: a keyword that alerts the compiler writer to the presence of a potential optimization. Then it's up to the compiler writer whether or not to take advantage of that. Language specs typically mandate behaviors, not optimizations.

Also, have you actually tried this on a variety of C++0x complaint compilers to see what happens? I would guess most of them would choke on your dual templates, since they won't be able to figure out which one to use if invoked with false.

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It's not quite the same. The result of a 'constexpr' function generally can be used where a constant expression is required, eg. an array bounds. Although I believe there is some leeway in the case of function templates. –  Richard Corden Oct 19 '09 at 18:11

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