Related
I need to print a ULONGLONG value (unsigned __int64). What format should i use in printf ?
I found %llu in another question but they say it is for linux only.
Thanks for your help.
Using Google to search for “Visual Studio printf unsigned __int64” produces this page as the first result, which says you can use the prefix I64, so the format specifier would be %I64u.
%llu is the standard way to print unsigned long long, it's not just for Linux, it's actually in C99. So the problem is actually to use a C99-compatible compiler, i.e, not Visual Studio.
C99 7.19.6 Formatted input/output functions
ll(ell-ell) Specifies that a following d, i, o, u, x, or X conversion specifier applies to a
long long int or unsigned long long int argument; or that a following n conversion specifier applies to a pointer to along long int argument.
I recommend you use PRIu64 format specified from a standard C library. It was designed to provide users with a format specifier for unsigned 64-bit integer across different architectures.
Here is an example (in C, not C++):
#include <stdint.h> /* For uint64_t */
#include <inttypes.h> /* For PRIu64 */
#include <stdio.h> /* For printf */
#include <stdlib.h> /* For exit status */
int main()
{
uint64_t n = 1986;
printf("And the winning number is.... %" PRIu64 "!\n", n);
return EXIT_SUCCESS;
}
Printf has different format specifiers for unsigned long long depending on the compiler, I have seen %llu and %Lu. In general I would advice you to use std::cout and similar instead.
Here is a work around for HEX output
printf("%08X%08X", static_cast<UINT32>((u64>>32)&0xFFFFFFFF), static_cast<UINT32>(u64)&0xFFFFFFFF));
For guys who forget all the time like me,
If you use Visual Studio (MSVC),
%I64u for uint64_t (unsigned __int64)
%I64d for int64_t (__int64)
%Iu for size_t
You should check this MSDN for the details, or just this section :)
#ifndef EIGHT_BIT
#define THIRTYTWO_BIT // default 32 bit
#endif
#ifdef THIRTYTWO_BIT
#define WORD unsigned long
#define WORDLENGTH 4
#if defined(WIN32) && !defined(__GNUC__)
#define WORD64 unsigned __int64
#else
#define WORD64 unsigned long long
#endif
// THIRTYTWO_BIT
#endif
#ifdef EIGHT_BIT
#define WORD unsigned short
#define WORDLENGTH 4
// EIGHT_BIT
#endif
It's just a definition of constants (aka defines) depending on the #define EIGHT_BIT.
If EIGHT_BIT is defined, WORD means unsigned short and WORDLENGTH is 4. Otherwise, WORD is unsigned long and WORDLENGTH is also 4. Additionally, WORD64 will be defined as unsigned long long unless you are on a WIN32 system and not using GCC.
All the "code" does it setup pre-processor symbols for any "live" code that you do have. If a symbol called EIGHT_BIT is defined before this code is pre-processed, it sets up WORD and WORDLENGTH accordingly (though WORDLENGTH's value is suspect), and it will set up the values differently if EIGHT_BIT is not already defined.
The first thing to note about this code is that none of it will actually be compiled into C. Every line that isn't whitespace or a comment starts with a pound sign (#), meaning they are preprocessor directives. A preprocessor directive alters the code before it even makes it to the compiler. For more information of preprocessor directives, see this article.
Now that we know that much, let's look through the code:
#ifndef EIGHT_BIT
#define THIRTYTWO_BIT // default 32 bit
#endif
If the macro EIGHT_BIT is not defined, define another macro called THIRTYTWO_BIT. This is most likely referring to the number of bits in a word on a processor. This code intends to be cross-platform, meaning that it can run on a number of processors. The snippet you posted pertains to managing different word widths.
#ifdef THIRTYTWO_BIT
#define WORD unsigned long
#define WORDLENGTH 4
If the macro THIRTYTWO_BIT is defined, then define a WORD to be an unsigned long, which has a WORDLENGTH of 4 (presumably bytes). Note that this statement isn't necessarily true, as the C standard only guarantees that a long will be as least as long as an int.
#if defined(WIN32) && !defined(__GNUC__)
#define WORD64 unsigned __int64
#else
#define WORD64 unsigned long long
#endif
If this is a 32-bit Windows platform and the GNU C compiler is not available, then use the Microsoft-specific datatype for 64-bit words (unsigned __int64). Otherwise, use the GNU C datatype (unsigned long long).
// THIRTYTWO_BIT
#endif
Every #if and #ifdef directive must be matched by a corresponding #endif to delineate where the conditional section ends. This line ends the #ifdef THIRTYTWO_BIT declaration made previously.
#ifdef EIGHT_BIT
#define WORD unsigned short
#define WORDLENGTH 4
// EIGHT_BIT
#endif
If the target processor has a word width of 8 bits, then define a WORD to be an unsigned short, and define the WORDLENGTH to be 4 (again, presumably in bytes).
I'm looking for a way to reliably determine whether C++ code is being compiled in 32 vs 64 bit. We've come up with what we think is a reasonable solution using macros, but was curious to know if people could think of cases where this might fail or if there is a better way to do this. Please note we are trying to do this in a cross-platform, multiple compiler environment.
#if ((ULONG_MAX) == (UINT_MAX))
# define IS32BIT
#else
# define IS64BIT
#endif
#ifdef IS64BIT
DoMy64BitOperation()
#else
DoMy32BitOperation()
#endif
Thanks.
Unfortunately there is no cross platform macro which defines 32 / 64 bit across the major compilers. I've found the most effective way to do this is the following.
First I pick my own representation. I prefer ENVIRONMENT64 / ENVIRONMENT32. Then I find out what all of the major compilers use for determining if it's a 64 bit environment or not and use that to set my variables.
// Check windows
#if _WIN32 || _WIN64
#if _WIN64
#define ENVIRONMENT64
#else
#define ENVIRONMENT32
#endif
#endif
// Check GCC
#if __GNUC__
#if __x86_64__ || __ppc64__
#define ENVIRONMENT64
#else
#define ENVIRONMENT32
#endif
#endif
Another easier route is to simply set these variables from the compiler command line.
template<int> void DoMyOperationHelper();
template<> void DoMyOperationHelper<4>()
{
// do 32-bits operations
}
template<> void DoMyOperationHelper<8>()
{
// do 64-bits operations
}
// helper function just to hide clumsy syntax
inline void DoMyOperation() { DoMyOperationHelper<sizeof(size_t)>(); }
int main()
{
// appropriate function will be selected at compile time
DoMyOperation();
return 0;
}
Unfortunately, in a cross platform, cross compiler environment, there is no single reliable method to do this purely at compile time.
Both _WIN32 and _WIN64 can sometimes both be undefined, if the project settings are flawed or corrupted (particularly on Visual Studio 2008 SP1).
A project labelled "Win32" could be set to 64-bit, due to a project configuration error.
On Visual Studio 2008 SP1, sometimes the intellisense does not grey out the correct parts of the code, according to the current #define. This makes it difficult to see exactly which #define is being used at compile time.
Therefore, the only reliable method is to combine 3 simple checks:
1) Compile time setting, and;
2) Runtime check, and;
3) Robust compile time checking.
Simple check 1/3: Compile time setting
Choose any method to set the required #define variable. I suggest the method from #JaredPar:
// Check windows
#if _WIN32 || _WIN64
#if _WIN64
#define ENV64BIT
#else
#define ENV32BIT
#endif
#endif
// Check GCC
#if __GNUC__
#if __x86_64__ || __ppc64__
#define ENV64BIT
#else
#define ENV32BIT
#endif
#endif
Simple check 2/3: Runtime check
In main(), double check to see if sizeof() makes sense:
#if defined(ENV64BIT)
if (sizeof(void*) != 8)
{
wprintf(L"ENV64BIT: Error: pointer should be 8 bytes. Exiting.");
exit(0);
}
wprintf(L"Diagnostics: we are running in 64-bit mode.\n");
#elif defined (ENV32BIT)
if (sizeof(void*) != 4)
{
wprintf(L"ENV32BIT: Error: pointer should be 4 bytes. Exiting.");
exit(0);
}
wprintf(L"Diagnostics: we are running in 32-bit mode.\n");
#else
#error "Must define either ENV32BIT or ENV64BIT".
#endif
Simple check 3/3: Robust compile time checking
The general rule is "every #define must end in a #else which generates an error".
#if defined(ENV64BIT)
// 64-bit code here.
#elif defined (ENV32BIT)
// 32-bit code here.
#else
// INCREASE ROBUSTNESS. ALWAYS THROW AN ERROR ON THE ELSE.
// - What if I made a typo and checked for ENV6BIT instead of ENV64BIT?
// - What if both ENV64BIT and ENV32BIT are not defined?
// - What if project is corrupted, and _WIN64 and _WIN32 are not defined?
// - What if I didn't include the required header file?
// - What if I checked for _WIN32 first instead of second?
// (in Windows, both are defined in 64-bit, so this will break codebase)
// - What if the code has just been ported to a different OS?
// - What if there is an unknown unknown, not mentioned in this list so far?
// I'm only human, and the mistakes above would break the *entire* codebase.
#error "Must define either ENV32BIT or ENV64BIT"
#endif
Update 2017-01-17
Comment from #AI.G:
4 years later (don't know if it was possible before) you can convert
the run-time check to compile-time one using static assert:
static_assert(sizeof(void*) == 4);. Now it's all done at compile time
:)
Appendix A
Incidentially, the rules above can be adapted to make your entire codebase more reliable:
Every if() statement ends in an "else" which generates a warning or error.
Every switch() statement ends in a "default:" which generates a warning or error.
The reason why this works well is that it forces you to think of every single case in advance, and not rely on (sometimes flawed) logic in the "else" part to execute the correct code.
I used this technique (among many others) to write a 30,000 line project that worked flawlessly from the day it was first deployed into production (that was 12 months ago).
You should be able to use the macros defined in stdint.h. In particular INTPTR_MAX is exactly the value you need.
#include <cstdint>
#if INTPTR_MAX == INT32_MAX
#define THIS_IS_32_BIT_ENVIRONMENT
#elif INTPTR_MAX == INT64_MAX
#define THIS_IS_64_BIT_ENVIRONMENT
#else
#error "Environment not 32 or 64-bit."
#endif
Some (all?) versions of Microsoft's compiler don't come with stdint.h. Not sure why, since it's a standard file. Here's a version you can use: http://msinttypes.googlecode.com/svn/trunk/stdint.h
That won't work on Windows for a start. Longs and ints are both 32 bits whether you're compiling for 32 bit or 64 bit windows. I would think checking if the size of a pointer is 8 bytes is probably a more reliable route.
You could do this:
#if __WORDSIZE == 64
char *size = "64bits";
#else
char *size = "32bits";
#endif
Try this:
#ifdef _WIN64
// 64 bit code
#elif _WIN32
// 32 bit code
#else
if(sizeof(void*)==4)
// 32 bit code
else
// 64 bit code
#endif
Below code works fine for most current environments:
#if defined(__LP64__) || defined(_WIN64) || (defined(__x86_64__) && !defined(__ILP32__) ) || defined(_M_X64) || defined(__ia64) || defined (_M_IA64) || defined(__aarch64__) || defined(__powerpc64__)
#define IS64BIT 1
#else
#define IS32BIT 1
#endif
"Compiled in 64 bit" is not well defined in C++.
C++ sets only lower limits for sizes such as int, long and void *. There is no guarantee that int is 64 bit even when compiled for a 64 bit platform. The model allows for e.g. 23 bit ints and sizeof(int *) != sizeof(char *)
There are different programming models for 64 bit platforms.
Your best bet is a platform specific test. Your second best, portable decision must be more specific in what is 64 bit.
Your approach was not too far off, but you are only checking whether long and int are of the same size. Theoretically, they could both be 64 bits, in which case your check would fail, assuming both to be 32 bits. Here is a check that actually checks the size of the types themselves, not their relative size:
#if ((UINT_MAX) == 0xffffffffu)
#define INT_IS32BIT
#else
#define INT_IS64BIT
#endif
#if ((ULONG_MAX) == 0xfffffffful)
#define LONG_IS32BIT
#else
#define LONG_IS64BIT
#endif
In principle, you can do this for any type for which you have a system defined macro with the maximal value.
Note, that the standard requires long long to be at least 64 bits even on 32 bit systems.
People already suggested methods that will try to determine if the program is being compiled in 32-bit or 64-bit.
And I want to add that you can use the c++11 feature static_assert to make sure that the architecture is what you think it is ("to relax").
So in the place where you define the macros:
#if ...
# define IS32BIT
static_assert(sizeof(void *) == 4, "Error: The Arch is not what I think it is")
#elif ...
# define IS64BIT
static_assert(sizeof(void *) == 8, "Error: The Arch is not what I think it is")
#else
# error "Cannot determine the Arch"
#endif
Borrowing from Contango's excellent answer above and combining it with "Better Macros, Better Flags" from Fluent C++, you can do:
// Macro for checking bitness (safer macros borrowed from
// https://www.fluentcpp.com/2019/05/28/better-macros-better-flags/)
#define MYPROJ_IS_BITNESS( X ) MYPROJ_IS_BITNESS_PRIVATE_DEFINITION_##X()
// Bitness checks borrowed from https://stackoverflow.com/a/12338526/201787
#if _WIN64 || ( __GNUC__ && __x86_64__ )
# define MYPROJ_IS_BITNESS_PRIVATE_DEFINITION_64() 1
# define MYPROJ_IS_BITNESS_PRIVATE_DEFINITION_32() 0
# define MYPROJ_IF_64_BIT_ELSE( x64, x86 ) (x64)
static_assert( sizeof( void* ) == 8, "Pointer size is unexpected for this bitness" );
#elif _WIN32 || __GNUC__
# define MYPROJ_IS_BITNESS_PRIVATE_DEFINITION_64() 0
# define MYPROJ_IS_BITNESS_PRIVATE_DEFINITION_32() 1
# define MYPROJ_IF_64_BIT_ELSE( x64, x86 ) (x86)
static_assert( sizeof( void* ) == 4, "Pointer size is unexpected for this bitness" );
#else
# error "Unknown bitness!"
#endif
Then you can use it like:
#if MYPROJ_IS_BITNESS( 64 )
DoMy64BitOperation()
#else
DoMy32BitOperation()
#endif
Or using the extra macro I added:
MYPROJ_IF_64_BIT_ELSE( DoMy64BitOperation(), DoMy32BitOperation() );
Here are a few more ways to do what you want in modern C++.
You can create a variable that defines the number of system bits:
static constexpr size_t sysbits = (CHAR_BIT * sizeof(void*));
And then in C++17 you can do something like:
void DoMy64BitOperation() {
std::cout << "64-bit!\n";
}
void DoMy32BitOperation() {
std::cout << "32-bit!\n";
}
inline void DoMySysBitOperation()
{
if constexpr(sysbits == 32)
DoMy32BitOperation();
else if constexpr(sysbits == 64)
DoMy64BitOperation();
/*else - other systems. */
}
Or in C++20:
template<void* = nullptr>
// template<int = 32> // May be clearer, pick whatever you like.
void DoMySysBitOperation()
requires(sysbits == 32)
{
std::cout << "32-bit!\n";
}
template<void* = nullptr>
// template<int = 64>
void DoMySysBitOperation()
requires(sysbits == 64)
{
std::cout << "64-bit!\n";
}
template<void* = nullptr>
void DoMySysBitOperation()
/* requires(sysbits == OtherSystem) */
{
std::cout << "Unknown System!\n";
}
The template<...> is usually not needed, but since those functions will have the same mangling name, we must enforce the compiler to pick the correct ones. Also, template<void* = nullptr> may be confusing ( The other template may be better and more logically correct ), I only used it as a workaround to satisfy the compiler name mangling.
If you can use project configurations in all your environments, that would make defining a 64- and 32-bit symbol easy. So you'd have project configurations like this:
32-bit Debug
32-bit Release
64-bit Debug
64-bit Release
EDIT: These are generic configurations, not targetted configurations. Call them whatever you want.
If you can't do that, I like Jared's idea.
I'd place 32-bit and 64-bit sources in different files and then select appropriate source files using the build system.
I'm adding this answer as a use case and complete example for the runtime-check described in another answer.
This is the approach I've been taking for conveying to the end-user whether the program was compiled as 64-bit or 32-bit (or other, for that matter):
version.h
#ifndef MY_VERSION
#define MY_VERSION
#include <string>
const std::string version = "0.09";
const std::string arch = (std::to_string(sizeof(void*) * 8) + "-bit");
#endif
test.cc
#include <iostream>
#include "version.h"
int main()
{
std::cerr << "My App v" << version << " [" << arch << "]" << std::endl;
}
Compile and Test
g++ -g test.cc
./a.out
My App v0.09 [64-bit]
I'm looking for a way to reliably determine whether C++ code is being compiled in 32 vs 64 bit. We've come up with what we think is a reasonable solution using macros, but was curious to know if people could think of cases where this might fail or if there is a better way to do this. Please note we are trying to do this in a cross-platform, multiple compiler environment.
#if ((ULONG_MAX) == (UINT_MAX))
# define IS32BIT
#else
# define IS64BIT
#endif
#ifdef IS64BIT
DoMy64BitOperation()
#else
DoMy32BitOperation()
#endif
Thanks.
Unfortunately there is no cross platform macro which defines 32 / 64 bit across the major compilers. I've found the most effective way to do this is the following.
First I pick my own representation. I prefer ENVIRONMENT64 / ENVIRONMENT32. Then I find out what all of the major compilers use for determining if it's a 64 bit environment or not and use that to set my variables.
// Check windows
#if _WIN32 || _WIN64
#if _WIN64
#define ENVIRONMENT64
#else
#define ENVIRONMENT32
#endif
#endif
// Check GCC
#if __GNUC__
#if __x86_64__ || __ppc64__
#define ENVIRONMENT64
#else
#define ENVIRONMENT32
#endif
#endif
Another easier route is to simply set these variables from the compiler command line.
template<int> void DoMyOperationHelper();
template<> void DoMyOperationHelper<4>()
{
// do 32-bits operations
}
template<> void DoMyOperationHelper<8>()
{
// do 64-bits operations
}
// helper function just to hide clumsy syntax
inline void DoMyOperation() { DoMyOperationHelper<sizeof(size_t)>(); }
int main()
{
// appropriate function will be selected at compile time
DoMyOperation();
return 0;
}
Unfortunately, in a cross platform, cross compiler environment, there is no single reliable method to do this purely at compile time.
Both _WIN32 and _WIN64 can sometimes both be undefined, if the project settings are flawed or corrupted (particularly on Visual Studio 2008 SP1).
A project labelled "Win32" could be set to 64-bit, due to a project configuration error.
On Visual Studio 2008 SP1, sometimes the intellisense does not grey out the correct parts of the code, according to the current #define. This makes it difficult to see exactly which #define is being used at compile time.
Therefore, the only reliable method is to combine 3 simple checks:
1) Compile time setting, and;
2) Runtime check, and;
3) Robust compile time checking.
Simple check 1/3: Compile time setting
Choose any method to set the required #define variable. I suggest the method from #JaredPar:
// Check windows
#if _WIN32 || _WIN64
#if _WIN64
#define ENV64BIT
#else
#define ENV32BIT
#endif
#endif
// Check GCC
#if __GNUC__
#if __x86_64__ || __ppc64__
#define ENV64BIT
#else
#define ENV32BIT
#endif
#endif
Simple check 2/3: Runtime check
In main(), double check to see if sizeof() makes sense:
#if defined(ENV64BIT)
if (sizeof(void*) != 8)
{
wprintf(L"ENV64BIT: Error: pointer should be 8 bytes. Exiting.");
exit(0);
}
wprintf(L"Diagnostics: we are running in 64-bit mode.\n");
#elif defined (ENV32BIT)
if (sizeof(void*) != 4)
{
wprintf(L"ENV32BIT: Error: pointer should be 4 bytes. Exiting.");
exit(0);
}
wprintf(L"Diagnostics: we are running in 32-bit mode.\n");
#else
#error "Must define either ENV32BIT or ENV64BIT".
#endif
Simple check 3/3: Robust compile time checking
The general rule is "every #define must end in a #else which generates an error".
#if defined(ENV64BIT)
// 64-bit code here.
#elif defined (ENV32BIT)
// 32-bit code here.
#else
// INCREASE ROBUSTNESS. ALWAYS THROW AN ERROR ON THE ELSE.
// - What if I made a typo and checked for ENV6BIT instead of ENV64BIT?
// - What if both ENV64BIT and ENV32BIT are not defined?
// - What if project is corrupted, and _WIN64 and _WIN32 are not defined?
// - What if I didn't include the required header file?
// - What if I checked for _WIN32 first instead of second?
// (in Windows, both are defined in 64-bit, so this will break codebase)
// - What if the code has just been ported to a different OS?
// - What if there is an unknown unknown, not mentioned in this list so far?
// I'm only human, and the mistakes above would break the *entire* codebase.
#error "Must define either ENV32BIT or ENV64BIT"
#endif
Update 2017-01-17
Comment from #AI.G:
4 years later (don't know if it was possible before) you can convert
the run-time check to compile-time one using static assert:
static_assert(sizeof(void*) == 4);. Now it's all done at compile time
:)
Appendix A
Incidentially, the rules above can be adapted to make your entire codebase more reliable:
Every if() statement ends in an "else" which generates a warning or error.
Every switch() statement ends in a "default:" which generates a warning or error.
The reason why this works well is that it forces you to think of every single case in advance, and not rely on (sometimes flawed) logic in the "else" part to execute the correct code.
I used this technique (among many others) to write a 30,000 line project that worked flawlessly from the day it was first deployed into production (that was 12 months ago).
You should be able to use the macros defined in stdint.h. In particular INTPTR_MAX is exactly the value you need.
#include <cstdint>
#if INTPTR_MAX == INT32_MAX
#define THIS_IS_32_BIT_ENVIRONMENT
#elif INTPTR_MAX == INT64_MAX
#define THIS_IS_64_BIT_ENVIRONMENT
#else
#error "Environment not 32 or 64-bit."
#endif
Some (all?) versions of Microsoft's compiler don't come with stdint.h. Not sure why, since it's a standard file. Here's a version you can use: http://msinttypes.googlecode.com/svn/trunk/stdint.h
That won't work on Windows for a start. Longs and ints are both 32 bits whether you're compiling for 32 bit or 64 bit windows. I would think checking if the size of a pointer is 8 bytes is probably a more reliable route.
You could do this:
#if __WORDSIZE == 64
char *size = "64bits";
#else
char *size = "32bits";
#endif
Try this:
#ifdef _WIN64
// 64 bit code
#elif _WIN32
// 32 bit code
#else
if(sizeof(void*)==4)
// 32 bit code
else
// 64 bit code
#endif
Below code works fine for most current environments:
#if defined(__LP64__) || defined(_WIN64) || (defined(__x86_64__) && !defined(__ILP32__) ) || defined(_M_X64) || defined(__ia64) || defined (_M_IA64) || defined(__aarch64__) || defined(__powerpc64__)
#define IS64BIT 1
#else
#define IS32BIT 1
#endif
"Compiled in 64 bit" is not well defined in C++.
C++ sets only lower limits for sizes such as int, long and void *. There is no guarantee that int is 64 bit even when compiled for a 64 bit platform. The model allows for e.g. 23 bit ints and sizeof(int *) != sizeof(char *)
There are different programming models for 64 bit platforms.
Your best bet is a platform specific test. Your second best, portable decision must be more specific in what is 64 bit.
Your approach was not too far off, but you are only checking whether long and int are of the same size. Theoretically, they could both be 64 bits, in which case your check would fail, assuming both to be 32 bits. Here is a check that actually checks the size of the types themselves, not their relative size:
#if ((UINT_MAX) == 0xffffffffu)
#define INT_IS32BIT
#else
#define INT_IS64BIT
#endif
#if ((ULONG_MAX) == 0xfffffffful)
#define LONG_IS32BIT
#else
#define LONG_IS64BIT
#endif
In principle, you can do this for any type for which you have a system defined macro with the maximal value.
Note, that the standard requires long long to be at least 64 bits even on 32 bit systems.
People already suggested methods that will try to determine if the program is being compiled in 32-bit or 64-bit.
And I want to add that you can use the c++11 feature static_assert to make sure that the architecture is what you think it is ("to relax").
So in the place where you define the macros:
#if ...
# define IS32BIT
static_assert(sizeof(void *) == 4, "Error: The Arch is not what I think it is")
#elif ...
# define IS64BIT
static_assert(sizeof(void *) == 8, "Error: The Arch is not what I think it is")
#else
# error "Cannot determine the Arch"
#endif
Borrowing from Contango's excellent answer above and combining it with "Better Macros, Better Flags" from Fluent C++, you can do:
// Macro for checking bitness (safer macros borrowed from
// https://www.fluentcpp.com/2019/05/28/better-macros-better-flags/)
#define MYPROJ_IS_BITNESS( X ) MYPROJ_IS_BITNESS_PRIVATE_DEFINITION_##X()
// Bitness checks borrowed from https://stackoverflow.com/a/12338526/201787
#if _WIN64 || ( __GNUC__ && __x86_64__ )
# define MYPROJ_IS_BITNESS_PRIVATE_DEFINITION_64() 1
# define MYPROJ_IS_BITNESS_PRIVATE_DEFINITION_32() 0
# define MYPROJ_IF_64_BIT_ELSE( x64, x86 ) (x64)
static_assert( sizeof( void* ) == 8, "Pointer size is unexpected for this bitness" );
#elif _WIN32 || __GNUC__
# define MYPROJ_IS_BITNESS_PRIVATE_DEFINITION_64() 0
# define MYPROJ_IS_BITNESS_PRIVATE_DEFINITION_32() 1
# define MYPROJ_IF_64_BIT_ELSE( x64, x86 ) (x86)
static_assert( sizeof( void* ) == 4, "Pointer size is unexpected for this bitness" );
#else
# error "Unknown bitness!"
#endif
Then you can use it like:
#if MYPROJ_IS_BITNESS( 64 )
DoMy64BitOperation()
#else
DoMy32BitOperation()
#endif
Or using the extra macro I added:
MYPROJ_IF_64_BIT_ELSE( DoMy64BitOperation(), DoMy32BitOperation() );
Here are a few more ways to do what you want in modern C++.
You can create a variable that defines the number of system bits:
static constexpr size_t sysbits = (CHAR_BIT * sizeof(void*));
And then in C++17 you can do something like:
void DoMy64BitOperation() {
std::cout << "64-bit!\n";
}
void DoMy32BitOperation() {
std::cout << "32-bit!\n";
}
inline void DoMySysBitOperation()
{
if constexpr(sysbits == 32)
DoMy32BitOperation();
else if constexpr(sysbits == 64)
DoMy64BitOperation();
/*else - other systems. */
}
Or in C++20:
template<void* = nullptr>
// template<int = 32> // May be clearer, pick whatever you like.
void DoMySysBitOperation()
requires(sysbits == 32)
{
std::cout << "32-bit!\n";
}
template<void* = nullptr>
// template<int = 64>
void DoMySysBitOperation()
requires(sysbits == 64)
{
std::cout << "64-bit!\n";
}
template<void* = nullptr>
void DoMySysBitOperation()
/* requires(sysbits == OtherSystem) */
{
std::cout << "Unknown System!\n";
}
The template<...> is usually not needed, but since those functions will have the same mangling name, we must enforce the compiler to pick the correct ones. Also, template<void* = nullptr> may be confusing ( The other template may be better and more logically correct ), I only used it as a workaround to satisfy the compiler name mangling.
If you can use project configurations in all your environments, that would make defining a 64- and 32-bit symbol easy. So you'd have project configurations like this:
32-bit Debug
32-bit Release
64-bit Debug
64-bit Release
EDIT: These are generic configurations, not targetted configurations. Call them whatever you want.
If you can't do that, I like Jared's idea.
I'd place 32-bit and 64-bit sources in different files and then select appropriate source files using the build system.
I'm adding this answer as a use case and complete example for the runtime-check described in another answer.
This is the approach I've been taking for conveying to the end-user whether the program was compiled as 64-bit or 32-bit (or other, for that matter):
version.h
#ifndef MY_VERSION
#define MY_VERSION
#include <string>
const std::string version = "0.09";
const std::string arch = (std::to_string(sizeof(void*) * 8) + "-bit");
#endif
test.cc
#include <iostream>
#include "version.h"
int main()
{
std::cerr << "My App v" << version << " [" << arch << "]" << std::endl;
}
Compile and Test
g++ -g test.cc
./a.out
My App v0.09 [64-bit]
I have some c(++) code that uses sprintf to convert a uint_64 to a string. This needs to be portable to both linux and Solaris.
On linux we use %ju, but there does not appear to be any equivalent on Solaris. The closest I can find is %lu, but this produces incorrect output. Some sample code:
#include <stdio.h>
#include <sys/types.h>
#ifdef SunOS
typedef uint64_t u_int64_t;
#endif
int main(int argc, char **argv) {
u_int64_t val = 123456789123L;
#ifdef SunOS
printf("%lu\n", val);
#else
printf("%ju\n", val);
#endif
}
On linux, the output is as expected; on Solaris 9 (don't ask), it's "28"
What can I use?
If you have have inttypes.h available you can use the macros it provides:
printf( "%" PRIu64 "\n", val);
Not pretty (I seem to be saying that a lot recently), but it works.
On a C99 compliant system:
#include <inttypes.h>
uint64_t big = ...;
printf("%" PRIu64 "\n", big);
See section 7.8 of the C99 standard.
The specifiers are {PRI,SCN}[diouxX]{N,LEASTN,MAX,FASTN,PTR}
Where PRI is for the printf() family, SCN is for the scanf() family, d and i for signed integral types; o,u,x,X are for unsigned integral types as octal, decimal, hex, and Hex; N is one of the supported widths; LEAST and FAST correspond to those modifiers; PTR is for intptr_t; and MAX is for intmax_t.
The answer depends on whether your code is actually C or C++. In C, you should be using an unsigned long long rather than another type (this is conformant to the current standard, and long long is pretty common as far as C99 support goes), appending ULL instead of L to your constant, and using (as has been mentioned) %llu as your specifier. If support for C99 doesn't exist, you may want to check the compiler documentation, as there is no other standard way to do it. long long is guarateed to be 64 bits at least.
You can use %llu for long long. However, this is not very portable either, because long long isn't guaranteed to be 64 bits. :-)
You can get uint64_t from stdint.h if you want to avoid the SunOS conditional typedef.