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In code, I sometimes see people specify constants in hex format like this:

const int has_nukes        = 0x0001;
const int has_bio_weapons  = 0x0002;
const int has_chem_weapons = 0x0004;
// ...
int arsenal = has_nukes | has_bio_weapons | has_chem_weapons; // all of them
if(arsenal &= has_bio_weapons){
  std::cout << "BIO!!"

But it doesn't make sense to me to use the hex format here. Is there a way to do it directly in binary? Something like this:

const int has_nukes        = 0b00000000000000000000000000000001;
const int has_bio_weapons  = 0b00000000000000000000000000000010;
const int has_chem_weapons = 0b00000000000000000000000000000100;
// ...

I know the C/C++ compilers won't compile this, but there must be a workaround? Is it possible in other languages like Java?

share|improve this question
I'm curious why the hex notation doesn't work for you? A number is a number. Binary notation would be much more prone to typos and would get really old for large numbers. – EBGreen Feb 11 '09 at 15:28
Interesting variables names. Are you designing a war game? – gnovice Feb 11 '09 at 15:29
Binary works better because the whole trick with the 'and' and 'or' operators works on the binary format and I want to be able to see the bit patterns. It's directly visible what bits are set. Even a beginner will be able to read the code without having to resort to a calculator. – Frank Feb 11 '09 at 15:31
@EBGreen: when you're programming microcontrollers, using binary notation is Extremely useful. So much so that some uC C compilers actually accept numbers in the form of 0b00101010. – Rocketmagnet Feb 11 '09 at 15:33
Careful with "arsenal &= has_bio_weapons". I think you meant "(arsenal & has_bio_weapons) == has_bio_weapons". – Mr Fooz Feb 12 '09 at 4:52

17 Answers 17

up vote 52 down vote accepted

I'd use a bit shift operator:

const int has_nukes        = 1<<0;
const int has_bio_weapons  = 1<<1;
const int has_chem_weapons = 1<<2;
// ...
int dangerous_mask = has_nukes | has_bio_weapons | has_chem_weapons;
bool is_dangerous = (country->flags & dangerous_mask) == dangerous_mask;

It is even better than flood of 0's.

share|improve this answer
My wild guess is that old compilers were dumb enough to actually shifted the 1 around, instead of converting that expression to an integer literal. – Calyth Feb 11 '09 at 18:40
I would suggest using an enum instead of constants. However, there is the problem where you cannot OR enums. You could make a class which overrides these, but you'll lose compile-time performance! Ah, such is life. – strager Feb 11 '09 at 19:26
One thing to watch out for when using this syntax, is that if you ever change the type to a wider integral type (e.g. unsigned long long), you'll have to change all the 1<<N to 1ULL<<N, at least for large N, otherwise silent unpredictable behavior could occur (if you're lucky you'll get a compiler warning)! (This is vs. the hex syntax where you wouldn't need to add a special suffix, since a sufficiently large integral type will be selected by the compiler.) – ndkrempel May 19 '12 at 23:24
@strager what benefit did enums have, other than being inlinable by less efficient compilers? anyway since C++11 added constexpr, that's always preferable. plain old consts could be inlined as literals too, though constexpr signals intent better and opens up a lot of other possibilities. – underscore_d Apr 20 at 20:00

By the way, the next C++ version will support user defined literals. They are already included into the working draft. This allows that sort of stuff (let's hope i don't have too many errors in it):

template<char... digits>
constexpr int operator "" _b() {
    return conv2bin<digits...>::value;

int main() {
    int const v = 110110110_b;

conv2bin would be a template like this:

template<char... digits>
struct conv2bin;

template<char high, char... digits>
struct conv2bin<high, digits...> {
    static_assert(high == '0' || high == '1', "no bin num!");
    static int const value = (high - '0') * (1 << sizeof...(digits)) + 

template<char high>
struct conv2bin<high> {
    static_assert(high == '0' || high == '1', "no bin num!");
    static int const value = (high - '0');

Well, what we get are binary literals that evaluate fully at compile time already, because of the "constexpr" above. The above uses a hard-coded int return type. I think one could even make it depend on the length of the binary string. It's using the following features, for anyone interested:

Actually, current GCC trunk already implements variadic templates and static assertions. Let's hope it will support the other two soon. I think C++1x will rock the house.

share|improve this answer
Very nice example, it's what I had in mind in my shorter answer but you fleshed it out very nicely! – Motti Apr 27 '09 at 11:39
Motti, thanks for your praise – Johannes Schaub - litb Apr 27 '09 at 21:22
According to the last link, shouldn't it be constexpr int operator"_b"()? – NikiC Jul 22 '10 at 15:19
What do you mean by the next C++ version? Your answer is from 2009 is it C++11? – Wolf Jun 26 '14 at 11:52
I found user literals being integrated into C++11: User-defined literals (since C++11) - – Wolf Jun 26 '14 at 12:00

In C++14 you will be able to use binary literals with the following syntax:

0b010101010 /* more zeros and ones */

This feature is already implemented in the latest clang and gcc. You can try it if you run those compilers with -std=c++1y option.

share|improve this answer
It now works with clang-3.4 (See; Just compiled and it indeed returns 3 : int main(int argc, char** argv) { int a = 0b00000011; return a; } – daminetreg Nov 7 '13 at 22:32
@daminetreg, yeah, it does. Actually I was talking exactly about clang 4.8 trunk in the post but didn't mention the version. – sasha.sochka Nov 8 '13 at 12:32
Isn't 4.8 the version of gcc ? Or did I miss something ? – daminetreg Nov 8 '13 at 23:50
Oops, my mistake, I was thinking about gcc while writing about clang. Of course, you're right. – sasha.sochka Nov 9 '13 at 14:24
WRT GCC and Clang, both support this syntax as an extension for both C and C++ and have long before C++1y was even proposed (Since GCC 4.3.) – Jonathan Baldwin Jan 17 '14 at 11:18

You can use << if you like.

int hasNukes = 1;
int hasBioWeapons = 1 << 1;
int hasChemWeapons = 1 << 2;
share|improve this answer
Thanks, that's even nicer than the 0b0000... option. – Frank Feb 11 '09 at 15:32

The C++ Standard Library is your friend:

#include <bitset>

const std::bitset <32> has_nukes( "00000000000000000000000000000001" );
share|improve this answer
Ha, that's nice. The only downside seems to be, for the purists among us, that it has to parse a string at runtime just to assign the value. With BOOST_BINARY, which someone here pointed to, that's not necessary. – Frank Feb 11 '09 at 15:57
or alternatively with const int has_nukes = bitset<32>("10101101").to_ulong(); – Johannes Schaub - litb Feb 11 '09 at 18:39

GCC supports binary constants as an extension since 4.3. See the announcement (look at the section "New Languages and Language specific improvements").

share|improve this answer
+1 Why does nobody realise this? Their loss -- it's awesome! Go GCC. – Arcane Engineer Feb 1 '12 at 18:40
That's not useful if your code will be compiled by something other than gcc (or some gcc-compatible implementation). – Keith Thompson May 20 '13 at 21:34

The term you want is binary literals

Ruby has them with the syntax you give.

One alternative is to define helper macros to convert for you. I found the following code at

/* Binary constant generator macro
By Tom Torfs - donated to the public domain

/* All macro's evaluate to compile-time constants */

/* *** helper macros *** /

/* turn a numeric literal into a hex constant
(avoids problems with leading zeroes)
8-bit constants max value 0x11111111, always fits in unsigned long
#define HEX__(n) 0x##n##LU

/* 8-bit conversion function */
#define B8__(x) ((x&0x0000000FLU)?1:0) \
+((x&0x000000F0LU)?2:0) \
+((x&0x00000F00LU)?4:0) \
+((x&0x0000F000LU)?8:0) \
+((x&0x000F0000LU)?16:0) \
+((x&0x00F00000LU)?32:0) \
+((x&0x0F000000LU)?64:0) \

/* *** user macros *** /

/* for upto 8-bit binary constants */
#define B8(d) ((unsigned char)B8__(HEX__(d)))

/* for upto 16-bit binary constants, MSB first */
#define B16(dmsb,dlsb) (((unsigned short)B8(dmsb)<<8) \
+ B8(dlsb))

/* for upto 32-bit binary constants, MSB first */
#define B32(dmsb,db2,db3,dlsb) (((unsigned long)B8(dmsb)<<24) \
+ ((unsigned long)B8(db2)<<16) \
+ ((unsigned long)B8(db3)<<8) \
+ B8(dlsb))

/* Sample usage:
B8(01010101) = 85
B16(10101010,01010101) = 43605
B32(10000000,11111111,10101010,01010101) = 2164238933
share|improve this answer

This discussion may be interesting... Might have been, as the link is dead unfortunately. It described a template based approach similar to other answers here.

And also there is a thing called BOOST_BINARY.

share|improve this answer
Thanks, this is another good workaround. – Frank Feb 11 '09 at 15:37
+1 for BOOST_BINARY, neat solution. – Tomas May 11 '10 at 15:53
The link to the discussion is broken. Could you please summarize it here instead? – Rob Kennedy Aug 28 '14 at 22:18
You've got a dead link with no context in your answer so it is now useless, at least your second link is googleable... – Troyseph Jun 9 '15 at 11:25

The next version of C++, C++0x, will introduce user defined literals. I'm not sure if binary numbers will be part of the standard but at the worst you'll be able to enable it yourself:

int operator "" _B(int i);

assert( 1010_B == 10);
share|improve this answer

I write binary literals like this:

const int has_nukes        = 0x0001;
const int has_bio_weapons  = 0x0002;
const int has_chem_weapons = 0x0004;

It's more compact than your suggested notation, and easier to read. For example:

const int upper_bit = 0b0001000000000000000;


const int upper_bit = 0x04000;

Did you notice that the binary version wasn't an even multiple of 4 bits? Did you think it was 0x10000?

With a little practice hex or octal are easier for a human than binary. And, in my opinion, easier to read that using shift operators. But I'll concede that my years of assembly language work may bias me on that point.

share|improve this answer
0b0001000000000000000 != 0x04000. I think you meant 0b100000000000000 – old_mountain Apr 24 '15 at 20:58

One, slightly horrible way you could do it is by generating a .h file with lots of #defines...

#define b00000000 0
#define b00000001 1
#define b00000010 2
#define b00000011 3
#define b00000100 4

etc. This might make sense for 8-bit numbers, but probably not for 16-bit or larger.

Alternatively, do this (similar to Zach Scrivena's answer):

#define bit(x) (1<<x)
int HAS_NUKES       = bit(HAS_NUKES_OFFSET);


share|improve this answer

Java doesn't support binary literals either, unfortunately. However, it has enums which can be used with an EnumSet. An EnumSet represents enum values internally with bit fields, and presents a Set interface for manipulating these flags.

Alternatively, you could use bit offsets (in decimal) when defining your values:

const int HAS_NUKES        = 0x1 << 0;
const int HAS_BIO_WEAPONS  = 0x1 << 1;
const int HAS_CHEM_WEAPONS = 0x1 << 2;
share|improve this answer
Java now supports binary literals! – Troyseph Jun 9 '15 at 11:28

I agree that it's useful to have an option for binary literals, and they are present in many programming languages. In C, I've decided to use a macro like this:

#define bitseq(a00,a01,a02,a03,a04,a05,a06,a07,a08,a09,a10,a11,a12,a13,a14,a15, \
           a16,a17,a18,a19,a20,a21,a22,a23,a24,a25,a26,a27,a28,a29,a30,a31) \
   (a31|a30<< 1|a29<< 2|a28<< 3|a27<< 4|a26<< 5|a25<< 6|a24<< 7| \
a23<< 8|a22<< 9|a21<<10|a20<<11|a19<<12|a18<<13|a17<<14|a16<<15| \
a15<<16|a14<<17|a13<<18|a12<<19|a11<<20|a10<<21|a09<<22|a08<<23| \

The usage is pretty much straightforward =)

share|improve this answer

There's no syntax for literal binary constants in C++ the way there is for hexadecimal and octal. The closest thing for what it looks like you're trying to do would probably be to learn and use bitset.

share|improve this answer

As an aside:

Especially if you're dealing with a large set, instead of going through the [minor] mental effort of writing a sequence of shift amounts, you can make each constant depend on the previously defined constant:

const int has_nukes        = 1;
const int has_bio_weapons  = has_nukes        << 1;
const int has_chem_weapons = has_bio_weapons  << 1;
const int has_nunchuks     = has_chem_weapons << 1;
// ...

Looks a bit redundant, but it's less typo-prone. Also, you can simply insert a new constant in the middle without having to touch any other line except the one immediately following it:

const int has_nukes        = 1;
const int has_gravity_gun  = has_nukes        << 1; // added
const int has_bio_weapons  = has_gravity_gun  << 1; // changed
const int has_chem_weapons = has_bio_weapons  << 1; // unaffected from here on
const int has_nunchuks     = has_chem_weapons << 1;
// ...

Compare to:

const int has_nukes        = 1 << 0;
const int has_bio_weapons  = 1 << 1;
const int has_chem_weapons = 1 << 2;
const int has_nunchuks     = 1 << 3;
// ...
const int has_scimatar     = 1 << 28;
const int has_rapier       = 1 << 28; // good luck spotting this typo!
const int has_katana       = 1 << 30;


const int has_nukes        = 1 << 0;
const int has_gravity_gun  = 1 << 1;  // added
const int has_bio_weapons  = 1 << 2;  // changed
const int has_chem_weapons = 1 << 3;  // changed
const int has_nunchuks     = 1 << 4;  // changed
// ...                                // changed all the way
const int has_scimatar     = 1 << 29; // changed *sigh*
const int has_rapier       = 1 << 30; // changed *sigh* 
const int has_katana       = 1 << 31; // changed *sigh*

As an aside to my aside, it's probably equally hard to spot a typo like this:

const int has_nukes        = 1;
const int has_gravity_gun  = has_nukes        << 1;
const int has_bio_weapons  = has_gravity_gun  << 1;
const int has_chem_weapons = has_gravity_gun  << 1; // oops!
const int has_nunchuks     = has_chem_weapons << 1;

So, I think the main advantage of this cascading syntax is when dealing with insertions and deletions of constants.

share|improve this answer

Another method:

template<unsigned int N>
class b
    static unsigned int const x = N;

    typedef b_<0>  _0000;
    typedef b_<1>  _0001;
    typedef b_<2>  _0010;
    typedef b_<3>  _0011;
    typedef b_<4>  _0100;
    typedef b_<5>  _0101;
    typedef b_<6>  _0110;
    typedef b_<7>  _0111;
    typedef b_<8>  _1000;
    typedef b_<9>  _1001;
    typedef b_<10> _1010;
    typedef b_<11> _1011;
    typedef b_<12> _1100;
    typedef b_<13> _1101;
    typedef b_<14> _1110;
    typedef b_<15> _1111;

    template<unsigned int N2>
    struct b_: public b<N << 4 | N2> {};

typedef b<0>  _0000;
typedef b<1>  _0001;
typedef b<2>  _0010;
typedef b<3>  _0011;
typedef b<4>  _0100;
typedef b<5>  _0101;
typedef b<6>  _0110;
typedef b<7>  _0111;
typedef b<8>  _1000;
typedef b<9>  _1001;
typedef b<10> _1010;
typedef b<11> _1011;
typedef b<12> _1100;
typedef b<13> _1101;
typedef b<14> _1110;
typedef b<15> _1111;


std::cout << _1101::_1001::_1101::_1101::x;

Implemented in CityLizard++ (citylizard/binary/b.hpp).

share|improve this answer

If you want to use bitset, auto, variadic templates, user-defined literals, static_assert, constexpr, and noexcept try this:

template<char... Bits>
  struct __checkbits
    static const bool valid = false;

template<char High, char... Bits>
  struct __checkbits<High, Bits...>
    static const bool valid = (High == '0' || High == '1')
                   && __checkbits<Bits...>::valid;

template<char High>
  struct __checkbits<High>
    static const bool valid = (High == '0' || High == '1');

template<char... Bits>
  inline constexpr std::bitset<sizeof...(Bits)>
  operator"" bits() noexcept
    static_assert(__checkbits<Bits...>::valid, "invalid digit in binary string");
    return std::bitset<sizeof...(Bits)>((char []){Bits..., '\0'});

Use it like this:

  auto bits = 0101010101010101010101010101010101010101010101010101010101010101bits;
  std::cout << bits << std::endl;
  std::cout << "size = " << bits.size() << std::endl;
  std::cout << "count = " << bits.count() << std::endl;
  std::cout << "value = " << bits.to_ullong() << std::endl;
  //  This triggers the static_assert at compile-time.
  auto badbits = 2101010101010101010101010101010101010101010101010101010101010101bits;
  //  This throws at run-time.
  std::bitset<64> badbits2("2101010101010101010101010101010101010101010101010101010101010101bits");

Thanks to @johannes-schaub-litb

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