Where are MIN and MAX defined in C, if at all?

What is the best way to implement these, as generically and type safely as possible? (Compiler extensions/builtins for mainstream compilers preferred.)

  • 3
    Can someone check this and tell if it is macro or a function? By this, I mean, in line min(x++, y++), x and y are incremented once or twice if I use this min. Commented Jul 20, 2021 at 12:09
  • @SouravKannanthaB umm... TIAS? Commented Aug 19, 2022 at 13:23
  • 1
    What all of the answers (circa 2023) below skip, is that there are fast ways to compute the min and max using doz (asm, difference-of-zero) instruction, for both signed and unsigned integers. But these instructions vary per processor, and for probably that reason, no one has ever added a C/ASM implementation to libc for this. Oh, the millions of CPU cycles wasted.. WHYYYyyyy....
    – Marco
    Commented Oct 31, 2023 at 13:30

17 Answers 17


Where are MIN and MAX defined in C, if at all?

They aren't.

What is the best way to implement these, as generically and type safe as possible (compiler extensions/builtins for mainstream compilers preferred).

As functions. I wouldn't use macros like #define MIN(X, Y) (((X) < (Y)) ? (X) : (Y)), especially if you plan to deploy your code. Either write your own, use something like standard fmax or fmin, or fix the macro using GCC's typeof (you get typesafety bonus too) in a GCC statement expression:

 #define max(a,b) \
   ({ __typeof__ (a) _a = (a); \
       __typeof__ (b) _b = (b); \
     _a > _b ? _a : _b; })

Everyone says "oh I know about double evaluation, it's no problem" and a few months down the road, you'll be debugging the silliest problems for hours on end.

Note the use of __typeof__ instead of typeof:

If you are writing a header file that must work when included in ISO C programs, write __typeof__ instead of typeof.

  • 87
    You know, it'd be quite handy if gcc had a warning along the lines of: warning: expression with side-effects multiply evaluated by macro at the point of use...
    – caf
    Commented Aug 9, 2010 at 5:28
  • 31
    @caf: wouldn't that require that the preprocessor have a more complicated knowledge of C syntax?
    – dreamlax
    Commented Aug 9, 2010 at 5:34
  • 3
    After much trying to figure out, I don't think there's anyway to do this in VC++, but your best best is to try to mess with MSVC++ 2010 new decltype keyword -- but even so, Visual Studio can't do compound statements in macros (and decltype is C++ anyway), i.e. GCC's ({ ... }) syntax so I'm pretty sure it's not possible, anyway. I haven't looked at any other compilers regarding this issue, sorry Luther :S Commented Aug 10, 2010 at 6:08
  • 11
    @dreamlax I once saw a case where someone had done MAX(someUpperBound, someRandomFunction()) to limit a random value to some upper bound. It was a terrible idea, but it also didn't even work, because the MAX he was using had the double evaluation problem, so he ended up with a different random number than the one that was initially evaluated. Commented Aug 12, 2014 at 17:15
  • 17
    @Soumen For example, if you call MIN(x++, y++) the preprocessor will generate the following code (((x++) < (y++)) ? (x++) : (y++)). So, x and y will be incremented twice.
    – Antonio
    Commented May 13, 2016 at 14:51

It's also provided in the GNU libc (Linux) and FreeBSD versions of sys/param.h, and has the definition provided by dreamlax.

On Debian:

$ uname -sr
Linux 2.6.11

$ cat /etc/debian_version

$ egrep 'MIN\(|MAX\(' /usr/include/sys/param.h
#define MIN(a,b) (((a)<(b))?(a):(b))
#define MAX(a,b) (((a)>(b))?(a):(b))

$ head -n 2 /usr/include/sys/param.h | grep GNU
This file is part of the GNU C Library.

On FreeBSD:

$ uname -sr

$ egrep 'MIN\(|MAX\(' /usr/include/sys/param.h
#define MIN(a,b) (((a)<(b))?(a):(b))
#define MAX(a,b) (((a)>(b))?(a):(b))

The source repositories are here:

  • I've added the definitions from the systems I have access to in my answer above (the comment field doesn't accept formatting as far as I can tell). Will try to find the links to the FreeBSD/Linux/glibc source repos.
    – Mikel
    Commented Aug 15, 2010 at 2:30
  • +1. Very nice. Works for openSUSE/Linux 3.1.0-1.2-desktop/gcc version 4.6.2 (SUSE Linux) too. :) Bad it's not portable.
    – Jack
    Commented Jul 26, 2012 at 18:08
  • Works on Cygwin too. Commented May 29, 2017 at 17:51
  • 7
    Wait a moment. It doesn't prevent double evaluation, does it? :3 Commented Nov 28, 2017 at 15:37

There's a std::min and std::max in C++, but AFAIK, there's no equivalent in the C standard library. You can define them yourself with macros like

#define MAX(x, y) (((x) > (y)) ? (x) : (y))
#define MIN(x, y) (((x) < (y)) ? (x) : (y))

But this causes problems if you write something like MAX(++a, ++b).

  • 13
    why putting too much brackets??? I found a quiz where they said #define MIN(A, B) ((A < B) ? A : B) is not a flexible way, why???
    – user2948075
    Commented Nov 4, 2014 at 15:05
  • 115
    @Makouda: Extra parentheses in macros help to avoid operator precedence problems. For example, consider #define MULT(x, y) x * y. Then MULT(a + b, a + b) expands to a + b * a + b, which parses as a + (b * a) + b due to precedence. That's not what the programmer probably intended.
    – dan04
    Commented Nov 5, 2014 at 1:09
  • 1
    that not needed when ?: has the lowest precedence anyway
    – wingerse
    Commented Dec 6, 2018 at 19:27
  • 6
    @WingerSendon: It doesn't; the comma operator does.
    – dan04
    Commented Jan 10, 2019 at 23:22
  • 2
    But you can't pass an expression with comma operator as a parameter to a macro unless you parenthesize it anyway
    – Ruslan
    Commented Feb 2, 2021 at 20:28

@David Titarenco nailed it here, but let me at least clean it up a bit to make it look nice, and show both min() and max() together to make copying and pasting from here easier. :)

Update 25 Apr. 2020: I've also added a Section 3 to show how this would be done with C++ templates too, as a valuable comparison for those learning both C and C++, or transitioning from one to the other. I've done my best to be thorough and factual and correct to make this answer a canonical reference I can come back to again and again, and I hope you find it as useful as I do.

1. The old C macro way:

This technique is commonly used, well-respected by those who know how to use it properly, the "de facto" way of doing things, and fine to use if used properly, but buggy (think: double-evaluation side effect) if you ever pass expressions including variable assignment in to compare:

#define MAX(a,b) ((a) > (b) ? (a) : (b))
#define MIN(a,b) ((a) < (b) ? (a) : (b))

2. The new and improved gcc and clang "statement expression" way:

This technique avoids the above "double-evaluation" side effects and bugs, and is therefore considered the superior, safer, and "more modern" GCC C way to do this. Expect it to work with both the gcc and clang compilers, since clang is, by design, gcc-compatible (see the clang note at the bottom of this answer).

BUT: DO watch out for "variable shadowing" effects still, as statement expressions are apparently inlined and therefore do NOT have their own local variable scope!

#define max(a,b)             \
({                           \
    __typeof__ (a) _a = (a); \
    __typeof__ (b) _b = (b); \
    _a > _b ? _a : _b;       \

#define min(a,b)             \
({                           \
    __typeof__ (a) _a = (a); \
    __typeof__ (b) _b = (b); \
    _a < _b ? _a : _b;       \

Note that in gcc statement expressions, the last expression in the code block is what is "returned" from the expression, as though it was returned from a function. GCC's documentation says it this way:

The last thing in the compound statement should be an expression followed by a semicolon; the value of this subexpression serves as the value of the entire construct. (If you use some other kind of statement last within the braces, the construct has type void, and thus effectively no value.)

3. [C++ only] The C++ template way:

C++ Note: if using C++, templates are probably recommended for this type of construct instead, but I personally dislike templates and would probably use one of the above constructs in C++ anyway, as I frequently use and prefer C styles in embedded C++ as well.

This section added 25 Apr. 2020:

I've been doing a ton of C++ the past few months, and the pressure to prefer templates over macros, where able, in the C++ community is quite strong. As a result, I've been getting better at using templates, and want to put in the C++ template versions here for completeness and to make this a more canonical and thorough answer.

Here's what basic function template versions of max() and min() might look like in C++:

template <typename T>
T max(T a, T b)
    return a > b ? a : b;

template <typename T>
T min(T a, T b)
    return a < b ? a : b;

Do additional reading about C++ templates here: Wikipedia: Template (C++).

However, both max() and min() are already part of the C++ standard library, in the <algorithm> header (#include <algorithm>). In the C++ standard library they are defined slightly differently than I have them above. The default prototypes for std::max<>() and std::min<>(), for instance, in C++14, looking at their prototypes in the cplusplus.com links just above, are:

template <class T> 
constexpr const T& max(const T& a, const T& b);

template <class T> 
constexpr const T& min(const T& a, const T& b);

Note that the keyword typename is an alias to class (so their usage is identical whether you say <typename T> or <class T>), since it was later acknowledged after the invention of C++ templates, that the template type might be a regular type (int, float, etc.) instead of only a class type.

Here you can see that both of the input types, as well as the return type, are const T&, which means "constant reference to type T". This means the input parameters and return value are passed by reference instead of passed by value. This is like passing by pointers, and is more efficient for large types, such as class objects. The constexpr part of the function modifies the function itself and indicates that the function must be capable of being evaluated at compile-time (at least if provided constexpr input parameters), but if it cannot be evaluated at compile-time, then it defaults back to a run-time evaluation, like any other normal function.

The compile-time aspect of a constexpr C++ function makes it kind-of C-macro-like, in that if compile-time evaluation is possible for a constexpr function, it will be done at compile-time, same as a MIN() or MAX() macro substitution could possibly be fully evaluated at compile-time in C or C++ too. For additional references for this C++ template info, see below.

4. [C++ only] C++ std::max()

If using C++, I'd like to add that the built-in std::max() function in the <algorithm> header file has a variety of forms. See the "Possible implementation" section on the documentation page at the cppreference.com community wiki (https://en.cppreference.com/w/cpp/algorithm/max) for 4 possible implementations for the 4 forms of std::max().

Normal usages include:

std::max(100, 200);

...but if you'd like to compare many numbers at once, you can use the 4th form, which accepts a std::initializer_list<T>, like this:

Function declaration:

template< class T, class Compare >
constexpr T max( std::initializer_list<T> ilist, Compare comp );


// Compare **3 or more numbers** by passing a curly-brace-initialized
// `std::initializer_list<>` to `std::max()`!:

std::max({100, 200, 300});                  // result is 300
std::max({100, 200, 300, 400});             // result is 400
std::max({100, 200, 300, 400, 500});        // result is 500
std::max({100, 200, 300, 400, 500, 600});   // result is 600
// etc.


  1. https://gcc.gnu.org/onlinedocs/gcc/Typeof.html#Typeof
  2. https://gcc.gnu.org/onlinedocs/gcc/Statement-Exprs.html#Statement-Exprs
  3. MIN and MAX in C
  4. Additional C++ template references added Apr. 2020:
  5. *****Wikipedia: Template (C++) <-- GREAT additional info about C++ templates!
  6. (My own question & answer): Why is `constexpr` part of the C++14 template prototype for `std::max()`?
  7. What's the difference between constexpr and const?

Clang note from Wikipedia:

[Clang] is designed to act as a drop-in replacement for the GNU Compiler Collection (GCC), supporting most of its compilation flags and unofficial language extensions.


  1. [my answer] Rounding integer division (instead of truncating) - I also use macros, gcc/clang statement expressions, and C++ templates here.
  • 6
    what is the point of the huge section about c++ when this question asks about c? all it does is replicate what std::max() and std::min() already do.
    – qwr
    Commented Jul 1, 2020 at 21:51
  • 1
    @qwr: The point: 1) to learn, 2) to replicate what std::max() and std::min() already do, so you can understand how they work (to learn), 3) to learn C++ from C, since many people start with C and then need to learn C++ too, or vice versa, so having both the C and the C++ answer together is helpful for anyone who writes in both. Myself, for instance: I'm an embedded software engineer. Sometimes I work on C code bases, and I come here to copy and paste verbatim my macro or gcc statement expression answers, and sometimes I work in C++ code bases and read my notes here to remember templates. Commented Jul 1, 2020 at 22:02
  • 1
    that is completely off-topic for this question
    – qwr
    Commented Jul 1, 2020 at 22:04
  • 8
    I wholeheartedly disagree: no answerer should be punished for going the extra mile and giving an answer more thorough than what is asked. Many people land on this page who are benefited by the extra information. But if you don't like it, close your eyes once you get to that part. Re-open them when you've sufficiently scrolled down the page. I made bold headings to make it clear when the C++ part starts, so one can easily ignore it if it is not applicable to their situation. Commented Jul 1, 2020 at 22:05
  • 1
    Note on solution 2 : variable shadowing can be mitigated to the extreme impossible by choosing something else that a and b for the name of arguments.. a<GUID> et b<GUID> et voila
    – sandwood
    Commented Oct 13, 2023 at 10:20

Avoid non-standard compiler extensions and implement it as a completely type-safe macro in pure standard C (ISO 9899:2011).


#define GENERIC_MAX(x, y) ((x) > (y) ? (x) : (y))

#define ENSURE_int(i)   _Generic((i), int:   (i))
#define ENSURE_float(f) _Generic((f), float: (f))

#define MAX(type, x, y) \
  (type)GENERIC_MAX(ENSURE_##type(x), ENSURE_##type(y))


MAX(int, 2, 3)


The macro MAX creates another macro based on the type parameter. This control macro, if implemented for the given type, is used to check that both parameters are of the correct type. If the type is not supported, there will be a compiler error.

If either x or y is not of the correct type, there will be a compiler error in the ENSURE_ macros. More such macros can be added if more types are supported. I've assumed that only arithmetic types (integers, floats, pointers etc) will be used and not structs or arrays etc.

If all types are correct, the GENERIC_MAX macro will be called. Extra parenthesis are needed around each macro parameter, as the usual standard precaution when writing C macros.

Then there's the usual problems with implicit type promotions in C. The ?:operator balances the 2nd and 3rd operand against each other. For example, the result of GENERIC_MAX(my_char1, my_char2) would be an int. To prevent the macro from doing such potentially dangerous type promotions, a final type cast to the intended type was used.


We want both parameters to the macro to be of the same type. If one of them is of a different type, the macro is no longer type safe, because an operator like ?: will yield implicit type promotions. And because it does, we also always need to cast the final result back to the intended type as explained above.

A macro with just one parameter could have been written in a much simpler way. But with 2 or more parameters, there is a need to include an extra type parameter. Because something like this is unfortunately impossible:

// this won't work
#define MAX(x, y)                                  \
  _Generic((x),                                    \
           int: GENERIC_MAX(x, ENSURE_int(y))      \
           float: GENERIC_MAX(x, ENSURE_float(y))  \

The problem is that if the above macro is called as MAX(1, 2) with two int, it will still try to macro-expand all possible scenarios of the _Generic association list. So the ENSURE_float macro will get expanded too, even though it isn't relevant for int. And since that macro intentionally only contains the float type, the code won't compile.

To solve this, I created the macro name during the pre-processor phase instead, with the ## operator, so that no macro gets accidentally expanded.


#include <stdio.h>

#define GENERIC_MAX(x, y) ((x) > (y) ? (x) : (y))

#define ENSURE_int(i)   _Generic((i), int:   (i))
#define ENSURE_float(f) _Generic((f), float: (f))

#define MAX(type, x, y) \
  (type)GENERIC_MAX(ENSURE_##type(x), ENSURE_##type(y))

int main (void)
  int    ia = 1,    ib = 2;
  float  fa = 3.0f, fb = 4.0f;
  double da = 5.0,  db = 6.0;

  printf("%d\n", MAX(int,   ia, ib)); // ok
  printf("%f\n", MAX(float, fa, fb)); // ok

//printf("%d\n", MAX(int,   ia, fa));  compiler error, one of the types is wrong
//printf("%f\n", MAX(float, fa, ib));  compiler error, one of the types is wrong
//printf("%f\n", MAX(double, fa, fb)); compiler error, the specified type is wrong
//printf("%f\n", MAX(float, da, db));  compiler error, one of the types is wrong

//printf("%d\n", MAX(unsigned int, ia, ib)); // wont get away with this either
//printf("%d\n", MAX(int32_t, ia, ib)); // wont get away with this either
  return 0;
  • 2
    That GENERIC_MAX macro is a bad idea by the way, you only have to try GENERIC_MAX(var++, 7) to find out why :-) Nowadays (especially with heavily optimising/inlining compilers), macros should pretty much be relegated to the simple forms only. The function-like ones are better as functions and the value-group ones better as enumerations.
    – paxdiablo
    Commented Sep 27, 2019 at 11:43
  • 1
    @paxdiablo Except _Generic function-like macros have better type safety than functions. As for anyone using horrible coding styles where ++ is mixed with other things in the same expression - well, that horrible coding style is their actual problem. It would however be possible to copy each parameter into a compound literal to avoid the multiple evaluations problem: ENSURE_##type( (type){x} )
    – Lundin
    Commented Apr 14, 2023 at 6:22
  • Interesting novel approach. Note that MAX(float, fa, fb) differs from MAX(float, fa, fb) when one of fa, fb is NAN. Commented May 22, 2023 at 14:29
  • @chux-ReinstateMonica For floating point numbers this whole thing is irrelevant anyway, since standard C got fmax etc functions at least since C99.
    – Lundin
    Commented May 23, 2023 at 6:49

This is a late answer, due to a fairly recent development. Since the OP accepted the answer that relies on a non-portable GCC (and clang) extension typeof - or __typeof__ for 'clean' ISO C - there's a better solution available as of gcc-4.9.

#define max(x,y) ( \
    { __auto_type __x = (x); __auto_type __y = (y); \
      __x > __y ? __x : __y; })

The obvious benefit of this extension is that each macro argument is only expanded once, unlike the __typeof__ solution.

__auto_type is a limited form of C++11's auto. It cannot (or should not?) be used in C++ code, though there's no good reason not to use the superior type inference capabilities of auto when using C++11.

That said, I assume there are no issues using this syntax when the macro is included in an extern "C" { ... } scope; e.g., from a C header. AFAIK, this extension has not found its way info clang

  • Related to Brett Hale's comment, clang started supporting __auto_type around 2016 (see patch).
    – Lars
    Commented Feb 7, 2019 at 15:21
  • Kudos for recognising the macro problem but I'd still posit that a function would probably be better :-)
    – paxdiablo
    Commented Sep 27, 2019 at 11:44
  • @paxdiablo - I agree, though the question has the c-preprocessor tag. A function is not guaranteed to be inlined even with said keyword, unless using something like gcc's __always_inline__ attribute.
    – Brett Hale
    Commented Oct 2, 2019 at 5:06
  • 1
    This still uses the GCC (and clang) ({ ... }) extension. I don't think it's any more portable than the version with typeof (with or without underscores).
    – zwol
    Commented Apr 29, 2021 at 14:15

I don't think that they are standardised macros. There are standardised functions for floating point already, fmax and fmin (and fmaxf for floats, and fmaxl for long doubles).

You can implement them as macros as long as you are aware of the issues of side-effects/double-evaluation.

#define MAX(a,b) ((a) > (b) ? a : b)
#define MIN(a,b) ((a) < (b) ? a : b)

In most cases, you can leave it to the compiler to determine what you're trying to do and optimise it as best it can. While this causes problems when used like MAX(i++, j++), I doubt there is ever much need in checking the maximum of incremented values in one go. Increment first, then check.

  • This should be the preferred answer as there clearly are min and max functions in the math library : cplusplus.com/reference/cmath/fmax
    – imranal
    Commented Jan 20, 2016 at 17:55
  • @imranal What are you exactly speaking about? The implementation code of those library? But that code is not exposed, i.e. they are not placing it in the interface of the library, being potentially unsafe.
    – Antonio
    Commented May 13, 2016 at 14:53
  • 1
    @Antonio I think you are using incorrect definitions of "exposed" and "interface". The interface of a c library are the externed variables, types, macros, and function declarations in a header file; fmin/fmax are declared in the header file, so they are said to be exposed. I am not sure what you are referring to as unsafe though. Commented Jun 27, 2016 at 0:28

I wrote this version that works for MSVC, GCC, C, and C++.

#if defined(__cplusplus) && !defined(__GNUC__)
#   include <algorithm>
#   define MIN std::min
#   define MAX std::max
//#   define TMIN(T, a, b) std::min<T>(a, b)
//#   define TMAX(T, a, b) std::max<T>(a, b)
#       define _CHOOSE2(binoper, lexpr, lvar, rexpr, rvar) \
                ({ \
                        decltype(lexpr) lvar = (lexpr); \
                        decltype(rexpr) rvar = (rexpr); \
                        lvar binoper rvar ? lvar : rvar; \
#       define _CHOOSE_VAR2(prefix, unique) prefix##unique
#       define _CHOOSE_VAR(prefix, unique) _CHOOSE_VAR2(prefix, unique)
#       define _CHOOSE(binoper, lexpr, rexpr) \
                _CHOOSE2( \
                        binoper, \
                        lexpr, _CHOOSE_VAR(_left, __COUNTER__), \
                        rexpr, _CHOOSE_VAR(_right, __COUNTER__) \
#       define MIN(a, b) _CHOOSE(<, a, b)
#       define MAX(a, b) _CHOOSE(>, a, b)
  • 3
    I upvoted but identifiers beginning with an underscore following by an uppercase letter are reserved.
    – dreamlax
    Commented May 30, 2016 at 5:10

If you need min/max in order to avoid an expensive branch, you shouldn't use the ternary operator, as it will compile down to a jump. Bit Twiddling Hacks describes a useful method for implementing a min/max function without branching.

int x;  // we want to find the minimum of x and y
int y;   
int r;  // the result goes here 

r = y ^ ((x ^ y) & -(x < y)); // min(x, y)

To find the maximum, use:

r = x ^ ((x ^ y) & -(x < y)); // max(x, y)

Quick and dirty versions:

If you know that INT_MIN <= x - y <= INT_MAX, then you can use the following, which are faster because (x - y) only needs to be evaluated once.

r = y + ((x - y) & ((x - y) >> (sizeof(int) * CHAR_BIT - 1))); // min(x, y)
r = x - ((x - y) & ((x - y) >> (sizeof(int) * CHAR_BIT - 1))); // max(x, y)
  • 3
    If the compiler is smart enough it can avoid the branch Commented Nov 1, 2011 at 22:38
  • 4
    If optimization is turned on, all modern compilers will emit a conditional move instead of a branch in most cases, so there is little point in using hacks like this. Commented Mar 10, 2015 at 15:15
  • 4
    Absolutely true, I have no idea what I was looking at back then, it's been a while. Both gcc and clang avoid branches with -O, both on x86 and armv7a.
    – cib
    Commented Mar 11, 2015 at 14:57

It's worth pointing out I think that if you define min and max with the ternary operation such as

#define MIN(a,b) (((a)<(b))?(a):(b))
#define MAX(a,b) (((a)>(b))?(a):(b))

then to get the same result for the special case of fmin(-0.0,0.0) and fmax(-0.0,0.0) you need to swap the arguments

fmax(a,b) = MAX(a,b)
fmin(a,b) = MIN(b,a)
  • Still won't work for NaN. fmin(3.0,NaN)==fmin(NaN,3.0)==fmax(3.0,NaN)==fmax(NaN,3.0)==3.0
    – greggo
    Commented Dec 14, 2018 at 17:38

Looks like Windef.h (a la #include <windows.h>) has max and min (lower case) macros, that also suffer from the "double evaluation" difficulty, but they're there for those that don't want to re-roll their own :)


Old GCC Extension: Operators <?, >?, <?=, >?=

In a very old version of GCC there were the operators <?, >? (see here, here it was in C++ but I think it also applied as a C extension back then) I have also seen the operators <?=, >?= corresponding to the assignment statements.

The operands were evaluated once and even allowed for a very short assignment statement. Its very short compared to common min/max assignments. There is nothing that can top this.

Those were a shorthand for the following:

min(a, b)   ===   a < b ? a : b   ===   a <? b;
max(a, b)   ===   a > b ? a : b   ===   a >? b;
a = min(a, b);   ===   if(b < a) a = b;   ===   a <?= b;
a = max(a, b);   ===   if(b > a) a = b;   ===   a >?= b;

Finding the minimum is very concise:

int find_min(const int* ints, int num_ints)
    assert(num_ints > 0);
    int min = ints[0];
    for(int i = 1; i < num_ints; ++i)
        min <?= ints[i];
    return min;

I hope this might be some day brought back to GCC, because I think these operators are genious.


A simple solution as the other answers suggest would be a macro along the lines of:

#define max(a, b) ((a) > (b) ? (a) : (b))

However this can cause unexpected results and unnecessary (re)computation if a and b are complex expressions (with side effects) rather than just variables.

The question did ask for compiler-specific extensions so as the other answers also suggest, a safer option would be to use GCC statement expressions and __typeof__.

#define max(a, b) ({ __typeof__(a) _a = (a); __typeof__(b) _b = (b); _a > _b ? _a : _b; })

This solution is great if you have GCC. But will not work at all otherwise.

A template function would be even better if you are using C++. But the question is tagged so a C++ only answer does not apply to all cases here.

I would like to offer a portable solution. Since the C library already has functions ending in l and ll for larger integer types, we could define our own min and max the same way, to match the functions found in the library, such as abs/absl/absll and div/divl/divll.

static inline int min(const int a, const int b) {
    return a < b ? a : b;
static inline int max(const int a, const int b) {
    return a > b ? a : b;
static inline long minl(const long a, const long b) {
    return a < b ? a : b;
static inline long maxl(const long a, const long b) {
    return a > b ? a : b;
static inline long long minll(const long long a, const long long b) {
    return a < b ? a : b;
static inline long long maxll(const long long a, const long long b) {
    return a > b ? a : b;

This solution is a good substitute for GCC extensions or C++ only features, and is safer than macros. We do not define fmin and fmax and their variants for floating point types because those already exist.


I know the guy said "C"... But if you have the chance, use a C++ template:

template<class T> T min(T a, T b) { return a < b ? a : b; }

Type safe, and no problems with the ++ mentioned in other comments.

  • 17
    Arguments should be const references, you never know what user will pass.
    – nmikhailov
    Commented Jun 12, 2013 at 14:33
  • 10
    Such a function has already been standardised (std::min).
    – dreamlax
    Commented Oct 2, 2017 at 20:25
  • C++ have a lot of standard functions for most of the normal purposes, don't reinvent the wheel. However MS also defines their own min/max which sometimes causes problem
    – phuclv
    Commented Jan 27, 2019 at 2:54

in gcc, you can use this:

#define max(a,b) \
    ({ __typeof__ (a) _a = (a); \
    __typeof__ (b) _b = (b); \
    _a > _b ? _a : _b; })

in msvc, you can use this:

#define SMART_MIN(x, y) \
    ([&]() -> decltype(x) { \
        decltype(x) _min1 = (x); \
        decltype(y) _min2 = (y); \
        return _min1 < _min2 ? _min1 : _min2; \

in this way, can make sure x, y won't be calculated 2 times


The maximum of two integers a and b is (int)(0.5((a+b)+abs(a-b))). This may also work with (double) and fabs(a-b) for doubles (similar for floats)

  • 2
    I am not sure it works with non integers. Floating point math has nonlinear precision. Commented Apr 9, 2014 at 14:41
  • 2
    To expand on @Treesrule14's comment: This doesn't work because computers don't treat numbers the same way as mathematicians. Floating point has rounding issues, so you'd be unlikely to get the right answer. Even if you use integer maths, MAX_INT+MAX_INT gives -2, so max(MAX_INT, MAX_INT) using your formula would come out as -1.
    – user9876
    Commented Apr 28, 2014 at 14:53
  • 0.5 immediately followed by ( does not compile.
    – CPlus
    Commented Apr 4 at 15:39

The simplest way is to define it as a global function in a .h file, and call it whenever you want, if your program is modular with lots of files. If not, double MIN(a,b){return (a<b?a:b)} is the simplest way.

  • @technosaurus, your response is really unhelpful. Tur1ing, it appears that the function is defined completely wrong (missing types on input params, missing semicolon after return statement), and converting int inputs to double is a poor way to do things, so the type should not be double. A define or statement expression would be better here (ex: see here), but if a function, consider making one function to do this for int32_t types, one for uint32_t types, and one for float or double types, for a total of 3 different functions. Commented Oct 27, 2019 at 22:13
  • 3
    @GabrielStaples This answer should be flagged as not an answer - there is no helping it. Although it could be used as an example of how to be the most wrong in the smallest amount of space. Recommending global functions in a header (not static inline even?) will break code with 2+ compilation units, doesn't even compile, naming a function like a macro, implied ints like its 1989, returning a double for no stated reason, implied casts that will cause warnings at best ... and most importantly IT DOESN'T ANSWER THE QUESTION - not generic, not type-safe and most definitely not the best way Commented Oct 28, 2019 at 0:08
  • 1
    Each one of those problems deserves further criticism that cannot be covered in sufficient detail. Commented Oct 28, 2019 at 2:32
  • @technosaurus This should definitely not be flagged as not an answer, because this does attempt to answer the question. Does it answer the question well? Maybe not. But it is not just a link, a comment, a 'thank you' message, a follow-up question.
    – CPlus
    Commented Dec 6, 2023 at 18:15

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