Given a real (n), a maximum value this real can be (upper), and a minimum value this real can be (lower), how can we most efficiently clip n, such that it remains between lower and upper?

Of course, using a bunch of if statements can do this, but that's boring! What about more compact and elegant/fun solutions?

My own quick attempt (C/C++):

float clip( float n, float lower, float upper )
    n = ( n > lower ) * n + !( n > lower ) * lower;
    return ( n < upper ) * n + !( n < upper ) * upper;

I'm sure there are other, better ways to do this, that's why I'm putting this out there..!

  • 2
    "cap" usually refers only to an upper limit. The word you want is "clip". – Ignacio Vazquez-Abrams Feb 17 '12 at 6:34
  • Thanks, I've changed it – Alex Z Feb 17 '12 at 6:37
  • 4
    I doubt about efficiency, but your solution really is not readable. Why don't you just define a some kind of "clamp" function and use that. – dbrank0 Feb 17 '12 at 6:42
  • 2
    Also read this related question: stackoverflow.com/questions/427477/… – dbrank0 Feb 17 '12 at 6:56
  • Hmm did a search and missed that :/ Must have been because I was originally using the term cap, not clip/clamp. Thanks – Alex Z Feb 17 '12 at 7:00

13 Answers 13


What about boring, old, readable, and shortest yet:

float clip(float n, float lower, float upper) {
  return std::max(lower, std::min(n, upper));


This expression could also be 'genericized' like so:

template <typename T>
T clip(const T& n, const T& lower, const T& upper) {
  return std::max(lower, std::min(n, upper));


Billy ONeal added:

Note that on windows you might have to define NOMINMAX because they define min and max macros which conflict


Why rewrite something that's already been written for you?

#include <boost/algorithm/clamp.hpp>
boost::algorithm::clamp(n, lower, upper);

As of C++17, this is now part of the STL:

#include <algorithm>
std::clamp(n, lower, upper);
  • 19
    standard answer: because not everyone is willing/allowed/physically able to pull in Boost. However, this implementation was suggested for migration to the stdlib, dunno the current status though. – underscore_d May 29 '16 at 14:40
  • 10
    Looks like it will be standard in C++17: en.cppreference.com/w/cpp/algorithm/clamp – Josh Kelley Jun 16 '16 at 20:43
  • clamp part of Swift standard library too – Warren Burton May 18 '17 at 13:28
  • 1
    @underscore_d don't worry it's part of C++17. until then you can continue constantly reinventing the wheel and avoid using good peer-reviewed portable code. – Trevor Boyd Smith May 4 '18 at 16:02
  • 4
    @TrevorBoydSmith I don't have anything against Boost, and your rather contrived evangelism for it is not needed. That said, it looks like I wasn't wrong in assessing the usual reasons that people don't just do what you want them to do and use Boost, and it's surprisingly not because they just want to annoy you by "avoid[ing] using good peer-reviewed portable code". I also don't see why you edited this existing answer to be completely different when (A) you could've posted your own but also (B) other people already had, but OK. – underscore_d May 5 '18 at 17:18

C++17 is expected to add a clamp function. Courtesy of cppreference.com:

template<class T>
constexpr const T& clamp( const T& v, const T& lo, const T& hi );

template<class T, class Compare>
constexpr const T& clamp( const T& v, const T& lo, const T& hi, Compare comp );

UPDATE: C++17's <algorithm> header added std::clamp(value, low, high).

In older C++ versions, I'd very rarely go beyond...

return n <= lower ? lower : n >= upper ? upper : n;

...or, if you find it more readable keeping the left-to-right ordering of lower, n and upper...

return n <= lower ? lower : n <= upper ? n : upper;

(using <= lower is better than < lower because when n == lower it avoids having to compare with upper)

If you know you might have them, you'd want to check if NaN / Inf etc. are preserved....

I say rarely and not never just because sometimes less branching can be faster, but you'd sure want to profile it and prove it helped and mattered....


You might like the ternary operator:

value = value<lower?lower:value;
value = value>upper?upper:value;

Inelegant, unsafe, costly but branchless:

n= 0.5 * (n + lower + fabs(n - lower));
n= 0.5 * (n + upper - fabs(upper - n));
  • 3
    This is my favourite for sheer obtuseness; but fabs() may contain branches depending on your library. To be REALLY branchless you could substitute fabs(x) with (x * (1 + (x < 0) * -2) – rvalue Jun 12 '14 at 3:48
  • 4
    That assumes that the evaluation of x < 0 is really done branchless. What about extracting the sign bit (msb) from the floating-point representation, cleanly documenting the non-portability? :-) – Yves Daoust Jun 12 '14 at 8:25

the best is clearly

template <typename t>
t clamp2(t x, t min, t max)
if (x < min) x = min;
if (x > max) x = max;
return x;

as it compiles to

movss   xmm0, cs:__real@c2c80000
maxss   xmm0, [rsp+38h+var_18]
movss   xmm1, cs:__real@42c80000
minss   xmm1, xmm0
movss   [rsp+38h+var_18], xmm1

it has 0 branches and should be the fastest of all posted above.

also msvc141 with the standard release settings

n = n + ((n < lower) * (lower - n)) + ((n > upper) * (upper - n));

The hyperbolic tangent function does just that in quite an elegant manner (used a lot for neural networks). See code below.

Tanh function axed on 0

float clip(float x, float min, float max) {
  return ((max-min)/2)*((exp(x) - exp(-x))/(exp(x) + exp(-x))) + max - (max-min)/2;
  • 3
    haha, oh wow. this may be elegant in the eyes of skilled mathematicians, but not i suspect to general readers, and i doubt it satisfies the "efficient" bit either. worth documenting, though, i guess ;-) – underscore_d May 29 '16 at 14:43
  • 11
    This does not do the kind of clipping intended by OP. clip(x, min, max) must return min for x < min, x for x in [min, max], and max for x > max. – Norman Jul 24 '16 at 17:07
  • We have other answers trying to optimize the original question to avoid CPU branches, and then we have four calls to exponential functions here. :) And an answer that is only useful for modelling the output of a neuron (with unity gain!), not a digital calculation. – Mark Lakata Mar 7 at 23:26

If you wish to use xtensor, it would support multi-dimensional arrays and the solution would be very elegant.

#include <iostream>
#include "xtensor/xarray.hpp"
#include "xtensor/xio.hpp"
#include "xtensor/xview.hpp"
#include "xtensor/xrandom.hpp"
xt::xarray<float> ar({2.1, 2.9, -2.1, -2.9});

//Answer is { 2, 2, -2, -2 }


A warning to anyone trying to do something like this, where you clamp to the possible values of the input type.

template<typename T>
T clamp(T input)
    return boost::algorithm::clamp(input, 

This will fail for some values of T and input. For example:


will return


Try it and see. The problem is that input is cast to T on entry to the function, before the comparisons are made. And if you static_cast<int16_t>(+32768), you get UB.

I don't have a good solution, other than the code below which is "better" but not complete. This works for small integer types (int16_t and int32_t) and single precision float, but has problems with int64_t and double.

template<typename T>
T clamp(double input)
    double intermediate = return boost::algorithm::clamp<double>(input, 
    return boost::numeric_cast<T>(intermediate);

The following header file should work for C and C++. Note that it undefines min and max if the macros are already defined:

#pragma once

#ifdef min
#undef min

#ifdef max
#undef max

#ifdef __cplusplus
#include <algorithm>

template <typename T>
T clip(T in, T low, T high)
    return std::min(std::max(in, low), high);
#else /* !__cplusplus */
#define min(a, b) (((a) < (b)) ? (a) : (b))
#define max(a, b) (((a) < (b)) ? (b) : (a))
#define clip(a, b, c) min(max((a), (b)), (c))
#endif /* __cplusplus */
  • 2
    why the f*** MS defined its own MIN MAX, and why the heck something like clamping a value is not in the C++ standard library? – GameDeveloper Apr 21 '15 at 22:28
  • 2
    @DarioOO Replying a bit late, but std::clamp() is available since C++17 – Calchas Aug 30 '16 at 15:49
  • 1
    it was about the time! XD – GameDeveloper Aug 30 '16 at 15:51
  • use #define NOMINMAX instead of #undefing them – phuclv Aug 8 '18 at 3:40

If performance really matters to you, what about an inline solution that avoids assignment when not required:

#define clip(n, lower, upper) if (n < lower) n= lower; else if (n > upper) n= upper
  • 9
    An inline function would avoid some of the general problems with macros... no reason to use macros here. – Tony Delroy Feb 20 '12 at 4:47
  • 1
    You are right, under MSVC 2003, the inline solution is even slightly faster than the macro ! For info: when the value is in-range / out-of-range, computation takes 2 / 7 ns on my machine (@2.2 GHz). – Yves Daoust Feb 20 '12 at 10:34
  • 2
    I'd put the "slightly faster" down to noise in your profiling. You could examine the assembly generated by the compiler, and it's likely the same or trivially different (e.g. in arbitary choice of registers). There's no inherent reason for the code to be different, and even when it is - either one could be better. But, macros suffer from various issues. See parashift.com/c++-faq-lite/inline-functions.html if you're interested in this stuff. – Tony Delroy Feb 20 '12 at 10:44
  • 1
    I took care of the repeatability issue in timing measurements. The time difference is consistent. But for practical purposes, it is insignificant. – Yves Daoust Feb 20 '12 at 11:09
  • 2
    @YvesDaoust As to how you'd write the function, I'd start with template<typename T> void clip(T &n, T const &lower, T const &upper) { ... } and take it from there. Using your macro with int n float lower and unsigned int upper is just looking for trouble with a capital T. Pun intended. – dgnuff Mar 29 '16 at 21:49

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