422

I want to use the PI constant and trigonometric functions in some C++ program. I get the trigonometric functions with include <math.h>. However, there doesn't seem to be a definition for PI in this header file.

How can I get PI without defining it manually?

19 Answers 19

490

On some (especially older) platforms (see the comments below) you might need to

#define _USE_MATH_DEFINES

and then include the necessary header file:

#include <math.h>

and the value of pi can be accessed via:

M_PI

In my math.h (2014) it is defined as:

# define M_PI           3.14159265358979323846  /* pi */

but check your math.h for more. An extract from the "old" math.h (in 2009):

/* Define _USE_MATH_DEFINES before including math.h to expose these macro
 * definitions for common math constants.  These are placed under an #ifdef
 * since these commonly-defined names are not part of the C/C++ standards.
 */

However:

  1. on newer platforms (at least on my 64 bit Ubuntu 14.04) I do not need to define the _USE_MATH_DEFINES

  2. On (recent) Linux platforms there are long double values too provided as a GNU Extension:

    # define M_PIl          3.141592653589793238462643383279502884L /* pi */
    
  • 47
    #define _USE_MATH_DEFINES followed by #include <math.h> defines M_PI in visual c++. Thanks. – Etan Nov 13 '09 at 8:30
  • 3
    Works with cygwin headers as well. – Rob Mar 4 '11 at 5:35
  • 1
    works in xcode aswell – madoke Mar 5 '12 at 3:05
  • 19
    You can always include cmath instead of math.h. – Richard J. Ross III Apr 15 '12 at 20:34
  • 9
    Even after defining _USE_MATH_DEFINES if GCC complains that's because __STRICT_ANSI__ is defined (perhaps you passed -pedantic or -std=c++11) which disallows M_PI to be defined, hence undefine it with -D__STRICT_ANSI__. When defining it yourself, since it's C++, instead of a macro you should constexpr auto M_PI = 3.14159265358979323846;. – legends2k Jan 23 '14 at 10:44
164

Pi can be calculated as atan(1)*4. You could calculate the value this way and cache it.

  • 75
    For c++11 users: constexpr double pi() { return std::atan(1)*4; } – matiu Sep 3 '12 at 16:17
  • 36
    -1: Works only if atan(1)*4 == 3.141592653589793238462643383279502884 (roughly speaking). I wouldn't bet on it. Be normal and use a raw literal to define the constant. Why lose precision when you don't need to? – Thomas Eding Oct 23 '12 at 23:49
  • 29
    One can avoid the multiplication operation with atan2(0, -1);. – legends2k May 29 '13 at 21:18
  • 37
    @matiu atan is not constexpr. – R. Martinho Fernandes Sep 5 '13 at 15:28
  • 39
    Try acos(-1) instead, no need for atan2. – Mehrdad Jul 9 '14 at 11:52
107

You could also use boost, which defines important math constants with maximum accuracy for the requested type (i.e. float vs double).

const double pi = boost::math::constants::pi<double>();

Check out the boost documentation for more examples.

  • 167
    Boost: Boosting the already unnecessary complexity of C++ since 1999! – Dan Moulding Jul 28 '10 at 18:22
  • 41
    Catchy and partly true. On the other hand boost can be phenomenally useful at times... – BuschnicK Jul 29 '10 at 14:52
  • 53
    @DanMoulding: Uhm. Is C the only other language you know? Because all other languages I know, except C, have a standard library which is magnitudes bigger than C++' (e.g. Python, Haskell, C#, PHP, Delphi, Erlang, Java, ......). From personal experience, that elitist not gonna use libs-opinion is a pest and probably the number one reason for bad software written in C++. – Sebastian Mach Jul 9 '13 at 6:15
  • 9
    @Gracchus: Yup. C++ without libraries (or without the new C++11 libraries) is, as much as I like that language and as much as I would like to code everything myself, not very productive. – Sebastian Mach Aug 11 '13 at 10:22
  • 11
    I believe he said complexity not size. Presumably referring to a) the 3 nested namespaces, and b) defining pi as a templated function rather than just a normal constant. – Timmmm Apr 3 '14 at 15:05
69

Get it from the FPU unit on chip instead:

double get_PI()
{
    double pi;
    __asm
    {
        fldpi
        fstp pi
    }
    return pi;
}

double PI = get_PI();
  • 33
    :-) probably not that platform independent, but a nice additional exotic solution! – Etan Jun 4 '15 at 18:25
  • 2
    i love how you though out of the box here ;) – VivienLeger May 10 '18 at 20:49
  • I love this answer. It is particularly useful when targeting older x86 platforms which is a small fad as of late where the optimizing compilers aren't as terribly involved as modern ones. Thanks for this Henrik! – Matt Feb 25 at 4:26
47

I would recommend just typing in pi to the precision you need. This would add no calculation time to your execution, and it would be portable without using any headers or #defines. Calculating acos or atan is always more expensive than using a precalculated value.

const double PI  =3.141592653589793238463;
const float  PI_F=3.14159265358979f;
  • 24
    This is a great example why we should not take this approach, we people make mistakes, rounding, copy&pasting, etc. I think using M_PI is the right approach. – nacho4d Jan 21 '14 at 1:47
  • 7
    If one is doing this in C++11, make the const a constexpr. – legends2k Jan 23 '14 at 10:51
  • 2
    @nacho4d I too prefer M_PI if it's available, but not all systems are POSIX compliant. I think this approach is better than the 4*atan(1) method for the cases where M_PI is not available. – m24p Feb 20 '14 at 16:17
  • 2
    "Calculating acos or atan is always more expensive" is not true. Any modern optimizing compiler knows all about standard math functions and can constant-propagate through them. See e.g. goo.gl/BvdJyr – Nemo Jan 23 '16 at 5:37
  • 2
    @Nemo, Counter example: godbolt.org/g/DsAern As has been said elsewhere, it appears only GCC does this currently and that's likely because it has declared the basic math functions as constexpr. – Parker Coates Jan 4 '17 at 20:19
45

Rather than writing

#define _USE_MATH_DEFINES

I would recommend using -D_USE_MATH_DEFINES or /D_USE_MATH_DEFINES depending on your compiler.

This way you are assured that even in the event of someone including the header before you do (and without the #define) you will still have the constants instead of an obscure compiler error that you will take ages to track down.

  • Good tip. If "you" are a compilation unit then of course you can ensure the macro is defined before anything is included. But if "you" are a header file, it's out of your control. – Steve Jessop Nov 13 '09 at 19:18
  • 3
    In fact even if "you" are a compilation unit... depending on the ordering of the headers is a the shortest path toward maintenance nightmare... – Matthieu M. Nov 13 '09 at 19:37
  • 1
    You don't have to depend on the ordering of the headers, though. It doesn't matter whether headers include each other, provided that you do the #define before you #include anything at all (at least, assuming that nothing #undefs it). Same applies to NDEBUG. – Steve Jessop Nov 14 '09 at 3:13
  • 1
    The very common issue in a project is that if you're compiling with Visual Studio for example you don't know in which order the compiler is going to go through your files so if you use <cmath> in different places it becomes a big pain (especially if it is included by another library you are including). It would have been much better if they put that part outside of the header guards but well can't do much about that now. The compiler directive works pretty well indeed. – meneldal May 18 '15 at 2:18
39

Since the official standard library doesn't define a constant PI you would have to define it yourself. So the answer to your question "How can I get PI without defining it manually?" is "You don't -- or you rely on some compiler-specific extensions.". If you're not concerned about portability you could check your compiler's manual for this.

C++ allows you to write

const double PI = std::atan(1.0)*4;

but the initialization of this constant is not guaranteed to be static. The G++ compiler however handles those math functions as intrinsics and is able to compute this constant expression at compile-time.

  • 14
    The standard does not define pi? You got to be kidding me... – Navin Mar 30 '14 at 5:14
  • 6
    I usually use acos(-1), as you say, they are compile-time evaluated. When I tested M_PI, acos(-1) and atan(1)*4, I got identical values. – Micah Sep 9 '14 at 19:14
  • The traditional way is to use 4*atan(1.): atan is easy to implement and multiplying by 4 is an exact operation. Of course, modern compilers fold (aim to fold) all constants with the required precision, and it's perfectly reasonable to use acos(-1) or even std::abs(std::arg(std::complex<double>(-1.,0.))) which is the inverse of Euler's formula and thus more aesthetically pleasing than it seems (I've added abs because I don't remember how the complex plane is cut or if that's defined at all). – tobi_s Oct 2 '18 at 9:05
30

From the Posix man page of math.h:

   The  <math.h>  header  shall  provide for the following constants.  The
   values are of type double and are accurate within the precision of  the
   double type.

   M_PI   Value of pi

   M_PI_2 Value of pi/2

   M_PI_4 Value of pi/4

   M_1_PI Value of 1/pi

   M_2_PI Value of 2/pi

   M_2_SQRTPI
          Value of 2/ sqrt pi
26

Standard C++ doesn't have a constant for PI.

Many C++ compilers define M_PI in cmath (or in math.h for C) as a non-standard extension. You may have to #define _USE_MATH_DEFINES before you can see it.

15

I would do

template<typename T>
T const pi = std::acos(-T(1));

or

template<typename T>
T const pi = std::arg(-std::log(T(2)));

I would not typing in π to the precision you need. What is that even supposed to mean? The precision you need is the precision of T, but we know nothing about T.

You might say: What are you talking about? T will be float, double or long double. So, just type in the precision of long double, i.e.

template<typename T>
T const pi = static_cast<T>(/* long double precision π */);

But do you really know that there won't be a new floating point type in the standard in the future with an even higher precision than long double? You don't.

And that's why the first solution is beautiful. You can be quite sure that the standard would overload the trigonometric functions for a new type.

And please, don't say that the evaluation of a trigonometric function at initialization is a performance penalty.

  • 1
    Note that arg(log(x)) == π for all 0 < x < 1. – 0xbadf00d Feb 26 '16 at 12:45
8

I generally prefer defining my own: const double PI = 2*acos(0.0); because not all implementations provide it for you.

The question of whether this function gets called at runtime or is static'ed out at compile time is usually not an issue, because it only happens once anyway.

  • 8
    acos(-1) is also pi. – Roderick Taylor Aug 5 '11 at 2:55
  • 3
    It's often less CPU instructions and/or less latency to load an immediate operand than read an operand from a memory location. Also, only expressions that are known at compile-time could be pre-computed (I mean double x = pi * 1.5; and the like). If you ever intend to use PI in crunchy math in tight loops, you better make sure the value is known to the compiler. – Eugene Ryabtsev Aug 19 '14 at 7:55
8

I use following in one of my common header in the project that covers all bases:

#define _USE_MATH_DEFINES
#include <cmath>

#ifndef M_PI
#define M_PI (3.14159265358979323846)
#endif

#ifndef M_PIl
#define M_PIl (3.14159265358979323846264338327950288)
#endif

On a side note, all of below compilers define M_PI and M_PIl constants if you include <cmath>. There is no need to add `#define _USE_MATH_DEFINES which is only required for VC++.

x86 GCC 4.4+
ARM GCC 4.5+
x86 Clang 3.0+
  • Can the downvoter comment on what is wrong with this answer. This is well researched and tested and being in use in real system. I had definitely like to improve it if something is wrong. – Shital Shah Jul 19 '16 at 7:02
  • 1
    FYI, Borland C++ compilers also define M_PI without needing _USE_MATH_DEFINES – Remy Lebeau Jan 25 '18 at 19:20
6

I just came across this article by Danny Kalev which has a great tip for C++14 and up.

template<typename T>
constexpr T pi = T(3.1415926535897932385);

I thought this was pretty cool (though I would use the highest precision PI in there I could), especially because templates can use it based on type.

template<typename T>
T circular_area(T r) {
  return pi<T> * r * r;
}
double darea= circular_area(5.5);//uses pi<double>
float farea= circular_area(5.5f);//uses pi<float>
4

Values like M_PI, M_PI_2, M_PI_4, etc are not standard C++ so a constexpr seems a better solution. Different const expressions can be formulated that calculate the same pi and it concerns me whether they (all) provide me the full accuracy. The C++ standard does not explicitly mention how to calculate pi. Therefore, I tend to fall back to defining pi manually. I would like to share the solution below which supports all kind of fractions of pi in full accuracy.

#include <ratio>
#include <iostream>

template<typename RATIO>
constexpr double dpipart()
{
    long double const pi = 3.14159265358979323846264338327950288419716939937510582097494459230781640628620899863;
    return static_cast<double>(pi * RATIO::num / RATIO::den);
}

int main()
{
    std::cout << dpipart<std::ratio<-1, 6>>() << std::endl;
}
  • 2
    Very nice. It might be necessary to have an "l" or "L" at the end of that number. I get a narrowing warning from my compiler gcc on linux. – Grant Rostig Feb 2 at 0:29
3

C++20 std::numbers::pi

At last, it has arrived: http://eel.is/c++draft/numbers

I expect the usage to be like:

#include <numbers>
#include <iostream>

int main() {
    std::cout << std::numbers::pi << std::endl;
}

I'll give it a try when support arrives to GCC, GCC 9.1.0 with g++-9 -std=c++2a still doesn't support it.

The accepted proposal describes:

5.0. “Headers” [headers] In the table [tab:cpp.library.headers], a new <math> header needs to be added.

[...]

namespace std {
namespace math { 
  template<typename T > inline constexpr T pi_v = unspecified;
    inline constexpr double pi = pi_v<double>;

There is also a std::numbers::e of course :-) How to calculate Euler constant or Euler powered in C++?

These constants use the C++14 variable template feature: C++14 Variable Templates: what is their purpose? Any usage example?

In earlier versions of the draft, the constant was under std::math::pi: http://www.open-std.org/jtc1/sc22/wg21/docs/papers/2019/p0631r7.pdf

2

On windows (cygwin + g++), I've found it necessary to add the flag -D_XOPEN_SOURCE=500 for the preprocessor to process the definition of M_PI in math.h.

  • 1
    Does this work on mingw? – Jerfov2 Dec 27 '15 at 18:34
  • 2
    This is not an answer, but a comment to fritzone's answer. – 0xbadf00d Feb 26 '16 at 12:47
  • 2
    @0xbadf00d: It is a completely standalone answer that provides the steps needed to get M_PI working on a particular platform. That isn't a comment on an answer for some other platform any more that an answer for some other platform is a comment on this one. – Ben Voigt Jun 9 '16 at 19:18
2

C++14 lets you do static constexpr auto pi = acos(-1);

  • 7
    std::acos is not a constexpr. So, your code won't compile. – 0xbadf00d May 5 '16 at 17:05
  • @0xbadf00d I compiled it with g++ – Willy Goat May 6 '16 at 3:00
  • 12
    @WillyGoat: Then g++ is wrong, because acos is not constexpr in C++14, and is not proposed to become constexpr even in C++17 – Ben Voigt Jun 9 '16 at 19:22
1

You can do this:

#include <cmath>
#ifndef M_PI
#define M_PI (3.14159265358979323846)
#endif

If M_PI is already defined in cmath, this won't do anything else than include cmath. If M_PI isn't defined (which is the case for example in Visual Studio), it will define it. In both cases, you can use M_PI to get the value of pi.

This value of pi comes from Qt Creator's qmath.h.

0

Some elegant solutions. I am doubtful that the precision of the trigonometric functions is equal to the precision of the types though. For those that prefer to write a constant value, this works for g++ :-

template<class T>
class X {
public:
            static constexpr T PI = (T) 3.14159265358979323846264338327950288419\
71693993751058209749445923078164062862089986280348253421170679821480865132823066\
47093844609550582231725359408128481117450284102701938521105559644622948954930381\
964428810975665933446128475648233786783165271201909145648566923460;
...
}

256 decimal digit accuracy should be enough for any future long long long double type. If more are required visit https://www.piday.org/million/.

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