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I want to make a function in C that can return PI to X places..

I'm just not sure how... Thanks

Edit: I don't care how slow it is I really just want an algorithm that will return PI at X decimal... Iv been looking at http://bellard.org/pi/ but I don't understand how to get the nth of Pi from this. Thanks

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9  
en.wikipedia.org/wiki/Pi is a good starting place. –  Bill Apr 16 '10 at 16:54
1  
Also, do you need to calculate Pi or simply format Pi? –  Bill Apr 16 '10 at 16:56
    
you can look at Pi Computation record bellard.org/pi/pi2700e9 just for fun.. –  LB40 Apr 16 '10 at 18:41
3  
In a convergent series with alternating positive and negative terms, the series will alternate above and below the target value. So you know from that that the value will always be between term n and term n+1. If term n and term n+1 match for their first k digits, then you know your target value to k digits. So in short, you get k digits of precision by stopping when the first k digits stop changing. (Non-alternating series work differently.) –  Alan Apr 17 '10 at 4:41
1  
More examples of this type of thing here: en.wikipedia.org/wiki/Convergent_series –  Alan Apr 17 '10 at 4:42
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11 Answers

up vote 19 down vote accepted

In calculus there is a thing called Taylor Series which provides an easy way to calculate many irrational values to arbitrary precision.

Pi/4 = 1 - 1/3 + 1/5 - 1/7 + ...
(from http://www.math.hmc.edu/funfacts/ffiles/30001.1-3.shtml )

Keep adding those terms until the number of digits of precision you want stabilize.

Taylor's theorem is a powerful tool, but the derivation of this series using the theorem is beyond the scope of the question. It's standard first-year university calculus and is easily googlable if you're interested in more detail.

Edit: I didn't mean to imply that this is the most practical method to calculate pi. That would depend on why you really need to do it. For practical purposes, you should just copy as many digits as you need from one of the many published versions. I was suggesting this as a simple introduction of how irrational values can be equated to infinite series.

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21  
This taylor series is probably one of the worst ways to generate PI on a computer. You have to have huge precision on your calculations and it'll take many billions of iterations to get past 3.14159. Go ahead, try and see. Or here's a web site that talks about it: cygnus-software.com/misc/pidigits.htm –  indiv Apr 16 '10 at 17:51
2  
@kts: That still doesn't change the fact that you need billions of iterations for any reasonably accurate answer. –  Billy ONeal Apr 16 '10 at 18:12
4  
@user146780: Simple. Notice that the terms are getting successively smaller and are alternately added and subtracted. So when you add a term, you are certainly above the real π. When you subtract, you are certainly below. So the last two partial sums provide an upper and lower bound for the true value. –  slacker Apr 16 '10 at 18:13
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@Alan: OK, but the question clearly says he's trying to write a function that can compute PI to X places... Anyway, I implemented this taylor series and after 1 billion iterations you have "3.14159265". After 3 billion iterations you have the next digit. The digit after that comes after 99 billion iterations. 99 billion. –  indiv Apr 16 '10 at 22:59
2  
Yes, if you want n decimal digits of precision, you'll need something on the order of 10^n iterations. I'm not disputing that it converges slowly. The OP seems to be interested in a learning exercise, not something of practical use. –  Alan Apr 17 '10 at 4:30
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PI

                                    char
                                _3141592654[3141
      ],__3141[3141];_314159[31415],_3141[31415];main(){register char*
      _3_141,*_3_1415, *_3__1415; register int _314,_31415,__31415,*_31,
    _3_14159,__3_1415;*_3141592654=__31415=2,_3141592654[0][_3141592654
   -1]=1[__3141]=5;__3_1415=1;do{_3_14159=_314=0,__31415++;for( _31415
  =0;_31415<(3,14-4)*__31415;_31415++)_31415[_3141]=_314159[_31415]= -
1;_3141[*_314159=_3_14159]=_314;_3_141=_3141592654+__3_1415;_3_1415=
__3_1415    +__3141;for         (_31415 = 3141-
       __3_1415  ;          _31415;_31415--
       ,_3_141 ++,          _3_1415++){_314
       +=_314<<2 ;          _314<<=1;_314+=
      *_3_1415;_31           =_314159+_314;
      if(!(*_31+1)           )* _31 =_314 /
      __31415,_314           [_3141]=_314 %
      __31415 ;* (           _3__1415=_3_141
     )+= *_3_1415             = *_31;while(*
     _3__1415 >=              31415/3141 ) *
     _3__1415+= -             10,(*--_3__1415
    )++;_314=_314             [_3141]; if ( !
    _3_14159 && *             _3_1415)_3_14159
    =1,__3_1415 =             3141-_31415;}if(
    _314+(__31415              >>1)>=__31415 )
    while ( ++ *               _3_141==3141/314
       )*_3_141--=0            ;}while(_3_14159
       ) ; { char *            __3_14= "3.1415";
       write((3,1),            (--*__3_14,__3_14
       ),(_3_14159              ++,++_3_14159))+
      3.1415926; }              for ( _31415 = 1;
     _31415<3141-               1;_31415++)write(
    31415% 314-(                3,14),_3141592654[
  _31415    ] +                "0123456789","314"
  [ 3]+1)-_314;                puts((*_3141592654=0
,_3141592654))                  ;_314= *"3.141592";}

(copied from: here)

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16  
Ohh simple as that! –  user216441 Apr 17 '10 at 18:57
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There are many algorithms for numeric approximation of π.

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As an alternative to JeffH's method of storing every variation, you can just store the maximum number of digits and cut off what you don't need:

#include <string>
#include <iostream>
using std::cout; using std::endl; using std::string;

// The first 99 decimal digits taken from:
// http://www.geom.uiuc.edu/~huberty/math5337/groupe/digits.html
// Add more as needed.
const string pi =
  "1415926535"
  "8979323846"
  "2643383279"
  "5028841971"
  "6939937510"
  "5820974944"
  "5923078164"
  "0628620899"
  "8628034825"
  "342117067";

// A function in C++ that returns pi to X places
string CalcPi(const size_t decimalDigitsCount) 
{
  string returnValue = "3";
  if (decimalDigitsCount > 0)
  {
    returnValue += "." + pi.substr(0, decimalDigitsCount);
  }
  return returnValue;
} 

int main()
{
  // Loop through all the values of "pi at x digits" that we have. 
  for (size_t i = 0; i <= pi.size(); ++i) 
  {
    cout << "pi(" << i << "): " << CalcPi(i) << endl;
  } 
}

http://codepad.org/6mqDa1zj

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3  
Given that pi is not going to change and that 43 digits is enough precision to calculate the circumference of the universe to a tolerance of the width of 1 proton, this is a pretty reasonable. Unfortunately, the question is about calculating the X'th digit and does not necessarily mean you have to get the digits before digit X and it wouldn't really be a solution here as X could be anything! –  Neil Trodden Apr 18 '10 at 19:35
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Try this algorithm. It's probably the fastest known algorithm that doesn't require arbitrary (read huge) precision floats, and can give you the result directly in base 10 (or any other).

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I believe the algorithm you're looking for is what's known as a "Spigot Algorithm." One particular kind is the BBP (Bailey-Borwein-Plouffe) formula.

I believe that's what you're looking for.

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Are you willing to look up values instead of computing them?

Since you didn't explicitly specify that your function has to calculate values, here's a possible solution if you are willing to have an upper limit on the number of digits it can "calculate":

// Initialize pis as far out as you want. 
// There are lots of places you can look up pi out to a specific # of digits.
double pis[] = {3.0, 3.1, 3.14, 3.141, 3.1416}; 

/* 
 * A function that returns pi out to a number of digits (up to a point)
 */
double CalcPi(int x)
{
    // NOTE: Should add range checking here. For now, do not access past end of pis[]
    return pis[x]; 
}

int main()
{
    // Loop through all the values of "pi at x digits" that we have.
    for (int ii=0; ii<(int)sizeof(pis)/sizeof(double); ii++)
    {
        double piAtXdigits = CalcPi(ii);
    }
}

Writing CalcPi() this way (if it meets your needs) has a side benefit of being equally screaming fast for any value of X within your upper limit.

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This solution could be coupled to a "computing solution": the array could be declared in a .hpp and defined (i.e. filled) by a metaprogram generating the corresponding .cpp file. The metaprogram would be parameterized by the maximum number of digits needed, and would compute the values to set them into the array. –  Luc Touraille Apr 16 '10 at 21:37
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You can tell the precision based on the last term you added (or subtracted). Since the amplitude of each term in Alan's sequence is always decreasing and each term alternates in sign, the sum won't change more than the last term.

Translating that babble: After adding 1/5, the sum won't change more than 1/5, so you are precise to within 1/5. Of course, you'll have to multiply this by 4, so you're really only precise to 4/5.

Unfortunately, math doesn't always translate easily into decimal digits.

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haha! way to go.. –  Egon Apr 17 '10 at 18:55
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Here's a paper (PDF) which explores the curious relationship between a sequence of points on the complex plane and how computing their "Mandelbrot number" (for lack a better term ... the number of iterations required to determine that the points in the sequence are not members of the Mandelbrot set) relates to PI.

Practical? Probably not.

Unexpected and interesting? I think so.

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Consider this a rough sketch, but it is a straightforward approach that a beginner could implement.

int x = 9;
double pi = double(22/7);
String piAsString = pi.toString();
String valueAtXPosition = piAsString.subString(x, x+1);
int valueAtXPosAsInt = Integer.parseInt(valueAtXPosition);
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2  
double pi = double(22/7); NO –  Bartek Banachewicz Feb 9 '13 at 14:17
    
This isn't the way to go. Especially if precision is necessary, since 22/7 is a very imprecise approximation. –  Itay Grudev Sep 22 '13 at 14:28
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