Tag Info

Hot answers tagged


Since I'm the current world record holder for the most digits of pi, I'll add my two cents: Unless you're actually setting a new world record, the common practice is just to verify the computed digits against the known values. So that's simple enough. In fact, I have a webpage that lists snippets of digits for the purpose of verifying computations against ...


The Monte Carlo method, as mentioned, applies some great concepts but it is, clearly, not the fastest --not by a long shot, not by any reasonable usefulness. Also, it all depends on what kind of accuracy you are looking for. The fastest pi I know of is the digits hard coded. Looking at Pi and Pi[PDF], there are a lot of formulas. Here is a method that ...


I really like this program, which approximates pi by looking at its own area :-) IOCCC 1988 : westley.c


Here's a general description of a technique for calculating pi that I learnt in high school. I only share this because I think it is simple enough that anyone can remember it, indefinitely, plus it teaches you the concept of "Monte-Carlo" methods -- which are statistical methods of arriving at answers that don't immediately appear to be deducible through ...


This style ensures that the maximum precision available on ANY architecture is used when assigning a value to PI.


Expanding on my comments. There's a very important concept here that's called information entropy. Out of full disclosure, I'm the current world record holder of the digits of Pi at 10 trillion digits (10^13). I have approximately 10,000 copies of everyone's social security number. However that doesn't mean I can just hack into everyone's accounts and ...


If you want recursion: PI = 2 * (1 + 1/3 * (1 + 2/5 * (1 + 3/7 * (...)))) This would become, after some rewriting: PI = 2 * F(1); with F(i): double F (int i) { return 1 + i / (2.0 * i + 1) * F(i + 1); } Isaac Newton (you may have heard of him before ;) ) came up with this trick. Note that I left out the end condition, to keep it simple. In real ...


Apparently %lld is the most common way, but that doesn't work on the compiler that I'm using (mingw32-gcc v4.6.0). The way to do it on this compiler is: %I64d So try this: if(e%n==0)printf("%15I64d -> %1.16I64d\n",e, 4*pi); and scanf("%I64d", &n); The only way I know of for doing this in a completely portable way is to use the defines in ...


Undoubtedly, for your purposes (which I assume is just a programming exercise), the best thing is to check your results against any of the listings of the digits of pi on the web. And how do we know that those values are correct? Well, I could say that there are computer-science-y ways to prove that an implementation of an algorithm is correct. More ...


In the interests of completeness, a C++ template version, which in an optimised build will compute PI at compile time and will inline to a single value. #include <iostream> template<int I> struct sign { enum {value = (I % 2) == 0 ? 1 : -1}; }; template<int I, int J> struct pi_calc { inline static double value () { ...


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 ...


You forgot parentheses around 4*t: pi = (a+b)**2 / (4*t) You can use decimal to perform calculation with higher precision. #!/usr/bin/env python from __future__ import with_statement import decimal def pi_gauss_legendre(): D = decimal.Decimal with decimal.localcontext() as ctx: ctx.prec += 2 a, b, t, p = 1, ...


Well, i % 1000 will never = 0, as your counter runs from i = 1, then in increments of 2. Hence, i is always odd, and will never be a multiple of 1000. The reason it never terminates is that the algorithm doesn't converge to exactly 3.14157 - it'll be a higher precision either under or over approximation. You want to say "When within a given delta of ...


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, ...


There are many algorithms for numeric approximation of π.


There's actually a whole book dedicated (amongst other things) to fast methods for the computation of \pi: 'Pi and the AGM', by Jonathan and Peter Borwein (available on Amazon). I studied the AGM and related algorithms quite a bit: it's quite interesting (though sometimes non-trivial). Note that to implement most modern algorithms to compute \pi, you will ...


How about using: double pi = Math.PI; If you want better precision than that, you will need to use an algorithmic system and the Decimal type.


You're missing the multiplication operator. Also, you want to do 4/3 in floating point, not integer math. volume = (4.0 / 3) * Math.PI * Math.pow(radius, 3); ^^ ^


Because we were all kind of bored in the Lounge I went ahead and implemented a search to find out the average offsets of 'messages' of specific lengths. I downloaded 1 million digits of Pi and looked for all subsequences of fixed length (e.g. 00..99). Depending on the message lenght, you get the following outputs: Digits Avg.Offset Unfound 1 ...


This is a classic example of Monte Carlo. But if you're trying to break the calculation of pi into parallel parts, why not just use an infinite series and let each core take a range, then sum the results as you go? http://mathworld.wolfram.com/PiFormulas.html


Mathematically, computers are both finite and non-continuous and therefore can neither know PI completely, nor correctly render a circle. However, in the digital realm neither of these exist anyway, so it is sufficient to approximate PI and then use that to approximately render the circle, resulting in exactly the same pixels that would have been calculated ...


You are using float in the Cython version -- that's single precision! Use double instead, which corresponds to Python's float (funnily enough). The C type float only has about 8 significant decimal digits, whereas double or Python's float have about 16 digits.


The following answers precisely how to do this in the fastest possible way -- with the least computing effort. Even if you don't like the answer, you have to admit that it is indeed the fastest way to get the value of PI. The FASTEST way to get the value of Pi is: chose your favorite programming language load it's Math library and find that Pi is already ...


This is Matlab >> sin(pi) ans = 1.2246e-016 And here's Python >>> from math import sin, pi >>> sin(pi) 1.2246467991473532e-16 You're running into the limits of floating point precision. I recommend having a read of What Every Computer Scientist Should Know About Floating Point Arithmetic. The e at the end of these numbers ...


The problem seems to be that multiprocessing has a limit to the largest int it can pass to subprocesses inside an xrange. Here's a quick test: import sys from multiprocessing import Pool def doit(n): print n if __name__ == "__main__": procs = int(sys.argv[1]) iters = int(float(sys.argv[2])) p = Pool(processes=procs) for points in p.map(doit, ...


You could use multiple approaches and see if they converge to the same answer. Or grab some from the 'net. The Chudnovsky algorithm is usually used as a very fast method of calculating pi. http://www.craig-wood.com/nick/articles/pi-chudnovsky/


The >> operator when used with numbers is right shift, not assignment. You want something like area = a * a * pi; Update You also need to use a floating point type or your answer won't be what you expect. float a; float pi = 3.14f; float area;


The BBP formula allows you to compute the nth digit - in base 2 (or 16) - without having to even bother with the previous n-1 digits first :)


The easiest way to do this would probably just have a std::string containing the digits that you want ("3.14159265358979323846264338327950288419"), and then just print the first input digits beyond the decimal point.


If you don't want to implement your own algorithm, you can use SymPy. from sympy.mpmath import mp mp.dps = 1000 # number of digits print(mp.pi) # print pi to a thousand places Reference

Only top voted, non community-wiki answers of a minimum length are eligible