I'm trying to generate a list of primes below 1 billion. I'm trying this, but this kind of structure is pretty shitty. Any suggestions?
a <- 1:1000000000
d <- 0
b <- for (i in a) {for (j in 1:i) {if (i %% j !=0) {d <- c(d,i)}}}
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I'm trying to generate a list of primes below 1 billion. I'm trying this, but this kind of structure is pretty shitty. Any suggestions?
a <- 1:1000000000
d <- 0
b <- for (i in a) {for (j in 1:i) {if (i %% j !=0) {d <- c(d,i)}}}
This is an implementation of the Sieve of Eratosthenes algorithm in R.
sieve <- function(n)
{
n <- as.integer(n)
if(n > 1e6) stop("n too large")
primes <- rep(TRUE, n)
primes[1] <- FALSE
last.prime <- 2L
for(i in last.prime:floor(sqrt(n)))
{
primes[seq.int(2L*last.prime, n, last.prime)] <- FALSE
last.prime <- last.prime + min(which(primes[(last.prime+1):n]))
}
which(primes)
}
sieve(1000000)
That sieve posted by George Dontas is a good starting point. Here's a much faster version with running times for 1e6 primes of 0.095s as opposed to 30s for the original version.
sieve <- function(n)
{
n <- as.integer(n)
if(n > 1e8) stop("n too large")
primes <- rep(TRUE, n)
primes[1] <- FALSE
last.prime <- 2L
fsqr <- floor(sqrt(n))
while (last.prime <= fsqr)
{
primes[seq.int(2L*last.prime, n, last.prime)] <- FALSE
sel <- which(primes[(last.prime+1):(fsqr+1)])
if(any(sel)){
last.prime <- last.prime + min(sel)
}else last.prime <- fsqr+1
}
which(primes)
}
Here are some alternate algorithms below coded about as fast as possible in R. They are slower than the sieve but a heck of a lot faster than the questioners original post.
Here's a recursive function that uses mod but is vectorized. It returns for 1e5 almost instantaneously and 1e6 in under 2s.
primes <- function(n){
primesR <- function(p, i = 1){
f <- p %% p[i] == 0 & p != p[i]
if (any(f)){
p <- primesR(p[!f], i+1)
}
p
}
primesR(2:n)
}
The next one isn't recursive and faster again. The code below does primes up to 1e6 in about 1.5s on my machine.
primest <- function(n){
p <- 2:n
i <- 1
while (p[i] <= sqrt(n)) {
p <- p[p %% p[i] != 0 | p==p[i]]
i <- i+1
}
p
}
BTW, the spuRs package has a number of prime finding functions including a sieve of E. Haven't checked to see what the speed is like for them.
And while I'm writing a very long answer... here's how you'd check in R if one value is prime.
isPrime <- function(x){
div <- 2:ceiling(sqrt(x))
!any(x %% div == 0)
}
floor
to ceiling
(done).
– John
Nov 4 '13 at 12:50
seq_len
should be faster than :
however the negative selection might cancel that out. Maybe it will be better when the number is very large.
– John
Sep 8 '17 at 22:40
Best way that I know of to generate all primes (without getting into crazy math) is to use the Sieve of Eratosthenes.
It is pretty straightforward to implement and allows you calculate primes without using division or modulus. The only downside is that it is memory intensive, but various optimizations can be made to improve memory (ignoring all even numbers for instance).
This method should be Faster and simpler.
allPrime <- function(n) {
primes <- rep(TRUE, n)
primes[1] <- FALSE
for (i in 1:sqrt(n)) {
if (primes[i]) primes[seq(i^2, n, i)] <- FALSE
}
which(primes)
}
0.12 second on my computer for n = 1e6
I implemented this in function AllPrimesUpTo
in package primefactr.
I recommend primegen, Dan Bernstein's implementation of the Atkin-Bernstein sieve. It's very fast and will scale well to other problems. You'll need to pass data out to the program to use it, but I imagine there are ways to do that?
You can also cheat and use the primes()
function in the schoolmath
package :D
The OP asked to generate all prime numbers below one billion. All of the answers provided thus far are either not capable of doing this, will take a long a time to execute, or currently not available in R (see the answer by @Charles). The package RcppAlgos
(I am the author) is capable of generating the requested output in just over 1 second
. It is based off of the segmented sieve of Eratosthenes by Kim Walisch.
library(RcppAlgos)
system.time(primeSieve(10^9))
user system elapsed
1.300 0.105 1.406
Moreover, below is a summary of packages (and the sieve
function above provided by @John) that can generate prime numbers.
library(schoolmath)
library(primefactr)
library(sfsmisc)
library(primes)
library(numbers)
library(spuRs)
library(randtoolbox)
library(matlab)
## and 'sieve' from @John
Before we begin, we note that the problems pointed out by @Henrik in schoolmath
still exists. Observe:
## 1 is NOT a prime number
schoolmath::primes(start = 1, end = 20)
[1] 1 2 3 5 7 11 13 17 19
## This should return 1, however it is saying that 52 "prime"
## numbers less than 10^4 are divisible by 7.... Huuuhhh????
sum(schoolmath::primes(start = 1, end = 10^4) %% 7L == 0)
[1] 52
The point is, don't use schoolmath
for generating primes at this point (no offense to the author... In fact, I have filed an issue with the maintainer).
Let's look at randtoolbox
as it appears to be incredibly efficient. Observe:
## the argument for get.primes is for how many prime numbers you need
## whereas most packages get all primes less than a certain number
microbenchmark(priRandtoolbox = get.primes(78498),
priRcppAlgos = RcppAlgos::primeSieve(10^6), unit = "relative")
Unit: relative
expr min lq mean median uq max neval
priRandtoolbox 1.00000 1.00000 1.00000 1.00000 1.000000 1.000000 100
priRcppAlgos 19.37208 18.30095 9.897374 7.639231 7.249031 5.449076 100
A closer look reveals that it is essentially a lookup table (found in the file randtoolbox.c
from the source code).
#include "primes.h"
void reconstruct_primes()
{
int i;
if (primeNumber[2] == 1)
for (i = 2; i < 100000; i++)
primeNumber[i] = primeNumber[i-1] + 2*primeNumber[i];
}
Where primes.h
is a header file that contains an array of "halves of differences between prime numbers". Thus, you will be limited by the number of elements in that array for generating primes (i.e. the first one hundred thousand primes). If you are only working with smaller primes (less than 1,299,709
(i.e. the 100,000th prime)) and you are working on a project that requires the nth
prime, randtoolbox
is the way to go.
Now, let's see how the rest of the packages compare in generating primes less than a million:
microbenchmark(priRcppAlgos = RcppAlgos::primeSieve(10^6),
priNumbers = numbers::Primes(10^6),
priSpuRs = spuRs::primesieve(c(), 2:10^6),
priPrimes = primes::generate_primes(1, 10^6),
priPrimefactr = primefactr::AllPrimesUpTo(10^6),
priSfsmisc = sfsmisc::primes(10^6),
priMatlab = matlab::primes(10^6),
priJohnSieve = sieve(10^6),
unit = "relative")
Unit: relative
expr min lq mean median uq max neval
priRcppAlgos 1.000000 1.00000 1.00000 1.000000 1.00000 1.000000 100
priNumbers 21.599399 21.27664 20.17172 20.348373 20.82308 10.992780 100
priSpuRs 223.240897 231.69938 198.16347 215.520998 202.37479 59.608137 100
priPrimes 41.689864 38.43470 33.74977 35.329320 33.21983 17.323242 100
priPrimefactr 39.452661 39.77808 38.64081 37.887232 36.71392 14.549090 100
priSfsmisc 9.667778 11.16356 11.58725 10.862231 11.61987 8.990612 100
priMatlab 21.055741 21.45761 21.46455 21.053058 20.86727 15.029687 100
priJohnSieve 9.316246 10.22913 10.52325 9.825776 10.30900 8.167797 100
Let's test the speed of generating primes over a range:
microbenchmark(priRcppAlgos = RcppAlgos::primeSieve(10^9, 10^9 + 10^6),
priNumbers = numbers::Primes(10^9, 10^9 + 10^6),
priPrimes = primes::generate_primes(10^9, 10^9 + 10^6),
unit = "relative", times = 20)
Unit: relative
expr min lq mean median uq max neval
priRcppAlgos 1.0000 1.0000 1.0000 1.0000 1.0000 1.00000 20
priNumbers 137.5877 134.2035 125.1085 133.1225 121.9784 94.93077 20
priPrimes 911.2896 877.6692 806.9694 861.4054 783.9666 568.05759 20 20
Now, let's remove the condition if(n > 1e8) stop("n too large")
in the sieve
function to test how fast it can generate the primes under a billion as well as the primes
function from the sfsmisc
package as they were the fastest after RcppAlgos
.
system.time(sieve(10^9))
user system elapsed
26.703 4.582 31.328
system.time(sfsmisc::primes(10^9))
user system elapsed
24.772 4.521 29.436
From this, we see that RcppAlgos
scales much better as n gets larger (i.e. 1.406
(see above) is roughly 20-22x
faster whereas it was only around 10x
for 10^6
).
And just for good measure:
## primes less than 10 billion
system.time(tenBillion <- RcppAlgos::primeSieve(10^10))
user system elapsed
16.510 1.784 18.296
length(tenBillion)
[1] 455052511
## Warning!!!... Large object created
tenBillionSize <- object.size(tenBillion)
print(tenBillionSize, units = "Gb")
3.4 Gb
Take Away
RcppAlgos::primeSieve
.randtoolbox::get.primes
.numbers
, primes
, & RcppAlgos
are the way to go.The isPrime() function posted above could use sieve(). One only needs to check if any of the primes < ceiling(sqrt(x)) divide x with no remainder. Need to handle 1 and 2, also.
isPrime <- function(x) {
div <- sieve(ceiling(sqrt(x)))
(x > 1) & ((x == 2) | !any(x %% div == 0))
}
sieve
from? What does it return, and why does this work?
– Matthew Lundberg
Jul 13 '14 at 3:35
x
do you actually need ceiling
rather than floor
in this computation? floor
is correct mathematically.
– Matthew Lundberg
Jul 13 '14 at 4:35
for (i in 2:1000) {
a = (2:(i-1))
b = as.matrix(i%%a)
c = colSums(b != 0)
if (c == i-2)
{
print(i)
}
}
prime = function(a,n){
n=c(2)
i=3
while(i <=a){
for(j in n[n<=sqrt(i)]){
r=0
if (i%%j == 0){
r=1}
if(r==1){break}
}
if(r!=1){n = c(n,i)}
i=i+2
}
print(n)
}