# TI-84 Plus Random Number Generator Algorithm

Edit: my main question is that I want to replicate the TI-84 plus RNG algorithm on my computer, so I can write it in a language like Javascript or Lua, to test it faster.

I tried using an emulator, but it turned out to be slower than the calculator.

Just for the people concerned: There is another question like this, but answer to that question just says how to transfer already-generated numbers over to the computer. I don't want this. I already tried something like it, but I had to leave the calculator running all weekend, and it still wasn't done.

• Could you clarify what you mean by "Does anybody know how the RNG on the TI-84 plus calculator works?" I don't understand what you're trying to do. Do you want to know how it's seeded? Do you want to know how random the distribution is? You mention you ran a long test that crashed, but there's no clear question.
– Dan
Sep 25, 2015 at 18:15
• I edited the question. Sep 25, 2015 at 18:19
• So you're trying to 'test it'? It's still not 100% clear what you're trying to do here. You don't just want a lot of random samples like the other question?
– Dan
Sep 25, 2015 at 18:25

The algorithm being used is from the paper Efficient and portable combined random number generators by P. L'Ecuyer.

The algorithm used by the Ti calculators is on the RHS side of p. 747. I've included a picture. I've translated this into a C++ program

``````#include <iostream>
#include <iomanip>
using namespace std;

long s1,s2;

double Uniform(){
long Z,k;
k  = s1 / 53668;
s1 = 40014*(s1-k*53668)-k*12211;
if(s1<0)
s1 = s1+2147483563;

k  = s2/52774;
s2 = 40692*(s2-k*52774)-k*3791;
if(s2<0)
s2 = s2+2147483399;

Z=s1-s2;
if(Z<1)
Z = Z+2147483562;

return Z*(4.656613e-10);
}

int main(){
s1 = 12345; //Gotta love these seed values!
s2 = 67890;
for(int i=0;i<10;i++)
cout<<std::setprecision(10)<<Uniform()<<endl;
}
``````

Note that the initial seeds are `s1 = 12345` and `s2 = 67890`.

And got an output from a Ti-83 (sorry, I couldn't find a Ti-84 ROM) emulator: This matches what my implementation produces I've just cranked the output precision on my implementation and get the following results:

``````0.9435973904
0.9083188494
0.1466878273
0.5147019439
0.4058096366
0.7338123019
0.04399198693
0.3393625207
``````

Note that they diverge from Ti's results in the less significant digits. This may be a difference in the way the two processors (Ti's Z80 versus my X86) perform floating point calculations. If so, it will be hard to overcome this issue. Nonetheless, the random numbers will still generate in the same sequence (with the caveat below) since the sequence relies on only integer mathematics, which are exact.

I've also used the `long` type to store intermediate values. There's some risk that the Ti implementation relies on integer overflow (I didn't read L'Ecuyer's paper too carefully), in which case you would have to adjust to `int32_t` or a similar type to emulate this behaviour. Assuming, again, that the processors perform similarly.

Edit

This site provides a Ti-Basic implementation of the code as follows:

``````:2147483563→mod1
:2147483399→mod2
:40014→mult1
:40692→mult2

#The RandSeed Algorithm
:abs(int(n))→n
:If n=0 Then
: 12345→seed1
: 67890→seed2
:Else
: mod(mult1*n,mod1)→seed1
: mod(n,mod2)→seed2
:EndIf

#The rand() Algorithm
:Local result
:mod(seed1*mult1,mod1)→seed1
:mod(seed2*mult2,mod2)→seed2
:(seed1-seed2)/mod1→result
:If result<0
: result+1→result
:Return result
``````

I translated this into C++ for testing:

``````#include <iostream>
#include <iomanip>
using namespace std;

long mod1  = 2147483563;
long mod2  = 2147483399;
long mult1 = 40014;
long mult2 = 40692;
long seed1,seed2;

void Seed(int n){
if(n<0) //Perform an abs
n = -n;
if(n==0){
seed1 = 12345; //Gotta love these seed values!
seed2 = 67890;
} else {
seed1 = (mult1*n)%mod1;
seed2 = n%mod2;
}
}

double Generate(){
double result;
seed1  = (seed1*mult1)%mod1;
seed2  = (seed2*mult2)%mod2;
result = (double)(seed1-seed2)/(double)mod1;
if(result<0)
result = result+1;
return result;
}

int main(){
Seed(0);
for(int i=0;i<10;i++)
cout<<setprecision(10)<<Generate()<<endl;
}
``````

This gave the following results:

``````0.9435974025
0.908318861
0.1466878292
0.5147019502
0.405809642
0.7338123114
0.04399198747
0.3393625248
0.9954663411
0.2003402617
``````

which match those achieved with the implementation based on the original paper.

• If you own a TI-84+ SE, you can legally use a TI-84+ SE ROM, such as the one found at tibasic.com/rom/TI84PlusSE.rom Oct 12, 2016 at 14:44
• You can get the 2.55 OS from the TI website, but the 2.43 is not available anymore. If you want a download, tell me. I got it from the TI support, but only because someone there still had it on lying around on a PC. Dec 21, 2017 at 7:54

I implemented rand, randInt, randM and randBin in Python. Thanks Richard for the C code. All implemented commands work as expected. You can also find it in this Gist.

``````import math

class TIprng(object):
def __init__(self):
self.mod1 = 2147483563
self.mod2 = 2147483399
self.mult1 = 40014
self.mult2 = 40692
self.seed1 = 12345
self.seed2 = 67890

def seed(self, n):
n = math.fabs(math.floor(n))
if (n == 0):
self.seed1 = 12345
self.seed2 = 67890
else:
self.seed1 = (self.mult1 * n) % self.mod1
self.seed2 = (n)% self.mod2

def rand(self, times = 0):
# like TI, this will return a list (array in python) if times == 1,
# or an integer if times isn't specified
if not(times):
self.seed1  = (self.seed1 * self.mult1) % self.mod1
self.seed2  = (self.seed2 * self.mult2)% self.mod2
result = (self.seed1 - self.seed2)/self.mod1
if(result<0):
result = result+1
return result
else:
return [self.rand() for _ in range(times)]

def randInt(self, minimum, maximum, times = 0):
# like TI, this will return a list (array in python) if times == 1,
# or an integer if times isn't specified
if not(times):
if (minimum < maximum):
return (minimum + math.floor((maximum- minimum + 1) * self.rand()))
else:
return (maximum + math.floor((minimum - maximum + 1) * self.rand()))
else:
return [self.randInt(minimum, maximum) for _ in range(times)]

def randBin(self, numtrials, prob, times = 0):
if not(times):
return sum([(self.rand() < prob) for _ in range(numtrials)])
else:
return [self.randBin(numtrials, prob) for _ in range(times)]

def randM(self, rows, columns):
# this will return an array of arrays
matrixArr = [[0 for x in range(columns)] for x in range(rows)]
# we go from bottom to top, from right to left
for row in reversed(range(rows)):
for column in reversed(range(columns)):
matrixArr[row][column] = self.randInt(-9, 9)
return matrixArr

testPRNG = TIprng()
testPRNG.seed(0)
print(testPRNG.randInt(0,100))
testPRNG.seed(0)
print(testPRNG.randM(3,4))
``````

The algorithm used by the TI-Basic `rand` command is L'Ecuyer's algorithm according to TIBasicDev.

rand generates a uniformly-distributed pseudorandom number (this page and others will sometimes drop the pseudo- prefix for simplicity) between 0 and 1. rand(n) generates a list of n uniformly-distributed pseudorandom numbers between 0 and 1. seed→rand seeds (initializes) the built-in pseudorandom number generator. The factory default seed is 0.

L'Ecuyer's algorithm is used by TI calculators to generate pseudorandom numbers.

Unfortunately I have not been able to find any source published by Texas Instruments backing up this claim, so I cannot with certainty that this is the algorthm used. I am also uncertain what exactly is referred to by L'Ecuyer's algorithm.

• `P. L’Ecuyer, “Combined Multiple Recursive Random Number Generators”, Operations Research, 44, 5 (1996), 816–822.` Sep 25, 2015 at 21:06
• This link describes the algorithm in detail: tibasicdev.wikidot.com/68k:randseed Sep 25, 2015 at 21:12
``````Here is a C++ program that works:
#include<cmath>
#include<iostream>
#include<iomanip>
using namespace std;
int main()
{

double seed1 = 12345;
double seed2 = 67890;
double mod1 = 2147483563;
double mod2 = 2147483399;
double result;
for(int i=0; i<10; i++)
{
seed1 = seed1*40014-mod1*floor((seed1*40014)/mod1);
seed2 = seed2*40692-mod2*floor((seed2*40692)/mod2);
result = (seed1 - seed2)/mod1;
if(result < 0)
{result = result + 1;}
cout<<setprecision(10)<<result<<endl;
}
return 0;
}
``````