# How to write a function to generate random number 0/1 use another random function?

If I have a function named rand1() which generates number 0(30% probability) or 1(70% probability), how to write a function rand2() which generates number 0 or 1 equiprobability use rand1() ?

Update：

Finally, I found this is a problem on book Introduction to Algorithms (2nd) (I have bought the Chinese edition of this book ), Excercise 5.1-3, the original problem is :

5.1-3 Suppose that you want to output 0 with probability 1/2 and 1 with probability 1/2. At your disposal is a procedure BIASED-RANDOM, that outputs either 0 or 1. It outputs 1 with some probability p and 0 with probability 1− p, where 0 < p < 1, but you do not know what p is. Give an algorithm that uses BIASED-RANDOM as a subroutine, and returns an unbiased answer, returning 0 with probability 1/2 and 1 with probability 1/2. What is the expected running time of your algorithm as a function of p?

the solution is : (see: http://www.cnblogs.com/meteorgan/archive/2012/05/04/2482317.html)

To get an unbiased random bit, given only calls to BIASED-RANDOM, call BIASED-RANDOM twice. Repeatedly do so until the two calls return different values, and when this occurs, return the Þrst of the two bits:

``````UNBIASED-RANDOM
while TRUE
do
x ← BIASED-RANDOM
y ← BIASED-RANDOM
if x != y
then return x
``````

To see that UNBIASED-RANDOM returns 0 and 1 each with probability 1/2, observe that the probability that a given iteration returns 0 is

``````Pr {x = 0 and y = 1} = (1 − p)p ,
``````

and the probability that a given iteration returns 1 is

``````Pr {x = 1 and y = 0} = p(1 − p) .
``````

(We rely on the bits returned by BIASED-RANDOM being independent.) Thus, the probability that a given iteration returns 0 equals the probability that it returns 1. Since there is no other way for UNBIASED-RANDOM to return a value, it returns 0 and 1 each with probability 1/2.

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Not really 50/50, but 49/51: You can generate with rand1() twice, if both are 1, then you can assign 0; assign 1 for other cases. –  nhahtdh Aug 25 '12 at 12:54
Homework? Interview question? –  Joachim Isaksson Aug 25 '12 at 12:56
today's interview question, I have no ideas. –  PanaStyle Aug 25 '12 at 12:58
Where does C come into play? –  Jens Gustedt Aug 25 '12 at 13:26
@JensGustedt - I don't think it does. `rand()` is a generic function, not specific to C. Have removed the C tag. –  Assad Ebrahim Aug 25 '12 at 14:00
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Generate two numbers, `a` and `b`.

If `a` is 0 and `b` is 1 (21% chance), generate a 0.
If `a` is 1 and `b` is 0 (21% chance), generate a 1.

For all other cases (58% chance), just generate a new `a` and `b` and try again.

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And what's the probability that this algorithm doesn't terminate? :-) –  Kerrek SB Aug 25 '12 at 13:05
@KerrekSB Zero. –  Qnan Aug 25 '12 at 13:05
@KerrekSB And the probability that it doesn't terminate after N calls to `rand1` is `0.58^N`. –  Qnan Aug 25 '12 at 13:06
@KerrekSB it's a en.wikipedia.org/wiki/Geometric_distribution for the number of runs, with p=0.42. So the mean is 1/p, or roughly 2.38. –  Qnan Aug 25 '12 at 13:12
+1 It is a rejection technique that by virtue of symmetry, is exact, though it may not be as efficient as desired. –  user85109 Aug 25 '12 at 13:30
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If you call `rand1` twice, there is an equal chance of getting `[1 0]` and `[0 1]`, so if you return the first of each non-matching pair (and discard matching pairs) you will get, on average, `0.5(1 - p2 - (1-p)2)` output bits per input bit (where `p` is the probability of `rand1` returning `1`; 0.7 in your example) and independently of `p`, each output bit will be 1 with probability 0.5.

However, we can do better.

Rather than throw away the matching pairs, we can remember them in the hope that they are followed by opposite matching pairs - The sequences `[0 0 1 1]` and `[1 1 0 0]` are also equally likely, and again we can return the first bit whenever we see such a sequence (still with output probability 0.5.) We can keep combining them indefinitely, looking for sequences like `[0 0 0 0 1 1 1 1]` etc.

And we can go even further - consider the input sequences `[0 0 0 1]` and `[0 1 0 0]` produce the same output (`[0]`) as it stands, but these two sequences were also equally likely, so we can extract an extra bit of output from this, returning `[0 0]` for the first case and `[0 1]` for the second. This is where it gets more complicated though, as you would need to start buffering output bits.

Both techniques can be applied recursively, and taken to the limit it becomes lossless (i.e. if `rand1` has a probability of 0.5, you get an average of one output bit per input bit.)

Full description (with math) here: http://www.eecs.harvard.edu/~michaelm/coinflipext.pdf

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You will need to figure out how close you want to get to 50% 0 50% 1.

If you add results from repeated calls to rand1. if the results is 0 or 2 then the value returned is 0 if it is 1 then return 1. (in code you can use modulo 2)

``````int val = rand1();   // prob 30%      0, and 70%      1

val=(val+rand1())%2; // prob 58%      0, and 42%      1  (#1 see math bellow)
val=(val+rand1())%2; // prob 46.8%    0, and 53.2%    1  (#2 see math bellow)
val=(val+rand1())%2; // prob 51.28%   0, and 48.72%   1
val=(val+rand1())%2; // prob 49.488%  0, and 50.512%  1
val=(val+rand1())%2; // prob 50.2048% 0, and 49.7952% 1
``````

You get the idea. so it is up to you to figure out how close you want the probabilities. every subsequent call will gets you closer to 50% 50% but it will never be exactly equal.

If you want the math for the probabilities:

# 1

``````prob ((val+rand1()%2) = 0) = (prob(val = 0)*prob(rand1() = 0)) + (prob(val = 1)*prob(rand1() = 1)
= (0.3*0.3)+(0.7*0.7)
= 0.09 + 0.49
= 0.58
= 58%

prob ((val+rand1()%2) = 1) = (prob(val = 1)*prob(rand1() = 0)) + (prob(val = 0)*prob(rand1() = 1)
= (0.7*0.3)+(0.3*0.7)
= 0.21 + 0.21
= 0.42
= 42%
``````

# 2

`````` prob ((val+rand1()%2) = 0) = (prob(val = 0)*prob(rand1() = 0)) + (prob(val = 1)*prob(rand1() = 1)
= (0.58*0.3)+(0.42*0.7)
= 0.174 + 0.294
= 0.468
= 46.8%

prob ((val+rand1()%2) = 1) = (prob(val = 1)*prob(rand1() = 0)) + (prob(val = 0)*prob(rand1() = 1)
= (0.42*0.3)+(0.58*0.7)
= 0.126 + 0.406
= 0.532
= 53.2%
``````
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Below `rand2` function will provide 50% probability for occurence of zero or one.

``````#define LIMIT_TO_CALCULATE_PROBABILITY 10 //set any even numbers

int rand2()
{
static int one_occurred = 0;
static int zero_occured = 0;
int rand_value = 0;
int limit = (LIMIT_TO_CALCULATE_PROBABILITY / 2);

if (LIMIT_TO_CALCULATE_PROBABILITY == (one_occured + zero_occured))
{
one_occured = 0;
zero_occured = 0;
}

rand_value = rand1();

if ((1 == rand_value) && (one_occured < limit))
{
one_occured++;
return rand_value;
}
else if ((0 == rand_value) && (zero_occured < limit))
{
zero_occured++;
return rand_value;
}
else if (1 == rand_value)
{
zero_occured++;
return 0;
}
else if (0 == rand_value)
{
one_occured++;
return 1;
}
}
``````
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This will produce correlated outputs, which is usually undesirable. –  finnw Aug 25 '12 at 14:17
If we keep the LIMIT_TO_CALCULATE_PROBABILITY as less as possible, then the correlated outputs occurence will be very less. –  raja ashok Aug 25 '12 at 14:24