In an interview, I was given the following problem to solve initially using pen/paper, then via a program to verify the result.

The question is as follows:

There are three people A,B and C. Each person is capable of hitting a target with a probability of 6/7, 4/5 and 3/4 respectively. What is the probability that if they were to each fire one shot that exactly two of them will hit the target?

The answer is:

```
P(...) = P(A)*P(B)*(1-P(C)) +
P(B)*P(C)*(1-P(A)) +
P(C)*P(A)*(1-P(B))
= 27.0/70.0
= 38.57142857142857142857142857142857142857....%
```

Below is my solution to the problem:

```
#include <cstdio>
#include <cctype>
#include <ctime>
#include <random>
int main()
{
std::mt19937 engine(time(0));
engine.discard(10000000);
std::uniform_real_distribution<double> uniform_real(0.0,1.0);
double prA = (6.0 / 7.0);
double prB = (4.0 / 5.0);
double prC = (3.0 / 4.0);
std::size_t trails = 4000000000;
std::size_t total_success = 0;
for (std::size_t i = 0; i < trails; ++i)
{
int current_success = 0;
if (uniform_real(engine) < prA) ++current_success;
if (uniform_real(engine) < prB) ++current_success;
if (uniform_real(engine) < prC) ++current_success;
if (current_success == 2)
++total_success;
double prob = (total_success * 1.0) / (i+1);
if ((i % 1000000) == 0)
{
printf("%05d Pr(...) = %12.10f error:%15.13f\n",
i,
prob,
std::abs((27.0/70.0) - prob));
}
}
return 0;
}
```

The problem is as follows, regardless of how large a number of trials I run, the probability flat-lines at around roughly 0.3857002101. Is there something wrong in the code?

The interviewer said it is trivial to get the result to converge to around 9 decimal place accuracy within 1 million trials, regardless of the seed.

Any ideas on where the bug is in my code?

**UPDATE 1:**
I've tried the above code with the following generators, they all seem to platau at around the same time roughly trial 10^9.

- std::mt19937_64
- std::ranlux48_base
- std::minstd_rand0

**UPDATE 2:**
Thinking about the problem, I've gone down the following track. The ratio 27/70 comprised of 27 and 70 which are both coprime and where factors of 70 under 4x10^9 is roughly 57x10^6 or about 1.4% of all the numbers. Hence the probability of getting the "exact" ratio of 27/70 out of two numbers selected at random between [0,4x10^9] is roughly 1.4% (as there are more factors of 27 within 4x10^9) - So getting the exact ratio is very low, and that number will be constant regardless of the number of trials.

Now if one where to talk about thick bounds - ie: numbers in the range of factors of 70 +/5, that increases the probability of choosing a pair of numbers at random within the range [0,4x10^9] that would give a ratio within specified/related tolerance to about roughly 14%, but with this technique the best we can get will be on average roughly 5 decimal places accurate when compared to the exact value. Is this way of reasoning correct?

`1/sqrt(N)`

where`N`

is the number of trials (see e.g. en.wikipedia.org/wiki/Monte_Carlo_integration ), so you'd need O(10^18) trials for a precision of 10^-9. Unless of course you use the analytical formula in which case you're done after one iteration... – Andre Holzner Nov 23 '12 at 6:34