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The problem I am given is the following:

Write a program to discover the answer to this puzzle:"Let's say men and women are paid equally (from the same uniform distribution). If women date randomly and marry the first man with a higher salary, what fraction of the population will get married?"

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My issue is that it seems that the percent married figure I am getting is wrong. Another poster asked this same question on the programmers exchange before, and the percentage getting married should be ~68%. However, I am getting closer to 75% (with a lot of variance). If anyone can take a look and let me know where I went wrong, I would be very grateful.

I realize, looking at the other question that was on the programmers exchange, that this is not the most efficient way to solve the problem. However, I would like to solve the problem in this manner before using more efficient approaches.

My code is below, the bulk of the problem is "solved" in the test function:

#include <cs50.h>
#include <stdio.h>
#include <stdlib.h>
#include <time.h>

#define ARRAY_SIZE 100
#define MARRIED 1
#define SINGLE 0
#define MAX_SALARY 1000000

bool arrayContains(int* array, int val);
int test();

int main()
{
    printf("Trial count: ");
    int trials = GetInt();

    int sum = 0;
    for(int i = 0; i < trials; i++)
    {
        sum += test();
    }

    int average = (sum/trials) * 100;

    printf("Approximately %d %% of the population will get married\n", average / ARRAY_SIZE);
}

int test()
{
    srand(time(NULL));

    int femArray[ARRAY_SIZE][2];    
    int maleArray[ARRAY_SIZE][2];

    // load up random numbers   
    for (int i = 0; i < ARRAY_SIZE; i++)
    {
        femArray[i][0] = (rand() % MAX_SALARY);
        femArray[i][1] = SINGLE;

        maleArray[i][0] = (rand() % MAX_SALARY);
        maleArray[i][1] = SINGLE;
    }

    srand(time(NULL));
    int singleFemales = 0;

    for (int k = 0; k < ARRAY_SIZE; k++)
    {
        int searches = 0; // count the unsuccessful matches
        int checkedMates[ARRAY_SIZE] = {[0 ... ARRAY_SIZE - 1] = ARRAY_SIZE + 1};

        while(true)
        {
            // ARRAY_SIZE - k is number of available people, subtract searches for people left
            // checked all possible mates
            if(((ARRAY_SIZE - k) - searches) == 0)
            {
                singleFemales++;
                break;
            }

            int randMale = rand() % ARRAY_SIZE; // find a random male

            while(arrayContains(checkedMates, randMale)) // ensure that the male was not checked earlier
            {
                randMale = rand() % ARRAY_SIZE;               
            }
            checkedMates[searches] = randMale;

            // male has a greater income and is single            
            if((femArray[k][0] < maleArray[randMale][0]) && (maleArray[randMale][1] == SINGLE))
            {
                femArray[k][1] = MARRIED;
                maleArray[randMale][1] = MARRIED;
                break;
            }
            else
            {
                searches++;
                continue;
            }
        }
    }

    return ARRAY_SIZE - singleFemales;
}

bool arrayContains(int* array, int val)
{
    for(int i = 0; i < ARRAY_SIZE; i++)
    {
        if (array[i] == val)
            return true;
    }
    return false;
}
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  • How many trials are you doing each time?
    – Le Woogush
    Feb 2, 2016 at 16:55
  • You should be able to reduce your variance by running a larger number of trials and / or by testing a larger population in each trial. Feb 2, 2016 at 17:06
  • 1
    You could also consider assigning uniformly-distributed salaries instead of choosing salaries randomly from a uniform distribution; since the order of the salaries does not matter, these are equivalent in the infinite-population limit. Feb 2, 2016 at 17:09
  • Additionally, rand() % MAX_SALARY is not uniformly distributed unless MAX_SALARY happens to evenly divide RAND_MAX + 1. Similar applies to rand() % ARRAY_SIZE. Feb 2, 2016 at 17:11
  • 1
    You're doing this using a simulation, but if you want a more direct approach, you could try using Poisson arrival distributions for a closed form answer.
    – Cloud
    Feb 2, 2016 at 18:44

1 Answer 1

2

In the first place, there is some ambiguity in the problem as to what it means for the women to "date randomly". There are at least two plausible interpretations:

  1. You cycle through the unmarried women, with each one randomly drawing one of the unmarried men and deciding, based on salary, whether to marry. On each pass through the available women, this probably results in some available men being dated by multiple women, and others being dated by none.

  2. You divide each trial into rounds. In each round, you randomly shuffle the unmarried men among the unmarried women, so that each unmarried man dates exactly one unmarried woman.

In either case, you must repeat the matching until there are no more matches possible, which occurs when the maximum salary among eligible men is less than or equal to the minimum salary among eligible women.

In my tests, the two interpretations produced slightly different statistics: about 69.5% married using interpretation 1, and about 67.6% using interpretation 2. 100 trials of 100 potential couples each was enough to produce fairly low variance between runs. In the common (non-statistical) sense of the term, for example, the results from one set of 10 runs varied between 67.13% and 68.27%.

You appear not to take either of those interpretations, however. If I'm reading your code correctly, you go through the women exactly once, and for each one you keep drawing random men until either you find one that that woman can marry or you have tested every one. It should be clear that this yields a greater chance for women early in the list to be married, and that order-based bias will at minimum increase the variance of your results. I find it plausible that it also exerts a net bias toward more marriages, but I don't have a good argument in support.

Additionally, as I wrote in comments, you introduce some bias through the way you select random integers. The rand() function returns an int between 0 and RAND_MAX, inclusive, for RAND_MAX + 1 possible values. For the sake of argument, let's suppose those values are uniformly distributed over that range. If you use the % operator to shrink the range of the result to N possible values, then that result is still uniformly distributed only if N evenly divides RAND_MAX + 1, because otherwise more rand() results map to some values than map to others. In fact, this applies to any strictly mathematical transformation you might think of to narrow the range of the rand() results.

For the salaries, I don't see why you even bother to map them to a restricted range. RAND_MAX is as good a maximum salary as any other; the statistics gleaned from the simulation don't depend on the range of salaries; but only on their uniform distribution.

For selecting random indices into your arrays, however, either for drawing men or for shuffling, you do need a restricted range, so you do need to take care. The best way to reduce bias in this case is to force the random numbers drawn to come from a range that is evenly divisible by the number of options by re-drawing as many times as necessary to ensure it:

/*
 * Returns a random `int` in the half-open interval [0, upper_bound).
 * upper_bound must be positive, and should not exceed RAND_MAX + 1.
 */
int random_draw(int upper_bound) {
    /* integer division truncates the remainder: */
    int rand_bound = (RAND_MAX / upper_bound) * upper_bound;

    for (;;) {
        int r = rand();

        if (r < rand_bound) {
            return r % upper_bound;
        }
    }
}
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  • "that result is still uniformly distributed only if N evenly divides RAND_MAX + 1, because otherwise more rand() results map to some values than map to others" Why is it that this happens?
    – Jon
    Feb 4, 2016 at 4:44
  • I removed rand() usage from the salary assigning portion of the program and simply equated salary to i (loop iteration counter). I also implemented the random_draw function you created (thank you), but it did not seem to have any effect. After implementing the salary change, the % married has shifted to the low 60s. Also, the cs50 library I linked only serves to read user input and provide the Boolean data type. Also, Quick question: Are you John Bollinger, creator of the Bollinger band technical indicator?
    – Jon
    Feb 4, 2016 at 4:47
  • @TomJacob, I am a different John Bollinger. Feb 4, 2016 at 13:57
  • @TomJacob, as to uniformity, suppose RAND_MAX were 3, yielding four possible rand() results: 0, 1, 2, and 3. Suppose further that you wanted to generate numbers between 0 and 2. If you generate them by computing rand() % 3 then the result is 0 if rand() returns either 0 or 3, but it is 1 or 2 only if rand() returns exactly that number. Thus, the probability of the overall result being 0 is 50%, whereas the probability of it being 1 or 2 is 25% each. The non-uniformity is much less pronounced for RAND_MAX much larger than N, but it is still there. Feb 4, 2016 at 14:02
  • As to the mean value your simulation predicts, the biggest take-home message of my answer is that the result depends on how you implement the random matching between women and men. I already described the two approaches I find most reasonable, and my implementations of both give results close to what you were expecting. I daresay number (2) is probably the model on which your target number was based. If you're implementing that model (which your original code does not do) but getting far different or widely varying results, then your code is wrong or buggy. Feb 4, 2016 at 14:09

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