Mark's answer is almost correct except for two issues:

- If a line is longer than
`length - 1`

characters (including the newline), then the `while`

loop will increment `count`

at least twice for the same line: once for the first `length - 1`

characters, another for the next `length - 1`

characters, etc.
- The calculation of
`rand() * count`

can cause an integer overflow.

To solve the first problem, you can call `fgets`

into a trash buffer until it returns `NULL`

(indicating an I/O error or EOF with no data read) or the trash buffer contains a newline:

```
count = 0;
while (fgets(line, length, stream) != NULL)
{
char *p = strchr(line, '\n');
if (p != NULL) {
assert(*p == '\n');
*p = '\0'; // trim the newline
}
else { // haven't reached EOL yet. Read & discard the rest of the line.
#define TRASH_LENGTH 1024
char trash[TRASH_LENGTH];
while((p = fgets(trash, TRASH_LENGTH, stream)) != NULL) {
if ((p = strchr(trash, '\n')) != NULL) // reached EOL
break;
}
}
assert(strchr(line, '\n') == NULL); // `line` does not contain a newline
count++;
// ...
```

The second problem can be solved with @tvanfosson's suggestion if floating-point arithmetic is not available:

```
int one_chance_in(size_t n)
{
if (rand() % n == 0) // `rand` returns an integer in [0, `RAND_MAX`]
return 1;
else
return 0;
}
```

But note that `rand() % n`

is not a uniform, discrete random variable even if `rand()`

is assumed to be one because the probability that `rand() % n == 0`

can be as much as 1/`RAND_MAX`

higher than the desired probability 1/`n`

. On my machine, `RAND_MAX`

is 2147483647, so the difference is 4.66 × 10^{-10}, but the C standard only requires that `RAND_MAX`

be at least 32767 (3.05 × 10^{-5} difference).

Also, for anyone left wondering why this scheme works (as I was), it might be helpful to work through the calculation of the probability that the first line remains in `keptline`

if there are *m* lines and generalize: In the first iteration of the loop, the probability that the first line is copied to `keptline`

is 1/1. In the second iteration of the loop, the probability that the second line does *not* overwrite the first line is 1/2. In the third iteration, the probability that the third line does *not* overwrite the first line is 2/3. Continuing, the probability that the last line does not overwrite the first line is (*m* - 1)/*m*. Thus, the probability that the first line remains in `keptline`

after iterating over all lines is:

1/1 × 1/2 × 2/3 × 3/4 × ... × (*m* - 2)/(*m* - 1) × (*m* - 1)/*m* = 1/*m*

The probability that the *second* line remains in `keptline`

is:

1/2 × 2/3 × 3/4 × ... × (*m* - 2)/(*m* - 1) × (*m* - 1)/*m* = 1/*m*

The probability that the *third* line remains in `keptline`

is:

1/3 × 3/4 × ... × (*m* - 2)/(*m* - 1) × (*m* - 1)/*m* = 1/*m*

Etc. They're all 1/*m*.