A problem with this statement is that it starts by asking for two "random" prime numbers. Without any explicit statement of the distribution of the required random primes, we are already stuck. (This is the beginning of a classic paradox, where we are asked to generate a "random" integer.)

But suppose that we change the statement to finding any two arbitrary primes, that yield the desired product with a given number of bits x. The answer is trivial.

The set of numbers that have exactly x bits in their binary representation is the half open set of integers [2^(x-1),2^x-1].

Choose an arbitrary prime number that is less than or equal to (2^x-1)/2. Call it p1.

Next, choose a second prime number that lies in the interval (2^(x-1)/p1,(2^x-1)/p1). Call it p2.

It must be true that p1*p2 will be in the desired interval.

For example, given x = 10, so the product must lie in the interval [512,1023], the set of integers with exactly 10 bits. (Note, there are apparently 147 such numbers in that interval, with exactly two prime factors.)

Step 1:

Choose p1 as any prime no larger than 1023/2 = 511.5. I'll pick p1 = 137. Then the second prime factor must be a prime that lies in the interval

```
[512 1023]/137
ans =
3.7372 7.4672
```

thus either 5 or 7.

```
dec2bin(137*[5 7])
ans =
1010101101
1110111111
```