Can anyone recommend any C++ libraries/routines/packages that contain strategies for maintaining the stability of various floating point operations?

Example: suppose you would like to sum across a vector/array of one million `long double`

in the unit interval (0,1), and that each number is of about the same order of magnitude. Naively summing `for (int i=0;i<1000000;++i) sum += array[i];`

is unreliable - for large enough `i`

, `sum`

will be of a much larger order of magnitude than `array[i]`

, and so `sum += array[i]`

would be equivalent to `sum += 0.00`

.
(Note: the solution to this example is a binary summing strategy.)

I deal with sums and products of thousands/millions of miniscule probabilities. I am using the arbitrary-precision library `MPFRC++`

with a 2048 bit significand, but the same concerns still apply.

I am chiefly concerned with:

- Strategies for accurately summing many numbers (e.g. above Example).
- When is multiplication and division potentially unstable? (If I want to normalize a large array of numbers, what should my normalization constant be? The smallest value? The largest? A median?)