What are the benefits of the following C code?

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Given log(a) and log(b), return log(a+b)

``````double log_sum(double log_a, double log_b){
double v;
if(log_a < log_b){
v=log_b+log(1+exp(log_a-log_b));
}
else{
v=log_a+log(1+exp(log_b-log_a));
}
return v;
}
``````

I want to know what are the benefits of the above function?

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It probably compiles. That's one benefit. – Mike Daniels Jul 21 '10 at 5:37
What do you mean exactly? Do you mean what is the benefit of the `if` statement? – j_random_hacker Jul 21 '10 at 5:43
-1 for being annoyingly vague. – JWWalker Jul 21 '10 at 5:55
Actually, I don't think it's 'annoyingly vague'. The example code appears to to compute a value that can be computed in different ways, most of which are simpler and/or take less code to represent. I take the question to mean "What are the benefits of doing it this way as opposed to the more obvious ways?" – johne Jul 21 '10 at 6:10

The primary (brute force) alternative looks like:

``````v = log(exp(log_a) + exp(log_b));
``````

That has three transcendental function evaluations.

The computation shown uses just two transcendental functions - and should be quicker.

It may also be more stable numerically.

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Others have already mentioned the potential loss of precision, but in this case the problem is really overflows. Try this:

``````double log_a = 100;
double log_b = 1000;
printf("%f\n", log_b+log(1+exp(log_a-log_b)));
printf("%f\n", log_a+log(1+exp(log_b-log_a)));
``````

On a typical platform, the first one will print "inf" while the second one will print "1000.000000".

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 Yes, that makes sense. – procrastinate_later Jul 22 '10 at 6:02

If you're asking about the if/else, it's to avoid loss of precision. All arithmetic operations on floating point numbers (except for multiplication by powers of 2 and certain cases of addition/subtraction of numbers of the same exponent) destroy information, and good floating point code will choose the method with the least loss of precision.

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Computers and logs don't always get along. As has been alluded to by others, accuracy becomes a real problem. This blog post goes a long way toward explaining this phenomenon. The article is about seemingly unnecessary library functions, and why they are actually very handy.

The function log1p computes log(1 + x). How hard could this be to implement?

There are all sorts of crazy rules and transforms you can use when dealing with logs/exponentials. What I'm guessing is that the author used some of these rules to either make the calculation more accurate, more efficient, or both.

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 +1, that's a good link. John D. Cook has written some good articles at www.codeproject.com as well. – j_random_hacker Jul 22 '10 at 3:44

Not really an answer, but a possible clue.

Numbers kept in "log form" can be multiplied or divided by simply adding or subtracting the numbers. For example, `exp(log(a) + log(b))` is the same as `a * b`. Or, using a = 41, b = 101, this would be `exp(3.71357 + 4.61512)`, which is `exp(8.32869)`, or `4140.98930`. Obviously precision plays a part, and I truncated the numbers to 5 digits. `41 * 101` is `4141`.

I haven't worked through your example code, nor is it immediately obvious to me why your code does things the way it does, but hopefully the above will be able to help you piece it together.

EDIT: I ran some numbers through your example code. If a = 41 and b = 101, and log_a = 3.71357 and log_b = 4.61512, then your example code computes `4.95582`, and `exp(4.95582)` is equal to `142.0`. The "simpler" way to get this same result is `log(exp(log_a) + exp(log_b))`, but as others have pointed out, this way involves three expensive transcendental functions, whereas your example code requires only two (plus a trivial comparison).

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Others have posted good answers for why to do this at all. I'm wondering about the if/else part. Regardless of whether `log_a` or `log_b` is bigger, both expressions for `v` should be equivalent to `log(a+b)`. In each case `0 < exp( ... ) <= 1`, and `log(1+exp( ... ))` is a small positive number. For some reason I don't know this must be good.

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If you mean as opposed to `log(exp(log_a) + exp(log_b))`, then the benefit is pretty clear; the way you mention only has to calculate one log and one exp, while this way has to calculate two exps. That is far more costly than an extra addition/subtraction/if test.

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I guess you ask why this function is better than directly computing `log(a+b)` by restoring `a` and `b`, summing them and computing `log()`:

`````` log( exp( log_a ) + exp( log_b ) )
``````

In that case you need to compute exponent twice, and in the function you ask about exponent is computed only once. Since computing exponent is relatively time consuming that might be faster.

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