I am having an interesting seg fault in the following function when I give it a number very close to 1.0. Specifically when the number would be rounded to 1.0 at FLOATING POINT precision.

double get_random_element(double random_number)
    if (random_number <= 0.0 || random_number >= 1.0)
        throw std::runtime_error("Can't have a random number not on the range (0.0, 1.0)");
    return -log(-log(random_number));

If random_number is 1.0 then log(1.0) = 0.0 and the log of zero is an undefined calculation leading to a seg fault. However I would have thought that the error checking on the first line would have prevented this from ever happening. Ddebugging shows that a number very close to 1 will pass through the error checking but return 0 from the log function anyway leading me to believe that the log function is using only single floating point precision.

my includes are as follows so i can only assume I'm using the log from math.h

#include <string>
#include <math.h>
#include <sstream>
#include <map>
#include <boost/random/mersenne_twister.hpp>
#include <boost/random/uniform_int.hpp>
#include <boost/random/uniform_real.hpp>
#include <boost/random/variate_generator.hpp>
#include <utility>

UPDATE: As pointed out an easy solution is to just use a floating point number as the argument and if a number equal to 1.0f is passed in to just remove std::numeric_limits::epsilon() to give a number which can be safely passed into the double log.

But the question I'd like answered is why does calling double log of a number near but not equal to 1 fail.

UPDATE 2: After recreating this problem in a test project I think the problem is actually in the inputs. If I pass in

double val = 1.0 - std::numerical_limits<double>::epsilon();

I have no problems with the function. However what I actually pass in is

boost::mt19937 random_generator;
double val = (random_generator()+1)/4294967297.0;

where random_generator is designed to return a number on the range [0, 2^32 - 1] == [0,4294967295]. So I decided to punch in the largest possible return value

double val = (4294967295+1)/4294967297.0;

which quickly gave me a warning about unsigned int overflow and sure enough generated a zero. I am recompiling with the following:


and hopefully this strange behaviour will be resolved.

UPDATE 3: I have finally found what is going on here... and as usual it comes down to user error (myself being the error). There was a second control path leading to this method which temporarily stored the double value as a float and then converted it back to double leading to 0.999999999 being rounded to 1.0 and then passed into the -log(-log(x)) function and causing it to fall over. What I still don't understand is why my checking

 if (random_number <= 0.0 || random_number >= 1.0) throw runtime_error(blah)

didn't catch the erroneous input before it was passed into the log functions?

  • No need to assume; use ::log and preprocess your source to verify – sehe May 15 '11 at 21:50
  • are you sure it's a seg fault? – David Heffernan May 15 '11 at 21:52
  • @sehe running a preprocessor shows math.h log functions imported @david not sure if it's a seg fault or just an unsupported opertation... but it kills the host application pretty good either way :) – Jamie Cook May 15 '11 at 22:03
  • 2
    @Jamie: Surely its the comparison between a double and 1.0f which is the problem? – quamrana May 15 '11 at 22:13
  • What compiler are you using ? Most importantly, what options did you pass about floating point operations (/fp:... with visual studio) ? Did you try with 1.0 instead of 1.0f (it shouldn't change anything) ? Did you try r + std::numeric_limits<double>::epsilon() > 1 instead of r >= 1 ? – Alexandre C. May 15 '11 at 22:16

I think quamrana has a good point (it immediately drew my attention too). However, I've been able to run this snippet for considerable length:

#include <math.h>
#include <boost/random/mersenne_twister.hpp>
#include <boost/random/uniform_real.hpp>

double get_random_element(double random_number)
    if (random_number <= 0 || random_number >= 1.0f)
        throw std::runtime_error("Can't have a random number not on the range (0.0, 1.0)");
    return -::log(-::log(random_number));

int main()
    boost::mt19937 rng; 
    boost::uniform_real<> random(std::numeric_limits<double>::epsilon(),1);
    for (;;)
        double r = random(rng);
        double gre = get_random_element(r);
        std::cout << "r = " << r << ", gre = " << gre << std::endl;
    return 0; // not reached


sehe@meerkat:/tmp$ ./t | grep '^r = 0.999999' 
r = 0.999999, gre = 14.4777
r = 0.999999, gre = 13.7012
r = 0.999999, gre = 14.0492
r = 0.999999, gre = 14.1161
[.... many many lines snipped ....]
r = 0.999999, gre = 14.3691
r = 0.999999, gre = 13.424
r = 0.999999, gre = 14.4822
r = 0.999999, gre = 14.286
r = 0.999999, gre = 14.4344
r = 0.999999, gre = 14.0572
r = 0.999999, gre = 14.0607
r = 0.999999, gre = 14.1126
r = 0.999999, gre = 13.575
r = 0.999999, gre = 13.4754
r = 0.999999, gre = 13.5486
r = 0.999999, gre = 14.1983

real    18m14.005s
user    20m5.667s
sys 12m19.302s

Perhaps you could use something similar in vein?

  • This makes me think that the problem may be with compiler flags. Try /fp:strict in MSVC (or the equivalent for your compiler) and see if the problem persists. – Alexandre C. May 15 '11 at 22:34
  • sehe, I've just updated the question... we are using a mersenne twister as you are but I'm not entirely sure what the uniform_real takes as arguments... are those inclusive or exclusive boundaries? – Jamie Cook May 15 '11 at 22:35
  • Simple documentation lookup: uniform_real models a random distribution. On each invocation, it returns a random floating-point value uniformly distributed in the range [min..max). I'm surprised you would write the input distribution yourself, yet be paranoid enough to need to check that fact :) – sehe May 15 '11 at 22:40
  • 1
    paranoia is funny like that :P The problem I see with the above code is that it is guaranteed to fail if run for long enough because your rng should at some stage generate a 0 which would lead to log of zero and a fail. But maybe it would have made more sense for us to use boost::uniform_real<> random(std::numerical_limits<double>::epsilon(),1); – Jamie Cook May 15 '11 at 22:47
  • I'm updating the sample code so as not to confuse future visitors. (I must admit I totally missed the fact that 0 wasn't allowable too :)) – sehe May 15 '11 at 22:50

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