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I always thought random numbers would lie between zero and one, without 1, i.e. they are numbers from the half-open interval [0,1). The documention on cppreference.com of std::generate_canonical confirms this.

However, when I run the following program:

#include <iostream>
#include <limits>
#include <random>

int main()
{
    std::mt19937 rng;

    std::seed_seq sequence{0, 1, 2, 3, 4, 5, 6, 7, 8, 9};
    rng.seed(sequence);
    rng.discard(12 * 629143 + 6);

    float random = std::generate_canonical<float,
                   std::numeric_limits<float>::digits>(rng);

    if (random == 1.0f)
    {
        std::cout << "Bug!\n";
    }

    return 0;
}

It gives me the following output:

Bug!

i.e. it generates me a perfect 1, which causes problems in my MC integration. Is that valid behavior or is there an error on my side? This gives the same output with G++ 4.7.3

g++ -std=c++11 test.c && ./a.out

and clang 3.3

clang++ -stdlib=libc++ -std=c++11 test.c && ./a.out

If this is correct behavior, how can I avoid 1?

Edit 1: G++ from git seems to suffer from the same problem. I am on

commit baf369d7a57fb4d0d5897b02549c3517bb8800fd
Date:   Mon Sep 1 08:26:51 2014 +0000

and compiling with ~/temp/prefix/bin/c++ -std=c++11 -Wl,-rpath,/home/cschwan/temp/prefix/lib64 test.c && ./a.out gives the same output, ldd yields

linux-vdso.so.1 (0x00007fff39d0d000)
libstdc++.so.6 => /home/cschwan/temp/prefix/lib64/libstdc++.so.6 (0x00007f123d785000)
libm.so.6 => /lib64/libm.so.6 (0x000000317ea00000)
libgcc_s.so.1 => /home/cschwan/temp/prefix/lib64/libgcc_s.so.1 (0x00007f123d54e000)
libc.so.6 => /lib64/libc.so.6 (0x000000317e600000)
/lib64/ld-linux-x86-64.so.2 (0x000000317e200000)

Edit 2: I reported the behavior here: https://gcc.gnu.org/bugzilla/show_bug.cgi?id=63176

Edit 3: The clang team seems to be aware of the problem: http://llvm.org/bugs/show_bug.cgi?id=18767

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  • 22
    @David Lively 1.f == 1.f in all cases (what all cases are there? I don't even seen any variables in 1.f == 1.f; there's only one case here: 1.f == 1.f, and that is invariably true). Please don't spread this myth further. Floating point comparisons are always exact. Sep 4, 2014 at 15:09
  • 15
    @DavidLively: No, it's not. The comparison is always exact. It's your operands that may not be exact if they are calculated and not literals. Sep 4, 2014 at 15:10
  • 2
    @Galik any positive number below 1.0 is a valid result. 1.0 is not. It's as simple as that. Rounding is irrelevant: the code gets a random number and doesn't perform any rounding on it. Sep 4, 2014 at 15:13
  • 7
    @DavidLively he's saying that there is only one value that compares equal to 1.0. That value is 1.0. Values close to 1.0 don't compare equal to 1.0. It doesn't matter what the generation function does: if it returns 1.0 it will compare equal to 1.0. If it doesn't return 1.0 it will not compare equal to 1.0. Your example using abs(random - 1.f) < numeric_limits<float>::epsilon checks if the result is close to 1.0, which is totally wrong in this context: there are numbers close to 1.0 that are valid results here, namely, all those that are less than 1.0. Sep 4, 2014 at 15:23
  • 4
    @Galik Yes, there will be trouble implementing that. But that trouble is for the implementer to deal with. The user must never see a 1.0, and the user must always see an equal distribution of all the results. Sep 4, 2014 at 15:30

3 Answers 3

122

The problem is in mapping from the codomain of std::mt19937 (std::uint_fast32_t) to float; the algorithm described by the standard gives incorrect results (inconsistent with its description of the output of the algorithm) when loss of precision occurs if the current IEEE754 rounding mode is anything other than round-to-negative-infinity (note that the default is round-to-nearest).

The 7549723rd output of mt19937 with your seed is 4294967257 (0xffffffd9u), which when rounded to 32-bit float gives 0x1p+32, which is equal to the max value of mt19937, 4294967295 (0xffffffffu) when that is also rounded to 32-bit float.

The standard could ensure correct behavior if it were to specify that when converting from the output of the URNG to the RealType of generate_canonical, rounding is to be performed towards negative infinity; this would give a correct result in this case. As QOI, it would be good for libstdc++ to make this change.

With this change, 1.0 will no longer be generated; instead the boundary values 0x1.fffffep-N for 0 < N <= 8 will be generated more often (approximately 2^(8 - N - 32) per N, depending on the actual distribution of MT19937).

I would recommend to not use float with std::generate_canonical directly; rather generate the number in double and then round towards negative infinity:

    double rd = std::generate_canonical<double,
        std::numeric_limits<float>::digits>(rng);
    float rf = rd;
    if (rf > rd) {
      rf = std::nextafter(rf, -std::numeric_limits<float>::infinity());
    }

This problem can also occur with std::uniform_real_distribution<float>; the solution is the same, to specialize the distribution on double and round the result towards negative infinity in float.

21
  • 2
    @user quality of implementation - all the things that make one conformant implementation better than another e.g. performance, behavior in edge cases, helpfulness of error messages.
    – ecatmur
    Sep 4, 2014 at 20:09
  • 2
    @supercat: To digress a bit, there actually are good reasons to try to make sine functions as accurate as possible for small angles, e.g. because small errors in sin(x) can turn into large errors in sin(x)/x (which occurs quite often in real-world calculations) when x is close to zero. The "extra precision" near multiples of π is generally just a side effect of that. Sep 4, 2014 at 20:16
  • 1
    @IlmariKaronen: For sufficiently small angles, sin(x) is simply x. My squawk at Java's sine function relates to is with angles that are near multiples of pi. I would posit that 99% of the time, when code asks for sin(x), what it really wants is the sine of (π/Math.PI) times x. The people maintaining Java insist that it's better to have a slow math routine report that the sine of Math.PI is difference between π and Math.PI than to have it report a value which is slightly less, notwithstanding that in 99% of applications it would be better...
    – supercat
    Sep 4, 2014 at 20:47
  • 3
    @ecatmur Suggestion; update this post to mention that std::uniform_real_distribution<float> suffers from the same problem as a consequence of this. (So that people searching for uniform_real_distribution will have this Q/A come up).
    – M.M
    Nov 25, 2014 at 21:53
  • 2
    @ecatmur, I'm not sure why you want to round towards negative infinity. Since generate_canonical should generate a number in the range [0,1), and we're talking about an error where it generates 1.0 occasionally, wouldn't rounding towards zero be just as effective? Aug 26, 2015 at 18:12
39

According to the standard, 1.0 is not valid.

C++11 §26.5.7.2 Function template generate_canonical

Each function instantiated from the template described in this section 26.5.7.2 maps the result of one or more invocations of a supplied uniform random number generator g to one member of the specified RealType such that, if the values gi produced by g are uniformly distributed, the instantiation’s results tj , 0 ≤ tj < 1, are distributed as uniformly as possible as specified below.

1
  • 25
    +1 I can't see any flaw in the OP's program, so I'm calling this a libstdc++ and libc++ bug... which itself seems a little unlikely, but there we go. Sep 4, 2014 at 15:14
-2

I just ran into a similar question with uniform_real_distribution, and here's how I interpret the Standard's parsimonious wording on the subject:

The Standard always defines math functions in terms of math, never in terms of IEEE floating-point (because the Standard still pretends that floating-point might not mean IEEE floating point). So, any time you see mathematical wording in the Standard, it's talking about real math, not IEEE.

The Standard says that both uniform_real_distribution<T>(0,1)(g) and generate_canonical<T,1000>(g) should return values in the half-open range [0,1). But these are mathematical values. When you take a real number in the half-open range [0,1) and represent it as IEEE floating-point, well, a significant fraction of the time it will round up to T(1.0).

When T is float (24 mantissa bits), we expect to see uniform_real_distribution<float>(0,1)(g) == 1.0f about 1 in 2^25 times. My brute-force experimentation with libc++ confirms this expectation.

template<class F>
void test(long long N, const F& get_a_float) {
    int count = 0;
    for (long long i = 0; i < N; ++i) {
        float f = get_a_float();
        if (f == 1.0f) {
            ++count;
        }
    }
    printf("Expected %d '1.0' results; got %d in practice\n", (int)(N >> 25), count);
}

int main() {
    std::mt19937 g(std::random_device{}());
    auto N = (1uLL << 29);
    test(N, [&g]() { return std::uniform_real_distribution<float>(0,1)(g); });
    test(N, [&g]() { return std::generate_canonical<float, 32>(g); });
}

Example output:

Expected 16 '1.0' results; got 19 in practice
Expected 16 '1.0' results; got 11 in practice

When T is double (53 mantissa bits), we expect to see uniform_real_distribution<double>(0,1)(g) == 1.0 about 1 in 2^54 times. I don't have the patience to test this expectation. :)

My understanding is that this behavior is fine. It may offend our sense of "half-open-rangeness" that a distribution claiming to return numbers "less than 1.0" can in fact return numbers that are equal to 1.0; but those are two different meanings of "1.0", see? The first is the mathematical 1.0; the second is the IEEE single-precision floating-point number 1.0. And we've been taught for decades not to compare floating-point numbers for exact equality.

Whatever algorithm you feed the random numbers into isn't going to care if it sometimes gets exactly 1.0. There's nothing you can do with a floating-point number except mathematical operations, and as soon as you do some mathematical operation, your code will have to deal with rounding. Even if you could legitimately assume that generate_canonical<float,1000>(g) != 1.0f, you still wouldn't be able to assume that generate_canonical<float,1000>(g) + 1.0f != 2.0f — because of rounding. You just can't get away from it; so why would we pretend in this single instance that you can?

3
  • 2
    I strongly disagree with this view. If the standard dictates values from a half-open interval and an implementation breaks this rule, the implementation is wrong. Unfortunately, as ecatmur correctly pointed out in his answer, the standard also dictates the algorithm which has a bug. This is also officially recognized here: open-std.org/jtc1/sc22/wg21/docs/lwg-active.html#2524
    – cschwan
    Sep 9, 2017 at 17:02
  • @cschwan: My interpretation is that the implementation is not breaking the rule. The standard dictates values from [0,1); the implementation returns values from [0,1); some of those values happen to round up to IEEE 1.0f but that's just unavoidable when you cast them to IEEE floats. If you want pure mathematical results, use a symbolic computation system; if you are trying to use IEEE floating-point to represent numbers that are within eps of 1, you are in a state of sin. Sep 9, 2017 at 19:15
  • Hypothetical example that would be broken by this bug: divide something by canonical - 1.0f. For every representable float in [0, 1.0), x-1.0f is non-zero. With exactly 1.0f, you can get a divide-by-zero instead of just a very tiny divisor. Jul 23, 2020 at 9:21

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