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I have been looking at some code which had a weird optimisation fault and, in the process, stumbled upon a fault condition in strtod(), which has a different behaviour to strtof(), right on the edge of denormal values. The behaviour of strtof() seems entirely reasonable to me, but strtod() does not! Specifically, it returns -0.0 for the input value "-0x1.fffffffffffffp-1023".

That is one extra bit set to one in the representation "-0x1.ffffffffffffep-1023" which it decodes correctly. More peculiar still adding extra trailing digits gets a value 2-1018 which I cannot explain. It looks to me like the special edge case on the transition from denormals to normal floats has been handled incorrectly leading to a zero value.

Can anyone explain the other strange number that additional extra digits provoke?

The fault is identical on both MSC 2022 and Intel 2023

Sample code MRE for doubles & output (float works as you would expect)

// strtod() fails to handle edge case overflow from denormals correctly
// 
// Problem manifests on both MS 2022 and Intel 2023 compilers so by design? but why???
// 
// using Windows 11 and Microsoft Visual Studio Community 2022 (64-bit) - Version 17.1.0
 
#include <math.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <errno.h>

void Show(const char *name, int err, double arg)
{
    unsigned iarg[2];
    memcpy(&iarg, &arg, sizeof arg);
    printf("\n\"%25s\" decoded errno=%i as 0x%08x%08x %.13a %30.22g",
           name, err, iarg[1], iarg[0], arg, arg);
}

void DecodeShow(const char *value)
{
    char *stopstr;
    double arg;
    errno = 0;
    arg = strtod(value, &stopstr);
    Show(value, errno, arg);
}

int main(void)
{
    printf("Test of doubles near denorm boundary\n");
    DecodeShow("-0x1.ffffffffffffp-1023");
    DecodeShow("-0x1.ffffffffffffep-1023");
    DecodeShow("-0x1.ffffffffffffe8p-1023");
    DecodeShow("-0x1.fffffffffffff0p-1023"); // hard fail == -0.0 !
    DecodeShow("-0x1.fffffffffffff8p-1023");
    DecodeShow("-0x1.ffffffffffffffp-1023");
    DecodeShow("-0x1.fffffffffffffffp-1023");
    printf("\n");
    DecodeShow("0x1.ffffffffffffe8p-1023");
    DecodeShow("0x1.fffffffffffff0p-1023"); // hard fail == +0.0
    DecodeShow("0x1.fffffffffffff8p-1023");
    DecodeShow("0x1.ffffffffffffffp-1023");
    printf("\n");
    DecodeShow("0x1.ffffffffffffep-1022");
    DecodeShow("-0x1.fffffffffffffp-1022");
    DecodeShow("-0x1.fffffffffffff8p-1022");
    DecodeShow("-0x1.ffffffffffffffp-1022");
}

Selected output around failure boundary:

" -0x1.ffffffffffffep-1023" decoded errno=0 as 0x800fffffffffffff -0x0.fffffffffffffp-1022  -2.225073858507200889025e-308
"-0x1.ffffffffffffe8p-1023" decoded errno=0 as 0x800fffffffffffff -0x0.fffffffffffffp-1022  -2.225073858507200889025e-308
"-0x1.fffffffffffff0p-1023" decoded errno=0 as 0x8000000000000000 -0x0.0000000000000p+0                             -0
"-0x1.fffffffffffff8p-1023" decoded errno=0 as 0x8040000000000000 -0x1.0000000000000p-1019  -1.780059086805761106472e-30

It is my view that extra trailing digits going beyond machine precision should not radically alter the floating point value that strtod decodes like this. I could not provoke the same failure by using decimal digit input strings - the transition across the boundary seemed well-behaved (although I can't rule out one spot value not working that I haven't yet found).

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  • 2
    Aside: #include <cstdint> suggests you are compiling this as C++.
    – Ian Abbott
    Jan 19 at 16:32
  • 1
    You should also set errno = 0 before calling strtod() and include its value after the call. See C11 7.22.1.3p10: "" Jan 19 at 16:40
  • 3
    Re "it is not using any C++ features so it is C code.", That's not how things work. C++ is not a superset of C
    – ikegami
    Jan 19 at 16:48
  • 1
    "I had meant to delete that include line before posting": You can also edit your question after posting (make sure it does not alter the behavior of your code).
    – chtz
    Jan 19 at 16:51
  • 3
    @MartinBrown You have my word for it that it is not always 0 on my machine. Posting code that allows us all to quickly gather relevant info helps as others may see variations with the implementation defined behavior of conversions near 0.0 and give insight to your issue. Jan 19 at 17:25

2 Answers 2

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The behaviour of [...] strtod() does not [seem reasonable]! Specifically, it returns -0.0 for the input value "-0x1.fffffffffffffp-1023".

I disagree that that specific result is unreasonable, but I'm inclined to agree that the combination of results you present does not seem reasonable.

"-0x1.fffffffffffffp-1023" should not be converted to a value whose magnitude is smaller than that of the value to which "-0x1.ffffffffffffep-1023" is converted. However, given that the former is not exactly representable in IEEE-754 binary64 format whereas the latter is (as a subnormal), it would be reasonable for both to be converted to the same result. And it would be reasonable -- and certainly not contrary to the language spec -- for that result to be -0.0. That's one of the two normalized doubles bracketing the exact arithmetic results. -0.0 is exactly what I would expect, in fact, of an implementation that rounds to a normalized number when the rounding mode is FE_TOWARDZERO.

Your result for "-0x1.fffffffffffff8p-1023" is much more concerning, however. The spec calls for the result to be correctly rounded, and I don't see any circumstances under which the result you report could satisfy that requirement.

Can anyone explain the other strange number that additional extra digits provoke?

In a sense: strtod() converting "-0x1.fffffffffffff8p-1023" to -0x1.0000000000000p-1019 is a manifestation of a bug in your C implementation. Probably the same for the -0.0 result for "-0x1.fffffffffffffp-1023". I have some vague ideas about what the implementation flaw might be, but it doesn't really matter, and I choose not to speculate in this answer.

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  • Thanks for your insight. This sounds a plausible explanation. Rounding mode default (unchanged) was actually FE_TONEAREST = 0 (Intel & MS). I was struck by the fact that strtof() did exactly what I expected to see at the corresponding boundary whereas strtod() doesn't. I wonder now if it is a length parity thing affecting rounding with 23 bits for a float mantissa vs 52 bits for a double. Jan 19 at 20:46
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This is the same issue reported at https://developercommunity.visualstudio.com/t/strtod-parses-0x0fffffffffffff8p-1022-i/10293606 . A bug was filed for it in Feb 2023 (it appears it was fixed in the compiler previously, but not strtod()).

I ran the five strtod() examples in the report and these four give incorrect conversions (includes your 0 example). Each should result in 0x1.0000000000000p-1022 but

0x0.fffffffffffff8p-1022 => 0x1.0000000000000p-1020
0x1.fffffffffffffp-1023 => 0x0.0000000000000p+0
0x7.ffffffffffffcp-1025 => 0x1.0000000000000p-1021
0xf.ffffffffffff8p-1026 => 0x1.0000000000000p-1020

Note the incorrect exponents. There was no speculation in the report about what went wrong.

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  • Thanks for taking the time to confirm the fault and find the previous bug report about it. Saves me generating a Repro. Thanks again! Jan 24 at 16:19
  • I wrote up an article about this (exploringbinary.com/…) to add to my "catalog" (thanks @njuffa).
    – Rick Regan
    Jan 26 at 22:16
  • Thanks for the mention! Shame I wasn't the first to report it. BTW the exact same fault is also present in the C/C++ system library strtod() for the Intel 2023 compiler (although not for compile time constants - it gets those right). Do they perhaps have a common origin? GCC13 gets them all right. Jan 27 at 9:46

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