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Edit: See the end of the question for an update on the answer.

I have spent several weeks tracking down a very odd bug in a piece of software I maintain. Long story short, there is an old piece of software that is in distribution, and a new piece of software that needs to match the output of the old. The two rely (in theory) on a common library.[1] However, I cannot duplicate the results being generated by the original version of the library, even though the source for the two versions of the library matches. The actual code in question is very simple. The original version looked like this (the "voodoo" commented isn't mine):[2]

// float rstr[101] declared and initialized elsewhere as a global

void my_function() {
    // I have elided several declarations not used until later in the function
    double tt, p1, p2, t2;
    char *ptr;

    ptr = NULL;
    p2 = 0.0;
    t2 = 0.0; /* voooooodoooooooooo */

    tt = (double) rstr[20];
    p1 = (double) rstr[8];

    // The code goes on and does lots of other things ...
}

The last statement I have included is where different behavior crops up. In the original program, rstr[8] has the value 101325., and after casting it to double[3] and assigning it, p1 has the value 101324.65625. Similarly, tt ends up with the value 373.149999999996. I have confirmed these values with both debug prints and examining the values in the debugger (including checking the hex values). This is not surprising in any sense, it is as expected with floating point values.

In a test wrapper around the same version of the library (as well as in any call to a refactored version of the library), the first assignment (to tt) produces the same results. However, p1 ends up as 101325.0, matching the original value in rstr[8]. This difference, while small, sometimes produces substantial variations in calculations that depend on the value of p1.

My test wrapper was simple, and matched the inclusion pattern of the original exactly, but eliminated all other context:

#include "the_header.h"

float rstr[101];
int main() {
    rstr[8] = 101325.;
    rstr[20] = 373.15;

    my_function();
}

Out of desperation, I have even gone to the trouble of looking at the disassembly generated by VC6.

4550:   tt = (double) rstr[20];
0042973F   fld         dword ptr [rstr+50h (006390a8)]
00429745   fstp        qword ptr [ebp-0Ch]
4551:   p1 = (double) rstr[8];
00429748   fld         dword ptr [rstr+20h (00639078)]
0042974E   fstp        qword ptr [ebp-14h]

The version generated by VC6 for the same library function when called by the test code wrapper (which matches the version generated by VC6 for my refactored version of the library):

60:       tt = (double) rstr[20];
00408BC8   fld         dword ptr [_rstr+50h (0045bc88)]
00408BCE   fstp        qword ptr [ebp-0Ch]
61:       p1 = (double) rstr[8];
00408BD1   fld         dword ptr [_rstr+20h (0045bc58)]
00408BD7   fstp        qword ptr [ebp-14h]

The only difference I can see, besides where in memory the array is stored and how far along through the program this is occuring, is the leading _ on the reference to rstr in the second. In general, VC6 uses a leading underscore for name-mangling with functions, but I cannot find any documentation of it doing name-mangling with array pointers. Nor can I see why these would produce different results in any case, unless that name-mangling is involved with reading the data accessed from the pointers in a different way.

The only other difference I can identify between the two (apart from calling context) is that the original is an MFC-based Win32 application, while the latter is a non-MFC console application. The two are otherwise configured the same way, and they are built with identical compilation flags and against the same C runtime.

Any suggestions would be much appreciated.


Edit: the solution, as several answers very helpfully pointed out, was to examine the binary/hex values and compare them to make sure the things I thought were exactly the same in fact were the same. This proved not to be the case—my strong protestations to the contrary notwithstanding.

Here I get to eat some humble pie and admit that while I thought I had checked those values, I had in fact checked some other, closely related values—a point I discovered only when I went back to look at the data again. As it turned out, the values being set in rstr[8] were very slightly different, and so the conversion to double highlighted the very slight differences, and these differences then propagated throughout the program in just the way I noted.

The discrepancy with the initialization I can explain based on the way the two programs work. Specifically, in one case rstr[8] is specified based on a user input to a GUI (and is in this case also the product of a conversion calculation), whereas in another, it is read in from a file where it has been stored with some loss of precision. Interestingly, in neither case was it actually exactly 101325.0, even the case in which it was read from a file where it had been stored as 1.01325e5.

This will teach me to double check my double checking of these sorts of things. Many thanks to Eric Postpischil and unwind for prompting me to check it again and for the prompt feedback. It was very helpful.


Footnotes

  1. In actuality, the original "library" was a header file with all the implementations done inline. The header was pulled in via #include and the functions referenced via extern statements. I have fixed this in a refactored version of the library that is actually a library, but see the rest of the question.
  2. Note that the variable names aren't mine, and are terrible. Likewise with the use of global variables, which is rampant in this piece of software. I left in the /* voooooodoooooooooo */ comment because it illustrates the… unusual… programming practices of my predecessor. I think that element is present because this was originally translated from Fortran and the developer had used it as a means of dealing with some sort of memory bug. The line has no effect whatsoever on the actual behavior of the code.
  3. I am well aware that there doesn't actually need to be a cast here, but this is how the original library worked, and I cannot modify it.
share|improve this question
2  
Note that the literal 373.15 is a double. You assign it to a float. a float is not able to exactly represent 373.15 . However, if the source is the same, what's different ? Different compiler ? compiler setting ? different calls to fesetround(), use of non standard _control_fp() ? –  nos Nov 21 '13 at 16:09
    
Correct, which is why I was not surprised by the original behavior of the program, in which the value displayed after casting to double was a long decimal rather than exact. –  Chris Krycho Nov 21 '13 at 16:10
1  
Note: In general, typical double needs 17 decimal digits to uniquely present its value. 101324.65625 shows 11 and 373.149999999996 shows 15. The degree of precision is not likely the issue here but may help. Further - I suspect your determination that rstr[8] has the value 101325 is due to an integer view of rstr[8] with integer truncation and it in fact has the exact value of 101325 21/32. –  chux Nov 21 '13 at 17:08
2  
Show me (from both codes) hex value of rstr[20] and tt value after this assignment tt = (double) rstr[20] - same with rstr[8] and p1 var. IMHO - there is sth wrong with your debug method or you are misinterpreting things that you see. –  Artur Nov 21 '13 at 17:57
1  
@chux, if there is an integer truncation going on, it is in the debugger view. That is certainly possible, but it is reporting it not as 101325 but 101325.—note the decimal. It may be inaccurately reporting it as a whole-valued decimal, and if so that's not the first bug I'll have found in VC6, but it's probably not truncation. –  Chris Krycho Nov 21 '13 at 18:38

4 Answers 4

up vote 6 down vote accepted

This:

In the original program, rstr[8] has the value 101325., and after casting it to double[3] and assigning it, p1 has the value 101324.65625

implies that the float value is not, in fact, exactly 101325.0, so when you convert to double you see more of the precision. I would (highly) suspect the method by which you inspect the float value, automatic (implicit and silent) rounding when printing is very common with floats. Inspect the bit pattern and decode it using the known format of the float on your system, to make sure you're not being tricked.

share|improve this answer
    
Good thought, but no, I've checked that; it is actually exact. More importantly, in any context except the original program (including a refactored version of the program, whether compiled in VC6, GCC, or clang), it ends up assigned to the double p1 as 101325. as well—in both VC6 and GCC. –  Chris Krycho Nov 21 '13 at 16:04
    
As noted, I'm going to actually pull the hex values again to confirm that they're the same. The main point of curiosity, from my point of view, is that it behaves differently when compiled with the same compiler. –  Chris Krycho Nov 21 '13 at 18:48
    
I now get to shamefully retract my previous statement. :/ I thought I had checked these as identical, but I was remembering a previous set of related values I had checked. I'll be updating the question accordingly. –  Chris Krycho Nov 21 '13 at 21:02

The possibilities are:

  1. Despite the reported observations, rstr[8] has the value 101324.65625 in the original program immediately before the assignment to p1, not the reported 101325.
  2. Despite the reported observations, p1 does not have the value 101324.65625 immediately after the assignment.
  3. The program is not performing the assignment (including the conversion to double) correctly.

To test 1, carefully inspect the value of rstr[8] immediately before the assignment. I suggest:

  • printing or logging the value to 20 significant digits, and
  • printing or logging the bytes that comprise rstr[8], then interpreting the bytes in IEEE-754 64-bit binary format, or
  • using a debugger to do both of the above.

Additionally, I suggest testing whether floating-point values are displayed sufficiently well by injecting the value 101324.65625 into rstr[8] (by assignment or debugger) and displaying it in the same way as used above.

To test 2, carefully inspect the value of p1 immediately after the assignment. I suggest the above, applied to p1 instead of rstr[8].

The disassembly code shown in the question would appear to disprove 3. However, I would consider these tests:

  • Test whether these instructions are actually executed, perhaps by setting a breakpoint on them in the debugger.
  • Examine the instructions in the debugger immediately before they are executed.
  • Examine the memory to be loaded, the floating-point register after the load instruction, and the memory after it is stored.
share|improve this answer
    
Great suggestions, thanks. As noted in my comment on the original question above, I'll go ahead and pull the bytes and check them. I should note that the point that is confusing me most is not the original assignment—which doesn't surprise me a bit—but that it behaves differently between two different approaches to the same library. –  Chris Krycho Nov 21 '13 at 18:36
    
Time to eat my words! See update I'm adding above. Thanks for the feedback and the detailed instructions on the best way to look at the data. As it turns out, option 1 was the case here. –  Chris Krycho Nov 21 '13 at 21:12
1  
@ChrisKrycho: It’s nice to have a bug involving definitive behavior that can be separated into cases and tested. –  Eric Postpischil Nov 21 '13 at 21:35

What you need to do (debugging wise) is get the binary value of rstr[20] and rstr[8] between the old and refactored version. The binary values of tt and p1 wouldn't hurt either. That will prove that the arrays are initialized the same. Assigning a double to a float array and then converting it back to a double is not loss-less.

The only odd case I can think of is the FPU's rounding mode is set differently between the old and refactored program. Check the source code for "_control_fp(", "fesetround(" or "fenv.h".

share|improve this answer
3  
Both 101324.65625 and 101325 are exactly representable in float (IEEE-754 32-bit binary floating-point in the implementations the OP is using). There would not be any error or rounding in conversion from double to float or vice-versa, regardless of the rounding mode. –  Eric Postpischil Nov 21 '13 at 16:24

The first rule of floating point is that results are approximations and should never be assumed to be exact.

Both the compiler and the CPU are able to do plenty of optimisations, and minor differences in optimisations (including lack of optimsations) can lead to minor differences in the resulting "approximations". This includes all sorts of things, like the order that operations are performed (e.g. don't assume that "(x + y) + z" is the same as "x + (y + z)"), if anything is pre-done by the compiler (e.g. constant folding), if something is inlined or not, etc.

For example, (internally) 80x86 uses 80-bit "extended precision" floating point which are more precise than double; so simply storing a result as double and loading it again causes different results to re-using the (higher precision) value already in the FPU's register.

Mostly what I'm saying is that if the exact value you're getting matters so much, then you shouldn't have been using floating point at all (consider "big rationals" or something).

share|improve this answer
    
You need to read the question more carefully. This is a maintenance task; I would not have chosen or advocated this approach (and in fact am not in future development), but it is certainly not possible to simply undo history. :) –  Chris Krycho Nov 21 '13 at 18:34

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