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I've ran into a pretty wierd problem with doubles. I have a list of floating point numbers (double) that are sorted in decreasing order. Later in my program I find however that they are not exactly sorted anymore. For example:

0.6545651031    <-- a
0.65456513001   <-- b

The two numbers in the middle are flipped. One might think that this problem lies in the representations of the numbers, and they are just printed out wrong. But I compare each number with the previous one using the same operator I use to sort them - there is no conversion to base 10 or similar going on:

double last_pt = 0;
for (int i = 0; i < npoints; i++) {
  if (last_pt && last_pt < track[i]->Pt()) {
    cout << "ERROR: new value " << track[i]->Pt()
         << " is higher than previous value " << last_pt << endl;
  last_pt = track[i]->Pt();

The values are compared during sorting by

bool moreThan(const Track& a, const Track& b) {
  return a.Pt() > b.Pt();

and I made sure that they are always double, and not converted to float. Pt() returns a double. There are no NaNs in the list, and I don't touch the list after sorting.

Why is this, what's wrong with these numbers, and (how) can I sort the numbers so that they stay sorted?

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AFAIK, float is almost always 32 bytes whereas double is 64 bytes, on both architectures. –  Constantinius Jul 4 '12 at 13:59
Thanks, that was what I was assuming. So at least it's probably not that... –  jdm Jul 4 '12 at 14:00
Could it be the sorting that is wrong? What do you use for sorting? –  Andreas Brinck Jul 4 '12 at 14:02
I hope a = b is a typo. –  R. Martinho Fernandes Jul 4 '12 at 14:03
Please add a working program that reproduces your error –  TemplateRex Jul 4 '12 at 14:13

2 Answers 2

Are you sure you're not converting double to float at some time? Let us take a look at binary representation of these two numbers:

0 01111111110 0100111100100011001010000011110111010101101100010101
0 01111111110 0100111100100011001010010010010011111101011010001001

In double we've got 1 bit of sign, 11 bits of exponent and 53 bits of mantissa, while in float there's 1 bit of sign, 8 bit of exponent and 23 bits of mantissa. Notice that mantissa in both numbers are identical at their first 23 bits.

Depending on rounding method, there would be different behaviour. In case when bits >23 are just trimmed, these two numbers as float are identical:

0 011111110 01001111001000110010100 (trim: 00011110111010101101100010101)
0 011111110 01001111001000110010100 (trim: 10010010011111101011010001001)
share|improve this answer
Good observation! This should help me narrow it down. It's a huge code base with different modules connected by configuration scripts :-/. That's why I can't easily come up with a minimal example. I was 90% sure, but can't exclude the possibility. –  jdm Jul 4 '12 at 14:19
Mind that unless the rounding mode has been changed explicitly it is round-to-nearest on x86 and x64 and the second number should have 1 in the lsb of the significand when converted to float (tested with gcc and icc with 32- and 64-bit Linux targets, as well as VS2010 with 32- and 64-bit targets, both with x87 and SSE instructions). –  Hristo Iliev Jul 4 '12 at 14:59

You're comparing the return value of a function. Floating point return values are returned in a floating point register, which has higher precision than a double. When comparing two such values (e.g. a.Pt() > b.Pt()), the compiler will call one of the functions, store the return value in an unnamed temporary of type double (thus rounding the results to double), then call the other function, and compare its results (still in the floating point register, and not rounded to double) with the stored value. This means that you can end up with cases where a.Pt() > b.Pt() and b.Pt() > a.Pt(), or a.Pt() > a.Pt(). Which will cause sort to get more than a little confused. (Formally, if we're talking about std::sort here, this results in undefined behavior, and I've heard of cases where it did cause a core dump.)

On the other hand, you say that Pt() "just returns a double field". If Pt() does no calculation what so ever; if it's only:

double Pt() const { return someDouble; }

, then this shouldn't be an issue (provided someDouble has type double). The extended precision can represent all possible double values exactly.

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Interesting, your right about the Pt() function (1.usa.gov/MJbljh). I just checked again, and it does perform a calculation (however, I do expect to calls to Pt() do always return the same value). –  jdm Jul 4 '12 at 14:55
This is only true for code that uses x87 FPU. The x64 ABI requires that floating-point values are passed in the XMM registers. –  Hristo Iliev Jul 4 '12 at 15:02
@jdm The calls themselves will always return the same value. But that value has extended precision, and the compiler will "spill" one of the return values to memory, before making the second function call. The value spilled to memory will be rounded to double precision. The solution is to force both return values to double precision, by assigning them to a local variable, and comparing the local variables, e.g. double t1 = a.Pt(); double t2 = b.Pt(); return t1 > t2;. –  James Kanze Jul 4 '12 at 15:16
Extended precision in return values would not cause the behavior reported by the asker. The two out-of-order floating-point values differ in double-precision, so they would differ in extended precision (and also differ if one were double, one were extended, and either was converted to the type of the other and then compared). This difference would cause them to be sorted correctly. –  Eric Postpischil Jul 4 '12 at 22:29
@EricPostpischil The problem is comparing an extended precision value with the same value, but which has been stored in a double. I've actually seen cases where the equivalent of a.Pt() > a.Pt() would return true. Which is enough to confuse std::sort. –  James Kanze Jul 5 '12 at 7:02

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