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I am trying to build a deterministic simulation, where the floating point numbers are truncated off via the following function: (I found it here: http://joshblog.net/2007/01/30/flash-floating-point-number-errors )

return Math.round(10000 * float) / 10000;

My question is: wouldn't the fact that I am dividing it by 10000, be in itself a source of floatpoint errors? IE every time a dividision takes place, it will result in a new float with further possible nondeterministic results.

EDIT: how about this? using only powers of 2

return Math.round(float* 1024) / 1024;
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This generally not an appropriate way to make floating-point code deterministic. Basic floating-point operations are completely deterministic, and making software deterministic is largely a matter of ensuring the compiler or interpreter uses the specific operations you intended. (For cross-platform or cross-version determinism, controlling the libraries is also important, since routines like log use approximations, which may vary between vendors and versions.) If you want to quantize as you ask, there are ways to do it with no scaling error, such as by using powers of 2 instead of 10. – Eric Postpischil Jul 6 '12 at 19:45
Thanks for the response Eric, it is indeed a Cross-platform issue, but as one of the platforms is Flash/Actionscript, using a Fixedpoint struct(with a 2 based shift) is not an option. Or is there another way to do it? – Martin K Jul 6 '12 at 20:53
Then it is a language/environment issue that I am not qualified to speak to, since I do not work in Flash/Actionscript. In particular, I do not know if Actionscript is specified well enough to guarantee identical floating-point operations on different platforms. I can say the division will only introduce a very small error, and it will be deterministic unless the compiler/interpreter modifies it (e.g., multiplying by a reciprocal instead), combines it with other operation, or uses extended precision for intermediate calculations. – Eric Postpischil Jul 6 '12 at 21:35
Additionally, note that rounding to multiples of a quantum helps only if you know that the errors so far have not accumulated to more than half of the quantum. Otherwise, the rounding operation may round to an undesired value. – Eric Postpischil Jul 6 '12 at 21:36
Yes, this 'rounding' would be applied to each individual function/statement that could result in a float ( otherwise the application runs off Integers) So how about modifying the above function to round off based on powers of 2? return Math.round(float* 1024) / 1024; - would this make it more deterministic? – Martin K Jul 6 '12 at 22:06
up vote 2 down vote accepted

My goal was to achieve greater consistency across platforms(C# / AS3 and 32/64 bits), while I accept that 100% consistency is not possible. (due to AS3 not capable of real integer math, as all internal operations are performed via floats)

What I have gathered so far( Thanks to Eric Postpischil and Jeffrey Sax):

Math.round(1024 * float) / 1024;

Out of the above, the "Math.round(1024 * float)" operation may NOT produce identical results on all platforms, if the "errors have accumulated to more than half of the quantum" which is possible even "within a single operation".

  • While this is mathematically possible, it is likely to be very rare, so overall this operation will still eliminate more inconsistencies than it would generate, so it is worthwhile to perform it as it will reduce inconsistency across platforms (though cannot eliminate them)


Where as for the "/ 1024" part, as 1024 is a power of 2, that is a straight bit shift, it will NOT introduce extra errors, where as if I divided by 1000 that would introduce a small chance of an extra error, as 1000 cannot be perfectly represented. So a division with 1000 could introduce another error after the rounding which the division by 1024 could not.


CONCLUSION: Math.round(1024 * float) / 1024; is better than Math.round(1000 * float) / 1000; although neither of them is perfect.

Is this an accurate statement?

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When you say deterministic, I'm assuming you want a reproducible simulation, where you get the exact same results every time you run the simulation.

To make this happen, you need to find the source of possible variation and eliminate it.

The only way is to compile to a binary for a specific architecture.

Floating-point arithmetic itself is fully specified. The floating-point standards (IEEE-754) are followed by all modern processors and leave no ambiguity.

There are two main variations:

  1. Differences in instruction sets. This is the most obvious one. If you compile your application to 32 or 64 bit, you will likely get slightly different results. 32 bit applications tend to use older style x87 instructions which use 80 bit intermediate values. This causes some results to be rounded differently. Even on x86 there are differences, if you use SSE instructions, which work on multiple operands at once. Some compilers may generate code that depends on how operands are aligned in memory.

  2. Differences in instruction ordering. Mathematically, (a+b)+c and a+(b+c) are equivalent (addition is associative). In floating-point calculations this is not the case. If a is one, b is minus one, and c a tiny number so that 1+c gets rounded to 1, then the expressions evaluate to c and 0, respectively. It is the compiler that decides which instructions to use. Depending on your language and platform, it may be the language compiler or the Just-in-Time IL/bytecode compiler. Either way, the compiler is a black box, and it may change the way it compiles code without our knowledge. The smallest difference can lead to a different end result.

The rounding approach looks nice in theory, but it doesn't work. No matter how you round, there are always cases where two different but equivalent sets of instructions produce a result that gets rounded differently.

The core reason is that rounding is not composable, in the sense that rounding to a digits, and then rounding to b (< a) digits is not equivalent to rounding to b digits from the beginning. For example: 1.49 rounded to one digit is 1.5 and rounding that to zero digits gives 2. But rounding to zero digits directly yields 1.

So, on an x87-based system which uses 80-bit 'extended' precision for intermediate values, you start with 64 significant bits. You can round this down directly to your desired precision. If you have double-precision intermediates, you get the same intermediate result, but rounded to 53 significant bits, which is then rounded to your desired precision.

Your only option is to produce machine code for a specific architecture.

Now, if your goal is only to minimize the differences instead of completely eliminating them, then the answer is straightforward: dividing or multiplying by a power of two (like 1024) does not introduce any additional round-off error in the range used by your application, while multiplying and dividing by a number like 1000 does.

If you look at accumulating errors as a random walk, then using 1000 for rounding requires more steps than using 1024. Both the multiplication and the division may introduce additional errors. So on average, the total error will be larger, and so you have a bigger chance that the rounding operation goes the wrong way. This is even true when you round on every operation.

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wow thats a lot of information! thanks, how about the dividing with 1024 (ie powers of 2)? wouldn't that make it consistent across different platforms? (Compiling to specific architecture is not an option, as its cross platform, ie one client is Flash/AS3 another one is C# ) – Martin K Jul 6 '12 at 21:47
In addition to those, there are problems with instruction contraction (such as replacing a*b+c with a fused multiply-add instruction) or other operation rewriting by the compiler/interpreter, differences in library routines (different vendors‘ log routines return different results), non-standard modes (denormals flushed to zeroes). – Eric Postpischil Jul 7 '12 at 0:55
It is not true that the standards leave no ambiguity. For example, underflow may be detected before rounding or after rounding. – Eric Postpischil Jul 7 '12 at 0:56
There is a list of things to do to obtain reproducible results on pages 51-52 of the IEEE Standard for Binary Floating-Point Arithmetic—2008. They require cooperation from the language processor et cetera. – Eric Postpischil Jul 7 '12 at 1:20
@MartinK, there are no CPU specifications that prevent “epsilons” larger than three decimals. The amount of error in a result is a function of the operations performed on it, and error analysis is a complicated task. It is possible for operations to produce an arbitrarily large error. (E.g., if you have an x with some amount of error x' and you multiply by y [which we suppose is exact], then the error is x'•|y|. So, if y is large, the error is large. And, if you have a z that is nearly equal to x, and you calculate (x-z)•y, then the relative error is large.) – Eric Postpischil Jul 8 '12 at 10:53

Dividing by 10,000 results in a rounding error equal to the difference between the exact mathematical result and the nearest number representable in double-precision, assuming IEEE 754 binary floating-point arithmetic in round-to-nearest mode. This error is at most 1/2 ULP (unit of least precision) of the result.

Multiplying by a power of two, rounding to an integer, and dividing by the same power of two will not cause have any errors in the rounding operations except: Multiplication with an exact result around 21024 (the exact threshold is slightly slower) or greater will produce a floating-point infinity. (In general, multiplication or division by powers of two can produce rounding errors when the result underflows the floating-point range, that is, when the exact mathematical result is in (0, 2-1022). However, underflow will not occur when calculating round(x*p)/p for p some positive power of 2 less than 21023.)

Quantizing numbers in this way will not in general produce deterministic results. Deviations between two platforms may occur when pre-quantization values have errors may straddle midpoints between quanta.

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"Multiplying by a power of two, rounding to an integer, and dividing by the same power of two will not cause have any errors in the rounding operations except: Multiplication with an exact result around 2^1024 (the exact threshold is slightly slower) or greater will produce a floating-point infinity. " - in plain english, are you saying that if the values I am working which are < 2^31, IE Integer sized, then the method of multiplying by 1024 and dividing by 1024 will produce Cross platform consistent results ??? – Martin K Jul 8 '12 at 11:18
No, I am saying that multiplying by a power of two produces no error and dividing by a power of two produces no error. However, this is not where the problem in your method lies. The problem lies in the round operation. The round operation is incapable of transforming non-deterministic results into deterministic results, in the absence of proof that the inputs to round do not straddle midway points. – Eric Postpischil Jul 8 '12 at 12:23
Eric, I do realise that without fixed point maths or true integer only maths it is NOT possible to be 100% deterministic, but as I also said one of my target languages is AS3, which is incapable of true integer maths, so I know it is not going to be perfect, but I am looking for the least bad solution, and from what you are saying it appears that multiplying1024->rounding->dividing1024 will introduce less extra errors than by doing the same with a 1000. So with all things being equal 1024 is better than 1000, there may still be errors, but less likely, Yes?? – Martin K Jul 8 '12 at 12:40
Rounding operands not known to be on the same side of the midway point on different platforms is unreliable. – Eric Postpischil Jul 8 '12 at 12:42
Ok putting it in another way, making the "arbitary" assumption of epsilon < .0001, which of out of the two options 1024 or 1000 is LESS likely to produce an error? – Martin K Jul 8 '12 at 12:45

Here is code demonstrating that rounding to multiples of a quantum does not produce deterministic results, even when there is no error in scaling.

The output I get is:

Machine 0 produces 0x1p+0 (1).
Machine 1 produces 0x1.004p+0 (1.0009765625).
The results differ.

The source code is:

#include <stdio.h>
#include <math.h>

// Round a value to the nearest multiple of the quantum.
static double Quantize(double x)
    static const double Quantum = 1024., InverseQuantum = 1/Quantum;

    return round(x * Quantum) * InverseQuantum;

int main(void)
    /*  For this example, we are in the middle of some calculation, where we
        have some value a from earlier operations.  a0 and a1 represent the
        calculated values of a on two different platforms.  Observe that the
        difference is as small as possible, just a single ULP.
    double a0 = 0x1.cbd9f42000000p0;
    double a1 = 0x1.cbd9f42000001p0;

    // Define a constant that the calculation uses.
    double b = 0x1.1d2b9fp-1;

    // Calculate the pre-quantization result on each machine.
    double x0 = a0 * b;
    double x1 = a1 * b;

    // Quantize the result on each machine.
    double y0 = Quantize(x0);
    double y1 = Quantize(x1);

    // Display the results.
    printf("Machine 0 produces %a (%.53g).\n", y0, y0);
    printf("Machine 1 produces %a (%.53g).\n", y1, y1);
    printf("The results %s.\n", y0 == y1 ? "are identical" : "differ");

    return 0;
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Eric I do accept this now, that the rounding operation MAY not eliminate all inconsistencies across platforms but it will still more likely to reduce them? Have a look at my own 'conclusions' answer! – Martin K Jul 8 '12 at 14:07

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