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Without getting into unnecessary details, is it possible for operations on floating-point numbers (x86_64) to return -however small- variations on their results, based on identical inputs? Even a single bit different?

I am simulating a basically chaotic system, and I expect small variations on the data to have visible effects. However I expected that, with the same data, the behavior of the program would be fixed. This is not the case. I get visible, but acceptable, differences with each run of the program.

I am thinking I have left some variable uninitialized somewhere...

The languages I am using are C++ and Python.


Russell's answer is correct. Floating point ops are deterministic. The non-determinism was caused by a dangling pointer.

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Can you provide an SSCCE? –  Mysticial Jul 15 '12 at 6:50
I am afraid not, it's a fairly complex program. :-( –  Panayiotis Karabassis Jul 15 '12 at 6:52

2 Answers 2

up vote 3 down vote accepted

Contra Thomas's answer, floating point operations are not non-deterministic. They are fiendishly subtle, but a given program should give the same outputs for the same inputs, if it is not using uninitialized memory or deliberately randomized data.

My first question is, what do you mean by "the same data"? How is that data getting into your program?

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Non-determinism may occur in multi-threaded programs which distribute floating-point jobs among multiple threads, if the timing of the threads affects the order in which results are incorporated into subsequent calculations. Non-determinism may also occur between different compilers, use of different compiler switches, compilations of the same program for different targets, different compiler versions, and even different compilations of the same source with identical switches (the compiler itself may be non-deterministic). –  Eric Postpischil Jul 15 '12 at 11:43
Well, the "data" is built into the program, a set of initial conditions are generated from constant literals, and then the simulation proceeds deterministically. No user input is accepted, no timer is read, no pointers are converted to ints, etc. To the best of my knowledge. Compiling with gcc's -Weffc++ warns against no uninitialized data. The simulation happens entirely in C++ and is only visualized by python. My other concern is iterator access, but as far as I know that happens deterministically too (first to last in std::vector, which is the only collection I use). –  Panayiotis Karabassis Jul 15 '12 at 12:02
The program is not recompiled between runs. BTW what about Thomas's quotation? Is it plainly wrong? Because it mentions the same installation, and the example cos(x) != cos(y) suggests a single run. –  Panayiotis Karabassis Jul 15 '12 at 12:04
I think Thomas's quotation is pointing out that cos(x) can != cos(x) for different calls to cos() in the same program, in contexts where register allocation or other compiler optimization pressures are different. A single call to cos() at a single point in the program compiles to a particular sequence of machine instructions, and those instructions produce the same output from the same input. –  Russell Borogove Jul 15 '12 at 18:00
Eric, those are good points except you're using the term non-determinism way, way too loosely. In the multithreading case, the order of thread execution, while unpredictable and unknown, is one of the inputs to the algorithm, and hence the result is deterministic for given inputs. –  Russell Borogove Jul 15 '12 at 18:02

Yes, this is possible. Quoting from the C++ FAQ:

Turns out that on some installations, cos(x) != cos(y) even though x == y. That's not a typo; read it again if you're not shocked: the cosine of something can be unequal to the cosine of the same thing. (Or the sine, or the tangent, or the log, or just about any other floating point computation.)


[F]loating point calculations and comparisons are often performed by special hardware that often contain special registers, and those registers often have more bits than a double. That means that intermediate floating point computations often have more bits than sizeof(double), and when a floating point value is written to RAM, it often gets truncated, often losing some bits of precision.

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Thanks, I could not find any uninitialized variables, so this must be it. –  Panayiotis Karabassis Jul 15 '12 at 7:19
That's not non-determinism, though. The same inputs into the same code should give the same results. The explanation you give here allows for two superficially similar blocks of code to yield two different results from the same inputs, but that's a different thing entirely. –  Russell Borogove Jul 15 '12 at 7:55
A context switch could result in registers being swapped out to RAM and back in, and context switches can occur at "nondeterministic" moments (from the program's point of view). Therefore, the same code could give different results depending on when a context switch happens. Or am I misunderstanding your point? –  Thomas Jul 15 '12 at 9:58
@Thomas: Context switches do not change registers, as visible by a process. The operating system saves and restores all state of the architecture-specified programming environment, including all bits of all regular registers. (A few special things may change, such as the lock state of load-and-reserve and store-conditional instructions.) Consider that these “extra” bits are unspecified in languages like C, but they are absolutely part of the programming environment for assembly-language programmers and must be preserved by the operating system. –  Eric Postpischil Jul 15 '12 at 11:08
Has this behavior actually been observed in a high-quality compiler that is largely conforming to C/C++? If cos were written as a C or C++ function, the language standards require that floating-point values be cast to the semantic type by the return statement. In other words, even if the compiler calculates with extended precision, the return value must be converted to double. Thus, given x==y, cos(x)==cos(y); after the return, there are no extra bits to retain or lose. A better example might be x+y==x+y, since this expression has no return to force a conversion. –  Eric Postpischil Jul 15 '12 at 11:31

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