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:

**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.

**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.