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I'm about to create a terrain for a mobile game which allows a huge terrain which is mostly limited by the available hardisk space.

This requires to keep the floating points limited to a "after-point-precision" of 2 numbers. What is a good approach to keep it at the precision of 2 numbers after the point?

Remember: I'm running on a mobile device, so the method should be fast and easy to use and should be applicable to any arithmetic which is needed for games.

More information

I'm not talking about space( i know how much space a float takes guys, really ), i'm talking about the issue that i loose precision when my floating point is going to have to many numbers after the decimal point.

Using a int would cause that i've to convert the int into a float each frame. I don't know how fast the conversion is but this seems to cost a lot of performance when doing it for a lot of objects. ( Remeber i'm on a mobile device ).

Of course i'm also not talking about the terrain, i'm talking about objects in the terrain! The terrain is a specialized system which actually can hold a terrain size which extends the limits of the floats a lot ( It's even possible to save north america in this system when you have enough disk space, but actually the limits are set to -99km to +99km ).

Edit 2

As usual in games the movement is timebased, means i need to multiply the speed of the object with a modifier given to me by unity, this corrupts my numbers which are limited to 2 numbers after the decimal point.

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Will an int not suffice and just have it represent the smallest possible accuracy you want? As in, 2 decimal places. Floating point issues then simply disappear. 1.02 then becomes 102 in int land. – Adam Houldsworth Mar 20 '12 at 13:43
First off, floats are four bytes no matter what number they contain. Second, if you can do the storage in integers, do it. Third, if you want to represent a large terrain in a small space then you're going to have to take advantage of some kind of compression technology. Is the terrain immutable? If so then you might be able to get good compression out of an immutable quadtree; that's a pretty standard technique for games with large terrain resources. – Eric Lippert Mar 20 '12 at 13:49
OK, so let's take a step back here. Why do you want to limit precision? Why are you making your logic less accurate and less precise, and slower when it could be more accurate, more precise and faster? – Eric Lippert Mar 20 '12 at 14:40
@FelixK.: You need to represent positions to within a centimeter over a range of 200 km. Let's bump that up to millimeter precision just for the heck of it. There are only two hundred million distinct points. Assign each of them an integer. A 32 bit integer can hold numbers between +/- two billion. Now all your calculations will be rounded to the nearest millimeter. – Eric Lippert Mar 20 '12 at 14:53
@EricLippert I have a feeling OP wants to multiply movement (force) by a float (time), so using floats make sense in this case as the result of such an operation is a float. His main problem is that he doesn't want floating point imprecision and wants to round the floats to a 0.01 precision point. I think my solution is good enough in this case. Representing all of the positions is also an interesting answer, but it won't help in getting movement. – SpaceToast Mar 20 '12 at 15:01

2 Answers 2

up vote 1 down vote accepted

An interesting way would be to implement this into the movement function:

float result = //multiply force by time
float modulus = result%0.01f;
result -= modulus; //you will do this in any case
if(modulus>=0.005f) {/*round up. if you want it to only round down, remove
  the next 2 lines, if you want it to only round up, remove
  the conditional statement*/
  result+=0.01f; }

I can't think about how to optimize it further, I removed the else statement and have it take away the modulus without condition as it will be done anyway.

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Made some test's, the performance seems to be ok as long not to many objects are moved. – Felix K. Mar 20 '12 at 15:44
Which is what I've been saying ^^. Mathematical operations actually take up very little performance, and, at the base, this is just 2-3 math operations for every object. A possible improvement would be to declare result and modulus OUTSIDE the loop to prevent deallocating-reallocating memory in each iteration (like: float result=0, modulus=0; //begin the loop where you just use them rather then declare them again and again – SpaceToast Mar 20 '12 at 15:54
Note that the rounding logic has an away-from-zero bias because it doesn't employ so-called "banker's rounding". – phoog Mar 20 '12 at 16:39
Some improvements: – Thorsten S. Mar 21 '12 at 22:36
a) Use binary numbers as smallest value: Instead of using 0.01f. use 0.0078125 if you do not mind. This is faster than a division with a filled mantissa because it is equivalent to a simple shift operation. b) Instead using the division use inverse multiplication because multiplication is faster than division. Ok, normally compilers get it, but the principle stays. c) At all it is following operations: Multiply with 128, floor(A fast replacement of floor is adding with 16777216 and subtracting 16777216 again), and multiply with 1/128. – Thorsten S. Mar 21 '12 at 22:44

Huh, doesn't matter what precision you choose to operate at they still take up the same amount of space. Single or double would make a difference, but the real question you should ask is do you need floating points at all. If you can fit the numbers in an int, do that.

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OP wants to use it in Unity3D. What I don't see is why he has a problem with float vars. – SpaceToast Mar 20 '12 at 13:50
+1 for pointing out no space is saved by limiting precision. – adelphus Mar 20 '12 at 13:50
I'm not interested in saving space. I like to keep the "after-point-precision" in a specific range to avoid precision issues with floats. – Felix K. Mar 20 '12 at 13:53
You can have it processed in the loop (0.01 increments (O(1)), automatically round them down (O(n)) or just ignore numbers past 0.01 (O(1)) – SpaceToast Mar 20 '12 at 13:55
Avoiding "precision" issues with floats is an exercise in futility, if it's a concern avoid floats. By the time you've ironed out all the potential for precision errors you'll have invented a badly designed inefficient and unmaintainable fixed point type anyway... – Tony Hopkinson Mar 20 '12 at 16:30

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