# Floating point versus fixed point: what are the pros/cons?

Floating point type represents a number by storing its significant digits and its exponent separately on separate binary words so it fits in 16, 32, 64 or 128 bits.

Fixed point type stores numbers with 2 words, one representing the integer part, another representing the part past the radix, in negative exponents, 2^-1, 2^-2, 2^-3, etc.

Float are better because they have wider range in an exponent sense, but not if one wants to store number with more precision for a certain range, for example only using integer from -16 to 16, thus using more bits to hold digits past the radix.

In terms of performances, which one has the best performance, or are there cases where some is faster than the other ?

In video game programming, does everybody use floating point because the FPU makes it faster, or because the performance drop is just negligible, or do they make their own fixed type ?

Why isn't there any fixed type in C/C++ ?

• My impression is that fixed point would be faster except that FPU's make floating point quite fast. And that fixed point (aside from integers) is not much supported in languages and CPUs because it's not very flexible, and can be pretty easily simulated using integers. But I'm not an expert in that area. Sep 11 '10 at 21:35
• Your understanding of how fixed-point numbers are represented is incorrect. Sep 11 '10 at 21:39
• @oli : damn it ! I'm losing it ! Sep 11 '10 at 22:30
• in fixed-point numbers, the denominator is implicitly hardcoded in the software (that is, all code that deals with the numbers assume a fixed exponent/denominator) For example, 1.30 decimal is represented as 85196 / 65536 if the denominator is 2^16. The denominator is not stored. Note that this representation is still inexact (1.300 == 85196.800 / 65536.000). Neither is floating-point. Sep 12 '10 at 0:00
• @jokoon your example is BCD-coding, somewhat. But not fixed-point Jul 29 '16 at 12:42

That definition covers a very limited subset of fixed point implementations.

It would be more correct to say that in fixed point only the mantissa is stored and the exponent is a constant determined a-priori. There is no requirement for the binary point to fall inside the mantissa, and definitely no requirement that it fall on a word boundary. For example, all of the following are "fixed point":

• 64 bit mantissa, scaled by 2-32 (this fits the definition listed in the question)
• 64 bit mantissa, scaled by 2-33 (now the integer and fractional parts cannot be separated by an octet boundary)
• 32 bit mantissa, scaled by 24 (now there is no fractional part)
• 32 bit mantissa, scaled by 2-40 (now there is no integer part)

GPUs tend to use fixed point with no integer part (typically 32-bit mantissa scaled by 2-32). Therefore APIs such as OpenGL and Direct3D often use floating-point types which are capable of holding these values. However, manipulating the integer mantissa is often more efficient so these APIs allow specifying coordinates (in texture space, color space, etc) this way as well.

As for your claim that C++ doesn't have a fixed point type, I disagree. All integer types in C++ are fixed point types. The exponent is often assumed to be zero, but this isn't required and I have quite a bit of fixed-point DSP code implemented in C++ this way.

• The difference between an integer and a true fixed-point type is that when doing fixed-point using integers you have to shift the result after a multiple or divide operation. A built-in fixed type would do that under the hood. On fixed-point DSP hardware, this is directly supported by the instruction set, but other wise if makes fixed-point * and / operations slower than the corresponding plain integer operatons. Sep 11 '10 at 22:04
• @Oli: Since DirectX9 they are; it is part of the DirectX9 specification. Sep 11 '10 at 22:15
• Well, you CAN shift the result after each multiply or divide, but that isn't necessarily a good idea. It's often desirable simply to let the (hidden) exponent of the result be different from the arguments, and do the shift at the very end. Sometimes the shift may never be necessary (if for example you simply want to compare the result to a constant, you can change the exponent of the constant to match without needing a runtime shift). Furthermore, shifting by certain intervals is free on many architectures, by storing e.g. AH or AL registers to memory instead of EAX. Sep 11 '10 at 23:03
• There's another pretty popular fixed-point implementation: infinite-digit decimal mantissa, scaled by 10^-2. Otherwise known as money. Obviously not relevant to game programming (well, not to the graphics part anyways, but actually pretty important for MMORPGs), but one of the most widely used fixed-point datatypes. Sep 11 '10 at 23:52
• @Jörg: Actually, at least for the `euro` currency, it was specified that operations should be conducted with 5 digits (to avoid too much rounding errors) and then rounded to 2 digits using mathematical rounding at the very end. Furthermore a number of currencies do not have any digit at all (for example, the yen, which subdivision has not been used since 1954). Sep 12 '10 at 12:25

At the code level, fixed-point arithmetic is simply integer arithmetic with an implied denominator.

For many simple arithmetic operations, fixed-point and integer operations are essentially the same. However, there are some operations which the intermediate values must be represented with a higher number of bits and then rounded off. For example, to multiply two 16-bit fixed-point numbers, the result must be temporarily stored in 32-bit before renormalizing (or saturating) back to 16-bit fixed-point.

When the software does not take advantage of vectorization (such as CPU-based SIMD or GPGPU), integer and fixed-point arithmeric is faster than FPU. When vectorization is used, the efficiency of vectorization matters a lot more, such that the performance differences between fixed-point and floating-point is moot.

Some architectures provide hardware implementations for certain math functions, such as `sin`, `cos`, `atan`, `sqrt`, for floating-point types only. Some architectures do not provide any hardware implementation at all. In both cases, specialized math software libraries may provide those functions by using only integer or fixed-point arithmetic. Often, such libraries will provide multiple level of precisions, for example, answers which are only accurate up to N-bits of precision, which is less than the full precision of the representation. The limited-precision versions may be faster than the highest-precision version.

Fixed point is widely used in DSP and embedded-systems where often the target processor has no FPU, and fixed point can be implemented reasonably efficiently using an integer ALU.

In terms of performance, that is likley to vary depending on the target architecture and application. Obviously if there is no FPU, then fixed point will be considerably faster. When you have an FPU it will depend on the application too. For example performing some functions such as sqrt() or log() will be much faster when directly supported in the instruction set rather thna implemented algorithmically.

There is no built-in fixed point type in C or C++ I imagine because they (or at least C) were envisaged as systems level languages and the need fixed point is somewhat domain specific, and also perhaps because on a general purpose processor there is typically no direct hardware support for fixed point.

In C++ defining a fixed-point data type class with suitable operator overloads and associated math functions can easily overcome this shortcomming. However there are good and bad solutions to this problem. A good example can be found here: http://www.drdobbs.com/cpp/207000448. The link to the code in that article is broken, but I tracked it down to ftp://66.77.27.238/sourcecode/ddj/2008/0804.zip

• Your link to the source code is also broken (at least at time of writing this), but I've also managed to find it on the site of the company that the original author works for: justsoftwaresolutions.co.uk/files/fixed_source.zip Dec 4 '10 at 11:48
• Note that I found a bug in the log() function, one of the the look-up tables was short by one value. This was verified by the author, but it looks like these files have not been updated. I'll post the details of the correction when I can dig it out. Dec 4 '10 at 12:08

The diferrence between floating point and integer math depends on the CPU you have in mind. On Intel chips the difference is not big in clockticks. Int math is still faster because there are multiple integer ALU's that can work in parallel. Compilers are also smart to use special adress calculation instructions to optimize add/multiply in a single instruction. Conversion counts as an operation too, so just choose your type and stick with it.

In C++ you can build your own type for fixed point math. You just define as struct with one int and override the appropriate overloads, and make them do what they normally do plus a shift to put the comma back to the right position.

• Actually, integer math isn't fastest. Spreading the work across integer ALU, FPU, and SIMD unit is fastest, but obviously much more complex. Sep 11 '10 at 21:59
• @Ben: True, but this is beyond the scope of this question.
– user180326
Sep 11 '10 at 22:17

You need to be careful when discussing "precision" in this context.

For the same number of bits in representation the maximum fixed point value has more significant bits than any floating point value (because the floating point format has to give some bits away to the exponent), but the minimum fixed point value has fewer than any non-denormalized floating point value (because the fixed point value wastes most of its mantissa in leading zeros).

Also depending on the way you divide the fixed point number up, the floating point value may be able to represent smaller numbers meaning that it has a more precise representation of "tiny but non-zero".

And so on.

You dont use float in games because it is faster or slower you use it because it is easier to implement the algorithms in floating point than in fixed point. You are assuming the reason has to do with computing speed and that is not the reason, it has to do with ease of programming.

For example you may define the width of the screen/viewport as going from 0.0 to 1.0, the height of the screen 0.0 to 1.0. The depth of the word 0.0 to 1.0. and so on. Matrix math, etc makes things real easy to implement. Do all of the math that way up to the point where you need to compute real pixels on a real screen size, say 800x400. Project the ray from the eye to the point on the object in the world and compute where it pierces the screen, using 0 to 1 math, then multiply x by 800, y times 400 and place that pixel.

floating point does not store the exponent and mantissa separately and the mantissa is a goofy number, what is left over after the exponent and sign, like 23 bits, not 16 or 32 or 64 bits.

floating point math at its core uses fixed point logic with extra logic and extra steps required. By definition compared apples to apples fixed point math is cheaper because you dont have to manipulate the data on the way into the alu and dont have to manipulate the data on the way out (normalize). When you add in IEEE and all of its garbage that adds even more logic, more clock cycles, etc. (properly signed infinity, quiet and signaling nans, different results for same operation if there is an exception handler enabled). As someone pointed out in a comment in a real system where you can do fixed and float in parallel, you can take advantage of some or all of the processors and recover some clocks that way. both with float and fixed clock rate can be increased by using vast quantities of chip real estate, fixed will remain cheaper, but float can approach fixed speeds using these kinds of tricks as well as parallel operation.

One issue not covered is the answers is a power consumption. Though it highly depends on specific hardware architecture, usually FPU consumes much more energy than ALU in CPU thus if you target mobile applications where power consumption is important it's worth consider fixed point impelementation of the algorithm.

• I wonder if you can design software to be sort of easily ported between floating and fixed point algorithms. So far I don't think that'd be easy... Dec 31 '13 at 16:03
• Actually it's pretty simple. All you need in most cases is 'typedef int32 fixed' and '#define MUL(a,b) ((int32)((int64)(a) * (b)) >> radix)' and you are ready to go. Dec 31 '13 at 22:18

It depends on what you're working on. If you're using fixed point then you lose precision; you have to select the number of places after the decimal place (which may not always be good enough). In floating point you don't need to worry about this as the precision offered is nearly always good enough for the task in hand - uses a standard form implementation to represent the number.

The pros and cons come down to speed and resources. On modern 32bit and 64bit platforms there is really no need to use fixed point. Most systems come with built in FPUs that are hardwired to be optimised for fixed point operations. Furthermore, most modern CPU intrinsics come with operations such as the SIMD set which help optimise vector based methods via vectorisation and unrolling. So fixed point only comes with a down side.

On embedded systems and small microcontrollers (8bit and 16bit) you may not have an FPU nor extended instruction sets. In which case you may be forced to use fixed point methods or the limited floating point instruction sets that are not very fast. So in these circumstances fixed point will be a better - or even your only - choice.