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I'm looking for a commonly understandable notation to define a fixed point number representation. The notation should be able to define both a power-of-two factor (using fractional bits) and a generic factor (sometimes I'm forced to use this, though less efficient). And also an optional offset should be defined.
I already know some possible notations, but all of them seem to be constrained to specific applications.

  • For example the Simulink notation would perfectly fit my needs, but it's known only in the Simulink world. Furthermore the overloaded usage of the fixdt() function is not so readable.

  • TI defines a really compact Q Formats, but the sign is implicit, and it doesn't manage a generic factor (i.e. not a power-of-two).

  • ASAM uses a generic 6-coefficient rational function with 2nd-degree numerator and denominator polynomials (COMPU_METHOD). Very generic, but not so friendly.

See also the Wikipedia discussion.

The question is only about the notation (not efficiency of the representation nor fixed-point manipulation). So it's a matter of code readability, maintenability and testability.

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The wikipedia link doesn't work for me. –  Barmar Mar 15 at 10:34
    
@omegatre I think you now mis-fixed the discussion link… –  DarkDust Mar 15 at 10:38
    
@DarkDust yes, thankyou –  omegatre Mar 15 at 10:41
    
Considering the research you did, any options left are probably more obscure than ones you list... Also, here at SO, opinion based questions are explicitly off topic, so you should re-phrase the last paragraph to not ask for opinions... –  hyde Mar 15 at 10:47
    
Please do not close this question. It is absolutely on-topic for fixed point arithmetic. This is not just nice to have, it is impossible to do reliable fixed point arithmetic without a given notation. –  hlovdal Mar 15 at 12:11

3 Answers 3

up vote 2 down vote accepted

Ah, yes. Having good naming annotations is absolutely critical to not introducing bugs with fixed point arithmetic. I use an explicit version of the Q notation which handles any division between M and N by appending _Q<M>_<N> to the name of the variable. This also makes it possible to include the signedness as well. There are no run-time performance penalties for this. Example:

uint8_t length_Q2_6;                // unsigned, 2 bit integer, 6 bit fraction
int32_t sensor_calibration_Q10_21;  // signed (1 bit), 10 bit integer, 21 bit fraction.

/*
 * Calculations with the bc program (with '-l' argument):
 *
 * sqrt(3)
 * 1.73205080756887729352
 *
 * obase=16
 * sqrt(3)
 * 1.BB67AE8584CAA73B0
 */
const uint32_t SQRT_3_Q7_25 = 1 << 25 | 0xBB67AE85U >> 7; /* Unsigned shift super important here! */

In case someone have not fully understood why such annotation is extremely important, Can you spot the if there is an bug in the following two examples?

Example 1:

speed_fraction = fix32_udiv(25, speed_percent << 25, 100 << 25);
squared_speed  = fix32_umul(25, speed_fraction, speed_fraction);
tmp1 = fix32_umul(25, squared_speed, SQRT_3);
tmp2 = fix32_umul(12, tmp1 >> (25-12), motor_volt << 12);

Example 2:

speed_fraction_Q7_25 = fix32_udiv(25, speed_percent << 25, 100 << 25);
squared_speed_Q7_25  = fix32_umul(25, speed_fraction_Q7_25, speed_fraction_Q7_25);
tmp1_Q7_25  = fix32_umul(25, squared_speed_Q7_25, SQRT_3_Q1_31);
tmp2_Q20_12 = fix32_umul(12, tmp1_Q7_25 >> (25-12), motor_volt << 12);

Imagine if one file contained #define SQRT_3 (1 << 25 | 0xBB67AE85U >> 7) and another file contained #define SQRT_3 (1 << 31 | 0xBB67AE85U >> 1) and code was moved between those files. For example 1 this has a high chance of going unnoticed and introduce the bug that is present in example 2 which here is done deliberately and has a zero chance of being done accidentally.

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In C, you can't use a user defined type like a builtin one. If you want to do that, you need to use C++. In that language you can define a class for your fixed point type, overload all the arithmetic operators (+, -, *, /, %, +=, -=, *=, /=, %=, --, ++, cast to other types), so that usage of the instances of this class really behave like the builtin types.

In C, you need to do what you want explicitly. There are two basic approaches.


Approach 1: Do the fixed point adjustments in the user code.
This is overhead-free, but you need to remember to do the correct adjustments. I believe, it is easiest to just add the number of past point bits to the end of the variable name, because the type system won't do you much good, even if you typedef'd all the point positions you use. Here is an example:

int64_t a_7 = (int64_t)(7.3*(1<<7));    //a variable with 7 past point bits
int64_t b_5 = (int64_t)(3.78*(1<<5));   //a variable with 5 past point bits
int64_t sum_7 = a_7 + (b_5 << 2);    //to add those two variables, we need to adjust the point position in b
int64_t product_12 = a_7 * b_5;    //the product produces a number with 12 past point bits

Of course, this is a lot of hassle, but at least you can easily check at every point whether the point adjustment is correct.


Approach 2: Define a struct for your fixed point numbers and encapsulate the arithmetic on it in a bunch of functions. Like this:

typedef struct FixedPoint {
    int64_t data;
    uint8_t pointPosition;
} FixedPoint;

FixedPoint fixed_add(FixedPoint a, FixedPoint b) {
    if(a.pointPosition >= b.PointPosition) {
        return (FixedPoint){
            .data = a.data + (b.data << a.pointPosition - b.pointPosition),
            .pointPosition = a.pointPosition
        };
    } else {
        return (FixedPoint){
            .data = (a.data << b.pointPosition - a.pointPosition) + b.data,
            .pointPosition = b.pointPosition
        };
    }
}

This approach is a bit cleaner in the usage, however, it introduces significant overhead. That overhead consists of:

  1. The function calls.

  2. The copying of the structs for parameter and result passing, or the pointer dereferences if you use pointers.

  3. The need to calculate the point adjustments at runtime.

This is pretty much similar to the overhead of a C++ class without templates. Using templates would move some decisions back to compile time, at the cost of loosing flexibility.

This object based approach is probably the most flexible one, and it allows you to add support for non-binary point positions in a transparent way.

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the question was about fixed point representation; your solution adds un-necessary overhead no matter how you cut it. You do not provide a way of representing the data, you just provide a wrapper... –  Pandrei Mar 15 at 11:19
    
@Pandrei If you look closely, you'll see that I'm actually representing numbers in fixed point format. And that I'm showing, how to actually do arithmetic on them. And, as you can easily see, I suggest two different solutions, one of which does not add any unnecessary runtime overhead. Really, all your points are completely unfounded. –  cmaster Mar 15 at 11:24
    
I'm only going to comment on your first suggestion (the second I find more complicated than letting the compiler emulate the fractional data types): your solution is not a representation scheme; you are mixing precision, you don't even mention the fact that certain operation will result in different format representation (like multiplication) and how to compensate for that. So it's not a valid representation scheme. –  Pandrei Mar 15 at 11:37
    
I've never seen that you can use a standalone . in C like that –  Lưu Vĩnh Phúc Mar 15 at 11:42
    
@LưuVĩnhPhúc That's an addition of the C11 standard, it allows you to set the individual data members of a struct by name, instead of having to rely on correct order of the values in the initializer list. –  cmaster Mar 15 at 11:44

Actually Q format is the most used representation in commercial applications: you use is when you need to deal with fractional numbers FAST and your processor does not have a FPU (floating point unit) is it cannot use float and double data types natively - it has to emulate instructions for them which are very expensive.

usually you use Q format to represent only the fractional part, though this not a must, you get more precision for your representation. Here's what you need to consider:

  • number of bits you use (Q15 uses 16 bitdata types, usually short int)
  • the first bit is the sign bit (out of 16 bits you are left with 15 for data value)
  • the rest of the bits are used to store the fractional part of your number.
  • since you are representing fractional numbers your value is somewhere in [0,1)
  • you can choose to use some bits for the integer part as well, but you would loose precision - e.g if you wanted to represent 3.3 in Q format, you would need 1 bit for sign, 2 bits for the integer part, and are left with 12 bits for the fractional part (assuming you are using 16 bits representation)-> this format is called 2Q12

Example: Say you want to represent 0.3 in Q15 format; you apply the Rule of Three:

      1 = 2^15 = 32768 = 0x8000
    0.3 = X
    -------------
    X = 0.3*32768 = 9830 = 0x666

You lost precision by doing this but at least the computation is fast now.

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