24

To do a linear interpolation between two variables a and b given a fraction f, I'm currently using this code:

float lerp(float a, float b, float f) 
{
    return (a * (1.0 - f)) + (b * f);
}

I think there's probably a more efficient way of doing it. I'm using a microcontroller without an FPU, so floating point operations are done in software. They are reasonably fast, but it's still something like 100 cycles to add or multiply.

Any suggestions?

n.b. for the sake of clarity in the equation in the code above, we can omit specifying 1.0 as an explicit floating-point literal.

25

Disregarding differences in precision, that expression is equivalent to

float lerp(float a, float b, float f)
{
    return a + f * (b - a);
}

That's 2 additions/subtractions and 1 multiplication instead of 2 addition/subtractions and 2 multiplications.

  • 28
    This is not an equivalent algorithm due to precision loss when a and b significantly differ in exponents. The OP's algorithm is always the better choice. For example, the algorithm in this answer, for lerp(-16.0e30, 16.0, 1.0) will return 0, as opposed to the correct result, 16, which the OP's algorithm produces. The precision loss occurs in the addition operator, when a is significantly larger than f * (b - a), and in the subtraction operator in (b - a). – Jason C May 17 '14 at 22:59
  • 1
    The original algorithm is also not much of a loss performance-wise: FP multiplication is much faster than FP addition, and if f is guaranteed to be between 0 and 1, certain optimizations to (1-f) are possible. – Sneftel May 17 '14 at 23:29
  • 1
    @Sneftel: Can you elaborate on the optimizations for 1 - f? I happen to be in that situation and am curious :D – Levi Morrison Sep 11 '14 at 1:54
  • 2
    @coredump Sorry about not noticing your comment 2 years ago (heh...). The OP's would still be more precise, in particular, if f * (b - a) is significantly different in magnitude than a in this algorithm then the addition falls apart. It's the addition/subtraction where you run into trouble. That said even the OP's can fail if f is too large relative to 1.0f, as 1.0f - f could become equivalent to -f for very large f. So if you're working with huge values for f you'll need to think hard about the math a bit. The issue is you run into things like 1.0 + 1.0e800 == 1.0e800. – Jason C Mar 20 '17 at 0:48
  • 3
    Just think of floating-point numbers as fixed-point mantissas and an exponent (it's more complicated than that but viewing them this way is sufficient to spot many trouble areas). So if you're exceeding the precision of the mantissa, you'll start to lose information. Conceptually similar to the fact that we cannot, for example, represent 1,230,000 in decimal with only two significant digits (1.2 * 10^6 is the closest we can get), so if you do 1,200,000 + 30,000 but you only have two significant digits at your disposal, you lose that 30,000. – Jason C Mar 20 '17 at 0:55
8

If you are on a micro-controller without an FPU then floating point is going to be very expensive. Could easily be twenty times slower for a floating point operation. The fastest solution is to just do all the math using integers.

The number of places after the fixed binary point (http://blog.credland.net/2013/09/binary-fixed-point-explanation.html?q=fixed+binary+point) is: XY_TABLE_FRAC_BITS.

Here's a function I use:

inline uint16_t unsignedInterpolate(uint16_t a, uint16_t b, uint16_t position) {
    uint32_t r1;
    uint16_t r2;

    /* 
     * Only one multiply, and one divide/shift right.  Shame about having to
     * cast to long int and back again.
     */

    r1 = (uint32_t) position * (b-a);
    r2 = (r1 >> XY_TABLE_FRAC_BITS) + a;
    return r2;    
}

With the function inlined it should be approx. 10-20 cycles.

If you've got a 32-bit micro-controller you'll be able to use bigger integers and get larger numbers or more accuracy without compromising performance. This function was used on a 16-bit system.

  • 1
    I read the website but am still a little confused at what position should be. Is this a value of 0 to 0xFFFF? or 0 to 0xFFFE? Also what is XY_TABLE_FRAC_BITS? 8? – jjxtra Apr 5 '17 at 22:15
  • @jjxtra: XY_TABLE_FRAC_BITS is just the (poorly) named integer constant whose value specifies where the assumed binary point is in the fixed point integer values being used (since it doesn't "float" around in them as it does in floating-point numbers). – martineau Oct 17 '18 at 18:45
6

Presuming floating-point math is available, the OP's algorithm is a good one and is always superior to the alternative a + f * (b - a) due to precision loss when a and b significantly differ in magnitude.

For example:

// OP's algorithm
float lint1 (float a, float b, float f) {
    return (a * (1.0f - f)) + (b * f);
}

// Algebraically simplified algorithm
float lint2 (float a, float b, float f) {
    return a + f * (b - a);
}

In that example, presuming 32-bit floats lint1(1.0e20, 1.0, 1.0) will correctly return 1.0, whereas lint2 will incorrectly return 0.0.

The majority of precision loss is in the addition and subtraction operators when the operands differ significantly in magnitude. In the above case, the culprits are the subtraction in b - a, and the addition in a + f * (b - a). The OP's algorithm does not suffer from this due to the components being completely multiplied before addition.


For the a=1e20, b=1 case, here is an example of differing results. Test program:

#include <stdio.h>
#include <math.h>

float lint1 (float a, float b, float f) {
    return (a * (1.0f - f)) + (b * f);
}

float lint2 (float a, float b, float f) {
    return a + f * (b - a);
}

int main () {
    const float a = 1.0e20;
    const float b = 1.0;
    int n;
    for (n = 0; n <= 1024; ++ n) {
        float f = (float)n / 1024.0f;
        float p1 = lint1(a, b, f);
        float p2 = lint2(a, b, f);
        if (p1 != p2) {
            printf("%i %.6f %f %f %.6e\n", n, f, p1, p2, p2 - p1);
        }
    }
    return 0;
}

Output, slightly adjusted for formatting:

    f            lint1               lint2             lint2-lint1
0.828125  17187500894208393216  17187499794696765440  -1.099512e+12
0.890625  10937500768952909824  10937499669441282048  -1.099512e+12
0.914062   8593750447104196608   8593749897348382720  -5.497558e+11
0.945312   5468750384476454912   5468749834720641024  -5.497558e+11
0.957031   4296875223552098304   4296874948674191360  -2.748779e+11
0.972656   2734375192238227456   2734374917360320512  -2.748779e+11
0.978516   2148437611776049152   2148437474337095680  -1.374390e+11
0.986328   1367187596119113728   1367187458680160256  -1.374390e+11
0.989258   1074218805888024576   1074218737168547840  -6.871948e+10
0.993164    683593798059556864    683593729340080128  -6.871948e+10
1.000000                     1                     0  -1.000000e+00
  • 3
    Interestingly, OP's version is not always superior. I thought it was then got bitten by this example: lerp(0.45, 0.45, 0.81965185546875). It obviously should give 0.45, but at least for double precision I get 0.45000000000000007 whereas clearly the a + (b-a)*f version gives a when a==b. I'd love to see an algorithm that has the property that lerp(a, b, f) returns a if f==0, b if f==1, and stays in the range [a,b] for f in [0,1]. – Ben Dec 22 '16 at 15:22
  • 1
    First, you need the case if a == b -> return a. However, exactly 0.45 is impossible to represent in double or floating point precision as it is not an exact power of 2. In your example, all parameters a, b, f are stored as double when inside the function call – returning a would never return exactly 0.45. (In the case of explicitly typed languages like C, of course) – Benjamin R Mar 20 '17 at 0:29
3

If you're coding for a microcontroller without floating-point operations, then it's better not to use floating-point numbers at all, and to use fixed-point arithmetic instead.

  • I'm planning to migrate to fixed point, but floating point is pretty fast already. – Thomas O Dec 4 '10 at 14:54
1

It is worth to note, that the standard linear interpolation formulas f1(t)=a+t(b-a), f2(t)=b-(b-a)(1-t), and f3(t)=a(1-t)+bt do not guarantee to be monotonic when using floating point arithmetic. Especially, if a != b, it is not guaranteed that the f1(1.0) == b or that f2(0.0) == a, while for a == b, f3(t) is not guaranteed to be equal to a, when 0 < t < 1.

This function has worked for me on processors that support IEEE754 floating point when I need the results to be monotonic (I use it with double precision, but float should work as well):

double lerp(double a, double b, double t) 
{
    if (t <= 0.5)
        return a+(b-a)*t;
    else
        return b-(b-a)*(1.0-t);
}
0

If you want to the final result to be an integer, it might be faster to use integers for the input as well.

int lerp_int(int a, int b, float f)
{
    //float diff = (float)(b-a);
    //float frac = f*diff;
    //return a + (int)frac;
    return a + (int)(f * (float)(b-a));
}

This does two casts and one float multiply. If a cast is faster than a float add/subtract on your platform, and if an integer answer is useful to you, this might be a reasonable alternative.

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