I am processing a series of points which all have the same Y value, but different X values. I go through the points by incrementing X by one. For example, I might have Y = 50 and X is the integers from -30 to 30. Part of my algorithm involves finding the distance to the origin from each point and then doing further processing.
After profiling, I've found that the sqrt call in the distance calculation is taking a significant amount of my time. Is there an iterative way to calculate the distance?
In other words:
I want to efficiently calculate:
r[n] = sqrt(x[n]*x[n] + y*y)). I can save information from the previous iteration. Each iteration changes by incrementing x, so
x[n] = x[n-1] + 1. I can not use sqrt or trig functions because they are too slow except at the beginning of each scanline.
I can use approximations as long as they are good enough (less than 0.l% error) and the errors introduced are smooth (I can't bin to a pre-calculated table of approximations).
Additional information: x and y are always integers between -150 and 150
I'm going to try a couple ideas out tomorrow and mark the best answer based on which is fastest.
I did some timings
- Distance formula: 16 ms / iteration
- Pete's interperlating solution: 8 ms / iteration
- wrang-wrang pre-calculation solution: 8ms / iteration
I was hoping the test would decide between the two, because I like both answers. I'm going to go with Pete's because it uses less memory.