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I have a one-dimensional grid that is defined as a list of sorted floating point values. The points are not equidistant, but it is guaranteed that there is no any pair of clashing points (distance==0).

I need to find the most efficient way to snap any given value to the closest grid point. The most clever way I could think of was as follows (np is numpy and myGrid is a numpy array)

absDiff = np.abs(myGrid - myValue)
ix = np.argmax(absDiff)
snappedValue = myGrid[ix]

The problem is that this approach is too slow and I need a more efficient one.

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2 Answers 2

up vote 1 down vote accepted
import bisect
def snap(myGrid, myValue):
    ix = bisect.bisect_right(myGrid, myValue)
    if ix == 0:
        return myGrid[0]
    elif ix == len(myGrid):
        return myGrid[-1]
        return min(myGrid[ix - 1], myGrid[ix], key=lambda gridValue: abs(gridValue - myValue))
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In a typical case your new point will fall between two existing points in the grid. You need to use binary search to find the two points it falls between and choose the closest one out of the two. That's it.

Now all that's left is process boundary cases properly: when the points falls before first/after last and when the point hits the existing point of the grid.

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