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For example, I have the following arrays:

x = [0, 1, 2, 3, 4.5, 5]
y = [2, 8, 3, 7,   8, 1]

I would like to be able to do the following given x:

>>> what_is_y_when_x_is(2)
(2, 3)
>>> what_is_y_when_x_is(3.1) # Perhaps set rules to round to nearest (or up or down)
(3, 7)

On the other hand, when given y:

>>> what_is_x_when_y_is(2)
(0, 2)
>>> what_is_x_when_y_is(max(y))
([1, 4.5], 8)

The circumstances of this problem

I could have plotted y versus x using a closed analytical function, which should be very easy by just calling foo_function(x). However, I'm running numerical simulations whose data plots do not have closed analytical solutions.

Attempted solution

I've tackled similar problems before and approached them roughly this way:

what_is_y_when_x_is(some_x)

  1. Search the array x for some_x.
  2. Get its index, i.
  3. Pick up y[i].

Question

Is there a better way to do this? Perhaps a built-in numpy function or a better algorithm?

share|improve this question
    
I can think of only one more efficient solution: sort your arrays, then use lnear interpolation to find the most probable index for y (or x, respectively), then start going further and further from that initial guess until you reach the destination. –  user529758 Jul 13 '12 at 9:29
    
Are you familiar with the scipy.interpolate module? For your use case I think several of the functions would be mode useful in practice than simply rounding to the nearest (although you could do that too.) –  DSM Jul 13 '12 at 16:16

4 Answers 4

You could use the bisect module for this. This is pure python - no numpy here:

>>> x = [0, 1, 2, 3, 4.5, 5]
>>> y = [2, 8, 3, 7,   8, 1]
>>> x_lookup = sorted(zip(x, y))
>>> y_lookup = sorted(map(tuple, map(reversed, zip(x, y))))
>>> 
>>> import bisect
>>> def pair_from_x(x):
...    return x_lookup[min(bisect.bisect_left(x_lookup, (x,)), len(x_lookup)-1)]
... 
>>> def pair_from_y(y):
...    return tuple(reversed(y_lookup[min(bisect.bisect_left(y_lookup, (y,)), len(y_lookup)-1)]))
... 

And some examples of using it:

>>> pair_from_x(0)
(0, 2)
>>> pair_from_x(-2)
(0, 2)
>>> pair_from_x(2)
(2, 3)
>>> pair_from_x(3)
(3, 7)
>>> pair_from_x(7)
(5, 1)
>>> 
>>> pair_from_y(0)
(5, 1)
>>> pair_from_y(1)
(5, 1)
>>> pair_from_y(3)
(2, 3)
>>> pair_from_y(4)
(3, 7)
>>> pair_from_y(8)
(1, 8)
share|improve this answer

You should look at numpy.searchsorted and also numpy.interp. Both of those look like they might do the trick. Here is an example:

import numpy as np
x = np.array([0, 1, 2, 3, 4.5, 5])
y = np.array([2, 8, 3, 7,   8, 1])

# y should be sorted for both of these methods
order = y.argsort()
y = y[order]
x = x[order]

def what_is_x_when_y_is(input, x, y):
    return x[y.searchsorted(input, 'left')]

def interp_x_from_y(input, x, y):
    return np.interp(input, y, x)

print what_is_x_when_y_is(7, x, y)
# 3
print interp_x_from_y(1.5, x, y)
# 2.5
share|improve this answer

The way you described is, as far as I'm considered, a good way. I'm not sure if you are, but I think you could use the .index(...) method on your array:

>>> li
['I', 'hope', 'this', 'answer', 'helps', 'you']
>>> li.index("hope")
1

Other than that, you might want to consider one array op "Points" which have an x and a y, though I'm not sure if this is possible of course. That way you won't have to keep two arrays in sync (same number of elements).

share|improve this answer
    
The .index() method returns the index of only the first match it finds, which also leads to the question: "What if there is no exact match?" –  Kit Jul 13 '12 at 9:43
    
You are totally right, then I would consider the "Point" thingy, and just iterate over the single list, check all the x values, and add their y values to an array. Then return this array. If there are no matching values it'll just return an empty array, which makes sense. Do the same for checking y-values. (The same thing is possible with an x-array and a y-array, though I think it's cleaner of you use "Points") –  The Oddler Jul 13 '12 at 9:55

I don't see any problem with your pipeline. You can write a snippet base on numpy.where to implement it efficiently. Note that you will have to pass your lists as numpy arrays first (this can be included in the function).

Below is an example of a function doing the job, with an option to round the target (I have included a which array argument, so everything can be done in just one function, whatever you want to search in x or y). Note that one of the output will be a numpy array, so modify it to convert it to anything you want (liste, tuple, etc ...).

import numpy as np

def pick(x_array, y_array, target, which_array='x', round=True):
    # ensure that x and y are numpy arrays
    x_array, y_array = np.array(x_array), np.array(y_array) 

    # optional: round to the nearest. True by default
    if round==True:
        target = np.round(target) 

    if which_array == 'x': # look for the target in x_array
        return target, y_array[np.where(x_array == target)[0]]
    if which_array == 'y': # look for the target in y_array
        return x_array[np.where(y_array == target)[0]], target

Results given by your examples:

# >>> what_is_y_when_x_is(2)
pick(x, y, 2, 'x')
(2, array([3]))

# >>> what_is_y_when_x_is(3.1)
pick(x, y, 3.1, 'x')
3.0, array([7]))

# >>> what_is_y_when_x_is(2)
pick(x, y, 2, 'y')
(array([ 0.]), 2)

# >>> what_is_x_when_y_is(max(y))
pick(x, y, max(y), 'y')
(array([ 1. ,  4.5]), 8)
share|improve this answer

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