numpy arrays: filling and extracting data quickly

See important clarification at bottom of this question.

I am using numpy to speed up some processing of longitude/latitude coordinates. Unfortunately, my numpy "optimizations" made my code run about 5x more slowly than it ran without using numpy.

The bottleneck seems to be in filling the numpy array with my data, and then extracting out that data after I have done the mathematical transformations. To fill the array I basically have a loop like:

``````point_list = GetMyPoints() # returns a long list of ( lon, lat ) coordinate pairs
n = len( point_list )
point_buffer = numpy.empty( ( n, 2 ), numpy.float32 )

for point_index in xrange( 0, n ):
point_buffer[ point_index ] = point_list[ point_index ]
``````

That loop, just filling in the numpy array before even operating on it, is extremely slow, much slower than the entire computation was without numpy. (That is, it's not just the slowness of the python loop itself, but apparently some huge overhead in actually transferring each small block of data from python to numpy.) There is similar slowness on the other end; after I have processed the numpy arrays, I access each modified coordinate pair in a loop, again as

``````some_python_tuple = point_buffer[ index ]
``````

Again that loop to pull the data out is much slower than the entire original computation without numpy. So, how do I actually fill the numpy array and extract data from the numpy array in a way that doesn't defeat the purpose of using numpy in the first place?

I am reading the data from a shape file using a C library that hands me the data as a regular python list. I understand that if the library handed me the coordinates already in a numpy array there would be no "filling" of the numpy array necessary. But unfortunately the starting point for me with the data is as a regular python list. And more to the point, in general I want to understand how you quickly fill a numpy array with data from within python.

Clarification

The loop shown above is actually oversimplified. I wrote it that way in this question because I wanted to focus on the problem I was seeing of trying to fill a numpy array slowly in a loop. I now understand that doing that is just slow.

In my actual application what I have is a shape file of coordinate points, and I have an API to retrieve the points for a given object. There are something like 200,000 objects. So I repeatedly call a function `GetShapeCoords( i )` to get the coords for object i. This returns a list of lists, where each sublist is a list of lon/lat pairs, and the reason it's a list of lists is that some of the objects are multi-part (i.e., multi-polygon). Then, in my original code, as I read in each object's points, I was doing a transformation on each point by calling a regular python function, and then plotting the transformed points using PIL. The whole thing took about 20 seconds to draw all 200,000 polygons. Not terrible, but much room for improvement. I noticed that at least half of those 20 seconds were spent doing the transformation logic, so I thought I'd do that in numpy. And my original implementation was just to read in the objects one at a time, and keep appending all the points from the sublists into one big numpy array, which I then could do the math stuff on in numpy.

So, I now understand that simply passing a whole python list to numpy is the right way to set up a big array. But in my case I only read one object at a time. So one thing I could do is keep appending points together in a big python list of lists of lists. And then when I've compiled some large number of objects' points in this way (say, 10000 objects), I could simply assign that monster list to numpy.

So my question now is three parts:

(a) Is it true that numpy can take that big, irregularly shaped, list of lists of lists, and slurp it okay and quickly?

(b) I then want to be able to transform all the points in the leaves of that monster tree. What is the expression to get numpy to, for instance, "go into each sublist, and then into each subsublist, and then for each coordinate pair you find in those subsublists multiply the first (lon coordinate) by 0.5"? Can I do that?

(c) Finally, I need to get those transformed coordinates back out in order to plot them.

Winston's answer below seems to give some hint at how I might do this all using itertools. What I want to do is pretty much like what Winston does, flattening the list out. But I can't quite just flatten it out. When I go to draw the data, I need to be able to know when one polygon stops and the next starts. So, I think I could make it work if there were a way to quickly mark the end of each polygon (i.e., each subsublist) with a special coordinate pair like (-1000, -1000) or something like that. Then I could flatten with itertools as in Winston's answer, and then do the transforms in numpy. Then I need to actually draw from point to point using PIL, and here I think I'd need to reassign the modified numpy array back to a python list, and then iterate through that list in a regular python loop to do the drawing. Does that seem like my best option short of just writing a C module to handle all the reading and drawing for me in one step?

-
what is `point_buffer_index` exactly? –  joris Apr 5 '11 at 23:48
sorry, point_buffer_index was a typo; it's been changed to point_index –  M Katz Apr 5 '11 at 23:53
Can you give an example of how `point_list` looks like? Because now it seems you just put each element of `point_list` in the corresponding point in `point_buffer`. And then you could just use `point_buffer = np.array(point_list)` –  joris Apr 6 '11 at 0:01
please, when you ask a performance question, don't simplify the performance problem part away. –  Winston Ewert Apr 6 '11 at 1:11
Winston, thanks, you are right. See my follow-up to your answer below. –  M Katz Apr 6 '11 at 2:47

You describe your data as being "lists of lists of lists of coordinates". From this I'm guessing your extraction looks like this:

``````for x in points:
for y in x:
for Z in y:
# z is a tuple with GPS coordinates
``````

Do this:

``````# initially, points is a list of lists of lists
points = itertools.chain.from_iterable(points)
# now points is an iterable producing lists
points = itertools.chain.from_iterable(points)
# now points is an iterable producing coordinates
points = itertools.chain.from_iterable(points)
# now points is an iterable producing individual floating points values
data = numpy.fromiter(points, float)
# data is a numpy array containing all the coordinates
data = data.reshape( data.size/2,2)
# data has now been reshaped to be an nx2 array
``````

itertools and numpy.fromiter are both implemented in c and really efficient. As a result, this should do the transformation very quickly.

The second part of your question doesn't really indicate what you want do with the data. Indexing numpy array is slower then indexing python lists. You get speed by performing operations in mass on the data. Without knowing more about what you are doing with that data, its hard to suggest how to fix it.

UPDATE:

I've gone ahead and done everything using itertools and numpy. I am not responsible from any brain damage resulting from attempting to understand this code.

``````# firstly, we use imap to call GetMyPoints a bunch of times
objects = itertools.imap(GetMyPoints, xrange(100))
# next, we use itertools.chain to flatten it into all of the polygons
polygons = itertools.chain.from_iterable(objects)
# tee gives us two iterators over the polygons
polygons_a, polygons_b = itertools.tee(polygons)
# the lengths will be the length of each polygon
polygon_lengths = itertools.imap(len, polygons_a)
# for the actual points, we'll flatten the polygons into points
points = itertools.chain.from_iterable(polygons_b)
# then we'll flatten the points into values
values = itertools.chain.from_iterable(points)

# package all of that into a numpy array
all_points = numpy.fromiter(values, float)
# reshape the numpy array so we have two values for each coordinate
all_points = all_points.reshape(all_points.size // 2, 2)

# produce an iterator of lengths, but put a zero in front
polygon_positions = itertools.chain([0], polygon_lengths)
# produce another numpy array from this
# however, we take the cumulative sum
# so that each index will be the starting index of a polygon
polygon_positions = numpy.cumsum( numpy.fromiter(polygon_positions, int) )

# now for the transformation
# multiply the first coordinate of every point by *.5
all_points[:,0] *= .5

# now to get it out

# polygon_positions is all of the starting positions
# polygon_postions[1:] is the same, but shifted on forward,
# thus it gives us the end of each slice
# slice makes these all slice objects
slices = itertools.starmap(slice, itertools.izip(polygon_positions, polygon_positions[1:]))
# polygons produces an iterator which uses the slices to fetch
# each polygon
polygons = itertools.imap(all_points.__getitem__, slices)

# just iterate over the polygon normally
# each one will be a slice of the numpy array
for polygon in polygons:
draw_polygon(polygon)
``````

You might find it best to deal with a single polygon at a time. Convert each polygon into a numpy array and do the vector operations on that. You'll probably get a significant speed advantage just doing that. Putting all of your data into numpy might be a little difficult.

This is more difficult then most numpy stuff because of your oddly shaped data. Numpy pretty much assumes a world of uniformly shaped data.

-
Winston, thanks for this answer. I did not know about itertools. Please see the clarification to my OP based on your feedback. –  M Katz Apr 6 '11 at 3:08
@M Katz, updated. –  Winston Ewert Apr 6 '11 at 3:58
Winston, I greatly appreciate you writing all of that out. I see that my life's purpose is now learning itertools (do they offer a PhD in itertools at Princeton?). I will try your code, but I am also going to try writing a simple C extension to simply do the reading, math, and drawing all in one place. –  M Katz Apr 6 '11 at 5:28
@M Katz, your presented a challenge. I had to see if I could do it. –  Winston Ewert Apr 6 '11 at 12:21

The point of using numpy arrays is to avoid as much as possible for loops. Writing for loops yourself will result in slow code, but with numpy arrays you can use predefined vectorized functions which are much faster (and easier!).

So for the conversion of a list to an array you can use:

``````point_buffer = np.array(point_list)
``````

If the list contains elements like `(lat, lon)`, then this will be converted to an array with two columns.

With that numpy array you can easily manipulate all elements at once. For example, to multiply the first element of each coordinate pair by 0.5 as in your question, you can do simply (assuming that the first elements are eg in the first column):

``````point_buffer[:,0] * 0.5
``````
-
Joris, thanks. Please see my comment to Winston and my elaborated problem description. –  M Katz Apr 6 '11 at 3:14

This will be faster:

``````numpy.array(point_buffer, dtype=numpy.float32)
``````

Modifiy the array, not the list. It would obviously be better to avoid creating the list in the first place if possible.

Edit 1: profiling

Here is some test code that demonstrates just how efficiently numpy converts lists to arrays (it's good). And that my list-to-buffer idea is only comparable to what numpy does, not better.

``````import timeit

setup = '''
import numpy
import itertools
import struct
big_list = numpy.random.random((10000,2)).tolist()'''

old_way = '''
a = numpy.empty(( len(big_list), 2), numpy.float32)
for i,e in enumerate(big_list):
a[i] = e
'''

normal_way = '''
a = numpy.array(big_list, dtype=numpy.float32)
'''

iter_way = '''
chain = itertools.chain.from_iterable(big_list)
a = numpy.fromiter(chain, dtype=numpy.float32)
'''

my_way = '''
chain = itertools.chain.from_iterable(big_list)
buffer = struct.pack('f'*len(big_list)*2,*chain)
a = numpy.frombuffer(buffer, numpy.float32)
'''

for way in [old_way, normal_way, iter_way, my_way]:
print timeit.Timer(way, setup).timeit(1)
``````

results:

``````0.22445492374
0.00450378469941
0.00523579114088
0.00451488946237
``````

Edit 2: Regarding the hierarchical nature of the data

If i understand that the data is always a list of lists of lists (object - polygon - coordinate), then this is the approach I'd take: Reduce the data to the lowest dimension that creates a square array (2D in this case) and track the indices of the higher-level branches with a separate array. This is essentially an implementation of Winston's idea of using numpy.fromiter of a itertools chain object. The only added idea is the branch indexing.

``````import numpy, itertools

# heirarchical list of lists of coord pairs
polys = [numpy.random.random((n,2)).tolist() for n in [5,7,12,6]]

# get the indices of the polygons:
lengs = numpy.array([0]+[len(l) for l in polys])

# convert the flattend list to an array:
chain = itertools.chain.from_iterable
a = numpy.fromiter(chain(chain(polys)), dtype=numpy.float32).reshape(lengs.sum(), 2)

# transform the coords
a *= .5

# get a transformed polygon (using the indices)
def get_poly(n):
i0 = p_idxs[n]
i1 = p_idxs[n+1]
return a[i0:i1]

print 'poly2', get_poly(2)
print 'poly0', get_poly(0)
``````
-
GetMyPoints() is just some function. In fact for me it's a compiled module, but as I say in the question it gives me a regular nested python list structure, and I'm trying to understand how to proceed given that I have to start with that regular nested python list. –  M Katz Apr 6 '11 at 0:07
Can you give an example of the returned list? Is it a list of lists, or a list of tuples? It comes in lat, lon pairs? `[[45.,144.],[50.,145.]]`? –  Paul Apr 6 '11 at 0:12
@Paul: I recommend using `timeit` rather than the time module to profile code snippets –  JoshAdel Apr 6 '11 at 1:17
@JoshAdel I was expecting this comment. Can you tell me why it might be inadequate in this case? I find timeit can be annoying sometimes when you want to inspect various elements of code in-situ or when you want your setup to create a random data common to all snippets. –  Paul Apr 6 '11 at 2:04
@Paul: The main arguments as I understand them are that it standardizes timings across platforms and provides a mechanism for running the timing multiple times to get more reliable performance measures. Your method isn't necessarily inadequate, and certainly in some cases (such as you mention) it might be preferable. For in situ cases, I tend to use a full profiler though. Just my two cents –  JoshAdel Apr 6 '11 at 2:24