# How to vectorize a simple for loop in Python/Numpy

I found dozens of examples how to vectorize for loops in Python/NumPy. Unfortunately, I don't get how I can reduce the computation time of my simple for loop using a vectorized form. Is it even possible in this case?

``````time = np.zeros(185000)
lat1 = np.array(([48.78,47.45],[38.56,39.53],...)) # ~ 200000 rows
lat2 = np.array(([7.78,5.45],[7.56,5.53],...)) # same number of rows as time
for ii in np.arange(len(time)):
pos = np.argwhere( (lat1[:,0]==lat2[ii,0]) and \
(lat1[:,1]==lat2[ii,1]) )
if pos.size:
pos = int(pos)
time[ii] = dtime[pos]
``````
-
What are `lat`, `lon` and `time`? In particular, what are their shapes? – larsmans Nov 14 '12 at 13:39
I updated sample values above. – HyperCube Nov 14 '12 at 14:05
Could you explain what's the meaning of `pos = np.argwhere( (lat1[:,0]==lat2[ii,0]) and (lat1[:,1]==lat2[ii,1]) )` ? So, you want to find such a row in lat2 which is equal to lat1? Aren't you afraid of float-rounding errors? If so, you could use binary search on lat2 (search in its sorted copy) – alex_jordan Nov 14 '12 at 14:46
I am looking for rows where lat1 and lat2 are equal in both columns. I need the rownumber of lat1 and lat2 where this is the case. At the moment "ii" and "pos" give me that and it works. I used np.around(XX,decimals=2) on both arrays to avoid rounding errors. – HyperCube Nov 14 '12 at 14:57
So, if `lat1 = [[1,2], [3,4], [5,6], [7,8]]` and `lat2 = [[3,4], [5,6], [7,8], [1,2]]` so the result of the algorithm should be `[1, 2, 3, 0]` (0-st element of lat2 is on 1-st position on lat1, 1 element of lat2 is on 2, 2 on 3, 3 on 0) Is this what you want? – alex_jordan Nov 14 '12 at 15:33

Probably the fastest way to find all matches is to sort both arrays and walk through them together, like this working example:

``````import numpy as np

def is_less(a, b):
# this ugliness is needed because we want to compare lexicographically same as np.lexsort(), from the last column backward
for i in range(len(a)-1, -1, -1):
if a[i]<b[i]: return True
elif a[i]>b[i]: return False
return False

def is_equal(a, b):
for i in range(len(a)):
if a[i] != b[i]: return False
return True

# lat1 = np.array(([48.78,47.45],[38.56,39.53]))
# lat2 = np.array(([7.78,5.45],[48.78,47.45],[7.56,5.53]))

idx1 = np.lexsort( lat1.transpose() )
idx2 = np.lexsort( lat2.transpose() )
ii = 0
jj = 0
while ii < len(idx1) and jj < len(idx2):
a = lat1[ idx1[ii] , : ]
b = lat2[ idx2[jj] , : ]
if is_equal( a, b ):
# do stuff with match
print "match found: lat1=%s lat2=%s %d and %d" % ( repr(a), repr(b), idx1[ii], idx2[jj] )
ii += 1
jj += 1
elif is_less( a, b ):
ii += 1
else:
jj += 1
``````

This may not be perfectly pythonic (perhaps someone can think of a nicer implementation using generators or itertools?) but it is hard to imagine any method that relies on searching one point at a time beating this in speed.

-
Unfortunately, this does not work for my data: dropbox.com/s/xs35kvoexi85bk0/arr.npy and dropbox.com/s/g4bdk509bvwzn3u/refarr.npy. arr should be lat1 and refarr lat2 in your code. – HyperCube Nov 16 '12 at 10:32
@HyperCube, please try the latest code above. Works here, 0.4 sec on your sample data (including the np.load()s). I had forgotten the (obvious) index dereferences lat1[ idx1[ii], ... ] and so forth; it just happened to work with the data I used. – Alex I Nov 16 '12 at 12:42
Works great! It takes 5.2 seconds on my machine for the complete data set compared to 10.3 seconds of the solution from alex_jordan – HyperCube Nov 16 '12 at 13:56
Awesome! O(N) instead of my O(N*log(N)). How haven't I thought of it. – alex_jordan Nov 16 '12 at 14:05

Here is a solution. I'm not really sure that it's possible to vectorize it. If you want to make it resistant to "float comparing error" you should modify `is_less` and `is_greater`. The whole algo is just a binary search.

``````import numpy as np

#lexicographicaly compare two points - a and b

def is_less(a, b):
i = 0
while i<len(a):
if a[i]<b[i]:
return True
else:
if a[i]>b[i]:
return False
i+=1
return False

def is_greater(a, b):
i = 0
while i<len(a):
if a[i]>b[i]:
return True
else:
if a[i]<b[i]:
return False
i+=1
return False

def binary_search(a, x, lo=0, hi=None):
if hi is None:
hi = len(a)
while lo < hi:
mid = (lo+hi)//2
midval = a[mid]
if is_less(midval, x):
lo = mid+1
elif is_greater(midval, x):
hi = mid
else:
return mid
return -1

def lex_sort(v): #sort by 1 and 2 column respectively
#return v[np.lexsort((v[:,2],v[:,1]))]
order = range(1, v.shape[1])
return v[np.lexsort(tuple(v[:,i] for i in order[::-1]))]

def sort_and_index(arr):
ind = np.indices((len(arr),)).reshape((len(arr), 1))
arr = np.hstack([ind, arr]) # add an index column as first column
arr = lex_sort(arr)
arr_cut = arr[:,1:] # an array to do binary search in
arr_ind = arr[:,:1] # shuffled indices
return arr_ind, arr_cut

#lat1 = np.array(([1,2,3], [3,4,5], [5,6,7], [7,8,9])) # ~ 200000 rows
lat1 = np.arange(1,800001,1).reshape((200000,4))
#lat2 = np.array(([3,4,5], [5,6,7], [7,8,9], [1,2,3])) # same number of rows as time
lat2 = np.arange(101,800101,1).reshape((200000,4))

lat1_ind, lat1_cut = sort_and_index(lat1)

time_arr = np.zeros(200000)
import time
start = time.time()

for ii, elem in enumerate(lat2):
pos = binary_search(lat1_cut, elem)
if pos == -1:
continue
pos = lat1_ind[pos][0]
#print "element in lat2 with index",ii,"has position",pos,"in lat1"
print time.time()-start
``````

The commented print is the place where you have corresponding indices of lat1 and lat2. Works for 7 seconds on 200000 rows.

-
Indeed, this is incredibly fast! However, I get strange results..I am checking right now why. What do I need to change if I lat1 and lat2 have 4 columns I want to compare with? Is it possible to just use them directly? – HyperCube Nov 15 '12 at 9:53
Furthermore, I simply don't get what is happening in the binary search and why this is so much faster than the simple loop in my starting post.. Do you have some literature on it for me? – HyperCube Nov 15 '12 at 9:57
Well, imagine that you have a sorted array `[1, 2, 6, 17, 25, 29, 37]` and you want to find the index of `25` element. One approach would be to iterate through the whole array and compare each element with the sought one. But our array is sorted so by looking at element at any index we can tell whether the sought element is to the right or to the left from this element. For example let us start from the centre of our array: current element is `17`, index is `3` (counting from 0). We are seeking for `25`, `25>17` so there is no sense in seeking our element in the left part (indices [0,3]). – alex_jordan Nov 15 '12 at 16:31
Thus we can instead of iterating through the whole array do the following smart procedure: 1) Select centre of input array 2) Compare current element with the sought one. 3) If equals then we've found otherwise there are two cases: sought is smaller and sought is bigger. If smaller, set input array = left half of input array and go to 1). If bigger, the same but the right half. This algorithm allows us to find the index in O(log2(N)) instead of O(N) time. Compare: N = 200000 log2(N) = 17.609640474436812. That roughly means that with binary search you will find element in maximum 17 operations. – alex_jordan Nov 15 '12 at 16:38
instead of 200000 operations with naive search algorithm. Here is a good explanation community.topcoder.com/… – alex_jordan Nov 15 '12 at 16:39