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:
#Not found
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.

`lat`

,`lon`

and`time`

? In particular, what are their shapes? – larsmans Nov 14 '12 at 13:39`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`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