I have two lists of objects. Each list is already sorted by a property of the object that is of the datetime type. I would like to combine the two lists into one sorted list. Is the best way just to do a sort or is there a smarter way to do this in Python?
22 Answers
is there a smarter way to do this in Python
This hasn't been mentioned, so I'll go ahead  there is a merge stdlib function in the heapq module of python 2.6+. If all you're looking to do is getting things done, this might be a better idea. Of course, if you want to implement your own, the merge of mergesort is the way to go.
>>> list1 = [1, 5, 8, 10, 50]
>>> list2 = [3, 4, 29, 41, 45, 49]
>>> from heapq import merge
>>> list(merge(list1, list2))
[1, 3, 4, 5, 8, 10, 29, 41, 45, 49, 50]
Here's the documentation.

5I've added link to heapq.py.
merge()
is implemented as a pure python function so It is easy to port it to older Python versions.– jfsJan 21, 2009 at 20:36 
2Though right, this solution seems to be one order of magnitude slower than the
sorted(l1+l2)
solution.– sonoSep 2, 2017 at 10:43 
2@Ale: That's not wholly surprising.
list.sort
(whichsorted
is implemented in terms of) uses TimSort, which is optimized to take advantage of existing ordering (or reverse ordering) in the underlying sequence, so even though it's theoreticallyO(n log n)
, in this case, it's much closer toO(n)
to perform the sort. Beyond that, CPython'slist.sort
is implemented in C (avoiding interpreter overhead), whileheapq.merge
is mostly implemented in Python, and optimizes for the "many iterables" case in a way that slows the "two iterables" case. Mar 24, 2018 at 0:43 
8The selling point for
heapq.merge
is that it doesn't require either the inputs or the outputs to belist
; it can consume iterators/generators and produces a generator, so huge inputs/outputs (not stored in RAM at once) can be combined without swap thrashing. It also handles merging an arbitrary number of input iterables with lower overhead than might be expected (it uses a heap to coordinate the merging, so the overhead scales with the log of the number of iterables, not linearly, but as noted, that doesn't matter for the "two iterable" case). Mar 24, 2018 at 0:51
People seem to be over complicating this.. Just combine the two lists, then sort them:
>>> l1 = [1, 3, 4, 7]
>>> l2 = [0, 2, 5, 6, 8, 9]
>>> l1.extend(l2)
>>> sorted(l1)
[0, 1, 2, 3, 4, 5, 6, 7, 8, 9]
..or shorter (and without modifying l1
):
>>> sorted(l1 + l2)
[0, 1, 2, 3, 4, 5, 6, 7, 8, 9]
..easy! Plus, it's using only two builtin functions, so assuming the lists are of a reasonable size, it should be quicker than implementing the sorting/merging in a loop. More importantly, the above is much less code, and very readable.
If your lists are large (over a few hundred thousand, I would guess), it may be quicker to use an alternative/custom sorting method, but there are likely other optimisations to be made first (e.g not storing millions of datetime
objects)
Using the timeit.Timer().repeat()
(which repeats the functions 1000000 times), I loosely benchmarked it against ghoseb's solution, and sorted(l1+l2)
is substantially quicker:
merge_sorted_lists
took..
[9.7439379692077637, 9.8844599723815918, 9.552299976348877]
sorted(l1+l2)
took..
[2.860386848449707, 2.7589840888977051, 2.7682540416717529]

6Finally a sane answer, taking actual benchmarking into account. :)  Also, 1 line to maintain instead of 1520 is much to be preferred.– DeestanJan 21, 2009 at 10:10

29Sorting a very short list created by appending two lists will indeed be very fast, as the constant overheads will dominate. Try doing this for lists with several million items, or files on disk with several billion items, and you'll soon find out why merging is preferable. Jan 21, 2009 at 10:16

6@Barry: If you have "several billion items" and a speed requisite, anything in Python is the wrong answer.– DeestanJan 21, 2009 at 10:24

11@Deestan: I disagree  there are times when speed will be dominated by other factors. Eg. if you're sorting data ondisk (merge 2 files), IO times will likely dominate and python's speed won't matter much, just the number of operations you do (and hence the algorithm).– BrianJan 21, 2009 at 10:41

9
Long story short, unless len(l1 + l2) ~ 1000000
use:
L = l1 + l2
L.sort()
Description of the figure and source code can be found here.
The figure was generated by the following command:
$ python makefigures.py nsublists 2 maxn=0x100000 s merge_funcs.merge_26 s merge_funcs.sort_builtin

You're comparing it against a golfed solution, not one that's actually trying to be efficient. Jun 20, 2018 at 13:47

@OrangeDog I don't understand what you are talking about. The point of the answer is that adding two lists and sorting them may be faster for small input than heapq.merge() from Python 2.6 (despite
merge()
being O(n) in time, O(1) in space and the sorting is O(n log n) in time, and the whole algorithm is O(n) in space here)¶ The comparison has only historical value now.– jfsJun 20, 2018 at 14:30 
this answer has nothing to do with
heapq.merge
, you're comparingsort
against somebody's codegolf submission. Jun 20, 2018 at 14:32 

1you're the one who said "the source code can be found here" and linked to a codegolf answer. Don't blame people for thinking that the code that can be found there is what you tested. Jun 20, 2018 at 14:49
This is simply merging. Treat each list as if it were a stack, and continuously pop the smaller of the two stack heads, adding the item to the result list, until one of the stacks is empty. Then add all remaining items to the resulting list.
res = []
while l1 and l2:
if l1[0] < l2[0]:
res.append(l1.pop(0))
else:
res.append(l2.pop(0))
res += l1
res += l2


4

en.wikipedia.org/wiki/Merge_sort and en.wikipedia.org/wiki/Merge_algorithm Jan 21, 2009 at 21:36

12

2@akaihola: If
len(L1 + L2) < 1000000
thensorted(L1 + L2)
is faster stackoverflow.com/questions/464342/…– jfsNov 13, 2010 at 17:09
There is a slight flaw in ghoseb's solution, making it O(n**2), rather than O(n).
The problem is that this is performing:
item = l1.pop(0)
With linked lists or deques this would be an O(1) operation, so wouldn't affect complexity, but since python lists are implemented as vectors, this copies the rest of the elements of l1 one space left, an O(n) operation. Since this is done each pass through the list, it turns an O(n) algorithm into an O(n**2) one. This can be corrected by using a method that doesn't alter the source lists, but just keeps track of the current position.
I've tried out benchmarking a corrected algorithm vs a simple sorted(l1+l2) as suggested by dbr
def merge(l1,l2):
if not l1: return list(l2)
if not l2: return list(l1)
# l2 will contain last element.
if l1[1] > l2[1]:
l1,l2 = l2,l1
it = iter(l2)
y = it.next()
result = []
for x in l1:
while y < x:
result.append(y)
y = it.next()
result.append(x)
result.append(y)
result.extend(it)
return result
I've tested these with lists generated with
l1 = sorted([random.random() for i in range(NITEMS)])
l2 = sorted([random.random() for i in range(NITEMS)])
For various sizes of list, I get the following timings (repeating 100 times):
# items: 1000 10000 100000 1000000
merge : 0.079 0.798 9.763 109.044
sort : 0.020 0.217 5.948 106.882
So in fact, it looks like dbr is right, just using sorted() is preferable unless you're expecting very large lists, though it does have worse algorithmic complexity. The break even point being at around a million items in each source list (2 million total).
One advantage of the merge approach though is that it is trivial to rewrite as a generator, which will use substantially less memory (no need for an intermediate list).
[Edit]
I've retried this with a situation closer to the question  using a list of objects containing a field "date
" which is a datetime object.
The above algorithm was changed to compare against .date
instead, and the sort method was changed to:
return sorted(l1 + l2, key=operator.attrgetter('date'))
This does change things a bit. The comparison being more expensive means that the number we perform becomes more important, relative to the constanttime speed of the implementation. This means merge makes up lost ground, surpassing the sort() method at 100,000 items instead. Comparing based on an even more complex object (large strings or lists for instance) would likely shift this balance even more.
# items: 1000 10000 100000 1000000[1]
merge : 0.161 2.034 23.370 253.68
sort : 0.111 1.523 25.223 313.20
[1]: Note: I actually only did 10 repeats for 1,000,000 items and scaled up accordingly as it was pretty slow.

Thanks for the fix. Would be great if you can exactly point out the flaw and your fix :) Jan 21, 2009 at 11:24

@ghoseb: I gave a brief description as a comment on your post, but I've now updated the answer to give more details  essentially l.pop() is an O(n) operation for lists. It's fixable by tracking position in some other manner (alternatively by popping from the tail instead, and reversing at the end)– BrianJan 21, 2009 at 11:42

Can you bench mark these same tests but comparing the dates like the question is requiring? I'm guessing this extra method will take up a fair amount of time relatively. Jan 21, 2009 at 11:57

I'd say the difference is due to the fact that sort() is implemented in c/c++ and compiled vs our merge() that is being interpreted. merge() should be faster on equal terms.– DrakoshaJan 21, 2009 at 12:09

Good point Drakosha. Show's that benchmarking is indeed the only way to know for certain. Jan 21, 2009 at 12:13
This is simple merging of two sorted lists. Take a look at the sample code below which merges two sorted lists of integers.
#!/usr/bin/env python
## merge.py  Merge two sorted lists * Python *
## Timestamp: "20090121 14:02:57 ghoseb"
l1 = [1, 3, 4, 7]
l2 = [0, 2, 5, 6, 8, 9]
def merge_sorted_lists(l1, l2):
"""Merge sort two sorted lists
Arguments:
 `l1`: First sorted list
 `l2`: Second sorted list
"""
sorted_list = []
# Copy both the args to make sure the original lists are not
# modified
l1 = l1[:]
l2 = l2[:]
while (l1 and l2):
if (l1[0] <= l2[0]): # Compare both heads
item = l1.pop(0) # Pop from the head
sorted_list.append(item)
else:
item = l2.pop(0)
sorted_list.append(item)
# Add the remaining of the lists
sorted_list.extend(l1 if l1 else l2)
return sorted_list
if __name__ == '__main__':
print merge_sorted_lists(l1, l2)
This should work fine with datetime objects. Hope this helps.

3Unfortunately this is counterproductive  normally merge would be O(n), but because you're popping from the left of each list (an O(n) operation), you're actually making it an O(n**2) process  worse than the naive sorted(l1+l2)– BrianJan 21, 2009 at 9:54

@Brian I actually think that this solution is the cleanest of all and I believe you're right on O(n) complexity of popping the first element from the list. You can eliminate that problem by using deque from collections, which gives you O(1) when popping an item from either side. docs.python.org/2/library/collections.html#collections.deque– mohi666May 8, 2015 at 0:59

@Brian,
head, tail = l[0], l[1:]
also will have O(n**2) complexity? Feb 12, 2016 at 17:14 
2@Brian: As an alternative to
collections.deque
, it could also be solved by creatingl1
andl2
in reverse order (l1 = l1[::1]
,l2 = l2[::1]
), then working from the righthand side rather than the left, replacingif l1[0] <= l2[0]:
withif l1[1] <= l2[1]:
, replacingpop(0)
withpop()
and changingsorted_list.extend(l1 if l1 else l2)
tosorted_list.extend(reversed(l1 if l1 else l2))
Mar 24, 2018 at 0:57
from datetime import datetime
from itertools import chain
from operator import attrgetter
class DT:
def __init__(self, dt):
self.dt = dt
list1 = [DT(datetime(2008, 12, 5, 2)),
DT(datetime(2009, 1, 1, 13)),
DT(datetime(2009, 1, 3, 5))]
list2 = [DT(datetime(2008, 12, 31, 23)),
DT(datetime(2009, 1, 2, 12)),
DT(datetime(2009, 1, 4, 15))]
list3 = sorted(chain(list1, list2), key=attrgetter('dt'))
for item in list3:
print item.dt
The output:
20081205 02:00:00
20081231 23:00:00
20090101 13:00:00
20090102 12:00:00
20090103 05:00:00
20090104 15:00:00
I bet this is faster than any of the fancy purePython merge algorithms, even for large data. Python 2.6's heapq.merge
is a whole another story.
def merge_sort(a,b):
pa = 0
pb = 0
result = []
while pa < len(a) and pb < len(b):
if a[pa] <= b[pb]:
result.append(a[pa])
pa += 1
else:
result.append(b[pb])
pb += 1
remained = a[pa:] + b[pb:]
result.extend(remained)
return result
Python's sort implementation "timsort" is specifically optimized for lists that contain ordered sections. Plus, it's written in C.
http://bugs.python.org/file4451/timsort.txt
http://en.wikipedia.org/wiki/Timsort
As people have mentioned, it may call the comparison function more times by some constant factor (but maybe call it more times in a shorter period in many cases!).
I would never rely on this, however. – Daniel Nadasi
I believe the Python developers are committed to keeping timsort, or at least keeping a sort that's O(n) in this case.
Generalized sorting (i.e. leaving apart radix sorts from limited value domains)
cannot be done in less than O(n log n) on a serial machine. – Barry Kelly
Right, sorting in the general case can't be faster than that. But since O() is an upper bound, timsort being O(n log n) on arbitrary input doesn't contradict its being O(n) given sorted(L1) + sorted(L2).
An implementation of the merging step in Merge Sort that iterates through both lists:
def merge_lists(L1, L2):
"""
L1, L2: sorted lists of numbers, one of them could be empty.
returns a merged and sorted list of L1 and L2.
"""
# When one of them is an empty list, returns the other list
if not L1:
return L2
elif not L2:
return L1
result = []
i = 0
j = 0
for k in range(len(L1) + len(L2)):
if L1[i] <= L2[j]:
result.append(L1[i])
if i < len(L1)  1:
i += 1
else:
result += L2[j:] # When the last element in L1 is reached,
break # append the rest of L2 to result.
else:
result.append(L2[j])
if j < len(L2)  1:
j += 1
else:
result += L1[i:] # When the last element in L2 is reached,
break # append the rest of L1 to result.
return result
L1 = [1, 3, 5]
L2 = [2, 4, 6, 8]
merge_lists(L1, L2) # Should return [1, 2, 3, 4, 5, 6, 8]
merge_lists([], L1) # Should return [1, 3, 5]
I'm still learning about algorithms, please let me know if the code could be improved in any aspect, your feedback is appreciated, thanks!
Use the 'merge' step of merge sort, it runs in O(n) time.
From wikipedia (pseudocode):
function merge(left,right)
var list result
while length(left) > 0 and length(right) > 0
if first(left) ≤ first(right)
append first(left) to result
left = rest(left)
else
append first(right) to result
right = rest(right)
end while
while length(left) > 0
append left to result
while length(right) > 0
append right to result
return result
Recursive implementation is below. Average performance is O(n).
def merge_sorted_lists(A, B, sorted_list = None):
if sorted_list == None:
sorted_list = []
slice_index = 0
for element in A:
if element <= B[0]:
sorted_list.append(element)
slice_index += 1
else:
return merge_sorted_lists(B, A[slice_index:], sorted_list)
return sorted_list + B
or generator with improved space complexity:
def merge_sorted_lists_as_generator(A, B):
slice_index = 0
for element in A:
if element <= B[0]:
slice_index += 1
yield element
else:
for sorted_element in merge_sorted_lists_as_generator(B, A[slice_index:]):
yield sorted_element
return
for element in B:
yield element
This is my solution in linear time without editing l1 and l2:
def merge(l1, l2):
m, m2 = len(l1), len(l2)
newList = []
l, r = 0, 0
while l < m and r < m2:
if l1[l] < l2[r]:
newList.append(l1[l])
l += 1
else:
newList.append(l2[r])
r += 1
return newList + l1[l:] + l2[r:]
I'd go with the following answer.
from math import floor
def merge_sort(l):
if len(l) < 2:
return l
left = merge_sort(l[:floor(len(l)/2)])
right = merge_sort(l[floor(len(l)/2):])
return merge(left, right)
def merge(a, b):
i, j = 0, 0
a_len, b_len = len(a), len(b)
output_length = a_len + b_len
out = list()
for _ in range(output_length):
if i < a_len and j < b_len and a[i] < b[j]:
out.append(a[i])
i = i + 1
elif j < b_len:
out.append(b[j])
j = j + 1
while (i < a_len):
out.append(a[i])
i += 1
while (j < b_len):
out.append(b[j])
j += 1
return out
if __name__ == '__main__':
print(merge_sort([7, 8, 9, 4, 5, 6]))
Well, the naive approach (combine 2 lists into large one and sort) will be O(N*log(N)) complexity. On the other hand, if you implement the merge manually (i do not know about any ready code in python libs for this, but i'm no expert) the complexity will be O(N), which is clearly faster. The idea is described wery well in post by Barry Kelly.

As a point of interest, the python sorting algorithm is very good, so the performance would likely be better than O(n log n), since the algorithm often takes advantage of regularities in the input data. I would never rely on this, however. Jan 21, 2009 at 7:45

Generalized sorting (i.e. leaving apart radix sorts from limited value domains) cannot be done in less than O(n log n) on a serial machine. Jan 21, 2009 at 10:17
If you want to do it in a manner more consistent with learning what goes on in the iteration try this
def merge_arrays(a, b):
l= []
while len(a) > 0 and len(b)>0:
if a[0] < b[0]: l.append(a.pop(0))
else:l.append(b.pop(0))
l.extend(a+b)
print( l )
import random
n=int(input("Enter size of table 1")); #size of list 1
m=int(input("Enter size of table 2")); # size of list 2
tb1=[random.randrange(1,101,1) for _ in range(n)] # filling the list with random
tb2=[random.randrange(1,101,1) for _ in range(m)] # numbers between 1 and 100
tb1.sort(); #sort the list 1
tb2.sort(); # sort the list 2
fus=[]; # creat an empty list
print(tb1); # print the list 1
print('');
print(tb2); # print the list 2
print('');
i=0;j=0; # varialbles to cross the list
while(i<n and j<m):
if(tb1[i]<tb2[j]):
fus.append(tb1[i]);
i+=1;
else:
fus.append(tb2[j]);
j+=1;
if(i<n):
fus+=tb1[i:n];
if(j<m):
fus+=tb2[j:m];
print(fus);
# this code is used to merge two sorted lists in one sorted list (FUS) without
#sorting the (FUS)

1It's not clear whether this is an answer to the question, let alone whether it actually does? Can you provide some sort of explanation?– BenAug 30, 2014 at 12:00


1You'll note that the higher voted answers (and most of the others) have some text that explain what's happening in the answer and why that answer is an answer to the question..– BenAug 30, 2014 at 12:11

because it merge two list in one sorted list and this is the answer of the question Aug 30, 2014 at 12:19
Have used merge step of the merge sort. But I have used generators. Time complexity O(n)
def merge(lst1,lst2):
len1=len(lst1)
len2=len(lst2)
i,j=0,0
while(i<len1 and j<len2):
if(lst1[i]<lst2[j]):
yield lst1[i]
i+=1
else:
yield lst2[j]
j+=1
if(i==len1):
while(j<len2):
yield lst2[j]
j+=1
elif(j==len2):
while(i<len1):
yield lst1[i]
i+=1
l1=[1,3,5,7]
l2=[2,4,6,8,9]
mergelst=(val for val in merge(l1,l2))
print(*mergelst)
This code has time complexity O(n) and can merge lists of any data type, given a quantifying function as the parameter func
. It produces a new merged list and does not modify either of the lists passed as arguments.
def merge_sorted_lists(listA,listB,func):
merged = list()
iA = 0
iB = 0
while True:
hasA = iA < len(listA)
hasB = iB < len(listB)
if not hasA and not hasB:
break
valA = None if not hasA else listA[iA]
valB = None if not hasB else listB[iB]
a = None if not hasA else func(valA)
b = None if not hasB else func(valB)
if (not hasB or a<b) and hasA:
merged.append(valA)
iA += 1
elif hasB:
merged.append(valB)
iB += 1
return merged
in O(m+n)
complexity
def merge_sorted_list(nums1: list, nums2:list) > list:
m = len(nums1)
n = len(nums2)
nums1 = nums1.copy()
nums2 = nums2.copy()
nums1.extend([0 for i in range(n)])
while m > 0 and n > 0:
if nums1[m1] >= nums2[n1]:
nums1[m+n1] = nums1[m1]
m = 1
else:
nums1[m+n1] = nums2[n1]
n = 1
if n > 0:
nums1[:n] = nums2[:n]
return nums1
l1 = [1, 3, 4, 7]
l2 = [0, 2, 5, 6, 8, 9]
print(merge_sorted_list(l1, l2))
output
[0, 1, 2, 3, 4, 5, 6, 7, 8, 9]
def compareDate(obj1, obj2):
if obj1.getDate() < obj2.getDate():
return 1
elif obj1.getDate() > obj2.getDate():
return 1
else:
return 0
list = list1 + list2
list.sort(compareDate)
Will sort the list in place. Define your own function for comparing two objects, and pass that function into the built in sort function.
Do NOT use bubble sort, it has horrible performance.

Merge sort will definately be faster, but a little more complicated if you have to implement it yourself. I think python uses quicksort. Jan 21, 2009 at 7:46
Hope this helps. Pretty Simple and straight forward:
l1 = [1, 3, 4, 7]
l2 = [0, 2, 5, 6, 8, 9]
l3 = l1 + l2
l3.sort()
print (l3)
[0, 1, 2, 3, 4, 5, 6, 7, 8, 9]

1OP didn't ask how to add and sort lists, was asking if there was a better or more "Python" way of doing it within their context. Jun 27, 2018 at 2:22