I have written basic python snippets to first insert values in a list and then reverse them. I found that there was a huge difference of speed of execution between insert and append methods.

Snippet 1:

L = []
for i in range(10**5):

Time taken to execute this :

real    0m0.070s
user    0m0.064s
sys         0m0.008s

Snippet 2:

l = []
for i in range(10**5):

Time taken to execute:

real    0m5.645s
user    0m5.516s
sys         0m0.020s

I expected the snippet 2 to perform much better than snippet1, since I am performing the reverse operation directly by inserting the numbers before. But the time taken says otherwise. I fail to understand why the latter method takes more time to execute, even though the method looks more elegant. Does any one have any explanation for this?


Note that your results will depend on the precise Python implementation. cpython (and pypy) automatically resize your list and overprovision space for future appends and thereby speed up the append furthermore.

Internally, lists are just chunks of memory with a constant size (on the heap). Sometimes you're lucky and can just increase the size of the chunk, but in many cases, an object will already be there. For example, assume you allocated a chunk of size 4 for a list [a,b,c,d], and some other piece of code allocated a chunk of size 6 for a dictionary:

Memory  0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
       |a b c d| | dictionary |

Assume your list has 4 elements, and another one is added. Now, you can simply resize the list to size 5:

Memory  0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
       |a b c d e| dictionary |

However, what do you do if you need another element now?

Well, the only thing you can do is acquire a new space and copy the contents of the list.

Memory 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21
                | dictionary |a  b  c  d  e  f |

Note that if you acquire space in bulk (the aforementioned overprovisioning), you'll only need to resize (and potentially copy) the list every now and then.

In contrast, when you insert at position 0, you always need to copy your list. Let's insert x:

Memory  0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
orig   |a b c d| |dictionary|
after  |x a b c d|dictionary|

Although there was enough space to append x at the end, we had to move (not even copy, which may be less expensive in memory) all the other values.


Here is the complete answer from Duncan Booth:

A list is implemented by an array of pointers to the objects it contains.

Every time you call 'insert(0, indx)', all of the pointers already in the list have to be moved up once position before the new one can be inserted at the beginning.

When you call 'append(indx)' the pointers only have to be copied if there isn't enough space in the currently allocated block for the new element. If there is space then there is no need to copy the existing elements, just put the new element on the end and update the length field. Whenever a new block does have to be allocated that particular append will be no faster than an insert, but some extra space will be allocated just in case you do wish to extend the list further.

If you expected insert to be faster, perhaps you thought that Python used a linked-list implementation. It doesn't do this, because in practice (for most applications) a list based implementation gives better performance.

I actually have nothing else to add.


If you need a datastructure that is as efficient in inserting at the start as it is in appending, then you should consider a deque.


I've learned a trick to insert x into the beginning of a list in "Python Pocket Reference":

l[:0] = [x]

It must be somehow very similar to l.insert(0, x), but when I try to comparing three options: append(x), insert(0, x) and l[:0] = [x], the last option performs a bit faster than the second one.

Here is the test code and the result

import time
def test():
    n = 10**5

    t0 = time.time()
    l = []
    for i in xrange(n): l.append(i)
    t1 = time.time() - t0
    print 'appending: %.5f' % t1

    t0 = time.time()
    l = []
    for i in xrange(n): l.insert(0, i)
    t2 = time.time() - t0
    print 'insert to 0: %.5f' % t2

    t0 = time.time()
    l = []
    for i in xrange(n): l[:0] = [i]
    t3 = time.time() - t0
    print 'set slice: %.5f' % t3

    return t1, t2, t3

if __name__ == '__main__':
    t = [0] * 3
    ntimes = 10

    for _ in xrange(ntimes):
        ti = test()

        for i in xrange(3):
            t[i] += ti[i]

    t = [i/ntimes for i in t]
    print 'average time:', t

average time

[0.011755657196044923, 4.1943151950836182, 3.3254094839096071]

Why it is about 25% faster than the insert(0, x)? I've tried to swap the code block of estimating t1, t2, t3, but the result is the same, so it is not about caching the list.

Here, it states that setting slice takes O(k + n)

  • 4
    If you look at the generated bytecode, the l[:0] = [x] uses primitive operations directly, while l.insert(0, x) generates a function call, that is much slower in python, because they can be aways dinamically overiden. – ReneSac Jan 14 '13 at 19:26
  • On the other hand, the function call is much more readable and explicit about your intent, so you should use that unless you profile your program and find this line of code being a bottleneck. As you saw, apropriate use of the data structure is much more important for performance than being a function call or not. – ReneSac Jan 14 '13 at 19:35

Insert method appropriately implementing in Queue . FIFO operation, inserts at the front of the list. ex :. items.insert(0,item)

Append method appropriately implementing in stack . LIFO operation, inserts at the end of the list. ex :. items.append(item)

When we are using insert data thru INSERT method make sure all indexes are re-sequenced.

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