# Finding and replacing elements in a list

I have to search through a list and replace all occurrences of one element with another. So far my attempts in code are getting me nowhere, what is the best way to do this?

For example, suppose my list has the following integers

``````a = [1, 2, 3, 4, 5, 1, 2, 3, 4, 5, 1]
``````

and I need to replace all occurrences of the number 1 with the value 10 so the output I need is

``````a = [10, 2, 3, 4, 5, 10, 2, 3, 4, 5, 10]
``````

Thus my goal is to replace all instances of the number 1 with the number 10.

Try using a list comprehension and a conditional expression.

``````>>> a=[1,2,3,1,3,2,1,1]
>>> [4 if x==1 else x for x in a]
[4, 2, 3, 4, 3, 2, 4, 4]
``````
• But this doesn't change `a` though right? I think OP wanted `a` to change
– Dula
Feb 3, 2016 at 23:26
• @Dula you can do a = [4 if x==1 else x for x in a], this will effect a Apr 11, 2016 at 7:57
• @Dula: the question is vague as to whether `a` should mutate, but (as Alekhya shows) it's trivial to handle either case when using a list comprehension. Aug 15, 2016 at 11:55
• If you want to mutate `a` then you should do `a[:] = [4 if x==1 else x for x in a]` (note the full list slice). Just doing the `a =` will create a new list `a` with a different `id()` (identity) from the original one Apr 25, 2017 at 12:15
• Just for evaluation purposes, note that this solution is by far the most consistent on time among the fast solutions (it doesn't matter if the item to replace is common or rare, runtime stays effectively constant). When the `list` is mostly items that stay unchanged, this is slower than optimized in-place solutions like kxr's answer. kxr's answer, for len 1000 inputs, takes anywhere from ⅓ the time of this solution (when there are no items that need to be replaced) to 3x as long (when all items must be replaced); much more variable. Feb 25, 2021 at 15:55

You can use the built-in `enumerate` to get both index and value while iterating the list. Then, use the value to test for a condition and the index to replace that value in the original list:

``````>>> a = [1, 2, 3, 4, 5, 1, 2, 3, 4, 5, 1]
>>> for i, n in enumerate(a):
...   if n == 1:
...      a[i] = 10
...
>>> a
[10, 2, 3, 4, 5, 10, 2, 3, 4, 5, 10]
``````
• This is a bad and very un-pythonic solution. Consider using list comprehension. Dec 31, 2016 at 11:56
• This is a fine if very un-pythonic solution. Consider using list comprehension. Feb 2, 2017 at 13:35
• This performs better than list comprehension though doesn't it? It does in-place updates instead of generating a new list. May 13, 2019 at 18:59
• @neverendingqs: No. Interpreter overhead dominates the operation, and the comprehension has less of it. The comprehension performs slightly better, especially with a higher proportion of elements passing the replacement condition. Have some timings: ideone.com/ZrCy6z Mar 31, 2020 at 23:26
• This is really slow in comparison to using native list methods like `.index(10)`. There is no reason to list every list element to find a the elements that need to be replaced. Please see timing in my answer here.
– dawg
May 10, 2020 at 19:09

If you have several values to replace, you can also use a dictionary:

``````a = [1, 2, 3, 4, 1, 5, 3, 2, 6, 1, 1]
replacements = {1:10, 2:20, 3:'foo'}
replacer = replacements.get  # For faster gets.

print([replacer(n, n) for n in a])

> [10, 20, 'foo', 4, 10, 5, 'foo', 20, 6, 10, 10]
``````

Note that this approach works only if the elements to be replaced are hashable. This is because dict keys are required to be hashable.

• @jrjc @roipoussiere for in-place replacements, the `try-except` is at least 50% faster! Take a look at this answer Nov 23, 2016 at 3:25
• Thanks! `try-except` is faster but it break the loop at the first occurrence of unknown item, and `dic.get(n,n)` is beautiful but slower than `if n in dic`. I edited my answer. Jan 2, 2017 at 14:26
• This will fail for unhashable elements. It is a problem of all naive dict based substitutions. (just try with `[1, {'boom!'}, 3]`)
– VPfB
Jul 9, 2019 at 9:29
• @Iftah: If you're super-concerned about performance, pre-binding the `get` method outside the listcomp will dramatically reduce runtime for large inputs. Since you don't actually need a reference to the `dict` itself, you could just change it to `dget = {1:10, 2:20, 3:'foo'}.get`, and the listcomp to `[dget(n, n) for n in a]`. Even in CPython 3.9, which significantly optimized method calls (it no longer needs to create a bound method object in simple cases), this still reduces overhead for a len 1000 input by ~30% (by replacing `LOAD_METHOD`/`CALL_METHOD` with just `CALL_FUNCTION`). Feb 25, 2021 at 16:07
• The pre-bound `get` optimization brings this to the point of being comparable with the `dic[n] if n in dic else n` approach (takes 20-30% longer in most of my test cases, vs. 60-100% longer when you have to look up `dic.get` on every loop). Feb 25, 2021 at 16:12

List comprehension works well, and looping through with enumerate can save you some memory (b/c the operation's essentially being done in place).

There's also functional programming. See usage of map:

``````>>> a = [1,2,3,2,3,4,3,5,6,6,5,4,5,4,3,4,3,2,1]
>>> map(lambda x: x if x != 4 else 'sss', a)
[1, 2, 3, 2, 3, 'sss', 3, 5, 6, 6, 5, 'sss', 5, 'sss', 3, 'sss', 3, 2, 1]
``````
• +1. It's too bad `lambda` and `map` are considered unpythonic. Apr 7, 2010 at 0:02
• I'm not sure that lambda or map is inherently unpythonic, but I'd agree that a list comprehension is cleaner and more readable than using the two of them in conjunction. Apr 7, 2010 at 2:14
• I don't consider them unpythonic myself, but many do, including Guido van Rossum (artima.com/weblogs/viewpost.jsp?thread=98196). It's one of those sectarian things. Apr 8, 2010 at 1:29
• @outis: `map`+`lambda` is less readable and slower than the equivalent listcomp. You can squeeze some performance out of `map` when the mapping function is a built-in implemented in C and the input is large enough for `map`'s per-item benefits to overcome the slightly higher fixed overhead, but when `map` needs a Python level function (e.g. a `lambda`) an equivalent genexpr/listcomp could inline (avoiding function call overhead), `map` really provides no benefit at all (as of 3.9, for a simple test case over `a = [*range(10)] * 100`, this `map` takes 2x as long as the equivalent listcomp). Feb 25, 2021 at 16:19
• Personally, I reserve my ire largely for `lambda`; I like `map` when I already have a function that does what I need laying around (the function is probably complicated enough to not be worth inlining in the listcomp anyway, or it's a built-in you can't inline anyway, e.g. `for line in map(str.rstrip, fileob):` to get the lines from a file one-by-one prestripped), but if I don't have such a function, I'd have to use a `lambda`, which ends up uglier and slower, as previously noted, so I may as well use the listcomp/genexpr. Feb 25, 2021 at 16:21

On long lists and rare occurrences its about 3x faster using `list.index()` - compared to single step iteration methods presented in the other answers.

``````def list_replace(lst, old=1, new=10):
"""replace list elements (inplace)"""
i = -1
try:
while True:
i = lst.index(old, i + 1)
lst[i] = new
except ValueError:
pass
``````
• This is the fastest method I have found. Please see timings in my answer. Great!
– dawg
May 10, 2020 at 19:05
• Note that the naïve version of this (without using `i` to provide a `start` argument for `list.index`) is `O(n²)`; in a simple local test, where the `lst` argument is the result of `list(range(10)) * 100` (1000 element `list`, where 100 elements, evenly spaced, get replaced), this is a noticeable; this answer (which is not naïve, and achieves `O(1)` performance) does the work in about 25 µs, where the naïve version took about 615 µs on the same machine. Feb 25, 2021 at 15:38
``````>>> a=[1,2,3,4,5,1,2,3,4,5,1]
>>> item_to_replace = 1
>>> replacement_value = 6
>>> indices_to_replace = [i for i,x in enumerate(a) if x==item_to_replace]
>>> indices_to_replace
[0, 5, 10]
>>> for i in indices_to_replace:
...     a[i] = replacement_value
...
>>> a
[6, 2, 3, 4, 5, 6, 2, 3, 4, 5, 6]
>>>
``````
• Medium fast but very sensible method. Please see timings in my answer.
– dawg
May 10, 2020 at 19:06

I know this is a very old question and there's a myriad of ways to do it. The simpler one I found is using `numpy` package.

``````import numpy

arr = numpy.asarray([1, 6, 1, 9, 8])
arr[ arr == 8 ] = 0 # change all occurrences of 8 by 0
print(arr)
``````
• Assuming you're already using `numpy`, this is a great solution; it's the same `O(n)` as all the other good solutions, but pushing all the work to vectorized C layer operations means it will outperform the other solutions dramatically by virtue of eliminating per-item interpreter overhead. Feb 25, 2021 at 16:44

My usecase was replacing `None` with some default value.

I've timed approaches to this problem that were presented here, including the one by @kxr - using `str.count`.

Test code in ipython with Python 3.8.1:

``````def rep1(lst, replacer = 0):
''' List comprehension, new list '''

return [item if item is not None else replacer for item in lst]

def rep2(lst, replacer = 0):
''' List comprehension, in-place '''
lst[:] =  [item if item is not None else replacer for item in lst]

return lst

def rep3(lst, replacer = 0):
''' enumerate() with comparison - in-place '''
for idx, item in enumerate(lst):
if item is None:
lst[idx] = replacer

return lst

def rep4(lst, replacer = 0):
''' Using str.index + Exception, in-place '''

idx = -1
# none_amount = lst.count(None)
while True:
try:
idx = lst.index(None, idx+1)
except ValueError:
break
else:
lst[idx] = replacer

return lst

def rep5(lst, replacer = 0):
''' Using str.index + str.count, in-place '''

idx = -1
for _ in range(lst.count(None)):
idx = lst.index(None, idx+1)
lst[idx] = replacer

return lst

def rep6(lst, replacer = 0):
''' Using map, return map iterator '''

return map(lambda item: item if item is not None else replacer, lst)

def rep7(lst, replacer = 0):
''' Using map, return new list '''

return list(map(lambda item: item if item is not None else replacer, lst))

lst = [5]*10**6
# lst = [None]*10**6

%timeit rep1(lst)
%timeit rep2(lst)
%timeit rep3(lst)
%timeit rep4(lst)
%timeit rep5(lst)
%timeit rep6(lst)
%timeit rep7(lst)
``````

I get:

``````26.3 ms ± 163 µs per loop (mean ± std. dev. of 7 runs, 10 loops each)
29.3 ms ± 206 µs per loop (mean ± std. dev. of 7 runs, 10 loops each)
33.8 ms ± 191 µs per loop (mean ± std. dev. of 7 runs, 10 loops each)
11.9 ms ± 37.8 µs per loop (mean ± std. dev. of 7 runs, 100 loops each)
11.9 ms ± 60.2 µs per loop (mean ± std. dev. of 7 runs, 100 loops each)
260 ns ± 1.84 ns per loop (mean ± std. dev. of 7 runs, 1000000 loops each)
56.5 ms ± 204 µs per loop (mean ± std. dev. of 7 runs, 10 loops each)
``````

Using the internal `str.index` is in fact faster than any manual comparison.

I didn't know if the exception in test 4 would be more laborious than using `str.count`, the difference seems negligible.

Note that `map()` (test 6) returns an iterator and not an actual list, thus test 7.

• You've shown that using the internal `str.index` is faster if you have nothing to replace. If all elements are `None` I'd expect `rep4` and `rep5` to be very slow, as the method is O(nm), whereas the others are O(n), with n elements and m `None` values. Jan 14, 2021 at 8:26
• @CrisLuengo: `rep4`/`rep5` scale fine; they both uses a `start` parameter based on the position of the last replacement, so they remain `O(n)`; `index` is `O(n)` if run on the whole `list` every time, but the `start` parameter ensures all the `index` calls put together traverses each index of the `list` exactly once. They get slower as the number of hits goes up, but for non-big-O related reasons (fixed overhead of the `index` call paid more); in practice, using kxr's better version of `rep4`, 1000 `None`s only takes ~3x longer than 1000 `1`s. Feb 25, 2021 at 16:38
• If you do want to incorporate that fixed overhead of the `index` calls, the real work done is `O(n + m)`, not `O(nm)`; you pay the fixed overhead of `index` (along with the associated work of reassigning values) once for each `None`, and the cumulative non-fixed overhead cost of all the `index` calls put together is `O(n)` in terms of the length of the `list`. Real big-O computations would still call it `O(n)` though, since `m` is bounded by `n`, meaning `m` can be interpreted as just another `n` term, and `O(n + n)` is the same as `O(n)` (since constant coeffcients in `2n` are dropped). Feb 25, 2021 at 16:40
• @ShadowRanger: Thanks, I thought `index` searched from the beginning every time, didn't pay enough attention. My comment about the test still stands though: it's showing times when nothing needs to be replaced. Better test data would be necessary. Feb 25, 2021 at 17:07

The answers for this old but relevant question are wildly variable in speed.

The fastest of the solution posted by kxr.

However, this is even faster and otherwise not here:

``````def f1(arr, find, replace):
base=0
for cnt in range(arr.count(find)):
offset=arr.index(find, base)
arr[offset]=replace
base=offset+1
``````

Here is timing for the various solutions. The faster ones are 3X faster than accepted answer and 5X faster than the slowest answer here.

To be fair, all methods needed to do inlace replacement of the array sent to the function.

``````def f1(arr, find, replace):
base=0
for cnt in range(arr.count(find)):
offset=arr.index(find, base)
arr[offset]=replace
base=offset+1

def f2(arr,find,replace):
for i,e in enumerate(arr):
if e==find:
arr[i]=replace

def f3(arr,find,replace):
# in place list comprehension
arr[:]=[replace if e==find else e for e in arr]

def f4(arr,find,replace):
# in place map and lambda -- SLOW
arr[:]=list(map(lambda x: x if x != find else replace, arr))

def f5(arr,find,replace):
# find index with comprehension
for i in [i for i, e in enumerate(arr) if e==find]:
arr[i]=replace

def f6(arr,find,replace):
# FASTEST but a little les clear
try:
while True:
arr[arr.index(find)]=replace
except ValueError:
pass

def f7(lst, old, new):
"""replace list elements (inplace)"""
i = -1
try:
while 1:
i = lst.index(old, i + 1)
lst[i] = new
except ValueError:
pass

import time

def cmpthese(funcs, args=(), cnt=1000, rate=True, micro=True):
"""Generate a Perl style function benchmark"""
def pprint_table(table):
"""Perl style table output"""
def format_field(field, fmt='{:,.0f}'):
if type(field) is str: return field
if type(field) is tuple: return field[1].format(field[0])
return fmt.format(field)

def get_max_col_w(table, index):
return max([len(format_field(row[index])) for row in table])

col_paddings=[get_max_col_w(table, i) for i in range(len(table[0]))]
for i,row in enumerate(table):
# left col
# rest of the cols
print(' '.join(row_tab))

results={}
for i in range(cnt):
for f in funcs:
start=time.perf_counter_ns()
f(*args)
stop=time.perf_counter_ns()
results.setdefault(f.__name__, []).append(stop-start)
results={k:float(sum(v))/len(v) for k,v in results.items()}
fastest=sorted(results,key=results.get, reverse=True)
table=[['']]
if rate: table[0].append('rate/sec')
if micro: table[0].append('\u03bcsec/pass')
table[0].extend(fastest)
for e in fastest:
tmp=[e]
if rate:
tmp.append('{:,}'.format(int(round(float(cnt)*1000000.0/results[e]))))

if micro:
tmp.append('{:,.1f}'.format(results[e]/float(cnt)))

for x in fastest:
if x==e: tmp.append('--')
else: tmp.append('{:.1%}'.format((results[x]-results[e])/results[e]))
table.append(tmp)

pprint_table(table)

if __name__=='__main__':
import sys
import time
print(sys.version)
cases=(
('small, found', 9, 100),
('large, found', 9, 1000),
)
for txt, tgt, mul in cases:
print(f'\n{txt}:')
arr=[1,2,3,4,5,6,7,8,9,0]*mul
args=(arr,tgt,'X')
cmpthese([f1,f2,f3, f4, f5, f6, f7],args)
``````

And the results:

``````3.9.1 (default, Feb  3 2021, 07:38:02)
[Clang 12.0.0 (clang-1200.0.32.29)]

small, found:
rate/sec μsec/pass     f4     f3     f5     f2     f6     f7     f1
f4  133,982       7.5     -- -38.8% -49.0% -52.5% -78.5% -78.6% -82.9%
f3  219,090       4.6  63.5%     -- -16.6% -22.4% -64.8% -65.0% -72.0%
f5  262,801       3.8  96.1%  20.0%     --  -6.9% -57.8% -58.0% -66.4%
f2  282,259       3.5 110.7%  28.8%   7.4%     -- -54.6% -54.9% -63.9%
f6  622,122       1.6 364.3% 184.0% 136.7% 120.4%     --  -0.7% -20.5%
f7  626,367       1.6 367.5% 185.9% 138.3% 121.9%   0.7%     -- -19.9%
f1  782,307       1.3 483.9% 257.1% 197.7% 177.2%  25.7%  24.9%     --

rate/sec μsec/pass     f4     f5     f2     f3     f6     f7     f1
f4   13,846      72.2     -- -40.3% -41.4% -47.8% -85.2% -85.4% -86.2%
f5   23,186      43.1  67.5%     --  -1.9% -12.5% -75.2% -75.5% -76.9%
f2   23,646      42.3  70.8%   2.0%     -- -10.8% -74.8% -75.0% -76.4%
f3   26,512      37.7  91.5%  14.3%  12.1%     -- -71.7% -72.0% -73.5%
f6   93,656      10.7 576.4% 303.9% 296.1% 253.3%     --  -1.0%  -6.5%
f7   94,594      10.6 583.2% 308.0% 300.0% 256.8%   1.0%     --  -5.6%
f1  100,206      10.0 623.7% 332.2% 323.8% 278.0%   7.0%   5.9%     --

large, found:
rate/sec μsec/pass     f4     f2     f5     f3     f6     f7     f1
f4      145   6,889.4     -- -33.3% -34.8% -48.6% -85.3% -85.4% -85.8%
f2      218   4,593.5  50.0%     --  -2.2% -22.8% -78.0% -78.1% -78.6%
f5      223   4,492.4  53.4%   2.3%     -- -21.1% -77.5% -77.6% -78.2%
f3      282   3,544.0  94.4%  29.6%  26.8%     -- -71.5% -71.6% -72.3%
f6      991   1,009.5 582.4% 355.0% 345.0% 251.1%     --  -0.4%  -2.8%
f7      995   1,005.4 585.2% 356.9% 346.8% 252.5%   0.4%     --  -2.4%
f1    1,019     981.3 602.1% 368.1% 357.8% 261.2%   2.9%   2.5%     --

rate/sec μsec/pass     f4     f5     f2     f3     f6     f7     f1
f4      147   6,812.0     -- -35.0% -36.4% -48.9% -85.7% -85.8% -86.1%
f5      226   4,424.8  54.0%     --  -2.0% -21.3% -78.0% -78.1% -78.6%
f2      231   4,334.9  57.1%   2.1%     -- -19.6% -77.6% -77.7% -78.2%
f3      287   3,484.0  95.5%  27.0%  24.4%     -- -72.1% -72.2% -72.8%
f6    1,028     972.3 600.6% 355.1% 345.8% 258.3%     --  -0.4%  -2.7%
f7    1,033     968.2 603.6% 357.0% 347.7% 259.8%   0.4%     --  -2.3%
f1    1,057     946.2 619.9% 367.6% 358.1% 268.2%   2.8%   2.3%     --
``````
• Your f1 and f6 are O(n^2), so for large enough lists they will eventually be much slower than the O(n) solutions. It's possibly worth finding the approximate crossover and switching strategies for some length of list. May 11, 2020 at 2:09
• How is f6 O(n^2)?
– dawg
May 11, 2020 at 4:17
• @dawg: `f6` is `O(n²)` because it uses `index` internally without adjusting the start position for the search. In a `list` consisting solely of things to replace, that means `n` calls to `index`, each of which do an average of `n / 2` work (the first one is `1` work, the last `n` work, it counts up in between; the first element of the `list` is checked `n` times, the second `n - 1` times, etc.). kxr's answer tracks the position of each replacement and uses it to avoid rechecking, keeping it to `O(n)`. Feb 25, 2021 at 21:13
• @ShadowRanger: I took your comments and fixed `f1` so now it tracks the base offset. No more `O(n²)`
– dawg
Feb 27, 2021 at 1:48
• @dawg: Yup, that works. Without the `+1`, it does rescan every element that it just replaced, so in the `list` of all elements to replace, it's checking each index twice, instead of just once, but that's a fixed multiplier that doesn't affect big-O (and avoiding the `+ 1` saves a surprisingly amount of work; the overhead of simple math is surprisingly high). Has one significant problem: It will go into an infinite loop if the replacement value compares equal to the search value, so if you're, say, replacing `1` with `True` or `1.0`, kaboom; I prefer kxr's approach for bulletproofing. Feb 27, 2021 at 2:07

In many cases, defining a replacer function and calling it in a loop is very readable. It's very useful if values need to be replaced using some rule. For example, to replace values depending on whether it's divisible by 15, 3 or 5, one can define a function that checks conditions and returns an appropriate value.

``````def fizzbuzz(num):
if num % 15 == 0:
return 'FizzBuzz'
elif num % 3 == 0:
return 'Fizz'
elif num % 5 == 0:
return 'Buzz'
else:
return num

a = [1, 2, 3, 4, 5, 10, 15, 1]
a[:] = (fizzbuzz(n) for n in a)
# or
a[:] = map(fizzbuzz, a)
a # [1, 2, 'Fizz', 4, 1, 'Buzz', 'Fizz', 2, 'Fizz', 1, 1]
``````

One thing to note is that (at least as of python 3.10) if a function needs to be called on every element in a list, then `map()` is faster than a comprehension.1

This difference is even more pronounced for built-in methods such as `dict.get()`.2 So @roipoussiere's solution can be made twice as fast by simply mapping it like the following.

``````a = [1, 2, 3, 4, 1, 5, 3, 2, 6, 1, 1]
replacer = {1:10, 2:20, 3:'foo'}.get
a[:] = map(replacer, a, a)        # in-place replacement
a1 = [*map(replacer, a, a)]       # new list
``````

1 `map()` is ~20% faster than calling a function in a list comprehension in the example below.

``````a = [1, 2, 3, 4, 1, 5, 3, 2, 6, 1, 1]*10000
%timeit [fizzbuzz(n) for n in a]
# 15.1 ms ± 443 µs per loop (mean ± std. dev. of 7 runs, 1,000 loops each)

%timeit list(map(fizzbuzz, a))
# 12.7 ms ± 27.4 µs per loop (mean ± std. dev. of 7 runs, 1,000 loops each)
``````

2 When replacing values using `dict.get()`, mapping it is ~2 times faster than calling it in a list comprehension.

``````a = [1, 2, 3, 4, 1, 5, 3, 2, 6, 1, 1]*10000
replacer = {1:10, 2:20, 3:'foo'}.get

%timeit [replacer(n,n) for n in a]
# 4.64 ms ± 195 µs per loop (mean ± std. dev. of 7 runs, 1,000 loops each)

%timeit list(map(replacer, a, a))
# 2.21 ms ± 13.3 µs per loop (mean ± std. dev. of 7 runs, 1,000 loops each)
``````

I might be a dumb-dumb, but I would write a separate, simple function for this:

``````def convertElements( oldlist, convert_dict ):
newlist = []
for e in oldlist:
if e in convert_dict:
newlist.append(convert_dict[e])
else:
newlist.append(e)
return newlist
``````

And then call this as needed like so:

``````a = [1,2,3,4,5,1,2,3,4,5,1]
a_new = convertElements(a, {1: 10})
## OUTPUT: a_new=[10, 2, 3, 4, 5, 10, 2, 3, 4, 5, 10]
``````
• No need for `if/else`. Simply do `newlist.append(convert_dict.get(e, e))`. The `get` method has a `default` argument that is returned if the key is not in the dict. So if it is not, return it... Then it can also become more conveniently a list-comp: `newlist = [convert_dict.get(e, e) for e in oldlist]` Jan 26, 2022 at 15:57