170

Is there any efficient mass string concatenation method in Python (like StringBuilder in C# or StringBuffer in Java)? I found following methods here:

  • Simple concatenation using +
  • Using string list and join method
  • Using UserString from MutableString module
  • Using character array and the array module
  • Using cStringIO from StringIO module

But what do you experts use or suggest, and why?

[A related question here]

2

12 Answers 12

146

You may be interested in this: An optimization anecdote by Guido. Although it is worth remembering also that this is an old article and it predates the existence of things like ''.join (although I guess string.joinfields is more-or-less the same)

On the strength of that, the array module may be fastest if you can shoehorn your problem into it. But ''.join is probably fast enough and has the benefit of being idiomatic and thus easier for other python programmers to understand.

Finally, the golden rule of optimization: don't optimize unless you know you need to, and measure rather than guessing.

You can measure different methods using the timeit module. That can tell you which is fastest, instead of random strangers on the internet making guesses.

5
  • 1
    Wanting to add onto the point about when to optimize: make sure to test against the worst cases. For example, I can increase my sample so that my current code goes from running at 0.17 seconds to 170 seconds. Well I want to test at larger sample sizes since there is less variation there.
    – Flipper
    Jan 8 '15 at 7:57
  • 4
    "Don't optimize until you know you need to." Unless you are just using a nominally different idiom and can avoid rework of your code with little extra effort. Aug 18 '16 at 11:51
  • 1
    One place you know you need to is interview (which is always a great time to brush up your deep understanding). Unfortunately I haven't found ANY modern article about this. (1) Is Java/C# String still that bad in 2017? (2) How about C++? (3) Now tell about latest and greatest in Python focusing on cases when we need to do millions of concatenations. Can we trust that join would work in linear time ? Nov 22 '17 at 13:30
  • What does "fast enough" mean for .join()? The main question is, does it a) create a copy of the string for concatenation (similar to s = s + 'abc'), which requires O(n) runtime, or b) simply append to the existing string without creating a copy, which requires O(1)?
    – CGFoX
    Oct 30 '19 at 7:23
  • @CGFoX s = s + 'abc' creates a brand-new str object, then makes s refer to that instead of the original object referred to by s. If you do this inside a loop, you are repeatedly copying the (increasingly long) value of s into a series of new object. ''.join, however, operates "inside" the str type. It only has to access the contents of the operands once, to copy into a str object pre-allocated to be large enough to hold the result.
    – chepner
    Jul 8 at 15:48
79

Python 3.6 changed the game for string concatenation of known components with Literal String Interpolation.

Given the test case from mkoistinen's answer, having strings

domain = 'some_really_long_example.com'
lang = 'en'
path = 'some/really/long/path/'

The contenders are

  • f'http://{domain}/{lang}/{path}' - 0.151 µs

  • 'http://%s/%s/%s' % (domain, lang, path) - 0.321 µs

  • 'http://' + domain + '/' + lang + '/' + path - 0.356 µs

  • ''.join(('http://', domain, '/', lang, '/', path)) - 0.249 µs (notice that building a constant-length tuple is slightly faster than building a constant-length list).

Thus currently the shortest and the most beautiful code possible is also fastest.

In alpha versions of Python 3.6 the implementation of f'' strings was the slowest possible - actually the generated byte code is pretty much equivalent to the ''.join() case with unnecessary calls to str.__format__ which without arguments would just return self unchanged. These inefficiencies were addressed before 3.6 final.

The speed can be contrasted with the fastest method for Python 2, which is + concatenation on my computer; and that takes 0.203 µs with 8-bit strings, and 0.259 µs if the strings are all Unicode.

65

''.join(sequenceofstrings) is what usually works best -- simplest and fastest.

12
  • 3
    @mshsayem, in Python a sequence can be any enumerable object, even a function. Aug 22 '09 at 20:06
  • 2
    I absolutely love the ''.join(sequence) idiom. It's especially useful to produce comma-separated lists: ', '.join([1, 2, 3]) gives the string '1, 2, 3'. Aug 22 '09 at 20:12
  • 8
    @mshsayem: "".join(chr(x) for x in xrange(65,91)) --- in this case, the argument to join is an iterator, created through a generator expression. There's no temporary list that gets constructed.
    – balpha
    Aug 22 '09 at 20:19
  • 2
    @balpha: and yet the generator version is slower than the list comprehension version: C:\temp>python -mtimeit "''.join(chr(x) for x in xrange(65,91))" 100000 loops, best of 3: 9.71 usec per loop C:\temp>python -mtimeit "''.join([chr(x) for x in xrange(65,91)])" 100000 loops, best of 3: 7.1 usec per loop
    – hughdbrown
    Aug 30 '09 at 5:35
  • 1
    @hughdbrown, yes, when you have free memory out the wazoo (typical timeit case) listcomp can be better optimized than genexp, often by 20-30%. When memory's tight things are different -- hard to reproduce in timeit, though!-) Aug 30 '09 at 6:15
40

It depends on what you're doing.

After Python 2.5, string concatenation with the + operator is pretty fast. If you're just concatenating a couple of values, using the + operator works best:

>>> x = timeit.Timer(stmt="'a' + 'b'")
>>> x.timeit()
0.039999961853027344

>>> x = timeit.Timer(stmt="''.join(['a', 'b'])")
>>> x.timeit()
0.76200008392333984

However, if you're putting together a string in a loop, you're better off using the list joining method:

>>> join_stmt = """
... joined_str = ''
... for i in xrange(100000):
...   joined_str += str(i)
... """
>>> x = timeit.Timer(join_stmt)
>>> x.timeit(100)
13.278000116348267

>>> list_stmt = """
... str_list = []
... for i in xrange(100000):
...   str_list.append(str(i))
... ''.join(str_list)
... """
>>> x = timeit.Timer(list_stmt)
>>> x.timeit(100)
12.401000022888184

...but notice that you have to be putting together a relatively high number of strings before the difference becomes noticeable.

1
  • 3
    1) In your first measurement it's probably the list construction that takes the time. Try with a tuple. 2) CPython performs uniformly good, however other Python implementations perform way worse with + and += Aug 23 '09 at 14:54
23

As per John Fouhy's answer, don't optimize unless you have to, but if you're here and asking this question, it may be precisely because you have to. In my case, I needed assemble some URLs from string variables... fast. I noticed no one (so far) seems to be considering the string format method, so I thought I'd try that and, mostly for mild interest, I thought I'd toss the string interpolation operator in there for good measuer. To be honest, I didn't think either of these would stack up to a direct '+' operation or a ''.join(). But guess what? On my Python 2.7.5 system, the string interpolation operator rules them all and string.format() is the worst performer:

# concatenate_test.py

from __future__ import print_function
import timeit

domain = 'some_really_long_example.com'
lang = 'en'
path = 'some/really/long/path/'
iterations = 1000000

def meth_plus():
    '''Using + operator'''
    return 'http://' + domain + '/' + lang + '/' + path

def meth_join():
    '''Using ''.join()'''
    return ''.join(['http://', domain, '/', lang, '/', path])

def meth_form():
    '''Using string.format'''
    return 'http://{0}/{1}/{2}'.format(domain, lang, path)

def meth_intp():
    '''Using string interpolation'''
    return 'http://%s/%s/%s' % (domain, lang, path)

plus = timeit.Timer(stmt="meth_plus()", setup="from __main__ import meth_plus")
join = timeit.Timer(stmt="meth_join()", setup="from __main__ import meth_join")
form = timeit.Timer(stmt="meth_form()", setup="from __main__ import meth_form")
intp = timeit.Timer(stmt="meth_intp()", setup="from __main__ import meth_intp")

plus.val = plus.timeit(iterations)
join.val = join.timeit(iterations)
form.val = form.timeit(iterations)
intp.val = intp.timeit(iterations)

min_val = min([plus.val, join.val, form.val, intp.val])

print('plus %0.12f (%0.2f%% as fast)' % (plus.val, (100 * min_val / plus.val), ))
print('join %0.12f (%0.2f%% as fast)' % (join.val, (100 * min_val / join.val), ))
print('form %0.12f (%0.2f%% as fast)' % (form.val, (100 * min_val / form.val), ))
print('intp %0.12f (%0.2f%% as fast)' % (intp.val, (100 * min_val / intp.val), ))

The results:

# python2.7 concatenate_test.py
plus 0.360787868500 (90.81% as fast)
join 0.452811956406 (72.36% as fast)
form 0.502608060837 (65.19% as fast)
intp 0.327636957169 (100.00% as fast)

If I use a shorter domain and shorter path, interpolation still wins out. The difference is more pronounced, though, with longer strings.

Now that I had a nice test script, I also tested under Python 2.6, 3.3 and 3.4, here's the results. In Python 2.6, the plus operator is the fastest! On Python 3, join wins out. Note: these tests are very repeatable on my system. So, 'plus' is always faster on 2.6, 'intp' is always faster on 2.7 and 'join' is always faster on Python 3.x.

# python2.6 concatenate_test.py
plus 0.338213920593 (100.00% as fast)
join 0.427221059799 (79.17% as fast)
form 0.515371084213 (65.63% as fast)
intp 0.378169059753 (89.43% as fast)

# python3.3 concatenate_test.py
plus 0.409130576998 (89.20% as fast)
join 0.364938726001 (100.00% as fast)
form 0.621366866995 (58.73% as fast)
intp 0.419064424001 (87.08% as fast)

# python3.4 concatenate_test.py
plus 0.481188605998 (85.14% as fast)
join 0.409673971997 (100.00% as fast)
form 0.652010936996 (62.83% as fast)
intp 0.460400978001 (88.98% as fast)

# python3.5 concatenate_test.py
plus 0.417167026084 (93.47% as fast)
join 0.389929617057 (100.00% as fast)
form 0.595661019906 (65.46% as fast)
intp 0.404455224983 (96.41% as fast)

Lesson learned:

  • Sometimes, my assumptions are dead wrong.
  • Test against the system env. you'll be running in production.
  • String interpolation isn't dead yet!

tl;dr:

  • If you using 2.6, use the + operator.
  • if you're using 2.7 use the '%' operator.
  • if you're using 3.x use ''.join().
4
  • 2
    Note: literal string interpolation is faster still for 3.6+ : f'http://{domain}/{lang}/{path}' May 1 '17 at 22:34
  • 1
    Also, .format() has three forms, in order from fast to slow: "{}".format(x), "{0}".format(x), "{x}".format(x=x) May 1 '17 at 22:45
  • The real lesson: when your problem domain is small, e.g. composing short strings, method most often does not matter. And even when it matters, e.g. you really are building a million strings, the overhead often matters more. It is a typical symptom of worrying about the wrong problem. Only when the overhead is not significant, e.g. when building up entire book as a string, the method difference start to matter.
    – Hui Zhou
    Sep 29 '17 at 15:49
  • Here's an example based on the above benchmark that includes f-strings gist.github.com/holmanb/84be00eab35477565cb95a1d62a741a9 May 2 at 1:09
10

it pretty much depends on the relative sizes of the new string after every new concatenation. With the + operator, for every concatenation a new string is made. If the intermediary strings are relatively long, the + becomes increasingly slower because the new intermediary string is being stored.

Consider this case:

from time import time
stri=''
a='aagsdfghfhdyjddtyjdhmfghmfgsdgsdfgsdfsdfsdfsdfsdfsdfddsksarigqeirnvgsdfsdgfsdfgfg'
l=[]
#case 1
t=time()
for i in range(1000):
    stri=stri+a+repr(i)
print time()-t

#case 2
t=time()
for i in xrange(1000):
    l.append(a+repr(i))
z=''.join(l)
print time()-t

#case 3
t=time()
for i in range(1000):
    stri=stri+repr(i)
print time()-t

#case 4
t=time()
for i in xrange(1000):
    l.append(repr(i))
z=''.join(l)
print time()-t

Results

1 0.00493192672729

2 0.000509023666382

3 0.00042200088501

4 0.000482797622681

In the case of 1&2, we add a large string, and join() performs about 10 times faster. In case 3&4, we add a small string, and '+' performs slightly faster

7

For python 3.8.6/3.9, I had to do some dirty hacks, because perfplot was giving out some errors. Here assume that x[0] is a a and x[1] is b: Performance

The plot is nearly same for large data. For small data, Performance 2

Taken by perfplot and this is the code, large data == range(8), small data == range(4).

import perfplot

from random import choice
from string import ascii_lowercase as letters

def generate_random(x):
    data = ''.join(choice(letters) for i in range(x))
    sata = ''.join(choice(letters) for i in range(x))
    return [data,sata]

def fstring_func(x):
    return [ord(i) for i in f'{x[0]}{x[1]}']

def format_func(x):
    return [ord(i) for i in "{}{}".format(x[0], x[1])]

def replace_func(x):
    return [ord(i) for i in "|~".replace('|', x[0]).replace('~', x[1])]

def join_func(x):
    return [ord(i) for i in "".join([x[0], x[1]])]

perfplot.show(
    setup=lambda n: generate_random(n),
    kernels=[
        fstring_func,
        format_func,
        replace_func,
        join_func,
    ],
    n_range=[int(k ** 2.5) for k in range(4)],
)

When medium data is there, and 4 strings are there x[0], x[1], x[2], x[3] instead of 2 string:

def generate_random(x):
    a =  ''.join(choice(letters) for i in range(x))
    b =  ''.join(choice(letters) for i in range(x))
    c =  ''.join(choice(letters) for i in range(x))
    d =  ''.join(choice(letters) for i in range(x))
    return [a,b,c,d]

Performance 3 Better to stick with fstrings. Also speed of %s is similar to .format()

3

I ran into a situation where I needed to have an appendable string of unknown size. These are the benchmark results (python 2.7.3):

$ python -m timeit -s 's=""' 's+="a"'
10000000 loops, best of 3: 0.176 usec per loop
$ python -m timeit -s 's=[]' 's.append("a")'
10000000 loops, best of 3: 0.196 usec per loop
$ python -m timeit -s 's=""' 's="".join((s,"a"))'
100000 loops, best of 3: 16.9 usec per loop
$ python -m timeit -s 's=""' 's="%s%s"%(s,"a")'
100000 loops, best of 3: 19.4 usec per loop

This seems to show that '+=' is the fastest. The results from the skymind link are a bit out of date.

(I realize that the second example is not complete, the final list would need to be joined. This does show, however, that simply preparing the list takes longer than the string concat.)

3
  • I'm getting sub 1-sec times for 3rd and 4th tests. Why you getting such high times? pastebin.com/qabNMCHS Aug 2 '13 at 8:03
  • @ronnieaka: He's getting sub 1-sec times for all tests. He is getting >1 µs for the 3rd & 4th, which you did not. I also get slower times on those tests (on Python 2.7.5, Linux). Could be CPU, version, build flags, who knows.
    – Thanatos
    Aug 17 '13 at 0:58
  • These benchmark results are useless. Especially, the first case, which isn't doing any string concatenation, just returning the second string value intact. Oct 13 '16 at 7:33
3

One Year later, let's test mkoistinen's answer with python 3.4.3:

  • plus 0.963564149000 (95.83% as fast)
  • join 0.923408469000 (100.00% as fast)
  • form 1.501130934000 (61.51% as fast)
  • intp 1.019677452000 (90.56% as fast)

Nothing changed. Join is still the fastest method. With intp being arguably the best choice in terms of readability you might want to use intp nevertheless.

1
  • 1
    Maybe it could be an addition to mkoistinen answer since it is a bit short of a full blown answer (or at least add the code you are using).
    – Trilarion
    Nov 29 '15 at 11:04
2

Probably "new f-strings in Python 3.6" is the most efficient way of concatenating strings.

Using %s

>>> timeit.timeit("""name = "Some"
... age = 100
... '%s is %s.' % (name, age)""", number = 10000)
0.0029734770068898797

Using .format

>>> timeit.timeit("""name = "Some"
... age = 100
... '{} is {}.'.format(name, age)""", number = 10000)
0.004015227983472869

Using f

>>> timeit.timeit("""name = "Some"
... age = 100
... f'{name} is {age}.'""", number = 10000)
0.0019175919878762215

Source: https://realpython.com/python-f-strings/

1

Inspired by @JasonBaker's benchmarks, here's a simple one comparing 10 "abcdefghijklmnopqrstuvxyz" strings, showing that .join() is faster; even with this tiny increase in variables:

Catenation

>>> x = timeit.Timer(stmt='"abcdefghijklmnopqrstuvxyz" + "abcdefghijklmnopqrstuvxyz" + "abcdefghijklmnopqrstuvxyz" + "abcdefghijklmnopqrstuvxyz" + "abcdefghijklmnopqrstuvxyz" + "abcdefghijklmnopqrstuvxyz" + "abcdefghijklmnopqrstuvxyz" + "abcdefghijklmnopqrstuvxyz" + "abcdefghijklmnopqrstuvxyz" + "abcdefghijklmnopqrstuvxyz" + "abcdefghijklmnopqrstuvxyz"')
>>> x.timeit()
0.9828147209324385

Join

>>> x = timeit.Timer(stmt='"".join(["abcdefghijklmnopqrstuvxyz", "abcdefghijklmnopqrstuvxyz", "abcdefghijklmnopqrstuvxyz", "abcdefghijklmnopqrstuvxyz", "abcdefghijklmnopqrstuvxyz", "abcdefghijklmnopqrstuvxyz", "abcdefghijklmnopqrstuvxyz", "abcdefghijklmnopqrstuvxyz", "abcdefghijklmnopqrstuvxyz", "abcdefghijklmnopqrstuvxyz", "abcdefghijklmnopqrstuvxyz"])')
>>> x.timeit()
0.6114138159765048
1
1

For a small set of short strings (i.e. 2 or 3 strings of no more than a few characters), plus is still way faster. Using mkoistinen's wonderful script in Python 2 and 3:

plus 2.679107467004 (100.00% as fast)
join 3.653773699996 (73.32% as fast)
form 6.594011374000 (40.63% as fast)
intp 4.568015249999 (58.65% as fast)

So when your code is doing a huge number of separate small concatenations, plus is the preferred way if speed is crucial.

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