Since Python's string can't be changed, I was wondering how to concatenate a string more efficiently?
I can write like it:
s += stringfromelsewhere
or like this:
s = []
s.append(somestring)
# later
s = ''.join(s)
While writing this question, I found a good article talking about the topic.
http://www.skymind.com/~ocrow/python_string/
But it's in Python 2.x., so the question would be did something change in Python 3?
The best way of appending a string to a string variable is to use + or +=. This is because it's readable and fast. They are also just as fast, which one you choose is a matter of taste, the latter one is the most common. Here are timings with the timeit module:
a = a + b:
0.11338996887207031
a += b:
0.11040496826171875
However, those who recommend having lists and appending to them and then joining those lists, do so because appending a string to a list is presumably very fast compared to extending a string. And this can be true, in some cases. Here, for example, is one million appends of a one-character string, first to a string, then to a list:
a += b:
0.10780501365661621
a.append(b):
0.1123361587524414
OK, turns out that even when the resulting string is a million characters long, appending was still faster.
Now let's try with appending a thousand character long string a hundred thousand times:
a += b:
0.41823482513427734
a.append(b):
0.010656118392944336
The end string, therefore, ends up being about 100MB long. That was pretty slow, appending to a list was much faster. That that timing doesn't include the final a.join(). So how long would that take?
a.join(a):
0.43739795684814453
Oups. Turns out even in this case, append/join is slower.
So where does this recommendation come from? Python 2?
a += b:
0.165287017822
a.append(b):
0.0132720470428
a.join(a):
0.114929914474
Well, append/join is marginally faster there if you are using extremely long strings (which you usually aren't, what would you have a string that's 100MB in memory?)
But the real clincher is Python 2.3. Where I won't even show you the timings, because it's so slow that it hasn't finished yet. These tests suddenly take minutes. Except for the append/join, which is just as fast as under later Pythons.
Yup. String concatenation was very slow in Python back in the stone age. But on 2.4 it isn't anymore (or at least Python 2.4.7), so the recommendation to use append/join became outdated in 2008, when Python 2.3 stopped being updated, and you should have stopped using it. :-)
(Update: Turns out when I did the testing more carefully that using + and += is faster for two strings on Python 2.3 as well. The recommendation to use ''.join() must be a misunderstanding)
However, this is CPython. Other implementations may have other concerns. And this is just yet another reason why premature optimization is the root of all evil. Don't use a technique that's supposed "faster" unless you first measure it.
Therefore the "best" version to do string concatenation is to use + or +=. And if that turns out to be slow for you, which is pretty unlikely, then do something else.
So why do I use a lot of append/join in my code? Because sometimes it's actually clearer. Especially when whatever you should concatenate together should be separated by spaces or commas or newlines.
If you are concatenating a lot of values, then neither. Appending a list is expensive. You can use StringIO for that. Especially if you are building it up over a lot of operations.
from cStringIO import StringIO
# python3: from io import StringIO
buf = StringIO()
buf.write('foo')
buf.write('foo')
buf.write('foo')
buf.getvalue()
# 'foofoofoo'
If you already have a complete list returned to you from some other operation, then just use the ''.join(aList)
From the python FAQ: What is the most efficient way to concatenate many strings together?
str and bytes objects are immutable, therefore concatenating many strings together is inefficient as each concatenation creates a new object. In the general case, the total runtime cost is quadratic in the total string length.
To accumulate many str objects, the recommended idiom is to place them into a list and call str.join() at the end:
chunks = [] for s in my_strings: chunks.append(s) result = ''.join(chunks)(another reasonably efficient idiom is to use io.StringIO)
To accumulate many bytes objects, the recommended idiom is to extend a bytearray object using in-place concatenation (the += operator):
result = bytearray() for b in my_bytes_objects: result += b
Edit: I was silly and had the results pasted backwards, making it look like appending to a list was faster than cStringIO. I have also added tests for bytearray/str concat, as well as a second round of tests using a larger list with larger strings. (python 2.7.3)
ipython test example for large lists of strings
try:
from cStringIO import StringIO
except:
from io import StringIO
source = ['foo']*1000
%%timeit buf = StringIO()
for i in source:
buf.write(i)
final = buf.getvalue()
# 1000 loops, best of 3: 1.27 ms per loop
%%timeit out = []
for i in source:
out.append(i)
final = ''.join(out)
# 1000 loops, best of 3: 9.89 ms per loop
%%timeit out = bytearray()
for i in source:
out += i
# 10000 loops, best of 3: 98.5 µs per loop
%%timeit out = ""
for i in source:
out += i
# 10000 loops, best of 3: 161 µs per loop
## Repeat the tests with a larger list, containing
## strings that are bigger than the small string caching
## done by the Python
source = ['foo']*1000
# cStringIO
# 10 loops, best of 3: 19.2 ms per loop
# list append and join
# 100 loops, best of 3: 144 ms per loop
# bytearray() +=
# 100 loops, best of 3: 3.8 ms per loop
# str() +=
# 100 loops, best of 3: 5.11 ms per loop
.join() is actually measuring .append(). To measure .join(), we should say %timeit "".join(source)?
In Python >= 3.6, the new f-string is an efficient way to concatenate a string.
>>> name = 'some_name'
>>> number = 123
>>>
>>> f'Name is {name} and the number is {number}.'
'Name is some_name and the number is 123.'
f'{a}{b}' isn't more efficient than a += b or a + b, I don't see how this is meaningfully responsive to a question that asks specifically about performance. This feature is syntax sugar (good and useful sugar, to be sure!), not a performance optimization.
Nov 18, 2020 at 23:10
Using in place string concatenation by '+' is THE WORST method of concatenation in terms of stability and cross implementation as it does not support all values. PEP8 standard discourages this and encourages the use of format(), join() and append() for long term use.
As quoted from the linked "Programming Recommendations" section:
For example, do not rely on CPython's efficient implementation of in-place string concatenation for statements in the form a += b or a = a + b. This optimization is fragile even in CPython (it only works for some types) and isn't present at all in implementations that don't use refcounting. In performance sensitive parts of the library, the ''.join() form should be used instead. This will ensure that concatenation occurs in linear time across various implementations.
You write this function
def str_join(*args):
return ''.join(map(str, args))
Then you can call simply wherever you want
str_join('Pine') # Returns : Pine
str_join('Pine', 'apple') # Returns : Pineapple
str_join('Pine', 'apple', 3) # Returns : Pineapple3
You can do in different ways.
str1 = "Hello"
str2 = "World"
str_list = ['Hello', 'World']
str_dict = {'str1': 'Hello', 'str2': 'World'}
# Concatenating With the + Operator
print(str1 + ' ' + str2) # Hello World
# String Formatting with the % Operator
print("%s %s" % (str1, str2)) # Hello World
# String Formatting with the { } Operators with str.format()
print("{}{}".format(str1, str2)) # Hello World
print("{0}{1}".format(str1, str2)) # Hello World
print("{str1} {str2}".format(str1=str_dict['str1'], str2=str_dict['str2'])) # Hello World
print("{str1} {str2}".format(**str_dict)) # Hello World
# Going From a List to a String in Python With .join()
print(' '.join(str_list)) # Hello World
# Python f'strings --> 3.6 onwards
print(f"{str1} {str2}") # Hello World
I created this little summary through following articles.
The recommended method is still to use append and join.
If the strings you are concatenating are literals, use String literal concatenation
re.compile(
"[A-Za-z_]" # letter or underscore
"[A-Za-z0-9_]*" # letter, digit or underscore
)
This is useful if you want to comment on part of a string (as above) or if you want to use raw strings or triple quotes for part of a literal but not all.
Since this happens at the syntax layer it uses zero concatenation operators.
As @jdi mentions Python documentation suggests to use str.join or io.StringIO for string concatenation. And says that a developer should expect quadratic time from += in a loop, even though there's an optimisation since Python 2.4. As this answer says:
If Python detects that the left argument has no other references, it calls
reallocto attempt to avoid a copy by resizing the string in place. This is not something you should ever rely on, because it's an implementation detail and because ifreallocends up needing to move the string frequently, performance degrades to O(n^2) anyway.
I will show an example of real-world code that naively relied on += this optimisation, but it didn't apply. The code below converts an iterable of short strings into bigger chunks to be used in a bulk API.
def test_concat_chunk(seq, split_by):
result = ['']
for item in seq:
if len(result[-1]) + len(item) > split_by:
result.append('')
result[-1] += item
return result
This code can literary run for hours because of quadratic time complexity. Below are alternatives with suggested data structures:
import io
def test_stringio_chunk(seq, split_by):
def chunk():
buf = io.StringIO()
size = 0
for item in seq:
if size + len(item) <= split_by:
size += buf.write(item)
else:
yield buf.getvalue()
buf = io.StringIO()
size = buf.write(item)
if size:
yield buf.getvalue()
return list(chunk())
def test_join_chunk(seq, split_by):
def chunk():
buf = []
size = 0
for item in seq:
if size + len(item) <= split_by:
buf.append(item)
size += len(item)
else:
yield ''.join(buf)
buf.clear()
buf.append(item)
size = len(item)
if size:
yield ''.join(buf)
return list(chunk())
And a micro-benchmark:
import timeit
import random
import string
import matplotlib.pyplot as plt
line = ''.join(random.choices(
string.ascii_uppercase + string.digits, k=512)) + '\n'
x = []
y_concat = []
y_stringio = []
y_join = []
n = 5
for i in range(1, 11):
x.append(i)
seq = [line] * (20 * 2 ** 20 // len(line))
chunk_size = i * 2 ** 20
y_concat.append(
timeit.timeit(lambda: test_concat_chunk(seq, chunk_size), number=n) / n)
y_stringio.append(
timeit.timeit(lambda: test_stringio_chunk(seq, chunk_size), number=n) / n)
y_join.append(
timeit.timeit(lambda: test_join_chunk(seq, chunk_size), number=n) / n)
plt.plot(x, y_concat)
plt.plot(x, y_stringio)
plt.plot(x, y_join)
plt.legend(['concat', 'stringio', 'join'], loc='upper left')
plt.show()
While somewhat dated, Code Like a Pythonista: Idiomatic Python recommends join() over + in this section. As does PythonSpeedPerformanceTips in its section on string concatenation, with the following disclaimer:
The accuracy of this section is disputed with respect to later versions of Python. In CPython 2.5, string concatenation is fairly fast, although this may not apply likewise to other Python implementations. See ConcatenationTestCode for a discussion.
my use case was slight different. I had to construct a query where more then 20 fields were dynamic. I followed this approach of using format method
query = "insert into {0}({1},{2},{3}) values({4}, {5}, {6})"
query.format('users','name','age','dna','suzan',1010,'nda')
this was comparatively simpler for me instead of using + or other ways
You can use this(more efficient) too. (https://softwareengineering.stackexchange.com/questions/304445/why-is-s-better-than-for-concatenation)
s += "%s" %(stringfromelsewhere)