# How to get the line count of a large file cheaply in Python

How do I get a line count of a large file in the most memory- and time-efficient manner?

``````def file_len(filename):
with open(filename) as f:
for i, _ in enumerate(f):
pass
return i + 1
``````
• Do you need exact line count or will an approximation suffice?
– pico
Commented May 11, 2009 at 20:14
• I would add i=-1 before for loop, since this code doesn't work for empty files. Commented Dec 27, 2011 at 16:13
• @Legend: I bet pico is thinking, get the file size (with seek(0,2) or equiv), divide by approximate line length. You could read a few lines at the beginning to guess the average line length.
– Anne
Commented Feb 7, 2012 at 17:02
• `enumerate(f, 1)` and ditch the `i + 1`? Commented Feb 21, 2013 at 12:25
• @IanMackinnon Works for empty files, but you have to initialize i to 0 before the for-loop.
– scai
Commented Aug 13, 2013 at 16:29

## 44 Answers

One line, faster than the `for` loop of the OP (although not the fastest) and very concise:

``````num_lines = sum(1 for _ in open('myfile.txt'))
``````

You can also boost the speed (and robustness) by using `rbU` mode and include it in a `with` block to close the file:

``````with open("myfile.txt", "rbU") as f:
num_lines = sum(1 for _ in f)
``````

Note: The `U` in `rbU` mode is deprecated since Python 3.3 and above, so iwe should use `rb` instead of `rbU` (and it has been removed in Python 3.11).

• its similar to sum(sequence of 1) every line is counting as 1. >>> [ 1 for line in range(10) ] [1, 1, 1, 1, 1, 1, 1, 1, 1, 1] >>> sum( 1 for line in range(10) ) 10 >>> Commented Dec 13, 2013 at 5:22
• num_lines = sum(1 for line in open('myfile.txt') if line.rstrip()) for filter empty lines Commented Mar 3, 2014 at 9:26
• as we open a file, will this be closed automatically once we iterate over all the elements? Is it required to 'close()'? I think we cannot use 'with open()' in this short statement, right? Commented Mar 18, 2014 at 15:31
• A slight lint improvement: `num_lines = sum(1 for _ in open('myfile.txt'))` Commented Jun 13, 2021 at 17:54
• It's not any faster than the other solutions, see stackoverflow.com/a/68385697/353337. Commented Jul 14, 2021 at 22:22

You can't get any better than that.

After all, any solution will have to read the entire file, figure out how many `\n` you have, and return that result.

Do you have a better way of doing that without reading the entire file? Not sure... The best solution will always be I/O-bound, best you can do is make sure you don't use unnecessary memory, but it looks like you have that covered.

[Edit May 2023]

As commented in many other answers, in Python 3 there are better alternatives. The `for` loop is not the most efficient. For example, using `mmap` or buffers is more efficient.

• Exactly, even WC is reading through the file, but in C and it's probably pretty optimized. Commented May 10, 2009 at 10:38
• As far as I understand the Python file IO is done through C as well. docs.python.org/library/stdtypes.html#file-objects Commented May 10, 2009 at 10:41
• @Tomalak That's a red herring. While python and wc might be issuing the same syscalls, python has opcode dispatch overhead that wc doesn't have. Commented Jan 11, 2013 at 22:53
• You can approximate a line count by sampling. It can be thousands of times faster. See: documentroot.com/2011/02/… Commented Jun 14, 2016 at 20:30
• Other answers seem to indicate this categorical answer is wrong, and should therefore be deleted rather than kept as accepted. Commented Jan 25, 2017 at 13:59

I believe that a memory mapped file will be the fastest solution. I tried four functions: the function posted by the OP (`opcount`); a simple iteration over the lines in the file (`simplecount`); readline with a memory-mapped filed (mmap) (`mapcount`); and the buffer read solution offered by Mykola Kharechko (`bufcount`).

I ran each function five times, and calculated the average run-time for a 1.2 million-line text file.

Windows XP, Python 2.5, 2 GB RAM, 2 GHz AMD processor

Here are my results:

``````mapcount : 0.465599966049
simplecount : 0.756399965286
bufcount : 0.546800041199
opcount : 0.718600034714
``````

Numbers for Python 2.6:

``````mapcount : 0.471799945831
simplecount : 0.634400033951
bufcount : 0.468800067902
opcount : 0.602999973297
``````

So the buffer read strategy seems to be the fastest for Windows/Python 2.6

Here is the code:

``````from __future__ import with_statement
import time
import mmap
import random
from collections import defaultdict

def mapcount(filename):
with open(filename, "r+") as f:
buf = mmap.mmap(f.fileno(), 0)
lines = 0
readline = buf.readline
while readline():
lines += 1
return lines

def simplecount(filename):
lines = 0
for line in open(filename):
lines += 1
return lines

def bufcount(filename):
f = open(filename)
lines = 0
buf_size = 1024 * 1024
read_f = f.read # loop optimization

buf = read_f(buf_size)
while buf:
lines += buf.count('\n')
buf = read_f(buf_size)

return lines

def opcount(fname):
with open(fname) as f:
for i, l in enumerate(f):
pass
return i + 1

counts = defaultdict(list)

for i in range(5):
for func in [mapcount, simplecount, bufcount, opcount]:
start_time = time.time()
assert func("big_file.txt") == 1209138
counts[func].append(time.time() - start_time)

for key, vals in counts.items():
print key.__name__, ":", sum(vals) / float(len(vals))
``````

All of these solutions ignore one way to make this run considerably faster, namely by using the unbuffered (raw) interface, using bytearrays, and doing your own buffering. (This only applies in Python 3. In Python 2, the raw interface may or may not be used by default, but in Python 3, you'll default into Unicode.)

Using a modified version of the timing tool, I believe the following code is faster (and marginally more Pythonic) than any of the solutions offered:

``````def rawcount(filename):
f = open(filename, 'rb')
lines = 0
buf_size = 1024 * 1024
read_f = f.raw.read

buf = read_f(buf_size)
while buf:
lines += buf.count(b'\n')
buf = read_f(buf_size)

return lines
``````

Using a separate generator function, this runs a smidge faster:

``````def _make_gen(reader):
b = reader(1024 * 1024)
while b:
yield b
b = reader(1024*1024)

def rawgencount(filename):
f = open(filename, 'rb')
f_gen = _make_gen(f.raw.read)
return sum(buf.count(b'\n') for buf in f_gen)
``````

This can be done completely with generators expressions in-line using itertools, but it gets pretty weird looking:

``````from itertools import (takewhile, repeat)

def rawincount(filename):
f = open(filename, 'rb')
bufgen = takewhile(lambda x: x, (f.raw.read(1024*1024) for _ in repeat(None)))
return sum(buf.count(b'\n') for buf in bufgen)
``````

Here are my timings:

``````function      average, s  min, s   ratio
rawincount        0.0043  0.0041   1.00
rawgencount       0.0044  0.0042   1.01
rawcount          0.0048  0.0045   1.09
bufcount          0.008   0.0068   1.64
wccount           0.01    0.0097   2.35
itercount         0.014   0.014    3.41
opcount           0.02    0.02     4.83
kylecount         0.021   0.021    5.05
simplecount       0.022   0.022    5.25
mapcount          0.037   0.031    7.46
``````
• I am working with 100Gb+ files, and your rawgencounts is the only feasible solution I have seen so far. Thanks! Commented Nov 10, 2015 at 11:47
• is `wccount` in this table for the subprocess shell `wc` tool? Commented Nov 11, 2015 at 18:05
• Thanks @michael-bacon, it's a really nice solution. You can make the `rawincount` solution less weird looking by using `bufgen = iter(partial(f.raw.read, 1024*1024), b'')` instead of combining `takewhile` and `repeat`. Commented Aug 6, 2019 at 6:32
• Oh, partial function, yeah, that's a nice little tweak. Also, I assumed that the 1024*1024 would get merged by the interpreter and treated as a constant but that was on hunch not documentation. Commented Aug 8, 2019 at 16:20
• @MichaelBacon, would it be faster to open the file with `buffering=0` and then calling read instead of just opening the file as "rb" and calling raw.read, or will that be optimized to the same thing? Commented Nov 19, 2019 at 18:53

You could execute a subprocess and run `wc -l filename`

``````import subprocess

def file_len(fname):
p = subprocess.Popen(['wc', '-l', fname], stdout=subprocess.PIPE,
stderr=subprocess.PIPE)
result, err = p.communicate()
if p.returncode != 0:
raise IOError(err)
return int(result.strip().split()[0])
``````
• what would be the windows version of this? Commented May 10, 2009 at 10:30
• You can refer to this SO question regarding that. stackoverflow.com/questions/247234/… Commented May 10, 2009 at 10:32
• Indeed, in my case (Mac OS X) this takes 0.13s versus 0.5s for counting the number of lines "for x in file(...)" produces, versus 1.0s counting repeated calls to str.find or mmap.find. (The file I used to test this has 1.3 million lines.) Commented May 10, 2009 at 12:06
• No need to involve the shell on that. edited answer and added example code; Commented May 11, 2009 at 12:23
• Is not cross platform. Commented Apr 12, 2017 at 15:03

After a perfplot analysis, one has to recommend the buffered read solution

``````def buf_count_newlines_gen(fname):
def _make_gen(reader):
while True:
b = reader(2 ** 16)
if not b: break
yield b

with open(fname, "rb") as f:
count = sum(buf.count(b"\n") for buf in _make_gen(f.raw.read))
return count
``````

It's fast and memory-efficient. Most other solutions are about 20 times slower.

Code to reproduce the plot:

``````import mmap
import subprocess
from functools import partial

import perfplot

def setup(n):
fname = "t.txt"
with open(fname, "w") as f:
for i in range(n):
f.write(str(i) + "\n")
return fname

def for_enumerate(fname):
i = 0
with open(fname) as f:
for i, _ in enumerate(f):
pass
return i + 1

def sum1(fname):
return sum(1 for _ in open(fname))

def mmap_count(fname):
with open(fname, "r+") as f:
buf = mmap.mmap(f.fileno(), 0)

lines = 0
while buf.readline():
lines += 1
return lines

def for_open(fname):
lines = 0
for _ in open(fname):
lines += 1
return lines

def buf_count_newlines(fname):
lines = 0
buf_size = 2 ** 16
with open(fname) as f:
buf = f.read(buf_size)
while buf:
lines += buf.count("\n")
buf = f.read(buf_size)
return lines

def buf_count_newlines_gen(fname):
def _make_gen(reader):
b = reader(2 ** 16)
while b:
yield b
b = reader(2 ** 16)

with open(fname, "rb") as f:
count = sum(buf.count(b"\n") for buf in _make_gen(f.raw.read))
return count

def wc_l(fname):
return int(subprocess.check_output(["wc", "-l", fname]).split()[0])

def sum_partial(fname):
with open(fname) as f:
count = sum(x.count("\n") for x in iter(partial(f.read, 2 ** 16), ""))
return count

def read_count(fname):
return open(fname).read().count("\n")

b = perfplot.bench(
setup=setup,
kernels=[
for_enumerate,
sum1,
mmap_count,
for_open,
wc_l,
buf_count_newlines,
buf_count_newlines_gen,
sum_partial,
read_count,
],
n_range=[2 ** k for k in range(27)],
xlabel="num lines",
)
b.save("out.png")
b.show()
``````
• I hae very long lines in my file; i'm thinking the buffer should be allocated only once using `readinto` Commented Aug 27, 2022 at 11:29
• Great graph: thanks for the code. But actually, this overlooks the case where a line is more than just than 10 characters. For long lines, `mmap` tends to be more efficient than `buf_count_newlines_gen`: see answer stackoverflow.com/a/76197308/1603480 Commented May 8, 2023 at 3:23

A one-line Bash solution similar to this answer, using the modern `subprocess.check_output` function:

``````def line_count(filename):
return int(subprocess.check_output(['wc', '-l', filename]).split()[0])
``````
• This answer should be voted up to a higher spot in this thread for Linux/Unix users. Despite the majority preferences in a cross-platform solution, this is a superb way on Linux/Unix. For a 184-million-line csv file I have to sample data from, it provides the best runtime. Other pure python solutions take on average 100+ seconds whereas subprocess call of `wc -l` takes ~ 5 seconds. Commented Jun 27, 2018 at 16:06
• `shell=True` is bad for security, it is better to avoid it. Commented May 9, 2020 at 22:16

Here is a Python program to use the multiprocessing library to distribute the line counting across machines/cores. My test improves counting a 20 million line file from 26 seconds to 7 seconds using an 8-core Windows 64-bit server. Note: not using memory mapping makes things much slower.

``````import multiprocessing, sys, time, os, mmap
import logging, logging.handlers

def init_logger(pid):
console_format = 'P{0} %(levelname)s %(message)s'.format(pid)
logger = logging.getLogger()  # New logger at root level
logger.setLevel(logging.INFO)
logger.handlers.append(logging.StreamHandler())
logger.handlers[0].setFormatter(logging.Formatter(console_format, '%d/%m/%y %H:%M:%S'))

def getFileLineCount(queues, pid, processes, file1):
init_logger(pid)
logging.info('start')

physical_file = open(file1, "r")
#  mmap.mmap(fileno, length[, tagname[, access[, offset]]]

m1 = mmap.mmap(physical_file.fileno(), 0, access=mmap.ACCESS_READ)

# Work out file size to divide up line counting

fSize = os.stat(file1).st_size
chunk = (fSize / processes) + 1

lines = 0

# Get where I start and stop
_seedStart = chunk * (pid)
_seekEnd = chunk * (pid+1)
seekStart = int(_seedStart)
seekEnd = int(_seekEnd)

if seekEnd < int(_seekEnd + 1):
seekEnd += 1

if _seedStart < int(seekStart + 1):
seekStart += 1

if seekEnd > fSize:
seekEnd = fSize

# Find where to start
if pid > 0:
m1.seek(seekStart)
# Read next line
l1 = m1.readline()  # Need to use readline with memory mapped files
seekStart = m1.tell()

# Tell previous rank my seek start to make their seek end

if pid > 0:
queues[pid-1].put(seekStart)
if pid < processes-1:
seekEnd = queues[pid].get()

m1.seek(seekStart)
l1 = m1.readline()

while len(l1) > 0:
lines += 1
l1 = m1.readline()
if m1.tell() > seekEnd or len(l1) == 0:
break

logging.info('done')
# Add up the results
if pid == 0:
for p in range(1, processes):
lines += queues[0].get()
queues[0].put(lines) # The total lines counted
else:
queues[0].put(lines)

m1.close()
physical_file.close()

if __name__ == '__main__':
init_logger('main')
if len(sys.argv) > 1:
file_name = sys.argv[1]
else:
logging.fatal('parameters required: file-name [processes]')
exit()

t = time.time()
processes = multiprocessing.cpu_count()
if len(sys.argv) > 2:
processes = int(sys.argv[2])
queues = [] # A queue for each process
for pid in range(processes):
queues.append(multiprocessing.Queue())
jobs = []
prev_pipe = 0
for pid in range(processes):
p = multiprocessing.Process(target = getFileLineCount, args=(queues, pid, processes, file_name,))
p.start()
jobs.append(p)

jobs[0].join() # Wait for counting to finish
lines = queues[0].get()

logging.info('finished {} Lines:{}'.format( time.time() - t, lines))
``````
• How does this work with files much bigger than main memory? for instance a 20GB file on a system with 4GB RAM and 2 cores Commented Sep 23, 2014 at 21:18
• Hard to test now, but I presume it would page the file in and out. Commented Sep 24, 2014 at 11:32
• This is pretty neat code. I was surprised to find that it is faster to use multiple processors. I figured that the IO would be the bottleneck. In older Python versions, line 21 needs int() like chunk = int((fSize / processes)) + 1 Commented Dec 30, 2014 at 19:45
• do it load all the file into the memory? what about a bigger fire where the size is bigger then the ram on the computer? Commented Dec 21, 2018 at 21:30
• Would you mind if I formatted the answer with black? black.vercel.app Commented Feb 5, 2022 at 8:27

I would use Python's file object method `readlines`, as follows:

``````with open(input_file) as foo:
lines = len(foo.readlines())
``````

This opens the file, creates a list of lines in the file, counts the length of the list, saves that to a variable and closes the file again.

• While this is one of the first ways that comes to mind, it probably isn't very memory efficient, especially if counting lines in files up to 10 GB (Like I do), which is a noteworthy disadvantage. Commented Apr 17, 2014 at 15:36
• @TimeSheep Is this an issue for files with many (say, billions) of small lines, or files which have extremely long lines (say, Gigabytes per line)? Commented Jun 3, 2018 at 17:40
• The reason I ask is, it would seem that the compiler should be able to optimize this away by not creating an intermediate list. Commented Jun 3, 2018 at 17:41
• @dmityugov Per Python docs, `xreadlines` has been deprecated since 2.3, as it just returns an iterator. `for line in file` is the stated replacement. See: docs.python.org/2/library/stdtypes.html#file.xreadlines Commented Aug 5, 2018 at 22:53

This is the fastest thing I have found using pure Python.

You can use whatever amount of memory you want by setting `buffer`, though 2**16 appears to be a sweet spot on my computer.

``````from functools import partial

buffer=2**16
with open(myfile) as f:
print sum(x.count('\n') for x in iter(partial(f.read,buffer), ''))
``````

I found the answer here Why is reading lines from stdin much slower in C++ than Python? and tweaked it just a tiny bit. It’s a very good read to understand how to count lines quickly, though `wc -l` is still about 75% faster than anything else.

``````def file_len(full_path):
""" Count number of lines in a file."""
f = open(full_path)
nr_of_lines = sum(1 for line in f)
f.close()
return nr_of_lines
``````
• The command "sum(1 for line in f)" seems to delete the content of the file. The command "f.readline()" returns null if I put it after that line. Commented May 12, 2021 at 15:35
• @EnteFetz that's because the file handle is exhausted, so there are no more lines to read. If you do `f.seek(0); f.readline()` this problem won't persist Commented Aug 5, 2022 at 2:57

Here is what I use, and it seems pretty clean:

``````import subprocess

def count_file_lines(file_path):
"""
Counts the number of lines in a file using wc utility.
:param file_path: path to file
:return: int, no of lines
"""
num = subprocess.check_output(['wc', '-l', file_path])
num = num.split(' ')
return int(num[0])
``````

This is marginally faster than using pure Python, but at the cost of memory usage. Subprocess will fork a new process with the same memory footprint as the parent process while it executes your command.

• Just as a side note, this won't work on Windows of course. Commented Feb 25, 2019 at 12:51
• core utils apparently provides "wc" for windows stackoverflow.com/questions/247234/…. You can also use a linux VM in your windows box if your code will end up running in linux in prod. Commented Feb 25, 2019 at 16:45
• Or WSL, highly advised over any VM if stuff like this is the only thing you do. `:-)` Commented Feb 25, 2019 at 16:59
• Yeah that works. I'm not a windows guy but from goolging I learned WSL = Windows Subsystem for Linux =) Commented Feb 25, 2019 at 21:39
• python3.7: subprocess return bytes, so code looks like this: int(subprocess.check_output(['wc', '-l', file_path]).decode("utf-8").lstrip().split(" ")[0]) Commented Dec 17, 2019 at 8:21

One line solution:

``````import os
os.system("wc -l  filename")
``````

My snippet:

``````>>> os.system('wc -l *.txt')
``````

Output:

``````0 bar.txt
1000 command.txt
3 test_file.txt
1003 total
``````
• Good idea, unfortunately this does not work on Windows though.
– Kim
Commented Jan 20, 2017 at 20:06
• if you want to be surfer of python , say good bye to windows.Believe me you will thank me one day . Commented Jan 22, 2017 at 10:38
• I just considered it noteworthy that this will only work on windows. I prefer working on a linux/unix stack myself, but when writing software IMHO one should consider the side effects a program could have when run under different OSes. As the OP did not mention his platform and in case anyone pops on this solution via google and copies it (unaware of the limitations a Windows system might have), I wanted to add the note.
– Kim
Commented Jan 22, 2017 at 12:42
• You can't save output of `os.system()` to variable and post-process it anyhow. Commented Jan 16, 2020 at 9:16
• @AnSe you are correct but question is not asked whether it saves or not.I guess you are understanding the context. Commented Jan 16, 2020 at 10:49

Kyle's answer

``````num_lines = sum(1 for line in open('my_file.txt'))
``````

is probably best. An alternative for this is:

``````num_lines =  len(open('my_file.txt').read().splitlines())
``````

Here is the comparison of performance of both:

``````In [20]: timeit sum(1 for line in open('Charts.ipynb'))
100000 loops, best of 3: 9.79 µs per loop

In [21]: timeit len(open('Charts.ipynb').read().splitlines())
100000 loops, best of 3: 12 µs per loop
``````

I got a small (4-8%) improvement with this version which reuses a constant buffer, so it should avoid any memory or GC overhead:

``````lines = 0
buffer = bytearray(2048)
with open(filename) as f:
while f.readinto(buffer) > 0:
lines += buffer.count('\n')
``````

You can play around with the buffer size and maybe see a little improvement.

• Nice. To account for files that don't end in \n, add 1 outside of loop if buffer and buffer[-1]!='\n' Commented Nov 14, 2013 at 18:37
• A bug: buffer in the last round might not be clean.
– Jay
Commented Nov 29, 2014 at 5:07
• what if in between buffers one portion ends with \ and the other portion starts with n? that will miss one new line in there, I would sudgest to variables to store the end and the start of each chunk, but that might add more time to the script =( Commented Dec 19, 2018 at 15:47
• What file size? And other context, like the underlying hardware (disk type and speed. RAM, incl. speed. L1, L2, and L3 cache sizes. Etc.) Commented Nov 2, 2023 at 14:17

As for me this variant will be the fastest:

``````#!/usr/bin/env python

def main():
f = open('filename')
lines = 0
buf_size = 1024 * 1024
read_f = f.read # loop optimization

buf = read_f(buf_size)
while buf:
lines += buf.count('\n')
buf = read_f(buf_size)

print lines

if __name__ == '__main__':
main()
``````

reasons: buffering faster than reading line by line and `string.count` is also very fast

• But is it? At least on OSX/python2.5 the OP's version is still about 10% faster according to timeit.py.
– dF.
Commented May 10, 2009 at 11:47
• What if the last line does not end in '\n'?
– tzot
Commented May 11, 2009 at 13:21
• I don't know how you tested it, dF, but on my machine it's ~2.5 times slower than any other option. Commented May 11, 2009 at 16:25
• You state that it will be the fastest and then state that you haven't tested it. Not very scientific eh? :) Commented May 11, 2009 at 18:37
• See solution and stats provided by Ryan Ginstrom answer below. Also check out JF Sebastian's comment and link on the same answer. Commented Mar 19, 2017 at 5:46

This code is shorter and clearer. It's probably the best way:

``````num_lines = open('yourfile.ext').read().count('\n')
``````
• You should also close the file.
– user3672754
Commented Jan 28, 2016 at 21:54
• It will load the whole file into memory. Commented Jun 2, 2018 at 18:42

Just to complete the methods in previous answers, I tried a variant with the fileinput module:

``````import fileinput as fi

def filecount(fname):
for line in fi.input(fname):
pass
return fi.lineno()
``````

And passed a 60-million-lines file to all the stated methods in previous answers:

``````mapcount:    6.13
simplecount: 4.59
opcount:     4.43
filecount:  43.3
bufcount:    0.171
``````

It's a little surprise to me that fileinput is that bad and scales far worse than all the other methods...

I have modified the buffer case like this:

``````def CountLines(filename):
f = open(filename)
try:
lines = 1
buf_size = 1024 * 1024
read_f = f.read # loop optimization
buf = read_f(buf_size)

# Empty file
if not buf:
return 0

while buf:
lines += buf.count('\n')
buf = read_f(buf_size)

return lines
finally:
f.close()
``````

Now also empty files and the last line (without \n) are counted.

• Maybe also explain (or add in comment in the code) what you changed and what for ;). Might give people some more inside in your code much easier (rather than "parsing" the code in the brain). Commented Nov 6, 2012 at 0:50
• The loop optimization I think allows Python to do a local variable lookup at read_f, python.org/doc/essays/list2str Commented Apr 3, 2015 at 15:39

There are already so many answers with great timing comparison, but I believe they are just looking at number of lines to measure performance (e.g., the great graph from Nico Schlömer).

To be accurate while measuring performance, we should look at:

• the number of lines
• the average size of the lines
• ... the resulting total size of the file (which might impact memory)

First of all, the function of the OP (with a `for`) and the function `sum(1 for line in f)` are not performing that well...

Good contenders are with `mmap` or `buffer`.

To summarize: based on my analysis (Python 3.9 on Windows with SSD):

1. For big files with relatively short lines (within 100 characters): use function with a buffer `buf_count_newlines_gen`

``````def buf_count_newlines_gen(fname: str) -> int:
"""Count the number of lines in a file"""
def _make_gen(reader):
b = reader(1024 * 1024)
while b:
yield b
b = reader(1024 * 1024)

with open(fname, "rb") as f:
count = sum(buf.count(b"\n") for buf in _make_gen(f.raw.read))
return count

``````
2. For files with potentially longer lines (up to 2000 characters), disregarding the number of lines: use function with mmap: `count_nb_lines_mmap`

``````def count_nb_lines_mmap(file: Path) -> int:
"""Count the number of lines in a file"""
with open(file, mode="rb") as f:
mm = mmap.mmap(f.fileno(), 0, access=mmap.ACCESS_READ)
nb_lines = 0
while mm.readline():
nb_lines += 1
mm.close()
return nb_lines
``````
3. For a short code with very good performance (especially for files of size up to medium size):

``````def itercount(filename: str) -> int:
"""Count the number of lines in a file"""
with open(filename, 'rb') as f:
return sum(1 for _ in f)
``````

Here is a summary of the different metrics (average time with `timeit` on 7 runs with 10 loops each):

Function Small file, short lines Small file, long lines Big file, short lines Big file, long lines Bigger file, short lines
... size ... 0.04 MB 1.16 MB 318 MB 17 MB 328 MB
... nb lines ... 915 lines < 100 chars 915 lines < 2000 chars 389000 lines < 100 chars 389,000 lines < 2000 chars 9.8 millions lines < 100 chars
`count_nb_lines_blocks` 0.183 ms 1.718 ms 36.799 ms 415.393 ms 517.920 ms
`count_nb_lines_mmap` 0.185 ms 0.582 ms 44.801 ms 185.461 ms 691.637 ms
`buf_count_newlines_gen` 0.665 ms 1.032 ms 15.620 ms 213.458 ms 318.939 ms
`itercount` 0.135 ms 0.817 ms 31.292 ms 223.120 ms 628.760 ms

Note: I have also compared `count_nb_lines_mmap` and `buf_count_newlines_gen` on a file of 8 GB, with 9.7 million lines of more than 800 characters. We got an average of 5.39 seconds for `buf_count_newlines_gen` vs. 4.2 seconds for `count_nb_lines_mmap`, so this latter function seems indeed better for files with longer lines.

Here is the code I have used:

``````import mmap
from pathlib import Path

def count_nb_lines_blocks(file: Path) -> int:
"""Count the number of lines in a file"""

def blocks(files, size=65536):
while True:
b = files.read(size)
if not b:
break
yield b

with open(file, encoding="utf-8", errors="ignore") as f:
return sum(bl.count("\n") for bl in blocks(f))

def count_nb_lines_mmap(file: Path) -> int:
"""Count the number of lines in a file"""
with open(file, mode="rb") as f:
mm = mmap.mmap(f.fileno(), 0, access=mmap.ACCESS_READ)
nb_lines = 0
while mm.readline():
nb_lines += 1
mm.close()
return nb_lines

def count_nb_lines_sum(file: Path) -> int:
"""Count the number of lines in a file"""
with open(file, "r", encoding="utf-8", errors="ignore") as f:
return sum(1 for line in f)

def count_nb_lines_for(file: Path) -> int:
"""Count the number of lines in a file"""
i = 0
with open(file) as f:
for i, _ in enumerate(f, start=1):
pass
return i

def buf_count_newlines_gen(fname: str) -> int:
"""Count the number of lines in a file"""
def _make_gen(reader):
b = reader(1024 * 1024)
while b:
yield b
b = reader(1024 * 1024)

with open(fname, "rb") as f:
count = sum(buf.count(b"\n") for buf in _make_gen(f.raw.read))
return count

def itercount(filename: str) -> int:
"""Count the number of lines in a file"""
with open(filename, 'rbU') as f:
return sum(1 for _ in f)

files = [small_file, big_file, small_file_shorter, big_file_shorter, small_file_shorter_sim_size, big_file_shorter_sim_size]
for file in files:
print(f"File: {file.name} (size: {file.stat().st_size / 1024 ** 2:.2f} MB)")
for func in [
count_nb_lines_blocks,
count_nb_lines_mmap,
count_nb_lines_sum,
count_nb_lines_for,
buf_count_newlines_gen,
itercount,
]:
result = func(file)
time = Timer(lambda: func(file)).repeat(7, 10)
print(f" * {func.__name__}: {result} lines in {mean(time) / 10 * 1000:.3f} ms")
print()
``````
``````File: small_file.ndjson (size: 1.16 MB)
* count_nb_lines_blocks: 915 lines in 1.718 ms
* count_nb_lines_mmap: 915 lines in 0.582 ms
* count_nb_lines_sum: 915 lines in 1.993 ms
* count_nb_lines_for: 915 lines in 3.876 ms
* buf_count_newlines_gen: 915 lines in 1.032 ms
* itercount: 915 lines in 0.817 ms

File: big_file.ndjson (size: 317.99 MB)
* count_nb_lines_blocks: 389000 lines in 415.393 ms
* count_nb_lines_mmap: 389000 lines in 185.461 ms
* count_nb_lines_sum: 389000 lines in 485.370 ms
* count_nb_lines_for: 389000 lines in 967.075 ms
* buf_count_newlines_gen: 389000 lines in 213.458 ms
* itercount: 389000 lines in 223.120 ms

File: small_file__shorter.ndjson (size: 0.04 MB)
* count_nb_lines_blocks: 915 lines in 0.183 ms
* count_nb_lines_mmap: 915 lines in 0.185 ms
* count_nb_lines_sum: 915 lines in 0.251 ms
* count_nb_lines_for: 915 lines in 0.244 ms
* buf_count_newlines_gen: 915 lines in 0.665 ms
* itercount: 915 lines in 0.135 ms

File: big_file__shorter.ndjson (size: 17.42 MB)
* count_nb_lines_blocks: 389000 lines in 36.799 ms
* count_nb_lines_mmap: 389000 lines in 44.801 ms
* count_nb_lines_sum: 389000 lines in 59.068 ms
* count_nb_lines_for: 389000 lines in 81.387 ms
* buf_count_newlines_gen: 389000 lines in 15.620 ms
* itercount: 389000 lines in 31.292 ms

File: small_file__shorter_sim_size.ndjson (size: 1.21 MB)
* count_nb_lines_blocks: 36457 lines in 1.920 ms
* count_nb_lines_mmap: 36457 lines in 2.615 ms
* count_nb_lines_sum: 36457 lines in 3.993 ms
* count_nb_lines_for: 36457 lines in 6.011 ms
* buf_count_newlines_gen: 36457 lines in 1.363 ms
* itercount: 36457 lines in 2.147 ms

File: big_file__shorter_sim_size.ndjson (size: 328.19 MB)
* count_nb_lines_blocks: 9834248 lines in 517.920 ms
* count_nb_lines_mmap: 9834248 lines in 691.637 ms
* count_nb_lines_sum: 9834248 lines in 1109.669 ms
* count_nb_lines_for: 9834248 lines in 1683.859 ms
* buf_count_newlines_gen: 9834248 lines in 318.939 ms
* itercount: 9834248 lines in 628.760 ms
``````
• Nice comparison BUT `Big file, long lines` with a `17mb` size is not that big !! Commented Feb 1 at 19:06
• @Enissay. It's not very big indeed, but still 389,000 lines so no short :) I did some tests on 8 GB text files: this was big ;) Commented Feb 4 at 7:43

If one wants to get the line count cheaply in Python in Linux, I recommend this method:

``````import os
print os.popen("wc -l file_path").readline().split()[0]
``````

file_path can be both abstract file path or relative path. Hope this may help.

This is a meta-comment on some of the other answers.

1. The line-reading and buffered `\n`-counting techniques won't return the same answer for every file, because some text files have no newline at the end of the last line. You can work around this by checking the last byte of the last nonempty buffer and adding 1 if it's not `b'\n'`.

2. In Python 3, opening the file in text mode and in binary mode can yield different results, because text mode by default recognizes CR, LF, and CRLF as line endings (converting them all to `'\n'`), while in binary mode only LF and CRLF will be counted if you count `b'\n'`. This applies whether you read by lines or into a fixed-size buffer. The classic Mac OS used CR as a line ending; I don't know how common those files are these days.

3. The buffer-reading approach uses a bounded amount of RAM independent of file size, while the line-reading approach could read the entire file into RAM at once in the worst case (especially if the file uses CR line endings). In the worst case it may use substantially more RAM than the file size, because of overhead from dynamic resizing of the line buffer and (if you opened in text mode) Unicode decoding and storage.

4. You can improve the memory usage, and probably the speed, of the buffered approach by pre-allocating a bytearray and using `readinto` instead of `read`. One of the existing answers (with few votes) does this, but it's buggy (it double-counts some bytes).

5. The top buffer-reading answer uses a large buffer (1 MiB). Using a smaller buffer can actually be faster because of OS readahead. If you read 32K or 64K at a time, the OS will probably start reading the next 32K/64K into the cache before you ask for it, and each trip to the kernel will return almost immediately. If you read 1 MiB at a time, the OS is unlikely to speculatively read a whole megabyte. It may preread a smaller amount but you will still spend a significant amount of time sitting in the kernel waiting for the disk to return the rest of the data.

There are a lot of answers already, but unfortunately most of them are just tiny economies on a barely optimizable problem...

I worked on several projects where line count was the core function of the software, and working as fast as possible with a huge number of files was of paramount importance.

The main bottleneck with line count is I/O access, as you need to read each line in order to detect the line return character, there is simply no way around. The second potential bottleneck is memory management: the more you load at once, the faster you can process, but this bottleneck is negligible compared to the first.

Hence, there are three major ways to reduce the processing time of a line count function, apart from tiny optimizations such as disabling GC collection and other micro-managing tricks:

1. Hardware solution: the major and most obvious way is non-programmatic: buy a very fast SSD/flash hard drive. By far, this is how you can get the biggest speed boosts.

2. Data preprocessing and lines parallelization: if you generate or can modify how the files you process are generated, or if it's acceptable that you can preprocess them. First convert the line return to Unix style (`\n`) as this will save 1 character compared to Windows (not a big save, but it's an easy gain), and secondly and most importantly, you can potentially write lines of fixed length. If you need variable length, you can pad smaller lines if the length variability is not that big. This way, you can calculate instantly the number of lines from the total file size, which is much faster to access. Also, by having fixed length lines, not only can you generally pre-allocate memory which will speed up processing, but also you can process lines in parallel! Of course, parallelization works better with a flash/SSD disk that has much faster random access I/O than HDDs.. Often, the best solution to a problem is to preprocess it so that it better fits your end purpose.

3. Disks parallelization + hardware solution: if you can buy multiple hard disks (and if possible SSD flash disks), then you can even go beyond the speed of one disk by leveraging parallelization, by storing your files in a balanced way (easiest is to balance by total size) among disks, and then read in parallel from all those disks. Then, you can expect to get a multiplier boost in proportion with the number of disks you have. If buying multiple disks is not an option for you, then parallelization likely won't help (except if your disk has multiple reading headers like some professional-grade disks, but even then the disk's internal cache memory and PCB circuitry will likely be a bottleneck and prevent you from fully using all heads in parallel, plus you have to devise a specific code for this hard drive you'll use because you need to know the exact cluster mapping so that you store your files on clusters under different heads, and so that you can read them with different heads after). Indeed, it's commonly known that sequential reading is almost always faster than random reading, and parallelization on a single disk will have a performance more similar to random reading than sequential reading (you can test your hard drive speed in both aspects using CrystalDiskMark for example).

If none of those are an option, then you can only rely on micromanaging tricks to improve by a few percents the speed of your line counting function, but don't expect anything really significant. Rather, you can expect the time you'll spend tweaking will be disproportionate compared to the returns in speed improvement you'll see.

• I don't think macOS uses two characters (only Windows). Classic Mac OS certainly didn't (just 13 (decimal) instead of 10 (decimal)). Commented Nov 2, 2023 at 15:32
``````print open('file.txt', 'r').read().count("\n") + 1
``````

## Using Numba

We can use Numba to JIT (Just in time) compile our function to machine code. `def numbacountparallel(fname)` runs 2.8x faster than `def file_len(fname)` from the question.

### Notes:

The OS had already cached the file to memory before the benchmarks were run as I don't see much disk activity on my PC. The time would be much slower when reading the file for the first time making the time advantage of using Numba insignificant.

The JIT compilation takes extra time the first time the function is called.

This would be useful if we were doing more than just counting lines.

Cython is another option.

### Conclusion

As counting lines will be I/O bound, use the def file_len(fname) from the question unless you want to do more than just count lines.

``````import timeit

from numba import jit, prange
import numpy as np

from itertools import (takewhile,repeat)

FILE = '../data/us_confirmed.csv' # 40.6MB, 371755 line file
CR = ord('\n')

# Copied from the question above. Used as a benchmark
def file_len(fname):
with open(fname) as f:
for i, l in enumerate(f):
pass
return i + 1

# Copied from another answer. Used as a benchmark
def rawincount(filename):
f = open(filename, 'rb')
bufgen = takewhile(lambda x: x, (f.read(1024*1024*10) for _ in repeat(None)))
return sum( buf.count(b'\n') for buf in bufgen )

# Single thread
@jit(nopython=True)
def numbacountsingle_chunk(bs):

c = 0
for i in range(len(bs)):
if bs[i] == CR:
c += 1

return c

def numbacountsingle(filename):
f = open(filename, "rb")
total = 0
while True:
chunk = f.read(1024*1024*10)
lines = numbacountsingle_chunk(chunk)
total += lines
if not chunk:
break

return total

# Multi thread
@jit(nopython=True, parallel=True)
def numbacountparallel_chunk(bs):

c = 0
for i in prange(len(bs)):
if bs[i] == CR:
c += 1

return c

def numbacountparallel(filename):
f = open(filename, "rb")
total = 0
while True:
chunk = f.read(1024*1024*10)
lines = numbacountparallel_chunk(np.frombuffer(chunk, dtype=np.uint8))
total += lines
if not chunk:
break

return total

print('numbacountparallel')
print(numbacountparallel(FILE)) # This allows Numba to compile and cache the function without adding to the time.
print(timeit.Timer(lambda: numbacountparallel(FILE)).timeit(number=100))

print('\nnumbacountsingle')
print(numbacountsingle(FILE))
print(timeit.Timer(lambda: numbacountsingle(FILE)).timeit(number=100))

print('\nfile_len')
print(file_len(FILE))
print(timeit.Timer(lambda: rawincount(FILE)).timeit(number=100))

print('\nrawincount')
print(rawincount(FILE))
print(timeit.Timer(lambda: rawincount(FILE)).timeit(number=100))
``````

Time in seconds for 100 calls to each function

``````numbacountparallel
371755
2.8007332000000003

numbacountsingle
371755
3.1508585999999994

file_len
371755
6.7945494

rawincount
371755
6.815438
``````

Simple methods:

1. Method 1

``````>>> f = len(open("myfile.txt").readlines())
>>> f
``````

Output:

``````430
``````
2. Method 2

``````>>> f = open("myfile.txt").read().count('\n')
>>> f
``````

Output:

``````430
``````
3. Method 3

``````num_lines = len(list(open('myfile.txt')))
``````
• In this example file is not closed. Commented Mar 26, 2019 at 9:32
• why did you give 3 options? how are they different? what are the benefits and drawbacks to each of these? Commented Oct 4, 2021 at 9:00
• Please add an explanation. Thanks in advance. Commented Nov 2, 2023 at 14:52
``````def count_text_file_lines(path):
with open(path, 'rt') as file:
line_count = sum(1 for _line in file)
return line_count
``````
• Could you please explain what is wrong with it if you think it is wrong? It worked for me. Thanks! Commented Dec 20, 2017 at 17:04
• I would be interested in why this answer was downvoted, too. It iterates over the file by lines and sums them up. I like it, it is short and to the point, what's wrong with it? Commented Mar 16, 2018 at 11:23
• I believe some people like to have at least a bit text and not pure raw code. @jciloa Just add something to explain why you use `rt` as open mode and why this implementation performs better than the one in the original question. Commented Jan 10 at 10:40

An alternative for big files is using `xreadlines():`

``````count = 0
for line in open(thefilepath).xreadlines(  ): count += 1
``````

For Python 3 please see: What substitutes xreadlines() in Python 3?

• Is it really more efficient than the initial algorithm in the question? Commented May 9, 2023 at 2:03

The result of opening a file is an iterator, which can be converted to a sequence, which has a length:

``````with open(filename) as f:
return len(list(f))
``````

This is more concise than your explicit loop, and avoids the `enumerate`.

• which means that 100 Mb file will need to be read into the memory. Commented May 10, 2009 at 11:41
• yep, good point, although I wonder about the speed (as opposed to memory) difference. It's probably possible to create an iterator that does this, but I think it would be equivalent to your solution. Commented May 10, 2009 at 11:53
• -1, it's not just the memory, but having to construct the list in memory.
– orip
Commented Sep 21, 2009 at 21:14

This could work:

``````import fileinput
import sys

counter = 0
for line in fileinput.input([sys.argv[1]]):
counter += 1

fileinput.close()
print counter
``````