I want python to read to the EOF so I can get an appropriate hash, whether it is sha1 or md5. Please help. Here is what I have so far:

import hashlib

inputFile = raw_input("Enter the name of the file:")
openedFile = open(inputFile)
readFile = openedFile.read()

md5Hash = hashlib.md5(readFile)
md5Hashed = md5Hash.hexdigest()

sha1Hash = hashlib.sha1(readFile)
sha1Hashed = sha1Hash.hexdigest()

print "File Name: %s" % inputFile
print "MD5: %r" % md5Hashed
print "SHA1: %r" % sha1Hashed
  • 6
    and what is the problem? – isedev Feb 27 '14 at 2:54
  • 1
    I want it to be able to hash a file. I need it to read until the EOF, whatever the file size may be. – user3358300 Feb 27 '14 at 3:00
  • 3
    that is exactly what file.read() does - read the entire file. – isedev Feb 27 '14 at 3:01
  • The documentation for the read() method says? – Ignacio Vazquez-Abrams Feb 27 '14 at 3:01
  • You should go through "what is hashing?". – Sharif Mamun Feb 27 '14 at 3:04

TL;DR use buffers to not use tons of memory.

We get to the crux of your problem, I believe, when we consider the memory implications of working with very large files. We don't want this bad boy to churn through 2 gigs of ram for a 2 gigabyte file so, as pasztorpisti points out, we gotta deal with those bigger files in chunks!

import sys
import hashlib

# BUF_SIZE is totally arbitrary, change for your app!
BUF_SIZE = 65536  # lets read stuff in 64kb chunks!

md5 = hashlib.md5()
sha1 = hashlib.sha1()

with open(sys.argv[1], 'rb') as f:
    while True:
        data = f.read(BUF_SIZE)
        if not data:

print("MD5: {0}".format(md5.hexdigest()))
print("SHA1: {0}".format(sha1.hexdigest()))

What we've done is we're updating our hashes of this bad boy in 64kb chunks as we go along with hashlib's handy dandy update method. This way we use a lot less memory than the 2gb it would take to hash the guy all at once!

You can test this with:

$ mkfile 2g bigfile
$ python hashes.py bigfile
MD5: a981130cf2b7e09f4686dc273cf7187e
SHA1: 91d50642dd930e9542c39d36f0516d45f4e1af0d
$ md5 bigfile
MD5 (bigfile) = a981130cf2b7e09f4686dc273cf7187e
$ shasum bigfile
91d50642dd930e9542c39d36f0516d45f4e1af0d  bigfile

Hope that helps!

Also all of this is outlined in the linked question on the right hand side: Get MD5 hash of big files in Python


In general when writing python it helps to get into the habit of following pep-8. For example, in python variables are typically underscore separated not camelCased. But that's just style and no one really cares about those things except people who have to read bad style... which might be you reading this code years from now.

  • @ranman Hello, I couldn't get the {0}".format(sha1.hexdigest()) part. Why do we use it instead of just using sha1.hexdigest() ? – Belial Jul 8 '15 at 14:25
  • @Belial What wasn't working? I was mainly just using that to differentiate between the two hashes... – Randall Hunt Sep 11 '15 at 22:47
  • @ranman Everything is working, I just never used this and haven't seen it in the literature. "{0}".format() ... unknown to me. :) – Belial Sep 12 '15 at 11:26
  • 1
    How should I choose BUF_SIZE? – Martin Thoma Aug 8 '17 at 15:09
  • 1
    This does doesn't generate the same results as the shasum binaries. The other answer listed below (the one using memoryview) is compatible with other hashing tools. – Robert Hafner Jan 31 '19 at 18:53

For the correct and efficient computation of the hash value of a file (in Python 3):

  • Open the file in binary mode (i.e. add 'b' to the filemode) to avoid character encoding and line-ending conversion issues.
  • Don't read the complete file into memory, since that is a waste of memory. Instead, sequentially read it block by block and update the hash for each block.
  • Eliminate double buffering, i.e. don't use buffered IO, because we already use an optimal block size.
  • Use readinto() to avoid buffer churning.


import hashlib

def sha256sum(filename):
    h  = hashlib.sha256()
    b  = bytearray(128*1024)
    mv = memoryview(b)
    with open(filename, 'rb', buffering=0) as f:
        for n in iter(lambda : f.readinto(mv), 0):
    return h.hexdigest()
  • 2
    How do you know what is an optimal block size? – Mitar Mar 2 '18 at 5:45
  • 1
    @Mitar, a lower bound is the maximum of the physical block (traditionally 512 bytes or 4KiB with newer disks) and the systems page size (4KiB on many system, other common choices: 8KiB and 64 KiB). Then you basically do some benchmarking and/or look at published benchmark results and related work (e.g. check what current rsync/GNU cp/... use). – maxschlepzig Mar 2 '18 at 20:31
  • Would resource.getpagesize be of any use here, if we wanted to try to optimize it somewhat dynamically? And what about mmap? – jpmc26 May 14 '18 at 17:40
  • @jpmc26, getpagesize() isn't that useful here - common values are 4 KiB or 8 KiB, something in that range, i.e. something much smaller than the 128 KiB - 128 KiB is generally a good choice. mmap doesn't help much in our use case as we sequentially read the complete file from front to back. mmap has advantages when the access pattern is more random-access like, if pages are accessed more than once and/or if it the mmap simplifies read buffer management. – maxschlepzig May 15 '18 at 8:13
  • 4
    I benchmarked both the solution of (1) @Randall Hunt and (2) yours (in this order, is important due to file cache) with a file of around 116GB and sha1sum algorithm. Solution 1 was modified in order to use a buffer of 20 * 4096 (PAGE_SIZE) and set buffering parameter to 0. Solution 2 only algorithm was modified (sha256 -> sha1). Result: (1) 3m37.137s (2) 3m30.003s . The native sha1sum in binary mode: 3m31.395s – bioinfornatics Jul 19 '19 at 9:55

I would propose simply:

def get_digest(file_path):
    h = hashlib.sha256()

    with open(file_path, 'rb') as file:
        while True:
            # Reading is buffered, so we can read smaller chunks.
            chunk = file.read(h.block_size)
            if not chunk:

    return h.hexdigest()

All other answers here seem to complicate too much. Python is already buffering when reading (in ideal manner, or you configure that buffering if you have more information about underlying storage) and so it is better to read in chunks the hash function finds ideal which makes it faster or at lest less CPU intensive to compute the hash function. So instead of disabling buffering and trying to emulate it yourself, you use Python buffering and control what you should be controlling: what the consumer of your data finds ideal, hash block size.

  • Perfect answer, but it would be nice, if you would back your statements with the related doc: Python3 - open() and Python2 - open(). Even mind the diff between both, Python3's approach is more sophisticated. Nevertheless, I really appreciated the consumer-centric perspective! – Murmel Sep 19 '19 at 9:28
  • 1
    hash.block_size is documented just as the 'internal block size of the hash algorithm'. Hashlib doesn't find it ideal. Nothing in the package documentation suggests that update() prefers hash.block_size sized input. It doesn't use less CPU if you call it like that. Your file.read() call leads to many unnecessary object creations and superfluous copies from the file buffer to your new chunk bytes object. – maxschlepzig Sep 19 '19 at 17:15
  • Hashes update their state in block_size chunks. If you are not providing them in those chunks, they have to buffer and wait for enough data to appear, or split given data into chunks internally. So, you can just handle that on the outside and then you simplify what happens internally. I find this ideal. See for example: stackoverflow.com/a/51335622/252025 – Mitar Sep 19 '19 at 21:04
  • 1
    The block_size is much smaller than any useful read size. Also, any useful block and read sizes are powers of two. Thus, the read size is divisible by the block size for all reads except possibly the last one. For example, the sha256 block size is 64 bytes. That means that update() is able to directly process the input without any buffering up to any multiple of block_size. Thus, only if the last read isn't divisible by the block size it has to buffer up to 63 bytes, once. Hence, your last comment is incorrect and doesn't support the claims you are making in your answer. – maxschlepzig Nov 5 '19 at 20:43
  • The point is that one does not have to optimize buffering because it is already done by Python when reading. So you just have to decide on the amount of looping you want to do when hashing over that existing buffer. – Mitar Nov 6 '19 at 4:44

I have programmed a module wich is able to hash big files with different algorithms.

pip3 install py_essentials

Use the module like this:

from py_essentials import hashing as hs
hash = hs.fileChecksum("path/to/the/file.txt", "sha256")
  • 1
    Is it cross-platform (Linux + Win)? Is it working with Python3? Also is it still maintained? – Basj Nov 7 '20 at 17:28
  • Yes it is cross platform and will still work. Also the other stuff in the package works fine. But I will no longer maintain this package of personal experiments, because it was just a learning for me as a developer. – phyyyl Nov 14 '20 at 22:22

Here is a Python 3, POSIX solution (not Windows!) that uses mmap to map the object into memory.

import hashlib
import mmap

def sha256sum(filename):
    h  = hashlib.sha256()
    with open(filename, 'rb') as f:
        with mmap.mmap(f.fileno(), 0, prot=mmap.PROT_READ) as mm:
    return h.hexdigest()
  • Naive question ... what is the advantage of using mmap in this scenario? – Jonathan B. Sep 28 '20 at 17:42
  • 1
    @JonathanB. most methods needlessly create bytes objects in memory, and call read too many or too little times. This will map the file directly into the virtual memory, and hash it from there - the operating system can map the file contents directly from the buffer cache into the reading process. This means this could be faster by a significant factor over this one – Antti Haapala Sep 28 '20 at 18:15
  • @JonathanB. I did the test and the difference is not that significant in this case, we're talking about ~15 % over the naive method. – Antti Haapala Sep 28 '20 at 18:26
  • 2
    I benchmarked this vs the read chunk by chunk method. This method took 3GB memory for hashing a 3GB file while maxschlepzig's answer took 12MB. They both roughly took the same amount of time on my Ubuntu box. – Seperman Mar 17 at 18:40
  • @Seperman you're measuring the RAM usage incorrectly. The memory is still available, the pages are mapped from the buffer cache. – Antti Haapala Mar 17 at 19:09
import hashlib
user = input("Enter ")
h = hashlib.md5(user.encode())
h2 = h.hexdigest()
with open("encrypted.txt","w") as e:

with open("encrypted.txt","r") as e:
    p = e.readline().strip()
  • 2
    You are basically doing echo $USER_INPUT | md5sum > encrypted.txt && cat encrypted.txt which does not deal with hashing of files, especially not with big ones. – Murmel Sep 19 '19 at 9:35
  • 1
    hashing != encrypting – bugmenot123 Dec 22 '19 at 14:05

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