I am trying to find an efficient way of parsing files that holds fixed width lines. For example, the first 20 characters represent a column, from 21:30 another one and so on.

Assuming that the line holds 100 characters, what would be an efficient way to parse a line into several components?

I could use string slicing per line, but it's a little bit ugly if the line is big. Are there any other fast methods?

11 Answers 11


Using the Python standard library's struct module would be fairly easy as well as extremely fast since it's written in C.

Here's how it could be used to do what you want. It also allows columns of characters to be skipped by specifying negative values for the number of characters in the field.

import struct

fieldwidths = (2, -10, 24)  # negative widths represent ignored padding fields
fmtstring = ' '.join('{}{}'.format(abs(fw), 'x' if fw < 0 else 's')
                        for fw in fieldwidths)
fieldstruct = struct.Struct(fmtstring)
parse = fieldstruct.unpack_from
print('fmtstring: {!r}, recsize: {} chars'.format(fmtstring, fieldstruct.size))

fields = parse(line)
print('fields: {}'.format(fields))


fmtstring: '2s 10x 24s', recsize: 36 chars
fields: ('AB', 'MNOPQRSTUVWXYZ0123456789')

The following modifications would adapt it work in Python 2 or 3 (and handle Unicode input):

import struct
import sys

fieldstruct = struct.Struct(fmtstring)
if sys.version_info[0] < 3:
    parse = fieldstruct.unpack_from
    # converts unicode input to byte string and results back to unicode string
    unpack = fieldstruct.unpack_from
    parse = lambda line: tuple(s.decode() for s in unpack(line.encode()))

Here's a way to do it with string slices, as you were considering but were concerned that it might get too ugly. The nice thing about it is, besides not being all that ugly, is that it works unchanged in both Python 2 and 3, as well as being able to handle Unicode strings. Speed-wise it is, of course, slower than the versions based the struct module, but could be sped-up slightly by removing the ability to have padding fields.

    from itertools import izip_longest  # added in Py 2.6
except ImportError:
    from itertools import zip_longest as izip_longest  # name change in Py 3.x

    from itertools import accumulate  # added in Py 3.2
except ImportError:
    def accumulate(iterable):
        'Return running totals (simplified version).'
        total = next(iterable)
        yield total
        for value in iterable:
            total += value
            yield total

def make_parser(fieldwidths):
    cuts = tuple(cut for cut in accumulate(abs(fw) for fw in fieldwidths))
    pads = tuple(fw < 0 for fw in fieldwidths) # bool values for padding fields
    flds = tuple(izip_longest(pads, (0,)+cuts, cuts))[:-1]  # ignore final one
    parse = lambda line: tuple(line[i:j] for pad, i, j in flds if not pad)
    # optional informational function attributes
    parse.size = sum(abs(fw) for fw in fieldwidths)
    parse.fmtstring = ' '.join('{}{}'.format(abs(fw), 'x' if fw < 0 else 's')
                                                for fw in fieldwidths)
    return parse

fieldwidths = (2, -10, 24)  # negative widths represent ignored padding fields
parse = make_parser(fieldwidths)
fields = parse(line)
print('format: {!r}, rec size: {} chars'.format(parse.fmtstring, parse.size))
print('fields: {}'.format(fields))


format: '2s 10x 24s', rec size: 36 chars
fields: ('AB', 'MNOPQRSTUVWXYZ0123456789')
  • +1 that's nice. In a way, I think this is similar to my approach (at least when you're getting the results), but obviously way faster. – Reiner Gerecke Feb 6 '11 at 20:15
  • 1
    How would that work with unicode? Or, a utf-8 encoded string? struct.unpack seems to operate on binary data. I can't get this working. – Reiner Gerecke Feb 6 '11 at 20:22
  • 3
    @Reiner Gerecke: The struct module is designed to operate on binary data. Files with fixed-width fields are legacy jobs which are also highly likely to pre-date UTF-8 (in mind set, if not in chronology). Bytes read from files are binary data. You don't have unicode in files. You need to decode bytes to get unicode. – John Machin Feb 6 '11 at 21:53
  • 1
    @Reiner Gerecke: Clarification: In those legacy file formats, each field is a fixed number of bytes, not a fixed number of characters. Although unlikely to be encoded in UTF-8, they can be encoded in an encoding that has a variable number of bytes per character e.g. gbk, big5, euc-jp, shift-jis, etc. If you wish to work in unicode, you can't decode the whole record at once; you need to decode each field. – John Machin Feb 6 '11 at 22:15
  • 1
    This breaks down entirely when you try to apply this for Unicode values (like in Python 3) with text outside the ASCII character set and where 'fixed width' means 'fixed number of characters', not bytes. – Martijn Pieters Nov 21 '14 at 16:06

I'm not really sure if this is efficient, but it should be readable (as opposed to do the slicing manually). I defined a function slices that gets a string and column lengths, and returns the substrings. I made it a generator, so for really long lines, it doesn't build a temporary list of substrings.

def slices(s, *args):
    position = 0
    for length in args:
        yield s[position:position + length]
        position += length


In [32]: list(slices('abcdefghijklmnopqrstuvwxyz0123456789', 2))
Out[32]: ['ab']

In [33]: list(slices('abcdefghijklmnopqrstuvwxyz0123456789', 2, 10, 50))
Out[33]: ['ab', 'cdefghijkl', 'mnopqrstuvwxyz0123456789']

In [51]: d,c,h = slices('dogcathouse', 3, 3, 5)
In [52]: d,c,h
Out[52]: ('dog', 'cat', 'house')

But I think the advantage of a generator is lost if you need all columns at once. Where one could benefit from is when you want to process columns one by one, say in a loop.

  • 2
    AFAICT, this method is slower than struct, but it is readable and easier to handle. I've done some tests using your slices function, struct module and also re module and it turns out for large files, struct is the fastest, re comes second (1.5x slower) and slices third (2x slower). There is however a small overhead using struct so your slices function can be faster on smaller files. – YeO May 14 '18 at 10:25

Two more options that are easier and prettier than already mentioned solutions:

The first is using pandas:

import pandas as pd

path = 'filename.txt'

# Using Pandas with a column specification
col_specification = [(0, 20), (21, 30), (31, 50), (51, 100)]
data = pd.read_fwf(path, colspecs=col_specification)

And the second option using numpy.loadtxt:

import numpy as np

# Using NumPy and letting it figure it out automagically
data_also = np.loadtxt(path)

It really depends on in what way you want to use your data.


The code below gives a sketch of what you might want to do if you have some serious fixed-column-width file handling to do.

"Serious" = multiple record types in each of multiple file types, records up to 1000 bytes, the layout-definer and "opposing" producer/consumer is a government department with attitude, layout changes result in unused columns, up to a million records in a file, ...

Features: Precompiles the struct formats. Ignores unwanted columns. Converts input strings to required data types (sketch omits error handling). Converts records to object instances (or dicts, or named tuples if you prefer).


import struct, datetime, io, pprint

# functions for converting input fields to usable data
cnv_text = rstrip
cnv_int = int
cnv_date_dmy = lambda s: datetime.datetime.strptime(s, "%d%m%Y") # ddmmyyyy
# etc

# field specs (field name, start pos (1-relative), len, converter func)
fieldspecs = [
    ('surname', 11, 20, cnv_text),
    ('given_names', 31, 20, cnv_text),
    ('birth_date', 51, 8, cnv_date_dmy),
    ('start_date', 71, 8, cnv_date_dmy),

fieldspecs.sort(key=lambda x: x[1]) # just in case

# build the format for struct.unpack
unpack_len = 0
unpack_fmt = ""
for fieldspec in fieldspecs:
    start = fieldspec[1] - 1
    end = start + fieldspec[2]
    if start > unpack_len:
        unpack_fmt += str(start - unpack_len) + "x"
    unpack_fmt += str(end - start) + "s"
    unpack_len = end
field_indices = range(len(fieldspecs))
print unpack_len, unpack_fmt
unpacker = struct.Struct(unpack_fmt).unpack_from

class Record(object):
    # or use named tuples

raw_data = """\
          Featherstonehaugh   Algernon Marmaduke  31121969            01012005XX

f = cStringIO.StringIO(raw_data)
headings = f.next()
for line in f:
    # The guts of this loop would of course be hidden away in a function/method
    # and could be made less ugly
    raw_fields = unpacker(line)
    r = Record()
    for x in field_indices:
        setattr(r, fieldspecs[x][0], fieldspecs[x][3](raw_fields[x]))
    print "Customer name:", r.given_names, r.surname


78 10x20s20s8s12x8s
{'birth_date': datetime.datetime(1969, 12, 31, 0, 0),
 'given_names': 'Algernon Marmaduke',
 'start_date': datetime.datetime(2005, 1, 1, 0, 0),
 'surname': 'Featherstonehaugh'}
Customer name: Algernon Marmaduke Featherstonehaugh
  • How would one update this code to parse records greater than 1000 bytes? I'm running into this error: struct.error: unpack_from requires a buffer of at least 1157 bytes – chris__allen Apr 4 '18 at 20:20
> str = '1234567890'
> w = [0,2,5,7,10]
> [ str[ w[i-1] : w[i] ] for i in range(1,len(w)) ]
['12', '345', '67', '890']

This is how I solved with a dictionary that contains where fields start and end. Giving start and end points helped me to manage changes at the length of the column also.

# fixed length
#      '---------- ------- ----------- -----------'
line = '20.06.2019 myname  active      mydevice   '
SLICES = {'date_start': 0,
         'date_end': 10,
         'name_start': 11,
         'name_end': 18,
         'status_start': 19,
         'status_end': 30,
         'device_start': 31,
         'device_end': 42}

def get_values_as_dict(line, SLICES):
    values = {}
    key_list = {key.split("_")[0] for key in SLICES.keys()}
    for key in key_list:
       values[key] = line[SLICES[key+"_start"]:SLICES[key+"_end"]].strip()
    return values

>>> print (get_values_as_dict(line,SLICES))
{'status': 'active', 'name': 'myname', 'date': '20.06.2019', 'device': 'mydevice'}

Here's a simple module for Python 3, based on John Machin's answer - adapt as needed :)


Parse and iterate through a fixedwidth text file, returning record objects.

Adapted from https://stackoverflow.com/a/4916375/243392


    import fixedwidth, pprint

    # define the fixed width fields we want
    # fieldspecs is a list of [name, description, start, width, type] arrays.
    fieldspecs = [
        ["FILEID", "File Identification", 1, 6, "A/N"],
        ["STUSAB", "State/U.S. Abbreviation (USPS)", 7, 2, "A"],
        ["SUMLEV", "Summary Level", 9, 3, "A/N"],
        ["LOGRECNO", "Logical Record Number", 19, 7, "N"],
        ["POP100", "Population Count (100%)", 30, 9, "N"],

    # define the fieldtype conversion functions
    fieldtype_fns = {
        'A': str.rstrip,
        'A/N': str.rstrip,
        'N': int,

    # iterate over record objects in the file
    with open(f, 'rb'):
        for record in fixedwidth.reader(f, fieldspecs, fieldtype_fns):

    # output:
    {'FILEID': 'SF1ST', 'LOGRECNO': 2, 'POP100': 1, 'STUSAB': 'TX', 'SUMLEV': '040'}
    {'FILEID': 'SF1ST', 'LOGRECNO': 3, 'POP100': 2, 'STUSAB': 'TX', 'SUMLEV': '040'}    


import struct, io

# fieldspec columns
iName, iDescription, iStart, iWidth, iType = range(5)

def get_struct_unpacker(fieldspecs):
    Build the format string for struct.unpack to use, based on the fieldspecs.
    fieldspecs is a list of [name, description, start, width, type] arrays.
    Returns a string like "6s2s3s7x7s4x9s".
    unpack_len = 0
    unpack_fmt = ""
    for fieldspec in fieldspecs:
        start = fieldspec[iStart] - 1
        end = start + fieldspec[iWidth]
        if start > unpack_len:
            unpack_fmt += str(start - unpack_len) + "x"
        unpack_fmt += str(end - start) + "s"
        unpack_len = end
    struct_unpacker = struct.Struct(unpack_fmt).unpack_from
    return struct_unpacker

class Record(object):
    # or use named tuples

def reader(f, fieldspecs, fieldtype_fns):
    Wrap a fixedwidth file and return records according to the given fieldspecs.
    fieldspecs is a list of [name, description, start, width, type] arrays.
    fieldtype_fns is a dictionary of functions used to transform the raw string values, 
    one for each type.

    # make sure fieldspecs are sorted properly
    fieldspecs.sort(key=lambda fieldspec: fieldspec[iStart])

    struct_unpacker = get_struct_unpacker(fieldspecs)

    field_indices = range(len(fieldspecs))

    for line in f:
        raw_fields = struct_unpacker(line) # split line into field values
        record = Record()
        for i in field_indices:
            fieldspec = fieldspecs[i]
            fieldname = fieldspec[iName]
            s = raw_fields[i].decode() # convert raw bytes to a string
            fn = fieldtype_fns[fieldspec[iType]] # get conversion function
            value = fn(s) # convert string to value (eg to an int)
            setattr(record, fieldname, value)
        yield record

if __name__=='__main__':

    # test module

    import pprint, io

    # define the fields we want
    # fieldspecs are [name, description, start, width, type]
    fieldspecs = [
        ["FILEID", "File Identification", 1, 6, "A/N"],
        ["STUSAB", "State/U.S. Abbreviation (USPS)", 7, 2, "A"],
        ["SUMLEV", "Summary Level", 9, 3, "A/N"],
        ["LOGRECNO", "Logical Record Number", 19, 7, "N"],
        ["POP100", "Population Count (100%)", 30, 9, "N"],

    # define a conversion function for integers
    def to_int(s):
        Convert a numeric string to an integer.
        Allows a leading ! as an indicator of missing or uncertain data.
        Returns None if no data.
            return int(s)
                return int(s[1:]) # ignore a leading !
                return None # assume has a leading ! and no value

    # define the conversion fns
    fieldtype_fns = {
        'A': str.rstrip,
        'A/N': str.rstrip,
        'N': to_int,
        # 'N': int,
        # 'D': lambda s: datetime.datetime.strptime(s, "%d%m%Y"), # ddmmyyyy
        # etc

    # define a fixedwidth sample
    sample = """\
SF1ST TX04089000  00000023748        1 
SF1ST TX04090000  00000033748!       2
SF1ST TX04091000  00000043748!        
    sample_data = sample.encode() # convert string to bytes
    file_like = io.BytesIO(sample_data) # create a file-like wrapper around bytes

    # iterate over record objects in the file
    for record in reader(file_like, fieldspecs, fieldtype_fns):
        # print(record)

Here is what NumPy uses under the hood (much much simplified, but still - this code is found in the LineSplitter class within the _iotools module):

import numpy as np

DELIMITER = (20, 10, 10, 20, 10, 10, 20)

idx = np.cumsum([0] + list(DELIMITER))
slices = [slice(i, j) for (i, j) in zip(idx[:-1], idx[1:])]

def parse(line):
    return [line[s] for s in slices]

It does not handle negative delimiters for ignoring column so it is not as versatile as struct, but it is faster.


String slicing doesn't have to be ugly as long as you keep it organized. Consider storing your field widths in a dictionary and then using the associated names to create an object:

from collections import OrderedDict

class Entry:
    def __init__(self, line):

        name2width = OrderedDict()
        name2width['foo'] = 2
        name2width['bar'] = 3
        name2width['baz'] = 2

        pos = 0
        for name, width in name2width.items():

            val = line[pos : pos + width]
            if len(val) != width:
                raise ValueError("not enough characters: \'{}\'".format(line))

            setattr(self, name, val)
            pos += width

file = "ab789yz\ncd987wx\nef555uv"

entry = []

for line in file.split('\n'):

print(entry[1].bar) # output: 987

Because my old work often handles 1 million lines of fixwidth data, I did research on this issue when I started using Python.

There are 2 types of FixedWidth

  1. ASCII FixedWidth (ascii character length = 1, double-byte encoded character length = 2)
  2. Unicode FixedWidth (ascii character & double-byte encoded character length = 1)

If the resource string is all composed of ascii characters, then ASCII FixedWidth = Unicode FixedWidth

Fortunately, string and byte are different in py3, which reduces a lot of confusion when dealing with double-byte encoded characters (e.g.gbk, big5, euc-jp, shift-jis, etc.).
For the processing of "ASCII FixedWidth", the String is usually converted to Bytes and then split.

Without importing third-party modules
totalLineCount = 1 million, lineLength = 800 byte , FixedWidthArgs=(10,25,4,....), I split the Line in about 5 ways and get the following conclusion:

  1. struct is the fastest (1x)
  2. Loop only, not pre-processing FixedWidthArgs is the slowest (5x+)
  3. slice(bytes) is faster than slice(string)
  4. The source string is the bytes test result: struct(1x) , operator.itemgetter(1.7x) , precompiled sliceObject & list comprehensions(2.8x), re.patten object (2.9x)

When dealing with large files, we often use with open ( file, "rb") as f:.
The method traverses one of the above files, about 2.4 second.
I think the appropriate handler, which processes 1 million rows of data, splits each row into 20 fields and takes less than 2.4 seconds.

I only find that stuct and itemgetter meet the requirements

ps: For normal display, I converted unicode str to bytes. If you are in a double-byte environment, you don't need to do this.

from itertools import accumulate
from operator import itemgetter

def oprt_parser(sArgs):
    sum_arg = tuple(accumulate(abs(i) for i in sArgs))
    # Negative parameter field index
    cuts = tuple(i for i,num in enumerate(sArgs) if num < 0)
    # Get slice args and Ignore fields of negative length
    ig_Args = tuple(item for i, item in enumerate(zip((0,)+sum_arg,sum_arg)) if i not in cuts)
    # Generate `operator.itemgetter` object
    oprtObj =itemgetter(*[slice(s,e) for s,e in ig_Args])
    return oprtObj

lineb = b'abcdefghijklmnopqrstuvwxyz\xb0\xa1\xb2\xbb\xb4\xd3\xb5\xc4\xb6\xee\xb7\xa2\xb8\xf6\xba\xcd0123456789'
line = lineb.decode("GBK")

# Unicode Fixed Width
fieldwidthsU = (13, -13, 4, -4, 5,-5) # Negative width fields is ignored
# ASCII Fixed Width
fieldwidths = (13, -13, 8, -8, 5,-5) # Negative width fields is ignored
# Unicode FixedWidth processing
parse = oprt_parser(fieldwidthsU)
fields = parse(line)
print('Unicode FixedWidth','fields: {}'.format(tuple(map(lambda s: s.encode("GBK"), fields))))
# ASCII FixedWidth processing
parse = oprt_parser(fieldwidths)
fields = parse(lineb)
print('ASCII FixedWidth','fields: {}'.format(fields))
fieldwidths = (2, -10, 24)
parse = oprt_parser(fieldwidths)
fields = parse(line)
print(f"fields: {fields}")


Unicode FixedWidth fields: (b'abcdefghijklm', b'\xb0\xa1\xb2\xbb\xb4\xd3\xb5\xc4', b'01234')
ASCII FixedWidth fields: (b'abcdefghijklm', b'\xb0\xa1\xb2\xbb\xb4\xd3\xb5\xc4', b'01234')
fields: ('AB', 'MNOPQRSTUVWXYZ0123456789')

oprt_parser is 4x make_parser(list comprehensions + slice)

During the research, it was found that when the cpu speed is faster, it seems that the efficiency of the re method increases faster.
Since I don't have more and better computers to test, provide my test code, if anyone is interested, you can test it with a faster computer.

Run Environment:

  • os:win10
  • python: 3.7.2
  • CPU:amd athlon x3 450
  • HD:seagate 1T
import timeit
import time
import re
from itertools import accumulate
from operator import itemgetter

def eff2(stmt,onlyNum= False,showResult=False):
    '''test function'''
    if onlyNum:
        rl = timeit.repeat(stmt=stmt,repeat=roundI,number=timesI,globals=globals())
        avg = sum(rl) / len(rl)
        return f"{avg * (10 ** 6)/timesI:0.4f}"
        rl = timeit.repeat(stmt=stmt,repeat=10,number=1000,globals=globals())
        avg = sum(rl) / len(rl)
        print(f"\tquick avg = {avg * (10 ** 6)/1000:0.4f} s/million")
        if showResult:
            print(f"\t  Result = {eval(stmt)}\n\t  timelist = {rl}\n")

def upDouble(argList,argRate):
    return [c*argRate for c in argList]

tbStr = "000000001111000002222真2233333333000000004444444QAZ55555555000000006666666ABC这些事中文字abcdefghijk"
tbBytes = tbStr.encode("GBK")
a20 = (4,4,2,2,2,3,2,2, 2 ,2,8,8,7,3,8,8,7,3, 12 ,11)
a20U = (4,4,2,2,2,3,2,2, 1 ,2,8,8,7,3,8,8,7,3, 6 ,11)
Slng = 800
rateS = Slng // 100

tStr = "".join(upDouble(tbStr , rateS))
tBytes = tStr.encode("GBK")
spltArgs = upDouble( a20 , rateS)
spltArgsU = upDouble( a20U , rateS)

testList = []
timesI = 100000
roundI = 5
print(f"test round = {roundI} timesI = {timesI} sourceLng = {len(tStr)} argFieldCount = {len(spltArgs)}")

print(f"pure str \n{''.ljust(60,'-')}")
# ==========================================
def str_parser(sArgs):
    def prsr(oStr):
        r = []
        r_ap = r.append
        for lng in sArgs:
            end = stt + lng 
            stt = end 
        return tuple(r)
    return prsr

Str_P = str_parser(spltArgsU)
# eff2("Str_P(tStr)")

print(f"pure bytes \n{''.ljust(60,'-')}")
# ==========================================
def byte_parser(sArgs):
    def prsr(oBytes):
        r, stt = [], 0
        r_ap = r.append
        for lng in sArgs:
            end = stt + lng
            stt = end
        return r
    return prsr
Byte_P = byte_parser(spltArgs)
# eff2("Byte_P(tBytes)")

# re,bytes
print(f"re compile object \n{''.ljust(60,'-')}")
# ==========================================

def rebc_parser(sArgs,otype="b"):
    re_Args = "".join([f"(.{{{n}}})" for n in sArgs])
    if otype == "b":
        rebc_Args = re.compile(re_Args.encode("GBK"))
        rebc_Args = re.compile(re_Args)
    def prsr(oBS):
        return rebc_Args.match(oBS).groups()
    return prsr
Rebc_P = rebc_parser(spltArgs)
# eff2("Rebc_P(tBytes)")

Rebc_Ps = rebc_parser(spltArgsU,"s")
# eff2("Rebc_Ps(tStr)")

print(f"struct \n{''.ljust(60,'-')}")
# ==========================================

import struct
def struct_parser(sArgs):
    struct_Args = " ".join(map(lambda x: str(x) + "s", sArgs))
    def prsr(oBytes):
        return struct.unpack(struct_Args, oBytes)
    return prsr
Struct_P = struct_parser(spltArgs)
# eff2("Struct_P(tBytes)")

print(f"List Comprehensions + slice \n{''.ljust(60,'-')}")
# ==========================================
import itertools
def slice_parser(sArgs):
    tl = tuple(itertools.accumulate(sArgs))
    slice_Args = tuple(zip((0,)+tl,tl))
    def prsr(oBytes):
        return [oBytes[s:e] for s, e in slice_Args]
    return prsr
Slice_P = slice_parser(spltArgs)
# eff2("Slice_P(tBytes)")

def sliceObj_parser(sArgs):
    tl = tuple(itertools.accumulate(sArgs))
    tl2 = tuple(zip((0,)+tl,tl))
    sliceObj_Args = tuple(slice(s,e) for s,e in tl2)
    def prsr(oBytes):
        return [oBytes[so] for so in sliceObj_Args]
    return prsr
SliceObj_P = sliceObj_parser(spltArgs)
# eff2("SliceObj_P(tBytes)")

SliceObj_Ps = sliceObj_parser(spltArgsU)
# eff2("SliceObj_Ps(tStr)")

print(f"operator.itemgetter + slice object \n{''.ljust(60,'-')}")
# ==========================================

def oprt_parser(sArgs):
    sum_arg = tuple(accumulate(abs(i) for i in sArgs))
    cuts = tuple(i for i,num in enumerate(sArgs) if num < 0)
    ig_Args = tuple(item for i,item in enumerate(zip((0,)+sum_arg,sum_arg)) if i not in cuts)
    oprtObj =itemgetter(*[slice(s,e) for s,e in ig_Args])
    return oprtObj

Oprt_P = oprt_parser(spltArgs)
# eff2("Oprt_P(tBytes)")

Oprt_Ps = oprt_parser(spltArgsU)
# eff2("Oprt_Ps(tStr)")

print("|".join([s.split("(")[0].center(11," ") for s in testList]))
print("|".join(["".center(11,"-") for s in testList]))
print("|".join([eff2(s,True).rjust(11," ") for s in testList]))


Test round = 5 timesI = 100000 sourceLng = 744 argFieldCount = 20
   Str_P | Byte_P | Rebc_P | Rebc_Ps | Struct_P | Slice_P | SliceObj_P|SliceObj_Ps| Oprt_P | Oprt_Ps
-----------|-----------|-----------|-----------|-- ---------|-----------|-----------|-----------|---- -------|-----------
     9.6315| 7.5952| 4.4187| 5.6867| 1.5123| 5.2915| 4.2673| 5.7121| 2.4713| 3.9051
  • @MartijnPieters More efficient function – notback Feb 20 '19 at 11:59

I like to process text files containing fixed width fields using regular expressions. More specifically, using named capture groups. It's fast, does not require importing large libraries and is quite descriptive and convenient (in my opinion).

I also like the fact that the named capture groups are basically auto-documenting the data format, acting as a sort of data specification, since each capture group can be written to define each fields' name, data type and length.

Here's simple example...

import re

data = [

record_regex = (

records = []

for line in data:
    match = re.match(record_regex, line)
    if match:


...that yields a convenient dictionary of each record:

    {'firstnumbers': '1234', 'lastnumber': '5', 'middletext': 'ABCDEFGHIJ'},
    {'firstnumbers': '6789', 'lastnumber': '0', 'middletext': 'KLMNOPQRST'}

Helpful tools, like the online regex tester and debugger, are available if you are not familiar (or comfortable) with Python regular expressions or named capture groups.

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