211

I have the following piece of Base64 encoded data, and I want to use the Python Base64 module to extract information from it. It seems that module does not work. How can I make it work?

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
25
  • 2
    Can you expand on the problem you're having? I just used base64.b64decode to decode it fine... Aug 12 '10 at 17:57
  • 1
    what is your method please? Did you use base64.b64decode(string) ?
    – ladyfafa
    Aug 12 '10 at 17:58
  • 1
    I think the result should be a series of coordinates, such as (x, y, z), with different values
    – ladyfafa
    Aug 12 '10 at 18:06
  • 9
    @ladyfafa, I don't know what to tell you. You were given a piece of data that was encoded in base64, and you know how to decode the string to get the original data - after that, you still have to understand the format of the data in order to be able to interpret it. Without giving us more information about the results, it's very difficult to tell you what to do with it. Even knowing that it's a series of coordinates isn't that helpful without knowing (for example) if they're 4 byte integers, or floats or what. Can you not get this information from the source of the data? Then we could help. Aug 12 '10 at 18:12
  • 3
    I mean where did this data come from? Did your cat type it for you? Did you convert a bitmap into a string? Did program XYZ output it?
    – Nick T
    Aug 12 '10 at 19:24
251
import base64
coded_string = '''Q5YACgA...'''
base64.b64decode(coded_string)

worked for me. At the risk of pasting an offensively-long result, I got:

>>> base64.b64decode(coded_string)
2: 'C\x96\x00\n\x00\x00\x00\x00C\x96\x00\x1b\x00\x00\x00\x00C\x96\x00-\x00\x00\x00\x00C\x96\x00?\x00\x00\x00\x00C\x96\x07M\x00\x00\x00\x00C\x96\x07_\x00\x00\x00\x00C\x96\x07p\x00\x00\x00\x00C\x96\x07\x82\x00\x00\x00\x00C\x96\x07\x94\x00\x00\x00\x00C\x96\x07\xa6Cq\xf0\x7fC\x96\x07\xb8DJ\x81\xc7C\x96\x07\xcaD\xa5\x9dtC\x96\x07\xdcD\xb6\x97\x11C\x96\x07\xeeD\x8b\x8flC\x96\x07\xffD\x03\xd4\xaaC\x96\x08\x11B\x05&\xdcC\x96\x08#\x00\x00\x00\x00C\x96\x085C\x0c\xc9\xb7C\x96\x08GCy\xc0\xebC\x96\x08YC\x81\xa4xC\x96\x08kC\x0f@\x9bC\x96\x08}\x00\x00\x00\x00C\x96\x08\x8e\x00\x00\x00\x00C\x96\x08\xa0\x00\x00\x00\x00C\x96\x08\xb2\x00\x00\x00\x00C\x96\x86\xf9\x00\x00\x00\x00C\x96\x87\x0b\x00\x00\x00\x00C\x96\x87\x1d\x00\x00\x00\x00C\x96\x87/\x00\x00\x00\x00C\x96\x87AA\x0b\xe7PC\x96\x87SCI\xf5gC\x96\x87eC\xd4J\xeaC\x96\x87wD\r\x17EC\x96\x87\x89D\x00F6C\x96\x87\x9bC\x9cg\xdeC\x96\x87\xadB\xd56\x0cC\x96\x87\xbf\x00\x00\x00\x00C\x96\x87\xd1\x00\x00\x00\x00C\x96\x87\xe3\x00\x00\x00\x00C\x96\x87\xf5\x00\x00\x00\x00C\x9cY}\x00\x00\x00\x00C\x9cY\x90\x00\x00\x00\x00C\x9cY\xa4\x00\x00\x00\x00C\x9cY\xb7\x00\x00\x00\x00C\x9cY\xcbC\x1f\xbd\xa3C\x9cY\xdeCCz{C\x9cY\xf1CD\x02\xa7C\x9cZ\x05C+\x9d\x97C\x9cZ\x18C\x03R\xe3C\x9cZ,\x00\x00\x00\x00C\x9cZ?
[stuff omitted as it exceeded SO's body length limits]
\xbb\x00\x00\x00\x00D\xc5!7\x00\x00\x00\x00D\xc5!\xb2\x00\x00\x00\x00D\xc7\x14x\x00\x00\x00\x00D\xc7\x14\xf6\x00\x00\x00\x00D\xc7\x15t\x00\x00\x00\x00D\xc7\x15\xf2\x00\x00\x00\x00D\xc7\x16pC5\x9f\xf9D\xc7\x16\xeeC[\xb5\xf5D\xc7\x17lCG\x1b;D\xc7\x17\xeaB\xe3\x0b\xa6D\xc7\x18h\x00\x00\x00\x00D\xc7\x18\xe6\x00\x00\x00\x00D\xc7\x19d\x00\x00\x00\x00D\xc7\x19\xe2\x00\x00\x00\x00D\xc7\xfe\xb4\x00\x00\x00\x00D\xc7\xff3\x00\x00\x00\x00D\xc7\xff\xb2\x00\x00\x00\x00D\xc8\x001\x00\x00\x00\x00'

What problem are you having, specifically?

2
  • 3
    I have exactlly the same process as you did, but what are the results ?
    – ladyfafa
    Aug 12 '10 at 18:01
  • This is pretty old but I think their issue was the above is it doesn't print anything. I assume print base64.b64decode(coded_string) was what they were looking for. Thanks for the simple example it helped me!
    – Cadoo
    Mar 12 '14 at 18:31
169

Python 3 (and 2)

import base64
a = 'eW91ciB0ZXh0'
base64.b64decode(a)

Python 2

A quick way to decode it without importing anything:

'eW91ciB0ZXh0'.decode('base64')

or more descriptive

>>> a = 'eW91ciB0ZXh0'
>>> a.decode('base64')
'your text'
1
  • 8
    Btw this also works for encoding >>> 'your text'.encode('base64')
    – Levite
    Feb 13 '15 at 9:53
19

I personally just use this Python code to decode Base64 strings:

print open("FILE-WITH-STRING", "rb").read().decode("base64")

So you can run it in a Bash script like this:

python -c 'print open("FILE-WITH-STRING", "rb").read().decode("base64")' > outputfile
file -i outputfile

twneale has also pointed out an even simpler solution: base64 -d

So you can use it like this:

cat "FILE WITH STRING" | base64 -d > OUTPUTFILE
#Or You Can Do This
echo "STRING" | base64 -d > OUTPUTFILE

That will save the decoded string to outputfile and then attempt to identify the file type using either the file tool or you can try TrID. The following command will decode the string into a file and then use TrID to automatically identify the file's type and add the extension.

echo "STRING" | base64 -d > OUTPUTFILE; trid -ce OUTPUTFILE
5
  • 1
    Or "cat FILE-WITH-STRING | base64 -d" > outputfile
    – twneale
    Mar 25 '13 at 13:45
  • @twneale Of course you come along and post something simple like that :) Easier to remember than my method but no need to rewrite my scripts. I'll add it to my answer.
    – japzone
    Mar 25 '13 at 14:56
  • I had no idea string.decode('base64') existed. That is so cool. Dec 12 '13 at 21:23
  • Be sure to close the file handle afterwards, your first code snippet doesn't do this and someone may use it as part of a larger application.
    – Rebs
    Sep 7 '16 at 6:27
  • On Mac OS X, use cat base64-image.txt | base64 --decode > base64-image.png
    – Mr-IDE
    Jul 10 '17 at 9:38
19

Base64 encode/decode example:

import base64

mystr = 'O João mordeu o cão!'

# Encode
mystr_encoded = base64.b64encode(mystr.encode('utf-8'))
# b'TyBKb8OjbyBtb3JkZXUgbyBjw6NvIQ=='

# Decode
mystr_encoded = base64.b64decode(mystr_encoded).decode('utf-8')
# 'O João mordeu o cão!'
1
  • 1
    This helped me in my project. Thanks @Slipstream Jul 25 at 11:20
15

Interesting if maddening puzzle...but here's the best I could get:

The data seems to repeat every 8 bytes or so.

import struct
import base64

target = \
r'''Q5YACgAAAABDlgAbAAAAAEOWAC0AAAAAQ5YAPwAAAABDlgdNAAAAAEOWB18AAAAAQ5YH 
[snip.]
ZAAAAABExxniAAAAAETH/rQAAAAARMf/MwAAAABEx/+yAAAAAETIADEAAAAA''' 

data = base64.b64decode(target)

cleaned_data = []
struct_format = ">ff"
for i in range(len(data) // 8):
   cleaned_data.append(struct.unpack_from(struct_format, data, 8*i))

That gives output like the following (a sampling of lines from the first 100 or so):

(300.00030517578125, 0.0)
(300.05975341796875, 241.93943786621094)
(301.05612182617187, 0.0)
(301.05667114257812, 8.7439727783203125)
(326.9617919921875, 0.0)
(326.96826171875, 0.0)
(328.34432983398438, 280.55218505859375)

That first number does seem to monotonically increase through the entire set. If you plot it:

import matplotlib.pyplot as plt
f, ax = plt.subplots()
ax.plot(*zip(*cleaned_data))

enter image description here

format = 'hhhh' (possibly with various paddings/directions (e.g. '<hhhh', '<xhhhh') also might be worth a look (again, random lines):

(-27069, 2560, 0, 0)
(-27069, 8968, 0, 0)
(-27069, 13576, 3139, -18487)
(-27069, 18184, 31043, -5184)
(-27069, -25721, -25533, -8601)
(-27069, -7289, 0, 0)
(-25533, 31066, 0, 0)
(-25533, -29350, 0, 0)
(-25533, 25179, 0, 0)
(-24509, -1888, 0, 0)
(-24509, -4447, 0, 0)
(-23741, -14725, 32067, 27475)
(-23741, -3973, 0, 0)
(-23485, 4908, -29629, -20922)
7
  • @Nick T, thanks, first of all, I think the first value should be positive, because it stands for the mass of a molecule, could never be a negative value; secondly, the toal number of elements in one of these tuples shall bestly be 3, that's all what I could guess about this data, they should be mass, intensity and time respectively
    – ladyfafa
    Aug 12 '10 at 19:37
  • it is absolutely right the mass goes in an ascending way "monotonically increase", suppose it is value on the x-axis, from 0 to an adequate maximum, whereas the intensity of this mass might vary sharply
    – ladyfafa
    Aug 12 '10 at 19:40
  • 2
    So this is data from a GC-MS? Try different formats, see docs.python.org/library/struct.html maybe '>fhh' or '>fHH'
    – Nick T
    Aug 12 '10 at 19:54
  • exactlly! you are genious, for sure :)
    – ladyfafa
    Aug 12 '10 at 19:57
  • I only used a GC-MS a few times in lab, but doesn't it just kick out an intensity vs. time plot? Mass we had to derive from time, calibrated with some known compounds.
    – Nick T
    Aug 12 '10 at 20:15
14

Well, I assume you are not on Interactive Mode and you used this code to decode your string:

import base64
your_string = 'Q5YACgAAAABDlgAbAAAAAEOWAC0AAAAAQ5YAPwAAAABDlgdNAAAAAEOWB18AAAAAQ5YHcAAAAABDlgeCAAAAAEOWB5QAAAAAQ5YHpkNx8H9Dlge4REqBx0OWB8pEpZ10Q5YH3ES2lxFDlgfuRIuPbEOWB/9EA9SqQ5YIEUIFJtxDlggjAAAAAEOWCDVDDMm3Q5YIR0N5wOtDlghZQ4GkeEOWCGtDD0CbQ5YIfQAAAABDlgiOAAAAAEOWCKAAAAAAQ5YIsgAAAABDlob5AAAAAEOWhwsAAAAAQ5aHHQAAAABDlocvAAAAAEOWh0FBC+dQQ5aHU0NJ9WdDlodlQ9RK6kOWh3dEDRdFQ5aHiUQARjZDloebQ5xn3kOWh61C1TYMQ5aHvwAAAABDlofRAAAAAEOWh+MAAAAAQ5aH9QAAAABDnFl9AAAAAEOcWZAAAAAAQ5xZpAAAAABDnFm3AAAAAEOcWctDH72jQ5xZ3kNDentDnFnxQ0QCp0OcWgVDK52XQ5xaGEMDUuNDnFosAAAAAEOcWj8AAAAAQ5xaUwAAAABDnFpmAAAAAEOcWnkAAAAAQ5xajQAAAABDnFqgAAAAAEOcWrRBnlHwQ5xax0MvOY9DnFraQ6AiZkOcWu5DquEAQ5xbAUNtwQNDnFsVQqVdQEOcWygAAAAAQ5xbPAAAAABDnFtPAAAAAEOcW2IAAAAAQ6Cg+AAAAABDoKEMAAAAAEOgoSEAAAAAQ6ChNQAAAABDoKFKQwi7a0OgoV5DOmAdQ6Chc0NSxE9DoKGHQy7KVUOgoZxCvXN4Q6ChsAAAAABDoKHFAAAAAEOgodkAAAAAQ6Ch7gAAAABDo3scAAAAAEOjezEAAAAAQ6N7RgAAAABDo3tcAAAAAEOje3FCY5O8Q6N7hkOOIjhDo3ubQ+yNhEOje7FD5+CaQ6N7xkN9U2tDo3vbAAAAAEOje/AAAAAAQ6N8BgAAAABDo3wbAAAAAEOjfDAAAAAAQ6QrkgAAAABDpCuoAAAAAEOkK70AAAAAQ6Qr0wAAAABDpCvoQwzvKUOkK/5Db9LnQ6QsE0OMRq5DpCwoQ4WYnEOkLD5DUWd9Q6QsU0MC2p1DpCxpAAAAAEOkLH4AAAAAQ6QskwAAAABDpCypAAAAAEOkLeoAAAAAQ6Qt/wAAAABDpC4VAAAAAEOkLioAAAAAQ6QuQELk8fJDpC5VQzIBUUOkLmpDE3S3Q6QugAAAAABDpC6VAAAAAEOkLqsAAAAAQ6QuwAAAAABDpMIjAAAAAEOkwjkAAAAAQ6TCTgAAAABDpMJkAAAAAEOkwnlDAogtQ6TCj0Nm3ZFDpMKlQ5AQSkOkwrpDdJURQ6TC0ELt1GxDpMLlAAAAAEOkwvsAAAAAQ6TDEAAAAABDpMMmAAAAAEOlUuoAAAAAQ6VTAAAAAABDpVMWAAAAAEOlUysAAAAAQ6VTQUIVw9xDpVNXQztuc0OlU2xDXwOpQ6VTgkLnklxDpVOYAAAAAEOlU64AAAAAQ6VTwwAAAABDpVPZAAAAAEOlgyQAAAAAQ6WDOgAAAABDpYNPAAAAAEOlg2UAAAAAQ6WDewAAAABDpYORAAAAAEOlg6YAAAAAQ6WDvAAAAABDpYPSAAAAAEOlg+gAAAAAQ6WD/QAAAABDpYQTAAAAAEOlhCkAAAAAQ6WEPwAAAABDqiJcAAAAAEOqInMAAAAAQ6oiigAAAABDqiKhAAAAAEOqIrhDOjjhQ6oiz0NL8gFDqiLmQyJ2X0OqIv0AAAAAQ6ojFAAAAABDqiMrAAAAAEOqI0IAAAAAQ6p+EwAAAABDqn4qAAAAAEOqfkEAAAAAQ6p+WAAAAABDqn5vQwzLhUOqfoZDZJlNQ6p+nUOX5SpDqn60Q6at5kOqfstDhSHAQ6p+4kLVJZZDqn75AAAAAEOqfxEAAAAAQ6p/KAAAAABDqn8/AAAAAEOqgZcAAAAAQ6qBrgAAAABDqoHFAAAAAEOqgdwAAAAAQ6qB9EMMs0NDqoILRHyldEOqgiJFFM7eQ6qCOUVg6OJDqoJQRW5RNUOqgmdFL4LSQ6qCfkSe+whDqoKVQydSLUOqgqwAAAAAQ6qCwwAAAABDqoLaAAAAAEOqgvIAAAAAQ6qw0gAAAABDqrDpAAAAAEOqsQAAAAAAQ6qxFwAAAABDqrEuQxCiB0OqsUZDfmUnQ6qxXUOJeMRDqrF0Q1Un5UOqsYtC9lyOQ6qxogAAAABDqrG5AAAAAEOqsdAAAAAAQ6qx6AAAAABDqwGcAAAAAEOrAbMAAAAAQ6sBygAAAABDqwHhAAAAAEOrAflDEU5HQ6sCEEP64TpDqwInRHAAYkOrAj5ElZzIQ6sCVUSCkc9DqwJtRBsdnkOrAoRDRp3HQ6sCm0JJ0uRDqwKyAAAAAEOrAsoAAAAAQ6sC4QAAAABDqwL4AAAAAEOrgUkAAAAAQ6uBYAAAAABDq4F3AAAAAEOrgY8AAAAAQ6uBpkKjOb5Dq4G9Q5AYHEOrgdVD2l3+Q6uB7EPb9xxDq4IDQ5Zv6EOrghtDGbKhQ6uCMgAAAABDq4JKAAAAAEOrgmEAAAAAQ6uCeAAAAABDrHxTAAAAAEOsfGsAAAAAQ6x8gwAAAABDrHyaAAAAAEOsfLIAAAAAQ6x8ykOV3rxDrHzhRCIkR0OsfPlESnsOQ6x9EUQraodDrH0oQ8DC7EOsfUBC5QRmQ6x9VwAAAABDrH1vAAAAAEOsfYcAAAAAQ6x9ngAAAABDsYDPAAAAAEOxgOgAAAAAQ7GBAQAAAABDsYEaAAAAAEOxgTNDHtFFQ7GBTENOOtdDsYFlQzQ0M0OxgX5CsakkQ7GBlwAAAABDsYGwAAAAAEOxgckAAAAAQ7GB4wAAAABDsYfZAAAAAEOxh/IAAAAAQ7GIDAAAAABDsYglAAAAAEOxiD5CNN5kQ7GIV0Mx6h9DsYhwQyLw10OxiIkAAAAAQ7GIokQvuWJDsYi7RTLrZEOxiNRFti0vQ7GI7UX0+WtDsYkGReZyqEOxiR9Fk7sbQ7GJOETYM4ZDsYlRQZhM0EOxiWpDPbMFQ7GJg0EE8DBDsYmcAAAAAEOxibUAAAAAQ7GJzgAAAABDsYnnAAAAAEOyBSwAAAAAQ7IFRgAAAABDsgVfAAAAAEOyBXgAAAAAQ7IFkUMeX/lDsgWqQ1qnIUOyBcNDakzLQ7IF3UNOK1lDsgX2QxcLFUOyBg8AAAAAQ7IGKAAAAABDsgZBAAAAAEOyBloAAAAAQ7IIIAAAAABDsgg5AAAAAEOyCFIAAAAAQ7IIawAAAABDsgiEQGvLQEOyCJ5DjE5EQ7IIt0RT8ohDsgjQRLITDUOyCOlEx/0eQ7IJAkSboYRDsgkbRBrElkOyCTVC8Q1qQ7IJTkNZN6lDsglnQ9HrdEOyCYBD3r0EQ7IJmUOUB7JDsgmyQt1s2EOyCcwAAAAAQ7IJ5QAAAABDsgn+AAAAAEOyChcAAAAAQ7KH1wAAAABDsofwAAAAAEOyiAkAAAAAQ7KIIwAAAABDsog8AAAAAEOyiFVDmdXKQ7KIbkRFmedDsoiIRIyTq0OyiKFEhXFjQ7KIukQk++pDsojUQ2Ti6UOyiO1C59eGQ7KJBgAAAABDsokgQx+8zUOyiTlDW2b7Q7KJUkNhYXFDsolsQw9giUOyiYUAAAAAQ7KJngAAAABDsom4AAAAAEOyidEAAAAAQ7KjJgAAAABDsqNAAAAAAEOyo1kAAAAAQ7KjcwAAAABDsqOMQxiW60Oyo6VDb3iLQ7Kjv0OCiUpDsqPYQ0zvUUOyo/FC2VN+Q7KkCwAAAABDsqQkAAAAAEOypD1CxVtqQ7KkV0NC+C9DsqRwQ3VyJ0OypIlDV0SRQ7Kko0LAkp5DsqS8AAAAAEOypNUAAAAAQ7Kk7wAAAABDsqUIAAAAAEOzgtQAAAAAQ7OC7QAAAABDs4MHAAAAAEOzgyAAAAAAQ7ODOgAAAABDs4NURBZFGEOzg21FAqNDQ7ODh0VyQZRDs4OgRZfF10Ozg7pFheg0Q7OD1EUfaltDs4PtREyHoEOzhAcAAAAAQ7OEIAAAAABDs4Q6AAAAAEOzhFQAAAAAQ7OEbQAAAABDtALeAAAAAEO0AvcAAAAAQ7QDEQAAAABDtAMrAAAAAEO0A0UAAAAAQ7QDXkNQ5IVDtAN4RAIEokO0A5JEHByTQ7QDrEPrpJ5DtAPFQ1wEy0O0A99Cf5dkQ7QD+QAAAABDtAQSAAAAAEO0BCwAAAAAQ7QERgAAAABDtIKCAAAAAEO0gpwAAAAAQ7SCtgAAAABDtILQAAAAAEO0gupCwzHOQ7SDA0NWhYdDtIMdQ6kekkO0gzdD65s+Q7SDUUPZmNxDtINrQ0uJw0O0g4VCwHqAQ7SDnwAAAABDtIO5AAAAAEO0g9MAAAAAQ7SD7AAAAABDuYw1AAAAAEO5jFEAAAAAQ7mMbAAAAABDuYyHAAAAAEO5jKNCQp50Q7mMvkO6WI5DuYzZRC4aE0O5jPVESsfrQ7mNEEQhx9ZDuY0rQ6WBqEO5jUdCGiqoQ7mNYgAAAABDuY19AAAAAEO5jZkAAAAAQ7mNtAAAAABDugxRAAAAAEO6DGwAAAAAQ7oMiAAAAABDugyjAAAAAEO6DL9DFS1NQ7oM2kOCy6BDugz2Q3wf9UO6DRFDKs7FQ7oNLUMkWulDug1IQ1WgIUO6DWRDP0LbQ7oNf0KzSzpDug2bAAAAAEO6DbYAAAAAQ7oN0gAAAABDug3tAAAAAEO6iY0AAAAAQ7qJqQAAAABDuonEAAAAAEO6ieAAAAAAQ7qJ/EKUY+5DuooXQ0F3k0O6ijNDiJBMQ7qKT0OKy05DuopqQ0Uf0UO6ioZCjaAQQ7qKogAAAABDuoq9AAAAAEO6itkAAAAAQ7qK9QAAAABDwis+AAAAAEPCK1wAAAAAQ8IregAAAABDwiuYAAAAAEPCK7ZDIAxFQ8Ir1EM3uZlDwivyQw/DxUPCLBAAAAAAQ8IsLQAAAABDwixLAAAAAEPCLGkAAAAAQ8KrFQAAAABDwqszAAAAAEPCq1EAAAAAQ8KrbwAAAABDwquNQuvJ8kPCq6tDXTspQ8KryUOF7VJDwqvnQ2qgd0PCrAVDWFCVQ8KsJENlY31DwqxCQzBR90PCrGBCks/EQ8KsfgAAAABDwqycAAAAAEPCrLoAAAAAQ8Ks2AAAAABDxaCeAAAAAEPFoL0AAAAAQ8Wg3AAAAABDxaD7AAAAAEPFoRpC6Bm+Q8WhOUNIlwtDxaFYQ0bbiUPFoXdC60cUQ8WhlgAAAABDxaG1AAAAAEPFodQAAAAAQ8Wh8wAAAABDxcLQAAAAAEPFwu8AAAAAQ8XDDgAAAABDxcMuAAAAAEPFw01DCdiTQ8XDbENSEiFDxcOLQzMgqUPFw6pCvkXoQ8XDyQAAAABDxcPoAAAAAEPFxAcAAAAAQ8XEJgAAAABDyqCrAAAAAEPKoMwAAAAAQ8qg7AAAAABDyqENAAAAAEPKoS5DFgyhQ8qhTkNJ8YtDyqFvQyCk7UPKoZAAAAAAQ8qhsAAAAABDyqHRAAAAAEPKofEAAAAAQ86hbQAAAABDzqGPAAAAAEPOobEAAAAAQ86h0wAAAABDzqH1QtiFfkPOohdDN+wBQ86iOEMicXdDzqJaAAAAAEPOonwAAAAAQ86ingAAAABDzqLAAAAAAEPPg5sAAAAAQ8+DvQAAAABDz4PfAAAAAEPPhAEAAAAAQ8+EJAAAAABDz4RGQzv7CUPPhGhEXJabQ8+EikTXGK5Dz4SsRQtcE0PPhM9E/wVMQ8+E8USdi5JDz4UTQ9CGQEPPhTVCsERWQ8+FVwAAAABDz4V6AAAAAEPPhZwAAAAAQ8+FvgAAAABD0AOmAAAAAEPQA8gAAAAAQ9AD6wAAAABD0AQNAAAAAEPQBC9DKyRrQ9AEUkPKA05D0AR0RCwHHUPQBJdEUzZEQ9AEuUQ94dVD0ATbQ/ChWkPQBP5DNpvFQ9AFIEFnWsBD0AVCAAAAAEPQBWUAAAAAQ9AFhwAAAABD0AWqAAAAAEPQg4AAAAAAQ9CDowAAAABD0IPFAAAAAEPQg+gAAAAAQ9CEC0LS1TZD0IQtQ8lMiEPQhFBEAV2PQ9CEckOvPy5D0ISVQhAVCEPQhLcAAAAAQ9CE2gAAAABD0IT8AAAAAEPQhR8AAAAAQ9F+hQAAAABD0X6oAAAAAEPRfssAAAAAQ9F+7gAAAABD0X8RAAAAAEPRfzRDXvi1Q9F/V0Pav3JD0X96Q/VLikPRf5xDwjysQ9F/v0NUF1ND0X/iQkRspEPRgAUAAAAAQ9GAKAAAAABD0YBLAAAAAEPRgG4AAAAAQ9M8gQAAAABD0zykAAAAAEPTPMgAAAAAQ9M86wAAAABD0z0PQyIWp0PTPTJDNPW/Q9M9VkMNGedD0z15AAAAAEPTPZwAAAAAQ9M9wAAAAABD0z3jAAAAAEPUoh8AAAAAQ9SiQwAAAABD1KJmAAAAAEPUoooAAAAAQ9SirkKYjL5D1KLSQy6TTUPUovZDOYDvQ9SjGkLawPpD1KM+AAAAAEPUo2IAAAAAQ9SjhgAAAABD1KOqAAAAAEPWiiwAAAAAQ9aKUQAAAABD1op1AAAAAEPWipoAAAAAQ9aKvkJ42vRD1orjQ6UBeEPWiwhEvTTGQ9aLLEVQripD1otRRZKn/EPWi3VFjjxkQ9aLmkU7lFtD1ou+RI+CDUPWi+NCDiKAQ9aMBwAAAABD1owsAAAAAEPWjFEAAAAAQ9aMdQAAAABD1pV1AAAAAEPWlZoAAAAAQ9aVvgAAAABD1pXjAAAAAEPWlgdC4s80Q9aWLENR95VD1pZQQzhC/0PWlnVC0TaKQ9aWmgAAAABD1pa+AAAAAEPWluMAAAAAQ9aXBwAAAABD1wpKAAAAAEPXCm8AAAAAQ9cKlAAAAABD1wq5AAAAAEPXCt0AAAAAQ9cLAkOM9OhD1wsnREXjmUPXC0xEi3MpQ9cLcER5n2RD1wuVRAxzB0PXC7pDbm1bQ9cL3kND/tdD1wwDQsah9EPXDCgAAAAAQ9cMTQAAAABD1wxxAAAAAEPXDJYAAAAAQ9eKAAAAAABD14olAAAAAEPXikoAAAAAQ9eKbgAAAABD14qTQr6yAkPXirhEAvzPQ9eK3URaCbtD14sCRFjVXEPXiydD7mQkQ9eLTEGr5HhD14txQymzDUPXi5ZDXmm/Q9eLu0MMb99D14vfAAAAAEPXjAQAAAAAQ9eMKQAAAABD14xOAAAAAEPejjkAAAAAQ96OYAAAAABD3o6IAAAAAEPejq8AAAAAQ96O1kLCXcBD3o7+Q82Q4kPejyVEXvwyQ96PTESd1VxD3o90RJ20oEPej5tEXtT0Q96PwkPOWbxD3o/qQwI770PekBFDDeXNQ96QOENBpAdD3pBgQ0iIqUPekIdDNQp7Q96QrkMWx49D3pDWAAAAAEPekP0AAAAAQ96RJAAAAABD3pFMAAAAAEPfDjkAAAAAQ98OYQAAAABD3w6IAAAAAEPfDrAAAAAAQ98O10AISkBD3w7/Qzb5V0PfDyZDvoRSQ98PTkPrjWZD3w91Q8YEBEPfD51DXByZQ98PxEJrbhRD3w/sAAAAAEPfEBMAAAAAQ98QOwAAAABD3xBiAAAAAEPfjlYAAAAAQ9+OfgAAAABD346lAAAAAEPfjs0AAAAAQ9+O9UMmm8lD348cQzD1g0Pfj0RCszhMQ9+PbAAAAABD34+TAAAAAEPfj7sAAAAAQ9+P4wAAAABD6lKzAAAAAEPqUt8AAAAAQ+pTCgAAAABD6lM2AAAAAEPqU2FC6LRAQ+pTjUNNqAVD6lO5Q3Zi/UPqU+RDST1xQ+pUEELOjkRD6lQ8AAAAAEPqVGcAAAAAQ+pUkwAAAABD6lS+AAAAAEPqVOpDFBk7Q+pVFkMzxf9D6lVBQxfgMUPqVW0AAAAAQ+pVmQAAAABD6lXEAAAAAEPqVfAAAAAAQ+qp4gAAAABD6qoOAAAAAEPqqjoAAAAAQ+qqZgAAAABD6qqRQxtGxUPqqr1DM9+nQ+qq6UMaTMlD6qsVAAAAAEPqq0AAAAAAQ+qrbAAAAABD6quYAAAAAEP0hdQAAAAAQ/SGAwAAAABD9IYzAAAAAEP0hmIAAAAAQ/SGkkMtUiND9IbBQ7i2DkP0hvFEDd8PQ/SHIEQVu79D9IdPQ8UR1EP0h39Ca+8EQ/SHrgAAAABD9IfeAAAAAEP0iA0AAAAAQ/SIPQAAAABD+RUtAAAAAEP5FV4AAAAAQ/kVkAAAAABD+RXBAAAAAEP5FfJCVW8oQ/kWJENG0adD+RZVQ1OdY0P5FoZCryaYQ/kWtwAAAABD+RbpAAAAAEP5FxoAAAAAQ/kXSwAAAABD+4xwAAAAAEP7jKIAAAAAQ/uM1AAAAABD+40HAAAAAEP7jTlC9zV6Q/uNa0RTp1JD+42dRNYseUP7jdBFBMwAQ/uOAkTfKPxD+440RHEDqEP7jmZDZQYzQ/uOmQAAAABD+47LAAAAAEP7jv0AAAAAQ/uPLwAAAABD+49iAAAAAEP8DB0AAAAAQ/wMTwAAAABD/AyCAAAAAEP8DLQAAAAAQ/wM50LANKBD/A0ZQzA9l0P8DUxDqOawQ/wNfkQJ8GRD/A2wRBZh8kP8DeNDxvUSQ/wOFUNFkX9D/A5IQ1nIi0P8DnpC1lEYQ/wOrQAAAABD/A7fAAAAAEP8DxIAAAAAQ/wPRAAAAABD/Cl/AAAAAEP8KbIAAAAAQ/wp5AAAAABD/CoXAAAAAEP8KklC/rV+Q/wqfEM2/AlD/CquQ1vrR0P8KuFDXZxtQ/wrE0NO+6lD/CtGQ0CkpUP8K3hDKv/tQ/wrqwAAAABD/CvdAAAAAEP8LBAAAAAAQ/wsQgAAAABEAchdAAAAAEQByHgAAAAARAHIkgAAAABEAcitAAAAAEQByMhDFFQtRAHI40NBZ/VEAcj9Qw4ojUQByRgAAAAARAHJMwAAAABEAclOAAAAAEQByWkAAAAARAiPBQAAAABECI8iAAAAAEQIj0AAAAAARAiPXgAAAABECI97QtIAQEQIj5lDQC1DRAiPt0NUR8tECI/UQyrKL0QIj/IAAAAARAiQDwAAAABECJAtAAAAAEQIkEsAAAAARBAtaQAAAABEEC2KAAAAAEQQLasAAAAARBAtzAAAAABEEC3tQxEM40QQLg5DZaXdRBAuL0NJKXtEEC5QQqsvrkQQLnEAAAAARBAukgAAAABEEC6zAAAAAEQQLtQAAAAARBBHOgAAAABEEEdbAAAAAEQQR3wAAAAARBBHnQAAAABEEEe+QtQGdEQQR99Dknh2RBBIAEQI1vxEEEgiRCYd2UQQSENEA8fXRBBIZEOAHJJEEEiFQqmfKEQQSKYAAAAARBBIxwAAAABEEEjoAAAAAEQQSQkAAAAARBlVmgAAAABEGVW/AAAAAEQZVeQAAAAARBlWCgAAAABEGVYvQyA4p0QZVlRDQEFRRBlWekMn+t9EGVafAAAAAEQZVsUAAAAARBlW6gAAAABEGVcPAAAAAEQeSQgAAAAARB5JMAAAAABEHklYAAAAAEQeSYAAAAAARB5JqEMFcstEHknPQ30s70QeSfdDfp4lRB5KH0Mti5FEHkpHAAAAAEQeSm8AAAAARB5KlgAAAABEHkq+AAAAAEQihscAAAAARCKG8QAAAABEIocbAAAAAEQih0UAAAAARCKHb0OkiJREIoeZRAMjbkQih8NECTC6RCKH7UPBZahEIogXQvNmskQiiEEAAAAARCKIawAAAABEIoiVAAAAAEQiiL8AAAAARCLISQAAAABEIshzAAAAAEQiyJ4AAAAARCLIyAAAAABEIsjyQ0iV30QiyRxDw6BSRCLJRkPte9xEIslwQ83zwkQiyZpDghpaRCLJxAAAAABEIsnuAAAAAEQiyhgAAAAARCLKQwAAAABEJiRvAAAAAEQmJJsAAAAARCYkxgAAAABEJiTyAAAAAEQmJR5DK/KrRCYlSkQjZoJEJiV2RICqBUQmJaJEgim/RCYlzkQvOIxEJiX5Q3y6R0QmJiUAAAAARCYmUQAAAABEJiZ9AAAAAEQmJqkAAAAARCYm1QAAAABEJjcdAAAAAEQmN0kAAAAARCY3dAAAAABEJjegAAAAAEQmN8xDBEj1RCY3+EM/mrtEJjgkQywKXUQmOFAAAAAARCY4fAAAAABEJjioAAAAAEQmONQAAAAARCY4/wAAAABEJjkrAAAAAEQmOVcAAAAARCY5g0JBR6REJjmvQz/4BUQmOdtDc6ohRCY6B0Mj/9NEJjozAAAAAEQmOl8AAAAARCY6iwAAAABEJjq2AAAAAEQmeQ0AAAAARCZ5OQAAAABEJnllAAAAAEQmeZEAAAAARCZ5vUOx1ixEJnnpQ75QAEQmehVDwh7uRCZ6QUO0zPJEJnptQ4qrsEQmepkAAAAARCZ6xQAAAABEJnrxAAAAAEQmex0AAAAARClCpwAAAABEKULUAAAAAEQpQwIAAAAARClDLwAAAABEKUNdQyANz0QpQ4pDSArxRClDuEL7XKZEKUPlAAAAAEQpRBMAAAAARClEQAAAAABEKURuAAAAAEQpXEUAAAAARClccgAAAABEKVygAAAAAEQpXM0AAAAARClc+0Ndlg1EKV0pQ9ngrkQpXVZEBnrCRCldhEPiHNxEKV2xQ3c46UQpXd8AAAAARCleDAAAAABEKV46AAAAAEQpXmgAAAAARC2UcwAAAABELZSjAAAAAEQtlNMAAAAARC2VAwAAAABELZUzQ66+WkQtlWNEAXWBRC2Vk0QB02FELZXCQ51yyEQtlfJBrxGwRC2WIgAAAABELZZSAAAAAEQtloIAAAAARC2WsgAAAABELuKlAAAAAEQu4tUAAAAARC7jBgAAAABELuM2AAAAAEQu42dDJDvtRC7jmEOQDyRELuPIQ5kAzkQu4/lDS6czRC7kKUJQiRBELuRaAAAAAEQu5IsAAAAARC7kuwAAAABELuTsAAAAAEQu5RwAAAAARC7lTQAAAABELuV+AAAAAEQu5a5DOYEhRC7l30Pef6pELuYPRCLAuUQu5kBEQEWRRC7mcERZXENELuahRGN6UkQu5tJEPj+ORC7nAkPumMpELuczQ0sKXUQu52NCYZr8RC7nlAAAAABELufFAAAAAEQu5/UAAAAARC7oJgAAAABEL+anAAAAAEQv5tgAAAAARC/nCQAAAABEL+c7AAAAAEQv52xDL7dZRC/nnUNiVZ1EL+fOQ0JbHUQv5/9CqyhcRC/oMAAAAABEL+hhAAAAAEQv6JMAAAAARC/oxAAAAABEMO0eAAAAAEQw7VAAAAAARDDtgQAAAABEMO2zAAAAAEQw7eVCUT7cRDDuF0PDnb5EMO5IRBZ3E0Qw7npEDDm8RDDurEOnWkBEMO7eQq2XfkQw7w8AAAAARDDvQQAAAABEMO9zAAAAAEQw76UAAAAARDIYsAAAAABEMhjiAAAAAEQyGRQAAAAARDIZRwAAAABEMhl5Qy11O0QyGaxDXkIHRDIZ3kMXpdlEMhoQAAAAAEQyGkNDZT89RDIadUQZnVJEMhqoRD0KeEQyGtpEDWCVRDIbDEM+nSVEMhs/AAAAAEQyG3EAAAAARDIbpAAAAABEMhvWAAAAAEQyHAgAAAAARDJ2+AAAAABEMncqAAAAAEQyd10AAAAARDJ3jwAAAABEMnfCQ6fqRkQyd/VDvIWyRDJ4J0Pn2wREMnhaRAqwhEQyeIxECz0aRDJ4v0PtS9BEMnjyQ8FijkQyeSRDo41YRDJ5VwAAAABEMnmKAAAAAEQyebwAAAAARDJ57wAAAABEM1/LAAAAAEQzX/4AAAAARDNgMQAAAABEM2BkAAAAAEQzYJdDM9+BRDNgy0PSzIBEM2D+RARTb0QzYTFD57s4RDNhZEOeAqxEM2GXAAAAAEQzYcoAAAAARDNh/QAAAABEM2IwAAAAAEQ04ccAAAAARDTh+wAAAABENOIvAAAAAEQ04mMAAAAARDTil0NvUs1ENOLKQ7mM+EQ04v5D2IziRDTjMkPIjeBENONmQ5x0FEQ045oAAAAARDTjzgAAAABENOQCAAAAAEQ05DYAAAAARDTndgAAAABENOeqAAAAAEQ0594AAAAARDToEgAAAABENOhGQoWMvEQ06HpDQjn9RDTorkOZ9sZENOjiQ7LKFEQ06RZDkzI2RDTpSkL3QTJENOl+AAAAAEQ06bIAAAAARDTp5gAAAABENOoaAAAAAEQ129gAAAAARDXcDAAAAABENdxBAAAAAEQ13HUAAAAARDXcqkMUJ6FENdzeQ1KteUQ13RNDdSurRDXdSENhih1ENd18QzJGj0Q13bEAAAAARDXd5QAAAABENd4aAAAAAEQ13k4AAAAARDtfyAAAAABEO2AAAAAAAEQ7YDgAAAAARDtgbwAAAABEO2CnQvuPWkQ7YN9DR2vLRDthF0NP6YFEO2FOQx9lJ0Q7YYYAAAAARDthvgAAAABEO2H2AAAAAEQ7Yi4AAAAARD1dFAAAAABEPV1NAAAAAEQ9XYYAAAAARD1dvwAAAABEPV34Qy/i/UQ9XjFDWMDLRD1eakNLJ+VEPV6jQwls40Q9XtwAAAAARD1fFQAAAABEPV9OAAAAAEQ9X4cAAAAARD1k3wAAAABEPWUYAAAAAEQ9ZVEAAAAARD1ligAAAABEPWXDQqbV1EQ9ZfxDPvz5RD1mNUN8Ak1EPWZuQ4QpLkQ9ZqdDdtHbRD1m4ENV/DVEPWcZQyQAmUQ9Z1EAAAAARD1nigAAAABEPWfDAAAAAEQ9Z/wAAAAAREEeKwAAAABEQR5mAAAAAERBHqEAAAAAREEe3QAAAABEQR8YQtDTRERBH1NDPvx3REEfjkNcAh1EQR/KQ1m890RBIAVDONTfREEgQELxvNJEQSB7AAAAAERBILcAAAAAREEg8gAAAABEQSEtAAAAAERCU3EAAAAAREJTrQAAAABEQlPpAAAAAERCVCUAAAAAREJUYUKXYq5EQlSdQzg4rURCVNlDpapGREJVFUPkLuZEQlVRRBRjCkRCVY1ELIQgREJVyUQk7ZpEQlYFRAlZ1ERCVkFDx9h+REJWfUMY4alEQla5AAAAAERCVvUAAAAAREJXMQAAAABEQldtAAAAAERFh5YAAAAAREWH1AAAAABERYgSAAAAAERFiFAAAAAAREWIjkMWkvtERYjMQ4g29ERFiQpDqf4mREWJSEOyObBERYmGQ6D0xkRFicRDUY2nREWKAkIfGvhERYpAAAAAAERFin4AAAAAREWKvAAAAABERYr6AAAAAERFjiAAAAAAREWOXgAAAABERY6cAAAAAERFjtoAAAAAREWPGEK9GuBERY9WQ2Ml50RFj5RDoK7UREWP0kOl+WhERZAQQ22uP0RFkE5Coc28REWQjAAAAABERZDKAAAAAERFkQgAAAAAREWRRgAAAABER8aUAAAAAERHxtQAAAAAREfHEwAAAABER8dTAAAAAERHx5JDh8FaREfH0UO9DJBER8gRQ9bfKERHyFBDzkoWREfIkEOuMHxER8jPAAAAAERHyQ4AAAAAREfJTgAAAABER8mNAAAAAERIbk4AAAAAREhujgAAAABESG7OAAAAAERIbw4AAAAAREhvTkMM9UlESG+NQ083Y0RIb81DOgL9REhwDUK2XghESHBNAAAAAERIcI0AAAAAREhwzQAAAABESHEMAAAAAERKh+IAAAAAREqIIwAAAABESohkAAAAAERKiKYAAAAAREqI50Lh96RESokoQ35MV0RKiWlDnMTYREqJqkNxeg9ESonrQr2M/kRKii0AAAAAREqKbgAAAABESoqvAAAAAERKivAAAAAAREvFtwAAAABES8X5AAAAAERLxjsAAAAAREvGfQAAAABES8a/QwTfiURLxwFDcL+ZREvHQ0OJfrJES8eFQ2HTSURLx8dDAQzpREvICQAAAABES8hLAAAAAERLyI0AAAAAREvIzwAAAABES8wpAAAAAERLzGsAAAAAREvMrQAAAABES8zvAAAAAERLzTFC78e2REvNc0NWbJ9ES821Q5QpeERLzfdDbnPBREvOOUJOhwhES857AAAAAERLzrwAAAAAREvO/gAAAABES89AAAAAAERMDGoAAAAAREwMrQAAAABETAzvAAAAAERMDTEAAAAAREwNc0MbaL1ETA21Q4XDPkRMDfdDlMa4REwOOkNYuqFETA58QoUC7kRMDr4AAAAAREwPAAAAAABETA9CAAAAAERMD4QAAAAARE+u2AAAAABET68dAAAAAERPr2EAAAAARE+vpgAAAABET6/qQyyLhURPsC9DWN/HRE+wc0NkY0tET7C4QxkM20RPsPwAAAAARE+xQQAAAABET7GFAAAAAERPscoAAAAARFAOCQAAAABEUA5OAAAAAERQDpMAAAAARFAO1wAAAABEUA8cQwDAqURQD2FDdvAjRFAPpkOL1RJEUA/qQ0OKJURQEC9CXTp0RFAQdAAAAABEUBC5AAAAAERQEP4AAAAARFARQgAAAABEVcuoAAAAAERVy/AAAAAARFXMOQAAAABEVcyCAAAAAERVzMpCzsoORFXNE0NaGXFEVc1bQ3R5C0RVzaRDKbY/RFXN7QAAAABEVc41AAAAAERVzn4AAAAARFXOxwAAAABEV5BlAAAAAERXkK4AAAAARFeQ+AAAAABEV5FCAAAAAERXkYxDKSu1RFeR1kNbVSFEV5IgQ1lH20RXkmlDOlYfRFeSs0M4QDVEV5L9Q0YP/0RXk0dDMzG5RFeTkQAAAABEV5PaAAAAAERXlCQAAAAARFeUbgAAAABEV6FpAAAAAERXobMAAAAARFeh/QAAAABEV6JHAAAAAERXopFDDVORRFei20NxGSNEV6MlQ22aoURXo25C9lnCRFejuAAAAABEV6QCAAAAAERXpEwAAAAARFeklgAAAABEV6W9AAAAAERXpgcAAAAARFemUQAAAABEV6abAAAAAERXpuVDLnHjRFenL0M9OBdEV6d5QxBdL0RXp8MAAAAARFeoDQAAAABEV6hWAAAAAERXqKAAAAAARF33JAAAAABEXfdzAAAAAERd98EAAAAARF34DwAAAABEXfheQy+tTURd+KxDS93XRF34+kM42jtEXflIQswuZkRd+ZcAAAAARF355QAAAABEXfozAAAAAERd+oEAAAAARF5M4QAAAABEXk0wAAAAAEReTX4AAAAARF5NzQAAAABEXk4bQrksMkReTmpDvnVcRF5OuEQoL11EXk8HREPcqkReT1VEI/uQRF5PpEPTigZEXk/zQ4LN9kReUEFDX7PhRF5QkAAAAABEXlDeAAAAAEReUS0AAAAARF5RewAAAABEXo0MAAAAAERejVsAAAAARF6NqQAAAABEXo34AAAAAERejkdDA7iRRF6OlUOCrD5EXo7kQ8vYCkRejzND56FuRF6PgUO0Y8BEXo/QQyOz3URekB8AAAAARF6QbgAAAABEXpC8AAAAAERekQsAAAAARF7MvgAAAABEXs0NAAAAAERezVwAAAAARF7NqgAAAABEXs35Q478yERezkhDw2IoRF7Ol0PtNthEXs7mQ+gZFERezzVDnL2ORF7PhAAAAABEXs/TAAAAAERe0CEAAAAARF7QcAAAAABEYs8hAAAAAERiz3MAAAAARGLPxQAAAABEYtAXAAAAAERi0GhCk7m4RGLQukOaFH5EYtEMQ8gFaERi0V1DoL7mRGLRr0MQ5L1EYtIBAAAAAERi0lMAAAAARGLSpAAAAABEYtL2AAAAAERjTncAAAAARGNOyQAAAABEY08bAAAAAERjT20AAAAARGNPv0MdKfNEY1ARQ4lspERjUGNDjNEARGNQtkM/hM9EY1EIQkeJ4ERjUVoAAAAARGNRrAAAAABEY1H+AAAAAERjUlAAAAAARGbfpAAAAABEZt/5AAAAAERm4E4AAAAARGbgogAAAABEZuD3Qw3sj0Rm4UxDPHMvRGbhoEMBtoVEZuH1AAAAAERm4koAAAAARGbingAAAABEZuLzAAAAAERnjyUAAAAARGePegAAAABEZ4/PAAAAAERnkCQAAAAARGeQeULWDGZEZ5DPQ061J0RnkSRDan7BRGeReUNAkQdEZ5HOQuC5/kRnkiMAAAAARGeSeQAAAABEZ5LOAAAAAERnkyMAAAAARG8fawAAAABEbx/GAAAAAERvICEAAAAARG8gfAAAAABEbyDXQrehxkRvITJDR2/vRG8hjUNuIblEbyHnQ1BEK0RvIkJDLuhfRG8inQAAAABEbyL4AAAAAERvI1MAAAAARG8jrgAAAABEcM5fAAAAAERwzrsAAAAARHDPFwAAAABEcM9zAAAAAERwz89DK5xDRHDQK0OGgeZEcNCHQ26Re0Rw0ONC5uMORHDRQAAAAABEcNGcAAAAAERw0fgAAAAARHDSVAAAAABEcQ4hAAAAAERxDn0AAAAARHEO2gAAAABEcQ82AAAAAERxD5JC/8MCRHEP70PZhmhEcRBLRCsGMERxEKdEHpPpRHERBEOzPEpEcRFgQpyPfERxEbwAAAAARHESGQAAAABEcRJ1AAAAAERxEtEAAAAARHFNqQAAAABEcU4FAAAAAERxTmIAAAAARHFOvgAAAABEcU8bQWGokERxT3dDXYpdRHFP1EPRHHxEcVAwQ/Hb1kRxUI1DyFA0RHFQ6UN6Ck1EcVFGQzioDURxUaNDau5XRHFR/0NnQT9EcVJcQxBEBURxUrgAAAAARHFTFQAAAABEcVNxAAAAAERxU84AAAAARHUP2wAAAABEdRA6AAAAAER1EJkAAAAARHUQ+QAAAABEdRFYQoIpDER1EbhDbzAjRHUSF0OZA/BEdRJ2Q5gAnkR1EtZDj7qGRHUTNUN1fidEdROVQxFdtUR1E/QAAAAARHUUUwAAAABEdRSzAAAAAER1FRIAAAAARIFNGgAAAABEgU1PAAAAAESBTYQAAAAARIFNuQAAAABEgU3uQy178USBTiNDb4JRRIFOWEOhvR5EgU6NQ7dIFESBTsNDkg3MRIFO+ELaUAREgU8tAAAAAESBT2IAAAAARIFPlwAAAABEgU/MAAAAAESBpzIAAAAARIGnZwAAAABEgaecAAAAAESBp9IAAAAARIGoB0Jew0REgag9QzrtF0SBqHJDhC78RIGop0NtEDlEgajdQy4kQ0SBqRIAAAAARIGpSAAAAABEgal9AAAAAESBqbMAAAAARIHnXgAAAABEgeeUAAAAAESB58kAAAAARIHn/wAAAABEgeg1QwZ+g0SB6GpDhNUoRIHooEOId6xEgejWQvQoEkSB6QsAAAAARIHpQQAAAABEgel2AAAAAESB6awAAAAARIIHpwAAAABEggfdAAAAAESCCBMAAAAARIIISAAAAABEggh+Qv4nckSCCLRDWj6rRIII6kNbO+tEggkfQwvuw0SCCVUAAAAARIIJiwAAAABEggnBAAAAAESCCfYAAAAARIInlQAAAABEgifLAAAAAESCKAAAAAAARIIoNgAAAABEgihsQpgZsESCKKJDTqwDRIIo2ENlUilEgikOQwzsVUSCKUMAAAAARIIpeQAAAABEgimvAAAAAESCKeUAAAAARIJjZgAAAABEgmOcAAAAAESCY9IAAAAARIJkCAAAAABEgmQ+QxAFj0SCZHRDUubtRIJkq0NEJytEgmThQrRT7ESCZRcAAAAARIJlTQAAAABEgmWDAAAAAESCZbkAAAAARILgJgAAAABEguBcAAAAAESC4JMAAAAARILgyQAAAABEguEAQykld0SC4TZDdX0HRILhbENFmp9EguGjQb3PWESC4dkAAAAARILiEAAAAABEguJGAAAAAESC4n0AAAAARILldwAAAABEguWtAAAAAESC5eMAAAAARILmGgAAAABEguZQQwBjuUSC5odDV6cNRILmvUM6wtdEgub0QqvdxESC5yoAAAAARILnYQAAAABEgueXAAAAAESC580AAAAARIQHrQAAAABEhAflAAAAAESECBwAAAAARIQIVAAAAABEhAiLQ6u3TESECMJDwF2mRIQI+kO6QMBEhAkxQ4fEYkSECWlC/e2yRIQJoAAAAABEhAnXAAAAAESECg8AAAAARIQKRgAAAABEhkcTAAAAAESGR00AAAAARIZHhgAAAABEhke/AAAAAESGR/lDLs0JRIZIMkNUEF9EhkhrQ0uXC0SGSKRDHr1tRIZI3gAAAABEhkkXAAAAAESGSVAAAAAARIZJikL/SApEhknDQ2n1HUSGSfxDaNZfRIZKNULoybBEhkpvAAAAAESGSqgAAAAARIZK4QAAAABEhksbAAAAAESKp1YAAAAARIqnkwAAAABEiqfQAAAAAESKqA0AAAAARIqoSkOZccZEiqiHQ8OX8ESKqMRD0uwsRIqpAUPBGSZEiqk+Q4aumESKqXsAAAAARIqpuAAAAABEiqn1AAAAAESKqjMAAAAARIsHRgAAAABEiweEAAAAAESLB8EAAAAARIsH/gAAAABEiwg8QRzZQESLCHlDOZ21RIsIt0NpEt9Eiwj0Qxy7mUSLCTIAAAAARIsJbwAAAABEiwmsAAAAAESLCepC1l7iRIsKJ0NKJGFEiwplQ2VGDUSLCqJDI96fRIsK3wAAAABEiwsdAAAAAESLC1oAAAAARIsLmAAAAABEi6aPAAAAAESLps0AAAAARIunCgAAAABEi6dIAAAAAESLp4ZDAlSPRIunxEN89OlEi6gCQ36+10SLqEBDKC6nRIuofgAAAABEi6i8AAAAAESLqPoAAAAARIupOAAAAABEi6l2AAAAAESLqbQAAAAARIup8kMy0NNEi6owQ4TQBkSLqm5DkiguRIuqrENtXpdEi6rqQtiDoESLqygAAAAARIurZgAAAABEi6ukAAAAAESLq+IAAAAARIwKEwAAAABEjApRAAAAAESMCpAAAAAARIwKzgAAAABEjAsMQvIq9kSMC0pDZhH9RIwLiUNv6lFEjAvHQzxNeUSMDAVDBf57RIwMRAAAAABEjAyCAAAAAESMDMAAAAAARIwM/wAAAABEjShkAAAAAESNKKMAAAAARI0o4wAAAABEjSkiAAAAAESNKWFDElYDRI0poENEpUlEjSngQ1ahVUSNKh9DTWGbRI0qXkMyvJNEjSqeAAAAAESNKt0AAAAARI0rHAAAAABEjStcAAAAAESNSBMAAAAARI1IUgAAAABEjUiSAAAAAESNSNEAAAAARI1JEEOD/sxEjUlQQ5zD+kSNSY9DiLWwRI1Jz0M8GlVEjUoOQt0cRESNSk0AAAAARI1KjQAAAABEjUrMAAAAAESNSwwAAAAARI38VAAAAABEjfyUAAAAAESN/NQAAAAARI39FAAAAABEjf1UQqmYCkSN/ZRDQgi5RI391EOHro5Ejf4VQ5lPvkSN/lVDkJFWRI3+lUNXxZNEjf7VQt7eVESN/xUAAAAARI3/VQAAAABEjf+VAAAAAESN/9UAAAAARI4DFgAAAABEjgNWAAAAAESOA5YAAAAARI4D1gAAAABEjgQWQqKKNkSOBFZDWtVLRI4ElkORPRJEjgTWQ1hZoUSOBRdCi7n2RI4FVwAAAABEjgWXAAAAAESOBdcAAAAARI4GFwAAAABEkxSUAAAAAESTFNkAAAAARJMVHQAAAABEkxViAAAAAESTFadDJaKtRJMV7ENTNDdEkxYwQysKnUSTFnUAAAAARJMWugAAAABEkxb+AAAAAESTF0MAAAAARJUa0gAAAABElRsZAAAAAESVG18AAAAARJUbpgAAAABElRvtQxH4LUSVHDNDZsFtRJUcekN8raNElRzBQ2M/m0SVHQdDWz+3RJUdTkNrpC1ElR2VQ1qkRUSVHdtDF/M1RJUeIgAAAABElR5pAAAAAESVHq8AAAAARJUe9gAAAABElaatAAAAAESVpvUAAAAARJWnPAAAAABElaeDAAAAAESVp8pDIWOXRJWoEUN/VZNElahYQ1lqnUSVqKBCB/rcRJWo5wAAAABElakuAAAAAESVqXUAAAAARJWpvAAAAABElaoDQjC90ESVqktDb5h/RJWqkkOowJBElarZQ6MNmESVqyBDZaT5RJWrZ0LD4VBElauuAAAAAESVq/YAAAAARJWsPQAAAABElayEAAAAAESWQrAAAAAARJZC+AAAAABElkNAAAAAAESWQ4gAAAAARJZDz0MVJttElkQXQ05HR0SWRF9DPkqdRJZEp0MQVC9ElkTuAAAAAESWRTYAAAAARJZFfgAAAABElkXGAAAAAESWvGkAAAAARJa8sgAAAABElrz6AAAAAESWvUIAAAAARJa9ikKlvF5Elr3SQ1O/L0SWvhtDkrv0RJa+Y0Oe1WZElr6rQ5PuTESWvvNDaqxTRJa/O0MEwgFElr+EAAAAAESWv8wAAAAARJbAFAAAAABElsBcAAAAAESZ16UAAAAARJnX8AAAAABEmdg7AAAAAESZ2IcAAAAARJnY0kH4EwBEmdkdQzrIE0SZ2WhDr/tKRJnZs0PPruhEmdn/Q6dHFESZ2kpDV+ORRJnalUNWgi1EmdrgQ3EyH0SZ2ytDPfUTRJnbd0KWcMBEmdvCAAAAAESZ3A0AAAAARJncWAAAAABEmdykAAAAAESaWekAAAAARJpaNQAAAABEmlqAAAAAAESaWswAAAAARJpbGEMn4mNEmltjQ4AIPESaW69DX28TRJpb+0Krmh5EmlxHAAAAAESaXJIAAAAARJpc3gAAAABEml0qAAAAAESdv/QAAAAARJ3AQwAAAABEncCSAAAAAESdwOEAAAAARJ3BMEI6TyhEncGAQz/wr0Sdwc9DlDxyRJ3CHkOVGYJEncJtQzpUF0SdwrxCKT/gRJ3DCwAAAABEncNaAAAAAESdw6kAAAAARJ3D+AAAAABEpBQCAAAAAESkFFcAAAAARKQUrQAAAABEpBUCAAAAAESkFVhDNdeLRKQVrUNA8RVEpBYDQzh+m0SkFlkAAAAARKQWrgAAAABEpBcEAAAAAESkF1kAAAAARKSmiAAAAABEpKbfAAAAAESkpzUAAAAARKSniwAAAABEpKfhQxLIMUSkqDdDaeADRKSojUNwUU9EpKjjQ0nNC0SkqTpDL+FvRKSpkAAAAABEpKnmAAAAAESkqjwAAAAARKSqkgAAAABEqfuwAAAAAESp/AwAAAAARKn8aAAAAABEqfzEAAAAAESp/SBDNOW9RKn9e0NlYU9Eqf3XQ0R360Sp/jNCwDr2RKn+jwAAAABEqf7rAAAAAESp/0YAAAAARKn/ogAAAABErEarAAAAAESsRwoAAAAARKxHaAAAAABErEfGAAAAAESsSCVCE4y4RKxIg0NICpdErEjhQ4IvIkSsSUBDKx7dRKxJngAAAABErEn8AAAAAESsSloAAAAARKxKuQAAAABEtQkRAAAAAES1CXkAAAAARLUJ4QAAAABEtQpKAAAAAES1CrJDJhD9RLULGkN2IZtEtQuCQ0j6M0S1C+pCqdwmRLUMUgAAAABEtQy6AAAAAES1DSMAAAAARLUNiwAAAABEt1aPAAAAAES3VvkAAAAARLdXZAAAAABEt1fPAAAAAES3WDpDesoPRLdYpUPA01ZEt1kPQ9YeGkS3WXpDvpdCRLdZ5UOX1rpEt1pQAAAAAES3WrsAAAAARLdbJgAAAABEt1uQAAAAAETFGvIAAAAARMUbbQAAAABExRvpAAAAAETFHGQAAAAARMUc30JvoHRExR1bQ31mOUTFHdZDt+aSRMUeUkPAB3pExR7NQ6mPcETFH0lDgLBwRMUfxEMHHK9ExSBAAAAAAETFILsAAAAARMUhNwAAAABExSGyAAAAAETHFHgAAAAARMcU9gAAAABExxV0AAAAAETHFfIAAAAARMcWcEM1n/lExxbuQ1u19UTHF2xDRxs7RMcX6kLjC6ZExxhoAAAAAETHGOYAAAAARMcZZAAAAABExxniAAAAAETH/rQAAAAARMf/MwAAAABEx/+yAAAAAETIADEAAAAA'
base64.b64decode(your_string)

Well first of all you need to assign the finished product to a variable to be able to be printed out:

code_string = base64.b64decode(your_string)

Then like any beginner programmer would know, you would print the results out: Python 2.7x:

print code_string

Python 3.x:

print(code_string)

After the successful decoding, you will get a string about the size of the not yet decoded string. I hope this helps you!

1

After decoding, it looks like the data is a repeating structure that's 8 bytes long, or some multiple thereof. It's just binary data though; what it might mean, I have no idea. There are 2064 entries, which means that it could be a list of 2064 8-byte items down to 129 128-byte items.

1
  • How to know that there are 2064 entries?
    – ladyfafa
    Aug 13 '10 at 0:58
1

I used chardet to detect possible encoding of this data (if it's text), but I get:

{'confidence': 0.0, 'encoding': None}. 

Then I tried to use pickle.load and got nothing again. I tried to save this as a file, tested many different formats and failed here too. Maybe you tell us what type does these 16512 bytes of mysterious data have?

6
  • I am sorry, I dont know it either, but I got a c++ code to deal with this data, but I dont know how to post the c++ code here in a right formate, seems to be too long (like -200 characters left) to be posted here :(
    – ladyfafa
    Aug 12 '10 at 19:19
  • maybe the C++ code is the key to this mysterious data, but I was puzzled by it actually, I mean I need to work with python to decode it correctly
    – ladyfafa
    Aug 12 '10 at 19:20
  • post at pastebin.com and give us the link. Problem bust be in different charmaps for base64 encoding and decoding.
    – Odomontois
    Aug 12 '10 at 19:31
  • I'm fairly bad with C++, but it does seem that the code is pulling out a 32-bit float, big-endian, like I was trying to do. I can't tell what the structure of peak p is, but I think that's what you just have to feed to struct.unpack
    – Nick T
    Aug 12 '10 at 20:53
  • me neither, could be a structure for storing those elements
    – ladyfafa
    Aug 12 '10 at 21:54
1

Note Slipstream's response, that base64.b64encode and base64.b64decode need a bytes-like object, not a string.

>>> import base64
>>> a = '{"name": "John", "age": 42}'
>>> base64.b64encode(a)
Traceback (most recent call last):
  File "<input>", line 1, in <module>
  File "/usr/lib/python3.6/base64.py", line 58, in b64encode
    encoded = binascii.b2a_base64(s, newline=False)
TypeError: a bytes-like object is required, not 'str'

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.