mirror of
https://github.com/SickGear/SickGear.git
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175 lines
6.2 KiB
Python
175 lines
6.2 KiB
Python
# Copyright (c) 2012 Amazon.com, Inc. or its affiliates. All Rights Reserved
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#
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# Permission is hereby granted, free of charge, to any person obtaining a
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# copy of this software and associated documentation files (the
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# "Software"), to deal in the Software without restriction, including
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# without limitation the rights to use, copy, modify, merge, publish, dis-
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# tribute, sublicense, and/or sell copies of the Software, and to permit
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# persons to whom the Software is furnished to do so, subject to the fol-
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# lowing conditions:
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#
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# The above copyright notice and this permission notice shall be included
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# in all copies or substantial portions of the Software.
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#
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# THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS
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# OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABIL-
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# ITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT
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# SHALL THE AUTHOR BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY,
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# WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
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# OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS
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# IN THE SOFTWARE.
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#
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import hashlib
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import math
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import binascii
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from boto.compat import six
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_MEGABYTE = 1024 * 1024
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DEFAULT_PART_SIZE = 4 * _MEGABYTE
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MAXIMUM_NUMBER_OF_PARTS = 10000
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def minimum_part_size(size_in_bytes, default_part_size=DEFAULT_PART_SIZE):
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"""Calculate the minimum part size needed for a multipart upload.
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Glacier allows a maximum of 10,000 parts per upload. It also
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states that the maximum archive size is 10,000 * 4 GB, which means
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the part size can range from 1MB to 4GB (provided it is one 1MB
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multiplied by a power of 2).
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This function will compute what the minimum part size must be in
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order to upload a file of size ``size_in_bytes``.
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It will first check if ``default_part_size`` is sufficient for
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a part size given the ``size_in_bytes``. If this is not the case,
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then the smallest part size than can accomodate a file of size
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``size_in_bytes`` will be returned.
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If the file size is greater than the maximum allowed archive
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size of 10,000 * 4GB, a ``ValueError`` will be raised.
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"""
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# The default part size (4 MB) will be too small for a very large
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# archive, as there is a limit of 10,000 parts in a multipart upload.
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# This puts the maximum allowed archive size with the default part size
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# at 40,000 MB. We need to do a sanity check on the part size, and find
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# one that works if the default is too small.
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part_size = _MEGABYTE
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if (default_part_size * MAXIMUM_NUMBER_OF_PARTS) < size_in_bytes:
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if size_in_bytes > (4096 * _MEGABYTE * 10000):
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raise ValueError("File size too large: %s" % size_in_bytes)
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min_part_size = size_in_bytes / 10000
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power = 3
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while part_size < min_part_size:
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part_size = math.ldexp(_MEGABYTE, power)
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power += 1
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part_size = int(part_size)
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else:
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part_size = default_part_size
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return part_size
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def chunk_hashes(bytestring, chunk_size=_MEGABYTE):
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chunk_count = int(math.ceil(len(bytestring) / float(chunk_size)))
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hashes = []
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for i in range(chunk_count):
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start = i * chunk_size
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end = (i + 1) * chunk_size
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hashes.append(hashlib.sha256(bytestring[start:end]).digest())
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if not hashes:
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return [hashlib.sha256(b'').digest()]
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return hashes
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def tree_hash(fo):
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"""
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Given a hash of each 1MB chunk (from chunk_hashes) this will hash
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together adjacent hashes until it ends up with one big one. So a
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tree of hashes.
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"""
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hashes = []
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hashes.extend(fo)
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while len(hashes) > 1:
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new_hashes = []
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while True:
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if len(hashes) > 1:
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first = hashes.pop(0)
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second = hashes.pop(0)
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new_hashes.append(hashlib.sha256(first + second).digest())
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elif len(hashes) == 1:
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only = hashes.pop(0)
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new_hashes.append(only)
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else:
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break
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hashes.extend(new_hashes)
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return hashes[0]
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def compute_hashes_from_fileobj(fileobj, chunk_size=1024 * 1024):
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"""Compute the linear and tree hash from a fileobj.
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This function will compute the linear/tree hash of a fileobj
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in a single pass through the fileobj.
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:param fileobj: A file like object.
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:param chunk_size: The size of the chunks to use for the tree
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hash. This is also the buffer size used to read from
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`fileobj`.
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:rtype: tuple
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:return: A tuple of (linear_hash, tree_hash). Both hashes
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are returned in hex.
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"""
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# Python 3+, not binary
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if six.PY3 and hasattr(fileobj, 'mode') and 'b' not in fileobj.mode:
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raise ValueError('File-like object must be opened in binary mode!')
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linear_hash = hashlib.sha256()
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chunks = []
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chunk = fileobj.read(chunk_size)
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while chunk:
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# It's possible to get a file-like object that has no mode (checked
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# above) and returns something other than bytes (e.g. str). So here
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# we try to catch that and encode to bytes.
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if not isinstance(chunk, bytes):
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chunk = chunk.encode(getattr(fileobj, 'encoding', '') or 'utf-8')
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linear_hash.update(chunk)
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chunks.append(hashlib.sha256(chunk).digest())
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chunk = fileobj.read(chunk_size)
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if not chunks:
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chunks = [hashlib.sha256(b'').digest()]
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return linear_hash.hexdigest(), bytes_to_hex(tree_hash(chunks))
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def bytes_to_hex(str_as_bytes):
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return binascii.hexlify(str_as_bytes)
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def tree_hash_from_str(str_as_bytes):
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"""
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:type str_as_bytes: str
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:param str_as_bytes: The string for which to compute the tree hash.
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:rtype: str
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:return: The computed tree hash, returned as hex.
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"""
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return bytes_to_hex(tree_hash(chunk_hashes(str_as_bytes)))
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class ResettingFileSender(object):
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def __init__(self, archive):
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self._archive = archive
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self._starting_offset = archive.tell()
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def __call__(self, connection, method, path, body, headers):
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try:
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connection.request(method, path, self._archive, headers)
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return connection.getresponse()
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finally:
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self._archive.seek(self._starting_offset)
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