s3-tests/s3tests/realistic.py

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import hashlib
import random
import string
import struct
import time
import math
import tempfile
import shutil
import os
NANOSECOND = int(1e9)
def generate_file_contents(size):
"""
A helper function to generate binary contents for a given size, and
calculates the md5 hash of the contents appending itself at the end of the
blob.
It uses sha1's hexdigest which is 40 chars long. So any binary generated
should remove the last 40 chars from the blob to retrieve the original hash
and binary so that validity can be proved.
"""
size = int(size)
contents = os.urandom(size)
content_hash = hashlib.sha1(contents).hexdigest()
return contents + content_hash
class FileValidator(object):
def __init__(self, f=None):
self._file = tempfile.SpooledTemporaryFile()
self.original_hash = None
self.new_hash = None
if f:
f.seek(0)
shutil.copyfileobj(f, self._file)
def valid(self):
"""
Returns True if this file looks valid. The file is valid if the end
of the file has the md5 digest for the first part of the file.
"""
self._file.seek(0)
contents = self._file.read()
self.original_hash, binary = contents[-40:], contents[:-40]
self.new_hash = hashlib.sha1(binary).hexdigest()
if not self.new_hash == self.original_hash:
print('original hash: ', self.original_hash)
print('new hash: ', self.new_hash)
print('size: ', self._file.tell())
return False
return True
# XXX not sure if we need all of these
def seek(self, offset, whence=os.SEEK_SET):
self._file.seek(offset, whence)
def tell(self):
return self._file.tell()
def read(self, size=-1):
return self._file.read(size)
def write(self, data):
self._file.write(data)
self._file.seek(0)
class RandomContentFile(object):
def __init__(self, size, seed):
self.size = size
self.seed = seed
self.random = random.Random(self.seed)
# Boto likes to seek once more after it's done reading, so we need to save the last chunks/seek value.
self.last_chunks = self.chunks = None
self.last_seek = None
# Let seek initialize the rest of it, rather than dup code
self.seek(0)
def _mark_chunk(self):
self.chunks.append([self.offset, int(round((time.time() - self.last_seek) * NANOSECOND))])
def seek(self, offset, whence=os.SEEK_SET):
if whence == os.SEEK_SET:
self.offset = offset
elif whence == os.SEEK_END:
self.offset = self.size + offset;
elif whence == os.SEEK_CUR:
self.offset += offset
assert self.offset == 0
self.random.seed(self.seed)
self.buffer = ''
self.hash = hashlib.md5()
self.digest_size = self.hash.digest_size
self.digest = None
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# Save the last seek time as our start time, and the last chunks
self.last_chunks = self.chunks
# Before emptying.
self.last_seek = time.time()
self.chunks = []
def tell(self):
return self.offset
def _generate(self):
# generate and return a chunk of pseudorandom data
size = min(self.size, 1*1024*1024) # generate at most 1 MB at a time
chunks = int(math.ceil(size/8.0)) # number of 8-byte chunks to create
l = [self.random.getrandbits(64) for _ in range(chunks)]
s = struct.pack(chunks*'Q', *l)
return s
def read(self, size=-1):
if size < 0:
size = self.size - self.offset
r = []
random_count = min(size, self.size - self.offset - self.digest_size)
if random_count > 0:
while len(self.buffer) < random_count:
self.buffer += self._generate()
self.offset += random_count
size -= random_count
data, self.buffer = self.buffer[:random_count], self.buffer[random_count:]
if self.hash is not None:
self.hash.update(data)
r.append(data)
digest_count = min(size, self.size - self.offset)
if digest_count > 0:
if self.digest is None:
self.digest = self.hash.digest()
self.hash = None
self.offset += digest_count
size -= digest_count
data = self.digest[:digest_count]
r.append(data)
self._mark_chunk()
return ''.join(r)
class PrecomputedContentFile(object):
def __init__(self, f):
self._file = tempfile.SpooledTemporaryFile()
f.seek(0)
shutil.copyfileobj(f, self._file)
self.last_chunks = self.chunks = None
self.seek(0)
def seek(self, offset, whence=os.SEEK_SET):
self._file.seek(offset, whence)
if self.tell() == 0:
# only reset the chunks when seeking to the beginning
self.last_chunks = self.chunks
self.last_seek = time.time()
self.chunks = []
def tell(self):
return self._file.tell()
def read(self, size=-1):
data = self._file.read(size)
self._mark_chunk()
return data
def _mark_chunk(self):
elapsed = time.time() - self.last_seek
elapsed_nsec = int(round(elapsed * NANOSECOND))
self.chunks.append([self.tell(), elapsed_nsec])
class FileVerifier(object):
def __init__(self):
self.size = 0
self.hash = hashlib.md5()
self.buf = ''
self.created_at = time.time()
self.chunks = []
def _mark_chunk(self):
self.chunks.append([self.size, int(round((time.time() - self.created_at) * NANOSECOND))])
def write(self, data):
self.size += len(data)
self.buf += data
digsz = -1*self.hash.digest_size
new_data, self.buf = self.buf[0:digsz], self.buf[digsz:]
self.hash.update(new_data)
self._mark_chunk()
def valid(self):
"""
Returns True if this file looks valid. The file is valid if the end
of the file has the md5 digest for the first part of the file.
"""
if self.size < self.hash.digest_size:
return self.hash.digest().startswith(self.buf)
return self.buf == self.hash.digest()
def files(mean, stddev, seed=None):
"""
Yields file-like objects with effectively random contents, where
the size of each file follows the normal distribution with `mean`
and `stddev`.
Beware, the file-likeness is very shallow. You can use boto's
`key.set_contents_from_file` to send these to S3, but they are not
full file objects.
The last 128 bits are the MD5 digest of the previous bytes, for
verifying round-trip data integrity. For example, if you
re-download the object and place the contents into a file called
``foo``, the following should print two identical lines:
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python -c 'import sys, hashlib; data=sys.stdin.read(); print hashlib.md5(data[:-16]).hexdigest(); print "".join("%02x" % ord(c) for c in data[-16:])' <foo
Except for objects shorter than 16 bytes, where the second line
will be proportionally shorter.
"""
rand = random.Random(seed)
while True:
while True:
size = int(rand.normalvariate(mean, stddev))
if size >= 0:
break
yield RandomContentFile(size=size, seed=rand.getrandbits(32))
def files2(mean, stddev, seed=None, numfiles=10):
"""
Yields file objects with effectively random contents, where the
size of each file follows the normal distribution with `mean` and
`stddev`.
Rather than continuously generating new files, this pre-computes and
stores `numfiles` files and yields them in a loop.
"""
# pre-compute all the files (and save with TemporaryFiles)
fs = []
for _ in range(numfiles):
t = tempfile.SpooledTemporaryFile()
t.write(generate_file_contents(random.normalvariate(mean, stddev)))
t.seek(0)
fs.append(t)
while True:
for f in fs:
yield f
def names(mean, stddev, charset=None, seed=None):
"""
Yields strings that are somewhat plausible as file names, where
the lenght of each filename follows the normal distribution with
`mean` and `stddev`.
"""
if charset is None:
charset = string.ascii_lowercase
rand = random.Random(seed)
while True:
while True:
length = int(rand.normalvariate(mean, stddev))
if length > 0:
break
name = ''.join(rand.choice(charset) for _ in range(length))
yield name