forked from openkylin/platform_build
1850 lines
68 KiB
Python
1850 lines
68 KiB
Python
# Copyright (C) 2014 The Android Open Source Project
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#
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# Licensed under the Apache License, Version 2.0 (the "License");
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# you may not use this file except in compliance with the License.
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# You may obtain a copy of the License at
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#
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# http://www.apache.org/licenses/LICENSE-2.0
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#
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# Unless required by applicable law or agreed to in writing, software
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# distributed under the License is distributed on an "AS IS" BASIS,
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# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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# See the License for the specific language governing permissions and
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# limitations under the License.
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from __future__ import print_function
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import array
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import copy
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import functools
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import heapq
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import itertools
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import logging
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import multiprocessing
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import os
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import os.path
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import re
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import sys
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import threading
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import zlib
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from collections import deque, namedtuple, OrderedDict
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from hashlib import sha1
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import common
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from rangelib import RangeSet
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__all__ = ["EmptyImage", "DataImage", "BlockImageDiff"]
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logger = logging.getLogger(__name__)
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# The tuple contains the style and bytes of a bsdiff|imgdiff patch.
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PatchInfo = namedtuple("PatchInfo", ["imgdiff", "content"])
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def compute_patch(srcfile, tgtfile, imgdiff=False):
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"""Calls bsdiff|imgdiff to compute the patch data, returns a PatchInfo."""
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patchfile = common.MakeTempFile(prefix='patch-')
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cmd = ['imgdiff', '-z'] if imgdiff else ['bsdiff']
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cmd.extend([srcfile, tgtfile, patchfile])
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# Don't dump the bsdiff/imgdiff commands, which are not useful for the case
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# here, since they contain temp filenames only.
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proc = common.Run(cmd, verbose=False)
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output, _ = proc.communicate()
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if proc.returncode != 0:
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raise ValueError(output)
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with open(patchfile, 'rb') as f:
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return PatchInfo(imgdiff, f.read())
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class Image(object):
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def RangeSha1(self, ranges):
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raise NotImplementedError
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def ReadRangeSet(self, ranges):
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raise NotImplementedError
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def TotalSha1(self, include_clobbered_blocks=False):
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raise NotImplementedError
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def WriteRangeDataToFd(self, ranges, fd):
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raise NotImplementedError
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class EmptyImage(Image):
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"""A zero-length image."""
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def __init__(self):
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self.blocksize = 4096
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self.care_map = RangeSet()
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self.clobbered_blocks = RangeSet()
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self.extended = RangeSet()
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self.total_blocks = 0
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self.file_map = {}
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self.hashtree_info = None
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def RangeSha1(self, ranges):
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return sha1().hexdigest()
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def ReadRangeSet(self, ranges):
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return ()
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def TotalSha1(self, include_clobbered_blocks=False):
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# EmptyImage always carries empty clobbered_blocks, so
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# include_clobbered_blocks can be ignored.
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assert self.clobbered_blocks.size() == 0
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return sha1().hexdigest()
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def WriteRangeDataToFd(self, ranges, fd):
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raise ValueError("Can't write data from EmptyImage to file")
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class DataImage(Image):
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"""An image wrapped around a single string of data."""
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def __init__(self, data, trim=False, pad=False):
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self.data = data
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self.blocksize = 4096
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assert not (trim and pad)
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partial = len(self.data) % self.blocksize
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padded = False
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if partial > 0:
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if trim:
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self.data = self.data[:-partial]
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elif pad:
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self.data += '\0' * (self.blocksize - partial)
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padded = True
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else:
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raise ValueError(("data for DataImage must be multiple of %d bytes "
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"unless trim or pad is specified") %
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(self.blocksize,))
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assert len(self.data) % self.blocksize == 0
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self.total_blocks = len(self.data) / self.blocksize
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self.care_map = RangeSet(data=(0, self.total_blocks))
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# When the last block is padded, we always write the whole block even for
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# incremental OTAs. Because otherwise the last block may get skipped if
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# unchanged for an incremental, but would fail the post-install
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# verification if it has non-zero contents in the padding bytes.
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# Bug: 23828506
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if padded:
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clobbered_blocks = [self.total_blocks-1, self.total_blocks]
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else:
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clobbered_blocks = []
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self.clobbered_blocks = clobbered_blocks
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self.extended = RangeSet()
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zero_blocks = []
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nonzero_blocks = []
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reference = '\0' * self.blocksize
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for i in range(self.total_blocks-1 if padded else self.total_blocks):
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d = self.data[i*self.blocksize : (i+1)*self.blocksize]
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if d == reference:
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zero_blocks.append(i)
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zero_blocks.append(i+1)
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else:
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nonzero_blocks.append(i)
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nonzero_blocks.append(i+1)
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assert zero_blocks or nonzero_blocks or clobbered_blocks
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self.file_map = dict()
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if zero_blocks:
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self.file_map["__ZERO"] = RangeSet(data=zero_blocks)
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if nonzero_blocks:
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self.file_map["__NONZERO"] = RangeSet(data=nonzero_blocks)
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if clobbered_blocks:
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self.file_map["__COPY"] = RangeSet(data=clobbered_blocks)
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def _GetRangeData(self, ranges):
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for s, e in ranges:
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yield self.data[s*self.blocksize:e*self.blocksize]
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def RangeSha1(self, ranges):
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h = sha1()
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for data in self._GetRangeData(ranges): # pylint: disable=not-an-iterable
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h.update(data)
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return h.hexdigest()
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def ReadRangeSet(self, ranges):
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return list(self._GetRangeData(ranges))
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def TotalSha1(self, include_clobbered_blocks=False):
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if not include_clobbered_blocks:
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return self.RangeSha1(self.care_map.subtract(self.clobbered_blocks))
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else:
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return sha1(self.data).hexdigest()
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def WriteRangeDataToFd(self, ranges, fd):
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for data in self._GetRangeData(ranges): # pylint: disable=not-an-iterable
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fd.write(data)
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class FileImage(Image):
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"""An image wrapped around a raw image file."""
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def __init__(self, path, hashtree_info_generator=None):
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self.path = path
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self.blocksize = 4096
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self._file_size = os.path.getsize(self.path)
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self._file = open(self.path, 'r')
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if self._file_size % self.blocksize != 0:
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raise ValueError("Size of file %s must be multiple of %d bytes, but is %d"
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% self.path, self.blocksize, self._file_size)
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self.total_blocks = self._file_size / self.blocksize
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self.care_map = RangeSet(data=(0, self.total_blocks))
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self.clobbered_blocks = RangeSet()
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self.extended = RangeSet()
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self.generator_lock = threading.Lock()
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self.hashtree_info = None
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if hashtree_info_generator:
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self.hashtree_info = hashtree_info_generator.Generate(self)
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zero_blocks = []
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nonzero_blocks = []
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reference = '\0' * self.blocksize
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for i in range(self.total_blocks):
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d = self._file.read(self.blocksize)
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if d == reference:
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zero_blocks.append(i)
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zero_blocks.append(i+1)
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else:
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nonzero_blocks.append(i)
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nonzero_blocks.append(i+1)
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assert zero_blocks or nonzero_blocks
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self.file_map = {}
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if zero_blocks:
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self.file_map["__ZERO"] = RangeSet(data=zero_blocks)
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if nonzero_blocks:
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self.file_map["__NONZERO"] = RangeSet(data=nonzero_blocks)
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if self.hashtree_info:
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self.file_map["__HASHTREE"] = self.hashtree_info.hashtree_range
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def __del__(self):
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self._file.close()
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def _GetRangeData(self, ranges):
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# Use a lock to protect the generator so that we will not run two
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# instances of this generator on the same object simultaneously.
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with self.generator_lock:
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for s, e in ranges:
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self._file.seek(s * self.blocksize)
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for _ in range(s, e):
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yield self._file.read(self.blocksize)
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def RangeSha1(self, ranges):
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h = sha1()
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for data in self._GetRangeData(ranges): # pylint: disable=not-an-iterable
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h.update(data)
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return h.hexdigest()
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def ReadRangeSet(self, ranges):
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return list(self._GetRangeData(ranges))
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def TotalSha1(self, include_clobbered_blocks=False):
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assert not self.clobbered_blocks
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return self.RangeSha1(self.care_map)
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def WriteRangeDataToFd(self, ranges, fd):
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for data in self._GetRangeData(ranges): # pylint: disable=not-an-iterable
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fd.write(data)
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class Transfer(object):
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def __init__(self, tgt_name, src_name, tgt_ranges, src_ranges, tgt_sha1,
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src_sha1, style, by_id):
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self.tgt_name = tgt_name
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self.src_name = src_name
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self.tgt_ranges = tgt_ranges
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self.src_ranges = src_ranges
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self.tgt_sha1 = tgt_sha1
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self.src_sha1 = src_sha1
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self.style = style
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# We use OrderedDict rather than dict so that the output is repeatable;
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# otherwise it would depend on the hash values of the Transfer objects.
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self.goes_before = OrderedDict()
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self.goes_after = OrderedDict()
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self.stash_before = []
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self.use_stash = []
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self.id = len(by_id)
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by_id.append(self)
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self._patch_info = None
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@property
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def patch_info(self):
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return self._patch_info
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@patch_info.setter
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def patch_info(self, info):
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if info:
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assert self.style == "diff"
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self._patch_info = info
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def NetStashChange(self):
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return (sum(sr.size() for (_, sr) in self.stash_before) -
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sum(sr.size() for (_, sr) in self.use_stash))
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def ConvertToNew(self):
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assert self.style != "new"
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self.use_stash = []
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self.style = "new"
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self.src_ranges = RangeSet()
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self.patch_info = None
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def __str__(self):
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return (str(self.id) + ": <" + str(self.src_ranges) + " " + self.style +
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" to " + str(self.tgt_ranges) + ">")
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@functools.total_ordering
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class HeapItem(object):
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def __init__(self, item):
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self.item = item
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# Negate the score since python's heap is a min-heap and we want the
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# maximum score.
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self.score = -item.score
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def clear(self):
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self.item = None
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def __bool__(self):
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return self.item is not None
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# Python 2 uses __nonzero__, while Python 3 uses __bool__.
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__nonzero__ = __bool__
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# The rest operations are generated by functools.total_ordering decorator.
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def __eq__(self, other):
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return self.score == other.score
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def __le__(self, other):
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return self.score <= other.score
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class ImgdiffStats(object):
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"""A class that collects imgdiff stats.
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It keeps track of the files that will be applied imgdiff while generating
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BlockImageDiff. It also logs the ones that cannot use imgdiff, with specific
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reasons. The stats is only meaningful when imgdiff not being disabled by the
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caller of BlockImageDiff. In addition, only files with supported types
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(BlockImageDiff.FileTypeSupportedByImgdiff()) are allowed to be logged.
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"""
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USED_IMGDIFF = "APK files diff'd with imgdiff"
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USED_IMGDIFF_LARGE_APK = "Large APK files split and diff'd with imgdiff"
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# Reasons for not applying imgdiff on APKs.
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SKIPPED_NONMONOTONIC = "Not used imgdiff due to having non-monotonic ranges"
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SKIPPED_SHARED_BLOCKS = "Not used imgdiff due to using shared blocks"
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SKIPPED_INCOMPLETE = "Not used imgdiff due to incomplete RangeSet"
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# The list of valid reasons, which will also be the dumped order in a report.
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REASONS = (
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USED_IMGDIFF,
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USED_IMGDIFF_LARGE_APK,
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SKIPPED_NONMONOTONIC,
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SKIPPED_SHARED_BLOCKS,
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SKIPPED_INCOMPLETE,
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)
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def __init__(self):
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self.stats = {}
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def Log(self, filename, reason):
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"""Logs why imgdiff can or cannot be applied to the given filename.
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Args:
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filename: The filename string.
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reason: One of the reason constants listed in REASONS.
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Raises:
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AssertionError: On unsupported filetypes or invalid reason.
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"""
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assert BlockImageDiff.FileTypeSupportedByImgdiff(filename)
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assert reason in self.REASONS
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if reason not in self.stats:
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self.stats[reason] = set()
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self.stats[reason].add(filename)
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def Report(self):
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"""Prints a report of the collected imgdiff stats."""
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def print_header(header, separator):
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logger.info(header)
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logger.info(separator * len(header) + '\n')
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print_header(' Imgdiff Stats Report ', '=')
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for key in self.REASONS:
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if key not in self.stats:
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continue
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values = self.stats[key]
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section_header = ' {} (count: {}) '.format(key, len(values))
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print_header(section_header, '-')
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logger.info(''.join([' {}\n'.format(name) for name in values]))
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class BlockImageDiff(object):
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"""Generates the diff of two block image objects.
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BlockImageDiff works on two image objects. An image object is anything that
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provides the following attributes:
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blocksize: the size in bytes of a block, currently must be 4096.
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total_blocks: the total size of the partition/image, in blocks.
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care_map: a RangeSet containing which blocks (in the range [0,
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total_blocks) we actually care about; i.e. which blocks contain data.
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file_map: a dict that partitions the blocks contained in care_map into
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smaller domains that are useful for doing diffs on. (Typically a domain
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is a file, and the key in file_map is the pathname.)
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clobbered_blocks: a RangeSet containing which blocks contain data but may
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be altered by the FS. They need to be excluded when verifying the
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partition integrity.
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ReadRangeSet(): a function that takes a RangeSet and returns the data
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contained in the image blocks of that RangeSet. The data is returned as
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a list or tuple of strings; concatenating the elements together should
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produce the requested data. Implementations are free to break up the
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data into list/tuple elements in any way that is convenient.
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RangeSha1(): a function that returns (as a hex string) the SHA-1 hash of
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all the data in the specified range.
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TotalSha1(): a function that returns (as a hex string) the SHA-1 hash of
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all the data in the image (ie, all the blocks in the care_map minus
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clobbered_blocks, or including the clobbered blocks if
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include_clobbered_blocks is True).
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When creating a BlockImageDiff, the src image may be None, in which case the
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list of transfers produced will never read from the original image.
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"""
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def __init__(self, tgt, src=None, threads=None, version=4,
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disable_imgdiff=False):
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if threads is None:
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threads = multiprocessing.cpu_count() // 2
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if threads == 0:
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threads = 1
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self.threads = threads
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self.version = version
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self.transfers = []
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self.src_basenames = {}
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self.src_numpatterns = {}
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self._max_stashed_size = 0
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self.touched_src_ranges = RangeSet()
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self.touched_src_sha1 = None
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self.disable_imgdiff = disable_imgdiff
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self.imgdiff_stats = ImgdiffStats() if not disable_imgdiff else None
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assert version in (3, 4)
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self.tgt = tgt
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if src is None:
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src = EmptyImage()
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self.src = src
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# The updater code that installs the patch always uses 4k blocks.
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assert tgt.blocksize == 4096
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assert src.blocksize == 4096
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# The range sets in each filemap should comprise a partition of
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# the care map.
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self.AssertPartition(src.care_map, src.file_map.values())
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self.AssertPartition(tgt.care_map, tgt.file_map.values())
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@property
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def max_stashed_size(self):
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return self._max_stashed_size
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@staticmethod
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def FileTypeSupportedByImgdiff(filename):
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"""Returns whether the file type is supported by imgdiff."""
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return filename.lower().endswith(('.apk', '.jar', '.zip'))
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def CanUseImgdiff(self, name, tgt_ranges, src_ranges, large_apk=False):
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"""Checks whether we can apply imgdiff for the given RangeSets.
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For files in ZIP format (e.g., APKs, JARs, etc.) we would like to use
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'imgdiff -z' if possible. Because it usually produces significantly smaller
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patches than bsdiff.
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This is permissible if all of the following conditions hold.
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- The imgdiff hasn't been disabled by the caller (e.g. squashfs);
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- The file type is supported by imgdiff;
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- The source and target blocks are monotonic (i.e. the data is stored with
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blocks in increasing order);
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- Both files don't contain shared blocks;
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- Both files have complete lists of blocks;
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- We haven't removed any blocks from the source set.
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If all these conditions are satisfied, concatenating all the blocks in the
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RangeSet in order will produce a valid ZIP file (plus possibly extra zeros
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in the last block). imgdiff is fine with extra zeros at the end of the file.
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Args:
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name: The filename to be diff'd.
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tgt_ranges: The target RangeSet.
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src_ranges: The source RangeSet.
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large_apk: Whether this is to split a large APK.
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Returns:
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A boolean result.
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"""
|
|
if self.disable_imgdiff or not self.FileTypeSupportedByImgdiff(name):
|
|
return False
|
|
|
|
if not tgt_ranges.monotonic or not src_ranges.monotonic:
|
|
self.imgdiff_stats.Log(name, ImgdiffStats.SKIPPED_NONMONOTONIC)
|
|
return False
|
|
|
|
if (tgt_ranges.extra.get('uses_shared_blocks') or
|
|
src_ranges.extra.get('uses_shared_blocks')):
|
|
self.imgdiff_stats.Log(name, ImgdiffStats.SKIPPED_SHARED_BLOCKS)
|
|
return False
|
|
|
|
if tgt_ranges.extra.get('incomplete') or src_ranges.extra.get('incomplete'):
|
|
self.imgdiff_stats.Log(name, ImgdiffStats.SKIPPED_INCOMPLETE)
|
|
return False
|
|
|
|
reason = (ImgdiffStats.USED_IMGDIFF_LARGE_APK if large_apk
|
|
else ImgdiffStats.USED_IMGDIFF)
|
|
self.imgdiff_stats.Log(name, reason)
|
|
return True
|
|
|
|
def Compute(self, prefix):
|
|
# When looking for a source file to use as the diff input for a
|
|
# target file, we try:
|
|
# 1) an exact path match if available, otherwise
|
|
# 2) a exact basename match if available, otherwise
|
|
# 3) a basename match after all runs of digits are replaced by
|
|
# "#" if available, otherwise
|
|
# 4) we have no source for this target.
|
|
self.AbbreviateSourceNames()
|
|
self.FindTransfers()
|
|
|
|
self.FindSequenceForTransfers()
|
|
|
|
# Ensure the runtime stash size is under the limit.
|
|
if common.OPTIONS.cache_size is not None:
|
|
stash_limit = (common.OPTIONS.cache_size *
|
|
common.OPTIONS.stash_threshold / self.tgt.blocksize)
|
|
# Ignore the stash limit and calculate the maximum simultaneously stashed
|
|
# blocks needed.
|
|
_, max_stashed_blocks = self.ReviseStashSize(ignore_stash_limit=True)
|
|
|
|
# We cannot stash more blocks than the stash limit simultaneously. As a
|
|
# result, some 'diff' commands will be converted to new; leading to an
|
|
# unintended large package. To mitigate this issue, we can carefully
|
|
# choose the transfers for conversion. The number '1024' can be further
|
|
# tweaked here to balance the package size and build time.
|
|
if max_stashed_blocks > stash_limit + 1024:
|
|
self.SelectAndConvertDiffTransfersToNew(
|
|
max_stashed_blocks - stash_limit)
|
|
# Regenerate the sequence as the graph has changed.
|
|
self.FindSequenceForTransfers()
|
|
|
|
# Revise the stash size again to keep the size under limit.
|
|
self.ReviseStashSize()
|
|
|
|
# Double-check our work.
|
|
self.AssertSequenceGood()
|
|
self.AssertSha1Good()
|
|
|
|
self.ComputePatches(prefix)
|
|
self.WriteTransfers(prefix)
|
|
|
|
# Report the imgdiff stats.
|
|
if not self.disable_imgdiff:
|
|
self.imgdiff_stats.Report()
|
|
|
|
def WriteTransfers(self, prefix):
|
|
def WriteSplitTransfers(out, style, target_blocks):
|
|
"""Limit the size of operand in command 'new' and 'zero' to 1024 blocks.
|
|
|
|
This prevents the target size of one command from being too large; and
|
|
might help to avoid fsync errors on some devices."""
|
|
|
|
assert style == "new" or style == "zero"
|
|
blocks_limit = 1024
|
|
total = 0
|
|
while target_blocks:
|
|
blocks_to_write = target_blocks.first(blocks_limit)
|
|
out.append("%s %s\n" % (style, blocks_to_write.to_string_raw()))
|
|
total += blocks_to_write.size()
|
|
target_blocks = target_blocks.subtract(blocks_to_write)
|
|
return total
|
|
|
|
out = []
|
|
total = 0
|
|
|
|
# In BBOTA v3+, it uses the hash of the stashed blocks as the stash slot
|
|
# id. 'stashes' records the map from 'hash' to the ref count. The stash
|
|
# will be freed only if the count decrements to zero.
|
|
stashes = {}
|
|
stashed_blocks = 0
|
|
max_stashed_blocks = 0
|
|
|
|
for xf in self.transfers:
|
|
|
|
for _, sr in xf.stash_before:
|
|
sh = self.src.RangeSha1(sr)
|
|
if sh in stashes:
|
|
stashes[sh] += 1
|
|
else:
|
|
stashes[sh] = 1
|
|
stashed_blocks += sr.size()
|
|
self.touched_src_ranges = self.touched_src_ranges.union(sr)
|
|
out.append("stash %s %s\n" % (sh, sr.to_string_raw()))
|
|
|
|
if stashed_blocks > max_stashed_blocks:
|
|
max_stashed_blocks = stashed_blocks
|
|
|
|
free_string = []
|
|
free_size = 0
|
|
|
|
# <# blocks> <src ranges>
|
|
# OR
|
|
# <# blocks> <src ranges> <src locs> <stash refs...>
|
|
# OR
|
|
# <# blocks> - <stash refs...>
|
|
|
|
size = xf.src_ranges.size()
|
|
src_str_buffer = [str(size)]
|
|
|
|
unstashed_src_ranges = xf.src_ranges
|
|
mapped_stashes = []
|
|
for _, sr in xf.use_stash:
|
|
unstashed_src_ranges = unstashed_src_ranges.subtract(sr)
|
|
sh = self.src.RangeSha1(sr)
|
|
sr = xf.src_ranges.map_within(sr)
|
|
mapped_stashes.append(sr)
|
|
assert sh in stashes
|
|
src_str_buffer.append("%s:%s" % (sh, sr.to_string_raw()))
|
|
stashes[sh] -= 1
|
|
if stashes[sh] == 0:
|
|
free_string.append("free %s\n" % (sh,))
|
|
free_size += sr.size()
|
|
stashes.pop(sh)
|
|
|
|
if unstashed_src_ranges:
|
|
src_str_buffer.insert(1, unstashed_src_ranges.to_string_raw())
|
|
if xf.use_stash:
|
|
mapped_unstashed = xf.src_ranges.map_within(unstashed_src_ranges)
|
|
src_str_buffer.insert(2, mapped_unstashed.to_string_raw())
|
|
mapped_stashes.append(mapped_unstashed)
|
|
self.AssertPartition(RangeSet(data=(0, size)), mapped_stashes)
|
|
else:
|
|
src_str_buffer.insert(1, "-")
|
|
self.AssertPartition(RangeSet(data=(0, size)), mapped_stashes)
|
|
|
|
src_str = " ".join(src_str_buffer)
|
|
|
|
# version 3+:
|
|
# zero <rangeset>
|
|
# new <rangeset>
|
|
# erase <rangeset>
|
|
# bsdiff patchstart patchlen srchash tgthash <tgt rangeset> <src_str>
|
|
# imgdiff patchstart patchlen srchash tgthash <tgt rangeset> <src_str>
|
|
# move hash <tgt rangeset> <src_str>
|
|
|
|
tgt_size = xf.tgt_ranges.size()
|
|
|
|
if xf.style == "new":
|
|
assert xf.tgt_ranges
|
|
assert tgt_size == WriteSplitTransfers(out, xf.style, xf.tgt_ranges)
|
|
total += tgt_size
|
|
elif xf.style == "move":
|
|
assert xf.tgt_ranges
|
|
assert xf.src_ranges.size() == tgt_size
|
|
if xf.src_ranges != xf.tgt_ranges:
|
|
# take into account automatic stashing of overlapping blocks
|
|
if xf.src_ranges.overlaps(xf.tgt_ranges):
|
|
temp_stash_usage = stashed_blocks + xf.src_ranges.size()
|
|
if temp_stash_usage > max_stashed_blocks:
|
|
max_stashed_blocks = temp_stash_usage
|
|
|
|
self.touched_src_ranges = self.touched_src_ranges.union(
|
|
xf.src_ranges)
|
|
|
|
out.append("%s %s %s %s\n" % (
|
|
xf.style,
|
|
xf.tgt_sha1,
|
|
xf.tgt_ranges.to_string_raw(), src_str))
|
|
total += tgt_size
|
|
elif xf.style in ("bsdiff", "imgdiff"):
|
|
assert xf.tgt_ranges
|
|
assert xf.src_ranges
|
|
# take into account automatic stashing of overlapping blocks
|
|
if xf.src_ranges.overlaps(xf.tgt_ranges):
|
|
temp_stash_usage = stashed_blocks + xf.src_ranges.size()
|
|
if temp_stash_usage > max_stashed_blocks:
|
|
max_stashed_blocks = temp_stash_usage
|
|
|
|
self.touched_src_ranges = self.touched_src_ranges.union(xf.src_ranges)
|
|
|
|
out.append("%s %d %d %s %s %s %s\n" % (
|
|
xf.style,
|
|
xf.patch_start, xf.patch_len,
|
|
xf.src_sha1,
|
|
xf.tgt_sha1,
|
|
xf.tgt_ranges.to_string_raw(), src_str))
|
|
total += tgt_size
|
|
elif xf.style == "zero":
|
|
assert xf.tgt_ranges
|
|
to_zero = xf.tgt_ranges.subtract(xf.src_ranges)
|
|
assert WriteSplitTransfers(out, xf.style, to_zero) == to_zero.size()
|
|
total += to_zero.size()
|
|
else:
|
|
raise ValueError("unknown transfer style '%s'\n" % xf.style)
|
|
|
|
if free_string:
|
|
out.append("".join(free_string))
|
|
stashed_blocks -= free_size
|
|
|
|
if common.OPTIONS.cache_size is not None:
|
|
# Sanity check: abort if we're going to need more stash space than
|
|
# the allowed size (cache_size * threshold). There are two purposes
|
|
# of having a threshold here. a) Part of the cache may have been
|
|
# occupied by some recovery logs. b) It will buy us some time to deal
|
|
# with the oversize issue.
|
|
cache_size = common.OPTIONS.cache_size
|
|
stash_threshold = common.OPTIONS.stash_threshold
|
|
max_allowed = cache_size * stash_threshold
|
|
assert max_stashed_blocks * self.tgt.blocksize <= max_allowed, \
|
|
'Stash size %d (%d * %d) exceeds the limit %d (%d * %.2f)' % (
|
|
max_stashed_blocks * self.tgt.blocksize, max_stashed_blocks,
|
|
self.tgt.blocksize, max_allowed, cache_size,
|
|
stash_threshold)
|
|
|
|
self.touched_src_sha1 = self.src.RangeSha1(self.touched_src_ranges)
|
|
|
|
if self.tgt.hashtree_info:
|
|
out.append("compute_hash_tree {} {} {} {} {}\n".format(
|
|
self.tgt.hashtree_info.hashtree_range.to_string_raw(),
|
|
self.tgt.hashtree_info.filesystem_range.to_string_raw(),
|
|
self.tgt.hashtree_info.hash_algorithm,
|
|
self.tgt.hashtree_info.salt,
|
|
self.tgt.hashtree_info.root_hash))
|
|
|
|
# Zero out extended blocks as a workaround for bug 20881595.
|
|
if self.tgt.extended:
|
|
assert (WriteSplitTransfers(out, "zero", self.tgt.extended) ==
|
|
self.tgt.extended.size())
|
|
total += self.tgt.extended.size()
|
|
|
|
# We erase all the blocks on the partition that a) don't contain useful
|
|
# data in the new image; b) will not be touched by dm-verity. Out of those
|
|
# blocks, we erase the ones that won't be used in this update at the
|
|
# beginning of an update. The rest would be erased at the end. This is to
|
|
# work around the eMMC issue observed on some devices, which may otherwise
|
|
# get starving for clean blocks and thus fail the update. (b/28347095)
|
|
all_tgt = RangeSet(data=(0, self.tgt.total_blocks))
|
|
all_tgt_minus_extended = all_tgt.subtract(self.tgt.extended)
|
|
new_dontcare = all_tgt_minus_extended.subtract(self.tgt.care_map)
|
|
|
|
erase_first = new_dontcare.subtract(self.touched_src_ranges)
|
|
if erase_first:
|
|
out.insert(0, "erase %s\n" % (erase_first.to_string_raw(),))
|
|
|
|
erase_last = new_dontcare.subtract(erase_first)
|
|
if erase_last:
|
|
out.append("erase %s\n" % (erase_last.to_string_raw(),))
|
|
|
|
out.insert(0, "%d\n" % (self.version,)) # format version number
|
|
out.insert(1, "%d\n" % (total,))
|
|
# v3+: the number of stash slots is unused.
|
|
out.insert(2, "0\n")
|
|
out.insert(3, str(max_stashed_blocks) + "\n")
|
|
|
|
with open(prefix + ".transfer.list", "wb") as f:
|
|
for i in out:
|
|
f.write(i)
|
|
|
|
self._max_stashed_size = max_stashed_blocks * self.tgt.blocksize
|
|
OPTIONS = common.OPTIONS
|
|
if OPTIONS.cache_size is not None:
|
|
max_allowed = OPTIONS.cache_size * OPTIONS.stash_threshold
|
|
logger.info(
|
|
"max stashed blocks: %d (%d bytes), limit: %d bytes (%.2f%%)\n",
|
|
max_stashed_blocks, self._max_stashed_size, max_allowed,
|
|
self._max_stashed_size * 100.0 / max_allowed)
|
|
else:
|
|
logger.info(
|
|
"max stashed blocks: %d (%d bytes), limit: <unknown>\n",
|
|
max_stashed_blocks, self._max_stashed_size)
|
|
|
|
def ReviseStashSize(self, ignore_stash_limit=False):
|
|
""" Revises the transfers to keep the stash size within the size limit.
|
|
|
|
Iterates through the transfer list and calculates the stash size each
|
|
transfer generates. Converts the affected transfers to new if we reach the
|
|
stash limit.
|
|
|
|
Args:
|
|
ignore_stash_limit: Ignores the stash limit and calculates the max
|
|
simultaneous stashed blocks instead. No change will be made to the
|
|
transfer list with this flag.
|
|
|
|
Return:
|
|
A tuple of (tgt blocks converted to new, max stashed blocks)
|
|
"""
|
|
logger.info("Revising stash size...")
|
|
stash_map = {}
|
|
|
|
# Create the map between a stash and its def/use points. For example, for a
|
|
# given stash of (raw_id, sr), stash_map[raw_id] = (sr, def_cmd, use_cmd).
|
|
for xf in self.transfers:
|
|
# Command xf defines (stores) all the stashes in stash_before.
|
|
for stash_raw_id, sr in xf.stash_before:
|
|
stash_map[stash_raw_id] = (sr, xf)
|
|
|
|
# Record all the stashes command xf uses.
|
|
for stash_raw_id, _ in xf.use_stash:
|
|
stash_map[stash_raw_id] += (xf,)
|
|
|
|
max_allowed_blocks = None
|
|
if not ignore_stash_limit:
|
|
# Compute the maximum blocks available for stash based on /cache size and
|
|
# the threshold.
|
|
cache_size = common.OPTIONS.cache_size
|
|
stash_threshold = common.OPTIONS.stash_threshold
|
|
max_allowed_blocks = cache_size * stash_threshold / self.tgt.blocksize
|
|
|
|
# See the comments for 'stashes' in WriteTransfers().
|
|
stashes = {}
|
|
stashed_blocks = 0
|
|
new_blocks = 0
|
|
max_stashed_blocks = 0
|
|
|
|
# Now go through all the commands. Compute the required stash size on the
|
|
# fly. If a command requires excess stash than available, it deletes the
|
|
# stash by replacing the command that uses the stash with a "new" command
|
|
# instead.
|
|
for xf in self.transfers:
|
|
replaced_cmds = []
|
|
|
|
# xf.stash_before generates explicit stash commands.
|
|
for stash_raw_id, sr in xf.stash_before:
|
|
# Check the post-command stashed_blocks.
|
|
stashed_blocks_after = stashed_blocks
|
|
sh = self.src.RangeSha1(sr)
|
|
if sh not in stashes:
|
|
stashed_blocks_after += sr.size()
|
|
|
|
if max_allowed_blocks and stashed_blocks_after > max_allowed_blocks:
|
|
# We cannot stash this one for a later command. Find out the command
|
|
# that will use this stash and replace the command with "new".
|
|
use_cmd = stash_map[stash_raw_id][2]
|
|
replaced_cmds.append(use_cmd)
|
|
logger.info("%10d %9s %s", sr.size(), "explicit", use_cmd)
|
|
else:
|
|
# Update the stashes map.
|
|
if sh in stashes:
|
|
stashes[sh] += 1
|
|
else:
|
|
stashes[sh] = 1
|
|
stashed_blocks = stashed_blocks_after
|
|
max_stashed_blocks = max(max_stashed_blocks, stashed_blocks)
|
|
|
|
# "move" and "diff" may introduce implicit stashes in BBOTA v3. Prior to
|
|
# ComputePatches(), they both have the style of "diff".
|
|
if xf.style == "diff":
|
|
assert xf.tgt_ranges and xf.src_ranges
|
|
if xf.src_ranges.overlaps(xf.tgt_ranges):
|
|
if (max_allowed_blocks and
|
|
stashed_blocks + xf.src_ranges.size() > max_allowed_blocks):
|
|
replaced_cmds.append(xf)
|
|
logger.info("%10d %9s %s", xf.src_ranges.size(), "implicit", xf)
|
|
else:
|
|
# The whole source ranges will be stashed for implicit stashes.
|
|
max_stashed_blocks = max(max_stashed_blocks,
|
|
stashed_blocks + xf.src_ranges.size())
|
|
|
|
# Replace the commands in replaced_cmds with "new"s.
|
|
for cmd in replaced_cmds:
|
|
# It no longer uses any commands in "use_stash". Remove the def points
|
|
# for all those stashes.
|
|
for stash_raw_id, sr in cmd.use_stash:
|
|
def_cmd = stash_map[stash_raw_id][1]
|
|
assert (stash_raw_id, sr) in def_cmd.stash_before
|
|
def_cmd.stash_before.remove((stash_raw_id, sr))
|
|
|
|
# Add up blocks that violates space limit and print total number to
|
|
# screen later.
|
|
new_blocks += cmd.tgt_ranges.size()
|
|
cmd.ConvertToNew()
|
|
|
|
# xf.use_stash may generate free commands.
|
|
for _, sr in xf.use_stash:
|
|
sh = self.src.RangeSha1(sr)
|
|
assert sh in stashes
|
|
stashes[sh] -= 1
|
|
if stashes[sh] == 0:
|
|
stashed_blocks -= sr.size()
|
|
stashes.pop(sh)
|
|
|
|
num_of_bytes = new_blocks * self.tgt.blocksize
|
|
logger.info(
|
|
" Total %d blocks (%d bytes) are packed as new blocks due to "
|
|
"insufficient cache size. Maximum blocks stashed simultaneously: %d",
|
|
new_blocks, num_of_bytes, max_stashed_blocks)
|
|
return new_blocks, max_stashed_blocks
|
|
|
|
def ComputePatches(self, prefix):
|
|
logger.info("Reticulating splines...")
|
|
diff_queue = []
|
|
patch_num = 0
|
|
with open(prefix + ".new.dat", "wb") as new_f:
|
|
for index, xf in enumerate(self.transfers):
|
|
if xf.style == "zero":
|
|
tgt_size = xf.tgt_ranges.size() * self.tgt.blocksize
|
|
logger.info(
|
|
"%10d %10d (%6.2f%%) %7s %s %s", tgt_size, tgt_size, 100.0,
|
|
xf.style, xf.tgt_name, str(xf.tgt_ranges))
|
|
|
|
elif xf.style == "new":
|
|
self.tgt.WriteRangeDataToFd(xf.tgt_ranges, new_f)
|
|
tgt_size = xf.tgt_ranges.size() * self.tgt.blocksize
|
|
logger.info(
|
|
"%10d %10d (%6.2f%%) %7s %s %s", tgt_size, tgt_size, 100.0,
|
|
xf.style, xf.tgt_name, str(xf.tgt_ranges))
|
|
|
|
elif xf.style == "diff":
|
|
# We can't compare src and tgt directly because they may have
|
|
# the same content but be broken up into blocks differently, eg:
|
|
#
|
|
# ["he", "llo"] vs ["h", "ello"]
|
|
#
|
|
# We want those to compare equal, ideally without having to
|
|
# actually concatenate the strings (these may be tens of
|
|
# megabytes).
|
|
if xf.src_sha1 == xf.tgt_sha1:
|
|
# These are identical; we don't need to generate a patch,
|
|
# just issue copy commands on the device.
|
|
xf.style = "move"
|
|
xf.patch_info = None
|
|
tgt_size = xf.tgt_ranges.size() * self.tgt.blocksize
|
|
if xf.src_ranges != xf.tgt_ranges:
|
|
logger.info(
|
|
"%10d %10d (%6.2f%%) %7s %s %s (from %s)", tgt_size, tgt_size,
|
|
100.0, xf.style,
|
|
xf.tgt_name if xf.tgt_name == xf.src_name else (
|
|
xf.tgt_name + " (from " + xf.src_name + ")"),
|
|
str(xf.tgt_ranges), str(xf.src_ranges))
|
|
else:
|
|
if xf.patch_info:
|
|
# We have already generated the patch (e.g. during split of large
|
|
# APKs or reduction of stash size)
|
|
imgdiff = xf.patch_info.imgdiff
|
|
else:
|
|
imgdiff = self.CanUseImgdiff(
|
|
xf.tgt_name, xf.tgt_ranges, xf.src_ranges)
|
|
xf.style = "imgdiff" if imgdiff else "bsdiff"
|
|
diff_queue.append((index, imgdiff, patch_num))
|
|
patch_num += 1
|
|
|
|
else:
|
|
assert False, "unknown style " + xf.style
|
|
|
|
patches = self.ComputePatchesForInputList(diff_queue, False)
|
|
|
|
offset = 0
|
|
with open(prefix + ".patch.dat", "wb") as patch_fd:
|
|
for index, patch_info, _ in patches:
|
|
xf = self.transfers[index]
|
|
xf.patch_len = len(patch_info.content)
|
|
xf.patch_start = offset
|
|
offset += xf.patch_len
|
|
patch_fd.write(patch_info.content)
|
|
|
|
tgt_size = xf.tgt_ranges.size() * self.tgt.blocksize
|
|
logger.info(
|
|
"%10d %10d (%6.2f%%) %7s %s %s %s", xf.patch_len, tgt_size,
|
|
xf.patch_len * 100.0 / tgt_size, xf.style,
|
|
xf.tgt_name if xf.tgt_name == xf.src_name else (
|
|
xf.tgt_name + " (from " + xf.src_name + ")"),
|
|
xf.tgt_ranges, xf.src_ranges)
|
|
|
|
def AssertSha1Good(self):
|
|
"""Check the SHA-1 of the src & tgt blocks in the transfer list.
|
|
|
|
Double check the SHA-1 value to avoid the issue in b/71908713, where
|
|
SparseImage.RangeSha1() messed up with the hash calculation in multi-thread
|
|
environment. That specific problem has been fixed by protecting the
|
|
underlying generator function 'SparseImage._GetRangeData()' with lock.
|
|
"""
|
|
for xf in self.transfers:
|
|
tgt_sha1 = self.tgt.RangeSha1(xf.tgt_ranges)
|
|
assert xf.tgt_sha1 == tgt_sha1
|
|
if xf.style == "diff":
|
|
src_sha1 = self.src.RangeSha1(xf.src_ranges)
|
|
assert xf.src_sha1 == src_sha1
|
|
|
|
def AssertSequenceGood(self):
|
|
# Simulate the sequences of transfers we will output, and check that:
|
|
# - we never read a block after writing it, and
|
|
# - we write every block we care about exactly once.
|
|
|
|
# Start with no blocks having been touched yet.
|
|
touched = array.array("B", "\0" * self.tgt.total_blocks)
|
|
|
|
# Imagine processing the transfers in order.
|
|
for xf in self.transfers:
|
|
# Check that the input blocks for this transfer haven't yet been touched.
|
|
|
|
x = xf.src_ranges
|
|
for _, sr in xf.use_stash:
|
|
x = x.subtract(sr)
|
|
|
|
for s, e in x:
|
|
# Source image could be larger. Don't check the blocks that are in the
|
|
# source image only. Since they are not in 'touched', and won't ever
|
|
# be touched.
|
|
for i in range(s, min(e, self.tgt.total_blocks)):
|
|
assert touched[i] == 0
|
|
|
|
# Check that the output blocks for this transfer haven't yet
|
|
# been touched, and touch all the blocks written by this
|
|
# transfer.
|
|
for s, e in xf.tgt_ranges:
|
|
for i in range(s, e):
|
|
assert touched[i] == 0
|
|
touched[i] = 1
|
|
|
|
if self.tgt.hashtree_info:
|
|
for s, e in self.tgt.hashtree_info.hashtree_range:
|
|
for i in range(s, e):
|
|
assert touched[i] == 0
|
|
touched[i] = 1
|
|
|
|
# Check that we've written every target block.
|
|
for s, e in self.tgt.care_map:
|
|
for i in range(s, e):
|
|
assert touched[i] == 1
|
|
|
|
def FindSequenceForTransfers(self):
|
|
"""Finds a sequence for the given transfers.
|
|
|
|
The goal is to minimize the violation of order dependencies between these
|
|
transfers, so that fewer blocks are stashed when applying the update.
|
|
"""
|
|
|
|
# Clear the existing dependency between transfers
|
|
for xf in self.transfers:
|
|
xf.goes_before = OrderedDict()
|
|
xf.goes_after = OrderedDict()
|
|
|
|
xf.stash_before = []
|
|
xf.use_stash = []
|
|
|
|
# Find the ordering dependencies among transfers (this is O(n^2)
|
|
# in the number of transfers).
|
|
self.GenerateDigraph()
|
|
# Find a sequence of transfers that satisfies as many ordering
|
|
# dependencies as possible (heuristically).
|
|
self.FindVertexSequence()
|
|
# Fix up the ordering dependencies that the sequence didn't
|
|
# satisfy.
|
|
self.ReverseBackwardEdges()
|
|
self.ImproveVertexSequence()
|
|
|
|
def ImproveVertexSequence(self):
|
|
logger.info("Improving vertex order...")
|
|
|
|
# At this point our digraph is acyclic; we reversed any edges that
|
|
# were backwards in the heuristically-generated sequence. The
|
|
# previously-generated order is still acceptable, but we hope to
|
|
# find a better order that needs less memory for stashed data.
|
|
# Now we do a topological sort to generate a new vertex order,
|
|
# using a greedy algorithm to choose which vertex goes next
|
|
# whenever we have a choice.
|
|
|
|
# Make a copy of the edge set; this copy will get destroyed by the
|
|
# algorithm.
|
|
for xf in self.transfers:
|
|
xf.incoming = xf.goes_after.copy()
|
|
xf.outgoing = xf.goes_before.copy()
|
|
|
|
L = [] # the new vertex order
|
|
|
|
# S is the set of sources in the remaining graph; we always choose
|
|
# the one that leaves the least amount of stashed data after it's
|
|
# executed.
|
|
S = [(u.NetStashChange(), u.order, u) for u in self.transfers
|
|
if not u.incoming]
|
|
heapq.heapify(S)
|
|
|
|
while S:
|
|
_, _, xf = heapq.heappop(S)
|
|
L.append(xf)
|
|
for u in xf.outgoing:
|
|
del u.incoming[xf]
|
|
if not u.incoming:
|
|
heapq.heappush(S, (u.NetStashChange(), u.order, u))
|
|
|
|
# if this fails then our graph had a cycle.
|
|
assert len(L) == len(self.transfers)
|
|
|
|
self.transfers = L
|
|
for i, xf in enumerate(L):
|
|
xf.order = i
|
|
|
|
def ReverseBackwardEdges(self):
|
|
"""Reverse unsatisfying edges and compute pairs of stashed blocks.
|
|
|
|
For each transfer, make sure it properly stashes the blocks it touches and
|
|
will be used by later transfers. It uses pairs of (stash_raw_id, range) to
|
|
record the blocks to be stashed. 'stash_raw_id' is an id that uniquely
|
|
identifies each pair. Note that for the same range (e.g. RangeSet("1-5")),
|
|
it is possible to have multiple pairs with different 'stash_raw_id's. Each
|
|
'stash_raw_id' will be consumed by one transfer. In BBOTA v3+, identical
|
|
blocks will be written to the same stash slot in WriteTransfers().
|
|
"""
|
|
|
|
logger.info("Reversing backward edges...")
|
|
in_order = 0
|
|
out_of_order = 0
|
|
stash_raw_id = 0
|
|
stash_size = 0
|
|
|
|
for xf in self.transfers:
|
|
for u in xf.goes_before.copy():
|
|
# xf should go before u
|
|
if xf.order < u.order:
|
|
# it does, hurray!
|
|
in_order += 1
|
|
else:
|
|
# it doesn't, boo. modify u to stash the blocks that it
|
|
# writes that xf wants to read, and then require u to go
|
|
# before xf.
|
|
out_of_order += 1
|
|
|
|
overlap = xf.src_ranges.intersect(u.tgt_ranges)
|
|
assert overlap
|
|
|
|
u.stash_before.append((stash_raw_id, overlap))
|
|
xf.use_stash.append((stash_raw_id, overlap))
|
|
stash_raw_id += 1
|
|
stash_size += overlap.size()
|
|
|
|
# reverse the edge direction; now xf must go after u
|
|
del xf.goes_before[u]
|
|
del u.goes_after[xf]
|
|
xf.goes_after[u] = None # value doesn't matter
|
|
u.goes_before[xf] = None
|
|
|
|
logger.info(
|
|
" %d/%d dependencies (%.2f%%) were violated; %d source blocks "
|
|
"stashed.", out_of_order, in_order + out_of_order,
|
|
(out_of_order * 100.0 / (in_order + out_of_order)) if (
|
|
in_order + out_of_order) else 0.0,
|
|
stash_size)
|
|
|
|
def FindVertexSequence(self):
|
|
logger.info("Finding vertex sequence...")
|
|
|
|
# This is based on "A Fast & Effective Heuristic for the Feedback
|
|
# Arc Set Problem" by P. Eades, X. Lin, and W.F. Smyth. Think of
|
|
# it as starting with the digraph G and moving all the vertices to
|
|
# be on a horizontal line in some order, trying to minimize the
|
|
# number of edges that end up pointing to the left. Left-pointing
|
|
# edges will get removed to turn the digraph into a DAG. In this
|
|
# case each edge has a weight which is the number of source blocks
|
|
# we'll lose if that edge is removed; we try to minimize the total
|
|
# weight rather than just the number of edges.
|
|
|
|
# Make a copy of the edge set; this copy will get destroyed by the
|
|
# algorithm.
|
|
for xf in self.transfers:
|
|
xf.incoming = xf.goes_after.copy()
|
|
xf.outgoing = xf.goes_before.copy()
|
|
xf.score = sum(xf.outgoing.values()) - sum(xf.incoming.values())
|
|
|
|
# We use an OrderedDict instead of just a set so that the output
|
|
# is repeatable; otherwise it would depend on the hash values of
|
|
# the transfer objects.
|
|
G = OrderedDict()
|
|
for xf in self.transfers:
|
|
G[xf] = None
|
|
s1 = deque() # the left side of the sequence, built from left to right
|
|
s2 = deque() # the right side of the sequence, built from right to left
|
|
|
|
heap = []
|
|
for xf in self.transfers:
|
|
xf.heap_item = HeapItem(xf)
|
|
heap.append(xf.heap_item)
|
|
heapq.heapify(heap)
|
|
|
|
# Use OrderedDict() instead of set() to preserve the insertion order. Need
|
|
# to use 'sinks[key] = None' to add key into the set. sinks will look like
|
|
# { key1: None, key2: None, ... }.
|
|
sinks = OrderedDict.fromkeys(u for u in G if not u.outgoing)
|
|
sources = OrderedDict.fromkeys(u for u in G if not u.incoming)
|
|
|
|
def adjust_score(iu, delta):
|
|
iu.score += delta
|
|
iu.heap_item.clear()
|
|
iu.heap_item = HeapItem(iu)
|
|
heapq.heappush(heap, iu.heap_item)
|
|
|
|
while G:
|
|
# Put all sinks at the end of the sequence.
|
|
while sinks:
|
|
new_sinks = OrderedDict()
|
|
for u in sinks:
|
|
if u not in G:
|
|
continue
|
|
s2.appendleft(u)
|
|
del G[u]
|
|
for iu in u.incoming:
|
|
adjust_score(iu, -iu.outgoing.pop(u))
|
|
if not iu.outgoing:
|
|
new_sinks[iu] = None
|
|
sinks = new_sinks
|
|
|
|
# Put all the sources at the beginning of the sequence.
|
|
while sources:
|
|
new_sources = OrderedDict()
|
|
for u in sources:
|
|
if u not in G:
|
|
continue
|
|
s1.append(u)
|
|
del G[u]
|
|
for iu in u.outgoing:
|
|
adjust_score(iu, +iu.incoming.pop(u))
|
|
if not iu.incoming:
|
|
new_sources[iu] = None
|
|
sources = new_sources
|
|
|
|
if not G:
|
|
break
|
|
|
|
# Find the "best" vertex to put next. "Best" is the one that
|
|
# maximizes the net difference in source blocks saved we get by
|
|
# pretending it's a source rather than a sink.
|
|
|
|
while True:
|
|
u = heapq.heappop(heap)
|
|
if u and u.item in G:
|
|
u = u.item
|
|
break
|
|
|
|
s1.append(u)
|
|
del G[u]
|
|
for iu in u.outgoing:
|
|
adjust_score(iu, +iu.incoming.pop(u))
|
|
if not iu.incoming:
|
|
sources[iu] = None
|
|
|
|
for iu in u.incoming:
|
|
adjust_score(iu, -iu.outgoing.pop(u))
|
|
if not iu.outgoing:
|
|
sinks[iu] = None
|
|
|
|
# Now record the sequence in the 'order' field of each transfer,
|
|
# and by rearranging self.transfers to be in the chosen sequence.
|
|
|
|
new_transfers = []
|
|
for x in itertools.chain(s1, s2):
|
|
x.order = len(new_transfers)
|
|
new_transfers.append(x)
|
|
del x.incoming
|
|
del x.outgoing
|
|
|
|
self.transfers = new_transfers
|
|
|
|
def GenerateDigraph(self):
|
|
logger.info("Generating digraph...")
|
|
|
|
# Each item of source_ranges will be:
|
|
# - None, if that block is not used as a source,
|
|
# - an ordered set of transfers.
|
|
source_ranges = []
|
|
for b in self.transfers:
|
|
for s, e in b.src_ranges:
|
|
if e > len(source_ranges):
|
|
source_ranges.extend([None] * (e-len(source_ranges)))
|
|
for i in range(s, e):
|
|
if source_ranges[i] is None:
|
|
source_ranges[i] = OrderedDict.fromkeys([b])
|
|
else:
|
|
source_ranges[i][b] = None
|
|
|
|
for a in self.transfers:
|
|
intersections = OrderedDict()
|
|
for s, e in a.tgt_ranges:
|
|
for i in range(s, e):
|
|
if i >= len(source_ranges):
|
|
break
|
|
# Add all the Transfers in source_ranges[i] to the (ordered) set.
|
|
if source_ranges[i] is not None:
|
|
for j in source_ranges[i]:
|
|
intersections[j] = None
|
|
|
|
for b in intersections:
|
|
if a is b:
|
|
continue
|
|
|
|
# If the blocks written by A are read by B, then B needs to go before A.
|
|
i = a.tgt_ranges.intersect(b.src_ranges)
|
|
if i:
|
|
if b.src_name == "__ZERO":
|
|
# the cost of removing source blocks for the __ZERO domain
|
|
# is (nearly) zero.
|
|
size = 0
|
|
else:
|
|
size = i.size()
|
|
b.goes_before[a] = size
|
|
a.goes_after[b] = size
|
|
|
|
def ComputePatchesForInputList(self, diff_queue, compress_target):
|
|
"""Returns a list of patch information for the input list of transfers.
|
|
|
|
Args:
|
|
diff_queue: a list of transfers with style 'diff'
|
|
compress_target: If True, compresses the target ranges of each
|
|
transfers; and save the size.
|
|
|
|
Returns:
|
|
A list of (transfer order, patch_info, compressed_size) tuples.
|
|
"""
|
|
|
|
if not diff_queue:
|
|
return []
|
|
|
|
if self.threads > 1:
|
|
logger.info("Computing patches (using %d threads)...", self.threads)
|
|
else:
|
|
logger.info("Computing patches...")
|
|
|
|
diff_total = len(diff_queue)
|
|
patches = [None] * diff_total
|
|
error_messages = []
|
|
|
|
# Using multiprocessing doesn't give additional benefits, due to the
|
|
# pattern of the code. The diffing work is done by subprocess.call, which
|
|
# already runs in a separate process (not affected much by the GIL -
|
|
# Global Interpreter Lock). Using multiprocess also requires either a)
|
|
# writing the diff input files in the main process before forking, or b)
|
|
# reopening the image file (SparseImage) in the worker processes. Doing
|
|
# neither of them further improves the performance.
|
|
lock = threading.Lock()
|
|
|
|
def diff_worker():
|
|
while True:
|
|
with lock:
|
|
if not diff_queue:
|
|
return
|
|
xf_index, imgdiff, patch_index = diff_queue.pop()
|
|
xf = self.transfers[xf_index]
|
|
|
|
message = []
|
|
compressed_size = None
|
|
|
|
patch_info = xf.patch_info
|
|
if not patch_info:
|
|
src_file = common.MakeTempFile(prefix="src-")
|
|
with open(src_file, "wb") as fd:
|
|
self.src.WriteRangeDataToFd(xf.src_ranges, fd)
|
|
|
|
tgt_file = common.MakeTempFile(prefix="tgt-")
|
|
with open(tgt_file, "wb") as fd:
|
|
self.tgt.WriteRangeDataToFd(xf.tgt_ranges, fd)
|
|
|
|
try:
|
|
patch_info = compute_patch(src_file, tgt_file, imgdiff)
|
|
except ValueError as e:
|
|
message.append(
|
|
"Failed to generate %s for %s: tgt=%s, src=%s:\n%s" % (
|
|
"imgdiff" if imgdiff else "bsdiff",
|
|
xf.tgt_name if xf.tgt_name == xf.src_name else
|
|
xf.tgt_name + " (from " + xf.src_name + ")",
|
|
xf.tgt_ranges, xf.src_ranges, e.message))
|
|
|
|
if compress_target:
|
|
tgt_data = self.tgt.ReadRangeSet(xf.tgt_ranges)
|
|
try:
|
|
# Compresses with the default level
|
|
compress_obj = zlib.compressobj(6, zlib.DEFLATED, -zlib.MAX_WBITS)
|
|
compressed_data = (compress_obj.compress("".join(tgt_data))
|
|
+ compress_obj.flush())
|
|
compressed_size = len(compressed_data)
|
|
except zlib.error as e:
|
|
message.append(
|
|
"Failed to compress the data in target range {} for {}:\n"
|
|
"{}".format(xf.tgt_ranges, xf.tgt_name, e.message))
|
|
|
|
if message:
|
|
with lock:
|
|
error_messages.extend(message)
|
|
|
|
with lock:
|
|
patches[patch_index] = (xf_index, patch_info, compressed_size)
|
|
|
|
threads = [threading.Thread(target=diff_worker)
|
|
for _ in range(self.threads)]
|
|
for th in threads:
|
|
th.start()
|
|
while threads:
|
|
threads.pop().join()
|
|
|
|
if error_messages:
|
|
logger.error('ERROR:')
|
|
logger.error('\n'.join(error_messages))
|
|
logger.error('\n\n\n')
|
|
sys.exit(1)
|
|
|
|
return patches
|
|
|
|
def SelectAndConvertDiffTransfersToNew(self, violated_stash_blocks):
|
|
"""Converts the diff transfers to reduce the max simultaneous stash.
|
|
|
|
Since the 'new' data is compressed with deflate, we can select the 'diff'
|
|
transfers for conversion by comparing its patch size with the size of the
|
|
compressed data. Ideally, we want to convert the transfers with a small
|
|
size increase, but using a large number of stashed blocks.
|
|
"""
|
|
TransferSizeScore = namedtuple("TransferSizeScore",
|
|
"xf, used_stash_blocks, score")
|
|
|
|
logger.info("Selecting diff commands to convert to new.")
|
|
diff_queue = []
|
|
for xf in self.transfers:
|
|
if xf.style == "diff" and xf.src_sha1 != xf.tgt_sha1:
|
|
use_imgdiff = self.CanUseImgdiff(xf.tgt_name, xf.tgt_ranges,
|
|
xf.src_ranges)
|
|
diff_queue.append((xf.order, use_imgdiff, len(diff_queue)))
|
|
|
|
# Remove the 'move' transfers, and compute the patch & compressed size
|
|
# for the remaining.
|
|
result = self.ComputePatchesForInputList(diff_queue, True)
|
|
|
|
conversion_candidates = []
|
|
for xf_index, patch_info, compressed_size in result:
|
|
xf = self.transfers[xf_index]
|
|
if not xf.patch_info:
|
|
xf.patch_info = patch_info
|
|
|
|
size_ratio = len(xf.patch_info.content) * 100.0 / compressed_size
|
|
diff_style = "imgdiff" if xf.patch_info.imgdiff else "bsdiff"
|
|
logger.info("%s, target size: %d blocks, style: %s, patch size: %d,"
|
|
" compression_size: %d, ratio %.2f%%", xf.tgt_name,
|
|
xf.tgt_ranges.size(), diff_style,
|
|
len(xf.patch_info.content), compressed_size, size_ratio)
|
|
|
|
used_stash_blocks = sum(sr.size() for _, sr in xf.use_stash)
|
|
# Convert the transfer to new if the compressed size is smaller or equal.
|
|
# We don't need to maintain the stash_before lists here because the
|
|
# graph will be regenerated later.
|
|
if len(xf.patch_info.content) >= compressed_size:
|
|
# Add the transfer to the candidate list with negative score. And it
|
|
# will be converted later.
|
|
conversion_candidates.append(TransferSizeScore(xf, used_stash_blocks,
|
|
-1))
|
|
elif used_stash_blocks > 0:
|
|
# This heuristic represents the size increase in the final package to
|
|
# remove per unit of stashed data.
|
|
score = ((compressed_size - len(xf.patch_info.content)) * 100.0
|
|
/ used_stash_blocks)
|
|
conversion_candidates.append(TransferSizeScore(xf, used_stash_blocks,
|
|
score))
|
|
# Transfers with lower score (i.e. less expensive to convert) will be
|
|
# converted first.
|
|
conversion_candidates.sort(key=lambda x: x.score)
|
|
|
|
# TODO(xunchang), improve the logic to find the transfers to convert, e.g.
|
|
# convert the ones that contribute to the max stash, run ReviseStashSize
|
|
# multiple times etc.
|
|
removed_stashed_blocks = 0
|
|
for xf, used_stash_blocks, _ in conversion_candidates:
|
|
logger.info("Converting %s to new", xf.tgt_name)
|
|
xf.ConvertToNew()
|
|
removed_stashed_blocks += used_stash_blocks
|
|
# Experiments show that we will get a smaller package size if we remove
|
|
# slightly more stashed blocks than the violated stash blocks.
|
|
if removed_stashed_blocks >= violated_stash_blocks:
|
|
break
|
|
|
|
logger.info("Removed %d stashed blocks", removed_stashed_blocks)
|
|
|
|
def FindTransfers(self):
|
|
"""Parse the file_map to generate all the transfers."""
|
|
|
|
def AddSplitTransfersWithFixedSizeChunks(tgt_name, src_name, tgt_ranges,
|
|
src_ranges, style, by_id):
|
|
"""Add one or multiple Transfer()s by splitting large files.
|
|
|
|
For BBOTA v3, we need to stash source blocks for resumable feature.
|
|
However, with the growth of file size and the shrink of the cache
|
|
partition source blocks are too large to be stashed. If a file occupies
|
|
too many blocks, we split it into smaller pieces by getting multiple
|
|
Transfer()s.
|
|
|
|
The downside is that after splitting, we may increase the package size
|
|
since the split pieces don't align well. According to our experiments,
|
|
1/8 of the cache size as the per-piece limit appears to be optimal.
|
|
Compared to the fixed 1024-block limit, it reduces the overall package
|
|
size by 30% for volantis, and 20% for angler and bullhead."""
|
|
|
|
pieces = 0
|
|
while (tgt_ranges.size() > max_blocks_per_transfer and
|
|
src_ranges.size() > max_blocks_per_transfer):
|
|
tgt_split_name = "%s-%d" % (tgt_name, pieces)
|
|
src_split_name = "%s-%d" % (src_name, pieces)
|
|
tgt_first = tgt_ranges.first(max_blocks_per_transfer)
|
|
src_first = src_ranges.first(max_blocks_per_transfer)
|
|
|
|
Transfer(tgt_split_name, src_split_name, tgt_first, src_first,
|
|
self.tgt.RangeSha1(tgt_first), self.src.RangeSha1(src_first),
|
|
style, by_id)
|
|
|
|
tgt_ranges = tgt_ranges.subtract(tgt_first)
|
|
src_ranges = src_ranges.subtract(src_first)
|
|
pieces += 1
|
|
|
|
# Handle remaining blocks.
|
|
if tgt_ranges.size() or src_ranges.size():
|
|
# Must be both non-empty.
|
|
assert tgt_ranges.size() and src_ranges.size()
|
|
tgt_split_name = "%s-%d" % (tgt_name, pieces)
|
|
src_split_name = "%s-%d" % (src_name, pieces)
|
|
Transfer(tgt_split_name, src_split_name, tgt_ranges, src_ranges,
|
|
self.tgt.RangeSha1(tgt_ranges), self.src.RangeSha1(src_ranges),
|
|
style, by_id)
|
|
|
|
def AddSplitTransfers(tgt_name, src_name, tgt_ranges, src_ranges, style,
|
|
by_id):
|
|
"""Find all the zip files and split the others with a fixed chunk size.
|
|
|
|
This function will construct a list of zip archives, which will later be
|
|
split by imgdiff to reduce the final patch size. For the other files,
|
|
we will plainly split them based on a fixed chunk size with the potential
|
|
patch size penalty.
|
|
"""
|
|
|
|
assert style == "diff"
|
|
|
|
# Change nothing for small files.
|
|
if (tgt_ranges.size() <= max_blocks_per_transfer and
|
|
src_ranges.size() <= max_blocks_per_transfer):
|
|
Transfer(tgt_name, src_name, tgt_ranges, src_ranges,
|
|
self.tgt.RangeSha1(tgt_ranges), self.src.RangeSha1(src_ranges),
|
|
style, by_id)
|
|
return
|
|
|
|
# Split large APKs with imgdiff, if possible. We're intentionally checking
|
|
# file types one more time (CanUseImgdiff() checks that as well), before
|
|
# calling the costly RangeSha1()s.
|
|
if (self.FileTypeSupportedByImgdiff(tgt_name) and
|
|
self.tgt.RangeSha1(tgt_ranges) != self.src.RangeSha1(src_ranges)):
|
|
if self.CanUseImgdiff(tgt_name, tgt_ranges, src_ranges, True):
|
|
large_apks.append((tgt_name, src_name, tgt_ranges, src_ranges))
|
|
return
|
|
|
|
AddSplitTransfersWithFixedSizeChunks(tgt_name, src_name, tgt_ranges,
|
|
src_ranges, style, by_id)
|
|
|
|
def AddTransfer(tgt_name, src_name, tgt_ranges, src_ranges, style, by_id,
|
|
split=False):
|
|
"""Wrapper function for adding a Transfer()."""
|
|
|
|
# We specialize diff transfers only (which covers bsdiff/imgdiff/move);
|
|
# otherwise add the Transfer() as is.
|
|
if style != "diff" or not split:
|
|
Transfer(tgt_name, src_name, tgt_ranges, src_ranges,
|
|
self.tgt.RangeSha1(tgt_ranges), self.src.RangeSha1(src_ranges),
|
|
style, by_id)
|
|
return
|
|
|
|
# Handle .odex files specially to analyze the block-wise difference. If
|
|
# most of the blocks are identical with only few changes (e.g. header),
|
|
# we will patch the changed blocks only. This avoids stashing unchanged
|
|
# blocks while patching. We limit the analysis to files without size
|
|
# changes only. This is to avoid sacrificing the OTA generation cost too
|
|
# much.
|
|
if (tgt_name.split(".")[-1].lower() == 'odex' and
|
|
tgt_ranges.size() == src_ranges.size()):
|
|
|
|
# 0.5 threshold can be further tuned. The tradeoff is: if only very
|
|
# few blocks remain identical, we lose the opportunity to use imgdiff
|
|
# that may have better compression ratio than bsdiff.
|
|
crop_threshold = 0.5
|
|
|
|
tgt_skipped = RangeSet()
|
|
src_skipped = RangeSet()
|
|
tgt_size = tgt_ranges.size()
|
|
tgt_changed = 0
|
|
for src_block, tgt_block in zip(src_ranges.next_item(),
|
|
tgt_ranges.next_item()):
|
|
src_rs = RangeSet(str(src_block))
|
|
tgt_rs = RangeSet(str(tgt_block))
|
|
if self.src.ReadRangeSet(src_rs) == self.tgt.ReadRangeSet(tgt_rs):
|
|
tgt_skipped = tgt_skipped.union(tgt_rs)
|
|
src_skipped = src_skipped.union(src_rs)
|
|
else:
|
|
tgt_changed += tgt_rs.size()
|
|
|
|
# Terminate early if no clear sign of benefits.
|
|
if tgt_changed > tgt_size * crop_threshold:
|
|
break
|
|
|
|
if tgt_changed < tgt_size * crop_threshold:
|
|
assert tgt_changed + tgt_skipped.size() == tgt_size
|
|
logger.info(
|
|
'%10d %10d (%6.2f%%) %s', tgt_skipped.size(), tgt_size,
|
|
tgt_skipped.size() * 100.0 / tgt_size, tgt_name)
|
|
AddSplitTransfers(
|
|
"%s-skipped" % (tgt_name,),
|
|
"%s-skipped" % (src_name,),
|
|
tgt_skipped, src_skipped, style, by_id)
|
|
|
|
# Intentionally change the file extension to avoid being imgdiff'd as
|
|
# the files are no longer in their original format.
|
|
tgt_name = "%s-cropped" % (tgt_name,)
|
|
src_name = "%s-cropped" % (src_name,)
|
|
tgt_ranges = tgt_ranges.subtract(tgt_skipped)
|
|
src_ranges = src_ranges.subtract(src_skipped)
|
|
|
|
# Possibly having no changed blocks.
|
|
if not tgt_ranges:
|
|
return
|
|
|
|
# Add the transfer(s).
|
|
AddSplitTransfers(
|
|
tgt_name, src_name, tgt_ranges, src_ranges, style, by_id)
|
|
|
|
def ParseAndValidateSplitInfo(patch_size, tgt_ranges, src_ranges,
|
|
split_info):
|
|
"""Parse the split_info and return a list of info tuples.
|
|
|
|
Args:
|
|
patch_size: total size of the patch file.
|
|
tgt_ranges: Ranges of the target file within the original image.
|
|
src_ranges: Ranges of the source file within the original image.
|
|
split_info format:
|
|
imgdiff version#
|
|
count of pieces
|
|
<patch_size_1> <tgt_size_1> <src_ranges_1>
|
|
...
|
|
<patch_size_n> <tgt_size_n> <src_ranges_n>
|
|
|
|
Returns:
|
|
[patch_start, patch_len, split_tgt_ranges, split_src_ranges]
|
|
"""
|
|
|
|
version = int(split_info[0])
|
|
assert version == 2
|
|
count = int(split_info[1])
|
|
assert len(split_info) - 2 == count
|
|
|
|
split_info_list = []
|
|
patch_start = 0
|
|
tgt_remain = copy.deepcopy(tgt_ranges)
|
|
# each line has the format <patch_size>, <tgt_size>, <src_ranges>
|
|
for line in split_info[2:]:
|
|
info = line.split()
|
|
assert len(info) == 3
|
|
patch_length = int(info[0])
|
|
|
|
split_tgt_size = int(info[1])
|
|
assert split_tgt_size % 4096 == 0
|
|
assert split_tgt_size / 4096 <= tgt_remain.size()
|
|
split_tgt_ranges = tgt_remain.first(split_tgt_size / 4096)
|
|
tgt_remain = tgt_remain.subtract(split_tgt_ranges)
|
|
|
|
# Find the split_src_ranges within the image file from its relative
|
|
# position in file.
|
|
split_src_indices = RangeSet.parse_raw(info[2])
|
|
split_src_ranges = RangeSet()
|
|
for r in split_src_indices:
|
|
curr_range = src_ranges.first(r[1]).subtract(src_ranges.first(r[0]))
|
|
assert not split_src_ranges.overlaps(curr_range)
|
|
split_src_ranges = split_src_ranges.union(curr_range)
|
|
|
|
split_info_list.append((patch_start, patch_length,
|
|
split_tgt_ranges, split_src_ranges))
|
|
patch_start += patch_length
|
|
|
|
# Check that the sizes of all the split pieces add up to the final file
|
|
# size for patch and target.
|
|
assert tgt_remain.size() == 0
|
|
assert patch_start == patch_size
|
|
return split_info_list
|
|
|
|
def SplitLargeApks():
|
|
"""Split the large apks files.
|
|
|
|
Example: Chrome.apk will be split into
|
|
src-0: Chrome.apk-0, tgt-0: Chrome.apk-0
|
|
src-1: Chrome.apk-1, tgt-1: Chrome.apk-1
|
|
...
|
|
|
|
After the split, the target pieces are continuous and block aligned; and
|
|
the source pieces are mutually exclusive. During the split, we also
|
|
generate and save the image patch between src-X & tgt-X. This patch will
|
|
be valid because the block ranges of src-X & tgt-X will always stay the
|
|
same afterwards; but there's a chance we don't use the patch if we
|
|
convert the "diff" command into "new" or "move" later.
|
|
"""
|
|
|
|
while True:
|
|
with transfer_lock:
|
|
if not large_apks:
|
|
return
|
|
tgt_name, src_name, tgt_ranges, src_ranges = large_apks.pop(0)
|
|
|
|
src_file = common.MakeTempFile(prefix="src-")
|
|
tgt_file = common.MakeTempFile(prefix="tgt-")
|
|
with open(src_file, "wb") as src_fd:
|
|
self.src.WriteRangeDataToFd(src_ranges, src_fd)
|
|
with open(tgt_file, "wb") as tgt_fd:
|
|
self.tgt.WriteRangeDataToFd(tgt_ranges, tgt_fd)
|
|
|
|
patch_file = common.MakeTempFile(prefix="patch-")
|
|
patch_info_file = common.MakeTempFile(prefix="split_info-")
|
|
cmd = ["imgdiff", "-z",
|
|
"--block-limit={}".format(max_blocks_per_transfer),
|
|
"--split-info=" + patch_info_file,
|
|
src_file, tgt_file, patch_file]
|
|
proc = common.Run(cmd)
|
|
imgdiff_output, _ = proc.communicate()
|
|
assert proc.returncode == 0, \
|
|
"Failed to create imgdiff patch between {} and {}:\n{}".format(
|
|
src_name, tgt_name, imgdiff_output)
|
|
|
|
with open(patch_info_file) as patch_info:
|
|
lines = patch_info.readlines()
|
|
|
|
patch_size_total = os.path.getsize(patch_file)
|
|
split_info_list = ParseAndValidateSplitInfo(patch_size_total,
|
|
tgt_ranges, src_ranges,
|
|
lines)
|
|
for index, (patch_start, patch_length, split_tgt_ranges,
|
|
split_src_ranges) in enumerate(split_info_list):
|
|
with open(patch_file) as f:
|
|
f.seek(patch_start)
|
|
patch_content = f.read(patch_length)
|
|
|
|
split_src_name = "{}-{}".format(src_name, index)
|
|
split_tgt_name = "{}-{}".format(tgt_name, index)
|
|
split_large_apks.append((split_tgt_name,
|
|
split_src_name,
|
|
split_tgt_ranges,
|
|
split_src_ranges,
|
|
patch_content))
|
|
|
|
logger.info("Finding transfers...")
|
|
|
|
large_apks = []
|
|
split_large_apks = []
|
|
cache_size = common.OPTIONS.cache_size
|
|
split_threshold = 0.125
|
|
max_blocks_per_transfer = int(cache_size * split_threshold /
|
|
self.tgt.blocksize)
|
|
empty = RangeSet()
|
|
for tgt_fn, tgt_ranges in sorted(self.tgt.file_map.items()):
|
|
if tgt_fn == "__ZERO":
|
|
# the special "__ZERO" domain is all the blocks not contained
|
|
# in any file and that are filled with zeros. We have a
|
|
# special transfer style for zero blocks.
|
|
src_ranges = self.src.file_map.get("__ZERO", empty)
|
|
AddTransfer(tgt_fn, "__ZERO", tgt_ranges, src_ranges,
|
|
"zero", self.transfers)
|
|
continue
|
|
|
|
elif tgt_fn == "__COPY":
|
|
# "__COPY" domain includes all the blocks not contained in any
|
|
# file and that need to be copied unconditionally to the target.
|
|
AddTransfer(tgt_fn, None, tgt_ranges, empty, "new", self.transfers)
|
|
continue
|
|
|
|
elif tgt_fn == "__HASHTREE":
|
|
continue
|
|
|
|
elif tgt_fn in self.src.file_map:
|
|
# Look for an exact pathname match in the source.
|
|
AddTransfer(tgt_fn, tgt_fn, tgt_ranges, self.src.file_map[tgt_fn],
|
|
"diff", self.transfers, True)
|
|
continue
|
|
|
|
b = os.path.basename(tgt_fn)
|
|
if b in self.src_basenames:
|
|
# Look for an exact basename match in the source.
|
|
src_fn = self.src_basenames[b]
|
|
AddTransfer(tgt_fn, src_fn, tgt_ranges, self.src.file_map[src_fn],
|
|
"diff", self.transfers, True)
|
|
continue
|
|
|
|
b = re.sub("[0-9]+", "#", b)
|
|
if b in self.src_numpatterns:
|
|
# Look for a 'number pattern' match (a basename match after
|
|
# all runs of digits are replaced by "#"). (This is useful
|
|
# for .so files that contain version numbers in the filename
|
|
# that get bumped.)
|
|
src_fn = self.src_numpatterns[b]
|
|
AddTransfer(tgt_fn, src_fn, tgt_ranges, self.src.file_map[src_fn],
|
|
"diff", self.transfers, True)
|
|
continue
|
|
|
|
AddTransfer(tgt_fn, None, tgt_ranges, empty, "new", self.transfers)
|
|
|
|
transfer_lock = threading.Lock()
|
|
threads = [threading.Thread(target=SplitLargeApks)
|
|
for _ in range(self.threads)]
|
|
for th in threads:
|
|
th.start()
|
|
while threads:
|
|
threads.pop().join()
|
|
|
|
# Sort the split transfers for large apks to generate a determinate package.
|
|
split_large_apks.sort()
|
|
for (tgt_name, src_name, tgt_ranges, src_ranges,
|
|
patch) in split_large_apks:
|
|
transfer_split = Transfer(tgt_name, src_name, tgt_ranges, src_ranges,
|
|
self.tgt.RangeSha1(tgt_ranges),
|
|
self.src.RangeSha1(src_ranges),
|
|
"diff", self.transfers)
|
|
transfer_split.patch_info = PatchInfo(True, patch)
|
|
|
|
def AbbreviateSourceNames(self):
|
|
for k in self.src.file_map.keys():
|
|
b = os.path.basename(k)
|
|
self.src_basenames[b] = k
|
|
b = re.sub("[0-9]+", "#", b)
|
|
self.src_numpatterns[b] = k
|
|
|
|
@staticmethod
|
|
def AssertPartition(total, seq):
|
|
"""Assert that all the RangeSets in 'seq' form a partition of the
|
|
'total' RangeSet (ie, they are nonintersecting and their union
|
|
equals 'total')."""
|
|
|
|
so_far = RangeSet()
|
|
for i in seq:
|
|
assert not so_far.overlaps(i)
|
|
so_far = so_far.union(i)
|
|
assert so_far == total
|