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OpenStack_Swift源代码分析——ObjectReplicator源代码分析(2)
1、Replicator运行代码具体分析
def replicate(self, override_devices=None, override_partitions=None): """Run a replication pass""" self.start = time.time() self.suffix_count = 0 self.suffix_sync = 0 self.suffix_hash = 0 self.replication_count = 0 self.last_replication_count = -1 self.partition_times = [] if override_devices is None: override_devices = [] if override_partitions is None: override_partitions = [] #heartbeat 为心跳函数 依据配置,配置没有 默觉得 300 stats = eventlet.spawn(self.heartbeat) #detect_lockup 检查死锁 lockup_detector = eventlet.spawn(self.detect_lockups) eventlet.sleep() # Give spawns a cycle try: #replication 的 woker 数量 self.run_pool = GreenPool(size=self.concurrency) # Returns a sorted list of jobs (dictionaries) that specify the # partitions, nodes, etc to be synced. # 返回专门为分区,节点同步工作的排序的列表 # jobs = self.collect_jobs() for job in jobs: #重写设备 if override_devices and job[‘device‘] not in override_devices: continue #重写分区 if override_partitions and job[‘partition‘] not in override_partitions: continue #假设重写设备及其重写分区在job 中 dev_path = join(self.devices_dir, job[‘device‘]) if self.mount_check and not ismount(dev_path): self.logger.warn(_(‘%s is not mounted‘), job[‘device‘]) continue #ring没有改变 if not self.check_ring(): self.logger.info(_("Ring change detected. Aborting " "current replication pass.")) return #假设 if job[‘delete‘]: self.run_pool.spawn(self.update_deleted, job) else: #运行的是更新 self.run_pool.spawn(self.update, job) with Timeout(self.lockup_timeout): self.run_pool.waitall() except (Exception, Timeout): self.logger.exception(_("Exception in top-level replication loop")) self.kill_coros() finally: stats.kill() lockup_detector.kill() self.stats_line()
def collect_jobs(self): """ Returns a sorted list of jobs (dictionaries) that specify the partitions, nodes, etc to be synced. """ jobs = [] ips = whataremyips() #replication_ip 和replication_port 在 RingBuilder中 load加入 #self.object_ring = Ring(self.swift_dir, ring_name=‘object‘) for local_dev in [dev for dev in self.object_ring.devs if dev and dev[‘replication_ip‘] in ips and dev[‘replication_port‘] == self.port]: dev_path = join(self.devices_dir, local_dev[‘device‘]) obj_path = join(dev_path, ‘objects‘) tmp_path = join(dev_path, ‘tmp‘) if self.mount_check and not ismount(dev_path): self.logger.warn(_(‘%s is not mounted‘), local_dev[‘device‘]) continue #Remove any file in a given path that that was last modified before mtime. #/srv/1/node/sdb1/tmp下的文件 unlink_older_than(tmp_path, time.time() - self.reclaim_age) if not os.path.exists(obj_path): try: mkdirs(obj_path) except Exception: self.logger.exception(‘ERROR creating %s‘ % obj_path) continue #root@kinglion-Lenovo-Product:/srv/1/node/sdb1/objects# ls #13069 133971 4799 58208 94238 for partition in os.listdir(obj_path): try: job_path = join(obj_path, partition) #推断当前路径是否为文件,假设是文件则删除 if isfile(job_path): # # Clean up any (probably zero-byte) files where a # partition should be. self.logger.warning(‘Removing partition directory ‘ ‘which was a file: %s‘, job_path) os.remove(job_path) continue #获得每一个partion相应的设备 part_nodes = self.object_ring.get_part_nodes(int(partition)) #nodes为不是本机器nodes的其它replica-1个nodes nodes = [node for node in part_nodes if node[‘id‘] != local_dev[‘id‘]] #对objects下全部partion遍历,故有jobs的长度最大为_replica2part2dev分区备份中出现此设备有此设备id的分区和 jobs.append( dict(path=job_path, device=local_dev[‘device‘], nodes=nodes, #len(nodes)>len(part_nodes)-1的情况是当前节点已经不再是 当前partition所相应的设备了,有可能删除了该设备 delete=len(nodes) > len(part_nodes) - 1, partition=partition)) except (ValueError, OSError): continue #打乱顺序 random.shuffle(jobs) if self.handoffs_first: # Move the handoff parts to the front of the list #将handoff 节点移到jobs队列的前边 jobs.sort(key=lambda job: not job[‘delete‘]) self.job_count = len(jobs) return jobs
对于第二层for循环,os.listdir(obj_path)列出objects目录下的全部partion,创建object是在objects目录下创建objects所映射的分区号的文件件,再在partion目录下创建以object的hash值后三位为名称的目录,然后再在后缀目录下创建以object的hash值为目录名的目录,object会存储为以object上传时间戳为名.data为文件后缀的文件。通过理解一致性hash算法可知,增加虚拟节点后每个设备会多个虚拟节点和其相应,假设一个设备相应的分区为n则,obj_path下子目录数目会<=n,由于存入的全部文件并不一定都能映射到当前设备所相应的分区。for循环首先判读obj_path下是否为文件,若是文件则删除,若不是则获得该分区号,依据分区号获得该分区号所映射的三个备份设备,并将设备id和本地设备id不想等的增加到nodes中,将nodes、path等信息增加到jobs中,最后打乱jobs的顺序,再将handoff 节点移到队列前边。返回jobs。再到replicate方法,首先我们看job[delete]为False的情况。当job[delete]为False会运行update方法,下边看update方法的详细实现:
def update(self, job): """ High-level method that replicates a single partition. :param job: a dict containing info about the partition to be replicated """ self.replication_count += 1 self.logger.increment(‘partition.update.count.%s‘ % (job[‘device‘],)) begin = time.time() try: #get_hashes 从hashes.pkl获取hashes值并更新 获取本地的hashes job[path] 为 job_path = join(obj_path, partition) local_hash为hashes.pkl中的反序列化回来的内容 hashed为改变的 hashed, local_hash = tpool_reraise( get_hashes, job[‘path‘], do_listdir=(self.replication_count % 10) == 0, reclaim_age=self.reclaim_age) self.suffix_hash += hashed self.logger.update_stats(‘suffix.hashes‘, hashed) # attempts_left = len(job[‘nodes‘]) #此时的nodes为除去本节点外的全部节点 由于 job[‘nodes]不包括本地节点get_more_nodes(int(job[‘partition‘]))能获得除去本partion所相应节点 外的其它全部节点 nodes = itertools.chain( job[‘nodes‘], self.object_ring.get_more_nodes(int(job[‘partition‘]))) #此时attempts_left 为2 若果replica为3 while attempts_left > 0: # If this throws StopIterator it will be caught way below node = next(nodes) attempts_left -= 1 try: with Timeout(self.http_timeout): #REPLICARE方法 相应 sever里面的RELICATE方法 resp = http_connect( node[‘replication_ip‘], node[‘replication_port‘], node[‘device‘], job[‘partition‘], ‘REPLICATE‘, ‘‘, headers=self.headers).getresponse() if resp.status == HTTP_INSUFFICIENT_STORAGE: self.logger.error(_(‘%(ip)s/%(device)s responded‘ ‘ as unmounted‘), node) attempts_left += 1 continue if resp.status != HTTP_OK: self.logger.error(_("Invalid response %(resp)s " "from %(ip)s"), {‘resp‘: resp.status, ‘ip‘: node[‘replication_ip‘]}) continue #remote_hash 为 请求 ‘REPLICATE 返回的 remote_hash = pickle.loads(resp.read()) del resp #找出本地后缀和远程后缀不同的 suffixes = [suffix for suffix in local_hash if local_hash[suffix] != remote_hash.get(suffix, -1)] #假设没有说明没有变动,则继续请求下一个节点 if not suffixes: continue #效果就是运行get_hashes方法 hashed, recalc_hash = tpool_reraise( get_hashes, job[‘path‘], recalculate=suffixes, reclaim_age=self.reclaim_age) self.logger.update_stats(‘suffix.hashes‘, hashed) local_hash = recalc_hash #假如 local_hash 为 123 321 122 remote_hash 123 321 124 则 122为变化的 #文件路径hash值后三位会不会反复 suffixes = [suffix for suffix in local_hash if local_hash[suffix] != remote_hash.get(suffix, -1)] #找到了不同的并知道其节点则将其同步到相应的节点,是基于推送模式的,故传的数据是自己本地的数据 self.sync(node, job, suffixes) #同步变化的 with Timeout(self.http_timeout): conn = http_connect( node[‘replication_ip‘], node[‘replication_port‘], node[‘device‘], job[‘partition‘], ‘REPLICATE‘, ‘/‘ + ‘-‘.join(suffixes), headers=self.headers) conn.getresponse().read() self.suffix_sync += len(suffixes) self.logger.update_stats(‘suffix.syncs‘, len(suffixes)) except (Exception, Timeout): self.logger.exception(_("Error syncing with node: %s") % node) #后缀数量 写日志时会用到 self.suffix_count += len(local_hash) except (Exception, Timeout): self.logger.exception(_("Error syncing partition")) finally: self.partition_times.append(time.time() - begin) self.logger.timing_since(‘partition.update.timing‘, begin)
update方法,中首先是获得本地文件里当前设备所相应hashes.pkl文件里每一个后缀所相应的hahes值,形如{‘a83‘: ‘0db7b416c9808517a1bb2157af20b09b‘},当中key为文件内容hash值的后三字节,value为后缀目录下全部子目录下(即以文件内容的md5值为名字的目录)全部.data文件的文件名称字的md5值,能够理解为全部文件名称的md5值和。
hashed, local_hash = tpool_reraise( get_hashes, job[‘path‘], do_listdir=(self.replication_count % 10) == 0, reclaim_age=self.reclaim_age)如上代码片段会运行get_hashes方法,并将后边參数传递给get_hashes
def get_hashes(partition_dir, recalculate=None, do_listdir=False, reclaim_age=ONE_WEEK): """ Get a list of hashes for the suffix dir. do_listdir causes it to mistrust the hash cache for suffix existence at the (unexpectedly high) cost of a listdir. reclaim_age is just passed on to hash_suffix. :param partition_dir: absolute path of partition to get hashes for :param recalculate: 形如 recalculate=[‘a83‘] list of suffixes(后缀,即 hash值的后缀 310即为后缀 root@kinglion-Lenovo-Product:/srv/1/node/sdb1/objects/94238# ls 310 hashes.pkl ) which should be recalculated(又一次计算) when got :param do_listdir: force existence check for all hashes in the partition(对partion中的hashe强行运行检查) :param reclaim_age: age at which to remove tombstones :returns: tuple of (number of suffix dirs hashed, dictionary of hashes) """
因没有传递recalulate这个參数故仅仅有do_listdir为True时会强制运行又一次计算后缀文件下全部文件名称字的hash值。文件名称字是时间戳,时间戳变了说明文件有更新,故须要和远程同步,检查是否为同一个版本号,不是同一个版本号的须要把本地版本号传递给远程server。
attempts_left = len(job[‘nodes‘]) #此时的nodes为除去本节点外的全部节点 由于 job[‘nodes]不包括本地节点get_more_nodes(int(job[‘partition‘]))能获得除去本partion所相应节点 外的其它全部节点 nodes = itertools.chain( job[‘nodes‘], self.object_ring.get_more_nodes(int(job[‘partition‘])))如上代码片段,attempts_left为当前job相应的分区去掉本地节点的其它的备份节点的个数。得到attempts_left后,下边接着更新了nodes,当中get_more_nodes方法会得到出去本分区所相应节点之外的其它全部节点的迭代器,全部nodes是除去本节点外全部节点的一个迭代器。
下边就是while循环,循环attempts_left次,
resp = http_connect( node[‘replication_ip‘], node[‘replication_port‘], node[‘device‘], job[‘partition‘], ‘REPLICATE‘, ‘‘, headers=self.headers).getresponse()
依据迭代得到的node请求,因副本节点首先被迭代到,故首先请求副本节点。若果成功请求读取resp返回的内容,得到远程设备同一个partion下的remote_hash
suffixes = [suffix for suffix in local_hash if local_hash[suffix] != remote_hash.get(suffix, -1)] #假设没有说明没有变动,则继续请求下一个节点 if not suffixes: continue对照两个设备同样partion下的hashes.pkl文件同样key而value不同的key。suffixes则说明和远程备份文件都是同一个版本号,继续请求下一个备份。假设不为空,则须要处理,同一时候再一次得到自己hashes.pkl目录中的内容,由于上一次请求时间中可能有其它的备份已经有新的更新推送到本server了。得到本地最新的hashes.pkl内容后再一次对照,得到不同的同样分区下的不同后缀
运行同步:
self.sync(node, job, suffixes) #同步变化的在同步变化时作者如今使用rsync方法,没有使用ssync,只是已经留出了ssync的实现,当ssync方法稳定时就会把rsync替换掉。(敬请期待)
def sync(self, node, job, suffixes): # Just exists for doc anchor point """ Synchronize local suffix directories from a partition with a remote node. :param node: the "dev" entry for the remote node to sync with :param job: information about the partition being synced :param suffixes: a list of suffixes which need to be pushed :returns: boolean indicating success or failure """ # self.sync_method = getattr(self, conf.get(‘sync_method‘) or ‘rsync‘) #配置没有 sync_method方法 则运行类自己的rsync方法 return self.sync_method(node, job, suffixes)sync_method方法从例如以下获得,没有配置则运行rsync方法
self.sync_method = getattr(self, conf.get(‘sync_method‘) or ‘rsync‘)
def rsync(self, node, job, suffixes): """ Uses rsync to implement the sync method. This was the first sync method in Swift. """ if not os.path.exists(job[‘path‘]): return False args = [ ‘rsync‘, ‘--recursive‘, ‘--whole-file‘, ‘--human-readable‘, ‘--xattrs‘, ‘--itemize-changes‘, ‘--ignore-existing‘, ‘--timeout=%s‘ % self.rsync_io_timeout, ‘--contimeout=%s‘ % self.rsync_io_timeout, ‘--bwlimit=%s‘ % self.rsync_bwlimit, ] node_ip = rsync_ip(node[‘replication_ip‘]) #包括了ip信息 if self.vm_test_mode: rsync_module = ‘%s::object%s‘ % (node_ip, node[‘replication_port‘]) else: rsync_module = ‘%s::object‘ % node_ip had_any = False for suffix in suffixes: spath = join(job[‘path‘], suffix) if os.path.exists(spath): args.append(spath) had_any = True if not had_any: return False args.append(join(rsync_module, node[‘device‘], ‘objects‘, job[‘partition‘])) #args里面包括了通的全部信息 包括设备名称,设备分区 return self._rsync(args) == 0rsync方法将接受的參数都放到args中,然后运行_rsync方法。
def _rsync(self, args): """ Execute the rsync binary to replicate a partition. :returns: return code of rsync process. 0 is successful """ start_time = time.time() ret_val = None try: with Timeout(self.rsync_timeout): #此处即为同步操作了,推送模式 proc = subprocess.Popen(args, stdout=subprocess.PIPE, stderr=subprocess.STDOUT) results = proc.stdout.read() ret_val = proc.wait() except Timeout: self.logger.error(_("Killing long-running rsync: %s"), str(args)) proc.kill() return 1 # failure response code total_time = time.time() - start_time for result in results.split(‘\n‘): if result == ‘‘: continue if result.startswith(‘cd+‘): continue if not ret_val: self.logger.info(result) else: self.logger.error(result) if ret_val: error_line = _(‘Bad rsync return code: %(ret)d <- %(args)s‘) % {‘args‘: str(args), ‘ret‘: ret_val} if self.rsync_error_log_line_length: error_line = error_line[:self.rsync_error_log_line_length] self.logger.error(error_line) elif results: self.logger.info( _("Successful rsync of %(src)s at %(dst)s (%(time).03f)"), {‘src‘: args[-2], ‘dst‘: args[-1], ‘time‘: total_time}) else: self.logger.debug( _("Successful rsync of %(src)s at %(dst)s (%(time).03f)"), {‘src‘: args[-2], ‘dst‘: args[-1], ‘time‘: total_time}) return ret_val当中例如以下代码片段就是运行详细的推送:
#此处即为同步操作了,推送模式 proc = subprocess.Popen(args, stdout=subprocess.PIPE, stderr=subprocess.STDOUT)
若job[delete]为True出现这样的情况的可能就是,因增删了设备,Ring 又一次调整,当前partion中的备份不再有此server的ID如partion号为45678的在rebalance前的对于的备份设备的id为[1,2,3],假设当前设备id为1,则又一次rebalance后当前partion相应的备份为[4,2,3],则就会出现job[delete]为True的情况,我们看其代码详细实现:
def update_deleted(self, job): """ High-level method that replicates a single partition that doesn‘t belong on (不应放在 )this node. :param job: a dict containing info about the partition to be replicated """ #得到parition下相应的后缀 def tpool_get_suffixes(path): return [suff for suff in os.listdir(path) if len(suff) == 3 and isdir(join(path, suff))] self.replication_count += 1 self.logger.increment(‘partition.delete.count.%s‘ % (job[‘device‘],)) begin = time.time() try: responses = [] suffixes = tpool.execute(tpool_get_suffixes, job[‘path‘]) if suffixes: for node in job[‘nodes‘]: success = self.sync(node, job, suffixes) #运行同步 if success: with Timeout(self.http_timeout): conn = http_connect( node[‘replication_ip‘], node[‘replication_port‘], node[‘device‘], job[‘partition‘], ‘REPLICATE‘, ‘/‘ + ‘-‘.join(suffixes), headers=self.headers) conn.getresponse().read() responses.append(success) if self.handoff_delete: # delete handoff if we have had handoff_delete successes delete_handoff = len([resp for resp in responses if resp]) >= self.handoff_delete else: # delete handoff if all syncs were successful delete_handoff = len(responses) == len(job[‘nodes‘]) and all(responses) #suffixes为空或 请求的三个已经都响应成功后删除本地partion下的文件 if not suffixes or delete_handoff: self.logger.info(_("Removing partition: %s"), job[‘path‘]) tpool.execute(shutil.rmtree, job[‘path‘], ignore_errors=True) except (Exception, Timeout): self.logger.exception(_("Error syncing handoff partition")) finally: self.partition_times.append(time.time() - begin) self.logger.timing_since(‘partition.delete.timing‘, begin)
至此 replicate操作就解说完成,文中若有理解不合理之处,请指正,谢谢!
OpenStack_Swift源代码分析——ObjectReplicator源代码分析(2)