欢迎来到福编程网,本站提供各种互联网专业知识!

在Ubuntu系统上部署分布式系统Ceph

发布时间:1970-01-01 作者:佚名 来源:互联网
这篇文章主要介绍了在Ubuntu系统上部署分布式系统Ceph的方法,文中对Ceph做了一个简单的说明,需要的朋友可以参考下

Ceph是统一存储系统,支持三种接口。

Object:有原生的API,而且也兼容Swift和S3的API

Block:支持精简配置、快照、克隆

File:Posix接口,支持快照

Ceph也是分布式存储系统,它的特点是:

高扩展性:使用普通x86服务器,支持10~1000台服务器,支持TB到PB级的扩展。

高可靠性:没有单点故障,多数据副本,自动管理,自动修复。

高性能:数据分布均衡,并行化度高。对于objects storage和block storage,不需要元数据服务器。

20151123104925507.png (1024×713)

架构

20151123105615641.jpg (500×423)

Ceph的底层是RADOS,它的意思是“A reliable, autonomous, distributed object storage”。 RADOS由两个组件组成:

OSD: Object Storage Device,提供存储资源。

Monitor:维护整个Ceph集群的全局状态。

RADOS具有很强的扩展性和可编程性,Ceph基于RADOS开发了

Object Storage、Block Storage、FileSystem。Ceph另外两个组件是:

MDS:用于保存CephFS的元数据。

RADOS Gateway:对外提供REST接口,兼容S3和Swift的API。

映射

Ceph的命名空间是 (Pool, Object),每个Object都会映射到一组OSD中(由这组OSD保存这个Object):

(Pool, Object) → (Pool, PG) → OSD set → Disk

Ceph中Pools的属性有:

Object的副本数

Placement Groups的数量

所使用的CRUSH Ruleset

在Ceph中,Object先映射到PG(Placement Group),再由PG映射到OSD set。每个Pool有多个PG,每个Object通过计算hash值并取模得到它所对应的PG。PG再映射到一组OSD(OSD的个数由Pool 的副本数决定),第一个OSD是Primary,剩下的都是Replicas。

数据映射(Data Placement)的方式决定了存储系统的性能和扩展性。(Pool, PG) → OSD set 的映射由四个因素决定:

CRUSH算法:一种伪随机算法。

OSD MAP:包含当前所有Pool的状态和所有OSD的状态。

CRUSH MAP:包含当前磁盘、服务器、机架的层级结构。

CRUSH Rules:数据映射的策略。这些策略可以灵活的设置object存放的区域。比如可以指定 pool1中所有objecst放置在机架1上,所有objects的第1个副本放置在机架1上的服务器A上,第2个副本分布在机架1上的服务器B上。 pool2中所有的object分布在机架2、3、4上,所有Object的第1个副本分布在机架2的服务器上,第2个副本分布在机架3的服 器上,第3个副本分布在机架4的服务器上。

20151123105728618.png (829×413)

Client从Monitors中得到CRUSH MAP、OSD MAP、CRUSH Ruleset,然后使用CRUSH算法计算出Object所在的OSD set。所以Ceph不需要Name服务器,Client直接和OSD进行通信。伪代码如下所示:

复制代码代码如下:

locator = object_name

obj_hash = hash(locator)

pg = obj_hash % num_pg

osds_for_pg = crush(pg) # returns a list of osds

primary = osds_for_pg[0]

replicas = osds_for_pg[1:]

这种数据映射的优点是:

把Object分成组,这降低了需要追踪和处理metadata的数量(在全局的层面上,我们不需要追踪和处理每个object的metadata和placement,只需要管理PG的metadata就可以了。PG的数量级远远低于object的数量级)。

增加PG的数量可以均衡每个OSD的负载,提高并行度。

分隔故障域,提高数据的可靠性。

强一致性

Ceph的读写操作采用Primary-Replica模型,Client只向Object所对应OSD set的Primary发起读写请求,这保证了数据的强一致性。

由于每个Object都只有一个Primary OSD,因此对Object的更新都是顺序的,不存在同步问题。

当Primary收到Object的写请求时,它负责把数据发送给其他Replicas,只要这个数据被保存在所有的OSD上时,Primary才应答Object的写请求,这保证了副本的一致性。

20151123105757102.png (410×364)

容错性

在分布式系统中,常见的故障有网络中断、掉电、服务器宕机、硬盘故障等,Ceph能够容忍这些故障,并进行自动修复,保证数据的可靠性和系统可用性。

Monitors是Ceph管家,维护着Ceph的全局状态。Monitors的功能和zookeeper类似,它们使用Quorum和Paxos算法去建立全局状态的共识。

OSDs可以进行自动修复,而且是并行修复。

故障检测:

OSD之间有心跳检测,当OSD A检测到OSD B没有回应时,会报告给Monitors说OSD B无法连接,则Monitors给OSD B标记为down状态,并更新OSD Map。当过了M秒之后还是无法连接到OSD B,则Monitors给OSD B标记为out状态(表明OSD B不能工作),并更新OSD Map。

备注:可以在Ceph中配置M的值。

故障恢复:

当某个PG对应的OSD set中有一个OSD被标记为down时(假如是Primary被标记为down,则某个Replica会成为新的Primary,并处理所有读写 object请求),则该PG处于active+degraded状态,也就是当前PG有效的副本数是N-1。

过了M秒之后,假如还是无法连接该OSD,则它被标记为out,Ceph会重新计算PG到OSD set的映射(当有新的OSD加入到集群时,也会重新计算所有PG到OSD set的映射),以此保证PG的有效副本数是N。

新OSD set的Primary先从旧的OSD set中收集PG log,得到一份Authoritative History(完整的、全序的操作序列),并让其他Replicas同意这份Authoritative History(也就是其他Replicas对PG的所有objects的状态达成一致),这个过程叫做Peering。

当Peering过程完成之后,PG进 入active+recoverying状态,Primary会迁移和同步那些降级的objects到所有的replicas上,保证这些objects 的副本数为N。

下面来看一下部署与配置

系统环境:Ubuntu 12.04.2

复制代码代码如下:

hostname:s1 osd.0/mon.a/mds.a ip:192.168.242.128

hostname:s2 osd.1/mon.b/mds.b ip:192.168.242.129

hostname:s3 osd.2/mon.c/mds.c ip:192.168.242.130

hostname:s4 client ip:192.168.242.131

免密钥:

s1/s2/s3 启用root,相互之间配置免密钥。

复制代码代码如下:

cat id_rsa.pub_s* >> authorized_keys

安装:

复制代码代码如下:

apt-get install ceph ceph-common ceph-fs-common (ceph-mds)

更新到新版本:

复制代码代码如下:

wget -q -O- ‘https://ceph.com/git/?p=ceph.git;a=blob_plain;f=keys/release.asc’| sudo apt-key add -

echo deb http://ceph.com/debian/ $(lsb_release -sc) main | tee /etc/apt/sources.list.d/ceph.list

apt-get update

apt-get install ceph

分区及挂载(使用btrfs):

复制代码代码如下:

root@s1:/data/osd.0# df -h|grep osd

/dev/sdb1 20G 180M 19G 1% /data/osd.0

root@s2:/data/osd.1# df -h|grep osd

/dev/sdb1 20G 173M 19G 1% /data/osd.1

root@s3:/data/osd.2# df -h|grep osd

/dev/sdb1 20G 180M 19G 1% /data/osd.2

root@s1:~/.ssh# mkdir -p /tmp/ceph/(每个server上执行)

配置:

复制代码代码如下:

root@s1:/data/osd.0# vim /etc/ceph/ceph.conf

[global]

auth cluster required = none

auth service required = none

auth client required = none

[osd]

osd data = /data/$name

[mon]

mon data = /data/$name

[mon.a]

host = s1

mon addr = 192.168.242.128:6789

[mon.b]

host = s2

mon addr = 192.168.242.129:6789

[mon.c]

host = s3

mon addr = 192.168.242.130:6789

[osd.0]

host = s1

brtfs devs = /dev/sdb1

[osd.1]

host = s2

brtfs devs = /dev/sdb1

[osd.2]

host = s3

brtfs devs = /dev/sdb1

[mds.a]

host = s1

[mds.b]

host = s2

[mds.c]

host = s3

同步配置

复制代码代码如下:

root@s1:~/.ssh# scp /etc/ceph/ceph.conf s2:/etc/ceph/

ceph.conf 100% 555 0.5KB/s 00:00

root@s1:~/.ssh# scp /etc/ceph/ceph.conf s3:/etc/ceph/

ceph.conf 100% 555 0.5KB/s 00:00

所有server上执行:

复制代码代码如下:

rm -rf /data/$name/* /data/mon/*(初始化前保持没有任何数据)

root@s1:~/.ssh# mkcephfs -a -c /etc/ceph/ceph.conf -k /etc/ceph/ceph.keyring

temp dir is /tmp/mkcephfs.qLmwP4Nd0G

preparing monmap in /tmp/mkcephfs.qLmwP4Nd0G/monmap

/usr/bin/monmaptool –create –clobber –add a 192.168.242.128:6789 –add b 192.168.242.129:6789 –add c 192.168.242.130:6789 –print /tmp/mkcephfs.qLmwP4Nd0G/monmap

/usr/bin/monmaptool: monmap file /tmp/mkcephfs.qLmwP4Nd0G/monmap

/usr/bin/monmaptool: generated fsid c26fac57-4941-411f-a6ac-3dcd024f2073

epoch 0

fsid c26fac57-4941-411f-a6ac-3dcd024f2073

last_changed 2014-05-08 16:08:06.102237

created 2014-05-08 16:08:06.102237

0: 192.168.242.128:6789/0 mon.a

1: 192.168.242.129:6789/0 mon.b

2: 192.168.242.130:6789/0 mon.c

/usr/bin/monmaptool: writing epoch 0 to /tmp/mkcephfs.qLmwP4Nd0G/monmap (3 monitors)

=== osd.0 ===

** WARNING: No osd journal is configured: write latency may be high.

If you will not be using an osd journal, write latency may be

relatively high. It can be reduced somewhat by lowering

filestore_max_sync_interval, but lower values mean lower write

throughput, especially with spinning disks.

2014-05-08 16:08:11.279610 b72cc740 created object store /data/osd.0 for osd.0 fsid c26fac57-4941-411f-a6ac-3dcd024f2073

creating private key for osd.0 keyring /tmp/mkcephfs.qLmwP4Nd0G/keyring.osd.0

creating /tmp/mkcephfs.qLmwP4Nd0G/keyring.osd.0

=== osd.1 ===

pushing conf and monmap to s2:/tmp/mkfs.ceph.5884

** WARNING: No osd journal is configured: write latency may be high.

If you will not be using an osd journal, write latency may be

relatively high. It can be reduced somewhat by lowering

filestore_max_sync_interval, but lower values mean lower write

throughput, especially with spinning disks.

2014-05-08 16:08:21.146302 b7234740 created object store /data/osd.1 for osd.1 fsid c26fac57-4941-411f-a6ac-3dcd024f2073

creating private key for osd.1 keyring /tmp/mkfs.ceph.5884/keyring.osd.1

creating /tmp/mkfs.ceph.5884/keyring.osd.1

collecting osd.1 key

=== osd.2 ===

pushing conf and monmap to s3:/tmp/mkfs.ceph.5884

** WARNING: No osd journal is configured: write latency may be high.

If you will not be using an osd journal, write latency may be

relatively high. It can be reduced somewhat by lowering

filestore_max_sync_interval, but lower values mean lower write

throughput, especially with spinning disks.

2014-05-08 16:08:27.264484 b72b3740 created object store /data/osd.2 for osd.2 fsid c26fac57-4941-411f-a6ac-3dcd024f2073

creating private key for osd.2 keyring /tmp/mkfs.ceph.5884/keyring.osd.2

creating /tmp/mkfs.ceph.5884/keyring.osd.2

collecting osd.2 key

=== mds.a ===

creating private key for mds.a keyring /tmp/mkcephfs.qLmwP4Nd0G/keyring.mds.a

creating /tmp/mkcephfs.qLmwP4Nd0G/keyring.mds.a

=== mds.b ===

pushing conf and monmap to s2:/tmp/mkfs.ceph.5884

creating private key for mds.b keyring /tmp/mkfs.ceph.5884/keyring.mds.b

creating /tmp/mkfs.ceph.5884/keyring.mds.b

collecting mds.b key

=== mds.c ===

pushing conf and monmap to s3:/tmp/mkfs.ceph.5884

creating private key for mds.c keyring /tmp/mkfs.ceph.5884/keyring.mds.c

creating /tmp/mkfs.ceph.5884/keyring.mds.c

collecting mds.c key

Building generic osdmap from /tmp/mkcephfs.qLmwP4Nd0G/conf

/usr/bin/osdmaptool: osdmap file ‘/tmp/mkcephfs.qLmwP4Nd0G/osdmap’

2014-05-08 16:08:26.100746 b731e740 adding osd.0 at {host=s1,pool=default,rack=unknownrack}

2014-05-08 16:08:26.101413 b731e740 adding osd.1 at {host=s2,pool=default,rack=unknownrack}

2014-05-08 16:08:26.101902 b731e740 adding osd.2 at {host=s3,pool=default,rack=unknownrack}

/usr/bin/osdmaptool: writing epoch 1 to /tmp/mkcephfs.qLmwP4Nd0G/osdmap

Generating admin key at /tmp/mkcephfs.qLmwP4Nd0G/keyring.admin

creating /tmp/mkcephfs.qLmwP4Nd0G/keyring.admin

Building initial monitor keyring

added entity mds.a auth auth(auid = 18446744073709551615 key=AQB3O2tTwDNwLRAAofpkrOMqtHCPTFX36EKAMA== with 0 caps)

added entity mds.b auth auth(auid = 18446744073709551615 key=AQB8O2tT8H8nIhAAq1O2lh4IV/cQ73FUUTOUug== with 0 caps)

added entity mds.c auth auth(auid = 18446744073709551615 key=AQB9O2tTWIfsKRAAVYeueMToC85tRSvlslV/jQ== with 0 caps)

added entity osd.0 auth auth(auid = 18446744073709551615 key=AQBrO2tTOLQpEhAA4MS83CnJRYAkoxrFSvC3aQ== with 0 caps)

added entity osd.1 auth auth(auid = 18446744073709551615 key=AQB1O2tTME0eChAA7U4xSrv7MJUZ8vxcEkILbw== with 0 caps)

added entity osd.2 auth auth(auid = 18446744073709551615 key=AQB7O2tT0FUKERAAQ/EJT5TclI2XSCLAWAZZOw== with 0 caps)

=== mon.a ===

/usr/bin/ceph-mon: created monfs at /data/mon for mon.a

=== mon.b ===

pushing everything to s2

/usr/bin/ceph-mon: created monfs at /data/mon for mon.b

=== mon.c ===

pushing everything to s3

/usr/bin/ceph-mon: created monfs at /data/mon for mon.c

placing client.admin keyring in /etc/ceph/ceph.keyring

上面提示了没有配置journal。

复制代码代码如下:

root@s1:~# /etc/init.d/ceph -a start

=== mon.a ===

Starting Ceph mon.a on s1…already running

=== mds.a ===

Starting Ceph mds.a on s1…already running

=== osd.0 ===

Starting Ceph osd.0 on s1…

** WARNING: Ceph is still under development. Any feedback can be directed **

** at ceph-devel@vger.kernel.org or http://ceph.newdream.net/. **

starting osd.0 at 0.0.0.0:6801/2264 osd_data /data/osd.0 (no journal)

查看状态:

复制代码代码如下:

root@s1:~# ceph -s

2014-05-09 09:37:40.477978 pg v444: 594 pgs: 594 active+clean; 38199 bytes data, 531 MB used, 56869 MB / 60472 MB avail

2014-05-09 09:37:40.485092 mds e23: 1/1/1 up {0=a=up:active}, 2 up:standby

2014-05-09 09:37:40.485601 osd e34: 3 osds: 3 up, 3 in

2014-05-09 09:37:40.486276 log 2014-05-09 09:36:25.843782 mds.0 192.168.242.128:6800/1053 1 : [INF] closing stale session client.4104 192.168.242.131:0/2123448720 after 302.954724

2014-05-09 09:37:40.486577 mon e1: 3 mons at {a=192.168.242.128:6789/0,b=192.168.242.129:6789/0,c=192.168.242.130:6789/0}

root@s1:~# for i in 1 2 3 ;do ceph health;done

2014-05-09 10:05:30.306575 mon <- [health]

2014-05-09 10:05:30.309366 mon.1 -> ‘HEALTH_OK’ (0)

2014-05-09 10:05:30.330317 mon <- [health]

2014-05-09 10:05:30.333608 mon.2 -> ‘HEALTH_OK’ (0)

2014-05-09 10:05:30.352617 mon <- [health]

2014-05-09 10:05:30.353984 mon.0 -> ‘HEALTH_OK’ (0)

并同时查看 s1、s2、s3 log可以看到,证明3个节点都正常:

复制代码代码如下:

2014-05-09 09:39:32.316795 b4bfeb40 mon.a@0(leader) e1 handle_command mon_command(health v 0) v1

2014-05-09 09:39:40.789748 b4bfeb40 mon.a@0(leader).osd e35 e35: 3 osds: 3 up, 3 in

2014-05-09 09:40:00.796979 b4bfeb40 mon.a@0(leader).osd e36 e36: 3 osds: 3 up, 3 in

2014-05-09 09:40:41.781141 b4bfeb40 mon.a@0(leader) e1 handle_command mon_command(health v 0) v1

2014-05-09 09:40:42.409235 b4bfeb40 mon.a@0(leader) e1 handle_command mon_command(health v 0) v1

log 里面会看到如下时间未同步信息:

复制代码代码如下:

2014-05-09 09:43:13.485212 b49fcb40 log [WRN] : message from mon.0 was stamped 6.050738s in the future, clocks not synchronized

2014-05-09 09:43:13.861985 b49fcb40 log [WRN] : message from mon.0 was stamped 6.050886s in the future, clocks not synchronized

2014-05-09 09:43:14.012633 b49fcb40 log [WRN] : message from mon.0 was stamped 6.050681s in the future, clocks not synchronized

2014-05-09 09:43:15.809439 b49fcb40 log [WRN] : message from mon.0 was stamped 6.050781s in the future, clocks not synchronized

所以我们在做集群之前最好能在集群内部做好ntp服务器,确保各节点之前时间一致。

3. 接下来在客户机s4上进行验证操作:

复制代码代码如下:

root@s4:/mnt# mount -t ceph s1:6789:/ /mnt/s1fs/

root@s4:/mnt# mount -t ceph s2:6789:/ /mnt/s2fs/

root@s4:/mnt# mount -t ceph s3:6789:/ /mnt/s3fs/

root@s4:~# df -h

Filesystem Size Used Avail Use% Mounted on

/dev/sda1 79G 1.3G 74G 2% /

udev 241M 4.0K 241M 1% /dev

tmpfs 100M 304K 99M 1% /run

none 5.0M 0 5.0M 0% /run/lock

none 248M 0 248M 0% /run/shm

192.168.242.130:6789:/ 60G 3.6G 56G 6% /mnt/s3fs

192.168.242.129:6789:/ 60G 3.6G 56G 6% /mnt/s2fs

192.168.242.128:6789:/ 60G 3.6G 56G 6% /mnt/s1fs

root@s4:/mnt/s2fs# touch aa

root@s4:/mnt/s2fs# ls -al /mnt/s1fs

total 4

drwxr-xr-x 1 root root 0 May 8 18:08 ./

drwxr-xr-x 7 root root 4096 May 8 17:28 ../

-rw-r–r– 1 root root 0 May 8 18:08 aa

root@s4:/mnt/s2fs# ls -al /mnt/s3fs

total 4

drwxr-xr-x 1 root root 0 May 8 18:08 ./

drwxr-xr-x 7 root root 4096 May 8 17:28 ../

-rw-r–r– 1 root root 0 May 8 18:08 aa

root@s4:/mnt/s2fs# rm -f aa

root@s4:/mnt/s2fs# ls -al /mnt/s1fs/

total 4

drwxr-xr-x 1 root root 0 May 8 2014 ./

drwxr-xr-x 7 root root 4096 May 8 17:28 ../

root@s4:/mnt/s2fs# ls -al /mnt/s3fs/

total 4

drwxr-xr-x 1 root root 0 May 8 18:07 ./

drwxr-xr-x 7 root root 4096 May 8 17:28 ../

接下来我们验证单点故障:

将s1服务停掉,

复制代码代码如下:

root@s1:~# /etc/init.d/ceph stop

=== mon.a ===

Stopping Ceph mon.a on s1…kill 965…done

=== mds.a ===

Stopping Ceph mds.a on s1…kill 1314…done

=== osd.0 ===

Stopping Ceph osd.0 on s1…kill 2265…done

s2上log 立马显示:

省掉了很多,基本的意思就是mon监控中心发现,剔除故障节点,进行自动切换,集群恢复。

复制代码代码如下:

2014-05-09 10:16:44.906370 a5af0b40 — 192.168.242.129:6802/1495 >> 192.168.242.128:6802/1466 pipe(0xb1e1b1a8 sd=19 pgs=3 cs=3 l=0).fault with nothing to send, going to standby

2014-05-09 10:16:44.906982 a68feb40 — 192.168.242.129:6803/1495 >> 192.168.242.128:0/1467 pipe(0xa6e00d50 sd=17 pgs=1 cs=1 l=0).fault with nothing to send, going to standby

2014-05-09 10:16:44.907415 a63f9b40 — 192.168.242.129:0/1506 >> 192.168.242.128:6803/1466 pipe(0xb1e26d50 sd=20 pgs=1 cs=1 l=0).fault with nothing to send, going to standby

2014-05-09 10:16:49.028640 b5199b40 mds.0.6 handle_mds_map i am now mds.0.6

2014-05-09 10:16:49.029018 b5199b40 mds.0.6 handle_mds_map state change up:reconnect –> up:rejoin

2014-05-09 10:16:49.029260 b5199b40 mds.0.6 rejoin_joint_start

2014-05-09 10:16:49.032134 b5199b40 mds.0.6 rejoin_done

==> /var/log/ceph/mon.b.log <==

2014-05-09 10:16:49.060870 b5198b40 log [INF] : mds.0 192.168.242.129:6804/1341 up:active

==> /var/log/ceph/mds.b.log <==

2014-05-09 10:16:49.073135 b5199b40 mds.0.6 handle_mds_map i am now mds.0.6

2014-05-09 10:16:49.073237 b5199b40 mds.0.6 handle_mds_map state change up:rejoin --> up:active

2014-05-09 10:16:49.073252 b5199b40 mds.0.6 recovery_done — successful recovery!

2014-05-09 10:16:49.073871 b5199b40 mds.0.6 active_start

2014-05-09 10:16:49.073934 b5199b40 mds.0.6 cluster recovered.

==> /var/log/ceph/mds.b.log <==

2014-05-09 10:16:49.073135 b5199b40 mds.0.6 handle_mds_map i am now mds.0.6

2014-05-09 10:16:49.073237 b5199b40 mds.0.6 handle_mds_map state change up:rejoin --> up:active

2014-05-09 10:16:49.073252 b5199b40 mds.0.6 recovery_done — successful recovery!

2014-05-09 10:16:49.073871 b5199b40 mds.0.6 active_start

2014-05-09 10:16:49.073934 b5199b40 mds.0.6 cluster recovered.

==> /var/log/ceph/mon.b.log <==

2014-05-09 10:18:24.366217 b5198b40 mon.b@1(leader) e1 handle_command mon_command(health v 0) v1

2014-05-09 10:18:25.717589 b5198b40 mon.b@1(leader) e1 handle_command mon_command(health v 0) v1

2014-05-09 10:18:29.481811 b5198b40 mon.b@1(leader) e1 handle_command mon_command(health v 0) v1

2014-05-09 10:21:39.184889 b4997b40 log [INF] : osd.0 out (down for 303.572445)

2014-05-09 10:21:39.195596 b5198b40 mon.b@1(leader).osd e42 e42: 3 osds: 2 up, 2 in

2014-05-09 10:21:40.199772 b5198b40 mon.b@1(leader).osd e43 e43: 3 osds: 2 up, 2 in

root@s2:~# ceph -s

2014-05-09 10:24:18.075291 pg v501: 594 pgs: 594 active+clean; 47294 bytes data, 359 MB used, 37907 MB / 40315 MB avail

2014-05-09 10:24:18.093637 mds e27: 1/1/1 up {0=b=up:active}, 1 up:standby

2014-05-09 10:24:18.094047 osd e43: 3 osds: 2 up, 2 in

2014-05-09 10:24:18.094833 log 2014-05-09 10:21:39.185547 mon.1 192.168.242.129:6789/0 40 : [INF] osd.0 out (down for 303.572445)

2014-05-09 10:24:18.095606 mon e1: 3 mons at {a=192.168.242.128:6789/0,b=192.168.242.129:6789/0,c=192.168.242.130:6789/0}

root@s1:~# ceph health

2014-05-09 10:18:43.185714 mon <- [health]

2014-05-09 10:18:43.189028 mon.2 -> ‘HEALTH_WARN 1/3 in osds are down; 1 mons down, quorum 1,2′ (0)

root@s2:~# ceph health

2014-05-09 10:23:40.655548 mon <- [health]

2014-05-09 10:23:40.658293 mon.2 -> ‘HEALTH_WARN 1 mons down, quorum 1,2′ (0)

root@s3:~# ceph health

2014-05-09 10:23:28.058080 mon <- [health]

2014-05-09 10:23:28.061126 mon.1 -> ‘HEALTH_WARN 1 mons down, quorum 1,2′ (0)

再接下来,关闭s2,只开启s3:

s3上log显示大量

复制代码代码如下:

==> /var/log/ceph/mds.c.log <==

2014-05-09 10:33:04.274503 b5180b40 mds.-1.0 ms_handle_connect on 192.168.242.130:6789/0

==> /var/log/ceph/osd.2.log <==

2014-05-09 10:33:04.832597 b4178b40 osd.2 43 heartbeat_check: no heartbeat from osd.1 since 2014-05-09 10:29:54.607954 (cutoff 2014-05-09 10:32:44.832568)

2014-05-09 10:33:05.084620 a7be9b40 osd.2 43 heartbeat_check: no heartbeat from osd.1 since 2014-05-09 10:29:54.607954 (cutoff 2014-05-09 10:32:45.084592)

2014-05-09 10:33:05.585583 a7be9b40 osd.2 43 heartbeat_check: no heartbeat from osd.1 since 2014-05-09 10:29:54.607954 (cutoff 2014-05-09 10:32:45.585553)

2014-05-09 10:33:05.834589 b4178b40 osd.2 43 heartbeat_check: no heartbeat from osd.1 since 2014-05-09 10:29:54.607954 (cutoff 2014-05-09 10:32:45.834559)

2014-05-09 10:33:06.086562 a7be9b40 osd.2 43 heartbeat_check: no heartbeat from osd.1 since 2014-05-09 10:29:54.607954 (cutoff 2014-05-09 10:32:46.086533)

2014-05-09 10:33:06.835683 b4178b40 osd.2 43 heartbeat_check: no heartbeat from osd.1 since 2014-05-09 10:29:54.607954 (cutoff 2014-05-09 10:32:46.835641)

2014-05-09 10:33:07.287766 a7be9b40 osd.2 43 heartbeat_check: no heartbeat from osd.1 since 2014-05-09 10:29:54.607954 (cutoff 2014-05-09 10:32:47.287737)

健康检测不能从s2上的osd.1 获取no heartbeat 。

s1、s2、s3上都有mon、mds、osd。但是总个集群中只有一个节点,所以不能提供服务。

相关推荐