mirror of
https://github.com/ceph/ceph
synced 2024-12-22 19:34:30 +00:00
7948e13b9d
Fixes: #6142 Signed-off-by: John Wilkins <john.wilkins@inktank.com>
358 lines
20 KiB
ReStructuredText
358 lines
20 KiB
ReStructuredText
==========================
|
|
Hardware Recommendations
|
|
==========================
|
|
|
|
Ceph was designed to run on commodity hardware, which makes building and
|
|
maintaining petabyte-scale data clusters economically feasible.
|
|
When planning out your cluster hardware, you will need to balance a number
|
|
of considerations, including failure domains and potential performance
|
|
issues. Hardware planning should include distributing Ceph daemons and
|
|
other processes that use Ceph across many hosts. Generally, we recommend
|
|
running Ceph daemons of a specific type on a host configured for that type
|
|
of daemon. We recommend using other hosts for processes that utilize your
|
|
data cluster (e.g., OpenStack, CloudStack, etc).
|
|
|
|
|
|
.. tip:: Check out the Ceph blog too. Articles like `Ceph Write Throughput 1`_,
|
|
`Ceph Write Throughput 2`_, `Argonaut v. Bobtail Performance Preview`_,
|
|
`Bobtail Performance - I/O Scheduler Comparison`_ and others are an
|
|
excellent source of information.
|
|
|
|
|
|
CPU
|
|
===
|
|
|
|
Ceph metadata servers dynamically redistribute their load, which is CPU
|
|
intensive. So your metadata servers should have significant processing power
|
|
(e.g., quad core or better CPUs). Ceph OSDs run the :term:`RADOS` service, calculate
|
|
data placement with :term:`CRUSH`, replicate data, and maintain their own copy of the
|
|
cluster map. Therefore, OSDs should have a reasonable amount of processing power
|
|
(e.g., dual core processors). Monitors simply maintain a master copy of the
|
|
cluster map, so they are not CPU intensive. You must also consider whether the
|
|
host machine will run CPU-intensive processes in addition to Ceph daemons. For
|
|
example, if your hosts will run computing VMs (e.g., OpenStack Nova), you will
|
|
need to ensure that these other processes leave sufficient processing power for
|
|
Ceph daemons. We recommend running additional CPU-intensive processes on
|
|
separate hosts.
|
|
|
|
|
|
RAM
|
|
===
|
|
|
|
Metadata servers and monitors must be capable of serving their data quickly, so
|
|
they should have plenty of RAM (e.g., 1GB of RAM per daemon instance). OSDs do
|
|
not require as much RAM for regular operations (e.g., 500MB of RAM per daemon
|
|
instance); however, during recovery they need significantly more RAM (e.g., ~1GB
|
|
per 1TB of storage per daemon). Generally, more RAM is better.
|
|
|
|
|
|
Data Storage
|
|
============
|
|
|
|
Plan your data storage configuration carefully. There are significant cost and
|
|
performance tradeoffs to consider when planning for data storage. Simultaneous
|
|
OS operations, and simultaneous request for read and write operations from
|
|
multiple daemons against a single drive can slow performance considerably. There
|
|
are also file system limitations to consider: btrfs is not quite stable enough
|
|
for production, but it has the ability to journal and write data simultaneously,
|
|
whereas XFS and ext4 do not.
|
|
|
|
.. important:: Since Ceph has to write all data to the journal before it can
|
|
send an ACK (for XFS and EXT4 at least), having the journal and OSD
|
|
performance in balance is really important!
|
|
|
|
|
|
Hard Disk Drives
|
|
----------------
|
|
|
|
OSDs should have plenty of hard disk drive space for object data. We recommend a
|
|
minimum hard disk drive size of 1 terabyte. Consider the cost-per-gigabyte
|
|
advantage of larger disks. We recommend dividing the price of the hard disk
|
|
drive by the number of gigabytes to arrive at a cost per gigabyte, because
|
|
larger drives may have a significant impact on the cost-per-gigabyte. For
|
|
example, a 1 terabyte hard disk priced at $75.00 has a cost of $0.07 per
|
|
gigabyte (i.e., $75 / 1024 = 0.0732). By contrast, a 3 terabyte hard disk priced
|
|
at $150.00 has a cost of $0.05 per gigabyte (i.e., $150 / 3072 = 0.0488). In the
|
|
foregoing example, using the 1 terabyte disks would generally increase the cost
|
|
per gigabyte by 40%--rendering your cluster substantially less cost efficient.
|
|
Also, the larger the storage drive capacity, the more memory per Ceph OSD Daemon
|
|
you will need, especially during rebalancing, backfilling and recovery. A
|
|
general rule of thumb is ~1GB of RAM for 1TB of storage space.
|
|
|
|
.. tip:: Running multiple OSDs on a single disk--irrespective of partitions--is
|
|
**NOT** a good idea.
|
|
|
|
.. tip:: Running an OSD and a monitor or a metadata server on a single
|
|
disk--irrespective of partitions--is **NOT** a good idea either.
|
|
|
|
Storage drives are subject to limitations on seek time, access time, read and
|
|
write times, as well as total throughput. These physical limitations affect
|
|
overall system performance--especially during recovery. We recommend using a
|
|
dedicated drive for the operating system and software, and one drive for each
|
|
Ceph OSD Daemon you run on the host. Most "slow OSD" issues arise due to running
|
|
an operating system, multiple OSDs, and/or multiple journals on the same drive.
|
|
Since the cost of troubleshooting performance issues on a small cluster likely
|
|
exceeds the cost of the extra disk drives, you can accelerate your cluster
|
|
design planning by avoiding the temptation to overtax the OSD storage drives.
|
|
|
|
You may run multiple Ceph OSD Daemons per hard disk drive, but this will likely
|
|
lead to resource contention and diminish the overall throughput. You may store a
|
|
journal and object data on the same drive, but this may increase the time it
|
|
takes to journal a write and ACK to the client. Ceph must write to the journal
|
|
before it can ACK the write. The btrfs filesystem can write journal data and
|
|
object data simultaneously, whereas XFS and ext4 cannot.
|
|
|
|
Ceph best practices dictate that you should run operating systems, OSD data and
|
|
OSD journals on separate drives.
|
|
|
|
|
|
Solid State Drives
|
|
------------------
|
|
|
|
One opportunity for performance improvement is to use solid-state drives (SSDs)
|
|
to reduce random access time and read latency while accelerating throughput.
|
|
SSDs often cost more than 10x as much per gigabyte when compared to a hard disk
|
|
drive, but SSDs often exhibit access times that are at least 100x faster than a
|
|
hard disk drive.
|
|
|
|
SSDs do not have moving mechanical parts so they aren't necessarily subject to
|
|
the same types of limitations as hard disk drives. SSDs do have significant
|
|
limitations though. When evaluating SSDs, it is important to consider the
|
|
performance of sequential reads and writes. An SSD that has 400MB/s sequential
|
|
write throughput may have much better performance than an SSD with 120MB/s of
|
|
sequential write throughput when storing multiple journals for multiple OSDs.
|
|
|
|
.. important:: We recommend exploring the use of SSDs to improve performance.
|
|
However, before making a significant investment in SSDs, we **strongly
|
|
recommend** both reviewing the performance metrics of an SSD and testing the
|
|
SSD in a test configuration to gauge performance.
|
|
|
|
Since SSDs have no moving mechanical parts, it makes sense to use them in the
|
|
areas of Ceph that do not use a lot of storage space (e.g., journals).
|
|
Relatively inexpensive SSDs may appeal to your sense of economy. Use caution.
|
|
Acceptable IOPS are not enough when selecting an SSD for use with Ceph. There
|
|
are a few important performance considerations for journals and SSDs:
|
|
|
|
- **Write-intensive semantics:** Journaling involves write-intensive semantics,
|
|
so you should ensure that the SSD you choose to deploy will perform equal to
|
|
or better than a hard disk drive when writing data. Inexpensive SSDs may
|
|
introduce write latency even as they accelerate access time, because
|
|
sometimes high performance hard drives can write as fast or faster than
|
|
some of the more economical SSDs available on the market!
|
|
|
|
- **Sequential Writes:** When you store multiple journals on an SSD you must
|
|
consider the sequential write limitations of the SSD too, since they may be
|
|
handling requests to write to multiple OSD journals simultaneously.
|
|
|
|
- **Partition Alignment:** A common problem with SSD performance is that
|
|
people like to partition drives as a best practice, but they often overlook
|
|
proper partition alignment with SSDs, which can cause SSDs to transfer data
|
|
much more slowly. Ensure that SSD partitions are properly aligned.
|
|
|
|
While SSDs are cost prohibitive for object storage, OSDs may see a significant
|
|
performance improvement by storing an OSD's journal on an SSD and the OSD's
|
|
object data on a separate hard disk drive. The ``osd journal`` configuration
|
|
setting defaults to ``/var/lib/ceph/osd/$cluster-$id/journal``. You can mount
|
|
this path to an SSD or to an SSD partition so that it is not merely a file on
|
|
the same disk as the object data.
|
|
|
|
One way Ceph accelerates CephFS filesystem performance is to segregate the
|
|
storage of CephFS metadata from the storage of the CephFS file contents. Ceph
|
|
provides a default ``metadata`` pool for CephFS metadata. You will never have to
|
|
create a pool for CephFS metadata, but you can create a CRUSH map hierarchy for
|
|
your CephFS metadata pool that points only to a host's SSD storage media. See
|
|
`Mapping Pools to Different Types of OSDs`_ for details.
|
|
|
|
|
|
Controllers
|
|
-----------
|
|
|
|
Disk controllers also have a significant impact on write throughput. Carefully,
|
|
consider your selection of disk controllers to ensure that they do not create
|
|
a performance bottleneck.
|
|
|
|
.. tip:: The Ceph blog is often an excellent source of information on Ceph
|
|
performance issues. See `Ceph Write Throughput 1`_ and `Ceph Write
|
|
Throughput 2`_ for additional details.
|
|
|
|
|
|
Additional Considerations
|
|
-------------------------
|
|
|
|
You may run multiple OSDs per host, but you should ensure that the sum of the
|
|
total throughput of your OSD hard disks doesn't exceed the network bandwidth
|
|
required to service a client's need to read or write data. You should also
|
|
consider what percentage of the overall data the cluster stores on each host. If
|
|
the percentage on a particular host is large and the host fails, it can lead to
|
|
problems such as exceeding the ``full ratio``, which causes Ceph to halt
|
|
operations as a safety precaution that prevents data loss.
|
|
|
|
When you run multiple OSDs per host, you also need to ensure that the kernel
|
|
is up to date. See `OS Recommendations`_ for notes on ``glibc`` and
|
|
``syncfs(2)`` to ensure that your hardware performs as expected when running
|
|
multiple OSDs per host.
|
|
|
|
Hosts with high numbers of OSDs (e.g., > 20) may spawn a lot of threads,
|
|
especially during recovery and rebalancing. Many Linux kernels default to
|
|
a relatively small maximum number of threads (e.g., 32k). If you encounter
|
|
problems starting up OSDs on hosts with a high number of OSDs, consider
|
|
setting ``kernel.pid_max`` to a higher number of threads. The theoretical
|
|
maximum is 4,194,303 threads. For example, you could add the following to
|
|
the ``/etc/sysctl.conf`` file::
|
|
|
|
kernel.pid_max = 4194303
|
|
|
|
|
|
Networks
|
|
========
|
|
|
|
We recommend that each host have at least two 1Gbps network interface
|
|
controllers (NICs). Since most commodity hard disk drives have a throughput of
|
|
approximately 100MB/second, your NICs should be able to handle the traffic for
|
|
the OSD disks on your host. We recommend a minimum of two NICs to account for a
|
|
public (front-side) network and a cluster (back-side) network. A cluster network
|
|
(preferably not connected to the internet) handles the additional load for data
|
|
replication and helps stop denial of service attacks that prevent the cluster
|
|
from achieving ``active + clean`` states for placement groups as OSDs replicate
|
|
data across the cluster. Consider starting with a 10Gbps network in your racks.
|
|
Replicating 1TB of data across a 1Gbps network takes 3 hours, and 3TBs (a
|
|
typical drive configuration) takes 9 hours. By contrast, with a 10Gbps network,
|
|
the replication times would be 20 minutes and 1 hour respectively. In a
|
|
petabyte-scale cluster, failure of an OSD disk should be an expectation, not an
|
|
exception. System administrators will appreciate PGs recovering from a
|
|
``degraded`` state to an ``active + clean`` state as rapidly as possible, with
|
|
price / performance tradeoffs taken into consideration. Additionally, some
|
|
deployment tools (e.g., Dell's Crowbar) deploy with five different networks,
|
|
but employ VLANs to make hardware and network cabling more manageable. VLANs
|
|
using 802.1q protocol require VLAN-capable NICs and Switches. The added hardware
|
|
expense may be offset by the operational cost savings for network setup and
|
|
maintenance. When using VLANs to handle VM traffic between between the cluster
|
|
and compute stacks (e.g., OpenStack, CloudStack, etc.), it is also worth
|
|
considering using 10G Ethernet. Top-of-rack routers for each network also need
|
|
to be able to communicate with spine routers that have even faster
|
|
throughput--e.g., 40Gbps to 100Gbps.
|
|
|
|
Your server hardware should have a Baseboard Management Controller (BMC).
|
|
Administration and deployment tools may also use BMCs extensively, so consider
|
|
the cost/benefit tradeoff of an out-of-band network for administration.
|
|
Hypervisor SSH access, VM image uploads, OS image installs, management sockets,
|
|
etc. can impose significant loads on a network. Running three networks may seem
|
|
like overkill, but each traffic path represents a potential capacity, throughput
|
|
and/or performance bottleneck that you should carefully consider before
|
|
deploying a large scale data cluster.
|
|
|
|
|
|
Failure Domains
|
|
===============
|
|
|
|
A failure domain is any failure that prevents access to one or more OSDs. That
|
|
could be a stopped daemon on a host; a hard disk failure, an OS crash, a
|
|
malfunctioning NIC, a failed power supply, a network outage, a power outage, and
|
|
so forth. When planning out your hardware needs, you must balance the
|
|
temptation to reduce costs by placing too many responsibilities into too few
|
|
failure domains, and the added costs of isolating every potential failure
|
|
domain.
|
|
|
|
|
|
Minimum Hardware Recommendations
|
|
================================
|
|
|
|
Ceph can run on inexpensive commodity hardware. Small production clusters
|
|
and development clusters can run successfully with modest hardware.
|
|
|
|
+--------------+----------------+-----------------------------------------+
|
|
| Process | Criteria | Minimum Recommended |
|
|
+==============+================+=========================================+
|
|
| ``ceph-osd`` | Processor | - 1x 64-bit AMD-64 |
|
|
| | | - 1x 32-bit ARM dual-core or better |
|
|
| | | - 1x i386 dual-core |
|
|
| +----------------+-----------------------------------------+
|
|
| | RAM | ~1GB for 1TB of storage per daemon |
|
|
| +----------------+-----------------------------------------+
|
|
| | Volume Storage | 1x storage drive per daemon |
|
|
| +----------------+-----------------------------------------+
|
|
| | Journal | 1x SSD partition per daemon (optional) |
|
|
| +----------------+-----------------------------------------+
|
|
| | Network | 2x 1GB Ethernet NICs |
|
|
+--------------+----------------+-----------------------------------------+
|
|
| ``ceph-mon`` | Processor | - 1x 64-bit AMD-64/i386 |
|
|
| | | - 1x 32-bit ARM dual-core or better |
|
|
| | | - 1x i386 dual-core |
|
|
| +----------------+-----------------------------------------+
|
|
| | RAM | 1 GB per daemon |
|
|
| +----------------+-----------------------------------------+
|
|
| | Disk Space | 10 GB per daemon |
|
|
| +----------------+-----------------------------------------+
|
|
| | Network | 2x 1GB Ethernet NICs |
|
|
+--------------+----------------+-----------------------------------------+
|
|
| ``ceph-mds`` | Processor | - 1x 64-bit AMD-64 quad-core |
|
|
| | | - 1x 32-bit ARM quad-core |
|
|
| | | - 1x i386 quad-core |
|
|
| +----------------+-----------------------------------------+
|
|
| | RAM | 1 GB minimum per daemon |
|
|
| +----------------+-----------------------------------------+
|
|
| | Disk Space | 1 MB per daemon |
|
|
| +----------------+-----------------------------------------+
|
|
| | Network | 2x 1GB Ethernet NICs |
|
|
+--------------+----------------+-----------------------------------------+
|
|
|
|
.. tip:: If you are running an OSD with a single disk, create a
|
|
partition for your volume storage that is separate from the partition
|
|
containing the OS. Generally, we recommend separate disks for the
|
|
OS and the volume storage.
|
|
|
|
|
|
Production Cluster Examples
|
|
===========================
|
|
|
|
Production clusters for petabyte scale data storage may also use commodity
|
|
hardware, but should have considerably more memory, processing power and data
|
|
storage to account for heavy traffic loads.
|
|
|
|
Dell Example
|
|
------------
|
|
|
|
A recent (2012) Ceph cluster project is using two fairly robust hardware
|
|
configurations for Ceph OSDs, and a lighter configuration for monitors.
|
|
|
|
+----------------+----------------+------------------------------------+
|
|
| Configuration | Criteria | Minimum Recommended |
|
|
+================+================+====================================+
|
|
| Dell PE R510 | Processor | 2x 64-bit quad-core Xeon CPUs |
|
|
| +----------------+------------------------------------+
|
|
| | RAM | 16 GB |
|
|
| +----------------+------------------------------------+
|
|
| | Volume Storage | 8x 2TB drives. 1 OS, 7 Storage |
|
|
| +----------------+------------------------------------+
|
|
| | Client Network | 2x 1GB Ethernet NICs |
|
|
| +----------------+------------------------------------+
|
|
| | OSD Network | 2x 1GB Ethernet NICs |
|
|
| +----------------+------------------------------------+
|
|
| | Mgmt. Network | 2x 1GB Ethernet NICs |
|
|
+----------------+----------------+------------------------------------+
|
|
| Dell PE R515 | Processor | 1x hex-core Opteron CPU |
|
|
| +----------------+------------------------------------+
|
|
| | RAM | 16 GB |
|
|
| +----------------+------------------------------------+
|
|
| | Volume Storage | 12x 3TB drives. Storage |
|
|
| +----------------+------------------------------------+
|
|
| | OS Storage | 1x 500GB drive. Operating System. |
|
|
| +----------------+------------------------------------+
|
|
| | Client Network | 2x 1GB Ethernet NICs |
|
|
| +----------------+------------------------------------+
|
|
| | OSD Network | 2x 1GB Ethernet NICs |
|
|
| +----------------+------------------------------------+
|
|
| | Mgmt. Network | 2x 1GB Ethernet NICs |
|
|
+----------------+----------------+------------------------------------+
|
|
|
|
|
|
|
|
|
|
|
|
.. _Ceph Write Throughput 1: http://ceph.com/community/ceph-performance-part-1-disk-controller-write-throughput/
|
|
.. _Ceph Write Throughput 2: http://ceph.com/community/ceph-performance-part-2-write-throughput-without-ssd-journals/
|
|
.. _Argonaut v. Bobtail Performance Preview: http://ceph.com/uncategorized/argonaut-vs-bobtail-performance-preview/
|
|
.. _Bobtail Performance - I/O Scheduler Comparison: http://ceph.com/community/ceph-bobtail-performance-io-scheduler-comparison/
|
|
.. _Mapping Pools to Different Types of OSDs: http://ceph.com/docs/master/rados/operations/crush-map/#placing-different-pools-on-different-osds
|
|
.. _OS Recommendations: ../os-recommendations
|