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.

CPU

CephFS metadata servers (MDS) are CPU-intensive. CephFS metadata servers (MDS) should therefore have quad-core (or better) CPUs and high clock rates (GHz). OSD nodes need enough processing power to run the RADOS service, to calculate data placement with CRUSH, to replicate data, and to maintain their own copies of the cluster map.

The requirements of one Ceph cluster are not the same as the requirements of another, but here are some general guidelines.

In earlier versions of Ceph, we would make hardware recommendations based on the number of cores per OSD, but this cores-per-OSD metric is no longer as useful a metric as the number of cycles per IOP and the number of IOPs per OSD. For example, for NVMe drives, Ceph can easily utilize five or six cores on real clusters and up to about fourteen cores on single OSDs in isolation. So cores per OSD are no longer as pressing a concern as they were. When selecting hardware, select for IOPs per core.

Monitor nodes and manager nodes have no heavy CPU demands and require only modest processors. If your host machines will run CPU-intensive processes in addition to Ceph daemons, make sure that you have enough processing power to run both the CPU-intensive processes and the Ceph daemons. (OpenStack Nova is one such example of a CPU-intensive process.) We recommend that you run non-Ceph CPU-intensive processes on separate hosts (that is, on hosts that are not your monitor and manager nodes) in order to avoid resource contention.

RAM

Generally, more RAM is better. Monitor / manager nodes for a modest cluster might do fine with 64GB; for a larger cluster with hundreds of OSDs 128GB is a reasonable target. There is a memory target for BlueStore OSDs that defaults to 4GB. Factor in a prudent margin for the operating system and administrative tasks (like monitoring and metrics) as well as increased consumption during recovery: provisioning ~8GB per BlueStore OSD is advised.

Monitors and managers (ceph-mon and ceph-mgr)

Monitor and manager daemon memory usage generally scales with the size of the cluster. Note that at boot-time and during topology changes and recovery these daemons will need more RAM than they do during steady-state operation, so plan for peak usage. For very small clusters, 32 GB suffices. For clusters of up to, say, 300 OSDs go with 64GB. For clusters built with (or which will grow to) even more OSDs you should provision 128GB. You may also want to consider tuning the following settings:

  • mon_osd_cache_size

  • rocksdb_cache_size

Metadata servers (ceph-mds)

The metadata daemon memory utilization depends on how much memory its cache is configured to consume. We recommend 1 GB as a minimum for most systems. See mds_cache_memory.

Memory

Bluestore uses its own memory to cache data rather than relying on the operating system’s page cache. In Bluestore you can adjust the amount of memory that the OSD attempts to consume by changing the osd_memory_target configuration option.

  • Setting the osd_memory_target below 2GB is typically not recommended (Ceph may fail to keep the memory consumption under 2GB and this may cause extremely slow performance).

  • Setting the memory target between 2GB and 4GB typically works but may result in degraded performance: metadata may be read from disk during IO unless the active data set is relatively small.

  • 4GB is the current default osd_memory_target size. This default was chosen for typical use cases, and is intended to balance memory requirements and OSD performance.

  • Setting the osd_memory_target higher than 4GB can improve performance when there many (small) objects or when large (256GB/OSD or more) data sets are processed.

Important

OSD memory autotuning is “best effort”. Although the OSD may unmap memory to allow the kernel to reclaim it, there is no guarantee that the kernel will actually reclaim freed memory within a specific time frame. This applies especially in older versions of Ceph, where transparent huge pages can prevent the kernel from reclaiming memory that was freed from fragmented huge pages. Modern versions of Ceph disable transparent huge pages at the application level to avoid this, but that does not guarantee that the kernel will immediately reclaim unmapped memory. The OSD may still at times exceed its memory target. We recommend budgeting approximately 20% extra memory on your system to prevent OSDs from going OOM (Out Of Memory) during temporary spikes or due to delay in the kernel reclaiming freed pages. That 20% value might be more or less than needed, depending on the exact configuration of the system.

When using the legacy FileStore back end, the page cache is used for caching data, so no tuning is normally needed. When using the legacy FileStore backend, the OSD memory consumption is related to the number of PGs per daemon in the system.

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 requests from multiple daemons for read and write operations against a single drive can slow performance.

Hard Disk Drives

OSDs should have plenty of storage drive space for object data. We recommend a minimum disk drive size of 1 terabyte. Consider the cost-per-gigabyte advantage of larger disks. We recommend dividing the price of the 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 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.

Tip

Running multiple OSDs on a single SAS / SATA drive is NOT a good idea. NVMe drives, however, can achieve improved performance by being split into two or more OSDs.

Tip

Running an OSD and a monitor or a metadata server on a single drive is also NOT a good idea.

Tip

With spinning disks, the SATA and SAS interface increasingly becomes a bottleneck at larger capacities. See also the Storage Networking Industry Association’s Total Cost of Ownership calculator.

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 (ideally mirrored) drive for the operating system and software, and one drive for each Ceph OSD Daemon you run on the host (modulo NVMe above). Many “slow OSD” issues (when they are not attributable to hardware failure) arise from running an operating system and multiple OSDs on the same drive.

It is technically possible to run multiple Ceph OSD Daemons per SAS / SATA drive, but this will lead to resource contention and diminish overall throughput.

To get the best performance out of Ceph, run the following on separate drives: (1) operating systems, (2) OSD data, and (3) BlueStore db. For more information on how to effectively use a mix of fast drives and slow drives in your Ceph cluster, see the block and block.db section of the Bluestore Configuration Reference.

Solid State Drives

Ceph performance can be improved by using solid-state drives (SSDs). This reduces random access time and reduces latency while accelerating throughput.

SSDs cost more per gigabyte than do hard disk drives, but SSDs often offer access times that are, at a minimum, 100 times faster than hard disk drives. SSDs avoid hotspot issues and bottleneck issues within busy clusters, and they may offer better economics when TCO is evaluated holistically.

SSDs do not have moving mechanical parts, so they are not 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.

Important

We recommend exploring the use of SSDs to improve performance. However, before making a significant investment in SSDs, we strongly recommend reviewing the performance metrics of an SSD and testing the SSD in a test configuration in order to gauge performance.

Relatively inexpensive SSDs may appeal to your sense of economy. Use caution. Acceptable IOPS are not the only factor to consider when selecting an SSD for use with Ceph.

SSDs have historically been cost prohibitive for object storage, but emerging QLC drives are closing the gap, offering greater density with lower power consumption and less power spent on cooling. HDD OSDs may see a significant performance improvement by offloading WAL+DB onto an SSD.

To get a better sense of the factors that determine the cost of storage, you might use the Storage Networking Industry Association’s Total Cost of Ownership calculator

Partition Alignment

When using SSDs with Ceph, make sure that your partitions are properly aligned. Improperly aligned partitions suffer slower data transfer speeds than do properly aligned partitions. For more information about proper partition alignment and example commands that show how to align partitions properly, see Werner Fischer’s blog post on partition alignment.

CephFS Metadata Segregation

One way that Ceph accelerates CephFS file system performance is by segregating 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 SSD storage media. See CRUSH Device Class for details.

Controllers

Disk controllers (HBAs) can have a significant impact on write throughput. Carefully consider your selection of HBAs to ensure that they do not create a performance bottleneck. Notably, RAID-mode (IR) HBAs may exhibit higher latency than simpler “JBOD” (IT) mode HBAs. The RAID SoC, write cache, and battery backup can substantially increase hardware and maintenance costs. Some RAID HBAs can be configured with an IT-mode “personality”.

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.

Benchmarking

BlueStore opens block devices in O_DIRECT and uses fsync frequently to ensure that data is safely persisted to media. You can evaluate a drive’s low-level write performance using fio. For example, 4kB random write performance is measured as follows:

# fio --name=/dev/sdX --ioengine=libaio --direct=1 --fsync=1 --readwrite=randwrite --blocksize=4k --runtime=300

Write Caches

Enterprise SSDs and HDDs normally include power loss protection features which use multi-level caches to speed up direct or synchronous writes. These devices can be toggled between two caching modes – a volatile cache flushed to persistent media with fsync, or a non-volatile cache written synchronously.

These two modes are selected by either “enabling” or “disabling” the write (volatile) cache. When the volatile cache is enabled, Linux uses a device in “write back” mode, and when disabled, it uses “write through”.

The default configuration (normally caching enabled) may not be optimal, and OSD performance may be dramatically increased in terms of increased IOPS and decreased commit_latency by disabling the write cache.

Users are therefore encouraged to benchmark their devices with fio as described earlier and persist the optimal cache configuration for their devices.

The cache configuration can be queried with hdparm, sdparm, smartctl or by reading the values in /sys/class/scsi_disk/*/cache_type, for example:

# hdparm -W /dev/sda

/dev/sda:
 write-caching =  1 (on)

# sdparm --get WCE /dev/sda
    /dev/sda: ATA       TOSHIBA MG07ACA1  0101
WCE           1  [cha: y]
# smartctl -g wcache /dev/sda
smartctl 7.1 2020-04-05 r5049 [x86_64-linux-4.18.0-305.19.1.el8_4.x86_64] (local build)
Copyright (C) 2002-19, Bruce Allen, Christian Franke, www.smartmontools.org

Write cache is:   Enabled

# cat /sys/class/scsi_disk/0\:0\:0\:0/cache_type
write back

The write cache can be disabled with those same tools:

# hdparm -W0 /dev/sda

/dev/sda:
 setting drive write-caching to 0 (off)
 write-caching =  0 (off)

# sdparm --clear WCE /dev/sda
    /dev/sda: ATA       TOSHIBA MG07ACA1  0101
# smartctl -s wcache,off /dev/sda
smartctl 7.1 2020-04-05 r5049 [x86_64-linux-4.18.0-305.19.1.el8_4.x86_64] (local build)
Copyright (C) 2002-19, Bruce Allen, Christian Franke, www.smartmontools.org

=== START OF ENABLE/DISABLE COMMANDS SECTION ===
Write cache disabled

Normally, disabling the cache using hdparm, sdparm, or smartctl results in the cache_type changing automatically to “write through”. If this is not the case, you can try setting it directly as follows. (Users should note that setting cache_type also correctly persists the caching mode of the device until the next reboot):

# echo "write through" > /sys/class/scsi_disk/0\:0\:0\:0/cache_type

# hdparm -W /dev/sda

/dev/sda:
 write-caching =  0 (off)

Tip

This udev rule (tested on CentOS 8) will set all SATA/SAS device cache_types to “write through”:

# cat /etc/udev/rules.d/99-ceph-write-through.rules
ACTION=="add", SUBSYSTEM=="scsi_disk", ATTR{cache_type}:="write through"

Tip

This udev rule (tested on CentOS 7) will set all SATA/SAS device cache_types to “write through”:

# cat /etc/udev/rules.d/99-ceph-write-through-el7.rules
ACTION=="add", SUBSYSTEM=="scsi_disk", RUN+="/bin/sh -c 'echo write through > /sys/class/scsi_disk/$kernel/cache_type'"

Tip

The sdparm utility can be used to view/change the volatile write cache on several devices at once:

# sdparm --get WCE /dev/sd*
    /dev/sda: ATA       TOSHIBA MG07ACA1  0101
WCE           0  [cha: y]
    /dev/sdb: ATA       TOSHIBA MG07ACA1  0101
WCE           0  [cha: y]
# sdparm --clear WCE /dev/sd*
    /dev/sda: ATA       TOSHIBA MG07ACA1  0101
    /dev/sdb: ATA       TOSHIBA MG07ACA1  0101

Additional Considerations

You typically will run multiple OSDs per host, but you should ensure that the aggregate throughput of your OSD drives 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.

Networks

Provision at least 10 Gb/s networking in your racks.

Speed

It takes three hours to replicate 1 TB of data across a 1 Gb/s network and it takes thirty hours to replicate 10 TB across a 1 Gb/s network. But it takes only twenty minutes to replicate 1 TB across a 10 Gb/s network, and it takes only one hour to replicate 10 TB across a 10 Gb/s network.

Cost

The larger the Ceph cluster, the more common OSD failures will be. The faster that a placement group (PG) can recover from a degraded state to an active + clean state, the better. Notably, fast recovery minimizes the liklihood of multiple, overlapping failures that can cause data to become temporarily unavailable or even lost. Of course, when provisioning your network, you will have to balance price against performance.

Some deployment tools employ VLANs to make hardware and network cabling more manageable. VLANs that use the 802.1q protocol require VLAN-capable NICs and switches. The added expense of this hardware may be offset by the operational cost savings on network setup and maintenance. When using VLANs to handle VM traffic between the cluster and compute stacks (e.g., OpenStack, CloudStack, etc.), there is additional value in using 10 Gb/s Ethernet or better; 40 Gb/s or 25/50/100 Gb/s networking as of 2022 is common for production clusters.

Top-of-rack (TOR) switches also need fast and redundant uplinks to spind spine switches / routers, often at least 40 Gb/s.

Baseboard Management Controller (BMC)

Your server chassis should have a Baseboard Management Controller (BMC). Well-known examples are iDRAC (Dell), CIMC (Cisco UCS), and iLO (HPE). Administration and deployment tools may also use BMCs extensively, especially via IPMI or Redfish, so consider the cost/benefit tradeoff of an out-of-band network for security and 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 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

  • 1 core minimum

  • 1 core per 200-500 MB/s

  • 1 core per 1000-3000 IOPS

  • Results are before replication.

  • Results may vary with different CPU models and Ceph features. (erasure coding, compression, etc)

  • ARM processors specifically may require additional cores.

  • Actual performance depends on many factors including drives, net, and client throughput and latency. Benchmarking is highly recommended.

RAM

  • 4GB+ per daemon (more is better)

  • 2-4GB often functions (may be slow)

  • Less than 2GB not recommended

Volume Storage

1x storage drive per daemon

DB/WAL

1x SSD partition per daemon (optional)

Network

1x 1GbE+ NICs (10GbE+ recommended)

ceph-mon

Processor

  • 2 cores minimum

RAM

2-4GB+ per daemon

Disk Space

60 GB per daemon

Network

1x 1GbE+ NICs

ceph-mds

Processor

  • 2 cores minimum

RAM

2GB+ per daemon

Disk Space

1 MB per daemon

Network

1x 1GbE+ 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.