OSD Scenarios ============= The following are all of the available options for the ``osd_scenario`` config setting. Defining an ``osd_scenario`` is mandatory for using ``ceph-ansible``. collocated ---------- This OSD scenario uses ``ceph-disk`` to create OSDs with collocated journals from raw devices. Use ``osd_scenario: collocated`` to enable this scenario. This scenario also has the following required configuration options: - ``devices`` This scenario has the following optional configuration options: - ``osd_objectstore``: defaults to ``filestore`` if not set. Available options are ``filestore`` or ``bluestore``. You can only select ``bluestore`` if the ceph release is Luminous or greater. - ``dmcrypt``: defaults to ``false`` if not set. This scenario supports encrypting your OSDs by setting ``dmcrypt: True``. If ``osd_objectstore: filestore`` is enabled both 'ceph data' and 'ceph journal' partitions will be stored on the same device. If ``osd_objectstore: bluestore`` is enabled 'ceph data', 'ceph block', 'ceph block.db', 'ceph block.wal' will be stored on the same device. The device will get 2 partitions: - One for 'data', called 'ceph data' - One for 'ceph block', 'ceph block.db', 'ceph block.wal' called 'ceph block' Example of what you will get:: [root@ceph-osd0 ~]# blkid /dev/sda* /dev/sda: PTTYPE="gpt" /dev/sda1: UUID="9c43e346-dd6e-431f-92d8-cbed4ccb25f6" TYPE="xfs" PARTLABEL="ceph data" PARTUUID="749c71c9-ed8f-4930-82a7-a48a3bcdb1c7" /dev/sda2: PARTLABEL="ceph block" PARTUUID="e6ca3e1d-4702-4569-abfa-e285de328e9d" An example of using the ``collocated`` OSD scenario with encryption would look like:: osd_scenario: collocated dmcrypt: true devices: - /dev/sda - /dev/sdb non-collocated -------------- This OSD scenario uses ``ceph-disk`` to create OSDs from raw devices with journals that exist on a dedicated device. Use ``osd_scenario: non-collocated`` to enable this scenario. This scenario also has the following required configuration options: - ``devices`` This scenario has the following optional configuration options: - ``dedicated_devices``: defaults to ``devices`` if not set - ``osd_objectstore``: defaults to ``filestore`` if not set. Available options are ``filestore`` or ``bluestore``. You can only select ``bluestore`` with the ceph release is Luminous or greater. - ``dmcrypt``: defaults to ``false`` if not set. This scenario supports encrypting your OSDs by setting ``dmcrypt: True``. If ``osd_objectstore: filestore`` is enabled 'ceph data' and 'ceph journal' partitions will be stored on different devices: - 'ceph data' will be stored on the device listed in ``devices`` - 'ceph journal' will be stored on the device listed in ``dedicated_devices`` Let's take an example, imagine ``devices`` was declared like this:: devices: - /dev/sda - /dev/sdb - /dev/sdc - /dev/sdd And ``dedicated_devices`` was declared like this:: dedicated_devices: - /dev/sdf - /dev/sdf - /dev/sdg - /dev/sdg This will result in the following mapping: - /dev/sda will have /dev/sdf1 as journal - /dev/sdb will have /dev/sdf2 as a journal - /dev/sdc will have /dev/sdg1 as a journal - /dev/sdd will have /dev/sdg2 as a journal .. note:: On a containerized scenario we only support A SINGLE journal for all the OSDs on a given machine. If you don't, bad things will happen This is a limitation we plan to fix at some point. If ``osd_objectstore: bluestore`` is enabled, both 'ceph block.db' and 'ceph block.wal' partitions will be stored on a dedicated device. So the following will happen: - The devices listed in ``devices`` will get 2 partitions, one for 'block' and one for 'data'. 'data' is only 100MB big and do not store any of your data, it's just a bunch of Ceph metadata. 'block' will store all your actual data. - The devices in ``dedicated_devices`` will get 1 partition for RocksDB DB, called 'block.db' and one for RocksDB WAL, called 'block.wal' By default ``dedicated_devices`` will represent block.db Example of what you will get:: [root@ceph-osd0 ~]# blkid /dev/sd* /dev/sda: PTTYPE="gpt" /dev/sda1: UUID="c6821801-2f21-4980-add0-b7fc8bd424d5" TYPE="xfs" PARTLABEL="ceph data" PARTUUID="f2cc6fa8-5b41-4428-8d3f-6187453464d0" /dev/sda2: PARTLABEL="ceph block" PARTUUID="ea454807-983a-4cf2-899e-b2680643bc1c" /dev/sdb: PTTYPE="gpt" /dev/sdb1: PARTLABEL="ceph block.db" PARTUUID="af5b2d74-4c08-42cf-be57-7248c739e217" /dev/sdb2: PARTLABEL="ceph block.wal" PARTUUID="af3f8327-9aa9-4c2b-a497-cf0fe96d126a" There is more device granularity for Bluestore ONLY if ``osd_objectstore: bluestore`` is enabled by setting the ``bluestore_wal_devices`` config option. By default, if ``bluestore_wal_devices`` is empty, it will get the content of ``dedicated_devices``. If set, then you will have a dedicated partition on a specific device for block.wal. Example of what you will get:: [root@ceph-osd0 ~]# blkid /dev/sd* /dev/sda: PTTYPE="gpt" /dev/sda1: UUID="39241ae9-d119-4335-96b3-0898da8f45ce" TYPE="xfs" PARTLABEL="ceph data" PARTUUID="961e7313-bdb7-49e7-9ae7-077d65c4c669" /dev/sda2: PARTLABEL="ceph block" PARTUUID="bff8e54e-b780-4ece-aa16-3b2f2b8eb699" /dev/sdb: PTTYPE="gpt" /dev/sdb1: PARTLABEL="ceph block.db" PARTUUID="0734f6b6-cc94-49e9-93de-ba7e1d5b79e3" /dev/sdc: PTTYPE="gpt" /dev/sdc1: PARTLABEL="ceph block.wal" PARTUUID="824b84ba-6777-4272-bbbd-bfe2a25cecf3" An example of using the ``non-collocated`` OSD scenario with encryption, bluestore and dedicated wal devices would look like:: osd_scenario: non-collocated osd_objectstore: bluestore dmcrypt: true devices: - /dev/sda - /dev/sdb dedicated_devices: - /dev/sdc - /dev/sdc bluestore_wal_devices: - /dev/sdd - /dev/sdd lvm --- This OSD scenario uses ``ceph-volume`` to create OSDs from logical volumes and is only available when the ceph release is Luminous or newer. .. note:: The creation of the logical volumes is not supported by ``ceph-ansible``, ``ceph-volume`` only creates OSDs from existing logical volumes. ``lvm_volumes`` is the config option that needs to be defined to configure the mappings for devices to be deployed. It is a list of dictionaries which expects a volume name and a volume group for logical volumes, but can also accept a partition in the case of ``filestore`` for the ``journal``. This scenario supports encrypting your OSDs by setting ``dmcrypt: True``. If set, all OSDs defined in ``lvm_volumes`` will be encrypted. The ``data`` key represents the logical volume name, raw device or partition that is to be used for your OSD data. The ``data_vg`` key represents the volume group name that your ``data`` logical volume resides on. This key is required for purging of OSDs created by this scenario. .. note:: Any logical volume or logical group used in ``lvm_volumes`` must be a name and not a path. .. note:: You can not use the same journal for many OSDs. ``filestore`` ^^^^^^^^^^^^^ There is filestore support which can be enabled with:: osd_objectstore: filestore To configure this scenario use the ``lvm_volumes`` config option. ``lvm_volumes`` is a list of dictionaries which expects a volume name and a volume group for logical volumes, but can also accept a parition in the case of ``filestore`` for the ``journal``. The following keys are accepted for a ``filestore`` deployment: * ``data`` * ``data_vg`` (not required if ``data`` is a raw device or partition) * ``journal`` * ``journal_vg`` (not required if ``journal`` is a partition and not a logical volume) * ``crush_device_class`` (optional, sets the crush device class for the OSD) The ``journal`` key represents the logical volume name or partition that will be used for your OSD journal. For example, a configuration to use the ``lvm`` osd scenario would look like:: osd_objectstore: filestore osd_scenario: lvm lvm_volumes: - data: data-lv1 data_vg: vg1 journal: journal-lv1 journal_vg: vg2 crush_device_class: foo - data: data-lv2 journal: /dev/sda data_vg: vg1 - data: data-lv3 journal: /dev/sdb1 data_vg: vg2 - data: /dev/sda journal: /dev/sdb1 - data: /dev/sda1 journal: journal-lv1 journal_vg: vg2 For example, a configuration to use the ``lvm`` osd scenario with encryption would look like:: osd_objectstore: filestore osd_scenario: lvm dmcrypt: True lvm_volumes: - data: data-lv1 data_vg: vg1 journal: journal-lv1 journal_vg: vg2 crush_device_class: foo ``bluestore`` ^^^^^^^^^^^^^ This scenario allows a combination of devices to be used in an OSD. ``bluestore`` can work just with a single "block" device (specified by the ``data`` and optionally ``data_vg``) or additionally with a ``block.wal`` and ``block.db`` (interchangeably) The following keys are accepted for a ``bluestore`` deployment: * ``data`` (required) * ``data_vg`` (not required if ``data`` is a raw device or partition) * ``db`` (optional for ``block.db``) * ``db_vg`` (optional for ``block.db``) * ``wal`` (optional for ``block.wal``) * ``wal_vg`` (optional for ``block.wal``) * ``crush_device_class`` (optional, sets the crush device class for the OSD) A ``bluestore`` lvm deployment, for all four different combinations supported could look like:: osd_objectstore: bluestore osd_scenario: lvm lvm_volumes: - data: data-lv1 data_vg: vg1 crush_device_class: foo - data: data-lv2 data_vg: vg1 wal: wal-lv1 wal_vg: vg2 - data: data-lv3 data_vg: vg2 db: db-lv1 db_vg: vg2 - data: data-lv4 data_vg: vg4 db: db-lv4 db_vg: vg4 wal: wal-lv4 wal_vg: vg4 - data: /dev/sda