diff --git a/ra/next/resource-agent-api.md b/ra/next/resource-agent-api.md index ff93f0d..5636af3 100644 --- a/ra/next/resource-agent-api.md +++ b/ra/next/resource-agent-api.md @@ -1,595 +1,594 @@ **DRAFT - DRAFT - DRAFT** **JOIN THE developers@clusterlabs.org MAILING LIST AND FOLLOW PULL REQUESTS AT https://github.com/ClusterLabs/OCF-spec/ TO DISCUSS CHANGES** # Open Clustering Framework Resource Agent API -Editor: Lars Marowsky-Brée - URL: https://github.com/ClusterLabs/OCF-spec/blob/master/ra/next/resource-agent-api.md ## Abstract The Open Clustering Framework Resource Agent (RA) API provides an abstraction layer between diverse, computer-hosted resources and diverse types of software managing such resources in a clustered environment. The RA API allows resources to be managed without any modification to the actual resource providers, by providing a standardized interface to common management tasks. It also allows (but does not require) RAs to be designed without consideration of specific software that might invoke them, and thus shared by any such software. ## Status of This Memo This is an Open Cluster Framework (OCF) document produced by ClusterLabs . This document describes proposed extensions to the OCF RA API, which may be incorporated into future versions of the standard. It has not been adopted as a standard, and should be considered for discussion purposes only. ## Copyright Notice -Copyright 2002,2018 Lars Marowsky-Brée +Originally Copyright 2002,2018 Lars Marowsky-Brée +Later changes copyright 2020 the Open Cluster Framework project contributors Permission is granted to copy, distribute and/or modify this document under the terms of the GNU Free Documentation License, Version 1.2 or any later version published by the Free Software Foundation; with no Invariant Sections, no Front-Cover Texts, and no Back-Cover Texts. A copy of the license can be found at http://www.gnu.org/licenses/fdl.txt. ## Terms used in this document ### Resource A _resource_, also known as a _resource instance_, is a logical entity that provides a particular computer-hosted service. Examples of resources include a disk volume, a network address, a web server, or a virtual machine. ### Cluster A _cluster_ is a collection of one or more computers under common administration running a set of resources. ### Resource Manager A _resource manager_ (RM), also known as a _cluster resource manager_ (CRM), is software that manages resources in a cluster. ### Resource Type A _resource type_ is a name indicating the service provided by a resource. This name should be suitable for use as a file name. ### Resource Agent A _resource agent_ (RA) is a software application implementing the RA API for a particular resource type. An RA allows a resource manager to perform specific mangement tasks for resource instances. ### Resource Agent Provider A _resource agent provider_ is an entity supplying one or more resource agents for installation on cluster hosts. Each provider should have a unique name suitable for use as a file system directory name. A provider may choose to supply multiple, separate collections of resource agents. In this case, each collection should have a unique name, and _provider_ may refer either to the entity as a whole, or to an individual collection. Currently, there is no central registry for provider names. Providers should choose names that do not appear to be already in use for publicly available resource agents. Each provider also chooses the resource type names used for the resource agents it provides. These do not need to be unique across providers. ### Resource Name A _resource name_ is a unique identifier chosen by the cluster administrator to identify a particular resource instance. ### Resource Parameters _Resource parameters_, also known as _instance parameters_, are attributes describing a particular resource instance. Each parameter has a name and a value, which must satisfy the requirements of POSIX environment variable names and values. The resource agent defines the names, meaning, and allowed values of parameters available for its resource type. The cluster administrator specifies the particular parameters used for each resource instance. ## API ### API Version Numbers The version number is of the form `x.y`, where `x` and `y` are positive numbers greater or equal to zero. `x` is referred to as the "major" number, and `y` as the "minor" number. The major number must be increased if a _backwards incompatible_ change is made to the API. A major number mismatch between the RA and the RM must be reported as an error by both sides. The minor number must be increased if _any_ change at all is made to the API. If the major is increased, the minor number should be reset to zero. The minor number can be used by both sides to see whether a certain additional feature is supported by the other party. ### The Resource Agent Directory Resource agents are executable files that must be made available beneath a common location on a host's file system, referred to as the _resource agent directory_. In the 1.0 version of this standard, the only acceptable location of this directory was `/usr/ocf/resource.d`. However, in practice, installations typically used the nonconforming location `/usr/lib/ocf/resource.d`. For strict compatibility with the standard, resource agents should be installed in the 1.0 location, and resource managers should look for agents there. For widest compatibility, resource agents and resource managers should allow the installer to choose the location of the directory, which should have a reasonable default, and should be identical for all resource agents and resource managers installed on a particular host. Resource managers may also choose to search multiple locations. ### The Resource Agent Directory Tree Each provider shall install its resource agents in a subdirectory of the resource agent directory, using the provider's name. This allows installation of multiple resource agents for the same type, but from different suppliers or package versions. Each resource agent should be installed as a file within the provider subdirectory, named according to the resource type. The provider subdirectory and resource agent file may be links to the actual locations. A simple example of a resource agent directory tree containing a single provider `acme` that provides resource agents `widget` and `gadget`: acme/ acme/widget acme/gadget Another example where multiple versions of acme's agents are installed: acme -> acme-2.0/ acme-1.0/ acme-1.0/widget acme-1.0/gadget acme-2.0/ acme-2.0/widget acme-2.0/gadget An example with two providers, an agent available from two providers, and an agent available under multiple names from the same provider: acme/ acme/widget acme/gadget betterco/ betterco/widget betterco/IP -> IPAddr betterco/IPAddr Resource managers may choose an agent for a specific resource type name from the available set in any manner they choose. ### Execution syntax After the RM has identified the executable to call, the RA will be called with the requested action as its sole argument. To allow for further extensions, the RA shall ignore all other arguments. ### Resource Agent Actions Resource agents must accept a single command-line argument specifying an action to be performed. RAs must be able to perform actions listed in this section as mandatory, and must advertise them as described in **Resource Agent Meta-Data**. RAs may support any additional actions, including but not limited to those listed in this section as optional. Actions must be idempotent. Invoking an already successfully performed action additional times must be successful and leave the resource instance in the requested state. For example, a start command given to a resource that has already been successfully started should return success without changing the state of the resource. An RA should not assume it is the only RA of its type running at any given time. Multiple resource instances of the same type may be running in parallel. An RA must return a well-defined status, as described under **Exit Status Codes**. This includes improper usage such as being called with an unsupported action. #### Mandatory Actions - `start` This must bring the resource instance online and makes it available for use. It should NOT terminate before the resource instance has either been fully started or an error has been encountered. It may try to implement recovery actions for certain cases of startup failures. `start` must succeed if the resource instance is already running. `start` must return an error if the resource instance is not fully started. - `stop` This must stop the resource instance. After the `stop` command has completed, no component of the resource shall remain active, and it must be possible to start it on the same node or another node, otherwise an error must be returned. The `stop` request by the RM includes the authorization to bring down the resource even by force as long as data integrity is maintained. Breaking currently active transactions should be avoided, but the request to offline the resource has higher priority than this. If this is not possible, the RA shall return an error, to allow higher-level recovery. The `stop` action should also clean up any artifacts such as leftover shared memory segments, semaphores, IPC message queues, lock files, etc. `stop` must succeed if the resource is already stopped. `stop` must return an error if the resource is not fully stopped. - `monitor` This must check the current status of the resource instance. The thoroughness of the check is influenced by the weight of the check, as described under **Monitor-Specific Parameters**. An RA may have additional instance parameters which are not strictly required to identify the resource instance but are useful for monitoring it. In particular, RAs may support an integer _depth_ parameter specifying how intrusive this check is allowed to be (which values for depth are supported and what degree of intrusiveness they correspond to is left to the RA). - `meta-data` This must display the XML information described under **Resource Agent Meta-Data** via standard output. #### Optional Actions - `demote` If the resource supports two modes of operation (_roles_), this action must put the resource in the default role (the role that a start action leaves the resource in). - `notify` If the resource requires special coordination when multiple instances are run simultaneously in the cluster, the resource agent should support this action, which should perform such coordination. When the RA supports this action, RMs should call the action for all active instances of this particular resource in the cluster before and after any demote, promote, start, or stop action performed on any instance of it. How the RM passes useful information to the RA when performing this action is currently left to the RM and RA, but may be formalized in a future version of this standard. - `promote` If the resource supports roles, this action must put the resource in the special (non-default) role. - `recover` A special case of the `start` action, this should try to recover a resource locally. It is recommended that this action is not advertised unless it is advantageous to use when compared to a stop and start action sequence. If this is not supported, it may be mapped to a stop and start action sequence by the RM. An example includes "recovering" an IP address by moving it to another interface; this is much less costly than initiating a full resource group fail-over to another node. - `reload` This should notify the resource instance of a configuration change external to the instance parameters. It should reload the configuration of the resource instance without disrupting the service. It is recommended that this action is not advertised unless it is advantageous to use when compared to a stop and start action sequence. If this is not supported, it may be mapped to a stop and start action sequence by the RM. - `validate-all` This should validate the instance parameters provided. This should perform a syntax check, and if possible a semantic check, on the instance parameters. ### Parameter passing The instance parameters and some additional attributes are passed in via the environment; this has been chosen because it does not reveal the parameters to an unprivileged user on the same system and environment variables can be easily accessed by all programming languages and shell scripts. The entire environment variable name space starting with `OCF_` is considered to be reserved for OCF use. #### Syntax for instance parameters They are directly converted to environment variables; the name is prefixed with `OCF_RESKEY_`. The instance parameter `force` with the value `yes` thus becomes `OCF_RESKEY_force=yes` in the environment. See the terms section on instance parameters for a more formal explanation. #### Global OCF attributes Currently, the following additional environment variables are defined: * `OCF_RA_VERSION_MAJOR` * `OCF_RA_VERSION_MINOR` Version number of the OCF Resource Agent API. If the script does not support this revision, it should report an error. See **API Version Numbers** for an explanation of the versioning scheme used. The version number is split into two numbers for ease of use in shell scripts. These two may be used by the RA to determine whether it is run under an OCF compliant RM. Example: ``` OCF_RA_VERSION_MAJOR=1 OCF_RA_VERSION_MINOR=1 ``` * `OCF_ROOT` Referring to the root of the OCF directory hierarchy. Example: `OCF_ROOT=/usr/ocf` * `OCF_RESOURCE_INSTANCE` The name of the resource instance. * `OCF_RESOURCE_TYPE` The name of the resource type being operated on. #### Monitor-Specific Parameters Resource agents may optionally support the parameters listed here when called with the `monitor` action. - `OCF_CHECK_LEVEL` - `0` The most lightweight check possible, which should not have an impact on the QoS. Example: Check for the existence of the process. - `10` A medium weight check, expected to be called multiple times per minute, which should not have a noticeable impact on the QoS. Example: Send a request for a static page to a webserver. - `20` A heavy weight check, called infrequently, which may impact system or service performance. Example: An internal consistency check to verify service integrity. Service must remain available during all of these operation. All other number are reserved. It is recommended that if a requested level is not implemented, the RA should perform the next lower level supported. ### Exit Status Codes These exit status codes are identical to those documented in the LSB 5.0 Core specification for non-status "Init Script Actions" , with additional explanations of how they shall be used by RAs. Non-zero status codes are referred to in this document as errors, however RA developers should keep in mind that RMs decide whether a status code is a failure or not (for example, if a particular error is the expected situation, it may not be considered a failure). - `0` No error, action succeeded completely - `1` Generic or unspecified error (current practice) The "monitor" action shall return this for a crashed, hung or otherwise non-functional resource. - `2` Invalid or excess argument(s) Likely error code for validate-all, if the instance parameters do not validate. Any other action is free to also return this exit status code for this case. - `3` Unimplemented feature RAs should return this for unsupported actions (for example, "reload"). - `4` User had insufficient privilege - `5` Program is not installed - `6` Program is not configured - `7` Program is not running Note: This is not the error code to be returned by a successful "stop" operation. A successful "stop" operation shall return 0. The "monitor" action shall return this value only for a _cleanly_ stopped resource. If in doubt, it should return 1. - `8-99` Reserved for future LSB use - `100-149` Reserved for distribution use - `150-199` Reserved for application use - `200-254` Reserved ## Relation to the LSB The RA API aims to make it possible for (but does not require) an RA to function as both an LSB-compliant init script and a cluster-aware RA. RAs may use helper functions defined for LSB init scripts. ## Resource Agent Meta-Data ### Format While the LSB uses shell script comments at the beginning of init scripts to provide meta-data, OCF RA meta-data is described using XML so that the meta-data can be: - Independent of the language the RA itself is written in, - Extensible, - Structured, and - Easy to parse from a variety of languages. RA meta-data shall conform to the XML schema formally described at . ### Example An example of a valid meta-data output is provided at . ### Semantics Certain meta-data XML elements warrant further explanation: - `resource-agent`: The optional `version` attribute should describe the version of the agent itself. - `version`: This is the version of the OCF RA standard with which the RA claims compatibility. - `longdesc` and `shortdesc`: These are hints to tools describing the purpose of the agent. They may contain any XML, but it is strongly recommended to limit the content to a text string. - `parameter`: - `unique` attribute: This is a hint to RMs and other tools that the combination of all parameters marked `unique` must be unique to the resource type. That is, no two resource instances of the same resource type may have the same combination of `unique` parameters. - `required` attribute: This is a hint to RMs and other tools that every resource instance of this resource type must specify a value for this parameter. - `longdesc` and `shortdesc`: The same guidance applies as described above when these tags appear under `resource-agent`. - `action`: Resource agents should advertise each action they support, including all mandatory actions, with an `action` element. - `name` attribute (required): This is a unique identifier for the action as described in **Resource Agent Actions**. There may be multiple `action` entries with the same name and different values for other attributes (for example, to recommend different timeout and interval values for status actions of different depths). - `timeout` attribute (required): This is a hint to RMs and other tools that every resource instance of this resource type should specify a timeout equal to or greater than this value (when used with any other attribute values specified in this entry). - `interval` attribute (optional): This is a hint to RMs and other tools that every resource instance of this resource type should repeat this action at intervals equal to this value (when used with any other attribute values specified in this entry). - `depth` attribute (optional): This is a hint to RMs and other tools that this action of the resource agent utilizes the depth parameter with this value, as described in **Resource Agent Actions**. - `role` attribute (optional): This is a hint to RMs and other tools that this action of the resource agent recognizes this role value, as described in **Resource Agent Actions**. ## Contributors - James Bottomley - Greg Freemyer - Simon Horman - Ragnar Kjørstad - Lars Marowsky-Brée - Alan Robertson - Yixiong Zou - Ken Gaillot