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API Hints & Quick How-Tos

Below you'll find some brief sections that show how some of the API calls in go-ceph work together. This is not meant to cover every possible use case but are recorded here as a quick way to get familiar with these calls.

General

Finding an API

The go-ceph project wraps existing APIs that are part of Ceph. There are two kinds of APIs that are wrapped. The first style of API is based on functions Ceph exports as client libraries in C. The three packages in go-ceph cephfs, rados, and rbd map to libcephfs, librados, and librbd respectively.

The go-ceph packages that wrap Ceph C APIs follow a documentation convention that aims to make it easier to map between the APIs. In functions that are implemented using a certain C API function a line with the term Implements: will be followed by the C function's declaration - matching what can be found in the C library's header file. For example, if you knew you wanted to wrap the rbd function to get an image's metadata, rbd_metadata_get, you could search within the source code or https://pkg.go.dev/github.com/ceph/go-ceph/rbd for rbd_metadata_get which would lead you to the GetMetadata method of the Image type.

The second style of API is based on functions implemented within Ceph services based on Ceph's "command" system. These functions are primarily accessed using the ceph command. Many of the functions within the ceph command are implemented by sending a structured JSON message to either the Ceph MON or MGR. Packages in go-ceph that wrap these sorts of APIs are found in cephfs/admin, rbd/admin, and common/admin/manager for example.

The command/JSON based API packages follow a different, but similar documentation convention to the C based APIs. Functions that roughly map to a particular ceph CLI command will contain a line with the term Similar To: followed by the ceph command it is similar to. For example, if you knew you wanted to create a CephFS subvolume group and would normally use the command ceph fs subvolumegroup create to do so, you could search within the source code or https://pkg.go.dev/github.com/ceph/go-ceph/cephfs/admin for ceph fs subvolumegroup create which would lead you to the CreateSubVolumeGroup property of the FSAdmin type.

Can't find the API you want?

The go-ceph project is maintained separately from Ceph and it is common for APIs to be added to Ceph that are not present in go-ceph. Sometimes we resolve the differences quickly but not always.

Generally, there is no simple way to access a C based API from Go without updates to the code. If there's an API that you need that doesn't appear to be wrapped by go-ceph, please file an issue. If you are comfortable writing Go and would like to try writing a wrapper function we're more than happy to welcome contributions as well.

The command/JSON based APIs can be accessed without directly wrapping them. The large majority of these functions are based on either rados.MgrCommand or rados.MonCommand. Both these functions accept a formatted JSON object that maps to a command line constant prefix and the variable argument values. Determining the JSON prefix and accepted arguments can be done using a special JSON-command: {"prefix": "get_command_descriptions"}. This will return a dump of all commands the service knows about.

You can then use this information to construct your own JSON to send to the server. For example the prefix fs subvolumegroup ls takes an argument vol_name which is annotated as a CephString. Thus you can send the JSON {"prefix": "fs subvolumegroup ls", "vol_name": "foobar":, "format": "json"}. The last parameter format is a special general argument that suggests to the server that you want the reply data to be JSON formatted.

That all said, while you can directly interact with the command/JSON based APIs we are also very happy to consider feature requests as well as contributions to make working with these API more Go-idiomatic, convenient, and common.

Preview APIs

When a new API is added to go-ceph we consider the API to be a "preview" API. This means that while we think the API is good enough to distribute we do not promise not to change it. We assume that most consumers of go-ceph want a stable API and so the preview APIs are "hidden" behind a go build tag. This tag, ceph_preview, can be passed to the Go build command such that when you import go-ceph packages the preview APIs will become "visible" to your code. Do be aware that if you use preview APIs in your code there is the chance they'll change between go-ceph releases.

Preview APIs do not show up on pkg.go.dev but we do list all of them in our API status document. We track when each API was added and when the API is expected to become stable.

rados Package

Connecting to a cluster

Connect to a Ceph cluster using a configuration file located in the default search paths.

conn, _ := rados.NewConn()
conn.ReadDefaultConfigFile()
conn.Connect()

A connection can be shutdown by calling the Shutdown method on the connection object (e.g. conn.Shutdown()). There are also other methods for configuring the connection. Specific configuration options can be set:

conn.SetConfigOption("log_file", "/dev/null")

and command line options can also be used using the ParseCmdLineArgs method.

args := []string{ "--mon-host", "1.1.1.1" }
err := conn.ParseCmdLineArgs(args)

For other configuration options see the full documentation.

Object I/O

Object in RADOS can be written to and read from with through an interface very similar to a standard file I/O interface:

// open a pool handle
ioctx, err := conn.OpenIOContext("mypool")

// write some data
bytesIn := []byte("input data")
err = ioctx.Write("obj", bytesIn, 0)

// read the data back out
bytesOut := make([]byte, len(bytesIn))
_, err := ioctx.Read("obj", bytesOut, 0)

if !bytes.Equal(bytesIn, bytesOut) {
    fmt.Println("Output is not input!")
}

Pool maintenance

The list of pools in a cluster can be retrieved using the ListPools method on the connection object. On a new cluster the following code snippet:

pools, _ := conn.ListPools()
fmt.Println(pools)

will produce the output [data metadata rbd], along with any other pools that might exist in your cluster. Pools can also be created and destroyed. The following creates a new, empty pool with default settings.

conn.MakePool("new_pool")

Deleting a pool is also easy. Call DeletePool(name string) on a connection object to delete a pool with the given name. The following will delete the pool named new_pool and remove all of the pool's data.

conn.DeletePool("new_pool")

Error Handling

As typical of Go codebases, a large number of functions in go-ceph return errors. Some of these errors are based on non-exported types. This is deliberate choice. However, much of the relevant data these types can contain are available. One does not have to resort to the somewhat brittle approach of converting errors to strings and matching on (parts of) said string.

In some cases the errors returned by calls are considered "sentinel" errors. These errors can be matched to exported values in the package using the errors.Is function from the Go standard library.

Example:

// we want to delete a pool, but oops, conn is disconnected
err := conn.DeletePool("foo")
if err != nil {
    if errors.Is(err, rados.ErrNotConnected) {
        // ... do something specific when not connected ...
    } else {
        // ... handle generic error ...
    }
}

Example:

err := rgw.MyAPICall()
if err != nil {
    if errors.Is(err, rgw.ErrInvalidAccessKey) {
       // ... do something specific to access errors ...
    } else if errors.Is(err, rgw.ErrNoSuchUser) {
       // ... do something specific to user not existing ...
    } else {
       // ... handle generic error ...
    }
}

In other cases the returned error doesn't match a specific error value but rather is implemented by a type that may carry additional data. Specifically, many errors in go-ceph implement an ErrorCode() int method. If this is the case you can use ErrorCode to access a numeric error code provided by calls to Ceph. Note that the error codes returned by Ceph often match unix/linux errnos - but the exact meaning of the values returned by ErrorCode() are determined by the Ceph APIs and go-ceph is just making them accessible.

Example:

type errorWithCode interface {
    ErrorCode() int
}

err := rados.SomeRadosFunc()
if err != nil {
    var ec errorWithCode
    if errors.As(err, &ec) {
        errCode := ec.ErrorCode()
        // ... do something with errCode ...
    } else {
        // ... handle generic error ...
    }
}

Note that Go allows type definitions inline so you can even write:

err := rados.SomeRadosFunc()
if err != nil {
    var ec interface { ErrorCode() int }
    if errors.As(err, &ec) {
        errCode := ec.ErrorCode()
        // ... do something with errCode ...
    } else {
        // ... handle generic error ...
    }
}

Newer packages in go-ceph generally prefer to latter approach to avoid creating lots of sentinels that are only used rarely.