This repo contains the low level API server framework used to create REST APIs consumed by Rancher projects such as github.com/rancher/ui and github.com/rancher/dashboard. The primary consumer of this framework is github.com/rancher/steve.
The API server is the interface between an HTTP client and a more complex application like rancher/steve. The two main components that are used to accomplish that are Schemas and Stores.
Schemas define metadata about an API type, describe CRUD handlers for the type, define formatting transformations, and declare the Store that will be used to transform and store the object.
Stores provide a common interface to perform CRUD operations on objects. The implementation of the interface commonly involves either storing the data as a field on the store object, forwarding it to another nested store, or calling out to an external resource like Kubernetes.
There are a few main types to be aware of.
APISchema adds additional functionality on top of wrangler's Schema type. In addition to metadata about the type of object it represents, it also defines CRUD handlers, formatting transformations, and the backing Store.
Store is an
interface for interacting with APIObject
s, APIObjectList
s, and APIEvent
s.
APIRequest
is a parsed version of an http.Request
that provides a standardized way of
interacting with a request. The default parser makes a set of assumptions about
how the request is formatted and routed so that it can populate fields such as
Name
, Namespace
, Type
, or Query
, among others. On top of the data found
in the request, APIRequest
stores additional context that can be passed to
any function that needs to handle the request, such as the server's full set of
schemas, an access control interface, a response writer and error handler.
APIObject is a wrapper around an underlying object. The struct provides the object's type and ID along with the unmodified object itself. If the underlying API object is a Kubernetes resource, the ID is the object's name and namespace for namespaced objects, or just its name for global objects. The type is the resource name and API group. It also includes any warnings that may have been emitted while processing the object.
APIObjectList is returned for list requests. It includes the slice of objects returned as well as chunking and pagination metadata if the list is not complete.
APIEvent is emitted on a channel created for a watch request. It is a wrapper for a Kubernetes event.
The API server starts with an HTTP server:
import "github.com/caas-team/apiserver/pkg/server"
s := server.DefaultAPIServer()
Add schemas by defining a Go struct and importing an empty instance of it on to the base schema list:
type Duck struct{
Name string `json:"name"`
}
s.Schemas.MustImportAndCustomize(Duck{}, nil)
If the API for this type needs to keep any state, a Store needs to be defined in the customize function:
import (
"github.com/caas-team/apiserver/pkg/types"
"github.com/caas-team/apiserver/pkg/store/empty"
)
type DuckStore struct {
ducks map[string]Duck
}
func (d *DuckStore) ByID(apiOp *types.APIRequest, schema *types.APISchema, id string) (types.APIObject, error) {
return types.APIObject{
Type: "ducks",
ID: id,
Object: ducks[id],
}, nil
}
// implement the rest of the Store interface
s.Schemas.MustImportAndCustomize(Duck{}, func(schema *types.APISchema) {
schema.Store = &DuckStore{}
}
To make this an HTTP-accessible API, define allowed HTTP methods for a single resource or for a collection:
s.Schemas.MustImportAndCustomize(Duck{}, func(schema *types.APISchema) {
schema.Store = &DuckStore{}
schema.ResourceMethods: []string{"GET"},
schema.CollectionMethods: []string{"GET"},
}
If HTTP methods are not defined on a schema, that schema can still be used in a response, it just can't be queried or manipulated by a client. The error and collection built-in schemas are examples of this kind of internal schema.
MustImportAndCustomize
is a convenience wrapper around MustAddSchema
, which
could also be used directly if desired:
import "github.com/rancher/wrangler/pkg/schemas"
s.Schemas.MustAddSchema(types.APISchema{
Schema: &schemas.Schema{
ID: "duck",
ResourceFields: map[string]schemas.Field{
"name": {Type: "string"},
},
},
Store: &DuckStore{},
})
Routes need to be defined in order for requests to be routed to the correct
schema. The parser assumes that some or all of these variables may be defined
in the as part of a gorilla/mux
router: "type", "name", "namespace", "link", "prefix", "action". It uses these
assumptions to decode the http.Request
into an APIRequest
. For example,
for a route like:
import "github.com/gorilla/mux"
router := mux.NewRouter()
router.Handle("/{prefix}/{type}/{namespace}/{name}", s)
then a request like
GET /pond/duck/mallard/bob
would generate an APIRequest like
APIRequest{
Type: "duck",
Prefix: "pond",
Namespace: "mallard",
Name: "bob",
Method: "GET",
}
and route the request to the "duck" registered schema.
An example server can be found in example.go and run on port 8080 with
go run example.go
API server provides a set of built-in and convenience schemas:
Provides read-only access to any schema definition.
Defines the format for an error response.
Defines the format for a list of objects.
Not built in to the default schemas, but can be added with:
import "github.com/caas-team/apiserver/pkg/store/apiroot"
apiroot.Register(s.Schemas, []string{"v1"})
This adds one or more "roots" relative to which schemas are defined, to allow for more than one schema version to coexist.
Also not built in, but can be added with
import "github.com/caas-team/apiserver/pkg/subscribe"
subscribe.Register(s.Schemas, nil, "")
The Subscribe
schema provides special handling for listening for events on a
channel and passing them through a websocket.
A useful tool for connecting to a websocket without a browser is websocat.
A subscription stream is started by making a websocket request for the
subscribe
type, which is routed to the
Subscribe
schema. It uses a custom handler to upgrade the connection to a websocket
connection.
The event stream is started when the client requests a resource type over the websocket connection. The message from the client consists of the resource type and optional filtering parameters. For example:
{"resourceType": "apps.deployments", "namespace": "default", "resourceVersion": "1000"}
will start watching events for the "apps.deployments" collection in namespace
"default" starting with the collection resource version "1000" (see the
Kubernetes documentation
for a detailed discussion of resource version semantics). Under the hood, the
API server calls the Watch
method for the schema's store for the resource
type.
The watch could be started for an individual resource by specifying the "id" field, for a set of labeled resources by using the "selector" field, or for all resources by omitting the "namespace" field.
To stop a watch deliberately, issue a "stop" message:
{"stop": true, "resourceType": "apps.deployments"}
Otherwise, the connection will time out after 30 minutes, and will terminate with a message with name "resource.stop". The client is responsible for restarting the connection.
If an error is encounted, a message with name "resource.error" will be sent with error details in the message.
Access control is defined on the server. By default, access control is based on
the defined ResourceMethods
and CollectionMethods
on the Schema
, and the
access is the same for every request. More complex access control, using RBAC,
for instance, can be defined by overriding the SchemaBasedAccess
struct:
import (
"k8s.io/apiserver/pkg/endpoints/request"
"github.com/caas-team/apiserver/pkg/apierror"
"github.com/caas-team/apiserver/pkg/server"
"github.com/caas-team/apiserver/pkg/types"
)
type accessControl struct{
server.SchemaBasedAccess
}
func (a *accessControl) CanList(apiOp *types.APIRequest, schema *types.APISchema) error {
user, ok := request.UserFrom(apiOp.Context())
if ok && user.GetName() == "george" {
return apierror.NewAPIError(validation.PermissionDenied, "no Georges allowed")
}
return nil
}
s.AccessControl = &accessControl{}