consul/internal/controller/controller.go

325 lines
9.8 KiB
Go

// Copyright (c) HashiCorp, Inc.
// SPDX-License-Identifier: BUSL-1.1
package controller
import (
"context"
"fmt"
"strings"
"time"
"github.com/hashicorp/consul/internal/controller/cache"
"github.com/hashicorp/consul/internal/controller/cache/index"
"github.com/hashicorp/consul/internal/resource"
"github.com/hashicorp/consul/proto-public/pbresource"
"github.com/hashicorp/go-hclog"
)
// DependencyMapper is called when a dependency watched via WithWatch is changed
// to determine which of the controller's managed resources need to be reconciled.
type DependencyMapper func(
ctx context.Context,
rt Runtime,
res *pbresource.Resource,
) ([]Request, error)
// Controller runs a reconciliation loop to respond to changes in resources and
// their dependencies. It is heavily inspired by Kubernetes' controller pattern:
// https://kubernetes.io/docs/concepts/architecture/controller/
//
// Use the builder methods in this package (starting with NewController) to construct
// a controller, and then pass it to a Manager to be executed.
type Controller struct {
name string
reconciler Reconciler
initializer Initializer
managedTypeWatch *watch
watches map[string]*watch
queries map[string]cache.Query
customWatches []customWatch
placement Placement
baseBackoff time.Duration
maxBackoff time.Duration
logger hclog.Logger
startCb RuntimeCallback
stopCb RuntimeCallback
}
type RuntimeCallback func(context.Context, Runtime)
// NewController creates a controller that is setup to watched the managed type.
// Extra cache indexes may be provided as well and these indexes will be automatically managed.
// Typically, further calls to other builder methods will be needed to fully configure
// the controller such as using WithReconcile to define the the code that will be called
// when the managed resource needs reconcilation.
func NewController(name string, managedType *pbresource.Type, indexes ...*index.Index) *Controller {
w := &watch{
watchedType: managedType,
indexes: make(map[string]*index.Index),
}
for _, idx := range indexes {
w.addIndex(idx)
}
return &Controller{
name: name,
managedTypeWatch: w,
watches: make(map[string]*watch),
queries: make(map[string]cache.Query),
}
}
// WithNotifyStart registers a callback to be run when the controller is being started.
// This happens prior to watches being started and with a fresh cache.
func (ctl *Controller) WithNotifyStart(start RuntimeCallback) *Controller {
ctl.startCb = start
return ctl
}
// WithNotifyStop registers a callback to be run when the controller has been stopped.
// This happens after all the watches and mapper/reconcile queues have been stopped. The
// cache will contain everything that was present when we started stopping watches.
func (ctl *Controller) WithNotifyStop(stop RuntimeCallback) *Controller {
ctl.stopCb = stop
return ctl
}
// WithReconciler changes the controller's reconciler.
func (ctl *Controller) WithReconciler(reconciler Reconciler) *Controller {
if reconciler == nil {
panic("reconciler must not be nil")
}
ctl.reconciler = reconciler
return ctl
}
// WithWatch enables watching of the specified resource type and mapping it to the managed type
// via the provided DependencyMapper. Extra cache indexes to calculate on the watched type
// may also be provided.
func (ctl *Controller) WithWatch(watchedType *pbresource.Type, mapper DependencyMapper, indexes ...*index.Index) *Controller {
key := resource.ToGVK(watchedType)
_, alreadyWatched := ctl.watches[key]
if alreadyWatched {
panic(fmt.Sprintf("resource type %q already has a configured watch", key))
}
w := newWatch(watchedType, mapper)
for _, idx := range indexes {
w.addIndex(idx)
}
ctl.watches[key] = w
return ctl
}
// WithQuery will add a named query to the controllers cache for usage during reconcile or in dependency mappers
func (ctl *Controller) WithQuery(queryName string, fn cache.Query) *Controller {
_, duplicate := ctl.queries[queryName]
if duplicate {
panic(fmt.Sprintf("a predefined cache query with name %q already exists", queryName))
}
ctl.queries[queryName] = fn
return ctl
}
// WithCustomWatch adds a new custom watch. Custom watches do not affect the controller cache.
func (ctl *Controller) WithCustomWatch(source *Source, mapper CustomDependencyMapper) *Controller {
if source == nil {
panic("source must not be nil")
}
if mapper == nil {
panic("mapper must not be nil")
}
ctl.customWatches = append(ctl.customWatches, customWatch{source, mapper})
return ctl
}
// WithLogger changes the controller's logger.
func (ctl *Controller) WithLogger(logger hclog.Logger) *Controller {
if logger == nil {
panic("logger must not be nil")
}
ctl.logger = logger
return ctl
}
// WithBackoff changes the base and maximum backoff values for the controller's
// retry rate limiter.
func (ctl *Controller) WithBackoff(base, max time.Duration) *Controller {
ctl.baseBackoff = base
ctl.maxBackoff = max
return ctl
}
// WithPlacement changes where and how many replicas of the controller will run.
// In the majority of cases, the default placement (one leader elected instance
// per cluster) is the most appropriate and you shouldn't need to override it.
func (ctl *Controller) WithPlacement(placement Placement) *Controller {
ctl.placement = placement
return ctl
}
// buildCache will construct a controller Cache given the watches/indexes that have
// been added to the controller. This is mainly to be used by the TestController and
// Manager when setting up how things
func (ctl *Controller) buildCache() cache.Cache {
c := cache.New()
addWatchToCache(c, ctl.managedTypeWatch)
for _, w := range ctl.watches {
addWatchToCache(c, w)
}
for name, query := range ctl.queries {
if err := c.AddQuery(name, query); err != nil {
panic(err)
}
}
return c
}
// String returns a textual description of the controller, useful for debugging.
func (ctl *Controller) String() string {
watchedTypes := make([]string, 0, len(ctl.watches))
for watchedType := range ctl.watches {
watchedTypes = append(watchedTypes, watchedType)
}
base, max := ctl.backoff()
return fmt.Sprintf(
"<Controller managed_type=%s, watched_types=[%s], backoff=<base=%s, max=%s>, placement=%s>",
resource.ToGVK(ctl.managedTypeWatch.watchedType),
strings.Join(watchedTypes, ", "),
base, max,
ctl.placement,
)
}
func (ctl *Controller) backoff() (time.Duration, time.Duration) {
base := ctl.baseBackoff
if base == 0 {
base = 5 * time.Millisecond
}
max := ctl.maxBackoff
if max == 0 {
max = 1000 * time.Second
}
return base, max
}
func (ctl *Controller) buildLogger(defaultLogger hclog.Logger) hclog.Logger {
logger := defaultLogger
if ctl.logger != nil {
logger = ctl.logger
}
return logger.With("controller", ctl.name, "managed_type", resource.ToGVK(ctl.managedTypeWatch.watchedType))
}
func addWatchToCache(c cache.Cache, w *watch) {
c.AddType(w.watchedType)
for _, index := range w.indexes {
if err := c.AddIndex(w.watchedType, index); err != nil {
panic(err)
}
}
}
// Placement determines where and how many replicas of the controller will run.
type Placement int
const (
// PlacementSingleton ensures there is a single, leader-elected, instance of
// the controller running in the cluster at any time. It's the default and is
// suitable for most use-cases.
PlacementSingleton Placement = iota
// PlacementEachServer ensures there is a replica of the controller running on
// each server in the cluster. It is useful for cases where the controller is
// responsible for applying some configuration resource to the server whenever
// it changes (e.g. rate-limit configuration). Generally, controllers in this
// placement mode should not modify resources.
PlacementEachServer
)
// String satisfies the fmt.Stringer interface.
func (p Placement) String() string {
switch p {
case PlacementSingleton:
return "singleton"
case PlacementEachServer:
return "each-server"
}
panic(fmt.Sprintf("unknown placement %d", p))
}
// Reconciler implements the business logic of a controller.
type Reconciler interface {
// Reconcile the resource identified by req.ID.
Reconcile(ctx context.Context, rt Runtime, req Request) error
}
// RequeueAfterError is an error that allows a Reconciler to override the
// exponential backoff behavior of the Controller, rather than applying
// the backoff algorithm, returning a RequeueAfterError will cause the
// Controller to reschedule the Request at a given time in the future.
type RequeueAfterError time.Duration
// Error implements the error interface.
func (r RequeueAfterError) Error() string {
return fmt.Sprintf("requeue at %s", time.Duration(r))
}
// RequeueAfter constructs a RequeueAfterError with the given duration
// setting.
func RequeueAfter(after time.Duration) error {
return RequeueAfterError(after)
}
// RequeueNow constructs a RequeueAfterError that reschedules the Request
// immediately.
func RequeueNow() error {
return RequeueAfterError(0)
}
// Request represents a request to reconcile the resource with the given ID.
type Request struct {
// ID of the resource that needs to be reconciled.
ID *pbresource.ID
}
// Key satisfies the queue.ItemType interface. It returns a string which will be
// used to de-duplicate requests in the queue.
func (r Request) Key() string {
return fmt.Sprintf(
"part=%q,peer=%q,ns=%q,name=%q,uid=%q",
r.ID.Tenancy.Partition,
r.ID.Tenancy.PeerName,
r.ID.Tenancy.Namespace,
r.ID.Name,
r.ID.Uid,
)
}
// Initializer implements the business logic that is executed when the
// controller is first started.
type Initializer interface {
Initialize(ctx context.Context, rt Runtime) error
}
// WithInitializer changes the controller's initializer.
func (c *Controller) WithInitializer(initializer Initializer) *Controller {
c.initializer = initializer
return c
}