Revision: Wed, 27 Nov 2024 11:25:26 GMT
v3.12 – outdated
This version of the documentation is outdated. Consider upgrading your project to Spiral Framework 3.14
Edit this page

Cookbook — Custom Dispatcher

It is possible to invoke application kernel using a custom data source, for example, Kafka, state-machine events, or attach to user-defined interrupt. In this section, we will try to demonstrate how to write a RoadRunner service plugin and a kernel dispatcher to consume data from this service. It is a good starting point for anyone who is interested in building custom plugins for RoadRunner or using Spiral to build scalable and extensible web applications.

In this example, we will be sending "ticks" to the kernel every second.

Attention Make sure to read about an application server first. This article expects that you are proficient in writing Golang code.

RoadRunner Service plugin

One way to take advantage of RoadRunner's performance is to use its plugin system, which allows you to extend the functionality of the server and customize it to fit your needs.

In this tutorial, we'll show you how to create a simple RoadRunner plugin called "ticker", which will periodically send ticks to the PHP workers with defined interval. This can be useful for tasks such as sending periodic updates to clients or running scheduled tasks.

Prerequisites

Before we begin, you'll need to have the following installed on your machine:

  • Go
  • Velox- the official RoadRunner builder tool. It allows you to build custom RoadRunner binaries from github and gitlab repositories.

See more
Read more how to create a RoadRunner plugin here and how to build a binary with custom plugins here.

Plugin Configuration

Here is an example of how to configure the ticker plugin in .rr.yaml:

yaml
.rr.yaml
server:
  command: php app.php

ticker:
  interval: 1s
  pool:
    num_workers: 2

As you can see, our configuration allows us to define the interval between ticks in the format 1s, 1m, 10s, ... and configure the worker pool. The interval field specifies the amount of time to wait between ticks.

Let's create a configuration file config.go for our service:

go
config.go
package ticker

import (
	"time"
	"github.com/roadrunner-server/sdk/v3/pool"
)

type Config struct {
	Interval time.Duration `mapstructure:"interval"`
	Pool     *pool.Config  `mapstructure:"pool"`
}

func (c *Config) InitDefaults() {
	if c.Pool == nil {
		c.Pool = &pool.Config{}
	}

    // Init default pool settings
	c.Pool.InitDefaults()

	// use default interval 1s when inteval is not defined or defined with wrong value 
	if c.Interval == 0 {
		c.Interval = time.Second
	}
}

In the config.go file, we defined a struct called Config to store the plugin configuration. It has an Interval field for storing the tick interval and a Pool field for storing the worker pool configuration. The InitDefaults function sets default values for these fields if they are not specified in the .rr.yaml file. The default interval is set to 1 second, and the default worker pool configuration is set to the default values provided by the RoadRunner SDK.

Plugin Service

We have defined the configuration for our ticker plugin, let's move on to creating the plugin service.

The plugin service is responsible for managing the workers and sending the ticks to them. To create the service, create a new file called plugin.go and add the following code to it:

go
plugin.go
package ticker

import (
	"context"
	"fmt"
	"sync"
	"time"

	"github.com/roadrunner-server/errors"
	"github.com/roadrunner-server/sdk/v3/payload"
	"github.com/roadrunner-server/sdk/v3/pool"
	"github.com/roadrunner-server/sdk/v3/pool/static_pool"
	"github.com/roadrunner-server/sdk/v3/worker"
	"go.uber.org/zap"
)

type Configurer interface {
	// UnmarshalKey takes a single key and unmarshal it into a Struct.
	UnmarshalKey(name string, out any) error

	// Has checks if config section exists.
	Has(name string) bool
}

// Server creates workers for the application.
type Server interface {
	NewPool(ctx context.Context, cfg *pool.Config, env map[string]string, _ *zap.Logger) (*static_pool.Pool, error)
}

type Pool interface {
	// Workers returns worker list associated with the pool.
	Workers() (workers []*worker.Process)

	// Exec payload
	Exec(ctx context.Context, p *payload.Payload) (*payload.Payload, error)

	// Reset kill all workers inside the watcher and replaces with new
	Reset(ctx context.Context) error

	// Destroy all underlying stack (but let them to complete the task).
	Destroy(ctx context.Context)
}

const (
	rrMode     string = "RR_MODE"
	pluginName string = "ticker"
)

type Plugin struct {
	mu     sync.RWMutex
	cfg    *Config
	server Server
	stopCh chan struct{}
	pool   Pool
}

func (p *Plugin) Init(cfg Configurer, server Server) error {
	// If config file doesn't contain plugin section, ignore it
    if !cfg.Has(pluginName) {
		return errors.E(errors.Disabled)
	}

	// read plugin config
	err := cfg.UnmarshalKey(pluginName, &p.cfg)
	if err != nil {
		return err
	}

	p.cfg.InitDefaults()

	p.stopCh = make(chan struct{}, 1)
	p.server = server

	return nil
}

func (p *Plugin) Serve() chan error {
	errCh := make(chan error, 1)

	var err error
	p.mu.Lock()
    // Create workers pool
	p.pool, err = p.server.NewPool(context.Background(), p.cfg.Pool, map[string]string{rrMode: pluginName}, nil)
	p.mu.Unlock()

	if err != nil {
		errCh <- err
		return errCh
	}

	go func() {
		var numTicks = 0
		var lastTick time.Time
        // Be careful with ticker! You should always stop it
		ticker := time.NewTicker(p.cfg.Interval)
		defer ticker.Stop()

		for {
			select {
			case <-p.stopCh:
				return
			case <-ticker.C:
				p.mu.RLock()
				_, err2 := p.pool.Exec(context.Background(), &payload.Payload{
					Context: []byte(fmt.Sprintf(`{"lastTick": %v}`, lastTick.Unix())),
					Body:    []byte(fmt.Sprintf(`{"tick": %v}`, numTicks)),
				})
				p.mu.RUnlock()
				if err != nil {
					errCh <- err2
					return
				}

				numTicks++
				lastTick = time.Now()
			}
		}
	}()

	return errCh
}

func (p *Plugin) Reset() error {
	p.mu.RLock()
	defer p.mu.RUnlock()

	if p.pool == nil {
		return nil
	}

	ctx, cancel := context.WithTimeout(context.Background(), time.Second*10)
	defer cancel()
	err := p.pool.Reset(ctx)
	if err != nil {
		return err
	}

	return nil
}

func (p *Plugin) Stop() error {
	p.stopCh <- struct{}{}
	return nil
}

func (p *Plugin) Name() string {
	return pluginName
}

func (p *Plugin) Weight() uint {
	return 10
}

When RoadRunner starts PHP workers, it can pass a value for the RR_MODE variable to indicate which plugin should be used. Spiral can then use the value of this variable to choose the appropriate dispatcher for the current environment.

Build the RoadRunner Binary with Velox

Next, we will use Velox to build a custom RoadRunner binary with our plugin.

Create a new file called plugins.toml and add the following configuration:

toml
plugins.toml
[velox]
build_args = ['-trimpath', '-ldflags', '-s -X github.com/roadrunner-server/roadrunner/v2/internal/meta.version=v2.12.1.custom -X github.com/roadrunner-server/roadrunner/v2/internal/meta.buildTime=00:00:00']

[roadrunner]
ref = "v2.12.1"

[github]
[github.token]
token = "xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx"

# ref -> master, commit or tag
[github.plugins]
logger = { ref = "master", owner = "roadrunner-server", repository = "logger" }
server = { ref = "master", owner = "roadrunner-server", repository = "server" }
ticker = { ref = "main", owner = "roadrunner-php", repository = "rr-examples", folder = "ticker" }


[log]
level = "debug"
mode = "development"

Then, run the following command to build the RoadRunner binary:

vx build -c plugins.toml -o .

Application Dispatcher

At first, we need to install spiral/roadrunner-worker package:

composer require spiral/roadrunner-worker

Now we can create our dispatcher:

php
namespace App\Dispatcher;

use Psr\Container\ContainerInterface;
use Spiral\Boot\DispatcherInterface;
use Spiral\Boot\EnvironmentInterface;
use Spiral\Boot\FinalizerInterface;
use Spiral\RoadRunner\Worker;

final class TickerDispatcher implements DispatcherInterface
{
    public function __construct(
        private readonly EnvironmentInterface $env,
        private readonly FinalizerInterface $finalizer,
        private readonly ContainerInterface $container
    ) {
    }

    public function canServe(): bool
    {
        return $this->env->get('RR_MODE') === 'ticker';
    }

    public function serve(): void
    {
        /** @var Worker $worker */
        $worker = $this->container->get(Worker::class);

        while ($payload = $worker->waitPayload()) {
            $data = \json_decode($payload->body, true);
            
            // Handle tick ... 
        
            // Respond Answer
            $worker->respond(new \Spiral\RoadRunner\Payload('OK'));

            // reset some stateful services
            $this->finalizer->finalize();
        }
    }
}

See more
Read more about the dispatchers in the Framework — Dispatchers section.

Create a Bootloader to register our dispatcher in the kernel:

php
app/src/Application/Bootloader/TickerBootloader.php
namespace App\Application\Bootloader;

use App\Dispatcher\TickerDispatcher;
use Spiral\Boot\Bootloader\Bootloader;
use Spiral\Boot\KernelInterface;

final class TickerBootloader extends Bootloader
{
    public function boot(KernelInterface $kernel, TickerDispatcher $ticker): void
    {
        $kernel->addDispatcher($ticker);
    }
}

Now we can run our application:

./rr serve

Note:
You can find code of ticker plugin here