aternos / taskmaster
Object-oriented PHP library for running tasks in parallel
Installs: 80 735
Dependents: 2
Suggesters: 0
Security: 0
Stars: 4
Watchers: 2
Forks: 2
Open Issues: 0
Requires
- php: >=8.1
Requires (Dev)
- phpbench/phpbench: ^1.2
- phpunit/phpunit: ^10.4
Suggests
- ext-parallel: Required for thread workers
- ext-pcntl: Required for fork workers
README
Taskmaster is an object-oriented PHP library for running tasks in parallel.
A task can be written in a few lines of code and then executed in different environments, e.g. in a forked process, a new process, a thread or just synchronous in the same process without changing any code.
Therefore, this library can run without any extensions that aren't part of the PHP core, but it's also
possible to use the advantages of advanced extensions such as pcntl
or parallel
if they are available.
It's even possible to proxy the creation of the environment through a proxy process that uses a different PHP binary/installation with different extensions. This allows using the advantages of the different strategies even in environments where this would not be possible otherwise, e.g. using forked processes on a webserver.
Tasks can communicate back to the main process during execution and handle results and errors gracefully.
This library is not supported on Windows due to a lack of essential features. The autodetect falls back to the sync worker on Windows, so running tasks should be possible, but running tasks in parallel does not work.
- Installation
- Basic Example
- Writing tasks
- Creating tasks
- Defining workers
- Running tasks
- Task/worker groups
Installation
composer require aternos/taskmaster
To use the ForkWorker
you have to install
the pcntl
extension.
For the ThreadWorker
the parallel
extension is required.
Basic Example
// Every task is its own class, the class should be autoloaded class SleepTask extends \Aternos\Taskmaster\Task\Task { // The run method is called when the task is executed public function run(): void { sleep(1); } } // The taskmaster object holds tasks and workers $taskmaster = new \Aternos\Taskmaster\Taskmaster(); // Set up the workers automatically $taskmaster->autoDetectWorkers(4); // Add tasks to the taskmaster for ($i = 0; $i < 8; $i++) { $taskmaster->runTask(new SleepTask()); } // Wait for all tasks to finish and stop the taskmaster $taskmaster->wait()->stop();
Writing tasks
A task is an instance of a class. When writing your own task class, it is recommended to extend the Task
class,
but implementing the TaskInterface
is also possible.
A class must define a run function and has some optional functions such as error handlers.
Tasks are serialized and therefore must not contain any unserializable fields such as closures or resources. They can define those fields when the task is executed in the run function.
The run()
function
The run function is called when the task is executed. It's the only required function for
a task. It can return a value that is passed back to the main process and can be handled by
defining a Task::handleResult(mixed $result)
function in your task.
In all current workers, the input/output streams are connected to the main process, so
you can use echo
and STDERR
to output something in your run()
function at any time.
Call back to the main process
A task (usually) runs in a different process than the main process. The result and errors are communicated back to the main process, but it's also possible to call back to the main process during execution.
The Task
class provides the Task::call()
and Task::callAsync()
functions to call
a function in the main process. The Task::call()
function blocks until the function is executed and the
result is returned. The Task::callAsync()
function returns a Promise
that resolves when the function is executed and the result is returned. While it is theoretically possible
to send multiple requests to the main process at the same time, the main process still has to process them
synchronously and therefore the async calls have no benefit. It's only recommended to use the async calls
if you want to do something else in the task while waiting for the result.
The first parameter of the Task::call()
and Task::callAsync()
functions is a Closure
of the function
that you want to call in the main process. The function has to be a public function of your task class. The second
and following parameters are the parameters that are passed to the function in the main process as first
and following arguments. The arguments have to be serializable.
Example:
class CallbackTask extends \Aternos\Taskmaster\Task\Task { static protected int $current = 0; #[OnParent] public function getCurrent(): int { return static::$current++; } #[OnChild] public function run(): void { $current = $this->call($this->getCurrent(...)); echo "I am task number $current\n"; } }
Child/parent attributes
As seen in the example above, it's possible to define functions that are executed in the main
process OnParent
,
in the child process OnChild
or in both OnBoth
using
attributes.
These attributes are optional (default is OnBoth
) and for methods mostly used as a
documentation for the developer to clearly show which methods are executed where. The only implemented
restriction for methods is that functions marked with the OnChild
attribute must not be called using the Task::call()
or Task::callAsync()
functions.
The attributes can also be used on properties:
Synchronized properties
Besides the usage for methods mentioned above, the attributes can also be used on properties to define where task properties are used and synchronized.
Properties marked with the OnParent
attribute are only available in the main process
and not serialized when running the task. They can contain unserializable values such as closures or resources.
Properties marked with the OnChild
attribute are initially serialized and sent to the
child process, so they can be set initially on the parent. After that, they are only available in the child
process and never synchronized back to the parent. So the child process in the Task::run()
function can
set the values of those properties to something unserializable.
Properties marked with the OnBoth
or no attribute are initially serialized and sent to the
child process. They are synchronized back to the parent when Task::callAsync()
or Task::call()
is
used to call a function in the main process. They are also synchronized back to the parent when the task
is finished or (safely) errors with an exception. The synchronisation ONLY happens on those events, changes
to the property are not immediately synchronized. The properties marked with this attribute have to be always
serializable.
Example:
class SynchronizedFieldTask extends \Aternos\Taskmaster\Task\Task { #[OnBoth] protected int $counter = 0; #[OnBoth] public function increaseCounter(): void { $this->counter++; } #[OnChild] public function run(): null { for ($i = 0; $i < 3; $i++) { $this->increaseCounter(); $this->call($this->increaseCounter(...)); } return $this->counter; } }
The result of this task is 6
because the counter
property is synchronized and increased on both sides.
Serialization in other classes
The OnParent
, OnChild
and OnBoth
attributes are only available in your Task
class. If other objects are serialized but
contain properties that should not be serialized, you can use the
SerializationTrait
in your class
and then add the Serializable
or NotSerializable
attributes to your properties.
You can use the Serializable
attribute to mark properties that should be serialized.
When using only the Serializable
attribute, all properties that are not marked with the
Serializable
attribute will be ignored.
You can use the NotSerializable
attribute to mark properties that should not be serialized.
When using only the NotSerializable
attribute, all properties that are not marked with the
NotSerializable
attribute will be serialized.
When using both attributes, all properties must be marked with either the Serializable
or NotSerializable
attribute, otherwise an exception will be thrown.
Synchronous environment
In some cases special handling is required when the task is executed in a synchronous environment
using the SyncWorker
, e.g. you might not want to close
file handles that are still used by other tasks. The Task::isSync()
function can
be used to check if the task is being executed synchronously.
Handling the result
The Task::handleResult()
function is called when the task returns a value. It can be used to handle
the result of the task. You can override this function to implement your own result handler.
It is not required to define this function.
The first parameter is the result of the task or null
if the task did not return a value.
The default implementation in the Task
class just stores the result in
the task object for later access using the Task::getResult()
function. If you override this
function, you should call the parent function to store the result or store the result yourself.
You can also use the TaskPromise
returned from the
Taskmaster::runTask()
function or obtainable from the task object using the Task::getPromise()
function
to handle the result. The TaskPromise
is resolved with the return value of the Task::run()
function.
You can use the TaskPromise::then()
function to handle the result. The first argument is the result,
the second argument is the task object.
Example:
$taskmaster->runTask(new SleepTask())->then(function(mixed $result, TaskInterface $task) { echo "The task returned " . $result . PHP_EOL; });
Timeout
You can define a timeout for a task using the Task::setTimeout(?float $timeout)
function or by
overriding the Task::getTimeout()
function. 0
means no timeout, null
means the default timeout
is set by the taskmaster defined by Taskmaster::setDefaultTaskTimeout(float $timeout)
. The timeout
is set in seconds and can be a float value down to microseconds.
If the task takes longer than the timeout, a TaskTimeoutException
is thrown.
Timeouts are only used in asynchronous workers, with a SyncWorker
the task is executed synchronously and therefore the timeout is not used.
Timeouts are not exact, they are evaluated in every update interval of the taskmaster. Therefore, the task can take a little longer than the timeout.
Handling errors
Critical errors
The Task::handleError()
function is called when the task caused a fatal unrecoverable error. The first
parameter is an Exception
that is thrown by the task or by this library. You can override this function
to implement your own error handler.
The three exception thrown by this library are the PhpFatalErrorException
cause by a fatal PHP error, the WorkerFailedException
that is thrown
when the worker process exited unexpectedly and the TaskTimeoutException
that is thrown when the task takes longer than the timeout.
PHP fatal errors can only be caught if they were caused in a separate process, e.g. when using
the ForkWorker
or the ProcessWorker
.
It's not recommended to rely on this.
If a worker fails and the task gets a WorkerFailedException
,
it is possible that this was not caused by the task itself and therefore a retry of the task might be possible.
This should be limited to a few retries to prevent endless loops.
The TaskTimeoutException
is thrown when the task takes longer than the timeout defined
by Task::getTimeout()
or the default defined by Taskmaster::setDefaultTaskTimeout()
.
The default error handler implementation in the Task
class stores the error in
the task object for later access using the Task::getError()
function and writes the error message to STDERR
.
When overriding this function, you should call the parent function to store the error or store the error yourself.
You can also use the TaskPromise
returned from the
Taskmaster::runTask()
function or obtainable from the task object using the Task::getPromise()
function
to handle the error. The TaskPromise
is rejected with the error. You can use the TaskPromise::catch()
function
to handle the error. The first argument is the error, the second argument is the task object.
Example:
$taskmaster->runTask(new SleepTask())->catch(function(Exception $error, TaskInterface $task) { echo "The task failed: " . $error->getMessage() . PHP_EOL; });
Uncritical errors
The Task::handleUncriticalError()
function is called when the task caused an uncritical error, e.g. a PHP warning.
You can override this function to implement your own error handler.
The first parameter is a PhpError
object that contains the error
details. The function should return true
if the error was handled or false
(default) if the PHP error
handler should continue (usually by logging/outputting the error).
The handleUncriticalError
function is called in the same process as the task itself.
When executing tasks synchronously using the SyncWorker
, no PHP
error handler is defined to avoid conflicts with other error handler of the main process. Therefore, the
handleUncriticalError
function is not called in this case.
Creating tasks
A task object can simply be created by instancing the task class:
$task = new SleepTask();
And then added to the taskmaster:
$taskmaster->runTask($task);
You can add all your tasks at the beginning:
for ($i = 0; $i < 100; $i++) { $taskmaster->runTask(new SleepTask()); }
or wait for the taskmaster to finish some tasks and then add more to avoid holding all tasks in memory:
for ($i = 0; $i < 10; $i++) { for ($j = 0; $j < 10; $j++) { $taskmaster->runTask(new SleepTask()); } $taskmaster->waitUntilAllTasksAreAssigned(); }
Task factory
The best way to dynamically create tasks when necessary is by creating a task factory, by extending the
TaskFactory
class or implementing
the TaskFactoryInterface
.
// Your own task factory extending the TaskFactory class class SleepTaskFactory extends \Aternos\Taskmaster\Task\TaskFactory { protected int $count = 0; public function createNextTask(?string $group): ?\Aternos\Taskmaster\Task\TaskInterface { if ($this->count++ < 100) { return new SleepTask(); } // Stop creating tasks after 100 tasks return null; } } $taskmaster->addTaskFactory(new SleepTaskFactory());
You could use the promise returned from Task::getPromise()
to also handle success and
failure of tasks in your task factory as well.
You can also use the existing IteratorTaskFactory
that creates tasks from an
iterator.
// Create an iterator that iterates over all files in the current directory $iterator = new \RecursiveIteratorIterator(new \RecursiveDirectoryIterator(".")); // Create the task factory using the iterator and a task class that gets the iterator value as constructor argument // Note, that the SplFileInfo object that you get from a DirectoryIterator is not serializable and therefore cannot be // stored in a task property, but you can use any other values, e.g. the file path $factory = new \Aternos\Taskmaster\Task\IteratorTaskFactory($iterator, FileTask::class); $taskmaster->addTaskFactory($factory);
You can add multiple task factories to a taskmaster. The taskmaster will use the factories in the order they were
added. If a factory returns null
, the next factory is used.
Defining workers
A worker executes tasks. There are different workers available that execute tasks in different environments.
Available workers
Currently, the following workers are available:
You can also write your own worker by extending the existing workers or implementing
the WorkerInterface
.
Creating workers
A worker object can simply be created by instancing the worker class:
$worker = new \Aternos\Taskmaster\Environment\Sync\SyncWorker();
You can define custom options for the worker by creating a TaskmasterOptions
object and passing it to the worker. If the options are not set, the default options from your Taskmaster
instance are used.
$options = new \Aternos\Taskmaster\TaskmasterOptions(); $options->setBootstrap(__DIR__ . '/vendor/autoload.php'); $options->setPhpExecutable('/usr/bin/php'); $worker = new \Aternos\Taskmaster\Environment\Process\ProcessWorker(); $worker->setOptions($options);
Currently only the bootstrap file and the PHP executable can be set as options. Those options are only
relevant for some workers, especially the ProcessWorker
.
Proxy workers
It's possible to proxy the creation of the worker through a proxy process that uses a different PHP binary or
environment, e.g. you can use a PHP CLI proxy process in a webserver environment to use
the ForkWorker
.
One proxy can be used for multiple workers.
Currently, the only available proxy is the ProcessProxy
that uses a new process opened
using proc_open()
to run the worker.
To use a proxy, create a new proxy object and pass it to the worker:
$proxy = new \Aternos\Taskmaster\Proxy\ProcessProxy(); $worker = new \Aternos\Taskmaster\Environment\Fork\ForkWorker(); $worker->setProxy($proxy);
You can also define TaskmasterOptions
for the proxy process.
If the options are not set, the default options from your Taskmaster
instance are used.
$options = new \Aternos\Taskmaster\TaskmasterOptions(); $options->setBootstrap(__DIR__ . '/vendor/autoload.php'); $options->setPhpExecutable('/usr/bin/php'); $proxy = new \Aternos\Taskmaster\Proxy\ProcessProxy(); $proxy->setOptions($options);
Defining workers manually
Before running any tasks, you have to define the workers that should be used.
// Add a single worker $taskmaster->addWorker(new \Aternos\Taskmaster\Environment\Sync\SyncWorker()); // Add a worker multiple times $taskmaster->addWorkers(new \Aternos\Taskmaster\Environment\Process\ProcessWorker(), 4); // Add multiple workers with the same proxy $worker = new \Aternos\Taskmaster\Environment\Fork\ForkWorker(); $worker->setProxy(new \Aternos\Taskmaster\Proxy\ProcessProxy()); $taskmaster->addWorkers($worker, 8); // Define/replace all workers at once $taskmaster->setWorkers([ new \Aternos\Taskmaster\Environment\Fork\ForkWorker(), new \Aternos\Taskmaster\Environment\Fork\ForkWorker(), new \Aternos\Taskmaster\Environment\Fork\ForkWorker(), ]);
Defining workers automatically
It's possible to detect the available workers and set them up automatically:
// create 4 automatically detected workers $taskmaster->autoDetectWorkers(4);
This will use the ForkWorker
if the pcntl
extension is available,
or the ProcessWorker
if the proc_open()
function is available
and fall back to the SyncWorker
otherwise.
The autoDetectWorkers()
function also supports loading the worker configuration from environment variables.
Defining workers using environment variables
When the autoDetectWorkers()
function is called, it also checks the following environment variables
to create the worker configuration:
When using the autoDetectWorkers()
function, it's possible to disable loading the worker configuration from
environment variables
by setting the second argument to false
or to just disable loading the worker count by setting the third argument
to false
.
// Load count and workers from environment variables $taskmaster->autoDetectWorkers(4); // Load nothing from environment variables $taskmaster->autoDetectWorkers(4, false); // Load worker types from environment variables, but keep the worker count $taskmaster->autoDetectWorkers(4, true, false);
Init tasks
You can define tasks that are executed on every worker instance before the first task is executed.
This is helpful to run some initial setup or (in case of the ForkWorker
)
to clear some variables that are inherited from the parent process, e.g. database connections.
// init tasks are always provided by a task factory $taskmaster->setDefaultInitTaskFactory(new InitTaskFactory()); // but taskmaster can create task factories automatically by cloning or instancing a task $taskmaster->setDefaultInitTask(new InitTask()); $taskmaster->setDefaultInitTask(InitTask::class); // you can also define a task factory for a specific worker $worker->setInitTaskFactory(new InitTaskFactory());
Running tasks
After writing your tasks, creating them and defining the workers, you can start running the tasks. You don't have to explicitly start the taskmaster, just running the update loop through the wait functions or manually is enough. Workers and proxies are started when necessary.
Configuring the taskmaster
Besides configuring workers and proxies directly, you can also configure the default TaskmasterOptions
on the taskmaster object. Those options are used for all workers and proxies that don't have their own options.
Bootstrap file
The bootstrap file is used to autoload classes in the worker process. This isn't used by every
worker, e.g. the SyncWorker
and the ForkWorker
don't need this, but the ProcessWorker
does.
$taskmaster->setBootstrap(__DIR__ . '/vendor/autoload.php');
If this is not set, Taskmaster tries to find the composer autoloader automatically.
PHP executable
The PHP executable is used to run the worker process. This is currently only used by the
ProcessWorker
and the ProcessProxy
.
$taskmaster->setPhpExecutable('/usr/bin/php');
The default value for the PHP executable is simply php
.
Waiting for tasks to finish
You can simply wait for all tasks to finish using the Taskmaster::wait()
function:
$taskmaster->wait();
This function blocks until all tasks are finished and then stops the taskmaster.
If you might want to add further tasks, you can also use the Taskmaster::waitUntilAllTasksAreAssigned()
function
to wait until all tasks are assigned to a worker and then add more tasks.
$taskmaster->waitUntilAllTasksAreAssigned();
This doesn't wait for all tasks to finish, but when all tasks are assigned to a worker, it's the best time to add more tasks to avoid any workers being idle.
You should still wait for all tasks to finish using Taskmaster::wait()
before stopping the taskmaster.
Waiting and handling tasks
You can also use the Taskmaster::waitAndHandleTasks()
function to handle tasks when they
finish instead of waiting for all tasks to finish.
foreach ($taskmaster->waitAndHandleTasks() as $task) { if ($task->getError()) { echo "Task failed: " . $task->getError()->getMessage() . PHP_EOL; } else { echo "Task finished: " . $task->getResult() . PHP_EOL; } }
The Taskmaster::waitAndHandleTasks()
function returns a generator that yields tasks when they finish.
You have to iterate over the generator to handle the tasks or the taskmaster will not continue to run.
Running the update loop manually
You can also run the update loop manually and do something else between the updates.
The Taskmaster::update()
function returns an array of all tasks that finished since the last update.
do { $finishedTasks = $taskmaster->update(); // do something else } while ($taskmaster->isRunning());
This is exactly the code of the Taskmaster::wait()
function, but you can do something else between the updates.
Stopping the taskmaster
After you've waited for all tasks to finish, you should stop the taskmaster:
$taskmaster->stop();
Task/worker groups
For a more complex setup, you can group several workers together and then define tasks that only run on a certain group.
// create a group A with 4 fork workers $workerA = new \Aternos\Taskmaster\Environment\Fork\ForkWorker(); $workerA->setGroup('A'); $taskmaster->addWorkers($workerA, 4); // create a group B with 2 process workers $workerB = new \Aternos\Taskmaster\Environment\Process\ProcessWorker(); $workerB->setGroup('B'); $taskmaster->addWorkers($workerB, 2); // create tasks that only run on group A for ($i = 0; $i < 10; $i++) { $taskA = new SleepTask(); $taskA->setGroup('A'); $taskmaster->runTask($taskA); } // create tasks that only run on group B for ($i = 0; $i < 5; $i++) { $taskB = new FileTask(); $taskB->setGroup('B'); $taskmaster->runTask($taskB); }
Groups in task factories
Task factories also support groups in two ways.
You can directly define, for which groups the task factory
should be called by returning an array of groups from the TaskFactory::getGroups()
function. You can return
null
if you want to create tasks for all groups or [null]
in an array if you want to be called for tasks
without a group.
And you get the group as a parameter in the TaskFactory::createNextTask(?string $group)
function. The group
parameter is null
if the task factory is called for tasks without a group.
class SleepTaskFactory extends \Aternos\Taskmaster\Task\TaskFactory { protected int $count = 0; public function getGroups() : ?array { return ['A', 'B']; } public function createNextTask(?string $group): ?\Aternos\Taskmaster\Task\TaskInterface { if ($this->count++ < 100) { return new SleepTask(); } return null; } }