Diogo Peralta Cordeiro 6e031d623a [VersionBump] 2.0.0beta0 | 3 years ago | |
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examples | 3 years ago | |
src | 3 years ago | |
tests | 3 years ago | |
CHANGELOG.md | 3 years ago | |
CONTRIBUTING.md | 3 years ago | |
FAQ.md | 3 years ago | |
LICENSE | 3 years ago | |
README.md | 3 years ago | |
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Flexible and feature-complete Redis client for PHP >= 5.3 and HHVM >= 2.3.0.
Predis does not require any additional C extension by default, but it can be optionally paired with phpiredis to lower the overhead of the serialization and parsing of the Redis RESP Protocol.
More details about this project can be found on the frequently asked questions.
EVALSHA
or EVAL
.SCAN
, SSCAN
, ZSCAN
and HSCAN
(Redis >= 2.8) based on PHP iterators.ext-curl
and ext-phpiredis
).This library can be found on Packagist for an easier management of projects dependencies using Composer or on our own PEAR channel for a more traditional installation using PEAR. Ultimately, compressed archives of each release are available on GitHub.
Predis relies on the autoloading features of PHP to load its files when needed and complies with the PSR-4 standard. Autoloading is handled automatically when dependencies are managed through Composer, but it is also possible to leverage its own autoloader in projects or scripts lacking any autoload facility:
// Prepend a base path if Predis is not available in your "include_path".
require 'Predis/Autoloader.php';
Predis\Autoloader::register();
It is also possible to create a phar archive directly
from the repository by launching the bin/create-phar
script. The generated phar already contains a
stub defining its own autoloader, so you just need to require()
it to start using the library.
When creating a client instance without passing any connection parameter, Predis assumes 127.0.0.1
and 6379
as default host and port. The default timeout for the connect()
operation is 5 seconds:
$client = new Predis\Client();
$client->set('foo', 'bar');
$value = $client->get('foo');
Connection parameters can be supplied either in the form of URI strings or named arrays. The latter is the preferred way to supply parameters, but URI strings can be useful when parameters are read from non-structured or partially-structured sources:
// Parameters passed using a named array:
$client = new Predis\Client([
'scheme' => 'tcp',
'host' => '10.0.0.1',
'port' => 6379,
]);
// Same set of parameters, passed using an URI string:
$client = new Predis\Client('tcp://10.0.0.1:6379');
Password protected servers can be accessed by adding password
to the parameters set. When ACLs are
enabled on Redis >= 6.0, both username
and password
are required for user authentication.
It is also possible to connect to local instances of Redis using UNIX domain sockets, in this case
the parameters must use the unix
scheme and specify a path for the socket file:
$client = new Predis\Client(['scheme' => 'unix', 'path' => '/path/to/redis.sock']);
$client = new Predis\Client('unix:/path/to/redis.sock');
The client can leverage TLS/SSL encryption to connect to secured remote Redis instances without the
need to configure an SSL proxy like stunnel. This can be useful when connecting to nodes running on
various cloud hosting providers. Encryption can be enabled with using the tls
scheme and an array
of suitable options passed via the ssl
parameter:
// Named array of connection parameters:
$client = new Predis\Client([
'scheme' => 'tls',
'ssl' => ['cafile' => 'private.pem', 'verify_peer' => true],
]);
// Same set of parameters, but using an URI string:
$client = new Predis\Client('tls://127.0.0.1?ssl[cafile]=private.pem&ssl[verify_peer]=1');
The connection schemes redis
(alias of
tcp
) and rediss
(alias of tls
) are
also supported, with the difference that URI strings containing these schemes are parsed following
the rules described on their respective IANA provisional registration documents.
The actual list of supported connection parameters can vary depending on each connection backend so it is recommended to refer to their specific documentation or implementation for details.
When an array of connection parameters is provided, Predis automatically works in cluster mode using client-side sharding. Both named arrays and URI strings can be mixed when providing configurations for each node:
$client = new Predis\Client([
'tcp://10.0.0.1?alias=first-node',
['host' => '10.0.0.2', 'alias' => 'second-node'],
]);
See the aggregate connections section of this document for more details.
Connections to Redis are lazy meaning that the client connects to a server only if and when needed.
While it is recommended to let the client do its own stuff under the hood, there may be times when
it is still desired to have control of when the connection is opened or closed: this can easily be
achieved by invoking $client->connect()
and $client->disconnect()
. Please note that the effect
of these methods on aggregate connections may differ depending on each specific implementation.
Many aspects and behaviors of the client can be configured by passing specific client options to the
second argument of Predis\Client::__construct()
:
$client = new Predis\Client($parameters, ['profile' => '2.8', 'prefix' => 'sample:']);
Options are managed using a mini DI-alike container and their values can be lazily initialized only when needed. The client options supported by default in Predis are:
profile
: specifies the profile to use to match a specific version of Redis.prefix
: prefix string automatically applied to keys found in commands.exceptions
: whether the client should throw or return responses upon Redis errors.connections
: list of connection backends or a connection factory instance.cluster
: specifies a cluster backend (predis
, redis
or callable object).replication
: specifies a replication backend (TRUE
, sentinel
or callable object).aggregate
: overrides cluster
and replication
to provide a custom connections aggregator.parameters
: list of default connection parameters for aggregate connections.Users can also provide custom options with values or callable objects (for lazy initialization) that are stored in the options container for later use through the library.
Aggregate connections are the foundation upon which Predis implements clustering and replication and they are used to group multiple connections to single Redis nodes and hide the specific logic needed to handle them properly depending on the context. Aggregate connections usually require an array of connection parameters when creating a new client instance.
By default, when no specific client options are set and an array of connection parameters is passed to the client's constructor, Predis configures itself to work in clustering mode using a traditional client-side sharding approach to create a cluster of independent nodes and distribute the keyspace among them. This approach needs some form of external health monitoring of nodes and requires manual operations to rebalance the keyspace when changing its configuration by adding or removing nodes:
$parameters = ['tcp://10.0.0.1', 'tcp://10.0.0.2', 'tcp://10.0.0.3'];
$client = new Predis\Client($parameters);
Along with Redis 3.0, a new supervised and coordinated type of clustering was introduced in the form
of redis-cluster. This kind of approach uses a different
algorithm to distribute the keyspaces, with Redis nodes coordinating themselves by communicating via
a gossip protocol to handle health status, rebalancing, nodes discovery and request redirection. In
order to connect to a cluster managed by redis-cluster, the client requires a list of its nodes (not
necessarily complete since it will automatically discover new nodes if necessary) and the cluster
client options set to redis
:
$parameters = ['tcp://10.0.0.1', 'tcp://10.0.0.2', 'tcp://10.0.0.3'];
$options = ['cluster' => 'redis'];
$client = new Predis\Client($parameters, $options);
The client can be configured to operate in a single master / multiple slaves setup to provide better service availability. When using replication, Predis recognizes read-only commands and sends them to a random slave in order to provide some sort of load-balancing and switches to the master as soon as it detects a command that performs any kind of operation that would end up modifying the keyspace or the value of a key. Instead of raising a connection error when a slave fails, the client attempts to fall back to a different slave among the ones provided in the configuration.
The basic configuration needed to use the client in replication mode requires one Redis server to be
identified as the master (this can be done via connection parameters using the alias
parameter set
to master
) and one or more servers acting as slaves:
$parameters = ['tcp://10.0.0.1?alias=master', 'tcp://10.0.0.2', 'tcp://10.0.0.3'];
$options = ['replication' => true];
$client = new Predis\Client($parameters, $options);
The above configuration has a static list of servers and relies entirely on the client's logic, but
it is possible to rely on redis-sentinel
for a more robust HA
environment with sentinel servers acting as a source of authority for clients for service discovery.
The minimum configuration required by the client to work with redis-sentinel is a list of connection
parameters pointing to a bunch of sentinel instances, the replication
option set to sentinel
and
the service
option set to the name of the service:
$sentinels = ['tcp://10.0.0.1', 'tcp://10.0.0.2', 'tcp://10.0.0.3'];
$options = ['replication' => 'sentinel', 'service' => 'mymaster'];
$client = new Predis\Client($sentinels, $options);
If the master and slave nodes are configured to require an authentication from clients, a password
must be provided via the global parameters
client option. This option can also be used to specify
a different database index. The client options array would then look like this:
$options = [
'replication' => 'sentinel',
'service' => 'mymaster',
'parameters' => [
'password' => $secretpassword,
'database' => 10,
],
];
While Predis is able to distinguish commands performing write and read-only operations, EVAL
and
EVALSHA
represent a corner case in which the client switches to the master node because it cannot
tell when a Lua script is safe to be executed on slaves. While this is indeed the default behavior,
when certain Lua scripts do not perform write operations it is possible to provide an hint to tell
the client to stick with slaves for their execution:
$parameters = ['tcp://10.0.0.1?alias=master', 'tcp://10.0.0.2', 'tcp://10.0.0.3'];
$options = ['replication' => function () {
// Set scripts that won't trigger a switch from a slave to the master node.
$strategy = new Predis\Replication\ReplicationStrategy();
$strategy->setScriptReadOnly($LUA_SCRIPT);
return new Predis\Connection\Aggregate\MasterSlaveReplication($strategy);
}];
$client = new Predis\Client($parameters, $options);
$client->eval($LUA_SCRIPT, 0); // Sticks to slave using `eval`...
$client->evalsha(sha1($LUA_SCRIPT), 0); // ... and `evalsha`, too.
The examples
directory contains a few scripts that demonstrate how the client can be
configured and used to leverage replication in both basic and complex scenarios.
Pipelining can help with performances when many commands need to be sent to a server by reducing the latency introduced by network round-trip timings. Pipelining also works with aggregate connections. The client can execute the pipeline inside a callable block or return a pipeline instance with the ability to chain commands thanks to its fluent interface:
// Executes a pipeline inside the given callable block:
$responses = $client->pipeline(function ($pipe) {
for ($i = 0; $i < 1000; $i++) {
$pipe->set("key:$i", str_pad($i, 4, '0', 0));
$pipe->get("key:$i");
}
});
// Returns a pipeline that can be chained thanks to its fluent interface:
$responses = $client->pipeline()->set('foo', 'bar')->get('foo')->execute();
The client provides an abstraction for Redis transactions based on MULTI
and EXEC
with a similar
interface to command pipelines:
// Executes a transaction inside the given callable block:
$responses = $client->transaction(function ($tx) {
$tx->set('foo', 'bar');
$tx->get('foo');
});
// Returns a transaction that can be chained thanks to its fluent interface:
$responses = $client->transaction()->set('foo', 'bar')->get('foo')->execute();
This abstraction can perform check-and-set operations thanks to WATCH
and UNWATCH
and provides
automatic retries of transactions aborted by Redis when WATCH
ed keys are touched. For an example
of a transaction using CAS you can see the following example.
While we try to update Predis to stay up to date with all the commands available in Redis, you might prefer to stick with an old version of the library or provide a different way to filter arguments or parse responses for specific commands. To achieve that, Predis provides the ability to implement new command classes to define or override commands in the default server profiles used by the client:
// Define a new command by extending Predis\Command\Command:
class BrandNewRedisCommand extends Predis\Command\Command
{
public function getId()
{
return 'NEWCMD';
}
}
// Inject your command in the current profile:
$client = new Predis\Client();
$client->getProfile()->defineCommand('newcmd', 'BrandNewRedisCommand');
$response = $client->newcmd();
There is also a method to send raw commands without filtering their arguments or parsing responses. Users must provide the list of arguments for the command as an array, following the signatures as defined by the Redis documentation for commands:
$response = $client->executeRaw(['SET', 'foo', 'bar']);
While it is possible to leverage Lua scripting on Redis 2.6+ using
directly EVAL
and EVALSHA
,
Predis offers script commands as an higher level abstraction built upon them to make things simple.
Script commands can be registered in the server profile used by the client and are accessible as if
they were plain Redis commands, but they define Lua scripts that get transmitted to the server for
remote execution. Internally they use EVALSHA
by default and
identify a script by its SHA1 hash to save bandwidth, but EVAL
is used as a fall back when needed:
// Define a new script command by extending Predis\Command\ScriptCommand:
class ListPushRandomValue extends Predis\Command\ScriptCommand
{
public function getKeysCount()
{
return 1;
}
public function getScript()
{
return <<<LUA
math.randomseed(ARGV[1])
local rnd = tostring(math.random())
redis.call('lpush', KEYS[1], rnd)
return rnd
LUA;
}
}
// Inject the script command in the current profile:
$client = new Predis\Client();
$client->getProfile()->defineCommand('lpushrand', 'ListPushRandomValue');
$response = $client->lpushrand('random_values', $seed = mt_rand());
Predis can use different connection backends to connect to Redis. Two of them leverage a third party
extension such as phpiredis resulting in major performance gains
especially when dealing with big multibulk responses. While one is based on PHP streams, the other
is based on socket resources provided by ext-socket
. Both support TCP/IP and UNIX domain sockets:
$client = new Predis\Client('tcp://127.0.0.1', [
'connections' => [
'tcp' => 'Predis\Connection\PhpiredisStreamConnection', // PHP stream resources
'unix' => 'Predis\Connection\PhpiredisSocketConnection', // ext-socket resources
],
]);
Developers can create their own connection classes to support whole new network backends, extend
existing classes or provide completely different implementations. Connection classes must implement
Predis\Connection\NodeConnectionInterface
or extend Predis\Connection\AbstractConnection
:
class MyConnectionClass implements Predis\Connection\NodeConnectionInterface
{
// Implementation goes here...
}
// Use MyConnectionClass to handle connections for the `tcp` scheme:
$client = new Predis\Client('tcp://127.0.0.1', [
'connections' => ['tcp' => 'MyConnectionClass'],
]);
For a more in-depth insight on how to create new connection backends you can refer to the actual
implementation of the standard connection classes available in the Predis\Connection
namespace.
Contributions to Predis are highly appreciated either in the form of pull requests for new features, bug fixes, or just bug reports. We only ask you to adhere to a basic set of rules before submitting your changes or filing bugs on the issue tracker to make it easier for everyone to stay consistent while working on the project.
ATTENTION: Do not ever run the test suite shipped with Predis against instances of Redis running in production environments or containing data you are interested in!
Predis has a comprehensive test suite covering every aspect of the library. This test suite performs
integration tests against a running instance of Redis (>= 2.4.0 is required) to verify the correct
behavior of the implementation of each command and automatically skips commands not defined in the
specified Redis profile. If you do not have Redis up and running, integration tests can be disabled.
By default the test suite is configured to execute integration tests using the profile for Redis 3.2
(which is the current stable version of Redis) but can optionally target a Redis instance built from
the unstable
branch by modifying phpunit.xml
and setting REDIS_SERVER_VERSION
to dev
so that
the development server profile will be used. You can refer to the tests README
for more detailed information about testing Predis.
Predis uses Travis CI for continuous integration and the history for past and current builds can be found on its project page.
The code for Predis is distributed under the terms of the MIT license (see LICENSE).