id | title | sidebar_label |
---|---|---|
client-libraries-cpp |
Pulsar C++ client |
C++ |
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You can use a Pulsar C++ client to create producers, consumers, and readers.
All the methods in producer, consumer, and reader of a C++ client are thread-safe. You can read the API docs for the C++ client.
Use one of the following methods to install a Pulsar C++ client.
Use Homebrew to install the latest tagged version with the library and headers:
brew install libpulsar
- Download any one of the Deb packages:
wget @pulsar:deb:client@
This package contains shared libraries libpulsar.so
and libpulsarnossl.so
.
wget @pulsar:deb:client-devel@
This package contains static libraries: libpulsar.a
, libpulsarwithdeps.a
and C/C++ headers.
- Install the package using the following command:
apt install ./apache-pulsar-client*.deb
Now, you can see Pulsar C++ client libraries installed under the /usr/lib
directory.
- Download any one of the RPM packages:
wget @pulsar:dist_rpm:client@
This package contains shared libraries: libpulsar.so
and libpulsarnossl.so
.
wget @pulsar:dist_rpm:client-debuginfo@
This package contains debug symbols for libpulsar.so
wget @pulsar:dist_rpm:client-devel@
This package contains static libraries: libpulsar.a
, libpulsarwithdeps.a
and C/C++ headers.
- Install the package using the following command:
rpm -ivh apache-pulsar-client*.rpm
Now, you can see Pulsar C++ client libraries installed under the /usr/lib
directory.
:::note
If you get an error like "libpulsar.so: cannot open shared object file: No such file or directory" when starting a Pulsar client, you need to run ldconfig
first.
:::
For how to build Pulsar C++ client on different platforms from source code, see compliation.
To connect to Pulsar using client libraries, you need to specify a Pulsar protocol URL.
You can assign Pulsar protocol URLs to specific clusters and use the pulsar
scheme. The following is an example of localhost
with the default port 6650
:
pulsar://localhost:6650
If you have multiple brokers, separate IP:port
by commas:
pulsar://localhost:6550,localhost:6651,localhost:6652
If you use TLS authentication, add +ssl
in the scheme:
pulsar+ssl://pulsar.us-west.example.com:6651
To use Pulsar as a producer, you need to create a producer on the C++ client. There are two main ways of using a producer:
- Blocking style : each call to
send
waits for an ack from the broker. - Non-blocking asynchronous style :
sendAsync
is called instead ofsend
and a callback is supplied for when the ack is received from the broker.
This example sends 100 messages using the blocking style. While simple, it does not produce high throughput as it waits for each ack to come back before sending the next message.
#include <pulsar/Client.h>
#include <thread>
using namespace pulsar;
int main() {
Client client("pulsar://localhost:6650");
Producer producer;
Result result = client.createProducer("persistent://public/default/my-topic", producer);
if (result != ResultOk) {
std::cout << "Error creating producer: " << result << std::endl;
return -1;
}
// Send 100 messages synchronously
int ctr = 0;
while (ctr < 100) {
std::string content = "msg" + std::to_string(ctr);
Message msg = MessageBuilder().setContent(content).setProperty("x", "1").build();
Result result = producer.send(msg);
if (result != ResultOk) {
std::cout << "The message " << content << " could not be sent, received code: " << result << std::endl;
} else {
std::cout << "The message " << content << " sent successfully" << std::endl;
}
std::this_thread::sleep_for(std::chrono::milliseconds(100));
ctr++;
}
std::cout << "Finished producing synchronously!" << std::endl;
client.close();
return 0;
}
This example sends 100 messages using the non-blocking style calling sendAsync
instead of send
. This allows the producer to have multiple messages in-flight at a time which increases throughput.
The producer configuration blockIfQueueFull
is useful here to avoid ResultProducerQueueIsFull
errors when the internal queue for outgoing send requests becomes full. Once the internal queue is full, sendAsync
becomes blocking which can make your code simpler.
Without this configuration, the result code ResultProducerQueueIsFull
is passed to the callback. You must decide how to deal with that (retry, discard etc).
#include <pulsar/Client.h>
#include <thread>
#include <atomic>
using namespace pulsar;
std::atomic<uint32_t> acksReceived;
void callback(Result code, const MessageId& msgId, std::string msgContent) {
// message processing logic here
std::cout << "Received ack for msg: " << msgContent << " with code: "
<< code << " -- MsgID: " << msgId << std::endl;
acksReceived++;
}
int main() {
Client client("pulsar://localhost:6650");
ProducerConfiguration producerConf;
producerConf.setBlockIfQueueFull(true);
Producer producer;
Result result = client.createProducer("persistent://public/default/my-topic",
producerConf, producer);
if (result != ResultOk) {
std::cout << "Error creating producer: " << result << std::endl;
return -1;
}
// Send 100 messages asynchronously
int ctr = 0;
while (ctr < 100) {
std::string content = "msg" + std::to_string(ctr);
Message msg = MessageBuilder().setContent(content).setProperty("x", "1").build();
producer.sendAsync(msg, std::bind(callback,
std::placeholders::_1, std::placeholders::_2, content));
std::this_thread::sleep_for(std::chrono::milliseconds(100));
ctr++;
}
// wait for 100 messages to be acked
while (acksReceived < 100) {
std::this_thread::sleep_for(std::chrono::milliseconds(100));
}
std::cout << "Finished producing asynchronously!" << std::endl;
client.close();
return 0;
}
When scaling out a Pulsar topic, you may configure a topic to have hundreds of partitions. Likewise, you may have also scaled out your producers so there are hundreds or even thousands of producers. This can put some strain on the Pulsar brokers as when you create a producer on a partitioned topic, internally it creates one internal producer per partition which involves communications to the brokers for each one. So for a topic with 1000 partitions and 1000 producers, it ends up creating 1,000,000 internal producers across the producer applications, each of which has to communicate with a broker to find out which broker it should connect to and then perform the connection handshake.
You can reduce the load caused by this combination of a large number of partitions and many producers by doing the following:
- use SinglePartition partition routing mode (this ensures that all messages are only sent to a single, randomly selected partition)
- use non-keyed messages (when messages are keyed, routing is based on the hash of the key and so messages will end up being sent to multiple partitions)
- use lazy producers (this ensures that an internal producer is only created on demand when a message needs to be routed to a partition)
With our example above, that reduces the number of internal producers spread out over the 1000 producer apps from 1,000,000 to just 1000.
Note that there can be extra latency for the first message sent. If you set a low send timeout, this timeout could be reached if the initial connection handshake is slow to complete.
ProducerConfiguration producerConf;
producerConf.setPartitionsRoutingMode(ProducerConfiguration::UseSinglePartition);
producerConf.setLazyStartPartitionedProducers(true);
Message chunking enables Pulsar to process large payload messages by splitting the message into chunks at the producer side and aggregating chunked messages at the consumer side.
The message chunking feature is OFF by default. The following is an example about how to enable message chunking when creating a producer.
ProducerConfiguration conf;
conf.setBatchingEnabled(false);
conf.setChunkingEnabled(true);
Producer producer;
client.createProducer("my-topic", conf, producer);
:::note
To enable chunking, you need to disable batching (setBatchingEnabled
=false
) concurrently.
:::
To use Pulsar as a consumer, you need to create a consumer on the C++ client. There are two main ways of using the consumer:
- Blocking style: synchronously calling
receive(msg)
. - Non-blocking (event-based) style: using a message listener.
The benefit of this approach is that it is the simplest code. Simply keeps calling receive(msg)
which blocks until a message is received.
This example starts a subscription at the earliest offset and consumes 100 messages.
#include <pulsar/Client.h>
using namespace pulsar;
int main() {
Client client("pulsar://localhost:6650");
Consumer consumer;
ConsumerConfiguration config;
config.setSubscriptionInitialPosition(InitialPositionEarliest);
Result result = client.subscribe("persistent://public/default/my-topic", "consumer-1", config, consumer);
if (result != ResultOk) {
std::cout << "Failed to subscribe: " << result << std::endl;
return -1;
}
Message msg;
int ctr = 0;
// consume 100 messages
while (ctr < 100) {
consumer.receive(msg);
std::cout << "Received: " << msg
<< " with payload '" << msg.getDataAsString() << "'" << std::endl;
consumer.acknowledge(msg);
ctr++;
}
std::cout << "Finished consuming synchronously!" << std::endl;
client.close();
return 0;
}
You can avoid running a loop by blocking calls with an event-based style by using a message listener which is invoked for each message that is received.
This example starts a subscription at the earliest offset and consumes 100 messages.
#include <pulsar/Client.h>
#include <atomic>
#include <thread>
using namespace pulsar;
std::atomic<uint32_t> messagesReceived;
void handleAckComplete(Result res) {
std::cout << "Ack res: " << res << std::endl;
}
void listener(Consumer consumer, const Message& msg) {
std::cout << "Got message " << msg << " with content '" << msg.getDataAsString() << "'" << std::endl;
messagesReceived++;
consumer.acknowledgeAsync(msg.getMessageId(), handleAckComplete);
}
int main() {
Client client("pulsar://localhost:6650");
Consumer consumer;
ConsumerConfiguration config;
config.setMessageListener(listener);
config.setSubscriptionInitialPosition(InitialPositionEarliest);
Result result = client.subscribe("persistent://public/default/my-topic", "consumer-1", config, consumer);
if (result != ResultOk) {
std::cout << "Failed to subscribe: " << result << std::endl;
return -1;
}
// wait for 100 messages to be consumed
while (messagesReceived < 100) {
std::this_thread::sleep_for(std::chrono::milliseconds(100));
}
std::cout << "Finished consuming asynchronously!" << std::endl;
client.close();
return 0;
}
You can limit the maximum number of chunked messages a consumer maintains concurrently by configuring the setMaxPendingChunkedMessage
and setAutoAckOldestChunkedMessageOnQueueFull
parameters. When the threshold is reached, the consumer drops pending messages by silently acknowledging them or asking the broker to redeliver them later.
The following is an example of how to configure message chunking.
ConsumerConfiguration conf;
conf.setAutoAckOldestChunkedMessageOnQueueFull(true);
conf.setMaxPendingChunkedMessage(100);
Consumer consumer;
client.subscribe("my-topic", "my-sub", conf, consumer);
If you use TLS authentication when connecting to Pulsar, you need to add ssl
in the connection URLs, and the default port is 6651
. The following is an example.
ClientConfiguration config = ClientConfiguration();
config.setUseTls(true);
config.setTlsTrustCertsFilePath("/path/to/cacert.pem");
config.setTlsAllowInsecureConnection(false);
config.setAuth(pulsar::AuthTls::create(
"/path/to/client-cert.pem", "/path/to/client-key.pem"););
Client client("pulsar+ssl://my-broker.com:6651", config);
For complete examples, refer to C++ client examples.
This section describes some examples about schema. For more information about schema, see Pulsar schema.
-
The following example shows how to create a producer with an Avro schema.
static const std::string exampleSchema = "{\"type\":\"record\",\"name\":\"Example\",\"namespace\":\"test\"," "\"fields\":[{\"name\":\"a\",\"type\":\"int\"},{\"name\":\"b\",\"type\":\"int\"}]}"; Producer producer; ProducerConfiguration producerConf; producerConf.setSchema(SchemaInfo(AVRO, "Avro", exampleSchema)); client.createProducer("topic-avro", producerConf, producer);
-
The following example shows how to create a consumer with an Avro schema.
static const std::string exampleSchema = "{\"type\":\"record\",\"name\":\"Example\",\"namespace\":\"test\"," "\"fields\":[{\"name\":\"a\",\"type\":\"int\"},{\"name\":\"b\",\"type\":\"int\"}]}"; ConsumerConfiguration consumerConf; Consumer consumer; consumerConf.setSchema(SchemaInfo(AVRO, "Avro", exampleSchema)); client.subscribe("topic-avro", "sub-2", consumerConf, consumer)
The following example shows how to create a producer and a consumer with a ProtobufNative schema.
-
Generate the
User
class using Protobuf3 or later versions.syntax = "proto3"; message User { string name = 1; int32 age = 2; }
-
Include the
ProtobufNativeSchema.h
in your source code. Ensure the Protobuf dependency has been added to your project.#include <pulsar/ProtobufNativeSchema.h>
-
Create a producer to send a
User
instance.ProducerConfiguration producerConf; producerConf.setSchema(createProtobufNativeSchema(User::GetDescriptor())); Producer producer; client.createProducer("topic-protobuf", producerConf, producer); User user; user.set_name("my-name"); user.set_age(10); std::string content; user.SerializeToString(&content); producer.send(MessageBuilder().setContent(content).build());
-
Create a consumer to receive a
User
instance.ConsumerConfiguration consumerConf; consumerConf.setSchema(createProtobufNativeSchema(User::GetDescriptor())); consumerConf.setSubscriptionInitialPosition(InitialPositionEarliest); Consumer consumer; client.subscribe("topic-protobuf", "my-sub", consumerConf, consumer); Message msg; consumer.receive(msg); User user2; user2.ParseFromArray(msg.getData(), msg.getLength());