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|
// -*- mode:C++; tab-width:8; c-basic-offset:2; indent-tabs-mode:t -*-
// vim: ts=8 sw=2 smarttab ft=cpp
#include "rgw_kafka.h"
#include "rgw_url.h"
#include <librdkafka/rdkafka.h>
#include "include/ceph_assert.h"
#include <sstream>
#include <cstring>
#include <unordered_map>
#include <string>
#include <vector>
#include <thread>
#include <atomic>
#include <mutex>
#include <boost/lockfree/queue.hpp>
#include "common/dout.h"
#define dout_subsys ceph_subsys_rgw
// TODO investigation, not necessarily issues:
// (1) in case of single threaded writer context use spsc_queue
// (2) check performance of emptying queue to local list, and go over the list and publish
// (3) use std::shared_mutex (c++17) or equivalent for the connections lock
// cmparisson operator between topic pointer and name
bool operator==(const rd_kafka_topic_t* rkt, const std::string& name) {
return name == std::string_view(rd_kafka_topic_name(rkt));
}
namespace rgw::kafka {
// status codes for publishing
static const int STATUS_CONNECTION_CLOSED = -0x1002;
static const int STATUS_QUEUE_FULL = -0x1003;
static const int STATUS_MAX_INFLIGHT = -0x1004;
static const int STATUS_MANAGER_STOPPED = -0x1005;
static const int STATUS_CONNECTION_IDLE = -0x1006;
// status code for connection opening
static const int STATUS_CONF_ALLOC_FAILED = -0x2001;
static const int STATUS_CONF_REPLCACE = -0x2002;
static const int STATUS_OK = 0x0;
// struct for holding the callback and its tag in the callback list
struct reply_callback_with_tag_t {
uint64_t tag;
reply_callback_t cb;
reply_callback_with_tag_t(uint64_t _tag, reply_callback_t _cb) : tag(_tag), cb(_cb) {}
bool operator==(uint64_t rhs) {
return tag == rhs;
}
};
typedef std::vector<reply_callback_with_tag_t> CallbackList;
// struct for holding the connection state object as well as list of topics
// it is used inside an intrusive ref counted pointer (boost::intrusive_ptr)
// since references to deleted objects may still exist in the calling code
struct connection_t {
rd_kafka_t* producer = nullptr;
rd_kafka_conf_t* temp_conf = nullptr;
std::vector<rd_kafka_topic_t*> topics;
uint64_t delivery_tag = 1;
int status = STATUS_OK;
CephContext* const cct;
CallbackList callbacks;
const std::string broker;
const bool use_ssl;
const bool verify_ssl; // TODO currently iognored, not supported in librdkafka v0.11.6
const boost::optional<std::string> ca_location;
const std::string user;
const std::string password;
const boost::optional<std::string> mechanism;
utime_t timestamp = ceph_clock_now();
// cleanup of all internal connection resource
// the object can still remain, and internal connection
// resources created again on successful reconnection
void destroy(int s) {
status = s;
// destroy temporary conf (if connection was never established)
if (temp_conf) {
rd_kafka_conf_destroy(temp_conf);
return;
}
if (!is_ok()) {
// no producer, nothing to destroy
return;
}
// wait for all remaining acks/nacks
rd_kafka_flush(producer, 5*1000 /* wait for max 5 seconds */);
// destroy all topics
std::for_each(topics.begin(), topics.end(), [](auto topic) {rd_kafka_topic_destroy(topic);});
// destroy producer
rd_kafka_destroy(producer);
producer = nullptr;
// fire all remaining callbacks (if not fired by rd_kafka_flush)
std::for_each(callbacks.begin(), callbacks.end(), [this](auto& cb_tag) {
cb_tag.cb(status);
ldout(cct, 20) << "Kafka destroy: invoking callback with tag="
<< cb_tag.tag << " for: " << broker
<< " with status: " << status << dendl;
});
callbacks.clear();
delivery_tag = 1;
ldout(cct, 20) << "Kafka destroy: complete for: " << broker << dendl;
}
bool is_ok() const {
return (producer != nullptr);
}
// ctor for setting immutable values
connection_t(CephContext* _cct, const std::string& _broker, bool _use_ssl, bool _verify_ssl,
const boost::optional<const std::string&>& _ca_location,
const std::string& _user, const std::string& _password, const boost::optional<const std::string&>& _mechanism) :
cct(_cct), broker(_broker), use_ssl(_use_ssl), verify_ssl(_verify_ssl), ca_location(_ca_location), user(_user), password(_password), mechanism(_mechanism) {}
// dtor also destroys the internals
~connection_t() {
destroy(status);
}
};
// convert int status to string - including RGW specific values
std::string status_to_string(int s) {
switch (s) {
case STATUS_OK:
return "STATUS_OK";
case STATUS_CONNECTION_CLOSED:
return "RGW_KAFKA_STATUS_CONNECTION_CLOSED";
case STATUS_QUEUE_FULL:
return "RGW_KAFKA_STATUS_QUEUE_FULL";
case STATUS_MAX_INFLIGHT:
return "RGW_KAFKA_STATUS_MAX_INFLIGHT";
case STATUS_MANAGER_STOPPED:
return "RGW_KAFKA_STATUS_MANAGER_STOPPED";
case STATUS_CONF_ALLOC_FAILED:
return "RGW_KAFKA_STATUS_CONF_ALLOC_FAILED";
case STATUS_CONF_REPLCACE:
return "RGW_KAFKA_STATUS_CONF_REPLCACE";
case STATUS_CONNECTION_IDLE:
return "RGW_KAFKA_STATUS_CONNECTION_IDLE";
}
return std::string(rd_kafka_err2str((rd_kafka_resp_err_t)s));
}
void message_callback(rd_kafka_t* rk, const rd_kafka_message_t* rkmessage, void* opaque) {
ceph_assert(opaque);
const auto conn = reinterpret_cast<connection_t*>(opaque);
const auto result = rkmessage->err;
if (!rkmessage->_private) {
ldout(conn->cct, 20) << "Kafka run: n/ack received, (no callback) with result=" << result << dendl;
return;
}
const auto tag = reinterpret_cast<uint64_t*>(rkmessage->_private);
const auto& callbacks_end = conn->callbacks.end();
const auto& callbacks_begin = conn->callbacks.begin();
const auto tag_it = std::find(callbacks_begin, callbacks_end, *tag);
if (tag_it != callbacks_end) {
ldout(conn->cct, 20) << "Kafka run: n/ack received, invoking callback with tag=" <<
*tag << " and result=" << rd_kafka_err2str(result) << dendl;
tag_it->cb(result);
conn->callbacks.erase(tag_it);
} else {
// TODO add counter for acks with no callback
ldout(conn->cct, 10) << "Kafka run: unsolicited n/ack received with tag=" <<
*tag << dendl;
}
delete tag;
// rkmessage is destroyed automatically by librdkafka
}
void log_callback(const rd_kafka_t* rk, int level, const char *fac, const char *buf) {
ceph_assert(rd_kafka_opaque(rk));
const auto conn = reinterpret_cast<connection_t*>(rd_kafka_opaque(rk));
if (level <= 3)
ldout(conn->cct, 1) << "RDKAFKA-" << level << "-" << fac << ": " << rd_kafka_name(rk) << ": " << buf << dendl;
else if (level <= 5)
ldout(conn->cct, 2) << "RDKAFKA-" << level << "-" << fac << ": " << rd_kafka_name(rk) << ": " << buf << dendl;
else if (level <= 6)
ldout(conn->cct, 10) << "RDKAFKA-" << level << "-" << fac << ": " << rd_kafka_name(rk) << ": " << buf << dendl;
else
ldout(conn->cct, 20) << "RDKAFKA-" << level << "-" << fac << ": " << rd_kafka_name(rk) << ": " << buf << dendl;
}
void poll_err_callback(rd_kafka_t *rk, int err, const char *reason, void *opaque) {
const auto conn = reinterpret_cast<connection_t*>(rd_kafka_opaque(rk));
ldout(conn->cct, 10) << "Kafka run: poll error(" << err << "): " << reason << dendl;
}
using connection_t_ptr = std::unique_ptr<connection_t>;
// utility function to create a producer, when the connection object already exists
bool new_producer(connection_t* conn) {
// reset all status codes
conn->status = STATUS_OK;
char errstr[512] = {0};
conn->temp_conf = rd_kafka_conf_new();
if (!conn->temp_conf) {
conn->status = STATUS_CONF_ALLOC_FAILED;
return false;
}
// get list of brokers based on the bootsrap broker
if (rd_kafka_conf_set(conn->temp_conf, "bootstrap.servers", conn->broker.c_str(), errstr, sizeof(errstr)) != RD_KAFKA_CONF_OK) goto conf_error;
if (conn->use_ssl) {
if (!conn->user.empty()) {
// use SSL+SASL
if (rd_kafka_conf_set(conn->temp_conf, "security.protocol", "SASL_SSL", errstr, sizeof(errstr)) != RD_KAFKA_CONF_OK ||
rd_kafka_conf_set(conn->temp_conf, "sasl.username", conn->user.c_str(), errstr, sizeof(errstr)) != RD_KAFKA_CONF_OK ||
rd_kafka_conf_set(conn->temp_conf, "sasl.password", conn->password.c_str(), errstr, sizeof(errstr)) != RD_KAFKA_CONF_OK) goto conf_error;
ldout(conn->cct, 20) << "Kafka connect: successfully configured SSL+SASL security" << dendl;
if (conn->mechanism) {
if (rd_kafka_conf_set(conn->temp_conf, "sasl.mechanism", conn->mechanism->c_str(), errstr, sizeof(errstr)) != RD_KAFKA_CONF_OK) goto conf_error;
ldout(conn->cct, 20) << "Kafka connect: successfully configured SASL mechanism" << dendl;
} else {
if (rd_kafka_conf_set(conn->temp_conf, "sasl.mechanism", "PLAIN", errstr, sizeof(errstr)) != RD_KAFKA_CONF_OK) goto conf_error;
ldout(conn->cct, 20) << "Kafka connect: using default SASL mechanism" << dendl;
}
} else {
// use only SSL
if (rd_kafka_conf_set(conn->temp_conf, "security.protocol", "SSL", errstr, sizeof(errstr)) != RD_KAFKA_CONF_OK) goto conf_error;
ldout(conn->cct, 20) << "Kafka connect: successfully configured SSL security" << dendl;
}
if (conn->ca_location) {
if (rd_kafka_conf_set(conn->temp_conf, "ssl.ca.location", conn->ca_location->c_str(), errstr, sizeof(errstr)) != RD_KAFKA_CONF_OK) goto conf_error;
ldout(conn->cct, 20) << "Kafka connect: successfully configured CA location" << dendl;
} else {
ldout(conn->cct, 20) << "Kafka connect: using default CA location" << dendl;
}
// Note: when librdkafka.1.0 is available the following line could be uncommented instead of the callback setting call
// if (rd_kafka_conf_set(conn->temp_conf, "enable.ssl.certificate.verification", "0", errstr, sizeof(errstr)) != RD_KAFKA_CONF_OK) goto conf_error;
ldout(conn->cct, 20) << "Kafka connect: successfully configured security" << dendl;
} else if (!conn->user.empty()) {
// use SASL+PLAINTEXT
if (rd_kafka_conf_set(conn->temp_conf, "security.protocol", "SASL_PLAINTEXT", errstr, sizeof(errstr)) != RD_KAFKA_CONF_OK ||
rd_kafka_conf_set(conn->temp_conf, "sasl.username", conn->user.c_str(), errstr, sizeof(errstr)) != RD_KAFKA_CONF_OK ||
rd_kafka_conf_set(conn->temp_conf, "sasl.password", conn->password.c_str(), errstr, sizeof(errstr)) != RD_KAFKA_CONF_OK) goto conf_error;
ldout(conn->cct, 20) << "Kafka connect: successfully configured SASL_PLAINTEXT" << dendl;
if (conn->mechanism) {
if (rd_kafka_conf_set(conn->temp_conf, "sasl.mechanism", conn->mechanism->c_str(), errstr, sizeof(errstr)) != RD_KAFKA_CONF_OK) goto conf_error;
ldout(conn->cct, 20) << "Kafka connect: successfully configured SASL mechanism" << dendl;
} else {
if (rd_kafka_conf_set(conn->temp_conf, "sasl.mechanism", "PLAIN", errstr, sizeof(errstr)) != RD_KAFKA_CONF_OK) goto conf_error;
ldout(conn->cct, 20) << "Kafka connect: using default SASL mechanism" << dendl;
}
}
// set the global callback for delivery success/fail
rd_kafka_conf_set_dr_msg_cb(conn->temp_conf, message_callback);
// set the global opaque pointer to be the connection itself
rd_kafka_conf_set_opaque(conn->temp_conf, conn);
// redirect kafka logs to RGW
rd_kafka_conf_set_log_cb(conn->temp_conf, log_callback);
// define poll callback to allow reconnect
rd_kafka_conf_set_error_cb(conn->temp_conf, poll_err_callback);
// create the producer
if (conn->producer) {
ldout(conn->cct, 5) << "Kafka connect: producer already exists. detroying the existing before creating a new one" << dendl;
conn->destroy(STATUS_CONF_REPLCACE);
}
conn->producer = rd_kafka_new(RD_KAFKA_PRODUCER, conn->temp_conf, errstr, sizeof(errstr));
if (!conn->producer) {
conn->status = rd_kafka_last_error();
ldout(conn->cct, 1) << "Kafka connect: failed to create producer: " << errstr << dendl;
return false;
}
ldout(conn->cct, 20) << "Kafka connect: successfully created new producer" << dendl;
{
// set log level of producer
const auto log_level = conn->cct->_conf->subsys.get_log_level(ceph_subsys_rgw);
if (log_level <= 1)
rd_kafka_set_log_level(conn->producer, 3);
else if (log_level <= 2)
rd_kafka_set_log_level(conn->producer, 5);
else if (log_level <= 10)
rd_kafka_set_log_level(conn->producer, 6);
else
rd_kafka_set_log_level(conn->producer, 7);
}
// conf ownership passed to producer
conn->temp_conf = nullptr;
return true;
conf_error:
conn->status = rd_kafka_last_error();
ldout(conn->cct, 1) << "Kafka connect: configuration failed: " << errstr << dendl;
return false;
}
// struct used for holding messages in the message queue
struct message_wrapper_t {
std::string conn_name;
std::string topic;
std::string message;
const reply_callback_t cb;
message_wrapper_t(const std::string& _conn_name,
const std::string& _topic,
const std::string& _message,
reply_callback_t _cb) : conn_name(_conn_name), topic(_topic), message(_message), cb(_cb) {}
};
typedef std::unordered_map<std::string, connection_t_ptr> ConnectionList;
typedef boost::lockfree::queue<message_wrapper_t*, boost::lockfree::fixed_sized<true>> MessageQueue;
class Manager {
public:
const size_t max_connections;
const size_t max_inflight;
const size_t max_queue;
const size_t max_idle_time;
private:
std::atomic<size_t> connection_count;
bool stopped;
int read_timeout_ms;
ConnectionList connections;
MessageQueue messages;
std::atomic<size_t> queued;
std::atomic<size_t> dequeued;
CephContext* const cct;
mutable std::mutex connections_lock;
std::thread runner;
// TODO use rd_kafka_produce_batch for better performance
void publish_internal(message_wrapper_t* message) {
const std::unique_ptr<message_wrapper_t> msg_deleter(message);
const auto conn_it = connections.find(message->conn_name);
if (conn_it == connections.end()) {
ldout(cct, 1) << "Kafka publish: connection was deleted while message was in the queue. error: " << STATUS_CONNECTION_CLOSED << dendl;
if (message->cb) {
message->cb(STATUS_CONNECTION_CLOSED);
}
return;
}
auto& conn = conn_it->second;
conn->timestamp = ceph_clock_now();
if (!conn->is_ok()) {
// connection had an issue while message was in the queue
// TODO add error stats
ldout(conn->cct, 1) << "Kafka publish: producer was closed while message was in the queue. error: " << status_to_string(conn->status) << dendl;
if (message->cb) {
message->cb(conn->status);
}
return;
}
// create a new topic unless it was already created
auto topic_it = std::find(conn->topics.begin(), conn->topics.end(), message->topic);
rd_kafka_topic_t* topic = nullptr;
if (topic_it == conn->topics.end()) {
topic = rd_kafka_topic_new(conn->producer, message->topic.c_str(), nullptr);
if (!topic) {
const auto err = rd_kafka_last_error();
ldout(conn->cct, 1) << "Kafka publish: failed to create topic: " << message->topic << " error: " << status_to_string(err) << dendl;
if (message->cb) {
message->cb(err);
}
conn->destroy(err);
return;
}
// TODO use the topics list as an LRU cache
conn->topics.push_back(topic);
ldout(conn->cct, 20) << "Kafka publish: successfully created topic: " << message->topic << dendl;
} else {
topic = *topic_it;
ldout(conn->cct, 20) << "Kafka publish: reused existing topic: " << message->topic << dendl;
}
const auto tag = (message->cb == nullptr ? nullptr : new uint64_t(conn->delivery_tag++));
const auto rc = rd_kafka_produce(
topic,
// TODO: non builtin partitioning
RD_KAFKA_PARTITION_UA,
// make a copy of the payload
// so it is safe to pass the pointer from the string
RD_KAFKA_MSG_F_COPY,
message->message.data(),
message->message.length(),
// optional key and its length
nullptr,
0,
// opaque data: tag, used in the global callback
// in order to invoke the real callback
// null if no callback exists
tag);
if (rc == -1) {
const auto err = rd_kafka_last_error();
ldout(conn->cct, 10) << "Kafka publish: failed to produce: " << rd_kafka_err2str(err) << dendl;
// TODO: dont error on full queue, and don't destroy connection, retry instead
// immediatly invoke callback on error if needed
if (message->cb) {
message->cb(err);
}
conn->destroy(err);
delete tag;
return;
}
if (tag) {
auto const q_len = conn->callbacks.size();
if (q_len < max_inflight) {
ldout(conn->cct, 20)
<< "Kafka publish (with callback, tag=" << *tag
<< "): OK. Queue has: " << q_len + 1 << " callbacks" << dendl;
conn->callbacks.emplace_back(*tag, message->cb);
} else {
// immediately invoke callback with error - this is not a connection error
ldout(conn->cct, 1) << "Kafka publish (with callback): failed with error: callback queue full" << dendl;
message->cb(STATUS_MAX_INFLIGHT);
// tag will be deleted when the global callback is invoked
}
} else {
ldout(conn->cct, 20) << "Kafka publish (no callback): OK" << dendl;
}
}
// the managers thread:
// (1) empty the queue of messages to be published
// (2) loop over all connections and read acks
// (3) manages deleted connections
// (4) TODO reconnect on connection errors
// (5) TODO cleanup timedout callbacks
void run() noexcept {
while (!stopped) {
// publish all messages in the queue
auto reply_count = 0U;
const auto send_count = messages.consume_all(std::bind(&Manager::publish_internal, this, std::placeholders::_1));
dequeued += send_count;
ConnectionList::iterator conn_it;
ConnectionList::const_iterator end_it;
{
// thread safe access to the connection list
// once the iterators are fetched they are guaranteed to remain valid
std::lock_guard lock(connections_lock);
conn_it = connections.begin();
end_it = connections.end();
}
// loop over all connections to read acks
for (;conn_it != end_it;) {
auto& conn = conn_it->second;
// Checking the connection idlesness
if(conn->timestamp.sec() + max_idle_time < ceph_clock_now()) {
ldout(conn->cct, 20) << "kafka run: deleting a connection due to idle behaviour: " << ceph_clock_now() << dendl;
std::lock_guard lock(connections_lock);
conn->status = STATUS_CONNECTION_IDLE;
conn_it = connections.erase(conn_it);
--connection_count; \
continue;
}
// try to reconnect the connection if it has an error
if (!conn->is_ok()) {
ldout(conn->cct, 10) << "Kafka run: connection status is: " << status_to_string(conn->status) << dendl;
const auto& broker = conn_it->first;
ldout(conn->cct, 20) << "Kafka run: retry connection" << dendl;
if (new_producer(conn.get()) == false) {
ldout(conn->cct, 10) << "Kafka run: connection (" << broker << ") retry failed" << dendl;
// TODO: add error counter for failed retries
// TODO: add exponential backoff for retries
} else {
ldout(conn->cct, 10) << "Kafka run: connection (" << broker << ") retry successfull" << dendl;
}
++conn_it;
continue;
}
reply_count += rd_kafka_poll(conn->producer, read_timeout_ms);
// just increment the iterator
++conn_it;
}
// if no messages were received or published
// across all connection, sleep for 100ms
if (send_count == 0 && reply_count == 0) {
std::this_thread::sleep_for(std::chrono::milliseconds(100));
}
}
}
// used in the dtor for message cleanup
static void delete_message(const message_wrapper_t* message) {
delete message;
}
public:
Manager(size_t _max_connections,
size_t _max_inflight,
size_t _max_queue,
int _read_timeout_ms,
CephContext* _cct) :
max_connections(_max_connections),
max_inflight(_max_inflight),
max_queue(_max_queue),
max_idle_time(30),
connection_count(0),
stopped(false),
read_timeout_ms(_read_timeout_ms),
connections(_max_connections),
messages(max_queue),
queued(0),
dequeued(0),
cct(_cct),
runner(&Manager::run, this) {
// The hashmap has "max connections" as the initial number of buckets,
// and allows for 10 collisions per bucket before rehash.
// This is to prevent rehashing so that iterators are not invalidated
// when a new connection is added.
connections.max_load_factor(10.0);
// give the runner thread a name for easier debugging
const auto rc = ceph_pthread_setname(runner.native_handle(), "kafka_manager");
ceph_assert(rc==0);
}
// non copyable
Manager(const Manager&) = delete;
const Manager& operator=(const Manager&) = delete;
// stop the main thread
void stop() {
stopped = true;
}
// connect to a broker, or reuse an existing connection if already connected
bool connect(std::string& broker,
const std::string& url,
bool use_ssl,
bool verify_ssl,
boost::optional<const std::string&> ca_location,
boost::optional<const std::string&> mechanism) {
if (stopped) {
ldout(cct, 1) << "Kafka connect: manager is stopped" << dendl;
return false;
}
std::string user;
std::string password;
if (!parse_url_authority(url, broker, user, password)) {
// TODO: increment counter
ldout(cct, 1) << "Kafka connect: URL parsing failed" << dendl;
return false;
}
// this should be validated by the regex in parse_url()
ceph_assert(user.empty() == password.empty());
if (!user.empty() && !use_ssl && !g_conf().get_val<bool>("rgw_allow_notification_secrets_in_cleartext")) {
ldout(cct, 1) << "Kafka connect: user/password are only allowed over secure connection" << dendl;
return false;
}
std::lock_guard lock(connections_lock);
const auto it = connections.find(broker);
// note that ssl vs. non-ssl connection to the same host are two separate conenctions
if (it != connections.end()) {
// connection found - return even if non-ok
ldout(cct, 20) << "Kafka connect: connection found" << dendl;
return it->second.get();
}
// connection not found, creating a new one
if (connection_count >= max_connections) {
// TODO: increment counter
ldout(cct, 1) << "Kafka connect: max connections exceeded" << dendl;
return false;
}
// create_connection must always return a connection object
// even if error occurred during creation.
// in such a case the creation will be retried in the main thread
++connection_count;
ldout(cct, 10) << "Kafka connect: new connection is created. Total connections: " << connection_count << dendl;
auto conn = connections.emplace(broker, std::make_unique<connection_t>(cct, broker, use_ssl, verify_ssl, ca_location, user, password, mechanism)).first->second.get();
if (!new_producer(conn)) {
ldout(cct, 10) << "Kafka connect: new connection is created. But producer creation failed. will retry" << dendl;
}
return true;
}
// TODO publish with confirm is needed in "none" case as well, cb should be invoked publish is ok (no ack)
int publish(const std::string& conn_name,
const std::string& topic,
const std::string& message) {
if (stopped) {
return STATUS_MANAGER_STOPPED;
}
if (messages.push(new message_wrapper_t(conn_name, topic, message, nullptr))) {
++queued;
return STATUS_OK;
}
return STATUS_QUEUE_FULL;
}
int publish_with_confirm(const std::string& conn_name,
const std::string& topic,
const std::string& message,
reply_callback_t cb) {
if (stopped) {
return STATUS_MANAGER_STOPPED;
}
if (messages.push(new message_wrapper_t(conn_name, topic, message, cb))) {
++queued;
return STATUS_OK;
}
return STATUS_QUEUE_FULL;
}
// dtor wait for thread to stop
// then connection are cleaned-up
~Manager() {
stopped = true;
runner.join();
messages.consume_all(delete_message);
}
// get the number of connections
size_t get_connection_count() const {
return connection_count;
}
// get the number of in-flight messages
size_t get_inflight() const {
size_t sum = 0;
std::lock_guard lock(connections_lock);
std::for_each(connections.begin(), connections.end(), [&sum](auto& conn_pair) {
sum += conn_pair.second->callbacks.size();
});
return sum;
}
// running counter of the queued messages
size_t get_queued() const {
return queued;
}
// running counter of the dequeued messages
size_t get_dequeued() const {
return dequeued;
}
};
// singleton manager
// note that the manager itself is not a singleton, and multiple instances may co-exist
// TODO make the pointer atomic in allocation and deallocation to avoid race conditions
static Manager* s_manager = nullptr;
static const size_t MAX_CONNECTIONS_DEFAULT = 256;
static const size_t MAX_INFLIGHT_DEFAULT = 8192;
static const size_t MAX_QUEUE_DEFAULT = 8192;
static const int READ_TIMEOUT_MS_DEFAULT = 500;
bool init(CephContext* cct) {
if (s_manager) {
return false;
}
// TODO: take conf from CephContext
s_manager = new Manager(MAX_CONNECTIONS_DEFAULT, MAX_INFLIGHT_DEFAULT, MAX_QUEUE_DEFAULT, READ_TIMEOUT_MS_DEFAULT, cct);
return true;
}
void shutdown() {
delete s_manager;
s_manager = nullptr;
}
bool connect(std::string& broker, const std::string& url, bool use_ssl, bool verify_ssl,
boost::optional<const std::string&> ca_location,
boost::optional<const std::string&> mechanism) {
if (!s_manager) return false;
return s_manager->connect(broker, url, use_ssl, verify_ssl, ca_location, mechanism);
}
int publish(const std::string& conn_name,
const std::string& topic,
const std::string& message) {
if (!s_manager) return STATUS_MANAGER_STOPPED;
return s_manager->publish(conn_name, topic, message);
}
int publish_with_confirm(const std::string& conn_name,
const std::string& topic,
const std::string& message,
reply_callback_t cb) {
if (!s_manager) return STATUS_MANAGER_STOPPED;
return s_manager->publish_with_confirm(conn_name, topic, message, cb);
}
size_t get_connection_count() {
if (!s_manager) return 0;
return s_manager->get_connection_count();
}
size_t get_inflight() {
if (!s_manager) return 0;
return s_manager->get_inflight();
}
size_t get_queued() {
if (!s_manager) return 0;
return s_manager->get_queued();
}
size_t get_dequeued() {
if (!s_manager) return 0;
return s_manager->get_dequeued();
}
size_t get_max_connections() {
if (!s_manager) return MAX_CONNECTIONS_DEFAULT;
return s_manager->max_connections;
}
size_t get_max_inflight() {
if (!s_manager) return MAX_INFLIGHT_DEFAULT;
return s_manager->max_inflight;
}
size_t get_max_queue() {
if (!s_manager) return MAX_QUEUE_DEFAULT;
return s_manager->max_queue;
}
} // namespace kafka
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