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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_amqp.h"
#include <amqp.h>
#include <amqp_ssl_socket.h>
#include <amqp_tcp_socket.h>
#include <amqp_framing.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 <boost/functional/hash.hpp>
#include "common/dout.h"
#include <openssl/ssl.h>
#define dout_subsys ceph_subsys_rgw
// TODO investigation, not necessarily issues:
// (1) in case of single threaded writer context use spsc_queue
// (2) support multiple channels
// (3) check performance of emptying queue to local list, and go over the list and publish
// (4) use std::shared_mutex (c++17) or equivalent for the connections lock
namespace rgw::amqp {
// RGW AMQP status codes for publishing
static const int RGW_AMQP_STATUS_BROKER_NACK = -0x1001;
static const int RGW_AMQP_STATUS_CONNECTION_CLOSED = -0x1002;
static const int RGW_AMQP_STATUS_QUEUE_FULL = -0x1003;
static const int RGW_AMQP_STATUS_MAX_INFLIGHT = -0x1004;
static const int RGW_AMQP_STATUS_MANAGER_STOPPED = -0x1005;
// RGW AMQP status code for connection opening
static const int RGW_AMQP_STATUS_CONN_ALLOC_FAILED = -0x2001;
static const int RGW_AMQP_STATUS_SOCKET_ALLOC_FAILED = -0x2002;
static const int RGW_AMQP_STATUS_SOCKET_OPEN_FAILED = -0x2003;
static const int RGW_AMQP_STATUS_LOGIN_FAILED = -0x2004;
static const int RGW_AMQP_STATUS_CHANNEL_OPEN_FAILED = -0x2005;
static const int RGW_AMQP_STATUS_VERIFY_EXCHANGE_FAILED = -0x2006;
static const int RGW_AMQP_STATUS_Q_DECLARE_FAILED = -0x2007;
static const int RGW_AMQP_STATUS_CONFIRM_DECLARE_FAILED = -0x2008;
static const int RGW_AMQP_STATUS_CONSUME_DECLARE_FAILED = -0x2009;
static const int RGW_AMQP_STATUS_SOCKET_CACERT_FAILED = -0x2010;
static const int RGW_AMQP_RESPONSE_SOCKET_ERROR = -0x3008;
static const int RGW_AMQP_NO_REPLY_CODE = 0x0;
// the amqp_connection_info struct does not hold any memory and just points to the URL string
// so, strings are copied into connection_id_t
connection_id_t::connection_id_t(const amqp_connection_info& info, const std::string& _exchange)
: host(info.host), port(info.port), vhost(info.vhost), exchange(_exchange), ssl(info.ssl) {}
// equality operator and hasher functor are needed
// so that connection_id_t could be used as key in unordered_map
bool operator==(const connection_id_t& lhs, const connection_id_t& rhs) {
return lhs.host == rhs.host && lhs.port == rhs.port &&
lhs.vhost == rhs.vhost && lhs.exchange == rhs.exchange;
}
struct connection_id_hasher {
std::size_t operator()(const connection_id_t& k) const {
std::size_t h = 0;
boost::hash_combine(h, k.host);
boost::hash_combine(h, k.port);
boost::hash_combine(h, k.vhost);
boost::hash_combine(h, k.exchange);
return h;
}
};
std::string to_string(const connection_id_t& id) {
return fmt::format("{}://{}:{}{}?exchange={}",
id.ssl ? "amqps" : "amqp",
id.host, id.port, id.vhost, id.exchange);
}
// automatically cleans amqp state when gets out of scope
class ConnectionCleaner {
private:
amqp_connection_state_t state;
public:
ConnectionCleaner(amqp_connection_state_t _state) : state(_state) {}
~ConnectionCleaner() {
if (state) {
amqp_destroy_connection(state);
}
}
// call reset() if cleanup is not needed anymore
void reset() {
state = nullptr;
}
};
// 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 the exchange
struct connection_t {
CephContext* cct = nullptr;
amqp_connection_state_t state = nullptr;
amqp_bytes_t reply_to_queue = amqp_empty_bytes;
uint64_t delivery_tag = 1;
int status = AMQP_STATUS_OK;
int reply_type = AMQP_RESPONSE_NORMAL;
int reply_code = RGW_AMQP_NO_REPLY_CODE;
CallbackList callbacks;
ceph::coarse_real_clock::time_point next_reconnect = ceph::coarse_real_clock::now();
bool mandatory = false;
const bool use_ssl = false;
std::string user;
std::string password;
bool verify_ssl = true;
boost::optional<std::string> ca_location;
utime_t timestamp = ceph_clock_now();
connection_t(CephContext* _cct, const amqp_connection_info& info, bool _verify_ssl, boost::optional<const std::string&> _ca_location) :
cct(_cct), use_ssl(info.ssl), user(info.user), password(info.password), verify_ssl(_verify_ssl), ca_location(_ca_location) {}
// 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;
ConnectionCleaner clean_state(state);
state = nullptr;
amqp_bytes_free(reply_to_queue);
reply_to_queue = amqp_empty_bytes;
// fire all remaining callbacks
std::for_each(callbacks.begin(), callbacks.end(), [this](auto& cb_tag) {
cb_tag.cb(status);
ldout(cct, 20) << "AMQP destroy: invoking callback with tag=" << cb_tag.tag << dendl;
});
callbacks.clear();
delivery_tag = 1;
}
bool is_ok() const {
return (state != nullptr);
}
// dtor also destroys the internals
~connection_t() {
destroy(RGW_AMQP_STATUS_CONNECTION_CLOSED);
}
};
// convert connection info to string
std::string to_string(const amqp_connection_info& info) {
std::stringstream ss;
ss << "connection info:" <<
"\nHost: " << info.host <<
"\nPort: " << info.port <<
"\nUser: " << info.user <<
"\nPassword: " << info.password <<
"\nvhost: " << info.vhost <<
"\nSSL support: " << info.ssl << std::endl;
return ss.str();
}
// convert reply to error code
int reply_to_code(const amqp_rpc_reply_t& reply) {
switch (reply.reply_type) {
case AMQP_RESPONSE_NONE:
case AMQP_RESPONSE_NORMAL:
return RGW_AMQP_NO_REPLY_CODE;
case AMQP_RESPONSE_LIBRARY_EXCEPTION:
return reply.library_error;
case AMQP_RESPONSE_SERVER_EXCEPTION:
if (reply.reply.decoded) {
const amqp_connection_close_t* m = (amqp_connection_close_t*)reply.reply.decoded;
return m->reply_code;
}
return reply.reply.id;
}
return RGW_AMQP_NO_REPLY_CODE;
}
// convert reply to string
std::string to_string(const amqp_rpc_reply_t& reply) {
std::stringstream ss;
switch (reply.reply_type) {
case AMQP_RESPONSE_NORMAL:
return "";
case AMQP_RESPONSE_NONE:
return "missing RPC reply type";
case AMQP_RESPONSE_LIBRARY_EXCEPTION:
return amqp_error_string2(reply.library_error);
case AMQP_RESPONSE_SERVER_EXCEPTION:
{
switch (reply.reply.id) {
case AMQP_CONNECTION_CLOSE_METHOD:
ss << "server connection error: ";
break;
case AMQP_CHANNEL_CLOSE_METHOD:
ss << "server channel error: ";
break;
default:
ss << "server unknown error: ";
break;
}
if (reply.reply.decoded) {
amqp_connection_close_t* m = (amqp_connection_close_t*)reply.reply.decoded;
ss << m->reply_code << " text: " << std::string((char*)m->reply_text.bytes, m->reply_text.len);
}
return ss.str();
}
default:
ss << "unknown error, method id: " << reply.reply.id;
return ss.str();
}
}
// convert status enum to string
std::string to_string(amqp_status_enum s) {
switch (s) {
case AMQP_STATUS_OK:
return "AMQP_STATUS_OK";
case AMQP_STATUS_NO_MEMORY:
return "AMQP_STATUS_NO_MEMORY";
case AMQP_STATUS_BAD_AMQP_DATA:
return "AMQP_STATUS_BAD_AMQP_DATA";
case AMQP_STATUS_UNKNOWN_CLASS:
return "AMQP_STATUS_UNKNOWN_CLASS";
case AMQP_STATUS_UNKNOWN_METHOD:
return "AMQP_STATUS_UNKNOWN_METHOD";
case AMQP_STATUS_HOSTNAME_RESOLUTION_FAILED:
return "AMQP_STATUS_HOSTNAME_RESOLUTION_FAILED";
case AMQP_STATUS_INCOMPATIBLE_AMQP_VERSION:
return "AMQP_STATUS_INCOMPATIBLE_AMQP_VERSION";
case AMQP_STATUS_CONNECTION_CLOSED:
return "AMQP_STATUS_CONNECTION_CLOSED";
case AMQP_STATUS_BAD_URL:
return "AMQP_STATUS_BAD_URL";
case AMQP_STATUS_SOCKET_ERROR:
return "AMQP_STATUS_SOCKET_ERROR";
case AMQP_STATUS_INVALID_PARAMETER:
return "AMQP_STATUS_INVALID_PARAMETER";
case AMQP_STATUS_TABLE_TOO_BIG:
return "AMQP_STATUS_TABLE_TOO_BIG";
case AMQP_STATUS_WRONG_METHOD:
return "AMQP_STATUS_WRONG_METHOD";
case AMQP_STATUS_TIMEOUT:
return "AMQP_STATUS_TIMEOUT";
case AMQP_STATUS_TIMER_FAILURE:
return "AMQP_STATUS_TIMER_FAILURE";
case AMQP_STATUS_HEARTBEAT_TIMEOUT:
return "AMQP_STATUS_HEARTBEAT_TIMEOUT";
case AMQP_STATUS_UNEXPECTED_STATE:
return "AMQP_STATUS_UNEXPECTED_STATE";
case AMQP_STATUS_SOCKET_CLOSED:
return "AMQP_STATUS_SOCKET_CLOSED";
case AMQP_STATUS_SOCKET_INUSE:
return "AMQP_STATUS_SOCKET_INUSE";
case AMQP_STATUS_BROKER_UNSUPPORTED_SASL_METHOD:
return "AMQP_STATUS_BROKER_UNSUPPORTED_SASL_METHOD";
#if AMQP_VERSION >= AMQP_VERSION_CODE(0, 8, 0, 0)
case AMQP_STATUS_UNSUPPORTED:
return "AMQP_STATUS_UNSUPPORTED";
#endif
case _AMQP_STATUS_NEXT_VALUE:
return "AMQP_STATUS_INTERNAL";
case AMQP_STATUS_TCP_ERROR:
return "AMQP_STATUS_TCP_ERROR";
case AMQP_STATUS_TCP_SOCKETLIB_INIT_ERROR:
return "AMQP_STATUS_TCP_SOCKETLIB_INIT_ERROR";
case _AMQP_STATUS_TCP_NEXT_VALUE:
return "AMQP_STATUS_INTERNAL";
case AMQP_STATUS_SSL_ERROR:
return "AMQP_STATUS_SSL_ERROR";
case AMQP_STATUS_SSL_HOSTNAME_VERIFY_FAILED:
return "AMQP_STATUS_SSL_HOSTNAME_VERIFY_FAILED";
case AMQP_STATUS_SSL_PEER_VERIFY_FAILED:
return "AMQP_STATUS_SSL_PEER_VERIFY_FAILED";
case AMQP_STATUS_SSL_CONNECTION_FAILED:
return "AMQP_STATUS_SSL_CONNECTION_FAILED";
case _AMQP_STATUS_SSL_NEXT_VALUE:
return "AMQP_STATUS_INTERNAL";
#if AMQP_VERSION >= AMQP_VERSION_CODE(0, 11, 0, 0)
case AMQP_STATUS_SSL_SET_ENGINE_FAILED:
return "AMQP_STATUS_SSL_SET_ENGINE_FAILED";
#endif
default:
return "AMQP_STATUS_UNKNOWN";
}
}
// TODO: add status_to_string on the connection object to prinf full status
// convert int status to string - including RGW specific values
std::string status_to_string(int s) {
switch (s) {
case RGW_AMQP_STATUS_BROKER_NACK:
return "RGW_AMQP_STATUS_BROKER_NACK";
case RGW_AMQP_STATUS_CONNECTION_CLOSED:
return "RGW_AMQP_STATUS_CONNECTION_CLOSED";
case RGW_AMQP_STATUS_QUEUE_FULL:
return "RGW_AMQP_STATUS_QUEUE_FULL";
case RGW_AMQP_STATUS_MAX_INFLIGHT:
return "RGW_AMQP_STATUS_MAX_INFLIGHT";
case RGW_AMQP_STATUS_MANAGER_STOPPED:
return "RGW_AMQP_STATUS_MANAGER_STOPPED";
case RGW_AMQP_STATUS_CONN_ALLOC_FAILED:
return "RGW_AMQP_STATUS_CONN_ALLOC_FAILED";
case RGW_AMQP_STATUS_SOCKET_ALLOC_FAILED:
return "RGW_AMQP_STATUS_SOCKET_ALLOC_FAILED";
case RGW_AMQP_STATUS_SOCKET_OPEN_FAILED:
return "RGW_AMQP_STATUS_SOCKET_OPEN_FAILED";
case RGW_AMQP_STATUS_LOGIN_FAILED:
return "RGW_AMQP_STATUS_LOGIN_FAILED";
case RGW_AMQP_STATUS_CHANNEL_OPEN_FAILED:
return "RGW_AMQP_STATUS_CHANNEL_OPEN_FAILED";
case RGW_AMQP_STATUS_VERIFY_EXCHANGE_FAILED:
return "RGW_AMQP_STATUS_VERIFY_EXCHANGE_FAILED";
case RGW_AMQP_STATUS_Q_DECLARE_FAILED:
return "RGW_AMQP_STATUS_Q_DECLARE_FAILED";
case RGW_AMQP_STATUS_CONFIRM_DECLARE_FAILED:
return "RGW_AMQP_STATUS_CONFIRM_DECLARE_FAILED";
case RGW_AMQP_STATUS_CONSUME_DECLARE_FAILED:
return "RGW_AMQP_STATUS_CONSUME_DECLARE_FAILED";
case RGW_AMQP_STATUS_SOCKET_CACERT_FAILED:
return "RGW_AMQP_STATUS_SOCKET_CACERT_FAILED";
}
return to_string((amqp_status_enum)s);
}
// check the result from calls and return if error (=null)
#define RETURN_ON_ERROR(C, S, OK) \
if (!OK) { \
C->status = S; \
return false; \
}
// in case of RPC calls, getting the RPC reply and return if an error is detected
#define RETURN_ON_REPLY_ERROR(C, ST, S) { \
const auto reply = amqp_get_rpc_reply(ST); \
if (reply.reply_type != AMQP_RESPONSE_NORMAL) { \
C->status = S; \
C->reply_type = reply.reply_type; \
C->reply_code = reply_to_code(reply); \
return false; \
} \
}
static const amqp_channel_t CHANNEL_ID = 1;
static const amqp_channel_t CONFIRMING_CHANNEL_ID = 2;
// utility function to create a connection, when the connection object already exists
bool new_state(connection_t* conn, const connection_id_t& conn_id) {
// state must be null at this point
ceph_assert(!conn->state);
// reset all status codes
conn->status = AMQP_STATUS_OK;
conn->reply_type = AMQP_RESPONSE_NORMAL;
conn->reply_code = RGW_AMQP_NO_REPLY_CODE;
auto state = amqp_new_connection();
if (!state) {
conn->status = RGW_AMQP_STATUS_CONN_ALLOC_FAILED;
return false;
}
// make sure that the connection state is cleaned up in case of error
ConnectionCleaner state_guard(state);
// create and open socket
amqp_socket_t *socket = nullptr;
if (conn->use_ssl) {
socket = amqp_ssl_socket_new(state);
#if AMQP_VERSION >= AMQP_VERSION_CODE(0, 10, 0, 1)
SSL_CTX* ssl_ctx = reinterpret_cast<SSL_CTX*>(amqp_ssl_socket_get_context(socket));
#else
// taken from https://github.com/alanxz/rabbitmq-c/pull/560
struct hack {
const struct amqp_socket_class_t *klass;
SSL_CTX *ctx;
};
struct hack *h = reinterpret_cast<struct hack*>(socket);
SSL_CTX* ssl_ctx = h->ctx;
#endif
// ensure system CA certificates get loaded
SSL_CTX_set_default_verify_paths(ssl_ctx);
}
else {
socket = amqp_tcp_socket_new(state);
}
if (!socket) {
conn->status = RGW_AMQP_STATUS_SOCKET_ALLOC_FAILED;
return false;
}
if (conn->use_ssl) {
if (!conn->verify_ssl) {
amqp_ssl_socket_set_verify_peer(socket, 0);
amqp_ssl_socket_set_verify_hostname(socket, 0);
}
if (conn->ca_location.has_value()) {
const auto s = amqp_ssl_socket_set_cacert(socket, conn->ca_location.get().c_str());
if (s != AMQP_STATUS_OK) {
conn->status = RGW_AMQP_STATUS_SOCKET_CACERT_FAILED;
conn->reply_code = s;
return false;
}
}
}
const auto s = amqp_socket_open(socket, conn_id.host.c_str(), conn_id.port);
if (s < 0) {
conn->status = RGW_AMQP_STATUS_SOCKET_OPEN_FAILED;
conn->reply_type = RGW_AMQP_RESPONSE_SOCKET_ERROR;
conn->reply_code = s;
return false;
}
// login to broker
const auto reply = amqp_login(state,
conn_id.vhost.c_str(),
AMQP_DEFAULT_MAX_CHANNELS,
AMQP_DEFAULT_FRAME_SIZE,
0, // no heartbeat TODO: add conf
AMQP_SASL_METHOD_PLAIN, // TODO: add other types of security
conn->user.c_str(),
conn->password.c_str());
if (reply.reply_type != AMQP_RESPONSE_NORMAL) {
conn->status = RGW_AMQP_STATUS_LOGIN_FAILED;
conn->reply_type = reply.reply_type;
conn->reply_code = reply_to_code(reply);
return false;
}
// open channels
{
const auto ok = amqp_channel_open(state, CHANNEL_ID);
RETURN_ON_ERROR(conn, RGW_AMQP_STATUS_CHANNEL_OPEN_FAILED, ok);
RETURN_ON_REPLY_ERROR(conn, state, RGW_AMQP_STATUS_CHANNEL_OPEN_FAILED);
}
{
const auto ok = amqp_channel_open(state, CONFIRMING_CHANNEL_ID);
RETURN_ON_ERROR(conn, RGW_AMQP_STATUS_CHANNEL_OPEN_FAILED, ok);
RETURN_ON_REPLY_ERROR(conn, state, RGW_AMQP_STATUS_CHANNEL_OPEN_FAILED);
}
{
const auto ok = amqp_confirm_select(state, CONFIRMING_CHANNEL_ID);
RETURN_ON_ERROR(conn, RGW_AMQP_STATUS_CONFIRM_DECLARE_FAILED, ok);
RETURN_ON_REPLY_ERROR(conn, state, RGW_AMQP_STATUS_CONFIRM_DECLARE_FAILED);
}
// verify that the topic exchange is there
// TODO: make this step optional
{
const auto ok = amqp_exchange_declare(state,
CHANNEL_ID,
amqp_cstring_bytes(conn_id.exchange.c_str()),
amqp_cstring_bytes("topic"),
1, // passive - exchange must already exist on broker
1, // durable
0, // dont auto-delete
0, // not internal
amqp_empty_table);
RETURN_ON_ERROR(conn, RGW_AMQP_STATUS_VERIFY_EXCHANGE_FAILED, ok);
RETURN_ON_REPLY_ERROR(conn, state, RGW_AMQP_STATUS_VERIFY_EXCHANGE_FAILED);
}
{
// create queue for confirmations
const auto queue_ok = amqp_queue_declare(state,
CHANNEL_ID, // use the regular channel for this call
amqp_empty_bytes, // let broker allocate queue name
0, // not passive - create the queue
0, // not durable
1, // exclusive
1, // auto-delete
amqp_empty_table // not args TODO add args from conf: TTL, max length etc.
);
RETURN_ON_ERROR(conn, RGW_AMQP_STATUS_Q_DECLARE_FAILED, queue_ok);
RETURN_ON_REPLY_ERROR(conn, state, RGW_AMQP_STATUS_Q_DECLARE_FAILED);
// define consumption for connection
const auto consume_ok = amqp_basic_consume(state,
CONFIRMING_CHANNEL_ID,
queue_ok->queue,
amqp_empty_bytes, // broker will generate consumer tag
1, // messages sent from client are never routed back
1, // client does not ack thr acks
1, // exclusive access to queue
amqp_empty_table // no parameters
);
RETURN_ON_ERROR(conn, RGW_AMQP_STATUS_CONSUME_DECLARE_FAILED, consume_ok);
RETURN_ON_REPLY_ERROR(conn, state, RGW_AMQP_STATUS_CONSUME_DECLARE_FAILED);
// broker generated consumer_tag could be used to cancel sending of n/acks from broker - not needed
state_guard.reset();
conn->state = state;
conn->reply_to_queue = amqp_bytes_malloc_dup(queue_ok->queue);
}
return true;
}
/// struct used for holding messages in the message queue
struct message_wrapper_t {
connection_id_t conn_id;
std::string topic;
std::string message;
reply_callback_t cb;
message_wrapper_t(const connection_id_t& _conn_id,
const std::string& _topic,
const std::string& _message,
reply_callback_t _cb) : conn_id(_conn_id), topic(_topic), message(_message), cb(_cb) {}
};
using connection_t_ptr = std::unique_ptr<connection_t>;
typedef std::unordered_map<connection_id_t, connection_t_ptr, connection_id_hasher> ConnectionList;
typedef boost::lockfree::queue<message_wrapper_t*, boost::lockfree::fixed_sized<true>> MessageQueue;
// macros used inside a loop where an iterator is either incremented or erased
#define INCREMENT_AND_CONTINUE(IT) \
++IT; \
continue;
#define ERASE_AND_CONTINUE(IT,CONTAINER) \
IT=CONTAINER.erase(IT); \
--connection_count; \
continue;
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;
std::atomic<bool> stopped;
struct timeval read_timeout;
ConnectionList connections;
MessageQueue messages;
std::atomic<size_t> queued;
std::atomic<size_t> dequeued;
CephContext* const cct;
mutable std::mutex connections_lock;
const ceph::coarse_real_clock::duration idle_time;
const ceph::coarse_real_clock::duration reconnect_time;
std::thread runner;
void publish_internal(message_wrapper_t* message) {
const std::unique_ptr<message_wrapper_t> msg_owner(message);
const auto& conn_id = message->conn_id;
auto conn_it = connections.find(conn_id);
if (conn_it == connections.end()) {
ldout(cct, 1) << "AMQP publish: connection '" << to_string(conn_id) << "' not found" << dendl;
if (message->cb) {
message->cb(RGW_AMQP_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
ldout(cct, 1) << "AMQP publish: connection '" << to_string(conn_id) << "' is closed" << dendl;
if (message->cb) {
message->cb(RGW_AMQP_STATUS_CONNECTION_CLOSED);
}
return;
}
if (message->cb == nullptr) {
const auto rc = amqp_basic_publish(conn->state,
CHANNEL_ID,
amqp_cstring_bytes(conn_id.exchange.c_str()),
amqp_cstring_bytes(message->topic.c_str()),
0, // does not have to be routable
0, // not immediate
nullptr, // no properties needed
amqp_cstring_bytes(message->message.c_str()));
if (rc == AMQP_STATUS_OK) {
ldout(cct, 20) << "AMQP publish (no callback): OK" << dendl;
return;
}
ldout(cct, 1) << "AMQP publish (no callback): failed with error " << status_to_string(rc) << dendl;
// an error occurred, close connection
// it will be retied by the main loop
conn->destroy(rc);
return;
}
amqp_basic_properties_t props;
props._flags =
AMQP_BASIC_DELIVERY_MODE_FLAG |
AMQP_BASIC_REPLY_TO_FLAG;
props.delivery_mode = 2; // persistent delivery TODO take from conf
props.reply_to = conn->reply_to_queue;
const auto rc = amqp_basic_publish(conn->state,
CONFIRMING_CHANNEL_ID,
amqp_cstring_bytes(conn_id.exchange.c_str()),
amqp_cstring_bytes(message->topic.c_str()),
conn->mandatory,
0, // not immediate
&props,
amqp_cstring_bytes(message->message.c_str()));
if (rc == AMQP_STATUS_OK) {
auto const q_len = conn->callbacks.size();
if (q_len < max_inflight) {
ldout(cct, 20) << "AMQP publish (with callback, tag=" << conn->delivery_tag << "): OK. Queue has: " << q_len << " callbacks" << dendl;
conn->callbacks.emplace_back(conn->delivery_tag++, message->cb);
} else {
// immediately invoke callback with error
ldout(cct, 1) << "AMQP publish (with callback): failed with error: callback queue full" << dendl;
message->cb(RGW_AMQP_STATUS_MAX_INFLIGHT);
}
} else {
// an error occurred, close connection
// it will be retied by the main loop
ldout(cct, 1) << "AMQP publish (with callback): failed with error: " << status_to_string(rc) << dendl;
conn->destroy(rc);
// immediately invoke callback with error
message->cb(rc);
}
}
// 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 {
amqp_frame_t frame;
while (!stopped) {
// publish all messages in the queue
const auto count = messages.consume_all(std::bind(&Manager::publish_internal, this, std::placeholders::_1));
dequeued += 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();
}
auto incoming_message = false;
// loop over all connections to read acks
for (;conn_it != end_it;) {
const auto& conn_id = conn_it->first;
auto& conn = conn_it->second;
if(conn->timestamp.sec() + max_idle_time < ceph_clock_now()) {
ldout(cct, 20) << "AMQP run: Time for deleting a connection due to idle behaviour: " << ceph_clock_now() << dendl;
ERASE_AND_CONTINUE(conn_it, connections);
}
// try to reconnect the connection if it has an error
if (!conn->is_ok()) {
const auto now = ceph::coarse_real_clock::now();
if (now >= conn->next_reconnect) {
// pointers are used temporarily inside the amqp_connection_info object
// as read-only values, hence the assignment, and const_cast are safe here
ldout(cct, 20) << "AMQP run: retry connection" << dendl;
if (!new_state(conn.get(), conn_id)) {
ldout(cct, 10) << "AMQP run: connection '" << to_string(conn_id) << "' retry failed. error: " <<
status_to_string(conn->status) << " (" << conn->reply_code << ")" << dendl;
// TODO: add error counter for failed retries
// TODO: add exponential backoff for retries
conn->next_reconnect = now + reconnect_time;
} else {
ldout(cct, 10) << "AMQP run: connection '" << to_string(conn_id) << "' retry successfull" << dendl;
}
}
INCREMENT_AND_CONTINUE(conn_it);
}
const auto rc = amqp_simple_wait_frame_noblock(conn->state, &frame, &read_timeout);
if (rc == AMQP_STATUS_TIMEOUT) {
// TODO mark connection as idle
INCREMENT_AND_CONTINUE(conn_it);
}
// this is just to prevent spinning idle, does not indicate that a message
// was successfully processed or not
incoming_message = true;
// check if error occurred that require reopening the connection
if (rc != AMQP_STATUS_OK) {
// an error occurred, close connection
// it will be retied by the main loop
ldout(cct, 1) << "AMQP run: connection read error: " << status_to_string(rc) << dendl;
conn->destroy(rc);
INCREMENT_AND_CONTINUE(conn_it);
}
if (frame.frame_type != AMQP_FRAME_METHOD) {
ldout(cct, 10) << "AMQP run: ignoring non n/ack messages. frame type: "
<< unsigned(frame.frame_type) << dendl;
// handler is for publish confirmation only - handle only method frames
INCREMENT_AND_CONTINUE(conn_it);
}
uint64_t tag;
bool multiple;
int result;
switch (frame.payload.method.id) {
case AMQP_BASIC_ACK_METHOD:
{
result = AMQP_STATUS_OK;
const auto ack = (amqp_basic_ack_t*)frame.payload.method.decoded;
ceph_assert(ack);
tag = ack->delivery_tag;
multiple = ack->multiple;
break;
}
case AMQP_BASIC_NACK_METHOD:
{
result = RGW_AMQP_STATUS_BROKER_NACK;
const auto nack = (amqp_basic_nack_t*)frame.payload.method.decoded;
ceph_assert(nack);
tag = nack->delivery_tag;
multiple = nack->multiple;
break;
}
case AMQP_BASIC_REJECT_METHOD:
{
result = RGW_AMQP_STATUS_BROKER_NACK;
const auto reject = (amqp_basic_reject_t*)frame.payload.method.decoded;
tag = reject->delivery_tag;
multiple = false;
break;
}
case AMQP_CONNECTION_CLOSE_METHOD:
// TODO on channel close, no need to reopen the connection
case AMQP_CHANNEL_CLOSE_METHOD:
{
// other side closed the connection, no need to continue
ldout(cct, 10) << "AMQP run: connection was closed by broker" << dendl;
conn->destroy(rc);
INCREMENT_AND_CONTINUE(conn_it);
}
case AMQP_BASIC_RETURN_METHOD:
// message was not delivered, returned to sender
ldout(cct, 10) << "AMQP run: message was not routable" << dendl;
INCREMENT_AND_CONTINUE(conn_it);
break;
default:
// unexpected method
ldout(cct, 10) << "AMQP run: unexpected message" << dendl;
INCREMENT_AND_CONTINUE(conn_it);
}
const auto tag_it = std::find(conn->callbacks.begin(), conn->callbacks.end(), tag);
if (tag_it != conn->callbacks.end()) {
if (multiple) {
// n/ack all up to (and including) the tag
ldout(cct, 20) << "AMQP run: multiple n/acks received with tag=" << tag << " and result=" << result << dendl;
auto it = conn->callbacks.begin();
while (it->tag <= tag && it != conn->callbacks.end()) {
ldout(cct, 20) << "AMQP run: invoking callback with tag=" << it->tag << dendl;
it->cb(result);
it = conn->callbacks.erase(it);
}
} else {
// n/ack a specific tag
ldout(cct, 20) << "AMQP run: n/ack received, invoking callback with tag=" << tag << " and result=" << result << dendl;
tag_it->cb(result);
conn->callbacks.erase(tag_it);
}
} else {
ldout(cct, 10) << "AMQP run: unsolicited n/ack received with tag=" << tag << dendl;
}
// just increment the iterator
++conn_it;
}
// if no messages were received or published, sleep for 100ms
if (count == 0 && !incoming_message) {
std::this_thread::sleep_for(idle_time);
}
}
}
// 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,
long _usec_timeout,
unsigned reconnect_time_ms,
unsigned idle_time_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{0, _usec_timeout},
connections(_max_connections),
messages(max_queue),
queued(0),
dequeued(0),
cct(_cct),
idle_time(std::chrono::milliseconds(idle_time_ms)),
reconnect_time(std::chrono::milliseconds(reconnect_time_ms)),
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(), "amqp_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(connection_id_t& id, const std::string& url, const std::string& exchange, bool mandatory_delivery, bool verify_ssl,
boost::optional<const std::string&> ca_location) {
if (stopped) {
ldout(cct, 1) << "AMQP connect: manager is stopped" << dendl;
return false;
}
amqp_connection_info info;
// cache the URL so that parsing could happen in-place
std::vector<char> url_cache(url.c_str(), url.c_str()+url.size()+1);
const auto retcode = amqp_parse_url(url_cache.data(), &info);
if (AMQP_STATUS_OK != retcode) {
ldout(cct, 1) << "AMQP connect: URL parsing failed. error: " << retcode << dendl;
return false;
}
connection_id_t tmp_id(info, exchange);
std::lock_guard lock(connections_lock);
const auto it = connections.find(tmp_id);
if (it != connections.end()) {
// connection found - return even if non-ok
ldout(cct, 20) << "AMQP connect: connection found" << dendl;
id = it->first;
return true;
}
// connection not found, creating a new one
if (connection_count >= max_connections) {
ldout(cct, 1) << "AMQP connect: max connections exceeded" << dendl;
return false;
}
// if error occurred during creation the creation will be retried in the main thread
++connection_count;
auto conn = connections.emplace(tmp_id, std::make_unique<connection_t>(cct, info, verify_ssl, ca_location)).first->second.get();
ldout(cct, 10) << "AMQP connect: new connection is created. Total connections: " << connection_count << dendl;
if (!new_state(conn, tmp_id)) {
ldout(cct, 1) << "AMQP connect: new connection '" << to_string(tmp_id) << "' is created. but state creation failed (will retry). error: " <<
status_to_string(conn->status) << " (" << conn->reply_code << ")" << dendl;
}
id = std::move(tmp_id);
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 connection_id_t& conn_id,
const std::string& topic,
const std::string& message) {
if (stopped) {
ldout(cct, 1) << "AMQP publish: manager is not running" << dendl;
return RGW_AMQP_STATUS_MANAGER_STOPPED;
}
auto wrapper = std::make_unique<message_wrapper_t>(conn_id, topic, message, nullptr);
if (messages.push(wrapper.get())) {
std::ignore = wrapper.release();
++queued;
return AMQP_STATUS_OK;
}
ldout(cct, 1) << "AMQP publish: queue is full" << dendl;
return RGW_AMQP_STATUS_QUEUE_FULL;
}
int publish_with_confirm(const connection_id_t& conn_id,
const std::string& topic,
const std::string& message,
reply_callback_t cb) {
if (stopped) {
ldout(cct, 1) << "AMQP publish_with_confirm: manager is not running" << dendl;
return RGW_AMQP_STATUS_MANAGER_STOPPED;
}
auto wrapper = std::make_unique<message_wrapper_t>(conn_id, topic, message, cb);
if (messages.push(wrapper.get())) {
std::ignore = wrapper.release();
++queued;
return AMQP_STATUS_OK;
}
ldout(cct, 1) << "AMQP publish_with_confirm: queue is full" << dendl;
return RGW_AMQP_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) {
// concurrent access to the callback vector is safe without locking
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 long READ_TIMEOUT_USEC = 100;
static const unsigned IDLE_TIME_MS = 100;
static const unsigned RECONNECT_TIME_MS = 100;
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_USEC, IDLE_TIME_MS, RECONNECT_TIME_MS, cct);
return true;
}
void shutdown() {
delete s_manager;
s_manager = nullptr;
}
bool connect(connection_id_t& conn_id, const std::string& url, const std::string& exchange, bool mandatory_delivery, bool verify_ssl,
boost::optional<const std::string&> ca_location) {
if (!s_manager) return false;
return s_manager->connect(conn_id, url, exchange, mandatory_delivery, verify_ssl, ca_location);
}
int publish(const connection_id_t& conn_id,
const std::string& topic,
const std::string& message) {
if (!s_manager) return RGW_AMQP_STATUS_MANAGER_STOPPED;
return s_manager->publish(conn_id, topic, message);
}
int publish_with_confirm(const connection_id_t& conn_id,
const std::string& topic,
const std::string& message,
reply_callback_t cb) {
if (!s_manager) return RGW_AMQP_STATUS_MANAGER_STOPPED;
return s_manager->publish_with_confirm(conn_id, 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 amqp
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