X-Git-Url: https://git.sesse.net/?p=cubemap;a=blobdiff_plain;f=server.cpp;h=7f07483390a8b2846013e594668831b48d5b884b;hp=a0a32f8e704a716cad99563cd75b4bc47cfeb41b;hb=b10d63c534fda113e65e24d252e509e616067ef9;hpb=3fd8650ccf3da3960a946d8ac9abc305aec399ce diff --git a/server.cpp b/server.cpp index a0a32f8..7f07483 100644 --- a/server.cpp +++ b/server.cpp @@ -17,10 +17,12 @@ #include #include +#include "tlse.h" + +#include "acceptor.h" #include "accesslog.h" #include "log.h" -#include "markpool.h" -#include "metacube.h" +#include "metacube2.h" #include "mutexlock.h" #include "parse.h" #include "server.h" @@ -28,14 +30,35 @@ #include "stream.h" #include "util.h" +#ifndef SO_MAX_PACING_RATE +#define SO_MAX_PACING_RATE 47 +#endif + using namespace std; extern AccessLogThread *access_log; +namespace { + +inline bool is_equal(timespec a, timespec b) +{ + return a.tv_sec == b.tv_sec && + a.tv_nsec == b.tv_nsec; +} + +inline bool is_earlier(timespec a, timespec b) +{ + if (a.tv_sec != b.tv_sec) + return a.tv_sec < b.tv_sec; + return a.tv_nsec < b.tv_nsec; +} + +} // namespace + Server::Server() { pthread_mutex_init(&mutex, NULL); - pthread_mutex_init(&queued_data_mutex, NULL); + pthread_mutex_init(&queued_clients_mutex, NULL); epoll_fd = epoll_create(1024); // Size argument is ignored. if (epoll_fd == -1) { @@ -46,10 +69,8 @@ Server::Server() Server::~Server() { - for (map::iterator stream_it = streams.begin(); - stream_it != streams.end(); - ++stream_it) { - delete stream_it->second; + for (size_t i = 0; i < streams.size(); ++i) { + delete streams[i]; } safe_close(epoll_fd); @@ -72,8 +93,14 @@ void Server::do_work() { while (!should_stop()) { // Wait until there's activity on at least one of the fds, - // or we are waken up due to new queued clients or data. - int nfds = epoll_pwait(epoll_fd, events, EPOLL_MAX_EVENTS, -1, &sigset_without_usr1_block); + // or 20 ms (about one frame at 50 fps) has elapsed. + // + // We could in theory wait forever and rely on wakeup() + // from add_client_deferred() and add_data_deferred(), + // but wakeup is a pretty expensive operation, and the + // two threads might end up fighting over a lock, so it's + // seemingly (much) more efficient to just have a timeout here. + int nfds = epoll_pwait(epoll_fd, events, EPOLL_MAX_EVENTS, EPOLL_TIMEOUT_MS, &sigset_without_usr1_block); if (nfds == -1 && errno != EINTR) { log_perror("epoll_wait"); exit(1); @@ -83,6 +110,7 @@ void Server::do_work() process_queued_data(); + // Process each client where we have socket activity. for (int i = 0; i < nfds; ++i) { Client *client = reinterpret_cast(events[i].data.u64); @@ -94,15 +122,58 @@ void Server::do_work() process_client(client); } - for (map::iterator stream_it = streams.begin(); - stream_it != streams.end(); - ++stream_it) { + // Process each client where its stream has new data, + // even if there was no socket activity. + for (size_t i = 0; i < streams.size(); ++i) { vector to_process; - swap(stream_it->second->to_process, to_process); + swap(streams[i]->to_process, to_process); for (size_t i = 0; i < to_process.size(); ++i) { process_client(to_process[i]); } } + + // Finally, go through each client to see if it's timed out + // in the READING_REQUEST state. (Seemingly there are clients + // that can hold sockets up for days at a time without sending + // anything at all.) + timespec timeout_time; + if (clock_gettime(CLOCK_MONOTONIC_COARSE, &timeout_time) == -1) { + log_perror("clock_gettime(CLOCK_MONOTONIC_COARSE)"); + continue; + } + timeout_time.tv_sec -= REQUEST_READ_TIMEOUT_SEC; + while (!clients_ordered_by_connect_time.empty()) { + const pair &connect_time_and_fd = clients_ordered_by_connect_time.front(); + + // See if we have reached the end of clients to process. + if (is_earlier(timeout_time, connect_time_and_fd.first)) { + break; + } + + // If this client doesn't exist anymore, just ignore it + // (it was deleted earlier). + map::iterator client_it = clients.find(connect_time_and_fd.second); + if (client_it == clients.end()) { + clients_ordered_by_connect_time.pop(); + continue; + } + Client *client = &client_it->second; + if (!is_equal(client->connect_time, connect_time_and_fd.first)) { + // Another client has taken this fd in the meantime. + clients_ordered_by_connect_time.pop(); + continue; + } + + if (client->state != Client::READING_REQUEST) { + // Only READING_REQUEST can time out. + clients_ordered_by_connect_time.pop(); + continue; + } + + // OK, it timed out. + close_client(client); + clients_ordered_by_connect_time.pop(); + } } } @@ -111,43 +182,84 @@ CubemapStateProto Server::serialize() // We don't serialize anything queued, so empty the queues. process_queued_data(); + // Set all clients in a consistent state before serializing + // (ie., they have no remaining lost data). Otherwise, increasing + // the backlog could take clients into a newly valid area of the backlog, + // sending a stream of zeros instead of skipping the data as it should. + // + // TODO: Do this when clients are added back from serialized state instead; + // it would probably be less wasteful. + for (map::iterator client_it = clients.begin(); + client_it != clients.end(); + ++client_it) { + skip_lost_data(&client_it->second); + } + CubemapStateProto serialized; for (map::const_iterator client_it = clients.begin(); client_it != clients.end(); ++client_it) { serialized.add_clients()->MergeFrom(client_it->second.serialize()); } - for (map::const_iterator stream_it = streams.begin(); - stream_it != streams.end(); - ++stream_it) { - serialized.add_streams()->MergeFrom(stream_it->second->serialize()); + for (size_t i = 0; i < streams.size(); ++i) { + serialized.add_streams()->MergeFrom(streams[i]->serialize()); } return serialized; } -void Server::add_client_deferred(int sock) +void Server::add_client_deferred(int sock, Acceptor *acceptor) { - MutexLock lock(&queued_data_mutex); - queued_add_clients.push_back(sock); - wakeup(); + MutexLock lock(&queued_clients_mutex); + queued_add_clients.push_back(std::make_pair(sock, acceptor)); } -void Server::add_client(int sock) +void Server::add_client(int sock, Acceptor *acceptor) { + const bool is_tls = acceptor->is_tls(); pair::iterator, bool> ret = clients.insert(make_pair(sock, Client(sock))); assert(ret.second == true); // Should not already exist. Client *client_ptr = &ret.first->second; + // Connection timestamps must be nondecreasing. I can't find any guarantee + // that even the monotonic clock can't go backwards by a small amount + // (think switching between CPUs with non-synchronized TSCs), so if + // this actually should happen, we hack around it by fudging + // connect_time. + if (!clients_ordered_by_connect_time.empty() && + is_earlier(client_ptr->connect_time, clients_ordered_by_connect_time.back().first)) { + client_ptr->connect_time = clients_ordered_by_connect_time.back().first; + } + clients_ordered_by_connect_time.push(make_pair(client_ptr->connect_time, sock)); + // Start listening on data from this socket. epoll_event ev; - ev.events = EPOLLIN | EPOLLET | EPOLLRDHUP; + if (is_tls) { + // Even in the initial state (READING_REQUEST), TLS needs to + // send data for the handshake, and thus might end up needing + // to know about EPOLLOUT. + ev.events = EPOLLIN | EPOLLOUT | EPOLLET | EPOLLRDHUP; + } else { + // EPOLLOUT will be added once we go out of READING_REQUEST. + ev.events = EPOLLIN | EPOLLET | EPOLLRDHUP; + } ev.data.u64 = reinterpret_cast(client_ptr); if (epoll_ctl(epoll_fd, EPOLL_CTL_ADD, sock, &ev) == -1) { log_perror("epoll_ctl(EPOLL_CTL_ADD)"); exit(1); } + if (is_tls) { + assert(tls_server_contexts.count(acceptor)); + client_ptr->tls_context = tls_accept(tls_server_contexts[acceptor]); + if (client_ptr->tls_context == NULL) { + log(ERROR, "tls_accept() failed"); + close_client(client_ptr); + return; + } + tls_make_exportable(client_ptr->tls_context, 1); + } + process_client(client_ptr); } @@ -155,98 +267,162 @@ void Server::add_client_from_serialized(const ClientProto &client) { MutexLock lock(&mutex); Stream *stream; - map::iterator stream_it = streams.find(client.stream_id()); - if (stream_it == streams.end()) { + int stream_index = lookup_stream_by_url(client.url()); + if (stream_index == -1) { + assert(client.state() != Client::SENDING_DATA); stream = NULL; } else { - stream = stream_it->second; + stream = streams[stream_index]; } pair::iterator, bool> ret = clients.insert(make_pair(client.sock(), Client(client, stream))); assert(ret.second == true); // Should not already exist. Client *client_ptr = &ret.first->second; + // Connection timestamps must be nondecreasing. + assert(clients_ordered_by_connect_time.empty() || + !is_earlier(client_ptr->connect_time, clients_ordered_by_connect_time.back().first)); + clients_ordered_by_connect_time.push(make_pair(client_ptr->connect_time, client.sock())); + // Start listening on data from this socket. epoll_event ev; if (client.state() == Client::READING_REQUEST) { - ev.events = EPOLLIN | EPOLLET | EPOLLRDHUP; + // See the corresponding comment in Server::add_client(). + if (client.has_tls_context()) { + ev.events = EPOLLIN | EPOLLOUT | EPOLLET | EPOLLRDHUP; + } else { + ev.events = EPOLLIN | EPOLLET | EPOLLRDHUP; + } } else { // If we don't have more data for this client, we'll be putting it into // the sleeping array again soon. ev.events = EPOLLOUT | EPOLLET | EPOLLRDHUP; } - ev.data.u64 = 0; // Keep Valgrind happy. ev.data.u64 = reinterpret_cast(client_ptr); if (epoll_ctl(epoll_fd, EPOLL_CTL_ADD, client.sock(), &ev) == -1) { log_perror("epoll_ctl(EPOLL_CTL_ADD)"); exit(1); } - if (client_ptr->state == Client::SENDING_DATA && - client_ptr->stream_pos == client_ptr->stream->bytes_received) { + if (client_ptr->state == Client::WAITING_FOR_KEYFRAME || + client_ptr->state == Client::PREBUFFERING || + (client_ptr->state == Client::SENDING_DATA && + client_ptr->stream_pos == client_ptr->stream->bytes_received)) { client_ptr->stream->put_client_to_sleep(client_ptr); } else { process_client(client_ptr); } } -void Server::add_stream(const string &stream_id, size_t backlog_size, Stream::Encoding encoding) +int Server::lookup_stream_by_url(const string &url) const +{ + map::const_iterator stream_url_it = stream_url_map.find(url); + if (stream_url_it == stream_url_map.end()) { + return -1; + } + return stream_url_it->second; +} + +int Server::add_stream(const string &url, size_t backlog_size, size_t prebuffering_bytes, Stream::Encoding encoding, Stream::Encoding src_encoding) { MutexLock lock(&mutex); - streams.insert(make_pair(stream_id, new Stream(stream_id, backlog_size, encoding))); + stream_url_map.insert(make_pair(url, streams.size())); + streams.push_back(new Stream(url, backlog_size, prebuffering_bytes, encoding, src_encoding)); + return streams.size() - 1; } -void Server::add_stream_from_serialized(const StreamProto &stream, int data_fd) +int Server::add_stream_from_serialized(const StreamProto &stream, int data_fd) { MutexLock lock(&mutex); - streams.insert(make_pair(stream.stream_id(), new Stream(stream, data_fd))); + stream_url_map.insert(make_pair(stream.url(), streams.size())); + streams.push_back(new Stream(stream, data_fd)); + return streams.size() - 1; } -void Server::set_backlog_size(const string &stream_id, size_t new_size) +void Server::set_backlog_size(int stream_index, size_t new_size) { MutexLock lock(&mutex); - assert(streams.count(stream_id) != 0); - streams[stream_id]->set_backlog_size(new_size); + assert(stream_index >= 0 && stream_index < ssize_t(streams.size())); + streams[stream_index]->set_backlog_size(new_size); } - -void Server::set_encoding(const string &stream_id, Stream::Encoding encoding) + +void Server::set_prebuffering_bytes(int stream_index, size_t new_amount) { MutexLock lock(&mutex); - assert(streams.count(stream_id) != 0); - streams[stream_id]->encoding = encoding; + assert(stream_index >= 0 && stream_index < ssize_t(streams.size())); + streams[stream_index]->prebuffering_bytes = new_amount; } -void Server::set_header(const string &stream_id, const string &http_header, const string &stream_header) +void Server::set_encoding(int stream_index, Stream::Encoding encoding) { MutexLock lock(&mutex); - find_stream(stream_id)->http_header = http_header; - find_stream(stream_id)->stream_header = stream_header; + assert(stream_index >= 0 && stream_index < ssize_t(streams.size())); + streams[stream_index]->encoding = encoding; +} - // If there are clients we haven't sent anything to yet, we should give - // them the header, so push back into the SENDING_HEADER state. - for (map::iterator client_it = clients.begin(); - client_it != clients.end(); - ++client_it) { - Client *client = &client_it->second; - if (client->state == Client::SENDING_DATA && - client->stream_pos == 0) { - construct_header(client); - } +void Server::set_src_encoding(int stream_index, Stream::Encoding encoding) +{ + MutexLock lock(&mutex); + assert(stream_index >= 0 && stream_index < ssize_t(streams.size())); + streams[stream_index]->src_encoding = encoding; +} + +void Server::set_header(int stream_index, const string &http_header, const string &stream_header) +{ + MutexLock lock(&mutex); + assert(stream_index >= 0 && stream_index < ssize_t(streams.size())); + streams[stream_index]->http_header = http_header; + + if (stream_header != streams[stream_index]->stream_header) { + // We cannot start at any of the older starting points anymore, + // since they'd get the wrong header for the stream (not to mention + // that a changed header probably means the stream restarted, + // which means any client starting on the old one would probably + // stop playing properly at the change point). Next block + // should be a suitable starting point (if not, something is + // pretty strange), so it will fill up again soon enough. + streams[stream_index]->suitable_starting_points.clear(); } + streams[stream_index]->stream_header = stream_header; } -void Server::set_mark_pool(const string &stream_id, MarkPool *mark_pool) +void Server::set_pacing_rate(int stream_index, uint32_t pacing_rate) { MutexLock lock(&mutex); assert(clients.empty()); - find_stream(stream_id)->mark_pool = mark_pool; + assert(stream_index >= 0 && stream_index < ssize_t(streams.size())); + streams[stream_index]->pacing_rate = pacing_rate; } -void Server::add_data_deferred(const string &stream_id, const char *data, size_t bytes) +void Server::add_gen204(const std::string &url, const std::string &allow_origin) { - MutexLock lock(&queued_data_mutex); - queued_data[stream_id].append(string(data, data + bytes)); - wakeup(); + MutexLock lock(&mutex); + assert(clients.empty()); + ping_url_map[url] = allow_origin; +} + +void Server::create_tls_context_for_acceptor(const Acceptor *acceptor) +{ + assert(acceptor->is_tls()); + + bool is_server = true; + TLSContext *server_context = tls_create_context(is_server, TLS_V12); + + const string &cert = acceptor->get_certificate_chain(); + int num_cert = tls_load_certificates(server_context, reinterpret_cast(cert.data()), cert.size()); + assert(num_cert > 0); // Should have been checked by config earlier. + + const string &key = acceptor->get_private_key(); + int num_key = tls_load_private_key(server_context, reinterpret_cast(key.data()), key.size()); + assert(num_key > 0); // Should have been checked by config earlier. + + tls_server_contexts.insert(make_pair(acceptor, server_context)); +} + +void Server::add_data_deferred(int stream_index, const char *data, size_t bytes, uint16_t metacube_flags) +{ + assert(stream_index >= 0 && stream_index < ssize_t(streams.size())); + streams[stream_index]->add_data_deferred(data, bytes, metacube_flags); } // See the .h file for postconditions after this function. @@ -254,28 +430,29 @@ void Server::process_client(Client *client) { switch (client->state) { case Client::READING_REQUEST: { + if (client->tls_context != NULL) { + if (send_pending_tls_data(client)) { + // send_pending_tls_data() hit postconditions #1 or #4. + return; + } + } + read_request_again: // Try to read more of the request. char buf[1024]; int ret; - do { - ret = read(client->sock, buf, sizeof(buf)); - } while (ret == -1 && errno == EINTR); - - if (ret == -1 && errno == EAGAIN) { - // No more data right now. Nothing to do. - // This is postcondition #2. - return; - } - if (ret == -1) { - log_perror("read"); - close_client(client); - return; - } - if (ret == 0) { - // OK, the socket is closed. - close_client(client); - return; + if (client->tls_context == NULL) { + ret = read_nontls_data(client, buf, sizeof(buf)); + if (ret == -1) { + // read_nontls_data() hit postconditions #1 or #2. + return; + } + } else { + ret = read_tls_data(client, buf, sizeof(buf)); + if (ret == -1) { + // read_tls_data() hit postconditions #1, #2 or #4. + return; + } } RequestParseStatus status = wait_for_double_newline(&client->request, buf, ret); @@ -299,25 +476,43 @@ read_request_again: assert(status == RP_FINISHED); + if (client->tls_context && !client->in_ktls_mode && tls_established(client->tls_context)) { + // We're ready to enter kTLS mode, unless we still have some + // handshake data to send (which then must be sent as non-kTLS). + if (send_pending_tls_data(client)) { + // send_pending_tls_data() hit postconditions #1 or #4. + return; + } + ret = tls_make_ktls(client->tls_context, client->sock); + if (ret < 0) { + log_tls_error("tls_make_ktls", ret); + close_client(client); + return; + } + client->in_ktls_mode = true; + } + int error_code = parse_request(client); if (error_code == 200) { construct_header(client); + } else if (error_code == 204) { + construct_204(client); } else { construct_error(client, error_code); } // We've changed states, so fall through. - assert(client->state == Client::SENDING_ERROR || + assert(client->state == Client::SENDING_SHORT_RESPONSE || client->state == Client::SENDING_HEADER); } - case Client::SENDING_ERROR: + case Client::SENDING_SHORT_RESPONSE: case Client::SENDING_HEADER: { -sending_header_or_error_again: +sending_header_or_short_response_again: int ret; do { ret = write(client->sock, - client->header_or_error.data() + client->header_or_error_bytes_sent, - client->header_or_error.size() - client->header_or_error_bytes_sent); + client->header_or_short_response.data() + client->header_or_short_response_bytes_sent, + client->header_or_short_response.size() - client->header_or_short_response_bytes_sent); } while (ret == -1 && errno == EINTR); if (ret == -1 && errno == EAGAIN) { @@ -335,54 +530,103 @@ sending_header_or_error_again: return; } - client->header_or_error_bytes_sent += ret; - assert(client->header_or_error_bytes_sent <= client->header_or_error.size()); + client->header_or_short_response_bytes_sent += ret; + assert(client->header_or_short_response_bytes_sent <= client->header_or_short_response.size()); - if (client->header_or_error_bytes_sent < client->header_or_error.size()) { + if (client->header_or_short_response_bytes_sent < client->header_or_short_response.size()) { // We haven't sent all yet. Fine; go another round. - goto sending_header_or_error_again; + goto sending_header_or_short_response_again; } // We're done sending the header or error! Clear it to release some memory. - client->header_or_error.clear(); + client->header_or_short_response.clear(); - if (client->state == Client::SENDING_ERROR) { + if (client->state == Client::SENDING_SHORT_RESPONSE) { // We're done sending the error, so now close. // This is postcondition #1. close_client(client); return; } - // Start sending from the end. In other words, we won't send any of the backlog, - // but we'll start sending immediately as we get data. - // This is postcondition #3. + Stream *stream = client->stream; + if (client->stream_pos == size_t(-2)) { + // Start sending from the beginning of the backlog. + client->stream_pos = min( + stream->bytes_received - stream->backlog_size, + 0); + client->state = Client::SENDING_DATA; + goto sending_data; + } else if (stream->prebuffering_bytes == 0) { + // Start sending from the first keyframe we get. In other + // words, we won't send any of the backlog, but we'll start + // sending immediately as we get the next keyframe block. + // Note that this is functionally identical to the next if branch, + // except that we save a binary search. + client->stream_pos = stream->bytes_received; + client->state = Client::WAITING_FOR_KEYFRAME; + } else { + // We're not going to send anything to the client before we have + // N bytes. However, this wait might be boring; we can just as well + // use it to send older data if we have it. We use lower_bound() + // so that we are conservative and never add extra latency over just + // waiting (assuming CBR or nearly so); otherwise, we could want e.g. + // 100 kB prebuffer but end up sending a 10 MB GOP. + deque::const_iterator starting_point_it = + lower_bound(stream->suitable_starting_points.begin(), + stream->suitable_starting_points.end(), + stream->bytes_received - stream->prebuffering_bytes); + if (starting_point_it == stream->suitable_starting_points.end()) { + // None found. Just put us at the end, and then wait for the + // first keyframe to appear. + client->stream_pos = stream->bytes_received; + client->state = Client::WAITING_FOR_KEYFRAME; + } else { + client->stream_pos = *starting_point_it; + client->state = Client::PREBUFFERING; + goto prebuffering; + } + } + // Fall through. + } + case Client::WAITING_FOR_KEYFRAME: { + Stream *stream = client->stream; + if (stream->suitable_starting_points.empty() || + client->stream_pos > stream->suitable_starting_points.back()) { + // We haven't received a keyframe since this stream started waiting, + // so keep on waiting for one. + // This is postcondition #3. + stream->put_client_to_sleep(client); + return; + } + client->stream_pos = stream->suitable_starting_points.back(); + client->state = Client::PREBUFFERING; + // Fall through. + } + case Client::PREBUFFERING: { +prebuffering: + Stream *stream = client->stream; + size_t bytes_to_send = stream->bytes_received - client->stream_pos; + assert(bytes_to_send <= stream->backlog_size); + if (bytes_to_send < stream->prebuffering_bytes) { + // We don't have enough bytes buffered to start this client yet. + // This is postcondition #3. + stream->put_client_to_sleep(client); + return; + } client->state = Client::SENDING_DATA; - client->stream_pos = client->stream->bytes_received; - client->stream->put_client_to_sleep(client); - return; + // Fall through. } case Client::SENDING_DATA: { -sending_data_again: - // See if there's some data we've lost. Ideally, we should drop to a block boundary, - // but resync will be the mux's problem. +sending_data: + skip_lost_data(client); Stream *stream = client->stream; + +sending_data_again: size_t bytes_to_send = stream->bytes_received - client->stream_pos; + assert(bytes_to_send <= stream->backlog_size); if (bytes_to_send == 0) { return; } - if (bytes_to_send > stream->backlog_size) { - size_t bytes_lost = bytes_to_send - stream->backlog_size; - client->stream_pos = stream->bytes_received - stream->backlog_size; - client->bytes_lost += bytes_lost; - ++client->num_loss_events; - bytes_to_send = stream->backlog_size; - - double loss_fraction = double(client->bytes_lost) / double(client->bytes_lost + client->bytes_sent); - log(WARNING, "[%s] Client lost %lld bytes (total loss: %.2f%%), maybe too slow connection", - client->remote_addr.c_str(), - (long long int)(bytes_lost), - 100.0 * loss_fraction); - } // See if we need to split across the circular buffer. bool more_data = false; @@ -393,7 +637,7 @@ sending_data_again: ssize_t ret; do { - loff_t offset = client->stream_pos % stream->backlog_size; + off_t offset = client->stream_pos % stream->backlog_size; ret = sendfile(client->sock, stream->data_fd, &offset, bytes_to_send); } while (ret == -1 && errno == EINTR); @@ -426,6 +670,150 @@ sending_data_again: } } +bool Server::send_pending_tls_data(Client *client) +{ + // See if there's data from the TLS library to write. + if (client->tls_data_to_send == NULL) { + client->tls_data_to_send = tls_get_write_buffer(client->tls_context, &client->tls_data_left_to_send); + if (client->tls_data_to_send == NULL) { + // Really no data to send. + return false; + } + } + +send_data_again: + int ret; + do { + ret = write(client->sock, client->tls_data_to_send, client->tls_data_left_to_send); + } while (ret == -1 && errno == EINTR); + assert(ret < 0 || size_t(ret) <= client->tls_data_left_to_send); + + if (ret == -1 && errno == EAGAIN) { + // We're out of socket space, so now we're at the “low edge” of epoll's + // edge triggering. epoll will tell us when there is more room, so for now, + // just return. + // This is postcondition #4. + return true; + } + if (ret == -1) { + // Error! Postcondition #1. + log_perror("write"); + close_client(client); + return true; + } + if (ret > 0 && size_t(ret) == client->tls_data_left_to_send) { + // All data has been sent, so we don't need to go to sleep. + tls_buffer_clear(client->tls_context); + client->tls_data_to_send = NULL; + return false; + } + + // More data to send, so try again. + client->tls_data_to_send += ret; + client->tls_data_left_to_send -= ret; + goto send_data_again; +} + +int Server::read_nontls_data(Client *client, char *buf, size_t max_size) +{ + int ret; + do { + ret = read(client->sock, buf, max_size); + } while (ret == -1 && errno == EINTR); + + if (ret == -1 && errno == EAGAIN) { + // No more data right now. Nothing to do. + // This is postcondition #2. + return -1; + } + if (ret == -1) { + log_perror("read"); + close_client(client); + return -1; + } + if (ret == 0) { + // OK, the socket is closed. + close_client(client); + return -1; + } + + return ret; +} + +int Server::read_tls_data(Client *client, char *buf, size_t max_size) +{ +read_again: + int ret; + do { + ret = read(client->sock, buf, max_size); + } while (ret == -1 && errno == EINTR); + + if (ret == -1 && errno == EAGAIN) { + // No more data right now. Nothing to do. + // This is postcondition #2. + return -1; + } + if (ret == -1) { + log_perror("read"); + close_client(client); + return -1; + } + if (ret == 0) { + // OK, the socket is closed. + close_client(client); + return -1; + } + + // Give it to the TLS library. + int err = tls_consume_stream(client->tls_context, reinterpret_cast(buf), ret, nullptr); + if (err < 0) { + log_tls_error("tls_consume_stream", err); + close_client(client); + return -1; + } + if (err == 0) { + // Not consumed any data. See if we can read more. + goto read_again; + } + + // Read any decrypted data available for us. (We can reuse buf, since it's free now.) + ret = tls_read(client->tls_context, reinterpret_cast(buf), max_size); + if (ret == 0) { + // No decrypted data for us yet, but there might be some more handshaking + // to send. Do that if needed, then look for more data. + if (send_pending_tls_data(client)) { + // send_pending_tls_data() hit postconditions #1 or #4. + return -1; + } + goto read_again; + } + if (ret < 0) { + log_tls_error("tls_read", ret); + close_client(client); + return -1; + } + + assert(ret > 0); + return ret; +} + +// See if there's some data we've lost. Ideally, we should drop to a block boundary, +// but resync will be the mux's problem. +void Server::skip_lost_data(Client *client) +{ + Stream *stream = client->stream; + if (stream == NULL) { + return; + } + size_t bytes_to_send = stream->bytes_received - client->stream_pos; + if (bytes_to_send > stream->backlog_size) { + size_t bytes_lost = bytes_to_send - stream->backlog_size; + client->stream_pos = stream->bytes_received - stream->backlog_size; + client->bytes_lost += bytes_lost; + ++client->num_loss_events; + } +} + int Server::parse_request(Client *client) { vector lines = split_lines(client->request); @@ -433,6 +821,18 @@ int Server::parse_request(Client *client) return 400; // Bad request (empty). } + // Parse the headers, for logging purposes. + // TODO: Case-insensitivity. + multimap headers = extract_headers(lines, client->remote_addr); + multimap::const_iterator referer_it = headers.find("Referer"); + if (referer_it != headers.end()) { + client->referer = referer_it->second; + } + multimap::const_iterator user_agent_it = headers.find("User-Agent"); + if (user_agent_it != headers.end()) { + client->user_agent = user_agent_it->second; + } + vector request_tokens = split_tokens(lines[0]); if (request_tokens.size() < 2) { return 400; // Bad request (empty). @@ -440,20 +840,35 @@ int Server::parse_request(Client *client) if (request_tokens[0] != "GET") { return 400; // Should maybe be 405 instead? } - if (streams.count(request_tokens[1]) == 0) { - return 404; // Not found. - } - client->stream_id = request_tokens[1]; - client->stream = find_stream(client->stream_id); - if (client->stream->mark_pool != NULL) { - client->fwmark = client->stream->mark_pool->get_mark(); + string url = request_tokens[1]; + client->url = url; + if (url.size() > 8 && url.find("?backlog") == url.size() - 8) { + client->stream_pos = -2; + url = url.substr(0, url.size() - 8); } else { - client->fwmark = 0; // No mark. + client->stream_pos = -1; + } + + map::const_iterator stream_url_map_it = stream_url_map.find(url); + if (stream_url_map_it == stream_url_map.end()) { + map::const_iterator ping_url_map_it = ping_url_map.find(url); + if (ping_url_map_it == ping_url_map.end()) { + return 404; // Not found. + } else { + return 204; // No error. + } + } + + Stream *stream = streams[stream_url_map_it->second]; + if (stream->http_header.empty()) { + return 503; // Service unavailable. } - if (setsockopt(client->sock, SOL_SOCKET, SO_MARK, &client->fwmark, sizeof(client->fwmark)) == -1) { - if (client->fwmark != 0) { - log_perror("setsockopt(SO_MARK)"); + + client->stream = stream; + if (setsockopt(client->sock, SOL_SOCKET, SO_MAX_PACING_RATE, &client->stream->pacing_rate, sizeof(client->stream->pacing_rate)) == -1) { + if (client->stream->pacing_rate != ~0U) { + log_perror("setsockopt(SO_MAX_PACING_RATE)"); } } client->request.clear(); @@ -463,24 +878,25 @@ int Server::parse_request(Client *client) void Server::construct_header(Client *client) { - Stream *stream = find_stream(client->stream_id); + Stream *stream = client->stream; if (stream->encoding == Stream::STREAM_ENCODING_RAW) { - client->header_or_error = stream->http_header + + client->header_or_short_response = stream->http_header + "\r\n" + stream->stream_header; } else if (stream->encoding == Stream::STREAM_ENCODING_METACUBE) { - client->header_or_error = stream->http_header + + client->header_or_short_response = stream->http_header + "Content-encoding: metacube\r\n" + "\r\n"; if (!stream->stream_header.empty()) { - metacube_block_header hdr; - memcpy(hdr.sync, METACUBE_SYNC, sizeof(hdr.sync)); + metacube2_block_header hdr; + memcpy(hdr.sync, METACUBE2_SYNC, sizeof(hdr.sync)); hdr.size = htonl(stream->stream_header.size()); - hdr.flags = htonl(METACUBE_FLAGS_HEADER); - client->header_or_error.append( + hdr.flags = htons(METACUBE_FLAGS_HEADER); + hdr.csum = htons(metacube2_compute_crc(&hdr)); + client->header_or_short_response.append( string(reinterpret_cast(&hdr), sizeof(hdr))); } - client->header_or_error.append(stream->stream_header); + client->header_or_short_response.append(stream->stream_header); } else { assert(false); } @@ -503,10 +919,42 @@ void Server::construct_error(Client *client, int error_code) char error[256]; snprintf(error, 256, "HTTP/1.0 %d Error\r\nContent-type: text/plain\r\n\r\nSomething went wrong. Sorry.\r\n", error_code); - client->header_or_error = error; + client->header_or_short_response = error; // Switch states. - client->state = Client::SENDING_ERROR; + client->state = Client::SENDING_SHORT_RESPONSE; + + epoll_event ev; + ev.events = EPOLLOUT | EPOLLET | EPOLLRDHUP; + ev.data.u64 = reinterpret_cast(client); + + if (epoll_ctl(epoll_fd, EPOLL_CTL_MOD, client->sock, &ev) == -1) { + log_perror("epoll_ctl(EPOLL_CTL_MOD)"); + exit(1); + } +} + +void Server::construct_204(Client *client) +{ + map::const_iterator ping_url_map_it = ping_url_map.find(client->url); + assert(ping_url_map_it != ping_url_map.end()); + + if (ping_url_map_it->second.empty()) { + client->header_or_short_response = + "HTTP/1.0 204 No Content\r\n" + "\r\n"; + } else { + char response[256]; + snprintf(response, 256, + "HTTP/1.0 204 No Content\r\n" + "Access-Control-Allow-Origin: %s\r\n" + "\r\n", + ping_url_map_it->second.c_str()); + client->header_or_short_response = response; + } + + // Switch states. + client->state = Client::SENDING_SHORT_RESPONSE; epoll_event ev; ev.events = EPOLLOUT | EPOLLET | EPOLLRDHUP; @@ -536,10 +984,10 @@ void Server::close_client(Client *client) if (client->stream != NULL) { delete_from(&client->stream->sleeping_clients, client); delete_from(&client->stream->to_process, client); - if (client->stream->mark_pool != NULL) { - int fwmark = client->fwmark; - client->stream->mark_pool->release_mark(fwmark); - } + } + + if (client->tls_context) { + tls_destroy_context(client->tls_context); } // Log to access_log. @@ -551,28 +999,18 @@ void Server::close_client(Client *client) clients.erase(client->sock); } -Stream *Server::find_stream(const string &stream_id) -{ - map::iterator it = streams.find(stream_id); - assert(it != streams.end()); - return it->second; -} - void Server::process_queued_data() { - MutexLock lock(&queued_data_mutex); + { + MutexLock lock(&queued_clients_mutex); + + for (size_t i = 0; i < queued_add_clients.size(); ++i) { + add_client(queued_add_clients[i].first, queued_add_clients[i].second); + } + queued_add_clients.clear(); + } - for (size_t i = 0; i < queued_add_clients.size(); ++i) { - add_client(queued_add_clients[i]); + for (size_t i = 0; i < streams.size(); ++i) { + streams[i]->process_queued_data(); } - queued_add_clients.clear(); - - for (map::iterator queued_it = queued_data.begin(); - queued_it != queued_data.end(); - ++queued_it) { - Stream *stream = find_stream(queued_it->first); - stream->add_data(queued_it->second.data(), queued_it->second.size()); - stream->wake_up_all_clients(); - } - queued_data.clear(); }