/* * Copyright (c) 2018-2020, Andreas Kling * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * 1. Redistributions of source code must retain the above copyright notice, this * list of conditions and the following disclaimer. * * 2. Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following disclaimer in the documentation * and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR * SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER * CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include //#define NETWORK_TASK_DEBUG //#define ETHERNET_DEBUG //#define ETHERNET_VERY_DEBUG //#define ARP_DEBUG //#define IPV4_DEBUG //#define ICMP_DEBUG //#define UDP_DEBUG //#define TCP_DEBUG namespace Kernel { static void handle_arp(const EthernetFrameHeader&, size_t frame_size); static void handle_ipv4(const EthernetFrameHeader&, size_t frame_size, const timeval& packet_timestamp); static void handle_icmp(const EthernetFrameHeader&, const IPv4Packet&, const timeval& packet_timestamp); static void handle_udp(const IPv4Packet&, const timeval& packet_timestamp); static void handle_tcp(const IPv4Packet&, const timeval& packet_timestamp); [[noreturn]] static void NetworkTask_main(void*); void NetworkTask::spawn() { RefPtr thread; Process::create_kernel_process(thread, "NetworkTask", NetworkTask_main, nullptr); } void NetworkTask_main(void*) { WaitQueue packet_wait_queue; u8 octet = 15; int pending_packets = 0; NetworkAdapter::for_each([&](auto& adapter) { if (String(adapter.class_name()) == "LoopbackAdapter") { adapter.set_ipv4_address({ 127, 0, 0, 1 }); adapter.set_ipv4_netmask({ 255, 0, 0, 0 }); adapter.set_ipv4_gateway({ 0, 0, 0, 0 }); } else { adapter.set_ipv4_address({ 10, 0, 2, octet++ }); adapter.set_ipv4_netmask({ 255, 255, 255, 0 }); adapter.set_ipv4_gateway({ 10, 0, 2, 2 }); } klog() << "NetworkTask: " << adapter.class_name() << " network adapter found: hw=" << adapter.mac_address().to_string().characters() << " address=" << adapter.ipv4_address().to_string().characters() << " netmask=" << adapter.ipv4_netmask().to_string().characters() << " gateway=" << adapter.ipv4_gateway().to_string().characters(); adapter.on_receive = [&]() { pending_packets++; packet_wait_queue.wake_all(); }; }); auto dequeue_packet = [&pending_packets](u8* buffer, size_t buffer_size, timeval& packet_timestamp) -> size_t { if (pending_packets == 0) return 0; size_t packet_size = 0; NetworkAdapter::for_each([&](auto& adapter) { if (packet_size || !adapter.has_queued_packets()) return; packet_size = adapter.dequeue_packet(buffer, buffer_size, packet_timestamp); pending_packets--; #ifdef NETWORK_TASK_DEBUG klog() << "NetworkTask: Dequeued packet from " << adapter.name().characters() << " (" << packet_size << " bytes)"; #endif }); return packet_size; }; size_t buffer_size = 64 * KiB; auto buffer_region = MM.allocate_kernel_region(buffer_size, "Kernel Packet Buffer", Region::Access::Read | Region::Access::Write); auto buffer = (u8*)buffer_region->vaddr().get(); timeval packet_timestamp; klog() << "NetworkTask: Enter main loop."; for (;;) { size_t packet_size = dequeue_packet(buffer, buffer_size, packet_timestamp); if (!packet_size) { packet_wait_queue.wait_on(nullptr, "NetworkTask"); continue; } if (packet_size < sizeof(EthernetFrameHeader)) { klog() << "NetworkTask: Packet is too small to be an Ethernet packet! (" << packet_size << ")"; continue; } auto& eth = *(const EthernetFrameHeader*)buffer; #ifdef ETHERNET_DEBUG dbgln("NetworkTask: From {} to {}, ether_type={:#04x}, packet_size={}", eth.source().to_string(), eth.destination().to_string(), eth.ether_type(), packet_size); #endif #ifdef ETHERNET_VERY_DEBUG for (size_t i = 0; i < packet_size; i++) { klog() << String::format("%#02x", buffer[i]); switch (i % 16) { case 7: klog() << " "; break; case 15: klog() << ""; break; default: klog() << " "; break; } } klog() << ""; #endif switch (eth.ether_type()) { case EtherType::ARP: handle_arp(eth, packet_size); break; case EtherType::IPv4: handle_ipv4(eth, packet_size, packet_timestamp); break; case EtherType::IPv6: // ignore break; default: klog() << "NetworkTask: Unknown ethernet type 0x" << String::format("%x", eth.ether_type()); } } } void handle_arp(const EthernetFrameHeader& eth, size_t frame_size) { constexpr size_t minimum_arp_frame_size = sizeof(EthernetFrameHeader) + sizeof(ARPPacket); if (frame_size < minimum_arp_frame_size) { klog() << "handle_arp: Frame too small (" << frame_size << ", need " << minimum_arp_frame_size << ")"; return; } auto& packet = *static_cast(eth.payload()); if (packet.hardware_type() != 1 || packet.hardware_address_length() != sizeof(MACAddress)) { dbgln("handle_arp: Hardware type not ethernet ({:#04x}, len={})", packet.hardware_type(), packet.hardware_address_length()); return; } if (packet.protocol_type() != EtherType::IPv4 || packet.protocol_address_length() != sizeof(IPv4Address)) { dbgln("handle_arp: Protocol type not IPv4 ({:#04x}, len={})", packet.protocol_type(), packet.protocol_address_length()); return; } #ifdef ARP_DEBUG dbgln("handle_arp: operation={:#04x}, sender={}/{}, target={}/{}", packet.operation(), packet.sender_hardware_address().to_string(), packet.sender_protocol_address().to_string(), packet.target_hardware_address().to_string(), packet.target_protocol_address().to_string()); #endif if (!packet.sender_hardware_address().is_zero() && !packet.sender_protocol_address().is_zero()) { // Someone has this IPv4 address. I guess we can try to remember that. // FIXME: Protect against ARP spamming. // FIXME: Support static ARP table entries. update_arp_table(packet.sender_protocol_address(), packet.sender_hardware_address()); } if (packet.operation() == ARPOperation::Request) { // Who has this IP address? if (auto adapter = NetworkAdapter::from_ipv4_address(packet.target_protocol_address())) { // We do! klog() << "handle_arp: Responding to ARP request for my IPv4 address (" << adapter->ipv4_address().to_string().characters() << ")"; ARPPacket response; response.set_operation(ARPOperation::Response); response.set_target_hardware_address(packet.sender_hardware_address()); response.set_target_protocol_address(packet.sender_protocol_address()); response.set_sender_hardware_address(adapter->mac_address()); response.set_sender_protocol_address(adapter->ipv4_address()); adapter->send(packet.sender_hardware_address(), response); } return; } } void handle_ipv4(const EthernetFrameHeader& eth, size_t frame_size, const timeval& packet_timestamp) { constexpr size_t minimum_ipv4_frame_size = sizeof(EthernetFrameHeader) + sizeof(IPv4Packet); if (frame_size < minimum_ipv4_frame_size) { klog() << "handle_ipv4: Frame too small (" << frame_size << ", need " << minimum_ipv4_frame_size << ")"; return; } auto& packet = *static_cast(eth.payload()); if (packet.length() < sizeof(IPv4Packet)) { klog() << "handle_ipv4: IPv4 packet too short (" << packet.length() << ", need " << sizeof(IPv4Packet) << ")"; return; } size_t actual_ipv4_packet_length = frame_size - sizeof(EthernetFrameHeader); if (packet.length() > actual_ipv4_packet_length) { klog() << "handle_ipv4: IPv4 packet claims to be longer than it is (" << packet.length() << ", actually " << actual_ipv4_packet_length << ")"; return; } #ifdef IPV4_DEBUG klog() << "handle_ipv4: source=" << packet.source().to_string().characters() << ", target=" << packet.destination().to_string().characters(); #endif switch ((IPv4Protocol)packet.protocol()) { case IPv4Protocol::ICMP: return handle_icmp(eth, packet, packet_timestamp); case IPv4Protocol::UDP: return handle_udp(packet, packet_timestamp); case IPv4Protocol::TCP: return handle_tcp(packet, packet_timestamp); default: klog() << "handle_ipv4: Unhandled protocol " << packet.protocol(); break; } } void handle_icmp(const EthernetFrameHeader& eth, const IPv4Packet& ipv4_packet, const timeval& packet_timestamp) { auto& icmp_header = *static_cast(ipv4_packet.payload()); #ifdef ICMP_DEBUG dbgln("handle_icmp: source={}, destination={}, type={:#02x}, code={:#02x}", ipv4_packet.source().to_string(), ipv4_packet.destination().to_string(), icmp_header.type(), icmp_header.code()); #endif { LOCKER(IPv4Socket::all_sockets().lock()); for (RefPtr socket : IPv4Socket::all_sockets().resource()) { LOCKER(socket->lock()); if (socket->protocol() != (unsigned)IPv4Protocol::ICMP) continue; socket->did_receive(ipv4_packet.source(), 0, KBuffer::copy(&ipv4_packet, sizeof(IPv4Packet) + ipv4_packet.payload_size()), packet_timestamp); } } auto adapter = NetworkAdapter::from_ipv4_address(ipv4_packet.destination()); if (!adapter) return; if (icmp_header.type() == ICMPType::EchoRequest) { auto& request = reinterpret_cast(icmp_header); klog() << "handle_icmp: EchoRequest from " << ipv4_packet.source().to_string().characters() << ": id=" << (u16)request.identifier << ", seq=" << (u16)request.sequence_number; size_t icmp_packet_size = ipv4_packet.payload_size(); if (icmp_packet_size < sizeof(ICMPEchoPacket)) { klog() << "handle_icmp: EchoRequest packet is too small, ignoring."; return; } auto buffer = ByteBuffer::create_zeroed(icmp_packet_size); auto& response = *(ICMPEchoPacket*)buffer.data(); response.header.set_type(ICMPType::EchoReply); response.header.set_code(0); response.identifier = request.identifier; response.sequence_number = request.sequence_number; if (size_t icmp_payload_size = icmp_packet_size - sizeof(ICMPEchoPacket)) memcpy(response.payload(), request.payload(), icmp_payload_size); response.header.set_checksum(internet_checksum(&response, icmp_packet_size)); // FIXME: What is the right TTL value here? Is 64 ok? Should we use the same TTL as the echo request? auto response_buffer = UserOrKernelBuffer::for_kernel_buffer((u8*)&response); adapter->send_ipv4(eth.source(), ipv4_packet.source(), IPv4Protocol::ICMP, response_buffer, buffer.size(), 64); } } void handle_udp(const IPv4Packet& ipv4_packet, const timeval& packet_timestamp) { if (ipv4_packet.payload_size() < sizeof(UDPPacket)) { klog() << "handle_udp: Packet too small (" << ipv4_packet.payload_size() << ", need " << sizeof(UDPPacket) << ")"; return; } auto adapter = NetworkAdapter::from_ipv4_address(ipv4_packet.destination()); if (!adapter && ipv4_packet.destination() != IPv4Address(255, 255, 255, 255)) { klog() << "handle_udp: this packet is not for me, it's for " << ipv4_packet.destination().to_string().characters(); return; } auto& udp_packet = *static_cast(ipv4_packet.payload()); #ifdef UDP_DEBUG klog() << "handle_udp: source=" << ipv4_packet.source().to_string().characters() << ":" << udp_packet.source_port() << ", destination=" << ipv4_packet.destination().to_string().characters() << ":" << udp_packet.destination_port() << " length=" << udp_packet.length(); #endif auto socket = UDPSocket::from_port(udp_packet.destination_port()); if (!socket) { klog() << "handle_udp: No UDP socket for port " << udp_packet.destination_port(); return; } ASSERT(socket->type() == SOCK_DGRAM); ASSERT(socket->local_port() == udp_packet.destination_port()); socket->did_receive(ipv4_packet.source(), udp_packet.source_port(), KBuffer::copy(&ipv4_packet, sizeof(IPv4Packet) + ipv4_packet.payload_size()), packet_timestamp); } void handle_tcp(const IPv4Packet& ipv4_packet, const timeval& packet_timestamp) { if (ipv4_packet.payload_size() < sizeof(TCPPacket)) { klog() << "handle_tcp: IPv4 payload is too small to be a TCP packet (" << ipv4_packet.payload_size() << ", need " << sizeof(TCPPacket) << ")"; return; } auto& tcp_packet = *static_cast(ipv4_packet.payload()); size_t minimum_tcp_header_size = 5 * sizeof(u32); size_t maximum_tcp_header_size = 15 * sizeof(u32); if (tcp_packet.header_size() < minimum_tcp_header_size || tcp_packet.header_size() > maximum_tcp_header_size) { klog() << "handle_tcp: TCP packet header has invalid size " << tcp_packet.header_size(); } if (ipv4_packet.payload_size() < tcp_packet.header_size()) { klog() << "handle_tcp: IPv4 payload is smaller than TCP header claims (" << ipv4_packet.payload_size() << ", supposedly " << tcp_packet.header_size() << ")"; return; } size_t payload_size = ipv4_packet.payload_size() - tcp_packet.header_size(); #ifdef TCP_DEBUG dbgln("handle_tcp: source={}:{}, destination={}:{}, seq_no={}, ack_no={}, flags={:#04x} ({}{}{}{}), window_size={}, payload_size={}", ipv4_packet.source().to_string(), tcp_packet.source_port(), ipv4_packet.destination().to_string(), tcp_packet.destination_port(), tcp_packet.sequence_number(), tcp_packet.ack_number(), tcp_packet.flags(), tcp_packet.has_syn() ? "SYN " : "", tcp_packet.has_ack() ? "ACK " : "", tcp_packet.has_fin() ? "FIN " : "", tcp_packet.has_rst() ? "RST " : "", tcp_packet.window_size(), payload_size); #endif auto adapter = NetworkAdapter::from_ipv4_address(ipv4_packet.destination()); if (!adapter) { klog() << "handle_tcp: this packet is not for me, it's for " << ipv4_packet.destination().to_string().characters(); return; } IPv4SocketTuple tuple(ipv4_packet.destination(), tcp_packet.destination_port(), ipv4_packet.source(), tcp_packet.source_port()); #ifdef TCP_DEBUG klog() << "handle_tcp: looking for socket; tuple=" << tuple.to_string().characters(); #endif auto socket = TCPSocket::from_tuple(tuple); if (!socket) { dbgln("handle_tcp: No TCP socket for tuple {}", tuple.to_string()); dbgln("handle_tcp: source={}:{}, destination={}:{}, seq_no={}, ack_no={}, flags={:#04x} ({}{}{}{}), window_size={}, payload_size={}", ipv4_packet.source().to_string(), tcp_packet.source_port(), ipv4_packet.destination().to_string(), tcp_packet.destination_port(), tcp_packet.sequence_number(), tcp_packet.ack_number(), tcp_packet.flags(), tcp_packet.has_syn() ? "SYN " : "", tcp_packet.has_ack() ? "ACK " : "", tcp_packet.has_fin() ? "FIN " : "", tcp_packet.has_rst() ? "RST " : "", tcp_packet.window_size(), payload_size); return; } LOCKER(socket->lock()); ASSERT(socket->type() == SOCK_STREAM); ASSERT(socket->local_port() == tcp_packet.destination_port()); #ifdef TCP_DEBUG klog() << "handle_tcp: got socket; state=" << socket->tuple().to_string().characters() << " " << TCPSocket::to_string(socket->state()); #endif socket->receive_tcp_packet(tcp_packet, ipv4_packet.payload_size()); [[maybe_unused]] int unused_rc {}; switch (socket->state()) { case TCPSocket::State::Closed: klog() << "handle_tcp: unexpected flags in Closed state"; // TODO: we may want to send an RST here, maybe as a configurable option return; case TCPSocket::State::TimeWait: klog() << "handle_tcp: unexpected flags in TimeWait state"; unused_rc = socket->send_tcp_packet(TCPFlags::RST); socket->set_state(TCPSocket::State::Closed); return; case TCPSocket::State::Listen: switch (tcp_packet.flags()) { case TCPFlags::SYN: { #ifdef TCP_DEBUG klog() << "handle_tcp: incoming connection"; #endif auto& local_address = ipv4_packet.destination(); auto& peer_address = ipv4_packet.source(); auto client = socket->create_client(local_address, tcp_packet.destination_port(), peer_address, tcp_packet.source_port()); if (!client) { klog() << "handle_tcp: couldn't create client socket"; return; } LOCKER(client->lock()); #ifdef TCP_DEBUG klog() << "handle_tcp: created new client socket with tuple " << client->tuple().to_string().characters(); #endif client->set_sequence_number(1000); client->set_ack_number(tcp_packet.sequence_number() + payload_size + 1); [[maybe_unused]] auto rc2 = client->send_tcp_packet(TCPFlags::SYN | TCPFlags::ACK); client->set_state(TCPSocket::State::SynReceived); return; } default: klog() << "handle_tcp: unexpected flags in Listen state"; // socket->send_tcp_packet(TCPFlags::RST); return; } case TCPSocket::State::SynSent: switch (tcp_packet.flags()) { case TCPFlags::SYN: socket->set_ack_number(tcp_packet.sequence_number() + payload_size + 1); unused_rc = socket->send_tcp_packet(TCPFlags::ACK); socket->set_state(TCPSocket::State::SynReceived); return; case TCPFlags::ACK | TCPFlags::SYN: socket->set_ack_number(tcp_packet.sequence_number() + payload_size + 1); unused_rc = socket->send_tcp_packet(TCPFlags::ACK); socket->set_state(TCPSocket::State::Established); socket->set_setup_state(Socket::SetupState::Completed); socket->set_connected(true); return; case TCPFlags::ACK | TCPFlags::FIN: socket->set_ack_number(tcp_packet.sequence_number() + payload_size + 1); unused_rc = socket->send_tcp_packet(TCPFlags::ACK); socket->set_state(TCPSocket::State::Closed); socket->set_error(TCPSocket::Error::FINDuringConnect); socket->set_setup_state(Socket::SetupState::Completed); return; case TCPFlags::ACK | TCPFlags::RST: socket->set_ack_number(tcp_packet.sequence_number() + payload_size); unused_rc = socket->send_tcp_packet(TCPFlags::ACK); socket->set_state(TCPSocket::State::Closed); socket->set_error(TCPSocket::Error::RSTDuringConnect); socket->set_setup_state(Socket::SetupState::Completed); return; default: klog() << "handle_tcp: unexpected flags in SynSent state"; unused_rc = socket->send_tcp_packet(TCPFlags::RST); socket->set_state(TCPSocket::State::Closed); socket->set_error(TCPSocket::Error::UnexpectedFlagsDuringConnect); socket->set_setup_state(Socket::SetupState::Completed); return; } case TCPSocket::State::SynReceived: switch (tcp_packet.flags()) { case TCPFlags::ACK: socket->set_ack_number(tcp_packet.sequence_number() + payload_size); switch (socket->direction()) { case TCPSocket::Direction::Incoming: if (!socket->has_originator()) { klog() << "handle_tcp: connection doesn't have an originating socket; maybe it went away?"; unused_rc = socket->send_tcp_packet(TCPFlags::RST); socket->set_state(TCPSocket::State::Closed); return; } socket->set_state(TCPSocket::State::Established); socket->set_setup_state(Socket::SetupState::Completed); socket->release_to_originator(); return; case TCPSocket::Direction::Outgoing: socket->set_state(TCPSocket::State::Established); socket->set_setup_state(Socket::SetupState::Completed); socket->set_connected(true); return; default: klog() << "handle_tcp: got ACK in SynReceived state but direction is invalid (" << TCPSocket::to_string(socket->direction()) << ")"; unused_rc = socket->send_tcp_packet(TCPFlags::RST); socket->set_state(TCPSocket::State::Closed); return; } return; default: klog() << "handle_tcp: unexpected flags in SynReceived state"; unused_rc = socket->send_tcp_packet(TCPFlags::RST); socket->set_state(TCPSocket::State::Closed); return; } case TCPSocket::State::CloseWait: switch (tcp_packet.flags()) { default: klog() << "handle_tcp: unexpected flags in CloseWait state"; unused_rc = socket->send_tcp_packet(TCPFlags::RST); socket->set_state(TCPSocket::State::Closed); return; } case TCPSocket::State::LastAck: switch (tcp_packet.flags()) { case TCPFlags::ACK: socket->set_ack_number(tcp_packet.sequence_number() + payload_size); socket->set_state(TCPSocket::State::Closed); return; default: klog() << "handle_tcp: unexpected flags in LastAck state"; unused_rc = socket->send_tcp_packet(TCPFlags::RST); socket->set_state(TCPSocket::State::Closed); return; } case TCPSocket::State::FinWait1: switch (tcp_packet.flags()) { case TCPFlags::ACK: socket->set_ack_number(tcp_packet.sequence_number() + payload_size); socket->set_state(TCPSocket::State::FinWait2); return; case TCPFlags::FIN: socket->set_ack_number(tcp_packet.sequence_number() + payload_size + 1); socket->set_state(TCPSocket::State::Closing); return; default: klog() << "handle_tcp: unexpected flags in FinWait1 state"; unused_rc = socket->send_tcp_packet(TCPFlags::RST); socket->set_state(TCPSocket::State::Closed); return; } case TCPSocket::State::FinWait2: switch (tcp_packet.flags()) { case TCPFlags::FIN: socket->set_ack_number(tcp_packet.sequence_number() + payload_size + 1); socket->set_state(TCPSocket::State::TimeWait); return; case TCPFlags::ACK | TCPFlags::RST: socket->set_state(TCPSocket::State::Closed); return; default: klog() << "handle_tcp: unexpected flags in FinWait2 state"; unused_rc = socket->send_tcp_packet(TCPFlags::RST); socket->set_state(TCPSocket::State::Closed); return; } case TCPSocket::State::Closing: switch (tcp_packet.flags()) { case TCPFlags::ACK: socket->set_ack_number(tcp_packet.sequence_number() + payload_size); socket->set_state(TCPSocket::State::TimeWait); return; default: klog() << "handle_tcp: unexpected flags in Closing state"; unused_rc = socket->send_tcp_packet(TCPFlags::RST); socket->set_state(TCPSocket::State::Closed); return; } case TCPSocket::State::Established: if (tcp_packet.has_fin()) { if (payload_size != 0) socket->did_receive(ipv4_packet.source(), tcp_packet.source_port(), KBuffer::copy(&ipv4_packet, sizeof(IPv4Packet) + ipv4_packet.payload_size()), packet_timestamp); socket->set_ack_number(tcp_packet.sequence_number() + payload_size + 1); unused_rc = socket->send_tcp_packet(TCPFlags::ACK); socket->set_state(TCPSocket::State::CloseWait); socket->set_connected(false); return; } socket->set_ack_number(tcp_packet.sequence_number() + payload_size); #ifdef TCP_DEBUG klog() << "Got packet with ack_no=" << tcp_packet.ack_number() << ", seq_no=" << tcp_packet.sequence_number() << ", payload_size=" << payload_size << ", acking it with new ack_no=" << socket->ack_number() << ", seq_no=" << socket->sequence_number(); #endif if (payload_size) { if (socket->did_receive(ipv4_packet.source(), tcp_packet.source_port(), KBuffer::copy(&ipv4_packet, sizeof(IPv4Packet) + ipv4_packet.payload_size()), packet_timestamp)) unused_rc = socket->send_tcp_packet(TCPFlags::ACK); } } } }