#include #include #include #include #include Lockable>& TCPSocket::sockets_by_port() { static Lockable>* s_map; if (!s_map) s_map = new Lockable>; return *s_map; } TCPSocketHandle TCPSocket::from_port(word port) { RetainPtr socket; { LOCKER(sockets_by_port().lock()); auto it = sockets_by_port().resource().find(port); if (it == sockets_by_port().resource().end()) return { }; socket = (*it).value; ASSERT(socket); } return { move(socket) }; } TCPSocket::TCPSocket(int protocol) : IPv4Socket(SOCK_STREAM, protocol) { } TCPSocket::~TCPSocket() { LOCKER(sockets_by_port().lock()); sockets_by_port().resource().remove(source_port()); } Retained TCPSocket::create(int protocol) { return adopt(*new TCPSocket(protocol)); } int TCPSocket::protocol_receive(const ByteBuffer& packet_buffer, void* buffer, size_t buffer_size, int flags, sockaddr* addr, socklen_t* addr_length) { (void)flags; (void)addr_length; ASSERT(!packet_buffer.is_null()); auto& ipv4_packet = *(const IPv4Packet*)(packet_buffer.pointer()); auto& tcp_packet = *static_cast(ipv4_packet.payload()); size_t payload_size = packet_buffer.size() - sizeof(IPv4Packet) - tcp_packet.header_size(); kprintf("payload_size %u, will it fit in %u?\n", payload_size, buffer_size); ASSERT(buffer_size >= payload_size); if (addr) { auto& ia = *(sockaddr_in*)addr; ia.sin_port = htons(tcp_packet.destination_port()); } memcpy(buffer, tcp_packet.payload(), payload_size); return payload_size; } int TCPSocket::protocol_send(const void* data, int data_length) { // FIXME: Figure out the adapter somehow differently. auto* adapter = NetworkAdapter::from_ipv4_address(IPv4Address(192, 168, 5, 2)); if (!adapter) ASSERT_NOT_REACHED(); send_tcp_packet(TCPFlags::PUSH | TCPFlags::ACK, data, data_length); return data_length; } void TCPSocket::send_tcp_packet(word flags, const void* payload, int payload_size) { // FIXME: Figure out the adapter somehow differently. auto& adapter = *NetworkAdapter::from_ipv4_address(IPv4Address(192, 168, 5, 2)); auto buffer = ByteBuffer::create_zeroed(sizeof(TCPPacket) + payload_size); auto& tcp_packet = *(TCPPacket*)(buffer.pointer()); ASSERT(source_port()); tcp_packet.set_source_port(source_port()); tcp_packet.set_destination_port(destination_port()); tcp_packet.set_window_size(1024); tcp_packet.set_sequence_number(m_sequence_number); tcp_packet.set_data_offset(sizeof(TCPPacket) / sizeof(dword)); tcp_packet.set_flags(flags); if (flags & TCPFlags::ACK) tcp_packet.set_ack_number(m_ack_number); if (flags == TCPFlags::SYN) { ++m_sequence_number; } else { m_sequence_number += payload_size; } memcpy(tcp_packet.payload(), payload, payload_size); tcp_packet.set_checksum(compute_tcp_checksum(adapter.ipv4_address(), destination_address(), tcp_packet, payload_size)); kprintf("sending tcp packet from %s:%u to %s:%u with (%s %s) seq_no=%u, ack_no=%u\n", adapter.ipv4_address().to_string().characters(), source_port(), destination_address().to_string().characters(), destination_port(), tcp_packet.has_syn() ? "SYN" : "", tcp_packet.has_ack() ? "ACK" : "", tcp_packet.sequence_number(), tcp_packet.ack_number() ); adapter.send_ipv4(MACAddress(), destination_address(), IPv4Protocol::TCP, move(buffer)); } NetworkOrdered TCPSocket::compute_tcp_checksum(const IPv4Address& source, const IPv4Address& destination, const TCPPacket& packet, word payload_size) { struct [[gnu::packed]] PseudoHeader { IPv4Address source; IPv4Address destination; byte zero; byte protocol; NetworkOrdered payload_size; }; PseudoHeader pseudo_header { source, destination, 0, (byte)IPv4Protocol::TCP, sizeof(TCPPacket) + payload_size }; dword checksum = 0; auto* w = (const NetworkOrdered*)&pseudo_header; for (size_t i = 0; i < sizeof(pseudo_header) / sizeof(word); ++i) { checksum += w[i]; if (checksum > 0xffff) checksum = (checksum >> 16) + (checksum & 0xffff); } w = (const NetworkOrdered*)&packet; for (size_t i = 0; i < sizeof(packet) / sizeof(word); ++i) { checksum += w[i]; if (checksum > 0xffff) checksum = (checksum >> 16) + (checksum & 0xffff); } ASSERT(packet.data_offset() * 4 == sizeof(TCPPacket)); w = (const NetworkOrdered*)packet.payload(); for (size_t i = 0; i < payload_size / sizeof(word); ++i) { checksum += w[i]; if (checksum > 0xffff) checksum = (checksum >> 16) + (checksum & 0xffff); } if (payload_size & 1) { word expanded_byte = ((const byte*)packet.payload())[payload_size - 1] << 8; checksum += expanded_byte; if (checksum > 0xffff) checksum = (checksum >> 16) + (checksum & 0xffff); } return ~(checksum & 0xffff); } KResult TCPSocket::protocol_connect() { // FIXME: Figure out the adapter somehow differently. auto* adapter = NetworkAdapter::from_ipv4_address(IPv4Address(192, 168, 5, 2)); if (!adapter) ASSERT_NOT_REACHED(); allocate_source_port_if_needed(); m_sequence_number = 0; m_ack_number = 0; send_tcp_packet(TCPFlags::SYN); m_state = State::Connecting; current->set_blocked_socket(this); block(Thread::BlockedConnect); Scheduler::yield(); ASSERT(is_connected()); return KSuccess; } int TCPSocket::protocol_allocate_source_port() { static const word first_ephemeral_port = 32768; static const word last_ephemeral_port = 60999; static const word ephemeral_port_range_size = last_ephemeral_port - first_ephemeral_port; word first_scan_port = first_ephemeral_port + (word)(RandomDevice::random_percentage() * ephemeral_port_range_size); LOCKER(sockets_by_port().lock()); for (word port = first_scan_port;;) { auto it = sockets_by_port().resource().find(port); if (it == sockets_by_port().resource().end()) { set_source_port(port); sockets_by_port().resource().set(port, this); return port; } ++port; if (port > last_ephemeral_port) port = first_ephemeral_port; if (port == first_scan_port) break; } return -EADDRINUSE; } bool TCPSocket::protocol_is_disconnected() const { return m_state == State::Disconnecting || m_state == State::Disconnected; }