ladybird/Kernel/Net/TCPSocket.cpp
sin-ack 0ccef94a49 Kernel: Drop the receive buffer when socket enters the TimeWait state
The TimeWait state is intended to prevent another socket from taking the
address tuple in case any packets are still in transit after the final
close. Since this state never delivers packets to userspace, it doesn't
make sense to keep the receive buffer around.
2021-09-16 16:50:23 +02:00

614 lines
22 KiB
C++

/*
* Copyright (c) 2018-2020, Andreas Kling <kling@serenityos.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <AK/Singleton.h>
#include <AK/Time.h>
#include <Kernel/Debug.h>
#include <Kernel/Devices/RandomDevice.h>
#include <Kernel/FileSystem/OpenFileDescription.h>
#include <Kernel/Locking/MutexProtected.h>
#include <Kernel/Net/EthernetFrameHeader.h>
#include <Kernel/Net/IPv4.h>
#include <Kernel/Net/NetworkAdapter.h>
#include <Kernel/Net/NetworkingManagement.h>
#include <Kernel/Net/Routing.h>
#include <Kernel/Net/TCP.h>
#include <Kernel/Net/TCPSocket.h>
#include <Kernel/Process.h>
#include <Kernel/Random.h>
namespace Kernel {
void TCPSocket::for_each(Function<void(const TCPSocket&)> callback)
{
sockets_by_tuple().for_each_shared([&](const auto& it) {
callback(*it.value);
});
}
void TCPSocket::set_state(State new_state)
{
dbgln_if(TCP_SOCKET_DEBUG, "TCPSocket({}) state moving from {} to {}", this, to_string(m_state), to_string(new_state));
auto was_disconnected = protocol_is_disconnected();
auto previous_role = m_role;
m_state = new_state;
if (new_state == State::Established && m_direction == Direction::Outgoing) {
set_role(Role::Connected);
[[maybe_unused]] auto rc = set_so_error(KSuccess);
}
if (new_state == State::TimeWait) {
// Once we hit TimeWait, we are only holding the socket in case there
// are packets on the way which we wouldn't want a new socket to get hit
// with, so there's no point in keeping the receive buffer around.
drop_receive_buffer();
}
if (new_state == State::Closed) {
closing_sockets().with_exclusive([&](auto& table) {
table.remove(tuple());
});
if (m_originator)
release_to_originator();
}
if (previous_role != m_role || was_disconnected != protocol_is_disconnected())
evaluate_block_conditions();
}
static Singleton<MutexProtected<HashMap<IPv4SocketTuple, RefPtr<TCPSocket>>>> s_socket_closing;
MutexProtected<HashMap<IPv4SocketTuple, RefPtr<TCPSocket>>>& TCPSocket::closing_sockets()
{
return *s_socket_closing;
}
static Singleton<MutexProtected<HashMap<IPv4SocketTuple, TCPSocket*>>> s_socket_tuples;
MutexProtected<HashMap<IPv4SocketTuple, TCPSocket*>>& TCPSocket::sockets_by_tuple()
{
return *s_socket_tuples;
}
RefPtr<TCPSocket> TCPSocket::from_tuple(const IPv4SocketTuple& tuple)
{
return sockets_by_tuple().with_shared([&](const auto& table) -> RefPtr<TCPSocket> {
auto exact_match = table.get(tuple);
if (exact_match.has_value())
return { *exact_match.value() };
auto address_tuple = IPv4SocketTuple(tuple.local_address(), tuple.local_port(), IPv4Address(), 0);
auto address_match = table.get(address_tuple);
if (address_match.has_value())
return { *address_match.value() };
auto wildcard_tuple = IPv4SocketTuple(IPv4Address(), tuple.local_port(), IPv4Address(), 0);
auto wildcard_match = table.get(wildcard_tuple);
if (wildcard_match.has_value())
return { *wildcard_match.value() };
return {};
});
}
KResultOr<NonnullRefPtr<TCPSocket>> TCPSocket::try_create_client(const IPv4Address& new_local_address, u16 new_local_port, const IPv4Address& new_peer_address, u16 new_peer_port)
{
auto tuple = IPv4SocketTuple(new_local_address, new_local_port, new_peer_address, new_peer_port);
return sockets_by_tuple().with_exclusive([&](auto& table) -> KResultOr<NonnullRefPtr<TCPSocket>> {
if (table.contains(tuple))
return EEXIST;
auto receive_buffer = TRY(try_create_receive_buffer());
auto client = TRY(TCPSocket::try_create(protocol(), move(receive_buffer)));
client->set_setup_state(SetupState::InProgress);
client->set_local_address(new_local_address);
client->set_local_port(new_local_port);
client->set_peer_address(new_peer_address);
client->set_peer_port(new_peer_port);
client->set_direction(Direction::Incoming);
client->set_originator(*this);
m_pending_release_for_accept.set(tuple, client);
table.set(tuple, client);
return { move(client) };
});
}
void TCPSocket::release_to_originator()
{
VERIFY(!!m_originator);
m_originator.strong_ref()->release_for_accept(this);
m_originator.clear();
}
void TCPSocket::release_for_accept(RefPtr<TCPSocket> socket)
{
VERIFY(m_pending_release_for_accept.contains(socket->tuple()));
m_pending_release_for_accept.remove(socket->tuple());
// FIXME: Should we observe this error somehow?
[[maybe_unused]] auto rc = queue_connection_from(*socket);
}
TCPSocket::TCPSocket(int protocol, NonnullOwnPtr<DoubleBuffer> receive_buffer, NonnullOwnPtr<KBuffer> scratch_buffer)
: IPv4Socket(SOCK_STREAM, protocol, move(receive_buffer), move(scratch_buffer))
{
m_last_retransmit_time = kgettimeofday();
}
TCPSocket::~TCPSocket()
{
sockets_by_tuple().with_exclusive([&](auto& table) {
table.remove(tuple());
});
dequeue_for_retransmit();
dbgln_if(TCP_SOCKET_DEBUG, "~TCPSocket in state {}", to_string(state()));
}
KResultOr<NonnullRefPtr<TCPSocket>> TCPSocket::try_create(int protocol, NonnullOwnPtr<DoubleBuffer> receive_buffer)
{
// Note: Scratch buffer is only used for SOCK_STREAM sockets.
auto scratch_buffer = TRY(KBuffer::try_create_with_size(65536));
return adopt_nonnull_ref_or_enomem(new (nothrow) TCPSocket(protocol, move(receive_buffer), move(scratch_buffer)));
}
KResultOr<size_t> TCPSocket::protocol_receive(ReadonlyBytes raw_ipv4_packet, UserOrKernelBuffer& buffer, size_t buffer_size, [[maybe_unused]] int flags)
{
auto& ipv4_packet = *reinterpret_cast<const IPv4Packet*>(raw_ipv4_packet.data());
auto& tcp_packet = *static_cast<const TCPPacket*>(ipv4_packet.payload());
size_t payload_size = raw_ipv4_packet.size() - sizeof(IPv4Packet) - tcp_packet.header_size();
dbgln_if(TCP_SOCKET_DEBUG, "payload_size {}, will it fit in {}?", payload_size, buffer_size);
VERIFY(buffer_size >= payload_size);
SOCKET_TRY(buffer.write(tcp_packet.payload(), payload_size));
return payload_size;
}
KResultOr<size_t> TCPSocket::protocol_send(const UserOrKernelBuffer& data, size_t data_length)
{
RoutingDecision routing_decision = route_to(peer_address(), local_address(), bound_interface());
if (routing_decision.is_zero())
return set_so_error(EHOSTUNREACH);
size_t mss = routing_decision.adapter->mtu() - sizeof(IPv4Packet) - sizeof(TCPPacket);
data_length = min(data_length, mss);
TRY(send_tcp_packet(TCPFlags::PUSH | TCPFlags::ACK, &data, data_length, &routing_decision));
return data_length;
}
KResult TCPSocket::send_ack(bool allow_duplicate)
{
if (!allow_duplicate && m_last_ack_number_sent == m_ack_number)
return KSuccess;
return send_tcp_packet(TCPFlags::ACK);
}
KResult TCPSocket::send_tcp_packet(u16 flags, const UserOrKernelBuffer* payload, size_t payload_size, RoutingDecision* user_routing_decision)
{
RoutingDecision routing_decision = user_routing_decision ? *user_routing_decision : route_to(peer_address(), local_address(), bound_interface());
if (routing_decision.is_zero())
return set_so_error(EHOSTUNREACH);
auto ipv4_payload_offset = routing_decision.adapter->ipv4_payload_offset();
const bool has_mss_option = flags == TCPFlags::SYN;
const size_t options_size = has_mss_option ? sizeof(TCPOptionMSS) : 0;
const size_t tcp_header_size = sizeof(TCPPacket) + options_size;
const size_t buffer_size = ipv4_payload_offset + tcp_header_size + payload_size;
auto packet = routing_decision.adapter->acquire_packet_buffer(buffer_size);
if (!packet)
return set_so_error(ENOMEM);
routing_decision.adapter->fill_in_ipv4_header(*packet, local_address(),
routing_decision.next_hop, peer_address(), IPv4Protocol::TCP,
buffer_size - ipv4_payload_offset, ttl());
memset(packet->buffer->data() + ipv4_payload_offset, 0, sizeof(TCPPacket));
auto& tcp_packet = *(TCPPacket*)(packet->buffer->data() + ipv4_payload_offset);
VERIFY(local_port());
tcp_packet.set_source_port(local_port());
tcp_packet.set_destination_port(peer_port());
tcp_packet.set_window_size(NumericLimits<u16>::max());
tcp_packet.set_sequence_number(m_sequence_number);
tcp_packet.set_data_offset(tcp_header_size / sizeof(u32));
tcp_packet.set_flags(flags);
if (flags & TCPFlags::ACK) {
m_last_ack_number_sent = m_ack_number;
m_last_ack_sent_time = kgettimeofday();
tcp_packet.set_ack_number(m_ack_number);
}
if (payload) {
if (auto result = payload->read(tcp_packet.payload(), payload_size); result.is_error()) {
routing_decision.adapter->release_packet_buffer(*packet);
return set_so_error(result);
}
}
if (flags & TCPFlags::SYN) {
++m_sequence_number;
} else {
m_sequence_number += payload_size;
}
if (has_mss_option) {
u16 mss = routing_decision.adapter->mtu() - sizeof(IPv4Packet) - sizeof(TCPPacket);
TCPOptionMSS mss_option { mss };
VERIFY(packet->buffer->size() >= ipv4_payload_offset + sizeof(TCPPacket) + sizeof(mss_option));
memcpy(packet->buffer->data() + ipv4_payload_offset + sizeof(TCPPacket), &mss_option, sizeof(mss_option));
}
tcp_packet.set_checksum(compute_tcp_checksum(local_address(), peer_address(), tcp_packet, payload_size));
routing_decision.adapter->send_packet(packet->bytes());
m_packets_out++;
m_bytes_out += buffer_size;
if (tcp_packet.has_syn() || payload_size > 0) {
m_unacked_packets.with_exclusive([&](auto& unacked_packets) {
unacked_packets.packets.append({ m_sequence_number, move(packet), ipv4_payload_offset, *routing_decision.adapter });
unacked_packets.size += payload_size;
enqueue_for_retransmit();
});
} else {
routing_decision.adapter->release_packet_buffer(*packet);
}
return KSuccess;
}
void TCPSocket::receive_tcp_packet(const TCPPacket& packet, u16 size)
{
if (packet.has_ack()) {
u32 ack_number = packet.ack_number();
dbgln_if(TCP_SOCKET_DEBUG, "TCPSocket: receive_tcp_packet: {}", ack_number);
int removed = 0;
m_unacked_packets.with_exclusive([&](auto& unacked_packets) {
while (!unacked_packets.packets.is_empty()) {
auto& packet = unacked_packets.packets.first();
dbgln_if(TCP_SOCKET_DEBUG, "TCPSocket: iterate: {}", packet.ack_number);
if (packet.ack_number <= ack_number) {
auto old_adapter = packet.adapter.strong_ref();
if (old_adapter)
old_adapter->release_packet_buffer(*packet.buffer);
TCPPacket& tcp_packet = *(TCPPacket*)(packet.buffer->buffer->data() + packet.ipv4_payload_offset);
auto payload_size = packet.buffer->buffer->data() + packet.buffer->buffer->size() - (u8*)tcp_packet.payload();
unacked_packets.size -= payload_size;
evaluate_block_conditions();
unacked_packets.packets.take_first();
removed++;
} else {
break;
}
}
if (unacked_packets.packets.is_empty()) {
m_retransmit_attempts = 0;
dequeue_for_retransmit();
}
dbgln_if(TCP_SOCKET_DEBUG, "TCPSocket: receive_tcp_packet acknowledged {} packets", removed);
});
}
m_packets_in++;
m_bytes_in += packet.header_size() + size;
}
bool TCPSocket::should_delay_next_ack() const
{
// FIXME: We don't know the MSS here so make a reasonable guess.
const size_t mss = 1500;
// RFC 1122 says we should send an ACK for every two full-sized segments.
if (m_ack_number >= m_last_ack_number_sent + 2 * mss)
return false;
// RFC 1122 says we should not delay ACKs for more than 500 milliseconds.
if (kgettimeofday() >= m_last_ack_sent_time + Time::from_milliseconds(500))
return false;
return true;
}
NetworkOrdered<u16> TCPSocket::compute_tcp_checksum(const IPv4Address& source, const IPv4Address& destination, const TCPPacket& packet, u16 payload_size)
{
struct [[gnu::packed]] PseudoHeader {
IPv4Address source;
IPv4Address destination;
u8 zero;
u8 protocol;
NetworkOrdered<u16> payload_size;
};
PseudoHeader pseudo_header { source, destination, 0, (u8)IPv4Protocol::TCP, packet.header_size() + payload_size };
u32 checksum = 0;
auto raw_pseudo_header = bit_cast<u16*>(&pseudo_header);
for (size_t i = 0; i < sizeof(pseudo_header) / sizeof(u16); ++i) {
checksum += AK::convert_between_host_and_network_endian(raw_pseudo_header[i]);
if (checksum > 0xffff)
checksum = (checksum >> 16) + (checksum & 0xffff);
}
auto raw_packet = bit_cast<u16*>(&packet);
for (size_t i = 0; i < packet.header_size() / sizeof(u16); ++i) {
checksum += AK::convert_between_host_and_network_endian(raw_packet[i]);
if (checksum > 0xffff)
checksum = (checksum >> 16) + (checksum & 0xffff);
}
VERIFY(packet.data_offset() * 4 == packet.header_size());
auto raw_payload = bit_cast<u16*>(packet.payload());
for (size_t i = 0; i < payload_size / sizeof(u16); ++i) {
checksum += AK::convert_between_host_and_network_endian(raw_payload[i]);
if (checksum > 0xffff)
checksum = (checksum >> 16) + (checksum & 0xffff);
}
if (payload_size & 1) {
u16 expanded_byte = ((const u8*)packet.payload())[payload_size - 1] << 8;
checksum += expanded_byte;
if (checksum > 0xffff)
checksum = (checksum >> 16) + (checksum & 0xffff);
}
return ~(checksum & 0xffff);
}
KResult TCPSocket::protocol_bind()
{
if (has_specific_local_address() && !m_adapter) {
m_adapter = NetworkingManagement::the().from_ipv4_address(local_address());
if (!m_adapter)
return set_so_error(EADDRNOTAVAIL);
}
return KSuccess;
}
KResult TCPSocket::protocol_listen(bool did_allocate_port)
{
if (!did_allocate_port) {
bool ok = sockets_by_tuple().with_exclusive([&](auto& table) -> bool {
if (table.contains(tuple()))
return false;
table.set(tuple(), this);
return true;
});
if (!ok)
return set_so_error(EADDRINUSE);
}
set_direction(Direction::Passive);
set_state(State::Listen);
set_setup_state(SetupState::Completed);
return KSuccess;
}
KResult TCPSocket::protocol_connect(OpenFileDescription& description, ShouldBlock should_block)
{
MutexLocker locker(mutex());
auto routing_decision = route_to(peer_address(), local_address());
if (routing_decision.is_zero())
return set_so_error(EHOSTUNREACH);
if (!has_specific_local_address())
set_local_address(routing_decision.adapter->ipv4_address());
if (auto result = allocate_local_port_if_needed(); result.error_or_port.is_error())
return result.error_or_port.error();
m_sequence_number = get_good_random<u32>();
m_ack_number = 0;
set_setup_state(SetupState::InProgress);
TRY(send_tcp_packet(TCPFlags::SYN));
m_state = State::SynSent;
set_role(Role::Connecting);
m_direction = Direction::Outgoing;
evaluate_block_conditions();
if (should_block == ShouldBlock::Yes) {
locker.unlock();
auto unblock_flags = Thread::FileBlocker::BlockFlags::None;
if (Thread::current()->block<Thread::ConnectBlocker>({}, description, unblock_flags).was_interrupted())
return set_so_error(EINTR);
locker.lock();
VERIFY(setup_state() == SetupState::Completed);
if (has_error()) { // TODO: check unblock_flags
set_role(Role::None);
if (error() == TCPSocket::Error::RetransmitTimeout)
return set_so_error(ETIMEDOUT);
else
return set_so_error(ECONNREFUSED);
}
return KSuccess;
}
return set_so_error(EINPROGRESS);
}
KResultOr<u16> TCPSocket::protocol_allocate_local_port()
{
constexpr u16 first_ephemeral_port = 32768;
constexpr u16 last_ephemeral_port = 60999;
constexpr u16 ephemeral_port_range_size = last_ephemeral_port - first_ephemeral_port;
u16 first_scan_port = first_ephemeral_port + get_good_random<u16>() % ephemeral_port_range_size;
return sockets_by_tuple().with_exclusive([&](auto& table) -> KResultOr<u16> {
for (u16 port = first_scan_port;;) {
IPv4SocketTuple proposed_tuple(local_address(), port, peer_address(), peer_port());
auto it = table.find(proposed_tuple);
if (it == table.end()) {
set_local_port(port);
table.set(proposed_tuple, this);
return port;
}
++port;
if (port > last_ephemeral_port)
port = first_ephemeral_port;
if (port == first_scan_port)
break;
}
return set_so_error(EADDRINUSE);
});
}
bool TCPSocket::protocol_is_disconnected() const
{
switch (m_state) {
case State::Closed:
case State::CloseWait:
case State::LastAck:
case State::FinWait1:
case State::FinWait2:
case State::Closing:
case State::TimeWait:
return true;
default:
return false;
}
}
void TCPSocket::shut_down_for_writing()
{
if (state() == State::Established) {
dbgln_if(TCP_SOCKET_DEBUG, " Sending FIN/ACK from Established and moving into FinWait1");
[[maybe_unused]] auto rc = send_tcp_packet(TCPFlags::FIN | TCPFlags::ACK);
set_state(State::FinWait1);
} else {
dbgln(" Shutting down TCPSocket for writing but not moving to FinWait1 since state is {}", to_string(state()));
}
}
KResult TCPSocket::close()
{
MutexLocker locker(mutex());
auto result = IPv4Socket::close();
if (state() == State::CloseWait) {
dbgln_if(TCP_SOCKET_DEBUG, " Sending FIN from CloseWait and moving into LastAck");
[[maybe_unused]] auto rc = send_tcp_packet(TCPFlags::FIN | TCPFlags::ACK);
set_state(State::LastAck);
}
if (state() != State::Closed && state() != State::Listen)
closing_sockets().with_exclusive([&](auto& table) {
table.set(tuple(), *this);
});
return result;
}
static Singleton<MutexProtected<TCPSocket::RetransmitList>> s_sockets_for_retransmit;
MutexProtected<TCPSocket::RetransmitList>& TCPSocket::sockets_for_retransmit()
{
return *s_sockets_for_retransmit;
}
void TCPSocket::enqueue_for_retransmit()
{
sockets_for_retransmit().with_exclusive([&](auto& list) {
list.append(*this);
});
}
void TCPSocket::dequeue_for_retransmit()
{
sockets_for_retransmit().with_exclusive([&](auto& list) {
list.remove(*this);
});
}
void TCPSocket::retransmit_packets()
{
auto now = kgettimeofday();
// RFC6298 says we should have at least one second between retransmits. According to
// RFC1122 we must do exponential backoff - even for SYN packets.
i64 retransmit_interval = 1;
for (decltype(m_retransmit_attempts) i = 0; i < m_retransmit_attempts; i++)
retransmit_interval *= 2;
if (m_last_retransmit_time > now - Time::from_seconds(retransmit_interval))
return;
dbgln_if(TCP_SOCKET_DEBUG, "TCPSocket({}) handling retransmit", this);
m_last_retransmit_time = now;
++m_retransmit_attempts;
if (m_retransmit_attempts > maximum_retransmits) {
set_state(TCPSocket::State::Closed);
set_error(TCPSocket::Error::RetransmitTimeout);
set_setup_state(Socket::SetupState::Completed);
return;
}
auto routing_decision = route_to(peer_address(), local_address(), bound_interface());
if (routing_decision.is_zero())
return;
m_unacked_packets.with_exclusive([&](auto& unacked_packets) {
for (auto& packet : unacked_packets.packets) {
packet.tx_counter++;
if constexpr (TCP_SOCKET_DEBUG) {
auto& tcp_packet = *(const TCPPacket*)(packet.buffer->buffer->data() + packet.ipv4_payload_offset);
dbgln("Sending TCP packet from {}:{} to {}:{} with ({}{}{}{}) seq_no={}, ack_no={}, tx_counter={}",
local_address(), local_port(),
peer_address(), peer_port(),
(tcp_packet.has_syn() ? "SYN " : ""),
(tcp_packet.has_ack() ? "ACK " : ""),
(tcp_packet.has_fin() ? "FIN " : ""),
(tcp_packet.has_rst() ? "RST " : ""),
tcp_packet.sequence_number(),
tcp_packet.ack_number(),
packet.tx_counter);
}
size_t ipv4_payload_offset = routing_decision.adapter->ipv4_payload_offset();
if (ipv4_payload_offset != packet.ipv4_payload_offset) {
// FIXME: Add support for this. This can happen if after a route change
// we ended up on another adapter which doesn't have the same layer 2 type
// like the previous adapter.
VERIFY_NOT_REACHED();
}
auto packet_buffer = packet.buffer->bytes();
routing_decision.adapter->fill_in_ipv4_header(*packet.buffer,
local_address(), routing_decision.next_hop, peer_address(),
IPv4Protocol::TCP, packet_buffer.size() - ipv4_payload_offset, ttl());
routing_decision.adapter->send_packet(packet_buffer);
m_packets_out++;
m_bytes_out += packet_buffer.size();
}
});
}
bool TCPSocket::can_write(const OpenFileDescription& file_description, size_t size) const
{
if (!IPv4Socket::can_write(file_description, size))
return false;
if (m_state == State::SynSent || m_state == State::SynReceived)
return false;
if (!file_description.is_blocking())
return true;
return m_unacked_packets.with_shared([&](auto& unacked_packets) {
return unacked_packets.size + size <= m_send_window_size;
});
}
}