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ladybird/Kernel/Net/IPv4Socket.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

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26 KiB
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/*
* Copyright (c) 2018-2020, Andreas Kling <kling@serenityos.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <AK/Singleton.h>
#include <AK/StringBuilder.h>
#include <Kernel/Debug.h>
#include <Kernel/FileSystem/OpenFileDescription.h>
#include <Kernel/Net/ARP.h>
#include <Kernel/Net/ICMP.h>
#include <Kernel/Net/IPv4.h>
#include <Kernel/Net/IPv4Socket.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/Net/UDP.h>
#include <Kernel/Net/UDPSocket.h>
#include <Kernel/Process.h>
#include <Kernel/UnixTypes.h>
#include <LibC/errno_numbers.h>
#include <LibC/sys/ioctl_numbers.h>
namespace Kernel {
static Singleton<MutexProtected<IPv4Socket::List>> s_all_sockets;
using BlockFlags = Thread::OpenFileDescriptionBlocker::BlockFlags;
MutexProtected<IPv4Socket::List>& IPv4Socket::all_sockets()
{
return *s_all_sockets;
}
KResultOr<NonnullOwnPtr<DoubleBuffer>> IPv4Socket::try_create_receive_buffer()
{
return DoubleBuffer::try_create(256 * KiB);
}
KResultOr<NonnullRefPtr<Socket>> IPv4Socket::create(int type, int protocol)
{
auto receive_buffer = TRY(IPv4Socket::try_create_receive_buffer());
if (type == SOCK_STREAM)
return TRY(TCPSocket::try_create(protocol, move(receive_buffer)));
if (type == SOCK_DGRAM)
return TRY(UDPSocket::try_create(protocol, move(receive_buffer)));
if (type == SOCK_RAW) {
auto raw_socket = adopt_ref_if_nonnull(new (nothrow) IPv4Socket(type, protocol, move(receive_buffer), {}));
if (raw_socket)
return raw_socket.release_nonnull();
return ENOMEM;
}
return EINVAL;
}
IPv4Socket::IPv4Socket(int type, int protocol, NonnullOwnPtr<DoubleBuffer> receive_buffer, OwnPtr<KBuffer> optional_scratch_buffer)
: Socket(AF_INET, type, protocol)
, m_receive_buffer(move(receive_buffer))
, m_scratch_buffer(move(optional_scratch_buffer))
{
dbgln_if(IPV4_SOCKET_DEBUG, "IPv4Socket({}) created with type={}, protocol={}", this, type, protocol);
m_buffer_mode = type == SOCK_STREAM ? BufferMode::Bytes : BufferMode::Packets;
if (m_buffer_mode == BufferMode::Bytes) {
VERIFY(m_scratch_buffer);
}
all_sockets().with_exclusive([&](auto& table) {
table.append(*this);
});
}
IPv4Socket::~IPv4Socket()
{
all_sockets().with_exclusive([&](auto& table) {
table.remove(*this);
});
}
void IPv4Socket::get_local_address(sockaddr* address, socklen_t* address_size)
{
sockaddr_in local_address = { AF_INET, htons(m_local_port), { m_local_address.to_in_addr_t() }, { 0 } };
memcpy(address, &local_address, min(static_cast<size_t>(*address_size), sizeof(sockaddr_in)));
*address_size = sizeof(sockaddr_in);
}
void IPv4Socket::get_peer_address(sockaddr* address, socklen_t* address_size)
{
sockaddr_in peer_address = { AF_INET, htons(m_peer_port), { m_peer_address.to_in_addr_t() }, { 0 } };
memcpy(address, &peer_address, min(static_cast<size_t>(*address_size), sizeof(sockaddr_in)));
*address_size = sizeof(sockaddr_in);
}
KResult IPv4Socket::bind(Userspace<const sockaddr*> user_address, socklen_t address_size)
{
VERIFY(setup_state() == SetupState::Unstarted);
if (address_size != sizeof(sockaddr_in))
return set_so_error(EINVAL);
sockaddr_in address {};
SOCKET_TRY(copy_from_user(&address, user_address, sizeof(sockaddr_in)));
if (address.sin_family != AF_INET)
return set_so_error(EINVAL);
auto requested_local_port = ntohs(address.sin_port);
if (!Process::current().is_superuser()) {
if (requested_local_port > 0 && requested_local_port < 1024) {
dbgln("UID {} attempted to bind {} to port {}", Process::current().uid(), class_name(), requested_local_port);
return set_so_error(EACCES);
}
}
m_local_address = IPv4Address((const u8*)&address.sin_addr.s_addr);
m_local_port = requested_local_port;
dbgln_if(IPV4_SOCKET_DEBUG, "IPv4Socket::bind {}({}) to {}:{}", class_name(), this, m_local_address, m_local_port);
return protocol_bind();
}
KResult IPv4Socket::listen(size_t backlog)
{
MutexLocker locker(mutex());
auto result = allocate_local_port_if_needed();
if (result.error_or_port.is_error() && result.error_or_port.error() != ENOPROTOOPT)
return result.error_or_port.error();
set_backlog(backlog);
set_role(Role::Listener);
evaluate_block_conditions();
dbgln_if(IPV4_SOCKET_DEBUG, "IPv4Socket({}) listening with backlog={}", this, backlog);
return protocol_listen(result.did_allocate);
}
KResult IPv4Socket::connect(OpenFileDescription& description, Userspace<const sockaddr*> address, socklen_t address_size, ShouldBlock should_block)
{
if (address_size != sizeof(sockaddr_in))
return set_so_error(EINVAL);
u16 sa_family_copy;
auto* user_address = reinterpret_cast<const sockaddr*>(address.unsafe_userspace_ptr());
SOCKET_TRY(copy_from_user(&sa_family_copy, &user_address->sa_family, sizeof(u16)));
if (sa_family_copy != AF_INET)
return set_so_error(EINVAL);
if (m_role == Role::Connected)
return set_so_error(EISCONN);
sockaddr_in safe_address {};
SOCKET_TRY(copy_from_user(&safe_address, (sockaddr_in const*)user_address, sizeof(sockaddr_in)));
m_peer_address = IPv4Address((const u8*)&safe_address.sin_addr.s_addr);
if (m_peer_address == IPv4Address { 0, 0, 0, 0 })
m_peer_address = IPv4Address { 127, 0, 0, 1 };
m_peer_port = ntohs(safe_address.sin_port);
return protocol_connect(description, should_block);
}
bool IPv4Socket::can_read(const OpenFileDescription&, size_t) const
{
if (m_role == Role::Listener)
return can_accept();
if (protocol_is_disconnected())
return true;
return m_can_read;
}
bool IPv4Socket::can_write(const OpenFileDescription&, size_t) const
{
return true;
}
PortAllocationResult IPv4Socket::allocate_local_port_if_needed()
{
MutexLocker locker(mutex());
if (m_local_port)
return { m_local_port, false };
auto port_or_error = protocol_allocate_local_port();
if (port_or_error.is_error())
return { port_or_error.error(), false };
m_local_port = port_or_error.value();
return { m_local_port, true };
}
KResultOr<size_t> IPv4Socket::sendto(OpenFileDescription&, const UserOrKernelBuffer& data, size_t data_length, [[maybe_unused]] int flags, Userspace<const sockaddr*> addr, socklen_t addr_length)
{
MutexLocker locker(mutex());
if (addr && addr_length != sizeof(sockaddr_in))
return set_so_error(EINVAL);
if (addr) {
sockaddr_in ia {};
SOCKET_TRY(copy_from_user(&ia, Userspace<const sockaddr_in*>(addr.ptr())));
if (ia.sin_family != AF_INET) {
dmesgln("sendto: Bad address family: {} is not AF_INET", ia.sin_family);
return set_so_error(EAFNOSUPPORT);
}
m_peer_address = IPv4Address((const u8*)&ia.sin_addr.s_addr);
m_peer_port = ntohs(ia.sin_port);
}
if (!is_connected() && m_peer_address.is_zero())
return set_so_error(EPIPE);
auto routing_decision = route_to(m_peer_address, m_local_address, bound_interface());
if (routing_decision.is_zero())
return set_so_error(EHOSTUNREACH);
if (m_local_address.to_u32() == 0)
m_local_address = routing_decision.adapter->ipv4_address();
if (auto result = allocate_local_port_if_needed(); result.error_or_port.is_error() && result.error_or_port.error() != ENOPROTOOPT)
return result.error_or_port.error();
dbgln_if(IPV4_SOCKET_DEBUG, "sendto: destination={}:{}", m_peer_address, m_peer_port);
if (type() == SOCK_RAW) {
auto ipv4_payload_offset = routing_decision.adapter->ipv4_payload_offset();
data_length = min(data_length, routing_decision.adapter->mtu() - ipv4_payload_offset);
auto packet = routing_decision.adapter->acquire_packet_buffer(ipv4_payload_offset + data_length);
if (!packet)
return set_so_error(ENOMEM);
routing_decision.adapter->fill_in_ipv4_header(*packet, local_address(), routing_decision.next_hop,
m_peer_address, (IPv4Protocol)protocol(), data_length, m_ttl);
if (auto result = data.read(packet->buffer->data() + ipv4_payload_offset, data_length); result.is_error()) {
routing_decision.adapter->release_packet_buffer(*packet);
return set_so_error(result);
}
routing_decision.adapter->send_packet(packet->bytes());
routing_decision.adapter->release_packet_buffer(*packet);
return data_length;
}
auto nsent_or_error = protocol_send(data, data_length);
if (!nsent_or_error.is_error())
Thread::current()->did_ipv4_socket_write(nsent_or_error.value());
return nsent_or_error;
}
KResultOr<size_t> IPv4Socket::receive_byte_buffered(OpenFileDescription& description, UserOrKernelBuffer& buffer, size_t buffer_length, int flags, Userspace<sockaddr*>, Userspace<socklen_t*>)
{
MutexLocker locker(mutex());
VERIFY(m_receive_buffer);
if (m_receive_buffer->is_empty()) {
if (protocol_is_disconnected())
return 0;
if (!description.is_blocking())
return set_so_error(EAGAIN);
locker.unlock();
auto unblocked_flags = BlockFlags::None;
auto res = Thread::current()->block<Thread::ReadBlocker>({}, description, unblocked_flags);
locker.lock();
if (!has_flag(unblocked_flags, BlockFlags::Read)) {
if (res.was_interrupted())
return set_so_error(EINTR);
// Unblocked due to timeout.
return set_so_error(EAGAIN);
}
}
KResultOr<size_t> nreceived_or_error { 0 };
if (flags & MSG_PEEK)
nreceived_or_error = m_receive_buffer->peek(buffer, buffer_length);
else
nreceived_or_error = m_receive_buffer->read(buffer, buffer_length);
if (!nreceived_or_error.is_error() && nreceived_or_error.value() > 0 && !(flags & MSG_PEEK))
Thread::current()->did_ipv4_socket_read(nreceived_or_error.value());
set_can_read(!m_receive_buffer->is_empty());
return nreceived_or_error;
}
KResultOr<size_t> IPv4Socket::receive_packet_buffered(OpenFileDescription& description, UserOrKernelBuffer& buffer, size_t buffer_length, int flags, Userspace<sockaddr*> addr, Userspace<socklen_t*> addr_length, Time& packet_timestamp)
{
MutexLocker locker(mutex());
ReceivedPacket taken_packet;
ReceivedPacket* packet { nullptr };
{
if (m_receive_queue.is_empty()) {
// FIXME: Shouldn't this return ENOTCONN instead of EOF?
// But if so, we still need to deliver at least one EOF read to userspace.. right?
if (protocol_is_disconnected())
return 0;
if (!description.is_blocking())
return set_so_error(EAGAIN);
}
if (!m_receive_queue.is_empty()) {
if (flags & MSG_PEEK) {
packet = &m_receive_queue.first();
} else {
taken_packet = m_receive_queue.take_first();
packet = &taken_packet;
}
set_can_read(!m_receive_queue.is_empty());
dbgln_if(IPV4_SOCKET_DEBUG, "IPv4Socket({}): recvfrom without blocking {} bytes, packets in queue: {}",
this,
packet->data->size(),
m_receive_queue.size());
}
}
if (!packet) {
if (protocol_is_disconnected()) {
dbgln("IPv4Socket({}) is protocol-disconnected, returning 0 in recvfrom!", this);
return 0;
}
locker.unlock();
auto unblocked_flags = BlockFlags::None;
auto res = Thread::current()->block<Thread::ReadBlocker>({}, description, unblocked_flags);
locker.lock();
if (!has_flag(unblocked_flags, BlockFlags::Read)) {
if (res.was_interrupted())
return set_so_error(EINTR);
// Unblocked due to timeout.
return set_so_error(EAGAIN);
}
VERIFY(m_can_read);
VERIFY(!m_receive_queue.is_empty());
if (flags & MSG_PEEK) {
packet = &m_receive_queue.first();
} else {
taken_packet = m_receive_queue.take_first();
packet = &taken_packet;
}
set_can_read(!m_receive_queue.is_empty());
dbgln_if(IPV4_SOCKET_DEBUG, "IPv4Socket({}): recvfrom with blocking {} bytes, packets in queue: {}",
this,
packet->data->size(),
m_receive_queue.size());
}
VERIFY(packet->data);
packet_timestamp = packet->timestamp;
if (addr) {
dbgln_if(IPV4_SOCKET_DEBUG, "Incoming packet is from: {}:{}", packet->peer_address, packet->peer_port);
sockaddr_in out_addr {};
memcpy(&out_addr.sin_addr, &packet->peer_address, sizeof(IPv4Address));
out_addr.sin_port = htons(packet->peer_port);
out_addr.sin_family = AF_INET;
Userspace<sockaddr_in*> dest_addr = addr.ptr();
SOCKET_TRY(copy_to_user(dest_addr, &out_addr));
socklen_t out_length = sizeof(sockaddr_in);
VERIFY(addr_length);
SOCKET_TRY(copy_to_user(addr_length, &out_length));
}
if (type() == SOCK_RAW) {
size_t bytes_written = min(packet->data->size(), buffer_length);
SOCKET_TRY(buffer.write(packet->data->data(), bytes_written));
return bytes_written;
}
return protocol_receive(packet->data->bytes(), buffer, buffer_length, flags);
}
KResultOr<size_t> IPv4Socket::recvfrom(OpenFileDescription& description, UserOrKernelBuffer& buffer, size_t buffer_length, int flags, Userspace<sockaddr*> user_addr, Userspace<socklen_t*> user_addr_length, Time& packet_timestamp)
{
if (user_addr_length) {
socklen_t addr_length;
SOCKET_TRY(copy_from_user(&addr_length, user_addr_length.unsafe_userspace_ptr()));
if (addr_length < sizeof(sockaddr_in))
return set_so_error(EINVAL);
}
dbgln_if(IPV4_SOCKET_DEBUG, "recvfrom: type={}, local_port={}", type(), local_port());
KResultOr<size_t> nreceived = 0;
if (buffer_mode() == BufferMode::Bytes)
nreceived = receive_byte_buffered(description, buffer, buffer_length, flags, user_addr, user_addr_length);
else
nreceived = receive_packet_buffered(description, buffer, buffer_length, flags, user_addr, user_addr_length, packet_timestamp);
if (!nreceived.is_error())
Thread::current()->did_ipv4_socket_read(nreceived.value());
return nreceived;
}
bool IPv4Socket::did_receive(const IPv4Address& source_address, u16 source_port, ReadonlyBytes packet, const Time& packet_timestamp)
{
MutexLocker locker(mutex());
if (is_shut_down_for_reading())
return false;
auto packet_size = packet.size();
if (buffer_mode() == BufferMode::Bytes) {
VERIFY(m_receive_buffer);
size_t space_in_receive_buffer = m_receive_buffer->space_for_writing();
if (packet_size > space_in_receive_buffer) {
dbgln("IPv4Socket({}): did_receive refusing packet since buffer is full.", this);
VERIFY(m_can_read);
return false;
}
auto scratch_buffer = UserOrKernelBuffer::for_kernel_buffer(m_scratch_buffer->data());
auto nreceived_or_error = protocol_receive(packet, scratch_buffer, m_scratch_buffer->size(), 0);
if (nreceived_or_error.is_error())
return false;
auto nwritten_or_error = m_receive_buffer->write(scratch_buffer, nreceived_or_error.value());
if (nwritten_or_error.is_error())
return false;
set_can_read(!m_receive_buffer->is_empty());
} else {
if (m_receive_queue.size() > 2000) {
dbgln("IPv4Socket({}): did_receive refusing packet since queue is full.", this);
return false;
}
auto data_or_error = KBuffer::try_create_with_bytes(packet);
if (data_or_error.is_error()) {
dbgln("IPv4Socket: did_receive unable to allocate storage for incoming packet.");
return false;
}
m_receive_queue.append({ source_address, source_port, packet_timestamp, data_or_error.release_value() });
set_can_read(true);
}
m_bytes_received += packet_size;
if constexpr (IPV4_SOCKET_DEBUG) {
if (buffer_mode() == BufferMode::Bytes)
dbgln("IPv4Socket({}): did_receive {} bytes, total_received={}", this, packet_size, m_bytes_received);
else
dbgln("IPv4Socket({}): did_receive {} bytes, total_received={}, packets in queue: {}",
this,
packet_size,
m_bytes_received,
m_receive_queue.size());
}
return true;
}
String IPv4Socket::absolute_path(const OpenFileDescription&) const
{
if (m_role == Role::None)
return "socket";
StringBuilder builder;
builder.append("socket:");
builder.appendff("{}:{}", m_local_address.to_string(), m_local_port);
if (m_role == Role::Accepted || m_role == Role::Connected)
builder.appendff(" / {}:{}", m_peer_address.to_string(), m_peer_port);
switch (m_role) {
case Role::Listener:
builder.append(" (listening)");
break;
case Role::Accepted:
builder.append(" (accepted)");
break;
case Role::Connected:
builder.append(" (connected)");
break;
case Role::Connecting:
builder.append(" (connecting)");
break;
default:
VERIFY_NOT_REACHED();
}
return builder.to_string();
}
KResult IPv4Socket::setsockopt(int level, int option, Userspace<const void*> user_value, socklen_t user_value_size)
{
if (level != IPPROTO_IP)
return Socket::setsockopt(level, option, user_value, user_value_size);
switch (option) {
case IP_TTL: {
if (user_value_size < sizeof(int))
return EINVAL;
int value;
TRY(copy_from_user(&value, static_ptr_cast<const int*>(user_value)));
if (value < 0 || value > 255)
return EINVAL;
m_ttl = value;
return KSuccess;
}
case IP_MULTICAST_LOOP: {
if (user_value_size != 1)
return EINVAL;
u8 value;
TRY(copy_from_user(&value, static_ptr_cast<const u8*>(user_value)));
if (value != 0 && value != 1)
return EINVAL;
m_multicast_loop = value;
return KSuccess;
}
case IP_ADD_MEMBERSHIP: {
if (user_value_size != sizeof(ip_mreq))
return EINVAL;
ip_mreq mreq;
TRY(copy_from_user(&mreq, static_ptr_cast<const ip_mreq*>(user_value)));
if (mreq.imr_interface.s_addr != INADDR_ANY)
return ENOTSUP;
IPv4Address address { (const u8*)&mreq.imr_multiaddr.s_addr };
if (!m_multicast_memberships.contains_slow(address))
m_multicast_memberships.append(address);
return KSuccess;
}
case IP_DROP_MEMBERSHIP: {
if (user_value_size != sizeof(ip_mreq))
return EINVAL;
ip_mreq mreq;
TRY(copy_from_user(&mreq, static_ptr_cast<const ip_mreq*>(user_value)));
if (mreq.imr_interface.s_addr != INADDR_ANY)
return ENOTSUP;
IPv4Address address { (const u8*)&mreq.imr_multiaddr.s_addr };
m_multicast_memberships.remove_first_matching([&address](auto& a) { return a == address; });
return KSuccess;
}
default:
return ENOPROTOOPT;
}
}
KResult IPv4Socket::getsockopt(OpenFileDescription& description, int level, int option, Userspace<void*> value, Userspace<socklen_t*> value_size)
{
if (level != IPPROTO_IP)
return Socket::getsockopt(description, level, option, value, value_size);
socklen_t size;
TRY(copy_from_user(&size, value_size.unsafe_userspace_ptr()));
switch (option) {
case IP_TTL:
if (size < sizeof(int))
return EINVAL;
TRY(copy_to_user(static_ptr_cast<int*>(value), (int*)&m_ttl));
size = sizeof(int);
return copy_to_user(value_size, &size);
case IP_MULTICAST_LOOP: {
if (size < 1)
return EINVAL;
TRY(copy_to_user(static_ptr_cast<u8*>(value), (const u8*)&m_multicast_loop));
size = 1;
return copy_to_user(value_size, &size);
}
default:
return ENOPROTOOPT;
}
}
KResult IPv4Socket::ioctl(OpenFileDescription&, unsigned request, Userspace<void*> arg)
{
REQUIRE_PROMISE(inet);
auto ioctl_route = [request, arg]() -> KResult {
auto user_route = static_ptr_cast<rtentry*>(arg);
rtentry route;
TRY(copy_from_user(&route, user_route));
Userspace<const char*> user_rt_dev((FlatPtr)route.rt_dev);
auto ifname = TRY(try_copy_kstring_from_user(user_rt_dev, IFNAMSIZ));
auto adapter = NetworkingManagement::the().lookup_by_name(ifname->view());
if (!adapter)
return ENODEV;
switch (request) {
case SIOCADDRT:
if (!Process::current().is_superuser())
return EPERM;
if (route.rt_gateway.sa_family != AF_INET)
return EAFNOSUPPORT;
if ((route.rt_flags & (RTF_UP | RTF_GATEWAY)) != (RTF_UP | RTF_GATEWAY))
return EINVAL; // FIXME: Find the correct value to return
adapter->set_ipv4_gateway(IPv4Address(((sockaddr_in&)route.rt_gateway).sin_addr.s_addr));
return KSuccess;
case SIOCDELRT:
// FIXME: Support gateway deletion
return KSuccess;
}
return EINVAL;
};
auto ioctl_arp = [request, arg]() -> KResult {
auto user_req = static_ptr_cast<arpreq*>(arg);
arpreq arp_req;
TRY(copy_from_user(&arp_req, user_req));
switch (request) {
case SIOCSARP:
if (!Process::current().is_superuser())
return EPERM;
if (arp_req.arp_pa.sa_family != AF_INET)
return EAFNOSUPPORT;
update_arp_table(IPv4Address(((sockaddr_in&)arp_req.arp_pa).sin_addr.s_addr), *(MACAddress*)&arp_req.arp_ha.sa_data[0], UpdateArp::Set);
return KSuccess;
case SIOCDARP:
if (!Process::current().is_superuser())
return EPERM;
if (arp_req.arp_pa.sa_family != AF_INET)
return EAFNOSUPPORT;
update_arp_table(IPv4Address(((sockaddr_in&)arp_req.arp_pa).sin_addr.s_addr), *(MACAddress*)&arp_req.arp_ha.sa_data[0], UpdateArp::Delete);
return KSuccess;
}
return EINVAL;
};
auto ioctl_interface = [request, arg]() -> KResult {
auto user_ifr = static_ptr_cast<ifreq*>(arg);
ifreq ifr;
TRY(copy_from_user(&ifr, user_ifr));
char namebuf[IFNAMSIZ + 1];
memcpy(namebuf, ifr.ifr_name, IFNAMSIZ);
namebuf[sizeof(namebuf) - 1] = '\0';
auto adapter = NetworkingManagement::the().lookup_by_name(namebuf);
if (!adapter)
return ENODEV;
switch (request) {
case SIOCSIFADDR:
if (!Process::current().is_superuser())
return EPERM;
if (ifr.ifr_addr.sa_family != AF_INET)
return EAFNOSUPPORT;
adapter->set_ipv4_address(IPv4Address(((sockaddr_in&)ifr.ifr_addr).sin_addr.s_addr));
return KSuccess;
case SIOCSIFNETMASK:
if (!Process::current().is_superuser())
return EPERM;
if (ifr.ifr_addr.sa_family != AF_INET)
return EAFNOSUPPORT;
adapter->set_ipv4_netmask(IPv4Address(((sockaddr_in&)ifr.ifr_netmask).sin_addr.s_addr));
return KSuccess;
case SIOCGIFADDR: {
auto ip4_addr = adapter->ipv4_address().to_u32();
auto& socket_address_in = reinterpret_cast<sockaddr_in&>(ifr.ifr_addr);
socket_address_in.sin_family = AF_INET;
socket_address_in.sin_addr.s_addr = ip4_addr;
return copy_to_user(user_ifr, &ifr);
}
case SIOCGIFNETMASK: {
auto ip4_netmask = adapter->ipv4_netmask().to_u32();
auto& socket_address_in = reinterpret_cast<sockaddr_in&>(ifr.ifr_addr);
socket_address_in.sin_family = AF_INET;
// NOTE: NOT ifr_netmask.
socket_address_in.sin_addr.s_addr = ip4_netmask;
return copy_to_user(user_ifr, &ifr);
}
case SIOCGIFHWADDR: {
auto mac_address = adapter->mac_address();
ifr.ifr_hwaddr.sa_family = AF_INET;
mac_address.copy_to(Bytes { ifr.ifr_hwaddr.sa_data, sizeof(ifr.ifr_hwaddr.sa_data) });
return copy_to_user(user_ifr, &ifr);
}
case SIOCGIFBRDADDR: {
// Broadcast address is basically the reverse of the netmask, i.e.
// instead of zeroing out the end, you OR with 1 instead.
auto ip4_netmask = adapter->ipv4_netmask().to_u32();
auto broadcast_addr = adapter->ipv4_address().to_u32() | ~ip4_netmask;
auto& socket_address_in = reinterpret_cast<sockaddr_in&>(ifr.ifr_addr);
socket_address_in.sin_family = AF_INET;
socket_address_in.sin_addr.s_addr = broadcast_addr;
return copy_to_user(user_ifr, &ifr);
}
case SIOCGIFMTU: {
auto ip4_metric = adapter->mtu();
ifr.ifr_addr.sa_family = AF_INET;
ifr.ifr_metric = ip4_metric;
return copy_to_user(user_ifr, &ifr);
}
case SIOCGIFFLAGS: {
// FIXME: stub!
constexpr short flags = 1;
ifr.ifr_addr.sa_family = AF_INET;
ifr.ifr_flags = flags;
return copy_to_user(user_ifr, &ifr);
}
case SIOCGIFCONF: {
// FIXME: stub!
return EINVAL;
}
}
return EINVAL;
};
switch (request) {
case SIOCSIFADDR:
case SIOCSIFNETMASK:
case SIOCGIFADDR:
case SIOCGIFHWADDR:
case SIOCGIFNETMASK:
case SIOCGIFBRDADDR:
case SIOCGIFMTU:
case SIOCGIFFLAGS:
case SIOCGIFCONF:
return ioctl_interface();
case SIOCADDRT:
case SIOCDELRT:
return ioctl_route();
case SIOCSARP:
case SIOCDARP:
return ioctl_arp();
case FIONREAD: {
int readable = m_receive_buffer->immediately_readable();
return copy_to_user(Userspace<int*>(arg), &readable);
}
}
return EINVAL;
}
KResult IPv4Socket::close()
{
[[maybe_unused]] auto rc = shutdown(SHUT_RDWR);
return KSuccess;
}
void IPv4Socket::shut_down_for_reading()
{
Socket::shut_down_for_reading();
set_can_read(true);
}
void IPv4Socket::set_can_read(bool value)
{
m_can_read = value;
if (value)
evaluate_block_conditions();
}
void IPv4Socket::drop_receive_buffer()
{
m_receive_buffer = nullptr;
}
}
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