/*
* Copyright (c) 2018-2021, Andreas Kling <kling@serenityos.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <AK/HashMap.h>
#include <AK/Singleton.h>
#include <Kernel/Debug.h>
#include <Kernel/Net/LoopbackAdapter.h>
#include <Kernel/Net/NetworkTask.h>
#include <Kernel/Net/NetworkingManagement.h>
#include <Kernel/Net/Routing.h>
#include <Kernel/Thread.h>
namespace Kernel {
static AK::Singleton<Lockable<HashMap<IPv4Address, MACAddress>>> s_arp_table;
class ARPTableBlocker : public Thread::Blocker {
public:
ARPTableBlocker(IPv4Address ip_addr, Optional<MACAddress>& addr);
virtual const char* state_string() const override { return "Routing (ARP)"; }
virtual Type blocker_type() const override { return Type::Routing; }
virtual bool should_block() override { return m_should_block; }
virtual void not_blocking(bool) override;
bool unblock(bool from_add_blocker, const IPv4Address& ip_addr, const MACAddress& addr)
{
if (m_ip_addr != ip_addr)
return false;
{
ScopedSpinLock lock(m_lock);
if (m_did_unblock)
return false;
m_did_unblock = true;
m_addr = addr;
}
if (!from_add_blocker)
unblock_from_blocker();
return true;
}
const IPv4Address& ip_addr() const { return m_ip_addr; }
private:
const IPv4Address m_ip_addr;
Optional<MACAddress>& m_addr;
bool m_did_unblock { false };
bool m_should_block { true };
};
class ARPTableBlockCondition : public Thread::BlockCondition {
public:
void unblock(const IPv4Address& ip_addr, const MACAddress& addr)
{
BlockCondition::unblock([&](auto& b, void*, bool&) {
VERIFY(b.blocker_type() == Thread::Blocker::Type::Routing);
auto& blocker = static_cast<ARPTableBlocker&>(b);
return blocker.unblock(false, ip_addr, addr);
});
}
protected:
virtual bool should_add_blocker(Thread::Blocker& b, void*) override
{
VERIFY(b.blocker_type() == Thread::Blocker::Type::Routing);
auto& blocker = static_cast<ARPTableBlocker&>(b);
auto val = s_arp_table->resource().get(blocker.ip_addr());
if (!val.has_value())
return true;
return blocker.unblock(true, blocker.ip_addr(), val.value());
}
};
static AK::Singleton<ARPTableBlockCondition> s_arp_table_block_condition;
ARPTableBlocker::ARPTableBlocker(IPv4Address ip_addr, Optional<MACAddress>& addr)
: m_ip_addr(ip_addr)
, m_addr(addr)
{
if (!set_block_condition(*s_arp_table_block_condition))
m_should_block = false;
}
void ARPTableBlocker::not_blocking(bool timeout_in_past)
{
VERIFY(timeout_in_past || !m_should_block);
auto addr = s_arp_table->resource().get(ip_addr());
ScopedSpinLock lock(m_lock);
if (!m_did_unblock) {
m_did_unblock = true;
m_addr = move(addr);
}
}
Lockable<HashMap<IPv4Address, MACAddress>>& arp_table()
{
return *s_arp_table;
}
void update_arp_table(const IPv4Address& ip_addr, const MACAddress& addr)
{
Locker locker(arp_table().lock());
arp_table().resource().set(ip_addr, addr);
s_arp_table_block_condition->unblock(ip_addr, addr);
if constexpr (ROUTING_DEBUG) {
dmesgln("ARP table ({} entries):", arp_table().resource().size());
for (auto& it : arp_table().resource()) {
dmesgln("{} :: {}", it.value.to_string(), it.key.to_string());
}
}
}
bool RoutingDecision::is_zero() const
{
return adapter.is_null() || next_hop.is_zero();
}
static MACAddress multicast_ethernet_address(IPv4Address const& address)
{
return MACAddress { 0x01, 0x00, 0x5e, (u8)(address[1] & 0x7f), address[2], address[3] };
}
RoutingDecision route_to(const IPv4Address& target, const IPv4Address& source, const RefPtr<NetworkAdapter> through)
{
auto matches = [&](auto& adapter) {
if (!through)
return true;
return through == adapter;
};
auto if_matches = [&](auto& adapter, const auto& mac) -> RoutingDecision {
if (!matches(adapter))
return { nullptr, {} };
return { adapter, mac };
};
if (target[0] == 0 && target[1] == 0 && target[2] == 0 && target[3] == 0)
return if_matches(*NetworkingManagement::the().loopback_adapter(), NetworkingManagement::the().loopback_adapter()->mac_address());
if (target[0] == 127)
return if_matches(*NetworkingManagement::the().loopback_adapter(), NetworkingManagement::the().loopback_adapter()->mac_address());
auto target_addr = target.to_u32();
auto source_addr = source.to_u32();
RefPtr<NetworkAdapter> local_adapter = nullptr;
RefPtr<NetworkAdapter> gateway_adapter = nullptr;
NetworkingManagement::the().for_each([source_addr, &target_addr, &local_adapter, &gateway_adapter, &matches, &through](NetworkAdapter& adapter) {
auto adapter_addr = adapter.ipv4_address().to_u32();
auto adapter_mask = adapter.ipv4_netmask().to_u32();
if (target_addr == adapter_addr) {
local_adapter = NetworkingManagement::the().loopback_adapter();
return;
}
if (!adapter.link_up() || (adapter_addr == 0 && !through))
return;
if (source_addr != 0 && source_addr != adapter_addr)
return;
if ((target_addr & adapter_mask) == (adapter_addr & adapter_mask) && matches(adapter))
local_adapter = adapter;
if (adapter.ipv4_gateway().to_u32() != 0 && matches(adapter))
gateway_adapter = adapter;
});
if (local_adapter && target == local_adapter->ipv4_address())
return { local_adapter, local_adapter->mac_address() };
if (!local_adapter && !gateway_adapter) {
dbgln_if(ROUTING_DEBUG, "Routing: Couldn't find a suitable adapter for route to {}", target);
return { nullptr, {} };
}
RefPtr<NetworkAdapter> adapter = nullptr;
IPv4Address next_hop_ip;
if (local_adapter) {
dbgln_if(ROUTING_DEBUG, "Routing: Got adapter for route (direct): {} ({}/{}) for {}",
local_adapter->name(),
local_adapter->ipv4_address(),
local_adapter->ipv4_netmask(),
target);
adapter = local_adapter;
next_hop_ip = target;
} else if (gateway_adapter) {
dbgln_if(ROUTING_DEBUG, "Routing: Got adapter for route (using gateway {}): {} ({}/{}) for {}",
gateway_adapter->ipv4_gateway(),
gateway_adapter->name(),
gateway_adapter->ipv4_address(),
gateway_adapter->ipv4_netmask(),
target);
adapter = gateway_adapter;
next_hop_ip = gateway_adapter->ipv4_gateway();
} else {
return { nullptr, {} };
}
// If it's a broadcast, we already know everything we need to know.
// FIXME: We should also deal with the case where `target_addr` is
// a broadcast to a subnet rather than a full broadcast.
if (target_addr == 0xffffffff && matches(adapter))
return { adapter, { 0xff, 0xff, 0xff, 0xff, 0xff, 0xff } };
if (adapter == NetworkingManagement::the().loopback_adapter())
return { adapter, adapter->mac_address() };
if ((target_addr & IPv4Address { 240, 0, 0, 0 }.to_u32()) == IPv4Address { 224, 0, 0, 0 }.to_u32())
return { adapter, multicast_ethernet_address(target) };
{
Locker locker(arp_table().lock());
auto addr = arp_table().resource().get(next_hop_ip);
if (addr.has_value()) {
dbgln_if(ROUTING_DEBUG, "Routing: Using cached ARP entry for {} ({})", next_hop_ip, addr.value().to_string());
return { adapter, addr.value() };
}
}
dbgln_if(ROUTING_DEBUG, "Routing: Sending ARP request via adapter {} for IPv4 address {}", adapter->name(), next_hop_ip);
ARPPacket request;
request.set_operation(ARPOperation::Request);
request.set_target_hardware_address({ 0xff, 0xff, 0xff, 0xff, 0xff, 0xff });
request.set_target_protocol_address(next_hop_ip);
request.set_sender_hardware_address(adapter->mac_address());
request.set_sender_protocol_address(adapter->ipv4_address());
adapter->send({ 0xff, 0xff, 0xff, 0xff, 0xff, 0xff }, request);
if (NetworkTask::is_current()) {
// FIXME: Waiting for the ARP response from inside the NetworkTask would
// deadlock, so let's hope that whoever called route_to() tries again in a bit.
dbgln_if(ROUTING_DEBUG, "Routing: Not waiting for ARP response from inside NetworkTask, sent ARP request using adapter {} for {}", adapter->name(), target);
return { nullptr, {} };
}
Optional<MACAddress> addr;
if (!Thread::current()->block<ARPTableBlocker>({}, next_hop_ip, addr).was_interrupted()) {
if (addr.has_value()) {
dbgln_if(ROUTING_DEBUG, "Routing: Got ARP response using adapter {} for {} ({})",
adapter->name(),
next_hop_ip,
addr.value().to_string());
return { adapter, addr.value() };
}
}
dbgln_if(ROUTING_DEBUG, "Routing: Couldn't find route using adapter {} for {}", adapter->name(), target);
return { nullptr, {} };
}
}