ladybird/Kernel/IPv4.h
Andreas Kling a017a77442 Kernel+LibC+Userland: Start working on an IPv4 socket backend.
The first userland networking program will be "ping" :^)
2019-03-12 15:51:42 +01:00

133 lines
3.7 KiB
C++

#pragma once
#include <AK/AKString.h>
#include <AK/Assertions.h>
#include <AK/Types.h>
#include <Kernel/NetworkOrdered.h>
#include <Kernel/StdLib.h>
enum class IPv4Protocol : word {
ICMP = 1,
TCP = 6,
UDP = 17,
};
NetworkOrdered<word> internet_checksum(const void*, size_t);
class [[gnu::packed]] IPv4Address {
public:
IPv4Address() { }
IPv4Address(const byte data[4])
{
memcpy(m_data, data, 4);
}
IPv4Address(byte a, byte b, byte c, byte d)
{
m_data[0] = a;
m_data[1] = b;
m_data[2] = c;
m_data[3] = d;
}
byte operator[](int i) const
{
ASSERT(i >= 0 && i < 4);
return m_data[i];
}
String to_string() const
{
return String::format("%u.%u.%u.%u", m_data[0], m_data[1], m_data[2], m_data[3]);
}
bool operator==(const IPv4Address& other) const { return m_data_as_dword == other.m_data_as_dword; }
bool operator!=(const IPv4Address& other) const { return m_data_as_dword != other.m_data_as_dword; }
private:
union {
byte m_data[4];
dword m_data_as_dword;
};
};
static_assert(sizeof(IPv4Address) == 4);
namespace AK {
template<>
struct Traits<IPv4Address> {
static unsigned hash(const IPv4Address& address) { return string_hash((const char*)&address, sizeof(address)); }
static void dump(const IPv4Address& address) { kprintf("%s", address.to_string().characters()); }
};
}
class [[gnu::packed]] IPv4Packet {
public:
byte version() const { return (m_version_and_ihl >> 4) & 0xf; }
void set_version(byte version) { m_version_and_ihl = (m_version_and_ihl & 0x0f) | (version << 4); }
byte internet_header_length() const { return m_version_and_ihl & 0xf; }
void set_internet_header_length(byte ihl) { m_version_and_ihl = (m_version_and_ihl & 0xf0) | (ihl & 0x0f); }
word length() const { return m_length; }
void set_length(word length) { m_length = length; }
word ident() const { return m_ident; }
void set_ident(word ident) { m_ident = ident; }
byte ttl() const { return m_ttl; }
void set_ttl(byte ttl) { m_ttl = ttl; }
byte protocol() const { return m_protocol; }
void set_protocol(byte protocol) { m_protocol = protocol; }
word checksum() const { return m_checksum; }
void set_checksum(word checksum) { m_checksum = checksum; }
const IPv4Address& source() const { return m_source; }
void set_source(const IPv4Address& address) { m_source = address; }
const IPv4Address& destination() const { return m_destination; }
void set_destination(const IPv4Address& address) { m_destination = address; }
void* payload() { return this + 1; }
const void* payload() const { return this + 1; }
word payload_size() const { return m_length - sizeof(IPv4Packet); }
NetworkOrdered<word> compute_checksum() const
{
ASSERT(!m_checksum);
return internet_checksum(this, sizeof(IPv4Packet));
}
private:
byte m_version_and_ihl { 0 };
byte m_dscp_and_ecn { 0 };
NetworkOrdered<word> m_length;
NetworkOrdered<word> m_ident;
NetworkOrdered<word> m_flags_and_fragment;
byte m_ttl { 0 };
NetworkOrdered<byte> m_protocol;
NetworkOrdered<word> m_checksum;
IPv4Address m_source;
IPv4Address m_destination;
};
static_assert(sizeof(IPv4Packet) == 20);
inline NetworkOrdered<word> internet_checksum(const void* ptr, size_t count)
{
dword checksum = 0;
auto* w = (const word*)ptr;
while (count > 1) {
checksum += convert_between_host_and_network(*w++);
if (checksum & 0x80000000)
checksum = (checksum & 0xffff) | (checksum >> 16);
count -= 2;
}
while (checksum >> 16)
checksum = (checksum & 0xffff) + (checksum >> 16);
return ~checksum & 0xffff;
}