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construct/include/ircd/rfc1035.h

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// Matrix Construct
//
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// Copyright (C) Matrix Construct Developers, Authors & Contributors
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// Copyright (C) 2016-2018 Jason Volk <jason@zemos.net>
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//
// Permission to use, copy, modify, and/or distribute this software for any
// purpose with or without fee is hereby granted, provided that the above
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// copyright notice and this permission notice is present in all copies. The
// full license for this software is available in the LICENSE file.
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#pragma once
#define HAVE_IRCD_RFC1035_H
/// RFC 1035 "Domain Names" (Nov. 1987)
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///
namespace ircd::rfc1035
{
IRCD_EXCEPTION(ircd::error, error)
struct header;
struct question;
struct answer;
struct record;
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enum class op :uint8_t;
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// Section 2.3.4 Size Limits
#ifndef NAME_MAX
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constexpr size_t NAME_MAX {255};
#endif
constexpr size_t LABEL_MAX {63};
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constexpr size_t TTL_MAX {std::numeric_limits<int32_t>::max()};
constexpr size_t LABEL_BUFSIZE {LABEL_MAX + 1};
constexpr size_t NAME_BUFSIZE {NAME_MAX + 1};
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extern const std::array<string_view, 25> rcode;
extern const std::unordered_map<string_view, uint16_t> qtype;
extern const std::map<uint16_t, string_view> rqtype;
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bool valid_label(std::nothrow_t, const string_view &);
bool valid_name(std::nothrow_t, const string_view &);
void valid_label(const string_view &);
void valid_name(const string_view &);
const_buffer make_name(const mutable_buffer &out, const string_view &fqdn);
size_t parse_name(const mutable_buffer &out, const const_buffer &in);
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mutable_buffer make_query(const mutable_buffer &, const header &, const vector_view<const question> &);
mutable_buffer make_query(const mutable_buffer &, const uint16_t &id, const vector_view<const question> &);
mutable_buffer make_query(const mutable_buffer &, const uint16_t &id, const question &);
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}
/// Direct representation of the DNS header. This is laid out for
/// little-endian platforms only. The uint16_t's are big endian when this is
/// punned on the wire data. The debug() function makes it into a pretty
/// string but makes no endian adjustments.
///
struct ircd::rfc1035::header
{
uint16_t id; ///< query identification number
uint8_t rd:1; ///< 0 = recursion not desired; 1 = desired
uint8_t tc:1; ///< 0 = not-truncated; 1 = 512 bytes of reply only
uint8_t aa:1; ///< 0 = non-authoritative; 1 = authoritative
uint8_t opcode:4; ///< purpose of message
uint8_t qr:1; ///< 0 = query; 1 = respnse
uint8_t rcode:4; ///< response code
uint8_t cd:1; ///< checking disabled by resolver
uint8_t ad:1; ///< authentic data from named
uint8_t unused:1; ///< unused bits (MBZ as of 4.9.3a3)
uint8_t ra:1; ///< 1 = recursion available
uint16_t qdcount; ///< number of question entries
uint16_t ancount; ///< number of answer entries
uint16_t nscount; ///< number of authority entries
uint16_t arcount; ///< number of resource entries
std::string debug() const;
}
__attribute__((packed));
static_assert
(
sizeof(ircd::rfc1035::header) == 12,
"The RFC1035 header is not the right size in this environment"
);
/// DNS operation code
///
enum class ircd::rfc1035::op
:uint8_t
{
QUERY = 0, ///< Query [RFC 1035]
IQUERY = 1, ///< Inverse Query [RFC 1035, RFC 3425]
STATUS = 2, ///< Server status request [RFC 1035]
NOTIFY = 4, ///< Notify [RFC 1996]
UPDATE = 5, ///< Update [RFC 2136]
};
/// Helper class to construct or parse a question. An object is constructed
/// with a fully qualified domain string and the query type (qtype).
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///
/// Note that each part of the fqdn cannot be longer than 63 characters. The
/// supplied buffer must be large enough to hold the output, which is about
/// the length of the fqdn + 6 bytes. The qtype can be specified as a string
/// i.e "A" or "PTR" and it will be translated into the protocol number for
/// you in the constructor. All integers are dealt with in host byte order.
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///
struct ircd::rfc1035::question
{
uint16_t qtype {0};
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uint16_t qclass {0x01};
string_view name;
char namebuf[NAME_BUFSIZE];
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/// Composes the question into buffer, returns used portion
mutable_buffer print(const mutable_buffer &) const;
const_buffer parse(const const_buffer &);
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/// Supply fully qualified domain name and numerical query type
question(const string_view &fqdn, const uint16_t &qtype);
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/// Supply fully qualified domain name and name of query type i.e "A"
question(const string_view &fqdn, const string_view &qtype)
:question{fqdn, rfc1035::qtype.at(qtype)}
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{}
question() = default;
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};
/// Helper class to parse an answer. When the DNS header is received we get
/// an answer count. For each answer in the answer section parse() is called
/// which stocks this object and then returns a buffer tight to that specific
/// answer section. The `rdata` is the actual record content which the user
/// can then treat later with rfc1035::record. All integers are dealt with in
/// host byte order.
///
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struct ircd::rfc1035::answer
{
uint16_t qtype {0};
uint16_t qclass {0};
uint32_t ttl {0};
uint16_t rdlength {0};
const_buffer rdata;
string_view name;
char namebuf[NAME_BUFSIZE];
const_buffer parse(const const_buffer &);
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answer() = default;
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};
/// Resource record abstract base. The purpose of this abstraction is to allow
/// records of any variety to all be dealt with via a `rfc1035::record *` ptr
/// and then be downcasted to the specific derived type elaborated below. Use
/// the as() template to downcast.
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///
/// Generally this object is not instantiated directly; each record type will
/// construct this instead. Nevertheless, the full raw data and type number
/// for the record is available in here. All constructors (for both this
/// abstraction and for the derivations) take an already-parsed rfc1035::answer
/// as their argument; the qtype and ttl information from the answer header is
/// included while the legacy qclass is omitted.
///
struct ircd::rfc1035::record
{
struct A;
struct AAAA;
struct CNAME;
struct SRV;
uint16_t type {0};
time_t ttl {0};
const_buffer rdata;
template<class T> const T &as() const;
record(const answer &);
record(const uint16_t &type);
record() = default;
virtual ~record() noexcept;
};
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namespace ircd::rfc1035
{
bool operator==(const record::A &, const record::A &);
bool operator!=(const record::A &, const record::A &);
bool operator==(const record::AAAA &, const record::AAAA &);
bool operator!=(const record::AAAA &, const record::AAAA &);
bool operator==(const record::CNAME &, const record::CNAME &);
bool operator!=(const record::CNAME &, const record::CNAME &);
bool operator==(const record::SRV &, const record::SRV &);
bool operator!=(const record::SRV &, const record::SRV &);
}
/// Downcast an abstract record reference to the specific record structure.
template<class T>
const T &
ircd::rfc1035::record::as()
const
{
return dynamic_cast<T &>(*this);
}
//
// Types of records
//
/// IPv4 address record.
/// The integer is laid out in host byte order.
struct ircd::rfc1035::record::A
:record
{
uint32_t ip4 {0};
void append(json::stack::object &) const;
A(const answer &);
A();
};
/// IPv6 address record.
/// The integer is laid out in host byte order.
struct ircd::rfc1035::record::AAAA
:record
{
uint128_t ip6 {0};
void append(json::stack::object &) const;
AAAA(const answer &);
AAAA();
};
/// Canonical name aliasing record
struct ircd::rfc1035::record::CNAME
:record
{
string_view name;
char namebuf[NAME_BUFSIZE];
void append(json::stack::object &) const;
CNAME(const answer &);
CNAME();
};
/// Service record.
/// The integers are laid out in host byte order.
struct ircd::rfc1035::record::SRV
:record
{
uint16_t priority {0};
uint16_t weight {0};
uint16_t port {0};
string_view tgt;
char tgtbuf[NAME_BUFSIZE];
void append(json::stack::object &) const;
SRV(const answer &);
SRV();
};