Agrega records al cache.

[z.facultad/75.74/practicos.git] / practicas / pipi / src / nameserver.cpp

#include "nameserver.h"
#include <sstream>
#include <algorithm>
#include <iterator>
#include <sstream>
#include <functional>
#ifdef DEBUG
#include <iostream>
#endif

NameServer::Name::Name(const std::string& s)
{
    std::istringstream iss(s);
    std::string tok;
    while (std::getline(iss, tok, '.'))
        push_back(tok);
}

std::ostream& operator<< (std::ostream& os, const NameServer::Name& name)
{
    if (name.empty())
        return os;
    std::copy(name.begin(), name.end() - 1,
            std::ostream_iterator< std::string >(os, "."));
    return os << name.back();
}

NameServer::Name::operator std::string () const
{
    std::stringstream ss;
    ss << *this;
    return ss.str();
}

/// Parsea una zona
static std::istream& parsezone(std::istream& is, NameServer::Zone& z)
    throw (std::runtime_error)
{
    std::string line, sname, ip;
    // [dominio] [ttl] [parent ip]
    while (std::getline(is, line) && (line == "")); // Salteo líneas en blanco
    if (!is)
        return is;
    std::istringstream iss(line);
    if (!(iss >> sname >> z.ttl >> ip))
        throw std::runtime_error("Error al parsear");
    z.name = sname;
#ifdef DEBUG_PARSER
    std::cerr << "NameServer::parsezone: IP = " << ip << "\n\n";
#endif
    z.parent = IPAddr(ip);
    // un record por linea, sin líneas vacías
    // [name] [type] [ip]
    while (std::getline(is, line) && (line != ""))
    {
        iss.clear();
        iss.str(line);
        std::string key, type;
        if (!(iss >> key >> type >> ip))
            throw std::runtime_error("Error al parsear");
        typedef NameServer::Record Rec;
#ifdef DEBUG_PARSER
        std::cerr << "NameServer::parsezone: IP = " << ip << "\n\n";
#endif
        Rec r((type == "NS") ? Rec::NS : Rec::A, IPAddr(ip));
        z.records.insert(NameServer::Zone::records_t::value_type(key, r));
    }
#ifdef DEBUG_PARSER
    std::cerr << "NameServer::parsezone: " << z << "\n\n";
#endif
    return is;
}

/// Constructor
NameServer::Zone::Zone(std::string sname, size_t ttl, const IPAddr& parent):
    name(sname), ttl(ttl), parent(parent)
{
}

/// Constructor
NameServer::Zone::Zone(std::istream& is)
    throw (std::runtime_error)
{
    // Parsea la zona
    if (!parsezone(is, *this))
        throw std::runtime_error("Error de parser, no hay zona");
}

/// Limpia una zona
void NameServer::Zone::clear()
{
    name.clear();
    records.clear();
}

/// Constructor
NameServer::NameServer(std::istream& is, IPIn& ipin, IPOut& ipout,
        DevQue& req_que, DevQue& res_que, DevQue& snd_que)
    throw (std::runtime_error):
    ipin(ipin), ipout(ipout), req_que(req_que), res_que(res_que),
        snd_que(snd_que)
{
    Zone z;
    while (parsezone(is, z))
    {
        zones.push_back(z);
        z.clear();
#ifdef DEBUG_PARSER
        std::cerr << "NameServer::NameServer: " << z << "\n\n";
#endif
    }

#ifdef DEBUG_RESOLV
    std::cout << "NameServer::NameServer: req_que_id = " << req_que.que_id
        << ", res_que_id = " << res_que.que_id
        << ", snd_que_id = " << snd_que.que_id << "\n";
#endif
}

/// Devuelve la parte izquierda de n, si la parte derecha coincide exactamente
/// con m, si no devuelve un vector vacío.
/// Elemplo: name_split("mi.domi.nio", "domi.nio") == ["mi"]
///          name_split("dos.mi.domi.nio", "domi.nio") == ["dos", "mi"]
///          name_split("domi.nio", "domi.nio") == []
///          name_split("papeli.nio", "domi.nio") == []
static NameServer::Name
name_split(NameServer::Name n, NameServer::Name m)
{
    NameServer::Name r;
    std::reverse(n.begin(), n.end());
    std::reverse(m.begin(), m.end());
    // Si m es más grande o igual que n, no hay nada que hacer
    if (n.size() <= m.size())
        return r;
    // Si no coincide la parte derecha, no hay nada que hacer
    NameServer::Name::size_type i;
    for (i = 0; i < m.size(); ++i)
        if (n[i] != m[i])
            return r;
    // Si era todo igual y sobran cosas, devolvemos lo que "sobra"
    while (i < n.size())
        r.push_back(n[i++]);
    std::reverse(r.begin(), r.end());
#ifdef DEBUG_NAME
    std::cerr << "NameServer::name_split(" << n << ", " << m << ") -> "
        << r << "\n";
#endif
    return r;
}

/// Devuelve -1 si es un nombre "hijo" (la parte derecha de n está contenida
/// completamente en m, pero m y n no son iguales), 0 si m == n y 1 si es
/// "padre" (m no coincide con la parte derecha de n).
/// Elemplo: namecmp("mi.domi.nio", "domi.nio") == -1
///          namecmp("otra.cosa", "domi.nio") == 1
///          namecmp("papeli.nio", "domi.nio") == 1
///          namecmp("domi.nio", "domi.nio") == 0
/*enum name_cmp_t
{
    NC_DIRECT_CHILD,  ///> Hijo directo, es decir, está en la zona m
    NC_CHILD,         ///> Hijo indirecto, está en una zona que cuelga de m
    NC_EQUAL,         ///> Es el host de la zona m
    NC_DIRECT_PARENT, ///> Padre directo, es decir, coincide en parte con m
    NC_PARENT         ///> Padre indirecto, es completamente distinto a m
};*/
#if 0
static int name_cmp(const NameServer::Name& n, const NameServer::Name& m)
{
    // Si m es más grande que n, seguro es padre
    if (n.size() < m.size())
        return 1;
    // Si no coincide la parte derecha, seguro es padre
    NameServer::Name::size_type i;
    for (i = m.size(); i > 0; --i)
        if (n[i-1] != m[i-1])
            return 1;
    // Si era todo igual y sobran cosas, es hijo
    if (i)
        return -1;
    // Si no, son iguales.
    return 0;
}
#endif

struct search_zone: std::unary_function< NameServer::Zone, bool >
{
    bool local;
    ResolvProtoResponse resp;
    const NameServer::Name& name;
    search_zone(const NameServer::Name& n): local(false), name(n) {}
    bool operator() (const NameServer::Zone& z)
    {
        bool found = false;
        NameServer::Name local_part = name_split(name, z.name);
        if (!local_part.empty()) // Está en esta zona
        {
            local = true;
            std::string n = local_part.back(); // Obtengo última parte
            // busco
            typedef NameServer::Zone::records_t::const_iterator itt;
            std::pair<itt, itt> p = z.records.equal_range(n);
            for (; p.first != p.second; ++p.first)
            {
                const NameServer::Record& r = (*p.first).second;
                // Tiene que buscar solo A porque era un nombre
                if ((local_part.size() == 1) && (r.type != NameServer::Record::A))
                    continue;
                // Tiene que seguir para abajo, solo busca NS
                if ((local_part.size() > 1) && r.type != NameServer::Record::NS)
                    continue;
                found = true;
                resp.ret = (r.type == NameServer::Record::NS) ? RP_RES_NS
                    : RP_RES_A;
                resp.ttl = z.ttl;
                resp.ips.push_back(r.ip);
            }
        }
        return found;
    }
};

/// Resuelve un nombre de forma directa (no recursiva)
ResolvProtoResponse NameServer::resolv_direct(const Name& n)
{
#ifdef DEBUG_TRACE
    std::cout << "NameServer::resolv_direct()\n";
#endif
#ifdef DEBUG_RESOLV
    std::cerr << "NameServer::resolv_direct -> tratando de resolver: "
        << n << "\n";
#endif
    search_zone zs(n);
    bool found;
    for (zones_t::const_iterator i = zones.begin(); i!= zones.end(); ++i)
        if ((found = zs(*i)))
            break;
    if (found)
    {
#ifdef DEBUG_RESOLV
        std::cerr << "NameServer::resolv_direct -> found (local/hijo): "
            << zs.resp << "\n";
#endif
        return zs.resp;
    }
    if (zs.local)
    {
#ifdef DEBUG_RESOLV
        std::cerr << "NameServer::resolv_direct -> NOT FOUND (es local pero "
            "no existe)\n";
#endif
        return ResolvProtoResponse(RP_RES_NOTFOUND);
    }
    cache_t::const_iterator i = cache.find(n);
    // TODO TTL!?!
    if (i != cache.end())
    {
#ifdef DEBUG_RESOLV
        std::cerr << "NameServer::resolv_direct -> found (en cache): "
            << i->second << "\n";
#endif
        const CacheRecord& cr = i->second;
        return ResolvProtoResponse(RP_RES_A, cr.ttl, cr.ips);
    }
    if (zones.size())
    {
        // Busco una zona con padre para ver si puedo "trepar"
        for (zones_t::const_iterator i = zones.begin(); i != zones.end(); ++i)
        {
#ifdef DEBUG_RESOLV
            std::cerr << "NameServer::resolv_direct -> evaluando padre "
                << i->parent << "\n";
#endif
            if (i->parent != IPAddr(0))
            {
#ifdef DEBUG_RESOLV
                std::cerr << "NameServer::resolv_direct -> found (al padre): "
                    << i->parent << "\n";
#endif
                ResolvProtoResponse rpr(RP_RES_NS, i->ttl);
                rpr.ips.push_back(i->parent);
                return rpr;
            }
        }
    }
#ifdef DEBUG_RESOLV
    std::cerr << "NameServer::resolv_direct -> NOT FOUND (no hay padre)\n";
#endif
    // No hay padre, no puedo hacer nada más
    return ResolvProtoResponse(RP_RES_NOTFOUND);
}

/// Resuelve un nombre de forma recursiva
ResolvProtoResponse NameServer::resolv_recursive(const Name& n)
{
#ifdef DEBUG_TRACE
    std::cout << "NameServer::resolv_recursive()\n";
#endif
    ResolvProtoResponse rpr = resolv_direct(n);
    switch (rpr.ret)
    {
        case RP_RES_NS:
#ifdef DEBUG_RESOLV
            std::cerr << "NameServer::resolv_recursive -> redirect a "
                << rpr << "\n";
#endif
            return resolv_recursive_r(n, rpr); // Sigo "bajando"
        case RP_RES_A:
#ifdef DEBUG_RESOLV
            std::cerr << "NameServer::resolv_recursive -> gotcha! "
                << rpr << "\n";
#endif
            break;
    }
    return rpr; // Devuelvo el A o NOTFOUND
}

/// Resuelve un nombre de forma recursiva entrando a otros ns
ResolvProtoResponse NameServer::resolv_recursive_r(const Name& n,
        ResolvProtoResponse rpr)
{
#ifdef DEBUG_TRACE
    std::cout << "NameServer::resolv_recursive_r()\n";
#endif
    ResolvProtoResponse r;
    for (ResolvProtoResponse::ipvec_t::const_iterator ip = rpr.ips.begin();
            ip != rpr.ips.end(); ++ip)
    {
        r = query(n, *ip);
        switch (r.ret)
        {
            case RP_RES_NS:
#ifdef DEBUG_RESOLV
                std::cerr << "NameServer::resolv_recursive_r -> redirect a "
                    << r << "\n";
#endif
                return resolv_recursive_r(n, r); // Sigo "bajando"
            case RP_RES_NOTFOUND:
#ifdef DEBUG_RESOLV
                std::cerr << "NameServer::resolv_recursive_r -> NOT FOUND en "
                    << *ip << ", sigo probando\n";
#endif
                break; // Sigo probando del mismo nivel
            case RP_RES_A:
#ifdef DEBUG_RESOLV
                std::cerr << "NameServer::resolv_recursive_r -> gotcha! "
                    << r << "\n";
#endif
                return r; // Gotcha!
        }
    }
#ifdef DEBUG_RESOLV
    std::cerr << "NameServer::resolv_recursive_r -> NOT FOUND, no hay más "
        "por hacer\n";
#endif
    return r; // NOTFOUND
}

/// Consulta a otro name server sobre un nombre
ResolvProtoResponse NameServer::query(const Name& n, const IPAddr& ip)
{
#ifdef DEBUG_TRACE
    std::cout << "NameServer::query()\n";
#endif
    ResolvProtoRequest r(std::string(n), RP_REQ_DIRECT);
#ifdef DEBUG_RESOLV
    std::cerr << "NameServer::query -> pidiendo " << r << " a " << ip << "\n";
#endif
    // Envía a través de la cola de envío
    snd_que.transmit(std::string(r), ip);
    Dev::mac_type mac = ip;
    std::string buf = res_que.receive(mac);
    ResolvProtoResponse resp(buf);
#ifdef DEBUG_RESOLV
    std::cerr << "NameServer::query -> recibido " << resp << " de "
        << ip << "\n";
#endif
    // Agrego a cache
    if (resp.ret == RP_RES_A)
        cache[n] = CacheRecord(time(NULL) + resp.ttl, resp.ips);
    return resp;
}

void NameServer::recv_loop()
{
#ifdef DEBUG_TRACE
    std::cout << "NameServer::recv_loop()\n";
#endif
    while (true)
    {
        IPAddr src, dst;
        uint8_t proto;
        std::string s = ipin.recv(proto, src, dst);
#ifdef DEBUG_RESOLV
            std::cout << "NameServer::recv_loop() -> recibido len=" << s.size()
                << " de " << src << " para " << dst << " (proto = "
                << unsigned(proto) << ")\n";
#endif
        if (proto == RESOLV_PROTO) // Si es para nosotros
        {
            rp_pkt_type_t type;
            memcpy(&type, s.data(), sizeof(uint8_t));
            switch (type)
            {
                // Request
                case RP_REQ_DIRECT:
                case RP_REQ_RECURSIVE:
#ifdef DEBUG_RESOLV
                    std::cout << "---> " << ResolvProtoRequest(s) << "\n";
#endif
                    req_que.transmit(s, src); // Encolo
                    break;
                // Response
                default:
#ifdef DEBUG_RESOLV
                    std::cout << "---> " << ResolvProtoResponse(s) << "\n";
#endif
                    res_que.transmit(s, src); // Encolo
            }
        }
    }
}

void NameServer::send_loop()
{
#ifdef DEBUG_TRACE
    std::cout << "NameServer::send_loop()\n";
#endif
    while (true)
    {
        Dev::mac_type mac = 0;
        std::string buf = snd_que.receive(mac);
#ifdef DEBUG_RESOLV
        std::cout << "NameServer::send_loop() -> envío request "
            << ResolvProtoResponse(buf) << "\n";
#endif
        ipout.send(buf, RESOLV_PROTO, IPAddr(mac));
    }
}

void NameServer::req_loop()
{
#ifdef DEBUG_TRACE
    std::cout << "NameServer::req_loop()\n";
#endif
    while (true)
    {
        Dev::mac_type mac = 0;
        ResolvProtoRequest req(req_que.receive(mac));
#ifdef DEBUG_RESOLV
        std::cout << "NameServer::req_loop() -> recibido " << req << "\n";
#endif
        ResolvProtoResponse res
            = (req.query_type == RP_REQ_DIRECT)
            ? resolv_direct(req.name)
            : resolv_recursive(req.name);
#ifdef DEBUG_RESOLV
        std::cout << "NameServer::req_loop() -> respondo " << res << "\n";
#endif
        snd_que.transmit(std::string(res), IPAddr(mac));
    }
}

std::ostream& operator<< (std::ostream& os, const NameServer::Record::type_t& t)
{
    if (t == NameServer::Record::NS)
        return os << "NS";
    else
        return os << "A";
}

std::ostream& operator<< (std::ostream& os, const NameServer::Record& r)
{
    return os << r.type << " " << r.ip;
}

std::ostream& operator<< (std::ostream& os,
        const NameServer::Zone::records_t::value_type& p)
{
    return os << p.first << ": " << p.second;
}

std::ostream& operator<< (std::ostream& os, const NameServer::Zone& z)
{
    os << "Zone " << z.name << " " << z.ttl << " " << z.parent << "\n";
    std::copy(z.records.begin(), z.records.end(), std::ostream_iterator<
            NameServer::Zone::records_t::value_type >(os, "\n"));
    return os;
}

std::ostream& operator<< (std::ostream& os, const NameServer::CacheRecord& cr)
{
    os << "CacheRecord(ttl=" << cr.ttl << ", records=";
    std::copy(cr.ips.begin(), cr.ips.end(),
            std::ostream_iterator< IPAddr >(os, ","));
    return os << ")";
}

std::ostream& operator<< (std::ostream& os, const NameServer& ns)
{
    os << "NameServer: zones[" << ns.zones.size() << "] (\n\n";
    std::copy(ns.zones.begin(), ns.zones.end(),
            std::ostream_iterator< NameServer::Zone >(os, "\n"));
    return os << ")";
}

// vim: set et sw=4 sts=4 :