[secnet] / udp.c

/* UDP send/receive module for secnet */

/* This module enables sites to communicate by sending UDP
 * packets. When an instance of the module is created we can
 * optionally bind to a particular local IP address (not implemented
 * yet).
 *
 * Packets are offered to registered receivers in turn. Once one
 * accepts it, it isn't offered to any more. */

#include "secnet.h"
#include <stdio.h>
#include <unistd.h>
#include <fcntl.h>
#include <string.h>
#include <errno.h>
#include <sys/socket.h>
#include <sys/wait.h>
#include <netinet/in.h>
#include <arpa/inet.h>
#include "util.h"
#include "unaligned.h"
#include "ipaddr.h"
#include "magic.h"

static beforepoll_fn udp_beforepoll;
static afterpoll_fn udp_afterpoll;
static comm_request_notify_fn request_notify;
static comm_release_notify_fn release_notify;
static comm_sendmsg_fn udp_sendmsg;

struct notify_list {
    comm_notify_fn *fn;
    void *state;
    struct notify_list *next;
};

struct udp {
    closure_t cl;
    struct comm_if ops;
    struct cloc loc;
    uint32_t addr;
    uint16_t port;
    int fd;
    string_t authbind;
    struct buffer_if *rbuf;
    struct notify_list *notify;
    bool_t use_proxy;
    struct sockaddr_in proxy;
};

static const char *saddr_to_string(const struct sockaddr_in *sin) {
    static char bufs[2][100];
    static int b;

    b ^= 1;
    snprintf(bufs[b], sizeof(bufs[b]), "[%s]:%d",
             inet_ntoa(sin->sin_addr),
             ntohs(sin->sin_port));
    return bufs[b];
}

static const char *addr_to_string(void *commst, const struct comm_addr *ca) {
    struct udp *st=commst;
    static char sbuf[100];

    struct sockaddr_in la;
    la.sin_addr.s_addr=htonl(st->addr);
    la.sin_port=htons(st->port);

    snprintf(sbuf, sizeof(sbuf), "udp:%s-%s",
             saddr_to_string(&la), saddr_to_string(&ca->sin));
    return sbuf;
}

static int udp_beforepoll(void *state, struct pollfd *fds, int *nfds_io,
                          int *timeout_io)
{
    struct udp *st=state;
    if (*nfds_io<1) {
        *nfds_io=1;
        return ERANGE;
    }
    *nfds_io=1;
    fds->fd=st->fd;
    fds->events=POLLIN;
    return 0;
}

static void udp_afterpoll(void *state, struct pollfd *fds, int nfds)
{
    struct udp *st=state;
    struct sockaddr_in from;
    socklen_t fromlen;
    struct notify_list *n;
    bool_t done;
    int rv;

    if (nfds && (fds->revents & POLLIN)) {
        do {
            FILLZERO(from);
            fromlen=sizeof(from);
            BUF_ASSERT_FREE(st->rbuf);
            BUF_ALLOC(st->rbuf,"udp_afterpoll");
            rv=recvfrom(st->fd, st->rbuf->start, st->rbuf->len, 0,
                        (struct sockaddr *)&from, &fromlen);
            if (rv>0) {
                st->rbuf->size=rv;
                if (st->use_proxy) {
                    /* Check that the packet came from our poxy server;
                       we shouldn't be contacted directly by anybody else
                       (since they can trivially forge source addresses) */
                    if (memcmp(&from.sin_addr,&st->proxy.sin_addr,4)!=0 ||
                        memcmp(&from.sin_port,&st->proxy.sin_port,2)!=0) {
                        Message(M_INFO,"udp: received packet that's not "
                                "from the proxy\n");
                        BUF_FREE(st->rbuf);
                        continue;
                    }
                    memcpy(&from.sin_addr,buf_unprepend(st->rbuf,4),4);
                    buf_unprepend(st->rbuf,2);
                    memcpy(&from.sin_port,buf_unprepend(st->rbuf,2),2);
                }
                struct comm_addr ca;
                FILLZERO(ca);
                ca.comm=&st->ops;
                ca.sin=from;
                done=False;
                for (n=st->notify; n; n=n->next) {
                    if (n->fn(n->state, st->rbuf, &ca)) {
                        done=True;
                        break;
                    }
                }
                if (!done) {
                    uint32_t msgtype;
                    if (st->rbuf->size>12 /* prevents traffic amplification */
                        && ((msgtype=get_uint32(st->rbuf->start+8))
                            != LABEL_NAK)) {
                        uint32_t source,dest;
                        /* Manufacture and send NAK packet */
                        source=get_uint32(st->rbuf->start); /* Us */
                        dest=get_uint32(st->rbuf->start+4); /* Them */
                        send_nak(&ca,source,dest,msgtype,st->rbuf,"unwanted");
                    }
                    BUF_FREE(st->rbuf);
                }
                BUF_ASSERT_FREE(st->rbuf);
            } else {
                BUF_FREE(st->rbuf);
            }
        } while (rv>=0);
    }
}

static void request_notify(void *commst, void *nst, comm_notify_fn *fn)
{
    struct udp *st=commst;
    struct notify_list *n;
    
    n=safe_malloc(sizeof(*n),"request_notify");
    n->fn=fn;
    n->state=nst;
    n->next=st->notify;
    st->notify=n;
}

static void release_notify(void *commst, void *nst, comm_notify_fn *fn)
{
    struct udp *st=commst;
    struct notify_list *n, **p, *t;

    /* XXX untested */
    p=&st->notify;
    for (n=st->notify; n; )
    {
        if (n->state==nst && n->fn==fn) {
            t=n;
            *p=n->next;
            n=n->next;
            free(t);
        } else {
            p=&n->next;
            n=n->next;
        }
    }
}

static bool_t udp_sendmsg(void *commst, struct buffer_if *buf,
                          const struct comm_addr *dest)
{
    struct udp *st=commst;
    uint8_t *sa;

    if (st->use_proxy) {
        sa=buf->start-8;
        memcpy(sa,&dest->sin.sin_addr,4);
        memset(sa+4,0,4);
        memcpy(sa+6,&dest->sin.sin_port,2);
        sendto(st->fd,sa,buf->size+8,0,(struct sockaddr *)&st->proxy,
               sizeof(st->proxy));
    } else {
        sendto(st->fd, buf->start, buf->size, 0,
               (struct sockaddr *)&dest->sin, sizeof(dest->sin));
    }

    return True;
}

static void udp_phase_hook(void *sst, uint32_t new_phase)
{
    struct udp *st=sst;
    struct sockaddr_in addr;

    st->fd=socket(PF_INET, SOCK_DGRAM, IPPROTO_UDP);
    if (st->fd<0) {
        fatal_perror("udp (%s:%d): socket",st->loc.file,st->loc.line);
    }
    if (fcntl(st->fd, F_SETFL, fcntl(st->fd, F_GETFL)|O_NONBLOCK)==-1) {
        fatal_perror("udp (%s:%d): fcntl(set O_NONBLOCK)",
                     st->loc.file,st->loc.line);
    }
    if (fcntl(st->fd, F_SETFD, FD_CLOEXEC)==-1) {
        fatal_perror("udp (%s:%d): fcntl(set FD_CLOEXEC)",
                     st->loc.file,st->loc.line);
    }

    FILLZERO(addr);
    addr.sin_family=AF_INET;
    addr.sin_addr.s_addr=htonl(st->addr);
    addr.sin_port=htons(st->port);
    if (st->authbind) {
        pid_t c;
        int status;

        /* XXX this fork() and waitpid() business needs to be hidden
           in some system-specific library functions. */
        c=fork();
        if (c==-1) {
            fatal_perror("udp_phase_hook: fork() for authbind");
        }
        if (c==0) {
            char *argv[4], addrstr[9], portstr[5];
            sprintf(addrstr,"%08lX",(long)addr.sin_addr.s_addr);
            sprintf(portstr,"%04X",addr.sin_port);
            argv[0]=st->authbind;
            argv[1]=addrstr;
            argv[2]=portstr;
            argv[3]=NULL;
            dup2(st->fd,0);
            execvp(st->authbind,argv);
            _exit(255);
        }
        while (waitpid(c,&status,0)==-1) {
            if (errno==EINTR) continue;
            fatal_perror("udp (%s:%d): authbind",st->loc.file,st->loc.line);
        }
        if (WIFSIGNALED(status)) {
            fatal("udp (%s:%d): authbind died on signal %d",st->loc.file,
                  st->loc.line, WTERMSIG(status));
        }
        if (WIFEXITED(status) && WEXITSTATUS(status)!=0) {
            fatal("udp (%s:%d): authbind died with status %d",st->loc.file,
                  st->loc.line, WEXITSTATUS(status));
        }
    } else {
        if (bind(st->fd, (struct sockaddr *)&addr, sizeof(addr))!=0) {
            fatal_perror("udp (%s:%d): bind",st->loc.file,st->loc.line);
        }
    }

    register_for_poll(st,udp_beforepoll,udp_afterpoll,1,"udp");
}

static list_t *udp_apply(closure_t *self, struct cloc loc, dict_t *context,
                         list_t *args)
{
    struct udp *st;
    item_t *i,*j;
    dict_t *d;
    list_t *l;
    uint32_t a;

    st=safe_malloc(sizeof(*st),"udp_apply(st)");
    st->loc=loc;
    st->cl.description="udp";
    st->cl.type=CL_COMM;
    st->cl.apply=NULL;
    st->cl.interface=&st->ops;
    st->ops.st=st;
    st->ops.min_start_pad=0;
    st->ops.request_notify=request_notify;
    st->ops.release_notify=release_notify;
    st->ops.sendmsg=udp_sendmsg;
    st->ops.addr_to_string=addr_to_string;
    st->port=0;
    st->use_proxy=False;

    i=list_elem(args,0);
    if (!i || i->type!=t_dict) {
        cfgfatal(st->loc,"udp","first argument must be a dictionary\n");
    }
    d=i->data.dict;

    j=dict_find_item(d,"address",False,"udp",st->loc);
    st->addr=j?string_item_to_ipaddr(j, "udp"):INADDR_ANY;
    st->port=dict_read_number(d,"port",True,"udp",st->loc,0);
    st->rbuf=find_cl_if(d,"buffer",CL_BUFFER,True,"udp",st->loc);
    st->authbind=dict_read_string(d,"authbind",False,"udp",st->loc);
    l=dict_lookup(d,"proxy");
    if (l) {
        st->use_proxy=True;
        FILLZERO(st->proxy);
        st->proxy.sin_family=AF_INET;
        i=list_elem(l,0);
        if (!i || i->type!=t_string) {
            cfgfatal(st->loc,"udp","proxy must supply ""addr"",port\n");
        }
        a=string_item_to_ipaddr(i,"proxy");
        st->proxy.sin_addr.s_addr=htonl(a);
        i=list_elem(l,1);
        if (!i || i->type!=t_number) {
            cfgfatal(st->loc,"udp","proxy must supply ""addr"",port\n");
        }
        st->proxy.sin_port=htons(i->data.number);
        st->ops.min_start_pad=8;
    }

    add_hook(PHASE_GETRESOURCES,udp_phase_hook,st);

    return new_closure(&st->cl);
}

void udp_module(dict_t *dict)
{
    add_closure(dict,"udp",udp_apply);
}