tcpdump/print-decnet.c
Denis Ovsienko c9e5ac541b libdnet has bugs, do not use it.
The only function tcpdump used in libdnet was dnet_htoa(), which tries
to translate a binary DECnet address to a nodename through a lookup in
/etc/decnet.conf. The translation is slow and has a bug, so stop using
the function and remove the dependency on libdnet.

This makes tcpdump always print DECnet addresses in numeric format, if
anybody needs the translation back they are welcome to fix libdnet or
(more realistically) add an implementation of dnet_htoa() to the tcpdump
source code and use it.

(This is a forward-port of commit 9a6eb27 from tcpdump-4.9 to master.
Sadly, together with libdnet this change removes the fine work that Guy
had done in the master branch in commits ebf3f19 and 4ef8d63 to put
libdnet usage right whilst my original "do not use libdnet" commit was
aging in the pipeline.)
2019-11-03 23:46:28 +00:00

1232 lines
36 KiB
C

/*
* Copyright (c) 1992, 1993, 1994, 1995, 1996, 1997
* The Regents of the University of California. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that: (1) source code distributions
* retain the above copyright notice and this paragraph in its entirety, (2)
* distributions including binary code include the above copyright notice and
* this paragraph in its entirety in the documentation or other materials
* provided with the distribution, and (3) all advertising materials mentioning
* features or use of this software display the following acknowledgement:
* ``This product includes software developed by the University of California,
* Lawrence Berkeley Laboratory and its contributors.'' Neither the name of
* the University nor the names of its contributors may be used to endorse
* or promote products derived from this software without specific prior
* written permission.
* THIS SOFTWARE IS PROVIDED ``AS IS'' AND WITHOUT ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, WITHOUT LIMITATION, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE.
*/
/* \summary: DECnet printer */
#ifdef HAVE_CONFIG_H
#include <config.h>
#endif
#include "netdissect-stdinc.h"
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include "netdissect.h"
#include "extract.h"
#include "addrtoname.h"
#ifndef _WIN32
typedef nd_uint8_t byte; /* single byte field */
#else
/*
* the keyword 'byte' generates conflicts in Windows
*/
typedef nd_uint8_t Byte; /* single byte field */
#define byte Byte
#endif /* _WIN32 */
typedef nd_uint16_t word; /* 2 byte field */
typedef nd_uint32_t longword; /* 4 bytes field */
/*
* Definitions for DECNET Phase IV protocol headers
*/
typedef union {
nd_byte dne_addr[6]; /* full ethernet address */
struct {
nd_byte dne_hiord[4]; /* DECnet HIORD prefix */
nd_byte dne_nodeaddr[2]; /* DECnet node address */
} dne_remote;
} etheraddr; /* Ethernet address */
#define HIORD 0x000400aa /* high 32-bits of address (swapped) */
#define AREAMASK 0176000 /* mask for area field */
#define AREASHIFT 10 /* bit-offset for area field */
#define NODEMASK 01777 /* mask for node address field */
/*
* Define long and short header formats.
*/
struct shorthdr
{
byte sh_flags; /* route flags */
word sh_dst; /* destination node address */
word sh_src; /* source node address */
byte sh_visits; /* visit count */
};
struct longhdr
{
byte lg_flags; /* route flags */
byte lg_darea; /* destination area (reserved) */
byte lg_dsarea; /* destination subarea (reserved) */
etheraddr lg_dst; /* destination id */
byte lg_sarea; /* source area (reserved) */
byte lg_ssarea; /* source subarea (reserved) */
etheraddr lg_src; /* source id */
byte lg_nextl2; /* next level 2 router (reserved) */
byte lg_visits; /* visit count */
byte lg_service; /* service class (reserved) */
byte lg_pt; /* protocol type (reserved) */
};
union routehdr
{
struct shorthdr rh_short; /* short route header */
struct longhdr rh_long; /* long route header */
};
/*
* Define the values of various fields in the protocol messages.
*
* 1. Data packet formats.
*/
#define RMF_MASK 7 /* mask for message type */
#define RMF_SHORT 2 /* short message format */
#define RMF_LONG 6 /* long message format */
#ifndef RMF_RQR
#define RMF_RQR 010 /* request return to sender */
#define RMF_RTS 020 /* returning to sender */
#define RMF_IE 040 /* intra-ethernet packet */
#endif /* RMR_RQR */
#define RMF_FVER 0100 /* future version flag */
#define RMF_PAD 0200 /* pad field */
#define RMF_PADMASK 0177 /* pad field mask */
#define VIS_MASK 077 /* visit field mask */
/*
* 2. Control packet formats.
*/
#define RMF_CTLMASK 017 /* mask for message type */
#define RMF_CTLMSG 01 /* control message indicator */
#define RMF_INIT 01 /* initialization message */
#define RMF_VER 03 /* verification message */
#define RMF_TEST 05 /* hello and test message */
#define RMF_L1ROUT 07 /* level 1 routing message */
#define RMF_L2ROUT 011 /* level 2 routing message */
#define RMF_RHELLO 013 /* router hello message */
#define RMF_EHELLO 015 /* endnode hello message */
#define TI_L2ROUT 01 /* level 2 router */
#define TI_L1ROUT 02 /* level 1 router */
#define TI_ENDNODE 03 /* endnode */
#define TI_VERIF 04 /* verification required */
#define TI_BLOCK 010 /* blocking requested */
#define VE_VERS 2 /* version number (2) */
#define VE_ECO 0 /* ECO number */
#define VE_UECO 0 /* user ECO number (0) */
#define P3_VERS 1 /* phase III version number (1) */
#define P3_ECO 3 /* ECO number (3) */
#define P3_UECO 0 /* user ECO number (0) */
#define II_L2ROUT 01 /* level 2 router */
#define II_L1ROUT 02 /* level 1 router */
#define II_ENDNODE 03 /* endnode */
#define II_VERIF 04 /* verification required */
#define II_NOMCAST 040 /* no multicast traffic accepted */
#define II_BLOCK 0100 /* blocking requested */
#define II_TYPEMASK 03 /* mask for node type */
#define TESTDATA 0252 /* test data bytes */
#define TESTLEN 1 /* length of transmitted test data */
/*
* Define control message formats.
*/
struct initmsgIII /* phase III initialization message */
{
byte inIII_flags; /* route flags */
word inIII_src; /* source node address */
byte inIII_info; /* routing layer information */
word inIII_blksize; /* maximum data link block size */
byte inIII_vers; /* version number */
byte inIII_eco; /* ECO number */
byte inIII_ueco; /* user ECO number */
byte inIII_rsvd; /* reserved image field */
};
struct initmsg /* initialization message */
{
byte in_flags; /* route flags */
word in_src; /* source node address */
byte in_info; /* routing layer information */
word in_blksize; /* maximum data link block size */
byte in_vers; /* version number */
byte in_eco; /* ECO number */
byte in_ueco; /* user ECO number */
word in_hello; /* hello timer */
byte in_rsvd; /* reserved image field */
};
struct verifmsg /* verification message */
{
byte ve_flags; /* route flags */
word ve_src; /* source node address */
byte ve_fcnval; /* function value image field */
};
struct testmsg /* hello and test message */
{
byte te_flags; /* route flags */
word te_src; /* source node address */
byte te_data; /* test data image field */
};
struct l1rout /* level 1 routing message */
{
byte r1_flags; /* route flags */
word r1_src; /* source node address */
byte r1_rsvd; /* reserved field */
};
struct l2rout /* level 2 routing message */
{
byte r2_flags; /* route flags */
word r2_src; /* source node address */
byte r2_rsvd; /* reserved field */
};
struct rhellomsg /* router hello message */
{
byte rh_flags; /* route flags */
byte rh_vers; /* version number */
byte rh_eco; /* ECO number */
byte rh_ueco; /* user ECO number */
etheraddr rh_src; /* source id */
byte rh_info; /* routing layer information */
word rh_blksize; /* maximum data link block size */
byte rh_priority; /* router's priority */
byte rh_area; /* reserved */
word rh_hello; /* hello timer */
byte rh_mpd; /* reserved */
};
struct ehellomsg /* endnode hello message */
{
byte eh_flags; /* route flags */
byte eh_vers; /* version number */
byte eh_eco; /* ECO number */
byte eh_ueco; /* user ECO number */
etheraddr eh_src; /* source id */
byte eh_info; /* routing layer information */
word eh_blksize; /* maximum data link block size */
byte eh_area; /* area (reserved) */
byte eh_seed[8]; /* verification seed */
etheraddr eh_router; /* designated router */
word eh_hello; /* hello timer */
byte eh_mpd; /* (reserved) */
byte eh_data; /* test data image field */
};
union controlmsg
{
struct initmsg cm_init; /* initialization message */
struct verifmsg cm_ver; /* verification message */
struct testmsg cm_test; /* hello and test message */
struct l1rout cm_l1rou; /* level 1 routing message */
struct l2rout cm_l2rout; /* level 2 routing message */
struct rhellomsg cm_rhello; /* router hello message */
struct ehellomsg cm_ehello; /* endnode hello message */
};
/* Macros for decoding routing-info fields */
#define RI_COST(x) ((x)&0777)
#define RI_HOPS(x) (((x)>>10)&037)
/*
* NSP protocol fields and values.
*/
#define NSP_TYPEMASK 014 /* mask to isolate type code */
#define NSP_SUBMASK 0160 /* mask to isolate subtype code */
#define NSP_SUBSHFT 4 /* shift to move subtype code */
#define MFT_DATA 0 /* data message */
#define MFT_ACK 04 /* acknowledgement message */
#define MFT_CTL 010 /* control message */
#define MFS_ILS 020 /* data or I/LS indicator */
#define MFS_BOM 040 /* beginning of message (data) */
#define MFS_MOM 0 /* middle of message (data) */
#define MFS_EOM 0100 /* end of message (data) */
#define MFS_INT 040 /* interrupt message */
#define MFS_DACK 0 /* data acknowledgement */
#define MFS_IACK 020 /* I/LS acknowledgement */
#define MFS_CACK 040 /* connect acknowledgement */
#define MFS_NOP 0 /* no operation */
#define MFS_CI 020 /* connect initiate */
#define MFS_CC 040 /* connect confirm */
#define MFS_DI 060 /* disconnect initiate */
#define MFS_DC 0100 /* disconnect confirm */
#define MFS_RCI 0140 /* retransmitted connect initiate */
#define SGQ_ACK 0100000 /* ack */
#define SGQ_NAK 0110000 /* negative ack */
#define SGQ_OACK 0120000 /* other channel ack */
#define SGQ_ONAK 0130000 /* other channel negative ack */
#define SGQ_MASK 07777 /* mask to isolate seq # */
#define SGQ_OTHER 020000 /* other channel qualifier */
#define SGQ_DELAY 010000 /* ack delay flag */
#define SGQ_EOM 0100000 /* pseudo flag for end-of-message */
#define LSM_MASK 03 /* mask for modifier field */
#define LSM_NOCHANGE 0 /* no change */
#define LSM_DONOTSEND 1 /* do not send data */
#define LSM_SEND 2 /* send data */
#define LSI_MASK 014 /* mask for interpretation field */
#define LSI_DATA 0 /* data segment or message count */
#define LSI_INTR 4 /* interrupt request count */
#define LSI_INTM 0377 /* funny marker for int. message */
#define COS_MASK 014 /* mask for flow control field */
#define COS_NONE 0 /* no flow control */
#define COS_SEGMENT 04 /* segment flow control */
#define COS_MESSAGE 010 /* message flow control */
#define COS_DEFAULT 1 /* default value for field */
#define COI_MASK 3 /* mask for version field */
#define COI_32 0 /* version 3.2 */
#define COI_31 1 /* version 3.1 */
#define COI_40 2 /* version 4.0 */
#define COI_41 3 /* version 4.1 */
#define MNU_MASK 140 /* mask for session control version */
#define MNU_10 000 /* session V1.0 */
#define MNU_20 040 /* session V2.0 */
#define MNU_ACCESS 1 /* access control present */
#define MNU_USRDATA 2 /* user data field present */
#define MNU_INVKPROXY 4 /* invoke proxy field present */
#define MNU_UICPROXY 8 /* use uic-based proxy */
#define DC_NORESOURCES 1 /* no resource reason code */
#define DC_NOLINK 41 /* no link terminate reason code */
#define DC_COMPLETE 42 /* disconnect complete reason code */
#define DI_NOERROR 0 /* user disconnect */
#define DI_SHUT 3 /* node is shutting down */
#define DI_NOUSER 4 /* destination end user does not exist */
#define DI_INVDEST 5 /* invalid end user destination */
#define DI_REMRESRC 6 /* insufficient remote resources */
#define DI_TPA 8 /* third party abort */
#define DI_PROTOCOL 7 /* protocol error discovered */
#define DI_ABORT 9 /* user abort */
#define DI_LOCALRESRC 32 /* insufficient local resources */
#define DI_REMUSERRESRC 33 /* insufficient remote user resources */
#define DI_BADACCESS 34 /* bad access control information */
#define DI_BADACCNT 36 /* bad ACCOUNT information */
#define DI_CONNECTABORT 38 /* connect request cancelled */
#define DI_TIMEDOUT 38 /* remote node or user crashed */
#define DI_UNREACHABLE 39 /* local timers expired due to ... */
#define DI_BADIMAGE 43 /* bad image data in connect */
#define DI_SERVMISMATCH 54 /* cryptographic service mismatch */
#define UC_OBJREJECT 0 /* object rejected connect */
#define UC_USERDISCONNECT 0 /* user disconnect */
#define UC_RESOURCES 1 /* insufficient resources (local or remote) */
#define UC_NOSUCHNODE 2 /* unrecognized node name */
#define UC_REMOTESHUT 3 /* remote node shutting down */
#define UC_NOSUCHOBJ 4 /* unrecognized object */
#define UC_INVOBJFORMAT 5 /* invalid object name format */
#define UC_OBJTOOBUSY 6 /* object too busy */
#define UC_NETWORKABORT 8 /* network abort */
#define UC_USERABORT 9 /* user abort */
#define UC_INVNODEFORMAT 10 /* invalid node name format */
#define UC_LOCALSHUT 11 /* local node shutting down */
#define UC_ACCESSREJECT 34 /* invalid access control information */
#define UC_NORESPONSE 38 /* no response from object */
#define UC_UNREACHABLE 39 /* node unreachable */
/*
* NSP message formats.
*/
struct nsphdr /* general nsp header */
{
byte nh_flags; /* message flags */
word nh_dst; /* destination link address */
word nh_src; /* source link address */
};
struct seghdr /* data segment header */
{
byte sh_flags; /* message flags */
word sh_dst; /* destination link address */
word sh_src; /* source link address */
word sh_seq[3]; /* sequence numbers */
};
struct minseghdr /* minimum data segment header */
{
byte ms_flags; /* message flags */
word ms_dst; /* destination link address */
word ms_src; /* source link address */
word ms_seq; /* sequence number */
};
struct lsmsg /* link service message (after hdr) */
{
byte ls_lsflags; /* link service flags */
byte ls_fcval; /* flow control value */
};
struct ackmsg /* acknowledgement message */
{
byte ak_flags; /* message flags */
word ak_dst; /* destination link address */
word ak_src; /* source link address */
word ak_acknum[2]; /* acknowledgement numbers */
};
struct minackmsg /* minimum acknowledgement message */
{
byte mk_flags; /* message flags */
word mk_dst; /* destination link address */
word mk_src; /* source link address */
word mk_acknum; /* acknowledgement number */
};
struct ciackmsg /* connect acknowledgement message */
{
byte ck_flags; /* message flags */
word ck_dst; /* destination link address */
};
struct cimsg /* connect initiate message */
{
byte ci_flags; /* message flags */
word ci_dst; /* destination link address (0) */
word ci_src; /* source link address */
byte ci_services; /* requested services */
byte ci_info; /* information */
word ci_segsize; /* maximum segment size */
};
struct ccmsg /* connect confirm message */
{
byte cc_flags; /* message flags */
word cc_dst; /* destination link address */
word cc_src; /* source link address */
byte cc_services; /* requested services */
byte cc_info; /* information */
word cc_segsize; /* maximum segment size */
byte cc_optlen; /* optional data length */
};
struct cnmsg /* generic connect message */
{
byte cn_flags; /* message flags */
word cn_dst; /* destination link address */
word cn_src; /* source link address */
byte cn_services; /* requested services */
byte cn_info; /* information */
word cn_segsize; /* maximum segment size */
};
struct dimsg /* disconnect initiate message */
{
byte di_flags; /* message flags */
word di_dst; /* destination link address */
word di_src; /* source link address */
word di_reason; /* reason code */
byte di_optlen; /* optional data length */
};
struct dcmsg /* disconnect confirm message */
{
byte dc_flags; /* message flags */
word dc_dst; /* destination link address */
word dc_src; /* source link address */
word dc_reason; /* reason code */
};
/* Forwards */
static int print_decnet_ctlmsg(netdissect_options *, const union routehdr *, u_int, u_int);
static void print_t_info(netdissect_options *, u_int);
static int print_l1_routes(netdissect_options *, const u_char *, u_int);
static int print_l2_routes(netdissect_options *, const u_char *, u_int);
static void print_i_info(netdissect_options *, u_int);
static int print_elist(const u_char *, u_int);
static int print_nsp(netdissect_options *, const u_char *, u_int);
static void print_reason(netdissect_options *, u_int);
void
decnet_print(netdissect_options *ndo,
const u_char *ap, u_int length,
u_int caplen)
{
const union routehdr *rhp;
u_int mflags;
uint16_t dst, src;
u_int hops;
u_int nsplen, pktlen;
const u_char *nspp;
ndo->ndo_protocol = "decnet";
if (length < sizeof(struct shorthdr)) {
nd_print_trunc(ndo);
return;
}
ND_TCHECK_LEN(ap, sizeof(short));
pktlen = GET_LE_U_2(ap);
if (pktlen < sizeof(struct shorthdr)) {
nd_print_trunc(ndo);
return;
}
if (pktlen > length) {
nd_print_trunc(ndo);
return;
}
length = pktlen;
rhp = (const union routehdr *)(ap + sizeof(short));
ND_TCHECK_1(rhp->rh_short.sh_flags);
mflags = GET_U_1(rhp->rh_short.sh_flags);
if (mflags & RMF_PAD) {
/* pad bytes of some sort in front of message */
u_int padlen = mflags & RMF_PADMASK;
if (ndo->ndo_vflag)
ND_PRINT("[pad:%u] ", padlen);
if (length < padlen + 2) {
nd_print_trunc(ndo);
return;
}
ND_TCHECK_LEN(ap + sizeof(short), padlen);
ap += padlen;
length -= padlen;
caplen -= padlen;
rhp = (const union routehdr *)(ap + sizeof(short));
ND_TCHECK_1(rhp->rh_short.sh_flags);
mflags = GET_U_1(rhp->rh_short.sh_flags);
}
if (mflags & RMF_FVER) {
ND_PRINT("future-version-decnet");
ND_DEFAULTPRINT(ap, min(length, caplen));
return;
}
/* is it a control message? */
if (mflags & RMF_CTLMSG) {
if (!print_decnet_ctlmsg(ndo, rhp, length, caplen))
goto trunc;
return;
}
switch (mflags & RMF_MASK) {
case RMF_LONG:
if (length < sizeof(struct longhdr)) {
nd_print_trunc(ndo);
return;
}
ND_TCHECK_SIZE(&rhp->rh_long);
dst =
GET_LE_U_2(rhp->rh_long.lg_dst.dne_remote.dne_nodeaddr);
src =
GET_LE_U_2(rhp->rh_long.lg_src.dne_remote.dne_nodeaddr);
hops = GET_U_1(rhp->rh_long.lg_visits);
nspp = ap + sizeof(short) + sizeof(struct longhdr);
nsplen = length - sizeof(struct longhdr);
break;
case RMF_SHORT:
ND_TCHECK_SIZE(&rhp->rh_short);
dst = GET_LE_U_2(rhp->rh_short.sh_dst);
src = GET_LE_U_2(rhp->rh_short.sh_src);
hops = (GET_U_1(rhp->rh_short.sh_visits) & VIS_MASK)+1;
nspp = ap + sizeof(short) + sizeof(struct shorthdr);
nsplen = length - sizeof(struct shorthdr);
break;
default:
ND_PRINT("unknown message flags under mask");
ND_DEFAULTPRINT((const u_char *)ap, min(length, caplen));
return;
}
ND_PRINT("%s > %s %u ",
dnaddr_string(ndo, src), dnaddr_string(ndo, dst), pktlen);
if (ndo->ndo_vflag) {
if (mflags & RMF_RQR)
ND_PRINT("RQR ");
if (mflags & RMF_RTS)
ND_PRINT("RTS ");
if (mflags & RMF_IE)
ND_PRINT("IE ");
ND_PRINT("%u hops ", hops);
}
if (!print_nsp(ndo, nspp, nsplen))
goto trunc;
return;
trunc:
nd_print_trunc(ndo);
return;
}
static int
print_decnet_ctlmsg(netdissect_options *ndo,
const union routehdr *rhp, u_int length,
u_int caplen)
{
/* Our caller has already checked for mflags */
u_int mflags = GET_U_1(rhp->rh_short.sh_flags);
const union controlmsg *cmp = (const union controlmsg *)rhp;
uint16_t src, dst;
u_int info, blksize, eco, ueco, hello, other, vers;
u_int priority;
const u_char *rhpx = (const u_char *)rhp;
int ret;
switch (mflags & RMF_CTLMASK) {
case RMF_INIT:
ND_PRINT("init ");
if (length < sizeof(struct initmsg))
goto trunc;
ND_TCHECK_SIZE(&cmp->cm_init);
src = GET_LE_U_2(cmp->cm_init.in_src);
info = GET_U_1(cmp->cm_init.in_info);
blksize = GET_LE_U_2(cmp->cm_init.in_blksize);
vers = GET_U_1(cmp->cm_init.in_vers);
eco = GET_U_1(cmp->cm_init.in_eco);
ueco = GET_U_1(cmp->cm_init.in_ueco);
hello = GET_LE_U_2(cmp->cm_init.in_hello);
print_t_info(ndo, info);
ND_PRINT("src %sblksize %u vers %u eco %u ueco %u hello %u",
dnaddr_string(ndo, src), blksize, vers, eco, ueco,
hello);
ret = 1;
break;
case RMF_VER:
ND_PRINT("verification ");
if (length < sizeof(struct verifmsg))
goto trunc;
ND_TCHECK_SIZE(&cmp->cm_ver);
src = GET_LE_U_2(cmp->cm_ver.ve_src);
other = GET_U_1(cmp->cm_ver.ve_fcnval);
ND_PRINT("src %s fcnval %o", dnaddr_string(ndo, src), other);
ret = 1;
break;
case RMF_TEST:
ND_PRINT("test ");
if (length < sizeof(struct testmsg))
goto trunc;
ND_TCHECK_SIZE(&cmp->cm_test);
src = GET_LE_U_2(cmp->cm_test.te_src);
other = GET_U_1(cmp->cm_test.te_data);
ND_PRINT("src %s data %o", dnaddr_string(ndo, src), other);
ret = 1;
break;
case RMF_L1ROUT:
ND_PRINT("lev-1-routing ");
if (length < sizeof(struct l1rout))
goto trunc;
ND_TCHECK_SIZE(&cmp->cm_l1rou);
src = GET_LE_U_2(cmp->cm_l1rou.r1_src);
ND_PRINT("src %s ", dnaddr_string(ndo, src));
ret = print_l1_routes(ndo, &(rhpx[sizeof(struct l1rout)]),
length - sizeof(struct l1rout));
break;
case RMF_L2ROUT:
ND_PRINT("lev-2-routing ");
if (length < sizeof(struct l2rout))
goto trunc;
ND_TCHECK_SIZE(&cmp->cm_l2rout);
src = GET_LE_U_2(cmp->cm_l2rout.r2_src);
ND_PRINT("src %s ", dnaddr_string(ndo, src));
ret = print_l2_routes(ndo, &(rhpx[sizeof(struct l2rout)]),
length - sizeof(struct l2rout));
break;
case RMF_RHELLO:
ND_PRINT("router-hello ");
if (length < sizeof(struct rhellomsg))
goto trunc;
ND_TCHECK_SIZE(&cmp->cm_rhello);
vers = GET_U_1(cmp->cm_rhello.rh_vers);
eco = GET_U_1(cmp->cm_rhello.rh_eco);
ueco = GET_U_1(cmp->cm_rhello.rh_ueco);
src =
GET_LE_U_2(cmp->cm_rhello.rh_src.dne_remote.dne_nodeaddr);
info = GET_U_1(cmp->cm_rhello.rh_info);
blksize = GET_LE_U_2(cmp->cm_rhello.rh_blksize);
priority = GET_U_1(cmp->cm_rhello.rh_priority);
hello = GET_LE_U_2(cmp->cm_rhello.rh_hello);
print_i_info(ndo, info);
ND_PRINT("vers %u eco %u ueco %u src %s blksize %u pri %u hello %u",
vers, eco, ueco, dnaddr_string(ndo, src),
blksize, priority, hello);
ret = print_elist(&(rhpx[sizeof(struct rhellomsg)]),
length - sizeof(struct rhellomsg));
break;
case RMF_EHELLO:
ND_PRINT("endnode-hello ");
if (length < sizeof(struct ehellomsg))
goto trunc;
ND_TCHECK_SIZE(&cmp->cm_ehello);
vers = GET_U_1(cmp->cm_ehello.eh_vers);
eco = GET_U_1(cmp->cm_ehello.eh_eco);
ueco = GET_U_1(cmp->cm_ehello.eh_ueco);
src =
GET_LE_U_2(cmp->cm_ehello.eh_src.dne_remote.dne_nodeaddr);
info = GET_U_1(cmp->cm_ehello.eh_info);
blksize = GET_LE_U_2(cmp->cm_ehello.eh_blksize);
/*seed*/
dst =
GET_LE_U_2(cmp->cm_ehello.eh_router.dne_remote.dne_nodeaddr);
hello = GET_LE_U_2(cmp->cm_ehello.eh_hello);
other = GET_U_1(cmp->cm_ehello.eh_data);
print_i_info(ndo, info);
ND_PRINT("vers %u eco %u ueco %u src %s blksize %u rtr %s hello %u data %o",
vers, eco, ueco, dnaddr_string(ndo, src),
blksize, dnaddr_string(ndo, dst), hello, other);
ret = 1;
break;
default:
ND_PRINT("unknown control message");
ND_DEFAULTPRINT((const u_char *)rhp, min(length, caplen));
ret = 1;
break;
}
return (ret);
trunc:
return (0);
}
static void
print_t_info(netdissect_options *ndo,
u_int info)
{
u_int ntype = info & 3;
switch (ntype) {
case 0: ND_PRINT("reserved-ntype? "); break;
case TI_L2ROUT: ND_PRINT("l2rout "); break;
case TI_L1ROUT: ND_PRINT("l1rout "); break;
case TI_ENDNODE: ND_PRINT("endnode "); break;
}
if (info & TI_VERIF)
ND_PRINT("verif ");
if (info & TI_BLOCK)
ND_PRINT("blo ");
}
static int
print_l1_routes(netdissect_options *ndo,
const u_char *rp, u_int len)
{
u_int count;
u_int id;
u_int info;
/* The last short is a checksum */
while (len > (3 * sizeof(short))) {
ND_TCHECK_LEN(rp, 3 * sizeof(short));
count = GET_LE_U_2(rp);
if (count > 1024)
return (1); /* seems to be bogus from here on */
rp += sizeof(short);
len -= sizeof(short);
id = GET_LE_U_2(rp);
rp += sizeof(short);
len -= sizeof(short);
info = GET_LE_U_2(rp);
rp += sizeof(short);
len -= sizeof(short);
ND_PRINT("{ids %u-%u cost %u hops %u} ", id, id + count,
RI_COST(info), RI_HOPS(info));
}
return (1);
trunc:
return (0);
}
static int
print_l2_routes(netdissect_options *ndo,
const u_char *rp, u_int len)
{
u_int count;
u_int area;
u_int info;
/* The last short is a checksum */
while (len > (3 * sizeof(short))) {
ND_TCHECK_LEN(rp, 3 * sizeof(short));
count = GET_LE_U_2(rp);
if (count > 1024)
return (1); /* seems to be bogus from here on */
rp += sizeof(short);
len -= sizeof(short);
area = GET_LE_U_2(rp);
rp += sizeof(short);
len -= sizeof(short);
info = GET_LE_U_2(rp);
rp += sizeof(short);
len -= sizeof(short);
ND_PRINT("{areas %u-%u cost %u hops %u} ", area, area + count,
RI_COST(info), RI_HOPS(info));
}
return (1);
trunc:
return (0);
}
static void
print_i_info(netdissect_options *ndo,
u_int info)
{
u_int ntype = info & II_TYPEMASK;
switch (ntype) {
case 0: ND_PRINT("reserved-ntype? "); break;
case II_L2ROUT: ND_PRINT("l2rout "); break;
case II_L1ROUT: ND_PRINT("l1rout "); break;
case II_ENDNODE: ND_PRINT("endnode "); break;
}
if (info & II_VERIF)
ND_PRINT("verif ");
if (info & II_NOMCAST)
ND_PRINT("nomcast ");
if (info & II_BLOCK)
ND_PRINT("blo ");
}
static int
print_elist(const u_char *elp _U_, u_int len _U_)
{
/* Not enough examples available for me to debug this */
return (1);
}
static int
print_nsp(netdissect_options *ndo,
const u_char *nspp, u_int nsplen)
{
const struct nsphdr *nsphp = (const struct nsphdr *)nspp;
u_int dst, src, flags;
if (nsplen < sizeof(struct nsphdr))
goto trunc;
ND_TCHECK_SIZE(nsphp);
flags = GET_U_1(nsphp->nh_flags);
dst = GET_LE_U_2(nsphp->nh_dst);
src = GET_LE_U_2(nsphp->nh_src);
switch (flags & NSP_TYPEMASK) {
case MFT_DATA:
switch (flags & NSP_SUBMASK) {
case MFS_BOM:
case MFS_MOM:
case MFS_EOM:
case MFS_BOM+MFS_EOM:
ND_PRINT("data %u>%u ", src, dst);
{
const struct seghdr *shp = (const struct seghdr *)nspp;
u_int ack;
u_int data_off = sizeof(struct minseghdr);
if (nsplen < data_off)
goto trunc;
ND_TCHECK_2(shp->sh_seq[0]);
ack = GET_LE_U_2(shp->sh_seq[0]);
if (ack & SGQ_ACK) { /* acknum field */
if ((ack & SGQ_NAK) == SGQ_NAK)
ND_PRINT("nak %u ", ack & SGQ_MASK);
else
ND_PRINT("ack %u ", ack & SGQ_MASK);
data_off += sizeof(short);
if (nsplen < data_off)
goto trunc;
ND_TCHECK_2(shp->sh_seq[1]);
ack = GET_LE_U_2(shp->sh_seq[1]);
if (ack & SGQ_OACK) { /* ackoth field */
if ((ack & SGQ_ONAK) == SGQ_ONAK)
ND_PRINT("onak %u ", ack & SGQ_MASK);
else
ND_PRINT("oack %u ", ack & SGQ_MASK);
data_off += sizeof(short);
if (nsplen < data_off)
goto trunc;
ND_TCHECK_2(shp->sh_seq[2]);
ack = GET_LE_U_2(shp->sh_seq[2]);
}
}
ND_PRINT("seg %u ", ack & SGQ_MASK);
}
break;
case MFS_ILS+MFS_INT:
ND_PRINT("intr ");
{
const struct seghdr *shp = (const struct seghdr *)nspp;
u_int ack;
u_int data_off = sizeof(struct minseghdr);
if (nsplen < data_off)
goto trunc;
ND_TCHECK_2(shp->sh_seq[0]);
ack = GET_LE_U_2(shp->sh_seq[0]);
if (ack & SGQ_ACK) { /* acknum field */
if ((ack & SGQ_NAK) == SGQ_NAK)
ND_PRINT("nak %u ", ack & SGQ_MASK);
else
ND_PRINT("ack %u ", ack & SGQ_MASK);
data_off += sizeof(short);
if (nsplen < data_off)
goto trunc;
ND_TCHECK_2(shp->sh_seq[1]);
ack = GET_LE_U_2(shp->sh_seq[1]);
if (ack & SGQ_OACK) { /* ackdat field */
if ((ack & SGQ_ONAK) == SGQ_ONAK)
ND_PRINT("nakdat %u ", ack & SGQ_MASK);
else
ND_PRINT("ackdat %u ", ack & SGQ_MASK);
data_off += sizeof(short);
if (nsplen < data_off)
goto trunc;
ND_TCHECK_2(shp->sh_seq[2]);
ack = GET_LE_U_2(shp->sh_seq[2]);
}
}
ND_PRINT("seg %u ", ack & SGQ_MASK);
}
break;
case MFS_ILS:
ND_PRINT("link-service %u>%u ", src, dst);
{
const struct seghdr *shp = (const struct seghdr *)nspp;
const struct lsmsg *lsmp =
(const struct lsmsg *)(nspp + sizeof(struct seghdr));
u_int ack;
u_int lsflags, fcval;
if (nsplen < sizeof(struct seghdr) + sizeof(struct lsmsg))
goto trunc;
ND_TCHECK_2(shp->sh_seq[0]);
ack = GET_LE_U_2(shp->sh_seq[0]);
if (ack & SGQ_ACK) { /* acknum field */
if ((ack & SGQ_NAK) == SGQ_NAK)
ND_PRINT("nak %u ", ack & SGQ_MASK);
else
ND_PRINT("ack %u ", ack & SGQ_MASK);
ND_TCHECK_2(shp->sh_seq[1]);
ack = GET_LE_U_2(shp->sh_seq[1]);
if (ack & SGQ_OACK) { /* ackdat field */
if ((ack & SGQ_ONAK) == SGQ_ONAK)
ND_PRINT("nakdat %u ", ack & SGQ_MASK);
else
ND_PRINT("ackdat %u ", ack & SGQ_MASK);
ND_TCHECK_2(shp->sh_seq[2]);
ack = GET_LE_U_2(shp->sh_seq[2]);
}
}
ND_PRINT("seg %u ", ack & SGQ_MASK);
ND_TCHECK_SIZE(lsmp);
lsflags = GET_U_1(lsmp->ls_lsflags);
fcval = GET_U_1(lsmp->ls_fcval);
switch (lsflags & LSI_MASK) {
case LSI_DATA:
ND_PRINT("dat seg count %u ", fcval);
switch (lsflags & LSM_MASK) {
case LSM_NOCHANGE:
break;
case LSM_DONOTSEND:
ND_PRINT("donotsend-data ");
break;
case LSM_SEND:
ND_PRINT("send-data ");
break;
default:
ND_PRINT("reserved-fcmod? %x", lsflags);
break;
}
break;
case LSI_INTR:
ND_PRINT("intr req count %u ", fcval);
break;
default:
ND_PRINT("reserved-fcval-int? %x", lsflags);
break;
}
}
break;
default:
ND_PRINT("reserved-subtype? %x %u > %u", flags, src, dst);
break;
}
break;
case MFT_ACK:
switch (flags & NSP_SUBMASK) {
case MFS_DACK:
ND_PRINT("data-ack %u>%u ", src, dst);
{
const struct ackmsg *amp = (const struct ackmsg *)nspp;
u_int ack;
if (nsplen < sizeof(struct ackmsg))
goto trunc;
ND_TCHECK_SIZE(amp);
ack = GET_LE_U_2(amp->ak_acknum[0]);
if (ack & SGQ_ACK) { /* acknum field */
if ((ack & SGQ_NAK) == SGQ_NAK)
ND_PRINT("nak %u ", ack & SGQ_MASK);
else
ND_PRINT("ack %u ", ack & SGQ_MASK);
ack = GET_LE_U_2(amp->ak_acknum[1]);
if (ack & SGQ_OACK) { /* ackoth field */
if ((ack & SGQ_ONAK) == SGQ_ONAK)
ND_PRINT("onak %u ", ack & SGQ_MASK);
else
ND_PRINT("oack %u ", ack & SGQ_MASK);
}
}
}
break;
case MFS_IACK:
ND_PRINT("ils-ack %u>%u ", src, dst);
{
const struct ackmsg *amp = (const struct ackmsg *)nspp;
u_int ack;
if (nsplen < sizeof(struct ackmsg))
goto trunc;
ND_TCHECK_SIZE(amp);
ack = GET_LE_U_2(amp->ak_acknum[0]);
if (ack & SGQ_ACK) { /* acknum field */
if ((ack & SGQ_NAK) == SGQ_NAK)
ND_PRINT("nak %u ", ack & SGQ_MASK);
else
ND_PRINT("ack %u ", ack & SGQ_MASK);
ND_TCHECK_2(amp->ak_acknum[1]);
ack = GET_LE_U_2(amp->ak_acknum[1]);
if (ack & SGQ_OACK) { /* ackdat field */
if ((ack & SGQ_ONAK) == SGQ_ONAK)
ND_PRINT("nakdat %u ", ack & SGQ_MASK);
else
ND_PRINT("ackdat %u ", ack & SGQ_MASK);
}
}
}
break;
case MFS_CACK:
ND_PRINT("conn-ack %u", dst);
break;
default:
ND_PRINT("reserved-acktype? %x %u > %u", flags, src, dst);
break;
}
break;
case MFT_CTL:
switch (flags & NSP_SUBMASK) {
case MFS_CI:
case MFS_RCI:
if ((flags & NSP_SUBMASK) == MFS_CI)
ND_PRINT("conn-initiate ");
else
ND_PRINT("retrans-conn-initiate ");
ND_PRINT("%u>%u ", src, dst);
{
const struct cimsg *cimp = (const struct cimsg *)nspp;
u_int services, info, segsize;
if (nsplen < sizeof(struct cimsg))
goto trunc;
ND_TCHECK_SIZE(cimp);
services = GET_U_1(cimp->ci_services);
info = GET_U_1(cimp->ci_info);
segsize = GET_LE_U_2(cimp->ci_segsize);
switch (services & COS_MASK) {
case COS_NONE:
break;
case COS_SEGMENT:
ND_PRINT("seg ");
break;
case COS_MESSAGE:
ND_PRINT("msg ");
break;
}
switch (info & COI_MASK) {
case COI_32:
ND_PRINT("ver 3.2 ");
break;
case COI_31:
ND_PRINT("ver 3.1 ");
break;
case COI_40:
ND_PRINT("ver 4.0 ");
break;
case COI_41:
ND_PRINT("ver 4.1 ");
break;
}
ND_PRINT("segsize %u ", segsize);
}
break;
case MFS_CC:
ND_PRINT("conn-confirm %u>%u ", src, dst);
{
const struct ccmsg *ccmp = (const struct ccmsg *)nspp;
u_int services, info;
u_int segsize, optlen;
if (nsplen < sizeof(struct ccmsg))
goto trunc;
ND_TCHECK_SIZE(ccmp);
services = GET_U_1(ccmp->cc_services);
info = GET_U_1(ccmp->cc_info);
segsize = GET_LE_U_2(ccmp->cc_segsize);
optlen = GET_U_1(ccmp->cc_optlen);
switch (services & COS_MASK) {
case COS_NONE:
break;
case COS_SEGMENT:
ND_PRINT("seg ");
break;
case COS_MESSAGE:
ND_PRINT("msg ");
break;
}
switch (info & COI_MASK) {
case COI_32:
ND_PRINT("ver 3.2 ");
break;
case COI_31:
ND_PRINT("ver 3.1 ");
break;
case COI_40:
ND_PRINT("ver 4.0 ");
break;
case COI_41:
ND_PRINT("ver 4.1 ");
break;
}
ND_PRINT("segsize %u ", segsize);
if (optlen) {
ND_PRINT("optlen %u ", optlen);
}
}
break;
case MFS_DI:
ND_PRINT("disconn-initiate %u>%u ", src, dst);
{
const struct dimsg *dimp = (const struct dimsg *)nspp;
u_int reason;
u_int optlen;
if (nsplen < sizeof(struct dimsg))
goto trunc;
ND_TCHECK_SIZE(dimp);
reason = GET_LE_U_2(dimp->di_reason);
optlen = GET_U_1(dimp->di_optlen);
print_reason(ndo, reason);
if (optlen) {
ND_PRINT("optlen %u ", optlen);
}
}
break;
case MFS_DC:
ND_PRINT("disconn-confirm %u>%u ", src, dst);
{
const struct dcmsg *dcmp = (const struct dcmsg *)nspp;
u_int reason;
ND_TCHECK_SIZE(dcmp);
reason = GET_LE_U_2(dcmp->dc_reason);
print_reason(ndo, reason);
}
break;
default:
ND_PRINT("reserved-ctltype? %x %u > %u", flags, src, dst);
break;
}
break;
default:
ND_PRINT("reserved-type? %x %u > %u", flags, src, dst);
break;
}
return (1);
trunc:
return (0);
}
static const struct tok reason2str[] = {
{ UC_OBJREJECT, "object rejected connect" },
{ UC_RESOURCES, "insufficient resources" },
{ UC_NOSUCHNODE, "unrecognized node name" },
{ DI_SHUT, "node is shutting down" },
{ UC_NOSUCHOBJ, "unrecognized object" },
{ UC_INVOBJFORMAT, "invalid object name format" },
{ UC_OBJTOOBUSY, "object too busy" },
{ DI_PROTOCOL, "protocol error discovered" },
{ DI_TPA, "third party abort" },
{ UC_USERABORT, "user abort" },
{ UC_INVNODEFORMAT, "invalid node name format" },
{ UC_LOCALSHUT, "local node shutting down" },
{ DI_LOCALRESRC, "insufficient local resources" },
{ DI_REMUSERRESRC, "insufficient remote user resources" },
{ UC_ACCESSREJECT, "invalid access control information" },
{ DI_BADACCNT, "bad ACCOUNT information" },
{ UC_NORESPONSE, "no response from object" },
{ UC_UNREACHABLE, "node unreachable" },
{ DC_NOLINK, "no link terminate" },
{ DC_COMPLETE, "disconnect complete" },
{ DI_BADIMAGE, "bad image data in connect" },
{ DI_SERVMISMATCH, "cryptographic service mismatch" },
{ 0, NULL }
};
static void
print_reason(netdissect_options *ndo,
u_int reason)
{
ND_PRINT("%s ", tok2str(reason2str, "reason-%u", reason));
}
const char *
dnnum_string(netdissect_options *ndo, u_short dnaddr)
{
char *str;
size_t siz;
u_int area = (u_short)(dnaddr & AREAMASK) >> AREASHIFT;
u_int node = dnaddr & NODEMASK;
/* malloc() return used by the 'dnaddrtable' hash table: do not free() */
str = (char *)malloc(siz = sizeof("00.0000"));
if (str == NULL)
(*ndo->ndo_error)(ndo, S_ERR_ND_MEM_ALLOC, "dnnum_string: malloc");
snprintf(str, siz, "%u.%u", area, node);
return(str);
}