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wireshark/plugins/h223/packet-h223.c

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/* packet-h223.c
* Routines for H.223 packet dissection
* Copyright (c) 2004-5 MX Telecom Ltd <richardv@mxtelecom.com>
*
* $Id$
*
* Ethereal - Network traffic analyzer
* By Gerald Combs <gerald@ethereal.com>
* Copyright 1998 Gerald Combs
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version 2
* of the License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
*/
#ifdef HAVE_CONFIG_H
# include "config.h"
#endif
#include <stdio.h>
#include <gmodule.h>
#include <glib.h>
#include <epan/emem.h>
#include <epan/bitswap.h>
#include <epan/circuit.h>
#include <epan/conversation.h>
#include <epan/packet.h>
#include <epan/stream.h>
#include <epan/reassemble.h>
#include <epan/iax2_codec_type.h>
#include <epan/dissectors/packet-frame.h>
#include <epan/dissectors/packet-h245.h>
#include "packet-h223.h"
#include "golay.h"
#include <string.h>
#define PROTO_TAG_H223 "H223"
/* Ethereal ID of the H.223 protocol */
static int proto_h223 = -1;
/* The following hf_* variables are used to hold the ethereal IDs of
* our header fields; they are filled out when we call
* proto_register_field_array() in proto_register_h223()
*/
static int hf_h223_non_h223_data = -1;
static int hf_h223_mux_stuffing_pdu = -1;
static int hf_h223_mux_pdu = -1;
static int hf_h223_mux_header = -1;
static int hf_h223_mux_rawhdr = -1;
static int hf_h223_mux_correctedhdr = -1;
static int hf_h223_mux_mc = -1;
static int hf_h223_mux_mpl = -1;
static int hf_h223_mux_deact = -1;
static int hf_h223_mux_vc = -1;
static int hf_h223_mux_extra = -1;
static int hf_h223_mux_hdlc2 = -1;
static int hf_h223_mux_fragments = -1;
static int hf_h223_mux_fragment = -1;
static int hf_h223_mux_fragment_overlap = -1;
static int hf_h223_mux_fragment_overlap_conflict = -1;
static int hf_h223_mux_fragment_multiple_tails = -1;
static int hf_h223_mux_fragment_too_long_fragment = -1;
static int hf_h223_mux_fragment_error = -1;
static int hf_h223_mux_reassembled_in = -1;
static int hf_h223_al_fragments = -1;
static int hf_h223_al_fragment = -1;
static int hf_h223_al_fragment_overlap = -1;
static int hf_h223_al_fragment_overlap_conflict = -1;
static int hf_h223_al_fragment_multiple_tails = -1;
static int hf_h223_al_fragment_too_long_fragment = -1;
static int hf_h223_al_fragment_error = -1;
static int hf_h223_al_reassembled_in = -1;
static int hf_h223_al1 = -1;
static int hf_h223_al1_framed = -1;
static int hf_h223_al2 = -1;
static int hf_h223_al2_sequenced = -1;
static int hf_h223_al2_seqno = -1;
static int hf_h223_al2_crc = -1;
static int hf_h223_al2_crc_bad = -1;
static int hf_h223_al_payload = -1;
/* These are the ids of the subtrees that we may be creating */
static gint ett_h223 = -1;
static gint ett_h223_non_h223_data = -1;
static gint ett_h223_mux_stuffing_pdu = -1;
static gint ett_h223_mux_pdu = -1;
static gint ett_h223_mux_header = -1;
static gint ett_h223_mux_deact = -1;
static gint ett_h223_mux_vc = -1;
static gint ett_h223_mux_extra = -1;
static gint ett_h223_mux_fragments = -1;
static gint ett_h223_mux_fragment = -1;
static gint ett_h223_al_fragments = -1;
static gint ett_h223_al_fragment = -1;
static gint ett_h223_al1 = -1;
static gint ett_h223_al2 = -1;
static gint ett_h223_al_payload = -1;
/* These are the handles of our subdissectors */
static dissector_handle_t data_handle=NULL;
static dissector_handle_t srp_handle=NULL;
static dissector_handle_t h245dg_handle=NULL;
static const fragment_items h223_mux_frag_items = {
&ett_h223_mux_fragment,
&ett_h223_mux_fragments,
&hf_h223_mux_fragments,
&hf_h223_mux_fragment,
&hf_h223_mux_fragment_overlap,
&hf_h223_mux_fragment_overlap_conflict,
&hf_h223_mux_fragment_multiple_tails,
&hf_h223_mux_fragment_too_long_fragment,
&hf_h223_mux_fragment_error,
&hf_h223_mux_reassembled_in,
"fragments"
};
static const fragment_items h223_al_frag_items = {
&ett_h223_al_fragment,
&ett_h223_al_fragments,
&hf_h223_al_fragments,
&hf_h223_al_fragment,
&hf_h223_al_fragment_overlap,
&hf_h223_al_fragment_overlap_conflict,
&hf_h223_al_fragment_multiple_tails,
&hf_h223_al_fragment_too_long_fragment,
&hf_h223_al_fragment_error,
&hf_h223_al_reassembled_in,
"fragments"
};
static guint32 pdu_offset; /* offset of the last pdu to start being dissected in the last packet to start being dissected */
/***************************************************************************
*
* virtual circuit number handling
*
* we have to be able to manage more than one H.223 call at a time,
* so have a hash which maps {call,vc} to an integer.
*/
typedef struct _h223_call_info h223_call_info;
typedef struct {
const h223_call_info* call; /* h223 call */
guint32 vc; /* child circuit */
} circuit_chain_key;
static GHashTable *circuit_chain_hashtable = NULL;
static guint circuit_chain_count = 1;
/* Hash Functions */
static gint circuit_chain_equal(gconstpointer v, gconstpointer w)
{
const circuit_chain_key *v1 = (const circuit_chain_key *)v;
const circuit_chain_key *v2 = (const circuit_chain_key *)w;
gint result;
result = ( v1->call == v2->call &&
v1->vc == v2 -> vc );
return result;;
}
static guint circuit_chain_hash (gconstpointer v)
{
const circuit_chain_key *key = (const circuit_chain_key *)v;
guint hash_val = ((guint32)(key->call))^(((guint32)key->vc) << 16);
return hash_val;
}
static guint32 circuit_chain_lookup(const h223_call_info* call_info,
guint32 child_vc)
{
circuit_chain_key key, *new_key;
guint32 circuit_id;
key.call = call_info;
key.vc = child_vc;
circuit_id = GPOINTER_TO_UINT(g_hash_table_lookup( circuit_chain_hashtable, &key ));
if( circuit_id == 0 ) {
new_key = se_alloc(sizeof(circuit_chain_key));
*new_key = key;
circuit_id = ++circuit_chain_count;
g_hash_table_insert(circuit_chain_hashtable, new_key, GUINT_TO_POINTER(circuit_id));
}
return circuit_id;
}
static void circuit_chain_init(void)
{
if (circuit_chain_hashtable)
g_hash_table_destroy(circuit_chain_hashtable);
circuit_chain_hashtable = g_hash_table_new(circuit_chain_hash, circuit_chain_equal);
circuit_chain_count = 1;
}
/***************************************************************************
*
* Call information management
*
*/
/* we keep information on each call in an h223_call_info structure
*
* We attach the h223_call_info structures to individual calls with
* circuit_add_proto_data().
*/
typedef struct _h223_mux_element_listitem h223_mux_element_listitem;
struct _h223_mux_element_listitem {
h223_mux_element *me;
guint32 first_frame;
guint32 pdu_offset;
h223_mux_element_listitem *next;
};
/* we have this information for each stream */
typedef struct {
gboolean current_pdu_header_parsed;
guint32 current_pdu_minlen;
guint32 current_pdu_read;
guint32 header_buf;
guint32 tail_buf;
gboolean first_pdu;
h223_mux_element_listitem* mux_table[16];
} h223_call_direction_data;
struct _h223_call_info {
/* H.223 specifies that the least-significant bit is transmitted first;
however this is at odds with IAX which transmits the MSB first, so
in general, all of our bytes are reversed. */
gboolean bitswapped;
/* H.223 level: 0 for standard H223, 1, 2 or 3 for the enhanced protocols
specified in the annexes
*/
int h223_level;
/* for H.223 streams over TCP (as opposed to IAX), this
stores the source address and port of the first packet spotted,
so that we can differentiate directions.
*/
address srcaddress;
guint32 srcport;
h223_call_direction_data direction_data[2];
};
typedef struct _h223_lc_params_listitem h223_lc_params_listitem;
struct _h223_lc_params_listitem
{
h223_lc_params *lc_params;
guint32 first_frame;
guint32 last_frame;
h223_lc_params_listitem *next;
};
typedef struct {
h223_lc_params_listitem *lc_params[2];
h223_call_info *call_info;
} h223_vc_info;
static void add_h223_mux_element(h223_call_direction_data *direct, guint8 mc, h223_mux_element *me, guint32 framenum)
{
h223_mux_element_listitem *li;
h223_mux_element_listitem **old_li_ptr;
h223_mux_element_listitem *old_li;
DISSECTOR_ASSERT(mc < 16);
li = se_alloc(sizeof(h223_mux_element_listitem));
old_li_ptr = &(direct->mux_table[mc]);
old_li = *old_li_ptr;
if( !old_li ) {
direct->mux_table[mc] = li;
} else {
while( old_li->next ) {
old_li_ptr = &(old_li->next);
old_li = *old_li_ptr;
}
if( framenum < old_li->first_frame || (framenum == old_li->first_frame && pdu_offset < old_li->pdu_offset) )
return;
else if ( framenum == old_li->first_frame && pdu_offset == old_li->pdu_offset )
*old_li_ptr = li; /* replace the tail of the list with the new item, since */
/* a single h223 pdu has just set the same MC twice.. */
else
old_li->next = li;
}
li->first_frame = framenum;
li->pdu_offset = pdu_offset;
li->next = 0;
li->me = me;
}
static h223_mux_element* find_h223_mux_element(h223_call_direction_data* direct, guint8 mc, guint32 framenum)
{
h223_mux_element_listitem* li;
DISSECTOR_ASSERT(mc < 16);
li = direct->mux_table[mc];
while( li && li->next && li->next->first_frame < framenum )
li = li->next;
while( li && li->next && li->next->first_frame == framenum && li->next->pdu_offset < pdu_offset )
li = li->next;
if( li ) {
return li->me;
} else {
return NULL;
}
}
static void add_h223_lc_params(h223_vc_info* vc_info, int direction, h223_lc_params *lc_params, guint32 framenum )
{
h223_lc_params_listitem *li = se_alloc(sizeof(h223_lc_params_listitem));
h223_lc_params_listitem **old_li_ptr = &(vc_info->lc_params[direction ? 0 : 1]);
h223_lc_params_listitem *old_li = *old_li_ptr;
if( !old_li ) {
vc_info->lc_params[direction ? 0 : 1] = li;
} else {
while( old_li->next ) {
old_li_ptr = &(old_li->next);
old_li = *old_li_ptr;
}
if( framenum < old_li->first_frame )
return;
else if( framenum == old_li->first_frame )
*old_li_ptr = li;
else {
old_li->next = li;
old_li->last_frame = framenum - 1;
}
}
li->first_frame = framenum;
li->last_frame = 0;
li->next = 0;
li->lc_params = lc_params;
}
static h223_lc_params* find_h223_lc_params(h223_vc_info* vc_info, int direction, guint32 framenum)
{
h223_lc_params_listitem* li = vc_info->lc_params[direction? 0 : 1];
while( li && li->next && li->next->first_frame <= framenum )
li = li->next;
if( li )
return li->lc_params;
else
return NULL;
}
static void init_direction_data(h223_call_direction_data *direct)
{
int i;
h223_mux_element *mc0_element;
direct -> first_pdu = TRUE;
for ( i = 0; i < 16; ++i )
direct->mux_table[i] = NULL;
/* set up MC 0 to contain just VC 0 */
mc0_element = se_alloc(sizeof(h223_mux_element));
add_h223_mux_element( direct, 0, mc0_element, 0 );
mc0_element->sublist = NULL;
mc0_element->vc = 0;
mc0_element->repeat_count = 0; /* until closing flag */
mc0_element->next = NULL;
}
static h223_vc_info* h223_vc_info_new( h223_call_info* call_info )
{
h223_vc_info *vc_info = se_alloc(sizeof(h223_vc_info));
vc_info->lc_params[0] = vc_info->lc_params[1] = NULL;
vc_info->call_info = call_info;
return vc_info;
}
static void init_logical_channel( packet_info* pinfo, h223_call_info* call_info, int vc, int direction, h223_lc_params* params )
{
guint32 circuit_id = circuit_chain_lookup(call_info, vc);
circuit_t *subcircuit;
h223_vc_info *vc_info;
subcircuit = find_circuit( CT_H223, circuit_id, pinfo->fd->num );
if( subcircuit == NULL ) {
subcircuit = circuit_new( CT_H223, circuit_id, pinfo->fd->num );
vc_info = h223_vc_info_new( call_info );
circuit_add_proto_data( subcircuit, proto_h223, vc_info );
} else {
vc_info = circuit_get_proto_data( subcircuit, proto_h223 );
}
add_h223_lc_params( vc_info, direction, params, pinfo->fd->num );
}
static void init_control_channels( packet_info* pinfo, h223_call_info* call_info )
{
h223_lc_params *vc0_params = se_alloc(sizeof(h223_lc_params));
vc0_params->al_type = al1Framed;
vc0_params->al_params = NULL;
vc0_params->segmentable = TRUE;
vc0_params->subdissector = srp_handle;
init_logical_channel( pinfo, call_info, 0, P2P_DIR_SENT, vc0_params );
init_logical_channel( pinfo, call_info, 0, P2P_DIR_RECV, vc0_params );
}
static h223_call_info *find_or_create_call_info ( packet_info * pinfo )
{
circuit_t *circ;
conversation_t *conv = NULL;
h223_call_info *data;
/* look for a circuit (eg, IAX call) first */
circ = find_circuit( pinfo->ctype, pinfo->circuit_id, pinfo->fd->num );
if( circ == NULL ) {
/* assume we're running atop TCP; use the converstion support */
conv = find_conversation( pinfo->fd->num,
&pinfo->src,&pinfo->dst,
pinfo->ptype,
pinfo->srcport,pinfo->destport, 0 );
if( conv == NULL ) {
conv = conversation_new( pinfo->fd->num,
&pinfo->src,&pinfo->dst,
pinfo->ptype,
pinfo->srcport,pinfo->destport, 0 );
}
}
if( circ )
data = (h223_call_info *)circuit_get_proto_data(circ, proto_h223);
else
data = (h223_call_info *)conversation_get_proto_data(conv, proto_h223);
if( data == NULL ) {
data = se_alloc(sizeof(h223_call_info));
if( circ ) {
circuit_add_proto_data(circ, proto_h223, data);
/* circuit-switched H.223 conversations are bitswapped */
data -> bitswapped = TRUE;
} else {
conversation_add_proto_data(conv, proto_h223, data);
/* add the source details so we can distinguish directions
* in future */
COPY_ADDRESS(&(data -> srcaddress), &(pinfo->src));
data -> srcport = pinfo->srcport;
/* packet-switched H.223 conversations are NOT bitswapped */
data -> bitswapped = FALSE;
}
/* initialise the call info */
init_direction_data(&data -> direction_data[0]);
init_direction_data(&data -> direction_data[1]);
/* FIXME shouldn't this be figured out dynamically? */
data -> h223_level = 2;
init_control_channels( pinfo, data );
}
/* work out what direction we're really going in */
if( circ ) {
if( pinfo->p2p_dir < 0 || pinfo->p2p_dir > 1)
pinfo->p2p_dir = P2P_DIR_SENT;
} else {
if( ADDRESSES_EQUAL( &(pinfo->src), &(data->srcaddress))
&& pinfo->srcport == data->srcport )
pinfo->p2p_dir = P2P_DIR_SENT;
else
pinfo->p2p_dir = P2P_DIR_RECV;
}
return data;
}
static void h223_set_mc( packet_info* pinfo, guint8 mc, h223_mux_element* me )
{
circuit_t *circ = find_circuit( pinfo->ctype, pinfo->circuit_id, pinfo->fd->num );
h223_vc_info* vc_info;
/* if this h245 pdu packet came from an h223 circuit, add the details on
* the new mux entry */
if(circ) {
vc_info = circuit_get_proto_data(circ, proto_h223);
add_h223_mux_element( &(vc_info->call_info->direction_data[pinfo->p2p_dir ? 0 : 1]), mc, me, pinfo->fd->num );
}
}
static void h223_add_lc( packet_info* pinfo, guint16 lc, h223_lc_params* params )
{
circuit_t *circ = find_circuit( pinfo->ctype, pinfo->circuit_id, pinfo->fd->num );
h223_vc_info* vc_info;
/* if this h245 pdu packet came from an h223 circuit, add the details on
* the new channel */
if(circ) {
vc_info = circuit_get_proto_data(circ, proto_h223);
init_logical_channel( pinfo, vc_info->call_info, lc, pinfo->p2p_dir, params );
}
}
/************************************************************************************
*
* AL-PDU dissection
*/
const guint8 crctable[256] = {
0x00, 0x91, 0xe3, 0x72, 0x07, 0x96, 0xe4, 0x75, 0x0e, 0x9f, 0xed, 0x7c, 0x09, 0x98, 0xea, 0x7b,
0x1c, 0x8d, 0xff, 0x6e, 0x1b, 0x8a, 0xf8, 0x69, 0x12, 0x83, 0xf1, 0x60, 0x15, 0x84, 0xf6, 0x67,
0x38, 0xa9, 0xdb, 0x4a, 0x3f, 0xae, 0xdc, 0x4d, 0x36, 0xa7, 0xd5, 0x44, 0x31, 0xa0, 0xd2, 0x43,
0x24, 0xb5, 0xc7, 0x56, 0x23, 0xb2, 0xc0, 0x51, 0x2a, 0xbb, 0xc9, 0x58, 0x2d, 0xbc, 0xce, 0x5f,
0x70, 0xe1, 0x93, 0x02, 0x77, 0xe6, 0x94, 0x05, 0x7e, 0xef, 0x9d, 0x0c, 0x79, 0xe8, 0x9a, 0x0b,
0x6c, 0xfd, 0x8f, 0x1e, 0x6b, 0xfa, 0x88, 0x19, 0x62, 0xf3, 0x81, 0x10, 0x65, 0xf4, 0x86, 0x17,
0x48, 0xd9, 0xab, 0x3a, 0x4f, 0xde, 0xac, 0x3d, 0x46, 0xd7, 0xa5, 0x34, 0x41, 0xd0, 0xa2, 0x33,
0x54, 0xc5, 0xb7, 0x26, 0x53, 0xc2, 0xb0, 0x21, 0x5a, 0xcb, 0xb9, 0x28, 0x5d, 0xcc, 0xbe, 0x2f,
0xe0, 0x71, 0x03, 0x92, 0xe7, 0x76, 0x04, 0x95, 0xee, 0x7f, 0x0d, 0x9c, 0xe9, 0x78, 0x0a, 0x9b,
0xfc, 0x6d, 0x1f, 0x8e, 0xfb, 0x6a, 0x18, 0x89, 0xf2, 0x63, 0x11, 0x80, 0xf5, 0x64, 0x16, 0x87,
0xd8, 0x49, 0x3b, 0xaa, 0xdf, 0x4e, 0x3c, 0xad, 0xd6, 0x47, 0x35, 0xa4, 0xd1, 0x40, 0x32, 0xa3,
0xc4, 0x55, 0x27, 0xb6, 0xc3, 0x52, 0x20, 0xb1, 0xca, 0x5b, 0x29, 0xb8, 0xcd, 0x5c, 0x2e, 0xbf,
0x90, 0x01, 0x73, 0xe2, 0x97, 0x06, 0x74, 0xe5, 0x9e, 0x0f, 0x7d, 0xec, 0x99, 0x08, 0x7a, 0xeb,
0x8c, 0x1d, 0x6f, 0xfe, 0x8b, 0x1a, 0x68, 0xf9, 0x82, 0x13, 0x61, 0xf0, 0x85, 0x14, 0x66, 0xf7,
0xa8, 0x39, 0x4b, 0xda, 0xaf, 0x3e, 0x4c, 0xdd, 0xa6, 0x37, 0x45, 0xd4, 0xa1, 0x30, 0x42, 0xd3,
0xb4, 0x25, 0x57, 0xc6, 0xb3, 0x22, 0x50, 0xc1, 0xba, 0x2b, 0x59, 0xc8, 0xbd, 0x2c, 0x5e, 0xcf };
static guint8 h223_al2_crc8bit( tvbuff_t *tvb ) {
guint32 len = tvb_reported_length(tvb) - 1;
const guint8* data = tvb_get_ptr( tvb, 0, len );
unsigned char crc = 0;
guint32 pos = 0;
while ( len-- )
crc = crctable[crc^data[pos++]];
return crc;
}
static void dissect_mux_al_pdu( tvbuff_t *tvb,
packet_info *pinfo,
proto_tree *vc_tree,
/* circuit_t* vc_circuit, */
h223_lc_params* lc_params )
{
proto_tree *al_tree = NULL;
proto_item *al_item;
proto_tree *al_subtree;
proto_item *al_subitem = NULL;
tvbuff_t *next_tvb = NULL;
dissector_handle_t subdissector = lc_params->subdissector;
guint32 len = tvb_reported_length(tvb);
gboolean all_done = FALSE;
guint8 calc_checksum;
guint8 real_checksum;
gboolean al2_sequenced;
switch( lc_params->al_type ) {
case al1Framed:
case al1NotFramed:
al_item = proto_tree_add_none_format(vc_tree, hf_h223_al1, tvb, 0, -1, "H.223 AL1 (%sframed)",
(lc_params->al_type==al1Framed)?"":"not ");
al_tree = proto_item_add_subtree (al_item, ett_h223_al1);
if(lc_params->al_type == al1Framed)
proto_tree_add_boolean_hidden(al_tree, hf_h223_al1_framed, tvb, 0, 1, TRUE );
next_tvb = tvb;
break;
case al2WithoutSequenceNumbers:
case al2WithSequenceNumbers:
if( lc_params->al_type == al2WithoutSequenceNumbers ) {
next_tvb = tvb_new_subset( tvb, 0, len-1, len-1 );
al2_sequenced = FALSE;
} else {
next_tvb = tvb_new_subset( tvb, 1, len-2, len-2 );
al2_sequenced = TRUE;
}
al_item = proto_tree_add_none_format(vc_tree, hf_h223_al2, tvb, 0, -1, "H223 AL2 (with%s sequence numbers)",
al2_sequenced?"":"out" );
al_tree = proto_item_add_subtree (al_item, ett_h223_al2);
if( al2_sequenced ) {
proto_tree_add_boolean_hidden(al_tree, hf_h223_al2_sequenced, tvb, 0, 1, TRUE );
proto_tree_add_uint_format(al_tree, hf_h223_al2_seqno, tvb, 0, 1, tvb_get_guint8( tvb, 0 ),
"Sequence number: %u", tvb_get_guint8( tvb, 0 ) );
}
calc_checksum = h223_al2_crc8bit(tvb);
real_checksum = tvb_get_guint8(tvb, len - 1);
if( calc_checksum == real_checksum ) {
al_subitem = proto_tree_add_item(al_tree, hf_h223_al_payload, next_tvb, 0, -1, FALSE);
proto_tree_add_uint_format(al_tree, hf_h223_al2_crc, tvb, len - 1, 1, real_checksum,
"CRC: 0x%02x (correct)", real_checksum );
} else {
call_dissector(data_handle, tvb, pinfo, al_tree);
proto_tree_add_boolean_hidden( al_tree, hf_h223_al2_crc_bad, tvb, len - 1, 1, TRUE );
proto_tree_add_uint_format(al_tree, hf_h223_al2_crc, tvb, len - 1, 1, real_checksum,
"CRC: 0x%02x (incorrect, should be 0x%02x)", real_checksum, calc_checksum );
all_done = TRUE;
}
break;
default:
break;
}
if (!subdissector)
subdissector = data_handle;
if(next_tvb && al_tree && !al_subitem && !all_done)
al_subitem = proto_tree_add_item(al_tree, hf_h223_al_payload, next_tvb, 0, -1, FALSE);
if(next_tvb && al_subitem && !all_done) {
al_subtree = proto_item_add_subtree(al_subitem, ett_h223_al_payload);
call_dissector(subdissector, next_tvb, pinfo, al_subtree);
} else if ( !all_done )
call_dissector(data_handle, tvb, pinfo, vc_tree);
}
/************************************************************************************
*
* MUX-PDU dissection
*/
/* dissect a fragment of a MUX-PDU which belongs to a particular VC
*
* tvb buffer containing the whole MUX-PDU
* offset offset within the MUX-PDU of this fragment
* pinfo info on the packet containing the last fragment of the MUX-PDU
* pkt_offset offset within that packet of the start of the final fragment of
* the MUX_PDU
* pdu_tree dissection tree for the PDU; a single item will be added (with
* its own subtree)
* vc VC for this SDU
* frag_len length of the MUX-SDU fragment
* end_of_mux_sdu true if this is a segmentable VC and this is the last
* fragment in an SDU
*/
static void dissect_mux_sdu_fragment(tvbuff_t *tvb, guint32 offset,
packet_info *pinfo,
guint32 pkt_offset,
proto_tree *pdu_tree,
h223_call_info* call_info,
guint16 vc, gint frag_len, gboolean end_of_mux_sdu)
{
/* update the circuit details before passing to a subdissector */
guint32 orig_circuit = pinfo->circuit_id;
guint32 orig_ctype = pinfo->ctype;
pinfo->circuit_id=circuit_chain_lookup(call_info, vc);
pinfo->ctype=CT_H223;
TRY {
tvbuff_t *next_tvb = tvb_new_subset(tvb, offset, frag_len, frag_len);
circuit_t *subcircuit=find_circuit(pinfo->ctype,pinfo->circuit_id,pinfo->fd->num);
dissector_handle_t subdissector = NULL;
proto_tree *vc_tree = NULL;
proto_item *vc_item;
h223_vc_info *vc_info = NULL;
h223_lc_params *lc_params = NULL;
gboolean stuffing = ( vc == 0 && frag_len == 0 );
if(pdu_tree && !stuffing) {
vc_item = proto_tree_add_uint(pdu_tree, hf_h223_mux_vc, next_tvb, 0, frag_len, vc);
vc_tree = proto_item_add_subtree (vc_item, ett_h223_mux_vc);
}
if( stuffing ) {
next_tvb = NULL;
subdissector = data_handle;
} else if( subcircuit == NULL ) {
g_message( "Frame %d: no subcircuit id %d found for circuit %d id %d, vc %d", pinfo->fd->num,
pinfo->circuit_id, orig_ctype, orig_circuit, vc );
subdissector = data_handle;
} else {
vc_info = circuit_get_proto_data(subcircuit, proto_h223);
if( vc_info != NULL ) {
lc_params = find_h223_lc_params( vc_info, pinfo->p2p_dir, pinfo->fd->num );
}
if( lc_params == NULL ) {
subdissector = data_handle;
} else {
if( lc_params->segmentable && lc_params->al_type != al1NotFramed ) {
stream_t *substream;
stream_pdu_fragment_t *frag;
substream = find_stream_circ(subcircuit,pinfo->p2p_dir);
if(substream == NULL )
substream = stream_new_circ(subcircuit,pinfo->p2p_dir);
frag = stream_find_frag(substream,pinfo->fd->num,offset+pkt_offset);
if(frag == NULL ) {
frag = stream_add_frag(substream,pinfo->fd->num,offset+pkt_offset,
next_tvb,pinfo,!end_of_mux_sdu);
}
next_tvb = stream_process_reassembled(
next_tvb, 0, pinfo,
"Reassembled H.223 AL-PDU",
frag, &h223_al_frag_items,
NULL, vc_tree);
}
}
}
if(next_tvb) {
if(lc_params)
dissect_mux_al_pdu(next_tvb, pinfo, vc_tree,/* subcircuit,*/ lc_params );
else
call_dissector(subdissector,next_tvb,pinfo,vc_tree);
}
}
/* restore the original circuit details for future PDUs */
FINALLY {
pinfo->ctype=orig_ctype;
pinfo->circuit_id=orig_circuit;
}
ENDTRY;
}
static guint32 mux_element_sublist_size( h223_mux_element* me )
{
h223_mux_element *current_me = me;
guint32 length = 0;
while ( current_me ) {
current_me = current_me->next;
if ( current_me->sublist )
length += current_me->repeat_count * mux_element_sublist_size( current_me->sublist );
else
length += current_me->repeat_count;
}
if ( length == 0 ) { /* should never happen, but to avoid infinite loops... */
DISSECTOR_ASSERT_NOT_REACHED();
length = 1;
}
return length;
}
static guint32 dissect_mux_payload_by_me_list( tvbuff_t *tvb, packet_info *pinfo, guint32 pkt_offset, proto_tree *pdu_tree,
h223_call_info* call_info, h223_mux_element* me, guint32 offset, gboolean endOfMuxSdu )
{
guint32 len = tvb_reported_length(tvb);
guint32 frag_len;
guint32 sublist_len;
int i;
while ( me ) {
if ( me->sublist ) {
if ( me->repeat_count == 0 ) {
for(sublist_len = mux_element_sublist_size( me->sublist );
offset + sublist_len <= len;
offset = dissect_mux_payload_by_me_list( tvb, pinfo, pkt_offset, pdu_tree,
call_info, me->sublist, offset, endOfMuxSdu ) );
} else {
for(i = 0; i < me->repeat_count; ++i)
offset = dissect_mux_payload_by_me_list( tvb, pinfo, pkt_offset, pdu_tree,
call_info, me->sublist, offset, endOfMuxSdu );
}
} else {
if ( me->repeat_count == 0 )
frag_len = len - offset;
else
frag_len = me->repeat_count;
dissect_mux_sdu_fragment( tvb, offset, pinfo, pkt_offset, pdu_tree,
call_info, me->vc, frag_len, (offset+frag_len==len) && endOfMuxSdu);
offset += frag_len;
}
me = me->next;
}
return offset;
}
/* dissect the payload of a MUX-PDU */
static void dissect_mux_payload( tvbuff_t *tvb, packet_info *pinfo, guint32 pkt_offset, proto_tree *pdu_tree,
h223_call_info* call_info, guint8 mc, gboolean endOfMuxSdu )
{
guint32 len = tvb_reported_length(tvb);
h223_mux_element* me = find_h223_mux_element( &(call_info->direction_data[pinfo->p2p_dir ? 0 : 1]), mc, pinfo->fd->num );
if( me ) {
dissect_mux_payload_by_me_list( tvb, pinfo, pkt_offset, pdu_tree, call_info, me, 0, endOfMuxSdu );
} else {
/* no entry found in mux-table. ignore packet and dissect as data */
proto_tree *vc_tree = NULL;
if(pdu_tree) {
proto_item *vc_item = proto_tree_add_item(pdu_tree, hf_h223_mux_deact, tvb, 0, len, FALSE);
vc_tree = proto_item_add_subtree(vc_item, ett_h223_mux_deact);
}
call_dissector(data_handle,tvb,pinfo,vc_tree);
}
}
/* dissect a reassembled mux-pdu
*
* tvb buffer containing mux-pdu, including header and closing flag
* pinfo packet info for packet containing the end of the mux-pdu
* pkt_offset offset within that packet of the start of the last fragment
* h223_tree dissection tree for h223 protocol; a single item will be added
* (with a sub-tree)
* call_info h223 info structure for this h223 call
* pdu_no index of this pdu within the call
*/
static void dissect_mux_pdu( tvbuff_t *tvb, packet_info * pinfo,
guint32 pkt_offset,
proto_tree *h223_tree,
h223_call_info *call_info)
{
guint32 offset = 0;
/* actual (as opposed to reported) payload len */
guint32 len;
guint32 raw_hdr = 0, correct_hdr = 0;
gint32 errors = 0;
guint16 closing_flag = 0;
guint8 mc = 0;
guint8 mpl = 0;
gboolean end_of_mux_sdu = FALSE;
tvbuff_t *pdu_tvb;
proto_item *pdu_item = NULL;
proto_tree *pdu_tree = NULL;
switch(call_info->h223_level) {
case 0: case 1:
raw_hdr = tvb_get_guint8(tvb,0);
mc = (guint8)((raw_hdr>>1) & 0xf);
end_of_mux_sdu = raw_hdr & 1;
offset++;
/* closing flag is one byte long for h223 level 0, two for level 1 */
len = mpl = tvb_length_remaining(tvb, offset)-(call_info->h223_level+1);
/* XXX should ignore pdus with incorrect HECs */
break;
case 2:
raw_hdr = tvb_get_letoh24(tvb,0);
errors = golay_errors(raw_hdr);
correct_hdr = ((errors == -1) ? raw_hdr : raw_hdr ^ (guint32)errors);
mc = (guint8)(correct_hdr & 0xf);
mpl = (guint8)((correct_hdr >> 4) & 0xff);
offset += 3;
len = tvb_length_remaining(tvb,offset)-2;
closing_flag = tvb_get_ntohs(tvb,offset+len);
end_of_mux_sdu = (closing_flag==(0xE14D ^ 0xFFFF));
break;
case 3:
/* XXX not implemented */
default:
len=0;
DISSECTOR_ASSERT_NOT_REACHED();
}
if( h223_tree ) {
if( mpl == 0 ) {
pdu_item = proto_tree_add_item (h223_tree, hf_h223_mux_stuffing_pdu, tvb, 0, -1, FALSE);
pdu_tree = proto_item_add_subtree (pdu_item, ett_h223_mux_stuffing_pdu);
} else {
pdu_item = proto_tree_add_item (h223_tree, hf_h223_mux_pdu, tvb, 0, -1, FALSE);
pdu_tree = proto_item_add_subtree (pdu_item, ett_h223_mux_pdu);
}
}
if( pdu_tree ) {
proto_item *item = proto_tree_add_item (pdu_tree, hf_h223_mux_header, tvb, 0, offset, FALSE);
proto_tree *hdr_tree = proto_item_add_subtree (item, ett_h223_mux_header);
switch(call_info->h223_level) {
case 0: case 1:
proto_tree_add_uint(hdr_tree,hf_h223_mux_mc,tvb,0,1,mc);
break;
case 2:
if( errors == -1 ) {
proto_tree_add_uint_format(hdr_tree, hf_h223_mux_rawhdr, tvb,
0, 3, raw_hdr,
"Raw value: 0x%06x (uncorrectable errors)", raw_hdr );
} else if( errors == 0 ) {
proto_tree_add_uint_format(hdr_tree, hf_h223_mux_rawhdr, tvb,
0, 3, raw_hdr,
"Raw value: 0x%06x (correct)", raw_hdr );
} else {
proto_tree_add_uint_format(hdr_tree, hf_h223_mux_rawhdr, tvb,
0, 3, raw_hdr,
"Raw value: 0x%06x (errors are 0x%06x)", raw_hdr, errors );
}
item = proto_tree_add_uint(hdr_tree,hf_h223_mux_correctedhdr,tvb,0,3,
correct_hdr);
PROTO_ITEM_SET_GENERATED(item);
proto_tree_add_uint(hdr_tree,hf_h223_mux_mc,tvb,0,1,mc);
proto_tree_add_uint(hdr_tree,hf_h223_mux_mpl,tvb,0,2,mpl);
break;
case 3:
/* XXX not implemented */
default:
DISSECTOR_ASSERT_NOT_REACHED();
}
}
pdu_tvb = tvb_new_subset(tvb, offset, len, mpl);
dissect_mux_payload(pdu_tvb,pinfo,offset+pkt_offset,pdu_tree,call_info,mc,end_of_mux_sdu);
offset += mpl;
/* any extra data in the PDU, beyond that indictated by the mpl, is
dissected as data. */
len -= mpl;
if( len > 0 ) {
tvbuff_t *next_tvb = tvb_new_subset(tvb, offset, len, len);
proto_tree *vc_tree = NULL;
if( pdu_tree ) {
proto_item *vc_item = proto_tree_add_item(pdu_tree, hf_h223_mux_extra, next_tvb, 0, len, FALSE);
vc_tree = proto_item_add_subtree(vc_item, ett_h223_mux_deact);
}
call_dissector(data_handle,next_tvb,pinfo,vc_tree);
offset += len;
}
/* add the closing HDLC flag */
if( pdu_tree )
proto_tree_add_item(pdu_tree,hf_h223_mux_hdlc2,tvb,offset,2,FALSE);
}
/************************************************************************************
*
* MUX-PDU delineation and defragmentation
*/
/* attempt to parse the header of a mux pdu */
static void attempt_mux_level0_header_parse(h223_call_direction_data *dirdata)
{
/* level 0 isn't byte-aligned, so is a complete pain to implement */
DISSECTOR_ASSERT_NOT_REACHED();
dirdata = dirdata;
}
static void attempt_mux_level1_header_parse(h223_call_direction_data *dirdata)
{
guint32 hdr;
if(dirdata->current_pdu_read != 2)
return;
hdr = dirdata->header_buf & 0xffff;
/* don't interpret a repeated hdlc as a header */
if(hdr == 0xE14D)
return;
/* + 1 byte of header and 2 bytes of closing HDLC */
dirdata -> current_pdu_minlen = (guint8)((hdr >> 12) & 0xff) + 3;
dirdata -> current_pdu_header_parsed = TRUE;
}
static void attempt_mux_level2_3_header_parse(h223_call_direction_data *dirdata)
{
guint32 hdr;
gint32 errors;
if(dirdata->current_pdu_read != 3)
return;
/* + 3 bytes of header and 2 bytes of closing HDLC */
dirdata -> current_pdu_minlen = 5;
hdr = dirdata->header_buf;
hdr =
((hdr & 0xFF0000) >> 16) |
(hdr & 0x00FF00) |
((hdr & 0x0000FF) << 16);
errors = golay_errors(hdr);
if(errors != -1) {
hdr ^= errors;
dirdata -> current_pdu_minlen += ((hdr >> 4) & 0xff);
}
dirdata -> current_pdu_header_parsed = TRUE;
}
static void (* const attempt_mux_header_parse[])(h223_call_direction_data *dirdata) = {
attempt_mux_level0_header_parse,
attempt_mux_level1_header_parse,
attempt_mux_level2_3_header_parse,
attempt_mux_level2_3_header_parse
};
static gboolean h223_mux_check_hdlc(int h223_level, h223_call_direction_data *dirdata)
{
guint32 masked;
switch(h223_level) {
case 0:
/* level 0 isn't byte-aligned, so is a complete pain to implement */
DISSECTOR_ASSERT_NOT_REACHED();
return FALSE;
break;
case 1:
masked = dirdata->tail_buf & 0xffff;
return masked == 0xE14D;
case 2: case 3:
masked = dirdata->tail_buf & 0xffff;
return masked == 0xE14D || masked == (0xE14D ^ 0xFFFF);
default:
DISSECTOR_ASSERT_NOT_REACHED();
return FALSE;
}
}
/* read a pdu (or the end of a pdu) from the tvb, and dissect it
*
* returns an offset to the next byte
*
* *pdu_found is set TRUE if a pdu was found, or FALSE if we reached the
* end of the tvb without completing one.
*/
static guint32 dissect_mux_pdu_fragment( tvbuff_t *tvb, guint32 start_offset, packet_info * pinfo,
guint32* pkt_offset,
proto_tree *tree,
proto_tree **h223_tree_p,
h223_call_info *call_info,
gboolean *pdu_found)
{
proto_item *h223_item = NULL;
proto_tree *volatile h223_tree = *h223_tree_p;
tvbuff_t *volatile next_tvb;
volatile guint32 offset = start_offset;
gboolean more_frags = TRUE;
proto_tree *pdu_tree;
h223_call_direction_data *dirdata = &call_info -> direction_data[pinfo->p2p_dir ? 0 : 1];
dirdata -> current_pdu_read = 0;
dirdata -> current_pdu_minlen = 0;
dirdata -> current_pdu_header_parsed = FALSE;
while( more_frags && offset < tvb_reported_length( tvb )) {
guint8 byte = tvb_get_guint8(tvb, offset++);
dirdata -> current_pdu_read++;
/* read a byte into the header buf, if necessary */
if(dirdata -> current_pdu_read <= 4) {
dirdata -> header_buf <<= 8;
dirdata -> header_buf |= byte;
}
/* read the byte into the tail buf */
dirdata -> tail_buf <<= 8;
dirdata -> tail_buf |= byte;
/* if we haven't parsed the header yet, attempt to do so now */
if(!dirdata -> current_pdu_header_parsed)
/* this sets current_pdu_header parsed if current_pdu_read == 3 */
(attempt_mux_header_parse[call_info->h223_level])(dirdata);
if(dirdata -> current_pdu_read >= dirdata -> current_pdu_minlen) {
if(h223_mux_check_hdlc(call_info->h223_level,dirdata)) {
dirdata -> current_pdu_minlen = 0;
dirdata -> current_pdu_read = 0;
dirdata -> current_pdu_header_parsed = FALSE;
more_frags = FALSE;
}
}
}
if( more_frags ) {
/* offset = tvb_reported length now */
pinfo->desegment_offset = offset - dirdata->current_pdu_read;
if(dirdata->current_pdu_read > dirdata->current_pdu_minlen)
pinfo->desegment_len = 1;
else
pinfo->desegment_len = dirdata->current_pdu_minlen - dirdata->current_pdu_read;
return offset;
}
if(!*h223_tree_p) {
/* add the 'h223' tree to the main tree */
if (tree) {
h223_item = proto_tree_add_item (tree, proto_h223, tvb, 0, -1, FALSE);
h223_tree = proto_item_add_subtree (h223_item, ett_h223);
*h223_tree_p = h223_tree;
}
}
*pdu_found = TRUE;
/* create a tvb for the fragment */
next_tvb = tvb_new_subset(tvb, start_offset, offset-start_offset,
offset-start_offset);
*pkt_offset += tvb_reported_length( next_tvb );
/* the first PDU isn't real H.223 data. */
if( dirdata->first_pdu ) {
dirdata->first_pdu = FALSE;
pdu_tree = NULL;
if( h223_tree ) {
proto_item *pdu_item = proto_tree_add_item (h223_tree, hf_h223_non_h223_data, tvb, 0, -1, FALSE);
pdu_tree = proto_item_add_subtree (pdu_item, ett_h223_non_h223_data);
}
call_dissector(data_handle,tvb, pinfo, pdu_tree);
return offset;
}
/* we catch boundserrors on the pdu so that errors on an
* individual pdu don't screw up the whole of the rest of the
* stream */
pdu_offset = *pkt_offset - tvb_reported_length( next_tvb );
TRY {
dissect_mux_pdu( next_tvb, pinfo, *pkt_offset - tvb_reported_length( next_tvb ), h223_tree, call_info);
}
CATCH2(BoundsError,ReportedBoundsError) {
if (check_col(pinfo->cinfo, COL_INFO))
col_append_str(pinfo->cinfo, COL_INFO,
"[Malformed Packet]");
proto_tree_add_protocol_format(h223_tree, proto_malformed,
tvb, 0, 0, "[Malformed Packet: %s]", pinfo->current_proto);
}
ENDTRY;
return offset;
}
/************************************************************************************
*
* main dissector entry point
*/
static void dissect_h223 (tvbuff_t * tvb, packet_info * pinfo, proto_tree * tree)
{
proto_tree *h223_tree = NULL;
h223_call_info *call_info = NULL;
guint32 offset = 0;
/* pkt_offset becomes different from offset if we reassemble a pdu:
*
* before: offset = a, pkt_offset = b
* offset = dissect_h223_mux_pdu_fragment(ending fragment, offset, &pkt_offset)
* after: offset = a + sizeof(ending frament), pkt_offset = b + sizeof(reassembled pdu)
*
* This lets us get a value "pkt_offset + offset_into_pdu" which will never decrease
* as we walk through a packet
*/
guint32 pkt_offset = 0;
gboolean pdu_found = FALSE;
if (check_col (pinfo->cinfo, COL_INFO))
col_clear (pinfo->cinfo, COL_INFO);
/* find or create the call_info for this call */
call_info = find_or_create_call_info(pinfo);
/* we may need to reverse the bit ordering before we go any further. */
if( call_info -> bitswapped ) {
tvbuff_t *reversed_tvb;
guint8 *data;
guint len;
guint i;
len = tvb_length(tvb);
data = g_malloc(len);
for( i=0; i<len; i++)
data[i]=BIT_SWAP(tvb_get_guint8(tvb,i));
reversed_tvb = tvb_new_real_data(data,len,tvb_reported_length(tvb));
/*
* Add the reversed tvbuff to the list of tvbuffs to which
* the tvbuff we were handed refers, so it'll get
* cleaned up when that tvbuff is cleaned up.
*/
tvb_set_child_real_data_tvbuff(tvb, reversed_tvb);
/* Add a freer */
tvb_set_free_cb(reversed_tvb, g_free);
/* Add the reversed data to the data source list. */
add_new_data_source(pinfo, reversed_tvb, "Bit-swapped H.223 frame" );
tvb = reversed_tvb;
}
while( offset < tvb_reported_length( tvb )) {
gboolean pdu_found_this_fragment = FALSE;
offset = dissect_mux_pdu_fragment( tvb, offset, pinfo, &pkt_offset, tree,
&h223_tree, call_info,
&pdu_found_this_fragment );
if( pdu_found_this_fragment )
pdu_found = TRUE;
}
if( !pdu_found && check_col (pinfo->cinfo, COL_INFO))
col_set_str (pinfo->cinfo, COL_INFO, "(No complete PDUs)");
/* set up the protocol and info fields in the summary pane */
if (check_col (pinfo->cinfo, COL_PROTOCOL))
col_set_str (pinfo->cinfo, COL_PROTOCOL, PROTO_TAG_H223);
}
static void h223_init_protocol (void)
{
circuit_chain_init();
}
void proto_register_h223 (void)
{
/* A header field is something you can search/filter on.
*
* We create a structure to register our fields. It consists of an
* array of hf_register_info structures, each of which are of the format
* {&(field id), {name, abbrev, type, display, strings, bitmask, blurb, HFILL}}.
*/
static hf_register_info hf[] = {
{ &hf_h223_non_h223_data,
{ "Non-H.223 data", "h223.non-h223", FT_NONE, BASE_NONE, NULL, 0x0,
"Initial data in stream, not a PDU", HFILL }},
{ &hf_h223_mux_stuffing_pdu,
{ "H.223 stuffing PDU", "h223.mux.stuffing", FT_NONE, BASE_NONE, NULL, 0x0,
"Empty PDU used for stuffing when no data available", HFILL }},
{ &hf_h223_mux_pdu,
{ "H.223 MUX-PDU", "h223.mux", FT_NONE, BASE_NONE, NULL, 0x0,
"H.223 MUX-PDU", HFILL }},
{ &hf_h223_mux_header,
{ "Header", "h223.mux.header", FT_NONE, BASE_NONE, NULL, 0x0,
"H.223 MUX header", HFILL }},
{ &hf_h223_mux_rawhdr,
{ "Raw value", "h223.mux.rawhdr", FT_UINT24, BASE_HEX, NULL, 0x0,
"Raw header bytes", HFILL }},
{ &hf_h223_mux_correctedhdr,
{ "Corrected value", "h223.mux.correctedhdr", FT_UINT24, BASE_HEX, NULL, 0x0,
"Corrected header bytes", HFILL }},
{ &hf_h223_mux_mc,
{ "Multiplex Code", "h223.mux.mc", FT_UINT8, BASE_DEC, NULL, 0x0,
"H.223 MUX multiplex code", HFILL }},
{ &hf_h223_mux_mpl,
{ "Multiplex Payload Length", "h223.mux.mpl", FT_UINT8, BASE_DEC, NULL, 0x0,
"H.223 MUX multiplex Payload Length", HFILL }},
{ &hf_h223_mux_deact,
{ "Deactivated multiplex table entry", "h223.mux.deactivated", FT_NONE, BASE_NONE, NULL, 0x0,
"mpl refers to an entry in the multiplex table which is not active", HFILL }},
{ &hf_h223_mux_vc,
{ "H.223 virtual circuit", "h223.mux.vc", FT_UINT16, BASE_DEC, NULL, 0x0,
"H.223 Virtual Circuit", HFILL }},
{ &hf_h223_mux_extra,
{ "Extraneous data", "h223.mux.extra", FT_NONE, BASE_DEC, NULL, 0x0,
"data beyond mpl", HFILL }},
{ &hf_h223_mux_hdlc2,
{ "HDLC flag", "h223.mux.hdlc", FT_UINT16, BASE_HEX, NULL, 0x0,
"framing flag", HFILL }},
/* fields for h.223-mux fragments */
{ &hf_h223_mux_fragment_overlap,
{ "Fragment overlap", "h223.mux.fragment.overlap", FT_BOOLEAN, BASE_NONE, NULL, 0x0,
"Fragment overlaps with other fragments", HFILL }},
{ &hf_h223_mux_fragment_overlap_conflict,
{ "Conflicting data in fragment overlap", "h223.mux.fragment.overlap.conflict", FT_BOOLEAN, BASE_NONE, NULL, 0x0,
"Overlapping fragments contained conflicting data", HFILL }},
{ &hf_h223_mux_fragment_multiple_tails,
{ "Multiple tail fragments found", "h223.mux.fragment.multipletails", FT_BOOLEAN, BASE_NONE, NULL, 0x0,
"Several tails were found when defragmenting the packet", HFILL }},
{ &hf_h223_mux_fragment_too_long_fragment,
{ "Fragment too long", "h223.mux.fragment.toolongfragment", FT_BOOLEAN, BASE_NONE, NULL, 0x0,
"Fragment contained data past end of packet", HFILL }},
{ &hf_h223_mux_fragment_error,
{ "Defragmentation error", "h223.mux.fragment.error", FT_FRAMENUM, BASE_NONE, NULL, 0x0,
"Defragmentation error due to illegal fragments", HFILL }},
{ &hf_h223_mux_fragment,
{ "H.223 MUX-PDU Fragment", "h223.mux.fragment", FT_FRAMENUM, BASE_NONE, NULL, 0x0,
"H.223 MUX-PDU Fragment", HFILL }},
{ &hf_h223_mux_fragments,
{ "H.223 MUX-PDU Fragments", "h223.mux.fragments", FT_NONE, BASE_NONE, NULL, 0x0,
"H.223 MUX-PDU Fragments", HFILL }},
{ &hf_h223_mux_reassembled_in,
{ "MUX-PDU fragment, reassembled in frame", "h223.mux.reassembled_in", FT_FRAMENUM, BASE_NONE, NULL, 0x0,
"This H.223 MUX-PDU packet is reassembled in this frame", HFILL }},
/* fields for h.223-al fragments */
{ &hf_h223_al_fragment_overlap,
{ "Fragment overlap", "h223.al.fragment.overlap", FT_BOOLEAN, BASE_NONE, NULL, 0x0,
"Fragment overlaps with other fragments", HFILL }},
{ &hf_h223_al_fragment_overlap_conflict,
{ "Conflicting data in fragment overlap", "h223.al.fragment.overlap.conflict", FT_BOOLEAN, BASE_NONE, NULL, 0x0,
"Overlapping fragments contained conflicting data", HFILL }},
{ &hf_h223_al_fragment_multiple_tails,
{ "Multiple tail fragments found", "h223.al.fragment.multipletails", FT_BOOLEAN, BASE_NONE, NULL, 0x0,
"Several tails were found when defragmenting the packet", HFILL }},
{ &hf_h223_al_fragment_too_long_fragment,
{ "Fragment too long", "h223.al.fragment.toolongfragment", FT_BOOLEAN, BASE_NONE, NULL, 0x0,
"Fragment contained data past end of packet", HFILL }},
{ &hf_h223_al_fragment_error,
{ "Defragmentation error", "h223.al.fragment.error", FT_FRAMENUM, BASE_NONE, NULL, 0x0,
"Defragmentation error due to illegal fragments", HFILL }},
{ &hf_h223_al_fragment,
{ "H.223 AL-PDU Fragment", "h223.al.fragment", FT_FRAMENUM, BASE_NONE, NULL, 0x0,
"H.223 AL-PDU Fragment", HFILL }},
{ &hf_h223_al_fragments,
{ "H.223 AL-PDU Fragments", "h223.al.fragments", FT_NONE, BASE_NONE, NULL, 0x0,
"H.223 AL-PDU Fragments", HFILL }},
{ &hf_h223_al_reassembled_in,
{ "AL-PDU fragment, reassembled in frame", "h223.al.reassembled_in", FT_FRAMENUM, BASE_NONE, NULL, 0x0,
"This H.223 AL-PDU packet is reassembled in this frame", HFILL }},
/* h223-als */
{ &hf_h223_al1,
{ "H.223 AL1", "h223.al1", FT_NONE, BASE_NONE, NULL, 0x0,
"H.223 AL-PDU using AL1", HFILL }},
{ &hf_h223_al1_framed,
{ "H.223 AL1 framing", "h223.al1.framed", FT_BOOLEAN, BASE_NONE, NULL, 0x0,
"", HFILL }},
{ &hf_h223_al2,
{ "H.223 AL2", "h223.al2", FT_NONE, BASE_NONE, NULL, 0x0,
"H.223 AL-PDU using AL2", HFILL }},
{ &hf_h223_al2_sequenced,
{ "H.223 AL2 sequenced", "h223.al2.sequenced", FT_BOOLEAN, BASE_NONE, NULL, 0x0,
"", HFILL }},
{ &hf_h223_al2_seqno,
{ "Sequence Number", "h223.al2.seqno", FT_UINT8, BASE_DEC, NULL, 0x0,
"H.223 AL2 sequence number", HFILL }},
{ &hf_h223_al2_crc,
{ "CRC", "h223.al2.crc", FT_UINT8, BASE_HEX, NULL, 0x0,
"CRC", HFILL }},
{ &hf_h223_al2_crc_bad,
{ "Bad CRC","h223.al2.crc_bad", FT_BOOLEAN, BASE_NONE, NULL, 0x0,
"", HFILL }},
{ &hf_h223_al_payload,
{ "H.223 AL Payload", "h223.al.payload", FT_NONE, BASE_NONE, NULL, 0x0,
"H.223 AL-PDU Payload", HFILL }},
};
static gint *ett[] = {
&ett_h223,
&ett_h223_non_h223_data,
&ett_h223_mux_stuffing_pdu,
&ett_h223_mux_pdu,
&ett_h223_mux_header,
&ett_h223_mux_deact,
&ett_h223_mux_vc,
&ett_h223_mux_extra,
&ett_h223_mux_fragments,
&ett_h223_mux_fragment,
&ett_h223_al_fragments,
&ett_h223_al_fragment,
&ett_h223_al1,
&ett_h223_al2,
&ett_h223_al_payload
};
if (proto_h223 == -1) { /* execute protocol initialization only once */
proto_h223 =
proto_register_protocol ("ITU-T Recommendation H.223", "H.223", "h223");
proto_register_field_array (proto_h223, hf, array_length (hf));
proto_register_subtree_array (ett, array_length (ett));
register_dissector("h223", dissect_h223, proto_h223);
/* register our init routine to be called at the start of a capture,
to clear out our hash tables etc */
register_init_routine(&h223_init_protocol);
}
h245_set_h223_set_mc_handle( &h223_set_mc );
h245_set_h223_add_lc_handle( &h223_add_lc );
}
void proto_reg_handoff_h223(void)
{
dissector_handle_t h223 = find_dissector("h223");
data_handle = find_dissector("data");
h245dg_handle = find_dissector("h245dg");
srp_handle = find_dissector("srp");
dissector_add_handle("tcp.port", h223);
dissector_add("iax2.dataformat", AST_DATAFORMAT_H223_H245, h223);
}
/* vim:set ts=8 et: */
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