Move dissectors to epan/dissectors directory.

Also move ncp222.py, x11-fields, process-x11-fields.pl,
make-reg-dotc, and make-reg-dotc.py.

Adjust #include lines in files that include packet-*.h
files.


git-svn-id: http://anonsvn.wireshark.org/wireshark/trunk@11410 f5534014-38df-0310-8fa8-9805f1628bb7

1 files changed, 3597 insertions, 0 deletions

diff --git a/epan/dissectors/packet-sna.c b/epan/dissectors/packet-sna.c
new file mode 100644
index 0000000000..be53b18c43
--- /dev/null
+++ b/epan/dissectors/packet-sna.c
@@ -0,0 +1,3597 @@
+/* packet-sna.c
+ * Routines for SNA
+ * Gilbert Ramirez <gram@alumni.rice.edu>
+ * Jochen Friedrich <jochen@scram.de>
+ *
+ * $Id$
+ *
+ * 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 <glib.h>
+#include <epan/packet.h>
+#include "llcsaps.h"
+#include "ppptypes.h"
+#include <epan/sna-utils.h>
+#include "prefs.h"
+#include "reassemble.h"
+#include "util.h"
+
+/*
+ * http://www.wanresources.com/snacell.html
+ * ftp://ftp.software.ibm.com/networking/pub/standards/aiw/formats/
+ *
+ */
+
+static int proto_sna = -1;
+static int proto_sna_xid = -1;
+static int hf_sna_th = -1;
+static int hf_sna_th_0 = -1;
+static int hf_sna_th_fid = -1;
+static int hf_sna_th_mpf = -1;
+static int hf_sna_th_odai = -1;
+static int hf_sna_th_efi = -1;
+static int hf_sna_th_daf = -1;
+static int hf_sna_th_oaf = -1;
+static int hf_sna_th_snf = -1;
+static int hf_sna_th_dcf = -1;
+static int hf_sna_th_lsid = -1;
+static int hf_sna_th_tg_sweep = -1;
+static int hf_sna_th_er_vr_supp_ind = -1;
+static int hf_sna_th_vr_pac_cnt_ind = -1;
+static int hf_sna_th_ntwk_prty = -1;
+static int hf_sna_th_tgsf = -1;
+static int hf_sna_th_mft = -1;
+static int hf_sna_th_piubf = -1;
+static int hf_sna_th_iern = -1;
+static int hf_sna_th_nlpoi = -1;
+static int hf_sna_th_nlp_cp = -1;
+static int hf_sna_th_ern = -1;
+static int hf_sna_th_vrn = -1;
+static int hf_sna_th_tpf = -1;
+static int hf_sna_th_vr_cwi = -1;
+static int hf_sna_th_tg_nonfifo_ind = -1;
+static int hf_sna_th_vr_sqti = -1;
+static int hf_sna_th_tg_snf = -1;
+static int hf_sna_th_vrprq = -1;
+static int hf_sna_th_vrprs = -1;
+static int hf_sna_th_vr_cwri = -1;
+static int hf_sna_th_vr_rwi = -1;
+static int hf_sna_th_vr_snf_send = -1;
+static int hf_sna_th_dsaf = -1;
+static int hf_sna_th_osaf = -1;
+static int hf_sna_th_snai = -1;
+static int hf_sna_th_def = -1;
+static int hf_sna_th_oef = -1;
+static int hf_sna_th_sa = -1;
+static int hf_sna_th_cmd_fmt = -1;
+static int hf_sna_th_cmd_type = -1;
+static int hf_sna_th_cmd_sn = -1;
+
+static int hf_sna_nlp_nhdr = -1;
+static int hf_sna_nlp_nhdr_0 = -1;
+static int hf_sna_nlp_sm = -1;
+static int hf_sna_nlp_tpf = -1;
+static int hf_sna_nlp_nhdr_1 = -1;
+static int hf_sna_nlp_ft = -1;
+static int hf_sna_nlp_tspi = -1;
+static int hf_sna_nlp_slowdn1 = -1;
+static int hf_sna_nlp_slowdn2 = -1;
+static int hf_sna_nlp_fra = -1;
+static int hf_sna_nlp_anr = -1;
+static int hf_sna_nlp_frh = -1;
+static int hf_sna_nlp_thdr = -1;
+static int hf_sna_nlp_tcid = -1;
+static int hf_sna_nlp_thdr_8 = -1;
+static int hf_sna_nlp_setupi = -1;
+static int hf_sna_nlp_somi = -1;
+static int hf_sna_nlp_eomi = -1;
+static int hf_sna_nlp_sri = -1;
+static int hf_sna_nlp_rasapi = -1;
+static int hf_sna_nlp_retryi = -1;
+static int hf_sna_nlp_thdr_9 = -1;
+static int hf_sna_nlp_lmi = -1;
+static int hf_sna_nlp_cqfi = -1;
+static int hf_sna_nlp_osi = -1;
+static int hf_sna_nlp_offset = -1;
+static int hf_sna_nlp_dlf = -1;
+static int hf_sna_nlp_bsn = -1;
+static int hf_sna_nlp_opti_len = -1;
+static int hf_sna_nlp_opti_type = -1;
+static int hf_sna_nlp_opti_0d_version = -1;
+static int hf_sna_nlp_opti_0d_4 = -1;
+static int hf_sna_nlp_opti_0d_target = -1;
+static int hf_sna_nlp_opti_0d_arb = -1;
+static int hf_sna_nlp_opti_0d_reliable = -1;
+static int hf_sna_nlp_opti_0d_dedicated = -1;
+static int hf_sna_nlp_opti_0e_stat = -1;
+static int hf_sna_nlp_opti_0e_gap = -1;
+static int hf_sna_nlp_opti_0e_idle = -1;
+static int hf_sna_nlp_opti_0e_nabsp = -1;
+static int hf_sna_nlp_opti_0e_sync = -1;
+static int hf_sna_nlp_opti_0e_echo = -1;
+static int hf_sna_nlp_opti_0e_rseq = -1;
+static int hf_sna_nlp_opti_0e_abspbeg = -1;
+static int hf_sna_nlp_opti_0e_abspend = -1;
+static int hf_sna_nlp_opti_0f_bits = -1;
+static int hf_sna_nlp_opti_10_tcid = -1;
+static int hf_sna_nlp_opti_12_sense = -1;
+static int hf_sna_nlp_opti_14_si_len = -1;
+static int hf_sna_nlp_opti_14_si_key = -1;
+static int hf_sna_nlp_opti_14_si_2 = -1;
+static int hf_sna_nlp_opti_14_si_refifo = -1;
+static int hf_sna_nlp_opti_14_si_mobility = -1;
+static int hf_sna_nlp_opti_14_si_dirsearch = -1;
+static int hf_sna_nlp_opti_14_si_limitres = -1;
+static int hf_sna_nlp_opti_14_si_ncescope = -1;
+static int hf_sna_nlp_opti_14_si_mnpsrscv = -1;
+static int hf_sna_nlp_opti_14_si_maxpsize = -1;
+static int hf_sna_nlp_opti_14_si_switch = -1;
+static int hf_sna_nlp_opti_14_si_alive = -1;
+static int hf_sna_nlp_opti_14_rr_len = -1;
+static int hf_sna_nlp_opti_14_rr_key = -1;
+static int hf_sna_nlp_opti_14_rr_2 = -1;
+static int hf_sna_nlp_opti_14_rr_bfe = -1;
+static int hf_sna_nlp_opti_14_rr_num = -1;
+static int hf_sna_nlp_opti_22_2 = -1;
+static int hf_sna_nlp_opti_22_type = -1;
+static int hf_sna_nlp_opti_22_raa = -1;
+static int hf_sna_nlp_opti_22_parity = -1;
+static int hf_sna_nlp_opti_22_arb = -1;
+static int hf_sna_nlp_opti_22_3 = -1;
+static int hf_sna_nlp_opti_22_ratereq = -1;
+static int hf_sna_nlp_opti_22_raterep = -1;
+static int hf_sna_nlp_opti_22_field1 = -1;
+static int hf_sna_nlp_opti_22_field2 = -1;
+static int hf_sna_nlp_opti_22_field3 = -1;
+static int hf_sna_nlp_opti_22_field4 = -1;
+
+static int hf_sna_rh = -1;
+static int hf_sna_rh_0 = -1;
+static int hf_sna_rh_1 = -1;
+static int hf_sna_rh_2 = -1;
+static int hf_sna_rh_rri = -1;
+static int hf_sna_rh_ru_category = -1;
+static int hf_sna_rh_fi = -1;
+static int hf_sna_rh_sdi = -1;
+static int hf_sna_rh_bci = -1;
+static int hf_sna_rh_eci = -1;
+static int hf_sna_rh_dr1 = -1;
+static int hf_sna_rh_lcci = -1;
+static int hf_sna_rh_dr2 = -1;
+static int hf_sna_rh_eri = -1;
+static int hf_sna_rh_rti = -1;
+static int hf_sna_rh_rlwi = -1;
+static int hf_sna_rh_qri = -1;
+static int hf_sna_rh_pi = -1;
+static int hf_sna_rh_bbi = -1;
+static int hf_sna_rh_ebi = -1;
+static int hf_sna_rh_cdi = -1;
+static int hf_sna_rh_csi = -1;
+static int hf_sna_rh_edi = -1;
+static int hf_sna_rh_pdi = -1;
+static int hf_sna_rh_cebi = -1;
+/*static int hf_sna_ru = -1;*/
+
+static int hf_sna_gds = -1;
+static int hf_sna_gds_len = -1;
+static int hf_sna_gds_type = -1;
+static int hf_sna_gds_cont = -1;
+
+static int hf_sna_xid = -1;
+static int hf_sna_xid_0 = -1;
+static int hf_sna_xid_id = -1;
+static int hf_sna_xid_format = -1;
+static int hf_sna_xid_type = -1;
+static int hf_sna_xid_len = -1;
+static int hf_sna_xid_idblock = -1;
+static int hf_sna_xid_idnum = -1;
+static int hf_sna_xid_3_8 = -1;
+static int hf_sna_xid_3_init_self = -1;
+static int hf_sna_xid_3_stand_bind = -1;
+static int hf_sna_xid_3_gener_bind = -1;
+static int hf_sna_xid_3_recve_bind = -1;
+static int hf_sna_xid_3_actpu = -1;
+static int hf_sna_xid_3_nwnode = -1;
+static int hf_sna_xid_3_cp = -1;
+static int hf_sna_xid_3_cpcp = -1;
+static int hf_sna_xid_3_state = -1;
+static int hf_sna_xid_3_nonact = -1;
+static int hf_sna_xid_3_cpchange = -1;
+static int hf_sna_xid_3_10 = -1;
+static int hf_sna_xid_3_asend_bind = -1;
+static int hf_sna_xid_3_arecv_bind = -1;
+static int hf_sna_xid_3_quiesce = -1;
+static int hf_sna_xid_3_pucap = -1;
+static int hf_sna_xid_3_pbn = -1;
+static int hf_sna_xid_3_pacing = -1;
+static int hf_sna_xid_3_11 = -1;
+static int hf_sna_xid_3_tgshare = -1;
+static int hf_sna_xid_3_dedsvc = -1;
+static int hf_sna_xid_3_12 = -1;
+static int hf_sna_xid_3_negcsup = -1;
+static int hf_sna_xid_3_negcomp = -1;
+static int hf_sna_xid_3_15 = -1;
+static int hf_sna_xid_3_partg = -1;
+static int hf_sna_xid_3_dlur = -1;
+static int hf_sna_xid_3_dlus = -1;
+static int hf_sna_xid_3_exbn = -1;
+static int hf_sna_xid_3_genodai = -1;
+static int hf_sna_xid_3_branch = -1;
+static int hf_sna_xid_3_brnn = -1;
+static int hf_sna_xid_3_tg = -1;
+static int hf_sna_xid_3_dlc = -1;
+static int hf_sna_xid_3_dlen = -1;
+
+static int hf_sna_control_len = -1;
+static int hf_sna_control_key = -1;
+static int hf_sna_control_hprkey = -1;
+static int hf_sna_control_05_delay = -1;
+static int hf_sna_control_05_type = -1;
+static int hf_sna_control_05_ptp = -1;
+static int hf_sna_control_0e_type = -1;
+static int hf_sna_control_0e_value = -1;
+
+static gint ett_sna = -1;
+static gint ett_sna_th = -1;
+static gint ett_sna_th_fid = -1;
+static gint ett_sna_nlp_nhdr = -1;
+static gint ett_sna_nlp_nhdr_0 = -1;
+static gint ett_sna_nlp_nhdr_1 = -1;
+static gint ett_sna_nlp_thdr = -1;
+static gint ett_sna_nlp_thdr_8 = -1;
+static gint ett_sna_nlp_thdr_9 = -1;
+static gint ett_sna_nlp_opti_un = -1;
+static gint ett_sna_nlp_opti_0d = -1;
+static gint ett_sna_nlp_opti_0d_4 = -1;
+static gint ett_sna_nlp_opti_0e = -1;
+static gint ett_sna_nlp_opti_0e_stat = -1;
+static gint ett_sna_nlp_opti_0e_absp = -1;
+static gint ett_sna_nlp_opti_0f = -1;
+static gint ett_sna_nlp_opti_10 = -1;
+static gint ett_sna_nlp_opti_12 = -1;
+static gint ett_sna_nlp_opti_14 = -1;
+static gint ett_sna_nlp_opti_14_si = -1;
+static gint ett_sna_nlp_opti_14_si_2 = -1;
+static gint ett_sna_nlp_opti_14_rr = -1;
+static gint ett_sna_nlp_opti_14_rr_2 = -1;
+static gint ett_sna_nlp_opti_22 = -1;
+static gint ett_sna_nlp_opti_22_2 = -1;
+static gint ett_sna_nlp_opti_22_3 = -1;
+static gint ett_sna_rh = -1;
+static gint ett_sna_rh_0 = -1;
+static gint ett_sna_rh_1 = -1;
+static gint ett_sna_rh_2 = -1;
+static gint ett_sna_gds = -1;
+static gint ett_sna_xid_0 = -1;
+static gint ett_sna_xid_id = -1;
+static gint ett_sna_xid_3_8 = -1;
+static gint ett_sna_xid_3_10 = -1;
+static gint ett_sna_xid_3_11 = -1;
+static gint ett_sna_xid_3_12 = -1;
+static gint ett_sna_xid_3_15 = -1;
+static gint ett_sna_control_un = -1;
+static gint ett_sna_control_05 = -1;
+static gint ett_sna_control_05hpr = -1;
+static gint ett_sna_control_05hpr_type = -1;
+static gint ett_sna_control_0e = -1;
+
+static dissector_handle_t data_handle;
+
+/* Defragment fragmented SNA BIUs*/
+static gboolean sna_defragment = FALSE;
+static GHashTable *sna_fragment_table = NULL;
+static GHashTable *sna_reassembled_table = NULL;
+
+/* Format Identifier */
+static const value_string sna_th_fid_vals[] = {
+	{ 0x0,	"SNA device <--> Non-SNA Device" },
+	{ 0x1,	"Subarea Nodes, without ER or VR" },
+	{ 0x2,	"Subarea Node <--> PU2" },
+	{ 0x3,	"Subarea Node or SNA host <--> Subarea Node" },
+	{ 0x4,	"Subarea Nodes, supporting ER and VR" },
+	{ 0x5,	"HPR RTP endpoint nodes" },
+	{ 0xa,	"HPR NLP Frame Routing" },
+	{ 0xb,	"HPR NLP Frame Routing" },
+	{ 0xc,	"HPR NLP Automatic Network Routing" },
+	{ 0xd,	"HPR NLP Automatic Network Routing" },
+	{ 0xf,	"Adjaced Subarea Nodes, supporting ER and VR" },
+	{ 0x0,	NULL }
+};
+
+/* Mapping Field */
+#define MPF_MIDDLE_SEGMENT  0
+#define MPF_LAST_SEGMENT    1
+#define MPF_FIRST_SEGMENT   2
+#define MPF_WHOLE_BIU       3
+
+static const value_string sna_th_mpf_vals[] = {
+	{ MPF_MIDDLE_SEGMENT,   "Middle segment of a BIU" },
+	{ MPF_LAST_SEGMENT,     "Last segment of a BIU" },
+	{ MPF_FIRST_SEGMENT,    "First segment of a BIU" },
+	{ MPF_WHOLE_BIU,        "Whole BIU" },
+	{ 0,   NULL }
+};
+
+/* Expedited Flow Indicator */
+static const value_string sna_th_efi_vals[] = {
+	{ 0, "Normal Flow" },
+	{ 1, "Expedited Flow" },
+	{ 0x0,	NULL }
+};
+
+/* Request/Response Indicator */
+static const value_string sna_rh_rri_vals[] = {
+	{ 0, "Request" },
+	{ 1, "Response" },
+	{ 0x0,	NULL }
+};
+
+/* Request/Response Unit Category */
+static const value_string sna_rh_ru_category_vals[] = {
+	{ 0, "Function Management Data (FMD)" },
+	{ 1, "Network Control (NC)" },
+	{ 2, "Data Flow Control (DFC)" },
+	{ 3, "Session Control (SC)" },
+	{ 0x0,	NULL }
+};
+
+/* Format Indicator */
+static const true_false_string sna_rh_fi_truth =
+	{ "FM Header", "No FM Header" };
+
+/* Sense Data Included */
+static const true_false_string sna_rh_sdi_truth =
+	{ "Included", "Not Included" };
+
+/* Begin Chain Indicator */
+static const true_false_string sna_rh_bci_truth =
+	{ "First in Chain", "Not First in Chain" };
+
+/* End Chain Indicator */
+static const true_false_string sna_rh_eci_truth =
+	{ "Last in Chain", "Not Last in Chain" };
+
+/* Lengith-Checked Compression Indicator */
+static const true_false_string sna_rh_lcci_truth =
+	{ "Compressed", "Not Compressed" };
+
+/* Response Type Indicator */
+static const true_false_string sna_rh_rti_truth =
+	{ "Negative", "Positive" };
+
+/* Queued Response Indicator */
+static const true_false_string sna_rh_qri_truth =
+	{ "Enqueue response in TC queues", "Response bypasses TC queues" };
+
+/* Code Selection Indicator */
+static const value_string sna_rh_csi_vals[] = {
+	{ 0, "EBCDIC" },
+	{ 1, "ASCII" },
+	{ 0x0,	NULL }
+};
+
+/* TG Sweep */
+static const value_string sna_th_tg_sweep_vals[] = {
+	{ 0, "This PIU may overtake any PU ahead of it." },
+	{ 1, "This PIU does not ovetake any PIU ahead of it." },
+	{ 0x0,	NULL }
+};
+
+/* ER_VR_SUPP_IND */
+static const value_string sna_th_er_vr_supp_ind_vals[] = {
+	{ 0, "Each node supports ER and VR protocols" },
+	{ 1, "Includes at least one node that does not support ER and VR"
+	    " protocols"  },
+	{ 0x0,	NULL }
+};
+
+/* VR_PAC_CNT_IND */
+static const value_string sna_th_vr_pac_cnt_ind_vals[] = {
+	{ 0, "Pacing count on the VR has not reached 0" },
+	{ 1, "Pacing count on the VR has reached 0" },
+	{ 0x0,	NULL }
+};
+
+/* NTWK_PRTY */
+static const value_string sna_th_ntwk_prty_vals[] = {
+	{ 0, "PIU flows at a lower priority" },
+	{ 1, "PIU flows at network priority (highest transmission priority)" },
+	{ 0x0,	NULL }
+};
+
+/* TGSF */
+static const value_string sna_th_tgsf_vals[] = {
+	{ 0, "Not segmented" },
+	{ 1, "Last segment" },
+	{ 2, "First segment" },
+	{ 3, "Middle segment" },
+	{ 0x0,	NULL }
+};
+
+/* PIUBF */
+static const value_string sna_th_piubf_vals[] = {
+	{ 0, "Single PIU frame" },
+	{ 1, "Last PIU of a multiple PIU frame" },
+	{ 2, "First PIU of a multiple PIU frame" },
+	{ 3, "Middle PIU of a multiple PIU frame" },
+	{ 0x0,	NULL }
+};
+
+/* NLPOI */
+static const value_string sna_th_nlpoi_vals[] = {
+	{ 0, "NLP starts within this FID4 TH" },
+	{ 1, "NLP byte 0 starts after RH byte 0 following NLP C/P pad" },
+	{ 0x0,	NULL }
+};
+
+/* TPF */
+static const value_string sna_th_tpf_vals[] = {
+	{ 0, "Low Priority" },
+	{ 1, "Medium Priority" },
+	{ 2, "High Priority" },
+	{ 3, "Network Priority" },
+	{ 0x0,	NULL }
+};
+
+/* VR_CWI */
+static const value_string sna_th_vr_cwi_vals[] = {
+	{ 0, "Increment window size" },
+	{ 1, "Decrement window size" },
+	{ 0x0,	NULL }
+};
+
+/* TG_NONFIFO_IND */
+static const true_false_string sna_th_tg_nonfifo_ind_truth =
+	{ "TG FIFO is not required", "TG FIFO is required" };
+
+/* VR_SQTI */
+static const value_string sna_th_vr_sqti_vals[] = {
+	{ 0, "Non-sequenced, Non-supervisory" },
+	{ 1, "Non-sequenced, Supervisory" },
+	{ 2, "Singly-sequenced" },
+	{ 0x0,	NULL }
+};
+
+/* VRPRQ */
+static const true_false_string sna_th_vrprq_truth = {
+	"VR pacing request is sent asking for a VR pacing response",
+	"No VR pacing response is requested",
+};
+
+/* VRPRS */
+static const true_false_string sna_th_vrprs_truth = {
+	"VR pacing response is sent in response to a VRPRQ bit set",
+	"No pacing response sent",
+};
+
+/* VR_CWRI */
+static const value_string sna_th_vr_cwri_vals[] = {
+	{ 0, "Increment window size by 1" },
+	{ 1, "Decrement window size by 1" },
+	{ 0x0,	NULL }
+};
+
+/* VR_RWI */
+static const true_false_string sna_th_vr_rwi_truth = {
+	"Reset window size to the minimum specified in NC_ACTVR",
+	"Do not reset window size",
+};
+
+/* Switching Mode */
+static const value_string sna_nlp_sm_vals[] = {
+	{ 5, "Function routing" },
+	{ 6, "Automatic network routing" },
+	{ 0x0,	NULL }
+};
+
+static const true_false_string sna_nlp_tspi_truth =
+	{ "Time sensitive", "Not time sensitive" };
+
+static const true_false_string sna_nlp_slowdn1_truth =
+	{ "Minor congestion", "No minor congestion" };
+
+static const true_false_string sna_nlp_slowdn2_truth =
+	{ "Major congestion", "No major congestion" };
+
+/* Function Type */
+static const value_string sna_nlp_ft_vals[] = {
+	{ 0x10, "LDLC" },
+	{ 0x0,	NULL }
+};
+
+static const value_string sna_nlp_frh_vals[] = {
+	{ 0x03, "XID complete request" },
+	{ 0x04, "XID complete response" },
+	{ 0x0,	NULL }
+};
+
+static const true_false_string sna_nlp_setupi_truth =
+	{ "Connection setup segment present", "Connection setup segment not"
+	    " present" };
+
+static const true_false_string sna_nlp_somi_truth =
+	{ "Start of message", "Not start of message" };
+
+static const true_false_string sna_nlp_eomi_truth =
+	{ "End of message", "Not end of message" };
+
+static const true_false_string sna_nlp_sri_truth =
+	{ "Status requested", "No status requested" };
+
+static const true_false_string sna_nlp_rasapi_truth =
+	{ "Reply as soon as possible", "No need to reply as soon as possible" };
+
+static const true_false_string sna_nlp_retryi_truth =
+	{ "Undefined", "Sender will retransmit" };
+
+static const true_false_string sna_nlp_lmi_truth =
+	{ "Last message", "Not last message" };
+
+static const true_false_string sna_nlp_cqfi_truth =
+	{ "CQFI included", "CQFI not included" };
+
+static const true_false_string sna_nlp_osi_truth =
+	{ "Optional segments present", "No optional segments present" };
+
+static const value_string sna_xid_3_state_vals[] = {
+	{ 0x00, "Exchange state indicators not supported" },
+	{ 0x01, "Negotiation-proceeding exchange" },
+	{ 0x02, "Prenegotiation exchange" },
+	{ 0x03, "Nonactivation exchange" },
+	{ 0x0, NULL }
+};
+
+static const value_string sna_xid_3_branch_vals[] = {
+	{ 0x00, "Sender does not support branch extender" },
+	{ 0x01, "TG is branch uplink" },
+	{ 0x02, "TG is branch downlink" },
+	{ 0x03, "TG is neither uplink nor downlink" },
+	{ 0x0, NULL }
+};
+
+static const value_string sna_xid_type_vals[] = {
+	{ 0x01, "T1 node" },
+	{ 0x02, "T2.0 or T2.1 node" },
+	{ 0x03, "Reserved" },
+	{ 0x04, "T4 or T5 node" },
+	{ 0x0, NULL }
+};
+
+static const value_string sna_nlp_opti_vals[] = {
+	{ 0x0d, "Connection Setup Segment" },
+	{ 0x0e, "Status Segment" },
+	{ 0x0f, "Client Out Of Band Bits Segment" },
+	{ 0x10, "Connection Identifier Exchange Segment" },
+	{ 0x12, "Connection Fault Segment" },
+	{ 0x14, "Switching Information Segment" },
+	{ 0x22, "Adaptive Rate-Based Segment" },
+	{ 0x0, NULL }
+};
+
+static const value_string sna_nlp_opti_0d_version_vals[] = {
+	{ 0x0101, "Version 1.1" },
+	{ 0x0, NULL }
+};
+
+static const value_string sna_nlp_opti_0f_bits_vals[] = {
+	{ 0x0001, "Request Deactivation" },
+	{ 0x8000, "Reply - OK" },
+	{ 0x8004, "Reply - Reject" },
+	{ 0x0, NULL }
+};
+
+static const value_string sna_nlp_opti_22_type_vals[] = {
+	{ 0x00, "Setup" },
+	{ 0x01, "Rate Reply" },
+	{ 0x02, "Rate Request" },
+	{ 0x03, "Rate Request/Rate Reply" },
+	{ 0x0, NULL }
+};
+
+static const value_string sna_nlp_opti_22_raa_vals[] = {
+	{ 0x00, "Normal" },
+	{ 0x01, "Restraint" },
+	{ 0x02, "Slowdown1" },
+	{ 0x03, "Slowdown2" },
+	{ 0x04, "Critical" },
+	{ 0x0, NULL }
+};
+
+static const value_string sna_nlp_opti_22_arb_vals[] = {
+	{ 0x00, "Base Mode ARB" },
+	{ 0x01, "Responsive Mode ARB" },
+	{ 0x0, NULL }
+};
+
+/* GDS Variable Type */
+static const value_string sna_gds_var_vals[] = {
+	{ 0x1210, "Change Number Of Sessions" },
+	{ 0x1211, "Exchange Log Name" },
+	{ 0x1212, "Control Point Management Services Unit" },
+	{ 0x1213, "Compare States" },
+	{ 0x1214, "LU Names Position" },
+	{ 0x1215, "LU Name" },
+	{ 0x1217, "Do Know" },
+	{ 0x1218, "Partner Restart" },
+	{ 0x1219, "Don't Know" },
+	{ 0x1220, "Sign-Off" },
+	{ 0x1221, "Sign-On" },
+	{ 0x1222, "SNMP-over-SNA" },
+	{ 0x1223, "Node Address Service" },
+	{ 0x12C1, "CP Capabilities" },
+	{ 0x12C2, "Topology Database Update" },
+	{ 0x12C3, "Register Resource" },
+	{ 0x12C4, "Locate" },
+	{ 0x12C5, "Cross-Domain Initiate" },
+	{ 0x12C9, "Delete Resource" },
+	{ 0x12CA, "Find Resource" },
+	{ 0x12CB, "Found Resource" },
+	{ 0x12CC, "Notify" },
+	{ 0x12CD, "Initiate-Other Cross-Domain" },
+	{ 0x12CE, "Route Setup" },
+	{ 0x12E1, "Error Log" },
+	{ 0x12F1, "Null Data" },
+	{ 0x12F2, "User Control Date" },
+	{ 0x12F3, "Map Name" },
+	{ 0x12F4, "Error Data" },
+	{ 0x12F6, "Authentication Token Data" },
+	{ 0x12F8, "Service Flow Authentication Token Data" },
+	{ 0x12FF, "Application Data" },
+	{ 0x1310, "MDS Message Unit" },
+	{ 0x1311, "MDS Routing Information" },
+	{ 0x1500, "FID2 Encapsulation" },
+	{ 0x0,    NULL }
+};
+
+/* Control Vector Type */
+static const value_string sna_control_vals[] = {
+	{ 0x00,   "SSCP-LU Session Capabilities Control Vector" },
+	{ 0x01,   "Date-Time Control Vector" },
+	{ 0x02,   "Subarea Routing Control Vector" },
+	{ 0x03,   "SDLC Secondary Station Control Vector" },
+	{ 0x04,   "LU Control Vector" },
+	{ 0x05,   "Channel Control Vector" },
+	{ 0x06,   "Cross-Domain Resource Manager (CDRM) Control Vector" },
+	{ 0x07,   "PU FMD-RU-Usage Control Vector" },
+	{ 0x08,   "Intensive Mode Control Vector" },
+	{ 0x09,   "Activation Request / Response Sequence Identifier Control"
+	    " Vector" },
+	{ 0x0a,   "User Request Correlator Control Vector" },
+	{ 0x0b,   "SSCP-PU Session Capabilities Control Vector" },
+	{ 0x0c,   "LU-LU Session Capabilities Control Vector" },
+	{ 0x0d,   "Mode / Class-of-Service / Virtual-Route-Identifier List"
+	    " Control Vector" },
+	{ 0x0e,   "Network Name Control Vector" },
+	{ 0x0f,   "Link Capabilities and Status Control Vector" },
+	{ 0x10,   "Product Set ID Control Vector" },
+	{ 0x11,   "Load Module Correlation Control Vector" },
+	{ 0x12,   "Network Identifier Control Vector" },
+	{ 0x13,   "Gateway Support Capabilities Control Vector" },
+	{ 0x14,   "Session Initiation Control Vector" },
+	{ 0x15,   "Network-Qualified Address Pair Control Vector" },
+	{ 0x16,   "Names Substitution Control Vector" },
+	{ 0x17,   "SSCP Identifier Control Vector" },
+	{ 0x18,   "SSCP Name Control Vector" },
+	{ 0x19,   "Resource Identifier Control Vector" },
+	{ 0x1a,   "NAU Address Control Vector" },
+	{ 0x1b,   "VRID List Control Vector" },
+	{ 0x1c,   "Network-Qualified Name Pair Control Vector" },
+	{ 0x1e,   "VR-ER Mapping Data Control Vector" },
+	{ 0x1f,   "ER Configuration Control Vector" },
+	{ 0x23,   "Local-Form Session Identifier Control Vector" },
+	{ 0x24,   "IPL Load Module Request Control Vector" },
+	{ 0x25,   "Security ID Control Control Vector" },
+	{ 0x26,   "Network Connection Endpoint Identifier Control Vector" },
+	{ 0x27,   "XRF Session Activation Control Vector" },
+	{ 0x28,   "Related Session Identifier Control Vector" },
+	{ 0x29,   "Session State Data Control Vector" },
+	{ 0x2a,   "Session Information Control Vector" },
+	{ 0x2b,   "Route Selection Control Vector" },
+	{ 0x2c,   "COS/TPF Control Vector" },
+	{ 0x2d,   "Mode Control Vector" },
+	{ 0x2f,   "LU Definition Control Vector" },
+	{ 0x30,   "Assign LU Characteristics Control Vector" },
+	{ 0x31,   "BIND Image Control Vector" },
+	{ 0x32,   "Short-Hold Mode Control Vector" },
+	{ 0x33,   "ENCP Search Control Control Vector" },
+	{ 0x34,   "LU Definition Override Control Vector" },
+	{ 0x35,   "Extended Sense Data Control Vector" },
+	{ 0x36,   "Directory Error Control Vector" },
+	{ 0x37,   "Directory Entry Correlator Control Vector" },
+	{ 0x38,   "Short-Hold Mode Emulation Control Vector" },
+	{ 0x39,   "Network Connection Endpoint (NCE) Instance Identifier"
+	    " Control Vector" },
+	{ 0x3a,   "Route Status Data Control Vector" },
+	{ 0x3b,   "VR Congestion Data Control Vector" },
+	{ 0x3c,   "Associated Resource Entry Control Vector" },
+	{ 0x3d,   "Directory Entry Control Vector" },
+	{ 0x3e,   "Directory Entry Characteristic Control Vector" },
+	{ 0x3f,   "SSCP (SLU) Capabilities Control Vector" },
+	{ 0x40,   "Real Associated Resource Control Vector" },
+	{ 0x41,   "Station Parameters Control Vector" },
+	{ 0x42,   "Dynamic Path Update Data Control Vector" },
+	{ 0x43,   "Extended SDLC Station Control Vector" },
+	{ 0x44,   "Node Descriptor Control Vector" },
+	{ 0x45,   "Node Characteristics Control Vector" },
+	{ 0x46,   "TG Descriptor Control Vector" },
+	{ 0x47,   "TG Characteristics Control Vector" },
+	{ 0x48,   "Topology Resource Descriptor Control Vector" },
+	{ 0x49,   "Multinode Persistent Sessions (MNPS) LU Names Control"
+	    " Vector" },
+	{ 0x4a,   "Real Owning Control Point Control Vector" },
+	{ 0x4b,   "RTP Transport Connection Identifier Control Vector" },
+	{ 0x51,   "DLUR/S Capabilities Control Vector" },
+	{ 0x52,   "Primary Send Pacing Window Size Control Vector" },
+	{ 0x56,   "Call Security Verification Control Vector" },
+	{ 0x57,   "DLC Connection Data Control Vector" },
+	{ 0x59,   "Installation-Defined CDINIT Data Control Vector" },
+	{ 0x5a,   "Session Services Extension Support Control Vector" },
+	{ 0x5b,   "Interchange Node Support Control Vector" },
+	{ 0x5c,   "APPN Message Transport Control Vector" },
+	{ 0x5d,   "Subarea Message Transport Control Vector" },
+	{ 0x5e,   "Related Request Control Vector" },
+	{ 0x5f,   "Extended Fully Qualified PCID Control Vector" },
+	{ 0x60,   "Fully Qualified PCID Control Vector" },
+	{ 0x61,   "HPR Capabilities Control Vector" },
+	{ 0x62,   "Session Address Control Vector" },
+	{ 0x63,   "Cryptographic Key Distribution Control Vector" },
+	{ 0x64,   "TCP/IP Information Control Vector" },
+	{ 0x65,   "Device Characteristics Control Vector" },
+	{ 0x66,   "Length-Checked Compression Control Vector" },
+	{ 0x67,   "Automatic Network Routing (ANR) Path Control Vector" },
+	{ 0x68,   "XRF/Session Cryptography Control Vector" },
+	{ 0x69,   "Switched Parameters Control Vector" },
+	{ 0x6a,   "ER Congestion Data Control Vector" },
+	{ 0x71,   "Triple DES Cryptography Key Continuation Control Vector" },
+	{ 0xfe,   "Control Vector Keys Not Recognized" },
+	{ 0x0,    NULL }
+};
+
+static const value_string sna_control_hpr_vals[] = {
+	{ 0x00,   "Node Identifier Control Vector" },
+	{ 0x03,   "Network ID Control Vector" },
+	{ 0x05,   "Network Address Control Vector" },
+	{ 0x0,    NULL }
+};
+
+static const value_string sna_control_0e_type_vals[] = {
+	{ 0xF1,   "PU Name" },
+	{ 0xF3,   "LU Name" },
+	{ 0xF4,   "CP Name" },
+	{ 0xF5,   "SSCP Name" },
+	{ 0xF6,   "NNCP Name" },
+	{ 0xF7,   "Link Station Name" },
+	{ 0xF8,   "CP Name of CP(PLU)" },
+	{ 0xF9,   "CP Name of CP(SLU)" },
+	{ 0xFA,   "Generic Name" },
+	{ 0x0,    NULL }
+};
+
+/* Values to direct the top-most dissector what to dissect
+ * after the TH. */
+enum next_dissection_enum {
+    stop_here,
+    rh_only,
+    everything
+};
+
+enum parse {
+    LT,
+    KL
+};
+
+typedef enum next_dissection_enum next_dissection_t;
+
+static void dissect_xid (tvbuff_t*, packet_info*, proto_tree*, proto_tree*);
+static void dissect_fid (tvbuff_t*, packet_info*, proto_tree*, proto_tree*);
+static void dissect_nlp (tvbuff_t*, packet_info*, proto_tree*, proto_tree*);
+static void dissect_gds (tvbuff_t*, packet_info*, proto_tree*, proto_tree*);
+static void dissect_rh (tvbuff_t*, int, proto_tree*);
+static void dissect_control(tvbuff_t*, int, int, proto_tree*, int, enum parse);
+
+/* --------------------------------------------------------------------
+ * Chapter 2 High-Performance Routing (HPR) Headers
+ * --------------------------------------------------------------------
+ */
+
+static void
+dissect_optional_0d(tvbuff_t *tvb, proto_tree *tree)
+{
+	int		bits, offset, len, pad;
+	proto_tree	*sub_tree;
+	proto_item	*sub_ti = NULL;
+
+	if (!tree)
+		return;
+
+	proto_tree_add_item(tree, hf_sna_nlp_opti_0d_version, tvb, 2, 2, FALSE);
+	bits = tvb_get_guint8(tvb, 4);
+
+	sub_ti = proto_tree_add_uint(tree, hf_sna_nlp_opti_0d_4,
+	    tvb, 4, 1, bits);
+	sub_tree = proto_item_add_subtree(sub_ti, 
+	    ett_sna_nlp_opti_0d_4);
+
+	proto_tree_add_boolean(sub_tree, hf_sna_nlp_opti_0d_target,
+	    tvb, 4, 1, bits);
+	proto_tree_add_boolean(sub_tree, hf_sna_nlp_opti_0d_arb,
+	    tvb, 4, 1, bits);
+	proto_tree_add_boolean(sub_tree, hf_sna_nlp_opti_0d_reliable,
+	    tvb, 4, 1, bits);
+	proto_tree_add_boolean(sub_tree, hf_sna_nlp_opti_0d_dedicated,
+	    tvb, 4, 1, bits);
+
+	proto_tree_add_text(tree, tvb, 5, 3, "Reserved");
+
+	offset = 8;
+
+	while (tvb_offset_exists(tvb, offset)) {
+		len = tvb_get_guint8(tvb, offset+0);
+		if (len) {
+			dissect_control(tvb, offset, len, tree, 1, LT);
+			pad = (len+3) & 0xfffc;
+			if (pad > len)
+				proto_tree_add_text(tree, tvb, offset+len,
+				    pad-len, "Padding");
+			offset += pad;
+		} else {
+			/* Avoid endless loop */
+			return;
+		}
+	}
+}
+
+static void
+dissect_optional_0e(tvbuff_t *tvb, packet_info *pinfo, proto_tree *tree)
+{
+	int		bits, offset;
+	proto_tree	*sub_tree;
+	proto_item	*sub_ti = NULL;
+
+	bits = tvb_get_guint8(tvb, 2);
+	offset = 20;
+
+	if (tree) {
+		sub_ti = proto_tree_add_item(tree, hf_sna_nlp_opti_0e_stat,
+		    tvb, 2, 1, FALSE);
+		sub_tree = proto_item_add_subtree(sub_ti, 
+		    ett_sna_nlp_opti_0e_stat);
+
+		proto_tree_add_boolean(sub_tree, hf_sna_nlp_opti_0e_gap,
+		    tvb, 2, 1, bits);
+		proto_tree_add_boolean(sub_tree, hf_sna_nlp_opti_0e_idle,
+		    tvb, 2, 1, bits);
+		proto_tree_add_item(tree, hf_sna_nlp_opti_0e_nabsp,
+		    tvb, 3, 1, FALSE);
+		proto_tree_add_item(tree, hf_sna_nlp_opti_0e_sync,
+		    tvb, 4, 2, FALSE);
+		proto_tree_add_item(tree, hf_sna_nlp_opti_0e_echo,
+		    tvb, 6, 2, FALSE);
+		proto_tree_add_item(tree, hf_sna_nlp_opti_0e_rseq,
+		    tvb, 8, 4, FALSE);
+		proto_tree_add_text(tree, tvb, 12, 8, "Reserved");
+
+		if (tvb_offset_exists(tvb, offset))
+			call_dissector(data_handle,
+			    tvb_new_subset(tvb, 4, -1, -1), pinfo, tree);
+	}
+	if (bits & 0x40) {
+		if (check_col(pinfo->cinfo, COL_INFO))
+			col_add_str(pinfo->cinfo, COL_INFO,
+			    "HPR Idle Message");
+	} else {
+		if (check_col(pinfo->cinfo, COL_INFO))
+			col_add_str(pinfo->cinfo, COL_INFO,
+			    "HPR Status Message");
+	}
+}
+
+static void
+dissect_optional_0f(tvbuff_t *tvb, packet_info *pinfo, proto_tree *tree)
+{
+	if (!tree)
+		return;
+
+	proto_tree_add_item(tree, hf_sna_nlp_opti_0f_bits, tvb, 2, 2, FALSE);
+	if (tvb_offset_exists(tvb, 4))
+		call_dissector(data_handle,
+		    tvb_new_subset(tvb, 4, -1, -1), pinfo, tree);
+}
+
+static void
+dissect_optional_10(tvbuff_t *tvb, packet_info *pinfo, proto_tree *tree)
+{
+	if (!tree)
+		return;
+
+	proto_tree_add_text(tree, tvb, 2, 2, "Reserved");
+	proto_tree_add_item(tree, hf_sna_nlp_opti_10_tcid, tvb, 4, 8, FALSE);
+	if (tvb_offset_exists(tvb, 12))
+		call_dissector(data_handle,
+		    tvb_new_subset(tvb, 12, -1, -1), pinfo, tree);
+}
+
+static void
+dissect_optional_12(tvbuff_t *tvb, proto_tree *tree)
+{
+	if (!tree)
+		return;
+
+	proto_tree_add_text(tree, tvb, 2, 2, "Reserved");
+	proto_tree_add_item(tree, hf_sna_nlp_opti_12_sense, tvb, 4, -1, FALSE);
+}
+
+static void
+dissect_optional_14(tvbuff_t *tvb, packet_info *pinfo, proto_tree *tree)
+{
+	proto_tree	*sub_tree, *bf_tree;
+	proto_item	*sub_item, *bf_item;
+	int		len, pad, type, bits, offset, num, sublen;
+
+	if (!tree)
+		return;
+
+	proto_tree_add_text(tree, tvb, 2, 2, "Reserved");
+
+	offset = 4;
+
+	len = tvb_get_guint8(tvb, offset);
+	type = tvb_get_guint8(tvb, offset+1);
+
+	if ((type != 0x83) || (len <= 16)) {
+		/* Invalid */
+		call_dissector(data_handle,
+		    tvb_new_subset(tvb, offset, -1, -1), pinfo, tree);
+		return;
+	}
+	sub_item = proto_tree_add_text(tree, tvb, offset, len,
+	    "Switching Information Control Vector");
+	sub_tree = proto_item_add_subtree(sub_item, ett_sna_nlp_opti_14_si);
+
+	proto_tree_add_uint(sub_tree, hf_sna_nlp_opti_14_si_len,
+	    tvb, offset, 1, len);
+	proto_tree_add_uint(sub_tree, hf_sna_nlp_opti_14_si_key,
+	    tvb, offset+1, 1, type);
+	
+	bits = tvb_get_guint8(tvb, offset+2);
+	bf_item = proto_tree_add_uint(sub_tree, hf_sna_nlp_opti_14_si_2,
+	    tvb, offset+2, 1, bits);
+	bf_tree = proto_item_add_subtree(bf_item, ett_sna_nlp_opti_14_si_2);
+
+	proto_tree_add_boolean(bf_tree, hf_sna_nlp_opti_14_si_refifo,
+	    tvb, offset+2, 1, bits);
+	proto_tree_add_boolean(bf_tree, hf_sna_nlp_opti_14_si_mobility,
+	    tvb, offset+2, 1, bits);
+	proto_tree_add_boolean(bf_tree, hf_sna_nlp_opti_14_si_dirsearch,
+	    tvb, offset+2, 1, bits);
+	proto_tree_add_boolean(bf_tree, hf_sna_nlp_opti_14_si_limitres,
+	    tvb, offset+2, 1, bits);
+	proto_tree_add_boolean(bf_tree, hf_sna_nlp_opti_14_si_ncescope,
+	    tvb, offset+2, 1, bits);
+	proto_tree_add_boolean(bf_tree, hf_sna_nlp_opti_14_si_mnpsrscv,
+	    tvb, offset+2, 1, bits);
+
+	proto_tree_add_text(sub_tree, tvb, offset+3, 1, "Reserved");
+	proto_tree_add_item(sub_tree, hf_sna_nlp_opti_14_si_maxpsize,
+	    tvb, offset+4, 4, FALSE);
+	proto_tree_add_item(sub_tree, hf_sna_nlp_opti_14_si_switch,
+	    tvb, offset+8, 4, FALSE);
+	proto_tree_add_item(sub_tree, hf_sna_nlp_opti_14_si_alive,
+	    tvb, offset+12, 4, FALSE);
+
+	dissect_control(tvb, offset+16, len-16, sub_tree, 1, LT);
+
+	pad = (len+3) & 0xfffc;
+	if (pad > len)
+		proto_tree_add_text(sub_tree, tvb, offset+len, pad-len,
+		    "Padding");
+	offset += pad;
+
+	len = tvb_get_guint8(tvb, offset);
+	type = tvb_get_guint8(tvb, offset+1);
+
+	if ((type != 0x85) || ( len < 4))  {
+		/* Invalid */
+		call_dissector(data_handle,
+		    tvb_new_subset(tvb, offset, -1, -1), pinfo, tree);
+		return;
+	}
+	sub_item = proto_tree_add_text(tree, tvb, offset, len,
+	    "Return Route TG Descriptor Control Vector");
+	sub_tree = proto_item_add_subtree(sub_item, ett_sna_nlp_opti_14_rr);
+
+	proto_tree_add_uint(sub_tree, hf_sna_nlp_opti_14_rr_len,
+	    tvb, offset, 1, len);
+	proto_tree_add_uint(sub_tree, hf_sna_nlp_opti_14_rr_key,
+	    tvb, offset+1, 1, type);
+	
+	bits = tvb_get_guint8(tvb, offset+2);
+	bf_item = proto_tree_add_uint(sub_tree, hf_sna_nlp_opti_14_rr_2,
+	    tvb, offset+2, 1, bits);
+	bf_tree = proto_item_add_subtree(bf_item, ett_sna_nlp_opti_14_rr_2);
+
+	proto_tree_add_boolean(bf_tree, hf_sna_nlp_opti_14_rr_bfe,
+	    tvb, offset+2, 1, bits);
+
+	num = tvb_get_guint8(tvb, offset+3);
+
+	proto_tree_add_uint(sub_tree, hf_sna_nlp_opti_14_rr_num,
+	    tvb, offset+3, 1, num);
+
+	offset += 4;
+
+	while (num) {
+		sublen = tvb_get_guint8(tvb, offset);
+		if (sublen) {
+			dissect_control(tvb, offset, sublen, sub_tree, 1, LT);
+		} else {
+			/* Invalid */
+			call_dissector(data_handle,
+			    tvb_new_subset(tvb, offset, -1, -1), pinfo, tree);
+			return;
+		}
+		/* No padding here */
+		offset += sublen;
+		num--;
+	}
+}
+
+static void
+dissect_optional_22(tvbuff_t *tvb, packet_info *pinfo, proto_tree *tree)
+{
+	proto_tree	*bf_tree;
+	proto_item	*bf_item;
+	int		bits, type;
+
+	if (!tree)
+		return;
+
+	bits = tvb_get_guint8(tvb, 2);
+	type = (bits & 0xc0) >> 6;
+
+	bf_item = proto_tree_add_uint(tree, hf_sna_nlp_opti_22_2,
+	    tvb, 2, 1, bits);
+	bf_tree = proto_item_add_subtree(bf_item, ett_sna_nlp_opti_22_2);
+
+	proto_tree_add_uint(bf_tree, hf_sna_nlp_opti_22_type,
+	    tvb, 2, 1, bits);
+	proto_tree_add_uint(bf_tree, hf_sna_nlp_opti_22_raa,
+	    tvb, 2, 1, bits);
+	proto_tree_add_boolean(bf_tree, hf_sna_nlp_opti_22_parity,
+	    tvb, 2, 1, bits);
+	proto_tree_add_uint(bf_tree, hf_sna_nlp_opti_22_arb,
+	    tvb, 2, 1, bits);
+
+	bits = tvb_get_guint8(tvb, 3);
+
+	bf_item = proto_tree_add_uint(tree, hf_sna_nlp_opti_22_3,
+	    tvb, 3, 1, bits);
+	bf_tree = proto_item_add_subtree(bf_item, ett_sna_nlp_opti_22_3);
+
+	proto_tree_add_uint(bf_tree, hf_sna_nlp_opti_22_ratereq,
+	    tvb, 3, 1, bits);
+	proto_tree_add_uint(bf_tree, hf_sna_nlp_opti_22_raterep,
+	    tvb, 3, 1, bits);
+
+	proto_tree_add_item(tree, hf_sna_nlp_opti_22_field1,
+	    tvb, 4, 4, FALSE);
+	proto_tree_add_item(tree, hf_sna_nlp_opti_22_field2,
+	    tvb, 8, 4, FALSE);
+
+	if (type == 0) {
+		proto_tree_add_item(tree, hf_sna_nlp_opti_22_field3,
+		    tvb, 12, 4, FALSE);
+		proto_tree_add_item(tree, hf_sna_nlp_opti_22_field4,
+		    tvb, 16, 4, FALSE);
+
+		if (tvb_offset_exists(tvb, 20))
+			call_dissector(data_handle,
+			    tvb_new_subset(tvb, 20, -1, -1), pinfo, tree);
+	} else {
+		if (tvb_offset_exists(tvb, 12))
+			call_dissector(data_handle,
+			    tvb_new_subset(tvb, 12, -1, -1), pinfo, tree);
+	}
+}
+
+static void
+dissect_optional(tvbuff_t *tvb, packet_info *pinfo, proto_tree *tree)
+{
+	proto_tree	*sub_tree;
+	proto_item	*sub_item;
+	int		offset, type, len;
+	gint		ett;
+
+	sub_tree = NULL;
+
+	offset = 0;
+
+	while (tvb_offset_exists(tvb, offset)) {
+		len = tvb_get_guint8(tvb, offset);
+		type = tvb_get_guint8(tvb, offset+1);
+
+		/* Prevent loop for invalid crap in packet */
+		if (len == 0) {
+			if (tree)
+				call_dissector(data_handle,
+				    tvb_new_subset(tvb, offset,
+				    -1, -1), pinfo, tree);
+			return;
+		}
+			
+		ett = ett_sna_nlp_opti_un;
+		if(type == 0x0d) ett = ett_sna_nlp_opti_0d;
+		if(type == 0x0e) ett = ett_sna_nlp_opti_0e;
+		if(type == 0x0f) ett = ett_sna_nlp_opti_0f;
+		if(type == 0x10) ett = ett_sna_nlp_opti_10;
+		if(type == 0x12) ett = ett_sna_nlp_opti_12;
+		if(type == 0x14) ett = ett_sna_nlp_opti_14;
+		if(type == 0x22) ett = ett_sna_nlp_opti_22;
+		if (tree) {
+			sub_item = proto_tree_add_text(tree, tvb,
+			    offset, len << 2,
+			    val_to_str(type, sna_nlp_opti_vals,
+			    "Unknown Segment Type"));
+			sub_tree = proto_item_add_subtree(sub_item, ett);
+			proto_tree_add_uint(sub_tree, hf_sna_nlp_opti_len,
+			    tvb, offset, 1, len);
+			proto_tree_add_uint(sub_tree, hf_sna_nlp_opti_type,
+			    tvb, offset+1, 1, type);
+		}
+		switch(type) {
+			case 0x0d:
+				dissect_optional_0d(tvb_new_subset(tvb, offset,
+				    len << 2, -1), sub_tree);
+				break;
+			case 0x0e:
+				dissect_optional_0e(tvb_new_subset(tvb, offset,
+				    len << 2, -1), pinfo, sub_tree);
+				break;
+			case 0x0f:
+				dissect_optional_0f(tvb_new_subset(tvb, offset,
+				    len << 2, -1), pinfo, sub_tree);
+				break;
+			case 0x10:
+				dissect_optional_10(tvb_new_subset(tvb, offset,
+				    len << 2, -1), pinfo, sub_tree);
+				break;
+			case 0x12:
+				dissect_optional_12(tvb_new_subset(tvb, offset,
+				    len << 2, -1), sub_tree);
+				break;
+			case 0x14:
+				dissect_optional_14(tvb_new_subset(tvb, offset,
+				    len << 2, -1), pinfo, sub_tree);
+				break;
+			case 0x22:
+				dissect_optional_22(tvb_new_subset(tvb, offset,
+				    len << 2, -1), pinfo, sub_tree);
+				break;
+			default:
+				call_dissector(data_handle,
+				    tvb_new_subset(tvb, offset,
+				    len << 2, -1), pinfo, sub_tree);
+		}
+		offset += (len << 2);
+	}
+}
+
+static void
+dissect_nlp(tvbuff_t *tvb, packet_info *pinfo, proto_tree *tree,
+    proto_tree *parent_tree)
+{
+	proto_tree	*nlp_tree, *bf_tree;
+	proto_item	*nlp_item, *bf_item, *h_item;
+	guint8		nhdr_0, nhdr_1, nhdr_x, thdr_8, thdr_9, fid;
+	guint32		thdr_len, thdr_dlf;
+	guint16		subindex;
+
+	int index = 0, counter = 0;
+
+	nlp_tree = NULL;
+	nlp_item = NULL;
+
+	nhdr_0 = tvb_get_guint8(tvb, index);
+	nhdr_1 = tvb_get_guint8(tvb, index+1);
+
+	if (check_col(pinfo->cinfo, COL_INFO))
+		col_add_str(pinfo->cinfo, COL_INFO, "HPR NLP Packet");
+
+	if (tree) {
+		/* Don't bother setting length. We'll set it later after we
+		 * find the lengths of NHDR */
+		nlp_item = proto_tree_add_item(tree, hf_sna_nlp_nhdr, tvb,
+		    index, -1, FALSE);
+		nlp_tree = proto_item_add_subtree(nlp_item, ett_sna_nlp_nhdr);
+
+		bf_item = proto_tree_add_uint(nlp_tree, hf_sna_nlp_nhdr_0, tvb,
+		    index, 1, nhdr_0);
+		bf_tree = proto_item_add_subtree(bf_item, ett_sna_nlp_nhdr_0);
+
+		proto_tree_add_uint(bf_tree, hf_sna_nlp_sm, tvb, index, 1,
+		    nhdr_0);
+		proto_tree_add_uint(bf_tree, hf_sna_nlp_tpf, tvb, index, 1,
+		    nhdr_0);
+
+		bf_item = proto_tree_add_uint(nlp_tree, hf_sna_nlp_nhdr_1, tvb,
+		    index+1, 1, nhdr_1);
+		bf_tree = proto_item_add_subtree(bf_item, ett_sna_nlp_nhdr_1);
+
+		proto_tree_add_uint(bf_tree, hf_sna_nlp_ft, tvb,
+		    index+1, 1, nhdr_1);
+		proto_tree_add_boolean(bf_tree, hf_sna_nlp_tspi, tvb,
+		    index+1, 1, nhdr_1);
+		proto_tree_add_boolean(bf_tree, hf_sna_nlp_slowdn1, tvb,
+		    index+1, 1, nhdr_1);
+		proto_tree_add_boolean(bf_tree, hf_sna_nlp_slowdn2, tvb,
+		    index+1, 1, nhdr_1);
+	}
+	/* ANR or FR lists */
+
+	index += 2;
+	counter = 0;
+
+	if ((nhdr_0 & 0xe0) == 0xa0) {
+		do {
+			nhdr_x = tvb_get_guint8(tvb, index + counter);
+			counter ++;
+		} while (nhdr_x != 0xff);
+		if (tree)
+			h_item = proto_tree_add_item(nlp_tree, 
+			    hf_sna_nlp_fra, tvb, index, counter, FALSE);
+		index += counter;
+		if (tree)
+			proto_tree_add_text(nlp_tree, tvb, index, 1,
+			    "Reserved");
+		index++;
+
+		if (tree)
+			proto_item_set_len(nlp_item, index);
+
+		if ((nhdr_1 & 0xf0) == 0x10) {
+			nhdr_x = tvb_get_guint8(tvb, index);
+			if (tree)
+				proto_tree_add_uint(tree, hf_sna_nlp_frh, 
+				    tvb, index, 1, nhdr_x);
+			index ++;
+
+			if (tvb_offset_exists(tvb, index))
+				call_dissector(data_handle,
+					tvb_new_subset(tvb, index, -1, -1),
+					pinfo, parent_tree);
+			return;
+		}
+	}
+	if ((nhdr_0 & 0xe0) == 0xc0) {
+		do {
+			nhdr_x = tvb_get_guint8(tvb, index + counter);
+			counter ++;
+		} while (nhdr_x != 0xff);
+		if (tree)
+			h_item = proto_tree_add_item(nlp_tree, hf_sna_nlp_anr, 
+			    tvb, index, counter, FALSE);
+		index += counter;
+
+		if (tree)
+			proto_tree_add_text(nlp_tree, tvb, index, 1,
+			    "Reserved");
+		index++;
+
+		if (tree)
+			proto_item_set_len(nlp_item, index);
+	}
+
+	thdr_8 = tvb_get_guint8(tvb, index+8);
+	thdr_9 = tvb_get_guint8(tvb, index+9);
+	thdr_len = tvb_get_ntohs(tvb, index+10);
+	thdr_dlf = tvb_get_ntohl(tvb, index+12);
+
+	if (tree) {
+		nlp_item = proto_tree_add_item(tree, hf_sna_nlp_thdr, tvb, 
+		    index, thdr_len << 2, FALSE);
+		nlp_tree = proto_item_add_subtree(nlp_item, ett_sna_nlp_thdr);
+
+		proto_tree_add_item(nlp_tree, hf_sna_nlp_tcid, tvb,
+		    index, 8, FALSE);
+		bf_item = proto_tree_add_uint(nlp_tree, hf_sna_nlp_thdr_8, tvb,
+		    index+8, 1, thdr_8);
+		bf_tree = proto_item_add_subtree(bf_item, ett_sna_nlp_thdr_8);
+
+		proto_tree_add_boolean(bf_tree, hf_sna_nlp_setupi, tvb,
+		    index+8, 1, thdr_8);
+		proto_tree_add_boolean(bf_tree, hf_sna_nlp_somi, tvb, index+8,
+		    1, thdr_8);
+		proto_tree_add_boolean(bf_tree, hf_sna_nlp_eomi, tvb, index+8,
+		    1, thdr_8);
+		proto_tree_add_boolean(bf_tree, hf_sna_nlp_sri, tvb, index+8,
+		    1, thdr_8);
+		proto_tree_add_boolean(bf_tree, hf_sna_nlp_rasapi, tvb,
+		    index+8, 1, thdr_8);
+		proto_tree_add_boolean(bf_tree, hf_sna_nlp_retryi, tvb,
+		    index+8, 1, thdr_8);
+
+		bf_item = proto_tree_add_uint(nlp_tree, hf_sna_nlp_thdr_9, tvb,
+		    index+9, 1, thdr_9);
+		bf_tree = proto_item_add_subtree(bf_item, ett_sna_nlp_thdr_9);
+
+		proto_tree_add_boolean(bf_tree, hf_sna_nlp_lmi, tvb, index+9,
+		    1, thdr_9);
+		proto_tree_add_boolean(bf_tree, hf_sna_nlp_cqfi, tvb, index+9,
+		    1, thdr_9);
+		proto_tree_add_boolean(bf_tree, hf_sna_nlp_osi, tvb, index+9,
+		    1, thdr_9);
+
+		proto_tree_add_uint(nlp_tree, hf_sna_nlp_offset, tvb, index+10,
+		    2, thdr_len);
+		proto_tree_add_uint(nlp_tree, hf_sna_nlp_dlf, tvb, index+12,
+		    4, thdr_dlf);
+		proto_tree_add_item(nlp_tree, hf_sna_nlp_bsn, tvb, index+16,
+		    4, FALSE);
+	}
+	subindex = 20;
+
+	if (((thdr_9 & 0x18) == 0x08) && ((thdr_len << 2) > subindex)) {
+		counter = tvb_get_guint8(tvb, index + subindex);
+		if (tvb_get_guint8(tvb, index+subindex+1) == 5)
+			dissect_control(tvb, index + subindex, counter+2, nlp_tree, 1, LT);
+		else
+			call_dissector(data_handle,
+			    tvb_new_subset(tvb, index + subindex, counter+2,
+			    -1), pinfo, nlp_tree);
+
+		subindex += (counter+2);
+	}
+	if ((thdr_9 & 0x04) && ((thdr_len << 2) > subindex))
+		dissect_optional(
+		    tvb_new_subset(tvb, index + subindex,
+		    (thdr_len << 2) - subindex, -1),
+		    pinfo, nlp_tree);
+
+	index += (thdr_len << 2);
+	if (((thdr_8 & 0x20) == 0) && thdr_dlf) {
+		if (check_col(pinfo->cinfo, COL_INFO))
+			col_add_str(pinfo->cinfo, COL_INFO, "HPR Fragment");
+		if (tvb_offset_exists(tvb, index)) {
+			call_dissector(data_handle,
+			    tvb_new_subset(tvb, index, -1, -1), pinfo,
+			    parent_tree);
+		}
+		return;
+	}
+	if (tvb_offset_exists(tvb, index)) {
+		/* Transmission Header Format Identifier */
+		fid = hi_nibble(tvb_get_guint8(tvb, index));
+		if (fid == 5) /* Only FID5 allowed for HPR */
+			dissect_fid(tvb_new_subset(tvb, index, -1, -1), pinfo,
+			    tree, parent_tree);
+		else {
+			if (tvb_get_ntohs(tvb, index+2) == 0x12ce) {
+				/* Route Setup */
+				if (check_col(pinfo->cinfo, COL_INFO))
+					col_add_str(pinfo->cinfo, COL_INFO,
+					    "HPR Route Setup");
+				dissect_gds(tvb_new_subset(tvb, index, -1, -1),
+				    pinfo, tree, parent_tree);
+			} else
+				call_dissector(data_handle, 
+				    tvb_new_subset(tvb, index, -1, -1),
+				    pinfo, parent_tree);
+		}
+	}
+}
+
+/* --------------------------------------------------------------------
+ * Chapter 3 Exchange Identification (XID) Information Fields
+ * --------------------------------------------------------------------
+ */
+
+static void
+dissect_xid1(tvbuff_t *tvb, proto_tree *tree)
+{
+	if (!tree)
+		return;
+
+	proto_tree_add_text(tree, tvb, 0, 2, "Reserved");
+
+}
+
+static void
+dissect_xid2(tvbuff_t *tvb, proto_tree *tree)
+{
+	guint		dlen, offset;
+
+	if (!tree)
+		return;
+
+	dlen = tvb_get_guint8(tvb, 0);
+
+	offset = dlen;
+
+	while (tvb_offset_exists(tvb, offset)) {
+		dlen = tvb_get_guint8(tvb, offset+1);
+		dissect_control(tvb, offset, dlen+2, tree, 0, KL);
+		offset += (dlen + 2);
+	}
+}
+
+static void
+dissect_xid3(tvbuff_t *tvb, proto_tree *tree)
+{
+	proto_tree	*sub_tree;
+	proto_item	*sub_ti = NULL;
+	guint		val, dlen, offset;
+
+	if (!tree)
+		return;
+
+	proto_tree_add_text(tree, tvb, 0, 2, "Reserved");
+
+	val = tvb_get_ntohs(tvb, 2);
+
+	sub_ti = proto_tree_add_uint(tree, hf_sna_xid_3_8, tvb,
+	    2, 2, val);
+	sub_tree = proto_item_add_subtree(sub_ti, ett_sna_xid_3_8);
+
+	proto_tree_add_boolean(sub_tree, hf_sna_xid_3_init_self, tvb, 2, 2,
+	    val);
+	proto_tree_add_boolean(sub_tree, hf_sna_xid_3_stand_bind, tvb, 2, 2,
+	    val);
+	proto_tree_add_boolean(sub_tree, hf_sna_xid_3_gener_bind, tvb, 2, 2,
+	    val);
+	proto_tree_add_boolean(sub_tree, hf_sna_xid_3_recve_bind, tvb, 2, 2,
+	    val);
+	proto_tree_add_boolean(sub_tree, hf_sna_xid_3_actpu, tvb, 2, 2, val);
+	proto_tree_add_boolean(sub_tree, hf_sna_xid_3_nwnode, tvb, 2, 2, val);
+	proto_tree_add_boolean(sub_tree, hf_sna_xid_3_cp, tvb, 2, 2, val);
+	proto_tree_add_boolean(sub_tree, hf_sna_xid_3_cpcp, tvb, 2, 2, val);
+	proto_tree_add_uint(sub_tree, hf_sna_xid_3_state, tvb, 2, 2, val);
+	proto_tree_add_boolean(sub_tree, hf_sna_xid_3_nonact, tvb, 2, 2, val);
+	proto_tree_add_boolean(sub_tree, hf_sna_xid_3_cpchange, tvb, 2, 2,
+	    val);
+
+	val = tvb_get_guint8(tvb, 4);
+
+	sub_ti = proto_tree_add_uint(tree, hf_sna_xid_3_10, tvb,
+	    4, 1, val);
+	sub_tree = proto_item_add_subtree(sub_ti, ett_sna_xid_3_10);
+
+	proto_tree_add_boolean(sub_tree, hf_sna_xid_3_asend_bind, tvb, 4, 1,
+	    val);
+	proto_tree_add_boolean(sub_tree, hf_sna_xid_3_arecv_bind, tvb, 4, 1,
+	    val);
+	proto_tree_add_boolean(sub_tree, hf_sna_xid_3_quiesce, tvb, 4, 1, val);
+	proto_tree_add_boolean(sub_tree, hf_sna_xid_3_pucap, tvb, 4, 1, val);
+	proto_tree_add_boolean(sub_tree, hf_sna_xid_3_pbn, tvb, 4, 1, val);
+	proto_tree_add_uint(sub_tree, hf_sna_xid_3_pacing, tvb, 4, 1, val);
+
+	val = tvb_get_guint8(tvb, 5);
+
+	sub_ti = proto_tree_add_uint(tree, hf_sna_xid_3_11, tvb,
+	    5, 1, val);
+	sub_tree = proto_item_add_subtree(sub_ti, ett_sna_xid_3_11);
+
+	proto_tree_add_boolean(sub_tree, hf_sna_xid_3_tgshare, tvb, 5, 1, val);
+	proto_tree_add_boolean(sub_tree, hf_sna_xid_3_dedsvc, tvb, 5, 1, val);
+
+	val = tvb_get_guint8(tvb, 6);
+
+	sub_ti = proto_tree_add_item(tree, hf_sna_xid_3_12, tvb,
+	    6, 1, FALSE);
+	sub_tree = proto_item_add_subtree(sub_ti, ett_sna_xid_3_12);
+
+	proto_tree_add_boolean(sub_tree, hf_sna_xid_3_negcsup, tvb, 6, 1, val);
+	proto_tree_add_boolean(sub_tree, hf_sna_xid_3_negcomp, tvb, 6, 1, val);
+
+	proto_tree_add_text(tree, tvb, 7, 2, "Reserved");
+
+	val = tvb_get_guint8(tvb, 9);
+
+	sub_ti = proto_tree_add_item(tree, hf_sna_xid_3_15, tvb,
+	    9, 1, FALSE);
+	sub_tree = proto_item_add_subtree(sub_ti, ett_sna_xid_3_15);
+
+	proto_tree_add_boolean(sub_tree, hf_sna_xid_3_partg, tvb, 9, 1, val);
+	proto_tree_add_boolean(sub_tree, hf_sna_xid_3_dlur, tvb, 9, 1, val);
+	proto_tree_add_boolean(sub_tree, hf_sna_xid_3_dlus, tvb, 9, 1, val);
+	proto_tree_add_boolean(sub_tree, hf_sna_xid_3_exbn, tvb, 9, 1, val);
+	proto_tree_add_boolean(sub_tree, hf_sna_xid_3_genodai, tvb, 9, 1, val);
+	proto_tree_add_uint(sub_tree, hf_sna_xid_3_branch, tvb, 9, 1, val);
+	proto_tree_add_boolean(sub_tree, hf_sna_xid_3_brnn, tvb, 9, 1, val);
+
+	proto_tree_add_item(tree, hf_sna_xid_3_tg, tvb, 10, 1, FALSE);
+	proto_tree_add_item(tree, hf_sna_xid_3_dlc, tvb, 11, 1, FALSE);
+
+	dlen = tvb_get_guint8(tvb, 12);
+
+	proto_tree_add_uint(tree, hf_sna_xid_3_dlen, tvb, 12, 1, dlen);
+
+	/* FIXME: DLC Dependent Data Go Here */
+
+	offset = 12 + dlen;
+
+	while (tvb_offset_exists(tvb, offset)) {
+		dlen = tvb_get_guint8(tvb, offset+1);
+		dissect_control(tvb, offset, dlen+2, tree, 0, KL);
+		offset += (dlen+2);
+	}
+}
+
+static void
+dissect_xid(tvbuff_t *tvb, packet_info *pinfo, proto_tree *tree,
+    proto_tree *parent_tree)
+{
+	proto_tree	*sub_tree;
+	proto_item	*sub_ti = NULL;
+	int		format, type, len;
+	guint32		id;
+
+	len = tvb_get_guint8(tvb, 1);
+	type = tvb_get_guint8(tvb, 0);
+	id = tvb_get_ntohl(tvb, 2);
+	format = hi_nibble(type);
+
+	/* Summary information */
+	if (check_col(pinfo->cinfo, COL_INFO))
+		col_add_fstr(pinfo->cinfo, COL_INFO,
+		    "SNA XID Format:%d Type:%s", format,
+		    val_to_str(lo_nibble(type), sna_xid_type_vals,
+		    "Unknown Type"));
+
+	if (tree) {
+		sub_ti = proto_tree_add_item(tree, hf_sna_xid_0, tvb,
+		    0, 1, FALSE);
+		sub_tree = proto_item_add_subtree(sub_ti, ett_sna_xid_0);
+
+		proto_tree_add_uint(sub_tree, hf_sna_xid_format, tvb, 0, 1,
+		    type);
+		proto_tree_add_uint(sub_tree, hf_sna_xid_type, tvb, 0, 1,
+		    type);
+
+		proto_tree_add_uint(tree, hf_sna_xid_len, tvb, 1, 1, len);
+
+		sub_ti = proto_tree_add_item(tree, hf_sna_xid_id, tvb,
+		    2, 4, FALSE);
+		sub_tree = proto_item_add_subtree(sub_ti, ett_sna_xid_id);
+
+		proto_tree_add_uint(sub_tree, hf_sna_xid_idblock, tvb, 2, 4,
+		    id);
+		proto_tree_add_uint(sub_tree, hf_sna_xid_idnum, tvb, 2, 4,
+		    id);
+
+		switch(format) {
+			case 0:
+				break;
+			case 1:
+				dissect_xid1(tvb_new_subset(tvb, 6, len-6, -1),
+				    tree);
+				break;
+			case 2:
+				dissect_xid2(tvb_new_subset(tvb, 6, len-6, -1),
+				    tree);
+				break;
+			case 3:
+				dissect_xid3(tvb_new_subset(tvb, 6, len-6, -1),
+				    tree);
+				break;
+			default:
+				/* external standards organizations */
+				call_dissector(data_handle,
+				    tvb_new_subset(tvb, 6, len-6, -1),
+				    pinfo, tree);
+		}
+	}
+
+	if (format == 0)
+		len = 6;
+
+	if (tvb_offset_exists(tvb, len))
+		call_dissector(data_handle,
+		    tvb_new_subset(tvb, len, -1, -1), pinfo, parent_tree);
+}
+
+/* --------------------------------------------------------------------
+ * Chapter 4 Transmission Headers (THs)
+ * --------------------------------------------------------------------
+ */
+
+#define RH_LEN	3
+
+static unsigned int
+mpf_value(guint8 th_byte)
+{
+	return (th_byte & 0x0c) >> 2;
+}
+
+#define FIRST_FRAG_NUMBER	0
+#define MIDDLE_FRAG_NUMBER	1
+#define LAST_FRAG_NUMBER	2
+
+/* FID2 is defragged by sequence. The weird thing is that we have neither
+ * absolute sequence numbers, nor byte offets. Other FIDs have byte offsets
+ * (the DCF field), but not FID2. The only thing we have to go with is "FIRST",
+ * "MIDDLE", or "LAST". If the BIU is split into 3 frames, then everything is
+ * fine, * "FIRST", "MIDDLE", and "LAST" map nicely onto frag-number 0, 1,
+ * and 2. However, if the BIU is split into 2 frames, then we only have
+ * "FIRST" and "LAST", and the mapping *should* be frag-number 0 and 1,
+ * *NOT* 0 and 2.
+ *
+ * The SNA docs say "FID2 PIUs cannot be blocked because there is no DCF in the
+ * TH format for deblocking" (note on Figure 4-2 in the IBM SNA documention,
+ * see the FTP URL in the comment near the top of this file). I *think*
+ * this means that the fragmented frames cannot arrive out of order.
+ * Well, I *want* it to mean this, because w/o this limitation, if you
+ * get a "FIRST" frame and a "LAST" frame, how long should you wait to
+ * see if a "MIDDLE" frame every arrives????? Thus, if frames *have* to
+ * arrive in order, then we're saved.
+ *
+ * The problem then boils down to figuring out if "LAST" means frag-number 1
+ * (in the case of a BIU split into 2 frames) or frag-number 2
+ * (in the case of a BIU split into 3 frames).
+ *
+ * Assuming fragmented FID2 BIU frames *do* arrive in order, the obvious
+ * way to handle the mapping of "LAST" to either frag-number 1 or
+ * frag-number 2 is to keep a hash which tracks the frames seen, etc.
+ * This consumes resources. A trickier way, but a way which works, is to
+ * always map the "LAST" BIU segment to frag-number 2. Here's the trickery:
+ * if we add frag-number 2, which we know to be the "LAST" BIU segment,
+ * and the reassembly code tells us that the the BIU is still not reassmebled,
+ * then, owing to the, ahem, /fact/, that fragmented BIU segments arrive
+ * in order :), we know that 1) "FIRST" did come, and 2) there's no "MIDDLE",
+ * because this BIU was fragmented into 2 frames, not 3. So, we'll be
+ * tricky and add a zero-length "MIDDLE" BIU frame (i.e, frag-number 1)
+ * to complete the reassembly.
+ */
+static tvbuff_t*
+defragment_by_sequence(packet_info *pinfo, tvbuff_t *tvb, int offset, int mpf,
+    int id)
+{
+	fragment_data *fd_head;
+	int frag_number = -1;
+	int more_frags = TRUE;
+	tvbuff_t *rh_tvb = NULL;
+	gint frag_len;
+
+	/* Determine frag_number and more_frags */
+	switch(mpf) {
+		case MPF_WHOLE_BIU:
+			/* nothing */
+			break;
+		case MPF_FIRST_SEGMENT:
+			frag_number = FIRST_FRAG_NUMBER;
+			break;
+		case MPF_MIDDLE_SEGMENT:
+			frag_number = MIDDLE_FRAG_NUMBER;
+			break;
+		case MPF_LAST_SEGMENT:
+			frag_number = LAST_FRAG_NUMBER;
+			more_frags = FALSE;
+			break;
+		default:
+			g_assert_not_reached();
+	}
+
+	/* If sna_defragment is on, and this is a fragment.. */
+	if (frag_number > -1) {
+		/* XXX - check length ??? */
+		frag_len = tvb_reported_length_remaining(tvb, offset);
+		if (tvb_bytes_exist(tvb, offset, frag_len)) {
+			fd_head = fragment_add_seq(tvb, offset, pinfo, id,
+			    sna_fragment_table, frag_number, frag_len,
+			    more_frags);
+
+			/* We added the LAST segment and reassembly didn't
+			 * complete. Insert a zero-length MIDDLE segment to
+			 * turn a 2-frame BIU-fragmentation into a 3-frame
+			 * BIU-fragmentation (empty middle frag).
+		         * See above long comment about this trickery. */
+
+			if (mpf == MPF_LAST_SEGMENT && !fd_head) {
+				fd_head = fragment_add_seq(tvb, offset, pinfo,
+				    id, sna_fragment_table,
+				    MIDDLE_FRAG_NUMBER, 0, TRUE);
+			}
+
+			if (fd_head != NULL) {
+				/* We have the complete reassembled payload. */
+				rh_tvb = tvb_new_real_data(fd_head->data,
+				    fd_head->len, fd_head->len);
+
+				/* Add the tvbuff to the chain of tvbuffs
+				 * so that it will get cleaned up too. */
+				tvb_set_child_real_data_tvbuff(tvb, rh_tvb);
+
+				/* Add the defragmented data to the data
+				 * source list. */
+				add_new_data_source(pinfo, rh_tvb,
+				    "Reassembled SNA BIU");
+			}
+		}
+	}
+	return rh_tvb;
+}
+
+#define SNA_FID01_ADDR_LEN	2
+
+/* FID Types 0 and 1 */
+static int
+dissect_fid0_1(tvbuff_t *tvb, packet_info *pinfo, proto_tree *tree)
+{
+	proto_tree	*bf_tree;
+	proto_item	*bf_item;
+	guint8		th_0;
+	const guint8	*ptr;
+
+	const int bytes_in_header = 10;
+
+	if (tree) {
+		/* Byte 0 */
+		th_0 = tvb_get_guint8(tvb, 0);
+		bf_item = proto_tree_add_uint(tree, hf_sna_th_0, tvb, 0, 1,
+		    th_0);
+		bf_tree = proto_item_add_subtree(bf_item, ett_sna_th_fid);
+
+		proto_tree_add_uint(bf_tree, hf_sna_th_fid, tvb, 0, 1, th_0);
+		proto_tree_add_uint(bf_tree, hf_sna_th_mpf, tvb, 0, 1, th_0);
+		proto_tree_add_uint(bf_tree, hf_sna_th_efi, tvb, 0, 1, th_0);
+
+		/* Byte 1 */
+		proto_tree_add_text(tree, tvb, 1, 1, "Reserved");
+
+		/* Bytes 2-3 */
+		proto_tree_add_item(tree, hf_sna_th_daf, tvb, 2, 2, FALSE);
+	}
+
+	/* Set DST addr */
+	ptr = tvb_get_ptr(tvb, 2, SNA_FID01_ADDR_LEN);
+	SET_ADDRESS(&pinfo->net_dst, AT_SNA, SNA_FID01_ADDR_LEN, ptr);
+	SET_ADDRESS(&pinfo->dst, AT_SNA, SNA_FID01_ADDR_LEN, ptr);
+
+	if (tree)
+		proto_tree_add_item(tree, hf_sna_th_oaf, tvb, 4, 2, FALSE);
+
+	/* Set SRC addr */
+	ptr = tvb_get_ptr(tvb, 4, SNA_FID01_ADDR_LEN);
+	SET_ADDRESS(&pinfo->net_src, AT_SNA, SNA_FID01_ADDR_LEN, ptr);
+	SET_ADDRESS(&pinfo->src, AT_SNA, SNA_FID01_ADDR_LEN, ptr);
+
+	/* If we're not filling a proto_tree, return now */
+	if (tree)
+		return bytes_in_header;
+
+	proto_tree_add_item(tree, hf_sna_th_snf, tvb, 6, 2, FALSE);
+	proto_tree_add_item(tree, hf_sna_th_dcf, tvb, 8, 2, FALSE);
+
+	return bytes_in_header;
+}
+
+#define SNA_FID2_ADDR_LEN	1
+
+/* FID Type 2 */
+static int
+dissect_fid2(tvbuff_t *tvb, packet_info *pinfo, proto_tree *tree,
+        tvbuff_t **rh_tvb_ptr, next_dissection_t *continue_dissecting)
+{
+	proto_tree	*bf_tree;
+	proto_item	*bf_item;
+	guint8		th_0=0, daf=0, oaf=0;
+	const guint8	*ptr;
+	unsigned int	mpf, id;
+
+	const int bytes_in_header = 6;
+
+	th_0 = tvb_get_guint8(tvb, 0);
+	mpf = mpf_value(th_0);
+
+	if (tree) {
+		daf = tvb_get_guint8(tvb, 2);
+		oaf = tvb_get_guint8(tvb, 3);
+
+		/* Byte 0 */
+		bf_item = proto_tree_add_uint(tree, hf_sna_th_0, tvb, 0, 1,
+		    th_0);
+		bf_tree = proto_item_add_subtree(bf_item, ett_sna_th_fid);
+
+		proto_tree_add_uint(bf_tree, hf_sna_th_fid, tvb, 0, 1, th_0);
+		proto_tree_add_uint(bf_tree, hf_sna_th_mpf, tvb, 0, 1, th_0);
+		proto_tree_add_uint(bf_tree, hf_sna_th_odai,tvb, 0, 1, th_0);
+		proto_tree_add_uint(bf_tree, hf_sna_th_efi, tvb, 0, 1, th_0);
+
+
+		/* Byte 1 */
+		proto_tree_add_text(tree, tvb, 1, 1, "Reserved");
+
+		/* Byte 2 */
+		proto_tree_add_uint_format(tree, hf_sna_th_daf, tvb, 2, 1, daf,
+		    "Destination Address Field: 0x%02x", daf);
+	}
+
+	/* Set DST addr */
+	ptr = tvb_get_ptr(tvb, 2, SNA_FID2_ADDR_LEN);
+	SET_ADDRESS(&pinfo->net_dst, AT_SNA, SNA_FID2_ADDR_LEN, ptr);
+	SET_ADDRESS(&pinfo->dst, AT_SNA, SNA_FID2_ADDR_LEN, ptr);
+
+	if (tree) {
+		/* Byte 3 */
+		proto_tree_add_uint_format(tree, hf_sna_th_oaf, tvb, 3, 1, oaf,
+		    "Origin Address Field: 0x%02x", oaf);
+	}
+
+	/* Set SRC addr */
+	ptr = tvb_get_ptr(tvb, 3, SNA_FID2_ADDR_LEN);
+	SET_ADDRESS(&pinfo->net_src, AT_SNA, SNA_FID2_ADDR_LEN, ptr);
+	SET_ADDRESS(&pinfo->src, AT_SNA, SNA_FID2_ADDR_LEN, ptr);
+
+	id = tvb_get_ntohs(tvb, 4);
+	if (tree)
+		proto_tree_add_uint(tree, hf_sna_th_snf, tvb, 4, 2, id);
+
+	if (mpf != MPF_WHOLE_BIU && !sna_defragment) {
+		if (mpf == MPF_FIRST_SEGMENT) {
+			*continue_dissecting = rh_only;
+        	} else {
+			*continue_dissecting = stop_here;
+        	}
+
+    	}
+	else if (sna_defragment) {
+		*rh_tvb_ptr = defragment_by_sequence(pinfo, tvb,
+		    bytes_in_header, mpf, id);
+	}
+
+	return bytes_in_header;
+}
+
+/* FID Type 3 */
+static int
+dissect_fid3(tvbuff_t *tvb, proto_tree *tree)
+{
+	proto_tree	*bf_tree;
+	proto_item	*bf_item;
+	guint8		th_0;
+
+	const int bytes_in_header = 2;
+
+	/* If we're not filling a proto_tree, return now */
+	if (!tree)
+		return bytes_in_header;
+
+	th_0 = tvb_get_guint8(tvb, 0);
+
+	/* Create the bitfield tree */
+	bf_item = proto_tree_add_uint(tree, hf_sna_th_0, tvb, 0, 1, th_0);
+	bf_tree = proto_item_add_subtree(bf_item, ett_sna_th_fid);
+
+	proto_tree_add_uint(bf_tree, hf_sna_th_fid, tvb, 0, 1, th_0);
+	proto_tree_add_uint(bf_tree, hf_sna_th_mpf, tvb, 0, 1, th_0);
+	proto_tree_add_uint(bf_tree, hf_sna_th_efi, tvb, 0, 1, th_0);
+
+	proto_tree_add_item(tree, hf_sna_th_lsid, tvb, 1, 1, FALSE);
+
+	return bytes_in_header;
+}
+
+static int
+dissect_fid4(tvbuff_t *tvb, packet_info *pinfo, proto_tree *tree)
+{
+	proto_tree	*bf_tree;
+	proto_item	*bf_item;
+	int		offset = 0;
+	guint8		th_byte, mft;
+	guint16		th_word;
+	guint16		def, oef;
+	guint32		dsaf, osaf;
+	static struct sna_fid_type_4_addr src, dst;
+
+	const int bytes_in_header = 26;
+
+	/* If we're not filling a proto_tree, return now */
+	if (!tree)
+		return bytes_in_header;
+
+	th_byte = tvb_get_guint8(tvb, offset);
+
+	/* Create the bitfield tree */
+	bf_item = proto_tree_add_uint(tree, hf_sna_th_0, tvb, offset,
+	    1, th_byte);
+	bf_tree = proto_item_add_subtree(bf_item, ett_sna_th_fid);
+
+	/* Byte 0 */
+	proto_tree_add_uint(bf_tree, hf_sna_th_fid, tvb,
+	    offset, 1, th_byte);
+	proto_tree_add_uint(bf_tree, hf_sna_th_tg_sweep, tvb,
+	    offset, 1, th_byte);
+	proto_tree_add_uint(bf_tree, hf_sna_th_er_vr_supp_ind, tvb,
+	    offset, 1, th_byte);
+	proto_tree_add_uint(bf_tree, hf_sna_th_vr_pac_cnt_ind, tvb,
+	    offset, 1, th_byte);
+	proto_tree_add_uint(bf_tree, hf_sna_th_ntwk_prty, tvb,
+	    offset, 1, th_byte);
+
+	offset += 1;
+	th_byte = tvb_get_guint8(tvb, offset);
+
+	/* Create the bitfield tree */
+	bf_item = proto_tree_add_text(tree, tvb, offset, 1,
+	    "Transmision Header Byte 1");
+	bf_tree = proto_item_add_subtree(bf_item, ett_sna_th_fid);
+
+	/* Byte 1 */
+	proto_tree_add_uint(bf_tree, hf_sna_th_tgsf, tvb, offset, 1,
+	    th_byte);
+	proto_tree_add_boolean(bf_tree, hf_sna_th_mft, tvb, offset, 1,
+	    th_byte);
+	proto_tree_add_uint(bf_tree, hf_sna_th_piubf, tvb, offset, 1,
+	    th_byte);
+
+	mft = th_byte & 0x04;
+	offset += 1;
+	th_byte = tvb_get_guint8(tvb, offset);
+
+	/* Create the bitfield tree */
+	bf_item = proto_tree_add_text(tree, tvb, offset, 1,
+	    "Transmision Header Byte 2");
+	bf_tree = proto_item_add_subtree(bf_item, ett_sna_th_fid);
+
+	/* Byte 2 */
+	if (mft) {
+		proto_tree_add_uint(bf_tree, hf_sna_th_nlpoi, tvb,
+		    offset, 1, th_byte);
+		proto_tree_add_uint(bf_tree, hf_sna_th_nlp_cp, tvb,
+		    offset, 1, th_byte);
+	} else {
+		proto_tree_add_uint(bf_tree, hf_sna_th_iern, tvb,
+		    offset, 1, th_byte);
+	}
+	proto_tree_add_uint(bf_tree, hf_sna_th_ern, tvb, offset, 1,
+	    th_byte);
+
+	offset += 1;
+	th_byte = tvb_get_guint8(tvb, offset);
+
+	/* Create the bitfield tree */
+	bf_item = proto_tree_add_text(tree, tvb, offset, 1,
+	    "Transmision Header Byte 3");
+	bf_tree = proto_item_add_subtree(bf_item, ett_sna_th_fid);
+
+	/* Byte 3 */
+	proto_tree_add_uint(bf_tree, hf_sna_th_vrn, tvb, offset, 1,
+	    th_byte);
+	proto_tree_add_uint(bf_tree, hf_sna_th_tpf, tvb, offset, 1,
+	    th_byte);
+
+	offset += 1;
+	th_word = tvb_get_ntohs(tvb, offset);
+
+	/* Create the bitfield tree */
+	bf_item = proto_tree_add_text(tree, tvb, offset, 2,
+	    "Transmision Header Bytes 4-5");
+	bf_tree = proto_item_add_subtree(bf_item, ett_sna_th_fid);
+
+	/* Bytes 4-5 */
+	proto_tree_add_uint(bf_tree, hf_sna_th_vr_cwi, tvb,
+	    offset, 2, th_word);
+	proto_tree_add_boolean(bf_tree, hf_sna_th_tg_nonfifo_ind, tvb,
+	    offset, 2, th_word);
+	proto_tree_add_uint(bf_tree, hf_sna_th_vr_sqti, tvb,
+	    offset, 2, th_word);
+
+	/* I'm not sure about byte-order on this one... */
+	proto_tree_add_uint(bf_tree, hf_sna_th_tg_snf, tvb,
+	    offset, 2, th_word);
+
+	offset += 2;
+	th_word = tvb_get_ntohs(tvb, offset);
+
+	/* Create the bitfield tree */
+	bf_item = proto_tree_add_text(tree, tvb, offset, 2,
+	    "Transmision Header Bytes 6-7");
+	bf_tree = proto_item_add_subtree(bf_item, ett_sna_th_fid);
+
+	/* Bytes 6-7 */
+	proto_tree_add_boolean(bf_tree, hf_sna_th_vrprq, tvb, offset,
+	    2, th_word);
+	proto_tree_add_boolean(bf_tree, hf_sna_th_vrprs, tvb, offset,
+	    2, th_word);
+	proto_tree_add_uint(bf_tree, hf_sna_th_vr_cwri, tvb, offset,
+	    2, th_word);
+	proto_tree_add_boolean(bf_tree, hf_sna_th_vr_rwi, tvb, offset,
+	    2, th_word);
+
+	/* I'm not sure about byte-order on this one... */
+	proto_tree_add_uint(bf_tree, hf_sna_th_vr_snf_send, tvb,
+	    offset, 2, th_word);
+
+	offset += 2;
+
+	dsaf = tvb_get_ntohl(tvb, 8);
+	/* Bytes 8-11 */
+	proto_tree_add_uint(tree, hf_sna_th_dsaf, tvb, offset, 4, dsaf);
+
+	offset += 4;
+
+	osaf = tvb_get_ntohl(tvb, 12);
+	/* Bytes 12-15 */
+	proto_tree_add_uint(tree, hf_sna_th_osaf, tvb, offset, 4, osaf);
+
+	offset += 4;
+	th_byte = tvb_get_guint8(tvb, offset);
+
+	/* Create the bitfield tree */
+	bf_item = proto_tree_add_text(tree, tvb, offset, 2,
+	    "Transmision Header Byte 16");
+	bf_tree = proto_item_add_subtree(bf_item, ett_sna_th_fid);
+
+	/* Byte 16 */
+	proto_tree_add_boolean(tree, hf_sna_th_snai, tvb, offset, 1, th_byte);
+
+	/* We luck out here because in their infinite wisdom the SNA
+	 * architects placed the MPF and EFI fields in the same bitfield
+	 * locations, even though for FID4 they're not in byte 0.
+	 * Thank you IBM! */
+	proto_tree_add_uint(tree, hf_sna_th_mpf, tvb, offset, 1, th_byte);
+	proto_tree_add_uint(tree, hf_sna_th_efi, tvb, offset, 1, th_byte);
+
+	offset += 2;
+	/* 1 for byte 16, 1 for byte 17 which is reserved */
+
+	def = tvb_get_ntohs(tvb, 18);
+	/* Bytes 18-25 */
+	proto_tree_add_uint(tree, hf_sna_th_def, tvb, offset, 2, def);
+
+	/* Addresses in FID 4 are discontiguous, sigh */
+	dst.saf = dsaf;
+	dst.ef = def;
+	SET_ADDRESS(&pinfo->net_dst, AT_SNA, SNA_FID_TYPE_4_ADDR_LEN,
+	    (guint8* )&dst);
+	SET_ADDRESS(&pinfo->dst, AT_SNA, SNA_FID_TYPE_4_ADDR_LEN,
+	    (guint8 *)&dst);
+
+	oef = tvb_get_ntohs(tvb, 20);
+	proto_tree_add_uint(tree, hf_sna_th_oef, tvb, offset+2, 2, oef);
+
+	/* Addresses in FID 4 are discontiguous, sigh */
+	src.saf = osaf;
+	src.ef = oef;
+	SET_ADDRESS(&pinfo->net_src, AT_SNA, SNA_FID_TYPE_4_ADDR_LEN,
+	    (guint8 *)&src);
+	SET_ADDRESS(&pinfo->src, AT_SNA, SNA_FID_TYPE_4_ADDR_LEN,
+	    (guint8 *)&src);
+
+	proto_tree_add_item(tree, hf_sna_th_snf, tvb, offset+4, 2, FALSE);
+	proto_tree_add_item(tree, hf_sna_th_dcf, tvb, offset+6, 2, FALSE);
+
+	return bytes_in_header;
+}
+
+/* FID Type 5 */
+static int
+dissect_fid5(tvbuff_t *tvb, proto_tree *tree)
+{
+	proto_tree	*bf_tree;
+	proto_item	*bf_item;
+	guint8		th_0;
+
+	const int bytes_in_header = 12;
+
+	/* If we're not filling a proto_tree, return now */
+	if (!tree)
+		return bytes_in_header;
+
+	th_0 = tvb_get_guint8(tvb, 0);
+
+	/* Create the bitfield tree */
+	bf_item = proto_tree_add_uint(tree, hf_sna_th_0, tvb, 0, 1, th_0);
+	bf_tree = proto_item_add_subtree(bf_item, ett_sna_th_fid);
+
+	proto_tree_add_uint(bf_tree, hf_sna_th_fid, tvb, 0, 1, th_0);
+	proto_tree_add_uint(bf_tree, hf_sna_th_mpf, tvb, 0, 1, th_0);
+	proto_tree_add_uint(bf_tree, hf_sna_th_efi, tvb, 0, 1, th_0);
+
+	proto_tree_add_text(tree, tvb, 1, 1, "Reserved");
+	proto_tree_add_item(tree, hf_sna_th_snf, tvb, 2, 2, FALSE);
+
+	proto_tree_add_item(tree, hf_sna_th_sa, tvb, 4, 8, FALSE);
+
+	return bytes_in_header;
+
+}
+
+/* FID Type f */
+static int
+dissect_fidf(tvbuff_t *tvb, proto_tree *tree)
+{
+	proto_tree	*bf_tree;
+	proto_item	*bf_item;
+	guint8		th_0;
+
+	const int bytes_in_header = 26;
+
+	/* If we're not filling a proto_tree, return now */
+	if (!tree)
+		return bytes_in_header;
+
+	th_0 = tvb_get_guint8(tvb, 0);
+
+	/* Create the bitfield tree */
+	bf_item = proto_tree_add_uint(tree, hf_sna_th_0, tvb, 0, 1, th_0);
+	bf_tree = proto_item_add_subtree(bf_item, ett_sna_th_fid);
+
+	proto_tree_add_uint(bf_tree, hf_sna_th_fid, tvb, 0, 1, th_0);
+	proto_tree_add_text(tree, tvb, 1, 1, "Reserved");
+
+	proto_tree_add_item(tree, hf_sna_th_cmd_fmt, tvb,  2, 1, FALSE);
+	proto_tree_add_item(tree, hf_sna_th_cmd_type, tvb, 3, 1, FALSE);
+	proto_tree_add_item(tree, hf_sna_th_cmd_sn, tvb,   4, 2, FALSE);
+
+	/* Yup, bytes 6-23 are reserved! */
+	proto_tree_add_text(tree, tvb, 6, 18, "Reserved");
+
+	proto_tree_add_item(tree, hf_sna_th_dcf, tvb, 24, 2, FALSE);
+
+	return bytes_in_header;
+}
+
+static void
+dissect_fid(tvbuff_t *tvb, packet_info *pinfo, proto_tree *tree,
+    proto_tree *parent_tree)
+{
+
+	proto_tree	*th_tree = NULL, *rh_tree = NULL;
+	proto_item	*th_ti = NULL, *rh_ti = NULL;
+	guint8		th_fid;
+	int		th_header_len = 0;
+	int		offset, rh_offset;
+	tvbuff_t	*rh_tvb = NULL;
+	next_dissection_t continue_dissecting = everything;
+
+	/* Transmission Header Format Identifier */
+	th_fid = hi_nibble(tvb_get_guint8(tvb, 0));
+
+	/* Summary information */
+	if (check_col(pinfo->cinfo, COL_INFO))
+		col_add_str(pinfo->cinfo, COL_INFO,
+		    val_to_str(th_fid, sna_th_fid_vals, "Unknown FID: %01x"));
+
+	if (tree) {
+		/* --- TH --- */
+		/* Don't bother setting length. We'll set it later after we
+		 * find the length of TH */
+		th_ti = proto_tree_add_item(tree, hf_sna_th, tvb,  0, -1,
+		    FALSE);
+		th_tree = proto_item_add_subtree(th_ti, ett_sna_th);
+	}
+
+	/* Get size of TH */
+	switch(th_fid) {
+		case 0x0:
+		case 0x1:
+			th_header_len = dissect_fid0_1(tvb, pinfo, th_tree);
+			break;
+		case 0x2:
+			th_header_len = dissect_fid2(tvb, pinfo, th_tree,
+			    &rh_tvb, &continue_dissecting);
+			break;
+		case 0x3:
+			th_header_len = dissect_fid3(tvb, th_tree);
+			break;
+		case 0x4:
+			th_header_len = dissect_fid4(tvb, pinfo, th_tree);
+			break;
+		case 0x5:
+			th_header_len = dissect_fid5(tvb, th_tree);
+			break;
+		case 0xf:
+			th_header_len = dissect_fidf(tvb, th_tree);
+			break;
+		default:
+			call_dissector(data_handle,
+			    tvb_new_subset(tvb, 1, -1, -1), pinfo, parent_tree);
+			return;
+	}
+
+	offset = th_header_len;
+
+	/* Short-circuit ? */
+	if (continue_dissecting == stop_here) {
+		if (tree) {
+			proto_tree_add_text(tree, tvb, offset, -1,
+			    "BIU segment data");
+		}
+		return;
+	}
+
+	/* If the FID dissector function didn't create an rh_tvb, then we just
+	 * use the rest of our tvbuff as the rh_tvb. */
+	if (!rh_tvb)
+		rh_tvb = tvb_new_subset(tvb, offset, -1, -1);
+	rh_offset = 0;
+
+	/* Process the rest of the SNA packet, starting with RH */
+	if (tree) {
+		proto_item_set_len(th_ti, th_header_len);
+
+		/* --- RH --- */
+		rh_ti = proto_tree_add_item(tree, hf_sna_rh, rh_tvb, rh_offset,
+		    RH_LEN, FALSE);
+		rh_tree = proto_item_add_subtree(rh_ti, ett_sna_rh);
+		dissect_rh(rh_tvb, rh_offset, rh_tree);
+	}
+
+	rh_offset += RH_LEN;
+
+	if (tvb_offset_exists(rh_tvb, rh_offset)) {
+		/* Short-circuit ? */
+		if (continue_dissecting == rh_only) {
+			if (tree)
+				proto_tree_add_text(tree, rh_tvb, rh_offset, -1,
+				    "BIU segment data");
+			return;
+        	}
+
+		call_dissector(data_handle, 
+		    tvb_new_subset(rh_tvb, rh_offset, -1, -1), 
+		    pinfo, parent_tree);
+	}
+}
+
+/* --------------------------------------------------------------------
+ * Chapter 5 Request/Response Headers (RHs)
+ * --------------------------------------------------------------------
+ */
+
+static void
+dissect_rh(tvbuff_t *tvb, int offset, proto_tree *tree)
+{
+	proto_tree	*bf_tree;
+	proto_item	*bf_item;
+	gboolean	is_response;
+	guint8		rh_0, rh_1, rh_2;
+
+	if (!tree)
+		return;
+
+	/* Create the bitfield tree for byte 0*/
+	rh_0 = tvb_get_guint8(tvb, offset);
+	is_response = (rh_0 & 0x80);
+
+	bf_item = proto_tree_add_uint(tree, hf_sna_rh_0, tvb, offset, 1, rh_0);
+	bf_tree = proto_item_add_subtree(bf_item, ett_sna_rh_0);
+
+	proto_tree_add_uint(bf_tree, hf_sna_rh_rri, tvb, offset, 1, rh_0);
+	proto_tree_add_uint(bf_tree, hf_sna_rh_ru_category, tvb, offset, 1,
+	    rh_0);
+	proto_tree_add_boolean(bf_tree, hf_sna_rh_fi, tvb, offset, 1, rh_0);
+	proto_tree_add_boolean(bf_tree, hf_sna_rh_sdi, tvb, offset, 1, rh_0);
+	proto_tree_add_boolean(bf_tree, hf_sna_rh_bci, tvb, offset, 1, rh_0);
+	proto_tree_add_boolean(bf_tree, hf_sna_rh_eci, tvb, offset, 1, rh_0);
+
+	offset += 1;
+	rh_1 = tvb_get_guint8(tvb, offset);
+
+	/* Create the bitfield tree for byte 1*/
+	bf_item = proto_tree_add_uint(tree, hf_sna_rh_1, tvb, offset, 1, rh_1);
+	bf_tree = proto_item_add_subtree(bf_item, ett_sna_rh_1);
+
+	proto_tree_add_boolean(bf_tree, hf_sna_rh_dr1, tvb,  offset, 1, rh_1);
+
+	if (!is_response)
+		proto_tree_add_boolean(bf_tree, hf_sna_rh_lcci, tvb, offset, 1,
+		    rh_1);
+
+	proto_tree_add_boolean(bf_tree, hf_sna_rh_dr2, tvb,  offset, 1, rh_1);
+
+	if (is_response) {
+		proto_tree_add_boolean(bf_tree, hf_sna_rh_rti, tvb,  offset, 1,
+		    rh_1);
+	} else {
+		proto_tree_add_boolean(bf_tree, hf_sna_rh_eri, tvb,  offset, 1,
+		    rh_1);
+		proto_tree_add_boolean(bf_tree, hf_sna_rh_rlwi, tvb, offset, 1,
+		    rh_1);
+	}
+
+	proto_tree_add_boolean(bf_tree, hf_sna_rh_qri, tvb, offset, 1, rh_1);
+	proto_tree_add_boolean(bf_tree, hf_sna_rh_pi, tvb,  offset, 1, rh_1);
+
+	offset += 1;
+	rh_2 = tvb_get_guint8(tvb, offset);
+
+	/* Create the bitfield tree for byte 2*/
+	bf_item = proto_tree_add_uint(tree, hf_sna_rh_2, tvb, offset, 1, rh_2);
+
+	if (!is_response) {
+		bf_tree = proto_item_add_subtree(bf_item, ett_sna_rh_2);
+
+		proto_tree_add_boolean(bf_tree, hf_sna_rh_bbi, tvb,  offset, 1,
+		    rh_2);
+		proto_tree_add_boolean(bf_tree, hf_sna_rh_ebi, tvb,  offset, 1,
+		    rh_2);
+		proto_tree_add_boolean(bf_tree, hf_sna_rh_cdi, tvb,  offset, 1,
+		    rh_2);
+		proto_tree_add_uint(bf_tree, hf_sna_rh_csi, tvb,  offset, 1,
+		    rh_2);
+		proto_tree_add_boolean(bf_tree, hf_sna_rh_edi, tvb,  offset, 1,
+		    rh_2);
+		proto_tree_add_boolean(bf_tree, hf_sna_rh_pdi, tvb,  offset, 1,
+		    rh_2);
+		proto_tree_add_boolean(bf_tree, hf_sna_rh_cebi, tvb, offset, 1,
+		    rh_2);
+	}
+
+	/* XXX - check for sdi. If TRUE, the next 4 bytes will be sense data */
+}
+
+/* --------------------------------------------------------------------
+ * Chapter 6 Request/Response Units (RUs)
+ * --------------------------------------------------------------------
+ */
+
+/* --------------------------------------------------------------------
+ * Chapter 9 Common Fields
+ * --------------------------------------------------------------------
+ */
+
+static void
+dissect_control_05hpr(tvbuff_t *tvb, proto_tree *tree, int hpr,
+    enum parse parse)
+{
+	proto_tree	*bf_tree;
+	proto_item	*bf_item;
+	guint8		type;
+	guint16		offset, len, pad;
+
+	if (!tree)
+		return;
+
+	type = tvb_get_guint8(tvb, 2);
+
+	bf_item = proto_tree_add_uint(tree, hf_sna_control_05_type, tvb,
+	    2, 1, type);
+	bf_tree = proto_item_add_subtree(bf_item, ett_sna_control_05hpr_type);
+
+	proto_tree_add_boolean(bf_tree, hf_sna_control_05_ptp, tvb, 2, 1, type);
+	proto_tree_add_text(tree, tvb, 3, 1, "Reserved");
+
+	offset = 4;
+
+	while (tvb_offset_exists(tvb, offset)) {
+		if (parse == LT) {
+			len = tvb_get_guint8(tvb, offset+0);
+		} else {
+			len = tvb_get_guint8(tvb, offset+1);
+		}
+		if (len) {
+			dissect_control(tvb, offset, len, tree, hpr, parse);
+			pad = (len+3) & 0xfffc;
+			if (pad > len)
+				proto_tree_add_text(tree, tvb, offset+len,
+				    pad-len, "Padding");
+			offset += pad;
+		} else {
+			return;
+		}
+	}
+}
+
+static void
+dissect_control_05(tvbuff_t *tvb, proto_tree *tree)
+{
+	if(!tree)
+		return;
+
+	proto_tree_add_item(tree, hf_sna_control_05_delay, tvb, 2, 2, FALSE);
+}
+
+static void
+dissect_control_0e(tvbuff_t *tvb, proto_tree *tree)
+{
+	gint	len;
+	guint8	*buf;
+
+	if (!tree)
+		return;
+
+	proto_tree_add_item(tree, hf_sna_control_0e_type, tvb, 2, 1, FALSE);
+
+	len = tvb_reported_length_remaining(tvb, 3);
+	if (len <= 0)
+		return;
+
+	buf = tvb_get_string(tvb, 3, len);
+	EBCDIC_to_ASCII(buf, len);
+	proto_tree_add_string(tree, hf_sna_control_0e_value, tvb, 3, len, buf);
+	g_free(buf);
+}
+
+static void
+dissect_control(tvbuff_t *parent_tvb, int offset, int control_len,
+    proto_tree *tree, int hpr, enum parse parse)
+{
+	tvbuff_t	*tvb;
+	gint		length, reported_length;
+	proto_tree	*sub_tree;
+	proto_item	*sub_item;
+	int		len, key;
+	gint		ett;
+
+	length = tvb_length_remaining(parent_tvb, offset);
+	reported_length = tvb_reported_length_remaining(parent_tvb, offset);
+	if (control_len < length)
+		length = control_len;
+	if (control_len < reported_length)
+		reported_length = control_len;
+	tvb = tvb_new_subset(parent_tvb, offset, length, reported_length);
+
+	sub_tree = NULL;
+
+	if (parse == LT) {
+		len = tvb_get_guint8(tvb, 0);
+		key = tvb_get_guint8(tvb, 1);
+	} else {
+		key = tvb_get_guint8(tvb, 0);
+		len = tvb_get_guint8(tvb, 1);
+	}
+	ett = ett_sna_control_un;
+
+	if (tree) {
+		if (key == 5) {
+			 if (hpr) ett = ett_sna_control_05hpr;
+			 else ett = ett_sna_control_05;
+		}
+		if (key == 0x0e) ett = ett_sna_control_0e;
+
+		if (((key == 0) || (key == 3) || (key == 5)) && hpr)
+			sub_item = proto_tree_add_text(tree, tvb, 0, -1,
+			    val_to_str(key, sna_control_hpr_vals,
+			    "Unknown Control Vector"));
+		else
+			sub_item = proto_tree_add_text(tree, tvb, 0, -1,
+			    val_to_str(key, sna_control_vals,
+			    "Unknown Control Vector"));
+		sub_tree = proto_item_add_subtree(sub_item, ett);
+		if (parse == LT) {
+			proto_tree_add_uint(sub_tree, hf_sna_control_len,
+			    tvb, 0, 1, len);
+			if (((key == 0) || (key == 3) || (key == 5)) && hpr)
+				proto_tree_add_uint(sub_tree,
+				    hf_sna_control_hprkey, tvb, 1, 1, key);
+			else
+				proto_tree_add_uint(sub_tree,
+				    hf_sna_control_key, tvb, 1, 1, key);
+		} else {
+			if (((key == 0) || (key == 3) || (key == 5)) && hpr)
+				proto_tree_add_uint(sub_tree,
+				    hf_sna_control_hprkey, tvb, 0, 1, key);
+			else
+				proto_tree_add_uint(sub_tree,
+				    hf_sna_control_key, tvb, 0, 1, key);
+			proto_tree_add_uint(sub_tree, hf_sna_control_len,
+			    tvb, 1, 1, len);
+		}
+	}
+	switch(key) {
+		case 0x05:
+			if (hpr)
+				dissect_control_05hpr(tvb, sub_tree, hpr,
+				    parse);
+			else
+				dissect_control_05(tvb, sub_tree);
+			break;
+		case 0x0e:
+			dissect_control_0e(tvb, sub_tree);
+			break;
+	}
+}
+
+/* --------------------------------------------------------------------
+ * Chapter 11 Function Management (FM) Headers
+ * --------------------------------------------------------------------
+ */
+
+/* --------------------------------------------------------------------
+ * Chapter 12 Presentation Services (PS) Headers
+ * --------------------------------------------------------------------
+ */
+
+/* --------------------------------------------------------------------
+ * Chapter 13 GDS Variables
+ * --------------------------------------------------------------------
+ */
+
+static void
+dissect_gds(tvbuff_t *tvb, packet_info *pinfo, proto_tree *tree, 
+    proto_tree *parent_tree)
+{
+	guint16		length;
+	guint16		type;
+	int		cont;
+	int		offset;
+	proto_tree	*gds_tree;
+	proto_item	*gds_item;
+
+	offset = 0;
+	cont   = 1;
+	type   = tvb_get_ntohs(tvb, offset+2);
+
+	while (cont) {
+		length = tvb_get_ntohs(tvb, offset) & 0x7fff;
+		cont   = (tvb_get_ntohs(tvb, offset) & 0x8000) ? 1 : 0;
+		type   = tvb_get_ntohs(tvb, offset+2);
+
+		if (length < 2 ) /* escape sequence ? */
+			return;
+		if (tree) {
+			gds_item = proto_tree_add_item(tree, hf_sna_gds, tvb,
+			    offset, length, FALSE);
+			gds_tree = proto_item_add_subtree(gds_item,
+			    ett_sna_gds);
+
+			proto_tree_add_uint(gds_tree, hf_sna_gds_len, tvb,
+			    offset, 2, length);
+			proto_tree_add_boolean(gds_tree, hf_sna_gds_cont, tvb,
+			    offset, 2, cont);
+			proto_tree_add_uint(gds_tree, hf_sna_gds_type, tvb,
+			    offset+2, 2, type);
+		}
+		offset += length;
+	}
+	if (tvb_offset_exists(tvb, offset))
+		call_dissector(data_handle,
+		    tvb_new_subset(tvb, offset, -1, -1), pinfo, parent_tree);
+}
+
+/* --------------------------------------------------------------------
+ * General stuff
+ * --------------------------------------------------------------------
+ */
+
+static void
+dissect_sna(tvbuff_t *tvb, packet_info *pinfo, proto_tree *tree)
+{
+	guint8		fid;
+	proto_tree	*sna_tree = NULL;
+	proto_item	*sna_ti = NULL;
+
+	if (check_col(pinfo->cinfo, COL_PROTOCOL))
+		col_set_str(pinfo->cinfo, COL_PROTOCOL, "SNA");
+	if (check_col(pinfo->cinfo, COL_INFO))
+		col_clear(pinfo->cinfo, COL_INFO);
+
+	/* SNA data should be printed in EBCDIC, not ASCII */
+	pinfo->fd->flags.encoding = CHAR_EBCDIC;
+
+	if (tree) {
+
+		/* Don't bother setting length. We'll set it later after we find
+		 * the lengths of TH/RH/RU */
+		sna_ti = proto_tree_add_item(tree, proto_sna, tvb, 0, -1,
+		    FALSE);
+		sna_tree = proto_item_add_subtree(sna_ti, ett_sna);
+	}
+
+	/* Transmission Header Format Identifier */
+	fid = hi_nibble(tvb_get_guint8(tvb, 0));
+	switch(fid) {
+		case 0xa:	/* HPR Network Layer Packet */
+		case 0xb:
+		case 0xc:
+		case 0xd:
+			dissect_nlp(tvb, pinfo, sna_tree, tree);
+			break;
+		default:
+			dissect_fid(tvb, pinfo, sna_tree, tree);
+	}
+}
+
+static void
+dissect_sna_xid(tvbuff_t *tvb, packet_info *pinfo, proto_tree *tree)
+{
+	proto_tree	*sna_tree = NULL;
+	proto_item	*sna_ti = NULL;
+
+	if (check_col(pinfo->cinfo, COL_PROTOCOL))
+		col_set_str(pinfo->cinfo, COL_PROTOCOL, "SNA");
+	if (check_col(pinfo->cinfo, COL_INFO))
+		col_clear(pinfo->cinfo, COL_INFO);
+
+	/* SNA data should be printed in EBCDIC, not ASCII */
+	pinfo->fd->flags.encoding = CHAR_EBCDIC;
+
+	if (tree) {
+
+		/* Don't bother setting length. We'll set it later after we find
+		 * the lengths of XID */
+		sna_ti = proto_tree_add_item(tree, proto_sna_xid, tvb, 0, -1,
+		    FALSE);
+		sna_tree = proto_item_add_subtree(sna_ti, ett_sna);
+	}
+	dissect_xid(tvb, pinfo, sna_tree, tree);
+}
+
+static void
+sna_init(void)
+{
+	fragment_table_init(&sna_fragment_table);
+	reassembled_table_init(&sna_reassembled_table);
+}
+
+
+void
+proto_register_sna(void)
+{
+        static hf_register_info hf[] = {
+                { &hf_sna_th,
+                { "Transmission Header", "sna.th", FT_NONE, BASE_NONE,
+		     NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_th_0,
+                { "Transmission Header Byte 0", "sna.th.0", FT_UINT8, BASE_HEX,
+		    NULL, 0x0,
+		    "TH Byte 0", HFILL }},
+
+                { &hf_sna_th_fid,
+                { "Format Identifer", "sna.th.fid", FT_UINT8, BASE_HEX,
+		    VALS(sna_th_fid_vals), 0xf0, "", HFILL }},
+
+                { &hf_sna_th_mpf,
+                { "Mapping Field", "sna.th.mpf", FT_UINT8,
+		    BASE_DEC, VALS(sna_th_mpf_vals), 0x0c, "", HFILL }},
+
+		{ &hf_sna_th_odai,
+		{ "ODAI Assignment Indicator", "sna.th.odai", FT_UINT8,
+		    BASE_DEC, NULL, 0x02, "", HFILL }},
+
+                { &hf_sna_th_efi,
+                { "Expedited Flow Indicator", "sna.th.efi", FT_UINT8,
+		    BASE_DEC, VALS(sna_th_efi_vals), 0x01, "", HFILL }},
+
+                { &hf_sna_th_daf,
+                { "Destination Address Field", "sna.th.daf", FT_UINT16,
+		    BASE_HEX, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_th_oaf,
+                { "Origin Address Field", "sna.th.oaf", FT_UINT16, BASE_HEX,
+		    NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_th_snf,
+                { "Sequence Number Field", "sna.th.snf", FT_UINT16, BASE_DEC,
+		    NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_th_dcf,
+                { "Data Count Field", "sna.th.dcf", FT_UINT16, BASE_DEC,
+		    NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_th_lsid,
+                { "Local Session Identification", "sna.th.lsid", FT_UINT8,
+		    BASE_HEX, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_th_tg_sweep,
+                { "Transmission Group Sweep", "sna.th.tg_sweep", FT_UINT8,
+		    BASE_DEC, VALS(sna_th_tg_sweep_vals), 0x08, "", HFILL }},
+
+                { &hf_sna_th_er_vr_supp_ind,
+                { "ER and VR Support Indicator", "sna.th.er_vr_supp_ind",
+		    FT_UINT8, BASE_DEC, VALS(sna_th_er_vr_supp_ind_vals),
+		    0x04, "", HFILL }},
+
+                { &hf_sna_th_vr_pac_cnt_ind,
+                { "Virtual Route Pacing Count Indicator",
+		    "sna.th.vr_pac_cnt_ind", FT_UINT8, BASE_DEC,
+		    VALS(sna_th_vr_pac_cnt_ind_vals), 0x02, "", HFILL }},
+
+                { &hf_sna_th_ntwk_prty,
+                { "Network Priority", "sna.th.ntwk_prty", FT_UINT8, BASE_DEC,
+		    VALS(sna_th_ntwk_prty_vals), 0x01, "", HFILL }},
+
+                { &hf_sna_th_tgsf,
+                { "Transmission Group Segmenting Field", "sna.th.tgsf",
+		    FT_UINT8, BASE_HEX, VALS(sna_th_tgsf_vals), 0xc0,
+		    "", HFILL }},
+
+                { &hf_sna_th_mft,
+                { "MPR FID4 Type", "sna.th.mft", FT_BOOLEAN, BASE_NONE,
+		    NULL, 0x04, "", HFILL }},
+
+                { &hf_sna_th_piubf,
+                { "PIU Blocking Field", "sna.th.piubf", FT_UINT8, BASE_HEX,
+		    VALS(sna_th_piubf_vals), 0x03, "", HFILL }},
+
+                { &hf_sna_th_iern,
+                { "Initial Explicit Route Number", "sna.th.iern", FT_UINT8,
+		    BASE_DEC, NULL, 0xf0, "", HFILL }},
+
+                { &hf_sna_th_nlpoi,
+                { "NLP Offset Indicator", "sna.th.nlpoi", FT_UINT8, BASE_DEC,
+		    VALS(sna_th_nlpoi_vals), 0x80, "", HFILL }},
+
+                { &hf_sna_th_nlp_cp,
+                { "NLP Count or Padding", "sna.th.nlp_cp", FT_UINT8, BASE_DEC,
+		    NULL, 0x70, "", HFILL }},
+
+                { &hf_sna_th_ern,
+                { "Explicit Route Number", "sna.th.ern", FT_UINT8, BASE_DEC,
+		    NULL, 0x0f, "", HFILL }},
+
+                { &hf_sna_th_vrn,
+                { "Virtual Route Number", "sna.th.vrn", FT_UINT8, BASE_DEC,
+		    NULL, 0xf0, "", HFILL }},
+
+                { &hf_sna_th_tpf,
+                { "Transmission Priority Field", "sna.th.tpf", FT_UINT8,
+		    BASE_HEX, VALS(sna_th_tpf_vals), 0x03, "", HFILL }},
+
+                { &hf_sna_th_vr_cwi,
+                { "Virtual Route Change Window Indicator", "sna.th.vr_cwi",
+		    FT_UINT16, BASE_DEC, VALS(sna_th_vr_cwi_vals), 0x8000,
+		    "Change Window Indicator", HFILL }},
+
+                { &hf_sna_th_tg_nonfifo_ind,
+                { "Transmission Group Non-FIFO Indicator",
+		    "sna.th.tg_nonfifo_ind", FT_BOOLEAN, 16,
+		    TFS(&sna_th_tg_nonfifo_ind_truth), 0x4000, "", HFILL }},
+
+                { &hf_sna_th_vr_sqti,
+                { "Virtual Route Sequence and Type Indicator", "sna.th.vr_sqti",
+		    FT_UINT16, BASE_HEX, VALS(sna_th_vr_sqti_vals), 0x3000,
+		    "Route Sequence and Type", HFILL }},
+
+                { &hf_sna_th_tg_snf,
+                { "Transmission Group Sequence Number Field", "sna.th.tg_snf",
+		    FT_UINT16, BASE_DEC, NULL, 0x0fff, "", HFILL }},
+
+                { &hf_sna_th_vrprq,
+                { "Virtual Route Pacing Request", "sna.th.vrprq", FT_BOOLEAN,
+		    16, TFS(&sna_th_vrprq_truth), 0x8000, "", HFILL }},
+
+                { &hf_sna_th_vrprs,
+                { "Virtual Route Pacing Response", "sna.th.vrprs", FT_BOOLEAN,
+		    16, TFS(&sna_th_vrprs_truth), 0x4000, "", HFILL }},
+
+                { &hf_sna_th_vr_cwri,
+                { "Virtual Route Change Window Reply Indicator",
+		    "sna.th.vr_cwri", FT_UINT16, BASE_DEC,
+		    VALS(sna_th_vr_cwri_vals), 0x2000, "", HFILL }},
+
+                { &hf_sna_th_vr_rwi,
+                { "Virtual Route Reset Window Indicator", "sna.th.vr_rwi",
+		    FT_BOOLEAN, 16, TFS(&sna_th_vr_rwi_truth), 0x1000,
+		    "", HFILL }},
+
+                { &hf_sna_th_vr_snf_send,
+                { "Virtual Route Send Sequence Number Field",
+		    "sna.th.vr_snf_send", FT_UINT16, BASE_DEC, NULL, 0x0fff,
+		    "Send Sequence Number Field", HFILL }},
+
+                { &hf_sna_th_dsaf,
+                { "Destination Subarea Address Field", "sna.th.dsaf",
+		    FT_UINT32, BASE_HEX, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_th_osaf,
+                { "Origin Subarea Address Field", "sna.th.osaf", FT_UINT32,
+		    BASE_HEX, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_th_snai,
+                { "SNA Indicator", "sna.th.snai", FT_BOOLEAN, 8, NULL, 0x10,
+		    "Used to identify whether the PIU originated or is destined"
+		    " for an SNA or non-SNA device.", HFILL }},
+
+                { &hf_sna_th_def,
+                { "Destination Element Field", "sna.th.def", FT_UINT16,
+		    BASE_HEX, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_th_oef,
+                { "Origin Element Field", "sna.th.oef", FT_UINT16, BASE_HEX,
+		    NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_th_sa,
+                { "Session Address", "sna.th.sa", FT_BYTES, BASE_HEX,
+		    NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_th_cmd_fmt,
+                { "Command Format", "sna.th.cmd_fmt", FT_UINT8, BASE_HEX,
+		    NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_th_cmd_type,
+                { "Command Type", "sna.th.cmd_type", FT_UINT8, BASE_HEX,
+		    NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_th_cmd_sn,
+                { "Command Sequence Number", "sna.th.cmd_sn", FT_UINT16,
+		    BASE_DEC, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_nlp_nhdr,
+                { "Network Layer Packet Header", "sna.nlp.nhdr", FT_NONE,
+		    BASE_NONE, NULL, 0x0, "NHDR", HFILL }},
+
+                { &hf_sna_nlp_nhdr_0,
+                { "Network Layer Packet Header Byte 0",	"sna.nlp.nhdr.0",
+		    FT_UINT8, BASE_HEX, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_nlp_nhdr_1,
+                { "Network Layer Packet Header Byte 1", "sna.nlp.nhdr.1",
+		    FT_UINT8, BASE_HEX, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_nlp_sm,
+                { "Switching Mode Field", "sna.nlp.nhdr.sm", FT_UINT8,
+		    BASE_HEX, VALS(sna_nlp_sm_vals), 0xe0, "", HFILL }},
+
+                { &hf_sna_nlp_tpf,
+                { "Transmission Priority Field", "sna.nlp.nhdr.tpf", FT_UINT8,
+		    BASE_HEX, VALS(sna_th_tpf_vals), 0x06, "", HFILL }},
+
+                { &hf_sna_nlp_ft,
+                { "Function Type", "sna.nlp.nhdr.ft", FT_UINT8, BASE_HEX,
+		    VALS(sna_nlp_ft_vals), 0xF0, "", HFILL }},
+
+                { &hf_sna_nlp_tspi,
+                { "Time Sensitive Packet Indicator", "sna.nlp.nhdr.tspi",
+		    FT_BOOLEAN, 8, TFS(&sna_nlp_tspi_truth), 0x08, "", HFILL }},
+
+                { &hf_sna_nlp_slowdn1,
+                { "Slowdown 1", "sna.nlp.nhdr.slowdn1", FT_BOOLEAN, 8,
+		    TFS(&sna_nlp_slowdn1_truth), 0x04, "", HFILL }},
+
+                { &hf_sna_nlp_slowdn2,
+                { "Slowdown 2", "sna.nlp.nhdr.slowdn2", FT_BOOLEAN, 8,
+		    TFS(&sna_nlp_slowdn2_truth), 0x02, "", HFILL }},
+
+                { &hf_sna_nlp_fra,
+                { "Function Routing Address Entry", "sna.nlp.nhdr.fra",
+		    FT_BYTES, BASE_NONE, NULL, 0, "", HFILL }},
+
+                { &hf_sna_nlp_anr,
+                { "Automatic Network Routing Entry", "sna.nlp.nhdr.anr",
+		    FT_BYTES, BASE_HEX, NULL, 0, "", HFILL }},
+
+                { &hf_sna_nlp_frh,
+                { "Transmission Priority Field", "sna.nlp.frh", FT_UINT8,
+		    BASE_HEX, VALS(sna_nlp_frh_vals), 0, "", HFILL }},
+
+                { &hf_sna_nlp_thdr,
+                { "RTP Transport Header", "sna.nlp.thdr", FT_NONE, BASE_NONE,
+		    NULL, 0x0, "THDR", HFILL }},
+
+                { &hf_sna_nlp_tcid,
+                { "Transport Connection Identifier", "sna.nlp.thdr.tcid",
+		    FT_BYTES, BASE_HEX, NULL, 0x0, "TCID", HFILL }},
+
+                { &hf_sna_nlp_thdr_8,
+                { "RTP Transport Packet Header Byte 8", "sna.nlp.thdr.8",
+		    FT_UINT8, BASE_HEX, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_nlp_setupi,
+                { "Setup Indicator", "sna.nlp.thdr.setupi", FT_BOOLEAN, 8,
+		    TFS(&sna_nlp_setupi_truth), 0x40, "", HFILL }},
+
+                { &hf_sna_nlp_somi,
+                { "Start Of Message Indicator", "sna.nlp.thdr.somi",
+		    FT_BOOLEAN, 8, TFS(&sna_nlp_somi_truth), 0x20, "", HFILL }},
+
+                { &hf_sna_nlp_eomi,
+                { "End Of Message Indicator", "sna.nlp.thdr.eomi", FT_BOOLEAN,
+		    8, TFS(&sna_nlp_eomi_truth), 0x10, "", HFILL }},
+
+                { &hf_sna_nlp_sri,
+                { "Session Request Indicator", "sna.nlp.thdr.sri", FT_BOOLEAN,
+		    8, TFS(&sna_nlp_sri_truth), 0x08, "", HFILL }},
+
+                { &hf_sna_nlp_rasapi,
+                { "Reply ASAP Indicator", "sna.nlp.thdr.rasapi", FT_BOOLEAN,
+		    8, TFS(&sna_nlp_rasapi_truth), 0x04, "", HFILL }},
+
+                { &hf_sna_nlp_retryi,
+                { "Retry Indicator", "sna.nlp.thdr.retryi", FT_BOOLEAN,
+		    8, TFS(&sna_nlp_retryi_truth), 0x02, "", HFILL }},
+
+                { &hf_sna_nlp_thdr_9,
+                { "RTP Transport Packet Header Byte 9", "sna.nlp.thdr.9",
+		    FT_UINT8, BASE_HEX, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_nlp_lmi,
+                { "Last Message Indicator", "sna.nlp.thdr.lmi", FT_BOOLEAN,
+		    8, TFS(&sna_nlp_lmi_truth), 0x80, "", HFILL }},
+
+                { &hf_sna_nlp_cqfi,
+                { "Connection Qualifyer Field Indicator", "sna.nlp.thdr.cqfi",
+		    FT_BOOLEAN, 8, TFS(&sna_nlp_cqfi_truth), 0x08, "", HFILL }},
+
+                { &hf_sna_nlp_osi,
+                { "Optional Segments Present Indicator", "sna.nlp.thdr.osi",
+		    FT_BOOLEAN, 8, TFS(&sna_nlp_osi_truth), 0x04, "", HFILL }},
+
+                { &hf_sna_nlp_offset,
+                { "Data Offset/4", "sna.nlp.thdr.offset", FT_UINT16, BASE_HEX,
+		    NULL, 0x0, "Data Offset in Words", HFILL }},
+
+                { &hf_sna_nlp_dlf,
+                { "Data Length Field", "sna.nlp.thdr.dlf", FT_UINT32, BASE_HEX,
+		    NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_nlp_bsn,
+                { "Byte Sequence Number", "sna.nlp.thdr.bsn", FT_UINT32,
+		    BASE_HEX, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_nlp_opti_len,
+                { "Optional Segment Length/4", "sna.nlp.thdr.optional.len",
+		    FT_UINT8, BASE_DEC, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_nlp_opti_type,
+                { "Optional Segment Type", "sna.nlp.thdr.optional.type",
+		    FT_UINT8, BASE_HEX, VALS(sna_nlp_opti_vals), 0x0, "",
+		    HFILL }},
+
+                { &hf_sna_nlp_opti_0d_version,
+                { "Version", "sna.nlp.thdr.optional.0d.version",
+		    FT_UINT16, BASE_HEX, VALS(sna_nlp_opti_0d_version_vals),
+		    0, "", HFILL }},
+
+                { &hf_sna_nlp_opti_0d_4,
+                { "Connection Setup Byte 4", "sna.nlp.thdr.optional.0e.4",
+		    FT_UINT8, BASE_HEX, NULL, 0, "", HFILL }},
+
+                { &hf_sna_nlp_opti_0d_target,
+                { "Target Resource ID Present",
+		    "sna.nlp.thdr.optional.0d.target",
+		    FT_BOOLEAN, 8, NULL, 0x80, "", HFILL }},
+
+                { &hf_sna_nlp_opti_0d_arb,
+                { "ARB Flow Control", "sna.nlp.thdr.optional.0d.arb",
+		    FT_BOOLEAN, 8, NULL, 0x10, "", HFILL }},
+
+                { &hf_sna_nlp_opti_0d_reliable,
+                { "Reliable Connection", "sna.nlp.thdr.optional.0d.reliable",
+		    FT_BOOLEAN, 8, NULL, 0x08, "", HFILL }},
+
+                { &hf_sna_nlp_opti_0d_dedicated,
+                { "Dedicated RTP Connection",
+		    "sna.nlp.thdr.optional.0d.dedicated",
+		    FT_BOOLEAN, 8, NULL, 0x04, "", HFILL }},
+
+                { &hf_sna_nlp_opti_0e_stat,
+                { "Status", "sna.nlp.thdr.optional.0e.stat",
+		    FT_UINT8, BASE_HEX, NULL, 0, "", HFILL }},
+
+                { &hf_sna_nlp_opti_0e_gap,
+                { "Gap Detected", "sna.nlp.thdr.optional.0e.gap",
+		    FT_BOOLEAN, 8, NULL, 0x80, "", HFILL }},
+
+                { &hf_sna_nlp_opti_0e_idle,
+                { "RTP Idle Packet", "sna.nlp.thdr.optional.0e.idle",
+		    FT_BOOLEAN, 8, NULL, 0x40, "", HFILL }},
+
+                { &hf_sna_nlp_opti_0e_nabsp,
+                { "Number Of ABSP", "sna.nlp.thdr.optional.0e.nabsp",
+		    FT_UINT8, BASE_DEC, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_nlp_opti_0e_sync,
+                { "Status Report Number", "sna.nlp.thdr.optional.0e.sync",
+		    FT_UINT16, BASE_HEX, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_nlp_opti_0e_echo,
+                { "Status Acknowledge Number", "sna.nlp.thdr.optional.0e.echo",
+		    FT_UINT16, BASE_HEX, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_nlp_opti_0e_rseq,
+                { "Received Sequence Number", "sna.nlp.thdr.optional.0e.rseq",
+		    FT_UINT32, BASE_HEX, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_nlp_opti_0e_abspbeg,
+                { "ABSP Begin", "sna.nlp.thdr.optional.0e.abspbeg",
+		    FT_UINT32, BASE_HEX, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_nlp_opti_0e_abspend,
+                { "ABSP End", "sna.nlp.thdr.optional.0e.abspend",
+		    FT_UINT32, BASE_HEX, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_nlp_opti_0f_bits,
+                { "Client Bits", "sna.nlp.thdr.optional.0f.bits",
+		    FT_UINT8, BASE_HEX, VALS(sna_nlp_opti_0f_bits_vals),
+		    0x0, "", HFILL }},
+
+                { &hf_sna_nlp_opti_10_tcid,
+                { "Transport Connection Identifier",
+		    "sna.nlp.thdr.optional.10.tcid",
+		    FT_BYTES, BASE_HEX, NULL, 0x0, "TCID", HFILL }},
+
+                { &hf_sna_nlp_opti_12_sense,
+                { "Sense Data", "sna.nlp.thdr.optional.12.sense",
+		    FT_BYTES, BASE_HEX, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_nlp_opti_14_si_len,
+                { "Length", "sna.nlp.thdr.optional.14.si.len",
+		    FT_UINT8, BASE_DEC, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_nlp_opti_14_si_key,
+                { "Key", "sna.nlp.thdr.optional.14.si.key",
+		    FT_UINT8, BASE_HEX, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_nlp_opti_14_si_2,
+                { "Switching Information Byte 2",
+		    "sna.nlp.thdr.optional.14.si.2",
+		    FT_UINT8, BASE_HEX, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_nlp_opti_14_si_refifo,
+                { "Resequencing (REFIFO) Indicator",
+		    "sna.nlp.thdr.optional.14.si.refifo",
+		    FT_BOOLEAN, 8, NULL, 0x80, "", HFILL }},
+
+                { &hf_sna_nlp_opti_14_si_mobility,
+                { "Mobility Indicator",
+		    "sna.nlp.thdr.optional.14.si.mobility",
+		    FT_BOOLEAN, 8, NULL, 0x40, "", HFILL }},
+
+                { &hf_sna_nlp_opti_14_si_dirsearch,
+                { "Directory Search Required on Path Switch Indicator",
+		    "sna.nlp.thdr.optional.14.si.dirsearch",
+		    FT_BOOLEAN, 8, NULL, 0x20, "", HFILL }},
+
+                { &hf_sna_nlp_opti_14_si_limitres,
+                { "Limited Resource Link Indicator",
+		    "sna.nlp.thdr.optional.14.si.limitres",
+		    FT_BOOLEAN, 8, NULL, 0x10, "", HFILL }},
+
+                { &hf_sna_nlp_opti_14_si_ncescope,
+                { "NCE Scope Indicator",
+		    "sna.nlp.thdr.optional.14.si.ncescope",
+		    FT_BOOLEAN, 8, NULL, 0x08, "", HFILL }},
+
+                { &hf_sna_nlp_opti_14_si_mnpsrscv,
+                { "MNPS RSCV Retention Indicator",
+		    "sna.nlp.thdr.optional.14.si.mnpsrscv",
+		    FT_BOOLEAN, 8, NULL, 0x04, "", HFILL }},
+
+                { &hf_sna_nlp_opti_14_si_maxpsize,
+                { "Maximum Packet Size On Return Path",
+		    "sna.nlp.thdr.optional.14.si.maxpsize",
+		    FT_UINT32, BASE_DEC, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_nlp_opti_14_si_switch,
+                { "Path Switch Time", "sna.nlp.thdr.optional.14.si.switch",
+		    FT_UINT32, BASE_DEC, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_nlp_opti_14_si_alive,
+                { "RTP Alive Timer", "sna.nlp.thdr.optional.14.si.alive",
+		    FT_UINT32, BASE_DEC, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_nlp_opti_14_rr_len,
+                { "Length", "sna.nlp.thdr.optional.14.rr.len",
+		    FT_UINT8, BASE_DEC, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_nlp_opti_14_rr_key,
+                { "Key", "sna.nlp.thdr.optional.14.rr.key",
+		    FT_UINT8, BASE_HEX, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_nlp_opti_14_rr_2,
+                { "Return Route TG Descriptor Byte 2",
+		    "sna.nlp.thdr.optional.14.rr.2",
+		    FT_UINT8, BASE_HEX, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_nlp_opti_14_rr_bfe,
+                { "BF Entry Indicator",
+		    "sna.nlp.thdr.optional.14.rr.bfe",
+		    FT_BOOLEAN, 8, NULL, 0x80, "", HFILL }},
+
+                { &hf_sna_nlp_opti_14_rr_num,
+                { "Number Of TG Control Vectors",
+		    "sna.nlp.thdr.optional.14.rr.num",
+		    FT_UINT8, BASE_DEC, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_nlp_opti_22_2,
+                { "Adaptive Rate Based Segment Byte 2",
+		    "sna.nlp.thdr.optional.22.2",
+		    FT_UINT8, BASE_HEX, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_nlp_opti_22_type,
+                { "Message Type",
+		    "sna.nlp.thdr.optional.22.type",
+		    FT_UINT8, BASE_HEX,
+		    VALS(sna_nlp_opti_22_type_vals), 0xc0, "", HFILL }},
+
+                { &hf_sna_nlp_opti_22_raa,
+                { "Rate Adjustment Action",
+		    "sna.nlp.thdr.optional.22.raa",
+		    FT_UINT8, BASE_HEX,
+		    VALS(sna_nlp_opti_22_raa_vals), 0x38, "", HFILL }},
+
+                { &hf_sna_nlp_opti_22_parity,
+                { "Parity Indicator",
+		    "sna.nlp.thdr.optional.22.parity",
+		    FT_BOOLEAN, 8, NULL, 0x04, "", HFILL }},
+
+                { &hf_sna_nlp_opti_22_arb,
+                { "ARB Mode",
+		    "sna.nlp.thdr.optional.22.arb",
+		    FT_UINT8, BASE_HEX,
+		    VALS(sna_nlp_opti_22_arb_vals), 0x03, "", HFILL }},
+
+                { &hf_sna_nlp_opti_22_3,
+                { "Adaptive Rate Based Segment Byte 3",
+		    "sna.nlp.thdr.optional.22.3",
+		    FT_UINT8, BASE_HEX, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_nlp_opti_22_ratereq,
+                { "Rate Request Correlator",
+		    "sna.nlp.thdr.optional.22.ratereq",
+		    FT_UINT8, BASE_DEC, NULL, 0xf0, "", HFILL }},
+
+                { &hf_sna_nlp_opti_22_raterep,
+                { "Rate Reply Correlator",
+		    "sna.nlp.thdr.optional.22.raterep",
+		    FT_UINT8, BASE_DEC, NULL, 0x0f, "", HFILL }},
+
+                { &hf_sna_nlp_opti_22_field1,
+                { "Field 1", "sna.nlp.thdr.optional.22.field1",
+		    FT_UINT32, BASE_DEC, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_nlp_opti_22_field2,
+                { "Field 2", "sna.nlp.thdr.optional.22.field2",
+		    FT_UINT32, BASE_DEC, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_nlp_opti_22_field3,
+                { "Field 3", "sna.nlp.thdr.optional.22.field3",
+		    FT_UINT32, BASE_DEC, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_nlp_opti_22_field4,
+                { "Field 4", "sna.nlp.thdr.optional.22.field4",
+		    FT_UINT32, BASE_DEC, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_rh,
+                { "Request/Response Header", "sna.rh", FT_NONE, BASE_NONE,
+		    NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_rh_0,
+                { "Request/Response Header Byte 0", "sna.rh.0", FT_UINT8,
+		    BASE_HEX, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_rh_1,
+                { "Request/Response Header Byte 1", "sna.rh.1", FT_UINT8,
+		    BASE_HEX, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_rh_2,
+                { "Request/Response Header Byte 2", "sna.rh.2", FT_UINT8,
+		    BASE_HEX, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_rh_rri,
+                { "Request/Response Indicator", "sna.rh.rri", FT_UINT8,
+		    BASE_DEC, VALS(sna_rh_rri_vals), 0x80, "", HFILL }},
+
+                { &hf_sna_rh_ru_category,
+                { "Request/Response Unit Category", "sna.rh.ru_category",
+		    FT_UINT8, BASE_HEX, VALS(sna_rh_ru_category_vals), 0x60,
+		    "", HFILL }},
+
+		{ &hf_sna_rh_fi,
+		{ "Format Indicator", "sna.rh.fi", FT_BOOLEAN, 8,
+		    TFS(&sna_rh_fi_truth), 0x08, "", HFILL }},
+
+		{ &hf_sna_rh_sdi,
+		{ "Sense Data Included", "sna.rh.sdi", FT_BOOLEAN, 8,
+		    TFS(&sna_rh_sdi_truth), 0x04, "", HFILL }},
+
+		{ &hf_sna_rh_bci,
+		{ "Begin Chain Indicator", "sna.rh.bci", FT_BOOLEAN, 8,
+		    TFS(&sna_rh_bci_truth), 0x02, "", HFILL }},
+
+		{ &hf_sna_rh_eci,
+		{ "End Chain Indicator", "sna.rh.eci", FT_BOOLEAN, 8,
+		    TFS(&sna_rh_eci_truth), 0x01, "", HFILL }},
+
+		{ &hf_sna_rh_dr1,
+		{ "Definite Response 1 Indicator", "sna.rh.dr1", FT_BOOLEAN,
+		    8, NULL, 0x80, "", HFILL }},
+
+		{ &hf_sna_rh_lcci,
+		{ "Length-Checked Compression Indicator", "sna.rh.lcci",
+		    FT_BOOLEAN, 8, TFS(&sna_rh_lcci_truth), 0x40, "", HFILL }},
+
+		{ &hf_sna_rh_dr2,
+		{ "Definite Response 2 Indicator", "sna.rh.dr2", FT_BOOLEAN,
+		    8, NULL, 0x20, "", HFILL }},
+
+		{ &hf_sna_rh_eri,
+		{ "Exception Response Indicator", "sna.rh.eri", FT_BOOLEAN,
+		    8, NULL, 0x10, "", HFILL }},
+
+		{ &hf_sna_rh_rti,
+		{ "Response Type Indicator", "sna.rh.rti", FT_BOOLEAN,
+		    8, TFS(&sna_rh_rti_truth), 0x10, "", HFILL }},
+
+		{ &hf_sna_rh_rlwi,
+		{ "Request Larger Window Indicator", "sna.rh.rlwi", FT_BOOLEAN,
+		    8, NULL, 0x04, "", HFILL }},
+
+		{ &hf_sna_rh_qri,
+		{ "Queued Response Indicator", "sna.rh.qri", FT_BOOLEAN,
+		    8, TFS(&sna_rh_qri_truth), 0x02, "", HFILL }},
+
+		{ &hf_sna_rh_pi,
+		{ "Pacing Indicator", "sna.rh.pi", FT_BOOLEAN,
+		    8, NULL, 0x01, "", HFILL }},
+
+		{ &hf_sna_rh_bbi,
+		{ "Begin Bracket Indicator", "sna.rh.bbi", FT_BOOLEAN,
+		    8, NULL, 0x80, "", HFILL }},
+
+		{ &hf_sna_rh_ebi,
+		{ "End Bracket Indicator", "sna.rh.ebi", FT_BOOLEAN,
+		    8, NULL, 0x40, "", HFILL }},
+
+		{ &hf_sna_rh_cdi,
+		{ "Change Direction Indicator", "sna.rh.cdi", FT_BOOLEAN,
+		    8, NULL, 0x20, "", HFILL }},
+
+		{ &hf_sna_rh_csi,
+		{ "Code Selection Indicator", "sna.rh.csi", FT_UINT8, BASE_DEC,
+		    VALS(sna_rh_csi_vals), 0x08, "", HFILL }},
+
+		{ &hf_sna_rh_edi,
+		{ "Enciphered Data Indicator", "sna.rh.edi", FT_BOOLEAN, 8,
+		    NULL, 0x04, "", HFILL }},
+
+		{ &hf_sna_rh_pdi,
+		{ "Padded Data Indicator", "sna.rh.pdi", FT_BOOLEAN, 8, NULL,
+		    0x02, "", HFILL }},
+
+		{ &hf_sna_rh_cebi,
+		{ "Conditional End Bracket Indicator", "sna.rh.cebi",
+		    FT_BOOLEAN, 8, NULL, 0x01, "", HFILL }},
+
+/*		{ &hf_sna_ru,
+		{ "Request/Response Unit", "sna.ru", FT_NONE, BASE_NONE,
+		    NULL, 0x0, "", HFILL }},*/
+
+		{ &hf_sna_gds,
+		{ "GDS Variable", "sna.gds", FT_NONE, BASE_NONE, NULL, 0x0,
+		    "", HFILL }},
+
+		{ &hf_sna_gds_len,
+		{ "GDS Variable Length", "sna.gds.len", FT_UINT16, BASE_DEC,
+		    NULL, 0x7fff, "", HFILL }},
+
+		{ &hf_sna_gds_cont,
+		{ "Continuation Flag", "sna.gds.cont", FT_BOOLEAN, 16, NULL,
+		    0x8000, "", HFILL }},
+
+		{ &hf_sna_gds_type,
+		{ "Type of Variable", "sna.gds.type", FT_UINT16, BASE_HEX,
+		    VALS(sna_gds_var_vals), 0x0, "", HFILL }},
+
+		{ &hf_sna_xid,
+		{ "XID", "sna.xid", FT_NONE, BASE_NONE, NULL, 0x0,
+		    "XID Frame", HFILL }},
+
+		{ &hf_sna_xid_0,
+		{ "XID Byte 0", "sna.xid.0", FT_UINT8, BASE_HEX, NULL, 0x0,
+		    "", HFILL }},
+
+		{ &hf_sna_xid_format,
+		{ "XID Format", "sna.xid.format", FT_UINT8, BASE_DEC, NULL,
+		    0xf0, "", HFILL }},
+
+		{ &hf_sna_xid_type,
+		{ "XID Type", "sna.xid.type", FT_UINT8, BASE_DEC,
+		    VALS(sna_xid_type_vals), 0x0f, "", HFILL }},
+
+		{ &hf_sna_xid_len,
+		{ "XID Length", "sna.xid.len", FT_UINT8, BASE_DEC, NULL, 0x0,
+		    "", HFILL }},
+
+		{ &hf_sna_xid_id,
+		{ "Node Identification", "sna.xid.id", FT_UINT32, BASE_HEX,
+		    NULL, 0x0, "", HFILL }},
+
+		{ &hf_sna_xid_idblock,
+		{ "ID Block", "sna.xid.idblock", FT_UINT32, BASE_HEX, NULL, 
+		    0xfff00000, "", HFILL }},
+
+		{ &hf_sna_xid_idnum,
+		{ "ID Number", "sna.xid.idnum", FT_UINT32, BASE_HEX, NULL,
+		    0x0fffff, "", HFILL }},
+
+		{ &hf_sna_xid_3_8,
+		{ "Characteristics of XID sender", "sna.xid.type3.8", FT_UINT16,
+		    BASE_HEX, NULL, 0x0, "", HFILL }},
+
+		{ &hf_sna_xid_3_init_self,
+		{ "INIT-SELF support", "sna.xid.type3.initself",
+		    FT_BOOLEAN, 16, NULL, 0x8000, "", HFILL }},
+
+		{ &hf_sna_xid_3_stand_bind,
+		{ "Stand-Alone BIND Support", "sna.xid.type3.stand_bind",
+		    FT_BOOLEAN, 16, NULL, 0x4000, "", HFILL }},
+
+		{ &hf_sna_xid_3_gener_bind,
+		{ "Whole BIND PIU generated indicator",
+		    "sna.xid.type3.gener_bind", FT_BOOLEAN, 16, NULL, 0x2000,
+		    "Whole BIND PIU generated", HFILL }},
+
+		{ &hf_sna_xid_3_recve_bind,
+		{ "Whole BIND PIU required indicator",
+		    "sna.xid.type3.recve_bind", FT_BOOLEAN, 16, NULL, 0x1000,
+		    "Whole BIND PIU required", HFILL }},
+
+		{ &hf_sna_xid_3_actpu,
+		{ "ACTPU suppression indicator", "sna.xid.type3.actpu",
+		    FT_BOOLEAN, 16, NULL, 0x0080, "", HFILL }},
+
+		{ &hf_sna_xid_3_nwnode,
+		{ "Sender is network node", "sna.xid.type3.nwnode",
+		    FT_BOOLEAN, 16, NULL, 0x0040, "", HFILL }},
+
+		{ &hf_sna_xid_3_cp,
+		{ "Control Point Services", "sna.xid.type3.cp",
+		    FT_BOOLEAN, 16, NULL, 0x0020, "", HFILL }},
+
+		{ &hf_sna_xid_3_cpcp,
+		{ "CP-CP session support", "sna.xid.type3.cpcp",
+		    FT_BOOLEAN, 16, NULL, 0x0010, "", HFILL }},
+
+		{ &hf_sna_xid_3_state,
+		{ "XID exchange state indicator", "sna.xid.type3.state",
+		    FT_UINT16, BASE_HEX, VALS(sna_xid_3_state_vals),
+		    0x000c, "", HFILL }},
+
+		{ &hf_sna_xid_3_nonact,
+		{ "Nonactivation Exchange", "sna.xid.type3.nonact",
+		    FT_BOOLEAN, 16, NULL, 0x0002, "", HFILL }},
+
+		{ &hf_sna_xid_3_cpchange,
+		{ "CP name change support", "sna.xid.type3.cpchange",
+		    FT_BOOLEAN, 16, NULL, 0x0001, "", HFILL }},
+
+		{ &hf_sna_xid_3_10,
+		{ "XID Type 3 Byte 10", "sna.xid.type3.10", FT_UINT8, BASE_HEX,
+		    NULL, 0x0, "", HFILL }},
+
+		{ &hf_sna_xid_3_asend_bind,
+		{ "Adaptive BIND pacing support as sender",
+		    "sna.xid.type3.asend_bind", FT_BOOLEAN, 8, NULL, 0x80,
+		    "Pacing support as sender", HFILL }},
+
+		{ &hf_sna_xid_3_arecv_bind,
+		{ "Adaptive BIND pacing support as receiver",
+		    "sna.xid.type3.asend_recv", FT_BOOLEAN, 8, NULL, 0x40,
+		    "Pacing support as receive", HFILL }},
+
+		{ &hf_sna_xid_3_quiesce,
+		{ "Quiesce TG Request",
+		    "sna.xid.type3.quiesce", FT_BOOLEAN, 8, NULL, 0x20,
+		    "", HFILL }},
+
+		{ &hf_sna_xid_3_pucap,
+		{ "PU Capabilities",
+		    "sna.xid.type3.pucap", FT_BOOLEAN, 8, NULL, 0x10,
+		    "", HFILL }},
+
+		{ &hf_sna_xid_3_pbn,
+		{ "Peripheral Border Node",
+		    "sna.xid.type3.pbn", FT_BOOLEAN, 8, NULL, 0x08,
+		    "", HFILL }},
+
+		{ &hf_sna_xid_3_pacing,
+		{ "Qualifier for adaptive BIND pacing support",
+		    "sna.xid.type3.pacing", FT_UINT8, BASE_HEX, NULL, 0x03,
+		    "", HFILL }},
+
+		{ &hf_sna_xid_3_11,
+		{ "XID Type 3 Byte 11", "sna.xid.type3.11", FT_UINT8, BASE_HEX,
+		    NULL, 0x0, "", HFILL }},
+
+		{ &hf_sna_xid_3_tgshare,
+		{ "TG Sharing Prohibited Indicator",
+		    "sna.xid.type3.tgshare", FT_BOOLEAN, 8, NULL, 0x40,
+		    "", HFILL }},
+
+		{ &hf_sna_xid_3_dedsvc,
+		{ "Dedicated SVC Idicator",
+		    "sna.xid.type3.dedsvc", FT_BOOLEAN, 8, NULL, 0x20,
+		    "", HFILL }},
+
+		{ &hf_sna_xid_3_12,
+		{ "XID Type 3 Byte 12", "sna.xid.type3.12", FT_UINT8, BASE_HEX,
+		    NULL, 0x0, "", HFILL }},
+
+		{ &hf_sna_xid_3_negcsup,
+		{ "Negotiation Complete Supported",
+		    "sna.xid.type3.negcsup", FT_BOOLEAN, 8, NULL, 0x80,
+		    "", HFILL }},
+
+		{ &hf_sna_xid_3_negcomp,
+		{ "Negotiation Complete",
+		    "sna.xid.type3.negcomp", FT_BOOLEAN, 8, NULL, 0x40,
+		    "", HFILL }},
+
+		{ &hf_sna_xid_3_15,
+		{ "XID Type 3 Byte 15", "sna.xid.type3.15", FT_UINT8, BASE_HEX,
+		    NULL, 0x0, "", HFILL }},
+
+		{ &hf_sna_xid_3_partg,
+		{ "Parallel TG Support",
+		    "sna.xid.type3.partg", FT_BOOLEAN, 8, NULL, 0x80,
+		    "", HFILL }},
+
+		{ &hf_sna_xid_3_dlur,
+		{ "Dependent LU Requester Indicator",
+		    "sna.xid.type3.dlur", FT_BOOLEAN, 8, NULL, 0x40,
+		    "", HFILL }},
+
+		{ &hf_sna_xid_3_dlus,
+		{ "DLUS Served LU Registration Indicator",
+		    "sna.xid.type3.dlus", FT_BOOLEAN, 8, NULL, 0x20,
+		    "", HFILL }},
+
+		{ &hf_sna_xid_3_exbn,
+		{ "Extended HPR Border Node",
+		    "sna.xid.type3.exbn", FT_BOOLEAN, 8, NULL, 0x10,
+		    "", HFILL }},
+
+		{ &hf_sna_xid_3_genodai,
+		{ "Generalized ODAI Usage Option",
+		    "sna.xid.type3.genodai", FT_BOOLEAN, 8, NULL, 0x08,
+		    "", HFILL }},
+
+		{ &hf_sna_xid_3_branch,
+		{ "Branch Indicator", "sna.xid.type3.branch",
+		    FT_UINT8, BASE_HEX, VALS(sna_xid_3_branch_vals),
+		    0x06, "", HFILL }},
+
+		{ &hf_sna_xid_3_brnn,
+		{ "Option Set 1123 Indicator",
+		    "sna.xid.type3.brnn", FT_BOOLEAN, 8, NULL, 0x01,
+		    "", HFILL }},
+
+		{ &hf_sna_xid_3_tg,
+		{ "XID TG", "sna.xid.type3.tg", FT_UINT8, BASE_HEX, NULL, 0x0,
+		    "", HFILL }},
+
+		{ &hf_sna_xid_3_dlc,
+		{ "XID DLC", "sna.xid.type3.dlc", FT_UINT8, BASE_HEX, NULL, 0x0,
+		    "", HFILL }},
+
+		{ &hf_sna_xid_3_dlen,
+		{ "DLC Dependent Section Length", "sna.xid.type3.dlen",
+		    FT_UINT8, BASE_DEC, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_control_len,
+                { "Control Vector Length", "sna.control.len",
+		    FT_UINT8, BASE_DEC, NULL, 0x0, "", HFILL }},
+
+                { &hf_sna_control_key,
+                { "Control Vector Key", "sna.control.key",
+		    FT_UINT8, BASE_HEX, VALS(sna_control_vals), 0x0, "",
+		    HFILL }},
+
+                { &hf_sna_control_hprkey,
+                { "Control Vector HPR Key", "sna.control.hprkey",
+		    FT_UINT8, BASE_HEX, VALS(sna_control_hpr_vals), 0x0, "",
+		    HFILL }},
+	
+                { &hf_sna_control_05_delay,
+                { "Channel Delay", "sna.control.05.delay",
+		    FT_UINT16, BASE_DEC, NULL, 0x0, "", HFILL }},
+	
+                { &hf_sna_control_05_type,
+                { "Network Address Type", "sna.control.05.type",
+		    FT_UINT8, BASE_HEX, NULL, 0x0, "", HFILL }},
+	
+                { &hf_sna_control_05_ptp,
+                { "Point-to-point", "sna.control.05.ptp",
+		    FT_BOOLEAN, 8, NULL, 0x80, "", HFILL }},
+	
+                { &hf_sna_control_0e_type,
+                { "Type", "sna.control.0e.type",
+		    FT_UINT8, BASE_HEX, VALS(sna_control_0e_type_vals),
+		    0, "", HFILL }},
+	
+                { &hf_sna_control_0e_value,
+                { "Value", "sna.control.0e.value",
+		    FT_STRING, BASE_NONE, NULL, 0, "", HFILL }},
+        };
+	static gint *ett[] = {
+		&ett_sna,
+		&ett_sna_th,
+		&ett_sna_th_fid,
+		&ett_sna_nlp_nhdr,
+		&ett_sna_nlp_nhdr_0,
+		&ett_sna_nlp_nhdr_1,
+		&ett_sna_nlp_thdr,
+		&ett_sna_nlp_thdr_8,
+		&ett_sna_nlp_thdr_9,
+		&ett_sna_nlp_opti_un,
+		&ett_sna_nlp_opti_0d,
+		&ett_sna_nlp_opti_0d_4,
+		&ett_sna_nlp_opti_0e,
+		&ett_sna_nlp_opti_0e_stat,
+		&ett_sna_nlp_opti_0e_absp,
+		&ett_sna_nlp_opti_0f,
+		&ett_sna_nlp_opti_10,
+		&ett_sna_nlp_opti_12,
+		&ett_sna_nlp_opti_14,
+		&ett_sna_nlp_opti_14_si,
+		&ett_sna_nlp_opti_14_si_2,
+		&ett_sna_nlp_opti_14_rr,
+		&ett_sna_nlp_opti_14_rr_2,
+		&ett_sna_nlp_opti_22,
+		&ett_sna_nlp_opti_22_2,
+		&ett_sna_nlp_opti_22_3,
+		&ett_sna_rh,
+		&ett_sna_rh_0,
+		&ett_sna_rh_1,
+		&ett_sna_rh_2,
+		&ett_sna_gds,
+		&ett_sna_xid_0,
+		&ett_sna_xid_id,
+		&ett_sna_xid_3_8,
+		&ett_sna_xid_3_10,
+		&ett_sna_xid_3_11,
+		&ett_sna_xid_3_12,
+		&ett_sna_xid_3_15,
+		&ett_sna_control_un,
+		&ett_sna_control_05,
+		&ett_sna_control_05hpr,
+		&ett_sna_control_05hpr_type,
+		&ett_sna_control_0e,
+	};
+	module_t *sna_module;
+
+	proto_sna = proto_register_protocol("Systems Network Architecture",
+	    "SNA", "sna");
+	proto_register_field_array(proto_sna, hf, array_length(hf));
+	proto_register_subtree_array(ett, array_length(ett));
+	register_dissector("sna", dissect_sna, proto_sna);
+
+	proto_sna_xid = proto_register_protocol(
+	    "Systems Network Architecture XID", "SNA XID", "sna_xid");
+	register_dissector("sna_xid", dissect_sna_xid, proto_sna_xid);
+
+	/* Register configuration options */
+	sna_module = prefs_register_protocol(proto_sna, NULL);
+	prefs_register_bool_preference(sna_module, "defragment",
+		"Reassemble fragmented BIUs",
+		"Whether fragmented BIUs should be reassembled",
+		&sna_defragment);
+}
+
+void
+proto_reg_handoff_sna(void)
+{
+	dissector_handle_t sna_handle;
+	dissector_handle_t sna_xid_handle;
+
+	sna_handle = find_dissector("sna");
+	sna_xid_handle = find_dissector("sna_xid");
+	dissector_add("llc.dsap", SAP_SNA_PATHCTRL, sna_handle);
+	dissector_add("llc.dsap", SAP_SNA1, sna_handle);
+	dissector_add("llc.dsap", SAP_SNA2, sna_handle);
+	dissector_add("llc.dsap", SAP_SNA3, sna_handle);
+	dissector_add("llc.xid_dsap", SAP_SNA_PATHCTRL, sna_xid_handle);
+	dissector_add("llc.xid_dsap", SAP_SNA1, sna_xid_handle);
+	dissector_add("llc.xid_dsap", SAP_SNA2, sna_xid_handle);
+	dissector_add("llc.xid_dsap", SAP_SNA3, sna_xid_handle);
+	/* RFC 2043 */
+	dissector_add("ppp.protocol", PPP_SNA, sna_handle);
+	data_handle = find_dissector("data");
+
+	register_init_routine(sna_init);
+}