//$Header: /home/dashley/cvsrep/e3ft_gpl01/e3ft_gpl01/winprojs/scirfmmon/source/log_packet.c,v 1.24 2009/01/17 22:12:37 dashley Exp $
//--------------------------------------------------------------------------------
//Copyright 2008 David T. Ashley
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//This source code and any program in which it is compiled/used is provided under the GNU GENERAL
//PUBLIC LICENSE, Version 3, full license text below.
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//--------------------------------------------------------------------------------
#define MODULE_LOG_PACKET

#include <stdio.h>
#include <sys/timeb.h>
#include <time.h>

#include "log_packet.h"

#include "c_main.h"
#include "ccmfatal.h"
#include "log.h"
#include "miscfunc.h"
#include "qchar.h"


static void LOG_PACKET_log_f_setpanid                      (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_acksetpanid                   (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_querypanid                    (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_resppanid                     (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_settransad                    (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_acksettransad                 (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_querytransad                  (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_resptransad                   (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_setrfchannel                  (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_acksetrfchannel               (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_queryrfchannel                (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_resprfchannel                 (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_endisallrfmsgs                (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_ackendisallrfmsgs             (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_queryrxallrfmsgsstatus        (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_resprxallrfmsgsstatus         (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_endisrfacksretries            (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_ackendisrfacksretries         (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_queryrfacksretriesstatus      (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_resprfacksretriesstatus       (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_setradiofeaturesoptions       (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_acksetradiofeaturesoptions   (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_queryradiofeaturesoptions     (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_respradiofeaturesoptions      (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_querystatistics               (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_respstatistics                (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_clearstatistics               (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_ackclearstatistics            (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_settxpowerlevel               (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_acksettxpowerlevel            (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_querytxpowerlevel             (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_resptxpowerlevel              (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_savecfgnvm                    (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_acksavecfgnvm                 (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_queryfirmwareversion          (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_respfirmwareversion           (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_setlowpowermode               (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_acksetlowpowermode               (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_senddata                      (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_acksenddata                   (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_rxeddata                      (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_resetrequest                  (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_ackresetrequest               (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_sendmsgapp                    (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_acksendmsgapp                 (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_rxedmsgapp                    (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_initfirmwaredownload          (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_ackinitfirmwaredownload       (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_transferfirmwareblock         (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_acktransferfirmwareblock      (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_terminatedownload             (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_ackterminatedownload          (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_setdigpincfg                  (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_acksetdigpincfg               (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_querydigpincfg                (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_respdigpincfg                 (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_setdigpinstate                (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_acksetdigpinstate             (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_querydigpinstate              (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_respdigpinstate               (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_queryanalogpinvalues          (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_respanalogpinvalues           (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_setanalogpinsleepstate        (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_acksetanalogpinsleepstate     (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_queryanalogpinsleepstate      (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_respanalogpinsleepstate       (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_setdigpinsleepstate           (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_acksetdigpinsleepstate        (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_querydigpinsleepstate         (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_respdigpinsleepstate          (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_setdebugmode                  (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_acksetdebugmode               (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_setledfunctionality           (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_acksetledfunctionality        (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_rxbytesidtoid                 (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_setprogrammablesettings       (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_acksetprogrammablesettings    (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_queryprogrammablesettings     (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);
static void LOG_PACKET_log_f_respprogrammablesettings      (int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);


struct LOG_PACKET_pkt_types_struct
   {
   char *tag_terse;                             //Terse tag for the log file and so on identifying this packet type.
   int  type_byte;                              //The type byte value.
   int  length_byte_min;                        //The minimum length byte value.
   int  length_byte_max;                        //The maximum length byte value.
   int  valid_from_host;                        //TRUE if this is valid transmitted from the host microcontroller.
   int  valid_from_rf_mod;                      //TRUE if this is valid transmitted from the RF module.
   void (*logptr)(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console);  
                                                //Function that will parse the full packet and log any errors,
                                                //then log the contents of the packet.  Note that gross packet formatting
                                                //errors (bad type, length, or checksum) are handled at a higher level.  This
                                                //only needs to flag errors in a packet with a correct type, length,
                                                //and checksum.
   };


static const struct LOG_PACKET_pkt_types_struct LOG_PACKET_pkt_type_lut_a[] =
   {
      //Tabulated in same order that appear in LSR documentation.
      //p. 9
      {
      "SET_PAN_ID (0x01)",
      0x01,
      0x07, 
      0x07, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_setpanid
      },
      //p. 9
      {
      "ACK_SET_PAN_ID (0x81)",
      0x81,
      0x05, 
      0x05, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_acksetpanid
      },
      //p. 10
      {
      "QUERY_PAN_ID (0x02)",
      0x02,
      0x05, 
      0x05, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_querypanid
      },
      //p. 10
      {
      "RESP_PAN_ID (0x82)",
      0x82,
      0x07, 
      0x07, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_resppanid
      },
      //p. 11
      {
      "SET_TRANS_AD (0x03)",
      0x03,
      0x0F, 
      0x0F, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_settransad
      },
      //p. 11
      {
      "ACK_SET_TRANS_AD (0x83)",
      0x83,
      0x05, 
      0x05, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_acksettransad
      },
      //p. 12
      {
      "QUERY_TRANS_AD (0x04)",
      0x04,
      0x05, 
      0x05, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_querytransad
      },
      //p. 12
      {
      "RESP_TRANS_AD (0x84)",
      0x84,
      0x0F, 
      0x0F, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_resptransad
      },
      //p. 13
      {
      "SET_RF_CHANNEL (0x05)",
      0x05,
      0x06, 
      0x06, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_setrfchannel
      },
      //p. 13
      {
      "ACK_SET_RF_CHANNEL (0x85)",
      0x85,
      0x05, 
      0x05, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_acksetrfchannel
      },
      //p. 14
      {
      "QUERY_RF_CHANNEL (0x06)",
      0x06,
      0x05, 
      0x05, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_queryrfchannel
      },
      //p. 14
      {
      "RESP_RF_CHANNEL (0x86)",
      0x86,
      0x06, 
      0x06, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_resprfchannel
      },
      //p. 15
      {
      "EN_DIS_ALL_RF_MSGS (0x07)",
      0x07,
      0x06, 
      0x06, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_endisallrfmsgs
      },
      //p. 15
      {
      "ACK_EN_DIS_ALL_RF_MSGS (0x87)",
      0x87,
      0x05, 
      0x05, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_ackendisallrfmsgs
      },
      //p. 16
      {
      "QUERY_RX_ALL_RF_MSGS_STATUS (0x08)",
      0x08,
      0x05, 
      0x05, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_queryrxallrfmsgsstatus
      },
      //p. 16
      {
      "RESP_RX_ALL_RF_MSGS_STATUS (0x88)",
      0x88,
      0x06, 
      0x06, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_resprxallrfmsgsstatus
      },
      //p. 17
      {
      "EN_DIS_RF_ACKS_RETRIES (0x09)",
      0x09,
      0x06, 
      0x06, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_endisrfacksretries
      },
      //p. 17
      {
      "ACK_EN_DIS_RF_ACKS_RETRIES (0x89)",
      0x89,
      0x05, 
      0x05, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_ackendisrfacksretries
      },
      //p. 18
      {
      "QUERY_RF_ACKS_RETRIES_STATUS (0x0A)",
      0x0A,
      0x05, 
      0x05, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_queryrfacksretriesstatus
      },
      //p. 18
      {
      "RESP_RF_ACKS_RETRIES_STATUS (0x8A)",
      0x8A,
      0x06, 
      0x06, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_resprfacksretriesstatus
      },
      //p. 19
      {
      "SET_RADIO_FEATURES_OPTIONS (0x0B)",
      0x0B,
      0x07, 
      0x07, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_setradiofeaturesoptions
      },
      //p. 19
      {
      "ACK_SET_RADIO_FEATURES_OPTIONS (0x8B)",
      0x8B,
      0x05, 
      0x05, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_acksetradiofeaturesoptions
      },
      //p. 20
      {
      "QUERY_RADIO_FEATURES_OPTIONS (0x0C)",
      0x0C,
      0x05, 
      0x05, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_queryradiofeaturesoptions
      },
      //p. 20
      {
      "RESP_RADIO_FEATURES_OPTIONS (0x8C)",
      0x8C,
      0x07, 
      0x07, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_respradiofeaturesoptions
      },
      //p. 21
      {
      "QUERY_STATISTICS (0x0D)",
      0x0D,
      0x05, 
      0x05, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_querystatistics
      },
      //p. 21
      {
      "RESP_STATISTICS (0x8D)",
      0x8D,
      0x15, 
      0x15, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_respstatistics
      },
      //p. 22
      {
      "CLEAR_STATISTICS (0x0E)",
      0x0E,
      0x05, 
      0x05, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_clearstatistics
      },
      //p. 22
      {
      "ACK_CLEAR_STATISTICS (0x8E)",
      0x8E,
      0x05, 
      0x05, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_ackclearstatistics
      },
      //p. 23
      {
      "SET_TX_POWER_LEVEL (0x0F)",
      0x0F,
      0x06, 
      0x06, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_settxpowerlevel
      },
      //p. 23
      {
      "ACK_SET_TX_POWER_LEVEL (0x8F)",
      0x8F,
      0x05, 
      0x05, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_acksettxpowerlevel
      },
      //p. 24
      {
      "QUERY_TX_POWER_LEVEL (0x10)",
      0x10,
      0x05, 
      0x05, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_querytxpowerlevel
      },
      //p. 24
      {
      "RESP_TX_POWER_LEVEL (0x90)",
      0x90,
      0x06, 
      0x06, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_resptxpowerlevel
      },
      //p. 25
      {
      "SAVE_CFG_NVM (0x11)",
      0x11,
      0x05, 
      0x05, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_savecfgnvm
      },
      //p. 25
      {
      "ACK_SAVE_CFG_NVM (0x91)",
      0x91,
      0x05, 
      0x05, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_acksavecfgnvm
      },
      //p. 26
      {
      "QUERY_FIRMWARE_VERSION (0x12)",
      0x12,
      0x05, 
      0x05, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_queryfirmwareversion
      },
      //p. 26
      {
      "RESP_FIRMWARE_VERSION (0x92)",
      0x92,
      11, 
      43, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_respfirmwareversion
      },
      //p. 27
      {
      "SET_LOW_POWER_MODE (0x13)",
      0x13,
      0x06, 
      0x06, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_setlowpowermode
      },
      //p. 27
      {
      "ACK_SET_LOW_POWER_MODE (0x93)",
      0x93,
      0x05, 
      0x05, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_acksetlowpowermode
      },
      //p. 28
      {
      "SEND_DATA (0x14)",
      0x14,
      11, 
      255, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_senddata
      },
      //p. 28
      {
      "ACK_SEND_DATA (0x94)",
      0x94,
      0x08, 
      0x08, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_acksenddata
      },
      //p. 29
      {
      "RXED_DATA (0x95)",
      0x95,
      14, 
      255, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_rxeddata
      },

      //p. 30
      {
      "RESET_REQUEST (0x18)",
      0x18,
      0x05, 
      0x05, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_resetrequest
      },
      //p. 30
      {
      "ACK_RESET_REQUEST (0x98)",
      0x98,
      0x05, 
      0x05, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_ackresetrequest
      },
      //p. 31
      {
      "SEND_MSG_APP (0x19)",
      0x19,
      6, 
      255, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_sendmsgapp
      },
      //p. 31
      {
      "ACK_SEND_MSG_APP (0x99)",
      0x99,
      0x05, 
      0x05, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_acksendmsgapp
      },
      //p. 32
      {
      "RXED_MSG_APP (0x9A)",
      0x9A,
      6, 
      255, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_rxedmsgapp
      },
      //p. 33
      {
      "INIT_FIRMWARE_DOWNLOAD (0x1B)",
      0x1B,
      0x0F, 
      0x0F, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_initfirmwaredownload
      },
      //p. 33
      {
      "ACK_INIT_FIRMWARE_DOWNLOAD (0x9B)",
      0x9B,
      0x0E, 
      0x0E, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_ackinitfirmwaredownload
      },
      //p. 34
      {
      "TRANSFER_FIRMWARE_BLOCK (0x1C)",
      0x1C,
      0x4F, 
      0x4F, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_transferfirmwareblock
      },
      //p. 34
      {
      "ACK_TRANSFER_FIRMWARE_BLOCK (0x9C)",
      0x9C,
      0x10, 
      0x10, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_acktransferfirmwareblock
      },
      //p. 35
      {
      "TERMINATE_DOWNLOAD (0x1D)",
      0x1D,
      0x0D, 
      0x0D, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_terminatedownload
      },
      //p. 35
      {
      "ACK_TERMINATE_DOWNLOAD (0x9D)",
      0x9D,
      0x0D, 
      0x0D, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_ackterminatedownload
      },
      //p. 36
      {
      "SET_DIG_PIN_CFG (0x1E)",
      0x1E,
      0x08, 
      0x08, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_setdigpincfg
      },
      //p. 36
      {
      "ACK_SET_DIG_PIN_CFG (0x9E)",
      0x9E,
      0x05, 
      0x05, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_acksetdigpincfg
      },
      //p. 37
      {
      "QUERY_DIG_PIN_CFG (0x1F)",
      0x1F,
      0x05, 
      0x05, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_querydigpincfg
      },
      //p. 37
      {
      "RESP_DIG_PIN_CFG (0x9F)",
      0x9F,
      0x08, 
      0x08, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_respdigpincfg
      },
      //p. 38
      {
      "SET_DIG_PIN_STATE (0x20)",
      0x20,
      0x06, 
      0x06, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_setdigpinstate
      },
      //p. 38
      {
      "ACK_SET_DIG_PIN_STATE (0xA0)",
      0xA0,
      0x05, 
      0x05, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_acksetdigpinstate
      },
      //p. 39
      {
      "QUERY_DIG_PIN_STATE (0x21)",
      0x21,
      0x05, 
      0x05, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_querydigpinstate
      },
      //p. 39
      {
      "RESP_DIG_PIN_STATE (0xA1)",
      0xA1,
      0x06, 
      0x06, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_respdigpinstate
      },
      //p. 40
      {
      "QUERY_ANALOG_PIN_VALUES (0x22)",
      0x22,
      0x05, 
      0x05, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_queryanalogpinvalues
      },
      //p. 40
      {
      "RESP_ANALOG_PIN_VALUES (0xA2)",
      0xA2,
      0x09, 
      0x09, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_respanalogpinvalues
      },
      //p. 41
      {
      "SET_ANALOG_PIN_SLEEP_STATE (0x23)",
      0x23,
      0x07, 
      0x07, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_setanalogpinsleepstate
      },
      //p. 41
      {
      "ACK_SET_ANALOG_PIN_SLEEP_STATE (0xA3)",
      0xA3,
      0x05, 
      0x05, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_acksetanalogpinsleepstate
      },
      //p. 42
      {
      "QUERY_ANALOG_PIN_SLEEP_STATE (0x24)",
      0x24,
      0x05, 
      0x05, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_queryanalogpinsleepstate
      },
      //p. 42
      {
      "RESP_ANALOG_PIN_SLEEP_STATE (0xA4)",
      0xA4,
      0x07, 
      0x07, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_respanalogpinsleepstate
      },
      //p. 43
      {
      "SET_DIG_PIN_SLEEP_STATE (0x25)",
      0x25,
      0x08, 
      0x08, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_setdigpinsleepstate
      },
      //p. 43
      {
      "ACK_SET_DIG_PIN_SLEEP_STATE (0xA5)",
      0xA5,
      0x05, 
      0x05, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_acksetdigpinsleepstate
      },
      //p. 44
      {
      "QUERY_DIG_PIN_SLEEP_STATE (0x26)",
      0x26,
      0x05, 
      0x05, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_querydigpinsleepstate
      },
      //p. 44
      {
      "RESP_DIG_PIN_SLEEP_STATE (0xA6)",
      0xA6,
      0x08, 
      0x08, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_respdigpinsleepstate
      },
      //p. 45
      {
      "SET_DEBUG_MODE (0x27)",
      0x27,
      0x06, 
      0x06, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_setdebugmode
      },
      //p. 45
      {
      "ACK_SET_DEBUG_MODE (0xA7)",
      0xA7,
      0x05, 
      0x05, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_acksetdebugmode
      },
      //p. 47
      {
      "SET_LED_FUNCTIONALITY (0x28)",
      0x28,
      0x06, 
      0x06, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_setledfunctionality
      },
      //p. 47
      {
      "ACK_SET_LED_FUNCTIONALITY (0xA8)",
      0xA8,
      0x05, 
      0x05, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_acksetledfunctionality
      },
      //p. 49
      {
      "RX_BYTES_ID_TO_ID (0xA9)",
      0xA9,
      14, 
      255, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_rxbytesidtoid
      },
      //p. 50
      {
      "SET_PROGRAMMABLE_SETTINGS (0x2A)",
      0x2A,
      0x15, 
      0x15, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_setprogrammablesettings
      },
      //p. 50
      {
      "ACK_SET_PROGRAMMABLE_SETTINGS (0xAA)",
      0xAA,
      0x07, 
      0x07, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_acksetprogrammablesettings
      },
      //p. 51
      {
      "QUERY_PROGRAMMABLE_SETTINGS (0x2B)",
      0x2B,
      0x05, 
      0x05, 
      TRUE,
      FALSE,
      LOG_PACKET_log_f_queryprogrammablesettings
      },
      //p. 51
      {
      "RESP_PROGRAMMABLE_SETTINGS (0xAB)",
      0xAB,
      0x15, 
      0x15, 
      FALSE,
      TRUE,
      LOG_PACKET_log_f_respprogrammablesettings
      },
   };

//Given a type and length byte, returns either:
//   a)The table index in the lookup table LOG_PACKET_pkt_type_lut_a[] corresponding to the 
//     information table entry.  This will be a non-negative number.
//   b)-1 to signal that the type byte is invalid.
//   c)-2 to signal that the type byte is valid but the length is invalid.
//
static int LOG_PACKET_type_length_lookup_a(int in_type, int in_length)
   {
   int i;

   for (i=0; i < (sizeof(LOG_PACKET_pkt_type_lut_a)/sizeof(LOG_PACKET_pkt_type_lut_a[0])); i++)
      {
      if (LOG_PACKET_pkt_type_lut_a[i].type_byte == in_type)
         {
         if (
               (in_length >= LOG_PACKET_pkt_type_lut_a[i].length_byte_min) 
               && 
               (in_length <= LOG_PACKET_pkt_type_lut_a[i].length_byte_max)
            )
            {
            //Type and length are consistent.  Return the index.
            return(i);
            }
         else
            {
            //Type is OK, but length is not.
            return(-2);
            }
         }
      }

   //If we're here, couldn't find a match on the type.
   return(-1);
   }


//Logs the bytes of a message.
static void LOG_PACKET_log_bytes(const struct __timeb64 *in_ts,
                                 QCHAR_TSE *in_pkts, 
                                 int in_npkts, 
                                 unsigned in_messagetype, 
				                     unsigned in_whichlogs)
   {
   int i, j, k;
   const int bytes_per_line = 14;
   int nlines;
   char buf[250];
   char buf_sub[250];

   nlines = (in_npkts + bytes_per_line - 1) / bytes_per_line;

   for (i=0; i<nlines; i++)
      {
      strcpy_s(buf, sizeof(buf), "     ");

      for (j=0; j<bytes_per_line; j++)
         {
         k = i * bytes_per_line + j;

         if (k >= in_npkts)
            break;

         sprintf_s(buf_sub, sizeof(buf_sub), "<%02X>", ((int)in_pkts[k].c) & 0xFF);
         strcat_s(buf, sizeof(buf), buf_sub);
         }

      LOG_write_ls(in_ts, 
                   in_messagetype, 
                   in_whichlogs, 
                   buf);
      }
   }


//This is the generic packet printer.  It is called when no more specific handler has been written.
//
static void LOG_PACKET_log_f_generic(int in_channel, 
                                     const struct __timeb64 *in_ts, 
                                     QCHAR_TSE *in_pkts, 
                                     int in_npkts, 
                                     int in_lutblentry, 
                                     int in_mirror_to_console,
                                     struct __timeb64 *t_last_msg,  //Static time of last message.
                                     int *first_time                //Static version of whether this is the first time.
                                     )
   {
   int cspan;
   int mdelta;
   char buf[250];

   if (*first_time)
      {
      memcpy(t_last_msg, &(in_pkts[0].ts), sizeof(*t_last_msg));
      *first_time = FALSE;
      }

   cspan = MISCFUNC_timb64_diff_bounded_ms(&(in_pkts[0].ts), &(in_pkts[in_npkts-1].ts));
   mdelta = MISCFUNC_timb64_diff_bounded_ms(t_last_msg, &(in_pkts[0].ts));
   memcpy(t_last_msg, &(in_pkts[0].ts), sizeof(*t_last_msg));

   sprintf_s(buf, sizeof(buf), "CH%02d:%s.", in_channel, LOG_PACKET_pkt_type_lut_a[in_lutblentry].tag_terse);

   LOG_write_ls(&(in_pkts[0].ts), 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);

   sprintf_s(buf, sizeof(buf), "     cspan=%d, mdelta=%d.", cspan, mdelta);

   LOG_write_ls(&(in_pkts[0].ts), 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);

   //The header.
   LOG_PACKET_log_bytes(&(in_pkts[0].ts),
                        in_pkts, 
                        3, 
                        LOG_MT_ROUTINE, 
				            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP));
   //The payload.
   LOG_PACKET_log_bytes(&(in_pkts[0].ts),
                        in_pkts+3, 
                        in_npkts-5, 
                        LOG_MT_ROUTINE, 
				            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP));
   //The trailer.
   LOG_PACKET_log_bytes(&(in_pkts[0].ts),
                        in_pkts+in_npkts-2, 
                        2, 
                        LOG_MT_ROUTINE, 
				            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP));
   }


static void LOG_PACKET_log_f_setpanid(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_acksetpanid(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_querypanid(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_resppanid(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_settransad(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   int cspan;
   int mdelta;
   int translongad[8];
   int transshortad[2];
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;
   char buf[250];

   if (first_time)
      {
      memcpy(&t_last_msg, &(in_pkts[0].ts), sizeof(t_last_msg));
      first_time = FALSE;
      }

   cspan = MISCFUNC_timb64_diff_bounded_ms(&(in_pkts[0].ts), &(in_pkts[in_npkts-1].ts));
   mdelta = MISCFUNC_timb64_diff_bounded_ms(&t_last_msg, &(in_pkts[0].ts));
   memcpy(&t_last_msg, &(in_pkts[0].ts), sizeof(t_last_msg));

   sprintf_s(buf, sizeof(buf), "CH%02d:%s.", in_channel, LOG_PACKET_pkt_type_lut_a[in_lutblentry].tag_terse);

   LOG_write_ls(&(in_pkts[0].ts), 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);

   sprintf_s(buf, sizeof(buf), "     cspan=%d, mdelta=%d.", cspan, mdelta);

   LOG_write_ls(&(in_pkts[0].ts), 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);

   //The header.
   LOG_PACKET_log_bytes(&(in_pkts[0].ts),
                        in_pkts, 
                        3, 
                        LOG_MT_ROUTINE, 
				            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP));
   //The payload.
   LOG_PACKET_log_bytes(&(in_pkts[0].ts),
                        in_pkts+3, 
                        in_npkts-5, 
                        LOG_MT_ROUTINE, 
				            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP));
   //The trailer.
   LOG_PACKET_log_bytes(&(in_pkts[0].ts),
                        in_pkts+in_npkts-2, 
                        2, 
                        LOG_MT_ROUTINE, 
				            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP));

   translongad[7]  = ((int)in_pkts[ 3].c) & 0xFF;
   translongad[6]  = ((int)in_pkts[ 4].c) & 0xFF;
   translongad[5]  = ((int)in_pkts[ 5].c) & 0xFF;
   translongad[4]  = ((int)in_pkts[ 6].c) & 0xFF;
   translongad[3]  = ((int)in_pkts[ 7].c) & 0xFF;
   translongad[2]  = ((int)in_pkts[ 8].c) & 0xFF;
   translongad[1]  = ((int)in_pkts[ 9].c) & 0xFF;
   translongad[0]  = ((int)in_pkts[10].c) & 0xFF;

   transshortad[1] = ((int)in_pkts[11].c) & 0xFF;
   transshortad[0] = ((int)in_pkts[12].c) & 0xFF;

   sprintf_s(buf, sizeof(buf), "     TRANS_LONG_AD: 0x%02X%02X%02X%02X%02X%02X%02X%02X, TRANS_SHORT_AD: 0x%02X%02X.", 
             translongad[0],
             translongad[1],
             translongad[2],
             translongad[3],
             translongad[4],
             translongad[5],
             translongad[6],
             translongad[7],
             transshortad[0],
             transshortad[1]);

   LOG_write_ls(&(in_pkts[0].ts), 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);
   }

   
static void LOG_PACKET_log_f_acksettransad(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_querytransad(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_resptransad(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }


static void LOG_PACKET_log_f_setrfchannel(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }


static void LOG_PACKET_log_f_acksetrfchannel(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }


static void LOG_PACKET_log_f_queryrfchannel(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }


static void LOG_PACKET_log_f_resprfchannel(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }


static void LOG_PACKET_log_f_endisallrfmsgs(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }


static void LOG_PACKET_log_f_ackendisallrfmsgs(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }


static void LOG_PACKET_log_f_queryrxallrfmsgsstatus(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }


static void LOG_PACKET_log_f_resprxallrfmsgsstatus(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }


static void LOG_PACKET_log_f_endisrfacksretries(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

static void LOG_PACKET_log_f_ackendisrfacksretries(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }


static void LOG_PACKET_log_f_queryrfacksretriesstatus(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }


static void LOG_PACKET_log_f_resprfacksretriesstatus(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_setradiofeaturesoptions(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_acksetradiofeaturesoptions(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_queryradiofeaturesoptions(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_respradiofeaturesoptions(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_querystatistics(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_respstatistics(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_clearstatistics(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_ackclearstatistics(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_settxpowerlevel(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_acksettxpowerlevel(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_querytxpowerlevel(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_resptxpowerlevel(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_savecfgnvm(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_acksavecfgnvm(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_queryfirmwareversion(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_respfirmwareversion(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_setlowpowermode(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_acksetlowpowermode(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }


static void LOG_PACKET_log_f_senddata(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   int idx;
   int cspan;
   int mdelta;
   int packetid;
   int targetsender;
   int addressmode;
   int desttransad[8];
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;
   char buf[250];

   if (first_time)
      {
      memcpy(&t_last_msg, &(in_pkts[0].ts), sizeof(t_last_msg));
      first_time = FALSE;
      }

   cspan = MISCFUNC_timb64_diff_bounded_ms(&(in_pkts[0].ts), &(in_pkts[in_npkts-1].ts));
   mdelta = MISCFUNC_timb64_diff_bounded_ms(&t_last_msg, &(in_pkts[0].ts));
   memcpy(&t_last_msg, &(in_pkts[0].ts), sizeof(t_last_msg));

   sprintf_s(buf, sizeof(buf), "CH%02d:%s.", in_channel, LOG_PACKET_pkt_type_lut_a[in_lutblentry].tag_terse);

   LOG_write_ls(&(in_pkts[0].ts), 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);

   sprintf_s(buf, sizeof(buf), "     cspan=%d, mdelta=%d.", cspan, mdelta);

   LOG_write_ls(&(in_pkts[0].ts), 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);

   //The header.
   LOG_PACKET_log_bytes(&(in_pkts[0].ts),
                        in_pkts, 
                        3, 
                        LOG_MT_ROUTINE, 
				            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP));
   //The payload.
   LOG_PACKET_log_bytes(&(in_pkts[0].ts),
                        in_pkts+3, 
                        in_npkts-5, 
                        LOG_MT_ROUTINE, 
				            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP));
   //The trailer.
   LOG_PACKET_log_bytes(&(in_pkts[0].ts),
                        in_pkts+in_npkts-2, 
                        2, 
                        LOG_MT_ROUTINE, 
				            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP));

   packetid     = ((int)in_pkts[3].c) & 0xFF;
   targetsender = ((int)in_pkts[4].c) & 0xFF;
   addressmode  = ((int)in_pkts[5].c) & 0xFF;

   sprintf_s(buf, sizeof(buf), "     PACKET_ID: 0x%02X, TARGET_SENDER: 0x%02X, ADDRESS_MODE: 0x%02X.", 
             packetid,
             targetsender,
             addressmode
             );

   LOG_write_ls(&(in_pkts[0].ts), 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);

   //Flag a bad address mode if it exists.
   if ((addressmode != 0x00) && (addressmode != 0x10))
      {
      sprintf_s(buf, sizeof(buf), "CH%02d:ADDRESS_MODE error in %s.", in_channel, LOG_PACKET_pkt_type_lut_a[in_lutblentry].tag_terse);

      LOG_write_ls(&(in_pkts[0].ts), 
                   LOG_MT_ALERT, 
                   LOG_LI_PKT | LOG_LI_ALERT | LOG_LI_COMP | LOG_LI_STDOUT, 
                   buf);

      sprintf_s(buf, sizeof(buf), "     ADDRESS_MODE: 0x%02X.", addressmode);

      LOG_write_ls(&(in_pkts[0].ts), 
                   LOG_MT_ALERT, 
                   LOG_LI_PKT | LOG_LI_ALERT | LOG_LI_COMP | LOG_LI_STDOUT, 
                   buf);
      }

   //Form up the destination address.  It may be short or long.
   FillMemory(desttransad, sizeof(desttransad), 0);

   idx = 6;
   if (in_npkts > idx)
      {
      desttransad[7] = ((int)in_pkts[idx].c) & 0xFF;
      }
   idx++;
   if (in_npkts > idx)
      {
      desttransad[6] = ((int)in_pkts[idx].c) & 0xFF;
      }
   idx++;

   if (addressmode & 0xf0) //Long address.
      {
      if (in_npkts > idx)
         {
         desttransad[5] = ((int)in_pkts[idx].c) & 0xFF;
         }
      idx++;
      if (in_npkts > idx)
         {
         desttransad[4] = ((int)in_pkts[idx].c) & 0xFF;
         }
      idx++;
      if (in_npkts > idx)
         {
         desttransad[3] = ((int)in_pkts[idx].c) & 0xFF;
         }
      idx++;
      if (in_npkts > idx)
         {
         desttransad[2] = ((int)in_pkts[idx].c) & 0xFF;
         }
      idx++;
      if (in_npkts > idx)
         {
         desttransad[1] = ((int)in_pkts[idx].c) & 0xFF;
         }
      idx++;
      if (in_npkts > idx)
         {
         desttransad[0] = ((int)in_pkts[idx].c) & 0xFF;
         }
      idx++;
      }

   //If we've overshot the data area (and the assumption is made that there is at least one
   //byte of data), this means that the address modes were inconsistent with the message length.
   //This is an error.
   if (idx > (in_npkts - 3))
      {
      sprintf_s(buf, sizeof(buf), "CH%02d:ADDRESS_MODE and message length error in %s.", in_channel, LOG_PACKET_pkt_type_lut_a[in_lutblentry].tag_terse);

      LOG_write_ls(&(in_pkts[0].ts), 
                   LOG_MT_ALERT, 
                   LOG_LI_PKT | LOG_LI_ALERT | LOG_LI_COMP | LOG_LI_STDOUT, 
                   buf);
      }

   //Emit the destination transceiver address.  There is some variability due
   //to the address mode.
   if (addressmode & 0xf0) //Destination transceiver long address.
      {
      sprintf_s(buf, 
                sizeof(buf), 
                "     DST_TRANS_AD: 0x%02X%02X%02X%02X02X%02X%02X%02X.", 
                ((int)desttransad[0]) & 0xFF,
                ((int)desttransad[1]) & 0xFF,
                ((int)desttransad[2]) & 0xFF,
                ((int)desttransad[3]) & 0xFF,
                ((int)desttransad[4]) & 0xFF,
                ((int)desttransad[5]) & 0xFF,
                ((int)desttransad[6]) & 0xFF,
                ((int)desttransad[7]) & 0xFF);
      }
   else
      {
      sprintf_s(buf, 
                sizeof(buf), 
                "     DST_TRANS_AD: 0x%02X%02X.", 
                ((int)desttransad[6]) & 0xFF,
                ((int)desttransad[7]) & 0xFF);
      }

   //And write the line to the log.
   LOG_write_ls(&(in_pkts[0].ts), 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);

   //Write the data bytes.
   LOG_write_ls(&(in_pkts[0].ts), 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                "     DATA:");

   LOG_PACKET_log_bytes(&(in_pkts[0].ts),
                        in_pkts + idx, 
                        in_npkts - idx - 2,
                        LOG_MT_ROUTINE, 
				            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP));
   }

   
static void LOG_PACKET_log_f_acksenddata(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   int cspan;
   int mdelta;
   int packetid;
   int acknack;
   int nretries;
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;
   char buf[250];

   if (first_time)
      {
      memcpy(&t_last_msg, &(in_pkts[0].ts), sizeof(t_last_msg));
      first_time = FALSE;
      }

   cspan = MISCFUNC_timb64_diff_bounded_ms(&(in_pkts[0].ts), &(in_pkts[in_npkts-1].ts));
   mdelta = MISCFUNC_timb64_diff_bounded_ms(&t_last_msg, &(in_pkts[0].ts));
   memcpy(&t_last_msg, &(in_pkts[0].ts), sizeof(t_last_msg));

   sprintf_s(buf, sizeof(buf), "CH%02d:%s.", in_channel, LOG_PACKET_pkt_type_lut_a[in_lutblentry].tag_terse);

   LOG_write_ls(&(in_pkts[0].ts), 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);

   sprintf_s(buf, sizeof(buf), "     cspan=%d, mdelta=%d.", cspan, mdelta);

   LOG_write_ls(&(in_pkts[0].ts), 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);

   //The header.
   LOG_PACKET_log_bytes(&(in_pkts[0].ts),
                        in_pkts, 
                        3, 
                        LOG_MT_ROUTINE, 
				            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP));
   //The payload.
   LOG_PACKET_log_bytes(&(in_pkts[0].ts),
                        in_pkts+3, 
                        in_npkts-5, 
                        LOG_MT_ROUTINE, 
				            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP));
   //The trailer.
   LOG_PACKET_log_bytes(&(in_pkts[0].ts),
                        in_pkts+in_npkts-2, 
                        2, 
                        LOG_MT_ROUTINE, 
				            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP));

   packetid  = ((int)in_pkts[ 3].c) & 0xFF;
   acknack   = ((int)in_pkts[ 4].c) & 0xFF;
   nretries  = ((int)in_pkts[ 5].c) & 0xFF;

   sprintf_s(buf, sizeof(buf), "     PACKET_ID: 0x%02X, ACK_NACK: 0x%02X, NUM_RETRIES: 0x%02X.", 
             packetid,
             acknack,
             nretries
             );

   LOG_write_ls(&(in_pkts[0].ts), 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);

   if (acknack != 0x01)
      {
      sprintf_s(buf, sizeof(buf), "CH%02d:ACK_NACK error in %s.", in_channel, LOG_PACKET_pkt_type_lut_a[in_lutblentry].tag_terse);

      LOG_write_ls(&(in_pkts[0].ts), 
                   LOG_MT_ALERT, 
                   LOG_LI_PKT | LOG_LI_ALERT | LOG_LI_COMP | LOG_LI_STDOUT, 
                   buf);

      sprintf_s(buf, sizeof(buf), "     ACK_NACK: 0x%02X.", acknack);

      LOG_write_ls(&(in_pkts[0].ts), 
                   LOG_MT_ALERT, 
                   LOG_LI_PKT | LOG_LI_ALERT | LOG_LI_COMP | LOG_LI_STDOUT, 
                   buf);
      }
   }

   
static void LOG_PACKET_log_f_rxeddata(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   int idx;
   int cspan;
   int mdelta;
   int packetid;
   int targetsender;
   int lqi;
   int addressmode;
   int desttransad[8];
   int srctransad[8];
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;
   char buf[250];

   if (first_time)
      {
      memcpy(&t_last_msg, &(in_pkts[0].ts), sizeof(t_last_msg));
      first_time = FALSE;
      }

   cspan = MISCFUNC_timb64_diff_bounded_ms(&(in_pkts[0].ts), &(in_pkts[in_npkts-1].ts));
   mdelta = MISCFUNC_timb64_diff_bounded_ms(&t_last_msg, &(in_pkts[0].ts));
   memcpy(&t_last_msg, &(in_pkts[0].ts), sizeof(t_last_msg));

   sprintf_s(buf, sizeof(buf), "CH%02d:%s.", in_channel, LOG_PACKET_pkt_type_lut_a[in_lutblentry].tag_terse);

   LOG_write_ls(&(in_pkts[0].ts), 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);

   sprintf_s(buf, sizeof(buf), "     cspan=%d, mdelta=%d.", cspan, mdelta);

   LOG_write_ls(&(in_pkts[0].ts), 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);

   //The header.
   LOG_PACKET_log_bytes(&(in_pkts[0].ts),
                        in_pkts, 
                        3, 
                        LOG_MT_ROUTINE, 
				            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP));
   //The payload.
   LOG_PACKET_log_bytes(&(in_pkts[0].ts),
                        in_pkts+3, 
                        in_npkts-5, 
                        LOG_MT_ROUTINE, 
				            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP));
   //The trailer.
   LOG_PACKET_log_bytes(&(in_pkts[0].ts),
                        in_pkts+in_npkts-2, 
                        2, 
                        LOG_MT_ROUTINE, 
				            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP));

   packetid     = ((int)in_pkts[3].c) & 0xFF;
   targetsender = ((int)in_pkts[4].c) & 0xFF;
   lqi          = ((int)in_pkts[5].c) & 0xFF;

   sprintf_s(buf, sizeof(buf), "     PACKET_ID: 0x%02X, TARGET_SENDER: 0x%02X, LQI: 0x%02X.", 
             packetid,
             targetsender,
             lqi
             );

   LOG_write_ls(&(in_pkts[0].ts), 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);

   addressmode = ((int)in_pkts[6].c) & 0xFF;

   sprintf_s(buf, sizeof(buf), "     ADDRESS_MODE: 0x%02X.", 
             addressmode);

   LOG_write_ls(&(in_pkts[0].ts), 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);

   //Flag a bad address mode if it exists.
   if ((addressmode != 0x00) && (addressmode != 0x01) && (addressmode != 0x10) && (addressmode != 0x11))
      {
      sprintf_s(buf, sizeof(buf), "CH%02d:ADDRESS_MODE error in %s.", in_channel, LOG_PACKET_pkt_type_lut_a[in_lutblentry].tag_terse);

      LOG_write_ls(&(in_pkts[0].ts), 
                   LOG_MT_ALERT, 
                   LOG_LI_PKT | LOG_LI_ALERT | LOG_LI_COMP | LOG_LI_STDOUT, 
                   buf);

      sprintf_s(buf, sizeof(buf), "     ADDRESS_MODE: 0x%02X.", addressmode);

      LOG_write_ls(&(in_pkts[0].ts), 
                   LOG_MT_ALERT, 
                   LOG_LI_PKT | LOG_LI_ALERT | LOG_LI_COMP | LOG_LI_STDOUT, 
                   buf);
      }

   //Form up the destination address.  It may be short or long.
   FillMemory(desttransad, sizeof(desttransad), 0);

   idx = 7;
   if (in_npkts > idx)
      {
      desttransad[7] = ((int)in_pkts[idx].c) & 0xFF;
      }
   idx++;
   if (in_npkts > idx)
      {
      desttransad[6] = ((int)in_pkts[idx].c) & 0xFF;
      }
   idx++;

   if (addressmode & 0xf0) //Long address.
      {
      if (in_npkts > idx)
         {
         desttransad[5] = ((int)in_pkts[idx].c) & 0xFF;
         }
      idx++;
      if (in_npkts > idx)
         {
         desttransad[4] = ((int)in_pkts[idx].c) & 0xFF;
         }
      idx++;
      if (in_npkts > idx)
         {
         desttransad[3] = ((int)in_pkts[idx].c) & 0xFF;
         }
      idx++;
      if (in_npkts > idx)
         {
         desttransad[2] = ((int)in_pkts[idx].c) & 0xFF;
         }
      idx++;
      if (in_npkts > idx)
         {
         desttransad[1] = ((int)in_pkts[idx].c) & 0xFF;
         }
      idx++;
      if (in_npkts > idx)
         {
         desttransad[0] = ((int)in_pkts[idx].c) & 0xFF;
         }
      idx++;
      }

   //Form up the source address.  It may be short or long.
   FillMemory(srctransad, sizeof(srctransad), 0);

   if (in_npkts > idx)
      {
      srctransad[7] = ((int)in_pkts[idx].c) & 0xFF;
      }
   idx++;
   if (in_npkts > idx)
      {
      srctransad[6] = ((int)in_pkts[idx].c) & 0xFF;
      }
   idx++;

   if (addressmode & 0x0f) //Long address.
      {
      if (in_npkts > idx)
         {
         srctransad[5] = ((int)in_pkts[idx].c) & 0xFF;
         }
      idx++;
      if (in_npkts > idx)
         {
         srctransad[4] = ((int)in_pkts[idx].c) & 0xFF;
         }
      idx++;
      if (in_npkts > idx)
         {
         srctransad[3] = ((int)in_pkts[idx].c) & 0xFF;
         }
      idx++;
      if (in_npkts > idx)
         {
         srctransad[2] = ((int)in_pkts[idx].c) & 0xFF;
         }
      idx++;
      if (in_npkts > idx)
         {
         srctransad[1] = ((int)in_pkts[idx].c) & 0xFF;
         }
      idx++;
      if (in_npkts > idx)
         {
         srctransad[0] = ((int)in_pkts[idx].c) & 0xFF;
         }
      idx++;
      }

   //If we've overshot the data area (and the assumption is made that there is at least one
   //byte of data), this means that the address modes were inconsistent with the message length.
   //This is an error.
   if (idx > (in_npkts - 3))
      {
      sprintf_s(buf, sizeof(buf), "CH%02d:ADDRESS_MODE and message length error in %s.", in_channel, LOG_PACKET_pkt_type_lut_a[in_lutblentry].tag_terse);

      LOG_write_ls(&(in_pkts[0].ts), 
                   LOG_MT_ALERT, 
                   LOG_LI_PKT | LOG_LI_ALERT | LOG_LI_COMP | LOG_LI_STDOUT, 
                   buf);
      }

   //Emit the destination transceiver and source transceiver address.  There is some variability due
   //to the address mode.
      {
      char minibuf[250];

      strcpy_s(buf, sizeof(buf), "     ");

      if (addressmode & 0xf0) //Destination transceiver long address.
         {
         sprintf_s(minibuf, 
                   sizeof(minibuf), 
                   "DST_TRANS_AD: 0x%02X%02X%02X%02X02X%02X%02X%02X,", 
                   ((int)desttransad[0]) & 0xFF,
                   ((int)desttransad[1]) & 0xFF,
                   ((int)desttransad[2]) & 0xFF,
                   ((int)desttransad[3]) & 0xFF,
                   ((int)desttransad[4]) & 0xFF,
                   ((int)desttransad[5]) & 0xFF,
                   ((int)desttransad[6]) & 0xFF,
                   ((int)desttransad[7]) & 0xFF);
         }
      else
         {
         sprintf_s(minibuf, 
                   sizeof(minibuf), 
                   "DST_TRANS_AD: 0x%02X%02X,", 
                   ((int)desttransad[6]) & 0xFF,
                   ((int)desttransad[7]) & 0xFF);
         }

      //Add in the string and some space.
      strcat_s(buf, sizeof(buf), minibuf);
      strcat_s(buf, sizeof(buf), " ");

      if (addressmode & 0x0f) //Source transceiver long address.
         {
         sprintf_s(minibuf, 
                   sizeof(minibuf), 
                   "SRC_TRANS_AD: 0x%02X%02X%02X%02X02X%02X%02X%02X.", 
                   ((int)srctransad[0]) & 0xFF,
                   ((int)srctransad[1]) & 0xFF,
                   ((int)srctransad[2]) & 0xFF,
                   ((int)srctransad[3]) & 0xFF,
                   ((int)srctransad[4]) & 0xFF,
                   ((int)srctransad[5]) & 0xFF,
                   ((int)srctransad[6]) & 0xFF,
                   ((int)srctransad[7]) & 0xFF);
         }
      else
         {
         sprintf_s(minibuf, 
                   sizeof(minibuf), 
                   "SRC_TRANS_AD: 0x%02X%02X.", 
                   ((int)srctransad[6]) & 0xFF,
                   ((int)srctransad[7]) & 0xFF);
         }

      //Add in the string.
      strcat_s(buf, sizeof(buf), minibuf);

      //And write the line to the log.
      LOG_write_ls(&(in_pkts[0].ts), 
                   LOG_MT_ROUTINE, 
                   (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                   buf);
      }

   //Write the data bytes.
   LOG_write_ls(&(in_pkts[0].ts), 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                "     DATA:");

   LOG_PACKET_log_bytes(&(in_pkts[0].ts),
                        in_pkts + idx, 
                        in_npkts - idx - 2,
                        LOG_MT_ROUTINE, 
				            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP));
   }

   
static void LOG_PACKET_log_f_resetrequest(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_ackresetrequest(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_sendmsgapp(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_acksendmsgapp(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_rxedmsgapp(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_initfirmwaredownload(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_ackinitfirmwaredownload(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_transferfirmwareblock(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_acktransferfirmwareblock(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_terminatedownload(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_ackterminatedownload(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_setdigpincfg(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_acksetdigpincfg(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_querydigpincfg(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_respdigpincfg(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_setdigpinstate(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_acksetdigpinstate(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_querydigpinstate(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_respdigpinstate(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_queryanalogpinvalues(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_respanalogpinvalues(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_setanalogpinsleepstate(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_acksetanalogpinsleepstate(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_queryanalogpinsleepstate(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_respanalogpinsleepstate(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_setdigpinsleepstate(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_acksetdigpinsleepstate(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_querydigpinsleepstate(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_respdigpinsleepstate(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_setdebugmode(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_acksetdebugmode(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_setledfunctionality(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   int cspan;
   int mdelta;
   int ledmode;
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;
   char buf[250];

   if (first_time)
      {
      memcpy(&t_last_msg, &(in_pkts[0].ts), sizeof(t_last_msg));
      first_time = FALSE;
      }

   cspan = MISCFUNC_timb64_diff_bounded_ms(&(in_pkts[0].ts), &(in_pkts[in_npkts-1].ts));
   mdelta = MISCFUNC_timb64_diff_bounded_ms(&t_last_msg, &(in_pkts[0].ts));
   memcpy(&t_last_msg, &(in_pkts[0].ts), sizeof(t_last_msg));

   sprintf_s(buf, sizeof(buf), "CH%02d:%s.", in_channel, LOG_PACKET_pkt_type_lut_a[in_lutblentry].tag_terse);

   LOG_write_ls(&(in_pkts[0].ts), 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);

   sprintf_s(buf, sizeof(buf), "     cspan=%d, mdelta=%d.", cspan, mdelta);

   LOG_write_ls(&(in_pkts[0].ts), 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);

   //The header.
   LOG_PACKET_log_bytes(&(in_pkts[0].ts),
                        in_pkts, 
                        3, 
                        LOG_MT_ROUTINE, 
				            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP));
   //The payload.
   LOG_PACKET_log_bytes(&(in_pkts[0].ts),
                        in_pkts+3, 
                        in_npkts-5, 
                        LOG_MT_ROUTINE, 
				            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP));
   //The trailer.
   LOG_PACKET_log_bytes(&(in_pkts[0].ts),
                        in_pkts+in_npkts-2, 
                        2, 
                        LOG_MT_ROUTINE, 
				            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP));

   ledmode  = ((int)in_pkts[3].c) & 0xFF;

   sprintf_s(buf, sizeof(buf), "     LED_MODE: 0x%02X.", 
             ledmode);

   LOG_write_ls(&(in_pkts[0].ts), 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);
   if (ledmode & 0xF8)  //Bits set in the mode that shouldn't be.
      {
      sprintf_s(buf, sizeof(buf), "CH%02d:LED_MODE error in %s.", in_channel, LOG_PACKET_pkt_type_lut_a[in_lutblentry].tag_terse);

      LOG_write_ls(&(in_pkts[0].ts), 
                   LOG_MT_ALERT, 
                   LOG_LI_PKT | LOG_LI_ALERT | LOG_LI_COMP | LOG_LI_STDOUT, 
                   buf);

      sprintf_s(buf, sizeof(buf), "     LED_MODE: 0x%02X.", ledmode);

      LOG_write_ls(&(in_pkts[0].ts), 
                   LOG_MT_ALERT, 
                   LOG_LI_PKT | LOG_LI_ALERT | LOG_LI_COMP | LOG_LI_STDOUT, 
                   buf);
      }
   }

   
static void LOG_PACKET_log_f_acksetledfunctionality(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_rxbytesidtoid(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;

   LOG_PACKET_log_f_generic(in_channel, 
                            in_ts, 
                            in_pkts, 
                            in_npkts, 
                            in_lutblentry, 
                            in_mirror_to_console,
                            &t_last_msg,
                            &first_time);
   }

   
static void LOG_PACKET_log_f_setprogrammablesettings(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   int cspan;
   int mdelta;
   int panidlsb, panidmsb, panid;
   int rfchannel;
   int receive_all;
   int rfacksretries;
   int rfpowerlevel;
   int txcvrlongad[8];
   int txcvrshortad[2];
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;
   char buf[250];

   if (first_time)
      {
      memcpy(&t_last_msg, &(in_pkts[0].ts), sizeof(t_last_msg));
      first_time = FALSE;
      }

   cspan = MISCFUNC_timb64_diff_bounded_ms(&(in_pkts[0].ts), &(in_pkts[in_npkts-1].ts));
   mdelta = MISCFUNC_timb64_diff_bounded_ms(&t_last_msg, &(in_pkts[0].ts));
   memcpy(&t_last_msg, &(in_pkts[0].ts), sizeof(t_last_msg));

   sprintf_s(buf, sizeof(buf), "CH%02d:%s.", in_channel, LOG_PACKET_pkt_type_lut_a[in_lutblentry].tag_terse);

   LOG_write_ls(&(in_pkts[0].ts), 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);

   sprintf_s(buf, sizeof(buf), "     cspan=%d, mdelta=%d.", cspan, mdelta);

   LOG_write_ls(&(in_pkts[0].ts), 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);

   //The header.
   LOG_PACKET_log_bytes(&(in_pkts[0].ts),
                        in_pkts, 
                        3, 
                        LOG_MT_ROUTINE, 
				            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP));
   //The payload.
   LOG_PACKET_log_bytes(&(in_pkts[0].ts),
                        in_pkts+3, 
                        in_npkts-5, 
                        LOG_MT_ROUTINE, 
				            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP));
   //The trailer.
   LOG_PACKET_log_bytes(&(in_pkts[0].ts),
                        in_pkts+in_npkts-2, 
                        2, 
                        LOG_MT_ROUTINE, 
				            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP));

   panidlsb = ((int)in_pkts[3].c) & 0xFF;
   panidmsb = ((int)in_pkts[4].c) & 0xFF;
   panid = 256 * panidmsb + panidlsb;

   txcvrlongad[7] = ((int)in_pkts[ 5].c) & 0xFF;
   txcvrlongad[6] = ((int)in_pkts[ 6].c) & 0xFF;
   txcvrlongad[5] = ((int)in_pkts[ 7].c) & 0xFF;
   txcvrlongad[4] = ((int)in_pkts[ 8].c) & 0xFF;
   txcvrlongad[3] = ((int)in_pkts[ 9].c) & 0xFF;
   txcvrlongad[2] = ((int)in_pkts[10].c) & 0xFF;
   txcvrlongad[1] = ((int)in_pkts[11].c) & 0xFF;
   txcvrlongad[0] = ((int)in_pkts[12].c) & 0xFF;

   sprintf_s(buf, sizeof(buf), "     PANID: 0x%04X, TXCVR_LONG_AD: 0x%02X%02X%02X%02X%02X%02X%02X%02X.", 
             panid,
             txcvrlongad[0],
             txcvrlongad[1],
             txcvrlongad[2],
             txcvrlongad[3],
             txcvrlongad[4],
             txcvrlongad[5],
             txcvrlongad[6],
             txcvrlongad[7]
             );

   LOG_write_ls(&(in_pkts[0].ts), 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);

   txcvrshortad[1] = ((int)in_pkts[13].c) & 0xFF;
   txcvrshortad[0] = ((int)in_pkts[14].c) & 0xFF;

   rfchannel       = ((int)in_pkts[15].c) & 0xFF;

   sprintf_s(buf, sizeof(buf), "     TXCVR_SHORT_AD: 0x%02X%02X, RF_CHANNEL: 0x%02X.", 
             txcvrshortad[0],
             txcvrshortad[1],
             rfchannel
             );

   LOG_write_ls(&(in_pkts[0].ts), 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);

   receive_all    = ((int)in_pkts[16].c) & 0xFF;
   rfacksretries  = ((int)in_pkts[17].c) & 0xFF;

   sprintf_s(buf, sizeof(buf), "     RECEIVE_ALL: 0x%02X, RF_ACKS_RETRIES: 0x%02X.", 
             receive_all,
             rfacksretries
             );

   LOG_write_ls(&(in_pkts[0].ts), 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);

   rfpowerlevel  = ((int)in_pkts[18].c) & 0xFF;

   sprintf_s(buf, sizeof(buf), "     RF_POWER_LEVEL: 0x%02X.", 
             rfpowerlevel
             );

   LOG_write_ls(&(in_pkts[0].ts), 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);
   }

   
static void LOG_PACKET_log_f_acksetprogrammablesettings(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   int cspan;
   int mdelta;
   int acknack;
   int status;
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;
   char buf[250];

   if (first_time)
      {
      memcpy(&t_last_msg, &(in_pkts[0].ts), sizeof(t_last_msg));
      first_time = FALSE;
      }

   cspan = MISCFUNC_timb64_diff_bounded_ms(&(in_pkts[0].ts), &(in_pkts[in_npkts-1].ts));
   mdelta = MISCFUNC_timb64_diff_bounded_ms(&t_last_msg, &(in_pkts[0].ts));
   memcpy(&t_last_msg, &(in_pkts[0].ts), sizeof(t_last_msg));

   sprintf_s(buf, sizeof(buf), "CH%02d:%s.", in_channel, LOG_PACKET_pkt_type_lut_a[in_lutblentry].tag_terse);

   LOG_write_ls(&(in_pkts[0].ts), 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);

   sprintf_s(buf, sizeof(buf), "     cspan=%d, mdelta=%d.", cspan, mdelta);

   LOG_write_ls(&(in_pkts[0].ts), 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);

   //The header.
   LOG_PACKET_log_bytes(&(in_pkts[0].ts),
                        in_pkts, 
                        3, 
                        LOG_MT_ROUTINE, 
				            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP));
   //The payload.
   LOG_PACKET_log_bytes(&(in_pkts[0].ts),
                        in_pkts+3, 
                        in_npkts-5, 
                        LOG_MT_ROUTINE, 
				            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP));
   //The trailer.
   LOG_PACKET_log_bytes(&(in_pkts[0].ts),
                        in_pkts+in_npkts-2, 
                        2, 
                        LOG_MT_ROUTINE, 
				            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP));

   acknack   = ((int)in_pkts[ 3].c) & 0xFF;
   status    = ((int)in_pkts[ 4].c) & 0xFF;

   sprintf_s(buf, sizeof(buf), "     ACK_NACK: 0x%02X, STATUS: 0x%02X.", 
             acknack,
             status
             );

   LOG_write_ls(&(in_pkts[0].ts), 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);

   if (acknack != 0x01)
      {
      sprintf_s(buf, sizeof(buf), "CH%02d:ACK_NACK error in %s.", in_channel, LOG_PACKET_pkt_type_lut_a[in_lutblentry].tag_terse);

      LOG_write_ls(&(in_pkts[0].ts), 
                   LOG_MT_ALERT, 
                   LOG_LI_PKT | LOG_LI_ALERT | LOG_LI_COMP | LOG_LI_STDOUT, 
                   buf);

      sprintf_s(buf, sizeof(buf), "     ACK_NACK: 0x%02X, STATUS: 0x%02X.", acknack, status);

      LOG_write_ls(&(in_pkts[0].ts), 
                   LOG_MT_ALERT, 
                   LOG_LI_PKT | LOG_LI_ALERT | LOG_LI_COMP | LOG_LI_STDOUT, 
                   buf);
      }
   }

   
static void LOG_PACKET_log_f_queryprogrammablesettings(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   int cspan;
   int mdelta;
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;
   char buf[250];

   if (first_time)
      {
      memcpy(&t_last_msg, &(in_pkts[0].ts), sizeof(t_last_msg));
      first_time = FALSE;
      }

   cspan = MISCFUNC_timb64_diff_bounded_ms(&(in_pkts[0].ts), &(in_pkts[in_npkts-1].ts));
   mdelta = MISCFUNC_timb64_diff_bounded_ms(&t_last_msg, &(in_pkts[0].ts));
   memcpy(&t_last_msg, &(in_pkts[0].ts), sizeof(t_last_msg));

   sprintf_s(buf, sizeof(buf), "CH%02d:%s.", in_channel, LOG_PACKET_pkt_type_lut_a[in_lutblentry].tag_terse);

   LOG_write_ls(in_ts, 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);

   sprintf_s(buf, sizeof(buf), "     cspan=%d, mdelta=%d.", cspan, mdelta);

   LOG_write_ls(in_ts, 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);

   //The header.
   LOG_PACKET_log_bytes(&(in_pkts[0].ts),
                        in_pkts, 
                        3, 
                        LOG_MT_ROUTINE, 
				            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP));
   //The payload.
   LOG_PACKET_log_bytes(&(in_pkts[0].ts),
                        in_pkts+3, 
                        in_npkts-5, 
                        LOG_MT_ROUTINE, 
				            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP));
   //The trailer.
   LOG_PACKET_log_bytes(&(in_pkts[0].ts),
                        in_pkts+in_npkts-2, 
                        2, 
                        LOG_MT_ROUTINE, 
				            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP));
   }

   
static void LOG_PACKET_log_f_respprogrammablesettings(int in_channel, const struct __timeb64 *in_ts, QCHAR_TSE *in_pkts, int in_npkts, int in_lutblentry, int in_mirror_to_console)
   {
   int cspan;
   int mdelta;
   int panidlsb, panidmsb, panid;
   int rfchannel;
   int receive_all;
   int rfacksretries;
   int rfpowerlevel;
   int txcvrlongad[8];
   int txcvrshortad[2];
   static struct __timeb64 t_last_msg;
   static int first_time = TRUE;
   char buf[250];

   if (first_time)
      {
      memcpy(&t_last_msg, &(in_pkts[0].ts), sizeof(t_last_msg));
      first_time = FALSE;
      }

   cspan = MISCFUNC_timb64_diff_bounded_ms(&(in_pkts[0].ts), &(in_pkts[in_npkts-1].ts));
   mdelta = MISCFUNC_timb64_diff_bounded_ms(&t_last_msg, &(in_pkts[0].ts));
   memcpy(&t_last_msg, &(in_pkts[0].ts), sizeof(t_last_msg));

   sprintf_s(buf, sizeof(buf), "CH%02d:%s.", in_channel, LOG_PACKET_pkt_type_lut_a[in_lutblentry].tag_terse);

   LOG_write_ls(in_ts, 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);

   sprintf_s(buf, sizeof(buf), "     cspan=%d, mdelta=%d.", cspan, mdelta);

   LOG_write_ls(in_ts, 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);

   //The header.
   LOG_PACKET_log_bytes(&(in_pkts[0].ts),
                        in_pkts, 
                        3, 
                        LOG_MT_ROUTINE, 
				            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP));
   //The payload.
   LOG_PACKET_log_bytes(&(in_pkts[0].ts),
                        in_pkts+3, 
                        in_npkts-5, 
                        LOG_MT_ROUTINE, 
				            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP));
   //The trailer.
   LOG_PACKET_log_bytes(&(in_pkts[0].ts),
                        in_pkts+in_npkts-2, 
                        2, 
                        LOG_MT_ROUTINE, 
				            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP));

   panidlsb = ((int)in_pkts[3].c) & 0xFF;
   panidmsb = ((int)in_pkts[4].c) & 0xFF;
   panid = 256 * panidmsb + panidlsb;

   txcvrlongad[7] = ((int)in_pkts[ 5].c) & 0xFF;
   txcvrlongad[6] = ((int)in_pkts[ 6].c) & 0xFF;
   txcvrlongad[5] = ((int)in_pkts[ 7].c) & 0xFF;
   txcvrlongad[4] = ((int)in_pkts[ 8].c) & 0xFF;
   txcvrlongad[3] = ((int)in_pkts[ 9].c) & 0xFF;
   txcvrlongad[2] = ((int)in_pkts[10].c) & 0xFF;
   txcvrlongad[1] = ((int)in_pkts[11].c) & 0xFF;
   txcvrlongad[0] = ((int)in_pkts[12].c) & 0xFF;

   sprintf_s(buf, sizeof(buf), "     PANID: 0x%04X, TXCVR_LONG_AD: 0x%02X%02X%02X%02X%02X%02X%02X%02X.", 
             panid,
             txcvrlongad[0],
             txcvrlongad[1],
             txcvrlongad[2],
             txcvrlongad[3],
             txcvrlongad[4],
             txcvrlongad[5],
             txcvrlongad[6],
             txcvrlongad[7]
             );

   LOG_write_ls(in_ts, 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);

   txcvrshortad[1] = ((int)in_pkts[13].c) & 0xFF;
   txcvrshortad[0] = ((int)in_pkts[14].c) & 0xFF;

   rfchannel       = ((int)in_pkts[15].c) & 0xFF;

   sprintf_s(buf, sizeof(buf), "     TXCVR_SHORT_AD: 0x%02X%02X, RF_CHANNEL: 0x%02X.", 
             txcvrshortad[0],
             txcvrshortad[1],
             rfchannel
             );

   LOG_write_ls(in_ts, 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);

   receive_all    = ((int)in_pkts[16].c) & 0xFF;
   rfacksretries  = ((int)in_pkts[17].c) & 0xFF;

   sprintf_s(buf, sizeof(buf), "     RECEIVE_ALL: 0x%02X, RF_ACKS_RETRIES: 0x%02X.", 
             receive_all,
             rfacksretries
             );

   LOG_write_ls(in_ts, 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);

   rfpowerlevel  = ((int)in_pkts[18].c) & 0xFF;

   sprintf_s(buf, sizeof(buf), "     RF_POWER_LEVEL: 0x%02X.", 
             rfpowerlevel
             );

   LOG_write_ls(in_ts, 
                LOG_MT_ROUTINE, 
                (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP), 
                buf);
   }


//Returns a pointer to a string describing an event.  The string is made for announcing events
//that can't be used for a particular intended purpose.
//
//This function is not thread-safe.
//
const char *LOG_PACKET_event_text_desc_a(const QCHAR_TSE *in_ev)
   {
   static char buf[250];

   switch (in_ev->ev)
      {
      case QCHAR_EV_CHAR:
         sprintf_s(buf, sizeof(buf), "Character: 0x%02X", ((int)in_ev->c) & 0xFF);
         break;
      case QCHAR_EV_BREAK:
         sprintf_s(buf, sizeof(buf), "Event: BREAK");
         break;
      case QCHAR_EV_FRAME:
         sprintf_s(buf, sizeof(buf), "Event: FRAMING_ERROR");
         break;
      case QCHAR_EV_OVERRUN:
         sprintf_s(buf, sizeof(buf), "Event: LOW_LEVEL_OVERRUN");
         break;
      case QCHAR_EV_RXOVER:
         sprintf_s(buf, sizeof(buf), "Event: RECEIVE_Q_OVERFLOW");
         break;
      case QCHAR_EV_RXPARITY:
         sprintf_s(buf, sizeof(buf), "Event: PARITY_ERROR");
         break;
      default:
         sprintf_s(buf, sizeof(buf), "Event: INTERNAL_SOFTWARE_ERROR");
         break;
      }

   return(buf);
   }


//Discards events that can't be the start of a packet.
//
static void LOG_PACKET_non_start_discard(int in_channel, QCHAR_CCEQ *in_q, const struct __timeb64 *in_ts, int in_mirror_to_console)
   {
   int done = FALSE;
   QCHAR_TSE item;

   while (!done)
      {
      //Can't proceed if no elements in queue.
      if (! QCHAR_cceq_nelem(in_q))
         {
         done = TRUE;
         }

      //Peek at the first element.
      if (!done)
         QCHAR_cceq_peek(in_q, &item);

      //If the first element is invalid, discard it, else we're done.
      if (!done)
         {
         if ((item.ev != QCHAR_EV_CHAR) || (item.c != 0x01))
            {
            char buf[250];

            sprintf_s(buf, sizeof(buf), "CH%02d:Non-packet start event discarded: %s.", in_channel, LOG_PACKET_event_text_desc_a(&item));

            LOG_write_ls(&(item.ts), 
                         LOG_MT_ALERT, 
                         (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_ALERT | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_ALERT | LOG_LI_STDOUT), 
                         buf);
            QCHAR_cceq_get(in_q, &item);
            }
         else
            {
            //First element is apparently a start element.  We're good.
            done = TRUE;
            }
         }
      }
   }


//Resynchronizes by discarding an apparent start element that can't be used and then looking for another
//start element.
//
static void LOG_PACKET_non_start_resync_discard(int in_channel, QCHAR_CCEQ *in_q, const struct __timeb64 *in_ts, int in_mirror_to_console)
   {
   QCHAR_TSE item;

   //Can't proceed if no elements in queue.
   if (! QCHAR_cceq_nelem(in_q))
      {
      return;
      }

   //Peek at the first element.
   QCHAR_cceq_peek(in_q, &item);

   //If the first element is a start element, discard it.
   if ((item.ev == QCHAR_EV_CHAR) && (item.c == 0x01))
      {
      char buf[250];

      sprintf_s(buf, sizeof(buf), "CH%02d:SOH start event discarded to resynchronize.", in_channel);

      LOG_write_ls(&(item.ts), 
                   LOG_MT_ALERT, 
                   (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_ALERT | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_ALERT | LOG_LI_STDOUT), 
                   buf);
      QCHAR_cceq_get(in_q, &item);
      }

   //Discard characters beyond the SOH that can't be the start.
   LOG_PACKET_non_start_discard(in_channel, in_q, in_ts, in_mirror_to_console);
   }


//Figures out whether a range is all characters and what the checksum is.  Note that end index is 1+.
//
static void LOG_PACKET_q_range_all_chars_cksum8(QCHAR_CCEQ *in_q, int in_sidx, int in_eidx, int *out_all_chars, int *out_cksum8)
   {
   int i;
   QCHAR_TSE item;
   int cksum8 = 0;
   int all_chars = TRUE;

   for (i=in_sidx; i<in_eidx; i++)
      {
      QCHAR_cceq_peek_n(in_q, i, &item);

      if (item.ev == QCHAR_EV_CHAR)
         {
         cksum8 += (((int)item.c) & 0xFF);
         cksum8 &= 0xFF;
         }
      else
         {
         all_chars = FALSE;
         }
      }

   *out_all_chars = all_chars;
   *out_cksum8 = cksum8;
   }


static void LOG_PACKET_emit(int in_channel, QCHAR_CCEQ *in_q, const struct __timeb64 *in_ts, int in_mirror_to_console)
   {
   int lut_index;
   int declared_length;
   int declared_checksum;
   int nqueue;
   int must_resync = FALSE;
   int done = FALSE;
   int packet_found;
   QCHAR_TSE item_soh;
   QCHAR_TSE item_length;
   QCHAR_TSE item_type;
   QCHAR_TSE item_checksum;
   QCHAR_TSE item_endbyte;
   QCHAR_TSE event_buf[256];
   char buf[250];

   while (! done)
      {
      packet_found = FALSE;
      must_resync = FALSE;

      //All packets have to start with a character 0x01.  Trash anything that is not a character and/or not
      //a 0x01.
      LOG_PACKET_non_start_discard(in_channel, in_q, in_ts, in_mirror_to_console);
   
      //If there is nothing left in the queue, we can't go further.
      nqueue = QCHAR_cceq_nelem(in_q);
      if (!nqueue)
         return;

      if (nqueue >= 3)
         //We can begin looking for anomalies as soon as 3 characters.
         {
         //Grab the presumed SOH.
         QCHAR_cceq_peek_n(in_q, 0, &item_soh);

         //Grab the presumed length.
         QCHAR_cceq_peek_n(in_q, 1, &item_length);

         //Grab the presumed type.
         QCHAR_cceq_peek_n(in_q, 2, &item_type);

         //If the SOH is not as expected, must resynchronize.
         if ((item_soh.ev != QCHAR_EV_CHAR) || (item_soh.c != 0x01))
            {
            sprintf_s(buf, sizeof(buf), "CH%02d:Expected: SOH.  Actual: %s.", in_channel, LOG_PACKET_event_text_desc_a(&item_soh));

            LOG_write_ls(in_ts, 
                         LOG_MT_ALERT, 
                         (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_ALERT | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_ALERT | LOG_LI_STDOUT), 
                         buf);

            must_resync = TRUE;
            }

         //If the length is not a received character, must resynchronize.
         if (item_length.ev != QCHAR_EV_CHAR)
            {
            sprintf_s(buf, sizeof(buf), "CH%02d:Expected: Length.  Actual: %s.", in_channel, LOG_PACKET_event_text_desc_a(&item_length));

            LOG_write_ls(in_ts, 
                         LOG_MT_ALERT, 
                         (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_ALERT | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_ALERT | LOG_LI_STDOUT), 
                         buf);

            must_resync = TRUE;
            }

         //If the type is not a received character, must resynchronize.
         if (item_type.ev != QCHAR_EV_CHAR)
            {
            sprintf_s(buf, sizeof(buf), "CH%02d:Expected: Type.  Actual: %s.", in_channel, LOG_PACKET_event_text_desc_a(&item_type));

            LOG_write_ls(in_ts, 
                         LOG_MT_ALERT, 
                         (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_ALERT | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_ALERT | LOG_LI_STDOUT), 
                         buf);

            must_resync = TRUE;
            }

         //Try to look up the length and type and get a table index.  This may result in an error.
         lut_index = LOG_PACKET_type_length_lookup_a(((int)item_type.c) & 0xFF, ((int)item_length.c) & 0xFF);

         if (lut_index < 0)
            {
            if (lut_index == -2)
               {
               //Type is invalid.  Must resync.
               sprintf_s(buf, sizeof(buf), "CH%02d:Type byte has invalid value (0x%02X).", in_channel, ((int)item_type.c) & 0xFF);

               LOG_write_ls(in_ts, 
                            LOG_MT_ALERT, 
                            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_ALERT | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_ALERT | LOG_LI_STDOUT), 
                            buf);

               must_resync = TRUE;
               }
            else if (lut_index == -1)
               {
               //Length is inconsistent with type.
               sprintf_s(buf, 
                         sizeof(buf), 
                         "CH%02d:Type is acceptable(0x%02X) but length is inconsistent (0x%02X).", 
                         in_channel, 
                         ((int)item_type.c) & 0xFF, 
                         ((int)item_length.c) & 0xFF);

               LOG_write_ls(in_ts, 
                            LOG_MT_ALERT, 
                            (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_ALERT | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_ALERT | LOG_LI_STDOUT), 
                            buf);

               must_resync = TRUE;
               }
            else
               {
               //Negative value but don't know why.  This is an impossible internal software error.
               CCMFATAL_fatal("Unexpected internal software error.", __FILE__, __LINE__);
               }
            }
         else
            {
            //Index >= 0, so it is a valid table index.
            //
            //Look to see if we have at least as many characters as the declared length.
            declared_length = ((int)item_length.c) & 0xFF;

            if (nqueue >= declared_length)
               {
               //We have enough characters.  Peek at the end byte.  If it is wrong, can't continue.
               QCHAR_cceq_peek_n(in_q, declared_length-1, &item_endbyte);
           
               if ((item_endbyte.ev != QCHAR_EV_CHAR) || (item_endbyte.c != 0x04))
                  {
                  sprintf_s(buf, sizeof(buf), "CH%02d:Expected: 0x04 endbyte.  Actual: %s.", in_channel, LOG_PACKET_event_text_desc_a(&item_endbyte));

                  LOG_write_ls(in_ts, 
                               LOG_MT_ALERT, 
                               (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_ALERT | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_ALERT | LOG_LI_STDOUT), 
                               buf);

                  must_resync = TRUE;
                  }
               else
                  {
                  //Gotta look at checksum.
                  QCHAR_cceq_peek_n(in_q, declared_length-2, &item_checksum);
           
                  if (item_checksum.ev != QCHAR_EV_CHAR)
                     {
                     sprintf_s(buf, sizeof(buf), "CH%02d:Expected: checksum is character.  Actual: %s.", in_channel, LOG_PACKET_event_text_desc_a(&item_checksum));

                     LOG_write_ls(in_ts, 
                                  LOG_MT_ALERT, 
                                  (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_ALERT | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_ALERT | LOG_LI_STDOUT), 
                                  buf);

                     must_resync = TRUE;
                     }
                  else
                     {
                     int calculated_checksum;
                     int all_chars;

                     declared_checksum = ((int)item_checksum.c) & 0xFF;

                     LOG_PACKET_q_range_all_chars_cksum8(in_q, 0, declared_length-2, &all_chars, &calculated_checksum);

                     if (! all_chars)
                        {
                        //Not everything was a character.  Must resync.
                        sprintf_s(buf, sizeof(buf), "CH%02d:Some packet items not characters.  Resynchronizing.", in_channel);

                        LOG_write_ls(in_ts, 
                                     LOG_MT_ALERT, 
                                     (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_ALERT | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_ALERT | LOG_LI_STDOUT), 
                                     buf);

                        must_resync = TRUE;
                        }
                     else
                        {
                        if (calculated_checksum != declared_checksum)
                           {
                           //Checksum error.  Must resync.
                           sprintf_s(buf, 
                                     sizeof(buf), 
                                     "CH%02d:Packet checksum mismatch.  Declared: 0x%02X.  Actual: 0x%02X.  Resynchronizing.", 
                                     in_channel, 
                                     declared_checksum, 
                                     calculated_checksum);

                           LOG_write_ls(in_ts, 
                                        LOG_MT_ALERT, 
                                        (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_ALERT | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_ALERT | LOG_LI_STDOUT), 
                                        buf);

                           must_resync = TRUE;
                           }
                        else
                           {
                           //Everything looks OK.  Issue a warning if the packet type is inconsistent with what is allowed.  By convention, channel 0 is the
                           //line from the host micro to the RF module, and channel 1 is the one back.
                           //
                           if ((in_channel == 0) && (!LOG_PACKET_pkt_type_lut_a[lut_index].valid_from_host))
                              {
                              //Packet not allowed from host.
                              sprintf_s(buf, 
                                        sizeof(buf), 
                                        "CH%02d:Packet type not allowed from host.", 
                                        in_channel);

                              LOG_write_ls(in_ts, 
                                           LOG_MT_ALERT, 
                                           (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_ALERT | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_ALERT | LOG_LI_STDOUT), 
                                           buf);
                              }
                           else if ((in_channel == 1) && (!LOG_PACKET_pkt_type_lut_a[lut_index].valid_from_rf_mod))
                              {
                              //Packet not allowed from RF module.
                              sprintf_s(buf, 
                                        sizeof(buf), 
                                        "CH%02d:Packet type not allowed from RF module.", 
                                        in_channel);

                              LOG_write_ls(in_ts, 
                                           LOG_MT_ALERT, 
                                           (in_mirror_to_console) ? (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_ALERT | LOG_LI_STDOUT) : (LOG_LI_PKT | LOG_LI_COMP | LOG_LI_ALERT | LOG_LI_STDOUT), 
                                           buf);
                              }

                           //We are in the green to call the function to handle the packet.  At the same time we get the
                           //characters ready for this function, we pull them from the queue.
                           //
                              {
                              int i;

                              //Be sure we're consistent.  Everybody gets a clean copy.
                              FillMemory(event_buf, sizeof(event_buf), 0);
                              
                              //Do the copy and queue removal.
                              for (i=0; i<declared_length; i++)
                                 {
                                 QCHAR_cceq_get(in_q, &(event_buf[i]));
                                 }

                              //Call the function to handle it.
                              (*LOG_PACKET_pkt_type_lut_a[lut_index].logptr)(in_channel,
                                                                             in_ts,
                                                                             event_buf, 
                                                                             declared_length, 
                                                                             lut_index, 
                                                                             in_mirror_to_console);  

                              //We did find a packet.
                              packet_found = TRUE;
                              }
                           }
                        }

                     }
                  }
               }
            }
         } //End if nqueue >= 3.

      //If the terminal event in the queue has aged out, must resync.
      nqueue = QCHAR_cceq_nelem(in_q);
      if (!nqueue)
         return;

      QCHAR_cceq_peek_n(in_q, nqueue-1, &item_endbyte);
      if (MISCFUNC_timb64_diff_bounded_ms(&(item_endbyte.ts), in_ts) > LOG_PACKET_CHAR_STRAGGLER_TIME)
         {
         must_resync = TRUE;
         }

      //Resync if requested.
      if (must_resync)
         {
         LOG_PACKET_non_start_resync_discard(in_channel, in_q, in_ts, in_mirror_to_console);
         }

      //We are not done if we found a packet or had to resync.
      if (!packet_found && !must_resync)
         done = TRUE;
      } //End while(! done)
   }


void LOG_PACKET_advance(QCHAR_CCEQ *in_q0, QCHAR_CCEQ *in_q1, const struct __timeb64 *in_ts, int in_mirror_to_console)
   {
   //All we need to do is gather as many characters as we can and group them by timestamp.  We need to do this
   //once for each channel.
   LOG_PACKET_emit(0, in_q0, in_ts, in_mirror_to_console);
   LOG_PACKET_emit(1, in_q1, in_ts, in_mirror_to_console);
   }


const char *LOG_PACKET_cvcinfo(void)
   {
   return("$Header: /home/dashley/cvsrep/e3ft_gpl01/e3ft_gpl01/winprojs/scirfmmon/source/log_packet.c,v 1.24 2009/01/17 22:12:37 dashley Exp $");
   }


const char *LOG_PACKET_hvcinfo(void)
   {
   return(LOG_PACKET_H_VERSION);
   }


//**************************************************************************
// $Log: log_packet.c,v $
// Revision 1.24  2009/01/17 22:12:37  dashley
// Issue where some errors not logged to console fixed.
//
// Revision 1.23  2009/01/16 17:56:16  dashley
// 0xAB data presentation completed.
//
// Revision 1.22  2009/01/16 17:46:45  dashley
// 0x03 data presentation completed.
//
// Revision 1.21  2009/01/16 17:33:39  dashley
// 0x28 data presentation completed.
//
// Revision 1.20  2009/01/16 17:06:42  dashley
// 0x94 data presentation completed.
//
// Revision 1.19  2009/01/16 05:19:25  dashley
// 0x14 data presentation completed.
//
// Revision 1.18  2009/01/16 04:49:50  dashley
// 0x95 data presentation completed.
//
// Revision 1.17  2009/01/15 21:43:11  dashley
// Edits.
//
// Revision 1.16  2009/01/15 20:11:58  dashley
// Edits.
//
// Revision 1.15  2009/01/15 19:14:38  dashley
// Edits.
//**************************************************************************
// End of $RCSfile: log_packet.c,v $.