view src/g23m-fad/tcpip/rnet/rnet_rt/rnet_rt_env.c @ 281:a75eefbf8be4

Phone boot with PWON: weed out short button presses Every standard end user phone has a design provision, most naturally implemented in firmware, whereby the PWON button effects a boot only if it is held down long enough - short presses of this PWON button are detected, assumed to be spurious and cause the fw to power back off instead of proceeding with boot. The present change introduces this standard function in FreeCalypso.
author Mychaela Falconia <falcon@freecalypso.org>
date Fri, 24 Sep 2021 02:03:08 +0000
parents fa8dc04885d8
children
line wrap: on
line source

/**
 * @file    rnet_rt_env.c
 *
 * Coding of the Riviera RNET Generic Functions,
 *
 * @author  Jose Yp-Tcha (j-yp-tcha@ti.com)
 * @version 0.1
 */

/*
 * $Id: rnet_rt_env.c,v 1.5 2002/10/30 15:23:34 rf Exp $
 * $Name: ti_20021030 $
 *
 * History:
 *
 *  Date         Author          Modification
 *  -------------------------------------------------------------------
 *  3/19/2002  Jose Yp-Tcha (j-yp-tcha@ti.com)    Create.
 *  3/29/2002 Regis Feneon      NexGenIP configuration
 *  5/6/2002    Regis Feneon  ATP driver support
 *  10/28/2002 Regis Feneon      added tests for RNET_RT_ETH_SUPPORT
 *
 * (C) Copyright 2002 by TI, All Rights Reserved
 */

#include "rnet_cfg.h"
#ifdef RNET_CFG_REAL_TRANSPORT

#ifdef _WINDOWS
#include "windows.h"
#include "rnet_rt_ngwinnet_i.h"
#endif

#include "rnet_rt_i.h"
#include "rnet_rt_env.h"

#include "rvm_priorities.h"
#include "rnet_trace_i.h"

#ifdef _WINDOWS
#define BUF_HEADER_SIZE 16
#else
#define BUF_HEADER_SIZE 0
#endif
#define BUF_DATA_SIZE 1500


/* Buffer for TCPIP internal memory menagement */
static T_RNET_RT_ENV_CTRL_BLK rnet_data_buf;
static unsigned char tcpip_buf[RNET_RT_BUFPOOL_SIZE];


/**
 * Pointer on the structure gathering all the global variables
 * used by RNET instance.
 */
T_RNET_RT_ENV_CTRL_BLK *rnet_rt_env_ctrl_blk_p;

/* Type 4, temporary */
T_RVM_RETURN rnet_rt_temp_core (void);

/**
 * Called by the RV manager to learn
 * tut requirements in terms of memory, SWEs...
 *
 * @param swe_info  Pointer to the structure to fill
 *            containing infos related to the tut SWE.
 *
 * @return  RVM_OK
 */
T_RVM_RETURN rnet_rt_get_info(T_RVM_INFO_SWE * swe_info)
{
  RNET_RT_SEND_TRACE("RNET_RT: get_info called", RV_TRACE_LEVEL_DEBUG_LOW);

  /* The SWE is a Type 4 SWE */
  swe_info->swe_type = RVM_SWE_TYPE_4;

  /* Used for info */
  memcpy(swe_info->type_info.type4.swe_name, "RNET_RT", sizeof("RNET_RT"));
  /*
   * This is the real way to indentify a SWE.
   * Look in rvm_use_id_list.h and rvm_ext_use_id_list.h.
   */
  swe_info->type_info.type4.swe_use_id = RNET_RT_USE_ID;

  /* SWE info */
  swe_info->type_info.type4.stack_size = RNET_RT_STACK_SIZE;
  swe_info->type_info.type4.priority = RVM_RNET_RT_TASK_PRIORITY;
  swe_info->type_info.type4.version = BUILD_VERSION_NUMBER(0,1,0);

  /* Memory bank info */
  swe_info->type_info.type4.nb_mem_bank = 1;
  memcpy(swe_info->type_info.type4.mem_bank[0].bank_name,
    "RNET_RT_PRIM", sizeof("RNET_RT_PRIM"));
  swe_info->type_info.type4.mem_bank[0].initial_params.size =
    RNET_RT_MB_PRIM_SIZE;


  swe_info->type_info.type4.mem_bank[0].initial_params.watermark =
    RNET_RT_MB_PRIM_WATERMARK;

  /*
   * Linked SWE info.
   */
#ifdef RNET_RT_ATP_SUPPORT
  /* we require ATP SWE to run */
  swe_info->type_info.type4.linked_swe_id[0] = ATP_USE_ID;
  swe_info->type_info.type4.nb_linked_swe = 1;
#else
  swe_info->type_info.type4.nb_linked_swe = 0;
#endif

  /* Set the return path: NOT USED. */
  swe_info->type_info.type4.return_path.callback_func = NULL;
  swe_info->type_info.type4.return_path.addr_id = 0;

  /* Generic functions */
  swe_info->type_info.type4.set_info = rnet_rt_set_info;
  swe_info->type_info.type4.init = rnet_rt_init;
/*
  swe_info->type_info.type3.start = rnet_rt_start;
  swe_info->type_info.type3.handle_message = rnet_rt_handle_message;
  swe_info->type_info.type3.handle_timer = rnet_rt_handle_timer;
*/
  swe_info->type_info.type4.stop = rnet_rt_stop;
  swe_info->type_info.type4.kill = rnet_rt_kill;

  /* Type 4 specific generic functions */
  swe_info->type_info.type4.core = rnet_rt_temp_core;
  /* End of specific generic functions */

  return RVM_OK;
}

/**
 * Called by the RV manager to inform the tut SWE about
 * addr_id, return path, mb_id and error function.
 *
 * It is called only once.
 *
 * @param addr_id     Address ID of the TUT SWE.
 *              Used to send messages to the SWE.
 * @param return_path   Return path array of the linked SWEs.
 * @param bk_id_table   Array of memory bank ids allocated to the SWE.
 * @param call_back_error_ft Callback function to call in case of unrecoverable error.
 * @return  RVM_MEMORY_ERR ou RVM_OK.
 */
T_RVM_RETURN rnet_rt_set_info ( T_RVF_ADDR_ID addr_id,
              T_RV_RETURN_PATH return_path[],
              T_RVF_MB_ID bk_id_table[],
              T_RVM_CB_FUNC call_back_error_ft)
{
  /* Memory bank status (red, yellow, green). */

  RNET_RT_SEND_TRACE("RNET_RT: set_info called", RV_TRACE_LEVEL_DEBUG_LOW);

  /* Create instance gathering all the variable used by TUT instance */
  rnet_rt_env_ctrl_blk_p = &rnet_data_buf;
  
  /* Store the address ID. */
  rnet_rt_env_ctrl_blk_p->addr_id = addr_id;

  /* Store the pointer to the error function. */
  rnet_rt_env_ctrl_blk_p->error_ft = call_back_error_ft;

  /*
   * Store the mem bank id.
   * Memory bank ID (mb_id) can be retrieved later using rvf_get_mb_id function.
   */
  rnet_rt_env_ctrl_blk_p->mb_id = bk_id_table[0];

  return RVM_OK;
}

/**
 * Called by the RV manager to initialize the
 * RNET SWE before creating the task and calling tut_start.
 *
 * @return  RVM_OK
 */

#define CFGMAX 40
#define CFG( opt, arg) { cfg[i].cfg_option = (opt); cfg[i++].cfg_arg = (arg); }

T_RVM_RETURN rnet_rt_init( void)
{
  int i, init_err;
  NGcfgent cfg[CFGMAX];
#ifdef _WINDOWS
  /* windows specific settings */
  NGuint ipaddr, ipnetmask, ipgateway, ipdns1, ipdns2;
  char *winpcapdev, *domain;
  static char tmpbuf[128], tmpbuf2[128];
#endif

  RNET_RT_SEND_TRACE("RNET_RT: init called", RV_TRACE_LEVEL_DEBUG_LOW);

  /*
   * NexGenIP initialisation
   */

#ifdef _WINDOWS
  /* get windows settings */
  if( (GetEnvironmentVariable( "RNET_RT_WIN32_IPADDR", tmpbuf, sizeof( tmpbuf)) == 0) ||
      (ngInetATON( tmpbuf, &ipaddr) != NG_EOK)) {
    ipaddr = 0;
  }
  if( (GetEnvironmentVariable( "RNET_RT_WIN32_IPNETMASK", tmpbuf, sizeof( tmpbuf)) == 0) ||
      (ngInetATON( tmpbuf, &ipnetmask) != NG_EOK)) {
    ipnetmask = 0;
  }
  if( (GetEnvironmentVariable( "RNET_RT_WIN32_IPGATEWAY", tmpbuf, sizeof( tmpbuf)) == 0) ||
      (ngInetATON( tmpbuf, &ipgateway) != NG_EOK)) {
    ipgateway = 0;
  }
  if( (GetEnvironmentVariable( "RNET_RT_WIN32_IPDNS1", tmpbuf, sizeof( tmpbuf)) == 0) ||
      (ngInetATON( tmpbuf, &ipdns1) != NG_EOK)) {
    ipdns1 = 0;
  }
  if( (GetEnvironmentVariable( "RNET_RT_WIN32_IPDNS2", tmpbuf, sizeof( tmpbuf)) == 0) ||
      (ngInetATON( tmpbuf, &ipdns1) != NG_EOK)) {
    ipdns2 = 0;
  }
  if( GetEnvironmentVariable( "RNET_RT_WIN32_WINPCAPDEV", tmpbuf, sizeof( tmpbuf)) == 0) {
    winpcapdev = NULL;
  }
  else {
    winpcapdev = tmpbuf;
  }
  if( GetEnvironmentVariable( "RNET_RT_WIN32_DOMAIN", tmpbuf, sizeof( tmpbuf2)) == 0) {
    domain = NULL;
  }
  else {
    domain = tmpbuf2;
  }
#endif

  /* allocate buffer pool */
  rnet_rt_env_ctrl_blk_p->buf_net = &tcpip_buf;

  /* initialise mutex */
  if( rvf_initialize_mutex( &rnet_rt_env_ctrl_blk_p->mutex) != RV_OK) {
    RNET_RT_SEND_TRACE("RNET_RT: Cannot initialize mutex ",RV_TRACE_LEVEL_ERROR);
    return RVM_INTERNAL_ERR;
  }

  /*
   * Configuration Table
   */
  i = 0;
  /* TCP */
  CFG( NG_CFG_PROTOADD, NG_CFG_PTR( &ngProto_TCP));
  CFG( NG_TCPO_TCB_MAX, NG_CFG_INT( RNET_RT_SOCK_MAX));
  CFG( NG_TCPO_TCB_TABLE, NG_CFG_PTR( (/*(rnet_data *)*/ rnet_rt_env_ctrl_blk_p)->tcbtable));
  /* UDP */
  CFG( NG_CFG_PROTOADD, NG_CFG_PTR( &ngProto_UDP));
  /* IP */
  CFG( NG_CFG_PROTOADD, NG_CFG_PTR( &ngProto_IP));
#ifdef _WINDOWS
  if( ipgateway != 0) {
    CFG( NG_IPO_ROUTE_DEFAULT, NG_CFG_LNG( ipgateway));
  }
#endif
#ifdef RNET_RT_ETH_SUPPORT
  /* ARP */
  CFG( NG_CFG_PROTOADD, NG_CFG_PTR( &ngProto_ARP));
  CFG( NG_ARPO_MAX, NG_CFG_INT( RNET_RT_ARP_MAX));
  CFG( NG_ARPO_TABLE, NG_CFG_PTR( (/*(rnet_data *)*/ rnet_rt_env_ctrl_blk_p)->arptable));
  CFG( NG_ARPO_EXPIRE, NG_CFG_INT( 120));
#endif
  /* RESOLVER */
  CFG( NG_CFG_PROTOADD, NG_CFG_PTR( &ngProto_RESOLV));
  CFG( NG_RSLVO_QUERY_MAX, NG_CFG_INT( RNET_RT_RESOLV_QUERY_MAX));
  CFG( NG_RSLVO_QUERY, NG_CFG_PTR( (/*(rnet_data *)*/ rnet_rt_env_ctrl_blk_p)->resolvquery));
  CFG( NG_RSLVO_CACHE_MAX, NG_CFG_INT( RNET_RT_RESOLV_CACHE_MAX));
  CFG( NG_RSLVO_CACHE_ENT, NG_CFG_PTR( (/*(rnet_data *)*/ rnet_rt_env_ctrl_blk_p)->resolvcache));
  CFG( NG_RSLVO_TO, NG_CFG_INT( RNET_RT_RESOLV_TIMEOUT));
#ifdef _WINDOWS
  if( ipdns1 != 0) {
    CFG( NG_RSLVO_SERV1_IPADDR, NG_CFG_LNG( ipdns1));
  }
  if( ipdns2 != 0) {
    CFG( NG_RSLVO_SERV2_IPADDR, NG_CFG_LNG( ipdns2));
  }
  if( domain != NULL) {
    CFG( NG_RSLVO_DOMAIN, NG_CFG_PTR( domain));
  }
#endif
#ifdef RNET_RT_LOOPBACK_SUPPORT
  /* Loopback Interface */
  CFG( NG_CFG_IFADD, NG_CFG_PTR( &rnet_rt_env_ctrl_blk_p->ifnet_lo));
  CFG( NG_CFG_DRIVER, NG_CFG_PTR( &ngNetDrv_LOOPBACK));
  CFG( NG_IFO_NAME, NG_CFG_PTR( "lo0"));
#endif
#if defined(_WINDOWS) && defined(RNET_RT_ETH_SUPPORT)
  /* Ethernet interface */
  CFG( NG_CFG_IFADD, NG_CFG_PTR( &rnet_rt_env_ctrl_blk_p->ifnet_eth));
  CFG( NG_CFG_DRIVER, NG_CFG_PTR( &ngNetDrv_WIN32));
  CFG( NG_IFO_NAME, NG_CFG_PTR( "eth0"));
  CFG( NG_IFO_OUTQ_MAX, NG_CFG_INT( 16));
  if( ipaddr != 0) {
    CFG( NG_IFO_ADDR, NG_CFG_LNG( ipaddr));
  }
  if( ipnetmask != 0) {
    CFG( NG_IFO_NETMASK, NG_CFG_LNG( ipnetmask));
  }
  if( winpcapdev != NULL) {
    CFG( NG_IFO_DEVPTR1, NG_CFG_PTR( winpcapdev));
  }
#endif
#ifdef RNET_RT_ATP_SUPPORT
  /* ATP point-to-point Interface */
  CFG( NG_CFG_IFADD, NG_CFG_PTR( &rnet_rt_env_ctrl_blk_p->ifnet_atp));
  CFG( NG_CFG_DRIVER, NG_CFG_PTR( &rnet_rt_netdrv_atp));
  CFG( NG_IFO_NAME, NG_CFG_PTR( "ppp0"));
#endif
#ifdef RNET_RT_DTI_SUPPORT
  /* DTI (i. e. GMS or GPRS) point-to-point Interface */
  CFG( NG_CFG_IFADD, NG_CFG_PTR( &rnet_rt_env_ctrl_blk_p->ifnet_dti));
  CFG( NG_CFG_DRIVER, NG_CFG_PTR( &rnet_rt_netdrv_dti));
  CFG( NG_IFO_NAME, NG_CFG_PTR( "gsm0"));
#endif
  /* end of table */
  CFG( NG_CFG_END, 0);

  /* initialise protocols and network interfaces */
  init_err = rnet_rt_ngip_init( rnet_rt_env_ctrl_blk_p->buf_net,
                                RNET_RT_BUFPOOL_SIZE,
                                BUF_HEADER_SIZE,
                                BUF_DATA_SIZE,
                                rnet_rt_env_ctrl_blk_p->socktable,
                                RNET_RT_SOCK_MAX,
                                cfg);
  if( init_err != NG_EOK) {
    RNET_RT_SEND_TRACE("RNET_RT: Cannot initialize NexGenIP stack ",RV_TRACE_LEVEL_ERROR);
    return RVM_INTERNAL_ERR;
  }

#ifdef RNET_RT_NGIP_DEBUG_ENABLE
  /* set debug */
  ngDebugModOnOff[NG_DBG_IP] = 1;
  ngDebugModOnOff[NG_DBG_UDP] = 1;
  ngDebugModOnOff[NG_DBG_TCP] = 1;
  ngDebugModOnOff[NG_DBG_RESOLV] = 1;
#endif

  return RVM_OK;
}

/**
 * Called by the RV manager to start the RNET SWE,
 *
 * @return  RVM_OK.
 */
T_RVM_RETURN rnet_rt_start( void)
{

  RNET_RT_SEND_TRACE("RNET_RT: start called", RV_TRACE_LEVEL_DEBUG_LOW);

  /* arm timer */

  /* It looks as if the timer runs by a factor of 10 slower in the
   * simulation than it ought to, so we speed it up again here. Target
   * testing must reveal if there is really a difference. */
  
#ifdef _SIMULATION_
#define MILLISECONDS_PER_SECOND 100
#else  /* _SIMULATION_ */
#define MILLISECONDS_PER_SECOND 1000
#endif    
  rvf_start_timer( RNET_RT_NGIP_TIMER,
                   RVF_MS_TO_TICKS(MILLISECONDS_PER_SECOND/NG_TIMERHZ),
                   FALSE);     // TRUE --> FALSE , set once timer for OMAPS00169870 05102008 by pinghua

  /* open interfaces */
  rvf_lock_mutex( &rnet_rt_env_ctrl_blk_p->mutex);
  rnet_rt_ngip_start();
  rvf_unlock_mutex( &rnet_rt_env_ctrl_blk_p->mutex);

  return RVM_OK;
}

/**
 * Called by the RV manager to stop the RNET SWE.
 *
 * @return  RVM_OK
 */
T_RVM_RETURN rnet_rt_stop( void)
{
  /* NB: Other SWEs have not been killed yet, tut can send messages to other SWEs. */
  RNET_RT_SEND_TRACE("RNET_RT: stop called", RV_TRACE_LEVEL_DEBUG_LOW);

  /* stop protocol timer */
  rvf_stop_timer( RNET_RT_NGIP_TIMER);

  /* shutdown TCP/IP stack */
  rvf_lock_mutex( &rnet_rt_env_ctrl_blk_p->mutex);
  rnet_rt_ngip_stop();
  rvf_unlock_mutex( &rnet_rt_env_ctrl_blk_p->mutex);

  /* release resources */

  rvf_delete_mutex( &rnet_rt_env_ctrl_blk_p->mutex);

#if 0
  rvf_free_buf( rnet_rt_env_ctrl_blk_p->buf_net);
  rvf_free_buf( rnet_rt_env_ctrl_blk_p);
#endif

  rnet_rt_env_ctrl_blk_p->buf_net = NULL;
  rnet_rt_env_ctrl_blk_p = NULL;

  return RVM_OK;
}

/**
 * Called by the RV manager to kill the RNET SWE,
 * after the rnet_stop function has been called.
 *
 * @return  RVM_OK
 */
T_RVM_RETURN rnet_rt_kill( void)
{
  /*
   * DO NOT SEND MESSAGES
   */

  return RVM_OK;
}

/* Temporary core for RNET */
T_RVM_RETURN rnet_rt_temp_core (void)
{
  T_RVM_RETURN error_status;
  T_RV_HDR *msg_p ;
  UINT16 rec_event;

  RNET_TRACE_HIGH("RNET_RT: core task started");

  /* start RNET */
  rnet_rt_start();

  error_status = RV_OK;
  while (error_status == RV_OK )
  {
    rec_event = rvf_wait(0xffff, 0); /* Wait (infinite) for all events. */
    if (rec_event & RVF_TASK_MBOX_0_EVT_MASK)
    {
      msg_p = rvf_read_mbox(0);
      error_status = rnet_rt_handle_message(msg_p);
    }
    if (rec_event & RVF_TIMER_1_EVT_MASK)
    {
      error_status = rnet_rt_handle_timer(NULL);
    }
  }
  if (error_status ==  RV_MEMORY_ERR ) /* If a memory error happened .. */
  {
    (void)(rnet_rt_env_ctrl_blk_p->error_ft("RNET", RVM_MEMORY_ERR, 0,
              " Memory Error : the RNET primitive memory bank is RED "));
  }
  return RVM_OK;
}

#endif /* ifdef RNET_CFG_REAL_TRANSPORT */