view src/g23m-aci/uart/uart_txp.c @ 221:5bf097aeaad7

LLS: when turning off all LEDs on boot, skip LED-C Having LLS turn off LED-A and LED-B on boot is normally unnecessary (they should already be off in Iota), but it is harmless, hence this logic is kept for robustness. However, having LLS read-modify-write the BCICTL2 register (to turn off LED-C) creates a potential race condition with FCHG writes to this register, especially in the case when baseband switch-on is caused by VCHG and charging is expected to start right away. Furthermore, control of the charging LED itself (on those hw targets that have it) is the responsibility of the FCHG SWE, hence LLS should leave it alone.
author Mychaela Falconia <falcon@freecalypso.org>
date Mon, 26 Apr 2021 21:55:13 +0000
parents fa8dc04885d8
children
line wrap: on
line source

/* 
+----------------------------------------------------------------------------- 
|  Project :  
|  Modul   :  
+----------------------------------------------------------------------------- 
|  Copyright 2002 Texas Instruments Berlin, AG 
|                 All rights reserved. 
| 
|                 This file is confidential and a trade secret of Texas 
|                 Instruments Berlin, AG 
|                 The receipt of or possession of this file does not convey 
|                 any rights to reproduce or disclose its contents or to 
|                 manufacture, use, or sell anything it may describe, in 
|                 whole, or in part, without the specific written consent of 
|                 Texas Instruments Berlin, AG. 
+----------------------------------------------------------------------------- 
|  Purpose :  This modul is part of the entity UART and implements all 
|             functions to handles the incoming primitives as described in 
|             the SDL-documentation (TX-statemachine)
+----------------------------------------------------------------------------- 
*/ 

#ifndef UART_TXP_C
#define UART_TXP_C
#endif /* !UART_TXP_C */

#define ENTITY_UART

#ifndef FF_MULTI_PORT
/*==== INCLUDES =============================================================*/

#ifdef WIN32
#include "nucleus.h"
#endif /* WIN32 */
#include "typedefs.h"   /* to get Condat data types */
#include "vsi.h"        /* to get a lot of macros */
#include "macdef.h"     /* to get a lot of macros */
#include "custom.h"
#include "gsm.h"        /* to get a lot of macros */
#include "cnf_uart.h"   /* to get cnf-definitions */
#include "mon_uart.h"   /* to get mon-definitions */
#include "prim.h"       /* to get the definitions of used SAP and directions */
#ifdef DTILIB
#include "dti.h"        /* to get dti lib */
#endif /* DTILIB */
#include "pei.h"        /* to get PEI interface */
#ifdef _TARGET_
#include "uart/serialswitch.h"
#include "uart/traceswitch.h"
#else /* _TARGET_ */
#include "serial_dat.h" /* to get definitions of serial driver */
#endif /* _TARGET_ */
#include "uart.h"       /* to get the global entity definitions */

#include "uart_txf.h"   /* to get tx functions */

#include "uart_kers.h"   /* to get ker signals */
#include "uart_drxs.h"   /* to get drx signals */

#ifdef _SIMULATION_
#include <stdio.h>      /* to get sprintf */
#include "uart_txp.h"   /* to get tx_writedata */
#endif /* _SIMULATION_ */
/*==== CONST ================================================================*/

/*==== LOCAL VARS ===========================================================*/

/*==== PRIVATE FUNCTIONS ====================================================*/

/*==== PUBLIC FUNCTIONS =====================================================*/



/*
+------------------------------------------------------------------------------
| Function    : tx_uart_driver_sent_ind
+------------------------------------------------------------------------------
| Description : Handles the primitive UART_DRIVER_SENT_IND
|
| Parameters  : *uart_device - affected device database
|
+------------------------------------------------------------------------------
*/
GLOBAL void tx_uart_driver_sent_ind ( T_UART_DATA* uart_device )
{
  T_desc2* temp_desc;
  T_DLC*  dlc;

  TRACE_EVENT( "tx_uart_driver_sent_ind()" );

  /*
   * set affected instance
   */
  uart_data = uart_device;

  switch( GET_STATE( UART_SERVICE_TX ) )
  {
    case TX_READY:
      /*
       * send DATA_SENT signal
       */
      dlc = &uart_data->dlc_table[UART_CONTROL_INSTANCE];
      uart_data->tx.dlc_instance = UART_EMPTY_INSTANCE;
      temp_desc                  = dlc->transmit_data;
      dlc->transmit_data         = NULL;
      uart_data->drx             = dlc->drx;
      sig_tx_drx_data_sent_req(temp_desc, dlc->transmit_pos);
      /*
       * determine whether there is still data to send
       */
      if(dlc->transmit_data EQ NULL)
      {
        /*
         * no more data
         */
        uart_data->tx.send_state = UART_TX_NOT_SENDING;
        break;
      }
      /*
       * inform dlc about sending
       */
      uart_data->drx = dlc->drx;
      sig_tx_drx_sending_req();
      /*
       * transmit data
       */
      if(uart_data EQ (&(uart_data_base[0])))
      {
        TRACE_EVENT("UF_WriteData()");
#ifdef _SIMULATION_
        tx_writedata(0);
#else /* _SIMULATION_ */
        UF_WriteData (uart_data->device, sm_suspend, tx_writeInFunc_0);
#endif /* else _SIMULATION_ */
      }
#ifdef FF_TWO_UART_PORTS
      else if(uart_data EQ (&(uart_data_base[1])))
      {
        TRACE_EVENT("UF_WriteData()");
#ifdef _SIMULATION_
        tx_writedata(1);
#else /* _SIMULATION_ */
        UF_WriteData (uart_data->device, sm_suspend, tx_writeInFunc_1);
#endif /* else _SIMULATION_ */
      }
#endif /* FF_TWO_UART_PORTS */
      else
      {
        TRACE_ERROR("wrong value of uart_data");
      }
      break;

    case TX_MUX:
      /*
       * send DATA_SENT signal
       */
      if(uart_data->tx.dlc_instance EQ UART_EMPTY_INSTANCE)
      {
        /*
         * use entry 0 for raw data
         */
        dlc = &uart_data->dlc_table[UART_CONTROL_INSTANCE];
      }
      else
      {
        dlc = &uart_data->dlc_table[uart_data->tx.dlc_instance];
      }
      temp_desc          = dlc->transmit_data;
      dlc->transmit_data = NULL;
      if(uart_data->tx.dlc_instance EQ UART_CONTROL_INSTANCE)
        sig_tx_ker_data_sent_ind(temp_desc, dlc->transmit_pos);
      else
      {
        uart_data->drx = dlc->drx;
        sig_tx_drx_data_sent_req(temp_desc, dlc->transmit_pos);
      }
      /*
       * determine next dlc allow to send
       */
      tx_next_send_allowed();
      if(uart_data->tx.dlc_instance EQ UART_EMPTY_INSTANCE)
      {
        /*
         * queue empty
         */
        uart_data->tx.send_state = UART_TX_NOT_SENDING;
        break;
      }
      /*
       * inform dlc about sending
       */
      dlc = &uart_data->dlc_table[uart_data->tx.dlc_instance];
      if(uart_data->tx.dlc_instance EQ UART_CONTROL_INSTANCE)
      {
        /*
         * Control channel
         */
        sig_tx_ker_sending_ind();
      }
      else
      {
        /*
         * Data channel
         */
        uart_data->drx = dlc->drx;
        sig_tx_drx_sending_req();
      }
      /*
       * transmit data
       */
#ifndef _SIMULATION_
      tx_flushUart();
#endif /* !_SIMULATION_ */
      if(uart_data EQ (&(uart_data_base[0])))
      {
        TRACE_EVENT("UF_WriteData()");
#ifdef _SIMULATION_
        tx_writedata(0);
#else /* _SIMULATION_ */
        UF_WriteData (uart_data->device, sm_suspend, tx_writeInFunc_0);
#endif /* else _SIMULATION_ */
      }
#ifdef FF_TWO_UART_PORTS
      else if(uart_data EQ (&(uart_data_base[1])))
      {
        TRACE_EVENT("UF_WriteData()");
#ifdef _SIMULATION_
        tx_writedata(1);
#else /* _SIMULATION_ */
        UF_WriteData (uart_data->device, sm_suspend, tx_writeInFunc_1);
#endif /* else _SIMULATION_ */
      }
#endif /* FF_TWO_UART_PORTS */
      else
      {
        TRACE_ERROR("wrong value of uart_data");
      }
      break;

    default:
      TRACE_ERROR( "UART_DRIVER_SENT_IND unexpected" );
      break;
  }
} /* tx_uart_driver_sent_ind() */



#ifdef _SIMULATION_
/*
+------------------------------------------------------------------------------
| Function    : tx_dti_ready_ind
+------------------------------------------------------------------------------
| Description : Handles the primitive DTI_READY_IND
|
| Parameters  : *dti_ready_ind - Ptr to primitive payload
|
+------------------------------------------------------------------------------
*/
GLOBAL void tx_dti_ready_ind ( T_DTI2_READY_IND *dti_ready_ind )
{
  TRACE_FUNCTION( "tx_dti_ready_ind" );
  
  /*
   * free the received primitive
   */
  PFREE(dti_ready_ind);
#ifdef DTI2 /* should combine "caller" and "read_data" */
            /* when using both devices in the test document?! */
  tx_uart_driver_sent_ind(&(uart_data_base[UART_TEST_C_ID_1]));
#else  /* DTI2 */
  tx_uart_driver_sent_ind(&(uart_data_base[dti_ready_ind->c_id]));
#endif /* DTI2 */
} /* tx_dti_ready_ind() */



/*
+------------------------------------------------------------------------------
| Function    : tx_writedata
+------------------------------------------------------------------------------
| Description : Simulates UF_WriteData call
|
| Parameters  : caller - calling UART instance
|
+------------------------------------------------------------------------------
*/
GLOBAL void tx_writedata (UBYTE caller)
{
  char          buf[100];
  T_reInstMode  reInstall;
  USHORT        size[2];
  USHORT        pos;
  USHORT        i;
  T_UART_DATA*  uart_device;

  TRACE_FUNCTION( "tx_writedata" );

  /*
   * set UART instance
   */
  uart_device = &(uart_data_base[caller]);

  {
    /*
     * calculation of SDU length: ((((frame-size + 3) * 2) + 2) * 8)
     */
    PALLOC_SDU (dti_data_test_req, DTI2_DATA_TEST_REQ, 1088);
#ifdef DTI2 /* should switch for C_ID_1/2 when using both devices in the test document?! */
    dti_data_test_req->link_id               = LINK_WRITEDATA_PORT_1; /* for write_data call */
    dti_data_test_req->parameters.p_id       = 0;
    dti_data_test_req->parameters.st_lines.st_flow    = 0;
    dti_data_test_req->parameters.st_lines.st_line_sa = 0;
    dti_data_test_req->parameters.st_lines.st_line_sb = 0;
    dti_data_test_req->parameters.st_lines.st_break_len = 0;
    dti_data_test_req->sdu.o_buf             = 0;
#else  /* DTI2 */
    dti_data_test_req->tui        = 3; /* for write_data call */
    dti_data_test_req->c_id       = caller;
    dti_data_test_req->p_id       = 0;
    dti_data_test_req->op_ack     = 0;
    dti_data_test_req->st_flow    = 0;
    dti_data_test_req->st_line_sa = 0;
    dti_data_test_req->st_line_sb = 0;
    dti_data_test_req->st_escape  = 0;
    dti_data_test_req->sdu.o_buf  = 0;
#endif /* DTI2 */

    uart_device->tx.dest[0] = dti_data_test_req->sdu.buf;
    uart_device->tx.dest[1] = NULL;
    size[0]                 = (USHORT)(1088 >> 3);
    size[1]                 = 0;

    /*
     * call actual function
     */
    if(caller EQ 0)
    {
      tx_writeInFunc_0 (FALSE, &reInstall, 1, uart_device->tx.dest, size);
    }
#ifdef FF_TWO_UART_PORTS
    else if(caller EQ 1)
    {
      tx_writeInFunc_1 (FALSE, &reInstall, 1, uart_device->tx.dest, size);
    }
#endif /* FF_TWO_UART_PORTS */
    else
    {
      TRACE_ERROR("wrong caller value");
    }

    /*
     * set length of sdu
     */
    dti_data_test_req->sdu.l_buf  = ((USHORT)(1088 >> 3) - size[0]) << 3;

    /*
     * trace output 
     */
    i   = 0;
    pos = 0;
    while(pos < (dti_data_test_req->sdu.l_buf >> 3))
    {
      i+= sprintf(&buf[i], "0x%02x, ", dti_data_test_req->sdu.buf[pos]);
      pos++;
      if(i > 80)
      {
        TRACE_FUNCTION( buf );
        i = 0;
      }
      else if(pos >= (dti_data_test_req->sdu.l_buf >> 3))
      {
        TRACE_FUNCTION( buf );
      }
    }
    /*
     * send primitive
     */
    PSEND (hCommMMI, dti_data_test_req);
  }
} /* tx_writedata() */
#endif /* _SIMULATION_ */
#endif /* !FF_MULTI_PORT */