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view src/cs/drivers/drv_app/pwr/pwr_disch.c @ 275:79cfefc1e2b4

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audio mode load: gracefully handle mode files of wrong AEC version Unfortunately our change of enabling L1_NEW_AEC (which is necessary in order to bring our Calypso ARM fw into match with the underlying DSP reality) brings along a change in the audio mode file binary format and file size - all those new tunable AEC parameters do need to be stored somewhere, after all. But we already have existing mode files in the old format, and setting AEC config to garbage when loading old audio modes (which is what would happen without the present change) is not an appealing proposition. The solution implemented in the present change is as follows: the audio mode loading code checks the file size, and if it differs from the active version of T_AUDIO_MODE, the T_AUDIO_AEC_CFG structure is cleared - set to the default (disabled AEC) for the compiled type of AEC. We got lucky in that this varying T_AUDIO_AEC_CFG structure sits at the end of T_AUDIO_MODE!
author Mychaela Falconia <falcon@freecalypso.org>
date Fri, 30 Jul 2021 02:55:48 +0000
parents 4e78acac3d88
children
line wrap: on
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/*******************************************************************************
 *
 * pwr_disch.c
 *
 * Purpose: This file contains functions for battery discharge management.
 *
 * (C) Texas Instruments 2001
 *
 ******************************************************************************/

#include "rv/rv_defined_swe.h"	   // for RVM_PWR_SWE

#ifdef RVM_PWR_SWE

#include "abb/abb.h"
#include "rvm/rvm_use_id_list.h"
#include "pwr/pwr_disch.h"
#include "power/power.h"
#include "spi/spi_task.h"
#include "pwr/pwr_cust.h"
#include "pwr/pwr_messages.h"
#include "spi/spi_env.h"
#include "pwr/pwr_env.h"

/* Define a pointer to the PWR Environment control block.  */
extern T_PWR_ENV_CTRL_BLK *pwr_env_ctrl_blk;




/*******************************************************************************
** Function         pwr_discharge_timer_process
**
** Description      
**
*******************************************************************************/
void pwr_discharge_timer_process(void)
{
   rvf_send_trace("TIMER3", 6, NULL_PARAM, RV_TRACE_LEVEL_DEBUG_LOW, PWR_USE_ID);
   if (SPI_GBL_INFO_PTR->is_gsm_on == TRUE)
   {
      pwr_handle_discharge(); /* battery discharge management */
   } 

}



/*******************************************************************************
** Function         pwr_handle_discharge
**
** Description      Compares the battery voltage with some thresholds and, if a 
**                  threshold is passed, sends event(s) to the upper layer.
**                  Re-start the timer with a value depending on the discharge 
**                  level.
**
*******************************************************************************/
void pwr_handle_discharge(void)
{
   UINT16 timer_value;
   UINT16 status;
   UINT16 bat_madc_voltage, bat_voltage;
   static T_PWR_PERCENT remain_capacity = 100;  /* since this variable is declared as static */
                                                /* it will keep its value from one function call to the other */
   T_PWR_PERCENT current_capacity;
  
   if (SPI_GBL_INFO_PTR->is_adc_on == FALSE) 
   {
      /* Start VBAT channel conversion by writing in the result register */
      ABB_Write_Register_on_page(PAGE0, VBATREG, 0x0000);
      rvf_delay(RVF_MS_TO_TICKS(5));
      bat_madc_voltage = ABB_Read_Register_on_page(PAGE0, VBATREG);
      rvf_send_trace("battery voltage (MADC code) ", 28, bat_madc_voltage, RV_TRACE_LEVEL_DEBUG_LOW, PWR_USE_ID);
   }
   else /* The L1 asks for ADC conversions */
   {
#ifndef _WINDOWS
      bat_madc_voltage = SPI_GBL_INFO_PTR->adc_result[0];
#else
      bat_madc_voltage = ABB_Read_Register_on_page(PAGE0, VBATREG);
#endif
   }

   /* Find the remaining capacity in the battery corresponding to this new voltage */
   bat_voltage = pwr_adc_to_mvolt(bat_madc_voltage);
   rvf_send_trace("battery voltage (mV) ", 21, bat_voltage, RV_TRACE_LEVEL_DEBUG_LOW, PWR_USE_ID);
   current_capacity = pwr_get_capacity_vs_voltage(bat_voltage);
   rvf_send_trace("current capacity (%) ", 21, current_capacity, RV_TRACE_LEVEL_DEBUG_LOW, PWR_USE_ID);

   status = ABB_Read_Status();

   /* Determine if a threshold has been passed */
   if (current_capacity != remain_capacity) 
   {
      /* a new threshold has been passed */
      remain_capacity = current_capacity;

      /* informs the upper layer */
      pwr_send_bat_discharge_event(remain_capacity);

      if (status & CHGPRES)   /* charger plugged */
      {
         if (remain_capacity == CHARGE_START_AGAIN_CAPACITY)
         {
            PWR_Charger_Plug();
         }
      }

      else  /* charger not plugged */
      {
         if(remain_capacity <= pwr_env_ctrl_blk->power_alert.remain_capa_threshold)
         {
            /* informs the upper layer that the battery is low */
            pwr_send_low_bat_event(remain_capacity);
            timer_value = SPI_TIMER3_INTERVAL_BIS; /* 10 s */
         }
         else  
         {
#ifndef _WINDOWS
            timer_value = SPI_TIMER3_INTERVAL; /* 1 minute */
#else
            timer_value = SPI_TIMER3_INTERVAL_BIS; /* 10 s */
#endif
         }

         /* Start timer with a value depending on the remaining capacity in the battery */
         rvf_start_timer (SPI_TIMER3,
                          RVF_MS_TO_TICKS (timer_value),
                          FALSE);
      }
   }

   else /* the capacity has not changed */
   {
#ifndef _WINDOWS
      timer_value = SPI_TIMER3_INTERVAL; /* 1 minute */
#else
      timer_value = SPI_TIMER3_INTERVAL_BIS; /* 10 s */
#endif

      /* Start timer with a value depending on the remaining capacity in the battery */
      rvf_start_timer (SPI_TIMER3,
                       RVF_MS_TO_TICKS (timer_value),
                       FALSE);

   }
}

#endif /* #ifdef RVM_PWR_SWE */