view src/cs/drivers/drv_app/lcc/lcc_handle_timers.c @ 208:ab79cf3c29a5

AT-over-RVTMUX mechanism ported over to the TCS3.2 version of ACI
author Mychaela Falconia <falcon@freecalypso.org>
date Fri, 14 Oct 2016 17:15:08 +0000
parents 945cf7f506b2
children
line wrap: on
line source

/******************************************************************************
 * Power Task (pwr)
 * Design and coding by Svend Kristian Lindholm, skl@ti.com
 *
 * Timers
 *
 * $Id: pwr_handle_timers.c 1.1 Wed, 20 Aug 2003 10:22:37 +0200 skl $
 *
 ******************************************************************************/
#ifndef __PWR_HANDLE_TIMERS_C_
#define __PWR_HANDLE_TIMERS_C_

UINT32 rvf_get_tick_count(void);
void pwr_check_timers(void);
T_RVM_RETURN pwr_create_timer(UINT32 *timer_begin);
T_RVM_RETURN pwr_start_timer(UINT32 *timer_begin);
void stop_ci_charge(void);
void pwr_modulate_off(void);
void pwr_send_msg(uint32 msg_id ,T_RVF_ADDR_ID src_addr_id, T_RVF_ADDR_ID  dest_addr_id);
int pwr_capacity(uint16 Vbat);
void mmi_send_msg(struct mmi_info_ind_s *event);
void end_charging_house_keeping(void);
void cv_charging_house_keeping(void);

// Timer functions

UINT32 pwr_timer_elapsed(UINT32 time_begin, UINT32 current_timer)
{
// return elapsed time in [ms]
    return (current_timer - time_begin) * 60 / 13;
}

T_RVM_RETURN pwr_start_timer(UINT32 *timer_begin)
{
    ttw(ttr(TTrTimer, "pwr_start_timer(%d)" NL, 0));

    // Start timer (will be checked each time an ADC measurement is received)
    *timer_begin  = rvf_get_tick_count();

    ttw(ttr(TTrTimer, "pwr_start_timer(%d)" NL, 0xFF));
    return (RV_OK);
}

T_RVM_RETURN pwr_stop_timer(UINT32 *timer_begin)
{
    ttw(ttr(TTrTimer, "pwr_stop_timer(%d)" NL, 0));

    *timer_begin  = 0;

    ttw(ttr(TTrTimer, "pwr_stop_timer(%d)" NL, 0xFF));
    return (RV_OK);
}

void pwr_stop_timers(void)
{
    // Only stop charging related timers - not supervision timers

    pwr_stop_timer(&pwr_ctrl->time_begin_T1);
    pwr_stop_timer(&pwr_ctrl->time_begin_T2);
    pwr_stop_timer(&pwr_ctrl->time_begin_T3);
    pwr_stop_timer(&pwr_ctrl->time_begin_T4);
    pwr_stop_timer(&pwr_ctrl->time_begin_mod_cycle);

}

T_RVM_RETURN pwr_create_timer(UINT32 *timer_begin)
{
    ttw(ttr(TTrTimer, "pwr_create_timer(%d)" NL, 0));

    *timer_begin  = 0;

    ttw(ttr(TTrTimer, "pwr_create_timer(%d)" NL, 0xFF));
    return (RV_OK);
}

T_RV_RET process_pwr_handle_T1_expiration (T_PWR_REQ *request)
{
    ttw(ttr(TTrTimer, "process_pwr_handle_T1_expiration(%d)" NL, 0));

    switch (pwr_ctrl->state) {
    case SUP :
        break;
    case CCI :
    case CCV :
    case LCI :
    case LCV :
        // Change state
        pwr_ctrl->state = SUP;
        end_charging_house_keeping();
        break;
    default :
        {
        // Exception Handling - Unknown State
        ttr(TTrFatal, "process_pwr_handle_T1_expiration: Unknown State: %d" NL, pwr_ctrl->state);
        break;
        }
    }
    ttw(ttr(TTrTimer, "process_pwr_handle_T1_expiration(%d)" NL, 0xFF));
    pwr_free(request);
}

T_RV_RET process_pwr_handle_T2_expiration (T_PWR_REQ *request)
{
    ttw(ttr(TTrTimer, "process_pwr_handle_T2_expiration(%d)" NL, 0));
    switch (pwr_ctrl->state) {
    case SUP :
        // Another timer did expire prior to the T2 timer - ignore this expiration
        break;
    case CCV :
    case LCV :
        // Change state
        pwr_ctrl->state = SUP;
        end_charging_house_keeping();
        break;
    default :
        {
        // Exception Handling - Unknown State
        ttr(TTrFatal, "process_pwr_handle_T2_expiration: Unknown State: %d" NL, pwr_ctrl->state);
        break;
        }
    }
    pwr_free(request);
    ttw(ttr(TTrTimer, "process_pwr_handle_T2_expiration(%d)" NL, 0xFF));
}

T_RV_RET process_pwr_handle_T3_expiration (T_PWR_REQ *request)
{
    ttw(ttr(TTrTimer, "process_pwr_handle_T3_expiration(%d)" NL, 0));
    switch (pwr_ctrl->state) {
    case SUP :
        // Stop & reset timers
        pwr_stop_timers();
        break;
    case CCI :
    case CCV :
    case LCI :
    case LCV :
        break;
    default :
        {
        // Exception Handling - Unknown State
        ttr(TTrFatal, "process_pwr_handle_T3_expiration: Unknown State: %d" NL, pwr_ctrl->state);
        break;
        }
    }
    pwr_free(request);
    ttw(ttr(TTrTimer, "process_pwr_handle_T3_expiration(%d)" NL, 0xFF));
}

T_RV_RET process_pwr_handle_T4_expiration (T_PWR_REQ *request)
{
    ttw(ttr(TTrTimer, "process_pwr_handle_T4_expiration(%d)" NL, 0));
    switch (pwr_ctrl->state) {
    case SUP :
        // Yes - since timing issues can make this timer expire in SUP state
        // It can take a long time before we know if a charger has been unplugged
        break;
    case CCV :
    case LCV :
        pwr_stop_timer(&pwr_ctrl->time_begin_T4);
        pwr_modulate_off();
        // Wait for duty cycle timer to expire before restarting this timer
        break;
    default :
        {
        // Exception Handling - Unknown State
        ttr(TTrFatal, "process_pwr_handle_T4_expiration: Unknown State: %d" NL, pwr_ctrl->state);
        break;
        }
    }
    pwr_free(request);
    ttw(ttr(TTrTimer, "process_pwr_handle_T4_expiration(%d)" NL, 0xFF));
}

T_RV_RET process_pwr_handle_mod_cycle_expiration (T_PWR_REQ *request)
{
    ttw(ttr(TTrTimer, "process_pwr_handle_mod_cycle_expiration(%d)" NL, 0));
    switch (pwr_ctrl->state) {
    case SUP :
        // Yes - since timing issues can make this timer expire in SUP state
        // It can take a long time before we know if a charger has been unplugged
        break;
    case CCV :
    case LCV :
        // Calculate k value
        // Start DC timer
        // Start T4 timer based on k value
        // Modulation ON
        cv_charging_house_keeping();
        break;
    default :
        {
        // Exception Handling - Unknown State
        ttr(TTrFatal, "process_pwr_handle_mod_cycle_expiration: Unknown State: %d" NL, pwr_ctrl->state);
        break;
        }
    }
    pwr_free(request);
    ttw(ttr(TTrTimer, "process_pwr_handle_mod_cycle_expiration(%d)" NL, 0xFF));
}

T_RV_RET process_pwr_handle_mmi_info_expiration(T_PWR_REQ *request)
{
    struct mmi_info_ind_s MMI_Event;

    ttw(ttr(TTrTimer, "process_pwr_handle_mmi_info_expiration(%d)" NL, 0));
    switch (pwr_ctrl->state) {
    case SUP :
        // Send MMI info events according to configured repetition interval
        if (pwr_ctrl->flag_mmi_registered == 1) {
            pwr_ctrl->mmi_ptr->header.msg_id = MMI_BAT_SUPERVISION_INFO_IND;
            pwr_ctrl->mmi_ptr->Vbat = pwr_cfg->data.Vbat_avg_mV;
            pwr_ctrl->mmi_ptr->Tbat = pwr_cfg->data.Tbat_avg;
            pwr_ctrl->mmi_ptr->Cbat = pwr_capacity(pwr_cfg->data.Vbat_avg_mV);
            mmi_send_msg(pwr_ctrl->mmi_ptr);
        }
        // Restart timer
        ttw(ttr(TTrTimerLow,"MMI info timer started(%d)" NL, 0));
        pwr_start_timer(&pwr_ctrl->time_begin_mmi_rep);

        break;
    case INI :
    case CCI :
    case CCV :
    case LCI :
    case LCV :
        // DON'T send any events when charging or initializing
        break;
    default :
        {
        // Exception Handling - Unknown State
        ttr(TTrFatal, "process_pwr_handle_mmi_info_expiration: Unknown State: %d" NL, pwr_ctrl->state);
        break;
        }
    }
    pwr_free(request);
    ttw(ttr(TTrTimer, "process_pwr_handle_mmi_info_expiration(%d)" NL, 0xFF));
}


void pwr_check_timers()
{
    UINT32 timer;

    ttw(ttr(TTrTimer, "pwr_check_timers(%d)" NL, 0));
    // Check timers T1, T2, T3, T4, duty cycle & mmi timer -  if expired send timer expired events
    timer  = rvf_get_tick_count();

    // T1
    if (pwr_ctrl->time_begin_T1 != 0) {
        // Started - but is it expired?
        pwr_ctrl->time_elapsed_T1  = pwr_timer_elapsed(pwr_ctrl->time_begin_T1, timer);
        if (pwr_ctrl->time_elapsed_T1 > pwr_cfg->bat.T1) {
            // EXPIRED!
            ttw(ttr(TTrTimer, "T1 expired (%d):" NL, pwr_ctrl->time_elapsed_T1));
            // 'Stop' timer
            pwr_ctrl->time_elapsed_T1 = 0;
            pwr_ctrl->time_begin_T1   = 0;
            // Send timer expired event
            pwr_send_msg(TIMER_T1_EXPIRED, pwr_ctrl->addr_id, pwr_ctrl->addr_id);
        }
    }
    // T2
    if (pwr_ctrl->time_begin_T2 != 0) {
        // Started - but is it expired?
        pwr_ctrl->time_elapsed_T2  = pwr_timer_elapsed(pwr_ctrl->time_begin_T2, timer);
        if (pwr_ctrl->time_elapsed_T2 > pwr_cfg->bat.T2) {
            // EXPIRED!
            ttw(ttr(TTrTimer, "T2 expired (%d):" NL, pwr_ctrl->time_elapsed_T2));
            // 'Stop' timer
            pwr_ctrl->time_elapsed_T2 = 0;
            pwr_ctrl->time_begin_T2   = 0;
            // Send timer expired event
            pwr_send_msg(TIMER_T2_EXPIRED, pwr_ctrl->addr_id, pwr_ctrl->addr_id);
        }
    }
    // T3
    if (pwr_ctrl->time_begin_T3 != 0) {
        // Started - but is it expired?
        pwr_ctrl->time_elapsed_T3  = pwr_timer_elapsed(pwr_ctrl->time_begin_T3, timer);
        if (pwr_ctrl->time_elapsed_T3 > pwr_cfg->bat.T3) {
            // EXPIRED!
            ttw(ttr(TTrTimer, "T3 expired (%d):" NL, pwr_ctrl->time_elapsed_T3));
            // 'Stop' timer
            pwr_ctrl->time_elapsed_T3 = 0;
            pwr_ctrl->time_begin_T3   = 0;
            // Send timer expired event
            pwr_send_msg(TIMER_T3_EXPIRED, pwr_ctrl->addr_id, pwr_ctrl->addr_id);
        }
    }
    // T4
    if (pwr_ctrl->time_begin_T4 != 0) {
        // Started - but is it expired?
        pwr_ctrl->time_elapsed_T4  = pwr_timer_elapsed(pwr_ctrl->time_begin_T4, timer);
        if (pwr_ctrl->time_elapsed_T4 > pwr_cfg->data.T4) {
            // EXPIRED!
            ttw(ttr(TTrTimer, "T4 expired (%d):" NL, pwr_ctrl->time_elapsed_T4));
            // 'Stop' timer
            pwr_ctrl->time_elapsed_T4 = 0;
            pwr_ctrl->time_begin_T4   = 0;
            // Send timer expired event
            pwr_send_msg(TIMER_T4_EXPIRED, pwr_ctrl->addr_id, pwr_ctrl->addr_id);
        }
    }
    // Duty cycle timer (Lithium only)
    if (pwr_ctrl->time_begin_mod_cycle != 0) {
        // Started - but is it expired?
        pwr_ctrl->time_elapsed_mod_cycle  = pwr_timer_elapsed(pwr_ctrl->time_begin_mod_cycle, timer);
        if (pwr_ctrl->time_elapsed_mod_cycle > pwr_cfg->common.mod_cycle) {
            // EXPIRED!
            ttw(ttr(TTrTimer, "DC expired (%d):" NL, pwr_ctrl->time_elapsed_mod_cycle));
            // 'Stop' timer
            pwr_ctrl->time_elapsed_mod_cycle = 0;
            pwr_ctrl->time_begin_mod_cycle   = 0;
            // Send timer expired event
            pwr_send_msg(TIMER_MOD_CYCLE_EXPIRED, pwr_ctrl->addr_id, pwr_ctrl->addr_id);
        }
    }
    // MMI repetition timer
    if (pwr_ctrl->time_begin_mmi_rep != 0) {
        // Started - but has it expired?
        pwr_ctrl->time_elapsed_mmi_rep  = pwr_timer_elapsed(pwr_ctrl->time_begin_mmi_rep, timer);
        if (pwr_ctrl->time_elapsed_mmi_rep > pwr_cfg->mmi.repetition) {
            // EXPIRED!
            // 'Stop' timer
            pwr_ctrl->time_elapsed_mmi_rep = 0;
            pwr_ctrl->time_begin_mmi_rep   = 0;
            ttw(ttr(TTrTimer, "MMI info timer expired (%d):" NL, pwr_ctrl->time_elapsed_mmi_rep));
            // Send timer expired event
            pwr_send_msg(TIMER_MMI_INFO_EXPIRED, pwr_ctrl->addr_id, pwr_ctrl->addr_id);
        }
    }
    ttw(ttr(TTrTimer, "pwr_check_timers(%d)" NL, 0xFF));

}
#endif