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//
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// Created by MightyPork on 2018/02/20.
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//
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#include "platform.h"
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#define FCAP_INTERNAL
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#include "_fcap_internal.h"
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static void UFCAP_StopMeasurement(Unit *unit);
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static void UFCAP_ConfigureForIndirectCapture(Unit *unit);
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static void UFCAP_ConfigureForDirectCapture(Unit *unit, uint16_t msec);
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static void UFCAP_ConfigureForFreeCapture(Unit *unit);
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uint32_t UFCAP_GetFreeCounterValue(Unit *unit)
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{
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struct priv * const priv = unit->data;
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TIM_TypeDef * const TIMx = priv->TIMx;
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return TIMx->CNT;
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}
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uint32_t UFCAP_FreeCounterClear(Unit *unit)
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{
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struct priv * const priv = unit->data;
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TIM_TypeDef * const TIMx = priv->TIMx;
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// this isn't perfect, we can miss one clock
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// but it's probably the best we can do here ...
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vPortEnterCritical();
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uint32_t val = TIMx->CNT;
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TIMx->CNT = 0;
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vPortExitCritical();
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return val;
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}
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static void UFCAP_IndirectBurstReportJob(Job *job)
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{
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Unit *unit = job->unit;
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struct priv * const priv = unit->data;
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uint8_t buf[20];
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PayloadBuilder pb = pb_start(buf, 20, NULL);
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pb_u16(&pb, PLAT_AHB_MHZ);
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pb_u16(&pb, priv->ind_burst.n_count);
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pb_u64(&pb, priv->ind_burst.period_acu);
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pb_u64(&pb, priv->ind_burst.ontime_acu);
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assert_param(pb.ok);
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com_respond_pb(priv->request_id, MSG_SUCCESS, &pb);
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// timer is already stopped, now in OPMODE_BUSY
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priv->opmode = OPMODE_IDLE;
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}
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static void UFCAP_SinglePulseReportJob(Job *job)
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{
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Unit *unit = job->unit;
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struct priv * const priv = unit->data;
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uint8_t buf[6];
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PayloadBuilder pb = pb_start(buf, 6, NULL);
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pb_u16(&pb, PLAT_AHB_MHZ);
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pb_u32(&pb, job->data1);
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assert_param(pb.ok);
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com_respond_pb(priv->request_id, MSG_SUCCESS, &pb);
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// timer is already stopped, now in OPMODE_BUSY
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priv->opmode = OPMODE_IDLE;
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}
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/**
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* Count is passed in data1
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* @param job
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*/
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static void UFCAP_DirectBurstReportJob(Job *job)
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{
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Unit *unit = job->unit;
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struct priv * const priv = unit->data;
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uint8_t buf[8];
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PayloadBuilder pb = pb_start(buf, 8, NULL);
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pb_u8(&pb, priv->direct_presc);
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pb_u16(&pb, priv->dir_burst.msec);
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pb_u32(&pb, job->data1);
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assert_param(pb.ok);
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com_respond_pb(priv->request_id, MSG_SUCCESS, &pb);
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// timer is already stopped, now in OPMODE_BUSY
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priv->opmode = OPMODE_IDLE;
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}
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void UFCAP_TIMxHandler(void *arg)
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{
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Unit *unit = arg;
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assert_param(unit);
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struct priv * const priv = unit->data;
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assert_param(priv);
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TIM_TypeDef * const TIMx = priv->TIMx;
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if (priv->opmode == OPMODE_INDIRECT_CONT) {
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if (LL_TIM_IsActiveFlag_CC1(TIMx)) {
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if (priv->n_skip > 0) {
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priv->n_skip--;
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} else {
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priv->ind_cont.last_period = LL_TIM_IC_GetCaptureCH1(TIMx);
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priv->ind_cont.last_ontime = priv->ind_cont.ontime;
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}
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LL_TIM_ClearFlag_CC1(TIMx);
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LL_TIM_ClearFlag_CC1OVR(TIMx);
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}
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if (LL_TIM_IsActiveFlag_CC2(TIMx)) {
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priv->ind_cont.ontime = LL_TIM_IC_GetCaptureCH2(TIMx);
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LL_TIM_ClearFlag_CC2(TIMx);
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LL_TIM_ClearFlag_CC2OVR(TIMx);
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}
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}
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else if (priv->opmode == OPMODE_SINGLE_PULSE) {
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if (LL_TIM_IsActiveFlag_CC2(TIMx)) {
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// single pulse - does not wait for the second edge
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uint32_t len = LL_TIM_IC_GetCaptureCH2(TIMx);
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priv->opmode = OPMODE_BUSY;
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UFCAP_StopMeasurement(unit);
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Job j = {
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.cb = UFCAP_SinglePulseReportJob,
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.unit = unit,
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.data1 = len,
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};
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scheduleJob(&j);
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}
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}
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else if (priv->opmode == OPMODE_INDIRECT_BURST) {
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if (LL_TIM_IsActiveFlag_CC1(TIMx)) {
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const uint32_t period = LL_TIM_IC_GetCaptureCH1(TIMx);
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const uint32_t ontime = priv->ind_burst.ontime;
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if (priv->n_skip > 0) {
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priv->n_skip--;
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} else {
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priv->ind_burst.ontime_acu += ontime;
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priv->ind_burst.period_acu += period;
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if (++priv->ind_burst.n_count == priv->ind_burst.n_target) {
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priv->opmode = OPMODE_BUSY;
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UFCAP_StopMeasurement(unit);
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Job j = {
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.cb = UFCAP_IndirectBurstReportJob,
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.unit = unit,
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};
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scheduleJob(&j);
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}
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}
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LL_TIM_ClearFlag_CC1(TIMx);
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LL_TIM_ClearFlag_CC1OVR(TIMx);
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}
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if (LL_TIM_IsActiveFlag_CC2(TIMx)) {
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priv->ind_burst.ontime = LL_TIM_IC_GetCaptureCH2(TIMx);
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LL_TIM_ClearFlag_CC2(TIMx);
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LL_TIM_ClearFlag_CC2OVR(TIMx);
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}
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}
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else if (priv->opmode == OPMODE_IDLE) {
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// clear everything - in idle it would cycle in the handler forever
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TIMx->SR = 0;
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}
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else {
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trap("Unhandled fcap TIMx irq");
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}
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}
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void UFCAP_TIMyHandler(void *arg)
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{
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Unit *unit = arg;
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assert_param(unit);
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struct priv *const priv = unit->data;
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assert_param(priv);
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TIM_TypeDef * const TIMx = priv->TIMx;
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TIM_TypeDef * const TIMy = priv->TIMy;
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uint32_t cnt = TIMx->CNT; // TIMx should be stopped now
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// dbg("> TIMy Handler, TIMx cntr is %d", cnt);
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priv->dir_cont.last_count = cnt;
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if (priv->opmode == OPMODE_DIRECT_CONT) {
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LL_TIM_DisableCounter(TIMx);
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LL_TIM_DisableCounter(TIMy);
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LL_TIM_SetCounter(TIMx, 0);
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LL_TIM_SetCounter(TIMy, 0);
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LL_TIM_EnableCounter(TIMy); // next loop
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LL_TIM_EnableCounter(TIMx);
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}
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else if (priv->opmode == OPMODE_DIRECT_BURST) {
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priv->opmode = OPMODE_BUSY;
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UFCAP_StopMeasurement(unit);
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Job j = {
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.cb = UFCAP_DirectBurstReportJob,
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.unit = unit,
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.data1 = cnt,
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};
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scheduleJob(&j);
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}
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else if (priv->opmode == OPMODE_IDLE) {
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// clear everything - in idle it would cycle in the handler forever
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TIMy->SR = 0;
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}
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else {
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trap("Unhandled fcap TIMy irq");
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}
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LL_TIM_ClearFlag_UPDATE(TIMy);
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}
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static void UFCAP_ClearTimerConfig(Unit *unit)
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{
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struct priv * const priv = unit->data;
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TIM_TypeDef * const TIMx = priv->TIMx;
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// CLEAR CURRENT STATE, STOP
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UFCAP_StopMeasurement(unit);
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// CONFIGURE TIMER BASIC PARAMS
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LL_TIM_SetPrescaler(TIMx, 0);
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LL_TIM_SetAutoReload(TIMx, 0xFFFFFFFF);
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LL_TIM_EnableARRPreload(TIMx);
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LL_TIM_GenerateEvent_UPDATE(TIMx);
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}
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/**
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* Reset all timer registers
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*
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* @param unit
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*/
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static void UFCAP_StopMeasurement(Unit *unit)
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{
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struct priv * const priv = unit->data;
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LL_TIM_DeInit(priv->TIMx); // clear all flags and settings
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LL_TIM_DeInit(priv->TIMy); // clear all flags and settings
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}
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/**
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* Switch the FCAP module opmode
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*
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* @param unit
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* @param opmode
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*/
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void UFCAP_SwitchMode(Unit *unit, enum fcap_opmode opmode)
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{
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struct priv * const priv = unit->data;
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if (opmode == priv->opmode) return;
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priv->opmode = opmode;
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switch (opmode) {
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case OPMODE_IDLE:
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// XXX maybe we should report the abort to the PC-side listener
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UFCAP_StopMeasurement(unit);
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break;
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case OPMODE_INDIRECT_CONT:
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priv->ind_cont.last_ontime = 0;
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priv->ind_cont.last_period = 0;
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priv->ind_cont.ontime = 0;
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priv->n_skip = 1; // discard the first cycle (will be incomplete)
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UFCAP_ConfigureForIndirectCapture(unit); // is also stopped and restarted
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break;
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case OPMODE_INDIRECT_BURST:
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priv->ind_burst.ontime = 0;
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priv->ind_burst.n_count = 0;
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priv->ind_burst.period_acu = 0;
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priv->ind_burst.ontime_acu = 0;
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priv->n_skip = 1; // discard the first cycle (will be incomplete)
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UFCAP_ConfigureForIndirectCapture(unit); // is also stopped and restarted
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break;
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case OPMODE_SINGLE_PULSE:
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priv->n_skip = 0;
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UFCAP_ConfigureForIndirectCapture(unit); // is also stopped and restarted
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break;
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case OPMODE_DIRECT_CONT:
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// msec is set by caller
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priv->dir_cont.last_count = 0;
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priv->n_skip = 1; // discard the first cycle (will be incomplete)
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UFCAP_ConfigureForDirectCapture(unit, priv->direct_msec);
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break;
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case OPMODE_DIRECT_BURST:
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// msec is set by caller
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priv->n_skip = 0; // no skip here (if there was any)
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UFCAP_ConfigureForDirectCapture(unit, (uint16_t) priv->dir_burst.msec);
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break;
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case OPMODE_FREE_COUNTER:
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UFCAP_ConfigureForFreeCapture(unit);
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break;
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default:
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trap("Unhandled opmode %d", (int)opmode);
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}
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}
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/**
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* Configure peripherals for an indirect capture (PWM measurement) - continuous or burst
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* @param unit
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*/
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static void UFCAP_ConfigureForIndirectCapture(Unit *unit)
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{
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struct priv * const priv = unit->data;
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TIM_TypeDef * const TIMx = priv->TIMx;
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const uint32_t ll_ch_a = priv->ll_ch_a;
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const uint32_t ll_ch_b = priv->ll_ch_b;
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UFCAP_ClearTimerConfig(unit);
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// Enable channels and select mapping to TIx signals
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// A - will be used to measure period
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// B - will be used to measure the duty cycle
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// _________ ______
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// _______| |________________|
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// A B A
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// irq irq,cap irq
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// reset
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// B irq may be used if we want to measure a pulse width
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// Normally TI1 = CH1, TI2 = CH2.
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// It's possible to select the other channel, which we use to connect both TIx to the shame CHx.
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LL_TIM_IC_SetActiveInput(TIMx, ll_ch_a, priv->a_direct ? LL_TIM_ACTIVEINPUT_DIRECTTI : LL_TIM_ACTIVEINPUT_INDIRECTTI);
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LL_TIM_IC_SetActiveInput(TIMx, ll_ch_b, priv->a_direct ? LL_TIM_ACTIVEINPUT_INDIRECTTI : LL_TIM_ACTIVEINPUT_DIRECTTI);
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LL_TIM_IC_SetPolarity(TIMx, ll_ch_a, priv->active_level ? LL_TIM_IC_POLARITY_RISING : LL_TIM_IC_POLARITY_FALLING);
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LL_TIM_IC_SetPolarity(TIMx, ll_ch_b, priv->active_level ? LL_TIM_IC_POLARITY_FALLING : LL_TIM_IC_POLARITY_RISING);
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if (priv->dfilter > 15) priv->dfilter = 15;
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uint32_t filter = LL_TIM_IC_FILTERS[priv->dfilter];
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LL_TIM_IC_SetFilter(TIMx, ll_ch_a, filter);
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LL_TIM_IC_SetFilter(TIMx, ll_ch_b, filter);
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LL_TIM_CC_EnableChannel(TIMx, ll_ch_a | ll_ch_b);
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LL_TIM_SetSlaveMode(TIMx, LL_TIM_SLAVEMODE_RESET);
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LL_TIM_SetTriggerInput(TIMx, LL_TIM_TS_TI1FP1); // Use Filtered Input 1 (TI1)
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LL_TIM_EnableMasterSlaveMode(TIMx);
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LL_TIM_ClearFlag_CC1(TIMx);
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LL_TIM_ClearFlag_CC1OVR(TIMx);
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LL_TIM_ClearFlag_CC2(TIMx);
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LL_TIM_ClearFlag_CC2OVR(TIMx);
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LL_TIM_EnableIT_CC1(TIMx);
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LL_TIM_EnableIT_CC2(TIMx);
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LL_TIM_EnableCounter(TIMx);
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}
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/**
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* Configure peripherals for an indirect capture (PWM measurement) - continuous or burst
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* @param unit
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*/
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static void UFCAP_ConfigureForDirectCapture(Unit *unit, uint16_t msec)
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{
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struct priv * const priv = unit->data;
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// dbg("Configuring Direct capture...");
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UFCAP_ClearTimerConfig(unit);
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{
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TIM_TypeDef *const TIMy = priv->TIMy;
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assert_param(PLAT_AHB_MHZ<=65);
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uint16_t presc = PLAT_AHB_MHZ*1000;
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uint32_t count = msec+1; // it's one tick longer because we generate OCREF on the exact msec count - it must be at least 1 tick long
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LL_TIM_SetPrescaler(TIMy, (uint32_t) (presc - 1));
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LL_TIM_SetAutoReload(TIMy, count - 1);
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LL_TIM_EnableARRPreload(TIMy);
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LL_TIM_GenerateEvent_UPDATE(TIMy);
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LL_TIM_SetOnePulseMode(TIMy, LL_TIM_ONEPULSEMODE_SINGLE);
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LL_TIM_OC_EnableFast(TIMy, LL_TIM_CHANNEL_CH1);
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// dbg("TIMy presc %d, count %d", (int) presc, (int) count);
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LL_TIM_SetTriggerOutput(TIMy, LL_TIM_TRGO_OC1REF);
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LL_TIM_OC_SetMode(TIMy, LL_TIM_CHANNEL_CH1, LL_TIM_OCMODE_PWM1); // 1 until CC, then 0
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LL_TIM_OC_SetCompareCH1(TIMy, count-1);
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LL_TIM_CC_EnableChannel(TIMy, LL_TIM_CHANNEL_CH1); // enable the output channel that produces a trigger
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LL_TIM_ClearFlag_UPDATE(TIMy);
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LL_TIM_EnableIT_UPDATE(TIMy);
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}
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{
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// TIMx - the slave
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TIM_TypeDef *const TIMx = priv->TIMx;
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LL_TIM_SetSlaveMode(TIMx, LL_TIM_SLAVEMODE_GATED);
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LL_TIM_SetTriggerInput(TIMx, LL_TIM_TS_ITR3); // ITR3 is TIM14 which we use as TIMy
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LL_TIM_EnableMasterSlaveMode(TIMx);
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uint32_t presc = LL_TIM_ETR_PRESCALER_DIV1;
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switch (priv->direct_presc) {
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case 1: presc = LL_TIM_ETR_PRESCALER_DIV1; break;
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case 2: presc = LL_TIM_ETR_PRESCALER_DIV2; break;
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case 4: presc = LL_TIM_ETR_PRESCALER_DIV4; break;
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case 8: presc = LL_TIM_ETR_PRESCALER_DIV8; break;
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default:
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priv->direct_presc = 1; // will be sent with the response
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}
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if (priv->dfilter > 15) priv->dfilter = 15;
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uint32_t filter = LL_TIM_ETR_FILTERS[priv->dfilter];
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LL_TIM_ConfigETR(TIMx,
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priv->active_level ? LL_TIM_ETR_POLARITY_NONINVERTED : LL_TIM_ETR_POLARITY_INVERTED,
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presc,
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filter);
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LL_TIM_EnableExternalClock(TIMx); // TODO must check and deny this mode if the pin is not on CH1 = external trigger input
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LL_TIM_SetCounter(TIMx, 0);
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LL_TIM_EnableCounter(TIMx);
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}
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LL_TIM_EnableCounter(priv->TIMy); // XXX this will start the first pulse (maybe)
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|
}
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|
|
/**
|
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|
|
* Freerunning capture (counting pulses - geiger)
|
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|
|
* @param unit
|
|
|
|
*/
|
|
|
|
static void UFCAP_ConfigureForFreeCapture(Unit *unit)
|
|
|
|
{
|
|
|
|
struct priv * const priv = unit->data;
|
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|
|
UFCAP_ClearTimerConfig(unit);
|
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|
|
TIM_TypeDef *const TIMx = priv->TIMx;
|
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|
|
LL_TIM_EnableExternalClock(TIMx);
|
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|
|
LL_TIM_SetCounter(TIMx, 0);
|
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|
|
LL_TIM_EnableCounter(TIMx);
|
|
|
|
}
|