micropython/ports/mimxrt/hal/pwm_backport.c

175 lines
6.6 KiB
C

/*
* This file is part of the MicroPython project, http://micropython.org/
*
* Copyright (c) 2015, Freescale Semiconductor, Inc.
* Copyright 2016-2017 NXP *
* Copyright (c) 2021 Robert Hammelrath
* SPDX-License-Identifier: BSD-3-Clause
*
*/
// These are a few functions taken from the NXP-Lib
// for PWM, for
// - dealing with an u16 duty cycle setting,
// - setting the pulse center position, and
// - factoring out pure duty cycle change.
#include "py/runtime.h"
#include "hal/pwm_backport.h"
void PWM_UpdatePwmDutycycle_u16(
PWM_Type *base, pwm_submodule_t subModule, pwm_channels_t pwmSignal, uint32_t dutyCycle, uint16_t Center_u16) {
assert((uint16_t)pwmSignal < 2U);
uint32_t pulseCnt = 0, pwmHighPulse = 0;
uint32_t center;
// check and confine bounds for Center_u16
if ((Center_u16 + dutyCycle / 2) >= PWM_FULL_SCALE) {
Center_u16 = PWM_FULL_SCALE - dutyCycle / 2 - 1;
} else if (Center_u16 < (dutyCycle / 2)) {
Center_u16 = dutyCycle / 2;
}
pulseCnt = base->SM[subModule].VAL1 + 1;
// Calculate pulse width and center position
pwmHighPulse = (pulseCnt * dutyCycle) / PWM_FULL_SCALE;
center = (pulseCnt * Center_u16) / PWM_FULL_SCALE;
// Setup the PWM dutycycle of channel A or B
if (pwmSignal == kPWM_PwmA) {
if (dutyCycle >= 65536) {
base->SM[subModule].VAL2 = 0;
base->SM[subModule].VAL3 = pulseCnt;
} else {
base->SM[subModule].VAL2 = center - pwmHighPulse / 2;
base->SM[subModule].VAL3 = base->SM[subModule].VAL2 + pwmHighPulse;
}
} else {
if (dutyCycle >= 65536) {
base->SM[subModule].VAL4 = 0;
base->SM[subModule].VAL5 = pulseCnt;
} else {
base->SM[subModule].VAL4 = center - pwmHighPulse / 2;
base->SM[subModule].VAL5 = base->SM[subModule].VAL4 + pwmHighPulse;
}
}
}
void PWM_SetupPwm_u16(PWM_Type *base, pwm_submodule_t subModule, pwm_signal_param_u16_t *chnlParams,
uint32_t pwmFreq_Hz, uint32_t srcClock_Hz, bool output_enable) {
uint32_t pwmClock;
uint16_t pulseCnt = 0;
uint8_t polarityShift = 0, outputEnableShift = 0;
// Divide the clock by the prescale value
pwmClock = (srcClock_Hz / (1U << ((base->SM[subModule].CTRL & PWM_CTRL_PRSC_MASK) >> PWM_CTRL_PRSC_SHIFT)));
pulseCnt = (pwmClock + (pwmFreq_Hz - 1) / 2) / pwmFreq_Hz;
base->SM[subModule].INIT = 0;
base->SM[subModule].VAL1 = pulseCnt - 1;
// Set up the Registers VAL2..VAL5 controlling the duty cycle of channel A/B
PWM_UpdatePwmDutycycle_u16(base, subModule, chnlParams->pwmChannel,
chnlParams->dutyCycle_u16, chnlParams->Center_u16);
// Setup register shift values based on the channel being configured.
// Also setup the deadtime value
if (chnlParams->pwmChannel == kPWM_PwmA) {
polarityShift = PWM_OCTRL_POLA_SHIFT;
outputEnableShift = PWM_OUTEN_PWMA_EN_SHIFT;
base->SM[subModule].DTCNT0 = PWM_DTCNT0_DTCNT0(chnlParams->deadtimeValue);
} else {
polarityShift = PWM_OCTRL_POLB_SHIFT;
outputEnableShift = PWM_OUTEN_PWMB_EN_SHIFT;
base->SM[subModule].DTCNT1 = PWM_DTCNT1_DTCNT1(chnlParams->deadtimeValue);
}
// Setup signal active level
if (chnlParams->level == kPWM_HighTrue) {
base->SM[subModule].OCTRL &= ~(1U << polarityShift);
} else {
base->SM[subModule].OCTRL |= (1U << polarityShift);
}
// Enable PWM output
if (output_enable) {
base->OUTEN |= (1U << (outputEnableShift + subModule));
}
}
void PWM_SetupPwmx_u16(PWM_Type *base, pwm_submodule_t subModule,
uint32_t pwmFreq_Hz, uint32_t duty_cycle, uint8_t invert, uint32_t srcClock_Hz) {
uint32_t pulseCnt;
uint32_t pwmClock;
// Divide the clock by the prescale value
pwmClock = (srcClock_Hz / (1U << ((base->SM[subModule].CTRL & PWM_CTRL_PRSC_MASK) >> PWM_CTRL_PRSC_SHIFT)));
pulseCnt = (pwmClock + (pwmFreq_Hz - 1) / 2) / pwmFreq_Hz - 1;
base->SM[subModule].INIT = 0;
base->SM[subModule].VAL0 = ((uint32_t)duty_cycle * pulseCnt) / PWM_FULL_SCALE;
base->SM[subModule].VAL1 = pulseCnt;
base->SM[subModule].OCTRL = (base->SM[subModule].OCTRL & ~PWM_OCTRL_POLX_MASK) | PWM_OCTRL_POLX(!invert);
// Switch the output on or off.
if (duty_cycle == 0) {
base->OUTEN &= ~(1U << subModule);
} else {
base->OUTEN |= (1U << subModule);
}
}
#ifdef FSL_FEATURE_SOC_TMR_COUNT
status_t QTMR_SetupPwm_u16(TMR_Type *base, qtmr_channel_selection_t channel, uint32_t pwmFreqHz,
uint32_t dutyCycleU16, bool outputPolarity, uint32_t srcClock_Hz, bool is_init) {
uint32_t periodCount, highCount, lowCount, reg;
// Counter values to generate a PWM signal
periodCount = ((srcClock_Hz + (pwmFreqHz - 1) / 2) / pwmFreqHz) - 2;
highCount = (periodCount * dutyCycleU16) / PWM_FULL_SCALE;
lowCount = periodCount - highCount;
// Setup the compare registers for PWM output
if (is_init == false) {
base->CHANNEL[channel].COMP1 = lowCount;
base->CHANNEL[channel].COMP2 = highCount;
}
// Setup the pre-load registers for PWM output
base->CHANNEL[channel].CMPLD1 = lowCount;
base->CHANNEL[channel].CMPLD2 = highCount;
reg = base->CHANNEL[channel].CSCTRL;
// Setup the compare load control for COMP1 and COMP2.
// Load COMP1 when CSCTRL[TCF2] is asserted, load COMP2 when CSCTRL[TCF1] is asserted
reg &= ~(TMR_CSCTRL_CL1_MASK | TMR_CSCTRL_CL2_MASK);
reg |= (TMR_CSCTRL_CL1(kQTMR_LoadOnComp2) | TMR_CSCTRL_CL2(kQTMR_LoadOnComp1));
base->CHANNEL[channel].CSCTRL = reg;
// Set OFLAG pin for output mode
base->CHANNEL[channel].SCTRL |= TMR_SCTRL_OEN_MASK;
if (outputPolarity) {
// Invert the polarity
base->CHANNEL[channel].SCTRL |= TMR_SCTRL_OPS_MASK;
} else {
// True polarity, no inversion
base->CHANNEL[channel].SCTRL &= ~TMR_SCTRL_OPS_MASK;
}
reg = base->CHANNEL[channel].CTRL;
reg &= ~(TMR_CTRL_OUTMODE_MASK);
if (dutyCycleU16 == 0) {
// Clear the output at the next compare
reg |= (TMR_CTRL_LENGTH_MASK | TMR_CTRL_OUTMODE(kQTMR_ClearOnCompare));
} else if (dutyCycleU16 >= 65536) {
// Set the output at the next compare
reg |= (TMR_CTRL_LENGTH_MASK | TMR_CTRL_OUTMODE(kQTMR_SetOnCompare));
} else {
// Count until compare value is reached and re-initialize the counter, toggle OFLAG output
// using alternating compare register
reg |= (TMR_CTRL_LENGTH_MASK | TMR_CTRL_OUTMODE(kQTMR_ToggleOnAltCompareReg));
}
base->CHANNEL[channel].CTRL = reg;
return kStatus_Success;
}
#endif // FSL_FEATURE_SOC_TMR_COUNT