circuitpython/ports/mimxrt/machine_pwm.c

619 lines
21 KiB
C
Raw Normal View History

mimxrt: Support PWM using the FLEXPWM and QTMR modules. Frequency range 15Hz/18Hz to > 1 MHz, with decreasing resolution of the duty cycle. The basic API is supported as documentated, except that keyword parameters are accepted for both the instatiaton and the PWM.init() call. Extensions: support PWM for channel pairs. Channel pairs are declared by supplying 2-element tuples for the pins. The two channels of a pair must be the A/B channel of a FLEXPWM module. These form than a complementary pair. Additional supported keyword arguments: - center=value Defines the center position of a pulse within the pulse cycle. The align keyword is actually shortcut for center. - sync=True|False: If set to True, the channels will be synchronized to a submodule 0 channel, which has already to be enabled. - align=PWM.MIDDLE | PMW.BEGIN | PWM.END. It defines, whether synchronized channels are Center-Aligned or Edge-aligned. The channels must be either complementary a channel pair or a group of synchronized channels. It may as well be applied to a single channel, but withiout any benefit. - invert= 0..3. Controls ouput inversion of the pins. Bit 0 controls the first pin, bit 1 the second. - deadtime=time_ns time of complementary channels for delaying the rising slope. - xor=0|1|2 xor causes the output of channel A and B to be xored. If applied to a X channel, it shows the value oif A ^ B. If applied to an A or B channel, both channel show the xored signal for xor=1. For xor=2, the xored signal is split between channels A and B. See also the Reference Manual, chapter about double pulses. The behavior of xor=2 can also be achieved using the center method for locating a pulse within a clock period. The output is enabled for board pins only. CPU pins may still be used for FLEXPWM, e.g. as sync source, but the signal will not be routed to the output. That applies only to FLEXPWM pins. The use of QTMR pins which are not board pins will be rejected. As part of this commit, the _WFE() statement is removed from ticks_delay_us64() to prevent PWM glitching during calls to sleep().
2021-07-26 06:48:25 -04:00
/*
* This file is part of the MicroPython project, http://micropython.org/
*
* The MIT License (MIT)
*
* Copyright (c) 2020-2021 Damien P. George
* Copyright (c) 2021 Robert Hammelrath
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*/
#include "py/runtime.h"
#include "py/mphal.h"
#include "modmachine.h"
#include "pin.h"
#include "fsl_clock.h"
#include "fsl_iomuxc.h"
#include "hal/pwm_backport.h"
#define PWM_MIDDLE (0)
#define PWM_BEGIN (1)
#define PWM_END (2)
#define PWM_CHANNEL1 (1)
#define PWM_CHANNEL2 (2)
typedef struct _machine_pwm_obj_t {
mp_obj_base_t base;
PWM_Type *instance;
bool is_flexpwm;
uint8_t complementary;
uint8_t module;
uint8_t submodule;
uint8_t channel1;
uint8_t channel2;
uint8_t invert;
bool sync;
uint32_t freq;
int16_t prescale;
uint16_t duty_u16;
uint32_t duty_ns;
uint16_t center;
uint32_t deadtime;
bool output_enable_1;
bool output_enable_2;
uint8_t xor;
bool is_init;
} machine_pwm_obj_t;
static char channel_char[] = {'B', 'A', 'X' };
static char *ERRMSG_FREQ = "PWM frequency too low";
static char *ERRMSG_INIT = "PWM set-up failed";
static char *ERRMSG_VALUE = "value larger than period";
STATIC void machine_pwm_start(machine_pwm_obj_t *self);
STATIC void mp_machine_pwm_print(const mp_print_t *print, mp_obj_t self_in, mp_print_kind_t kind) {
machine_pwm_obj_t *self = MP_OBJ_TO_PTR(self_in);
if (self->is_flexpwm) {
mp_printf(print, "<FLEXPWM module=%u submodule=%u ", self->module, self->submodule);
if (self->complementary) {
mp_printf(print, "channel=%c/%c", channel_char[self->channel1], channel_char[self->channel2]);
} else {
mp_printf(print, "channel=%c", channel_char[self->channel1]);
}
if (self->duty_ns != 0) {
mp_printf(print, " duty_ns=%u", self->duty_ns);
} else {
mp_printf(print, " duty_u16=%u", self->duty_u16);
}
mp_printf(print, " freq=%u center=%u, deadtime=%u, sync=%u>",
self->freq, self->center, self->deadtime, self->sync);
#ifdef FSL_FEATURE_SOC_TMR_COUNT
} else {
mp_printf(print, "<QTMR_PWM module=%u channel=%u freq1=%u ",
self->module, self->channel1, self->freq);
if (self->duty_ns != 0) {
mp_printf(print, "duty_ns=%u>", self->duty_ns);
} else {
mp_printf(print, "duty_u16=%u>", self->duty_u16);
}
#endif
}
}
// Utility functions for decoding and convertings
//
STATIC uint32_t duty_ns_to_duty_u16(uint32_t freq, uint32_t duty_ns) {
uint64_t duty = (uint64_t)duty_ns * freq * PWM_FULL_SCALE / 1000000000ULL;
if (duty >= PWM_FULL_SCALE) {
mp_raise_ValueError(MP_ERROR_TEXT(ERRMSG_VALUE));
}
return (uint32_t)duty;
}
STATIC uint8_t module_decode(char channel) {
switch (channel) {
case '0':
return kPWM_Module_0;
case '1':
return kPWM_Module_1;
case '2':
return kPWM_Module_2;
case '3':
return kPWM_Module_3;
default:
return kPWM_Module_1;
}
}
STATIC uint8_t channel_decode(char channel) {
switch (channel) {
case 'A':
return kPWM_PwmA;
case 'B':
return kPWM_PwmB;
case 'X':
return kPWM_PwmX;
default:
return kPWM_PwmA;
}
}
// decode the AF objects module and Port numer. Returns NULL if it is not a FLEXPWM object
STATIC const machine_pin_af_obj_t *af_name_decode_flexpwm(const machine_pin_af_obj_t *af_obj,
uint8_t *module, uint8_t *submodule, uint8_t *channel) {
const char *str;
size_t len;
str = (char *)qstr_data(af_obj->name, &len);
// test for the name starting with FLEXPWM
if (len < 15 || strncmp(str, "FLEXPWM", 7) != 0) {
return NULL;
}
// Get module, submodule and channel from the name, e.g. FLEXPWM1_PWM0_A
*module = str[7] - '0';
*submodule = module_decode(str[12]);
*channel = channel_decode(str[14]);
return af_obj;
}
#ifdef FSL_FEATURE_SOC_TMR_COUNT
STATIC uint8_t qtmr_decode(char channel) {
switch (channel) {
case '0':
return kQTMR_Channel_0;
case '1':
return kQTMR_Channel_1;
case '2':
return kQTMR_Channel_2;
case '3':
return kQTMR_Channel_3;
default:
return kPWM_Module_1;
}
}
// decode the AF objects module and Port numer. Returns NULL if it is not a QTMR object
STATIC const machine_pin_af_obj_t *af_name_decode_qtmr(const machine_pin_af_obj_t *af_obj, uint8_t *module, uint8_t *channel) {
const char *str;
size_t len;
str = (char *)qstr_data(af_obj->name, &len);
// test for the name starting with TMR
if (len < 11 || strncmp(str, "TMR", 3) != 0) {
return NULL;
}
// Get module, submodule and channel from the name, e.g. FLEXPWM1_PWM0_A
*module = str[3] - '0';
*channel = qtmr_decode(str[10]);
return af_obj;
}
#endif
STATIC bool is_board_pin(const machine_pin_obj_t *pin) {
for (int i = 0; i < num_board_pins; i++) {
if (pin == machine_pin_board_pins[i]) {
return true;
}
}
return false;
}
// Functions for configuring the PWM Device
//
STATIC int calc_prescaler(uint32_t clock, uint32_t freq) {
float temp = (float)clock / (float)PWM_FULL_SCALE / (float)freq;
for (int prescale = 0; prescale < 8; prescale++, temp /= 2) {
if (temp <= 1) {
return prescale;
}
}
// Frequency too low, cannot scale down.
return -1;
}
STATIC void configure_flexpwm(machine_pwm_obj_t *self) {
pwm_signal_param_u16_t pwmSignal;
// Initialize PWM module.
uint32_t pwmSourceClockInHz = CLOCK_GetFreq(kCLOCK_IpgClk);
int prescale = calc_prescaler(pwmSourceClockInHz, self->freq);
if (prescale < 0) {
mp_raise_ValueError(MP_ERROR_TEXT(ERRMSG_FREQ));
}
if (self->prescale != prescale || self->is_init == false) {
pwm_config_t pwmConfig;
PWM_GetDefaultConfig(&pwmConfig);
self->prescale = prescale;
pwmConfig.prescale = prescale;
pwmConfig.reloadLogic = kPWM_ReloadPwmFullCycle;
if (self->complementary) {
pwmConfig.pairOperation = self->channel1 == kPWM_PwmA ? kPWM_ComplementaryPwmA : kPWM_ComplementaryPwmB;
} else {
pwmConfig.pairOperation = kPWM_Independent;
}
pwmConfig.clockSource = kPWM_BusClock;
pwmConfig.enableWait = false;
pwmConfig.initializationControl = self->sync ? kPWM_Initialize_MasterSync : kPWM_Initialize_LocalSync;
if (PWM_Init(self->instance, self->submodule, &pwmConfig) == kStatus_Fail) {
mp_raise_ValueError(MP_ERROR_TEXT(ERRMSG_INIT));
}
}
// Disable the fault detect function to avoid using the xbara
PWM_SetupFaultDisableMap(self->instance, self->submodule, self->channel1, kPWM_faultchannel_0, 0);
PWM_SetupFaultDisableMap(self->instance, self->submodule, self->channel1, kPWM_faultchannel_1, 0);
if (self->complementary) {
PWM_SetupFaultDisableMap(self->instance, self->submodule, self->channel2, kPWM_faultchannel_0, 0);
PWM_SetupFaultDisableMap(self->instance, self->submodule, self->channel2, kPWM_faultchannel_1, 0);
}
if (self->channel1 != kPWM_PwmX) { // Only for A/B channels
// Initialize the channel parameters
pwmSignal.pwmChannel = self->channel1;
pwmSignal.level = (self->invert & PWM_CHANNEL1) ? kPWM_LowTrue : kPWM_HighTrue;
pwmSignal.dutyCycle_u16 = self->duty_u16;
pwmSignal.Center_u16 = self->center;
pwmSignal.deadtimeValue = ((uint64_t)pwmSourceClockInHz * self->deadtime) / 1000000000ULL;
PWM_SetupPwm_u16(self->instance, self->submodule, &pwmSignal, self->freq,
pwmSourceClockInHz, self->output_enable_1);
if (self->complementary) {
// Initialize the second channel of the pair.
pwmSignal.pwmChannel = self->channel2;
pwmSignal.level = (self->invert & PWM_CHANNEL2) ? kPWM_LowTrue : kPWM_HighTrue;
PWM_SetupPwm_u16(self->instance, self->submodule, &pwmSignal, self->freq,
pwmSourceClockInHz, self->output_enable_2);
}
if (self->xor == 1) {
// Set the DBLEN bit for A, B = A ^ B
self->instance->SM[self->submodule].CTRL &= ~PWM_CTRL_SPLIT_MASK;
self->instance->SM[self->submodule].CTRL |= PWM_CTRL_DBLEN_MASK;
} else if (self->xor == 2) {
// Set the DBLEN and SPLIT bits for A, B = A ^ B
self->instance->SM[self->submodule].CTRL |= PWM_CTRL_DBLEN_MASK | PWM_CTRL_SPLIT_MASK;
} else {
self->instance->SM[self->submodule].CTRL &= ~(PWM_CTRL_DBLEN_MASK | PWM_CTRL_SPLIT_MASK);
}
} else {
PWM_SetupPwmx_u16(self->instance, self->submodule, self->freq, self->duty_u16,
self->invert, pwmSourceClockInHz);
if (self->xor) {
// Set the DBLX bit for X = A ^ B
self->instance->SM[self->submodule].CTRL |= PWM_CTRL_DBLX_MASK;
} else {
self->instance->SM[self->submodule].CTRL &= ~PWM_CTRL_DBLX_MASK;
}
}
// Set the load okay bit for the submodules
PWM_SetPwmLdok(self->instance, 1 << self->submodule, true);
// Start the PWM generation from the Submodules
PWM_StartTimer(self->instance, 1 << self->submodule);
}
#ifdef FSL_FEATURE_SOC_TMR_COUNT
STATIC void configure_qtmr(machine_pwm_obj_t *self) {
qtmr_config_t qtmrConfig;
int prescale;
TMR_Type *instance = (TMR_Type *)self->instance;
prescale = calc_prescaler(CLOCK_GetFreq(kCLOCK_IpgClk), self->freq);
if (prescale < 0) {
mp_raise_ValueError(MP_ERROR_TEXT(ERRMSG_FREQ));
}
if (prescale != self->prescale) {
QTMR_GetDefaultConfig(&qtmrConfig);
qtmrConfig.primarySource = prescale + kQTMR_ClockDivide_1;
QTMR_Init(instance, self->channel1, &qtmrConfig);
self->prescale = prescale;
}
// Set up the PWM channel
if (QTMR_SetupPwm_u16(instance, self->channel1, self->freq, self->duty_u16,
self->invert, CLOCK_GetFreq(kCLOCK_IpgClk) / (1 << prescale), self->is_init) == kStatus_Fail) {
mp_raise_ValueError(MP_ERROR_TEXT(ERRMSG_INIT));
}
// Start the output
QTMR_StartTimer(instance, self->channel1, kQTMR_PriSrcRiseEdge);
}
#endif // FSL_FEATURE_SOC_TMR_COUNT
STATIC void configure_pwm(machine_pwm_obj_t *self) {
// Set the clock frequencies
// Freq range is 15Hz to ~ 3 MHz.
static bool set_frequency = true;
// set the frequency only once
if (set_frequency) {
CLOCK_SetDiv(kCLOCK_IpgDiv, 0x3); // Set IPG PODF to 3, divide by 4
set_frequency = false;
}
if (self->duty_ns != 0) {
self->duty_u16 = duty_ns_to_duty_u16(self->freq, self->duty_ns);
}
if (self->is_flexpwm) {
configure_flexpwm(self);
#ifdef FSL_FEATURE_SOC_TMR_COUNT
} else {
configure_qtmr(self);
#endif
}
}
// Micropython API functions
//
STATIC void mp_machine_pwm_init_helper(machine_pwm_obj_t *self,
size_t n_args, const mp_obj_t *pos_args, mp_map_t *kw_args) {
enum { ARG_freq, ARG_duty_u16, ARG_duty_ns, ARG_center, ARG_align,
ARG_invert, ARG_sync, ARG_xor, ARG_deadtime };
static const mp_arg_t allowed_args[] = {
{ MP_QSTR_freq, MP_ARG_INT, {.u_int = 0} },
{ MP_QSTR_duty_u16, MP_ARG_INT, {.u_int = 0} },
{ MP_QSTR_duty_ns, MP_ARG_INT, {.u_int = 0} },
{ MP_QSTR_center, MP_ARG_KW_ONLY | MP_ARG_INT, {.u_int = -1} },
{ MP_QSTR_align, MP_ARG_KW_ONLY | MP_ARG_INT, {.u_int = -1}},
{ MP_QSTR_invert, MP_ARG_KW_ONLY | MP_ARG_INT, {.u_int = -1}},
{ MP_QSTR_sync, MP_ARG_KW_ONLY | MP_ARG_INT, {.u_int = -1}},
{ MP_QSTR_xor, MP_ARG_KW_ONLY | MP_ARG_INT, {.u_int = -1}},
{ MP_QSTR_deadtime, MP_ARG_KW_ONLY | MP_ARG_INT, {.u_int = -1}},
};
mp_arg_val_t args[MP_ARRAY_SIZE(allowed_args)];
mp_arg_parse_all(n_args, pos_args, kw_args,
MP_ARRAY_SIZE(allowed_args), allowed_args, args);
if ((n_args + kw_args->used) > 0 || self->is_init == false) {
// Maybe change PWM timer
if (args[ARG_freq].u_int > 0) {
self->freq = args[ARG_freq].u_int;
}
// Set duty_u16 cycle?
uint32_t duty = args[ARG_duty_u16].u_int;
if (duty != 0) {
if (duty >= PWM_FULL_SCALE) {
mp_raise_ValueError(MP_ERROR_TEXT(ERRMSG_VALUE));
}
self->duty_u16 = duty;
self->duty_ns = 0;
}
// Set duty_ns value?
duty = args[ARG_duty_ns].u_int;
if (duty != 0) {
self->duty_ns = duty;
self->duty_u16 = duty_ns_to_duty_u16(self->freq, self->duty_ns);
}
// Set center value?
int32_t center = args[ARG_center].u_int;
if (center >= 0) {
if (center >= PWM_FULL_SCALE) {
mp_raise_ValueError(MP_ERROR_TEXT(ERRMSG_VALUE));
}
self->center = center;
} else { // Use alignment setting shortcut
if (args[ARG_align].u_int >= 0) {
uint8_t align = args[ARG_align].u_int & 3; // limit to 0..3
if (align == PWM_BEGIN) {
self->center = self->duty_u16 / 2;
} else if (align == PWM_END) {
self->center = PWM_FULL_SCALE - self->duty_u16 / 2;
} else {
self->center = 32768; // Default value: mid.
}
}
}
if (args[ARG_invert].u_int >= 0) {
self->invert = args[ARG_invert].u_int & (PWM_CHANNEL1 | PWM_CHANNEL2);
}
if (args[ARG_sync].u_int >= 0) {
self->sync = args[ARG_sync].u_int != false && self->submodule != 0;
}
if (args[ARG_xor].u_int >= 0) {
self->xor = args[ARG_xor].u_int & 0x03;
}
if (args[ARG_deadtime].u_int >= 0) {
self->deadtime = args[ARG_deadtime].u_int;
}
configure_pwm(self);
self->is_init = true;
} else {
machine_pwm_start(self);
}
}
// PWM(pin | pin-tuple, freq, [args])
STATIC mp_obj_t mp_machine_pwm_make_new(const mp_obj_type_t *type, size_t n_args, size_t n_kw, const mp_obj_t *args) {
// Check number of arguments
mp_arg_check_num(n_args, n_kw, 1, MP_OBJ_FUN_ARGS_MAX, true);
mp_obj_t *pins;
const machine_pin_obj_t *pin1;
const machine_pin_obj_t *pin2;
// Get referred Pin object(s)
if (mp_obj_is_type(args[0], &mp_type_tuple)) {
mp_obj_get_array_fixed_n(args[0], 2, &pins);
pin1 = pin_find(pins[0]);
pin2 = pin_find(pins[1]);
} else {
pin1 = pin_find(args[0]);
pin2 = NULL;
}
// Check whether it supports PWM and decode submodule & channel
const machine_pin_af_obj_t *af_obj1 = NULL;
uint8_t submodule1;
uint8_t channel1;
const machine_pin_af_obj_t *af_obj2 = NULL;
uint8_t submodule2;
uint8_t channel2;
uint8_t module;
bool is_flexpwm = false;
for (int i = 0; i < pin1->af_list_len; ++i) {
af_obj1 = af_name_decode_flexpwm(&(pin1->af_list[i]), &module, &submodule1, &channel1);
if (af_obj1 != NULL) {
break;
}
}
if (pin2 != NULL) {
for (int i = 0; i < pin1->af_list_len; ++i) {
af_obj2 = af_name_decode_flexpwm(&(pin2->af_list[i]), &module, &submodule2, &channel2);
if (af_obj2 != NULL) {
break;
}
}
}
if (af_obj1 == NULL) {
submodule1 = 0;
#ifdef FSL_FEATURE_SOC_TMR_COUNT
// Check for QTimer support
if (is_board_pin(pin1)) {
for (int i = 0; i < pin1->af_list_len; ++i) {
af_obj1 = af_name_decode_qtmr(&(pin1->af_list[i]), &module, &channel1);
if (af_obj1 != NULL) {
break;
}
}
}
#endif
if (af_obj1 == NULL) {
mp_raise_ValueError(MP_ERROR_TEXT("the requested Pin(s) does not support PWM"));
}
} else {
// is flexpwm, check for instance match
is_flexpwm = true;
if (pin2 != NULL && af_obj1->instance != af_obj2->instance && submodule1 != submodule2) {
mp_raise_ValueError(MP_ERROR_TEXT("the pins must be a A/B pair of a submodule"));
}
}
// Create and populate the PWM object.
machine_pwm_obj_t *self = m_new_obj(machine_pwm_obj_t);
self->base.type = &machine_pwm_type;
self->is_flexpwm = is_flexpwm;
self->instance = af_obj1->instance;
self->module = module;
self->submodule = submodule1;
self->channel1 = channel1;
self->invert = 0;
self->freq = 1000;
self->prescale = -1;
self->duty_u16 = 32768;
self->duty_ns = 0;
self->center = 32768;
self->output_enable_1 = is_board_pin(pin1);
self->sync = false;
self->deadtime = 0;
self->xor = 0;
self->is_init = false;
// Initialize the Pin(s).
CLOCK_EnableClock(kCLOCK_Iomuxc); // just in case it was not set yet
IOMUXC_SetPinMux(pin1->muxRegister, af_obj1->af_mode, af_obj1->input_register, af_obj1->input_daisy,
pin1->configRegister, 0U);
IOMUXC_SetPinConfig(pin1->muxRegister, af_obj1->af_mode, af_obj1->input_register, af_obj1->input_daisy,
pin1->configRegister, 0x10B0U);
// Settings for the second pin, if given.
if (pin2 != NULL && pin2 != pin1) {
self->complementary = 1;
self->channel2 = channel2;
self->output_enable_2 = is_board_pin(pin2);
// Initialize the Pin(s)
IOMUXC_SetPinMux(pin2->muxRegister, af_obj2->af_mode, af_obj2->input_register, af_obj2->input_daisy,
pin2->configRegister, 0U);
IOMUXC_SetPinConfig(pin2->muxRegister, af_obj2->af_mode, af_obj2->input_register, af_obj2->input_daisy,
pin2->configRegister, 0x10B0U);
} else {
self->complementary = 0;
}
// Process the remaining parameters.
mp_map_t kw_args;
mp_map_init_fixed_table(&kw_args, n_kw, args + n_args);
mp_machine_pwm_init_helper(self, n_args - 1, args + 1, &kw_args);
return MP_OBJ_FROM_PTR(self);
}
// Disable all PWM devices. Called on soft reset
void machine_pwm_deinit_all(void) {
static PWM_Type *const pwm_bases[] = PWM_BASE_PTRS;
for (int i = 1; i < ARRAY_SIZE(pwm_bases); i++) {
PWM_StopTimer(pwm_bases[i], 0x0f); // Stop all submodules
pwm_bases[i]->OUTEN = 0; // Disable ouput on all submodules, all channels
}
#ifdef FSL_FEATURE_SOC_TMR_COUNT
static TMR_Type *const tmr_bases[] = TMR_BASE_PTRS;
for (int i = 1; i < ARRAY_SIZE(tmr_bases); i++) {
for (int j = 0; j < 4; j++) {
QTMR_StopTimer(tmr_bases[i], j); // Stop all timers
}
}
#endif
}
STATIC void machine_pwm_start(machine_pwm_obj_t *self) {
if (self->is_flexpwm) {
PWM_StartTimer(self->instance, 1 << self->submodule);
#ifdef FSL_FEATURE_SOC_TMR_COUNT
} else {
QTMR_StartTimer((TMR_Type *)self->instance, self->channel1, kQTMR_PriSrcRiseEdge);
#endif
}
}
STATIC void mp_machine_pwm_deinit(machine_pwm_obj_t *self) {
if (self->is_flexpwm) {
PWM_StopTimer(self->instance, 1 << self->submodule);
#ifdef FSL_FEATURE_SOC_TMR_COUNT
} else {
QTMR_StopTimer((TMR_Type *)self->instance, self->channel1);
#endif
}
}
mp_obj_t mp_machine_pwm_freq_get(machine_pwm_obj_t *self) {
return MP_OBJ_NEW_SMALL_INT(self->freq);
}
void mp_machine_pwm_freq_set(machine_pwm_obj_t *self, mp_int_t freq) {
self->freq = freq;
configure_pwm(self);
}
mp_obj_t mp_machine_pwm_duty_get_u16(machine_pwm_obj_t *self) {
return MP_OBJ_NEW_SMALL_INT(self->duty_u16);
}
void mp_machine_pwm_duty_set_u16(machine_pwm_obj_t *self, mp_int_t duty) {
if (duty >= 0) {
if (duty >= PWM_FULL_SCALE) {
mp_raise_ValueError(MP_ERROR_TEXT(ERRMSG_VALUE));
}
self->duty_u16 = duty;
self->duty_ns = 0;
configure_pwm(self);
}
}
mp_obj_t mp_machine_pwm_duty_get_ns(machine_pwm_obj_t *self) {
return MP_OBJ_NEW_SMALL_INT(1000000000ULL / self->freq * self->duty_u16 / PWM_FULL_SCALE);
}
void mp_machine_pwm_duty_set_ns(machine_pwm_obj_t *self, mp_int_t duty) {
if (duty >= 0) {
self->duty_ns = duty;
self->duty_u16 = duty_ns_to_duty_u16(self->freq, self->duty_ns);
configure_pwm(self);
}
}