/* * Copyright (C) 2016 Stefan BrĂ¼ns * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA */ /* Set the following three defines to your needs */ #ifndef __PWM_H__ #define __PWM_H__ /*SUPPORT UP TO 8 PWM CHANNEL*/ //#define PWM_CHANNEL_NUM_MAX 8 // ----------------------------------------------------------------------------- // pwm.h // ----------------------------------------------------------------------------- struct pwm_param { uint32 period; uint32 freq; uint32 duty[PWM_CHANNEL_NUM_MAX]; //PWM_CHANNEL<=8 }; /* pwm_init should be called only once, for now */ void pwm_init(uint32 period, uint32 *duty,uint32 pwm_channel_num,uint32 (*pin_info_list)[3]); void pwm_start(void); void pwm_set_duty(uint32 duty, uint8 channel); uint32 pwm_get_duty(uint8 channel); void pwm_set_period(uint32 period); uint32 pwm_get_period(void); uint32 get_pwm_version(void); void set_pwm_debug_en(uint8 print_en); // ----------------------------------------------------------------------------- // pwm.c // ----------------------------------------------------------------------------- #ifndef SDK_PWM_PERIOD_COMPAT_MODE #define SDK_PWM_PERIOD_COMPAT_MODE 0 #endif #ifndef PWM_MAX_CHANNELS #define PWM_MAX_CHANNELS 8 #endif #define PWM_DEBUG 0 #define PWM_USE_NMI 1 /* no user servicable parts beyond this point */ #define PWM_MAX_TICKS 0x7fffff #if SDK_PWM_PERIOD_COMPAT_MODE #define PWM_PERIOD_TO_TICKS(x) (x * 0.2) #define PWM_DUTY_TO_TICKS(x) (x * 5) #define PWM_MAX_DUTY (PWM_MAX_TICKS * 0.2) #define PWM_MAX_PERIOD (PWM_MAX_TICKS * 5) #else #define PWM_PERIOD_TO_TICKS(x) (x) #define PWM_DUTY_TO_TICKS(x) (x) #define PWM_MAX_DUTY PWM_MAX_TICKS #define PWM_MAX_PERIOD PWM_MAX_TICKS #endif #include #include #include #include // from SDK hw_timer.c #define TIMER1_DIVIDE_BY_16 0x0004 #define TIMER1_ENABLE_TIMER 0x0080 struct pwm_phase { uint32_t ticks; ///< delay until next phase, in 200ns units uint16_t on_mask; ///< GPIO mask to switch on uint16_t off_mask; ///< GPIO mask to switch off }; /* Three sets of PWM phases, the active one, the one used * starting with the next cycle, and the one updated * by pwm_start. After the update pwm_next_set * is set to the last updated set. pwm_current_set is set to * pwm_next_set from the interrupt routine during the first * pwm phase */ typedef struct pwm_phase (pwm_phase_array)[PWM_MAX_CHANNELS + 2]; static pwm_phase_array pwm_phases[3]; static struct { struct pwm_phase* next_set; struct pwm_phase* current_set; uint8_t current_phase; } pwm_state; static uint32_t pwm_period; static uint32_t pwm_period_ticks; static uint32_t pwm_duty[PWM_MAX_CHANNELS]; static uint16_t gpio_mask[PWM_MAX_CHANNELS]; static uint8_t pwm_channels; // 3-tuples of MUX_REGISTER, MUX_VALUE and GPIO number typedef uint32_t (pin_info_type)[3]; struct gpio_regs { uint32_t out; /* 0x60000300 */ uint32_t out_w1ts; /* 0x60000304 */ uint32_t out_w1tc; /* 0x60000308 */ uint32_t enable; /* 0x6000030C */ uint32_t enable_w1ts; /* 0x60000310 */ uint32_t enable_w1tc; /* 0x60000314 */ uint32_t in; /* 0x60000318 */ uint32_t status; /* 0x6000031C */ uint32_t status_w1ts; /* 0x60000320 */ uint32_t status_w1tc; /* 0x60000324 */ }; static struct gpio_regs* gpio = (struct gpio_regs*)(0x60000300); struct timer_regs { uint32_t frc1_load; /* 0x60000600 */ uint32_t frc1_count; /* 0x60000604 */ uint32_t frc1_ctrl; /* 0x60000608 */ uint32_t frc1_int; /* 0x6000060C */ uint8_t pad[16]; uint32_t frc2_load; /* 0x60000620 */ uint32_t frc2_count; /* 0x60000624 */ uint32_t frc2_ctrl; /* 0x60000628 */ uint32_t frc2_int; /* 0x6000062C */ uint32_t frc2_alarm; /* 0x60000630 */ }; static struct timer_regs* timer = (struct timer_regs*)(0x60000600); static void ICACHE_RAM_ATTR pwm_intr_handler(void) { if ((pwm_state.current_set[pwm_state.current_phase].off_mask == 0) && (pwm_state.current_set[pwm_state.current_phase].on_mask == 0)) { pwm_state.current_set = pwm_state.next_set; pwm_state.current_phase = 0; } do { // force write to GPIO registers on each loop asm volatile ("" : : : "memory"); gpio->out_w1ts = (uint32_t)(pwm_state.current_set[pwm_state.current_phase].on_mask); gpio->out_w1tc = (uint32_t)(pwm_state.current_set[pwm_state.current_phase].off_mask); uint32_t ticks = pwm_state.current_set[pwm_state.current_phase].ticks; pwm_state.current_phase++; if (ticks) { if (ticks >= 16) { // constant interrupt overhead ticks -= 9; timer->frc1_int &= ~FRC1_INT_CLR_MASK; WRITE_PERI_REG(&timer->frc1_load, ticks); return; } ticks *= 4; do { ticks -= 1; // stop compiler from optimizing delay loop to noop asm volatile ("" : : : "memory"); } while (ticks > 0); } } while (1); } /** * period: initial period (base unit 1us OR 200ns) * duty: array of initial duty values, may be NULL, may be freed after pwm_init * pwm_channel_num: number of channels to use * pin_info_list: array of pin_info */ void ICACHE_FLASH_ATTR pwm_init(uint32_t period, uint32_t *duty, uint32_t pwm_channel_num, uint32_t (*pin_info_list)[3]) { int i, j, n; pwm_channels = pwm_channel_num; if (pwm_channels > PWM_MAX_CHANNELS) pwm_channels = PWM_MAX_CHANNELS; for (i = 0; i < 3; i++) { for (j = 0; j < (PWM_MAX_CHANNELS + 2); j++) { pwm_phases[i][j].ticks = 0; pwm_phases[i][j].on_mask = 0; pwm_phases[i][j].off_mask = 0; } } pwm_state.current_set = pwm_state.next_set = 0; pwm_state.current_phase = 0; uint32_t all = 0; // PIN info: MUX-Register, Mux-Setting, PIN-Nr for (n = 0; n < pwm_channels; n++) { pin_info_type* pin_info = &pin_info_list[n]; PIN_FUNC_SELECT((*pin_info)[0], (*pin_info)[1]); gpio_mask[n] = 1 << (*pin_info)[2]; all |= 1 << (*pin_info)[2]; if (duty) pwm_set_duty(duty[n], n); } GPIO_REG_WRITE(GPIO_OUT_W1TC_ADDRESS, all); GPIO_REG_WRITE(GPIO_ENABLE_W1TS_ADDRESS, all); pwm_set_period(period); #if PWM_USE_NMI ETS_FRC_TIMER1_NMI_INTR_ATTACH(pwm_intr_handler); #else ETS_FRC_TIMER1_INTR_ATTACH(pwm_intr_handler, NULL); #endif TM1_EDGE_INT_ENABLE(); timer->frc1_int &= ~FRC1_INT_CLR_MASK; timer->frc1_ctrl = 0; pwm_start(); } __attribute__ ((noinline)) static uint8_t ICACHE_FLASH_ATTR _pwm_phases_prep(struct pwm_phase* pwm) { uint8_t n, phases; for (n = 0; n < pwm_channels + 2; n++) { pwm[n].ticks = 0; pwm[n].on_mask = 0; pwm[n].off_mask = 0; } phases = 1; for (n = 0; n < pwm_channels; n++) { uint32_t ticks = PWM_DUTY_TO_TICKS(pwm_duty[n]); if (ticks == 0) { pwm[0].off_mask |= gpio_mask[n]; } else if (ticks >= pwm_period_ticks) { pwm[0].on_mask |= gpio_mask[n]; } else { if (ticks < (pwm_period_ticks/2)) { pwm[phases].ticks = ticks; pwm[0].on_mask |= gpio_mask[n]; pwm[phases].off_mask = gpio_mask[n]; } else { pwm[phases].ticks = pwm_period_ticks - ticks; pwm[phases].on_mask = gpio_mask[n]; pwm[0].off_mask |= gpio_mask[n]; } phases++; } } pwm[phases].ticks = pwm_period_ticks; // bubble sort, lowest to hightest duty n = 2; while (n < phases) { if (pwm[n].ticks < pwm[n - 1].ticks) { struct pwm_phase t = pwm[n]; pwm[n] = pwm[n - 1]; pwm[n - 1] = t; if (n > 2) n--; } else { n++; } } #if PWM_DEBUG int t = 0; for (t = 0; t <= phases; t++) { ets_printf("%d @%d: %04x %04x\n", t, pwm[t].ticks, pwm[t].on_mask, pwm[t].off_mask); } #endif // shift left to align right edge; uint8_t l = 0, r = 1; while (r <= phases) { uint32_t diff = pwm[r].ticks - pwm[l].ticks; if (diff && (diff <= 16)) { uint16_t mask = pwm[r].on_mask | pwm[r].off_mask; pwm[l].off_mask ^= pwm[r].off_mask; pwm[l].on_mask ^= pwm[r].on_mask; pwm[0].off_mask ^= pwm[r].on_mask; pwm[0].on_mask ^= pwm[r].off_mask; pwm[r].ticks = pwm_period_ticks - diff; pwm[r].on_mask ^= mask; pwm[r].off_mask ^= mask; } else { l = r; } r++; } #if PWM_DEBUG for (t = 0; t <= phases; t++) { ets_printf("%d @%d: %04x %04x\n", t, pwm[t].ticks, pwm[t].on_mask, pwm[t].off_mask); } #endif // sort again n = 2; while (n <= phases) { if (pwm[n].ticks < pwm[n - 1].ticks) { struct pwm_phase t = pwm[n]; pwm[n] = pwm[n - 1]; pwm[n - 1] = t; if (n > 2) n--; } else { n++; } } // merge same duty l = 0, r = 1; while (r <= phases) { if (pwm[r].ticks == pwm[l].ticks) { pwm[l].off_mask |= pwm[r].off_mask; pwm[l].on_mask |= pwm[r].on_mask; pwm[r].on_mask = 0; pwm[r].off_mask = 0; } else { l++; if (l != r) { struct pwm_phase t = pwm[l]; pwm[l] = pwm[r]; pwm[r] = t; } } r++; } phases = l; #if PWM_DEBUG for (t = 0; t <= phases; t++) { ets_printf("%d @%d: %04x %04x\n", t, pwm[t].ticks, pwm[t].on_mask, pwm[t].off_mask); } #endif // transform absolute end time to phase durations for (n = 0; n < phases; n++) { pwm[n].ticks = pwm[n + 1].ticks - pwm[n].ticks; // subtract common overhead pwm[n].ticks--; } pwm[phases].ticks = 0; // do a cyclic shift if last phase is short if (pwm[phases - 1].ticks < 16) { for (n = 0; n < phases - 1; n++) { struct pwm_phase t = pwm[n]; pwm[n] = pwm[n + 1]; pwm[n + 1] = t; } } #if PWM_DEBUG for (t = 0; t <= phases; t++) { ets_printf("%d +%d: %04x %04x\n", t, pwm[t].ticks, pwm[t].on_mask, pwm[t].off_mask); } ets_printf("\n"); #endif return phases; } void ICACHE_FLASH_ATTR pwm_start(void) { pwm_phase_array* pwm = &pwm_phases[0]; if ((*pwm == pwm_state.next_set) || (*pwm == pwm_state.current_set)) pwm++; if ((*pwm == pwm_state.next_set) || (*pwm == pwm_state.current_set)) pwm++; uint8_t phases = _pwm_phases_prep(*pwm); // all with 0% / 100% duty - stop timer if (phases == 1) { if (pwm_state.next_set) { #if PWM_DEBUG ets_printf("PWM stop\n"); #endif timer->frc1_ctrl = 0; ETS_FRC1_INTR_DISABLE(); } pwm_state.next_set = NULL; GPIO_REG_WRITE(GPIO_OUT_W1TS_ADDRESS, (*pwm)[0].on_mask); GPIO_REG_WRITE(GPIO_OUT_W1TC_ADDRESS, (*pwm)[0].off_mask); return; } // start if not running if (!pwm_state.next_set) { #if PWM_DEBUG ets_printf("PWM start\n"); #endif pwm_state.current_set = pwm_state.next_set = *pwm; pwm_state.current_phase = phases - 1; ETS_FRC1_INTR_ENABLE(); RTC_REG_WRITE(FRC1_LOAD_ADDRESS, 0); timer->frc1_ctrl = TIMER1_DIVIDE_BY_16 | TIMER1_ENABLE_TIMER; return; } pwm_state.next_set = *pwm; } void ICACHE_FLASH_ATTR pwm_set_duty(uint32_t duty, uint8_t channel) { if (channel > PWM_MAX_CHANNELS) return; if (duty > PWM_MAX_DUTY) duty = PWM_MAX_DUTY; pwm_duty[channel] = duty; } uint32_t ICACHE_FLASH_ATTR pwm_get_duty(uint8_t channel) { if (channel > PWM_MAX_CHANNELS) return 0; return pwm_duty[channel]; } void ICACHE_FLASH_ATTR pwm_set_period(uint32_t period) { pwm_period = period; if (pwm_period > PWM_MAX_PERIOD) pwm_period = PWM_MAX_PERIOD; pwm_period_ticks = PWM_PERIOD_TO_TICKS(period); } uint32_t ICACHE_FLASH_ATTR pwm_get_period(void) { return pwm_period; } uint32_t ICACHE_FLASH_ATTR get_pwm_version(void) { return 1; } void ICACHE_FLASH_ATTR set_pwm_debug_en(uint8_t print_en) { (void) print_en; } #endif