/* * Copyright (c) 2023 HPMicro * * SPDX-License-Identifier: BSD-3-Clause * */ #ifndef HPM_PWMV2_DRV_H #define HPM_PWMV2_DRV_H #include "hpm_common.h" #include "hpm_pwmv2_regs.h" #include "hpm_soc_feature.h" /** * @brief PWM driver APIs * @defgroup pwmv2_interface PWMV2 driver APIs * @ingroup motor_interfaces * @{ * */ #define PWM_UNLOCK_KEY (0xB0382607UL) #define PWM_CMP_UNABLE_OUTPUT_INDEX (16) /* IRQ enable bit mask */ #define PWM_IRQ_FAULT PWM_IRQEN_FAULTIRQE_MASK #define PWM_IRQ_EX_RELOAD PWM_IRQEN_XRLDIRQE_MASK #define PWM_IRQ_HALF_RELOAD PWM_IRQEN_HALFRLDIRQE_MASK #define PWM_IRQ_RELOAD PWM_IRQEN_RLDIRQE_MASK #define PWM_IRQ_CMP(x) PWM_IRQEN_CMPIRQEX_SET((1 << x)) /* PWM force output mask */ #define PWM_FORCE_OUTPUT(pwm_index, force_output) \ (force_output << (pwm_index << 1)) #define PWM_DUTY_CYCLE_FP_MAX ((1U << 24) - 1) #ifndef PWMV2_SOC_CAL_COUNT_MAX #define PWMV2_SOC_CAL_COUNT_MAX 8 #endif #define PWMV2_SHADOW_INDEX(x) PWMV2_SHADOW_VAL_##x #define PWMV2_CMP_INDEX(x) PWMV2_CMP_VAL_WORK_##x #define PWMV2_CALCULATE_INDEX(x) PWMV2_CAL_##x #define PWMV2_CAL_SHADOW_OFFSET_ZERO (31) typedef enum { pwm_counter_0 = 0, pwm_counter_1 = 1, pwm_counter_2 = 2, pwm_counter_3 = 3, } pwm_counter_t; typedef enum { pwm_channel_0 = 0, pwm_channel_1 = 1, pwm_channel_2 = 2, pwm_channel_3 = 3, pwm_channel_4 = 4, pwm_channel_5 = 5, pwm_channel_6 = 6, pwm_channel_7 = 7, } pwm_channel_t; typedef enum { pwm_reload_update_on_shlk = 0, pwm_reload_update_on_compare_point = 1, pwm_reload_update_on_reload = 2, pwm_reload_update_on_trigger = 3, } pwm_reload_update_time_t; /** * @brief pwm output type * */ typedef enum { pwm_force_output_0 = 0, /**< output 0 */ pwm_force_output_1 = 1, /**< output 1 */ pwm_force_output_high_z = 2, /**< output */ pwm_force_output_no_force = 3, } pwm_force_mode_t; typedef enum { pwm_fault_output_0 = 0, /**< output 0 */ pwm_fault_output_1 = 1, /**< output 1 */ pwm_fault_output_high_z = 2, /**< output */ } pwm_fault_mode_t; typedef enum { pad_fault_active_low = 1, pad_fault_active_high = 0, } pwm_fault_pad_polarity_t; typedef enum { pwm_shadow_register_output_polarity_on_shlk = 0, pwm_shadow_register_output_polarity_on_reload = 1, } pwm_shadow_register_output_polarity_t; typedef enum { pwm_force_update_shadow_immediately = 0, /**< after software set shlk bit of shlk register */ pwm_force_update_shadow_at_cmp_point = 1, pwm_force_update_shadow_at_reload = 2, /**< immediately after the register being modified */ pwm_force_update_shadow_none = 3, /**< after SHSYNCI assert */ } pwm_force_shadow_trigger_t; typedef enum { pwm_force_immediately = 0, /**< after software set shlk bit of shlk register */ pwm_force_at_reload = 1, pwm_force_at_trigmux = 2, pwm_force_none = 3, /**< after SHSYNCI assert */ } pwm_force_trigger_t; typedef enum { pwm_logic_four_cmp_or = 0, pwm_logic_four_cmp_and = 1, pwm_logic_four_cmp_xor = 2, pwm_logic_four_cmp_cd = 3, } pwm_logic_four_cmp_cfg_t; /** * @brief select when to recover PWM output after fault * */ typedef enum { pwm_fault_recovery_immediately = 0, /**< immediately*/ pwm_fault_recovery_on_reload = 1, /**< after pwm timer counter reload time*/ pwm_fault_recovery_on_hw_event = 2, /**< after hardware event assert*/ pwm_fault_recovery_on_fault_clear = 3, /**< after software write faultclr bit in GCR register*/ } pwm_fault_recovery_trigger_t; typedef enum { pwm_dac_channel_0 = 0, pwm_dac_channel_1 = 1, pwm_dac_channel_2 = 2, pwm_dac_channel_3 = 3, } pwm_dac_channel_t; typedef enum { pwm_capture_from_trigmux = 0, pwm_capture_from_gpio = 1 } pwm_capture_input_select_t; typedef enum { pwm_dma_0 = 0, pwm_dma_1 = 1, pwm_dma_2 = 2, pwm_dma_3 = 3, } pwm_dma_chn_t; typedef enum { pwm_shadow_register_update_on_shlk = 0, /**< after software set shlk bit of shlk register*/ pwm_shadow_register_update_on_modify = 1, /**< immediately after the register being modified*/ pwm_shadow_register_update_on_reload = 2, pwm_shadow_register_update_on_trigmux = 3, pwm_shadow_register_update_on_rld_cmp_select0 = 4, pwm_shadow_register_update_on_rld_cmp_select1 = 5, pwm_shadow_register_update_on_none = 6 } pwm_cmp_shadow_register_update_trigger_t; typedef enum { cmp_value_from_shadow_val = 0, cmp_value_from_calculate = 0x20, cmp_value_from_capture_posedge = 0x30, cmp_value_from_counters = 0x38, cmp_value_fffff000 = 0x3e, cmp_value_ffffff00 = 0x3f } pwm_cmp_source_t; /** * @brief pwm compare config * */ typedef struct pwmv2_cmp_config { uint32_t cmp; /**< compare value */ bool enable_half_cmp; /**< enable half compare value */ bool enable_hrcmp; /**< enable high precision pwm */ pwm_cmp_source_t cmp_source; /**< @ref pwm_cmp_source_t */ pwm_counter_t cmp_use_counter; /**< select one from 4 counters, only for CMP_N>=16 */ uint8_t cmp_source_index; /**< soure index */ uint8_t mode; /**< compare work mode: pwm_cmp_mode_output_compare or pwm_cmp_mode_input_capture */ pwm_cmp_shadow_register_update_trigger_t update_trigger; /**< compare configuration update trigger, need update trigger use pwm_shadow_register_update_on_trigmux */ uint8_t update_trigger_index; /**< select one trigger from 8, should set to pulse in trig_mux */ uint8_t hrcmp; /**< high precision pwm */ } pwmv2_cmp_config_t; /** * @brief pwm fault source config * */ typedef struct pwmv2_async_fault_source_config { uint8_t async_signal_from_pad_index; /**< select from 16bit async fault from pad*/ pwm_fault_pad_polarity_t fault_async_pad_level; /**< fault polarity for input fault from pad, 1-active low; 0-active high */ } pwmv2_async_fault_source_config_t; /** * @brief pwm config data * */ typedef struct pwmv2_config { bool enable_output; /**< enable pwm output */ bool enable_async_fault; /**< enable the input async faults from pad directly */ bool enable_sync_fault; /**< enable the input faults from trig_mux */ bool invert_output; /**< invert pwm output level */ bool enable_four_cmp; /**< Enable the four cmp functions */ pwmv2_async_fault_source_config_t async_fault_source; pwm_shadow_register_output_polarity_t update_polarity_time; pwm_logic_four_cmp_cfg_t logic; /**< valid only for pwm0/2/4/6 when trig_sel4 is set */ uint8_t update_trigger; /**< pwm config update trigger */ uint8_t fault_mode; /**< fault mode */ pwm_fault_recovery_trigger_t fault_recovery_trigger; /**< fault recoverty trigger */ uint8_t fault_recovery_trigmux_index; /**< select one trigger from 8, should set to pulse in trig_mux */ uint8_t force_shadow_trigmux_index; /**< select one trigger from 8, should set to pulse in trig_mux */ pwm_force_shadow_trigger_t force_shadow_trigger; /**< will load shadow register(force)mode) to force_mode_work at this time */ uint8_t force_trigmux_index; /**< select one trigger from 8 as force signal */ pwm_force_trigger_t force_trigger; /**< @ref pwm_force_trigger_t */ uint32_t dead_zone_in_half_cycle; /**< dead zone in half cycle*/ } pwmv2_config_t; /** * @brief pair pwm config * */ typedef struct pwmv2_pair_config { pwmv2_config_t pwm[2]; /**< pwm config data */ } pwmv2_pair_config_t; typedef struct pwmv2_cmp_calculate_cfg { uint8_t counter_index; /**< select one of 4 counter reload time */ uint8_t in_index; /**< 0~3 to select one of the dac input value; 4~7 to select one of the current counter value */ uint8_t in_offset_index; /**< from one of the shadow_val */ int8_t t_param; /**< period parameter */ int8_t d_param; /**< dac/counter value parameter */ int8_t up_limit_param; uint8_t up_limit_offset_index; /**< from one of the shadow_val */ int8_t low_limit_param; uint8_t low_limit_offset_index; /**< from one of the shadow_val */ bool enable_up_limit; bool enbale_low_limit; } pwmv2_cmp_calculate_cfg_t; #ifdef __cplusplus extern "C" { #endif /** * @brief pwm deinitialize function * * @param[in] pwm_x PWM base address, HPM_PWMx(x=0..n) * */ void pwmv2_deinit(PWMV2_Type *pwm_x); /** * @brief issue all shawdow register * * @param[in] pwm_x PWM base address, HPM_PWMx(x=0..n) */ static inline void pwmv2_issue_shadow_register_lock_event(PWMV2_Type *pwm_x) { pwm_x->WORK_CTRL1 |= PWMV2_WORK_CTRL1_SHADOW_LOCK_MASK; } /** * @brief lock all shawdow register * * @param[in] pwm_x PWM base address, HPM_PWMx(x=0..n) */ static inline void pwmv2_shadow_register_lock(PWMV2_Type *pwm_x) { pwm_x->WORK_CTRL1 |= PWMV2_WORK_CTRL1_SHADOW_LOCK_MASK; } /** * @brief select one trigger from 8, set to use input signal(selected by cnt_reload_trig) to reload timer * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t * @param trig_index one trigger from 8 */ static inline void pwmv2_set_counter_reload_trigmux_index(PWMV2_Type *pwm_x, pwm_counter_t counter, uint8_t trig_index) { pwm_x->CNT[counter].CFG2 = (pwm_x->CNT[counter].CFG2 & ~PWMV2_CNT_CFG2_CNT_RELOAD_TRIG_MASK) | PWMV2_CNT_CFG2_CNT_RELOAD_TRIG_SET(trig_index); } /** * @brief Multiple counters are enabled at the same time * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param mask bit0 - cnt0, bit1 - cnt1, bitn - cntn, n==3 */ static inline void pwmv2_enable_multi_counter_sync(PWMV2_Type *pwm_x, uint8_t mask) { pwm_x->CNT_GLBCFG &= ~(PWMV2_CNT_GLBCFG_TIMER_ENABLE_SET(mask)); fencerw(); pwm_x->CNT_GLBCFG |= PWMV2_CNT_GLBCFG_TIMER_ENABLE_SET(mask); } /** * @brief Multiple pwm out at the same time * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param mask bit0 - cnt0, bit1 - cnt1, bitn - cntn, n==3 */ static inline void pwmv2_start_pwm_output_sync(PWMV2_Type *pwm_x, uint8_t mask) { pwm_x->CNT_GLBCFG |= PWMV2_CNT_GLBCFG_CNT_SW_START_SET(mask); } /** * @brief unlock all shadow register * * @param[in] pwm_x PWM base address, HPM_PWMx(x=0..n) */ static inline void pwmv2_shadow_register_unlock(PWMV2_Type *pwm_x) { pwm_x->WORK_CTRL0 = PWM_UNLOCK_KEY; } /** * @brief The shadow registers can be updated only when related unlock_bit is set. * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param mask bit2 to bit 29 for value_shadow, bit30 for force_mode, bit31 for polarity. */ static inline void pwmv2_shadow_unlock_bit_mask(PWMV2_Type *pwm_x, uint32_t mask) { pwm_x->UNLOCK = mask; } /** * @brief Set the value of the shadow register * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param index shadow index * @param value normal value (24bit) * @param high_resolution_tick High precision pwm values (0 -255) * @param enable_half_cycle half-cycle pwm */ static inline void pwmv2_set_shadow_val(PWMV2_Type *pwm_x, uint8_t index, uint32_t value, uint8_t high_resolution_tick, bool enable_half_cycle) { pwm_x->SHADOW_VAL[index] = PWMV2_SHADOW_VAL_VALUE_SET(((value << 8) | (enable_half_cycle << 7) | (high_resolution_tick))); } /** * @brief force pwm output * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t * @param mode @ref pwm_force_mode_t * @param invert 0 - low level, 1 - high level */ static inline void pwmv2_force_output(PWMV2_Type *pwm_x, pwm_channel_t chn, pwm_force_mode_t mode, bool invert) { pwm_x->FORCE_MODE = (pwm_x->FORCE_MODE & ~(PWMV2_FORCE_MODE_POLARITY_SET((1 << (chn << 1))) | PWMV2_FORCE_MODE_FORCE_MODE_SET((3 << (chn << 1))))) | PWMV2_FORCE_MODE_POLARITY_SET((invert << (chn << 1))) | PWMV2_FORCE_MODE_FORCE_MODE_SET((mode << (chn << 1))); } /** * @brief enable four pwm outputs * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t */ static inline void pwmv2_enable_four_cmp(PWMV2_Type *pwm_x, pwm_channel_t chn) { pwm_x->PWM[chn].CFG0 |= PWMV2_PWM_CFG0_TRIG_SEL4_MASK; } /** * @brief disable four pwm outputs * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t */ static inline void pwmv2_disable_four_cmp(PWMV2_Type *pwm_x, pwm_channel_t chn) { pwm_x->PWM[chn].CFG0 &= ~PWMV2_PWM_CFG0_TRIG_SEL4_MASK; } /** * @brief Direct selection of the fail signal from the pin * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t * @param pad_index motor pad */ static inline void pwmv2_fault_signal_select_from_pad(PWMV2_Type *pwm_x, pwm_channel_t chn, uint8_t pad_index) { pwm_x->PWM[chn].CFG0 = (pwm_x->PWM[chn].CFG0 & ~PWMV2_PWM_CFG0_FAULT_SEL_ASYNC_MASK) | PWMV2_PWM_CFG0_FAULT_SEL_ASYNC_SET(pad_index); } /** * @brief Configure the polarity of the fail signal * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t * @param polarity @ref pwm_fault_pad_polarity_t */ static inline void pwmv2_fault_signal_polarity(PWMV2_Type *pwm_x, pwm_channel_t chn, pwm_fault_pad_polarity_t polarity) { pwm_x->PWM[chn].CFG0 = (pwm_x->PWM[chn].CFG0 & ~PWMV2_PWM_CFG0_FAULT_POL_ASYNC_MASK) | PWMV2_PWM_CFG0_FAULT_POL_ASYNC_SET(polarity); } /** * @brief Enable the fault signal from the pin * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t */ static inline void pwmv2_enable_fault_from_pad(PWMV2_Type *pwm_x, pwm_channel_t chn) { pwm_x->PWM[chn].CFG0 |= PWMV2_PWM_CFG0_FAULT_EN_ASYNC_MASK; } /** * @brief Disable the fault signal from the pin * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t */ static inline void pwmv2_disable_fault_from_pad(PWMV2_Type *pwm_x, pwm_channel_t chn) { pwm_x->PWM[chn].CFG0 &= ~PWMV2_PWM_CFG0_FAULT_EN_ASYNC_MASK; } /** * @brief Enable the fault signal from the trigmux * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t */ static inline void pwmv2_enable_fault_from_trigmux(PWMV2_Type *pwm_x, pwm_channel_t chn) { pwm_x->PWM[chn].CFG0 |= PWMV2_PWM_CFG0_FAULT_EN_SYNC_MASK; } /** * @brief Disable the fault signal from the trigmux * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t */ static inline void pwmv2_disable_fault_from_trigmux(PWMV2_Type *pwm_x, pwm_channel_t chn) { pwm_x->PWM[chn].CFG0 &= ~PWMV2_PWM_CFG0_FAULT_EN_SYNC_MASK; } /** * @brief Enable pwm output invert * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t */ static inline void pwmv2_enable_output_invert(PWMV2_Type *pwm_x, pwm_channel_t chn) { pwm_x->PWM[chn].CFG0 |= PWMV2_PWM_CFG0_OUT_POLARITY_MASK; } /** * @brief Disable pwm output invert * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t */ static inline void pwmv2_disable_output_invert(PWMV2_Type *pwm_x, pwm_channel_t chn) { pwm_x->PWM[chn].CFG0 &= ~PWMV2_PWM_CFG0_OUT_POLARITY_MASK; } /** * @brief Enable invert operations via shadow registers * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t * @param update_select @ref pwm_shadow_register_output_polarity_t */ static inline void pwmv2_enable_invert_by_shadow(PWMV2_Type *pwm_x, pwm_channel_t chn, pwm_shadow_register_output_polarity_t update_select) { pwm_x->PWM[chn].CFG0 |= PWMV2_PWM_CFG0_POLARITY_OPT0_MASK; pwm_x->PWM[chn].CFG0 = (pwm_x->PWM[chn].CFG0 & ~PWMV2_PWM_CFG0_POL_UPDATE_SEL_MASK) | PWMV2_PWM_CFG0_POL_UPDATE_SEL_SET(update_select); } /** * @brief Disable invert operations via shadow registers * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t * @param update_select @ref pwm_shadow_register_output_polarity_t */ static inline void pwmv2_disable_invert_by_shadow(PWMV2_Type *pwm_x, pwm_channel_t chn) { pwm_x->PWM[chn].CFG0 &= ~PWMV2_PWM_CFG0_POLARITY_OPT0_MASK; } /** * @brief Enable pwm output * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t */ static inline void pwmv2_channel_enable_output(PWMV2_Type *pwm_x, pwm_channel_t chn) { pwm_x->PWM[chn].CFG1 |= PWMV2_PWM_CFG1_HIGHZ_EN_N_MASK; } /** * @brief Disable pwm output * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t */ static inline void pwmv2_channel_disable_output(PWMV2_Type *pwm_x, pwm_channel_t chn) { pwm_x->PWM[chn].CFG1 &= ~PWMV2_PWM_CFG1_HIGHZ_EN_N_MASK; } /** * @brief Forces the output configuration to be updated from the time shadow hosting takes effect * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t * @param update_time @ref pwm_force_shadow_trigger_t */ static inline void pwmv2_force_update_time_by_shadow(PWMV2_Type *pwm_x, pwm_channel_t chn, pwm_force_shadow_trigger_t update_time) { pwm_x->PWM[chn].CFG1 = (pwm_x->PWM[chn].CFG1 & ~PWMV2_PWM_CFG1_FORCE_UPDATE_TIME_MASK) | PWMV2_PWM_CFG1_FORCE_UPDATE_TIME_SET(update_time); } /** * @brief set the fault mode * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t * @param mode @ref pwm_fault_mode_t */ static inline void pwmv2_set_fault_mode(PWMV2_Type *pwm_x, pwm_channel_t chn, pwm_fault_mode_t mode) { pwm_x->PWM[chn].CFG1 = (pwm_x->PWM[chn].CFG1 & ~PWMV2_PWM_CFG1_FAULT_MODE_MASK) | PWMV2_PWM_CFG1_FAULT_MODE_SET(mode); } /** * @brief Set the fault mode recovery time * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t * @param trig @ref pwm_fault_recovery_trigger_t */ static inline void pwmv2_set_fault_recovery_time(PWMV2_Type *pwm_x, pwm_channel_t chn, pwm_fault_recovery_trigger_t trig) { pwm_x->PWM[chn].CFG1 = (pwm_x->PWM[chn].CFG1 & ~PWMV2_PWM_CFG1_FAULT_REC_TIME_MASK) | PWMV2_PWM_CFG1_FAULT_REC_TIME_SET(trig); } /** * @brief Trigger forced mode by hardware signal * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t */ static inline void pwmv2_enable_force_by_hardware(PWMV2_Type *pwm_x, pwm_channel_t chn) { pwm_x->PWM[chn].CFG1 &= ~PWMV2_PWM_CFG1_SW_FORCE_EN_MASK; } /** * @brief Enable force mode triggered by software * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t */ static inline void pwmv2_enable_force_by_software(PWMV2_Type *pwm_x, pwm_channel_t chn) { pwm_x->PWM[chn].CFG1 |= PWMV2_PWM_CFG1_SW_FORCE_EN_MASK; } /** * @brief Disable force mode triggered by software * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t */ static inline void pwmv2_disable_force_by_software(PWMV2_Type *pwm_x, pwm_channel_t chn) { pwm_x->PWM[chn].CFG1 &= ~PWMV2_PWM_CFG1_SW_FORCE_EN_MASK; } /** * @brief Enable pwm complementary mode * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t */ static inline void pwmv2_enable_pair_mode(PWMV2_Type *pwm_x, pwm_channel_t chn) { pwm_x->PWM[chn].CFG1 |= PWMV2_PWM_CFG1_PAIR_MODE_MASK; } /** * @brief Disable pwm complementary mode * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t */ static inline void pwmv2_disable_pair_mode(PWMV2_Type *pwm_x, pwm_channel_t chn) { pwm_x->PWM[chn].CFG1 &= ~PWMV2_PWM_CFG1_PAIR_MODE_MASK; } /** * @brief Configure the logic between the 4 cmp, valid only if the 4 cmp output is enabled * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t * @param logic @ref pwm_logic_four_cmp_cfg_t */ static inline void pwmv2_set_four_cmp_logic(PWMV2_Type *pwm_x, pwm_channel_t chn, pwm_logic_four_cmp_cfg_t logic) { pwm_x->PWM[chn].CFG1 = (pwm_x->PWM[chn].CFG1 & ~PWMV2_PWM_CFG1_PWM_LOGIC_MASK) | PWMV2_PWM_CFG1_PWM_LOGIC_SET(logic); } /** * @brief Setting the effective time of forced output * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t * @param time @ref pwm_force_trigger_t */ static inline void pwmv2_set_force_update_time(PWMV2_Type *pwm_x, pwm_channel_t chn, pwm_force_trigger_t time) { pwm_x->PWM[chn].CFG1 = (pwm_x->PWM[chn].CFG1 & ~PWMV2_PWM_CFG1_FORCE_TIME_MASK) | PWMV2_PWM_CFG1_FORCE_TIME_SET(time); } /** * @brief Selecting trigmux's signal as a forced mode trigger source * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t * @param trigmux_index trigmux index */ static inline void pwmv2_trig_force_mode_select_trigmux_index(PWMV2_Type *pwm_x, pwm_channel_t chn, uint8_t trigmux_index) { pwm_x->PWM[chn].CFG1 = (pwm_x->PWM[chn].CFG1 & ~PWMV2_PWM_CFG1_FORCE_TRIG_SEL_MASK) | PWMV2_PWM_CFG1_FORCE_TRIG_SEL_SET(trigmux_index); } /** * @brief Selection of trigger signals for software or hardware trigmux * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t * @param trigmux_index select one trigger from 8 */ static inline void pwmv2_trig_force_hardware_or_software_select_trigmux_index(PWMV2_Type *pwm_x, pwm_channel_t chn, uint8_t trigmux_index) { pwm_x->PWM[chn].CFG1 = (pwm_x->PWM[chn].CFG1 & ~PWMV2_PWM_CFG1_FORCE_ACT_SEL_MASK) | PWMV2_PWM_CFG1_FORCE_ACT_SEL_SET(trigmux_index); } /** * @brief Select the trigger source that forces the output to take effect * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t * @param trigmux_index select one trigger from 8 */ static inline void pwmv2_select_force_trigmux_index(PWMV2_Type *pwm_x, pwm_channel_t chn, uint8_t trigmux_index) { pwm_x->PWM[chn].CFG1 = (pwm_x->PWM[chn].CFG1 & ~PWMV2_PWM_CFG1_PWM_FORCE_SEL_MASK) | PWMV2_PWM_CFG1_PWM_FORCE_SEL_SET(trigmux_index); } /** * @brief Selection of trigger signal for fault recovery * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t * @param trigmux_index select one trigger from 8 */ static inline void pwmv2_select_recovery_fault_trigmux_index(PWMV2_Type *pwm_x, pwm_channel_t chn, uint8_t trigmux_index) { pwm_x->PWM[chn].CFG1 = (pwm_x->PWM[chn].CFG1 & ~PWMV2_PWM_CFG1_FAULT_REC_SEL_MASK) | PWMV2_PWM_CFG1_FAULT_REC_SEL_SET(trigmux_index); } /** * @brief set pwm dead area * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t * @param dead dead area time */ static inline void pwmv2_set_dead_area(PWMV2_Type *pwm_x, pwm_channel_t chn, uint32_t dead) { pwm_x->PWM[chn].DEAD_AREA = PWMV2_PWM_DEAD_AREA_DEAD_AREA_SET((dead << 8)); } /** * @brief Setting the comparator as an input to trigmux * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param trigmux_chn @ref pwm_channel_t * @param cmp_index cmp index */ static inline void pwmv2_set_trigout_cmp_index(PWMV2_Type *pwm_x, pwm_channel_t trigmux_chn, uint8_t cmp_index) { pwm_x->TRIGGER_CFG[trigmux_chn] = (pwm_x->TRIGGER_CFG[trigmux_chn] & ~PWMV2_TRIGGER_CFG_TRIGGER_OUT_SEL_MASK) | PWMV2_TRIGGER_CFG_TRIGGER_OUT_SEL_SET(cmp_index); } /** * @brief Enable software forced output * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t */ static inline void pwmv2_enable_software_force(PWMV2_Type *pwm_x, pwm_channel_t chn) { pwm_x->GLB_CTRL |= PWMV2_GLB_CTRL_SW_FORCE_SET((1 << chn)); } /** * @brief Disable software forced output * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t */ static inline void pwmv2_disable_software_force(PWMV2_Type *pwm_x, pwm_channel_t chn) { pwm_x->GLB_CTRL &= ~(PWMV2_GLB_CTRL_SW_FORCE_SET((1 << chn))); } #ifdef PWM_SOC_HRPWM_SUPPORT /** * @brief Add a delay after deadband, 0-255ths of a clock cycle * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param delay_tick 0-255 */ static inline void pwmv2_add_delay_tick_after_dead_area(PWMV2_Type *pwm_x, uint8_t delay_tick) { pwm_x->GLB_CTRL = (pwm_x->GLB_CTRL & ~PWMV2_GLB_CTRL_OUTPUT_DELAY_MASK) | PWMV2_GLB_CTRL_OUTPUT_DELAY_SET(delay_tick); } /** * @brief Enable high precision pwm * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) */ static inline void pwmv2_enable_hrpwm(PWMV2_Type *pwm_x) { pwm_x->GLB_CTRL |= PWMV2_GLB_CTRL_HR_PWM_EN_MASK; } /** * @brief Disable high precision pwm * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) */ static inline void pwmv2_disable_hrpwm(PWMV2_Type *pwm_x) { pwm_x->GLB_CTRL &= ~PWMV2_GLB_CTRL_HR_PWM_EN_MASK; } #endif /** * @brief Enable the software dac mode * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param dac_index @ref pwm_dac_channel_t */ static inline void pwmv2_enable_software_dac_mode(PWMV2_Type *pwm_x, pwm_dac_channel_t dac_index) { pwm_x->GLB_CTRL2 |= PWMV2_GLB_CTRL2_DAC_SW_MODE_SET((1 << dac_index)); } /** * @brief Disable the software dac mode * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param dac_index @ref pwm_dac_channel_t */ static inline void pwmv2_disable_software_dac_mode(PWMV2_Type *pwm_x, pwm_dac_channel_t dac_index) { pwm_x->GLB_CTRL2 &= ~PWMV2_GLB_CTRL2_DAC_SW_MODE_SET((1 << dac_index)); } /** * @brief Enable debug mode * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) */ static inline void pwmv2_enable_debug_mode(PWMV2_Type *pwm_x) { pwm_x->GLB_CTRL2 |= PWMV2_GLB_CTRL2_DEBUG_IN_EN_MASK; } /** * @brief Disable debug mode * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) */ static inline void pwmv2_disable_debug_mode(PWMV2_Type *pwm_x) { pwm_x->GLB_CTRL2 &= ~PWMV2_GLB_CTRL2_DEBUG_IN_EN_MASK; } /** * @brief Clear fault event * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t */ static inline void pwmv2_clear_fault_event(PWMV2_Type *pwm_x, pwm_channel_t chn) { pwm_x->GLB_CTRL2 = (pwm_x->GLB_CTRL2 & ~(PWMV2_GLB_CTRL2_FAULT_CLEAR_MASK)) | PWMV2_GLB_CTRL2_FAULT_CLEAR_SET((1 << chn)); } /** * @brief Using the Shadow Register Function * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) */ static inline void pwmv2_enable_shadow_lock_feature(PWMV2_Type *pwm_x) { pwm_x->GLB_CTRL2 |= PWMV2_GLB_CTRL2_SHADOW_LOCK_EN_MASK; } /** * @brief Do not use the shadow register function * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) */ static inline void pwmv2_disable_shadow_lock_feature(PWMV2_Type *pwm_x) { pwm_x->GLB_CTRL2 &= ~PWMV2_GLB_CTRL2_SHADOW_LOCK_EN_MASK; } /** * @brief Get counter work status * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter_index @ref pwm_counter_t * @return uint32_t status mask */ static inline uint32_t pwmv2_get_counter_working_status(PWMV2_Type *pwm_x, pwm_counter_t counter_index) { return PWMV2_CNT_RELOAD_WORK_VALUE_GET(pwm_x->CNT_RELOAD_WORK[counter_index]); } /** * @brief Get cmp work status * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param cmp_index cmp index * @return uint32_t status mask */ static inline uint32_t pwmv2_get_cmp_working_status(PWMV2_Type *pwm_x, uint8_t cmp_index) { return PWMV2_CMP_VAL_WORK_VALUE_GET(pwm_x->CMP_VAL_WORK[cmp_index]); } /** * @brief Get force mode work status * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @return uint32_t status mask */ static inline uint32_t pwmv2_get_force_working_status(PWMV2_Type *pwm_x) { return PWMV2_FORCE_WORK_FORCE_MODE_GET(pwm_x->FORCE_WORK); } /** * @brief Get the status of the output polarity * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @return uint32_t polarity */ static inline uint32_t pwmv2_get_force_work_out_polarity_status(PWMV2_Type *pwm_x) { return PWMV2_FORCE_WORK_OUT_POLARITY_GET(pwm_x->FORCE_WORK); } /** * @brief Getting the value of a counter * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter_index @ref pwm_counter_t * @return uint32_t counter value */ static inline uint32_t pwmv2_get_counter_value(PWMV2_Type *pwm_x, pwm_counter_t counter_index) { return PWMV2_CNT_VAL_VALUE_GET(pwm_x->CNT_VAL[counter_index]); } /** * @brief set dac value * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param dac_index @ref pwm_dac_channel_t * @param value dac value */ static inline void pwmv2_set_dac_value(PWMV2_Type *pwm_x, pwm_dac_channel_t dac_index, uint32_t value) { pwm_x->DAC_VALUE_SV[dac_index] = PWMV2_DAC_VALUE_SV_VALUE_SET(value); } /** * @brief get capture posedge value * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t * @return uint32_t posedge value */ static inline uint32_t pwmv2_get_capture_posedge_value(PWMV2_Type *pwm_x, pwm_channel_t chn) { return PWMV2_CAPTURE_POS_CAPTURE_POS_GET(pwm_x->CAPTURE_POS[chn]); } /** * @brief Select the input source for the captured signal * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t * @param select @ref pwm_capture_input_select_t */ static inline void pwmv2_capture_selection_input_source(PWMV2_Type *pwm_x, pwm_channel_t chn, pwm_capture_input_select_t select) { pwm_x->CAPTURE_POS[chn] = (pwm_x->CAPTURE_POS[chn] & ~PWMV2_CAPTURE_POS_CAPTURE_SELGPIO_MASK) | PWMV2_CAPTURE_POS_CAPTURE_SELGPIO_SET(select); } /** * @brief Set the counter to be used for the capture channel * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t * @param counter_index counter index */ static inline void pwmv2_set_capture_counter_index(PWMV2_Type *pwm_x, pwm_channel_t chn, uint8_t counter_index) { pwm_x->CAPTURE_POS[chn] = (pwm_x->CAPTURE_POS[chn] & ~PWMV2_CAPTURE_POS_CNT_INDEX_MASK) | PWMV2_CAPTURE_POS_CNT_INDEX_SET(counter_index); } /** * @brief get capture negedge value * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t * @return uint32_t posedge value */ static inline uint32_t pwmv2_get_capture_negedge_value(PWMV2_Type *pwm_x, pwm_channel_t chn) { return PWMV2_CAPTURE_NEG_CAPTURE_NEG_GET(pwm_x->CAPTURE_NEG[chn]); } /** * @brief Get all interrupt status * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @return uint32_t irq status mask */ static inline uint32_t pwmv2_get_irq_status_all(PWMV2_Type *pwm_x) { return pwm_x->IRQ_STS; } /** * @brief clear calculate overflow irq status * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) */ static inline void pwmv2_clear_calculate_overflow_irq_status(PWMV2_Type *pwm_x) { pwm_x->IRQ_STS &= PWMV2_IRQ_STS_IRQ_CAL_OVERFLOW_MASK; } /** * @brief enable calculate overflow irq * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) */ static inline void pwmv2_enable_calculate_overflow_irq(PWMV2_Type *pwm_x) { pwm_x->IRQ_EN |= PWMV2_IRQ_EN_IRQ_EN_OVERFLOW_MASK; } /** * @brief Disable calculate overflow irq * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) */ static inline void pwmv2_disable_calculate_overflow_irq(PWMV2_Type *pwm_x) { pwm_x->IRQ_EN &= ~PWMV2_IRQ_EN_IRQ_EN_OVERFLOW_MASK; } /** * @brief Get cmp irq status * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @return uint32_t irq status */ static inline uint32_t pwmv2_get_cmp_irq_status(PWMV2_Type *pwm_x) { return PWMV2_IRQ_STS_CMP_IRQ_STS_CMP_GET(pwm_x->IRQ_STS_CMP); } /** * @brief Clear cmp irq status * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param mask uint32_t irq status */ static inline void pwmv2_clear_cmp_irq_status(PWMV2_Type *pwm_x, uint32_t mask) { pwm_x->IRQ_STS_CMP = PWMV2_IRQ_STS_CMP_IRQ_STS_CMP_SET(mask); } /** * @brief Get reload irq status * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @return uint32_t reload irq status */ static inline uint32_t pwmv2_get_reload_irq_status(PWMV2_Type *pwm_x) { return PWMV2_IRQ_STS_RELOAD_IRQ_STS_RELOAD_GET(pwm_x->IRQ_STS_RELOAD); } /** * @brief Clear reload irq status * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param mask irq status mask */ static inline void pwmv2_clear_reload_irq_status(PWMV2_Type *pwm_x, uint32_t mask) { pwm_x->IRQ_STS_RELOAD = PWMV2_IRQ_STS_RELOAD_IRQ_STS_RELOAD_SET(mask); } /** * @brief Get capture posedge irq status * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @return uint32_t irq status */ static inline uint32_t pwmv2_get_capture_posedge_irq_status(PWMV2_Type *pwm_x) { return PWMV2_IRQ_STS_CAP_POS_IRQ_STS_CAP_POS_GET(pwm_x->IRQ_STS_CAP_POS); } /** * @brief Clear capture posedge irq status * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param mask capture posedge irq mask */ static inline void pwmv2_clear_capture_posedge_irq_status(PWMV2_Type *pwm_x, uint32_t mask) { pwm_x->IRQ_STS_CAP_POS = PWMV2_IRQ_STS_CAP_POS_IRQ_STS_CAP_POS_SET(mask); } /** * @brief Get capture negedge irq status * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @return uint32_t irq status */ static inline uint32_t pwmv2_get_capture_negedge_irq_status(PWMV2_Type *pwm_x) { return PWMV2_IRQ_STS_CAP_NEG_IRQ_STS_CAP_NEG_GET(pwm_x->IRQ_STS_CAP_NEG); } /** * @brief Clear capture negedge irq status * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param mask capture posedge irq mask */ static inline void pwmv2_clear_capture_negedge_irq_status(PWMV2_Type *pwm_x, uint32_t mask) { pwm_x->IRQ_STS_CAP_NEG = PWMV2_IRQ_STS_CAP_NEG_IRQ_STS_CAP_NEG_SET(mask); } /** * @brief Get fault irq status * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @return uint32_t irq status */ static inline uint32_t pwmv2_get_fault_irq_status(PWMV2_Type *pwm_x) { return PWMV2_IRQ_STS_FAULT_IRQ_STS_FAULT_GET(pwm_x->IRQ_STS_FAULT); } /** * @brief Clear fault irq status * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @return uint32_t irq status */ static inline void pwmv2_clear_fault_irq_status(PWMV2_Type *pwm_x, uint32_t mask) { pwm_x->IRQ_STS_FAULT = PWMV2_IRQ_STS_FAULT_IRQ_STS_FAULT_SET(mask); } /** * @brief Get burstend irq status * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @return uint32_t irq status */ static inline uint32_t pwmv2_get_burstend_irq_status(PWMV2_Type *pwm_x) { return PWMV2_IRQ_STS_BURSTEND_IRQ_STS_BURSTEND_GET(pwm_x->IRQ_STS_BURSTEND); } /** * @brief Clear burstend irq status * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param mask mask status */ static inline void pwmv2_clear_burstend__irq_status(PWMV2_Type *pwm_x, uint32_t mask) { pwm_x->IRQ_STS_BURSTEND = PWMV2_IRQ_STS_BURSTEND_IRQ_STS_BURSTEND_SET(mask); } /** * @brief enable cmp irq * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param cmp_index cmp index */ static inline void pwmv2_enable_cmp_irq(PWMV2_Type *pwm_x, uint8_t cmp_index) { pwm_x->IRQ_EN_CMP |= PWMV2_IRQ_EN_CMP_IRQ_EN_CMP_SET(1 << cmp_index); } /** * @brief disable cmp irq * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param cmp_index cmp index */ static inline void pwmv2_disable_cmp_irq(PWMV2_Type *pwm_x, uint8_t cmp_index) { pwm_x->IRQ_EN_CMP &= ~PWMV2_IRQ_EN_CMP_IRQ_EN_CMP_SET(1 << cmp_index); } /** * @brief enable reload irq * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter_index @ref pwm_counter_t */ static inline void pwmv2_enable_reload_irq(PWMV2_Type *pwm_x, pwm_counter_t counter_index) { pwm_x->IRQ_EN_RELOAD |= PWMV2_IRQ_EN_RELOAD_IRQ_EN_RELOAD_SET(1 << counter_index); } /** * @brief disable reload irq * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter_index @ref pwm_counter_t */ static inline void pwmv2_disable_reload_irq(PWMV2_Type *pwm_x, pwm_counter_t counter_index) { pwm_x->IRQ_EN_RELOAD &= ~PWMV2_IRQ_EN_RELOAD_IRQ_EN_RELOAD_SET(1 << counter_index); } /** * @brief enable capture posedge irq * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param channel_index @ref pwm_counter_t */ static inline void pwmv2_enable_capture_posedge_irq(PWMV2_Type *pwm_x, pwm_channel_t channel_index) { pwm_x->IRQ_EN_CAP_POS |= PWMV2_IRQ_EN_CAP_POS_IRQ_EN_CAP_POS_SET(1 << channel_index); } /** * @brief disable capture posedge irq * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param channel_index @ref pwm_counter_t */ static inline void pwmv2_disable_capture_posedge_irq(PWMV2_Type *pwm_x, pwm_channel_t channel_index) { pwm_x->IRQ_EN_CAP_POS &= ~PWMV2_IRQ_EN_CAP_POS_IRQ_EN_CAP_POS_SET(1 << channel_index); } /** * @brief enable capture nedege irq * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param channel_index @ref pwm_channel_t */ static inline void pwmv2_enable_capture_nededge_irq(PWMV2_Type *pwm_x, pwm_channel_t channel_index) { pwm_x->IRQ_EN_CAP_NEG |= PWMV2_IRQ_EN_CAP_NEG_IRQ_EN_CAP_NEG_SET(1 << channel_index); } /** * @brief disable capture nedege irq * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param channel_index @ref pwm_channel_t */ static inline void pwmv2_disable_capture_nededge_irq(PWMV2_Type *pwm_x, pwm_channel_t channel_index) { pwm_x->IRQ_EN_CAP_NEG &= ~PWMV2_IRQ_EN_CAP_NEG_IRQ_EN_CAP_NEG_SET(1 << channel_index); } /** * @brief enable fault irq * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param channel_index @ref pwm_channel_t */ static inline void pwmv2_enable_fault_irq(PWMV2_Type *pwm_x, pwm_channel_t channel_index) { pwm_x->IRQ_EN_FAULT |= PWMV2_IRQ_EN_FAULT_IRQ_EN_FAULT_SET(1 << channel_index); } /** * @brief disable fault irq * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param channel_index @ref pwm_channel_t */ static inline void pwmv2_disable_fault_irq(PWMV2_Type *pwm_x, pwm_channel_t channel_index) { pwm_x->IRQ_EN_FAULT &= ~PWMV2_IRQ_EN_FAULT_IRQ_EN_FAULT_SET(1 << channel_index); } /** * @brief enable burstend irq * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter_index @ref pwm_counter_t */ static inline void pwmv2_enable_burstend_irq(PWMV2_Type *pwm_x, pwm_counter_t counter_index) { pwm_x->IRQ_EN_BURSTEND |= PWMV2_IRQ_EN_FAULT_IRQ_EN_FAULT_SET(1 << counter_index); } /** * @brief disable burstend irq * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter_index @ref pwm_counter_t */ static inline void pwmv2_disable_burstend_irq(PWMV2_Type *pwm_x, pwm_counter_t counter_index) { pwm_x->IRQ_EN_BURSTEND &= ~PWMV2_IRQ_EN_FAULT_IRQ_EN_FAULT_SET(1 << counter_index); } /** * @brief enable dma at compare point * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param dma_channel @ref pwm_dma_chn_t * @param cmp_index cmp index */ static inline void pwmv2_enable_dma_at_compare_point(PWMV2_Type *pwm_x, pwm_dma_chn_t dma_channel, uint8_t cmp_index) { pwm_x->DMA_EN = (pwm_x->DMA_EN & ~((PWMV2_DMA_EN_DMA0_SEL_MASK | PWMV2_DMA_EN_DMA0_EN_MASK) << (PWMV2_DMA_EN_DMA1_SEL_SHIFT * dma_channel))) | ((PWMV2_DMA_EN_DMA0_SEL_SET(cmp_index) | PWMV2_DMA_EN_DMA0_EN_MASK) << (PWMV2_DMA_EN_DMA1_SEL_SHIFT * dma_channel)); } /** * @brief disable dma at compare point * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param dma_channel @ref pwm_dma_chn_t */ static inline void pwmv2_disable_dma_at_compare_point(PWMV2_Type *pwm_x, pwm_dma_chn_t dma_channel) { pwm_x->DMA_EN &= ~((PWMV2_DMA_EN_DMA0_SEL_MASK | PWMV2_DMA_EN_DMA0_EN_MASK) << (PWMV2_DMA_EN_DMA1_SEL_SHIFT * dma_channel)); } /** * @brief enable dma at reload point * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param dma_channel @ref pwm_dma_chn_t * @param reload_index @ref pwm_counter_t */ static inline void pwmv2_enable_dma_at_reload_point(PWMV2_Type *pwm_x, pwm_dma_chn_t dma_channel, pwm_counter_t reload_index) { pwm_x->DMA_EN = (pwm_x->DMA_EN & ~((PWMV2_DMA_EN_DMA0_SEL_MASK | PWMV2_DMA_EN_DMA0_EN_MASK) << (PWMV2_DMA_EN_DMA1_SEL_SHIFT * dma_channel))) | ((PWMV2_DMA_EN_DMA0_SEL_SET(reload_index + 24) | PWMV2_DMA_EN_DMA0_EN_MASK) << (PWMV2_DMA_EN_DMA1_SEL_SHIFT * dma_channel)); } /** * @brief disable dma at reload point * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param dma_channel @ref pwm_dma_chn_t */ static inline void pwmv2_disable_dma_at_reload_point(PWMV2_Type *pwm_x, pwm_dma_chn_t dma_channel) { pwm_x->DMA_EN &= ~((PWMV2_DMA_EN_DMA0_SEL_MASK | PWMV2_DMA_EN_DMA0_EN_MASK) << (PWMV2_DMA_EN_DMA1_SEL_SHIFT * dma_channel)); } /** * @brief select compare point 0 index * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t * @param cmp_index cmp index */ static inline void pwmv2_reload_select_compare_point0_index(PWMV2_Type *pwm_x, pwm_counter_t counter, uint8_t cmp_index) { pwm_x->CNT[counter].CFG0 = (pwm_x->CNT[counter].CFG0 & ~(PWMV2_CNT_CFG0_RLD_CMP_SEL0_MASK)) | PWMV2_CNT_CFG0_RLD_CMP_SEL0_SET(cmp_index); } /** * @brief select compare point 1 index * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t * @param cmp_index cmp index */ static inline void pwmv2_reload_select_compare_point1_index(PWMV2_Type *pwm_x, pwm_counter_t counter, uint8_t cmp_index) { pwm_x->CNT[counter].CFG0 = (pwm_x->CNT[counter].CFG0 & ~(PWMV2_CNT_CFG0_RLD_CMP_SEL1_MASK)) | PWMV2_CNT_CFG0_RLD_CMP_SEL1_SET(cmp_index); } /** * @brief Select the input trigger source for the reload point * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t * @param trig_index trig index */ static inline void pwmv2_reload_select_input_trigger(PWMV2_Type *pwm_x, pwm_counter_t counter, uint8_t trig_index) { pwm_x->CNT[counter].CFG0 = (pwm_x->CNT[counter].CFG0 & ~(PWMV2_CNT_CFG0_RLD_TRIG_SEL_MASK)) | PWMV2_CNT_CFG0_RLD_TRIG_SEL_SET(trig_index); } /** * @brief Set reload update time * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t * @param update @ref pwm_reload_update_time_t */ static inline void pwmv2_set_reload_update_time(PWMV2_Type *pwm_x, pwm_counter_t counter, pwm_reload_update_time_t update) { pwm_x->CNT[counter].CFG0 = (pwm_x->CNT[counter].CFG0 & ~(PWMV2_CNT_CFG0_RLD_UPDATE_TIME_MASK)) | PWMV2_CNT_CFG0_RLD_UPDATE_TIME_SET(update); } /** * @brief Set dac data parameter * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t * @param dac_parameter dac parameter */ static inline void pwmv2_counter_set_dac_data_parameter(PWMV2_Type *pwm_x, pwm_counter_t counter, uint8_t dac_parameter) { pwm_x->CNT[counter].CFG0 = (pwm_x->CNT[counter].CFG0 & ~PWMV2_CNT_CFG0_CNT_D_PARAM_MASK) | PWMV2_CNT_CFG0_CNT_D_PARAM_SET(dac_parameter); } /** * @brief Select dac index * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t * @param dac_index @ref pwm_dac_channel_t */ static inline void pwmv2_conuter_select_dac_index(PWMV2_Type *pwm_x, pwm_counter_t counter, pwm_dac_channel_t dac_index) { pwm_x->CNT[counter].CFG1 = (pwm_x->CNT[counter].CFG1 & ~PWMV2_CNT_CFG1_CNT_DAC_INDEX_MASK) | PWMV2_CNT_CFG1_CNT_DAC_INDEX_SET(dac_index); } /** * @brief Enable the upper limit of the calculation unit * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t */ static inline void pwmv2_counter_up_limit_enable(PWMV2_Type *pwm_x, pwm_counter_t counter) { pwm_x->CNT[counter].CFG1 |= PWMV2_CNT_CFG1_CNT_LU_EN_MASK; } /** * @brief Disable the upper limit of the calculation unit * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t */ static inline void pwmv2_counter_up_limit_disable(PWMV2_Type *pwm_x, pwm_counter_t counter) { pwm_x->CNT[counter].CFG1 &= ~PWMV2_CNT_CFG1_CNT_LU_EN_MASK; } /** * @brief Select the upper limit from the shadow register * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t * @param index shadow index */ static inline void pwmv2_counter_select_up_limit_from_shadow_value(PWMV2_Type *pwm_x, pwm_counter_t counter, uint8_t index) { pwm_x->CNT[counter].CFG1 = (pwm_x->CNT[counter].CFG1 & ~PWMV2_CNT_CFG1_CNT_LIM_UP_MASK) | PWMV2_CNT_CFG1_CNT_LIM_UP_SET(index); } /** * @brief Enable the lower limit of the calculation unit * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t */ static inline void pwmv2_counter_low_limit_enable(PWMV2_Type *pwm_x, pwm_counter_t counter) { pwm_x->CNT[counter].CFG1 |= PWMV2_CNT_CFG1_CNT_LL_EN_MASK; } /** * @brief Disable the lower limit of the calculation unit * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t */ static inline void pwmv2_counter_low_limit_disable(PWMV2_Type *pwm_x, pwm_counter_t counter) { pwm_x->CNT[counter].CFG1 &= ~PWMV2_CNT_CFG1_CNT_LL_EN_MASK; } /** * @brief Select the lower limit from the shadow register * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t * @param index shadow index */ static inline void pwmv2_counter_select_low_limit_from_shadow_value(PWMV2_Type *pwm_x, pwm_counter_t counter, uint8_t index) { pwm_x->CNT[counter].CFG1 = (pwm_x->CNT[counter].CFG1 & ~PWMV2_CNT_CFG1_CNT_LIM_LO_MASK) | PWMV2_CNT_CFG1_CNT_LIM_LO_SET(index); } /** * @brief Select data offset from shadow register * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t * @param index shadow index */ static inline void pwmv2_counter_select_data_offset_from_shadow_value(PWMV2_Type *pwm_x, pwm_counter_t counter, uint8_t index) { pwm_x->CNT[counter].CFG1 = (pwm_x->CNT[counter].CFG1 & ~PWMV2_CNT_CFG1_CNT_IN_OFF_MASK) | PWMV2_CNT_CFG1_CNT_IN_OFF_SET(index); } /** * @brief enable counter reload by trigmux * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t */ static inline void pwmv2_counter_enable_reload_by_trig(PWMV2_Type *pwm_x, pwm_counter_t counter) { pwm_x->CNT[counter].CFG2 |= PWMV2_CNT_CFG2_CNT_RELOAD_EN_MASK; } /** * @brief disable counter reload by trigmux * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t */ static inline void pwmv2_counter_disable_reload_by_trig(PWMV2_Type *pwm_x, pwm_counter_t counter) { pwm_x->CNT[counter].CFG2 &= ~PWMV2_CNT_CFG2_CNT_RELOAD_EN_MASK; } /** * @brief Select counter update by trigmux1 * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t * @param trig_index trigmux index */ static inline void pwmv2_counter_update_trig1(PWMV2_Type *pwm_x, pwm_counter_t counter, uint8_t trig_index) { pwm_x->CNT[counter].CFG2 = (pwm_x->CNT[counter].CFG2 & ~PWMV2_CNT_CFG2_CNT_UPDATE_TRIG1_MASK) | PWMV2_CNT_CFG2_CNT_UPDATE_TRIG1_SET(trig_index); } /** * @brief Enable counter update by trigmux1 * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t */ static inline void pwmv2_counter_enable_update_trig1(PWMV2_Type *pwm_x, pwm_counter_t counter) { pwm_x->CNT[counter].CFG2 |= PWMV2_CNT_CFG2_CNT_UPDATE_EN1_MASK; } /** * @brief Disable counter update by trigmux1 * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t */ static inline void pwmv2_counter_disable_update_trig1(PWMV2_Type *pwm_x, pwm_counter_t counter) { pwm_x->CNT[counter].CFG2 &= ~PWMV2_CNT_CFG2_CNT_UPDATE_EN1_MASK; } /** * @brief Enable change counter value to one of the calculation cell output when cnt_update_triger1 issued * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t * @param cal_index cal index */ static inline void pwmv2_counter_set_trig1_calculate_cell_index(PWMV2_Type *pwm_x, pwm_counter_t counter, uint8_t cal_index) { pwm_x->CNT[counter].CFG2 = (pwm_x->CNT[counter].CFG2 & ~PWMV2_CNT_CFG2_CNT_TRIG1_MASK) | PWMV2_CNT_CFG2_CNT_TRIG1_SET(cal_index); } /** * @brief Select counter update by trigmux0 * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t * @param trig_index trigmux index */ static inline void pwmv2_counter_update_trig0(PWMV2_Type *pwm_x, pwm_counter_t counter, uint8_t trig_index) { pwm_x->CNT[counter].CFG2 = (pwm_x->CNT[counter].CFG2 & ~PWMV2_CNT_CFG2_CNT_UPDATE_TRIG0_MASK) | PWMV2_CNT_CFG2_CNT_UPDATE_TRIG0_SET(trig_index); } /** * @brief Enable counter update by trigmux0 * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t */ static inline void pwmv2_counter_enable_update_trig0(PWMV2_Type *pwm_x, pwm_counter_t counter) { pwm_x->CNT[counter].CFG2 |= PWMV2_CNT_CFG2_CNT_UPDATE_EN0_MASK; } /** * @brief Disable counter update by trigmux0 * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t */ static inline void pwmv2_counter_disable_update_trig0(PWMV2_Type *pwm_x, pwm_counter_t counter) { pwm_x->CNT[counter].CFG2 &= ~PWMV2_CNT_CFG2_CNT_UPDATE_EN0_MASK; } /** * @brief Enable change counter value to one of the calculation cell output when cnt_update_triger0 issued * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t * @param cal_index cal index */ static inline void pwmv2_counter_set_trig0_calculate_cell_index(PWMV2_Type *pwm_x, pwm_counter_t counter, uint8_t cal_index) { pwm_x->CNT[counter].CFG2 = (pwm_x->CNT[counter].CFG2 & ~PWMV2_CNT_CFG2_CNT_TRIG0_MASK) | PWMV2_CNT_CFG2_CNT_TRIG0_SET(cal_index); } /** * @brief Set trigmux index to start counter * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t * @param trig_index trig index */ static inline void pwmv2_counter_start_select_trigger_index(PWMV2_Type *pwm_x, pwm_counter_t counter, uint8_t trig_index) { pwm_x->CNT[counter].CFG3 = (pwm_x->CNT[counter].CFG3 & ~PWMV2_CNT_CFG3_CNT_START_SEL_MASK) | PWMV2_CNT_CFG3_CNT_START_SEL_SET(trig_index); } /** * @brief Enable trigmux to trigger counter initiation * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t */ static inline void pwmv2_counter_start_trigger_enable(PWMV2_Type *pwm_x, pwm_counter_t counter) { pwm_x->CNT[counter].CFG3 |= PWMV2_CNT_CFG3_CNT_HW_START_EN_MASK; } /** * @brief Disable trigmux to trigger counter initiation * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t */ static inline void pwmv2_counter_start_trigger_disable(PWMV2_Type *pwm_x, pwm_counter_t counter) { pwm_x->CNT[counter].CFG3 &= ~PWMV2_CNT_CFG3_CNT_HW_START_EN_MASK; } /** * @brief Set counter burst value * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t * @param burst burst value */ static inline void pwmv2_set_counter_burst(PWMV2_Type *pwm_x, pwm_counter_t counter, uint16_t burst) { pwm_x->CNT[counter].CFG3 |= PWMV2_CNT_CFG3_CNT_BURST_SET(burst); } /** * @brief Disable counter burst function * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t */ static inline void pwmv2_counter_burst_disable(PWMV2_Type *pwm_x, pwm_counter_t counter) { pwm_x->CNT[counter].CFG3 |= PWMV2_CNT_CFG3_CNT_BURST_MASK; } /** * @brief start pwm output * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t */ static inline void pwmv2_start_pwm_output(PWMV2_Type *pwm_x, pwm_counter_t counter) { pwm_x->CNT_GLBCFG |= PWMV2_CNT_GLBCFG_CNT_SW_START_SET((1 << counter)); } /** * @brief Reset pwm counter * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t */ static inline void pwmv2_reset_counter(PWMV2_Type *pwm_x, pwm_counter_t counter) { pwm_x->CNT_GLBCFG |= PWMV2_CNT_GLBCFG_TIMER_RESET_SET((1 << counter)); } /** * @brief Enable pwm counter * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t */ static inline void pwmv2_enable_counter(PWMV2_Type *pwm_x, pwm_counter_t counter) { pwm_x->CNT_GLBCFG |= PWMV2_CNT_GLBCFG_TIMER_ENABLE_SET((1 << counter)); } /** * @brief Disable pwm counter * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param counter @ref pwm_counter_t */ static inline void pwmv2_disable_counter(PWMV2_Type *pwm_x, pwm_counter_t counter) { pwm_x->CNT_GLBCFG &= ~PWMV2_CNT_GLBCFG_TIMER_ENABLE_SET((1 << counter)); } /** * @brief Set calculate up limit parameter * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param cal_index calculate index * @param value parameter */ static inline void pwmv2_calculate_set_up_limit_parameter(PWMV2_Type *pwm_x, uint8_t cal_index, uint8_t value) { pwm_x->CAL[cal_index].CFG0 = (pwm_x->CAL[cal_index].CFG0 & ~PWMV2_CAL_CFG0_CAL_LU_PARAM_MASK) | PWMV2_CAL_CFG0_CAL_LU_PARAM_SET(value); } /** * @brief Set calculate low limit parameter * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param cal_index calculate index * @param value parameter */ static inline void pwmv2_calculate_set_low_limit_parameter(PWMV2_Type *pwm_x, uint8_t cal_index, uint8_t value) { pwm_x->CAL[cal_index].CFG0 = (pwm_x->CAL[cal_index].CFG0 & ~PWMV2_CAL_CFG0_CAL_LL_PARAM_MASK) | PWMV2_CAL_CFG0_CAL_LL_PARAM_SET(value); } /** * @brief Set calculate period parameter * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param cal_index calculate index * @param value parameter */ static inline void pwmv2_calculate_set_period_parameter(PWMV2_Type *pwm_x, uint8_t cal_index, uint8_t value) { pwm_x->CAL[cal_index].CFG0 = (pwm_x->CAL[cal_index].CFG0 & ~PWMV2_CAL_CFG0_CAL_T_PARAM_MASK) | PWMV2_CAL_CFG0_CAL_T_PARAM_SET(value); } /** * @brief Set calculate dac value parameter * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param cal_index calculate index * @param value parameter */ static inline void pwmv2_calculate_set_dac_value_parameter(PWMV2_Type *pwm_x, uint8_t cal_index, uint8_t value) { pwm_x->CAL[cal_index].CFG0 = (pwm_x->CAL[cal_index].CFG0 & ~PWMV2_CAL_CFG0_CAL_D_PARAM_MASK) | PWMV2_CAL_CFG0_CAL_D_PARAM_SET(value); } /** * @brief Select calculate index to counter * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param cal_index calculate index * @param counter_calculate counter index */ static inline void pwmv2_calculate_select_counter_calculate_index(PWMV2_Type *pwm_x, uint8_t cal_index, uint8_t counter_calculate) { pwm_x->CAL[cal_index].CFG1 = (pwm_x->CAL[cal_index].CFG1 & ~PWMV2_CAL_CFG1_CAL_T_INDEX_MASK) | PWMV2_CAL_CFG1_CAL_T_INDEX_SET(counter_calculate); } /** * @brief Select calculate input value * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param cal_index calculate index * @param index shadow index */ static inline void pwmv2_calculate_select_in_value(PWMV2_Type *pwm_x, uint8_t cal_index, uint8_t index) { pwm_x->CAL[cal_index].CFG1 = (pwm_x->CAL[cal_index].CFG1 & ~PWMV2_CAL_CFG1_CAL_IN_INDEX_MASK) | PWMV2_CAL_CFG1_CAL_IN_INDEX_SET(index); } /** * @brief enable calculate up limit * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param cal_index calculate index */ static inline void pwmv2_calculate_enable_up_limit(PWMV2_Type *pwm_x, uint8_t cal_index) { pwm_x->CAL[cal_index].CFG1 |= PWMV2_CAL_CFG1_CAL_LU_EN_MASK; } /** * @brief disable calculate up limit * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param cal_index calculate index */ static inline void pwmv2_calculate_disable_up_limit(PWMV2_Type *pwm_x, uint8_t cal_index) { pwm_x->CAL[cal_index].CFG1 &= ~PWMV2_CAL_CFG1_CAL_LU_EN_MASK; } /** * @brief Select up limit offset from shadow index * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param cal_index calculate index * @param shadow_index shadow index */ static inline void pwmv2_calculate_select_up_limit_offset(PWMV2_Type *pwm_x, uint8_t cal_index, uint8_t shadow_index) { pwm_x->CAL[cal_index].CFG1 = (pwm_x->CAL[cal_index].CFG1 & ~PWMV2_CAL_CFG1_CAL_LIM_UP_MASK) | PWMV2_CAL_CFG1_CAL_LIM_UP_SET(shadow_index); } /** * @brief Select low limit offset from shadow index * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param cal_index calculate index * @param shadow_index shadow index */ static inline void pwmv2_calculate_select_low_limit_offset(PWMV2_Type *pwm_x, uint8_t cal_index, uint8_t shadow_index) { pwm_x->CAL[cal_index].CFG1 = (pwm_x->CAL[cal_index].CFG1 & ~PWMV2_CAL_CFG1_CAL_LIM_LO_MASK) | PWMV2_CAL_CFG1_CAL_LIM_LO_SET(shadow_index); } /** * @brief Select offset from shadow index * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param cal_index calculate index * @param shadow_index shadow index */ static inline void pwmv2_calculate_select_in_offset(PWMV2_Type *pwm_x, uint8_t cal_index, uint8_t shadow_index) { pwm_x->CAL[cal_index].CFG1 = (pwm_x->CAL[cal_index].CFG1 & ~PWMV2_CAL_CFG1_CAL_IN_OFF_MASK) | PWMV2_CAL_CFG1_CAL_IN_OFF_SET(shadow_index); } /** * @brief enable low limit * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param cal_index calculate index */ static inline void pwmv2_calculate_enable_low_limit(PWMV2_Type *pwm_x, uint8_t cal_index) { pwm_x->CAL[cal_index].CFG1 |= PWMV2_CAL_CFG1_CAL_LL_EN_MASK; } /** * @brief disable low limit * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param cal_index calculate index */ static inline void pwmv2_calculate_disable_low_limit(PWMV2_Type *pwm_x, uint8_t cal_index) { pwm_x->CAL[cal_index].CFG1 &= ~PWMV2_CAL_CFG1_CAL_LL_EN_MASK; } /** * @brief Select cmp trigmux index * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param cmp_index cmp index * @param trig_index trigmux index */ static inline void pwmv2_select_cmp_trigmux(PWMV2_Type *pwm_x, uint8_t cmp_index, uint8_t trig_index) { pwm_x->CMP[cmp_index].CFG = (pwm_x->CMP[cmp_index].CFG & ~PWMV2_CMP_CFG_CMP_TRIG_SEL_MASK) | PWMV2_CMP_CFG_CMP_TRIG_SEL_SET(trig_index); } /** * @brief Select cmp update trigmux time * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param cmp_index cmp index * @param trig_time @ref pwm_cmp_shadow_register_update_trigger_t */ static inline void pwmv2_cmp_update_trig_time(PWMV2_Type *pwm_x, uint8_t cmp_index, pwm_cmp_shadow_register_update_trigger_t trig_time) { pwm_x->CMP[cmp_index].CFG = (pwm_x->CMP[cmp_index].CFG & ~PWMV2_CMP_CFG_CMP_UPDATE_TIME_MASK) | PWMV2_CMP_CFG_CMP_UPDATE_TIME_SET(trig_time); } /** * @brief Select cmp source * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param cmp_index cmp index * @param cmp_sel @ref pwm_cmp_source_t * @param index source index */ static inline void pwmv2_select_cmp_source(PWMV2_Type *pwm_x, uint8_t cmp_index, pwm_cmp_source_t cmp_sel, uint8_t index) { pwm_x->CMP[cmp_index].CFG = (pwm_x->CMP[cmp_index].CFG & ~PWMV2_CMP_CFG_CMP_IN_SEL_MASK) | PWMV2_CMP_CFG_CMP_IN_SEL_SET((cmp_sel + index)); } /** * @brief Select cmp use counter * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param cmp_index cmp index * @param counter_index @ref pwm_counter_t */ static inline void pwmv2_cmp_select_counter(PWMV2_Type *pwm_x, uint8_t cmp_index, pwm_counter_t counter_index) { if (cmp_index >= 16) { pwm_x->CMP[cmp_index].CFG = (pwm_x->CMP[cmp_index].CFG & ~PWMV2_CMP_CFG_CMP_CNT_MASK) | PWMV2_CMP_CFG_CMP_CNT_SET((counter_index)); } } /** * @brief config pwm cmp * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param index cmp index * @param config @ref pwmv2_cmp_config_t */ void pwmv2_config_cmp(PWMV2_Type *pwm_x, uint8_t index, pwmv2_cmp_config_t *config); /** * @brief config async fault source * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param index cmp index * @param config @ref pwmv2_async_fault_source_config_t */ void pwmv2_config_async_fault_source(PWMV2_Type *pwm_x, pwm_channel_t index, pwmv2_async_fault_source_config_t *config); /** * @brief config pwm * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param index @ref pwm_channel_t * @param config @ref pwmv2_config_t * @param enable_pair_mode bool */ void pwmv2_config_pwm(PWMV2_Type *pwm_x, pwm_channel_t index, pwmv2_config_t *config, bool enable_pair_mode); /** * @brief Set pwm waveform * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t * @param pwm_config @ref pwmv2_config_t * @param cmp_start_index cmp start index * @param cmp @ref pwmv2_cmp_config_t * @param cmp_num cmp number * @return hpm_stat_t @ref hpm_stat_t */ hpm_stat_t pwmv2_setup_waveform(PWMV2_Type *pwm_x, pwm_channel_t chn, pwmv2_config_t *pwm_config, uint8_t cmp_start_index, pwmv2_cmp_config_t *cmp, uint8_t cmp_num); /** * @brief set the pwm waveform complementary mode * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param chn @ref pwm_channel_t * @param pwm_pair_config @ref pwmv2_pair_config_t * @param cmp_start_index cmp start index * @param cmp @ref pwmv2_cmp_config_t * @param cmp_num cmp number * @return hpm_stat_t @ref hpm_stat_t */ hpm_stat_t pwmv2_setup_waveform_in_pair(PWMV2_Type *pwm_x, pwm_channel_t chn, pwmv2_pair_config_t *pwm_pair_config, uint8_t cmp_start_index, pwmv2_cmp_config_t *cmp, uint8_t cmp_num); /** * @brief Configure the cmp calculate unit * * @param pwm_x PWM base address, HPM_PWMx(x=0..n) * @param cal_index calculate index * @param cal @ref pwmv2_cmp_calculate_cfg_t */ void pwmv2_setup_cmp_calculate(PWMV2_Type *pwm_x, uint8_t cal_index, pwmv2_cmp_calculate_cfg_t *cal); #ifdef __cplusplus } #endif /** * @} */ #endif /* HPM_PWMV2_DRV_H */