/** * Copyright (c) 2015 - 2019, Nordic Semiconductor ASA * * All rights reserved. * * Redistribution and use in source and binary forms, with or without modification, * are permitted provided that the following conditions are met: * * 1. Redistributions of source code must retain the above copyright notice, this * list of conditions and the following disclaimer. * * 2. Redistributions in binary form, except as embedded into a Nordic * Semiconductor ASA integrated circuit in a product or a software update for * such product, must reproduce the above copyright notice, this list of * conditions and the following disclaimer in the documentation and/or other * materials provided with the distribution. * * 3. Neither the name of Nordic Semiconductor ASA nor the names of its * contributors may be used to endorse or promote products derived from this * software without specific prior written permission. * * 4. This software, with or without modification, must only be used with a * Nordic Semiconductor ASA integrated circuit. * * 5. Any software provided in binary form under this license must not be reverse * engineered, decompiled, modified and/or disassembled. * * THIS SOFTWARE IS PROVIDED BY NORDIC SEMICONDUCTOR ASA "AS IS" AND ANY EXPRESS * OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES * OF MERCHANTABILITY, NONINFRINGEMENT, AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL NORDIC SEMICONDUCTOR ASA OR CONTRIBUTORS BE * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE * GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * */ #ifndef NRFX_PWM_H__ #define NRFX_PWM_H__ #include #include #ifdef __cplusplus extern "C" { #endif /** * @defgroup nrfx_pwm PWM driver * @{ * @ingroup nrf_pwm * @brief Pulse Width Modulation (PWM) peripheral driver. */ /** * @brief PWM driver instance data structure. */ typedef struct { NRF_PWM_Type * p_registers; ///< Pointer to the structure with PWM peripheral instance registers. uint8_t drv_inst_idx; ///< Driver instance index. } nrfx_pwm_t; /** * @brief Macro for creating a PWM driver instance. */ #define NRFX_PWM_INSTANCE(id) \ { \ .p_registers = NRFX_CONCAT_2(NRF_PWM, id), \ .drv_inst_idx = NRFX_CONCAT_3(NRFX_PWM, id, _INST_IDX), \ } enum { #if NRFX_CHECK(NRFX_PWM0_ENABLED) NRFX_PWM0_INST_IDX, #endif #if NRFX_CHECK(NRFX_PWM1_ENABLED) NRFX_PWM1_INST_IDX, #endif #if NRFX_CHECK(NRFX_PWM2_ENABLED) NRFX_PWM2_INST_IDX, #endif #if NRFX_CHECK(NRFX_PWM3_ENABLED) NRFX_PWM3_INST_IDX, #endif NRFX_PWM_ENABLED_COUNT }; /** * @brief This value can be provided instead of a pin number for any channel * to specify that its output is not used and therefore does not need * to be connected to a pin. */ #define NRFX_PWM_PIN_NOT_USED 0xFF /** * @brief This value can be added to a pin number to inverse its polarity * (set idle state = 1). */ #define NRFX_PWM_PIN_INVERTED 0x80 /** * @brief PWM driver configuration structure. */ typedef struct { uint8_t output_pins[NRF_PWM_CHANNEL_COUNT]; ///< Pin numbers for individual output channels (optional). /**< Use @ref NRFX_PWM_PIN_NOT_USED * if a given output channel is not needed. */ uint8_t irq_priority; ///< Interrupt priority. nrf_pwm_clk_t base_clock; ///< Base clock frequency. nrf_pwm_mode_t count_mode; ///< Operating mode of the pulse generator counter. uint16_t top_value; ///< Value up to which the pulse generator counter counts. nrf_pwm_dec_load_t load_mode; ///< Mode of loading sequence data from RAM. nrf_pwm_dec_step_t step_mode; ///< Mode of advancing the active sequence. } nrfx_pwm_config_t; /** * @brief PWM driver default configuration. */ #define NRFX_PWM_DEFAULT_CONFIG \ { \ .output_pins = { NRFX_PWM_DEFAULT_CONFIG_OUT0_PIN, \ NRFX_PWM_DEFAULT_CONFIG_OUT1_PIN, \ NRFX_PWM_DEFAULT_CONFIG_OUT2_PIN, \ NRFX_PWM_DEFAULT_CONFIG_OUT3_PIN }, \ .irq_priority = NRFX_PWM_DEFAULT_CONFIG_IRQ_PRIORITY, \ .base_clock = (nrf_pwm_clk_t)NRFX_PWM_DEFAULT_CONFIG_BASE_CLOCK, \ .count_mode = (nrf_pwm_mode_t)NRFX_PWM_DEFAULT_CONFIG_COUNT_MODE, \ .top_value = NRFX_PWM_DEFAULT_CONFIG_TOP_VALUE, \ .load_mode = (nrf_pwm_dec_load_t)NRFX_PWM_DEFAULT_CONFIG_LOAD_MODE, \ .step_mode = (nrf_pwm_dec_step_t)NRFX_PWM_DEFAULT_CONFIG_STEP_MODE, \ } /** * @brief PWM flags providing additional playback options. */ typedef enum { NRFX_PWM_FLAG_STOP = 0x01, /**< When the requested playback is finished, the peripheral should be stopped. @note The STOP task is triggered when the last value of the final sequence is loaded from RAM, and the peripheral stops at the end of the current PWM period. For sequences with configured repeating of duty cycle values, this might result in less than the requested number of repeats of the last value. */ NRFX_PWM_FLAG_LOOP = 0x02, /**< When the requested playback is finished, it should be started from the beginning. This flag is ignored if used together with @ref NRFX_PWM_FLAG_STOP. @note The playback restart is done via a shortcut configured in the PWM peripheral. This shortcut triggers the proper starting task when the final value of previous playback is read from RAM and applied to the pulse generator counter. When this mechanism is used together with the @ref NRF_PWM_STEP_TRIGGERED mode, the playback restart will occur right after switching to the final value (this final value will be played only once). */ NRFX_PWM_FLAG_SIGNAL_END_SEQ0 = 0x04, /**< The event handler should be called when the last value from sequence 0 is loaded. */ NRFX_PWM_FLAG_SIGNAL_END_SEQ1 = 0x08, /**< The event handler should be called when the last value from sequence 1 is loaded. */ NRFX_PWM_FLAG_NO_EVT_FINISHED = 0x10, /**< The playback finished event (enabled by default) should be suppressed. */ NRFX_PWM_FLAG_START_VIA_TASK = 0x80, /**< The playback should not be started directly by the called function. Instead, the function should only prepare it and return the address of the task to be triggered to start the playback. */ } nrfx_pwm_flag_t; /** * @brief PWM driver event type. */ typedef enum { NRFX_PWM_EVT_FINISHED, ///< Sequence playback finished. NRFX_PWM_EVT_END_SEQ0, /**< End of sequence 0 reached. Its data can be safely modified now. */ NRFX_PWM_EVT_END_SEQ1, /**< End of sequence 1 reached. Its data can be safely modified now. */ NRFX_PWM_EVT_STOPPED, ///< The PWM peripheral has been stopped. } nrfx_pwm_evt_type_t; /** * @brief PWM driver event handler type. */ typedef void (* nrfx_pwm_handler_t)(nrfx_pwm_evt_type_t event_type); /** * @brief Function for initializing the PWM driver. * * @param[in] p_instance Pointer to the driver instance structure. * @param[in] p_config Pointer to the structure with initial configuration. * * @param[in] handler Event handler provided by the user. If NULL is passed * instead, event notifications are not done and PWM * interrupts are disabled. * * @retval NRFX_SUCCESS If initialization was successful. * @retval NRFX_ERROR_INVALID_STATE If the driver was already initialized. */ nrfx_err_t nrfx_pwm_init(nrfx_pwm_t const * const p_instance, nrfx_pwm_config_t const * p_config, nrfx_pwm_handler_t handler); /** * @brief Function for uninitializing the PWM driver. * * If any sequence playback is in progress, it is stopped immediately. * * @param[in] p_instance Pointer to the driver instance structure. */ void nrfx_pwm_uninit(nrfx_pwm_t const * const p_instance); /** * @brief Function for starting a single sequence playback. * * To take advantage of the looping mechanism in the PWM peripheral, both * sequences must be used (single sequence can be played back only once by * the peripheral). Therefore, the provided sequence is internally set and * played back as both sequence 0 and sequence 1. Consequently, if end of * sequence notifications are required, events for both sequences should be * used (that means that both the @ref NRFX_PWM_FLAG_SIGNAL_END_SEQ0 flag * and the @ref NRFX_PWM_FLAG_SIGNAL_END_SEQ1 flag should be specified and * the @ref NRFX_PWM_EVT_END_SEQ0 event and the @ref NRFX_PWM_EVT_END_SEQ1 * event should be handled in the same way). * * Use the @ref NRFX_PWM_FLAG_START_VIA_TASK flag if you want the playback * to be only prepared by this function, and you want to start it later by * triggering a task (using PPI for instance). The function will then return * the address of the task to be triggered. * * @note The array containing the duty cycle values for the specified sequence * must be in RAM and cannot be allocated on stack. * For detailed information, see @ref nrf_pwm_sequence_t. * * @param[in] p_instance Pointer to the driver instance structure. * @param[in] p_sequence Sequence to be played back. * @param[in] playback_count Number of playbacks to be performed (must not be 0). * @param[in] flags Additional options. Pass any combination of * @ref nrfx_pwm_flag_t "playback flags", or 0 * for default settings. * * @return Address of the task to be triggered to start the playback if the @ref * NRFX_PWM_FLAG_START_VIA_TASK flag was used, 0 otherwise. */ uint32_t nrfx_pwm_simple_playback(nrfx_pwm_t const * const p_instance, nrf_pwm_sequence_t const * p_sequence, uint16_t playback_count, uint32_t flags); /** * @brief Function for starting a two-sequence playback. * * Use the @ref NRFX_PWM_FLAG_START_VIA_TASK flag if you want the playback * to be only prepared by this function, and you want to start it later by * triggering a task (using PPI for instance). The function will then return * the address of the task to be triggered. * * @note The array containing the duty cycle values for the specified sequence * must be in RAM and cannot be allocated on stack. * For detailed information, see @ref nrf_pwm_sequence_t. * * @param[in] p_instance Pointer to the driver instance structure. * @param[in] p_sequence_0 First sequence to be played back. * @param[in] p_sequence_1 Second sequence to be played back. * @param[in] playback_count Number of playbacks to be performed (must not be 0). * @param[in] flags Additional options. Pass any combination of * @ref nrfx_pwm_flag_t "playback flags", or 0 * for default settings. * * @return Address of the task to be triggered to start the playback if the @ref * NRFX_PWM_FLAG_START_VIA_TASK flag was used, 0 otherwise. */ uint32_t nrfx_pwm_complex_playback(nrfx_pwm_t const * const p_instance, nrf_pwm_sequence_t const * p_sequence_0, nrf_pwm_sequence_t const * p_sequence_1, uint16_t playback_count, uint32_t flags); /** * @brief Function for advancing the active sequence. * * This function only applies to @ref NRF_PWM_STEP_TRIGGERED mode. * * @param[in] p_instance Pointer to the driver instance structure. */ __STATIC_INLINE void nrfx_pwm_step(nrfx_pwm_t const * const p_instance); /** * @brief Function for stopping the sequence playback. * * The playback is stopped at the end of the current PWM period. * This means that if the active sequence is configured to repeat each duty * cycle value for a certain number of PWM periods, the last played value * might appear on the output less times than requested. * * @note This function can be instructed to wait until the playback is stopped * (by setting @p wait_until_stopped to true). Note that, depending on * the length of the PMW period, this might take a significant amount of * time. Alternatively, the @ref nrfx_pwm_is_stopped function can be * used to poll the status, or the @ref NRFX_PWM_EVT_STOPPED event can * be used to get the notification when the playback is stopped, provided * the event handler is defined. * * @param[in] p_instance Pointer to the driver instance structure. * @param[in] wait_until_stopped If true, the function will not return until * the playback is stopped. * * @retval true If the PWM peripheral is stopped. * @retval false If the PWM peripheral is not stopped. */ bool nrfx_pwm_stop(nrfx_pwm_t const * const p_instance, bool wait_until_stopped); /** * @brief Function for checking the status of the PWM peripheral. * * @param[in] p_instance Pointer to the driver instance structure. * * @retval true If the PWM peripheral is stopped. * @retval false If the PWM peripheral is not stopped. */ bool nrfx_pwm_is_stopped(nrfx_pwm_t const * const p_instance); /** * @brief Function for updating the sequence data during playback. * * @param[in] p_instance Pointer to the driver instance structure. * @param[in] seq_id Identifier of the sequence (0 or 1). * @param[in] p_sequence Pointer to the new sequence definition. */ __STATIC_INLINE void nrfx_pwm_sequence_update( nrfx_pwm_t const * const p_instance, uint8_t seq_id, nrf_pwm_sequence_t const * p_sequence); /** * @brief Function for updating the pointer to the duty cycle values * in the specified sequence during playback. * * @param[in] p_instance Pointer to the driver instance structure. * @param[in] seq_id Identifier of the sequence (0 or 1). * @param[in] values New pointer to the duty cycle values. */ __STATIC_INLINE void nrfx_pwm_sequence_values_update(nrfx_pwm_t const * const p_instance, uint8_t seq_id, nrf_pwm_values_t values); /** * @brief Function for updating the number of duty cycle values * in the specified sequence during playback. * * @param[in] p_instance Pointer to the driver instance structure. * @param[in] seq_id Identifier of the sequence (0 or 1). * @param[in] length New number of the duty cycle values. */ __STATIC_INLINE void nrfx_pwm_sequence_length_update(nrfx_pwm_t const * const p_instance, uint8_t seq_id, uint16_t length); /** * @brief Function for updating the number of repeats for duty cycle values * in specified sequence during playback. * * @param[in] p_instance Pointer to the driver instance structure. * @param[in] seq_id Identifier of the sequence (0 or 1). * @param[in] repeats New number of repeats. */ __STATIC_INLINE void nrfx_pwm_sequence_repeats_update(nrfx_pwm_t const * const p_instance, uint8_t seq_id, uint32_t repeats); /** * @brief Function for updating the additional delay after the specified * sequence during playback. * * @param[in] p_instance Pointer to the driver instance structure. * @param[in] seq_id Identifier of the sequence (0 or 1). * @param[in] end_delay New end delay value (in PWM periods). */ __STATIC_INLINE void nrfx_pwm_sequence_end_delay_update(nrfx_pwm_t const * const p_instance, uint8_t seq_id, uint32_t end_delay); /** * @brief Function for returning the address of a specified PWM task that can * be used in PPI module. * * @param[in] p_instance Pointer to the driver instance structure. * @param[in] task Requested task. * * @return Task address. */ __STATIC_INLINE uint32_t nrfx_pwm_task_address_get(nrfx_pwm_t const * const p_instance, nrf_pwm_task_t task); /**@brief Function for returning the address of a specified PWM event that can * be used in PPI module. * * @param[in] p_instance Pointer to the driver instance structure. * @param[in] event Requested event. * * @return Event address. */ __STATIC_INLINE uint32_t nrfx_pwm_event_address_get(nrfx_pwm_t const * const p_instance, nrf_pwm_event_t event); #ifndef SUPPRESS_INLINE_IMPLEMENTATION __STATIC_INLINE void nrfx_pwm_step(nrfx_pwm_t const * const p_instance) { nrf_pwm_task_trigger(p_instance->p_registers, NRF_PWM_TASK_NEXTSTEP); } __STATIC_INLINE void nrfx_pwm_sequence_update(nrfx_pwm_t const * const p_instance, uint8_t seq_id, nrf_pwm_sequence_t const * p_sequence) { nrf_pwm_sequence_set(p_instance->p_registers, seq_id, p_sequence); } __STATIC_INLINE void nrfx_pwm_sequence_values_update(nrfx_pwm_t const * const p_instance, uint8_t seq_id, nrf_pwm_values_t values) { nrf_pwm_seq_ptr_set(p_instance->p_registers, seq_id, values.p_raw); } __STATIC_INLINE void nrfx_pwm_sequence_length_update(nrfx_pwm_t const * const p_instance, uint8_t seq_id, uint16_t length) { nrf_pwm_seq_cnt_set(p_instance->p_registers, seq_id, length); } __STATIC_INLINE void nrfx_pwm_sequence_repeats_update(nrfx_pwm_t const * const p_instance, uint8_t seq_id, uint32_t repeats) { nrf_pwm_seq_refresh_set(p_instance->p_registers, seq_id, repeats); } __STATIC_INLINE void nrfx_pwm_sequence_end_delay_update(nrfx_pwm_t const * const p_instance, uint8_t seq_id, uint32_t end_delay) { nrf_pwm_seq_end_delay_set(p_instance->p_registers, seq_id, end_delay); } __STATIC_INLINE uint32_t nrfx_pwm_task_address_get(nrfx_pwm_t const * const p_instance, nrf_pwm_task_t task) { return nrf_pwm_task_address_get(p_instance->p_registers, task); } __STATIC_INLINE uint32_t nrfx_pwm_event_address_get(nrfx_pwm_t const * const p_instance, nrf_pwm_event_t event) { return nrf_pwm_event_address_get(p_instance->p_registers, event); } #endif // SUPPRESS_INLINE_IMPLEMENTATION void nrfx_pwm_0_irq_handler(void); void nrfx_pwm_1_irq_handler(void); void nrfx_pwm_2_irq_handler(void); void nrfx_pwm_3_irq_handler(void); /** @} */ #ifdef __cplusplus } #endif #endif // NRFX_PWM_H__