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VesiScan-Basic-firmware-test/modules/nrfx/drivers/src/nrfx_pwm.c
Charles Kwon 72f5eb3cd9 Initial commit: MT firmware project 
- BLE peripheral applications
- dr_piezo and bladder_patch projects

Co-Authored-By: Claude Opus 4.5 <noreply@anthropic.com>
2026-01-25 17:26:39 +09:00

524 lines
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/**
* Copyright (c) 2015 - 2021, 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.
*
*/
#include <nrfx.h>
#if NRFX_CHECK(NRFX_PWM_ENABLED)
#if !(NRFX_CHECK(NRFX_PWM0_ENABLED) || NRFX_CHECK(NRFX_PWM1_ENABLED) || \
NRFX_CHECK(NRFX_PWM2_ENABLED) || NRFX_CHECK(NRFX_PWM3_ENABLED))
#error "No enabled PWM instances. Check <nrfx_config.h>."
#endif
#include <nrfx_pwm.h>
#include <hal/nrf_gpio.h>
#define NRFX_LOG_MODULE PWM
#include <nrfx_log.h>
#if NRFX_CHECK(NRFX_PWM_NRF52_ANOMALY_109_WORKAROUND_ENABLED)
// The workaround uses interrupts to wake up the CPU and ensure it is active
// when PWM is about to start a DMA transfer. For initial transfer, done when
// a playback is started via PPI, a specific EGU instance is used to generate
// an interrupt. During the playback, the PWM interrupt triggered on SEQEND
// event of a preceding sequence is used to protect the transfer done for
// the next sequence to be played.
#include <hal/nrf_egu.h>
#define USE_DMA_ISSUE_WORKAROUND
#endif
#if defined(USE_DMA_ISSUE_WORKAROUND)
#define EGU_IRQn(i) EGU_IRQn_(i)
#define EGU_IRQn_(i) SWI##i##_EGU##i##_IRQn
#define EGU_IRQHandler(i) EGU_IRQHandler_(i)
#define EGU_IRQHandler_(i) nrfx_swi_##i##_irq_handler
#define DMA_ISSUE_EGU_IDX NRFX_PWM_NRF52_ANOMALY_109_EGU_INSTANCE
#define DMA_ISSUE_EGU NRFX_CONCAT_2(NRF_EGU, DMA_ISSUE_EGU_IDX)
#define DMA_ISSUE_EGU_IRQn EGU_IRQn(DMA_ISSUE_EGU_IDX)
#define DMA_ISSUE_EGU_IRQHandler EGU_IRQHandler(DMA_ISSUE_EGU_IDX)
#endif
// Control block - driver instance local data.
typedef struct
{
#if defined(USE_DMA_ISSUE_WORKAROUND)
uint32_t starting_task_address;
#endif
nrfx_pwm_handler_t handler;
nrfx_drv_state_t volatile state;
uint8_t flags;
} pwm_control_block_t;
static pwm_control_block_t m_cb[NRFX_PWM_ENABLED_COUNT];
static void configure_pins(nrfx_pwm_t const * const p_instance,
nrfx_pwm_config_t const * p_config)
{
uint32_t out_pins[NRF_PWM_CHANNEL_COUNT];
uint8_t i;
for (i = 0; i < NRF_PWM_CHANNEL_COUNT; ++i)
{
uint8_t output_pin = p_config->output_pins[i];
if (output_pin != NRFX_PWM_PIN_NOT_USED)
{
bool inverted = output_pin & NRFX_PWM_PIN_INVERTED;
out_pins[i] = output_pin & ~NRFX_PWM_PIN_INVERTED;
if (inverted)
{
nrf_gpio_pin_set(out_pins[i]);
}
else
{
nrf_gpio_pin_clear(out_pins[i]);
}
nrf_gpio_cfg_output(out_pins[i]);
}
else
{
out_pins[i] = NRF_PWM_PIN_NOT_CONNECTED;
}
}
nrf_pwm_pins_set(p_instance->p_registers, out_pins);
}
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)
{
NRFX_ASSERT(p_config);
nrfx_err_t err_code;
pwm_control_block_t * p_cb = &m_cb[p_instance->drv_inst_idx];
if (p_cb->state != NRFX_DRV_STATE_UNINITIALIZED)
{
err_code = NRFX_ERROR_INVALID_STATE;
NRFX_LOG_WARNING("Function: %s, error code: %s.",
__func__,
NRFX_LOG_ERROR_STRING_GET(err_code));
return err_code;
}
p_cb->handler = handler;
configure_pins(p_instance, p_config);
nrf_pwm_enable(p_instance->p_registers);
nrf_pwm_configure(p_instance->p_registers,
p_config->base_clock, p_config->count_mode, p_config->top_value);
nrf_pwm_decoder_set(p_instance->p_registers,
p_config->load_mode, p_config->step_mode);
nrf_pwm_shorts_set(p_instance->p_registers, 0);
nrf_pwm_int_set(p_instance->p_registers, 0);
nrf_pwm_event_clear(p_instance->p_registers, NRF_PWM_EVENT_LOOPSDONE);
nrf_pwm_event_clear(p_instance->p_registers, NRF_PWM_EVENT_SEQEND0);
nrf_pwm_event_clear(p_instance->p_registers, NRF_PWM_EVENT_SEQEND1);
nrf_pwm_event_clear(p_instance->p_registers, NRF_PWM_EVENT_STOPPED);
// The workaround for nRF52 Anomaly 109 "protects" DMA transfers by handling
// interrupts generated on SEQEND0 and SEQEND1 events (this ensures that
// the 64 MHz clock is ready when data for the next sequence to be played
// is read). Therefore, the PWM interrupt must be enabled even if the event
// handler is not used.
#if defined(USE_DMA_ISSUE_WORKAROUND)
NRFX_IRQ_PRIORITY_SET(DMA_ISSUE_EGU_IRQn, p_config->irq_priority);
NRFX_IRQ_ENABLE(DMA_ISSUE_EGU_IRQn);
#else
if (p_cb->handler)
#endif
{
NRFX_IRQ_PRIORITY_SET(nrfx_get_irq_number(p_instance->p_registers),
p_config->irq_priority);
NRFX_IRQ_ENABLE(nrfx_get_irq_number(p_instance->p_registers));
}
p_cb->state = NRFX_DRV_STATE_INITIALIZED;
err_code = NRFX_SUCCESS;
NRFX_LOG_INFO("Function: %s, error code: %s.", __func__, NRFX_LOG_ERROR_STRING_GET(err_code));
return err_code;
}
void nrfx_pwm_uninit(nrfx_pwm_t const * const p_instance)
{
pwm_control_block_t * p_cb = &m_cb[p_instance->drv_inst_idx];
NRFX_ASSERT(p_cb->state != NRFX_DRV_STATE_UNINITIALIZED);
NRFX_IRQ_DISABLE(nrfx_get_irq_number(p_instance->p_registers));
#if defined(USE_DMA_ISSUE_WORKAROUND)
NRFX_IRQ_DISABLE(DMA_ISSUE_EGU_IRQn);
#endif
nrf_pwm_disable(p_instance->p_registers);
p_cb->state = NRFX_DRV_STATE_UNINITIALIZED;
}
static uint32_t start_playback(nrfx_pwm_t const * const p_instance,
pwm_control_block_t * p_cb,
uint8_t flags,
nrf_pwm_task_t starting_task)
{
p_cb->state = NRFX_DRV_STATE_POWERED_ON;
p_cb->flags = flags;
if (p_cb->handler)
{
// The notification about finished playback is by default enabled,
// but this can be suppressed.
// The notification that the peripheral has stopped is always enabled.
uint32_t int_mask = NRF_PWM_INT_LOOPSDONE_MASK |
NRF_PWM_INT_STOPPED_MASK;
// The workaround for nRF52 Anomaly 109 "protects" DMA transfers by
// handling interrupts generated on SEQEND0 and SEQEND1 events (see
// 'nrfx_pwm_init'), hence these events must be always enabled
// to generate interrupts.
// However, the user handler is called for them only when requested
// (see 'irq_handler').
#if defined(USE_DMA_ISSUE_WORKAROUND)
int_mask |= NRF_PWM_INT_SEQEND0_MASK | NRF_PWM_INT_SEQEND1_MASK;
#else
if (flags & NRFX_PWM_FLAG_SIGNAL_END_SEQ0)
{
int_mask |= NRF_PWM_INT_SEQEND0_MASK;
}
if (flags & NRFX_PWM_FLAG_SIGNAL_END_SEQ1)
{
int_mask |= NRF_PWM_INT_SEQEND1_MASK;
}
#endif
if (flags & NRFX_PWM_FLAG_NO_EVT_FINISHED)
{
int_mask &= ~NRF_PWM_INT_LOOPSDONE_MASK;
}
nrf_pwm_int_set(p_instance->p_registers, int_mask);
}
#if defined(USE_DMA_ISSUE_WORKAROUND)
else
{
nrf_pwm_int_set(p_instance->p_registers,
NRF_PWM_INT_SEQEND0_MASK | NRF_PWM_INT_SEQEND1_MASK);
}
#endif
nrf_pwm_event_clear(p_instance->p_registers, NRF_PWM_EVENT_STOPPED);
if (flags & NRFX_PWM_FLAG_START_VIA_TASK)
{
uint32_t starting_task_address =
nrf_pwm_task_address_get(p_instance->p_registers, starting_task);
#if defined(USE_DMA_ISSUE_WORKAROUND)
// To "protect" the initial DMA transfer it is required to start
// the PWM by triggering the proper task from EGU interrupt handler,
// it is not safe to do it directly via PPI.
p_cb->starting_task_address = starting_task_address;
nrf_egu_int_enable(DMA_ISSUE_EGU,
nrf_egu_int_get(DMA_ISSUE_EGU, p_instance->drv_inst_idx));
return (uint32_t)nrf_egu_task_trigger_address_get(DMA_ISSUE_EGU,
p_instance->drv_inst_idx);
#else
return starting_task_address;
#endif
}
nrf_pwm_task_trigger(p_instance->p_registers, starting_task);
return 0;
}
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)
{
pwm_control_block_t * p_cb = &m_cb[p_instance->drv_inst_idx];
NRFX_ASSERT(p_cb->state != NRFX_DRV_STATE_UNINITIALIZED);
NRFX_ASSERT(playback_count > 0);
NRFX_ASSERT(nrfx_is_in_ram(p_sequence->values.p_raw));
// To take advantage of the looping mechanism, we need to use both sequences
// (single sequence can be played back only once).
nrf_pwm_sequence_set(p_instance->p_registers, 0, p_sequence);
nrf_pwm_sequence_set(p_instance->p_registers, 1, p_sequence);
bool odd = (playback_count & 1);
nrf_pwm_loop_set(p_instance->p_registers,
(playback_count / 2) + (odd ? 1 : 0));
uint32_t shorts_mask;
if (flags & NRFX_PWM_FLAG_STOP)
{
shorts_mask = NRF_PWM_SHORT_LOOPSDONE_STOP_MASK;
}
else if (flags & NRFX_PWM_FLAG_LOOP)
{
shorts_mask = odd ? NRF_PWM_SHORT_LOOPSDONE_SEQSTART1_MASK
: NRF_PWM_SHORT_LOOPSDONE_SEQSTART0_MASK;
}
else
{
shorts_mask = 0;
}
nrf_pwm_shorts_set(p_instance->p_registers, shorts_mask);
NRFX_LOG_INFO("Function: %s, sequence length: %d.",
__func__,
p_sequence->length);
NRFX_LOG_DEBUG("Sequence data:");
NRFX_LOG_HEXDUMP_DEBUG((uint8_t *)p_sequence->values.p_raw,
p_sequence->length * sizeof(uint16_t));
return start_playback(p_instance, p_cb, flags,
odd ? NRF_PWM_TASK_SEQSTART1 : NRF_PWM_TASK_SEQSTART0);
}
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)
{
pwm_control_block_t * p_cb = &m_cb[p_instance->drv_inst_idx];
NRFX_ASSERT(p_cb->state != NRFX_DRV_STATE_UNINITIALIZED);
NRFX_ASSERT(playback_count > 0);
NRFX_ASSERT(nrfx_is_in_ram(p_sequence_0->values.p_raw));
NRFX_ASSERT(nrfx_is_in_ram(p_sequence_1->values.p_raw));
nrf_pwm_sequence_set(p_instance->p_registers, 0, p_sequence_0);
nrf_pwm_sequence_set(p_instance->p_registers, 1, p_sequence_1);
nrf_pwm_loop_set(p_instance->p_registers, playback_count);
uint32_t shorts_mask;
if (flags & NRFX_PWM_FLAG_STOP)
{
shorts_mask = NRF_PWM_SHORT_LOOPSDONE_STOP_MASK;
}
else if (flags & NRFX_PWM_FLAG_LOOP)
{
shorts_mask = NRF_PWM_SHORT_LOOPSDONE_SEQSTART0_MASK;
}
else
{
shorts_mask = 0;
}
nrf_pwm_shorts_set(p_instance->p_registers, shorts_mask);
NRFX_LOG_INFO("Function: %s, sequence 0 length: %d.",
__func__,
p_sequence_0->length);
NRFX_LOG_INFO("Function: %s, sequence 1 length: %d.",
__func__,
p_sequence_1->length);
NRFX_LOG_DEBUG("Sequence 0 data:");
NRFX_LOG_HEXDUMP_DEBUG(p_sequence_0->values.p_raw,
p_sequence_0->length * sizeof(uint16_t));
NRFX_LOG_DEBUG("Sequence 1 data:");
NRFX_LOG_HEXDUMP_DEBUG(p_sequence_1->values.p_raw,
p_sequence_1->length * sizeof(uint16_t));
return start_playback(p_instance, p_cb, flags, NRF_PWM_TASK_SEQSTART0);
}
bool nrfx_pwm_stop(nrfx_pwm_t const * const p_instance,
bool wait_until_stopped)
{
NRFX_ASSERT(m_cb[p_instance->drv_inst_idx].state != NRFX_DRV_STATE_UNINITIALIZED);
bool ret_val = false;
// Deactivate shortcuts before triggering the STOP task, otherwise the PWM
// could be immediately started again if the LOOPSDONE event occurred in
// the same peripheral clock cycle as the STOP task was triggered.
nrf_pwm_shorts_set(p_instance->p_registers, 0);
// Trigger the STOP task even if the PWM appears to be already stopped.
// It won't harm, but it could help if for some strange reason the stopped
// status was not reported correctly.
nrf_pwm_task_trigger(p_instance->p_registers, NRF_PWM_TASK_STOP);
if (nrfx_pwm_is_stopped(p_instance))
{
ret_val = true;
}
else
{
do {
if (nrfx_pwm_is_stopped(p_instance))
{
ret_val = true;
break;
}
} while (wait_until_stopped);
}
NRFX_LOG_INFO("%s returned %d.", __func__, ret_val);
return ret_val;
}
bool nrfx_pwm_is_stopped(nrfx_pwm_t const * const p_instance)
{
pwm_control_block_t * p_cb = &m_cb[p_instance->drv_inst_idx];
NRFX_ASSERT(p_cb->state != NRFX_DRV_STATE_UNINITIALIZED);
bool ret_val = false;
// If the event handler is used (interrupts are enabled), the state will
// be changed in interrupt handler when the STOPPED event occurs.
if (p_cb->state != NRFX_DRV_STATE_POWERED_ON)
{
ret_val = true;
}
// If interrupts are disabled, we must check the STOPPED event here.
if (nrf_pwm_event_check(p_instance->p_registers, NRF_PWM_EVENT_STOPPED))
{
p_cb->state = NRFX_DRV_STATE_INITIALIZED;
NRFX_LOG_INFO("Disabled.");
ret_val = true;
}
NRFX_LOG_INFO("%s returned %d.", __func__, ret_val);
return ret_val;
}
static void irq_handler(NRF_PWM_Type * p_pwm, pwm_control_block_t * p_cb)
{
// The user handler is called for SEQEND0 and SEQEND1 events only when the
// user asks for it (by setting proper flags when starting the playback).
if (nrf_pwm_event_check(p_pwm, NRF_PWM_EVENT_SEQEND0))
{
nrf_pwm_event_clear(p_pwm, NRF_PWM_EVENT_SEQEND0);
if ((p_cb->flags & NRFX_PWM_FLAG_SIGNAL_END_SEQ0) && p_cb->handler)
{
p_cb->handler(NRFX_PWM_EVT_END_SEQ0);
}
}
if (nrf_pwm_event_check(p_pwm, NRF_PWM_EVENT_SEQEND1))
{
nrf_pwm_event_clear(p_pwm, NRF_PWM_EVENT_SEQEND1);
if ((p_cb->flags & NRFX_PWM_FLAG_SIGNAL_END_SEQ1) && p_cb->handler)
{
p_cb->handler(NRFX_PWM_EVT_END_SEQ1);
}
}
// For LOOPSDONE the handler is called by default, but the user can disable
// this (via flags).
if (nrf_pwm_event_check(p_pwm, NRF_PWM_EVENT_LOOPSDONE))
{
nrf_pwm_event_clear(p_pwm, NRF_PWM_EVENT_LOOPSDONE);
if (!(p_cb->flags & NRFX_PWM_FLAG_NO_EVT_FINISHED) && p_cb->handler)
{
p_cb->handler(NRFX_PWM_EVT_FINISHED);
}
}
// The STOPPED event is always propagated to the user handler.
if (nrf_pwm_event_check(p_pwm, NRF_PWM_EVENT_STOPPED))
{
nrf_pwm_event_clear(p_pwm, NRF_PWM_EVENT_STOPPED);
p_cb->state = NRFX_DRV_STATE_INITIALIZED;
if (p_cb->handler)
{
p_cb->handler(NRFX_PWM_EVT_STOPPED);
}
}
}
#if defined(USE_DMA_ISSUE_WORKAROUND)
// See 'start_playback' why this is needed.
void DMA_ISSUE_EGU_IRQHandler(void)
{
int i;
for (i = 0; i < NRFX_PWM_ENABLED_COUNT; ++i)
{
volatile uint32_t * p_event_reg =
nrf_egu_event_triggered_address_get(DMA_ISSUE_EGU, i);
if (*p_event_reg)
{
*p_event_reg = 0;
*(volatile uint32_t *)(m_cb[i].starting_task_address) = 1;
}
}
}
#endif
#if NRFX_CHECK(NRFX_PWM0_ENABLED)
void nrfx_pwm_0_irq_handler(void)
{
irq_handler(NRF_PWM0, &m_cb[NRFX_PWM0_INST_IDX]);
}
#endif
#if NRFX_CHECK(NRFX_PWM1_ENABLED)
void nrfx_pwm_1_irq_handler(void)
{
irq_handler(NRF_PWM1, &m_cb[NRFX_PWM1_INST_IDX]);
}
#endif
#if NRFX_CHECK(NRFX_PWM2_ENABLED)
void nrfx_pwm_2_irq_handler(void)
{
irq_handler(NRF_PWM2, &m_cb[NRFX_PWM2_INST_IDX]);
}
#endif
#if NRFX_CHECK(NRFX_PWM3_ENABLED)
void nrfx_pwm_3_irq_handler(void)
{
irq_handler(NRF_PWM3, &m_cb[NRFX_PWM3_INST_IDX]);
}
#endif
#endif // NRFX_CHECK(NRFX_PWM_ENABLED)
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