blob: 9cc3d6537101d05f9c7cffb08c4a93faa8c30a3a [file] [log] [blame]
/*
* Copyright (c) 2018 Kokoon Technology Limited
* Copyright (c) 2019 Song Qiang <songqiang1304521@gmail.com>
* Copyright (c) 2019 Endre Karlson
* Copyright (c) 2020 Teslabs Engineering S.L.
* Copyright (c) 2021 Marius Scholtz, RIC Electronics
* Copyright (c) 2023 Hein Wessels, Nobleo Technology
*
* SPDX-License-Identifier: Apache-2.0
*/
#define DT_DRV_COMPAT st_stm32_adc
#include <errno.h>
#include <zephyr/drivers/adc.h>
#include <zephyr/drivers/pinctrl.h>
#include <zephyr/device.h>
#include <zephyr/kernel.h>
#include <zephyr/init.h>
#include <soc.h>
#include <stm32_ll_adc.h>
#if defined(CONFIG_SOC_SERIES_STM32U5X)
#include <stm32_ll_pwr.h>
#endif /* CONFIG_SOC_SERIES_STM32U5X */
#define ADC_CONTEXT_USES_KERNEL_TIMER
#define ADC_CONTEXT_ENABLE_ON_COMPLETE
#include "adc_context.h"
#define LOG_LEVEL CONFIG_ADC_LOG_LEVEL
#include <zephyr/logging/log.h>
LOG_MODULE_REGISTER(adc_stm32);
#include <zephyr/drivers/clock_control/stm32_clock_control.h>
#include <zephyr/irq.h>
#if defined(CONFIG_SOC_SERIES_STM32F3X)
#if defined(ADC1_V2_5)
#define STM32F3X_ADC_V2_5
#elif defined(ADC5_V1_1)
#define STM32F3X_ADC_V1_1
#endif
#endif
/* reference voltage for the ADC */
#define STM32_ADC_VREF_MV DT_INST_PROP(0, vref_mv)
#if !defined(CONFIG_SOC_SERIES_STM32F0X) && \
!defined(CONFIG_SOC_SERIES_STM32G0X) && \
!defined(CONFIG_SOC_SERIES_STM32L0X) && \
!defined(CONFIG_SOC_SERIES_STM32WLX)
#define RANK(n) LL_ADC_REG_RANK_##n
static const uint32_t table_rank[] = {
RANK(1),
RANK(2),
RANK(3),
RANK(4),
RANK(5),
RANK(6),
RANK(7),
RANK(8),
RANK(9),
RANK(10),
RANK(11),
RANK(12),
RANK(13),
RANK(14),
RANK(15),
RANK(16),
};
#define SEQ_LEN(n) LL_ADC_REG_SEQ_SCAN_ENABLE_##n##RANKS
/* Length of this array signifies the maximum sequence length */
static const uint32_t table_seq_len[] = {
LL_ADC_REG_SEQ_SCAN_DISABLE,
SEQ_LEN(2),
SEQ_LEN(3),
SEQ_LEN(4),
SEQ_LEN(5),
SEQ_LEN(6),
SEQ_LEN(7),
SEQ_LEN(8),
SEQ_LEN(9),
SEQ_LEN(10),
SEQ_LEN(11),
SEQ_LEN(12),
SEQ_LEN(13),
SEQ_LEN(14),
SEQ_LEN(15),
SEQ_LEN(16),
};
#endif
#define RES(n) LL_ADC_RESOLUTION_##n##B
static const uint32_t table_resolution[] = {
#if defined(CONFIG_SOC_SERIES_STM32F1X) || \
defined(STM32F3X_ADC_V2_5)
RES(12),
#elif defined(CONFIG_SOC_SERIES_STM32U5X)
RES(6),
RES(8),
RES(10),
RES(12),
RES(14),
#elif !defined(CONFIG_SOC_SERIES_STM32H7X)
RES(6),
RES(8),
RES(10),
RES(12),
#else
RES(8),
RES(10),
RES(12),
RES(14),
RES(16),
#endif
};
#define SMP_TIME(x, y) LL_ADC_SAMPLINGTIME_##x##CYCLE##y
/*
* Conversion time in ADC cycles. Many values should have been 0.5 less,
* but the adc api system currently does not support describing 'half cycles'.
* So all half cycles are counted as one.
*/
#if defined(CONFIG_SOC_SERIES_STM32F0X) || defined(CONFIG_SOC_SERIES_STM32F1X)
static const uint16_t acq_time_tbl[8] = {2, 8, 14, 29, 42, 56, 72, 240};
static const uint32_t table_samp_time[] = {
SMP_TIME(1, _5),
SMP_TIME(7, S_5),
SMP_TIME(13, S_5),
SMP_TIME(28, S_5),
SMP_TIME(41, S_5),
SMP_TIME(55, S_5),
SMP_TIME(71, S_5),
SMP_TIME(239, S_5),
};
#elif defined(CONFIG_SOC_SERIES_STM32F2X) || \
defined(CONFIG_SOC_SERIES_STM32F4X) || \
defined(CONFIG_SOC_SERIES_STM32F7X)
static const uint16_t acq_time_tbl[8] = {3, 15, 28, 56, 84, 112, 144, 480};
static const uint32_t table_samp_time[] = {
SMP_TIME(3, S),
SMP_TIME(15, S),
SMP_TIME(28, S),
SMP_TIME(56, S),
SMP_TIME(84, S),
SMP_TIME(112, S),
SMP_TIME(144, S),
SMP_TIME(480, S),
};
#elif defined(CONFIG_SOC_SERIES_STM32F3X)
#ifdef ADC5_V1_1
static const uint16_t acq_time_tbl[8] = {2, 3, 5, 8, 20, 62, 182, 602};
static const uint32_t table_samp_time[] = {
SMP_TIME(1, _5),
SMP_TIME(2, S_5),
SMP_TIME(4, S_5),
SMP_TIME(7, S_5),
SMP_TIME(19, S_5),
SMP_TIME(61, S_5),
SMP_TIME(181, S_5),
SMP_TIME(601, S_5),
};
#else
static const uint16_t acq_time_tbl[8] = {2, 8, 14, 29, 42, 56, 72, 240};
static const uint32_t table_samp_time[] = {
SMP_TIME(1, _5),
SMP_TIME(7, S_5),
SMP_TIME(13, S_5),
SMP_TIME(28, S_5),
SMP_TIME(41, S_5),
SMP_TIME(55, S_5),
SMP_TIME(71, S_5),
SMP_TIME(239, S_5),
};
#endif /* ADC5_V1_1 */
#elif defined(CONFIG_SOC_SERIES_STM32L0X) || \
defined(CONFIG_SOC_SERIES_STM32G0X) || \
defined(CONFIG_SOC_SERIES_STM32WLX)
static const uint16_t acq_time_tbl[8] = {2, 4, 8, 13, 20, 40, 80, 161};
static const uint32_t table_samp_time[] = {
SMP_TIME(1, _5),
SMP_TIME(3, S_5),
SMP_TIME(7, S_5),
SMP_TIME(12, S_5),
SMP_TIME(19, S_5),
SMP_TIME(39, S_5),
SMP_TIME(79, S_5),
SMP_TIME(160, S_5),
};
#elif defined(CONFIG_SOC_SERIES_STM32L4X) || \
defined(CONFIG_SOC_SERIES_STM32L5X) || \
defined(CONFIG_SOC_SERIES_STM32WBX) || \
defined(CONFIG_SOC_SERIES_STM32G4X)
static const uint16_t acq_time_tbl[8] = {3, 7, 13, 25, 48, 93, 248, 641};
static const uint32_t table_samp_time[] = {
SMP_TIME(2, S_5),
SMP_TIME(6, S_5),
SMP_TIME(12, S_5),
SMP_TIME(24, S_5),
SMP_TIME(47, S_5),
SMP_TIME(92, S_5),
SMP_TIME(247, S_5),
SMP_TIME(640, S_5),
};
#elif defined(CONFIG_SOC_SERIES_STM32L1X)
static const uint16_t acq_time_tbl[8] = {5, 10, 17, 25, 49, 97, 193, 385};
static const uint32_t table_samp_time[] = {
SMP_TIME(4, S),
SMP_TIME(9, S),
SMP_TIME(16, S),
SMP_TIME(24, S),
SMP_TIME(48, S),
SMP_TIME(96, S),
SMP_TIME(192, S),
SMP_TIME(384, S),
};
#elif defined(CONFIG_SOC_SERIES_STM32H7X)
static const uint16_t acq_time_tbl[8] = {2, 3, 9, 17, 33, 65, 388, 811};
static const uint32_t table_samp_time[] = {
SMP_TIME(1, _5),
SMP_TIME(2, S_5),
SMP_TIME(8, S_5),
SMP_TIME(16, S_5),
SMP_TIME(32, S_5),
SMP_TIME(64, S_5),
SMP_TIME(387, S_5),
SMP_TIME(810, S_5),
};
#elif defined(CONFIG_SOC_SERIES_STM32U5X)
static const uint16_t acq_time_tbl[8] = {5, 6, 12, 20, 36, 68, 391, 814};
static const uint32_t table_samp_time[] = {
SMP_TIME(5,),
SMP_TIME(6, S),
SMP_TIME(12, S),
SMP_TIME(20, S),
SMP_TIME(36, S),
SMP_TIME(68, S),
SMP_TIME(391, S_5),
SMP_TIME(814, S),
};
#endif
/* External channels (maximum). */
#define STM32_CHANNEL_COUNT 20
struct adc_stm32_data {
struct adc_context ctx;
const struct device *dev;
uint16_t *buffer;
uint16_t *repeat_buffer;
uint8_t resolution;
uint32_t channels;
uint8_t channel_count;
uint8_t samples_count;
#if defined(CONFIG_SOC_SERIES_STM32F0X) || \
defined(CONFIG_SOC_SERIES_STM32G0X) || \
defined(CONFIG_SOC_SERIES_STM32L0X)
int8_t acq_time_index;
#endif
};
struct adc_stm32_cfg {
ADC_TypeDef *base;
void (*irq_cfg_func)(void);
struct stm32_pclken pclken;
const struct pinctrl_dev_config *pcfg;
bool has_temp_channel;
bool has_vref_channel;
bool has_vbat_channel;
int8_t temp_channel;
int8_t vref_channel;
int8_t vbat_channel;
};
#ifdef CONFIG_ADC_STM32_SHARED_IRQS
static bool init_irq = true;
#endif
static int check_buffer_size(const struct adc_sequence *sequence,
uint8_t active_channels)
{
size_t needed_buffer_size;
needed_buffer_size = active_channels * sizeof(uint16_t);
if (sequence->options) {
needed_buffer_size *= (1 + sequence->options->extra_samplings);
}
if (sequence->buffer_size < needed_buffer_size) {
LOG_ERR("Provided buffer is too small (%u/%u)",
sequence->buffer_size, needed_buffer_size);
return -ENOMEM;
}
return 0;
}
static void adc_stm32_start_conversion(const struct device *dev)
{
const struct adc_stm32_cfg *config = dev->config;
ADC_TypeDef *adc = (ADC_TypeDef *)config->base;
LOG_DBG("Starting conversion");
#if defined(CONFIG_SOC_SERIES_STM32F0X) || \
defined(CONFIG_SOC_SERIES_STM32F3X) || \
defined(CONFIG_SOC_SERIES_STM32L0X) || \
defined(CONFIG_SOC_SERIES_STM32L4X) || \
defined(CONFIG_SOC_SERIES_STM32L5X) || \
defined(CONFIG_SOC_SERIES_STM32WBX) || \
defined(CONFIG_SOC_SERIES_STM32G0X) || \
defined(CONFIG_SOC_SERIES_STM32G4X) || \
defined(CONFIG_SOC_SERIES_STM32H7X) || \
defined(CONFIG_SOC_SERIES_STM32U5X) || \
defined(CONFIG_SOC_SERIES_STM32WLX)
LL_ADC_REG_StartConversion(adc);
#else
LL_ADC_REG_StartConversionSWStart(adc);
#endif
}
#if !defined(CONFIG_SOC_SERIES_STM32F2X) && \
!defined(CONFIG_SOC_SERIES_STM32F4X) && \
!defined(CONFIG_SOC_SERIES_STM32F7X) && \
!defined(CONFIG_SOC_SERIES_STM32F1X) && \
!defined(STM32F3X_ADC_V2_5) && \
!defined(CONFIG_SOC_SERIES_STM32L1X)
static void adc_stm32_calib(const struct device *dev)
{
const struct adc_stm32_cfg *config =
(const struct adc_stm32_cfg *)dev->config;
ADC_TypeDef *adc = config->base;
#if defined(STM32F3X_ADC_V1_1) || \
defined(CONFIG_SOC_SERIES_STM32L4X) || \
defined(CONFIG_SOC_SERIES_STM32L5X) || \
defined(CONFIG_SOC_SERIES_STM32WBX) || \
defined(CONFIG_SOC_SERIES_STM32G4X)
LL_ADC_StartCalibration(adc, LL_ADC_SINGLE_ENDED);
#elif defined(CONFIG_SOC_SERIES_STM32F0X) || \
defined(CONFIG_SOC_SERIES_STM32G0X) || \
defined(CONFIG_SOC_SERIES_STM32L0X) || \
defined(CONFIG_SOC_SERIES_STM32WLX)
LL_ADC_StartCalibration(adc);
#elif defined(CONFIG_SOC_SERIES_STM32U5X)
LL_ADC_StartCalibration(adc, LL_ADC_CALIB_OFFSET);
#elif defined(CONFIG_SOC_SERIES_STM32H7X)
LL_ADC_StartCalibration(adc, LL_ADC_CALIB_OFFSET, LL_ADC_SINGLE_ENDED);
#endif
while (LL_ADC_IsCalibrationOnGoing(adc)) {
}
}
#endif
/*
* Disable ADC peripheral, and wait until it is disabled
*/
static inline void adc_stm32_disable(ADC_TypeDef *adc)
{
if (LL_ADC_IsEnabled(adc) != 1UL) {
return;
}
LL_ADC_Disable(adc);
while (LL_ADC_IsEnabled(adc) == 1UL) {
}
}
#if defined(CONFIG_SOC_SERIES_STM32G0X) || \
defined(CONFIG_SOC_SERIES_STM32G4X) || \
defined(CONFIG_SOC_SERIES_STM32H7X) || \
defined(CONFIG_SOC_SERIES_STM32L0X) || \
defined(CONFIG_SOC_SERIES_STM32L4X) || \
defined(CONFIG_SOC_SERIES_STM32L5X) || \
defined(CONFIG_SOC_SERIES_STM32U5X) || \
defined(CONFIG_SOC_SERIES_STM32WBX) || \
defined(CONFIG_SOC_SERIES_STM32WLX)
#ifdef LL_ADC_OVS_RATIO_2
/* table for shifting oversampling mostly for ADC3 != ADC_VER_V5_V90 */
static const uint32_t stm32_adc_ratio_table[] = {
0,
LL_ADC_OVS_RATIO_2,
LL_ADC_OVS_RATIO_4,
LL_ADC_OVS_RATIO_8,
LL_ADC_OVS_RATIO_16,
LL_ADC_OVS_RATIO_32,
LL_ADC_OVS_RATIO_64,
LL_ADC_OVS_RATIO_128,
LL_ADC_OVS_RATIO_256,
};
#endif /* ! ADC_VER_V5_V90 */
/*
* Function to configure the oversampling scope. It is basically a wrapper over
* LL_ADC_SetOverSamplingScope() which in addition stops the ADC if needed.
*/
static void adc_stm32_oversampling_scope(ADC_TypeDef *adc, uint32_t ovs_scope)
{
#if defined(CONFIG_SOC_SERIES_STM32L0X) || \
defined(CONFIG_SOC_SERIES_STM32WLX)
/*
* setting OVS bits is conditioned to ADC state: ADC must be disabled
* or enabled without conversion on going : disable it, it will stop
*/
if (LL_ADC_GetOverSamplingScope(adc) == ovs_scope) {
return;
}
adc_stm32_disable(adc);
#endif
LL_ADC_SetOverSamplingScope(adc, ovs_scope);
}
#if !defined(CONFIG_SOC_SERIES_STM32H7X)
/*
* Function to configure the oversampling ratio and shift. It is basically a
* wrapper over LL_ADC_SetOverSamplingRatioShift() which in addition stops the
* ADC if needed.
*/
static void adc_stm32_oversampling_ratioshift(ADC_TypeDef *adc, uint32_t ratio, uint32_t shift)
{
#if defined(CONFIG_SOC_SERIES_STM32L0X) || \
defined(CONFIG_SOC_SERIES_STM32WLX)
/*
* setting OVS bits is conditioned to ADC state: ADC must be disabled
* or enabled without conversion on going : disable it, it will stop
*/
if ((LL_ADC_GetOverSamplingRatio(adc) == ratio)
&& (LL_ADC_GetOverSamplingShift(adc) == shift)) {
return;
}
adc_stm32_disable(adc);
#endif
LL_ADC_ConfigOverSamplingRatioShift(adc, ratio, shift);
}
#endif
/*
* Function to configure the oversampling ratio and shit using stm32 LL
* ratio is directly the sequence->oversampling (a 2^n value)
* shift is the corresponding LL_ADC_OVS_SHIFT_RIGHT_x constant
*/
static void adc_stm32_oversampling(ADC_TypeDef *adc, uint8_t ratio, uint32_t shift)
{
adc_stm32_oversampling_scope(adc, LL_ADC_OVS_GRP_REGULAR_CONTINUED);
#if defined(CONFIG_SOC_SERIES_STM32H7X)
/*
* Set bits manually to circumvent bug in LL Libraries
* https://github.com/STMicroelectronics/STM32CubeH7/issues/177
*/
#if defined(ADC_VER_V5_V90)
if (adc == ADC3) {
MODIFY_REG(adc->CFGR2, (ADC_CFGR2_OVSS | ADC3_CFGR2_OVSR),
(shift | stm32_adc_ratio_table[ratio]));
} else {
MODIFY_REG(adc->CFGR2, (ADC_CFGR2_OVSS | ADC_CFGR2_OVSR),
(shift | (((1UL << ratio) - 1) << ADC_CFGR2_OVSR_Pos)));
}
#endif /* ADC_VER_V5_V90*/
MODIFY_REG(adc->CFGR2, (ADC_CFGR2_OVSS | ADC_CFGR2_OVSR),
(shift | (((1UL << ratio) - 1) << ADC_CFGR2_OVSR_Pos)));
#elif defined(CONFIG_SOC_SERIES_STM32U5X)
if (adc == ADC1) {
/* the LL function expects a value from 1 to 1024 */
adc_stm32_oversampling_ratioshift(adc, (1 << ratio), shift);
} else {
/* the LL function expects a value LL_ADC_OVS_RATIO_x */
adc_stm32_oversampling_ratioshift(adc, stm32_adc_ratio_table[ratio], shift);
}
#else /* CONFIG_SOC_SERIES_STM32H7X */
adc_stm32_oversampling_ratioshift(adc, stm32_adc_ratio_table[ratio], shift);
#endif /* CONFIG_SOC_SERIES_STM32H7X */
}
#endif /* CONFIG_SOC_SERIES_STM32xxx */
/*
* Enable ADC peripheral, and wait until ready if required by SOC.
*/
static int adc_stm32_enable(ADC_TypeDef *adc)
{
if (LL_ADC_IsEnabled(adc) == 1UL) {
return 0;
}
#if defined(CONFIG_SOC_SERIES_STM32L4X) || \
defined(CONFIG_SOC_SERIES_STM32L5X) || \
defined(CONFIG_SOC_SERIES_STM32WBX) || \
defined(CONFIG_SOC_SERIES_STM32G0X) || \
defined(CONFIG_SOC_SERIES_STM32G4X) || \
defined(CONFIG_SOC_SERIES_STM32H7X) || \
defined(CONFIG_SOC_SERIES_STM32U5X) || \
defined(CONFIG_SOC_SERIES_STM32WLX)
LL_ADC_ClearFlag_ADRDY(adc);
LL_ADC_Enable(adc);
/*
* Enabling ADC modules in L4, WB, G0 and G4 series may fail if they are
* still not stabilized, this will wait for a short time to ensure ADC
* modules are properly enabled.
*/
uint32_t count_timeout = 0;
while (LL_ADC_IsActiveFlag_ADRDY(adc) == 0) {
if (LL_ADC_IsEnabled(adc) == 0UL) {
LL_ADC_Enable(adc);
count_timeout++;
if (count_timeout == 10) {
return -ETIMEDOUT;
}
}
}
#else
/*
* On the stm32F10x, do not re-enable the ADC :
* if ADON holds 1 (LL_ADC_IsEnabled is true) and 1 is written,
* then conversion starts ; that's not what is expected
*/
LL_ADC_Enable(adc);
#endif
return 0;
}
/*
* Enable internal channel source
*/
static void adc_stm32_set_common_path(const struct device *dev, uint32_t PathInternal)
{
const struct adc_stm32_cfg *config =
(const struct adc_stm32_cfg *)dev->config;
ADC_TypeDef *adc = (ADC_TypeDef *)config->base;
ARG_UNUSED(adc); /* Avoid 'unused variable' warning for some families */
/* Do not remove existing paths */
PathInternal |= LL_ADC_GetCommonPathInternalCh(__LL_ADC_COMMON_INSTANCE(adc));
LL_ADC_SetCommonPathInternalCh(__LL_ADC_COMMON_INSTANCE(adc), PathInternal);
}
static void adc_stm32_setup_channel(const struct device *dev, uint8_t channel_id)
{
const struct adc_stm32_cfg *config = dev->config;
ADC_TypeDef *adc = (ADC_TypeDef *)config->base;
if (config->temp_channel == channel_id) {
adc_stm32_disable(adc);
adc_stm32_set_common_path(dev, LL_ADC_PATH_INTERNAL_TEMPSENSOR);
k_usleep(LL_ADC_DELAY_TEMPSENSOR_STAB_US);
}
if (config->vref_channel == channel_id) {
adc_stm32_disable(adc);
adc_stm32_set_common_path(dev, LL_ADC_PATH_INTERNAL_VREFINT);
#ifdef LL_ADC_DELAY_VREFINT_STAB_US
k_usleep(LL_ADC_DELAY_VREFINT_STAB_US);
#endif
}
#if defined(LL_ADC_CHANNEL_VBAT)
/* Enable the bridge divider only when needed for ADC conversion. */
if (config->vbat_channel == channel_id) {
adc_stm32_disable(adc);
adc_stm32_set_common_path(dev, LL_ADC_PATH_INTERNAL_VBAT);
}
#endif /* LL_ADC_CHANNEL_VBAT */
}
static void adc_stm32_unset_common_path(const struct device *dev, uint32_t PathInternal)
{
const struct adc_stm32_cfg *config = dev->config;
ADC_TypeDef *adc = (ADC_TypeDef *)config->base;
const uint32_t currentPath = LL_ADC_GetCommonPathInternalCh(__LL_ADC_COMMON_INSTANCE(adc));
ARG_UNUSED(adc); /* Avoid 'unused variable' warning for some families */
PathInternal = ~PathInternal & currentPath;
LL_ADC_SetCommonPathInternalCh(__LL_ADC_COMMON_INSTANCE(adc), PathInternal);
}
static void adc_stm32_teardown_channels(const struct device *dev)
{
const struct adc_stm32_cfg *config = dev->config;
struct adc_stm32_data *data = dev->data;
ADC_TypeDef *adc = (ADC_TypeDef *)config->base;
uint8_t channel_id;
for (uint32_t channels = data->channels; channels; channels &= ~BIT(channel_id)) {
channel_id = find_lsb_set(channels) - 1;
if (config->temp_channel == channel_id) {
adc_stm32_disable(adc);
adc_stm32_unset_common_path(dev, LL_ADC_PATH_INTERNAL_TEMPSENSOR);
}
if (config->vref_channel == channel_id) {
adc_stm32_disable(adc);
adc_stm32_unset_common_path(dev, LL_ADC_PATH_INTERNAL_VREFINT);
}
#if defined(LL_ADC_CHANNEL_VBAT)
/* Enable the bridge divider only when needed for ADC conversion. */
if (config->vbat_channel == channel_id) {
adc_stm32_disable(adc);
adc_stm32_unset_common_path(dev, LL_ADC_PATH_INTERNAL_VBAT);
}
#endif /* LL_ADC_CHANNEL_VBAT */
}
adc_stm32_enable(adc);
}
static int start_read(const struct device *dev,
const struct adc_sequence *sequence)
{
const struct adc_stm32_cfg *config = dev->config;
struct adc_stm32_data *data = dev->data;
ADC_TypeDef *adc = (ADC_TypeDef *)config->base;
uint8_t resolution;
int err;
switch (sequence->resolution) {
#if defined(CONFIG_SOC_SERIES_STM32F1X) || \
defined(STM32F3X_ADC_V2_5)
case 12:
resolution = table_resolution[0];
break;
#elif defined(CONFIG_SOC_SERIES_STM32U5X)
case 6:
resolution = table_resolution[0];
break;
case 8:
resolution = table_resolution[1];
break;
case 10:
resolution = table_resolution[2];
break;
case 12:
resolution = table_resolution[3];
break;
case 14:
resolution = table_resolution[4];
break;
#elif !defined(CONFIG_SOC_SERIES_STM32H7X)
case 6:
resolution = table_resolution[0];
break;
case 8:
resolution = table_resolution[1];
break;
case 10:
resolution = table_resolution[2];
break;
case 12:
resolution = table_resolution[3];
break;
#else
case 8:
resolution = table_resolution[0];
break;
case 10:
resolution = table_resolution[1];
break;
case 12:
resolution = table_resolution[2];
break;
case 14:
resolution = table_resolution[3];
break;
case 16:
resolution = table_resolution[4];
break;
#endif
default:
LOG_ERR("Invalid resolution");
return -EINVAL;
}
data->buffer = sequence->buffer;
data->channels = sequence->channels;
data->channel_count = POPCOUNT(data->channels);
data->samples_count = 0;
if (data->channel_count == 0) {
LOG_ERR("No channels selected");
return -EINVAL;
}
if (data->channels > BIT(STM32_CHANNEL_COUNT) - 1) {
LOG_ERR("Channels bitmask uses out of range channel");
return -EINVAL;
}
#if !defined(CONFIG_SOC_SERIES_STM32F0X) && \
!defined(CONFIG_SOC_SERIES_STM32G0X) && \
!defined(CONFIG_SOC_SERIES_STM32L0X) && \
!defined(CONFIG_SOC_SERIES_STM32WLX)
if (data->channel_count > ARRAY_SIZE(table_seq_len)) {
LOG_ERR("Too many channels for sequencer. Max: %d", ARRAY_SIZE(table_seq_len));
return -EINVAL;
}
#else
if (data->channel_count > 1) {
LOG_ERR("This device only supports single channel sampling");
return -EINVAL;
}
#endif
uint8_t channel_id;
uint8_t channel_index = 0;
/* Iterate over selected channels in bitmask keeping track of:
* - channel_index: ranging from 0 -> ( data->channel_count - 1 )
* - channel_id: ordinal position of channel in data->channels bitmask
*/
for (uint32_t channels = data->channels; channels;
channels &= ~BIT(channel_id), channel_index++) {
channel_id = find_lsb_set(channels) - 1;
uint32_t channel = __LL_ADC_DECIMAL_NB_TO_CHANNEL(channel_id);
adc_stm32_setup_channel(dev, channel_id);
#if defined(CONFIG_SOC_SERIES_STM32H7X)
/*
* Each channel in the sequence must be previously enabled in PCSEL.
* This register controls the analog switch integrated in the IO level.
*/
LL_ADC_SetChannelPreSelection(adc, channel);
#elif defined(CONFIG_SOC_SERIES_STM32U5X)
/*
* Each channel in the sequence must be previously enabled in PCSEL.
* This register controls the analog switch integrated in the IO level.
* Only for ADC1 instance (ADC4 has no Channel preselection capability).
*/
if (adc == ADC1) {
LL_ADC_SetChannelPreselection(adc, channel);
}
#endif
#if defined(CONFIG_SOC_SERIES_STM32F0X) || \
defined(CONFIG_SOC_SERIES_STM32L0X)
LL_ADC_REG_SetSequencerChannels(adc, channel);
#elif defined(CONFIG_SOC_SERIES_STM32WLX)
/* Init the the ADC group for REGULAR conversion*/
LL_ADC_REG_SetSequencerConfigurable(adc, LL_ADC_REG_SEQ_CONFIGURABLE);
LL_ADC_REG_SetTriggerSource(adc, LL_ADC_REG_TRIG_SOFTWARE);
LL_ADC_REG_SetSequencerLength(adc, LL_ADC_REG_SEQ_SCAN_DISABLE);
LL_ADC_REG_SetOverrun(adc, LL_ADC_REG_OVR_DATA_OVERWRITTEN);
LL_ADC_REG_SetSequencerRanks(adc, LL_ADC_REG_RANK_1, channel);
LL_ADC_REG_SetSequencerChannels(adc, channel);
/* Wait for config complete config is ready */
while (LL_ADC_IsActiveFlag_CCRDY(adc) == 0) {
}
LL_ADC_ClearFlag_CCRDY(adc);
#elif defined(CONFIG_SOC_SERIES_STM32G0X)
/* STM32G0 in "not fully configurable" sequencer mode */
LL_ADC_REG_SetSequencerChannels(adc, channel);
LL_ADC_REG_SetSequencerConfigurable(adc, LL_ADC_REG_SEQ_FIXED);
while (LL_ADC_IsActiveFlag_CCRDY(adc) == 0) {
}
LL_ADC_ClearFlag_CCRDY(adc);
#elif defined(CONFIG_SOC_SERIES_STM32U5X)
if (adc != ADC4) {
LL_ADC_REG_SetSequencerRanks(adc, table_rank[channel_index], channel);
LL_ADC_REG_SetSequencerLength(adc, table_seq_len[channel_index]);
} else {
LL_ADC_REG_SetSequencerConfigurable(adc, LL_ADC_REG_SEQ_FIXED);
LL_ADC_REG_SetSequencerLength(adc,
BIT(__LL_ADC_CHANNEL_TO_DECIMAL_NB(channel)));
}
#else
LL_ADC_REG_SetSequencerRanks(adc, table_rank[channel_index], channel);
LL_ADC_REG_SetSequencerLength(adc, table_seq_len[channel_index]);
#endif
}
err = check_buffer_size(sequence, data->channel_count);
if (err) {
return err;
}
#if defined(CONFIG_SOC_SERIES_STM32G0X) || \
defined(CONFIG_SOC_SERIES_STM32WLX)
if (LL_ADC_GetResolution(adc) != resolution) {
/*
* Writing ADC_CFGR1 register while ADEN bit is set
* resets RES[1:0] bitfield. We need to disable and enable adc.
*/
adc_stm32_disable(adc);
LL_ADC_SetResolution(adc, resolution);
}
#elif !defined(CONFIG_SOC_SERIES_STM32F1X) && \
!defined(STM32F3X_ADC_V2_5)
LL_ADC_SetResolution(adc, resolution);
#endif
#if defined(CONFIG_SOC_SERIES_STM32G0X) || \
defined(CONFIG_SOC_SERIES_STM32G4X) || \
defined(CONFIG_SOC_SERIES_STM32H7X) || \
defined(CONFIG_SOC_SERIES_STM32L0X) || \
defined(CONFIG_SOC_SERIES_STM32L4X) || \
defined(CONFIG_SOC_SERIES_STM32L5X) || \
defined(CONFIG_SOC_SERIES_STM32U5X) || \
defined(CONFIG_SOC_SERIES_STM32WBX) || \
defined(CONFIG_SOC_SERIES_STM32WLX)
switch (sequence->oversampling) {
case 0:
adc_stm32_oversampling_scope(adc, LL_ADC_OVS_DISABLE);
break;
case 1:
adc_stm32_oversampling(adc, 1, LL_ADC_OVS_SHIFT_RIGHT_1);
break;
case 2:
adc_stm32_oversampling(adc, 2, LL_ADC_OVS_SHIFT_RIGHT_2);
break;
case 3:
adc_stm32_oversampling(adc, 3, LL_ADC_OVS_SHIFT_RIGHT_3);
break;
case 4:
adc_stm32_oversampling(adc, 4, LL_ADC_OVS_SHIFT_RIGHT_4);
break;
case 5:
adc_stm32_oversampling(adc, 5, LL_ADC_OVS_SHIFT_RIGHT_5);
break;
case 6:
adc_stm32_oversampling(adc, 6, LL_ADC_OVS_SHIFT_RIGHT_6);
break;
case 7:
adc_stm32_oversampling(adc, 7, LL_ADC_OVS_SHIFT_RIGHT_7);
break;
case 8:
adc_stm32_oversampling(adc, 8, LL_ADC_OVS_SHIFT_RIGHT_8);
break;
#if defined(CONFIG_SOC_SERIES_STM32H7X) || defined(CONFIG_SOC_SERIES_STM32U5X)
/* stm32 U5, H7 ADC1 & 2 have oversampling ratio from 1..1024 */
case 9:
adc_stm32_oversampling(adc, 9, LL_ADC_OVS_SHIFT_RIGHT_9);
break;
case 10:
adc_stm32_oversampling(adc, 10, LL_ADC_OVS_SHIFT_RIGHT_10);
break;
#endif /* CONFIG_SOC_SERIES_STM32H7X */
default:
LOG_ERR("Invalid oversampling");
adc_stm32_enable(adc);
return -EINVAL;
}
#else
if (sequence->oversampling) {
LOG_ERR("Oversampling not supported");
return -ENOTSUP;
}
#endif
if (sequence->calibrate) {
#if !defined(CONFIG_SOC_SERIES_STM32F2X) && \
!defined(CONFIG_SOC_SERIES_STM32F4X) && \
!defined(CONFIG_SOC_SERIES_STM32F7X) && \
!defined(CONFIG_SOC_SERIES_STM32F1X) && \
!defined(STM32F3X_ADC_V2_5) && \
!defined(CONFIG_SOC_SERIES_STM32L1X)
/* we cannot calibrate the ADC while the ADC is enabled */
adc_stm32_disable(adc);
adc_stm32_calib(dev);
#else
LOG_ERR("Calibration not supported");
return -ENOTSUP;
#endif
}
/*
* Make sure the ADC is enabled as it might have been disabled earlier
* to set the resolution, to set the oversampling or to perform the
* calibration.
*/
adc_stm32_enable(adc);
#if defined(CONFIG_SOC_SERIES_STM32F0X) || \
defined(STM32F3X_ADC_V1_1) || \
defined(CONFIG_SOC_SERIES_STM32L0X) || \
defined(CONFIG_SOC_SERIES_STM32L4X) || \
defined(CONFIG_SOC_SERIES_STM32L5X) || \
defined(CONFIG_SOC_SERIES_STM32WBX) || \
defined(CONFIG_SOC_SERIES_STM32G0X) || \
defined(CONFIG_SOC_SERIES_STM32G4X) || \
defined(CONFIG_SOC_SERIES_STM32H7X) || \
defined(CONFIG_SOC_SERIES_STM32U5X) || \
defined(CONFIG_SOC_SERIES_STM32WLX)
LL_ADC_EnableIT_EOC(adc);
#elif defined(STM32F3X_ADC_V2_5) || \
defined(CONFIG_SOC_SERIES_STM32F1X)
LL_ADC_EnableIT_EOS(adc);
#else
LL_ADC_EnableIT_EOCS(adc);
#endif
adc_context_start_read(&data->ctx, sequence);
int result = adc_context_wait_for_completion(&data->ctx);
return result;
}
static void adc_context_start_sampling(struct adc_context *ctx)
{
struct adc_stm32_data *data =
CONTAINER_OF(ctx, struct adc_stm32_data, ctx);
data->repeat_buffer = data->buffer;
adc_stm32_start_conversion(data->dev);
}
static void adc_context_update_buffer_pointer(struct adc_context *ctx,
bool repeat_sampling)
{
struct adc_stm32_data *data =
CONTAINER_OF(ctx, struct adc_stm32_data, ctx);
if (repeat_sampling) {
data->buffer = data->repeat_buffer;
}
}
static void adc_stm32_isr(const struct device *dev)
{
struct adc_stm32_data *data = dev->data;
const struct adc_stm32_cfg *config =
(const struct adc_stm32_cfg *)dev->config;
ADC_TypeDef *adc = config->base;
*data->buffer++ = LL_ADC_REG_ReadConversionData32(adc);
/* ISR is triggered after each conversion, and at the end-of-sequence. */
if (++data->samples_count == data->channel_count) {
data->samples_count = 0;
adc_context_on_sampling_done(&data->ctx, dev);
}
LOG_DBG("%s ISR triggered.", dev->name);
}
static void adc_context_on_complete(struct adc_context *ctx, int status)
{
struct adc_stm32_data *data =
CONTAINER_OF(ctx, struct adc_stm32_data, ctx);
ARG_UNUSED(status);
adc_stm32_teardown_channels(data->dev);
}
static int adc_stm32_read(const struct device *dev,
const struct adc_sequence *sequence)
{
struct adc_stm32_data *data = dev->data;
int error;
adc_context_lock(&data->ctx, false, NULL);
error = start_read(dev, sequence);
adc_context_release(&data->ctx, error);
return error;
}
#ifdef CONFIG_ADC_ASYNC
static int adc_stm32_read_async(const struct device *dev,
const struct adc_sequence *sequence,
struct k_poll_signal *async)
{
struct adc_stm32_data *data = dev->data;
int error;
adc_context_lock(&data->ctx, true, async);
error = start_read(dev, sequence);
adc_context_release(&data->ctx, error);
return error;
}
#endif
static int adc_stm32_check_acq_time(uint16_t acq_time)
{
if (acq_time == ADC_ACQ_TIME_MAX) {
return ARRAY_SIZE(acq_time_tbl) - 1;
}
for (int i = 0; i < 8; i++) {
if (acq_time == ADC_ACQ_TIME(ADC_ACQ_TIME_TICKS,
acq_time_tbl[i])) {
return i;
}
}
if (acq_time == ADC_ACQ_TIME_DEFAULT) {
return 0;
}
LOG_ERR("Conversion time not supported.");
return -EINVAL;
}
static void adc_stm32_setup_speed(const struct device *dev, uint8_t id,
uint8_t acq_time_index)
{
const struct adc_stm32_cfg *config =
(const struct adc_stm32_cfg *)dev->config;
ADC_TypeDef *adc = config->base;
#if defined(CONFIG_SOC_SERIES_STM32F0X) || defined(CONFIG_SOC_SERIES_STM32L0X)
LL_ADC_SetSamplingTimeCommonChannels(adc,
table_samp_time[acq_time_index]);
#elif defined(CONFIG_SOC_SERIES_STM32G0X)
/* Errata ES0418 and more: ADC sampling time might be one cycle longer */
if (acq_time_index < 2) {
acq_time_index = 2;
}
LL_ADC_SetSamplingTimeCommonChannels(adc, LL_ADC_SAMPLINGTIME_COMMON_1,
table_samp_time[acq_time_index]);
#elif defined(CONFIG_SOC_SERIES_STM32WLX)
LL_ADC_SetChannelSamplingTime(adc,
__LL_ADC_DECIMAL_NB_TO_CHANNEL(id),
LL_ADC_SAMPLINGTIME_COMMON_1);
LL_ADC_SetSamplingTimeCommonChannels(adc,
__LL_ADC_DECIMAL_NB_TO_CHANNEL(id),
table_samp_time[acq_time_index]);
#elif defined(CONFIG_SOC_SERIES_STM32U5X)
if (adc != ADC4) {
LL_ADC_SetChannelSamplingTime(adc,
__LL_ADC_DECIMAL_NB_TO_CHANNEL(id),
table_samp_time[acq_time_index]);
} else {
LL_ADC_SetSamplingTimeCommonChannels(adc,
LL_ADC_SAMPLINGTIME_COMMON_1,
table_samp_time[acq_time_index]);
}
#else
LL_ADC_SetChannelSamplingTime(adc,
__LL_ADC_DECIMAL_NB_TO_CHANNEL(id),
table_samp_time[acq_time_index]);
#endif
}
static int adc_stm32_channel_setup(const struct device *dev,
const struct adc_channel_cfg *channel_cfg)
{
#if defined(CONFIG_SOC_SERIES_STM32F0X) || \
defined(CONFIG_SOC_SERIES_STM32G0X) || \
defined(CONFIG_SOC_SERIES_STM32L0X)
struct adc_stm32_data *data = dev->data;
#endif
int acq_time_index;
if (channel_cfg->channel_id >= STM32_CHANNEL_COUNT) {
LOG_ERR("Channel %d is not valid", channel_cfg->channel_id);
return -EINVAL;
}
acq_time_index = adc_stm32_check_acq_time(
channel_cfg->acquisition_time);
if (acq_time_index < 0) {
return acq_time_index;
}
#if defined(CONFIG_SOC_SERIES_STM32F0X) || \
defined(CONFIG_SOC_SERIES_STM32G0X) || \
defined(CONFIG_SOC_SERIES_STM32L0X)
if (data->acq_time_index == -1) {
data->acq_time_index = acq_time_index;
} else {
/* All channels of F0/L0 must have identical acquisition time.*/
if (acq_time_index != data->acq_time_index) {
return -EINVAL;
}
}
#endif
if (channel_cfg->differential) {
LOG_ERR("Differential channels are not supported");
return -EINVAL;
}
if (channel_cfg->gain != ADC_GAIN_1) {
LOG_ERR("Invalid channel gain");
return -EINVAL;
}
if (channel_cfg->reference != ADC_REF_INTERNAL) {
LOG_ERR("Invalid channel reference");
return -EINVAL;
}
adc_stm32_setup_speed(dev, channel_cfg->channel_id,
acq_time_index);
LOG_DBG("Channel setup succeeded!");
return 0;
}
static int adc_stm32_init(const struct device *dev)
{
struct adc_stm32_data *data = dev->data;
const struct adc_stm32_cfg *config = dev->config;
const struct device *const clk = DEVICE_DT_GET(STM32_CLOCK_CONTROL_NODE);
ADC_TypeDef *adc = (ADC_TypeDef *)config->base;
int err;
LOG_DBG("Initializing....");
if (!device_is_ready(clk)) {
LOG_ERR("clock control device not ready");
return -ENODEV;
}
data->dev = dev;
#if defined(CONFIG_SOC_SERIES_STM32F0X) || \
defined(CONFIG_SOC_SERIES_STM32G0X) || \
defined(CONFIG_SOC_SERIES_STM32L0X)
/*
* All conversion time for all channels on one ADC instance for F0 and
* L0 series chips has to be the same. For STM32G0 currently only one
* of the two available common channel conversion times is used.
* This additional variable is for checking if the conversion time
* selection of all channels on one ADC instance is the same.
*/
data->acq_time_index = -1;
#endif
if (clock_control_on(clk,
(clock_control_subsys_t *) &config->pclken) != 0) {
return -EIO;
}
/* Configure dt provided device signals when available */
err = pinctrl_apply_state(config->pcfg, PINCTRL_STATE_DEFAULT);
if (err < 0) {
LOG_ERR("ADC pinctrl setup failed (%d)", err);
return err;
}
#if defined(CONFIG_SOC_SERIES_STM32U5X)
/* Enable the independent analog supply */
LL_PWR_EnableVDDA();
#endif /* CONFIG_SOC_SERIES_STM32U5X */
#if defined(CONFIG_SOC_SERIES_STM32L4X) || \
defined(CONFIG_SOC_SERIES_STM32L5X) || \
defined(CONFIG_SOC_SERIES_STM32WBX) || \
defined(CONFIG_SOC_SERIES_STM32G4X) || \
defined(CONFIG_SOC_SERIES_STM32H7X) || \
defined(CONFIG_SOC_SERIES_STM32U5X)
/*
* L4, WB, G4, H7 and U5 series STM32 needs to be awaken from deep sleep
* mode, and restore its calibration parameters if there are some
* previously stored calibration parameters.
*/
LL_ADC_DisableDeepPowerDown(adc);
#elif defined(CONFIG_SOC_SERIES_STM32WLX)
/* The ADC clock must be disabled by clock gating during CPU1 sleep/stop */
LL_APB2_GRP1_DisableClockSleep(LL_APB2_GRP1_PERIPH_ADC);
#endif
/*
* F3, L4, WB, G0 and G4 ADC modules need some time
* to be stabilized before performing any enable or calibration actions.
*/
#if defined(STM32F3X_ADC_V1_1) || \
defined(CONFIG_SOC_SERIES_STM32L4X) || \
defined(CONFIG_SOC_SERIES_STM32L5X) || \
defined(CONFIG_SOC_SERIES_STM32WBX) || \
defined(CONFIG_SOC_SERIES_STM32G0X) || \
defined(CONFIG_SOC_SERIES_STM32G4X) || \
defined(CONFIG_SOC_SERIES_STM32H7X) || \
defined(CONFIG_SOC_SERIES_STM32U5X) || \
defined(CONFIG_SOC_SERIES_STM32WLX)
LL_ADC_EnableInternalRegulator(adc);
k_busy_wait(LL_ADC_DELAY_INTERNAL_REGUL_STAB_US);
#endif
#if defined(CONFIG_SOC_SERIES_STM32F0X) || \
defined(CONFIG_SOC_SERIES_STM32L0X) || \
defined(CONFIG_SOC_SERIES_STM32WLX)
LL_ADC_SetClock(adc, LL_ADC_CLOCK_SYNC_PCLK_DIV4);
#elif defined(CONFIG_SOC_SERIES_STM32L4X) || \
defined(CONFIG_SOC_SERIES_STM32L5X) || \
defined(CONFIG_SOC_SERIES_STM32WBX) || \
defined(CONFIG_SOC_SERIES_STM32G0X) || \
defined(CONFIG_SOC_SERIES_STM32G4X) || \
defined(CONFIG_SOC_SERIES_STM32H7X)
LL_ADC_SetCommonClock(__LL_ADC_COMMON_INSTANCE(adc),
LL_ADC_CLOCK_SYNC_PCLK_DIV4);
#elif defined(STM32F3X_ADC_V1_1)
/*
* Set the synchronous clock mode to HCLK/1 (DIV1) or HCLK/2 (DIV2)
* Both are valid common clock setting values.
* The HCLK/1(DIV1) is possible only if
* the ahb-prescaler = <1> in the RCC_CFGR.
*/
LL_ADC_SetCommonClock(__LL_ADC_COMMON_INSTANCE(adc),
LL_ADC_CLOCK_SYNC_PCLK_DIV2);
#elif defined(CONFIG_SOC_SERIES_STM32L1X) || \
defined(CONFIG_SOC_SERIES_STM32U5X)
LL_ADC_SetCommonClock(__LL_ADC_COMMON_INSTANCE(adc),
LL_ADC_CLOCK_ASYNC_DIV4);
#endif
#if !defined(CONFIG_SOC_SERIES_STM32F2X) && \
!defined(CONFIG_SOC_SERIES_STM32F4X) && \
!defined(CONFIG_SOC_SERIES_STM32F7X) && \
!defined(CONFIG_SOC_SERIES_STM32F1X) && \
!defined(STM32F3X_ADC_V2_5) && \
!defined(CONFIG_SOC_SERIES_STM32L1X)
/*
* Calibration of F1 and F3 (ADC1_V2_5) series has to be started
* after ADC Module is enabled.
*/
adc_stm32_calib(dev);
#endif
#if defined(CONFIG_SOC_SERIES_STM32F0X) || \
defined(CONFIG_SOC_SERIES_STM32L0X) || \
defined(CONFIG_SOC_SERIES_STM32L4X) || \
defined(CONFIG_SOC_SERIES_STM32L5X) || \
defined(CONFIG_SOC_SERIES_STM32WBX) || \
defined(CONFIG_SOC_SERIES_STM32G0X) || \
defined(CONFIG_SOC_SERIES_STM32G4X) || \
defined(CONFIG_SOC_SERIES_STM32H7X) || \
defined(CONFIG_SOC_SERIES_STM32U5X) || \
defined(CONFIG_SOC_SERIES_STM32WLX)
if (LL_ADC_IsActiveFlag_ADRDY(adc)) {
LL_ADC_ClearFlag_ADRDY(adc);
}
#endif
#if defined(CONFIG_SOC_SERIES_STM32F0X) || \
defined(STM32F3X_ADC_V1_1) || \
defined(CONFIG_SOC_SERIES_STM32L0X) || \
defined(CONFIG_SOC_SERIES_STM32L4X) || \
defined(CONFIG_SOC_SERIES_STM32L5X) || \
defined(CONFIG_SOC_SERIES_STM32WBX) || \
defined(CONFIG_SOC_SERIES_STM32G0X) || \
defined(CONFIG_SOC_SERIES_STM32G4X) || \
defined(CONFIG_SOC_SERIES_STM32H7X) || \
defined(CONFIG_SOC_SERIES_STM32U5X) || \
defined(CONFIG_SOC_SERIES_STM32WLX)
/*
* ADC modules on these series have to wait for some cycles to be
* enabled.
*/
uint32_t adc_rate, wait_cycles;
if (clock_control_get_rate(clk,
(clock_control_subsys_t *) &config->pclken, &adc_rate) < 0) {
LOG_ERR("ADC clock rate get error.");
}
wait_cycles = SystemCoreClock / adc_rate *
LL_ADC_DELAY_CALIB_ENABLE_ADC_CYCLES;
for (int i = wait_cycles; i >= 0; i--) {
}
#endif
err = adc_stm32_enable(adc);
if (err < 0) {
return err;
}
config->irq_cfg_func();
#if defined(CONFIG_SOC_SERIES_STM32F1X) || \
defined(STM32F3X_ADC_V2_5)
/*
* Calibration of F1 and F3 (ADC1_V2_5) must starts after two cycles
* after ADON is set.
*/
LL_ADC_StartCalibration(adc);
LL_ADC_REG_SetTriggerSource(adc, LL_ADC_REG_TRIG_SOFTWARE);
#endif
#ifdef CONFIG_SOC_SERIES_STM32H7X
/*
* To ensure linearity the factory calibration values
* should be loaded on initialization.
*/
uint32_t channel_offset = 0U;
uint32_t linear_calib_buffer = 0U;
if (adc == ADC1) {
channel_offset = 0UL;
} else if (adc == ADC2) {
channel_offset = 8UL;
} else /*Case ADC3*/ {
channel_offset = 16UL;
}
/* Read factory calibration factors */
for (uint32_t count = 0UL; count < ADC_LINEAR_CALIB_REG_COUNT; count++) {
linear_calib_buffer = *(uint32_t *)(
ADC_LINEAR_CALIB_REG_1_ADDR + channel_offset + count
);
LL_ADC_SetCalibrationLinearFactor(
adc, LL_ADC_CALIB_LINEARITY_WORD1 << count,
linear_calib_buffer
);
}
#endif
adc_context_unlock_unconditionally(&data->ctx);
return 0;
}
static const struct adc_driver_api api_stm32_driver_api = {
.channel_setup = adc_stm32_channel_setup,
.read = adc_stm32_read,
#ifdef CONFIG_ADC_ASYNC
.read_async = adc_stm32_read_async,
#endif
.ref_internal = STM32_ADC_VREF_MV, /* VREF is usually connected to VDD */
};
#ifdef CONFIG_ADC_STM32_SHARED_IRQS
bool adc_stm32_is_irq_active(ADC_TypeDef *adc)
{
#if defined(CONFIG_SOC_SERIES_STM32G4X)
return LL_ADC_IsActiveFlag_EOC(adc) ||
#else
return LL_ADC_IsActiveFlag_EOCS(adc) ||
#endif /* CONFIG_SOC_SERIES_STM32G4X */
LL_ADC_IsActiveFlag_OVR(adc) ||
LL_ADC_IsActiveFlag_JEOS(adc) ||
LL_ADC_IsActiveFlag_AWD1(adc);
}
#define HANDLE_IRQS(index) \
static const struct device *const dev_##index = \
DEVICE_DT_INST_GET(index); \
const struct adc_stm32_cfg *cfg_##index = dev_##index->config; \
ADC_TypeDef *adc_##index = (ADC_TypeDef *)(cfg_##index->base); \
\
if (adc_stm32_is_irq_active(adc_##index)) { \
adc_stm32_isr(dev_##index); \
}
static void adc_stm32_shared_irq_handler(void)
{
DT_INST_FOREACH_STATUS_OKAY(HANDLE_IRQS);
}
static void adc_stm32_irq_init(void)
{
if (init_irq) {
init_irq = false;
IRQ_CONNECT(DT_INST_IRQN(0),
DT_INST_IRQ(0, priority),
adc_stm32_shared_irq_handler, NULL, 0);
irq_enable(DT_INST_IRQN(0));
}
}
#define ADC_STM32_IRQ_CONFIG(index)
#define ADC_STM32_IRQ_FUNC(index) \
.irq_cfg_func = adc_stm32_irq_init, \
#else
#define ADC_STM32_IRQ_CONFIG(index) \
static void adc_stm32_cfg_func_##index(void) \
{ \
IRQ_CONNECT(DT_INST_IRQN(index), \
DT_INST_IRQ(index, priority), \
adc_stm32_isr, DEVICE_DT_INST_GET(index), 0); \
irq_enable(DT_INST_IRQN(index)); \
}
#define ADC_STM32_IRQ_FUNC(index) \
.irq_cfg_func = adc_stm32_cfg_func_##index,
#endif /* CONFIG_ADC_STM32_SHARED_IRQS */
#define ADC_STM32_INIT(index) \
\
PINCTRL_DT_INST_DEFINE(index); \
\
ADC_STM32_IRQ_CONFIG(index) \
\
static const struct adc_stm32_cfg adc_stm32_cfg_##index = { \
.base = (ADC_TypeDef *)DT_INST_REG_ADDR(index), \
ADC_STM32_IRQ_FUNC(index) \
.pclken = { \
.enr = DT_INST_CLOCKS_CELL(index, bits), \
.bus = DT_INST_CLOCKS_CELL(index, bus), \
}, \
.pcfg = PINCTRL_DT_INST_DEV_CONFIG_GET(index), \
.has_temp_channel = DT_INST_PROP(index, has_temp_channel), \
.has_vref_channel = DT_INST_PROP(index, has_vref_channel), \
.has_vbat_channel = DT_INST_PROP(index, has_vbat_channel), \
.temp_channel = DT_INST_PROP_OR(index, temp_channel, 0xFF), \
.vref_channel = DT_INST_PROP_OR(index, vref_channel, 0xFF), \
.vbat_channel = DT_INST_PROP_OR(index, vbat_channel, 0xFF), \
}; \
\
static struct adc_stm32_data adc_stm32_data_##index = { \
ADC_CONTEXT_INIT_TIMER(adc_stm32_data_##index, ctx), \
ADC_CONTEXT_INIT_LOCK(adc_stm32_data_##index, ctx), \
ADC_CONTEXT_INIT_SYNC(adc_stm32_data_##index, ctx), \
}; \
\
DEVICE_DT_INST_DEFINE(index, \
&adc_stm32_init, NULL, \
&adc_stm32_data_##index, &adc_stm32_cfg_##index, \
POST_KERNEL, CONFIG_ADC_INIT_PRIORITY, \
&api_stm32_driver_api);
DT_INST_FOREACH_STATUS_OKAY(ADC_STM32_INIT)