rt-thread/bsp/imxrt/libraries/MIMXRT1170/MIMXRT1176/drivers/fsl_lpadc.c

613 lines
23 KiB
C

/*
* Copyright (c) 2016, Freescale Semiconductor, Inc.
* Copyright 2016-2020 NXP
* All rights reserved.
*
* SPDX-License-Identifier: BSD-3-Clause
*/
#include "fsl_lpadc.h"
/* Component ID definition, used by tools. */
#ifndef FSL_COMPONENT_ID
#define FSL_COMPONENT_ID "platform.drivers.lpadc"
#endif
/*******************************************************************************
* Prototypes
******************************************************************************/
/*!
* @brief Get instance number for LPADC module.
*
* @param base LPADC peripheral base address
*/
static uint32_t LPADC_GetInstance(ADC_Type *base);
/*******************************************************************************
* Variables
******************************************************************************/
/*! @brief Pointers to LPADC bases for each instance. */
static ADC_Type *const s_lpadcBases[] = ADC_BASE_PTRS;
#if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL)
/*! @brief Pointers to LPADC clocks for each instance. */
static const clock_ip_name_t s_lpadcClocks[] = LPADC_CLOCKS;
#endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */
/*******************************************************************************
* Code
******************************************************************************/
static uint32_t LPADC_GetInstance(ADC_Type *base)
{
uint32_t instance;
/* Find the instance index from base address mappings. */
for (instance = 0; instance < ARRAY_SIZE(s_lpadcBases); instance++)
{
if (s_lpadcBases[instance] == base)
{
break;
}
}
assert(instance < ARRAY_SIZE(s_lpadcBases));
return instance;
}
/*!
* brief Initializes the LPADC module.
*
* param base LPADC peripheral base address.
* param config Pointer to configuration structure. See "lpadc_config_t".
*/
void LPADC_Init(ADC_Type *base, const lpadc_config_t *config)
{
/* Check if the pointer is available. */
assert(config != NULL);
uint32_t tmp32 = 0U;
#if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL)
/* Enable the clock for LPADC instance. */
(void)CLOCK_EnableClock(s_lpadcClocks[LPADC_GetInstance(base)]);
#endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */
/* Reset the module. */
LPADC_DoResetConfig(base);
#if (defined(FSL_FEATURE_LPADC_FIFO_COUNT) && (FSL_FEATURE_LPADC_FIFO_COUNT == 2))
LPADC_DoResetFIFO0(base);
LPADC_DoResetFIFO1(base);
#else
LPADC_DoResetFIFO(base);
#endif /* FSL_FEATURE_LPADC_FIFO_COUNT */
/* Disable the module before setting configuration. */
LPADC_Enable(base, false);
/* Configure the module generally. */
if (config->enableInDozeMode)
{
base->CTRL &= ~ADC_CTRL_DOZEN_MASK;
}
else
{
base->CTRL |= ADC_CTRL_DOZEN_MASK;
}
#if defined(FSL_FEATURE_LPADC_HAS_CTRL_CAL_AVGS) && FSL_FEATURE_LPADC_HAS_CTRL_CAL_AVGS
/* Set calibration average mode. */
base->CTRL |= ADC_CTRL_CAL_AVGS(config->conversionAverageMode);
#endif /* FSL_FEATURE_LPADC_HAS_CTRL_CAL_AVGS */
/* ADCx_CFG. */
#if defined(FSL_FEATURE_LPADC_HAS_CFG_ADCKEN) && FSL_FEATURE_LPADC_HAS_CFG_ADCKEN
if (config->enableInternalClock)
{
tmp32 |= ADC_CFG_ADCKEN_MASK;
}
#endif /* FSL_FEATURE_LPADC_HAS_CFG_ADCKEN */
#if defined(FSL_FEATURE_LPADC_HAS_CFG_VREF1RNG) && FSL_FEATURE_LPADC_HAS_CFG_VREF1RNG
if (config->enableVref1LowVoltage)
{
tmp32 |= ADC_CFG_VREF1RNG_MASK;
}
#endif /* FSL_FEATURE_LPADC_HAS_CFG_VREF1RNG */
if (config->enableAnalogPreliminary)
{
tmp32 |= ADC_CFG_PWREN_MASK;
}
tmp32 |= ADC_CFG_PUDLY(config->powerUpDelay) /* Power up delay. */
| ADC_CFG_REFSEL(config->referenceVoltageSource) /* Reference voltage. */
| ADC_CFG_PWRSEL(config->powerLevelMode) /* Power configuration. */
| ADC_CFG_TPRICTRL(config->triggerPriorityPolicy); /* Trigger priority policy. */
base->CFG = tmp32;
/* ADCx_PAUSE. */
if (config->enableConvPause)
{
base->PAUSE = ADC_PAUSE_PAUSEEN_MASK | ADC_PAUSE_PAUSEDLY(config->convPauseDelay);
}
else
{
base->PAUSE = 0U;
}
#if (defined(FSL_FEATURE_LPADC_FIFO_COUNT) && (FSL_FEATURE_LPADC_FIFO_COUNT == 2))
/* ADCx_FCTRL0. */
base->FCTRL[0] = ADC_FCTRL_FWMARK(config->FIFO0Watermark);
/* ADCx_FCTRL1. */
base->FCTRL[1] = ADC_FCTRL_FWMARK(config->FIFO1Watermark);
#else
/* ADCx_FCTRL. */
base->FCTRL = ADC_FCTRL_FWMARK(config->FIFOWatermark);
#endif /* FSL_FEATURE_LPADC_FIFO_COUNT */
/* Enable the module after setting configuration. */
LPADC_Enable(base, true);
}
/*!
* brief Gets an available pre-defined settings for initial configuration.
*
* This function initializes the converter configuration structure with an available settings. The default values are:
* code
* config->enableInDozeMode = true;
* config->conversionAverageMode = kLPADC_ConversionAverage1;
* config->enableAnalogPreliminary = false;
* config->powerUpDelay = 0x80;
* config->referenceVoltageSource = kLPADC_ReferenceVoltageAlt1;
* config->powerLevelMode = kLPADC_PowerLevelAlt1;
* config->triggerPriorityPolicy = kLPADC_TriggerPriorityPreemptImmediately;
* config->enableConvPause = false;
* config->convPauseDelay = 0U;
* config->FIFO0Watermark = 0U;
* config->FIFO1Watermark = 0U;
* config->FIFOWatermark = 0U;
* endcode
* param config Pointer to configuration structure.
*/
void LPADC_GetDefaultConfig(lpadc_config_t *config)
{
/* Initializes the configure structure to zero. */
(void)memset(config, 0, sizeof(*config));
#if defined(FSL_FEATURE_LPADC_HAS_CFG_ADCKEN) && FSL_FEATURE_LPADC_HAS_CFG_ADCKEN
config->enableInternalClock = false;
#endif /* FSL_FEATURE_LPADC_HAS_CFG_ADCKEN */
#if defined(FSL_FEATURE_LPADC_HAS_CFG_VREF1RNG) && FSL_FEATURE_LPADC_HAS_CFG_VREF1RNG
config->enableVref1LowVoltage = false;
#endif /* FSL_FEATURE_LPADC_HAS_CFG_VREF1RNG */
config->enableInDozeMode = true;
#if defined(FSL_FEATURE_LPADC_HAS_CTRL_CAL_AVGS) && FSL_FEATURE_LPADC_HAS_CTRL_CAL_AVGS
/* Set calibration average mode. */
config->conversionAverageMode = kLPADC_ConversionAverage1;
#endif /* FSL_FEATURE_LPADC_HAS_CTRL_CAL_AVGS */
config->enableAnalogPreliminary = false;
config->powerUpDelay = 0x80;
config->referenceVoltageSource = kLPADC_ReferenceVoltageAlt1;
config->powerLevelMode = kLPADC_PowerLevelAlt1;
config->triggerPriorityPolicy = kLPADC_TriggerPriorityPreemptImmediately;
config->enableConvPause = false;
config->convPauseDelay = 0U;
#if (defined(FSL_FEATURE_LPADC_FIFO_COUNT) && (FSL_FEATURE_LPADC_FIFO_COUNT == 2))
config->FIFO0Watermark = 0U;
config->FIFO1Watermark = 0U;
#else
config->FIFOWatermark = 0U;
#endif /* FSL_FEATURE_LPADC_FIFO_COUNT */
}
/*!
* brief De-initializes the LPADC module.
*
* param base LPADC peripheral base address.
*/
void LPADC_Deinit(ADC_Type *base)
{
/* Disable the module. */
LPADC_Enable(base, false);
#if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL)
/* Gate the clock. */
(void)CLOCK_DisableClock(s_lpadcClocks[LPADC_GetInstance(base)]);
#endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */
}
#if (defined(FSL_FEATURE_LPADC_FIFO_COUNT) && (FSL_FEATURE_LPADC_FIFO_COUNT == 2))
/*!
* brief Get the result in conversion FIFOn.
*
* param base LPADC peripheral base address.
* param result Pointer to structure variable that keeps the conversion result in conversion FIFOn.
* param index Result FIFO index.
*
* return Status whether FIFOn entry is valid.
*/
bool LPADC_GetConvResult(ADC_Type *base, lpadc_conv_result_t *result, uint8_t index)
{
assert(result != NULL); /* Check if the input pointer is available. */
uint32_t tmp32;
tmp32 = base->RESFIFO[index];
if (0U == (ADC_RESFIFO_VALID_MASK & tmp32))
{
return false; /* FIFO is empty. Discard any read from RESFIFO. */
}
result->commandIdSource = (tmp32 & ADC_RESFIFO_CMDSRC_MASK) >> ADC_RESFIFO_CMDSRC_SHIFT;
result->loopCountIndex = (tmp32 & ADC_RESFIFO_LOOPCNT_MASK) >> ADC_RESFIFO_LOOPCNT_SHIFT;
result->triggerIdSource = (tmp32 & ADC_RESFIFO_TSRC_MASK) >> ADC_RESFIFO_TSRC_SHIFT;
result->convValue = (uint16_t)(tmp32 & ADC_RESFIFO_D_MASK);
return true;
}
#else
/*!
* brief Get the result in conversion FIFO.
*
* param base LPADC peripheral base address.
* param result Pointer to structure variable that keeps the conversion result in conversion FIFO.
*
* return Status whether FIFO entry is valid.
*/
bool LPADC_GetConvResult(ADC_Type *base, lpadc_conv_result_t *result)
{
assert(result != NULL); /* Check if the input pointer is available. */
uint32_t tmp32;
tmp32 = base->RESFIFO;
if (0U == (ADC_RESFIFO_VALID_MASK & tmp32))
{
return false; /* FIFO is empty. Discard any read from RESFIFO. */
}
result->commandIdSource = (tmp32 & ADC_RESFIFO_CMDSRC_MASK) >> ADC_RESFIFO_CMDSRC_SHIFT;
result->loopCountIndex = (tmp32 & ADC_RESFIFO_LOOPCNT_MASK) >> ADC_RESFIFO_LOOPCNT_SHIFT;
result->triggerIdSource = (tmp32 & ADC_RESFIFO_TSRC_MASK) >> ADC_RESFIFO_TSRC_SHIFT;
result->convValue = (uint16_t)(tmp32 & ADC_RESFIFO_D_MASK);
return true;
}
#endif /* FSL_FEATURE_LPADC_FIFO_COUNT */
/*!
* brief Configure the conversion trigger source.
*
* Each programmable trigger can launch the conversion command in command buffer.
*
* param base LPADC peripheral base address.
* param triggerId ID for each trigger. Typically, the available value range is from 0.
* param config Pointer to configuration structure. See to #lpadc_conv_trigger_config_t.
*/
void LPADC_SetConvTriggerConfig(ADC_Type *base, uint32_t triggerId, const lpadc_conv_trigger_config_t *config)
{
assert(triggerId < ADC_TCTRL_COUNT); /* Check if the triggerId is available in this device. */
assert(config != NULL); /* Check if the input pointer is available. */
uint32_t tmp32;
tmp32 = ADC_TCTRL_TCMD(config->targetCommandId) /* Trigger command select. */
| ADC_TCTRL_TDLY(config->delayPower) /* Trigger delay select. */
| ADC_TCTRL_TPRI(config->priority) /* Trigger priority setting. */
#if (defined(FSL_FEATURE_LPADC_FIFO_COUNT) && (FSL_FEATURE_LPADC_FIFO_COUNT == 2))
| ADC_TCTRL_FIFO_SEL_A(config->channelAFIFOSelect)
#if !(defined(FSL_FEATURE_LPADC_HAS_NO_TCTRL_FIFO_SEL_B) && FSL_FEATURE_LPADC_HAS_NO_TCTRL_FIFO_SEL_B)
| ADC_TCTRL_FIFO_SEL_B(config->channelBFIFOSelect)
#endif /* FSL_FEATURE_LPADC_HAS_NO_TCTRL_FIFO_SEL_B */
#endif /* FSL_FEATURE_LPADC_FIFO_COUNT */
;
if (config->enableHardwareTrigger)
{
tmp32 |= ADC_TCTRL_HTEN_MASK;
}
base->TCTRL[triggerId] = tmp32;
}
/*!
* brief Gets an available pre-defined settings for trigger's configuration.
*
* This function initializes the trigger's configuration structure with an available settings. The default values are:
* code
* config->commandIdSource = 0U;
* config->loopCountIndex = 0U;
* config->triggerIdSource = 0U;
* config->enableHardwareTrigger = false;
* config->channelAFIFOSelect = 0U;
* config->channelBFIFOSelect = 0U;
* endcode
* param config Pointer to configuration structure.
*/
void LPADC_GetDefaultConvTriggerConfig(lpadc_conv_trigger_config_t *config)
{
assert(config != NULL); /* Check if the input pointer is available. */
/* Initializes the configure structure to zero. */
(void)memset(config, 0, sizeof(*config));
config->targetCommandId = 0U;
config->delayPower = 0U;
config->priority = 0U;
#if (defined(FSL_FEATURE_LPADC_FIFO_COUNT) && (FSL_FEATURE_LPADC_FIFO_COUNT == 2))
config->channelAFIFOSelect = 0U;
config->channelBFIFOSelect = 0U;
#endif /* FSL_FEATURE_LPADC_FIFO_COUNT */
config->enableHardwareTrigger = false;
}
/*!
* brief Configure conversion command.
*
* param base LPADC peripheral base address.
* param commandId ID for command in command buffer. Typically, the available value range is 1 - 15.
* param config Pointer to configuration structure. See to #lpadc_conv_command_config_t.
*/
void LPADC_SetConvCommandConfig(ADC_Type *base, uint32_t commandId, const lpadc_conv_command_config_t *config)
{
assert(commandId < (ADC_CMDL_COUNT + 1U)); /* Check if the commandId is available on this device. */
assert(config != NULL); /* Check if the input pointer is available. */
uint32_t tmp32 = 0;
commandId--; /* The available command number are 1-15, while the index of register group are 0-14. */
/* ADCx_CMDL. */
tmp32 = ADC_CMDL_ADCH(config->channelNumber); /* Channel number. */
#if defined(FSL_FEATURE_LPADC_HAS_CMDL_CSCALE) && FSL_FEATURE_LPADC_HAS_CMDL_CSCALE
tmp32 |= ADC_CMDL_CSCALE(config->sampleScaleMode); /* Full/Part scale input voltage. */
#endif /* FSL_FEATURE_LPADC_HAS_CMDL_CSCALE */
#if defined(FSL_FEATURE_LPADC_HAS_CMDL_CTYPE) && FSL_FEATURE_LPADC_HAS_CMDL_CTYPE
tmp32 |= ADC_CMDL_CTYPE(config->sampleChannelMode);
#else
switch (config->sampleChannelMode) /* Sample input. */
{
case kLPADC_SampleChannelSingleEndSideB:
tmp32 |= ADC_CMDL_ABSEL_MASK;
break;
#if defined(FSL_FEATURE_LPADC_HAS_CMDL_DIFF) && FSL_FEATURE_LPADC_HAS_CMDL_DIFF
case kLPADC_SampleChannelDiffBothSideAB:
tmp32 |= ADC_CMDL_DIFF_MASK;
break;
case kLPADC_SampleChannelDiffBothSideBA:
tmp32 |= ADC_CMDL_ABSEL_MASK | ADC_CMDL_DIFF_MASK;
break;
#endif /* FSL_FEATURE_LPADC_HAS_CMDL_DIFF */
default: /* kLPADC_SampleChannelSingleEndSideA. */
break;
}
#endif /* FSL_FEATURE_LPADC_HAS_CMDL_CTYPE */
#if defined(FSL_FEATURE_LPADC_HAS_CMDL_MODE) && FSL_FEATURE_LPADC_HAS_CMDL_MODE
tmp32 |= ADC_CMDL_MODE(config->conversionResolutionMode);
#endif /* FSL_FEATURE_LPADC_HAS_CMDL_MODE */
base->CMD[commandId].CMDL = tmp32;
/* ADCx_CMDH. */
tmp32 = ADC_CMDH_NEXT(config->chainedNextCommandNumber) /* Next Command Select. */
| ADC_CMDH_LOOP(config->loopCount) /* Loop Count Select. */
| ADC_CMDH_AVGS(config->hardwareAverageMode) /* Hardware Average Select. */
| ADC_CMDH_STS(config->sampleTimeMode) /* Sample Time Select. */
| ADC_CMDH_CMPEN(config->hardwareCompareMode); /* Hardware compare enable. */
#if (defined(FSL_FEATURE_LPADC_HAS_CMDH_WAIT_TRIG) && FSL_FEATURE_LPADC_HAS_CMDH_WAIT_TRIG)
if (config->enableWaitTrigger)
{
tmp32 |= ADC_CMDH_WAIT_TRIG_MASK; /* Wait trigger enable. */
}
#endif /* FSL_FEATURE_LPADC_HAS_CMDH_WAIT_TRIG */
if (config->enableAutoChannelIncrement)
{
tmp32 |= ADC_CMDH_LWI_MASK;
}
base->CMD[commandId].CMDH = tmp32;
/* Hardware compare settings.
* Not all Command Buffers have an associated Compare Value register. The compare function is only available on
* Command Buffers that have a corresponding Compare Value register.
*/
if (kLPADC_HardwareCompareDisabled != config->hardwareCompareMode)
{
/* Check if the hardware compare feature is available for indicated command buffer. */
assert(commandId < ADC_CV_COUNT);
/* Set CV register. */
base->CV[commandId] = ADC_CV_CVH(config->hardwareCompareValueHigh) /* Compare value high. */
| ADC_CV_CVL(config->hardwareCompareValueLow); /* Compare value low. */
}
}
/*!
* brief Gets an available pre-defined settings for conversion command's configuration.
*
* This function initializes the conversion command's configuration structure with an available settings. The default
* values are:
* code
* config->sampleScaleMode = kLPADC_SampleFullScale;
* config->channelSampleMode = kLPADC_SampleChannelSingleEndSideA;
* config->channelNumber = 0U;
* config->chainedNextCmdNumber = 0U;
* config->enableAutoChannelIncrement = false;
* config->loopCount = 0U;
* config->hardwareAverageMode = kLPADC_HardwareAverageCount1;
* config->sampleTimeMode = kLPADC_SampleTimeADCK3;
* config->hardwareCompareMode = kLPADC_HardwareCompareDisabled;
* config->hardwareCompareValueHigh = 0U;
* config->hardwareCompareValueLow = 0U;
* config->conversionResolutionMode = kLPADC_ConversionResolutionStandard;
* config->enableWaitTrigger = false;
* endcode
* param config Pointer to configuration structure.
*/
void LPADC_GetDefaultConvCommandConfig(lpadc_conv_command_config_t *config)
{
assert(config != NULL); /* Check if the input pointer is available. */
/* Initializes the configure structure to zero. */
(void)memset(config, 0, sizeof(*config));
#if defined(FSL_FEATURE_LPADC_HAS_CMDL_CSCALE) && FSL_FEATURE_LPADC_HAS_CMDL_CSCALE
config->sampleScaleMode = kLPADC_SampleFullScale;
#endif /* FSL_FEATURE_LPADC_HAS_CMDL_CSCALE */
config->sampleChannelMode = kLPADC_SampleChannelSingleEndSideA;
config->channelNumber = 0U;
config->chainedNextCommandNumber = 0U; /* No next command defined. */
config->enableAutoChannelIncrement = false;
config->loopCount = 0U;
config->hardwareAverageMode = kLPADC_HardwareAverageCount1;
config->sampleTimeMode = kLPADC_SampleTimeADCK3;
config->hardwareCompareMode = kLPADC_HardwareCompareDisabled;
config->hardwareCompareValueHigh = 0U; /* No used. */
config->hardwareCompareValueLow = 0U; /* No used. */
#if defined(FSL_FEATURE_LPADC_HAS_CMDL_MODE) && FSL_FEATURE_LPADC_HAS_CMDL_MODE
config->conversionResolutionMode = kLPADC_ConversionResolutionStandard;
#endif /* FSL_FEATURE_LPADC_HAS_CMDL_MODE */
#if defined(FSL_FEATURE_LPADC_HAS_CMDH_WAIT_TRIG) && FSL_FEATURE_LPADC_HAS_CMDH_WAIT_TRIG
config->enableWaitTrigger = false;
#endif /* FSL_FEATURE_LPADC_HAS_CMDH_WAIT_TRIG */
}
#if defined(FSL_FEATURE_LPADC_HAS_CFG_CALOFS) && FSL_FEATURE_LPADC_HAS_CFG_CALOFS
/*!
* brief Enable the calibration function.
*
* When CALOFS is set, the ADC is configured to perform a calibration function anytime the ADC executes
* a conversion. Any channel selected is ignored and the value returned in the RESFIFO is a signed value
* between -31 and 31. -32 is not a valid and is never a returned value. Software should copy the lower 6-
* bits of the conversion result stored in the RESFIFO after a completed calibration conversion to the
* OFSTRIM field. The OFSTRIM field is used in normal operation for offset correction.
*
* param base LPADC peripheral base address.
* param enable switcher to the calibration function.
*/
void LPADC_EnableCalibration(ADC_Type *base, bool enable)
{
LPADC_Enable(base, false);
if (enable)
{
base->CFG |= ADC_CFG_CALOFS_MASK;
}
else
{
base->CFG &= ~ADC_CFG_CALOFS_MASK;
}
LPADC_Enable(base, true);
}
#if defined(FSL_FEATURE_LPADC_HAS_OFSTRIM) && FSL_FEATURE_LPADC_HAS_OFSTRIM
/*!
* brief Do auto calibration.
*
* Calibration function should be executed before using converter in application. It used the software trigger and a
* dummy conversion, get the offset and write them into the OFSTRIM register. It called some of functional API
* including: -LPADC_EnableCalibration(...) -LPADC_LPADC_SetOffsetValue(...) -LPADC_SetConvCommandConfig(...)
* -LPADC_SetConvTriggerConfig(...)
*
* param base LPADC peripheral base address.
*/
void LPADC_DoAutoCalibration(ADC_Type *base)
{
assert(0u == LPADC_GetConvResultCount(base));
uint32_t mLpadcCMDL;
uint32_t mLpadcCMDH;
uint32_t mLpadcTrigger;
lpadc_conv_trigger_config_t mLpadcTriggerConfigStruct;
lpadc_conv_command_config_t mLpadcCommandConfigStruct;
lpadc_conv_result_t mLpadcResultConfigStruct;
/* Enable the calibration function. */
LPADC_EnableCalibration(base, true);
/* Keep the CMD and TRG state here and restore it later if the calibration completes.*/
mLpadcCMDL = base->CMD[0].CMDL; /* CMD1L. */
mLpadcCMDH = base->CMD[0].CMDH; /* CMD1H. */
mLpadcTrigger = base->TCTRL[0]; /* Trigger0. */
/* Set trigger0 configuration - for software trigger. */
LPADC_GetDefaultConvTriggerConfig(&mLpadcTriggerConfigStruct);
mLpadcTriggerConfigStruct.targetCommandId = 1U; /* CMD1 is executed. */
LPADC_SetConvTriggerConfig(base, 0U, &mLpadcTriggerConfigStruct); /* Configurate the trigger0. */
/* Set conversion CMD configuration. */
LPADC_GetDefaultConvCommandConfig(&mLpadcCommandConfigStruct);
mLpadcCommandConfigStruct.hardwareAverageMode = kLPADC_HardwareAverageCount128;
LPADC_SetConvCommandConfig(base, 1U, &mLpadcCommandConfigStruct); /* Set CMD1 configuration. */
/* Do calibration. */
LPADC_DoSoftwareTrigger(base, 1U); /* 1U is trigger0 mask. */
while (!LPADC_GetConvResult(base, &mLpadcResultConfigStruct))
{
}
/* The valid bits of data are bits 14:3 in the RESFIFO register. */
LPADC_SetOffsetValue(base, (uint32_t)(mLpadcResultConfigStruct.convValue) >> 3UL);
/* Disable the calibration function. */
LPADC_EnableCalibration(base, false);
/* restore CMD and TRG registers. */
base->CMD[0].CMDL = mLpadcCMDL; /* CMD1L. */
base->CMD[0].CMDH = mLpadcCMDH; /* CMD1H. */
base->TCTRL[0] = mLpadcTrigger; /* Trigger0. */
}
#endif /* FSL_FEATURE_LPADC_HAS_OFSTRIM */
#endif /* FSL_FEATURE_LPADC_HAS_CFG_CALOFS */
#if defined(FSL_FEATURE_LPADC_HAS_CTRL_CALOFS) && FSL_FEATURE_LPADC_HAS_CTRL_CALOFS
/*!
* brief Do offset calibration.
*
* param base LPADC peripheral base address.
*/
void LPADC_DoOffsetCalibration(ADC_Type *base)
{
LPADC_EnableOffsetCalibration(base, true);
while (ADC_STAT_CAL_RDY_MASK != (base->STAT & ADC_STAT_CAL_RDY_MASK))
{
}
}
#if defined(FSL_FEATURE_LPADC_HAS_CTRL_CAL_REQ) && FSL_FEATURE_LPADC_HAS_CTRL_CAL_REQ
/*!
* brief Do auto calibration.
*
* param base LPADC peripheral base address.
*/
void LPADC_DoAutoCalibration(ADC_Type *base)
{
assert((0u == LPADC_GetConvResultCount(base, 0)) && (0u == LPADC_GetConvResultCount(base, 1)));
uint32_t GCCa;
uint32_t GCCb;
uint32_t GCRa;
uint32_t GCRb;
/* Request gain calibration. */
base->CTRL |= ADC_CTRL_CAL_REQ_MASK;
while ((ADC_GCC_RDY_MASK != (base->GCC[0] & ADC_GCC_RDY_MASK)) ||
(ADC_GCC_RDY_MASK != (base->GCC[1] & ADC_GCC_RDY_MASK)))
{
}
/* Calculate gain offset. */
GCCa = (base->GCC[0] & ADC_GCC_GAIN_CAL_MASK);
GCCb = (base->GCC[1] & ADC_GCC_GAIN_CAL_MASK);
GCRa = (uint16_t)((GCCa << 16U) /
(0x1FFFFU - GCCa)); /* Gain_CalA = (131072 / (131072-(ADC_GCC_GAIN_CAL(ADC0->GCC[0])) - 1. */
GCRb = (uint16_t)((GCCb << 16U) /
(0x1FFFFU - GCCb)); /* Gain_CalB = (131072 / (131072-(ADC_GCC_GAIN_CAL(ADC0->GCC[1])) - 1. */
base->GCR[0] = ADC_GCR_GCALR(GCRa);
base->GCR[1] = ADC_GCR_GCALR(GCRb);
/* Indicate the values are valid. */
base->GCR[0] |= ADC_GCR_RDY_MASK;
base->GCR[1] |= ADC_GCR_RDY_MASK;
while (ADC_STAT_CAL_RDY_MASK != (base->STAT & ADC_STAT_CAL_RDY_MASK))
{
}
}
#endif /* FSL_FEATURE_LPADC_HAS_CTRL_CAL_REQ */
#endif /* FSL_FEATURE_LPADC_HAS_CFG_CALOFS */