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[freertos] / FreeRTOS / Demo / CORTEX_EFM32_Gecko_Starter_Kit_Simplicity_Studio / Source / SilLabs_Code / emlib / inc / em_adc.h

/***************************************************************************//**\r
 * @file em_adc.h\r
 * @brief Analog to Digital Converter (ADC) peripheral API\r
 * @version 4.0.0\r
 *******************************************************************************\r
 * @section License\r
 * <b>(C) Copyright 2014 Silicon Labs, http://www.silabs.com</b>\r
 *******************************************************************************\r
 *\r
 * Permission is granted to anyone to use this software for any purpose,\r
 * including commercial applications, and to alter it and redistribute it\r
 * freely, subject to the following restrictions:\r
 *\r
 * 1. The origin of this software must not be misrepresented; you must not\r
 *    claim that you wrote the original software.\r
 * 2. Altered source versions must be plainly marked as such, and must not be\r
 *    misrepresented as being the original software.\r
 * 3. This notice may not be removed or altered from any source distribution.\r
 *\r
 * DISCLAIMER OF WARRANTY/LIMITATION OF REMEDIES: Silicon Labs has no\r
 * obligation to support this Software. Silicon Labs is providing the\r
 * Software "AS IS", with no express or implied warranties of any kind,\r
 * including, but not limited to, any implied warranties of merchantability\r
 * or fitness for any particular purpose or warranties against infringement\r
 * of any proprietary rights of a third party.\r
 *\r
 * Silicon Labs will not be liable for any consequential, incidental, or\r
 * special damages, or any other relief, or for any claim by any third party,\r
 * arising from your use of this Software.\r
 *\r
 ******************************************************************************/\r
\r
\r
#ifndef __SILICON_LABS_EM_ADC_H_\r
#define __SILICON_LABS_EM_ADC_H_\r
\r
#include "em_device.h"\r
#if defined(ADC_COUNT) && (ADC_COUNT > 0)\r
\r
#include <stdbool.h>\r
\r
#ifdef __cplusplus\r
extern "C" {\r
#endif\r
\r
/***************************************************************************//**\r
 * @addtogroup EM_Library\r
 * @{\r
 ******************************************************************************/\r
\r
/***************************************************************************//**\r
 * @addtogroup ADC\r
 * @{\r
 ******************************************************************************/\r
\r
/*******************************************************************************\r
 ********************************   ENUMS   ************************************\r
 ******************************************************************************/\r
\r
/** Acquisition time (in ADC clock cycles). */\r
typedef enum\r
{\r
  adcAcqTime1   = _ADC_SINGLECTRL_AT_1CYCLE,    /**< 1 clock cycle. */\r
  adcAcqTime2   = _ADC_SINGLECTRL_AT_2CYCLES,   /**< 2 clock cycles. */\r
  adcAcqTime4   = _ADC_SINGLECTRL_AT_4CYCLES,   /**< 4 clock cycles. */\r
  adcAcqTime8   = _ADC_SINGLECTRL_AT_8CYCLES,   /**< 8 clock cycles. */\r
  adcAcqTime16  = _ADC_SINGLECTRL_AT_16CYCLES,  /**< 16 clock cycles. */\r
  adcAcqTime32  = _ADC_SINGLECTRL_AT_32CYCLES,  /**< 32 clock cycles. */\r
  adcAcqTime64  = _ADC_SINGLECTRL_AT_64CYCLES,  /**< 64 clock cycles. */\r
  adcAcqTime128 = _ADC_SINGLECTRL_AT_128CYCLES, /**< 128 clock cycles. */\r
  adcAcqTime256 = _ADC_SINGLECTRL_AT_256CYCLES  /**< 256 clock cycles. */\r
} ADC_AcqTime_TypeDef;\r
\r
\r
/** Lowpass filter mode. */\r
typedef enum\r
{\r
  /** No filter or decoupling capacitor. */\r
  adcLPFilterBypass = _ADC_CTRL_LPFMODE_BYPASS,\r
\r
  /** On-chip RC filter. */\r
  adcLPFilterRC     = _ADC_CTRL_LPFMODE_RCFILT,\r
\r
  /** On-chip decoupling capacitor. */\r
  adcLPFilterDeCap  = _ADC_CTRL_LPFMODE_DECAP\r
} ADC_LPFilter_TypeDef;\r
\r
\r
/** Oversample rate select. */\r
typedef enum\r
{\r
  /** 2 samples per conversion result. */\r
  adcOvsRateSel2    = _ADC_CTRL_OVSRSEL_X2,\r
\r
  /** 4 samples per conversion result. */\r
  adcOvsRateSel4    = _ADC_CTRL_OVSRSEL_X4,\r
\r
  /** 8 samples per conversion result. */\r
  adcOvsRateSel8    = _ADC_CTRL_OVSRSEL_X8,\r
\r
  /** 16 samples per conversion result. */\r
  adcOvsRateSel16   = _ADC_CTRL_OVSRSEL_X16,\r
\r
  /** 32 samples per conversion result. */\r
  adcOvsRateSel32   = _ADC_CTRL_OVSRSEL_X32,\r
\r
  /** 64 samples per conversion result. */\r
  adcOvsRateSel64   = _ADC_CTRL_OVSRSEL_X64,\r
\r
  /** 128 samples per conversion result. */\r
  adcOvsRateSel128  = _ADC_CTRL_OVSRSEL_X128,\r
\r
  /** 256 samples per conversion result. */\r
  adcOvsRateSel256  = _ADC_CTRL_OVSRSEL_X256,\r
\r
  /** 512 samples per conversion result. */\r
  adcOvsRateSel512  = _ADC_CTRL_OVSRSEL_X512,\r
\r
  /** 1024 samples per conversion result. */\r
  adcOvsRateSel1024 = _ADC_CTRL_OVSRSEL_X1024,\r
\r
  /** 2048 samples per conversion result. */\r
  adcOvsRateSel2048 = _ADC_CTRL_OVSRSEL_X2048,\r
\r
  /** 4096 samples per conversion result. */\r
  adcOvsRateSel4096 = _ADC_CTRL_OVSRSEL_X4096\r
} ADC_OvsRateSel_TypeDef;\r
\r
\r
/** Peripheral Reflex System signal used to trigger single sample. */\r
typedef enum\r
{\r
  adcPRSSELCh0 = _ADC_SINGLECTRL_PRSSEL_PRSCH0, /**< PRS channel 0. */\r
  adcPRSSELCh1 = _ADC_SINGLECTRL_PRSSEL_PRSCH1, /**< PRS channel 1. */\r
  adcPRSSELCh2 = _ADC_SINGLECTRL_PRSSEL_PRSCH2, /**< PRS channel 2. */\r
  adcPRSSELCh3 = _ADC_SINGLECTRL_PRSSEL_PRSCH3, /**< PRS channel 3. */\r
#if defined( _ADC_SINGLECTRL_PRSSEL_PRSCH4 )\r
  adcPRSSELCh4 = _ADC_SINGLECTRL_PRSSEL_PRSCH4, /**< PRS channel 4. */\r
#endif\r
#if defined( _ADC_SINGLECTRL_PRSSEL_PRSCH5 )\r
  adcPRSSELCh5 = _ADC_SINGLECTRL_PRSSEL_PRSCH5, /**< PRS channel 5. */\r
#endif\r
#if defined( _ADC_SINGLECTRL_PRSSEL_PRSCH6 )\r
  adcPRSSELCh6 = _ADC_SINGLECTRL_PRSSEL_PRSCH6, /**< PRS channel 6. */\r
#endif\r
#if defined( _ADC_SINGLECTRL_PRSSEL_PRSCH7 )\r
  adcPRSSELCh7 = _ADC_SINGLECTRL_PRSSEL_PRSCH7, /**< PRS channel 7. */\r
#endif\r
#if defined( _ADC_SINGLECTRL_PRSSEL_PRSCH8 )\r
  adcPRSSELCh8 = _ADC_SINGLECTRL_PRSSEL_PRSCH8, /**< PRS channel 8. */\r
#endif\r
#if defined( _ADC_SINGLECTRL_PRSSEL_PRSCH9 )\r
  adcPRSSELCh9 = _ADC_SINGLECTRL_PRSSEL_PRSCH9, /**< PRS channel 9. */\r
#endif\r
#if defined( _ADC_SINGLECTRL_PRSSEL_PRSCH10 )\r
  adcPRSSELCh10 = _ADC_SINGLECTRL_PRSSEL_PRSCH10, /**< PRS channel 10. */\r
#endif\r
#if defined( _ADC_SINGLECTRL_PRSSEL_PRSCH11 )\r
  adcPRSSELCh11 = _ADC_SINGLECTRL_PRSSEL_PRSCH11, /**< PRS channel 11. */\r
#endif\r
} ADC_PRSSEL_TypeDef;\r
\r
\r
/** Reference to ADC sample. */\r
typedef enum\r
{\r
  /** Internal 1.25V reference. */\r
  adcRef1V25      = _ADC_SINGLECTRL_REF_1V25,\r
\r
  /** Internal 2.5V reference. */\r
  adcRef2V5       = _ADC_SINGLECTRL_REF_2V5,\r
\r
  /** Buffered VDD. */\r
  adcRefVDD       = _ADC_SINGLECTRL_REF_VDD,\r
\r
  /** Internal differential 5V reference. */\r
  adcRef5VDIFF    = _ADC_SINGLECTRL_REF_5VDIFF,\r
\r
  /** Single ended ext. ref. from pin 6. */\r
  adcRefExtSingle = _ADC_SINGLECTRL_REF_EXTSINGLE,\r
\r
  /** Differential ext. ref. from pin 6 and 7. */\r
  adcRef2xExtDiff = _ADC_SINGLECTRL_REF_2XEXTDIFF,\r
\r
  /** Unbuffered 2xVDD. */\r
  adcRef2xVDD     = _ADC_SINGLECTRL_REF_2XVDD\r
} ADC_Ref_TypeDef;\r
\r
\r
/** Sample resolution. */\r
typedef enum\r
{\r
  adcRes12Bit = _ADC_SINGLECTRL_RES_12BIT, /**< 12 bit sampling. */\r
  adcRes8Bit  = _ADC_SINGLECTRL_RES_8BIT,  /**< 8 bit sampling. */\r
  adcRes6Bit  = _ADC_SINGLECTRL_RES_6BIT,  /**< 6 bit sampling. */\r
  adcResOVS   = _ADC_SINGLECTRL_RES_OVS    /**< Oversampling. */\r
} ADC_Res_TypeDef;\r
\r
\r
/** Single sample input selection. */\r
typedef enum\r
{\r
  /* Differential mode disabled */\r
  adcSingleInpCh0      = _ADC_SINGLECTRL_INPUTSEL_CH0,      /**< Channel 0. */\r
  adcSingleInpCh1      = _ADC_SINGLECTRL_INPUTSEL_CH1,      /**< Channel 1. */\r
  adcSingleInpCh2      = _ADC_SINGLECTRL_INPUTSEL_CH2,      /**< Channel 2. */\r
  adcSingleInpCh3      = _ADC_SINGLECTRL_INPUTSEL_CH3,      /**< Channel 3. */\r
  adcSingleInpCh4      = _ADC_SINGLECTRL_INPUTSEL_CH4,      /**< Channel 4. */\r
  adcSingleInpCh5      = _ADC_SINGLECTRL_INPUTSEL_CH5,      /**< Channel 5. */\r
  adcSingleInpCh6      = _ADC_SINGLECTRL_INPUTSEL_CH6,      /**< Channel 6. */\r
  adcSingleInpCh7      = _ADC_SINGLECTRL_INPUTSEL_CH7,      /**< Channel 7. */\r
  adcSingleInpTemp     = _ADC_SINGLECTRL_INPUTSEL_TEMP,     /**< Temperature reference. */\r
  adcSingleInpVDDDiv3  = _ADC_SINGLECTRL_INPUTSEL_VDDDIV3,  /**< VDD divided by 3. */\r
  adcSingleInpVDD      = _ADC_SINGLECTRL_INPUTSEL_VDD,      /**< VDD. */\r
  adcSingleInpVSS      = _ADC_SINGLECTRL_INPUTSEL_VSS,      /**< VSS. */\r
  adcSingleInpVrefDiv2 = _ADC_SINGLECTRL_INPUTSEL_VREFDIV2, /**< Vref divided by 2. */\r
  adcSingleInpDACOut0  = _ADC_SINGLECTRL_INPUTSEL_DAC0OUT0, /**< DAC output 0. */\r
  adcSingleInpDACOut1  = _ADC_SINGLECTRL_INPUTSEL_DAC0OUT1, /**< DAC output 1. */\r
  /* TBD: Use define when available */\r
  adcSingleInpATEST    = 15,                                /**< ATEST. */\r
\r
  /* Differential mode enabled */\r
  adcSingleInpCh0Ch1   = _ADC_SINGLECTRL_INPUTSEL_CH0CH1,   /**< Positive Ch0, negative Ch1. */\r
  adcSingleInpCh2Ch3   = _ADC_SINGLECTRL_INPUTSEL_CH2CH3,   /**< Positive Ch2, negative Ch3. */\r
  adcSingleInpCh4Ch5   = _ADC_SINGLECTRL_INPUTSEL_CH4CH5,   /**< Positive Ch4, negative Ch5. */\r
  adcSingleInpCh6Ch7   = _ADC_SINGLECTRL_INPUTSEL_CH6CH7,   /**< Positive Ch6, negative Ch7. */\r
  /* TBD: Use define when available */\r
  adcSingleInpDiff0    = 4                                  /**< Differential 0. */\r
} ADC_SingleInput_TypeDef;\r
\r
\r
/** ADC Start command. */\r
typedef enum\r
{\r
  /** Start single conversion. */\r
  adcStartSingle        = ADC_CMD_SINGLESTART,\r
\r
  /** Start scan sequence. */\r
  adcStartScan          = ADC_CMD_SCANSTART,\r
\r
  /**\r
   * Start scan sequence and single conversion, typically used when tailgating\r
   * single conversion after scan sequence.\r
   */\r
  adcStartScanAndSingle = ADC_CMD_SCANSTART | ADC_CMD_SINGLESTART\r
} ADC_Start_TypeDef;\r
\r
\r
/** Warm-up mode. */\r
typedef enum\r
{\r
  /** ADC shutdown after each conversion. */\r
  adcWarmupNormal          = _ADC_CTRL_WARMUPMODE_NORMAL,\r
\r
  /** Do not warm-up bandgap references. */\r
  adcWarmupFastBG          = _ADC_CTRL_WARMUPMODE_FASTBG,\r
\r
  /** Reference selected for scan mode kept warm.*/\r
  adcWarmupKeepScanRefWarm = _ADC_CTRL_WARMUPMODE_KEEPSCANREFWARM,\r
\r
  /** ADC and reference selected for scan mode kept warm.*/\r
  adcWarmupKeepADCWarm     = _ADC_CTRL_WARMUPMODE_KEEPADCWARM\r
} ADC_Warmup_TypeDef;\r
\r
\r
/*******************************************************************************\r
 *******************************   STRUCTS   ***********************************\r
 ******************************************************************************/\r
\r
/** ADC init structure, common for single conversion and scan sequence. */\r
typedef struct\r
{\r
  /**\r
   * Oversampling rate select. In order to have any effect, oversampling must\r
   * be enabled for single/scan mode.\r
   */\r
  ADC_OvsRateSel_TypeDef ovsRateSel;\r
\r
  /** Lowpass or decoupling capacitor filter to use. */\r
  ADC_LPFilter_TypeDef   lpfMode;\r
\r
  /** Warm-up mode to use for ADC. */\r
  ADC_Warmup_TypeDef     warmUpMode;\r
\r
  /**\r
   * Timebase used for ADC warm up. Select N to give (N+1)HFPERCLK cycles.\r
   * (Additional delay is added for bandgap references, please refer to the\r
   * reference manual.) Normally, N should be selected so that the timebase\r
   * is at least 1 us. See ADC_TimebaseCalc() for a way to obtain\r
   * a suggested timebase of at least 1 us.\r
   */\r
  uint8_t                timebase;\r
\r
  /** Clock division factor N, ADC clock =  HFPERCLK / (N + 1). */\r
  uint8_t                prescale;\r
\r
  /** Enable/disable conversion tailgating. */\r
  bool                   tailgate;\r
} ADC_Init_TypeDef;\r
\r
/** Default config for ADC init structure. */\r
#define ADC_INIT_DEFAULT                                                     \\r
  { adcOvsRateSel2,                /* 2x oversampling (if enabled). */       \\r
    adcLPFilterBypass,             /* No input filter selected. */           \\r
    adcWarmupNormal,               /* ADC shutdown after each conversion. */ \\r
    _ADC_CTRL_TIMEBASE_DEFAULT,    /* Use HW default value. */               \\r
    _ADC_CTRL_PRESC_DEFAULT,       /* Use HW default value. */               \\r
    false                          /* Do not use tailgate. */                \\r
  }\r
\r
\r
/** Scan sequence init structure. */\r
typedef struct\r
{\r
  /**\r
   * Peripheral reflex system trigger selection. Only applicable if @p prsEnable\r
   * is enabled.\r
   */\r
  ADC_PRSSEL_TypeDef  prsSel;\r
\r
  /** Acquisition time (in ADC clock cycles). */\r
  ADC_AcqTime_TypeDef acqTime;\r
\r
  /**\r
   * Sample reference selection. Notice that for external references, the\r
   * ADC calibration register must be set explicitly.\r
   */\r
  ADC_Ref_TypeDef     reference;\r
\r
  /** Sample resolution. */\r
  ADC_Res_TypeDef     resolution;\r
\r
  /**\r
   * Input scan selection. If single ended (@p diff is false), use logical\r
   * combination of ADC_SCANCTRL_INPUTMASK_CHx defines. If differential input\r
   * (@p diff is true), use logical combination of ADC_SCANCTRL_INPUTMASK_CHxCHy\r
   * defines. (Notice underscore prefix for defines used.)\r
   */\r
  uint32_t            input;\r
\r
  /** Select if single ended or differential input. */\r
  bool                diff;\r
\r
  /** Peripheral reflex system trigger enable. */\r
  bool                prsEnable;\r
\r
  /** Select if left adjustment should be done. */\r
  bool                leftAdjust;\r
\r
  /** Select if continuous conversion until explicit stop. */\r
  bool                rep;\r
} ADC_InitScan_TypeDef;\r
\r
/** Default config for ADC scan init structure. */\r
#define ADC_INITSCAN_DEFAULT                                                        \\r
  { adcPRSSELCh0,              /* PRS ch0 (if enabled). */                          \\r
    adcAcqTime1,               /* 1 ADC_CLK cycle acquisition time. */              \\r
    adcRef1V25,                /* 1.25V internal reference. */                      \\r
    adcRes12Bit,               /* 12 bit resolution. */                             \\r
    0,                         /* No input selected. */                             \\r
    false,                     /* Single ended input. */                            \\r
    false,                     /* PRS disabled. */                                  \\r
    false,                     /* Right adjust. */                                  \\r
    false                      /* Deactivate conversion after one scan sequence. */ \\r
  }\r
\r
\r
/** Single conversion init structure. */\r
typedef struct\r
{\r
  /**\r
   * Peripheral reflex system trigger selection. Only applicable if @p prsEnable\r
   * is enabled.\r
   */\r
  ADC_PRSSEL_TypeDef      prsSel;\r
\r
  /** Acquisition time (in ADC clock cycles). */\r
  ADC_AcqTime_TypeDef     acqTime;\r
\r
  /**\r
   * Sample reference selection. Notice that for external references, the\r
   * ADC calibration register must be set explicitly.\r
   */\r
  ADC_Ref_TypeDef         reference;\r
\r
  /** Sample resolution. */\r
  ADC_Res_TypeDef         resolution;\r
\r
  /**\r
   * Sample input selection, use single ended or differential input according\r
   * to setting of @p diff.\r
   */\r
  ADC_SingleInput_TypeDef input;\r
\r
  /** Select if single ended or differential input. */\r
  bool                    diff;\r
\r
  /** Peripheral reflex system trigger enable. */\r
  bool                    prsEnable;\r
\r
  /** Select if left adjustment should be done. */\r
  bool                    leftAdjust;\r
\r
  /** Select if continuous conversion until explicit stop. */\r
  bool                    rep;\r
} ADC_InitSingle_TypeDef;\r
\r
/** Default config for ADC single conversion init structure. */\r
#define ADC_INITSINGLE_DEFAULT                                                      \\r
  { adcPRSSELCh0,              /* PRS ch0 (if enabled). */                          \\r
    adcAcqTime1,               /* 1 ADC_CLK cycle acquisition time. */              \\r
    adcRef1V25,                /* 1.25V internal reference. */                      \\r
    adcRes12Bit,               /* 12 bit resolution. */                             \\r
    adcSingleInpCh0,           /* CH0 input selected. */                            \\r
    false,                     /* Single ended input. */                            \\r
    false,                     /* PRS disabled. */                                  \\r
    false,                     /* Right adjust. */                                  \\r
    false                      /* Deactivate conversion after one scan sequence. */ \\r
  }\r
\r
\r
/*******************************************************************************\r
 *****************************   PROTOTYPES   **********************************\r
 ******************************************************************************/\r
\r
/***************************************************************************//**\r
 * @brief\r
 *   Get single conversion result.\r
 *\r
 * @note\r
 *   Do only use if single conversion data valid.\r
 *\r
 * @param[in] adc\r
 *   Pointer to ADC peripheral register block.\r
 *\r
 * @return\r
 *\r
 ******************************************************************************/\r
__STATIC_INLINE uint32_t ADC_DataSingleGet(ADC_TypeDef *adc)\r
{\r
  return(adc->SINGLEDATA);\r
}\r
\r
\r
/***************************************************************************//**\r
 * @brief\r
 *   Get scan result.\r
 *\r
 * @note\r
 *   Do only use if scan data valid.\r
 *\r
 * @param[in] adc\r
 *   Pointer to ADC peripheral register block.\r
 ******************************************************************************/\r
__STATIC_INLINE uint32_t ADC_DataScanGet(ADC_TypeDef *adc)\r
{\r
  return(adc->SCANDATA);\r
}\r
\r
\r
void ADC_Init(ADC_TypeDef *adc, const ADC_Init_TypeDef *init);\r
void ADC_InitScan(ADC_TypeDef *adc, const ADC_InitScan_TypeDef *init);\r
void ADC_InitSingle(ADC_TypeDef *adc, const ADC_InitSingle_TypeDef *init);\r
\r
/***************************************************************************//**\r
 * @brief\r
 *   Clear one or more pending ADC interrupts.\r
 *\r
 * @param[in] adc\r
 *   Pointer to ADC peripheral register block.\r
 *\r
 * @param[in] flags\r
 *   Pending ADC interrupt source to clear. Use a bitwise logic OR combination\r
 *   of valid interrupt flags for the ADC module (ADC_IF_nnn).\r
 ******************************************************************************/\r
__STATIC_INLINE void ADC_IntClear(ADC_TypeDef *adc, uint32_t flags)\r
{\r
  adc->IFC = flags;\r
}\r
\r
\r
/***************************************************************************//**\r
 * @brief\r
 *   Disable one or more ADC interrupts.\r
 *\r
 * @param[in] adc\r
 *   Pointer to ADC peripheral register block.\r
 *\r
 * @param[in] flags\r
 *   ADC interrupt sources to disable. Use a bitwise logic OR combination of\r
 *   valid interrupt flags for the ADC module (ADC_IF_nnn).\r
 ******************************************************************************/\r
__STATIC_INLINE void ADC_IntDisable(ADC_TypeDef *adc, uint32_t flags)\r
{\r
  adc->IEN &= ~(flags);\r
}\r
\r
\r
/***************************************************************************//**\r
 * @brief\r
 *   Enable one or more ADC interrupts.\r
 *\r
 * @note\r
 *   Depending on the use, a pending interrupt may already be set prior to\r
 *   enabling the interrupt. Consider using ADC_IntClear() prior to enabling\r
 *   if such a pending interrupt should be ignored.\r
 *\r
 * @param[in] adc\r
 *   Pointer to ADC peripheral register block.\r
 *\r
 * @param[in] flags\r
 *   ADC interrupt sources to enable. Use a bitwise logic OR combination of\r
 *   valid interrupt flags for the ADC module (ADC_IF_nnn).\r
 ******************************************************************************/\r
__STATIC_INLINE void ADC_IntEnable(ADC_TypeDef *adc, uint32_t flags)\r
{\r
  adc->IEN |= flags;\r
}\r
\r
\r
/***************************************************************************//**\r
 * @brief\r
 *   Get pending ADC interrupt flags.\r
 *\r
 * @note\r
 *   The event bits are not cleared by the use of this function.\r
 *\r
 * @param[in] adc\r
 *   Pointer to ADC peripheral register block.\r
 *\r
 * @return\r
 *   ADC interrupt sources pending. A bitwise logic OR combination of valid\r
 *   interrupt flags for the ADC module (ADC_IF_nnn).\r
 ******************************************************************************/\r
__STATIC_INLINE uint32_t ADC_IntGet(ADC_TypeDef *adc)\r
{\r
  return(adc->IF);\r
}\r
\r
\r
/***************************************************************************//**\r
 * @brief\r
 *   Set one or more pending ADC interrupts from SW.\r
 *\r
 * @param[in] adc\r
 *   Pointer to ADC peripheral register block.\r
 *\r
 * @param[in] flags\r
 *   ADC interrupt sources to set to pending. Use a bitwise logic OR combination\r
 *   of valid interrupt flags for the ADC module (ADC_IF_nnn).\r
 ******************************************************************************/\r
__STATIC_INLINE void ADC_IntSet(ADC_TypeDef *adc, uint32_t flags)\r
{\r
  adc->IFS = flags;\r
}\r
\r
uint8_t ADC_PrescaleCalc(uint32_t adcFreq, uint32_t hfperFreq);\r
\r
\r
/***************************************************************************//**\r
 * @brief\r
 *   Start scan sequence and/or single conversion.\r
 *\r
 * @param[in] adc\r
 *   Pointer to ADC peripheral register block.\r
 *\r
 * @param[in] cmd\r
 *   Command indicating which type of sampling to start.\r
 ******************************************************************************/\r
__STATIC_INLINE void ADC_Start(ADC_TypeDef *adc, ADC_Start_TypeDef cmd)\r
{\r
  adc->CMD = (uint32_t)cmd;\r
}\r
\r
void ADC_Reset(ADC_TypeDef *adc);\r
uint8_t ADC_TimebaseCalc(uint32_t hfperFreq);\r
\r
/** @} (end addtogroup ADC) */\r
/** @} (end addtogroup EM_Library) */\r
\r
#ifdef __cplusplus\r
}\r
#endif\r
\r
#endif /* defined(ADC_COUNT) && (ADC_COUNT > 0) */\r
#endif /* __SILICON_LABS_EM_ADC_H_ */\r