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TARGET_EFM32ZG_STK3200/TARGET_Silicon_Labs/TARGET_EFM32/emlib/inc/em_cmu.h
- Committer:
- Kojto
- Date:
- 2015-04-29
- Revision:
- 98:8ab26030e058
- Child:
- 113:f141b2784e32
File content as of revision 98:8ab26030e058:
/***************************************************************************//**
* @file em_cmu.h
* @brief Clock management unit (CMU) API
* @version 3.20.12
*******************************************************************************
* @section License
* <b>(C) Copyright 2014 Silicon Labs, http://www.silabs.com</b>
*******************************************************************************
*
* Permission is granted to anyone to use this software for any purpose,
* including commercial applications, and to alter it and redistribute it
* freely, subject to the following restrictions:
*
* 1. The origin of this software must not be misrepresented; you must not
* claim that you wrote the original software.
* 2. Altered source versions must be plainly marked as such, and must not be
* misrepresented as being the original software.
* 3. This notice may not be removed or altered from any source distribution.
*
* DISCLAIMER OF WARRANTY/LIMITATION OF REMEDIES: Silicon Labs has no
* obligation to support this Software. Silicon Labs is providing the
* Software "AS IS", with no express or implied warranties of any kind,
* including, but not limited to, any implied warranties of merchantability
* or fitness for any particular purpose or warranties against infringement
* of any proprietary rights of a third party.
*
* Silicon Labs will not be liable for any consequential, incidental, or
* special damages, or any other relief, or for any claim by any third party,
* arising from your use of this Software.
*
******************************************************************************/
#ifndef __SILICON_LABS_EM_CMU_H_
#define __SILICON_LABS_EM_CMU_H_
#include "em_device.h"
#if defined( CMU_PRESENT )
#include <stdbool.h>
#include "em_bitband.h"
#ifdef __cplusplus
extern "C" {
#endif
/***************************************************************************//**
* @addtogroup EM_Library
* @{
******************************************************************************/
/***************************************************************************//**
* @addtogroup CMU
* @{
******************************************************************************/
/** @cond DO_NOT_INCLUDE_WITH_DOXYGEN */
/* Select register ids, for internal use */
#define CMU_NOSEL_REG 0
#define CMU_HFCLKSEL_REG 1
#define CMU_LFACLKSEL_REG 2
#define CMU_LFBCLKSEL_REG 3
#define CMU_DBGCLKSEL_REG 4
#if defined( _CMU_CMD_USBCCLKSEL_MASK )
#define CMU_USBCCLKSEL_REG 5
#endif
#if defined( _CMU_LFCLKSEL_LFC_MASK )
#define CMU_LFCCLKSEL_REG 6
#endif
#define CMU_SEL_REG_POS 0
#define CMU_SEL_REG_MASK 0xf
/* Divisor register ids, for internal use */
#define CMU_NODIV_REG 0
#define CMU_HFPERCLKDIV_REG 1
#define CMU_HFCORECLKDIV_REG 2
#define CMU_LFAPRESC0_REG 3
#define CMU_LFBPRESC0_REG 4
#if defined( _CMU_CTRL_HFCLKDIV_MASK )
#define CMU_HFCLKDIV_REG 5
#endif
#define CMU_DIV_REG_POS 4
#define CMU_DIV_REG_MASK 0xf
/* Enable register ids, for internal use */
#define CMU_NO_EN_REG 0
#define CMU_HFPERCLKDIV_EN_REG 1
#define CMU_HFPERCLKEN0_EN_REG 2
#define CMU_HFCORECLKEN0_EN_REG 3
#define CMU_LFACLKEN0_EN_REG 4
#define CMU_LFBCLKEN0_EN_REG 5
#define CMU_PCNT_EN_REG 6
#if defined( _CMU_LFCCLKEN0_MASK )
#define CMU_LFCCLKEN0_EN_REG 7
#endif
#define CMU_EN_REG_POS 8
#define CMU_EN_REG_MASK 0xf
/* Enable register bit position, for internal use */
#define CMU_EN_BIT_POS 12
#define CMU_EN_BIT_MASK 0x1f
/* Clock branch bitfield position, for internal use */
#define CMU_HF_CLK_BRANCH 0
#define CMU_HFPER_CLK_BRANCH 1
#define CMU_HFCORE_CLK_BRANCH 2
#define CMU_LFA_CLK_BRANCH 3
#define CMU_RTC_CLK_BRANCH 4
#define CMU_LETIMER_CLK_BRANCH 5
#define CMU_LCDPRE_CLK_BRANCH 6
#define CMU_LCD_CLK_BRANCH 7
#define CMU_LESENSE_CLK_BRANCH 8
#define CMU_LFB_CLK_BRANCH 9
#define CMU_LEUART0_CLK_BRANCH 10
#define CMU_LEUART1_CLK_BRANCH 11
#define CMU_DBG_CLK_BRANCH 12
#define CMU_AUX_CLK_BRANCH 13
#define CMU_USBC_CLK_BRANCH 14
#define CMU_LFC_CLK_BRANCH 15
#define CMU_USBLE_CLK_BRANCH 16
#define CMU_CLK_BRANCH_POS 17
#define CMU_CLK_BRANCH_MASK 0x1f
/** @endcond */
/*******************************************************************************
******************************** ENUMS ************************************
******************************************************************************/
/** Clock divisors. These values are valid for prescalers. */
#define cmuClkDiv_1 1 /**< Divide clock by 1. */
#define cmuClkDiv_2 2 /**< Divide clock by 2. */
#define cmuClkDiv_4 4 /**< Divide clock by 4. */
#define cmuClkDiv_8 8 /**< Divide clock by 8. */
#define cmuClkDiv_16 16 /**< Divide clock by 16. */
#define cmuClkDiv_32 32 /**< Divide clock by 32. */
#define cmuClkDiv_64 64 /**< Divide clock by 64. */
#define cmuClkDiv_128 128 /**< Divide clock by 128. */
#define cmuClkDiv_256 256 /**< Divide clock by 256. */
#define cmuClkDiv_512 512 /**< Divide clock by 512. */
#define cmuClkDiv_1024 1024 /**< Divide clock by 1024. */
#define cmuClkDiv_2048 2048 /**< Divide clock by 2048. */
#define cmuClkDiv_4096 4096 /**< Divide clock by 4096. */
#define cmuClkDiv_8192 8192 /**< Divide clock by 8192. */
#define cmuClkDiv_16384 16384 /**< Divide clock by 16384. */
#define cmuClkDiv_32768 32768 /**< Divide clock by 32768. */
/** Clock divider configuration */
typedef uint32_t CMU_ClkDiv_TypeDef;
/** High frequency RC bands. */
typedef enum
{
/** 1MHz RC band. */
cmuHFRCOBand_1MHz = _CMU_HFRCOCTRL_BAND_1MHZ,
/** 7MHz RC band. */
cmuHFRCOBand_7MHz = _CMU_HFRCOCTRL_BAND_7MHZ,
/** 11MHz RC band. */
cmuHFRCOBand_11MHz = _CMU_HFRCOCTRL_BAND_11MHZ,
/** 14MHz RC band. */
cmuHFRCOBand_14MHz = _CMU_HFRCOCTRL_BAND_14MHZ,
/** 21MHz RC band. */
cmuHFRCOBand_21MHz = _CMU_HFRCOCTRL_BAND_21MHZ,
#if defined( _CMU_HFRCOCTRL_BAND_28MHZ )
/** 28MHz RC band. */
cmuHFRCOBand_28MHz = _CMU_HFRCOCTRL_BAND_28MHZ
#endif
} CMU_HFRCOBand_TypeDef;
#if defined( _CMU_AUXHFRCOCTRL_BAND_MASK )
/** AUX High frequency RC bands. */
typedef enum
{
/** 1MHz RC band. */
cmuAUXHFRCOBand_1MHz = _CMU_AUXHFRCOCTRL_BAND_1MHZ,
/** 7MHz RC band. */
cmuAUXHFRCOBand_7MHz = _CMU_AUXHFRCOCTRL_BAND_7MHZ,
/** 11MHz RC band. */
cmuAUXHFRCOBand_11MHz = _CMU_AUXHFRCOCTRL_BAND_11MHZ,
/** 14MHz RC band. */
cmuAUXHFRCOBand_14MHz = _CMU_AUXHFRCOCTRL_BAND_14MHZ,
/** 21MHz RC band. */
cmuAUXHFRCOBand_21MHz = _CMU_AUXHFRCOCTRL_BAND_21MHZ,
#if defined( _CMU_AUXHFRCOCTRL_BAND_28MHZ )
/** 28MHz RC band. */
cmuAUXHFRCOBand_28MHz = _CMU_AUXHFRCOCTRL_BAND_28MHZ
#endif
} CMU_AUXHFRCOBand_TypeDef;
#endif
#if defined( _CMU_USHFRCOCONF_BAND_MASK )
/** USB High frequency RC bands. */
typedef enum
{
/** 24MHz RC band. */
cmuUSHFRCOBand_24MHz = _CMU_USHFRCOCONF_BAND_24MHZ,
/** 48MHz RC band. */
cmuUSHFRCOBand_48MHz = _CMU_USHFRCOCONF_BAND_48MHZ,
} CMU_USHFRCOBand_TypeDef;
#endif
/** Clock points in CMU. Please refer to CMU overview in reference manual. */
typedef enum
{
/*******************/
/* HF clock branch */
/*******************/
/** High frequency clock */
#if defined( _CMU_CTRL_HFCLKDIV_MASK )
cmuClock_HF = (CMU_HFCLKDIV_REG << CMU_DIV_REG_POS) |
(CMU_HFCLKSEL_REG << CMU_SEL_REG_POS) |
(CMU_NO_EN_REG << CMU_EN_REG_POS) |
(0 << CMU_EN_BIT_POS) |
(CMU_HF_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#else
cmuClock_HF = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_HFCLKSEL_REG << CMU_SEL_REG_POS) |
(CMU_NO_EN_REG << CMU_EN_REG_POS) |
(0 << CMU_EN_BIT_POS) |
(CMU_HF_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
/** Debug clock */
cmuClock_DBG = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_DBGCLKSEL_REG << CMU_SEL_REG_POS) |
(CMU_NO_EN_REG << CMU_EN_REG_POS) |
(0 << CMU_EN_BIT_POS) |
(CMU_DBG_CLK_BRANCH << CMU_CLK_BRANCH_POS),
/** AUX clock */
cmuClock_AUX = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_NO_EN_REG << CMU_EN_REG_POS) |
(0 << CMU_EN_BIT_POS) |
(CMU_AUX_CLK_BRANCH << CMU_CLK_BRANCH_POS),
/**********************************/
/* HF peripheral clock sub-branch */
/**********************************/
/** High frequency peripheral clock */
cmuClock_HFPER = (CMU_HFPERCLKDIV_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_HFPERCLKDIV_EN_REG << CMU_EN_REG_POS) |
(_CMU_HFPERCLKDIV_HFPERCLKEN_SHIFT << CMU_EN_BIT_POS) |
(CMU_HFPER_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#if defined(_CMU_HFPERCLKEN0_USART0_MASK)
/** Universal sync/async receiver/transmitter 0 clock. */
cmuClock_USART0 = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_HFPERCLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_HFPERCLKEN0_USART0_SHIFT << CMU_EN_BIT_POS) |
(CMU_HFPER_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
#if defined(_CMU_HFPERCLKEN0_USARTRF0_MASK)
/** Universal sync/async receiver/transmitter 0 clock. */
cmuClock_USARTRF0 = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_HFPERCLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_HFPERCLKEN0_USARTRF0_SHIFT << CMU_EN_BIT_POS) |
(CMU_HFPER_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
#if defined(_CMU_HFPERCLKEN0_USART1_MASK)
/** Universal sync/async receiver/transmitter 1 clock. */
cmuClock_USART1 = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_HFPERCLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_HFPERCLKEN0_USART1_SHIFT << CMU_EN_BIT_POS) |
(CMU_HFPER_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
#if defined(_CMU_HFPERCLKEN0_USART2_MASK)
/** Universal sync/async receiver/transmitter 2 clock. */
cmuClock_USART2 = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_HFPERCLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_HFPERCLKEN0_USART2_SHIFT << CMU_EN_BIT_POS) |
(CMU_HFPER_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
#if defined(_CMU_HFPERCLKEN0_UART0_MASK)
/** Universal async receiver/transmitter 0 clock. */
cmuClock_UART0 = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_HFPERCLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_HFPERCLKEN0_UART0_SHIFT << CMU_EN_BIT_POS) |
(CMU_HFPER_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
#if defined(_CMU_HFPERCLKEN0_UART1_MASK)
/** Universal async receiver/transmitter 1 clock. */
cmuClock_UART1 = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_HFPERCLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_HFPERCLKEN0_UART1_SHIFT << CMU_EN_BIT_POS) |
(CMU_HFPER_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
#if defined(_CMU_HFPERCLKEN0_TIMER0_MASK)
/** Timer 0 clock. */
cmuClock_TIMER0 = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_HFPERCLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_HFPERCLKEN0_TIMER0_SHIFT << CMU_EN_BIT_POS) |
(CMU_HFPER_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
#if defined(_CMU_HFPERCLKEN0_TIMER1_MASK)
/** Timer 1 clock. */
cmuClock_TIMER1 = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_HFPERCLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_HFPERCLKEN0_TIMER1_SHIFT << CMU_EN_BIT_POS) |
(CMU_HFPER_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
#if defined(_CMU_HFPERCLKEN0_TIMER2_MASK)
/** Timer 2 clock. */
cmuClock_TIMER2 = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_HFPERCLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_HFPERCLKEN0_TIMER2_SHIFT << CMU_EN_BIT_POS) |
(CMU_HFPER_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
#if defined(_CMU_HFPERCLKEN0_TIMER3_MASK)
/** Timer 3 clock. */
cmuClock_TIMER3 = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_HFPERCLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_HFPERCLKEN0_TIMER3_SHIFT << CMU_EN_BIT_POS) |
(CMU_HFPER_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
#if defined(_CMU_HFPERCLKEN0_ACMP0_MASK)
/** Analog comparator 0 clock. */
cmuClock_ACMP0 = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_HFPERCLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_HFPERCLKEN0_ACMP0_SHIFT << CMU_EN_BIT_POS) |
(CMU_HFPER_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
#if defined(_CMU_HFPERCLKEN0_ACMP1_MASK)
/** Analog comparator 1 clock. */
cmuClock_ACMP1 = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_HFPERCLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_HFPERCLKEN0_ACMP1_SHIFT << CMU_EN_BIT_POS) |
(CMU_HFPER_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
#if defined(_CMU_HFPERCLKEN0_PRS_MASK)
/** Peripheral reflex system clock. */
cmuClock_PRS = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_HFPERCLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_HFPERCLKEN0_PRS_SHIFT << CMU_EN_BIT_POS) |
(CMU_HFPER_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
#if defined(_CMU_HFPERCLKEN0_DAC0_MASK)
/** Digital to analog converter 0 clock. */
cmuClock_DAC0 = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_HFPERCLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_HFPERCLKEN0_DAC0_SHIFT << CMU_EN_BIT_POS) |
(CMU_HFPER_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
#if defined(_CMU_HFPERCLKEN0_IDAC0_MASK)
/** Digital to analog converter 0 clock. */
cmuClock_IDAC0 = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_HFPERCLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_HFPERCLKEN0_IDAC0_SHIFT << CMU_EN_BIT_POS) |
(CMU_HFPER_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
#if defined(GPIO_PRESENT)
/** General purpose input/output clock. */
cmuClock_GPIO = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_HFPERCLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_HFPERCLKEN0_GPIO_SHIFT << CMU_EN_BIT_POS) |
(CMU_HFPER_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
#if defined(VCMP_PRESENT)
/** Voltage comparator clock. */
cmuClock_VCMP = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_HFPERCLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_HFPERCLKEN0_VCMP_SHIFT << CMU_EN_BIT_POS) |
(CMU_HFPER_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
#if defined(_CMU_HFPERCLKEN0_ADC0_MASK)
/** Analog to digital converter 0 clock. */
cmuClock_ADC0 = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_HFPERCLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_HFPERCLKEN0_ADC0_SHIFT << CMU_EN_BIT_POS) |
(CMU_HFPER_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
#if defined(_CMU_HFPERCLKEN0_I2C0_MASK)
/** I2C 0 clock. */
cmuClock_I2C0 = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_HFPERCLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_HFPERCLKEN0_I2C0_SHIFT << CMU_EN_BIT_POS) |
(CMU_HFPER_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
#if defined(_CMU_HFPERCLKEN0_I2C1_MASK)
/** I2C 1 clock. */
cmuClock_I2C1 = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_HFPERCLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_HFPERCLKEN0_I2C1_SHIFT << CMU_EN_BIT_POS) |
(CMU_HFPER_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
/**********************/
/* HF core sub-branch */
/**********************/
/** Core clock */
cmuClock_CORE = (CMU_HFCORECLKDIV_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_NO_EN_REG << CMU_EN_REG_POS) |
(0 << CMU_EN_BIT_POS) |
(CMU_HFCORE_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#if defined(AES_PRESENT)
/** Advanced encryption standard accelerator clock. */
cmuClock_AES = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_HFCORECLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_HFCORECLKEN0_AES_SHIFT << CMU_EN_BIT_POS) |
(CMU_HFCORE_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
#if defined(DMA_PRESENT)
/** Direct memory access controller clock. */
cmuClock_DMA = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_HFCORECLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_HFCORECLKEN0_DMA_SHIFT << CMU_EN_BIT_POS) |
(CMU_HFCORE_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
/** Low energy clocking module clock. */
cmuClock_CORELE = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_HFCORECLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_HFCORECLKEN0_LE_SHIFT << CMU_EN_BIT_POS) |
(CMU_HFCORE_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#if defined(EBI_PRESENT)
/** External bus interface clock. */
cmuClock_EBI = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_HFCORECLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_HFCORECLKEN0_EBI_SHIFT << CMU_EN_BIT_POS) |
(CMU_HFCORE_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
#if defined(USB_PRESENT)
/** USB Core clock. */
cmuClock_USBC = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_USBCCLKSEL_REG << CMU_SEL_REG_POS) |
(CMU_HFCORECLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_HFCORECLKEN0_USBC_SHIFT << CMU_EN_BIT_POS) |
(CMU_USBC_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
#if defined(USB_PRESENT)
/** USB clock. */
cmuClock_USB = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_HFCORECLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_HFCORECLKEN0_USB_SHIFT << CMU_EN_BIT_POS) |
(CMU_HFCORE_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
/***************/
/* LF A branch */
/***************/
/** Low frequency A clock */
cmuClock_LFA = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_LFACLKSEL_REG << CMU_SEL_REG_POS) |
(CMU_NO_EN_REG << CMU_EN_REG_POS) |
(0 << CMU_EN_BIT_POS) |
(CMU_LFA_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#if defined(RTC_PRESENT)
/** Real time counter clock. */
cmuClock_RTC = (CMU_LFAPRESC0_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_LFACLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_LFACLKEN0_RTC_SHIFT << CMU_EN_BIT_POS) |
(CMU_RTC_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
#if defined(_CMU_LFACLKEN0_LETIMER0_MASK)
/** Low energy timer 0 clock. */
cmuClock_LETIMER0 = (CMU_LFAPRESC0_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_LFACLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_LFACLKEN0_LETIMER0_SHIFT << CMU_EN_BIT_POS) |
(CMU_LETIMER_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
#if defined(_CMU_LFACLKEN0_LCD_MASK)
/** Liquid crystal display, pre FDIV clock. */
cmuClock_LCDpre = (CMU_LFAPRESC0_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_NO_EN_REG << CMU_EN_REG_POS) |
(0 << CMU_EN_BIT_POS) |
(CMU_LCDPRE_CLK_BRANCH << CMU_CLK_BRANCH_POS),
/** Liquid crystal display clock. Please notice that FDIV prescaler
* must be set by special API. */
cmuClock_LCD = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_LFACLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_LFACLKEN0_LCD_SHIFT << CMU_EN_BIT_POS) |
(CMU_LCD_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
#if defined(_CMU_PCNTCTRL_PCNT0CLKEN_MASK)
/** Pulse counter 0 clock. */
cmuClock_PCNT0 = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_PCNT_EN_REG << CMU_EN_REG_POS) |
(_CMU_PCNTCTRL_PCNT0CLKEN_SHIFT << CMU_EN_BIT_POS) |
(CMU_LFA_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
#if defined(_CMU_PCNTCTRL_PCNT1CLKEN_MASK)
/** Pulse counter 1 clock. */
cmuClock_PCNT1 = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_PCNT_EN_REG << CMU_EN_REG_POS) |
(_CMU_PCNTCTRL_PCNT1CLKEN_SHIFT << CMU_EN_BIT_POS) |
(CMU_LFA_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
#if defined(_CMU_PCNTCTRL_PCNT2CLKEN_MASK)
/** Pulse counter 2 clock. */
cmuClock_PCNT2 = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_PCNT_EN_REG << CMU_EN_REG_POS) |
(_CMU_PCNTCTRL_PCNT2CLKEN_SHIFT << CMU_EN_BIT_POS) |
(CMU_LFA_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
#if defined(_CMU_LFACLKEN0_LESENSE_MASK)
/** LESENSE clock. */
cmuClock_LESENSE = (CMU_LFAPRESC0_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_LFACLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_LFACLKEN0_LESENSE_SHIFT << CMU_EN_BIT_POS) |
(CMU_LESENSE_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
/***************/
/* LF B branch */
/***************/
/** Low frequency B clock */
cmuClock_LFB = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_LFBCLKSEL_REG << CMU_SEL_REG_POS) |
(CMU_NO_EN_REG << CMU_EN_REG_POS) |
(0 << CMU_EN_BIT_POS) |
(CMU_LFB_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#if defined(_CMU_LFBCLKEN0_LEUART0_MASK)
/** Low energy universal asynchronous receiver/transmitter 0 clock. */
cmuClock_LEUART0 = (CMU_LFBPRESC0_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_LFBCLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_LFBCLKEN0_LEUART0_SHIFT << CMU_EN_BIT_POS) |
(CMU_LEUART0_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
#if defined(_CMU_LFBCLKEN0_LEUART1_MASK)
/** Low energy universal asynchronous receiver/transmitter 1 clock. */
cmuClock_LEUART1 = (CMU_LFBPRESC0_REG << CMU_DIV_REG_POS) |
(CMU_NOSEL_REG << CMU_SEL_REG_POS) |
(CMU_LFBCLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_LFBCLKEN0_LEUART1_SHIFT << CMU_EN_BIT_POS) |
(CMU_LEUART1_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
/***************/
/* LF C branch */
/***************/
/** Low frequency C clock */
#if defined( _CMU_LFCLKSEL_LFC_MASK )
cmuClock_LFC = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_LFCCLKSEL_REG << CMU_SEL_REG_POS) |
(CMU_NO_EN_REG << CMU_EN_REG_POS) |
(0 << CMU_EN_BIT_POS) |
(CMU_LFC_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
#if defined(_CMU_LFCCLKEN0_USBLE_MASK)
/** USB LE clock. */
cmuClock_USBLE = (CMU_NODIV_REG << CMU_DIV_REG_POS) |
(CMU_LFCCLKSEL_REG << CMU_SEL_REG_POS) |
(CMU_LFCCLKEN0_EN_REG << CMU_EN_REG_POS) |
(_CMU_LFCCLKEN0_USBLE_SHIFT << CMU_EN_BIT_POS) |
(CMU_USBLE_CLK_BRANCH << CMU_CLK_BRANCH_POS),
#endif
} CMU_Clock_TypeDef;
/** Oscillator types. */
typedef enum
{
cmuOsc_LFXO, /**< Low frequency crystal oscillator. */
cmuOsc_LFRCO, /**< Low frequency RC oscillator. */
cmuOsc_HFXO, /**< High frequency crystal oscillator. */
cmuOsc_HFRCO, /**< High frequency RC oscillator. */
cmuOsc_AUXHFRCO, /**< Auxiliary high frequency RC oscillator. */
#if defined( _CMU_STATUS_USHFRCOENS_MASK )
cmuOsc_USHFRCO, /**< USB high frequency RC oscillator */
#endif
#if defined( _CMU_LFCLKSEL_LFAE_ULFRCO )
cmuOsc_ULFRCO /**< Ultra low frequency RC oscillator. */
#endif
} CMU_Osc_TypeDef;
/** Selectable clock sources. */
typedef enum
{
cmuSelect_Error, /**< Usage error. */
cmuSelect_Disabled, /**< Clock selector disabled. */
cmuSelect_LFXO, /**< Low frequency crystal oscillator. */
cmuSelect_LFRCO, /**< Low frequency RC oscillator. */
cmuSelect_HFXO, /**< High frequency crystal oscillator. */
cmuSelect_HFRCO, /**< High frequency RC oscillator. */
cmuSelect_CORELEDIV2, /**< Core low energy clock divided by 2. */
cmuSelect_AUXHFRCO, /**< Auxilliary clock source can be used for debug clock */
cmuSelect_HFCLK, /**< Divided HFCLK on Giant for debug clock, undivided on Tiny Gecko and for USBC (not used on Gecko) */
#if defined( _CMU_STATUS_USHFRCOENS_MASK )
cmuSelect_USHFRCO, /**< USB high frequency RC oscillator */
#endif
#if defined( _CMU_CMD_HFCLKSEL_USHFRCODIV2 )
cmuSelect_USHFRCODIV2,/**< USB high frequency RC oscillator */
#endif
#if defined( _CMU_LFCLKSEL_LFAE_ULFRCO )
cmuSelect_ULFRCO, /**< Ultra low frequency RC oscillator. */
#endif
} CMU_Select_TypeDef;
/*******************************************************************************
***************************** PROTOTYPES **********************************
******************************************************************************/
void CMU_ClockEnable(CMU_Clock_TypeDef clock, bool enable);
uint32_t CMU_ClockFreqGet(CMU_Clock_TypeDef clock);
CMU_ClkDiv_TypeDef CMU_ClockDivGet(CMU_Clock_TypeDef clock);
CMU_Select_TypeDef CMU_ClockSelectGet(CMU_Clock_TypeDef clock);
void CMU_ClockDivSet(CMU_Clock_TypeDef clock, CMU_ClkDiv_TypeDef div);
void CMU_ClockSelectSet(CMU_Clock_TypeDef clock, CMU_Select_TypeDef ref);
CMU_HFRCOBand_TypeDef CMU_HFRCOBandGet(void);
void CMU_HFRCOBandSet(CMU_HFRCOBand_TypeDef band);
#if defined( _CMU_AUXHFRCOCTRL_BAND_MASK )
CMU_AUXHFRCOBand_TypeDef CMU_AUXHFRCOBandGet(void);
void CMU_AUXHFRCOBandSet(CMU_AUXHFRCOBand_TypeDef band);
#endif
#if defined( _CMU_USHFRCOCONF_BAND_MASK )
CMU_USHFRCOBand_TypeDef CMU_USHFRCOBandGet(void);
void CMU_USHFRCOBandSet(CMU_USHFRCOBand_TypeDef band);
#endif
void CMU_HFRCOStartupDelaySet(uint32_t delay);
uint32_t CMU_HFRCOStartupDelayGet(void);
void CMU_OscillatorEnable(CMU_Osc_TypeDef osc, bool enable, bool wait);
uint32_t CMU_OscillatorTuningGet(CMU_Osc_TypeDef osc);
void CMU_OscillatorTuningSet(CMU_Osc_TypeDef osc, uint32_t val);
bool CMU_PCNTClockExternalGet(unsigned int inst);
void CMU_PCNTClockExternalSet(unsigned int inst, bool external);
uint32_t CMU_LCDClkFDIVGet(void);
void CMU_LCDClkFDIVSet(uint32_t div);
void CMU_FreezeEnable(bool enable);
uint32_t CMU_Calibrate(uint32_t HFCycles, CMU_Osc_TypeDef reference);
#if defined( _CMU_CALCTRL_UPSEL_MASK ) && defined( _CMU_CALCTRL_DOWNSEL_MASK )
void CMU_CalibrateConfig(uint32_t downCycles, CMU_Osc_TypeDef downSel,
CMU_Osc_TypeDef upSel);
#endif
/***************************************************************************//**
* @brief
* Clear one or more pending CMU interrupts.
*
* @param[in] flags
* CMU interrupt sources to clear.
******************************************************************************/
__STATIC_INLINE void CMU_IntClear(uint32_t flags)
{
CMU->IFC = flags;
}
/***************************************************************************//**
* @brief
* Disable one or more CMU interrupts.
*
* @param[in] flags
* CMU interrupt sources to disable.
******************************************************************************/
__STATIC_INLINE void CMU_IntDisable(uint32_t flags)
{
CMU->IEN &= ~flags;
}
/***************************************************************************//**
* @brief
* Enable one or more CMU interrupts.
*
* @note
* Depending on the use, a pending interrupt may already be set prior to
* enabling the interrupt. Consider using CMU_IntClear() prior to enabling
* if such a pending interrupt should be ignored.
*
* @param[in] flags
* CMU interrupt sources to enable.
******************************************************************************/
__STATIC_INLINE void CMU_IntEnable(uint32_t flags)
{
CMU->IEN |= flags;
}
/***************************************************************************//**
* @brief
* Get pending CMU interrupts.
*
* @return
* CMU interrupt sources pending.
******************************************************************************/
__STATIC_INLINE uint32_t CMU_IntGet(void)
{
return CMU->IF;
}
/***************************************************************************//**
* @brief
* Get enabled and pending CMU interrupt flags.
*
* @details
* Useful for handling more interrupt sources in the same interrupt handler.
*
* @note
* The event bits are not cleared by the use of this function.
*
* @return
* Pending and enabled CMU interrupt sources.
* The return value is the bitwise AND combination of
* - the OR combination of enabled interrupt sources in CMU_IEN_nnn
* register (CMU_IEN_nnn) and
* - the OR combination of valid interrupt flags of the CMU module
* (CMU_IF_nnn).
******************************************************************************/
__STATIC_INLINE uint32_t CMU_IntGetEnabled(void)
{
uint32_t tmp = 0U;
/* Store LESENSE->IEN in temporary variable in order to define explicit order
* of volatile accesses. */
tmp = CMU->IEN;
/* Bitwise AND of pending and enabled interrupts */
return CMU->IF & tmp;
}
/**************************************************************************//**
* @brief
* Set one or more pending CMU interrupts from SW.
*
* @param[in] flags
* CMU interrupt sources to set to pending.
*****************************************************************************/
__STATIC_INLINE void CMU_IntSet(uint32_t flags)
{
CMU->IFS = flags;
}
/***************************************************************************//**
* @brief
* Lock the CMU in order to protect some of its registers against unintended
* modification.
*
* @details
* Please refer to the reference manual for CMU registers that will be
* locked.
*
* @note
* If locking the CMU registers, they must be unlocked prior to using any
* CMU API functions modifying CMU registers protected by the lock.
******************************************************************************/
__STATIC_INLINE void CMU_Lock(void)
{
CMU->LOCK = CMU_LOCK_LOCKKEY_LOCK;
}
/***************************************************************************//**
* @brief
* Unlock the CMU so that writing to locked registers again is possible.
******************************************************************************/
__STATIC_INLINE void CMU_Unlock(void)
{
CMU->LOCK = CMU_LOCK_LOCKKEY_UNLOCK;
}
/***************************************************************************//**
* @brief
* Get calibration count register
* @note
* If continuous calibrartion mode is active, calibration busy will allmost
* always be on, and we just need to read the value, where the normal case
* would be that this function call has been triggered by the CALRDY
* interrupt flag.
* @return
* Calibration count, the number of UPSEL clocks (see CMU_CalibrateConfig)
* in the period of DOWNSEL oscillator clock cycles configured by a previous
* write operation to CMU->CALCNT
******************************************************************************/
__STATIC_INLINE uint32_t CMU_CalibrateCountGet(void)
{
/* Wait until calibration completes, UNLESS continuous calibration mode is */
/* active */
#if defined( CMU_CALCTRL_CONT )
if (!(CMU->CALCTRL & CMU_CALCTRL_CONT))
{
while (CMU->STATUS & CMU_STATUS_CALBSY)
;
}
#else
while (CMU->STATUS & CMU_STATUS_CALBSY)
;
#endif
return CMU->CALCNT;
}
/***************************************************************************//**
* @brief
* Starts calibration
* @note
* This call is usually invoked after CMU_CalibrateConfig() and possibly
* CMU_CalibrateCont()
******************************************************************************/
__STATIC_INLINE void CMU_CalibrateStart(void)
{
CMU->CMD = CMU_CMD_CALSTART;
}
#if defined( CMU_CMD_CALSTOP )
/***************************************************************************//**
* @brief
* Stop the calibration counters
******************************************************************************/
__STATIC_INLINE void CMU_CalibrateStop(void)
{
CMU->CMD = CMU_CMD_CALSTOP;
}
#endif
#if defined( CMU_CALCTRL_CONT )
/***************************************************************************//**
* @brief
* Configures continuous calibration mode
* @param[in] enable
* If true, enables continuous calibration, if false disables continuous
* calibrartion
******************************************************************************/
__STATIC_INLINE void CMU_CalibrateCont(bool enable)
{
BITBAND_Peripheral(&(CMU->CALCTRL), _CMU_CALCTRL_CONT_SHIFT, enable);
}
#endif
/** @} (end addtogroup CMU) */
/** @} (end addtogroup EM_Library) */
#ifdef __cplusplus
}
#endif
#endif /* defined( CMU_PRESENT ) */
#endif /* __SILICON_LABS_EM_CMU_H_ */
