FreeRTOS/Demo/CORTEX_M7_SAMV71_Xplained_AtmelStudio/libchip_samv7/source/pwmc.c - third_party/github/FreeRTOS/FreeRTOS-Kernel - Git at Google

 /* ----------------------------------------------------------------------------
  *         SAM Software Package License
  * ----------------------------------------------------------------------------
  * Copyright (c) 2011, Atmel Corporation
  *
  * All rights reserved.
  *
  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that the following conditions are met:
  *
  * - Redistributions of source code must retain the above copyright notice,
  * this list of conditions and the disclaimer below.
  *
  * Atmel's name may not be used to endorse or promote products derived from
  * this software without specific prior written permission.
  *
  * DISCLAIMER: THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR
  * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
  * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
  * DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR ANY DIRECT, INDIRECT,
  * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
  * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA,
  * OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
  * LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
  * NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE,
  * EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
  * ----------------------------------------------------------------------------
  */

 /** \addtogroup pwm_module Working with PWM
  *  \ingroup peripherals_module
  * The PWM driver provides the interface to configure and use the PWM
  * peripheral.
  *
  * The PWM macrocell controls square output waveforms of 4 channels.
  * Characteristics of output waveforms such as period, duty-cycle,
  * dead-time can be configured.\n
  * Some of PWM channels can be linked together as synchronous channel and
  * duty-cycle of synchronous channels can be updated by PDC automatically.
  *
  * Before enabling the channels, they must have been configured first.
  * The main settings include:
  * <ul>
  * <li>Configuration of the clock generator.</li>
  * <li>Selection of the clock for each channel.</li>
  * <li>Configuration of output waveform characteristics, such as period,
  * duty-cycle etc.</li>
  * <li>Configuration for synchronous channels if needed.</li>
  *    - Selection of the synchronous channels.
  *    - Selection of the moment when the WRDY flag and the corresponding PDC
  *      transfer request are set (PTRM and PTRCS in the PWM_SCM register).
  *    - Configuration of the update mode (UPDM in the PWM_SCM register).
  *    - Configuration of the update period (UPR in the PWM_SCUP register).
  * </ul>
  *
  * After the channels is enabled, the user must use respective update registers
  * to change the wave characteristics to prevent unexpected output waveform.
  * i.e. PWM_CDTYUPDx register should be used if user want to change duty-cycle
  * when the channel is enabled.
  *
  * For more accurate information, please look at the PWM section of the
  * Datasheet.
  *
  * Related files :\n
  * \ref pwmc.c\n
  * \ref pwmc.h.\n
  */
 /*@{*/
 /*@}*/

 /**
  * \file
  *
  * Implementation of the Pulse Width Modulation Controller (PWM) peripheral.
  *
  */

 /*----------------------------------------------------------------------------
  *        Headers
  *----------------------------------------------------------------------------*/

 #include "chip.h"

 #include <stdint.h>
 #include <assert.h>

 /*----------------------------------------------------------------------------
  *         Local functions
  *----------------------------------------------------------------------------*/

 /**
  * \brief Finds a prescaler/divisor couple to generate the desired frequency
  * from MCK.
  *
  * Returns the value to enter in PWM_CLK or 0 if the configuration cannot be
  * met.
  *
  * \param frequency  Desired frequency in Hz.
  * \param mck  Master clock frequency in Hz.
  */
 static uint16_t FindClockConfiguration(
 		uint32_t frequency,
 		uint32_t mck)
 {
 	uint32_t divisors[11] = {1, 2, 4, 8, 16, 32, 64, 128, 256, 512, 1024};
 	uint8_t divisor = 0;
 	uint32_t prescaler;

 	assert(frequency < mck);

 	/* Find prescaler and divisor values */
 	prescaler = (mck / divisors[divisor]) / frequency;
 	while ((prescaler > 255) && (divisor < 11)) {
 		divisor++;
 		prescaler = (mck / divisors[divisor]) / frequency;
 	}

 	/* Return result */
 	if ( divisor < 11 ) {
 		TRACE_DEBUG( "Found divisor=%u and prescaler=%u for freq=%uHz\n\r",
 				divisors[divisor], prescaler, frequency ) ;

 		return prescaler | (divisor << 8) ;
 	} else {
 		return 0 ;
 	}
 }

 /*----------------------------------------------------------------------------
  *        Exported functions
  *----------------------------------------------------------------------------*/

 /**
  * \brief Configures PWM a channel with the given parameters, basic configure
  * function.
  *
  * The PWM controller must have been clocked in the PMC prior to calling this
  * function.
  * Beware: this function disables the channel. It waits until disable is effective.
  *
  * \param channel  Channel number.
  * \param prescaler  Channel prescaler.
  * \param alignment  Channel alignment.
  * \param polarity  Channel polarity.
  */
 void PWMC_ConfigureChannel(
 		Pwm* pPwm,
 		uint8_t channel,
 		uint32_t prescaler,
 		uint32_t alignment,
 		uint32_t polarity)
 {
 	pPwm->PWM_CH_NUM[0].PWM_CMR = 1;

 	//    assert(prescaler < PWM_CMR0_CPRE_MCKB);
 	assert((alignment & (uint32_t)~PWM_CMR_CALG) == 0);
 	assert((polarity & (uint32_t)~PWM_CMR_CPOL) == 0);

 	/* Disable channel (effective at the end of the current period) */
 	if ((pPwm->PWM_SR & (1 << channel)) != 0) {
 		pPwm->PWM_DIS = 1 << channel;
 		while ((pPwm->PWM_SR & (1 << channel)) != 0);
 	}

 	/* Configure channel */
 	pPwm->PWM_CH_NUM[channel].PWM_CMR = prescaler | alignment | polarity;
 }

 /**
  * \brief Configures PWM a channel with the given parameters, extend configure
  * function.
  * The PWM controller must have been clocked in the PMC prior to calling this
  * function.
  * Beware: this function disables the channel. It waits until disable is effective.
  *
  * \param channel            Channel number.
  * \param prescaler          Channel prescaler.
  * \param alignment          Channel alignment.
  * \param polarity           Channel polarity.
  * \param countEventSelect   Channel counter event selection.
  * \param DTEnable           Channel dead time generator enable.
  * \param DTHInverte         Channel Dead-Time PWMHx output Inverted.
  * \param DTLInverte         Channel Dead-Time PWMHx output Inverted.
  */
 void PWMC_ConfigureChannelExt(
 		Pwm* pPwm,
 		uint8_t channel,
 		uint32_t prescaler,
 		uint32_t alignment,
 		uint32_t polarity,
 		uint32_t countEventSelect,
 		uint32_t DTEnable,
 		uint32_t DTHInverte,
 		uint32_t DTLInverte)
 {
 	//    assert(prescaler < PWM_CMR0_CPRE_MCKB);
 	assert((alignment & (uint32_t)~PWM_CMR_CALG) == 0);
 	assert((polarity & (uint32_t)~PWM_CMR_CPOL) == 0);
 	assert((countEventSelect & (uint32_t)~PWM_CMR_CES) == 0);
 	assert((DTEnable & (uint32_t)~PWM_CMR_DTE) == 0);
 	assert((DTHInverte & (uint32_t)~PWM_CMR_DTHI) == 0);
 	assert((DTLInverte & (uint32_t)~PWM_CMR_DTLI) == 0);

 	/* Disable channel (effective at the end of the current period) */
 	if ((pPwm->PWM_SR & (1 << channel)) != 0) {
 		pPwm->PWM_DIS = 1 << channel;
 		while ((pPwm->PWM_SR & (1 << channel)) != 0);
 	}

 	/* Configure channel */
 	pPwm->PWM_CH_NUM[channel].PWM_CMR = prescaler | alignment | polarity |
 		countEventSelect | DTEnable | DTHInverte | DTLInverte;
 }

 /**
  * \brief Configures PWM clocks A & B to run at the given frequencies.
  *
  * This function finds the best MCK divisor and prescaler values automatically.
  *
  * \param clka  Desired clock A frequency (0 if not used).
  * \param clkb  Desired clock B frequency (0 if not used).
  * \param mck  Master clock frequency.
  */
 void PWMC_ConfigureClocks(Pwm* pPwm, uint32_t clka, uint32_t clkb, uint32_t mck)
 {
 	uint32_t mode = 0;
 	uint32_t result;

 	/* Clock A */
 	if (clka != 0) {
 		result = FindClockConfiguration(clka, mck);
 		assert( result != 0 ) ;
 		mode |= result;
 	}

 	/* Clock B */
 	if (clkb != 0) {
 		result = FindClockConfiguration(clkb, mck);
 		assert( result != 0 ) ;
 		mode |= (result << 16);
 	}

 	/* Configure clocks */
 	TRACE_DEBUG( "Setting PWM_CLK = 0x%08X\n\r", mode ) ;
 	pPwm->PWM_CLK = mode;
 }

 /**
  * \brief Sets the period value used by a PWM channel.
  *
  * This function writes directly to the CPRD register if the channel is disabled;
  * otherwise, it uses the update register CPRDUPD.
  *
  * \param channel Channel number.
  * \param period  Period value.
  */
 void PWMC_SetPeriod( Pwm* pPwm, uint8_t channel, uint16_t period)
 {
 	/* If channel is disabled, write to CPRD */
 	if ((pPwm->PWM_SR & (1 << channel)) == 0) {

 		pPwm->PWM_CH_NUM[channel].PWM_CPRD = period;
 	} else {
 	/* Otherwise use update register */
 		pPwm->PWM_CH_NUM[channel].PWM_CPRDUPD = period;
 	}
 }

 /**
  * \brief Sets the duty cycle used by a PWM channel.
  * This function writes directly to the CDTY register if the channel is disabled;
  * otherwise it uses the update register CDTYUPD.
  * Note that the duty cycle must always be inferior or equal to the channel
  * period.
  *
  * \param channel  Channel number.
  * \param duty     Duty cycle value.
  */
 void PWMC_SetDutyCycle( Pwm* pPwm, uint8_t channel, uint16_t duty)
 {
 	assert(duty <= pPwm->PWM_CH_NUM[channel].PWM_CPRD);

 	/* If channel is disabled, write to CDTY */
 	if ((pPwm->PWM_SR & (1 << channel)) == 0) {
 		pPwm->PWM_CH_NUM[channel].PWM_CDTY = duty;
 	} else {
 		/* Otherwise use update register */
 		pPwm->PWM_CH_NUM[channel].PWM_CDTYUPD = duty;
 	}
 }

 /**
  * \brief Sets the dead time used by a PWM channel.
  * This function writes directly to the DT register if the channel is disabled;
  * otherwise it uses the update register DTUPD.
  * Note that the dead time must always be inferior or equal to the channel
  * period.
  *
  * \param channel  Channel number.
  * \param timeH    Dead time value for PWMHx output.
  * \param timeL    Dead time value for PWMLx output.
  */
 void PWMC_SetDeadTime( Pwm* pPwm, uint8_t channel, uint16_t timeH, uint16_t timeL)
 {
 	assert(timeH <= pPwm->PWM_CH_NUM[channel].PWM_CPRD);
 	assert(timeL <= pPwm->PWM_CH_NUM[channel].PWM_CPRD);

 	/* If channel is disabled, write to DT */
 	if ((pPwm->PWM_SR & (1 << channel)) == 0) {
 		pPwm->PWM_CH_NUM[channel].PWM_DT = timeH | (timeL << 16);
 	} else {
 	/* Otherwise use update register */
 		pPwm->PWM_CH_NUM[channel].PWM_DTUPD = timeH | (timeL << 16);
 	}
 }

 /**
  * \brief Configures Synchronous channel with the given parameters.
  * Beware: At this time, the channels should be disabled.
  *
  * \param channels                 Bitwise OR of Synchronous channels.
  * \param updateMode               Synchronous channel update mode.
  * \param requestMode              PDC transfer request mode.
  * \param requestComparisonSelect  PDC transfer request comparison selection.
  */
 void PWMC_ConfigureSyncChannel( Pwm* pPwm,
 		uint32_t channels,
 		uint32_t updateMode,
 		uint32_t requestMode,
 		uint32_t requestComparisonSelect)
 {
 	pPwm->PWM_SCM = channels | updateMode | requestMode | requestComparisonSelect;
 }

 /**
  * \brief Sets the update period of the synchronous channels.
  * This function writes directly to the SCUP register if the channel #0 is disabled;
  * otherwise it uses the update register SCUPUPD.
  *
  * \param period   update period.
  */
 void PWMC_SetSyncChannelUpdatePeriod( Pwm* pPwm, uint8_t period)
 {
 	/* If channel is disabled, write to SCUP */
 	if ((pPwm->PWM_SR & (1 << 0)) == 0) {
 		pPwm->PWM_SCUP = period;
 	} else {
 	/* Otherwise use update register */
 		pPwm->PWM_SCUPUPD = period;
 	}
 }

 /**
  * \brief Sets synchronous channels update unlock.
  *
  * Note: If the UPDM field is set to 0, writing the UPDULOCK bit to 1
  * triggers the update of the period value, the duty-cycle and
  * the dead-time values of synchronous channels at the beginning
  * of the next PWM period. If the field UPDM is set to 1 or 2,
  * writing the UPDULOCK bit to 1 triggers only the update of
  * the period value and of the dead-time values of synchronous channels.
  * This bit is automatically reset when the update is done.
  */
 void PWMC_SetSyncChannelUpdateUnlock( Pwm* pPwm )
 {
 	pPwm->PWM_SCUC = PWM_SCUC_UPDULOCK;
 }

 /**
  * \brief Enables the given PWM channel.
  *
  * This does NOT enable the corresponding pin;this must be done in the user code.
  *
  * \param channel  Channel number.
  */
 void PWMC_EnableChannel( Pwm* pPwm, uint8_t channel)
 {
 	pPwm->PWM_ENA = 1 << channel;
 }

 /**
  * \brief Disables the given PWM channel.
  *
  * Beware, channel will be effectively disabled at the end of the current period.
  * Application can check channel is disabled using the following wait loop:
  * while ((PWM->PWM_SR & (1 << channel)) != 0);
  *
  * \param channel  Channel number.
  */
 void PWMC_DisableChannel( Pwm* pPwm, uint8_t channel)
 {
 	pPwm->PWM_DIS = 1 << channel;
 }

 /**
  * \brief Enables the period interrupt for the given PWM channel.
  *
  * \param channel  Channel number.
  */
 void PWMC_EnableChannelIt( Pwm* pPwm, uint8_t channel)
 {
 	pPwm->PWM_IER1 = 1 << channel;
 }

 /**
  * \brief Return PWM Interrupt Status2 Register
  *
  */
 uint32_t PWMC_GetStatus2( Pwm* pPwm)
 {
 	return pPwm->PWM_ISR2;
 }

 /**
  * \brief Disables the period interrupt for the given PWM channel.
  *
  * \param channel  Channel number.
  */
 void PWMC_DisableChannelIt( Pwm* pPwm, uint8_t channel)
 {
 	pPwm->PWM_IDR1 = 1 << channel;
 }

 /**
  * \brief Enables the selected interrupts sources on a PWMC peripheral.
  *
  * \param sources1  Bitwise OR of selected interrupt sources of PWM_IER1.
  * \param sources2  Bitwise OR of selected interrupt sources of PWM_IER2.
  */
 void PWMC_EnableIt( Pwm* pPwm, uint32_t sources1, uint32_t sources2)
 {
 	pPwm->PWM_IER1 = sources1;
 	pPwm->PWM_IER2 = sources2;
 }

 /**
  * \brief Disables the selected interrupts sources on a PWMC peripheral.
  *
  * \param sources1  Bitwise OR of selected interrupt sources of PWM_IDR1.
  * \param sources2  Bitwise OR of selected interrupt sources of PWM_IDR2.
  */
 void PWMC_DisableIt( Pwm* pPwm, uint32_t sources1, uint32_t sources2)
 {
 	pPwm->PWM_IDR1 = sources1;
 	pPwm->PWM_IDR2 = sources2;
 }

 /**
  * \brief Set PWM output override value.
  *
  * \param value  Bitwise OR of output override value.
  */
 void PWMC_SetOverrideValue( Pwm* pPwm, uint32_t value)
 {
 	pPwm->PWM_OOV = value;
 }

 /**
  * \brief Enable override output.
  *
  * \param value  Bitwise OR of output selection.
  * \param sync   0: enable the output asynchronously, 1: enable it synchronously
  */
 void PWMC_EnableOverrideOutput( Pwm* pPwm, uint32_t value, uint32_t sync)
 {
 	if (sync) {
 		pPwm->PWM_OSSUPD = value;
 	} else {
 		pPwm->PWM_OSS = value;
 	}
 }

 /**
  * \brief Output Selection for override PWM output.
  *
  * \param value  Bitwise OR of output override value.
  */
 void PWMC_OutputOverrideSelection( Pwm* pPwm, uint32_t value )
 {
 	pPwm->PWM_OS = value;
 }


 /**
  * \brief Disable override output.
  *
  * \param value  Bitwise OR of output selection.
  * \param sync   0: enable the output asynchronously, 1: enable it synchronously
  */
 void PWMC_DisableOverrideOutput( Pwm* pPwm, uint32_t value, uint32_t sync)
 {
 	if (sync) {

 		pPwm->PWM_OSCUPD = value;
 	} else {

 		pPwm->PWM_OSC = value;
 	}
 }

 /**
  * \brief Set PWM fault mode.
  *
  * \param mode  Bitwise OR of fault mode.
  */
 void PWMC_SetFaultMode( Pwm* pPwm, uint32_t mode)
 {
 	pPwm->PWM_FMR = mode;
 }

 /**
  * \brief PWM fault clear.
  *
  * \param fault  Bitwise OR of fault to clear.
  */
 void PWMC_FaultClear( Pwm* pPwm, uint32_t fault)
 {
 	pPwm->PWM_FCR = fault;
 }

 /**
  * \brief Set PWM fault protection value.
  *
  * \param value  Bitwise OR of fault protection value.
  */
 void PWMC_SetFaultProtectionValue( Pwm* pPwm, uint32_t value)
 {
 	pPwm->PWM_FPV1 = value;
 }

 /**
  * \brief Enable PWM fault protection.
  *
  * \param value  Bitwise OR of FPEx[y].
  */
 void PWMC_EnableFaultProtection( Pwm* pPwm, uint32_t value)
 {
 	pPwm->PWM_FPE = value;
 }

 /**
  * \brief Configure comparison unit.
  *
  * \param x     comparison x index
  * \param value comparison x value.
  * \param mode  comparison x mode
  */
 void PWMC_ConfigureComparisonUnit( Pwm* pPwm, uint32_t x, uint32_t value, uint32_t mode)
 {
 	assert(x < 8);

 	/* If channel is disabled, write to CMPxM & CMPxV */
 	if ((pPwm->PWM_SR & (1 << 0)) == 0) {
 		pPwm->PWM_CMP[x].PWM_CMPM = mode;
 		pPwm->PWM_CMP[x].PWM_CMPV = value;
 	} else {
 		/* Otherwise use update register */
 		pPwm->PWM_CMP[x].PWM_CMPMUPD = mode;
 		pPwm->PWM_CMP[x].PWM_CMPVUPD = value;
 	}
 }

 /**
  * \brief Configure event line mode.
  *
  * \param x    Line x
  * \param mode Bitwise OR of line mode selection
  */
 void PWMC_ConfigureEventLineMode( Pwm* pPwm, uint32_t x, uint32_t mode)
 {
 	assert(x < 2);

 	if (x == 0) {
 		pPwm->PWM_ELMR[0] = mode;
 	} else if (x == 1) {
 		pPwm->PWM_ELMR[1] = mode;
 	}
 }
	/* ----------------------------------------------------------------------------
	* SAM Software Package License
	* ----------------------------------------------------------------------------
	* Copyright (c) 2011, Atmel Corporation
	*
	* All rights reserved.
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions are met:
	*
	* - Redistributions of source code must retain the above copyright notice,
	* this list of conditions and the disclaimer below.
	*
	* Atmel's name may not be used to endorse or promote products derived from
	* this software without specific prior written permission.
	*
	* DISCLAIMER: THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR
	* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
	* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
	* DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR ANY DIRECT, INDIRECT,
	* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
	* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA,
	* OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
	* LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
	* NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE,
	* EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	* ----------------------------------------------------------------------------
	*/

	/** \addtogroup pwm_module Working with PWM
	* \ingroup peripherals_module
	* The PWM driver provides the interface to configure and use the PWM
	* peripheral.
	*
	* The PWM macrocell controls square output waveforms of 4 channels.
	* Characteristics of output waveforms such as period, duty-cycle,
	* dead-time can be configured.\n
	* Some of PWM channels can be linked together as synchronous channel and
	* duty-cycle of synchronous channels can be updated by PDC automatically.
	*
	* Before enabling the channels, they must have been configured first.
	* The main settings include:
	* <ul>
	* <li>Configuration of the clock generator.</li>
	* <li>Selection of the clock for each channel.</li>
	* <li>Configuration of output waveform characteristics, such as period,
	* duty-cycle etc.</li>
	* <li>Configuration for synchronous channels if needed.</li>
	* - Selection of the synchronous channels.
	* - Selection of the moment when the WRDY flag and the corresponding PDC
	* transfer request are set (PTRM and PTRCS in the PWM_SCM register).
	* - Configuration of the update mode (UPDM in the PWM_SCM register).
	* - Configuration of the update period (UPR in the PWM_SCUP register).
	* </ul>
	*
	* After the channels is enabled, the user must use respective update registers
	* to change the wave characteristics to prevent unexpected output waveform.
	* i.e. PWM_CDTYUPDx register should be used if user want to change duty-cycle
	* when the channel is enabled.
	*
	* For more accurate information, please look at the PWM section of the
	* Datasheet.
	*
	* Related files :\n
	* \ref pwmc.c\n
	* \ref pwmc.h.\n
	*/
	/@{/
	/@}/

	/**
	* \file
	*
	* Implementation of the Pulse Width Modulation Controller (PWM) peripheral.
	*
	*/

	/*----------------------------------------------------------------------------
	* Headers
	----------------------------------------------------------------------------/

	#include "chip.h"

	#include <stdint.h>
	#include <assert.h>

	/*----------------------------------------------------------------------------
	* Local functions
	----------------------------------------------------------------------------/

	/**
	* \brief Finds a prescaler/divisor couple to generate the desired frequency
	* from MCK.
	*
	* Returns the value to enter in PWM_CLK or 0 if the configuration cannot be
	* met.
	*
	* \param frequency Desired frequency in Hz.
	* \param mck Master clock frequency in Hz.
	*/
	static uint16_t FindClockConfiguration(
	uint32_t frequency,
	uint32_t mck)
	{
	uint32_t divisors[11] = {1, 2, 4, 8, 16, 32, 64, 128, 256, 512, 1024};
	uint8_t divisor = 0;
	uint32_t prescaler;

	assert(frequency < mck);

	/* Find prescaler and divisor values */
	prescaler = (mck / divisors[divisor]) / frequency;
	while ((prescaler > 255) && (divisor < 11)) {
	divisor++;
	prescaler = (mck / divisors[divisor]) / frequency;
	}

	/* Return result */
	if ( divisor < 11 ) {
	TRACE_DEBUG( "Found divisor=%u and prescaler=%u for freq=%uHz\n\r",
	divisors[divisor], prescaler, frequency ) ;

	return prescaler \| (divisor << 8) ;
	} else {
	return 0 ;
	}
	}

	/*----------------------------------------------------------------------------
	* Exported functions
	----------------------------------------------------------------------------/

	/**
	* \brief Configures PWM a channel with the given parameters, basic configure
	* function.
	*
	* The PWM controller must have been clocked in the PMC prior to calling this
	* function.
	* Beware: this function disables the channel. It waits until disable is effective.
	*
	* \param channel Channel number.
	* \param prescaler Channel prescaler.
	* \param alignment Channel alignment.
	* \param polarity Channel polarity.
	*/
	void PWMC_ConfigureChannel(
	Pwm* pPwm,
	uint8_t channel,
	uint32_t prescaler,
	uint32_t alignment,
	uint32_t polarity)
	{
	pPwm->PWM_CH_NUM[0].PWM_CMR = 1;

	// assert(prescaler < PWM_CMR0_CPRE_MCKB);
	assert((alignment & (uint32_t)~PWM_CMR_CALG) == 0);
	assert((polarity & (uint32_t)~PWM_CMR_CPOL) == 0);

	/* Disable channel (effective at the end of the current period) */
	if ((pPwm->PWM_SR & (1 << channel)) != 0) {
	pPwm->PWM_DIS = 1 << channel;
	while ((pPwm->PWM_SR & (1 << channel)) != 0);
	}

	/* Configure channel */
	pPwm->PWM_CH_NUM[channel].PWM_CMR = prescaler \| alignment \| polarity;
	}

	/**
	* \brief Configures PWM a channel with the given parameters, extend configure
	* function.
	* The PWM controller must have been clocked in the PMC prior to calling this
	* function.
	* Beware: this function disables the channel. It waits until disable is effective.
	*
	* \param channel Channel number.
	* \param prescaler Channel prescaler.
	* \param alignment Channel alignment.
	* \param polarity Channel polarity.
	* \param countEventSelect Channel counter event selection.
	* \param DTEnable Channel dead time generator enable.
	* \param DTHInverte Channel Dead-Time PWMHx output Inverted.
	* \param DTLInverte Channel Dead-Time PWMHx output Inverted.
	*/
	void PWMC_ConfigureChannelExt(
	Pwm* pPwm,
	uint8_t channel,
	uint32_t prescaler,
	uint32_t alignment,
	uint32_t polarity,
	uint32_t countEventSelect,
	uint32_t DTEnable,
	uint32_t DTHInverte,
	uint32_t DTLInverte)
	{
	// assert(prescaler < PWM_CMR0_CPRE_MCKB);
	assert((alignment & (uint32_t)~PWM_CMR_CALG) == 0);
	assert((polarity & (uint32_t)~PWM_CMR_CPOL) == 0);
	assert((countEventSelect & (uint32_t)~PWM_CMR_CES) == 0);
	assert((DTEnable & (uint32_t)~PWM_CMR_DTE) == 0);
	assert((DTHInverte & (uint32_t)~PWM_CMR_DTHI) == 0);
	assert((DTLInverte & (uint32_t)~PWM_CMR_DTLI) == 0);

	/* Disable channel (effective at the end of the current period) */
	if ((pPwm->PWM_SR & (1 << channel)) != 0) {
	pPwm->PWM_DIS = 1 << channel;
	while ((pPwm->PWM_SR & (1 << channel)) != 0);
	}

	/* Configure channel */
	pPwm->PWM_CH_NUM[channel].PWM_CMR = prescaler \| alignment \| polarity \|
	countEventSelect \| DTEnable \| DTHInverte \| DTLInverte;
	}

	/**
	* \brief Configures PWM clocks A & B to run at the given frequencies.
	*
	* This function finds the best MCK divisor and prescaler values automatically.
	*
	* \param clka Desired clock A frequency (0 if not used).
	* \param clkb Desired clock B frequency (0 if not used).
	* \param mck Master clock frequency.
	*/
	void PWMC_ConfigureClocks(Pwm* pPwm, uint32_t clka, uint32_t clkb, uint32_t mck)
	{
	uint32_t mode = 0;
	uint32_t result;

	/* Clock A */
	if (clka != 0) {
	result = FindClockConfiguration(clka, mck);
	assert( result != 0 ) ;
	mode \|= result;
	}

	/* Clock B */
	if (clkb != 0) {
	result = FindClockConfiguration(clkb, mck);
	assert( result != 0 ) ;
	mode \|= (result << 16);
	}

	/* Configure clocks */
	TRACE_DEBUG( "Setting PWM_CLK = 0x%08X\n\r", mode ) ;
	pPwm->PWM_CLK = mode;
	}

	/**
	* \brief Sets the period value used by a PWM channel.
	*
	* This function writes directly to the CPRD register if the channel is disabled;
	* otherwise, it uses the update register CPRDUPD.
	*
	* \param channel Channel number.
	* \param period Period value.
	*/
	void PWMC_SetPeriod( Pwm* pPwm, uint8_t channel, uint16_t period)
	{
	/* If channel is disabled, write to CPRD */
	if ((pPwm->PWM_SR & (1 << channel)) == 0) {

	pPwm->PWM_CH_NUM[channel].PWM_CPRD = period;
	} else {
	/* Otherwise use update register */
	pPwm->PWM_CH_NUM[channel].PWM_CPRDUPD = period;
	}
	}

	/**
	* \brief Sets the duty cycle used by a PWM channel.
	* This function writes directly to the CDTY register if the channel is disabled;
	* otherwise it uses the update register CDTYUPD.
	* Note that the duty cycle must always be inferior or equal to the channel
	* period.
	*
	* \param channel Channel number.
	* \param duty Duty cycle value.
	*/
	void PWMC_SetDutyCycle( Pwm* pPwm, uint8_t channel, uint16_t duty)
	{
	assert(duty <= pPwm->PWM_CH_NUM[channel].PWM_CPRD);

	/* If channel is disabled, write to CDTY */
	if ((pPwm->PWM_SR & (1 << channel)) == 0) {
	pPwm->PWM_CH_NUM[channel].PWM_CDTY = duty;
	} else {
	/* Otherwise use update register */
	pPwm->PWM_CH_NUM[channel].PWM_CDTYUPD = duty;
	}
	}

	/**
	* \brief Sets the dead time used by a PWM channel.
	* This function writes directly to the DT register if the channel is disabled;
	* otherwise it uses the update register DTUPD.
	* Note that the dead time must always be inferior or equal to the channel
	* period.
	*
	* \param channel Channel number.
	* \param timeH Dead time value for PWMHx output.
	* \param timeL Dead time value for PWMLx output.
	*/
	void PWMC_SetDeadTime( Pwm* pPwm, uint8_t channel, uint16_t timeH, uint16_t timeL)
	{
	assert(timeH <= pPwm->PWM_CH_NUM[channel].PWM_CPRD);
	assert(timeL <= pPwm->PWM_CH_NUM[channel].PWM_CPRD);

	/* If channel is disabled, write to DT */
	if ((pPwm->PWM_SR & (1 << channel)) == 0) {
	pPwm->PWM_CH_NUM[channel].PWM_DT = timeH \| (timeL << 16);
	} else {
	/* Otherwise use update register */
	pPwm->PWM_CH_NUM[channel].PWM_DTUPD = timeH \| (timeL << 16);
	}
	}

	/**
	* \brief Configures Synchronous channel with the given parameters.
	* Beware: At this time, the channels should be disabled.
	*
	* \param channels Bitwise OR of Synchronous channels.
	* \param updateMode Synchronous channel update mode.
	* \param requestMode PDC transfer request mode.
	* \param requestComparisonSelect PDC transfer request comparison selection.
	*/
	void PWMC_ConfigureSyncChannel( Pwm* pPwm,
	uint32_t channels,
	uint32_t updateMode,
	uint32_t requestMode,
	uint32_t requestComparisonSelect)
	{
	pPwm->PWM_SCM = channels \| updateMode \| requestMode \| requestComparisonSelect;
	}

	/**
	* \brief Sets the update period of the synchronous channels.
	* This function writes directly to the SCUP register if the channel #0 is disabled;
	* otherwise it uses the update register SCUPUPD.
	*
	* \param period update period.
	*/
	void PWMC_SetSyncChannelUpdatePeriod( Pwm* pPwm, uint8_t period)
	{
	/* If channel is disabled, write to SCUP */
	if ((pPwm->PWM_SR & (1 << 0)) == 0) {
	pPwm->PWM_SCUP = period;
	} else {
	/* Otherwise use update register */
	pPwm->PWM_SCUPUPD = period;
	}
	}

	/**
	* \brief Sets synchronous channels update unlock.
	*
	* Note: If the UPDM field is set to 0, writing the UPDULOCK bit to 1
	* triggers the update of the period value, the duty-cycle and
	* the dead-time values of synchronous channels at the beginning
	* of the next PWM period. If the field UPDM is set to 1 or 2,
	* writing the UPDULOCK bit to 1 triggers only the update of
	* the period value and of the dead-time values of synchronous channels.
	* This bit is automatically reset when the update is done.
	*/
	void PWMC_SetSyncChannelUpdateUnlock( Pwm* pPwm )
	{
	pPwm->PWM_SCUC = PWM_SCUC_UPDULOCK;
	}

	/**
	* \brief Enables the given PWM channel.
	*
	* This does NOT enable the corresponding pin;this must be done in the user code.
	*
	* \param channel Channel number.
	*/
	void PWMC_EnableChannel( Pwm* pPwm, uint8_t channel)
	{
	pPwm->PWM_ENA = 1 << channel;
	}

	/**
	* \brief Disables the given PWM channel.
	*
	* Beware, channel will be effectively disabled at the end of the current period.
	* Application can check channel is disabled using the following wait loop:
	* while ((PWM->PWM_SR & (1 << channel)) != 0);
	*
	* \param channel Channel number.
	*/
	void PWMC_DisableChannel( Pwm* pPwm, uint8_t channel)
	{
	pPwm->PWM_DIS = 1 << channel;
	}

	/**
	* \brief Enables the period interrupt for the given PWM channel.
	*
	* \param channel Channel number.
	*/
	void PWMC_EnableChannelIt( Pwm* pPwm, uint8_t channel)
	{
	pPwm->PWM_IER1 = 1 << channel;
	}

	/**
	* \brief Return PWM Interrupt Status2 Register
	*
	*/
	uint32_t PWMC_GetStatus2( Pwm* pPwm)
	{
	return pPwm->PWM_ISR2;
	}

	/**
	* \brief Disables the period interrupt for the given PWM channel.
	*
	* \param channel Channel number.
	*/
	void PWMC_DisableChannelIt( Pwm* pPwm, uint8_t channel)
	{
	pPwm->PWM_IDR1 = 1 << channel;
	}

	/**
	* \brief Enables the selected interrupts sources on a PWMC peripheral.
	*
	* \param sources1 Bitwise OR of selected interrupt sources of PWM_IER1.
	* \param sources2 Bitwise OR of selected interrupt sources of PWM_IER2.
	*/
	void PWMC_EnableIt( Pwm* pPwm, uint32_t sources1, uint32_t sources2)
	{
	pPwm->PWM_IER1 = sources1;
	pPwm->PWM_IER2 = sources2;
	}

	/**
	* \brief Disables the selected interrupts sources on a PWMC peripheral.
	*
	* \param sources1 Bitwise OR of selected interrupt sources of PWM_IDR1.
	* \param sources2 Bitwise OR of selected interrupt sources of PWM_IDR2.
	*/
	void PWMC_DisableIt( Pwm* pPwm, uint32_t sources1, uint32_t sources2)
	{
	pPwm->PWM_IDR1 = sources1;
	pPwm->PWM_IDR2 = sources2;
	}

	/**
	* \brief Set PWM output override value.
	*
	* \param value Bitwise OR of output override value.
	*/
	void PWMC_SetOverrideValue( Pwm* pPwm, uint32_t value)
	{
	pPwm->PWM_OOV = value;
	}

	/**
	* \brief Enable override output.
	*
	* \param value Bitwise OR of output selection.
	* \param sync 0: enable the output asynchronously, 1: enable it synchronously
	*/
	void PWMC_EnableOverrideOutput( Pwm* pPwm, uint32_t value, uint32_t sync)
	{
	if (sync) {
	pPwm->PWM_OSSUPD = value;
	} else {
	pPwm->PWM_OSS = value;
	}
	}

	/**
	* \brief Output Selection for override PWM output.
	*
	* \param value Bitwise OR of output override value.
	*/
	void PWMC_OutputOverrideSelection( Pwm* pPwm, uint32_t value )
	{
	pPwm->PWM_OS = value;
	}


	/**
	* \brief Disable override output.
	*
	* \param value Bitwise OR of output selection.
	* \param sync 0: enable the output asynchronously, 1: enable it synchronously
	*/
	void PWMC_DisableOverrideOutput( Pwm* pPwm, uint32_t value, uint32_t sync)
	{
	if (sync) {

	pPwm->PWM_OSCUPD = value;
	} else {

	pPwm->PWM_OSC = value;
	}
	}

	/**
	* \brief Set PWM fault mode.
	*
	* \param mode Bitwise OR of fault mode.
	*/
	void PWMC_SetFaultMode( Pwm* pPwm, uint32_t mode)
	{
	pPwm->PWM_FMR = mode;
	}

	/**
	* \brief PWM fault clear.
	*
	* \param fault Bitwise OR of fault to clear.
	*/
	void PWMC_FaultClear( Pwm* pPwm, uint32_t fault)
	{
	pPwm->PWM_FCR = fault;
	}

	/**
	* \brief Set PWM fault protection value.
	*
	* \param value Bitwise OR of fault protection value.
	*/
	void PWMC_SetFaultProtectionValue( Pwm* pPwm, uint32_t value)
	{
	pPwm->PWM_FPV1 = value;
	}

	/**
	* \brief Enable PWM fault protection.
	*
	* \param value Bitwise OR of FPEx[y].
	*/
	void PWMC_EnableFaultProtection( Pwm* pPwm, uint32_t value)
	{
	pPwm->PWM_FPE = value;
	}

	/**
	* \brief Configure comparison unit.
	*
	* \param x comparison x index
	* \param value comparison x value.
	* \param mode comparison x mode
	*/
	void PWMC_ConfigureComparisonUnit( Pwm* pPwm, uint32_t x, uint32_t value, uint32_t mode)
	{
	assert(x < 8);

	/* If channel is disabled, write to CMPxM & CMPxV */
	if ((pPwm->PWM_SR & (1 << 0)) == 0) {
	pPwm->PWM_CMP[x].PWM_CMPM = mode;
	pPwm->PWM_CMP[x].PWM_CMPV = value;
	} else {
	/* Otherwise use update register */
	pPwm->PWM_CMP[x].PWM_CMPMUPD = mode;
	pPwm->PWM_CMP[x].PWM_CMPVUPD = value;
	}
	}

	/**
	* \brief Configure event line mode.
	*
	* \param x Line x
	* \param mode Bitwise OR of line mode selection
	*/
	void PWMC_ConfigureEventLineMode( Pwm* pPwm, uint32_t x, uint32_t mode)
	{
	assert(x < 2);

	if (x == 0) {
	pPwm->PWM_ELMR[0] = mode;
	} else if (x == 1) {
	pPwm->PWM_ELMR[1] = mode;
	}
	}