include/linux/atmel_pwm.h - maze/linux - Git at Google

 #ifndef __LINUX_ATMEL_PWM_H
 #define __LINUX_ATMEL_PWM_H

 /**
  * struct pwm_channel - driver handle to a PWM channel
  * @regs: base of this channel's registers
  * @index: number of this channel (0..31)
  * @mck: base clock rate, which can be prescaled and maybe subdivided
  *
  * Drivers initialize a pwm_channel structure using pwm_channel_alloc().
  * Then they configure its clock rate (derived from MCK), alignment,
  * polarity, and duty cycle by writing directly to the channel registers,
  * before enabling the channel by calling pwm_channel_enable().
  *
  * After emitting a PWM signal for the desired length of time, drivers
  * may then pwm_channel_disable() or pwm_channel_free().  Both of these
  * disable the channel, but when it's freed the IRQ is deconfigured and
  * the channel must later be re-allocated and reconfigured.
  *
  * Note that if the period or duty cycle need to be changed while the
  * PWM channel is operating, drivers must use the PWM_CUPD double buffer
  * mechanism, either polling until they change or getting implicitly
  * notified through a once-per-period interrupt handler.
  */
 struct pwm_channel {
 	void __iomem	*regs;
 	unsigned	index;
 	unsigned long	mck;
 };

 extern int pwm_channel_alloc(int index, struct pwm_channel *ch);
 extern int pwm_channel_free(struct pwm_channel *ch);

 extern int pwm_clk_alloc(unsigned prescale, unsigned div);
 extern void pwm_clk_free(unsigned clk);

 extern int __pwm_channel_onoff(struct pwm_channel *ch, int enabled);

 #define pwm_channel_enable(ch)	__pwm_channel_onoff((ch), 1)
 #define pwm_channel_disable(ch)	__pwm_channel_onoff((ch), 0)

 /* periodic interrupts, mostly for CUPD changes to period or cycle */
 extern int pwm_channel_handler(struct pwm_channel *ch,
 		void (*handler)(struct pwm_channel *ch));

 /* per-channel registers (banked at pwm_channel->regs) */
 #define PWM_CMR		0x00		/* mode register */
 #define		PWM_CPR_CPD	(1 << 10)	/* set: CUPD modifies period */
 #define		PWM_CPR_CPOL	(1 << 9)	/* set: idle high */
 #define		PWM_CPR_CALG	(1 << 8)	/* set: center align */
 #define		PWM_CPR_CPRE	(0xf << 0)	/* mask: rate is mck/(2^pre) */
 #define		PWM_CPR_CLKA	(0xb << 0)	/* rate CLKA */
 #define		PWM_CPR_CLKB	(0xc << 0)	/* rate CLKB */
 #define PWM_CDTY	0x04		/* duty cycle (max of CPRD) */
 #define PWM_CPRD	0x08		/* period (count up from zero) */
 #define PWM_CCNT	0x0c		/* counter (20 bits?) */
 #define PWM_CUPD	0x10		/* update CPRD (or CDTY) next period */

 static inline void
 pwm_channel_writel(struct pwm_channel *pwmc, unsigned offset, u32 val)
 {
 	__raw_writel(val, pwmc->regs + offset);
 }

 static inline u32 pwm_channel_readl(struct pwm_channel *pwmc, unsigned offset)
 {
 	return __raw_readl(pwmc->regs + offset);
 }

 #endif /* __LINUX_ATMEL_PWM_H */
	#ifndef __LINUX_ATMEL_PWM_H
	#define __LINUX_ATMEL_PWM_H

	/**
	* struct pwm_channel - driver handle to a PWM channel
	* @regs: base of this channel's registers
	* @index: number of this channel (0..31)
	* @mck: base clock rate, which can be prescaled and maybe subdivided
	*
	* Drivers initialize a pwm_channel structure using pwm_channel_alloc().
	* Then they configure its clock rate (derived from MCK), alignment,
	* polarity, and duty cycle by writing directly to the channel registers,
	* before enabling the channel by calling pwm_channel_enable().
	*
	* After emitting a PWM signal for the desired length of time, drivers
	* may then pwm_channel_disable() or pwm_channel_free(). Both of these
	* disable the channel, but when it's freed the IRQ is deconfigured and
	* the channel must later be re-allocated and reconfigured.
	*
	* Note that if the period or duty cycle need to be changed while the
	* PWM channel is operating, drivers must use the PWM_CUPD double buffer
	* mechanism, either polling until they change or getting implicitly
	* notified through a once-per-period interrupt handler.
	*/
	struct pwm_channel {
	void __iomem *regs;
	unsigned index;
	unsigned long mck;
	};

	extern int pwm_channel_alloc(int index, struct pwm_channel *ch);
	extern int pwm_channel_free(struct pwm_channel *ch);

	extern int pwm_clk_alloc(unsigned prescale, unsigned div);
	extern void pwm_clk_free(unsigned clk);

	extern int __pwm_channel_onoff(struct pwm_channel *ch, int enabled);

	#define pwm_channel_enable(ch) __pwm_channel_onoff((ch), 1)
	#define pwm_channel_disable(ch) __pwm_channel_onoff((ch), 0)

	/* periodic interrupts, mostly for CUPD changes to period or cycle */
	extern int pwm_channel_handler(struct pwm_channel *ch,
	void (handler)(struct pwm_channel ch));

	/* per-channel registers (banked at pwm_channel->regs) */
	#define PWM_CMR 0x00 /* mode register */
	#define PWM_CPR_CPD (1 << 10) /* set: CUPD modifies period */
	#define PWM_CPR_CPOL (1 << 9) /* set: idle high */
	#define PWM_CPR_CALG (1 << 8) /* set: center align */
	#define PWM_CPR_CPRE (0xf << 0) /* mask: rate is mck/(2^pre) */
	#define PWM_CPR_CLKA (0xb << 0) /* rate CLKA */
	#define PWM_CPR_CLKB (0xc << 0) /* rate CLKB */
	#define PWM_CDTY 0x04 /* duty cycle (max of CPRD) */
	#define PWM_CPRD 0x08 /* period (count up from zero) */
	#define PWM_CCNT 0x0c /* counter (20 bits?) */
	#define PWM_CUPD 0x10 /* update CPRD (or CDTY) next period */

	static inline void
	pwm_channel_writel(struct pwm_channel *pwmc, unsigned offset, u32 val)
	{
	__raw_writel(val, pwmc->regs + offset);
	}

	static inline u32 pwm_channel_readl(struct pwm_channel *pwmc, unsigned offset)
	{
	return __raw_readl(pwmc->regs + offset);
	}

	#endif /* __LINUX_ATMEL_PWM_H */