drivers/clocksource/tcb_clksrc.c - pub/scm/linux/kernel/git/mbroz/linux - Git at Google

 // SPDX-License-Identifier: GPL-2.0
 #include <linux/init.h>
 #include <linux/clocksource.h>
 #include <linux/clockchips.h>
 #include <linux/interrupt.h>
 #include <linux/irq.h>

 #include <linux/clk.h>
 #include <linux/err.h>
 #include <linux/ioport.h>
 #include <linux/io.h>
 #include <linux/platform_device.h>
 #include <linux/syscore_ops.h>
 #include <linux/atmel_tc.h>


 /*
  * We're configured to use a specific TC block, one that's not hooked
  * up to external hardware, to provide a time solution:
  *
  *   - Two channels combine to create a free-running 32 bit counter
  *     with a base rate of 5+ MHz, packaged as a clocksource (with
  *     resolution better than 200 nsec).
  *   - Some chips support 32 bit counter. A single channel is used for
  *     this 32 bit free-running counter. the second channel is not used.
  *
  *   - The third channel may be used to provide a 16-bit clockevent
  *     source, used in either periodic or oneshot mode.  This runs
  *     at 32 KiHZ, and can handle delays of up to two seconds.
  *
  * A boot clocksource and clockevent source are also currently needed,
  * unless the relevant platforms (ARM/AT91, AVR32/AT32) are changed so
  * this code can be used when init_timers() is called, well before most
  * devices are set up.  (Some low end AT91 parts, which can run uClinux,
  * have only the timers in one TC block... they currently don't support
  * the tclib code, because of that initialization issue.)
  *
  * REVISIT behavior during system suspend states... we should disable
  * all clocks and save the power.  Easily done for clockevent devices,
  * but clocksources won't necessarily get the needed notifications.
  * For deeper system sleep states, this will be mandatory...
  */

 static void __iomem *tcaddr;
 static struct
 {
 	u32 cmr;
 	u32 imr;
 	u32 rc;
 	bool clken;
 } tcb_cache[3];
 static u32 bmr_cache;

 static u64 tc_get_cycles(struct clocksource *cs)
 {
 	unsigned long	flags;
 	u32		lower, upper;

 	raw_local_irq_save(flags);
 	do {
 		upper = readl_relaxed(tcaddr + ATMEL_TC_REG(1, CV));
 		lower = readl_relaxed(tcaddr + ATMEL_TC_REG(0, CV));
 	} while (upper != readl_relaxed(tcaddr + ATMEL_TC_REG(1, CV)));

 	raw_local_irq_restore(flags);
 	return (upper << 16) | lower;
 }

 static u64 tc_get_cycles32(struct clocksource *cs)
 {
 	return readl_relaxed(tcaddr + ATMEL_TC_REG(0, CV));
 }

 void tc_clksrc_suspend(struct clocksource *cs)
 {
 	int i;

 	for (i = 0; i < ARRAY_SIZE(tcb_cache); i++) {
 		tcb_cache[i].cmr = readl(tcaddr + ATMEL_TC_REG(i, CMR));
 		tcb_cache[i].imr = readl(tcaddr + ATMEL_TC_REG(i, IMR));
 		tcb_cache[i].rc = readl(tcaddr + ATMEL_TC_REG(i, RC));
 		tcb_cache[i].clken = !!(readl(tcaddr + ATMEL_TC_REG(i, SR)) &
 					ATMEL_TC_CLKSTA);
 	}

 	bmr_cache = readl(tcaddr + ATMEL_TC_BMR);
 }

 void tc_clksrc_resume(struct clocksource *cs)
 {
 	int i;

 	for (i = 0; i < ARRAY_SIZE(tcb_cache); i++) {
 		/* Restore registers for the channel, RA and RB are not used  */
 		writel(tcb_cache[i].cmr, tcaddr + ATMEL_TC_REG(i, CMR));
 		writel(tcb_cache[i].rc, tcaddr + ATMEL_TC_REG(i, RC));
 		writel(0, tcaddr + ATMEL_TC_REG(i, RA));
 		writel(0, tcaddr + ATMEL_TC_REG(i, RB));
 		/* Disable all the interrupts */
 		writel(0xff, tcaddr + ATMEL_TC_REG(i, IDR));
 		/* Reenable interrupts that were enabled before suspending */
 		writel(tcb_cache[i].imr, tcaddr + ATMEL_TC_REG(i, IER));
 		/* Start the clock if it was used */
 		if (tcb_cache[i].clken)
 			writel(ATMEL_TC_CLKEN, tcaddr + ATMEL_TC_REG(i, CCR));
 	}

 	/* Dual channel, chain channels */
 	writel(bmr_cache, tcaddr + ATMEL_TC_BMR);
 	/* Finally, trigger all the channels*/
 	writel(ATMEL_TC_SYNC, tcaddr + ATMEL_TC_BCR);
 }

 static struct clocksource clksrc = {
 	.name           = "tcb_clksrc",
 	.rating         = 200,
 	.read           = tc_get_cycles,
 	.mask           = CLOCKSOURCE_MASK(32),
 	.flags		= CLOCK_SOURCE_IS_CONTINUOUS,
 	.suspend	= tc_clksrc_suspend,
 	.resume		= tc_clksrc_resume,
 };

 #ifdef CONFIG_GENERIC_CLOCKEVENTS

 struct tc_clkevt_device {
 	struct clock_event_device	clkevt;
 	struct clk			*clk;
 	void __iomem			*regs;
 };

 static struct tc_clkevt_device *to_tc_clkevt(struct clock_event_device *clkevt)
 {
 	return container_of(clkevt, struct tc_clkevt_device, clkevt);
 }

 /* For now, we always use the 32K clock ... this optimizes for NO_HZ,
  * because using one of the divided clocks would usually mean the
  * tick rate can never be less than several dozen Hz (vs 0.5 Hz).
  *
  * A divided clock could be good for high resolution timers, since
  * 30.5 usec resolution can seem "low".
  */
 static u32 timer_clock;

 static int tc_shutdown(struct clock_event_device *d)
 {
 	struct tc_clkevt_device *tcd = to_tc_clkevt(d);
 	void __iomem		*regs = tcd->regs;

 	writel(0xff, regs + ATMEL_TC_REG(2, IDR));
 	writel(ATMEL_TC_CLKDIS, regs + ATMEL_TC_REG(2, CCR));
 	if (!clockevent_state_detached(d))
 		clk_disable(tcd->clk);

 	return 0;
 }

 static int tc_set_oneshot(struct clock_event_device *d)
 {
 	struct tc_clkevt_device *tcd = to_tc_clkevt(d);
 	void __iomem		*regs = tcd->regs;

 	if (clockevent_state_oneshot(d) || clockevent_state_periodic(d))
 		tc_shutdown(d);

 	clk_enable(tcd->clk);

 	/* slow clock, count up to RC, then irq and stop */
 	writel(timer_clock | ATMEL_TC_CPCSTOP | ATMEL_TC_WAVE |
 		     ATMEL_TC_WAVESEL_UP_AUTO, regs + ATMEL_TC_REG(2, CMR));
 	writel(ATMEL_TC_CPCS, regs + ATMEL_TC_REG(2, IER));

 	/* set_next_event() configures and starts the timer */
 	return 0;
 }

 static int tc_set_periodic(struct clock_event_device *d)
 {
 	struct tc_clkevt_device *tcd = to_tc_clkevt(d);
 	void __iomem		*regs = tcd->regs;

 	if (clockevent_state_oneshot(d) || clockevent_state_periodic(d))
 		tc_shutdown(d);

 	/* By not making the gentime core emulate periodic mode on top
 	 * of oneshot, we get lower overhead and improved accuracy.
 	 */
 	clk_enable(tcd->clk);

 	/* slow clock, count up to RC, then irq and restart */
 	writel(timer_clock | ATMEL_TC_WAVE | ATMEL_TC_WAVESEL_UP_AUTO,
 		     regs + ATMEL_TC_REG(2, CMR));
 	writel((32768 + HZ / 2) / HZ, tcaddr + ATMEL_TC_REG(2, RC));

 	/* Enable clock and interrupts on RC compare */
 	writel(ATMEL_TC_CPCS, regs + ATMEL_TC_REG(2, IER));

 	/* go go gadget! */
 	writel(ATMEL_TC_CLKEN | ATMEL_TC_SWTRG, regs +
 		     ATMEL_TC_REG(2, CCR));
 	return 0;
 }

 static int tc_next_event(unsigned long delta, struct clock_event_device *d)
 {
 	writel_relaxed(delta, tcaddr + ATMEL_TC_REG(2, RC));

 	/* go go gadget! */
 	writel_relaxed(ATMEL_TC_CLKEN | ATMEL_TC_SWTRG,
 			tcaddr + ATMEL_TC_REG(2, CCR));
 	return 0;
 }

 static struct tc_clkevt_device clkevt = {
 	.clkevt	= {
 		.name			= "tc_clkevt",
 		.features		= CLOCK_EVT_FEAT_PERIODIC |
 					  CLOCK_EVT_FEAT_ONESHOT,
 		/* Should be lower than at91rm9200's system timer */
 		.rating			= 125,
 		.set_next_event		= tc_next_event,
 		.set_state_shutdown	= tc_shutdown,
 		.set_state_periodic	= tc_set_periodic,
 		.set_state_oneshot	= tc_set_oneshot,
 	},
 };

 static irqreturn_t ch2_irq(int irq, void *handle)
 {
 	struct tc_clkevt_device	*dev = handle;
 	unsigned int		sr;

 	sr = readl_relaxed(dev->regs + ATMEL_TC_REG(2, SR));
 	if (sr & ATMEL_TC_CPCS) {
 		dev->clkevt.event_handler(&dev->clkevt);
 		return IRQ_HANDLED;
 	}

 	return IRQ_NONE;
 }

 static int __init setup_clkevents(struct atmel_tc *tc, int clk32k_divisor_idx)
 {
 	int ret;
 	struct clk *t2_clk = tc->clk[2];
 	int irq = tc->irq[2];

 	ret = clk_prepare_enable(tc->slow_clk);
 	if (ret)
 		return ret;

 	/* try to enable t2 clk to avoid future errors in mode change */
 	ret = clk_prepare_enable(t2_clk);
 	if (ret) {
 		clk_disable_unprepare(tc->slow_clk);
 		return ret;
 	}

 	clk_disable(t2_clk);

 	clkevt.regs = tc->regs;
 	clkevt.clk = t2_clk;

 	timer_clock = clk32k_divisor_idx;

 	clkevt.clkevt.cpumask = cpumask_of(0);

 	ret = request_irq(irq, ch2_irq, IRQF_TIMER, "tc_clkevt", &clkevt);
 	if (ret) {
 		clk_unprepare(t2_clk);
 		clk_disable_unprepare(tc->slow_clk);
 		return ret;
 	}

 	clockevents_config_and_register(&clkevt.clkevt, 32768, 1, 0xffff);

 	return ret;
 }

 #else /* !CONFIG_GENERIC_CLOCKEVENTS */

 static int __init setup_clkevents(struct atmel_tc *tc, int clk32k_divisor_idx)
 {
 	/* NOTHING */
 	return 0;
 }

 #endif

 static void __init tcb_setup_dual_chan(struct atmel_tc *tc, int mck_divisor_idx)
 {
 	/* channel 0:  waveform mode, input mclk/8, clock TIOA0 on overflow */
 	writel(mck_divisor_idx			/* likely divide-by-8 */
 			| ATMEL_TC_WAVE
 			| ATMEL_TC_WAVESEL_UP		/* free-run */
 			| ATMEL_TC_ACPA_SET		/* TIOA0 rises at 0 */
 			| ATMEL_TC_ACPC_CLEAR,		/* (duty cycle 50%) */
 			tcaddr + ATMEL_TC_REG(0, CMR));
 	writel(0x0000, tcaddr + ATMEL_TC_REG(0, RA));
 	writel(0x8000, tcaddr + ATMEL_TC_REG(0, RC));
 	writel(0xff, tcaddr + ATMEL_TC_REG(0, IDR));	/* no irqs */
 	writel(ATMEL_TC_CLKEN, tcaddr + ATMEL_TC_REG(0, CCR));

 	/* channel 1:  waveform mode, input TIOA0 */
 	writel(ATMEL_TC_XC1			/* input: TIOA0 */
 			| ATMEL_TC_WAVE
 			| ATMEL_TC_WAVESEL_UP,		/* free-run */
 			tcaddr + ATMEL_TC_REG(1, CMR));
 	writel(0xff, tcaddr + ATMEL_TC_REG(1, IDR));	/* no irqs */
 	writel(ATMEL_TC_CLKEN, tcaddr + ATMEL_TC_REG(1, CCR));

 	/* chain channel 0 to channel 1*/
 	writel(ATMEL_TC_TC1XC1S_TIOA0, tcaddr + ATMEL_TC_BMR);
 	/* then reset all the timers */
 	writel(ATMEL_TC_SYNC, tcaddr + ATMEL_TC_BCR);
 }

 static void __init tcb_setup_single_chan(struct atmel_tc *tc, int mck_divisor_idx)
 {
 	/* channel 0:  waveform mode, input mclk/8 */
 	writel(mck_divisor_idx			/* likely divide-by-8 */
 			| ATMEL_TC_WAVE
 			| ATMEL_TC_WAVESEL_UP,		/* free-run */
 			tcaddr + ATMEL_TC_REG(0, CMR));
 	writel(0xff, tcaddr + ATMEL_TC_REG(0, IDR));	/* no irqs */
 	writel(ATMEL_TC_CLKEN, tcaddr + ATMEL_TC_REG(0, CCR));

 	/* then reset all the timers */
 	writel(ATMEL_TC_SYNC, tcaddr + ATMEL_TC_BCR);
 }

 static int __init tcb_clksrc_init(void)
 {
 	static char bootinfo[] __initdata
 		= KERN_DEBUG "%s: tc%d at %d.%03d MHz\n";

 	struct platform_device *pdev;
 	struct atmel_tc *tc;
 	struct clk *t0_clk;
 	u32 rate, divided_rate = 0;
 	int best_divisor_idx = -1;
 	int clk32k_divisor_idx = -1;
 	int i;
 	int ret;

 	tc = atmel_tc_alloc(CONFIG_ATMEL_TCB_CLKSRC_BLOCK);
 	if (!tc) {
 		pr_debug("can't alloc TC for clocksource\n");
 		return -ENODEV;
 	}
 	tcaddr = tc->regs;
 	pdev = tc->pdev;

 	t0_clk = tc->clk[0];
 	ret = clk_prepare_enable(t0_clk);
 	if (ret) {
 		pr_debug("can't enable T0 clk\n");
 		goto err_free_tc;
 	}

 	/* How fast will we be counting?  Pick something over 5 MHz.  */
 	rate = (u32) clk_get_rate(t0_clk);
 	for (i = 0; i < 5; i++) {
 		unsigned divisor = atmel_tc_divisors[i];
 		unsigned tmp;

 		/* remember 32 KiHz clock for later */
 		if (!divisor) {
 			clk32k_divisor_idx = i;
 			continue;
 		}

 		tmp = rate / divisor;
 		pr_debug("TC: %u / %-3u [%d] --> %u\n", rate, divisor, i, tmp);
 		if (best_divisor_idx > 0) {
 			if (tmp < 5 * 1000 * 1000)
 				continue;
 		}
 		divided_rate = tmp;
 		best_divisor_idx = i;
 	}


 	printk(bootinfo, clksrc.name, CONFIG_ATMEL_TCB_CLKSRC_BLOCK,
 			divided_rate / 1000000,
 			((divided_rate % 1000000) + 500) / 1000);

 	if (tc->tcb_config && tc->tcb_config->counter_width == 32) {
 		/* use apropriate function to read 32 bit counter */
 		clksrc.read = tc_get_cycles32;
 		/* setup ony channel 0 */
 		tcb_setup_single_chan(tc, best_divisor_idx);
 	} else {
 		/* tclib will give us three clocks no matter what the
 		 * underlying platform supports.
 		 */
 		ret = clk_prepare_enable(tc->clk[1]);
 		if (ret) {
 			pr_debug("can't enable T1 clk\n");
 			goto err_disable_t0;
 		}
 		/* setup both channel 0 & 1 */
 		tcb_setup_dual_chan(tc, best_divisor_idx);
 	}

 	/* and away we go! */
 	ret = clocksource_register_hz(&clksrc, divided_rate);
 	if (ret)
 		goto err_disable_t1;

 	/* channel 2:  periodic and oneshot timer support */
 	ret = setup_clkevents(tc, clk32k_divisor_idx);
 	if (ret)
 		goto err_unregister_clksrc;

 	return 0;

 err_unregister_clksrc:
 	clocksource_unregister(&clksrc);

 err_disable_t1:
 	if (!tc->tcb_config || tc->tcb_config->counter_width != 32)
 		clk_disable_unprepare(tc->clk[1]);

 err_disable_t0:
 	clk_disable_unprepare(t0_clk);

 err_free_tc:
 	atmel_tc_free(tc);
 	return ret;
 }
 arch_initcall(tcb_clksrc_init);
	// SPDX-License-Identifier: GPL-2.0
	#include <linux/init.h>
	#include <linux/clocksource.h>
	#include <linux/clockchips.h>
	#include <linux/interrupt.h>
	#include <linux/irq.h>

	#include <linux/clk.h>
	#include <linux/err.h>
	#include <linux/ioport.h>
	#include <linux/io.h>
	#include <linux/platform_device.h>
	#include <linux/syscore_ops.h>
	#include <linux/atmel_tc.h>


	/*
	* We're configured to use a specific TC block, one that's not hooked
	* up to external hardware, to provide a time solution:
	*
	* - Two channels combine to create a free-running 32 bit counter
	* with a base rate of 5+ MHz, packaged as a clocksource (with
	* resolution better than 200 nsec).
	* - Some chips support 32 bit counter. A single channel is used for
	* this 32 bit free-running counter. the second channel is not used.
	*
	* - The third channel may be used to provide a 16-bit clockevent
	* source, used in either periodic or oneshot mode. This runs
	* at 32 KiHZ, and can handle delays of up to two seconds.
	*
	* A boot clocksource and clockevent source are also currently needed,
	* unless the relevant platforms (ARM/AT91, AVR32/AT32) are changed so
	* this code can be used when init_timers() is called, well before most
	* devices are set up. (Some low end AT91 parts, which can run uClinux,
	* have only the timers in one TC block... they currently don't support
	* the tclib code, because of that initialization issue.)
	*
	* REVISIT behavior during system suspend states... we should disable
	* all clocks and save the power. Easily done for clockevent devices,
	* but clocksources won't necessarily get the needed notifications.
	* For deeper system sleep states, this will be mandatory...
	*/

	static void __iomem *tcaddr;
	static struct
	{
	u32 cmr;
	u32 imr;
	u32 rc;
	bool clken;
	} tcb_cache[3];
	static u32 bmr_cache;

	static u64 tc_get_cycles(struct clocksource *cs)
	{
	unsigned long flags;
	u32 lower, upper;

	raw_local_irq_save(flags);
	do {
	upper = readl_relaxed(tcaddr + ATMEL_TC_REG(1, CV));
	lower = readl_relaxed(tcaddr + ATMEL_TC_REG(0, CV));
	} while (upper != readl_relaxed(tcaddr + ATMEL_TC_REG(1, CV)));

	raw_local_irq_restore(flags);
	return (upper << 16) \| lower;
	}

	static u64 tc_get_cycles32(struct clocksource *cs)
	{
	return readl_relaxed(tcaddr + ATMEL_TC_REG(0, CV));
	}

	void tc_clksrc_suspend(struct clocksource *cs)
	{
	int i;

	for (i = 0; i < ARRAY_SIZE(tcb_cache); i++) {
	tcb_cache[i].cmr = readl(tcaddr + ATMEL_TC_REG(i, CMR));
	tcb_cache[i].imr = readl(tcaddr + ATMEL_TC_REG(i, IMR));
	tcb_cache[i].rc = readl(tcaddr + ATMEL_TC_REG(i, RC));
	tcb_cache[i].clken = !!(readl(tcaddr + ATMEL_TC_REG(i, SR)) &
	ATMEL_TC_CLKSTA);
	}

	bmr_cache = readl(tcaddr + ATMEL_TC_BMR);
	}

	void tc_clksrc_resume(struct clocksource *cs)
	{
	int i;

	for (i = 0; i < ARRAY_SIZE(tcb_cache); i++) {
	/* Restore registers for the channel, RA and RB are not used */
	writel(tcb_cache[i].cmr, tcaddr + ATMEL_TC_REG(i, CMR));
	writel(tcb_cache[i].rc, tcaddr + ATMEL_TC_REG(i, RC));
	writel(0, tcaddr + ATMEL_TC_REG(i, RA));
	writel(0, tcaddr + ATMEL_TC_REG(i, RB));
	/* Disable all the interrupts */
	writel(0xff, tcaddr + ATMEL_TC_REG(i, IDR));
	/* Reenable interrupts that were enabled before suspending */
	writel(tcb_cache[i].imr, tcaddr + ATMEL_TC_REG(i, IER));
	/* Start the clock if it was used */
	if (tcb_cache[i].clken)
	writel(ATMEL_TC_CLKEN, tcaddr + ATMEL_TC_REG(i, CCR));
	}

	/* Dual channel, chain channels */
	writel(bmr_cache, tcaddr + ATMEL_TC_BMR);
	/* Finally, trigger all the channels*/
	writel(ATMEL_TC_SYNC, tcaddr + ATMEL_TC_BCR);
	}

	static struct clocksource clksrc = {
	.name = "tcb_clksrc",
	.rating = 200,
	.read = tc_get_cycles,
	.mask = CLOCKSOURCE_MASK(32),
	.flags = CLOCK_SOURCE_IS_CONTINUOUS,
	.suspend = tc_clksrc_suspend,
	.resume = tc_clksrc_resume,
	};

	#ifdef CONFIG_GENERIC_CLOCKEVENTS

	struct tc_clkevt_device {
	struct clock_event_device clkevt;
	struct clk *clk;
	void __iomem *regs;
	};

	static struct tc_clkevt_device to_tc_clkevt(struct clock_event_device clkevt)
	{
	return container_of(clkevt, struct tc_clkevt_device, clkevt);
	}

	/* For now, we always use the 32K clock ... this optimizes for NO_HZ,
	* because using one of the divided clocks would usually mean the
	* tick rate can never be less than several dozen Hz (vs 0.5 Hz).
	*
	* A divided clock could be good for high resolution timers, since
	* 30.5 usec resolution can seem "low".
	*/
	static u32 timer_clock;

	static int tc_shutdown(struct clock_event_device *d)
	{
	struct tc_clkevt_device *tcd = to_tc_clkevt(d);
	void __iomem *regs = tcd->regs;

	writel(0xff, regs + ATMEL_TC_REG(2, IDR));
	writel(ATMEL_TC_CLKDIS, regs + ATMEL_TC_REG(2, CCR));
	if (!clockevent_state_detached(d))
	clk_disable(tcd->clk);

	return 0;
	}

	static int tc_set_oneshot(struct clock_event_device *d)
	{
	struct tc_clkevt_device *tcd = to_tc_clkevt(d);
	void __iomem *regs = tcd->regs;

	if (clockevent_state_oneshot(d) \|\| clockevent_state_periodic(d))
	tc_shutdown(d);

	clk_enable(tcd->clk);

	/* slow clock, count up to RC, then irq and stop */
	writel(timer_clock \| ATMEL_TC_CPCSTOP \| ATMEL_TC_WAVE \|
	ATMEL_TC_WAVESEL_UP_AUTO, regs + ATMEL_TC_REG(2, CMR));
	writel(ATMEL_TC_CPCS, regs + ATMEL_TC_REG(2, IER));

	/* set_next_event() configures and starts the timer */
	return 0;
	}

	static int tc_set_periodic(struct clock_event_device *d)
	{
	struct tc_clkevt_device *tcd = to_tc_clkevt(d);
	void __iomem *regs = tcd->regs;

	if (clockevent_state_oneshot(d) \|\| clockevent_state_periodic(d))
	tc_shutdown(d);

	/* By not making the gentime core emulate periodic mode on top
	* of oneshot, we get lower overhead and improved accuracy.
	*/
	clk_enable(tcd->clk);

	/* slow clock, count up to RC, then irq and restart */
	writel(timer_clock \| ATMEL_TC_WAVE \| ATMEL_TC_WAVESEL_UP_AUTO,
	regs + ATMEL_TC_REG(2, CMR));
	writel((32768 + HZ / 2) / HZ, tcaddr + ATMEL_TC_REG(2, RC));

	/* Enable clock and interrupts on RC compare */
	writel(ATMEL_TC_CPCS, regs + ATMEL_TC_REG(2, IER));

	/* go go gadget! */
	writel(ATMEL_TC_CLKEN \| ATMEL_TC_SWTRG, regs +
	ATMEL_TC_REG(2, CCR));
	return 0;
	}

	static int tc_next_event(unsigned long delta, struct clock_event_device *d)
	{
	writel_relaxed(delta, tcaddr + ATMEL_TC_REG(2, RC));

	/* go go gadget! */
	writel_relaxed(ATMEL_TC_CLKEN \| ATMEL_TC_SWTRG,
	tcaddr + ATMEL_TC_REG(2, CCR));
	return 0;
	}

	static struct tc_clkevt_device clkevt = {
	.clkevt = {
	.name = "tc_clkevt",
	.features = CLOCK_EVT_FEAT_PERIODIC \|
	CLOCK_EVT_FEAT_ONESHOT,
	/* Should be lower than at91rm9200's system timer */
	.rating = 125,
	.set_next_event = tc_next_event,
	.set_state_shutdown = tc_shutdown,
	.set_state_periodic = tc_set_periodic,
	.set_state_oneshot = tc_set_oneshot,
	},
	};

	static irqreturn_t ch2_irq(int irq, void *handle)
	{
	struct tc_clkevt_device *dev = handle;
	unsigned int sr;

	sr = readl_relaxed(dev->regs + ATMEL_TC_REG(2, SR));
	if (sr & ATMEL_TC_CPCS) {
	dev->clkevt.event_handler(&dev->clkevt);
	return IRQ_HANDLED;
	}

	return IRQ_NONE;
	}

	static int __init setup_clkevents(struct atmel_tc *tc, int clk32k_divisor_idx)
	{
	int ret;
	struct clk *t2_clk = tc->clk[2];
	int irq = tc->irq[2];

	ret = clk_prepare_enable(tc->slow_clk);
	if (ret)
	return ret;

	/* try to enable t2 clk to avoid future errors in mode change */
	ret = clk_prepare_enable(t2_clk);
	if (ret) {
	clk_disable_unprepare(tc->slow_clk);
	return ret;
	}

	clk_disable(t2_clk);

	clkevt.regs = tc->regs;
	clkevt.clk = t2_clk;

	timer_clock = clk32k_divisor_idx;

	clkevt.clkevt.cpumask = cpumask_of(0);

	ret = request_irq(irq, ch2_irq, IRQF_TIMER, "tc_clkevt", &clkevt);
	if (ret) {
	clk_unprepare(t2_clk);
	clk_disable_unprepare(tc->slow_clk);
	return ret;
	}

	clockevents_config_and_register(&clkevt.clkevt, 32768, 1, 0xffff);

	return ret;
	}

	#else /* !CONFIG_GENERIC_CLOCKEVENTS */

	static int __init setup_clkevents(struct atmel_tc *tc, int clk32k_divisor_idx)
	{
	/* NOTHING */
	return 0;
	}

	#endif

	static void __init tcb_setup_dual_chan(struct atmel_tc *tc, int mck_divisor_idx)
	{
	/* channel 0: waveform mode, input mclk/8, clock TIOA0 on overflow */
	writel(mck_divisor_idx /* likely divide-by-8 */
	\| ATMEL_TC_WAVE
	\| ATMEL_TC_WAVESEL_UP /* free-run */
	\| ATMEL_TC_ACPA_SET /* TIOA0 rises at 0 */
	\| ATMEL_TC_ACPC_CLEAR, /* (duty cycle 50%) */
	tcaddr + ATMEL_TC_REG(0, CMR));
	writel(0x0000, tcaddr + ATMEL_TC_REG(0, RA));
	writel(0x8000, tcaddr + ATMEL_TC_REG(0, RC));
	writel(0xff, tcaddr + ATMEL_TC_REG(0, IDR)); /* no irqs */
	writel(ATMEL_TC_CLKEN, tcaddr + ATMEL_TC_REG(0, CCR));

	/* channel 1: waveform mode, input TIOA0 */
	writel(ATMEL_TC_XC1 /* input: TIOA0 */
	\| ATMEL_TC_WAVE
	\| ATMEL_TC_WAVESEL_UP, /* free-run */
	tcaddr + ATMEL_TC_REG(1, CMR));
	writel(0xff, tcaddr + ATMEL_TC_REG(1, IDR)); /* no irqs */
	writel(ATMEL_TC_CLKEN, tcaddr + ATMEL_TC_REG(1, CCR));

	/* chain channel 0 to channel 1*/
	writel(ATMEL_TC_TC1XC1S_TIOA0, tcaddr + ATMEL_TC_BMR);
	/* then reset all the timers */
	writel(ATMEL_TC_SYNC, tcaddr + ATMEL_TC_BCR);
	}

	static void __init tcb_setup_single_chan(struct atmel_tc *tc, int mck_divisor_idx)
	{
	/* channel 0: waveform mode, input mclk/8 */
	writel(mck_divisor_idx /* likely divide-by-8 */
	\| ATMEL_TC_WAVE
	\| ATMEL_TC_WAVESEL_UP, /* free-run */
	tcaddr + ATMEL_TC_REG(0, CMR));
	writel(0xff, tcaddr + ATMEL_TC_REG(0, IDR)); /* no irqs */
	writel(ATMEL_TC_CLKEN, tcaddr + ATMEL_TC_REG(0, CCR));

	/* then reset all the timers */
	writel(ATMEL_TC_SYNC, tcaddr + ATMEL_TC_BCR);
	}

	static int __init tcb_clksrc_init(void)
	{
	static char bootinfo[] __initdata
	= KERN_DEBUG "%s: tc%d at %d.%03d MHz\n";

	struct platform_device *pdev;
	struct atmel_tc *tc;
	struct clk *t0_clk;
	u32 rate, divided_rate = 0;
	int best_divisor_idx = -1;
	int clk32k_divisor_idx = -1;
	int i;
	int ret;

	tc = atmel_tc_alloc(CONFIG_ATMEL_TCB_CLKSRC_BLOCK);
	if (!tc) {
	pr_debug("can't alloc TC for clocksource\n");
	return -ENODEV;
	}
	tcaddr = tc->regs;
	pdev = tc->pdev;

	t0_clk = tc->clk[0];
	ret = clk_prepare_enable(t0_clk);
	if (ret) {
	pr_debug("can't enable T0 clk\n");
	goto err_free_tc;
	}

	/* How fast will we be counting? Pick something over 5 MHz. */
	rate = (u32) clk_get_rate(t0_clk);
	for (i = 0; i < 5; i++) {
	unsigned divisor = atmel_tc_divisors[i];
	unsigned tmp;

	/* remember 32 KiHz clock for later */
	if (!divisor) {
	clk32k_divisor_idx = i;
	continue;
	}

	tmp = rate / divisor;
	pr_debug("TC: %u / %-3u [%d] --> %u\n", rate, divisor, i, tmp);
	if (best_divisor_idx > 0) {
	if (tmp < 5 * 1000 * 1000)
	continue;
	}
	divided_rate = tmp;
	best_divisor_idx = i;
	}


	printk(bootinfo, clksrc.name, CONFIG_ATMEL_TCB_CLKSRC_BLOCK,
	divided_rate / 1000000,
	((divided_rate % 1000000) + 500) / 1000);

	if (tc->tcb_config && tc->tcb_config->counter_width == 32) {
	/* use apropriate function to read 32 bit counter */
	clksrc.read = tc_get_cycles32;
	/* setup ony channel 0 */
	tcb_setup_single_chan(tc, best_divisor_idx);
	} else {
	/* tclib will give us three clocks no matter what the
	* underlying platform supports.
	*/
	ret = clk_prepare_enable(tc->clk[1]);
	if (ret) {
	pr_debug("can't enable T1 clk\n");
	goto err_disable_t0;
	}
	/* setup both channel 0 & 1 */
	tcb_setup_dual_chan(tc, best_divisor_idx);
	}

	/* and away we go! */
	ret = clocksource_register_hz(&clksrc, divided_rate);
	if (ret)
	goto err_disable_t1;

	/* channel 2: periodic and oneshot timer support */
	ret = setup_clkevents(tc, clk32k_divisor_idx);
	if (ret)
	goto err_unregister_clksrc;

	return 0;

	err_unregister_clksrc:
	clocksource_unregister(&clksrc);

	err_disable_t1:
	if (!tc->tcb_config \|\| tc->tcb_config->counter_width != 32)
	clk_disable_unprepare(tc->clk[1]);

	err_disable_t0:
	clk_disable_unprepare(t0_clk);

	err_free_tc:
	atmel_tc_free(tc);
	return ret;
	}
	arch_initcall(tcb_clksrc_init);