arch/arm/cpu/arm926ejs/armada100/timer.c - github/trini/u-boot - Gitiles

 /*
  * (C) Copyright 2010
  * Marvell Semiconductor <www.marvell.com>
  * Written-by: Prafulla Wadaskar <prafulla@marvell.com>
  * Contributor: Mahavir Jain <mjain@marvell.com>
  *
  * SPDX-License-Identifier:	GPL-2.0+
  */

 #include <common.h>
 #include <asm/arch/cpu.h>
 #include <asm/arch/armada100.h>

 /*
  * Timer registers
  * Refer Section A.6 in Datasheet
  */
 struct armd1tmr_registers {
 	u32 clk_ctrl;	/* Timer clk control reg */
 	u32 match[9];	/* Timer match registers */
 	u32 count[3];	/* Timer count registers */
 	u32 status[3];
 	u32 ie[3];
 	u32 preload[3];	/* Timer preload value */
 	u32 preload_ctrl[3];
 	u32 wdt_match_en;
 	u32 wdt_match_r;
 	u32 wdt_val;
 	u32 wdt_sts;
 	u32 icr[3];
 	u32 wdt_icr;
 	u32 cer;	/* Timer count enable reg */
 	u32 cmr;
 	u32 ilr[3];
 	u32 wcr;
 	u32 wfar;
 	u32 wsar;
 	u32 cvwr;
 };

 #define TIMER			0	/* Use TIMER 0 */
 /* Each timer has 3 match registers */
 #define MATCH_CMP(x)		((3 * TIMER) + x)
 #define TIMER_LOAD_VAL 		0xffffffff
 #define	COUNT_RD_REQ		0x1

 DECLARE_GLOBAL_DATA_PTR;
 /* Using gd->arch.tbu from timestamp and gd->arch.tbl for lastdec */

 /* For preventing risk of instability in reading counter value,
  * first set read request to register cvwr and then read same
  * register after it captures counter value.
  */
 ulong read_timer(void)
 {
 	struct armd1tmr_registers *armd1timers =
 		(struct armd1tmr_registers *) ARMD1_TIMER_BASE;
 	volatile int loop=100;

 	writel(COUNT_RD_REQ, &armd1timers->cvwr);
 	while (loop--);
 	return(readl(&armd1timers->cvwr));
 }

 ulong get_timer_masked(void)
 {
 	ulong now = read_timer();

 	if (now >= gd->arch.tbl) {
 		/* normal mode */
 		gd->arch.tbu += now - gd->arch.tbl;
 	} else {
 		/* we have an overflow ... */
 		gd->arch.tbu += now + TIMER_LOAD_VAL - gd->arch.tbl;
 	}
 	gd->arch.tbl = now;

 	return gd->arch.tbu;
 }

 ulong get_timer(ulong base)
 {
 	return ((get_timer_masked() / (CONFIG_SYS_HZ_CLOCK / 1000)) -
 		base);
 }

 void __udelay(unsigned long usec)
 {
 	ulong delayticks;
 	ulong endtime;

 	delayticks = (usec * (CONFIG_SYS_HZ_CLOCK / 1000000));
 	endtime = get_timer_masked() + delayticks;

 	while (get_timer_masked() < endtime);
 }

 /*
  * init the Timer
  */
 int timer_init(void)
 {
 	struct armd1apb1_registers *apb1clkres =
 		(struct armd1apb1_registers *) ARMD1_APBC1_BASE;
 	struct armd1tmr_registers *armd1timers =
 		(struct armd1tmr_registers *) ARMD1_TIMER_BASE;

 	/* Enable Timer clock at 3.25 MHZ */
 	writel(APBC_APBCLK | APBC_FNCLK | APBC_FNCLKSEL(3), &apb1clkres->timers);

 	/* load value into timer */
 	writel(0x0, &armd1timers->clk_ctrl);
 	/* Use Timer 0 Match Resiger 0 */
 	writel(TIMER_LOAD_VAL, &armd1timers->match[MATCH_CMP(0)]);
 	/* Preload value is 0 */
 	writel(0x0, &armd1timers->preload[TIMER]);
 	/* Enable match comparator 0 for Timer 0 */
 	writel(0x1, &armd1timers->preload_ctrl[TIMER]);

 	/* Enable timer 0 */
 	writel(0x1, &armd1timers->cer);
 	/* init the gd->arch.tbu and gd->arch.tbl value */
 	gd->arch.tbl = read_timer();
 	gd->arch.tbu = 0;

 	return 0;
 }

 #define MPMU_APRR_WDTR	(1<<4)
 #define TMR_WFAR	0xbaba	/* WDT Register First key */
 #define TMP_WSAR	0xeb10	/* WDT Register Second key */

 /*
  * This function uses internal Watchdog Timer
  * based reset mechanism.
  * Steps to write watchdog registers (protected access)
  * 1. Write key value to TMR_WFAR reg.
  * 2. Write key value to TMP_WSAR reg.
  * 3. Perform write operation.
  */
 void reset_cpu (unsigned long ignored)
 {
 	struct armd1mpmu_registers *mpmu =
 		(struct armd1mpmu_registers *) ARMD1_MPMU_BASE;
 	struct armd1tmr_registers *armd1timers =
 		(struct armd1tmr_registers *) ARMD1_TIMER_BASE;
 	u32 val;

 	/* negate hardware reset to the WDT after system reset */
 	val = readl(&mpmu->aprr);
 	val = val | MPMU_APRR_WDTR;
 	writel(val, &mpmu->aprr);

 	/* reset/enable WDT clock */
 	writel(APBC_APBCLK | APBC_FNCLK | APBC_RST, &mpmu->wdtpcr);
 	readl(&mpmu->wdtpcr);
 	writel(APBC_APBCLK | APBC_FNCLK, &mpmu->wdtpcr);
 	readl(&mpmu->wdtpcr);

 	/* clear previous WDT status */
 	writel(TMR_WFAR, &armd1timers->wfar);
 	writel(TMP_WSAR, &armd1timers->wsar);
 	writel(0, &armd1timers->wdt_sts);

 	/* set match counter */
 	writel(TMR_WFAR, &armd1timers->wfar);
 	writel(TMP_WSAR, &armd1timers->wsar);
 	writel(0xf, &armd1timers->wdt_match_r);

 	/* enable WDT reset */
 	writel(TMR_WFAR, &armd1timers->wfar);
 	writel(TMP_WSAR, &armd1timers->wsar);
 	writel(0x3, &armd1timers->wdt_match_en);

 	while(1);
 }

 /*
  * This function is derived from PowerPC code (read timebase as long long).
  * On ARM it just returns the timer value.
  */
 unsigned long long get_ticks(void)
 {
 	return get_timer(0);
 }

 /*
  * This function is derived from PowerPC code (timebase clock frequency).
  * On ARM it returns the number of timer ticks per second.
  */
 ulong get_tbclk (void)
 {
 	return (ulong)CONFIG_SYS_HZ;
 }
	/*
	* (C) Copyright 2010
	* Marvell Semiconductor <www.marvell.com>
	* Written-by: Prafulla Wadaskar <prafulla@marvell.com>
	* Contributor: Mahavir Jain <mjain@marvell.com>
	*
	* SPDX-License-Identifier: GPL-2.0+
	*/

	#include <common.h>
	#include <asm/arch/cpu.h>
	#include <asm/arch/armada100.h>

	/*
	* Timer registers
	* Refer Section A.6 in Datasheet
	*/
	struct armd1tmr_registers {
	u32 clk_ctrl; /* Timer clk control reg */
	u32 match[9]; /* Timer match registers */
	u32 count[3]; /* Timer count registers */
	u32 status[3];
	u32 ie[3];
	u32 preload[3]; /* Timer preload value */
	u32 preload_ctrl[3];
	u32 wdt_match_en;
	u32 wdt_match_r;
	u32 wdt_val;
	u32 wdt_sts;
	u32 icr[3];
	u32 wdt_icr;
	u32 cer; /* Timer count enable reg */
	u32 cmr;
	u32 ilr[3];
	u32 wcr;
	u32 wfar;
	u32 wsar;
	u32 cvwr;
	};

	#define TIMER 0 /* Use TIMER 0 */
	/* Each timer has 3 match registers */
	#define MATCH_CMP(x) ((3 * TIMER) + x)
	#define TIMER_LOAD_VAL 0xffffffff
	#define COUNT_RD_REQ 0x1

	DECLARE_GLOBAL_DATA_PTR;
	/* Using gd->arch.tbu from timestamp and gd->arch.tbl for lastdec */

	/* For preventing risk of instability in reading counter value,
	* first set read request to register cvwr and then read same
	* register after it captures counter value.
	*/
	ulong read_timer(void)
	{
	struct armd1tmr_registers *armd1timers =
	(struct armd1tmr_registers *) ARMD1_TIMER_BASE;
	volatile int loop=100;

	writel(COUNT_RD_REQ, &armd1timers->cvwr);
	while (loop--);
	return(readl(&armd1timers->cvwr));
	}

	ulong get_timer_masked(void)
	{
	ulong now = read_timer();

	if (now >= gd->arch.tbl) {
	/* normal mode */
	gd->arch.tbu += now - gd->arch.tbl;
	} else {
	/* we have an overflow ... */
	gd->arch.tbu += now + TIMER_LOAD_VAL - gd->arch.tbl;
	}
	gd->arch.tbl = now;

	return gd->arch.tbu;
	}

	ulong get_timer(ulong base)
	{
	return ((get_timer_masked() / (CONFIG_SYS_HZ_CLOCK / 1000)) -
	base);
	}

	void __udelay(unsigned long usec)
	{
	ulong delayticks;
	ulong endtime;

	delayticks = (usec * (CONFIG_SYS_HZ_CLOCK / 1000000));
	endtime = get_timer_masked() + delayticks;

	while (get_timer_masked() < endtime);
	}

	/*
	* init the Timer
	*/
	int timer_init(void)
	{
	struct armd1apb1_registers *apb1clkres =
	(struct armd1apb1_registers *) ARMD1_APBC1_BASE;
	struct armd1tmr_registers *armd1timers =
	(struct armd1tmr_registers *) ARMD1_TIMER_BASE;

	/* Enable Timer clock at 3.25 MHZ */
	writel(APBC_APBCLK \| APBC_FNCLK \| APBC_FNCLKSEL(3), &apb1clkres->timers);

	/* load value into timer */
	writel(0x0, &armd1timers->clk_ctrl);
	/* Use Timer 0 Match Resiger 0 */
	writel(TIMER_LOAD_VAL, &armd1timers->match[MATCH_CMP(0)]);
	/* Preload value is 0 */
	writel(0x0, &armd1timers->preload[TIMER]);
	/* Enable match comparator 0 for Timer 0 */
	writel(0x1, &armd1timers->preload_ctrl[TIMER]);

	/* Enable timer 0 */
	writel(0x1, &armd1timers->cer);
	/* init the gd->arch.tbu and gd->arch.tbl value */
	gd->arch.tbl = read_timer();
	gd->arch.tbu = 0;

	return 0;
	}

	#define MPMU_APRR_WDTR (1<<4)
	#define TMR_WFAR 0xbaba /* WDT Register First key */
	#define TMP_WSAR 0xeb10 /* WDT Register Second key */

	/*
	* This function uses internal Watchdog Timer
	* based reset mechanism.
	* Steps to write watchdog registers (protected access)
	* 1. Write key value to TMR_WFAR reg.
	* 2. Write key value to TMP_WSAR reg.
	* 3. Perform write operation.
	*/
	void reset_cpu (unsigned long ignored)
	{
	struct armd1mpmu_registers *mpmu =
	(struct armd1mpmu_registers *) ARMD1_MPMU_BASE;
	struct armd1tmr_registers *armd1timers =
	(struct armd1tmr_registers *) ARMD1_TIMER_BASE;
	u32 val;

	/* negate hardware reset to the WDT after system reset */
	val = readl(&mpmu->aprr);
	val = val \| MPMU_APRR_WDTR;
	writel(val, &mpmu->aprr);

	/* reset/enable WDT clock */
	writel(APBC_APBCLK \| APBC_FNCLK \| APBC_RST, &mpmu->wdtpcr);
	readl(&mpmu->wdtpcr);
	writel(APBC_APBCLK \| APBC_FNCLK, &mpmu->wdtpcr);
	readl(&mpmu->wdtpcr);

	/* clear previous WDT status */
	writel(TMR_WFAR, &armd1timers->wfar);
	writel(TMP_WSAR, &armd1timers->wsar);
	writel(0, &armd1timers->wdt_sts);

	/* set match counter */
	writel(TMR_WFAR, &armd1timers->wfar);
	writel(TMP_WSAR, &armd1timers->wsar);
	writel(0xf, &armd1timers->wdt_match_r);

	/* enable WDT reset */
	writel(TMR_WFAR, &armd1timers->wfar);
	writel(TMP_WSAR, &armd1timers->wsar);
	writel(0x3, &armd1timers->wdt_match_en);

	while(1);
	}

	/*
	* This function is derived from PowerPC code (read timebase as long long).
	* On ARM it just returns the timer value.
	*/
	unsigned long long get_ticks(void)
	{
	return get_timer(0);
	}

	/*
	* This function is derived from PowerPC code (timebase clock frequency).
	* On ARM it returns the number of timer ticks per second.
	*/
	ulong get_tbclk (void)
	{
	return (ulong)CONFIG_SYS_HZ;
	}