arm/at91/at91tctmr.c

*ef06fc5cSmaxv/*$NetBSD: at91tctmr.c,v 1.9 2020/07/03 16:23:02 maxv Exp $*/
c62a0ac4Smatt
c62a0ac4Smatt/*
c62a0ac4Smatt * AT91 Timer Counter (TC) based clock functions
c62a0ac4Smatt * Copyright (c) 2007, Embedtronics Oy
c62a0ac4Smatt * All rights reserved.
c62a0ac4Smatt *
c62a0ac4Smatt * Based on vx115_clk.c,
c62a0ac4Smatt * Copyright (c) 2006, Jon Sevy <jsevy@cs.drexel.edu>
c62a0ac4Smatt *
c62a0ac4Smatt * Based on epclk.c
c62a0ac4Smatt * Copyright (c) 2004 Jesse Off
c62a0ac4Smatt * All rights reserved.
c62a0ac4Smatt *
c62a0ac4Smatt * Redistribution and use in source and binary forms, with or without
c62a0ac4Smatt * modification, are permitted provided that the following conditions
c62a0ac4Smatt * are met:
c62a0ac4Smatt * 1. Redistributions of source code must retain the above copyright
c62a0ac4Smatt *    notice, this list of conditions and the following disclaimer.
c62a0ac4Smatt * 2. Redistributions in binary form must reproduce the above copyright
c62a0ac4Smatt *    notice, this list of conditions and the following disclaimer in the
c62a0ac4Smatt *    documentation and/or other materials provided with the distribution.
c62a0ac4Smatt *
c62a0ac4Smatt * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
c62a0ac4Smatt * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
c62a0ac4Smatt * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
c62a0ac4Smatt * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
c62a0ac4Smatt * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
c62a0ac4Smatt * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
c62a0ac4Smatt * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
c62a0ac4Smatt * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
c62a0ac4Smatt * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
c62a0ac4Smatt * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
c62a0ac4Smatt * POSSIBILITY OF SUCH DAMAGE.
c62a0ac4Smatt */
c62a0ac4Smatt
c62a0ac4Smatt/*
c62a0ac4Smatt * Driver for the AT91RM9200 clock tick.
c62a0ac4Smatt * We use Timer 1 for the system clock
c62a0ac4Smatt */
c62a0ac4Smatt
c62a0ac4Smatt#include <sys/cdefs.h>
*ef06fc5cSmaxv__KERNEL_RCSID(0, "$NetBSD: at91tctmr.c,v 1.9 2020/07/03 16:23:02 maxv Exp $");
c62a0ac4Smatt
c62a0ac4Smatt#include <sys/types.h>
c62a0ac4Smatt#include <sys/param.h>
c62a0ac4Smatt#include <sys/systm.h>
c62a0ac4Smatt#include <sys/kernel.h>
c62a0ac4Smatt#include <sys/time.h>
c62a0ac4Smatt#include <sys/timetc.h>
c62a0ac4Smatt#include <sys/device.h>
c62a0ac4Smatt
c62a0ac4Smatt#include <dev/clock_subr.h>
c62a0ac4Smatt
cf10107dSdyoung#include <sys/bus.h>
c62a0ac4Smatt#include <machine/intr.h>
c62a0ac4Smatt
c62a0ac4Smatt#include <arm/cpufunc.h>
c62a0ac4Smatt#include <arm/at91/at91reg.h>
c62a0ac4Smatt#include <arm/at91/at91var.h>
c62a0ac4Smatt#include <arm/at91/at91tcreg.h>
c62a0ac4Smatt
c62a0ac4Smatt#include <opt_hz.h>     /* for HZ */
c62a0ac4Smatt
c62a0ac4Smatt
c62a0ac4Smatt#define DEBUG_CLK
c62a0ac4Smatt#ifdef DEBUG_CLK
c62a0ac4Smatt#define DPRINTF(fmt...)  printf(fmt)
c62a0ac4Smatt#else
c62a0ac4Smatt#define DPRINTF(fmt...)
c62a0ac4Smatt#endif
c62a0ac4Smatt
c62a0ac4Smatt
c62a0ac4Smattstatic int at91tctmr_match(device_t, cfdata_t, void *);
c62a0ac4Smattstatic void at91tctmr_attach(device_t, device_t, void *);
c62a0ac4Smatt
c62a0ac4Smattvoid rtcinit(void);
c62a0ac4Smatt
c62a0ac4Smatt/* callback functions for intr_functions */
c62a0ac4Smattstatic int at91tctmr_intr(void* arg);
c62a0ac4Smatt
c62a0ac4Smattstruct at91tctmr_softc {
c62a0ac4Smatt	device_t	sc_dev;
c62a0ac4Smatt	u_char		*sc_addr;
c62a0ac4Smatt	int		sc_pid;
c62a0ac4Smatt	int		sc_initialized;
c62a0ac4Smatt	uint32_t	sc_timerclock;
c62a0ac4Smatt	uint32_t	sc_divider;
c62a0ac4Smatt	uint32_t	sc_usec_per_tick;
c62a0ac4Smatt};
c62a0ac4Smatt
c62a0ac4Smattstatic struct at91tctmr_softc *at91tctmr_sc = NULL;
238c9fcdSaymeric#if 0
c62a0ac4Smattstatic struct timeval lasttv;
238c9fcdSaymeric#endif
c62a0ac4Smatt
c62a0ac4Smatt
c62a0ac4Smatt
c62a0ac4Smatt/* Match value for clock timer; running at master clock, want HZ ticks per second  */
c62a0ac4Smatt/* NOTE: don't change there without visiting the functions below which      */
c62a0ac4Smatt/* convert between timer counts and microseconds                            */
c62a0ac4Smatt
c62a0ac4Smattstatic inline uint32_t
c62a0ac4Smattat91tctmr_count_to_usec(struct at91tctmr_softc *sc, uint32_t count)
c62a0ac4Smatt{
c62a0ac4Smatt    uint64_t tmp;
c62a0ac4Smatt
c62a0ac4Smatt    tmp = count;
c62a0ac4Smatt    tmp *= 1000000U;
c62a0ac4Smatt
c62a0ac4Smatt    return (tmp / sc->sc_timerclock);
c62a0ac4Smatt}
c62a0ac4Smatt
c62a0ac4Smatt#if 0
c62a0ac4Smatt/* This may only be called when overflow is avoided; typically, */
c62a0ac4Smatt/* it will be used when usec < USEC_PER_TICK              */
c62a0ac4Smattstatic uint32_t
c62a0ac4Smattusec_to_timer_count(uint32_t usec)
c62a0ac4Smatt{
c62a0ac4Smatt    uint32_t result;
c62a0ac4Smatt
c62a0ac4Smatt    /* convert specified number of usec to timer ticks, and round up */
c62a0ac4Smatt    result = (AT91_SCLK * usec) / 1000000;
c62a0ac4Smatt
c62a0ac4Smatt    if ((result * 1000000) != (usec * AT91_SCLK))
c62a0ac4Smatt    {
c62a0ac4Smatt        /* round up */
c62a0ac4Smatt        result += 1;
c62a0ac4Smatt    }
c62a0ac4Smatt
c62a0ac4Smatt    return result;
c62a0ac4Smatt
c62a0ac4Smatt}
c62a0ac4Smatt#endif
c62a0ac4Smatt
c62a0ac4Smatt/* macros to simplify writing to the timer controller */
08a4aba7Sskrllstatic inline uint32_t
c62a0ac4SmattREAD_TC(struct at91tctmr_softc *sc, uint offset)
c62a0ac4Smatt{
08a4aba7Sskrll	volatile uint32_t *addr = (void*)(sc->sc_addr + offset);
c62a0ac4Smatt	return *addr;
c62a0ac4Smatt}
c62a0ac4Smatt
c62a0ac4Smatt//bus_space_read_4(sc->sc_iot, sc->sc_ioh, offset)
c62a0ac4Smattstatic inline void
08a4aba7SskrllWRITE_TC(struct at91tctmr_softc *sc, uint offset, uint32_t value)
c62a0ac4Smatt{
08a4aba7Sskrll	volatile uint32_t *addr = (void*)(sc->sc_addr + offset);
c62a0ac4Smatt	*addr = value;
c62a0ac4Smatt}
c62a0ac4Smatt
c62a0ac4Smatt
c62a0ac4SmattCFATTACH_DECL_NEW(at91tctmr, sizeof(struct at91tctmr_softc),
c62a0ac4Smatt    at91tctmr_match, at91tctmr_attach, NULL, NULL);
c62a0ac4Smatt
238c9fcdSaymeric#if 0
c62a0ac4Smattstatic u_int at91tctmr_get_timecount(struct timecounter *);
c62a0ac4Smatt
c62a0ac4Smattstatic struct timecounter at91tctmr_timecounter = {
482eef70Srin	.tc_get_timecount = at91tctmr_get_timecount,
482eef70Srin	.tc_counter_mask = 0xffffffff,
482eef70Srin	.tc_frequency = COUNTS_PER_SEC,
482eef70Srin	.tc_name = "at91tctmr",
482eef70Srin	.tc_quality = 100,
c62a0ac4Smatt};
238c9fcdSaymeric#endif
c62a0ac4Smatt
c62a0ac4Smattstatic int
c62a0ac4Smattat91tctmr_match(device_t parent, cfdata_t match, void *aux)
c62a0ac4Smatt{
c62a0ac4Smatt	if (strcmp(match->cf_name, "at91tctmr") == 0)
c62a0ac4Smatt		return 2;
c62a0ac4Smatt	return 0;
c62a0ac4Smatt}
c62a0ac4Smatt
c62a0ac4Smattstatic void
c62a0ac4Smattat91tctmr_attach(device_t parent, device_t self, void *aux)
c62a0ac4Smatt{
c62a0ac4Smatt    struct at91tctmr_softc *sc = device_private(self);
c62a0ac4Smatt    struct at91bus_attach_args *sa = aux;
c62a0ac4Smatt
c62a0ac4Smatt    aprint_normal("\n");
c62a0ac4Smatt
c62a0ac4Smatt    sc->sc_dev = self;
c62a0ac4Smatt    sc->sc_addr = (void*)sa->sa_addr;
c62a0ac4Smatt    sc->sc_pid = sa->sa_pid;
c62a0ac4Smatt
c62a0ac4Smatt    if (at91tctmr_sc == NULL)
c62a0ac4Smatt        at91tctmr_sc = sc;
c62a0ac4Smatt
c62a0ac4Smatt    at91_peripheral_clock(sc->sc_pid, 1);
c62a0ac4Smatt
c62a0ac4Smatt    WRITE_TC(sc, TC_CCR, TC_CCR_CLKDIS);
c62a0ac4Smatt    WRITE_TC(sc, TC_IDR, -1);	/* make sure interrupts are disabled	*/
c62a0ac4Smatt
c62a0ac4Smatt    /* find divider */
08a4aba7Sskrll    uint32_t cmr = 0;
c62a0ac4Smatt    if (AT91_MSTCLK / 2U / HZ <= 65536) {
c62a0ac4Smatt      sc->sc_timerclock = AT91_MSTCLK / 2U;
c62a0ac4Smatt      cmr = TC_CMR_TCCLKS_MCK_DIV_2;
c62a0ac4Smatt    } else if (AT91_MSTCLK / 8U / HZ <= 65536) {
c62a0ac4Smatt      sc->sc_timerclock = AT91_MSTCLK / 8U;
c62a0ac4Smatt      cmr = TC_CMR_TCCLKS_MCK_DIV_8;
c62a0ac4Smatt    } else if (AT91_MSTCLK / 32U / HZ <= 65536) {
c62a0ac4Smatt      sc->sc_timerclock = AT91_MSTCLK / 32U;
c62a0ac4Smatt      cmr = TC_CMR_TCCLKS_MCK_DIV_32;
c62a0ac4Smatt    } else if (AT91_MSTCLK / 128U / HZ <= 65536) {
c62a0ac4Smatt      sc->sc_timerclock = AT91_MSTCLK / 128U;
c62a0ac4Smatt      cmr = TC_CMR_TCCLKS_MCK_DIV_128;
c62a0ac4Smatt    } else
a0bdfc61Smatt      panic("%s: cannot setup timer to reach HZ", device_xname(sc->sc_dev));
c62a0ac4Smatt
c62a0ac4Smatt    sc->sc_divider = (sc->sc_timerclock + HZ - 1) / HZ; /* round up */
c62a0ac4Smatt    sc->sc_usec_per_tick = 1000000UL / (sc->sc_timerclock / sc->sc_divider);
c62a0ac4Smatt
c62a0ac4Smatt    WRITE_TC(sc, TC_CMR, TC_CMR_WAVE | cmr | TC_CMR_WAVSEL_UP_RC);
c62a0ac4Smatt    WRITE_TC(sc, TC_CCR, TC_CCR_CLKEN);
c62a0ac4Smatt    WRITE_TC(sc, TC_RC,  sc->sc_divider - 1);
c62a0ac4Smatt    WRITE_TC(sc, TC_CCR, TC_CCR_SWTRG);
c62a0ac4Smatt
c62a0ac4Smatt    sc->sc_initialized = 1;
c62a0ac4Smatt
c62a0ac4Smatt    DPRINTF("%s: done, tclock=%"PRIu32" div=%"PRIu32" uspertick=%"PRIu32"\n", __FUNCTION__, sc->sc_timerclock, sc->sc_divider, sc->sc_usec_per_tick);
c62a0ac4Smatt
c62a0ac4Smatt}
c62a0ac4Smatt
c62a0ac4Smatt/*
c62a0ac4Smatt * at91tctmr_intr:
c62a0ac4Smatt *
c62a0ac4Smatt *Handle the hardclock interrupt.
c62a0ac4Smatt */
c62a0ac4Smattstatic int
c62a0ac4Smattat91tctmr_intr(void *arg)
c62a0ac4Smatt{
c62a0ac4Smatt    struct at91tctmr_softc *sc = arg;
c62a0ac4Smatt
c62a0ac4Smatt    /* make sure it's the kernel timer that generated the interrupt  */
c62a0ac4Smatt    /* need to do this since the interrupt line is shared by the    */
c62a0ac4Smatt    /* other interval and PWM timers                                */
c62a0ac4Smatt    if (READ_TC(sc, TC_SR) & TC_SR_CPCS) {
c62a0ac4Smatt        /* call the kernel timer handler */
c62a0ac4Smatt        hardclock((struct clockframe*) arg);
c62a0ac4Smatt        return 1;
c62a0ac4Smatt    } else {
c62a0ac4Smatt        /* it's one of the other timers; just pass it on */
c62a0ac4Smatt        return 0;
c62a0ac4Smatt    }
c62a0ac4Smatt}
c62a0ac4Smatt
c62a0ac4Smatt/*
c62a0ac4Smatt * setstatclockrate:
c62a0ac4Smatt *
c62a0ac4Smatt *Set the rate of the statistics clock.
c62a0ac4Smatt *
c62a0ac4Smatt *We assume that hz is either stathz or profhz, and that neither
c62a0ac4Smatt *will change after being set by cpu_initclocks().  We could
c62a0ac4Smatt *recalculate the intervals here, but that would be a pain.
c62a0ac4Smatt */
c62a0ac4Smattvoid
c62a0ac4Smattsetstatclockrate(int hzz)
c62a0ac4Smatt{
c62a0ac4Smatt        /* use hardclock */
c62a0ac4Smatt	(void)hzz;
c62a0ac4Smatt}
c62a0ac4Smatt
c62a0ac4Smatt/*
c62a0ac4Smatt * cpu_initclocks:
c62a0ac4Smatt *
c62a0ac4Smatt *Initialize the clock and get it going.
c62a0ac4Smatt */
c62a0ac4Smattstatic void udelay(unsigned int usec);
c62a0ac4Smatt
c62a0ac4Smattvoid
c62a0ac4Smattcpu_initclocks(void)
c62a0ac4Smatt{
c62a0ac4Smatt    struct at91tctmr_softc *sc = at91tctmr_sc;
c62a0ac4Smatt
c62a0ac4Smatt    if (!sc || !sc->sc_initialized)
c62a0ac4Smatt	panic("%s: driver has not been initialized! (sc=%p)", __FUNCTION__, sc);
c62a0ac4Smatt
c62a0ac4Smatt    hz = sc->sc_timerclock / sc->sc_divider;
c62a0ac4Smatt    stathz = profhz = 0;
c62a0ac4Smatt
c62a0ac4Smatt    /* set up and enable interval timer 1 as kernel timer, */
c62a0ac4Smatt    /* using 32kHz clock source */
c62a0ac4Smatt
c62a0ac4Smatt    /* register interrupt handler */
c62a0ac4Smatt    at91_intr_establish(sc->sc_pid, IPL_CLOCK, INTR_HIGH_LEVEL, at91tctmr_intr, sc);
c62a0ac4Smatt
c62a0ac4Smatt    /* enable interrupts from timer */
c62a0ac4Smatt    WRITE_TC(sc, TC_IER, TC_SR_CPCS);
c62a0ac4Smatt}
c62a0ac4Smatt
c62a0ac4Smatt
c62a0ac4Smatt
c62a0ac4Smatt
c62a0ac4Smattstatic void udelay(unsigned int usec)
c62a0ac4Smatt{
c62a0ac4Smatt    struct at91tctmr_softc *sc = at91tctmr_sc;
08a4aba7Sskrll    uint32_t prev_cvr, cvr, divi = READ_TC(sc, TC_RC), diff;
c62a0ac4Smatt    int prev_ticks, ticks, ticks2;
c62a0ac4Smatt    unsigned footick = (sc->sc_timerclock * 64ULL / 1000000UL);
c62a0ac4Smatt
c62a0ac4Smatt    if (usec > 0) {
*ef06fc5cSmaxv      prev_ticks = getticks();
c62a0ac4Smatt      __insn_barrier();
c62a0ac4Smatt      prev_cvr = READ_TC(sc, TC_CV);
*ef06fc5cSmaxv      ticks = getticks();
c62a0ac4Smatt      __insn_barrier();
c62a0ac4Smatt      if (ticks != prev_ticks) {
c62a0ac4Smatt	prev_cvr = READ_TC(sc, TC_CV);
c62a0ac4Smatt	prev_ticks = ticks;
c62a0ac4Smatt      }
c62a0ac4Smatt      for (;;) {
*ef06fc5cSmaxv	ticks = getticks();
c62a0ac4Smatt	__insn_barrier();
c62a0ac4Smatt	cvr = READ_TC(sc, TC_CV);
*ef06fc5cSmaxv	ticks2 = getticks();
c62a0ac4Smatt	__insn_barrier();
c62a0ac4Smatt	if (ticks2 != ticks) {
c62a0ac4Smatt	  cvr = READ_TC(sc, TC_CV);
c62a0ac4Smatt	}
c62a0ac4Smatt	diff = (ticks2 - prev_ticks) * divi;
c62a0ac4Smatt	if (cvr < prev_cvr) {
c62a0ac4Smatt	  if (!diff)
c62a0ac4Smatt	    diff = divi;
c62a0ac4Smatt	  diff -= prev_cvr - cvr;
c62a0ac4Smatt	} else
c62a0ac4Smatt	  diff += cvr - prev_cvr;
c62a0ac4Smatt	diff = diff * 64 / footick;
c62a0ac4Smatt	if (diff) {
c62a0ac4Smatt	  if (usec <= diff)
c62a0ac4Smatt	    break;
c62a0ac4Smatt	  prev_ticks = ticks2;
c62a0ac4Smatt	  prev_cvr = (prev_cvr + footick * diff / 64) % divi;
c62a0ac4Smatt	  usec -= diff;
c62a0ac4Smatt	}
c62a0ac4Smatt      }
c62a0ac4Smatt    }
c62a0ac4Smatt}
c62a0ac4Smatt
c62a0ac4Smatt
c62a0ac4Smatt
c62a0ac4Smatt/*
c62a0ac4Smatt * delay:
c62a0ac4Smatt *
c62a0ac4Smatt *Delay for at least N microseconds. Note that due to our coarse clock,
c62a0ac4Smatt *  our resolution is 61 us. But we round up so we'll wait at least as
c62a0ac4Smatt *  long as requested.
c62a0ac4Smatt */
c62a0ac4Smattvoid
c62a0ac4Smattdelay(unsigned int usec)
c62a0ac4Smatt{
c62a0ac4Smatt    struct at91tctmr_softc *sc = at91tctmr_sc;
c62a0ac4Smatt
c62a0ac4Smatt#ifdef DEBUG
c62a0ac4Smatt    if (sc == NULL) {
c62a0ac4Smatt        printf("delay: called before start at91tc\n");
c62a0ac4Smatt        return;
c62a0ac4Smatt    }
c62a0ac4Smatt#endif
c62a0ac4Smatt
c62a0ac4Smatt    if (usec >= sc->sc_usec_per_tick) {
c62a0ac4Smatt        /* have more than 1 tick; just do in ticks */
c62a0ac4Smatt        unsigned int ticks = (usec + sc->sc_usec_per_tick - 1) / sc->sc_usec_per_tick;
c62a0ac4Smatt        while (ticks-- > 0) {
c62a0ac4Smatt	  udelay(sc->sc_usec_per_tick);
c62a0ac4Smatt	}
c62a0ac4Smatt    } else {
c62a0ac4Smatt        /* less than 1 tick; can do as usec */
c62a0ac4Smatt        udelay(usec);
c62a0ac4Smatt    }
c62a0ac4Smatt
c62a0ac4Smatt}
c62a0ac4Smatt