Merge tag 'rtc-5.3' of git://git.kernel.org/pub/scm/linux/kernel/git/abelloni/linux

[mirror_ubuntu-jammy-kernel.git] / drivers / clocksource / timer-stm32.c

// SPDX-License-Identifier: GPL-2.0-only
/*
 * Copyright (C) Maxime Coquelin 2015
 * Author:  Maxime Coquelin <mcoquelin.stm32@gmail.com>
 *
 * Inspired by time-efm32.c from Uwe Kleine-Koenig
 */

#include <linux/kernel.h>
#include <linux/clocksource.h>
#include <linux/clockchips.h>
#include <linux/delay.h>
#include <linux/irq.h>
#include <linux/interrupt.h>
#include <linux/of.h>
#include <linux/of_address.h>
#include <linux/of_irq.h>
#include <linux/clk.h>
#include <linux/reset.h>
#include <linux/sched_clock.h>
#include <linux/slab.h>

#include "timer-of.h"

#define TIM_CR1         0x00
#define TIM_DIER        0x0c
#define TIM_SR          0x10
#define TIM_EGR         0x14
#define TIM_CNT         0x24
#define TIM_PSC         0x28
#define TIM_ARR         0x2c
#define TIM_CCR1        0x34

#define TIM_CR1_CEN     BIT(0)
#define TIM_CR1_UDIS    BIT(1)
#define TIM_CR1_OPM     BIT(3)
#define TIM_CR1_ARPE    BIT(7)

#define TIM_DIER_UIE    BIT(0)
#define TIM_DIER_CC1IE  BIT(1)

#define TIM_SR_UIF      BIT(0)

#define TIM_EGR_UG      BIT(0)

#define TIM_PSC_MAX     USHRT_MAX
#define TIM_PSC_CLKRATE 10000

struct stm32_timer_private {
        int bits;
};

/**
 * stm32_timer_of_bits_set - set accessor helper
 * @to: a timer_of structure pointer
 * @bits: the number of bits (16 or 32)
 *
 * Accessor helper to set the number of bits in the timer-of private
 * structure.
 *
 */
static void stm32_timer_of_bits_set(struct timer_of *to, int bits)
{
        struct stm32_timer_private *pd = to->private_data;

        pd->bits = bits;
}

/**
 * stm32_timer_of_bits_get - get accessor helper
 * @to: a timer_of structure pointer
 *
 * Accessor helper to get the number of bits in the timer-of private
 * structure.
 *
 * Returns an integer corresponding to the number of bits.
 */
static int stm32_timer_of_bits_get(struct timer_of *to)
{
        struct stm32_timer_private *pd = to->private_data;

        return pd->bits;
}

static void __iomem *stm32_timer_cnt __read_mostly;

static u64 notrace stm32_read_sched_clock(void)
{
        return readl_relaxed(stm32_timer_cnt);
}

static struct delay_timer stm32_timer_delay;

static unsigned long stm32_read_delay(void)
{
        return readl_relaxed(stm32_timer_cnt);
}

static void stm32_clock_event_disable(struct timer_of *to)
{
        writel_relaxed(0, timer_of_base(to) + TIM_DIER);
}

/**
 * stm32_timer_start - Start the counter without event
 * @to: a timer_of structure pointer
 *
 * Start the timer in order to have the counter reset and start
 * incrementing but disable interrupt event when there is a counter
 * overflow. By default, the counter direction is used as upcounter.
 */
static void stm32_timer_start(struct timer_of *to)
{
        writel_relaxed(TIM_CR1_UDIS | TIM_CR1_CEN, timer_of_base(to) + TIM_CR1);
}

static int stm32_clock_event_shutdown(struct clock_event_device *clkevt)
{
        struct timer_of *to = to_timer_of(clkevt);

        stm32_clock_event_disable(to);

        return 0;
}

static int stm32_clock_event_set_next_event(unsigned long evt,
                                            struct clock_event_device *clkevt)
{
        struct timer_of *to = to_timer_of(clkevt);
        unsigned long now, next;

        next = readl_relaxed(timer_of_base(to) + TIM_CNT) + evt;
        writel_relaxed(next, timer_of_base(to) + TIM_CCR1);
        now = readl_relaxed(timer_of_base(to) + TIM_CNT);

        if ((next - now) > evt)
                return -ETIME;

        writel_relaxed(TIM_DIER_CC1IE, timer_of_base(to) + TIM_DIER);

        return 0;
}

static int stm32_clock_event_set_periodic(struct clock_event_device *clkevt)
{
        struct timer_of *to = to_timer_of(clkevt);

        stm32_timer_start(to);

        return stm32_clock_event_set_next_event(timer_of_period(to), clkevt);
}

static int stm32_clock_event_set_oneshot(struct clock_event_device *clkevt)
{
        struct timer_of *to = to_timer_of(clkevt);

        stm32_timer_start(to);

        return 0;
}

static irqreturn_t stm32_clock_event_handler(int irq, void *dev_id)
{
        struct clock_event_device *clkevt = (struct clock_event_device *)dev_id;
        struct timer_of *to = to_timer_of(clkevt);

        writel_relaxed(0, timer_of_base(to) + TIM_SR);

        if (clockevent_state_periodic(clkevt))
                stm32_clock_event_set_periodic(clkevt);
        else
                stm32_clock_event_shutdown(clkevt);

        clkevt->event_handler(clkevt);

        return IRQ_HANDLED;
}

/**
 * stm32_timer_width - Sort out the timer width (32/16)
 * @to: a pointer to a timer-of structure
 *
 * Write the 32-bit max value and read/return the result. If the timer
 * is 32 bits wide, the result will be UINT_MAX, otherwise it will
 * be truncated by the 16-bit register to USHRT_MAX.
 *
 */
static void __init stm32_timer_set_width(struct timer_of *to)
{
        u32 width;

        writel_relaxed(UINT_MAX, timer_of_base(to) + TIM_ARR);

        width = readl_relaxed(timer_of_base(to) + TIM_ARR);

        stm32_timer_of_bits_set(to, width == UINT_MAX ? 32 : 16);
}

/**
 * stm32_timer_set_prescaler - Compute and set the prescaler register
 * @to: a pointer to a timer-of structure
 *
 * Depending on the timer width, compute the prescaler to always
 * target a 10MHz timer rate for 16 bits. 32-bit timers are
 * considered precise and long enough to not use the prescaler.
 */
static void __init stm32_timer_set_prescaler(struct timer_of *to)
{
        int prescaler = 1;

        if (stm32_timer_of_bits_get(to) != 32) {
                prescaler = DIV_ROUND_CLOSEST(timer_of_rate(to),
                                              TIM_PSC_CLKRATE);
                /*
                 * The prescaler register is an u16, the variable
                 * can't be greater than TIM_PSC_MAX, let's cap it in
                 * this case.
                 */
                prescaler = prescaler < TIM_PSC_MAX ? prescaler : TIM_PSC_MAX;
        }

        writel_relaxed(prescaler - 1, timer_of_base(to) + TIM_PSC);
        writel_relaxed(TIM_EGR_UG, timer_of_base(to) + TIM_EGR);
        writel_relaxed(0, timer_of_base(to) + TIM_SR);

        /* Adjust rate and period given the prescaler value */
        to->of_clk.rate = DIV_ROUND_CLOSEST(to->of_clk.rate, prescaler);
        to->of_clk.period = DIV_ROUND_UP(to->of_clk.rate, HZ);
}

static int __init stm32_clocksource_init(struct timer_of *to)
{
        u32 bits = stm32_timer_of_bits_get(to);
        const char *name = to->np->full_name;

        /*
         * This driver allows to register several timers and relies on
         * the generic time framework to select the right one.
         * However, nothing allows to do the same for the
         * sched_clock. We are not interested in a sched_clock for the
         * 16-bit timers but only for the 32-bit one, so if no 32-bit
         * timer is registered yet, we select this 32-bit timer as a
         * sched_clock.
         */
        if (bits == 32 && !stm32_timer_cnt) {

                /*
                 * Start immediately the counter as we will be using
                 * it right after.
                 */
                stm32_timer_start(to);

                stm32_timer_cnt = timer_of_base(to) + TIM_CNT;
                sched_clock_register(stm32_read_sched_clock, bits, timer_of_rate(to));
                pr_info("%s: STM32 sched_clock registered\n", name);

                stm32_timer_delay.read_current_timer = stm32_read_delay;
                stm32_timer_delay.freq = timer_of_rate(to);
                register_current_timer_delay(&stm32_timer_delay);
                pr_info("%s: STM32 delay timer registered\n", name);
        }

        return clocksource_mmio_init(timer_of_base(to) + TIM_CNT, name,
                                     timer_of_rate(to), bits == 32 ? 250 : 100,
                                     bits, clocksource_mmio_readl_up);
}

static void __init stm32_clockevent_init(struct timer_of *to)
{
        u32 bits = stm32_timer_of_bits_get(to);

        to->clkevt.name = to->np->full_name;
        to->clkevt.features = CLOCK_EVT_FEAT_PERIODIC | CLOCK_EVT_FEAT_ONESHOT;
        to->clkevt.set_state_shutdown = stm32_clock_event_shutdown;
        to->clkevt.set_state_periodic = stm32_clock_event_set_periodic;
        to->clkevt.set_state_oneshot = stm32_clock_event_set_oneshot;
        to->clkevt.tick_resume = stm32_clock_event_shutdown;
        to->clkevt.set_next_event = stm32_clock_event_set_next_event;
        to->clkevt.rating = bits == 32 ? 250 : 100;

        clockevents_config_and_register(&to->clkevt, timer_of_rate(to), 0x1,
                                        (1 <<  bits) - 1);

        pr_info("%pOF: STM32 clockevent driver initialized (%d bits)\n",
                to->np, bits);
}

static int __init stm32_timer_init(struct device_node *node)
{
        struct reset_control *rstc;
        struct timer_of *to;
        int ret;

        to = kzalloc(sizeof(*to), GFP_KERNEL);
        if (!to)
                return -ENOMEM;

        to->flags = TIMER_OF_IRQ | TIMER_OF_CLOCK | TIMER_OF_BASE;
        to->of_irq.handler = stm32_clock_event_handler;

        ret = timer_of_init(node, to);
        if (ret)
                goto err;

        to->private_data = kzalloc(sizeof(struct stm32_timer_private),
                                   GFP_KERNEL);
        if (!to->private_data) {
                ret = -ENOMEM;
                goto deinit;
        }

        rstc = of_reset_control_get(node, NULL);
        if (!IS_ERR(rstc)) {
                reset_control_assert(rstc);
                reset_control_deassert(rstc);
        }

        stm32_timer_set_width(to);

        stm32_timer_set_prescaler(to);

        ret = stm32_clocksource_init(to);
        if (ret)
                goto deinit;

        stm32_clockevent_init(to);
        return 0;

deinit:
        timer_of_cleanup(to);
err:
        kfree(to);
        return ret;
}

TIMER_OF_DECLARE(stm32, "st,stm32-timer", stm32_timer_init);