Linux 4.19-rc7

[linux-2.6/btrfs-unstable.git] / arch / powerpc / kernel / tau_6xx.c

// SPDX-License-Identifier: GPL-2.0
/*
 * temp.c       Thermal management for cpu's with Thermal Assist Units
 *
 * Written by Troy Benjegerdes <hozer@drgw.net>
 *
 * TODO:
 * dynamic power management to limit peak CPU temp (using ICTC)
 * calibration???
 *
 * Silly, crazy ideas: use cpu load (from scheduler) and ICTC to extend battery
 * life in portables, and add a 'performance/watt' metric somewhere in /proc
 */

#include <linux/errno.h>
#include <linux/jiffies.h>
#include <linux/kernel.h>
#include <linux/param.h>
#include <linux/string.h>
#include <linux/mm.h>
#include <linux/interrupt.h>
#include <linux/init.h>

#include <asm/io.h>
#include <asm/reg.h>
#include <asm/nvram.h>
#include <asm/cache.h>
#include <asm/8xx_immap.h>
#include <asm/machdep.h>
#include <asm/asm-prototypes.h>

#include "setup.h"

static struct tau_temp
{
        int interrupts;
        unsigned char low;
        unsigned char high;
        unsigned char grew;
} tau[NR_CPUS];

struct timer_list tau_timer;

#undef DEBUG

/* TODO: put these in a /proc interface, with some sanity checks, and maybe
 * dynamic adjustment to minimize # of interrupts */
/* configurable values for step size and how much to expand the window when
 * we get an interrupt. These are based on the limit that was out of range */
#define step_size               2       /* step size when temp goes out of range */
#define window_expand           1       /* expand the window by this much */
/* configurable values for shrinking the window */
#define shrink_timer    2*HZ    /* period between shrinking the window */
#define min_window      2       /* minimum window size, degrees C */

static void set_thresholds(unsigned long cpu)
{
#ifdef CONFIG_TAU_INT
        /*
         * setup THRM1,
         * threshold, valid bit, enable interrupts, interrupt when below threshold
         */
        mtspr(SPRN_THRM1, THRM1_THRES(tau[cpu].low) | THRM1_V | THRM1_TIE | THRM1_TID);

        /* setup THRM2,
         * threshold, valid bit, enable interrupts, interrupt when above threshold
         */
        mtspr (SPRN_THRM2, THRM1_THRES(tau[cpu].high) | THRM1_V | THRM1_TIE);
#else
        /* same thing but don't enable interrupts */
        mtspr(SPRN_THRM1, THRM1_THRES(tau[cpu].low) | THRM1_V | THRM1_TID);
        mtspr(SPRN_THRM2, THRM1_THRES(tau[cpu].high) | THRM1_V);
#endif
}

static void TAUupdate(int cpu)
{
        unsigned thrm;

#ifdef DEBUG
        printk("TAUupdate ");
#endif

        /* if both thresholds are crossed, the step_sizes cancel out
         * and the window winds up getting expanded twice. */
        if((thrm = mfspr(SPRN_THRM1)) & THRM1_TIV){ /* is valid? */
                if(thrm & THRM1_TIN){ /* crossed low threshold */
                        if (tau[cpu].low >= step_size){
                                tau[cpu].low -= step_size;
                                tau[cpu].high -= (step_size - window_expand);
                        }
                        tau[cpu].grew = 1;
#ifdef DEBUG
                        printk("low threshold crossed ");
#endif
                }
        }
        if((thrm = mfspr(SPRN_THRM2)) & THRM1_TIV){ /* is valid? */
                if(thrm & THRM1_TIN){ /* crossed high threshold */
                        if (tau[cpu].high <= 127-step_size){
                                tau[cpu].low += (step_size - window_expand);
                                tau[cpu].high += step_size;
                        }
                        tau[cpu].grew = 1;
#ifdef DEBUG
                        printk("high threshold crossed ");
#endif
                }
        }

#ifdef DEBUG
        printk("grew = %d\n", tau[cpu].grew);
#endif

#ifndef CONFIG_TAU_INT /* tau_timeout will do this if not using interrupts */
        set_thresholds(cpu);
#endif

}

#ifdef CONFIG_TAU_INT
/*
 * TAU interrupts - called when we have a thermal assist unit interrupt
 * with interrupts disabled
 */

void TAUException(struct pt_regs * regs)
{
        int cpu = smp_processor_id();

        irq_enter();
        tau[cpu].interrupts++;

        TAUupdate(cpu);

        irq_exit();
}
#endif /* CONFIG_TAU_INT */

static void tau_timeout(void * info)
{
        int cpu;
        unsigned long flags;
        int size;
        int shrink;

        /* disabling interrupts *should* be okay */
        local_irq_save(flags);
        cpu = smp_processor_id();

#ifndef CONFIG_TAU_INT
        TAUupdate(cpu);
#endif

        size = tau[cpu].high - tau[cpu].low;
        if (size > min_window && ! tau[cpu].grew) {
                /* do an exponential shrink of half the amount currently over size */
                shrink = (2 + size - min_window) / 4;
                if (shrink) {
                        tau[cpu].low += shrink;
                        tau[cpu].high -= shrink;
                } else { /* size must have been min_window + 1 */
                        tau[cpu].low += 1;
#if 1 /* debug */
                        if ((tau[cpu].high - tau[cpu].low) != min_window){
                                printk(KERN_ERR "temp.c: line %d, logic error\n", __LINE__);
                        }
#endif
                }
        }

        tau[cpu].grew = 0;

        set_thresholds(cpu);

        /*
         * Do the enable every time, since otherwise a bunch of (relatively)
         * complex sleep code needs to be added. One mtspr every time
         * tau_timeout is called is probably not a big deal.
         *
         * Enable thermal sensor and set up sample interval timer
         * need 20 us to do the compare.. until a nice 'cpu_speed' function
         * call is implemented, just assume a 500 mhz clock. It doesn't really
         * matter if we take too long for a compare since it's all interrupt
         * driven anyway.
         *
         * use a extra long time.. (60 us @ 500 mhz)
         */
        mtspr(SPRN_THRM3, THRM3_SITV(500*60) | THRM3_E);

        local_irq_restore(flags);
}

static void tau_timeout_smp(struct timer_list *unused)
{

        /* schedule ourselves to be run again */
        mod_timer(&tau_timer, jiffies + shrink_timer) ;
        on_each_cpu(tau_timeout, NULL, 0);
}

/*
 * setup the TAU
 *
 * Set things up to use THRM1 as a temperature lower bound, and THRM2 as an upper bound.
 * Start off at zero
 */

int tau_initialized = 0;

static void __init TAU_init_smp(void *info)
{
        unsigned long cpu = smp_processor_id();

        /* set these to a reasonable value and let the timer shrink the
         * window */
        tau[cpu].low = 5;
        tau[cpu].high = 120;

        set_thresholds(cpu);
}

static int __init TAU_init(void)
{
        /* We assume in SMP that if one CPU has TAU support, they
         * all have it --BenH
         */
        if (!cpu_has_feature(CPU_FTR_TAU)) {
                printk("Thermal assist unit not available\n");
                tau_initialized = 0;
                return 1;
        }


        /* first, set up the window shrinking timer */
        timer_setup(&tau_timer, tau_timeout_smp, 0);
        tau_timer.expires = jiffies + shrink_timer;
        add_timer(&tau_timer);

        on_each_cpu(TAU_init_smp, NULL, 0);

        printk("Thermal assist unit ");
#ifdef CONFIG_TAU_INT
        printk("using interrupts, ");
#else
        printk("using timers, ");
#endif
        printk("shrink_timer: %d jiffies\n", shrink_timer);
        tau_initialized = 1;

        return 0;
}

__initcall(TAU_init);

/*
 * return current temp
 */

u32 cpu_temp_both(unsigned long cpu)
{
        return ((tau[cpu].high << 16) | tau[cpu].low);
}

u32 cpu_temp(unsigned long cpu)
{
        return ((tau[cpu].high + tau[cpu].low) / 2);
}

u32 tau_interrupts(unsigned long cpu)
{
        return (tau[cpu].interrupts);
}