/* * Copyright (c) 2014-2015, The Linux Foundation. All rights reserved. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License version 2 and * only version 2 as published by the Free Software Foundation. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. */ #define pr_fmt(fmt) "cache-hwmon: " fmt #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "governor.h" #include "governor_cache_hwmon.h" struct cache_hwmon_node { unsigned int cycles_per_low_req; unsigned int cycles_per_med_req; unsigned int cycles_per_high_req; unsigned int min_busy; unsigned int max_busy; unsigned int tolerance_mrps; unsigned int guard_band_mhz; unsigned int decay_rate; unsigned long prev_mhz; ktime_t prev_ts; bool mon_started; struct list_head list; void *orig_data; struct cache_hwmon *hw; struct attribute_group *attr_grp; }; static LIST_HEAD(cache_hwmon_list); static DEFINE_MUTEX(list_lock); static int use_cnt; static DEFINE_MUTEX(register_lock); static DEFINE_MUTEX(monitor_lock); #define show_attr(name) \ static ssize_t show_##name(struct device *dev, \ struct device_attribute *attr, char *buf) \ { \ struct devfreq *df = to_devfreq(dev); \ struct cache_hwmon_node *hw = df->data; \ return snprintf(buf, PAGE_SIZE, "%u\n", hw->name); \ } #define store_attr(name, _min, _max) \ static ssize_t store_##name(struct device *dev, \ struct device_attribute *attr, const char *buf, \ size_t count) \ { \ int ret; \ unsigned int val; \ struct devfreq *df = to_devfreq(dev); \ struct cache_hwmon_node *hw = df->data; \ ret = sscanf(buf, "%u", &val); \ if (ret != 1) \ return -EINVAL; \ val = max(val, _min); \ val = min(val, _max); \ hw->name = val; \ return count; \ } #define gov_attr(__attr, min, max) \ show_attr(__attr) \ store_attr(__attr, min, max) \ static DEVICE_ATTR(__attr, 0644, show_##__attr, store_##__attr) #define MIN_MS 10U #define MAX_MS 500U static struct cache_hwmon_node *find_hwmon_node(struct devfreq *df) { struct cache_hwmon_node *node, *found = NULL; mutex_lock(&list_lock); list_for_each_entry(node, &cache_hwmon_list, list) if (node->hw->dev == df->dev.parent || node->hw->of_node == df->dev.parent->of_node) { found = node; break; } mutex_unlock(&list_lock); return found; } static unsigned long measure_mrps_and_set_irq(struct cache_hwmon_node *node, struct mrps_stats *stat) { ktime_t ts; unsigned int us; struct cache_hwmon *hw = node->hw; /* * Since we are stopping the counters, we don't want this short work * to be interrupted by other tasks and cause the measurements to be * wrong. Not blocking interrupts to avoid affecting interrupt * latency and since they should be short anyway because they run in * atomic context. */ preempt_disable(); ts = ktime_get(); us = ktime_to_us(ktime_sub(ts, node->prev_ts)); if (!us) us = 1; hw->meas_mrps_and_set_irq(hw, node->tolerance_mrps, us, stat); node->prev_ts = ts; preempt_enable(); trace_cache_hwmon_meas(dev_name(hw->df->dev.parent), stat->mrps[HIGH], stat->mrps[MED], stat->mrps[LOW], stat->busy_percent, us); return 0; } static void compute_cache_freq(struct cache_hwmon_node *node, struct mrps_stats *mrps, unsigned long *freq) { unsigned long new_mhz; unsigned int busy; new_mhz = mrps->mrps[HIGH] * node->cycles_per_high_req + mrps->mrps[MED] * node->cycles_per_med_req + mrps->mrps[LOW] * node->cycles_per_low_req; busy = max(node->min_busy, mrps->busy_percent); busy = min(node->max_busy, busy); new_mhz *= 100; new_mhz /= busy; if (new_mhz < node->prev_mhz) { new_mhz = new_mhz * node->decay_rate + node->prev_mhz * (100 - node->decay_rate); new_mhz /= 100; } node->prev_mhz = new_mhz; new_mhz += node->guard_band_mhz; *freq = new_mhz * 1000; trace_cache_hwmon_update(dev_name(node->hw->df->dev.parent), *freq); } #define TOO_SOON_US (1 * USEC_PER_MSEC) int update_cache_hwmon(struct cache_hwmon *hwmon) { struct cache_hwmon_node *node; struct devfreq *df; ktime_t ts; unsigned int us; int ret; if (!hwmon) return -EINVAL; df = hwmon->df; if (!df) return -ENODEV; node = df->data; if (!node) return -ENODEV; mutex_lock(&monitor_lock); if (!node->mon_started) { mutex_unlock(&monitor_lock); return -EBUSY; } dev_dbg(df->dev.parent, "Got update request\n"); devfreq_monitor_stop(df); /* * Don't recalc cache freq if the interrupt comes right after a * previous cache freq calculation. This is done for two reasons: * * 1. Sampling the cache request during a very short duration can * result in a very inaccurate measurement due to very short * bursts. * 2. This can only happen if the limit was hit very close to the end * of the previous sample period. Which means the current cache * request estimate is not very off and doesn't need to be * readjusted. */ ts = ktime_get(); us = ktime_to_us(ktime_sub(ts, node->prev_ts)); if (us > TOO_SOON_US) { mutex_lock(&df->lock); ret = update_devfreq(df); if (ret) dev_err(df->dev.parent, "Unable to update freq on request!\n"); mutex_unlock(&df->lock); } devfreq_monitor_start(df); mutex_unlock(&monitor_lock); return 0; } static int devfreq_cache_hwmon_get_freq(struct devfreq *df, unsigned long *freq, u32 *flag) { struct mrps_stats stat; struct cache_hwmon_node *node = df->data; memset(&stat, 0, sizeof(stat)); measure_mrps_and_set_irq(node, &stat); compute_cache_freq(node, &stat, freq); return 0; } gov_attr(cycles_per_low_req, 1U, 100U); gov_attr(cycles_per_med_req, 1U, 100U); gov_attr(cycles_per_high_req, 1U, 100U); gov_attr(min_busy, 1U, 100U); gov_attr(max_busy, 1U, 100U); gov_attr(tolerance_mrps, 0U, 100U); gov_attr(guard_band_mhz, 0U, 500U); gov_attr(decay_rate, 0U, 100U); static struct attribute *dev_attr[] = { &dev_attr_cycles_per_low_req.attr, &dev_attr_cycles_per_med_req.attr, &dev_attr_cycles_per_high_req.attr, &dev_attr_min_busy.attr, &dev_attr_max_busy.attr, &dev_attr_tolerance_mrps.attr, &dev_attr_guard_band_mhz.attr, &dev_attr_decay_rate.attr, NULL, }; static struct attribute_group dev_attr_group = { .name = "cache_hwmon", .attrs = dev_attr, }; static int start_monitoring(struct devfreq *df) { int ret; struct mrps_stats mrps; struct device *dev = df->dev.parent; struct cache_hwmon_node *node; struct cache_hwmon *hw; node = find_hwmon_node(df); if (!node) { dev_err(dev, "Unable to find HW monitor!\n"); return -ENODEV; } hw = node->hw; hw->df = df; node->orig_data = df->data; df->data = node; node->prev_ts = ktime_get(); node->prev_mhz = 0; mrps.mrps[HIGH] = (df->previous_freq / 1000) - node->guard_band_mhz; mrps.mrps[HIGH] /= node->cycles_per_high_req; mrps.mrps[MED] = mrps.mrps[LOW] = 0; ret = hw->start_hwmon(hw, &mrps); if (ret) { dev_err(dev, "Unable to start HW monitor!\n"); goto err_start; } mutex_lock(&monitor_lock); devfreq_monitor_start(df); node->mon_started = true; mutex_unlock(&monitor_lock); ret = sysfs_create_group(&df->dev.kobj, &dev_attr_group); if (ret) { dev_err(dev, "Error creating sys entries!\n"); goto sysfs_fail; } return 0; sysfs_fail: mutex_lock(&monitor_lock); node->mon_started = false; devfreq_monitor_stop(df); mutex_unlock(&monitor_lock); hw->stop_hwmon(hw); err_start: df->data = node->orig_data; node->orig_data = NULL; hw->df = NULL; return ret; } static void stop_monitoring(struct devfreq *df) { struct cache_hwmon_node *node = df->data; struct cache_hwmon *hw = node->hw; sysfs_remove_group(&df->dev.kobj, &dev_attr_group); mutex_lock(&monitor_lock); node->mon_started = false; devfreq_monitor_stop(df); mutex_unlock(&monitor_lock); hw->stop_hwmon(hw); df->data = node->orig_data; node->orig_data = NULL; hw->df = NULL; } static int devfreq_cache_hwmon_ev_handler(struct devfreq *df, unsigned int event, void *data) { int ret; unsigned int sample_ms; switch (event) { case DEVFREQ_GOV_START: sample_ms = df->profile->polling_ms; sample_ms = max(MIN_MS, sample_ms); sample_ms = min(MAX_MS, sample_ms); df->profile->polling_ms = sample_ms; ret = start_monitoring(df); if (ret) return ret; dev_dbg(df->dev.parent, "Enabled Cache HW monitor governor\n"); break; case DEVFREQ_GOV_STOP: stop_monitoring(df); dev_dbg(df->dev.parent, "Disabled Cache HW monitor governor\n"); break; case DEVFREQ_GOV_INTERVAL: sample_ms = *(unsigned int *)data; sample_ms = max(MIN_MS, sample_ms); sample_ms = min(MAX_MS, sample_ms); devfreq_interval_update(df, &sample_ms); break; } return 0; } static struct devfreq_governor devfreq_cache_hwmon = { .name = "cache_hwmon", .get_target_freq = devfreq_cache_hwmon_get_freq, .event_handler = devfreq_cache_hwmon_ev_handler, }; int register_cache_hwmon(struct device *dev, struct cache_hwmon *hwmon) { int ret = 0; struct cache_hwmon_node *node; if (!hwmon->dev && !hwmon->of_node) return -EINVAL; node = devm_kzalloc(dev, sizeof(*node), GFP_KERNEL); if (!node) { dev_err(dev, "Unable to register gov. Out of memory!\n"); return -ENOMEM; } node->cycles_per_med_req = 20; node->cycles_per_high_req = 35; node->min_busy = 100; node->max_busy = 100; node->tolerance_mrps = 5; node->guard_band_mhz = 100; node->decay_rate = 90; node->hw = hwmon; node->attr_grp = &dev_attr_group; mutex_lock(®ister_lock); if (!use_cnt) { ret = devfreq_add_governor(&devfreq_cache_hwmon); if (!ret) use_cnt++; } mutex_unlock(®ister_lock); if (!ret) { dev_info(dev, "Cache HWmon governor registered.\n"); } else { dev_err(dev, "Failed to add Cache HWmon governor\n"); return ret; } mutex_lock(&list_lock); list_add_tail(&node->list, &cache_hwmon_list); mutex_unlock(&list_lock); return ret; } MODULE_DESCRIPTION("HW monitor based cache freq driver"); MODULE_LICENSE("GPL v2");