Gitiles
Code Review Sign In
gerrit-public.fairphone.software / kernel / msm-4.9 / a18908edd5d012e5bba60da58de3d94691a4ca4d / . / kernel / sched / walt.c
blob: 0050ca56b2699d4b2f46e98325e41158728e9ac1 [file] [log] [blame]
/*
* Copyright (c) 2016-2019, 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.
*
*
* Window Assisted Load Tracking (WALT) implementation credits:
* Srivatsa Vaddagiri, Steve Muckle, Syed Rameez Mustafa, Joonwoo Park,
* Pavan Kumar Kondeti, Olav Haugan
*
* 2016-03-06: Integration with EAS/refactoring by Vikram Mulukutla
* and Todd Kjos
*/
#include <linux/syscore_ops.h>
#include <linux/cpufreq.h>
#include <linux/list_sort.h>
#include <linux/jiffies.h>
#include <linux/sched/core_ctl.h>
#include <trace/events/sched.h>
#include "sched.h"
#include "walt.h"
#include <trace/events/sched.h>
const char *task_event_names[] = {"PUT_PREV_TASK", "PICK_NEXT_TASK",
"TASK_WAKE", "TASK_MIGRATE", "TASK_UPDATE",
"IRQ_UPDATE"};
const char *migrate_type_names[] = {"GROUP_TO_RQ", "RQ_TO_GROUP",
"RQ_TO_RQ", "GROUP_TO_GROUP"};
#define SCHED_FREQ_ACCOUNT_WAIT_TIME 0
#define SCHED_ACCOUNT_WAIT_TIME 1
#define EARLY_DETECTION_DURATION 9500000
static ktime_t ktime_last;
static bool sched_ktime_suspended;
static struct cpu_cycle_counter_cb cpu_cycle_counter_cb;
static bool use_cycle_counter;
DEFINE_MUTEX(cluster_lock);
static atomic64_t walt_irq_work_lastq_ws;
u64 walt_load_reported_window;
static struct irq_work walt_cpufreq_irq_work;
static struct irq_work walt_migration_irq_work;
void
walt_fixup_cumulative_runnable_avg(struct rq *rq,
struct task_struct *p, u64 new_task_load)
{
s64 task_load_delta = (s64)new_task_load - task_load(p);
struct walt_sched_stats *stats = &rq->walt_stats;
stats->cumulative_runnable_avg += task_load_delta;
if ((s64)stats->cumulative_runnable_avg < 0)
panic("cra less than zero: tld: %lld, task_load(p) = %u\n",
task_load_delta, task_load(p));
walt_fixup_cum_window_demand(rq, task_load_delta);
}
u64 sched_ktime_clock(void)
{
if (unlikely(sched_ktime_suspended))
return ktime_to_ns(ktime_last);
return ktime_get_ns();
}
static void sched_resume(void)
{
sched_ktime_suspended = false;
}
static int sched_suspend(void)
{
ktime_last = ktime_get();
sched_ktime_suspended = true;
return 0;
}
static struct syscore_ops sched_syscore_ops = {
.resume = sched_resume,
.suspend = sched_suspend
};
static int __init sched_init_ops(void)
{
register_syscore_ops(&sched_syscore_ops);
return 0;
}
late_initcall(sched_init_ops);
static void acquire_rq_locks_irqsave(const cpumask_t *cpus,
unsigned long *flags)
{
int cpu, level = 0;
local_irq_save(*flags);
for_each_cpu(cpu, cpus) {
if (level == 0)
raw_spin_lock(&cpu_rq(cpu)->lock);
else
raw_spin_lock_nested(&cpu_rq(cpu)->lock, level);
level++;
}
}
static void release_rq_locks_irqrestore(const cpumask_t *cpus,
unsigned long *flags)
{
int cpu;
for_each_cpu(cpu, cpus)
raw_spin_unlock(&cpu_rq(cpu)->lock);
local_irq_restore(*flags);
}
#ifdef CONFIG_HZ_300
/*
* Tick interval becomes to 3333333 due to
* rounding error when HZ=300.
*/
#define MIN_SCHED_RAVG_WINDOW (3333333 * 6)
#else
/* Min window size (in ns) = 20ms */
#define MIN_SCHED_RAVG_WINDOW 20000000
#endif
/* Max window size (in ns) = 1s */
#define MAX_SCHED_RAVG_WINDOW 1000000000
/* 1 -> use PELT based load stats, 0 -> use window-based load stats */
unsigned int __read_mostly walt_disabled = 0;
__read_mostly unsigned int sysctl_sched_cpu_high_irqload = (10 * NSEC_PER_MSEC);
unsigned int sysctl_sched_walt_rotate_big_tasks;
unsigned int walt_rotation_enabled;
/*
* sched_window_stats_policy and sched_ravg_hist_size have a 'sysctl' copy
* associated with them. This is required for atomic update of those variables
* when being modifed via sysctl interface.
*
* IMPORTANT: Initialize both copies to same value!!
*/
__read_mostly unsigned int sched_ravg_hist_size = 5;
__read_mostly unsigned int sysctl_sched_ravg_hist_size = 5;
static __read_mostly unsigned int sched_io_is_busy = 1;
__read_mostly unsigned int sched_window_stats_policy =
WINDOW_STATS_MAX_RECENT_AVG;
__read_mostly unsigned int sysctl_sched_window_stats_policy =
WINDOW_STATS_MAX_RECENT_AVG;
/* Window size (in ns) */
__read_mostly unsigned int sched_ravg_window = MIN_SCHED_RAVG_WINDOW;
/*
* A after-boot constant divisor for cpu_util_freq_walt() to apply the load
* boost.
*/
__read_mostly unsigned int walt_cpu_util_freq_divisor;
/* Initial task load. Newly created tasks are assigned this load. */
unsigned int __read_mostly sysctl_sched_init_task_load_pct = 15;
/*
* Maximum possible frequency across all cpus. Task demand and cpu
* capacity (cpu_power) metrics are scaled in reference to it.
*/
unsigned int max_possible_freq = 1;
/*
* Minimum possible max_freq across all cpus. This will be same as
* max_possible_freq on homogeneous systems and could be different from
* max_possible_freq on heterogenous systems. min_max_freq is used to derive
* capacity (cpu_power) of cpus.
*/
unsigned int min_max_freq = 1;
unsigned int max_capacity = 1024; /* max(rq->capacity) */
unsigned int min_capacity = 1024; /* min(rq->capacity) */
unsigned int max_possible_capacity = 1024; /* max(rq->max_possible_capacity) */
unsigned int
min_max_possible_capacity = 1024; /* min(rq->max_possible_capacity) */
/* Temporarily disable window-stats activity on all cpus */
unsigned int __read_mostly sched_disable_window_stats;
/*
* Task load is categorized into buckets for the purpose of top task tracking.
* The entire range of load from 0 to sched_ravg_window needs to be covered
* in NUM_LOAD_INDICES number of buckets. Therefore the size of each bucket
* is given by sched_ravg_window / NUM_LOAD_INDICES. Since the default value
* of sched_ravg_window is MIN_SCHED_RAVG_WINDOW, use that to compute
* sched_load_granule.
*/
__read_mostly unsigned int sched_load_granule =
MIN_SCHED_RAVG_WINDOW / NUM_LOAD_INDICES;
/* Size of bitmaps maintained to track top tasks */
static const unsigned int top_tasks_bitmap_size =
BITS_TO_LONGS(NUM_LOAD_INDICES + 1) * sizeof(unsigned long);
/*
* This governs what load needs to be used when reporting CPU busy time
* to the cpufreq governor.
*/
__read_mostly unsigned int sysctl_sched_freq_reporting_policy;
static int __init set_sched_ravg_window(char *str)
{
unsigned int window_size;
get_option(&str, &window_size);
if (window_size < MIN_SCHED_RAVG_WINDOW ||
window_size > MAX_SCHED_RAVG_WINDOW) {
WARN_ON(1);
return -EINVAL;
}
sched_ravg_window = window_size;
return 0;
}
early_param("sched_ravg_window", set_sched_ravg_window);
static int __init set_sched_predl(char *str)
{
unsigned int predl;
get_option(&str, &predl);
sched_predl = !!predl;
return 0;
}
early_param("sched_predl", set_sched_predl);
void inc_rq_walt_stats(struct rq *rq, struct task_struct *p)
{
inc_nr_big_task(&rq->walt_stats, p);
walt_inc_cumulative_runnable_avg(rq, p);
}
void dec_rq_walt_stats(struct rq *rq, struct task_struct *p)
{
dec_nr_big_task(&rq->walt_stats, p);
walt_dec_cumulative_runnable_avg(rq, p);
}
void fixup_walt_sched_stats_common(struct rq *rq, struct task_struct *p,
u32 new_task_load, u32 new_pred_demand)
{
s64 task_load_delta = (s64)new_task_load - task_load(p);
s64 pred_demand_delta = PRED_DEMAND_DELTA;
fixup_cumulative_runnable_avg(&rq->walt_stats, task_load_delta,
pred_demand_delta);
walt_fixup_cum_window_demand(rq, task_load_delta);
}
/*
* Demand aggregation for frequency purpose:
*
* CPU demand of tasks from various related groups is aggregated per-cluster and
* added to the "max_busy_cpu" in that cluster, where max_busy_cpu is determined
* by just rq->prev_runnable_sum.
*
* Some examples follow, which assume:
* Cluster0 = CPU0-3, Cluster1 = CPU4-7
* One related thread group A that has tasks A0, A1, A2
*
* A->cpu_time[X].curr/prev_sum = counters in which cpu execution stats of
* tasks belonging to group A are accumulated when they run on cpu X.
*
* CX->curr/prev_sum = counters in which cpu execution stats of all tasks
* not belonging to group A are accumulated when they run on cpu X
*
* Lets say the stats for window M was as below:
*
* C0->prev_sum = 1ms, A->cpu_time[0].prev_sum = 5ms
* Task A0 ran 5ms on CPU0
* Task B0 ran 1ms on CPU0
*
* C1->prev_sum = 5ms, A->cpu_time[1].prev_sum = 6ms
* Task A1 ran 4ms on CPU1
* Task A2 ran 2ms on CPU1
* Task B1 ran 5ms on CPU1
*
* C2->prev_sum = 0ms, A->cpu_time[2].prev_sum = 0
* CPU2 idle
*
* C3->prev_sum = 0ms, A->cpu_time[3].prev_sum = 0
* CPU3 idle
*
* In this case, CPU1 was most busy going by just its prev_sum counter. Demand
* from all group A tasks are added to CPU1. IOW, at end of window M, cpu busy
* time reported to governor will be:
*
*
* C0 busy time = 1ms
* C1 busy time = 5 + 5 + 6 = 16ms
*
*/
__read_mostly int sched_freq_aggregate_threshold;
static u64
update_window_start(struct rq *rq, u64 wallclock, int event)
{
s64 delta;
int nr_windows;
u64 old_window_start = rq->window_start;
delta = wallclock - rq->window_start;
BUG_ON(delta < 0);
if (delta < sched_ravg_window)
return old_window_start;
nr_windows = div64_u64(delta, sched_ravg_window);
rq->window_start += (u64)nr_windows * (u64)sched_ravg_window;
rq->cum_window_demand = rq->walt_stats.cumulative_runnable_avg;
return old_window_start;
}
int register_cpu_cycle_counter_cb(struct cpu_cycle_counter_cb *cb)
{
unsigned long flags;
mutex_lock(&cluster_lock);
if (!cb->get_cpu_cycle_counter) {
mutex_unlock(&cluster_lock);
return -EINVAL;
}
acquire_rq_locks_irqsave(cpu_possible_mask, &flags);
cpu_cycle_counter_cb = *cb;
use_cycle_counter = true;
release_rq_locks_irqrestore(cpu_possible_mask, &flags);
mutex_unlock(&cluster_lock);
return 0;
}
/*
* Assumes rq_lock is held and wallclock was recorded in the same critical
* section as this function's invocation.
*/
static inline u64 read_cycle_counter(int cpu, u64 wallclock)
{
struct rq *rq = cpu_rq(cpu);
if (rq->last_cc_update != wallclock) {
rq->cycles = cpu_cycle_counter_cb.get_cpu_cycle_counter(cpu);
rq->last_cc_update = wallclock;
}
return rq->cycles;
}
static void update_task_cpu_cycles(struct task_struct *p, int cpu,
u64 wallclock)
{
if (use_cycle_counter)
p->cpu_cycles = read_cycle_counter(cpu, wallclock);
}
void clear_ed_task(struct task_struct *p, struct rq *rq)
{
if (p == rq->ed_task)
rq->ed_task = NULL;
}
bool early_detection_notify(struct rq *rq, u64 wallclock)
{
struct task_struct *p;
int loop_max = 10;
rq->ed_task = NULL;
if ((!walt_rotation_enabled && sched_boost_policy() ==
SCHED_BOOST_NONE) || !rq->cfs.h_nr_running)
return 0;
list_for_each_entry(p, &rq->cfs_tasks, se.group_node) {
if (!loop_max)
break;
if (wallclock - p->last_wake_ts >= EARLY_DETECTION_DURATION) {
rq->ed_task = p;
return 1;
}
loop_max--;
}
return 0;
}
void sched_account_irqstart(int cpu, struct task_struct *curr, u64 wallclock)
{
struct rq *rq = cpu_rq(cpu);
if (!rq->window_start || sched_disable_window_stats)
return;
/*
* We don’t have to note down an irqstart event when cycle
* counter is not used.
*/
if (!use_cycle_counter)
return;
if (is_idle_task(curr)) {
/* We're here without rq->lock held, IRQ disabled */
raw_spin_lock(&rq->lock);
update_task_cpu_cycles(curr, cpu, sched_ktime_clock());
raw_spin_unlock(&rq->lock);
}
}
/*
* Return total number of tasks "eligible" to run on highest capacity cpu
*
* This is simply nr_big_tasks for cpus which are not of max_capacity and
* nr_running for cpus of max_capacity
*/
unsigned int nr_eligible_big_tasks(int cpu)
{
struct rq *rq = cpu_rq(cpu);
if (!is_max_capacity_cpu(cpu))
return rq->walt_stats.nr_big_tasks;
return rq->nr_running;
}
void clear_walt_request(int cpu)
{
struct rq *rq = cpu_rq(cpu);
unsigned long flags;
clear_boost_kick(cpu);
clear_reserved(cpu);
if (rq->push_task) {
struct task_struct *push_task = NULL;
raw_spin_lock_irqsave(&rq->lock, flags);
if (rq->push_task) {
clear_reserved(rq->push_cpu);
push_task = rq->push_task;
rq->push_task = NULL;
}
rq->active_balance = 0;
raw_spin_unlock_irqrestore(&rq->lock, flags);
if (push_task)
put_task_struct(push_task);
}
}
void sched_account_irqtime(int cpu, struct task_struct *curr,
u64 delta, u64 wallclock)
{
struct rq *rq = cpu_rq(cpu);
unsigned long flags, nr_windows;
u64 cur_jiffies_ts;
raw_spin_lock_irqsave(&rq->lock, flags);
/*
* cputime (wallclock) uses sched_clock so use the same here for
* consistency.
*/
delta += sched_clock() - wallclock;
cur_jiffies_ts = get_jiffies_64();
if (is_idle_task(curr))
update_task_ravg(curr, rq, IRQ_UPDATE, sched_ktime_clock(),
delta);
nr_windows = cur_jiffies_ts - rq->irqload_ts;
if (nr_windows) {
if (nr_windows < 10) {
/* Decay CPU's irqload by 3/4 for each window. */
rq->avg_irqload *= (3 * nr_windows);
rq->avg_irqload = div64_u64(rq->avg_irqload,
4 * nr_windows);
} else {
rq->avg_irqload = 0;
}
rq->avg_irqload += rq->cur_irqload;
rq->cur_irqload = 0;
}
rq->cur_irqload += delta;
rq->irqload_ts = cur_jiffies_ts;
raw_spin_unlock_irqrestore(&rq->lock, flags);
}
/*
* Special case the last index and provide a fast path for index = 0.
* Note that sched_load_granule can change underneath us if we are not
* holding any runqueue locks while calling the two functions below.
*/
static u32 top_task_load(struct rq *rq)
{
int index = rq->prev_top;
u8 prev = 1 - rq->curr_table;
if (!index) {
int msb = NUM_LOAD_INDICES - 1;
if (!test_bit(msb, rq->top_tasks_bitmap[prev]))
return 0;
else
return sched_load_granule;
} else if (index == NUM_LOAD_INDICES - 1) {
return sched_ravg_window;
} else {
return (index + 1) * sched_load_granule;
}
}
u64 freq_policy_load(struct rq *rq)
{
unsigned int reporting_policy = sysctl_sched_freq_reporting_policy;
int freq_aggr_thresh = sched_freq_aggregate_threshold;
struct sched_cluster *cluster = rq->cluster;
u64 aggr_grp_load = cluster->aggr_grp_load;
u64 load, tt_load = 0;
u64 coloc_boost_load = cluster->coloc_boost_load;
if (rq->ed_task != NULL) {
load = sched_ravg_window;
goto done;
}
if (aggr_grp_load > freq_aggr_thresh)
load = rq->prev_runnable_sum + aggr_grp_load;
else
load = rq->prev_runnable_sum + rq->grp_time.prev_runnable_sum;
if (coloc_boost_load)
load = max_t(u64, load, coloc_boost_load);
tt_load = top_task_load(rq);
switch (reporting_policy) {
case FREQ_REPORT_MAX_CPU_LOAD_TOP_TASK:
load = max_t(u64, load, tt_load);
break;
case FREQ_REPORT_TOP_TASK:
load = tt_load;
break;
case FREQ_REPORT_CPU_LOAD:
break;
default:
break;
}
done:
trace_sched_load_to_gov(rq, aggr_grp_load, tt_load, freq_aggr_thresh,
load, reporting_policy, walt_rotation_enabled,
sysctl_sched_little_cluster_coloc_fmin_khz,
coloc_boost_load);
return load;
}
/*
* In this function we match the accumulated subtractions with the current
* and previous windows we are operating with. Ignore any entries where
* the window start in the load_subtraction struct does not match either
* the curent or the previous window. This could happen whenever CPUs
* become idle or busy with interrupts disabled for an extended period.
*/
static inline void account_load_subtractions(struct rq *rq)
{
u64 ws = rq->window_start;
u64 prev_ws = ws - sched_ravg_window;
struct load_subtractions *ls = rq->load_subs;
int i;
for (i = 0; i < NUM_TRACKED_WINDOWS; i++) {
if (ls[i].window_start == ws) {
rq->curr_runnable_sum -= ls[i].subs;
rq->nt_curr_runnable_sum -= ls[i].new_subs;
} else if (ls[i].window_start == prev_ws) {
rq->prev_runnable_sum -= ls[i].subs;
rq->nt_prev_runnable_sum -= ls[i].new_subs;
}
ls[i].subs = 0;
ls[i].new_subs = 0;
}
BUG_ON((s64)rq->prev_runnable_sum < 0);
BUG_ON((s64)rq->curr_runnable_sum < 0);
BUG_ON((s64)rq->nt_prev_runnable_sum < 0);
BUG_ON((s64)rq->nt_curr_runnable_sum < 0);
}
static inline void create_subtraction_entry(struct rq *rq, u64 ws, int index)
{
rq->load_subs[index].window_start = ws;
rq->load_subs[index].subs = 0;
rq->load_subs[index].new_subs = 0;
}
static int get_top_index(unsigned long *bitmap, unsigned long old_top)
{
int index = find_next_bit(bitmap, NUM_LOAD_INDICES, old_top);
if (index == NUM_LOAD_INDICES)
return 0;
return NUM_LOAD_INDICES - 1 - index;
}
static bool get_subtraction_index(struct rq *rq, u64 ws)
{
int i;
u64 oldest = ULLONG_MAX;
int oldest_index = 0;
for (i = 0; i < NUM_TRACKED_WINDOWS; i++) {
u64 entry_ws = rq->load_subs[i].window_start;
if (ws == entry_ws)
return i;
if (entry_ws < oldest) {
oldest = entry_ws;
oldest_index = i;
}
}
create_subtraction_entry(rq, ws, oldest_index);
return oldest_index;
}
static void update_rq_load_subtractions(int index, struct rq *rq,
u32 sub_load, bool new_task)
{
rq->load_subs[index].subs += sub_load;
if (new_task)
rq->load_subs[index].new_subs += sub_load;
}
void update_cluster_load_subtractions(struct task_struct *p,
int cpu, u64 ws, bool new_task)
{
struct sched_cluster *cluster = cpu_cluster(cpu);
struct cpumask cluster_cpus = cluster->cpus;
u64 prev_ws = ws - sched_ravg_window;
int i;
cpumask_clear_cpu(cpu, &cluster_cpus);
raw_spin_lock(&cluster->load_lock);
for_each_cpu(i, &cluster_cpus) {
struct rq *rq = cpu_rq(i);
int index;
if (p->ravg.curr_window_cpu[i]) {
index = get_subtraction_index(rq, ws);
update_rq_load_subtractions(index, rq,
p->ravg.curr_window_cpu[i], new_task);
p->ravg.curr_window_cpu[i] = 0;
}
if (p->ravg.prev_window_cpu[i]) {
index = get_subtraction_index(rq, prev_ws);
update_rq_load_subtractions(index, rq,
p->ravg.prev_window_cpu[i], new_task);
p->ravg.prev_window_cpu[i] = 0;
}
}
raw_spin_unlock(&cluster->load_lock);
}
static inline void inter_cluster_migration_fixup
(struct task_struct *p, int new_cpu, int task_cpu, bool new_task)
{
struct rq *dest_rq = cpu_rq(new_cpu);
struct rq *src_rq = cpu_rq(task_cpu);
if (same_freq_domain(new_cpu, task_cpu))
return;
p->ravg.curr_window_cpu[new_cpu] = p->ravg.curr_window;
p->ravg.prev_window_cpu[new_cpu] = p->ravg.prev_window;
dest_rq->curr_runnable_sum += p->ravg.curr_window;
dest_rq->prev_runnable_sum += p->ravg.prev_window;
src_rq->curr_runnable_sum -= p->ravg.curr_window_cpu[task_cpu];
src_rq->prev_runnable_sum -= p->ravg.prev_window_cpu[task_cpu];
if (new_task) {
dest_rq->nt_curr_runnable_sum += p->ravg.curr_window;
dest_rq->nt_prev_runnable_sum += p->ravg.prev_window;
src_rq->nt_curr_runnable_sum -=
p->ravg.curr_window_cpu[task_cpu];
src_rq->nt_prev_runnable_sum -=
p->ravg.prev_window_cpu[task_cpu];
}
p->ravg.curr_window_cpu[task_cpu] = 0;
p->ravg.prev_window_cpu[task_cpu] = 0;
update_cluster_load_subtractions(p, task_cpu,
src_rq->window_start, new_task);
BUG_ON((s64)src_rq->prev_runnable_sum < 0);
BUG_ON((s64)src_rq->curr_runnable_sum < 0);
BUG_ON((s64)src_rq->nt_prev_runnable_sum < 0);
BUG_ON((s64)src_rq->nt_curr_runnable_sum < 0);
}
static u32 load_to_index(u32 load)
{
u32 index = load / sched_load_granule;
return min(index, (u32)(NUM_LOAD_INDICES - 1));
}
static void
migrate_top_tasks(struct task_struct *p, struct rq *src_rq, struct rq *dst_rq)
{
int index;
int top_index;
u32 curr_window = p->ravg.curr_window;
u32 prev_window = p->ravg.prev_window;
u8 src = src_rq->curr_table;
u8 dst = dst_rq->curr_table;
u8 *src_table;
u8 *dst_table;
if (curr_window) {
src_table = src_rq->top_tasks[src];
dst_table = dst_rq->top_tasks[dst];
index = load_to_index(curr_window);
src_table[index] -= 1;
dst_table[index] += 1;
if (!src_table[index])
__clear_bit(NUM_LOAD_INDICES - index - 1,
src_rq->top_tasks_bitmap[src]);
if (dst_table[index] == 1)
__set_bit(NUM_LOAD_INDICES - index - 1,
dst_rq->top_tasks_bitmap[dst]);
if (index > dst_rq->curr_top)
dst_rq->curr_top = index;
top_index = src_rq->curr_top;
if (index == top_index && !src_table[index])
src_rq->curr_top = get_top_index(
src_rq->top_tasks_bitmap[src], top_index);
}
if (prev_window) {
src = 1 - src;
dst = 1 - dst;
src_table = src_rq->top_tasks[src];
dst_table = dst_rq->top_tasks[dst];
index = load_to_index(prev_window);
src_table[index] -= 1;
dst_table[index] += 1;
if (!src_table[index])
__clear_bit(NUM_LOAD_INDICES - index - 1,
src_rq->top_tasks_bitmap[src]);
if (dst_table[index] == 1)
__set_bit(NUM_LOAD_INDICES - index - 1,
dst_rq->top_tasks_bitmap[dst]);
if (index > dst_rq->prev_top)
dst_rq->prev_top = index;
top_index = src_rq->prev_top;
if (index == top_index && !src_table[index])
src_rq->prev_top = get_top_index(
src_rq->top_tasks_bitmap[src], top_index);
}
}
void fixup_busy_time(struct task_struct *p, int new_cpu)
{
struct rq *src_rq = task_rq(p);
struct rq *dest_rq = cpu_rq(new_cpu);
u64 wallclock;
u64 *src_curr_runnable_sum, *dst_curr_runnable_sum;
u64 *src_prev_runnable_sum, *dst_prev_runnable_sum;
u64 *src_nt_curr_runnable_sum, *dst_nt_curr_runnable_sum;
u64 *src_nt_prev_runnable_sum, *dst_nt_prev_runnable_sum;
bool new_task;
struct related_thread_group *grp;
if (!p->on_rq && p->state != TASK_WAKING)
return;
if (exiting_task(p)) {
clear_ed_task(p, src_rq);
return;
}
if (p->state == TASK_WAKING)
double_rq_lock(src_rq, dest_rq);
if (sched_disable_window_stats)
goto done;
wallclock = sched_ktime_clock();
update_task_ravg(task_rq(p)->curr, task_rq(p),
TASK_UPDATE,
wallclock, 0);
update_task_ravg(dest_rq->curr, dest_rq,
TASK_UPDATE, wallclock, 0);
update_task_ravg(p, task_rq(p), TASK_MIGRATE,
wallclock, 0);
update_task_cpu_cycles(p, new_cpu, wallclock);
/*
* When a task is migrating during the wakeup, adjust
* the task's contribution towards cumulative window
* demand.
*/
if (p->state == TASK_WAKING && p->last_sleep_ts >=
src_rq->window_start) {
walt_fixup_cum_window_demand(src_rq, -(s64)p->ravg.demand);
walt_fixup_cum_window_demand(dest_rq, p->ravg.demand);
}
new_task = is_new_task(p);
/* Protected by rq_lock */
grp = p->grp;
/*
* For frequency aggregation, we continue to do migration fixups
* even for intra cluster migrations. This is because, the aggregated
* load has to reported on a single CPU regardless.
*/
if (grp) {
struct group_cpu_time *cpu_time;
cpu_time = &src_rq->grp_time;
src_curr_runnable_sum = &cpu_time->curr_runnable_sum;
src_prev_runnable_sum = &cpu_time->prev_runnable_sum;
src_nt_curr_runnable_sum = &cpu_time->nt_curr_runnable_sum;
src_nt_prev_runnable_sum = &cpu_time->nt_prev_runnable_sum;
cpu_time = &dest_rq->grp_time;
dst_curr_runnable_sum = &cpu_time->curr_runnable_sum;
dst_prev_runnable_sum = &cpu_time->prev_runnable_sum;
dst_nt_curr_runnable_sum = &cpu_time->nt_curr_runnable_sum;
dst_nt_prev_runnable_sum = &cpu_time->nt_prev_runnable_sum;
if (p->ravg.curr_window) {
*src_curr_runnable_sum -= p->ravg.curr_window;
*dst_curr_runnable_sum += p->ravg.curr_window;
if (new_task) {
*src_nt_curr_runnable_sum -=
p->ravg.curr_window;
*dst_nt_curr_runnable_sum +=
p->ravg.curr_window;
}
}
if (p->ravg.prev_window) {
*src_prev_runnable_sum -= p->ravg.prev_window;
*dst_prev_runnable_sum += p->ravg.prev_window;
if (new_task) {
*src_nt_prev_runnable_sum -=
p->ravg.prev_window;
*dst_nt_prev_runnable_sum +=
p->ravg.prev_window;
}
}
} else {
inter_cluster_migration_fixup(p, new_cpu,
task_cpu(p), new_task);
}
migrate_top_tasks(p, src_rq, dest_rq);
if (!same_freq_domain(new_cpu, task_cpu(p))) {
src_rq->notif_pending = true;
dest_rq->notif_pending = true;
sched_irq_work_queue(&walt_migration_irq_work);
}
if (p == src_rq->ed_task) {
src_rq->ed_task = NULL;
dest_rq->ed_task = p;
}
done:
if (p->state == TASK_WAKING)
double_rq_unlock(src_rq, dest_rq);
}
void set_window_start(struct rq *rq)
{
static int sync_cpu_available;
if (likely(rq->window_start))
return;
if (!sync_cpu_available) {
rq->window_start = 1;
sync_cpu_available = 1;
atomic64_set(&walt_irq_work_lastq_ws, rq->window_start);
walt_load_reported_window =
atomic64_read(&walt_irq_work_lastq_ws);
} else {
struct rq *sync_rq = cpu_rq(cpumask_any(cpu_online_mask));
raw_spin_unlock(&rq->lock);
double_rq_lock(rq, sync_rq);
rq->window_start = sync_rq->window_start;
rq->curr_runnable_sum = rq->prev_runnable_sum = 0;
rq->nt_curr_runnable_sum = rq->nt_prev_runnable_sum = 0;
raw_spin_unlock(&sync_rq->lock);
}
rq->curr->ravg.mark_start = rq->window_start;
}
unsigned int max_possible_efficiency = 1;
unsigned int min_possible_efficiency = UINT_MAX;
#define INC_STEP 8
#define DEC_STEP 2
#define CONSISTENT_THRES 16
#define INC_STEP_BIG 16
/*
* bucket_increase - update the count of all buckets
*
* @buckets: array of buckets tracking busy time of a task
* @idx: the index of bucket to be incremented
*
* Each time a complete window finishes, count of bucket that runtime
* falls in (@idx) is incremented. Counts of all other buckets are
* decayed. The rate of increase and decay could be different based
* on current count in the bucket.
*/
static inline void bucket_increase(u8 *buckets, int idx)
{
int i, step;
for (i = 0; i < NUM_BUSY_BUCKETS; i++) {
if (idx != i) {
if (buckets[i] > DEC_STEP)
buckets[i] -= DEC_STEP;
else
buckets[i] = 0;
} else {
step = buckets[i] >= CONSISTENT_THRES ?
INC_STEP_BIG : INC_STEP;
if (buckets[i] > U8_MAX - step)
buckets[i] = U8_MAX;
else
buckets[i] += step;
}
}
}
static inline int busy_to_bucket(u32 normalized_rt)
{
int bidx;
bidx = mult_frac(normalized_rt, NUM_BUSY_BUCKETS, max_task_load());
bidx = min(bidx, NUM_BUSY_BUCKETS - 1);
/*
* Combine lowest two buckets. The lowest frequency falls into
* 2nd bucket and thus keep predicting lowest bucket is not
* useful.
*/
if (!bidx)
bidx++;
return bidx;
}
/*
* get_pred_busy - calculate predicted demand for a task on runqueue
*
* @rq: runqueue of task p
* @p: task whose prediction is being updated
* @start: starting bucket. returned prediction should not be lower than
* this bucket.
* @runtime: runtime of the task. returned prediction should not be lower
* than this runtime.
* Note: @start can be derived from @runtime. It's passed in only to
* avoid duplicated calculation in some cases.
*
* A new predicted busy time is returned for task @p based on @runtime
* passed in. The function searches through buckets that represent busy
* time equal to or bigger than @runtime and attempts to find the bucket to
* to use for prediction. Once found, it searches through historical busy
* time and returns the latest that falls into the bucket. If no such busy
* time exists, it returns the medium of that bucket.
*/
static u32 get_pred_busy(struct rq *rq, struct task_struct *p,
int start, u32 runtime)
{
int i;
u8 *buckets = p->ravg.busy_buckets;
u32 *hist = p->ravg.sum_history;
u32 dmin, dmax;
u64 cur_freq_runtime = 0;
int first = NUM_BUSY_BUCKETS, final;
u32 ret = runtime;
/* skip prediction for new tasks due to lack of history */
if (unlikely(is_new_task(p)))
goto out;
/* find minimal bucket index to pick */
for (i = start; i < NUM_BUSY_BUCKETS; i++) {
if (buckets[i]) {
first = i;
break;
}
}
/* if no higher buckets are filled, predict runtime */
if (first >= NUM_BUSY_BUCKETS)
goto out;
/* compute the bucket for prediction */
final = first;
/* determine demand range for the predicted bucket */
if (final < 2) {
/* lowest two buckets are combined */
dmin = 0;
final = 1;
} else {
dmin = mult_frac(final, max_task_load(), NUM_BUSY_BUCKETS);
}
dmax = mult_frac(final + 1, max_task_load(), NUM_BUSY_BUCKETS);
/*
* search through runtime history and return first runtime that falls
* into the range of predicted bucket.
*/
for (i = 0; i < sched_ravg_hist_size; i++) {
if (hist[i] >= dmin && hist[i] < dmax) {
ret = hist[i];
break;
}
}
/* no historical runtime within bucket found, use average of the bin */
if (ret < dmin)
ret = (dmin + dmax) / 2;
/*
* when updating in middle of a window, runtime could be higher
* than all recorded history. Always predict at least runtime.
*/
ret = max(runtime, ret);
out:
trace_sched_update_pred_demand(rq, p, runtime,
mult_frac((unsigned int)cur_freq_runtime, 100,
sched_ravg_window), ret);
return ret;
}
static inline u32 calc_pred_demand(struct rq *rq, struct task_struct *p)
{
if (p->ravg.pred_demand >= p->ravg.curr_window)
return p->ravg.pred_demand;
return get_pred_busy(rq, p, busy_to_bucket(p->ravg.curr_window),
p->ravg.curr_window);
}
/*
* predictive demand of a task is calculated at the window roll-over.
* if the task current window busy time exceeds the predicted
* demand, update it here to reflect the task needs.
*/
void update_task_pred_demand(struct rq *rq, struct task_struct *p, int event)
{
u32 new, old;
if (!sched_predl)
return;
if (is_idle_task(p) || exiting_task(p))
return;
if (event != PUT_PREV_TASK && event != TASK_UPDATE &&
(!SCHED_FREQ_ACCOUNT_WAIT_TIME ||
(event != TASK_MIGRATE &&
event != PICK_NEXT_TASK)))
return;
/*
* TASK_UPDATE can be called on sleeping task, when its moved between
* related groups
*/
if (event == TASK_UPDATE) {
if (!p->on_rq && !SCHED_FREQ_ACCOUNT_WAIT_TIME)
return;
}
new = calc_pred_demand(rq, p);
old = p->ravg.pred_demand;
if (old >= new)
return;
if (task_on_rq_queued(p) && (!task_has_dl_policy(p) ||
!p->dl.dl_throttled))
p->sched_class->fixup_walt_sched_stats(rq, p,
p->ravg.demand,
new);
p->ravg.pred_demand = new;
}
void clear_top_tasks_bitmap(unsigned long *bitmap)
{
memset(bitmap, 0, top_tasks_bitmap_size);
__set_bit(NUM_LOAD_INDICES, bitmap);
}
static void update_top_tasks(struct task_struct *p, struct rq *rq,
u32 old_curr_window, int new_window, bool full_window)
{
u8 curr = rq->curr_table;
u8 prev = 1 - curr;
u8 *curr_table = rq->top_tasks[curr];
u8 *prev_table = rq->top_tasks[prev];
int old_index, new_index, update_index;
u32 curr_window = p->ravg.curr_window;
u32 prev_window = p->ravg.prev_window;
bool zero_index_update;
if (old_curr_window == curr_window && !new_window)
return;
old_index = load_to_index(old_curr_window);
new_index = load_to_index(curr_window);
if (!new_window) {
zero_index_update = !old_curr_window && curr_window;
if (old_index != new_index || zero_index_update) {
if (old_curr_window)
curr_table[old_index] -= 1;
if (curr_window)
curr_table[new_index] += 1;
if (new_index > rq->curr_top)
rq->curr_top = new_index;
}
if (!curr_table[old_index])
__clear_bit(NUM_LOAD_INDICES - old_index - 1,
rq->top_tasks_bitmap[curr]);
if (curr_table[new_index] == 1)
__set_bit(NUM_LOAD_INDICES - new_index - 1,
rq->top_tasks_bitmap[curr]);
return;
}
/*
* The window has rolled over for this task. By the time we get
* here, curr/prev swaps would has already occurred. So we need
* to use prev_window for the new index.
*/
update_index = load_to_index(prev_window);
if (full_window) {
/*
* Two cases here. Either 'p' ran for the entire window or
* it didn't run at all. In either case there is no entry
* in the prev table. If 'p' ran the entire window, we just
* need to create a new entry in the prev table. In this case
* update_index will be correspond to sched_ravg_window
* so we can unconditionally update the top index.
*/
if (prev_window) {
prev_table[update_index] += 1;
rq->prev_top = update_index;
}
if (prev_table[update_index] == 1)
__set_bit(NUM_LOAD_INDICES - update_index - 1,
rq->top_tasks_bitmap[prev]);
} else {
zero_index_update = !old_curr_window && prev_window;
if (old_index != update_index || zero_index_update) {
if (old_curr_window)
prev_table[old_index] -= 1;
prev_table[update_index] += 1;
if (update_index > rq->prev_top)
rq->prev_top = update_index;
if (!prev_table[old_index])
__clear_bit(NUM_LOAD_INDICES - old_index - 1,
rq->top_tasks_bitmap[prev]);
if (prev_table[update_index] == 1)
__set_bit(NUM_LOAD_INDICES - update_index - 1,
rq->top_tasks_bitmap[prev]);
}
}
if (curr_window) {
curr_table[new_index] += 1;
if (new_index > rq->curr_top)
rq->curr_top = new_index;
if (curr_table[new_index] == 1)
__set_bit(NUM_LOAD_INDICES - new_index - 1,
rq->top_tasks_bitmap[curr]);
}
}
static void rollover_top_tasks(struct rq *rq, bool full_window)
{
u8 curr_table = rq->curr_table;
u8 prev_table = 1 - curr_table;
int curr_top = rq->curr_top;
clear_top_tasks_table(rq->top_tasks[prev_table]);
clear_top_tasks_bitmap(rq->top_tasks_bitmap[prev_table]);
if (full_window) {
curr_top = 0;
clear_top_tasks_table(rq->top_tasks[curr_table]);
clear_top_tasks_bitmap(
rq->top_tasks_bitmap[curr_table]);
}
rq->curr_table = prev_table;
rq->prev_top = curr_top;
rq->curr_top = 0;
}
static u32 empty_windows[NR_CPUS];
static void rollover_task_window(struct task_struct *p, bool full_window)
{
u32 *curr_cpu_windows = empty_windows;
u32 curr_window;
int i;
/* Rollover the sum */
curr_window = 0;
if (!full_window) {
curr_window = p->ravg.curr_window;
curr_cpu_windows = p->ravg.curr_window_cpu;
}
p->ravg.prev_window = curr_window;
p->ravg.curr_window = 0;
/* Roll over individual CPU contributions */
for (i = 0; i < nr_cpu_ids; i++) {
p->ravg.prev_window_cpu[i] = curr_cpu_windows[i];
p->ravg.curr_window_cpu[i] = 0;
}
}
void sched_set_io_is_busy(int val)
{
sched_io_is_busy = val;
}
static inline int cpu_is_waiting_on_io(struct rq *rq)
{
if (!sched_io_is_busy)
return 0;
return atomic_read(&rq->nr_iowait);
}
static int account_busy_for_cpu_time(struct rq *rq, struct task_struct *p,
u64 irqtime, int event)
{
if (is_idle_task(p)) {
/* TASK_WAKE && TASK_MIGRATE is not possible on idle task! */
if (event == PICK_NEXT_TASK)
return 0;
/* PUT_PREV_TASK, TASK_UPDATE && IRQ_UPDATE are left */
return irqtime || cpu_is_waiting_on_io(rq);
}
if (event == TASK_WAKE)
return 0;
if (event == PUT_PREV_TASK || event == IRQ_UPDATE)
return 1;
/*
* TASK_UPDATE can be called on sleeping task, when its moved between
* related groups
*/
if (event == TASK_UPDATE) {
if (rq->curr == p)
return 1;
return p->on_rq ? SCHED_FREQ_ACCOUNT_WAIT_TIME : 0;
}
/* TASK_MIGRATE, PICK_NEXT_TASK left */
return SCHED_FREQ_ACCOUNT_WAIT_TIME;
}
#define DIV64_U64_ROUNDUP(X, Y) div64_u64((X) + (Y - 1), Y)
static inline u64 scale_exec_time(u64 delta, struct rq *rq)
{
u32 freq;
freq = cpu_cycles_to_freq(rq->cc.cycles, rq->cc.time);
delta = DIV64_U64_ROUNDUP(delta * freq, max_possible_freq);
delta *= rq->cluster->exec_scale_factor;
delta >>= 10;
return delta;
}
/* Convert busy time to frequency equivalent
* Assumes load is scaled to 1024
*/
static inline unsigned int load_to_freq(struct rq *rq, unsigned int load)
{
return mult_frac(cpu_max_possible_freq(cpu_of(rq)), load,
(unsigned int) capacity_orig_of(cpu_of(rq)));
}
bool do_pl_notif(struct rq *rq)
{
u64 prev = rq->old_busy_time;
u64 pl = rq->walt_stats.pred_demands_sum;
int cpu = cpu_of(rq);
/* If already at max freq, bail out */
if (capacity_orig_of(cpu) == capacity_curr_of(cpu))
return false;
prev = max(prev, rq->old_estimated_time);
pl = div64_u64(pl, sched_ravg_window >> SCHED_CAPACITY_SHIFT);
/* 400 MHz filter. */
return (pl > prev) && (load_to_freq(rq, pl - prev) > 400000);
}
static void rollover_cpu_window(struct rq *rq, bool full_window)
{
u64 curr_sum = rq->curr_runnable_sum;
u64 nt_curr_sum = rq->nt_curr_runnable_sum;
u64 grp_curr_sum = rq->grp_time.curr_runnable_sum;
u64 grp_nt_curr_sum = rq->grp_time.nt_curr_runnable_sum;
if (unlikely(full_window)) {
curr_sum = 0;
nt_curr_sum = 0;
grp_curr_sum = 0;
grp_nt_curr_sum = 0;
}
rq->prev_runnable_sum = curr_sum;
rq->nt_prev_runnable_sum = nt_curr_sum;
rq->grp_time.prev_runnable_sum = grp_curr_sum;
rq->grp_time.nt_prev_runnable_sum = grp_nt_curr_sum;
rq->curr_runnable_sum = 0;
rq->nt_curr_runnable_sum = 0;
rq->grp_time.curr_runnable_sum = 0;
rq->grp_time.nt_curr_runnable_sum = 0;
}
/*
* Account cpu activity in its busy time counters (rq->curr/prev_runnable_sum)
*/
static void update_cpu_busy_time(struct task_struct *p, struct rq *rq,
int event, u64 wallclock, u64 irqtime)
{
int new_window, full_window = 0;
int p_is_curr_task = (p == rq->curr);
u64 mark_start = p->ravg.mark_start;
u64 window_start = rq->window_start;
u32 window_size = sched_ravg_window;
u64 delta;
u64 *curr_runnable_sum = &rq->curr_runnable_sum;
u64 *prev_runnable_sum = &rq->prev_runnable_sum;
u64 *nt_curr_runnable_sum = &rq->nt_curr_runnable_sum;
u64 *nt_prev_runnable_sum = &rq->nt_prev_runnable_sum;
bool new_task;
struct related_thread_group *grp;
int cpu = rq->cpu;
u32 old_curr_window = p->ravg.curr_window;
new_window = mark_start < window_start;
if (new_window) {
full_window = (window_start - mark_start) >= window_size;
if (p->ravg.active_windows < USHRT_MAX)
p->ravg.active_windows++;
}
new_task = is_new_task(p);
/*
* Handle per-task window rollover. We don't care about the idle
* task or exiting tasks.
*/
if (!is_idle_task(p) && !exiting_task(p)) {
if (new_window)
rollover_task_window(p, full_window);
}
if (p_is_curr_task && new_window) {
rollover_cpu_window(rq, full_window);
rollover_top_tasks(rq, full_window);
}
if (!account_busy_for_cpu_time(rq, p, irqtime, event))
goto done;
grp = p->grp;
if (grp) {
struct group_cpu_time *cpu_time = &rq->grp_time;
curr_runnable_sum = &cpu_time->curr_runnable_sum;
prev_runnable_sum = &cpu_time->prev_runnable_sum;
nt_curr_runnable_sum = &cpu_time->nt_curr_runnable_sum;
nt_prev_runnable_sum = &cpu_time->nt_prev_runnable_sum;
}
if (!new_window) {
/*
* account_busy_for_cpu_time() = 1 so busy time needs
* to be accounted to the current window. No rollover
* since we didn't start a new window. An example of this is
* when a task starts execution and then sleeps within the
* same window.
*/
if (!irqtime || !is_idle_task(p) || cpu_is_waiting_on_io(rq))
delta = wallclock - mark_start;
else
delta = irqtime;
delta = scale_exec_time(delta, rq);
*curr_runnable_sum += delta;
if (new_task)
*nt_curr_runnable_sum += delta;
if (!is_idle_task(p) && !exiting_task(p)) {
p->ravg.curr_window += delta;
p->ravg.curr_window_cpu[cpu] += delta;
}
goto done;
}
if (!p_is_curr_task) {
/*
* account_busy_for_cpu_time() = 1 so busy time needs
* to be accounted to the current window. A new window
* has also started, but p is not the current task, so the
* window is not rolled over - just split up and account
* as necessary into curr and prev. The window is only
* rolled over when a new window is processed for the current
* task.
*
* Irqtime can't be accounted by a task that isn't the
* currently running task.
*/
if (!full_window) {
/*
* A full window hasn't elapsed, account partial
* contribution to previous completed window.
*/
delta = scale_exec_time(window_start - mark_start, rq);
if (!exiting_task(p)) {
p->ravg.prev_window += delta;
p->ravg.prev_window_cpu[cpu] += delta;
}
} else {
/*
* Since at least one full window has elapsed,
* the contribution to the previous window is the
* full window (window_size).
*/
delta = scale_exec_time(window_size, rq);
if (!exiting_task(p)) {
p->ravg.prev_window = delta;
p->ravg.prev_window_cpu[cpu] = delta;
}
}
*prev_runnable_sum += delta;
if (new_task)
*nt_prev_runnable_sum += delta;
/* Account piece of busy time in the current window. */
delta = scale_exec_time(wallclock - window_start, rq);
*curr_runnable_sum += delta;
if (new_task)
*nt_curr_runnable_sum += delta;
if (!exiting_task(p)) {
p->ravg.curr_window = delta;
p->ravg.curr_window_cpu[cpu] = delta;
}
goto done;
}
if (!irqtime || !is_idle_task(p) || cpu_is_waiting_on_io(rq)) {
/*
* account_busy_for_cpu_time() = 1 so busy time needs
* to be accounted to the current window. A new window
* has started and p is the current task so rollover is
* needed. If any of these three above conditions are true
* then this busy time can't be accounted as irqtime.
*
* Busy time for the idle task or exiting tasks need not
* be accounted.
*
* An example of this would be a task that starts execution
* and then sleeps once a new window has begun.
*/
if (!full_window) {
/*
* A full window hasn't elapsed, account partial
* contribution to previous completed window.
*/
delta = scale_exec_time(window_start - mark_start, rq);
if (!is_idle_task(p) && !exiting_task(p)) {
p->ravg.prev_window += delta;
p->ravg.prev_window_cpu[cpu] += delta;
}
} else {
/*
* Since at least one full window has elapsed,
* the contribution to the previous window is the
* full window (window_size).
*/
delta = scale_exec_time(window_size, rq);
if (!is_idle_task(p) && !exiting_task(p)) {
p->ravg.prev_window = delta;
p->ravg.prev_window_cpu[cpu] = delta;
}
}
/*
* Rollover is done here by overwriting the values in
* prev_runnable_sum and curr_runnable_sum.
*/
*prev_runnable_sum += delta;
if (new_task)
*nt_prev_runnable_sum += delta;
/* Account piece of busy time in the current window. */
delta = scale_exec_time(wallclock - window_start, rq);
*curr_runnable_sum += delta;
if (new_task)
*nt_curr_runnable_sum += delta;
if (!is_idle_task(p) && !exiting_task(p)) {
p->ravg.curr_window = delta;
p->ravg.curr_window_cpu[cpu] = delta;
}
goto done;
}
if (irqtime) {
/*
* account_busy_for_cpu_time() = 1 so busy time needs
* to be accounted to the current window. A new window
* has started and p is the current task so rollover is
* needed. The current task must be the idle task because
* irqtime is not accounted for any other task.
*
* Irqtime will be accounted each time we process IRQ activity
* after a period of idleness, so we know the IRQ busy time
* started at wallclock - irqtime.
*/
BUG_ON(!is_idle_task(p));
mark_start = wallclock - irqtime;
/*
* Roll window over. If IRQ busy time was just in the current
* window then that is all that need be accounted.
*/
if (mark_start > window_start) {
*curr_runnable_sum = scale_exec_time(irqtime, rq);
return;
}
/*
* The IRQ busy time spanned multiple windows. Process the
* busy time preceding the current window start first.
*/
delta = window_start - mark_start;
if (delta > window_size)
delta = window_size;
delta = scale_exec_time(delta, rq);
*prev_runnable_sum += delta;
/* Process the remaining IRQ busy time in the current window. */
delta = wallclock - window_start;
rq->curr_runnable_sum = scale_exec_time(delta, rq);
return;
}
done:
if (!is_idle_task(p) && !exiting_task(p))
update_top_tasks(p, rq, old_curr_window,
new_window, full_window);
}
static inline u32 predict_and_update_buckets(struct rq *rq,
struct task_struct *p, u32 runtime) {
int bidx;
u32 pred_demand;
if (!sched_predl)
return 0;
bidx = busy_to_bucket(runtime);
pred_demand = get_pred_busy(rq, p, bidx, runtime);
bucket_increase(p->ravg.busy_buckets, bidx);
return pred_demand;
}
static int
account_busy_for_task_demand(struct rq *rq, struct task_struct *p, int event)
{
/*
* No need to bother updating task demand for exiting tasks
* or the idle task.
*/
if (exiting_task(p) || is_idle_task(p))
return 0;
/*
* When a task is waking up it is completing a segment of non-busy
* time. Likewise, if wait time is not treated as busy time, then
* when a task begins to run or is migrated, it is not running and
* is completing a segment of non-busy time.
*/
if (event == TASK_WAKE || (!SCHED_ACCOUNT_WAIT_TIME &&
(event == PICK_NEXT_TASK || event == TASK_MIGRATE)))
return 0;
/*
* TASK_UPDATE can be called on sleeping task, when its moved between
* related groups
*/
if (event == TASK_UPDATE) {
if (rq->curr == p)
return 1;
return p->on_rq ? SCHED_ACCOUNT_WAIT_TIME : 0;
}
return 1;
}
/*
* Called when new window is starting for a task, to record cpu usage over
* recently concluded window(s). Normally 'samples' should be 1. It can be > 1
* when, say, a real-time task runs without preemption for several windows at a
* stretch.
*/
static void update_history(struct rq *rq, struct task_struct *p,
u32 runtime, int samples, int event)
{
u32 *hist = &p->ravg.sum_history[0];
int ridx, widx;
u32 max = 0, avg, demand, pred_demand;
u64 sum = 0;
u64 prev_demand;
/* Ignore windows where task had no activity */
if (!runtime || is_idle_task(p) || exiting_task(p) || !samples)
goto done;
prev_demand = p->ravg.demand;
/* Push new 'runtime' value onto stack */
widx = sched_ravg_hist_size - 1;
ridx = widx - samples;
for (; ridx >= 0; --widx, --ridx) {
hist[widx] = hist[ridx];
sum += hist[widx];
if (hist[widx] > max)
max = hist[widx];
}
for (widx = 0; widx < samples && widx < sched_ravg_hist_size; widx++) {
hist[widx] = runtime;
sum += hist[widx];
if (hist[widx] > max)
max = hist[widx];
}
p->ravg.sum = 0;
if (sched_window_stats_policy == WINDOW_STATS_RECENT) {
demand = runtime;
} else if (sched_window_stats_policy == WINDOW_STATS_MAX) {
demand = max;
} else {
avg = div64_u64(sum, sched_ravg_hist_size);
if (sched_window_stats_policy == WINDOW_STATS_AVG)
demand = avg;
else
demand = max(avg, runtime);
}
pred_demand = predict_and_update_buckets(rq, p, runtime);
/*
* A throttled deadline sched class task gets dequeued without
* changing p->on_rq. Since the dequeue decrements walt stats
* avoid decrementing it here again.
*
* When window is rolled over, the cumulative window demand
* is reset to the cumulative runnable average (contribution from
* the tasks on the runqueue). If the current task is dequeued
* already, it's demand is not included in the cumulative runnable
* average. So add the task demand separately to cumulative window
* demand.
*/
if (!task_has_dl_policy(p) || !p->dl.dl_throttled) {
if (task_on_rq_queued(p))
p->sched_class->fixup_walt_sched_stats(rq, p, demand,
pred_demand);
else if (rq->curr == p)
walt_fixup_cum_window_demand(rq, demand);
}
p->ravg.demand = demand;
p->ravg.coloc_demand = div64_u64(sum, sched_ravg_hist_size);
p->ravg.pred_demand = pred_demand;
done:
trace_sched_update_history(rq, p, runtime, samples, event);
}
static u64 add_to_task_demand(struct rq *rq, struct task_struct *p, u64 delta)
{
delta = scale_exec_time(delta, rq);
p->ravg.sum += delta;
if (unlikely(p->ravg.sum > sched_ravg_window))
p->ravg.sum = sched_ravg_window;
return delta;
}
/*
* Account cpu demand of task and/or update task's cpu demand history
*
* ms = p->ravg.mark_start;
* wc = wallclock
* ws = rq->window_start
*
* Three possibilities:
*
* a) Task event is contained within one window.
* window_start < mark_start < wallclock
*
* ws ms wc
* | | |
* V V V
* |---------------|
*
* In this case, p->ravg.sum is updated *iff* event is appropriate
* (ex: event == PUT_PREV_TASK)
*
* b) Task event spans two windows.
* mark_start < window_start < wallclock
*
* ms ws wc
* | | |
* V V V
* -----|-------------------
*
* In this case, p->ravg.sum is updated with (ws - ms) *iff* event
* is appropriate, then a new window sample is recorded followed
* by p->ravg.sum being set to (wc - ws) *iff* event is appropriate.
*
* c) Task event spans more than two windows.
*
* ms ws_tmp ws wc
* | | | |
* V V V V
* ---|-------|-------|-------|-------|------
* | |
* |<------ nr_full_windows ------>|
*
* In this case, p->ravg.sum is updated with (ws_tmp - ms) first *iff*
* event is appropriate, window sample of p->ravg.sum is recorded,
* 'nr_full_window' samples of window_size is also recorded *iff*
* event is appropriate and finally p->ravg.sum is set to (wc - ws)
* *iff* event is appropriate.
*
* IMPORTANT : Leave p->ravg.mark_start unchanged, as update_cpu_busy_time()
* depends on it!
*/
static u64 update_task_demand(struct task_struct *p, struct rq *rq,
int event, u64 wallclock)
{
u64 mark_start = p->ravg.mark_start;
u64 delta, window_start = rq->window_start;
int new_window, nr_full_windows;
u32 window_size = sched_ravg_window;
u64 runtime;
new_window = mark_start < window_start;
if (!account_busy_for_task_demand(rq, p, event)) {
if (new_window)
/*
* If the time accounted isn't being accounted as
* busy time, and a new window started, only the
* previous window need be closed out with the
* pre-existing demand. Multiple windows may have
* elapsed, but since empty windows are dropped,
* it is not necessary to account those.
*/
update_history(rq, p, p->ravg.sum, 1, event);
return 0;
}
if (!new_window) {
/*
* The simple case - busy time contained within the existing
* window.
*/
return add_to_task_demand(rq, p, wallclock - mark_start);
}
/*
* Busy time spans at least two windows. Temporarily rewind
* window_start to first window boundary after mark_start.
*/
delta = window_start - mark_start;
nr_full_windows = div64_u64(delta, window_size);
window_start -= (u64)nr_full_windows * (u64)window_size;
/* Process (window_start - mark_start) first */
runtime = add_to_task_demand(rq, p, window_start - mark_start);
/* Push new sample(s) into task's demand history */
update_history(rq, p, p->ravg.sum, 1, event);
if (nr_full_windows) {
u64 scaled_window = scale_exec_time(window_size, rq);
update_history(rq, p, scaled_window, nr_full_windows, event);
runtime += nr_full_windows * scaled_window;
}
/*
* Roll window_start back to current to process any remainder
* in current window.
*/
window_start += (u64)nr_full_windows * (u64)window_size;
/* Process (wallclock - window_start) next */
mark_start = window_start;
runtime += add_to_task_demand(rq, p, wallclock - mark_start);
return runtime;
}
static void
update_task_rq_cpu_cycles(struct task_struct *p, struct rq *rq, int event,
u64 wallclock, u64 irqtime)
{
u64 cur_cycles;
int cpu = cpu_of(rq);
lockdep_assert_held(&rq->lock);
if (!use_cycle_counter) {
rq->cc.cycles = cpu_cur_freq(cpu);
rq->cc.time = 1;
return;
}
cur_cycles = read_cycle_counter(cpu, wallclock);
/*
* If current task is idle task and irqtime == 0 CPU was
* indeed idle and probably its cycle counter was not
* increasing. We still need estimatied CPU frequency
* for IO wait time accounting. Use the previously
* calculated frequency in such a case.
*/
if (!is_idle_task(rq->curr) || irqtime) {
if (unlikely(cur_cycles < p->cpu_cycles))
rq->cc.cycles = cur_cycles + (U64_MAX - p->cpu_cycles);
else
rq->cc.cycles = cur_cycles - p->cpu_cycles;
rq->cc.cycles = rq->cc.cycles * NSEC_PER_MSEC;
if (event == IRQ_UPDATE && is_idle_task(p))
/*
* Time between mark_start of idle task and IRQ handler
* entry time is CPU cycle counter stall period.
* Upon IRQ handler entry sched_account_irqstart()
* replenishes idle task's cpu cycle counter so
* rq->cc.cycles now represents increased cycles during
* IRQ handler rather than time between idle entry and
* IRQ exit. Thus use irqtime as time delta.
*/
rq->cc.time = irqtime;
else
rq->cc.time = wallclock - p->ravg.mark_start;
BUG_ON((s64)rq->cc.time < 0);
}
p->cpu_cycles = cur_cycles;
trace_sched_get_task_cpu_cycles(cpu, event, rq->cc.cycles, rq->cc.time, p);
}
static inline void run_walt_irq_work(u64 old_window_start, struct rq *rq)
{
u64 result;
if (old_window_start == rq->window_start)
return;
result = atomic64_cmpxchg(&walt_irq_work_lastq_ws, old_window_start,
rq->window_start);
if (result == old_window_start)
sched_irq_work_queue(&walt_cpufreq_irq_work);
}
/* Reflect task activity on its demand and cpu's busy time statistics */
void update_task_ravg(struct task_struct *p, struct rq *rq, int event,
u64 wallclock, u64 irqtime)
{
u64 old_window_start;
if (!rq->window_start || sched_disable_window_stats ||
p->ravg.mark_start == wallclock)
return;
lockdep_assert_held(&rq->lock);
old_window_start = update_window_start(rq, wallclock, event);
if (!p->ravg.mark_start) {
update_task_cpu_cycles(p, cpu_of(rq), wallclock);
goto done;
}
update_task_rq_cpu_cycles(p, rq, event, wallclock, irqtime);
update_task_demand(p, rq, event, wallclock);
update_cpu_busy_time(p, rq, event, wallclock, irqtime);
update_task_pred_demand(rq, p, event);
if (exiting_task(p))
goto done;
trace_sched_update_task_ravg(p, rq, event, wallclock, irqtime,
rq->cc.cycles, rq->cc.time, &rq->grp_time);
trace_sched_update_task_ravg_mini(p, rq, event, wallclock, irqtime,
rq->cc.cycles, rq->cc.time, &rq->grp_time);
done:
p->ravg.mark_start = wallclock;
run_walt_irq_work(old_window_start, rq);
}
u32 sched_get_init_task_load(struct task_struct *p)
{
return p->init_load_pct;
}
int sched_set_init_task_load(struct task_struct *p, int init_load_pct)
{
if (init_load_pct < 0 || init_load_pct > 100)
return -EINVAL;
p->init_load_pct = init_load_pct;
return 0;
}
void init_new_task_load(struct task_struct *p)
{
int i;
u32 init_load_windows;
u32 init_load_pct;
p->init_load_pct = 0;
rcu_assign_pointer(p->grp, NULL);
INIT_LIST_HEAD(&p->grp_list);
memset(&p->ravg, 0, sizeof(struct ravg));
p->cpu_cycles = 0;
p->ravg.curr_window_cpu = kcalloc(nr_cpu_ids, sizeof(u32), GFP_KERNEL);
p->ravg.prev_window_cpu = kcalloc(nr_cpu_ids, sizeof(u32), GFP_KERNEL);
/* Don't have much choice. CPU frequency would be bogus */
BUG_ON(!p->ravg.curr_window_cpu || !p->ravg.prev_window_cpu);
if (current->init_load_pct)
init_load_pct = current->init_load_pct;
else
init_load_pct = sysctl_sched_init_task_load_pct;
init_load_windows = div64_u64((u64)init_load_pct *
(u64)sched_ravg_window, 100);
p->ravg.demand = init_load_windows;
p->ravg.coloc_demand = init_load_windows;
p->ravg.pred_demand = 0;
for (i = 0; i < RAVG_HIST_SIZE_MAX; ++i)
p->ravg.sum_history[i] = init_load_windows;
p->misfit = false;
}
/*
* kfree() may wakeup kswapd. So this function should NOT be called
* with any CPU's rq->lock acquired.
*/
void free_task_load_ptrs(struct task_struct *p)
{
kfree(p->ravg.curr_window_cpu);
kfree(p->ravg.prev_window_cpu);
/*
* update_task_ravg() can be called for exiting tasks. While the
* function itself ensures correct behavior, the corresponding
* trace event requires that these pointers be NULL.
*/
p->ravg.curr_window_cpu = NULL;
p->ravg.prev_window_cpu = NULL;
}
void reset_task_stats(struct task_struct *p)
{
u32 sum = 0;
u32 *curr_window_ptr = NULL;
u32 *prev_window_ptr = NULL;
if (exiting_task(p)) {
sum = EXITING_TASK_MARKER;
} else {
curr_window_ptr = p->ravg.curr_window_cpu;
prev_window_ptr = p->ravg.prev_window_cpu;
memset(curr_window_ptr, 0, sizeof(u32) * nr_cpu_ids);
memset(prev_window_ptr, 0, sizeof(u32) * nr_cpu_ids);
}
memset(&p->ravg, 0, sizeof(struct ravg));
p->ravg.curr_window_cpu = curr_window_ptr;
p->ravg.prev_window_cpu = prev_window_ptr;
/* Retain EXITING_TASK marker */
p->ravg.sum_history[0] = sum;
}
void mark_task_starting(struct task_struct *p)
{
u64 wallclock;
struct rq *rq = task_rq(p);
if (!rq->window_start || sched_disable_window_stats) {
reset_task_stats(p);
return;
}
wallclock = sched_ktime_clock();
p->ravg.mark_start = p->last_wake_ts = wallclock;
p->last_enqueued_ts = wallclock;
p->last_switch_out_ts = 0;
update_task_cpu_cycles(p, cpu_of(rq), wallclock);
}
static cpumask_t all_cluster_cpus = CPU_MASK_NONE;
DECLARE_BITMAP(all_cluster_ids, NR_CPUS);
struct sched_cluster *sched_cluster[NR_CPUS];
int num_clusters;
struct list_head cluster_head;
static void
insert_cluster(struct sched_cluster *cluster, struct list_head *head)
{
struct sched_cluster *tmp;
struct list_head *iter = head;
list_for_each_entry(tmp, head, list) {
if (cluster->max_power_cost < tmp->max_power_cost)
break;
iter = &tmp->list;
}
list_add(&cluster->list, iter);
}
static struct sched_cluster *alloc_new_cluster(const struct cpumask *cpus)
{
struct sched_cluster *cluster = NULL;
cluster = kzalloc(sizeof(struct sched_cluster), GFP_ATOMIC);
if (!cluster) {
__WARN_printf("Cluster allocation failed. Possible bad scheduling\n");
return NULL;
}
INIT_LIST_HEAD(&cluster->list);
cluster->max_power_cost = 1;
cluster->min_power_cost = 1;
cluster->capacity = 1024;
cluster->max_possible_capacity = 1024;
cluster->efficiency = 1;
cluster->load_scale_factor = 1024;
cluster->cur_freq = 1;
cluster->max_freq = 1;
cluster->max_mitigated_freq = UINT_MAX;
cluster->min_freq = 1;
cluster->max_possible_freq = 1;
cluster->dstate = 0;
cluster->dstate_wakeup_energy = 0;
cluster->dstate_wakeup_latency = 0;
cluster->freq_init_done = false;
raw_spin_lock_init(&cluster->load_lock);
cluster->cpus = *cpus;
cluster->efficiency = arch_get_cpu_efficiency(cpumask_first(cpus));
if (cluster->efficiency > max_possible_efficiency)
max_possible_efficiency = cluster->efficiency;
if (cluster->efficiency < min_possible_efficiency)
min_possible_efficiency = cluster->efficiency;
cluster->notifier_sent = 0;
return cluster;
}
static void add_cluster(const struct cpumask *cpus, struct list_head *head)
{
struct sched_cluster *cluster = alloc_new_cluster(cpus);
int i;
if (!cluster)
return;
for_each_cpu(i, cpus)
cpu_rq(i)->cluster = cluster;
insert_cluster(cluster, head);
set_bit(num_clusters, all_cluster_ids);
num_clusters++;
}
static int compute_max_possible_capacity(struct sched_cluster *cluster)
{
int capacity = 1024;
capacity *= capacity_scale_cpu_efficiency(cluster);
capacity >>= 10;
capacity *= (1024 * cluster->max_possible_freq) / min_max_freq;
capacity >>= 10;
return capacity;
}
void walt_update_min_max_capacity(void)
{
unsigned long flags;
acquire_rq_locks_irqsave(cpu_possible_mask, &flags);
__update_min_max_capacity();
release_rq_locks_irqrestore(cpu_possible_mask, &flags);
}
unsigned int max_power_cost = 1;
static int
compare_clusters(void *priv, struct list_head *a, struct list_head *b)
{
struct sched_cluster *cluster1, *cluster2;
int ret;
cluster1 = container_of(a, struct sched_cluster, list);
cluster2 = container_of(b, struct sched_cluster, list);
/*
* Don't assume higher capacity means higher power. If the
* power cost is same, sort the higher capacity cluster before
* the lower capacity cluster to start placing the tasks
* on the higher capacity cluster.
*/
ret = cluster1->max_power_cost > cluster2->max_power_cost ||
(cluster1->max_power_cost == cluster2->max_power_cost &&
cluster1->max_possible_capacity <
cluster2->max_possible_capacity);
return ret;
}
static void sort_clusters(void)
{
struct sched_cluster *cluster;
struct list_head new_head;
unsigned int tmp_max = 1;
INIT_LIST_HEAD(&new_head);
for_each_sched_cluster(cluster) {
cluster->max_power_cost = power_cost(cluster_first_cpu(cluster),
true);
cluster->min_power_cost = power_cost(cluster_first_cpu(cluster),
false);
if (cluster->max_power_cost > tmp_max)
tmp_max = cluster->max_power_cost;
}
max_power_cost = tmp_max;
move_list(&new_head, &cluster_head, true);
list_sort(NULL, &new_head, compare_clusters);
assign_cluster_ids(&new_head);
/*
* Ensure cluster ids are visible to all CPUs before making
* cluster_head visible.
*/
move_list(&cluster_head, &new_head, false);
}
int __read_mostly min_power_cpu;
void walt_sched_energy_populated_callback(void)
{
struct sched_cluster *cluster;
int prev_max = 0, next_min = 0;
mutex_lock(&cluster_lock);
if (num_clusters == 1) {
sysctl_sched_is_big_little = 0;
mutex_unlock(&cluster_lock);
return;
}
sort_clusters();
for_each_sched_cluster(cluster) {
if (cluster->min_power_cost > prev_max) {
prev_max = cluster->max_power_cost;
continue;
}
/*
* We assume no overlap in the power curves of
* clusters on a big.LITTLE system.
*/
sysctl_sched_is_big_little = 0;
next_min = cluster->min_power_cost;
}
/*
* Find the OPP at which the lower power cluster
* power is overlapping with the next cluster.
*/
if (!sysctl_sched_is_big_little) {
int cpu = cluster_first_cpu(sched_cluster[0]);
struct sched_group_energy *sge = sge_array[cpu][SD_LEVEL1];
int i;
for (i = 1; i < sge->nr_cap_states; i++) {
if (sge->cap_states[i].power >= next_min) {
sched_smp_overlap_capacity =
sge->cap_states[i-1].cap;
break;
}
}
min_power_cpu = cpu;
}
mutex_unlock(&cluster_lock);
}
static void update_all_clusters_stats(void)
{
struct sched_cluster *cluster;
u64 highest_mpc = 0, lowest_mpc = U64_MAX;
unsigned long flags;
acquire_rq_locks_irqsave(cpu_possible_mask, &flags);
for_each_sched_cluster(cluster) {
u64 mpc;
cluster->capacity = compute_capacity(cluster);
mpc = cluster->max_possible_capacity =
compute_max_possible_capacity(cluster);
cluster->load_scale_factor = compute_load_scale_factor(cluster);
cluster->exec_scale_factor =
DIV_ROUND_UP(cluster->efficiency * 1024,
max_possible_efficiency);
if (mpc > highest_mpc)
highest_mpc = mpc;
if (mpc < lowest_mpc)
lowest_mpc = mpc;
}
max_possible_capacity = highest_mpc;
min_max_possible_capacity = lowest_mpc;
__update_min_max_capacity();
sched_update_freq_max_load(cpu_possible_mask);
release_rq_locks_irqrestore(cpu_possible_mask, &flags);
}
void update_cluster_topology(void)
{
struct cpumask cpus = *cpu_possible_mask;
const struct cpumask *cluster_cpus;
struct list_head new_head;
int i;
INIT_LIST_HEAD(&new_head);
for_each_cpu(i, &cpus) {
cluster_cpus = cpu_coregroup_mask(i);
cpumask_or(&all_cluster_cpus, &all_cluster_cpus, cluster_cpus);
cpumask_andnot(&cpus, &cpus, cluster_cpus);
add_cluster(cluster_cpus, &new_head);
}
assign_cluster_ids(&new_head);
/*
* Ensure cluster ids are visible to all CPUs before making
* cluster_head visible.
*/
move_list(&cluster_head, &new_head, false);
update_all_clusters_stats();
}
struct sched_cluster init_cluster = {
.list = LIST_HEAD_INIT(init_cluster.list),
.id = 0,
.max_power_cost = 1,
.min_power_cost = 1,
.capacity = 1024,
.max_possible_capacity = 1024,
.efficiency = 1,
.load_scale_factor = 1024,
.cur_freq = 1,
.max_freq = 1,
.max_mitigated_freq = UINT_MAX,
.min_freq = 1,
.max_possible_freq = 1,
.dstate = 0,
.dstate_wakeup_energy = 0,
.dstate_wakeup_latency = 0,
.exec_scale_factor = 1024,
.notifier_sent = 0,
.wake_up_idle = 0,
.aggr_grp_load = 0,
.coloc_boost_load = 0,
};
void init_clusters(void)
{
bitmap_clear(all_cluster_ids, 0, NR_CPUS);
init_cluster.cpus = *cpu_possible_mask;
raw_spin_lock_init(&init_cluster.load_lock);
INIT_LIST_HEAD(&cluster_head);
}
static unsigned long cpu_max_table_freq[NR_CPUS];
static int cpufreq_notifier_policy(struct notifier_block *nb,
unsigned long val, void *data)
{
struct cpufreq_policy *policy = (struct cpufreq_policy *)data;
struct sched_cluster *cluster = NULL;
struct cpumask policy_cluster = *policy->related_cpus;
unsigned int orig_max_freq = 0;
int i, j, update_capacity = 0;
if (val != CPUFREQ_NOTIFY && val != CPUFREQ_REMOVE_POLICY &&
val != CPUFREQ_CREATE_POLICY)
return 0;
if (val == CPUFREQ_REMOVE_POLICY || val == CPUFREQ_CREATE_POLICY) {
walt_update_min_max_capacity();
return 0;
}
max_possible_freq = max(max_possible_freq, policy->cpuinfo.max_freq);
if (min_max_freq == 1)
min_max_freq = UINT_MAX;
min_max_freq = min(min_max_freq, policy->cpuinfo.max_freq);
BUG_ON(!min_max_freq);
BUG_ON(!policy->max);
for_each_cpu(i, &policy_cluster)
cpu_max_table_freq[i] = policy->cpuinfo.max_freq;
for_each_cpu(i, &policy_cluster) {
cluster = cpu_rq(i)->cluster;
cpumask_andnot(&policy_cluster, &policy_cluster,
&cluster->cpus);
orig_max_freq = cluster->max_freq;
cluster->min_freq = policy->min;
cluster->max_freq = policy->max;
cluster->cur_freq = policy->cur;
if (!cluster->freq_init_done) {
mutex_lock(&cluster_lock);
for_each_cpu(j, &cluster->cpus)
cpumask_copy(&cpu_rq(j)->freq_domain_cpumask,
policy->related_cpus);
cluster->max_possible_freq = policy->cpuinfo.max_freq;
cluster->max_possible_capacity =
compute_max_possible_capacity(cluster);
cluster->freq_init_done = true;
sort_clusters();
update_all_clusters_stats();
mutex_unlock(&cluster_lock);
continue;
}
update_capacity += (orig_max_freq != cluster->max_freq);
}
if (update_capacity)
update_cpu_cluster_capacity(policy->related_cpus);
return 0;
}
static struct notifier_block notifier_policy_block = {
.notifier_call = cpufreq_notifier_policy
};
static int cpufreq_notifier_trans(struct notifier_block *nb,
unsigned long val, void *data)
{
struct cpufreq_freqs *freq = (struct cpufreq_freqs *)data;
unsigned int cpu = freq->cpu, new_freq = freq->new;
unsigned long flags;
struct sched_cluster *cluster;
struct cpumask policy_cpus = cpu_rq(cpu)->freq_domain_cpumask;
int i, j;
if (val != CPUFREQ_POSTCHANGE)
return NOTIFY_DONE;
if (cpu_cur_freq(cpu) == new_freq)
return NOTIFY_OK;
for_each_cpu(i, &policy_cpus) {
cluster = cpu_rq(i)->cluster;
if (!use_cycle_counter) {
for_each_cpu(j, &cluster->cpus) {
struct rq *rq = cpu_rq(j);
raw_spin_lock_irqsave(&rq->lock, flags);
update_task_ravg(rq->curr, rq, TASK_UPDATE,
sched_ktime_clock(), 0);
raw_spin_unlock_irqrestore(&rq->lock, flags);
}
}
cluster->cur_freq = new_freq;
cpumask_andnot(&policy_cpus, &policy_cpus, &cluster->cpus);
}
return NOTIFY_OK;
}
static struct notifier_block notifier_trans_block = {
.notifier_call = cpufreq_notifier_trans
};
static int register_walt_callback(void)
{
int ret;
ret = cpufreq_register_notifier(&notifier_policy_block,
CPUFREQ_POLICY_NOTIFIER);
if (!ret)
ret = cpufreq_register_notifier(&notifier_trans_block,
CPUFREQ_TRANSITION_NOTIFIER);
return ret;
}
/*
* cpufreq callbacks can be registered at core_initcall or later time.
* Any registration done prior to that is "forgotten" by cpufreq. See
* initialization of variable init_cpufreq_transition_notifier_list_called
* for further information.
*/
core_initcall(register_walt_callback);
static void transfer_busy_time(struct rq *rq, struct related_thread_group *grp,
struct task_struct *p, int event);
/*
* Enable colocation and frequency aggregation for all threads in a process.
* The children inherits the group id from the parent.
*/
unsigned int __read_mostly sysctl_sched_enable_thread_grouping;
/* Maximum allowed threshold before freq aggregation must be enabled */
#define MAX_FREQ_AGGR_THRESH 1000
struct related_thread_group *related_thread_groups[MAX_NUM_CGROUP_COLOC_ID];
static LIST_HEAD(active_related_thread_groups);
DEFINE_RWLOCK(related_thread_group_lock);
unsigned int __read_mostly sysctl_sched_freq_aggregate_threshold_pct;
/*
* Task groups whose aggregate demand on a cpu is more than
* sched_group_upmigrate need to be up-migrated if possible.
*/
unsigned int __read_mostly sched_group_upmigrate = 20000000;
unsigned int __read_mostly sysctl_sched_group_upmigrate_pct = 100;
/*
* Task groups, once up-migrated, will need to drop their aggregate
* demand to less than sched_group_downmigrate before they are "down"
* migrated.
*/
unsigned int __read_mostly sched_group_downmigrate = 19000000;
unsigned int __read_mostly sysctl_sched_group_downmigrate_pct = 95;
static int
group_will_fit(struct sched_cluster *cluster, struct related_thread_group *grp,
u64 demand, bool group_boost)
{
int cpu = cluster_first_cpu(cluster);
int prev_capacity = 0;
unsigned int threshold = sched_group_upmigrate;
u64 load;
if (cluster->capacity == max_capacity)
return 1;
if (group_boost)
return 0;
if (!demand)
return 1;
if (grp->preferred_cluster)
prev_capacity = grp->preferred_cluster->capacity;
if (cluster->capacity < prev_capacity)
threshold = sched_group_downmigrate;
load = scale_load_to_cpu(demand, cpu);
if (load < threshold)
return 1;
return 0;
}
unsigned long __weak arch_get_cpu_efficiency(int cpu)
{
return SCHED_CAPACITY_SCALE;
}
/* Return cluster which can offer required capacity for group */
static struct sched_cluster *best_cluster(struct related_thread_group *grp,
u64 total_demand, bool group_boost)
{
struct sched_cluster *cluster = NULL;
for_each_sched_cluster(cluster) {
if (group_will_fit(cluster, grp, total_demand, group_boost))
return cluster;
}
return sched_cluster[0];
}
int preferred_cluster(struct sched_cluster *cluster, struct task_struct *p)
{
struct related_thread_group *grp;
int rc = 1;
rcu_read_lock();
grp = task_related_thread_group(p);
if (grp)
rc = (grp->preferred_cluster == cluster);
rcu_read_unlock();
return rc;
}
static void _set_preferred_cluster(struct related_thread_group *grp)
{
struct task_struct *p;
u64 combined_demand = 0;
bool group_boost = false;
u64 wallclock;
if (list_empty(&grp->tasks))
return;
if (!sysctl_sched_is_big_little) {
grp->preferred_cluster = sched_cluster[0];
return;
}
wallclock = sched_ktime_clock();
/*
* wakeup of two or more related tasks could race with each other and
* could result in multiple calls to _set_preferred_cluster being issued
* at same time. Avoid overhead in such cases of rechecking preferred
* cluster
*/
if (wallclock - grp->last_update < sched_ravg_window / 10)
return;
list_for_each_entry(p, &grp->tasks, grp_list) {
if (task_boost_policy(p) == SCHED_BOOST_ON_BIG) {
group_boost = true;
break;
}
if (p->ravg.mark_start < wallclock -
(sched_ravg_window * sched_ravg_hist_size))
continue;
combined_demand += p->ravg.coloc_demand;
}
grp->preferred_cluster = best_cluster(grp,
combined_demand, group_boost);
grp->last_update = sched_ktime_clock();
trace_sched_set_preferred_cluster(grp, combined_demand);
}
void set_preferred_cluster(struct related_thread_group *grp)
{
raw_spin_lock(&grp->lock);
_set_preferred_cluster(grp);
raw_spin_unlock(&grp->lock);
}
int update_preferred_cluster(struct related_thread_group *grp,
struct task_struct *p, u32 old_load)
{
u32 new_load = task_load(p);
if (!grp)
return 0;
/*
* Update if task's load has changed significantly or a complete window
* has passed since we last updated preference
*/
if (abs(new_load - old_load) > sched_ravg_window / 4 ||
sched_ktime_clock() - grp->last_update > sched_ravg_window)
return 1;
return 0;
}
DEFINE_MUTEX(policy_mutex);
#define pct_to_real(tunable) \
(div64_u64((u64)tunable * (u64)max_task_load(), 100))
unsigned int update_freq_aggregate_threshold(unsigned int threshold)
{
unsigned int old_threshold;
mutex_lock(&policy_mutex);
old_threshold = sysctl_sched_freq_aggregate_threshold_pct;
sysctl_sched_freq_aggregate_threshold_pct = threshold;
sched_freq_aggregate_threshold =
pct_to_real(sysctl_sched_freq_aggregate_threshold_pct);
mutex_unlock(&policy_mutex);
return old_threshold;
}
#define ADD_TASK 0
#define REM_TASK 1
#define DEFAULT_CGROUP_COLOC_ID 1
static inline struct related_thread_group*
lookup_related_thread_group(unsigned int group_id)
{
return related_thread_groups[group_id];
}
int alloc_related_thread_groups(void)
{
int i, ret;
struct related_thread_group *grp;
/* groupd_id = 0 is invalid as it's special id to remove group. */
for (i = 1; i < MAX_NUM_CGROUP_COLOC_ID; i++) {
grp = kzalloc(sizeof(*grp), GFP_NOWAIT);
if (!grp) {
ret = -ENOMEM;
goto err;
}
grp->id = i;
INIT_LIST_HEAD(&grp->tasks);
INIT_LIST_HEAD(&grp->list);
raw_spin_lock_init(&grp->lock);
related_thread_groups[i] = grp;
}
return 0;
err:
for (i = 1; i < MAX_NUM_CGROUP_COLOC_ID; i++) {
grp = lookup_related_thread_group(i);
if (grp) {
kfree(grp);
related_thread_groups[i] = NULL;
} else {
break;
}
}
return ret;
}
static void remove_task_from_group(struct task_struct *p)
{
struct related_thread_group *grp = p->grp;
struct rq *rq;
int empty_group = 1;
struct rq_flags rf;
raw_spin_lock(&grp->lock);
rq = __task_rq_lock(p, &rf);
transfer_busy_time(rq, p->grp, p, REM_TASK);
list_del_init(&p->grp_list);
rcu_assign_pointer(p->grp, NULL);
__task_rq_unlock(rq, &rf);
if (!list_empty(&grp->tasks)) {
empty_group = 0;
_set_preferred_cluster(grp);
}
raw_spin_unlock(&grp->lock);
/* Reserved groups cannot be destroyed */
if (empty_group && grp->id != DEFAULT_CGROUP_COLOC_ID)
/*
* We test whether grp->list is attached with list_empty()
* hence re-init the list after deletion.
*/
list_del_init(&grp->list);
}
static int
add_task_to_group(struct task_struct *p, struct related_thread_group *grp)
{
struct rq *rq;
struct rq_flags rf;
raw_spin_lock(&grp->lock);
/*
* Change p->grp under rq->lock. Will prevent races with read-side
* reference of p->grp in various hot-paths
*/
rq = __task_rq_lock(p, &rf);
transfer_busy_time(rq, grp, p, ADD_TASK);
list_add(&p->grp_list, &grp->tasks);
rcu_assign_pointer(p->grp, grp);
__task_rq_unlock(rq, &rf);
_set_preferred_cluster(grp);
raw_spin_unlock(&grp->lock);
return 0;
}
void add_new_task_to_grp(struct task_struct *new)
{
unsigned long flags;
struct related_thread_group *grp;
struct task_struct *leader = new->group_leader;
unsigned int leader_grp_id = sched_get_group_id(leader);
if (!sysctl_sched_enable_thread_grouping &&
leader_grp_id != DEFAULT_CGROUP_COLOC_ID)
return;
if (thread_group_leader(new))
return;
if (leader_grp_id == DEFAULT_CGROUP_COLOC_ID) {
if (!same_schedtune(new, leader))
return;
}
write_lock_irqsave(&related_thread_group_lock, flags);
rcu_read_lock();
grp = task_related_thread_group(leader);
rcu_read_unlock();
/*
* It's possible that someone already added the new task to the
* group. A leader's thread group is updated prior to calling
* this function. It's also possible that the leader has exited
* the group. In either case, there is nothing else to do.
*/
if (!grp || new->grp) {
write_unlock_irqrestore(&related_thread_group_lock, flags);
return;
}
raw_spin_lock(&grp->lock);
rcu_assign_pointer(new->grp, grp);
list_add(&new->grp_list, &grp->tasks);
raw_spin_unlock(&grp->lock);
write_unlock_irqrestore(&related_thread_group_lock, flags);
}
static int __sched_set_group_id(struct task_struct *p, unsigned int group_id)
{
int rc = 0;
unsigned long flags;
struct related_thread_group *grp = NULL;
if (group_id >= MAX_NUM_CGROUP_COLOC_ID)
return -EINVAL;
raw_spin_lock_irqsave(&p->pi_lock, flags);
write_lock(&related_thread_group_lock);
/* Switching from one group to another directly is not permitted */
if ((current != p && p->flags & PF_EXITING) ||
(!p->grp && !group_id) ||
(p->grp && group_id))
goto done;
if (!group_id) {
remove_task_from_group(p);
goto done;
}
grp = lookup_related_thread_group(group_id);
if (list_empty(&grp->list))
list_add(&grp->list, &active_related_thread_groups);
rc = add_task_to_group(p, grp);
done:
write_unlock(&related_thread_group_lock);
raw_spin_unlock_irqrestore(&p->pi_lock, flags);
return rc;
}
int sched_set_group_id(struct task_struct *p, unsigned int group_id)
{
/* DEFAULT_CGROUP_COLOC_ID is a reserved id */
if (group_id == DEFAULT_CGROUP_COLOC_ID)
return -EINVAL;
return __sched_set_group_id(p, group_id);
}
unsigned int sched_get_group_id(struct task_struct *p)
{
unsigned int group_id;
struct related_thread_group *grp;
rcu_read_lock();
grp = task_related_thread_group(p);
group_id = grp ? grp->id : 0;
rcu_read_unlock();
return group_id;
}
#if defined(CONFIG_SCHED_TUNE) && defined(CONFIG_CGROUP_SCHEDTUNE)
/*
* We create a default colocation group at boot. There is no need to
* synchronize tasks between cgroups at creation time because the
* correct cgroup hierarchy is not available at boot. Therefore cgroup
* colocation is turned off by default even though the colocation group
* itself has been allocated. Furthermore this colocation group cannot
* be destroyted once it has been created. All of this has been as part
* of runtime optimizations.
*
* The job of synchronizing tasks to the colocation group is done when
* the colocation flag in the cgroup is turned on.
*/
static int __init create_default_coloc_group(void)
{
struct related_thread_group *grp = NULL;
unsigned long flags;
grp = lookup_related_thread_group(DEFAULT_CGROUP_COLOC_ID);
write_lock_irqsave(&related_thread_group_lock, flags);
list_add(&grp->list, &active_related_thread_groups);
write_unlock_irqrestore(&related_thread_group_lock, flags);
update_freq_aggregate_threshold(MAX_FREQ_AGGR_THRESH);
return 0;
}
late_initcall(create_default_coloc_group);
int sync_cgroup_colocation(struct task_struct *p, bool insert)
{
unsigned int grp_id = insert ? DEFAULT_CGROUP_COLOC_ID : 0;
return __sched_set_group_id(p, grp_id);
}
#endif
void update_cpu_cluster_capacity(const cpumask_t *cpus)
{
int i;
struct sched_cluster *cluster;
struct cpumask cpumask;
unsigned long flags;
cpumask_copy(&cpumask, cpus);
acquire_rq_locks_irqsave(cpu_possible_mask, &flags);
for_each_cpu(i, &cpumask) {
cluster = cpu_rq(i)->cluster;
cpumask_andnot(&cpumask, &cpumask, &cluster->cpus);
cluster->capacity = compute_capacity(cluster);
cluster->load_scale_factor = compute_load_scale_factor(cluster);
}
__update_min_max_capacity();
release_rq_locks_irqrestore(cpu_possible_mask, &flags);
}
static unsigned long max_cap[NR_CPUS];
static unsigned long thermal_cap_cpu[NR_CPUS];
unsigned long thermal_cap(int cpu)
{
return thermal_cap_cpu[cpu] ?: SCHED_CAPACITY_SCALE;
}
unsigned long do_thermal_cap(int cpu, unsigned long thermal_max_freq)
{
struct sched_domain *sd;
struct sched_group *sg;
struct rq *rq = cpu_rq(cpu);
int nr_cap_states;
if (!max_cap[cpu]) {
rcu_read_lock();
sd = rcu_dereference(per_cpu(sd_ea, cpu));
if (!sd || !sd->groups || !sd->groups->sge ||
!sd->groups->sge->cap_states) {
rcu_read_unlock();
return rq->cpu_capacity_orig;
}
sg = sd->groups;
nr_cap_states = sg->sge->nr_cap_states;
max_cap[cpu] = sg->sge->cap_states[nr_cap_states - 1].cap;
rcu_read_unlock();
}
if (cpu_max_table_freq[cpu])
return div64_ul(thermal_max_freq * max_cap[cpu],
cpu_max_table_freq[cpu]);
else
return rq->cpu_capacity_orig;
}
static DEFINE_SPINLOCK(cpu_freq_min_max_lock);
void sched_update_cpu_freq_min_max(const cpumask_t *cpus, u32 fmin, u32 fmax)
{
struct cpumask cpumask;
struct sched_cluster *cluster;
int i, update_capacity = 0;
unsigned long flags;
spin_lock_irqsave(&cpu_freq_min_max_lock, flags);
cpumask_copy(&cpumask, cpus);
for_each_cpu(i, &cpumask)
thermal_cap_cpu[i] = do_thermal_cap(i, fmax);
for_each_cpu(i, &cpumask) {
cluster = cpu_rq(i)->cluster;
cpumask_andnot(&cpumask, &cpumask, &cluster->cpus);
update_capacity += (cluster->max_mitigated_freq != fmax);
cluster->max_mitigated_freq = fmax;
}
spin_unlock_irqrestore(&cpu_freq_min_max_lock, flags);
if (update_capacity)
update_cpu_cluster_capacity(cpus);
}
void note_task_waking(struct task_struct *p, u64 wallclock)
{
p->last_wake_ts = wallclock;
}
/*
* Task's cpu usage is accounted in:
* rq->curr/prev_runnable_sum, when its ->grp is NULL
* grp->cpu_time[cpu]->curr/prev_runnable_sum, when its ->grp is !NULL
*
* Transfer task's cpu usage between those counters when transitioning between
* groups
*/
static void transfer_busy_time(struct rq *rq, struct related_thread_group *grp,
struct task_struct *p, int event)
{
u64 wallclock;
struct group_cpu_time *cpu_time;
u64 *src_curr_runnable_sum, *dst_curr_runnable_sum;
u64 *src_prev_runnable_sum, *dst_prev_runnable_sum;
u64 *src_nt_curr_runnable_sum, *dst_nt_curr_runnable_sum;
u64 *src_nt_prev_runnable_sum, *dst_nt_prev_runnable_sum;
int migrate_type;
int cpu = cpu_of(rq);
bool new_task;
int i;
wallclock = sched_ktime_clock();
update_task_ravg(rq->curr, rq, TASK_UPDATE, wallclock, 0);
update_task_ravg(p, rq, TASK_UPDATE, wallclock, 0);
new_task = is_new_task(p);
cpu_time = &rq->grp_time;
if (event == ADD_TASK) {
migrate_type = RQ_TO_GROUP;
src_curr_runnable_sum = &rq->curr_runnable_sum;
dst_curr_runnable_sum = &cpu_time->curr_runnable_sum;
src_prev_runnable_sum = &rq->prev_runnable_sum;
dst_prev_runnable_sum = &cpu_time->prev_runnable_sum;
src_nt_curr_runnable_sum = &rq->nt_curr_runnable_sum;
dst_nt_curr_runnable_sum = &cpu_time->nt_curr_runnable_sum;
src_nt_prev_runnable_sum = &rq->nt_prev_runnable_sum;
dst_nt_prev_runnable_sum = &cpu_time->nt_prev_runnable_sum;
*src_curr_runnable_sum -= p->ravg.curr_window_cpu[cpu];
*src_prev_runnable_sum -= p->ravg.prev_window_cpu[cpu];
if (new_task) {
*src_nt_curr_runnable_sum -=
p->ravg.curr_window_cpu[cpu];
*src_nt_prev_runnable_sum -=
p->ravg.prev_window_cpu[cpu];
}
update_cluster_load_subtractions(p, cpu,
rq->window_start, new_task);
} else {
migrate_type = GROUP_TO_RQ;
src_curr_runnable_sum = &cpu_time->curr_runnable_sum;
dst_curr_runnable_sum = &rq->curr_runnable_sum;
src_prev_runnable_sum = &cpu_time->prev_runnable_sum;
dst_prev_runnable_sum = &rq->prev_runnable_sum;
src_nt_curr_runnable_sum = &cpu_time->nt_curr_runnable_sum;
dst_nt_curr_runnable_sum = &rq->nt_curr_runnable_sum;
src_nt_prev_runnable_sum = &cpu_time->nt_prev_runnable_sum;
dst_nt_prev_runnable_sum = &rq->nt_prev_runnable_sum;
*src_curr_runnable_sum -= p->ravg.curr_window;
*src_prev_runnable_sum -= p->ravg.prev_window;
if (new_task) {
*src_nt_curr_runnable_sum -= p->ravg.curr_window;
*src_nt_prev_runnable_sum -= p->ravg.prev_window;
}
/*
* Need to reset curr/prev windows for all CPUs, not just the
* ones in the same cluster. Since inter cluster migrations
* did not result in the appropriate book keeping, the values
* per CPU would be inaccurate.
*/
for_each_possible_cpu(i) {
p->ravg.curr_window_cpu[i] = 0;
p->ravg.prev_window_cpu[i] = 0;
}
}
*dst_curr_runnable_sum += p->ravg.curr_window;
*dst_prev_runnable_sum += p->ravg.prev_window;
if (new_task) {
*dst_nt_curr_runnable_sum += p->ravg.curr_window;
*dst_nt_prev_runnable_sum += p->ravg.prev_window;
}
/*
* When a task enter or exits a group, it's curr and prev windows are
* moved to a single CPU. This behavior might be sub-optimal in the
* exit case, however, it saves us the overhead of handling inter
* cluster migration fixups while the task is part of a related group.
*/
p->ravg.curr_window_cpu[cpu] = p->ravg.curr_window;
p->ravg.prev_window_cpu[cpu] = p->ravg.prev_window;
trace_sched_migration_update_sum(p, migrate_type, rq);
BUG_ON((s64)*src_curr_runnable_sum < 0);
BUG_ON((s64)*src_prev_runnable_sum < 0);
BUG_ON((s64)*src_nt_curr_runnable_sum < 0);
BUG_ON((s64)*src_nt_prev_runnable_sum < 0);
}
unsigned int sysctl_sched_little_cluster_coloc_fmin_khz;
static u64 coloc_boost_load;
void walt_map_freq_to_load(void)
{
struct sched_cluster *cluster;
for_each_sched_cluster(cluster) {
if (is_min_capacity_cluster(cluster)) {
int fcpu = cluster_first_cpu(cluster);
coloc_boost_load = div64_u64(
((u64)sched_ravg_window *
arch_scale_cpu_capacity(NULL, fcpu) *
sysctl_sched_little_cluster_coloc_fmin_khz),
(u64)1024 * cpu_max_possible_freq(fcpu));
coloc_boost_load = div64_u64(coloc_boost_load << 2, 5);
break;
}
}
}
static void walt_update_coloc_boost_load(void)
{
struct related_thread_group *grp;
struct sched_cluster *cluster;
if (!sysctl_sched_little_cluster_coloc_fmin_khz ||
sysctl_sched_boost == CONSERVATIVE_BOOST)
return;
grp = lookup_related_thread_group(DEFAULT_CGROUP_COLOC_ID);
if (!grp || !grp->preferred_cluster ||
is_min_capacity_cluster(grp->preferred_cluster))
return;
for_each_sched_cluster(cluster) {
if (is_min_capacity_cluster(cluster)) {
cluster->coloc_boost_load = coloc_boost_load;
break;
}
}
}
int sched_little_cluster_coloc_fmin_khz_handler(struct ctl_table *table,
int write, void __user *buffer, size_t *lenp,
loff_t *ppos)
{
int ret;
static DEFINE_MUTEX(mutex);
mutex_lock(&mutex);
ret = proc_dointvec_minmax(table, write, buffer, lenp, ppos);
if (ret || !write)
goto done;
walt_map_freq_to_load();
done:
mutex_unlock(&mutex);
return ret;
}
/*
* Runs in hard-irq context. This should ideally run just after the latest
* window roll-over.
*/
void walt_irq_work(struct irq_work *irq_work)
{
struct sched_cluster *cluster;
struct rq *rq;
int cpu;
u64 wc, total_grp_load = 0;
int flag = SCHED_CPUFREQ_WALT;
bool is_migration = false;
int level = 0;
/* Am I the window rollover work or the migration work? */
if (irq_work == &walt_migration_irq_work)
is_migration = true;
for_each_cpu(cpu, cpu_possible_mask) {
if (level == 0)
raw_spin_lock(&cpu_rq(cpu)->lock);
else
raw_spin_lock_nested(&cpu_rq(cpu)->lock, level);
level++;
}
wc = sched_ktime_clock();
walt_load_reported_window = atomic64_read(&walt_irq_work_lastq_ws);
for_each_sched_cluster(cluster) {
u64 aggr_grp_load = 0;
raw_spin_lock(&cluster->load_lock);
for_each_cpu(cpu, &cluster->cpus) {
rq = cpu_rq(cpu);
if (rq->curr) {
update_task_ravg(rq->curr, rq,
TASK_UPDATE, wc, 0);
account_load_subtractions(rq);
aggr_grp_load += rq->grp_time.prev_runnable_sum;
}
}
cluster->aggr_grp_load = aggr_grp_load;
total_grp_load = aggr_grp_load;
cluster->coloc_boost_load = 0;
raw_spin_unlock(&cluster->load_lock);
}
if (total_grp_load)
walt_update_coloc_boost_load();
for_each_sched_cluster(cluster) {
for_each_cpu(cpu, &cluster->cpus) {
int nflag = flag;
rq = cpu_rq(cpu);
if (is_migration) {
if (rq->notif_pending) {
nflag |= SCHED_CPUFREQ_INTERCLUSTER_MIG;
rq->notif_pending = false;
} else {
nflag |= SCHED_CPUFREQ_FORCE_UPDATE;
}
}
cpufreq_update_util(rq, nflag);
}
}
for_each_cpu(cpu, cpu_possible_mask)
raw_spin_unlock(&cpu_rq(cpu)->lock);
if (!is_migration)
core_ctl_check(this_rq()->window_start);
}
void walt_rotation_checkpoint(int nr_big)
{
if (!hmp_capable())
return;
if (!sysctl_sched_walt_rotate_big_tasks || sched_boost() != NO_BOOST) {
walt_rotation_enabled = 0;
return;
}
walt_rotation_enabled = nr_big >= num_possible_cpus();
}
int walt_proc_update_handler(struct ctl_table *table, int write,
void __user *buffer, size_t *lenp,
loff_t *ppos)
{
int ret;
unsigned int *data = (unsigned int *)table->data;
static DEFINE_MUTEX(mutex);
mutex_lock(&mutex);
ret = proc_dointvec_minmax(table, write, buffer, lenp, ppos);
if (ret || !write) {
mutex_unlock(&mutex);
return ret;
}
if (data == &sysctl_sched_group_upmigrate_pct)
sched_group_upmigrate =
pct_to_real(sysctl_sched_group_upmigrate_pct);
else if (data == &sysctl_sched_group_downmigrate_pct)
sched_group_downmigrate =
pct_to_real(sysctl_sched_group_downmigrate_pct);
else
ret = -EINVAL;
mutex_unlock(&mutex);
return ret;
}
void walt_sched_init(struct rq *rq)
{
int j;
cpumask_set_cpu(cpu_of(rq), &rq->freq_domain_cpumask);
init_irq_work(&walt_migration_irq_work, walt_irq_work);
init_irq_work(&walt_cpufreq_irq_work, walt_irq_work);
walt_rotate_work_init();
rq->walt_stats.cumulative_runnable_avg = 0;
rq->window_start = 0;
rq->cum_window_start = 0;
rq->walt_stats.nr_big_tasks = 0;
rq->walt_flags = 0;
rq->cur_irqload = 0;
rq->avg_irqload = 0;
rq->irqload_ts = 0;
rq->static_cpu_pwr_cost = 0;
rq->cc.cycles = 1;
rq->cc.time = 1;
rq->cstate = 0;
rq->wakeup_latency = 0;
rq->wakeup_energy = 0;
/*
* All cpus part of same cluster by default. This avoids the
* need to check for rq->cluster being non-NULL in hot-paths
* like select_best_cpu()
*/
rq->cluster = &init_cluster;
rq->curr_runnable_sum = rq->prev_runnable_sum = 0;
rq->nt_curr_runnable_sum = rq->nt_prev_runnable_sum = 0;
memset(&rq->grp_time, 0, sizeof(struct group_cpu_time));
rq->old_busy_time = 0;
rq->old_estimated_time = 0;
rq->old_busy_time_group = 0;
rq->walt_stats.pred_demands_sum = 0;
rq->ed_task = NULL;
rq->curr_table = 0;
rq->prev_top = 0;
rq->curr_top = 0;
rq->last_cc_update = 0;
rq->cycles = 0;
for (j = 0; j < NUM_TRACKED_WINDOWS; j++) {
memset(&rq->load_subs[j], 0,
sizeof(struct load_subtractions));
rq->top_tasks[j] = kcalloc(NUM_LOAD_INDICES,
sizeof(u8), GFP_NOWAIT);
/* No other choice */
BUG_ON(!rq->top_tasks[j]);
clear_top_tasks_bitmap(rq->top_tasks_bitmap[j]);
}
rq->cum_window_demand = 0;
rq->notif_pending = false;
walt_cpu_util_freq_divisor =
(sched_ravg_window >> SCHED_CAPACITY_SHIFT) * 100;
}