cpuidle/drivers/mobile: Add new governor for mobile/embedded systems

The objective is the same for all the governors: save energy, but at
the end the governors menu, ladder and teo aim to improve the
performances with an acceptable energy drop for some workloads which
are identified for servers and desktops (with the help of a firmware).

The ladder governor is designed for server with a periodic tick
configuration.

The menu governor does not behave nicely with the mobile platform and
the energy saving for the multimedia workloads is worst than picking
up randomly an idle state.

The teo governor acts efficiently, it promotes shallower state for
performances which is perfect for the servers / desktop but inadequate
for mobile because the energy consumed is too high.

It is very difficult to do changes in these governors for embedded
systems without impacting performances on servers/desktops or ruin the
optimizations for the workloads on these platforms.

The mobile governor is a new governor targeting embedded systems
running on battery where the energy saving has a higher priority than
servers or desktops. This governor aims to save energy as much as
possible but with a performance degradation tolerance.

In this way, we can optimize the governor for specific mobile workload
and more generally embedded systems without impacting other platforms.

The mobile governor is built on top of the paradigm 'separate the wake
up sources signals and analyze them'. Three categories of wake up
signals are identified:
 - deterministic : timers
 - predictable : most of the devices interrupt
 - unpredictable : IPI rescheduling, random signals

The latter needs an iterative approach and the help of the scheduler
to give more input to the governor.

The governor uses the irq timings where we predict the next interrupt
occurrences on the current CPU and the next timer. It is well suited
for mobile and more generally embedded systems where the interrupts
are usually pinned on one CPU and where the power is more important
than the performances.

The multimedia applications on the embedded system spawn multiple
threads which are migrated across the different CPUs and waking
between them up. In order to catch this situation we have also to
track the idle task rescheduling duration with a relative degree of
confidence as the scheduler is involved in the task migrations. The
resched information is in the scope of the governor via the reflect
callback.

The governor begins with a clean foundation basing the prediction on
the irq behavior returned by the irq timings, the timers and the idle
task rescheduling. The advantage of the approach is we have a full
view of the wakeup sources as we identify them separately and then we
can control the situation without relying on biased heuristics.

This first iteration provides a basic prediction but improves on some
mobile platforms better energy for better performance for multimedia
workloads.

The scheduling aspect will be optimized iteratively with non
regression testing for previous identified workloads on an Android
reference platform.

Signed-off-by: Daniel Lezcano <daniel.lezcano@linaro.org>

---
 drivers/cpuidle/Kconfig            |  11 ++-
 drivers/cpuidle/governors/Makefile |   1 +
 drivers/cpuidle/governors/mobile.c | 151 +++++++++++++++++++++++++++++
 3 files changed, 162 insertions(+), 1 deletion(-)
 create mode 100644 drivers/cpuidle/governors/mobile.c

-- 
2.17.1

Hi Daniel,

I tried your "mobile" governor, albeit not on a mobile device.

On 2019.06.20 04:58 Daniel Lezcano wrote:

...

> The mobile governor is a new governor targeting embedded systems

> running on battery where the energy saving has a higher priority than

> servers or desktops. This governor aims to save energy as much as

> possible but with a performance degradation tolerance.

>

> In this way, we can optimize the governor for specific mobile workload

> and more generally embedded systems without impacting other platforms.


I just wanted to observe the lower energy, accepting performance
degradation. My workloads may have been inappropriate.

...

> +

> +#define EMA_ALPHA_VAL		64

> +#define EMA_ALPHA_SHIFT		7

> +#define MAX_RESCHED_INTERVAL_MS	100

> +

> +static DEFINE_PER_CPU(struct mobile_device, mobile_devices);

> +

> +static int mobile_ema_new(s64 value, s64 ema_old)

> +{

> +	if (likely(ema_old))

> +		return ema_old + (((value - ema_old) * EMA_ALPHA_VAL) >>

> +				  EMA_ALPHA_SHIFT);

> +	return value;

> +}


Do you have any information as to why these numbers?
Without any background, the filter seems overly new value weighted to me.
It is an infinite impulse response type filter, currently at:

output = 0.5 * old + 0.5 * new.

I tried, but didn't get anything conclusive:

output = 0.875 * old + 0.125 * new.

I did it this way:

#define EMA_ALPHA_VAL           7
#define EMA_ALPHA_SHIFT         3
#define MAX_RESCHED_INTERVAL_MS 100

static DEFINE_PER_CPU(struct mobile_device, mobile_devices);

static int mobile_ema_new(s64 value, s64 ema_old)
{
        if (likely(ema_old))
                return ((ema_old * EMA_ALPHA_VAL) + value) >>
                                  EMA_ALPHA_SHIFT;
        return value;
}

...

> +	/*

> +	 * Sum all the residencies in order to compute the total

> +	 * duration of the idle task.

> +	 */

> +	residency = dev->last_residency - s->exit_latency;


What about when the CPU comes out of the idle state before it
even gets fully into it? Under such conditions it seems to hold
much too hard at idle states that are too deep, to the point
where energy goes up while performance goes down.

Anyway, I did a bunch of tests and such, but have deleted
most from this e-mail, because it's just noise. I'll
include just one set:

For a work load that would normally result in a lot of use
of shallow idle states (single core pipe-test * 2 cores).
I got (all kernel 5.2-rc5 + this patch):

Idle governor, teo; CPU frequency scaling: intel-cpufreq/ondemand;
Processor package power: 40.4 watts; 4.9 uSec/loop

Idle governor, teo; CPU frequency scaling: intel-cpufreq/ondemand;
Processor package power: 34 watts; 5.2 uSec/loop

Idle governor, mobile; CPU frequency scaling: intel-cpufreq/ondemand;
Processor package power: 25.9 watts; 11.1 uSec/loop

Idle governor, menu; CPU frequency scaling: intel-cpufreq/ondemand;
Processor package power: 34.2 watts; 5.23 uSec/loop

Idle governor, teo; CPU frequency scaling: intel-cpufreq/ondemand;
Maximum CPU frequency limited to 73% to match mobile energy.
Processor package power: 25.4 watts; 6.4 uSec/loop

... Doug

Hi Doug,

On 03/07/2019 16:23, Doug Smythies wrote:
> Hi Daniel,

> 

> I tried your "mobile" governor, albeit not on a mobile device.

> 

> On 2019.06.20 04:58 Daniel Lezcano wrote:

> 

> ...

> 

>> The mobile governor is a new governor targeting embedded systems

>> running on battery where the energy saving has a higher priority than

>> servers or desktops. This governor aims to save energy as much as

>> possible but with a performance degradation tolerance.

>>

>> In this way, we can optimize the governor for specific mobile workload

>> and more generally embedded systems without impacting other platforms.

> 

> I just wanted to observe the lower energy, accepting performance

> degradation. My workloads may have been inappropriate.


Thanks for trying the governor. It is still basic but will be improved
step by step regarding clearly identified workload and with more help
from the scheduler. This is the first phase of the governor providing
the base bricks.

>> +

>> +#define EMA_ALPHA_VAL		64

>> +#define EMA_ALPHA_SHIFT		7

>> +#define MAX_RESCHED_INTERVAL_MS	100

>> +

>> +static DEFINE_PER_CPU(struct mobile_device, mobile_devices);

>> +

>> +static int mobile_ema_new(s64 value, s64 ema_old)

>> +{

>> +	if (likely(ema_old))

>> +		return ema_old + (((value - ema_old) * EMA_ALPHA_VAL) >>

>> +				  EMA_ALPHA_SHIFT);

>> +	return value;

>> +}

> 

> Do you have any information as to why these numbers?

>

> Without any background, the filter seems overly new value weighted to me.

> It is an infinite impulse response type filter, currently at:

> 

> output = 0.5 * old + 0.5 * new.

> 

> I tried, but didn't get anything conclusive:

> 

> output = 0.875 * old + 0.125 * new.

> 

> I did it this way:

> 

> #define EMA_ALPHA_VAL           7

> #define EMA_ALPHA_SHIFT         3

> #define MAX_RESCHED_INTERVAL_MS 100


Ok, I will have a look at these values.

> static DEFINE_PER_CPU(struct mobile_device, mobile_devices);

> 

> static int mobile_ema_new(s64 value, s64 ema_old)

> {

>         if (likely(ema_old))

>                 return ((ema_old * EMA_ALPHA_VAL) + value) >>

>                                   EMA_ALPHA_SHIFT;

>         return value;

> }

> 

> ...

> 

>> +	/*

>> +	 * Sum all the residencies in order to compute the total

>> +	 * duration of the idle task.

>> +	 */

>> +	residency = dev->last_residency - s->exit_latency;

> 

> What about when the CPU comes out of the idle state before it

> even gets fully into it? Under such conditions it seems to hold

> much too hard at idle states that are too deep, to the point

> where energy goes up while performance goes down.


I'm not sure there is something we can do here :/


> Anyway, I did a bunch of tests and such, but have deleted

> most from this e-mail, because it's just noise. I'll

> include just one set:

> 

> For a work load that would normally result in a lot of use

> of shallow idle states (single core pipe-test * 2 cores).


Can you share the tests and the command lines?


> I got (all kernel 5.2-rc5 + this patch):

> 

> Idle governor, teo; CPU frequency scaling: intel-cpufreq/ondemand;

> Processor package power: 40.4 watts; 4.9 uSec/loop

> 

> Idle governor, teo; CPU frequency scaling: intel-cpufreq/ondemand;

> Processor package power: 34 watts; 5.2 uSec/loop

> 

> Idle governor, mobile; CPU frequency scaling: intel-cpufreq/ondemand;

> Processor package power: 25.9 watts; 11.1 uSec/loop

> 

> Idle governor, menu; CPU frequency scaling: intel-cpufreq/ondemand;

> Processor package power: 34.2 watts; 5.23 uSec/loop

> 

> Idle governor, teo; CPU frequency scaling: intel-cpufreq/ondemand;

> Maximum CPU frequency limited to 73% to match mobile energy.

> Processor package power: 25.4 watts; 6.4 uSec/loop


Ok that's interesting. Thanks for the values.

The governor can be better by selecting the shallow states, the
scheduler has to interact with the governor to give clues about the
load, that is identified and will be the next step.

Is it possible to check with the schedutil governor instead?



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On Thursday, June 20, 2019 1:58:08 PM CEST Daniel Lezcano wrote:
> The objective is the same for all the governors: save energy, but at

> the end the governors menu, ladder and teo aim to improve the

> performances with an acceptable energy drop for some workloads which

> are identified for servers and desktops (with the help of a firmware).

> 

> The ladder governor is designed for server with a periodic tick

> configuration.

> 

> The menu governor does not behave nicely with the mobile platform and

> the energy saving for the multimedia workloads is worst than picking

> up randomly an idle state.

> 

> The teo governor acts efficiently, it promotes shallower state for

> performances which is perfect for the servers / desktop but inadequate

> for mobile because the energy consumed is too high.

> 

> It is very difficult to do changes in these governors for embedded

> systems without impacting performances on servers/desktops or ruin the

> optimizations for the workloads on these platforms.

> 

> The mobile governor is a new governor targeting embedded systems

> running on battery where the energy saving has a higher priority than

> servers or desktops. This governor aims to save energy as much as

> possible but with a performance degradation tolerance.

> 

> In this way, we can optimize the governor for specific mobile workload

> and more generally embedded systems without impacting other platforms.

> 

> The mobile governor is built on top of the paradigm 'separate the wake

> up sources signals and analyze them'. Three categories of wake up

> signals are identified:

>  - deterministic : timers

>  - predictable : most of the devices interrupt

>  - unpredictable : IPI rescheduling, random signals

> 

> The latter needs an iterative approach and the help of the scheduler

> to give more input to the governor.

> 

> The governor uses the irq timings where we predict the next interrupt

> occurrences on the current CPU and the next timer. It is well suited

> for mobile and more generally embedded systems where the interrupts

> are usually pinned on one CPU and where the power is more important

> than the performances.

> 

> The multimedia applications on the embedded system spawn multiple

> threads which are migrated across the different CPUs and waking

> between them up. In order to catch this situation we have also to

> track the idle task rescheduling duration with a relative degree of

> confidence as the scheduler is involved in the task migrations. The

> resched information is in the scope of the governor via the reflect

> callback.

> 

> The governor begins with a clean foundation basing the prediction on

> the irq behavior returned by the irq timings, the timers and the idle

> task rescheduling. The advantage of the approach is we have a full

> view of the wakeup sources as we identify them separately and then we

> can control the situation without relying on biased heuristics.

> 

> This first iteration provides a basic prediction but improves on some

> mobile platforms better energy for better performance for multimedia

> workloads.

> 

> The scheduling aspect will be optimized iteratively with non

> regression testing for previous identified workloads on an Android

> reference platform.

> 

> Signed-off-by: Daniel Lezcano <daniel.lezcano@linaro.org>


Note that there are build issues reported by 0-day that need to be fixed.

Also, IMO this really should be documented better in the tree, not just in the changelog.
At least the use case to be covered by this governor should be clearly documented and
it would be good to describe the algorithm.

> ---

>  drivers/cpuidle/Kconfig            |  11 ++-

>  drivers/cpuidle/governors/Makefile |   1 +

>  drivers/cpuidle/governors/mobile.c | 151 +++++++++++++++++++++++++++++

>  3 files changed, 162 insertions(+), 1 deletion(-)

>  create mode 100644 drivers/cpuidle/governors/mobile.c

> 

> diff --git a/drivers/cpuidle/Kconfig b/drivers/cpuidle/Kconfig

> index a4ac31e4a58c..e2376d85e288 100644

> --- a/drivers/cpuidle/Kconfig

> +++ b/drivers/cpuidle/Kconfig

> @@ -5,7 +5,7 @@ config CPU_IDLE

>  	bool "CPU idle PM support"

>  	default y if ACPI || PPC_PSERIES

>  	select CPU_IDLE_GOV_LADDER if (!NO_HZ && !NO_HZ_IDLE)

> -	select CPU_IDLE_GOV_MENU if (NO_HZ || NO_HZ_IDLE) && !CPU_IDLE_GOV_TEO

> +	select CPU_IDLE_GOV_MENU if (NO_HZ || NO_HZ_IDLE) && !CPU_IDLE_GOV_TEO && !CPU_IDLE_GOV_MOBILE

>  	help

>  	  CPU idle is a generic framework for supporting software-controlled

>  	  idle processor power management.  It includes modular cross-platform

> @@ -33,6 +33,15 @@ config CPU_IDLE_GOV_TEO

>  	  Some workloads benefit from using it and it generally should be safe

>  	  to use.  Say Y here if you are not happy with the alternatives.

>  

> +config CPU_IDLE_GOV_MOBILE

> +	bool "Mobile governor"

> +	select IRQ_TIMINGS

> +	help

> +	  The mobile governor is based on irq timings measurements and

> +	  pattern research combined with the next timer. This governor

> +	  suits very well on embedded systems where the interrupts are

> +	  grouped on a single core and the power is the priority.

> +

>  config DT_IDLE_STATES

>  	bool

>  

> diff --git a/drivers/cpuidle/governors/Makefile b/drivers/cpuidle/governors/Makefile

> index 42f44cc610dd..f09da7178670 100644

> --- a/drivers/cpuidle/governors/Makefile

> +++ b/drivers/cpuidle/governors/Makefile

> @@ -6,3 +6,4 @@

>  obj-$(CONFIG_CPU_IDLE_GOV_LADDER) += ladder.o

>  obj-$(CONFIG_CPU_IDLE_GOV_MENU) += menu.o

>  obj-$(CONFIG_CPU_IDLE_GOV_TEO) += teo.o

> +obj-$(CONFIG_CPU_IDLE_GOV_MOBILE) += mobile.o

> diff --git a/drivers/cpuidle/governors/mobile.c b/drivers/cpuidle/governors/mobile.c

> new file mode 100644

> index 000000000000..8fda0f9b960b

> --- /dev/null

> +++ b/drivers/cpuidle/governors/mobile.c

> @@ -0,0 +1,151 @@

> +// SPDX-License-Identifier: GPL-2.0

> +/*

> + * Copyright (C) 2019, Linaro Ltd

> + * Author: Daniel Lezcano <daniel.lezcano@linaro.org>

> + */

> +#include <linux/cpuidle.h>

> +#include <linux/kernel.h>

> +#include <linux/sched.h>

> +#include <linux/slab.h>

> +#include <linux/tick.h>

> +#include <linux/interrupt.h>

> +#include <linux/sched/clock.h>

> +

> +struct mobile_device {

> +	u64 idle_ema_avg;

> +	u64 idle_total;

> +	unsigned long last_jiffies;

> +};

> +

> +#define EMA_ALPHA_VAL		64

> +#define EMA_ALPHA_SHIFT		7

> +#define MAX_RESCHED_INTERVAL_MS	100

> +

> +static DEFINE_PER_CPU(struct mobile_device, mobile_devices);

> +

> +static int mobile_ema_new(s64 value, s64 ema_old)

> +{

> +	if (likely(ema_old))

> +		return ema_old + (((value - ema_old) * EMA_ALPHA_VAL) >>

> +				  EMA_ALPHA_SHIFT);

> +	return value;

> +}

> +

> +static void mobile_reflect(struct cpuidle_device *dev, int index)

> +{

> +        struct mobile_device *mobile_dev = this_cpu_ptr(&mobile_devices);

> +	struct cpuidle_driver *drv = cpuidle_get_cpu_driver(dev);

> +	struct cpuidle_state *s = &drv->states[index];

> +	int residency;

> +

> +	/*

> +	 * The idle task was not rescheduled since

> +	 * MAX_RESCHED_INTERVAL_MS, let's consider the duration is

> +	 * long enough to clear our stats.

> +	 */

> +	if (time_after(jiffies, mobile_dev->last_jiffies +

> +		       msecs_to_jiffies(MAX_RESCHED_INTERVAL_MS)))

> +		mobile_dev->idle_ema_avg = 0;


Why jiffies?  Any particular reason?

> +

> +	/*

> +	 * Sum all the residencies in order to compute the total

> +	 * duration of the idle task.

> +	 */

> +	residency = dev->last_residency - s->exit_latency;

> +	if (residency > 0)

> +		mobile_dev->idle_total += residency;

> +

> +	/*

> +	 * We exited the idle state with the need_resched() flag, the

> +	 * idle task will be rescheduled, so store the duration the

> +	 * idle task was scheduled in an exponential moving average and

> +	 * reset the total of the idle duration.

> +	 */

> +	if (need_resched()) {

> +		mobile_dev->idle_ema_avg = mobile_ema_new(mobile_dev->idle_total,

> +						      mobile_dev->idle_ema_avg);

> +		mobile_dev->idle_total = 0;

> +		mobile_dev->last_jiffies = jiffies;

> +	}

> +}

> +

> +static int mobile_select(struct cpuidle_driver *drv, struct cpuidle_device *dev,

> +		       bool *stop_tick)

> +{

> +	struct mobile_device *mobile_dev = this_cpu_ptr(&mobile_devices);

> +	int latency_req = cpuidle_governor_latency_req(dev->cpu);

> +	int i, index = 0;

> +	ktime_t delta_next;

> +	u64 now, irq_length, timer_length;

> +	u64 idle_duration_us;

> +

> +	/*

> +	 * Get the present time as reference for the next steps

> +	 */

> +	now = local_clock();

> +

> +	/*

> +	 * Get the next interrupt event giving the 'now' as a

> +	 * reference, if the next event appears to have already

> +	 * expired then we get the 'now' returned which ends up with a

> +	 * zero duration.

> +	 */

> +	irq_length = irq_timings_next_event(now) - now;

> +

> +	/*

> +	 * Get the timer duration before expiration.

> +	 */


This comment is rather redundant and the one below too. :-)

> +	timer_length = ktime_to_ns(tick_nohz_get_sleep_length(&delta_next));

> +

> +	/*

> +	 * Get the smallest duration between the timer and the irq next event.

> +	 */

> +	idle_duration_us = min_t(u64, irq_length, timer_length) / NSEC_PER_USEC;

> +

> +	/*

> +	 * Get the idle task duration average if the information is

> +	 * available.


IMO it would be good to explain this step in more detail, especially the purpose of it.

> +	 */

> +	if (mobile_dev->idle_ema_avg)

> +		idle_duration_us = min_t(u64, idle_duration_us,

> +					 mobile_dev->idle_ema_avg);

> +

> +	for (i = 0; i < drv->state_count; i++) {

> +		struct cpuidle_state *s = &drv->states[i];

> +		struct cpuidle_state_usage *su = &dev->states_usage[i];

> +

> +		if (s->disabled || su->disable)

> +			continue;

> +

> +		if (s->exit_latency > latency_req)

> +			break;

> +

> +		if (idle_duration_us > s->exit_latency)

> +			idle_duration_us = idle_duration_us - s->exit_latency;


Why do you want this?

It only causes you to miss an opportunity to select a deeper state sometimes,
so what's the reason?

Moreover, I don't think you should update idle_duration_us here, as the updated
value will go to the next step if the check below doesn't trigger.

> +

> +		if (s->target_residency > idle_duration_us)

> +			break;

> +

> +		index = i;

> +	}

> +

> +	if (!index)

> +		*stop_tick = false;


Well, this means that the tick is stopped for all idle states deeper than state 0.

If there are any states between state 0 and the deepest one and they are below
the tick boundary, you may very well suffer the "powernightmares" problem
because of this.

> +

> +	return index;

> +}

> +

> +static struct cpuidle_governor mobile_governor = {

> +	.name =		"mobile",

> +	.rating =	20,

> +	.select =	mobile_select,

> +	.reflect =	mobile_reflect,

> +};

> +

> +static int __init init_governor(void)

> +{

> +	irq_timings_enable();

> +	return cpuidle_register_governor(&mobile_governor);

> +}

> +

> +postcore_initcall(init_governor);

>

On 2019.07.03 12:12 Doug Smythies wrote:
> On 2019.07.03 08:16 Daniel Lezcano wrote:

>> On 03/07/2019 16:23, Doug Smythies wrote:

>>> On 2019.06.20 04:58 Daniel Lezcano wrote:


> ...

>>> Anyway, I did a bunch of tests and such, but have deleted

>>> most from this e-mail, because it's just noise. I'll

>>> include just one set:

>>> 

>>> For a work load that would normally result in a lot of use

>>> of shallow idle states (single core pipe-test * 2 cores).

>>

>> Can you share the tests and the command lines?

>

> Yes, give me a few days to repeat the tests and write

> it up properly. I am leaving town in an hour and for a day.


O.K. I re-did the tests and made a new web page with, I think,
everything I used.

...

>> The governor can be better by selecting the shallow states, the

>> scheduler has to interact with the governor to give clues about the

>> load, that is identified and will be the next step.

>>

>> Is it possible to check with the schedutil governor instead?

>

> Oh, I already have some data, just didn't include it before:

>

> Idle governor, teo; CPU frequency scaling: intel-cpufreq/schedutil;

> Processor package power: 40.4 watts; 4.9 uSec/loop

>

> Idle governor, mobile; CPU frequency scaling: intel-cpufreq/schedutil;

> Processor package power: 12.7 watts; 19.7 uSec/loop

>

> Idle governor, teo; CPU frequency scaling: intel-cpufreq/schedutil;

> Idle states 0-3 disabled (note: Idle state 4 is the deepest on my system)

> Processor package power: 36.9 watts; 8.3 uSec/loop

> In my notes I wrote: "Huh?? I do not understand this result, as I had

> expected more similar to the mobile governor". But I did not investigate.


The reason for the big difference was/is that with the "mobile"
governor the CPU frequency never scales up for this test. It can be
sluggish to scale up with the teo and the menu governors, but always
eventually does. I also tried the acpi-cpufreq driver with similar results.

> Anyway, the schedutil test is the one I'll repeat and write up better.


New summary (similar to old):

governor 		usec/loop	watts
mobile		19.8		12.67
teo			4.87		40.28
menu			4.85		40.25
teo-idle-0-3-dis	8.30		36.85

Graphs, details and source codes:
http://www.smythies.com/~doug/linux/idle/mobile/index.html

... Doug

Hi Rafael,

On 04/07/2019 12:14, Rafael J. Wysocki wrote:
> On Thursday, June 20, 2019 1:58:08 PM CEST Daniel Lezcano wrote:

>> The objective is the same for all the governors: save energy, but at

>> the end the governors menu, ladder and teo aim to improve the

>> performances with an acceptable energy drop for some workloads which

>> are identified for servers and desktops (with the help of a firmware).

>>

>> The ladder governor is designed for server with a periodic tick

>> configuration.

>>

>> The menu governor does not behave nicely with the mobile platform and

>> the energy saving for the multimedia workloads is worst than picking

>> up randomly an idle state.

>>

>> The teo governor acts efficiently, it promotes shallower state for

>> performances which is perfect for the servers / desktop but inadequate

>> for mobile because the energy consumed is too high.

>>

>> It is very difficult to do changes in these governors for embedded

>> systems without impacting performances on servers/desktops or ruin the

>> optimizations for the workloads on these platforms.

>>

>> The mobile governor is a new governor targeting embedded systems

>> running on battery where the energy saving has a higher priority than

>> servers or desktops. This governor aims to save energy as much as

>> possible but with a performance degradation tolerance.

>>

>> In this way, we can optimize the governor for specific mobile workload

>> and more generally embedded systems without impacting other platforms.

>>

>> The mobile governor is built on top of the paradigm 'separate the wake

>> up sources signals and analyze them'. Three categories of wake up

>> signals are identified:

>>  - deterministic : timers

>>  - predictable : most of the devices interrupt

>>  - unpredictable : IPI rescheduling, random signals

>>

>> The latter needs an iterative approach and the help of the scheduler

>> to give more input to the governor.

>>

>> The governor uses the irq timings where we predict the next interrupt

>> occurrences on the current CPU and the next timer. It is well suited

>> for mobile and more generally embedded systems where the interrupts

>> are usually pinned on one CPU and where the power is more important

>> than the performances.

>>

>> The multimedia applications on the embedded system spawn multiple

>> threads which are migrated across the different CPUs and waking

>> between them up. In order to catch this situation we have also to

>> track the idle task rescheduling duration with a relative degree of

>> confidence as the scheduler is involved in the task migrations. The

>> resched information is in the scope of the governor via the reflect

>> callback.

>>

>> The governor begins with a clean foundation basing the prediction on

>> the irq behavior returned by the irq timings, the timers and the idle

>> task rescheduling. The advantage of the approach is we have a full

>> view of the wakeup sources as we identify them separately and then we

>> can control the situation without relying on biased heuristics.

>>

>> This first iteration provides a basic prediction but improves on some

>> mobile platforms better energy for better performance for multimedia

>> workloads.

>>

>> The scheduling aspect will be optimized iteratively with non

>> regression testing for previous identified workloads on an Android

>> reference platform.

>>

>> Signed-off-by: Daniel Lezcano <daniel.lezcano@linaro.org>

> 

> Note that there are build issues reported by 0-day that need to be fixed.

> Also, IMO this really should be documented better in the tree, not just in the changelog.

> At least the use case to be covered by this governor should be clearly documented and

> it would be good to describe the algorithm.


Ok, I will add some documentation.

>> ---

>>  drivers/cpuidle/Kconfig            |  11 ++-

>>  drivers/cpuidle/governors/Makefile |   1 +

>>  drivers/cpuidle/governors/mobile.c | 151 +++++++++++++++++++++++++++++

>>  3 files changed, 162 insertions(+), 1 deletion(-)

>>  create mode 100644 drivers/cpuidle/governors/mobile.c

>>

>> diff --git a/drivers/cpuidle/Kconfig b/drivers/cpuidle/Kconfig

>> index a4ac31e4a58c..e2376d85e288 100644

>> --- a/drivers/cpuidle/Kconfig

>> +++ b/drivers/cpuidle/Kconfig

>> @@ -5,7 +5,7 @@ config CPU_IDLE

>>  	bool "CPU idle PM support"

>>  	default y if ACPI || PPC_PSERIES

>>  	select CPU_IDLE_GOV_LADDER if (!NO_HZ && !NO_HZ_IDLE)

>> -	select CPU_IDLE_GOV_MENU if (NO_HZ || NO_HZ_IDLE) && !CPU_IDLE_GOV_TEO

>> +	select CPU_IDLE_GOV_MENU if (NO_HZ || NO_HZ_IDLE) && !CPU_IDLE_GOV_TEO && !CPU_IDLE_GOV_MOBILE

>>  	help

>>  	  CPU idle is a generic framework for supporting software-controlled

>>  	  idle processor power management.  It includes modular cross-platform

>> @@ -33,6 +33,15 @@ config CPU_IDLE_GOV_TEO

>>  	  Some workloads benefit from using it and it generally should be safe

>>  	  to use.  Say Y here if you are not happy with the alternatives.

>>  

>> +config CPU_IDLE_GOV_MOBILE

>> +	bool "Mobile governor"

>> +	select IRQ_TIMINGS

>> +	help

>> +	  The mobile governor is based on irq timings measurements and

>> +	  pattern research combined with the next timer. This governor

>> +	  suits very well on embedded systems where the interrupts are

>> +	  grouped on a single core and the power is the priority.

>> +

>>  config DT_IDLE_STATES

>>  	bool

>>  

>> diff --git a/drivers/cpuidle/governors/Makefile b/drivers/cpuidle/governors/Makefile

>> index 42f44cc610dd..f09da7178670 100644

>> --- a/drivers/cpuidle/governors/Makefile

>> +++ b/drivers/cpuidle/governors/Makefile

>> @@ -6,3 +6,4 @@

>>  obj-$(CONFIG_CPU_IDLE_GOV_LADDER) += ladder.o

>>  obj-$(CONFIG_CPU_IDLE_GOV_MENU) += menu.o

>>  obj-$(CONFIG_CPU_IDLE_GOV_TEO) += teo.o

>> +obj-$(CONFIG_CPU_IDLE_GOV_MOBILE) += mobile.o

>> diff --git a/drivers/cpuidle/governors/mobile.c b/drivers/cpuidle/governors/mobile.c

>> new file mode 100644

>> index 000000000000..8fda0f9b960b

>> --- /dev/null

>> +++ b/drivers/cpuidle/governors/mobile.c

>> @@ -0,0 +1,151 @@

>> +// SPDX-License-Identifier: GPL-2.0

>> +/*

>> + * Copyright (C) 2019, Linaro Ltd

>> + * Author: Daniel Lezcano <daniel.lezcano@linaro.org>

>> + */

>> +#include <linux/cpuidle.h>

>> +#include <linux/kernel.h>

>> +#include <linux/sched.h>

>> +#include <linux/slab.h>

>> +#include <linux/tick.h>

>> +#include <linux/interrupt.h>

>> +#include <linux/sched/clock.h>

>> +

>> +struct mobile_device {

>> +	u64 idle_ema_avg;

>> +	u64 idle_total;

>> +	unsigned long last_jiffies;

>> +};

>> +

>> +#define EMA_ALPHA_VAL		64

>> +#define EMA_ALPHA_SHIFT		7

>> +#define MAX_RESCHED_INTERVAL_MS	100

>> +

>> +static DEFINE_PER_CPU(struct mobile_device, mobile_devices);

>> +

>> +static int mobile_ema_new(s64 value, s64 ema_old)

>> +{

>> +	if (likely(ema_old))

>> +		return ema_old + (((value - ema_old) * EMA_ALPHA_VAL) >>

>> +				  EMA_ALPHA_SHIFT);

>> +	return value;

>> +}

>> +

>> +static void mobile_reflect(struct cpuidle_device *dev, int index)

>> +{

>> +        struct mobile_device *mobile_dev = this_cpu_ptr(&mobile_devices);

>> +	struct cpuidle_driver *drv = cpuidle_get_cpu_driver(dev);

>> +	struct cpuidle_state *s = &drv->states[index];

>> +	int residency;

>> +

>> +	/*

>> +	 * The idle task was not rescheduled since

>> +	 * MAX_RESCHED_INTERVAL_MS, let's consider the duration is

>> +	 * long enough to clear our stats.

>> +	 */

>> +	if (time_after(jiffies, mobile_dev->last_jiffies +

>> +		       msecs_to_jiffies(MAX_RESCHED_INTERVAL_MS)))

>> +		mobile_dev->idle_ema_avg = 0;

> 

> Why jiffies?  Any particular reason?


I used jiffies to not use the local_clock() call for the overhead. I
agree the resolution could be too low. Perhaps it makes more sense to
move idle start and idle end variable from the cpuidle_enter function to
the cpuidle device structure, so the information can be reused by the
subsequent users.

>> +

>> +	/*

>> +	 * Sum all the residencies in order to compute the total

>> +	 * duration of the idle task.

>> +	 */

>> +	residency = dev->last_residency - s->exit_latency;

>> +	if (residency > 0)

>> +		mobile_dev->idle_total += residency;

>> +

>> +	/*

>> +	 * We exited the idle state with the need_resched() flag, the

>> +	 * idle task will be rescheduled, so store the duration the

>> +	 * idle task was scheduled in an exponential moving average and

>> +	 * reset the total of the idle duration.

>> +	 */

>> +	if (need_resched()) {

>> +		mobile_dev->idle_ema_avg = mobile_ema_new(mobile_dev->idle_total,

>> +						      mobile_dev->idle_ema_avg);

>> +		mobile_dev->idle_total = 0;

>> +		mobile_dev->last_jiffies = jiffies;

>> +	}

>> +}

>> +

>> +static int mobile_select(struct cpuidle_driver *drv, struct cpuidle_device *dev,

>> +		       bool *stop_tick)

>> +{

>> +	struct mobile_device *mobile_dev = this_cpu_ptr(&mobile_devices);

>> +	int latency_req = cpuidle_governor_latency_req(dev->cpu);

>> +	int i, index = 0;

>> +	ktime_t delta_next;

>> +	u64 now, irq_length, timer_length;

>> +	u64 idle_duration_us;

>> +

>> +	/*

>> +	 * Get the present time as reference for the next steps

>> +	 */

>> +	now = local_clock();

>> +

>> +	/*

>> +	 * Get the next interrupt event giving the 'now' as a

>> +	 * reference, if the next event appears to have already

>> +	 * expired then we get the 'now' returned which ends up with a

>> +	 * zero duration.

>> +	 */

>> +	irq_length = irq_timings_next_event(now) - now;

>> +

>> +	/*

>> +	 * Get the timer duration before expiration.

>> +	 */

> 

> This comment is rather redundant and the one below too. :-)


Right.

>> +	timer_length = ktime_to_ns(tick_nohz_get_sleep_length(&delta_next));

>> +

>> +	/*

>> +	 * Get the smallest duration between the timer and the irq next event.

>> +	 */

>> +	idle_duration_us = min_t(u64, irq_length, timer_length) / NSEC_PER_USEC;

>> +

>> +	/*

>> +	 * Get the idle task duration average if the information is

>> +	 * available.

> 

> IMO it would be good to explain this step in more detail, especially the purpose of it.


Ok.

>> +	 */

>> +	if (mobile_dev->idle_ema_avg)

>> +		idle_duration_us = min_t(u64, idle_duration_us,

>> +					 mobile_dev->idle_ema_avg);

>> +

>> +	for (i = 0; i < drv->state_count; i++) {

>> +		struct cpuidle_state *s = &drv->states[i];

>> +		struct cpuidle_state_usage *su = &dev->states_usage[i];

>> +

>> +		if (s->disabled || su->disable)

>> +			continue;

>> +

>> +		if (s->exit_latency > latency_req)

>> +			break;

>> +

>> +		if (idle_duration_us > s->exit_latency)

>> +			idle_duration_us = idle_duration_us - s->exit_latency;

> 

> Why do you want this?

> 

> It only causes you to miss an opportunity to select a deeper state sometimes,

> so what's the reason?


On the mobile platform the exit latencies are very high (with an order
of magnitude of several milliseconds) for a very limited number of idle
states. The real idle duration must be determined to compare to the
target residency. Without this test, the governor is constantly choosing
wrongly a deep idle state.

> Moreover, I don't think you should update idle_duration_us here, as the updated

> value will go to the next step if the check below doesn't trigger.


Right, I spotted it also and fixed with:

+               if (s->exit_latency >= idle_duration_us)
+                       break;

+               if (s->target_residency > (idle_duration_us -
s->exit_latency))
                        break;

>> +

>> +		if (s->target_residency > idle_duration_us)

>> +			break;

>> +

>> +		index = i;

>> +	}

>> +

>> +	if (!index)

>> +		*stop_tick = false;

> 

> Well, this means that the tick is stopped for all idle states deeper than state 0.

> 

> If there are any states between state 0 and the deepest one and they are below

> the tick boundary, you may very well suffer the "powernightmares" problem

> because of this.


What would you suggest?

if (!index || ((idle_duration_us < TICK_USEC) &&
		!tick_nohz_tick_stopped()))
	*stop_tick = false;

?

There are too few idle states to restart a selection at this point, so
preventing stopping the tick is enough at this point IMO.


>> +	return index;

>> +}

>> +

>> +static struct cpuidle_governor mobile_governor = {

>> +	.name =		"mobile",

>> +	.rating =	20,

>> +	.select =	mobile_select,

>> +	.reflect =	mobile_reflect,

>> +};

>> +

>> +static int __init init_governor(void)

>> +{

>> +	irq_timings_enable();

>> +	return cpuidle_register_governor(&mobile_governor);

>> +}

>> +

>> +postcore_initcall(init_governor);

>>

> 

> 

> 

> 



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