There is a particular situation when the cooling device is cpufreq and the heat
dissipation is not efficient enough where the temperature increases little by
little until reaching the critical threshold and leading to a SoC reset.
The behavior is reproducible on a hikey6220 with bad heat dissipation (eg.
stacked with other boards).
Running a simple C program doing while(1); for each CPU of the SoC makes the
temperature to reach the passive regulation trip point and ends up to the
maximum allowed temperature followed by a reset.
What is observed is a ping pong between two cpu frequencies, 1.2GHz and 900MHz
while the temperature continues to grow.
It appears the step wise governor calls get_target_state() the first time with
the throttle set to true and the trend to 'raising'. The code selects logically
the next state, so the cpu frequency decreases from 1.2GHz to 900MHz, so far so
good. The temperature decreases immediately but still stays greater than the
trip point, then get_target_state() is called again, this time with the
throttle set to true *and* the trend to 'dropping'. From there the algorithm
assumes we have to step down the state and the cpu frequency jumps back to
1.2GHz. But the temperature is still higher than the trip point, so
get_target_state() is called with throttle=1 and trend='raising' again, we jump
to 900MHz, then get_target_state() is called with throttle=1 and
trend='dropping', we jump to 1.2GHz, etc ... but the temperature does not
stabilizes and continues to increase.
Keeping the next_target untouched when 'throttle' is true at 'dropping' time
fixes the issue.
Signed-off-by: Daniel Lezcano <[email protected]>
---
drivers/thermal/step_wise.c | 8 +++++---
1 file changed, 5 insertions(+), 3 deletions(-)
diff --git a/drivers/thermal/step_wise.c b/drivers/thermal/step_wise.c
index be95826..a01259a 100644
--- a/drivers/thermal/step_wise.c
+++ b/drivers/thermal/step_wise.c
@@ -94,9 +94,11 @@ static unsigned long get_target_state(struct thermal_instance *instance,
if (!throttle)
next_target = THERMAL_NO_TARGET;
} else {
- next_target = cur_state - 1;
- if (next_target > instance->upper)
- next_target = instance->upper;
+ if (!throttle) {
+ next_target = cur_state - 1;
+ if (next_target > instance->upper)
+ next_target = instance->upper;
+ }
}
break;
case THERMAL_TREND_DROP_FULL:
--
2.7.4
On Wed, Sep 06, 2017 at 08:58:46AM +0200, Daniel Lezcano wrote:
> There is a particular situation when the cooling device is cpufreq and the heat
> dissipation is not efficient enough where the temperature increases little by
> little until reaching the critical threshold and leading to a SoC reset.
>
> The behavior is reproducible on a hikey6220 with bad heat dissipation (eg.
> stacked with other boards).
>
> Running a simple C program doing while(1); for each CPU of the SoC makes the
> temperature to reach the passive regulation trip point and ends up to the
> maximum allowed temperature followed by a reset.
>
> What is observed is a ping pong between two cpu frequencies, 1.2GHz and 900MHz
> while the temperature continues to grow.
>
> It appears the step wise governor calls get_target_state() the first time with
> the throttle set to true and the trend to 'raising'. The code selects logically
> the next state, so the cpu frequency decreases from 1.2GHz to 900MHz, so far so
> good. The temperature decreases immediately but still stays greater than the
> trip point, then get_target_state() is called again, this time with the
> throttle set to true *and* the trend to 'dropping'. From there the algorithm
> assumes we have to step down the state and the cpu frequency jumps back to
> 1.2GHz. But the temperature is still higher than the trip point, so
> get_target_state() is called with throttle=1 and trend='raising' again, we jump
> to 900MHz, then get_target_state() is called with throttle=1 and
> trend='dropping', we jump to 1.2GHz, etc ... but the temperature does not
> stabilizes and continues to increase.
>
> Keeping the next_target untouched when 'throttle' is true at 'dropping' time
> fixes the issue.
Can you maybe elaborate a bit more on "fixes the issue"? May be worth
adding to the commit message a log of thermal trace events showing which
cooling states the step wise governor chooses before and after your
change.
>
> Signed-off-by: Daniel Lezcano <[email protected]>
> ---
> drivers/thermal/step_wise.c | 8 +++++---
> 1 file changed, 5 insertions(+), 3 deletions(-)
>
> diff --git a/drivers/thermal/step_wise.c b/drivers/thermal/step_wise.c
> index be95826..a01259a 100644
> --- a/drivers/thermal/step_wise.c
> +++ b/drivers/thermal/step_wise.c
> @@ -94,9 +94,11 @@ static unsigned long get_target_state(struct thermal_instance *instance,
> if (!throttle)
> next_target = THERMAL_NO_TARGET;
> } else {
> - next_target = cur_state - 1;
> - if (next_target > instance->upper)
> - next_target = instance->upper;
> + if (!throttle) {
> + next_target = cur_state - 1;
> + if (next_target > instance->upper)
> + next_target = instance->upper;
> + }
> }
> break;
> case THERMAL_TREND_DROP_FULL:
> --
> 2.7.4
>
There is a particular situation when the cooling device is cpufreq and the heat
dissipation is not efficient enough where the temperature increases little by
little until reaching the critical threshold and leading to a SoC reset.
The behavior is reproducible on a hikey6220 with bad heat dissipation (eg.
stacked with other boards).
Running a simple C program doing while(1); for each CPU of the SoC makes the
temperature to reach the passive regulation trip point and ends up to the
maximum allowed temperature followed by a reset.
This issue has been also reported by running the libhugetlbfs test suite.
What is observed is a ping pong between two cpu frequencies, 1.2GHz and 900MHz
while the temperature continues to grow.
It appears the step wise governor calls get_target_state() the first time with
the throttle set to true and the trend to 'raising'. The code selects logically
the next state, so the cpu frequency decreases from 1.2GHz to 900MHz, so far so
good. The temperature decreases immediately but still stays greater than the
trip point, then get_target_state() is called again, this time with the
throttle set to true *and* the trend to 'dropping'. From there the algorithm
assumes we have to step down the state and the cpu frequency jumps back to
1.2GHz. But the temperature is still higher than the trip point, so
get_target_state() is called with throttle=1 and trend='raising' again, we jump
to 900MHz, then get_target_state() is called with throttle=1 and
trend='dropping', we jump to 1.2GHz, etc ... but the temperature does not
stabilizes and continues to increase.
[ 237.922654] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
[ 237.922678] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=1
[ 237.922690] thermal cooling_device0: cur_state=0
[ 237.922701] thermal cooling_device0: old_target=0, target=1
[ 238.026656] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=2,throttle=1
[ 238.026680] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=2,throttle=1
[ 238.026694] thermal cooling_device0: cur_state=1
[ 238.026707] thermal cooling_device0: old_target=1, target=0
[ 238.134647] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
[ 238.134667] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=1
[ 238.134679] thermal cooling_device0: cur_state=0
[ 238.134690] thermal cooling_device0: old_target=0, target=1
In this situation the temperature continues to increase while the trend is
oscillating between 'dropping' and 'raising'. We need to keep the current state
untouched if the throttle is set, so the temperature can decrease or a higher
state could be selected, thus prevening this oscillation.
Keeping the next_target untouched when 'throttle' is true at 'dropping' time
fixes the issue.
The following traces show the governor does not change the next state if
trend==2 (dropping) and throttle==1.
[ 2306.127987] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
[ 2306.128009] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=1
[ 2306.128021] thermal cooling_device0: cur_state=0
[ 2306.128031] thermal cooling_device0: old_target=0, target=1
[ 2306.231991] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=2,throttle=1
[ 2306.232016] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=2,throttle=1
[ 2306.232030] thermal cooling_device0: cur_state=1
[ 2306.232042] thermal cooling_device0: old_target=1, target=1
[ 2306.335982] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=0,throttle=1
[ 2306.336006] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=0,throttle=1
[ 2306.336021] thermal cooling_device0: cur_state=1
[ 2306.336034] thermal cooling_device0: old_target=1, target=1
[ 2306.439984] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=2,throttle=1
[ 2306.440008] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=2,throttle=0
[ 2306.440022] thermal cooling_device0: cur_state=1
[ 2306.440034] thermal cooling_device0: old_target=1, target=0
[ ... ]
After a while, if the temperature continues to increase, the next state becomes
2 which is 720MHz on the hikey. That results in the temperature stabilizing
around the trip point.
[ 2455.831982] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
[ 2455.832006] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=0
[ 2455.832019] thermal cooling_device0: cur_state=1
[ 2455.832032] thermal cooling_device0: old_target=1, target=1
[ 2455.935985] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=0,throttle=1
[ 2455.936013] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=0,throttle=0
[ 2455.936027] thermal cooling_device0: cur_state=1
[ 2455.936040] thermal cooling_device0: old_target=1, target=1
[ 2456.043984] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=0,throttle=1
[ 2456.044009] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=0,throttle=0
[ 2456.044023] thermal cooling_device0: cur_state=1
[ 2456.044036] thermal cooling_device0: old_target=1, target=1
[ 2456.148001] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
[ 2456.148028] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=1
[ 2456.148042] thermal cooling_device0: cur_state=1
[ 2456.148055] thermal cooling_device0: old_target=1, target=2
[ 2456.252009] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=2,throttle=1
[ 2456.252041] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=2,throttle=0
[ 2456.252058] thermal cooling_device0: cur_state=2
[ 2456.252075] thermal cooling_device0: old_target=2, target=1
IOW, this change is needed to keep the state for a cooling device if the
temperature trend is oscillating while the temperature increases slightly.
Without this change, the situation above leads to a catastrophic crash by a
hardware reset on hikey.
Signed-off-by: Daniel Lezcano <[email protected]>
---
drivers/thermal/step_wise.c | 8 +++++---
1 file changed, 5 insertions(+), 3 deletions(-)
diff --git a/drivers/thermal/step_wise.c b/drivers/thermal/step_wise.c
index bd2f133..703bd0d 100644
--- a/drivers/thermal/step_wise.c
+++ b/drivers/thermal/step_wise.c
@@ -95,9 +95,11 @@ static unsigned long get_target_state(struct thermal_instance *instance,
if (!throttle)
next_target = THERMAL_NO_TARGET;
} else {
- next_target = cur_state - 1;
- if (next_target > instance->upper)
- next_target = instance->upper;
+ if (!throttle) {
+ next_target = cur_state - 1;
+ if (next_target > instance->upper)
+ next_target = instance->upper;
+ }
}
break;
case THERMAL_TREND_DROP_FULL:
--
2.7.4
On Friday 08 September 2017 02:35 PM, Daniel Lezcano wrote:
> There is a particular situation when the cooling device is cpufreq and the heat
> dissipation is not efficient enough where the temperature increases little by
> little until reaching the critical threshold and leading to a SoC reset.
>
> The behavior is reproducible on a hikey6220 with bad heat dissipation (eg.
> stacked with other boards).
>
> Running a simple C program doing while(1); for each CPU of the SoC makes the
> temperature to reach the passive regulation trip point and ends up to the
> maximum allowed temperature followed by a reset.
>
> This issue has been also reported by running the libhugetlbfs test suite.
>
> What is observed is a ping pong between two cpu frequencies, 1.2GHz and 900MHz
> while the temperature continues to grow.
>
> It appears the step wise governor calls get_target_state() the first time with
> the throttle set to true and the trend to 'raising'. The code selects logically
> the next state, so the cpu frequency decreases from 1.2GHz to 900MHz, so far so
> good. The temperature decreases immediately but still stays greater than the
> trip point, then get_target_state() is called again, this time with the
> throttle set to true *and* the trend to 'dropping'. From there the algorithm
> assumes we have to step down the state and the cpu frequency jumps back to
> 1.2GHz. But the temperature is still higher than the trip point, so
> get_target_state() is called with throttle=1 and trend='raising' again, we jump
> to 900MHz, then get_target_state() is called with throttle=1 and
> trend='dropping', we jump to 1.2GHz, etc ... but the temperature does not
> stabilizes and continues to increase.
>
> [ 237.922654] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
> [ 237.922678] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=1
> [ 237.922690] thermal cooling_device0: cur_state=0
> [ 237.922701] thermal cooling_device0: old_target=0, target=1
> [ 238.026656] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=2,throttle=1
> [ 238.026680] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=2,throttle=1
> [ 238.026694] thermal cooling_device0: cur_state=1
> [ 238.026707] thermal cooling_device0: old_target=1, target=0
> [ 238.134647] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
> [ 238.134667] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=1
> [ 238.134679] thermal cooling_device0: cur_state=0
> [ 238.134690] thermal cooling_device0: old_target=0, target=1
>
> In this situation the temperature continues to increase while the trend is
> oscillating between 'dropping' and 'raising'. We need to keep the current state
> untouched if the throttle is set, so the temperature can decrease or a higher
> state could be selected, thus prevening this oscillation.
>
> Keeping the next_target untouched when 'throttle' is true at 'dropping' time
> fixes the issue.
>
> The following traces show the governor does not change the next state if
> trend==2 (dropping) and throttle==1.
>
> [ 2306.127987] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
> [ 2306.128009] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=1
> [ 2306.128021] thermal cooling_device0: cur_state=0
> [ 2306.128031] thermal cooling_device0: old_target=0, target=1
> [ 2306.231991] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=2,throttle=1
> [ 2306.232016] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=2,throttle=1
> [ 2306.232030] thermal cooling_device0: cur_state=1
> [ 2306.232042] thermal cooling_device0: old_target=1, target=1
> [ 2306.335982] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=0,throttle=1
> [ 2306.336006] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=0,throttle=1
> [ 2306.336021] thermal cooling_device0: cur_state=1
> [ 2306.336034] thermal cooling_device0: old_target=1, target=1
> [ 2306.439984] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=2,throttle=1
> [ 2306.440008] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=2,throttle=0
> [ 2306.440022] thermal cooling_device0: cur_state=1
> [ 2306.440034] thermal cooling_device0: old_target=1, target=0
>
> [ ... ]
>
> After a while, if the temperature continues to increase, the next state becomes
> 2 which is 720MHz on the hikey. That results in the temperature stabilizing
> around the trip point.
>
> [ 2455.831982] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
> [ 2455.832006] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=0
> [ 2455.832019] thermal cooling_device0: cur_state=1
> [ 2455.832032] thermal cooling_device0: old_target=1, target=1
> [ 2455.935985] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=0,throttle=1
> [ 2455.936013] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=0,throttle=0
> [ 2455.936027] thermal cooling_device0: cur_state=1
> [ 2455.936040] thermal cooling_device0: old_target=1, target=1
> [ 2456.043984] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=0,throttle=1
> [ 2456.044009] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=0,throttle=0
> [ 2456.044023] thermal cooling_device0: cur_state=1
> [ 2456.044036] thermal cooling_device0: old_target=1, target=1
> [ 2456.148001] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
> [ 2456.148028] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=1
> [ 2456.148042] thermal cooling_device0: cur_state=1
> [ 2456.148055] thermal cooling_device0: old_target=1, target=2
> [ 2456.252009] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=2,throttle=1
> [ 2456.252041] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=2,throttle=0
> [ 2456.252058] thermal cooling_device0: cur_state=2
> [ 2456.252075] thermal cooling_device0: old_target=2, target=1
>
> IOW, this change is needed to keep the state for a cooling device if the
> temperature trend is oscillating while the temperature increases slightly.
>
> Without this change, the situation above leads to a catastrophic crash by a
> hardware reset on hikey.
Daniel,
By design this governor is throttling and un-throttling based on the
computed trend.
Why not add an intermediate trip point with the highest cooling enabled.
Say High alert trip point that allows only the lowest OPP for cpufreq to
operate.
For example: alert trip is at 100C (where cpufreq cooling kicks in)
critical trip is at 125C(shutdown temperature).
We have Something like below @110C which allows only the lowest
frequency or lowest 2 frequencies based on experimentation:
+&cpu_trips {
+ cpu_high_alert: cpu_high_alert {
+ temperature = <110000>; /* millicelsius */
+ hysteresis = <2000>; /* millicelsius */
+ type = "passive";
+ };
+};
+
+&cpu_cooling_maps {
+ map1: map1 {
+ trip = <&cpu_high_alert>;
+ cooling-device =
+ <&cpu0 2 THERMAL_NO_LIMIT>;
+ };
+};
+
I have seen this problem myself on dra7 platforms. The above will cool
the device post 110C by keeping the cpu frequency at the lowest or lower
values. That way when you are in between 100 - 110C you can still get
highest performance depending on the trend computed and post 110C.
My 2 cents on this.
Regards,
Keerthy
>
> Signed-off-by: Daniel Lezcano <[email protected]>
> ---
> drivers/thermal/step_wise.c | 8 +++++---
> 1 file changed, 5 insertions(+), 3 deletions(-)
>
> diff --git a/drivers/thermal/step_wise.c b/drivers/thermal/step_wise.c
> index bd2f133..703bd0d 100644
> --- a/drivers/thermal/step_wise.c
> +++ b/drivers/thermal/step_wise.c
> @@ -95,9 +95,11 @@ static unsigned long get_target_state(struct thermal_instance *instance,
> if (!throttle)
> next_target = THERMAL_NO_TARGET;
> } else {
> - next_target = cur_state - 1;
> - if (next_target > instance->upper)
> - next_target = instance->upper;
> + if (!throttle) {
> + next_target = cur_state - 1;
> + if (next_target > instance->upper)
> + next_target = instance->upper;
> + }
> }
> break;
> case THERMAL_TREND_DROP_FULL:
>
On Friday 08 September 2017 03:19 PM, Keerthy wrote:
>
>
> On Friday 08 September 2017 02:35 PM, Daniel Lezcano wrote:
>> There is a particular situation when the cooling device is cpufreq and the heat
>> dissipation is not efficient enough where the temperature increases little by
>> little until reaching the critical threshold and leading to a SoC reset.
>>
>> The behavior is reproducible on a hikey6220 with bad heat dissipation (eg.
>> stacked with other boards).
>>
>> Running a simple C program doing while(1); for each CPU of the SoC makes the
>> temperature to reach the passive regulation trip point and ends up to the
>> maximum allowed temperature followed by a reset.
>>
>> This issue has been also reported by running the libhugetlbfs test suite.
>>
>> What is observed is a ping pong between two cpu frequencies, 1.2GHz and 900MHz
>> while the temperature continues to grow.
>>
>> It appears the step wise governor calls get_target_state() the first time with
>> the throttle set to true and the trend to 'raising'. The code selects logically
>> the next state, so the cpu frequency decreases from 1.2GHz to 900MHz, so far so
>> good. The temperature decreases immediately but still stays greater than the
>> trip point, then get_target_state() is called again, this time with the
>> throttle set to true *and* the trend to 'dropping'. From there the algorithm
>> assumes we have to step down the state and the cpu frequency jumps back to
>> 1.2GHz. But the temperature is still higher than the trip point, so
>> get_target_state() is called with throttle=1 and trend='raising' again, we jump
>> to 900MHz, then get_target_state() is called with throttle=1 and
>> trend='dropping', we jump to 1.2GHz, etc ... but the temperature does not
>> stabilizes and continues to increase.
>>
>> [ 237.922654] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
>> [ 237.922678] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=1
>> [ 237.922690] thermal cooling_device0: cur_state=0
>> [ 237.922701] thermal cooling_device0: old_target=0, target=1
>> [ 238.026656] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=2,throttle=1
>> [ 238.026680] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=2,throttle=1
>> [ 238.026694] thermal cooling_device0: cur_state=1
>> [ 238.026707] thermal cooling_device0: old_target=1, target=0
>> [ 238.134647] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
>> [ 238.134667] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=1
>> [ 238.134679] thermal cooling_device0: cur_state=0
>> [ 238.134690] thermal cooling_device0: old_target=0, target=1
>>
>> In this situation the temperature continues to increase while the trend is
>> oscillating between 'dropping' and 'raising'. We need to keep the current state
>> untouched if the throttle is set, so the temperature can decrease or a higher
>> state could be selected, thus prevening this oscillation.
>>
>> Keeping the next_target untouched when 'throttle' is true at 'dropping' time
>> fixes the issue.
>>
>> The following traces show the governor does not change the next state if
>> trend==2 (dropping) and throttle==1.
>>
>> [ 2306.127987] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
>> [ 2306.128009] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=1
>> [ 2306.128021] thermal cooling_device0: cur_state=0
>> [ 2306.128031] thermal cooling_device0: old_target=0, target=1
>> [ 2306.231991] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=2,throttle=1
>> [ 2306.232016] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=2,throttle=1
>> [ 2306.232030] thermal cooling_device0: cur_state=1
>> [ 2306.232042] thermal cooling_device0: old_target=1, target=1
>> [ 2306.335982] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=0,throttle=1
>> [ 2306.336006] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=0,throttle=1
>> [ 2306.336021] thermal cooling_device0: cur_state=1
>> [ 2306.336034] thermal cooling_device0: old_target=1, target=1
>> [ 2306.439984] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=2,throttle=1
>> [ 2306.440008] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=2,throttle=0
>> [ 2306.440022] thermal cooling_device0: cur_state=1
>> [ 2306.440034] thermal cooling_device0: old_target=1, target=0
>>
>> [ ... ]
>>
>> After a while, if the temperature continues to increase, the next state becomes
>> 2 which is 720MHz on the hikey. That results in the temperature stabilizing
>> around the trip point.
>>
>> [ 2455.831982] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
>> [ 2455.832006] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=0
>> [ 2455.832019] thermal cooling_device0: cur_state=1
>> [ 2455.832032] thermal cooling_device0: old_target=1, target=1
>> [ 2455.935985] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=0,throttle=1
>> [ 2455.936013] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=0,throttle=0
>> [ 2455.936027] thermal cooling_device0: cur_state=1
>> [ 2455.936040] thermal cooling_device0: old_target=1, target=1
>> [ 2456.043984] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=0,throttle=1
>> [ 2456.044009] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=0,throttle=0
>> [ 2456.044023] thermal cooling_device0: cur_state=1
>> [ 2456.044036] thermal cooling_device0: old_target=1, target=1
>> [ 2456.148001] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
>> [ 2456.148028] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=1
>> [ 2456.148042] thermal cooling_device0: cur_state=1
>> [ 2456.148055] thermal cooling_device0: old_target=1, target=2
>> [ 2456.252009] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=2,throttle=1
>> [ 2456.252041] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=2,throttle=0
>> [ 2456.252058] thermal cooling_device0: cur_state=2
>> [ 2456.252075] thermal cooling_device0: old_target=2, target=1
>>
>> IOW, this change is needed to keep the state for a cooling device if the
>> temperature trend is oscillating while the temperature increases slightly.
>>
>> Without this change, the situation above leads to a catastrophic crash by a
>> hardware reset on hikey.
>
> Daniel,
>
> By design this governor is throttling and un-throttling based on the
> computed trend.
>
> Why not add an intermediate trip point with the highest cooling enabled.
> Say High alert trip point that allows only the lowest OPP for cpufreq to
> operate.
>
> For example: alert trip is at 100C (where cpufreq cooling kicks in)
> critical trip is at 125C(shutdown temperature).
>
> We have Something like below @110C which allows only the lowest
> frequency or lowest 2 frequencies based on experimentation:
>
> +&cpu_trips {
> + cpu_high_alert: cpu_high_alert {
> + temperature = <110000>; /* millicelsius */
> + hysteresis = <2000>; /* millicelsius */
> + type = "passive";
> + };
> +};
> +
> +&cpu_cooling_maps {
> + map1: map1 {
> + trip = <&cpu_high_alert>;
> + cooling-device =
> + <&cpu0 2 THERMAL_NO_LIMIT>;
> + };
> +};
> +
>
> I have seen this problem myself on dra7 platforms. The above will cool
> the device post 110C by keeping the cpu frequency at the lowest or lower
> values. That way when you are in between 100 - 110C you can still get
> highest performance depending on the trend computed and post 110C.
Post 110C cooling is guaranteed by not allowing the cpu frequency
hitting the higher values.
>
> My 2 cents on this.
>
> Regards,
> Keerthy
>>
>> Signed-off-by: Daniel Lezcano <[email protected]>
>> ---
>> drivers/thermal/step_wise.c | 8 +++++---
>> 1 file changed, 5 insertions(+), 3 deletions(-)
>>
>> diff --git a/drivers/thermal/step_wise.c b/drivers/thermal/step_wise.c
>> index bd2f133..703bd0d 100644
>> --- a/drivers/thermal/step_wise.c
>> +++ b/drivers/thermal/step_wise.c
>> @@ -95,9 +95,11 @@ static unsigned long get_target_state(struct thermal_instance *instance,
>> if (!throttle)
>> next_target = THERMAL_NO_TARGET;
>> } else {
>> - next_target = cur_state - 1;
>> - if (next_target > instance->upper)
>> - next_target = instance->upper;
>> + if (!throttle) {
>> + next_target = cur_state - 1;
>> + if (next_target > instance->upper)
>> + next_target = instance->upper;
>> + }
>> }
>> break;
>> case THERMAL_TREND_DROP_FULL:
>>
On 08/09/2017 11:49, Keerthy wrote:
>
>
> On Friday 08 September 2017 02:35 PM, Daniel Lezcano wrote:
>> There is a particular situation when the cooling device is cpufreq and the heat
>> dissipation is not efficient enough where the temperature increases little by
>> little until reaching the critical threshold and leading to a SoC reset.
>>
>> The behavior is reproducible on a hikey6220 with bad heat dissipation (eg.
>> stacked with other boards).
>>
>> Running a simple C program doing while(1); for each CPU of the SoC makes the
>> temperature to reach the passive regulation trip point and ends up to the
>> maximum allowed temperature followed by a reset.
>>
>> This issue has been also reported by running the libhugetlbfs test suite.
>>
>> What is observed is a ping pong between two cpu frequencies, 1.2GHz and 900MHz
>> while the temperature continues to grow.
>>
>> It appears the step wise governor calls get_target_state() the first time with
>> the throttle set to true and the trend to 'raising'. The code selects logically
>> the next state, so the cpu frequency decreases from 1.2GHz to 900MHz, so far so
>> good. The temperature decreases immediately but still stays greater than the
>> trip point, then get_target_state() is called again, this time with the
>> throttle set to true *and* the trend to 'dropping'. From there the algorithm
>> assumes we have to step down the state and the cpu frequency jumps back to
>> 1.2GHz. But the temperature is still higher than the trip point, so
>> get_target_state() is called with throttle=1 and trend='raising' again, we jump
>> to 900MHz, then get_target_state() is called with throttle=1 and
>> trend='dropping', we jump to 1.2GHz, etc ... but the temperature does not
>> stabilizes and continues to increase.
>>
>> [ 237.922654] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
>> [ 237.922678] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=1
>> [ 237.922690] thermal cooling_device0: cur_state=0
>> [ 237.922701] thermal cooling_device0: old_target=0, target=1
>> [ 238.026656] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=2,throttle=1
>> [ 238.026680] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=2,throttle=1
>> [ 238.026694] thermal cooling_device0: cur_state=1
>> [ 238.026707] thermal cooling_device0: old_target=1, target=0
>> [ 238.134647] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
>> [ 238.134667] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=1
>> [ 238.134679] thermal cooling_device0: cur_state=0
>> [ 238.134690] thermal cooling_device0: old_target=0, target=1
>>
>> In this situation the temperature continues to increase while the trend is
>> oscillating between 'dropping' and 'raising'. We need to keep the current state
>> untouched if the throttle is set, so the temperature can decrease or a higher
>> state could be selected, thus prevening this oscillation.
>>
>> Keeping the next_target untouched when 'throttle' is true at 'dropping' time
>> fixes the issue.
>>
>> The following traces show the governor does not change the next state if
>> trend==2 (dropping) and throttle==1.
>>
>> [ 2306.127987] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
>> [ 2306.128009] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=1
>> [ 2306.128021] thermal cooling_device0: cur_state=0
>> [ 2306.128031] thermal cooling_device0: old_target=0, target=1
>> [ 2306.231991] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=2,throttle=1
>> [ 2306.232016] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=2,throttle=1
>> [ 2306.232030] thermal cooling_device0: cur_state=1
>> [ 2306.232042] thermal cooling_device0: old_target=1, target=1
>> [ 2306.335982] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=0,throttle=1
>> [ 2306.336006] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=0,throttle=1
>> [ 2306.336021] thermal cooling_device0: cur_state=1
>> [ 2306.336034] thermal cooling_device0: old_target=1, target=1
>> [ 2306.439984] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=2,throttle=1
>> [ 2306.440008] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=2,throttle=0
>> [ 2306.440022] thermal cooling_device0: cur_state=1
>> [ 2306.440034] thermal cooling_device0: old_target=1, target=0
>>
>> [ ... ]
>>
>> After a while, if the temperature continues to increase, the next state becomes
>> 2 which is 720MHz on the hikey. That results in the temperature stabilizing
>> around the trip point.
>>
>> [ 2455.831982] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
>> [ 2455.832006] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=0
>> [ 2455.832019] thermal cooling_device0: cur_state=1
>> [ 2455.832032] thermal cooling_device0: old_target=1, target=1
>> [ 2455.935985] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=0,throttle=1
>> [ 2455.936013] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=0,throttle=0
>> [ 2455.936027] thermal cooling_device0: cur_state=1
>> [ 2455.936040] thermal cooling_device0: old_target=1, target=1
>> [ 2456.043984] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=0,throttle=1
>> [ 2456.044009] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=0,throttle=0
>> [ 2456.044023] thermal cooling_device0: cur_state=1
>> [ 2456.044036] thermal cooling_device0: old_target=1, target=1
>> [ 2456.148001] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
>> [ 2456.148028] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=1
>> [ 2456.148042] thermal cooling_device0: cur_state=1
>> [ 2456.148055] thermal cooling_device0: old_target=1, target=2
>> [ 2456.252009] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=2,throttle=1
>> [ 2456.252041] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=2,throttle=0
>> [ 2456.252058] thermal cooling_device0: cur_state=2
>> [ 2456.252075] thermal cooling_device0: old_target=2, target=1
>>
>> IOW, this change is needed to keep the state for a cooling device if the
>> temperature trend is oscillating while the temperature increases slightly.
>>
>> Without this change, the situation above leads to a catastrophic crash by a
>> hardware reset on hikey.
>
> Daniel,
>
> By design this governor is throttling and un-throttling based on the
> computed trend.
Hi Keerthy,
that was true until commit 3dbfff3d (Nov 2012) but now the function has:
[ ... ]
case THERMAL_TREND_RAISING:
if (throttle) {
next_target = cur_state < instance->upper ?
(cur_state + 1) : instance->upper;
if (next_target < instance->lower)
next_target = instance->lower;
}
break;
If "the trend is raising and we have to throttle" then state++
The change I'm proposing is an action which is the mirror of the one above.
If "the trend is dropping and we don't have to throttle" then state--
> Why not add an intermediate trip point with the highest cooling enabled.
> Say High alert trip point that allows only the lowest OPP for cpufreq to
> operate.
>
> For example: alert trip is at 100C (where cpufreq cooling kicks in)
> critical trip is at 125C(shutdown temperature).
>
> We have Something like below @110C which allows only the lowest
> frequency or lowest 2 frequencies based on experimentation:
>
> +&cpu_trips {
> + cpu_high_alert: cpu_high_alert {
> + temperature = <110000>; /* millicelsius */
> + hysteresis = <2000>; /* millicelsius */
> + type = "passive";
> + };
> +};
> +
> +&cpu_cooling_maps {
> + map1: map1 {
> + trip = <&cpu_high_alert>;
> + cooling-device =
> + <&cpu0 2 THERMAL_NO_LIMIT>;
> + };
> +};
> +
>
> I have seen this problem myself on dra7 platforms. The above will cool
> the device post 110C by keeping the cpu frequency at the lowest or lower
> values. That way when you are in between 100 - 110C you can still get
> highest performance depending on the trend computed and post 110C.
Yeah, so we can drop the graveyard legendary card at clash royal without
any lag and boil our hands ;)
Seriously, from my POV, that is a hack to workaround a governor which is
unable to stabilize the temperature in a specific situation.
This patch fixes this.
-- Daniel
--
<http://www.linaro.org/> Linaro.org │ Open source software for ARM SoCs
Follow Linaro: <http://www.facebook.com/pages/Linaro> Facebook |
<http://twitter.com/#!/linaroorg> Twitter |
<http://www.linaro.org/linaro-blog/> Blog
On Friday 08 September 2017 05:17 PM, Daniel Lezcano wrote:
> On 08/09/2017 11:49, Keerthy wrote:
>>
>>
>> On Friday 08 September 2017 02:35 PM, Daniel Lezcano wrote:
>>> There is a particular situation when the cooling device is cpufreq and the heat
>>> dissipation is not efficient enough where the temperature increases little by
>>> little until reaching the critical threshold and leading to a SoC reset.
>>>
>>> The behavior is reproducible on a hikey6220 with bad heat dissipation (eg.
>>> stacked with other boards).
>>>
>>> Running a simple C program doing while(1); for each CPU of the SoC makes the
>>> temperature to reach the passive regulation trip point and ends up to the
>>> maximum allowed temperature followed by a reset.
>>>
>>> This issue has been also reported by running the libhugetlbfs test suite.
>>>
>>> What is observed is a ping pong between two cpu frequencies, 1.2GHz and 900MHz
>>> while the temperature continues to grow.
>>>
>>> It appears the step wise governor calls get_target_state() the first time with
>>> the throttle set to true and the trend to 'raising'. The code selects logically
>>> the next state, so the cpu frequency decreases from 1.2GHz to 900MHz, so far so
>>> good. The temperature decreases immediately but still stays greater than the
>>> trip point, then get_target_state() is called again, this time with the
>>> throttle set to true *and* the trend to 'dropping'. From there the algorithm
>>> assumes we have to step down the state and the cpu frequency jumps back to
>>> 1.2GHz. But the temperature is still higher than the trip point, so
>>> get_target_state() is called with throttle=1 and trend='raising' again, we jump
>>> to 900MHz, then get_target_state() is called with throttle=1 and
>>> trend='dropping', we jump to 1.2GHz, etc ... but the temperature does not
>>> stabilizes and continues to increase.
>>>
>>> [ 237.922654] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
>>> [ 237.922678] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=1
>>> [ 237.922690] thermal cooling_device0: cur_state=0
>>> [ 237.922701] thermal cooling_device0: old_target=0, target=1
>>> [ 238.026656] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=2,throttle=1
>>> [ 238.026680] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=2,throttle=1
>>> [ 238.026694] thermal cooling_device0: cur_state=1
>>> [ 238.026707] thermal cooling_device0: old_target=1, target=0
>>> [ 238.134647] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
>>> [ 238.134667] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=1
>>> [ 238.134679] thermal cooling_device0: cur_state=0
>>> [ 238.134690] thermal cooling_device0: old_target=0, target=1
>>>
>>> In this situation the temperature continues to increase while the trend is
>>> oscillating between 'dropping' and 'raising'. We need to keep the current state
>>> untouched if the throttle is set, so the temperature can decrease or a higher
>>> state could be selected, thus prevening this oscillation.
>>>
>>> Keeping the next_target untouched when 'throttle' is true at 'dropping' time
>>> fixes the issue.
>>>
>>> The following traces show the governor does not change the next state if
>>> trend==2 (dropping) and throttle==1.
>>>
>>> [ 2306.127987] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
>>> [ 2306.128009] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=1
>>> [ 2306.128021] thermal cooling_device0: cur_state=0
>>> [ 2306.128031] thermal cooling_device0: old_target=0, target=1
>>> [ 2306.231991] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=2,throttle=1
>>> [ 2306.232016] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=2,throttle=1
>>> [ 2306.232030] thermal cooling_device0: cur_state=1
>>> [ 2306.232042] thermal cooling_device0: old_target=1, target=1
>>> [ 2306.335982] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=0,throttle=1
>>> [ 2306.336006] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=0,throttle=1
>>> [ 2306.336021] thermal cooling_device0: cur_state=1
>>> [ 2306.336034] thermal cooling_device0: old_target=1, target=1
>>> [ 2306.439984] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=2,throttle=1
>>> [ 2306.440008] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=2,throttle=0
>>> [ 2306.440022] thermal cooling_device0: cur_state=1
>>> [ 2306.440034] thermal cooling_device0: old_target=1, target=0
>>>
>>> [ ... ]
>>>
>>> After a while, if the temperature continues to increase, the next state becomes
>>> 2 which is 720MHz on the hikey. That results in the temperature stabilizing
>>> around the trip point.
>>>
>>> [ 2455.831982] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
>>> [ 2455.832006] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=0
>>> [ 2455.832019] thermal cooling_device0: cur_state=1
>>> [ 2455.832032] thermal cooling_device0: old_target=1, target=1
>>> [ 2455.935985] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=0,throttle=1
>>> [ 2455.936013] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=0,throttle=0
>>> [ 2455.936027] thermal cooling_device0: cur_state=1
>>> [ 2455.936040] thermal cooling_device0: old_target=1, target=1
>>> [ 2456.043984] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=0,throttle=1
>>> [ 2456.044009] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=0,throttle=0
>>> [ 2456.044023] thermal cooling_device0: cur_state=1
>>> [ 2456.044036] thermal cooling_device0: old_target=1, target=1
>>> [ 2456.148001] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
>>> [ 2456.148028] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=1
>>> [ 2456.148042] thermal cooling_device0: cur_state=1
>>> [ 2456.148055] thermal cooling_device0: old_target=1, target=2
>>> [ 2456.252009] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=2,throttle=1
>>> [ 2456.252041] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=2,throttle=0
>>> [ 2456.252058] thermal cooling_device0: cur_state=2
>>> [ 2456.252075] thermal cooling_device0: old_target=2, target=1
>>>
>>> IOW, this change is needed to keep the state for a cooling device if the
>>> temperature trend is oscillating while the temperature increases slightly.
>>>
>>> Without this change, the situation above leads to a catastrophic crash by a
>>> hardware reset on hikey.
>>
>> Daniel,
>>
>> By design this governor is throttling and un-throttling based on the
>> computed trend.
>
> Hi Keerthy,
>
> that was true until commit 3dbfff3d (Nov 2012) but now the function has:
Daniel,
I understand that commit. It still is stepwise every time you see the
trend toggling you end up changing the cooling level. That is what i meant.
>
> [ ... ]
>
> case THERMAL_TREND_RAISING:
> if (throttle) {
> next_target = cur_state < instance->upper ?
> (cur_state + 1) : instance->upper;
> if (next_target < instance->lower)
> next_target = instance->lower;
> }
> break;
>
> If "the trend is raising and we have to throttle" then state++
>
> The change I'm proposing is an action which is the mirror of the one above.
>
> If "the trend is dropping and we don't have to throttle" then state--
I understand this completely.
>
>
>> Why not add an intermediate trip point with the highest cooling enabled.
>> Say High alert trip point that allows only the lowest OPP for cpufreq to
>> operate.
>>
>> For example: alert trip is at 100C (where cpufreq cooling kicks in)
>> critical trip is at 125C(shutdown temperature).
>>
>> We have Something like below @110C which allows only the lowest
>> frequency or lowest 2 frequencies based on experimentation:
>>
>> +&cpu_trips {
>> + cpu_high_alert: cpu_high_alert {
>> + temperature = <110000>; /* millicelsius */
>> + hysteresis = <2000>; /* millicelsius */
>> + type = "passive";
>> + };
>> +};
>> +
>> +&cpu_cooling_maps {
>> + map1: map1 {
>> + trip = <&cpu_high_alert>;
>> + cooling-device =
>> + <&cpu0 2 THERMAL_NO_LIMIT>;
>> + };
>> +};
>> +
>>
>> I have seen this problem myself on dra7 platforms. The above will cool
>> the device post 110C by keeping the cpu frequency at the lowest or lower
>> values. That way when you are in between 100 - 110C you can still get
>> highest performance depending on the trend computed and post 110C.
>
> Yeah, so we can drop the graveyard legendary card at clash royal without
> any lag and boil our hands ;)
>
> Seriously, from my POV, that is a hack to workaround a governor which is
> unable to stabilize the temperature in a specific situation.
>
> This patch fixes this.
This definitely is an issue i have seen on dra7 and if step_wise by
design can accommodate this change, It will fix the issue!
Then you should be updating the documentation as well.
/*
* If the temperature is higher than a trip point,
* a. if the trend is THERMAL_TREND_RAISING, use higher cooling
* state for this trip point
* b. if the trend is THERMAL_TREND_DROPPING, use lower cooling
* state for this trip point
Now with your patch applied the point b. will change to:
b. if the trend is THERMAL_TREND_DROPPING, Maintain the same cooling
level till the temperature drops below trip point.
Regards,
Keerthy
>
> -- Daniel
>
On 08/09/2017 14:25, Keerthy wrote:
>
[ ... ]
> This definitely is an issue i have seen on dra7 and if step_wise by
> design can accommodate this change, It will fix the issue!
Ah, ok. I understood you thought we should not do the change and use the
DT crit trip instead.
> Then you should be updating the documentation as well.
>
> /*
> * If the temperature is higher than a trip point,
> * a. if the trend is THERMAL_TREND_RAISING, use higher cooling
> * state for this trip point
> * b. if the trend is THERMAL_TREND_DROPPING, use lower cooling
> * state for this trip point
>
> Now with your patch applied the point b. will change to:
>
> b. if the trend is THERMAL_TREND_DROPPING, Maintain the same cooling
> level till the temperature drops below trip point.
Ok, I will change accordingly.
Thanks.
-- Daniel
--
<http://www.linaro.org/> Linaro.org │ Open source software for ARM SoCs
Follow Linaro: <http://www.facebook.com/pages/Linaro> Facebook |
<http://twitter.com/#!/linaroorg> Twitter |
<http://www.linaro.org/linaro-blog/> Blog
There is a particular situation when the cooling device is cpufreq and the heat
dissipation is not efficient enough where the temperature increases little by
little until reaching the critical threshold and leading to a SoC reset.
The behavior is reproducible on a hikey6220 with bad heat dissipation (eg.
stacked with other boards).
Running a simple C program doing while(1); for each CPU of the SoC makes the
temperature to reach the passive regulation trip point and ends up to the
maximum allowed temperature followed by a reset.
This issue has been also reported by running the libhugetlbfs test suite.
What is observed is a ping pong between two cpu frequencies, 1.2GHz and 900MHz
while the temperature continues to grow.
It appears the step wise governor calls get_target_state() the first time with
the throttle set to true and the trend to 'raising'. The code selects logically
the next state, so the cpu frequency decreases from 1.2GHz to 900MHz, so far so
good. The temperature decreases immediately but still stays greater than the
trip point, then get_target_state() is called again, this time with the
throttle set to true *and* the trend to 'dropping'. From there the algorithm
assumes we have to step down the state and the cpu frequency jumps back to
1.2GHz. But the temperature is still higher than the trip point, so
get_target_state() is called with throttle=1 and trend='raising' again, we jump
to 900MHz, then get_target_state() is called with throttle=1 and
trend='dropping', we jump to 1.2GHz, etc ... but the temperature does not
stabilizes and continues to increase.
[ 237.922654] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
[ 237.922678] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=1
[ 237.922690] thermal cooling_device0: cur_state=0
[ 237.922701] thermal cooling_device0: old_target=0, target=1
[ 238.026656] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=2,throttle=1
[ 238.026680] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=2,throttle=1
[ 238.026694] thermal cooling_device0: cur_state=1
[ 238.026707] thermal cooling_device0: old_target=1, target=0
[ 238.134647] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
[ 238.134667] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=1
[ 238.134679] thermal cooling_device0: cur_state=0
[ 238.134690] thermal cooling_device0: old_target=0, target=1
In this situation the temperature continues to increase while the trend is
oscillating between 'dropping' and 'raising'. We need to keep the current state
untouched if the throttle is set, so the temperature can decrease or a higher
state could be selected, thus preventing this oscillation.
Keeping the next_target untouched when 'throttle' is true at 'dropping' time
fixes the issue.
The following traces show the governor does not change the next state if
trend==2 (dropping) and throttle==1.
[ 2306.127987] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
[ 2306.128009] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=1
[ 2306.128021] thermal cooling_device0: cur_state=0
[ 2306.128031] thermal cooling_device0: old_target=0, target=1
[ 2306.231991] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=2,throttle=1
[ 2306.232016] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=2,throttle=1
[ 2306.232030] thermal cooling_device0: cur_state=1
[ 2306.232042] thermal cooling_device0: old_target=1, target=1
[ 2306.335982] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=0,throttle=1
[ 2306.336006] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=0,throttle=1
[ 2306.336021] thermal cooling_device0: cur_state=1
[ 2306.336034] thermal cooling_device0: old_target=1, target=1
[ 2306.439984] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=2,throttle=1
[ 2306.440008] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=2,throttle=0
[ 2306.440022] thermal cooling_device0: cur_state=1
[ 2306.440034] thermal cooling_device0: old_target=1, target=0
[ ... ]
After a while, if the temperature continues to increase, the next state becomes
2 which is 720MHz on the hikey. That results in the temperature stabilizing
around the trip point.
[ 2455.831982] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
[ 2455.832006] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=0
[ 2455.832019] thermal cooling_device0: cur_state=1
[ 2455.832032] thermal cooling_device0: old_target=1, target=1
[ 2455.935985] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=0,throttle=1
[ 2455.936013] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=0,throttle=0
[ 2455.936027] thermal cooling_device0: cur_state=1
[ 2455.936040] thermal cooling_device0: old_target=1, target=1
[ 2456.043984] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=0,throttle=1
[ 2456.044009] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=0,throttle=0
[ 2456.044023] thermal cooling_device0: cur_state=1
[ 2456.044036] thermal cooling_device0: old_target=1, target=1
[ 2456.148001] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
[ 2456.148028] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=1
[ 2456.148042] thermal cooling_device0: cur_state=1
[ 2456.148055] thermal cooling_device0: old_target=1, target=2
[ 2456.252009] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=2,throttle=1
[ 2456.252041] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=2,throttle=0
[ 2456.252058] thermal cooling_device0: cur_state=2
[ 2456.252075] thermal cooling_device0: old_target=2, target=1
IOW, this change is needed to keep the state for a cooling device if the
temperature trend is oscillating while the temperature increases slightly.
Without this change, the situation above leads to a catastrophic crash by a
hardware reset on hikey. This issue has been reported to happen on an OMAP
dra7xx also.
Signed-off-by: Daniel Lezcano <[email protected]>
Cc: Keerthy <[email protected]>
Cc: John Stultz <[email protected]>
Cc: Leo Yan <[email protected]>
---
drivers/thermal/step_wise.c | 11 ++++++-----
1 file changed, 6 insertions(+), 5 deletions(-)
diff --git a/drivers/thermal/step_wise.c b/drivers/thermal/step_wise.c
index be95826..ee047ca 100644
--- a/drivers/thermal/step_wise.c
+++ b/drivers/thermal/step_wise.c
@@ -31,8 +31,7 @@
* If the temperature is higher than a trip point,
* a. if the trend is THERMAL_TREND_RAISING, use higher cooling
* state for this trip point
- * b. if the trend is THERMAL_TREND_DROPPING, use lower cooling
- * state for this trip point
+ * b. if the trend is THERMAL_TREND_DROPPING, do nothing
* c. if the trend is THERMAL_TREND_RAISE_FULL, use upper limit
* for this trip point
* d. if the trend is THERMAL_TREND_DROP_FULL, use lower limit
@@ -94,9 +93,11 @@ static unsigned long get_target_state(struct thermal_instance *instance,
if (!throttle)
next_target = THERMAL_NO_TARGET;
} else {
- next_target = cur_state - 1;
- if (next_target > instance->upper)
- next_target = instance->upper;
+ if (!throttle) {
+ next_target = cur_state - 1;
+ if (next_target > instance->upper)
+ next_target = instance->upper;
+ }
}
break;
case THERMAL_TREND_DROP_FULL:
--
2.7.4
On Friday 08 September 2017 07:42 PM, Daniel Lezcano wrote:
> There is a particular situation when the cooling device is cpufreq and the heat
> dissipation is not efficient enough where the temperature increases little by
> little until reaching the critical threshold and leading to a SoC reset.
>
> The behavior is reproducible on a hikey6220 with bad heat dissipation (eg.
> stacked with other boards).
>
> Running a simple C program doing while(1); for each CPU of the SoC makes the
> temperature to reach the passive regulation trip point and ends up to the
> maximum allowed temperature followed by a reset.
>
> This issue has been also reported by running the libhugetlbfs test suite.
>
> What is observed is a ping pong between two cpu frequencies, 1.2GHz and 900MHz
> while the temperature continues to grow.
>
> It appears the step wise governor calls get_target_state() the first time with
> the throttle set to true and the trend to 'raising'. The code selects logically
> the next state, so the cpu frequency decreases from 1.2GHz to 900MHz, so far so
> good. The temperature decreases immediately but still stays greater than the
> trip point, then get_target_state() is called again, this time with the
> throttle set to true *and* the trend to 'dropping'. From there the algorithm
> assumes we have to step down the state and the cpu frequency jumps back to
> 1.2GHz. But the temperature is still higher than the trip point, so
> get_target_state() is called with throttle=1 and trend='raising' again, we jump
> to 900MHz, then get_target_state() is called with throttle=1 and
> trend='dropping', we jump to 1.2GHz, etc ... but the temperature does not
> stabilizes and continues to increase.
>
> [ 237.922654] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
> [ 237.922678] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=1
> [ 237.922690] thermal cooling_device0: cur_state=0
> [ 237.922701] thermal cooling_device0: old_target=0, target=1
> [ 238.026656] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=2,throttle=1
> [ 238.026680] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=2,throttle=1
> [ 238.026694] thermal cooling_device0: cur_state=1
> [ 238.026707] thermal cooling_device0: old_target=1, target=0
> [ 238.134647] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
> [ 238.134667] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=1
> [ 238.134679] thermal cooling_device0: cur_state=0
> [ 238.134690] thermal cooling_device0: old_target=0, target=1
>
> In this situation the temperature continues to increase while the trend is
> oscillating between 'dropping' and 'raising'. We need to keep the current state
> untouched if the throttle is set, so the temperature can decrease or a higher
> state could be selected, thus preventing this oscillation.
>
> Keeping the next_target untouched when 'throttle' is true at 'dropping' time
> fixes the issue.
>
> The following traces show the governor does not change the next state if
> trend==2 (dropping) and throttle==1.
>
> [ 2306.127987] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
> [ 2306.128009] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=1
> [ 2306.128021] thermal cooling_device0: cur_state=0
> [ 2306.128031] thermal cooling_device0: old_target=0, target=1
> [ 2306.231991] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=2,throttle=1
> [ 2306.232016] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=2,throttle=1
> [ 2306.232030] thermal cooling_device0: cur_state=1
> [ 2306.232042] thermal cooling_device0: old_target=1, target=1
> [ 2306.335982] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=0,throttle=1
> [ 2306.336006] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=0,throttle=1
> [ 2306.336021] thermal cooling_device0: cur_state=1
> [ 2306.336034] thermal cooling_device0: old_target=1, target=1
> [ 2306.439984] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=2,throttle=1
> [ 2306.440008] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=2,throttle=0
> [ 2306.440022] thermal cooling_device0: cur_state=1
> [ 2306.440034] thermal cooling_device0: old_target=1, target=0
>
> [ ... ]
>
> After a while, if the temperature continues to increase, the next state becomes
> 2 which is 720MHz on the hikey. That results in the temperature stabilizing
> around the trip point.
>
> [ 2455.831982] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
> [ 2455.832006] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=0
> [ 2455.832019] thermal cooling_device0: cur_state=1
> [ 2455.832032] thermal cooling_device0: old_target=1, target=1
> [ 2455.935985] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=0,throttle=1
> [ 2455.936013] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=0,throttle=0
> [ 2455.936027] thermal cooling_device0: cur_state=1
> [ 2455.936040] thermal cooling_device0: old_target=1, target=1
> [ 2456.043984] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=0,throttle=1
> [ 2456.044009] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=0,throttle=0
> [ 2456.044023] thermal cooling_device0: cur_state=1
> [ 2456.044036] thermal cooling_device0: old_target=1, target=1
> [ 2456.148001] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=1,throttle=1
> [ 2456.148028] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=1,throttle=1
> [ 2456.148042] thermal cooling_device0: cur_state=1
> [ 2456.148055] thermal cooling_device0: old_target=1, target=2
> [ 2456.252009] thermal thermal_zone0: Trip0[type=1,temp=65000]:trend=2,throttle=1
> [ 2456.252041] thermal thermal_zone0: Trip1[type=1,temp=75000]:trend=2,throttle=0
> [ 2456.252058] thermal cooling_device0: cur_state=2
> [ 2456.252075] thermal cooling_device0: old_target=2, target=1
>
> IOW, this change is needed to keep the state for a cooling device if the
> temperature trend is oscillating while the temperature increases slightly.
>
> Without this change, the situation above leads to a catastrophic crash by a
> hardware reset on hikey. This issue has been reported to happen on an OMAP
> dra7xx also.
Tested on am57xx-evm and saw that cooling level was not reduced even
when temperatures dropped(Negative trend) when the current temperature
was above trip point.
The cooling level was only reduced when the current temperature fell
below the trip point.
Tested-by: Keerthy <[email protected]>
Reviewed-by: Keerthy <[email protected]>
>
> Signed-off-by: Daniel Lezcano <[email protected]>
> Cc: Keerthy <[email protected]>
> Cc: John Stultz <[email protected]>
> Cc: Leo Yan <[email protected]>
> ---
> drivers/thermal/step_wise.c | 11 ++++++-----
> 1 file changed, 6 insertions(+), 5 deletions(-)
>
> diff --git a/drivers/thermal/step_wise.c b/drivers/thermal/step_wise.c
> index be95826..ee047ca 100644
> --- a/drivers/thermal/step_wise.c
> +++ b/drivers/thermal/step_wise.c
> @@ -31,8 +31,7 @@
> * If the temperature is higher than a trip point,
> * a. if the trend is THERMAL_TREND_RAISING, use higher cooling
> * state for this trip point
> - * b. if the trend is THERMAL_TREND_DROPPING, use lower cooling
> - * state for this trip point
> + * b. if the trend is THERMAL_TREND_DROPPING, do nothing
> * c. if the trend is THERMAL_TREND_RAISE_FULL, use upper limit
> * for this trip point
> * d. if the trend is THERMAL_TREND_DROP_FULL, use lower limit
> @@ -94,9 +93,11 @@ static unsigned long get_target_state(struct thermal_instance *instance,
> if (!throttle)
> next_target = THERMAL_NO_TARGET;
> } else {
> - next_target = cur_state - 1;
> - if (next_target > instance->upper)
> - next_target = instance->upper;
> + if (!throttle) {
> + next_target = cur_state - 1;
> + if (next_target > instance->upper)
> + next_target = instance->upper;
> + }
> }
> break;
> case THERMAL_TREND_DROP_FULL:
>