On 7/16/19 10:42 PM, Dmitry Osipenko wrote:
В Tue, 16 Jul 2019 22:25:25 -0700
Sowjanya Komatineni <skomatineni@xxxxxxxxxx> пишет:
On 7/16/19 9:11 PM, Dmitry Osipenko wrote:
В Tue, 16 Jul 2019 19:35:49 -0700
Sowjanya Komatineni <skomatineni@xxxxxxxxxx> пишет:
On 7/16/19 7:18 PM, Sowjanya Komatineni wrote:
On 7/16/19 3:06 PM, Sowjanya Komatineni wrote:
On 7/16/19 3:00 PM, Dmitry Osipenko wrote:
17.07.2019 0:35, Sowjanya Komatineni пишет:
On 7/16/19 2:21 PM, Dmitry Osipenko wrote:
17.07.2019 0:12, Sowjanya Komatineni пишет:
On 7/16/19 1:47 PM, Dmitry Osipenko wrote:
16.07.2019 22:26, Sowjanya Komatineni пишет:
On 7/16/19 11:43 AM, Dmitry Osipenko wrote:
16.07.2019 21:30, Sowjanya Komatineni пишет:
On 7/16/19 11:25 AM, Dmitry Osipenko wrote:
16.07.2019 21:19, Sowjanya Komatineni пишет:
On 7/16/19 9:50 AM, Sowjanya Komatineni wrote:
On 7/16/19 8:00 AM, Dmitry Osipenko wrote:
16.07.2019 11:06, Peter De Schrijver пишет:
On Tue, Jul 16, 2019 at 03:24:26PM +0800, Joseph Lo
wrote:
OK, Will add to CPUFreq driver...
The other thing that also need attention is that
T124 CPUFreq
driver
implicitly relies on DFLL driver to be probed
first, which is
icky.
Should I add check for successful dfll clk
register explicitly in
CPUFreq driver probe and defer till dfll clk
registers?
Probably you should use the "device links". See
[1][2] for the
example.
[1]
https://elixir.bootlin.com/linux/v5.2.1/source/drivers/gpu/drm/tegra/dc.c#L2383
[2]
https://www.kernel.org/doc/html/latest/driver-api/device_link.html
Return EPROBE_DEFER instead of EINVAL if
device_link_add() fails.
And
use of_find_device_by_node() to get the DFLL's
device, see [3].
[3]
https://git.kernel.org/pub/scm/linux/kernel/git/next/linux-next.git/tree/drivers/devfreq/tegra20-devfreq.c#n100
Will go thru and add...
Looks like I initially confused this case with getting
orphaned clock.
I'm now seeing that the DFLL driver registers the clock
and then
clk_get(dfll) should be returning EPROBE_DEFER until
DFLL driver is
probed, hence everything should be fine as-is and there
is no real
need
for the 'device link'. Sorry for the confusion!
Sorry, I didn't follow the mail thread. Just
regarding the DFLL
part.
As you know it, the DFLL clock is one of the CPU
clock sources and
integrated with DVFS control logic with the
regulator. We will not
switch
CPU to other clock sources once we switched to
DFLL. Because the
CPU has
been regulated by the DFLL HW with the DVFS table
(CVB or OPP
table
you see
in the driver.). We shouldn't reparent it to other
sources with
unknew
freq/volt pair. That's not guaranteed to work. We
allow switching to
open-loop mode but different sources.
Okay, then the CPUFreq driver will have to enforce
DFLL freq to
PLLP's
rate before switching to PLLP in order to have a
proper CPU voltage.
PLLP freq is safe to work for any CPU voltage. So no
need to enforce
DFLL freq to PLLP rate before changing CCLK_G source
to PLLP during
suspend
Sorry, please ignore my above comment. During suspend,
need to change
CCLK_G source to PLLP when dfll is in closed loop mode
first and
then
dfll need to be set to open loop.
Okay.
And I don't exactly understand why we need to
switch to PLLP in
CPU
idle
driver. Just keep it on CL-DVFS mode all the time.
In SC7 entry, the dfll suspend function moves it
the open-loop
mode. That's
all. The sc7-entryfirmware will handle the rest of
the sequence to
turn off
the CPU power.
In SC7 resume, the warmboot code will handle the
sequence to
turn on
regulator and power up the CPU cluster. And leave
it on PLL_P.
After
resuming to the kernel, we re-init DFLL, restore
the CPU clock
policy (CPU
runs on DFLL open-loop mode) and then moving to
close-loop mode.
The DFLL is re-inited after switching CCLK to DFLL
parent during of
the
early clocks-state restoring by CaR driver. Hence
instead of having
odd
hacks in the CaR driver, it is much nicer to have a
proper suspend-resume sequencing of the device
drivers. In this case
CPUFreq
driver is the driver that enables DFLL and switches
CPU to that
clock
source, which means that this driver is also should
be responsible for
management of the DFLL's state during of
suspend/resume process. If
CPUFreq driver disables DFLL during suspend and
re-enables it
during
resume, then looks like the CaR driver hacks around
DFLL are not
needed.
The DFLL part looks good to me. BTW, change the
patch subject to
"Add
suspend-resume support" seems more appropriate to
me.
To clarify this, the sequences for DFLL use are as
follows (assuming
all
required DFLL hw configuration has been done)
Switch to DFLL:
0) Save current parent and frequency
1) Program DFLL to open loop mode
2) Enable DFLL
3) Change cclk_g parent to DFLL
For OVR regulator:
4) Change PWM output pin from tristate to output
5) Enable DFLL PWM output
For I2C regulator:
4) Enable DFLL I2C output
6) Program DFLL to closed loop mode
Switch away from DFLL:
0) Change cclk_g parent to PLLP so the CPU frequency
is ok for
any
vdd_cpu voltage
1) Program DFLL to open loop mode
I see during switch away from DFLL (suspend), cclk_g
parent is not
changed to PLLP before changing dfll to open loop mode.
Will add this ...
The CPUFreq driver switches parent to PLLP during the
probe, similar
should be done on suspend.
I'm also wondering if it's always safe to switch to PLLP
in the probe.
If CPU is running on a lower freq than PLLP, then some
other more
appropriate intermediate parent should be selected.
CPU parents are PLL_X, PLL_P, and dfll. PLL_X always runs
at higher
rate
so switching to PLL_P during CPUFreq probe prior to dfll
clock enable
should be safe.
AFAIK, PLLX could run at ~200MHz. There is also a divided
output of
PLLP
which CCLKG supports, the PLLP_OUT4.
Probably, realistically, CPU is always running off a fast
PLLX during
boot, but I'm wondering what may happen on KEXEC. I guess
ideally CPUFreq driver should also have a 'shutdown'
callback to teardown DFLL
on a reboot, but likely that there are other clock-related
problems as
well that may break KEXEC and thus it is not very
important at the
moment.
[snip]
During bootup CPUG sources from PLL_X. By PLL_P source
above I meant
PLL_P_OUT4.
As per clock policies, PLL_X is always used for high freq
like
800Mhz
and for low frequency it will be sourced from PLLP.
Alright, then please don't forget to pre-initialize
PLLP_OUT4 rate to a
reasonable value using tegra_clk_init_table or
assigned-clocks.
PLLP_OUT4 rate update is not needed as it is safe to run at
408Mhz because it is below fmax @ Vmin
So even 204MHz CVB entries are having the same voltage as
408MHz, correct? It's not instantly obvious to me from the
DFLL driver's code where the fmax @ Vmin is defined, I see
that there is the min_millivolts
and frequency entries starting from 204MHZ defined
per-table.
Yes at Vmin CPU Fmax is ~800Mhz. So anything below that will
work at Vmin voltage and PLLP max is 408Mhz.
Thank you for the clarification. It would be good to have that
commented
in the code as well.
OK, Will add...
Regarding, adding suspend/resume to CPUFreq, CPUFreq suspend
happens very early even before disabling non-boot CPUs and also
need to export clock driver APIs to CPUFreq.
Was thinking of below way of implementing this...
Clock DFLL driver Suspend:
- Save CPU clock policy registers, and Perform dfll
suspend which sets in open loop mode
CPU Freq driver Suspend: does nothing
Clock DFLL driver Resume:
- Re-init DFLL, Set in Open-Loop mode, restore CPU Clock
policy registers which actually sets source to DFLL along with
other CPU Policy register restore.
CPU Freq driver Resume:
- do clk_prepare_enable which acutally sets DFLL in
Closed loop mode
Adding one more note: Switching CPU Clock to PLLP is not needed as
CPU CLock can be from dfll in open-loop mode as DFLL is not
disabled anywhere throught the suspend/resume path and SC7 entry
FW and Warm boot code will switch CPU source to PLLP.
Since CPU resumes on PLLP, it will be cleaner to suspend it on PLLP
as well. And besides, seems that currently disabling DFLL clock will
disable DFLL completely and then you'd want to re-init the DFLL on
resume any ways. So better to just disable DFLL completely on
suspend, which should happen on clk_disable(dfll).
Will switch to PLLP during CPUFreq suspend. With decision of using
clk_disable during suspend, its mandatory to switch to PLLP as DFLL
is completely disabled.
My earlier concern was on restoring CPU policy as we can't do that
from CPUFreq driver and need export from clock driver.
Clear now and will do CPU clock policy restore in after dfll re-init.
Why the policy can't be saved/restored by the CaR driver as a context of
any other clock?
restoring cpu clock policy involves programming source and
super_cclkg_divider.
cclk_g is registered as clk_super_mux and it doesn't use frac_div ops to
do save/restore its divider.
Also, during clock context we cant restore cclk_g as cclk_g source will
be dfll and dfll will not be resumed/re-initialized by the time
clk_super_mux save/restore happens.
we can't use save/restore context for dfll clk_ops because dfllCPU_out
parent to CCLK_G is first in the clock tree and dfll_ref and dfll_soc
peripheral clocks are not restored by the time dfll restore happens.
Also dfll peripheral clock enables need to be restored before dfll
restore happens which involves programming dfll controller for
re-initialization.
So dfll resume/re-init is done in clk-tegra210 at end of all clocks
restore in V5 series but instead of in clk-tegra210 driver I moved now
to dfll-fcpu driver pm_ops as all dfll dependencies will be restored
thru clk_restore_context by then. This will be in V6.
Also I don't see Tegra124 CPU Freq driver using flag
CPUFREQ_NEED_INITIAL_FREQ_CHECK.
Tegra124 CPUFreq driver is not using cpufreq_driver
<https://elixir.bootlin.com/linux/v5.2.1/ident/cpufreq_driver>
T124 driver is a wrapper around cpufreq-dt driver.