Re: [PATCH V5 11/18] clk: tegra210: Add support for Tegra210 clocks

From: Dmitry Osipenko
Date: Wed Jul 17 2019 - 18:49:18 EST


18.07.2019 0:57, Sowjanya Komatineni ÐÐÑÐÑ:
>
> On 7/17/19 2:51 PM, Sowjanya Komatineni wrote:
>>
>> On 7/17/19 2:30 PM, Dmitry Osipenko wrote:
>>> 17.07.2019 23:11, Sowjanya Komatineni ÐÐÑÐÑ:
>>>> On 7/17/19 1:01 PM, Sowjanya Komatineni wrote:
>>>>> On 7/17/19 12:43 PM, Dmitry Osipenko wrote:
>>>>>> 17.07.2019 21:54, Sowjanya Komatineni ÐÐÑÐÑ:
>>>>>>> On 7/17/19 11:51 AM, Sowjanya Komatineni wrote:
>>>>>>>> On 7/17/19 11:32 AM, Dmitry Osipenko wrote:
>>>>>>>>> 17.07.2019 20:29, Sowjanya Komatineni ÐÐÑÐÑ:
>>>>>>>>>> On 7/17/19 8:17 AM, Dmitry Osipenko wrote:
>>>>>>>>>>> 17.07.2019 9:36, Sowjanya Komatineni ÐÐÑÐÑ:
>>>>>>>>>>>> On 7/16/19 11:33 PM, Dmitry Osipenko wrote:
>>>>>>>>>>>>> Ð Tue, 16 Jul 2019 22:55:52 -0700
>>>>>>>>>>>>> Sowjanya Komatineni <skomatineni@xxxxxxxxxx> ÐÐÑÐÑ:
>>>>>>>>>>>>>
>>>>>>>>>>>>>> On 7/16/19 10:42 PM, Dmitry Osipenko wrote:
>>>>>>>>>>>>>>> Ð Tue, 16 Jul 2019 22:25:25 -0700
>>>>>>>>>>>>>>> Sowjanya Komatineni <skomatineni@xxxxxxxxxx> ÐÐÑÐÑ:
>>>>>>>>>>>>>>>> On 7/16/19 9:11 PM, Dmitry Osipenko wrote:
>>>>>>>>>>>>>>>>> Ð Tue, 16 Jul 2019 19:35:49 -0700
>>>>>>>>>>>>>>>>> Sowjanya Komatineni <skomatineni@xxxxxxxxxx> ÐÐÑÐÑ:
>>>>>>>>>>>>>>>>>> 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 ÐÐÑÐÑ:
>>>>>>>>>>>>>>>>>>>>>> On 7/16/19 2:21 PM, Dmitry Osipenko wrote:
>>>>>>>>>>>>>>>>>>>>>>> 17.07.2019 0:12, Sowjanya Komatineni ÐÐÑÐÑ:
>>>>>>>>>>>>>>>>>>>>>>>> On 7/16/19 1:47 PM, Dmitry Osipenko wrote:
>>>>>>>>>>>>>>>>>>>>>>>>> 16.07.2019 22:26, Sowjanya Komatineni ÐÐÑÐÑ:
>>>>>>>>>>>>>>>>>>>>>>>>>> On 7/16/19 11:43 AM, Dmitry Osipenko wrote:
>>>>>>>>>>>>>>>>>>>>>>>>>>> 16.07.2019 21:30, Sowjanya Komatineni ÐÐÑÐÑ:
>>>>>>>>>>>>>>>>>>>>>>>>>>>> On 7/16/19 11:25 AM, Dmitry Osipenko wrote:
>>>>>>>>>>>>>>>>>>>>>>>>>>>>> 16.07.2019 21:19, Sowjanya Komatineni ÐÐÑÐÑ:
>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> 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 ÐÐÑÐÑ:
>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> 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:
>>>>>>>>>>>>>>>>>>>
>>>>>>>>>>>>>>>>>>> ÂÂÂÂÂÂ ÂÂÂ ÂÂÂ - 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:
>>>>>>>>>>>>>>>>>>>
>>>>>>>>>>>>>>>>>>> ÂÂÂÂÂÂ ÂÂÂ ÂÂÂ - 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:
>>>>>>>>>>>>>>>>>>>
>>>>>>>>>>>>>>>>>>> ÂÂÂÂÂÂ ÂÂÂ ÂÂÂ - 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.
>>>>>>>>>>>>> That can be changed of course and I guess it also could be as
>>>>>>>>>>>>> simple as
>>>>>>>>>>>>> saving and restoring of two raw u32 values of the
>>>>>>>>>>>>> policy/divider
>>>>>>>>>>>>> registers.
>>>>>>>>>>>>>
>>>>>>>>>>>>>> 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.
>>>>>>>>>>>>> Since DFLL is now guaranteed to be disabled across CaR
>>>>>>>>>>>>> suspend/resume
>>>>>>>>>>>>> (hence it has nothing to do in regards to CCLK) and given that
>>>>>>>>>>>>> PLLs
>>>>>>>>>>>>> state is restored before the rest of the clocks, I don't
>>>>>>>>>>>>> see why
>>>>>>>>>>>>> not to
>>>>>>>>>>>>> implement CCLK save/restore in a generic fasion. CPU policy
>>>>>>>>>>>>> wull be
>>>>>>>>>>>>> restored to either PLLP or PLLX (if CPUFreq driver is
>>>>>>>>>>>>> disabled).
>>>>>>>>>>>>>
>>>>>>>>>>>> CCLK_G save/restore should happen in clk_super_mux ops
>>>>>>>>>>>> save/context and
>>>>>>>>>>>> clk_super_mux save/restore happens very early as cclk_g is
>>>>>>>>>>>> first
>>>>>>>>>>>> in the
>>>>>>>>>>>> clock tree and save/restore traverses through the tree
>>>>>>>>>>>> top-bottom
>>>>>>>>>>>> order.
>>>>>>>>>>> If CCLK_G is restored before the PLLs, then just change the
>>>>>>>>>>> clocks
>>>>>>>>>>> order
>>>>>>>>>>> such that it won't happen.
>>>>>>>>>>>
>>>>>>>>>> I dont think we can change clocks order for CCLK_G.
>>>>>>>>>>
>>>>>>>>>> During bootup, cclk_g is registered after all pll's and
>>>>>>>>>> peripheral
>>>>>>>>>> clocks which is the way we wanted, So cclk_g will be the first
>>>>>>>>>> one in
>>>>>>>>>> the clk list as clk_register adds new clock first in the list.
>>>>>>>>>>
>>>>>>>>>> When clk_save_context and clk_restore_context APIs iterates
>>>>>>>>>> over the
>>>>>>>>>> list, cclk_g is the first
>>>>>>>>> Looking at clk_core_restore_context(), I see that it walks up CLKs
>>>>>>>>> list
>>>>>>>>> from parent to children, hence I don't understand how it can ever
>>>>>>>>> happen
>>>>>>>>> that CCLK will be restored before the parent. The clocks
>>>>>>>>> registration
>>>>>>>>> order doesn't matter at all in that case.
>>>>>>>> yes from parent to children and dfllCPU_out is the top in the
>>>>>>>> list and
>>>>>>>> its child is cclk_g.
>>>>>>>>
>>>>>>>> the way clocks are registered is the order I see in the clock
>>>>>>>> list and
>>>>>>>> looking into clk_register API it adds new node first in the list.
>>>>>>>>
>>>>>>> cclkg_g & dfll register happens after all plls and peripheral
>>>>>>> clocks as
>>>>>>> it need ref, soc and peripheral clocks to be enabled.
>>>>>>>> So they are the last to get registered and so becomes first in the
>>>>>>>> list.
>>>>>>>>
>>>>>>>> During save/restore context, it traverses thru this list and
>>>>>>>> first in
>>>>>>>> the list is dfllcpu_OUT (parent) and its child (cclk_g)
>>>>>>>>
>>>>>>>> saving should not be an issue at all but we cant restore
>>>>>>>> cclk_g/dfll
>>>>>>>> in normal way thru clk_ops restore as plls and peripherals restore
>>>>>>>> doesn't happen by that time.
>>>>>>>>
>>>>>>> I was referring to clk_restore_context where it iterates thru
>>>>>>> root list
>>>>>>> and for each core from the root list clk_core_restore does
>>>>>>> restore of
>>>>>>> parent and children.
>>>>>>>
>>>>>>> dfllCPU_Out gets first in the list and its child is cclk_g
>>>>>>>
>>>>>>> https://elixir.bootlin.com/linux/v5.2.1/source/drivers/clk/clk.c#L1105
>>>>>>>
>>>>>> What list you're talking about? clk_summary? It shows current
>>>>>> *active*
>>>>>> clocks configuration, if you'll try to disable CPUFreq driver then
>>>>>> the
>>>>>> parent of CCLK_G should be PLLX. Similarly when CPU is reparented to
>>>>>> PLLP on driver's suspend, then PLLP is the parent.
>>>>>>
>>>>>>>>>>>> DFLL enable thru CPUFreq resume happens after all
>>>>>>>>>>>> clk_restore_context
>>>>>>>>>>>> happens. So during clk_restore_context, dfll re-init doesnt
>>>>>>>>>>>> happen
>>>>>>>>>>>> and
>>>>>>>>>>>> doing cpu clock policy restore during super_mux clk_ops will
>>>>>>>>>>>> crash as
>>>>>>>>>>>> DFLL is not initialized and its clock is not enabled but CPU
>>>>>>>>>>>> clock
>>>>>>>>>>>> restore sets source to DFLL if we restore during super_clk_mux
>>>>>>>>>>> If CPU was suspended on PLLP, then it will be restored on
>>>>>>>>>>> PLLP by
>>>>>>>>>>> CaR. I
>>>>>>>>>>> don't understand what DFLL has to do with the CCLK in that case
>>>>>>>>>>> during
>>>>>>>>>>> the clocks restore.
>>>>>>>>>> My above comment is in reference to your request of doing
>>>>>>>>>> save/restore
>>>>>>>>>> for cclk_g in normal fashion thru save/restore context. Because
>>>>>>>>>> of the
>>>>>>>>>> clk order I mentioned above, we cclk_g will be the first one to
>>>>>>>>>> go thru
>>>>>>>>>> save/context.
>>>>>>>>>>
>>>>>>>>>> During save_context of cclk_g, source can be from PLLX, dfll.
>>>>>>>>>>
>>>>>>>>>> Issue will be when we do restore during clk_restore_context of
>>>>>>>>>> cclk_g as
>>>>>>>>>> by that time PLLX/dfll will not be restored.
>>>>>>>>>>
>>>>>>>>> Seems we already agreed that DFLL will be disabled by the CPUFreq
>>>>>>>>> driver
>>>>>>>>> on suspend. Hence CCLK can't be from DFLL if CPU is reparented to
>>>>>>>>> PLLP
>>>>>>>>> on CPUFreq driver's suspend, otherwise CPU keeps running from a
>>>>>>>>> boot-state PLLX if CPUFreq driver is disabled.
>>>>>>>> Yes suspend should not be an issue but issue will be during resume
>>>>>>>> where if we do cclk_g restore in normal way thru
>>>>>>>> clk_restore_context,
>>>>>>>> cclk_g restore happens very early as dfllCPU out is the first
>>>>>>>> one that
>>>>>>>> goes thru restore context and plls/peripherals are not resumed by
>>>>>>>> then.
>>>>>>>>
>>>>>>>> CPU runs from PLLX if dfll clock enable fails during boot. So
>>>>>>>> when it
>>>>>>>> gets to suspend, we save CPU running clock source as either PLLX or
>>>>>>>> DFLL and then we switch to PLLP.
>>>>>>>>
>>>>>>>>
>>>>>>>> On resume, CPU runs from PLLP by warm boot code and we need to
>>>>>>>> restore
>>>>>>>> back its source to the one it was using from saved source context
>>>>>>>> (which can be either PLLX or DFLL)
>>>>>>>>
>>>>>>>> So PLLs & DFLL resume need to happen before CCLKG restore/resume.
>>>>>>>>
>>>>>>>>
>>>>>>>> With all above discussions, we do DFLL disable in CPUFreq driver on
>>>>>>>> suspend and on CPUFreq resume we enable DFLL back and restore CPU
>>>>>>>> clock source it was using during suspend (which will be either
>>>>>>>> PLLX if
>>>>>>>> dfll enable fails during probe or it will be using DFLL).
>>>>>> During suspend CPU's parent shall be PLLP and not DFLL (note that
>>>>>> it is
>>>>>> disabled) after reparenting to PLLP by the CPUFreq driver.
>>>>>>
>>>>> CPU source context should be saved before switching to safe source of
>>>>> PLLP as on resume we need to restore back to source it was using
>>>>> before we switch to safe source during suspend entry.
>>>>>
>>>>> So saved context for CPU Source will be either dfll or PLLX
>>>>>
>>>> PLLP reparenting is only during suspend/entry to have it as safe source
>>>> but actual CPU source it was running from before suspending is either
>>>> dfll/pllx which should be the one to be restored on CPUFreq resume.
>>>> Resume happens with CPU running from PLLP till it gets to the point of
>>>> restoring its original source (dfll or pllx)
>>> CaR should restore CPU to PLLP or PLLX, while CPUFreq driver restores
>>> CPU to DFLL. Please see more comments below.
>>>
>>>>>>>> So i was trying to say dfll/cclk_g restore can't be done in
>>>>>>>> normal way
>>>>>>>> thru clk_ops save/restore context
>>>>>> Let's see what happens if CPUFreq is active:
>>>>>>
>>>>>> 1. CPUFreq driver probe happens
>>>>>> ÂÂÂÂÂ2. CPU is reparented to PLLP
>>>>>> ÂÂÂÂÂ3. DFLL inited
>>>>>> ÂÂÂÂÂ4. CPU is reparented to DFLL
>>>>>>
>>>>>> 5. CPUFreq driver suspend happens
>>>>>> ÂÂÂÂÂ6. CPU is reparented to PLLP
>>>>>> ÂÂÂÂÂ7. DFLL is disabled
>>>>>>
>>>>>> 8. Car suspend happens
>>>>>> ÂÂÂÂÂ9. DFLL context saved
>>>>>> ÂÂÂÂÂ10. PLLP/PLLX context saved
>>>>>> ÂÂÂÂÂ11. CCLK context saved
>>>>>>
>>>>>> 12. Car resume happens
>>>>>> ÂÂÂÂÂ13. DFLL context restored
>>>>>> ÂÂÂÂÂ14. PLLP/PLLX context restored
>>>>>> ÂÂÂÂÂ15. CCLK context restored
>>>>>>
>>>>>> 16. CPUFreq driver resume happens
>>>>>> ÂÂÂÂÂ17. DFLL re-inited
>>>>>> ÂÂÂÂÂ18. CPU is reparented to DFLL
>>>>>
>>>>> Below is the order of sequence it should be based on the order of clk
>>>>> register.
>>>>>
>>>>> My comments inline in this sequence.
>>>>>
>>>>> 1. CPUFreq driver probe happens
>>>>> ÂÂÂÂÂ2. CPU is reparented to PLLP
>>>>> ÂÂÂÂÂ3. DFLL inited
>>>>> ÂÂÂÂÂ4. CPU is reparented to DFLL
>>>>>
>>>>>
>>>>> 5. CPUFreq driver suspend happens
>>>>> ÂÂÂÂÂ6. Save CPU source which could be either dfll or pllx
>>> Please see my next comment.
>>>
>>>>> ÂÂÂÂÂ7. CPU is reparented to safe known source PLLP
>>>>> ÂÂÂÂÂ8. DFLL is disabled
>>>>>
>>>>> 8. Car suspend happens
>>>>> ÂÂÂÂÂ9. DFLL context saved (With DFLL disabled in CPUFreq suspend,
>>>>> nothing to be saved here as last freq req will always be saved).
>>>>> ÂÂÂÂÂ10. CCLK context saved (CPU clock source will be saved in CPUFreq
>>>>> driver suspend which could be either dfll or pllx)
>>> That I don't understand. The CPU's clock source state should be saved at
>>> the moment of the CaR's suspending (i.e. CCLK policy will be set to PLLP
>>> or PLLX) and then CCLK state should be also restored by the CaR in
>>> step 14.
>>
>> CPU clock to be saved and restored should be the source used before we
>> switch it to safe PLLP for suspend/resume operation.
>>
>> This original source could be either PLLX or DFLL which it was using
>> before we disable DFLL during CPU Freq suspend.
>>
>> If we save CPU clock source at moment of CAR suspending, it will be
>> PLLP as we switch to safe PLLP in CPUFreq driver suspend.
>>
>> Infact, we dont need to restore CPU clock source to PLLP anywhere in
>> resume as it comes up with PLLP source from warm boot code itself.

You must always maintain proper suspend/resume encapsulation, otherwise
it's a total mess. It doesn't matter that CCLK is restored to PLLP even
that CPU is already running off PLLP after warmboot.

>> But we need to restore CPU source to original source it was using
>> before we switch to safe PLLP source for suspend operation. This
>> original source could be PLLX/DFLL and this should be re-stored in
>> CPUFreq resume as by this time PLLs and peripherals are restored and
>> dfll is re-initialized.
>>
>> So saving actual CPU source before switching to intermediate safe PLLP
>> in CPUFreq driver and then restoring back during CPUFreq resume should
>> be good as CPUFreq resume happens right after all clocks (plls
>> restore, peripherals restore, dfll resume)>>
>>> CPUFreq driver should only switch CPU to PLLP and disable DFLL on
>>> suspend in step 5, that's it. On resume CPUFreq driver will restore CPU
>>> to DFLL in step 18.
>> Also I don't think we should hard-code to force CPU source to DFLL on
>> CPUFreq resume.
>>
>> Reason is during CPU Probe when it tries to switch to dfll source, for
>> some reason if dfll enable fails it sets CPU to its original source
>> which will be PLLX.

No!

1. CPU voltage could be too low for PLLX
2. PLLX rate can't be changed without manual reparenting CPU to
intermediate clock
3. CPUFreq can't manually manage CPU voltage

DFLL-restoring failure is an extreme case. CPU must be kept on a safe
PLLP in that case and disable_cpufreq() must be invoked as well.

>> So CPU source could be either DFLL or PLLX in CPUFreq
>> tegra124_cpu_switch_to_dfll
>>
>>>>> ÂÂÂÂÂ11. PLLP/PLLX context saved
>>>>> ÂÂÂÂÂ12. Peripheral Clock saved
>>>>>
>>>>> 12. Car resume happens
>>>>> ÂÂÂÂÂ13. DFLL context restored : No DFLL context to be restored and we
>>>>> only need to reinitialize DFLL and re-initialize can't be done here as
>>>>> this is the 1st to get restored and PLL/Peripheral clocks are not
>>>>> restored by this time. So we can't use clk_ops restore for DFLL
>>> It looks to me that clk_core_restore_context() should just do
>>> hlist_for_each_entry *_reverse*. Don't you think so?
>>
>> Thought of that but this is in core driver and is used by other
>> non-tegra clock driver and not sure if that impacts for those.

The reverse ordering should be correct, I think it's just a shortcoming
of the CCF that need to be fixed. But will better to make a more
thorough research, asking Stephen and Michael for the clarification.

>> But with decision of switching CPUFreq with dfll clock enable/disable
>> during CPUFreq suspend/resume, we can re-init dfll during dfll-fcpu
>> driver resume and we don't need CCLK save/restore.
>>
> the way of all clocks order is good except cclk_g which has dependency
> on multiple clocks.

CCLK_G has a single parent at a time. What "multiple clocks" you're
talking about? Please explain.

> reverse list order during restore might not work as all other clocks are
> in proper order no with any ref clocks for plls getting restored prior
> to their clients

Why? The ref clocks should be registered first and be the roots for PLLs
and the rest. If it's not currently the case, then this need to be
fixed. You need to ensure that each clock is modeled properly. If some
child clock really depends on multiple parents, then the parents need to
in the correct order or CCF need to be taught about such multi-dependencies.

If some required feature is missed, then you have to implement it
properly and for all, that's how things are done in upstream. Sometimes
it's quite a lot of extra work that everyone are benefiting from in the end.

[snip]