Re: [PATCH] drm/msm/dsi: Stash away calculated vco frequency on recalc

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On 09/06/2021 01:11, Stephen Boyd wrote:
Quoting Dmitry Baryshkov (2021-06-08 14:41:21)
Hi Stephen,

On 08/06/2021 22:55, Stephen Boyd wrote:
A problem was reported on CoachZ devices where the display wouldn't come
up, or it would be distorted. It turns out that the PLL code here wasn't
getting called once dsi_pll_10nm_vco_recalc_rate() started returning the
same exact frequency, down to the Hz, that the bootloader was setting
instead of 0 when the clk was registered with the clk framework.

After commit 001d8dc33875 ("drm/msm/dsi: remove temp data from global
pll structure") we use a hardcoded value for the parent clk frequency,
i.e.  VCO_REF_CLK_RATE, and we also hardcode the value for FRAC_BITS,
instead of getting it from the config structure. This combination of
changes to the recalc function allows us to properly calculate the
frequency of the PLL regardless of whether or not the PLL has been
clk_prepare()d or clk_set_rate()d. That's a good improvement.

Unfortunately, this means that now we won't call down into the PLL clk
driver when we call clk_set_rate() because the frequency calculated in
the framework matches the frequency that is set in hardware. If the rate
is the same as what we want it should be OK to not call the set_rate PLL
op. The real problem is that the prepare op in this driver uses a
private struct member to stash away the vco frequency so that it can
call the set_rate op directly during prepare. Once the set_rate op is
never called because recalc_rate told us the rate is the same, we don't
set this private struct member before the prepare op runs, so we try to
call the set_rate function directly with a frequency of 0. This
effectively kills the PLL and configures it for a rate that won't work.
Calling set_rate from prepare is really quite bad and will confuse any
downstream clks about what the rate actually is of their parent. Fixing
that will be a rather large change though so we leave that to later.

For now, let's stash away the rate we calculate during recalc so that
the prepare op knows what frequency to set, instead of 0. This way
things keep working and the display can enable the PLL properly. In the
future, we should remove that code from the prepare op so that it
doesn't even try to call the set rate function.

Cc: Dmitry Baryshkov <dmitry.baryshkov@xxxxxxxxxx>
Cc: Abhinav Kumar <abhinavk@xxxxxxxxxxxxxx>
Fixes: 001d8dc33875 ("drm/msm/dsi: remove temp data from global pll structure")
Signed-off-by: Stephen Boyd <swboyd@xxxxxxxxxxxx>

Thank you for the lengthy explanation. May I suggest another solution:
   - Apply
https://lore.kernel.org/linux-arm-msm/010101750064e17e-3db0087e-fc37-494d-aac9-2c2b9b0a7c5b-000000@xxxxxxxxxxxxxxxxxxxxxxx/

   - And make save_state for 7nm and 10nm cache vco freq (like 14nm does).

What do you think?


Maybe that can be done for the next merge window? I'd like to get the
smallest possible patch in as a fix for this cycle given that the Fixes
tag is a recent regression introduced during the most recent merge
window.

I honestly have no idea what's going on with the clk driver in these
files but from the clk framework perspective there are bigger problems
than caching the vco freq properly. As I stated in the commit text
above, calling set_rate from prepare is plain bad. That should stop.

Could you please spend few more words, on why calling the clock's set_rate() callback from the same clock's prepare callback is bad? I don't see how this would affect downstream clocks (as we do not change the frequency, we just set the registers).

 From my quick glance, the patch you mention looks like another
workaround instead of a proper fix. Why would we need to save the
registers at boot and then snap them back into place on enable? Maybe we
shouldn't reset the phy after registering the clks? Instead register the
clks after the phy is reset so recalc_rate can accurately calculate the
frequency.

The problem here is not about registration. PHY gets reset not just only on registration, it also might be powered off/reset later (e.g. when the DSI output is disabled for any reason). And during each of these resets we have to keep the PLL state. So keeping the state from the bootloaders seems also natural to me.

I suppose that would break continuous splash screen though
where you want the PLL to stay running the entire boot? But then
issuing a reset would break that, wouldn't it? As you can see I'm pretty
confused about how this is all supposed to work.

Yes, the continuous splash would be broken by resetting the PHY early.

Note: my problem isn't about recovering what boot sets, it's mostly
exposing incorrect usage of the clk framework in this driver because it
relies on this chain of events:

  1) recalc rate calculates something different than what is
     set via clk_set_rate()

  2) clk_set_rate() is called with the different rate

  3) clk_prepare() is called to actually enable the PLL and wait for it
     to start

If clk_prepare() was called before clk_set_rate(), which is totally
valid, then it should similarly fail and think the rate is 0 and the PLL
won't lock. Does implementing save_state fix that? If so, it seems like
we have two pieces of code working around each other, maybe for
suspend/resume purposes.

Ah, we were safe here because the DSI driver first calls clk_set_rate, then clk_prepare_enable for the link clocks, which in turn makes VCO clock first receive the rate and then enable PLL.

I admit this patch I'm proposing is another workaround, but at least it
makes things work again without going off and adding a bunch of register
save/restore logic.

I think we can not come with the better solution in the next day or two, we should merge your workaround. For now I'm trying to understand what are the alternatives and which of them can be better.

Also it's not about registers save/resore. We can add a call to recalc_rate to pll_save_state (as 14nm driver does).


--
With best wishes
Dmitry



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