[RFC PATCH 2/2] clk: mediatek: Add frequency hopping support
AngeloGioacchino Del Regno
angelogioacchino.delregno at collabora.com
Thu Jul 28 01:21:45 PDT 2022
Il 28/07/22 06:37, Edward-JW Yang ha scritto:
> Hi AngeloGioacchino,
>
> Thanks for the advices.
>
> On Thu, 2022-07-21 at 17:43 +0800, AngeloGioacchino Del Regno wrote:
>> Il 20/07/22 15:51, Edward-JW Yang ha scritto:
>>> Hi AngeloGioacchino,
>>>
>>> Thanks for all the advices and examples.
>>>
>>> On Thu, 2022-07-14 at 19:04 +0800, AngeloGioacchino Del Regno wrote:
>>>> Il 06/07/22 15:07, Edward-JW Yang ha scritto:
>>>>> On Wed, 2022-06-29 at 16:54 +0800, Chen-Yu Tsai wrote:
>>>>>> On Tue, Jun 28, 2022 at 6:09 PM AngeloGioacchino Del Regno
>>>>>> <angelogioacchino.delregno at collabora.com> wrote:
>>>>>>>
>>>>>>> Il 24/06/22 09:12, Edward-JW Yang ha scritto:
>>>>>>>> Hi AngeloGioacchino,
>>>>>>>>
>>>>>>>> Thanks for all the advices.
>>>>>>>>
>>>>>>>> On Mon, 2022-06-13 at 17:43 +0800, AngeloGioacchino Del Regno wrote:
>>>>>>>>> Il 12/06/22 15:54, Johnson Wang ha scritto:
>>>>>>>>>> Add frequency hopping support and spread spectrum clocking
>>>>>>>>>> control for MT8186.
>>>>>>>>>>
>>>>>>>>>> Signed-off-by: Edward-JW Yang <edward-jw.yang at mediatek.com>
>>>>>>>>>> Signed-off-by: Johnson Wang <johnson.wang at mediatek.com>
>>>>>>>>>
>>>>>>>>> Before going on with the review, there's one important consideration:
>>>>>>>>> the Frequency Hopping control is related to PLLs only (so, no other clock
>>>>>>>>> types get in the mix).
>>>>>>>>>
>>>>>>>>> Checking the code, the *main* thing that we do here is initializing the
>>>>>>>>> FHCTL by setting some registers, and we're performing the actual frequency
>>>>>>>>> hopping operation in clk-pll, which is right but, at this point, I think
>>>>>>>>> that the best way to proceed is to add the "FHCTL superpowers" to clk-pll
>>>>>>>>> itself, instead of adding multiple new files and devicetree bindings that
>>>>>>>>> are specific to the FHCTL itself.
>>>>>>>>>
>>>>>>>>> This would mean that the `fh-id` and `perms` params that you're setting in
>>>>>>>>> the devicetree get transferred to clk-mt8186 (and hardcoded there), as to
>>>>>>>>> extend the PLL declarations to include these two: that will also simplify
>>>>>>>>> the driver so that you won't have to match names here and there.
>>>>>>>>>
>>>>>>>>> Just an example:
>>>>>>>>>
>>>>>>>>> PLL(CLK_APMIXED_CCIPLL, "ccipll", 0x0224, 0x0230, 0,
>>>>>>>>>
>>>>>>>>> PLL_AO, 0, 22, 0x0228, 24, 0, 0, 0, 0x0228, 2, FHCTL_PERM_DBG_DUMP),
>>>>>>>>>
>>>>>>>>> Besides, there are another couple of reasons why you should do that instead,
>>>>>>>>> of which:
>>>>>>>>> - The devicetree should be "generic enough", we shall not see the direct value
>>>>>>>>> to write to the registers in there (yet, perms assigns exactly that)
>>>>>>>>> - These values won't change on a per-device basis, I believe? They're SoC-related,
>>>>>>>>> not board-related, right?
>>>>>>>>>
>>>>>>>>> In case they're board related (and/or related to TZ permissions), we can always add
>>>>>>>>> a bool property to the apmixedsys to advertise that board X needs to use an
>>>>>>>>> alternative permission (ex.: `mediatek,secure-fhctl`).
>>>>>>>>
>>>>>>>> I think we should remain clk-fhctl files because FHCTL is a independent HW and is
>>>>>>>> not a necessary component of clk-pll.
>>>>>>>
>>>>>>> I know what FHCTL is, but thank you anyway for the explanation, that's appreciated.
>>>>>>> In any case, this not being a *mandatory* component doesn't mean that when it is
>>>>>>> enabled it's not changing the way we manage the PLLs..........
>>>>>>>
>>>>>>>> Frequency hopping function from FHCTL is not used to replace original flow of
>>>>>>>> set_rate in clk-pll. They are two different ways to change PLL's frequency. The
>>>>>>>
>>>>>>> I disagree: when we want to use FHCTL, we effectively hand-over PLL control from
>>>>>>> APMIXEDSYS to the Frequency Hopping controller - and we're effectively replacing
>>>>>>> the set_rate() logic of clk-pll.
>>>>>
>>>>> Do you mean we need to drop the current set_rate() logic (direct register write) and
>>>>> use Frequency Hopping Controller instead?
>>>>>
>>>>
>>>> On PLLs that are supported by the Frequency Hopping controller, yes: we should
>>>> simply use a different .set_rate() callback in clk-pll.c, and we should return
>>>> a failure if the FHCTL fails to set the rate - so we should *not* fall back to
>>>> direct register writes, as on some platforms and in some conditions, using
>>>> direct register writes (which means that we skip FHCTL), may lead to unstable
>>>> system.
>>>>
>>>> This means that we need logic such that, in mtk_clk_register_pll(), we end up
>>>> having something like that:
>>>>
>>>> if (fhctl_is_enabled(pll))
>>>> init.ops = &mtk_pll_fhctl_ops;
>>>> else
>>>> init.ops = &mtk_pll_ops;
>>>>
>>>>> I need to mention that not all PLL support FHCTL, only those PLLs with FHCTL HW can
>>>>> choose to use FHCTL. Take 8186 for example, there are three PLLs don't support FHCTL
>>>>> HW.
>>>>
>>>> Where we declare the PLLs, for example, in clk-mt8186-apmixedsys.c, we can declare
>>>> that such PLL can be managed by FHCTL, for example:
>>>>
>>>> PLL(CLK_APMIXED_ARMPLL_LL, "armpll_ll", 0x0204, 0x0210, 0,
>>>>
>>>> PLL_AO, 0, 22, 0x0208, 24, 0, 0, 0, 0x0208),
>>>>
>>>> becomes
>>>>
>>>> PLL(CLK_APMIXED_ARMPLL_LL, "armpll_ll", 0x0204, 0x0210, 0,
>>>>
>>>> PLL_AO, 0, 22, 0x0208, 24, 0, 0, 0, 0x0208, true);
>>>>
>>>> where 'true' means "FHCTL is supported".
>>>
>>> Does it still have an independent FHCTL driver after modifying to this? From your example,
>>> setup a clk_ops and add FHCTL properities into PLL(), seems FHCTL driver is merged into
>>> clk-pll and become part of clk-pll driver.
>>>
>>
>> The direct-MMIO part of FHCTL becomes part of the clk-pll driver, yes - but then
>> I also find it unacceptable to embed the IPI communication inside of there, so we
>> can have an "external" helper for that.
>
> I think clk-pll driver should focus on PLL HW itself. Since PLL can work alone without
> FHCTL, adding FHCTL control into clk-pll may be a little strange. For this PLL+FHCTL
> combination, I want to add a new type of clock driver, like clk-pll-fh. It might be a
> easier way to maintain FHCTL HW related changes and won't affect to clk-pll.
>
That makes sense, and it's doable as long as we're not duplicating clk-pll's code
to clk-pll-fh and also as long as we're hardcoding the availability of FHCTL in the
SoC-specific clock drivers like I explained in the PLL macro from the previous
example. Let's go!
>>
>>
>>> We tend to have an indepentent driver and dts for FHCTL, and mutate only .set_rate()
>>> callback function instead of whole clk_ops. The boot-up sequence is like:
>>>
>>> 1. clk-pll + clk dts
>>> probe -> clk-pll original flow, nothing to change
>>>
>>> /* clk-pll provide multation API for set_rate */
>>> /* mutate necessary set_rate() instead of mutating all ops */
>>> def register_fhctl_set_rate(pll_name, callback)
>>> ops = find_pll_ops_by_name(pll_name)
>>> log("change set_rate to fhctl callback for $pll_name")
>>> ops->set_rate = callback
>>>
>>> 2. FHCTL driver + fhctl dts
>>> probe
>>> options = parsing dts (board specific, hopping disalbe or ssc-rate)
>>> init FHCTL HW
>>> for PLL in dts
>>> if (ssc-rate > 0)
>>> enable_ssc(ssc-rate)
>>> if (hop-enabled)
>>> /* mutate CCF set_rate, FHCTL engaged CCF */
>>> register_fhctl_CCF(pll_name, callback)
>>>
>>
>> I really don't like having PLL names in devicetree: they're already defined in
>> clock drivers and they will change on a per-SoC basis - and we do have per-SoC
>> drivers...
>>
>> Whatever goes to devicetree should be something that we need to vary on a
>> per-board/platform(project) basis, so, enablement of FHCTL per-pll (by using
>> handles and numeral bindings as per the example that I previously wrote),
>> enablement of spread spectrum and its rate... and nothing else.
>
> OK, we will remove PLL names in devicetree.
>
Great.
>>
>>>>
>>>> Then, we register the PLLs with something like:
>>>>
>>>> mtk_clk_register_plls(node, plls, num_plls, clk_data, fhctl_register_version);
>>>>
>>>> ...where fhctl_register_version is used to assign the right fhctl register offsets.
>>>> Also, it's not needed to assign all of the register offsets statically, because
>>>> they can be easily calculated based on the number of supported PLLs, since the
>>>> registers are structured like
>>>>
>>>> [FHCTL GLOBAL REGISTERS] <--- hp_en...slope1
>>>> [FHCTL SSC GLOBAL REGISTERS] <--- DSSC_CFG, DSSC0...x_CON
>>>>
>>>> [FHCTL PER-PLL REGISTERS] <--- CFG...MON
>>>> ^^^ where this is repeated X times for X PLLs.
>>>>
>>>> so, keeping the example of MT8186, we can get the per-pll register like:
>>>>
>>>> #define FHCTL_PLL_OFFSET 0x3c
>>>> #define FHCTL_PLL_LEN 0x14
>>>>
>>>> #define FHCTLx_CFG(pll_id) (FHCTL_PLL_OFFSET + (pll_id * FHCTL_PLL_LEN))
>>>> #define FHCTLx_UPDNLMT(pll_id) (FHCTL_PLL_OFFSET + (pll_id * FHCTL_PLL_LEN) + 0x4)
>>>> #define FHCTLx_DDS(pll_id) (FHCTL_PLL_OFFSET + (pll_id * FHCTL_PLL_LEN) + 0x8)
>>>>
>>>> we don't need to put all of them in a structure and for each PLL.
>>>
>>> We use structure instead of using macros is because the register offset may have
>>> difference between ICs. If we use macro, we need to maintain different versions of macros.
>>> Using structure to store these register offsets is more flexible.
>>>
>>
>> I understand. What I don't like about your specific approach is the amount of
>> register offsets that we store in that structure, looks like it's a bit too many.
>>
>> I've seen that there's a common pattern at least by checking downstream 5.10 and
>> MT8186/95 layouts, so I still think that using these macros will be beneficial.
>>
>> We can always add parameters to the structure in a later commit: in my opinion,
>> that will help to engineer a better, shorter, cleaner solution for calculating
>> these registers anyway... but I will leave this choice to you, anyway, since you
>> know about way more SoCs than I do.
>
> OK, we will reduce the structure.
>
Perfect!
>>
>>>>
>>>>> So, we need both APMIXEDSYS and Frequency Hopping Controller in set_rate() logic to
>>>>> handle this two types of PLL.
>>>>>
>>>>
>>>> As already said, we preventively know which PLLs support FHCTL and which does not,
>>>> so we can use a different .set_rate() callback.
>>>
>>> Ok, we can use a different .set_rate() callback when fhctl driver probing.
>>>
>>>>
>>>>>>>
>>>>>>>> current set_rate method in clk-pll changes PLL register setting directly. Another
>>>>>>>> way uses FHCTL to change PLL rate.
>>>>>>>
>>>>>>> ...and of course, if we change that, we're effectively mutating the functionality
>>>>>>> of the MediaTek clk-pll driver and please understand that seeing a clear mutation
>>>>>>> in that driver is a bit more human-readable.
>>>>>>>
>>>>>>> Besides, this makes me think about one question: is there any instance in which,
>>>>>>> when FHCTL rate setting fails, we fall back to direct register writes?
>>>>>>>
>>>>>>> I don't think that this is feasible because we have a register in FHCTL that
>>>>>>> effectively hands over control to it, so direct register writes should not work
>>>>>>> when the PLL is not under APMIXEDSYS control, but I'm asking just to be extremely
>>>>>>> sure that my understanding is right.
>>>>>
>>>>> It won't fall back to direct register writes when FHCTL rate setting fails. But, PLL
>>>>> control mode will switch back to APMIXEDSYS after frequency hopping completed.
>>>>>
>>>>> There are two cases that we need to fall back to direct register writes:
>>>>> 1. PLL support FHCTL but it doesn't want to use FHCTL.
>>>>> 2. PLL doesn't support FHCTL HW.
>>>>>
>>>>
>>>> For case N.1, if this is board-specific, we have to resort to devicetree properties
>>>> that will enable/disable FHCTL on specific PLLs.
>>>>
>>>> mediatek,fhctl-disable = <CLK_APMIXED_MSDCPLL>, <CLK_APMIXED_NNAPLL>;
>>>>
>>>> mediatek,ssc-enable = <CLK_APMIXED_MFGPLL>, <CLK_APMIXED_TVDPLL>;
>>>>
>>>> These are just examples - I don't currently know if it's a better idea to have an
>>>> allowlist or a blocklist as devicetree properties, as that depends on the expected
>>>> number of PLLs for which we en/dis fhctl or just ssc (if we generally want fhctl
>>>> enabled on all but one PLLs, we should use fhctl-disable, otherwise, fhctl-enable).
>>>
>>> We also have a properity "ssc-rate" for setting up the ssc rate in percentage. The "ssc-
>>> rate" properity is under fhctl dts node and can be setup on each fhctl-PLL.
>>>
>>
>> Right. For that, we could have a default sensible percentage when SSC is enabled
>> but no rate is set in devicetree, or we can perhaps consider SSC enabled when any
>> meaningful SSC rate is set... For example:
>>
>> mediatek,ssc-enable = <CLK_APMIXED_MFGPLL>, <CLK_APMIXED_TVDPLL>;
>> mediatek,ssc-percent = <5>, <5>;
>>
>> ... or something like:
>>
>> mediatek,ssc = <CLK_APMIXED_MFGPLL 5>, <CLK_APMIXED_TVDPLL 5>;
>>
>> ...but I'd like to have some feedback on that from somebody else, as I don't know
>> if that would be acceptable in devicetree, or if there's any cleaner, niftier
>> solution.
>
> OK, we will use this:
>
> mediatek,hopping-ssc-percent = <CLK_APMIXED_MFGPLL 5>, <CLK_APMIXED_TVDPLL 5>;
>
Looks good.
>>
>>>>
>>>>>>>
>>>>>>>> We will set some PLL's frequency be controlled
>>>>>>>> by clk-pll and some are controlled by FHCTL.
>>>>>>>
>>>>>>> Another question: is this also changing on a per-board basis?
>>>>>>>
>>>>>>> (note: the pll names in the example are random and not specific to anything)
>>>>>>>
>>>>>>> Example: board A wants FHCTL on MMPLL, TVDPLL, MPLL, but *shall not* hand over
>>>>>>> NNAPLL, MFGPLL
>>>>>>> board B wants FHCTL on NNAPLL, TVDPLL but *shall not* hand over MMPLL
>>>>>>>
>>>>>>> Granted that the two A, B boards are using the same SoC, can that ever happen?
>>>>>
>>>>> This could happen if A, B boards have different desense issue.
>>>>>
>>>>
>>>> Ok, so it's definitely board specific. Devicetree is the way to go for this.
>>>>
>>>>>>>
>>>>>>>> And use `perms` param to decide
>>>>>>>> whether a PLL is using FHCTL to change its frequency.
>>>>>>>
>>>>>>> The perms param seems to be about:
>>>>>>> * Enabling debug (but you're not providing any way to actually use debugging
>>>>>>> features, so what's the point?)
>>>>>
>>>>> Debugging feature is not used yet, we can removed it.
>>>>>
>>>>
>>>> If the debugging features of the FHCTL driver will be like what I can see on
>>>> the downstream MT6893 5.10 kernel, that's not really applicable to upstream.
>>>>
>>>> In that case, please remove the debug.
>>>
>>> Ok, we will remove it.
>>>
>>>>
>>>>>>> * Handing over PLL control to FHCTL for hopping (can be as well done with
>>>>>>> simply using a different .set_rate() callback instead of a flag)
>>>>>
>>>>> There has some PLL that have FHCTL but don't want to use FHCTL. The flag is used in
>>>>> this case.
>>>>>
>>>>
>>>> Use the flag to set the right .set_rate() callback, set at probe time, instead of
>>>> checking that flag at every set_rate() call.
>>>
>>> We will setup .set_rate() callback when doing fhctl-pll init.
>>>
>>>>
>>>>>>> * Enabling/disabling Spread Spectrum Clocking (and I think that this is a
>>>>>>> legit use for flags, but if it's just one flag, you can as well use a
>>>>>>> bool and manage this with a devicetree param like "enable-ssc")
>>>>>>>
>>>>>>> That said, I think that the current way of enabling the FHCTL is more complicated
>>>>>>> than how it should really be.
>>>>>
>>>>> Here needs an option to decide whether to enable FHCTL-hopping or FHCTL-ssc since
>>>>> these two are per-board basis.
>>>>>
>>>>> We cannot force all PLL hand over to FHCTL for hopping casue not all PLLs support
>>>>> FHCTL and not all PLLs have need of using FHCTL-hopping.
>>>>>
>>>>
>>>> Board specific -> devicetree
>>>>
>>>> SoC specific -> hardcode, no devicetree.
>>>>
>>>>>>>
>>>>>>>>
>>>>>>>> FHCTL has another function called SSC(spread spectrum clocking) which is used to
>>>>>>>> solve PLL de-sense problem. De-sense problem is board-related so we introduce a
>>>>>>>> `ssc-rate` param in the devicetree to decide whether SSC is enabled and how many
>>>>>>>> rate should be set. Mixing SSC function into clk-pll may cause clk-pll more
>>>>>>>> complex.
>>>>>>>>
>>>>>>>
>>>>>>> Thing is, I don't get why you think that adding SSC to clk-pll would complicate it
>>>>>>> so much... it's really just a few register writes and nothing else, so I really
>>>>>>> don't see where the problem is, here.
>>>>>>>
>>>>>>> Another issue is that this driver may be largely incomplete, so perhaps I can't
>>>>>>> really see the complications you're talking about? Is this the case?
>>>>>>>
>>>>>>> Regarding keeping the FHCTL code in separated files, that's fine, but I would still
>>>>>>> integrate it tightly in clk-pll and its registration flow, because - yes, this is
>>>>>>> for sure not mandatory, but the main parameters are constant, they never change for
>>>>>>> a specific PLL, as they're register offsets, bits and masks (which, again, will
>>>>>>> never change as long as we're using the same SoC).
>>>>>
>>>>> The driver may need to supoport microP by future HW design, standalone file clk-
>>>>> fhctl.c helps to trigger init flow of such as ap-init-flow, microP-init-flow .....,
>>>>> and those different init-flow also need to run some communication API with microP.
>>>>> Those communication APIs are not suitable to merge into clk-pll.
>>>>>
>>>>
>>>> Let's use clk-fhctl as an helper then, we can make sure to call the init flow for
>>>> the microP in the SoC-specific clock drivers, I think that's not a problem?
>>>>
>>>> clk_mtfuturesoc_someip_probe()
>>>> {
>>>> .... register clocks ....
>>>>
>>>> freqhopping_microp_init();
>>>>
>>>> return ret;
>>>> }
>>>>
>>>> If there's hardware out there that supports such feature and a downstream kernel to
>>>> look at, please tell me which one, so that I will be able to check it out and
>>>> perhaps understand how this flow works.
>>>>
>>>> P.S.: I guess it's not fhctl-sspm?
>>>
>>> You could find clk-fhctl-mcupm.c and clk-fhctl-gpueb.c on the downstream MT6893 5.10
>>> kernel. Those codes require the PLL hardware specification to determine which PLL
>>> group(eg. PLL TOP group, GPUEB group) runs on which microP and has responsibilty to
>>> communicate with the microP.
>>>
>>> If we implement these things into clk-pll driver, clk-pll driver not only needs to control
>>> PLL frequency but also needs to deal with microP IPI. It makes clk-pll driver have others
>>> works that is not belong to PLL operation. That's why we tend to have a standalone driver
>>> for FHCTL.
>>>
>>
>> Ok having something to analyze made this entire thing a bit more clear in my mind,
>> thanks for the pointers.
>>
>> Analyzing clk-fhctl-mcupm and clk-fhctl-gpueb makes me see that there's a lot of
>> common code between the two: x_hopping_v1(), x_ssc_enable_v1(), x_ssc_disable_v1()
>> (where x = {gpueb,mcupm}) are really the same functions, duplicated and renamed
>> and nothing else.
>> The only difference is the get_xxxx_ipidev(), which is avoidable by assigning
>> mboxes = <...something...> in devicetree (gpueb mailbox, or mcupm mailbox).
>>
>> Even the `FH_DEVCTL_CMD_ID` enumeration uses the same values!
>>
>> To unroll that riddle, I would at that point add a new MediaTek specific clock
>> driver (like clk-pll) and call it `clk-ipi.c`, because that's what it does in
>> the end: whatever we do, goes through a mailbox instead of a direct MMIO write.
>>
>> That clk-fhctl-ipi would contain a probe function that gets the mailbox handle,
>> then we would add something like `clk_fhctl_set_rate()` function, export it in
>> the `clk-mtk.h` or in a new `clk-fhctl.h` header, then assign the right callback
>> in either the SoC's clock driver (by registering a different clock type, which,
>> in this case, would be clk-fhctl-ipi instead of clk-pll), or in clk-pll itself...
>>
>> In the end, I'm effectively proposing to:
>>
>> 1. Merge the direct-MMIO handling of FHCTL in clk-pll;
>> 2. Create a new driver (and clock type, eventually) for the IPI handling of FHCTL.
>
> From your idea, I think we can also create a new clock type for fhctl such as clk-pll-fh
> and add a new PLL register function for PLL+FHCTL. Then we can change the registery
> interface and won't affect the legacy ICs. Also, if FHCTL has changes, we only need to
> modify clk-pll-fh.
> I think using a new clock type has extendibility for FHCTL changes and also compatiable
> with legacy ICs.
>
> clk-pll.h
> /* Define FHCTL data structure and contains mtk_pll_data.
> * We can use mtk_pll_data later. */
> mtk_pll_fh_data {
> struct mtk_pll_data pll_data;
> /* fhctl_data */
> unsigned int fh_id;
> unsigned int ssc_rate;
> ...
> }
>
> clk-mt8186-apmixedsys.c
> func clk_mt8186_apmixed_probe()
> /* There are two implementations.
> * If ICs need FHCTL such as MT8186, use mtk_clk_register_pllfhs()
> * For those legacy ICs which don't need FHCTL, still use
> * mtk_clk_register_plls().
> */
> /* 1. Need FHCTL. Use API from clk-pll-fh.c */
> fhctl_parse_dt()
> mtk_clk_register_pllfhs(plls data, fh-plls data)
>
> /* 2. Legacy ICs. Use API from clk-pll.c */
> mtk_clk_register_plls()
I'm not sure if we're saying the very same thing here, but for the sake of being
clear and avoiding any misunderstanding, here's my description.
We should call both functions: register_pllfhs() for the PLLs that have support for
freqhopping, register_plls() for the ones that *do not support* freqhopping.
Example for PLL_A, PLL_B, PLL_C, PLL_D:
Freqhopping supported (enabled or not): PLL_A, PLL_B
Freqhopping NOT supported at all: PLL_C, PLL_D
fhplls_data[] = { PLL_A, PLL_B };
plls_data[] = { PLL_C, PLL_D };
func mtk_clk_register_pllfhs(fhdata)
walk through fhplls_data only, other plls are not passed to this function
func clk_mt8186_apmixed_probe()
/* Some PLLs must be controlled directly via MMIO, while others
* support Frequency Hopping through FHCTL.
* Where FHCTL is supported, register clock with register_pllfhs.
* PLLs that are not supported by FHCTL: register with register_plls.
*/
/* Register FHCTL PLLs */
fhctl_parse_dt()
mtk_clk_register_pllfhs(array of plls supporting pllfh)
/* Register the PLLs that do not support FHCTL at all */
mtk_clk_register_plls(all the other PLLs that cannot be FHCTL-controlled)
>
> clk-pll.c
> /* No functional changes, so legacy ICs won't be affected.
> * Export clk_ops functions to clk-pll-fh.c
> */
> func mtk_clk_register_plls()
> init.ops = &mtk_pll_ops;
>
> clk-pll-fh.c
> /* A clock type of FHCTL PLL. Used to setup HW data and ops.
> * Most of ops functions inherit from clk-pll.c.
> * If PLL not support or not enable FHCTL, fallback to use &mtk_pll_ops.
> */
> func mtk_clk_register_pllfhs(plls data, fh-plls data)
> fhctl_match_pll_data() /* match mtk_pll_data and mtk_pll_fh_data */
> fhctl_hw_init()
> if (fhctl_is_supported_and_enabled(pll))
Overall, this seems to look good, minor one nit: if FHCTL is *not supported* on
a PLL, we should *not* even call mtk_clk_register_pllfhs on that PLL, so your
pseudocode would be just:
if (fhctl_is_enabled(pll))
> init.ops = &mtk_pll_fhctl_ops;
> else
> init.ops = &mtk_pll_ops;
>
> if (ssc_is_enable(pll))
> fhctl_ssc_enable(pll)
>
> clk-fhctl.c
> /* APIs of FHCTL HW operations */
> func fhctl_hw_init()
> func fhctl_hopping()
> func fhctl_ssc_enable()
>
>
So it seems that we've reached an agreement here, this was a nice planning
discussion; we should now have a nice and solid base to work on, which is
great.
Cheers,
Angelo
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