[v2,2/2] pwm: sprd: Add Spreadtrum PWM support

This patch adds the Spreadtrum PWM support, which provides maximum 4
channels.

Signed-off-by: Neo Hou <neo.hou@unisoc.com>

Signed-off-by: Baolin Wang <baolin.wang@linaro.org>

---
Changes from v1:
 - Add depending on HAS_IOMEM.
 - Rename parameters' names.
 - Implement .apply() instead of .config(), .enable() and .disable().
 - Use NSEC_PER_SEC instead of 1000000000ULL.
 - Add some comments to make code more readable.
 - Remove some redundant operation.
 - Use standard clock properties to set clock parent.
 - Other coding style optimization.
---
 drivers/pwm/Kconfig    |   11 ++
 drivers/pwm/Makefile   |    1 +
 drivers/pwm/pwm-sprd.c |  307 ++++++++++++++++++++++++++++++++++++++++++++++++
 3 files changed, 319 insertions(+)
 create mode 100644 drivers/pwm/pwm-sprd.c

-- 
1.7.9.5

Hi Uwe,

On Wed, 14 Aug 2019 at 18:55, Uwe Kleine-König
<u.kleine-koenig@pengutronix.de> wrote:
>

> Hello Baolin,

>

> On Wed, Aug 14, 2019 at 06:01:50PM +0800, Baolin Wang wrote:

> > On Wed, 14 Aug 2019 at 17:23, Uwe Kleine-König

> > <u.kleine-koenig@pengutronix.de> wrote:

> > > On Wed, Aug 14, 2019 at 04:42:28PM +0800, Baolin Wang wrote:

> > > > On Tue, 13 Aug 2019 at 23:16, Uwe Kleine-König

> > > > <u.kleine-koenig@pengutronix.de> wrote:

> > > > > On Tue, Aug 13, 2019 at 09:46:41PM +0800, Baolin Wang wrote:

> > > > > [...]

> > > > Not really, our hardware's method is, when you changed a new

> > > > configuration (MOD or duty is changed) , the hardware will wait for a

> > > > while to complete current period, then change to the new period.

> > >

> > > Can you describe that in more detail? This doesn't explain why MOD must be

> > > configured before DUTY. Is there another reason for that?

> >

> > Sorry, I did not explain this explicitly. When we change a new PWM

> > configuration, the PWM controller will make sure the current period is

> > completed before changing to a new period. Once setting the MOD

> > register (since we always set MOD firstly), that will tell the

> > hardware that a new period need to change.

>

> So if the current period just ended after you reconfigured MOD but

> before you wrote to DUTY we'll see a bogus period, right? I assume the

> same holds true for writing the prescale value?


I confirmed again, I am sorry I missed something before. Yes, like you
said before, writing DUTY triggers the hardware to actually apply the
values written to MOD and DUTY to the output. So write DUTY last. I
will update the comments and change the PWM configure like:

sprd_pwm_write(spc, pwm->hwpwm, SPRD_PWM_PRESCALE, prescale);
sprd_pwm_write(spc, pwm->hwpwm, SPRD_PWM_MOD, SPRD_PWM_MOD_MAX);
sprd_pwm_write(spc, pwm->hwpwm, SPRD_PWM_DUTY, duty);

>

> > The reason MOD must be configured before DUTY is that, if we

> > configured DUTY firstly, the PWM can work abnormally if the current

> > DUTY is larger than previous MOD. That is also our hardware's

> > limitation.

>

> OK, so you must not get into a situation where DUTY > MOD, right?

>

> Now if the hardware was configured for

>

>         period = 8s, duty = 4s

>

> and now you are supposed to change to

>

>         period = 2s, duty = 1s

>

> you'd need to write DUTY first, don't you?

>

> > > > > > +static int sprd_pwm_remove(struct platform_device *pdev)

> > > > > > +{

> > > > > > +     struct sprd_pwm_chip *spc = platform_get_drvdata(pdev);

> > > > > > +     int ret, i;

> > > > > > +

> > > > > > +     ret = pwmchip_remove(&spc->chip);

> > > > > > +

> > > > > > +     for (i = 0; i < spc->num_pwms; i++) {

> > > > > > +             struct sprd_pwm_chn *chn = &spc->chn[i];

> > > > > > +

> > > > > > +             clk_bulk_disable_unprepare(SPRD_PWM_NUM_CLKS, chn->clks);

> > > > >

> > > > > If a PWM was still running you're effectively stopping it here, right?

> > > > > Are you sure you don't disable once more than you enabled?

> > > >

> > > > Yes, you are right. I should check current enable status of the PWM channel.

> > > > Thanks for your comments.

> > >

> > > I didn't recheck, but I think the right approach is to not fiddle with

> > > the clocks at all and rely on the PWM framework to not let someone call

> > > sprd_pwm_remove when a PWM is still in use.

> >

> > So you mean just return pwmchip_remove(&spc->chip); ?

>

> right.

>

> I just rechecked: If there is still a pwm in use, pwmchip_remove returns

> -EBUSY. So this should be safe.


Yes. Thanks for your comments.


--
Baolin Wang
Best Regards

On 14. 08. 19 11:23, Uwe Kleine-König wrote:
> Hello Baolin,

> 

> On Wed, Aug 14, 2019 at 04:42:28PM +0800, Baolin Wang wrote:

>> On Tue, 13 Aug 2019 at 23:16, Uwe Kleine-König

>> <u.kleine-koenig@pengutronix.de> wrote:

>>> On Tue, Aug 13, 2019 at 09:46:41PM +0800, Baolin Wang wrote:

>>> [...]

>> Not really, our hardware's method is, when you changed a new

>> configuration (MOD or duty is changed) , the hardware will wait for a

>> while to complete current period, then change to the new period.

> 

> Can you describe that in more detail? This doesn't explain why MOD must be

> configured before DUTY. Is there another reason for that?

> 

>>>> +static int sprd_pwm_apply(struct pwm_chip *chip, struct pwm_device *pwm,

>>>> +                       struct pwm_state *state)

>>>> +{

>>>> +     struct sprd_pwm_chip *spc =

>>>> +             container_of(chip, struct sprd_pwm_chip, chip);

>>>> +     struct sprd_pwm_chn *chn = &spc->chn[pwm->hwpwm];

>>>> +     struct pwm_state cstate;

>>>> +     int ret;

>>>> +

>>>> +     pwm_get_state(pwm, &cstate);

>>>

>>> I don't like it when pwm drivers call pwm_get_state(). If ever

>>> pwm_get_state would take a lock, this would deadlock as the lock is

>>> probably already taken when your .apply() callback is running. Moreover

>>> the (expensive) calculations are not used appropriately. See below.

>>

>> I do not think so, see:

>>

>> static inline void pwm_get_state(const struct pwm_device *pwm, struct

>> pwm_state *state)

>> {

>>          *state = pwm->state;

>> }

> 

> OK, the PWM framework currently caches this for you. Still I would

> prefer if you didn't call PWM API functions in your lowlevel driver.

> There is (up to now) nothing bad that will happen if you do it anyhow,

> but when the PWM framework evolves it might (and I want to work on such

> an evolution). You must not call clk_get_rate() in a .set_rate()

> callback of a clock either.

>   

>>>> +     if (state->enabled) {

>>>> +             if (!cstate.enabled) {

>>>

>>> To just know the value of cstate.enabled you only need to read the

>>> register with the ENABLE flag. That is cheaper than calling get_state.

>>>

>>>> +                     /*

>>>> +                      * The clocks to PWM channel has to be enabled first

>>>> +                      * before writing to the registers.

>>>> +                      */

>>>> +                     ret = clk_bulk_prepare_enable(SPRD_PWM_NUM_CLKS,

>>>> +                                                   chn->clks);

>>>> +                     if (ret) {

>>>> +                             dev_err(spc->dev,

>>>> +                                     "failed to enable pwm%u clocks\n",

>>>> +                                     pwm->hwpwm);

>>>> +                             return ret;

>>>> +                     }

>>>> +             }

>>>> +

>>>> +             if (state->period != cstate.period ||

>>>> +                 state->duty_cycle != cstate.duty_cycle) {

>>>

>>> This is a coarse check. If state->period and cstate.period only differ

>>> by one calling sprd_pwm_config(spc, pwm, state->duty_cycle,

>>> state->period) probably results in a noop. So you're doing an expensive

>>> division to get an unreliable check. It would be better to calculate the

>>> register values from the requested state and compare the register

>>> values. The costs are more or less the same than calling .get_state and

>>> the check is reliable. And you don't need to spend another division to

>>> calculate the new register values.

>>

>> Same as above comment.

> 

> When taking the caching into account (which I wouldn't) the check is

> still incomplete. OK, you could argue avoiding the recalculation in 90%

> (to just say some number) of the cases where it is unnecessary is good.

>   

>>>

>>>> +                     ret = sprd_pwm_config(spc, pwm, state->duty_cycle,

>>>> +                                           state->period);

>>>> +                     if (ret)

>>>> +                             return ret;

>>>> +             }

>>>> +

>>>> +             sprd_pwm_write(spc, pwm->hwpwm, SPRD_PWM_ENABLE, 1);

>>>> +     } else if (cstate.enabled) {

>>>> +             sprd_pwm_write(spc, pwm->hwpwm, SPRD_PWM_ENABLE, 0);

>>>> +

>>>> +             clk_bulk_disable_unprepare(SPRD_PWM_NUM_CLKS, chn->clks);

>>>

>>> Assuming writing SPRD_PWM_ENABLE = 0 to the hardware completes the

>>> currently running period and the write doesn't block that long: Does

>>> disabling the clocks interfere with completing the period?

>>

>> Writing SPRD_PWM_ENABLE = 0 will stop the PWM immediately, will not

>> waiting for completing the currently period.

> 

> The currently active period is supposed to be completed. If you cannot

> implement this please point this out as limitation at the top of the

> driver.

> 

> Honestly I think most pwm users won't mind and they should get the

> possibility to tell they prefer pwm_apply_state to return immediately

> even if this could result in a spike. But we're not there yet.

> (Actually there are three things a PWM consumer might want:

> 

>   a) stop immediately;

>   b) complete the currently running period, then stop and return only

>      when the period is completed; or

>   c) complete the currently running period and then stop, return immediately if

>      possible.

> 

> Currently the expected semantic is b).


Hi Uwe et all,

I am sorry for interrupting your discussion. From my (last year or so)
observation of the PWM mailing list I see this as a common pattern in
almost every submission of a new PWM driver. That is PWM driver authors
keep submitting solution a) and you tell them the expected behavior
is b).

Why is that? I hope that the fact that implementing a) is simpler
than b) is not the main reason. I believe that people think a)
is the correct solution.

I agree that smooth transition from one period/duty setting to
different setting makes sense. But I also believe the expected
behavior of setting enabled=0 is different. That is to stop
immediately the technology that is fed by the PWM signal.
Otherwise the concept of enabled/disabled does not make sense
because setting duty=0 would have the same effect.

So I still wonder where the expectation for b) is coming from.
What would be the physical/electrical reasoning for b)?
Why/how it can be dangerous/harmful for any device to stop the
PWM signal immediately?

Would be great to finally reach consensus on that so the expected
behavior can be documented. I know you already attempted that [1].
I think you have done a great job but I still consider the part
about state changes little controversial and unresolved.

Best regards,
Michal

[1] http://patchwork.ozlabs.org/patch/1021566/