On Thu, 13 Jun 2019 at 20:05, Doug Anderson dianders@chromium.org wrote:
Hi,
On Thu, Jun 13, 2019 at 2:30 AM Ulf Hansson ulf.hansson@linaro.org wrote:
@@ -937,6 +937,10 @@ static int mmc_sdio_pre_suspend(struct mmc_host *host) */ static int mmc_sdio_suspend(struct mmc_host *host) {
/* Prevent processing of SDIO IRQs in suspended state. */mmc_card_set_suspended(host->card);Do you need to claim / release the host around the call to mmc_card_set_suspended() to avoid races?
The intent is that the races should be taken care of like this:
- In MMC_CAP2_SDIO_IRQ_NOTHREAD case, the call to
cancel_delayed_work_sync() below, will make sure that if there are any new work scheduled beyond that point, mmc_card_suspended() will be set and process_sdio_pending_irqs() will bail out.
- In the non MMC_CAP2_SDIO_IRQ_NOTHREAD case, the call to
mmc_claim_host() below will make sure if there is any new attempt to claim the host from the kthread, mmc_card_suspended() will be set and process_sdio_pending_irqs() bails out.
Ideally in the long run and want to remove the SDIO kthread, so perhaps this is good enough for now, what do you think?
I was more worried about the safety of mmc_card_set_suspended() itself. That is:
#define mmc_card_set_suspended(c) ((c)->state |= MMC_STATE_SUSPENDED)
...so it's doing a read-modify-write of "state". Is that safe to do without any type of locking?
In this case, yes I think so.
The point is, it really doesn't matter if the reader (work or thread), reads a non-updated value, because the synchronization is managed by the later mmc_claim_host() and the cancel_delayed_work_sync().
BTW, the important point is that the call to cancel_delayed_work_sync(), must not be done while keeping the host claimed, as then it could deadlock.
Definitely. I was thinking of this sequence:
mmc_claim_host(host); mmc_card_set_suspended(host->card); mmc_release_host(host);
This would work, but claiming/releasing the host is just unnecessary and "expensive".
cancel_delayed_work_sync(&host->sdio_irq_work);
mmc_claim_host(host);
if (!err && host->sdio_irqs) { if (!(host->caps2 & MMC_CAP2_SDIO_IRQ_NOTHREAD)) wake_up_process(host->sdio_irq_thread);diff --git a/drivers/mmc/core/sdio_irq.c b/drivers/mmc/core/sdio_irq.c index 931e6226c0b3..9f54a259a1b3 100644 --- a/drivers/mmc/core/sdio_irq.c +++ b/drivers/mmc/core/sdio_irq.c @@ -34,6 +34,10 @@ static int process_sdio_pending_irqs(struct mmc_host *host) unsigned char pending; struct sdio_func *func;
/* Don't process SDIO IRQs if the card is suspended. */if (mmc_card_suspended(card))return 0;Is it really OK to just return like this? I guess there are two (somewhat opposite) worries I'd have. See A) and B) below:
Let me comment on A) and B) below, for sure there are more problems to address.
The main reason to why I think it's okay to bail out here, is because I think it still improves the current behavior a lot. So, rather than solving all problems at once, I wanted to take a step by step approach.
A) Do we need to do anything extra to make sure we actually call the interrupt handler after we've resumed? I guess we can't actually "lose" the interrupt since it will be sitting asserted in CCCR_INTx until we deal with it (right?), but maybe we need to do something to ensure the handler gets called once we're done resuming?
Good point!
Although, it also depends on if we are going to power off the SDIO card or not. In other words, if the SDIO IRQ are configured as a system wakeup.
Even if it's not a system wakeup, we still don't want to drop the interrupt on the ground though, do we? For instance, think about a level-triggered GPIO interrupt that's _not_ a wakeup interrupt. If that gets asserted in suspend then we won't wakeup the system, but as soon as the system gets to a certain point in the resume sequence then we should pass the interrupt on to the handler. If an edge triggered (but non-wakeup) interrupt fires when the system is resuming then we should similarly not drop it, should we?
GPIOs is clearly different.
When it comes to SDIO cards, re-playing/re-kicking an SDIO IRQ doesn't make sense in case the SDIO card was powered off during system suspend. The reason is simply because the internal state inside the SDIO card gets lost at a power off. For example, the used SDIO func number, needs to re-enabled before any SDIO IRQs can be delivered for it.
So yes, I really think we should drop the SDIO IRQ, unless it's configured as a wakeup. Simply because it's not valid after the system has resumed.
Moreover there is another related problem, if the SDIO IRQ are configured as a system wakeup, and if there is an IRQ raised during the system suspend process, the system suspend process should be aborted but it may not. This is another issue that currently isn't supported. The PM core helps to deals with this, but to take advantage of that, the host controller device device must be configured via the common wakeup interfaces, such as the device_init_wakeup(), for example.
As per earlier discussions I don't have any good examples of SDIO IRQs being able to wakeup the device to poke at. ...but from GPIO-based wakeups I'm used to the suspend code masking the interrupt (so it doesn't fire anymore after the suspend call) but leaving it enabled and configured as a wakeup. I guess we'd have to think about how that translates. Your patch seems to be acting as a "mask" of the interrupt, at least on my dw_mmc tests where the hardware presents the interrupt like it was edge triggered. ...so it would work OK there I'd guess.
A2): new MMC_CAP2_SDIO_IRQ_NOTHREAD case
Should we do something to re-kick things? We could call sdio_signal_irq() in mmc_sdio_resume() I guess? I was worried that might conflict with those that call sdio_run_irqs() directly but it seems like that's nobody as of commit 89f3c365f3e1 ("mmc: sdhci: Fix SDIO IRQ thread deadlock").
Good point!
Again, whether we should re-kick things depends on if the SDIO IRQ is configured as wakeup, but in general using sdio_signal_irq() should work.
The other part I am considering is to disable the SDIO irq, in case of "mmc_card_keep_power() && !mmc_card_wake_sdio_irq()".
Moreover, if !mmc_card_keep_power(), then there really shouldn't be any IRQs registered so perhaps we should add a special check for that and return an error code.
I haven't looked through all the details here but I can dig if you want. On other drivers it's generally OK to leave your interrupt registered (just disabled and/or masked) across suspend/resume, but maybe that's not OK for SDIO cards without keep power?
In the end this boils done to dividing the responsibility of whom does what, at the different layers.
Restoring power to an SDIO card, often ends up with the SDIO func driver having to re-load a FW and perhaps apply some initial HW settings for the corresponding chip.
That said, having the mmc core via mmc_sdio_suspend|resume(), to deal with disable/enable of the SDIO IRQs (and the SDIO func number), seems like doing things upside-down. It may not even work correctly, until the chip have been programmed with a new FW.
In regards to other callers of sdio_run_irqs(). I have a patch that makes it this function static, as it really should not need to be used other than from the work queue path. Let me post it asap to cover that gap. Again, thanks for pointing this out!
Yeah, I was thinking of posting that too, but happy to have you do it! :-)
...side note: overall looking at this code path, two additional questions come up for me. One is why sdio_run_irqs() hardcodes "sdio_irq_pending" as true. That means we won't _ever_ poll CCCR_INTx in the 1-function case, right? That seems wrong. The other is why
In the 1-function case, the idea is that we don't have to read the CCCR_INTx to find out what func number the IRQ belongs to.
This is the same behavior consistent as with the kthread case, see mmc_signal_sdio_irq(), unless I am mistaken.
I think there's at least the bug that nothing will ever set "sdio_irq_pending" to false in the MMC_CAP2_SDIO_IRQ_NOTHREAD case, right? So we'll set it to true the first time and from then on out it will never be false again?
Right.
Although, I consider this a different problem (dealing with the things we have discussed above) and it seems like we should address that as additional changes on top.
mmc_sdio_resume() always calls host->ops->enable_sdio_irq(host, 1) at resume time when nobody ever turned the IRQs off.
That's correct and it leads to unbalanced calls of host->ops->enable_sdio_irq(). This needs to be fixed as well.
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B) Are there any instances where the interrupt will just keep firing over and over again because we don't handle it?
As per above, this _isn't_ happening on dw_mmc on my setup because dw_mmc seems to treat the SDIO interrupt as edge triggered. ...but is this true everywhere? If we were using SDIO in 1-bit mode on dw_mmc, would the interrupt re-assert right away? If dw_mmc were configured to use a dedicated pin would it re-assert right away? What about other host controllers?
If you're sure no host controllers will keep asserting the interrupt over and over then I guess we don't need to worry about it? ...otherwise we'd need to find some way to mask the interrupt and we'd need to make sure whatever we do doesn't interfere with anyone who supports the SDIO interrupt as a wake source, right?
For the MMC_CAP2_SDIO_IRQ_NOTHREAD case, the expected behavior by the host driver is to prior calling sdio_signal_irq(), is should temporary disable the SDIO IRQ. Then, when the host->ops->ack_sdio_irq is called from the work, the IRQ has been processed, which tells the host driver to re-enable the SDIO IRQ.
So what I'm imagining is this:
- mmc_sdio_suspend() starts; calls mmc_card_set_suspended() and
cancel_delayed_work_sync().
SDIO interrupt comes in; host controller calls sdio_signal_irq()
sdio_signal_irq() queues delayed work, which gets scheduled right away.
sdio_run_irqs() calls process_sdio_pending_irqs() which is a no-op
(because we're suspended)
- sdio_run_irqs() calls host->ops->ack_sdio_irq(), which re-enables
more interrupts.
- If SDIO interrupt was truly level triggered, we'll go straight back
to #2 because we never actually removed the true source of the level-triggered interrupt by handling it.
We'll run steps #2 - #6 above ad nauseam until we finally manage to get to the point in the suspend process where the system actually masks/disables all driver interrupts. This happens sometime _after_ the host controller's suspend call happens. Technically this might not really hurt anything (other than burning CPU cycles) because the system workqueue isn't all that high priority so I think the suspend can continue happening while we're looping. ...but it still doesn't seem great.
You are right, thanks for point this out so clearly. I have already started drafting additional patches on top, but allow me a few more days before I can post them.
In regards to $subject patch, even if it may introduce the behavior you described above, I still think it's an improvement comparing to the existing behavior. Allowing to process the SDIO IRQ is just far worse.
We don't end up in the above situation in my tests because the SDIO interrupt was acting as an edge triggered interrupt. ...and because, as per below, we eventually turn the clock off.
In the kthread case, this is managed by mmc_signal_sdio_irq() and the sdio_irq_thread() that calls host->ops->enable_sdio_irq() both to enable/disable the IRQ (but there are other problems with that).
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Overall, I can confirm that on my system your patch actually does work. ...so if all of the above concerns are moot and won't cause anyone else problems then I can say that they don't seem to cause any problems on my system. On rk3288-veyron-jerry:
- Before your patch, I got failures at iteration 18, then 32, then 55,
then 7, then 26.
- After your patch I could do 100 iterations of suspend/resume with no
failures. I also put printouts to confirm your patch was having an effect.
Great news, thanks a lot for testing and sharing these result.
One more thing to consider. After the system suspend callback have been called for the mmc host driver (assuming SDIO IRQ isn't configured as system wakeup), the host driver shouldn't really receive SDIO IRQs and nor should it signal them via sdio_signal_irq(), simply because it has suspended its device/controller and beyond that point, the behavior might be undefined. Can you check to see if this is happening, or possibly you already know that this is the case and that we are "lucky"?
It's happening fine as long as we're loose with the term "after". :-) Most certainly when we just finished executing the last line of the host controller's suspend call then the system can't have done anything to prevent interrupts from going off. Even if the very next thing that the core OS did was to disable interrupts there would still be at least a few CPU instructions in there where we could have finished the suspend call and interrupts were still enabled at the system level.
It looks like the actual suspension of interrupts is in suspend_device_irqs() which is called right before the "no irq" calls are made. ...so in theory we could still get interrupts for quite a while after the host controller's suspend call.
Yes, this is common problem, not specific to this one.
In practice it actually looks to be impossible for dw_mmc, though. ...part of dw_mmc's suspend call turns off both the ciu (card clock) and biu (bus clock). I believe this means that the controller is fully unclocked and there's no way it could give an interrupt.
In fact, the only time we actually get into trouble in dw_mmc is right at the beginning of the resume code where we start re-initting the host controller (and turning its clocks on) and then the interrupt fires before we're quite ready.
Okay, so that we may need to look into sooner or later. Anyway, let's see what my following patches can help with in regards to this as well.
Kind regards Uffe