at 17:39, Rafael J. Wysocki <r...@rjwysocki.net> wrote:

On Friday, July 5, 2019 9:02:01 AM CEST Kai-Heng Feng wrote:
at 19:57, Bjorn Helgaas <helg...@kernel.org> wrote:

On Mon, May 27, 2019 at 11:57:47AM -0500, Bjorn Helgaas wrote:
On Thu, May 23, 2019 at 12:39:23PM +0800, Kai-Heng Feng wrote:
at 04:52, Bjorn Helgaas <helg...@kernel.org> wrote:
On Wed, May 22, 2019 at 02:39:56PM -0400, Alan Stern wrote:
On Wed, 22 May 2019, Bjorn Helgaas wrote:
On Wed, May 22, 2019 at 11:46:25PM +0800, Kai Heng Feng wrote:
On May 22, 2019, at 9:48 PM, Bjorn Helgaas <helg...@kernel.org>
wrote:
On Wed, May 22, 2019 at 11:42:14AM +0800, Kai Heng Feng wrote:
at 6:23 AM, Bjorn Helgaas <helg...@kernel.org> wrote:
On Wed, May 22, 2019 at 12:31:04AM +0800, Kai-Heng Feng wrote:
There's an xHC device that doesn't wake when
a USB device gets plugged
to its USB port. The driver's own runtime
suspend callback was called,
PME signaling was enabled, but it stays at PCI D0.

...
And I guess this patch basically means we wouldn't call
the driver's suspend callback if we're merely going to
stay at D0, so the driver would have no idea anything
happened.  That might match Documentation/power/pci.txt
better, because it suggests that the suspend callback is
related to putting a device in a low-power state, and D0
is not a low-power state.

Yes, the patch is to let the device stay at D0 and don’t run
driver’s own runtime suspend routine.

I guess I’ll just proceed to send a V2 with updated commit message?

Now that I understand what "runtime suspended to D0" means, help me
understand what's actually wrong.

Kai's point is that the xhci-hcd driver thinks the device is now
in runtime suspend, because the runtime_suspend method has been
executed.  But in fact the device is still in D0, and as a
result, PME signalling may not work correctly.

The device claims to be able to signal PME from D0 (this is from the
lspci
in https://bugzilla.kernel.org/show_bug.cgi?id=203673):

  00:10.0 USB controller: Advanced Micro Devices, Inc. [AMD] FCH USB XHCI 
Controller (rev 20) (prog-if 30 [XHCI])
    Capabilities: [50] Power Management version 3
      Flags: PMEClk- DSI- D1- D2- AuxCurrent=0mA PME(D0+,D1-,D2-,D3hot+,D3cold+)

From the xHCI spec r1.0, sec 4.15.2.3, it looks like a connect
detected while in D0 should assert PME# if enabled (and WCE is
set).

I think section 4.15.2.3 is about S3 wake up, no S0 we are
discussing here.

S0 and S3 are system-level ideas and have no meaning to an individual
PCI device.  The xHC is a PCI device and can't tell whether the system
as a whole is in S0 or S3.  If a PCI device claims to be able to
generate PME while in D0, that applies regardless of the system state.

xHCI r1.0, sec A.1 says "The host controller should be capable of
asserting PME# when in any supported device state."  In sec 4.19.2,
Figure 42 says PME# should be asserted whenever PMCSR.PME_En=1 and
WCE=1 and a connection is detected.

Figure 42 also shows that CSC (Connect Status Change) and related bits
feed into Port Status Change Event Generation.  So I assume the xhci
driver normally detects connect/disconnect via CSC, but the runtime
suspend method makes it use PME# instead?

And the way your patch works is by avoiding that xhci runtime suspend
method, so it *always* uses CSC and never uses PME#?  If that's the
case, we're just papering over a problem without really understanding
it.

I'm wondering if this platform has a firmware defect.  Here's my
thinking.  The xHC is a Root Complex Integrated Endpoint, so its PME
signaling is a little unusual.

The typical scenario is that a PCIe device is below a Root Port.  In
that case, it would send a PME Message upstream to the Root Port.  Per
PCIe r4.0, sec 6.1.6, when configured for native PME support (for ACPI
systems, I assume this means "when firmware has granted PME control to
the OS via _OSC"), the Root Port would generate a normal PCI INTx or
MSI interrupt:

  PCI Express-aware software can enable a mode where the Root Complex
  signals PME via an interrupt. When configured for native PME
  support, a Root Port receives the PME Message and sets the PME
  Status bit in its Root Status register. If software has set the PME
  Interrupt Enable bit in the Root Control register to 1b, the Root
  Port then generates an interrupt.

But on this platform the xHC is a Root Complex Integrated Endpoint, so
there is no Root Port upstream from it, and that mechanism can't be
used.  Per PCIe r4.0, sec 1.3.2.3, RCiEPs signal PME via "the same
mechanism as PCI systems" or via Root Complex Event Collectors:

  An RCiEP must signal PME and error conditions through the same
  mechanisms used on PCI systems. If a Root Complex Event Collector is
  implemented, an RCiEP may optionally signal PME and error conditions
  through a Root Complex Event Collector.

This platform has no Root Complex Event Collectors, so the xHC should
signal PME via the same mechanism as PCI systems, i.e., asserting a
PME# signal.  I think this means the OS cannot use native PCIe PME
control because it doesn't know what interrupt PME# is connected to.
The PCI Firmware Spec r3.2, sec 4.5.1 (also quoted in ACPI v6.2, sec
6.2.11.3), says:

  PCI Express Native Power Management Events control

  The firmware sets this bit to 1 to grant control over PCI Express
  native power management event interrupts (PMEs). If firmware
  allows the operating system control of this feature, then in the
  context of the _OSC method, it must ensure that all PMEs are
  routed to root port interrupts as described in the PCI Express
  Base Specification.

This platform cannot route all PMEs to Root Port interrupts because
the xHC RCiEP cannot report PME via a Root Port, so I think its _OSC
method should not grant control of PCIe Native Power Management Events
to the OS, and I think that would mean we have to use the ACPI
mechanism for PME on this platform.

Can you confirm or deny any of this line of reasoning?  I'm wondering
if there's something wrong with the platform's _OSC, so Linux thinks
it can use native PME, but that doesn't work for this device.

It’s a platform in development so the name can’t be disclosed.

Please attach a complete dmesg log to the bugzilla.  You can remove
identifying details like the platform name, but I want to see the
results of the _OSC negotiation.

Thanks for the dmesg log
(https://bugzilla.kernel.org/attachment.cgi?id=283109).  It shows:

  acpi PNP0A08:00: _OSC: OS supports [ExtendedConfig ASPM ClockPM Segments MSI 
HPX-Type3]
  acpi PNP0A08:00: _OSC: platform does not support [SHPCHotplug LTR]
  acpi PNP0A08:00: _OSC: OS now controls [PCIeHotplug PME AER PCIeCapability]

I think it is incorrect for the platform to give the OS native control
over PME because the OS has no way to know how the RCiEP PMEs are
routed.  But it would be interesting to know how BIOSes on other
platforms with RCiEPs handle this, and I did post a question to the
PCI-SIG to see if there's any guidance there.

Is there any update from PCI-SIG?

I really think we don’t need wakeup capability in D0 because D0 is a
working state.

Well, in theory, devices may stay in D0 over suspend-to-idle and they may need to signal wakeup then. Using PME for that would be kind of handy (if it worked) as it
would allow special handling of in-band IRQs to be avoided in that case.

That makes sense but doesn’t apply to this case.
This patch only avoids D0 runtime suspend, suspend-to-idle will call system-wide suspend routine which still enables D0 PME.

It’ll be great if you can review my v3 patch here:
https://patchwork.kernel.org/patch/10960271/

Kai-Heng

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