On 2/5/2019 11:19 AM, Evan Green wrote:
On Tue, Feb 5, 2019 at 9:52 AM Marc Gonzalez <marc.w.gonza...@free.fr> wrote:

On 05/02/2019 18:24, Marc Gonzalez wrote:

/*** system hangs here for several seconds, then reboots ***/

Silly me. The system crashes in ufshcd_dump_regs() which is a bug
I fixed myself. Once I cherry-pick the appropriate fix, the board
no longer reboots, but UFS init does fail.

Full boot log here:
https://pastebin.ubuntu.com/p/KwpRnWMFw5/

In any case, it's obvious that disabling vccq on this system is
a mistake. How would you solve the problem? (A quirk on top of a
quirk sounds silly.)


I think Bjorn is right that this whole quirk seems to be compensating
for an incorrectly specified device tree (one that specifies
vccq-supply but that doesn't go anywhere).... though maybe this was
made to support boards with footprint-compatible UFS parts from
different vendors? Like the same DT is used for two different SKUs,
one which stamps down a UFS part that uses VCCQ, and another that
doesn't use it, though the wire is there.

This doesn't make sense from a DT perspective, as I understand it. If some board has different configurations (say different display panels), FW is supposed to somehow detect that, and edit the DT before passing the DT off to Linux.

In your example, if SKU1 has a UFS part that needs VCCQ, and SKU2 does not, then FW should somehow query the HW, determine which SKU the device is, and patch vccq in or out of the DT as necessary.


But the revert itself shouldn't really fix anything for you Marc,
should it? It looks like this quirk turns on for Samsung and SKHynix
parts, which presumably just don't use VCCQ. So maybe your device tree
doesn't match your schematics, where the DT's vccq supply is actually
the vccq2 supply going into the UFS chip?

I see the same issue on the reference device, the MSM8998 MTP. The schematics for that indicate there is both vccq and vccq2, at different voltages. vccq goes to both the UFS block, and the phy.

Digging into things, the problem doesn't seem to be that vccq is off - the phy will keep it on. However, the load from the phy is minimal. What really loads the regulator is the UFS block. Without the load from the UFS block, the regulator is likely in a low power mode.

I cannot tell if vccq is routed to the actual storage chip based on the documentation I see, however I can tell that it powers blocks within the host controller block which assist the controller in communicating with the storage chip. These blocks consume quite a bit of power, so likely, if the regulator load is not properly accounted for, these blocks brownout, and communication with the storage chip is broken.

The schematics do refer to this input to the UFS block as "vccq".

So, at a minimum, the host controller itself consumes vccq, and therefore it is unfair to disable vccq solely based on the UFS storage chip that happens to be connected to the controller.

So, we've got two boards that are actually harmed by this quirk. I've not seen anything indicating what harm happens without this quirk. Can someone indicate what that is?

--
Jeffrey Hugo
Qualcomm Datacenter Technologies as an affiliate of Qualcomm Technologies, Inc.
Qualcomm Technologies, Inc. is a member of the
Code Aurora Forum, a Linux Foundation Collaborative Project.

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