Hi,
On 25-09-17 15:45, Peter Rosin wrote:
On 2017-09-25 13:35, Hans de Goede wrote:
Hi,
On 25-09-17 12:34, Peter Rosin wrote:
On 2017-09-13 17:48, Hans de Goede wrote:
Hi,
On 13-09-17 17:07, Rob Herring wrote:
On Wed, Sep 13, 2017 at 9:06 AM, Hans de Goede <hdegoede@xxxxxxxxxx> wrote:
Hi,
On 13-09-17 15:38, Rob Herring wrote:
On Wed, Sep 13, 2017 at 3:56 AM, Hans de Goede <hdegoede@xxxxxxxxxx>
wrote:
Hi,
On 13-09-17 00:20, Rob Herring wrote:
On Tue, Sep 05, 2017 at 06:42:20PM +0200, Hans de Goede wrote:
Add mux support to the fusb302 driver, call devm_tcpc_gen_mux_create()
to let the generic tcpc_mux_dev code create a tcpc_mux_dev for us.
Also document the mux-names used by the generic tcpc_mux_dev code in
our devicetree bindings.
Cc: Rob Herring <robh+dt@xxxxxxxxxx>
Cc: Mark Rutland <mark.rutland@xxxxxxx>
Cc: devicetree@xxxxxxxxxxxxxxx
Signed-off-by: Hans de Goede <hdegoede@xxxxxxxxxx>
---
Documentation/devicetree/bindings/usb/fcs,fusb302.txt | 3 +++
drivers/staging/typec/fusb302/fusb302.c | 11
++++++++++-
2 files changed, 13 insertions(+), 1 deletion(-)
diff --git a/Documentation/devicetree/bindings/usb/fcs,fusb302.txt
b/Documentation/devicetree/bindings/usb/fcs,fusb302.txt
index 472facfa5a71..63d639eadacd 100644
--- a/Documentation/devicetree/bindings/usb/fcs,fusb302.txt
+++ b/Documentation/devicetree/bindings/usb/fcs,fusb302.txt
@@ -6,6 +6,9 @@ Required properties :
- interrupts : Interrupt specifier
Optional properties :
+- mux-controls : List of mux-ctrl-specifiers containing 1 or
2
muxes
+- mux-names : "type-c-mode-mux" when using 1 mux, or
+ "type-c-mode-mux", "usb-role-mux" when
using
2 muxes
I'm not sure this is the right place for this. The mux is outside the
FUSB302. In a type-C connector node or USB phy node would make more
sense to me.
The mux certainly does not belong in the USB phy node, it sits between
the
USB PHY
and the Type-C connector and can for example also mux the Type-C pins to
a
Display
Port PHY.
Thinking about this some more, the mux(es) should be its own node(s).
Then the question is where to put the nodes.
Right, the mux will be its own node per
Documentation/devicetree/bindings/mux/mux-controller.txt
the bindings bit this patch is adding is only adding phandles pointing
to that mux-node as the fusb302 "consumes" the mux functionality.
So as such (the fusb302 is the component which should control the mux)
I do believe that the bindings this patch adds are correct.
Humm, that's not how the mux binding works. The mux controller is what
drives the mux select lines and is the provider. The consumer is the
mux device itself. What decides the mux state is determined by what
you are muxing, not which node has mux-controls property.
By putting mux-controls in fusb302 node, you are saying fusb302 is a
mux (or contains a mux).
As for putting it in a type-C connector node, currently we do not have
such
a node,
Well, you should. Type-C connectors are certainly complicated enough
that we'll need one. Plus we already require connector nodes for
display outputs, so what do we do once you add display muxing?
An interesting question, I'm working on this for x86 + ACPI boards actually,
not a board using DT I've been adding DT bindings docs for device-properties
I use because that seems like the right thing to do where the binding is
obvious
(which I believe it is in this case as the fusb302 is the mux consumer) and
because the device-property code should work the same on x86 + ACPI
(where some platform-specific drivers attach the device properties) and
on e.g. ARM + DT.
The rest should probably be left to be figured out when an actual DT
using device using the fusb302 or another Type-C controller shows up.
Well this is a new one (maybe, I suppose others have sneaked by). If
ACPI folks want to use DT bindings, then what do I care. But I have no
interest in reviewing ACPI properties. The whole notion of sharing
bindings between DT and ACPI beyond anything trivial is flawed IMO.
The ptifalls have been discussed multiple times before, so I'm not
going to repeat them here.
Ok, so shall I just drop the Documentation/devicetree/bindings/usb/fcs,fusb302.txt
part of this patch then ?
I totally agree with the concern that Rob expressed about handling USB C
muxes in a non-adhoc way. And this makes this series scary. I don't know
enough details about USB C muxes and PD (I just have a very superficial
mental model) to tell if this series is going down the right path. Or
how terrible it will be to fix things up if not?
The series extends the mux subsystem with muxes that pins semantics
to specific states. That is new, and shows up exactly here when Rob is
not happy about the binding. And if Rob does not want this in the
DT bindings then I'm not so sure it is wise to do it at all? This
problem doesn't go away just because you remove the binding. I think
I would feel much better if there was a path forward on how to
represent USB C muxes in DT and how that would fit with the driver
structure.
If you compare to the i2c-muxes, there is a relatively new i2c-mux-gpmux
driver that uses some general purpose mux from the mux subsystem to
implement an i2c-mux. If USB C muxes where to be done similarly, I'd
imagine there should be a general abstraction of what USB C muxes provide
somewhere outside of the mux subsystem, and a bunch of implementations
of that abstraction. One of those implementations could be to use "raw"
muxes from the mux subsystem. Of course, this is not what this series is
doing.
Also, muxes that are not general purpose such as the ones added to the
mux subsystem by this series could perhaps be repurposed for some other
application, but since the interface implemented does not really obey
the rules (the provided mux controller interacts with different sets of
signals depending on the state) this will not be possible.
These issues are what has caused me to do a lot of thinking and to sit
silent, sorry about that, but I would like input from someone more
experienced. If possible. But I'm not sure where to turn?
As a crazy example, why is it not possible to hook up one signal pair
from the USB C mux, not to DP, but instead to some I2C controller? Then,
if done right, i2c-mux-gpmux could be hooked up with the relevant mux
controller and use the signal pair for I2C, with the mux controller
acting as a gate. So, maybe a bit crazy, but something like that is how
I think it should work from the mux subsystem point of view. And while
maybe crazy and while it might not be technically possible to do I2C
over a USB C connector for some reason, I do think that whatever
abstraction you come up with for USB C muxes, it has to deal with and
broker requests from both the USB subsystem and whatever other
subsystems deals with the alt pairs. Be it graphics for DP signals, or
whatever. IIUC, the alt signals need not be graphics, and it would be
sad to implement the USB C mux it in a way that makes it hard to use
the alt pairs for something else.
[maybe my understanding of USB C is just wrong]
So 2 things:
1) The Type-C subsys does actually abstract the mux outside of the
Type-C port-manager (TCPM) core in the form of a tcpc_mux_dev, so for
DT based platforms we could instantiate a tcpc_mux_dev from a node
which then represents the mux as usual.
2) What is very different from how the mux subsys currently is used,
is who is in control of the mux. Currently a subsys which wants to
route data through the mux selects the mux in the right mode, and
then deselects it when done. This assumes that the mux can mux
the data paths to the requested destination at all times, just not
to multiple destinations at once. With Type-C and any moment in
time, there really is only one correct setting as the mux is
connect to a Type-C device on the other side which typically
only has one config. So what happens with Type-C is that the TCPM
negotiates with the externally connected Type-C device, and then
sets the mux to the one and only correct setting for that device
to be fully functional.
So your i2c example, for example, will not work with the normal
way where the i2c subsys asks the mux to mux a data-pair to the i2c
controller, as that only makes sense when your theoretical Type-C
device which talks i2c over a pair is connected externally, where
as when something else is connected then trying to talk i2c might
even damage the connected device. So with Type-C it is the TCPM
and only the TCPM which controls the mux.
If I get this correctly, some code (the TCPM?) negotiates with the
other side over PD, and after that the way to set up the USB C mux
is known and will not change until the cable is unplugged (unless
we go wild and renegotiate, but let's assume that will not happen).
Correct.
What I don't get is why do you want to squeeze what the TCPM(?) is
doing with its specialized mux into the existing mux subsystem
interface?
That is a good question, this really started with the micro-usb
otg stuff, where we have more or less the same problem in a much
simpler way:
1) We have a cable plugged in which determined if we should mux the
usb2 data lines on a micro-usb to an usb-host or an usb-device/gadget
controller.
2) Some way to detect the type of cable plugged in
3) A hardware block or dedicated chip which is independent from 2,
which needs to be controlled by the code implementing 2.
So we need some glue layer with an abstract (device independent)
interface between 2 and 3 so that we can plug random combinations
of 2 and 3 together. In the beginning I tried using the extcon
framework for that, but that is not really a good fit.
Then someone else did some patches for the otg-mux found on the
Intel Cherry Trail block where using the mux subsys for this and
that seemed like a good idea to me.
And sofar I must say that from my pov the mux subsys does work
quite well for this, but now that I better understand the initial
design of the mux subsys I can understand that you are reluctant
about my use case.
I mean, the mux interface isn't really a perfect fit with its
locking and support for multiple consumers etc that really just gets
in the way of setting a register in some chip to some value. Which
is all that is really needed when you know that the TCPM is the only
one accessing the chip.
And from the point of view of the mux subsystem, the USB C muxes
like the Pericom driver will be in a class of their own. Muxes of
that class can really only be used by one thing -- the TCPM code.
So, I don't see the benefit of doing this through the mux subsystem.
My hope is that the TCPM code is generic, and that by putting the
USB C mux inside the mux subsystem, you can keep the TCPM code
generic?
Correct, the TCPM code is generic and for example the Cherry Trail
SoC OTG mux needs to be controller by either:
A) Something which is detecting the type of cable connected to a
micro-usb (either a PMIC or a gpio reading the ID pin) on devices
with a micro-usb connecter; or
B) The TCPM code on devices with a Type-C connector.
So this is another example where the mux-subsys more or less is
a pretty good fit.
As for the locking, you're right that the locking is not necessary,
but the Type-C connector and its muxes have a clearly defined idle
state, so the deselect functionality also is a decent fit there.
That might be good for the TCPM code, but it does create a
new class of devices in the mux subsystem, and opens the door for
other classes later on.
Why not just add a function pointer that the generic TCPM code calls
if it is set, and then add some code somewhere more local to the TCPM
code to back that call, and completely avoid the mux subsystem?
See the above example about 2 completely different ways how we
need to control the Cherry Trail SoC OTG mux. We really need some
sort of abstraction layer here, and then some way to hook the TCPM
and the Type-C and OTG-mux together, either through pnode handles
in DT on DT platforms or through something like the lookup table
code one of my patches add on x86.
For me using the mux subsys for this works well. But as said I
can understand you being reluctant. Alternatively we could add a
new usb_mux subsys for this I guess.
Regards,
Hans
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