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docs: i2c: i2c-topology: reorder sections more logically

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The sequence of sections is a bit confusing here:

 * we list the mux locking scheme for existing drivers before introducing
   what mux locking schemes are
 * we list the caveats for each locking scheme (which are tricky) before
   the example of the simple use case

Restructure it entirely with the following logic:

 * Intro ("I2C muxes and complex topologies")
 * Locking
   - mux-locked
     - example
     - caveats
   - parent-locked
     - example
     - caveats
 * Complex examples
 * Mux type of existing device drivers

While there, also apply some other improvements:

 * convert the caveat list from a table (with only one column carrying
   content) to a bullet list.
 * add a small introductory text to bridge the gap from listing the use
   cases to telling about the hardware components to handle them and then
   the device drivers that implement those.
 * make empty lines usage more uniform

Signed-off-by: Luca Ceresoli <luca.ceresoli@bootlin.com>
Acked-by: Peter Rosin <peda@axentia.se>
Signed-off-by: Wolfram Sang <wsa@kernel.org>
This commit is contained in:
Luca Ceresoli 2022-08-24 10:31:04 +02:00 committed by Wolfram Sang
parent 12c035a1a8
commit 92d5d6434d
1 changed files with 114 additions and 97 deletions
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211
Documentation/i2c/i2c-topology.rst
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@ -16,7 +16,10 @@ Some example use cases are:
from the I2C bus, at least most of the time, and sits behind a gate
that has to be operated before the device can be accessed.
These constructs are represented as I2C adapter trees by Linux, where
Several types of hardware components such as I2C muxes, I2C gates and I2C
arbitrators allow to handle such needs.
These components are represented as I2C adapter trees by Linux, where
each adapter has a parent adapter (except the root adapter) and zero or
more child adapters. The root adapter is the actual adapter that issues
I2C transfers, and all adapters with a parent are part of an "i2c-mux"
@ -34,46 +37,7 @@ Locking
=======
There are two variants of locking available to I2C muxes, they can be
mux-locked or parent-locked muxes. As is evident from below, it can be
useful to know if a mux is mux-locked or if it is parent-locked. The
following list was correct at the time of writing:
In drivers/i2c/muxes/:
====================== =============================================
i2c-arb-gpio-challenge Parent-locked
i2c-mux-gpio Normally parent-locked, mux-locked iff
all involved gpio pins are controlled by the
same I2C root adapter that they mux.
i2c-mux-gpmux Normally parent-locked, mux-locked iff
specified in device-tree.
i2c-mux-ltc4306 Mux-locked
i2c-mux-mlxcpld Parent-locked
i2c-mux-pca9541 Parent-locked
i2c-mux-pca954x Parent-locked
i2c-mux-pinctrl Normally parent-locked, mux-locked iff
all involved pinctrl devices are controlled
by the same I2C root adapter that they mux.
i2c-mux-reg Parent-locked
====================== =============================================
In drivers/iio/:
====================== =============================================
gyro/mpu3050 Mux-locked
imu/inv_mpu6050/ Mux-locked
====================== =============================================
In drivers/media/:
======================= =============================================
dvb-frontends/lgdt3306a Mux-locked
dvb-frontends/m88ds3103 Parent-locked
dvb-frontends/rtl2830 Parent-locked
dvb-frontends/rtl2832 Mux-locked
dvb-frontends/si2168 Mux-locked
usb/cx231xx/ Parent-locked
======================= =============================================
mux-locked or parent-locked muxes.
Mux-locked muxes
@ -88,40 +52,8 @@ full transaction, unrelated I2C transfers may interleave the different
stages of the transaction. This has the benefit that the mux driver
may be easier and cleaner to implement, but it has some caveats.
==== =====================================================================
ML1. If you build a topology with a mux-locked mux being the parent
of a parent-locked mux, this might break the expectation from the
parent-locked mux that the root adapter is locked during the
transaction.
ML2. It is not safe to build arbitrary topologies with two (or more)
mux-locked muxes that are not siblings, when there are address
collisions between the devices on the child adapters of these
non-sibling muxes.
I.e. the select-transfer-deselect transaction targeting e.g. device
address 0x42 behind mux-one may be interleaved with a similar
operation targeting device address 0x42 behind mux-two. The
intent with such a topology would in this hypothetical example
be that mux-one and mux-two should not be selected simultaneously,
but mux-locked muxes do not guarantee that in all topologies.
ML3. A mux-locked mux cannot be used by a driver for auto-closing
gates/muxes, i.e. something that closes automatically after a given
number (one, in most cases) of I2C transfers. Unrelated I2C transfers
may creep in and close prematurely.
ML4. If any non-I2C operation in the mux driver changes the I2C mux state,
the driver has to lock the root adapter during that operation.
Otherwise garbage may appear on the bus as seen from devices
behind the mux, when an unrelated I2C transfer is in flight during
the non-I2C mux-changing operation.
==== =====================================================================
Mux-locked Example
------------------
~~~~~~~~~~~~~~~~~~
::
@ -152,6 +84,43 @@ This means that accesses to D2 are lockout out for the full duration
of the entire operation. But accesses to D3 are possibly interleaved
at any point.
Mux-locked caveats
~~~~~~~~~~~~~~~~~~
When using a mux-locked mux, be aware of the following restrictions:
[ML1]
If you build a topology with a mux-locked mux being the parent
of a parent-locked mux, this might break the expectation from the
parent-locked mux that the root adapter is locked during the
transaction.
[ML2]
It is not safe to build arbitrary topologies with two (or more)
mux-locked muxes that are not siblings, when there are address
collisions between the devices on the child adapters of these
non-sibling muxes.
I.e. the select-transfer-deselect transaction targeting e.g. device
address 0x42 behind mux-one may be interleaved with a similar
operation targeting device address 0x42 behind mux-two. The
intent with such a topology would in this hypothetical example
be that mux-one and mux-two should not be selected simultaneously,
but mux-locked muxes do not guarantee that in all topologies.
[ML3]
A mux-locked mux cannot be used by a driver for auto-closing
gates/muxes, i.e. something that closes automatically after a given
number (one, in most cases) of I2C transfers. Unrelated I2C transfers
may creep in and close prematurely.
[ML4]
If any non-I2C operation in the mux driver changes the I2C mux state,
the driver has to lock the root adapter during that operation.
Otherwise garbage may appear on the bus as seen from devices
behind the mux, when an unrelated I2C transfer is in flight during
the non-I2C mux-changing operation.
Parent-locked muxes
-------------------
@ -160,28 +129,10 @@ Parent-locked muxes lock the parent adapter during the full select-
transfer-deselect transaction. The implication is that the mux driver
has to ensure that any and all I2C transfers through that parent
adapter during the transaction are unlocked I2C transfers (using e.g.
__i2c_transfer), or a deadlock will follow. There are a couple of
caveats.
==== ====================================================================
PL1. If you build a topology with a parent-locked mux being the child
of another mux, this might break a possible assumption from the
child mux that the root adapter is unused between its select op
and the actual transfer (e.g. if the child mux is auto-closing
and the parent mux issues I2C transfers as part of its select).
This is especially the case if the parent mux is mux-locked, but
it may also happen if the parent mux is parent-locked.
PL2. If select/deselect calls out to other subsystems such as gpio,
pinctrl, regmap or iio, it is essential that any I2C transfers
caused by these subsystems are unlocked. This can be convoluted to
accomplish, maybe even impossible if an acceptably clean solution
is sought.
==== ====================================================================
__i2c_transfer), or a deadlock will follow.
Parent-locked Example
---------------------
~~~~~~~~~~~~~~~~~~~~~
::
@ -211,10 +162,30 @@ When there is an access to D1, this happens:
9. M1 unlocks its parent adapter.
10. M1 unlocks muxes on its parent.
This means that accesses to both D2 and D3 are locked out for the full
duration of the entire operation.
Parent-locked Caveats
~~~~~~~~~~~~~~~~~~~~~
When using a parent-locked mux, be aware of the following restrictions:
[PL1]
If you build a topology with a parent-locked mux being the child
of another mux, this might break a possible assumption from the
child mux that the root adapter is unused between its select op
and the actual transfer (e.g. if the child mux is auto-closing
and the parent mux issues I2C transfers as part of its select).
This is especially the case if the parent mux is mux-locked, but
it may also happen if the parent mux is parent-locked.
[PL2]
If select/deselect calls out to other subsystems such as gpio,
pinctrl, regmap or iio, it is essential that any I2C transfers
caused by these subsystems are unlocked. This can be convoluted to
accomplish, maybe even impossible if an acceptably clean solution
is sought.
Complex Examples
================
@ -260,8 +231,10 @@ This is a good topology::
When device D1 is accessed, accesses to D2 are locked out for the
full duration of the operation (muxes on the top child adapter of M1
are locked). But accesses to D3 and D4 are possibly interleaved at
any point. Accesses to D3 locks out D1 and D2, but accesses to D4
are still possibly interleaved.
any point.
Accesses to D3 locks out D1 and D2, but accesses to D4 are still possibly
interleaved.
Mux-locked mux as parent of parent-locked mux
@ -393,3 +366,47 @@ This is a good topology::
When D1 or D2 are accessed, accesses to D3 and D4 are locked out while
accesses to D5 may interleave. When D3 or D4 are accessed, accesses to
all other devices are locked out.
Mux type of existing device drivers
===================================
Whether a device is mux-locked or parent-locked depends on its
implementation. The following list was correct at the time of writing:
In drivers/i2c/muxes/:
====================== =============================================
i2c-arb-gpio-challenge Parent-locked
i2c-mux-gpio Normally parent-locked, mux-locked iff
all involved gpio pins are controlled by the
same I2C root adapter that they mux.
i2c-mux-gpmux Normally parent-locked, mux-locked iff
specified in device-tree.
i2c-mux-ltc4306 Mux-locked
i2c-mux-mlxcpld Parent-locked
i2c-mux-pca9541 Parent-locked
i2c-mux-pca954x Parent-locked
i2c-mux-pinctrl Normally parent-locked, mux-locked iff
all involved pinctrl devices are controlled
by the same I2C root adapter that they mux.
i2c-mux-reg Parent-locked
====================== =============================================
In drivers/iio/:
====================== =============================================
gyro/mpu3050 Mux-locked
imu/inv_mpu6050/ Mux-locked
====================== =============================================
In drivers/media/:
======================= =============================================
dvb-frontends/lgdt3306a Mux-locked
dvb-frontends/m88ds3103 Parent-locked
dvb-frontends/rtl2830 Parent-locked
dvb-frontends/rtl2832 Mux-locked
dvb-frontends/si2168 Mux-locked
usb/cx231xx/ Parent-locked
======================= =============================================