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author | Mauro Carvalho Chehab <mchehab+samsung@kernel.org> | 2019-07-26 14:51:16 +0200 |
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committer | Jonathan Corbet <corbet@lwn.net> | 2019-07-31 21:25:27 +0200 |
commit | ccf988b66d697efcd0ceccc2398e0d9b909cd17c (patch) | |
tree | 94022b812a20419675e4cac5af1540d75523d31d /Documentation/i2c/gpio-fault-injection.rst | |
parent | docs: ubifs-authentication.md: convert to ReST (diff) | |
download | linux-ccf988b66d697efcd0ceccc2398e0d9b909cd17c.tar.xz linux-ccf988b66d697efcd0ceccc2398e0d9b909cd17c.zip |
docs: i2c: convert to ReST and add to driver-api bookset
Convert each file at I2C subsystem, renaming them to .rst and
adding to the driver-api book.
Signed-off-by: Mauro Carvalho Chehab <mchehab+samsung@kernel.org>
Acked-by: Wolfram Sang <wsa@the-dreams.de>
Acked-by: Alexandre Belloni <alexandre.belloni@bootlin.com>
Acked-by: Jonathan Cameron <Jonathan.Cameron@huawei.com>
Signed-off-by: Jonathan Corbet <corbet@lwn.net>
Diffstat (limited to 'Documentation/i2c/gpio-fault-injection.rst')
-rw-r--r-- | Documentation/i2c/gpio-fault-injection.rst | 136 |
1 files changed, 136 insertions, 0 deletions
diff --git a/Documentation/i2c/gpio-fault-injection.rst b/Documentation/i2c/gpio-fault-injection.rst new file mode 100644 index 000000000000..9dca6ec7d266 --- /dev/null +++ b/Documentation/i2c/gpio-fault-injection.rst @@ -0,0 +1,136 @@ +========================= +Linux I2C fault injection +========================= + +The GPIO based I2C bus master driver can be configured to provide fault +injection capabilities. It is then meant to be connected to another I2C bus +which is driven by the I2C bus master driver under test. The GPIO fault +injection driver can create special states on the bus which the other I2C bus +master driver should handle gracefully. + +Once the Kconfig option I2C_GPIO_FAULT_INJECTOR is enabled, there will be an +'i2c-fault-injector' subdirectory in the Kernel debugfs filesystem, usually +mounted at /sys/kernel/debug. There will be a separate subdirectory per GPIO +driven I2C bus. Each subdirectory will contain files to trigger the fault +injection. They will be described now along with their intended use-cases. + +Wire states +=========== + +"scl" +----- + +By reading this file, you get the current state of SCL. By writing, you can +change its state to either force it low or to release it again. So, by using +"echo 0 > scl" you force SCL low and thus, no communication will be possible +because the bus master under test will not be able to clock. It should detect +the condition of SCL being unresponsive and report an error to the upper +layers. + +"sda" +----- + +By reading this file, you get the current state of SDA. By writing, you can +change its state to either force it low or to release it again. So, by using +"echo 0 > sda" you force SDA low and thus, data cannot be transmitted. The bus +master under test should detect this condition and trigger a bus recovery (see +I2C specification version 4, section 3.1.16) using the helpers of the Linux I2C +core (see 'struct bus_recovery_info'). However, the bus recovery will not +succeed because SDA is still pinned low until you manually release it again +with "echo 1 > sda". A test with an automatic release can be done with the +"incomplete transfers" class of fault injectors. + +Incomplete transfers +==================== + +The following fault injectors create situations where SDA will be held low by a +device. Bus recovery should be able to fix these situations. But please note: +there are I2C client devices which detect a stuck SDA on their side and release +it on their own after a few milliseconds. Also, there might be an external +device deglitching and monitoring the I2C bus. It could also detect a stuck SDA +and will init a bus recovery on its own. If you want to implement bus recovery +in a bus master driver, make sure you checked your hardware setup for such +devices before. And always verify with a scope or logic analyzer! + +"incomplete_address_phase" +-------------------------- + +This file is write only and you need to write the address of an existing I2C +client device to it. Then, a read transfer to this device will be started, but +it will stop at the ACK phase after the address of the client has been +transmitted. Because the device will ACK its presence, this results in SDA +being pulled low by the device while SCL is high. So, similar to the "sda" file +above, the bus master under test should detect this condition and try a bus +recovery. This time, however, it should succeed and the device should release +SDA after toggling SCL. + +"incomplete_write_byte" +----------------------- + +Similar to above, this file is write only and you need to write the address of +an existing I2C client device to it. + +The injector will again stop at one ACK phase, so the device will keep SDA low +because it acknowledges data. However, there are two differences compared to +'incomplete_address_phase': + +a) the message sent out will be a write message +b) after the address byte, a 0x00 byte will be transferred. Then, stop at ACK. + +This is a highly delicate state, the device is set up to write any data to +register 0x00 (if it has registers) when further clock pulses happen on SCL. +This is why bus recovery (up to 9 clock pulses) must either check SDA or send +additional STOP conditions to ensure the bus has been released. Otherwise +random data will be written to a device! + +Lost arbitration +================ + +Here, we want to simulate the condition where the master under test loses the +bus arbitration against another master in a multi-master setup. + +"lose_arbitration" +------------------ + +This file is write only and you need to write the duration of the arbitration +intereference (in µs, maximum is 100ms). The calling process will then sleep +and wait for the next bus clock. The process is interruptible, though. + +Arbitration lost is achieved by waiting for SCL going down by the master under +test and then pulling SDA low for some time. So, the I2C address sent out +should be corrupted and that should be detected properly. That means that the +address sent out should have a lot of '1' bits to be able to detect corruption. +There doesn't need to be a device at this address because arbitration lost +should be detected beforehand. Also note, that SCL going down is monitored +using interrupts, so the interrupt latency might cause the first bits to be not +corrupted. A good starting point for using this fault injector on an otherwise +idle bus is:: + + # echo 200 > lose_arbitration & + # i2cget -y <bus_to_test> 0x3f + +Panic during transfer +===================== + +This fault injector will create a Kernel panic once the master under test +started a transfer. This usually means that the state machine of the bus master +driver will be ungracefully interrupted and the bus may end up in an unusual +state. Use this to check if your shutdown/reboot/boot code can handle this +scenario. + +"inject_panic" +-------------- + +This file is write only and you need to write the delay between the detected +start of a transmission and the induced Kernel panic (in µs, maximum is 100ms). +The calling process will then sleep and wait for the next bus clock. The +process is interruptible, though. + +Start of a transfer is detected by waiting for SCL going down by the master +under test. A good starting point for using this fault injector is:: + + # echo 0 > inject_panic & + # i2cget -y <bus_to_test> <some_address> + +Note that there doesn't need to be a device listening to the address you are +using. Results may vary depending on that, though. |