1.. SPDX-License-Identifier: GFDL-1.1-no-invariants-or-later
2
3CEC Pin Framework Error Injection
4=================================
5
6The CEC Pin Framework is a core CEC framework for CEC hardware that only
7has low-level support for the CEC bus. Most hardware today will have
8high-level CEC support where the hardware deals with driving the CEC bus,
9but some older devices aren't that fancy. However, this framework also
10allows you to connect the CEC pin to a GPIO on e.g. a Raspberry Pi and
11you have now made a CEC adapter.
12
13What makes doing this so interesting is that since we have full control
14over the bus it is easy to support error injection. This is ideal to
15test how well CEC adapters can handle error conditions.
16
17Currently only the cec-gpio driver (when the CEC line is directly
18connected to a pull-up GPIO line) and the AllWinner A10/A20 drm driver
19support this framework.
20
21If ``CONFIG_CEC_PIN_ERROR_INJ`` is enabled, then error injection is available
22through debugfs. Specifically, in ``/sys/kernel/debug/cec/cecX/`` there is
23now an ``error-inj`` file.
24
25.. note::
26
27    The error injection commands are not a stable ABI and may change in the
28    future.
29
30With ``cat error-inj`` you can see both the possible commands and the current
31error injection status::
32
33	$ cat /sys/kernel/debug/cec/cec0/error-inj
34	# Clear error injections:
35	#   clear          clear all rx and tx error injections
36	#   rx-clear       clear all rx error injections
37	#   tx-clear       clear all tx error injections
38	#   <op> clear     clear all rx and tx error injections for <op>
39	#   <op> rx-clear  clear all rx error injections for <op>
40	#   <op> tx-clear  clear all tx error injections for <op>
41	#
42	# RX error injection:
43	#   <op>[,<mode>] rx-nack              NACK the message instead of sending an ACK
44	#   <op>[,<mode>] rx-low-drive <bit>   force a low-drive condition at this bit position
45	#   <op>[,<mode>] rx-add-byte          add a spurious byte to the received CEC message
46	#   <op>[,<mode>] rx-remove-byte       remove the last byte from the received CEC message
47	#    any[,<mode>] rx-arb-lost [<poll>] generate a POLL message to trigger an arbitration lost
48	#
49	# TX error injection settings:
50	#   tx-ignore-nack-until-eom           ignore early NACKs until EOM
51	#   tx-custom-low-usecs <usecs>        define the 'low' time for the custom pulse
52	#   tx-custom-high-usecs <usecs>       define the 'high' time for the custom pulse
53	#   tx-custom-pulse                    transmit the custom pulse once the bus is idle
54	#
55	# TX error injection:
56	#   <op>[,<mode>] tx-no-eom            don't set the EOM bit
57	#   <op>[,<mode>] tx-early-eom         set the EOM bit one byte too soon
58	#   <op>[,<mode>] tx-add-bytes <num>   append <num> (1-255) spurious bytes to the message
59	#   <op>[,<mode>] tx-remove-byte       drop the last byte from the message
60	#   <op>[,<mode>] tx-short-bit <bit>   make this bit shorter than allowed
61	#   <op>[,<mode>] tx-long-bit <bit>    make this bit longer than allowed
62	#   <op>[,<mode>] tx-custom-bit <bit>  send the custom pulse instead of this bit
63	#   <op>[,<mode>] tx-short-start       send a start pulse that's too short
64	#   <op>[,<mode>] tx-long-start        send a start pulse that's too long
65	#   <op>[,<mode>] tx-custom-start      send the custom pulse instead of the start pulse
66	#   <op>[,<mode>] tx-last-bit <bit>    stop sending after this bit
67	#   <op>[,<mode>] tx-low-drive <bit>   force a low-drive condition at this bit position
68	#
69	# <op>       CEC message opcode (0-255) or 'any'
70	# <mode>     'once' (default), 'always', 'toggle' or 'off'
71	# <bit>      CEC message bit (0-159)
72	#            10 bits per 'byte': bits 0-7: data, bit 8: EOM, bit 9: ACK
73	# <poll>     CEC poll message used to test arbitration lost (0x00-0xff, default 0x0f)
74	# <usecs>    microseconds (0-10000000, default 1000)
75
76	clear
77
78You can write error injection commands to ``error-inj`` using
79``echo 'cmd' >error-inj`` or ``cat cmd.txt >error-inj``. The ``cat error-inj``
80output contains the current error commands. You can save the output to a file
81and use it as an input to ``error-inj`` later.
82
83Basic Syntax
84------------
85
86Leading spaces/tabs are ignored. If the next character is a ``#`` or the end
87of the line was reached, then the whole line is ignored. Otherwise a command
88is expected.
89
90The error injection commands fall in two main groups: those relating to
91receiving CEC messages and those relating to transmitting CEC messages. In
92addition, there are commands to clear existing error injection commands and
93to create custom pulses on the CEC bus.
94
95Most error injection commands can be executed for specific CEC opcodes or for
96all opcodes (``any``). Each command also has a 'mode' which can be ``off``
97(can be used to turn off an existing error injection command), ``once``
98(the default) which will trigger the error injection only once for the next
99received or transmitted message, ``always`` to always trigger the error
100injection and ``toggle`` to toggle the error injection on or off for every
101transmit or receive.
102
103So '``any rx-nack``' will NACK the next received CEC message,
104'``any,always rx-nack``' will NACK all received CEC messages and
105'``0x82,toggle rx-nack``' will only NACK if an Active Source message was
106received and do that only for every other received message.
107
108After an error was injected with mode ``once`` the error injection command
109is cleared automatically, so ``once`` is a one-time deal.
110
111All combinations of ``<op>`` and error injection commands can co-exist. So
112this is fine::
113
114	0x9e tx-add-bytes 1
115	0x9e tx-early-eom
116	0x9f tx-add-bytes 2
117	any rx-nack
118
119All four error injection commands will be active simultaneously.
120
121However, if the same ``<op>`` and command combination is specified,
122but with different arguments::
123
124	0x9e tx-add-bytes 1
125	0x9e tx-add-bytes 2
126
127Then the second will overwrite the first.
128
129Clear Error Injections
130----------------------
131
132``clear``
133    Clear all error injections.
134
135``rx-clear``
136    Clear all receive error injections
137
138``tx-clear``
139    Clear all transmit error injections
140
141``<op> clear``
142    Clear all error injections for the given opcode.
143
144``<op> rx-clear``
145    Clear all receive error injections for the given opcode.
146
147``<op> tx-clear``
148    Clear all transmit error injections for the given opcode.
149
150Receive Messages
151----------------
152
153``<op>[,<mode>] rx-nack``
154    NACK broadcast messages and messages directed to this CEC adapter.
155    Every byte of the message will be NACKed in case the transmitter
156    keeps transmitting after the first byte was NACKed.
157
158``<op>[,<mode>] rx-low-drive <bit>``
159    Force a Low Drive condition at this bit position. If <op> specifies
160    a specific CEC opcode then the bit position must be at least 18,
161    otherwise the opcode hasn't been received yet. This tests if the
162    transmitter can handle the Low Drive condition correctly and reports
163    the error correctly. Note that a Low Drive in the first 4 bits can also
164    be interpreted as an Arbitration Lost condition by the transmitter.
165    This is implementation dependent.
166
167``<op>[,<mode>] rx-add-byte``
168    Add a spurious 0x55 byte to the received CEC message, provided
169    the message was 15 bytes long or less. This is useful to test
170    the high-level protocol since spurious bytes should be ignored.
171
172``<op>[,<mode>] rx-remove-byte``
173    Remove the last byte from the received CEC message, provided it
174    was at least 2 bytes long. This is useful to test the high-level
175    protocol since messages that are too short should be ignored.
176
177``<op>[,<mode>] rx-arb-lost <poll>``
178    Generate a POLL message to trigger an Arbitration Lost condition.
179    This command is only allowed for ``<op>`` values of ``next`` or ``all``.
180    As soon as a start bit has been received the CEC adapter will switch
181    to transmit mode and it will transmit a POLL message. By default this is
182    0x0f, but it can also be specified explicitly via the ``<poll>`` argument.
183
184    This command can be used to test the Arbitration Lost condition in
185    the remote CEC transmitter. Arbitration happens when two CEC adapters
186    start sending a message at the same time. In that case the initiator
187    with the most leading zeroes wins and the other transmitter has to
188    stop transmitting ('Arbitration Lost'). This is very hard to test,
189    except by using this error injection command.
190
191    This does not work if the remote CEC transmitter has logical address
192    0 ('TV') since that will always win.
193
194Transmit Messages
195-----------------
196
197``tx-ignore-nack-until-eom``
198    This setting changes the behavior of transmitting CEC messages. Normally
199    as soon as the receiver NACKs a byte the transmit will stop, but the
200    specification also allows that the full message is transmitted and only
201    at the end will the transmitter look at the ACK bit. This is not
202    recommended behavior since there is no point in keeping the CEC bus busy
203    for longer than is strictly needed. Especially given how slow the bus is.
204
205    This setting can be used to test how well a receiver deals with
206    transmitters that ignore NACKs until the very end of the message.
207
208``<op>[,<mode>] tx-no-eom``
209    Don't set the EOM bit. Normally the last byte of the message has the EOM
210    (End-Of-Message) bit set. With this command the transmit will just stop
211    without ever sending an EOM. This can be used to test how a receiver
212    handles this case. Normally receivers have a time-out after which
213    they will go back to the Idle state.
214
215``<op>[,<mode>] tx-early-eom``
216    Set the EOM bit one byte too soon. This obviously only works for messages
217    of two bytes or more. The EOM bit will be set for the second-to-last byte
218    and not for the final byte. The receiver should ignore the last byte in
219    this case. Since the resulting message is likely to be too short for this
220    same reason the whole message is typically ignored. The receiver should be
221    in Idle state after the last byte was transmitted.
222
223``<op>[,<mode>] tx-add-bytes <num>``
224    Append ``<num>`` (1-255) spurious bytes to the message. The extra bytes
225    have the value of the byte position in the message. So if you transmit a
226    two byte message (e.g. a Get CEC Version message) and add 2 bytes, then
227    the full message received by the remote CEC adapter is
228    ``0x40 0x9f 0x02 0x03``.
229
230    This command can be used to test buffer overflows in the receiver. E.g.
231    what does it do when it receives more than the maximum message size of 16
232    bytes.
233
234``<op>[,<mode>] tx-remove-byte``
235    Drop the last byte from the message, provided the message is at least
236    two bytes long. The receiver should ignore messages that are too short.
237
238``<op>[,<mode>] tx-short-bit <bit>``
239    Make this bit period shorter than allowed. The bit position cannot be
240    an Ack bit.  If <op> specifies a specific CEC opcode then the bit position
241    must be at least 18, otherwise the opcode hasn't been received yet.
242    Normally the period of a data bit is between 2.05 and 2.75 milliseconds.
243    With this command the period of this bit is 1.8 milliseconds, this is
244    done by reducing the time the CEC bus is high. This bit period is less
245    than is allowed and the receiver should respond with a Low Drive
246    condition.
247
248    This command is ignored for 0 bits in bit positions 0 to 3. This is
249    because the receiver also looks for an Arbitration Lost condition in
250    those first four bits and it is undefined what will happen if it
251    sees a too-short 0 bit.
252
253``<op>[,<mode>] tx-long-bit <bit>``
254    Make this bit period longer than is valid. The bit position cannot be
255    an Ack bit.  If <op> specifies a specific CEC opcode then the bit position
256    must be at least 18, otherwise the opcode hasn't been received yet.
257    Normally the period of a data bit is between 2.05 and 2.75 milliseconds.
258    With this command the period of this bit is 2.9 milliseconds, this is
259    done by increasing the time the CEC bus is high.
260
261    Even though this bit period is longer than is valid it is undefined what
262    a receiver will do. It might just accept it, or it might time out and
263    return to Idle state. Unfortunately the CEC specification is silent about
264    this.
265
266    This command is ignored for 0 bits in bit positions 0 to 3. This is
267    because the receiver also looks for an Arbitration Lost condition in
268    those first four bits and it is undefined what will happen if it
269    sees a too-long 0 bit.
270
271``<op>[,<mode>] tx-short-start``
272    Make this start bit period shorter than allowed. Normally the period of
273    a start bit is between 4.3 and 4.7 milliseconds. With this command the
274    period of the start bit is 4.1 milliseconds, this is done by reducing
275    the time the CEC bus is high. This start bit period is less than is
276    allowed and the receiver should return to Idle state when this is detected.
277
278``<op>[,<mode>] tx-long-start``
279    Make this start bit period longer than is valid. Normally the period of
280    a start bit is between 4.3 and 4.7 milliseconds. With this command the
281    period of the start bit is 5 milliseconds, this is done by increasing
282    the time the CEC bus is high. This start bit period is more than is
283    valid and the receiver should return to Idle state when this is detected.
284
285    Even though this start bit period is longer than is valid it is undefined
286    what a receiver will do. It might just accept it, or it might time out and
287    return to Idle state. Unfortunately the CEC specification is silent about
288    this.
289
290``<op>[,<mode>] tx-last-bit <bit>``
291    Just stop transmitting after this bit.  If <op> specifies a specific CEC
292    opcode then the bit position must be at least 18, otherwise the opcode
293    hasn't been received yet. This command can be used to test how the receiver
294    reacts when a message just suddenly stops. It should time out and go back
295    to Idle state.
296
297``<op>[,<mode>] tx-low-drive <bit>``
298    Force a Low Drive condition at this bit position. If <op> specifies a
299    specific CEC opcode then the bit position must be at least 18, otherwise
300    the opcode hasn't been received yet. This can be used to test how the
301    receiver handles Low Drive conditions. Note that if this happens at bit
302    positions 0-3 the receiver can interpret this as an Arbitration Lost
303    condition. This is implementation dependent.
304
305Custom Pulses
306-------------
307
308``tx-custom-low-usecs <usecs>``
309    This defines the duration in microseconds that the custom pulse pulls
310    the CEC line low. The default is 1000 microseconds.
311
312``tx-custom-high-usecs <usecs>``
313    This defines the duration in microseconds that the custom pulse keeps the
314    CEC line high (unless another CEC adapter pulls it low in that time).
315    The default is 1000 microseconds. The total period of the custom pulse is
316    ``tx-custom-low-usecs + tx-custom-high-usecs``.
317
318``<op>[,<mode>] tx-custom-bit <bit>``
319    Send the custom bit instead of a regular data bit. The bit position cannot
320    be an Ack bit.  If <op> specifies a specific CEC opcode then the bit
321    position must be at least 18, otherwise the opcode hasn't been received yet.
322
323``<op>[,<mode>] tx-custom-start``
324    Send the custom bit instead of a regular start bit.
325
326``tx-custom-pulse``
327    Transmit a single custom pulse as soon as the CEC bus is idle.
328