fault-codes 4.9 KB

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  1. This is a summary of the most important conventions for use of fault
  2. codes in the I2C/SMBus stack.
  3. A "Fault" is not always an "Error"
  4. ----------------------------------
  5. Not all fault reports imply errors; "page faults" should be a familiar
  6. example. Software often retries idempotent operations after transient
  7. faults. There may be fancier recovery schemes that are appropriate in
  8. some cases, such as re-initializing (and maybe resetting). After such
  9. recovery, triggered by a fault report, there is no error.
  10. In a similar way, sometimes a "fault" code just reports one defined
  11. result for an operation ... it doesn't indicate that anything is wrong
  12. at all, just that the outcome wasn't on the "golden path".
  13. In short, your I2C driver code may need to know these codes in order
  14. to respond correctly. Other code may need to rely on YOUR code reporting
  15. the right fault code, so that it can (in turn) behave correctly.
  16. I2C and SMBus fault codes
  17. -------------------------
  18. These are returned as negative numbers from most calls, with zero or
  19. some positive number indicating a non-fault return. The specific
  20. numbers associated with these symbols differ between architectures,
  21. though most Linux systems use <asm-generic/errno*.h> numbering.
  22. Note that the descriptions here are not exhaustive. There are other
  23. codes that may be returned, and other cases where these codes should
  24. be returned. However, drivers should not return other codes for these
  25. cases (unless the hardware doesn't provide unique fault reports).
  26. Also, codes returned by adapter probe methods follow rules which are
  27. specific to their host bus (such as PCI, or the platform bus).
  28. EAGAIN
  29. Returned by I2C adapters when they lose arbitration in master
  30. transmit mode: some other master was transmitting different
  31. data at the same time.
  32. Also returned when trying to invoke an I2C operation in an
  33. atomic context, when some task is already using that I2C bus
  34. to execute some other operation.
  35. EBADMSG
  36. Returned by SMBus logic when an invalid Packet Error Code byte
  37. is received. This code is a CRC covering all bytes in the
  38. transaction, and is sent before the terminating STOP. This
  39. fault is only reported on read transactions; the SMBus slave
  40. may have a way to report PEC mismatches on writes from the
  41. host. Note that even if PECs are in use, you should not rely
  42. on these as the only way to detect incorrect data transfers.
  43. EBUSY
  44. Returned by SMBus adapters when the bus was busy for longer
  45. than allowed. This usually indicates some device (maybe the
  46. SMBus adapter) needs some fault recovery (such as resetting),
  47. or that the reset was attempted but failed.
  48. EINVAL
  49. This rather vague error means an invalid parameter has been
  50. detected before any I/O operation was started. Use a more
  51. specific fault code when you can.
  52. EIO
  53. This rather vague error means something went wrong when
  54. performing an I/O operation. Use a more specific fault
  55. code when you can.
  56. ENODEV
  57. Returned by driver probe() methods. This is a bit more
  58. specific than ENXIO, implying the problem isn't with the
  59. address, but with the device found there. Driver probes
  60. may verify the device returns *correct* responses, and
  61. return this as appropriate. (The driver core will warn
  62. about probe faults other than ENXIO and ENODEV.)
  63. ENOMEM
  64. Returned by any component that can't allocate memory when
  65. it needs to do so.
  66. ENXIO
  67. Returned by I2C adapters to indicate that the address phase
  68. of a transfer didn't get an ACK. While it might just mean
  69. an I2C device was temporarily not responding, usually it
  70. means there's nothing listening at that address.
  71. Returned by driver probe() methods to indicate that they
  72. found no device to bind to. (ENODEV may also be used.)
  73. EOPNOTSUPP
  74. Returned by an adapter when asked to perform an operation
  75. that it doesn't, or can't, support.
  76. For example, this would be returned when an adapter that
  77. doesn't support SMBus block transfers is asked to execute
  78. one. In that case, the driver making that request should
  79. have verified that functionality was supported before it
  80. made that block transfer request.
  81. Similarly, if an I2C adapter can't execute all legal I2C
  82. messages, it should return this when asked to perform a
  83. transaction it can't. (These limitations can't be seen in
  84. the adapter's functionality mask, since the assumption is
  85. that if an adapter supports I2C it supports all of I2C.)
  86. EPROTO
  87. Returned when slave does not conform to the relevant I2C
  88. or SMBus (or chip-specific) protocol specifications. One
  89. case is when the length of an SMBus block data response
  90. (from the SMBus slave) is outside the range 1-32 bytes.
  91. ETIMEDOUT
  92. This is returned by drivers when an operation took too much
  93. time, and was aborted before it completed.
  94. SMBus adapters may return it when an operation took more
  95. time than allowed by the SMBus specification; for example,
  96. when a slave stretches clocks too far. I2C has no such
  97. timeouts, but it's normal for I2C adapters to impose some
  98. arbitrary limits (much longer than SMBus!) too.