nfc.txt 5.2 KB

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  1. Linux NFC subsystem
  2. ===================
  3. The Near Field Communication (NFC) subsystem is required to standardize the
  4. NFC device drivers development and to create an unified userspace interface.
  5. This document covers the architecture overview, the device driver interface
  6. description and the userspace interface description.
  7. Architecture overview
  8. ---------------------
  9. The NFC subsystem is responsible for:
  10. - NFC adapters management;
  11. - Polling for targets;
  12. - Low-level data exchange;
  13. The subsystem is divided in some parts. The 'core' is responsible for
  14. providing the device driver interface. On the other side, it is also
  15. responsible for providing an interface to control operations and low-level
  16. data exchange.
  17. The control operations are available to userspace via generic netlink.
  18. The low-level data exchange interface is provided by the new socket family
  19. PF_NFC. The NFC_SOCKPROTO_RAW performs raw communication with NFC targets.
  20. +--------------------------------------+
  21. | USER SPACE |
  22. +--------------------------------------+
  23. ^ ^
  24. | low-level | control
  25. | data exchange | operations
  26. | |
  27. | v
  28. | +-----------+
  29. | AF_NFC | netlink |
  30. | socket +-----------+
  31. | raw ^
  32. | |
  33. v v
  34. +---------+ +-----------+
  35. | rawsock | <--------> | core |
  36. +---------+ +-----------+
  37. ^
  38. |
  39. v
  40. +-----------+
  41. | driver |
  42. +-----------+
  43. Device Driver Interface
  44. -----------------------
  45. When registering on the NFC subsystem, the device driver must inform the core
  46. of the set of supported NFC protocols and the set of ops callbacks. The ops
  47. callbacks that must be implemented are the following:
  48. * start_poll - setup the device to poll for targets
  49. * stop_poll - stop on progress polling operation
  50. * activate_target - select and initialize one of the targets found
  51. * deactivate_target - deselect and deinitialize the selected target
  52. * data_exchange - send data and receive the response (transceive operation)
  53. Userspace interface
  54. --------------------
  55. The userspace interface is divided in control operations and low-level data
  56. exchange operation.
  57. CONTROL OPERATIONS:
  58. Generic netlink is used to implement the interface to the control operations.
  59. The operations are composed by commands and events, all listed below:
  60. * NFC_CMD_GET_DEVICE - get specific device info or dump the device list
  61. * NFC_CMD_START_POLL - setup a specific device to polling for targets
  62. * NFC_CMD_STOP_POLL - stop the polling operation in a specific device
  63. * NFC_CMD_GET_TARGET - dump the list of targets found by a specific device
  64. * NFC_EVENT_DEVICE_ADDED - reports an NFC device addition
  65. * NFC_EVENT_DEVICE_REMOVED - reports an NFC device removal
  66. * NFC_EVENT_TARGETS_FOUND - reports START_POLL results when 1 or more targets
  67. are found
  68. The user must call START_POLL to poll for NFC targets, passing the desired NFC
  69. protocols through NFC_ATTR_PROTOCOLS attribute. The device remains in polling
  70. state until it finds any target. However, the user can stop the polling
  71. operation by calling STOP_POLL command. In this case, it will be checked if
  72. the requester of STOP_POLL is the same of START_POLL.
  73. If the polling operation finds one or more targets, the event TARGETS_FOUND is
  74. sent (including the device id). The user must call GET_TARGET to get the list of
  75. all targets found by such device. Each reply message has target attributes with
  76. relevant information such as the supported NFC protocols.
  77. All polling operations requested through one netlink socket are stopped when
  78. it's closed.
  79. LOW-LEVEL DATA EXCHANGE:
  80. The userspace must use PF_NFC sockets to perform any data communication with
  81. targets. All NFC sockets use AF_NFC:
  82. struct sockaddr_nfc {
  83. sa_family_t sa_family;
  84. __u32 dev_idx;
  85. __u32 target_idx;
  86. __u32 nfc_protocol;
  87. };
  88. To establish a connection with one target, the user must create an
  89. NFC_SOCKPROTO_RAW socket and call the 'connect' syscall with the sockaddr_nfc
  90. struct correctly filled. All information comes from NFC_EVENT_TARGETS_FOUND
  91. netlink event. As a target can support more than one NFC protocol, the user
  92. must inform which protocol it wants to use.
  93. Internally, 'connect' will result in an activate_target call to the driver.
  94. When the socket is closed, the target is deactivated.
  95. The data format exchanged through the sockets is NFC protocol dependent. For
  96. instance, when communicating with MIFARE tags, the data exchanged are MIFARE
  97. commands and their responses.
  98. The first received package is the response to the first sent package and so
  99. on. In order to allow valid "empty" responses, every data received has a NULL
  100. header of 1 byte.