Documentation/nfc/nfc-hci.txt - pub/scm/linux/kernel/git/klassert/ipsec-next - Git at Google

 HCI backend for NFC Core

 Author: Eric Lapuyade, Samuel Ortiz
 Contact: eric.lapuyade@intel.com, samuel.ortiz@intel.com

 General
 -------

 The HCI layer implements much of the ETSI TS 102 622 V10.2.0 specification. It
 enables easy writing of HCI-based NFC drivers. The HCI layer runs as an NFC Core
 backend, implementing an abstract nfc device and translating NFC Core API
 to HCI commands and events.

 HCI
 ---

 HCI registers as an nfc device with NFC Core. Requests coming from userspace are
 routed through netlink sockets to NFC Core and then to HCI. From this point,
 they are translated in a sequence of HCI commands sent to the HCI layer in the
 host controller (the chip). The sending context blocks while waiting for the
 response to arrive.
 HCI events can also be received from the host controller. They will be handled
 and a translation will be forwarded to NFC Core as needed.
 HCI uses 2 execution contexts:
 - one for executing commands : nfc_hci_msg_tx_work(). Only one command
 can be executing at any given moment.
 - one for dispatching received events and commands : nfc_hci_msg_rx_work().

 HCI Session initialization:
 ---------------------------

 The Session initialization is an HCI standard which must unfortunately
 support proprietary gates. This is the reason why the driver will pass a list
 of proprietary gates that must be part of the session. HCI will ensure all
 those gates have pipes connected when the hci device is set up.

 HCI Gates and Pipes
 -------------------

 A gate defines the 'port' where some service can be found. In order to access
 a service, one must create a pipe to that gate and open it. In this
 implementation, pipes are totally hidden. The public API only knows gates.
 This is consistent with the driver need to send commands to proprietary gates
 without knowing the pipe connected to it.

 Driver interface
 ----------------

 A driver would normally register itself with HCI and provide the following
 entry points:

 struct nfc_hci_ops {
 	int (*open)(struct nfc_hci_dev *hdev);
 	void (*close)(struct nfc_hci_dev *hdev);
 	int (*hci_ready) (struct nfc_hci_dev *hdev);
 	int (*xmit)(struct nfc_hci_dev *hdev, struct sk_buff *skb);
 	int (*start_poll)(struct nfc_hci_dev *hdev, u32 protocols);
 	int (*target_from_gate)(struct nfc_hci_dev *hdev, u8 gate,
 				struct nfc_target *target);
 	int (*complete_target_discovered) (struct nfc_hci_dev *hdev, u8 gate,
 					   struct nfc_target *target);
 	int (*data_exchange) (struct nfc_hci_dev *hdev,
 			      struct nfc_target *target,
 			      struct sk_buff *skb, struct sk_buff **res_skb);
 	int (*check_presence)(struct nfc_hci_dev *hdev,
 			      struct nfc_target *target);
 };

 - open() and close() shall turn the hardware on and off.
 - hci_ready() is an optional entry point that is called right after the hci
 session has been set up. The driver can use it to do additional initialization
 that must be performed using HCI commands.
 - xmit() shall simply write a frame to the chip.
 - start_poll() is an optional entrypoint that shall set the hardware in polling
 mode. This must be implemented only if the hardware uses proprietary gates or a
 mechanism slightly different from the HCI standard.
 - target_from_gate() is an optional entrypoint to return the nfc protocols
 corresponding to a proprietary gate.
 - complete_target_discovered() is an optional entry point to let the driver
 perform additional proprietary processing necessary to auto activate the
 discovered target.
 - data_exchange() must be implemented by the driver if proprietary HCI commands
 are required to send data to the tag. Some tag types will require custom
 commands, others can be written to using the standard HCI commands. The driver
 can check the tag type and either do proprietary processing, or return 1 to ask
 for standard processing.
 - check_presence() is an optional entry point that will be called regularly
 by the core to check that an activated tag is still in the field. If this is
 not implemented, the core will not be able to push tag_lost events to the user
 space

 On the rx path, the driver is responsible to push incoming HCP frames to HCI
 using nfc_hci_recv_frame(). HCI will take care of re-aggregation and handling
 This must be done from a context that can sleep.

 SHDLC
 -----

 Most chips use shdlc to ensure integrity and delivery ordering of the HCP
 frames between the host controller (the chip) and hosts (entities connected
 to the chip, like the cpu). In order to simplify writing the driver, an shdlc
 layer is available for use by the driver.
 When used, the driver actually registers with shdlc, and shdlc will register
 with HCI. HCI sees shdlc as the driver and thus send its HCP frames
 through shdlc->xmit.
 SHDLC adds a new execution context (nfc_shdlc_sm_work()) to run its state
 machine and handle both its rx and tx path.

 Included Drivers
 ----------------

 An HCI based driver for an NXP PN544, connected through I2C bus, and using
 shdlc is included.

 Execution Contexts
 ------------------

 The execution contexts are the following:
 - IRQ handler (IRQH):
 fast, cannot sleep. stores incoming frames into an shdlc rx queue

 - SHDLC State Machine worker (SMW)
 handles shdlc rx & tx queues. Dispatches HCI cmd responses.

 - HCI Tx Cmd worker (MSGTXWQ)
 Serializes execution of HCI commands. Completes execution in case of response
 timeout.

 - HCI Rx worker (MSGRXWQ)
 Dispatches incoming HCI commands or events.

 - Syscall context from a userspace call (SYSCALL)
 Any entrypoint in HCI called from NFC Core

 Workflow executing an HCI command (using shdlc)
 -----------------------------------------------

 Executing an HCI command can easily be performed synchronously using the
 following API:

 int nfc_hci_send_cmd (struct nfc_hci_dev *hdev, u8 gate, u8 cmd,
 			const u8 *param, size_t param_len, struct sk_buff **skb)

 The API must be invoked from a context that can sleep. Most of the time, this
 will be the syscall context. skb will return the result that was received in
 the response.

 Internally, execution is asynchronous. So all this API does is to enqueue the
 HCI command, setup a local wait queue on stack, and wait_event() for completion.
 The wait is not interruptible because it is guaranteed that the command will
 complete after some short timeout anyway.

 MSGTXWQ context will then be scheduled and invoke nfc_hci_msg_tx_work().
 This function will dequeue the next pending command and send its HCP fragments
 to the lower layer which happens to be shdlc. It will then start a timer to be
 able to complete the command with a timeout error if no response arrive.

 SMW context gets scheduled and invokes nfc_shdlc_sm_work(). This function
 handles shdlc framing in and out. It uses the driver xmit to send frames and
 receives incoming frames in an skb queue filled from the driver IRQ handler.
 SHDLC I(nformation) frames payload are HCP fragments. They are aggregated to
 form complete HCI frames, which can be a response, command, or event.

 HCI Responses are dispatched immediately from this context to unblock
 waiting command execution. Response processing involves invoking the completion
 callback that was provided by nfc_hci_msg_tx_work() when it sent the command.
 The completion callback will then wake the syscall context.

 Workflow receiving an HCI event or command
 ------------------------------------------

 HCI commands or events are not dispatched from SMW context. Instead, they are
 queued to HCI rx_queue and will be dispatched from HCI rx worker
 context (MSGRXWQ). This is done this way to allow a cmd or event handler
 to also execute other commands (for example, handling the
 NFC_HCI_EVT_TARGET_DISCOVERED event from PN544 requires to issue an
 ANY_GET_PARAMETER to the reader A gate to get information on the target
 that was discovered).

 Typically, such an event will be propagated to NFC Core from MSGRXWQ context.
	HCI backend for NFC Core

	Author: Eric Lapuyade, Samuel Ortiz
	Contact: eric.lapuyade@intel.com, samuel.ortiz@intel.com

	General
	-------

	The HCI layer implements much of the ETSI TS 102 622 V10.2.0 specification. It
	enables easy writing of HCI-based NFC drivers. The HCI layer runs as an NFC Core
	backend, implementing an abstract nfc device and translating NFC Core API
	to HCI commands and events.

	HCI
	---

	HCI registers as an nfc device with NFC Core. Requests coming from userspace are
	routed through netlink sockets to NFC Core and then to HCI. From this point,
	they are translated in a sequence of HCI commands sent to the HCI layer in the
	host controller (the chip). The sending context blocks while waiting for the
	response to arrive.
	HCI events can also be received from the host controller. They will be handled
	and a translation will be forwarded to NFC Core as needed.
	HCI uses 2 execution contexts:
	- one for executing commands : nfc_hci_msg_tx_work(). Only one command
	can be executing at any given moment.
	- one for dispatching received events and commands : nfc_hci_msg_rx_work().

	HCI Session initialization:
	---------------------------

	The Session initialization is an HCI standard which must unfortunately
	support proprietary gates. This is the reason why the driver will pass a list
	of proprietary gates that must be part of the session. HCI will ensure all
	those gates have pipes connected when the hci device is set up.

	HCI Gates and Pipes
	-------------------

	A gate defines the 'port' where some service can be found. In order to access
	a service, one must create a pipe to that gate and open it. In this
	implementation, pipes are totally hidden. The public API only knows gates.
	This is consistent with the driver need to send commands to proprietary gates
	without knowing the pipe connected to it.

	Driver interface
	----------------

	A driver would normally register itself with HCI and provide the following
	entry points:

	struct nfc_hci_ops {
	int (open)(struct nfc_hci_dev hdev);
	void (close)(struct nfc_hci_dev hdev);
	int (hci_ready) (struct nfc_hci_dev hdev);
	int (xmit)(struct nfc_hci_dev hdev, struct sk_buff *skb);
	int (start_poll)(struct nfc_hci_dev hdev, u32 protocols);
	int (target_from_gate)(struct nfc_hci_dev hdev, u8 gate,
	struct nfc_target *target);
	int (complete_target_discovered) (struct nfc_hci_dev hdev, u8 gate,
	struct nfc_target *target);
	int (data_exchange) (struct nfc_hci_dev hdev,
	struct nfc_target *target,
	struct sk_buff skb, struct sk_buff *res_skb);
	int (check_presence)(struct nfc_hci_dev hdev,
	struct nfc_target *target);
	};

	- open() and close() shall turn the hardware on and off.
	- hci_ready() is an optional entry point that is called right after the hci
	session has been set up. The driver can use it to do additional initialization
	that must be performed using HCI commands.
	- xmit() shall simply write a frame to the chip.
	- start_poll() is an optional entrypoint that shall set the hardware in polling
	mode. This must be implemented only if the hardware uses proprietary gates or a
	mechanism slightly different from the HCI standard.
	- target_from_gate() is an optional entrypoint to return the nfc protocols
	corresponding to a proprietary gate.
	- complete_target_discovered() is an optional entry point to let the driver
	perform additional proprietary processing necessary to auto activate the
	discovered target.
	- data_exchange() must be implemented by the driver if proprietary HCI commands
	are required to send data to the tag. Some tag types will require custom
	commands, others can be written to using the standard HCI commands. The driver
	can check the tag type and either do proprietary processing, or return 1 to ask
	for standard processing.
	- check_presence() is an optional entry point that will be called regularly
	by the core to check that an activated tag is still in the field. If this is
	not implemented, the core will not be able to push tag_lost events to the user
	space

	On the rx path, the driver is responsible to push incoming HCP frames to HCI
	using nfc_hci_recv_frame(). HCI will take care of re-aggregation and handling
	This must be done from a context that can sleep.

	SHDLC
	-----

	Most chips use shdlc to ensure integrity and delivery ordering of the HCP
	frames between the host controller (the chip) and hosts (entities connected
	to the chip, like the cpu). In order to simplify writing the driver, an shdlc
	layer is available for use by the driver.
	When used, the driver actually registers with shdlc, and shdlc will register
	with HCI. HCI sees shdlc as the driver and thus send its HCP frames
	through shdlc->xmit.
	SHDLC adds a new execution context (nfc_shdlc_sm_work()) to run its state
	machine and handle both its rx and tx path.

	Included Drivers
	----------------

	An HCI based driver for an NXP PN544, connected through I2C bus, and using
	shdlc is included.

	Execution Contexts
	------------------

	The execution contexts are the following:
	- IRQ handler (IRQH):
	fast, cannot sleep. stores incoming frames into an shdlc rx queue

	- SHDLC State Machine worker (SMW)
	handles shdlc rx & tx queues. Dispatches HCI cmd responses.

	- HCI Tx Cmd worker (MSGTXWQ)
	Serializes execution of HCI commands. Completes execution in case of response
	timeout.

	- HCI Rx worker (MSGRXWQ)
	Dispatches incoming HCI commands or events.

	- Syscall context from a userspace call (SYSCALL)
	Any entrypoint in HCI called from NFC Core

	Workflow executing an HCI command (using shdlc)
	-----------------------------------------------

	Executing an HCI command can easily be performed synchronously using the
	following API:

	int nfc_hci_send_cmd (struct nfc_hci_dev *hdev, u8 gate, u8 cmd,
	const u8 param, size_t param_len, struct sk_buff *skb)

	The API must be invoked from a context that can sleep. Most of the time, this
	will be the syscall context. skb will return the result that was received in
	the response.

	Internally, execution is asynchronous. So all this API does is to enqueue the
	HCI command, setup a local wait queue on stack, and wait_event() for completion.
	The wait is not interruptible because it is guaranteed that the command will
	complete after some short timeout anyway.

	MSGTXWQ context will then be scheduled and invoke nfc_hci_msg_tx_work().
	This function will dequeue the next pending command and send its HCP fragments
	to the lower layer which happens to be shdlc. It will then start a timer to be
	able to complete the command with a timeout error if no response arrive.

	SMW context gets scheduled and invokes nfc_shdlc_sm_work(). This function
	handles shdlc framing in and out. It uses the driver xmit to send frames and
	receives incoming frames in an skb queue filled from the driver IRQ handler.
	SHDLC I(nformation) frames payload are HCP fragments. They are aggregated to
	form complete HCI frames, which can be a response, command, or event.

	HCI Responses are dispatched immediately from this context to unblock
	waiting command execution. Response processing involves invoking the completion
	callback that was provided by nfc_hci_msg_tx_work() when it sent the command.
	The completion callback will then wake the syscall context.

	Workflow receiving an HCI event or command
	------------------------------------------

	HCI commands or events are not dispatched from SMW context. Instead, they are
	queued to HCI rx_queue and will be dispatched from HCI rx worker
	context (MSGRXWQ). This is done this way to allow a cmd or event handler
	to also execute other commands (for example, handling the
	NFC_HCI_EVT_TARGET_DISCOVERED event from PN544 requires to issue an
	ANY_GET_PARAMETER to the reader A gate to get information on the target
	that was discovered).

	Typically, such an event will be propagated to NFC Core from MSGRXWQ context.