2012-04-11 01:43:08 +08:00
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HCI backend for NFC Core
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Author: Eric Lapuyade, Samuel Ortiz
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Contact: eric.lapuyade@intel.com, samuel.ortiz@intel.com
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General
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-------
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The HCI layer implements much of the ETSI TS 102 622 V10.2.0 specification. It
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enables easy writing of HCI-based NFC drivers. The HCI layer runs as an NFC Core
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backend, implementing an abstract nfc device and translating NFC Core API
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to HCI commands and events.
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HCI
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---
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HCI registers as an nfc device with NFC Core. Requests coming from userspace are
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routed through netlink sockets to NFC Core and then to HCI. From this point,
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they are translated in a sequence of HCI commands sent to the HCI layer in the
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host controller (the chip). The sending context blocks while waiting for the
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response to arrive.
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HCI events can also be received from the host controller. They will be handled
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and a translation will be forwarded to NFC Core as needed.
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HCI uses 2 execution contexts:
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2012-05-07 18:31:17 +08:00
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- one for executing commands : nfc_hci_msg_tx_work(). Only one command
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2012-04-11 01:43:08 +08:00
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can be executing at any given moment.
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2012-05-07 18:31:17 +08:00
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- one for dispatching received events and commands : nfc_hci_msg_rx_work().
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2012-04-11 01:43:08 +08:00
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HCI Session initialization:
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---------------------------
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The Session initialization is an HCI standard which must unfortunately
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support proprietary gates. This is the reason why the driver will pass a list
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of proprietary gates that must be part of the session. HCI will ensure all
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those gates have pipes connected when the hci device is set up.
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HCI Gates and Pipes
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-------------------
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A gate defines the 'port' where some service can be found. In order to access
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a service, one must create a pipe to that gate and open it. In this
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implementation, pipes are totally hidden. The public API only knows gates.
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This is consistent with the driver need to send commands to proprietary gates
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without knowing the pipe connected to it.
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Driver interface
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----------------
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A driver would normally register itself with HCI and provide the following
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entry points:
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struct nfc_hci_ops {
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int (*open)(struct nfc_hci_dev *hdev);
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void (*close)(struct nfc_hci_dev *hdev);
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int (*hci_ready) (struct nfc_hci_dev *hdev);
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int (*xmit)(struct nfc_hci_dev *hdev, struct sk_buff *skb);
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int (*start_poll)(struct nfc_hci_dev *hdev, u32 protocols);
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int (*target_from_gate)(struct nfc_hci_dev *hdev, u8 gate,
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struct nfc_target *target);
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int (*complete_target_discovered) (struct nfc_hci_dev *hdev, u8 gate,
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struct nfc_target *target);
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int (*data_exchange) (struct nfc_hci_dev *hdev,
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struct nfc_target *target,
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struct sk_buff *skb, struct sk_buff **res_skb);
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int (*check_presence)(struct nfc_hci_dev *hdev,
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struct nfc_target *target);
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};
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2012-05-07 18:31:17 +08:00
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- open() and close() shall turn the hardware on and off.
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- hci_ready() is an optional entry point that is called right after the hci
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session has been set up. The driver can use it to do additional initialization
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that must be performed using HCI commands.
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- xmit() shall simply write a frame to the chip.
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- start_poll() is an optional entrypoint that shall set the hardware in polling
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mode. This must be implemented only if the hardware uses proprietary gates or a
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mechanism slightly different from the HCI standard.
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- target_from_gate() is an optional entrypoint to return the nfc protocols
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corresponding to a proprietary gate.
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- complete_target_discovered() is an optional entry point to let the driver
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perform additional proprietary processing necessary to auto activate the
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discovered target.
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- data_exchange() must be implemented by the driver if proprietary HCI commands
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are required to send data to the tag. Some tag types will require custom
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commands, others can be written to using the standard HCI commands. The driver
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can check the tag type and either do proprietary processing, or return 1 to ask
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for standard processing.
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- check_presence() is an optional entry point that will be called regularly
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by the core to check that an activated tag is still in the field. If this is
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not implemented, the core will not be able to push tag_lost events to the user
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space
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On the rx path, the driver is responsible to push incoming HCP frames to HCI
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using nfc_hci_recv_frame(). HCI will take care of re-aggregation and handling
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This must be done from a context that can sleep.
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SHDLC
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-----
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Most chips use shdlc to ensure integrity and delivery ordering of the HCP
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frames between the host controller (the chip) and hosts (entities connected
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to the chip, like the cpu). In order to simplify writing the driver, an shdlc
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layer is available for use by the driver.
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When used, the driver actually registers with shdlc, and shdlc will register
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with HCI. HCI sees shdlc as the driver and thus send its HCP frames
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through shdlc->xmit.
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SHDLC adds a new execution context (nfc_shdlc_sm_work()) to run its state
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machine and handle both its rx and tx path.
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Included Drivers
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----------------
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An HCI based driver for an NXP PN544, connected through I2C bus, and using
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shdlc is included.
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Execution Contexts
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------------------
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The execution contexts are the following:
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- IRQ handler (IRQH):
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fast, cannot sleep. stores incoming frames into an shdlc rx queue
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- SHDLC State Machine worker (SMW)
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handles shdlc rx & tx queues. Dispatches HCI cmd responses.
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- HCI Tx Cmd worker (MSGTXWQ)
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Serializes execution of HCI commands. Completes execution in case of response
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timeout.
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- HCI Rx worker (MSGRXWQ)
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Dispatches incoming HCI commands or events.
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- Syscall context from a userspace call (SYSCALL)
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Any entrypoint in HCI called from NFC Core
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Workflow executing an HCI command (using shdlc)
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-----------------------------------------------
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Executing an HCI command can easily be performed synchronously using the
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following API:
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int nfc_hci_send_cmd (struct nfc_hci_dev *hdev, u8 gate, u8 cmd,
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const u8 *param, size_t param_len, struct sk_buff **skb)
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The API must be invoked from a context that can sleep. Most of the time, this
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will be the syscall context. skb will return the result that was received in
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the response.
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Internally, execution is asynchronous. So all this API does is to enqueue the
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HCI command, setup a local wait queue on stack, and wait_event() for completion.
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The wait is not interruptible because it is guaranteed that the command will
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complete after some short timeout anyway.
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MSGTXWQ context will then be scheduled and invoke nfc_hci_msg_tx_work().
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This function will dequeue the next pending command and send its HCP fragments
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to the lower layer which happens to be shdlc. It will then start a timer to be
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able to complete the command with a timeout error if no response arrive.
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SMW context gets scheduled and invokes nfc_shdlc_sm_work(). This function
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handles shdlc framing in and out. It uses the driver xmit to send frames and
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receives incoming frames in an skb queue filled from the driver IRQ handler.
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SHDLC I(nformation) frames payload are HCP fragments. They are aggregated to
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form complete HCI frames, which can be a response, command, or event.
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HCI Responses are dispatched immediately from this context to unblock
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waiting command execution. Response processing involves invoking the completion
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callback that was provided by nfc_hci_msg_tx_work() when it sent the command.
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The completion callback will then wake the syscall context.
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Workflow receiving an HCI event or command
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------------------------------------------
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HCI commands or events are not dispatched from SMW context. Instead, they are
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queued to HCI rx_queue and will be dispatched from HCI rx worker
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context (MSGRXWQ). This is done this way to allow a cmd or event handler
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to also execute other commands (for example, handling the
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NFC_HCI_EVT_TARGET_DISCOVERED event from PN544 requires to issue an
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ANY_GET_PARAMETER to the reader A gate to get information on the target
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that was discovered).
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Typically, such an event will be propagated to NFC Core from MSGRXWQ context.
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