forked from Minki/linux
136 lines
3.9 KiB
Plaintext
136 lines
3.9 KiB
Plaintext
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Intel(R) Management Engine (ME) Client bus API
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===============================================
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Rationale
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=========
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MEI misc character device is useful for dedicated applications to send and receive
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data to the many FW appliance found in Intel's ME from the user space.
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However for some of the ME functionalities it make sense to leverage existing software
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stack and expose them through existing kernel subsystems.
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In order to plug seamlessly into the kernel device driver model we add kernel virtual
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bus abstraction on top of the MEI driver. This allows implementing linux kernel drivers
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for the various MEI features as a stand alone entities found in their respective subsystem.
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Existing device drivers can even potentially be re-used by adding an MEI CL bus layer to
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the existing code.
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MEI CL bus API
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===========
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A driver implementation for an MEI Client is very similar to existing bus
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based device drivers. The driver registers itself as an MEI CL bus driver through
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the mei_cl_driver structure:
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struct mei_cl_driver {
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struct device_driver driver;
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const char *name;
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const struct mei_cl_device_id *id_table;
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int (*probe)(struct mei_cl_device *dev, const struct mei_cl_id *id);
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int (*remove)(struct mei_cl_device *dev);
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};
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struct mei_cl_id {
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char name[MEI_NAME_SIZE];
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kernel_ulong_t driver_info;
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};
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The mei_cl_id structure allows the driver to bind itself against a device name.
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To actually register a driver on the ME Client bus one must call the mei_cl_add_driver()
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API. This is typically called at module init time.
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Once registered on the ME Client bus, a driver will typically try to do some I/O on
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this bus and this should be done through the mei_cl_send() and mei_cl_recv()
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routines. The latter is synchronous (blocks and sleeps until data shows up).
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In order for drivers to be notified of pending events waiting for them (e.g.
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an Rx event) they can register an event handler through the
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mei_cl_register_event_cb() routine. Currently only the MEI_EVENT_RX event
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will trigger an event handler call and the driver implementation is supposed
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to call mei_recv() from the event handler in order to fetch the pending
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received buffers.
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Example
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=======
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As a theoretical example let's pretend the ME comes with a "contact" NFC IP.
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The driver init and exit routines for this device would look like:
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#define CONTACT_DRIVER_NAME "contact"
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static struct mei_cl_device_id contact_mei_cl_tbl[] = {
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{ CONTACT_DRIVER_NAME, },
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/* required last entry */
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{ }
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};
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MODULE_DEVICE_TABLE(mei_cl, contact_mei_cl_tbl);
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static struct mei_cl_driver contact_driver = {
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.id_table = contact_mei_tbl,
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.name = CONTACT_DRIVER_NAME,
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.probe = contact_probe,
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.remove = contact_remove,
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};
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static int contact_init(void)
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{
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int r;
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r = mei_cl_driver_register(&contact_driver);
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if (r) {
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pr_err(CONTACT_DRIVER_NAME ": driver registration failed\n");
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return r;
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}
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return 0;
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}
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static void __exit contact_exit(void)
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{
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mei_cl_driver_unregister(&contact_driver);
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}
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module_init(contact_init);
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module_exit(contact_exit);
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And the driver's simplified probe routine would look like that:
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int contact_probe(struct mei_cl_device *dev, struct mei_cl_device_id *id)
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{
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struct contact_driver *contact;
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[...]
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mei_cl_register_event_cb(dev, contact_event_cb, contact);
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return 0;
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}
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In the probe routine the driver basically registers an ME bus event handler
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which is as close as it can get to registering a threaded IRQ handler.
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The handler implementation will typically call some I/O routine depending on
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the pending events:
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#define MAX_NFC_PAYLOAD 128
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static void contact_event_cb(struct mei_cl_device *dev, u32 events,
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void *context)
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{
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struct contact_driver *contact = context;
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if (events & BIT(MEI_EVENT_RX)) {
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u8 payload[MAX_NFC_PAYLOAD];
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int payload_size;
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payload_size = mei_recv(dev, payload, MAX_NFC_PAYLOAD);
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if (payload_size <= 0)
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return;
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/* Hook to the NFC subsystem */
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nfc_hci_recv_frame(contact->hdev, payload, payload_size);
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}
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}
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