[PATCH v2 23/27] staging: unisys: visorbus: Add kerneldoc-style comments for visorbus API

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From: David Binder <david.binder@xxxxxxxxxx>

Adds kerneldoc-style comments for those functions which may be used outside
of the visorbus driver.

Signed-off-by: David Binder <david.binder@xxxxxxxxxx>
Signed-off-by: David Kershner <david.kershner@xxxxxxxxxx>
Reviewed-by: Tim Sell <Timothy.Sell@xxxxxxxxxx>
---
 drivers/staging/unisys/include/visorbus.h       | 127 ++++++++++++++++++++++++
 drivers/staging/unisys/visorbus/visorbus_main.c |  42 --------
 2 files changed, 127 insertions(+), 42 deletions(-)

diff --git a/drivers/staging/unisys/include/visorbus.h b/drivers/staging/unisys/include/visorbus.h
index 2c103e8..99c7beb 100644
--- a/drivers/staging/unisys/include/visorbus.h
+++ b/drivers/staging/unisys/include/visorbus.h
@@ -177,22 +177,149 @@ struct visor_device {
 
 #define to_visor_device(x) container_of(x, struct visor_device, device)
 
+/**
+ * visorbus_register_visor_driver() - registers the provided driver
+ * @struct visor_driver *: the driver to register
+ *
+ * A particular type of visor driver calls this function to register
+ * the driver.  The caller MUST fill in the following fields within the
+ * #drv structure:
+ *     name, version, owner, channel_types, probe, remove
+ *
+ * Here's how the whole Linux bus / driver / device model works.
+ *
+ * At system start-up, the visorbus kernel module is loaded, which registers
+ * visorbus_type as a bus type, using bus_register().
+ *
+ * All kernel modules that support particular device types on a
+ * visorbus bus are loaded.  Each of these kernel modules calls
+ * visorbus_register_visor_driver() in their init functions, passing a
+ * visor_driver struct.  visorbus_register_visor_driver() in turn calls
+ * register_driver(&visor_driver.driver).  This .driver member is
+ * initialized with generic methods (like probe), whose sole responsibility
+ * is to act as a broker for the real methods, which are within the
+ * visor_driver struct.  (This is the way the subclass behavior is
+ * implemented, since visor_driver is essentially a subclass of the
+ * generic driver.)  Whenever a driver_register() happens, core bus code in
+ * the kernel does (see device_attach() in drivers/base/dd.c):
+ *
+ *     for each dev associated with the bus (the bus that driver is on) that
+ *     does not yet have a driver
+ *         if bus.match(dev,newdriver) == yes_matched  ** .match specified
+ *                                                ** during bus_register().
+ *             newdriver.probe(dev)  ** for visor drivers, this will call
+ *                   ** the generic driver.probe implemented in visorbus.c,
+ *                   ** which in turn calls the probe specified within the
+ *                   ** struct visor_driver (which was specified by the
+ *                   ** actual device driver as part of
+ *                   ** visorbus_register_visor_driver()).
+ *
+ * The above dance also happens when a new device appears.
+ * So the question is, how are devices created within the system?
+ * Basically, just call device_add(dev).  See pci_bus_add_devices().
+ * pci_scan_device() shows an example of how to build a device struct.  It
+ * returns the newly-created struct to pci_scan_single_device(), who adds it
+ * to the list of devices at PCIBUS.devices.  That list of devices is what
+ * is traversed by pci_bus_add_devices().
+ *
+ * Return: integer indicating success (zero) or failure (non-zero)
+ */
 int visorbus_register_visor_driver(struct visor_driver *);
+
+/**
+ * visorbus_unregister_visor_driver() - unregisters the provided driver
+ * @struct visor_driver *: the driver to unregister
+ */
 void visorbus_unregister_visor_driver(struct visor_driver *);
+
+/**
+ * visorbus_read_channel() - reads from the designated channel into
+ *                           the provided buffer
+ * @dev:    the device whose channel is read from
+ * @offset: the offset into the channel at which reading starts
+ * @dest:   the destination buffer that is written into from the channel
+ * @nbytes: the number of bytes to read from the channel
+ *
+ * If receiving a message, use the visorchannel_signalremove()
+ * function instead.
+ *
+ * Return: integer indicating success (zero) or failure (non-zero)
+ */
 int visorbus_read_channel(struct visor_device *dev,
 			  unsigned long offset, void *dest,
 			  unsigned long nbytes);
+
+/**
+ * visorbus_write_channel() - writes the provided buffer into the designated
+ *                            channel
+ * @dev:    the device whose channel is written to
+ * @offset: the offset into the channel at which writing starts
+ * @src:    the source buffer that is written into the channel
+ * @nbytes: the number of bytes to write into the channel
+ *
+ * If sending a message, use the visorchannel_signalinsert()
+ * function instead.
+ *
+ * Return: integer indicating success (zero) or failure (non-zero)
+ */
 int visorbus_write_channel(struct visor_device *dev,
 			   unsigned long offset, void *src,
 			   unsigned long nbytes);
+/**
+ * visorbus_enable_channel_interrupts() - enables interrupts on the
+ *                                        designated device
+ * @dev: the device on which to enable interrupts
+ */
 void visorbus_enable_channel_interrupts(struct visor_device *dev);
+
+/**
+ * visorbus_disable_channel_interrupts() - disables interrupts on the
+ *                                         designated device
+ * @dev: the device on which to disable interrupts
+ */
 void visorbus_disable_channel_interrupts(struct visor_device *dev);
 
+/**
+ * visorchannel_signalremove() - removes a message from the designated
+ *                               channel/queue
+ * @channel: the channel the message will be removed from
+ * @queue:   the queue the message will be removed from
+ * @msg:     the message to remove
+ *
+ * Return: boolean indicating whether the removal succeeded or failed
+ */
 bool visorchannel_signalremove(struct visorchannel *channel, u32 queue,
 			       void *msg);
+
+/**
+ * visorchannel_signalinsert() - inserts a message into the designated
+ *                               channel/queue
+ * @channel: the channel the message will be added to
+ * @queue:   the queue the message will be added to
+ * @msg:     the message to insert
+ *
+ * Return: boolean indicating whether the insertion succeeded or failed
+ */
 bool visorchannel_signalinsert(struct visorchannel *channel, u32 queue,
 			       void *msg);
+
+/**
+ * visorchannel_signalempty() - checks if the designated channel/queue
+ *                              contains any messages
+ * @channel: the channel to query
+ * @queue:   the queue in the channel to query
+ *
+ * Return: boolean indicating whether any messages in the designated
+ *         channel/queue are present
+ */
 bool visorchannel_signalempty(struct visorchannel *channel, u32 queue);
+
+/**
+ * visorchannel_get_uuid() - queries the UUID of the designated channel
+ * @channel: the channel to query
+ *
+ * Return: the UUID of the provided channel
+ */
 uuid_le visorchannel_get_uuid(struct visorchannel *channel);
 
 #define BUS_ROOT_DEVICE		UINT_MAX
diff --git a/drivers/staging/unisys/visorbus/visorbus_main.c b/drivers/staging/unisys/visorbus/visorbus_main.c
index 850998e..0a537c7 100644
--- a/drivers/staging/unisys/visorbus/visorbus_main.c
+++ b/drivers/staging/unisys/visorbus/visorbus_main.c
@@ -616,48 +616,6 @@ visordriver_remove_device(struct device *xdev)
 	return 0;
 }
 
-/**
- * A particular type of visor driver calls this function to register
- * the driver.  The caller MUST fill in the following fields within the
- * #drv structure:
- *     name, version, owner, channel_types, probe, remove
- *
- * Here's how the whole Linux bus / driver / device model works.
- *
- * At system start-up, the visorbus kernel module is loaded, which registers
- * visorbus_type as a bus type, using bus_register().
- *
- * All kernel modules that support particular device types on a
- * visorbus bus are loaded.  Each of these kernel modules calls
- * visorbus_register_visor_driver() in their init functions, passing a
- * visor_driver struct.  visorbus_register_visor_driver() in turn calls
- * register_driver(&visor_driver.driver).  This .driver member is
- * initialized with generic methods (like probe), whose sole responsibility
- * is to act as a broker for the real methods, which are within the
- * visor_driver struct.  (This is the way the subclass behavior is
- * implemented, since visor_driver is essentially a subclass of the
- * generic driver.)  Whenever a driver_register() happens, core bus code in
- * the kernel does (see device_attach() in drivers/base/dd.c):
- *
- *     for each dev associated with the bus (the bus that driver is on) that
- *     does not yet have a driver
- *         if bus.match(dev,newdriver) == yes_matched  ** .match specified
- *                                                ** during bus_register().
- *             newdriver.probe(dev)  ** for visor drivers, this will call
- *                   ** the generic driver.probe implemented in visorbus.c,
- *                   ** which in turn calls the probe specified within the
- *                   ** struct visor_driver (which was specified by the
- *                   ** actual device driver as part of
- *                   ** visorbus_register_visor_driver()).
- *
- * The above dance also happens when a new device appears.
- * So the question is, how are devices created within the system?
- * Basically, just call device_add(dev).  See pci_bus_add_devices().
- * pci_scan_device() shows an example of how to build a device struct.  It
- * returns the newly-created struct to pci_scan_single_device(), who adds it
- * to the list of devices at PCIBUS.devices.  That list of devices is what
- * is traversed by pci_bus_add_devices().
- */
 int visorbus_register_visor_driver(struct visor_driver *drv)
 {
 	int rc = 0;
-- 
1.9.1

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