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Some watchdogs require a minimum time between heartbeats. Examples are the watchdogs in DA9062 and AT91SAM9x. Signed-off-by: Guenter Roeck <linux@roeck-us.net> Signed-off-by: Wim Van Sebroeck <wim@iguana.be>
266 lines
13 KiB
Plaintext
266 lines
13 KiB
Plaintext
The Linux WatchDog Timer Driver Core kernel API.
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===============================================
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Last reviewed: 12-Feb-2013
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Wim Van Sebroeck <wim@iguana.be>
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Introduction
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------------
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This document does not describe what a WatchDog Timer (WDT) Driver or Device is.
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It also does not describe the API which can be used by user space to communicate
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with a WatchDog Timer. If you want to know this then please read the following
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file: Documentation/watchdog/watchdog-api.txt .
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So what does this document describe? It describes the API that can be used by
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WatchDog Timer Drivers that want to use the WatchDog Timer Driver Core
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Framework. This framework provides all interfacing towards user space so that
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the same code does not have to be reproduced each time. This also means that
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a watchdog timer driver then only needs to provide the different routines
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(operations) that control the watchdog timer (WDT).
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The API
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-------
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Each watchdog timer driver that wants to use the WatchDog Timer Driver Core
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must #include <linux/watchdog.h> (you would have to do this anyway when
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writing a watchdog device driver). This include file contains following
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register/unregister routines:
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extern int watchdog_register_device(struct watchdog_device *);
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extern void watchdog_unregister_device(struct watchdog_device *);
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The watchdog_register_device routine registers a watchdog timer device.
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The parameter of this routine is a pointer to a watchdog_device structure.
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This routine returns zero on success and a negative errno code for failure.
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The watchdog_unregister_device routine deregisters a registered watchdog timer
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device. The parameter of this routine is the pointer to the registered
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watchdog_device structure.
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The watchdog subsystem includes an registration deferral mechanism,
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which allows you to register an watchdog as early as you wish during
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the boot process.
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The watchdog device structure looks like this:
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struct watchdog_device {
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int id;
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struct device *parent;
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const struct attribute_group **groups;
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const struct watchdog_info *info;
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const struct watchdog_ops *ops;
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unsigned int bootstatus;
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unsigned int timeout;
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unsigned int min_timeout;
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unsigned int max_timeout;
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unsigned int min_hw_heartbeat_ms;
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unsigned int max_hw_heartbeat_ms;
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struct notifier_block reboot_nb;
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struct notifier_block restart_nb;
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void *driver_data;
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struct watchdog_core_data *wd_data;
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unsigned long status;
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struct list_head deferred;
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};
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It contains following fields:
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* id: set by watchdog_register_device, id 0 is special. It has both a
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/dev/watchdog0 cdev (dynamic major, minor 0) as well as the old
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/dev/watchdog miscdev. The id is set automatically when calling
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watchdog_register_device.
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* parent: set this to the parent device (or NULL) before calling
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watchdog_register_device.
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* groups: List of sysfs attribute groups to create when creating the watchdog
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device.
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* info: a pointer to a watchdog_info structure. This structure gives some
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additional information about the watchdog timer itself. (Like it's unique name)
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* ops: a pointer to the list of watchdog operations that the watchdog supports.
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* timeout: the watchdog timer's timeout value (in seconds).
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This is the time after which the system will reboot if user space does
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not send a heartbeat request if WDOG_ACTIVE is set.
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* min_timeout: the watchdog timer's minimum timeout value (in seconds).
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If set, the minimum configurable value for 'timeout'.
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* max_timeout: the watchdog timer's maximum timeout value (in seconds),
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as seen from userspace. If set, the maximum configurable value for
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'timeout'. Not used if max_hw_heartbeat_ms is non-zero.
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* min_hw_heartbeat_ms: Minimum time between heartbeats sent to the chip,
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in milli-seconds.
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* max_hw_heartbeat_ms: Maximum hardware heartbeat, in milli-seconds.
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If set, the infrastructure will send heartbeats to the watchdog driver
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if 'timeout' is larger than max_hw_heartbeat_ms, unless WDOG_ACTIVE
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is set and userspace failed to send a heartbeat for at least 'timeout'
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seconds. max_hw_heartbeat_ms must be set if a driver does not implement
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the stop function.
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* reboot_nb: notifier block that is registered for reboot notifications, for
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internal use only. If the driver calls watchdog_stop_on_reboot, watchdog core
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will stop the watchdog on such notifications.
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* restart_nb: notifier block that is registered for machine restart, for
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internal use only. If a watchdog is capable of restarting the machine, it
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should define ops->restart. Priority can be changed through
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watchdog_set_restart_priority.
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* bootstatus: status of the device after booting (reported with watchdog
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WDIOF_* status bits).
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* driver_data: a pointer to the drivers private data of a watchdog device.
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This data should only be accessed via the watchdog_set_drvdata and
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watchdog_get_drvdata routines.
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* wd_data: a pointer to watchdog core internal data.
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* status: this field contains a number of status bits that give extra
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information about the status of the device (Like: is the watchdog timer
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running/active, or is the nowayout bit set).
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* deferred: entry in wtd_deferred_reg_list which is used to
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register early initialized watchdogs.
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The list of watchdog operations is defined as:
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struct watchdog_ops {
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struct module *owner;
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/* mandatory operations */
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int (*start)(struct watchdog_device *);
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int (*stop)(struct watchdog_device *);
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/* optional operations */
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int (*ping)(struct watchdog_device *);
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unsigned int (*status)(struct watchdog_device *);
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int (*set_timeout)(struct watchdog_device *, unsigned int);
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unsigned int (*get_timeleft)(struct watchdog_device *);
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int (*restart)(struct watchdog_device *);
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void (*ref)(struct watchdog_device *) __deprecated;
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void (*unref)(struct watchdog_device *) __deprecated;
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long (*ioctl)(struct watchdog_device *, unsigned int, unsigned long);
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};
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It is important that you first define the module owner of the watchdog timer
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driver's operations. This module owner will be used to lock the module when
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the watchdog is active. (This to avoid a system crash when you unload the
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module and /dev/watchdog is still open).
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Some operations are mandatory and some are optional. The mandatory operations
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are:
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* start: this is a pointer to the routine that starts the watchdog timer
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device.
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The routine needs a pointer to the watchdog timer device structure as a
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parameter. It returns zero on success or a negative errno code for failure.
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Not all watchdog timer hardware supports the same functionality. That's why
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all other routines/operations are optional. They only need to be provided if
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they are supported. These optional routines/operations are:
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* stop: with this routine the watchdog timer device is being stopped.
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The routine needs a pointer to the watchdog timer device structure as a
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parameter. It returns zero on success or a negative errno code for failure.
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Some watchdog timer hardware can only be started and not be stopped. A
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driver supporting such hardware does not have to implement the stop routine.
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If a driver has no stop function, the watchdog core will set WDOG_HW_RUNNING
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and start calling the driver's keepalive pings function after the watchdog
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device is closed.
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If a watchdog driver does not implement the stop function, it must set
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max_hw_heartbeat_ms.
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* ping: this is the routine that sends a keepalive ping to the watchdog timer
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hardware.
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The routine needs a pointer to the watchdog timer device structure as a
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parameter. It returns zero on success or a negative errno code for failure.
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Most hardware that does not support this as a separate function uses the
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start function to restart the watchdog timer hardware. And that's also what
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the watchdog timer driver core does: to send a keepalive ping to the watchdog
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timer hardware it will either use the ping operation (when available) or the
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start operation (when the ping operation is not available).
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(Note: the WDIOC_KEEPALIVE ioctl call will only be active when the
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WDIOF_KEEPALIVEPING bit has been set in the option field on the watchdog's
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info structure).
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* status: this routine checks the status of the watchdog timer device. The
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status of the device is reported with watchdog WDIOF_* status flags/bits.
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* set_timeout: this routine checks and changes the timeout of the watchdog
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timer device. It returns 0 on success, -EINVAL for "parameter out of range"
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and -EIO for "could not write value to the watchdog". On success this
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routine should set the timeout value of the watchdog_device to the
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achieved timeout value (which may be different from the requested one
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because the watchdog does not necessarily have a 1 second resolution).
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Drivers implementing max_hw_heartbeat_ms set the hardware watchdog heartbeat
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to the minimum of timeout and max_hw_heartbeat_ms. Those drivers set the
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timeout value of the watchdog_device either to the requested timeout value
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(if it is larger than max_hw_heartbeat_ms), or to the achieved timeout value.
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(Note: the WDIOF_SETTIMEOUT needs to be set in the options field of the
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watchdog's info structure).
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If the watchdog driver does not have to perform any action but setting the
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watchdog_device.timeout, this callback can be omitted.
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If set_timeout is not provided but, WDIOF_SETTIMEOUT is set, the watchdog
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infrastructure updates the timeout value of the watchdog_device internally
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to the requested value.
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* get_timeleft: this routines returns the time that's left before a reset.
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* restart: this routine restarts the machine. It returns 0 on success or a
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negative errno code for failure.
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* ioctl: if this routine is present then it will be called first before we do
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our own internal ioctl call handling. This routine should return -ENOIOCTLCMD
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if a command is not supported. The parameters that are passed to the ioctl
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call are: watchdog_device, cmd and arg.
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The 'ref' and 'unref' operations are no longer used and deprecated.
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The status bits should (preferably) be set with the set_bit and clear_bit alike
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bit-operations. The status bits that are defined are:
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* WDOG_ACTIVE: this status bit indicates whether or not a watchdog timer device
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is active or not from user perspective. User space is expected to send
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heartbeat requests to the driver while this flag is set.
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* WDOG_NO_WAY_OUT: this bit stores the nowayout setting for the watchdog.
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If this bit is set then the watchdog timer will not be able to stop.
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* WDOG_HW_RUNNING: Set by the watchdog driver if the hardware watchdog is
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running. The bit must be set if the watchdog timer hardware can not be
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stopped. The bit may also be set if the watchdog timer is running after
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booting, before the watchdog device is opened. If set, the watchdog
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infrastructure will send keepalives to the watchdog hardware while
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WDOG_ACTIVE is not set.
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Note: when you register the watchdog timer device with this bit set,
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then opening /dev/watchdog will skip the start operation but send a keepalive
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request instead.
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To set the WDOG_NO_WAY_OUT status bit (before registering your watchdog
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timer device) you can either:
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* set it statically in your watchdog_device struct with
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.status = WATCHDOG_NOWAYOUT_INIT_STATUS,
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(this will set the value the same as CONFIG_WATCHDOG_NOWAYOUT) or
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* use the following helper function:
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static inline void watchdog_set_nowayout(struct watchdog_device *wdd, int nowayout)
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Note: The WatchDog Timer Driver Core supports the magic close feature and
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the nowayout feature. To use the magic close feature you must set the
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WDIOF_MAGICCLOSE bit in the options field of the watchdog's info structure.
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The nowayout feature will overrule the magic close feature.
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To get or set driver specific data the following two helper functions should be
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used:
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static inline void watchdog_set_drvdata(struct watchdog_device *wdd, void *data)
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static inline void *watchdog_get_drvdata(struct watchdog_device *wdd)
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The watchdog_set_drvdata function allows you to add driver specific data. The
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arguments of this function are the watchdog device where you want to add the
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driver specific data to and a pointer to the data itself.
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The watchdog_get_drvdata function allows you to retrieve driver specific data.
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The argument of this function is the watchdog device where you want to retrieve
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data from. The function returns the pointer to the driver specific data.
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To initialize the timeout field, the following function can be used:
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extern int watchdog_init_timeout(struct watchdog_device *wdd,
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unsigned int timeout_parm, struct device *dev);
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The watchdog_init_timeout function allows you to initialize the timeout field
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using the module timeout parameter or by retrieving the timeout-sec property from
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the device tree (if the module timeout parameter is invalid). Best practice is
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to set the default timeout value as timeout value in the watchdog_device and
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then use this function to set the user "preferred" timeout value.
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This routine returns zero on success and a negative errno code for failure.
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To disable the watchdog on reboot, the user must call the following helper:
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static inline void watchdog_stop_on_reboot(struct watchdog_device *wdd);
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To change the priority of the restart handler the following helper should be
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used:
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void watchdog_set_restart_priority(struct watchdog_device *wdd, int priority);
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User should follow the following guidelines for setting the priority:
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* 0: should be called in last resort, has limited restart capabilities
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* 128: default restart handler, use if no other handler is expected to be
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available, and/or if restart is sufficient to restart the entire system
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* 255: highest priority, will preempt all other restart handlers
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