qemu-e2k/include/hw/qdev-core.h
Mark Kanda 04accf43df oslib-posix: initialize backend memory objects in parallel
QEMU initializes preallocated backend memory as the objects are parsed from
the command line. This is not optimal in some cases (e.g. memory spanning
multiple NUMA nodes) because the memory objects are initialized in series.

Allow the initialization to occur in parallel (asynchronously). In order to
ensure optimal thread placement, asynchronous initialization requires prealloc
context threads to be in use.

Signed-off-by: Mark Kanda <mark.kanda@oracle.com>
Message-ID: <20240131165327.3154970-2-mark.kanda@oracle.com>
Tested-by: Mario Casquero <mcasquer@redhat.com>
Signed-off-by: David Hildenbrand <david@redhat.com>
2024-02-06 08:15:22 +01:00

1110 lines
38 KiB
C

#ifndef QDEV_CORE_H
#define QDEV_CORE_H
#include "qemu/atomic.h"
#include "qemu/queue.h"
#include "qemu/bitmap.h"
#include "qemu/rcu.h"
#include "qemu/rcu_queue.h"
#include "qom/object.h"
#include "hw/hotplug.h"
#include "hw/resettable.h"
/**
* DOC: The QEMU Device API
*
* All modern devices should represented as a derived QOM class of
* TYPE_DEVICE. The device API introduces the additional methods of
* @realize and @unrealize to represent additional stages in a device
* objects life cycle.
*
* Realization
* -----------
*
* Devices are constructed in two stages:
*
* 1) object instantiation via object_initialize() and
* 2) device realization via the #DeviceState.realized property
*
* The former may not fail (and must not abort or exit, since it is called
* during device introspection already), and the latter may return error
* information to the caller and must be re-entrant.
* Trivial field initializations should go into #TypeInfo.instance_init.
* Operations depending on @props static properties should go into @realize.
* After successful realization, setting static properties will fail.
*
* As an interim step, the #DeviceState.realized property can also be
* set with qdev_realize(). In the future, devices will propagate this
* state change to their children and along busses they expose. The
* point in time will be deferred to machine creation, so that values
* set in @realize will not be introspectable beforehand. Therefore
* devices must not create children during @realize; they should
* initialize them via object_initialize() in their own
* #TypeInfo.instance_init and forward the realization events
* appropriately.
*
* Any type may override the @realize and/or @unrealize callbacks but needs
* to call the parent type's implementation if keeping their functionality
* is desired. Refer to QOM documentation for further discussion and examples.
*
* .. note::
* Since TYPE_DEVICE doesn't implement @realize and @unrealize, types
* derived directly from it need not call their parent's @realize and
* @unrealize. For other types consult the documentation and
* implementation of the respective parent types.
*
* Hiding a device
* ---------------
*
* To hide a device, a DeviceListener function hide_device() needs to
* be registered. It can be used to defer adding a device and
* therefore hide it from the guest. The handler registering to this
* DeviceListener can save the QOpts passed to it for re-using it
* later. It must return if it wants the device to be hidden or
* visible. When the handler function decides the device shall be
* visible it will be added with qdev_device_add() and realized as any
* other device. Otherwise qdev_device_add() will return early without
* adding the device. The guest will not see a "hidden" device until
* it was marked visible and qdev_device_add called again.
*
*/
enum {
DEV_NVECTORS_UNSPECIFIED = -1,
};
#define TYPE_DEVICE "device"
OBJECT_DECLARE_TYPE(DeviceState, DeviceClass, DEVICE)
typedef enum DeviceCategory {
DEVICE_CATEGORY_BRIDGE,
DEVICE_CATEGORY_USB,
DEVICE_CATEGORY_STORAGE,
DEVICE_CATEGORY_NETWORK,
DEVICE_CATEGORY_INPUT,
DEVICE_CATEGORY_DISPLAY,
DEVICE_CATEGORY_SOUND,
DEVICE_CATEGORY_MISC,
DEVICE_CATEGORY_CPU,
DEVICE_CATEGORY_WATCHDOG,
DEVICE_CATEGORY_MAX
} DeviceCategory;
typedef void (*DeviceRealize)(DeviceState *dev, Error **errp);
typedef void (*DeviceUnrealize)(DeviceState *dev);
typedef void (*DeviceReset)(DeviceState *dev);
typedef void (*BusRealize)(BusState *bus, Error **errp);
typedef void (*BusUnrealize)(BusState *bus);
/**
* struct DeviceClass - The base class for all devices.
* @props: Properties accessing state fields.
* @realize: Callback function invoked when the #DeviceState:realized
* property is changed to %true.
* @unrealize: Callback function invoked when the #DeviceState:realized
* property is changed to %false.
* @hotpluggable: indicates if #DeviceClass is hotpluggable, available
* as readonly "hotpluggable" property of #DeviceState instance
*
*/
struct DeviceClass {
/* private: */
ObjectClass parent_class;
/* public: */
/**
* @categories: device categories device belongs to
*/
DECLARE_BITMAP(categories, DEVICE_CATEGORY_MAX);
/**
* @fw_name: name used to identify device to firmware interfaces
*/
const char *fw_name;
/**
* @desc: human readable description of device
*/
const char *desc;
/**
* @props_: properties associated with device, should only be
* assigned by using device_class_set_props(). The underscore
* ensures a compile-time error if someone attempts to assign
* dc->props directly.
*/
Property *props_;
/**
* @user_creatable: Can user instantiate with -device / device_add?
*
* All devices should support instantiation with device_add, and
* this flag should not exist. But we're not there, yet. Some
* devices fail to instantiate with cryptic error messages.
* Others instantiate, but don't work. Exposing users to such
* behavior would be cruel; clearing this flag will protect them.
* It should never be cleared without a comment explaining why it
* is cleared.
*
* TODO remove once we're there
*/
bool user_creatable;
bool hotpluggable;
/* callbacks */
/**
* @reset: deprecated device reset method pointer
*
* Modern code should use the ResettableClass interface to
* implement a multi-phase reset.
*
* TODO: remove once every reset callback is unused
*/
DeviceReset reset;
DeviceRealize realize;
DeviceUnrealize unrealize;
/**
* @vmsd: device state serialisation description for
* migration/save/restore
*/
const VMStateDescription *vmsd;
/**
* @bus_type: bus type
* private: to qdev / bus.
*/
const char *bus_type;
};
typedef struct NamedGPIOList NamedGPIOList;
struct NamedGPIOList {
char *name;
qemu_irq *in;
int num_in;
int num_out;
QLIST_ENTRY(NamedGPIOList) node;
};
typedef struct Clock Clock;
typedef struct NamedClockList NamedClockList;
struct NamedClockList {
char *name;
Clock *clock;
bool output;
bool alias;
QLIST_ENTRY(NamedClockList) node;
};
typedef struct {
bool engaged_in_io;
} MemReentrancyGuard;
typedef QLIST_HEAD(, NamedGPIOList) NamedGPIOListHead;
typedef QLIST_HEAD(, NamedClockList) NamedClockListHead;
typedef QLIST_HEAD(, BusState) BusStateHead;
/**
* struct DeviceState - common device state, accessed with qdev helpers
*
* This structure should not be accessed directly. We declare it here
* so that it can be embedded in individual device state structures.
*/
struct DeviceState {
/* private: */
Object parent_obj;
/* public: */
/**
* @id: global device id
*/
char *id;
/**
* @canonical_path: canonical path of realized device in the QOM tree
*/
char *canonical_path;
/**
* @realized: has device been realized?
*/
bool realized;
/**
* @pending_deleted_event: track pending deletion events during unplug
*/
bool pending_deleted_event;
/**
* @pending_deleted_expires_ms: optional timeout for deletion events
*/
int64_t pending_deleted_expires_ms;
/**
* @opts: QDict of options for the device
*/
QDict *opts;
/**
* @hotplugged: was device added after PHASE_MACHINE_READY?
*/
int hotplugged;
/**
* @allow_unplug_during_migration: can device be unplugged during migration
*/
bool allow_unplug_during_migration;
/**
* @parent_bus: bus this device belongs to
*/
BusState *parent_bus;
/**
* @gpios: QLIST of named GPIOs the device provides.
*/
NamedGPIOListHead gpios;
/**
* @clocks: QLIST of named clocks the device provides.
*/
NamedClockListHead clocks;
/**
* @child_bus: QLIST of child buses
*/
BusStateHead child_bus;
/**
* @num_child_bus: number of @child_bus entries
*/
int num_child_bus;
/**
* @instance_id_alias: device alias for handling legacy migration setups
*/
int instance_id_alias;
/**
* @alias_required_for_version: indicates @instance_id_alias is
* needed for migration
*/
int alias_required_for_version;
/**
* @reset: ResettableState for the device; handled by Resettable interface.
*/
ResettableState reset;
/**
* @unplug_blockers: list of reasons to block unplugging of device
*/
GSList *unplug_blockers;
/**
* @mem_reentrancy_guard: Is the device currently in mmio/pio/dma?
*
* Used to prevent re-entrancy confusing things.
*/
MemReentrancyGuard mem_reentrancy_guard;
};
struct DeviceListener {
void (*realize)(DeviceListener *listener, DeviceState *dev);
void (*unrealize)(DeviceListener *listener, DeviceState *dev);
/*
* This callback is called upon init of the DeviceState and
* informs qdev if a device should be visible or hidden. We can
* hide a failover device depending for example on the device
* opts.
*
* On errors, it returns false and errp is set. Device creation
* should fail in this case.
*/
bool (*hide_device)(DeviceListener *listener, const QDict *device_opts,
bool from_json, Error **errp);
QTAILQ_ENTRY(DeviceListener) link;
};
#define TYPE_BUS "bus"
DECLARE_OBJ_CHECKERS(BusState, BusClass,
BUS, TYPE_BUS)
struct BusClass {
ObjectClass parent_class;
/* FIXME first arg should be BusState */
void (*print_dev)(Monitor *mon, DeviceState *dev, int indent);
char *(*get_dev_path)(DeviceState *dev);
/*
* This callback is used to create Open Firmware device path in accordance
* with OF spec http://forthworks.com/standards/of1275.pdf. Individual bus
* bindings can be found at http://playground.sun.com/1275/bindings/.
*/
char *(*get_fw_dev_path)(DeviceState *dev);
/*
* Return whether the device can be added to @bus,
* based on the address that was set (via device properties)
* before realize. If not, on return @errp contains the
* human-readable error message.
*/
bool (*check_address)(BusState *bus, DeviceState *dev, Error **errp);
BusRealize realize;
BusUnrealize unrealize;
/* maximum devices allowed on the bus, 0: no limit. */
int max_dev;
/* number of automatically allocated bus ids (e.g. ide.0) */
int automatic_ids;
};
typedef struct BusChild {
struct rcu_head rcu;
DeviceState *child;
int index;
QTAILQ_ENTRY(BusChild) sibling;
} BusChild;
#define QDEV_HOTPLUG_HANDLER_PROPERTY "hotplug-handler"
typedef QTAILQ_HEAD(, BusChild) BusChildHead;
typedef QLIST_ENTRY(BusState) BusStateEntry;
/**
* struct BusState:
* @obj: parent object
* @parent: parent Device
* @name: name of bus
* @hotplug_handler: link to a hotplug handler associated with bus.
* @max_index: max number of child buses
* @realized: is the bus itself realized?
* @full: is the bus full?
* @num_children: current number of child buses
*/
struct BusState {
/* private: */
Object obj;
/* public: */
DeviceState *parent;
char *name;
HotplugHandler *hotplug_handler;
int max_index;
bool realized;
bool full;
int num_children;
/**
* @children: an RCU protected QTAILQ, thus readers must use RCU
* to access it, and writers must hold the big qemu lock
*/
BusChildHead children;
/**
* @sibling: next bus
*/
BusStateEntry sibling;
/**
* @reset: ResettableState for the bus; handled by Resettable interface.
*/
ResettableState reset;
};
/**
* typedef GlobalProperty - a global property type
*
* @used: Set to true if property was used when initializing a device.
* @optional: If set to true, GlobalProperty will be skipped without errors
* if the property doesn't exist.
*
* An error is fatal for non-hotplugged devices, when the global is applied.
*/
typedef struct GlobalProperty {
const char *driver;
const char *property;
const char *value;
bool used;
bool optional;
} GlobalProperty;
static inline void
compat_props_add(GPtrArray *arr,
GlobalProperty props[], size_t nelem)
{
int i;
for (i = 0; i < nelem; i++) {
g_ptr_array_add(arr, (void *)&props[i]);
}
}
/*** Board API. This should go away once we have a machine config file. ***/
/**
* qdev_new: Create a device on the heap
* @name: device type to create (we assert() that this type exists)
*
* This only allocates the memory and initializes the device state
* structure, ready for the caller to set properties if they wish.
* The device still needs to be realized.
*
* Return: a derived DeviceState object with a reference count of 1.
*/
DeviceState *qdev_new(const char *name);
/**
* qdev_try_new: Try to create a device on the heap
* @name: device type to create
*
* This is like qdev_new(), except it returns %NULL when type @name
* does not exist, rather than asserting.
*
* Return: a derived DeviceState object with a reference count of 1 or
* NULL if type @name does not exist.
*/
DeviceState *qdev_try_new(const char *name);
/**
* qdev_is_realized() - check if device is realized
* @dev: The device to check.
*
* Context: May be called outside big qemu lock.
* Return: true if the device has been fully constructed, false otherwise.
*/
static inline bool qdev_is_realized(DeviceState *dev)
{
return qatomic_load_acquire(&dev->realized);
}
/**
* qdev_realize: Realize @dev.
* @dev: device to realize
* @bus: bus to plug it into (may be NULL)
* @errp: pointer to error object
*
* "Realize" the device, i.e. perform the second phase of device
* initialization.
* @dev must not be plugged into a bus already.
* If @bus, plug @dev into @bus. This takes a reference to @dev.
* If @dev has no QOM parent, make one up, taking another reference.
*
* If you created @dev using qdev_new(), you probably want to use
* qdev_realize_and_unref() instead.
*
* Return: true on success, else false setting @errp with error
*/
bool qdev_realize(DeviceState *dev, BusState *bus, Error **errp);
/**
* qdev_realize_and_unref: Realize @dev and drop a reference
* @dev: device to realize
* @bus: bus to plug it into (may be NULL)
* @errp: pointer to error object
*
* Realize @dev and drop a reference.
* This is like qdev_realize(), except the caller must hold a
* (private) reference, which is dropped on return regardless of
* success or failure. Intended use::
*
* dev = qdev_new();
* [...]
* qdev_realize_and_unref(dev, bus, errp);
*
* Now @dev can go away without further ado.
*
* If you are embedding the device into some other QOM device and
* initialized it via some variant on object_initialize_child() then
* do not use this function, because that family of functions arrange
* for the only reference to the child device to be held by the parent
* via the child<> property, and so the reference-count-drop done here
* would be incorrect. For that use case you want qdev_realize().
*
* Return: true on success, else false setting @errp with error
*/
bool qdev_realize_and_unref(DeviceState *dev, BusState *bus, Error **errp);
/**
* qdev_unrealize: Unrealize a device
* @dev: device to unrealize
*
* This function will "unrealize" a device, which is the first phase
* of correctly destroying a device that has been realized. It will:
*
* - unrealize any child buses by calling qbus_unrealize()
* (this will recursively unrealize any devices on those buses)
* - call the unrealize method of @dev
*
* The device can then be freed by causing its reference count to go
* to zero.
*
* Warning: most devices in QEMU do not expect to be unrealized. Only
* devices which are hot-unpluggable should be unrealized (as part of
* the unplugging process); all other devices are expected to last for
* the life of the simulation and should not be unrealized and freed.
*/
void qdev_unrealize(DeviceState *dev);
void qdev_set_legacy_instance_id(DeviceState *dev, int alias_id,
int required_for_version);
HotplugHandler *qdev_get_bus_hotplug_handler(DeviceState *dev);
HotplugHandler *qdev_get_machine_hotplug_handler(DeviceState *dev);
bool qdev_hotplug_allowed(DeviceState *dev, Error **errp);
/**
* qdev_get_hotplug_handler() - Get handler responsible for device wiring
* @dev: the device we want the HOTPLUG_HANDLER for.
*
* Note: in case @dev has a parent bus, it will be returned as handler unless
* machine handler overrides it.
*
* Return: pointer to object that implements TYPE_HOTPLUG_HANDLER interface
* or NULL if there aren't any.
*/
HotplugHandler *qdev_get_hotplug_handler(DeviceState *dev);
void qdev_unplug(DeviceState *dev, Error **errp);
void qdev_simple_device_unplug_cb(HotplugHandler *hotplug_dev,
DeviceState *dev, Error **errp);
void qdev_machine_creation_done(void);
bool qdev_machine_modified(void);
/**
* qdev_add_unplug_blocker: Add an unplug blocker to a device
*
* @dev: Device to be blocked from unplug
* @reason: Reason for blocking
*/
void qdev_add_unplug_blocker(DeviceState *dev, Error *reason);
/**
* qdev_del_unplug_blocker: Remove an unplug blocker from a device
*
* @dev: Device to be unblocked
* @reason: Pointer to the Error used with qdev_add_unplug_blocker.
* Used as a handle to lookup the blocker for deletion.
*/
void qdev_del_unplug_blocker(DeviceState *dev, Error *reason);
/**
* qdev_unplug_blocked: Confirm if a device is blocked from unplug
*
* @dev: Device to be tested
* @errp: The reasons why the device is blocked, if any
*
* Returns: true (also setting @errp) if device is blocked from unplug,
* false otherwise
*/
bool qdev_unplug_blocked(DeviceState *dev, Error **errp);
/**
* typedef GpioPolarity - Polarity of a GPIO line
*
* GPIO lines use either positive (active-high) logic,
* or negative (active-low) logic.
*
* In active-high logic (%GPIO_POLARITY_ACTIVE_HIGH), a pin is
* active when the voltage on the pin is high (relative to ground);
* whereas in active-low logic (%GPIO_POLARITY_ACTIVE_LOW), a pin
* is active when the voltage on the pin is low (or grounded).
*/
typedef enum {
GPIO_POLARITY_ACTIVE_LOW,
GPIO_POLARITY_ACTIVE_HIGH
} GpioPolarity;
/**
* qdev_get_gpio_in: Get one of a device's anonymous input GPIO lines
* @dev: Device whose GPIO we want
* @n: Number of the anonymous GPIO line (which must be in range)
*
* Returns the qemu_irq corresponding to an anonymous input GPIO line
* (which the device has set up with qdev_init_gpio_in()). The index
* @n of the GPIO line must be valid (i.e. be at least 0 and less than
* the total number of anonymous input GPIOs the device has); this
* function will assert() if passed an invalid index.
*
* This function is intended to be used by board code or SoC "container"
* device models to wire up the GPIO lines; usually the return value
* will be passed to qdev_connect_gpio_out() or a similar function to
* connect another device's output GPIO line to this input.
*
* For named input GPIO lines, use qdev_get_gpio_in_named().
*
* Return: qemu_irq corresponding to anonymous input GPIO line
*/
qemu_irq qdev_get_gpio_in(DeviceState *dev, int n);
/**
* qdev_get_gpio_in_named: Get one of a device's named input GPIO lines
* @dev: Device whose GPIO we want
* @name: Name of the input GPIO array
* @n: Number of the GPIO line in that array (which must be in range)
*
* Returns the qemu_irq corresponding to a named input GPIO line
* (which the device has set up with qdev_init_gpio_in_named()).
* The @name string must correspond to an input GPIO array which exists on
* the device, and the index @n of the GPIO line must be valid (i.e.
* be at least 0 and less than the total number of input GPIOs in that
* array); this function will assert() if passed an invalid name or index.
*
* For anonymous input GPIO lines, use qdev_get_gpio_in().
*
* Return: qemu_irq corresponding to named input GPIO line
*/
qemu_irq qdev_get_gpio_in_named(DeviceState *dev, const char *name, int n);
/**
* qdev_connect_gpio_out: Connect one of a device's anonymous output GPIO lines
* @dev: Device whose GPIO to connect
* @n: Number of the anonymous output GPIO line (which must be in range)
* @pin: qemu_irq to connect the output line to
*
* This function connects an anonymous output GPIO line on a device
* up to an arbitrary qemu_irq, so that when the device asserts that
* output GPIO line, the qemu_irq's callback is invoked.
* The index @n of the GPIO line must be valid (i.e. be at least 0 and
* less than the total number of anonymous output GPIOs the device has
* created with qdev_init_gpio_out()); otherwise this function will assert().
*
* Outbound GPIO lines can be connected to any qemu_irq, but the common
* case is connecting them to another device's inbound GPIO line, using
* the qemu_irq returned by qdev_get_gpio_in() or qdev_get_gpio_in_named().
*
* It is not valid to try to connect one outbound GPIO to multiple
* qemu_irqs at once, or to connect multiple outbound GPIOs to the
* same qemu_irq. (Warning: there is no assertion or other guard to
* catch this error: the model will just not do the right thing.)
* Instead, for fan-out you can use the TYPE_SPLIT_IRQ device: connect
* a device's outbound GPIO to the splitter's input, and connect each
* of the splitter's outputs to a different device. For fan-in you
* can use the TYPE_OR_IRQ device, which is a model of a logical OR
* gate with multiple inputs and one output.
*
* For named output GPIO lines, use qdev_connect_gpio_out_named().
*/
void qdev_connect_gpio_out(DeviceState *dev, int n, qemu_irq pin);
/**
* qdev_connect_gpio_out_named: Connect one of a device's named output
* GPIO lines
* @dev: Device whose GPIO to connect
* @name: Name of the output GPIO array
* @n: Number of the anonymous output GPIO line (which must be in range)
* @input_pin: qemu_irq to connect the output line to
*
* This function connects an anonymous output GPIO line on a device
* up to an arbitrary qemu_irq, so that when the device asserts that
* output GPIO line, the qemu_irq's callback is invoked.
* The @name string must correspond to an output GPIO array which exists on
* the device, and the index @n of the GPIO line must be valid (i.e.
* be at least 0 and less than the total number of input GPIOs in that
* array); this function will assert() if passed an invalid name or index.
*
* Outbound GPIO lines can be connected to any qemu_irq, but the common
* case is connecting them to another device's inbound GPIO line, using
* the qemu_irq returned by qdev_get_gpio_in() or qdev_get_gpio_in_named().
*
* It is not valid to try to connect one outbound GPIO to multiple
* qemu_irqs at once, or to connect multiple outbound GPIOs to the
* same qemu_irq; see qdev_connect_gpio_out() for details.
*
* For anonymous output GPIO lines, use qdev_connect_gpio_out().
*/
void qdev_connect_gpio_out_named(DeviceState *dev, const char *name, int n,
qemu_irq input_pin);
/**
* qdev_get_gpio_out_connector: Get the qemu_irq connected to an output GPIO
* @dev: Device whose output GPIO we are interested in
* @name: Name of the output GPIO array
* @n: Number of the output GPIO line within that array
*
* Returns whatever qemu_irq is currently connected to the specified
* output GPIO line of @dev. This will be NULL if the output GPIO line
* has never been wired up to the anything. Note that the qemu_irq
* returned does not belong to @dev -- it will be the input GPIO or
* IRQ of whichever device the board code has connected up to @dev's
* output GPIO.
*
* You probably don't need to use this function -- it is used only
* by the platform-bus subsystem.
*
* Return: qemu_irq associated with GPIO or NULL if un-wired.
*/
qemu_irq qdev_get_gpio_out_connector(DeviceState *dev, const char *name, int n);
/**
* qdev_intercept_gpio_out: Intercept an existing GPIO connection
* @dev: Device to intercept the outbound GPIO line from
* @icpt: New qemu_irq to connect instead
* @name: Name of the output GPIO array
* @n: Number of the GPIO line in the array
*
* .. note::
* This function is provided only for use by the qtest testing framework
* and is not suitable for use in non-testing parts of QEMU.
*
* This function breaks an existing connection of an outbound GPIO
* line from @dev, and replaces it with the new qemu_irq @icpt, as if
* ``qdev_connect_gpio_out_named(dev, icpt, name, n)`` had been called.
* The previously connected qemu_irq is returned, so it can be restored
* by a second call to qdev_intercept_gpio_out() if desired.
*
* Return: old disconnected qemu_irq if one existed
*/
qemu_irq qdev_intercept_gpio_out(DeviceState *dev, qemu_irq icpt,
const char *name, int n);
BusState *qdev_get_child_bus(DeviceState *dev, const char *name);
/*** Device API. ***/
/**
* qdev_init_gpio_in: create an array of anonymous input GPIO lines
* @dev: Device to create input GPIOs for
* @handler: Function to call when GPIO line value is set
* @n: Number of GPIO lines to create
*
* Devices should use functions in the qdev_init_gpio_in* family in
* their instance_init or realize methods to create any input GPIO
* lines they need. There is no functional difference between
* anonymous and named GPIO lines. Stylistically, named GPIOs are
* preferable (easier to understand at callsites) unless a device
* has exactly one uniform kind of GPIO input whose purpose is obvious.
* Note that input GPIO lines can serve as 'sinks' for IRQ lines.
*
* See qdev_get_gpio_in() for how code that uses such a device can get
* hold of an input GPIO line to manipulate it.
*/
void qdev_init_gpio_in(DeviceState *dev, qemu_irq_handler handler, int n);
/**
* qdev_init_gpio_out: create an array of anonymous output GPIO lines
* @dev: Device to create output GPIOs for
* @pins: Pointer to qemu_irq or qemu_irq array for the GPIO lines
* @n: Number of GPIO lines to create
*
* Devices should use functions in the qdev_init_gpio_out* family
* in their instance_init or realize methods to create any output
* GPIO lines they need. There is no functional difference between
* anonymous and named GPIO lines. Stylistically, named GPIOs are
* preferable (easier to understand at callsites) unless a device
* has exactly one uniform kind of GPIO output whose purpose is obvious.
*
* The @pins argument should be a pointer to either a "qemu_irq"
* (if @n == 1) or a "qemu_irq []" array (if @n > 1) in the device's
* state structure. The device implementation can then raise and
* lower the GPIO line by calling qemu_set_irq(). (If anything is
* connected to the other end of the GPIO this will cause the handler
* function for that input GPIO to be called.)
*
* See qdev_connect_gpio_out() for how code that uses such a device
* can connect to one of its output GPIO lines.
*
* There is no need to release the @pins allocated array because it
* will be automatically released when @dev calls its instance_finalize()
* handler.
*/
void qdev_init_gpio_out(DeviceState *dev, qemu_irq *pins, int n);
/**
* qdev_init_gpio_out_named: create an array of named output GPIO lines
* @dev: Device to create output GPIOs for
* @pins: Pointer to qemu_irq or qemu_irq array for the GPIO lines
* @name: Name to give this array of GPIO lines
* @n: Number of GPIO lines to create
*
* Like qdev_init_gpio_out(), but creates an array of GPIO output lines
* with a name. Code using the device can then connect these GPIO lines
* using qdev_connect_gpio_out_named().
*/
void qdev_init_gpio_out_named(DeviceState *dev, qemu_irq *pins,
const char *name, int n);
/**
* qdev_init_gpio_in_named_with_opaque() - create an array of input GPIO lines
* @dev: Device to create input GPIOs for
* @handler: Function to call when GPIO line value is set
* @opaque: Opaque data pointer to pass to @handler
* @name: Name of the GPIO input (must be unique for this device)
* @n: Number of GPIO lines in this input set
*/
void qdev_init_gpio_in_named_with_opaque(DeviceState *dev,
qemu_irq_handler handler,
void *opaque,
const char *name, int n);
/**
* qdev_init_gpio_in_named() - create an array of input GPIO lines
* @dev: device to add array to
* @handler: a &typedef qemu_irq_handler function to call when GPIO is set
* @name: Name of the GPIO input (must be unique for this device)
* @n: Number of GPIO lines in this input set
*
* Like qdev_init_gpio_in_named_with_opaque(), but the opaque pointer
* passed to the handler is @dev (which is the most commonly desired behaviour).
*/
static inline void qdev_init_gpio_in_named(DeviceState *dev,
qemu_irq_handler handler,
const char *name, int n)
{
qdev_init_gpio_in_named_with_opaque(dev, handler, dev, name, n);
}
/**
* qdev_pass_gpios: create GPIO lines on container which pass through to device
* @dev: Device which has GPIO lines
* @container: Container device which needs to expose them
* @name: Name of GPIO array to pass through (NULL for the anonymous GPIO array)
*
* In QEMU, complicated devices like SoCs are often modelled with a
* "container" QOM device which itself contains other QOM devices and
* which wires them up appropriately. This function allows the container
* to create GPIO arrays on itself which simply pass through to a GPIO
* array of one of its internal devices.
*
* If @dev has both input and output GPIOs named @name then both will
* be passed through. It is not possible to pass a subset of the array
* with this function.
*
* To users of the container device, the GPIO array created on @container
* behaves exactly like any other.
*/
void qdev_pass_gpios(DeviceState *dev, DeviceState *container,
const char *name);
BusState *qdev_get_parent_bus(const DeviceState *dev);
/*** BUS API. ***/
DeviceState *qdev_find_recursive(BusState *bus, const char *id);
/* Returns 0 to walk children, > 0 to skip walk, < 0 to terminate walk. */
typedef int (qbus_walkerfn)(BusState *bus, void *opaque);
typedef int (qdev_walkerfn)(DeviceState *dev, void *opaque);
void qbus_init(void *bus, size_t size, const char *typename,
DeviceState *parent, const char *name);
BusState *qbus_new(const char *typename, DeviceState *parent, const char *name);
bool qbus_realize(BusState *bus, Error **errp);
void qbus_unrealize(BusState *bus);
/* Returns > 0 if either devfn or busfn skip walk somewhere in cursion,
* < 0 if either devfn or busfn terminate walk somewhere in cursion,
* 0 otherwise. */
int qbus_walk_children(BusState *bus,
qdev_walkerfn *pre_devfn, qbus_walkerfn *pre_busfn,
qdev_walkerfn *post_devfn, qbus_walkerfn *post_busfn,
void *opaque);
int qdev_walk_children(DeviceState *dev,
qdev_walkerfn *pre_devfn, qbus_walkerfn *pre_busfn,
qdev_walkerfn *post_devfn, qbus_walkerfn *post_busfn,
void *opaque);
/**
* device_cold_reset() - perform a recursive cold reset on a device
* @dev: device to reset.
*
* Reset device @dev and perform a recursive processing using the resettable
* interface. It triggers a RESET_TYPE_COLD.
*/
void device_cold_reset(DeviceState *dev);
/**
* bus_cold_reset() - perform a recursive cold reset on a bus
* @bus: bus to reset
*
* Reset bus @bus and perform a recursive processing using the resettable
* interface. It triggers a RESET_TYPE_COLD.
*/
void bus_cold_reset(BusState *bus);
/**
* device_is_in_reset() - check device reset state
* @dev: device to check
*
* Return: true if the device @dev is currently being reset.
*/
bool device_is_in_reset(DeviceState *dev);
/**
* bus_is_in_reset() - check bus reset state
* @bus: bus to check
*
* Return: true if the bus @bus is currently being reset.
*/
bool bus_is_in_reset(BusState *bus);
/* This should go away once we get rid of the NULL bus hack */
BusState *sysbus_get_default(void);
char *qdev_get_fw_dev_path(DeviceState *dev);
char *qdev_get_own_fw_dev_path_from_handler(BusState *bus, DeviceState *dev);
/**
* device_class_set_props(): add a set of properties to an device
* @dc: the parent DeviceClass all devices inherit
* @props: an array of properties, terminate by DEFINE_PROP_END_OF_LIST()
*
* This will add a set of properties to the object. It will fault if
* you attempt to add an existing property defined by a parent class.
* To modify an inherited property you need to use????
*/
void device_class_set_props(DeviceClass *dc, Property *props);
/**
* device_class_set_parent_reset() - legacy set device reset handlers
* @dc: device class
* @dev_reset: function pointer to reset handler
* @parent_reset: function pointer to parents reset handler
*
* Modern code should use the ResettableClass interface to
* implement a multi-phase reset instead.
*
* TODO: remove the function when DeviceClass's reset method
* is not used anymore.
*/
void device_class_set_parent_reset(DeviceClass *dc,
DeviceReset dev_reset,
DeviceReset *parent_reset);
/**
* device_class_set_parent_realize() - set up for chaining realize fns
* @dc: The device class
* @dev_realize: the device realize function
* @parent_realize: somewhere to save the parents realize function
*
* This is intended to be used when the new realize function will
* eventually call its parent realization function during creation.
* This requires storing the function call somewhere (usually in the
* instance structure) so you can eventually call
* dc->parent_realize(dev, errp)
*/
void device_class_set_parent_realize(DeviceClass *dc,
DeviceRealize dev_realize,
DeviceRealize *parent_realize);
/**
* device_class_set_parent_unrealize() - set up for chaining unrealize fns
* @dc: The device class
* @dev_unrealize: the device realize function
* @parent_unrealize: somewhere to save the parents unrealize function
*
* This is intended to be used when the new unrealize function will
* eventually call its parent unrealization function during the
* unrealize phase. This requires storing the function call somewhere
* (usually in the instance structure) so you can eventually call
* dc->parent_unrealize(dev);
*/
void device_class_set_parent_unrealize(DeviceClass *dc,
DeviceUnrealize dev_unrealize,
DeviceUnrealize *parent_unrealize);
const VMStateDescription *qdev_get_vmsd(DeviceState *dev);
const char *qdev_fw_name(DeviceState *dev);
void qdev_assert_realized_properly(void);
Object *qdev_get_machine(void);
/**
* qdev_get_human_name() - Return a human-readable name for a device
* @dev: The device. Must be a valid and non-NULL pointer.
*
* .. note::
* This function is intended for user friendly error messages.
*
* Returns: A newly allocated string containing the device id if not null,
* else the object canonical path.
*
* Use g_free() to free it.
*/
char *qdev_get_human_name(DeviceState *dev);
/* FIXME: make this a link<> */
bool qdev_set_parent_bus(DeviceState *dev, BusState *bus, Error **errp);
extern bool qdev_hot_removed;
char *qdev_get_dev_path(DeviceState *dev);
void qbus_set_hotplug_handler(BusState *bus, Object *handler);
void qbus_set_bus_hotplug_handler(BusState *bus);
static inline bool qbus_is_hotpluggable(BusState *bus)
{
HotplugHandler *plug_handler = bus->hotplug_handler;
bool ret = !!plug_handler;
if (plug_handler) {
HotplugHandlerClass *hdc;
hdc = HOTPLUG_HANDLER_GET_CLASS(plug_handler);
if (hdc->is_hotpluggable_bus) {
ret = hdc->is_hotpluggable_bus(plug_handler, bus);
}
}
return ret;
}
/**
* qbus_mark_full: Mark this bus as full, so no more devices can be attached
* @bus: Bus to mark as full
*
* By default, QEMU will allow devices to be plugged into a bus up
* to the bus class's device count limit. Calling this function
* marks a particular bus as full, so that no more devices can be
* plugged into it. In particular this means that the bus will not
* be considered as a candidate for plugging in devices created by
* the user on the commandline or via the monitor.
* If a machine has multiple buses of a given type, such as I2C,
* where some of those buses in the real hardware are used only for
* internal devices and some are exposed via expansion ports, you
* can use this function to mark the internal-only buses as full
* after you have created all their internal devices. Then user
* created devices will appear on the expansion-port bus where
* guest software expects them.
*/
static inline void qbus_mark_full(BusState *bus)
{
bus->full = true;
}
void device_listener_register(DeviceListener *listener);
void device_listener_unregister(DeviceListener *listener);
/**
* qdev_should_hide_device() - check if device should be hidden
*
* @opts: options QDict
* @from_json: true if @opts entries are typed, false for all strings
* @errp: pointer to error object
*
* When a device is added via qdev_device_add() this will be called.
*
* Return: if the device should be added now or not.
*/
bool qdev_should_hide_device(const QDict *opts, bool from_json, Error **errp);
typedef enum MachineInitPhase {
/* current_machine is NULL. */
PHASE_NO_MACHINE,
/* current_machine is not NULL, but current_machine->accel is NULL. */
PHASE_MACHINE_CREATED,
/*
* current_machine->accel is not NULL, but the machine properties have
* not been validated and machine_class->init has not yet been called.
*/
PHASE_ACCEL_CREATED,
/*
* Late backend objects have been created and initialized.
*/
PHASE_LATE_BACKENDS_CREATED,
/*
* machine_class->init has been called, thus creating any embedded
* devices and validating machine properties. Devices created at
* this time are considered to be cold-plugged.
*/
PHASE_MACHINE_INITIALIZED,
/*
* QEMU is ready to start CPUs and devices created at this time
* are considered to be hot-plugged. The monitor is not restricted
* to "preconfig" commands.
*/
PHASE_MACHINE_READY,
} MachineInitPhase;
bool phase_check(MachineInitPhase phase);
void phase_advance(MachineInitPhase phase);
#endif