#ifndef QDEV_CORE_H #define QDEV_CORE_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" 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_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); /** * DeviceClass: * @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 * * # Realization # * Devices are constructed in two stages, * 1) object instantiation via object_initialize() and * 2) device realization via #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. * * * * 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. * */ struct DeviceClass { /*< private >*/ ObjectClass parent_class; /*< public >*/ DECLARE_BITMAP(categories, DEVICE_CATEGORY_MAX); const char *fw_name; const char *desc; /* * The underscore at the end ensures a compile-time error if someone * assigns to dc->props instead of using device_class_set_props. */ Property *props_; /* * Can this device be instantiated 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 method here is deprecated and replaced by methods in the * resettable class interface to implement a multi-phase reset. * TODO: remove once every reset callback is unused */ DeviceReset reset; DeviceRealize realize; DeviceUnrealize unrealize; /* device state */ const VMStateDescription *vmsd; /* 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; }; /** * DeviceState: * @realized: Indicates whether the device has been fully constructed. * When accessed outside big qemu lock, must be accessed with * qatomic_load_acquire() * @reset: ResettableState for the device; handled by Resettable interface. * * 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 >*/ const char *id; char *canonical_path; bool realized; bool pending_deleted_event; QemuOpts *opts; int hotplugged; bool allow_unplug_during_migration; BusState *parent_bus; QLIST_HEAD(, NamedGPIOList) gpios; QLIST_HEAD(, NamedClockList) clocks; QLIST_HEAD(, BusState) child_bus; int num_child_bus; int instance_id_alias; int alias_required_for_version; ResettableState reset; }; 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. */ bool (*hide_device)(DeviceListener *listener, QemuOpts *device_opts); 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); void (*reset)(BusState *bus); /* * 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" /** * BusState: * @hotplug_handler: link to a hotplug handler associated with bus. * @reset: ResettableState for the bus; handled by Resettable interface. */ struct BusState { Object obj; DeviceState *parent; char *name; HotplugHandler *hotplug_handler; int max_index; bool realized; bool full; int num_children; /* * children is a RCU QTAILQ, thus readers must use RCU to access it, * and writers must hold the big qemu lock */ QTAILQ_HEAD(, BusChild) children; QLIST_ENTRY(BusState) sibling; ResettableState reset; }; /** * GlobalProperty: * @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. * The returned object has 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. */ DeviceState *qdev_try_new(const char *name); /** * 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. * On success, return true. * On failure, store an error through @errp and return false. * * If you created @dev using qdev_new(), you probably want to use * qdev_realize_and_unref() instead. */ 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(). */ 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 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 * * Find HOTPLUG_HANDLER for @dev that provides [pre|un]plug callbacks for it. * * Note: in case @dev has a parent bus, it will be returned as handler unless * machine handler overrides it. * * Returns: 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); /** * 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(). */ 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(). */ 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_IRQ_SPLIT 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: Connect one of a device's anonymous 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) * @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 named output GPIO lines, use qdev_connect_gpio_out_named(). */ void qdev_connect_gpio_out_named(DeviceState *dev, const char *name, int n, qemu_irq 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. */ 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 * * 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. */ 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: 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 * for the specified device * * @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 * for the specified device * * 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(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_create(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); /** * @qdev_reset_all: * Reset @dev. See @qbus_reset_all() for more details. * * Note: This function is deprecated and will be removed when it becomes unused. * Please use device_cold_reset() now. */ void qdev_reset_all(DeviceState *dev); void qdev_reset_all_fn(void *opaque); /** * @qbus_reset_all: * @bus: Bus to be reset. * * Reset @bus and perform a bus-level ("hard") reset of all devices connected * to it, including recursive processing of all buses below @bus itself. A * hard reset means that qbus_reset_all will reset all state of the device. * For PCI devices, for example, this will include the base address registers * or configuration space. * * Note: This function is deprecated and will be removed when it becomes unused. * Please use bus_cold_reset() now. */ void qbus_reset_all(BusState *bus); void qbus_reset_all_fn(void *opaque); /** * device_cold_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: * * 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: * Return true if the device @dev is currently being reset. */ bool device_is_in_reset(DeviceState *dev); /** * bus_is_in_reset: * 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_legacy_reset: * * Reset a single device (by calling the reset method). * Note: This function is deprecated and will be removed when it becomes unused. * Please use device_cold_reset() now. */ void device_legacy_reset(DeviceState *dev); void device_class_set_props(DeviceClass *dc, Property *props); /** * device_class_set_parent_reset: * 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); void device_class_set_parent_realize(DeviceClass *dc, DeviceRealize dev_realize, DeviceRealize *parent_realize); 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); /* 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) { return bus->hotplug_handler; } /** * 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: * @opts: QemuOpts as passed on cmdline. * * Check if a device should be added. * When a device is added via qdev_device_add() this will be called, * and return if the device should be added now or not. */ bool qdev_should_hide_device(QemuOpts *opts); 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, /* * 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; extern bool phase_check(MachineInitPhase phase); extern void phase_advance(MachineInitPhase phase); #endif