src/lib/ddk/include/ddk/driver.h - fuchsia - Git at Google

 // Copyright 2016 The Fuchsia Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef SRC_LIB_DDK_INCLUDE_DDK_DRIVER_H_
 #define SRC_LIB_DDK_INCLUDE_DDK_DRIVER_H_

 #include <stdint.h>
 #include <zircon/compiler.h>
 #include <zircon/types.h>

 __BEGIN_CDECLS

 typedef struct zx_device zx_device_t;
 typedef struct zx_driver zx_driver_t;
 typedef struct zx_protocol_device zx_protocol_device_t;
 typedef struct zx_device_prop zx_device_prop_t;
 typedef struct zx_driver_rec zx_driver_rec_t;

 typedef struct zx_bind_inst zx_bind_inst_t;
 typedef struct zx_driver_binding zx_driver_binding_t;

 // echo -n "zx_driver_ops_v0.5" | sha256sum | cut -c1-16
 #define DRIVER_OPS_VERSION 0x2b3490fa40d9f452

 typedef struct zx_driver_ops {
   uint64_t version;  // DRIVER_OPS_VERSION

   // Opportunity to do on-load work. Called ony once, before any other ops are called. The driver
   // may optionally return a context pointer to be passed to the other driver ops.
   //
   // This hook will only be executed on the devhost's main thread.
   zx_status_t (*init)(void** out_ctx);

   // Requests that the driver bind to the provided device, initialize it, and publish any
   // children.
   //
   // This hook will only be executed on the devhost's main thread.
   zx_status_t (*bind)(void* ctx, zx_device_t* device);

   // Only provided by bus manager drivers, create() is invoked to instantiate a bus device
   // instance in a new device host process
   //
   // This hook will only be executed on the devhost's main thread.
   zx_status_t (*create)(void* ctx, zx_device_t* parent, const char* name, const char* args,
                         zx_handle_t rpc_channel);

   // Last call before driver is unloaded.
   //
   // This hook will only be executed on the devhost's main thread.
   void (*release)(void* ctx);

   // Allows the driver to run its hardware unit tests. If tests are enabled for the driver, and
   // run_unit_tests() is implemented, then it will be called after init(). If run_unit_tests()
   // returns true, indicating that the tests passed, then driver operation continues as normal
   // and the driver should be prepared to accept calls to bind(). The tests may write output to
   // |channel| in the form of fuchsia.driver.test.Logger messages. The driver-unit-test library
   // may be used to assist with the implementation of the tests, including output via |channel|.
   //
   // This hook will only be executed on the devhost's main thread.
   bool (*run_unit_tests)(void* ctx, zx_device_t* parent, zx_handle_t channel);
 } zx_driver_ops_t;

 // echo -n "device_add_args_v0.5" | sha256sum | cut -c1-16
 #define DEVICE_ADD_ARGS_VERSION 0x96a64134d56e88e3

 enum {
   // Do not attempt to bind drivers to this device automatically
   DEVICE_ADD_NON_BINDABLE = (1 << 0),

   // This is a device instance (not visible in devfs or eligible for binding)
   DEVICE_ADD_INSTANCE = (1 << 1),

   // Children of this device will be loaded in their own devhost process,
   // behind a proxy of this device
   DEVICE_ADD_MUST_ISOLATE = (1 << 2),

   // This device will not be visible in devfs or available for binding
   // until device_make_visible() is called on it.
   DEVICE_ADD_INVISIBLE = (1 << 3),

   // This device is allowed to be bindable in multiple composite devices
   DEVICE_ADD_ALLOW_MULTI_COMPOSITE = (1 << 4),
 };

 // Device Manager API

 // One of DEV_POWER_STATE_*
 typedef uint8_t device_power_state_t;

 typedef struct device_power_state_info {
   device_power_state_t state_id;
   // Restore time for coming out of this state to working D0 state.
   zx_duration_t restore_latency;
   // Is this device wakeup_capable?
   bool wakeup_capable;
   // Deepest system system sleep state that the device can wake the system from.
   int32_t system_wake_state;
 } device_power_state_info_t;

 // One of DEV_PERFORMANCE_STATE_*
 typedef uint32_t device_performance_state_t;

 typedef struct device_performance_state_info {
   device_performance_state_t state_id;
   // Restore time for coming out of this state to fully performant state.
   zx_duration_t restore_latency;
   // TODO(ravoorir): Figure out how best can a device have metadata that is
   // specific to a performant state of a specific device. For ex: The power
   // manager wants to know what a cpu device's operating point is for a
   // particular performant state.
 } device_performance_state_info_t;

 typedef struct device_add_args {
   // DEVICE_ADD_ARGS_VERSION
   uint64_t version;

   // Driver name is copied to internal structure
   // max length is ZX_DEVICE_NAME_MAX
   const char* name;

   // Context pointer for use by the driver
   // and passed to driver in all zx_protocol_device_t callbacks
   void* ctx;

   // Pointer to device's device protocol operations
   const zx_protocol_device_t* ops;

   // Optional list of device properties.  This list cannot contain more than
   // one property with an id in the range [BIND_TOPO_START, BIND_TOPO_END].
   zx_device_prop_t* props;

   // Number of device properties
   uint32_t prop_count;

   // List of power_states that the device supports.
   // List cannot be more than MAX_DEVICE_POWER_STATES size.
   const device_power_state_info_t* power_states;

   // Number of power states in the list
   uint8_t power_state_count;

   // List of performant states that the device supports.
   // List cannot be more than MAX_DEVICE_PERFORMANCE_STATES size.
   const device_performance_state_info_t* performance_states;

   // Number of performant power states in the list
   uint8_t performance_state_count;

   // Optional custom protocol for this device
   uint32_t proto_id;

   // Optional custom protocol operations for this device
   void* proto_ops;
   // Arguments used with DEVICE_ADD_MUST_ISOLATE
   // these will be passed to the create() driver op of
   // the proxy device in the new devhost
   const char* proxy_args;

   // Zero or more of DEVICE_ADD_*
   uint32_t flags;

   // Optional channel passed to the |dev| that serves as an open connection for the client.
   // If DEVICE_ADD_MUST_ISOLATE is set, the client will be connected to the proxy instead.
   // If DEVICE_ADD_INVISIBLE is set, the client will not be connected until
   // device_make_visible is called.
   zx_handle_t client_remote;

   // Optional VMO representing that will get used in devfs inspect tree.
   zx_handle_t inspect_vmo;
 } device_add_args_t;

 typedef struct device_make_visible_args {
   // List of power_states that the device supports.
   // List cannot be more than MAX_DEVICE_POWER_STATES size.
   const device_power_state_info_t* power_states;

   // Number of power states in the list
   uint8_t power_state_count;

   // List of performant states that the device supports.
   // List cannot be more than MAX_DEVICE_PERFORMANCE_STATES size.
   const device_performance_state_info_t* performance_states;

   // Number of performant power states in the list
   uint8_t performance_state_count;
 } device_make_visible_args_t;

 typedef device_make_visible_args_t device_init_reply_args_t;

 struct zx_driver_rec {
   const zx_driver_ops_t* ops;
   zx_driver_t* driver;
   uint32_t log_flags;
 };

 // This global symbol is initialized by the driver loader in devhost
 extern zx_driver_rec_t __zircon_driver_rec__;

 zx_status_t device_add_from_driver(zx_driver_t* drv, zx_device_t* parent, device_add_args_t* args,
                                    zx_device_t** out);

 // Creates a device and adds it to the devmgr.
 // device_add_args_t contains all "in" arguments.
 // All device_add_args_t values are copied, so device_add_args_t can be stack allocated.
 // The device_add_args_t.name string value is copied.
 // All other pointer fields are copied as pointers.
 // The newly added device will be active before this call returns, so be sure to have
 // the "out" pointer point to your device-local structure so callbacks can access
 // it immediately.
 //
 // If this call is successful, but the device needs to be torn down, device_async_remove() should
 // be called.  If |args->ctx| is backed by memory, it is the programmer's responsibility to not
 // free that memory until the device's |release| hook is called.
 static inline zx_status_t device_add(zx_device_t* parent, device_add_args_t* args,
                                      zx_device_t** out) {
   return device_add_from_driver(__zircon_driver_rec__.driver, parent, args, out);
 }

 // This is used to signal completion of the device's |init| hook.
 // This will make the device visible and able to be unbound.
 // This can be called from any thread - it does not necessarily need to be called before
 // the |init| hook returns.
 // If |status| is ZX_OK, the driver may provide optional power state information via |args|.
 // If |status| is not ZX_OK, the device will be scheduled to be removed.
 void device_init_reply(zx_device_t* device, zx_status_t status,
                        const device_init_reply_args_t* args);

 zx_status_t device_rebind(zx_device_t* device);
 void device_make_visible(zx_device_t* device, const device_make_visible_args_t* args);

 // Schedules the removal of the given device and all its descendents. When a device is
 // being removed, its |unbind| hook will be invoked.
 // It is safe to call this as long as the device has not completed its |release| hook.
 // Multiple requests to remove the same device will have no effect.
 void device_async_remove(zx_device_t* device);
 // This is used to signal completion of the device's |unbind| hook.
 // This does not necessarily need to be called from within the |unbind| hook.
 void device_unbind_reply(zx_device_t* device);

 // This is used to signal completion of the device's |suspend| hook.
 // Need not necessarily need to be called from within the |suspend| hook.
 // |status| is the status of the suspend.
 // If |status| is success, the |out_state| is same as the requested_state that is
 // sent to the suspend hook. If |status| is failure, the |out_state| is the
 // state that the device can go into.
 void device_suspend_reply(zx_device_t* device, zx_status_t status, uint8_t out_state);

 // This is used to signal completion of the device's |resume| hook.
 // Need not necessarily need to be called from within the |resume| hook.
 // |status| is the status of the resume operation.
 // If |status| is success, the |out_perf_state| has the working performance state
 // that the device is in currently.
 // If |status| is failure, the |out_power_state| has the power state
 // the device is in currently.
 void device_resume_reply(zx_device_t* device, zx_status_t status, uint8_t out_power_state,
                          uint32_t out_perf_state);

 // Retrieves a profile handle into |out_profile| from the scheduler for the
 // given |priority| and |name|. Ownership of |out_profile| is given to the
 // caller. See fuchsia.scheduler.ProfileProvider for more detail.
 //
 // The profile handle can be used with zx_object_set_profile() to control thread
 // priority.
 //
 // The current arguments are transitional, and will likely change in the future.
 zx_status_t device_get_profile(zx_device_t* device, uint32_t priority, const char* name,
                                zx_handle_t* out_profile);

 // Retrieves a deadline profile handle into |out_profile| from the scheduler for
 // the given deadline parameters.  See |device_get_profile|
 zx_status_t device_get_deadline_profile(zx_device_t* device, uint64_t capacity, uint64_t deadline,
                                         uint64_t period, const char* name,
                                         zx_handle_t* out_profile);

 // A description of a part of a device fragment.  It provides a bind program
 // that will match a device on the path from the root of the device tree to the
 // target device.
 typedef struct device_fragment_part {
   uint32_t instruction_count;
   const zx_bind_inst_t* match_program;
 } device_fragment_part_t;

 // A description of a device that makes up part of a composite device.  The
 // particular device is identified by a sequence of part descriptions.  Each
 // part description must match either the target device or one of its ancestors.
 // The first element in |parts| must describe the root of the device tree.  The
 // last element in |parts| must describe the target device itself.  The
 // remaining elements of |parts| must match devices on the path from the root to
 // the target device, in order.  Some of those devices may be skipped, but every
 // element of |parts| must have a match.  Every device on the path that has a
 // property from the range [BIND_TOPO_START, BIND_TOPO_END] must be matched to
 // an element of |parts|.  This sequences of matches between |parts| and devices
 // must be unique.
 typedef struct device_fragment {
   const char* name;
   uint32_t parts_count;
   const device_fragment_part_t* parts;
 } device_fragment_t;

 //
 typedef struct device_metadata {
   uint32_t type;
   const void* data;
   size_t length;
 } device_metadata_t;

 // A description of the composite device with properties |props| and made of
 // |fragments| devices. The composite device will reside in the same devhost
 // as the device that matches |fragments[coresident_device_index]|, unless
 // |coresident_device_index| is UINT32_MAX, in which case it reside in a new devhost.
 // |metadata_list| contains the metadata to be added to the composite device, if any.
 typedef struct composite_device_desc {
   const zx_device_prop_t* props;
   size_t props_count;
   const device_fragment_t* fragments;
   size_t fragments_count;
   uint32_t coresident_device_index;
   const device_metadata_t* metadata_list;
   size_t metadata_count;
 } composite_device_desc_t;

 // Neccesary because banjo cannot generate this type correctly.
 typedef struct composite_device_fragment {
   char name[32];
   zx_device_t* device;
 } composite_device_fragment_t;

 // Create a composite device with the properties |comp_desc|.
 // Once all of the fragment devices are found, the composite
 // device will be published with protocol_id ZX_PROTOCOL_COMPOSITE and the
 // given properties.  A driver may then bind to the created device, and
 // access its parents via the protocol operations returned by
 // get_protocol(ZX_PROTOCOL_COMPOSITE).
 //
 // |name| must be no longer than ZX_DEVICE_NAME_MAX, and is used primarily as a
 // diagnostic.
 //
 // |dev| must be the zx_device_t corresponding to the "sys" device (i.e., the
 // Platform Bus Driver's device).
 zx_status_t device_add_composite(zx_device_t* dev, const char* name,
                                  const composite_device_desc_t* comp_desc);

 // temporary accessor for root resource handle
 zx_handle_t get_root_resource(void);

 // Callback type for load_firmware.
 typedef void (*load_firmware_callback_t)(void* ctx, zx_status_t status, zx_handle_t fw,
                                          size_t size);

 // Drivers may need to load firmware for a device, typically during the call to
 // bind the device. The devmgr will look for the firmware at the given path
 // relative to system-defined locations for device firmware. The load will be done asynchronously,
 // and the given callback will be called with the status of the call, a handle to the fw (or
 // ZX_HANDLE_INVALID if invalid), and the size of the loaded firmware.
 void load_firmware_async(zx_device_t* device, const char* path, load_firmware_callback_t callback,
                          void* context);

 // Synchronous version of load_firmware_async that blocks the current thread until the firmware is
 // loaded. Care should be taken when using this variant, as it may cause deadlocks if storage is
 // backed by a driver in the same driver host.
 zx_status_t load_firmware(zx_device_t* device, const char* path, zx_handle_t* fw, size_t* size);

 // Protocol Identifiers
 #define DDK_PROTOCOL_DEF(tag, val, name, flags) ZX_PROTOCOL_##tag = val,
 enum {
 #include <ddk/protodefs.h>
 };

 __END_CDECLS

 #endif  // SRC_LIB_DDK_INCLUDE_DDK_DRIVER_H_
	// Copyright 2016 The Fuchsia Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef SRC_LIB_DDK_INCLUDE_DDK_DRIVER_H_
	#define SRC_LIB_DDK_INCLUDE_DDK_DRIVER_H_

	#include <stdint.h>
	#include <zircon/compiler.h>
	#include <zircon/types.h>

	__BEGIN_CDECLS

	typedef struct zx_device zx_device_t;
	typedef struct zx_driver zx_driver_t;
	typedef struct zx_protocol_device zx_protocol_device_t;
	typedef struct zx_device_prop zx_device_prop_t;
	typedef struct zx_driver_rec zx_driver_rec_t;

	typedef struct zx_bind_inst zx_bind_inst_t;
	typedef struct zx_driver_binding zx_driver_binding_t;

	// echo -n "zx_driver_ops_v0.5" \| sha256sum \| cut -c1-16
	#define DRIVER_OPS_VERSION 0x2b3490fa40d9f452

	typedef struct zx_driver_ops {
	uint64_t version; // DRIVER_OPS_VERSION

	// Opportunity to do on-load work. Called ony once, before any other ops are called. The driver
	// may optionally return a context pointer to be passed to the other driver ops.
	//
	// This hook will only be executed on the devhost's main thread.
	zx_status_t (init)(void* out_ctx);

	// Requests that the driver bind to the provided device, initialize it, and publish any
	// children.
	//
	// This hook will only be executed on the devhost's main thread.
	zx_status_t (bind)(void ctx, zx_device_t* device);

	// Only provided by bus manager drivers, create() is invoked to instantiate a bus device
	// instance in a new device host process
	//
	// This hook will only be executed on the devhost's main thread.
	zx_status_t (create)(void ctx, zx_device_t* parent, const char* name, const char* args,
	zx_handle_t rpc_channel);

	// Last call before driver is unloaded.
	//
	// This hook will only be executed on the devhost's main thread.
	void (release)(void ctx);

	// Allows the driver to run its hardware unit tests. If tests are enabled for the driver, and
	// run_unit_tests() is implemented, then it will be called after init(). If run_unit_tests()
	// returns true, indicating that the tests passed, then driver operation continues as normal
	// and the driver should be prepared to accept calls to bind(). The tests may write output to
	// \|channel\| in the form of fuchsia.driver.test.Logger messages. The driver-unit-test library
	// may be used to assist with the implementation of the tests, including output via \|channel\|.
	//
	// This hook will only be executed on the devhost's main thread.
	bool (run_unit_tests)(void ctx, zx_device_t* parent, zx_handle_t channel);
	} zx_driver_ops_t;

	// echo -n "device_add_args_v0.5" \| sha256sum \| cut -c1-16
	#define DEVICE_ADD_ARGS_VERSION 0x96a64134d56e88e3

	enum {
	// Do not attempt to bind drivers to this device automatically
	DEVICE_ADD_NON_BINDABLE = (1 << 0),

	// This is a device instance (not visible in devfs or eligible for binding)
	DEVICE_ADD_INSTANCE = (1 << 1),

	// Children of this device will be loaded in their own devhost process,
	// behind a proxy of this device
	DEVICE_ADD_MUST_ISOLATE = (1 << 2),

	// This device will not be visible in devfs or available for binding
	// until device_make_visible() is called on it.
	DEVICE_ADD_INVISIBLE = (1 << 3),

	// This device is allowed to be bindable in multiple composite devices
	DEVICE_ADD_ALLOW_MULTI_COMPOSITE = (1 << 4),
	};

	// Device Manager API

	// One of DEV_POWER_STATE_*
	typedef uint8_t device_power_state_t;

	typedef struct device_power_state_info {
	device_power_state_t state_id;
	// Restore time for coming out of this state to working D0 state.
	zx_duration_t restore_latency;
	// Is this device wakeup_capable?
	bool wakeup_capable;
	// Deepest system system sleep state that the device can wake the system from.
	int32_t system_wake_state;
	} device_power_state_info_t;

	// One of DEV_PERFORMANCE_STATE_*
	typedef uint32_t device_performance_state_t;

	typedef struct device_performance_state_info {
	device_performance_state_t state_id;
	// Restore time for coming out of this state to fully performant state.
	zx_duration_t restore_latency;
	// TODO(ravoorir): Figure out how best can a device have metadata that is
	// specific to a performant state of a specific device. For ex: The power
	// manager wants to know what a cpu device's operating point is for a
	// particular performant state.
	} device_performance_state_info_t;

	typedef struct device_add_args {
	// DEVICE_ADD_ARGS_VERSION
	uint64_t version;

	// Driver name is copied to internal structure
	// max length is ZX_DEVICE_NAME_MAX
	const char* name;

	// Context pointer for use by the driver
	// and passed to driver in all zx_protocol_device_t callbacks
	void* ctx;

	// Pointer to device's device protocol operations
	const zx_protocol_device_t* ops;

	// Optional list of device properties. This list cannot contain more than
	// one property with an id in the range [BIND_TOPO_START, BIND_TOPO_END].
	zx_device_prop_t* props;

	// Number of device properties
	uint32_t prop_count;

	// List of power_states that the device supports.
	// List cannot be more than MAX_DEVICE_POWER_STATES size.
	const device_power_state_info_t* power_states;

	// Number of power states in the list
	uint8_t power_state_count;

	// List of performant states that the device supports.
	// List cannot be more than MAX_DEVICE_PERFORMANCE_STATES size.
	const device_performance_state_info_t* performance_states;

	// Number of performant power states in the list
	uint8_t performance_state_count;

	// Optional custom protocol for this device
	uint32_t proto_id;

	// Optional custom protocol operations for this device
	void* proto_ops;
	// Arguments used with DEVICE_ADD_MUST_ISOLATE
	// these will be passed to the create() driver op of
	// the proxy device in the new devhost
	const char* proxy_args;

	// Zero or more of DEVICE_ADD_*
	uint32_t flags;

	// Optional channel passed to the \|dev\| that serves as an open connection for the client.
	// If DEVICE_ADD_MUST_ISOLATE is set, the client will be connected to the proxy instead.
	// If DEVICE_ADD_INVISIBLE is set, the client will not be connected until
	// device_make_visible is called.
	zx_handle_t client_remote;

	// Optional VMO representing that will get used in devfs inspect tree.
	zx_handle_t inspect_vmo;
	} device_add_args_t;

	typedef struct device_make_visible_args {
	// List of power_states that the device supports.
	// List cannot be more than MAX_DEVICE_POWER_STATES size.
	const device_power_state_info_t* power_states;

	// Number of power states in the list
	uint8_t power_state_count;

	// List of performant states that the device supports.
	// List cannot be more than MAX_DEVICE_PERFORMANCE_STATES size.
	const device_performance_state_info_t* performance_states;

	// Number of performant power states in the list
	uint8_t performance_state_count;
	} device_make_visible_args_t;

	typedef device_make_visible_args_t device_init_reply_args_t;

	struct zx_driver_rec {
	const zx_driver_ops_t* ops;
	zx_driver_t* driver;
	uint32_t log_flags;
	};

	// This global symbol is initialized by the driver loader in devhost
	extern zx_driver_rec_t __zircon_driver_rec__;

	zx_status_t device_add_from_driver(zx_driver_t* drv, zx_device_t* parent, device_add_args_t* args,
	zx_device_t** out);

	// Creates a device and adds it to the devmgr.
	// device_add_args_t contains all "in" arguments.
	// All device_add_args_t values are copied, so device_add_args_t can be stack allocated.
	// The device_add_args_t.name string value is copied.
	// All other pointer fields are copied as pointers.
	// The newly added device will be active before this call returns, so be sure to have
	// the "out" pointer point to your device-local structure so callbacks can access
	// it immediately.
	//
	// If this call is successful, but the device needs to be torn down, device_async_remove() should
	// be called. If \|args->ctx\| is backed by memory, it is the programmer's responsibility to not
	// free that memory until the device's \|release\| hook is called.
	static inline zx_status_t device_add(zx_device_t* parent, device_add_args_t* args,
	zx_device_t** out) {
	return device_add_from_driver(__zircon_driver_rec__.driver, parent, args, out);
	}

	// This is used to signal completion of the device's \|init\| hook.
	// This will make the device visible and able to be unbound.
	// This can be called from any thread - it does not necessarily need to be called before
	// the \|init\| hook returns.
	// If \|status\| is ZX_OK, the driver may provide optional power state information via \|args\|.
	// If \|status\| is not ZX_OK, the device will be scheduled to be removed.
	void device_init_reply(zx_device_t* device, zx_status_t status,
	const device_init_reply_args_t* args);

	zx_status_t device_rebind(zx_device_t* device);
	void device_make_visible(zx_device_t* device, const device_make_visible_args_t* args);

	// Schedules the removal of the given device and all its descendents. When a device is
	// being removed, its \|unbind\| hook will be invoked.
	// It is safe to call this as long as the device has not completed its \|release\| hook.
	// Multiple requests to remove the same device will have no effect.
	void device_async_remove(zx_device_t* device);
	// This is used to signal completion of the device's \|unbind\| hook.
	// This does not necessarily need to be called from within the \|unbind\| hook.
	void device_unbind_reply(zx_device_t* device);

	// This is used to signal completion of the device's \|suspend\| hook.
	// Need not necessarily need to be called from within the \|suspend\| hook.
	// \|status\| is the status of the suspend.
	// If \|status\| is success, the \|out_state\| is same as the requested_state that is
	// sent to the suspend hook. If \|status\| is failure, the \|out_state\| is the
	// state that the device can go into.
	void device_suspend_reply(zx_device_t* device, zx_status_t status, uint8_t out_state);

	// This is used to signal completion of the device's \|resume\| hook.
	// Need not necessarily need to be called from within the \|resume\| hook.
	// \|status\| is the status of the resume operation.
	// If \|status\| is success, the \|out_perf_state\| has the working performance state
	// that the device is in currently.
	// If \|status\| is failure, the \|out_power_state\| has the power state
	// the device is in currently.
	void device_resume_reply(zx_device_t* device, zx_status_t status, uint8_t out_power_state,
	uint32_t out_perf_state);

	// Retrieves a profile handle into \|out_profile\| from the scheduler for the
	// given \|priority\| and \|name\|. Ownership of \|out_profile\| is given to the
	// caller. See fuchsia.scheduler.ProfileProvider for more detail.
	//
	// The profile handle can be used with zx_object_set_profile() to control thread
	// priority.
	//
	// The current arguments are transitional, and will likely change in the future.
	zx_status_t device_get_profile(zx_device_t* device, uint32_t priority, const char* name,
	zx_handle_t* out_profile);

	// Retrieves a deadline profile handle into \|out_profile\| from the scheduler for
	// the given deadline parameters. See \|device_get_profile\|
	zx_status_t device_get_deadline_profile(zx_device_t* device, uint64_t capacity, uint64_t deadline,
	uint64_t period, const char* name,
	zx_handle_t* out_profile);

	// A description of a part of a device fragment. It provides a bind program
	// that will match a device on the path from the root of the device tree to the
	// target device.
	typedef struct device_fragment_part {
	uint32_t instruction_count;
	const zx_bind_inst_t* match_program;
	} device_fragment_part_t;

	// A description of a device that makes up part of a composite device. The
	// particular device is identified by a sequence of part descriptions. Each
	// part description must match either the target device or one of its ancestors.
	// The first element in \|parts\| must describe the root of the device tree. The
	// last element in \|parts\| must describe the target device itself. The
	// remaining elements of \|parts\| must match devices on the path from the root to
	// the target device, in order. Some of those devices may be skipped, but every
	// element of \|parts\| must have a match. Every device on the path that has a
	// property from the range [BIND_TOPO_START, BIND_TOPO_END] must be matched to
	// an element of \|parts\|. This sequences of matches between \|parts\| and devices
	// must be unique.
	typedef struct device_fragment {
	const char* name;
	uint32_t parts_count;
	const device_fragment_part_t* parts;
	} device_fragment_t;

	//
	typedef struct device_metadata {
	uint32_t type;
	const void* data;
	size_t length;
	} device_metadata_t;

	// A description of the composite device with properties \|props\| and made of
	// \|fragments\| devices. The composite device will reside in the same devhost
	// as the device that matches \|fragments[coresident_device_index]\|, unless
	// \|coresident_device_index\| is UINT32_MAX, in which case it reside in a new devhost.
	// \|metadata_list\| contains the metadata to be added to the composite device, if any.
	typedef struct composite_device_desc {
	const zx_device_prop_t* props;
	size_t props_count;
	const device_fragment_t* fragments;
	size_t fragments_count;
	uint32_t coresident_device_index;
	const device_metadata_t* metadata_list;
	size_t metadata_count;
	} composite_device_desc_t;

	// Neccesary because banjo cannot generate this type correctly.
	typedef struct composite_device_fragment {
	char name[32];
	zx_device_t* device;
	} composite_device_fragment_t;

	// Create a composite device with the properties \|comp_desc\|.
	// Once all of the fragment devices are found, the composite
	// device will be published with protocol_id ZX_PROTOCOL_COMPOSITE and the
	// given properties. A driver may then bind to the created device, and
	// access its parents via the protocol operations returned by
	// get_protocol(ZX_PROTOCOL_COMPOSITE).
	//
	// \|name\| must be no longer than ZX_DEVICE_NAME_MAX, and is used primarily as a
	// diagnostic.
	//
	// \|dev\| must be the zx_device_t corresponding to the "sys" device (i.e., the
	// Platform Bus Driver's device).
	zx_status_t device_add_composite(zx_device_t* dev, const char* name,
	const composite_device_desc_t* comp_desc);

	// temporary accessor for root resource handle
	zx_handle_t get_root_resource(void);

	// Callback type for load_firmware.
	typedef void (load_firmware_callback_t)(void ctx, zx_status_t status, zx_handle_t fw,
	size_t size);

	// Drivers may need to load firmware for a device, typically during the call to
	// bind the device. The devmgr will look for the firmware at the given path
	// relative to system-defined locations for device firmware. The load will be done asynchronously,
	// and the given callback will be called with the status of the call, a handle to the fw (or
	// ZX_HANDLE_INVALID if invalid), and the size of the loaded firmware.
	void load_firmware_async(zx_device_t* device, const char* path, load_firmware_callback_t callback,
	void* context);

	// Synchronous version of load_firmware_async that blocks the current thread until the firmware is
	// loaded. Care should be taken when using this variant, as it may cause deadlocks if storage is
	// backed by a driver in the same driver host.
	zx_status_t load_firmware(zx_device_t* device, const char* path, zx_handle_t* fw, size_t* size);

	// Protocol Identifiers
	#define DDK_PROTOCOL_DEF(tag, val, name, flags) ZX_PROTOCOL_##tag = val,
	enum {
	#include <ddk/protodefs.h>
	};

	__END_CDECLS

	#endif // SRC_LIB_DDK_INCLUDE_DDK_DRIVER_H_