xref: /xnu-8019.80.24/osfmk/kern/kern_types.h (revision a325d9c4a84054e40bbe985afedcb50ab80993ea)

/*
 * Copyright (c) 2000-2007 Apple Inc. All rights reserved.
 *
 * @APPLE_OSREFERENCE_LICENSE_HEADER_START@
 *
 * This file contains Original Code and/or Modifications of Original Code
 * as defined in and that are subject to the Apple Public Source License
 * Version 2.0 (the 'License'). You may not use this file except in
 * compliance with the License. The rights granted to you under the License
 * may not be used to create, or enable the creation or redistribution of,
 * unlawful or unlicensed copies of an Apple operating system, or to
 * circumvent, violate, or enable the circumvention or violation of, any
 * terms of an Apple operating system software license agreement.
 *
 * Please obtain a copy of the License at
 * http://www.opensource.apple.com/apsl/ and read it before using this file.
 *
 * The Original Code and all software distributed under the License are
 * distributed on an 'AS IS' basis, WITHOUT WARRANTY OF ANY KIND, EITHER
 * EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES,
 * INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY,
 * FITNESS FOR A PARTICULAR PURPOSE, QUIET ENJOYMENT OR NON-INFRINGEMENT.
 * Please see the License for the specific language governing rights and
 * limitations under the License.
 *
 * @APPLE_OSREFERENCE_LICENSE_HEADER_END@
 */
/*
 * @OSF_COPYRIGHT@
 */

#ifndef _KERN_KERN_TYPES_H_
#define _KERN_KERN_TYPES_H_

#include <stdint.h>
#include <mach/mach_types.h>
#include <mach/machine/vm_types.h>

#ifdef  KERNEL_PRIVATE

#ifndef MACH_KERNEL_PRIVATE

struct zone;

#ifndef __LP64__
struct wait_queue { unsigned int opaque[2]; uintptr_t opaquep[2]; };
#else
struct wait_queue { unsigned char opaque[32]; };
#endif

#endif  /* MACH_KERNEL_PRIVATE */

typedef struct zone                     *zone_t;
#define         ZONE_NULL               ((zone_t) 0)

typedef struct wait_queue               *wait_queue_t;
#define         WAIT_QUEUE_NULL         ((wait_queue_t) 0)
#define                 SIZEOF_WAITQUEUE        sizeof(struct wait_queue)

typedef void *                          ipc_kobject_t;
#define         IKO_NULL                        ((ipc_kobject_t) 0)

#endif  /* KERNEL_PRIVATE */

typedef void *event_t;          /* wait event */
#define         NO_EVENT                        ((event_t) 0)

typedef uint64_t event64_t;             /* 64 bit wait event */
#define         NO_EVENT64              ((event64_t) 0)
#define         CAST_EVENT64_T(a_ptr)   ((event64_t)((uintptr_t)(a_ptr)))

/*
 *	Possible wait_result_t values.
 */
typedef int wait_result_t;
#define THREAD_WAITING          -1              /* thread is waiting */
#define THREAD_AWAKENED         0               /* normal wakeup */
#define THREAD_TIMED_OUT        1               /* timeout expired */
#define THREAD_INTERRUPTED      2               /* aborted/interrupted */
#define THREAD_RESTART          3               /* restart operation entirely */
#define THREAD_NOT_WAITING      10              /* thread didn't need to wait */

typedef void (*thread_continue_t)(void *, wait_result_t);
#define THREAD_CONTINUE_NULL    ((thread_continue_t) NULL)

/*
 * Interruptible flag for waits.
 *
 * THREAD_UNINT: Uninterruptible wait
 *   Wait will only end when someone explicitly wakes up the thread, or if the
 *   wait timeout expires.
 *
 *   Use this state if the system as a whole cannot recover from a thread being
 *   interrupted out of the wait.
 *
 * THREAD_INTERRUPTIBLE:
 *    Wait will end if someone explicitly wakes up the thread, the wait timeout
 *    expires,  or the current thread is being terminated.
 *
 *    This value can be used when your operation may not be cleanly restartable
 *    for the current process or thread (i.e. the loss of state would be only visible
 *    to the current client).  Since the thread is exiting anyways, you're willing
 *    to cut the operation short.  The system as a whole must be able to cleanly
 *    deal with the interruption (i.e. remain in a consistent and recoverable state).
 *
 * THREAD_ABORTSAFE:
 *    Wait will end if someone explicitly wakes up the thread, the wait timeout
 *    expires, the current thread is being terminated, if any signal arrives for
 *    the task, or thread_abort_safely() is called on the thread.
 *
 *    Using this value means that you are willing to be interrupted in the face
 *    of any user signal, and safely rewind the thread back to the user/kernel
 *    boundary.  Many syscalls will try to restart the operation they were performing
 *    after the signal has been handled.
 *
 *    You must provide this value for any unbounded wait - otherwise you will
 *    pend user signals forever.
 *
 * THREAD_WAIT_NOREPORT:
 *    The scheduler has a callback (sched_call) that some subsystems use to
 *    decide whether more threads should be thrown at a given problem by trying
 *    to maintain a good level of concurrency.
 *
 *    When the wait will not be helped by adding more threads (e.g. lock
 *    contention), using this flag as an argument to assert_wait* (or any of its
 *    wrappers) will prevent the next wait/block to cause thread creation.
 *
 *    This comes in two flavors: THREAD_WAIT_NOREPORT_KERNEL, and
 *    THREAD_WAIT_NOREPORT_USER to prevent reporting about the wait for kernel
 *    and user threads respectively.
 *
 * Thread interrupt mask:
 *
 *    The current maximum interruptible state for the thread, as set by
 *    thread_interrupt_level(), will limit the conditions that will cause a wake.
 *    This is useful for code that can't be interrupted to set before calling code
 *    that doesn't know that.
 *
 * Thread termination vs safe abort:
 *
 *    Termination abort: thread_abort(), thread_terminate()
 *
 *    A termination abort is sticky.  Once a thread is marked for termination, every
 *    THREAD_INTERRUPTIBLE wait will return immediately with THREAD_INTERRUPTED
 *    until the thread successfully exits.
 *
 *    Safe abort: thread_abort_safely()
 *
 *    A safe abort is not sticky.  The current wait, (or the next wait if the thread
 *    is not currently waiting) will be interrupted, but then the abort condition is cleared.
 *    The next wait will sleep as normal. Safe aborts only have a single effect.
 *
 *    The path back to the user/kernel boundary must not make any further unbounded
 *    wait calls. The waiter should detect the THREAD_INTERRUPTED return code
 *    from an ABORTSAFE wait and return an error code that causes its caller
 *    to understand that the current operation has been interrupted, and its
 *    caller should return a similar error code, and so on until the
 *    user/kernel boundary is reached.  For Mach, the error code is usually KERN_ABORTED,
 *    for BSD it is EINTR.
 *
 *    Debuggers rely on the safe abort mechanism - a signaled thread must return to
 *    the AST at the user/kernel boundary for the debugger to finish attaching.
 *
 *    No wait/block will ever disappear a thread out from under the waiter. The block
 *    call will always either return or call the passed in continuation.
 */
typedef int wait_interrupt_t;
#define THREAD_UNINT                    0x00000000  /* not interruptible      */
#define THREAD_INTERRUPTIBLE            0x00000001  /* may not be restartable */
#define THREAD_ABORTSAFE                0x00000002  /* abortable safely       */
#define THREAD_WAIT_NOREPORT_KERNEL     0x80000000
#define THREAD_WAIT_NOREPORT_USER       0x40000000
#define THREAD_WAIT_NOREPORT            (THREAD_WAIT_NOREPORT_KERNEL | THREAD_WAIT_NOREPORT_USER)

typedef int wait_timeout_urgency_t;
#define TIMEOUT_URGENCY_SYS_NORMAL      0x00            /* use default leeway thresholds for system */
#define TIMEOUT_URGENCY_SYS_CRITICAL    0x01            /* use critical leeway thresholds for system */
#define TIMEOUT_URGENCY_SYS_BACKGROUND  0x02            /* use background leeway thresholds for system */

#define TIMEOUT_URGENCY_USER_MASK       0x10            /* mask to identify user timeout urgency classes */
#define TIMEOUT_URGENCY_USER_NORMAL     0x10            /* use default leeway thresholds for user */
#define TIMEOUT_URGENCY_USER_CRITICAL   0x11            /* use critical leeway thresholds for user */
#define TIMEOUT_URGENCY_USER_BACKGROUND 0x12            /* use background leeway thresholds for user */

#define TIMEOUT_URGENCY_MASK            0x13            /* mask to identify timeout urgency */

#define TIMEOUT_URGENCY_LEEWAY          0x20            /* don't ignore provided leeway value */

#define TIMEOUT_URGENCY_FIRST_AVAIL     0x40            /* first available bit outside of urgency mask/leeway */
#define TIMEOUT_URGENCY_RATELIMITED     0x80

/*
 * Timeout and deadline tokens for waits.
 * The following tokens define common values for leeway and deadline parameters.
 */
#define TIMEOUT_NO_LEEWAY               (0ULL)
#define TIMEOUT_WAIT_FOREVER            (0ULL)

#ifdef  KERNEL_PRIVATE

/*
 * n.b. this is defined in thread_call.h, but in the TIMEOUT_URGENCY flags space:
 * #define THREAD_CALL_CONTINUOUS	0x100
 */

#ifdef  MACH_KERNEL_PRIVATE

#include <kern/misc_protos.h>
typedef  struct clock                   *clock_t;

typedef struct mig_object               *mig_object_t;
#define MIG_OBJECT_NULL                 ((mig_object_t) 0)

typedef struct mig_notify               *mig_notify_t;
#define MIG_NOTIFY_NULL                 ((mig_notify_t) 0)

typedef struct pset_node                *pset_node_t;
#define PSET_NODE_NULL                  ((pset_node_t) 0)

typedef struct affinity_set             *affinity_set_t;
#define AFFINITY_SET_NULL               ((affinity_set_t) 0)

typedef struct run_queue               *run_queue_t;
#define RUN_QUEUE_NULL                 ((run_queue_t) 0)

typedef struct grrr_run_queue               *grrr_run_queue_t;
#define GRRR_RUN_QUEUE_NULL                 ((grrr_run_queue_t) 0)

typedef struct grrr_group                                       *grrr_group_t;
#define GRRR_GROUP_NULL                                         ((grrr_group_t) 0)

#if defined(CONFIG_SCHED_MULTIQ)
typedef struct sched_group              *sched_group_t;
#define SCHED_GROUP_NULL                ((sched_group_t) 0)
#endif /* defined(CONFIG_SCHED_MULTIQ) */

#else   /* MACH_KERNEL_PRIVATE */

struct wait_queue_set;
struct _wait_queue_link;

#endif  /* MACH_KERNEL_PRIVATE */

typedef struct wait_queue_set   *wait_queue_set_t;
#define WAIT_QUEUE_SET_NULL     ((wait_queue_set_t)0)
#define SIZEOF_WAITQUEUE_SET    wait_queue_set_size()

typedef struct _wait_queue_link *wait_queue_link_t;
#define WAIT_QUEUE_LINK_NULL    ((wait_queue_link_t)0)
#define SIZEOF_WAITQUEUE_LINK   wait_queue_link_size()

typedef struct perfcontrol_state        *perfcontrol_state_t;
#define PERFCONTROL_STATE_NULL          ((perfcontrol_state_t)0)

/*
 * Enum to define the event which caused the CLPC callout
 */
typedef enum perfcontrol_event {
	/*
	 * Thread State Update Events
	 * Used to indicate events that update properties for
	 * a given thread. These events are passed as part of the
	 * sched_perfcontrol_state_update_t callout
	 */
	QUANTUM_EXPIRY          = 1,
	THREAD_GROUP_UPDATE     = 2,
	PERFCONTROL_ATTR_UPDATE = 3,
	/*
	 * Context Switch Events
	 * Used to indicate events that switch from one thread
	 * to the other. These events are passed as part of the
	 * sched_perfcontrol_csw_t callout.
	 */
	CONTEXT_SWITCH          = 10,
	IDLE                    = 11
} perfcontrol_event;

/*
 * Flags for the sched_perfcontrol_csw_t, sched_perfcontrol_state_update_t
 * & sched_perfcontrol_thread_group_blocked_t/sched_perfcontrol_thread_group_unblocked_t
 * callouts.
 * Currently defined flags are:
 *
 * PERFCONTROL_CALLOUT_WAKE_UNSAFE: Flag to indicate its unsafe to
 * do a wakeup as part of this callout. If this is set, it
 * indicates that the scheduler holds a spinlock which might be needed
 * in the wakeup path. In that case CLPC should do a thread_call
 * instead of a direct wakeup to run their workloop thread.
 *
 * PERFCONTROL_CALLOUT_BLOCKING_TG_RENDER_SERVER: Flag to indicate
 * that the render server thread group is blocking/unblocking progress
 * of another thread group. The render server thread group is well
 * known to CLPC, so XNU simply passes this flag instead of taking
 * a reference on it. It is illegal to pass both the TG identity and
 * this flag in the callout; this flag should only be set with the
 * blocking/unblocking TG being NULL.
 */
#define PERFCONTROL_CALLOUT_WAKE_UNSAFE                 (0x1)
#define PERFCONTROL_CALLOUT_BLOCKING_TG_RENDER_SERVER   (0x2)

/*
 * Enum to define the perfcontrol class for thread.
 * thread_get_perfcontrol_class() takes the thread's
 * priority, QoS, urgency etc. into consideration and
 * produces a value in this enum.
 */
typedef enum perfcontrol_class {
	/* Idle thread */
	PERFCONTROL_CLASS_IDLE           = 1,
	/* Kernel thread */
	PERFCONTROL_CLASS_KERNEL         = 2,
	/* Realtime Thread */
	PERFCONTROL_CLASS_REALTIME       = 3,
	/* Background Thread */
	PERFCONTROL_CLASS_BACKGROUND     = 4,
	/* Utility Thread */
	PERFCONTROL_CLASS_UTILITY        = 5,
	/* Non-UI Thread (Default/Legacy) */
	PERFCONTROL_CLASS_NONUI          = 6,
	/* UI Thread (UI/IN) */
	PERFCONTROL_CLASS_UI             = 7,
	/* Above UI Thread */
	PERFCONTROL_CLASS_ABOVEUI        = 8,
	/* Maximum class */
	PERFCONTROL_CLASS_MAX            = 9,
} perfcontrol_class_t;

/*
 * struct sched_clutch_edge
 *
 * Represents an edge from one cluster to another in the Edge Scheduler.
 * An edge has the following properties:
 * - Edge Weight: A value which indicates the likelihood of migrating threads
 *   across that edge. The actual unit of the edge weight is in (usecs) of
 *   scheduling delay.
 * - Migration Allowed: Bit indicating if migrations are allowed across this
 *   edge from src to dst.
 * - Steal Allowed: Bit indicating whether the dst cluster is allowed to steal
 *   across that edge when a processor in that cluster goes idle.
 *
 * These values can be modified by CLPC for better load balancing, thermal
 * mitigations etc.
 */
typedef union sched_clutch_edge {
	struct {
		uint32_t
		/* boolean_t */ sce_migration_allowed : 1,
		/* boolean_t */ sce_steal_allowed     : 1,
		    _reserved             : 30;
		uint32_t        sce_migration_weight;
	};
	uint64_t sce_edge_packed;
} sched_clutch_edge;

/*
 * Cluster shared resource management
 *
 * The options describe the various shared cluster resource
 * types that can be contended under load and need special
 * handling from the scheduler.
 */
__options_decl(cluster_shared_rsrc_type_t, uint32_t, {
	CLUSTER_SHARED_RSRC_TYPE_RR                     = 0,
	CLUSTER_SHARED_RSRC_TYPE_NATIVE_FIRST           = 1,
	CLUSTER_SHARED_RSRC_TYPE_COUNT                  = 2,
	CLUSTER_SHARED_RSRC_TYPE_MIN                    = CLUSTER_SHARED_RSRC_TYPE_RR,
	CLUSTER_SHARED_RSRC_TYPE_NONE                   = CLUSTER_SHARED_RSRC_TYPE_COUNT,
});

#endif  /* KERNEL_PRIVATE */

#endif  /* _KERN_KERN_TYPES_H_ */