[apple/xnu.git] / osfmk / kern / clock_oldops.c

/*
 * Copyright (c) 2000-2008 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@
 */
/*
 *	DEPRECATED INTERFACES - Should be removed
 *
 *	Purpose:	Routines for the creation and use of kernel
 *			alarm clock services. This file and the ipc
 *			routines in kern/ipc_clock.c constitute the
 *			machine-independent clock service layer.
 */

#include <mach/mach_types.h>

#include <kern/host.h>
#include <kern/spl.h>
#include <kern/sched_prim.h>
#include <kern/thread.h>
#include <kern/ipc_host.h>
#include <kern/clock.h>
#include <kern/zalloc.h>

#include <ipc/ipc_types.h>
#include <ipc/ipc_port.h>

#include <mach/mach_traps.h>
#include <mach/mach_time.h>

#include <mach/clock_server.h>
#include <mach/clock_reply.h>
#include <mach/clock_priv_server.h>

#include <mach/mach_host_server.h>
#include <mach/host_priv_server.h>
#include <libkern/section_keywords.h>

/*
 * Actual clock alarm structure. Used for user clock_sleep() and
 * clock_alarm() calls. Alarms are allocated from the alarm free
 * list and entered in time priority order into the active alarm
 * chain of the target clock.
 */
struct	alarm {
	struct	alarm	*al_next;		/* next alarm in chain */
	struct	alarm	*al_prev;		/* previous alarm in chain */
	int				al_status;		/* alarm status */
	mach_timespec_t	al_time;		/* alarm time */
	struct {				/* message alarm data */
		int				type;		/* alarm type */
		ipc_port_t		port;		/* alarm port */
		mach_msg_type_name_t
						port_type;	/* alarm port type */
		struct	clock	*clock;		/* alarm clock */
		void			*data;		/* alarm data */
	} al_alrm;
#define al_type		al_alrm.type
#define al_port		al_alrm.port
#define al_port_type	al_alrm.port_type
#define al_clock	al_alrm.clock
#define al_data		al_alrm.data
	long			al_seqno;		/* alarm sequence number */
};
typedef struct alarm	alarm_data_t;

/* alarm status */
#define ALARM_FREE	0		/* alarm is on free list */
#define	ALARM_SLEEP	1		/* active clock_sleep() */
#define ALARM_CLOCK	2		/* active clock_alarm() */
#define ALARM_DONE	4		/* alarm has expired */

/* local data declarations */
decl_simple_lock_data(static,alarm_lock)	/* alarm synchronization */
static struct	zone		*alarm_zone;	/* zone for user alarms */
static struct	alarm		*alrmfree;		/* alarm free list pointer */
static struct	alarm		*alrmdone;		/* alarm done list pointer */
static struct	alarm		*alrmlist;
static long					alrm_seqno;		/* uniquely identifies alarms */
static thread_call_data_t	alarm_done_call;
static timer_call_data_t	alarm_expire_timer;

extern	struct clock	clock_list[];
extern	int		clock_count;

static void		post_alarm(
					alarm_t			alarm);

static void		set_alarm(
					mach_timespec_t	*alarm_time);

static int		check_time(
					alarm_type_t	alarm_type,
					mach_timespec_t	*alarm_time,
					mach_timespec_t	*clock_time);

static void		alarm_done(void);

static void		alarm_expire(void);

static kern_return_t	clock_sleep_internal(
							clock_t				clock,
							sleep_type_t		sleep_type,
							mach_timespec_t		*sleep_time);

int		rtclock_init(void);

kern_return_t	rtclock_gettime(
	mach_timespec_t			*cur_time);

kern_return_t	rtclock_getattr(
	clock_flavor_t			flavor,
	clock_attr_t			attr,
	mach_msg_type_number_t	*count);

SECURITY_READ_ONLY_EARLY(struct clock_ops) sysclk_ops = {
	NULL,			rtclock_init,
	rtclock_gettime,
	rtclock_getattr,
};

kern_return_t	calend_gettime(
	mach_timespec_t			*cur_time);

kern_return_t	calend_getattr(
	clock_flavor_t			flavor,
	clock_attr_t			attr,
	mach_msg_type_number_t	*count);

SECURITY_READ_ONLY_EARLY(struct clock_ops) calend_ops = {
	NULL, NULL,
	calend_gettime,
	calend_getattr,
};

/*
 *	Macros to lock/unlock clock system.
 */
#define LOCK_ALARM(s)			\
	s = splclock();			\
	simple_lock(&alarm_lock);

#define UNLOCK_ALARM(s)			\
	simple_unlock(&alarm_lock);	\
	splx(s);

void
clock_oldconfig(void)
{
	clock_t			clock;
	int	i;

	simple_lock_init(&alarm_lock, 0);
	thread_call_setup(&alarm_done_call, (thread_call_func_t)alarm_done, NULL);
	timer_call_setup(&alarm_expire_timer, (timer_call_func_t)alarm_expire, NULL);

	/*
	 * Configure clock devices.
	 */
	for (i = 0; i < clock_count; i++) {
		clock = &clock_list[i];
		if (clock->cl_ops && clock->cl_ops->c_config) {
			if ((*clock->cl_ops->c_config)() == 0)
				clock->cl_ops = NULL;
		}
	}

	/* start alarm sequence numbers at 0 */
	alrm_seqno = 0;
}

void
clock_oldinit(void)
{
	clock_t			clock;
	int	i;

	/*
	 * Initialize basic clock structures.
	 */
	for (i = 0; i < clock_count; i++) {
		clock = &clock_list[i];
		if (clock->cl_ops && clock->cl_ops->c_init)
			(*clock->cl_ops->c_init)();
	}
}

/*
 * Initialize the clock ipc service facility.
 */
void
clock_service_create(void)
{
	clock_t			clock;
	int	i;

	/*
	 * Initialize ipc clock services.
	 */
	for (i = 0; i < clock_count; i++) {
		clock = &clock_list[i];
		if (clock->cl_ops) {
			ipc_clock_init(clock);
			ipc_clock_enable(clock);
		}
	}

	/*
	 * Perform miscellaneous late
	 * initialization.
	 */
	i = sizeof(struct alarm);
	alarm_zone = zinit(i, (4096/i)*i, 10*i, "alarms");
}

/*
 * Get the service port on a clock.
 */
kern_return_t
host_get_clock_service(
	host_t			host,
	clock_id_t		clock_id,
	clock_t			*clock)		/* OUT */
{
	if (host == HOST_NULL || clock_id < 0 || clock_id >= clock_count) {
		*clock = CLOCK_NULL;
		return (KERN_INVALID_ARGUMENT);
	}

	*clock = &clock_list[clock_id];
	if ((*clock)->cl_ops == 0)
		return (KERN_FAILURE);
	return (KERN_SUCCESS);
}

/*
 * Get the control port on a clock.
 */
kern_return_t
host_get_clock_control(
	host_priv_t		host_priv,
	clock_id_t		clock_id,
	clock_t			*clock)		/* OUT */
{
	if (host_priv == HOST_PRIV_NULL ||
			clock_id < 0 || clock_id >= clock_count) {
		*clock = CLOCK_NULL;
		return (KERN_INVALID_ARGUMENT);
	}

	*clock = &clock_list[clock_id];
	if ((*clock)->cl_ops == 0)
		return (KERN_FAILURE);
	return (KERN_SUCCESS);
}

/*
 * Get the current clock time.
 */
kern_return_t
clock_get_time(
	clock_t			clock,
	mach_timespec_t	*cur_time)	/* OUT */
{
	if (clock == CLOCK_NULL)
		return (KERN_INVALID_ARGUMENT);
	return ((*clock->cl_ops->c_gettime)(cur_time));
}

kern_return_t
rtclock_gettime(
	mach_timespec_t		*time)	/* OUT */
{
	clock_sec_t		secs;
	clock_nsec_t	nsecs;

	clock_get_system_nanotime(&secs, &nsecs);
	time->tv_sec = (unsigned int)secs;
	time->tv_nsec = nsecs;

	return (KERN_SUCCESS);
}

kern_return_t
calend_gettime(
	mach_timespec_t		*time)	/* OUT */
{
	clock_sec_t		secs;
	clock_nsec_t	nsecs;

	clock_get_calendar_nanotime(&secs, &nsecs);
	time->tv_sec = (unsigned int)secs;
	time->tv_nsec = nsecs;

	return (KERN_SUCCESS);
}

/*
 * Get clock attributes.
 */
kern_return_t
clock_get_attributes(
	clock_t					clock,
	clock_flavor_t			flavor,
	clock_attr_t			attr,		/* OUT */
	mach_msg_type_number_t	*count)		/* IN/OUT */
{
	if (clock == CLOCK_NULL)
		return (KERN_INVALID_ARGUMENT);
	if (clock->cl_ops->c_getattr)
		return (clock->cl_ops->c_getattr(flavor, attr, count));
	return (KERN_FAILURE);
}

kern_return_t
rtclock_getattr(
	clock_flavor_t			flavor,
	clock_attr_t			attr,		/* OUT */
	mach_msg_type_number_t	*count)		/* IN/OUT */
{
	if (*count != 1)
		return (KERN_FAILURE);

	switch (flavor) {

	case CLOCK_GET_TIME_RES:	/* >0 res */
	case CLOCK_ALARM_CURRES:	/* =0 no alarm */
	case CLOCK_ALARM_MINRES:
	case CLOCK_ALARM_MAXRES:
		*(clock_res_t *) attr = NSEC_PER_SEC / 100;
		break;

	default:
		return (KERN_INVALID_VALUE);
	}

	return (KERN_SUCCESS);
}

kern_return_t
calend_getattr(
	clock_flavor_t			flavor,
	clock_attr_t			attr,		/* OUT */
	mach_msg_type_number_t	*count)		/* IN/OUT */
{
	if (*count != 1)
		return (KERN_FAILURE);

	switch (flavor) {

	case CLOCK_GET_TIME_RES:	/* >0 res */
		*(clock_res_t *) attr = NSEC_PER_SEC / 100;
		break;

	case CLOCK_ALARM_CURRES:	/* =0 no alarm */
	case CLOCK_ALARM_MINRES:
	case CLOCK_ALARM_MAXRES:
		*(clock_res_t *) attr = 0;
		break;

	default:
		return (KERN_INVALID_VALUE);
	}

	return (KERN_SUCCESS);
}

/*
 * Set the current clock time.
 */
kern_return_t
clock_set_time(
	clock_t					clock,
__unused mach_timespec_t	new_time)
{
	if (clock == CLOCK_NULL)
		return (KERN_INVALID_ARGUMENT);
	return (KERN_FAILURE);
}

/*
 * Set the clock alarm resolution.
 */
kern_return_t
clock_set_attributes(
	clock_t						clock,
__unused clock_flavor_t			flavor,
__unused clock_attr_t			attr,
__unused mach_msg_type_number_t	count)
{
	if (clock == CLOCK_NULL)
		return (KERN_INVALID_ARGUMENT);
	return (KERN_FAILURE);
}

/*
 * Setup a clock alarm.
 */
kern_return_t
clock_alarm(
	clock_t					clock,
	alarm_type_t			alarm_type,
	mach_timespec_t			alarm_time,
	ipc_port_t				alarm_port,
	mach_msg_type_name_t	alarm_port_type)
{
	alarm_t					alarm;
	mach_timespec_t			clock_time;
	int						chkstat;
	kern_return_t			reply_code;
	spl_t					s;

	if (clock == CLOCK_NULL)
		return (KERN_INVALID_ARGUMENT);
	if (clock != &clock_list[SYSTEM_CLOCK])
		return (KERN_FAILURE);
	if (IP_VALID(alarm_port) == 0)
		return (KERN_INVALID_CAPABILITY);

	/*
	 * Check alarm parameters. If parameters are invalid,
	 * send alarm message immediately.
	 */
	(*clock->cl_ops->c_gettime)(&clock_time);
	chkstat = check_time(alarm_type, &alarm_time, &clock_time);
	if (chkstat <= 0) {
		reply_code = (chkstat < 0 ? KERN_INVALID_VALUE : KERN_SUCCESS);
		clock_alarm_reply(alarm_port, alarm_port_type,
				  reply_code, alarm_type, clock_time);
		return (KERN_SUCCESS);
	}

	/*
	 * Get alarm and add to clock alarm list.
	 */

	LOCK_ALARM(s);
	if ((alarm = alrmfree) == 0) {
		UNLOCK_ALARM(s);
		alarm = (alarm_t) zalloc(alarm_zone);
		if (alarm == 0)
			return (KERN_RESOURCE_SHORTAGE);
		LOCK_ALARM(s);
	}
	else
		alrmfree = alarm->al_next;

	alarm->al_status = ALARM_CLOCK;
	alarm->al_time = alarm_time;
	alarm->al_type = alarm_type;
	alarm->al_port = alarm_port;
	alarm->al_port_type = alarm_port_type;
	alarm->al_clock = clock;
	alarm->al_seqno = alrm_seqno++;
	post_alarm(alarm);
	UNLOCK_ALARM(s);

	return (KERN_SUCCESS);
}

/*
 * Sleep on a clock. System trap. User-level libmach clock_sleep
 * interface call takes a mach_timespec_t sleep_time argument which it
 * converts to sleep_sec and sleep_nsec arguments which are then
 * passed to clock_sleep_trap.
 */
kern_return_t
clock_sleep_trap(
	struct clock_sleep_trap_args *args)
{
	mach_port_name_t	clock_name = args->clock_name;
	sleep_type_t		sleep_type = args->sleep_type;
	int					sleep_sec = args->sleep_sec;
	int					sleep_nsec = args->sleep_nsec;
	mach_vm_address_t	wakeup_time_addr = args->wakeup_time;  
	clock_t				clock;
	mach_timespec_t		swtime;
	kern_return_t		rvalue;

	/*
	 * Convert the trap parameters.
	 */
	if (clock_name == MACH_PORT_NULL)
		clock = &clock_list[SYSTEM_CLOCK];
	else
		clock = port_name_to_clock(clock_name);

	swtime.tv_sec  = sleep_sec;
	swtime.tv_nsec = sleep_nsec;

	/*
	 * Call the actual clock_sleep routine.
	 */
	rvalue = clock_sleep_internal(clock, sleep_type, &swtime);

	/*
	 * Return current time as wakeup time.
	 */
	if (rvalue != KERN_INVALID_ARGUMENT && rvalue != KERN_FAILURE) {
		copyout((char *)&swtime, wakeup_time_addr, sizeof(mach_timespec_t));
	}
	return (rvalue);
}	

static kern_return_t
clock_sleep_internal(
	clock_t				clock,
	sleep_type_t		sleep_type,
	mach_timespec_t		*sleep_time)
{
	alarm_t				alarm;
	mach_timespec_t		clock_time;
	kern_return_t		rvalue;
	int					chkstat;
	spl_t				s;

	if (clock == CLOCK_NULL)
		return (KERN_INVALID_ARGUMENT);

	if (clock != &clock_list[SYSTEM_CLOCK])
		return (KERN_FAILURE);

	/*
	 * Check sleep parameters. If parameters are invalid
	 * return an error, otherwise post alarm request.
	 */
	(*clock->cl_ops->c_gettime)(&clock_time);

	chkstat = check_time(sleep_type, sleep_time, &clock_time);
	if (chkstat < 0)
		return (KERN_INVALID_VALUE);
	rvalue = KERN_SUCCESS;
	if (chkstat > 0) {
		wait_result_t wait_result;

		/*
		 * Get alarm and add to clock alarm list.
		 */

		LOCK_ALARM(s);
		if ((alarm = alrmfree) == 0) {
			UNLOCK_ALARM(s);
			alarm = (alarm_t) zalloc(alarm_zone);
			if (alarm == 0)
				return (KERN_RESOURCE_SHORTAGE);
			LOCK_ALARM(s);
		}
		else
			alrmfree = alarm->al_next;

		/*
		 * Wait for alarm to occur.
		 */
		wait_result = assert_wait((event_t)alarm, THREAD_ABORTSAFE);
		if (wait_result == THREAD_WAITING) {
			alarm->al_time = *sleep_time;
			alarm->al_status = ALARM_SLEEP;
			post_alarm(alarm);
			UNLOCK_ALARM(s);

			wait_result = thread_block(THREAD_CONTINUE_NULL);

			/*
			 * Note if alarm expired normally or whether it
			 * was aborted. If aborted, delete alarm from
			 * clock alarm list. Return alarm to free list.
			 */
			LOCK_ALARM(s);
			if (alarm->al_status != ALARM_DONE) {
				assert(wait_result != THREAD_AWAKENED);
				if (((alarm->al_prev)->al_next = alarm->al_next) != NULL)
					(alarm->al_next)->al_prev = alarm->al_prev;
				rvalue = KERN_ABORTED;
			}
			*sleep_time = alarm->al_time;
			alarm->al_status = ALARM_FREE;
		} else {
			assert(wait_result == THREAD_INTERRUPTED);
			assert(alarm->al_status == ALARM_FREE);
			rvalue = KERN_ABORTED;
		}
		alarm->al_next = alrmfree;
		alrmfree = alarm;
		UNLOCK_ALARM(s);
	}
	else
		*sleep_time = clock_time;

	return (rvalue);
}

/*
 * Service clock alarm expirations.
 */
static void
alarm_expire(void)
{
	clock_t				clock;
	alarm_t	alrm1;
	alarm_t	alrm2;
	mach_timespec_t		clock_time;
	mach_timespec_t		*alarm_time;
	spl_t				s;

	clock = &clock_list[SYSTEM_CLOCK];
	(*clock->cl_ops->c_gettime)(&clock_time);

	/*
	 * Update clock alarm list. Alarms that are due are moved
	 * to the alarmdone list to be serviced by a thread callout.
	 */
	LOCK_ALARM(s);
	alrm1 = (alarm_t)&alrmlist;
	while ((alrm2 = alrm1->al_next) != NULL) {
		alarm_time = &alrm2->al_time;
		if (CMP_MACH_TIMESPEC(alarm_time, &clock_time) > 0)
			break;

		/*
		 * Alarm has expired, so remove it from the
		 * clock alarm list.
		 */  
		if ((alrm1->al_next = alrm2->al_next) != NULL)
			(alrm1->al_next)->al_prev = alrm1;

		/*
		 * If a clock_sleep() alarm, wakeup the thread
		 * which issued the clock_sleep() call.
		 */
		if (alrm2->al_status == ALARM_SLEEP) {
			alrm2->al_next = NULL;
			alrm2->al_status = ALARM_DONE;
			alrm2->al_time = clock_time;
			thread_wakeup((event_t)alrm2);
		}

 		/*
		 * If a clock_alarm() alarm, place the alarm on
		 * the alarm done list and schedule the alarm
		 * delivery mechanism.
		 */
		else {
			assert(alrm2->al_status == ALARM_CLOCK);
			if ((alrm2->al_next = alrmdone) != NULL)
				alrmdone->al_prev = alrm2;
			else
				thread_call_enter(&alarm_done_call);
			alrm2->al_prev = (alarm_t)&alrmdone;
			alrmdone = alrm2;
			alrm2->al_status = ALARM_DONE;
			alrm2->al_time = clock_time;
		}
	}

	/*
	 * Setup to expire for the next pending alarm.
	 */
	if (alrm2)
		set_alarm(alarm_time);
	UNLOCK_ALARM(s);
}

static void
alarm_done(void)
{
	alarm_t	alrm;
	kern_return_t		code;
	spl_t				s;

	LOCK_ALARM(s);
	while ((alrm = alrmdone) != NULL) {
		if ((alrmdone = alrm->al_next) != NULL)
			alrmdone->al_prev = (alarm_t)&alrmdone;
		UNLOCK_ALARM(s);

		code = (alrm->al_status == ALARM_DONE? KERN_SUCCESS: KERN_ABORTED);
		if (alrm->al_port != IP_NULL) {
			/* Deliver message to designated port */
			if (IP_VALID(alrm->al_port)) {
				clock_alarm_reply(alrm->al_port, alrm->al_port_type, code,
								  				alrm->al_type, alrm->al_time);
			}

			LOCK_ALARM(s);
			alrm->al_status = ALARM_FREE;
			alrm->al_next = alrmfree;
			alrmfree = alrm;
		}
		else
			panic("clock_alarm_deliver");
	}

	UNLOCK_ALARM(s);
}

/*
 * Post an alarm on the active alarm list.
 *
 * Always called from within a LOCK_ALARM() code section.
 */
static void
post_alarm(
	alarm_t				alarm)
{
	alarm_t	alrm1, alrm2;
	mach_timespec_t		*alarm_time;
	mach_timespec_t		*queue_time;

	/*
	 * Traverse alarm list until queue time is greater
	 * than alarm time, then insert alarm.
	 */
	alarm_time = &alarm->al_time;
	alrm1 = (alarm_t)&alrmlist;
	while ((alrm2 = alrm1->al_next) != NULL) {
		queue_time = &alrm2->al_time;
		if (CMP_MACH_TIMESPEC(queue_time, alarm_time) > 0)
			break;
		alrm1 = alrm2;
	}
	alrm1->al_next = alarm;
	alarm->al_next = alrm2;
	alarm->al_prev = alrm1;
	if (alrm2)
		alrm2->al_prev  = alarm;

	/*
	 * If the inserted alarm is the 'earliest' alarm,
	 * reset the device layer alarm time accordingly.
	 */
	if (alrmlist == alarm)
		set_alarm(alarm_time);
}

static void
set_alarm(
	mach_timespec_t		*alarm_time)
{
	uint64_t	abstime;

	nanotime_to_absolutetime(alarm_time->tv_sec, alarm_time->tv_nsec, &abstime);
	timer_call_enter_with_leeway(&alarm_expire_timer, NULL, abstime, 0, TIMER_CALL_USER_NORMAL, FALSE);
}

/*
 * Check the validity of 'alarm_time' and 'alarm_type'. If either
 * argument is invalid, return a negative value. If the 'alarm_time'
 * is now, return a 0 value. If the 'alarm_time' is in the future,
 * return a positive value.
 */
static int
check_time(
	alarm_type_t		alarm_type,
	mach_timespec_t		*alarm_time,
	mach_timespec_t		*clock_time)
{
	int					result;

	if (BAD_ALRMTYPE(alarm_type))
		return (-1);
	if (BAD_MACH_TIMESPEC(alarm_time))
		return (-1);
	if ((alarm_type & ALRMTYPE) == TIME_RELATIVE)
		ADD_MACH_TIMESPEC(alarm_time, clock_time);

	result = CMP_MACH_TIMESPEC(alarm_time, clock_time);

	return ((result >= 0)? result: 0);
}

#ifndef	__LP64__

mach_timespec_t
clock_get_system_value(void)
{
	clock_t				clock = &clock_list[SYSTEM_CLOCK];
	mach_timespec_t		value;

	(void) (*clock->cl_ops->c_gettime)(&value);

	return value;
}

mach_timespec_t
clock_get_calendar_value(void)
{
	clock_t				clock = &clock_list[CALENDAR_CLOCK];
	mach_timespec_t		value = MACH_TIMESPEC_ZERO;

	(void) (*clock->cl_ops->c_gettime)(&value);

	return value;
}

#endif	/* __LP64__ */
Commit	Line	Data
0c530ab8	1	/*
b0d623f7	2	* Copyright (c) 2000-2008 Apple Inc. All rights reserved.
0c530ab8	3	*
2d21ac55	4	* @APPLE_OSREFERENCE_LICENSE_HEADER_START@
0c530ab8	5	*
2d21ac55 A	6	* This file contains Original Code and/or Modifications of Original Code
	7	* as defined in and that are subject to the Apple Public Source License
	8	* Version 2.0 (the 'License'). You may not use this file except in
	9	* compliance with the License. The rights granted to you under the License
	10	* may not be used to create, or enable the creation or redistribution of,
	11	* unlawful or unlicensed copies of an Apple operating system, or to
	12	* circumvent, violate, or enable the circumvention or violation of, any
	13	* terms of an Apple operating system software license agreement.
0c530ab8	14	*
2d21ac55 A	15	* Please obtain a copy of the License at
	16	* http://www.opensource.apple.com/apsl/ and read it before using this file.
	17	*
	18	* The Original Code and all software distributed under the License are
	19	* distributed on an 'AS IS' basis, WITHOUT WARRANTY OF ANY KIND, EITHER
0c530ab8 A	20	* EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES,
0c530ab8 A	21	* INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY,
2d21ac55 A	22	* FITNESS FOR A PARTICULAR PURPOSE, QUIET ENJOYMENT OR NON-INFRINGEMENT.
	23	* Please see the License for the specific language governing rights and
	24	* limitations under the License.
0c530ab8	25	*
2d21ac55	26	* @APPLE_OSREFERENCE_LICENSE_HEADER_END@
0c530ab8 A	27	*/
	28	/*
	29	* @OSF_COPYRIGHT@
	30	*/
	31	/*
	32	* DEPRECATED INTERFACES - Should be removed
	33	*
	34	* Purpose: Routines for the creation and use of kernel
	35	* alarm clock services. This file and the ipc
	36	* routines in kern/ipc_clock.c constitute the
	37	* machine-independent clock service layer.
	38	*/
	39
	40	#include <mach/mach_types.h>
	41
0c530ab8 A	42	#include <kern/host.h>
	43	#include <kern/spl.h>
	44	#include <kern/sched_prim.h>
	45	#include <kern/thread.h>
	46	#include <kern/ipc_host.h>
	47	#include <kern/clock.h>
	48	#include <kern/zalloc.h>
	49
	50	#include <ipc/ipc_types.h>
	51	#include <ipc/ipc_port.h>
	52
	53	#include <mach/mach_traps.h>
	54	#include <mach/mach_time.h>
	55
	56	#include <mach/clock_server.h>
	57	#include <mach/clock_reply.h>
	58	#include <mach/clock_priv_server.h>
	59
	60	#include <mach/mach_host_server.h>
	61	#include <mach/host_priv_server.h>
5ba3f43e	62	#include <libkern/section_keywords.h>
0c530ab8 A	63
	64	/*
	65	* Actual clock alarm structure. Used for user clock_sleep() and
	66	* clock_alarm() calls. Alarms are allocated from the alarm free
	67	* list and entered in time priority order into the active alarm
	68	* chain of the target clock.
	69	*/
	70	struct alarm {
	71	struct alarm al_next; / next alarm in chain */
	72	struct alarm al_prev; / previous alarm in chain */
	73	int al_status; /* alarm status */
	74	mach_timespec_t al_time; /* alarm time */
	75	struct { /* message alarm data */
	76	int type; /* alarm type */
	77	ipc_port_t port; /* alarm port */
	78	mach_msg_type_name_t
	79	port_type; /* alarm port type */
	80	struct clock clock; / alarm clock */
	81	void data; / alarm data */
	82	} al_alrm;
	83	#define al_type al_alrm.type
	84	#define al_port al_alrm.port
	85	#define al_port_type al_alrm.port_type
	86	#define al_clock al_alrm.clock
	87	#define al_data al_alrm.data
	88	long al_seqno; /* alarm sequence number */
	89	};
	90	typedef struct alarm alarm_data_t;
	91
	92	/* alarm status */
	93	#define ALARM_FREE 0 /* alarm is on free list */
	94	#define ALARM_SLEEP 1 /* active clock_sleep() */
	95	#define ALARM_CLOCK 2 /* active clock_alarm() */
	96	#define ALARM_DONE 4 /* alarm has expired */
	97
	98	/* local data declarations */
	99	decl_simple_lock_data(static,alarm_lock) /* alarm synchronization */
	100	static struct zone alarm_zone; / zone for user alarms */
	101	static struct alarm alrmfree; / alarm free list pointer */
	102	static struct alarm alrmdone; / alarm done list pointer */
	103	static struct alarm *alrmlist;
	104	static long alrm_seqno; /* uniquely identifies alarms */
	105	static thread_call_data_t alarm_done_call;
	106	static timer_call_data_t alarm_expire_timer;
	107
	108	extern struct clock clock_list[];
	109	extern int clock_count;
	110
	111	static void post_alarm(
	112	alarm_t alarm);
	113
	114	static void set_alarm(
	115	mach_timespec_t *alarm_time);
	116
	117	static int check_time(
	118	alarm_type_t alarm_type,
	119	mach_timespec_t *alarm_time,
	120	mach_timespec_t *clock_time);
	121
	122	static void alarm_done(void);
	123
	124	static void alarm_expire(void);
	125
	126	static kern_return_t clock_sleep_internal(
127	clock_t clock,
128	sleep_type_t sleep_type,
129	mach_timespec_t *sleep_time);
130
0c530ab8 A	131	int rtclock_init(void);
	132
	133	kern_return_t rtclock_gettime(
	134	mach_timespec_t *cur_time);
	135
	136	kern_return_t rtclock_getattr(
	137	clock_flavor_t flavor,
	138	clock_attr_t attr,
	139	mach_msg_type_number_t *count);
	140
5ba3f43e	141	SECURITY_READ_ONLY_EARLY(struct clock_ops) sysclk_ops = {
fe8ab488	142	NULL, rtclock_init,
0c530ab8 A	143	rtclock_gettime,
	144	rtclock_getattr,
	145	};
	146
	147	kern_return_t calend_gettime(
	148	mach_timespec_t *cur_time);
	149
	150	kern_return_t calend_getattr(
	151	clock_flavor_t flavor,
	152	clock_attr_t attr,
	153	mach_msg_type_number_t *count);
	154
5ba3f43e	155	SECURITY_READ_ONLY_EARLY(struct clock_ops) calend_ops = {
2d21ac55	156	NULL, NULL,
0c530ab8 A	157	calend_gettime,
	158	calend_getattr,
	159	};
	160
	161	/*
	162	* Macros to lock/unlock clock system.
	163	*/
	164	#define LOCK_ALARM(s) \
	165	s = splclock(); \
	166	simple_lock(&alarm_lock);
	167
	168	#define UNLOCK_ALARM(s) \
	169	simple_unlock(&alarm_lock); \
	170	splx(s);
	171
	172	void
	173	clock_oldconfig(void)
	174	{
	175	clock_t clock;
39037602	176	int i;
0c530ab8 A	177
	178	simple_lock_init(&alarm_lock, 0);
	179	thread_call_setup(&alarm_done_call, (thread_call_func_t)alarm_done, NULL);
	180	timer_call_setup(&alarm_expire_timer, (timer_call_func_t)alarm_expire, NULL);
	181
	182	/*
	183	* Configure clock devices.
	184	*/
	185	for (i = 0; i < clock_count; i++) {
	186	clock = &clock_list[i];
	187	if (clock->cl_ops && clock->cl_ops->c_config) {
	188	if ((*clock->cl_ops->c_config)() == 0)
2d21ac55	189	clock->cl_ops = NULL;
0c530ab8 A	190	}
	191	}
	192
	193	/* start alarm sequence numbers at 0 */
	194	alrm_seqno = 0;
	195	}
	196
	197	void
	198	clock_oldinit(void)
	199	{
	200	clock_t clock;
39037602	201	int i;
0c530ab8 A	202
	203	/*
	204	* Initialize basic clock structures.
	205	*/
	206	for (i = 0; i < clock_count; i++) {
	207	clock = &clock_list[i];
	208	if (clock->cl_ops && clock->cl_ops->c_init)
	209	(*clock->cl_ops->c_init)();
	210	}
	211	}
	212
	213	/*
	214	* Initialize the clock ipc service facility.
	215	*/
	216	void
	217	clock_service_create(void)
	218	{
	219	clock_t clock;
39037602	220	int i;
0c530ab8 A	221
	222	/*
	223	* Initialize ipc clock services.
	224	*/
	225	for (i = 0; i < clock_count; i++) {
	226	clock = &clock_list[i];
	227	if (clock->cl_ops) {
	228	ipc_clock_init(clock);
	229	ipc_clock_enable(clock);
	230	}
	231	}
	232
	233	/*
	234	* Perform miscellaneous late
	235	* initialization.
	236	*/
	237	i = sizeof(struct alarm);
	238	alarm_zone = zinit(i, (4096/i)i, 10i, "alarms");
	239	}
	240
	241	/*
	242	* Get the service port on a clock.
	243	*/
	244	kern_return_t
	245	host_get_clock_service(
	246	host_t host,
	247	clock_id_t clock_id,
	248	clock_t clock) / OUT */
	249	{
	250	if (host == HOST_NULL \|\| clock_id < 0 \|\| clock_id >= clock_count) {
	251	*clock = CLOCK_NULL;
	252	return (KERN_INVALID_ARGUMENT);
	253	}
	254
	255	*clock = &clock_list[clock_id];
	256	if ((*clock)->cl_ops == 0)
	257	return (KERN_FAILURE);
	258	return (KERN_SUCCESS);
	259	}
	260
	261	/*
	262	* Get the control port on a clock.
	263	*/
	264	kern_return_t
	265	host_get_clock_control(
	266	host_priv_t host_priv,
	267	clock_id_t clock_id,
	268	clock_t clock) / OUT */
	269	{
	270	if (host_priv == HOST_PRIV_NULL \|\|
	271	clock_id < 0 \|\| clock_id >= clock_count) {
	272	*clock = CLOCK_NULL;
	273	return (KERN_INVALID_ARGUMENT);
	274	}
	275
	276	*clock = &clock_list[clock_id];
	277	if ((*clock)->cl_ops == 0)
	278	return (KERN_FAILURE);
	279	return (KERN_SUCCESS);
	280	}
	281
	282	/*
	283	* Get the current clock time.
	284	*/
285	kern_return_t
286	clock_get_time(
287	clock_t clock,
288	mach_timespec_t cur_time) / OUT */
289	{
290	if (clock == CLOCK_NULL)
291	return (KERN_INVALID_ARGUMENT);
292	return ((*clock->cl_ops->c_gettime)(cur_time));
293	}
294
295	kern_return_t
296	rtclock_gettime(
297	mach_timespec_t time) / OUT */
298	{
b0d623f7 A	299	clock_sec_t secs;
	300	clock_nsec_t nsecs;
	301
	302	clock_get_system_nanotime(&secs, &nsecs);
	303	time->tv_sec = (unsigned int)secs;
	304	time->tv_nsec = nsecs;
0c530ab8 A	305
	306	return (KERN_SUCCESS);
	307	}
	308
	309	kern_return_t
	310	calend_gettime(
	311	mach_timespec_t time) / OUT */
	312	{
b0d623f7 A	313	clock_sec_t secs;
	314	clock_nsec_t nsecs;
	315
	316	clock_get_calendar_nanotime(&secs, &nsecs);
	317	time->tv_sec = (unsigned int)secs;
	318	time->tv_nsec = nsecs;
0c530ab8 A	319
	320	return (KERN_SUCCESS);
	321	}
	322
	323	/*
	324	* Get clock attributes.
	325	*/
	326	kern_return_t
	327	clock_get_attributes(
	328	clock_t clock,
	329	clock_flavor_t flavor,
	330	clock_attr_t attr, /* OUT */
	331	mach_msg_type_number_t count) / IN/OUT */
	332	{
	333	if (clock == CLOCK_NULL)
	334	return (KERN_INVALID_ARGUMENT);
	335	if (clock->cl_ops->c_getattr)
	336	return (clock->cl_ops->c_getattr(flavor, attr, count));
	337	return (KERN_FAILURE);
	338	}
	339
	340	kern_return_t
	341	rtclock_getattr(
	342	clock_flavor_t flavor,
	343	clock_attr_t attr, /* OUT */
	344	mach_msg_type_number_t count) / IN/OUT */
	345	{
	346	if (*count != 1)
	347	return (KERN_FAILURE);
	348
	349	switch (flavor) {
	350
	351	case CLOCK_GET_TIME_RES: /* >0 res */
	352	case CLOCK_ALARM_CURRES: /* =0 no alarm */
	353	case CLOCK_ALARM_MINRES:
	354	case CLOCK_ALARM_MAXRES:
	355	(clock_res_t ) attr = NSEC_PER_SEC / 100;
	356	break;
	357
	358	default:
	359	return (KERN_INVALID_VALUE);
	360	}
	361
	362	return (KERN_SUCCESS);
	363	}
	364
	365	kern_return_t
	366	calend_getattr(
	367	clock_flavor_t flavor,
	368	clock_attr_t attr, /* OUT */
	369	mach_msg_type_number_t count) / IN/OUT */
	370	{
	371	if (*count != 1)
	372	return (KERN_FAILURE);
	373
	374	switch (flavor) {
	375
	376	case CLOCK_GET_TIME_RES: /* >0 res */
	377	(clock_res_t ) attr = NSEC_PER_SEC / 100;
	378	break;
	379
	380	case CLOCK_ALARM_CURRES: /* =0 no alarm */
	381	case CLOCK_ALARM_MINRES:
	382	case CLOCK_ALARM_MAXRES:
383	(clock_res_t ) attr = 0;
384	break;
385
386	default:
387	return (KERN_INVALID_VALUE);
388	}
389
390	return (KERN_SUCCESS);
391	}
392
393	/*
394	* Set the current clock time.
395	*/
396	kern_return_t
397	clock_set_time(
398	clock_t clock,
399	__unused mach_timespec_t new_time)
400	{
401	if (clock == CLOCK_NULL)
402	return (KERN_INVALID_ARGUMENT);
403	return (KERN_FAILURE);
404	}
405
406	/*
407	* Set the clock alarm resolution.
408	*/
409	kern_return_t
410	clock_set_attributes(
411	clock_t clock,
412	__unused clock_flavor_t flavor,
413	__unused clock_attr_t attr,
414	__unused mach_msg_type_number_t count)
415	{
416	if (clock == CLOCK_NULL)
417	return (KERN_INVALID_ARGUMENT);
418	return (KERN_FAILURE);
419	}
420
421	/*
422	* Setup a clock alarm.
423	*/
424	kern_return_t
425	clock_alarm(
426	clock_t clock,
427	alarm_type_t alarm_type,
428	mach_timespec_t alarm_time,
429	ipc_port_t alarm_port,
430	mach_msg_type_name_t alarm_port_type)
431	{
432	alarm_t alarm;
433	mach_timespec_t clock_time;
434	int chkstat;
435	kern_return_t reply_code;
436	spl_t s;
437
438	if (clock == CLOCK_NULL)
439	return (KERN_INVALID_ARGUMENT);
440	if (clock != &clock_list[SYSTEM_CLOCK])
441	return (KERN_FAILURE);
442	if (IP_VALID(alarm_port) == 0)
443	return (KERN_INVALID_CAPABILITY);
444
445	/*
446	* Check alarm parameters. If parameters are invalid,
447	* send alarm message immediately.
448	*/
449	(*clock->cl_ops->c_gettime)(&clock_time);
450	chkstat = check_time(alarm_type, &alarm_time, &clock_time);
451	if (chkstat <= 0) {
452	reply_code = (chkstat < 0 ? KERN_INVALID_VALUE : KERN_SUCCESS);
453	clock_alarm_reply(alarm_port, alarm_port_type,
454	reply_code, alarm_type, clock_time);
455	return (KERN_SUCCESS);
456	}
457
458	/*
459	* Get alarm and add to clock alarm list.
460	*/
461
462	LOCK_ALARM(s);
463	if ((alarm = alrmfree) == 0) {
464	UNLOCK_ALARM(s);
465	alarm = (alarm_t) zalloc(alarm_zone);
466	if (alarm == 0)
467	return (KERN_RESOURCE_SHORTAGE);
468	LOCK_ALARM(s);
469	}
470	else
471	alrmfree = alarm->al_next;
472
473	alarm->al_status = ALARM_CLOCK;
474	alarm->al_time = alarm_time;
475	alarm->al_type = alarm_type;
476	alarm->al_port = alarm_port;
477	alarm->al_port_type = alarm_port_type;
478	alarm->al_clock = clock;
479	alarm->al_seqno = alrm_seqno++;
480	post_alarm(alarm);
481	UNLOCK_ALARM(s);
482
483	return (KERN_SUCCESS);
484	}
485
486	/*
487	* Sleep on a clock. System trap. User-level libmach clock_sleep
488	* interface call takes a mach_timespec_t sleep_time argument which it
489	* converts to sleep_sec and sleep_nsec arguments which are then
490	* passed to clock_sleep_trap.
491	*/
492	kern_return_t
493	clock_sleep_trap(
494	struct clock_sleep_trap_args *args)
495	{
496	mach_port_name_t clock_name = args->clock_name;
497	sleep_type_t sleep_type = args->sleep_type;
498	int sleep_sec = args->sleep_sec;
499	int sleep_nsec = args->sleep_nsec;
500	mach_vm_address_t wakeup_time_addr = args->wakeup_time;
501	clock_t clock;
502	mach_timespec_t swtime;
503	kern_return_t rvalue;
504
505	/*
506	* Convert the trap parameters.
507	*/
508	if (clock_name == MACH_PORT_NULL)
509	clock = &clock_list[SYSTEM_CLOCK];
510	else
511	clock = port_name_to_clock(clock_name);
512
513	swtime.tv_sec = sleep_sec;
514	swtime.tv_nsec = sleep_nsec;
515
516	/*
517	* Call the actual clock_sleep routine.
518	*/
519	rvalue = clock_sleep_internal(clock, sleep_type, &swtime);
520
521	/*
522	* Return current time as wakeup time.
523	*/
524	if (rvalue != KERN_INVALID_ARGUMENT && rvalue != KERN_FAILURE) {
525	copyout((char *)&swtime, wakeup_time_addr, sizeof(mach_timespec_t));
526	}
527	return (rvalue);
528	}
529
530	static kern_return_t
531	clock_sleep_internal(
532	clock_t clock,
533	sleep_type_t sleep_type,
534	mach_timespec_t *sleep_time)
535	{
536	alarm_t alarm;
537	mach_timespec_t clock_time;
538	kern_return_t rvalue;
539	int chkstat;
540	spl_t s;
541
542	if (clock == CLOCK_NULL)
543	return (KERN_INVALID_ARGUMENT);
544
545	if (clock != &clock_list[SYSTEM_CLOCK])
546	return (KERN_FAILURE);
547
548	/*
549	* Check sleep parameters. If parameters are invalid
550	* return an error, otherwise post alarm request.
551	*/
552	(*clock->cl_ops->c_gettime)(&clock_time);
553
554	chkstat = check_time(sleep_type, sleep_time, &clock_time);
555	if (chkstat < 0)
556	return (KERN_INVALID_VALUE);
557	rvalue = KERN_SUCCESS;
558	if (chkstat > 0) {
559	wait_result_t wait_result;
560
561	/*
562	* Get alarm and add to clock alarm list.
563	*/
564
565	LOCK_ALARM(s);
566	if ((alarm = alrmfree) == 0) {
567	UNLOCK_ALARM(s);
568	alarm = (alarm_t) zalloc(alarm_zone);
569	if (alarm == 0)
570	return (KERN_RESOURCE_SHORTAGE);
571	LOCK_ALARM(s);
572	}
573	else
574	alrmfree = alarm->al_next;
575
576	/*
577	* Wait for alarm to occur.
578	*/
579	wait_result = assert_wait((event_t)alarm, THREAD_ABORTSAFE);
580	if (wait_result == THREAD_WAITING) {
581	alarm->al_time = *sleep_time;
582	alarm->al_status = ALARM_SLEEP;
583	post_alarm(alarm);
584	UNLOCK_ALARM(s);
585
586	wait_result = thread_block(THREAD_CONTINUE_NULL);
587
588	/*
589	* Note if alarm expired normally or whether it
590	* was aborted. If aborted, delete alarm from
591	* clock alarm list. Return alarm to free list.
592	*/
593	LOCK_ALARM(s);
594	if (alarm->al_status != ALARM_DONE) {
595	assert(wait_result != THREAD_AWAKENED);
596	if (((alarm->al_prev)->al_next = alarm->al_next) != NULL)
597	(alarm->al_next)->al_prev = alarm->al_prev;
598	rvalue = KERN_ABORTED;
599	}
600	*sleep_time = alarm->al_time;
601	alarm->al_status = ALARM_FREE;
602	} else {
603	assert(wait_result == THREAD_INTERRUPTED);
604	assert(alarm->al_status == ALARM_FREE);
605	rvalue = KERN_ABORTED;
606	}
607	alarm->al_next = alrmfree;
608	alrmfree = alarm;
609	UNLOCK_ALARM(s);
610	}
611	else
612	*sleep_time = clock_time;
613
614	return (rvalue);
615	}
616
617	/*
618	* Service clock alarm expirations.
619	*/
620	static void
621	alarm_expire(void)
622	{
623	clock_t clock;
39037602 A	624	alarm_t alrm1;
39037602 A	625	alarm_t alrm2;
0c530ab8 A	626	mach_timespec_t clock_time;
	627	mach_timespec_t *alarm_time;
	628	spl_t s;
	629
	630	clock = &clock_list[SYSTEM_CLOCK];
	631	(*clock->cl_ops->c_gettime)(&clock_time);
	632
	633	/*
	634	* Update clock alarm list. Alarms that are due are moved
	635	* to the alarmdone list to be serviced by a thread callout.
	636	*/
	637	LOCK_ALARM(s);
	638	alrm1 = (alarm_t)&alrmlist;
	639	while ((alrm2 = alrm1->al_next) != NULL) {
	640	alarm_time = &alrm2->al_time;
	641	if (CMP_MACH_TIMESPEC(alarm_time, &clock_time) > 0)
	642	break;
	643
	644	/*
	645	* Alarm has expired, so remove it from the
	646	* clock alarm list.
	647	*/
	648	if ((alrm1->al_next = alrm2->al_next) != NULL)
	649	(alrm1->al_next)->al_prev = alrm1;
	650
	651	/*
	652	* If a clock_sleep() alarm, wakeup the thread
	653	* which issued the clock_sleep() call.
	654	*/
	655	if (alrm2->al_status == ALARM_SLEEP) {
2d21ac55	656	alrm2->al_next = NULL;
0c530ab8 A	657	alrm2->al_status = ALARM_DONE;
	658	alrm2->al_time = clock_time;
	659	thread_wakeup((event_t)alrm2);
	660	}
	661
	662	/*
	663	* If a clock_alarm() alarm, place the alarm on
	664	* the alarm done list and schedule the alarm
	665	* delivery mechanism.
	666	*/
	667	else {
	668	assert(alrm2->al_status == ALARM_CLOCK);
	669	if ((alrm2->al_next = alrmdone) != NULL)
	670	alrmdone->al_prev = alrm2;
	671	else
	672	thread_call_enter(&alarm_done_call);
	673	alrm2->al_prev = (alarm_t)&alrmdone;
	674	alrmdone = alrm2;
	675	alrm2->al_status = ALARM_DONE;
	676	alrm2->al_time = clock_time;
	677	}
	678	}
	679
	680	/*
	681	* Setup to expire for the next pending alarm.
	682	*/
	683	if (alrm2)
	684	set_alarm(alarm_time);
	685	UNLOCK_ALARM(s);
	686	}
	687
	688	static void
	689	alarm_done(void)
	690	{
39037602	691	alarm_t alrm;
0c530ab8 A	692	kern_return_t code;
	693	spl_t s;
	694
	695	LOCK_ALARM(s);
	696	while ((alrm = alrmdone) != NULL) {
	697	if ((alrmdone = alrm->al_next) != NULL)
	698	alrmdone->al_prev = (alarm_t)&alrmdone;
	699	UNLOCK_ALARM(s);
	700
	701	code = (alrm->al_status == ALARM_DONE? KERN_SUCCESS: KERN_ABORTED);
	702	if (alrm->al_port != IP_NULL) {
	703	/* Deliver message to designated port */
	704	if (IP_VALID(alrm->al_port)) {
	705	clock_alarm_reply(alrm->al_port, alrm->al_port_type, code,
	706	alrm->al_type, alrm->al_time);
	707	}
	708
	709	LOCK_ALARM(s);
	710	alrm->al_status = ALARM_FREE;
	711	alrm->al_next = alrmfree;
	712	alrmfree = alrm;
	713	}
	714	else
	715	panic("clock_alarm_deliver");
	716	}
	717
	718	UNLOCK_ALARM(s);
	719	}
	720
	721	/*
	722	* Post an alarm on the active alarm list.
	723	*
	724	* Always called from within a LOCK_ALARM() code section.
	725	*/
	726	static void
	727	post_alarm(
	728	alarm_t alarm)
	729	{
39037602	730	alarm_t alrm1, alrm2;
0c530ab8 A	731	mach_timespec_t *alarm_time;
	732	mach_timespec_t *queue_time;
	733
	734	/*
	735	* Traverse alarm list until queue time is greater
	736	* than alarm time, then insert alarm.
	737	*/
	738	alarm_time = &alarm->al_time;
	739	alrm1 = (alarm_t)&alrmlist;
	740	while ((alrm2 = alrm1->al_next) != NULL) {
	741	queue_time = &alrm2->al_time;
	742	if (CMP_MACH_TIMESPEC(queue_time, alarm_time) > 0)
	743	break;
	744	alrm1 = alrm2;
	745	}
	746	alrm1->al_next = alarm;
	747	alarm->al_next = alrm2;
	748	alarm->al_prev = alrm1;
	749	if (alrm2)
	750	alrm2->al_prev = alarm;
	751
	752	/*
	753	* If the inserted alarm is the 'earliest' alarm,
	754	* reset the device layer alarm time accordingly.
	755	*/
	756	if (alrmlist == alarm)
	757	set_alarm(alarm_time);
	758	}
	759
	760	static void
	761	set_alarm(
	762	mach_timespec_t *alarm_time)
	763	{
	764	uint64_t abstime;
	765
	766	nanotime_to_absolutetime(alarm_time->tv_sec, alarm_time->tv_nsec, &abstime);
39236c6e	767	timer_call_enter_with_leeway(&alarm_expire_timer, NULL, abstime, 0, TIMER_CALL_USER_NORMAL, FALSE);
0c530ab8 A	768	}
	769
	770	/*
	771	* Check the validity of 'alarm_time' and 'alarm_type'. If either
	772	* argument is invalid, return a negative value. If the 'alarm_time'
	773	* is now, return a 0 value. If the 'alarm_time' is in the future,
	774	* return a positive value.
	775	*/
	776	static int
	777	check_time(
	778	alarm_type_t alarm_type,
	779	mach_timespec_t *alarm_time,
	780	mach_timespec_t *clock_time)
	781	{
	782	int result;
	783
	784	if (BAD_ALRMTYPE(alarm_type))
	785	return (-1);
	786	if (BAD_MACH_TIMESPEC(alarm_time))
	787	return (-1);
	788	if ((alarm_type & ALRMTYPE) == TIME_RELATIVE)
	789	ADD_MACH_TIMESPEC(alarm_time, clock_time);
	790
	791	result = CMP_MACH_TIMESPEC(alarm_time, clock_time);
	792
	793	return ((result >= 0)? result: 0);
	794	}
	795
b0d623f7 A	796	#ifndef __LP64__
b0d623f7 A	797
0c530ab8 A	798	mach_timespec_t
	799	clock_get_system_value(void)
	800	{
	801	clock_t clock = &clock_list[SYSTEM_CLOCK];
	802	mach_timespec_t value;
	803
	804	(void) (*clock->cl_ops->c_gettime)(&value);
	805
	806	return value;
	807	}
	808
	809	mach_timespec_t
	810	clock_get_calendar_value(void)
	811	{
	812	clock_t clock = &clock_list[CALENDAR_CLOCK];
	813	mach_timespec_t value = MACH_TIMESPEC_ZERO;
	814
	815	(void) (*clock->cl_ops->c_gettime)(&value);
	816
	817	return value;
	818	}
b0d623f7 A	819
b0d623f7 A	820	#endif /* __LP64__ */