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

/*
 * Copyright (c) 2000 Apple Computer, Inc. All rights reserved.
 *
 * @APPLE_LICENSE_HEADER_START@
 * 
 * The contents of this file constitute Original Code as defined in and
 * are subject to the Apple Public Source License Version 1.1 (the
 * "License").  You may not use this file except in compliance with the
 * License.  Please obtain a copy of the License at
 * http://www.apple.com/publicsource and read it before using this file.
 * 
 * This 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 OR NON-INFRINGEMENT.  Please see the
 * License for the specific language governing rights and limitations
 * under the License.
 * 
 * @APPLE_LICENSE_HEADER_END@
 */
/*
 * @OSF_COPYRIGHT@
 */
/* 
 * Mach Operating System
 * Copyright (c) 1991,1990,1989 Carnegie Mellon University
 * All Rights Reserved.
 * 
 * Permission to use, copy, modify and distribute this software and its
 * documentation is hereby granted, provided that both the copyright
 * notice and this permission notice appear in all copies of the
 * software, derivative works or modified versions, and any portions
 * thereof, and that both notices appear in supporting documentation.
 * 
 * CARNEGIE MELLON ALLOWS FREE USE OF THIS SOFTWARE IN ITS "AS IS"
 * CONDITION.  CARNEGIE MELLON DISCLAIMS ANY LIABILITY OF ANY KIND FOR
 * ANY DAMAGES WHATSOEVER RESULTING FROM THE USE OF THIS SOFTWARE.
 * 
 * Carnegie Mellon requests users of this software to return to
 * 
 *  Software Distribution Coordinator  or  Software.Distribution@CS.CMU.EDU
 *  School of Computer Science
 *  Carnegie Mellon University
 *  Pittsburgh PA 15213-3890
 * 
 * any improvements or extensions that they make and grant Carnegie Mellon
 * the rights to redistribute these changes.
 */

/*
 */
#include	<mach_prof.h>

#include	<mach/task_server.h>
#include	<mach/thread_act_server.h>

#if MACH_PROF
#include        <cpus.h>
#include	<kern/thread.h>
#include	<kern/thread_swap.h>
#include	<kern/queue.h>
#include	<kern/profile.h>
#include	<kern/sched_prim.h>
#include	<kern/spl.h>
#include	<kern/misc_protos.h>
#include	<ipc/ipc_space.h>
#include        <machine/machparam.h>
#include	<mach/prof.h>

thread_t profile_thread_id = THREAD_NULL;
int profile_sample_count = 0;	/* Provided for looking at from kdb. */
extern kern_return_t task_suspend(task_t task);	/* ack */

/* Forwards */
prof_data_t	pbuf_alloc(void);
void		pbuf_free(
			prof_data_t	pbuf);
void		profile_thread(void);
void		send_last_sample_buf(
			prof_data_t	pbuf);

/*
 *****************************************************************************
 * profile_thread is the profile/trace kernel support thread. It is started
 * by a server/user request through task_sample, or thread_sample. The profile
 * thread dequeues messages and sends them to the receive_prof thread, in the
 * server, via the send_samples and send_notices mig interface functions. If
 * there are no messages in the queue profile thread blocks until wakened by
 * profile (called in from mach_clock), or last_sample (called by thread/task_
 * sample).
*/

void
profile_thread(void)
{
    spl_t	    s;
    buffer_t	    buf_entry;
    queue_entry_t   prof_queue_entry;
    prof_data_t	    pbuf;
    kern_return_t   kr;
    int		    j;

    thread_swappable(current_act(), FALSE);

    /* Initialise the queue header for the prof_queue */
    mpqueue_init(&prof_queue);

    while (TRUE) {

	/* Dequeue the first buffer. */
	s = splsched();
	mpdequeue_head(&prof_queue, &prof_queue_entry);
	splx(s);

	if ((buf_entry = (buffer_t) prof_queue_entry) == NULLPBUF) { 
	    assert_wait((event_t) profile_thread, THREAD_UNINT);
	    thread_block(THREAD_CONTINUE_NULL);
	    if (current_thread()->wait_result != THREAD_AWAKENED)
		break;
	} else 
	{
	    int		    dropped;

	    pbuf = buf_entry->p_prof;
	    kr = send_samples(pbuf->prof_port, (void *)buf_entry->p_zone,
			(mach_msg_type_number_t)buf_entry->p_index);
	    profile_sample_count += buf_entry->p_index;
	    if (kr != KERN_SUCCESS)
	      printf("send_samples(%x, %x, %d) error %x\n",
			pbuf->prof_port, buf_entry->p_zone, buf_entry->p_index, kr); 
	    dropped = buf_entry->p_dropped;
	    if (dropped > 0) {
		printf("kernel: profile dropped %d sample%s\n", dropped,
		       dropped == 1 ? "" : "s");
		buf_entry->p_dropped = 0;
	    }

	    /* Indicate you've finished the dirty job */
	    buf_entry->p_full = FALSE;
	    if (buf_entry->p_wakeme)
	      thread_wakeup((event_t) &buf_entry->p_wakeme);
	}

    }
    /* The profile thread has been signalled to exit.  Any threads waiting
       for the last buffer of samples to be acknowledged should be woken
       up now.  */
    profile_thread_id = THREAD_NULL;
    while (1) {
	s = splsched();
	mpdequeue_head(&prof_queue, &prof_queue_entry);
	splx(s);
	if ((buf_entry = (buffer_t) prof_queue_entry) == NULLPBUF)
	    break;
	if (buf_entry->p_wakeme)
	    thread_wakeup((event_t) &buf_entry->p_wakeme);
    }
#if 0	/* XXXXX */
    thread_halt_self();
#else
	panic("profile_thread(): halt_self");
#endif	/* XXXXX */
}

/*
 *****************************************************************************
 * send_last_sample is the drain mechanism to allow partial profiled buffers
 * to be sent to the receive_prof thread in the server.
 *****************************************************************************
*/

void
send_last_sample_buf(prof_data_t pbuf)
{
    spl_t    s;
    buffer_t buf_entry;

    if (pbuf == NULLPROFDATA)
	return;

    /* Ask for the sending of the last PC buffer.
     * Make a request to the profile_thread by inserting
     * the buffer in the send queue, and wake it up. 
     * The last buffer must be inserted at the head of the
     * send queue, so the profile_thread handles it immediatly. 
     */ 
    buf_entry = pbuf->prof_area + pbuf->prof_index;
    buf_entry->p_prof = pbuf;

    /* 
       Watch out in case profile thread exits while we are about to
       queue data for it.
     */
    s = splsched();
    if (profile_thread_id == THREAD_NULL)
	splx(s);
    else {
	buf_entry->p_wakeme = 1;
	mpenqueue_tail(&prof_queue, &buf_entry->p_list);
	thread_wakeup((event_t) profile_thread);
	assert_wait((event_t) &buf_entry->p_wakeme, THREAD_ABORTSAFE);
	splx(s); 
	thread_block(THREAD_CONTINUE_NULL);
    }
}


/*
 *****************************************************************************
 * add clock tick parameters to profile/trace buffers. Called from the mach_
 * clock heritz_tick function. DCI version stores thread, sp, and pc values
 * into the profile/trace buffers. MACH_PROF version just stores pc values.
 *****************************************************************************
 */

void
profile(natural_t	pc,
	prof_data_t	pbuf)
{
    natural_t inout_val = pc; 
    buffer_t buf_entry;

    if (pbuf == NULLPROFDATA)
	return;
    
    /* Inserts the PC value in the buffer of the thread */
    set_pbuf_value(pbuf, &inout_val); 
    switch((int)inout_val) {
    case 0: 
	if (profile_thread_id == THREAD_NULL) {
	  reset_pbuf_area(pbuf);
	}
	break;
    case 1: 
	/* Normal case, value successfully inserted */
	break;
    case 2 : 
	/*
	 * The value we have just inserted caused the
	 * buffer to be full, and ready to be sent.
	 * If profile_thread_id is null, the profile
	 * thread has been killed.  Since this generally
	 * happens only when the O/S server task of which
	 * it is a part is killed, it is not a great loss
	 * to throw away the data.
	 */
	if (profile_thread_id == THREAD_NULL) {
	  reset_pbuf_area(pbuf);
	  break;
	}

	buf_entry = (buffer_t) &pbuf->prof_area[pbuf->prof_index];
	buf_entry->p_prof = pbuf;
	mpenqueue_tail(&prof_queue, &buf_entry->p_list);
	
	/* Switch to another buffer */
	reset_pbuf_area(pbuf);
	
	/* Wake up the profile thread */
	if (profile_thread_id != THREAD_NULL)
	  thread_wakeup((event_t) profile_thread);
	break;
      
      default: 
	printf("profile : unexpected case\n"); 
    }
}

/*
 *****************************************************************************
 * pbuf_alloc creates a profile/trace buffer and assoc. zones for storing
 * profiled items.
 *****************************************************************************
 */

prof_data_t
pbuf_alloc(void)
{
	register prof_data_t pbuf;
	register int i;
	register natural_t *zone;

	pbuf = (prof_data_t)kalloc(sizeof(struct prof_data));
	if (!pbuf)
		return(NULLPROFDATA);
	pbuf->prof_port = MACH_PORT_NULL;
	for (i=0; i< NB_PROF_BUFFER; i++) {
		zone = (natural_t *)kalloc(SIZE_PROF_BUFFER*sizeof(natural_t));
		if (!zone) {
			i--;
			while (i--)
				kfree((vm_offset_t)pbuf->prof_area[i].p_zone,
				      SIZE_PROF_BUFFER*sizeof(natural_t));
			kfree((vm_offset_t)pbuf, sizeof(struct prof_data));
			return(NULLPROFDATA);
		}
		pbuf->prof_area[i].p_zone = zone;
		pbuf->prof_area[i].p_full = FALSE;
	}
	pbuf->prof_port = MACH_PORT_NULL;
	return(pbuf);
}

/*
 *****************************************************************************
 * pbuf_free free memory allocated for storing profile/trace items. Called
 * when a task is no longer profiled/traced. Pbuf_free tears down the memory
 * alloced in pbuf_alloc. It does not check to see if the structures are valid
 * since it is only called by functions in this file.
 *****************************************************************************
 */
void
pbuf_free(
	prof_data_t	pbuf)
{
	register int i;

	if (pbuf->prof_port)
		ipc_port_release_send(pbuf->prof_port);
	
	for(i=0; i < NB_PROF_BUFFER ; i++)
		kfree((vm_offset_t)pbuf->prof_area[i].p_zone,
		      SIZE_PROF_BUFFER*sizeof(natural_t));
	kfree((vm_offset_t)pbuf, sizeof(struct prof_data));
}

#endif /* MACH_PROF */

/*
 *****************************************************************************
 * Thread_sample is used by MACH_PROF to profile a single thread, and is only
 * stub in DCI.
 *****************************************************************************
 */

kern_return_t
thread_sample(
	thread_act_t	thr_act,
	ipc_port_t	reply)
{
    /* 
     * This routine is called every time that a new thread has made
     * a request for the sampling service. We must keep track of the 
     * correspondance between its identity (thread) and the port
     * we are going to use as a reply port to send out the samples resulting 
     * from its execution. 
     */
#if !MACH_PROF
    return KERN_FAILURE;
#else 
    prof_data_t	    pbuf;
    vm_offset_t	    vmpbuf;

    if (reply != MACH_PORT_NULL) {
	if (thr_act->act_profiled) 	/* yuck! */
		return KERN_INVALID_ARGUMENT;
	/* Start profiling this activation, do the initialization. */
	pbuf = pbuf_alloc();
	if ((thr_act->profil_buffer = pbuf) == NULLPROFDATA) {
	    printf("thread_sample: cannot allocate pbuf\n");
	    return KERN_RESOURCE_SHORTAGE;
	} 
	else {
	    if (!set_pbuf_nb(pbuf, NB_PROF_BUFFER-1)) {
		printf("mach_sample_thread: cannot set pbuf_nb\n");
		return KERN_FAILURE;
	    }
	    reset_pbuf_area(pbuf);
	}
	pbuf->prof_port = reply;
	thr_act->act_profiled = TRUE;
	thr_act->act_profiled_own = TRUE;
	if (profile_thread_id == THREAD_NULL)
	    profile_thread_id = kernel_thread(kernel_task, profile_thread);
    } else {
	if (!thr_act->act_profiled)
		return(KERN_INVALID_ARGUMENT);

	thr_act->act_profiled = FALSE;
	/* do not stop sampling if thread is not profiled by its own */

	if (!thr_act->act_profiled_own)
	    return KERN_SUCCESS;
	else
	    thr_act->act_profiled_own = FALSE;

	send_last_sample_buf(thr_act->profil_buffer);
	pbuf_free(thr_act->profil_buffer);
	thr_act->profil_buffer = NULLPROFDATA;
    }
    return KERN_SUCCESS;
#endif /* MACH_PROF */
}

/*
 *****************************************************************************
 * Task_sample is used to profile/trace tasks - all thread within a task using
 * a common profile buffer to collect items generated by the hertz_tick. For
 * each task profiled a profile buffer is created that associates a reply port
 * (used to send the data to a server thread), task (used for throttling), and
 * a zone area (used to store profiled/traced items).
 *****************************************************************************
 */

kern_return_t
task_sample(
	task_t		task,
	ipc_port_t	reply)
{
#if !MACH_PROF
    return KERN_FAILURE;
#else
    prof_data_t	    pbuf=task->profil_buffer;
    vm_offset_t	    vmpbuf;
    boolean_t	    turnon = (reply != MACH_PORT_NULL);

    if (task == TASK_NULL)
	    return KERN_INVALID_ARGUMENT;
    if (turnon)			/* Do we want to profile this task? */
    {
	pbuf = pbuf_alloc();	/* allocate a profile buffer */
	task_lock(task);
	if (task->task_profiled) { /* if it is already profiled return so */
		task_unlock(task);
		if (pbuf != NULLPROFDATA)
		    pbuf_free(pbuf);
		return(KERN_INVALID_ARGUMENT);
	}
	if (pbuf == NULLPROFDATA) {
	    task_unlock(task);
	    return KERN_RESOURCE_SHORTAGE; /* can't allocate a buffer, quit */
	}
	task->profil_buffer = pbuf;
	
	if (!set_pbuf_nb(pbuf, NB_PROF_BUFFER-1)) {
	    pbuf_free(pbuf);
	    task_unlock(task);
	    return KERN_FAILURE;
	}
	reset_pbuf_area(pbuf);
	pbuf->prof_port = reply; /* assoc. buffer with reply port */
    } else {			/* We want to stop profiling/tracing */
	task_lock(task);
	if (!task->task_profiled) { /* but this task is not being profiled */
	    task_unlock(task);
	    return(KERN_INVALID_ARGUMENT);
	}
    }

    /*
     * turnon = FALSE && task_profile = TRUE ||
     * turnon = TRUE  && task_profile = FALSE
     */

    if (turnon != task->task_profiled) {
	int actual, i;
	thread_act_t thr_act;

	if (turnon && profile_thread_id == THREAD_NULL)	/* 1st time thru? */
	    profile_thread_id =	/* then start profile thread. */
		kernel_thread(kernel_task, profile_thread);
	task->task_profiled = turnon;  
	actual = task->thr_act_count; 
	for (i = 0, thr_act = (thread_act_t)queue_first(&task->thr_acts);
	     i < actual;
	     i++, thr_act = (thread_act_t)queue_next(&thr_act->thr_acts)) {
		  if (!thr_act->act_profiled_own) {
		    thr_act->act_profiled = turnon;
		    if (turnon) {
			thr_act->profil_buffer = task->profil_buffer;
		  	thr_act->act_profiled = TRUE;
		    } else {
			thr_act->act_profiled = FALSE;
		        thr_act->profil_buffer = NULLPROFDATA;
		    }
		  }
	}
	if (!turnon) {		/* drain buffers and clean-up */
	    send_last_sample_buf(task->profil_buffer);
	    pbuf_free(task->profil_buffer);
	    task->profil_buffer = NULLPROFDATA;
	}
    }

    task_unlock(task);
    return KERN_SUCCESS;
#endif /* MACH_PROF */
}
Commit	Line	Data
1c79356b A	1	/*
	2	* Copyright (c) 2000 Apple Computer, Inc. All rights reserved.
	3	*
	4	* @APPLE_LICENSE_HEADER_START@
	5	*
de355530 A	6	* The contents of this file constitute Original Code as defined in and
	7	* are subject to the Apple Public Source License Version 1.1 (the
	8	* "License"). You may not use this file except in compliance with the
	9	* License. Please obtain a copy of the License at
	10	* http://www.apple.com/publicsource and read it before using this file.
1c79356b	11	*
de355530 A	12	* This Original Code and all software distributed under the License are
de355530 A	13	* distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY KIND, EITHER
1c79356b A	14	* EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES,
1c79356b A	15	* INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY,
de355530 A	16	* FITNESS FOR A PARTICULAR PURPOSE OR NON-INFRINGEMENT. Please see the
	17	* License for the specific language governing rights and limitations
	18	* under the License.
1c79356b A	19	*
	20	* @APPLE_LICENSE_HEADER_END@
	21	*/
	22	/*
	23	* @OSF_COPYRIGHT@
	24	*/
	25	/*
	26	* Mach Operating System
	27	* Copyright (c) 1991,1990,1989 Carnegie Mellon University
	28	* All Rights Reserved.
	29	*
	30	* Permission to use, copy, modify and distribute this software and its
	31	* documentation is hereby granted, provided that both the copyright
	32	* notice and this permission notice appear in all copies of the
	33	* software, derivative works or modified versions, and any portions
	34	* thereof, and that both notices appear in supporting documentation.
	35	*
	36	* CARNEGIE MELLON ALLOWS FREE USE OF THIS SOFTWARE IN ITS "AS IS"
	37	* CONDITION. CARNEGIE MELLON DISCLAIMS ANY LIABILITY OF ANY KIND FOR
	38	* ANY DAMAGES WHATSOEVER RESULTING FROM THE USE OF THIS SOFTWARE.
	39	*
	40	* Carnegie Mellon requests users of this software to return to
	41	*
	42	* Software Distribution Coordinator or Software.Distribution@CS.CMU.EDU
	43	* School of Computer Science
	44	* Carnegie Mellon University
	45	* Pittsburgh PA 15213-3890
	46	*
	47	* any improvements or extensions that they make and grant Carnegie Mellon
	48	* the rights to redistribute these changes.
	49	*/
	50
	51	/*
	52	*/
	53	#include <mach_prof.h>
	54
	55	#include <mach/task_server.h>
	56	#include <mach/thread_act_server.h>
	57
	58	#if MACH_PROF
	59	#include <cpus.h>
	60	#include <kern/thread.h>
	61	#include <kern/thread_swap.h>
	62	#include <kern/queue.h>
	63	#include <kern/profile.h>
	64	#include <kern/sched_prim.h>
	65	#include <kern/spl.h>
	66	#include <kern/misc_protos.h>
	67	#include <ipc/ipc_space.h>
	68	#include <machine/machparam.h>
	69	#include <mach/prof.h>
	70
	71	thread_t profile_thread_id = THREAD_NULL;
	72	int profile_sample_count = 0; /* Provided for looking at from kdb. */
	73	extern kern_return_t task_suspend(task_t task); /* ack */
	74
	75	/* Forwards */
	76	prof_data_t pbuf_alloc(void);
	77	void pbuf_free(
	78	prof_data_t pbuf);
	79	void profile_thread(void);
	80	void send_last_sample_buf(
	81	prof_data_t pbuf);
	82
83	/*
84	*****************************************************************************
85	* profile_thread is the profile/trace kernel support thread. It is started
86	* by a server/user request through task_sample, or thread_sample. The profile
87	* thread dequeues messages and sends them to the receive_prof thread, in the
88	* server, via the send_samples and send_notices mig interface functions. If
89	* there are no messages in the queue profile thread blocks until wakened by
90	* profile (called in from mach_clock), or last_sample (called by thread/task_
91	* sample).
92	*/
93
94	void
95	profile_thread(void)
96	{
97	spl_t s;
98	buffer_t buf_entry;
99	queue_entry_t prof_queue_entry;
100	prof_data_t pbuf;
101	kern_return_t kr;
102	int j;
103
104	thread_swappable(current_act(), FALSE);
105
106	/* Initialise the queue header for the prof_queue */
107	mpqueue_init(&prof_queue);
108
109	while (TRUE) {
110
111	/* Dequeue the first buffer. */
112	s = splsched();
113	mpdequeue_head(&prof_queue, &prof_queue_entry);
114	splx(s);
115
116	if ((buf_entry = (buffer_t) prof_queue_entry) == NULLPBUF) {
117	assert_wait((event_t) profile_thread, THREAD_UNINT);
9bccf70c	118	thread_block(THREAD_CONTINUE_NULL);
1c79356b A	119	if (current_thread()->wait_result != THREAD_AWAKENED)
	120	break;
	121	} else
	122	{
	123	int dropped;
	124
	125	pbuf = buf_entry->p_prof;
	126	kr = send_samples(pbuf->prof_port, (void *)buf_entry->p_zone,
	127	(mach_msg_type_number_t)buf_entry->p_index);
	128	profile_sample_count += buf_entry->p_index;
	129	if (kr != KERN_SUCCESS)
	130	printf("send_samples(%x, %x, %d) error %x\n",
	131	pbuf->prof_port, buf_entry->p_zone, buf_entry->p_index, kr);
	132	dropped = buf_entry->p_dropped;
	133	if (dropped > 0) {
	134	printf("kernel: profile dropped %d sample%s\n", dropped,
	135	dropped == 1 ? "" : "s");
	136	buf_entry->p_dropped = 0;
	137	}
	138
	139	/* Indicate you've finished the dirty job */
	140	buf_entry->p_full = FALSE;
	141	if (buf_entry->p_wakeme)
	142	thread_wakeup((event_t) &buf_entry->p_wakeme);
	143	}
	144
	145	}
	146	/* The profile thread has been signalled to exit. Any threads waiting
	147	for the last buffer of samples to be acknowledged should be woken
	148	up now. */
	149	profile_thread_id = THREAD_NULL;
	150	while (1) {
	151	s = splsched();
	152	mpdequeue_head(&prof_queue, &prof_queue_entry);
	153	splx(s);
	154	if ((buf_entry = (buffer_t) prof_queue_entry) == NULLPBUF)
	155	break;
	156	if (buf_entry->p_wakeme)
	157	thread_wakeup((event_t) &buf_entry->p_wakeme);
	158	}
	159	#if 0 /* XXXXX */
	160	thread_halt_self();
	161	#else
	162	panic("profile_thread(): halt_self");
	163	#endif /* XXXXX */
	164	}
	165
	166	/*
	167	*****************************************************************************
	168	* send_last_sample is the drain mechanism to allow partial profiled buffers
	169	* to be sent to the receive_prof thread in the server.
	170	*****************************************************************************
	171	*/
	172
	173	void
	174	send_last_sample_buf(prof_data_t pbuf)
	175	{
	176	spl_t s;
	177	buffer_t buf_entry;
	178
	179	if (pbuf == NULLPROFDATA)
	180	return;
	181
	182	/* Ask for the sending of the last PC buffer.
183	* Make a request to the profile_thread by inserting
184	* the buffer in the send queue, and wake it up.
185	* The last buffer must be inserted at the head of the
186	* send queue, so the profile_thread handles it immediatly.
187	*/
188	buf_entry = pbuf->prof_area + pbuf->prof_index;
189	buf_entry->p_prof = pbuf;
190
191	/*
192	Watch out in case profile thread exits while we are about to
193	queue data for it.
194	*/
195	s = splsched();
196	if (profile_thread_id == THREAD_NULL)
197	splx(s);
198	else {
199	buf_entry->p_wakeme = 1;
200	mpenqueue_tail(&prof_queue, &buf_entry->p_list);
201	thread_wakeup((event_t) profile_thread);
202	assert_wait((event_t) &buf_entry->p_wakeme, THREAD_ABORTSAFE);
203	splx(s);
9bccf70c	204	thread_block(THREAD_CONTINUE_NULL);
1c79356b A	205	}
	206	}
	207
	208
	209	/*
	210	*****************************************************************************
	211	* add clock tick parameters to profile/trace buffers. Called from the mach_
	212	* clock heritz_tick function. DCI version stores thread, sp, and pc values
	213	* into the profile/trace buffers. MACH_PROF version just stores pc values.
	214	*****************************************************************************
	215	*/
	216
	217	void
	218	profile(natural_t pc,
	219	prof_data_t pbuf)
	220	{
	221	natural_t inout_val = pc;
	222	buffer_t buf_entry;
	223
	224	if (pbuf == NULLPROFDATA)
	225	return;
	226
	227	/* Inserts the PC value in the buffer of the thread */
	228	set_pbuf_value(pbuf, &inout_val);
	229	switch((int)inout_val) {
	230	case 0:
	231	if (profile_thread_id == THREAD_NULL) {
	232	reset_pbuf_area(pbuf);
	233	}
	234	break;
	235	case 1:
	236	/* Normal case, value successfully inserted */
	237	break;
	238	case 2 :
	239	/*
	240	* The value we have just inserted caused the
	241	* buffer to be full, and ready to be sent.
	242	* If profile_thread_id is null, the profile
	243	* thread has been killed. Since this generally
	244	* happens only when the O/S server task of which
	245	* it is a part is killed, it is not a great loss
	246	* to throw away the data.
	247	*/
	248	if (profile_thread_id == THREAD_NULL) {
	249	reset_pbuf_area(pbuf);
	250	break;
	251	}
	252
	253	buf_entry = (buffer_t) &pbuf->prof_area[pbuf->prof_index];
	254	buf_entry->p_prof = pbuf;
	255	mpenqueue_tail(&prof_queue, &buf_entry->p_list);
	256
	257	/* Switch to another buffer */
	258	reset_pbuf_area(pbuf);
	259
	260	/* Wake up the profile thread */
	261	if (profile_thread_id != THREAD_NULL)
	262	thread_wakeup((event_t) profile_thread);
	263	break;
	264
	265	default:
	266	printf("profile : unexpected case\n");
	267	}
	268	}
269
270	/*
271	*****************************************************************************
272	* pbuf_alloc creates a profile/trace buffer and assoc. zones for storing
273	* profiled items.
274	*****************************************************************************
275	*/
276
277	prof_data_t
278	pbuf_alloc(void)
279	{
280	register prof_data_t pbuf;
281	register int i;
282	register natural_t *zone;
283
284	pbuf = (prof_data_t)kalloc(sizeof(struct prof_data));
285	if (!pbuf)
286	return(NULLPROFDATA);
287	pbuf->prof_port = MACH_PORT_NULL;
288	for (i=0; i< NB_PROF_BUFFER; i++) {
289	zone = (natural_t )kalloc(SIZE_PROF_BUFFERsizeof(natural_t));
290	if (!zone) {
291	i--;
292	while (i--)
293	kfree((vm_offset_t)pbuf->prof_area[i].p_zone,
294	SIZE_PROF_BUFFER*sizeof(natural_t));
295	kfree((vm_offset_t)pbuf, sizeof(struct prof_data));
296	return(NULLPROFDATA);
297	}
298	pbuf->prof_area[i].p_zone = zone;
299	pbuf->prof_area[i].p_full = FALSE;
300	}
301	pbuf->prof_port = MACH_PORT_NULL;
302	return(pbuf);
303	}
304
305	/*
306	*****************************************************************************
307	* pbuf_free free memory allocated for storing profile/trace items. Called
308	* when a task is no longer profiled/traced. Pbuf_free tears down the memory
309	* alloced in pbuf_alloc. It does not check to see if the structures are valid
310	* since it is only called by functions in this file.
311	*****************************************************************************
312	*/
313	void
314	pbuf_free(
315	prof_data_t pbuf)
316	{
317	register int i;
318
319	if (pbuf->prof_port)
320	ipc_port_release_send(pbuf->prof_port);
321
322	for(i=0; i < NB_PROF_BUFFER ; i++)
323	kfree((vm_offset_t)pbuf->prof_area[i].p_zone,
324	SIZE_PROF_BUFFER*sizeof(natural_t));
325	kfree((vm_offset_t)pbuf, sizeof(struct prof_data));
326	}
327
328	#endif /* MACH_PROF */
329
330	/*
331	*****************************************************************************
332	* Thread_sample is used by MACH_PROF to profile a single thread, and is only
333	* stub in DCI.
334	*****************************************************************************
335	*/
336
337	kern_return_t
338	thread_sample(
339	thread_act_t thr_act,
340	ipc_port_t reply)
341	{
342	/*
343	* This routine is called every time that a new thread has made
344	* a request for the sampling service. We must keep track of the
345	* correspondance between its identity (thread) and the port
346	* we are going to use as a reply port to send out the samples resulting
347	* from its execution.
348	*/
349	#if !MACH_PROF
350	return KERN_FAILURE;
351	#else
352	prof_data_t pbuf;
353	vm_offset_t vmpbuf;
354
355	if (reply != MACH_PORT_NULL) {
356	if (thr_act->act_profiled) /* yuck! */
357	return KERN_INVALID_ARGUMENT;
358	/* Start profiling this activation, do the initialization. */
359	pbuf = pbuf_alloc();
360	if ((thr_act->profil_buffer = pbuf) == NULLPROFDATA) {
361	printf("thread_sample: cannot allocate pbuf\n");
362	return KERN_RESOURCE_SHORTAGE;
363	}
364	else {
365	if (!set_pbuf_nb(pbuf, NB_PROF_BUFFER-1)) {
366	printf("mach_sample_thread: cannot set pbuf_nb\n");
367	return KERN_FAILURE;
368	}
369	reset_pbuf_area(pbuf);
370	}
371	pbuf->prof_port = reply;
372	thr_act->act_profiled = TRUE;
373	thr_act->act_profiled_own = TRUE;
374	if (profile_thread_id == THREAD_NULL)
375	profile_thread_id = kernel_thread(kernel_task, profile_thread);
376	} else {
377	if (!thr_act->act_profiled)
378	return(KERN_INVALID_ARGUMENT);
379
380	thr_act->act_profiled = FALSE;
381	/* do not stop sampling if thread is not profiled by its own */
382
383	if (!thr_act->act_profiled_own)
384	return KERN_SUCCESS;
385	else
386	thr_act->act_profiled_own = FALSE;
387
388	send_last_sample_buf(thr_act->profil_buffer);
389	pbuf_free(thr_act->profil_buffer);
390	thr_act->profil_buffer = NULLPROFDATA;
391	}
392	return KERN_SUCCESS;
393	#endif /* MACH_PROF */
394	}
395
396	/*
397	*****************************************************************************
398	* Task_sample is used to profile/trace tasks - all thread within a task using
399	* a common profile buffer to collect items generated by the hertz_tick. For
400	* each task profiled a profile buffer is created that associates a reply port
401	* (used to send the data to a server thread), task (used for throttling), and
402	* a zone area (used to store profiled/traced items).
403	*****************************************************************************
404	*/
405
406	kern_return_t
407	task_sample(
408	task_t task,
409	ipc_port_t reply)
410	{
411	#if !MACH_PROF
412	return KERN_FAILURE;
413	#else
414	prof_data_t pbuf=task->profil_buffer;
415	vm_offset_t vmpbuf;
416	boolean_t turnon = (reply != MACH_PORT_NULL);
417
418	if (task == TASK_NULL)
419	return KERN_INVALID_ARGUMENT;
420	if (turnon) /* Do we want to profile this task? */
421	{
422	pbuf = pbuf_alloc(); /* allocate a profile buffer */
423	task_lock(task);
424	if (task->task_profiled) { /* if it is already profiled return so */
425	task_unlock(task);
426	if (pbuf != NULLPROFDATA)
427	pbuf_free(pbuf);
428	return(KERN_INVALID_ARGUMENT);
429	}
430	if (pbuf == NULLPROFDATA) {
431	task_unlock(task);
432	return KERN_RESOURCE_SHORTAGE; /* can't allocate a buffer, quit */
433	}
434	task->profil_buffer = pbuf;
435
436	if (!set_pbuf_nb(pbuf, NB_PROF_BUFFER-1)) {
437	pbuf_free(pbuf);
438	task_unlock(task);
439	return KERN_FAILURE;
440	}
441	reset_pbuf_area(pbuf);
442	pbuf->prof_port = reply; /* assoc. buffer with reply port */
443	} else { /* We want to stop profiling/tracing */
444	task_lock(task);
445	if (!task->task_profiled) { /* but this task is not being profiled */
446	task_unlock(task);
447	return(KERN_INVALID_ARGUMENT);
448	}
449	}
450
451	/*
452	* turnon = FALSE && task_profile = TRUE \|\|
453	* turnon = TRUE && task_profile = FALSE
454	*/
455
456	if (turnon != task->task_profiled) {
457	int actual, i;
458	thread_act_t thr_act;
459
460	if (turnon && profile_thread_id == THREAD_NULL) /* 1st time thru? */
461	profile_thread_id = /* then start profile thread. */
462	kernel_thread(kernel_task, profile_thread);
463	task->task_profiled = turnon;
464	actual = task->thr_act_count;
465	for (i = 0, thr_act = (thread_act_t)queue_first(&task->thr_acts);
466	i < actual;
467	i++, thr_act = (thread_act_t)queue_next(&thr_act->thr_acts)) {
468	if (!thr_act->act_profiled_own) {
469	thr_act->act_profiled = turnon;
470	if (turnon) {
471	thr_act->profil_buffer = task->profil_buffer;
472	thr_act->act_profiled = TRUE;
473	} else {
474	thr_act->act_profiled = FALSE;
475	thr_act->profil_buffer = NULLPROFDATA;
476	}
477	}
478	}
479	if (!turnon) { /* drain buffers and clean-up */
480	send_last_sample_buf(task->profil_buffer);
481	pbuf_free(task->profil_buffer);
482	task->profil_buffer = NULLPROFDATA;
483	}
484	}
485
486	task_unlock(task);
487	return KERN_SUCCESS;
488	#endif /* MACH_PROF */
489	}
490