File:  [DragonFly] / src / sys / netproto / atm / atm_subr.c
Revision 1.12: download - view: text, annotated - select for diffs
Sun Apr 11 07:41:52 2004 UTC (10 years ago) by hsu
Branches: MAIN
CVS tags: HEAD
Silence compiler warning by adding include files.

/*
 *
 * ===================================
 * HARP  |  Host ATM Research Platform
 * ===================================
 *
 *
 * This Host ATM Research Platform ("HARP") file (the "Software") is
 * made available by Network Computing Services, Inc. ("NetworkCS")
 * "AS IS".  NetworkCS does not provide maintenance, improvements or
 * support of any kind.
 *
 * NETWORKCS MAKES NO WARRANTIES OR REPRESENTATIONS, EXPRESS OR IMPLIED,
 * INCLUDING, BUT NOT LIMITED TO, IMPLIED WARRANTIES OF MERCHANTABILITY
 * AND FITNESS FOR A PARTICULAR PURPOSE, AS TO ANY ELEMENT OF THE
 * SOFTWARE OR ANY SUPPORT PROVIDED IN CONNECTION WITH THIS SOFTWARE.
 * In no event shall NetworkCS be responsible for any damages, including
 * but not limited to consequential damages, arising from or relating to
 * any use of the Software or related support.
 *
 * Copyright 1994-1998 Network Computing Services, Inc.
 *
 * Copies of this Software may be made, however, the above copyright
 * notice must be reproduced on all copies.
 *
 *	@(#) $FreeBSD: src/sys/netatm/atm_subr.c,v 1.7 2000/02/13 03:31:59 peter Exp $
 *	@(#) $DragonFly: src/sys/netproto/atm/atm_subr.c,v 1.12 2004/04/11 07:41:52 hsu Exp $
 */

/*
 * Core ATM Services
 * -----------------
 *
 * Miscellaneous ATM subroutines
 *
 */

#include "kern_include.h"

#include <sys/thread2.h>
#include <sys/msgport2.h>

/*
 * Global variables
 */
struct atm_pif		*atm_interface_head = NULL;
struct atm_ncm		*atm_netconv_head = NULL;
Atm_endpoint		*atm_endpoints[ENDPT_MAX+1] = {NULL};
struct sp_info		*atm_pool_head = NULL;
struct stackq_entry	*atm_stackq_head = NULL, *atm_stackq_tail;
#ifdef sgi
int			atm_intr_index;
#endif
struct atm_sock_stat	atm_sock_stat = { { 0 } };
int			atm_init = 0;
int			atm_debug = 0;
int			atm_dev_print = 0;
int			atm_print_data = 0;
int			atm_version = ATM_VERSION;
struct timeval		atm_debugtime = {0, 0};
struct ifqueue		atm_intrq;

struct sp_info	atm_attributes_pool = {
	"atm attributes pool",		/* si_name */
	sizeof(Atm_attributes),		/* si_blksiz */
	10,				/* si_blkcnt */
	100				/* si_maxallow */
};


/*
 * Local functions
 */
static void	atm_compact (struct atm_time *);
static KTimeout_ret	atm_timexp (void *);
static void	atm_intr(struct netmsg *);

/*
 * Local variables
 */
static struct atm_time	*atm_timeq = NULL;
static struct atm_time	atm_compactimer = {0, 0};

static struct sp_info	atm_stackq_pool = {
	"Service stack queue pool",	/* si_name */
	sizeof(struct stackq_entry),	/* si_blksiz */
	10,				/* si_blkcnt */
	10				/* si_maxallow */
};


/*
 * Initialize ATM kernel
 * 
 * Performs any initialization required before things really get underway.
 * Called from ATM domain initialization or from first registration function 
 * which gets called.
 *
 * Arguments:
 *	none
 *
 * Returns:
 *	none
 *
 */
void
atm_initialize()
{
	/*
	 * Never called from interrupts, so no locking needed
	 */
	if (atm_init)
		return;
	atm_init = 1;

#ifndef __DragonFly__
	/*
	 * Add ATM protocol family
	 */
	(void) protocol_family(&atmdomain, NULL, NULL);
#endif

	atm_intrq.ifq_maxlen = ATM_INTRQ_MAX;
#ifdef sgi
	atm_intr_index = register_isr(atm_intr);
#endif
#ifdef __DragonFly__
	netisr_register(NETISR_ATM, cpu0_portfn, atm_intr);
#endif

	/*
	 * Initialize subsystems
	 */
	atm_aal5_init();

	/*
	 * Prime the timer
	 */
	(void) timeout(atm_timexp, (void *)0, hz/ATM_HZ);

	/*
	 * Start the compaction timer
	 */
	atm_timeout(&atm_compactimer, SPOOL_COMPACT, atm_compact);
}


/*
 * Allocate a Control Block
 * 
 * Gets a new control block allocated from the specified storage pool, 
 * acquiring memory for new pool chunks if required.  The returned control
 * block's contents will be cleared.
 *
 * Arguments:
 *	sip	pointer to sp_info for storage pool
 *
 * Returns:
 *	addr	pointer to allocated control block
 *	0 	allocation failed
 *
 */
void *
atm_allocate(sip)
	struct sp_info	*sip;
{
	void		*bp;
	struct sp_chunk	*scp;
	struct sp_link	*slp;
	int		s = splnet();

	/*
	 * Count calls
	 */
	sip->si_allocs++;

	/*
	 * Are there any free in the pool?
	 */
	if (sip->si_free) {

		/*
		 * Find first chunk with a free block
		 */
		for (scp = sip->si_poolh; scp; scp = scp->sc_next) {
			if (scp->sc_freeh != NULL)
				break;
		}

	} else {

		/*
		 * No free blocks - have to allocate a new
		 * chunk (but put a limit to this)
		 */
		struct sp_link	*slp_next;
		int	i;

		/*
		 * First time for this pool??
		 */
		if (sip->si_chunksiz == 0) {
			size_t	n;

			/*
			 * Initialize pool information
			 */
			n = sizeof(struct sp_chunk) +
				sip->si_blkcnt * 
				(sip->si_blksiz + sizeof(struct sp_link));
			sip->si_chunksiz = roundup(n, SPOOL_ROUNDUP);

			/*
			 * Place pool on kernel chain
			 */
			LINK2TAIL(sip, struct sp_info, atm_pool_head, si_next);
		}

		if (sip->si_chunks >= sip->si_maxallow) {
			sip->si_fails++;
			(void) splx(s);
			return (NULL);
		}

		scp = (struct sp_chunk *)
			KM_ALLOC(sip->si_chunksiz, M_DEVBUF, M_NOWAIT);
		if (scp == NULL) {
			sip->si_fails++;
			(void) splx(s);
			return (NULL);
		}
		scp->sc_next = NULL;
		scp->sc_info = sip;
		scp->sc_magic = SPOOL_MAGIC;
		scp->sc_used = 0;

		/*
		 * Divy up chunk into free blocks
		 */
		slp = (struct sp_link *)(scp + 1);
		scp->sc_freeh = slp;

		for (i = sip->si_blkcnt; i > 1; i--) { 
			slp_next = (struct sp_link *)((caddr_t)(slp + 1) + 
					sip->si_blksiz);
			slp->sl_u.slu_next = slp_next;
			slp = slp_next;
		}
		slp->sl_u.slu_next = NULL;
		scp->sc_freet = slp;

		/*
		 * Add new chunk to end of pool
		 */
		if (sip->si_poolh)
			sip->si_poolt->sc_next = scp;
		else
			sip->si_poolh = scp;
		sip->si_poolt = scp;
		
		sip->si_chunks++;
		sip->si_total += sip->si_blkcnt;
		sip->si_free += sip->si_blkcnt;
		if (sip->si_chunks > sip->si_maxused)
			sip->si_maxused = sip->si_chunks;
	}

	/*
	 * Allocate the first free block in chunk
	 */
	slp = scp->sc_freeh;
	scp->sc_freeh = slp->sl_u.slu_next;
	scp->sc_used++;
	sip->si_free--;
	bp = (slp + 1);

	/*
	 * Save link back to pool chunk
	 */
	slp->sl_u.slu_chunk = scp;

	/*
	 * Clear out block
	 */
	KM_ZERO(bp, sip->si_blksiz);

	(void) splx(s);
	return (bp);
}


/*
 * Free a Control Block
 * 
 * Returns a previously allocated control block back to the owners 
 * storage pool.  
 *
 * Arguments:
 *	bp	pointer to block to be freed
 *
 * Returns:
 *	none
 *
 */
void
atm_free(bp)
	void		*bp;
{
	struct sp_info	*sip;
	struct sp_chunk	*scp;
	struct sp_link	*slp;
	int		s = splnet();

	/*
	 * Get containing chunk and pool info
	 */
	slp = (struct sp_link *)bp;
	slp--;
	scp = slp->sl_u.slu_chunk;
	if (scp->sc_magic != SPOOL_MAGIC)
		panic("atm_free: chunk magic missing");
	sip = scp->sc_info;

	/*
	 * Add block to free chain
	 */
	if (scp->sc_freeh) {
		scp->sc_freet->sl_u.slu_next = slp;
		scp->sc_freet = slp;
	} else
		scp->sc_freeh = scp->sc_freet = slp;
	slp->sl_u.slu_next = NULL;
	sip->si_free++;
	scp->sc_used--;

	(void) splx(s);
	return;
}


/*
 * Storage Pool Compaction
 * 
 * Called periodically in order to perform compaction of the
 * storage pools.  Each pool will be checked to see if any chunks 
 * can be freed, taking some care to avoid freeing too many chunks
 * in order to avoid memory thrashing.
 *
 * Called at splnet.
 *
 * Arguments:
 *	tip	pointer to timer control block (atm_compactimer)
 *
 * Returns:
 *	none
 *
 */
static void
atm_compact(tip)
	struct atm_time	*tip;
{
	struct sp_info	*sip;
	struct sp_chunk	*scp;
	int		i;
	struct sp_chunk	*scp_prev;

	/*
	 * Check out all storage pools
	 */
	for (sip = atm_pool_head; sip; sip = sip->si_next) {

		/*
		 * Always keep a minimum number of chunks around
		 */
		if (sip->si_chunks <= SPOOL_MIN_CHUNK)
			continue;

		/*
		 * Maximum chunks to free at one time will leave
		 * pool with at least 50% utilization, but never
		 * go below minimum chunk count.
		 */
		i = ((sip->si_free * 2) - sip->si_total) / sip->si_blkcnt;
		i = MIN(i, sip->si_chunks - SPOOL_MIN_CHUNK);

		/*
		 * Look for chunks to free
		 */
		scp_prev = NULL;
		for (scp = sip->si_poolh; scp && i > 0; ) {

			if (scp->sc_used == 0) {

				/*
				 * Found a chunk to free, so do it
				 */
				if (scp_prev) {
					scp_prev->sc_next = scp->sc_next;
					if (sip->si_poolt == scp)
						sip->si_poolt = scp_prev;
				} else
					sip->si_poolh = scp->sc_next;

				KM_FREE((caddr_t)scp, sip->si_chunksiz,
					M_DEVBUF);

				/*
				 * Update pool controls
				 */
				sip->si_chunks--;
				sip->si_total -= sip->si_blkcnt;
				sip->si_free -= sip->si_blkcnt;
				i--;
				if (scp_prev)
					scp = scp_prev->sc_next;
				else
					scp = sip->si_poolh;
			} else {
				scp_prev = scp;
				scp = scp->sc_next;
			}
		}
	}

	/*
	 * Restart the compaction timer
	 */
	atm_timeout(&atm_compactimer, SPOOL_COMPACT, atm_compact);

	return;
}


/*
 * Release a Storage Pool
 * 
 * Frees all dynamic storage acquired for a storage pool.
 * This function is normally called just prior to a module's unloading.
 *
 * Arguments:
 *	sip	pointer to sp_info for storage pool
 *
 * Returns:
 *	none
 *
 */
void
atm_release_pool(sip)
	struct sp_info	*sip;
{
	struct sp_chunk	*scp, *scp_next;
	int		s = splnet();

	/*
	 * Free each chunk in pool
	 */
	for (scp = sip->si_poolh; scp; scp = scp_next) {

		/*
		 * Check for memory leaks
		 */
		if (scp->sc_used)
			panic("atm_release_pool: unfreed blocks");

		scp_next = scp->sc_next;

		KM_FREE((caddr_t)scp, sip->si_chunksiz, M_DEVBUF);
	}

	/*
	 * Update pool controls
	 */
	sip->si_poolh = NULL;
	sip->si_chunks = 0;
	sip->si_total = 0;
	sip->si_free = 0;

	/*
	 * Unlink pool from active chain
	 */
	sip->si_chunksiz = 0;
	UNLINK(sip, struct sp_info, atm_pool_head, si_next);

	(void) splx(s);
	return;
}


/*
 * Handle timer tick expiration
 * 
 * Decrement tick count in first block on timer queue.  If there
 * are blocks with expired timers, call their timeout function.
 * This function is called ATM_HZ times per second.
 *
 * Arguments:
 *	arg	argument passed on timeout() call
 *
 * Returns:
 *	none
 *
 */
static KTimeout_ret
atm_timexp(arg)
	void	*arg;
{
	struct atm_time	*tip;
	int		s = splimp();


	/*
	 * Decrement tick count
	 */
	if (((tip = atm_timeq) == NULL) || (--tip->ti_ticks > 0)) {
		goto restart;
	}

	/*
	 * Stack queue should have been drained
	 */
#ifdef DIAGNOSTIC
	if (atm_stackq_head != NULL)
		panic("atm_timexp: stack queue not empty");
#endif

	/*
	 * Dispatch expired timers
	 */
	while (((tip = atm_timeq) != NULL) && (tip->ti_ticks == 0)) {
		void	(*func)(struct atm_time *);

		/*
		 * Remove expired block from queue
		 */
		atm_timeq = tip->ti_next;
		tip->ti_flag &= ~TIF_QUEUED;

		/*
		 * Call timeout handler (with network interrupts locked out)
		 */
		func = tip->ti_func;
		(void) splx(s);
		s = splnet();
		(*func)(tip);
		(void) splx(s);
		s = splimp();

		/*
		 * Drain any deferred calls
		 */
		STACK_DRAIN();
	}

restart:
	/*
	 * Restart the timer
	 */
	(void) splx(s);
	(void) timeout(atm_timexp, (void *)0, hz/ATM_HZ);

	return;
}


/*
 * Schedule a control block timeout
 * 
 * Place the supplied timer control block on the timer queue.  The
 * function (func) will be called in 't' timer ticks with the
 * control block address as its only argument.  There are ATM_HZ
 * timer ticks per second.  The ticks value stored in each block is
 * a delta of the number of ticks from the previous block in the queue.
 * Thus, for each tick interval, only the first block in the queue 
 * needs to have its tick value decremented.
 *
 * Arguments:
 *	tip	pointer to timer control block
 *	t	number of timer ticks until expiration
 *	func	pointer to function to call at expiration 
 *
 * Returns:
 *	none
 *
 */
void
atm_timeout(tip, t, func)
	struct atm_time	*tip;
	int		t;
	void		(*func)(struct atm_time *);
{
	struct atm_time	*tip1, *tip2;
	int		s;


	/*
	 * Check for double queueing error
	 */
	if (tip->ti_flag & TIF_QUEUED)
		panic("atm_timeout: double queueing");

	/*
	 * Make sure we delay at least a little bit
	 */
	if (t <= 0)
		t = 1;

	/*
	 * Find out where we belong on the queue
	 */
	s = splimp();
	for (tip1 = NULL, tip2 = atm_timeq; tip2 && (tip2->ti_ticks <= t); 
					    tip1 = tip2, tip2 = tip1->ti_next) {
		t -= tip2->ti_ticks;
	}

	/*
	 * Place ourselves on queue and update timer deltas
	 */
	if (tip1 == NULL)
		atm_timeq = tip;
	else
		tip1->ti_next = tip;
	tip->ti_next = tip2;

	if (tip2)
		tip2->ti_ticks -= t;
	
	/*
	 * Setup timer block
	 */
	tip->ti_flag |= TIF_QUEUED;
	tip->ti_ticks = t;
	tip->ti_func = func;

	(void) splx(s);
	return;
}


/*
 * Cancel a timeout
 * 
 * Remove the supplied timer control block from the timer queue.
 *
 * Arguments:
 *	tip	pointer to timer control block
 *
 * Returns:
 *	0	control block successfully dequeued
 * 	1	control block not on timer queue
 *
 */
int
atm_untimeout(tip)
	struct atm_time	*tip;
{
	struct atm_time	*tip1, *tip2;
	int		s;

	/*
	 * Is control block queued?
	 */
	if ((tip->ti_flag & TIF_QUEUED) == 0)
		return(1);

	/*
	 * Find control block on the queue
	 */
	s = splimp();
	for (tip1 = NULL, tip2 = atm_timeq; tip2 && (tip2 != tip); 
					    tip1 = tip2, tip2 = tip1->ti_next) {
	}

	if (tip2 == NULL) {
		(void) splx(s);
		return (1);
	}

	/*
	 * Remove block from queue and update timer deltas
	 */
	tip2 = tip->ti_next;
	if (tip1 == NULL)
		atm_timeq = tip2;
	else
		tip1->ti_next = tip2;

	if (tip2)
		tip2->ti_ticks += tip->ti_ticks;
	
	/*
	 * Reset timer block
	 */
	tip->ti_flag &= ~TIF_QUEUED;

	(void) splx(s);
	return (0);
}


/*
 * Queue a Stack Call 
 * 
 * Queues a stack call which must be deferred to the global stack queue.
 * The call parameters are stored in entries which are allocated from the
 * stack queue storage pool.
 *
 * Arguments:
 *	cmd	stack command
 *	func	destination function
 *	token	destination layer's token
 *	cvp	pointer to  connection vcc
 *	arg1	command argument
 *	arg2	command argument
 *
 * Returns:
 *	0 	call queued
 *	errno	call not queued - reason indicated
 *
 */
int
atm_stack_enq(cmd, func, token, cvp, arg1, arg2)
	int		cmd;
	void		(*func)(int, void *, int, int);
	void		*token;
	Atm_connvc	*cvp;
	int		arg1;
	int		arg2;
{
	struct stackq_entry	*sqp;
	int		s = splnet();

	/*
	 * Get a new queue entry for this call
	 */
	sqp = (struct stackq_entry *)atm_allocate(&atm_stackq_pool);
	if (sqp == NULL) {
		(void) splx(s);
		return (ENOMEM);
	}

	/*
	 * Fill in new entry
	 */
	sqp->sq_next = NULL;
	sqp->sq_cmd = cmd;
	sqp->sq_func = func;
	sqp->sq_token = token;
	sqp->sq_arg1 = arg1;
	sqp->sq_arg2 = arg2;
	sqp->sq_connvc = cvp;

	/*
	 * Put new entry at end of queue
	 */
	if (atm_stackq_head == NULL)
		atm_stackq_head = sqp;
	else
		atm_stackq_tail->sq_next = sqp;
	atm_stackq_tail = sqp;

	(void) splx(s);
	return (0);
}


/*
 * Drain the Stack Queue
 * 
 * Dequeues and processes entries from the global stack queue.  
 *
 * Arguments:
 *	none
 *
 * Returns:
 *	none
 *
 */
void
atm_stack_drain()
{
	struct stackq_entry	*sqp, *qprev, *qnext;
	int		s = splnet();
	int		cnt;

	/*
	 * Loop thru entire queue until queue is empty
	 *	(but panic rather loop forever)
	 */
	do {
		cnt = 0;
		qprev = NULL;
		for (sqp = atm_stackq_head; sqp; ) {

			/*
			 * Got an eligible entry, do STACK_CALL stuff
			 */
			if (sqp->sq_cmd & STKCMD_UP) {
				if (sqp->sq_connvc->cvc_downcnt) {

					/*
					 * Cant process now, skip it
					 */
					qprev = sqp;
					sqp = sqp->sq_next;
					continue;
				}

				/*
				 * OK, dispatch the call
				 */
				sqp->sq_connvc->cvc_upcnt++;
				(*sqp->sq_func)(sqp->sq_cmd, 
						sqp->sq_token,
						sqp->sq_arg1,
						sqp->sq_arg2);
				sqp->sq_connvc->cvc_upcnt--;
			} else {
				if (sqp->sq_connvc->cvc_upcnt) {

					/*
					 * Cant process now, skip it
					 */
					qprev = sqp;
					sqp = sqp->sq_next;
					continue;
				}

				/*
				 * OK, dispatch the call
				 */
				sqp->sq_connvc->cvc_downcnt++;
				(*sqp->sq_func)(sqp->sq_cmd, 
						sqp->sq_token,
						sqp->sq_arg1,
						sqp->sq_arg2);
				sqp->sq_connvc->cvc_downcnt--;
			}

			/*
			 * Dequeue processed entry and free it
			 */
			cnt++;
			qnext = sqp->sq_next;
			if (qprev)
				qprev->sq_next = qnext;
			else
				atm_stackq_head = qnext;
			if (qnext == NULL)
				atm_stackq_tail = qprev;
			atm_free((caddr_t)sqp);
			sqp = qnext;
		}
	} while (cnt > 0);

	/*
	 * Make sure entire queue was drained
	 */
	if (atm_stackq_head != NULL)
		panic("atm_stack_drain: Queue not emptied");

	(void) splx(s);
}


/*
 * Process Interrupt Queue
 * 
 * Processes entries on the ATM interrupt queue.  This queue is used by
 * device interface drivers in order to schedule events from the driver's 
 * lower (interrupt) half to the driver's stack services.
 *
 * The interrupt routines must store the stack processing function to call
 * and a token (typically a driver/stack control block) at the front of the
 * queued buffer.  We assume that the function pointer and token values are 
 * both contained (and properly aligned) in the first buffer of the chain.
 *
 * Arguments:
 *	none
 *
 * Returns:
 *	none
 *
 */
static void
atm_intr(struct netmsg *msg)
{
	struct mbuf *m = ((struct netmsg_packet *)msg)->nm_packet;
	caddr_t		cp;
	atm_intr_func_t	func;
	void		*token;

	/*
	 * Get function to call and token value
	 */
	KB_DATASTART(m, cp, caddr_t);
	func = *(atm_intr_func_t *)cp;
	cp += sizeof(func);
	token = *(void **)cp;
	KB_HEADADJ(m, -(sizeof(func) + sizeof(token)));
	if (KB_LEN(m) == 0) {
		KBuffer		*m1;
		KB_UNLINKHEAD(m, m1);
		m = m1;
	}

	/*
	 * Call processing function
	 */
	(*func)(token, m);

	/*
	 * Drain any deferred calls
	 */
	STACK_DRAIN();
	lwkt_replymsg(&msg->nm_lmsg, 0);
}

/*
 * Print a pdu buffer chain
 * 
 * Arguments:
 *	m	pointer to pdu buffer chain
 *	msg	pointer to message header string
 *
 * Returns:
 *	none
 *
 */
void
atm_pdu_print(m, msg)
	KBuffer		*m;
	char		*msg;
{
	caddr_t		cp;
	int		i;
	char		c = ' ';

	printf("%s:", msg);
	while (m) { 
		KB_DATASTART(m, cp, caddr_t);
		printf("%cbfr=%p data=%p len=%d: ",
			c, m, cp, KB_LEN(m));
		c = '\t';
		if (atm_print_data) {
			for (i = 0; i < KB_LEN(m); i++) {
				printf("%2x ", (u_char)*cp++);
			}
			printf("<end_bfr>\n");
		} else {
			printf("\n");
		}
		m = KB_NEXT(m);
	}
}