sys/netinet/dccp_tfrc.c

1.1    rjs /*	$KAME: dccp_tfrc.c,v 1.16 2006/03/01 17:34:08 nishida Exp $	*/
1.2  pooka /*	$NetBSD: dccp_tfrc.c,v 1.2 2015/08/24 22:21:26 pooka Exp $ */
1.1    rjs
1.1    rjs /*
1.1    rjs  * Copyright (c) 2003  Nils-Erik Mattsson
1.1    rjs  * All rights reserved.
1.1    rjs  *
1.1    rjs  * Redistribution and use in source and binary forms, with or without
1.1    rjs  * modification, are permitted provided that the following conditions
1.1    rjs  * are met:
1.1    rjs  *
1.1    rjs  * 1. Redistributions of source code must retain the above copyright
1.1    rjs  *    notice, this list of conditions and the following disclaimer.
1.1    rjs  * 2. Redistributions in binary form must reproduce the above copyright
1.1    rjs  *    notice, this list of conditions and the following disclaimer in the
1.1    rjs  *    documentation and/or other materials provided with the distribution.
1.1    rjs  * 3. The name of the author may not be used to endorse or promote products
1.1    rjs  *    derived from this software without specific prior written permission.
1.1    rjs  *
1.1    rjs  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
1.1    rjs  * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
1.1    rjs  * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
1.1    rjs  * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
1.1    rjs  * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
1.1    rjs  * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
1.1    rjs  * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
1.1    rjs  * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
1.1    rjs  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
1.1    rjs  * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
1.1    rjs  *
1.1    rjs  * Id: dccp_tfrc.c,v 1.47 2003/05/28 17:36:15 nilmat-8 Exp
1.1    rjs  */
1.1    rjs
1.1    rjs #include <sys/cdefs.h>
1.2  pooka __KERNEL_RCSID(0, "$NetBSD: dccp_tfrc.c,v 1.2 2015/08/24 22:21:26 pooka Exp $");
1.1    rjs
1.2  pooka #ifdef _KERNEL_OPT
1.1    rjs #include "opt_dccp.h"
1.2  pooka #endif
1.1    rjs
1.1    rjs /*
1.1    rjs  * This implementation conforms to the drafts of DCCP dated Mars 2003.
1.1    rjs  * The options used are window counter, elapsed time, loss event rate
1.1    rjs  * and receive rate.  No support for history discounting or oscillation
1.1    rjs  * prevention.
1.1    rjs  */
1.1    rjs
1.1    rjs #include <sys/param.h>
1.1    rjs #include <sys/systm.h>
1.1    rjs #include <sys/domain.h>
1.1    rjs #include <sys/kernel.h>
1.1    rjs #include <sys/lock.h>
1.1    rjs #include <sys/malloc.h>
1.1    rjs #include <sys/mbuf.h>
1.1    rjs #include <sys/proc.h>
1.1    rjs #include <sys/protosw.h>
1.1    rjs #include <sys/signalvar.h>
1.1    rjs #include <sys/socket.h>
1.1    rjs #include <sys/socketvar.h>
1.1    rjs #include <sys/mutex.h>
1.1    rjs #include <sys/sysctl.h>
1.1    rjs #include <sys/syslog.h>
1.1    rjs #include <sys/queue.h>
1.1    rjs #include <sys/callout.h>
1.1    rjs
1.1    rjs #include <net/if.h>
1.1    rjs #include <net/route.h>
1.1    rjs
1.1    rjs #include <netinet/in.h>
1.1    rjs #include <netinet/in_systm.h>
1.1    rjs #include <netinet/ip.h>
1.1    rjs
1.1    rjs #include <netinet/in_pcb.h>
1.1    rjs #include <netinet/in_var.h>
1.1    rjs #include <netinet/ip_icmp.h>
1.1    rjs #include <netinet/icmp_var.h>
1.1    rjs #include <netinet/ip_var.h>
1.1    rjs
1.1    rjs #include <netinet/dccp.h>
1.1    rjs #include <netinet/dccp_var.h>
1.1    rjs #include <netinet/dccp_tfrc.h>
1.1    rjs #include <netinet/dccp_tfrc_lookup.h>
1.1    rjs
1.1    rjs #define TFRCDEBUG
1.1    rjs #if 0
1.1    rjs #define TFRCDEBUGTIMERS
1.1    rjs #define NOTFRCSENDER
1.1    rjs #define NOTFRCRECV
1.1    rjs #endif
1.1    rjs
1.1    rjs #ifdef TFRCDEBUG
1.1    rjs #ifdef __FreeBSD__
1.1    rjs #define TFRC_DEBUG(args) log args
1.1    rjs #else
1.1    rjs #define TFRC_DEBUG(args) dccp_log args
1.1    rjs #endif
1.1    rjs #else
1.1    rjs #define TFRC_DEBUG(args)
1.1    rjs #endif
1.1    rjs
1.1    rjs #ifdef TFRCDEBUGTIMERS
1.1    rjs #ifdef __FreeBSD__
1.1    rjs #define TFRC_DEBUG_TIME(args) log args
1.1    rjs #else
1.1    rjs #define TFRC_DEBUG_TIME(args) dccp_log args
1.1    rjs #endif
1.1    rjs #else
1.1    rjs #define TFRC_DEBUG_TIME(args)
1.1    rjs #endif
1.1    rjs
1.1    rjs #if !defined(__FreeBSD__) || __FreeBSD_version < 500000
1.1    rjs #define	INP_INFO_LOCK_INIT(x,y)
1.1    rjs #define	INP_INFO_WLOCK(x)
1.1    rjs #define INP_INFO_WUNLOCK(x)
1.1    rjs #define	INP_INFO_RLOCK(x)
1.1    rjs #define INP_INFO_RUNLOCK(x)
1.1    rjs #define	INP_LOCK(x)
1.1    rjs #define INP_UNLOCK(x)
1.1    rjs #endif
1.1    rjs
1.1    rjs
1.1    rjs /* Timeval operations */
1.1    rjs const struct timeval delta_half = {0, TFRC_OPSYS_TIME_GRAN / 2};
1.1    rjs
1.1    rjs /*
1.1    rjs  * Half time value struct (accurate to +- 0.5us)
1.1    rjs  * args:  tvp  -  pointer to timeval structure
1.1    rjs  * Tested u:OK
1.1    rjs  */
1.1    rjs #define HALFTIMEVAL(tvp) \
1.1    rjs         do { \
1.1    rjs 		if ((tvp)->tv_sec & 1)							\
1.1    rjs 			(tvp)->tv_usec += 1000000;					\
1.1    rjs 			(tvp)->tv_sec = (tvp)->tv_sec >> 1;			\
1.1    rjs 			(tvp)->tv_usec = (tvp)->tv_usec >> 1;		\
1.1    rjs         } while (0)
1.1    rjs
1.1    rjs /* Sender side */
1.1    rjs
1.1    rjs /* Calculate new t_ipi (inter packet interval) by
1.1    rjs  *    t_ipi = s/X_inst;
1.1    rjs  * args:  ccbp - pointer to sender ccb block
1.1    rjs  * Tested u:OK - Note: No check for x = 0 -> t_ipi = {0xFFF...,0xFFF}
1.1    rjs  */
1.1    rjs #define CALCNEWTIPI(ccbp) \
1.1    rjs         do { \
1.1    rjs 			struct fixpoint x1, y1;									\
1.1    rjs 			x1.num = ccbp->s;										\
1.1    rjs 			x1.denom = 1;											\
1.1    rjs 			fixpoint_div(&x1, &x1, &(ccbp)->x);						\
1.1    rjs 			y1.num = (ccbp)->t_ipi.tv_sec = fixpoint_getlong(&x1);	\
1.1    rjs 			y1.denom = 1;											\
1.1    rjs 			fixpoint_sub(&x1, &x1, &y1);								\
1.1    rjs 			y1.num = 1000000;										\
1.1    rjs 			y1.denom = 1;											\
1.1    rjs 			fixpoint_mul(&x1, &x1, &y1);								\
1.1    rjs 			(ccbp)->t_ipi.tv_usec = fixpoint_getlong(&x1);			\
1.1    rjs         } while (0)
1.1    rjs
1.1    rjs /* Calculate new delta by
1.1    rjs  *    delta = min(t_ipi/2, t_gran/2);
1.1    rjs  * args: ccbp - pointer to sender ccb block
1.1    rjs  * Tested u:OK
1.1    rjs  */
1.1    rjs #define CALCNEWDELTA(ccbp) \
1.1    rjs          do { 													\
1.1    rjs 			(ccbp)->delta = delta_half;							\
1.1    rjs 			if ((ccbp)->t_ipi.tv_sec == 0 &&					\
1.1    rjs 			    (ccbp)->t_ipi.tv_usec < TFRC_OPSYS_TIME_GRAN) {	\
1.1    rjs 				(ccbp)->delta = (ccbp)->t_ipi;					\
1.1    rjs 				HALFTIMEVAL(&((ccbp)->delta));					\
1.1    rjs 			}													\
1.1    rjs 		 } while (0)
1.1    rjs
1.1    rjs #ifdef TFRCDEBUG
1.1    rjs #define PRINTFLOAT(x) TFRC_DEBUG((LOG_INFO, "%lld/%lld", (x)->num, (x)->denom));
1.1    rjs #endif
1.1    rjs
1.1    rjs const struct fixpoint tfrc_smallest_p = { 4LL, 1000000LL };
1.1    rjs
1.1    rjs /* External declarations */
1.1    rjs extern int dccp_get_option(char *, int, int, char *, int);
1.1    rjs
1.1    rjs /* Forward declarations */
1.1    rjs void tfrc_time_no_feedback(void *);
1.1    rjs void tfrc_time_send(void *);
1.1    rjs void tfrc_set_send_timer(struct tfrc_send_ccb *, struct timeval);
1.1    rjs void tfrc_updateX(struct tfrc_send_ccb *, struct timeval);
1.1    rjs const struct fixpoint *tfrc_calcX(u_int16_t, u_int32_t,
1.1    rjs 	const struct fixpoint *);
1.1    rjs void tfrc_send_term(void *);
1.1    rjs
1.1    rjs static void normalize(long long *, long long *);
1.1    rjs struct fixpoint *fixpoint_add(struct fixpoint *, const struct fixpoint *,
1.1    rjs 	const struct fixpoint *);
1.1    rjs struct fixpoint *fixpoint_sub(struct fixpoint *, const struct fixpoint *,
1.1    rjs 	const struct fixpoint *);
1.1    rjs int fixpoint_cmp(const struct fixpoint *, const struct fixpoint *);
1.1    rjs struct fixpoint *fixpoint_mul(struct fixpoint *, const struct fixpoint *,
1.1    rjs 	const struct fixpoint *);
1.1    rjs struct fixpoint *fixpoint_div(struct fixpoint *, const struct fixpoint *,
1.1    rjs 	const struct fixpoint *);
1.1    rjs long fixpoint_getlong(const struct fixpoint *);
1.1    rjs
1.1    rjs const struct fixpoint *flookup(const struct fixpoint *);
1.1    rjs const struct fixpoint *tfrc_flookup_reverse(const struct fixpoint *);
1.1    rjs
1.1    rjs /*
1.1    rjs  * Calculate the send rate according to TCP throughput eq.
1.1    rjs  * args: s - packet size (in bytes)
1.1    rjs  *       R - Round trip time  (in micro seconds)
1.1    rjs  *       p - loss event rate  (0<=p<=1)
1.1    rjs  * returns:  calculated send rate (in bytes per second)
1.1    rjs  * Tested u:OK
1.1    rjs  */
1.1    rjs __inline const struct fixpoint *
1.1    rjs tfrc_calcX(u_int16_t s, u_int32_t r, const struct fixpoint *p)
1.1    rjs {
1.1    rjs 	static struct fixpoint x;
1.1    rjs
1.1    rjs 	x.num = 1000000 * s;
1.1    rjs 	x.denom = 1 * r;
1.1    rjs 	fixpoint_div(&x, &x, p);
1.1    rjs 	return &x;
1.1    rjs }
1.1    rjs
1.1    rjs /*
1.1    rjs  * Function called by the send timer (to send packet)
1.1    rjs  * args: cb -  sender congestion control block
1.1    rjs  */
1.1    rjs void
1.1    rjs tfrc_time_send(void *ccb)
1.1    rjs {
1.1    rjs 	struct tfrc_send_ccb *cb = (struct tfrc_send_ccb *) ccb;
1.1    rjs 	int s;
1.1    rjs 	/*struct inpcb *inp;*/
1.1    rjs
1.1    rjs 	if (cb->state == TFRC_SSTATE_TERM) {
1.1    rjs 		TFRC_DEBUG((LOG_INFO,
1.1    rjs 			"TFRC - Send timer is ordered to terminate. (tfrc_time_send)\n"));
1.1    rjs 		return;
1.1    rjs 	}
1.1    rjs 	if (callout_pending(&cb->ch_stimer)) {
1.1    rjs 		TFRC_DEBUG((LOG_INFO,
1.1    rjs 		    "TFRC - Callout pending. (tfrc_time_send)\n"));
1.1    rjs 		return;
1.1    rjs 	}
1.1    rjs 	/* aquire locks for dccp_output */
1.1    rjs 	s = splsoftnet();
1.1    rjs 	INP_INFO_RLOCK(&dccpbinfo);
1.1    rjs 	/*inp = cb->pcb->d_inpcb;*/
1.1    rjs 	INP_LOCK(inp);
1.1    rjs 	INP_INFO_RUNLOCK(&dccpbinfo);
1.1    rjs
1.1    rjs 	callout_stop(&cb->ch_stimer);
1.1    rjs
1.1    rjs 	dccp_output(cb->pcb, 1);
1.1    rjs 	/* make sure we schedule next send time */
1.1    rjs 	tfrc_send_packet_sent(cb, 0, -1);
1.1    rjs
1.1    rjs 	/* release locks */
1.1    rjs 	INP_UNLOCK(inp);
1.1    rjs 	splx(s);
1.1    rjs }
1.1    rjs /*
1.1    rjs  * Calculate and set when the send timer should expire
1.1    rjs  * args: cb -  sender congestion control block
1.1    rjs  *       t_now - timeval struct containing actual time
1.1    rjs  * Tested u:OK
1.1    rjs  */
1.1    rjs void
1.1    rjs tfrc_set_send_timer(struct tfrc_send_ccb * cb, struct timeval t_now)
1.1    rjs {
1.1    rjs 	struct timeval t_temp;
1.1    rjs 	long t_ticks;
1.1    rjs
1.1    rjs 	/* set send timer to fire in t_ipi - (t_now-t_nom_old) or in other
1.1    rjs 	 * words after t_nom - t_now */
1.1    rjs 	t_temp = cb->t_nom;
1.1    rjs 	timersub(&t_temp, &t_now, &t_temp);
1.1    rjs
1.1    rjs #ifdef TFRCDEBUG
1.1    rjs 	if (t_temp.tv_sec < 0 || t_temp.tv_usec < 0)
1.1    rjs 		panic("TFRC - scheduled a negative time! (tfrc_set_send_timer)");
1.1    rjs #endif
1.1    rjs
1.1    rjs 	t_ticks = (t_temp.tv_usec + 1000000 * t_temp.tv_sec) / (1000000 / hz);
1.1    rjs 	if (t_ticks == 0) t_ticks = 1;
1.1    rjs
1.1    rjs 	TFRC_DEBUG_TIME((LOG_INFO,
1.1    rjs 	    "TFRC scheduled send timer to expire in %ld ticks (hz=%lu)\n", t_ticks, (unsigned long)hz));
1.1    rjs
1.1    rjs 	callout_reset(&cb->ch_stimer, t_ticks, tfrc_time_send, cb);
1.1    rjs }
1.1    rjs
1.1    rjs /*
1.1    rjs  * Update X by
1.1    rjs  *    If (p > 0)
1.1    rjs  *       x_calc = calcX(s,R,p);
1.1    rjs  *       X = max(min(X_calc, 2*X_recv), s/t_mbi);
1.1    rjs  *    Else
1.1    rjs  *       If (t_now - tld >= R)
1.1    rjs  *          X = max(min("2*X, 2*X_recv),s/R);
1.1    rjs  *          tld = t_now;
1.1    rjs  * args: cb -  sender congestion control block
1.1    rjs  *       t_now - timeval struct containing actual time
1.1    rjs  * Tested u:OK
1.1    rjs  */
1.1    rjs void
1.1    rjs tfrc_updateX(struct tfrc_send_ccb * cb, struct timeval t_now)
1.1    rjs {
1.1    rjs 	struct fixpoint temp, temp2;
1.1    rjs 	struct timeval t_temp, t_rtt = {0, 0};
1.1    rjs
1.1    rjs 	/* to avoid large error in calcX */
1.1    rjs 	if (fixpoint_cmp(&cb->p, &tfrc_smallest_p) >= 0) {
1.1    rjs 		cb->x_calc = *tfrc_calcX(cb->s, cb->rtt, &cb->p);
1.1    rjs 		temp = cb->x_recv;
1.1    rjs 		temp.num *= 2;
1.1    rjs 		if (fixpoint_cmp(&cb->x_calc, &temp) < 0)
1.1    rjs 			temp = cb->x_calc;
1.1    rjs 		cb->x = temp;
1.1    rjs 		temp2.num = cb->s;
1.1    rjs 		temp2.denom = TFRC_MAX_BACK_OFF_TIME;
1.1    rjs 		if (fixpoint_cmp(&temp, &temp2) < 0)
1.1    rjs 			cb->x = temp2;
1.1    rjs 		normalize(&cb->x.num, &cb->x.denom);
1.1    rjs 		TFRC_DEBUG((LOG_INFO, "TFRC updated send rate to "));
1.1    rjs 		PRINTFLOAT(&cb->x);
1.1    rjs 		TFRC_DEBUG((LOG_INFO, " bytes/s (tfrc_updateX, p>0)\n"));
1.1    rjs 	} else {
1.1    rjs 		t_rtt.tv_usec = cb->rtt % 1000000;
1.1    rjs 		t_rtt.tv_sec = cb->rtt / 1000000;
1.1    rjs 		t_temp = t_now;
1.1    rjs 		timersub(&t_temp, &cb->t_ld, &t_temp);
1.1    rjs 		if (timercmp(&t_temp, &t_rtt, >=)) {
1.1    rjs 			temp = cb->x_recv;
1.1    rjs 			temp.num *= 2;
1.1    rjs 			temp2 = cb->x;
1.1    rjs 			temp2.num *= 2;
1.1    rjs 			if (fixpoint_cmp(&temp2, &temp) < 0)
1.1    rjs 				temp = temp2;
1.1    rjs 			cb->x.num = cb->s;
1.1    rjs 			cb->x.denom = 1;
1.1    rjs 			cb->x.num *= 1000000;
1.1    rjs 			cb->x.denom *= cb->rtt;
1.1    rjs 			if (fixpoint_cmp(&temp, &cb->x) > 0)
1.1    rjs 				cb->x = temp;
1.1    rjs 			normalize(&cb->x.num, &cb->x.denom);
1.1    rjs 			cb->t_ld = t_now;
1.1    rjs 			TFRC_DEBUG((LOG_INFO, "TFRC updated send rate to "));
1.1    rjs 			PRINTFLOAT(&cb->x);
1.1    rjs 			TFRC_DEBUG((LOG_INFO, " bytes/s (tfrc_updateX, p==0)\n"));
1.1    rjs 		} else
1.1    rjs 			TFRC_DEBUG((LOG_INFO, "TFRC didn't update send rate! (tfrc_updateX, p==0)\n"));
1.1    rjs 	}
1.1    rjs }
1.1    rjs
1.1    rjs /*
1.1    rjs  * Function called by the no feedback timer
1.1    rjs  * args:  cb -  sender congestion control block
1.1    rjs  * Tested u:OK
1.1    rjs  */
1.1    rjs void
1.1    rjs tfrc_time_no_feedback(void *ccb)
1.1    rjs {
1.1    rjs 	struct fixpoint v, w;
1.1    rjs 	u_int32_t next_time_out = 1;	/* remove init! */
1.1    rjs 	struct timeval t_now;
1.1    rjs 	struct tfrc_send_ccb *cb = (struct tfrc_send_ccb *) ccb;
1.1    rjs
1.1    rjs 	mutex_enter(&(cb->mutex));
1.1    rjs
1.1    rjs 	if (cb->state == TFRC_SSTATE_TERM) {
1.1    rjs 		TFRC_DEBUG((LOG_INFO, "TFRC - No feedback timer is ordered to terminate\n"));
1.1    rjs 		goto nf_release;
1.1    rjs 	}
1.1    rjs 	if (callout_pending(&(cb)->ch_nftimer)) {
1.1    rjs 		TFRC_DEBUG((LOG_INFO, "TFRC - Callout pending, exiting...(tfrc_time_no_feedback)\n"));
1.1    rjs 		goto nf_release;
1.1    rjs 	}
1.1    rjs 	switch (cb->state) {
1.1    rjs 	case TFRC_SSTATE_NO_FBACK:
1.1    rjs 		TFRC_DEBUG((LOG_INFO, "TFRC - no feedback timer expired, state NO_FBACK\n"));
1.1    rjs 		/* half send rate */
1.1    rjs 		cb->x.denom *= 2;
1.1    rjs 		v.num = cb->s;
1.1    rjs 		v.denom *= TFRC_MAX_BACK_OFF_TIME;
1.1    rjs 		if (fixpoint_cmp(&cb->x, &v) < 0)
1.1    rjs 			cb->x = v;
1.1    rjs
1.1    rjs 		TFRC_DEBUG((LOG_INFO, "TFRC updated send rate to "));
1.1    rjs 		PRINTFLOAT(&cb->x);
1.1    rjs 		TFRC_DEBUG((LOG_INFO, " bytes/s (tfrc_time_no_feedback\n"));
1.1    rjs
1.1    rjs 		/* reschedule next time out */
1.1    rjs
1.1    rjs 		v.num = 2;
1.1    rjs 		v.denom = 1;
1.1    rjs 		w.num = cb->s;
1.1    rjs 		w.denom = 1;
1.1    rjs 		fixpoint_mul(&v, &v, &w);
1.1    rjs 		fixpoint_div(&v, &v, &(cb->x));
1.1    rjs 		v.num *= 1000000;
1.1    rjs 		normalize(&v.num, &v.denom);
1.1    rjs 		next_time_out = v.num / v.denom;
1.1    rjs 		if (next_time_out < TFRC_INITIAL_TIMEOUT * 1000000)
1.1    rjs 			next_time_out = TFRC_INITIAL_TIMEOUT * 1000000;
1.1    rjs 		break;
1.1    rjs 	case TFRC_SSTATE_FBACK:
1.1    rjs 		/*
1.1    rjs 	 	 * Check if IDLE since last timeout and recv rate is less than
1.1    rjs 		 * 4 packets per RTT
1.1    rjs 		 */
1.1    rjs
1.1    rjs 		v.num = cb->s;
1.1    rjs 		v.num *= 4;
1.1    rjs 		v.denom *= cb->rtt;
1.1    rjs 		v.num *= 1000000;
1.1    rjs 		normalize(&v.num, &v.denom);
1.1    rjs 		if (!cb->idle || fixpoint_cmp(&cb->x_recv, &v) >= 0) {
1.1    rjs 			TFRC_DEBUG((LOG_INFO, "TFRC - no feedback timer expired, state FBACK, not idle\n"));
1.1    rjs 			/* Half sending rate */
1.1    rjs
1.1    rjs 			/*
1.1    rjs 			 * If (X_calc > 2* X_recv) X_recv = max(X_recv/2,
1.1    rjs 			 * s/(2*t_mbi)); Else X_recv = X_calc/4;
1.1    rjs 			 */
1.1    rjs 			v.num = TFRC_SMALLEST_P;
1.1    rjs 			v.denom = 1;
1.1    rjs 			if (fixpoint_cmp(&cb->p, &v) < 0 && cb->x_calc.num == 0)
1.1    rjs 				panic("TFRC - X_calc is zero! (tfrc_time_no_feedback)\n");
1.1    rjs
1.1    rjs 			/* check also if p i zero -> x_calc is infinity ?? */
1.1    rjs 			w = cb->x_recv;
1.1    rjs 			w.num *= 2;
1.1    rjs 			if (fixpoint_cmp(&cb->p, &v) || fixpoint_cmp(&cb->x_calc, &w) > 0) {
1.1    rjs 				cb->x_recv.denom *= 2;
1.1    rjs 				w.num = cb->s;
1.1    rjs 				w.denom *= (2 * TFRC_MAX_BACK_OFF_TIME);
1.1    rjs 				if (fixpoint_cmp(&cb->x_recv, &w) < 0)
1.1    rjs 					cb->x_recv = w;
1.1    rjs 			} else
1.1    rjs 				cb->x_recv.denom *= 4;
1.1    rjs 			normalize(&cb->x_recv.num, &cb->x_recv.denom);
1.1    rjs
1.1    rjs 			/* Update sending rate */
1.1    rjs 			microtime(&t_now);
1.1    rjs 			tfrc_updateX(cb, t_now);
1.1    rjs 		}
1.1    rjs 		/* Schedule no feedback timer to expire in max(4*R, 2*s/X) */
1.1    rjs 		v.num = cb->s;
1.1    rjs 		v.num *= 2;
1.1    rjs 		fixpoint_div(&v, &v, &cb->x);
1.1    rjs 		v.num *= 1000000;
1.1    rjs 		next_time_out = v.num / v.denom;
1.1    rjs 		if (next_time_out < cb->t_rto)
1.1    rjs 			next_time_out = cb->t_rto;
1.1    rjs 		break;
1.1    rjs 	default:
1.1    rjs 		panic("tfrc_no_feedback: Illegal state!");
1.1    rjs 		break;
1.1    rjs 	}
1.1    rjs
1.1    rjs 	/* Set timer */
1.1    rjs
1.1    rjs 	next_time_out = next_time_out / (1000000 / hz);
1.1    rjs 	if (next_time_out == 0)
1.1    rjs 		next_time_out = 1;
1.1    rjs
1.1    rjs 	TFRC_DEBUG_TIME((LOG_INFO, "TFRC scheduled no feedback timer to expire in %u ticks (hz=%u)\n", next_time_out, hz));
1.1    rjs
1.1    rjs 	callout_reset(&cb->ch_nftimer, next_time_out, tfrc_time_no_feedback, cb);
1.1    rjs
1.1    rjs 	/* set idle flag */
1.1    rjs 	cb->idle = 1;
1.1    rjs nf_release:
1.1    rjs 	mutex_exit(&(cb->mutex));
1.1    rjs }
1.1    rjs
1.1    rjs /*
1.1    rjs  * Removes ccb from memory
1.1    rjs  * args: ccb - ccb of sender
1.1    rjs  */
1.1    rjs void
1.1    rjs tfrc_send_term(void *ccb)
1.1    rjs {
1.1    rjs 	struct tfrc_send_ccb *cb = (struct tfrc_send_ccb *) ccb;
1.1    rjs
1.1    rjs 	if (ccb == 0)
1.1    rjs 		panic("TFRC - Sender ccb is null! (free)");
1.1    rjs
1.1    rjs 	/* free sender */
1.1    rjs
1.1    rjs 	mutex_destroy(&(cb->mutex));
1.1    rjs
1.1    rjs 	free(cb, M_PCB);
1.1    rjs 	TFRC_DEBUG((LOG_INFO, "TFRC sender is destroyed\n"));
1.1    rjs }
1.1    rjs
1.1    rjs /* Functions declared in struct dccp_cc_sw */
1.1    rjs
1.1    rjs /*
1.1    rjs  * Initialises the sender side
1.1    rjs  * args:  pcb - dccp protocol control block
1.1    rjs  * returns: pointer to a tfrc_send_ccb struct on success, otherwise 0
1.1    rjs  * Tested u:OK
1.1    rjs  */
1.1    rjs void *
1.1    rjs tfrc_send_init(struct dccpcb * pcb)
1.1    rjs {
1.1    rjs 	struct tfrc_send_ccb *ccb;
1.1    rjs
1.1    rjs 	ccb = malloc(sizeof(struct tfrc_send_ccb), M_PCB, M_NOWAIT | M_ZERO);
1.1    rjs 	if (ccb == 0) {
1.1    rjs 		TFRC_DEBUG((LOG_INFO, "Unable to allocate memory for tfrc_send_ccb!\n"));
1.1    rjs 		return 0;
1.1    rjs 	}
1.1    rjs 	/* init sender */
1.1    rjs
1.1    rjs 	mutex_init(&(ccb->mutex), MUTEX_DEFAULT, IPL_SOFTNET);
1.1    rjs
1.1    rjs 	ccb->pcb = pcb;
1.1    rjs 	if (ccb->pcb->avgpsize >= TFRC_MIN_PACKET_SIZE && ccb->pcb->avgpsize <= TFRC_MAX_PACKET_SIZE)
1.1    rjs 		ccb->s = (u_int16_t) ccb->pcb->avgpsize;
1.1    rjs 	else
1.1    rjs 		ccb->s = TFRC_STD_PACKET_SIZE;
1.1    rjs
1.1    rjs 	TFRC_DEBUG((LOG_INFO, "TFRC - Sender is using packet size %u\n", ccb->s));
1.1    rjs
1.1    rjs 	ccb->x.num = ccb->s;	/* set transmissionrate to 1 packet per second */
1.1    rjs 	ccb->x.denom = 1;
1.1    rjs
1.1    rjs 	ccb->t_ld.tv_sec = -1;
1.1    rjs 	ccb->t_ld.tv_usec = 0;
1.1    rjs
1.1    rjs #ifdef TFRCDEBUG
1.1    rjs 	ccb->t_last_win_count.tv_sec = -1;
1.1    rjs #endif
1.1    rjs 	callout_init(&ccb->ch_stimer, 0);
1.1    rjs 	callout_init(&ccb->ch_nftimer, 0);
1.1    rjs
1.1    rjs 	/* init packet history */
1.1    rjs 	TAILQ_INIT(&(ccb->hist));
1.1    rjs
1.1    rjs 	ccb->state = TFRC_SSTATE_NO_SENT;
1.1    rjs
1.1    rjs 	TFRC_DEBUG((LOG_INFO, "TFRC sender initialised!\n"));
1.1    rjs 	dccpstat.tfrcs_send_conn++;
1.1    rjs 	return ccb;
1.1    rjs }
1.1    rjs
1.1    rjs /*
1.1    rjs  * Free the sender side
1.1    rjs  * args: ccb - ccb of sender
1.1    rjs  * Tested u:OK
1.1    rjs  */
1.1    rjs void
1.1    rjs tfrc_send_free(void *ccb)
1.1    rjs {
1.1    rjs 	struct s_hist_entry *elm, *elm2;
1.1    rjs 	struct tfrc_send_ccb *cb = (struct tfrc_send_ccb *) ccb;
1.1    rjs
1.1    rjs 	TFRC_DEBUG((LOG_INFO, "TFRC send free called!\n"));
1.1    rjs
1.1    rjs 	if (ccb == 0)
1.1    rjs 		return;
1.1    rjs
1.1    rjs 	/* uninit sender */
1.1    rjs
1.1    rjs 	/* get mutex */
1.1    rjs 	mutex_enter(&(cb->mutex));
1.1    rjs
1.1    rjs 	cb->state = TFRC_SSTATE_TERM;
1.1    rjs 	/* unschedule timers */
1.1    rjs 	callout_stop(&cb->ch_stimer);
1.1    rjs 	callout_stop(&cb->ch_nftimer);
1.1    rjs
1.1    rjs 	/* Empty packet history */
1.1    rjs 	elm = TAILQ_FIRST(&(cb->hist));
1.1    rjs 	while (elm != NULL) {
1.1    rjs 		elm2 = TAILQ_NEXT(elm, linfo);
1.1    rjs 		free(elm, M_TEMP);	/* M_TEMP ?? */
1.1    rjs 		elm = elm2;
1.1    rjs 	}
1.1    rjs 	TAILQ_INIT(&(cb->hist));
1.1    rjs
1.1    rjs 	mutex_exit(&(cb->mutex));
1.1    rjs
1.1    rjs 	/* schedule the removal of ccb */
1.1    rjs 	callout_reset(&cb->ch_stimer, TFRC_SEND_WAIT_TERM * hz, tfrc_send_term, cb);
1.1    rjs }
1.1    rjs
1.1    rjs /*
1.1    rjs  * Ask TFRC whether one can send a packet or not
1.1    rjs  * args: ccb  -  ccb block for current connection
1.1    rjs  * returns: 1 if ok, else 0.
1.1    rjs  */
1.1    rjs int
1.1    rjs tfrc_send_packet(void *ccb, long datasize)
1.1    rjs {
1.1    rjs 	struct s_hist_entry *new_packet;
1.1    rjs 	u_int8_t answer = 0;
1.1    rjs 	u_int8_t win_count = 0;
1.1    rjs 	u_int32_t uw_win_count = 0;
1.1    rjs 	struct timeval t_now, t_temp;
1.1    rjs 	struct tfrc_send_ccb *cb = (struct tfrc_send_ccb *) ccb;
1.1    rjs #ifdef NOTFRCSENDER
1.1    rjs 	return 1;
1.1    rjs #endif
1.1    rjs
1.1    rjs 	/* check if pure ACK or Terminating */
1.1    rjs 	if (datasize == 0 || cb->state == TFRC_SSTATE_TERM) {
1.1    rjs 		return 1;
1.1    rjs 	} else if (cb->state == TFRC_SSTATE_TERM) {
1.1    rjs 		TFRC_DEBUG((LOG_INFO, "TFRC - Asked to send packet when terminating!\n"));
1.1    rjs 		return 0;
1.1    rjs 	}
1.1    rjs 	/* we have data to send */
1.1    rjs 	mutex_enter(&(cb->mutex));
1.1    rjs
1.1    rjs 	/* check to see if we already have allocated memory last time */
1.1    rjs 	new_packet = TAILQ_FIRST(&(cb->hist));
1.1    rjs
1.1    rjs 	if ((new_packet != NULL && new_packet->t_sent.tv_sec >= 0) || new_packet == NULL) {
1.1    rjs 		/* check to see if we have memory to add to packet history */
1.1    rjs 		new_packet = malloc(sizeof(struct s_hist_entry), M_TEMP, M_NOWAIT);	/* M_TEMP?? */
1.1    rjs 		if (new_packet == NULL) {
1.1    rjs 			TFRC_DEBUG((LOG_INFO, "TFRC - Not enough memory to add packet to packet history (send refused)! (tfrc_send_packet)\n"));
1.1    rjs 			answer = 0;
1.1    rjs 			dccpstat.tfrcs_send_nomem++;
1.1    rjs 			goto sp_release;
1.1    rjs 		}
1.1    rjs 		new_packet->t_sent.tv_sec = -1;	/* mark as unsent */
1.1    rjs 		TAILQ_INSERT_HEAD(&(cb->hist), new_packet, linfo);
1.1    rjs 	}
1.1    rjs 	switch (cb->state) {
1.1    rjs 	case TFRC_SSTATE_NO_SENT:
1.1    rjs 		TFRC_DEBUG((LOG_INFO, "TFRC - DCCP ask permission to send first data packet (tfrc_send_packet)\n"));
1.1    rjs 		microtime(&(cb->t_nom));	/* set nominal send time for initial packet */
1.1    rjs 		t_now = cb->t_nom;
1.1    rjs
1.1    rjs 		/* init feedback timer */
1.1    rjs
1.1    rjs 		callout_reset(&cb->ch_nftimer, TFRC_INITIAL_TIMEOUT * hz, tfrc_time_no_feedback, cb);
1.1    rjs 		win_count = 0;
1.1    rjs 		cb->t_last_win_count = t_now;
1.1    rjs 		TFRC_DEBUG((LOG_INFO, "TFRC - Permission granted. Scheduled no feedback timer (initial) to expire in %u ticks (hz=%u) (tfrc_send_packet)\n", TFRC_INITIAL_TIMEOUT * hz, hz));
1.1    rjs 		/* start send timer */
1.1    rjs
1.1    rjs 		/* Calculate new t_ipi */
1.1    rjs 		CALCNEWTIPI(cb);
1.1    rjs 		timeradd(&cb->t_nom, &cb->t_ipi, &cb->t_nom);
1.1    rjs 		/* Calculate new delta */
1.1    rjs 		CALCNEWDELTA(cb);
1.1    rjs 		tfrc_set_send_timer(cb, t_now);	/* if so schedule sendtimer */
1.1    rjs 		cb->state = TFRC_SSTATE_NO_FBACK;
1.1    rjs 		answer = 1;
1.1    rjs 		break;
1.1    rjs 	case TFRC_SSTATE_NO_FBACK:
1.1    rjs 	case TFRC_SSTATE_FBACK:
1.1    rjs 		if (!callout_pending(&cb->ch_stimer)) {
1.1    rjs 			microtime(&t_now);
1.1    rjs
1.1    rjs 			t_temp = t_now;
1.1    rjs 			timeradd(&t_temp, &cb->delta, &t_temp);
1.1    rjs
1.1    rjs 			if ((timercmp(&(t_temp), &(cb->t_nom), >))) {
1.1    rjs 				/* Packet can be sent */
1.1    rjs
1.1    rjs #ifdef TFRCDEBUG
1.1    rjs 				if (cb->t_last_win_count.tv_sec == -1)
1.1    rjs 					panic("TFRC - t_last_win_count unitialized (tfrc_send_packet)\n");
1.1    rjs #endif
1.1    rjs 				t_temp = t_now;
1.1    rjs 				timersub(&t_temp, &(cb->t_last_win_count), &t_temp);
1.1    rjs
1.1    rjs 				/* XXX calculate window counter */
1.1    rjs 				if (cb->state == TFRC_SSTATE_NO_FBACK) {
1.1    rjs 					/* Assume RTT = t_rto(initial)/4 */
1.1    rjs 					uw_win_count = (t_temp.tv_sec + (t_temp.tv_usec / 1000000))
1.1    rjs 							/ TFRC_INITIAL_TIMEOUT / (4 * TFRC_WIN_COUNT_PER_RTT);
1.1    rjs 				} else {
1.1    rjs 					if (cb->rtt)
1.1    rjs 						uw_win_count = (t_temp.tv_sec * 1000000 + t_temp.tv_usec)
1.1    rjs 								/ cb->rtt / TFRC_WIN_COUNT_PER_RTT;
1.1    rjs 					else
1.1    rjs 						uw_win_count = 0;
1.1    rjs 				}
1.1    rjs 				uw_win_count += cb->last_win_count;
1.1    rjs 				win_count = uw_win_count % TFRC_WIN_COUNT_LIMIT;
1.1    rjs 				answer = 1;
1.1    rjs 			} else {
1.1    rjs 				answer = 0;
1.1    rjs 			}
1.1    rjs 		} else {
1.1    rjs 			answer = 0;
1.1    rjs 		}
1.1    rjs 		break;
1.1    rjs 	default:
1.1    rjs 		panic("tfrc_send_packet: Illegal state!");
1.1    rjs 		break;
1.1    rjs 	}
1.1    rjs
1.1    rjs 	if (answer) {
1.1    rjs 		cb->pcb->ccval = win_count;
1.1    rjs 		new_packet->win_count = win_count;
1.1    rjs 	}
1.1    rjs
1.1    rjs sp_release:
1.1    rjs 	mutex_exit(&(cb->mutex));
1.1    rjs 	return answer;
1.1    rjs }
1.1    rjs /* Notify sender that a packet has been sent
1.1    rjs  * args: ccb - ccb block for current connection
1.1    rjs  *	 moreToSend - if there exists more packets to send
1.1    rjs  *       dataSize -   packet size
1.1    rjs  */
1.1    rjs void
1.1    rjs tfrc_send_packet_sent(void *ccb, int moreToSend, long datasize)
1.1    rjs {
1.1    rjs 	struct timeval t_now, t_temp;
1.1    rjs 	struct s_hist_entry *packet;
1.1    rjs 	struct tfrc_send_ccb *cb = (struct tfrc_send_ccb *) ccb;
1.1    rjs
1.1    rjs #ifdef NOTFRCSENDER
1.1    rjs 	return;
1.1    rjs #endif
1.1    rjs
1.1    rjs 	if (cb->state == TFRC_SSTATE_TERM) {
1.1    rjs 		TFRC_DEBUG((LOG_INFO, "TFRC - Packet sent when terminating!\n"));
1.1    rjs 		return;
1.1    rjs 	}
1.1    rjs 	mutex_enter(&(cb->mutex));
1.1    rjs 	microtime(&t_now);
1.1    rjs
1.1    rjs 	/* check if we have sent a data packet */
1.1    rjs 	if (datasize > 0) {
1.1    rjs 		/* add send time to history */
1.1    rjs 		packet = TAILQ_FIRST(&(cb->hist));
1.1    rjs 		if (packet == NULL)
1.1    rjs 			panic("TFRC - Packet does not exist in history! (tfrc_send_packet_sent)");
1.1    rjs 		else if (packet != NULL && packet->t_sent.tv_sec >= 0)
1.1    rjs 			panic("TFRC - No unsent packet in history! (tfrc_send_packet_sent)");
1.1    rjs 		packet->t_sent = t_now;
1.1    rjs 		packet->seq = cb->pcb->seq_snd;
1.1    rjs 		/* check if win_count have changed */
1.1    rjs 		if (packet->win_count != cb->last_win_count) {
1.1    rjs 			cb->t_last_win_count = t_now;
1.1    rjs 			cb->last_win_count = packet->win_count;
1.1    rjs 		}
1.1    rjs 		TFRC_DEBUG((LOG_INFO, "TFRC - Packet sent (%llu, %u, (%lu.%lu)",
1.1    rjs 			packet->seq, packet->win_count, packet->t_sent.tv_sec, packet->t_sent.tv_usec));
1.1    rjs 		cb->idle = 0;
1.1    rjs 	}
1.1    rjs
1.1    rjs 	/* if timer is running, do nothing */
1.1    rjs 	if (callout_pending(&cb->ch_stimer)) {
1.1    rjs 		goto sps_release;
1.1    rjs 	}
1.1    rjs
1.1    rjs 	switch (cb->state) {
1.1    rjs 	case TFRC_SSTATE_NO_SENT:
1.1    rjs 		/* if first was pure ack */
1.1    rjs 		if (datasize == 0) {
1.1    rjs 			goto sps_release;
1.1    rjs 		} else
1.1    rjs 			panic("TFRC - First packet sent is noted as a data packet in tfrc_send_packet_sent\n");
1.1    rjs 		break;
1.1    rjs 	case TFRC_SSTATE_NO_FBACK:
1.1    rjs 	case TFRC_SSTATE_FBACK:
1.1    rjs 		if (datasize <= 0) {	/* we have ack (or simulate a sent
1.1    rjs 								 * packet which never can have
1.1    rjs 								 * moreToSend */
1.1    rjs 			moreToSend = 0;
1.1    rjs 		} else {
1.1    rjs 			/* Calculate new t_ipi */
1.1    rjs 			CALCNEWTIPI(cb);
1.1    rjs 			timeradd(&cb->t_nom, &cb->t_ipi, &cb->t_nom);
1.1    rjs 			/* Calculate new delta */
1.1    rjs 			CALCNEWDELTA(cb);
1.1    rjs 		}
1.1    rjs
1.1    rjs 		if (!moreToSend) {
1.1    rjs 			/* loop until we find a send time in the future */
1.1    rjs 			microtime(&t_now);
1.1    rjs 			t_temp = t_now;
1.1    rjs 			timeradd(&t_temp, &cb->delta, &t_temp);
1.1    rjs 			while ((timercmp(&(t_temp), &(cb->t_nom), >))) {
1.1    rjs 				/* Calculate new t_ipi */
1.1    rjs 				CALCNEWTIPI(cb);
1.1    rjs 				timeradd(&cb->t_nom, &cb->t_ipi, &cb->t_nom);
1.1    rjs
1.1    rjs 				/* Calculate new delta */
1.1    rjs 				CALCNEWDELTA(cb);
1.1    rjs
1.1    rjs 				microtime(&t_now);
1.1    rjs 				t_temp = t_now;
1.1    rjs 				timeradd(&t_temp, &cb->delta, &t_temp);
1.1    rjs 			}
1.1    rjs 			tfrc_set_send_timer(cb, t_now);
1.1    rjs 		} else {
1.1    rjs 			microtime(&t_now);
1.1    rjs 			t_temp = t_now;
1.1    rjs 			timeradd(&t_temp, &cb->delta, &t_temp);
1.1    rjs
1.1    rjs 			/* Check if next packet can not be sent immediately */
1.1    rjs 			if (!(timercmp(&(t_temp), &(cb->t_nom), >))) {
1.1    rjs 				tfrc_set_send_timer(cb, t_now);		/* if so schedule sendtimer */
1.1    rjs 			}
1.1    rjs 		}
1.1    rjs 		break;
1.1    rjs 	default:
1.1    rjs 		panic("tfrc_send_packet_sent: Illegal state!");
1.1    rjs 		break;
1.1    rjs 	}
1.1    rjs
1.1    rjs sps_release:
1.1    rjs 	mutex_exit(&(cb->mutex));
1.1    rjs }
1.1    rjs /* Notify that a an ack package was received (i.e. a feedback packet)
1.1    rjs  * args: ccb  -  ccb block for current connection
1.1    rjs  */
1.1    rjs void
1.1    rjs tfrc_send_packet_recv(void *ccb, char *options, int optlen)
1.1    rjs {
1.1    rjs 	u_int32_t next_time_out;
1.1    rjs 	struct timeval t_now;
1.1    rjs 	struct fixpoint x,y;
1.1    rjs 	int res;
1.1    rjs 	u_int16_t t_elapsed = 0;
1.1    rjs 	u_int32_t t_elapsed_l = 0;
1.1    rjs 	u_int32_t pinv;
1.1    rjs 	u_int32_t x_recv;
1.1    rjs
1.1    rjs 	u_int32_t r_sample;
1.1    rjs
1.1    rjs 	struct s_hist_entry *elm, *elm2;
1.1    rjs 	struct tfrc_send_ccb *cb = (struct tfrc_send_ccb *) ccb;
1.1    rjs
1.1    rjs #ifdef NOTFRCSENDER
1.1    rjs 	return;
1.1    rjs #endif
1.1    rjs
1.1    rjs 	if (cb->state == TFRC_SSTATE_TERM) {
1.1    rjs 		TFRC_DEBUG((LOG_INFO, "TFRC - Sender received a packet when terminating!\n"));
1.1    rjs 		return;
1.1    rjs 	}
1.1    rjs 	/* we are only interested in ACKs */
1.1    rjs 	if (!(cb->pcb->type_rcv == DCCP_TYPE_ACK || cb->pcb->type_rcv == DCCP_TYPE_DATAACK))
1.1    rjs 		return;
1.1    rjs
1.1    rjs 	res = dccp_get_option(options, optlen, TFRC_OPT_LOSS_RATE, (char *) &pinv, 6);
1.1    rjs 	if (res == 0) {
1.1    rjs 		TFRC_DEBUG((LOG_INFO, "TFRC - Missing Loss rate option! (tfrc_send_packet_recv)\n"));
1.1    rjs 		dccpstat.tfrcs_send_noopt++;
1.1    rjs 		return;
1.1    rjs 	}
1.1    rjs
1.1    rjs 	res = dccp_get_option(options, optlen, DCCP_OPT_ELAPSEDTIME, (char *) &t_elapsed_l, 6);
1.1    rjs 	if (res == 0) {
1.1    rjs 		/* try 2 bytes elapsed time */
1.1    rjs 		res = dccp_get_option(options, optlen, DCCP_OPT_ELAPSEDTIME, (char *) &t_elapsed, 4);
1.1    rjs 		if (res == 0){
1.1    rjs 			TFRC_DEBUG((LOG_INFO, "TFRC - Missing elapsed time option! (tfrc_send_packet_recv)\n"));
1.1    rjs 			dccpstat.tfrcs_send_noopt++;
1.1    rjs 			return;
1.1    rjs 		}
1.1    rjs 	}
1.1    rjs 	res = dccp_get_option(options, optlen, TFRC_OPT_RECEIVE_RATE, (char *) &x_recv, 4);
1.1    rjs 	if (res == 0) {
1.1    rjs 		TFRC_DEBUG((LOG_INFO, "TFRC - Missing x_recv option! (tfrc_send_packet_recv)\n"));
1.1    rjs 		dccpstat.tfrcs_send_noopt++;
1.1    rjs 		return;
1.1    rjs 	}
1.1    rjs 	dccpstat.tfrcs_send_fbacks++;
1.1    rjs 	/* change byte order */
1.1    rjs 	if (t_elapsed)
1.1    rjs 		t_elapsed = ntohs(t_elapsed);
1.1    rjs 	else
1.1    rjs 		t_elapsed_l = ntohl(t_elapsed_l);
1.1    rjs 	x_recv = ntohl(x_recv);
1.1    rjs 	pinv = ntohl(pinv);
1.1    rjs 	if (pinv == 0xFFFFFFFF) pinv = 0;
1.1    rjs
1.1    rjs 	if (t_elapsed)
1.1    rjs 		TFRC_DEBUG((LOG_INFO, "TFRC - Receieved options on ack %llu: pinv=%u, t_elapsed=%u, x_recv=%u ! (tfrc_send_packet_recv)\n", cb->pcb->ack_rcv, pinv, t_elapsed, x_recv));
1.1    rjs 	else
1.1    rjs 		TFRC_DEBUG((LOG_INFO, "TFRC - Receieved options on ack %llu: pinv=%u, t_elapsed=%u, x_recv=%u ! (tfrc_send_packet_recv)\n", cb->pcb->ack_rcv, pinv, t_elapsed_l, x_recv));
1.1    rjs
1.1    rjs 	mutex_enter(&(cb->mutex));
1.1    rjs
1.1    rjs 	switch (cb->state) {
1.1    rjs 	case TFRC_SSTATE_NO_FBACK:
1.1    rjs 	case TFRC_SSTATE_FBACK:
1.1    rjs 		/* Calculate new round trip sample by R_sample = (t_now -
1.1    rjs 		 * t_recvdata)-t_delay; */
1.1    rjs
1.1    rjs 		/* get t_recvdata from history */
1.1    rjs 		elm = TAILQ_FIRST(&(cb->hist));
1.1    rjs 		while (elm != NULL) {
1.1    rjs 			if (elm->seq == cb->pcb->ack_rcv)
1.1    rjs 				break;
1.1    rjs 			elm = TAILQ_NEXT(elm, linfo);
1.1    rjs 		}
1.1    rjs
1.1    rjs 		if (elm == NULL) {
1.1    rjs 			TFRC_DEBUG((LOG_INFO,
1.1    rjs 				"TFRC - Packet does not exist in history (seq=%llu)! (tfrc_send_packet_recv)", cb->pcb->ack_rcv));
1.1    rjs 			goto sar_release;
1.1    rjs 		}
1.1    rjs 		/* Update RTT */
1.1    rjs 		microtime(&t_now);
1.1    rjs 		timersub(&t_now, &(elm->t_sent), &t_now);
1.1    rjs 		r_sample = t_now.tv_sec * 1000000 + t_now.tv_usec;
1.1    rjs 		if (t_elapsed)
1.1    rjs 			r_sample = r_sample - ((u_int32_t) t_elapsed * 10); /* t_elapsed in us */
1.1    rjs 		else
1.1    rjs 			r_sample = r_sample - (t_elapsed_l * 10);	/* t_elapsed in us */
1.1    rjs
1.1    rjs 		/* Update RTT estimate by If (No feedback recv) R = R_sample;
1.1    rjs 		 * Else R = q*R+(1-q)*R_sample; */
1.1    rjs 		if (cb->state == TFRC_SSTATE_NO_FBACK) {
1.1    rjs 			cb->state = TFRC_SSTATE_FBACK;
1.1    rjs 			cb->rtt = r_sample;
1.1    rjs 		} else {
1.1    rjs 			cb->rtt = (u_int32_t) (TFRC_RTT_FILTER_CONST * cb->rtt +
1.1    rjs 			    (1 - TFRC_RTT_FILTER_CONST) * r_sample);
1.1    rjs 		}
1.1    rjs
1.1    rjs 		TFRC_DEBUG((LOG_INFO, "TFRC - New RTT estimate %u (tfrc_send_packet_recv)\n", cb->rtt));
1.1    rjs
1.1    rjs 		/* Update timeout interval */
1.1    rjs 		cb->t_rto = 4 * cb->rtt;
1.1    rjs
1.1    rjs 		/* Update receive rate */
1.1    rjs 		x.num = x_recv;
1.1    rjs 		y.num = 8;
1.1    rjs 		x.denom = y.denom = 1;
1.1    rjs 		fixpoint_div(&(cb)->x_recv, &x, &y);
1.1    rjs
1.1    rjs 		/* Update loss event rate */
1.1    rjs 		if (pinv == 0) {
1.1    rjs 			cb->p.num = cb->p.denom = 0;
1.1    rjs 		} else {
1.1    rjs 			cb->p.num  = 1.0;
1.1    rjs 			cb->p.denom = pinv;
1.1    rjs 			if (fixpoint_cmp(&cb->p, &tfrc_smallest_p) <= 0) {
1.1    rjs 				cb->p.num  = tfrc_smallest_p.num;
1.1    rjs 				cb->p.denom  = tfrc_smallest_p.denom;
1.1    rjs 				TFRC_DEBUG((LOG_INFO, "TFRC - Smallest p used!\n"));
1.1    rjs 			}
1.1    rjs 		}
1.1    rjs
1.1    rjs 		/* unschedule no feedback timer */
1.1    rjs 		if (!callout_pending(&cb->ch_nftimer)) {
1.1    rjs 			callout_stop(&cb->ch_nftimer);
1.1    rjs 		}
1.1    rjs 		/* Update sending rate */
1.1    rjs 		microtime(&t_now);
1.1    rjs 		tfrc_updateX(cb, t_now);
1.1    rjs
1.1    rjs 		/* Update next send time */
1.1    rjs 		timersub(&cb->t_nom, &cb->t_ipi, &cb->t_nom);
1.1    rjs
1.1    rjs 		/* Calculate new t_ipi */
1.1    rjs 		CALCNEWTIPI(cb);
1.1    rjs 		timeradd(&cb->t_nom, &cb->t_ipi, &cb->t_nom);
1.1    rjs 		/* Calculate new delta */
1.1    rjs 		CALCNEWDELTA(cb);
1.1    rjs
1.1    rjs 		if (callout_pending(&cb->ch_stimer)) {
1.1    rjs 			callout_stop(&cb->ch_stimer);
1.1    rjs 		}
1.1    rjs
1.1    rjs #if 0 /* XXX do not send ack of ack so far */
1.1    rjs 		dccp_output(cb->pcb, 1);
1.1    rjs 		tfrc_send_packet_sent(cb, 0, -1);	/* make sure we schedule next send time */
1.1    rjs #endif
1.1    rjs
1.1    rjs 		/* remove all packets older than the one acked from history */
1.1    rjs 		/* elm points to acked package! */
1.1    rjs
1.1    rjs 		elm2 = TAILQ_NEXT(elm, linfo);
1.1    rjs
1.1    rjs 		while (elm2 != NULL) {
1.1    rjs 			TAILQ_REMOVE(&(cb->hist), elm2, linfo);
1.1    rjs 			free(elm2, M_TEMP);
1.1    rjs 			elm2 = TAILQ_NEXT(elm, linfo);
1.1    rjs 		}
1.1    rjs
1.1    rjs 		/* Schedule no feedback timer to expire in max(4*R, 2*s/X) */
1.1    rjs 		/* next_time_out = (u_int32_t) (2 * cb->s * 1000000 / cb->x); */
1.1    rjs
1.1    rjs 		x.num = 2;
1.1    rjs 		x.denom = 1;
1.1    rjs 		y.num = cb->s;
1.1    rjs 		y.denom = 1;
1.1    rjs 		fixpoint_mul(&x, &x, &y);
1.1    rjs 		fixpoint_div(&x, &x, &(cb->x));
1.1    rjs 		x.num *= 1000000;
1.1    rjs 		normalize(&x.num, &x.denom);
1.1    rjs 		next_time_out = x.num / x.denom;
1.1    rjs
1.1    rjs 		if (next_time_out < cb->t_rto)
1.1    rjs 			next_time_out = cb->t_rto;
1.1    rjs 		TFRC_DEBUG_TIME((LOG_INFO,
1.1    rjs 			"TFRC - Scheduled no feedback timer to expire in %u ticks (%u us) (hz=%u)(tfrc_send_packet_recv)\n",
1.1    rjs 			next_time_out / (1000000 / hz), next_time_out, hz));
1.1    rjs 		next_time_out = next_time_out / (1000000 / hz);
1.1    rjs 		if (next_time_out == 0)
1.1    rjs 			next_time_out = 1;
1.1    rjs
1.1    rjs 		callout_reset(&cb->ch_nftimer, next_time_out, tfrc_time_no_feedback, cb);
1.1    rjs
1.1    rjs 		/* set idle flag */
1.1    rjs 		cb->idle = 1;
1.1    rjs 		break;
1.1    rjs 	default:
1.1    rjs 		panic("tfrc_send_packet_recv: Illegal state!");
1.1    rjs 		break;
1.1    rjs 	}
1.1    rjs sar_release:
1.1    rjs 	mutex_exit(&(cb->mutex));
1.1    rjs }
1.1    rjs /* Receiver side */
1.1    rjs
1.1    rjs /* Forward declarations */
1.1    rjs long tfrc_calclmean(struct tfrc_recv_ccb *);
1.1    rjs void tfrc_recv_send_feedback(struct tfrc_recv_ccb *);
1.1    rjs int tfrc_recv_add_hist(struct tfrc_recv_ccb *, struct r_hist_entry *);
1.1    rjs void tfrc_recv_detectLoss(struct tfrc_recv_ccb *);
1.1    rjs u_int32_t tfrc_recv_calcFirstLI(struct tfrc_recv_ccb *);
1.1    rjs void tfrc_recv_updateLI(struct tfrc_recv_ccb *, long, u_int8_t);
1.1    rjs
1.1    rjs /* Weights used to calculate loss event rate */
1.1    rjs /* const double tfrc_recv_w[] = { 1,  1,   1,   1,  0.8,  0.6, 0.4, 0.2}; */
1.1    rjs const struct fixpoint tfrc_recv_w[] = {{1,1},  {1,1},  {1,1},  {1,1},  {4,5},  {3,5}, {2,5}, {1,5}};
1.1    rjs
1.1    rjs /* Find a data packet in history
1.1    rjs  * args:  cb - ccb of receiver
1.1    rjs  *        elm - pointer to element (variable)
1.1    rjs  *        num - number in history (variable)
1.1    rjs  * returns:  elm points to found packet, otherwise NULL
1.1    rjs  * Tested u:OK
1.1    rjs  */
1.1    rjs #define TFRC_RECV_FINDDATAPACKET(cb,elm,num) \
1.1    rjs   do { \
1.1    rjs     elm = TAILQ_FIRST(&((cb)->hist)); \
1.1    rjs       while ((elm) != NULL) { \
1.1    rjs         if ((elm)->type == DCCP_TYPE_DATA || (elm)->type == DCCP_TYPE_DATAACK) \
1.1    rjs           (num)--; \
1.1    rjs         if (num == 0) \
1.1    rjs           break; \
1.1    rjs         elm = TAILQ_NEXT((elm), linfo); \
1.1    rjs       } \
1.1    rjs   } while (0)
1.1    rjs
1.1    rjs /* Find next data packet in history
1.1    rjs  * args:  cb - ccb of receiver
1.1    rjs  *        elm - pointer to element (variable)
1.1    rjs  * returns:  elm points to found packet, otherwise NULL
1.1    rjs  * Tested u:OK
1.1    rjs  */
1.1    rjs #define TFRC_RECV_NEXTDATAPACKET(cb,elm) \
1.1    rjs   do { \
1.1    rjs     if (elm != NULL) { \
1.1    rjs       elm = TAILQ_NEXT(elm, linfo); \
1.1    rjs       while ((elm) != NULL && (elm)->type != DCCP_TYPE_DATA && (elm)->type != DCCP_TYPE_DATAACK) { \
1.1    rjs         elm = TAILQ_NEXT((elm), linfo); \
1.1    rjs       } \
1.1    rjs     } \
1.1    rjs   } while (0)
1.1    rjs
1.1    rjs /*
1.1    rjs  * Calculate avarage loss Interval I_mean
1.1    rjs  * args: cb - ccb of receiver
1.1    rjs  * returns: avarage loss interval
1.1    rjs  * Tested u:OK
1.1    rjs  */
1.1    rjs long
1.1    rjs tfrc_calclmean(struct tfrc_recv_ccb * cb)
1.1    rjs {
1.1    rjs 	struct li_hist_entry *elm;
1.1    rjs 	struct fixpoint l_tot;
1.1    rjs 	struct fixpoint l_tot0 = {0,0};
1.1    rjs 	struct fixpoint l_tot1 = {0,0};
1.1    rjs 	struct fixpoint W_tot = {0, 0};
1.1    rjs 	struct fixpoint tmp;
1.1    rjs 	int i;
1.1    rjs 	elm = TAILQ_FIRST(&(cb->li_hist));
1.1    rjs
1.1    rjs 	for (i = 0; i < TFRC_RECV_IVAL_F_LENGTH; i++) {
1.1    rjs #ifdef TFRCDEBUG
1.1    rjs 		if (elm == 0)
1.1    rjs 			goto I_panic;
1.1    rjs #endif
1.1    rjs
1.1    rjs /*
1.1    rjs 		I_tot0 = I_tot0 + (elm->interval * tfrc_recv_w[i]);
1.1    rjs 		W_tot = W_tot + tfrc_recv_w[i];
1.1    rjs */
1.1    rjs 		tmp.num = elm->interval;
1.1    rjs 		tmp.denom = 1;
1.1    rjs 		fixpoint_mul(&tmp, &tmp, &tfrc_recv_w[i]);
1.1    rjs 		fixpoint_add(&l_tot0, &l_tot0, &tmp);
1.1    rjs 		fixpoint_add(&W_tot, &W_tot, &tfrc_recv_w[i]);
1.1    rjs
1.1    rjs 		elm = TAILQ_NEXT(elm, linfo);
1.1    rjs 	}
1.1    rjs
1.1    rjs 	elm = TAILQ_FIRST(&(cb->li_hist));
1.1    rjs 	elm = TAILQ_NEXT(elm, linfo);
1.1    rjs
1.1    rjs 	for (i = 1; i <= TFRC_RECV_IVAL_F_LENGTH; i++) {
1.1    rjs #ifdef TFRCDEBUG
1.1    rjs 		if (elm == 0)
1.1    rjs 			goto I_panic;
1.1    rjs #endif
1.1    rjs /*
1.1    rjs 		I_tot1 = I_tot1 + (elm->interval * tfrc_recv_w[i - 1]);
1.1    rjs */
1.1    rjs 		tmp.num = elm->interval;
1.1    rjs 		tmp.denom = 1;
1.1    rjs 		fixpoint_mul(&tmp, &tmp, &tfrc_recv_w[i-1]);
1.1    rjs 		fixpoint_add(&l_tot1, &l_tot1, &tmp);
1.1    rjs
1.1    rjs 		elm = TAILQ_NEXT(elm, linfo);
1.1    rjs 	}
1.1    rjs
1.1    rjs 	/* I_tot = max(I_tot0, I_tot1) */
1.1    rjs 	/*
1.1    rjs 	I_tot = I_tot0;
1.1    rjs 	if (I_tot0 < I_tot1)
1.1    rjs 		I_tot = I_tot1;
1.1    rjs
1.1    rjs 	if (I_tot < W_tot)
1.1    rjs 		I_tot = W_tot;
1.1    rjs 	return (I_tot / W_tot);
1.1    rjs 	*/
1.1    rjs
1.1    rjs 	l_tot.num = l_tot0.num;
1.1    rjs 	l_tot.denom = l_tot0.denom;
1.1    rjs 	if (fixpoint_cmp(&l_tot0, &l_tot1) < 0){
1.1    rjs 		l_tot.num = l_tot1.num;
1.1    rjs 		l_tot.denom = l_tot1.denom;
1.1    rjs 	}
1.1    rjs
1.1    rjs 	if (fixpoint_cmp(&l_tot, &W_tot) < 0){
1.1    rjs 		l_tot.num = W_tot.num;
1.1    rjs 		l_tot.denom = W_tot.denom;
1.1    rjs 	}
1.1    rjs 	fixpoint_div(&tmp, &l_tot, &W_tot);
1.1    rjs 	return(fixpoint_getlong(&tmp));
1.1    rjs
1.1    rjs #ifdef TFRCDEBUG
1.1    rjs I_panic:
1.1    rjs 	panic("TFRC - Missing entry in interval history! (tfrc_calclmean)");
1.1    rjs #endif
1.1    rjs }
1.1    rjs
1.1    rjs /*
1.1    rjs  * Send a feedback packet
1.1    rjs  * args: cb - ccb for receiver
1.1    rjs  * Tested u:OK
1.1    rjs  */
1.1    rjs void
1.1    rjs tfrc_recv_send_feedback(struct tfrc_recv_ccb * cb)
1.1    rjs {
1.1    rjs 	u_int32_t x_recv, pinv;
1.1    rjs 	u_int32_t t_elapsed;
1.1    rjs 	struct r_hist_entry *elm;
1.1    rjs 	struct fixpoint x;
1.1    rjs 	struct timeval t_now, t_temp;
1.1    rjs 	int num;
1.1    rjs
1.1    rjs 	x.num = 1;
1.1    rjs 	x.denom = 4000000000LL;		/* -> 1/p > 4 000 000 000 */
1.1    rjs 	if (fixpoint_cmp(&cb->p, &x) < 0)
1.1    rjs 		/*  if (cb->p < 0.00000000025)	-> 1/p > 4 000 000 000 */
1.1    rjs 		pinv = 0xFFFFFFFF;
1.1    rjs 	else {
1.1    rjs 		/*	pinv = (u_int32_t) (1.0 / cb->p); */
1.1    rjs 		x.num = 1;
1.1    rjs 		x.denom = 1;
1.1    rjs 		fixpoint_div(&x, &x, &(cb)->p);
1.1    rjs 		pinv = fixpoint_getlong(&x);
1.1    rjs 	}
1.1    rjs
1.1    rjs 	switch (cb->state) {
1.1    rjs 	case TFRC_RSTATE_NO_DATA:
1.1    rjs 		x_recv = 0;
1.1    rjs 		break;
1.1    rjs 	case TFRC_RSTATE_DATA:
1.1    rjs 		/* Calculate x_recv */
1.1    rjs 		microtime(&t_temp);
1.1    rjs 		timersub(&t_temp, &cb->t_last_feedback, &t_temp);
1.1    rjs
1.1    rjs 		x_recv = (u_int32_t) (cb->bytes_recv * 8 * 1000000) / (t_temp.tv_sec * 1000000 + t_temp.tv_usec);
1.1    rjs
1.1    rjs 		break;
1.1    rjs 	default:
1.1    rjs 		panic("tfrc_recv_send_feedback: Illegal state!");
1.1    rjs 		break;
1.1    rjs 	}
1.1    rjs
1.1    rjs 	/* Find largest win_count so far (data packet with highest seqnum so far) */
1.1    rjs 	num = 1;
1.1    rjs 	TFRC_RECV_FINDDATAPACKET(cb, elm, num);
1.1    rjs
1.1    rjs 	if (elm == NULL)
1.1    rjs 		panic("No data packet in history! (tfrc_recv_send_feedback)");
1.1    rjs
1.1    rjs
1.1    rjs 	microtime(&t_now);
1.1    rjs 	timersub(&t_now, &elm->t_recv, &t_now);
1.1    rjs 	t_elapsed = (u_int32_t) (t_now.tv_sec * 100000 + t_now.tv_usec / 10);
1.1    rjs
1.1    rjs 	/* change byte order */
1.1    rjs 	t_elapsed = htonl(t_elapsed);
1.1    rjs 	x_recv = htonl(x_recv);
1.1    rjs 	pinv = htonl(pinv);
1.1    rjs
1.1    rjs 	/* add options from variables above */
1.1    rjs 	if (dccp_add_option(cb->pcb, TFRC_OPT_LOSS_RATE, (char *) &pinv, 4)
1.1    rjs 	    || dccp_add_option(cb->pcb, DCCP_OPT_ELAPSEDTIME, (char *) &t_elapsed, 4)
1.1    rjs 	    || dccp_add_option(cb->pcb, TFRC_OPT_RECEIVE_RATE, (char *) &x_recv, 4)) {
1.1    rjs 		TFRC_DEBUG((LOG_INFO, "TFRC - Can't add options, aborting send feedback (tfrc_send_feedback)"));
1.1    rjs 		/* todo: remove options */
1.1    rjs 		dccpstat.tfrcs_recv_erropt++;
1.1    rjs 		return;
1.1    rjs 	}
1.1    rjs 	cb->pcb->ack_snd = elm->seq;
1.1    rjs 	cb->last_counter = elm->win_count;
1.1    rjs 	cb->seq_last_counter = elm->seq;
1.1    rjs 	microtime(&(cb->t_last_feedback));
1.1    rjs 	cb->bytes_recv = 0;
1.1    rjs
1.1    rjs 	TFRC_DEBUG_TIME((LOG_INFO, "TFRC - Sending a feedback packet with (t_elapsed %u, pinv %x, x_recv %u, ack=%llu) (tfrc_recv_send_feedback)\n", ntohs(t_elapsed), ntohl(pinv), ntohl(x_recv), elm->seq));
1.1    rjs
1.1    rjs 	dccpstat.tfrcs_recv_fbacks++;
1.1    rjs 	dccp_output(cb->pcb, 1);
1.1    rjs }
1.1    rjs /*
1.1    rjs  * Calculate first loss interval
1.1    rjs  * args: cb - ccb of the receiver
1.1    rjs  * returns: loss interval
1.1    rjs  * Tested u:OK
1.1    rjs  */
1.1    rjs u_int32_t
1.1    rjs tfrc_recv_calcFirstLI(struct tfrc_recv_ccb * cb)
1.1    rjs {
1.1    rjs 	struct r_hist_entry *elm, *elm2;
1.1    rjs 	struct timeval t_temp;
1.1    rjs 	int temp;
1.1    rjs 	struct fixpoint x_recv, fval, t_rtt, x;
1.1    rjs 	const struct fixpoint *fval2;
1.1    rjs 	int win_count;
1.1    rjs
1.1    rjs 	temp = 1;
1.1    rjs 	TFRC_RECV_FINDDATAPACKET(cb, elm, temp);
1.1    rjs
1.1    rjs 	if (elm == NULL)
1.1    rjs 		panic("Packet history contains no data packets! (tfrc_recv_calcFirstLI)\n");
1.1    rjs 	t_temp = elm->t_recv;
1.1    rjs 	win_count = elm->win_count;
1.1    rjs 	elm2 = elm;
1.1    rjs 	TFRC_RECV_NEXTDATAPACKET(cb, elm2);
1.1    rjs 	while (elm2 != NULL) {
1.1    rjs 		temp = win_count - (int) (elm2->win_count);
1.1    rjs 		if (temp < 0)
1.1    rjs 			temp = temp + TFRC_WIN_COUNT_LIMIT;
1.1    rjs
1.1    rjs 		if (temp > 4)
1.1    rjs 			break;
1.1    rjs 		elm = elm2;
1.1    rjs 		TFRC_RECV_NEXTDATAPACKET(cb, elm2);
1.1    rjs 	}
1.1    rjs
1.1    rjs 	if (elm2 == NULL) {
1.1    rjs 		TFRC_DEBUG((LOG_INFO, "TFRC - Could not find a win_count interval > 4 \n"));
1.1    rjs 		elm2 = elm;
1.1    rjs 		if (temp == 0) {
1.1    rjs 			TFRC_DEBUG((LOG_INFO, "TFRC - Could not find a win_count interval > 0. Defaulting to 1 (tfrc_recv_calcFirstLI)\n"));
1.1    rjs 			temp = 1;
1.1    rjs 		}
1.1    rjs 	}
1.1    rjs 	timersub(&t_temp, &elm2->t_recv, &t_temp);
1.1    rjs 	t_rtt.num = t_temp.tv_sec * 1000000 + t_temp.tv_usec;
1.1    rjs 	t_rtt.denom = 1000000;
1.1    rjs
1.1    rjs 	if (t_rtt.num < 0 && t_rtt.denom < 0) {
1.1    rjs 		TFRC_DEBUG((LOG_INFO, "TFRC - Approximation of RTT is negative!\n"));
1.1    rjs 		t_rtt.num = -t_rtt.num;
1.1    rjs 		t_rtt.denom = -t_rtt.denom;
1.1    rjs 	}
1.1    rjs
1.1    rjs 	TFRC_DEBUG((LOG_INFO, "TFRC - Approximated rtt to "));
1.1    rjs 	PRINTFLOAT(&t_rtt);
1.1    rjs 	TFRC_DEBUG((LOG_INFO, " s (tfrc_recv_calcFirstLI)\n"));
1.1    rjs
1.1    rjs 	/* Calculate x_recv */
1.1    rjs 	microtime(&t_temp);
1.1    rjs 	timersub(&t_temp, &cb->t_last_feedback, &t_temp);
1.1    rjs 	/*
1.1    rjs 		x_recv = (((double) (cb->bytes_recv)) /
1.1    rjs 	    (((double) t_temp.tv_sec) + ((double) t_temp.tv_usec) / 1000000.0));
1.1    rjs 	*/
1.1    rjs 	x_recv.num = cb->bytes_recv * 1000000;
1.1    rjs 	x_recv.denom = t_temp.tv_sec * 1000000 + t_temp.tv_usec;
1.1    rjs
1.1    rjs 	TFRC_DEBUG((LOG_INFO, "TFRC - Receive rate XXX"));
1.1    rjs 	PRINTFLOAT(&x_recv);
1.1    rjs 	TFRC_DEBUG((LOG_INFO, " bytes/s (tfrc_recv_calcFirstLI)\n"));
1.1    rjs
1.1    rjs 	/*	fval = ((double) (cb->s)) / (x_recv * t_rtt); */
1.1    rjs 	fval.num = cb->s;
1.1    rjs 	fval.denom = 1;
1.1    rjs 	fixpoint_div(&fval, &fval, &x_recv);
1.1    rjs 	fixpoint_div(&fval, &fval, &t_rtt);
1.1    rjs
1.1    rjs 	TFRC_DEBUG((LOG_INFO, "TFRC - Fvalue to locate XXX"));
1.1    rjs 	PRINTFLOAT(&fval);
1.1    rjs 	TFRC_DEBUG((LOG_INFO, " (tfrc_recv_calcFirstLI)\n"));
1.1    rjs 	fval2 = tfrc_flookup_reverse(&fval);
1.1    rjs 	TFRC_DEBUG((LOG_INFO, "TFRC - Lookup gives p= XXX"));
1.1    rjs 	PRINTFLOAT(&fval);
1.1    rjs 	TFRC_DEBUG((LOG_INFO, " (tfrc_recv_calcFirstLI)\n"));
1.1    rjs 	if (fval2->num == 0 && fval2->denom == 0)
1.1    rjs 		return (u_int32_t) 0xFFFFFFFF;
1.1    rjs 	x.num = x.denom = 1;
1.1    rjs 	fixpoint_div(&x, &x, fval2);
1.1    rjs 	return (u_int32_t) (fixpoint_getlong(&x));
1.1    rjs }
1.1    rjs /* Add packet to recv history (sorted on seqnum)
1.1    rjs  * Do not add packets that are already lost
1.1    rjs  * args: cb - ccb of receiver
1.1    rjs  *       packet - packet to insert
1.1    rjs  * returns:  1 if the packet was considered lost, 0 otherwise
1.1    rjs  * Tested u:OK
1.1    rjs  */
1.1    rjs int
1.1    rjs tfrc_recv_add_hist(struct tfrc_recv_ccb * cb, struct r_hist_entry * packet)
1.1    rjs {
1.1    rjs 	struct r_hist_entry *elm, *elm2;
1.1    rjs 	u_int8_t num_later = 0, win_count;
1.1    rjs 	u_int32_t seq_num = packet->seq;
1.1    rjs 	int temp;
1.1    rjs
1.1    rjs 	TFRC_DEBUG((LOG_INFO, "TFRC - Adding packet (seq=%llu,win_count=%u,type=%u,ndp=%u) to history! (tfrc_recv_add_hist)\n", packet->seq, packet->win_count, packet->type, packet->ndp));
1.1    rjs
1.1    rjs 	if (TAILQ_EMPTY(&(cb->hist))) {
1.1    rjs 		TAILQ_INSERT_HEAD(&(cb->hist), packet, linfo);
1.1    rjs 	} else {
1.1    rjs 		elm = TAILQ_FIRST(&(cb->hist));
1.1    rjs 		if ((seq_num > elm->seq
1.1    rjs 			&& seq_num - elm->seq < TFRC_RECV_NEW_SEQ_RANGE) ||
1.1    rjs 		    (seq_num < elm->seq
1.1    rjs 			&& elm->seq - seq_num > DCCP_SEQ_NUM_LIMIT - TFRC_RECV_NEW_SEQ_RANGE)) {
1.1    rjs 			TAILQ_INSERT_HEAD(&(cb->hist), packet, linfo);
1.1    rjs 		} else {
1.1    rjs 			if (elm->type == DCCP_TYPE_DATA || elm->type == DCCP_TYPE_DATAACK)
1.1    rjs 				num_later = 1;
1.1    rjs
1.1    rjs 			elm2 = TAILQ_NEXT(elm, linfo);
1.1    rjs 			while (elm2 != NULL) {
1.1    rjs 				if ((seq_num > elm2->seq
1.1    rjs 					&& seq_num - elm2->seq < TFRC_RECV_NEW_SEQ_RANGE) ||
1.1    rjs 				    (seq_num < elm2->seq
1.1    rjs 					&& elm2->seq - seq_num > DCCP_SEQ_NUM_LIMIT - TFRC_RECV_NEW_SEQ_RANGE)) {
1.1    rjs 					TAILQ_INSERT_AFTER(&(cb->hist), elm, packet, linfo);
1.1    rjs 					break;
1.1    rjs 				}
1.1    rjs 				elm = elm2;
1.1    rjs 				elm2 = TAILQ_NEXT(elm, linfo);
1.1    rjs
1.1    rjs 				if (elm->type == DCCP_TYPE_DATA || elm->type == DCCP_TYPE_DATAACK)
1.1    rjs 					num_later++;
1.1    rjs
1.1    rjs 				if (num_later == TFRC_RECV_NUM_LATE_LOSS) {
1.1    rjs 					free(packet, M_TEMP);
1.1    rjs 					TFRC_DEBUG((LOG_INFO, "TFRC - Packet already lost! (tfrc_recv_add_hist)\n"));
1.1    rjs 					return 1;
1.1    rjs 					break;
1.1    rjs 				}
1.1    rjs 			}
1.1    rjs
1.1    rjs 			if (elm2 == NULL && num_later < TFRC_RECV_NUM_LATE_LOSS) {
1.1    rjs 				TAILQ_INSERT_TAIL(&(cb->hist), packet, linfo);
1.1    rjs 			}
1.1    rjs 		}
1.1    rjs 	}
1.1    rjs
1.1    rjs 	/* trim history (remove all packets after the NUM_LATE_LOSS+1 data
1.1    rjs 	 * packets) */
1.1    rjs 	if (TAILQ_FIRST(&(cb->li_hist)) != NULL) {
1.1    rjs 		num_later = TFRC_RECV_NUM_LATE_LOSS + 1;
1.1    rjs 		TFRC_RECV_FINDDATAPACKET(cb, elm, num_later);
1.1    rjs 		if (elm != NULL) {
1.1    rjs 			elm2 = TAILQ_NEXT(elm, linfo);
1.1    rjs 			while (elm2 != NULL) {
1.1    rjs 				TAILQ_REMOVE(&(cb->hist), elm2, linfo);
1.1    rjs 				free(elm2, M_TEMP);
1.1    rjs 				elm2 = TAILQ_NEXT(elm, linfo);
1.1    rjs 			}
1.1    rjs 		}
1.1    rjs 	} else {
1.1    rjs 		/* we have no loss interval history so we need at least one
1.1    rjs 		 * rtt:s of data packets to approximate rtt */
1.1    rjs 		num_later = TFRC_RECV_NUM_LATE_LOSS + 1;
1.1    rjs 		TFRC_RECV_FINDDATAPACKET(cb, elm2, num_later);
1.1    rjs 		if (elm2 != NULL) {
1.1    rjs 			num_later = 1;
1.1    rjs 			TFRC_RECV_FINDDATAPACKET(cb, elm, num_later);
1.1    rjs 			win_count = elm->win_count;
1.1    rjs
1.1    rjs 			elm = elm2;
1.1    rjs 			TFRC_RECV_NEXTDATAPACKET(cb, elm2);
1.1    rjs 			while (elm2 != NULL) {
1.1    rjs 				temp = win_count - (int) (elm2->win_count);
1.1    rjs 				if (temp < 0)
1.1    rjs 					temp = temp + TFRC_WIN_COUNT_LIMIT;
1.1    rjs
1.1    rjs 				if (temp > TFRC_WIN_COUNT_PER_RTT + 1) {
1.1    rjs 					/* we have found a packet older than
1.1    rjs 					 * one rtt remove the rest */
1.1    rjs 					elm = TAILQ_NEXT(elm2, linfo);
1.1    rjs
1.1    rjs 					while (elm != NULL) {
1.1    rjs 						TAILQ_REMOVE(&(cb->hist), elm, linfo);
1.1    rjs 						free(elm, M_TEMP);
1.1    rjs 						elm = TAILQ_NEXT(elm2, linfo);
1.1    rjs 					}
1.1    rjs 					break;
1.1    rjs 				}
1.1    rjs 				elm = elm2;
1.1    rjs 				TFRC_RECV_NEXTDATAPACKET(cb, elm2);
1.1    rjs 			}
1.1    rjs 		}		/* end if (exist atleast 4 data packets) */
1.1    rjs 	}
1.1    rjs
1.1    rjs 	return 0;
1.1    rjs }
1.1    rjs /*
1.1    rjs  * Detect loss events and update loss interval history
1.1    rjs  * args: cb - ccb of the receiver
1.1    rjs  * Tested u:OK
1.1    rjs  */
1.1    rjs void
1.1    rjs tfrc_recv_detectLoss(struct tfrc_recv_ccb * cb)
1.1    rjs {
1.1    rjs 	struct r_hist_entry *bLoss, *aLoss, *elm, *elm2;
1.1    rjs 	u_int8_t num_later = TFRC_RECV_NUM_LATE_LOSS;
1.1    rjs 	long seq_temp = 0;
1.1    rjs 	long seq_loss = -1;
1.1    rjs 	u_int8_t win_loss = 0;
1.1    rjs
1.1    rjs 	TFRC_RECV_FINDDATAPACKET(cb, bLoss, num_later);
1.1    rjs
1.1    rjs 	if (bLoss == NULL) {
1.1    rjs 		/* not enough packets yet to cause the first loss event */
1.1    rjs 	} else {		/* bloss != NULL */
1.1    rjs 		num_later = TFRC_RECV_NUM_LATE_LOSS + 1;
1.1    rjs 		TFRC_RECV_FINDDATAPACKET(cb, aLoss, num_later);
1.1    rjs 		if (aLoss == NULL) {
1.1    rjs 			if (TAILQ_EMPTY(&(cb->li_hist))) {
1.1    rjs 				/* no loss event have occured yet */
1.1    rjs
1.1    rjs 				/* todo: find a lost data packet by comparing
1.1    rjs 				 * to initial seq num */
1.1    rjs
1.1    rjs 			} else {
1.1    rjs 				panic("Less than 4 data packets in history (tfrc_recv_detecLossEvent)\n");
1.1    rjs 			}
1.1    rjs 		} else {	/* aLoss != NULL */
1.1    rjs 			/* locate a lost data packet */
1.1    rjs 			elm = bLoss;
1.1    rjs 			elm2 = TAILQ_NEXT(elm, linfo);
1.1    rjs 			do {
1.1    rjs 				seq_temp = ((long) (elm->seq)) - ((long) elm2->seq);
1.1    rjs
1.1    rjs 				if (seq_temp < 0)
1.1    rjs 					seq_temp = seq_temp + DCCP_SEQ_NUM_LIMIT;
1.1    rjs
1.1    rjs 				if (seq_temp != 1) {
1.1    rjs 					/* check no data packets */
1.1    rjs 					if (elm->type == DCCP_TYPE_DATA || elm->type == DCCP_TYPE_DATAACK)
1.1    rjs 						seq_temp = seq_temp - 1;
1.1    rjs 					if (seq_temp % DCCP_NDP_LIMIT != ((int) elm->ndp - (int) elm2->ndp + DCCP_NDP_LIMIT) % DCCP_NDP_LIMIT)
1.1    rjs 						seq_loss = (elm2->seq + 1) % DCCP_SEQ_NUM_LIMIT;
1.1    rjs 				}
1.1    rjs 				elm = elm2;
1.1    rjs 				elm2 = TAILQ_NEXT(elm2, linfo);
1.1    rjs 			} while (elm != aLoss);
1.1    rjs
1.1    rjs 			if (seq_loss != -1) {
1.1    rjs 				win_loss = aLoss->win_count;
1.1    rjs 			}
1.1    rjs 		}
1.1    rjs 	}			/* end if (bLoss == NULL) */
1.1    rjs 	tfrc_recv_updateLI(cb, seq_loss, win_loss);
1.1    rjs }
1.1    rjs /* Updates the loss interval history
1.1    rjs  * cb   -  congestion control block
1.1    rjs  * seq_loss  -  sequence number of lost packet (-1 for none)
1.1    rjs  * win_loss  -  window counter for previous (from the lost packet view) packet
1.1    rjs  * Tested u:OK
1.1    rjs  */
1.1    rjs void
1.1    rjs tfrc_recv_updateLI(struct tfrc_recv_ccb * cb, long seq_loss, u_int8_t win_loss)
1.1    rjs {
1.1    rjs 	struct r_hist_entry *elm;
1.1    rjs 	struct li_hist_entry *li_elm, *li_elm2;
1.1    rjs 	u_int8_t num_later = TFRC_RECV_NUM_LATE_LOSS;
1.1    rjs 	long seq_temp = 0;
1.1    rjs 	int i;
1.1    rjs 	u_int8_t win_start;
1.1    rjs 	int debug_info = 0;
1.1    rjs 	if (seq_loss != -1) {	/* we have found a packet loss! */
1.1    rjs 		dccpstat.tfrcs_recv_losts++;
1.1    rjs 		TFRC_DEBUG((LOG_INFO, "TFRC - seqloss=%i, winloss=%i\n", (int) seq_loss, (int) win_loss));
1.1    rjs 		if (TAILQ_EMPTY(&(cb->li_hist))) {
1.1    rjs 			debug_info = 1;
1.1    rjs 			/* first loss detected */
1.1    rjs 			TFRC_DEBUG((LOG_INFO, "TFRC - First loss event detected! (tfrc_recv_updateLI)\n"));
1.1    rjs 			/* create history */
1.1    rjs 			for (i = 0; i < TFRC_RECV_IVAL_F_LENGTH + 1; i++) {
1.1    rjs 				li_elm = malloc(sizeof(struct li_hist_entry),
1.1    rjs 				    M_TEMP, M_NOWAIT | M_ZERO);	/* M_TEMP?? */
1.1    rjs 				if (li_elm == NULL) {
1.1    rjs 					TFRC_DEBUG((LOG_INFO, "TFRC - Not enough memory for loss interval history!\n"));
1.1    rjs 					/* Empty loss interval history */
1.1    rjs 					li_elm = TAILQ_FIRST(&(cb->li_hist));
1.1    rjs 					while (li_elm != NULL) {
1.1    rjs 						li_elm2 = TAILQ_NEXT(li_elm, linfo);
1.1    rjs 						free(li_elm, M_TEMP);	/* M_TEMP ?? */
1.1    rjs 						li_elm = li_elm2;
1.1    rjs 					}
1.1    rjs 					return;
1.1    rjs 				}
1.1    rjs 				TAILQ_INSERT_HEAD(&(cb->li_hist), li_elm, linfo);
1.1    rjs 			}
1.1    rjs
1.1    rjs 			li_elm->seq = seq_loss;
1.1    rjs 			li_elm->win_count = win_loss;
1.1    rjs
1.1    rjs 			li_elm = TAILQ_NEXT(li_elm, linfo);
1.1    rjs 			/* add approx interval */
1.1    rjs 			li_elm->interval = tfrc_recv_calcFirstLI(cb);
1.1    rjs
1.1    rjs 		} else {	/* we have a loss interval history */
1.1    rjs 			debug_info = 2;
1.1    rjs 			/* Check if the loss is in the same loss event as
1.1    rjs 			 * interval start */
1.1    rjs 			win_start = (TAILQ_FIRST(&(cb->li_hist)))->win_count;
1.1    rjs 			if ((win_loss > win_start
1.1    rjs 				&& win_loss - win_start > TFRC_WIN_COUNT_PER_RTT) ||
1.1    rjs 			    (win_loss < win_start
1.1    rjs 				&& win_start - win_loss < TFRC_WIN_COUNT_LIMIT - TFRC_WIN_COUNT_PER_RTT)) {
1.1    rjs 				/* new loss event detected */
1.1    rjs 				/* calculate last interval length */
1.1    rjs 				seq_temp = seq_loss - ((long) ((TAILQ_FIRST(&(cb->li_hist)))->seq));
1.1    rjs 				if (seq_temp < 0)
1.1    rjs 					seq_temp = seq_temp + DCCP_SEQ_NUM_LIMIT;
1.1    rjs
1.1    rjs 				(TAILQ_FIRST(&(cb->li_hist)))->interval = seq_temp;
1.1    rjs
1.1    rjs 				TFRC_DEBUG((LOG_INFO, "TFRC - New loss event detected!, interval %i (tfrc_recv_updateLI)\n", (int) seq_temp));
1.1    rjs 				/* Remove oldest interval */
1.1    rjs 				li_elm = TAILQ_LAST(&(cb->li_hist), li_hist_head);
1.1    rjs 				TAILQ_REMOVE(&(cb->li_hist), li_elm, linfo);
1.1    rjs
1.1    rjs 				/* Create the newest interval */
1.1    rjs 				li_elm->seq = seq_loss;
1.1    rjs 				li_elm->win_count = win_loss;
1.1    rjs
1.1    rjs 				/* insert it into history */
1.1    rjs 				TAILQ_INSERT_HEAD(&(cb->li_hist), li_elm, linfo);
1.1    rjs 			} else
1.1    rjs 				TFRC_DEBUG((LOG_INFO, "TFRC - Loss belongs to previous loss event (tfrc_recv_updateLI)!\n"));
1.1    rjs 		}
1.1    rjs 	}
1.1    rjs 	if (TAILQ_FIRST(&(cb->li_hist)) != NULL) {
1.1    rjs 		/* calculate interval to last loss event */
1.1    rjs 		num_later = 1;
1.1    rjs 		TFRC_RECV_FINDDATAPACKET(cb, elm, num_later);
1.1    rjs
1.1    rjs 		seq_temp = ((long) (elm->seq)) -
1.1    rjs 		    ((long) ((TAILQ_FIRST(&(cb->li_hist)))->seq));
1.1    rjs 		if (seq_temp < 0)
1.1    rjs 			seq_temp = seq_temp + DCCP_SEQ_NUM_LIMIT;
1.1    rjs
1.1    rjs 		(TAILQ_FIRST(&(cb->li_hist)))->interval = seq_temp;
1.1    rjs 		if (debug_info > 0) {
1.1    rjs 			TFRC_DEBUG((LOG_INFO, "TFRC - Highest data packet received %llu (tfrc_recv_updateLI)\n", elm->seq));
1.1    rjs 		}
1.1    rjs 	}
1.1    rjs }
1.1    rjs
1.1    rjs
1.1    rjs /* Functions declared in struct dccp_cc_sw */
1.1    rjs /* Initialises the receiver side
1.1    rjs  * returns: pointer to a tfrc_recv_ccb struct on success, otherwise 0
1.1    rjs  * Tested u:OK
1.1    rjs  */
1.1    rjs void *
1.1    rjs tfrc_recv_init(struct dccpcb * pcb)
1.1    rjs {
1.1    rjs 	struct tfrc_recv_ccb *ccb;
1.1    rjs
1.1    rjs 	ccb = malloc(sizeof(struct tfrc_recv_ccb), M_PCB, M_NOWAIT | M_ZERO);
1.1    rjs 	if (ccb == 0) {
1.1    rjs 		TFRC_DEBUG((LOG_INFO, "TFRC - Unable to allocate memory for tfrc_recv_ccb!\n"));
1.1    rjs 		return 0;
1.1    rjs 	}
1.1    rjs 	/* init recv here */
1.1    rjs
1.1    rjs 	mutex_init(&(ccb->mutex), MUTEX_DEFAULT, IPL_SOFTNET);
1.1    rjs
1.1    rjs 	ccb->pcb = pcb;
1.1    rjs
1.1    rjs 	if (ccb->pcb->avgpsize >= TFRC_MIN_PACKET_SIZE && ccb->pcb->avgpsize <= TFRC_MAX_PACKET_SIZE)
1.1    rjs 		ccb->s = (u_int16_t) ccb->pcb->avgpsize;
1.1    rjs 	else
1.1    rjs 		ccb->s = TFRC_STD_PACKET_SIZE;
1.1    rjs
1.1    rjs 	TFRC_DEBUG((LOG_INFO, "TFRC - Receiver is using packet size %u\n", ccb->s));
1.1    rjs
1.1    rjs 	/* init packet history */
1.1    rjs 	TAILQ_INIT(&(ccb->hist));
1.1    rjs
1.1    rjs 	/* init loss interval history */
1.1    rjs 	TAILQ_INIT(&(ccb->li_hist));
1.1    rjs
1.1    rjs 	ccb->state = TFRC_RSTATE_NO_DATA;
1.1    rjs 	TFRC_DEBUG((LOG_INFO, "TFRC receiver initialised!\n"));
1.1    rjs 	dccpstat.tfrcs_recv_conn++;
1.1    rjs 	return ccb;
1.1    rjs }
1.1    rjs /* Free the receiver side
1.1    rjs  * args: ccb - ccb of recevier
1.1    rjs  * Tested u:OK
1.1    rjs  */
1.1    rjs void
1.1    rjs tfrc_recv_free(void *ccb)
1.1    rjs {
1.1    rjs 	struct r_hist_entry *elm, *elm2;
1.1    rjs 	struct li_hist_entry *li_elm, *li_elm2;
1.1    rjs 	struct tfrc_recv_ccb *cb = (struct tfrc_recv_ccb *) ccb;
1.1    rjs
1.1    rjs 	if (ccb == 0)
1.1    rjs 		panic("TFRC - Receiver ccb is null! (free)");
1.1    rjs
1.1    rjs 	/* uninit recv here */
1.1    rjs
1.1    rjs 	cb->state = TFRC_RSTATE_TERM;
1.1    rjs 	/* get mutex */
1.1    rjs 	mutex_enter(&(cb->mutex));
1.1    rjs
1.1    rjs 	/* Empty packet history */
1.1    rjs 	elm = TAILQ_FIRST(&(cb->hist));
1.1    rjs 	while (elm != NULL) {
1.1    rjs 		elm2 = TAILQ_NEXT(elm, linfo);
1.1    rjs 		free(elm, M_TEMP);	/* M_TEMP ?? */
1.1    rjs 		elm = elm2;
1.1    rjs 	}
1.1    rjs 	TAILQ_INIT(&(cb->hist));
1.1    rjs
1.1    rjs 	/* Empty loss interval history */
1.1    rjs 	li_elm = TAILQ_FIRST(&(cb->li_hist));
1.1    rjs 	while (li_elm != NULL) {
1.1    rjs 		li_elm2 = TAILQ_NEXT(li_elm, linfo);
1.1    rjs 		free(li_elm, M_TEMP);	/* M_TEMP ?? */
1.1    rjs 		li_elm = li_elm2;
1.1    rjs 	}
1.1    rjs 	TAILQ_INIT(&(cb->li_hist));
1.1    rjs
1.1    rjs 	mutex_exit(&(cb->mutex));
1.1    rjs 	mutex_destroy(&(cb->mutex));
1.1    rjs
1.1    rjs 	free(ccb, M_PCB);
1.1    rjs
1.1    rjs 	TFRC_DEBUG((LOG_INFO, "TFRC receiver is destroyed\n"));
1.1    rjs }
1.1    rjs
1.1    rjs
1.1    rjs /*
1.1    rjs  * Tell TFRC that a packet has been received
1.1    rjs  * args: ccb  -  ccb block for current connection
1.1    rjs  */
1.1    rjs void
1.1    rjs tfrc_recv_packet_recv(void *ccb, char *options, int optlen)
1.1    rjs {
1.1    rjs 	struct r_hist_entry *packet;
1.1    rjs 	u_int8_t win_count = 0;
1.1    rjs 	struct fixpoint p_prev;
1.1    rjs 	int ins = 0;
1.1    rjs 	struct tfrc_recv_ccb *cb = (struct tfrc_recv_ccb *) ccb;
1.1    rjs
1.1    rjs #ifdef NOTFRCRECV
1.1    rjs 	return;
1.1    rjs #endif
1.1    rjs
1.1    rjs 	if (!(cb->state == TFRC_RSTATE_NO_DATA || cb->state == TFRC_RSTATE_DATA)) {
1.1    rjs 		panic("TFRC - Illegal state! (tfrc_recv_packet_recv)\n");
1.1    rjs 		return;
1.1    rjs 	}
1.1    rjs 	/* Check which type */
1.1    rjs 	switch (cb->pcb->type_rcv) {
1.1    rjs 	case DCCP_TYPE_ACK:
1.1    rjs 		if (cb->state == TFRC_RSTATE_NO_DATA)
1.1    rjs 			return;
1.1    rjs 		break;
1.1    rjs 	case DCCP_TYPE_DATA:
1.1    rjs 	case DCCP_TYPE_DATAACK:
1.1    rjs 		break;
1.1    rjs 	default:
1.1    rjs 		TFRC_DEBUG((LOG_INFO, "TFRC - Received not data/dataack/ack packet! (tfrc_recv_packet_recv)"));
1.1    rjs 		return;
1.1    rjs 	}
1.1    rjs
1.1    rjs 	mutex_enter(&(cb->mutex));
1.1    rjs
1.1    rjs 	/* Add packet to history */
1.1    rjs
1.1    rjs 	packet = malloc(sizeof(struct r_hist_entry), M_TEMP, M_NOWAIT);	/* M_TEMP?? */
1.1    rjs 	if (packet == NULL) {
1.1    rjs 		TFRC_DEBUG((LOG_INFO, "TFRC - Not enough memory to add received packet to history (consider it lost)! (tfrc_recv_packet_recv)"));
1.1    rjs 		dccpstat.tfrcs_recv_nomem++;
1.1    rjs 		goto rp_release;
1.1    rjs 	}
1.1    rjs 	microtime(&(packet->t_recv));
1.1    rjs 	packet->seq = cb->pcb->seq_rcv;
1.1    rjs 	packet->type = cb->pcb->type_rcv;
1.1    rjs 	packet->ndp = cb->pcb->ndp_rcv;
1.1    rjs
1.1    rjs 	/* get window counter */
1.1    rjs 	win_count = cb->pcb->ccval;
1.1    rjs 	packet->win_count = win_count;
1.1    rjs
1.1    rjs 	ins = tfrc_recv_add_hist(cb, packet);
1.1    rjs
1.1    rjs 	/* check if we got a data packet */
1.1    rjs 	if (cb->pcb->type_rcv != DCCP_TYPE_ACK) {
1.1    rjs
1.1    rjs 		switch (cb->state) {
1.1    rjs 		case TFRC_RSTATE_NO_DATA:
1.1    rjs 			TFRC_DEBUG((LOG_INFO, "TFRC - Send an inital feedback packet (tfrc_recv_packet_recv)\n"));
1.1    rjs 			tfrc_recv_send_feedback(cb);
1.1    rjs 			cb->state = TFRC_RSTATE_DATA;
1.1    rjs 			break;
1.1    rjs 		case TFRC_RSTATE_DATA:
1.1    rjs 			cb->bytes_recv = cb->bytes_recv + cb->pcb->len_rcv;
1.1    rjs 			if (!ins) {
1.1    rjs 				/* find loss event */
1.1    rjs 				tfrc_recv_detectLoss(cb);
1.1    rjs 				p_prev.num = cb->p.num;
1.1    rjs 				p_prev.denom = cb->p.denom;
1.1    rjs
1.1    rjs 				/* Calculate loss event rate */
1.1    rjs 				if (!TAILQ_EMPTY(&(cb->li_hist))) {
1.1    rjs 					cb->p.num = 1;
1.1    rjs 					cb->p.denom = tfrc_calclmean(cb);
1.1    rjs 				}
1.1    rjs 				/* check send conditions then send */
1.1    rjs
1.1    rjs 				if (fixpoint_cmp(&(cb)->p, &p_prev) > 0) {
1.1    rjs 					TFRC_DEBUG((LOG_INFO, "TFRC - Send a feedback packet because p>p_prev (tfrc_recv_packet_recv)\n"));
1.1    rjs 					tfrc_recv_send_feedback(cb);
1.1    rjs 				} else {
1.1    rjs 					if ((cb->pcb->seq_rcv > cb->seq_last_counter
1.1    rjs 						&& cb->pcb->seq_rcv - cb->seq_last_counter < TFRC_RECV_NEW_SEQ_RANGE) ||
1.1    rjs 					    (cb->pcb->seq_rcv < cb->seq_last_counter
1.1    rjs 						&& cb->seq_last_counter - cb->pcb->seq_rcv > DCCP_SEQ_NUM_LIMIT - TFRC_RECV_NEW_SEQ_RANGE)) {
1.1    rjs
1.1    rjs 						/* the sequence number is
1.1    rjs 						 * newer than seq_last_count */
1.1    rjs 						if ((win_count > cb->last_counter
1.1    rjs 							&& win_count - cb->last_counter > TFRC_WIN_COUNT_PER_RTT) ||
1.1    rjs 						    (win_count < cb->last_counter
1.1    rjs 							&& cb->last_counter - win_count < TFRC_WIN_COUNT_LIMIT - TFRC_WIN_COUNT_PER_RTT)) {
1.1    rjs
1.1    rjs 							TFRC_DEBUG((LOG_INFO, "TFRC - Send a feedback packet (%i)(win_count larger) (tfrc_recv_packet_recv)\n", (win_count - cb->last_counter + TFRC_WIN_COUNT_LIMIT) % TFRC_WIN_COUNT_LIMIT));
1.1    rjs
1.1    rjs 							tfrc_recv_send_feedback(cb);
1.1    rjs 						}
1.1    rjs 					}	/* end newer seqnum */
1.1    rjs 				}	/* end p > p_prev */
1.1    rjs
1.1    rjs 			}
1.1    rjs 			break;
1.1    rjs 		default:
1.1    rjs 			panic("tfrc_recv_packet_recv: Illegal state!");
1.1    rjs 			break;
1.1    rjs 		}
1.1    rjs
1.1    rjs 	}			/* end if not pure ack */
1.1    rjs rp_release:
1.1    rjs 	mutex_exit(&(cb->mutex));
1.1    rjs }
1.1    rjs
1.1    rjs
1.1    rjs /*
1.1    rjs  * fixpoint routines
1.1    rjs  */
1.1    rjs static void
1.1    rjs normalize(long long *num, long long *denom)
1.1    rjs {
1.1    rjs 	static const int prime[] = { 2, 3, 5, 7, 11, 13, 17, 19, 0 };
1.1    rjs 	int i;
1.1    rjs
1.1    rjs 	if (!*denom) return;
1.1    rjs 	if (*denom < 0) {
1.1    rjs 		*num *= (-1);
1.1    rjs 		*denom *= (-1);
1.1    rjs 	}
1.1    rjs
1.1    rjs 	if (*num % *denom == 0) {
1.1    rjs 		*num /= *denom;
1.1    rjs 		*denom = 1;
1.1    rjs 	}
1.1    rjs 	for (i = 0; prime[i]; i++)
1.1    rjs 		while (*num % prime[i] == 0 && *denom % prime[i] == 0) {
1.1    rjs 			*num /= prime[i];
1.1    rjs 			*denom /= prime[i];
1.1    rjs 		}
1.1    rjs }
1.1    rjs
1.1    rjs struct fixpoint *
1.1    rjs fixpoint_add(struct fixpoint *x, const struct fixpoint *a,
1.1    rjs 	     const struct fixpoint *b)
1.1    rjs {
1.1    rjs 	long long num, denom;
1.1    rjs
1.1    rjs 	num = a->num * b->denom + a->denom * b->num;
1.1    rjs 	denom = a->denom * b->denom;
1.1    rjs 	normalize(&num, &denom);
1.1    rjs
1.1    rjs 	x->num = num;
1.1    rjs 	x->denom = denom;
1.1    rjs 	return (x);
1.1    rjs }
1.1    rjs
1.1    rjs struct fixpoint *
1.1    rjs fixpoint_sub(struct fixpoint *x, const struct fixpoint *a,
1.1    rjs 	     const struct fixpoint *b)
1.1    rjs {
1.1    rjs 	long long num, denom;
1.1    rjs
1.1    rjs 	if (!a->denom) {
1.1    rjs 		x->num = -1 * b->num;
1.1    rjs 		x->denom = -1 * b->denom;
1.1    rjs 		return (x);
1.1    rjs 	}
1.1    rjs 	if (!b->denom) {
1.1    rjs 		x->num = a->num;
1.1    rjs 		x->denom = a->denom;
1.1    rjs 		return (x);
1.1    rjs 	}
1.1    rjs 	num = a->num * b->denom - a->denom * b->num;
1.1    rjs 	denom = a->denom * b->denom;
1.1    rjs 	normalize(&num, &denom);
1.1    rjs
1.1    rjs 	x->num = num;
1.1    rjs 	x->denom = denom;
1.1    rjs 	return (x);
1.1    rjs }
1.1    rjs
1.1    rjs int
1.1    rjs fixpoint_cmp(const struct fixpoint *a, const struct fixpoint *b)
1.1    rjs {
1.1    rjs 	struct fixpoint x;
1.1    rjs
1.1    rjs 	fixpoint_sub(&x, a, b);
1.1    rjs 	if (x.num > 0)
1.1    rjs 		return (1);
1.1    rjs 	else if (x.num < 0)
1.1    rjs 		return (-1);
1.1    rjs 	else
1.1    rjs 		return (0);
1.1    rjs }
1.1    rjs
1.1    rjs struct fixpoint *
1.1    rjs fixpoint_mul(struct fixpoint *x, const struct fixpoint *a,
1.1    rjs 	     const struct fixpoint *b)
1.1    rjs {
1.1    rjs 	long long num, denom;
1.1    rjs
1.1    rjs 	num = a->num * b->num;
1.1    rjs 	denom = a->denom * b->denom;
1.1    rjs 	normalize(&num, &denom);
1.1    rjs
1.1    rjs 	x->num = num;
1.1    rjs 	x->denom = denom;
1.1    rjs 	return (x);
1.1    rjs }
1.1    rjs
1.1    rjs struct fixpoint *
1.1    rjs fixpoint_div(struct fixpoint *x, const struct fixpoint *a,
1.1    rjs 	     const struct fixpoint *b)
1.1    rjs {
1.1    rjs 	long long num, denom;
1.1    rjs
1.1    rjs 	num = a->num * b->denom;
1.1    rjs 	denom = a->denom * b->num;
1.1    rjs 	normalize(&num, &denom);
1.1    rjs
1.1    rjs 	x->num = num;
1.1    rjs 	x->denom = denom;
1.1    rjs 	return (x);
1.1    rjs }
1.1    rjs
1.1    rjs long
1.1    rjs fixpoint_getlong(const struct fixpoint *x)
1.1    rjs {
1.1    rjs
1.1    rjs 	if (x->denom == 0)
1.1    rjs 		return (0);
1.1    rjs 	return (x->num / x->denom);
1.1    rjs }
1.1    rjs
1.1    rjs const struct fixpoint flargex = { 2LL, 1000LL };
1.1    rjs const struct fixpoint fsmallx = { 1LL, 100000LL };
1.1    rjs const struct fixpoint fsmallstep = { 4LL, 1000000LL };
1.1    rjs
1.1    rjs /*
1.1    rjs  * FLOOKUP macro. NOTE! 0<=(int x)<=1
1.1    rjs  * Tested u:OK
1.1    rjs  */
1.1    rjs const struct fixpoint *
1.1    rjs flookup(const struct fixpoint *x)
1.1    rjs {
1.1    rjs 	static const struct fixpoint y = { 250000, 1 };
1.1    rjs 	struct fixpoint z;
1.1    rjs 	int i;
1.1    rjs
1.1    rjs 	if (fixpoint_cmp(x, &flargex) >= 0) {
1.1    rjs 		if (x->num == 0)
1.1    rjs 			return NULL;
1.1    rjs 		i = x->denom / x->num;
1.1    rjs #ifdef TFRCDEBUG
1.1    rjs 		if (i >= sizeof(flarge_table) / sizeof(flarge_table[0]))
1.1    rjs 			panic("flarge_table lookup failed");
1.1    rjs #endif
1.1    rjs
1.1    rjs 		return &flarge_table[i];
1.1    rjs 	} else {
1.1    rjs 		fixpoint_mul(&z, x, &y);
1.1    rjs 		if (z.num == 0)
1.1    rjs 			return NULL;
1.1    rjs 		i = fixpoint_getlong(&z);
1.1    rjs #ifdef TFRCDEBUG
1.1    rjs 		if (i >= sizeof(fsmall_table) / sizeof(fsmall_table[0]))
1.1    rjs 			panic("fsmall_table lookup failed");
1.1    rjs #endif
1.1    rjs
1.1    rjs 		return &fsmall_table[i];
1.1    rjs 	}
1.1    rjs }
1.1    rjs
1.1    rjs /*
1.1    rjs  * Inverse of the FLOOKUP above
1.1    rjs  * args: fvalue - function value to match
1.1    rjs  * returns:  p  closest to that value
1.1    rjs  * Tested u:OK
1.1    rjs  */
1.1    rjs const struct fixpoint *
1.1    rjs tfrc_flookup_reverse(const struct fixpoint *fvalue)
1.1    rjs {
1.1    rjs 	static struct fixpoint x;
1.1    rjs 	int ctr;
1.1    rjs
1.1    rjs 	if (fixpoint_cmp(fvalue, &flarge_table[1]) >= 0) {
1.1    rjs 		/* 1.0 */
1.1    rjs 		x.num = 1;
1.1    rjs 		x.denom = 1;
1.1    rjs 		return &x;
1.1    rjs 	} else if (fixpoint_cmp(fvalue, &flarge_table[sizeof(flarge_table) /
1.1    rjs 	    sizeof(flarge_table[0]) - 1]) >= 0) {
1.1    rjs 		ctr = sizeof(flarge_table) / sizeof(flarge_table[0]) - 1;
1.1    rjs 		while (ctr > 1 && fixpoint_cmp(fvalue, &flarge_table[ctr]) >= 0)
1.1    rjs 			ctr--;
1.1    rjs
1.1    rjs 		/* round to smallest */
1.1    rjs 		ctr = ctr + 1;
1.1    rjs
1.1    rjs 		/* round to nearest */
1.1    rjs 		return &flarge_table[ctr];
1.1    rjs 	} else if (fixpoint_cmp(fvalue, &fsmall_table[0]) >= 0) {
1.1    rjs 		ctr = 0;
1.1    rjs 		while (ctr < sizeof(fsmall_table) / sizeof(fsmall_table[0]) &&
1.1    rjs 		    fixpoint_cmp(fvalue, &fsmall_table[ctr]) > 0)
1.1    rjs 			ctr++;
1.1    rjs 		x = fsmallstep;
1.1    rjs 		x.num *= ctr;
1.1    rjs 		return &x;
1.1    rjs 	}
1.1    rjs 	return &fsmallstep;
1.1    rjs }