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/*
* Ouroboros - Copyright (C) 2016 - 2020
*
* Flow and Retransmission Control
*
* Dimitri Staessens <dimitri.staessens@ugent.be>
* Sander Vrijders <sander.vrijders@ugent.be>
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public License
* version 2.1 as published by the Free Software Foundation.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., http://www.fsf.org/about/contact/.
*/
#define FRCT_PCILEN (sizeof(struct frct_pci))
struct frct_cr {
uint32_t lwe; /* Left window edge */
uint32_t rwe; /* Right window edge */
uint8_t cflags;
uint32_t seqno; /* SEQ to send, or last SEQ Ack'd */
struct timespec act; /* Last seen activity */
time_t inact; /* Inactivity (s) */
};
struct frcti {
int fd;
time_t mpl;
time_t a;
time_t r;
time_t srtt; /* Smoothed rtt */
time_t mdev; /* Deviation */
time_t rto; /* Retransmission timeout */
uint32_t rttseq;
struct timespec t_probe; /* Probe time */
bool probe; /* Probe active */
struct frct_cr snd_cr;
struct frct_cr rcv_cr;
ssize_t rq[RQ_SIZE];
pthread_rwlock_t lock;
};
enum frct_flags {
FRCT_DATA = 0x01, /* PDU carries data */
FRCT_DRF = 0x02, /* Data run flag */
FRCT_ACK = 0x04, /* ACK field valid */
FRCT_FC = 0x08, /* FC window valid */
FRCT_RDVS = 0x10, /* Rendez-vous */
FRCT_FFGM = 0x20, /* First Fragment */
FRCT_MFGM = 0x40, /* More fragments */
};
struct frct_pci {
uint8_t flags;
uint8_t pad;
uint16_t window;
uint32_t seqno;
uint32_t ackno;
} __attribute__((packed));
static bool before(uint32_t seq1,
uint32_t seq2)
{
return (int32_t)(seq1 - seq2) < 0;
}
static bool after(uint32_t seq1,
uint32_t seq2)
{
return (int32_t)(seq2 - seq1) < 0;
}
static int __send_ack(int fd,
int ackno)
{
struct shm_du_buff * sdb;
struct frct_pci * pci;
ssize_t idx;
struct flow * f;
/* Raw calls needed to bypass frcti. */
#ifdef RXM_BLOCKING
idx = shm_rdrbuff_alloc_b(ai.rdrb, sizeof(*pci), NULL, &sdb, NULL);
#else
idx = shm_rdrbuff_alloc(ai.rdrb, sizeof(*pci), NULL, &sdb);
#endif
if (idx < 0)
return -ENOMEM;
pci = (struct frct_pci *) shm_du_buff_head(sdb);
memset(pci, 0, sizeof(*pci));
pci->flags = FRCT_ACK;
pci->ackno = hton32(ackno);
f = &ai.flows[fd];
#ifdef RXM_BLOCKING
if (shm_rbuff_write_b(f->tx_rb, idx, NULL)) {
#else
if (shm_rbuff_write(f->tx_rb, idx)) {
#endif
ipcp_sdb_release(sdb);
return -ENOMEM;
}
shm_flow_set_notify(f->set, f->flow_id, FLOW_PKT);
return 0;
}
static void frct_send_ack(struct frcti * frcti)
{
struct timespec now;
time_t diff;
uint32_t ackno;
int fd;
assert(frcti);
pthread_rwlock_rdlock(&frcti->lock);
if (frcti->rcv_cr.lwe == frcti->rcv_cr.seqno) {
pthread_rwlock_unlock(&frcti->lock);
return;
}
ackno = frcti->rcv_cr.lwe;
fd = frcti->fd;
clock_gettime(PTHREAD_COND_CLOCK, &now);
diff = ts_diff_ns(&frcti->rcv_cr.act, &now);
pthread_rwlock_unlock(&frcti->lock);
if (diff > frcti->a || diff < DELT_ACK)
return;
if (__send_ack(fd, ackno) < 0)
return;
pthread_rwlock_wrlock(&frcti->lock);
if (after(frcti->rcv_cr.lwe, frcti->rcv_cr.seqno))
frcti->rcv_cr.seqno = frcti->rcv_cr.lwe;
pthread_rwlock_unlock(&frcti->lock);
}
static struct frcti * frcti_create(int fd)
{
struct frcti * frcti;
ssize_t idx;
struct timespec now;
time_t mpl;
time_t a;
time_t r;
frcti = malloc(sizeof(*frcti));
if (frcti == NULL)
goto fail_malloc;
memset(frcti, 0, sizeof(*frcti));
if (pthread_rwlock_init(&frcti->lock, NULL))
goto fail_lock;
for (idx = 0; idx < RQ_SIZE; ++idx)
frcti->rq[idx] = -1;
clock_gettime(PTHREAD_COND_CLOCK, &now);
frcti->mpl = mpl = DELT_MPL;
frcti->a = a = DELT_A;
frcti->r = r = DELT_R;
frcti->fd = fd;
frcti->rttseq = 0;
frcti->probe = false;
frcti->srtt = 0; /* Updated on first ACK */
frcti->mdev = 10 * MILLION; /* Initial rxm will be after 20 ms */
frcti->rto = 20 * MILLION; /* Initial rxm will be after 20 ms */
if (ai.flows[fd].qs.loss == 0) {
frcti->snd_cr.cflags |= FRCTFRTX | FRCTFLINGER;
frcti->rcv_cr.cflags |= FRCTFRTX;
}
frcti->snd_cr.inact = (3 * mpl + a + r) / BILLION + 1; /* s */
frcti->snd_cr.act.tv_sec = now.tv_sec - (frcti->snd_cr.inact + 1);
frcti->rcv_cr.inact = (2 * mpl + a + r) / BILLION + 1; /* s */
frcti->rcv_cr.act.tv_sec = now.tv_sec - (frcti->rcv_cr.inact + 1);
return frcti;
fail_lock:
free(frcti);
fail_malloc:
return NULL;
}
static void frcti_destroy(struct frcti * frcti)
{
pthread_rwlock_destroy(&frcti->lock);
free(frcti);
}
static uint16_t frcti_getflags(struct frcti * frcti)
{
uint16_t ret;
assert(frcti);
pthread_rwlock_rdlock(&frcti->lock);
ret = frcti->snd_cr.cflags;
pthread_rwlock_unlock(&frcti->lock);
return ret;
}
static void frcti_setflags(struct frcti * frcti,
uint16_t flags)
{
flags |= FRCTFRESCNTRL | FRCTFRTX; /* Should not be set by command */
assert(frcti);
pthread_rwlock_wrlock(&frcti->lock);
frcti->snd_cr.cflags &= FRCTFRESCNTRL | FRCTFRTX; /* Zero other flags */
frcti->snd_cr.cflags &= flags;
pthread_rwlock_unlock(&frcti->lock);
}
#define frcti_queued_pdu(frcti) \
(frcti == NULL ? idx : __frcti_queued_pdu(frcti))
#define frcti_snd(frcti, sdb) \
(frcti == NULL ? 0 : __frcti_snd(frcti, sdb))
#define frcti_rcv(frcti, sdb) \
(frcti == NULL ? 0 : __frcti_rcv(frcti, sdb))
#define frcti_tick(frcti) \
(frcti == NULL ? 0 : __frcti_tick())
#define frcti_dealloc(frcti) \
(frcti == NULL ? 0 : __frcti_dealloc(frcti))
static ssize_t __frcti_queued_pdu(struct frcti * frcti)
{
ssize_t idx;
size_t pos;
assert(frcti);
/* See if we already have the next PDU. */
pthread_rwlock_wrlock(&frcti->lock);
pos = frcti->rcv_cr.lwe & (RQ_SIZE - 1);
idx = frcti->rq[pos];
if (idx != -1) {
++frcti->rcv_cr.lwe;
frcti->rq[pos] = -1;
}
pthread_rwlock_unlock(&frcti->lock);
return idx;
}
static ssize_t __frcti_pdu_ready(struct frcti * frcti)
{
ssize_t idx;
size_t pos;
assert(frcti);
/* See if we already have the next PDU. */
pthread_rwlock_rdlock(&frcti->lock);
pos = frcti->rcv_cr.lwe & (RQ_SIZE - 1);
idx = frcti->rq[pos];
pthread_rwlock_unlock(&frcti->lock);
return idx;
}
#include <timerwheel.c>
/*
* Send a final ACK for everything that has not been ACK'd.
* If the flow should be kept active for retransmission,
* the returned time will be negative.
*/
static time_t __frcti_dealloc(struct frcti * frcti)
{
struct timespec now;
time_t wait;
int ackno;
int fd = -1;
clock_gettime(PTHREAD_COND_CLOCK, &now);
pthread_rwlock_rdlock(&frcti->lock);
ackno = frcti->rcv_cr.lwe;
if (frcti->rcv_cr.lwe != frcti->rcv_cr.seqno)
fd = frcti->fd;
wait = MAX(frcti->rcv_cr.inact - now.tv_sec + frcti->rcv_cr.act.tv_sec,
frcti->snd_cr.inact - now.tv_sec + frcti->snd_cr.act.tv_sec);
if (frcti->snd_cr.cflags & FRCTFLINGER
&& before(frcti->snd_cr.lwe, frcti->snd_cr.seqno))
wait = -wait;
pthread_rwlock_unlock(&frcti->lock);
if (fd != -1)
__send_ack(fd, ackno);
return wait;
}
static int __frcti_snd(struct frcti * frcti,
struct shm_du_buff * sdb)
{
struct frct_pci * pci;
struct timespec now;
struct frct_cr * snd_cr;
struct frct_cr * rcv_cr;
uint32_t seqno;
bool rtx;
assert(frcti);
snd_cr = &frcti->snd_cr;
rcv_cr = &frcti->rcv_cr;
timerwheel_move();
pci = (struct frct_pci *) shm_du_buff_head_alloc(sdb, FRCT_PCILEN);
if (pci == NULL)
return -1;
memset(pci, 0, sizeof(*pci));
clock_gettime(PTHREAD_COND_CLOCK, &now);
pthread_rwlock_wrlock(&frcti->lock);
rtx = snd_cr->cflags & FRCTFRTX;
pci->flags |= FRCT_DATA;
/* Set DRF if there are no unacknowledged packets. */
if (snd_cr->seqno == snd_cr->lwe)
pci->flags |= FRCT_DRF;
/* Choose a new sequence number if sender inactivity expired. */
if (now.tv_sec - snd_cr->act.tv_sec > snd_cr->inact) {
/* There are no unacknowledged packets. */
assert(snd_cr->seqno == snd_cr->lwe);
random_buffer(&snd_cr->seqno, sizeof(snd_cr->seqno));
frcti->snd_cr.lwe = snd_cr->seqno - 1;
}
seqno = snd_cr->seqno;
pci->seqno = hton32(seqno);
if (!rtx) {
snd_cr->lwe++;
} else {
if (!frcti->probe) {
frcti->rttseq = snd_cr->seqno;
frcti->t_probe = now;
frcti->probe = true;
}
if (now.tv_sec - rcv_cr->act.tv_sec <= rcv_cr->inact) {
pci->flags |= FRCT_ACK;
pci->ackno = hton32(rcv_cr->lwe);
rcv_cr->seqno = rcv_cr->lwe;
}
}
snd_cr->seqno++;
snd_cr->act = now;
pthread_rwlock_unlock(&frcti->lock);
if (rtx)
timerwheel_rxm(frcti, seqno, sdb);
return 0;
}
static void rtt_estimator(struct frcti * frcti,
time_t mrtt)
{
time_t srtt = frcti->srtt;
time_t rttvar = frcti->mdev;
if (srtt == 0) { /* first measurement */
srtt = mrtt;
rttvar = mrtt >> 1;
} else {
time_t delta = mrtt - srtt;
srtt += (delta >> 3);
rttvar += (ABS(delta) - rttvar) >> 2;
}
frcti->srtt = MAX(1000U, srtt);
frcti->mdev = MAX(100U, rttvar);
frcti->rto = MAX(RTO_MIN, frcti->srtt + (frcti->mdev << 1));
}
static void __frcti_tick(void)
{
timerwheel_move();
}
/* Always queues the next application packet on the RQ. */
static void __frcti_rcv(struct frcti * frcti,
struct shm_du_buff * sdb)
{
ssize_t idx;
size_t pos;
struct frct_pci * pci;
struct timespec now;
struct frct_cr * rcv_cr;
uint32_t seqno;
uint32_t ackno;
int fd = -1;
assert(frcti);
rcv_cr = &frcti->rcv_cr;
clock_gettime(PTHREAD_COND_CLOCK, &now);
pci = (struct frct_pci *) shm_du_buff_head_release(sdb, FRCT_PCILEN);
idx = shm_du_buff_get_idx(sdb);
seqno = ntoh32(pci->seqno);
pos = seqno & (RQ_SIZE - 1);
pthread_rwlock_wrlock(&frcti->lock);
if (now.tv_sec - rcv_cr->act.tv_sec > rcv_cr->inact) {
if (pci->flags & FRCT_DRF) /* New run. */
rcv_cr->lwe = seqno;
else
goto drop_packet;
}
if (pci->flags & FRCT_ACK) {
ackno = ntoh32(pci->ackno);
if (after(ackno, frcti->snd_cr.lwe))
frcti->snd_cr.lwe = ackno;
if (frcti->probe && after(ackno, frcti->rttseq)) {
rtt_estimator(frcti, ts_diff_ns(&frcti->t_probe, &now));
frcti->probe = false;
}
}
if (!(pci->flags & FRCT_DATA))
goto drop_packet;
if (before(seqno, rcv_cr->lwe)) {
rcv_cr->seqno = seqno;
goto drop_packet;
}
if (rcv_cr->cflags & FRCTFRTX) {
if ((seqno - rcv_cr->lwe) >= RQ_SIZE)
goto drop_packet; /* Out of rq. */
if (frcti->rq[pos] != -1)
goto drop_packet; /* Duplicate in rq. */
fd = frcti->fd;
} else {
rcv_cr->lwe = seqno;
}
frcti->rq[pos] = idx;
rcv_cr->act = now;
pthread_rwlock_unlock(&frcti->lock);
if (fd != -1)
timerwheel_ack(fd, frcti);
return;
drop_packet:
pthread_rwlock_unlock(&frcti->lock);
frct_send_ack(frcti);
shm_rdrbuff_remove(ai.rdrb, idx);
return;
}
/* Filter fqueue events for non-data packets */
int frcti_filter(struct fqueue * fq)
{
struct shm_du_buff * sdb;
int fd;
ssize_t idx;
struct frcti * frcti;
struct shm_rbuff * rb;
while (fq->next < fq->fqsize) {
if (fq->fqueue[fq->next + 1] != FLOW_PKT)
return 1;
pthread_rwlock_rdlock(&ai.lock);
fd = ai.ports[fq->fqueue[fq->next]].fd;
rb = ai.flows[fd].rx_rb;
frcti = ai.flows[fd].frcti;
if (frcti == NULL) {
pthread_rwlock_unlock(&ai.lock);
return 1;
}
if (__frcti_pdu_ready(frcti) >= 0) {
pthread_rwlock_unlock(&ai.lock);
return 1;
}
idx = shm_rbuff_read(rb);
if (idx < 0) {
pthread_rwlock_unlock(&ai.lock);
return 0;
}
sdb = shm_rdrbuff_get(ai.rdrb, idx);
__frcti_rcv(frcti, sdb);
if (__frcti_pdu_ready(frcti) >= 0) {
pthread_rwlock_unlock(&ai.lock);
return 1;
}
pthread_rwlock_unlock(&ai.lock);
fq->next += 2;
}
return fq->next < fq->fqsize;
}
|