freebsd-nq/sys/kern/subr_gtaskqueue.c

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/*-
* Copyright (c) 2000 Doug Rabson
* Copyright (c) 2014 Jeff Roberson
* Copyright (c) 2016 Matthew Macy
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*/
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
#include <sys/param.h>
#include <sys/systm.h>
#include <sys/bus.h>
#include <sys/cpuset.h>
#include <sys/interrupt.h>
#include <sys/kernel.h>
#include <sys/kthread.h>
#include <sys/libkern.h>
#include <sys/limits.h>
#include <sys/lock.h>
#include <sys/malloc.h>
#include <sys/mutex.h>
#include <sys/proc.h>
#include <sys/sched.h>
#include <sys/smp.h>
#include <sys/gtaskqueue.h>
#include <sys/unistd.h>
#include <machine/stdarg.h>
static MALLOC_DEFINE(M_GTASKQUEUE, "gtaskqueue", "Group Task Queues");
static void gtaskqueue_thread_enqueue(void *);
static void gtaskqueue_thread_loop(void *arg);
TASKQGROUP_DEFINE(softirq, mp_ncpus, 1);
struct gtaskqueue_busy {
struct gtask *tb_running;
TAILQ_ENTRY(gtaskqueue_busy) tb_link;
};
static struct gtask * const TB_DRAIN_WAITER = (struct gtask *)0x1;
struct gtaskqueue {
STAILQ_HEAD(, gtask) tq_queue;
gtaskqueue_enqueue_fn tq_enqueue;
void *tq_context;
char *tq_name;
TAILQ_HEAD(, gtaskqueue_busy) tq_active;
struct mtx tq_mutex;
struct thread **tq_threads;
int tq_tcount;
int tq_spin;
int tq_flags;
int tq_callouts;
taskqueue_callback_fn tq_callbacks[TASKQUEUE_NUM_CALLBACKS];
void *tq_cb_contexts[TASKQUEUE_NUM_CALLBACKS];
};
#define TQ_FLAGS_ACTIVE (1 << 0)
#define TQ_FLAGS_BLOCKED (1 << 1)
#define TQ_FLAGS_UNLOCKED_ENQUEUE (1 << 2)
#define DT_CALLOUT_ARMED (1 << 0)
#define TQ_LOCK(tq) \
do { \
if ((tq)->tq_spin) \
mtx_lock_spin(&(tq)->tq_mutex); \
else \
mtx_lock(&(tq)->tq_mutex); \
} while (0)
#define TQ_ASSERT_LOCKED(tq) mtx_assert(&(tq)->tq_mutex, MA_OWNED)
#define TQ_UNLOCK(tq) \
do { \
if ((tq)->tq_spin) \
mtx_unlock_spin(&(tq)->tq_mutex); \
else \
mtx_unlock(&(tq)->tq_mutex); \
} while (0)
#define TQ_ASSERT_UNLOCKED(tq) mtx_assert(&(tq)->tq_mutex, MA_NOTOWNED)
#ifdef INVARIANTS
static void
gtask_dump(struct gtask *gtask)
{
printf("gtask: %p ta_flags=%x ta_priority=%d ta_func=%p ta_context=%p\n",
gtask, gtask->ta_flags, gtask->ta_priority, gtask->ta_func, gtask->ta_context);
}
#endif
static __inline int
TQ_SLEEP(struct gtaskqueue *tq, void *p, struct mtx *m, int pri, const char *wm,
int t)
{
if (tq->tq_spin)
return (msleep_spin(p, m, wm, t));
return (msleep(p, m, pri, wm, t));
}
static struct gtaskqueue *
_gtaskqueue_create(const char *name, int mflags,
taskqueue_enqueue_fn enqueue, void *context,
int mtxflags, const char *mtxname __unused)
{
struct gtaskqueue *queue;
char *tq_name;
tq_name = malloc(TASKQUEUE_NAMELEN, M_GTASKQUEUE, mflags | M_ZERO);
if (!tq_name)
return (NULL);
snprintf(tq_name, TASKQUEUE_NAMELEN, "%s", (name) ? name : "taskqueue");
queue = malloc(sizeof(struct gtaskqueue), M_GTASKQUEUE, mflags | M_ZERO);
if (!queue)
return (NULL);
STAILQ_INIT(&queue->tq_queue);
TAILQ_INIT(&queue->tq_active);
queue->tq_enqueue = enqueue;
queue->tq_context = context;
queue->tq_name = tq_name;
queue->tq_spin = (mtxflags & MTX_SPIN) != 0;
queue->tq_flags |= TQ_FLAGS_ACTIVE;
if (enqueue == gtaskqueue_thread_enqueue)
queue->tq_flags |= TQ_FLAGS_UNLOCKED_ENQUEUE;
mtx_init(&queue->tq_mutex, tq_name, NULL, mtxflags);
return (queue);
}
/*
* Signal a taskqueue thread to terminate.
*/
static void
gtaskqueue_terminate(struct thread **pp, struct gtaskqueue *tq)
{
while (tq->tq_tcount > 0 || tq->tq_callouts > 0) {
wakeup(tq);
TQ_SLEEP(tq, pp, &tq->tq_mutex, PWAIT, "taskqueue_destroy", 0);
}
}
static void
gtaskqueue_free(struct gtaskqueue *queue)
{
TQ_LOCK(queue);
queue->tq_flags &= ~TQ_FLAGS_ACTIVE;
gtaskqueue_terminate(queue->tq_threads, queue);
KASSERT(TAILQ_EMPTY(&queue->tq_active), ("Tasks still running?"));
KASSERT(queue->tq_callouts == 0, ("Armed timeout tasks"));
mtx_destroy(&queue->tq_mutex);
free(queue->tq_threads, M_GTASKQUEUE);
free(queue->tq_name, M_GTASKQUEUE);
free(queue, M_GTASKQUEUE);
}
int
grouptaskqueue_enqueue(struct gtaskqueue *queue, struct gtask *gtask)
{
#ifdef INVARIANTS
if (queue == NULL) {
gtask_dump(gtask);
panic("queue == NULL");
}
#endif
TQ_LOCK(queue);
if (gtask->ta_flags & TASK_ENQUEUED) {
TQ_UNLOCK(queue);
return (0);
}
STAILQ_INSERT_TAIL(&queue->tq_queue, gtask, ta_link);
gtask->ta_flags |= TASK_ENQUEUED;
TQ_UNLOCK(queue);
if ((queue->tq_flags & TQ_FLAGS_BLOCKED) == 0)
queue->tq_enqueue(queue->tq_context);
return (0);
}
static void
gtaskqueue_task_nop_fn(void *context)
{
}
/*
* Block until all currently queued tasks in this taskqueue
* have begun execution. Tasks queued during execution of
* this function are ignored.
*/
static void
gtaskqueue_drain_tq_queue(struct gtaskqueue *queue)
{
struct gtask t_barrier;
if (STAILQ_EMPTY(&queue->tq_queue))
return;
/*
* Enqueue our barrier after all current tasks, but with
* the highest priority so that newly queued tasks cannot
* pass it. Because of the high priority, we can not use
* taskqueue_enqueue_locked directly (which drops the lock
* anyway) so just insert it at tail while we have the
* queue lock.
*/
GTASK_INIT(&t_barrier, 0, USHRT_MAX, gtaskqueue_task_nop_fn, &t_barrier);
STAILQ_INSERT_TAIL(&queue->tq_queue, &t_barrier, ta_link);
t_barrier.ta_flags |= TASK_ENQUEUED;
/*
* Once the barrier has executed, all previously queued tasks
* have completed or are currently executing.
*/
while (t_barrier.ta_flags & TASK_ENQUEUED)
TQ_SLEEP(queue, &t_barrier, &queue->tq_mutex, PWAIT, "-", 0);
}
/*
* Block until all currently executing tasks for this taskqueue
* complete. Tasks that begin execution during the execution
* of this function are ignored.
*/
static void
gtaskqueue_drain_tq_active(struct gtaskqueue *queue)
{
struct gtaskqueue_busy tb_marker, *tb_first;
if (TAILQ_EMPTY(&queue->tq_active))
return;
/* Block taskq_terminate().*/
queue->tq_callouts++;
/*
* Wait for all currently executing taskqueue threads
* to go idle.
*/
tb_marker.tb_running = TB_DRAIN_WAITER;
TAILQ_INSERT_TAIL(&queue->tq_active, &tb_marker, tb_link);
while (TAILQ_FIRST(&queue->tq_active) != &tb_marker)
TQ_SLEEP(queue, &tb_marker, &queue->tq_mutex, PWAIT, "-", 0);
TAILQ_REMOVE(&queue->tq_active, &tb_marker, tb_link);
/*
* Wakeup any other drain waiter that happened to queue up
* without any intervening active thread.
*/
tb_first = TAILQ_FIRST(&queue->tq_active);
if (tb_first != NULL && tb_first->tb_running == TB_DRAIN_WAITER)
wakeup(tb_first);
/* Release taskqueue_terminate(). */
queue->tq_callouts--;
if ((queue->tq_flags & TQ_FLAGS_ACTIVE) == 0)
wakeup_one(queue->tq_threads);
}
void
gtaskqueue_block(struct gtaskqueue *queue)
{
TQ_LOCK(queue);
queue->tq_flags |= TQ_FLAGS_BLOCKED;
TQ_UNLOCK(queue);
}
void
gtaskqueue_unblock(struct gtaskqueue *queue)
{
TQ_LOCK(queue);
queue->tq_flags &= ~TQ_FLAGS_BLOCKED;
if (!STAILQ_EMPTY(&queue->tq_queue))
queue->tq_enqueue(queue->tq_context);
TQ_UNLOCK(queue);
}
static void
gtaskqueue_run_locked(struct gtaskqueue *queue)
{
struct gtaskqueue_busy tb;
struct gtaskqueue_busy *tb_first;
struct gtask *gtask;
KASSERT(queue != NULL, ("tq is NULL"));
TQ_ASSERT_LOCKED(queue);
tb.tb_running = NULL;
while (STAILQ_FIRST(&queue->tq_queue)) {
TAILQ_INSERT_TAIL(&queue->tq_active, &tb, tb_link);
/*
* Carefully remove the first task from the queue and
* clear its TASK_ENQUEUED flag
*/
gtask = STAILQ_FIRST(&queue->tq_queue);
KASSERT(gtask != NULL, ("task is NULL"));
STAILQ_REMOVE_HEAD(&queue->tq_queue, ta_link);
gtask->ta_flags &= ~TASK_ENQUEUED;
tb.tb_running = gtask;
TQ_UNLOCK(queue);
KASSERT(gtask->ta_func != NULL, ("task->ta_func is NULL"));
gtask->ta_func(gtask->ta_context);
TQ_LOCK(queue);
tb.tb_running = NULL;
wakeup(gtask);
TAILQ_REMOVE(&queue->tq_active, &tb, tb_link);
tb_first = TAILQ_FIRST(&queue->tq_active);
if (tb_first != NULL &&
tb_first->tb_running == TB_DRAIN_WAITER)
wakeup(tb_first);
}
}
static int
task_is_running(struct gtaskqueue *queue, struct gtask *gtask)
{
struct gtaskqueue_busy *tb;
TQ_ASSERT_LOCKED(queue);
TAILQ_FOREACH(tb, &queue->tq_active, tb_link) {
if (tb->tb_running == gtask)
return (1);
}
return (0);
}
static int
gtaskqueue_cancel_locked(struct gtaskqueue *queue, struct gtask *gtask)
{
if (gtask->ta_flags & TASK_ENQUEUED)
STAILQ_REMOVE(&queue->tq_queue, gtask, gtask, ta_link);
gtask->ta_flags &= ~TASK_ENQUEUED;
return (task_is_running(queue, gtask) ? EBUSY : 0);
}
int
gtaskqueue_cancel(struct gtaskqueue *queue, struct gtask *gtask)
{
int error;
TQ_LOCK(queue);
error = gtaskqueue_cancel_locked(queue, gtask);
TQ_UNLOCK(queue);
return (error);
}
void
gtaskqueue_drain(struct gtaskqueue *queue, struct gtask *gtask)
{
if (!queue->tq_spin)
WITNESS_WARN(WARN_GIANTOK | WARN_SLEEPOK, NULL, __func__);
TQ_LOCK(queue);
while ((gtask->ta_flags & TASK_ENQUEUED) || task_is_running(queue, gtask))
TQ_SLEEP(queue, gtask, &queue->tq_mutex, PWAIT, "-", 0);
TQ_UNLOCK(queue);
}
void
gtaskqueue_drain_all(struct gtaskqueue *queue)
{
if (!queue->tq_spin)
WITNESS_WARN(WARN_GIANTOK | WARN_SLEEPOK, NULL, __func__);
TQ_LOCK(queue);
gtaskqueue_drain_tq_queue(queue);
gtaskqueue_drain_tq_active(queue);
TQ_UNLOCK(queue);
}
static int
_gtaskqueue_start_threads(struct gtaskqueue **tqp, int count, int pri,
cpuset_t *mask, const char *name, va_list ap)
{
char ktname[MAXCOMLEN + 1];
struct thread *td;
struct gtaskqueue *tq;
int i, error;
if (count <= 0)
return (EINVAL);
vsnprintf(ktname, sizeof(ktname), name, ap);
tq = *tqp;
tq->tq_threads = malloc(sizeof(struct thread *) * count, M_GTASKQUEUE,
M_NOWAIT | M_ZERO);
if (tq->tq_threads == NULL) {
printf("%s: no memory for %s threads\n", __func__, ktname);
return (ENOMEM);
}
for (i = 0; i < count; i++) {
if (count == 1)
error = kthread_add(gtaskqueue_thread_loop, tqp, NULL,
&tq->tq_threads[i], RFSTOPPED, 0, "%s", ktname);
else
error = kthread_add(gtaskqueue_thread_loop, tqp, NULL,
&tq->tq_threads[i], RFSTOPPED, 0,
"%s_%d", ktname, i);
if (error) {
/* should be ok to continue, taskqueue_free will dtrt */
printf("%s: kthread_add(%s): error %d", __func__,
ktname, error);
tq->tq_threads[i] = NULL; /* paranoid */
} else
tq->tq_tcount++;
}
for (i = 0; i < count; i++) {
if (tq->tq_threads[i] == NULL)
continue;
td = tq->tq_threads[i];
if (mask) {
error = cpuset_setthread(td->td_tid, mask);
/*
* Failing to pin is rarely an actual fatal error;
* it'll just affect performance.
*/
if (error)
printf("%s: curthread=%llu: can't pin; "
"error=%d\n",
__func__,
(unsigned long long) td->td_tid,
error);
}
thread_lock(td);
sched_prio(td, pri);
sched_add(td, SRQ_BORING);
thread_unlock(td);
}
return (0);
}
static int
gtaskqueue_start_threads(struct gtaskqueue **tqp, int count, int pri,
const char *name, ...)
{
va_list ap;
int error;
va_start(ap, name);
error = _gtaskqueue_start_threads(tqp, count, pri, NULL, name, ap);
va_end(ap);
return (error);
}
static inline void
gtaskqueue_run_callback(struct gtaskqueue *tq,
enum taskqueue_callback_type cb_type)
{
taskqueue_callback_fn tq_callback;
TQ_ASSERT_UNLOCKED(tq);
tq_callback = tq->tq_callbacks[cb_type];
if (tq_callback != NULL)
tq_callback(tq->tq_cb_contexts[cb_type]);
}
static void
gtaskqueue_thread_loop(void *arg)
{
struct gtaskqueue **tqp, *tq;
Roll up iflib commits from github. This pulls in most of the work done by Matt Macy as well as other changes which he has accepted via pull request to his github repo at https://github.com/mattmacy/networking/ This should bring -CURRENT and the github repo into close enough sync to allow small feature branches rather than a large chain of interdependant patches being developed out of tree. The reset of the synchronization should be able to be completed on github by splitting the remaining changes that are not yet ready into short feature branches for later review as smaller commits. Here is a summary of changes included in this patch: 1) More checks when INVARIANTS are enabled for eariler problem detection 2) Group Task Queue cleanups - Fix use of duplicate shortdesc for gtaskqueue malloc type. Some interfaces such as memguard(9) use the short description to identify malloc types, so duplicates should be avoided. 3) Allow gtaskqueues to use ithreads in addition to taskqueues - In some cases, this can improve performance 4) Better logging when taskqgroup_attach*() fails to set interrupt affinity. 5) Do not start gtaskqueues until they're needed 6) Have mp_ring enqueue function enter the ABDICATED rather than BUSY state. This moves the TX to the gtaskq and allows processing to continue faster as well as make TX batching more likely. 7) Add an ift_txd_errata function to struct if_txrx. This allows drivers to inspect/modify mbufs before transmission. 8) Add a new IFLIB_NEED_ZERO_CSUM for drivers to indicate they need checksums zeroed for checksum offload to work. This avoids modifying packet data in the TX path when possible. 9) Use ithreads for iflib I/O instead of taskqueues 10) Clean up ioctl and support async ioctl functions 11) Prefetch two cachlines from each mbuf instead of one up to 128B. We often need to parse packet header info beyond 64B. 12) Fix potential memory corruption due to fence post error in bit_nclear() usage. 13) Improved hang detection and handling 14) If the packet is smaller than MTU, disable the TSO flags. This avoids extra packet parsing when not needed. 15) Move TCP header parsing inside the IS_TSO?() test. This avoids extra packet parsing when not needed. 16) Pass chains of mbufs that are not consumed by lro to if_input() rather call if_input() for each mbuf. 17) Re-arrange packet header loads to get as much work as possible done before a cache stall. 18) Lock the context when calling IFDI_ATTACH_PRE()/IFDI_ATTACH_POST()/ IFDI_DETACH(); 19) Attempt to distribute RX/TX tasks across cores more sensibly, especially when RX and TX share an interrupt. RX will attempt to take the first threads on a core, and TX will attempt to take successive threads. 20) Allow iflib_softirq_alloc_generic() to request affinity to the same cpus an interrupt has affinity with. This allows TX queues to ensure they are serviced by the socket the device is on. 21) Add new iflib sysctls to net.iflib: - timer_int - interval at which to run per-queue timers in ticks - force_busdma 22) Add new per-device iflib sysctls to dev.X.Y.iflib - rx_budget allows tuning the batch size on the RX path - watchdog_events Count of watchdog events seen since load 23) Fix error where netmap_rxq_init() could get called before IFDI_INIT() 24) e1000: Fixed version of r323008: post-cold sleep instead of DELAY when waiting for firmware - After interrupts are enabled, convert all waits to sleeps - Eliminates e1000 software/firmware synchronization busy waits after startup 25) e1000: Remove special case for budget=1 in em_txrx.c - Premature optimization which may actually be incorrect with multi-segment packets 26) e1000: Split out TX interrupt rather than share an interrupt for RX and TX. - Allows better performance by keeping RX and TX paths separate 27) e1000: Separate igb from em code where suitable Much easier to understand separate functions and "if (is_igb)" than previous tests like "if (reg_icr & (E1000_ICR_RXSEQ | E1000_ICR_LSC))" #blamebruno Reviewed by: sbruno Approved by: sbruno (mentor) Sponsored by: Limelight Networks Differential Revision: https://reviews.freebsd.org/D12235
2017-09-13 01:18:42 +00:00
tqp = arg;
tq = *tqp;
gtaskqueue_run_callback(tq, TASKQUEUE_CALLBACK_TYPE_INIT);
TQ_LOCK(tq);
Roll up iflib commits from github. This pulls in most of the work done by Matt Macy as well as other changes which he has accepted via pull request to his github repo at https://github.com/mattmacy/networking/ This should bring -CURRENT and the github repo into close enough sync to allow small feature branches rather than a large chain of interdependant patches being developed out of tree. The reset of the synchronization should be able to be completed on github by splitting the remaining changes that are not yet ready into short feature branches for later review as smaller commits. Here is a summary of changes included in this patch: 1) More checks when INVARIANTS are enabled for eariler problem detection 2) Group Task Queue cleanups - Fix use of duplicate shortdesc for gtaskqueue malloc type. Some interfaces such as memguard(9) use the short description to identify malloc types, so duplicates should be avoided. 3) Allow gtaskqueues to use ithreads in addition to taskqueues - In some cases, this can improve performance 4) Better logging when taskqgroup_attach*() fails to set interrupt affinity. 5) Do not start gtaskqueues until they're needed 6) Have mp_ring enqueue function enter the ABDICATED rather than BUSY state. This moves the TX to the gtaskq and allows processing to continue faster as well as make TX batching more likely. 7) Add an ift_txd_errata function to struct if_txrx. This allows drivers to inspect/modify mbufs before transmission. 8) Add a new IFLIB_NEED_ZERO_CSUM for drivers to indicate they need checksums zeroed for checksum offload to work. This avoids modifying packet data in the TX path when possible. 9) Use ithreads for iflib I/O instead of taskqueues 10) Clean up ioctl and support async ioctl functions 11) Prefetch two cachlines from each mbuf instead of one up to 128B. We often need to parse packet header info beyond 64B. 12) Fix potential memory corruption due to fence post error in bit_nclear() usage. 13) Improved hang detection and handling 14) If the packet is smaller than MTU, disable the TSO flags. This avoids extra packet parsing when not needed. 15) Move TCP header parsing inside the IS_TSO?() test. This avoids extra packet parsing when not needed. 16) Pass chains of mbufs that are not consumed by lro to if_input() rather call if_input() for each mbuf. 17) Re-arrange packet header loads to get as much work as possible done before a cache stall. 18) Lock the context when calling IFDI_ATTACH_PRE()/IFDI_ATTACH_POST()/ IFDI_DETACH(); 19) Attempt to distribute RX/TX tasks across cores more sensibly, especially when RX and TX share an interrupt. RX will attempt to take the first threads on a core, and TX will attempt to take successive threads. 20) Allow iflib_softirq_alloc_generic() to request affinity to the same cpus an interrupt has affinity with. This allows TX queues to ensure they are serviced by the socket the device is on. 21) Add new iflib sysctls to net.iflib: - timer_int - interval at which to run per-queue timers in ticks - force_busdma 22) Add new per-device iflib sysctls to dev.X.Y.iflib - rx_budget allows tuning the batch size on the RX path - watchdog_events Count of watchdog events seen since load 23) Fix error where netmap_rxq_init() could get called before IFDI_INIT() 24) e1000: Fixed version of r323008: post-cold sleep instead of DELAY when waiting for firmware - After interrupts are enabled, convert all waits to sleeps - Eliminates e1000 software/firmware synchronization busy waits after startup 25) e1000: Remove special case for budget=1 in em_txrx.c - Premature optimization which may actually be incorrect with multi-segment packets 26) e1000: Split out TX interrupt rather than share an interrupt for RX and TX. - Allows better performance by keeping RX and TX paths separate 27) e1000: Separate igb from em code where suitable Much easier to understand separate functions and "if (is_igb)" than previous tests like "if (reg_icr & (E1000_ICR_RXSEQ | E1000_ICR_LSC))" #blamebruno Reviewed by: sbruno Approved by: sbruno (mentor) Sponsored by: Limelight Networks Differential Revision: https://reviews.freebsd.org/D12235
2017-09-13 01:18:42 +00:00
while ((tq->tq_flags & TQ_FLAGS_ACTIVE) != 0) {
/* XXX ? */
gtaskqueue_run_locked(tq);
/*
* Because taskqueue_run() can drop tq_mutex, we need to
* check if the TQ_FLAGS_ACTIVE flag wasn't removed in the
* meantime, which means we missed a wakeup.
*/
if ((tq->tq_flags & TQ_FLAGS_ACTIVE) == 0)
break;
TQ_SLEEP(tq, tq, &tq->tq_mutex, 0, "-", 0);
}
gtaskqueue_run_locked(tq);
/*
* This thread is on its way out, so just drop the lock temporarily
* in order to call the shutdown callback. This allows the callback
* to look at the taskqueue, even just before it dies.
*/
TQ_UNLOCK(tq);
gtaskqueue_run_callback(tq, TASKQUEUE_CALLBACK_TYPE_SHUTDOWN);
TQ_LOCK(tq);
/* rendezvous with thread that asked us to terminate */
tq->tq_tcount--;
wakeup_one(tq->tq_threads);
TQ_UNLOCK(tq);
kthread_exit();
}
static void
gtaskqueue_thread_enqueue(void *context)
{
struct gtaskqueue **tqp, *tq;
tqp = context;
tq = *tqp;
wakeup_one(tq);
}
static struct gtaskqueue *
gtaskqueue_create_fast(const char *name, int mflags,
taskqueue_enqueue_fn enqueue, void *context)
{
return _gtaskqueue_create(name, mflags, enqueue, context,
MTX_SPIN, "fast_taskqueue");
}
struct taskqgroup_cpu {
LIST_HEAD(, grouptask) tgc_tasks;
struct gtaskqueue *tgc_taskq;
int tgc_cnt;
int tgc_cpu;
};
struct taskqgroup {
struct taskqgroup_cpu tqg_queue[MAXCPU];
struct mtx tqg_lock;
char * tqg_name;
int tqg_adjusting;
int tqg_stride;
int tqg_cnt;
};
struct taskq_bind_task {
struct gtask bt_task;
int bt_cpuid;
};
static void
taskqgroup_cpu_create(struct taskqgroup *qgroup, int idx, int cpu)
{
struct taskqgroup_cpu *qcpu;
qcpu = &qgroup->tqg_queue[idx];
LIST_INIT(&qcpu->tgc_tasks);
qcpu->tgc_taskq = gtaskqueue_create_fast(NULL, M_WAITOK,
taskqueue_thread_enqueue, &qcpu->tgc_taskq);
gtaskqueue_start_threads(&qcpu->tgc_taskq, 1, PI_SOFT,
"%s_%d", qgroup->tqg_name, idx);
qcpu->tgc_cpu = cpu;
}
static void
taskqgroup_cpu_remove(struct taskqgroup *qgroup, int idx)
{
gtaskqueue_free(qgroup->tqg_queue[idx].tgc_taskq);
}
/*
* Find the taskq with least # of tasks that doesn't currently have any
* other queues from the uniq identifier.
*/
static int
taskqgroup_find(struct taskqgroup *qgroup, void *uniq)
{
struct grouptask *n;
int i, idx, mincnt;
int strict;
mtx_assert(&qgroup->tqg_lock, MA_OWNED);
if (qgroup->tqg_cnt == 0)
return (0);
idx = -1;
mincnt = INT_MAX;
/*
* Two passes; First scan for a queue with the least tasks that
* does not already service this uniq id. If that fails simply find
* the queue with the least total tasks;
*/
for (strict = 1; mincnt == INT_MAX; strict = 0) {
for (i = 0; i < qgroup->tqg_cnt; i++) {
if (qgroup->tqg_queue[i].tgc_cnt > mincnt)
continue;
if (strict) {
LIST_FOREACH(n,
&qgroup->tqg_queue[i].tgc_tasks, gt_list)
if (n->gt_uniq == uniq)
break;
if (n != NULL)
continue;
}
mincnt = qgroup->tqg_queue[i].tgc_cnt;
idx = i;
}
}
if (idx == -1)
panic("taskqgroup_find: Failed to pick a qid.");
return (idx);
}
/*
* smp_started is unusable since it is not set for UP kernels or even for
* SMP kernels when there is 1 CPU. This is usually handled by adding a
* (mp_ncpus == 1) test, but that would be broken here since we need to
* to synchronize with the SI_SUB_SMP ordering. Even in the pure SMP case
* smp_started only gives a fuzzy ordering relative to SI_SUB_SMP.
*
* So maintain our own flag. It must be set after all CPUs are started
* and before SI_SUB_SMP:SI_ORDER_ANY so that the SYSINIT for delayed
* adjustment is properly delayed. SI_ORDER_FOURTH is clearly before
* SI_ORDER_ANY and unclearly after the CPUs are started. It would be
* simpler for adjustment to pass a flag indicating if it is delayed.
*/
static int tqg_smp_started;
static void
tqg_record_smp_started(void *arg)
{
tqg_smp_started = 1;
}
SYSINIT(tqg_record_smp_started, SI_SUB_SMP, SI_ORDER_FOURTH,
tqg_record_smp_started, NULL);
void
taskqgroup_attach(struct taskqgroup *qgroup, struct grouptask *gtask,
void *uniq, int irq, char *name)
{
cpuset_t mask;
int qid, error;
gtask->gt_uniq = uniq;
snprintf(gtask->gt_name, GROUPTASK_NAMELEN, "%s", name ? name : "grouptask");
gtask->gt_irq = irq;
gtask->gt_cpu = -1;
mtx_lock(&qgroup->tqg_lock);
qid = taskqgroup_find(qgroup, uniq);
qgroup->tqg_queue[qid].tgc_cnt++;
LIST_INSERT_HEAD(&qgroup->tqg_queue[qid].tgc_tasks, gtask, gt_list);
gtask->gt_taskqueue = qgroup->tqg_queue[qid].tgc_taskq;
if (irq != -1 && tqg_smp_started) {
gtask->gt_cpu = qgroup->tqg_queue[qid].tgc_cpu;
CPU_ZERO(&mask);
CPU_SET(qgroup->tqg_queue[qid].tgc_cpu, &mask);
mtx_unlock(&qgroup->tqg_lock);
error = intr_setaffinity(irq, CPU_WHICH_IRQ, &mask);
if (error)
printf("%s: setaffinity failed: %d\n", __func__, error);
} else
mtx_unlock(&qgroup->tqg_lock);
}
static void
taskqgroup_attach_deferred(struct taskqgroup *qgroup, struct grouptask *gtask)
{
cpuset_t mask;
int qid, cpu, error;
mtx_lock(&qgroup->tqg_lock);
qid = taskqgroup_find(qgroup, gtask->gt_uniq);
cpu = qgroup->tqg_queue[qid].tgc_cpu;
if (gtask->gt_irq != -1) {
mtx_unlock(&qgroup->tqg_lock);
CPU_ZERO(&mask);
CPU_SET(cpu, &mask);
error = intr_setaffinity(gtask->gt_irq, CPU_WHICH_IRQ, &mask);
mtx_lock(&qgroup->tqg_lock);
if (error)
printf("%s: %s setaffinity failed: %d\n", __func__, gtask->gt_name, error);
}
qgroup->tqg_queue[qid].tgc_cnt++;
LIST_INSERT_HEAD(&qgroup->tqg_queue[qid].tgc_tasks, gtask,
gt_list);
MPASS(qgroup->tqg_queue[qid].tgc_taskq != NULL);
gtask->gt_taskqueue = qgroup->tqg_queue[qid].tgc_taskq;
mtx_unlock(&qgroup->tqg_lock);
}
int
taskqgroup_attach_cpu(struct taskqgroup *qgroup, struct grouptask *gtask,
void *uniq, int cpu, int irq, char *name)
{
cpuset_t mask;
int i, qid, error;
qid = -1;
gtask->gt_uniq = uniq;
snprintf(gtask->gt_name, GROUPTASK_NAMELEN, "%s", name ? name : "grouptask");
gtask->gt_irq = irq;
gtask->gt_cpu = cpu;
mtx_lock(&qgroup->tqg_lock);
if (tqg_smp_started) {
for (i = 0; i < qgroup->tqg_cnt; i++)
if (qgroup->tqg_queue[i].tgc_cpu == cpu) {
qid = i;
break;
}
if (qid == -1) {
mtx_unlock(&qgroup->tqg_lock);
printf("%s: qid not found for %s cpu=%d\n", __func__, gtask->gt_name, cpu);
return (EINVAL);
}
} else
qid = 0;
qgroup->tqg_queue[qid].tgc_cnt++;
LIST_INSERT_HEAD(&qgroup->tqg_queue[qid].tgc_tasks, gtask, gt_list);
gtask->gt_taskqueue = qgroup->tqg_queue[qid].tgc_taskq;
cpu = qgroup->tqg_queue[qid].tgc_cpu;
mtx_unlock(&qgroup->tqg_lock);
CPU_ZERO(&mask);
CPU_SET(cpu, &mask);
if (irq != -1 && tqg_smp_started) {
error = intr_setaffinity(irq, CPU_WHICH_IRQ, &mask);
if (error)
printf("%s: setaffinity failed: %d\n", __func__, error);
}
return (0);
}
static int
taskqgroup_attach_cpu_deferred(struct taskqgroup *qgroup, struct grouptask *gtask)
{
cpuset_t mask;
int i, qid, irq, cpu, error;
qid = -1;
irq = gtask->gt_irq;
cpu = gtask->gt_cpu;
MPASS(tqg_smp_started);
mtx_lock(&qgroup->tqg_lock);
for (i = 0; i < qgroup->tqg_cnt; i++)
if (qgroup->tqg_queue[i].tgc_cpu == cpu) {
qid = i;
break;
}
if (qid == -1) {
mtx_unlock(&qgroup->tqg_lock);
printf("%s: qid not found for %s cpu=%d\n", __func__, gtask->gt_name, cpu);
return (EINVAL);
}
qgroup->tqg_queue[qid].tgc_cnt++;
LIST_INSERT_HEAD(&qgroup->tqg_queue[qid].tgc_tasks, gtask, gt_list);
MPASS(qgroup->tqg_queue[qid].tgc_taskq != NULL);
gtask->gt_taskqueue = qgroup->tqg_queue[qid].tgc_taskq;
mtx_unlock(&qgroup->tqg_lock);
CPU_ZERO(&mask);
CPU_SET(cpu, &mask);
if (irq != -1) {
error = intr_setaffinity(irq, CPU_WHICH_IRQ, &mask);
if (error)
printf("%s: setaffinity failed: %d\n", __func__, error);
}
return (0);
}
void
taskqgroup_detach(struct taskqgroup *qgroup, struct grouptask *gtask)
{
int i;
mtx_lock(&qgroup->tqg_lock);
for (i = 0; i < qgroup->tqg_cnt; i++)
if (qgroup->tqg_queue[i].tgc_taskq == gtask->gt_taskqueue)
break;
if (i == qgroup->tqg_cnt)
panic("taskqgroup_detach: task %s not in group\n", gtask->gt_name);
qgroup->tqg_queue[i].tgc_cnt--;
LIST_REMOVE(gtask, gt_list);
mtx_unlock(&qgroup->tqg_lock);
gtask->gt_taskqueue = NULL;
}
static void
taskqgroup_binder(void *ctx)
{
struct taskq_bind_task *gtask = (struct taskq_bind_task *)ctx;
cpuset_t mask;
int error;
CPU_ZERO(&mask);
CPU_SET(gtask->bt_cpuid, &mask);
error = cpuset_setthread(curthread->td_tid, &mask);
thread_lock(curthread);
sched_bind(curthread, gtask->bt_cpuid);
thread_unlock(curthread);
if (error)
printf("%s: setaffinity failed: %d\n", __func__,
error);
free(gtask, M_DEVBUF);
}
static void
taskqgroup_bind(struct taskqgroup *qgroup)
{
struct taskq_bind_task *gtask;
int i;
/*
* Bind taskqueue threads to specific CPUs, if they have been assigned
* one.
*/
if (qgroup->tqg_cnt == 1)
return;
for (i = 0; i < qgroup->tqg_cnt; i++) {
gtask = malloc(sizeof (*gtask), M_DEVBUF, M_WAITOK);
GTASK_INIT(&gtask->bt_task, 0, 0, taskqgroup_binder, gtask);
gtask->bt_cpuid = qgroup->tqg_queue[i].tgc_cpu;
grouptaskqueue_enqueue(qgroup->tqg_queue[i].tgc_taskq,
&gtask->bt_task);
}
}
static int
_taskqgroup_adjust(struct taskqgroup *qgroup, int cnt, int stride)
{
LIST_HEAD(, grouptask) gtask_head = LIST_HEAD_INITIALIZER(NULL);
struct grouptask *gtask;
int i, k, old_cnt, old_cpu, cpu;
mtx_assert(&qgroup->tqg_lock, MA_OWNED);
if (cnt < 1 || cnt * stride > mp_ncpus || !tqg_smp_started) {
printf("%s: failed cnt: %d stride: %d "
"mp_ncpus: %d tqg_smp_started: %d\n",
__func__, cnt, stride, mp_ncpus, tqg_smp_started);
return (EINVAL);
}
if (qgroup->tqg_adjusting) {
printf("%s failed: adjusting\n", __func__);
return (EBUSY);
}
qgroup->tqg_adjusting = 1;
old_cnt = qgroup->tqg_cnt;
old_cpu = 0;
if (old_cnt < cnt)
old_cpu = qgroup->tqg_queue[old_cnt].tgc_cpu;
mtx_unlock(&qgroup->tqg_lock);
/*
* Set up queue for tasks added before boot.
*/
if (old_cnt == 0) {
LIST_SWAP(&gtask_head, &qgroup->tqg_queue[0].tgc_tasks,
grouptask, gt_list);
qgroup->tqg_queue[0].tgc_cnt = 0;
}
/*
* If new taskq threads have been added.
*/
cpu = old_cpu;
for (i = old_cnt; i < cnt; i++) {
taskqgroup_cpu_create(qgroup, i, cpu);
for (k = 0; k < stride; k++)
cpu = CPU_NEXT(cpu);
}
mtx_lock(&qgroup->tqg_lock);
qgroup->tqg_cnt = cnt;
qgroup->tqg_stride = stride;
/*
* Adjust drivers to use new taskqs.
*/
for (i = 0; i < old_cnt; i++) {
while ((gtask = LIST_FIRST(&qgroup->tqg_queue[i].tgc_tasks))) {
LIST_REMOVE(gtask, gt_list);
qgroup->tqg_queue[i].tgc_cnt--;
LIST_INSERT_HEAD(&gtask_head, gtask, gt_list);
}
}
mtx_unlock(&qgroup->tqg_lock);
while ((gtask = LIST_FIRST(&gtask_head))) {
LIST_REMOVE(gtask, gt_list);
if (gtask->gt_cpu == -1)
taskqgroup_attach_deferred(qgroup, gtask);
else if (taskqgroup_attach_cpu_deferred(qgroup, gtask))
taskqgroup_attach_deferred(qgroup, gtask);
}
#ifdef INVARIANTS
mtx_lock(&qgroup->tqg_lock);
for (i = 0; i < qgroup->tqg_cnt; i++) {
MPASS(qgroup->tqg_queue[i].tgc_taskq != NULL);
LIST_FOREACH(gtask, &qgroup->tqg_queue[i].tgc_tasks, gt_list)
MPASS(gtask->gt_taskqueue != NULL);
}
mtx_unlock(&qgroup->tqg_lock);
#endif
/*
* If taskq thread count has been reduced.
*/
for (i = cnt; i < old_cnt; i++)
taskqgroup_cpu_remove(qgroup, i);
taskqgroup_bind(qgroup);
mtx_lock(&qgroup->tqg_lock);
qgroup->tqg_adjusting = 0;
return (0);
}
int
taskqgroup_adjust(struct taskqgroup *qgroup, int cnt, int stride)
{
int error;
mtx_lock(&qgroup->tqg_lock);
error = _taskqgroup_adjust(qgroup, cnt, stride);
mtx_unlock(&qgroup->tqg_lock);
return (error);
}
struct taskqgroup *
taskqgroup_create(char *name)
{
struct taskqgroup *qgroup;
qgroup = malloc(sizeof(*qgroup), M_GTASKQUEUE, M_WAITOK | M_ZERO);
mtx_init(&qgroup->tqg_lock, "taskqgroup", NULL, MTX_DEF);
qgroup->tqg_name = name;
LIST_INIT(&qgroup->tqg_queue[0].tgc_tasks);
return (qgroup);
}
void
taskqgroup_destroy(struct taskqgroup *qgroup)
{
}