@@ -170,6 +170,7 @@ otx2_tim_timer_cancel_burst(const struct rte_event_timer_adapter *adptr,
int ret;
RTE_SET_USED(adptr);
+ rte_atomic_thread_fence(__ATOMIC_ACQUIRE);
for (index = 0; index < nb_timers; index++) {
if (tim[index]->state == RTE_EVENT_TIMER_CANCELED) {
rte_errno = EALREADY;
@@ -84,7 +84,13 @@ tim_bkt_inc_lock(struct otx2_tim_bkt *bktp)
static inline void
tim_bkt_dec_lock(struct otx2_tim_bkt *bktp)
{
- __atomic_add_fetch(&bktp->lock, 0xff, __ATOMIC_RELEASE);
+ __atomic_fetch_sub(&bktp->lock, 1, __ATOMIC_RELEASE);
+}
+
+static inline void
+tim_bkt_dec_lock_relaxed(struct otx2_tim_bkt *bktp)
+{
+ __atomic_fetch_sub(&bktp->lock, 1, __ATOMIC_RELAXED);
}
static inline uint32_t
@@ -246,22 +252,20 @@ tim_add_entry_sp(struct otx2_tim_ring * const tim_ring,
if (tim_bkt_get_nent(lock_sema) != 0) {
uint64_t hbt_state;
#ifdef RTE_ARCH_ARM64
- asm volatile(
- " ldaxr %[hbt], [%[w1]] \n"
- " tbz %[hbt], 33, dne%= \n"
- " sevl \n"
- "rty%=: wfe \n"
- " ldaxr %[hbt], [%[w1]] \n"
- " tbnz %[hbt], 33, rty%= \n"
- "dne%=: \n"
- : [hbt] "=&r" (hbt_state)
- : [w1] "r" ((&bkt->w1))
- : "memory"
- );
+ asm volatile(" ldxr %[hbt], [%[w1]] \n"
+ " tbz %[hbt], 33, dne%= \n"
+ " sevl \n"
+ "rty%=: wfe \n"
+ " ldxr %[hbt], [%[w1]] \n"
+ " tbnz %[hbt], 33, rty%= \n"
+ "dne%=: \n"
+ : [hbt] "=&r"(hbt_state)
+ : [w1] "r"((&bkt->w1))
+ : "memory");
#else
do {
hbt_state = __atomic_load_n(&bkt->w1,
- __ATOMIC_ACQUIRE);
+ __ATOMIC_RELAXED);
} while (hbt_state & BIT_ULL(33));
#endif
@@ -282,10 +286,10 @@ tim_add_entry_sp(struct otx2_tim_ring * const tim_ring,
if (unlikely(chunk == NULL)) {
bkt->chunk_remainder = 0;
- tim_bkt_dec_lock(bkt);
tim->impl_opaque[0] = 0;
tim->impl_opaque[1] = 0;
tim->state = RTE_EVENT_TIMER_ERROR;
+ tim_bkt_dec_lock(bkt);
return -ENOMEM;
}
mirr_bkt->current_chunk = (uintptr_t)chunk;
@@ -298,12 +302,11 @@ tim_add_entry_sp(struct otx2_tim_ring * const tim_ring,
/* Copy work entry. */
*chunk = *pent;
- tim_bkt_inc_nent(bkt);
- tim_bkt_dec_lock(bkt);
-
tim->impl_opaque[0] = (uintptr_t)chunk;
tim->impl_opaque[1] = (uintptr_t)bkt;
- tim->state = RTE_EVENT_TIMER_ARMED;
+ __atomic_store_n(&tim->state, RTE_EVENT_TIMER_ARMED, __ATOMIC_RELEASE);
+ tim_bkt_inc_nent(bkt);
+ tim_bkt_dec_lock_relaxed(bkt);
return 0;
}
@@ -331,22 +334,20 @@ tim_add_entry_mp(struct otx2_tim_ring * const tim_ring,
if (tim_bkt_get_nent(lock_sema) != 0) {
uint64_t hbt_state;
#ifdef RTE_ARCH_ARM64
- asm volatile(
- " ldaxr %[hbt], [%[w1]] \n"
- " tbz %[hbt], 33, dne%= \n"
- " sevl \n"
- "rty%=: wfe \n"
- " ldaxr %[hbt], [%[w1]] \n"
- " tbnz %[hbt], 33, rty%= \n"
- "dne%=: \n"
- : [hbt] "=&r" (hbt_state)
- : [w1] "r" ((&bkt->w1))
- : "memory"
- );
+ asm volatile(" ldxr %[hbt], [%[w1]] \n"
+ " tbz %[hbt], 33, dne%= \n"
+ " sevl \n"
+ "rty%=: wfe \n"
+ " ldxr %[hbt], [%[w1]] \n"
+ " tbnz %[hbt], 33, rty%= \n"
+ "dne%=: \n"
+ : [hbt] "=&r"(hbt_state)
+ : [w1] "r"((&bkt->w1))
+ : "memory");
#else
do {
hbt_state = __atomic_load_n(&bkt->w1,
- __ATOMIC_ACQUIRE);
+ __ATOMIC_RELAXED);
} while (hbt_state & BIT_ULL(33));
#endif
@@ -359,26 +360,23 @@ tim_add_entry_mp(struct otx2_tim_ring * const tim_ring,
rem = tim_bkt_fetch_rem(lock_sema);
if (rem < 0) {
+ tim_bkt_dec_lock(bkt);
#ifdef RTE_ARCH_ARM64
- asm volatile(
- " ldaxrh %w[rem], [%[crem]] \n"
- " tbz %w[rem], 15, dne%= \n"
- " sevl \n"
- "rty%=: wfe \n"
- " ldaxrh %w[rem], [%[crem]] \n"
- " tbnz %w[rem], 15, rty%= \n"
- "dne%=: \n"
- : [rem] "=&r" (rem)
- : [crem] "r" (&bkt->chunk_remainder)
- : "memory"
- );
+ asm volatile(" ldxr %[rem], [%[crem]] \n"
+ " tbz %[rem], 63, dne%= \n"
+ " sevl \n"
+ "rty%=: wfe \n"
+ " ldxr %[rem], [%[crem]] \n"
+ " tbnz %[rem], 63, rty%= \n"
+ "dne%=: \n"
+ : [rem] "=&r"(rem)
+ : [crem] "r"(&bkt->w1)
+ : "memory");
#else
- while (__atomic_load_n(&bkt->chunk_remainder,
- __ATOMIC_ACQUIRE) < 0)
+ while (__atomic_load_n((int64_t *)&bkt->w1, __ATOMIC_RELAXED) <
+ 0)
;
#endif
- /* Goto diff bucket. */
- tim_bkt_dec_lock(bkt);
goto __retry;
} else if (!rem) {
/* Only one thread can be here*/
@@ -388,18 +386,21 @@ tim_add_entry_mp(struct otx2_tim_ring * const tim_ring,
chunk = tim_insert_chunk(bkt, mirr_bkt, tim_ring);
if (unlikely(chunk == NULL)) {
- tim_bkt_set_rem(bkt, 0);
- tim_bkt_dec_lock(bkt);
tim->impl_opaque[0] = 0;
tim->impl_opaque[1] = 0;
tim->state = RTE_EVENT_TIMER_ERROR;
+ tim_bkt_set_rem(bkt, 0);
+ tim_bkt_dec_lock(bkt);
return -ENOMEM;
}
*chunk = *pent;
- while (tim_bkt_fetch_lock(lock_sema) !=
- (-tim_bkt_fetch_rem(lock_sema)))
- lock_sema = __atomic_load_n(&bkt->w1, __ATOMIC_ACQUIRE);
-
+ if (tim_bkt_fetch_lock(lock_sema)) {
+ do {
+ lock_sema = __atomic_load_n(&bkt->w1,
+ __ATOMIC_RELAXED);
+ } while (tim_bkt_fetch_lock(lock_sema) - 1);
+ rte_atomic_thread_fence(__ATOMIC_ACQUIRE);
+ }
mirr_bkt->current_chunk = (uintptr_t)chunk;
__atomic_store_n(&bkt->chunk_remainder,
tim_ring->nb_chunk_slots - 1, __ATOMIC_RELEASE);
@@ -409,12 +410,11 @@ tim_add_entry_mp(struct otx2_tim_ring * const tim_ring,
*chunk = *pent;
}
- /* Copy work entry. */
- tim_bkt_inc_nent(bkt);
- tim_bkt_dec_lock(bkt);
tim->impl_opaque[0] = (uintptr_t)chunk;
tim->impl_opaque[1] = (uintptr_t)bkt;
- tim->state = RTE_EVENT_TIMER_ARMED;
+ __atomic_store_n(&tim->state, RTE_EVENT_TIMER_ARMED, __ATOMIC_RELEASE);
+ tim_bkt_inc_nent(bkt);
+ tim_bkt_dec_lock_relaxed(bkt);
return 0;
}
@@ -463,6 +463,23 @@ tim_add_entry_brst(struct otx2_tim_ring * const tim_ring,
if (lock_cnt) {
tim_bkt_dec_lock(bkt);
+#ifdef RTE_ARCH_ARM64
+ asm volatile(" ldxrb %w[lock_cnt], [%[lock]] \n"
+ " tst %w[lock_cnt], 255 \n"
+ " beq dne%= \n"
+ " sevl \n"
+ "rty%=: wfe \n"
+ " ldxrb %w[lock_cnt], [%[lock]] \n"
+ " tst %w[lock_cnt], 255 \n"
+ " bne rty%= \n"
+ "dne%=: \n"
+ : [lock_cnt] "=&r"(lock_cnt)
+ : [lock] "r"(&bkt->lock)
+ : "memory");
+#else
+ while (__atomic_load_n(&bkt->lock, __ATOMIC_RELAXED))
+ ;
+#endif
goto __retry;
}
@@ -471,22 +488,20 @@ tim_add_entry_brst(struct otx2_tim_ring * const tim_ring,
if (tim_bkt_get_nent(lock_sema) != 0) {
uint64_t hbt_state;
#ifdef RTE_ARCH_ARM64
- asm volatile(
- " ldaxr %[hbt], [%[w1]] \n"
- " tbz %[hbt], 33, dne%= \n"
- " sevl \n"
- "rty%=: wfe \n"
- " ldaxr %[hbt], [%[w1]] \n"
- " tbnz %[hbt], 33, rty%= \n"
- "dne%=: \n"
- : [hbt] "=&r" (hbt_state)
- : [w1] "r" ((&bkt->w1))
- : "memory"
- );
+ asm volatile(" ldxr %[hbt], [%[w1]] \n"
+ " tbz %[hbt], 33, dne%= \n"
+ " sevl \n"
+ "rty%=: wfe \n"
+ " ldxr %[hbt], [%[w1]] \n"
+ " tbnz %[hbt], 33, rty%= \n"
+ "dne%=: \n"
+ : [hbt] "=&r"(hbt_state)
+ : [w1] "r"((&bkt->w1))
+ : "memory");
#else
do {
hbt_state = __atomic_load_n(&bkt->w1,
- __ATOMIC_ACQUIRE);
+ __ATOMIC_RELAXED);
} while (hbt_state & BIT_ULL(33));
#endif
@@ -563,19 +578,18 @@ tim_rm_entry(struct rte_event_timer *tim)
bkt = (struct otx2_tim_bkt *)(uintptr_t)tim->impl_opaque[1];
lock_sema = tim_bkt_inc_lock(bkt);
if (tim_bkt_get_hbt(lock_sema) || !tim_bkt_get_nent(lock_sema)) {
- tim_bkt_dec_lock(bkt);
tim->impl_opaque[0] = 0;
tim->impl_opaque[1] = 0;
+ tim_bkt_dec_lock(bkt);
return -ENOENT;
}
entry->w0 = 0;
entry->wqe = 0;
- tim_bkt_dec_lock(bkt);
-
tim->state = RTE_EVENT_TIMER_CANCELED;
tim->impl_opaque[0] = 0;
tim->impl_opaque[1] = 0;
+ tim_bkt_dec_lock(bkt);
return 0;
}