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e0ce98d57c
Previous code used 4 atomics to do aggsum_flush_bucket() and 2 more to re-borrow after the flush. But since asc_borrowed and asc_delta are accessed only while holding asc_lock, it makes no any sense to modify as_lower_bound and as_upper_bound in multiple steps. Instead of that the new code uses only 2 atomics in all the cases, one per as_*_bound variable. I think even that is overkill, simple atomic store and load could be used here, since all modifications are done under the as_lock, but there are no such primitives in ZFS code now. While there, make borrow code consider previous borrow value, so that on mixed request patterns reduce chance of needing to borrow again if much larger request follows tiny one that needed borrow. Also reduce as_numbuckets from uint64_t to u_int. It makes no sense to use so large division operation on every aggsum_add(). Reviewed-by: Brian Behlendorf <behlendorf1@llnl.gov> Reviewed-by: Paul Dagnelie <pcd@delphix.com> Signed-off-by: Alexander Motin <mav@FreeBSD.org> Sponsored-By: iXsystems, Inc. Closes #9930
238 lines
8.2 KiB
C
238 lines
8.2 KiB
C
/*
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* CDDL HEADER START
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*
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* This file and its contents are supplied under the terms of the
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* Common Development and Distribution License ("CDDL"), version 1.0.
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* You may only use this file in accordance with the terms of version
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* 1.0 of the CDDL.
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*
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* A full copy of the text of the CDDL should have accompanied this
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* source. A copy of the CDDL is also available via the Internet at
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* http://www.illumos.org/license/CDDL.
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*
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* CDDL HEADER END
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*/
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/*
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* Copyright (c) 2017, 2018 by Delphix. All rights reserved.
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*/
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#include <sys/zfs_context.h>
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#include <sys/aggsum.h>
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/*
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* Aggregate-sum counters are a form of fanned-out counter, used when atomic
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* instructions on a single field cause enough CPU cache line contention to
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* slow system performance. Due to their increased overhead and the expense
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* involved with precisely reading from them, they should only be used in cases
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* where the write rate (increment/decrement) is much higher than the read rate
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* (get value).
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*
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* Aggregate sum counters are comprised of two basic parts, the core and the
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* buckets. The core counter contains a lock for the entire counter, as well
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* as the current upper and lower bounds on the value of the counter. The
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* aggsum_bucket structure contains a per-bucket lock to protect the contents of
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* the bucket, the current amount that this bucket has changed from the global
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* counter (called the delta), and the amount of increment and decrement we have
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* "borrowed" from the core counter.
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*
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* The basic operation of an aggsum is simple. Threads that wish to modify the
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* counter will modify one bucket's counter (determined by their current CPU, to
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* help minimize lock and cache contention). If the bucket already has
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* sufficient capacity borrowed from the core structure to handle their request,
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* they simply modify the delta and return. If the bucket does not, we clear
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* the bucket's current state (to prevent the borrowed amounts from getting too
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* large), and borrow more from the core counter. Borrowing is done by adding to
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* the upper bound (or subtracting from the lower bound) of the core counter,
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* and setting the borrow value for the bucket to the amount added (or
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* subtracted). Clearing the bucket is the opposite; we add the current delta
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* to both the lower and upper bounds of the core counter, subtract the borrowed
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* incremental from the upper bound, and add the borrowed decrement from the
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* lower bound. Note that only borrowing and clearing require access to the
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* core counter; since all other operations access CPU-local resources,
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* performance can be much higher than a traditional counter.
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*
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* Threads that wish to read from the counter have a slightly more challenging
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* task. It is fast to determine the upper and lower bounds of the aggum; this
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* does not require grabbing any locks. This suffices for cases where an
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* approximation of the aggsum's value is acceptable. However, if one needs to
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* know whether some specific value is above or below the current value in the
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* aggsum, they invoke aggsum_compare(). This function operates by repeatedly
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* comparing the target value to the upper and lower bounds of the aggsum, and
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* then clearing a bucket. This proceeds until the target is outside of the
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* upper and lower bounds and we return a response, or the last bucket has been
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* cleared and we know that the target is equal to the aggsum's value. Finally,
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* the most expensive operation is determining the precise value of the aggsum.
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* To do this, we clear every bucket and then return the upper bound (which must
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* be equal to the lower bound). What makes aggsum_compare() and aggsum_value()
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* expensive is clearing buckets. This involves grabbing the global lock
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* (serializing against themselves and borrow operations), grabbing a bucket's
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* lock (preventing threads on those CPUs from modifying their delta), and
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* zeroing out the borrowed value (forcing that thread to borrow on its next
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* request, which will also be expensive). This is what makes aggsums well
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* suited for write-many read-rarely operations.
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*/
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/*
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* We will borrow aggsum_borrow_multiplier times the current request, so we will
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* have to get the as_lock approximately every aggsum_borrow_multiplier calls to
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* aggsum_delta().
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*/
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static uint_t aggsum_borrow_multiplier = 10;
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void
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aggsum_init(aggsum_t *as, uint64_t value)
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{
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bzero(as, sizeof (*as));
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as->as_lower_bound = as->as_upper_bound = value;
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mutex_init(&as->as_lock, NULL, MUTEX_DEFAULT, NULL);
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as->as_numbuckets = boot_ncpus;
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as->as_buckets = kmem_zalloc(boot_ncpus * sizeof (aggsum_bucket_t),
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KM_SLEEP);
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for (int i = 0; i < as->as_numbuckets; i++) {
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mutex_init(&as->as_buckets[i].asc_lock,
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NULL, MUTEX_DEFAULT, NULL);
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}
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}
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void
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aggsum_fini(aggsum_t *as)
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{
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for (int i = 0; i < as->as_numbuckets; i++)
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mutex_destroy(&as->as_buckets[i].asc_lock);
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kmem_free(as->as_buckets, as->as_numbuckets * sizeof (aggsum_bucket_t));
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mutex_destroy(&as->as_lock);
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}
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int64_t
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aggsum_lower_bound(aggsum_t *as)
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{
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return (as->as_lower_bound);
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}
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int64_t
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aggsum_upper_bound(aggsum_t *as)
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{
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return (as->as_upper_bound);
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}
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static void
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aggsum_flush_bucket(aggsum_t *as, struct aggsum_bucket *asb)
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{
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ASSERT(MUTEX_HELD(&as->as_lock));
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ASSERT(MUTEX_HELD(&asb->asc_lock));
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/*
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* We use atomic instructions for this because we read the upper and
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* lower bounds without the lock, so we need stores to be atomic.
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*/
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atomic_add_64((volatile uint64_t *)&as->as_lower_bound,
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asb->asc_delta + asb->asc_borrowed);
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atomic_add_64((volatile uint64_t *)&as->as_upper_bound,
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asb->asc_delta - asb->asc_borrowed);
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asb->asc_delta = 0;
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asb->asc_borrowed = 0;
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}
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uint64_t
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aggsum_value(aggsum_t *as)
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{
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int64_t rv;
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mutex_enter(&as->as_lock);
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if (as->as_lower_bound == as->as_upper_bound) {
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rv = as->as_lower_bound;
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for (int i = 0; i < as->as_numbuckets; i++) {
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ASSERT0(as->as_buckets[i].asc_delta);
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ASSERT0(as->as_buckets[i].asc_borrowed);
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}
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mutex_exit(&as->as_lock);
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return (rv);
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}
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for (int i = 0; i < as->as_numbuckets; i++) {
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struct aggsum_bucket *asb = &as->as_buckets[i];
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mutex_enter(&asb->asc_lock);
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aggsum_flush_bucket(as, asb);
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mutex_exit(&asb->asc_lock);
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}
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VERIFY3U(as->as_lower_bound, ==, as->as_upper_bound);
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rv = as->as_lower_bound;
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mutex_exit(&as->as_lock);
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return (rv);
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}
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void
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aggsum_add(aggsum_t *as, int64_t delta)
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{
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struct aggsum_bucket *asb;
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int64_t borrow;
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kpreempt_disable();
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asb = &as->as_buckets[CPU_SEQID % as->as_numbuckets];
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kpreempt_enable();
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/* Try fast path if we already borrowed enough before. */
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mutex_enter(&asb->asc_lock);
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if (asb->asc_delta + delta <= (int64_t)asb->asc_borrowed &&
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asb->asc_delta + delta >= -(int64_t)asb->asc_borrowed) {
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asb->asc_delta += delta;
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mutex_exit(&asb->asc_lock);
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return;
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}
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mutex_exit(&asb->asc_lock);
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/*
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* We haven't borrowed enough. Take the global lock and borrow
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* considering what is requested now and what we borrowed before.
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*/
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borrow = (delta < 0 ? -delta : delta) * aggsum_borrow_multiplier;
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mutex_enter(&as->as_lock);
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mutex_enter(&asb->asc_lock);
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delta += asb->asc_delta;
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asb->asc_delta = 0;
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if (borrow >= asb->asc_borrowed)
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borrow -= asb->asc_borrowed;
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else
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borrow = (borrow - (int64_t)asb->asc_borrowed) / 4;
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asb->asc_borrowed += borrow;
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atomic_add_64((volatile uint64_t *)&as->as_lower_bound,
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delta - borrow);
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atomic_add_64((volatile uint64_t *)&as->as_upper_bound,
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delta + borrow);
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mutex_exit(&asb->asc_lock);
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mutex_exit(&as->as_lock);
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}
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/*
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* Compare the aggsum value to target efficiently. Returns -1 if the value
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* represented by the aggsum is less than target, 1 if it's greater, and 0 if
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* they are equal.
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*/
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int
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aggsum_compare(aggsum_t *as, uint64_t target)
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{
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if (as->as_upper_bound < target)
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return (-1);
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if (as->as_lower_bound > target)
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return (1);
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mutex_enter(&as->as_lock);
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for (int i = 0; i < as->as_numbuckets; i++) {
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struct aggsum_bucket *asb = &as->as_buckets[i];
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mutex_enter(&asb->asc_lock);
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aggsum_flush_bucket(as, asb);
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mutex_exit(&asb->asc_lock);
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if (as->as_upper_bound < target) {
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mutex_exit(&as->as_lock);
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return (-1);
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}
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if (as->as_lower_bound > target) {
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mutex_exit(&as->as_lock);
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return (1);
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}
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}
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VERIFY3U(as->as_lower_bound, ==, as->as_upper_bound);
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ASSERT3U(as->as_lower_bound, ==, target);
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mutex_exit(&as->as_lock);
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return (0);
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}
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