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1 /*
2 * CDDL HEADER START
3 *
4 * This file and its contents are supplied under the terms of the
5 * Common Development and Distribution License ("CDDL"), version 1.0.
6 * You may only use this file in accordance with the terms of version
7 * 1.0 of the CDDL.
8 *
9 * A full copy of the text of the CDDL should have accompanied this
10 * source. A copy of the CDDL is also available via the Internet at
11 * http://www.illumos.org/license/CDDL.
12 *
13 * CDDL HEADER END
14 */
15 /*
16 * Copyright (c) 2017, 2018 by Delphix. All rights reserved.
17 */
19 #include <sys/zfs_context.h>
20 #include <sys/aggsum.h>
22 /*
23 * Aggregate-sum counters are a form of fanned-out counter, used when atomic
24 * instructions on a single field cause enough CPU cache line contention to
25 * slow system performance. Due to their increased overhead and the expense
26 * involved with precisely reading from them, they should only be used in cases
27 * where the write rate (increment/decrement) is much higher than the read rate
28 * (get value).
29 *
30 * Aggregate sum counters are comprised of two basic parts, the core and the
31 * buckets. The core counter contains a lock for the entire counter, as well
32 * as the current upper and lower bounds on the value of the counter. The
33 * aggsum_bucket structure contains a per-bucket lock to protect the contents of
34 * the bucket, the current amount that this bucket has changed from the global
35 * counter (called the delta), and the amount of increment and decrement we have
36 * "borrowed" from the core counter.
37 *
38 * The basic operation of an aggsum is simple. Threads that wish to modify the
39 * counter will modify one bucket's counter (determined by their current CPU, to
40 * help minimize lock and cache contention). If the bucket already has
41 * sufficient capacity borrowed from the core structure to handle their request,
42 * they simply modify the delta and return. If the bucket does not, we clear
43 * the bucket's current state (to prevent the borrowed amounts from getting too
44 * large), and borrow more from the core counter. Borrowing is done by adding to
45 * the upper bound (or subtracting from the lower bound) of the core counter,
46 * and setting the borrow value for the bucket to the amount added (or
47 * subtracted). Clearing the bucket is the opposite; we add the current delta
48 * to both the lower and upper bounds of the core counter, subtract the borrowed
49 * incremental from the upper bound, and add the borrowed decrement from the
50 * lower bound. Note that only borrowing and clearing require access to the
51 * core counter; since all other operations access CPU-local resources,
52 * performance can be much higher than a traditional counter.
53 *
54 * Threads that wish to read from the counter have a slightly more challenging
55 * task. It is fast to determine the upper and lower bounds of the aggum; this
56 * does not require grabbing any locks. This suffices for cases where an
57 * approximation of the aggsum's value is acceptable. However, if one needs to
58 * know whether some specific value is above or below the current value in the
59 * aggsum, they invoke aggsum_compare(). This function operates by repeatedly
60 * comparing the target value to the upper and lower bounds of the aggsum, and
61 * then clearing a bucket. This proceeds until the target is outside of the
62 * upper and lower bounds and we return a response, or the last bucket has been
63 * cleared and we know that the target is equal to the aggsum's value. Finally,
64 * the most expensive operation is determining the precise value of the aggsum.
65 * To do this, we clear every bucket and then return the upper bound (which must
66 * be equal to the lower bound). What makes aggsum_compare() and aggsum_value()
67 * expensive is clearing buckets. This involves grabbing the global lock
68 * (serializing against themselves and borrow operations), grabbing a bucket's
69 * lock (preventing threads on those CPUs from modifying their delta), and
70 * zeroing out the borrowed value (forcing that thread to borrow on its next
71 * request, which will also be expensive). This is what makes aggsums well
72 * suited for write-many read-rarely operations.
73 *
74 * Note that the aggsums do not expand if more CPUs are hot-added. In that
75 * case, we will have less fanout than boot_ncpus, but we don't want to always
76 * reserve the RAM necessary to create the extra slots for additional CPUs up
77 * front, and dynamically adding them is a complex task.
78 */
80 /*
81 * We will borrow 2^aggsum_borrow_shift times the current request, so we will
82 * have to get the as_lock approximately every 2^aggsum_borrow_shift calls to
83 * aggsum_add().
84 */
87 void
89 {
93 /*
94 * Too many buckets may hurt read performance without improving
95 * write. From 12 CPUs use bucket per 2 CPUs, from 48 per 4, etc.
96 */
104 }
105 }
107 void
109 {
114 }
116 int64_t
118 {
120 }
122 uint64_t
124 {
126 }
128 uint64_t
130 {
141 }
144 }
155 }
162 }
164 void
166 {
173 /* Try fast path if we already borrowed enough before. */
180 }
183 /*
184 * We haven't borrowed enough. Take the global lock and borrow
185 * considering what is requested now and what we borrowed before.
186 */
192 else
204 }
206 /*
207 * Compare the aggsum value to target efficiently. Returns -1 if the value
208 * represented by the aggsum is less than target, 1 if it's greater, and 0 if
209 * they are equal.
210 */
211 int
213 {
238 }
245 }