256 lines
7.5 KiB
C
256 lines
7.5 KiB
C
/* Copyright (c) 2018, The Tor Project, Inc. */
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/* See LICENSE for licensing information */
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/**
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* \file token_bucket.c
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* \brief Functions to use and manipulate token buckets, used for
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* rate-limiting on connections and globally.
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*
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* Tor uses these token buckets to keep track of bandwidth usage, and
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* sometimes other things too.
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*
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* There are two layers of abstraction here: "raw" token buckets, in which all
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* the pieces are decoupled, and "read-write" token buckets, which combine all
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* the moving parts into one.
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*
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* Token buckets may become negative.
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**/
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#define TOKEN_BUCKET_PRIVATE
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#include "token_bucket.h"
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#include "util_bug.h"
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/**
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* Set the <b>rate</b> and <b>burst</b> value in a token_bucket_cfg.
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*
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* Note that the <b>rate</b> value is in arbitrary units, but those units will
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* determine the units of token_bucket_raw_dec(), token_bucket_raw_refill, and
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* so on.
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*/
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void
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token_bucket_cfg_init(token_bucket_cfg_t *cfg,
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uint32_t rate,
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uint32_t burst)
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{
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tor_assert_nonfatal(rate > 0);
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tor_assert_nonfatal(burst > 0);
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if (burst > TOKEN_BUCKET_MAX_BURST)
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burst = TOKEN_BUCKET_MAX_BURST;
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cfg->rate = rate;
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cfg->burst = burst;
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}
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/**
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* Initialize a raw token bucket and its associated timestamp to the "full"
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* state, according to <b>cfg</b>.
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*/
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void
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token_bucket_raw_reset(token_bucket_raw_t *bucket,
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const token_bucket_cfg_t *cfg)
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{
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bucket->bucket = cfg->burst;
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}
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/**
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* Adust a preexisting token bucket to respect the new configuration
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* <b>cfg</b>, by decreasing its current level if needed. */
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void
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token_bucket_raw_adjust(token_bucket_raw_t *bucket,
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const token_bucket_cfg_t *cfg)
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{
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bucket->bucket = MIN(bucket->bucket, cfg->burst);
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}
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/**
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* Given an amount of <b>elapsed</b> time units, and a bucket configuration
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* <b>cfg</b>, refill the level of <b>bucket</b> accordingly. Note that the
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* units of time in <b>elapsed</b> must correspond to those used to set the
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* rate in <b>cfg</b>, or the result will be illogical.
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*/
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int
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token_bucket_raw_refill_steps(token_bucket_raw_t *bucket,
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const token_bucket_cfg_t *cfg,
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const uint32_t elapsed)
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{
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const int was_empty = (bucket->bucket <= 0);
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/* The casts here prevent an underflow.
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*
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* Note that even if the bucket value is negative, subtracting it from
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* "burst" will still produce a correct result. If this result is
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* ridiculously high, then the "elapsed > gap / rate" check below
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* should catch it. */
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const size_t gap = ((size_t)cfg->burst) - ((size_t)bucket->bucket);
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if (elapsed > gap / cfg->rate) {
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bucket->bucket = cfg->burst;
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} else {
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bucket->bucket += cfg->rate * elapsed;
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}
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return was_empty && bucket->bucket > 0;
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}
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/**
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* Decrement a provided bucket by <b>n</b> units. Note that <b>n</b>
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* must be nonnegative.
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*/
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int
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token_bucket_raw_dec(token_bucket_raw_t *bucket,
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ssize_t n)
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{
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if (BUG(n < 0))
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return 0;
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const int becomes_empty = bucket->bucket > 0 && n >= bucket->bucket;
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bucket->bucket -= n;
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return becomes_empty;
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}
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/** Convert a rate in bytes per second to a rate in bytes per step */
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STATIC uint32_t
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rate_per_sec_to_rate_per_step(uint32_t rate)
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{
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/*
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The precise calculation we'd want to do is
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(rate / 1000) * to_approximate_msec(TICKS_PER_STEP). But to minimize
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rounding error, we do it this way instead, and divide last.
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*/
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uint64_t units = (uint64_t) rate * TICKS_PER_STEP;
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uint32_t val = (uint32_t)
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(monotime_coarse_stamp_units_to_approx_msec(units) / 1000);
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return val ? val : 1;
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}
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/**
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* Initialize a token bucket in *<b>bucket</b>, set up to allow <b>rate</b>
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* bytes per second, with a maximum burst of <b>burst</b> bytes. The bucket
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* is created such that <b>now_ts</b> is the current timestamp. The bucket
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* starts out full.
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*/
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void
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token_bucket_rw_init(token_bucket_rw_t *bucket,
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uint32_t rate,
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uint32_t burst,
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uint32_t now_ts)
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{
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memset(bucket, 0, sizeof(token_bucket_rw_t));
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token_bucket_rw_adjust(bucket, rate, burst);
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token_bucket_rw_reset(bucket, now_ts);
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}
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/**
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* Change the configured rate (in bytes per second) and burst (in bytes)
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* for the token bucket in *<b>bucket</b>.
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*/
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void
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token_bucket_rw_adjust(token_bucket_rw_t *bucket,
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uint32_t rate,
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uint32_t burst)
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{
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token_bucket_cfg_init(&bucket->cfg,
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rate_per_sec_to_rate_per_step(rate),
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burst);
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token_bucket_raw_adjust(&bucket->read_bucket, &bucket->cfg);
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token_bucket_raw_adjust(&bucket->write_bucket, &bucket->cfg);
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}
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/**
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* Reset <b>bucket</b> to be full, as of timestamp <b>now_ts</b>.
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*/
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void
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token_bucket_rw_reset(token_bucket_rw_t *bucket,
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uint32_t now_ts)
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{
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token_bucket_raw_reset(&bucket->read_bucket, &bucket->cfg);
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token_bucket_raw_reset(&bucket->write_bucket, &bucket->cfg);
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bucket->last_refilled_at_timestamp = now_ts;
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}
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/**
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* Refill <b>bucket</b> as appropriate, given that the current timestamp
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* is <b>now_ts</b>.
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*
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* Return a bitmask containing TB_READ iff read bucket was empty and became
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* nonempty, and TB_WRITE iff the write bucket was empty and became nonempty.
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*/
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int
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token_bucket_rw_refill(token_bucket_rw_t *bucket,
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uint32_t now_ts)
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{
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const uint32_t elapsed_ticks =
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(now_ts - bucket->last_refilled_at_timestamp);
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if (elapsed_ticks > UINT32_MAX-(300*1000)) {
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/* Either about 48 days have passed since the last refill, or the
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* monotonic clock has somehow moved backwards. (We're looking at you,
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* Windows.). We accept up to a 5 minute jump backwards as
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* "unremarkable".
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*/
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return 0;
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}
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const uint32_t elapsed_steps = elapsed_ticks / TICKS_PER_STEP;
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if (!elapsed_steps) {
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/* Note that if less than one whole step elapsed, we don't advance the
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* time in last_refilled_at. That's intentional: we want to make sure
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* that we add some bytes to it eventually. */
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return 0;
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}
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int flags = 0;
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if (token_bucket_raw_refill_steps(&bucket->read_bucket,
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&bucket->cfg, elapsed_steps))
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flags |= TB_READ;
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if (token_bucket_raw_refill_steps(&bucket->write_bucket,
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&bucket->cfg, elapsed_steps))
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flags |= TB_WRITE;
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bucket->last_refilled_at_timestamp = now_ts;
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return flags;
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}
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/**
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* Decrement the read token bucket in <b>bucket</b> by <b>n</b> bytes.
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*
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* Return true if the bucket was nonempty and became empty; return false
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* otherwise.
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*/
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int
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token_bucket_rw_dec_read(token_bucket_rw_t *bucket,
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ssize_t n)
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{
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return token_bucket_raw_dec(&bucket->read_bucket, n);
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}
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/**
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* Decrement the write token bucket in <b>bucket</b> by <b>n</b> bytes.
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*
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* Return true if the bucket was nonempty and became empty; return false
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* otherwise.
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*/
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int
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token_bucket_rw_dec_write(token_bucket_rw_t *bucket,
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ssize_t n)
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{
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return token_bucket_raw_dec(&bucket->write_bucket, n);
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}
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/**
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* As token_bucket_rw_dec_read and token_bucket_rw_dec_write, in a single
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* operation. Return a bitmask of TB_READ and TB_WRITE to indicate
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* which buckets became empty.
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*/
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int
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token_bucket_rw_dec(token_bucket_rw_t *bucket,
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ssize_t n_read, ssize_t n_written)
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{
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int flags = 0;
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if (token_bucket_rw_dec_read(bucket, n_read))
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flags |= TB_READ;
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if (token_bucket_rw_dec_write(bucket, n_written))
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flags |= TB_WRITE;
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return flags;
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}
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