mirror of
https://github.com/schoebel/mars
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210 lines
5.9 KiB
C
210 lines
5.9 KiB
C
/*
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* MARS Long Distance Replication Software
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*
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* This file is part of MARS project: http://schoebel.github.io/mars/
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*
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* Copyright (C) 2010-2014 Thomas Schoebel-Theuer
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* Copyright (C) 2011-2014 1&1 Internet AG
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*
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* This program is free software; you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation; either version 2 of the License, or
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* (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License along
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* with this program; if not, write to the Free Software Foundation, Inc.,
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* 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
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*/
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#include "lib_limiter.h"
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#include "lamport.h"
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#include <linux/kernel.h>
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#include <linux/module.h>
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/* For precisions, _internal_ time is in multiples of the following basic time units */
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#define LIMITER_TIME_RESOLUTION NSEC_PER_SEC
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#define DEFAULT_MIN_WINDOW (LIMITER_TIME_RESOLUTION * 1)
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#define DEFAULT_MAX_WINDOW (LIMITER_TIME_RESOLUTION * 4)
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#define MIN_DIVIDER (DEFAULT_MIN_WINDOW / 10)
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#define MAX_DIVIDER (DEFAULT_MAX_WINDOW * 10)
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#define CLAMP_WINDOW(x) \
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(x) < MIN_DIVIDER ? MIN_DIVIDER : \
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(x) > MAX_DIVIDER ? MAX_DIVIDER : \
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(x)
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#define MS_TO_TR(x) ((__s64)(x) * (LIMITER_TIME_RESOLUTION / 1000))
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#define TR_TO_MS(x) ((x) / (LIMITER_TIME_RESOLUTION / 1000))
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int mars_limit(struct mars_limiter *lim, int amount)
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{
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int delay = 0;
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struct lamport_time now;
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if (unlikely(amount < 0))
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amount = 0;
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get_real_lamport(&now);
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/* Compute the maximum delay along the path
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* down to the root of the hierarchy tree.
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*/
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while (lim != NULL) {
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struct lamport_time diff = lamport_time_sub(now, lim->lim_stamp);
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__s64 window = lamport_time_to_ns(&diff);
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__s64 rate_raw;
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int rate;
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int max_rate;
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/* Sometimes, raw CPU clocks may do weired things...
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* Small windows in the denominator could fake unrealistic rates.
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* Do not divide by too small numbers.
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*/
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window = CLAMP_WINDOW(window);
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if (unlikely(lim->lim_min_window_ms <= TR_TO_MS(MAX_DIVIDER)))
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lim->lim_min_window_ms = TR_TO_MS(DEFAULT_MIN_WINDOW);
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if (unlikely(lim->lim_max_window_ms <= lim->lim_min_window_ms))
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lim->lim_max_window_ms = lim->lim_min_window_ms + TR_TO_MS(DEFAULT_MAX_WINDOW);
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/* Update total statistics.
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* They will intentionally wrap around.
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* Userspace must take care of that.
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*/
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if (likely(amount > 0)) {
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lim->lim_total_amount += amount;
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lim->lim_total_ops++;
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}
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/* Only use incremental accumulation at repeated calls, but
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* never after longer pauses.
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*/
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if (!lim->lim_stamp.tv_sec ||
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window > MS_TO_TR(lim->lim_max_window_ms)) {
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/* reset, start over with new measurement cycle */
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memset(&diff, 0, sizeof(diff));
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lim->lim_stamp = now;
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lim->lim_ops_accu = 0;
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lim->lim_amount_accu = 0;
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lim->lim_ops_rate = 0;
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lim->lim_amount_rate = 0;
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window = MIN_DIVIDER;
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} else {
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__s64 diff_window;
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/* Try to keep the window between min_window and 2 * min_window.
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* We wait until min_window has been exceeded _twice_,
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* and then reduce the window by only 1 * min_window.
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*/
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diff_window = window - MS_TO_TR(lim->lim_min_window_ms);
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if (diff_window > MS_TO_TR(lim->lim_min_window_ms)) {
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__s64 used_up;
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__s64 add_window = 0;
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used_up = lim->lim_amount_accu * diff_window / window;
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if (used_up > 0) {
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add_window = diff_window;
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lim->lim_amount_accu -= used_up;
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if (unlikely(lim->lim_amount_accu < 0))
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lim->lim_amount_accu = 0;
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}
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used_up = lim->lim_ops_accu * diff_window / window;
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if (used_up > 0) {
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if (diff_window > add_window)
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add_window = diff_window;
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lim->lim_ops_accu -= used_up;
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if (unlikely(lim->lim_ops_accu < 0))
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lim->lim_ops_accu = 0;
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}
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if (add_window > 0) {
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lamport_time_add_ns(&lim->lim_stamp, add_window);
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/* recompute the new window */
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diff = lamport_time_sub(now, lim->lim_stamp);
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window = lamport_time_to_ns(&diff);
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window = CLAMP_WINDOW(window);
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}
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}
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}
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/* Races are possible, but taken into account.
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* There is no real harm from rarely lost updates.
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*/
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if (likely(amount > 0)) {
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lim->lim_amount_accu += amount;
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lim->lim_ops_accu++;
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}
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/* compute amount values */
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rate_raw = lim->lim_amount_accu * LIMITER_TIME_RESOLUTION / window;
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rate = rate_raw;
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if (unlikely(rate_raw > INT_MAX)) {
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rate = INT_MAX;
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}
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lim->lim_amount_rate = rate;
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/* amount limit exceeded? */
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max_rate = lim->lim_max_amount_rate;
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if (max_rate > 0 && rate > max_rate) {
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int this_delay = (window * rate / max_rate - window);
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// compute maximum
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if (this_delay > delay && this_delay > 0)
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delay = this_delay;
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}
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/* compute ops values */
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rate_raw = lim->lim_ops_accu * LIMITER_TIME_RESOLUTION / window;
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rate = rate_raw;
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if (unlikely(rate_raw > INT_MAX)) {
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rate = INT_MAX;
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}
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lim->lim_ops_rate = rate;
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/* ops limit exceeded? */
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max_rate = lim->lim_max_ops_rate;
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if (max_rate > 0 && rate > max_rate) {
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int this_delay = (window * rate / max_rate - window);
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// compute maximum
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if (this_delay > delay && this_delay > 0)
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delay = this_delay;
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}
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lim = lim->lim_father;
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}
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return TR_TO_MS(delay);
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}
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void mars_limit_sleep(struct mars_limiter *lim, int amount)
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{
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int sleep = mars_limit(lim, amount);
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if (sleep > 0) {
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if (unlikely(lim->lim_max_delay_ms <= 0))
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lim->lim_max_delay_ms = 1000;
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if (sleep > lim->lim_max_delay_ms)
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sleep = lim->lim_max_delay_ms;
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brick_msleep(sleep);
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}
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}
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void mars_limit_reset(struct mars_limiter *lim)
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{
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if (!lim)
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return;
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memset(&lim->lim_stamp, 0, sizeof(lim->lim_stamp));
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mars_limit(lim, 0);
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}
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