/*- * Copyright (c) 2016-2019 Netflix, Inc. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ /* * Author: Randall Stewart */ #include __FBSDID("$FreeBSD$"); #include #include #include #include void reset_time(struct time_filter *tf, uint32_t time_len) { tf->cur_time_limit = time_len; } void reset_time_small(struct time_filter_small *tf, uint32_t time_len) { tf->cur_time_limit = time_len; } /* * A time filter can be a filter for MIN or MAX. * You call setup_time_filter() with the pointer to * the filter structure, the type (FILTER_TYPE_MIN/MAX) and * the time length. You can optionally reset the time length * later with reset_time(). * * You generally call apply_filter_xxx() to apply the new value * to the filter. You also provide a time (now). The filter will * age out entries based on the time now and your time limit * so that you are always maintaining the min or max in that * window of time. Time is a relative thing, it might be ticks * in milliseconds, it might be round trip times, its really * up to you to decide what it is. * * To access the current flitered value you can use the macro * get_filter_value() which returns the correct entry that * has the "current" value in the filter. * * One thing that used to be here is a single apply_filter(). But * this meant that we then had to store the type of filter in * the time_filter structure. In order to keep it at a cache * line size I split it to two functions. * */ int setup_time_filter(struct time_filter *tf, int fil_type, uint32_t time_len) { uint64_t set_val; int i; /* * You must specify either a MIN or MAX filter, * though its up to the user to use the correct * apply. */ if ((fil_type != FILTER_TYPE_MIN) && (fil_type != FILTER_TYPE_MAX)) return(EINVAL); if (time_len < NUM_FILTER_ENTRIES) return(EINVAL); if (fil_type == FILTER_TYPE_MIN) set_val = 0xffffffffffffffff; else set_val = 0; for(i=0; ientries[i].value = set_val; tf->entries[i].time_up = 0; } tf->cur_time_limit = time_len; return(0); } int setup_time_filter_small(struct time_filter_small *tf, int fil_type, uint32_t time_len) { uint32_t set_val; int i; /* * You must specify either a MIN or MAX filter, * though its up to the user to use the correct * apply. */ if ((fil_type != FILTER_TYPE_MIN) && (fil_type != FILTER_TYPE_MAX)) return(EINVAL); if (time_len < NUM_FILTER_ENTRIES) return(EINVAL); if (fil_type == FILTER_TYPE_MIN) set_val = 0xffffffff; else set_val = 0; for(i=0; ientries[i].value = set_val; tf->entries[i].time_up = 0; } tf->cur_time_limit = time_len; return(0); } static void check_update_times(struct time_filter *tf, uint64_t value, uint32_t now) { int i, j, fnd; uint32_t tim; uint32_t time_limit; for(i=0; i<(NUM_FILTER_ENTRIES-1); i++) { tim = now - tf->entries[i].time_up; time_limit = (tf->cur_time_limit * (NUM_FILTER_ENTRIES-i))/NUM_FILTER_ENTRIES; if (tim >= time_limit) { fnd = 0; for(j=(i+1); jentries[i].time_up < tf->entries[j].time_up) { tf->entries[i].value = tf->entries[j].value; tf->entries[i].time_up = tf->entries[j].time_up; fnd = 1; break; } } if (fnd == 0) { /* Nothing but the same old entry */ tf->entries[i].value = value; tf->entries[i].time_up = now; } } } i = NUM_FILTER_ENTRIES-1; tim = now - tf->entries[i].time_up; time_limit = (tf->cur_time_limit * (NUM_FILTER_ENTRIES-i))/NUM_FILTER_ENTRIES; if (tim >= time_limit) { tf->entries[i].value = value; tf->entries[i].time_up = now; } } static void check_update_times_small(struct time_filter_small *tf, uint32_t value, uint32_t now) { int i, j, fnd; uint32_t tim; uint32_t time_limit; for(i=0; i<(NUM_FILTER_ENTRIES-1); i++) { tim = now - tf->entries[i].time_up; time_limit = (tf->cur_time_limit * (NUM_FILTER_ENTRIES-i))/NUM_FILTER_ENTRIES; if (tim >= time_limit) { fnd = 0; for(j=(i+1); jentries[i].time_up < tf->entries[j].time_up) { tf->entries[i].value = tf->entries[j].value; tf->entries[i].time_up = tf->entries[j].time_up; fnd = 1; break; } } if (fnd == 0) { /* Nothing but the same old entry */ tf->entries[i].value = value; tf->entries[i].time_up = now; } } } i = NUM_FILTER_ENTRIES-1; tim = now - tf->entries[i].time_up; time_limit = (tf->cur_time_limit * (NUM_FILTER_ENTRIES-i))/NUM_FILTER_ENTRIES; if (tim >= time_limit) { tf->entries[i].value = value; tf->entries[i].time_up = now; } } void filter_reduce_by(struct time_filter *tf, uint64_t reduce_by, uint32_t now) { int i; /* * Reduce our filter main by reduce_by and * update its time. Then walk other's and * make them the new value too. */ if (reduce_by < tf->entries[0].value) tf->entries[0].value -= reduce_by; else tf->entries[0].value = 0; tf->entries[0].time_up = now; for(i=1; ientries[i].value = tf->entries[0].value; tf->entries[i].time_up = now; } } void filter_reduce_by_small(struct time_filter_small *tf, uint32_t reduce_by, uint32_t now) { int i; /* * Reduce our filter main by reduce_by and * update its time. Then walk other's and * make them the new value too. */ if (reduce_by < tf->entries[0].value) tf->entries[0].value -= reduce_by; else tf->entries[0].value = 0; tf->entries[0].time_up = now; for(i=1; ientries[i].value = tf->entries[0].value; tf->entries[i].time_up = now; } } void filter_increase_by(struct time_filter *tf, uint64_t incr_by, uint32_t now) { int i; /* * Increase our filter main by incr_by and * update its time. Then walk other's and * make them the new value too. */ tf->entries[0].value += incr_by; tf->entries[0].time_up = now; for(i=1; ientries[i].value = tf->entries[0].value; tf->entries[i].time_up = now; } } void filter_increase_by_small(struct time_filter_small *tf, uint32_t incr_by, uint32_t now) { int i; /* * Increase our filter main by incr_by and * update its time. Then walk other's and * make them the new value too. */ tf->entries[0].value += incr_by; tf->entries[0].time_up = now; for(i=1; ientries[i].value = tf->entries[0].value; tf->entries[i].time_up = now; } } void forward_filter_clock(struct time_filter *tf, uint32_t ticks_forward) { /* * Bring forward all time values by N ticks. This * postpones expiring slots by that amount. */ int i; for(i=0; ientries[i].time_up += ticks_forward; } } void forward_filter_clock_small(struct time_filter_small *tf, uint32_t ticks_forward) { /* * Bring forward all time values by N ticks. This * postpones expiring slots by that amount. */ int i; for(i=0; ientries[i].time_up += ticks_forward; } } void tick_filter_clock(struct time_filter *tf, uint32_t now) { int i; uint32_t tim, time_limit; /* * We start at two positions back. This * is because the oldest worst value is * preserved always, i.e. it can't expire * due to clock ticking with no updated value. * * The other choice would be to fill it in with * zero, but I don't like that option since * some measurement is better than none (even * if its your oldest measurment). */ for(i=(NUM_FILTER_ENTRIES-2); i>=0 ; i--) { tim = now - tf->entries[i].time_up; time_limit = (tf->cur_time_limit * (NUM_FILTER_ENTRIES-i))/NUM_FILTER_ENTRIES; if (tim >= time_limit) { /* * This entry is expired, pull down * the next one up. */ tf->entries[i].value = tf->entries[(i+1)].value; tf->entries[i].time_up = tf->entries[(i+1)].time_up; } } } void tick_filter_clock_small(struct time_filter_small *tf, uint32_t now) { int i; uint32_t tim, time_limit; /* * We start at two positions back. This * is because the oldest worst value is * preserved always, i.e. it can't expire * due to clock ticking with no updated value. * * The other choice would be to fill it in with * zero, but I don't like that option since * some measurement is better than none (even * if its your oldest measurment). */ for(i=(NUM_FILTER_ENTRIES-2); i>=0 ; i--) { tim = now - tf->entries[i].time_up; time_limit = (tf->cur_time_limit * (NUM_FILTER_ENTRIES-i))/NUM_FILTER_ENTRIES; if (tim >= time_limit) { /* * This entry is expired, pull down * the next one up. */ tf->entries[i].value = tf->entries[(i+1)].value; tf->entries[i].time_up = tf->entries[(i+1)].time_up; } } } uint32_t apply_filter_min(struct time_filter *tf, uint64_t value, uint32_t now) { int i, j; if (value <= tf->entries[0].value) { /* Zap them all */ for(i=0; ientries[i].value = value; tf->entries[i].time_up = now; } return (tf->entries[0].value); } for (j=1; jentries[j].value) { for(i=j; ientries[i].value = value; tf->entries[i].time_up = now; } break; } } check_update_times(tf, value, now); return (tf->entries[0].value); } uint32_t apply_filter_min_small(struct time_filter_small *tf, uint32_t value, uint32_t now) { int i, j; if (value <= tf->entries[0].value) { /* Zap them all */ for(i=0; ientries[i].value = value; tf->entries[i].time_up = now; } return (tf->entries[0].value); } for (j=1; jentries[j].value) { for(i=j; ientries[i].value = value; tf->entries[i].time_up = now; } break; } } check_update_times_small(tf, value, now); return (tf->entries[0].value); } uint32_t apply_filter_max(struct time_filter *tf, uint64_t value, uint32_t now) { int i, j; if (value >= tf->entries[0].value) { /* Zap them all */ for(i=0; ientries[i].value = value; tf->entries[i].time_up = now; } return (tf->entries[0].value); } for (j=1; j= tf->entries[j].value) { for(i=j; ientries[i].value = value; tf->entries[i].time_up = now; } break; } } check_update_times(tf, value, now); return (tf->entries[0].value); } uint32_t apply_filter_max_small(struct time_filter_small *tf, uint32_t value, uint32_t now) { int i, j; if (value >= tf->entries[0].value) { /* Zap them all */ for(i=0; ientries[i].value = value; tf->entries[i].time_up = now; } return (tf->entries[0].value); } for (j=1; j= tf->entries[j].value) { for(i=j; ientries[i].value = value; tf->entries[i].time_up = now; } break; } } check_update_times_small(tf, value, now); return (tf->entries[0].value); }