/* SPDX-License-Identifier: GPL-2.0-or-later */ /* * q_sfq.c SFQ. * * Authors: Alexey Kuznetsov, */ #include #include #include #include #include #include #include #include #include #include "utils.h" #include "tc_util.h" #include "tc_red.h" static void explain(void) { fprintf(stderr, "Usage: ... sfq [ limit NUMBER ] [ perturb SECS ] [ quantum BYTES ]\n" " [ divisor NUMBER ] [ flows NUMBER] [ depth NUMBER ]\n" " [ headdrop ]\n" " [ redflowlimit BYTES ] [ min BYTES ] [ max BYTES ]\n" " [ avpkt BYTES ] [ burst PACKETS ] [ probability P ]\n" " [ ecn ] [ harddrop ]\n"); } static int sfq_parse_opt(const struct qdisc_util *qu, int argc, char **argv, struct nlmsghdr *n, const char *dev) { int ok = 0, red = 0; struct tc_sfq_qopt_v1 opt = {}; unsigned int burst = 0; int wlog; unsigned int avpkt = 1000; double probability = 0.02; while (argc > 0) { if (strcmp(*argv, "quantum") == 0) { NEXT_ARG(); if (get_size(&opt.v0.quantum, *argv)) { fprintf(stderr, "Illegal \"limit\"\n"); return -1; } ok++; } else if (strcmp(*argv, "perturb") == 0) { NEXT_ARG(); if (get_integer(&opt.v0.perturb_period, *argv, 0)) { fprintf(stderr, "Illegal \"perturb\"\n"); return -1; } ok++; } else if (strcmp(*argv, "limit") == 0) { NEXT_ARG(); if (get_u32(&opt.v0.limit, *argv, 0)) { fprintf(stderr, "Illegal \"limit\"\n"); return -1; } if (opt.v0.limit < 2) { fprintf(stderr, "Illegal \"limit\", must be > 1\n"); return -1; } ok++; } else if (strcmp(*argv, "divisor") == 0) { NEXT_ARG(); if (get_u32(&opt.v0.divisor, *argv, 0)) { fprintf(stderr, "Illegal \"divisor\"\n"); return -1; } ok++; } else if (strcmp(*argv, "flows") == 0) { NEXT_ARG(); if (get_u32(&opt.v0.flows, *argv, 0)) { fprintf(stderr, "Illegal \"flows\"\n"); return -1; } ok++; } else if (strcmp(*argv, "depth") == 0) { NEXT_ARG(); if (get_u32(&opt.depth, *argv, 0)) { fprintf(stderr, "Illegal \"flows\"\n"); return -1; } ok++; } else if (strcmp(*argv, "headdrop") == 0) { opt.headdrop = 1; ok++; } else if (strcmp(*argv, "redflowlimit") == 0) { NEXT_ARG(); if (get_u32(&opt.limit, *argv, 0)) { fprintf(stderr, "Illegal \"redflowlimit\"\n"); return -1; } red++; } else if (strcmp(*argv, "min") == 0) { NEXT_ARG(); if (get_u32(&opt.qth_min, *argv, 0)) { fprintf(stderr, "Illegal \"min\"\n"); return -1; } red++; } else if (strcmp(*argv, "max") == 0) { NEXT_ARG(); if (get_u32(&opt.qth_max, *argv, 0)) { fprintf(stderr, "Illegal \"max\"\n"); return -1; } red++; } else if (strcmp(*argv, "burst") == 0) { NEXT_ARG(); if (get_unsigned(&burst, *argv, 0)) { fprintf(stderr, "Illegal \"burst\"\n"); return -1; } red++; } else if (strcmp(*argv, "avpkt") == 0) { NEXT_ARG(); if (get_size(&avpkt, *argv)) { fprintf(stderr, "Illegal \"avpkt\"\n"); return -1; } red++; } else if (strcmp(*argv, "probability") == 0) { NEXT_ARG(); if (sscanf(*argv, "%lg", &probability) != 1) { fprintf(stderr, "Illegal \"probability\"\n"); return -1; } red++; } else if (strcmp(*argv, "ecn") == 0) { opt.flags |= TC_RED_ECN; red++; } else if (strcmp(*argv, "harddrop") == 0) { opt.flags |= TC_RED_HARDDROP; red++; } else if (strcmp(*argv, "help") == 0) { explain(); return -1; } else { fprintf(stderr, "What is \"%s\"?\n", *argv); explain(); return -1; } argc--; argv++; } if (red) { if (!opt.limit) { fprintf(stderr, "Required parameter (redflowlimit) is missing\n"); return -1; } /* Compute default min/max thresholds based on Sally Floyd's recommendations: http://www.icir.org/floyd/REDparameters.txt */ if (!opt.qth_max) opt.qth_max = opt.limit / 4; if (!opt.qth_min) opt.qth_min = opt.qth_max / 3; if (!burst) burst = (2 * opt.qth_min + opt.qth_max) / (3 * avpkt); if (opt.qth_max > opt.limit) { fprintf(stderr, "\"max\" is larger than \"limit\"\n"); return -1; } if (opt.qth_min >= opt.qth_max) { fprintf(stderr, "\"min\" is not smaller than \"max\"\n"); return -1; } wlog = tc_red_eval_ewma(opt.qth_min, burst, avpkt); if (wlog < 0) { fprintf(stderr, "SFQ: failed to calculate EWMA constant.\n"); return -1; } if (wlog >= 10) fprintf(stderr, "SFQ: WARNING. Burst %u seems to be too large.\n", burst); opt.Wlog = wlog; wlog = tc_red_eval_P(opt.qth_min, opt.qth_max, probability); if (wlog < 0) { fprintf(stderr, "SFQ: failed to calculate probability.\n"); return -1; } opt.Plog = wlog; opt.max_P = probability * pow(2, 32); } if (ok || red) addattr_l(n, 1024, TCA_OPTIONS, &opt, sizeof(opt)); return 0; } static int sfq_print_opt(const struct qdisc_util *qu, FILE *f, struct rtattr *opt) { struct tc_sfq_qopt *qopt; struct tc_sfq_qopt_v1 *qopt_ext = NULL; if (opt == NULL) return 0; if (RTA_PAYLOAD(opt) < sizeof(*qopt)) return -1; if (RTA_PAYLOAD(opt) >= sizeof(*qopt_ext)) qopt_ext = RTA_DATA(opt); qopt = RTA_DATA(opt); print_uint(PRINT_ANY, "limit", "limit %up ", qopt->limit); print_size(PRINT_ANY, "quantum", "quantum %s ", qopt->quantum); if (qopt_ext && qopt_ext->depth) print_uint(PRINT_ANY, "depth", "depth %u ", qopt_ext->depth); if (qopt_ext && qopt_ext->headdrop) print_bool(PRINT_ANY, "headdrop", "headdrop ", true); if (show_details) print_uint(PRINT_ANY, "flows", "flows %u ", qopt->flows); print_uint(PRINT_ANY, "divisor", "divisor %u ", qopt->divisor); if (qopt->perturb_period) print_int(PRINT_ANY, "perturb", "perturb %dsec ", qopt->perturb_period); if (qopt_ext && qopt_ext->qth_min) { print_uint(PRINT_ANY, "ewma", "ewma %u ", qopt_ext->Wlog); print_size(PRINT_ANY, "min", "min %s ", qopt_ext->qth_min); print_size(PRINT_ANY, "max", "max %s ", qopt_ext->qth_max); print_float(PRINT_ANY, "probability", "probability %lg ", qopt_ext->max_P / pow(2, 32)); tc_red_print_flags(qopt_ext->flags); if (show_stats) { print_nl(); print_uint(PRINT_ANY, "prob_mark", " prob_mark %u", qopt_ext->stats.prob_mark); print_uint(PRINT_ANY, "prob_mark_head", " prob_mark_head %u", qopt_ext->stats.prob_mark_head); print_uint(PRINT_ANY, "prob_drop", " prob_drop %u", qopt_ext->stats.prob_drop); print_nl(); print_uint(PRINT_ANY, "forced_mark", " forced_mark %u", qopt_ext->stats.forced_mark); print_uint(PRINT_ANY, "forced_mark_head", " forced_mark_head %u", qopt_ext->stats.forced_mark_head); print_uint(PRINT_ANY, "forced_drop", " forced_drop %u", qopt_ext->stats.forced_drop); } } return 0; } static int sfq_print_xstats(const struct qdisc_util *qu, FILE *f, struct rtattr *xstats) { struct tc_sfq_xstats *st; if (xstats == NULL) return 0; if (RTA_PAYLOAD(xstats) < sizeof(*st)) return -1; st = RTA_DATA(xstats); print_int(PRINT_ANY, "allot", " allot %d", st->allot); return 0; } struct qdisc_util sfq_qdisc_util = { .id = "sfq", .parse_qopt = sfq_parse_opt, .print_qopt = sfq_print_opt, .print_xstats = sfq_print_xstats, };