// SPDX-License-Identifier: (GPL-2.0+ OR BSD-3-Clause) /* Copyright 2020 NXP */ #include #include #include #include #include #include "utils.h" #include "rt_names.h" #include "tc_util.h" #include "list.h" #include struct gate_entry { struct list_head list; uint8_t gate_state; uint32_t interval; int32_t ipv; int32_t maxoctets; }; static void explain(void) { fprintf(stderr, "Usage: gate [ priority PRIO-SPEC ] [ base-time BASE-TIME ]\n" " [ cycle-time CYCLE-TIME ]\n" " [ cycle-time-ext CYCLE-TIME-EXT ]\n" " [ clockid CLOCKID ] [flags FLAGS]\n" " [ sched-entry GATE0 INTERVAL [ INTERNAL-PRIO-VALUE MAX-OCTETS ] ]\n" " [ sched-entry GATE1 INTERVAL [ INTERNAL-PRIO-VALUE MAX-OCTETS ] ]\n" " ......\n" " [ sched-entry GATEn INTERVAL [ INTERNAL-PRIO-VALUE MAX-OCTETS ] ]\n" " [ CONTROL ]\n" " GATEn := open | close\n" " INTERVAL : nanoseconds period of gate slot\n" " INTERNAL-PRIO-VALUE : internal priority decide which\n" " rx queue number direct to.\n" " default to be -1 which means wildcard.\n" " MAX-OCTETS : maximum number of MSDU octets that are\n" " permitted to pas the gate during the\n" " specified TimeInterval.\n" " default to be -1 which means wildcard.\n" " CONTROL := pipe | drop | continue | pass |\n" " goto chain \n"); } static void usage(void) { explain(); exit(-1); } static void explain_entry_format(void) { fprintf(stderr, "Usage: sched-entry [ ]\n"); } static int parse_gate(const struct action_util *a, int *argc_p, char ***argv_p, int tca_id, struct nlmsghdr *n); static int print_gate(const struct action_util *au, FILE *f, struct rtattr *arg); struct action_util gate_action_util = { .id = "gate", .parse_aopt = parse_gate, .print_aopt = print_gate, }; static int get_gate_state(__u8 *val, const char *arg) { if (!strcasecmp("OPEN", arg)) { *val = 1; return 0; } if (!strcasecmp("CLOSE", arg)) { *val = 0; return 0; } return -1; } static struct gate_entry *create_gate_entry(uint8_t gate_state, uint32_t interval, int32_t ipv, int32_t maxoctets) { struct gate_entry *e; e = calloc(1, sizeof(*e)); if (!e) return NULL; e->gate_state = gate_state; e->interval = interval; e->ipv = ipv; e->maxoctets = maxoctets; return e; } static int add_gate_list(struct list_head *gate_entries, struct nlmsghdr *n) { struct gate_entry *e; list_for_each_entry(e, gate_entries, list) { struct rtattr *a; a = addattr_nest(n, 1024, TCA_GATE_ONE_ENTRY | NLA_F_NESTED); if (e->gate_state) addattr(n, MAX_MSG, TCA_GATE_ENTRY_GATE); addattr_l(n, MAX_MSG, TCA_GATE_ENTRY_INTERVAL, &e->interval, sizeof(e->interval)); addattr_l(n, MAX_MSG, TCA_GATE_ENTRY_IPV, &e->ipv, sizeof(e->ipv)); addattr_l(n, MAX_MSG, TCA_GATE_ENTRY_MAX_OCTETS, &e->maxoctets, sizeof(e->maxoctets)); addattr_nest_end(n, a); } return 0; } static void free_entries(struct list_head *gate_entries) { struct gate_entry *e, *n; list_for_each_entry_safe(e, n, gate_entries, list) { list_del(&e->list); free(e); } } static int parse_gate(const struct action_util *a, int *argc_p, char ***argv_p, int tca_id, struct nlmsghdr *n) { struct tc_gate parm = {.action = TC_ACT_PIPE}; struct list_head gate_entries; __s32 clockid = CLOCKID_INVALID; struct rtattr *tail, *nle; char **argv = *argv_p; int argc = *argc_p; __s64 base_time = 0; __s64 cycle_time = 0; __s64 cycle_time_ext = 0; int entry_num = 0; char *invalidarg; __u32 flags = 0; int prio = -1; int err; if (matches(*argv, "gate") != 0) return -1; NEXT_ARG(); if (argc <= 0) return -1; INIT_LIST_HEAD(&gate_entries); while (argc > 0) { if (matches(*argv, "index") == 0) { NEXT_ARG(); if (get_u32(&parm.index, *argv, 10)) { invalidarg = "index"; goto err_arg; } } else if (matches(*argv, "priority") == 0) { NEXT_ARG(); if (get_s32(&prio, *argv, 0)) { invalidarg = "priority"; goto err_arg; } } else if (matches(*argv, "base-time") == 0) { NEXT_ARG(); if (get_s64(&base_time, *argv, 10) && get_time64(&base_time, *argv)) { invalidarg = "base-time"; goto err_arg; } } else if (matches(*argv, "cycle-time") == 0) { NEXT_ARG(); if (get_s64(&cycle_time, *argv, 10) && get_time64(&cycle_time, *argv)) { invalidarg = "cycle-time"; goto err_arg; } } else if (matches(*argv, "cycle-time-ext") == 0) { NEXT_ARG(); if (get_s64(&cycle_time_ext, *argv, 10) && get_time64(&cycle_time_ext, *argv)) { invalidarg = "cycle-time-ext"; goto err_arg; } } else if (matches(*argv, "clockid") == 0) { NEXT_ARG(); if (get_clockid(&clockid, *argv)) { invalidarg = "clockid"; goto err_arg; } } else if (matches(*argv, "flags") == 0) { NEXT_ARG(); if (get_u32(&flags, *argv, 0)) { invalidarg = "flags"; goto err_arg; } } else if (matches(*argv, "sched-entry") == 0) { unsigned int maxoctets_uint = 0; int32_t maxoctets = -1; struct gate_entry *e; uint8_t gate_state = 0; __s64 interval_s64 = 0; uint32_t interval = 0; int32_t ipv = -1; if (!NEXT_ARG_OK()) { explain_entry_format(); fprintf(stderr, "\"sched-entry\" is incomplete\n"); free_entries(&gate_entries); return -1; } NEXT_ARG(); if (get_gate_state(&gate_state, *argv)) { explain_entry_format(); fprintf(stderr, "\"sched-entry\" is incomplete\n"); free_entries(&gate_entries); return -1; } if (!NEXT_ARG_OK()) { explain_entry_format(); fprintf(stderr, "\"sched-entry\" is incomplete\n"); free_entries(&gate_entries); return -1; } NEXT_ARG(); if (get_u32(&interval, *argv, 0) && get_time64(&interval_s64, *argv)) { explain_entry_format(); fprintf(stderr, "\"sched-entry\" is incomplete\n"); free_entries(&gate_entries); return -1; } if (interval_s64 > UINT_MAX) { fprintf(stderr, "\"interval\" is too large\n"); free_entries(&gate_entries); return -1; } else if (interval_s64) { interval = interval_s64; } if (!NEXT_ARG_OK()) goto create_entry; NEXT_ARG(); if (get_s32(&ipv, *argv, 0)) { PREV_ARG(); goto create_entry; } if (!gate_state) ipv = -1; if (!NEXT_ARG_OK()) goto create_entry; NEXT_ARG(); if (get_s32(&maxoctets, *argv, 0) && get_size(&maxoctets_uint, *argv)) PREV_ARG(); if (maxoctets_uint > INT_MAX) { fprintf(stderr, "\"maxoctets\" is too large\n"); free_entries(&gate_entries); return -1; } else if (maxoctets_uint ) { maxoctets = maxoctets_uint; } if (!gate_state) maxoctets = -1; create_entry: e = create_gate_entry(gate_state, interval, ipv, maxoctets); if (!e) { fprintf(stderr, "gate: not enough memory\n"); free_entries(&gate_entries); return -1; } list_add_tail(&e->list, &gate_entries); entry_num++; } else if (matches(*argv, "help") == 0) { usage(); } else { break; } argc--; argv++; } parse_action_control_dflt(&argc, &argv, &parm.action, false, TC_ACT_PIPE); if (!entry_num && !parm.index) { fprintf(stderr, "gate: must add at least one entry\n"); return -1; } tail = addattr_nest(n, MAX_MSG, tca_id | NLA_F_NESTED); addattr_l(n, MAX_MSG, TCA_GATE_PARMS, &parm, sizeof(parm)); if (prio != -1) addattr_l(n, MAX_MSG, TCA_GATE_PRIORITY, &prio, sizeof(prio)); if (flags) addattr_l(n, MAX_MSG, TCA_GATE_FLAGS, &flags, sizeof(flags)); if (base_time) addattr_l(n, MAX_MSG, TCA_GATE_BASE_TIME, &base_time, sizeof(base_time)); if (cycle_time) addattr_l(n, MAX_MSG, TCA_GATE_CYCLE_TIME, &cycle_time, sizeof(cycle_time)); if (cycle_time_ext) addattr_l(n, MAX_MSG, TCA_GATE_CYCLE_TIME_EXT, &cycle_time_ext, sizeof(cycle_time_ext)); if (clockid != CLOCKID_INVALID) addattr_l(n, MAX_MSG, TCA_GATE_CLOCKID, &clockid, sizeof(clockid)); nle = addattr_nest(n, MAX_MSG, TCA_GATE_ENTRY_LIST | NLA_F_NESTED); err = add_gate_list(&gate_entries, n); if (err < 0) { fprintf(stderr, "Could not add entries to netlink message\n"); free_entries(&gate_entries); return -1; } addattr_nest_end(n, nle); addattr_nest_end(n, tail); free_entries(&gate_entries); *argc_p = argc; *argv_p = argv; return 0; err_arg: invarg(invalidarg, *argv); free_entries(&gate_entries); return -1; } static int print_gate_list(struct rtattr *list) { struct rtattr *item; int rem; rem = RTA_PAYLOAD(list); print_string(PRINT_FP, NULL, "%s", _SL_); print_string(PRINT_FP, NULL, "\tschedule:%s", _SL_); open_json_array(PRINT_JSON, "schedule"); for (item = RTA_DATA(list); RTA_OK(item, rem); item = RTA_NEXT(item, rem)) { struct rtattr *tb[TCA_GATE_ENTRY_MAX + 1]; __u32 index = 0, interval = 0; __u8 gate_state = 0; __s32 ipv = -1, maxoctets = -1; SPRINT_BUF(buf); parse_rtattr_nested(tb, TCA_GATE_ENTRY_MAX, item); if (tb[TCA_GATE_ENTRY_INDEX]) index = rta_getattr_u32(tb[TCA_GATE_ENTRY_INDEX]); if (tb[TCA_GATE_ENTRY_GATE]) gate_state = 1; if (tb[TCA_GATE_ENTRY_INTERVAL]) interval = rta_getattr_u32(tb[TCA_GATE_ENTRY_INTERVAL]); if (tb[TCA_GATE_ENTRY_IPV]) ipv = rta_getattr_s32(tb[TCA_GATE_ENTRY_IPV]); if (tb[TCA_GATE_ENTRY_MAX_OCTETS]) maxoctets = rta_getattr_s32(tb[TCA_GATE_ENTRY_MAX_OCTETS]); open_json_object(NULL); print_uint(PRINT_ANY, "number", "\t number %4u", index); print_string(PRINT_ANY, "gate_state", "\tgate-state %s ", gate_state ? "open" : "close"); print_uint(PRINT_JSON, "interval", NULL, interval); memset(buf, 0, sizeof(buf)); print_string(PRINT_FP, NULL, "\tinterval %s", sprint_time64(interval, buf)); if (ipv != -1) { print_uint(PRINT_ANY, "ipv", "\t ipv %-10u", ipv); } else { print_int(PRINT_JSON, "ipv", NULL, ipv); print_string(PRINT_FP, NULL, "\t ipv %s", "wildcard"); } if (maxoctets != -1) { print_size(PRINT_ANY, "max_octets", "\t max-octets %s", maxoctets); } else { print_string(PRINT_FP, NULL, "\t max-octets %s", "wildcard"); print_int(PRINT_JSON, "max_octets", NULL, maxoctets); } close_json_object(); print_string(PRINT_FP, NULL, "%s", _SL_); } close_json_array(PRINT_ANY, ""); return 0; } static int print_gate(const struct action_util *au, FILE *f, struct rtattr *arg) { struct tc_gate *parm; struct rtattr *tb[TCA_GATE_MAX + 1]; __s32 clockid = CLOCKID_INVALID; __s64 base_time = 0; __s64 cycle_time = 0; __s64 cycle_time_ext = 0; SPRINT_BUF(buf); int prio = -1; if (arg == NULL) return -1; parse_rtattr_nested(tb, TCA_GATE_MAX, arg); if (!tb[TCA_GATE_PARMS]) { fprintf(stderr, "Missing gate parameters\n"); return -1; } print_string(PRINT_FP, NULL, "%s", "\n"); parm = RTA_DATA(tb[TCA_GATE_PARMS]); if (tb[TCA_GATE_PRIORITY]) prio = rta_getattr_s32(tb[TCA_GATE_PRIORITY]); if (prio != -1) { print_int(PRINT_ANY, "priority", "\tpriority %-8d", prio); } else { print_string(PRINT_FP, NULL, "\tpriority %s", "wildcard"); print_int(PRINT_JSON, "priority", NULL, prio); } if (tb[TCA_GATE_CLOCKID]) clockid = rta_getattr_s32(tb[TCA_GATE_CLOCKID]); print_string(PRINT_ANY, "clockid", "\tclockid %s", get_clock_name(clockid)); if (tb[TCA_GATE_FLAGS]) { __u32 flags; flags = rta_getattr_u32(tb[TCA_GATE_FLAGS]); print_0xhex(PRINT_ANY, "flags", "\tflags %#x", flags); } print_string(PRINT_FP, NULL, "%s", "\n"); if (tb[TCA_GATE_BASE_TIME]) base_time = rta_getattr_s64(tb[TCA_GATE_BASE_TIME]); memset(buf, 0, sizeof(buf)); print_string(PRINT_FP, NULL, "\tbase-time %s", sprint_time64(base_time, buf)); print_lluint(PRINT_JSON, "base_time", NULL, base_time); if (tb[TCA_GATE_CYCLE_TIME]) cycle_time = rta_getattr_s64(tb[TCA_GATE_CYCLE_TIME]); memset(buf, 0, sizeof(buf)); print_string(PRINT_FP, NULL, "\tcycle-time %s", sprint_time64(cycle_time, buf)); print_lluint(PRINT_JSON, "cycle_time", NULL, cycle_time); if (tb[TCA_GATE_CYCLE_TIME_EXT]) cycle_time_ext = rta_getattr_s64(tb[TCA_GATE_CYCLE_TIME_EXT]); memset(buf, 0, sizeof(buf)); print_string(PRINT_FP, NULL, "\tcycle-time-ext %s", sprint_time64(cycle_time_ext, buf)); print_lluint(PRINT_JSON, "cycle_time_ext", NULL, cycle_time_ext); if (tb[TCA_GATE_ENTRY_LIST]) print_gate_list(tb[TCA_GATE_ENTRY_LIST]); print_action_control(f, "\t", parm->action, ""); print_uint(PRINT_ANY, "index", "\n\t index %u", parm->index); print_int(PRINT_ANY, "ref", " ref %d", parm->refcnt); print_int(PRINT_ANY, "bind", " bind %d", parm->bindcnt); if (show_stats) { if (tb[TCA_GATE_TM]) { struct tcf_t *tm = RTA_DATA(tb[TCA_GATE_TM]); print_tm(f, tm); } } print_string(PRINT_FP, NULL, "%s", "\n"); return 0; }