/* * utils.c * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version * 2 of the License, or (at your option) any later version. * * Authors: Alexey Kuznetsov, * */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef HAVE_LIBCAP #include #endif #include "rt_names.h" #include "utils.h" #include "ll_map.h" #include "namespace.h" int resolve_hosts; int timestamp_short; int pretty; const char *_SL_ = "\n"; int read_prop(const char *dev, char *prop, long *value) { char fname[128], buf[80], *endp, *nl; FILE *fp; long result; int ret; ret = snprintf(fname, sizeof(fname), "/sys/class/net/%s/%s", dev, prop); if (ret <= 0 || ret >= sizeof(fname)) { fprintf(stderr, "could not build pathname for property\n"); return -1; } fp = fopen(fname, "r"); if (fp == NULL) { fprintf(stderr, "fopen %s: %s\n", fname, strerror(errno)); return -1; } if (!fgets(buf, sizeof(buf), fp)) { fprintf(stderr, "property \"%s\" in file %s is currently unknown\n", prop, fname); fclose(fp); goto out; } nl = strchr(buf, '\n'); if (nl) *nl = '\0'; fclose(fp); result = strtol(buf, &endp, 0); if (*endp || buf == endp) { fprintf(stderr, "value \"%s\" in file %s is not a number\n", buf, fname); goto out; } if ((result == LONG_MAX || result == LONG_MIN) && errno == ERANGE) { fprintf(stderr, "strtol %s: %s", fname, strerror(errno)); goto out; } *value = result; return 0; out: fprintf(stderr, "Failed to parse %s\n", fname); return -1; } /* Parse a percent e.g: '30%' * return: 0 = ok, -1 = error, 1 = out of range */ int parse_percent(double *val, const char *str) { char *p; *val = strtod(str, &p) / 100.; if (*val == HUGE_VALF || *val == HUGE_VALL) return 1; if (*p && strcmp(p, "%")) return -1; return 0; } int get_hex(char c) { if (c >= 'A' && c <= 'F') return c - 'A' + 10; if (c >= 'a' && c <= 'f') return c - 'a' + 10; if (c >= '0' && c <= '9') return c - '0'; return -1; } int get_integer(int *val, const char *arg, int base) { long res; char *ptr; if (!arg || !*arg) return -1; res = strtol(arg, &ptr, base); /* If there were no digits at all, strtol() stores * the original value of nptr in *endptr (and returns 0). * In particular, if *nptr is not '\0' but **endptr is '\0' on return, * the entire string is valid. */ if (!ptr || ptr == arg || *ptr) return -1; /* If an underflow occurs, strtol() returns LONG_MIN. * If an overflow occurs, strtol() returns LONG_MAX. * In both cases, errno is set to ERANGE. */ if ((res == LONG_MAX || res == LONG_MIN) && errno == ERANGE) return -1; /* Outside range of int */ if (res < INT_MIN || res > INT_MAX) return -1; *val = res; return 0; } int mask2bits(__u32 netmask) { unsigned int bits = 0; __u32 mask = ntohl(netmask); __u32 host = ~mask; /* a valid netmask must be 2^n - 1 */ if ((host & (host + 1)) != 0) return -1; for (; mask; mask <<= 1) ++bits; return bits; } static int get_netmask(unsigned int *val, const char *arg, int base) { inet_prefix addr; if (!get_unsigned(val, arg, base)) return 0; /* try coverting dotted quad to CIDR */ if (!get_addr_1(&addr, arg, AF_INET) && addr.family == AF_INET) { int b = mask2bits(addr.data[0]); if (b >= 0) { *val = b; return 0; } } return -1; } int get_unsigned(unsigned int *val, const char *arg, int base) { unsigned long res; char *ptr; if (!arg || !*arg) return -1; res = strtoul(arg, &ptr, base); /* empty string or trailing non-digits */ if (!ptr || ptr == arg || *ptr) return -1; /* overflow */ if (res == ULONG_MAX && errno == ERANGE) return -1; /* out side range of unsigned */ if (res > UINT_MAX) return -1; *val = res; return 0; } /* * get_time_rtt is "translated" from a similar routine "get_time" in * tc_util.c. We don't use the exact same routine because tc passes * microseconds to the kernel and the callers of get_time_rtt want to * pass milliseconds (standard unit for rtt values since 2.6.27), and * have a different assumption for the units of a "raw" number. */ int get_time_rtt(unsigned int *val, const char *arg, int *raw) { double t; unsigned long res; char *p; if (strchr(arg, '.') != NULL) { t = strtod(arg, &p); if (t < 0.0) return -1; /* no digits? */ if (!p || p == arg) return -1; /* over/underflow */ if ((t == HUGE_VALF || t == HUGE_VALL) && errno == ERANGE) return -1; } else { res = strtoul(arg, &p, 0); /* empty string? */ if (!p || p == arg) return -1; /* overflow */ if (res == ULONG_MAX && errno == ERANGE) return -1; t = (double)res; } if (p == arg) return -1; *raw = 1; if (*p) { *raw = 0; if (strcasecmp(p, "s") == 0 || strcasecmp(p, "sec") == 0 || strcasecmp(p, "secs") == 0) t *= 1000; else if (strcasecmp(p, "ms") == 0 || strcasecmp(p, "msec") == 0 || strcasecmp(p, "msecs") == 0) t *= 1.0; /* allow suffix, do nothing */ else return -1; } /* emulate ceil() without having to bring-in -lm and always be >= 1 */ *val = t; if (*val < t) *val += 1; return 0; } int get_u64(__u64 *val, const char *arg, int base) { unsigned long long res; char *ptr; if (!arg || !*arg) return -1; res = strtoull(arg, &ptr, base); /* empty string or trailing non-digits */ if (!ptr || ptr == arg || *ptr) return -1; /* overflow */ if (res == ULLONG_MAX && errno == ERANGE) return -1; /* in case ULL is 128 bits */ if (res > 0xFFFFFFFFFFFFFFFFULL) return -1; *val = res; return 0; } int get_u32(__u32 *val, const char *arg, int base) { unsigned long res; char *ptr; if (!arg || !*arg) return -1; res = strtoul(arg, &ptr, base); /* empty string or trailing non-digits */ if (!ptr || ptr == arg || *ptr) return -1; /* overflow */ if (res == ULONG_MAX && errno == ERANGE) return -1; /* in case UL > 32 bits */ if (res > 0xFFFFFFFFUL) return -1; *val = res; return 0; } int get_u16(__u16 *val, const char *arg, int base) { unsigned long res; char *ptr; if (!arg || !*arg) return -1; res = strtoul(arg, &ptr, base); /* empty string or trailing non-digits */ if (!ptr || ptr == arg || *ptr) return -1; /* overflow */ if (res == ULONG_MAX && errno == ERANGE) return -1; if (res > 0xFFFFUL) return -1; *val = res; return 0; } int get_u8(__u8 *val, const char *arg, int base) { unsigned long res; char *ptr; if (!arg || !*arg) return -1; res = strtoul(arg, &ptr, base); /* empty string or trailing non-digits */ if (!ptr || ptr == arg || *ptr) return -1; /* overflow */ if (res == ULONG_MAX && errno == ERANGE) return -1; if (res > 0xFFUL) return -1; *val = res; return 0; } int get_s32(__s32 *val, const char *arg, int base) { long res; char *ptr; errno = 0; if (!arg || !*arg) return -1; res = strtol(arg, &ptr, base); if (!ptr || ptr == arg || *ptr) return -1; if ((res == LONG_MIN || res == LONG_MAX) && errno == ERANGE) return -1; if (res > INT32_MAX || res < INT32_MIN) return -1; *val = res; return 0; } int get_s16(__s16 *val, const char *arg, int base) { long res; char *ptr; if (!arg || !*arg) return -1; res = strtol(arg, &ptr, base); if (!ptr || ptr == arg || *ptr) return -1; if ((res == LONG_MIN || res == LONG_MAX) && errno == ERANGE) return -1; if (res > 0x7FFF || res < -0x8000) return -1; *val = res; return 0; } int get_s8(__s8 *val, const char *arg, int base) { long res; char *ptr; if (!arg || !*arg) return -1; res = strtol(arg, &ptr, base); if (!ptr || ptr == arg || *ptr) return -1; if ((res == LONG_MIN || res == LONG_MAX) && errno == ERANGE) return -1; if (res > 0x7F || res < -0x80) return -1; *val = res; return 0; } int get_be64(__be64 *val, const char *arg, int base) { __u64 v; int ret = get_u64(&v, arg, base); if (!ret) *val = htonll(v); return ret; } int get_be32(__be32 *val, const char *arg, int base) { __u32 v; int ret = get_u32(&v, arg, base); if (!ret) *val = htonl(v); return ret; } int get_be16(__be16 *val, const char *arg, int base) { __u16 v; int ret = get_u16(&v, arg, base); if (!ret) *val = htons(v); return ret; } /* This uses a non-standard parsing (ie not inet_aton, or inet_pton) * because of legacy choice to parse 10.8 as 10.8.0.0 not 10.0.0.8 */ static int get_addr_ipv4(__u8 *ap, const char *cp) { int i; for (i = 0; i < 4; i++) { unsigned long n; char *endp; n = strtoul(cp, &endp, 0); if (n > 255) return -1; /* bogus network value */ if (endp == cp) /* no digits */ return -1; ap[i] = n; if (*endp == '\0') break; if (i == 3 || *endp != '.') return -1; /* extra characters */ cp = endp + 1; } return 1; } int get_addr64(__u64 *ap, const char *cp) { int i; union { __u16 v16[4]; __u64 v64; } val; for (i = 0; i < 4; i++) { unsigned long n; char *endp; n = strtoul(cp, &endp, 16); if (n > 0xffff) return -1; /* bogus network value */ if (endp == cp) /* no digits */ return -1; val.v16[i] = htons(n); if (*endp == '\0') break; if (i == 3 || *endp != ':') return -1; /* extra characters */ cp = endp + 1; } *ap = val.v64; return 1; } static void set_address_type(inet_prefix *addr) { switch (addr->family) { case AF_INET: if (!addr->data[0]) addr->flags |= ADDRTYPE_INET_UNSPEC; else if (IN_MULTICAST(ntohl(addr->data[0]))) addr->flags |= ADDRTYPE_INET_MULTI; else addr->flags |= ADDRTYPE_INET; break; case AF_INET6: if (IN6_IS_ADDR_UNSPECIFIED(addr->data)) addr->flags |= ADDRTYPE_INET_UNSPEC; else if (IN6_IS_ADDR_MULTICAST(addr->data)) addr->flags |= ADDRTYPE_INET_MULTI; else addr->flags |= ADDRTYPE_INET; break; } } static int __get_addr_1(inet_prefix *addr, const char *name, int family) { memset(addr, 0, sizeof(*addr)); if (strcmp(name, "default") == 0) { if ((family == AF_DECnet) || (family == AF_MPLS)) return -1; addr->family = family; addr->bytelen = af_byte_len(addr->family); addr->bitlen = -2; addr->flags |= PREFIXLEN_SPECIFIED; return 0; } if (strcmp(name, "all") == 0 || strcmp(name, "any") == 0) { if ((family == AF_DECnet) || (family == AF_MPLS)) return -1; addr->family = family; addr->bytelen = 0; addr->bitlen = -2; return 0; } if (family == AF_PACKET) { int len; len = ll_addr_a2n((char *) &addr->data, sizeof(addr->data), name); if (len < 0) return -1; addr->family = AF_PACKET; addr->bytelen = len; addr->bitlen = len * 8; return 0; } if (strchr(name, ':')) { addr->family = AF_INET6; if (family != AF_UNSPEC && family != AF_INET6) return -1; if (inet_pton(AF_INET6, name, addr->data) <= 0) return -1; addr->bytelen = 16; addr->bitlen = -1; return 0; } if (family == AF_DECnet) { struct dn_naddr dna; addr->family = AF_DECnet; if (dnet_pton(AF_DECnet, name, &dna) <= 0) return -1; memcpy(addr->data, dna.a_addr, 2); addr->bytelen = 2; addr->bitlen = -1; return 0; } if (family == AF_MPLS) { unsigned int maxlabels; int i; addr->family = AF_MPLS; if (mpls_pton(AF_MPLS, name, addr->data, sizeof(addr->data)) <= 0) return -1; addr->bytelen = 4; addr->bitlen = 20; /* How many bytes do I need? */ maxlabels = sizeof(addr->data) / sizeof(struct mpls_label); for (i = 0; i < maxlabels; i++) { if (ntohl(addr->data[i]) & MPLS_LS_S_MASK) { addr->bytelen = (i + 1)*4; break; } } return 0; } addr->family = AF_INET; if (family != AF_UNSPEC && family != AF_INET) return -1; if (get_addr_ipv4((__u8 *)addr->data, name) <= 0) return -1; addr->bytelen = 4; addr->bitlen = -1; return 0; } int get_addr_1(inet_prefix *addr, const char *name, int family) { int ret; ret = __get_addr_1(addr, name, family); if (ret) return ret; set_address_type(addr); return 0; } int af_bit_len(int af) { switch (af) { case AF_INET6: return 128; case AF_INET: return 32; case AF_DECnet: return 16; case AF_IPX: return 80; case AF_MPLS: return 20; } return 0; } int af_byte_len(int af) { return af_bit_len(af) / 8; } int get_prefix_1(inet_prefix *dst, char *arg, int family) { char *slash; int err, bitlen, flags; slash = strchr(arg, '/'); if (slash) *slash = 0; err = get_addr_1(dst, arg, family); if (slash) *slash = '/'; if (err) return err; bitlen = af_bit_len(dst->family); flags = 0; if (slash) { unsigned int plen; if (dst->bitlen == -2) return -1; if (get_netmask(&plen, slash + 1, 0)) return -1; if (plen > bitlen) return -1; flags |= PREFIXLEN_SPECIFIED; bitlen = plen; } else { if (dst->bitlen == -2) bitlen = 0; } dst->flags |= flags; dst->bitlen = bitlen; return 0; } static const char *family_name_verbose(int family) { if (family == AF_UNSPEC) return "any valid"; return family_name(family); } int get_addr(inet_prefix *dst, const char *arg, int family) { if (get_addr_1(dst, arg, family)) { fprintf(stderr, "Error: %s address is expected rather than \"%s\".\n", family_name_verbose(family), arg); exit(1); } return 0; } int get_addr_rta(inet_prefix *dst, const struct rtattr *rta, int family) { const int len = RTA_PAYLOAD(rta); const void *data = RTA_DATA(rta); switch (len) { case 4: dst->family = AF_INET; dst->bytelen = 4; memcpy(dst->data, data, 4); break; case 16: dst->family = AF_INET6; dst->bytelen = 16; memcpy(dst->data, data, 16); break; case 2: dst->family = AF_DECnet; dst->bytelen = 2; memcpy(dst->data, data, 2); break; case 10: dst->family = AF_IPX; dst->bytelen = 10; memcpy(dst->data, data, 10); break; default: return -1; } if (family != AF_UNSPEC && family != dst->family) return -2; dst->bitlen = -1; dst->flags = 0; set_address_type(dst); return 0; } int get_prefix(inet_prefix *dst, char *arg, int family) { if (family == AF_PACKET) { fprintf(stderr, "Error: \"%s\" may be inet prefix, but it is not allowed in this context.\n", arg); exit(1); } if (get_prefix_1(dst, arg, family)) { fprintf(stderr, "Error: %s prefix is expected rather than \"%s\".\n", family_name_verbose(family), arg); exit(1); } return 0; } __u32 get_addr32(const char *name) { inet_prefix addr; if (get_addr_1(&addr, name, AF_INET)) { fprintf(stderr, "Error: an IP address is expected rather than \"%s\"\n", name); exit(1); } return addr.data[0]; } void incomplete_command(void) { fprintf(stderr, "Command line is not complete. Try option \"help\"\n"); exit(-1); } void missarg(const char *key) { fprintf(stderr, "Error: argument \"%s\" is required\n", key); exit(-1); } void invarg(const char *msg, const char *arg) { fprintf(stderr, "Error: argument \"%s\" is wrong: %s\n", arg, msg); exit(-1); } void duparg(const char *key, const char *arg) { fprintf(stderr, "Error: duplicate \"%s\": \"%s\" is the second value.\n", key, arg); exit(-1); } void duparg2(const char *key, const char *arg) { fprintf(stderr, "Error: either \"%s\" is duplicate, or \"%s\" is a garbage.\n", key, arg); exit(-1); } int nodev(const char *dev) { fprintf(stderr, "Cannot find device \"%s\"\n", dev); return -1; } int check_ifname(const char *name) { /* These checks mimic kernel checks in dev_valid_name */ if (*name == '\0') return -1; if (strlen(name) >= IFNAMSIZ) return -1; while (*name) { if (*name == '/' || isspace(*name)) return -1; ++name; } return 0; } /* buf is assumed to be IFNAMSIZ */ int get_ifname(char *buf, const char *name) { int ret; ret = check_ifname(name); if (ret == 0) strncpy(buf, name, IFNAMSIZ); return ret; } const char *get_ifname_rta(int ifindex, const struct rtattr *rta) { const char *name; if (rta) { name = rta_getattr_str(rta); } else { fprintf(stderr, "BUG: device with ifindex %d has nil ifname\n", ifindex); name = ll_idx_n2a(ifindex); } if (check_ifname(name)) return NULL; return name; } int matches(const char *cmd, const char *pattern) { int len = strlen(cmd); if (len > strlen(pattern)) return -1; return memcmp(pattern, cmd, len); } int inet_addr_match(const inet_prefix *a, const inet_prefix *b, int bits) { const __u32 *a1 = a->data; const __u32 *a2 = b->data; int words = bits >> 0x05; bits &= 0x1f; if (words) if (memcmp(a1, a2, words << 2)) return -1; if (bits) { __u32 w1, w2; __u32 mask; w1 = a1[words]; w2 = a2[words]; mask = htonl((0xffffffff) << (0x20 - bits)); if ((w1 ^ w2) & mask) return 1; } return 0; } int inet_addr_match_rta(const inet_prefix *m, const struct rtattr *rta) { inet_prefix dst; if (!rta || m->family == AF_UNSPEC || m->bitlen <= 0) return 0; if (get_addr_rta(&dst, rta, m->family)) return -1; return inet_addr_match(&dst, m, m->bitlen); } int __iproute2_hz_internal; int __get_hz(void) { char name[1024]; int hz = 0; FILE *fp; if (getenv("HZ")) return atoi(getenv("HZ")) ? : HZ; if (getenv("PROC_NET_PSCHED")) snprintf(name, sizeof(name)-1, "%s", getenv("PROC_NET_PSCHED")); else if (getenv("PROC_ROOT")) snprintf(name, sizeof(name)-1, "%s/net/psched", getenv("PROC_ROOT")); else strcpy(name, "/proc/net/psched"); fp = fopen(name, "r"); if (fp) { unsigned int nom, denom; if (fscanf(fp, "%*08x%*08x%08x%08x", &nom, &denom) == 2) if (nom == 1000000) hz = denom; fclose(fp); } if (hz) return hz; return HZ; } int __iproute2_user_hz_internal; int __get_user_hz(void) { return sysconf(_SC_CLK_TCK); } const char *rt_addr_n2a_r(int af, int len, const void *addr, char *buf, int buflen) { switch (af) { case AF_INET: case AF_INET6: return inet_ntop(af, addr, buf, buflen); case AF_MPLS: return mpls_ntop(af, addr, buf, buflen); case AF_IPX: return ipx_ntop(af, addr, buf, buflen); case AF_DECnet: { struct dn_naddr dna = { 2, { 0, 0, } }; memcpy(dna.a_addr, addr, 2); return dnet_ntop(af, &dna, buf, buflen); } case AF_PACKET: return ll_addr_n2a(addr, len, ARPHRD_VOID, buf, buflen); case AF_BRIDGE: { const union { struct sockaddr sa; struct sockaddr_in sin; struct sockaddr_in6 sin6; } *sa = addr; switch (sa->sa.sa_family) { case AF_INET: return inet_ntop(AF_INET, &sa->sin.sin_addr, buf, buflen); case AF_INET6: return inet_ntop(AF_INET6, &sa->sin6.sin6_addr, buf, buflen); } /* fallthrough */ } default: return "???"; } } const char *rt_addr_n2a(int af, int len, const void *addr) { static char buf[256]; return rt_addr_n2a_r(af, len, addr, buf, 256); } int read_family(const char *name) { int family = AF_UNSPEC; if (strcmp(name, "inet") == 0) family = AF_INET; else if (strcmp(name, "inet6") == 0) family = AF_INET6; else if (strcmp(name, "dnet") == 0) family = AF_DECnet; else if (strcmp(name, "link") == 0) family = AF_PACKET; else if (strcmp(name, "ipx") == 0) family = AF_IPX; else if (strcmp(name, "mpls") == 0) family = AF_MPLS; else if (strcmp(name, "bridge") == 0) family = AF_BRIDGE; return family; } const char *family_name(int family) { if (family == AF_INET) return "inet"; if (family == AF_INET6) return "inet6"; if (family == AF_DECnet) return "dnet"; if (family == AF_PACKET) return "link"; if (family == AF_IPX) return "ipx"; if (family == AF_MPLS) return "mpls"; if (family == AF_BRIDGE) return "bridge"; return "???"; } #ifdef RESOLVE_HOSTNAMES struct namerec { struct namerec *next; const char *name; inet_prefix addr; }; #define NHASH 257 static struct namerec *nht[NHASH]; static const char *resolve_address(const void *addr, int len, int af) { struct namerec *n; struct hostent *h_ent; unsigned int hash; static int notfirst; if (af == AF_INET6 && ((__u32 *)addr)[0] == 0 && ((__u32 *)addr)[1] == 0 && ((__u32 *)addr)[2] == htonl(0xffff)) { af = AF_INET; addr += 12; len = 4; } hash = *(__u32 *)(addr + len - 4) % NHASH; for (n = nht[hash]; n; n = n->next) { if (n->addr.family == af && n->addr.bytelen == len && memcmp(n->addr.data, addr, len) == 0) return n->name; } n = malloc(sizeof(*n)); if (n == NULL) return NULL; n->addr.family = af; n->addr.bytelen = len; n->name = NULL; memcpy(n->addr.data, addr, len); n->next = nht[hash]; nht[hash] = n; if (++notfirst == 1) sethostent(1); fflush(stdout); h_ent = gethostbyaddr(addr, len, af); if (h_ent != NULL) n->name = strdup(h_ent->h_name); /* Even if we fail, "negative" entry is remembered. */ return n->name; } #endif const char *format_host_r(int af, int len, const void *addr, char *buf, int buflen) { #ifdef RESOLVE_HOSTNAMES if (resolve_hosts) { const char *n; len = len <= 0 ? af_byte_len(af) : len; if (len > 0 && (n = resolve_address(addr, len, af)) != NULL) return n; } #endif return rt_addr_n2a_r(af, len, addr, buf, buflen); } const char *format_host(int af, int len, const void *addr) { static char buf[256]; return format_host_r(af, len, addr, buf, 256); } char *hexstring_n2a(const __u8 *str, int len, char *buf, int blen) { char *ptr = buf; int i; for (i = 0; i < len; i++) { if (blen < 3) break; sprintf(ptr, "%02x", str[i]); ptr += 2; blen -= 2; } return buf; } __u8 *hexstring_a2n(const char *str, __u8 *buf, int blen, unsigned int *len) { unsigned int cnt = 0; char *endptr; if (strlen(str) % 2) return NULL; while (cnt < blen && strlen(str) > 1) { unsigned int tmp; char tmpstr[3]; strncpy(tmpstr, str, 2); tmpstr[2] = '\0'; errno = 0; tmp = strtoul(tmpstr, &endptr, 16); if (errno != 0 || tmp > 0xFF || *endptr != '\0') return NULL; buf[cnt++] = tmp; str += 2; } if (len) *len = cnt; return buf; } int hex2mem(const char *buf, uint8_t *mem, int count) { int i, j; int c; for (i = 0, j = 0; i < count; i++, j += 2) { c = get_hex(buf[j]); if (c < 0) return -1; mem[i] = c << 4; c = get_hex(buf[j + 1]); if (c < 0) return -1; mem[i] |= c; } return 0; } int addr64_n2a(__u64 addr, char *buff, size_t len) { __u16 *words = (__u16 *)&addr; __u16 v; int i, ret; size_t written = 0; char *sep = ":"; for (i = 0; i < 4; i++) { v = ntohs(words[i]); if (i == 3) sep = ""; ret = snprintf(&buff[written], len - written, "%x%s", v, sep); if (ret < 0) return ret; written += ret; } return written; } /* Print buffer and escape bytes that are !isprint or among 'escape' */ void print_escape_buf(const __u8 *buf, size_t len, const char *escape) { size_t i; for (i = 0; i < len; ++i) { if (isprint(buf[i]) && buf[i] != '\\' && !strchr(escape, buf[i])) printf("%c", buf[i]); else printf("\\%03o", buf[i]); } } int print_timestamp(FILE *fp) { struct timeval tv; struct tm *tm; gettimeofday(&tv, NULL); tm = localtime(&tv.tv_sec); if (timestamp_short) { char tshort[40]; strftime(tshort, sizeof(tshort), "%Y-%m-%dT%H:%M:%S", tm); fprintf(fp, "[%s.%06ld] ", tshort, tv.tv_usec); } else { char *tstr = asctime(tm); tstr[strlen(tstr)-1] = 0; fprintf(fp, "Timestamp: %s %ld usec\n", tstr, tv.tv_usec); } return 0; } unsigned int print_name_and_link(const char *fmt, const char *name, struct rtattr *tb[]) { const char *link = NULL; unsigned int m_flag = 0; SPRINT_BUF(b1); if (tb[IFLA_LINK]) { int iflink = rta_getattr_u32(tb[IFLA_LINK]); if (iflink) { if (tb[IFLA_LINK_NETNSID]) { if (is_json_context()) { print_int(PRINT_JSON, "link_index", NULL, iflink); } else { link = ll_idx_n2a(iflink); } } else { link = ll_index_to_name(iflink); if (is_json_context()) { print_string(PRINT_JSON, "link", NULL, link); link = NULL; } m_flag = ll_index_to_flags(iflink); m_flag = !(m_flag & IFF_UP); } } else { if (is_json_context()) print_null(PRINT_JSON, "link", NULL, NULL); else link = "NONE"; } if (link) { snprintf(b1, sizeof(b1), "%s@%s", name, link); name = b1; } } print_color_string(PRINT_ANY, COLOR_IFNAME, "ifname", fmt, name); return m_flag; } int cmdlineno; /* Like glibc getline but handle continuation lines and comments */ ssize_t getcmdline(char **linep, size_t *lenp, FILE *in) { ssize_t cc; char *cp; cc = getline(linep, lenp, in); if (cc < 0) return cc; /* eof or error */ ++cmdlineno; cp = strchr(*linep, '#'); if (cp) *cp = '\0'; while ((cp = strstr(*linep, "\\\n")) != NULL) { char *line1 = NULL; size_t len1 = 0; ssize_t cc1; cc1 = getline(&line1, &len1, in); if (cc1 < 0) { fprintf(stderr, "Missing continuation line\n"); return cc1; } ++cmdlineno; *cp = 0; cp = strchr(line1, '#'); if (cp) *cp = '\0'; *lenp = strlen(*linep) + strlen(line1) + 1; *linep = realloc(*linep, *lenp); if (!*linep) { fprintf(stderr, "Out of memory\n"); *lenp = 0; return -1; } cc += cc1 - 2; strcat(*linep, line1); free(line1); } return cc; } /* split command line into argument vector */ int makeargs(char *line, char *argv[], int maxargs) { static const char ws[] = " \t\r\n"; char *cp = line; int argc = 0; while (*cp) { /* skip leading whitespace */ cp += strspn(cp, ws); if (*cp == '\0') break; if (argc >= (maxargs - 1)) { fprintf(stderr, "Too many arguments to command\n"); exit(1); } /* word begins with quote */ if (*cp == '\'' || *cp == '"') { char quote = *cp++; argv[argc++] = cp; /* find ending quote */ cp = strchr(cp, quote); if (cp == NULL) { fprintf(stderr, "Unterminated quoted string\n"); exit(1); } } else { argv[argc++] = cp; /* find end of word */ cp += strcspn(cp, ws); if (*cp == '\0') break; } /* separate words */ *cp++ = 0; } argv[argc] = NULL; return argc; } void print_nlmsg_timestamp(FILE *fp, const struct nlmsghdr *n) { char *tstr; time_t secs = ((__u32 *)NLMSG_DATA(n))[0]; long usecs = ((__u32 *)NLMSG_DATA(n))[1]; tstr = asctime(localtime(&secs)); tstr[strlen(tstr)-1] = 0; fprintf(fp, "Timestamp: %s %lu us\n", tstr, usecs); } static int on_netns(char *nsname, void *arg) { struct netns_func *f = arg; if (netns_switch(nsname)) return -1; return f->func(nsname, f->arg); } static int on_netns_label(char *nsname, void *arg) { printf("\nnetns: %s\n", nsname); return on_netns(nsname, arg); } int do_each_netns(int (*func)(char *nsname, void *arg), void *arg, bool show_label) { struct netns_func nsf = { .func = func, .arg = arg }; if (show_label) return netns_foreach(on_netns_label, &nsf); return netns_foreach(on_netns, &nsf); } char *int_to_str(int val, char *buf) { sprintf(buf, "%d", val); return buf; } int get_guid(__u64 *guid, const char *arg) { unsigned long int tmp; char *endptr; int i; #define GUID_STR_LEN 23 /* Verify strict format: format string must be * xx:xx:xx:xx:xx:xx:xx:xx where xx can be an arbitrary * hex digit */ if (strlen(arg) != GUID_STR_LEN) return -1; /* make sure columns are in place */ for (i = 0; i < 7; i++) if (arg[2 + i * 3] != ':') return -1; *guid = 0; for (i = 0; i < 8; i++) { tmp = strtoul(arg + i * 3, &endptr, 16); if (endptr != arg + i * 3 + 2) return -1; if (tmp > 255) return -1; *guid |= tmp << (56 - 8 * i); } return 0; } /* This is a necessary workaround for multicast route dumps */ int get_real_family(int rtm_type, int rtm_family) { if (rtm_type != RTN_MULTICAST) return rtm_family; if (rtm_family == RTNL_FAMILY_IPMR) return AF_INET; if (rtm_family == RTNL_FAMILY_IP6MR) return AF_INET6; return rtm_family; } /* Based on copy_rtnl_link_stats() from kernel at net/core/rtnetlink.c */ static void copy_rtnl_link_stats64(struct rtnl_link_stats64 *stats64, const struct rtnl_link_stats *stats) { __u64 *a = (__u64 *)stats64; const __u32 *b = (const __u32 *)stats; const __u32 *e = b + sizeof(*stats) / sizeof(*b); while (b < e) *a++ = *b++; } #define IPSTATS_MIB_MAX_LEN (__IPSTATS_MIB_MAX * sizeof(__u64)) static void get_snmp_counters(struct rtnl_link_stats64 *stats64, struct rtattr *s) { __u64 *mib = (__u64 *)RTA_DATA(s); memset(stats64, 0, sizeof(*stats64)); stats64->rx_packets = mib[IPSTATS_MIB_INPKTS]; stats64->rx_bytes = mib[IPSTATS_MIB_INOCTETS]; stats64->tx_packets = mib[IPSTATS_MIB_OUTPKTS]; stats64->tx_bytes = mib[IPSTATS_MIB_OUTOCTETS]; stats64->rx_errors = mib[IPSTATS_MIB_INDISCARDS]; stats64->tx_errors = mib[IPSTATS_MIB_OUTDISCARDS]; stats64->multicast = mib[IPSTATS_MIB_INMCASTPKTS]; stats64->rx_frame_errors = mib[IPSTATS_MIB_CSUMERRORS]; } int get_rtnl_link_stats_rta(struct rtnl_link_stats64 *stats64, struct rtattr *tb[]) { struct rtnl_link_stats stats; void *s; struct rtattr *rta; int size, len; if (tb[IFLA_STATS64]) { rta = tb[IFLA_STATS64]; size = sizeof(struct rtnl_link_stats64); s = stats64; } else if (tb[IFLA_STATS]) { rta = tb[IFLA_STATS]; size = sizeof(struct rtnl_link_stats); s = &stats; } else if (tb[IFLA_PROTINFO]) { struct rtattr *ptb[IPSTATS_MIB_MAX_LEN + 1]; parse_rtattr_nested(ptb, IPSTATS_MIB_MAX_LEN, tb[IFLA_PROTINFO]); if (ptb[IFLA_INET6_STATS]) get_snmp_counters(stats64, ptb[IFLA_INET6_STATS]); return sizeof(*stats64); } else { return -1; } len = RTA_PAYLOAD(rta); if (len < size) memset(s + len, 0, size - len); else len = size; memcpy(s, RTA_DATA(rta), len); if (s != stats64) copy_rtnl_link_stats64(stats64, s); return size; } #ifdef NEED_STRLCPY size_t strlcpy(char *dst, const char *src, size_t size) { size_t srclen = strlen(src); if (size) { size_t minlen = min(srclen, size - 1); memcpy(dst, src, minlen); dst[minlen] = '\0'; } return srclen; } size_t strlcat(char *dst, const char *src, size_t size) { size_t dlen = strlen(dst); if (dlen >= size) return dlen + strlen(src); return dlen + strlcpy(dst + dlen, src, size - dlen); } #endif void drop_cap(void) { #ifdef HAVE_LIBCAP /* don't harmstring root/sudo */ if (getuid() != 0 && geteuid() != 0) { cap_t capabilities; cap_value_t net_admin = CAP_NET_ADMIN; cap_flag_t inheritable = CAP_INHERITABLE; cap_flag_value_t is_set; capabilities = cap_get_proc(); if (!capabilities) exit(EXIT_FAILURE); if (cap_get_flag(capabilities, net_admin, inheritable, &is_set) != 0) exit(EXIT_FAILURE); /* apps with ambient caps can fork and call ip */ if (is_set == CAP_CLEAR) { if (cap_clear(capabilities) != 0) exit(EXIT_FAILURE); if (cap_set_proc(capabilities) != 0) exit(EXIT_FAILURE); } cap_free(capabilities); } #endif }