/* * Copyright (c) 1991, 1992 Paul Kranenburg * Copyright (c) 1993 Branko Lankester * Copyright (c) 1993, 1994, 1995, 1996 Rick Sladkey * Copyright (c) 1996-2000 Wichert Akkerman * Copyright (c) 2005-2016 Dmitry V. Levin * Copyright (c) 2016-2018 The strace developers. * 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. * 3. The name of the author may not be used to endorse or promote products * derived from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``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 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. */ #include "defs.h" #include "print_fields.h" #include #include #include #include #include "netlink.h" #include #include #include #include #include #ifdef HAVE_NETIPX_IPX_H # include #endif #include "xlat/addrfams.h" #include "xlat/arp_hardware_types.h" #include "xlat/ethernet_protocols.h" #include "xlat/af_packet_types.h" #include "xlat/bdaddr_types.h" #include "xlat/bluetooth_l2_cid.h" #include "xlat/bluetooth_l2_psm.h" #include "xlat/hci_channels.h" #define SIZEOF_SA_FAMILY sizeof(((struct sockaddr *) 0)->sa_family) const size_t arp_hardware_types_size = ARRAY_SIZE(arp_hardware_types) - 1; const size_t ethernet_protocols_size = ARRAY_SIZE(ethernet_protocols) - 1; static void print_sockaddr_data_un(const void *const buf, const int addrlen) { const struct sockaddr_un *const sa_un = buf; const int un_len = addrlen > (int) sizeof(*sa_un) ? (int) sizeof(*sa_un) : addrlen; const int path_len = un_len - SIZEOF_SA_FAMILY; tprints("sun_path="); if (sa_un->sun_path[0]) { print_quoted_string(sa_un->sun_path, path_len + 1, QUOTE_0_TERMINATED); } else { tprints("@"); print_quoted_string(sa_un->sun_path + 1, path_len - 1, 0); } } bool print_inet_addr(const int af, const void *const addr, const unsigned int len, const char *const var_name) { char buf[INET6_ADDRSTRLEN]; switch (af) { case AF_INET: if (inet_ntop(af, addr, buf, sizeof(buf))) { if (var_name) tprintf("%s=inet_addr(\"%s\")", var_name, buf); else tprints(buf); return true; } break; case AF_INET6: if (inet_ntop(af, addr, buf, sizeof(buf))) { if (var_name) tprintf("inet_pton(%s, \"%s\", &%s)", "AF_INET6", buf, var_name); else tprints(buf); return true; } break; } if (var_name) tprintf("%s=", var_name); print_quoted_string(addr, len, QUOTE_FORCE_HEX); return false; } bool decode_inet_addr(struct tcb *const tcp, const kernel_ulong_t addr, const unsigned int len, const int family, const char *const var_name) { union { struct in_addr a4; struct in6_addr a6; } addrbuf; size_t size = 0; switch (family) { case AF_INET: size = sizeof(addrbuf.a4); break; case AF_INET6: size = sizeof(addrbuf.a6); break; } if (!size || len < size) { if (var_name) tprintf("%s=", var_name); printstr_ex(tcp, addr, len, QUOTE_FORCE_HEX); return false; } if (umoven(tcp, addr, size, &addrbuf) < 0) { if (var_name) tprintf("%s=", var_name); printaddr(addr); return false; } return print_inet_addr(family, &addrbuf, size, var_name); } static void print_sockaddr_data_in(const void *const buf, const int addrlen) { const struct sockaddr_in *const sa_in = buf; PRINT_FIELD_NET_PORT("", *sa_in, sin_port); PRINT_FIELD_INET4_ADDR(", ", *sa_in, sin_addr); } #define SIN6_MIN_LEN offsetof(struct sockaddr_in6, sin6_scope_id) static void print_sockaddr_data_in6(const void *const buf, const int addrlen) { const struct sockaddr_in6 *const sa_in6 = buf; PRINT_FIELD_NET_PORT("", *sa_in6, sin6_port); PRINT_FIELD_INET_ADDR(", ", *sa_in6, sin6_addr, AF_INET6); tprintf(", sin6_flowinfo=htonl(%u)", ntohl(sa_in6->sin6_flowinfo)); if (addrlen <= (int) SIN6_MIN_LEN) return; #if defined IN6_IS_ADDR_LINKLOCAL && defined IN6_IS_ADDR_MC_LINKLOCAL if (IN6_IS_ADDR_LINKLOCAL(&sa_in6->sin6_addr) || IN6_IS_ADDR_MC_LINKLOCAL(&sa_in6->sin6_addr)) PRINT_FIELD_IFINDEX(", ", *sa_in6, sin6_scope_id); else #endif PRINT_FIELD_U(", ", *sa_in6, sin6_scope_id); } /** * Check that we can print an AX.25 address in its native form, otherwise it * makes sense to print it in raw also (or in raw only). */ enum xlat_style check_ax25_address(const ax25_address *addr) { enum xlat_style ret = XLAT_STYLE_DEFAULT; bool space_seen = false; bool char_seen = false; for (size_t i = 0; i < ARRAY_SIZE(addr->ax25_call) - 1; i++) { unsigned char c = addr->ax25_call[i]; /* The lowest bit should be zero */ if (c & 1) ret = XLAT_STYLE_VERBOSE; c >>= 1; if (c == ' ') space_seen = true; else char_seen = true; /* Sane address contains only numbers and uppercase letters */ if ((c < '0' || c > '9') && (c < 'A' || c > 'Z') && c != ' ') ret = XLAT_STYLE_VERBOSE; if (c != ' ' && space_seen) ret = XLAT_STYLE_VERBOSE; /* non-printable chars */ if (c < ' ' || c > 0x7e /* characters used for printing comments */ || c == '*' || c == '/') return XLAT_STYLE_RAW; } if (addr->ax25_call[ARRAY_SIZE(addr->ax25_call) - 1] & ~0x1e) ret = XLAT_STYLE_VERBOSE; if (!char_seen && addr->ax25_call[ARRAY_SIZE(addr->ax25_call) - 1]) ret = XLAT_STYLE_VERBOSE; return ret; } /** Convert a (presumably) valid AX.25 to a string */ static const char * ax25_addr2str(const ax25_address *addr) { static char buf[ARRAY_SIZE(addr->ax25_call) + sizeof("-15")]; char *p = buf; size_t end; for (end = ARRAY_SIZE(addr->ax25_call) - 1; end; end--) if ((addr->ax25_call[end - 1] >> 1) != ' ') break; for (size_t i = 0; i < end; i++) *p++ = ((unsigned char) addr->ax25_call[i]) >> 1; *p++ = '-'; unsigned char ssid = (addr->ax25_call[ARRAY_SIZE(addr->ax25_call) - 1] >> 1) & 0xf; if (ssid > 9) { *p++ = '1'; ssid -= 10; } *p++ = ssid + '0'; *p = '\0'; if (buf[0] == '-' && buf[1] == '0') return "*"; return buf; } static void print_ax25_addr_raw(const ax25_address *addr) { PRINT_FIELD_HEX_ARRAY("{", *addr, ax25_call); tprints("}"); } void print_ax25_addr(const void /* ax25_address */ *addr_void) { const ax25_address *addr = addr_void; enum xlat_style xs = check_ax25_address(addr); if (xs == XLAT_STYLE_DEFAULT) xs = xlat_verbose(xlat_verbosity); if (xs != XLAT_STYLE_ABBREV) print_ax25_addr_raw(addr); if (xs == XLAT_STYLE_RAW) return; const char *addr_str = ax25_addr2str(addr); (xs == XLAT_STYLE_VERBOSE ? tprints_comment : tprints)(addr_str); } static void print_sockaddr_data_ax25(const void *const buf, const int addrlen) { const struct full_sockaddr_ax25 *const sax25 = buf; size_t addrlen_us = MAX(addrlen, 0); bool full = sax25->fsa_ax25.sax25_ndigis || (addrlen_us > sizeof(struct sockaddr_ax25)); if (full) tprints("fsa_ax25={"); tprints("sax25_call="); print_ax25_addr(&sax25->fsa_ax25.sax25_call); PRINT_FIELD_D(", ", sax25->fsa_ax25, sax25_ndigis); if (!full) return; tprints("}"); size_t has_digis = MIN((addrlen_us - sizeof(sax25->fsa_ax25)) / sizeof(sax25->fsa_digipeater[0]), ARRAY_SIZE(sax25->fsa_digipeater)); size_t want_digis = MIN( (unsigned int) MAX(sax25->fsa_ax25.sax25_ndigis, 0), ARRAY_SIZE(sax25->fsa_digipeater)); size_t digis = MIN(has_digis, want_digis); if (want_digis == 0) goto digis_end; tprints(", fsa_digipeater=["); for (size_t i = 0; i < digis; i++) { if (i) tprints(", "); print_ax25_addr(sax25->fsa_digipeater + i); } if (want_digis > has_digis) tprintf("%s/* ??? */", digis ? ", " : ""); tprints("]"); digis_end: if (addrlen_us > (has_digis * sizeof(sax25->fsa_digipeater[0]) + sizeof(sax25->fsa_ax25))) tprints(", ..."); } void print_x25_addr(const void /* struct x25_address */ *addr_void) { const struct x25_address *addr = addr_void; tprints("{x25_addr="); print_quoted_cstring(addr->x25_addr, sizeof(addr->x25_addr)); tprints("}"); } static void print_sockaddr_data_x25(const void *const buf, const int addrlen) { const struct sockaddr_x25 *const sa_x25 = buf; PRINT_FIELD_X25_ADDR("", *sa_x25, sx25_addr); } static void print_sockaddr_data_nl(const void *const buf, const int addrlen) { const struct sockaddr_nl *const sa_nl = buf; PRINT_FIELD_D("", *sa_nl, nl_pid); PRINT_FIELD_0X(", ", *sa_nl, nl_groups); } static void print_sockaddr_data_ll(const void *const buf, const int addrlen) { const struct sockaddr_ll *const sa_ll = buf; tprints("sll_protocol=htons("); printxval_search(ethernet_protocols, ntohs(sa_ll->sll_protocol), "ETH_P_???"); PRINT_FIELD_IFINDEX("), ", *sa_ll, sll_ifindex); tprints(", sll_hatype="); printxval_search(arp_hardware_types, sa_ll->sll_hatype, "ARPHRD_???"); tprints(", sll_pkttype="); printxval_index(af_packet_types, sa_ll->sll_pkttype, "PACKET_???"); tprintf(", sll_halen=%u", sa_ll->sll_halen); if (sa_ll->sll_halen) { const unsigned int oob_halen = addrlen - offsetof(struct sockaddr_ll, sll_addr); unsigned int i; tprints(", sll_addr=["); for (i = 0; i < sa_ll->sll_halen; ++i) { if (i) tprints(", "); if (i >= oob_halen) { tprints("..."); break; } tprintf("%#02x", sa_ll->sll_addr[i]); } tprints("]"); } } static void print_sockaddr_data_raw(const void *const buf, const int addrlen) { const char *const data = buf + SIZEOF_SA_FAMILY; const int datalen = addrlen - SIZEOF_SA_FAMILY; tprints("sa_data="); print_quoted_string(data, datalen, 0); } static uint16_t btohs(uint16_t val) { #ifdef WORDS_BIGENDIAN return (val << 8) | (val >> 8); #else return val; #endif } static void print_bluetooth_l2_psm(const char *prefix, uint16_t psm) { const uint16_t psm_he = btohs(psm); const char *psm_name = xlookup(bluetooth_l2_psm, psm_he); const bool psm_str = psm_name || (psm_he >= L2CAP_PSM_LE_DYN_START && psm_he <= L2CAP_PSM_LE_DYN_END) || (psm_he >= L2CAP_PSM_DYN_START); tprintf("%shtobs(", prefix); if (xlat_verbose(xlat_verbosity) != XLAT_STYLE_ABBREV || !psm_str) tprintf("%#x", psm_he); if (xlat_verbose(xlat_verbosity) == XLAT_STYLE_RAW) goto print_bluetooth_l2_psm_end; if (xlat_verbose(xlat_verbosity) == XLAT_STYLE_VERBOSE || !psm_str) tprints(" /* "); if (psm_name) { tprints(psm_name); } else if (psm_he >= L2CAP_PSM_LE_DYN_START && psm_he <= L2CAP_PSM_LE_DYN_END) { print_xlat(L2CAP_PSM_LE_DYN_START); tprintf(" + %u", psm_he - L2CAP_PSM_LE_DYN_START); } else if (psm_he >= L2CAP_PSM_DYN_START) { print_xlat(L2CAP_PSM_DYN_START); tprintf(" + %u", psm_he - L2CAP_PSM_DYN_START); } else { tprints("L2CAP_PSM_???"); } if (xlat_verbose(xlat_verbosity) == XLAT_STYLE_VERBOSE || !psm_str) tprints(" */"); print_bluetooth_l2_psm_end: tprints(")"); } static void print_bluetooth_l2_cid(const char *prefix, uint16_t cid) { const uint16_t cid_he = btohs(cid); const char *cid_name = xlookup(bluetooth_l2_cid, cid_he); const bool cid_str = cid_name || (cid_he >= L2CAP_CID_DYN_START); tprintf("%shtobs(", prefix); if (xlat_verbose(xlat_verbosity) != XLAT_STYLE_ABBREV || !cid_str) tprintf("%#x", cid_he); if (xlat_verbose(xlat_verbosity) == XLAT_STYLE_RAW) goto print_bluetooth_l2_cid_end; if (xlat_verbose(xlat_verbosity) == XLAT_STYLE_VERBOSE || !cid_str) tprints(" /* "); if (cid_name) { tprints(cid_name); } else if (cid_he >= L2CAP_CID_DYN_START) { print_xlat(L2CAP_CID_DYN_START); tprintf(" + %u", cid_he - L2CAP_CID_DYN_START); } else { tprints("L2CAP_CID_???"); } if (xlat_verbose(xlat_verbosity) == XLAT_STYLE_VERBOSE || !cid_str) tprints(" */"); print_bluetooth_l2_cid_end: tprints(")"); } static void print_sockaddr_data_bt(const void *const buf, const int addrlen) { struct sockaddr_hci { /* sa_family_t */ uint16_t hci_family; uint16_t hci_dev; uint16_t hci_channel; }; struct bdaddr { uint8_t b[6]; } ATTRIBUTE_PACKED; struct sockaddr_sco { /* sa_family_t */ uint16_t sco_family; struct bdaddr sco_bdaddr; }; struct sockaddr_rc { /* sa_family_t */ uint16_t rc_family; struct bdaddr rc_bdaddr; uint8_t rc_channel; }; struct sockaddr_l2 { /* sa_family_t */ uint16_t l2_family; /* little endian */ uint16_t l2_psm; struct bdaddr l2_bdaddr; /* little endian */ uint16_t l2_cid; uint8_t l2_bdaddr_type; }; switch (addrlen) { case sizeof(struct sockaddr_hci): { const struct sockaddr_hci *const hci = buf; tprintf("hci_dev=htobs(%hu), hci_channel=", btohs(hci->hci_dev)); printxval_index(hci_channels, hci->hci_channel, "HCI_CHANNEL_???"); break; } case sizeof(struct sockaddr_sco): { const struct sockaddr_sco *const sco = buf; print_mac_addr("sco_bdaddr=", sco->sco_bdaddr.b, sizeof(sco->sco_bdaddr.b)); break; } case sizeof(struct sockaddr_rc): { const struct sockaddr_rc *const rc = buf; print_mac_addr("rc_bdaddr=", rc->rc_bdaddr.b, sizeof(rc->rc_bdaddr.b)); tprintf(", rc_channel=%u", rc->rc_channel); break; } case offsetof(struct sockaddr_l2, l2_bdaddr_type): case sizeof(struct sockaddr_l2): { const struct sockaddr_l2 *const l2 = buf; print_bluetooth_l2_psm("l2_psm=", l2->l2_psm); print_mac_addr(", l2_bdaddr=", l2->l2_bdaddr.b, sizeof(l2->l2_bdaddr.b)); print_bluetooth_l2_cid(", l2_cid=", l2->l2_cid); if (addrlen == sizeof(struct sockaddr_l2)) { tprints(", l2_bdaddr_type="); printxval_index(bdaddr_types, l2->l2_bdaddr_type, "BDADDR_???"); } break; } default: print_sockaddr_data_raw(buf, addrlen); break; } } typedef void (* const sockaddr_printer)(const void *const, const int); static const struct { const sockaddr_printer printer; const int min_len; } sa_printers[] = { [AF_UNIX] = { print_sockaddr_data_un, SIZEOF_SA_FAMILY + 1 }, [AF_INET] = { print_sockaddr_data_in, sizeof(struct sockaddr_in) }, [AF_AX25] = { print_sockaddr_data_ax25, sizeof(struct sockaddr_ax25) }, [AF_X25] = { print_sockaddr_data_x25, sizeof(struct sockaddr_x25) }, [AF_INET6] = { print_sockaddr_data_in6, SIN6_MIN_LEN }, [AF_NETLINK] = { print_sockaddr_data_nl, SIZEOF_SA_FAMILY + 1 }, [AF_PACKET] = { print_sockaddr_data_ll, sizeof(struct sockaddr_ll) }, [AF_BLUETOOTH] = { print_sockaddr_data_bt, SIZEOF_SA_FAMILY + 1 }, }; void print_sockaddr(const void *const buf, const int addrlen) { const struct sockaddr *const sa = buf; tprints("{sa_family="); printxval_index(addrfams, sa->sa_family, "AF_???"); if (addrlen > (int) SIZEOF_SA_FAMILY) { tprints(", "); if (sa->sa_family < ARRAY_SIZE(sa_printers) && sa_printers[sa->sa_family].printer && addrlen >= sa_printers[sa->sa_family].min_len) { sa_printers[sa->sa_family].printer(buf, addrlen); } else { print_sockaddr_data_raw(buf, addrlen); } } tprints("}"); } int decode_sockaddr(struct tcb *const tcp, const kernel_ulong_t addr, int addrlen) { if (addrlen < 2) { printaddr(addr); return -1; } union { struct sockaddr sa; struct sockaddr_storage storage; char pad[sizeof(struct sockaddr_storage) + 1]; } addrbuf; if ((unsigned) addrlen > sizeof(addrbuf.storage)) addrlen = sizeof(addrbuf.storage); if (umoven_or_printaddr(tcp, addr, addrlen, addrbuf.pad)) return -1; memset(&addrbuf.pad[addrlen], 0, sizeof(addrbuf.pad) - addrlen); print_sockaddr(&addrbuf, addrlen); return addrbuf.sa.sa_family; }