// SPDX-License-Identifier: LGPL-2.1-or-later /* * * BlueZ - Bluetooth protocol stack for Linux * * Copyright (C) 2011-2014 Intel Corporation * Copyright (C) 2002-2010 Marcel Holtmann * * */ #ifdef HAVE_CONFIG_H #include #endif #define _GNU_SOURCE #include #include #include #include #include "lib/bluetooth.h" #include "lib/uuid.h" #include "src/shared/util.h" #include "bt.h" #include "packet.h" #include "display.h" #include "l2cap.h" #include "sdp.h" #define MAX_TID 16 #define MAX_CONT_SIZE 17 struct tid_data { bool inuse; uint16_t tid; uint16_t channel; uint8_t cont[MAX_CONT_SIZE]; }; static struct tid_data tid_list[MAX_TID]; static struct tid_data *get_tid(uint16_t tid, uint16_t channel) { int i, n = -1; for (i = 0; i < MAX_TID; i++) { if (!tid_list[i].inuse) { if (n < 0) n = i; continue; } if (tid_list[i].tid == tid && tid_list[i].channel == channel) return &tid_list[i]; } if (n < 0) return NULL; tid_list[n].inuse = true; tid_list[n].tid = tid; tid_list[n].channel = channel; return &tid_list[n]; } static void clear_tid(struct tid_data *tid) { if (tid) tid->inuse = false; } static void print_uint(uint8_t indent, const uint8_t *data, uint32_t size) { switch (size) { case 1: print_field("%*c0x%2.2x", indent, ' ', data[0]); break; case 2: print_field("%*c0x%4.4x", indent, ' ', get_be16(data)); break; case 4: print_field("%*c0x%8.8x", indent, ' ', get_be32(data)); break; case 8: print_field("%*c0x%16.16" PRIx64, indent, ' ', get_be64(data)); break; default: packet_hexdump(data, size); break; } } static void print_sint(uint8_t indent, const uint8_t *data, uint32_t size) { packet_hexdump(data, size); } static void print_uuid(uint8_t indent, const uint8_t *data, uint32_t size) { switch (size) { case 2: print_field("%*c%s (0x%4.4x)", indent, ' ', bt_uuid16_to_str(get_be16(data)), get_be16(data)); break; case 4: print_field("%*c%s (0x%8.8x)", indent, ' ', bt_uuid32_to_str(get_be32(data)), get_be32(data)); break; case 16: /* BASE_UUID = 00000000-0000-1000-8000-00805F9B34FB */ print_field("%*c%8.8x-%4.4x-%4.4x-%4.4x-%4.4x%8.4x", indent, ' ', get_be32(data), get_be16(data + 4), get_be16(data + 6), get_be16(data + 8), get_be16(data + 10), get_be32(data + 12)); if (get_be16(data + 4) == 0x0000 && get_be16(data + 6) == 0x1000 && get_be16(data + 8) == 0x8000 && get_be16(data + 10) == 0x0080 && get_be32(data + 12) == 0x5F9B34FB) print_field("%*c%s", indent, ' ', bt_uuid32_to_str(get_be32(data))); break; default: packet_hexdump(data, size); break; } } static void print_string(uint8_t indent, const uint8_t *data, uint32_t size) { char *str = alloca(size + 1); str[size] = '\0'; strncpy(str, (const char *) data, size); print_field("%*c%s [len %d]", indent, ' ', str, size); } static void print_boolean(uint8_t indent, const uint8_t *data, uint32_t size) { print_field("%*c%s", indent, ' ', data[0] ? "true" : "false"); } #define SIZES(args...) ((uint8_t[]) { args, 0xff } ) static struct { uint8_t value; uint8_t *sizes; bool recurse; const char *str; void (*print) (uint8_t indent, const uint8_t *data, uint32_t size); } type_table[] = { { 0, SIZES(0), false, "Nil" }, { 1, SIZES(0, 1, 2, 3, 4), false, "Unsigned Integer", print_uint }, { 2, SIZES(0, 1, 2, 3, 4), false, "Signed Integer", print_sint }, { 3, SIZES(1, 2, 4), false, "UUID", print_uuid }, { 4, SIZES(5, 6, 7), false, "String", print_string }, { 5, SIZES(0), false, "Boolean", print_boolean }, { 6, SIZES(5, 6, 7), true, "Sequence" }, { 7, SIZES(5, 6, 7), true, "Alternative" }, { 8, SIZES(5, 6, 7), false, "URL", print_string }, { } }; static struct { uint8_t index; uint8_t bits; uint8_t size; const char *str; } size_table[] = { { 0, 0, 1, "1 byte" }, { 1, 0, 2, "2 bytes" }, { 2, 0, 4, "4 bytes" }, { 3, 0, 8, "8 bytes" }, { 4, 0, 16, "16 bytes" }, { 5, 8, 0, "8 bits" }, { 6, 16, 0, "16 bits" }, { 7, 32, 0, "32 bits" }, { } }; static bool valid_size(uint8_t size, uint8_t *sizes) { int i; for (i = 0; sizes[i] != 0xff; i++) { if (sizes[i] == size) return true; } return false; } static uint8_t get_bits(const uint8_t *data, uint32_t size) { int i; for (i = 0; size_table[i].str; i++) { if (size_table[i].index == (data[0] & 0x07)) return size_table[i].bits; } return 0; } static uint32_t get_size(const uint8_t *data, uint32_t size) { int i; for (i = 0; size_table[i].str; i++) { if (size_table[i].index == (data[0] & 0x07)) { switch (size_table[i].bits) { case 0: if ((data[0] & 0xf8) == 0) return 0; else return size_table[i].size; case 8: return data[1]; case 16: return get_be16(data + 1); case 32: return get_be32(data + 1); default: return 0; } } } return 0; } static void decode_data_elements(uint32_t position, uint8_t indent, const uint8_t *data, uint32_t size, void (*print_func) (uint32_t, uint8_t, uint8_t, const uint8_t *, uint32_t)) { uint32_t datalen, elemlen, extrabits; int i; if (!size) return; extrabits = get_bits(data, size); if (size < 1 + (extrabits / 8)) { print_text(COLOR_ERROR, "data element descriptor too short"); packet_hexdump(data, size); return; } datalen = get_size(data, size); if (size < 1 + (extrabits / 8) + datalen) { print_text(COLOR_ERROR, "data element size too short"); packet_hexdump(data, size); return; } elemlen = 1 + (extrabits / 8) + datalen; for (i = 0; type_table[i].str; i++) { uint8_t type = (data[0] & 0xf8) >> 3; if (type_table[i].value != type) continue; if (print_func) { print_func(position, indent, type, data + 1 + (extrabits / 8), datalen); break; } print_field("%*c%s (%d) with %u byte%s [%u extra bits] len %u", indent, ' ', type_table[i].str, type, datalen, datalen == 1 ? "" : "s", extrabits, elemlen); if (!valid_size(data[0] & 0x07, type_table[i].sizes)) { print_text(COLOR_ERROR, "invalid data element size"); packet_hexdump(data + 1 + (extrabits / 8), datalen); break; } if (type_table[i].recurse) decode_data_elements(0, indent + 2, data + 1 + (extrabits / 8), datalen, print_func); else if (type_table[i].print) type_table[i].print(indent + 2, data + 1 + (extrabits / 8), datalen); break; } if (elemlen > size) { print_text(COLOR_ERROR, "invalid data element size"); return; } data += elemlen; size -= elemlen; decode_data_elements(position + 1, indent, data, size, print_func); } static uint32_t get_bytes(const uint8_t *data, uint32_t size) { switch (data[0] & 0x07) { case 5: return 2 + data[1]; case 6: return 3 + get_be16(data + 1); case 7: return 5 + get_be32(data + 1); } return 0; } static struct { uint16_t id; const char *str; } attribute_table[] = { { 0x0000, "Service Record Handle" }, { 0x0001, "Service Class ID List" }, { 0x0002, "Service Record State" }, { 0x0003, "Service ID" }, { 0x0004, "Protocol Descriptor List" }, { 0x0005, "Browse Group List" }, { 0x0006, "Language Base Attribute ID List" }, { 0x0007, "Service Info Time To Live" }, { 0x0008, "Service Availability" }, { 0x0009, "Bluetooth Profile Descriptor List" }, { 0x000a, "Documentation URL" }, { 0x000b, "Client Executable URL" }, { 0x000c, "Icon URL" }, { 0x000d, "Additional Protocol Descriptor List" }, { } }; static void print_attr(uint32_t position, uint8_t indent, uint8_t type, const uint8_t *data, uint32_t size) { int i; if ((position % 2) == 0) { uint16_t id = get_be16(data); const char *str = "Unknown"; for (i = 0; attribute_table[i].str; i++) { if (attribute_table[i].id == id) str = attribute_table[i].str; } print_field("%*cAttribute: %s (0x%4.4x) [len %d]", indent, ' ', str, id, size); return; } for (i = 0; type_table[i].str; i++) { if (type_table[i].value != type) continue; if (type_table[i].recurse) decode_data_elements(0, indent + 2, data, size, NULL); else if (type_table[i].print) type_table[i].print(indent + 2, data, size); break; } } static void print_attr_list(uint32_t position, uint8_t indent, uint8_t type, const uint8_t *data, uint32_t size) { print_field("%*cAttribute list: [len %d] {position %d}", indent, ' ', size, position); decode_data_elements(0, indent + 2, data, size, print_attr); } static void print_attr_lists(uint32_t position, uint8_t indent, uint8_t type, const uint8_t *data, uint32_t size) { decode_data_elements(0, indent, data, size, print_attr_list); } static void print_continuation(const uint8_t *data, uint16_t size) { if (data[0] != size - 1) { print_text(COLOR_ERROR, "invalid continuation state"); packet_hexdump(data, size); return; } print_field("Continuation state: %d", data[0]); packet_hexdump(data + 1, size - 1); } static void store_continuation(struct tid_data *tid, const uint8_t *data, uint16_t size) { if (size > MAX_CONT_SIZE) { print_text(COLOR_ERROR, "invalid continuation size"); return; } memcpy(tid->cont, data, size); print_continuation(data, size); } #define MAX_CONT 8 struct cont_data { uint16_t channel; uint8_t cont[17]; void *data; uint32_t size; }; static struct cont_data cont_list[MAX_CONT]; static void handle_continuation(struct tid_data *tid, bool nested, uint16_t bytes, const uint8_t *data, uint16_t size) { uint8_t *newdata; int i, n = -1; if (bytes + 1 > size) { print_text(COLOR_ERROR, "missing continuation state"); return; } if (tid->cont[0] == 0x00 && data[bytes] == 0x00) { decode_data_elements(0, 2, data, bytes, nested ? print_attr_lists : print_attr_list); print_continuation(data + bytes, size - bytes); return; } for (i = 0; i < MAX_CONT; i++) { if (cont_list[i].cont[0] == 0x00) { if (n < 0) n = i; continue; } if (cont_list[i].channel != tid->channel) continue; if (cont_list[i].cont[0] != tid->cont[0]) continue; if (!memcmp(cont_list[i].cont + 1, tid->cont + 1, tid->cont[0])) { n = i; break; } } print_continuation(data + bytes, size - bytes); if (n < 0) return; newdata = realloc(cont_list[n].data, cont_list[n].size + bytes); if (!newdata) { print_text(COLOR_ERROR, "failed buffer allocation"); free(cont_list[n].data); cont_list[n].data = NULL; cont_list[n].size = 0; return; } cont_list[n].channel = tid->channel; cont_list[n].data = newdata; if (bytes > 0) { memcpy(cont_list[n].data + cont_list[n].size, data, bytes); cont_list[n].size += bytes; } if (data[bytes] == 0x00) { print_field("Combined attribute bytes: %d", cont_list[n].size); decode_data_elements(0, 2, cont_list[n].data, cont_list[n].size, nested ? print_attr_lists : print_attr_list); free(cont_list[n].data); cont_list[n].data = NULL; cont_list[n].size = 0; } else memcpy(cont_list[n].cont, data + bytes, data[bytes] + 1); } static uint16_t common_rsp(const struct l2cap_frame *frame, struct tid_data *tid) { uint16_t bytes; if (frame->size < 2) { print_text(COLOR_ERROR, "invalid size"); packet_hexdump(frame->data, frame->size); return 0; } bytes = get_be16(frame->data); print_field("Attribute bytes: %d", bytes); if (bytes > frame->size - 2) { print_text(COLOR_ERROR, "invalid attribute size"); packet_hexdump(frame->data + 2, frame->size - 2); return 0; } return bytes; } static const char *error_str(uint16_t code) { switch (code) { case 0x0001: return "Invalid Version"; case 0x0002: return "Invalid Record Handle"; case 0x0003: return "Invalid Syntax"; case 0x0004: return "Invalid PDU Size"; case 0x0005: return "Invalid Continuation State"; default: return "Unknown"; } } static void error_rsp(const struct l2cap_frame *frame, struct tid_data *tid) { uint16_t error; clear_tid(tid); if (frame->size < 2) { print_text(COLOR_ERROR, "invalid size"); packet_hexdump(frame->data, frame->size); return; } error = get_be16(frame->data); print_field("Error code: %s (0x%4.4x)", error_str(error), error); } static void service_req(const struct l2cap_frame *frame, struct tid_data *tid) { uint32_t search_bytes; search_bytes = get_bytes(frame->data, frame->size); print_field("Search pattern: [len %d]", search_bytes); if (search_bytes + 2 > frame->size) { print_text(COLOR_ERROR, "invalid search list length"); packet_hexdump(frame->data, frame->size); return; } decode_data_elements(0, 2, frame->data, search_bytes, NULL); print_field("Max record count: %d", get_be16(frame->data + search_bytes)); print_continuation(frame->data + search_bytes + 2, frame->size - search_bytes - 2); } static void service_rsp(const struct l2cap_frame *frame, struct tid_data *tid) { uint16_t count; int i; clear_tid(tid); if (frame->size < 4) { print_text(COLOR_ERROR, "invalid size"); packet_hexdump(frame->data, frame->size); return; } count = get_be16(frame->data + 2); if (count * 4 > frame->size) { print_text(COLOR_ERROR, "invalid record count"); return; } print_field("Total record count: %d", get_be16(frame->data)); print_field("Current record count: %d", count); for (i = 0; i < count; i++) print_field("Record handle: 0x%4.4x", get_be32(frame->data + 4 + (i * 4))); print_continuation(frame->data + 4 + (count * 4), frame->size - 4 - (count * 4)); } static void attr_req(const struct l2cap_frame *frame, struct tid_data *tid) { uint32_t attr_bytes; if (frame->size < 6) { print_text(COLOR_ERROR, "invalid size"); packet_hexdump(frame->data, frame->size); return; } print_field("Record handle: 0x%4.4x", get_be32(frame->data)); print_field("Max attribute bytes: %d", get_be16(frame->data + 4)); attr_bytes = get_bytes(frame->data + 6, frame->size - 6); print_field("Attribute list: [len %d]", attr_bytes); if (attr_bytes + 6 > frame->size) { print_text(COLOR_ERROR, "invalid attribute list length"); packet_hexdump(frame->data, frame->size); return; } decode_data_elements(0, 2, frame->data + 6, attr_bytes, NULL); store_continuation(tid, frame->data + 6 + attr_bytes, frame->size - 6 - attr_bytes); } static void attr_rsp(const struct l2cap_frame *frame, struct tid_data *tid) { uint16_t bytes; bytes = common_rsp(frame, tid); handle_continuation(tid, false, bytes, frame->data + 2, frame->size - 2); clear_tid(tid); } static void search_attr_req(const struct l2cap_frame *frame, struct tid_data *tid) { uint32_t search_bytes, attr_bytes; search_bytes = get_bytes(frame->data, frame->size); print_field("Search pattern: [len %d]", search_bytes); if (search_bytes + 2 > frame->size) { print_text(COLOR_ERROR, "invalid search list length"); packet_hexdump(frame->data, frame->size); return; } decode_data_elements(0, 2, frame->data, search_bytes, NULL); print_field("Max record count: %d", get_be16(frame->data + search_bytes)); attr_bytes = get_bytes(frame->data + search_bytes + 2, frame->size - search_bytes - 2); print_field("Attribute list: [len %d]", attr_bytes); if (search_bytes + attr_bytes > frame->size) { print_text(COLOR_ERROR, "invalid attribute list length"); return; } decode_data_elements(0, 2, frame->data + search_bytes + 2, attr_bytes, NULL); store_continuation(tid, frame->data + search_bytes + 2 + attr_bytes, frame->size - search_bytes - 2 - attr_bytes); } static void search_attr_rsp(const struct l2cap_frame *frame, struct tid_data *tid) { uint16_t bytes; bytes = common_rsp(frame, tid); handle_continuation(tid, true, bytes, frame->data + 2, frame->size - 2); clear_tid(tid); } struct sdp_data { uint8_t pdu; const char *str; void (*func) (const struct l2cap_frame *frame, struct tid_data *tid); }; static const struct sdp_data sdp_table[] = { { 0x01, "Error Response", error_rsp }, { 0x02, "Service Search Request", service_req }, { 0x03, "Service Search Response", service_rsp }, { 0x04, "Service Attribute Request", attr_req }, { 0x05, "Service Attribute Response", attr_rsp }, { 0x06, "Service Search Attribute Request", search_attr_req }, { 0x07, "Service Search Attribute Response", search_attr_rsp }, { } }; void sdp_packet(const struct l2cap_frame *frame) { uint8_t pdu; uint16_t tid, plen; struct l2cap_frame sdp_frame; struct tid_data *tid_info; const struct sdp_data *sdp_data = NULL; const char *pdu_color, *pdu_str; int i; l2cap_frame_pull(&sdp_frame, frame, 0); if (!l2cap_frame_get_u8(&sdp_frame, &pdu) || !l2cap_frame_get_be16(&sdp_frame, &tid) || !l2cap_frame_get_be16(&sdp_frame, &plen)) { print_text(COLOR_ERROR, "frame too short"); packet_hexdump(frame->data, frame->size); return; } if (sdp_frame.size != plen) { print_text(COLOR_ERROR, "invalid frame size"); packet_hexdump(sdp_frame.data, sdp_frame.size); return; } for (i = 0; sdp_table[i].str; i++) { if (sdp_table[i].pdu == pdu) { sdp_data = &sdp_table[i]; break; } } if (sdp_data) { if (sdp_data->func) { if (frame->in) pdu_color = COLOR_MAGENTA; else pdu_color = COLOR_BLUE; } else pdu_color = COLOR_WHITE_BG; pdu_str = sdp_data->str; } else { pdu_color = COLOR_WHITE_BG; pdu_str = "Unknown"; } print_indent(6, pdu_color, "SDP: ", pdu_str, COLOR_OFF, " (0x%2.2x) tid %d len %d", pdu, tid, plen); tid_info = get_tid(tid, frame->chan); if (!sdp_data || !sdp_data->func || !tid_info) { packet_hexdump(sdp_frame.data, sdp_frame.size); return; } sdp_data->func(&sdp_frame, tid_info); }