// SPDX-License-Identifier: GPL-2.0-or-later /* * * BlueZ - Bluetooth protocol stack for Linux * * Copyright (C) 2012 Intel Corporation. All rights reserved. * * */ #ifdef HAVE_CONFIG_H #include #endif #define _GNU_SOURCE #include #include #include #include #include #include #include #include #include "bluetooth/bluetooth.h" #include "src/shared/ad.h" #include "src/shared/btp.h" #include "src/shared/io.h" #include "src/shared/mainloop.h" #include "src/shared/queue.h" #include "src/shared/shell.h" #include "src/shared/util.h" #define DEFAULT_SOCKET_PATH "/tmp/bt-stack-tester" #define PROMPT_ON COLOR_BLUE "[btpclient]" COLOR_OFF "> " #define EVT_OPCODE_BASE 0x80 #define DEFAULT_INDEX 0x00 struct ad_data { uint8_t data[25]; uint8_t len; }; struct name_func_entry { const char *name; void (*func)(void); }; struct indexstr_data { int index; const char *str; }; struct bitfield_data { uint32_t bit; const char *str; }; struct opcode_data { uint8_t opcode; int bit; const char *str; void (*cmd_func)(const void *data, uint16_t size); uint16_t cmd_size; bool cmd_fixed; void (*rsp_func)(const void *data, uint16_t size); uint16_t rsp_size; bool rsp_fixed; void (*evt_func)(const void *data, uint16_t size); uint16_t evt_size; bool evt_fixed; }; struct service_data { uint8_t id; int bit; const char *str; const struct opcode_data *opcode_table; }; struct advertise_data { struct bt_ad *ad; struct bt_ad *scan; }; struct client_data { int fd; /* Incoming buffer for response and event */ uint8_t buf[512]; }; struct btpclientctl { int server_fd; char *socket_path; bool debug_enabled; bool enable_dump; bool client_active; struct client_data *client_data; /* Outgoing buffer for command */ uint8_t buf[560]; uint16_t buf_len; }; static struct advertise_data *advertise_data; static struct btpclientctl *btpclientctl; static uint8_t bt_index = DEFAULT_INDEX; static void hexdump_print(const char *str, void *user_data) { bt_shell_printf("%s%s\n", (char *) user_data, str); } static bool parse_argument_on_off(int argc, char *argv[], uint8_t *val) { if (!strcasecmp(argv[1], "on") || !strcasecmp(argv[1], "yes")) *val = 1; else if (!strcasecmp(argv[1], "off") || !strcasecmp(argv[1], "no")) *val = 0; else *val = atoi(argv[1]); return true; } static bool parse_argument_list(int argc, char *argv[], uint8_t *val, const struct indexstr_data *table) { int i; for (i = 0; table[i].str; i++) { if (strcasecmp(argv[1], table[i].str) == 0) { *val = table[i].index; return true; } } bt_shell_printf("Invalid argument %s\n", argv[1]); return false; } static bool parse_argument_bitfield_list(int argc, char *argv[], uint32_t *val, const struct bitfield_data *table) { int i; for (i = 0; table[i].str; i++) { if (strcasecmp(argv[0], table[i].str) == 0) { *val = table[i].bit; return true; } } bt_shell_printf("Invalid argument %s\n", argv[0]); return false; } static bool parse_argument_addr(int argc, char *argv[], uint8_t *addr_type, bdaddr_t *bdaddr) { if (argc < 3) { bt_shell_printf("Invalid parameter\n"); return false; } *addr_type = atoi(argv[1]); str2ba(argv[2], bdaddr); return true; } static char *argument_gen(const char *text, int state, const struct indexstr_data *list) { static int index, len; const char *arg; if (!state) { index = 0; len = strlen(text); } while ((arg = list[index].str)) { index++; if (!strncasecmp(arg, text, len)) return strdup(arg); } return NULL; } static char *argument_gen_bitfield(const char *text, int state, const struct bitfield_data *list) { static int index, len; const char *arg; if (!state) { index = 0; len = strlen(text); } while ((arg = list[index].str)) { index++; if (!strncasecmp(arg, text, len)) return strdup(arg); } return NULL; } static char *argument_gen_name_func_entry(const char *text, int state, const struct name_func_entry *list) { static int index, len; const char *arg; if (!state) { index = 0; len = strlen(text); } while ((arg = list[index].name)) { index++; if (!strncasecmp(arg, text, len)) return strdup(arg); } return NULL; } static const struct service_data service_table[]; static const struct service_data *find_service_data(uint8_t service_id) { int i; for (i = 0; service_table[i].str; i++) { if (service_table[i].id == service_id) return &service_table[i]; } return NULL; } static const struct opcode_data *find_opcode_data(uint8_t opcode, const struct opcode_data *table) { int i; for (i = 0; table[i].str; i++) { if (table[i].opcode == opcode) return &table[i]; } return NULL; } static const char *get_indexstr(int val, const struct indexstr_data *table) { int i; for (i = 0; table[i].str; i++) { if (val == table[i].index) return table[i].str; } return "Unknown"; } static uint32_t print_bitfield(uint32_t val, const struct bitfield_data *table, const char *prefix) { uint32_t mask = val; int i; for (i = 0; table[i].str; i++) { if (val & (((uint32_t) 1) << table[i].bit)) { bt_shell_printf("%s%s (0x%4.4x)\n", prefix, table[i].str, table[i].bit); mask &= ~(((uint32_t) 1) << table[i].bit); } } return mask; } static void print_bdaddr(const bdaddr_t *address, uint8_t address_type) { char addr[18]; ba2str(address, addr); if (address_type == BTP_GAP_ADDR_PUBLIC) bt_shell_printf("\t%s (public)\n", addr); else if (address_type == BTP_GAP_ADDR_RANDOM) bt_shell_printf("\t%s (random)\n", addr); else bt_shell_printf("\t%s (unknown)\n", addr); } static void null_cmd(const void *data, uint16_t size) { /* Empty */ } static void null_rsp(const void *data, uint16_t size) { /* Empty */ } static void null_evt(const void *data, uint16_t size) { /* Empty */ } static const struct indexstr_data error_table[] = { { 0x01, "Failed" }, { 0x02, "Unknown Command" }, { 0x03, "Not Ready" }, { 0x04, "Invalid Index" }, { } }; static void print_error_rsp(const void *data, uint16_t size) { uint8_t reason = ((uint8_t *)data)[0]; bt_shell_printf(COLOR_RED "\tReason: %s (%d)\n" COLOR_OFF, get_indexstr(reason, error_table), reason); } static const char *service_to_str(uint8_t service_id) { int i; for (i = 0; service_table[i].str; i++) { if (service_table[i].id == service_id) return service_table[i].str; } return "Unknown Service ID"; } static const char *get_supported_service(int bit) { int i; for (i = 0; service_table[i].str; i++) { if (service_table[i].bit == bit) return service_table[i].str; } return NULL; } static const char *get_supported_command(const struct opcode_data *table, int bit) { int i; for (i = 0; table[i].str; i++) { if (table[i].bit == bit) return table[i].str; } return NULL; } static void print_btp_hdr(struct btp_hdr *btp_hdr, const char *type_str, const char *opcode_str) { bt_shell_printf("%s: %s(%d) %s(0x%02x) INDEX(0x%02x)\n", type_str, service_to_str(btp_hdr->service), btp_hdr->service, opcode_str, btp_hdr->opcode, btp_hdr->index); } static const struct opcode_data opcode_table_core[]; static void print_core_read_supported_commands_rsp(const void *data, uint16_t size) { uint8_t cmds; const char *str; int i, bit; cmds = ((uint8_t *)data)[0]; for (i = 1; i < (int)(sizeof(cmds) * 8); i++) { bit = 0; bit = 1 << i; if (cmds & bit) { str = get_supported_command(opcode_table_core, i); if (str) bt_shell_printf("\t%s (Bit %d)\n", str, i); else bt_shell_printf("\tUNKNOWN (Bit %d)\n", i); } } } static void print_core_read_supported_services_rsp(const void *data, uint16_t size) { uint8_t services; const char *str; int i, bit; services = ((uint8_t *)data)[0]; for (i = 0; i < (int)(sizeof(services) * 8); i++) { bit = 1 << i; if (services & bit) { str = get_supported_service(i); if (str) bt_shell_printf("\t%s (Bit %d)\n", str, i); else bt_shell_printf("\tUNKNOWN (Bit %d)\n", i); } } } static void print_core_register_service_cmd(const void *data, uint16_t size) { const struct btp_core_register_cp *cp = data; bt_shell_printf("\tService ID: %s(0x%02x)\n", service_to_str(cp->service_id), cp->service_id); } static void print_core_unregister_service_cmd(const void *data, uint16_t size) { const struct btp_core_unregister_cp *cp = data; bt_shell_printf("\tService ID: %s(0x%02x)\n", service_to_str(cp->service_id), cp->service_id); } static const struct opcode_data opcode_table_core[] = { { 0x00, 0, "Error", null_cmd, 0, true, print_error_rsp, 1, true }, { 0x01, 1, "Read Supported Commands", null_cmd, 0, true, print_core_read_supported_commands_rsp, 1, true }, { 0x02, 2, "Read Supported Services", null_cmd, 0, true, print_core_read_supported_services_rsp, 1, true }, { 0x03, 3, "Register Service", print_core_register_service_cmd, 1, true, null_rsp, 0, true }, { 0x04, 4, "Unregister Service", print_core_unregister_service_cmd, 1, true, null_rsp, 0, true }, { 0x80, -1, "IUT Ready", null_cmd, 0, true, null_rsp, 0, true, null_evt, 0, true }, { } }; static const struct opcode_data opcode_table_gap[]; static void print_gap_read_supported_commands_rsp(const void *data, uint16_t size) { uint16_t cmds; const char *str; int i; cmds = le16_to_cpu(((uint16_t *)data)[0]); for (i = 1; i < (int)(sizeof(cmds) * 8); i++) { if (cmds & (1 << i)) { str = get_supported_command(opcode_table_gap, i); if (str) bt_shell_printf("\t%s (Bit %d)\n", str, i); else bt_shell_printf("\tUNKNOWN (Bit %d)\n", i); } } } static void print_gap_read_controller_index_list_rsp(const void *data, uint16_t size) { const struct btp_gap_read_index_rp *list = data; int i; for (i = 0; i < list->num; i++) bt_shell_printf("\tIndex: %d\n", list->indexes[i]); } static const struct bitfield_data gap_setting_table[] = { { 0, "Powered" }, { 1, "Connectable" }, { 2, "Fast Connectable" }, { 3, "Discoverable" }, { 4, "Bondable" }, { 5, "Link Layer Security" }, { 6, "Secure Simple Pairing" }, { 7, "BR/EDR" }, { 8, "High Speed" }, { 9, "Low Energy" }, { 10, "Advertising" }, { 11, "Secure Connection" }, { 12, "Debug Keys" }, { 13, "Privacy" }, { 14, "Controller Configuration" }, { 15, "Static Address" }, { } }; static void print_gap_settings(uint32_t val, const struct bitfield_data *table, const char *prefix) { uint32_t mask; mask = print_bitfield(val, table, prefix); if (mask) bt_shell_printf("%sUnknown settings (0x%4.4x)\n", prefix, mask); } static void print_gap_read_controller_information_rsp(const void *data, uint16_t size) { const struct btp_gap_read_info_rp *info = data; char addr[18]; ba2str(&info->address, addr); bt_shell_printf("\tAddress: %s\n", addr); bt_shell_printf("\tSupported Settings\n"); print_gap_settings(le32_to_cpu(info->supported_settings), gap_setting_table, "\t\t"); bt_shell_printf("\tCurrent Settings\n"); print_gap_settings(le32_to_cpu(info->current_settings), gap_setting_table, "\t\t"); bt_shell_printf("\tClass: 0x%02x%02x%02x\n", info->cod[2], info->cod[1], info->cod[0]); bt_shell_printf("\tShort: %s\n", info->short_name); bt_shell_printf("\tName: %s\n", info->name); } static void print_gap_reset_rsp(const void *data, uint16_t size) { const struct btp_gap_reset_rp *rp = data; print_gap_settings(le32_to_cpu(rp->current_settings), gap_setting_table, "\t"); } static const struct indexstr_data on_off_table[] = { { 0x00, "Off" }, { 0x01, "On" }, { } }; static void print_gap_set_powered_cmd(const void *data, uint16_t size) { const struct btp_gap_set_powered_cp *cp = data; bt_shell_printf("\tSet Power: %s (%d)\n", get_indexstr(cp->powered, on_off_table), cp->powered); } static void print_gap_set_powered_rsp(const void *data, uint16_t size) { const struct btp_gap_set_powered_rp *rp = data; print_gap_settings(le32_to_cpu(rp->current_settings), gap_setting_table, "\t"); } static void print_gap_set_connectable_cmd(const void *data, uint16_t size) { const struct btp_gap_set_connectable_cp *cp = data; bt_shell_printf("\t Set Connectable: %s (%d)\n", get_indexstr(cp->connectable, on_off_table), cp->connectable); } static void print_gap_set_connectable_rsp(const void *data, uint16_t size) { const struct btp_gap_set_connectable_rp *rp = data; print_gap_settings(le32_to_cpu(rp->current_settings), gap_setting_table, "\t"); } static void print_gap_set_fast_connectable_cmd(const void *data, uint16_t size) { const struct btp_gap_set_fast_connectable_cp *cp = data; bt_shell_printf("\t Set Fast Connectable: %s (%d)\n", get_indexstr(cp->fast_connectable, on_off_table), cp->fast_connectable); } static void print_gap_set_fast_connectable_rsp(const void *data, uint16_t size) { const struct btp_gap_set_fast_connectable_rp *rp = data; print_gap_settings(le32_to_cpu(rp->current_settings), gap_setting_table, "\t"); } static const struct indexstr_data gap_discoverable_table[] = { { 0x00, "Off" }, { 0x01, "On" }, { 0x02, "Limited" }, { } }; static void print_gap_set_discoverable_cmd(const void *data, uint16_t size) { const struct btp_gap_set_discoverable_cp *cp = data; bt_shell_printf("\t Set Discoverable: %s (%d)\n", get_indexstr(cp->discoverable, gap_discoverable_table), cp->discoverable); } static void print_gap_set_discoverable_rsp(const void *data, uint16_t size) { const struct btp_gap_set_discoverable_rp *rp = data; print_gap_settings(le32_to_cpu(rp->current_settings), gap_setting_table, "\t"); } static void print_gap_set_bondable_cmd(const void *data, uint16_t size) { const struct btp_gap_set_bondable_cp *cp = data; bt_shell_printf("\t Set Bondable: %s (%d)\n", get_indexstr(cp->bondable, on_off_table), cp->bondable); } static void print_gap_set_bondable_rsp(const void *data, uint16_t size) { const struct btp_gap_set_bondable_rp *rp = data; print_gap_settings(le32_to_cpu(rp->current_settings), gap_setting_table, "\t"); } const struct indexstr_data ad_type_table[] = { { 0x01, "BT_AD_FLAGS" }, { 0x02, "BT_AD_UUID16_SOME" }, { 0x03, "BT_AD_UUID16_ALL" }, { 0x04, "BT_AD_UUID32_SOME" }, { 0x05, "BT_AD_UUID32_ALL" }, { 0x06, "BT_AD_UUID128_SOME" }, { 0x07, "BT_AD_UUID128_ALL" }, { 0x08, "BT_AD_NAME_SHORT" }, { 0x09, "BT_AD_NAME_COMPLETE" }, { 0x0a, "BT_AD_TX_POWER" }, { 0x0d, "BT_AD_CLASS_OF_DEV" }, { 0x0e, "BT_AD_SSP_HASH" }, { 0x0f, "BT_AD_SSP_RANDOMIZER" }, { 0x10, "BT_AD_DEVICE_ID" }, { 0x10, "BT_AD_SMP_TK" }, { 0x11, "BT_AD_SMP_OOB_FLAGS" }, { 0x12, "BT_AD_PERIPHERAL_CONN_INTERVAL" }, { 0x14, "BT_AD_SOLICIT16" }, { 0x15, "BT_AD_SOLICIT128" }, { 0x16, "BT_AD_SERVICE_DATA16" }, { 0x17, "BT_AD_PUBLIC_ADDRESS" }, { 0x18, "BT_AD_RANDOM_ADDRESS" }, { 0x19, "BT_AD_GAP_APPEARANCE" }, { 0x1a, "BT_AD_ADVERTISING_INTERVAL" }, { 0x1b, "BT_AD_LE_DEVICE_ADDRESS" }, { 0x1c, "BT_AD_LE_ROLE" }, { 0x1d, "BT_AD_SSP_HASH_P256" }, { 0x1e, "BT_AD_SSP_RANDOMIZER_P256" }, { 0x1f, "BT_AD_SOLICIT32" }, { 0x20, "BT_AD_SERVICE_DATA32" }, { 0x21, "BT_AD_SERVICE_DATA128" }, { 0x22, "BT_AD_LE_SC_CONFIRM_VALUE" }, { 0x23, "BT_AD_LE_SC_RANDOM_VALUE" }, { 0x24, "BT_AD_URI" }, { 0x25, "BT_AD_INDOOR_POSITIONING" }, { 0x26, "BT_AD_TRANSPORT_DISCOVERY" }, { 0x27, "BT_AD_LE_SUPPORTED_FEATURES" }, { 0x28, "BT_AD_CHANNEL_MAP_UPDATE_IND" }, { 0x29, "BT_AD_MESH_PROV" }, { 0x2a, "BT_AD_MESH_DATA" }, { 0x2b, "BT_AD_MESH_BEACON" }, { 0x3d, "BT_AD_3D_INFO_DATA" }, { 0xff, "BT_AD_MANUFACTURER_DATA" } }; struct ad_struct { uint8_t length; uint8_t type; uint8_t data[0]; }; static void print_ad_data(const uint8_t *data, size_t data_len) { struct ad_struct *ad_struct; size_t count = 0; if (!data || !data_len) { bt_shell_printf("\tEmpty\n"); return; } while (count < data_len) { ad_struct = (struct ad_struct *)(data + count); bt_shell_printf("Type: %s(0x%02x)\n", get_indexstr(ad_struct->type, ad_type_table), ad_struct->type); bt_shell_hexdump(ad_struct->data, ad_struct->length - 1); count += ad_struct->length + 1; } } static void print_gap_start_advertising_cmd(const void *data, uint16_t size) { const struct btp_gap_start_adv_cp *cp = data; if (cp->adv_data_len) { bt_shell_printf("\tAdvertising Data:\n"); print_ad_data(cp->data, cp->adv_data_len); } if (cp->scan_rsp_len) { bt_shell_printf("\tScan Response Data:\n"); print_ad_data(cp->data + cp->adv_data_len, cp->scan_rsp_len); } } static void print_gap_start_advertising_rsp(const void *data, uint16_t size) { const struct btp_gap_start_adv_rp *rp = data; print_gap_settings(le32_to_cpu(rp->current_settings), gap_setting_table, "\t"); } static void print_gap_stop_advertising_rsp(const void *data, uint16_t size) { const struct btp_gap_start_adv_rp *rp = data; print_gap_settings(le32_to_cpu(rp->current_settings), gap_setting_table, "\t"); } static const struct bitfield_data gap_discovery_flags_table[] = { { 0, "LE" }, { 1, "BREDE" }, { 2, "Limited" }, { 3, "Active" }, { 4, "Observation" }, { } }; static void print_gap_start_discovery_cmd(const void *data, uint16_t size) { const struct btp_gap_start_discovery_cp *cp = data; uint32_t mask; mask = print_bitfield(le32_to_cpu(cp->flags), gap_discovery_flags_table, "\t\t"); if (mask) bt_shell_printf("\t\tUnknown flags (0x%4.4x)\n", mask); } static void print_gap_connect_cmd(const void *data, uint16_t size) { const struct btp_gap_connect_cp *cp = data; print_bdaddr(&cp->address, cp->address_type); } static void print_gap_disconnect_cmd(const void *data, uint16_t size) { const struct btp_gap_disconnect_cp *cp = data; print_bdaddr(&cp->address, cp->address_type); } static const struct indexstr_data gap_io_capa_table[] = { { 0x00, "DisplayOnly" }, { 0x01, "DisplayYesNo" }, { 0x02, "KeyboardOnly" }, { 0x03, "NoInputOutput" }, { 0x04, "KeyboardDisplay" }, { } }; static void print_gap_set_io_capa_cmd(const void *data, uint16_t size) { const struct btp_gap_set_io_capa_cp *cp = data; bt_shell_printf("\tIO Capa: %s (%d)\n", get_indexstr(cp->capa, gap_io_capa_table), cp->capa); } static void print_gap_pair_cmd(const void *data, uint16_t size) { const struct btp_gap_pair_cp *cp = data; print_bdaddr(&cp->address, cp->address_type); } static void print_gap_unpair_cmd(const void *data, uint16_t size) { const struct btp_gap_unpair_cp *cp = data; print_bdaddr(&cp->address, cp->address_type); } static void print_gap_passkey_entry_response_cmd(const void *data, uint16_t size) { const struct btp_gap_passkey_entry_rsp_cp *cp = data; print_bdaddr(&cp->address, cp->address_type); bt_shell_printf("\tPasskey: %d\n", le32_to_cpu(cp->passkey)); } static void print_gap_passkey_confirmation_response_cmd(const void *data, uint16_t size) { const struct btp_gap_passkey_confirm_rsp_cp *cp = data; print_bdaddr(&cp->address, cp->address_type); bt_shell_printf("\tMatch: %d\n", cp->match); } static void print_gap_new_settings_evt(const void *data, uint16_t size) { const struct btp_new_settings_ev *ev = data; print_gap_settings(le32_to_cpu(ev->current_settings), gap_setting_table, "\t"); } static void print_gap_eir(const uint8_t *eir, uint16_t eir_len, const char *prefix) { char str[64]; int i, n; if (eir_len == 0) { bt_shell_printf("%sEIR Data: Empty\n", prefix); return; } bt_shell_printf("%sEIR Data:\n", prefix); for (i = 0, n = 0; i < eir_len; i++) { n += sprintf(str + n, "%02x ", eir[i]); if ((i % 16) == 15) { str[n] = '\0'; bt_shell_printf("\t%s%s\n", prefix, str); n = 0; } } } static const struct bitfield_data gap_device_found_flags_table[] = { { 0, "RSSI Valid" }, { 1, "Adv_Data Included" }, { 2, "Scan_Rsp Included" }, { } }; static void print_gap_device_found_evt(const void *data, uint16_t size) { const struct btp_device_found_ev *ev = data; print_bdaddr(&ev->address, ev->address_type); bt_shell_printf("\tRSSI: %d\n", ev->rssi); bt_shell_printf("\tFlags:\n"); print_bitfield(ev->flags, gap_device_found_flags_table, "\t\t"); print_gap_eir(ev->eir, ev->eir_len, "\t"); } static void print_gap_device_connected_evt(const void *data, uint16_t size) { const struct btp_gap_device_connected_ev *ev = data; print_bdaddr(&ev->address, ev->address_type); } static void print_gap_device_disconnected_evt(const void *data, uint16_t size) { const struct btp_gap_device_disconnected_ev *ev = data; print_bdaddr(&ev->address, ev->address_type); } static void print_gap_passkey_display_evt(const void *data, uint16_t size) { const struct btp_gap_passkey_display_ev *ev = data; print_bdaddr(&ev->address, ev->address_type); bt_shell_printf("\tPasskey: %d\n", le32_to_cpu(ev->passkey)); } static void print_gap_passkey_enter_request_evt(const void *data, uint16_t size) { const struct btp_gap_passkey_req_ev *ev = data; print_bdaddr(&ev->address, ev->address_type); } static void print_gap_passkey_confirm_request_evt(const void *data, uint16_t size) { const struct btp_gap_passkey_confirm_ev *ev = data; print_bdaddr(&ev->address, ev->address_type); bt_shell_printf("\tPasskey: %d\n", le32_to_cpu(ev->passkey)); } static void print_gap_identity_resolved_evt(const void *data, uint16_t size) { const struct btp_gap_identity_resolved_ev *ev = data; print_bdaddr(&ev->address, ev->address_type); bt_shell_printf("\tIdentity: "); print_bdaddr(&ev->identity_address, ev->identity_address_type); } static const struct opcode_data opcode_table_gap[] = { { 0x00, 0, "Error", null_cmd, 0, true, print_error_rsp, 1, true }, { 0x01, 1, "Read Supported Commands", null_cmd, 0, true, print_gap_read_supported_commands_rsp, 2, true }, { 0x02, 2, "Read Controller Index List", null_cmd, 0, true, print_gap_read_controller_index_list_rsp, 2, false }, { 0x03, 3, "Read Controller Information", null_cmd, 0, true, print_gap_read_controller_information_rsp, 277, true }, { 0x04, 4, "Reset", null_cmd, 0, true, print_gap_reset_rsp, 4, true }, { 0x05, 5, "Set Powered", print_gap_set_powered_cmd, 1, true, print_gap_set_powered_rsp, 4, true }, { 0x06, 6, "Set Connectable", print_gap_set_connectable_cmd, 1, true, print_gap_set_connectable_rsp, 4, true }, { 0x07, 7, "Set Fast Connectable", print_gap_set_fast_connectable_cmd, 1, true, print_gap_set_fast_connectable_rsp, 4, true }, { 0x08, 8, "Set Discoverable", print_gap_set_discoverable_cmd, 1, true, print_gap_set_discoverable_rsp, 4, true }, { 0x09, 9, "Set Bondable", print_gap_set_bondable_cmd, 1, true, print_gap_set_bondable_rsp, 4, true }, { 0x0a, 10, "Starting Advertising", print_gap_start_advertising_cmd, 2, false, print_gap_start_advertising_rsp, 4, true }, { 0x0b, 11, "Stop Advertising", null_cmd, 0, true, print_gap_stop_advertising_rsp, 4, true }, { 0x0c, 12, "Start Discovery", print_gap_start_discovery_cmd, 1, true, null_rsp, 0, true }, { 0x0d, 13, "Stop Discovery", null_cmd, 0, true, null_rsp, 0, true }, { 0x0e, 14, "Connect", print_gap_connect_cmd, 7, true, null_rsp, 0, true }, { 0x0f, 15, "Disconnect", print_gap_disconnect_cmd, 7, true, null_rsp, 0, true }, { 0x10, 16, "Set I/O Capability", print_gap_set_io_capa_cmd, 1, true, null_rsp, 0, true }, { 0x11, 17, "Pair", print_gap_pair_cmd, 7, true, null_rsp, 0, true }, { 0x12, 18, "Unpair", print_gap_unpair_cmd, 7, true, null_rsp, 0, true }, { 0x13, 19, "Passkey Entry Response", print_gap_passkey_entry_response_cmd, 11, true, null_rsp, 0, true }, { 0x14, 20, "Passkey Confirmation Response", print_gap_passkey_confirmation_response_cmd, 8, true, null_rsp, 0, true }, { 0x80, -1, "New Settings", null_cmd, 0, true, null_rsp, 0, true, print_gap_new_settings_evt, 4, true }, { 0x81, -1, "Device Found", null_cmd, 0, true, null_rsp, 0, true, print_gap_device_found_evt, 11, false }, { 0x82, -1, "Device Connected", null_cmd, 0, true, null_rsp, 0, true, print_gap_device_connected_evt, 7, true }, { 0x83, -1, "Device Disconnected", null_cmd, 0, true, null_rsp, 0, true, print_gap_device_disconnected_evt, 7, true }, { 0x84, -1, "Passkey Display", null_cmd, 0, true, null_rsp, 0, true, print_gap_passkey_display_evt, 11, true }, { 0x85, -1, "Passkey Entry Request", null_cmd, 0, true, null_rsp, 0, true, print_gap_passkey_enter_request_evt, 7, true }, { 0x86, -1, "Passkey Confirm Request", null_cmd, 0, true, null_rsp, 0, true, print_gap_passkey_confirm_request_evt, 11, true }, { 0x87, -1, "Identity Resolved", null_cmd, 0, true, null_rsp, 0, true, print_gap_identity_resolved_evt, 14, true }, { } }; static const struct service_data service_table[] = { { 0x00, 0, "Core", opcode_table_core}, { 0x01, 1, "GAP", opcode_table_gap}, { } }; static bool write_packet(int fd, const void *data, size_t size) { while (size > 0) { ssize_t written; written = write(fd, data, size); if (written < 0) { if (errno == EAGAIN || errno == EINTR) continue; return false; } if (btpclientctl->enable_dump) util_hexdump('<', data, written, hexdump_print, "OUT: "); data += written; size -= written; } return true; } static void btp_print_cmd(struct btp_hdr *btp_hdr, void *data) { const struct service_data *table; const struct opcode_data *opcode_data; table = find_service_data(btp_hdr->service); if (!table) { bt_shell_printf("Unknown Service: 0x%02x\n", btp_hdr->service); return; } opcode_data = find_opcode_data(btp_hdr->opcode, table->opcode_table); if (!opcode_data) { bt_shell_printf("Unknown Opcode: 0x%02x\n", btp_hdr->opcode); return; } print_btp_hdr(btp_hdr, "CMD", opcode_data->str); if (opcode_data->cmd_fixed) { if (btp_hdr->data_len != opcode_data->cmd_size) { bt_shell_printf("Invalid Parameter length %d\n", btp_hdr->data_len); return; } } else { if (btp_hdr->data_len < opcode_data->cmd_size) { bt_shell_printf("Invalid Parameter length %d\n", btp_hdr->data_len); return; } } opcode_data->cmd_func(data, btp_hdr->data_len); } static void btp_print_rsp(struct btp_hdr *btp_hdr, void *data) { const struct service_data *table; const struct opcode_data *opcode_data; table = find_service_data(btp_hdr->service); if (!table) { bt_shell_printf("Unknown Service: 0x%02x\n", btp_hdr->service); return; } opcode_data = find_opcode_data(btp_hdr->opcode, table->opcode_table); if (!opcode_data) { bt_shell_printf("Unknown Opcode: 0x%02x\n", btp_hdr->opcode); return; } print_btp_hdr(btp_hdr, "RSP", opcode_data->str); if (opcode_data->rsp_fixed) { if (btp_hdr->data_len != opcode_data->rsp_size) { bt_shell_printf("Invalid Parameter length %d\n", btp_hdr->data_len); return; } } else { if (btp_hdr->data_len < opcode_data->rsp_size) { bt_shell_printf("Invalid Parameter length %d\n", btp_hdr->data_len); return; } } opcode_data->rsp_func(data, btp_hdr->data_len); } static void btp_print_evt(struct btp_hdr *btp_hdr, void *data) { const struct service_data *table; const struct opcode_data *opcode_data; table = find_service_data(btp_hdr->service); if (!table) { bt_shell_printf("Unknown Service: 0x%02x\n", btp_hdr->service); return; } opcode_data = find_opcode_data(btp_hdr->opcode, table->opcode_table); if (!opcode_data) { bt_shell_printf("Unknown Opcode: 0x%02x\n", btp_hdr->opcode); return; } print_btp_hdr(btp_hdr, "EVT", opcode_data->str); if (opcode_data->evt_fixed) { if (btp_hdr->data_len != opcode_data->evt_size) { bt_shell_printf("Invalid Parameter length %d\n", btp_hdr->data_len); return; } } else { if (btp_hdr->data_len < opcode_data->evt_size) { bt_shell_printf("Invalid Parameter length %d\n", btp_hdr->data_len); return; } } opcode_data->evt_func(data, btp_hdr->data_len); } static bool send_cmd(uint8_t service_id, uint8_t opcode, uint8_t index, uint16_t data_len, void *data) { struct btp_hdr *hdr; int client_fd; if (!btpclientctl->client_active) { bt_shell_printf("ERROR: Client is not active\n"); return false; } hdr = (struct btp_hdr *)(btpclientctl->buf); hdr->service = service_id; hdr->opcode = opcode; hdr->index = index; hdr->data_len = cpu_to_le16(data_len); if (data) memcpy(hdr->data, data, data_len); btpclientctl->buf_len = sizeof(*hdr) + data_len; client_fd = btpclientctl->client_data->fd; btp_print_cmd(hdr, data_len ? hdr->data : NULL); if (!write_packet(client_fd, btpclientctl->buf, btpclientctl->buf_len)) { fprintf(stderr, "Failed to send command to client\n"); mainloop_remove_fd(client_fd); return false; } return true; } static void client_read_destroy(void *user_data) { struct client_data *client_data = user_data; close(client_data->fd); free(client_data); btpclientctl->client_active = false; bt_shell_printf("Client is disconnected\n"); } static void client_read_callback(int fd, uint32_t events, void *user_data) { struct client_data *client_data = user_data; struct btp_hdr *btp_hdr; uint8_t *data, *ptr; ssize_t len, pkt_len; if (events & (EPOLLERR | EPOLLHUP)) { fprintf(stderr, "Error from client connection\n"); mainloop_remove_fd(client_data->fd); return; } if (events & EPOLLRDHUP) { fprintf(stderr, "Remote hangeup of cliient connection\n"); mainloop_remove_fd(client_data->fd); return; } /* Read incoming packet */ len = read(client_data->fd, client_data->buf, sizeof(client_data->buf)); if (len < 0) { if (errno == EAGAIN || errno == EINTR) return; fprintf(stderr, "Read from client descriptor failed\n"); mainloop_remove_fd(client_data->fd); return; } if (len < (ssize_t)sizeof(struct btp_hdr) - 1) return; ptr = client_data->buf; while (len) { btp_hdr = (struct btp_hdr *)ptr; pkt_len = sizeof(*btp_hdr) + btp_hdr->data_len; if (btpclientctl->enable_dump) util_hexdump('>', ptr, pkt_len, hexdump_print, "IN : "); if (btp_hdr->data_len) data = btp_hdr->data; else data = NULL; if (btp_hdr->opcode < EVT_OPCODE_BASE) btp_print_rsp(btp_hdr, data); else btp_print_evt(btp_hdr, data); ptr += pkt_len; len -= pkt_len; } } static struct client_data *setup_client(int client_fd) { struct client_data *client_data; client_data = new0(struct client_data, 1); if (!client_data) return NULL; client_data->fd = client_fd; mainloop_add_fd(client_data->fd, EPOLLIN | EPOLLRDHUP, client_read_callback, client_data, client_read_destroy); return client_data; } static void server_callback(int fd, uint32_t events, void *user_data) { union { struct sockaddr common; struct sockaddr_un sun; struct sockaddr_in sin; } addr; socklen_t len; int client_fd; struct client_data *client_data; struct btpclientctl *btpclientctl = user_data; if (events & (EPOLLERR | EPOLLHUP)) { mainloop_quit(); return; } memset(&addr, 0, sizeof(addr)); len = sizeof(addr); if (getsockname(fd, &addr.common, &len) < 0) { perror("Failed to get socket name"); return; } client_fd = accept(fd, &addr.common, &len); if (client_fd < 0) { perror("Failed to accept client socket"); return; } bt_shell_printf("Client is connected\n"); /* Setup Client */ client_data = setup_client(client_fd); if (!client_data) { fprintf(stderr, "Failed to setup client\n"); close(client_fd); return; } btpclientctl->client_data = client_data; btpclientctl->client_active = true; } static int open_socket(const char *path) { struct sockaddr_un addr; size_t len; int fd; len = strlen(path); if (len > sizeof(addr.sun_path) - 1) { fprintf(stderr, "Socket path is too long\n"); return -1; } unlink(path); fd = socket(AF_UNIX, SOCK_STREAM, 0); if (fd < 0) { perror("Failed to open Unix server socket"); return -1; } memset(&addr, 0, sizeof(addr)); addr.sun_family = AF_UNIX; strncpy(addr.sun_path, path, sizeof(addr.sun_path) - 1); if (bind(fd, (struct sockaddr *)&addr, sizeof(addr)) < 0) { perror("Failed to bind Unix server socket"); goto error_close; } if (listen(fd, 1) < 0) { perror("Failed to listen Unix server socket"); goto error_close; } bt_shell_printf("Waiting for client connection...\n"); if (chmod(path, 0666) < 0) { perror("Failed to change Unix socket file mode"); goto error_close; } return fd; error_close: close(fd); return -1; } static void cmd_core_read_cmds(int argc, char **argv) { if (!send_cmd(BTP_CORE_SERVICE, BTP_OP_CORE_READ_SUPPORTED_COMMANDS, BTP_INDEX_NON_CONTROLLER, 0, NULL)) return bt_shell_noninteractive_quit(EXIT_FAILURE); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } static void cmd_core_read_services(int argc, char **argv) { if (!send_cmd(BTP_CORE_SERVICE, BTP_OP_CORE_READ_SUPPORTED_SERVICES, BTP_INDEX_NON_CONTROLLER, 0, NULL)) return bt_shell_noninteractive_quit(EXIT_FAILURE); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } static void cmd_core_register_service(int argc, char **argv) { uint8_t service_id; service_id = atoi(argv[1]); if (service_id == 0) { bt_shell_printf("CORE service is already registered\n"); return bt_shell_noninteractive_quit(EXIT_FAILURE); } if (!send_cmd(BTP_CORE_SERVICE, BTP_OP_CORE_REGISTER, BTP_INDEX_NON_CONTROLLER, 1, &service_id)) return bt_shell_noninteractive_quit(EXIT_FAILURE); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } static void cmd_core_unregister_service(int argc, char **argv) { uint8_t service_id; service_id = atoi(argv[1]); if (service_id == 0) { bt_shell_printf("Cannot unregister CORE service\n"); return bt_shell_noninteractive_quit(EXIT_FAILURE); } if (!send_cmd(BTP_CORE_SERVICE, BTP_OP_CORE_UNREGISTER, BTP_INDEX_NON_CONTROLLER, 1, &service_id)) return bt_shell_noninteractive_quit(EXIT_FAILURE); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } static void cmd_set_index(int argc, char **argv) { uint8_t index; bt_shell_printf("Set Default Controller Index\n"); index = atoi(argv[1]); if (index == bt_index) { bt_shell_printf("Controller index is already set\n"); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } bt_index = index; bt_shell_printf("Controller index is updated to 0x%02x\n", bt_index); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } static void cmd_gap_read_cmds(int argc, char **argv) { if (!send_cmd(BTP_GAP_SERVICE, BTP_OP_GAP_READ_SUPPORTED_COMMANDS, BTP_INDEX_NON_CONTROLLER, 0, NULL)) return bt_shell_noninteractive_quit(EXIT_FAILURE); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } static void cmd_gap_read_index(int argc, char **argv) { if (!send_cmd(BTP_GAP_SERVICE, BTP_OP_GAP_READ_CONTROLLER_INDEX_LIST, BTP_INDEX_NON_CONTROLLER, 0, NULL)) return bt_shell_noninteractive_quit(EXIT_FAILURE); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } static void cmd_gap_read_info(int argc, char **argv) { uint8_t index; index = atoi(argv[1]); if (!send_cmd(BTP_GAP_SERVICE, BTP_OP_GAP_READ_COTROLLER_INFO, index, 0, NULL)) return bt_shell_noninteractive_quit(EXIT_FAILURE); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } static void cmd_gap_reset(int argc, char **argv) { if (!send_cmd(BTP_GAP_SERVICE, BTP_OP_GAP_RESET, bt_index, 0, NULL)) return bt_shell_noninteractive_quit(EXIT_FAILURE); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } static char *gap_on_off_gen(const char *text, int state) { return argument_gen(text, state, on_off_table); } static void cmd_gap_power(int argc, char **argv) { struct btp_gap_set_powered_cp cp; if (!parse_argument_on_off(argc, argv, &cp.powered)) return bt_shell_noninteractive_quit(EXIT_FAILURE); if (!send_cmd(BTP_GAP_SERVICE, BTP_OP_GAP_SET_POWERED, bt_index, sizeof(cp), &cp)) return bt_shell_noninteractive_quit(EXIT_FAILURE); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } static void cmd_gap_connectable(int argc, char **argv) { struct btp_gap_set_connectable_cp cp; if (!parse_argument_on_off(argc, argv, &cp.connectable)) return bt_shell_noninteractive_quit(EXIT_FAILURE); if (!send_cmd(BTP_GAP_SERVICE, BTP_OP_GAP_SET_CONNECTABLE, bt_index, sizeof(cp), &cp)) return bt_shell_noninteractive_quit(EXIT_FAILURE); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } static void cmd_gap_fast_connectable(int argc, char **argv) { struct btp_gap_set_fast_connectable_cp cp; if (!parse_argument_on_off(argc, argv, &cp.fast_connectable)) return bt_shell_noninteractive_quit(EXIT_FAILURE); if (!send_cmd(BTP_GAP_SERVICE, BTP_OP_GAP_SET_FAST_CONNECTABLE, bt_index, sizeof(cp), &cp)) return bt_shell_noninteractive_quit(EXIT_FAILURE); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } static char *gap_discoverable_gen(const char *text, int state) { return argument_gen(text, state, gap_discoverable_table); } static void cmd_gap_discoverable(int argc, char **argv) { struct btp_gap_set_discoverable_cp cp; memset(&cp, 0, sizeof(cp)); if (!parse_argument_list(argc, argv, &cp.discoverable, gap_discoverable_table)) return bt_shell_noninteractive_quit(EXIT_FAILURE); if (!send_cmd(BTP_GAP_SERVICE, BTP_OP_GAP_SET_DISCOVERABLE, bt_index, sizeof(cp), &cp)) return bt_shell_noninteractive_quit(EXIT_FAILURE); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } static void cmd_gap_bondable(int argc, char **argv) { struct btp_gap_set_bondable_cp cp; if (!parse_argument_on_off(argc, argv, &cp.bondable)) return bt_shell_noninteractive_quit(EXIT_FAILURE); if (!send_cmd(BTP_GAP_SERVICE, BTP_OP_GAP_SET_BONDABLE, bt_index, sizeof(cp), &cp)) return bt_shell_noninteractive_quit(EXIT_FAILURE); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } /* * This function converts the advertise data in the format of BT Spec to the * format of BTP Spec. */ static void ad_convert_data(uint8_t *data, size_t len) { struct ad_struct *ad_struct; size_t count = 0; uint8_t new_len; if (!data || !len) return; while (count < len) { ad_struct = (struct ad_struct *)(data + count); /* Swap AD_Type and AD_Len and update AD_Len */ new_len = ad_struct->length - 1; ad_struct->length = ad_struct->type; ad_struct->type = new_len; count += new_len + 2; } } static void cmd_gap_start_adv(int argc, char **argv) { struct btp_gap_start_adv_cp *cp; uint8_t *ad_data, *scan_data; size_t ad_len, scan_len; size_t total; int status = EXIT_SUCCESS; /* Generate advertise data */ ad_data = bt_ad_generate(advertise_data->ad, &ad_len); scan_data = bt_ad_generate(advertise_data->scan, &scan_len); if (!ad_data && !scan_data) { bt_shell_printf("No Advertise or Scan data available\n"); status = EXIT_FAILURE; goto exit_error_free_data; } total = ad_len + scan_len + 2; cp = (struct btp_gap_start_adv_cp *)malloc(total); if (!cp) { bt_shell_printf("Failed to allocated buffer\n"); status = EXIT_FAILURE; goto exit_error_free_data; } memset(cp, 0, total); /* * Convert Advertise Data in the format specified in BTP Spec. * BTP uses { AD_Type, AD_Len, AD_Data } struct instead of the format * defined in the BT spec and BlueZ, { AD_Len, AD_Type, AD_Data }. * * In order to comply it, AD_Type and AD_Len need to be swapped and * AD_Len needs be updated to exclude the length of AD_Type. */ ad_convert_data(ad_data, ad_len); ad_convert_data(scan_data, scan_len); /* Copy Advertise data */ cp->adv_data_len = ad_len; memcpy(cp->data, ad_data, ad_len); /* Copy Scan Response data */ cp->scan_rsp_len = scan_len; memcpy(cp->data + ad_len, scan_data, scan_len); if (!send_cmd(BTP_GAP_SERVICE, BTP_OP_GAP_START_ADVERTISING, bt_index, total, cp)) { status = EXIT_FAILURE; goto exit_error_free_cp; } exit_error_free_cp: free(cp); exit_error_free_data: free(ad_data); free(scan_data); return bt_shell_noninteractive_quit(status); } static void cmd_gap_stop_adv(int argc, char **argv) { if (!send_cmd(BTP_GAP_SERVICE, BTP_OP_GAP_STOP_ADVERTISING, bt_index, 0, NULL)) return bt_shell_noninteractive_quit(EXIT_FAILURE); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } static char *gap_start_disc_gen(const char *text, int state) { return argument_gen_bitfield(text, state, gap_discovery_flags_table); } static void cmd_gap_start_disc(int argc, char **argv) { struct btp_gap_start_discovery_cp cp; int i; uint32_t f; memset(&cp, 0, sizeof(cp)); for (i = 1; i < argc; i++) { if (!parse_argument_bitfield_list(argc - i, &argv[i], &f, gap_discovery_flags_table)) return bt_shell_noninteractive_quit(EXIT_FAILURE); cp.flags |= (1 << f); } if (!send_cmd(BTP_GAP_SERVICE, BTP_OP_GAP_START_DISCOVERY, bt_index, sizeof(cp), &cp)) return bt_shell_noninteractive_quit(EXIT_FAILURE); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } static void cmd_gap_stop_disc(int argc, char **argv) { if (!send_cmd(BTP_GAP_SERVICE, BTP_OP_GAP_STOP_DISCOVERY, bt_index, 0, NULL)) return bt_shell_noninteractive_quit(EXIT_FAILURE); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } static void cmd_gap_connect(int argc, char **argv) { struct btp_gap_connect_cp cp; memset(&cp, 0, sizeof(cp)); if (!parse_argument_addr(argc, argv, &cp.address_type, &cp.address)) return bt_shell_noninteractive_quit(EXIT_FAILURE); if (!send_cmd(BTP_GAP_SERVICE, BTP_OP_GAP_CONNECT, bt_index, sizeof(cp), &cp)) return bt_shell_noninteractive_quit(EXIT_FAILURE); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } static void cmd_gap_disconnect(int argc, char **argv) { struct btp_gap_disconnect_cp cp; memset(&cp, 0, sizeof(cp)); if (!parse_argument_addr(argc, argv, &cp.address_type, &cp.address)) return bt_shell_noninteractive_quit(EXIT_FAILURE); if (!send_cmd(BTP_GAP_SERVICE, BTP_OP_GAP_DISCONNECT, bt_index, sizeof(cp), &cp)) return bt_shell_noninteractive_quit(EXIT_FAILURE); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } static char *gap_io_capa_gen(const char *text, int state) { return argument_gen(text, state, gap_io_capa_table); } static void cmd_gap_set_io_capa(int argc, char **argv) { struct btp_gap_set_io_capa_cp cp; memset(&cp, 0, sizeof(cp)); if (argc != 2) { bt_shell_printf("Invalid parameter\n"); return bt_shell_noninteractive_quit(EXIT_FAILURE); } if (!parse_argument_list(argc, argv, &cp.capa, gap_io_capa_table)) return bt_shell_noninteractive_quit(EXIT_FAILURE); if (!send_cmd(BTP_GAP_SERVICE, BTP_OP_GAP_SET_IO_CAPA, bt_index, sizeof(cp), &cp)) return bt_shell_noninteractive_quit(EXIT_FAILURE); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } static void cmd_gap_pair(int argc, char **argv) { struct btp_gap_pair_cp cp; memset(&cp, 0, sizeof(cp)); if (!parse_argument_addr(argc, argv, &cp.address_type, &cp.address)) return bt_shell_noninteractive_quit(EXIT_FAILURE); if (!send_cmd(BTP_GAP_SERVICE, BTP_OP_GAP_PAIR, bt_index, sizeof(cp), &cp)) return bt_shell_noninteractive_quit(EXIT_FAILURE); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } static void cmd_gap_unpair(int argc, char **argv) { struct btp_gap_unpair_cp cp; memset(&cp, 0, sizeof(cp)); if (!parse_argument_addr(argc, argv, &cp.address_type, &cp.address)) return bt_shell_noninteractive_quit(EXIT_FAILURE); if (!send_cmd(BTP_GAP_SERVICE, BTP_OP_GAP_UNPAIR, bt_index, sizeof(cp), &cp)) return bt_shell_noninteractive_quit(EXIT_FAILURE); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } static bool ad_add_data(struct ad_data *data, int argc, char *argv[]) { char *endptr = NULL; int i; long value; memset(data, 0, sizeof(*data)); for (i = 0; i < argc; i++) { endptr = NULL; value = strtol(argv[i], &endptr, 0); if (!endptr || *endptr != '\0' || value > UINT8_MAX) { bt_shell_printf("Invalid data index at %d\n", i); return false; } data->data[data->len] = value; data->len++; } return true; } static void cmd_ad_show(int argc, char **argv) { uint8_t *data; size_t data_len; bt_shell_printf("Advertise Data:\n"); data = bt_ad_generate(advertise_data->ad, &data_len); print_ad_data(data, data_len); bt_shell_printf("Scan Response Data:\n"); data = bt_ad_generate(advertise_data->scan, &data_len); print_ad_data(data, data_len); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } static void cmd_ad_name(int argc, char **argv) { if (argc < 2) { cmd_ad_show(argc, argv); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } if (!bt_ad_add_name(advertise_data->ad, argv[1])) { bt_shell_printf("Failed to add local name\n"); return bt_shell_noninteractive_quit(EXIT_FAILURE); } cmd_ad_show(argc, argv); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } static void cmd_ad_appearance(int argc, char **argv) { long value; char *endptr = NULL; if (argc < 2) { cmd_ad_show(argc, argv); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } value = strtol(argv[1], &endptr, 0); if (!endptr || *endptr != '\0' || value > UINT16_MAX) { bt_shell_printf("Invalid argument: %s\n", argv[1]); return bt_shell_noninteractive_quit(EXIT_FAILURE); } if (!bt_ad_add_appearance(advertise_data->ad, value)) { bt_shell_printf("Failed to add appearance\n"); return bt_shell_noninteractive_quit(EXIT_FAILURE); } cmd_ad_show(argc, argv); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } static void cmd_ad_uuids(int argc, char **argv) { int i; if (argc < 2) { cmd_ad_show(argc, argv); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } for (i = 1; i < argc; i++) { bt_uuid_t uuid; if (bt_string_to_uuid(&uuid, argv[i]) < 0) { bt_shell_printf("Invalid argument: %s\n", argv[i]); goto fail; } if (!bt_ad_add_service_uuid(advertise_data->ad, &uuid)) { bt_shell_printf("Failed to add service uuid\n"); goto fail; } } cmd_ad_show(argc, argv); return bt_shell_noninteractive_quit(EXIT_SUCCESS); fail: bt_ad_clear_service_uuid(advertise_data->ad); return bt_shell_noninteractive_quit(EXIT_FAILURE); } static void cmd_ad_manufacturer(int argc, char **argv) { long value; char *endptr = NULL; struct ad_data data; if (argc < 2) { cmd_ad_show(argc, argv); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } value = strtol(argv[1], &endptr, 0); if (!endptr || *endptr != '\0' || value > UINT16_MAX) { bt_shell_printf("Invalid manufacture id: %s\n", argv[1]); return bt_shell_noninteractive_quit(EXIT_FAILURE); } if (!ad_add_data(&data, argc-2, argv + 2)) return bt_shell_noninteractive_quit(EXIT_FAILURE); if (!bt_ad_add_manufacturer_data(advertise_data->ad, value, data.data, data.len)) { bt_shell_printf("Failed to add manufacturer data\n"); return bt_shell_noninteractive_quit(EXIT_FAILURE); } cmd_ad_show(argc, argv); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } static void cmd_ad_solicit(int argc, char **argv) { int i; if (argc < 2) { cmd_ad_show(argc, argv); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } for (i = 1; i < argc; i++) { bt_uuid_t uuid; if (bt_string_to_uuid(&uuid, argv[i]) < 0) { bt_shell_printf("Invalid argument: %s\n", argv[i]); goto fail; } if (!bt_ad_add_solicit_uuid(advertise_data->ad, &uuid)) { bt_shell_printf("Failed to add service uuid\n"); goto fail; } } cmd_ad_show(argc, argv); return bt_shell_noninteractive_quit(EXIT_SUCCESS); fail: bt_ad_clear_solicit_uuid(advertise_data->ad); return bt_shell_noninteractive_quit(EXIT_FAILURE); } static void cmd_ad_service_data(int argc, char **argv) { bt_uuid_t uuid; struct ad_data data; if (argc < 2) { cmd_ad_show(argc, argv); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } if (bt_string_to_uuid(&uuid, argv[1]) < 0) { bt_shell_printf("Invalid argument: %s\n", argv[1]); goto fail; } if (!ad_add_data(&data, argc-2, argv + 2)) return bt_shell_noninteractive_quit(EXIT_FAILURE); if (!bt_ad_add_service_data(advertise_data->ad, &uuid, data.data, data.len)) { bt_shell_printf("Failed to add service data\n"); return bt_shell_noninteractive_quit(EXIT_FAILURE); } cmd_ad_show(argc, argv); return bt_shell_noninteractive_quit(EXIT_SUCCESS); fail: bt_ad_clear_service_data(advertise_data->ad); return bt_shell_noninteractive_quit(EXIT_FAILURE); } static void cmd_ad_data(int argc, char **argv) { long value; char *endptr = NULL; struct ad_data data; if (argc < 2) { cmd_ad_show(argc, argv); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } value = strtol(argv[1], &endptr, 0); if (!endptr || *endptr != '\0' || value > UINT8_MAX) { bt_shell_printf("Invalid data type: %s\n", argv[1]); return bt_shell_noninteractive_quit(EXIT_FAILURE); } if (!ad_add_data(&data, argc-2, argv + 2)) return bt_shell_noninteractive_quit(EXIT_FAILURE); if (!bt_ad_add_data(advertise_data->ad, value, data.data, data.len)) { bt_shell_printf("Failed to add data\n"); return bt_shell_noninteractive_quit(EXIT_FAILURE); } cmd_ad_show(argc, argv); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } static void cmd_scan_rsp_name(int argc, char **argv) { if (argc < 2) { cmd_ad_show(argc, argv); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } if (!bt_ad_add_name(advertise_data->scan, argv[1])) { bt_shell_printf("Failed to add local name\n"); return bt_shell_noninteractive_quit(EXIT_FAILURE); } cmd_ad_show(argc, argv); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } static void ad_clear_name(void) { bt_ad_clear_name(advertise_data->ad); } static void ad_clear_appearance(void) { bt_ad_clear_appearance(advertise_data->ad); } static void ad_clear_uuids(void) { bt_ad_clear_service_uuid(advertise_data->ad); } static void ad_clear_manufacturer(void) { bt_ad_clear_manufacturer_data(advertise_data->ad); } static void ad_clear_solicit(void) { bt_ad_clear_solicit_uuid(advertise_data->ad); } static void ad_clear_service(void) { bt_ad_clear_service_data(advertise_data->ad); } static void ad_clear_data(void) { bt_ad_clear_data(advertise_data->ad); } static void ad_clear_scan_rsp(void) { bt_ad_clear_name(advertise_data->scan); } static void ad_clear_all(void) { ad_clear_name(); ad_clear_appearance(); ad_clear_uuids(); ad_clear_manufacturer(); ad_clear_solicit(); ad_clear_service(); ad_clear_data(); ad_clear_scan_rsp(); } static const struct name_func_entry ad_clear_entry_table[] = { { "name", ad_clear_name }, { "appearance", ad_clear_appearance }, { "uuids", ad_clear_uuids }, { "manufacturer", ad_clear_manufacturer }, { "solicit", ad_clear_solicit }, { "service", ad_clear_service }, { "data", ad_clear_data }, { "scan-rsp", ad_clear_scan_rsp }, { "all", ad_clear_all }, { } }; static void cmd_ad_clear(int argc, char **argv) { const struct name_func_entry *entry; if (argc < 2) { ad_clear_all(); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } for (entry = ad_clear_entry_table; entry && entry->name; entry++) { if (!strcmp(entry->name, argv[1])) { entry->func(); goto done; } } bt_shell_printf("Invalid argument: %s\n", argv[1]); return bt_shell_noninteractive_quit(EXIT_FAILURE); done: cmd_ad_show(argc, argv); return bt_shell_noninteractive_quit(EXIT_SUCCESS); } static char *ad_clear_gen(const char *text, int state) { return argument_gen_name_func_entry(text, state, ad_clear_entry_table); } static const struct bt_shell_menu ad_menu = { .name = "ad", .desc = "Advertise Options Submenu", .entries = { { "show", NULL, cmd_ad_show, "Show current saved advertise data" }, { "name", "[name]", cmd_ad_name, "Set/Get the local name" }, { "appearance", "[value]", cmd_ad_appearance, "Set/Get the appearance" }, { "uuids", "[uuid ...]", cmd_ad_uuids, "Set/Get advertise service uuids" }, { "manufacturer", "[id] [data=xx xx ...]", cmd_ad_manufacturer, "Set/Get manufacturer data" }, { "solicit", "[uuid ...]", cmd_ad_solicit, "Set/Get solicit uuids" }, { "service", "[uuid] [data=xx xx ...]", cmd_ad_service_data, "Set/Get service data" }, { "data", "[type] [data=xx xx ...]", cmd_ad_data, "Set/Get advertise data" }, { "scan-rsp", "[name]", cmd_scan_rsp_name, "Set/Get scan rsp data with name" }, { "clear", "[all/name/appearance/uuids/...]", cmd_ad_clear, "Clear advertise configuration", ad_clear_gen }, { } }, }; static const struct bt_shell_menu gap_menu = { .name = "gap", .desc = "GAP API Submenu", .entries = { { "read-cmds", NULL, cmd_gap_read_cmds, "Show supported commands" }, { "list", NULL, cmd_gap_read_index, "Show index of controllers" }, { "read-info", "", cmd_gap_read_info, "Read controller information" }, { "reset", NULL, cmd_gap_reset, "Reset controller and stack" }, { "power", "", cmd_gap_power, "Set controller power", gap_on_off_gen }, { "connectable", "", cmd_gap_connectable, "Set controller connectable", gap_on_off_gen }, { "fast-connectable", "", cmd_gap_fast_connectable, "Set controller fast connectable", gap_on_off_gen }, { "discoverable", "", cmd_gap_discoverable, "Set controller discoverable", gap_discoverable_gen }, { "bondable", "", cmd_gap_bondable, "Set controller bondable", gap_on_off_gen }, { "start-adv", NULL, cmd_gap_start_adv, "Start Advertising" }, { "stop-adv", NULL, cmd_gap_stop_adv, "Stop Advertising" }, { "start-disc", "", cmd_gap_start_disc, "Start discovery", gap_start_disc_gen }, { "stop-disc", NULL, cmd_gap_stop_disc, "Stop discovery" }, { "connect", " ", cmd_gap_connect, "Connect" }, { "disconnect", " ", cmd_gap_disconnect, "Disconnect" }, { "set-capa", "", cmd_gap_set_io_capa, "Set IO capability", gap_io_capa_gen }, { "pair", " ", cmd_gap_pair, "Pair" }, { "unpair", " ", cmd_gap_unpair, "Unpair" }, { } }, }; static const struct bt_shell_menu main_menu = { .name = "main", .entries = { { "read-cmds", NULL, cmd_core_read_cmds, "Read supported commands" }, { "read-services", NULL, cmd_core_read_services, "Read supported services" }, { "register", "", cmd_core_register_service, "Register service" }, { "unregister", "", cmd_core_unregister_service, "Unregister service" }, { "index", "", cmd_set_index, "Set controller index. Default is 0" }, { } }, }; static const struct option main_options[] = { { "socket", required_argument, 0, 's' }, { "dump ", required_argument, 0, 'd' }, { 0, 0, 0, 0 } }; static const char *socket_path_option; static const char *dump_option; static const char **optargs[] = { &socket_path_option, &dump_option, }; static const char *help[] = { "Socket path to listen for BTP client\n", "Use \"on\" to enable hex dump\n" }; static const struct bt_shell_opt opt = { .options = main_options, .optno = sizeof(main_options) / sizeof(struct option), .optstr = "s:d:", .optarg = optargs, .help = help, }; int main(int argc, char *argv[]) { int status; int server_fd; bt_shell_init(argc, argv, &opt); bt_shell_set_menu(&main_menu); bt_shell_add_submenu(&ad_menu); bt_shell_add_submenu(&gap_menu); btpclientctl = new0(struct btpclientctl, 1); if (!btpclientctl) { bt_shell_printf("Failed to allocate btpclientctl\n"); status = EXIT_FAILURE; goto error_exit; } if (socket_path_option) btpclientctl->socket_path = strdup(socket_path_option); else btpclientctl->socket_path = strdup(DEFAULT_SOCKET_PATH); if (dump_option && !strcasecmp(dump_option, "on")) btpclientctl->enable_dump = true; else btpclientctl->enable_dump = false; advertise_data = new0(struct advertise_data, 1); if (!advertise_data) { status = EXIT_FAILURE; goto error_free_clientctl; } advertise_data->ad = bt_ad_new(); if (!advertise_data->ad) { status = EXIT_FAILURE; goto error_free_advertise_data; } advertise_data->scan = bt_ad_new(); if (!advertise_data->scan) { status = EXIT_FAILURE; goto error_free_ad; } bt_shell_attach(fileno(stdin)); server_fd = open_socket(btpclientctl->socket_path); if (server_fd < 0) { status = EXIT_FAILURE; goto error_free_scan; } btpclientctl->server_fd = server_fd; mainloop_add_fd(btpclientctl->server_fd, EPOLLIN, server_callback, btpclientctl, NULL); bt_shell_set_prompt(PROMPT_ON, COLOR_BLUE); status = bt_shell_run(); close(btpclientctl->server_fd); error_free_scan: bt_ad_unref(advertise_data->scan); error_free_ad: bt_ad_unref(advertise_data->ad); error_free_advertise_data: free(advertise_data); error_free_clientctl: free(btpclientctl->socket_path); free(btpclientctl); error_exit: return status; }