/* * * BlueZ - Bluetooth protocol stack for Linux * * Copyright (C) 2012 Intel Corporation. All rights reserved. * * * 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. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA * */ #ifdef HAVE_CONFIG_H #include #endif #include #include #include #include #include #include #include #include #include #include "monitor/bt.h" #include "src/shared/mainloop.h" #include "src/shared/util.h" #include "src/shared/hci.h" #define CMD_RESET 0xfc01 struct cmd_reset { uint8_t reset_type; uint8_t patch_enable; uint8_t otp_ddc_reload; uint8_t boot_option; uint32_t boot_addr; } __attribute__ ((packed)); #define CMD_NO_OPERATION 0xfc02 #define CMD_READ_VERSION 0xfc05 struct rsp_read_version { uint8_t status; uint8_t hw_platform; uint8_t hw_variant; uint8_t hw_revision; uint8_t fw_variant; uint8_t fw_revision; uint8_t fw_build_nn; uint8_t fw_build_cw; uint8_t fw_build_yy; uint8_t fw_patch; } __attribute__ ((packed)); #define CMD_READ_BOOT_PARAMS 0xfc0d struct rsp_read_boot_params { uint8_t status; uint8_t otp_format; uint8_t otp_content; uint8_t otp_patch; uint16_t dev_revid; uint8_t secure_boot; uint8_t key_from_hdr; uint8_t key_type; uint8_t otp_lock; uint8_t api_lock; uint8_t debug_lock; uint8_t otp_bdaddr[6]; uint8_t min_fw_build_nn; uint8_t min_fw_build_cw; uint8_t min_fw_build_yy; uint8_t limited_cce; uint8_t unlocked_state; } __attribute__ ((packed)); #define CMD_WRITE_BOOT_PARAMS 0xfc0e struct cmd_write_boot_params { uint32_t boot_addr; uint8_t fw_build_nn; uint8_t fw_build_cw; uint8_t fw_build_yy; } __attribute__ ((packed)); #define CMD_MANUFACTURER_MODE 0xfc11 struct cmd_manufacturer_mode { uint8_t mode_switch; uint8_t reset; } __attribute__ ((packed)); #define CMD_WRITE_BD_DATA 0xfc2f struct cmd_write_bd_data { uint8_t bdaddr[6]; uint8_t reserved1[6]; uint8_t features[8]; uint8_t le_features; uint8_t reserved2[32]; uint8_t lmp_version; uint8_t reserved3[26]; } __attribute__ ((packed)); #define CMD_READ_BD_DATA 0xfc30 struct rsp_read_bd_data { uint8_t status; uint8_t bdaddr[6]; uint8_t reserved1[6]; uint8_t features[8]; uint8_t le_features; uint8_t reserved2[32]; uint8_t lmp_version; uint8_t reserved3[26]; } __attribute__ ((packed)); #define CMD_WRITE_BD_ADDRESS 0xfc31 struct cmd_write_bd_address { uint8_t bdaddr[6]; } __attribute__ ((packed)); #define CMD_ACT_DEACT_TRACES 0xfc43 struct cmd_act_deact_traces { uint8_t tx_trace; uint8_t tx_arq; uint8_t rx_trace; } __attribute__ ((packed)); #define CMD_TRIGGER_EXCEPTION 0xfc4d struct cmd_trigger_exception { uint8_t type; } __attribute__ ((packed)); #define CMD_MEMORY_WRITE 0xfc8e static struct bt_hci *hci_dev; static uint16_t hci_index = 0; #define FIRMWARE_BASE_PATH "/lib/firmware" static bool set_bdaddr = false; static const char *set_bdaddr_value = NULL; static bool get_bddata = false; static bool load_firmware = false; static const char *load_firmware_value = NULL; static uint8_t *firmware_data = NULL; static size_t firmware_size = 0; static size_t firmware_offset = 0; static bool check_firmware = false; static const char *check_firmware_value = NULL; uint8_t manufacturer_mode_reset = 0x00; static bool use_manufacturer_mode = false; static bool set_traces = false; static bool set_exception = false; static bool reset_on_exit = false; static bool cold_boot = false; static void reset_complete(const void *data, uint8_t size, void *user_data) { uint8_t status = *((uint8_t *) data); if (status) { fprintf(stderr, "Failed to reset (0x%02x)\n", status); mainloop_quit(); return; } mainloop_quit(); } static void cold_boot_complete(const void *data, uint8_t size, void *user_data) { uint8_t status = *((uint8_t *) data); if (status) { fprintf(stderr, "Failed to cold boot (0x%02x)\n", status); mainloop_quit(); return; } if (reset_on_exit) { bt_hci_send(hci_dev, BT_HCI_CMD_RESET, NULL, 0, reset_complete, NULL, NULL); return; } mainloop_quit(); } static void leave_manufacturer_mode_complete(const void *data, uint8_t size, void *user_data) { uint8_t status = *((uint8_t *) data); if (status) { fprintf(stderr, "Failed to leave manufacturer mode (0x%02x)\n", status); mainloop_quit(); return; } if (reset_on_exit) { bt_hci_send(hci_dev, BT_HCI_CMD_RESET, NULL, 0, reset_complete, NULL, NULL); return; } mainloop_quit(); } static void shutdown_device(void) { bt_hci_flush(hci_dev); free(firmware_data); if (use_manufacturer_mode) { struct cmd_manufacturer_mode cmd; cmd.mode_switch = 0x00; cmd.reset = manufacturer_mode_reset; bt_hci_send(hci_dev, CMD_MANUFACTURER_MODE, &cmd, sizeof(cmd), leave_manufacturer_mode_complete, NULL, NULL); return; } if (reset_on_exit) { bt_hci_send(hci_dev, BT_HCI_CMD_RESET, NULL, 0, reset_complete, NULL, NULL); return; } mainloop_quit(); } static void write_bd_address_complete(const void *data, uint8_t size, void *user_data) { uint8_t status = *((uint8_t *) data); if (status) { fprintf(stderr, "Failed to write address (0x%02x)\n", status); mainloop_quit(); return; } shutdown_device(); } static void read_bd_addr_complete(const void *data, uint8_t size, void *user_data) { const struct bt_hci_rsp_read_bd_addr *rsp = data; struct cmd_write_bd_address cmd; if (rsp->status) { fprintf(stderr, "Failed to read address (0x%02x)\n", rsp->status); mainloop_quit(); shutdown_device(); return; } if (set_bdaddr_value) { fprintf(stderr, "Setting address is not supported\n"); mainloop_quit(); return; } printf("Controller Address\n"); printf("\tOld BD_ADDR: %2.2X:%2.2X:%2.2X:%2.2X:%2.2X:%2.2X\n", rsp->bdaddr[5], rsp->bdaddr[4], rsp->bdaddr[3], rsp->bdaddr[2], rsp->bdaddr[1], rsp->bdaddr[0]); memcpy(cmd.bdaddr, rsp->bdaddr, 6); cmd.bdaddr[0] = (hci_index & 0xff); printf("\tNew BD_ADDR: %2.2X:%2.2X:%2.2X:%2.2X:%2.2X:%2.2X\n", cmd.bdaddr[5], cmd.bdaddr[4], cmd.bdaddr[3], cmd.bdaddr[2], cmd.bdaddr[1], cmd.bdaddr[0]); bt_hci_send(hci_dev, CMD_WRITE_BD_ADDRESS, &cmd, sizeof(cmd), write_bd_address_complete, NULL, NULL); } static void act_deact_traces_complete(const void *data, uint8_t size, void *user_data) { uint8_t status = *((uint8_t *) data); if (status) { fprintf(stderr, "Failed to activate traces (0x%02x)\n", status); shutdown_device(); return; } shutdown_device(); } static void act_deact_traces(void) { struct cmd_act_deact_traces cmd; cmd.tx_trace = 0x03; cmd.tx_arq = 0x03; cmd.rx_trace = 0x03; bt_hci_send(hci_dev, CMD_ACT_DEACT_TRACES, &cmd, sizeof(cmd), act_deact_traces_complete, NULL, NULL); } static void trigger_exception(void) { struct cmd_trigger_exception cmd; cmd.type = 0x00; bt_hci_send(hci_dev, CMD_TRIGGER_EXCEPTION, &cmd, sizeof(cmd), NULL, NULL, NULL); shutdown_device(); } static void write_bd_data_complete(const void *data, uint8_t size, void *user_data) { uint8_t status = *((uint8_t *) data); if (status) { fprintf(stderr, "Failed to write data (0x%02x)\n", status); shutdown_device(); return; } if (set_traces) { act_deact_traces(); return; } shutdown_device(); } static void read_bd_data_complete(const void *data, uint8_t size, void *user_data) { const struct rsp_read_bd_data *rsp = data; if (rsp->status) { fprintf(stderr, "Failed to read data (0x%02x)\n", rsp->status); shutdown_device(); return; } printf("Controller Data\n"); printf("\tBD_ADDR: %2.2X:%2.2X:%2.2X:%2.2X:%2.2X:%2.2X\n", rsp->bdaddr[5], rsp->bdaddr[4], rsp->bdaddr[3], rsp->bdaddr[2], rsp->bdaddr[1], rsp->bdaddr[0]); printf("\tLMP Version: %u\n", rsp->lmp_version); printf("\tLMP Features: 0x%2.2x 0x%2.2x 0x%2.2x 0x%2.2x" " 0x%2.2x 0x%2.2x 0x%2.2x 0x%2.2x\n", rsp->features[0], rsp->features[1], rsp->features[2], rsp->features[3], rsp->features[4], rsp->features[5], rsp->features[6], rsp->features[7]); printf("\tLE Features: 0x%2.2x\n", rsp->le_features); if (set_bdaddr) { struct cmd_write_bd_data cmd; memcpy(cmd.bdaddr, rsp->bdaddr, 6); cmd.bdaddr[0] = (hci_index & 0xff); cmd.lmp_version = 0x07; memcpy(cmd.features, rsp->features, 8); cmd.le_features = rsp->le_features; cmd.le_features |= 0x1e; memcpy(cmd.reserved1, rsp->reserved1, sizeof(cmd.reserved1)); memcpy(cmd.reserved2, rsp->reserved2, sizeof(cmd.reserved2)); memcpy(cmd.reserved3, rsp->reserved3, sizeof(cmd.reserved3)); bt_hci_send(hci_dev, CMD_WRITE_BD_DATA, &cmd, sizeof(cmd), write_bd_data_complete, NULL, NULL); return; } shutdown_device(); } static void firmware_command_complete(const void *data, uint8_t size, void *user_data) { uint8_t status = *((uint8_t *) data); if (status) { fprintf(stderr, "Failed to load firmware (0x%02x)\n", status); manufacturer_mode_reset = 0x01; shutdown_device(); return; } if (firmware_offset >= firmware_size) { printf("Activating firmware\n"); manufacturer_mode_reset = 0x02; shutdown_device(); return; } if (firmware_data[firmware_offset] == 0x01) { uint16_t opcode; uint8_t dlen; opcode = firmware_data[firmware_offset + 2] << 8 | firmware_data[firmware_offset + 1]; dlen = firmware_data[firmware_offset + 3]; bt_hci_send(hci_dev, opcode, firmware_data + firmware_offset + 4, dlen, firmware_command_complete, NULL, NULL); firmware_offset += dlen + 4; if (firmware_data[firmware_offset] == 0x02) { dlen = firmware_data[firmware_offset + 2]; firmware_offset += dlen + 3; } } else { fprintf(stderr, "Invalid packet in firmware\n"); manufacturer_mode_reset = 0x01; shutdown_device(); } } static void enter_manufacturer_mode_complete(const void *data, uint8_t size, void *user_data) { uint8_t status = *((uint8_t *) data); if (status) { fprintf(stderr, "Failed to enter manufacturer mode (0x%02x)\n", status); mainloop_quit(); return; } if (load_firmware) { uint8_t status = BT_HCI_ERR_SUCCESS; firmware_command_complete(&status, sizeof(status), NULL); return; } if (get_bddata || set_bdaddr) { bt_hci_send(hci_dev, CMD_READ_BD_DATA, NULL, 0, read_bd_data_complete, NULL, NULL); return; } if (set_traces) { act_deact_traces(); return; } if (set_exception) { trigger_exception(); return; } shutdown_device(); } static void request_firmware(const char *path) { unsigned int cmd_num = 0; unsigned int evt_num = 0; struct stat st; ssize_t len; int fd; fd = open(path, O_RDONLY); if (fd < 0) { fprintf(stderr, "Failed to open firmware %s\n", path); shutdown_device(); return; } if (fstat(fd, &st) < 0) { fprintf(stderr, "Failed to get firmware size\n"); close(fd); shutdown_device(); return; } firmware_data = malloc(st.st_size); if (!firmware_data) { fprintf(stderr, "Failed to allocate firmware buffer\n"); close(fd); shutdown_device(); return; } len = read(fd, firmware_data, st.st_size); if (len < 0) { fprintf(stderr, "Failed to read firmware file\n"); close(fd); shutdown_device(); return; } close(fd); if (len < st.st_size) { fprintf(stderr, "Firmware size does not match buffer\n"); shutdown_device(); return; } firmware_size = len; if (firmware_data[0] == 0xff) firmware_offset = 1; while (firmware_offset < firmware_size) { uint16_t opcode; uint8_t evt, dlen; switch (firmware_data[firmware_offset]) { case 0x01: opcode = firmware_data[firmware_offset + 2] << 8 | firmware_data[firmware_offset + 1]; dlen = firmware_data[firmware_offset + 3]; if (opcode != CMD_MEMORY_WRITE) printf("Unexpected opcode 0x%02x\n", opcode); firmware_offset += dlen + 4; cmd_num++; break; case 0x02: evt = firmware_data[firmware_offset + 1]; dlen = firmware_data[firmware_offset + 2]; if (evt != BT_HCI_EVT_CMD_COMPLETE) printf("Unexpected event 0x%02x\n", evt); firmware_offset += dlen + 3; evt_num++; break; default: fprintf(stderr, "Invalid firmware file\n"); shutdown_device(); return; } } printf("Firmware with %u commands and %u events\n", cmd_num, evt_num); if (firmware_data[0] == 0xff) firmware_offset = 1; } static void read_boot_params_complete(const void *data, uint8_t size, void *user_data) { const struct rsp_read_boot_params *rsp = data; if (rsp->status) { fprintf(stderr, "Failed to read boot params (0x%02x)\n", rsp->status); mainloop_quit(); return; } if (size != sizeof(*rsp)) { fprintf(stderr, "Size mismatch for read boot params\n"); mainloop_quit(); return; } printf("Secure Boot Parameters\n"); printf("\tOTP Format Version:\t%u\n", rsp->otp_format); printf("\tOTP Content Version:\t%u\n", rsp->otp_content); printf("\tOTP ROM Patch Version:\t%u\n", rsp->otp_patch); printf("\tDevice Revision ID:\t%u\n", le16_to_cpu(rsp->dev_revid)); printf("\tSecure Boot Enable:\t%u\n", rsp->secure_boot); printf("\tTake Key From Header:\t%u\n", rsp->key_from_hdr); printf("\tRSA Key Type:\t\t%u\n", rsp->key_type); printf("\tOTP Lock:\t\t%u\n", rsp->otp_lock); printf("\tAPI Lock:\t\t%u\n", rsp->api_lock); printf("\tDebug Lock:\t\t%u\n", rsp->debug_lock); printf("\tMin FW Build Number:\t%u-%u.%u\n", rsp->min_fw_build_nn, rsp->min_fw_build_cw, 2000 + rsp->min_fw_build_yy); printf("\tLimited CCE to ISSC:\t%u\n", rsp->limited_cce); printf("\tUnlocked State:\t\t%u\n", rsp->unlocked_state); mainloop_quit(); } static const struct { uint8_t val; const char *str; } hw_variant_table[] = { { 0x06, "iBT 1.1 (XG223)" }, { 0x07, "iBT 2.0 (WP)" }, { 0x08, "iBT 2.5 (StP)" }, { 0x09, "iBT 1.5 (AG610)" }, { 0x0a, "iBT 2.1 (AG620)" }, { 0x0b, "iBT 3.0 (LnP)" }, { 0x0c, "iBT 3.0 (WsP)" }, { 0x12, "iBT 3.5 (ThP)" }, { } }; static const struct { uint8_t val; const char *str; } fw_variant_table[] = { { 0x01, "iBT 1.0 - iBT 2.5" }, { 0x06, "iBT Bootloader" }, { 0x23, "iBT 3.x Bluetooth FW" }, { } }; static void read_version_complete(const void *data, uint8_t size, void *user_data) { const struct rsp_read_version *rsp = data; const char *str; int i; if (rsp->status) { fprintf(stderr, "Failed to read version (0x%02x)\n", rsp->status); mainloop_quit(); return; } if (size != sizeof(*rsp)) { fprintf(stderr, "Size mismatch for read version response\n"); mainloop_quit(); return; } if (cold_boot) { struct cmd_reset cmd; cmd.reset_type = 0x01; cmd.patch_enable = 0x00; cmd.otp_ddc_reload = 0x01; cmd.boot_option = 0x00; cmd.boot_addr = cpu_to_le32(0x00000000); bt_hci_send(hci_dev, CMD_RESET, &cmd, sizeof(cmd), cold_boot_complete, NULL, NULL); return; } if (load_firmware) { if (load_firmware_value) { printf("Firmware: %s\n", load_firmware_value); request_firmware(load_firmware_value); } else { char fw_name[PATH_MAX]; snprintf(fw_name, sizeof(fw_name), "%s/%s/ibt-hw-%x.%x.%x-fw-%x.%x.%x.%x.%x.bseq", FIRMWARE_BASE_PATH, "intel", rsp->hw_platform, rsp->hw_variant, rsp->hw_revision, rsp->fw_variant, rsp->fw_revision, rsp->fw_build_nn, rsp->fw_build_cw, rsp->fw_build_yy); printf("Firmware: %s\n", fw_name); printf("Patch level: %d\n", rsp->fw_patch); request_firmware(fw_name); } } if (use_manufacturer_mode) { struct cmd_manufacturer_mode cmd; cmd.mode_switch = 0x01; cmd.reset = 0x00; bt_hci_send(hci_dev, CMD_MANUFACTURER_MODE, &cmd, sizeof(cmd), enter_manufacturer_mode_complete, NULL, NULL); return; } if (set_bdaddr) { bt_hci_send(hci_dev, BT_HCI_CMD_READ_BD_ADDR, NULL, 0, read_bd_addr_complete, NULL, NULL); return; } printf("Controller Version Information\n"); printf("\tHardware Platform:\t%u\n", rsp->hw_platform); str = "Reserved"; for (i = 0; hw_variant_table[i].str; i++) { if (hw_variant_table[i].val == rsp->hw_variant) { str = hw_variant_table[i].str; break; } } printf("\tHardware Variant:\t%s (0x%02x)\n", str, rsp->hw_variant); printf("\tHardware Revision:\t%u.%u\n", rsp->hw_revision >> 4, rsp->hw_revision & 0x0f); str = "Reserved"; for (i = 0; fw_variant_table[i].str; i++) { if (fw_variant_table[i].val == rsp->fw_variant) { str = fw_variant_table[i].str; break; } } printf("\tFirmware Variant:\t%s (0x%02x)\n", str, rsp->fw_variant); printf("\tFirmware Revision:\t%u.%u\n", rsp->fw_revision >> 4, rsp->fw_revision & 0x0f); printf("\tFirmware Build Number:\t%u-%u.%u\n", rsp->fw_build_nn, rsp->fw_build_cw, 2000 + rsp->fw_build_yy); printf("\tFirmware Patch Number:\t%u\n", rsp->fw_patch); if (rsp->hw_variant == 0x0b && rsp->fw_variant == 0x06) { bt_hci_send(hci_dev, CMD_READ_BOOT_PARAMS, NULL, 0, read_boot_params_complete, NULL, NULL); return; } mainloop_quit(); } struct css_hdr { uint32_t module_type; uint32_t header_len; uint32_t header_version; uint32_t module_id; uint32_t module_vendor; uint32_t date; uint32_t size; uint32_t key_size; uint32_t modulus_size; uint32_t exponent_size; uint8_t reserved[88]; } __attribute__ ((packed)); static void analyze_firmware(const char *path) { unsigned int cmd_num = 0; struct css_hdr *css; struct stat st; ssize_t len; int fd; fd = open(path, O_RDONLY); if (fd < 0) { fprintf(stderr, "Failed to open firmware %s\n", path); return; } if (fstat(fd, &st) < 0) { fprintf(stderr, "Failed to get firmware size\n"); close(fd); return; } firmware_data = malloc(st.st_size); if (!firmware_data) { fprintf(stderr, "Failed to allocate firmware buffer\n"); close(fd); return; } len = read(fd, firmware_data, st.st_size); if (len < 0) { fprintf(stderr, "Failed to read firmware file\n"); close(fd); goto done; } close(fd); if (len != st.st_size) { fprintf(stderr, "Failed to read complete firmware file\n"); goto done; } if ((size_t) len < sizeof(*css)) { fprintf(stderr, "Firmware file is too short\n"); goto done; } css = (void *) firmware_data; printf("Module type:\t%u\n", le32_to_cpu(css->module_type)); printf("Header len:\t%u DWORDs / %u bytes\n", le32_to_cpu(css->header_len), le32_to_cpu(css->header_len) * 4); printf("Header version:\t%u.%u\n", le32_to_cpu(css->header_version) >> 16, le32_to_cpu(css->header_version) & 0xffff); printf("Module ID:\t%u\n", le32_to_cpu(css->module_id)); printf("Module vendor:\t%u\n", le32_to_cpu(css->module_vendor)); printf("Date:\t\t%u\n", le32_to_cpu(css->date)); printf("Size:\t\t%u DWORDs / %u bytes\n", le32_to_cpu(css->size), le32_to_cpu(css->size) * 4); printf("Key size:\t%u DWORDs / %u bytes\n", le32_to_cpu(css->key_size), le32_to_cpu(css->key_size) * 4); printf("Modulus size:\t%u DWORDs / %u bytes\n", le32_to_cpu(css->modulus_size), le32_to_cpu(css->modulus_size) * 4); printf("Exponent size:\t%u DWORDs / %u bytes\n", le32_to_cpu(css->exponent_size), le32_to_cpu(css->exponent_size) * 4); printf("\n"); if ((size_t) len != le32_to_cpu(css->size) * 4) { fprintf(stderr, "CSS.size does not match file length\n"); goto done; } if (le32_to_cpu(css->header_len) != (sizeof(*css) / 4) + le32_to_cpu(css->key_size) + le32_to_cpu(css->modulus_size) + le32_to_cpu(css->exponent_size)) { fprintf(stderr, "CSS.headerLen does not match data sizes\n"); goto done; } firmware_size = le32_to_cpu(css->size) * 4; firmware_offset = le32_to_cpu(css->header_len) * 4; while (firmware_offset < firmware_size) { uint16_t opcode; uint8_t dlen; opcode = get_le16(firmware_data + firmware_offset); dlen = firmware_data[firmware_offset + 2]; switch (opcode) { case CMD_NO_OPERATION: case CMD_WRITE_BOOT_PARAMS: case CMD_MEMORY_WRITE: break; default: printf("Unexpected opcode 0x%02x\n", opcode); break; } firmware_offset += dlen + 3; cmd_num++; } printf("Firmware with %u commands\n", cmd_num); done: free(firmware_data); } static void signal_callback(int signum, void *user_data) { switch (signum) { case SIGINT: case SIGTERM: mainloop_quit(); break; } } static void usage(void) { printf("bluemoon - Bluemoon configuration utility\n" "Usage:\n"); printf("\tbluemoon [options]\n"); printf("Options:\n" "\t-A, --bdaddr [addr] Set Bluetooth address\n" "\t-F, --firmware [file] Load firmware\n" "\t-C, --check Check firmware image\n" "\t-R, --reset Reset controller\n" "\t-B, --coldboot Cold boot controller\n" "\t-E, --exception Trigger exception\n" "\t-i, --index Use specified controller\n" "\t-h, --help Show help options\n"); } static const struct option main_options[] = { { "bdaddr", optional_argument, NULL, 'A' }, { "bddata", no_argument, NULL, 'D' }, { "firmware", optional_argument, NULL, 'F' }, { "check", required_argument, NULL, 'C' }, { "traces", no_argument, NULL, 'T' }, { "reset", no_argument, NULL, 'R' }, { "coldboot", no_argument, NULL, 'B' }, { "exception",no_argument, NULL, 'E' }, { "index", required_argument, NULL, 'i' }, { "raw", no_argument, NULL, 'r' }, { "version", no_argument, NULL, 'v' }, { "help", no_argument, NULL, 'h' }, { } }; int main(int argc, char *argv[]) { const char *str; bool use_raw = false; int exit_status; for (;;) { int opt; opt = getopt_long(argc, argv, "A::DF::C:TRBEi:rvh", main_options, NULL); if (opt < 0) break; switch (opt) { case 'A': if (optarg) set_bdaddr_value = optarg; set_bdaddr = true; break; case 'D': use_manufacturer_mode = true; get_bddata = true; break; case 'F': use_manufacturer_mode = true; if (optarg) load_firmware_value = optarg; load_firmware = true; break; case 'C': check_firmware_value = optarg; check_firmware = true; break; case 'E': use_manufacturer_mode = true; set_exception = true; break; case 'T': use_manufacturer_mode = true; set_traces = true; break; case 'R': reset_on_exit = true; break; case 'B': cold_boot = true; break; case 'i': if (strlen(optarg) > 3 && !strncmp(optarg, "hci", 3)) str = optarg + 3; else str = optarg; if (!isdigit(*str)) { usage(); return EXIT_FAILURE; } hci_index = atoi(str); break; case 'r': use_raw = true; break; case 'v': printf("%s\n", VERSION); return EXIT_SUCCESS; case 'h': usage(); return EXIT_SUCCESS; default: return EXIT_FAILURE; } } if (argc - optind > 0) { fprintf(stderr, "Invalid command line parameters\n"); return EXIT_FAILURE; } mainloop_init(); printf("Bluemoon configuration utility ver %s\n", VERSION); if (check_firmware) { analyze_firmware(check_firmware_value); return EXIT_SUCCESS; } if (use_raw) { hci_dev = bt_hci_new_raw_device(hci_index); if (!hci_dev) { fprintf(stderr, "Failed to open HCI raw device\n"); return EXIT_FAILURE; } } else { hci_dev = bt_hci_new_user_channel(hci_index); if (!hci_dev) { fprintf(stderr, "Failed to open HCI user channel\n"); return EXIT_FAILURE; } } bt_hci_send(hci_dev, CMD_READ_VERSION, NULL, 0, read_version_complete, NULL, NULL); exit_status = mainloop_run_with_signal(signal_callback, NULL); bt_hci_unref(hci_dev); return exit_status; }