/****************************************************************************** * * Copyright (C) 2015, The linux Foundation. All rights reserved. * * Not a Contribution. * * Copyright (C) 2009-2012 Broadcom Corporation * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at: * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * ******************************************************************************/ /************************************************************************************ * * Filename: mcap_tool.c * * Description: Bluedroid MCAP TOOL application * ***********************************************************************************/ #include #include #include #include #include #include #include #include #include #include #include #include "l2c_api.h" #include #include #include #include #include #include #include #include "bt_testapp.h" #include "mca_defs.h" #include "mca_api.h" /************************************************************************************ ** Constants & Macros ************************************************************************************/ //#define TRUE 1 //#define FALSE 0 #define PID_FILE "/data/.bdt_pid" #ifndef MAX #define MAX(x, y) ((x) > (y) ? (x) : (y)) #endif #define CASE_RETURN_STR(const) case const: return #const; #define TRANSPORT_BREDR 1 //Add tranport parameter to create bond /************************************************************************************ ** Local type definitions ************************************************************************************/ /************************************************************************************ ** Static variables ************************************************************************************/ static unsigned char main_done = 0; static bt_status_t status; static bool strict_mode = FALSE; /* Main API */ static bluetooth_device_t* bt_device; const bt_interface_t* sBtInterface = NULL; static gid_t groups[] = { AID_NET_BT, AID_INET, AID_NET_BT_ADMIN, AID_SYSTEM, AID_MISC, AID_SDCARD_RW, AID_NET_ADMIN, AID_VPN}; /* Set to 1 when the Bluedroid stack is enabled */ static unsigned char bt_enabled = 0; enum { DISCONNECT, CONNECTING, CONNECTED, DISCONNECTING }; static int g_AdapterState = BT_STATE_OFF; static int g_PairState = BT_BOND_STATE_NONE; btmcap_interface_t *sMcapIface = NULL; tMCA_HANDLE g_Mcap_Handle = 0; tMCA_DEP g_Mcap_Dep = 0; tL2CAP_FCR_OPTS g_fcr_opts = { L2CAP_FCR_ERTM_MODE, MCA_FCR_OPT_TX_WINDOW_SIZE, /* Tx window size */ MCA_FCR_OPT_MAX_TX_B4_DISCNT, /* Maximum transmissions before disconnecting */ MCA_FCR_OPT_RETX_TOUT, /* Retransmission timeout (2 secs) */ MCA_FCR_OPT_MONITOR_TOUT, /* Monitor timeout (12 secs) */ MCA_FCR_OPT_MPS_SIZE /* MPS segment size */ }; tMCA_CHNL_CFG g_chnl_cfg = { { L2CAP_FCR_ERTM_MODE, MCA_FCR_OPT_TX_WINDOW_SIZE, /* Tx window size */ MCA_FCR_OPT_MAX_TX_B4_DISCNT, /* Maximum transmissions before disconnecting */ MCA_FCR_OPT_RETX_TOUT, /* Retransmission timeout (2 secs) */ MCA_FCR_OPT_MONITOR_TOUT, /* Monitor timeout (12 secs) */ MCA_FCR_OPT_MPS_SIZE /* MPS segment size */ }, BT_DEFAULT_BUFFER_SIZE, BT_DEFAULT_BUFFER_SIZE, BT_DEFAULT_BUFFER_SIZE, BT_DEFAULT_BUFFER_SIZE, MCA_FCS_NONE, 572 }; UINT16 g_Peer_Mtu = 0; UINT16 g_Mdl_Id = 0; tMCA_DL g_Mdl = 0; tMCA_CL g_Mcl = 0; /************************************************************************************ ** Static functions ************************************************************************************/ static void process_cmd(char *p, unsigned char is_job); static void bdt_log(const char *fmt_str, ...); int GetBdAddr(char *p, bt_bdaddr_t *pbd_addr); static int str2bd(char *str, bt_bdaddr_t *addr) { int32_t i = 0; for (i = 0; i < 6; i++) { addr->address[i] = (uint8_t) strtoul(str, (char **)&str, 16); str++; } return 0; } /************************************************************************************ ** Externs ************************************************************************************/ /************************************************************************************ ** MCAP Callbacks ************************************************************************************/ static void mcap_ctrl_cb(tMCA_HANDLE handle, tMCA_CL mcl, UINT8 event, tMCA_CTRL *p_data) { tMCA_RESULT Ret; //printf("%s:: handle=%d, mcl=%d, event=0x%x, g_Mdl=%d, g_Mdl_Id=%d \n", __FUNCTION__, handle, mcl, event, g_Mdl, g_Mdl_Id); switch(event) { case MCA_CREATE_IND_EVT: //printf("%s::Create_ind::Mdl_Id=%d, OpCode=%d, dep_id=%d, cfg=%d \n", __FUNCTION__, p_data->create_ind.mdl_id, //p_data->create_ind.op_code, p_data->create_ind.dep_id, p_data->create_ind.cfg); g_Mdl = p_data->create_ind.mdl_id; Ret = sMcapIface->CreateMdlRsp(mcl, p_data->create_ind.dep_id, g_Mdl, p_data->create_ind.cfg, MCA_SUCCESS, &g_chnl_cfg); break; case MCA_CONNECT_IND_EVT: //printf("%s::Connect_Ind:: peer_mtu=%d \n", __FUNCTION__, p_data->connect_ind.mtu); g_Mcl = mcl; break; case MCA_DISCONNECT_IND_EVT: g_Mcl = 0; break; case MCA_OPEN_IND_EVT: case MCA_OPEN_CFM_EVT: g_Mdl_Id = p_data->open_ind.mdl_id; g_Mdl = p_data->open_ind.mdl; g_Peer_Mtu = p_data->open_ind.mtu; break; case MCA_RECONNECT_IND_EVT: //printf("%s::Reconnect Ind:: Mdl_Id=%d, g_Mdl_Id=%d\n", __FUNCTION__, p_data->reconnect_ind.mdl_id, g_Mdl_Id); Ret = sMcapIface->ReconnectMdlRsp(mcl, g_Mcap_Dep, p_data->reconnect_ind.mdl_id, (g_Mdl_Id==p_data->reconnect_ind.mdl_id) ?MCA_RSP_SUCCESS :MCA_RSP_BAD_MDL, &g_chnl_cfg); break; case MCA_DELETE_IND_EVT: //printf("%s::Delete Ind:: Mdl_Id=%d\n", __FUNCTION__, p_data->delete_ind.mdl_id); if((0xffff==p_data->delete_ind.mdl_id)||(g_Mdl_Id == p_data->delete_ind.mdl_id)) g_Mdl_Id = 0; break; case MCA_SYNC_CAP_IND_EVT: //printf("%s::Sync Cap Ind::\n", __FUNCTION__); break; case MCA_ABORT_IND_EVT: //printf("%s::Abort_Ind::Mdl_Id=%d, opCode=%d \n", __FUNCTION__, p_data->abort_ind.mdl_id, p_data->abort_ind.op_code); break; } } static void mcap_data_cb(tMCA_DL mdl, BT_HDR *p_pkt) { //printf("%s:: mdl=%d, event=%d, len=%d, offset=%d, layer_specific=%d\n", __FUNCTION__, mdl, p_pkt->event, p_pkt->len, p_pkt->offset, p_pkt->layer_specific); } /************************************************************************************ ** Shutdown helper functions ************************************************************************************/ static void bdt_shutdown(void) { bdt_log("shutdown bdroid test app\n"); main_done = 1; } /***************************************************************************** ** Android's init.rc does not yet support applying linux capabilities *****************************************************************************/ static void config_permissions(void) { struct __user_cap_header_struct header; struct __user_cap_data_struct cap[2]; bdt_log("set_aid_and_cap : pid %d, uid %d gid %d", getpid(), getuid(), getgid()); header.pid = 0; prctl(PR_SET_KEEPCAPS, 1, 0, 0, 0); setuid(AID_BLUETOOTH); setgid(AID_BLUETOOTH); header.version = _LINUX_CAPABILITY_VERSION_3; cap[CAP_TO_INDEX(CAP_NET_RAW)].permitted |= CAP_TO_MASK(CAP_NET_RAW); cap[CAP_TO_INDEX(CAP_NET_ADMIN)].permitted |= CAP_TO_MASK(CAP_NET_ADMIN); cap[CAP_TO_INDEX(CAP_NET_BIND_SERVICE)].permitted |= CAP_TO_MASK(CAP_NET_BIND_SERVICE); cap[CAP_TO_INDEX(CAP_SYS_RAWIO)].permitted |= CAP_TO_MASK(CAP_SYS_RAWIO); cap[CAP_TO_INDEX(CAP_SYS_NICE)].permitted |= CAP_TO_MASK(CAP_SYS_NICE); cap[CAP_TO_INDEX(CAP_SETGID)].permitted |= CAP_TO_MASK(CAP_SETGID); cap[CAP_TO_INDEX(CAP_WAKE_ALARM)].permitted |= CAP_TO_MASK(CAP_WAKE_ALARM); cap[CAP_TO_INDEX(CAP_NET_RAW)].effective |= CAP_TO_MASK(CAP_NET_RAW); cap[CAP_TO_INDEX(CAP_NET_ADMIN)].effective |= CAP_TO_MASK(CAP_NET_ADMIN); cap[CAP_TO_INDEX(CAP_NET_BIND_SERVICE)].effective |= CAP_TO_MASK(CAP_NET_BIND_SERVICE); cap[CAP_TO_INDEX(CAP_SYS_RAWIO)].effective |= CAP_TO_MASK(CAP_SYS_RAWIO); cap[CAP_TO_INDEX(CAP_SYS_NICE)].effective |= CAP_TO_MASK(CAP_SYS_NICE); cap[CAP_TO_INDEX(CAP_SETGID)].effective |= CAP_TO_MASK(CAP_SETGID); cap[CAP_TO_INDEX(CAP_WAKE_ALARM)].effective |= CAP_TO_MASK(CAP_WAKE_ALARM); capset(&header, &cap[0]); setgroups(sizeof(groups)/sizeof(groups[0]), groups); } /***************************************************************************** ** Logger API *****************************************************************************/ void bdt_log(const char *fmt_str, ...) { static char buffer[1024]; va_list ap; va_start(ap, fmt_str); vsnprintf(buffer, 1024, fmt_str, ap); va_end(ap); fprintf(stdout, "%s\n", buffer); } /******************************************************************************* ** Misc helper functions *******************************************************************************/ static const char* dump_bt_status(bt_status_t status) { switch(status) { CASE_RETURN_STR(BT_STATUS_SUCCESS) CASE_RETURN_STR(BT_STATUS_FAIL) CASE_RETURN_STR(BT_STATUS_NOT_READY) CASE_RETURN_STR(BT_STATUS_NOMEM) CASE_RETURN_STR(BT_STATUS_BUSY) CASE_RETURN_STR(BT_STATUS_UNSUPPORTED) default: return "unknown status code"; } } #if 0 static void hex_dump(char *msg, void *data, int size, int trunc) { unsigned char *p = data; unsigned char c; int n; char bytestr[4] = {0}; char addrstr[10] = {0}; char hexstr[ 16*3 + 5] = {0}; char charstr[16*1 + 5] = {0}; bdt_log("%s \n", msg); /* truncate */ if(trunc && (size>32)) size = 32; for(n=1;n<=size;n++) { if (n%16 == 1) { /* store address for this line */ snprintf(addrstr, sizeof(addrstr), "%.4x", ((unsigned int)p-(unsigned int)data) ); } c = *p; if (isalnum(c) == 0) { c = '.'; } /* store hex str (for left side) */ snprintf(bytestr, sizeof(bytestr), "%02X ", *p); strlcat(hexstr, bytestr, sizeof(hexstr)-strlen(hexstr)-1); /* store char str (for right side) */ snprintf(bytestr, sizeof(bytestr), "%c", c); strlcat(charstr, bytestr, sizeof(charstr)-strlen(charstr)-1); if(n%16 == 0) { /* line completed */ bdt_log("[%4.4s] %-50.50s %s\n", addrstr, hexstr, charstr); hexstr[0] = 0; charstr[0] = 0; } else if(n%8 == 0) { /* half line: add whitespaces */ strlcat(hexstr, " ", sizeof(hexstr)-strlen(hexstr)-1); strlcat(charstr, " ", sizeof(charstr)-strlen(charstr)-1); } p++; /* next byte */ } if (strlen(hexstr) > 0) { /* print rest of buffer if not empty */ bdt_log("[%4.4s] %-50.50s %s\n", addrstr, hexstr, charstr); } } #endif /******************************************************************************* ** Console helper functions *******************************************************************************/ void skip_blanks(char **p) { while (**p == ' ') (*p)++; } uint32_t get_int(char **p, int DefaultValue) { uint32_t Value = 0; unsigned char UseDefault; UseDefault = 1; skip_blanks(p); while ( ((**p)<= '9' && (**p)>= '0') ) { Value = Value * 10 + (**p) - '0'; UseDefault = 0; (*p)++; } if (UseDefault) return DefaultValue; else return Value; } int get_signed_int(char **p, int DefaultValue) { int Value = 0; unsigned char UseDefault; unsigned char NegativeNum = 0; UseDefault = 1; skip_blanks(p); if ( (**p) == '-') { NegativeNum = 1; (*p)++; } while ( ((**p)<= '9' && (**p)>= '0') ) { Value = Value * 10 + (**p) - '0'; UseDefault = 0; (*p)++; } if (UseDefault) return DefaultValue; else return ((NegativeNum == 0)? Value : -Value); } void get_str(char **p, char *Buffer) { skip_blanks(p); while (**p != 0 && **p != ' ') { *Buffer = **p; (*p)++; Buffer++; } *Buffer = 0; } uint32_t get_hex_any(char **p, int DefaultValue, unsigned int NumOfNibble) { uint32_t Value = 0; unsigned char UseDefault; //unsigned char NumOfNibble = 8; //Since we are returning uint32, max allowed is 4 bytes(8 nibbles). UseDefault = 1; skip_blanks(p); while ((NumOfNibble) && (((**p)<= '9' && (**p)>= '0') || ((**p)<= 'f' && (**p)>= 'a') || ((**p)<= 'F' && (**p)>= 'A')) ) { if (**p >= 'a') Value = Value * 16 + (**p) - 'a' + 10; else if (**p >= 'A') Value = Value * 16 + (**p) - 'A' + 10; else Value = Value * 16 + (**p) - '0'; UseDefault = 0; (*p)++; NumOfNibble--; } if (UseDefault) return DefaultValue; else return Value; } uint32_t get_hex(char **p, int DefaultValue) { //unsigned char NumOfNibble = 8; //Since we are returning uint32, max allowed is 4 bytes(8 nibbles). return (get_hex_any(p, DefaultValue, 8)); } uint32_t get_hex_byte(char **p, int DefaultValue) { return (get_hex_any(p, DefaultValue, 2)); } void get_bdaddr(const char *str, bt_bdaddr_t *bd) { char *d = ((char *)bd), *endp; int i; for(i = 0; i < 6; i++) { *d++ = strtol(str, &endp, 16); if (*endp != ':' && i != 5) { memset(bd, 0, sizeof(bt_bdaddr_t)); return; } str = endp + 1; } } #define is_cmd(str) ((strlen(str) == strlen(cmd)) && strncmp((const char *)&cmd, str, strlen(str)) == 0) #define if_cmd(str) if (is_cmd(str)) typedef void (t_console_cmd_handler) (char *p); typedef struct { const char *name; t_console_cmd_handler *handler; const char *help; unsigned char is_job; } t_cmd; const t_cmd console_cmd_list[]; static int console_cmd_maxlen = 0; static void cmdjob_handler(void *param) { char *job_cmd = (char*)param; bdt_log("cmdjob starting (%s)", job_cmd); process_cmd(job_cmd, 1); bdt_log("cmdjob terminating"); free(job_cmd); } static int create_cmdjob(char *cmd) { pthread_t thread_id; char *job_cmd; job_cmd = malloc(strlen(cmd)+1); /* freed in job handler */ if(job_cmd) { strlcpy(job_cmd, cmd, strlen(job_cmd)+1); if (pthread_create(&thread_id, NULL, (void*)cmdjob_handler, (void*)job_cmd)!=0) perror("pthread_create"); } else bdt_log("Mecap_test: Cannot Allocate memory for cmdjob"); return 0; } /******************************************************************************* ** Load stack lib *******************************************************************************/ int HAL_load(void) { int err = 0; hw_module_t* module; hw_device_t* device; bdt_log("Loading HAL lib + extensions"); err = hw_get_module(BT_HARDWARE_MODULE_ID, (hw_module_t const**)&module); if (err == 0) { err = module->methods->open(module, BT_HARDWARE_MODULE_ID, &device); if (err == 0) { bt_device = (bluetooth_device_t *)device; sBtInterface = bt_device->get_bluetooth_interface(); } } bdt_log("HAL library loaded (%s)", strerror(err)); return err; } int HAL_unload(void) { int err = 0; bdt_log("Unloading HAL lib"); sBtInterface = NULL; bdt_log("HAL library unloaded (%s)", strerror(err)); return err; } /******************************************************************************* ** HAL test functions & callbacks *******************************************************************************/ void setup_test_env(void) { int i = 0; while (console_cmd_list[i].name != NULL) { console_cmd_maxlen = MAX(console_cmd_maxlen, (int)strlen(console_cmd_list[i].name)); i++; } } void check_return_status(bt_status_t status) { if (status != BT_STATUS_SUCCESS) { bdt_log("HAL REQUEST FAILED status : %d (%s)", status, dump_bt_status(status)); } else { bdt_log("HAL REQUEST SUCCESS"); } } static void adapter_state_changed(bt_state_t state) { int V1 = 1000, V2=2; bt_property_t property = {9 /*BT_PROPERTY_DISCOVERY_TIMEOUT*/, 4, &V1}; bt_property_t property1 = {7 /*SCAN*/, 2, &V2}; bt_property_t property2 ={1,6,"Bluedroid"}; g_AdapterState = state; if (state == BT_STATE_ON) { bt_enabled = 1; status = sBtInterface->set_adapter_property(&property1); status = sBtInterface->set_adapter_property(&property); status = sBtInterface->set_adapter_property(&property2); } else { bt_enabled = 0; } } static void adapter_properties_changed(bt_status_t status, int num_properties, bt_property_t *properties) { char Bd_addr[15] = {0}; if(NULL == properties) { printf("properties is null\n"); return; } switch(properties->type) { case BT_PROPERTY_BDADDR: memcpy(Bd_addr, properties->val, properties->len); printf("Local Bd Addr = %02x:%02x:%02x:%02x:%02x:%02x\n", Bd_addr[0], Bd_addr[1], Bd_addr[2], Bd_addr[3], Bd_addr[4], Bd_addr[5]); break; default : break; } return; } static void discovery_state_changed(bt_discovery_state_t state) { printf("Discovery State Updated : %s\n", (state == BT_DISCOVERY_STOPPED)?"STOPPED":"STARTED"); } static void pin_request_cb(bt_bdaddr_t *remote_bd_addr, bt_bdname_t *bd_name, uint32_t cod, bool min_16_digit) { bt_pin_code_t pincode = {{ 0x31, 0x32, 0x33, 0x34}}; if(BT_STATUS_SUCCESS != sBtInterface->pin_reply(remote_bd_addr, TRUE, 4, &pincode)) { printf("Pin Reply failed\n"); } } static void ssp_request_cb(bt_bdaddr_t *remote_bd_addr, bt_bdname_t *bd_name, uint32_t cod, bt_ssp_variant_t pairing_variant, uint32_t pass_key) { printf("ssp_request_cb : %s %d %u\n", bd_name->name, pairing_variant, pass_key); if(BT_STATUS_SUCCESS != sBtInterface->ssp_reply(remote_bd_addr, pairing_variant, TRUE, pass_key)) { printf("SSP Reply failed\n"); } } static void bond_state_changed_cb(bt_status_t status, bt_bdaddr_t *remote_bd_addr, bt_bond_state_t state) { printf("Bond State Changed = %d\n", state); g_PairState = state; } static void acl_state_changed(bt_status_t status, bt_bdaddr_t *remote_bd_addr, bt_acl_state_t state) { printf("acl_state_changed : remote_bd_addr=%02x:%02x:%02x:%02x:%02x:%02x, acl status=%s \n", remote_bd_addr->address[0], remote_bd_addr->address[1], remote_bd_addr->address[2], remote_bd_addr->address[3], remote_bd_addr->address[4], remote_bd_addr->address[5], (state == BT_ACL_STATE_CONNECTED)?"ACL Connected" :"ACL Disconnected" ); } static void dut_mode_recv(uint16_t opcode, uint8_t *buf, uint8_t len) { bdt_log("DUT MODE RECV : NOT IMPLEMENTED"); } #if BLE_INCLUDED == TRUE static void le_test_mode(bt_status_t status, uint16_t packet_count) { bdt_log("LE TEST MODE END status:%s number_of_packets:%d", dump_bt_status(status), packet_count); } #endif static bt_callbacks_t bt_callbacks = { sizeof(bt_callbacks_t), adapter_state_changed, adapter_properties_changed, /*adapter_properties_cb */ NULL, /* remote_device_properties_cb */ NULL, /* device_found_cb */ discovery_state_changed, /* discovery_state_changed_cb */ pin_request_cb, /* pin_request_cb */ ssp_request_cb, /* ssp_request_cb */ bond_state_changed_cb, /*bond_state_changed_cb */ acl_state_changed, /* acl_state_changed_cb */ NULL, /* thread_evt_cb */ dut_mode_recv, /*dut_mode_recv_cb */ // NULL, /*authorize_request_cb */ #if BLE_INCLUDED == TRUE le_test_mode, /* le_test_mode_cb */ #else NULL, #endif NULL, NULL }; static bool set_wake_alarm(uint64_t delay_millis, bool should_wake, alarm_cb cb, void *data) { static timer_t timer; static bool timer_created; if (!timer_created) { struct sigevent sigevent; memset(&sigevent, 0, sizeof(sigevent)); sigevent.sigev_notify = SIGEV_THREAD; sigevent.sigev_notify_function = (void (*)(union sigval))cb; sigevent.sigev_value.sival_ptr = data; timer_create(CLOCK_MONOTONIC, &sigevent, &timer); timer_created = true; } struct itimerspec new_value; new_value.it_value.tv_sec = delay_millis / 1000; new_value.it_value.tv_nsec = (delay_millis % 1000) * 1000 * 1000; new_value.it_interval.tv_sec = 0; new_value.it_interval.tv_nsec = 0; timer_settime(timer, 0, &new_value, NULL); return true; } static int acquire_wake_lock(const char *lock_name) { return BT_STATUS_SUCCESS; } static int release_wake_lock(const char *lock_name) { return BT_STATUS_SUCCESS; } static bt_os_callouts_t callouts = { sizeof(bt_os_callouts_t), set_wake_alarm, acquire_wake_lock, release_wake_lock, }; void bdt_init(void) { bdt_log("INIT BT "); status = sBtInterface->init(&bt_callbacks, false); if (status == BT_STATUS_SUCCESS) { status = sBtInterface->set_os_callouts(&callouts); } check_return_status(status); } void bdt_enable(void) { bdt_log("ENABLE BT"); if (bt_enabled) { bdt_log("Bluetooth is already enabled"); return; } status = sBtInterface->enable(strict_mode); check_return_status(status); } void bdt_disable(void) { bdt_log("DISABLE BT"); if (!bt_enabled) { bdt_log("Bluetooth is already disabled"); return; } status = sBtInterface->disable(); check_return_status(status); } void bdt_dut_mode_configure(char *p) { int32_t mode = -1; bdt_log("BT DUT MODE CONFIGURE"); if (!bt_enabled) { bdt_log("Bluetooth must be enabled for test_mode to work."); return; } mode = get_signed_int(&p, mode); if ((mode != 0) && (mode != 1)) { bdt_log("Please specify mode: 1 to enter, 0 to exit"); return; } status = sBtInterface->dut_mode_configure(mode); check_return_status(status); } #define HCI_LE_RECEIVER_TEST_OPCODE 0x201D #define HCI_LE_TRANSMITTER_TEST_OPCODE 0x201E #define HCI_LE_END_TEST_OPCODE 0x201F void bdt_le_test_mode(char *p) { int cmd; unsigned char buf[3]; int arg1, arg2, arg3; bdt_log("BT LE TEST MODE"); if (!bt_enabled) { bdt_log("Bluetooth must be enabled for le_test to work."); return; } memset(buf, 0, sizeof(buf)); cmd = get_int(&p, 0); switch (cmd) { case 0x1: /* RX TEST */ arg1 = get_int(&p, -1); if (arg1 < 0) bdt_log("%s Invalid arguments", __FUNCTION__); buf[0] = arg1; status = sBtInterface->le_test_mode(HCI_LE_RECEIVER_TEST_OPCODE, buf, 1); break; case 0x2: /* TX TEST */ arg1 = get_int(&p, -1); arg2 = get_int(&p, -1); arg3 = get_int(&p, -1); if ((arg1 < 0) || (arg2 < 0) || (arg3 < 0)) bdt_log("%s Invalid arguments", __FUNCTION__); buf[0] = arg1; buf[1] = arg2; buf[2] = arg3; status = sBtInterface->le_test_mode(HCI_LE_TRANSMITTER_TEST_OPCODE, buf, 3); break; case 0x3: /* END TEST */ status = sBtInterface->le_test_mode(HCI_LE_END_TEST_OPCODE, buf, 0); break; default: bdt_log("Unsupported command"); return; break; } if (status != BT_STATUS_SUCCESS) { bdt_log("%s Test 0x%x Failed with status:0x%x", __FUNCTION__, cmd, status); } return; } void bdt_cleanup(void) { bdt_log("CLEANUP"); sBtInterface->cleanup(); } /******************************************************************************* ** Console commands *******************************************************************************/ void do_help(char *p) { int i = 0; char line[128]; int pos = 0; while (console_cmd_list[i].name != NULL) { pos = snprintf(line, sizeof(line), "%s", (char*)console_cmd_list[i].name); bdt_log("%s %s\n", (char*)line, (char*)console_cmd_list[i].help); i++; } } void do_quit(char *p) { bdt_shutdown(); } /******************************************************************* * * BT TEST CONSOLE COMMANDS * * Parses argument lists and passes to API test function * */ void do_init(char *p) { bdt_init(); } void do_enable(char *p) { bdt_enable(); } void do_disable(char *p) { bdt_disable(); } void do_cleanup(char *p) { bdt_cleanup(); } /******************************************************************************* ** MCAP API commands *******************************************************************************/ void do_mcap_register(char *p) { tMCA_REG Mca_Reg; Mca_Reg.rsp_tout = 5000; //Need to check if we have to give in msec or seconds Mca_Reg.ctrl_psm = get_hex(&p, -1); // arg1 Mca_Reg.data_psm = get_hex(&p, -1); // arg2 Mca_Reg.sec_mask = get_int(&p, -1); // arg3 g_Mcap_Handle = sMcapIface->Register(&Mca_Reg, mcap_ctrl_cb); printf("%s:: Ret=%d \n", __FUNCTION__, g_Mcap_Handle); } void do_mcap_deregister(char *p) { sMcapIface->Deregister(g_Mcap_Handle); printf("%s:: Handle=%d \n", __FUNCTION__, g_Mcap_Handle); } void do_mcap_create_dep(char *p) { tMCA_RESULT Ret = 0; int type = 0; tMCA_CS Mca_cs ; type = get_int(&p, -1); // arg1 memset ((void*)&Mca_cs ,0 ,sizeof(tMCA_CS)); Mca_cs.type = (0 == type) ? MCA_TDEP_ECHO :MCA_TDEP_DATA; Mca_cs.max_mdl = MCA_NUM_MDLS; Mca_cs.p_data_cback = mcap_data_cb; Ret = sMcapIface->CreateDep(g_Mcap_Handle, &g_Mcap_Dep, &Mca_cs); printf("%s:: Ret=%d \n", __FUNCTION__, Ret); } static void do_mcap_delete_dep(char *p) { tMCA_RESULT Ret = 0; Ret = sMcapIface->DeleteDep(g_Mcap_Handle, g_Mcap_Dep); printf("%s:: Ret=%d \n", __FUNCTION__, Ret); } static void do_mcap_connect(char *p) { tMCA_RESULT Ret = 0; bt_bdaddr_t bd_addr = {{0}}; UINT16 ctrl_psm = 0; UINT16 sec_mask = 0; char buf[64]; get_str(&p, buf); str2bd(buf, &bd_addr); ctrl_psm = get_hex(&p, -1);// arg2 sec_mask = get_int(&p, -1);// arg3 printf("ctrl_psm=%d, secMask=%d \n", ctrl_psm, sec_mask); Ret = sMcapIface->ConnectReq(g_Mcap_Handle, bd_addr.address, ctrl_psm, sec_mask); printf("%s:: Ret=%d \n", __FUNCTION__, Ret); } static void do_mcap_disconnect(char *p) { tMCA_RESULT Ret = 0; Ret = sMcapIface->DisconnectReq(g_Mcl); printf("%s:: Ret=%d \n", __FUNCTION__, Ret); } static void do_mcap_create_mdl(char *p) { tMCA_RESULT Ret = 0; UINT16 data_psm = 0; data_psm = get_hex(&p, -1); // arg1 Ret = sMcapIface->CreateMdl(g_Mcl, g_Mcap_Dep, data_psm, 1, 1, 1, &g_chnl_cfg); printf("%s:: Ret=%d \n", __FUNCTION__, Ret); } static void do_mcap_close(char *p) { tMCA_RESULT Ret = 0; Ret = sMcapIface->CloseReq(g_Mdl); printf("%s:: Ret=%d \n", __FUNCTION__, Ret); } static void do_pairing(char *p) { bt_bdaddr_t bd_addr = {{0}}; if(FALSE == GetBdAddr(p, &bd_addr)) return; // arg1 if(BT_STATUS_SUCCESS != sBtInterface->create_bond(&bd_addr, TRANSPORT_BREDR)) { printf("Failed to Initiate Pairing \n"); return; } } /******************************************************************* * * CONSOLE COMMAND TABLE * */ const t_cmd console_cmd_list[] = { /* * INTERNAL */ { "help", do_help, "lists all available console commands", 0 }, { "quit", do_quit, "", 0}, /* * API CONSOLE COMMANDS */ /* Init and Cleanup shall be called automatically */ { "enable", do_enable, ":: enables bluetooth", 0 }, { "disable", do_disable, ":: disables bluetooth", 0 }, { "pair", do_pairing, ":: BdAddr<00112233445566>", 0 }, { "register", do_mcap_register, "::Ctrl_Psm, Data_Psm, Security<0-10>", 0 }, { "deregister", do_mcap_deregister, "::", 0 }, { "create_data_endpoint", do_mcap_create_dep, "::Type<0-Echo, 1-NormalData>", 0 }, { "delete_data_endpoint", do_mcap_delete_dep, "::", 0 }, { "connect", do_mcap_connect, ":: BdAddr<00112233445566>, Ctrl_Psm, SecMask", 0 }, { "disconnect", do_mcap_disconnect, ":: BdAddr<00112233445566>", 0 }, { "create_mdl", do_mcap_create_mdl, ":: Data_Psm", 0 }, { "close_data_channel", do_mcap_close, "::", 0 }, /* last entry */ {NULL, NULL, "", 0}, }; /* * Main console command handler */ static void process_cmd(char *p, unsigned char is_job) { char cmd[2048]; int i = 0; char *p_saved = p; get_str(&p, cmd); /* table commands */ while (console_cmd_list[i].name != NULL) { if (is_cmd(console_cmd_list[i].name)) { if (!is_job && console_cmd_list[i].is_job) create_cmdjob(p_saved); else { console_cmd_list[i].handler(p); } return; } i++; } bdt_log("%s : unknown command\n", p_saved); do_help(NULL); } int main (int argc, char * argv[]) { config_permissions(); bdt_log("\n:::::::::::::::::::::::::::::::::::::::::::::::::::"); bdt_log(":: Bluedroid test app starting"); if ( HAL_load() < 0 ) { perror("HAL failed to initialize, exit\n"); unlink(PID_FILE); exit(0); } setup_test_env(); /* Automatically perform the init */ bdt_init(); sleep(5); bdt_enable(); sleep(5); sMcapIface = (btmcap_interface_t *)sBtInterface->get_testapp_interface(TEST_APP_MCAP); //sSmpIface = sBtInterface->get_testapp_interface(TEST_APP_SMP); sleep(1); sMcapIface->Init(); while(!main_done) { char line[2048]; /* command prompt */ printf( ">" ); fflush(stdout); fgets (line, 2048, stdin); if (line[0]!= '\0') { /* remove linefeed */ line[strlen(line)-1] = 0; process_cmd(line, 0); memset(line, '\0', 2048); } } /* FIXME: Commenting this out as for some reason, the application does not exit otherwise*/ //bdt_cleanup(); HAL_unload(); bdt_log(":: Bluedroid test app terminating"); return 0; } int GetBdAddr(char *p, bt_bdaddr_t *pbd_addr) { char Arr[13] = {0}; UINT8 k1 = 0; UINT8 k2 = 0; int i; if(12 != strlen(p)) { printf("\nInvalid Bd Address. Format[112233445566]\n"); return FALSE; } strlcpy(Arr, p, sizeof(Arr)); for(i=0; i<12; i++) { Arr[i] = tolower(Arr[i]); } for(i=0; i<6; i++) { k1 = (UINT8) ( (Arr[i*2] >= 'a') ? ( 10 + (UINT8)( Arr[i*2] - 'a' )) : (Arr[i*2] - '0') ); k2 = (UINT8) ( (Arr[(i*2)+1] >= 'a') ? ( 10 + (UINT8)( Arr[(i*2)+1] - 'a' )) : (Arr[(i*2)+1] - '0') ); if ( (k1>15)||(k2>15) ) { return FALSE; } pbd_addr->address[i] = (k1<<4 | k2); } return TRUE; }