/****************************************************************************** * * 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: btif_pan.c * * Description: PAN Profile Bluetooth Interface * * ***********************************************************************************/ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #define LOG_TAG "bt_btif_pan" #include "btif_common.h" #include "btif_util.h" #include "btm_api.h" #include "btcore/include/bdaddr.h" #include "device/include/controller.h" #include "bta_api.h" #include "bta_pan_api.h" #include "btif_sock_thread.h" #include "btif_sock_util.h" #include "btif_pan_internal.h" #include "gki.h" #include "osi/include/osi.h" #include "osi/include/log.h" #define FORWARD_IGNORE 1 #define FORWARD_SUCCESS 0 #define FORWARD_FAILURE (-1) #define FORWARD_CONGEST (-2) //#define PANU_DISABLED TRUE #if (PAN_NAP_DISABLED == TRUE) && (PANU_DISABLED == TRUE) #define BTPAN_LOCAL_ROLE BTPAN_ROLE_NONE #elif PAN_NAP_DISABLED == TRUE #define BTPAN_LOCAL_ROLE BTPAN_ROLE_PANU #elif PANU_DISABLED == TRUE #define BTPAN_LOCAL_ROLE BTPAN_ROLE_PANNAP #else #define BTPAN_LOCAL_ROLE (BTPAN_ROLE_PANU | BTPAN_ROLE_PANNAP) #endif #define asrt(s) if (!(s)) BTIF_TRACE_ERROR("btif_pan: ## %s assert %s failed at line:%d ##",__FUNCTION__, #s, __LINE__) #define MIN(x, y) (((x) < (y)) ? (x) : (y)) btpan_cb_t btpan_cb; static bool jni_initialized; static bool stack_initialized; static bt_status_t btpan_jni_init(const btpan_callbacks_t* callbacks); static void btpan_jni_cleanup(); static bt_status_t btpan_connect(const bt_bdaddr_t *bd_addr, int local_role, int remote_role); static bt_status_t btpan_disconnect(const bt_bdaddr_t *bd_addr); static bt_status_t btpan_enable(int local_role); static int btpan_get_local_role(void); static void btpan_tap_fd_signaled(int fd, int type, int flags, uint32_t user_id); static void btpan_cleanup_conn(btpan_conn_t* conn); static void bta_pan_callback(tBTA_PAN_EVT event, tBTA_PAN *p_data); static void btu_exec_tap_fd_read(void *p_param); static btpan_interface_t pan_if = { sizeof(pan_if), btpan_jni_init, btpan_enable, btpan_get_local_role, btpan_connect, btpan_disconnect, btpan_jni_cleanup }; btpan_interface_t *btif_pan_get_interface() { return &pan_if; } /******************************************************************************* ** ** Function btif_pan_init ** ** Description initializes the pan interface ** ** Returns bt_status_t ** *******************************************************************************/ void btif_pan_init() { BTIF_TRACE_DEBUG("jni_initialized = %d, btpan_cb.enabled:%d", jni_initialized, btpan_cb.enabled); stack_initialized = true; if (jni_initialized && !btpan_cb.enabled) { BTIF_TRACE_DEBUG("Enabling PAN...."); memset(&btpan_cb, 0, sizeof(btpan_cb)); btpan_cb.tap_fd = INVALID_FD; btpan_cb.flow = 1; for (int i = 0; i < MAX_PAN_CONNS; i++) btpan_cleanup_conn(&btpan_cb.conns[i]); BTA_PanEnable(bta_pan_callback); btpan_cb.enabled = 1; btpan_enable(BTPAN_LOCAL_ROLE); } } static void pan_disable() { if (btpan_cb.enabled) { btpan_cb.enabled = 0; BTA_PanDisable(); if (btpan_cb.tap_fd != INVALID_FD) { btpan_tap_close(btpan_cb.tap_fd); btpan_cb.tap_fd = INVALID_FD; } } } void btif_pan_cleanup() { if (!stack_initialized) return; // Bluetooth is shuting down, invalidate all BTA PAN handles for (int i = 0; i < MAX_PAN_CONNS; i++) btpan_cleanup_conn(&btpan_cb.conns[i]); pan_disable(); stack_initialized = false; } static btpan_callbacks_t callback; static bt_status_t btpan_jni_init(const btpan_callbacks_t* callbacks) { BTIF_TRACE_DEBUG("stack_initialized = %d, btpan_cb.enabled:%d", stack_initialized, btpan_cb.enabled); callback = *callbacks; jni_initialized = TRUE; if (stack_initialized && !btpan_cb.enabled) btif_pan_init(); return BT_STATUS_SUCCESS; } static void btpan_jni_cleanup() { pan_disable(); jni_initialized = false; } static inline int bta_role_to_btpan(int bta_pan_role) { int btpan_role = 0; BTIF_TRACE_DEBUG("bta_pan_role:0x%x", bta_pan_role); if (bta_pan_role & PAN_ROLE_NAP_SERVER) btpan_role |= BTPAN_ROLE_PANNAP; if (bta_pan_role & PAN_ROLE_CLIENT) btpan_role |= BTPAN_ROLE_PANU; return btpan_role; } static inline int btpan_role_to_bta(int btpan_role) { int bta_pan_role = PAN_ROLE_INACTIVE; BTIF_TRACE_DEBUG("btpan_role:0x%x", btpan_role); if (btpan_role & BTPAN_ROLE_PANNAP) bta_pan_role |= PAN_ROLE_NAP_SERVER; if (btpan_role & BTPAN_ROLE_PANU) bta_pan_role |= PAN_ROLE_CLIENT; return bta_pan_role; } static volatile int btpan_dev_local_role; static tBTA_PAN_ROLE_INFO bta_panu_info = {PANU_SERVICE_NAME, 0, PAN_SECURITY}; static tBTA_PAN_ROLE_INFO bta_pan_nap_info = {PAN_NAP_SERVICE_NAME, 1, PAN_SECURITY}; static bt_status_t btpan_enable(int local_role) { #if BTA_PAN_INCLUDED == TRUE BTIF_TRACE_DEBUG("%s - local_role: %d", __func__, local_role); int bta_pan_role = btpan_role_to_bta(local_role); BTA_PanSetRole(bta_pan_role, &bta_panu_info, NULL, &bta_pan_nap_info); btpan_dev_local_role = local_role; return BT_STATUS_SUCCESS; #else return BT_STATUS_FAIL; #endif } static int btpan_get_local_role() { BTIF_TRACE_DEBUG("btpan_dev_local_role:%d", btpan_dev_local_role); return btpan_dev_local_role; } static bt_status_t btpan_connect(const bt_bdaddr_t *bd_addr, int local_role, int remote_role) { BTIF_TRACE_DEBUG("local_role:%d, remote_role:%d", local_role, remote_role); int bta_local_role = btpan_role_to_bta(local_role); int bta_remote_role = btpan_role_to_bta(remote_role); btpan_new_conn(-1, bd_addr->address, bta_local_role, bta_remote_role); BTA_PanOpen((UINT8*)bd_addr->address, bta_local_role, bta_remote_role); return BT_STATUS_SUCCESS; } static void btif_in_pan_generic_evt(UINT16 event, char *p_param) { BTIF_TRACE_EVENT("%s: event=%d", __FUNCTION__, event); switch (event) { case BTIF_PAN_CB_DISCONNECTING: { bt_bdaddr_t *bd_addr = (bt_bdaddr_t*)p_param; btpan_conn_t* conn = btpan_find_conn_addr(bd_addr->address); int btpan_conn_local_role; int btpan_remote_role; asrt(conn != NULL); if (conn) { btpan_conn_local_role = bta_role_to_btpan(conn->local_role); btpan_remote_role = bta_role_to_btpan(conn->remote_role); callback.connection_state_cb(BTPAN_STATE_DISCONNECTING, BT_STATUS_SUCCESS, (const bt_bdaddr_t*)conn->peer, btpan_conn_local_role, btpan_remote_role); } } break; default: { BTIF_TRACE_WARNING("%s : Unknown event 0x%x", __FUNCTION__, event); } break; } } static bt_status_t btpan_disconnect(const bt_bdaddr_t *bd_addr) { btpan_conn_t* conn = btpan_find_conn_addr(bd_addr->address); if (conn && conn->handle >= 0) { /* Inform the application that the disconnect has been initiated successfully */ btif_transfer_context(btif_in_pan_generic_evt, BTIF_PAN_CB_DISCONNECTING, (char *)bd_addr, sizeof(bt_bdaddr_t), NULL); BTA_PanClose(conn->handle); return BT_STATUS_SUCCESS; } return BT_STATUS_FAIL; } static int pan_pth = -1; void create_tap_read_thread(int tap_fd) { if (pan_pth < 0) pan_pth = btsock_thread_create(btpan_tap_fd_signaled, NULL); if (pan_pth >= 0) btsock_thread_add_fd(pan_pth, tap_fd, 0, SOCK_THREAD_FD_RD, 0); } void destroy_tap_read_thread(void) { if (pan_pth >= 0) { btsock_thread_exit(pan_pth); pan_pth = -1; } } static int tap_if_up(const char *devname, const bt_bdaddr_t *addr) { struct ifreq ifr; int sk, err; sk = socket(AF_INET, SOCK_DGRAM, 0); if (sk < 0) return -1; //set mac addr memset(&ifr, 0, sizeof(ifr)); strncpy(ifr.ifr_name, devname, IFNAMSIZ - 1); err = TEMP_FAILURE_RETRY(ioctl(sk, SIOCGIFHWADDR, &ifr)); if (err < 0) { BTIF_TRACE_ERROR("Could not get network hardware for interface:%s, errno:%s", devname, strerror(errno)); close(sk); return -1; } strncpy(ifr.ifr_name, devname, IFNAMSIZ - 1); memcpy(ifr.ifr_hwaddr.sa_data, addr->address, 6); /* The IEEE has specified that the most significant bit of the most significant byte is used to * determine a multicast address. If its a 1, that means multicast, 0 means unicast. * Kernel returns an error if we try to set a multicast address for the tun-tap ethernet interface. * Mask this bit to avoid any issue with auto generated address. */ if (ifr.ifr_hwaddr.sa_data[0] & 0x01) { BTIF_TRACE_WARNING("Not a unicast MAC address, force multicast bit flipping"); ifr.ifr_hwaddr.sa_data[0] &= ~0x01; } err = TEMP_FAILURE_RETRY(ioctl(sk, SIOCSIFHWADDR, (caddr_t)&ifr)); if (err < 0) { BTIF_TRACE_ERROR("Could not set bt address for interface:%s, errno:%s", devname, strerror(errno)); close(sk); return -1; } //bring it up memset(&ifr, 0, sizeof(ifr)); strncpy(ifr.ifr_name, devname, IF_NAMESIZE - 1); ifr.ifr_flags |= IFF_UP; ifr.ifr_flags |= IFF_MULTICAST; err = TEMP_FAILURE_RETRY(ioctl(sk, SIOCSIFFLAGS, (caddr_t) &ifr)); if (err < 0) { BTIF_TRACE_ERROR("Could not bring up network interface:%s, errno:%d", devname, errno); close(sk); return -1; } close(sk); BTIF_TRACE_DEBUG("network interface: %s is up", devname); return 0; } static int tap_if_down(const char *devname) { struct ifreq ifr; int sk; sk = socket(AF_INET, SOCK_DGRAM, 0); if (sk < 0) return -1; memset(&ifr, 0, sizeof(ifr)); strncpy(ifr.ifr_name, devname, IF_NAMESIZE - 1); ifr.ifr_flags &= ~IFF_UP; TEMP_FAILURE_RETRY(ioctl(sk, SIOCSIFFLAGS, (caddr_t) &ifr)); close(sk); return 0; } void btpan_set_flow_control(BOOLEAN enable) { if (btpan_cb.tap_fd == -1) return; btpan_cb.flow = enable; if (enable) { btsock_thread_add_fd(pan_pth, btpan_cb.tap_fd, 0, SOCK_THREAD_FD_RD, 0); bta_dmexecutecallback(btu_exec_tap_fd_read, (void *)btpan_cb.tap_fd); } } int btpan_tap_open() { struct ifreq ifr; int fd, err; const char *clonedev = "/dev/tun"; /* open the clone device */ if ((fd = TEMP_FAILURE_RETRY(open(clonedev, O_RDWR))) < 0) { BTIF_TRACE_DEBUG("could not open %s, err:%d", clonedev, errno); return fd; } memset(&ifr, 0, sizeof(ifr)); ifr.ifr_flags = IFF_TAP | IFF_NO_PI; strncpy(ifr.ifr_name, TAP_IF_NAME, IFNAMSIZ); /* try to create the device */ if ((err = TEMP_FAILURE_RETRY(ioctl(fd, TUNSETIFF, (void *) &ifr))) < 0) { BTIF_TRACE_DEBUG("ioctl error:%d, errno:%s", err, strerror(errno)); close(fd); return err; } if (tap_if_up(TAP_IF_NAME, controller_get_interface()->get_address()) == 0) { int flags = TEMP_FAILURE_RETRY(fcntl(fd, F_GETFL, 0)); TEMP_FAILURE_RETRY(fcntl(fd, F_SETFL, flags | O_NONBLOCK)); return fd; } BTIF_TRACE_ERROR("can not bring up tap interface:%s", TAP_IF_NAME); close(fd); return INVALID_FD; } int btpan_tap_send(int tap_fd, const BD_ADDR src, const BD_ADDR dst, UINT16 proto, const char* buf, UINT16 len, BOOLEAN ext, BOOLEAN forward) { UNUSED(ext); UNUSED(forward); if (tap_fd != INVALID_FD) { tETH_HDR eth_hdr; memcpy(ð_hdr.h_dest, dst, ETH_ADDR_LEN); memcpy(ð_hdr.h_src, src, ETH_ADDR_LEN); eth_hdr.h_proto = htons(proto); char packet[TAP_MAX_PKT_WRITE_LEN + sizeof(tETH_HDR)]; memcpy(packet, ð_hdr, sizeof(tETH_HDR)); if (len > TAP_MAX_PKT_WRITE_LEN) { LOG_ERROR("btpan_tap_send eth packet size:%d is exceeded limit!", len); return -1; } memcpy(packet + sizeof(tETH_HDR), buf, len); /* Send data to network interface */ int ret = TEMP_FAILURE_RETRY(write(tap_fd, packet, len + sizeof(tETH_HDR))); BTIF_TRACE_DEBUG("ret:%d", ret); return ret; } return -1; } int btpan_tap_close(int fd) { if (tap_if_down(TAP_IF_NAME) == 0) close(fd); if (pan_pth >= 0) btsock_thread_wakeup(pan_pth); return 0; } btpan_conn_t * btpan_find_conn_handle(UINT16 handle) { for (int i = 0; i < MAX_PAN_CONNS; i++) { if (btpan_cb.conns[i].handle == handle) return &btpan_cb.conns[i]; } return NULL; } btpan_conn_t* btpan_find_conn_addr(const BD_ADDR addr) { for (int i = 0; i < MAX_PAN_CONNS; i++) { if (memcmp(btpan_cb.conns[i].peer, addr, sizeof(BD_ADDR)) == 0) return &btpan_cb.conns[i]; } return NULL; } static void btpan_open_conn(btpan_conn_t* conn, tBTA_PAN *p_data) { BTIF_TRACE_API("btpan_open_conn: local_role:%d, peer_role: %d, handle:%d, conn: %p", p_data->open.local_role, p_data->open.peer_role, p_data->open.handle, conn); if (conn == NULL) conn = btpan_new_conn(p_data->open.handle, p_data->open.bd_addr, p_data->open.local_role, p_data->open.peer_role); if (conn) { BTIF_TRACE_DEBUG("btpan_open_conn:tap_fd:%d, open_count:%d, " "conn->handle:%d should = handle:%d, local_role:%d, remote_role:%d", btpan_cb.tap_fd, btpan_cb.open_count, conn->handle, p_data->open.handle, conn->local_role, conn->remote_role); btpan_cb.open_count++; conn->handle = p_data->open.handle; if (btpan_cb.tap_fd < 0) { btpan_cb.tap_fd = btpan_tap_open(); if(btpan_cb.tap_fd >= 0) create_tap_read_thread(btpan_cb.tap_fd); } if (btpan_cb.tap_fd >= 0) { btpan_cb.flow = 1; conn->state = PAN_STATE_OPEN; } } } static void btpan_close_conn(btpan_conn_t* conn) { BTIF_TRACE_API("btpan_close_conn: %p",conn); if (conn && conn->state == PAN_STATE_OPEN) { BTIF_TRACE_DEBUG("btpan_close_conn: PAN_STATE_OPEN"); conn->state = PAN_STATE_CLOSE; btpan_cb.open_count--; if (btpan_cb.open_count == 0) { destroy_tap_read_thread(); if (btpan_cb.tap_fd != INVALID_FD) { btpan_tap_close(btpan_cb.tap_fd); btpan_cb.tap_fd = INVALID_FD; } } } } static void btpan_cleanup_conn(btpan_conn_t* conn) { if (conn) { conn->handle = -1; conn->state = -1; memset(&conn->peer, 0, sizeof(conn->peer)); memset(&conn->eth_addr, 0, sizeof(conn->eth_addr)); conn->local_role = conn->remote_role = 0; } } btpan_conn_t* btpan_new_conn(int handle, const BD_ADDR addr, int local_role, int remote_role) { for (int i = 0; i < MAX_PAN_CONNS; i++) { BTIF_TRACE_DEBUG("conns[%d]:%d", i, btpan_cb.conns[i].handle); if (btpan_cb.conns[i].handle == -1) { BTIF_TRACE_DEBUG("handle:%d, local_role:%d, remote_role:%d", handle, local_role, remote_role); btpan_cb.conns[i].handle = handle; bdcpy(btpan_cb.conns[i].peer, addr); btpan_cb.conns[i].local_role = local_role; btpan_cb.conns[i].remote_role = remote_role; return &btpan_cb.conns[i]; } } BTIF_TRACE_DEBUG("MAX_PAN_CONNS:%d exceeded, return NULL as failed", MAX_PAN_CONNS); return NULL; } void btpan_close_handle(btpan_conn_t *p) { BTIF_TRACE_DEBUG("btpan_close_handle : close handle %d", p->handle); p->handle = -1; p->local_role = -1; p->remote_role = -1; memset(&p->peer, 0, 6); } static inline bool should_forward(tETH_HDR* hdr) { uint16_t proto = ntohs(hdr->h_proto); if (proto == ETH_P_IP || proto == ETH_P_ARP || proto == ETH_P_IPV6) return true; BTIF_TRACE_DEBUG("unknown proto:%x", proto); return false; } static int forward_bnep(tETH_HDR* eth_hdr, BT_HDR *hdr) { int broadcast = eth_hdr->h_dest[0] & 1; // Find the right connection to send this frame over. for (int i = 0; i < MAX_PAN_CONNS; i++) { UINT16 handle = btpan_cb.conns[i].handle; if (handle != (UINT16)-1 && (broadcast || memcmp(btpan_cb.conns[i].eth_addr, eth_hdr->h_dest, sizeof(BD_ADDR)) == 0 || memcmp(btpan_cb.conns[i].peer, eth_hdr->h_dest, sizeof(BD_ADDR)) == 0)) { BTA_PanSetPmState(handle, BTA_PAN_PM_CONN_BUSY); int result = PAN_WriteBuf(handle, eth_hdr->h_dest, eth_hdr->h_src, ntohs(eth_hdr->h_proto), hdr, 0); BTA_PanSetPmState(handle, BTA_PAN_PM_CONN_IDLE); switch (result) { case PAN_Q_SIZE_EXCEEDED: return FORWARD_CONGEST; case PAN_SUCCESS: return FORWARD_SUCCESS; default: return FORWARD_FAILURE; } } } GKI_freebuf(hdr); return FORWARD_IGNORE; } static void bta_pan_callback_transfer(UINT16 event, char *p_param) { tBTA_PAN *p_data = (tBTA_PAN *)p_param; switch(event) { case BTA_PAN_ENABLE_EVT: BTIF_TRACE_DEBUG("BTA_PAN_ENABLE_EVT"); break; case BTA_PAN_SET_ROLE_EVT: { int btpan_role = bta_role_to_btpan(p_data->set_role.role); bt_status_t status = p_data->set_role.status == BTA_PAN_SUCCESS ? BT_STATUS_SUCCESS : BT_STATUS_FAIL; btpan_control_state_t state = btpan_role == 0 ? BTPAN_STATE_DISABLED : BTPAN_STATE_ENABLED; callback.control_state_cb(state, btpan_role, status, TAP_IF_NAME); break; } case BTA_PAN_OPENING_EVT: { btpan_conn_t* conn; bdstr_t bds; bdaddr_to_string((bt_bdaddr_t *)p_data->opening.bd_addr, bds, sizeof(bds)); BTIF_TRACE_DEBUG("BTA_PAN_OPENING_EVT handle %d, addr: %s", p_data->opening.handle, bds); conn = btpan_find_conn_addr(p_data->opening.bd_addr); asrt(conn != NULL); if (conn) { conn->handle = p_data->opening.handle; int btpan_conn_local_role = bta_role_to_btpan(conn->local_role); int btpan_remote_role = bta_role_to_btpan(conn->remote_role); callback.connection_state_cb(BTPAN_STATE_CONNECTING, BT_STATUS_SUCCESS, (const bt_bdaddr_t*)p_data->opening.bd_addr, btpan_conn_local_role, btpan_remote_role); } else BTIF_TRACE_ERROR("connection not found"); break; } case BTA_PAN_OPEN_EVT: { btpan_connection_state_t state; bt_status_t status; btpan_conn_t *conn = btpan_find_conn_handle(p_data->open.handle); LOG_VERBOSE("%s pan connection open status: %d", __func__, p_data->open.status); if (p_data->open.status == BTA_PAN_SUCCESS) { state = BTPAN_STATE_CONNECTED; status = BT_STATUS_SUCCESS; btpan_open_conn(conn, p_data); } else { state = BTPAN_STATE_DISCONNECTED; status = BT_STATUS_FAIL; btpan_cleanup_conn(conn); } /* debug("BTA_PAN_OPEN_EVT handle:%d, conn:%p", p_data->open.handle, conn); */ /* debug("conn bta local_role:%d, bta remote role:%d", conn->local_role, conn->remote_role); */ int btpan_conn_local_role = bta_role_to_btpan(p_data->open.local_role); int btpan_remote_role = bta_role_to_btpan(p_data->open.peer_role); callback.connection_state_cb(state, status, (const bt_bdaddr_t*)p_data->open.bd_addr, btpan_conn_local_role, btpan_remote_role); break; } case BTA_PAN_CLOSE_EVT: { btpan_conn_t* conn = btpan_find_conn_handle(p_data->close.handle); LOG_INFO("%s: event = BTA_PAN_CLOSE_EVT handle %d", __FUNCTION__, p_data->close.handle); btpan_close_conn(conn); if (conn && conn->handle >= 0) { int btpan_conn_local_role = bta_role_to_btpan(conn->local_role); int btpan_remote_role = bta_role_to_btpan(conn->remote_role); callback.connection_state_cb(BTPAN_STATE_DISCONNECTED, 0, (const bt_bdaddr_t*)conn->peer, btpan_conn_local_role, btpan_remote_role); btpan_cleanup_conn(conn); } else BTIF_TRACE_ERROR("pan handle not found (%d)", p_data->close.handle); break; } default: BTIF_TRACE_WARNING("Unknown pan event %d", event); break; } } static void bta_pan_callback(tBTA_PAN_EVT event, tBTA_PAN *p_data) { btif_transfer_context(bta_pan_callback_transfer, event, (char*)p_data, sizeof(tBTA_PAN), NULL); } #define IS_EXCEPTION(e) ((e) & (POLLHUP | POLLRDHUP | POLLERR | POLLNVAL)) static void btu_exec_tap_fd_read(void *p_param) { struct pollfd ufd; int fd = (int)p_param; if (fd == INVALID_FD || fd != btpan_cb.tap_fd) return; // Don't occupy BTU context too long, avoid GKI buffer overruns and // give other profiles a chance to run by limiting the amount of memory // PAN can use from the shared pool buffer. for (int i = 0; i < PAN_POOL_MAX && btif_is_enabled() && btpan_cb.flow; i++) { BT_HDR *buffer = (BT_HDR *)GKI_getpoolbuf(PAN_POOL_ID); if (!buffer) { BTIF_TRACE_WARNING("%s unable to allocate buffer for packet.", __func__); break; } buffer->offset = PAN_MINIMUM_OFFSET; buffer->len = GKI_get_buf_size(buffer) - sizeof(BT_HDR) - buffer->offset; UINT8 *packet = (UINT8 *)buffer + sizeof(BT_HDR) + buffer->offset; // If we don't have an undelivered packet left over, pull one from the TAP driver. // We save it in the congest_packet right away in case we can't deliver it in this // attempt. if (!btpan_cb.congest_packet_size) { ssize_t ret = TEMP_FAILURE_RETRY(read(fd, btpan_cb.congest_packet, sizeof(btpan_cb.congest_packet))); switch (ret) { case -1: BTIF_TRACE_ERROR("%s unable to read from driver: %s", __func__, strerror(errno)); GKI_freebuf(buffer); //add fd back to monitor thread to try it again later btsock_thread_add_fd(pan_pth, fd, 0, SOCK_THREAD_FD_RD, 0); return; case 0: BTIF_TRACE_WARNING("%s end of file reached.", __func__); GKI_freebuf(buffer); //add fd back to monitor thread to process the exception btsock_thread_add_fd(pan_pth, fd, 0, SOCK_THREAD_FD_RD, 0); return; default: btpan_cb.congest_packet_size = ret; break; } } memcpy(packet, btpan_cb.congest_packet, MIN(btpan_cb.congest_packet_size, buffer->len)); buffer->len = MIN(btpan_cb.congest_packet_size, buffer->len); if (buffer->len > sizeof(tETH_HDR) && should_forward((tETH_HDR *)packet)) { // Extract the ethernet header from the buffer since the PAN_WriteBuf inside // forward_bnep can't handle two pointers that point inside the same GKI buffer. tETH_HDR hdr; memcpy(&hdr, packet, sizeof(tETH_HDR)); // Skip the ethernet header. buffer->len -= sizeof(tETH_HDR); buffer->offset += sizeof(tETH_HDR); if (forward_bnep(&hdr, buffer) != FORWARD_CONGEST) btpan_cb.congest_packet_size = 0; } else { BTIF_TRACE_WARNING("%s dropping packet of length %d", __func__, buffer->len); btpan_cb.congest_packet_size = 0; GKI_freebuf(buffer); } // Bail out of the loop if reading from the TAP fd would block. ufd.fd = fd; ufd.events = POLLIN; ufd.revents = 0; if (TEMP_FAILURE_RETRY(poll(&ufd, 1, 0)) <= 0 || IS_EXCEPTION(ufd.revents)) break; } if (btpan_cb.flow) { //add fd back to monitor thread when the flow is on btsock_thread_add_fd(pan_pth, fd, 0, SOCK_THREAD_FD_RD, 0); } } static void btif_pan_close_all_conns() { if (!stack_initialized) return; for (int i = 0; i < MAX_PAN_CONNS; ++i) { if (btpan_cb.conns[i].handle != -1) BTA_PanClose(btpan_cb.conns[i].handle); } } static void btpan_tap_fd_signaled(int fd, int type, int flags, uint32_t user_id) { assert(btpan_cb.tap_fd == INVALID_FD || btpan_cb.tap_fd == fd); if (btpan_cb.tap_fd != fd) { BTIF_TRACE_WARNING("%s Signaled on mismatched fds exp:%d act:%d\n", __func__, btpan_cb.tap_fd, fd); return; } if (flags & SOCK_THREAD_FD_EXCEPTION) { btpan_cb.tap_fd = INVALID_FD; btpan_tap_close(fd); btif_pan_close_all_conns(); } else if (flags & SOCK_THREAD_FD_RD) bta_dmexecutecallback(btu_exec_tap_fd_read, (void *)fd); }