/* * * BlueZ - Bluetooth protocol stack for Linux * * Copyright (C) 2014 Google Inc. * * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * This library 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 * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA * */ #include #include #include #include #include #include "io.h" #include "queue.h" #include "util.h" #include "timeout.h" #include "uuid.h" #include "att.h" #include "crypto.h" #define ATT_MIN_PDU_LEN 1 /* At least 1 byte for the opcode. */ #define ATT_OP_CMD_MASK 0x40 #define ATT_OP_SIGNED_MASK 0x80 #define ATT_TIMEOUT_INTERVAL 30000 /* 30000 ms */ /* * Common Profile and Service Error Code descriptions (see Supplement to the * Bluetooth Core Specification, sections 1.2 and 2). The error codes within * 0xE0-0xFC are reserved for future use. The remaining 3 are defined as the * following: */ #define BT_ERROR_CCC_IMPROPERLY_CONFIGURED 0xfd #define BT_ERROR_ALREADY_IN_PROGRESS 0xfe #define BT_ERROR_OUT_OF_RANGE 0xff /* Length of signature in write signed packet */ #define BT_ATT_SIGNATURE_LEN 12 struct att_send_op; struct bt_att { int ref_count; int fd; struct io *io; bool io_on_l2cap; int io_sec_level; /* Only used for non-L2CAP */ struct queue *req_queue; /* Queued ATT protocol requests */ struct att_send_op *pending_req; struct queue *ind_queue; /* Queued ATT protocol indications */ struct att_send_op *pending_ind; struct queue *write_queue; /* Queue of PDUs ready to send */ bool writer_active; struct queue *notify_list; /* List of registered callbacks */ struct queue *disconn_list; /* List of disconnect handlers */ bool in_req; /* There's a pending incoming request */ uint8_t *buf; uint16_t mtu; unsigned int next_send_id; /* IDs for "send" ops */ unsigned int next_reg_id; /* IDs for registered callbacks */ bt_att_timeout_func_t timeout_callback; bt_att_destroy_func_t timeout_destroy; void *timeout_data; bt_att_debug_func_t debug_callback; bt_att_destroy_func_t debug_destroy; void *debug_data; struct bt_crypto *crypto; struct sign_info *local_sign; struct sign_info *remote_sign; }; struct sign_info { uint8_t key[16]; bt_att_counter_func_t counter; void *user_data; }; enum att_op_type { ATT_OP_TYPE_REQ, ATT_OP_TYPE_RSP, ATT_OP_TYPE_CMD, ATT_OP_TYPE_IND, ATT_OP_TYPE_NOT, ATT_OP_TYPE_CONF, ATT_OP_TYPE_UNKNOWN, }; static const struct { uint8_t opcode; enum att_op_type type; } att_opcode_type_table[] = { { BT_ATT_OP_ERROR_RSP, ATT_OP_TYPE_RSP }, { BT_ATT_OP_MTU_REQ, ATT_OP_TYPE_REQ }, { BT_ATT_OP_MTU_RSP, ATT_OP_TYPE_RSP }, { BT_ATT_OP_FIND_INFO_REQ, ATT_OP_TYPE_REQ }, { BT_ATT_OP_FIND_INFO_RSP, ATT_OP_TYPE_RSP }, { BT_ATT_OP_FIND_BY_TYPE_VAL_REQ, ATT_OP_TYPE_REQ }, { BT_ATT_OP_FIND_BY_TYPE_VAL_RSP, ATT_OP_TYPE_RSP }, { BT_ATT_OP_READ_BY_TYPE_REQ, ATT_OP_TYPE_REQ }, { BT_ATT_OP_READ_BY_TYPE_RSP, ATT_OP_TYPE_RSP }, { BT_ATT_OP_READ_REQ, ATT_OP_TYPE_REQ }, { BT_ATT_OP_READ_RSP, ATT_OP_TYPE_RSP }, { BT_ATT_OP_READ_BLOB_REQ, ATT_OP_TYPE_REQ }, { BT_ATT_OP_READ_BLOB_RSP, ATT_OP_TYPE_RSP }, { BT_ATT_OP_READ_MULT_REQ, ATT_OP_TYPE_REQ }, { BT_ATT_OP_READ_MULT_RSP, ATT_OP_TYPE_RSP }, { BT_ATT_OP_READ_BY_GRP_TYPE_REQ, ATT_OP_TYPE_REQ }, { BT_ATT_OP_READ_BY_GRP_TYPE_RSP, ATT_OP_TYPE_RSP }, { BT_ATT_OP_WRITE_REQ, ATT_OP_TYPE_REQ }, { BT_ATT_OP_WRITE_RSP, ATT_OP_TYPE_RSP }, { BT_ATT_OP_WRITE_CMD, ATT_OP_TYPE_CMD }, { BT_ATT_OP_SIGNED_WRITE_CMD, ATT_OP_TYPE_CMD }, { BT_ATT_OP_PREP_WRITE_REQ, ATT_OP_TYPE_REQ }, { BT_ATT_OP_PREP_WRITE_RSP, ATT_OP_TYPE_RSP }, { BT_ATT_OP_EXEC_WRITE_REQ, ATT_OP_TYPE_REQ }, { BT_ATT_OP_EXEC_WRITE_RSP, ATT_OP_TYPE_RSP }, { BT_ATT_OP_HANDLE_VAL_NOT, ATT_OP_TYPE_NOT }, { BT_ATT_OP_HANDLE_VAL_IND, ATT_OP_TYPE_IND }, { BT_ATT_OP_HANDLE_VAL_CONF, ATT_OP_TYPE_CONF }, { } }; static enum att_op_type get_op_type(uint8_t opcode) { int i; for (i = 0; att_opcode_type_table[i].opcode; i++) { if (att_opcode_type_table[i].opcode == opcode) return att_opcode_type_table[i].type; } return ATT_OP_TYPE_UNKNOWN; } static const struct { uint8_t req_opcode; uint8_t rsp_opcode; } att_req_rsp_mapping_table[] = { { BT_ATT_OP_MTU_REQ, BT_ATT_OP_MTU_RSP }, { BT_ATT_OP_FIND_INFO_REQ, BT_ATT_OP_FIND_INFO_RSP}, { BT_ATT_OP_FIND_BY_TYPE_VAL_REQ, BT_ATT_OP_FIND_BY_TYPE_VAL_RSP }, { BT_ATT_OP_READ_BY_TYPE_REQ, BT_ATT_OP_READ_BY_TYPE_RSP }, { BT_ATT_OP_READ_REQ, BT_ATT_OP_READ_RSP }, { BT_ATT_OP_READ_BLOB_REQ, BT_ATT_OP_READ_BLOB_RSP }, { BT_ATT_OP_READ_MULT_REQ, BT_ATT_OP_READ_MULT_RSP }, { BT_ATT_OP_READ_BY_GRP_TYPE_REQ, BT_ATT_OP_READ_BY_GRP_TYPE_RSP }, { BT_ATT_OP_WRITE_REQ, BT_ATT_OP_WRITE_RSP }, { BT_ATT_OP_PREP_WRITE_REQ, BT_ATT_OP_PREP_WRITE_RSP }, { BT_ATT_OP_EXEC_WRITE_REQ, BT_ATT_OP_EXEC_WRITE_RSP }, { } }; static uint8_t get_req_opcode(uint8_t rsp_opcode) { int i; for (i = 0; att_req_rsp_mapping_table[i].rsp_opcode; i++) { if (att_req_rsp_mapping_table[i].rsp_opcode == rsp_opcode) return att_req_rsp_mapping_table[i].req_opcode; } return 0; } struct att_send_op { unsigned int id; unsigned int timeout_id; enum att_op_type type; uint16_t opcode; void *pdu; uint16_t len; bt_att_response_func_t callback; bt_att_destroy_func_t destroy; void *user_data; }; static void destroy_att_send_op(void *data) { struct att_send_op *op = data; if (op->timeout_id) timeout_remove(op->timeout_id); if (op->destroy) op->destroy(op->user_data); free(op->pdu); free(op); } static void cancel_att_send_op(struct att_send_op *op) { if (op->destroy) op->destroy(op->user_data); op->user_data = NULL; op->callback = NULL; op->destroy = NULL; } struct att_notify { unsigned int id; uint16_t opcode; bt_att_notify_func_t callback; bt_att_destroy_func_t destroy; void *user_data; }; static void destroy_att_notify(void *data) { struct att_notify *notify = data; if (notify->destroy) notify->destroy(notify->user_data); free(notify); } static bool match_notify_id(const void *a, const void *b) { const struct att_notify *notify = a; unsigned int id = PTR_TO_UINT(b); return notify->id == id; } struct att_disconn { unsigned int id; bool removed; bt_att_disconnect_func_t callback; bt_att_destroy_func_t destroy; void *user_data; }; static void destroy_att_disconn(void *data) { struct att_disconn *disconn = data; if (disconn->destroy) disconn->destroy(disconn->user_data); free(disconn); } static bool match_disconn_id(const void *a, const void *b) { const struct att_disconn *disconn = a; unsigned int id = PTR_TO_UINT(b); return disconn->id == id; } static bool encode_pdu(struct bt_att *att, struct att_send_op *op, const void *pdu, uint16_t length) { uint16_t pdu_len = 1; struct sign_info *sign = att->local_sign; uint32_t sign_cnt; if (sign && (op->opcode & ATT_OP_SIGNED_MASK)) pdu_len += BT_ATT_SIGNATURE_LEN; if (length && pdu) pdu_len += length; if (pdu_len > att->mtu) return false; op->len = pdu_len; op->pdu = malloc(op->len); if (!op->pdu) return false; ((uint8_t *) op->pdu)[0] = op->opcode; if (pdu_len > 1) memcpy(op->pdu + 1, pdu, length); if (!sign || !(op->opcode & ATT_OP_SIGNED_MASK)) return true; if (!sign->counter(&sign_cnt, sign->user_data)) goto fail; if ((bt_crypto_sign_att(att->crypto, sign->key, op->pdu, 1 + length, sign_cnt, &((uint8_t *) op->pdu)[1 + length]))) return true; util_debug(att->debug_callback, att->debug_data, "ATT unable to generate signature"); fail: free(op->pdu); return false; } static struct att_send_op *create_att_send_op(struct bt_att *att, uint8_t opcode, const void *pdu, uint16_t length, bt_att_response_func_t callback, void *user_data, bt_att_destroy_func_t destroy) { struct att_send_op *op; enum att_op_type op_type; if (length && !pdu) return NULL; op_type = get_op_type(opcode); if (op_type == ATT_OP_TYPE_UNKNOWN) return NULL; /* If the opcode corresponds to an operation type that does not elicit a * response from the remote end, then no callback should have been * provided, since it will never be called. */ if (callback && op_type != ATT_OP_TYPE_REQ && op_type != ATT_OP_TYPE_IND) return NULL; /* Similarly, if the operation does elicit a response then a callback * must be provided. */ if (!callback && (op_type == ATT_OP_TYPE_REQ || op_type == ATT_OP_TYPE_IND)) return NULL; op = new0(struct att_send_op, 1); if (!op) return NULL; op->type = op_type; op->opcode = opcode; op->callback = callback; op->destroy = destroy; op->user_data = user_data; if (!encode_pdu(att, op, pdu, length)) { free(op); return NULL; } return op; } static struct att_send_op *pick_next_send_op(struct bt_att *att) { struct att_send_op *op; /* See if any operations are already in the write queue */ op = queue_pop_head(att->write_queue); if (op) return op; /* If there is no pending request, pick an operation from the * request queue. */ if (!att->pending_req) { op = queue_pop_head(att->req_queue); if (op) return op; } /* There is either a request pending or no requests queued. If there is * no pending indication, pick an operation from the indication queue. */ if (!att->pending_ind) { op = queue_pop_head(att->ind_queue); if (op) return op; } return NULL; } struct timeout_data { struct bt_att *att; unsigned int id; }; static bool timeout_cb(void *user_data) { struct timeout_data *timeout = user_data; struct bt_att *att = timeout->att; struct att_send_op *op = NULL; if (att->pending_req && att->pending_req->id == timeout->id) { op = att->pending_req; att->pending_req = NULL; } else if (att->pending_ind && att->pending_ind->id == timeout->id) { op = att->pending_ind; att->pending_ind = NULL; } if (!op) return false; util_debug(att->debug_callback, att->debug_data, "Operation timed out: 0x%02x", op->opcode); if (att->timeout_callback) att->timeout_callback(op->id, op->opcode, att->timeout_data); op->timeout_id = 0; destroy_att_send_op(op); /* * Directly terminate the connection as required by the ATT protocol. * This should trigger an io disconnect event which will clean up the * io and notify the upper layer. */ io_shutdown(att->io); return false; } static void write_watch_destroy(void *user_data) { struct bt_att *att = user_data; att->writer_active = false; } static bool can_write_data(struct io *io, void *user_data) { struct bt_att *att = user_data; struct att_send_op *op; struct timeout_data *timeout; ssize_t ret; struct iovec iov; op = pick_next_send_op(att); if (!op) return false; iov.iov_base = op->pdu; iov.iov_len = op->len; ret = io_send(io, &iov, 1); if (ret < 0) { util_debug(att->debug_callback, att->debug_data, "write failed: %s", strerror(-ret)); if (op->callback) op->callback(BT_ATT_OP_ERROR_RSP, NULL, 0, op->user_data); destroy_att_send_op(op); return true; } util_debug(att->debug_callback, att->debug_data, "ATT op 0x%02x", op->opcode); util_hexdump('<', op->pdu, ret, att->debug_callback, att->debug_data); /* Based on the operation type, set either the pending request or the * pending indication. If it came from the write queue, then there is * no need to keep it around. */ switch (op->type) { case ATT_OP_TYPE_REQ: att->pending_req = op; break; case ATT_OP_TYPE_IND: att->pending_ind = op; break; case ATT_OP_TYPE_RSP: /* Set in_req to false to indicate that no request is pending */ att->in_req = false; /* Fall through to the next case */ case ATT_OP_TYPE_CMD: case ATT_OP_TYPE_NOT: case ATT_OP_TYPE_CONF: case ATT_OP_TYPE_UNKNOWN: default: destroy_att_send_op(op); return true; } timeout = new0(struct timeout_data, 1); if (!timeout) return true; timeout->att = att; timeout->id = op->id; op->timeout_id = timeout_add(ATT_TIMEOUT_INTERVAL, timeout_cb, timeout, free); /* Return true as there may be more operations ready to write. */ return true; } static void wakeup_writer(struct bt_att *att) { if (att->writer_active) return; /* Set the write handler only if there is anything that can be sent * at all. */ if (queue_isempty(att->write_queue)) { if ((att->pending_req || queue_isempty(att->req_queue)) && (att->pending_ind || queue_isempty(att->ind_queue))) return; } if (!io_set_write_handler(att->io, can_write_data, att, write_watch_destroy)) return; att->writer_active = true; } static void disconn_handler(void *data, void *user_data) { struct att_disconn *disconn = data; int err = PTR_TO_INT(user_data); if (disconn->removed) return; if (disconn->callback) disconn->callback(err, disconn->user_data); } static bool disconnect_cb(struct io *io, void *user_data) { struct bt_att *att = user_data; int err; socklen_t len; len = sizeof(err); if (getsockopt(att->fd, SOL_SOCKET, SO_ERROR, &err, &len) < 0) { util_debug(att->debug_callback, att->debug_data, "Failed to obtain disconnect error: %s", strerror(errno)); err = 0; } util_debug(att->debug_callback, att->debug_data, "Physical link disconnected: %s", strerror(err)); io_destroy(att->io); att->io = NULL; bt_att_cancel_all(att); bt_att_ref(att); queue_foreach(att->disconn_list, disconn_handler, INT_TO_PTR(err)); bt_att_unregister_all(att); bt_att_unref(att); return false; } static void handle_rsp(struct bt_att *att, uint8_t opcode, uint8_t *pdu, ssize_t pdu_len) { struct att_send_op *op = att->pending_req; uint8_t req_opcode; uint8_t rsp_opcode; uint8_t *rsp_pdu = NULL; uint16_t rsp_pdu_len = 0; /* * If no request is pending, then the response is unexpected. Disconnect * the bearer. */ if (!op) { util_debug(att->debug_callback, att->debug_data, "Received unexpected ATT response"); io_shutdown(att->io); return; } /* * If the received response doesn't match the pending request, or if * the request is malformed, end the current request with failure. */ if (opcode == BT_ATT_OP_ERROR_RSP) { if (pdu_len != 4) goto fail; req_opcode = pdu[0]; } else if (!(req_opcode = get_req_opcode(opcode))) goto fail; if (req_opcode != op->opcode) goto fail; rsp_opcode = opcode; if (pdu_len > 0) { rsp_pdu = pdu; rsp_pdu_len = pdu_len; } goto done; fail: util_debug(att->debug_callback, att->debug_data, "Failed to handle response PDU; opcode: 0x%02x", opcode); rsp_opcode = BT_ATT_OP_ERROR_RSP; done: if (op->callback) op->callback(rsp_opcode, rsp_pdu, rsp_pdu_len, op->user_data); destroy_att_send_op(op); att->pending_req = NULL; wakeup_writer(att); } static void handle_conf(struct bt_att *att, uint8_t *pdu, ssize_t pdu_len) { struct att_send_op *op = att->pending_ind; /* * Disconnect the bearer if the confirmation is unexpected or the PDU is * invalid. */ if (!op || pdu_len) { util_debug(att->debug_callback, att->debug_data, "Received unexpected/invalid ATT confirmation"); io_shutdown(att->io); return; } if (op->callback) op->callback(BT_ATT_OP_HANDLE_VAL_CONF, NULL, 0, op->user_data); destroy_att_send_op(op); att->pending_ind = NULL; wakeup_writer(att); } struct notify_data { uint8_t opcode; uint8_t *pdu; ssize_t pdu_len; bool handler_found; }; static bool opcode_match(uint8_t opcode, uint8_t test_opcode) { enum att_op_type op_type = get_op_type(test_opcode); if (opcode == BT_ATT_ALL_REQUESTS && (op_type == ATT_OP_TYPE_REQ || op_type == ATT_OP_TYPE_CMD)) return true; return opcode == test_opcode; } static void respond_not_supported(struct bt_att *att, uint8_t opcode) { uint8_t pdu[4]; pdu[0] = opcode; pdu[1] = 0; pdu[2] = 0; pdu[3] = BT_ATT_ERROR_REQUEST_NOT_SUPPORTED; bt_att_send(att, BT_ATT_OP_ERROR_RSP, pdu, sizeof(pdu), NULL, NULL, NULL); } static bool handle_signed(struct bt_att *att, uint8_t opcode, uint8_t *pdu, ssize_t pdu_len) { uint8_t *signature; uint32_t sign_cnt; struct sign_info *sign; /* Check if there is enough data for a signature */ if (pdu_len < 2 + BT_ATT_SIGNATURE_LEN) goto fail; sign = att->remote_sign; if (!sign) goto fail; signature = pdu + (pdu_len - BT_ATT_SIGNATURE_LEN); sign_cnt = get_le32(signature); /* Validate counter */ if (!sign->counter(&sign_cnt, sign->user_data)) goto fail; /* Generate signature and verify it */ if (!bt_crypto_sign_att(att->crypto, sign->key, pdu, pdu_len - BT_ATT_SIGNATURE_LEN, sign_cnt, signature)) goto fail; return true; fail: util_debug(att->debug_callback, att->debug_data, "ATT failed to verify signature: 0x%02x", opcode); return false; } static void handle_notify(struct bt_att *att, uint8_t opcode, uint8_t *pdu, ssize_t pdu_len) { const struct queue_entry *entry; bool found; if (opcode & ATT_OP_SIGNED_MASK) { if (!handle_signed(att, opcode, pdu, pdu_len)) return; pdu_len -= BT_ATT_SIGNATURE_LEN; } bt_att_ref(att); found = false; entry = queue_get_entries(att->notify_list); while (entry) { struct att_notify *notify = entry->data; entry = entry->next; if (!opcode_match(notify->opcode, opcode)) continue; found = true; if (notify->callback) notify->callback(opcode, pdu, pdu_len, notify->user_data); /* callback could remove all entries from notify list */ if (queue_isempty(att->notify_list)) break; } /* * If this was a request and no handler was registered for it, respond * with "Not Supported" */ if (!found && get_op_type(opcode) == ATT_OP_TYPE_REQ) respond_not_supported(att, opcode); bt_att_unref(att); } static bool can_read_data(struct io *io, void *user_data) { struct bt_att *att = user_data; uint8_t opcode; uint8_t *pdu; ssize_t bytes_read; bytes_read = read(att->fd, att->buf, att->mtu); if (bytes_read < 0) return false; util_hexdump('>', att->buf, bytes_read, att->debug_callback, att->debug_data); if (bytes_read < ATT_MIN_PDU_LEN) return true; pdu = att->buf; opcode = pdu[0]; bt_att_ref(att); /* Act on the received PDU based on the opcode type */ switch (get_op_type(opcode)) { case ATT_OP_TYPE_RSP: util_debug(att->debug_callback, att->debug_data, "ATT response received: 0x%02x", opcode); handle_rsp(att, opcode, pdu + 1, bytes_read - 1); break; case ATT_OP_TYPE_CONF: util_debug(att->debug_callback, att->debug_data, "ATT confirmation received: 0x%02x", opcode); handle_conf(att, pdu + 1, bytes_read - 1); break; case ATT_OP_TYPE_REQ: /* * If a request is currently pending, then the sequential * protocol was violated. Disconnect the bearer, which will * promptly notify the upper layer via disconnect handlers. */ if (att->in_req) { util_debug(att->debug_callback, att->debug_data, "Received request while another is " "pending: 0x%02x", opcode); io_shutdown(att->io); bt_att_unref(att); return false; } att->in_req = true; /* Fall through to the next case */ case ATT_OP_TYPE_CMD: case ATT_OP_TYPE_NOT: case ATT_OP_TYPE_UNKNOWN: case ATT_OP_TYPE_IND: default: /* For all other opcodes notify the upper layer of the PDU and * let them act on it. */ util_debug(att->debug_callback, att->debug_data, "ATT PDU received: 0x%02x", opcode); handle_notify(att, opcode, pdu + 1, bytes_read - 1); break; } bt_att_unref(att); return true; } static bool is_io_l2cap_based(int fd) { int domain; int proto; int err; socklen_t len; domain = 0; len = sizeof(domain); err = getsockopt(fd, SOL_SOCKET, SO_DOMAIN, &domain, &len); if (err < 0) return false; if (domain != AF_BLUETOOTH) return false; proto = 0; len = sizeof(proto); err = getsockopt(fd, SOL_SOCKET, SO_PROTOCOL, &proto, &len); if (err < 0) return false; return proto == BTPROTO_L2CAP; } static void bt_att_free(struct bt_att *att) { if (att->pending_req) destroy_att_send_op(att->pending_req); if (att->pending_ind) destroy_att_send_op(att->pending_ind); io_destroy(att->io); bt_crypto_unref(att->crypto); queue_destroy(att->req_queue, NULL); queue_destroy(att->ind_queue, NULL); queue_destroy(att->write_queue, NULL); queue_destroy(att->notify_list, NULL); queue_destroy(att->disconn_list, NULL); if (att->timeout_destroy) att->timeout_destroy(att->timeout_data); if (att->debug_destroy) att->debug_destroy(att->debug_data); free(att->local_sign); free(att->remote_sign); free(att->buf); free(att); } struct bt_att *bt_att_new(int fd) { struct bt_att *att; if (fd < 0) return NULL; att = new0(struct bt_att, 1); if (!att) return NULL; att->fd = fd; att->mtu = BT_ATT_DEFAULT_LE_MTU; att->buf = malloc(att->mtu); if (!att->buf) goto fail; att->io = io_new(fd); if (!att->io) goto fail; /* crypto is optional, if not available leave it NULL */ att->crypto = bt_crypto_new(); att->req_queue = queue_new(); if (!att->req_queue) goto fail; att->ind_queue = queue_new(); if (!att->ind_queue) goto fail; att->write_queue = queue_new(); if (!att->write_queue) goto fail; att->notify_list = queue_new(); if (!att->notify_list) goto fail; att->disconn_list = queue_new(); if (!att->disconn_list) goto fail; if (!io_set_read_handler(att->io, can_read_data, att, NULL)) goto fail; if (!io_set_disconnect_handler(att->io, disconnect_cb, att, NULL)) goto fail; att->io_on_l2cap = is_io_l2cap_based(att->fd); if (!att->io_on_l2cap) att->io_sec_level = BT_SECURITY_LOW; return bt_att_ref(att); fail: bt_att_free(att); return NULL; } struct bt_att *bt_att_ref(struct bt_att *att) { if (!att) return NULL; __sync_fetch_and_add(&att->ref_count, 1); return att; } void bt_att_unref(struct bt_att *att) { if (!att) return; if (__sync_sub_and_fetch(&att->ref_count, 1)) return; bt_att_unregister_all(att); bt_att_cancel_all(att); bt_att_free(att); } bool bt_att_set_close_on_unref(struct bt_att *att, bool do_close) { if (!att || !att->io) return false; return io_set_close_on_destroy(att->io, do_close); } int bt_att_get_fd(struct bt_att *att) { if (!att) return -1; return att->fd; } bool bt_att_set_debug(struct bt_att *att, bt_att_debug_func_t callback, void *user_data, bt_att_destroy_func_t destroy) { if (!att) return false; if (att->debug_destroy) att->debug_destroy(att->debug_data); att->debug_callback = callback; att->debug_destroy = destroy; att->debug_data = user_data; return true; } uint16_t bt_att_get_mtu(struct bt_att *att) { if (!att) return 0; return att->mtu; } bool bt_att_set_mtu(struct bt_att *att, uint16_t mtu) { void *buf; if (!att) return false; if (mtu < BT_ATT_DEFAULT_LE_MTU) return false; buf = malloc(mtu); if (!buf) return false; free(att->buf); att->mtu = mtu; att->buf = buf; return true; } bool bt_att_set_timeout_cb(struct bt_att *att, bt_att_timeout_func_t callback, void *user_data, bt_att_destroy_func_t destroy) { if (!att) return false; if (att->timeout_destroy) att->timeout_destroy(att->timeout_data); att->timeout_callback = callback; att->timeout_destroy = destroy; att->timeout_data = user_data; return true; } unsigned int bt_att_register_disconnect(struct bt_att *att, bt_att_disconnect_func_t callback, void *user_data, bt_att_destroy_func_t destroy) { struct att_disconn *disconn; if (!att || !att->io) return 0; disconn = new0(struct att_disconn, 1); if (!disconn) return 0; disconn->callback = callback; disconn->destroy = destroy; disconn->user_data = user_data; if (att->next_reg_id < 1) att->next_reg_id = 1; disconn->id = att->next_reg_id++; if (!queue_push_tail(att->disconn_list, disconn)) { free(disconn); return 0; } return disconn->id; } bool bt_att_unregister_disconnect(struct bt_att *att, unsigned int id) { struct att_disconn *disconn; if (!att || !id) return false; disconn = queue_remove_if(att->disconn_list, match_disconn_id, UINT_TO_PTR(id)); if (!disconn) return false; destroy_att_disconn(disconn); return true; } unsigned int bt_att_send(struct bt_att *att, uint8_t opcode, const void *pdu, uint16_t length, bt_att_response_func_t callback, void *user_data, bt_att_destroy_func_t destroy) { struct att_send_op *op; bool result; if (!att || !att->io) return 0; op = create_att_send_op(att, opcode, pdu, length, callback, user_data, destroy); if (!op) return 0; if (att->next_send_id < 1) att->next_send_id = 1; op->id = att->next_send_id++; /* Add the op to the correct queue based on its type */ switch (op->type) { case ATT_OP_TYPE_REQ: result = queue_push_tail(att->req_queue, op); break; case ATT_OP_TYPE_IND: result = queue_push_tail(att->ind_queue, op); break; case ATT_OP_TYPE_CMD: case ATT_OP_TYPE_NOT: case ATT_OP_TYPE_UNKNOWN: case ATT_OP_TYPE_RSP: case ATT_OP_TYPE_CONF: default: result = queue_push_tail(att->write_queue, op); break; } if (!result) { free(op->pdu); free(op); return 0; } wakeup_writer(att); return op->id; } static bool match_op_id(const void *a, const void *b) { const struct att_send_op *op = a; unsigned int id = PTR_TO_UINT(b); return op->id == id; } bool bt_att_cancel(struct bt_att *att, unsigned int id) { struct att_send_op *op; if (!att || !id) return false; if (att->pending_req && att->pending_req->id == id) { /* Don't cancel the pending request; remove it's handlers */ cancel_att_send_op(att->pending_req); return true; } if (att->pending_ind && att->pending_ind->id == id) { /* Don't cancel the pending indication; remove it's handlers */ cancel_att_send_op(att->pending_ind); return true; } op = queue_remove_if(att->req_queue, match_op_id, UINT_TO_PTR(id)); if (op) goto done; op = queue_remove_if(att->ind_queue, match_op_id, UINT_TO_PTR(id)); if (op) goto done; op = queue_remove_if(att->write_queue, match_op_id, UINT_TO_PTR(id)); if (op) goto done; if (!op) return false; done: destroy_att_send_op(op); wakeup_writer(att); return true; } bool bt_att_cancel_all(struct bt_att *att) { if (!att) return false; queue_remove_all(att->req_queue, NULL, NULL, destroy_att_send_op); queue_remove_all(att->ind_queue, NULL, NULL, destroy_att_send_op); queue_remove_all(att->write_queue, NULL, NULL, destroy_att_send_op); if (att->pending_req) /* Don't cancel the pending request; remove it's handlers */ cancel_att_send_op(att->pending_req); if (att->pending_ind) /* Don't cancel the pending request; remove it's handlers */ cancel_att_send_op(att->pending_ind); return true; } static uint8_t att_ecode_from_error(int err) { /* * If the error fits in a single byte, treat it as an ATT protocol * error as is. Since "0" is not a valid ATT protocol error code, we map * that to UNLIKELY below. */ if (err > 0 && err < UINT8_MAX) return err; /* * Since we allow UNIX errnos, map them to appropriate ATT protocol * and "Common Profile and Service" error codes. */ switch (err) { case -ENOENT: return BT_ATT_ERROR_INVALID_HANDLE; case -ENOMEM: return BT_ATT_ERROR_INSUFFICIENT_RESOURCES; case -EALREADY: return BT_ERROR_ALREADY_IN_PROGRESS; case -EOVERFLOW: return BT_ERROR_OUT_OF_RANGE; } return BT_ATT_ERROR_UNLIKELY; } unsigned int bt_att_send_error_rsp(struct bt_att *att, uint8_t opcode, uint16_t handle, int error) { struct bt_att_pdu_error_rsp pdu; uint8_t ecode; if (!att || !opcode) return 0; ecode = att_ecode_from_error(error); memset(&pdu, 0, sizeof(pdu)); pdu.opcode = opcode; put_le16(handle, &pdu.handle); pdu.ecode = ecode; return bt_att_send(att, BT_ATT_OP_ERROR_RSP, &pdu, sizeof(pdu), NULL, NULL, NULL); } unsigned int bt_att_register(struct bt_att *att, uint8_t opcode, bt_att_notify_func_t callback, void *user_data, bt_att_destroy_func_t destroy) { struct att_notify *notify; if (!att || !callback || !att->io) return 0; notify = new0(struct att_notify, 1); if (!notify) return 0; notify->opcode = opcode; notify->callback = callback; notify->destroy = destroy; notify->user_data = user_data; if (att->next_reg_id < 1) att->next_reg_id = 1; notify->id = att->next_reg_id++; if (!queue_push_tail(att->notify_list, notify)) { free(notify); return 0; } return notify->id; } bool bt_att_unregister(struct bt_att *att, unsigned int id) { struct att_notify *notify; if (!att || !id) return false; notify = queue_remove_if(att->notify_list, match_notify_id, UINT_TO_PTR(id)); if (!notify) return false; destroy_att_notify(notify); return true; } bool bt_att_unregister_all(struct bt_att *att) { if (!att) return false; queue_remove_all(att->notify_list, NULL, NULL, destroy_att_notify); queue_remove_all(att->disconn_list, NULL, NULL, destroy_att_disconn); return true; } int bt_att_get_sec_level(struct bt_att *att) { struct bt_security sec; socklen_t len; if (!att) return -EINVAL; if (!att->io_on_l2cap) return att->io_sec_level; memset(&sec, 0, sizeof(sec)); len = sizeof(sec); if (getsockopt(att->fd, SOL_BLUETOOTH, BT_SECURITY, &sec, &len) < 0) return -EIO; return sec.level; } bool bt_att_set_sec_level(struct bt_att *att, int level) { struct bt_security sec; if (!att || level < BT_SECURITY_LOW || level > BT_SECURITY_HIGH) return false; if (!att->io_on_l2cap) { att->io_sec_level = level; return true; } memset(&sec, 0, sizeof(sec)); sec.level = level; if (setsockopt(att->fd, SOL_BLUETOOTH, BT_SECURITY, &sec, sizeof(sec)) < 0) return false; return true; } static bool sign_set_key(struct sign_info **sign, uint8_t key[16], bt_att_counter_func_t func, void *user_data) { if (!(*sign)) { *sign = new0(struct sign_info, 1); if (!(*sign)) return false; } (*sign)->counter = func; (*sign)->user_data = user_data; memcpy((*sign)->key, key, 16); return true; } bool bt_att_set_local_key(struct bt_att *att, uint8_t sign_key[16], bt_att_counter_func_t func, void *user_data) { if (!att) return false; return sign_set_key(&att->local_sign, sign_key, func, user_data); } bool bt_att_set_remote_key(struct bt_att *att, uint8_t sign_key[16], bt_att_counter_func_t func, void *user_data) { if (!att) return false; return sign_set_key(&att->remote_sign, sign_key, func, user_data); } bool bt_att_has_crypto(struct bt_att *att) { if (!att) return false; return att->crypto ? true : false; }