/* * * BlueZ - Bluetooth protocol stack for Linux * * Copyright (C) 2014 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 "lib/bluetooth.h" #include "lib/rfcomm.h" #include "lib/mgmt.h" #include "monitor/bt.h" #include "emulator/bthost.h" #include "emulator/hciemu.h" #include "src/shared/tester.h" #include "src/shared/mgmt.h" struct test_data { struct mgmt *mgmt; uint16_t mgmt_index; struct hciemu *hciemu; enum hciemu_type hciemu_type; const void *test_data; unsigned int io_id; uint16_t conn_handle; }; struct rfcomm_client_data { uint8_t server_channel; uint8_t client_channel; int expected_connect_err; const uint8_t *send_data; const uint8_t *read_data; uint16_t data_len; }; struct rfcomm_server_data { uint8_t server_channel; uint8_t client_channel; bool expected_status; const uint8_t *send_data; const uint8_t *read_data; uint16_t data_len; }; static void mgmt_debug(const char *str, void *user_data) { const char *prefix = user_data; tester_print("%s%s", prefix, str); } static void read_info_callback(uint8_t status, uint16_t length, const void *param, void *user_data) { struct test_data *data = tester_get_data(); const struct mgmt_rp_read_info *rp = param; char addr[18]; uint16_t manufacturer; uint32_t supported_settings, current_settings; tester_print("Read Info callback"); tester_print(" Status: 0x%02x", status); if (status || !param) { tester_pre_setup_failed(); return; } ba2str(&rp->bdaddr, addr); manufacturer = btohs(rp->manufacturer); supported_settings = btohl(rp->supported_settings); current_settings = btohl(rp->current_settings); tester_print(" Address: %s", addr); tester_print(" Version: 0x%02x", rp->version); tester_print(" Manufacturer: 0x%04x", manufacturer); tester_print(" Supported settings: 0x%08x", supported_settings); tester_print(" Current settings: 0x%08x", current_settings); tester_print(" Class: 0x%02x%02x%02x", rp->dev_class[2], rp->dev_class[1], rp->dev_class[0]); tester_print(" Name: %s", rp->name); tester_print(" Short name: %s", rp->short_name); if (strcmp(hciemu_get_address(data->hciemu), addr)) { tester_pre_setup_failed(); return; } tester_pre_setup_complete(); } static void index_added_callback(uint16_t index, uint16_t length, const void *param, void *user_data) { struct test_data *data = tester_get_data(); tester_print("Index Added callback"); tester_print(" Index: 0x%04x", index); data->mgmt_index = index; mgmt_send(data->mgmt, MGMT_OP_READ_INFO, data->mgmt_index, 0, NULL, read_info_callback, NULL, NULL); } static void index_removed_callback(uint16_t index, uint16_t length, const void *param, void *user_data) { struct test_data *data = tester_get_data(); tester_print("Index Removed callback"); tester_print(" Index: 0x%04x", index); if (index != data->mgmt_index) return; mgmt_unregister_index(data->mgmt, data->mgmt_index); mgmt_unref(data->mgmt); data->mgmt = NULL; tester_post_teardown_complete(); } static void read_index_list_callback(uint8_t status, uint16_t length, const void *param, void *user_data) { struct test_data *data = tester_get_data(); tester_print("Read Index List callback"); tester_print(" Status: 0x%02x", status); if (status || !param) { tester_pre_setup_failed(); return; } mgmt_register(data->mgmt, MGMT_EV_INDEX_ADDED, MGMT_INDEX_NONE, index_added_callback, NULL, NULL); mgmt_register(data->mgmt, MGMT_EV_INDEX_REMOVED, MGMT_INDEX_NONE, index_removed_callback, NULL, NULL); data->hciemu = hciemu_new(data->hciemu_type); if (!data->hciemu) { tester_warn("Failed to setup HCI emulation"); tester_pre_setup_failed(); } tester_print("New hciemu instance created"); } static void test_pre_setup(const void *test_data) { struct test_data *data = tester_get_data(); data->mgmt = mgmt_new_default(); if (!data->mgmt) { tester_warn("Failed to setup management interface"); tester_pre_setup_failed(); return; } if (tester_use_debug()) mgmt_set_debug(data->mgmt, mgmt_debug, "mgmt: ", NULL); mgmt_send(data->mgmt, MGMT_OP_READ_INDEX_LIST, MGMT_INDEX_NONE, 0, NULL, read_index_list_callback, NULL, NULL); } static void test_post_teardown(const void *test_data) { struct test_data *data = tester_get_data(); if (data->io_id > 0) { g_source_remove(data->io_id); data->io_id = 0; } hciemu_unref(data->hciemu); data->hciemu = NULL; } static void test_data_free(void *test_data) { struct test_data *data = test_data; free(data); } static void client_connectable_complete(uint16_t opcode, uint8_t status, const void *param, uint8_t len, void *user_data) { switch (opcode) { case BT_HCI_CMD_WRITE_SCAN_ENABLE: break; default: return; } tester_print("Client set connectable status 0x%02x", status); if (status) tester_setup_failed(); else tester_setup_complete(); } static void setup_powered_client_callback(uint8_t status, uint16_t length, const void *param, void *user_data) { struct test_data *data = tester_get_data(); struct bthost *bthost; if (status != MGMT_STATUS_SUCCESS) { tester_setup_failed(); return; } tester_print("Controller powered on"); bthost = hciemu_client_get_host(data->hciemu); bthost_set_cmd_complete_cb(bthost, client_connectable_complete, data); bthost_write_scan_enable(bthost, 0x03); } static void setup_powered_client(const void *test_data) { struct test_data *data = tester_get_data(); unsigned char param[] = { 0x01 }; tester_print("Powering on controller"); mgmt_send(data->mgmt, MGMT_OP_SET_POWERED, data->mgmt_index, sizeof(param), param, setup_powered_client_callback, NULL, NULL); } static void setup_powered_server_callback(uint8_t status, uint16_t length, const void *param, void *user_data) { if (status != MGMT_STATUS_SUCCESS) { tester_setup_failed(); return; } tester_print("Controller powered on"); tester_setup_complete(); } static void setup_powered_server(const void *test_data) { struct test_data *data = tester_get_data(); unsigned char param[] = { 0x01 }; tester_print("Powering on controller"); mgmt_send(data->mgmt, MGMT_OP_SET_CONNECTABLE, data->mgmt_index, sizeof(param), param, NULL, NULL, NULL); mgmt_send(data->mgmt, MGMT_OP_SET_POWERED, data->mgmt_index, sizeof(param), param, setup_powered_server_callback, NULL, NULL); } const struct rfcomm_client_data connect_success = { .server_channel = 0x0c, .client_channel = 0x0c }; const uint8_t data[] = {0, 1, 2, 3, 4, 5, 6, 7, 8}; const struct rfcomm_client_data connect_send_success = { .server_channel = 0x0c, .client_channel = 0x0c, .data_len = sizeof(data), .send_data = data }; const struct rfcomm_client_data connect_read_success = { .server_channel = 0x0c, .client_channel = 0x0c, .data_len = sizeof(data), .read_data = data }; const struct rfcomm_client_data connect_nval = { .server_channel = 0x0c, .client_channel = 0x0e, .expected_connect_err = -ECONNREFUSED }; const struct rfcomm_server_data listen_success = { .server_channel = 0x0c, .client_channel = 0x0c, .expected_status = true }; const struct rfcomm_server_data listen_send_success = { .server_channel = 0x0c, .client_channel = 0x0c, .expected_status = true, .data_len = sizeof(data), .send_data = data }; const struct rfcomm_server_data listen_read_success = { .server_channel = 0x0c, .client_channel = 0x0c, .expected_status = true, .data_len = sizeof(data), .read_data = data }; const struct rfcomm_server_data listen_nval = { .server_channel = 0x0c, .client_channel = 0x0e, .expected_status = false }; static void test_basic(const void *test_data) { int sk; sk = socket(PF_BLUETOOTH, SOCK_STREAM, BTPROTO_RFCOMM); if (sk < 0) { tester_warn("Can't create socket: %s (%d)", strerror(errno), errno); tester_test_failed(); return; } close(sk); tester_test_passed(); } static int create_rfcomm_sock(bdaddr_t *address, uint8_t channel) { int sk; struct sockaddr_rc addr; sk = socket(PF_BLUETOOTH, SOCK_STREAM | SOCK_NONBLOCK, BTPROTO_RFCOMM); memset(&addr, 0, sizeof(addr)); addr.rc_family = AF_BLUETOOTH; addr.rc_channel = channel; bacpy(&addr.rc_bdaddr, address); if (bind(sk, (struct sockaddr *) &addr, sizeof(addr)) < 0) { close(sk); return -1; } return sk; } static int connect_rfcomm_sock(int sk, const bdaddr_t *bdaddr, uint8_t channel) { struct sockaddr_rc addr; int err; memset(&addr, 0, sizeof(addr)); addr.rc_family = AF_BLUETOOTH; bacpy(&addr.rc_bdaddr, bdaddr); addr.rc_channel = htobs(channel); err = connect(sk, (struct sockaddr *) &addr, sizeof(addr)); if (err < 0 && !(errno == EAGAIN || errno == EINPROGRESS)) return err; return 0; } static gboolean client_received_data(GIOChannel *io, GIOCondition cond, gpointer user_data) { struct test_data *data = tester_get_data(); const struct rfcomm_client_data *cli = data->test_data; int sk; ssize_t ret; char buf[248]; sk = g_io_channel_unix_get_fd(io); ret = read(sk, buf, cli->data_len); if (cli->data_len != ret) { tester_test_failed(); return false; } if (memcmp(cli->read_data, buf, cli->data_len)) tester_test_failed(); else tester_test_passed(); return false; } static gboolean rc_connect_cb(GIOChannel *io, GIOCondition cond, gpointer user_data) { struct test_data *data = tester_get_data(); const struct rfcomm_client_data *cli = data->test_data; socklen_t len = sizeof(int); int sk, err, sk_err; tester_print("Connected"); data->io_id = 0; sk = g_io_channel_unix_get_fd(io); if (getsockopt(sk, SOL_SOCKET, SO_ERROR, &sk_err, &len) < 0) err = -errno; else err = -sk_err; if (cli->expected_connect_err && err == cli->expected_connect_err) { tester_test_passed(); return false; } if (cli->send_data) { ssize_t ret; tester_print("Writing %u bytes of data", cli->data_len); ret = write(sk, cli->send_data, cli->data_len); if (cli->data_len != ret) { tester_warn("Failed to write %u bytes: %s (%d)", cli->data_len, strerror(errno), errno); tester_test_failed(); } return false; } else if (cli->read_data) { g_io_add_watch(io, G_IO_IN, client_received_data, NULL); bthost_send_rfcomm_data(hciemu_client_get_host(data->hciemu), data->conn_handle, cli->client_channel, cli->read_data, cli->data_len); return false; } if (err < 0) tester_test_failed(); else tester_test_passed(); return false; } static void client_hook_func(const void *data, uint16_t len, void *user_data) { struct test_data *test_data = tester_get_data(); const struct rfcomm_client_data *cli = test_data->test_data; ssize_t ret; tester_print("bthost received %u bytes of data", len); if (cli->data_len != len) { tester_test_failed(); return; } ret = memcmp(cli->send_data, data, len); if (ret) tester_test_failed(); else tester_test_passed(); } static void server_hook_func(const void *data, uint16_t len, void *user_data) { struct test_data *test_data = tester_get_data(); const struct rfcomm_server_data *srv = test_data->test_data; ssize_t ret; if (srv->data_len != len) { tester_test_failed(); return; } ret = memcmp(srv->send_data, data, len); if (ret) tester_test_failed(); else tester_test_passed(); } static void rfcomm_connect_cb(uint16_t handle, uint16_t cid, void *user_data, bool status) { struct test_data *data = tester_get_data(); const struct rfcomm_client_data *cli = data->test_data; struct bthost *bthost = hciemu_client_get_host(data->hciemu); if (cli->send_data) bthost_add_rfcomm_chan_hook(bthost, handle, cli->client_channel, client_hook_func, NULL); else if (cli->read_data) data->conn_handle = handle; } static void test_connect(const void *test_data) { struct test_data *data = tester_get_data(); struct bthost *bthost = hciemu_client_get_host(data->hciemu); const struct rfcomm_client_data *cli = data->test_data; const uint8_t *client_addr, *master_addr; GIOChannel *io; int sk; bthost_add_l2cap_server(bthost, 0x0003, NULL, NULL, NULL); bthost_add_rfcomm_server(bthost, cli->server_channel, rfcomm_connect_cb, NULL); master_addr = hciemu_get_master_bdaddr(data->hciemu); client_addr = hciemu_get_client_bdaddr(data->hciemu); sk = create_rfcomm_sock((bdaddr_t *) master_addr, 0); if (connect_rfcomm_sock(sk, (const bdaddr_t *) client_addr, cli->client_channel) < 0) { close(sk); tester_test_failed(); return; } io = g_io_channel_unix_new(sk); g_io_channel_set_close_on_unref(io, TRUE); data->io_id = g_io_add_watch(io, G_IO_OUT, rc_connect_cb, NULL); g_io_channel_unref(io); tester_print("Connect in progress %d", sk); } static gboolean server_received_data(GIOChannel *io, GIOCondition cond, gpointer user_data) { struct test_data *data = tester_get_data(); const struct rfcomm_server_data *srv = data->test_data; char buf[1024]; ssize_t ret; int sk; sk = g_io_channel_unix_get_fd(io); ret = read(sk, buf, srv->data_len); if (ret != srv->data_len) { tester_test_failed(); return false; } if (memcmp(buf, srv->read_data, srv->data_len)) tester_test_failed(); else tester_test_passed(); return false; } static gboolean rfcomm_listen_cb(GIOChannel *io, GIOCondition cond, gpointer user_data) { struct test_data *data = tester_get_data(); const struct rfcomm_server_data *srv = data->test_data; int sk, new_sk; data->io_id = 0; sk = g_io_channel_unix_get_fd(io); new_sk = accept(sk, NULL, NULL); if (new_sk < 0) { tester_test_failed(); return false; } if (srv->send_data) { ssize_t ret; ret = write(new_sk, srv->send_data, srv->data_len); if (ret != srv->data_len) tester_test_failed(); close(new_sk); return false; } else if (srv->read_data) { GIOChannel *new_io; new_io = g_io_channel_unix_new(new_sk); g_io_channel_set_close_on_unref(new_io, TRUE); data->io_id = g_io_add_watch(new_io, G_IO_IN, server_received_data, NULL); g_io_channel_unref(new_io); return false; } close(new_sk); tester_test_passed(); return false; } static void connection_cb(uint16_t handle, uint16_t cid, void *user_data, bool status) { struct test_data *data = tester_get_data(); const struct rfcomm_server_data *srv = data->test_data; struct bthost *bthost = hciemu_client_get_host(data->hciemu); if (srv->read_data) { data->conn_handle = handle; bthost_send_rfcomm_data(bthost, data->conn_handle, srv->client_channel, srv->read_data, srv->data_len); return; } else if (srv->data_len) { return; } if (srv->expected_status == status) tester_test_passed(); else tester_test_failed(); } static void client_new_conn(uint16_t handle, void *user_data) { struct test_data *data = tester_get_data(); const struct rfcomm_server_data *srv = data->test_data; struct bthost *bthost; bthost = hciemu_client_get_host(data->hciemu); bthost_add_rfcomm_chan_hook(bthost, handle, srv->client_channel, server_hook_func, NULL); bthost_connect_rfcomm(bthost, handle, srv->client_channel, connection_cb, NULL); } static void test_server(const void *test_data) { struct test_data *data = tester_get_data(); const struct rfcomm_server_data *srv = data->test_data; const uint8_t *master_addr; struct bthost *bthost; GIOChannel *io; int sk; master_addr = hciemu_get_master_bdaddr(data->hciemu); sk = create_rfcomm_sock((bdaddr_t *) master_addr, srv->server_channel); if (sk < 0) { tester_test_failed(); return; } if (listen(sk, 5) < 0) { tester_warn("listening on socket failed: %s (%u)", strerror(errno), errno); tester_test_failed(); close(sk); return; } io = g_io_channel_unix_new(sk); g_io_channel_set_close_on_unref(io, TRUE); data->io_id = g_io_add_watch(io, G_IO_IN, rfcomm_listen_cb, NULL); g_io_channel_unref(io); tester_print("Listening for connections"); bthost = hciemu_client_get_host(data->hciemu); bthost_set_connect_cb(bthost, client_new_conn, data); bthost_hci_connect(bthost, master_addr, BDADDR_BREDR); } #define test_rfcomm(name, data, setup, func) \ do { \ struct test_data *user; \ user = malloc(sizeof(struct test_data)); \ if (!user) \ break; \ user->hciemu_type = HCIEMU_TYPE_BREDR; \ user->test_data = data; \ user->io_id = 0; \ tester_add_full(name, data, \ test_pre_setup, setup, func, NULL, \ test_post_teardown, 2, user, test_data_free); \ } while (0) int main(int argc, char *argv[]) { tester_init(&argc, &argv); test_rfcomm("Basic RFCOMM Socket - Success", NULL, setup_powered_client, test_basic); test_rfcomm("Basic RFCOMM Socket Client - Success", &connect_success, setup_powered_client, test_connect); test_rfcomm("Basic RFCOMM Socket Client - Write Success", &connect_send_success, setup_powered_client, test_connect); test_rfcomm("Basic RFCOMM Socket Client - Read Success", &connect_read_success, setup_powered_client, test_connect); test_rfcomm("Basic RFCOMM Socket Client - Conn Refused", &connect_nval, setup_powered_client, test_connect); test_rfcomm("Basic RFCOMM Socket Server - Success", &listen_success, setup_powered_server, test_server); test_rfcomm("Basic RFCOMM Socket Server - Write Success", &listen_send_success, setup_powered_server, test_server); test_rfcomm("Basic RFCOMM Socket Server - Read Success", &listen_read_success, setup_powered_server, test_server); test_rfcomm("Basic RFCOMM Socket Server - Conn Refused", &listen_nval, setup_powered_server, test_server); return tester_run(); }