/* * Copyright (C) 2014 BlueKitchen GmbH * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. Neither the name of the copyright holders nor the names of * contributors may be used to endorse or promote products derived * from this software without specific prior written permission. * 4. Any redistribution, use, or modification is done solely for * personal benefit and not for any commercial purpose or for * monetary gain. * * THIS SOFTWARE IS PROVIDED BY BLUEKITCHEN GMBH AND CONTRIBUTORS * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL MATTHIAS * RINGWALD OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS * OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF * THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * Please inquire about commercial licensing options at * contact@bluekitchen-gmbh.com * */ #define __BTSTACK_FILE__ "spp_streamer_client.c" /* * spp_streamer_client.c */ // ***************************************************************************** /* EXAMPLE_START(spp_streamer_client): Client for SPP Streamer * * @text Note: The SPP Streamer Client scans for and connects to SPP Streamer, * and measures the throughput. */ // ***************************************************************************** #include #include #include #include #include #include "btstack.h" #define RFCOMM_SERVER_CHANNEL 1 #define TEST_COD 0x1234 typedef enum { // SPP W4_PEER_COD, W4_SCAN_COMPLETE, W4_SDP_RESULT, W4_SDP_COMPLETE, W4_RFCOMM_CHANNEL, SENDING, DONE } state_t; static btstack_packet_callback_registration_t hci_event_callback_registration; static bd_addr_t peer_addr; static state_t state; // SPP static uint16_t rfcomm_mtu; static uint16_t rfcomm_cid = 0; // static uint32_t data_to_send = DATA_VOLUME; /** * Find remote peer by COD */ #define INQUIRY_INTERVAL 5 static void start_scan(void){ printf("Starting inquiry scan..\n"); state = W4_PEER_COD; gap_inquiry_start(INQUIRY_INTERVAL); } static void stop_scan(void){ printf("Stopping inquiry scan..\n"); state = W4_SCAN_COMPLETE; gap_inquiry_stop(); } /* * @section Track throughput * @text We calculate the throughput by setting a start time and measuring the amount of * data sent. After a configurable REPORT_INTERVAL_MS, we print the throughput in kB/s * and reset the counter and start time. */ /* LISTING_START(tracking): Tracking throughput */ #define REPORT_INTERVAL_MS 3000 static uint32_t test_data_transferred; static uint32_t test_data_start; static void test_reset(void){ test_data_start = btstack_run_loop_get_time_ms(); test_data_transferred = 0; } static void test_track_transferred(int bytes_sent){ test_data_transferred += bytes_sent; // evaluate uint32_t now = btstack_run_loop_get_time_ms(); uint32_t time_passed = now - test_data_start; if (time_passed < REPORT_INTERVAL_MS) return; // print speed int bytes_per_second = test_data_transferred * 1000 / time_passed; printf("%u bytes -> %u.%03u kB/s\n", (int) test_data_transferred, (int) bytes_per_second / 1000, bytes_per_second % 1000); // restart test_data_start = now; test_data_transferred = 0; } /* LISTING_END(tracking): Tracking throughput */ /* * @section Packet Handler * * @text The packet handler of the combined example is just the combination of the individual packet handlers. */ static void packet_handler (uint8_t packet_type, uint16_t channel, uint8_t *packet, uint16_t size){ UNUSED(channel); bd_addr_t event_addr; uint8_t rfcomm_channel_nr; uint32_t class_of_device; switch (packet_type) { case HCI_EVENT_PACKET: switch (hci_event_packet_get_type(packet)) { case HCI_EVENT_PIN_CODE_REQUEST: // inform about pin code request printf("Pin code request - using '0000'\n"); hci_event_pin_code_request_get_bd_addr(packet, event_addr); gap_pin_code_response(event_addr, "0000"); break; case HCI_EVENT_USER_CONFIRMATION_REQUEST: // inform about user confirmation request printf("SSP User Confirmation Request with numeric value '%06"PRIu32"'\n", little_endian_read_32(packet, 8)); printf("SSP User Confirmation Auto accept\n"); break; case RFCOMM_EVENT_INCOMING_CONNECTION: // data: event (8), len(8), address(48), channel (8), rfcomm_cid (16) rfcomm_event_incoming_connection_get_bd_addr(packet, event_addr); rfcomm_channel_nr = rfcomm_event_incoming_connection_get_server_channel(packet); rfcomm_cid = rfcomm_event_incoming_connection_get_rfcomm_cid(packet); printf("RFCOMM channel %u requested for %s\n", rfcomm_channel_nr, bd_addr_to_str(event_addr)); rfcomm_accept_connection(rfcomm_cid); break; case RFCOMM_EVENT_CHANNEL_OPENED: // data: event(8), len(8), status (8), address (48), server channel(8), rfcomm_cid(16), max frame size(16) if (rfcomm_event_channel_opened_get_status(packet)) { printf("RFCOMM channel open failed, status %u\n", rfcomm_event_channel_opened_get_status(packet)); } else { rfcomm_cid = rfcomm_event_channel_opened_get_rfcomm_cid(packet); rfcomm_mtu = rfcomm_event_channel_opened_get_max_frame_size(packet); printf("RFCOMM channel open succeeded. New RFCOMM Channel ID %u, max frame size %u\n", rfcomm_cid, rfcomm_mtu); test_reset(); // disable page/inquiry scan to get max performance gap_discoverable_control(0); gap_connectable_control(0); } break; case RFCOMM_EVENT_CHANNEL_CLOSED: printf("RFCOMM channel closed\n"); rfcomm_cid = 0; // re-enable page/inquiry scan again gap_discoverable_control(1); gap_connectable_control(1); break; case BTSTACK_EVENT_STATE: if (btstack_event_state_get_state(packet) != HCI_STATE_WORKING) return; start_scan(); break; case GAP_EVENT_INQUIRY_RESULT: if (state != W4_PEER_COD) break; class_of_device = gap_event_inquiry_result_get_class_of_device(packet); gap_event_inquiry_result_get_bd_addr(packet, event_addr); if (class_of_device == TEST_COD){ memcpy(peer_addr, event_addr, 6); printf("Peer found: %s\n", bd_addr_to_str(peer_addr)); stop_scan(); } else { printf("Device found: %s with COD: 0x%06x\n", bd_addr_to_str(event_addr), (int) class_of_device); } break; case GAP_EVENT_INQUIRY_COMPLETE: switch (state){ case W4_PEER_COD: printf("Inquiry complete\n"); printf("Peer not found, starting scan again\n"); start_scan(); break; case W4_SCAN_COMPLETE: printf("Start to connect\n"); state = W4_RFCOMM_CHANNEL; rfcomm_create_channel(packet_handler, peer_addr, RFCOMM_SERVER_CHANNEL, NULL); break; default: break; } if (state == W4_PEER_COD){ } break; default: break; } break; case RFCOMM_DATA_PACKET: test_track_transferred(size); #if 0 printf("RCV: '"); for (i=0;i