/*
* Copyright (c) 2019-2023 Beijing Hanwei Innovation Technology Ltd. Co. and
* its subsidiaries and affiliates (collectly called MKSEMI).
*
* All rights reserved.
*
* 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, except as embedded into an MKSEMI
* integrated circuit in a product or a software update for such product,
* 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 MKSEMI nor the names of its contributors may be used
* to endorse or promote products derived from this software without
* specific prior written permission.
*
* 4. This software, with or without modification, must only be used with a
* MKSEMI integrated circuit.
*
* 5. Any software provided in binary form under this license must not be
* reverse engineered, decompiled, modified and/or disassembled.
*
* THIS SOFTWARE IS PROVIDED BY MKSEMI "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, NONINFRINGEMENT, AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL MKSEMI 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.
*/
#include "mk_trace.h"
#include "mk_wdt.h"
#include "mk_reset.h"
#include "mk_gpio.h"
#include "mk_misc.h"
#include "mk_sleep_timer.h"
#include "mk_power.h"
#include "mk_uwb.h"
#include "mk_calib.h"
#include "mk_flash.h"
#include "board.h"
#include "pal_sys.h"
#include "wsf_os.h"
#include "wsf_timer.h"
#include "wsf_buf.h"
#include "wsf_nvm.h"
#include "app.h"
#include "uwb_data_transfer.h"
#include "uwb_api.h"
#include "lib_ranging.h"
#include "uwb_data.h"
#include "libc_rom.h"
#define INITIATOR_ADDR (0xAAA1)
#define RESPONDER0_ADDR (0xAAA2)
#define RESPONDER1_ADDR (0xAAA3)
#define RESPONDER2_ADDR (0xAAA4)
#define RESPONDER_NUM (1)
static uint32_t session_id = 0x0001;
static uint8_t transfer_on_flag = 0;
//*****************************************************************************
//
// WSF buffer pools.
//
//*****************************************************************************
#if UWB_SERIAL_DATA_TRANSFER_EN == 0
#define WSF_BUF_POOLS 5
// Default pool descriptor.
static wsfBufPoolDesc_t poolDescriptors[WSF_BUF_POOLS] = {
{32, 26}, {64, 24}, {128, 4}, {256 + 32, 4}, {1024 + 32, 2},
};
#else
#define WSF_BUF_POOLS 4
// Default pool descriptor.
static wsfBufPoolDesc_t poolDescriptors[WSF_BUF_POOLS] = {
{32, 29},
{64, 32},
{272, 4},
{1040, 2},
};
#endif
static void sleep_timer_callback(void *dev, uint32_t time)
{
// LOG_INFO(TRACE_MODULE_APP, "Wake up by sleep timer %d\r\n", time);
}
//
// Button Handlers
//
static void GPIO_UserHandler(enum IO_PIN_T pin)
{
// LOG_INFO(TRACE_MODULE_APP, "GPIO Interrupt happen\r\n");
if (pin == BOARD_SW_1)
{
app_button_event_set(APP_BUTTON1_EVT);
}
}
void app_process_handle(uint8_t msg_id, const void *param)
{
switch (msg_id)
{
case APP_TEST_TIMER1_MSG:
{
}
break;
case APP_DEBOUNCE_TIMER1_MSG:
{
if (gpio_pin_get_val(BOARD_SW_1))
{
return;
}
LOG_INFO(TRACE_MODULE_APP, "DEBOUNCE TIMER1\r\n");
if (transfer_on_flag)
{
uwbapi_session_stop(session_id);
transfer_on_flag = 0;
}
else
{
// Start transfering
uwbapi_session_start(session_id, NULL);
transfer_on_flag = 1;
}
}
break;
default:
break;
}
}
static void board_init(void)
{
// Clock configuration
board_clock_run();
// Pin configuration
board_pins_config();
// Trace configuration
board_debug_console_open(TRACE_PORT_UART0);
// Reset reason
reset_cause_get();
reset_cause_clear();
// Load calibration parameters from NVM
uint32_t internal_flash = (REG_READ(0x40000018) >> 17) & 0x1;
uint32_t external_flash = (REG_READ(0x40010030) >> 28) & 0x3;
if (internal_flash || external_flash == 1)
{
WsfNvmInit();
board_calibration_params_load();
flash_close(FLASH_ID0);
}
else
{
board_calibration_params_default();
}
// Chip calibration
calib_chip();
// Configure IO_02 for role selection
gpio_open();
gpio_pin_set_dir(IO_PIN_2, GPIO_DIR_IN, 0);
io_pull_set(IO_PIN_2, IO_PULL_UP, IO_PULL_UP_LEVEL1);
board_led_init();
board_led_on(BOARD_LED_1);
board_button_init(GPIO_UserHandler);
board_configure();
}
/*
Serial Port Data Format: Data Length (2B) | Data
08 00 11 22 33 44 55 66 77 88
*/
int main(void)
{
// Initialize MCU system
board_init();
// Disable watchdog timer
wdt_close(WDT_ID0);
LOG_INFO(TRACE_MODULE_APP, "FiRa data transfer example\r\n");
// Platform init for WSF
PalSysInit();
// Initialize os
//
// Set up timers for the WSF scheduler.
//
WsfOsInit();
WsfTimerInit();
sys_tick_callback_set(WsfTimerUpdateTicks);
//
// Initialize a buffer pool for WSF dynamic memory needs.
//
uint32_t wsfBufMemLen = WsfBufInit(WSF_BUF_POOLS, poolDescriptors);
if (wsfBufMemLen > FREE_MEM_SIZE)
{
LOG_INFO(TRACE_MODULE_APP, "Memory pool is not enough %d\r\n", wsfBufMemLen - FREE_MEM_SIZE);
}
//
// Create app task
//
wsfHandlerId_t handlerId = WsfOsSetNextHandler(app_handler);
app_init(handlerId);
//
// Create ranging task
//
handlerId = WsfOsSetNextHandler(ranging_handler);
data_transfer_init(handlerId);
uwb_open();
uwbs_init();
uwb_app_config.ranging_flow_mode = (uint8_t)(RANGING_FLOW_DATA_TRANSFER);
uwb_app_config.session_param.tx_power_level = board_param.tx_power_fcc[CALIB_CH(uwb_app_config.ppdu_params.ch_num)];
uwb_app_config.ppdu_params.rx_ant_id = (uint8_t)(RX_MAIN_ANT_PORT);
// Initialize ranging session
uwbapi_session_init(session_id, SESSION_TYPE_DATA_TRANSFER);
// Initialize ranging parameters
struct APP_CFG_PARAM_T param = {0};
param.ch_num = UWB_CH_NUM;
param.prf_mode = UWB_MEAN_PRF;
param.preamble_code_index = UWB_PREAMBLE_CODE_IDX;
param.preamble_duration = UWB_PREAMBLE_DURATION;
param.sfd_id = UWB_SFD_ID;
param.psdu_data_rate = UWB_PSDU_DATA_RATE;
param.sts_segment_num = UWB_STS_SEGMENT_NUM;
param.sts_segment_len = UWB_STS_SEGMENT_LEN;
param.rframe_config = UWB_RFRAME_TYPE;
param.sts_config = STS_STATIC;
memcpy(param.session_key, (uint8_t *)SESSION_KEY_DYNAMIC_STS_TEST, 16);
param.key_rotation = 0;
param.key_rotation_rate = 8;
param.ranging_round_usage = DATA_TRANSFER_PHASE;
param.mac_address_mode = ARRD_SHORT_USE_SHORT;
param.controlees_num = RESPONDER_NUM;
param.multi_node_mode = param.controlees_num > 1 ? ONE_TO_MANY : UNICAST;
param.result_report_config = 0x0F;
param.ranging_round_control = 0x3;
param.hopping_mode = 0x00;
param.stride_length = 0x00;
// Load local & peer short address
uint16_t local_addr = 0;
uint16_t peer_addr = 0;
if (gpio_pin_get_val(IO_PIN_2) == 0)
{
param.device_role = DEV_ROLE_INITIATOR;
local_addr = INITIATOR_ADDR;
if (board_param.flag & (1 << BOARD_LOCAL_SHORT_ADDR))
{
local_addr = board_param.local_short_addr;
}
param.src_dev_mac_addr[0] = local_addr & 0xff;
param.src_dev_mac_addr[1] = (local_addr >> 8) & 0xff;
peer_addr = RESPONDER0_ADDR;
param.dst_dev_mac_addr[0] = peer_addr & 0xff;
param.dst_dev_mac_addr[1] = (peer_addr >> 8) & 0xff;
peer_addr = RESPONDER1_ADDR;
param.dst_dev_mac_addr[2] = peer_addr & 0xff;
param.dst_dev_mac_addr[3] = (peer_addr >> 8) & 0xff;
peer_addr = RESPONDER2_ADDR;
param.dst_dev_mac_addr[4] = peer_addr & 0xff;
param.dst_dev_mac_addr[5] = (peer_addr >> 8) & 0xff;
}
else
{
param.device_role = DEV_ROLE_RESPONDER;
local_addr = RESPONDER0_ADDR;
if (board_param.flag & (1 << BOARD_LOCAL_SHORT_ADDR))
{
local_addr = board_param.local_short_addr;
}
param.src_dev_mac_addr[0] = local_addr & 0xff;
param.src_dev_mac_addr[1] = (local_addr >> 8) & 0xff;
peer_addr = INITIATOR_ADDR;
if (board_param.flag & (1 << BOARD_PEER_SHORT_ADDR))
{
peer_addr = board_param.peer_short_addr;
}
param.dst_dev_mac_addr[0] = peer_addr & 0xff;
param.dst_dev_mac_addr[1] = (peer_addr >> 8) & 0xff;
}
param.device_type = param.device_role == DEV_ROLE_INITIATOR ? DEV_TYPE_CONTROLLER : DEV_TYPE_CONTROLEE;
param.slot_duration = UWB_RANGING_SLOT_DURATION;
param.ranging_interval = UWB_RANGING_INTERVAL;
param.slots_per_round = UWB_RANGING_INTERVAL / RSTU_TO_MS(UWB_RANGING_SLOT_DURATION);
// Configure session parameters
uwbapi_session_set_app_config(session_id, ¶m);
// Disable encryption
uwbs_security_enable_set(0);
// Start transfering
uwbapi_session_start(session_id, NULL);
transfer_on_flag = 1;
// TX data periodically
#if UWB_SERIAL_DATA_TRANSFER_EN
uwb_serial_data_transfer_init();
#else
uwb_slot_bitmap_size_set(8);
uwb_data_transfer_init_test();
#endif
// Initialize low power mode
power_init();
#if LOW_POWER_EN
power_mode_request(POWER_UNIT_USER, POWER_MODE_POWER_DOWN);
#else
power_mode_request(POWER_UNIT_USER, POWER_MODE_SLEEP);
#endif
// Enable sleep timer
sleep_timer_open(true, SLEEP_TIMER_MODE_ONESHOT, sleep_timer_callback);
while (1)
{
wsfOsDispatcher();
power_manage();
}
}
void app_restore_from_power_down(void)
{
}