/* generated HAL source file - do not edit */ #include "hal_data.h" /* Nominal and Data bit timing configuration */ can_bit_timing_cfg_t g_canfd1_bit_timing_cfg = { /* Actual bitrate: 500000 Hz. Actual sample point: 75 %. */ .baud_rate_prescaler = 1, .time_segment_1 = 59, .time_segment_2 = 20, .synchronization_jump_width = 4 }; can_bit_timing_cfg_t g_canfd1_data_timing_cfg = { /* Actual bitrate: 2000000 Hz. Actual sample point: 75 %. */ .baud_rate_prescaler = 1, .time_segment_1 = 14, .time_segment_2 = 5, .synchronization_jump_width = 1 }; extern const canfd_afl_entry_t p_canfd1_afl[CANFD_CFG_AFL_CH1_RULE_NUM]; #ifndef CANFD_PRV_GLOBAL_CFG #define CANFD_PRV_GLOBAL_CFG canfd_global_cfg_t g_canfd_global_cfg = { .global_interrupts = CANFD_CFG_GLOBAL_ERR_SOURCES, .global_config = (CANFD_CFG_TX_PRIORITY | CANFD_CFG_DLC_CHECK | CANFD_CFD_CLOCK_SOURCE | CANFD_CFG_FD_OVERFLOW | (uint32_t) (CANFD_CFG_TIMER_PRESCALER << R_CANFD_CFDGCFG_ITRCP_Pos)), .rx_mb_config = (CANFD_CFG_RXMB_NUMBER | (CANFD_CFG_RXMB_SIZE << R_CANFD_CFDRMNB_RMPLS_Pos)), .global_err_ipl = CANFD_CFG_GLOBAL_ERR_IPL, .rx_fifo_ipl = CANFD_CFG_RX_FIFO_IPL, .rx_fifo_config = { ((CANFD_CFG_RXFIFO0_INT_THRESHOLD << R_CANFD_CFDRFCC_RFIGCV_Pos) | (CANFD_CFG_RXFIFO0_DEPTH << R_CANFD_CFDRFCC_RFDC_Pos) | (CANFD_CFG_RXFIFO0_PAYLOAD << R_CANFD_CFDRFCC_RFPLS_Pos) | (CANFD_CFG_RXFIFO0_INT_MODE) | (CANFD_CFG_RXFIFO0_ENABLE)), ((CANFD_CFG_RXFIFO1_INT_THRESHOLD << R_CANFD_CFDRFCC_RFIGCV_Pos) | (CANFD_CFG_RXFIFO1_DEPTH << R_CANFD_CFDRFCC_RFDC_Pos) | (CANFD_CFG_RXFIFO1_PAYLOAD << R_CANFD_CFDRFCC_RFPLS_Pos) | (CANFD_CFG_RXFIFO1_INT_MODE) | (CANFD_CFG_RXFIFO1_ENABLE)), ((CANFD_CFG_RXFIFO2_INT_THRESHOLD << R_CANFD_CFDRFCC_RFIGCV_Pos) | (CANFD_CFG_RXFIFO2_DEPTH << R_CANFD_CFDRFCC_RFDC_Pos) | (CANFD_CFG_RXFIFO2_PAYLOAD << R_CANFD_CFDRFCC_RFPLS_Pos) | (CANFD_CFG_RXFIFO2_INT_MODE) | (CANFD_CFG_RXFIFO2_ENABLE)), ((CANFD_CFG_RXFIFO3_INT_THRESHOLD << R_CANFD_CFDRFCC_RFIGCV_Pos) | (CANFD_CFG_RXFIFO3_DEPTH << R_CANFD_CFDRFCC_RFDC_Pos) | (CANFD_CFG_RXFIFO3_PAYLOAD << R_CANFD_CFDRFCC_RFPLS_Pos) | (CANFD_CFG_RXFIFO3_INT_MODE) | (CANFD_CFG_RXFIFO3_ENABLE)), ((CANFD_CFG_RXFIFO4_INT_THRESHOLD << R_CANFD_CFDRFCC_RFIGCV_Pos) | (CANFD_CFG_RXFIFO4_DEPTH << R_CANFD_CFDRFCC_RFDC_Pos) | (CANFD_CFG_RXFIFO4_PAYLOAD << R_CANFD_CFDRFCC_RFPLS_Pos) | (CANFD_CFG_RXFIFO4_INT_MODE) | (CANFD_CFG_RXFIFO4_ENABLE)), ((CANFD_CFG_RXFIFO5_INT_THRESHOLD << R_CANFD_CFDRFCC_RFIGCV_Pos) | (CANFD_CFG_RXFIFO5_DEPTH << R_CANFD_CFDRFCC_RFDC_Pos) | (CANFD_CFG_RXFIFO5_PAYLOAD << R_CANFD_CFDRFCC_RFPLS_Pos) | (CANFD_CFG_RXFIFO5_INT_MODE) | (CANFD_CFG_RXFIFO5_ENABLE)), ((CANFD_CFG_RXFIFO6_INT_THRESHOLD << R_CANFD_CFDRFCC_RFIGCV_Pos) | (CANFD_CFG_RXFIFO6_DEPTH << R_CANFD_CFDRFCC_RFDC_Pos) | (CANFD_CFG_RXFIFO6_PAYLOAD << R_CANFD_CFDRFCC_RFPLS_Pos) | (CANFD_CFG_RXFIFO6_INT_MODE) | (CANFD_CFG_RXFIFO6_ENABLE)), ((CANFD_CFG_RXFIFO7_INT_THRESHOLD << R_CANFD_CFDRFCC_RFIGCV_Pos) | (CANFD_CFG_RXFIFO7_DEPTH << R_CANFD_CFDRFCC_RFDC_Pos) | (CANFD_CFG_RXFIFO7_PAYLOAD << R_CANFD_CFDRFCC_RFPLS_Pos) | (CANFD_CFG_RXFIFO7_INT_MODE) | (CANFD_CFG_RXFIFO7_ENABLE)), }, .common_fifo_config = { CANFD_CFG_COMMONFIFO0, CANFD_CFG_COMMONFIFO1, CANFD_CFG_COMMONFIFO2, CANFD_CFG_COMMONFIFO3, CANFD_CFG_COMMONFIFO4, CANFD_CFG_COMMONFIFO5, } }; #endif canfd_extended_cfg_t g_canfd1_extended_cfg = { .p_afl = p_canfd1_afl, .txmb_txi_enable = ((1ULL << 1) | 0ULL), .error_interrupts = ( 0U), .p_data_timing = &g_canfd1_data_timing_cfg, .delay_compensation = (1), .p_global_cfg = &g_canfd_global_cfg, }; canfd_instance_ctrl_t g_canfd1_ctrl; const can_cfg_t g_canfd1_cfg = { .channel = 1, .p_bit_timing = &g_canfd1_bit_timing_cfg, .p_callback = canfd1_callback, .p_extend = &g_canfd1_extended_cfg, .p_context = NULL, .ipl = (12), #if defined(VECTOR_NUMBER_CAN1_COMFRX) .rx_irq = VECTOR_NUMBER_CAN1_COMFRX, #else .rx_irq = FSP_INVALID_VECTOR, #endif #if defined(VECTOR_NUMBER_CAN1_TX) .tx_irq = VECTOR_NUMBER_CAN1_TX, #else .tx_irq = FSP_INVALID_VECTOR, #endif #if defined(VECTOR_NUMBER_CAN1_CHERR) .error_irq = VECTOR_NUMBER_CAN1_CHERR, #else .error_irq = FSP_INVALID_VECTOR, #endif }; /* Instance structure to use this module. */ const can_instance_t g_canfd1 = { .p_ctrl = &g_canfd1_ctrl, .p_cfg = &g_canfd1_cfg, .p_api = &g_canfd_on_canfd }; /* Nominal and Data bit timing configuration */ can_bit_timing_cfg_t g_canfd0_bit_timing_cfg = { /* Actual bitrate: 500000 Hz. Actual sample point: 75 %. */ .baud_rate_prescaler = 1, .time_segment_1 = 59, .time_segment_2 = 20, .synchronization_jump_width = 4 }; can_bit_timing_cfg_t g_canfd0_data_timing_cfg = { /* Actual bitrate: 2000000 Hz. Actual sample point: 75 %. */ .baud_rate_prescaler = 1, .time_segment_1 = 14, .time_segment_2 = 5, .synchronization_jump_width = 1 }; extern const canfd_afl_entry_t p_canfd0_afl[CANFD_CFG_AFL_CH0_RULE_NUM]; #ifndef CANFD_PRV_GLOBAL_CFG #define CANFD_PRV_GLOBAL_CFG canfd_global_cfg_t g_canfd_global_cfg = { .global_interrupts = CANFD_CFG_GLOBAL_ERR_SOURCES, .global_config = (CANFD_CFG_TX_PRIORITY | CANFD_CFG_DLC_CHECK | CANFD_CFD_CLOCK_SOURCE | CANFD_CFG_FD_OVERFLOW | (uint32_t) (CANFD_CFG_TIMER_PRESCALER << R_CANFD_CFDGCFG_ITRCP_Pos)), .rx_mb_config = (CANFD_CFG_RXMB_NUMBER | (CANFD_CFG_RXMB_SIZE << R_CANFD_CFDRMNB_RMPLS_Pos)), .global_err_ipl = CANFD_CFG_GLOBAL_ERR_IPL, .rx_fifo_ipl = CANFD_CFG_RX_FIFO_IPL, .rx_fifo_config = { ((CANFD_CFG_RXFIFO0_INT_THRESHOLD << R_CANFD_CFDRFCC_RFIGCV_Pos) | (CANFD_CFG_RXFIFO0_DEPTH << R_CANFD_CFDRFCC_RFDC_Pos) | (CANFD_CFG_RXFIFO0_PAYLOAD << R_CANFD_CFDRFCC_RFPLS_Pos) | (CANFD_CFG_RXFIFO0_INT_MODE) | (CANFD_CFG_RXFIFO0_ENABLE)), ((CANFD_CFG_RXFIFO1_INT_THRESHOLD << R_CANFD_CFDRFCC_RFIGCV_Pos) | (CANFD_CFG_RXFIFO1_DEPTH << R_CANFD_CFDRFCC_RFDC_Pos) | (CANFD_CFG_RXFIFO1_PAYLOAD << R_CANFD_CFDRFCC_RFPLS_Pos) | (CANFD_CFG_RXFIFO1_INT_MODE) | (CANFD_CFG_RXFIFO1_ENABLE)), ((CANFD_CFG_RXFIFO2_INT_THRESHOLD << R_CANFD_CFDRFCC_RFIGCV_Pos) | (CANFD_CFG_RXFIFO2_DEPTH << R_CANFD_CFDRFCC_RFDC_Pos) | (CANFD_CFG_RXFIFO2_PAYLOAD << R_CANFD_CFDRFCC_RFPLS_Pos) | (CANFD_CFG_RXFIFO2_INT_MODE) | (CANFD_CFG_RXFIFO2_ENABLE)), ((CANFD_CFG_RXFIFO3_INT_THRESHOLD << R_CANFD_CFDRFCC_RFIGCV_Pos) | (CANFD_CFG_RXFIFO3_DEPTH << R_CANFD_CFDRFCC_RFDC_Pos) | (CANFD_CFG_RXFIFO3_PAYLOAD << R_CANFD_CFDRFCC_RFPLS_Pos) | (CANFD_CFG_RXFIFO3_INT_MODE) | (CANFD_CFG_RXFIFO3_ENABLE)), ((CANFD_CFG_RXFIFO4_INT_THRESHOLD << R_CANFD_CFDRFCC_RFIGCV_Pos) | (CANFD_CFG_RXFIFO4_DEPTH << R_CANFD_CFDRFCC_RFDC_Pos) | (CANFD_CFG_RXFIFO4_PAYLOAD << R_CANFD_CFDRFCC_RFPLS_Pos) | (CANFD_CFG_RXFIFO4_INT_MODE) | (CANFD_CFG_RXFIFO4_ENABLE)), ((CANFD_CFG_RXFIFO5_INT_THRESHOLD << R_CANFD_CFDRFCC_RFIGCV_Pos) | (CANFD_CFG_RXFIFO5_DEPTH << R_CANFD_CFDRFCC_RFDC_Pos) | (CANFD_CFG_RXFIFO5_PAYLOAD << R_CANFD_CFDRFCC_RFPLS_Pos) | (CANFD_CFG_RXFIFO5_INT_MODE) | (CANFD_CFG_RXFIFO5_ENABLE)), ((CANFD_CFG_RXFIFO6_INT_THRESHOLD << R_CANFD_CFDRFCC_RFIGCV_Pos) | (CANFD_CFG_RXFIFO6_DEPTH << R_CANFD_CFDRFCC_RFDC_Pos) | (CANFD_CFG_RXFIFO6_PAYLOAD << R_CANFD_CFDRFCC_RFPLS_Pos) | (CANFD_CFG_RXFIFO6_INT_MODE) | (CANFD_CFG_RXFIFO6_ENABLE)), ((CANFD_CFG_RXFIFO7_INT_THRESHOLD << R_CANFD_CFDRFCC_RFIGCV_Pos) | (CANFD_CFG_RXFIFO7_DEPTH << R_CANFD_CFDRFCC_RFDC_Pos) | (CANFD_CFG_RXFIFO7_PAYLOAD << R_CANFD_CFDRFCC_RFPLS_Pos) | (CANFD_CFG_RXFIFO7_INT_MODE) | (CANFD_CFG_RXFIFO7_ENABLE)), }, .common_fifo_config = { CANFD_CFG_COMMONFIFO0, CANFD_CFG_COMMONFIFO1, CANFD_CFG_COMMONFIFO2, CANFD_CFG_COMMONFIFO3, CANFD_CFG_COMMONFIFO4, CANFD_CFG_COMMONFIFO5, } }; #endif canfd_extended_cfg_t g_canfd0_extended_cfg = { .p_afl = p_canfd0_afl, .txmb_txi_enable = ((1ULL << 0) | 0ULL), .error_interrupts = ( 0U), .p_data_timing = &g_canfd0_data_timing_cfg, .delay_compensation = (1), .p_global_cfg = &g_canfd_global_cfg, }; canfd_instance_ctrl_t g_canfd0_ctrl; const can_cfg_t g_canfd0_cfg = { .channel = 0, .p_bit_timing = &g_canfd0_bit_timing_cfg, .p_callback = canfd0_callback, .p_extend = &g_canfd0_extended_cfg, .p_context = NULL, .ipl = (12), #if defined(VECTOR_NUMBER_CAN0_COMFRX) .rx_irq = VECTOR_NUMBER_CAN0_COMFRX, #else .rx_irq = FSP_INVALID_VECTOR, #endif #if defined(VECTOR_NUMBER_CAN0_TX) .tx_irq = VECTOR_NUMBER_CAN0_TX, #else .tx_irq = FSP_INVALID_VECTOR, #endif #if defined(VECTOR_NUMBER_CAN0_CHERR) .error_irq = VECTOR_NUMBER_CAN0_CHERR, #else .error_irq = FSP_INVALID_VECTOR, #endif }; /* Instance structure to use this module. */ const can_instance_t g_canfd0 = { .p_ctrl = &g_canfd0_ctrl, .p_cfg = &g_canfd0_cfg, .p_api = &g_canfd_on_canfd }; sci_uart_instance_ctrl_t g_uart0_ctrl; #define FSP_NOT_DEFINED (1) #if (FSP_NOT_DEFINED) != (FSP_NOT_DEFINED) /* If the transfer module is DMAC, define a DMAC transfer callback. */ extern void sci_uart_tx_dmac_callback(sci_uart_instance_ctrl_t * p_instance_ctrl); void g_uart0_tx_transfer_callback (transfer_callback_args_t * p_args) { FSP_PARAMETER_NOT_USED(p_args); sci_uart_tx_dmac_callback(&g_uart0_ctrl); } #endif #if (FSP_NOT_DEFINED) != (FSP_NOT_DEFINED) /* If the transfer module is DMAC, define a DMAC transfer callback. */ extern void sci_uart_rx_dmac_callback(sci_uart_instance_ctrl_t * p_instance_ctrl); void g_uart0_rx_transfer_callback (transfer_callback_args_t * p_args) { FSP_PARAMETER_NOT_USED(p_args); sci_uart_rx_dmac_callback(&g_uart0_ctrl); } #endif #undef FSP_NOT_DEFINED sci_baud_setting_t g_uart0_baud_setting = { /* Baud rate calculated with 0.160% error. */ .baudrate_bits_b.abcse = 0, .baudrate_bits_b.abcs = 0, .baudrate_bits_b.bgdm = 1, .baudrate_bits_b.cks = 0, .baudrate_bits_b.brr = 51, .baudrate_bits_b.mddr = (uint8_t) 256, .baudrate_bits_b.brme = false }; /** UART extended configuration for UARTonSCI HAL driver */ const sci_uart_extended_cfg_t g_uart0_cfg_extend = { .clock = SCI_UART_CLOCK_INT, .rx_edge_start = SCI_UART_START_BIT_FALLING_EDGE, .noise_cancel = SCI_UART_NOISE_CANCELLATION_DISABLE, .rx_fifo_trigger = SCI_UART_RX_FIFO_TRIGGER_MAX, .p_baud_setting = &g_uart0_baud_setting, #if 1 .clock_source = SCI_UART_CLOCK_SOURCE_SCI0ASYNCCLK, #else .clock_source = SCI_UART_CLOCK_SOURCE_PCLKM, #endif .flow_control = SCI_UART_FLOW_CONTROL_RTS, #if 0xFF != 0xFF .flow_control_pin = BSP_IO_PORT_FF_PIN_0xFF, #else .flow_control_pin = (bsp_io_port_pin_t) UINT16_MAX, #endif .rs485_setting = { .enable = SCI_UART_RS485_DISABLE, .polarity = SCI_UART_RS485_DE_POLARITY_HIGH, .assertion_time = 1, .negation_time = 1, }, }; /** UART interface configuration */ const uart_cfg_t g_uart0_cfg = { .channel = 0, .data_bits = UART_DATA_BITS_8, .parity = UART_PARITY_OFF, .stop_bits = UART_STOP_BITS_1, .p_callback = user_uart0_callback, .p_context = NULL, .p_extend = &g_uart0_cfg_extend, .p_transfer_tx = g_uart0_P_TRANSFER_TX, .p_transfer_rx = g_uart0_P_TRANSFER_RX, .rxi_ipl = (12), .txi_ipl = (12), .tei_ipl = (12), .eri_ipl = (12), #if defined(VECTOR_NUMBER_SCI0_RXI) .rxi_irq = VECTOR_NUMBER_SCI0_RXI, #else .rxi_irq = FSP_INVALID_VECTOR, #endif #if defined(VECTOR_NUMBER_SCI0_TXI) .txi_irq = VECTOR_NUMBER_SCI0_TXI, #else .txi_irq = FSP_INVALID_VECTOR, #endif #if defined(VECTOR_NUMBER_SCI0_TEI) .tei_irq = VECTOR_NUMBER_SCI0_TEI, #else .tei_irq = FSP_INVALID_VECTOR, #endif #if defined(VECTOR_NUMBER_SCI0_ERI) .eri_irq = VECTOR_NUMBER_SCI0_ERI, #else .eri_irq = FSP_INVALID_VECTOR, #endif }; /* Instance structure to use this module. */ const uart_instance_t g_uart0 = { .p_ctrl = &g_uart0_ctrl, .p_cfg = &g_uart0_cfg, .p_api = &g_uart_on_sci }; void g_hal_init(void) { g_common_init(); }