/* generated HAL source file - do not edit */ #include "hal_data.h" /* Macros to tie dynamic ELC links to ADC_TRIGGER_SYNC_ELC option in adc_trigger_t. */ #define ADC_TRIGGER_ADC0 ADC_TRIGGER_SYNC_ELC #define ADC_TRIGGER_ADC0_B ADC_TRIGGER_SYNC_ELC #define ADC_TRIGGER_ADC1 ADC_TRIGGER_SYNC_ELC #define ADC_TRIGGER_ADC1_B ADC_TRIGGER_SYNC_ELC adc_instance_ctrl_t g_adc1_ctrl; const adc_extended_cfg_t g_adc1_cfg_extend = { .add_average_count = ADC_ADD_OFF, .clearing = ADC_CLEAR_AFTER_READ_ON, .trigger_group_b = ADC_TRIGGER_SYNC_ELC, .double_trigger_mode = ADC_DOUBLE_TRIGGER_DISABLED, .adc_vref_control = ADC_VREF_CONTROL_VREFH, }; const adc_cfg_t g_adc1_cfg = { .unit = 1, .mode = ADC_MODE_SINGLE_SCAN, .resolution = ADC_RESOLUTION_12_BIT, .alignment = (adc_alignment_t)ADC_ALIGNMENT_RIGHT, .trigger = ADC_TRIGGER_SOFTWARE, .p_callback = NULL, .p_context = NULL, .p_extend = &g_adc1_cfg_extend, #if defined(VECTOR_NUMBER_ADC1_SCAN_END) .scan_end_irq = VECTOR_NUMBER_ADC1_SCAN_END, #else .scan_end_irq = FSP_INVALID_VECTOR, #endif .scan_end_ipl = (BSP_IRQ_DISABLED), #if defined(VECTOR_NUMBER_ADC1_SCAN_END_B) .scan_end_b_irq = VECTOR_NUMBER_ADC1_SCAN_END_B, #else .scan_end_b_irq = FSP_INVALID_VECTOR, #endif .scan_end_b_ipl = (BSP_IRQ_DISABLED), }; const adc_channel_cfg_t g_adc1_channel_cfg = { .scan_mask = 0, .scan_mask_group_b = 0, .priority_group_a = ADC_GROUP_A_PRIORITY_OFF, .add_mask = 0, .sample_hold_mask = 0, .sample_hold_states = 24, }; /* Instance structure to use this module. */ const adc_instance_t g_adc1 = { .p_ctrl = &g_adc1_ctrl, .p_cfg = &g_adc1_cfg, .p_channel_cfg = &g_adc1_channel_cfg, .p_api = &g_adc_on_adc }; iic_master_instance_ctrl_t g_i2c_master0_ctrl; const iic_master_extended_cfg_t g_i2c_master0_extend = { .timeout_mode = IIC_MASTER_TIMEOUT_MODE_SHORT, /* Actual calculated bitrate: 98945. Actual calculated duty cycle: 51%. */ .clock_settings.brl_value = 15, .clock_settings.brh_value = 16, .clock_settings.cks_value = 4, }; const i2c_master_cfg_t g_i2c_master0_cfg = { .channel = 0, .rate = I2C_MASTER_RATE_STANDARD, .slave = 0x00, .addr_mode = I2C_MASTER_ADDR_MODE_7BIT, #define RA_NOT_DEFINED (1) #if (RA_NOT_DEFINED == RA_NOT_DEFINED) .p_transfer_tx = NULL, #else .p_transfer_tx = &RA_NOT_DEFINED, #endif #if (RA_NOT_DEFINED == RA_NOT_DEFINED) .p_transfer_rx = NULL, #else .p_transfer_rx = &RA_NOT_DEFINED, #endif #undef RA_NOT_DEFINED .p_callback = callback_iic, .p_context = NULL, #if defined(VECTOR_NUMBER_IIC0_RXI) .rxi_irq = VECTOR_NUMBER_IIC0_RXI, #else .rxi_irq = FSP_INVALID_VECTOR, #endif #if defined(VECTOR_NUMBER_IIC0_TXI) .txi_irq = VECTOR_NUMBER_IIC0_TXI, #else .txi_irq = FSP_INVALID_VECTOR, #endif #if defined(VECTOR_NUMBER_IIC0_TEI) .tei_irq = VECTOR_NUMBER_IIC0_TEI, #else .tei_irq = FSP_INVALID_VECTOR, #endif #if defined(VECTOR_NUMBER_IIC0_ERI) .eri_irq = VECTOR_NUMBER_IIC0_ERI, #else .eri_irq = FSP_INVALID_VECTOR, #endif .ipl = (12), .p_extend = &g_i2c_master0_extend, }; /* Instance structure to use this module. */ const i2c_master_instance_t g_i2c_master0 = { .p_ctrl = &g_i2c_master0_ctrl, .p_cfg = &g_i2c_master0_cfg, .p_api = &g_i2c_master_on_iic }; adc_instance_ctrl_t g_adc0_ctrl; const adc_extended_cfg_t g_adc0_cfg_extend = { .add_average_count = ADC_ADD_OFF, .clearing = ADC_CLEAR_AFTER_READ_ON, .trigger_group_b = ADC_TRIGGER_SYNC_ELC, .double_trigger_mode = ADC_DOUBLE_TRIGGER_DISABLED, .adc_vref_control = ADC_VREF_CONTROL_VREFH, }; const adc_cfg_t g_adc0_cfg = { .unit = 0, .mode = ADC_MODE_SINGLE_SCAN, .resolution = ADC_RESOLUTION_12_BIT, .alignment = (adc_alignment_t)ADC_ALIGNMENT_RIGHT, .trigger = ADC_TRIGGER_SOFTWARE, .p_callback = NULL, .p_context = NULL, .p_extend = &g_adc0_cfg_extend, #if defined(VECTOR_NUMBER_ADC0_SCAN_END) .scan_end_irq = VECTOR_NUMBER_ADC0_SCAN_END, #else .scan_end_irq = FSP_INVALID_VECTOR, #endif .scan_end_ipl = (BSP_IRQ_DISABLED), #if defined(VECTOR_NUMBER_ADC0_SCAN_END_B) .scan_end_b_irq = VECTOR_NUMBER_ADC0_SCAN_END_B, #else .scan_end_b_irq = FSP_INVALID_VECTOR, #endif .scan_end_b_ipl = (BSP_IRQ_DISABLED), }; const adc_channel_cfg_t g_adc0_channel_cfg = { .scan_mask = 0, .scan_mask_group_b = 0, .priority_group_a = ADC_GROUP_A_PRIORITY_OFF, .add_mask = 0, .sample_hold_mask = 0, .sample_hold_states = 24, }; /* Instance structure to use this module. */ const adc_instance_t g_adc0 = { .p_ctrl = &g_adc0_ctrl, .p_cfg = &g_adc0_cfg, .p_channel_cfg = &g_adc0_channel_cfg, .p_api = &g_adc_on_adc }; lpm_instance_ctrl_t g_lpm0_ctrl; const lpm_cfg_t g_lpm0_cfg = { .low_power_mode = LPM_MODE_SLEEP, .snooze_cancel_sources = LPM_SNOOZE_CANCEL_SOURCE_NONE, .standby_wake_sources = LPM_STANDBY_WAKE_SOURCE_RTCALM | (lpm_standby_wake_source_t)0, .snooze_request_source = LPM_SNOOZE_REQUEST_RXD0_FALLING, .snooze_end_sources = (lpm_snooze_end_t)0, .dtc_state_in_snooze = LPM_SNOOZE_DTC_DISABLE, #if BSP_FEATURE_LPM_HAS_SBYCR_OPE .output_port_enable = LPM_OUTPUT_PORT_ENABLE_RETAIN, #endif #if BSP_FEATURE_LPM_HAS_DEEP_STANDBY .io_port_state = LPM_IO_PORT_NO_CHANGE, .power_supply_state = LPM_POWER_SUPPLY_DEEPCUT0, .deep_standby_cancel_source = (lpm_deep_standby_cancel_source_t)0, .deep_standby_cancel_edge = (lpm_deep_standby_cancel_edge_t)0, #endif .p_extend = NULL, }; const lpm_instance_t g_lpm0 = { .p_api = &g_lpm_on_lpm, .p_ctrl = &g_lpm0_ctrl, .p_cfg = &g_lpm0_cfg }; dtc_instance_ctrl_t g_transfer1_ctrl; transfer_info_t g_transfer1_info = { .dest_addr_mode = TRANSFER_ADDR_MODE_INCREMENTED, .repeat_area = TRANSFER_REPEAT_AREA_DESTINATION, .irq = TRANSFER_IRQ_END, .chain_mode = TRANSFER_CHAIN_MODE_DISABLED, .src_addr_mode = TRANSFER_ADDR_MODE_FIXED, .size = TRANSFER_SIZE_2_BYTE, .mode = TRANSFER_MODE_NORMAL, .p_dest = (void *)NULL, .p_src = (void const *)NULL, .num_blocks = 0, .length = 0, }; const dtc_extended_cfg_t g_transfer1_cfg_extend = { .activation_source = VECTOR_NUMBER_SPI0_RXI, }; const transfer_cfg_t g_transfer1_cfg = { .p_info = &g_transfer1_info, .p_extend = &g_transfer1_cfg_extend, }; /* Instance structure to use this module. */ const transfer_instance_t g_transfer1 = { .p_ctrl = &g_transfer1_ctrl, .p_cfg = &g_transfer1_cfg, .p_api = &g_transfer_on_dtc }; dtc_instance_ctrl_t g_transfer0_ctrl; transfer_info_t g_transfer0_info = { .dest_addr_mode = TRANSFER_ADDR_MODE_FIXED, .repeat_area = TRANSFER_REPEAT_AREA_SOURCE, .irq = TRANSFER_IRQ_END, .chain_mode = TRANSFER_CHAIN_MODE_DISABLED, .src_addr_mode = TRANSFER_ADDR_MODE_INCREMENTED, .size = TRANSFER_SIZE_2_BYTE, .mode = TRANSFER_MODE_NORMAL, .p_dest = (void *)NULL, .p_src = (void const *)NULL, .num_blocks = 0, .length = 0, }; const dtc_extended_cfg_t g_transfer0_cfg_extend = { .activation_source = VECTOR_NUMBER_SPI0_TXI, }; const transfer_cfg_t g_transfer0_cfg = { .p_info = &g_transfer0_info, .p_extend = &g_transfer0_cfg_extend, }; /* Instance structure to use this module. */ const transfer_instance_t g_transfer0 = { .p_ctrl = &g_transfer0_ctrl, .p_cfg = &g_transfer0_cfg, .p_api = &g_transfer_on_dtc }; spi_instance_ctrl_t g_spi0_ctrl; /** SPI extended configuration for SPI HAL driver */ const spi_extended_cfg_t g_spi0_ext_cfg = { .spi_clksyn = SPI_SSL_MODE_CLK_SYN, .spi_comm = SPI_COMMUNICATION_FULL_DUPLEX, .ssl_polarity = SPI_SSLP_LOW, .ssl_select = SPI_SSL_SELECT_SSL0, .mosi_idle = SPI_MOSI_IDLE_VALUE_FIXING_DISABLE, .parity = SPI_PARITY_MODE_DISABLE, .byte_swap = SPI_BYTE_SWAP_DISABLE, .spck_div = { /* Actual calculated bitrate: 15000000. */ .spbr = 3, .brdv = 0 }, .spck_delay = SPI_DELAY_COUNT_1, .ssl_negation_delay = SPI_DELAY_COUNT_1, .next_access_delay = SPI_DELAY_COUNT_1 }; /** SPI configuration for SPI HAL driver */ const spi_cfg_t g_spi0_cfg = { .channel = 0, #if defined(VECTOR_NUMBER_SPI0_RXI) .rxi_irq = VECTOR_NUMBER_SPI0_RXI, #else .rxi_irq = FSP_INVALID_VECTOR, #endif #if defined(VECTOR_NUMBER_SPI0_TXI) .txi_irq = VECTOR_NUMBER_SPI0_TXI, #else .txi_irq = FSP_INVALID_VECTOR, #endif #if defined(VECTOR_NUMBER_SPI0_TEI) .tei_irq = VECTOR_NUMBER_SPI0_TEI, #else .tei_irq = FSP_INVALID_VECTOR, #endif #if defined(VECTOR_NUMBER_SPI0_ERI) .eri_irq = VECTOR_NUMBER_SPI0_ERI, #else .eri_irq = FSP_INVALID_VECTOR, #endif .rxi_ipl = (12), .txi_ipl = (12), .tei_ipl = (12), .eri_ipl = (12), .operating_mode = SPI_MODE_MASTER, .clk_phase = SPI_CLK_PHASE_EDGE_ODD, .clk_polarity = SPI_CLK_POLARITY_LOW, .mode_fault = SPI_MODE_FAULT_ERROR_DISABLE, .bit_order = SPI_BIT_ORDER_MSB_FIRST, .p_transfer_tx = g_spi0_P_TRANSFER_TX, .p_transfer_rx = g_spi0_P_TRANSFER_RX, .p_callback = spi_callback, .p_context = NULL, .p_extend = (void *)&g_spi0_ext_cfg, }; /* Instance structure to use this module. */ const spi_instance_t g_spi0 = { .p_ctrl = &g_spi0_ctrl, .p_cfg = &g_spi0_cfg, .p_api = &g_spi_on_spi }; icu_instance_ctrl_t g_external_irq13_ctrl; const external_irq_cfg_t g_external_irq13_cfg = { .channel = 13, .trigger = EXTERNAL_IRQ_TRIG_RISING, .filter_enable = false, .pclk_div = EXTERNAL_IRQ_PCLK_DIV_BY_64, .p_callback = callback_icu, .p_context = NULL, .p_extend = NULL, .ipl = (12), #if defined(VECTOR_NUMBER_ICU_IRQ13) .irq = VECTOR_NUMBER_ICU_IRQ13, #else .irq = FSP_INVALID_VECTOR, #endif }; /* Instance structure to use this module. */ const external_irq_instance_t g_external_irq13 = { .p_ctrl = &g_external_irq13_ctrl, .p_cfg = &g_external_irq13_cfg, .p_api = &g_external_irq_on_icu }; icu_instance_ctrl_t g_external_irq12_ctrl; const external_irq_cfg_t g_external_irq12_cfg = { .channel = 12, .trigger = EXTERNAL_IRQ_TRIG_RISING, .filter_enable = false, .pclk_div = EXTERNAL_IRQ_PCLK_DIV_BY_64, .p_callback = callback_icu, .p_context = NULL, .p_extend = NULL, .ipl = (12), #if defined(VECTOR_NUMBER_ICU_IRQ12) .irq = VECTOR_NUMBER_ICU_IRQ12, #else .irq = FSP_INVALID_VECTOR, #endif }; /* Instance structure to use this module. */ const external_irq_instance_t g_external_irq12 = { .p_ctrl = &g_external_irq12_ctrl, .p_cfg = &g_external_irq12_cfg, .p_api = &g_external_irq_on_icu }; icu_instance_ctrl_t g_external_irq11_ctrl; const external_irq_cfg_t g_external_irq11_cfg = { .channel = 11, .trigger = EXTERNAL_IRQ_TRIG_RISING, .filter_enable = false, .pclk_div = EXTERNAL_IRQ_PCLK_DIV_BY_64, .p_callback = callback_icu, .p_context = NULL, .p_extend = NULL, .ipl = (12), #if defined(VECTOR_NUMBER_ICU_IRQ11) .irq = VECTOR_NUMBER_ICU_IRQ11, #else .irq = FSP_INVALID_VECTOR, #endif }; /* Instance structure to use this module. */ const external_irq_instance_t g_external_irq11 = { .p_ctrl = &g_external_irq11_ctrl, .p_cfg = &g_external_irq11_cfg, .p_api = &g_external_irq_on_icu }; icu_instance_ctrl_t g_external_irq10_ctrl; const external_irq_cfg_t g_external_irq10_cfg = { .channel = 10, .trigger = EXTERNAL_IRQ_TRIG_RISING, .filter_enable = false, .pclk_div = EXTERNAL_IRQ_PCLK_DIV_BY_64, .p_callback = callback_icu, .p_context = NULL, .p_extend = NULL, .ipl = (12), #if defined(VECTOR_NUMBER_ICU_IRQ10) .irq = VECTOR_NUMBER_ICU_IRQ10, #else .irq = FSP_INVALID_VECTOR, #endif }; /* Instance structure to use this module. */ const external_irq_instance_t g_external_irq10 = { .p_ctrl = &g_external_irq10_ctrl, .p_cfg = &g_external_irq10_cfg, .p_api = &g_external_irq_on_icu }; icu_instance_ctrl_t g_external_irq9_ctrl; const external_irq_cfg_t g_external_irq9_cfg = { .channel = 9, .trigger = EXTERNAL_IRQ_TRIG_RISING, .filter_enable = false, .pclk_div = EXTERNAL_IRQ_PCLK_DIV_BY_64, .p_callback = callback_icu, .p_context = NULL, .p_extend = NULL, .ipl = (12), #if defined(VECTOR_NUMBER_ICU_IRQ9) .irq = VECTOR_NUMBER_ICU_IRQ9, #else .irq = FSP_INVALID_VECTOR, #endif }; /* Instance structure to use this module. */ const external_irq_instance_t g_external_irq9 = { .p_ctrl = &g_external_irq9_ctrl, .p_cfg = &g_external_irq9_cfg, .p_api = &g_external_irq_on_icu }; icu_instance_ctrl_t g_external_irq8_ctrl; const external_irq_cfg_t g_external_irq8_cfg = { .channel = 8, .trigger = EXTERNAL_IRQ_TRIG_RISING, .filter_enable = false, .pclk_div = EXTERNAL_IRQ_PCLK_DIV_BY_64, .p_callback = callback_icu, .p_context = NULL, .p_extend = NULL, .ipl = (12), #if defined(VECTOR_NUMBER_ICU_IRQ8) .irq = VECTOR_NUMBER_ICU_IRQ8, #else .irq = FSP_INVALID_VECTOR, #endif }; /* Instance structure to use this module. */ const external_irq_instance_t g_external_irq8 = { .p_ctrl = &g_external_irq8_ctrl, .p_cfg = &g_external_irq8_cfg, .p_api = &g_external_irq_on_icu }; icu_instance_ctrl_t g_external_irq7_ctrl; const external_irq_cfg_t g_external_irq7_cfg = { .channel = 7, .trigger = EXTERNAL_IRQ_TRIG_RISING, .filter_enable = false, .pclk_div = EXTERNAL_IRQ_PCLK_DIV_BY_64, .p_callback = callback_icu, .p_context = NULL, .p_extend = NULL, .ipl = (12), #if defined(VECTOR_NUMBER_ICU_IRQ7) .irq = VECTOR_NUMBER_ICU_IRQ7, #else .irq = FSP_INVALID_VECTOR, #endif }; /* Instance structure to use this module. */ const external_irq_instance_t g_external_irq7 = { .p_ctrl = &g_external_irq7_ctrl, .p_cfg = &g_external_irq7_cfg, .p_api = &g_external_irq_on_icu }; icu_instance_ctrl_t g_external_irq6_ctrl; const external_irq_cfg_t g_external_irq6_cfg = { .channel = 6, .trigger = EXTERNAL_IRQ_TRIG_RISING, .filter_enable = false, .pclk_div = EXTERNAL_IRQ_PCLK_DIV_BY_64, .p_callback = callback_icu, .p_context = NULL, .p_extend = NULL, .ipl = (12), #if defined(VECTOR_NUMBER_ICU_IRQ6) .irq = VECTOR_NUMBER_ICU_IRQ6, #else .irq = FSP_INVALID_VECTOR, #endif }; /* Instance structure to use this module. */ const external_irq_instance_t g_external_irq6 = { .p_ctrl = &g_external_irq6_ctrl, .p_cfg = &g_external_irq6_cfg, .p_api = &g_external_irq_on_icu }; icu_instance_ctrl_t g_external_irq5_ctrl; const external_irq_cfg_t g_external_irq5_cfg = { .channel = 5, .trigger = EXTERNAL_IRQ_TRIG_RISING, .filter_enable = false, .pclk_div = EXTERNAL_IRQ_PCLK_DIV_BY_64, .p_callback = callback_icu, .p_context = NULL, .p_extend = NULL, .ipl = (12), #if defined(VECTOR_NUMBER_ICU_IRQ5) .irq = VECTOR_NUMBER_ICU_IRQ5, #else .irq = FSP_INVALID_VECTOR, #endif }; /* Instance structure to use this module. */ const external_irq_instance_t g_external_irq5 = { .p_ctrl = &g_external_irq5_ctrl, .p_cfg = &g_external_irq5_cfg, .p_api = &g_external_irq_on_icu }; icu_instance_ctrl_t g_external_irq4_ctrl; const external_irq_cfg_t g_external_irq4_cfg = { .channel = 4, .trigger = EXTERNAL_IRQ_TRIG_RISING, .filter_enable = false, .pclk_div = EXTERNAL_IRQ_PCLK_DIV_BY_64, .p_callback = callback_icu, .p_context = NULL, .p_extend = NULL, .ipl = (12), #if defined(VECTOR_NUMBER_ICU_IRQ4) .irq = VECTOR_NUMBER_ICU_IRQ4, #else .irq = FSP_INVALID_VECTOR, #endif }; /* Instance structure to use this module. */ const external_irq_instance_t g_external_irq4 = { .p_ctrl = &g_external_irq4_ctrl, .p_cfg = &g_external_irq4_cfg, .p_api = &g_external_irq_on_icu }; icu_instance_ctrl_t g_external_irq3_ctrl; const external_irq_cfg_t g_external_irq3_cfg = { .channel = 3, .trigger = EXTERNAL_IRQ_TRIG_RISING, .filter_enable = false, .pclk_div = EXTERNAL_IRQ_PCLK_DIV_BY_64, .p_callback = callback_icu, .p_context = NULL, .p_extend = NULL, .ipl = (12), #if defined(VECTOR_NUMBER_ICU_IRQ3) .irq = VECTOR_NUMBER_ICU_IRQ3, #else .irq = FSP_INVALID_VECTOR, #endif }; /* Instance structure to use this module. */ const external_irq_instance_t g_external_irq3 = { .p_ctrl = &g_external_irq3_ctrl, .p_cfg = &g_external_irq3_cfg, .p_api = &g_external_irq_on_icu }; icu_instance_ctrl_t g_external_irq2_ctrl; const external_irq_cfg_t g_external_irq2_cfg = { .channel = 2, .trigger = EXTERNAL_IRQ_TRIG_RISING, .filter_enable = false, .pclk_div = EXTERNAL_IRQ_PCLK_DIV_BY_64, .p_callback = callback_icu, .p_context = NULL, .p_extend = NULL, .ipl = (12), #if defined(VECTOR_NUMBER_ICU_IRQ2) .irq = VECTOR_NUMBER_ICU_IRQ2, #else .irq = FSP_INVALID_VECTOR, #endif }; /* Instance structure to use this module. */ const external_irq_instance_t g_external_irq2 = { .p_ctrl = &g_external_irq2_ctrl, .p_cfg = &g_external_irq2_cfg, .p_api = &g_external_irq_on_icu }; icu_instance_ctrl_t g_external_irq1_ctrl; const external_irq_cfg_t g_external_irq1_cfg = { .channel = 1, .trigger = EXTERNAL_IRQ_TRIG_RISING, .filter_enable = false, .pclk_div = EXTERNAL_IRQ_PCLK_DIV_BY_64, .p_callback = callback_icu, .p_context = NULL, .p_extend = NULL, .ipl = (12), #if defined(VECTOR_NUMBER_ICU_IRQ1) .irq = VECTOR_NUMBER_ICU_IRQ1, #else .irq = FSP_INVALID_VECTOR, #endif }; /* Instance structure to use this module. */ const external_irq_instance_t g_external_irq1 = { .p_ctrl = &g_external_irq1_ctrl, .p_cfg = &g_external_irq1_cfg, .p_api = &g_external_irq_on_icu }; icu_instance_ctrl_t g_external_irq0_ctrl; const external_irq_cfg_t g_external_irq0_cfg = { .channel = 0, .trigger = EXTERNAL_IRQ_TRIG_RISING, .filter_enable = false, .pclk_div = EXTERNAL_IRQ_PCLK_DIV_BY_64, .p_callback = callback_icu, .p_context = NULL, .p_extend = NULL, .ipl = (12), #if defined(VECTOR_NUMBER_ICU_IRQ0) .irq = VECTOR_NUMBER_ICU_IRQ0, #else .irq = FSP_INVALID_VECTOR, #endif }; /* Instance structure to use this module. */ const external_irq_instance_t g_external_irq0 = { .p_ctrl = &g_external_irq0_ctrl, .p_cfg = &g_external_irq0_cfg, .p_api = &g_external_irq_on_icu }; agt_instance_ctrl_t g_timer1_ctrl; const agt_extended_cfg_t g_timer1_extend = { .count_source = AGT_CLOCK_PCLKB, .agto = AGT_PIN_CFG_DISABLED, .agtoa = AGT_PIN_CFG_DISABLED, .agtob = AGT_PIN_CFG_DISABLED, .measurement_mode = AGT_MEASURE_DISABLED, .agtio_filter = AGT_AGTIO_FILTER_NONE, .enable_pin = AGT_ENABLE_PIN_NOT_USED, .trigger_edge = AGT_TRIGGER_EDGE_RISING, }; const timer_cfg_t g_timer1_cfg = { .mode = TIMER_MODE_PERIODIC, /* Actual period: 0.0010922666666666667 seconds. Actual duty: 50%. */ .period_counts = 0x10000, .duty_cycle_counts = 0x8000, .source_div = (timer_source_div_t)0, .channel = 1, .p_callback = callback_agt, /** If NULL then do not add & */ #if defined(NULL) .p_context = NULL, #else .p_context = &NULL, #endif .p_extend = &g_timer1_extend, .cycle_end_ipl = (5), #if defined(VECTOR_NUMBER_AGT1_INT) .cycle_end_irq = VECTOR_NUMBER_AGT1_INT, #else .cycle_end_irq = FSP_INVALID_VECTOR, #endif }; /* Instance structure to use this module. */ const timer_instance_t g_timer1 = { .p_ctrl = &g_timer1_ctrl, .p_cfg = &g_timer1_cfg, .p_api = &g_timer_on_agt }; agt_instance_ctrl_t g_timer0_ctrl; const agt_extended_cfg_t g_timer0_extend = { .count_source = AGT_CLOCK_PCLKB, .agto = AGT_PIN_CFG_DISABLED, .agtoa = AGT_PIN_CFG_DISABLED, .agtob = AGT_PIN_CFG_DISABLED, .measurement_mode = AGT_MEASURE_DISABLED, .agtio_filter = AGT_AGTIO_FILTER_NONE, .enable_pin = AGT_ENABLE_PIN_NOT_USED, .trigger_edge = AGT_TRIGGER_EDGE_RISING, }; const timer_cfg_t g_timer0_cfg = { .mode = TIMER_MODE_PERIODIC, /* Actual period: 0.0010922666666666667 seconds. Actual duty: 50%. */ .period_counts = 0x10000, .duty_cycle_counts = 0x8000, .source_div = (timer_source_div_t)0, .channel = 0, .p_callback = callback_agt, /** If NULL then do not add & */ #if defined(NULL) .p_context = NULL, #else .p_context = &NULL, #endif .p_extend = &g_timer0_extend, .cycle_end_ipl = (5), #if defined(VECTOR_NUMBER_AGT0_INT) .cycle_end_irq = VECTOR_NUMBER_AGT0_INT, #else .cycle_end_irq = FSP_INVALID_VECTOR, #endif }; /* Instance structure to use this module. */ const timer_instance_t g_timer0 = { .p_ctrl = &g_timer0_ctrl, .p_cfg = &g_timer0_cfg, .p_api = &g_timer_on_agt }; flash_hp_instance_ctrl_t g_flash0_ctrl; const flash_cfg_t g_flash0_cfg = { .data_flash_bgo = false, .p_callback = NULL, .p_context = NULL, #if defined(VECTOR_NUMBER_FCU_FRDYI) .irq = VECTOR_NUMBER_FCU_FRDYI, #else .irq = FSP_INVALID_VECTOR, #endif #if defined(VECTOR_NUMBER_FCU_FIFERR) .err_irq = VECTOR_NUMBER_FCU_FIFERR, #else .err_irq = FSP_INVALID_VECTOR, #endif .err_ipl = (BSP_IRQ_DISABLED), .ipl = (BSP_IRQ_DISABLED), }; /* Instance structure to use this module. */ const flash_instance_t g_flash0 = { .p_ctrl = &g_flash0_ctrl, .p_cfg = &g_flash0_cfg, .p_api = &g_flash_on_flash_hp }; rtc_instance_ctrl_t g_rtc0_ctrl; const rtc_error_adjustment_cfg_t g_rtc0_err_cfg = { .adjustment_mode = RTC_ERROR_ADJUSTMENT_MODE_AUTOMATIC, .adjustment_period = RTC_ERROR_ADJUSTMENT_PERIOD_10_SECOND, .adjustment_type = RTC_ERROR_ADJUSTMENT_NONE, .adjustment_value = 0, }; const rtc_cfg_t g_rtc0_cfg = { .clock_source = RTC_CLOCK_SOURCE_LOCO, .freq_compare_value_loco = 255, .p_err_cfg = &g_rtc0_err_cfg, .p_callback = NULL, .p_context = NULL, .alarm_ipl = (14), .periodic_ipl = (14), .carry_ipl = (14), #if defined(VECTOR_NUMBER_RTC_ALARM) .alarm_irq = VECTOR_NUMBER_RTC_ALARM, #else .alarm_irq = FSP_INVALID_VECTOR, #endif #if defined(VECTOR_NUMBER_RTC_PERIOD) .periodic_irq = VECTOR_NUMBER_RTC_PERIOD, #else .periodic_irq = FSP_INVALID_VECTOR, #endif #if defined(VECTOR_NUMBER_RTC_CARRY) .carry_irq = VECTOR_NUMBER_RTC_CARRY, #else .carry_irq = FSP_INVALID_VECTOR, #endif }; /* Instance structure to use this module. */ const rtc_instance_t g_rtc0 = { .p_ctrl = &g_rtc0_ctrl, .p_cfg = &g_rtc0_cfg, .p_api = &g_rtc_on_rtc }; sci_uart_instance_ctrl_t g_uart8_ctrl; baud_setting_t g_uart8_baud_setting = { /* Baud rate calculated with 0.160% error. */ .abcse = 0, .abcs = 0, .bgdm = 1, .cks = 0, .brr = 64, .mddr = (uint8_t)256, .brme = false }; /** UART extended configuration for UARTonSCI HAL driver */ const sci_uart_extended_cfg_t g_uart8_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_uart8_baud_setting, .uart_mode = UART_MODE_RS232, .ctsrts_en = SCI_UART_CTSRTS_RTS_OUTPUT, #if 0 .flow_control_pin = BSP_IO_PORT_00_PIN_00, #else .flow_control_pin = (bsp_io_port_pin_t)(0xFFFFU), #endif }; /** UART interface configuration */ const uart_cfg_t g_uart8_cfg = { .channel = 8, .data_bits = UART_DATA_BITS_8, .parity = UART_PARITY_OFF, .stop_bits = UART_STOP_BITS_1, .p_callback = user_uart_callback, .p_context = NULL, .p_extend = &g_uart8_cfg_extend, #define RA_NOT_DEFINED (1) #if (RA_NOT_DEFINED == RA_NOT_DEFINED) .p_transfer_tx = NULL, #else .p_transfer_tx = &RA_NOT_DEFINED, #endif #if (RA_NOT_DEFINED == RA_NOT_DEFINED) .p_transfer_rx = NULL, #else .p_transfer_rx = &RA_NOT_DEFINED, #endif #undef RA_NOT_DEFINED .rxi_ipl = (12), .txi_ipl = (12), .tei_ipl = (12), .eri_ipl = (12), #if defined(VECTOR_NUMBER_SCI8_RXI) .rxi_irq = VECTOR_NUMBER_SCI8_RXI, #else .rxi_irq = FSP_INVALID_VECTOR, #endif #if defined(VECTOR_NUMBER_SCI8_TXI) .txi_irq = VECTOR_NUMBER_SCI8_TXI, #else .txi_irq = FSP_INVALID_VECTOR, #endif #if defined(VECTOR_NUMBER_SCI8_TEI) .tei_irq = VECTOR_NUMBER_SCI8_TEI, #else .tei_irq = FSP_INVALID_VECTOR, #endif #if defined(VECTOR_NUMBER_SCI8_ERI) .eri_irq = VECTOR_NUMBER_SCI8_ERI, #else .eri_irq = FSP_INVALID_VECTOR, #endif }; /* Instance structure to use this module. */ const uart_instance_t g_uart8 = { .p_ctrl = &g_uart8_ctrl, .p_cfg = &g_uart8_cfg, .p_api = &g_uart_on_sci }; sci_uart_instance_ctrl_t g_uart2_ctrl; baud_setting_t g_uart2_baud_setting = { /* Baud rate calculated with 0.160% error. */ .abcse = 0, .abcs = 0, .bgdm = 1, .cks = 0, .brr = 64, .mddr = (uint8_t)256, .brme = false }; /** UART extended configuration for UARTonSCI HAL driver */ const sci_uart_extended_cfg_t g_uart2_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_uart2_baud_setting, .uart_mode = UART_MODE_RS232, .ctsrts_en = SCI_UART_CTSRTS_RTS_OUTPUT, #if 0 .flow_control_pin = BSP_IO_PORT_00_PIN_00, #else .flow_control_pin = (bsp_io_port_pin_t)(0xFFFFU), #endif }; /** UART interface configuration */ const uart_cfg_t g_uart2_cfg = { .channel = 2, .data_bits = UART_DATA_BITS_8, .parity = UART_PARITY_OFF, .stop_bits = UART_STOP_BITS_1, .p_callback = user_uart_callback, .p_context = NULL, .p_extend = &g_uart2_cfg_extend, #define RA_NOT_DEFINED (1) #if (RA_NOT_DEFINED == RA_NOT_DEFINED) .p_transfer_tx = NULL, #else .p_transfer_tx = &RA_NOT_DEFINED, #endif #if (RA_NOT_DEFINED == RA_NOT_DEFINED) .p_transfer_rx = NULL, #else .p_transfer_rx = &RA_NOT_DEFINED, #endif #undef RA_NOT_DEFINED .rxi_ipl = (12), .txi_ipl = (12), .tei_ipl = (12), .eri_ipl = (12), #if defined(VECTOR_NUMBER_SCI2_RXI) .rxi_irq = VECTOR_NUMBER_SCI2_RXI, #else .rxi_irq = FSP_INVALID_VECTOR, #endif #if defined(VECTOR_NUMBER_SCI2_TXI) .txi_irq = VECTOR_NUMBER_SCI2_TXI, #else .txi_irq = FSP_INVALID_VECTOR, #endif #if defined(VECTOR_NUMBER_SCI2_TEI) .tei_irq = VECTOR_NUMBER_SCI2_TEI, #else .tei_irq = FSP_INVALID_VECTOR, #endif #if defined(VECTOR_NUMBER_SCI2_ERI) .eri_irq = VECTOR_NUMBER_SCI2_ERI, #else .eri_irq = FSP_INVALID_VECTOR, #endif }; /* Instance structure to use this module. */ const uart_instance_t g_uart2 = { .p_ctrl = &g_uart2_ctrl, .p_cfg = &g_uart2_cfg, .p_api = &g_uart_on_sci }; sci_uart_instance_ctrl_t g_uart0_ctrl; baud_setting_t g_uart0_baud_setting = { /* Baud rate calculated with 0.160% error. */ .abcse = 0, .abcs = 0, .bgdm = 1, .cks = 0, .brr = 64, .mddr = (uint8_t)256, .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, .uart_mode = UART_MODE_RS232, .ctsrts_en = SCI_UART_CTSRTS_RTS_OUTPUT, #if 0 .flow_control_pin = BSP_IO_PORT_00_PIN_00, #else .flow_control_pin = (bsp_io_port_pin_t)(0xFFFFU), #endif }; /** 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_uart_callback, .p_context = NULL, .p_extend = &g_uart0_cfg_extend, #define RA_NOT_DEFINED (1) #if (RA_NOT_DEFINED == RA_NOT_DEFINED) .p_transfer_tx = NULL, #else .p_transfer_tx = &RA_NOT_DEFINED, #endif #if (RA_NOT_DEFINED == RA_NOT_DEFINED) .p_transfer_rx = NULL, #else .p_transfer_rx = &RA_NOT_DEFINED, #endif #undef RA_NOT_DEFINED .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(); }