/* * Copyright (c) 2012 - 2019, Nordic Semiconductor ASA * 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 a Nordic * Semiconductor ASA 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 Nordic Semiconductor ASA 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 * Nordic Semiconductor ASA 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 NORDIC SEMICONDUCTOR ASA "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 NORDIC SEMICONDUCTOR ASA 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. */ pub type c_schar = i8; pub type c_uchar = u8; pub type c_char = u8; pub type c_short = i16; pub type c_ushort = u16; pub type c_int = i32; pub type c_uint = u32; pub type c_long = i32; pub type c_ulong = u32; pub type c_longlong = i64; pub type c_ulonglong = u64; pub type c_void = core::ffi::c_void; trait ToAsm { fn to_asm(self) -> u32; } fn to_asm(t: T) -> u32 { t.to_asm() } impl ToAsm for u32 { fn to_asm(self) -> u32 { self } } impl ToAsm for u16 { fn to_asm(self) -> u32 { self as u32 } } impl ToAsm for u8 { fn to_asm(self) -> u32 { self as u32 } } impl ToAsm for i8 { fn to_asm(self) -> u32 { self as u32 } } impl ToAsm for *const T { fn to_asm(self) -> u32 { self as u32 } } impl ToAsm for *mut T { fn to_asm(self) -> u32 { self as u32 } } impl ToAsm for Option { fn to_asm(self) -> u32 { match self { Some(x) => x.to_asm(), None => 0, } } } impl ToAsm for unsafe extern "C" fn(X) -> R { fn to_asm(self) -> u32 { self as u32 } } impl ToAsm for unsafe extern "C" fn(X, Y) -> R { fn to_asm(self) -> u32 { self as u32 } } impl ToAsm for unsafe extern "C" fn(X, Y, Z) -> R { fn to_asm(self) -> u32 { self as u32 } } /* automatically generated by rust-bindgen 0.55.1 */ #[repr(C)] #[derive(Copy, Clone, Debug, Default, Eq, Hash, Ord, PartialEq, PartialOrd)] pub struct __BindgenBitfieldUnit { storage: Storage, align: [Align; 0], } impl __BindgenBitfieldUnit { #[inline] pub const fn new(storage: Storage) -> Self { Self { storage, align: [] } } } impl __BindgenBitfieldUnit where Storage: AsRef<[u8]> + AsMut<[u8]>, { #[inline] pub fn get_bit(&self, index: usize) -> bool { debug_assert!(index / 8 < self.storage.as_ref().len()); let byte_index = index / 8; let byte = self.storage.as_ref()[byte_index]; let bit_index = if cfg!(target_endian = "big") { 7 - (index % 8) } else { index % 8 }; let mask = 1 << bit_index; byte & mask == mask } #[inline] pub fn set_bit(&mut self, index: usize, val: bool) { debug_assert!(index / 8 < self.storage.as_ref().len()); let byte_index = index / 8; let byte = &mut self.storage.as_mut()[byte_index]; let bit_index = if cfg!(target_endian = "big") { 7 - (index % 8) } else { index % 8 }; let mask = 1 << bit_index; if val { *byte |= mask; } else { *byte &= !mask; } } #[inline] pub fn get(&self, bit_offset: usize, bit_width: u8) -> u64 { debug_assert!(bit_width <= 64); debug_assert!(bit_offset / 8 < self.storage.as_ref().len()); debug_assert!((bit_offset + (bit_width as usize)) / 8 <= self.storage.as_ref().len()); let mut val = 0; for i in 0..(bit_width as usize) { if self.get_bit(i + bit_offset) { let index = if cfg!(target_endian = "big") { bit_width as usize - 1 - i } else { i }; val |= 1 << index; } } val } #[inline] pub fn set(&mut self, bit_offset: usize, bit_width: u8, val: u64) { debug_assert!(bit_width <= 64); debug_assert!(bit_offset / 8 < self.storage.as_ref().len()); debug_assert!((bit_offset + (bit_width as usize)) / 8 <= self.storage.as_ref().len()); for i in 0..(bit_width as usize) { let mask = 1 << i; let val_bit_is_set = val & mask == mask; let index = if cfg!(target_endian = "big") { bit_width as usize - 1 - i } else { i }; self.set_bit(index + bit_offset, val_bit_is_set); } } } #[repr(C)] #[derive(Default)] pub struct __IncompleteArrayField(::core::marker::PhantomData, [T; 0]); impl __IncompleteArrayField { #[inline] pub const fn new() -> Self { __IncompleteArrayField(::core::marker::PhantomData, []) } #[inline] pub fn as_ptr(&self) -> *const T { self as *const _ as *const T } #[inline] pub fn as_mut_ptr(&mut self) -> *mut T { self as *mut _ as *mut T } #[inline] pub unsafe fn as_slice(&self, len: usize) -> &[T] { ::core::slice::from_raw_parts(self.as_ptr(), len) } #[inline] pub unsafe fn as_mut_slice(&mut self, len: usize) -> &mut [T] { ::core::slice::from_raw_parts_mut(self.as_mut_ptr(), len) } } impl ::core::fmt::Debug for __IncompleteArrayField { fn fmt(&self, fmt: &mut ::core::fmt::Formatter<'_>) -> ::core::fmt::Result { fmt.write_str("__IncompleteArrayField") } } #[repr(C)] pub struct __BindgenUnionField(::core::marker::PhantomData); impl __BindgenUnionField { #[inline] pub const fn new() -> Self { __BindgenUnionField(::core::marker::PhantomData) } #[inline] pub unsafe fn as_ref(&self) -> &T { ::core::mem::transmute(self) } #[inline] pub unsafe fn as_mut(&mut self) -> &mut T { ::core::mem::transmute(self) } } impl ::core::default::Default for __BindgenUnionField { #[inline] fn default() -> Self { Self::new() } } impl ::core::clone::Clone for __BindgenUnionField { #[inline] fn clone(&self) -> Self { Self::new() } } impl ::core::marker::Copy for __BindgenUnionField {} impl ::core::fmt::Debug for __BindgenUnionField { fn fmt(&self, fmt: &mut ::core::fmt::Formatter<'_>) -> ::core::fmt::Result { fmt.write_str("__BindgenUnionField") } } impl ::core::hash::Hash for __BindgenUnionField { fn hash(&self, _state: &mut H) {} } impl ::core::cmp::PartialEq for __BindgenUnionField { fn eq(&self, _other: &__BindgenUnionField) -> bool { true } } impl ::core::cmp::Eq for __BindgenUnionField {} pub const NRF_ERROR_BASE_NUM: u32 = 0; pub const NRF_ERROR_SDM_BASE_NUM: u32 = 4096; pub const NRF_ERROR_SOC_BASE_NUM: u32 = 8192; pub const NRF_ERROR_STK_BASE_NUM: u32 = 12288; pub const NRF_SUCCESS: u32 = 0; pub const NRF_ERROR_SVC_HANDLER_MISSING: u32 = 1; pub const NRF_ERROR_SOFTDEVICE_NOT_ENABLED: u32 = 2; pub const NRF_ERROR_INTERNAL: u32 = 3; pub const NRF_ERROR_NO_MEM: u32 = 4; pub const NRF_ERROR_NOT_FOUND: u32 = 5; pub const NRF_ERROR_NOT_SUPPORTED: u32 = 6; pub const NRF_ERROR_INVALID_PARAM: u32 = 7; pub const NRF_ERROR_INVALID_STATE: u32 = 8; pub const NRF_ERROR_INVALID_LENGTH: u32 = 9; pub const NRF_ERROR_INVALID_FLAGS: u32 = 10; pub const NRF_ERROR_INVALID_DATA: u32 = 11; pub const NRF_ERROR_DATA_SIZE: u32 = 12; pub const NRF_ERROR_TIMEOUT: u32 = 13; pub const NRF_ERROR_NULL: u32 = 14; pub const NRF_ERROR_FORBIDDEN: u32 = 15; pub const NRF_ERROR_INVALID_ADDR: u32 = 16; pub const NRF_ERROR_BUSY: u32 = 17; pub const NRF_ERROR_CONN_COUNT: u32 = 18; pub const NRF_ERROR_RESOURCES: u32 = 19; pub const NRF_ERROR_SDM_LFCLK_SOURCE_UNKNOWN: u32 = 4096; pub const NRF_ERROR_SDM_INCORRECT_INTERRUPT_CONFIGURATION: u32 = 4097; pub const NRF_ERROR_SDM_INCORRECT_CLENR0: u32 = 4098; pub const BLE_ERROR_NOT_ENABLED: u32 = 12289; pub const BLE_ERROR_INVALID_CONN_HANDLE: u32 = 12290; pub const BLE_ERROR_INVALID_ATTR_HANDLE: u32 = 12291; pub const BLE_ERROR_INVALID_ADV_HANDLE: u32 = 12292; pub const BLE_ERROR_INVALID_ROLE: u32 = 12293; pub const BLE_ERROR_BLOCKED_BY_OTHER_LINKS: u32 = 12294; pub const NRF_L2CAP_ERR_BASE: u32 = 12544; pub const NRF_GAP_ERR_BASE: u32 = 12800; pub const NRF_GATTC_ERR_BASE: u32 = 13056; pub const NRF_GATTS_ERR_BASE: u32 = 13312; pub const NRF_ERROR_SOC_MUTEX_ALREADY_TAKEN: u32 = 8192; pub const NRF_ERROR_SOC_NVIC_INTERRUPT_NOT_AVAILABLE: u32 = 8193; pub const NRF_ERROR_SOC_NVIC_INTERRUPT_PRIORITY_NOT_ALLOWED: u32 = 8194; pub const NRF_ERROR_SOC_NVIC_SHOULD_NOT_RETURN: u32 = 8195; pub const NRF_ERROR_SOC_POWER_MODE_UNKNOWN: u32 = 8196; pub const NRF_ERROR_SOC_POWER_POF_THRESHOLD_UNKNOWN: u32 = 8197; pub const NRF_ERROR_SOC_POWER_OFF_SHOULD_NOT_RETURN: u32 = 8198; pub const NRF_ERROR_SOC_RAND_NOT_ENOUGH_VALUES: u32 = 8199; pub const NRF_ERROR_SOC_PPI_INVALID_CHANNEL: u32 = 8200; pub const NRF_ERROR_SOC_PPI_INVALID_GROUP: u32 = 8201; pub const SOC_SVC_BASE: u32 = 32; pub const SOC_SVC_BASE_NOT_AVAILABLE: u32 = 44; pub const NRF_RADIO_NOTIFICATION_INACTIVE_GUARANTEED_TIME_US: u32 = 62; pub const NRF_RADIO_MINIMUM_TIMESLOT_LENGTH_EXTENSION_TIME_US: u32 = 200; pub const NRF_RADIO_MAX_EXTENSION_PROCESSING_TIME_US: u32 = 20; pub const NRF_RADIO_MIN_EXTENSION_MARGIN_US: u32 = 82; pub const SOC_ECB_KEY_LENGTH: u32 = 16; pub const SOC_ECB_CLEARTEXT_LENGTH: u32 = 16; pub const SOC_ECB_CIPHERTEXT_LENGTH: u32 = 16; pub const NRF_RADIO_LENGTH_MIN_US: u32 = 100; pub const NRF_RADIO_LENGTH_MAX_US: u32 = 100000; pub const NRF_RADIO_DISTANCE_MAX_US: u32 = 127999999; pub const NRF_RADIO_EARLIEST_TIMEOUT_MAX_US: u32 = 127999999; pub const NRF_RADIO_START_JITTER_US: u32 = 2; pub const SD_MAJOR_VERSION: u32 = 7; pub const SD_MINOR_VERSION: u32 = 0; pub const SD_BUGFIX_VERSION: u32 = 1; pub const SD_VARIANT_ID: u32 = 140; pub const SD_VERSION: u32 = 7000001; pub const SDM_SVC_BASE: u32 = 16; pub const SD_UNIQUE_STR_SIZE: u32 = 20; pub const SDM_INFO_FIELD_INVALID: u32 = 0; pub const SOFTDEVICE_INFO_STRUCT_OFFSET: u32 = 8192; pub const SD_INFO_STRUCT_SIZE_OFFSET: u32 = 8192; pub const SD_SIZE_OFFSET: u32 = 8200; pub const SD_FWID_OFFSET: u32 = 8204; pub const SD_ID_OFFSET: u32 = 8208; pub const SD_VERSION_OFFSET: u32 = 8212; pub const SD_UNIQUE_STR_OFFSET: u32 = 8216; pub const SD_FLASH_SIZE: u32 = 155648; pub const NRF_FAULT_ID_SD_RANGE_START: u32 = 0; pub const NRF_FAULT_ID_APP_RANGE_START: u32 = 4096; pub const NRF_FAULT_ID_SD_ASSERT: u32 = 1; pub const NRF_FAULT_ID_APP_MEMACC: u32 = 4097; pub const NRF_CLOCK_LF_ACCURACY_250_PPM: u32 = 0; pub const NRF_CLOCK_LF_ACCURACY_500_PPM: u32 = 1; pub const NRF_CLOCK_LF_ACCURACY_150_PPM: u32 = 2; pub const NRF_CLOCK_LF_ACCURACY_100_PPM: u32 = 3; pub const NRF_CLOCK_LF_ACCURACY_75_PPM: u32 = 4; pub const NRF_CLOCK_LF_ACCURACY_50_PPM: u32 = 5; pub const NRF_CLOCK_LF_ACCURACY_30_PPM: u32 = 6; pub const NRF_CLOCK_LF_ACCURACY_20_PPM: u32 = 7; pub const NRF_CLOCK_LF_ACCURACY_10_PPM: u32 = 8; pub const NRF_CLOCK_LF_ACCURACY_5_PPM: u32 = 9; pub const NRF_CLOCK_LF_ACCURACY_2_PPM: u32 = 10; pub const NRF_CLOCK_LF_ACCURACY_1_PPM: u32 = 11; pub const NRF_CLOCK_LF_SRC_RC: u32 = 0; pub const NRF_CLOCK_LF_SRC_XTAL: u32 = 1; pub const NRF_CLOCK_LF_SRC_SYNTH: u32 = 2; pub const BLE_HCI_STATUS_CODE_SUCCESS: u32 = 0; pub const BLE_HCI_STATUS_CODE_UNKNOWN_BTLE_COMMAND: u32 = 1; pub const BLE_HCI_STATUS_CODE_UNKNOWN_CONNECTION_IDENTIFIER: u32 = 2; pub const BLE_HCI_AUTHENTICATION_FAILURE: u32 = 5; pub const BLE_HCI_STATUS_CODE_PIN_OR_KEY_MISSING: u32 = 6; pub const BLE_HCI_MEMORY_CAPACITY_EXCEEDED: u32 = 7; pub const BLE_HCI_CONNECTION_TIMEOUT: u32 = 8; pub const BLE_HCI_STATUS_CODE_COMMAND_DISALLOWED: u32 = 12; pub const BLE_HCI_STATUS_CODE_INVALID_BTLE_COMMAND_PARAMETERS: u32 = 18; pub const BLE_HCI_REMOTE_USER_TERMINATED_CONNECTION: u32 = 19; pub const BLE_HCI_REMOTE_DEV_TERMINATION_DUE_TO_LOW_RESOURCES: u32 = 20; pub const BLE_HCI_REMOTE_DEV_TERMINATION_DUE_TO_POWER_OFF: u32 = 21; pub const BLE_HCI_LOCAL_HOST_TERMINATED_CONNECTION: u32 = 22; pub const BLE_HCI_UNSUPPORTED_REMOTE_FEATURE: u32 = 26; pub const BLE_HCI_STATUS_CODE_INVALID_LMP_PARAMETERS: u32 = 30; pub const BLE_HCI_STATUS_CODE_UNSPECIFIED_ERROR: u32 = 31; pub const BLE_HCI_STATUS_CODE_LMP_RESPONSE_TIMEOUT: u32 = 34; pub const BLE_HCI_STATUS_CODE_LMP_ERROR_TRANSACTION_COLLISION: u32 = 35; pub const BLE_HCI_STATUS_CODE_LMP_PDU_NOT_ALLOWED: u32 = 36; pub const BLE_HCI_INSTANT_PASSED: u32 = 40; pub const BLE_HCI_PAIRING_WITH_UNIT_KEY_UNSUPPORTED: u32 = 41; pub const BLE_HCI_DIFFERENT_TRANSACTION_COLLISION: u32 = 42; pub const BLE_HCI_PARAMETER_OUT_OF_MANDATORY_RANGE: u32 = 48; pub const BLE_HCI_CONTROLLER_BUSY: u32 = 58; pub const BLE_HCI_CONN_INTERVAL_UNACCEPTABLE: u32 = 59; pub const BLE_HCI_DIRECTED_ADVERTISER_TIMEOUT: u32 = 60; pub const BLE_HCI_CONN_TERMINATED_DUE_TO_MIC_FAILURE: u32 = 61; pub const BLE_HCI_CONN_FAILED_TO_BE_ESTABLISHED: u32 = 62; pub const BLE_SVC_BASE: u32 = 96; pub const BLE_SVC_LAST: u32 = 107; pub const BLE_GAP_SVC_BASE: u32 = 108; pub const BLE_GAP_SVC_LAST: u32 = 154; pub const BLE_GATTC_SVC_BASE: u32 = 155; pub const BLE_GATTC_SVC_LAST: u32 = 167; pub const BLE_GATTS_SVC_BASE: u32 = 168; pub const BLE_GATTS_SVC_LAST: u32 = 183; pub const BLE_L2CAP_SVC_BASE: u32 = 184; pub const BLE_L2CAP_SVC_LAST: u32 = 191; pub const BLE_EVT_INVALID: u32 = 0; pub const BLE_EVT_BASE: u32 = 1; pub const BLE_EVT_LAST: u32 = 15; pub const BLE_GAP_EVT_BASE: u32 = 16; pub const BLE_GAP_EVT_LAST: u32 = 47; pub const BLE_GATTC_EVT_BASE: u32 = 48; pub const BLE_GATTC_EVT_LAST: u32 = 79; pub const BLE_GATTS_EVT_BASE: u32 = 80; pub const BLE_GATTS_EVT_LAST: u32 = 111; pub const BLE_L2CAP_EVT_BASE: u32 = 112; pub const BLE_L2CAP_EVT_LAST: u32 = 143; pub const BLE_OPT_INVALID: u32 = 0; pub const BLE_OPT_BASE: u32 = 1; pub const BLE_OPT_LAST: u32 = 31; pub const BLE_GAP_OPT_BASE: u32 = 32; pub const BLE_GAP_OPT_LAST: u32 = 63; pub const BLE_GATT_OPT_BASE: u32 = 64; pub const BLE_GATT_OPT_LAST: u32 = 95; pub const BLE_GATTC_OPT_BASE: u32 = 96; pub const BLE_GATTC_OPT_LAST: u32 = 127; pub const BLE_GATTS_OPT_BASE: u32 = 128; pub const BLE_GATTS_OPT_LAST: u32 = 159; pub const BLE_L2CAP_OPT_BASE: u32 = 160; pub const BLE_L2CAP_OPT_LAST: u32 = 191; pub const BLE_CFG_INVALID: u32 = 0; pub const BLE_CFG_BASE: u32 = 1; pub const BLE_CFG_LAST: u32 = 31; pub const BLE_CONN_CFG_BASE: u32 = 32; pub const BLE_CONN_CFG_LAST: u32 = 63; pub const BLE_GAP_CFG_BASE: u32 = 64; pub const BLE_GAP_CFG_LAST: u32 = 95; pub const BLE_GATT_CFG_BASE: u32 = 96; pub const BLE_GATT_CFG_LAST: u32 = 127; pub const BLE_GATTC_CFG_BASE: u32 = 128; pub const BLE_GATTC_CFG_LAST: u32 = 159; pub const BLE_GATTS_CFG_BASE: u32 = 160; pub const BLE_GATTS_CFG_LAST: u32 = 191; pub const BLE_L2CAP_CFG_BASE: u32 = 192; pub const BLE_L2CAP_CFG_LAST: u32 = 223; pub const BLE_CONN_HANDLE_INVALID: u32 = 65535; pub const BLE_CONN_HANDLE_ALL: u32 = 65534; pub const BLE_UUID_UNKNOWN: u32 = 0; pub const BLE_UUID_SERVICE_PRIMARY: u32 = 10240; pub const BLE_UUID_SERVICE_SECONDARY: u32 = 10241; pub const BLE_UUID_SERVICE_INCLUDE: u32 = 10242; pub const BLE_UUID_CHARACTERISTIC: u32 = 10243; pub const BLE_UUID_DESCRIPTOR_CHAR_EXT_PROP: u32 = 10496; pub const BLE_UUID_DESCRIPTOR_CHAR_USER_DESC: u32 = 10497; pub const BLE_UUID_DESCRIPTOR_CLIENT_CHAR_CONFIG: u32 = 10498; pub const BLE_UUID_DESCRIPTOR_SERVER_CHAR_CONFIG: u32 = 10499; pub const BLE_UUID_DESCRIPTOR_CHAR_PRESENTATION_FORMAT: u32 = 10500; pub const BLE_UUID_DESCRIPTOR_CHAR_AGGREGATE_FORMAT: u32 = 10501; pub const BLE_UUID_GATT: u32 = 6145; pub const BLE_UUID_GATT_CHARACTERISTIC_SERVICE_CHANGED: u32 = 10757; pub const BLE_UUID_GAP: u32 = 6144; pub const BLE_UUID_GAP_CHARACTERISTIC_DEVICE_NAME: u32 = 10752; pub const BLE_UUID_GAP_CHARACTERISTIC_APPEARANCE: u32 = 10753; pub const BLE_UUID_GAP_CHARACTERISTIC_RECONN_ADDR: u32 = 10755; pub const BLE_UUID_GAP_CHARACTERISTIC_PPCP: u32 = 10756; pub const BLE_UUID_GAP_CHARACTERISTIC_CAR: u32 = 10918; pub const BLE_UUID_GAP_CHARACTERISTIC_RPA_ONLY: u32 = 10953; pub const BLE_UUID_TYPE_UNKNOWN: u32 = 0; pub const BLE_UUID_TYPE_BLE: u32 = 1; pub const BLE_UUID_TYPE_VENDOR_BEGIN: u32 = 2; pub const BLE_APPEARANCE_UNKNOWN: u32 = 0; pub const BLE_APPEARANCE_GENERIC_PHONE: u32 = 64; pub const BLE_APPEARANCE_GENERIC_COMPUTER: u32 = 128; pub const BLE_APPEARANCE_GENERIC_WATCH: u32 = 192; pub const BLE_APPEARANCE_WATCH_SPORTS_WATCH: u32 = 193; pub const BLE_APPEARANCE_GENERIC_CLOCK: u32 = 256; pub const BLE_APPEARANCE_GENERIC_DISPLAY: u32 = 320; pub const BLE_APPEARANCE_GENERIC_REMOTE_CONTROL: u32 = 384; pub const BLE_APPEARANCE_GENERIC_EYE_GLASSES: u32 = 448; pub const BLE_APPEARANCE_GENERIC_TAG: u32 = 512; pub const BLE_APPEARANCE_GENERIC_KEYRING: u32 = 576; pub const BLE_APPEARANCE_GENERIC_MEDIA_PLAYER: u32 = 640; pub const BLE_APPEARANCE_GENERIC_BARCODE_SCANNER: u32 = 704; pub const BLE_APPEARANCE_GENERIC_THERMOMETER: u32 = 768; pub const BLE_APPEARANCE_THERMOMETER_EAR: u32 = 769; pub const BLE_APPEARANCE_GENERIC_HEART_RATE_SENSOR: u32 = 832; pub const BLE_APPEARANCE_HEART_RATE_SENSOR_HEART_RATE_BELT: u32 = 833; pub const BLE_APPEARANCE_GENERIC_BLOOD_PRESSURE: u32 = 896; pub const BLE_APPEARANCE_BLOOD_PRESSURE_ARM: u32 = 897; pub const BLE_APPEARANCE_BLOOD_PRESSURE_WRIST: u32 = 898; pub const BLE_APPEARANCE_GENERIC_HID: u32 = 960; pub const BLE_APPEARANCE_HID_KEYBOARD: u32 = 961; pub const BLE_APPEARANCE_HID_MOUSE: u32 = 962; pub const BLE_APPEARANCE_HID_JOYSTICK: u32 = 963; pub const BLE_APPEARANCE_HID_GAMEPAD: u32 = 964; pub const BLE_APPEARANCE_HID_DIGITIZERSUBTYPE: u32 = 965; pub const BLE_APPEARANCE_HID_CARD_READER: u32 = 966; pub const BLE_APPEARANCE_HID_DIGITAL_PEN: u32 = 967; pub const BLE_APPEARANCE_HID_BARCODE: u32 = 968; pub const BLE_APPEARANCE_GENERIC_GLUCOSE_METER: u32 = 1024; pub const BLE_APPEARANCE_GENERIC_RUNNING_WALKING_SENSOR: u32 = 1088; pub const BLE_APPEARANCE_RUNNING_WALKING_SENSOR_IN_SHOE: u32 = 1089; pub const BLE_APPEARANCE_RUNNING_WALKING_SENSOR_ON_SHOE: u32 = 1090; pub const BLE_APPEARANCE_RUNNING_WALKING_SENSOR_ON_HIP: u32 = 1091; pub const BLE_APPEARANCE_GENERIC_CYCLING: u32 = 1152; pub const BLE_APPEARANCE_CYCLING_CYCLING_COMPUTER: u32 = 1153; pub const BLE_APPEARANCE_CYCLING_SPEED_SENSOR: u32 = 1154; pub const BLE_APPEARANCE_CYCLING_CADENCE_SENSOR: u32 = 1155; pub const BLE_APPEARANCE_CYCLING_POWER_SENSOR: u32 = 1156; pub const BLE_APPEARANCE_CYCLING_SPEED_CADENCE_SENSOR: u32 = 1157; pub const BLE_APPEARANCE_GENERIC_PULSE_OXIMETER: u32 = 3136; pub const BLE_APPEARANCE_PULSE_OXIMETER_FINGERTIP: u32 = 3137; pub const BLE_APPEARANCE_PULSE_OXIMETER_WRIST_WORN: u32 = 3138; pub const BLE_APPEARANCE_GENERIC_WEIGHT_SCALE: u32 = 3200; pub const BLE_APPEARANCE_GENERIC_OUTDOOR_SPORTS_ACT: u32 = 5184; pub const BLE_APPEARANCE_OUTDOOR_SPORTS_ACT_LOC_DISP: u32 = 5185; pub const BLE_APPEARANCE_OUTDOOR_SPORTS_ACT_LOC_AND_NAV_DISP: u32 = 5186; pub const BLE_APPEARANCE_OUTDOOR_SPORTS_ACT_LOC_POD: u32 = 5187; pub const BLE_APPEARANCE_OUTDOOR_SPORTS_ACT_LOC_AND_NAV_POD: u32 = 5188; pub const BLE_GATT_ATT_MTU_DEFAULT: u32 = 23; pub const BLE_GATT_HANDLE_INVALID: u32 = 0; pub const BLE_GATT_HANDLE_START: u32 = 1; pub const BLE_GATT_HANDLE_END: u32 = 65535; pub const BLE_GATT_TIMEOUT_SRC_PROTOCOL: u32 = 0; pub const BLE_GATT_OP_INVALID: u32 = 0; pub const BLE_GATT_OP_WRITE_REQ: u32 = 1; pub const BLE_GATT_OP_WRITE_CMD: u32 = 2; pub const BLE_GATT_OP_SIGN_WRITE_CMD: u32 = 3; pub const BLE_GATT_OP_PREP_WRITE_REQ: u32 = 4; pub const BLE_GATT_OP_EXEC_WRITE_REQ: u32 = 5; pub const BLE_GATT_EXEC_WRITE_FLAG_PREPARED_CANCEL: u32 = 0; pub const BLE_GATT_EXEC_WRITE_FLAG_PREPARED_WRITE: u32 = 1; pub const BLE_GATT_HVX_INVALID: u32 = 0; pub const BLE_GATT_HVX_NOTIFICATION: u32 = 1; pub const BLE_GATT_HVX_INDICATION: u32 = 2; pub const BLE_GATT_STATUS_SUCCESS: u32 = 0; pub const BLE_GATT_STATUS_UNKNOWN: u32 = 1; pub const BLE_GATT_STATUS_ATTERR_INVALID: u32 = 256; pub const BLE_GATT_STATUS_ATTERR_INVALID_HANDLE: u32 = 257; pub const BLE_GATT_STATUS_ATTERR_READ_NOT_PERMITTED: u32 = 258; pub const BLE_GATT_STATUS_ATTERR_WRITE_NOT_PERMITTED: u32 = 259; pub const BLE_GATT_STATUS_ATTERR_INVALID_PDU: u32 = 260; pub const BLE_GATT_STATUS_ATTERR_INSUF_AUTHENTICATION: u32 = 261; pub const BLE_GATT_STATUS_ATTERR_REQUEST_NOT_SUPPORTED: u32 = 262; pub const BLE_GATT_STATUS_ATTERR_INVALID_OFFSET: u32 = 263; pub const BLE_GATT_STATUS_ATTERR_INSUF_AUTHORIZATION: u32 = 264; pub const BLE_GATT_STATUS_ATTERR_PREPARE_QUEUE_FULL: u32 = 265; pub const BLE_GATT_STATUS_ATTERR_ATTRIBUTE_NOT_FOUND: u32 = 266; pub const BLE_GATT_STATUS_ATTERR_ATTRIBUTE_NOT_LONG: u32 = 267; pub const BLE_GATT_STATUS_ATTERR_INSUF_ENC_KEY_SIZE: u32 = 268; pub const BLE_GATT_STATUS_ATTERR_INVALID_ATT_VAL_LENGTH: u32 = 269; pub const BLE_GATT_STATUS_ATTERR_UNLIKELY_ERROR: u32 = 270; pub const BLE_GATT_STATUS_ATTERR_INSUF_ENCRYPTION: u32 = 271; pub const BLE_GATT_STATUS_ATTERR_UNSUPPORTED_GROUP_TYPE: u32 = 272; pub const BLE_GATT_STATUS_ATTERR_INSUF_RESOURCES: u32 = 273; pub const BLE_GATT_STATUS_ATTERR_RFU_RANGE1_BEGIN: u32 = 274; pub const BLE_GATT_STATUS_ATTERR_RFU_RANGE1_END: u32 = 383; pub const BLE_GATT_STATUS_ATTERR_APP_BEGIN: u32 = 384; pub const BLE_GATT_STATUS_ATTERR_APP_END: u32 = 415; pub const BLE_GATT_STATUS_ATTERR_RFU_RANGE2_BEGIN: u32 = 416; pub const BLE_GATT_STATUS_ATTERR_RFU_RANGE2_END: u32 = 479; pub const BLE_GATT_STATUS_ATTERR_RFU_RANGE3_BEGIN: u32 = 480; pub const BLE_GATT_STATUS_ATTERR_RFU_RANGE3_END: u32 = 508; pub const BLE_GATT_STATUS_ATTERR_CPS_WRITE_REQ_REJECTED: u32 = 508; pub const BLE_GATT_STATUS_ATTERR_CPS_CCCD_CONFIG_ERROR: u32 = 509; pub const BLE_GATT_STATUS_ATTERR_CPS_PROC_ALR_IN_PROG: u32 = 510; pub const BLE_GATT_STATUS_ATTERR_CPS_OUT_OF_RANGE: u32 = 511; pub const BLE_GATT_CPF_FORMAT_RFU: u32 = 0; pub const BLE_GATT_CPF_FORMAT_BOOLEAN: u32 = 1; pub const BLE_GATT_CPF_FORMAT_2BIT: u32 = 2; pub const BLE_GATT_CPF_FORMAT_NIBBLE: u32 = 3; pub const BLE_GATT_CPF_FORMAT_UINT8: u32 = 4; pub const BLE_GATT_CPF_FORMAT_UINT12: u32 = 5; pub const BLE_GATT_CPF_FORMAT_UINT16: u32 = 6; pub const BLE_GATT_CPF_FORMAT_UINT24: u32 = 7; pub const BLE_GATT_CPF_FORMAT_UINT32: u32 = 8; pub const BLE_GATT_CPF_FORMAT_UINT48: u32 = 9; pub const BLE_GATT_CPF_FORMAT_UINT64: u32 = 10; pub const BLE_GATT_CPF_FORMAT_UINT128: u32 = 11; pub const BLE_GATT_CPF_FORMAT_SINT8: u32 = 12; pub const BLE_GATT_CPF_FORMAT_SINT12: u32 = 13; pub const BLE_GATT_CPF_FORMAT_SINT16: u32 = 14; pub const BLE_GATT_CPF_FORMAT_SINT24: u32 = 15; pub const BLE_GATT_CPF_FORMAT_SINT32: u32 = 16; pub const BLE_GATT_CPF_FORMAT_SINT48: u32 = 17; pub const BLE_GATT_CPF_FORMAT_SINT64: u32 = 18; pub const BLE_GATT_CPF_FORMAT_SINT128: u32 = 19; pub const BLE_GATT_CPF_FORMAT_FLOAT32: u32 = 20; pub const BLE_GATT_CPF_FORMAT_FLOAT64: u32 = 21; pub const BLE_GATT_CPF_FORMAT_SFLOAT: u32 = 22; pub const BLE_GATT_CPF_FORMAT_FLOAT: u32 = 23; pub const BLE_GATT_CPF_FORMAT_DUINT16: u32 = 24; pub const BLE_GATT_CPF_FORMAT_UTF8S: u32 = 25; pub const BLE_GATT_CPF_FORMAT_UTF16S: u32 = 26; pub const BLE_GATT_CPF_FORMAT_STRUCT: u32 = 27; pub const BLE_GATT_CPF_NAMESPACE_BTSIG: u32 = 1; pub const BLE_GATT_CPF_NAMESPACE_DESCRIPTION_UNKNOWN: u32 = 0; pub const MBR_SVC_BASE: u32 = 24; pub const MBR_PAGE_SIZE_IN_WORDS: u32 = 1024; pub const MBR_SIZE: u32 = 4096; pub const MBR_BOOTLOADER_ADDR: u32 = 4088; pub const MBR_PARAM_PAGE_ADDR: u32 = 4092; pub const BLE_ERROR_GAP_UUID_LIST_MISMATCH: u32 = 12800; pub const BLE_ERROR_GAP_DISCOVERABLE_WITH_WHITELIST: u32 = 12801; pub const BLE_ERROR_GAP_INVALID_BLE_ADDR: u32 = 12802; pub const BLE_ERROR_GAP_WHITELIST_IN_USE: u32 = 12803; pub const BLE_ERROR_GAP_DEVICE_IDENTITIES_IN_USE: u32 = 12804; pub const BLE_ERROR_GAP_DEVICE_IDENTITIES_DUPLICATE: u32 = 12805; pub const BLE_GAP_ROLE_INVALID: u32 = 0; pub const BLE_GAP_ROLE_PERIPH: u32 = 1; pub const BLE_GAP_ROLE_CENTRAL: u32 = 2; pub const BLE_GAP_TIMEOUT_SRC_SCAN: u32 = 1; pub const BLE_GAP_TIMEOUT_SRC_CONN: u32 = 2; pub const BLE_GAP_TIMEOUT_SRC_AUTH_PAYLOAD: u32 = 3; pub const BLE_GAP_ADDR_TYPE_PUBLIC: u32 = 0; pub const BLE_GAP_ADDR_TYPE_RANDOM_STATIC: u32 = 1; pub const BLE_GAP_ADDR_TYPE_RANDOM_PRIVATE_RESOLVABLE: u32 = 2; pub const BLE_GAP_ADDR_TYPE_RANDOM_PRIVATE_NON_RESOLVABLE: u32 = 3; pub const BLE_GAP_ADDR_TYPE_ANONYMOUS: u32 = 127; pub const BLE_GAP_DEFAULT_PRIVATE_ADDR_CYCLE_INTERVAL_S: u32 = 900; pub const BLE_GAP_MAX_PRIVATE_ADDR_CYCLE_INTERVAL_S: u32 = 41400; pub const BLE_GAP_ADDR_LEN: u32 = 6; pub const BLE_GAP_PRIVACY_MODE_OFF: u32 = 0; pub const BLE_GAP_PRIVACY_MODE_DEVICE_PRIVACY: u32 = 1; pub const BLE_GAP_PRIVACY_MODE_NETWORK_PRIVACY: u32 = 2; pub const BLE_GAP_POWER_LEVEL_INVALID: u32 = 127; pub const BLE_GAP_ADV_SET_HANDLE_NOT_SET: u32 = 255; pub const BLE_GAP_ADV_SET_COUNT_DEFAULT: u32 = 1; pub const BLE_GAP_ADV_SET_COUNT_MAX: u32 = 1; pub const BLE_GAP_ADV_SET_DATA_SIZE_MAX: u32 = 31; pub const BLE_GAP_ADV_SET_DATA_SIZE_EXTENDED_MAX_SUPPORTED: u32 = 255; pub const BLE_GAP_ADV_SET_DATA_SIZE_EXTENDED_CONNECTABLE_MAX_SUPPORTED: u32 = 238; pub const BLE_GAP_ADV_REPORT_SET_ID_NOT_AVAILABLE: u32 = 255; pub const BLE_GAP_EVT_ADV_SET_TERMINATED_REASON_TIMEOUT: u32 = 1; pub const BLE_GAP_EVT_ADV_SET_TERMINATED_REASON_LIMIT_REACHED: u32 = 2; pub const BLE_GAP_AD_TYPE_FLAGS: u32 = 1; pub const BLE_GAP_AD_TYPE_16BIT_SERVICE_UUID_MORE_AVAILABLE: u32 = 2; pub const BLE_GAP_AD_TYPE_16BIT_SERVICE_UUID_COMPLETE: u32 = 3; pub const BLE_GAP_AD_TYPE_32BIT_SERVICE_UUID_MORE_AVAILABLE: u32 = 4; pub const BLE_GAP_AD_TYPE_32BIT_SERVICE_UUID_COMPLETE: u32 = 5; pub const BLE_GAP_AD_TYPE_128BIT_SERVICE_UUID_MORE_AVAILABLE: u32 = 6; pub const BLE_GAP_AD_TYPE_128BIT_SERVICE_UUID_COMPLETE: u32 = 7; pub const BLE_GAP_AD_TYPE_SHORT_LOCAL_NAME: u32 = 8; pub const BLE_GAP_AD_TYPE_COMPLETE_LOCAL_NAME: u32 = 9; pub const BLE_GAP_AD_TYPE_TX_POWER_LEVEL: u32 = 10; pub const BLE_GAP_AD_TYPE_CLASS_OF_DEVICE: u32 = 13; pub const BLE_GAP_AD_TYPE_SIMPLE_PAIRING_HASH_C: u32 = 14; pub const BLE_GAP_AD_TYPE_SIMPLE_PAIRING_RANDOMIZER_R: u32 = 15; pub const BLE_GAP_AD_TYPE_SECURITY_MANAGER_TK_VALUE: u32 = 16; pub const BLE_GAP_AD_TYPE_SECURITY_MANAGER_OOB_FLAGS: u32 = 17; pub const BLE_GAP_AD_TYPE_SLAVE_CONNECTION_INTERVAL_RANGE: u32 = 18; pub const BLE_GAP_AD_TYPE_SOLICITED_SERVICE_UUIDS_16BIT: u32 = 20; pub const BLE_GAP_AD_TYPE_SOLICITED_SERVICE_UUIDS_128BIT: u32 = 21; pub const BLE_GAP_AD_TYPE_SERVICE_DATA: u32 = 22; pub const BLE_GAP_AD_TYPE_PUBLIC_TARGET_ADDRESS: u32 = 23; pub const BLE_GAP_AD_TYPE_RANDOM_TARGET_ADDRESS: u32 = 24; pub const BLE_GAP_AD_TYPE_APPEARANCE: u32 = 25; pub const BLE_GAP_AD_TYPE_ADVERTISING_INTERVAL: u32 = 26; pub const BLE_GAP_AD_TYPE_LE_BLUETOOTH_DEVICE_ADDRESS: u32 = 27; pub const BLE_GAP_AD_TYPE_LE_ROLE: u32 = 28; pub const BLE_GAP_AD_TYPE_SIMPLE_PAIRING_HASH_C256: u32 = 29; pub const BLE_GAP_AD_TYPE_SIMPLE_PAIRING_RANDOMIZER_R256: u32 = 30; pub const BLE_GAP_AD_TYPE_SERVICE_DATA_32BIT_UUID: u32 = 32; pub const BLE_GAP_AD_TYPE_SERVICE_DATA_128BIT_UUID: u32 = 33; pub const BLE_GAP_AD_TYPE_LESC_CONFIRMATION_VALUE: u32 = 34; pub const BLE_GAP_AD_TYPE_LESC_RANDOM_VALUE: u32 = 35; pub const BLE_GAP_AD_TYPE_URI: u32 = 36; pub const BLE_GAP_AD_TYPE_3D_INFORMATION_DATA: u32 = 61; pub const BLE_GAP_AD_TYPE_MANUFACTURER_SPECIFIC_DATA: u32 = 255; pub const BLE_GAP_ADV_FLAG_LE_LIMITED_DISC_MODE: u32 = 1; pub const BLE_GAP_ADV_FLAG_LE_GENERAL_DISC_MODE: u32 = 2; pub const BLE_GAP_ADV_FLAG_BR_EDR_NOT_SUPPORTED: u32 = 4; pub const BLE_GAP_ADV_FLAG_LE_BR_EDR_CONTROLLER: u32 = 8; pub const BLE_GAP_ADV_FLAG_LE_BR_EDR_HOST: u32 = 16; pub const BLE_GAP_ADV_FLAGS_LE_ONLY_LIMITED_DISC_MODE: u32 = 5; pub const BLE_GAP_ADV_FLAGS_LE_ONLY_GENERAL_DISC_MODE: u32 = 6; pub const BLE_GAP_ADV_INTERVAL_MIN: u32 = 32; pub const BLE_GAP_ADV_INTERVAL_MAX: u32 = 16384; pub const BLE_GAP_SCAN_INTERVAL_MIN: u32 = 4; pub const BLE_GAP_SCAN_INTERVAL_MAX: u32 = 65535; pub const BLE_GAP_SCAN_WINDOW_MIN: u32 = 4; pub const BLE_GAP_SCAN_WINDOW_MAX: u32 = 65535; pub const BLE_GAP_SCAN_TIMEOUT_MIN: u32 = 1; pub const BLE_GAP_SCAN_TIMEOUT_UNLIMITED: u32 = 0; pub const BLE_GAP_SCAN_BUFFER_MIN: u32 = 31; pub const BLE_GAP_SCAN_BUFFER_MAX: u32 = 31; pub const BLE_GAP_SCAN_BUFFER_EXTENDED_MIN: u32 = 255; pub const BLE_GAP_SCAN_BUFFER_EXTENDED_MAX: u32 = 1650; pub const BLE_GAP_SCAN_BUFFER_EXTENDED_MAX_SUPPORTED: u32 = 255; pub const BLE_GAP_ADV_TYPE_CONNECTABLE_SCANNABLE_UNDIRECTED: u32 = 1; pub const BLE_GAP_ADV_TYPE_CONNECTABLE_NONSCANNABLE_DIRECTED_HIGH_DUTY_CYCLE: u32 = 2; pub const BLE_GAP_ADV_TYPE_CONNECTABLE_NONSCANNABLE_DIRECTED: u32 = 3; pub const BLE_GAP_ADV_TYPE_NONCONNECTABLE_SCANNABLE_UNDIRECTED: u32 = 4; pub const BLE_GAP_ADV_TYPE_NONCONNECTABLE_NONSCANNABLE_UNDIRECTED: u32 = 5; pub const BLE_GAP_ADV_TYPE_EXTENDED_CONNECTABLE_NONSCANNABLE_UNDIRECTED: u32 = 6; pub const BLE_GAP_ADV_TYPE_EXTENDED_CONNECTABLE_NONSCANNABLE_DIRECTED: u32 = 7; pub const BLE_GAP_ADV_TYPE_EXTENDED_NONCONNECTABLE_SCANNABLE_UNDIRECTED: u32 = 8; pub const BLE_GAP_ADV_TYPE_EXTENDED_NONCONNECTABLE_SCANNABLE_DIRECTED: u32 = 9; pub const BLE_GAP_ADV_TYPE_EXTENDED_NONCONNECTABLE_NONSCANNABLE_UNDIRECTED: u32 = 10; pub const BLE_GAP_ADV_TYPE_EXTENDED_NONCONNECTABLE_NONSCANNABLE_DIRECTED: u32 = 11; pub const BLE_GAP_ADV_FP_ANY: u32 = 0; pub const BLE_GAP_ADV_FP_FILTER_SCANREQ: u32 = 1; pub const BLE_GAP_ADV_FP_FILTER_CONNREQ: u32 = 2; pub const BLE_GAP_ADV_FP_FILTER_BOTH: u32 = 3; pub const BLE_GAP_ADV_DATA_STATUS_COMPLETE: u32 = 0; pub const BLE_GAP_ADV_DATA_STATUS_INCOMPLETE_MORE_DATA: u32 = 1; pub const BLE_GAP_ADV_DATA_STATUS_INCOMPLETE_TRUNCATED: u32 = 2; pub const BLE_GAP_ADV_DATA_STATUS_INCOMPLETE_MISSED: u32 = 3; pub const BLE_GAP_SCAN_FP_ACCEPT_ALL: u32 = 0; pub const BLE_GAP_SCAN_FP_WHITELIST: u32 = 1; pub const BLE_GAP_SCAN_FP_ALL_NOT_RESOLVED_DIRECTED: u32 = 2; pub const BLE_GAP_SCAN_FP_WHITELIST_NOT_RESOLVED_DIRECTED: u32 = 3; pub const BLE_GAP_ADV_TIMEOUT_HIGH_DUTY_MAX: u32 = 128; pub const BLE_GAP_ADV_TIMEOUT_LIMITED_MAX: u32 = 18000; pub const BLE_GAP_ADV_TIMEOUT_GENERAL_UNLIMITED: u32 = 0; pub const BLE_GAP_DISC_MODE_NOT_DISCOVERABLE: u32 = 0; pub const BLE_GAP_DISC_MODE_LIMITED: u32 = 1; pub const BLE_GAP_DISC_MODE_GENERAL: u32 = 2; pub const BLE_GAP_IO_CAPS_DISPLAY_ONLY: u32 = 0; pub const BLE_GAP_IO_CAPS_DISPLAY_YESNO: u32 = 1; pub const BLE_GAP_IO_CAPS_KEYBOARD_ONLY: u32 = 2; pub const BLE_GAP_IO_CAPS_NONE: u32 = 3; pub const BLE_GAP_IO_CAPS_KEYBOARD_DISPLAY: u32 = 4; pub const BLE_GAP_AUTH_KEY_TYPE_NONE: u32 = 0; pub const BLE_GAP_AUTH_KEY_TYPE_PASSKEY: u32 = 1; pub const BLE_GAP_AUTH_KEY_TYPE_OOB: u32 = 2; pub const BLE_GAP_KP_NOT_TYPE_PASSKEY_START: u32 = 0; pub const BLE_GAP_KP_NOT_TYPE_PASSKEY_DIGIT_IN: u32 = 1; pub const BLE_GAP_KP_NOT_TYPE_PASSKEY_DIGIT_OUT: u32 = 2; pub const BLE_GAP_KP_NOT_TYPE_PASSKEY_CLEAR: u32 = 3; pub const BLE_GAP_KP_NOT_TYPE_PASSKEY_END: u32 = 4; pub const BLE_GAP_SEC_STATUS_SUCCESS: u32 = 0; pub const BLE_GAP_SEC_STATUS_TIMEOUT: u32 = 1; pub const BLE_GAP_SEC_STATUS_PDU_INVALID: u32 = 2; pub const BLE_GAP_SEC_STATUS_RFU_RANGE1_BEGIN: u32 = 3; pub const BLE_GAP_SEC_STATUS_RFU_RANGE1_END: u32 = 128; pub const BLE_GAP_SEC_STATUS_PASSKEY_ENTRY_FAILED: u32 = 129; pub const BLE_GAP_SEC_STATUS_OOB_NOT_AVAILABLE: u32 = 130; pub const BLE_GAP_SEC_STATUS_AUTH_REQ: u32 = 131; pub const BLE_GAP_SEC_STATUS_CONFIRM_VALUE: u32 = 132; pub const BLE_GAP_SEC_STATUS_PAIRING_NOT_SUPP: u32 = 133; pub const BLE_GAP_SEC_STATUS_ENC_KEY_SIZE: u32 = 134; pub const BLE_GAP_SEC_STATUS_SMP_CMD_UNSUPPORTED: u32 = 135; pub const BLE_GAP_SEC_STATUS_UNSPECIFIED: u32 = 136; pub const BLE_GAP_SEC_STATUS_REPEATED_ATTEMPTS: u32 = 137; pub const BLE_GAP_SEC_STATUS_INVALID_PARAMS: u32 = 138; pub const BLE_GAP_SEC_STATUS_DHKEY_FAILURE: u32 = 139; pub const BLE_GAP_SEC_STATUS_NUM_COMP_FAILURE: u32 = 140; pub const BLE_GAP_SEC_STATUS_BR_EDR_IN_PROG: u32 = 141; pub const BLE_GAP_SEC_STATUS_X_TRANS_KEY_DISALLOWED: u32 = 142; pub const BLE_GAP_SEC_STATUS_RFU_RANGE2_BEGIN: u32 = 143; pub const BLE_GAP_SEC_STATUS_RFU_RANGE2_END: u32 = 255; pub const BLE_GAP_SEC_STATUS_SOURCE_LOCAL: u32 = 0; pub const BLE_GAP_SEC_STATUS_SOURCE_REMOTE: u32 = 1; pub const BLE_GAP_CP_MIN_CONN_INTVL_NONE: u32 = 65535; pub const BLE_GAP_CP_MIN_CONN_INTVL_MIN: u32 = 6; pub const BLE_GAP_CP_MIN_CONN_INTVL_MAX: u32 = 3200; pub const BLE_GAP_CP_MAX_CONN_INTVL_NONE: u32 = 65535; pub const BLE_GAP_CP_MAX_CONN_INTVL_MIN: u32 = 6; pub const BLE_GAP_CP_MAX_CONN_INTVL_MAX: u32 = 3200; pub const BLE_GAP_CP_SLAVE_LATENCY_MAX: u32 = 499; pub const BLE_GAP_CP_CONN_SUP_TIMEOUT_NONE: u32 = 65535; pub const BLE_GAP_CP_CONN_SUP_TIMEOUT_MIN: u32 = 10; pub const BLE_GAP_CP_CONN_SUP_TIMEOUT_MAX: u32 = 3200; pub const BLE_GAP_DEVNAME_DEFAULT: &'static [u8; 6usize] = b"nRF5x\0"; pub const BLE_GAP_DEVNAME_DEFAULT_LEN: u32 = 31; pub const BLE_GAP_DEVNAME_MAX_LEN: u32 = 248; pub const BLE_GAP_RSSI_THRESHOLD_INVALID: u32 = 255; pub const BLE_GAP_PHY_AUTO: u32 = 0; pub const BLE_GAP_PHY_1MBPS: u32 = 1; pub const BLE_GAP_PHY_2MBPS: u32 = 2; pub const BLE_GAP_PHY_CODED: u32 = 4; pub const BLE_GAP_PHY_NOT_SET: u32 = 255; pub const BLE_GAP_PHYS_SUPPORTED: u32 = 7; pub const BLE_GAP_SEC_RAND_LEN: u32 = 8; pub const BLE_GAP_SEC_KEY_LEN: u32 = 16; pub const BLE_GAP_LESC_P256_PK_LEN: u32 = 64; pub const BLE_GAP_LESC_DHKEY_LEN: u32 = 32; pub const BLE_GAP_PASSKEY_LEN: u32 = 6; pub const BLE_GAP_WHITELIST_ADDR_MAX_COUNT: u32 = 8; pub const BLE_GAP_DEVICE_IDENTITIES_MAX_COUNT: u32 = 8; pub const BLE_GAP_CONN_COUNT_DEFAULT: u32 = 1; pub const BLE_GAP_EVENT_LENGTH_MIN: u32 = 2; pub const BLE_GAP_EVENT_LENGTH_CODED_PHY_MIN: u32 = 6; pub const BLE_GAP_EVENT_LENGTH_DEFAULT: u32 = 3; pub const BLE_GAP_ROLE_COUNT_PERIPH_DEFAULT: u32 = 1; pub const BLE_GAP_ROLE_COUNT_CENTRAL_DEFAULT: u32 = 3; pub const BLE_GAP_ROLE_COUNT_CENTRAL_SEC_DEFAULT: u32 = 1; pub const BLE_GAP_ROLE_COUNT_COMBINED_MAX: u32 = 20; pub const BLE_GAP_DATA_LENGTH_AUTO: u32 = 0; pub const BLE_GAP_AUTH_PAYLOAD_TIMEOUT_MAX: u32 = 48000; pub const BLE_GAP_AUTH_PAYLOAD_TIMEOUT_MIN: u32 = 1; pub const BLE_GAP_SEC_MODE: u32 = 0; pub const BLE_GAP_CHANNEL_COUNT: u32 = 40; pub const BLE_GAP_QOS_CHANNEL_SURVEY_INTERVAL_CONTINUOUS: u32 = 0; pub const BLE_GAP_QOS_CHANNEL_SURVEY_INTERVAL_MIN_US: u32 = 7500; pub const BLE_GAP_QOS_CHANNEL_SURVEY_INTERVAL_MAX_US: u32 = 4000000; pub const BLE_GAP_CHAR_INCL_CONFIG_INCLUDE: u32 = 0; pub const BLE_GAP_CHAR_INCL_CONFIG_EXCLUDE_WITH_SPACE: u32 = 1; pub const BLE_GAP_CHAR_INCL_CONFIG_EXCLUDE_WITHOUT_SPACE: u32 = 2; pub const BLE_GAP_PPCP_INCL_CONFIG_DEFAULT: u32 = 0; pub const BLE_GAP_CAR_INCL_CONFIG_DEFAULT: u32 = 0; pub const BLE_L2CAP_CH_COUNT_MAX: u32 = 64; pub const BLE_L2CAP_MTU_MIN: u32 = 23; pub const BLE_L2CAP_MPS_MIN: u32 = 23; pub const BLE_L2CAP_CID_INVALID: u32 = 0; pub const BLE_L2CAP_CREDITS_DEFAULT: u32 = 1; pub const BLE_L2CAP_CH_SETUP_REFUSED_SRC_LOCAL: u32 = 1; pub const BLE_L2CAP_CH_SETUP_REFUSED_SRC_REMOTE: u32 = 2; pub const BLE_L2CAP_CH_STATUS_CODE_SUCCESS: u32 = 0; pub const BLE_L2CAP_CH_STATUS_CODE_LE_PSM_NOT_SUPPORTED: u32 = 2; pub const BLE_L2CAP_CH_STATUS_CODE_NO_RESOURCES: u32 = 4; pub const BLE_L2CAP_CH_STATUS_CODE_INSUFF_AUTHENTICATION: u32 = 5; pub const BLE_L2CAP_CH_STATUS_CODE_INSUFF_AUTHORIZATION: u32 = 6; pub const BLE_L2CAP_CH_STATUS_CODE_INSUFF_ENC_KEY_SIZE: u32 = 7; pub const BLE_L2CAP_CH_STATUS_CODE_INSUFF_ENC: u32 = 8; pub const BLE_L2CAP_CH_STATUS_CODE_INVALID_SCID: u32 = 9; pub const BLE_L2CAP_CH_STATUS_CODE_SCID_ALLOCATED: u32 = 10; pub const BLE_L2CAP_CH_STATUS_CODE_UNACCEPTABLE_PARAMS: u32 = 11; pub const BLE_L2CAP_CH_STATUS_CODE_NOT_UNDERSTOOD: u32 = 32768; pub const BLE_L2CAP_CH_STATUS_CODE_TIMEOUT: u32 = 49152; pub const BLE_ERROR_GATTC_PROC_NOT_PERMITTED: u32 = 13056; pub const BLE_GATTC_ATTR_INFO_FORMAT_16BIT: u32 = 1; pub const BLE_GATTC_ATTR_INFO_FORMAT_128BIT: u32 = 2; pub const BLE_GATTC_WRITE_CMD_TX_QUEUE_SIZE_DEFAULT: u32 = 1; pub const BLE_ERROR_GATTS_INVALID_ATTR_TYPE: u32 = 13312; pub const BLE_ERROR_GATTS_SYS_ATTR_MISSING: u32 = 13313; pub const BLE_GATTS_FIX_ATTR_LEN_MAX: u32 = 510; pub const BLE_GATTS_VAR_ATTR_LEN_MAX: u32 = 512; pub const BLE_GATTS_SRVC_TYPE_INVALID: u32 = 0; pub const BLE_GATTS_SRVC_TYPE_PRIMARY: u32 = 1; pub const BLE_GATTS_SRVC_TYPE_SECONDARY: u32 = 2; pub const BLE_GATTS_ATTR_TYPE_INVALID: u32 = 0; pub const BLE_GATTS_ATTR_TYPE_PRIM_SRVC_DECL: u32 = 1; pub const BLE_GATTS_ATTR_TYPE_SEC_SRVC_DECL: u32 = 2; pub const BLE_GATTS_ATTR_TYPE_INC_DECL: u32 = 3; pub const BLE_GATTS_ATTR_TYPE_CHAR_DECL: u32 = 4; pub const BLE_GATTS_ATTR_TYPE_CHAR_VAL: u32 = 5; pub const BLE_GATTS_ATTR_TYPE_DESC: u32 = 6; pub const BLE_GATTS_ATTR_TYPE_OTHER: u32 = 7; pub const BLE_GATTS_OP_INVALID: u32 = 0; pub const BLE_GATTS_OP_WRITE_REQ: u32 = 1; pub const BLE_GATTS_OP_WRITE_CMD: u32 = 2; pub const BLE_GATTS_OP_SIGN_WRITE_CMD: u32 = 3; pub const BLE_GATTS_OP_PREP_WRITE_REQ: u32 = 4; pub const BLE_GATTS_OP_EXEC_WRITE_REQ_CANCEL: u32 = 5; pub const BLE_GATTS_OP_EXEC_WRITE_REQ_NOW: u32 = 6; pub const BLE_GATTS_VLOC_INVALID: u32 = 0; pub const BLE_GATTS_VLOC_STACK: u32 = 1; pub const BLE_GATTS_VLOC_USER: u32 = 2; pub const BLE_GATTS_AUTHORIZE_TYPE_INVALID: u32 = 0; pub const BLE_GATTS_AUTHORIZE_TYPE_READ: u32 = 1; pub const BLE_GATTS_AUTHORIZE_TYPE_WRITE: u32 = 2; pub const BLE_GATTS_SYS_ATTR_FLAG_SYS_SRVCS: u32 = 1; pub const BLE_GATTS_SYS_ATTR_FLAG_USR_SRVCS: u32 = 2; pub const BLE_GATTS_SERVICE_CHANGED_DEFAULT: u32 = 1; pub const BLE_GATTS_ATTR_TAB_SIZE_MIN: u32 = 248; pub const BLE_GATTS_ATTR_TAB_SIZE_DEFAULT: u32 = 1408; pub const BLE_GATTS_HVN_TX_QUEUE_SIZE_DEFAULT: u32 = 1; pub const BLE_EVT_PTR_ALIGNMENT: u32 = 4; pub const BLE_USER_MEM_TYPE_INVALID: u32 = 0; pub const BLE_USER_MEM_TYPE_GATTS_QUEUED_WRITES: u32 = 1; pub const BLE_UUID_VS_COUNT_DEFAULT: u32 = 10; pub const BLE_UUID_VS_COUNT_MAX: u32 = 254; pub const BLE_CONN_CFG_TAG_DEFAULT: u32 = 0; pub const SD_TIMERS_USED: u32 = 1; pub const SD_SWI_USED: u32 = 54; pub type int_least64_t = i64; pub type uint_least64_t = u64; pub type int_fast64_t = i64; pub type uint_fast64_t = u64; pub type int_least32_t = i32; pub type uint_least32_t = u32; pub type int_fast32_t = i32; pub type uint_fast32_t = u32; pub type int_least16_t = i16; pub type uint_least16_t = u16; pub type int_fast16_t = i16; pub type uint_fast16_t = u16; pub type int_least8_t = i8; pub type uint_least8_t = u8; pub type int_fast8_t = i8; pub type uint_fast8_t = u8; pub type intmax_t = self::c_longlong; pub type uintmax_t = self::c_ulonglong; pub const NRF_SOC_SVCS_SD_PPI_CHANNEL_ENABLE_GET: NRF_SOC_SVCS = 32; pub const NRF_SOC_SVCS_SD_PPI_CHANNEL_ENABLE_SET: NRF_SOC_SVCS = 33; pub const NRF_SOC_SVCS_SD_PPI_CHANNEL_ENABLE_CLR: NRF_SOC_SVCS = 34; pub const NRF_SOC_SVCS_SD_PPI_CHANNEL_ASSIGN: NRF_SOC_SVCS = 35; pub const NRF_SOC_SVCS_SD_PPI_GROUP_TASK_ENABLE: NRF_SOC_SVCS = 36; pub const NRF_SOC_SVCS_SD_PPI_GROUP_TASK_DISABLE: NRF_SOC_SVCS = 37; pub const NRF_SOC_SVCS_SD_PPI_GROUP_ASSIGN: NRF_SOC_SVCS = 38; pub const NRF_SOC_SVCS_SD_PPI_GROUP_GET: NRF_SOC_SVCS = 39; pub const NRF_SOC_SVCS_SD_FLASH_PAGE_ERASE: NRF_SOC_SVCS = 40; pub const NRF_SOC_SVCS_SD_FLASH_WRITE: NRF_SOC_SVCS = 41; pub const NRF_SOC_SVCS_SD_PROTECTED_REGISTER_WRITE: NRF_SOC_SVCS = 43; pub const NRF_SOC_SVCS_SD_MUTEX_NEW: NRF_SOC_SVCS = 44; pub const NRF_SOC_SVCS_SD_MUTEX_ACQUIRE: NRF_SOC_SVCS = 45; pub const NRF_SOC_SVCS_SD_MUTEX_RELEASE: NRF_SOC_SVCS = 46; pub const NRF_SOC_SVCS_SD_RAND_APPLICATION_POOL_CAPACITY_GET: NRF_SOC_SVCS = 47; pub const NRF_SOC_SVCS_SD_RAND_APPLICATION_BYTES_AVAILABLE_GET: NRF_SOC_SVCS = 48; pub const NRF_SOC_SVCS_SD_RAND_APPLICATION_VECTOR_GET: NRF_SOC_SVCS = 49; pub const NRF_SOC_SVCS_SD_POWER_MODE_SET: NRF_SOC_SVCS = 50; pub const NRF_SOC_SVCS_SD_POWER_SYSTEM_OFF: NRF_SOC_SVCS = 51; pub const NRF_SOC_SVCS_SD_POWER_RESET_REASON_GET: NRF_SOC_SVCS = 52; pub const NRF_SOC_SVCS_SD_POWER_RESET_REASON_CLR: NRF_SOC_SVCS = 53; pub const NRF_SOC_SVCS_SD_POWER_POF_ENABLE: NRF_SOC_SVCS = 54; pub const NRF_SOC_SVCS_SD_POWER_POF_THRESHOLD_SET: NRF_SOC_SVCS = 55; pub const NRF_SOC_SVCS_SD_POWER_POF_THRESHOLDVDDH_SET: NRF_SOC_SVCS = 56; pub const NRF_SOC_SVCS_SD_POWER_RAM_POWER_SET: NRF_SOC_SVCS = 57; pub const NRF_SOC_SVCS_SD_POWER_RAM_POWER_CLR: NRF_SOC_SVCS = 58; pub const NRF_SOC_SVCS_SD_POWER_RAM_POWER_GET: NRF_SOC_SVCS = 59; pub const NRF_SOC_SVCS_SD_POWER_GPREGRET_SET: NRF_SOC_SVCS = 60; pub const NRF_SOC_SVCS_SD_POWER_GPREGRET_CLR: NRF_SOC_SVCS = 61; pub const NRF_SOC_SVCS_SD_POWER_GPREGRET_GET: NRF_SOC_SVCS = 62; pub const NRF_SOC_SVCS_SD_POWER_DCDC_MODE_SET: NRF_SOC_SVCS = 63; pub const NRF_SOC_SVCS_SD_POWER_DCDC0_MODE_SET: NRF_SOC_SVCS = 64; pub const NRF_SOC_SVCS_SD_APP_EVT_WAIT: NRF_SOC_SVCS = 65; pub const NRF_SOC_SVCS_SD_CLOCK_HFCLK_REQUEST: NRF_SOC_SVCS = 66; pub const NRF_SOC_SVCS_SD_CLOCK_HFCLK_RELEASE: NRF_SOC_SVCS = 67; pub const NRF_SOC_SVCS_SD_CLOCK_HFCLK_IS_RUNNING: NRF_SOC_SVCS = 68; pub const NRF_SOC_SVCS_SD_RADIO_NOTIFICATION_CFG_SET: NRF_SOC_SVCS = 69; pub const NRF_SOC_SVCS_SD_ECB_BLOCK_ENCRYPT: NRF_SOC_SVCS = 70; pub const NRF_SOC_SVCS_SD_ECB_BLOCKS_ENCRYPT: NRF_SOC_SVCS = 71; pub const NRF_SOC_SVCS_SD_RADIO_SESSION_OPEN: NRF_SOC_SVCS = 72; pub const NRF_SOC_SVCS_SD_RADIO_SESSION_CLOSE: NRF_SOC_SVCS = 73; pub const NRF_SOC_SVCS_SD_RADIO_REQUEST: NRF_SOC_SVCS = 74; pub const NRF_SOC_SVCS_SD_EVT_GET: NRF_SOC_SVCS = 75; pub const NRF_SOC_SVCS_SD_TEMP_GET: NRF_SOC_SVCS = 76; pub const NRF_SOC_SVCS_SD_POWER_USBPWRRDY_ENABLE: NRF_SOC_SVCS = 77; pub const NRF_SOC_SVCS_SD_POWER_USBDETECTED_ENABLE: NRF_SOC_SVCS = 78; pub const NRF_SOC_SVCS_SD_POWER_USBREMOVED_ENABLE: NRF_SOC_SVCS = 79; pub const NRF_SOC_SVCS_SD_POWER_USBREGSTATUS_GET: NRF_SOC_SVCS = 80; pub const NRF_SOC_SVCS_SVC_SOC_LAST: NRF_SOC_SVCS = 81; #[doc = "@brief The SVC numbers used by the SVC functions in the SoC library."] pub type NRF_SOC_SVCS = self::c_uint; pub const NRF_MUTEX_VALUES_NRF_MUTEX_FREE: NRF_MUTEX_VALUES = 0; pub const NRF_MUTEX_VALUES_NRF_MUTEX_TAKEN: NRF_MUTEX_VALUES = 1; #[doc = "@brief Possible values of a ::nrf_mutex_t."] pub type NRF_MUTEX_VALUES = self::c_uint; #[doc = "< Constant latency mode. See power management in the reference manual."] pub const NRF_POWER_MODES_NRF_POWER_MODE_CONSTLAT: NRF_POWER_MODES = 0; #[doc = "< Low power mode. See power management in the reference manual."] pub const NRF_POWER_MODES_NRF_POWER_MODE_LOWPWR: NRF_POWER_MODES = 1; #[doc = "@brief Power modes."] pub type NRF_POWER_MODES = self::c_uint; #[doc = "< 1.7 Volts power failure threshold."] pub const NRF_POWER_THRESHOLDS_NRF_POWER_THRESHOLD_V17: NRF_POWER_THRESHOLDS = 4; #[doc = "< 1.8 Volts power failure threshold."] pub const NRF_POWER_THRESHOLDS_NRF_POWER_THRESHOLD_V18: NRF_POWER_THRESHOLDS = 5; #[doc = "< 1.9 Volts power failure threshold."] pub const NRF_POWER_THRESHOLDS_NRF_POWER_THRESHOLD_V19: NRF_POWER_THRESHOLDS = 6; #[doc = "< 2.0 Volts power failure threshold."] pub const NRF_POWER_THRESHOLDS_NRF_POWER_THRESHOLD_V20: NRF_POWER_THRESHOLDS = 7; #[doc = "< 2.1 Volts power failure threshold."] pub const NRF_POWER_THRESHOLDS_NRF_POWER_THRESHOLD_V21: NRF_POWER_THRESHOLDS = 8; #[doc = "< 2.2 Volts power failure threshold."] pub const NRF_POWER_THRESHOLDS_NRF_POWER_THRESHOLD_V22: NRF_POWER_THRESHOLDS = 9; #[doc = "< 2.3 Volts power failure threshold."] pub const NRF_POWER_THRESHOLDS_NRF_POWER_THRESHOLD_V23: NRF_POWER_THRESHOLDS = 10; #[doc = "< 2.4 Volts power failure threshold."] pub const NRF_POWER_THRESHOLDS_NRF_POWER_THRESHOLD_V24: NRF_POWER_THRESHOLDS = 11; #[doc = "< 2.5 Volts power failure threshold."] pub const NRF_POWER_THRESHOLDS_NRF_POWER_THRESHOLD_V25: NRF_POWER_THRESHOLDS = 12; #[doc = "< 2.6 Volts power failure threshold."] pub const NRF_POWER_THRESHOLDS_NRF_POWER_THRESHOLD_V26: NRF_POWER_THRESHOLDS = 13; #[doc = "< 2.7 Volts power failure threshold."] pub const NRF_POWER_THRESHOLDS_NRF_POWER_THRESHOLD_V27: NRF_POWER_THRESHOLDS = 14; #[doc = "< 2.8 Volts power failure threshold."] pub const NRF_POWER_THRESHOLDS_NRF_POWER_THRESHOLD_V28: NRF_POWER_THRESHOLDS = 15; #[doc = "@brief Power failure thresholds"] pub type NRF_POWER_THRESHOLDS = self::c_uint; #[doc = "< 2.7 Volts power failure threshold."] pub const NRF_POWER_THRESHOLDVDDHS_NRF_POWER_THRESHOLDVDDH_V27: NRF_POWER_THRESHOLDVDDHS = 0; #[doc = "< 2.8 Volts power failure threshold."] pub const NRF_POWER_THRESHOLDVDDHS_NRF_POWER_THRESHOLDVDDH_V28: NRF_POWER_THRESHOLDVDDHS = 1; #[doc = "< 2.9 Volts power failure threshold."] pub const NRF_POWER_THRESHOLDVDDHS_NRF_POWER_THRESHOLDVDDH_V29: NRF_POWER_THRESHOLDVDDHS = 2; #[doc = "< 3.0 Volts power failure threshold."] pub const NRF_POWER_THRESHOLDVDDHS_NRF_POWER_THRESHOLDVDDH_V30: NRF_POWER_THRESHOLDVDDHS = 3; #[doc = "< 3.1 Volts power failure threshold."] pub const NRF_POWER_THRESHOLDVDDHS_NRF_POWER_THRESHOLDVDDH_V31: NRF_POWER_THRESHOLDVDDHS = 4; #[doc = "< 3.2 Volts power failure threshold."] pub const NRF_POWER_THRESHOLDVDDHS_NRF_POWER_THRESHOLDVDDH_V32: NRF_POWER_THRESHOLDVDDHS = 5; #[doc = "< 3.3 Volts power failure threshold."] pub const NRF_POWER_THRESHOLDVDDHS_NRF_POWER_THRESHOLDVDDH_V33: NRF_POWER_THRESHOLDVDDHS = 6; #[doc = "< 3.4 Volts power failure threshold."] pub const NRF_POWER_THRESHOLDVDDHS_NRF_POWER_THRESHOLDVDDH_V34: NRF_POWER_THRESHOLDVDDHS = 7; #[doc = "< 3.5 Volts power failure threshold."] pub const NRF_POWER_THRESHOLDVDDHS_NRF_POWER_THRESHOLDVDDH_V35: NRF_POWER_THRESHOLDVDDHS = 8; #[doc = "< 3.6 Volts power failure threshold."] pub const NRF_POWER_THRESHOLDVDDHS_NRF_POWER_THRESHOLDVDDH_V36: NRF_POWER_THRESHOLDVDDHS = 9; #[doc = "< 3.7 Volts power failure threshold."] pub const NRF_POWER_THRESHOLDVDDHS_NRF_POWER_THRESHOLDVDDH_V37: NRF_POWER_THRESHOLDVDDHS = 10; #[doc = "< 3.8 Volts power failure threshold."] pub const NRF_POWER_THRESHOLDVDDHS_NRF_POWER_THRESHOLDVDDH_V38: NRF_POWER_THRESHOLDVDDHS = 11; #[doc = "< 3.9 Volts power failure threshold."] pub const NRF_POWER_THRESHOLDVDDHS_NRF_POWER_THRESHOLDVDDH_V39: NRF_POWER_THRESHOLDVDDHS = 12; #[doc = "< 4.0 Volts power failure threshold."] pub const NRF_POWER_THRESHOLDVDDHS_NRF_POWER_THRESHOLDVDDH_V40: NRF_POWER_THRESHOLDVDDHS = 13; #[doc = "< 4.1 Volts power failure threshold."] pub const NRF_POWER_THRESHOLDVDDHS_NRF_POWER_THRESHOLDVDDH_V41: NRF_POWER_THRESHOLDVDDHS = 14; #[doc = "< 4.2 Volts power failure threshold."] pub const NRF_POWER_THRESHOLDVDDHS_NRF_POWER_THRESHOLDVDDH_V42: NRF_POWER_THRESHOLDVDDHS = 15; #[doc = "@brief Power failure thresholds for high voltage"] pub type NRF_POWER_THRESHOLDVDDHS = self::c_uint; #[doc = "< The DCDC is disabled."] pub const NRF_POWER_DCDC_MODES_NRF_POWER_DCDC_DISABLE: NRF_POWER_DCDC_MODES = 0; #[doc = "< The DCDC is enabled."] pub const NRF_POWER_DCDC_MODES_NRF_POWER_DCDC_ENABLE: NRF_POWER_DCDC_MODES = 1; #[doc = "@brief DC/DC converter modes."] pub type NRF_POWER_DCDC_MODES = self::c_uint; #[doc = "< The event does not have a notification."] pub const NRF_RADIO_NOTIFICATION_DISTANCES_NRF_RADIO_NOTIFICATION_DISTANCE_NONE: NRF_RADIO_NOTIFICATION_DISTANCES = 0; #[doc = "< The distance from the active notification to start of radio activity."] pub const NRF_RADIO_NOTIFICATION_DISTANCES_NRF_RADIO_NOTIFICATION_DISTANCE_800US: NRF_RADIO_NOTIFICATION_DISTANCES = 1; #[doc = "< The distance from the active notification to start of radio activity."] pub const NRF_RADIO_NOTIFICATION_DISTANCES_NRF_RADIO_NOTIFICATION_DISTANCE_1740US: NRF_RADIO_NOTIFICATION_DISTANCES = 2; #[doc = "< The distance from the active notification to start of radio activity."] pub const NRF_RADIO_NOTIFICATION_DISTANCES_NRF_RADIO_NOTIFICATION_DISTANCE_2680US: NRF_RADIO_NOTIFICATION_DISTANCES = 3; #[doc = "< The distance from the active notification to start of radio activity."] pub const NRF_RADIO_NOTIFICATION_DISTANCES_NRF_RADIO_NOTIFICATION_DISTANCE_3620US: NRF_RADIO_NOTIFICATION_DISTANCES = 4; #[doc = "< The distance from the active notification to start of radio activity."] pub const NRF_RADIO_NOTIFICATION_DISTANCES_NRF_RADIO_NOTIFICATION_DISTANCE_4560US: NRF_RADIO_NOTIFICATION_DISTANCES = 5; #[doc = "< The distance from the active notification to start of radio activity."] pub const NRF_RADIO_NOTIFICATION_DISTANCES_NRF_RADIO_NOTIFICATION_DISTANCE_5500US: NRF_RADIO_NOTIFICATION_DISTANCES = 6; #[doc = "@brief Radio notification distances."] pub type NRF_RADIO_NOTIFICATION_DISTANCES = self::c_uint; #[doc = "< The event does not have a radio notification signal."] pub const NRF_RADIO_NOTIFICATION_TYPES_NRF_RADIO_NOTIFICATION_TYPE_NONE: NRF_RADIO_NOTIFICATION_TYPES = 0; #[doc = "< Using interrupt for notification when the radio will be enabled."] pub const NRF_RADIO_NOTIFICATION_TYPES_NRF_RADIO_NOTIFICATION_TYPE_INT_ON_ACTIVE: NRF_RADIO_NOTIFICATION_TYPES = 1; #[doc = "< Using interrupt for notification when the radio has been disabled."] pub const NRF_RADIO_NOTIFICATION_TYPES_NRF_RADIO_NOTIFICATION_TYPE_INT_ON_INACTIVE: NRF_RADIO_NOTIFICATION_TYPES = 2; #[doc = "< Using interrupt for notification both when the radio will be enabled and disabled."] pub const NRF_RADIO_NOTIFICATION_TYPES_NRF_RADIO_NOTIFICATION_TYPE_INT_ON_BOTH: NRF_RADIO_NOTIFICATION_TYPES = 3; #[doc = "@brief Radio notification types."] pub type NRF_RADIO_NOTIFICATION_TYPES = self::c_uint; #[doc = "< This signal indicates the start of the radio timeslot."] pub const NRF_RADIO_CALLBACK_SIGNAL_TYPE_NRF_RADIO_CALLBACK_SIGNAL_TYPE_START: NRF_RADIO_CALLBACK_SIGNAL_TYPE = 0; #[doc = "< This signal indicates the NRF_TIMER0 interrupt."] pub const NRF_RADIO_CALLBACK_SIGNAL_TYPE_NRF_RADIO_CALLBACK_SIGNAL_TYPE_TIMER0: NRF_RADIO_CALLBACK_SIGNAL_TYPE = 1; #[doc = "< This signal indicates the NRF_RADIO interrupt."] pub const NRF_RADIO_CALLBACK_SIGNAL_TYPE_NRF_RADIO_CALLBACK_SIGNAL_TYPE_RADIO: NRF_RADIO_CALLBACK_SIGNAL_TYPE = 2; #[doc = "< This signal indicates extend action failed."] pub const NRF_RADIO_CALLBACK_SIGNAL_TYPE_NRF_RADIO_CALLBACK_SIGNAL_TYPE_EXTEND_FAILED: NRF_RADIO_CALLBACK_SIGNAL_TYPE = 3; #[doc = "< This signal indicates extend action succeeded."] pub const NRF_RADIO_CALLBACK_SIGNAL_TYPE_NRF_RADIO_CALLBACK_SIGNAL_TYPE_EXTEND_SUCCEEDED: NRF_RADIO_CALLBACK_SIGNAL_TYPE = 4; #[doc = "@brief The Radio signal callback types."] pub type NRF_RADIO_CALLBACK_SIGNAL_TYPE = self::c_uint; #[doc = "< Return without action."] pub const NRF_RADIO_SIGNAL_CALLBACK_ACTION_NRF_RADIO_SIGNAL_CALLBACK_ACTION_NONE: NRF_RADIO_SIGNAL_CALLBACK_ACTION = 0; #[doc = "< Request an extension of the current"] #[doc = "timeslot. Maximum execution time for this action:"] #[doc = "@ref NRF_RADIO_MAX_EXTENSION_PROCESSING_TIME_US."] #[doc = "This action must be started at least"] #[doc = "@ref NRF_RADIO_MIN_EXTENSION_MARGIN_US before"] #[doc = "the end of the timeslot."] pub const NRF_RADIO_SIGNAL_CALLBACK_ACTION_NRF_RADIO_SIGNAL_CALLBACK_ACTION_EXTEND: NRF_RADIO_SIGNAL_CALLBACK_ACTION = 1; #[doc = "< End the current radio timeslot."] pub const NRF_RADIO_SIGNAL_CALLBACK_ACTION_NRF_RADIO_SIGNAL_CALLBACK_ACTION_END: NRF_RADIO_SIGNAL_CALLBACK_ACTION = 2; #[doc = "< Request a new radio timeslot and end the current timeslot."] pub const NRF_RADIO_SIGNAL_CALLBACK_ACTION_NRF_RADIO_SIGNAL_CALLBACK_ACTION_REQUEST_AND_END: NRF_RADIO_SIGNAL_CALLBACK_ACTION = 3; #[doc = "@brief The actions requested by the signal callback."] #[doc = ""] #[doc = " This code gives the SOC instructions about what action to take when the signal callback has"] #[doc = " returned."] pub type NRF_RADIO_SIGNAL_CALLBACK_ACTION = self::c_uint; #[doc = "< The SoftDevice will guarantee that the high frequency clock source is the"] #[doc = "external crystal for the whole duration of the timeslot. This should be the"] #[doc = "preferred option for events that use the radio or require high timing accuracy."] #[doc = "@note The SoftDevice will automatically turn on and off the external crystal,"] #[doc = "at the beginning and end of the timeslot, respectively. The crystal may also"] #[doc = "intentionally be left running after the timeslot, in cases where it is needed"] #[doc = "by the SoftDevice shortly after the end of the timeslot."] pub const NRF_RADIO_HFCLK_CFG_NRF_RADIO_HFCLK_CFG_XTAL_GUARANTEED: NRF_RADIO_HFCLK_CFG = 0; #[doc = "< This configuration allows for earlier and tighter scheduling of timeslots."] #[doc = "The RC oscillator may be the clock source in part or for the whole duration of the timeslot."] #[doc = "The RC oscillator's accuracy must therefore be taken into consideration."] #[doc = "@note If the application will use the radio peripheral in timeslots with this configuration,"] #[doc = "it must make sure that the crystal is running and stable before starting the radio."] pub const NRF_RADIO_HFCLK_CFG_NRF_RADIO_HFCLK_CFG_NO_GUARANTEE: NRF_RADIO_HFCLK_CFG = 1; #[doc = "@brief Radio timeslot high frequency clock source configuration."] pub type NRF_RADIO_HFCLK_CFG = self::c_uint; #[doc = "< High (equal priority as the normal connection priority of the SoftDevice stack(s))."] pub const NRF_RADIO_PRIORITY_NRF_RADIO_PRIORITY_HIGH: NRF_RADIO_PRIORITY = 0; #[doc = "< Normal (equal priority as the priority of secondary activities of the SoftDevice stack(s))."] pub const NRF_RADIO_PRIORITY_NRF_RADIO_PRIORITY_NORMAL: NRF_RADIO_PRIORITY = 1; #[doc = "@brief Radio timeslot priorities."] pub type NRF_RADIO_PRIORITY = self::c_uint; #[doc = "< Request radio timeslot as early as possible. This should always be used for the first request in a session."] pub const NRF_RADIO_REQUEST_TYPE_NRF_RADIO_REQ_TYPE_EARLIEST: NRF_RADIO_REQUEST_TYPE = 0; #[doc = "< Normal radio timeslot request."] pub const NRF_RADIO_REQUEST_TYPE_NRF_RADIO_REQ_TYPE_NORMAL: NRF_RADIO_REQUEST_TYPE = 1; #[doc = "@brief Radio timeslot request type."] pub type NRF_RADIO_REQUEST_TYPE = self::c_uint; #[doc = "< Event indicating that the HFCLK has started."] pub const NRF_SOC_EVTS_NRF_EVT_HFCLKSTARTED: NRF_SOC_EVTS = 0; #[doc = "< Event indicating that a power failure warning has occurred."] pub const NRF_SOC_EVTS_NRF_EVT_POWER_FAILURE_WARNING: NRF_SOC_EVTS = 1; #[doc = "< Event indicating that the ongoing flash operation has completed successfully."] pub const NRF_SOC_EVTS_NRF_EVT_FLASH_OPERATION_SUCCESS: NRF_SOC_EVTS = 2; #[doc = "< Event indicating that the ongoing flash operation has timed out with an error."] pub const NRF_SOC_EVTS_NRF_EVT_FLASH_OPERATION_ERROR: NRF_SOC_EVTS = 3; #[doc = "< Event indicating that a radio timeslot was blocked."] pub const NRF_SOC_EVTS_NRF_EVT_RADIO_BLOCKED: NRF_SOC_EVTS = 4; #[doc = "< Event indicating that a radio timeslot was canceled by SoftDevice."] pub const NRF_SOC_EVTS_NRF_EVT_RADIO_CANCELED: NRF_SOC_EVTS = 5; #[doc = "< Event indicating that a radio timeslot signal callback handler return was invalid."] pub const NRF_SOC_EVTS_NRF_EVT_RADIO_SIGNAL_CALLBACK_INVALID_RETURN: NRF_SOC_EVTS = 6; #[doc = "< Event indicating that a radio timeslot session is idle."] pub const NRF_SOC_EVTS_NRF_EVT_RADIO_SESSION_IDLE: NRF_SOC_EVTS = 7; #[doc = "< Event indicating that a radio timeslot session is closed."] pub const NRF_SOC_EVTS_NRF_EVT_RADIO_SESSION_CLOSED: NRF_SOC_EVTS = 8; #[doc = "< Event indicating that a USB 3.3 V supply is ready."] pub const NRF_SOC_EVTS_NRF_EVT_POWER_USB_POWER_READY: NRF_SOC_EVTS = 9; #[doc = "< Event indicating that voltage supply is detected on VBUS."] pub const NRF_SOC_EVTS_NRF_EVT_POWER_USB_DETECTED: NRF_SOC_EVTS = 10; #[doc = "< Event indicating that voltage supply is removed from VBUS."] pub const NRF_SOC_EVTS_NRF_EVT_POWER_USB_REMOVED: NRF_SOC_EVTS = 11; pub const NRF_SOC_EVTS_NRF_EVT_NUMBER_OF_EVTS: NRF_SOC_EVTS = 12; #[doc = "@brief SoC Events."] pub type NRF_SOC_EVTS = self::c_uint; #[doc = "@brief Represents a mutex for use with the nrf_mutex functions."] #[doc = " @note Accessing the value directly is not safe, use the mutex functions!"] pub type nrf_mutex_t = u8; #[doc = "@brief Parameters for a request for a timeslot as early as possible."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct nrf_radio_request_earliest_t { #[doc = "< High frequency clock source, see @ref NRF_RADIO_HFCLK_CFG."] pub hfclk: u8, #[doc = "< The radio timeslot priority, see @ref NRF_RADIO_PRIORITY."] pub priority: u8, #[doc = "< The radio timeslot length (in the range 100 to 100,000] microseconds)."] pub length_us: u32, #[doc = "< Longest acceptable delay until the start of the requested timeslot (up to @ref NRF_RADIO_EARLIEST_TIMEOUT_MAX_US microseconds)."] pub timeout_us: u32, } #[test] fn bindgen_test_layout_nrf_radio_request_earliest_t() { assert_eq!( ::core::mem::size_of::(), 12usize, concat!("Size of: ", stringify!(nrf_radio_request_earliest_t)) ); assert_eq!( ::core::mem::align_of::(), 4usize, concat!("Alignment of ", stringify!(nrf_radio_request_earliest_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).hfclk as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(nrf_radio_request_earliest_t), "::", stringify!(hfclk) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).priority as *const _ as usize }, 1usize, concat!( "Offset of field: ", stringify!(nrf_radio_request_earliest_t), "::", stringify!(priority) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).length_us as *const _ as usize }, 4usize, concat!( "Offset of field: ", stringify!(nrf_radio_request_earliest_t), "::", stringify!(length_us) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).timeout_us as *const _ as usize }, 8usize, concat!( "Offset of field: ", stringify!(nrf_radio_request_earliest_t), "::", stringify!(timeout_us) ) ); } #[doc = "@brief Parameters for a normal radio timeslot request."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct nrf_radio_request_normal_t { #[doc = "< High frequency clock source, see @ref NRF_RADIO_HFCLK_CFG."] pub hfclk: u8, #[doc = "< The radio timeslot priority, see @ref NRF_RADIO_PRIORITY."] pub priority: u8, #[doc = "< Distance from the start of the previous radio timeslot (up to @ref NRF_RADIO_DISTANCE_MAX_US microseconds)."] pub distance_us: u32, #[doc = "< The radio timeslot length (in the range [100..100,000] microseconds)."] pub length_us: u32, } #[test] fn bindgen_test_layout_nrf_radio_request_normal_t() { assert_eq!( ::core::mem::size_of::(), 12usize, concat!("Size of: ", stringify!(nrf_radio_request_normal_t)) ); assert_eq!( ::core::mem::align_of::(), 4usize, concat!("Alignment of ", stringify!(nrf_radio_request_normal_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).hfclk as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(nrf_radio_request_normal_t), "::", stringify!(hfclk) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).priority as *const _ as usize }, 1usize, concat!( "Offset of field: ", stringify!(nrf_radio_request_normal_t), "::", stringify!(priority) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).distance_us as *const _ as usize }, 4usize, concat!( "Offset of field: ", stringify!(nrf_radio_request_normal_t), "::", stringify!(distance_us) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).length_us as *const _ as usize }, 8usize, concat!( "Offset of field: ", stringify!(nrf_radio_request_normal_t), "::", stringify!(length_us) ) ); } #[doc = "@brief Radio timeslot request parameters."] #[repr(C)] #[derive(Copy, Clone)] pub struct nrf_radio_request_t { #[doc = "< Type of request, see @ref NRF_RADIO_REQUEST_TYPE."] pub request_type: u8, #[doc = "< Parameter union."] pub params: nrf_radio_request_t__bindgen_ty_1, } #[repr(C)] #[derive(Copy, Clone)] pub union nrf_radio_request_t__bindgen_ty_1 { #[doc = "< Parameters for requesting a radio timeslot as early as possible."] pub earliest: nrf_radio_request_earliest_t, #[doc = "< Parameters for requesting a normal radio timeslot."] pub normal: nrf_radio_request_normal_t, _bindgen_union_align: [u32; 3usize], } #[test] fn bindgen_test_layout_nrf_radio_request_t__bindgen_ty_1() { assert_eq!( ::core::mem::size_of::(), 12usize, concat!("Size of: ", stringify!(nrf_radio_request_t__bindgen_ty_1)) ); assert_eq!( ::core::mem::align_of::(), 4usize, concat!( "Alignment of ", stringify!(nrf_radio_request_t__bindgen_ty_1) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).earliest as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(nrf_radio_request_t__bindgen_ty_1), "::", stringify!(earliest) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).normal as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(nrf_radio_request_t__bindgen_ty_1), "::", stringify!(normal) ) ); } #[test] fn bindgen_test_layout_nrf_radio_request_t() { assert_eq!( ::core::mem::size_of::(), 16usize, concat!("Size of: ", stringify!(nrf_radio_request_t)) ); assert_eq!( ::core::mem::align_of::(), 4usize, concat!("Alignment of ", stringify!(nrf_radio_request_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).request_type as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(nrf_radio_request_t), "::", stringify!(request_type) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).params as *const _ as usize }, 4usize, concat!( "Offset of field: ", stringify!(nrf_radio_request_t), "::", stringify!(params) ) ); } #[doc = "@brief Return parameters of the radio timeslot signal callback."] #[repr(C)] #[derive(Copy, Clone)] pub struct nrf_radio_signal_callback_return_param_t { #[doc = "< The action requested by the application when returning from the signal callback, see @ref NRF_RADIO_SIGNAL_CALLBACK_ACTION."] pub callback_action: u8, #[doc = "< Parameter union."] pub params: nrf_radio_signal_callback_return_param_t__bindgen_ty_1, } #[repr(C)] #[derive(Copy, Clone)] pub union nrf_radio_signal_callback_return_param_t__bindgen_ty_1 { #[doc = "< Additional parameters for return_code @ref NRF_RADIO_SIGNAL_CALLBACK_ACTION_REQUEST_AND_END."] pub request: nrf_radio_signal_callback_return_param_t__bindgen_ty_1__bindgen_ty_1, #[doc = "< Additional parameters for return_code @ref NRF_RADIO_SIGNAL_CALLBACK_ACTION_EXTEND."] pub extend: nrf_radio_signal_callback_return_param_t__bindgen_ty_1__bindgen_ty_2, _bindgen_union_align: u32, } #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct nrf_radio_signal_callback_return_param_t__bindgen_ty_1__bindgen_ty_1 { #[doc = "< The request parameters for the next radio timeslot."] pub p_next: *mut nrf_radio_request_t, } #[test] fn bindgen_test_layout_nrf_radio_signal_callback_return_param_t__bindgen_ty_1__bindgen_ty_1() { assert_eq!( ::core::mem::size_of::( ), 4usize, concat!( "Size of: ", stringify!(nrf_radio_signal_callback_return_param_t__bindgen_ty_1__bindgen_ty_1) ) ); assert_eq!( ::core::mem::align_of::( ), 4usize, concat!( "Alignment of ", stringify!(nrf_radio_signal_callback_return_param_t__bindgen_ty_1__bindgen_ty_1) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::< nrf_radio_signal_callback_return_param_t__bindgen_ty_1__bindgen_ty_1, >())) .p_next as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(nrf_radio_signal_callback_return_param_t__bindgen_ty_1__bindgen_ty_1), "::", stringify!(p_next) ) ); } #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct nrf_radio_signal_callback_return_param_t__bindgen_ty_1__bindgen_ty_2 { #[doc = "< Requested extension of the radio timeslot duration (microseconds) (for minimum time see @ref NRF_RADIO_MINIMUM_TIMESLOT_LENGTH_EXTENSION_TIME_US)."] pub length_us: u32, } #[test] fn bindgen_test_layout_nrf_radio_signal_callback_return_param_t__bindgen_ty_1__bindgen_ty_2() { assert_eq!( ::core::mem::size_of::( ), 4usize, concat!( "Size of: ", stringify!(nrf_radio_signal_callback_return_param_t__bindgen_ty_1__bindgen_ty_2) ) ); assert_eq!( ::core::mem::align_of::( ), 4usize, concat!( "Alignment of ", stringify!(nrf_radio_signal_callback_return_param_t__bindgen_ty_1__bindgen_ty_2) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::< nrf_radio_signal_callback_return_param_t__bindgen_ty_1__bindgen_ty_2, >())) .length_us as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(nrf_radio_signal_callback_return_param_t__bindgen_ty_1__bindgen_ty_2), "::", stringify!(length_us) ) ); } #[test] fn bindgen_test_layout_nrf_radio_signal_callback_return_param_t__bindgen_ty_1() { assert_eq!( ::core::mem::size_of::(), 4usize, concat!( "Size of: ", stringify!(nrf_radio_signal_callback_return_param_t__bindgen_ty_1) ) ); assert_eq!( ::core::mem::align_of::(), 4usize, concat!( "Alignment of ", stringify!(nrf_radio_signal_callback_return_param_t__bindgen_ty_1) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())) .request as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(nrf_radio_signal_callback_return_param_t__bindgen_ty_1), "::", stringify!(request) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())) .extend as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(nrf_radio_signal_callback_return_param_t__bindgen_ty_1), "::", stringify!(extend) ) ); } #[test] fn bindgen_test_layout_nrf_radio_signal_callback_return_param_t() { assert_eq!( ::core::mem::size_of::(), 8usize, concat!( "Size of: ", stringify!(nrf_radio_signal_callback_return_param_t) ) ); assert_eq!( ::core::mem::align_of::(), 4usize, concat!( "Alignment of ", stringify!(nrf_radio_signal_callback_return_param_t) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).callback_action as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(nrf_radio_signal_callback_return_param_t), "::", stringify!(callback_action) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).params as *const _ as usize }, 4usize, concat!( "Offset of field: ", stringify!(nrf_radio_signal_callback_return_param_t), "::", stringify!(params) ) ); } #[doc = "@brief The radio timeslot signal callback type."] #[doc = ""] #[doc = " @note In case of invalid return parameters, the radio timeslot will automatically end"] #[doc = " immediately after returning from the signal callback and the"] #[doc = " @ref NRF_EVT_RADIO_SIGNAL_CALLBACK_INVALID_RETURN event will be sent."] #[doc = " @note The returned struct pointer must remain valid after the signal callback"] #[doc = " function returns. For instance, this means that it must not point to a stack variable."] #[doc = ""] #[doc = " @param[in] signal_type Type of signal, see @ref NRF_RADIO_CALLBACK_SIGNAL_TYPE."] #[doc = ""] #[doc = " @return Pointer to structure containing action requested by the application."] pub type nrf_radio_signal_callback_t = ::core::option::Option< unsafe extern "C" fn(signal_type: u8) -> *mut nrf_radio_signal_callback_return_param_t, >; #[doc = "@brief AES ECB parameter typedefs"] pub type soc_ecb_key_t = [u8; 16usize]; pub type soc_ecb_cleartext_t = [u8; 16usize]; pub type soc_ecb_ciphertext_t = [u8; 16usize]; #[doc = "@brief AES ECB data structure"] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct nrf_ecb_hal_data_t { #[doc = "< Encryption key."] pub key: soc_ecb_key_t, #[doc = "< Cleartext data."] pub cleartext: soc_ecb_cleartext_t, #[doc = "< Ciphertext data."] pub ciphertext: soc_ecb_ciphertext_t, } #[test] fn bindgen_test_layout_nrf_ecb_hal_data_t() { assert_eq!( ::core::mem::size_of::(), 48usize, concat!("Size of: ", stringify!(nrf_ecb_hal_data_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!("Alignment of ", stringify!(nrf_ecb_hal_data_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).key as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(nrf_ecb_hal_data_t), "::", stringify!(key) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).cleartext as *const _ as usize }, 16usize, concat!( "Offset of field: ", stringify!(nrf_ecb_hal_data_t), "::", stringify!(cleartext) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).ciphertext as *const _ as usize }, 32usize, concat!( "Offset of field: ", stringify!(nrf_ecb_hal_data_t), "::", stringify!(ciphertext) ) ); } #[doc = "@brief AES ECB block. Used to provide multiple blocks in a single call"] #[doc = "to @ref sd_ecb_blocks_encrypt."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct nrf_ecb_hal_data_block_t { #[doc = "< Pointer to the Encryption key."] pub p_key: *const soc_ecb_key_t, #[doc = "< Pointer to the Cleartext data."] pub p_cleartext: *const soc_ecb_cleartext_t, #[doc = "< Pointer to the Ciphertext data."] pub p_ciphertext: *mut soc_ecb_ciphertext_t, } #[test] fn bindgen_test_layout_nrf_ecb_hal_data_block_t() { assert_eq!( ::core::mem::size_of::(), 12usize, concat!("Size of: ", stringify!(nrf_ecb_hal_data_block_t)) ); assert_eq!( ::core::mem::align_of::(), 4usize, concat!("Alignment of ", stringify!(nrf_ecb_hal_data_block_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).p_key as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(nrf_ecb_hal_data_block_t), "::", stringify!(p_key) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).p_cleartext as *const _ as usize }, 4usize, concat!( "Offset of field: ", stringify!(nrf_ecb_hal_data_block_t), "::", stringify!(p_cleartext) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).p_ciphertext as *const _ as usize }, 8usize, concat!( "Offset of field: ", stringify!(nrf_ecb_hal_data_block_t), "::", stringify!(p_ciphertext) ) ); } #[doc = "@brief Initialize a mutex."] #[doc = ""] #[doc = " @param[in] p_mutex Pointer to the mutex to initialize."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_mutex_new(p_mutex: *mut nrf_mutex_t) -> u32 { let ret: u32; core::arch::asm!("svc 44", inout("r0") to_asm(p_mutex) => ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Attempt to acquire a mutex."] #[doc = ""] #[doc = " @param[in] p_mutex Pointer to the mutex to acquire."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS The mutex was successfully acquired."] #[doc = " @retval ::NRF_ERROR_SOC_MUTEX_ALREADY_TAKEN The mutex could not be acquired."] #[inline(always)] pub unsafe fn sd_mutex_acquire(p_mutex: *mut nrf_mutex_t) -> u32 { let ret: u32; core::arch::asm!("svc 45", inout("r0") to_asm(p_mutex) => ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Release a mutex."] #[doc = ""] #[doc = " @param[in] p_mutex Pointer to the mutex to release."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_mutex_release(p_mutex: *mut nrf_mutex_t) -> u32 { let ret: u32; core::arch::asm!("svc 46", inout("r0") to_asm(p_mutex) => ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Query the capacity of the application random pool."] #[doc = ""] #[doc = " @param[out] p_pool_capacity The capacity of the pool."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_rand_application_pool_capacity_get(p_pool_capacity: *mut u8) -> u32 { let ret: u32; core::arch::asm!("svc 47", inout("r0") to_asm(p_pool_capacity) => ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Get number of random bytes available to the application."] #[doc = ""] #[doc = " @param[out] p_bytes_available The number of bytes currently available in the pool."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_rand_application_bytes_available_get(p_bytes_available: *mut u8) -> u32 { let ret: u32; core::arch::asm!("svc 48", inout("r0") to_asm(p_bytes_available) => ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Get random bytes from the application pool."] #[doc = ""] #[doc = " @param[out] p_buff Pointer to unit8_t buffer for storing the bytes."] #[doc = " @param[in] length Number of bytes to take from pool and place in p_buff."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS The requested bytes were written to p_buff."] #[doc = " @retval ::NRF_ERROR_SOC_RAND_NOT_ENOUGH_VALUES No bytes were written to the buffer, because there were not enough bytes available."] #[inline(always)] pub unsafe fn sd_rand_application_vector_get(p_buff: *mut u8, length: u8) -> u32 { let ret: u32; core::arch::asm!("svc 49", inout("r0") to_asm(p_buff) => ret, inout("r1") to_asm(length) => _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Gets the reset reason register."] #[doc = ""] #[doc = " @param[out] p_reset_reason Contents of the NRF_POWER->RESETREAS register."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_power_reset_reason_get(p_reset_reason: *mut u32) -> u32 { let ret: u32; core::arch::asm!("svc 52", inout("r0") to_asm(p_reset_reason) => ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Clears the bits of the reset reason register."] #[doc = ""] #[doc = " @param[in] reset_reason_clr_msk Contains the bits to clear from the reset reason register."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_power_reset_reason_clr(reset_reason_clr_msk: u32) -> u32 { let ret: u32; core::arch::asm!("svc 53", inout("r0") to_asm(reset_reason_clr_msk) => ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Sets the power mode when in CPU sleep."] #[doc = ""] #[doc = " @param[in] power_mode The power mode to use when in CPU sleep, see @ref NRF_POWER_MODES. @sa sd_app_evt_wait"] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS The power mode was set."] #[doc = " @retval ::NRF_ERROR_SOC_POWER_MODE_UNKNOWN The power mode was unknown."] #[inline(always)] pub unsafe fn sd_power_mode_set(power_mode: u8) -> u32 { let ret: u32; core::arch::asm!("svc 50", inout("r0") to_asm(power_mode) => ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Puts the chip in System OFF mode."] #[doc = ""] #[doc = " @retval ::NRF_ERROR_SOC_POWER_OFF_SHOULD_NOT_RETURN"] #[inline(always)] pub unsafe fn sd_power_system_off() -> u32 { let ret: u32; core::arch::asm!("svc 51", lateout("r0") ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Enables or disables the power-fail comparator."] #[doc = ""] #[doc = " Enabling this will give a SoftDevice event (NRF_EVT_POWER_FAILURE_WARNING) when the power failure warning occurs."] #[doc = " The event can be retrieved with sd_evt_get();"] #[doc = ""] #[doc = " @param[in] pof_enable True if the power-fail comparator should be enabled, false if it should be disabled."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_power_pof_enable(pof_enable: u8) -> u32 { let ret: u32; core::arch::asm!("svc 54", inout("r0") to_asm(pof_enable) => ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Enables or disables the USB power ready event."] #[doc = ""] #[doc = " Enabling this will give a SoftDevice event (NRF_EVT_POWER_USB_POWER_READY) when a USB 3.3 V supply is ready."] #[doc = " The event can be retrieved with sd_evt_get();"] #[doc = ""] #[doc = " @param[in] usbpwrrdy_enable True if the power ready event should be enabled, false if it should be disabled."] #[doc = ""] #[doc = " @note Calling this function on a chip without USBD peripheral will result in undefined behaviour."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_power_usbpwrrdy_enable(usbpwrrdy_enable: u8) -> u32 { let ret: u32; core::arch::asm!("svc 77", inout("r0") to_asm(usbpwrrdy_enable) => ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Enables or disables the power USB-detected event."] #[doc = ""] #[doc = " Enabling this will give a SoftDevice event (NRF_EVT_POWER_USB_DETECTED) when a voltage supply is detected on VBUS."] #[doc = " The event can be retrieved with sd_evt_get();"] #[doc = ""] #[doc = " @param[in] usbdetected_enable True if the power ready event should be enabled, false if it should be disabled."] #[doc = ""] #[doc = " @note Calling this function on a chip without USBD peripheral will result in undefined behaviour."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_power_usbdetected_enable(usbdetected_enable: u8) -> u32 { let ret: u32; core::arch::asm!("svc 78", inout("r0") to_asm(usbdetected_enable) => ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Enables or disables the power USB-removed event."] #[doc = ""] #[doc = " Enabling this will give a SoftDevice event (NRF_EVT_POWER_USB_REMOVED) when a voltage supply is removed from VBUS."] #[doc = " The event can be retrieved with sd_evt_get();"] #[doc = ""] #[doc = " @param[in] usbremoved_enable True if the power ready event should be enabled, false if it should be disabled."] #[doc = ""] #[doc = " @note Calling this function on a chip without USBD peripheral will result in undefined behaviour."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_power_usbremoved_enable(usbremoved_enable: u8) -> u32 { let ret: u32; core::arch::asm!("svc 79", inout("r0") to_asm(usbremoved_enable) => ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Get USB supply status register content."] #[doc = ""] #[doc = " @param[out] usbregstatus The content of USBREGSTATUS register."] #[doc = ""] #[doc = " @note Calling this function on a chip without USBD peripheral will result in undefined behaviour."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_power_usbregstatus_get(usbregstatus: *mut u32) -> u32 { let ret: u32; core::arch::asm!("svc 80", inout("r0") to_asm(usbregstatus) => ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Sets the power failure comparator threshold value."] #[doc = ""] #[doc = " @note: Power failure comparator threshold setting. This setting applies both for normal voltage"] #[doc = " mode (supply connected to both VDD and VDDH) and high voltage mode (supply connected to"] #[doc = " VDDH only)."] #[doc = ""] #[doc = " @param[in] threshold The power-fail threshold value to use, see @ref NRF_POWER_THRESHOLDS."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS The power failure threshold was set."] #[doc = " @retval ::NRF_ERROR_SOC_POWER_POF_THRESHOLD_UNKNOWN The power failure threshold is unknown."] #[inline(always)] pub unsafe fn sd_power_pof_threshold_set(threshold: u8) -> u32 { let ret: u32; core::arch::asm!("svc 55", inout("r0") to_asm(threshold) => ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Sets the power failure comparator threshold value for high voltage."] #[doc = ""] #[doc = " @note: Power failure comparator threshold setting for high voltage mode (supply connected to"] #[doc = " VDDH only). This setting does not apply for normal voltage mode (supply connected to both"] #[doc = " VDD and VDDH)."] #[doc = ""] #[doc = " @param[in] threshold The power-fail threshold value to use, see @ref NRF_POWER_THRESHOLDVDDHS."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS The power failure threshold was set."] #[doc = " @retval ::NRF_ERROR_SOC_POWER_POF_THRESHOLD_UNKNOWN The power failure threshold is unknown."] #[inline(always)] pub unsafe fn sd_power_pof_thresholdvddh_set(threshold: u8) -> u32 { let ret: u32; core::arch::asm!("svc 56", inout("r0") to_asm(threshold) => ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Writes the NRF_POWER->RAM[index].POWERSET register."] #[doc = ""] #[doc = " @param[in] index Contains the index in the NRF_POWER->RAM[index].POWERSET register to write to."] #[doc = " @param[in] ram_powerset Contains the word to write to the NRF_POWER->RAM[index].POWERSET register."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_power_ram_power_set(index: u8, ram_powerset: u32) -> u32 { let ret: u32; core::arch::asm!("svc 57", inout("r0") to_asm(index) => ret, inout("r1") to_asm(ram_powerset) => _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Writes the NRF_POWER->RAM[index].POWERCLR register."] #[doc = ""] #[doc = " @param[in] index Contains the index in the NRF_POWER->RAM[index].POWERCLR register to write to."] #[doc = " @param[in] ram_powerclr Contains the word to write to the NRF_POWER->RAM[index].POWERCLR register."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_power_ram_power_clr(index: u8, ram_powerclr: u32) -> u32 { let ret: u32; core::arch::asm!("svc 58", inout("r0") to_asm(index) => ret, inout("r1") to_asm(ram_powerclr) => _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Get contents of NRF_POWER->RAM[index].POWER register, indicates power status of RAM[index] blocks."] #[doc = ""] #[doc = " @param[in] index Contains the index in the NRF_POWER->RAM[index].POWER register to read from."] #[doc = " @param[out] p_ram_power Content of NRF_POWER->RAM[index].POWER register."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_power_ram_power_get(index: u8, p_ram_power: *mut u32) -> u32 { let ret: u32; core::arch::asm!("svc 59", inout("r0") to_asm(index) => ret, inout("r1") to_asm(p_ram_power) => _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Set bits in the general purpose retention registers (NRF_POWER->GPREGRET*)."] #[doc = ""] #[doc = " @param[in] gpregret_id 0 for GPREGRET, 1 for GPREGRET2."] #[doc = " @param[in] gpregret_msk Bits to be set in the GPREGRET register."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_power_gpregret_set(gpregret_id: u32, gpregret_msk: u32) -> u32 { let ret: u32; core::arch::asm!("svc 60", inout("r0") to_asm(gpregret_id) => ret, inout("r1") to_asm(gpregret_msk) => _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Clear bits in the general purpose retention registers (NRF_POWER->GPREGRET*)."] #[doc = ""] #[doc = " @param[in] gpregret_id 0 for GPREGRET, 1 for GPREGRET2."] #[doc = " @param[in] gpregret_msk Bits to be clear in the GPREGRET register."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_power_gpregret_clr(gpregret_id: u32, gpregret_msk: u32) -> u32 { let ret: u32; core::arch::asm!("svc 61", inout("r0") to_asm(gpregret_id) => ret, inout("r1") to_asm(gpregret_msk) => _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Get contents of the general purpose retention registers (NRF_POWER->GPREGRET*)."] #[doc = ""] #[doc = " @param[in] gpregret_id 0 for GPREGRET, 1 for GPREGRET2."] #[doc = " @param[out] p_gpregret Contents of the GPREGRET register."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_power_gpregret_get(gpregret_id: u32, p_gpregret: *mut u32) -> u32 { let ret: u32; core::arch::asm!("svc 62", inout("r0") to_asm(gpregret_id) => ret, inout("r1") to_asm(p_gpregret) => _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Enable or disable the DC/DC regulator for the regulator stage 1 (REG1)."] #[doc = ""] #[doc = " @param[in] dcdc_mode The mode of the DCDC, see @ref NRF_POWER_DCDC_MODES."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[doc = " @retval ::NRF_ERROR_INVALID_PARAM The DCDC mode is invalid."] #[inline(always)] pub unsafe fn sd_power_dcdc_mode_set(dcdc_mode: u8) -> u32 { let ret: u32; core::arch::asm!("svc 63", inout("r0") to_asm(dcdc_mode) => ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Enable or disable the DC/DC regulator for the regulator stage 0 (REG0)."] #[doc = ""] #[doc = " For more details on the REG0 stage, please see product specification."] #[doc = ""] #[doc = " @param[in] dcdc_mode The mode of the DCDC0, see @ref NRF_POWER_DCDC_MODES."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[doc = " @retval ::NRF_ERROR_INVALID_PARAM The dcdc_mode is invalid."] #[inline(always)] pub unsafe fn sd_power_dcdc0_mode_set(dcdc_mode: u8) -> u32 { let ret: u32; core::arch::asm!("svc 64", inout("r0") to_asm(dcdc_mode) => ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Request the high frequency crystal oscillator."] #[doc = ""] #[doc = " Will start the high frequency crystal oscillator, the startup time of the crystal varies"] #[doc = " and the ::sd_clock_hfclk_is_running function can be polled to check if it has started."] #[doc = ""] #[doc = " @see sd_clock_hfclk_is_running"] #[doc = " @see sd_clock_hfclk_release"] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_clock_hfclk_request() -> u32 { let ret: u32; core::arch::asm!("svc 66", lateout("r0") ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Releases the high frequency crystal oscillator."] #[doc = ""] #[doc = " Will stop the high frequency crystal oscillator, this happens immediately."] #[doc = ""] #[doc = " @see sd_clock_hfclk_is_running"] #[doc = " @see sd_clock_hfclk_request"] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_clock_hfclk_release() -> u32 { let ret: u32; core::arch::asm!("svc 67", lateout("r0") ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Checks if the high frequency crystal oscillator is running."] #[doc = ""] #[doc = " @see sd_clock_hfclk_request"] #[doc = " @see sd_clock_hfclk_release"] #[doc = ""] #[doc = " @param[out] p_is_running 1 if the external crystal oscillator is running, 0 if not."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_clock_hfclk_is_running(p_is_running: *mut u32) -> u32 { let ret: u32; core::arch::asm!("svc 68", inout("r0") to_asm(p_is_running) => ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Waits for an application event."] #[doc = ""] #[doc = " An application event is either an application interrupt or a pended interrupt when the interrupt"] #[doc = " is disabled."] #[doc = ""] #[doc = " When the application waits for an application event by calling this function, an interrupt that"] #[doc = " is enabled will be taken immediately on pending since this function will wait in thread mode,"] #[doc = " then the execution will return in the application's main thread."] #[doc = ""] #[doc = " In order to wake up from disabled interrupts, the SEVONPEND flag has to be set in the Cortex-M"] #[doc = " MCU's System Control Register (SCR), CMSIS_SCB. In that case, when a disabled interrupt gets"] #[doc = " pended, this function will return to the application's main thread."] #[doc = ""] #[doc = " @note The application must ensure that the pended flag is cleared using ::sd_nvic_ClearPendingIRQ"] #[doc = " in order to sleep using this function. This is only necessary for disabled interrupts, as"] #[doc = " the interrupt handler will clear the pending flag automatically for enabled interrupts."] #[doc = ""] #[doc = " @note If an application interrupt has happened since the last time sd_app_evt_wait was"] #[doc = " called this function will return immediately and not go to sleep. This is to avoid race"] #[doc = " conditions that can occur when a flag is updated in the interrupt handler and processed"] #[doc = " in the main loop."] #[doc = ""] #[doc = " @post An application interrupt has happened or a interrupt pending flag is set."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_app_evt_wait() -> u32 { let ret: u32; core::arch::asm!("svc 65", lateout("r0") ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Get PPI channel enable register contents."] #[doc = ""] #[doc = " @param[out] p_channel_enable The contents of the PPI CHEN register."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_ppi_channel_enable_get(p_channel_enable: *mut u32) -> u32 { let ret: u32; core::arch::asm!("svc 32", inout("r0") to_asm(p_channel_enable) => ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Set PPI channel enable register."] #[doc = ""] #[doc = " @param[in] channel_enable_set_msk Mask containing the bits to set in the PPI CHEN register."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_ppi_channel_enable_set(channel_enable_set_msk: u32) -> u32 { let ret: u32; core::arch::asm!("svc 33", inout("r0") to_asm(channel_enable_set_msk) => ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Clear PPI channel enable register."] #[doc = ""] #[doc = " @param[in] channel_enable_clr_msk Mask containing the bits to clear in the PPI CHEN register."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_ppi_channel_enable_clr(channel_enable_clr_msk: u32) -> u32 { let ret: u32; core::arch::asm!("svc 34", inout("r0") to_asm(channel_enable_clr_msk) => ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Assign endpoints to a PPI channel."] #[doc = ""] #[doc = " @param[in] channel_num Number of the PPI channel to assign."] #[doc = " @param[in] evt_endpoint Event endpoint of the PPI channel."] #[doc = " @param[in] task_endpoint Task endpoint of the PPI channel."] #[doc = ""] #[doc = " @retval ::NRF_ERROR_SOC_PPI_INVALID_CHANNEL The channel number is invalid."] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_ppi_channel_assign( channel_num: u8, evt_endpoint: *const self::c_void, task_endpoint: *const self::c_void, ) -> u32 { let ret: u32; core::arch::asm!("svc 35", inout("r0") to_asm(channel_num) => ret, inout("r1") to_asm(evt_endpoint) => _, inout("r2") to_asm(task_endpoint) => _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Task to enable a channel group."] #[doc = ""] #[doc = " @param[in] group_num Number of the channel group."] #[doc = ""] #[doc = " @retval ::NRF_ERROR_SOC_PPI_INVALID_GROUP The group number is invalid"] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_ppi_group_task_enable(group_num: u8) -> u32 { let ret: u32; core::arch::asm!("svc 36", inout("r0") to_asm(group_num) => ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Task to disable a channel group."] #[doc = ""] #[doc = " @param[in] group_num Number of the PPI group."] #[doc = ""] #[doc = " @retval ::NRF_ERROR_SOC_PPI_INVALID_GROUP The group number is invalid."] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_ppi_group_task_disable(group_num: u8) -> u32 { let ret: u32; core::arch::asm!("svc 37", inout("r0") to_asm(group_num) => ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Assign PPI channels to a channel group."] #[doc = ""] #[doc = " @param[in] group_num Number of the channel group."] #[doc = " @param[in] channel_msk Mask of the channels to assign to the group."] #[doc = ""] #[doc = " @retval ::NRF_ERROR_SOC_PPI_INVALID_GROUP The group number is invalid."] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_ppi_group_assign(group_num: u8, channel_msk: u32) -> u32 { let ret: u32; core::arch::asm!("svc 38", inout("r0") to_asm(group_num) => ret, inout("r1") to_asm(channel_msk) => _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Gets the PPI channels of a channel group."] #[doc = ""] #[doc = " @param[in] group_num Number of the channel group."] #[doc = " @param[out] p_channel_msk Mask of the channels assigned to the group."] #[doc = ""] #[doc = " @retval ::NRF_ERROR_SOC_PPI_INVALID_GROUP The group number is invalid."] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_ppi_group_get(group_num: u8, p_channel_msk: *mut u32) -> u32 { let ret: u32; core::arch::asm!("svc 39", inout("r0") to_asm(group_num) => ret, inout("r1") to_asm(p_channel_msk) => _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Configures the Radio Notification signal."] #[doc = ""] #[doc = " @note"] #[doc = " - The notification signal latency depends on the interrupt priority settings of SWI used"] #[doc = " for notification signal."] #[doc = " - To ensure that the radio notification signal behaves in a consistent way, the radio"] #[doc = " notifications must be configured when there is no protocol stack or other SoftDevice"] #[doc = " activity in progress. It is recommended that the radio notification signal is"] #[doc = " configured directly after the SoftDevice has been enabled."] #[doc = " - In the period between the ACTIVE signal and the start of the Radio Event, the SoftDevice"] #[doc = " will interrupt the application to do Radio Event preparation."] #[doc = " - Using the Radio Notification feature may limit the bandwidth, as the SoftDevice may have"] #[doc = " to shorten the connection events to have time for the Radio Notification signals."] #[doc = ""] #[doc = " @param[in] type Type of notification signal, see @ref NRF_RADIO_NOTIFICATION_TYPES."] #[doc = " @ref NRF_RADIO_NOTIFICATION_TYPE_NONE shall be used to turn off radio"] #[doc = " notification. Using @ref NRF_RADIO_NOTIFICATION_DISTANCE_NONE is"] #[doc = " recommended (but not required) to be used with"] #[doc = " @ref NRF_RADIO_NOTIFICATION_TYPE_NONE."] #[doc = ""] #[doc = " @param[in] distance Distance between the notification signal and start of radio activity, see @ref NRF_RADIO_NOTIFICATION_DISTANCES."] #[doc = " This parameter is ignored when @ref NRF_RADIO_NOTIFICATION_TYPE_NONE or"] #[doc = " @ref NRF_RADIO_NOTIFICATION_TYPE_INT_ON_INACTIVE is used."] #[doc = ""] #[doc = " @retval ::NRF_ERROR_INVALID_PARAM The group number is invalid."] #[doc = " @retval ::NRF_ERROR_INVALID_STATE A protocol stack or other SoftDevice is running. Stop all"] #[doc = " running activities and retry."] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_radio_notification_cfg_set(type_: u8, distance: u8) -> u32 { let ret: u32; core::arch::asm!("svc 69", inout("r0") to_asm(type_) => ret, inout("r1") to_asm(distance) => _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Encrypts a block according to the specified parameters."] #[doc = ""] #[doc = " 128-bit AES encryption."] #[doc = ""] #[doc = " @note:"] #[doc = " - The application may set the SEVONPEND bit in the SCR to 1 to make the SoftDevice sleep while"] #[doc = " the ECB is running. The SEVONPEND bit should only be cleared (set to 0) from application"] #[doc = " main or low interrupt level."] #[doc = ""] #[doc = " @param[in, out] p_ecb_data Pointer to the ECB parameters' struct (two input"] #[doc = " parameters and one output parameter)."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_ecb_block_encrypt(p_ecb_data: *mut nrf_ecb_hal_data_t) -> u32 { let ret: u32; core::arch::asm!("svc 70", inout("r0") to_asm(p_ecb_data) => ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Encrypts multiple data blocks provided as an array of data block structures."] #[doc = ""] #[doc = " @details: Performs 128-bit AES encryption on multiple data blocks"] #[doc = ""] #[doc = " @note:"] #[doc = " - The application may set the SEVONPEND bit in the SCR to 1 to make the SoftDevice sleep while"] #[doc = " the ECB is running. The SEVONPEND bit should only be cleared (set to 0) from application"] #[doc = " main or low interrupt level."] #[doc = ""] #[doc = " @param[in] block_count Count of blocks in the p_data_blocks array."] #[doc = " @param[in,out] p_data_blocks Pointer to the first entry in a contiguous array of"] #[doc = " @ref nrf_ecb_hal_data_block_t structures."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_ecb_blocks_encrypt( block_count: u8, p_data_blocks: *mut nrf_ecb_hal_data_block_t, ) -> u32 { let ret: u32; core::arch::asm!("svc 71", inout("r0") to_asm(block_count) => ret, inout("r1") to_asm(p_data_blocks) => _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Gets any pending events generated by the SoC API."] #[doc = ""] #[doc = " The application should keep calling this function to get events, until ::NRF_ERROR_NOT_FOUND is returned."] #[doc = ""] #[doc = " @param[out] p_evt_id Set to one of the values in @ref NRF_SOC_EVTS, if any events are pending."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS An event was pending. The event id is written in the p_evt_id parameter."] #[doc = " @retval ::NRF_ERROR_NOT_FOUND No pending events."] #[inline(always)] pub unsafe fn sd_evt_get(p_evt_id: *mut u32) -> u32 { let ret: u32; core::arch::asm!("svc 75", inout("r0") to_asm(p_evt_id) => ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Get the temperature measured on the chip"] #[doc = ""] #[doc = " This function will block until the temperature measurement is done."] #[doc = " It takes around 50 us from call to return."] #[doc = ""] #[doc = " @param[out] p_temp Result of temperature measurement. Die temperature in 0.25 degrees Celsius."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS A temperature measurement was done, and the temperature was written to temp"] #[inline(always)] pub unsafe fn sd_temp_get(p_temp: *mut i32) -> u32 { let ret: u32; core::arch::asm!("svc 76", inout("r0") to_asm(p_temp) => ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Flash Write"] #[doc = ""] #[doc = " Commands to write a buffer to flash"] #[doc = ""] #[doc = " If the SoftDevice is enabled:"] #[doc = " This call initiates the flash access command, and its completion will be communicated to the"] #[doc = " application with exactly one of the following events:"] #[doc = " - @ref NRF_EVT_FLASH_OPERATION_SUCCESS - The command was successfully completed."] #[doc = " - @ref NRF_EVT_FLASH_OPERATION_ERROR - The command could not be started."] #[doc = ""] #[doc = " If the SoftDevice is not enabled no event will be generated, and this call will return @ref NRF_SUCCESS when the"] #[doc = " write has been completed"] #[doc = ""] #[doc = " @note"] #[doc = " - This call takes control over the radio and the CPU during flash erase and write to make sure that"] #[doc = " they will not interfere with the flash access. This means that all interrupts will be blocked"] #[doc = " for a predictable time (depending on the NVMC specification in the device's Product Specification"] #[doc = " and the command parameters)."] #[doc = " - The data in the p_src buffer should not be modified before the @ref NRF_EVT_FLASH_OPERATION_SUCCESS"] #[doc = " or the @ref NRF_EVT_FLASH_OPERATION_ERROR have been received if the SoftDevice is enabled."] #[doc = " - This call will make the SoftDevice trigger a hardfault when the page is written, if it is"] #[doc = " protected."] #[doc = ""] #[doc = ""] #[doc = " @param[in] p_dst Pointer to start of flash location to be written."] #[doc = " @param[in] p_src Pointer to buffer with data to be written."] #[doc = " @param[in] size Number of 32-bit words to write. Maximum size is the number of words in one"] #[doc = " flash page. See the device's Product Specification for details."] #[doc = ""] #[doc = " @retval ::NRF_ERROR_INVALID_ADDR Tried to write to a non existing flash address, or p_dst or p_src was unaligned."] #[doc = " @retval ::NRF_ERROR_BUSY The previous command has not yet completed."] #[doc = " @retval ::NRF_ERROR_INVALID_LENGTH Size was 0, or higher than the maximum allowed size."] #[doc = " @retval ::NRF_ERROR_FORBIDDEN Tried to write to an address outside the application flash area."] #[doc = " @retval ::NRF_SUCCESS The command was accepted."] #[inline(always)] pub unsafe fn sd_flash_write(p_dst: *mut u32, p_src: *const u32, size: u32) -> u32 { let ret: u32; core::arch::asm!("svc 41", inout("r0") to_asm(p_dst) => ret, inout("r1") to_asm(p_src) => _, inout("r2") to_asm(size) => _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Flash Erase page"] #[doc = ""] #[doc = " Commands to erase a flash page"] #[doc = " If the SoftDevice is enabled:"] #[doc = " This call initiates the flash access command, and its completion will be communicated to the"] #[doc = " application with exactly one of the following events:"] #[doc = " - @ref NRF_EVT_FLASH_OPERATION_SUCCESS - The command was successfully completed."] #[doc = " - @ref NRF_EVT_FLASH_OPERATION_ERROR - The command could not be started."] #[doc = ""] #[doc = " If the SoftDevice is not enabled no event will be generated, and this call will return @ref NRF_SUCCESS when the"] #[doc = " erase has been completed"] #[doc = ""] #[doc = " @note"] #[doc = " - This call takes control over the radio and the CPU during flash erase and write to make sure that"] #[doc = " they will not interfere with the flash access. This means that all interrupts will be blocked"] #[doc = " for a predictable time (depending on the NVMC specification in the device's Product Specification"] #[doc = " and the command parameters)."] #[doc = " - This call will make the SoftDevice trigger a hardfault when the page is erased, if it is"] #[doc = " protected."] #[doc = ""] #[doc = ""] #[doc = " @param[in] page_number Page number of the page to erase"] #[doc = ""] #[doc = " @retval ::NRF_ERROR_INTERNAL If a new session could not be opened due to an internal error."] #[doc = " @retval ::NRF_ERROR_INVALID_ADDR Tried to erase to a non existing flash page."] #[doc = " @retval ::NRF_ERROR_BUSY The previous command has not yet completed."] #[doc = " @retval ::NRF_ERROR_FORBIDDEN Tried to erase a page outside the application flash area."] #[doc = " @retval ::NRF_SUCCESS The command was accepted."] #[inline(always)] pub unsafe fn sd_flash_page_erase(page_number: u32) -> u32 { let ret: u32; core::arch::asm!("svc 40", inout("r0") to_asm(page_number) => ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Opens a session for radio timeslot requests."] #[doc = ""] #[doc = " @note Only one session can be open at a time."] #[doc = " @note p_radio_signal_callback(@ref NRF_RADIO_CALLBACK_SIGNAL_TYPE_START) will be called when the radio timeslot"] #[doc = " starts. From this point the NRF_RADIO and NRF_TIMER0 peripherals can be freely accessed"] #[doc = " by the application."] #[doc = " @note p_radio_signal_callback(@ref NRF_RADIO_CALLBACK_SIGNAL_TYPE_TIMER0) is called whenever the NRF_TIMER0"] #[doc = " interrupt occurs."] #[doc = " @note p_radio_signal_callback(@ref NRF_RADIO_CALLBACK_SIGNAL_TYPE_RADIO) is called whenever the NRF_RADIO"] #[doc = " interrupt occurs."] #[doc = " @note p_radio_signal_callback() will be called at ARM interrupt priority level 0. This"] #[doc = " implies that none of the sd_* API calls can be used from p_radio_signal_callback()."] #[doc = ""] #[doc = " @param[in] p_radio_signal_callback The signal callback."] #[doc = ""] #[doc = " @retval ::NRF_ERROR_INVALID_ADDR p_radio_signal_callback is an invalid function pointer."] #[doc = " @retval ::NRF_ERROR_BUSY If session cannot be opened."] #[doc = " @retval ::NRF_ERROR_INTERNAL If a new session could not be opened due to an internal error."] #[doc = " @retval ::NRF_SUCCESS Otherwise."] #[inline(always)] pub unsafe fn sd_radio_session_open(p_radio_signal_callback: nrf_radio_signal_callback_t) -> u32 { let ret: u32; core::arch::asm!("svc 72", inout("r0") to_asm(p_radio_signal_callback) => ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Closes a session for radio timeslot requests."] #[doc = ""] #[doc = " @note Any current radio timeslot will be finished before the session is closed."] #[doc = " @note If a radio timeslot is scheduled when the session is closed, it will be canceled."] #[doc = " @note The application cannot consider the session closed until the @ref NRF_EVT_RADIO_SESSION_CLOSED"] #[doc = " event is received."] #[doc = ""] #[doc = " @retval ::NRF_ERROR_FORBIDDEN If session not opened."] #[doc = " @retval ::NRF_ERROR_BUSY If session is currently being closed."] #[doc = " @retval ::NRF_SUCCESS Otherwise."] #[inline(always)] pub unsafe fn sd_radio_session_close() -> u32 { let ret: u32; core::arch::asm!("svc 73", lateout("r0") ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Requests a radio timeslot."] #[doc = ""] #[doc = " @note The request type is determined by p_request->request_type, and can be one of @ref NRF_RADIO_REQ_TYPE_EARLIEST"] #[doc = " and @ref NRF_RADIO_REQ_TYPE_NORMAL. The first request in a session must always be of type @ref NRF_RADIO_REQ_TYPE_EARLIEST."] #[doc = " @note For a normal request (@ref NRF_RADIO_REQ_TYPE_NORMAL), the start time of a radio timeslot is specified by"] #[doc = " p_request->distance_us and is given relative to the start of the previous timeslot."] #[doc = " @note A too small p_request->distance_us will lead to a @ref NRF_EVT_RADIO_BLOCKED event."] #[doc = " @note Timeslots scheduled too close will lead to a @ref NRF_EVT_RADIO_BLOCKED event."] #[doc = " @note See the SoftDevice Specification for more on radio timeslot scheduling, distances and lengths."] #[doc = " @note If an opportunity for the first radio timeslot is not found before 100 ms after the call to this"] #[doc = " function, it is not scheduled, and instead a @ref NRF_EVT_RADIO_BLOCKED event is sent."] #[doc = " The application may then try to schedule the first radio timeslot again."] #[doc = " @note Successful requests will result in nrf_radio_signal_callback_t(@ref NRF_RADIO_CALLBACK_SIGNAL_TYPE_START)."] #[doc = " Unsuccessful requests will result in a @ref NRF_EVT_RADIO_BLOCKED event, see @ref NRF_SOC_EVTS."] #[doc = " @note The jitter in the start time of the radio timeslots is +/- @ref NRF_RADIO_START_JITTER_US us."] #[doc = " @note The nrf_radio_signal_callback_t(@ref NRF_RADIO_CALLBACK_SIGNAL_TYPE_START) call has a latency relative to the"] #[doc = " specified radio timeslot start, but this does not affect the actual start time of the timeslot."] #[doc = " @note NRF_TIMER0 is reset at the start of the radio timeslot, and is clocked at 1MHz from the high frequency"] #[doc = " (16 MHz) clock source. If p_request->hfclk_force_xtal is true, the high frequency clock is"] #[doc = " guaranteed to be clocked from the external crystal."] #[doc = " @note The SoftDevice will neither access the NRF_RADIO peripheral nor the NRF_TIMER0 peripheral"] #[doc = " during the radio timeslot."] #[doc = ""] #[doc = " @param[in] p_request Pointer to the request parameters."] #[doc = ""] #[doc = " @retval ::NRF_ERROR_FORBIDDEN Either:"] #[doc = " - The session is not open."] #[doc = " - The session is not IDLE."] #[doc = " - This is the first request and its type is not @ref NRF_RADIO_REQ_TYPE_EARLIEST."] #[doc = " - The request type was set to @ref NRF_RADIO_REQ_TYPE_NORMAL after a"] #[doc = " @ref NRF_RADIO_REQ_TYPE_EARLIEST request was blocked."] #[doc = " @retval ::NRF_ERROR_INVALID_ADDR If the p_request pointer is invalid."] #[doc = " @retval ::NRF_ERROR_INVALID_PARAM If the parameters of p_request are not valid."] #[doc = " @retval ::NRF_SUCCESS Otherwise."] #[inline(always)] pub unsafe fn sd_radio_request(p_request: *const nrf_radio_request_t) -> u32 { let ret: u32; core::arch::asm!("svc 74", inout("r0") to_asm(p_request) => ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Write register protected by the SoftDevice"] #[doc = ""] #[doc = " This function writes to a register that is write-protected by the SoftDevice. Please refer to your"] #[doc = " SoftDevice Specification for more details about which registers that are protected by SoftDevice."] #[doc = " This function can write to the following protected peripheral:"] #[doc = " - ACL"] #[doc = ""] #[doc = " @note Protected registers may be read directly."] #[doc = " @note Register that are write-once will return @ref NRF_SUCCESS on second set, even the value in"] #[doc = " the register has not changed. See the Product Specification for more details about register"] #[doc = " properties."] #[doc = ""] #[doc = " @param[in] p_register Pointer to register to be written."] #[doc = " @param[in] value Value to be written to the register."] #[doc = ""] #[doc = " @retval ::NRF_ERROR_INVALID_ADDR This function can not write to the reguested register."] #[doc = " @retval ::NRF_SUCCESS Value successfully written to register."] #[doc = ""] #[inline(always)] pub unsafe fn sd_protected_register_write(p_register: *mut u32, value: u32) -> u32 { let ret: u32; core::arch::asm!("svc 43", inout("r0") to_asm(p_register) => ret, inout("r1") to_asm(value) => _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "< ::sd_softdevice_enable"] pub const NRF_SD_SVCS_SD_SOFTDEVICE_ENABLE: NRF_SD_SVCS = 16; #[doc = "< ::sd_softdevice_disable"] pub const NRF_SD_SVCS_SD_SOFTDEVICE_DISABLE: NRF_SD_SVCS = 17; #[doc = "< ::sd_softdevice_is_enabled"] pub const NRF_SD_SVCS_SD_SOFTDEVICE_IS_ENABLED: NRF_SD_SVCS = 18; #[doc = "< ::sd_softdevice_vector_table_base_set"] pub const NRF_SD_SVCS_SD_SOFTDEVICE_VECTOR_TABLE_BASE_SET: NRF_SD_SVCS = 19; #[doc = "< Placeholder for last SDM SVC"] pub const NRF_SD_SVCS_SVC_SDM_LAST: NRF_SD_SVCS = 20; #[doc = "@brief nRF SoftDevice Manager API SVC numbers."] pub type NRF_SD_SVCS = self::c_uint; #[doc = "@brief Type representing LFCLK oscillator source."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct nrf_clock_lf_cfg_t { #[doc = "< LF oscillator clock source, see @ref NRF_CLOCK_LF_SRC."] pub source: u8, #[doc = "< Only for ::NRF_CLOCK_LF_SRC_RC: Calibration timer interval in 1/4 second"] #[doc = "units (nRF52: 1-32)."] #[doc = "@note To avoid excessive clock drift, 0.5 degrees Celsius is the"] #[doc = "maximum temperature change allowed in one calibration timer"] #[doc = "interval. The interval should be selected to ensure this."] #[doc = ""] #[doc = "@note Must be 0 if source is not ::NRF_CLOCK_LF_SRC_RC."] pub rc_ctiv: u8, #[doc = "< Only for ::NRF_CLOCK_LF_SRC_RC: How often (in number of calibration"] #[doc = "intervals) the RC oscillator shall be calibrated if the temperature"] #[doc = "hasn't changed."] #[doc = "0: Always calibrate even if the temperature hasn't changed."] #[doc = "1: Only calibrate if the temperature has changed (legacy - nRF51 only)."] #[doc = "2-33: Check the temperature and only calibrate if it has changed,"] #[doc = "however calibration will take place every rc_temp_ctiv"] #[doc = "intervals in any case."] #[doc = ""] #[doc = "@note Must be 0 if source is not ::NRF_CLOCK_LF_SRC_RC."] #[doc = ""] #[doc = "@note For nRF52, the application must ensure calibration at least once"] #[doc = "every 8 seconds to ensure +/-500 ppm clock stability. The"] #[doc = "recommended configuration for ::NRF_CLOCK_LF_SRC_RC on nRF52 is"] #[doc = "rc_ctiv=16 and rc_temp_ctiv=2. This will ensure calibration at"] #[doc = "least once every 8 seconds and for temperature changes of 0.5"] #[doc = "degrees Celsius every 4 seconds. See the Product Specification"] #[doc = "for the nRF52 device being used for more information."] pub rc_temp_ctiv: u8, #[doc = "< External clock accuracy used in the LL to compute timing"] #[doc = "windows, see @ref NRF_CLOCK_LF_ACCURACY."] pub accuracy: u8, } #[test] fn bindgen_test_layout_nrf_clock_lf_cfg_t() { assert_eq!( ::core::mem::size_of::(), 4usize, concat!("Size of: ", stringify!(nrf_clock_lf_cfg_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!("Alignment of ", stringify!(nrf_clock_lf_cfg_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).source as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(nrf_clock_lf_cfg_t), "::", stringify!(source) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).rc_ctiv as *const _ as usize }, 1usize, concat!( "Offset of field: ", stringify!(nrf_clock_lf_cfg_t), "::", stringify!(rc_ctiv) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).rc_temp_ctiv as *const _ as usize }, 2usize, concat!( "Offset of field: ", stringify!(nrf_clock_lf_cfg_t), "::", stringify!(rc_temp_ctiv) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).accuracy as *const _ as usize }, 3usize, concat!( "Offset of field: ", stringify!(nrf_clock_lf_cfg_t), "::", stringify!(accuracy) ) ); } #[doc = "@brief Fault Handler type."] #[doc = ""] #[doc = " When certain unrecoverable errors occur within the application or SoftDevice the fault handler will be called back."] #[doc = " The protocol stack will be in an undefined state when this happens and the only way to recover will be to"] #[doc = " perform a reset, using e.g. CMSIS NVIC_SystemReset()."] #[doc = " If the application returns from the fault handler the SoftDevice will call NVIC_SystemReset()."] #[doc = ""] #[doc = " @note It is recommended to either perform a reset in the fault handler or to let the SoftDevice reset the device."] #[doc = " Otherwise SoC peripherals may behave in an undefined way. For example, the RADIO peripherial may"] #[doc = " continously transmit packets."] #[doc = ""] #[doc = " @note This callback is executed in HardFault context, thus SVC functions cannot be called from the fault callback."] #[doc = ""] #[doc = " @param[in] id Fault identifier. See @ref NRF_FAULT_IDS."] #[doc = " @param[in] pc The program counter of the instruction that triggered the fault."] #[doc = " @param[in] info Optional additional information regarding the fault. Refer to each Fault identifier for details."] #[doc = ""] #[doc = " @note When id is set to @ref NRF_FAULT_ID_APP_MEMACC, pc will contain the address of the instruction being executed at the time when"] #[doc = " the fault is detected by the CPU. The CPU program counter may have advanced up to 2 instructions (no branching) after the one that triggered the fault."] pub type nrf_fault_handler_t = ::core::option::Option; #[doc = "@brief Enables the SoftDevice and by extension the protocol stack."] #[doc = ""] #[doc = " @note Some care must be taken if a low frequency clock source is already running when calling this function:"] #[doc = " If the LF clock has a different source then the one currently running, it will be stopped. Then, the new"] #[doc = " clock source will be started."] #[doc = ""] #[doc = " @note This function has no effect when returning with an error."] #[doc = ""] #[doc = " @post If return code is ::NRF_SUCCESS"] #[doc = " - SoC library and protocol stack APIs are made available."] #[doc = " - A portion of RAM will be unavailable (see relevant SDS documentation)."] #[doc = " - Some peripherals will be unavailable or available only through the SoC API (see relevant SDS documentation)."] #[doc = " - Interrupts will not arrive from protected peripherals or interrupts."] #[doc = " - nrf_nvic_ functions must be used instead of CMSIS NVIC_ functions for reliable usage of the SoftDevice."] #[doc = " - Interrupt latency may be affected by the SoftDevice (see relevant SDS documentation)."] #[doc = " - Chosen low frequency clock source will be running."] #[doc = ""] #[doc = " @param p_clock_lf_cfg Low frequency clock source and accuracy."] #[doc = "If NULL the clock will be configured as an RC source with rc_ctiv = 16 and .rc_temp_ctiv = 2"] #[doc = "In the case of XTAL source, the PPM accuracy of the chosen clock source must be greater than or equal to the actual characteristics of your XTAL clock."] #[doc = " @param fault_handler Callback to be invoked in case of fault, cannot be NULL."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[doc = " @retval ::NRF_ERROR_INVALID_ADDR Invalid or NULL pointer supplied."] #[doc = " @retval ::NRF_ERROR_INVALID_STATE SoftDevice is already enabled, and the clock source and fault handler cannot be updated."] #[doc = " @retval ::NRF_ERROR_SDM_INCORRECT_INTERRUPT_CONFIGURATION SoftDevice interrupt is already enabled, or an enabled interrupt has an illegal priority level."] #[doc = " @retval ::NRF_ERROR_SDM_LFCLK_SOURCE_UNKNOWN Unknown low frequency clock source selected."] #[doc = " @retval ::NRF_ERROR_INVALID_PARAM Invalid clock source configuration supplied in p_clock_lf_cfg."] #[inline(always)] pub unsafe fn sd_softdevice_enable( p_clock_lf_cfg: *const nrf_clock_lf_cfg_t, fault_handler: nrf_fault_handler_t, ) -> u32 { let ret: u32; core::arch::asm!("svc 16", inout("r0") to_asm(p_clock_lf_cfg) => ret, inout("r1") to_asm(fault_handler) => _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Disables the SoftDevice and by extension the protocol stack."] #[doc = ""] #[doc = " Idempotent function to disable the SoftDevice."] #[doc = ""] #[doc = " @post SoC library and protocol stack APIs are made unavailable."] #[doc = " @post All interrupts that was protected by the SoftDevice will be disabled and initialized to priority 0 (highest)."] #[doc = " @post All peripherals used by the SoftDevice will be reset to default values."] #[doc = " @post All of RAM become available."] #[doc = " @post All interrupts are forwarded to the application."] #[doc = " @post LFCLK source chosen in ::sd_softdevice_enable will be left running."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_softdevice_disable() -> u32 { let ret: u32; core::arch::asm!("svc 17", lateout("r0") ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Check if the SoftDevice is enabled."] #[doc = ""] #[doc = " @param[out] p_softdevice_enabled If the SoftDevice is enabled: 1 else 0."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_softdevice_is_enabled(p_softdevice_enabled: *mut u8) -> u32 { let ret: u32; core::arch::asm!("svc 18", inout("r0") to_asm(p_softdevice_enabled) => ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "@brief Sets the base address of the interrupt vector table for interrupts forwarded from the SoftDevice"] #[doc = ""] #[doc = " This function is only intended to be called when a bootloader is enabled."] #[doc = ""] #[doc = " @param[in] address The base address of the interrupt vector table for forwarded interrupts."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[inline(always)] pub unsafe fn sd_softdevice_vector_table_base_set(address: u32) -> u32 { let ret: u32; core::arch::asm!("svc 19", inout("r0") to_asm(address) => ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = " @brief 128 bit UUID values."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_uuid128_t { #[doc = "< Little-Endian UUID bytes."] pub uuid128: [u8; 16usize], } #[test] fn bindgen_test_layout_ble_uuid128_t() { assert_eq!( ::core::mem::size_of::(), 16usize, concat!("Size of: ", stringify!(ble_uuid128_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!("Alignment of ", stringify!(ble_uuid128_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).uuid128 as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_uuid128_t), "::", stringify!(uuid128) ) ); } #[doc = " @brief Bluetooth Low Energy UUID type, encapsulates both 16-bit and 128-bit UUIDs."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_uuid_t { #[doc = "< 16-bit UUID value or octets 12-13 of 128-bit UUID."] pub uuid: u16, #[doc = "< UUID type, see @ref BLE_UUID_TYPES. If type is @ref BLE_UUID_TYPE_UNKNOWN, the value of uuid is undefined."] pub type_: u8, } #[test] fn bindgen_test_layout_ble_uuid_t() { assert_eq!( ::core::mem::size_of::(), 4usize, concat!("Size of: ", stringify!(ble_uuid_t)) ); assert_eq!( ::core::mem::align_of::(), 2usize, concat!("Alignment of ", stringify!(ble_uuid_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).uuid as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_uuid_t), "::", stringify!(uuid) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).type_ as *const _ as usize }, 2usize, concat!( "Offset of field: ", stringify!(ble_uuid_t), "::", stringify!(type_) ) ); } #[doc = "@brief Data structure."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_data_t { #[doc = "< Pointer to the data buffer provided to/from the application."] pub p_data: *mut u8, #[doc = "< Length of the data buffer, in bytes."] pub len: u16, } #[test] fn bindgen_test_layout_ble_data_t() { assert_eq!( ::core::mem::size_of::(), 8usize, concat!("Size of: ", stringify!(ble_data_t)) ); assert_eq!( ::core::mem::align_of::(), 4usize, concat!("Alignment of ", stringify!(ble_data_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).p_data as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_data_t), "::", stringify!(p_data) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).len as *const _ as usize }, 4usize, concat!( "Offset of field: ", stringify!(ble_data_t), "::", stringify!(len) ) ); } #[doc = " @brief BLE GATT connection configuration parameters, set with @ref sd_ble_cfg_set."] #[doc = ""] #[doc = " @retval ::NRF_ERROR_INVALID_PARAM att_mtu is smaller than @ref BLE_GATT_ATT_MTU_DEFAULT."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gatt_conn_cfg_t { #[doc = "< Maximum size of ATT packet the SoftDevice can send or receive."] #[doc = "The default and minimum value is @ref BLE_GATT_ATT_MTU_DEFAULT."] #[doc = "@mscs"] #[doc = "@mmsc{@ref BLE_GATTC_MTU_EXCHANGE}"] #[doc = "@mmsc{@ref BLE_GATTS_MTU_EXCHANGE}"] #[doc = "@endmscs"] pub att_mtu: u16, } #[test] fn bindgen_test_layout_ble_gatt_conn_cfg_t() { assert_eq!( ::core::mem::size_of::(), 2usize, concat!("Size of: ", stringify!(ble_gatt_conn_cfg_t)) ); assert_eq!( ::core::mem::align_of::(), 2usize, concat!("Alignment of ", stringify!(ble_gatt_conn_cfg_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).att_mtu as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gatt_conn_cfg_t), "::", stringify!(att_mtu) ) ); } #[doc = "@brief GATT Characteristic Properties."] #[repr(C, packed)] #[derive(Debug, Copy, Clone)] pub struct ble_gatt_char_props_t { pub _bitfield_1: __BindgenBitfieldUnit<[u8; 1usize], u8>, } #[test] fn bindgen_test_layout_ble_gatt_char_props_t() { assert_eq!( ::core::mem::size_of::(), 1usize, concat!("Size of: ", stringify!(ble_gatt_char_props_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!("Alignment of ", stringify!(ble_gatt_char_props_t)) ); } impl ble_gatt_char_props_t { #[inline] pub fn broadcast(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(0usize, 1u8) as u8) } } #[inline] pub fn set_broadcast(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(0usize, 1u8, val as u64) } } #[inline] pub fn read(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(1usize, 1u8) as u8) } } #[inline] pub fn set_read(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(1usize, 1u8, val as u64) } } #[inline] pub fn write_wo_resp(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(2usize, 1u8) as u8) } } #[inline] pub fn set_write_wo_resp(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(2usize, 1u8, val as u64) } } #[inline] pub fn write(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(3usize, 1u8) as u8) } } #[inline] pub fn set_write(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(3usize, 1u8, val as u64) } } #[inline] pub fn notify(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(4usize, 1u8) as u8) } } #[inline] pub fn set_notify(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(4usize, 1u8, val as u64) } } #[inline] pub fn indicate(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(5usize, 1u8) as u8) } } #[inline] pub fn set_indicate(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(5usize, 1u8, val as u64) } } #[inline] pub fn auth_signed_wr(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(6usize, 1u8) as u8) } } #[inline] pub fn set_auth_signed_wr(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(6usize, 1u8, val as u64) } } #[inline] pub fn new_bitfield_1( broadcast: u8, read: u8, write_wo_resp: u8, write: u8, notify: u8, indicate: u8, auth_signed_wr: u8, ) -> __BindgenBitfieldUnit<[u8; 1usize], u8> { let mut __bindgen_bitfield_unit: __BindgenBitfieldUnit<[u8; 1usize], u8> = Default::default(); __bindgen_bitfield_unit.set(0usize, 1u8, { let broadcast: u8 = unsafe { ::core::mem::transmute(broadcast) }; broadcast as u64 }); __bindgen_bitfield_unit.set(1usize, 1u8, { let read: u8 = unsafe { ::core::mem::transmute(read) }; read as u64 }); __bindgen_bitfield_unit.set(2usize, 1u8, { let write_wo_resp: u8 = unsafe { ::core::mem::transmute(write_wo_resp) }; write_wo_resp as u64 }); __bindgen_bitfield_unit.set(3usize, 1u8, { let write: u8 = unsafe { ::core::mem::transmute(write) }; write as u64 }); __bindgen_bitfield_unit.set(4usize, 1u8, { let notify: u8 = unsafe { ::core::mem::transmute(notify) }; notify as u64 }); __bindgen_bitfield_unit.set(5usize, 1u8, { let indicate: u8 = unsafe { ::core::mem::transmute(indicate) }; indicate as u64 }); __bindgen_bitfield_unit.set(6usize, 1u8, { let auth_signed_wr: u8 = unsafe { ::core::mem::transmute(auth_signed_wr) }; auth_signed_wr as u64 }); __bindgen_bitfield_unit } } #[doc = "@brief GATT Characteristic Extended Properties."] #[repr(C, packed)] #[derive(Debug, Copy, Clone)] pub struct ble_gatt_char_ext_props_t { pub _bitfield_1: __BindgenBitfieldUnit<[u8; 1usize], u8>, } #[test] fn bindgen_test_layout_ble_gatt_char_ext_props_t() { assert_eq!( ::core::mem::size_of::(), 1usize, concat!("Size of: ", stringify!(ble_gatt_char_ext_props_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!("Alignment of ", stringify!(ble_gatt_char_ext_props_t)) ); } impl ble_gatt_char_ext_props_t { #[inline] pub fn reliable_wr(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(0usize, 1u8) as u8) } } #[inline] pub fn set_reliable_wr(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(0usize, 1u8, val as u64) } } #[inline] pub fn wr_aux(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(1usize, 1u8) as u8) } } #[inline] pub fn set_wr_aux(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(1usize, 1u8, val as u64) } } #[inline] pub fn new_bitfield_1(reliable_wr: u8, wr_aux: u8) -> __BindgenBitfieldUnit<[u8; 1usize], u8> { let mut __bindgen_bitfield_unit: __BindgenBitfieldUnit<[u8; 1usize], u8> = Default::default(); __bindgen_bitfield_unit.set(0usize, 1u8, { let reliable_wr: u8 = unsafe { ::core::mem::transmute(reliable_wr) }; reliable_wr as u64 }); __bindgen_bitfield_unit.set(1usize, 1u8, { let wr_aux: u8 = unsafe { ::core::mem::transmute(wr_aux) }; wr_aux as u64 }); __bindgen_bitfield_unit } } #[doc = "< ::sd_mbr_command"] pub const NRF_MBR_SVCS_SD_MBR_COMMAND: NRF_MBR_SVCS = 24; #[doc = "@brief nRF Master Boot Record API SVC numbers."] pub type NRF_MBR_SVCS = self::c_uint; #[doc = "< Copy a new BootLoader. @see ::sd_mbr_command_copy_bl_t"] pub const NRF_MBR_COMMANDS_SD_MBR_COMMAND_COPY_BL: NRF_MBR_COMMANDS = 0; #[doc = "< Copy a new SoftDevice. @see ::sd_mbr_command_copy_sd_t"] pub const NRF_MBR_COMMANDS_SD_MBR_COMMAND_COPY_SD: NRF_MBR_COMMANDS = 1; #[doc = "< Initialize forwarding interrupts to SD, and run reset function in SD. Does not require any parameters in ::sd_mbr_command_t params."] pub const NRF_MBR_COMMANDS_SD_MBR_COMMAND_INIT_SD: NRF_MBR_COMMANDS = 2; #[doc = "< This command works like memcmp. @see ::sd_mbr_command_compare_t"] pub const NRF_MBR_COMMANDS_SD_MBR_COMMAND_COMPARE: NRF_MBR_COMMANDS = 3; #[doc = "< Change the address the MBR starts after a reset. @see ::sd_mbr_command_vector_table_base_set_t"] pub const NRF_MBR_COMMANDS_SD_MBR_COMMAND_VECTOR_TABLE_BASE_SET: NRF_MBR_COMMANDS = 4; pub const NRF_MBR_COMMANDS_SD_MBR_COMMAND_RESERVED: NRF_MBR_COMMANDS = 5; #[doc = "< Start forwarding all interrupts to this address. @see ::sd_mbr_command_irq_forward_address_set_t"] pub const NRF_MBR_COMMANDS_SD_MBR_COMMAND_IRQ_FORWARD_ADDRESS_SET: NRF_MBR_COMMANDS = 6; #[doc = "@brief Possible values for ::sd_mbr_command_t.command"] pub type NRF_MBR_COMMANDS = self::c_uint; #[doc = "@brief This command copies part of a new SoftDevice"] #[doc = ""] #[doc = " The destination area is erased before copying."] #[doc = " If dst is in the middle of a flash page, that whole flash page will be erased."] #[doc = " If (dst+len) is in the middle of a flash page, that whole flash page will be erased."] #[doc = ""] #[doc = " The user of this function is responsible for setting the BPROT registers."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS indicates that the contents of the memory blocks where copied correctly."] #[doc = " @retval ::NRF_ERROR_INTERNAL indicates that the contents of the memory blocks where not verified correctly after copying."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct sd_mbr_command_copy_sd_t { #[doc = "< Pointer to the source of data to be copied."] pub src: *mut u32, #[doc = "< Pointer to the destination where the content is to be copied."] pub dst: *mut u32, #[doc = "< Number of 32 bit words to copy. Must be a multiple of @ref MBR_PAGE_SIZE_IN_WORDS words."] pub len: u32, } #[test] fn bindgen_test_layout_sd_mbr_command_copy_sd_t() { assert_eq!( ::core::mem::size_of::(), 12usize, concat!("Size of: ", stringify!(sd_mbr_command_copy_sd_t)) ); assert_eq!( ::core::mem::align_of::(), 4usize, concat!("Alignment of ", stringify!(sd_mbr_command_copy_sd_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).src as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(sd_mbr_command_copy_sd_t), "::", stringify!(src) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).dst as *const _ as usize }, 4usize, concat!( "Offset of field: ", stringify!(sd_mbr_command_copy_sd_t), "::", stringify!(dst) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).len as *const _ as usize }, 8usize, concat!( "Offset of field: ", stringify!(sd_mbr_command_copy_sd_t), "::", stringify!(len) ) ); } #[doc = "@brief This command works like memcmp, but takes the length in words."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS indicates that the contents of both memory blocks are equal."] #[doc = " @retval ::NRF_ERROR_NULL indicates that the contents of the memory blocks are not equal."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct sd_mbr_command_compare_t { #[doc = "< Pointer to block of memory."] pub ptr1: *mut u32, #[doc = "< Pointer to block of memory."] pub ptr2: *mut u32, #[doc = "< Number of 32 bit words to compare."] pub len: u32, } #[test] fn bindgen_test_layout_sd_mbr_command_compare_t() { assert_eq!( ::core::mem::size_of::(), 12usize, concat!("Size of: ", stringify!(sd_mbr_command_compare_t)) ); assert_eq!( ::core::mem::align_of::(), 4usize, concat!("Alignment of ", stringify!(sd_mbr_command_compare_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).ptr1 as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(sd_mbr_command_compare_t), "::", stringify!(ptr1) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).ptr2 as *const _ as usize }, 4usize, concat!( "Offset of field: ", stringify!(sd_mbr_command_compare_t), "::", stringify!(ptr2) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).len as *const _ as usize }, 8usize, concat!( "Offset of field: ", stringify!(sd_mbr_command_compare_t), "::", stringify!(len) ) ); } #[doc = "@brief This command copies a new BootLoader."] #[doc = ""] #[doc = " The MBR assumes that either @ref MBR_BOOTLOADER_ADDR or @ref MBR_UICR_BOOTLOADER_ADDR is set to"] #[doc = " the address where the bootloader will be copied. If both addresses are set, the MBR will prioritize"] #[doc = " @ref MBR_BOOTLOADER_ADDR."] #[doc = ""] #[doc = " The bootloader destination is erased by this function."] #[doc = " If (destination+bl_len) is in the middle of a flash page, that whole flash page will be erased."] #[doc = ""] #[doc = " This command requires that @ref MBR_PARAM_PAGE_ADDR or @ref MBR_UICR_PARAM_PAGE_ADDR is set,"] #[doc = " see @ref sd_mbr_command."] #[doc = ""] #[doc = " This command will use the flash protect peripheral (BPROT or ACL) to protect the flash that is"] #[doc = " not intended to be written."] #[doc = ""] #[doc = " On success, this function will not return. It will start the new bootloader from reset-vector as normal."] #[doc = ""] #[doc = " @retval ::NRF_ERROR_INTERNAL indicates an internal error that should not happen."] #[doc = " @retval ::NRF_ERROR_FORBIDDEN if the bootloader address is not set."] #[doc = " @retval ::NRF_ERROR_INVALID_LENGTH if parameters attempts to read or write outside flash area."] #[doc = " @retval ::NRF_ERROR_NO_MEM No MBR parameter page is provided. See @ref sd_mbr_command."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct sd_mbr_command_copy_bl_t { #[doc = "< Pointer to the source of the bootloader to be be copied."] pub bl_src: *mut u32, #[doc = "< Number of 32 bit words to copy for BootLoader."] pub bl_len: u32, } #[test] fn bindgen_test_layout_sd_mbr_command_copy_bl_t() { assert_eq!( ::core::mem::size_of::(), 8usize, concat!("Size of: ", stringify!(sd_mbr_command_copy_bl_t)) ); assert_eq!( ::core::mem::align_of::(), 4usize, concat!("Alignment of ", stringify!(sd_mbr_command_copy_bl_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).bl_src as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(sd_mbr_command_copy_bl_t), "::", stringify!(bl_src) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).bl_len as *const _ as usize }, 4usize, concat!( "Offset of field: ", stringify!(sd_mbr_command_copy_bl_t), "::", stringify!(bl_len) ) ); } #[doc = "@brief Change the address the MBR starts after a reset"] #[doc = ""] #[doc = " Once this function has been called, this address is where the MBR will start to forward"] #[doc = " interrupts to after a reset."] #[doc = ""] #[doc = " To restore default forwarding, this function should be called with @ref address set to 0. If a"] #[doc = " bootloader is present, interrupts will be forwarded to the bootloader. If not, interrupts will"] #[doc = " be forwarded to the SoftDevice."] #[doc = ""] #[doc = " The location of a bootloader can be specified in @ref MBR_BOOTLOADER_ADDR or"] #[doc = " @ref MBR_UICR_BOOTLOADER_ADDR. If both addresses are set, the MBR will prioritize"] #[doc = " @ref MBR_BOOTLOADER_ADDR."] #[doc = ""] #[doc = " This command requires that @ref MBR_PARAM_PAGE_ADDR or @ref MBR_UICR_PARAM_PAGE_ADDR is set,"] #[doc = " see @ref sd_mbr_command."] #[doc = ""] #[doc = " On success, this function will not return. It will reset the device."] #[doc = ""] #[doc = " @retval ::NRF_ERROR_INTERNAL indicates an internal error that should not happen."] #[doc = " @retval ::NRF_ERROR_INVALID_ADDR if parameter address is outside of the flash size."] #[doc = " @retval ::NRF_ERROR_NO_MEM No MBR parameter page is provided. See @ref sd_mbr_command."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct sd_mbr_command_vector_table_base_set_t { #[doc = "< The base address of the interrupt vector table for forwarded interrupts."] pub address: u32, } #[test] fn bindgen_test_layout_sd_mbr_command_vector_table_base_set_t() { assert_eq!( ::core::mem::size_of::(), 4usize, concat!( "Size of: ", stringify!(sd_mbr_command_vector_table_base_set_t) ) ); assert_eq!( ::core::mem::align_of::(), 4usize, concat!( "Alignment of ", stringify!(sd_mbr_command_vector_table_base_set_t) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).address as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(sd_mbr_command_vector_table_base_set_t), "::", stringify!(address) ) ); } #[doc = "@brief Sets the base address of the interrupt vector table for interrupts forwarded from the MBR"] #[doc = ""] #[doc = " Unlike sd_mbr_command_vector_table_base_set_t, this function does not reset, and it does not"] #[doc = " change where the MBR starts after reset."] #[doc = ""] #[doc = " @retval ::NRF_SUCCESS"] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct sd_mbr_command_irq_forward_address_set_t { #[doc = "< The base address of the interrupt vector table for forwarded interrupts."] pub address: u32, } #[test] fn bindgen_test_layout_sd_mbr_command_irq_forward_address_set_t() { assert_eq!( ::core::mem::size_of::(), 4usize, concat!( "Size of: ", stringify!(sd_mbr_command_irq_forward_address_set_t) ) ); assert_eq!( ::core::mem::align_of::(), 4usize, concat!( "Alignment of ", stringify!(sd_mbr_command_irq_forward_address_set_t) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).address as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(sd_mbr_command_irq_forward_address_set_t), "::", stringify!(address) ) ); } #[doc = "@brief Input structure containing data used when calling ::sd_mbr_command"] #[doc = ""] #[doc = " Depending on what command value that is set, the corresponding params value type must also be"] #[doc = " set. See @ref NRF_MBR_COMMANDS for command types and corresponding params value type. If command"] #[doc = " @ref SD_MBR_COMMAND_INIT_SD is set, it is not necessary to set any values under params."] #[repr(C)] #[derive(Copy, Clone)] pub struct sd_mbr_command_t { #[doc = "< Type of command to be issued. See @ref NRF_MBR_COMMANDS."] pub command: u32, #[doc = "< Command parameters."] pub params: sd_mbr_command_t__bindgen_ty_1, } #[repr(C)] #[derive(Copy, Clone)] pub union sd_mbr_command_t__bindgen_ty_1 { #[doc = "< Parameters for copy SoftDevice."] pub copy_sd: sd_mbr_command_copy_sd_t, #[doc = "< Parameters for verify."] pub compare: sd_mbr_command_compare_t, #[doc = "< Parameters for copy BootLoader. Requires parameter page."] pub copy_bl: sd_mbr_command_copy_bl_t, #[doc = "< Parameters for vector table base set. Requires parameter page."] pub base_set: sd_mbr_command_vector_table_base_set_t, #[doc = "< Parameters for irq forward address set"] pub irq_forward_address_set: sd_mbr_command_irq_forward_address_set_t, _bindgen_union_align: [u32; 3usize], } #[test] fn bindgen_test_layout_sd_mbr_command_t__bindgen_ty_1() { assert_eq!( ::core::mem::size_of::(), 12usize, concat!("Size of: ", stringify!(sd_mbr_command_t__bindgen_ty_1)) ); assert_eq!( ::core::mem::align_of::(), 4usize, concat!("Alignment of ", stringify!(sd_mbr_command_t__bindgen_ty_1)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).copy_sd as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(sd_mbr_command_t__bindgen_ty_1), "::", stringify!(copy_sd) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).compare as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(sd_mbr_command_t__bindgen_ty_1), "::", stringify!(compare) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).copy_bl as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(sd_mbr_command_t__bindgen_ty_1), "::", stringify!(copy_bl) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).base_set as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(sd_mbr_command_t__bindgen_ty_1), "::", stringify!(base_set) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).irq_forward_address_set as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(sd_mbr_command_t__bindgen_ty_1), "::", stringify!(irq_forward_address_set) ) ); } #[test] fn bindgen_test_layout_sd_mbr_command_t() { assert_eq!( ::core::mem::size_of::(), 16usize, concat!("Size of: ", stringify!(sd_mbr_command_t)) ); assert_eq!( ::core::mem::align_of::(), 4usize, concat!("Alignment of ", stringify!(sd_mbr_command_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).command as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(sd_mbr_command_t), "::", stringify!(command) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).params as *const _ as usize }, 4usize, concat!( "Offset of field: ", stringify!(sd_mbr_command_t), "::", stringify!(params) ) ); } #[doc = "@brief Issue Master Boot Record commands"] #[doc = ""] #[doc = " Commands used when updating a SoftDevice and bootloader."] #[doc = ""] #[doc = " The @ref SD_MBR_COMMAND_COPY_BL and @ref SD_MBR_COMMAND_VECTOR_TABLE_BASE_SET requires"] #[doc = " parameters to be retained by the MBR when resetting the IC. This is done in a separate flash"] #[doc = " page. The location of the flash page should be provided by the application in either"] #[doc = " @ref MBR_PARAM_PAGE_ADDR or @ref MBR_UICR_PARAM_PAGE_ADDR. If both addresses are set, the MBR"] #[doc = " will prioritize @ref MBR_PARAM_PAGE_ADDR. This page will be cleared by the MBR and is used to"] #[doc = " store the command before reset. When an address is specified, the page it refers to must not be"] #[doc = " used by the application. If no address is provided by the application, i.e. both"] #[doc = " @ref MBR_PARAM_PAGE_ADDR and @ref MBR_UICR_PARAM_PAGE_ADDR is 0xFFFFFFFF, MBR commands which use"] #[doc = " flash will be unavailable and return @ref NRF_ERROR_NO_MEM."] #[doc = ""] #[doc = " @param[in] param Pointer to a struct describing the command."] #[doc = ""] #[doc = " @note For a complete set of return values, see ::sd_mbr_command_copy_sd_t,"] #[doc = " ::sd_mbr_command_copy_bl_t, ::sd_mbr_command_compare_t,"] #[doc = " ::sd_mbr_command_vector_table_base_set_t, ::sd_mbr_command_irq_forward_address_set_t"] #[doc = ""] #[doc = " @retval ::NRF_ERROR_NO_MEM No MBR parameter page provided"] #[doc = " @retval ::NRF_ERROR_INVALID_PARAM if an invalid command is given."] #[inline(always)] pub unsafe fn sd_mbr_command(param: *mut sd_mbr_command_t) -> u32 { let ret: u32; core::arch::asm!("svc 24", inout("r0") to_asm(param) => ret, lateout("r1") _, lateout("r2") _, lateout("r3") _, lateout("r12") _, ); ret } #[doc = "< Set own Bluetooth Address."] pub const BLE_GAP_SVCS_SD_BLE_GAP_ADDR_SET: BLE_GAP_SVCS = 108; #[doc = "< Get own Bluetooth Address."] pub const BLE_GAP_SVCS_SD_BLE_GAP_ADDR_GET: BLE_GAP_SVCS = 109; #[doc = "< Set active whitelist."] pub const BLE_GAP_SVCS_SD_BLE_GAP_WHITELIST_SET: BLE_GAP_SVCS = 110; #[doc = "< Set device identity list."] pub const BLE_GAP_SVCS_SD_BLE_GAP_DEVICE_IDENTITIES_SET: BLE_GAP_SVCS = 111; #[doc = "< Set Privacy settings"] pub const BLE_GAP_SVCS_SD_BLE_GAP_PRIVACY_SET: BLE_GAP_SVCS = 112; #[doc = "< Get Privacy settings"] pub const BLE_GAP_SVCS_SD_BLE_GAP_PRIVACY_GET: BLE_GAP_SVCS = 113; #[doc = "< Configure an advertising set."] pub const BLE_GAP_SVCS_SD_BLE_GAP_ADV_SET_CONFIGURE: BLE_GAP_SVCS = 114; #[doc = "< Start Advertising."] pub const BLE_GAP_SVCS_SD_BLE_GAP_ADV_START: BLE_GAP_SVCS = 115; #[doc = "< Stop Advertising."] pub const BLE_GAP_SVCS_SD_BLE_GAP_ADV_STOP: BLE_GAP_SVCS = 116; #[doc = "< Connection Parameter Update."] pub const BLE_GAP_SVCS_SD_BLE_GAP_CONN_PARAM_UPDATE: BLE_GAP_SVCS = 117; #[doc = "< Disconnect."] pub const BLE_GAP_SVCS_SD_BLE_GAP_DISCONNECT: BLE_GAP_SVCS = 118; #[doc = "< Set TX Power."] pub const BLE_GAP_SVCS_SD_BLE_GAP_TX_POWER_SET: BLE_GAP_SVCS = 119; #[doc = "< Set Appearance."] pub const BLE_GAP_SVCS_SD_BLE_GAP_APPEARANCE_SET: BLE_GAP_SVCS = 120; #[doc = "< Get Appearance."] pub const BLE_GAP_SVCS_SD_BLE_GAP_APPEARANCE_GET: BLE_GAP_SVCS = 121; #[doc = "< Set PPCP."] pub const BLE_GAP_SVCS_SD_BLE_GAP_PPCP_SET: BLE_GAP_SVCS = 122; #[doc = "< Get PPCP."] pub const BLE_GAP_SVCS_SD_BLE_GAP_PPCP_GET: BLE_GAP_SVCS = 123; #[doc = "< Set Device Name."] pub const BLE_GAP_SVCS_SD_BLE_GAP_DEVICE_NAME_SET: BLE_GAP_SVCS = 124; #[doc = "< Get Device Name."] pub const BLE_GAP_SVCS_SD_BLE_GAP_DEVICE_NAME_GET: BLE_GAP_SVCS = 125; #[doc = "< Initiate Pairing/Bonding."] pub const BLE_GAP_SVCS_SD_BLE_GAP_AUTHENTICATE: BLE_GAP_SVCS = 126; #[doc = "< Reply with Security Parameters."] pub const BLE_GAP_SVCS_SD_BLE_GAP_SEC_PARAMS_REPLY: BLE_GAP_SVCS = 127; #[doc = "< Reply with an authentication key."] pub const BLE_GAP_SVCS_SD_BLE_GAP_AUTH_KEY_REPLY: BLE_GAP_SVCS = 128; #[doc = "< Reply with an LE Secure Connections DHKey."] pub const BLE_GAP_SVCS_SD_BLE_GAP_LESC_DHKEY_REPLY: BLE_GAP_SVCS = 129; #[doc = "< Notify of a keypress during an authentication procedure."] pub const BLE_GAP_SVCS_SD_BLE_GAP_KEYPRESS_NOTIFY: BLE_GAP_SVCS = 130; #[doc = "< Get the local LE Secure Connections OOB data."] pub const BLE_GAP_SVCS_SD_BLE_GAP_LESC_OOB_DATA_GET: BLE_GAP_SVCS = 131; #[doc = "< Set the remote LE Secure Connections OOB data."] pub const BLE_GAP_SVCS_SD_BLE_GAP_LESC_OOB_DATA_SET: BLE_GAP_SVCS = 132; #[doc = "< Initiate encryption procedure."] pub const BLE_GAP_SVCS_SD_BLE_GAP_ENCRYPT: BLE_GAP_SVCS = 133; #[doc = "< Reply with Security Information."] pub const BLE_GAP_SVCS_SD_BLE_GAP_SEC_INFO_REPLY: BLE_GAP_SVCS = 134; #[doc = "< Obtain connection security level."] pub const BLE_GAP_SVCS_SD_BLE_GAP_CONN_SEC_GET: BLE_GAP_SVCS = 135; #[doc = "< Start reporting of changes in RSSI."] pub const BLE_GAP_SVCS_SD_BLE_GAP_RSSI_START: BLE_GAP_SVCS = 136; #[doc = "< Stop reporting of changes in RSSI."] pub const BLE_GAP_SVCS_SD_BLE_GAP_RSSI_STOP: BLE_GAP_SVCS = 137; #[doc = "< Start Scanning."] pub const BLE_GAP_SVCS_SD_BLE_GAP_SCAN_START: BLE_GAP_SVCS = 138; #[doc = "< Stop Scanning."] pub const BLE_GAP_SVCS_SD_BLE_GAP_SCAN_STOP: BLE_GAP_SVCS = 139; #[doc = "< Connect."] pub const BLE_GAP_SVCS_SD_BLE_GAP_CONNECT: BLE_GAP_SVCS = 140; #[doc = "< Cancel ongoing connection procedure."] pub const BLE_GAP_SVCS_SD_BLE_GAP_CONNECT_CANCEL: BLE_GAP_SVCS = 141; #[doc = "< Get the last RSSI sample."] pub const BLE_GAP_SVCS_SD_BLE_GAP_RSSI_GET: BLE_GAP_SVCS = 142; #[doc = "< Initiate or respond to a PHY Update Procedure."] pub const BLE_GAP_SVCS_SD_BLE_GAP_PHY_UPDATE: BLE_GAP_SVCS = 143; #[doc = "< Initiate or respond to a Data Length Update Procedure."] pub const BLE_GAP_SVCS_SD_BLE_GAP_DATA_LENGTH_UPDATE: BLE_GAP_SVCS = 144; #[doc = "< Start Quality of Service (QoS) channel survey module."] pub const BLE_GAP_SVCS_SD_BLE_GAP_QOS_CHANNEL_SURVEY_START: BLE_GAP_SVCS = 145; #[doc = "< Stop Quality of Service (QoS) channel survey module."] pub const BLE_GAP_SVCS_SD_BLE_GAP_QOS_CHANNEL_SURVEY_STOP: BLE_GAP_SVCS = 146; #[doc = "< Get the Address used on air while Advertising."] pub const BLE_GAP_SVCS_SD_BLE_GAP_ADV_ADDR_GET: BLE_GAP_SVCS = 147; #[doc = "< Get the next connection event counter."] pub const BLE_GAP_SVCS_SD_BLE_GAP_NEXT_CONN_EVT_COUNTER_GET: BLE_GAP_SVCS = 148; pub const BLE_GAP_SVCS_SD_BLE_GAP_CONN_EVT_TRIGGER_START: BLE_GAP_SVCS = 149; #[doc = " Start triggering a given task on connection event start."] pub const BLE_GAP_SVCS_SD_BLE_GAP_CONN_EVT_TRIGGER_STOP: BLE_GAP_SVCS = 150; #[doc = "@brief GAP API SVC numbers."] pub type BLE_GAP_SVCS = self::c_uint; #[doc = "< Connected to peer. \\n See @ref ble_gap_evt_connected_t"] pub const BLE_GAP_EVTS_BLE_GAP_EVT_CONNECTED: BLE_GAP_EVTS = 16; #[doc = "< Disconnected from peer. \\n See @ref ble_gap_evt_disconnected_t."] pub const BLE_GAP_EVTS_BLE_GAP_EVT_DISCONNECTED: BLE_GAP_EVTS = 17; #[doc = "< Connection Parameters updated. \\n See @ref ble_gap_evt_conn_param_update_t."] pub const BLE_GAP_EVTS_BLE_GAP_EVT_CONN_PARAM_UPDATE: BLE_GAP_EVTS = 18; #[doc = "< Request to provide security parameters. \\n Reply with @ref sd_ble_gap_sec_params_reply. \\n See @ref ble_gap_evt_sec_params_request_t."] pub const BLE_GAP_EVTS_BLE_GAP_EVT_SEC_PARAMS_REQUEST: BLE_GAP_EVTS = 19; #[doc = "< Request to provide security information. \\n Reply with @ref sd_ble_gap_sec_info_reply. \\n See @ref ble_gap_evt_sec_info_request_t."] pub const BLE_GAP_EVTS_BLE_GAP_EVT_SEC_INFO_REQUEST: BLE_GAP_EVTS = 20; #[doc = "< Request to display a passkey to the user. \\n In LESC Numeric Comparison, reply with @ref sd_ble_gap_auth_key_reply. \\n See @ref ble_gap_evt_passkey_display_t."] pub const BLE_GAP_EVTS_BLE_GAP_EVT_PASSKEY_DISPLAY: BLE_GAP_EVTS = 21; #[doc = "< Notification of a keypress on the remote device.\\n See @ref ble_gap_evt_key_pressed_t"] pub const BLE_GAP_EVTS_BLE_GAP_EVT_KEY_PRESSED: BLE_GAP_EVTS = 22; #[doc = "< Request to provide an authentication key. \\n Reply with @ref sd_ble_gap_auth_key_reply. \\n See @ref ble_gap_evt_auth_key_request_t."] pub const BLE_GAP_EVTS_BLE_GAP_EVT_AUTH_KEY_REQUEST: BLE_GAP_EVTS = 23; #[doc = "< Request to calculate an LE Secure Connections DHKey. \\n Reply with @ref sd_ble_gap_lesc_dhkey_reply. \\n See @ref ble_gap_evt_lesc_dhkey_request_t"] pub const BLE_GAP_EVTS_BLE_GAP_EVT_LESC_DHKEY_REQUEST: BLE_GAP_EVTS = 24; #[doc = "< Authentication procedure completed with status. \\n See @ref ble_gap_evt_auth_status_t."] pub const BLE_GAP_EVTS_BLE_GAP_EVT_AUTH_STATUS: BLE_GAP_EVTS = 25; #[doc = "< Connection security updated. \\n See @ref ble_gap_evt_conn_sec_update_t."] pub const BLE_GAP_EVTS_BLE_GAP_EVT_CONN_SEC_UPDATE: BLE_GAP_EVTS = 26; #[doc = "< Timeout expired. \\n See @ref ble_gap_evt_timeout_t."] pub const BLE_GAP_EVTS_BLE_GAP_EVT_TIMEOUT: BLE_GAP_EVTS = 27; #[doc = "< RSSI report. \\n See @ref ble_gap_evt_rssi_changed_t."] pub const BLE_GAP_EVTS_BLE_GAP_EVT_RSSI_CHANGED: BLE_GAP_EVTS = 28; #[doc = "< Advertising report. \\n See @ref ble_gap_evt_adv_report_t."] pub const BLE_GAP_EVTS_BLE_GAP_EVT_ADV_REPORT: BLE_GAP_EVTS = 29; #[doc = "< Security Request. \\n See @ref ble_gap_evt_sec_request_t."] pub const BLE_GAP_EVTS_BLE_GAP_EVT_SEC_REQUEST: BLE_GAP_EVTS = 30; #[doc = "< Connection Parameter Update Request. \\n Reply with @ref sd_ble_gap_conn_param_update. \\n See @ref ble_gap_evt_conn_param_update_request_t."] pub const BLE_GAP_EVTS_BLE_GAP_EVT_CONN_PARAM_UPDATE_REQUEST: BLE_GAP_EVTS = 31; #[doc = "< Scan request report. \\n See @ref ble_gap_evt_scan_req_report_t."] pub const BLE_GAP_EVTS_BLE_GAP_EVT_SCAN_REQ_REPORT: BLE_GAP_EVTS = 32; #[doc = "< PHY Update Request. \\n Reply with @ref sd_ble_gap_phy_update. \\n See @ref ble_gap_evt_phy_update_request_t."] pub const BLE_GAP_EVTS_BLE_GAP_EVT_PHY_UPDATE_REQUEST: BLE_GAP_EVTS = 33; #[doc = "< PHY Update Procedure is complete. \\n See @ref ble_gap_evt_phy_update_t."] pub const BLE_GAP_EVTS_BLE_GAP_EVT_PHY_UPDATE: BLE_GAP_EVTS = 34; #[doc = "< Data Length Update Request. \\n Reply with @ref sd_ble_gap_data_length_update. \\n See @ref ble_gap_evt_data_length_update_request_t."] pub const BLE_GAP_EVTS_BLE_GAP_EVT_DATA_LENGTH_UPDATE_REQUEST: BLE_GAP_EVTS = 35; #[doc = "< LL Data Channel PDU payload length updated. \\n See @ref ble_gap_evt_data_length_update_t."] pub const BLE_GAP_EVTS_BLE_GAP_EVT_DATA_LENGTH_UPDATE: BLE_GAP_EVTS = 36; #[doc = "< Channel survey report. \\n See @ref ble_gap_evt_qos_channel_survey_report_t."] pub const BLE_GAP_EVTS_BLE_GAP_EVT_QOS_CHANNEL_SURVEY_REPORT: BLE_GAP_EVTS = 37; #[doc = "< Advertising set terminated. \\n See @ref ble_gap_evt_adv_set_terminated_t."] pub const BLE_GAP_EVTS_BLE_GAP_EVT_ADV_SET_TERMINATED: BLE_GAP_EVTS = 38; #[doc = "@brief GAP Event IDs."] #[doc = " IDs that uniquely identify an event coming from the stack to the application."] pub type BLE_GAP_EVTS = self::c_uint; #[doc = "< Channel Map. @ref ble_gap_opt_ch_map_t"] pub const BLE_GAP_OPTS_BLE_GAP_OPT_CH_MAP: BLE_GAP_OPTS = 32; #[doc = "< Local connection latency. @ref ble_gap_opt_local_conn_latency_t"] pub const BLE_GAP_OPTS_BLE_GAP_OPT_LOCAL_CONN_LATENCY: BLE_GAP_OPTS = 33; #[doc = "< Set passkey. @ref ble_gap_opt_passkey_t"] pub const BLE_GAP_OPTS_BLE_GAP_OPT_PASSKEY: BLE_GAP_OPTS = 34; #[doc = "< Compatibility mode. @ref ble_gap_opt_compat_mode_1_t"] pub const BLE_GAP_OPTS_BLE_GAP_OPT_COMPAT_MODE_1: BLE_GAP_OPTS = 35; #[doc = "< Set Authenticated payload timeout. @ref ble_gap_opt_auth_payload_timeout_t"] pub const BLE_GAP_OPTS_BLE_GAP_OPT_AUTH_PAYLOAD_TIMEOUT: BLE_GAP_OPTS = 36; #[doc = "< Disable slave latency. @ref ble_gap_opt_slave_latency_disable_t"] pub const BLE_GAP_OPTS_BLE_GAP_OPT_SLAVE_LATENCY_DISABLE: BLE_GAP_OPTS = 37; #[doc = "@brief GAP Option IDs."] #[doc = " IDs that uniquely identify a GAP option."] pub type BLE_GAP_OPTS = self::c_uint; #[doc = "< Role count configuration."] pub const BLE_GAP_CFGS_BLE_GAP_CFG_ROLE_COUNT: BLE_GAP_CFGS = 64; #[doc = "< Device name configuration."] pub const BLE_GAP_CFGS_BLE_GAP_CFG_DEVICE_NAME: BLE_GAP_CFGS = 65; #[doc = "< Peripheral Preferred Connection Parameters characteristic"] #[doc = "inclusion configuration."] pub const BLE_GAP_CFGS_BLE_GAP_CFG_PPCP_INCL_CONFIG: BLE_GAP_CFGS = 66; #[doc = "< Central Address Resolution characteristic"] #[doc = "inclusion configuration."] pub const BLE_GAP_CFGS_BLE_GAP_CFG_CAR_INCL_CONFIG: BLE_GAP_CFGS = 67; #[doc = "@brief GAP Configuration IDs."] #[doc = ""] #[doc = " IDs that uniquely identify a GAP configuration."] pub type BLE_GAP_CFGS = self::c_uint; #[doc = "< Advertiser role."] pub const BLE_GAP_TX_POWER_ROLES_BLE_GAP_TX_POWER_ROLE_ADV: BLE_GAP_TX_POWER_ROLES = 1; #[doc = "< Scanner and initiator role."] pub const BLE_GAP_TX_POWER_ROLES_BLE_GAP_TX_POWER_ROLE_SCAN_INIT: BLE_GAP_TX_POWER_ROLES = 2; #[doc = "< Connection role."] pub const BLE_GAP_TX_POWER_ROLES_BLE_GAP_TX_POWER_ROLE_CONN: BLE_GAP_TX_POWER_ROLES = 3; #[doc = "@brief GAP TX Power roles."] pub type BLE_GAP_TX_POWER_ROLES = self::c_uint; #[doc = "@brief Advertising event properties."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_adv_properties_t { #[doc = "< Advertising type. See @ref BLE_GAP_ADV_TYPES."] pub type_: u8, pub _bitfield_1: __BindgenBitfieldUnit<[u8; 1usize], u8>, } #[test] fn bindgen_test_layout_ble_gap_adv_properties_t() { assert_eq!( ::core::mem::size_of::(), 2usize, concat!("Size of: ", stringify!(ble_gap_adv_properties_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!("Alignment of ", stringify!(ble_gap_adv_properties_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).type_ as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_adv_properties_t), "::", stringify!(type_) ) ); } impl ble_gap_adv_properties_t { #[inline] pub fn anonymous(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(0usize, 1u8) as u8) } } #[inline] pub fn set_anonymous(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(0usize, 1u8, val as u64) } } #[inline] pub fn include_tx_power(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(1usize, 1u8) as u8) } } #[inline] pub fn set_include_tx_power(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(1usize, 1u8, val as u64) } } #[inline] pub fn new_bitfield_1( anonymous: u8, include_tx_power: u8, ) -> __BindgenBitfieldUnit<[u8; 1usize], u8> { let mut __bindgen_bitfield_unit: __BindgenBitfieldUnit<[u8; 1usize], u8> = Default::default(); __bindgen_bitfield_unit.set(0usize, 1u8, { let anonymous: u8 = unsafe { ::core::mem::transmute(anonymous) }; anonymous as u64 }); __bindgen_bitfield_unit.set(1usize, 1u8, { let include_tx_power: u8 = unsafe { ::core::mem::transmute(include_tx_power) }; include_tx_power as u64 }); __bindgen_bitfield_unit } } #[doc = "@brief Advertising report type."] #[repr(C)] #[repr(align(2))] #[derive(Debug, Copy, Clone)] pub struct ble_gap_adv_report_type_t { pub _bitfield_1: __BindgenBitfieldUnit<[u8; 2usize], u16>, } #[test] fn bindgen_test_layout_ble_gap_adv_report_type_t() { assert_eq!( ::core::mem::size_of::(), 2usize, concat!("Size of: ", stringify!(ble_gap_adv_report_type_t)) ); assert_eq!( ::core::mem::align_of::(), 2usize, concat!("Alignment of ", stringify!(ble_gap_adv_report_type_t)) ); } impl ble_gap_adv_report_type_t { #[inline] pub fn connectable(&self) -> u16 { unsafe { ::core::mem::transmute(self._bitfield_1.get(0usize, 1u8) as u16) } } #[inline] pub fn set_connectable(&mut self, val: u16) { unsafe { let val: u16 = ::core::mem::transmute(val); self._bitfield_1.set(0usize, 1u8, val as u64) } } #[inline] pub fn scannable(&self) -> u16 { unsafe { ::core::mem::transmute(self._bitfield_1.get(1usize, 1u8) as u16) } } #[inline] pub fn set_scannable(&mut self, val: u16) { unsafe { let val: u16 = ::core::mem::transmute(val); self._bitfield_1.set(1usize, 1u8, val as u64) } } #[inline] pub fn directed(&self) -> u16 { unsafe { ::core::mem::transmute(self._bitfield_1.get(2usize, 1u8) as u16) } } #[inline] pub fn set_directed(&mut self, val: u16) { unsafe { let val: u16 = ::core::mem::transmute(val); self._bitfield_1.set(2usize, 1u8, val as u64) } } #[inline] pub fn scan_response(&self) -> u16 { unsafe { ::core::mem::transmute(self._bitfield_1.get(3usize, 1u8) as u16) } } #[inline] pub fn set_scan_response(&mut self, val: u16) { unsafe { let val: u16 = ::core::mem::transmute(val); self._bitfield_1.set(3usize, 1u8, val as u64) } } #[inline] pub fn extended_pdu(&self) -> u16 { unsafe { ::core::mem::transmute(self._bitfield_1.get(4usize, 1u8) as u16) } } #[inline] pub fn set_extended_pdu(&mut self, val: u16) { unsafe { let val: u16 = ::core::mem::transmute(val); self._bitfield_1.set(4usize, 1u8, val as u64) } } #[inline] pub fn status(&self) -> u16 { unsafe { ::core::mem::transmute(self._bitfield_1.get(5usize, 2u8) as u16) } } #[inline] pub fn set_status(&mut self, val: u16) { unsafe { let val: u16 = ::core::mem::transmute(val); self._bitfield_1.set(5usize, 2u8, val as u64) } } #[inline] pub fn reserved(&self) -> u16 { unsafe { ::core::mem::transmute(self._bitfield_1.get(7usize, 9u8) as u16) } } #[inline] pub fn set_reserved(&mut self, val: u16) { unsafe { let val: u16 = ::core::mem::transmute(val); self._bitfield_1.set(7usize, 9u8, val as u64) } } #[inline] pub fn new_bitfield_1( connectable: u16, scannable: u16, directed: u16, scan_response: u16, extended_pdu: u16, status: u16, reserved: u16, ) -> __BindgenBitfieldUnit<[u8; 2usize], u16> { let mut __bindgen_bitfield_unit: __BindgenBitfieldUnit<[u8; 2usize], u16> = Default::default(); __bindgen_bitfield_unit.set(0usize, 1u8, { let connectable: u16 = unsafe { ::core::mem::transmute(connectable) }; connectable as u64 }); __bindgen_bitfield_unit.set(1usize, 1u8, { let scannable: u16 = unsafe { ::core::mem::transmute(scannable) }; scannable as u64 }); __bindgen_bitfield_unit.set(2usize, 1u8, { let directed: u16 = unsafe { ::core::mem::transmute(directed) }; directed as u64 }); __bindgen_bitfield_unit.set(3usize, 1u8, { let scan_response: u16 = unsafe { ::core::mem::transmute(scan_response) }; scan_response as u64 }); __bindgen_bitfield_unit.set(4usize, 1u8, { let extended_pdu: u16 = unsafe { ::core::mem::transmute(extended_pdu) }; extended_pdu as u64 }); __bindgen_bitfield_unit.set(5usize, 2u8, { let status: u16 = unsafe { ::core::mem::transmute(status) }; status as u64 }); __bindgen_bitfield_unit.set(7usize, 9u8, { let reserved: u16 = unsafe { ::core::mem::transmute(reserved) }; reserved as u64 }); __bindgen_bitfield_unit } } #[doc = "@brief Advertising Auxiliary Pointer."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_aux_pointer_t { #[doc = "< Time offset from the beginning of advertising packet to the auxiliary packet in 100 us units."] pub aux_offset: u16, #[doc = "< Indicates the PHY on which the auxiliary advertising packet is sent. See @ref BLE_GAP_PHYS."] pub aux_phy: u8, } #[test] fn bindgen_test_layout_ble_gap_aux_pointer_t() { assert_eq!( ::core::mem::size_of::(), 4usize, concat!("Size of: ", stringify!(ble_gap_aux_pointer_t)) ); assert_eq!( ::core::mem::align_of::(), 2usize, concat!("Alignment of ", stringify!(ble_gap_aux_pointer_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).aux_offset as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_aux_pointer_t), "::", stringify!(aux_offset) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).aux_phy as *const _ as usize }, 2usize, concat!( "Offset of field: ", stringify!(ble_gap_aux_pointer_t), "::", stringify!(aux_phy) ) ); } #[doc = "@brief Bluetooth Low Energy address."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_addr_t { pub _bitfield_1: __BindgenBitfieldUnit<[u8; 1usize], u8>, #[doc = "< 48-bit address, LSB format."] #[doc = "@ref addr is not used if @ref addr_type is @ref BLE_GAP_ADDR_TYPE_ANONYMOUS."] pub addr: [u8; 6usize], } #[test] fn bindgen_test_layout_ble_gap_addr_t() { assert_eq!( ::core::mem::size_of::(), 7usize, concat!("Size of: ", stringify!(ble_gap_addr_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!("Alignment of ", stringify!(ble_gap_addr_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).addr as *const _ as usize }, 1usize, concat!( "Offset of field: ", stringify!(ble_gap_addr_t), "::", stringify!(addr) ) ); } impl ble_gap_addr_t { #[inline] pub fn addr_id_peer(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(0usize, 1u8) as u8) } } #[inline] pub fn set_addr_id_peer(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(0usize, 1u8, val as u64) } } #[inline] pub fn addr_type(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(1usize, 7u8) as u8) } } #[inline] pub fn set_addr_type(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(1usize, 7u8, val as u64) } } #[inline] pub fn new_bitfield_1( addr_id_peer: u8, addr_type: u8, ) -> __BindgenBitfieldUnit<[u8; 1usize], u8> { let mut __bindgen_bitfield_unit: __BindgenBitfieldUnit<[u8; 1usize], u8> = Default::default(); __bindgen_bitfield_unit.set(0usize, 1u8, { let addr_id_peer: u8 = unsafe { ::core::mem::transmute(addr_id_peer) }; addr_id_peer as u64 }); __bindgen_bitfield_unit.set(1usize, 7u8, { let addr_type: u8 = unsafe { ::core::mem::transmute(addr_type) }; addr_type as u64 }); __bindgen_bitfield_unit } } #[doc = "@brief GAP connection parameters."] #[doc = ""] #[doc = " @note When ble_conn_params_t is received in an event, both min_conn_interval and"] #[doc = " max_conn_interval will be equal to the connection interval set by the central."] #[doc = ""] #[doc = " @note If both conn_sup_timeout and max_conn_interval are specified, then the following constraint applies:"] #[doc = " conn_sup_timeout * 4 > (1 + slave_latency) * max_conn_interval"] #[doc = " that corresponds to the following Bluetooth Spec requirement:"] #[doc = " The Supervision_Timeout in milliseconds shall be larger than"] #[doc = " (1 + Conn_Latency) * Conn_Interval_Max * 2, where Conn_Interval_Max is given in milliseconds."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_conn_params_t { #[doc = "< Minimum Connection Interval in 1.25 ms units, see @ref BLE_GAP_CP_LIMITS."] pub min_conn_interval: u16, #[doc = "< Maximum Connection Interval in 1.25 ms units, see @ref BLE_GAP_CP_LIMITS."] pub max_conn_interval: u16, #[doc = "< Slave Latency in number of connection events, see @ref BLE_GAP_CP_LIMITS."] pub slave_latency: u16, #[doc = "< Connection Supervision Timeout in 10 ms units, see @ref BLE_GAP_CP_LIMITS."] pub conn_sup_timeout: u16, } #[test] fn bindgen_test_layout_ble_gap_conn_params_t() { assert_eq!( ::core::mem::size_of::(), 8usize, concat!("Size of: ", stringify!(ble_gap_conn_params_t)) ); assert_eq!( ::core::mem::align_of::(), 2usize, concat!("Alignment of ", stringify!(ble_gap_conn_params_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).min_conn_interval as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_conn_params_t), "::", stringify!(min_conn_interval) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).max_conn_interval as *const _ as usize }, 2usize, concat!( "Offset of field: ", stringify!(ble_gap_conn_params_t), "::", stringify!(max_conn_interval) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).slave_latency as *const _ as usize }, 4usize, concat!( "Offset of field: ", stringify!(ble_gap_conn_params_t), "::", stringify!(slave_latency) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).conn_sup_timeout as *const _ as usize }, 6usize, concat!( "Offset of field: ", stringify!(ble_gap_conn_params_t), "::", stringify!(conn_sup_timeout) ) ); } #[doc = "@brief GAP connection security modes."] #[doc = ""] #[doc = " Security Mode 0 Level 0: No access permissions at all (this level is not defined by the Bluetooth Core specification).\\n"] #[doc = " Security Mode 1 Level 1: No security is needed (aka open link).\\n"] #[doc = " Security Mode 1 Level 2: Encrypted link required, MITM protection not necessary.\\n"] #[doc = " Security Mode 1 Level 3: MITM protected encrypted link required.\\n"] #[doc = " Security Mode 1 Level 4: LESC MITM protected encrypted link using a 128-bit strength encryption key required.\\n"] #[doc = " Security Mode 2 Level 1: Signing or encryption required, MITM protection not necessary.\\n"] #[doc = " Security Mode 2 Level 2: MITM protected signing required, unless link is MITM protected encrypted.\\n"] #[repr(C, packed)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_conn_sec_mode_t { pub _bitfield_1: __BindgenBitfieldUnit<[u8; 1usize], u8>, } #[test] fn bindgen_test_layout_ble_gap_conn_sec_mode_t() { assert_eq!( ::core::mem::size_of::(), 1usize, concat!("Size of: ", stringify!(ble_gap_conn_sec_mode_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!("Alignment of ", stringify!(ble_gap_conn_sec_mode_t)) ); } impl ble_gap_conn_sec_mode_t { #[inline] pub fn sm(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(0usize, 4u8) as u8) } } #[inline] pub fn set_sm(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(0usize, 4u8, val as u64) } } #[inline] pub fn lv(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(4usize, 4u8) as u8) } } #[inline] pub fn set_lv(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(4usize, 4u8, val as u64) } } #[inline] pub fn new_bitfield_1(sm: u8, lv: u8) -> __BindgenBitfieldUnit<[u8; 1usize], u8> { let mut __bindgen_bitfield_unit: __BindgenBitfieldUnit<[u8; 1usize], u8> = Default::default(); __bindgen_bitfield_unit.set(0usize, 4u8, { let sm: u8 = unsafe { ::core::mem::transmute(sm) }; sm as u64 }); __bindgen_bitfield_unit.set(4usize, 4u8, { let lv: u8 = unsafe { ::core::mem::transmute(lv) }; lv as u64 }); __bindgen_bitfield_unit } } #[doc = "@brief GAP connection security status."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_conn_sec_t { #[doc = "< Currently active security mode for this connection."] pub sec_mode: ble_gap_conn_sec_mode_t, #[doc = "< Length of currently active encryption key, 7 to 16 octets (only applicable for bonding procedures)."] pub encr_key_size: u8, } #[test] fn bindgen_test_layout_ble_gap_conn_sec_t() { assert_eq!( ::core::mem::size_of::(), 2usize, concat!("Size of: ", stringify!(ble_gap_conn_sec_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!("Alignment of ", stringify!(ble_gap_conn_sec_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).sec_mode as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_conn_sec_t), "::", stringify!(sec_mode) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).encr_key_size as *const _ as usize }, 1usize, concat!( "Offset of field: ", stringify!(ble_gap_conn_sec_t), "::", stringify!(encr_key_size) ) ); } #[doc = "@brief Identity Resolving Key."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_irk_t { #[doc = "< Array containing IRK."] pub irk: [u8; 16usize], } #[test] fn bindgen_test_layout_ble_gap_irk_t() { assert_eq!( ::core::mem::size_of::(), 16usize, concat!("Size of: ", stringify!(ble_gap_irk_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!("Alignment of ", stringify!(ble_gap_irk_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).irk as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_irk_t), "::", stringify!(irk) ) ); } #[doc = "@brief Channel mask (40 bits)."] #[doc = " Every channel is represented with a bit positioned as per channel index defined in Bluetooth Core Specification v5.0,"] #[doc = " Vol 6, Part B, Section 1.4.1. The LSB contained in array element 0 represents channel index 0, and bit 39 represents"] #[doc = " channel index 39. If a bit is set to 1, the channel is not used."] pub type ble_gap_ch_mask_t = [u8; 5usize]; #[doc = "@brief GAP advertising parameters."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_adv_params_t { #[doc = "< The properties of the advertising events."] pub properties: ble_gap_adv_properties_t, #[doc = "< Address of a known peer."] #[doc = "@note ble_gap_addr_t::addr_type cannot be"] #[doc = "@ref BLE_GAP_ADDR_TYPE_ANONYMOUS."] #[doc = "- When privacy is enabled and the local device uses"] #[doc = "@ref BLE_GAP_ADDR_TYPE_RANDOM_PRIVATE_RESOLVABLE addresses,"] #[doc = "the device identity list is searched for a matching entry. If"] #[doc = "the local IRK for that device identity is set, the local IRK"] #[doc = "for that device will be used to generate the advertiser address"] #[doc = "field in the advertising packet."] #[doc = "- If @ref ble_gap_adv_properties_t::type is directed, this must be"] #[doc = "set to the targeted scanner or initiator. If the peer address is"] #[doc = "in the device identity list, the peer IRK for that device will be"] #[doc = "used to generate @ref BLE_GAP_ADDR_TYPE_RANDOM_PRIVATE_RESOLVABLE"] #[doc = "target addresses used in the advertising event PDUs."] pub p_peer_addr: *const ble_gap_addr_t, #[doc = "< Advertising interval in 625 us units. @sa BLE_GAP_ADV_INTERVALS."] #[doc = "@note If @ref ble_gap_adv_properties_t::type is set to"] #[doc = "@ref BLE_GAP_ADV_TYPE_CONNECTABLE_NONSCANNABLE_DIRECTED_HIGH_DUTY_CYCLE"] #[doc = "advertising, this parameter is ignored."] pub interval: u32, #[doc = "< Advertising duration in 10 ms units. When timeout is reached,"] #[doc = "an event of type @ref BLE_GAP_EVT_ADV_SET_TERMINATED is raised."] #[doc = "@sa BLE_GAP_ADV_TIMEOUT_VALUES."] #[doc = "@note The SoftDevice will always complete at least one advertising"] #[doc = "event even if the duration is set too low."] pub duration: u16, #[doc = "< Maximum advertising events that shall be sent prior to disabling"] #[doc = "advertising. Setting the value to 0 disables the limitation. When"] #[doc = "the count of advertising events specified by this parameter"] #[doc = "(if not 0) is reached, advertising will be automatically stopped"] #[doc = "and an event of type @ref BLE_GAP_EVT_ADV_SET_TERMINATED is raised"] #[doc = "@note If @ref ble_gap_adv_properties_t::type is set to"] #[doc = "@ref BLE_GAP_ADV_TYPE_CONNECTABLE_NONSCANNABLE_DIRECTED_HIGH_DUTY_CYCLE,"] #[doc = "this parameter is ignored."] pub max_adv_evts: u8, #[doc = "< Channel mask for primary and secondary advertising channels."] #[doc = "At least one of the primary channels, that is channel index 37-39, must be used."] #[doc = "Masking away secondary advertising channels is not supported."] pub channel_mask: ble_gap_ch_mask_t, #[doc = "< Filter Policy. @sa BLE_GAP_ADV_FILTER_POLICIES."] pub filter_policy: u8, #[doc = "< Indicates the PHY on which the primary advertising channel packets"] #[doc = "are transmitted. If set to @ref BLE_GAP_PHY_AUTO, @ref BLE_GAP_PHY_1MBPS"] #[doc = "will be used."] #[doc = "Valid values are @ref BLE_GAP_PHY_1MBPS and @ref BLE_GAP_PHY_CODED."] #[doc = "@note The primary_phy shall indicate @ref BLE_GAP_PHY_1MBPS if"] #[doc = "@ref ble_gap_adv_properties_t::type is not an extended advertising type."] pub primary_phy: u8, #[doc = "< Indicates the PHY on which the secondary advertising channel packets"] #[doc = "are transmitted."] #[doc = "If set to @ref BLE_GAP_PHY_AUTO, @ref BLE_GAP_PHY_1MBPS will be used."] #[doc = "Valid values are"] #[doc = "@ref BLE_GAP_PHY_1MBPS, @ref BLE_GAP_PHY_2MBPS, and @ref BLE_GAP_PHY_CODED."] #[doc = "If @ref ble_gap_adv_properties_t::type is an extended advertising type"] #[doc = "and connectable, this is the PHY that will be used to establish a"] #[doc = "connection and send AUX_ADV_IND packets on."] #[doc = "@note This parameter will be ignored when"] #[doc = "@ref ble_gap_adv_properties_t::type is not an extended advertising type."] pub secondary_phy: u8, pub _bitfield_1: __BindgenBitfieldUnit<[u8; 1usize], u8>, } #[test] fn bindgen_test_layout_ble_gap_adv_params_t() { assert_eq!( ::core::mem::size_of::(), 24usize, concat!("Size of: ", stringify!(ble_gap_adv_params_t)) ); assert_eq!( ::core::mem::align_of::(), 4usize, concat!("Alignment of ", stringify!(ble_gap_adv_params_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).properties as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_adv_params_t), "::", stringify!(properties) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).p_peer_addr as *const _ as usize }, 4usize, concat!( "Offset of field: ", stringify!(ble_gap_adv_params_t), "::", stringify!(p_peer_addr) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).interval as *const _ as usize }, 8usize, concat!( "Offset of field: ", stringify!(ble_gap_adv_params_t), "::", stringify!(interval) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).duration as *const _ as usize }, 12usize, concat!( "Offset of field: ", stringify!(ble_gap_adv_params_t), "::", stringify!(duration) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).max_adv_evts as *const _ as usize }, 14usize, concat!( "Offset of field: ", stringify!(ble_gap_adv_params_t), "::", stringify!(max_adv_evts) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).channel_mask as *const _ as usize }, 15usize, concat!( "Offset of field: ", stringify!(ble_gap_adv_params_t), "::", stringify!(channel_mask) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).filter_policy as *const _ as usize }, 20usize, concat!( "Offset of field: ", stringify!(ble_gap_adv_params_t), "::", stringify!(filter_policy) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).primary_phy as *const _ as usize }, 21usize, concat!( "Offset of field: ", stringify!(ble_gap_adv_params_t), "::", stringify!(primary_phy) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).secondary_phy as *const _ as usize }, 22usize, concat!( "Offset of field: ", stringify!(ble_gap_adv_params_t), "::", stringify!(secondary_phy) ) ); } impl ble_gap_adv_params_t { #[inline] pub fn set_id(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(0usize, 4u8) as u8) } } #[inline] pub fn set_set_id(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(0usize, 4u8, val as u64) } } #[inline] pub fn scan_req_notification(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(4usize, 1u8) as u8) } } #[inline] pub fn set_scan_req_notification(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(4usize, 1u8, val as u64) } } #[inline] pub fn new_bitfield_1( set_id: u8, scan_req_notification: u8, ) -> __BindgenBitfieldUnit<[u8; 1usize], u8> { let mut __bindgen_bitfield_unit: __BindgenBitfieldUnit<[u8; 1usize], u8> = Default::default(); __bindgen_bitfield_unit.set(0usize, 4u8, { let set_id: u8 = unsafe { ::core::mem::transmute(set_id) }; set_id as u64 }); __bindgen_bitfield_unit.set(4usize, 1u8, { let scan_req_notification: u8 = unsafe { ::core::mem::transmute(scan_req_notification) }; scan_req_notification as u64 }); __bindgen_bitfield_unit } } #[doc = "@brief GAP advertising data buffers."] #[doc = ""] #[doc = " The application must provide the buffers for advertisement. The memory shall reside in application RAM, and"] #[doc = " shall never be modified while advertising. The data shall be kept alive until either:"] #[doc = " - @ref BLE_GAP_EVT_ADV_SET_TERMINATED is raised."] #[doc = " - @ref BLE_GAP_EVT_CONNECTED is raised with @ref ble_gap_evt_connected_t::adv_handle set to the corresponding"] #[doc = " advertising handle."] #[doc = " - Advertising is stopped."] #[doc = " - Advertising data is changed."] #[doc = " To update advertising data while advertising, provide new buffers to @ref sd_ble_gap_adv_set_configure."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_adv_data_t { #[doc = "< Advertising data."] #[doc = "@note"] #[doc = "Advertising data can only be specified for a @ref ble_gap_adv_properties_t::type"] #[doc = "that is allowed to contain advertising data."] pub adv_data: ble_data_t, #[doc = "< Scan response data."] #[doc = "@note"] #[doc = "Scan response data can only be specified for a @ref ble_gap_adv_properties_t::type"] #[doc = "that is scannable."] pub scan_rsp_data: ble_data_t, } #[test] fn bindgen_test_layout_ble_gap_adv_data_t() { assert_eq!( ::core::mem::size_of::(), 16usize, concat!("Size of: ", stringify!(ble_gap_adv_data_t)) ); assert_eq!( ::core::mem::align_of::(), 4usize, concat!("Alignment of ", stringify!(ble_gap_adv_data_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).adv_data as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_adv_data_t), "::", stringify!(adv_data) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).scan_rsp_data as *const _ as usize }, 8usize, concat!( "Offset of field: ", stringify!(ble_gap_adv_data_t), "::", stringify!(scan_rsp_data) ) ); } #[doc = "@brief GAP scanning parameters."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_scan_params_t { pub _bitfield_1: __BindgenBitfieldUnit<[u8; 1usize], u8>, #[doc = "< Bitfield of PHYs to scan on. If set to @ref BLE_GAP_PHY_AUTO,"] #[doc = "scan_phys will default to @ref BLE_GAP_PHY_1MBPS."] #[doc = "- If @ref ble_gap_scan_params_t::extended is set to 0, the only"] #[doc = "supported PHY is @ref BLE_GAP_PHY_1MBPS."] #[doc = "- When used with @ref sd_ble_gap_scan_start,"] #[doc = "the bitfield indicates the PHYs the scanner will use for scanning"] #[doc = "on primary advertising channels. The scanner will accept"] #[doc = "@ref BLE_GAP_PHYS_SUPPORTED as secondary advertising channel PHYs."] #[doc = "- When used with @ref sd_ble_gap_connect, the bitfield indicates"] #[doc = "the PHYs the initiator will use for scanning on primary advertising"] #[doc = "channels. The initiator will accept connections initiated on either"] #[doc = "of the @ref BLE_GAP_PHYS_SUPPORTED PHYs."] #[doc = "If scan_phys contains @ref BLE_GAP_PHY_1MBPS and/or @ref BLE_GAP_PHY_2MBPS,"] #[doc = "the primary scan PHY is @ref BLE_GAP_PHY_1MBPS."] #[doc = "If scan_phys also contains @ref BLE_GAP_PHY_CODED, the primary scan"] #[doc = "PHY will also contain @ref BLE_GAP_PHY_CODED. If the only scan PHY is"] #[doc = "@ref BLE_GAP_PHY_CODED, the primary scan PHY is"] #[doc = "@ref BLE_GAP_PHY_CODED only."] pub scan_phys: u8, #[doc = "< Scan interval in 625 us units. @sa BLE_GAP_SCAN_INTERVALS."] pub interval: u16, #[doc = "< Scan window in 625 us units. @sa BLE_GAP_SCAN_WINDOW."] #[doc = "If scan_phys contains both @ref BLE_GAP_PHY_1MBPS and"] #[doc = "@ref BLE_GAP_PHY_CODED interval shall be larger than or"] #[doc = "equal to twice the scan window."] pub window: u16, #[doc = "< Scan timeout in 10 ms units. @sa BLE_GAP_SCAN_TIMEOUT."] pub timeout: u16, #[doc = "< Channel mask for primary and secondary advertising channels."] #[doc = "At least one of the primary channels, that is channel index 37-39, must be"] #[doc = "set to 0."] #[doc = "Masking away secondary channels is not supported."] pub channel_mask: ble_gap_ch_mask_t, } #[test] fn bindgen_test_layout_ble_gap_scan_params_t() { assert_eq!( ::core::mem::size_of::(), 14usize, concat!("Size of: ", stringify!(ble_gap_scan_params_t)) ); assert_eq!( ::core::mem::align_of::(), 2usize, concat!("Alignment of ", stringify!(ble_gap_scan_params_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).scan_phys as *const _ as usize }, 1usize, concat!( "Offset of field: ", stringify!(ble_gap_scan_params_t), "::", stringify!(scan_phys) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).interval as *const _ as usize }, 2usize, concat!( "Offset of field: ", stringify!(ble_gap_scan_params_t), "::", stringify!(interval) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).window as *const _ as usize }, 4usize, concat!( "Offset of field: ", stringify!(ble_gap_scan_params_t), "::", stringify!(window) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).timeout as *const _ as usize }, 6usize, concat!( "Offset of field: ", stringify!(ble_gap_scan_params_t), "::", stringify!(timeout) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).channel_mask as *const _ as usize }, 8usize, concat!( "Offset of field: ", stringify!(ble_gap_scan_params_t), "::", stringify!(channel_mask) ) ); } impl ble_gap_scan_params_t { #[inline] pub fn extended(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(0usize, 1u8) as u8) } } #[inline] pub fn set_extended(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(0usize, 1u8, val as u64) } } #[inline] pub fn report_incomplete_evts(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(1usize, 1u8) as u8) } } #[inline] pub fn set_report_incomplete_evts(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(1usize, 1u8, val as u64) } } #[inline] pub fn active(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(2usize, 1u8) as u8) } } #[inline] pub fn set_active(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(2usize, 1u8, val as u64) } } #[inline] pub fn filter_policy(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(3usize, 2u8) as u8) } } #[inline] pub fn set_filter_policy(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(3usize, 2u8, val as u64) } } #[inline] pub fn new_bitfield_1( extended: u8, report_incomplete_evts: u8, active: u8, filter_policy: u8, ) -> __BindgenBitfieldUnit<[u8; 1usize], u8> { let mut __bindgen_bitfield_unit: __BindgenBitfieldUnit<[u8; 1usize], u8> = Default::default(); __bindgen_bitfield_unit.set(0usize, 1u8, { let extended: u8 = unsafe { ::core::mem::transmute(extended) }; extended as u64 }); __bindgen_bitfield_unit.set(1usize, 1u8, { let report_incomplete_evts: u8 = unsafe { ::core::mem::transmute(report_incomplete_evts) }; report_incomplete_evts as u64 }); __bindgen_bitfield_unit.set(2usize, 1u8, { let active: u8 = unsafe { ::core::mem::transmute(active) }; active as u64 }); __bindgen_bitfield_unit.set(3usize, 2u8, { let filter_policy: u8 = unsafe { ::core::mem::transmute(filter_policy) }; filter_policy as u64 }); __bindgen_bitfield_unit } } #[doc = "@brief Privacy."] #[doc = ""] #[doc = " The privacy feature provides a way for the device to avoid being tracked over a period of time."] #[doc = " The privacy feature, when enabled, hides the local device identity and replaces it with a private address"] #[doc = " that is automatically refreshed at a specified interval."] #[doc = ""] #[doc = " If a device still wants to be recognized by other peers, it needs to share it's Identity Resolving Key (IRK)."] #[doc = " With this key, a device can generate a random private address that can only be recognized by peers in possession of that key,"] #[doc = " and devices can establish connections without revealing their real identities."] #[doc = ""] #[doc = " Both network privacy (@ref BLE_GAP_PRIVACY_MODE_NETWORK_PRIVACY) and device privacy (@ref BLE_GAP_PRIVACY_MODE_DEVICE_PRIVACY)"] #[doc = " are supported."] #[doc = ""] #[doc = " @note If the device IRK is updated, the new IRK becomes the one to be distributed in all"] #[doc = " bonding procedures performed after @ref sd_ble_gap_privacy_set returns."] #[doc = " The IRK distributed during bonding procedure is the device IRK that is active when @ref sd_ble_gap_sec_params_reply is called."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_privacy_params_t { #[doc = "< Privacy mode, see @ref BLE_GAP_PRIVACY_MODES. Default is @ref BLE_GAP_PRIVACY_MODE_OFF."] pub privacy_mode: u8, #[doc = "< The private address type must be either @ref BLE_GAP_ADDR_TYPE_RANDOM_PRIVATE_RESOLVABLE or @ref BLE_GAP_ADDR_TYPE_RANDOM_PRIVATE_NON_RESOLVABLE."] pub private_addr_type: u8, #[doc = "< Private address cycle interval in seconds. Providing an address cycle value of 0 will use the default value defined by @ref BLE_GAP_DEFAULT_PRIVATE_ADDR_CYCLE_INTERVAL_S."] pub private_addr_cycle_s: u16, #[doc = "< When used as input, pointer to IRK structure that will be used as the default IRK. If NULL, the device default IRK will be used."] #[doc = "When used as output, pointer to IRK structure where the current default IRK will be written to. If NULL, this argument is ignored."] #[doc = "By default, the default IRK is used to generate random private resolvable addresses for the local device unless instructed otherwise."] pub p_device_irk: *mut ble_gap_irk_t, } #[test] fn bindgen_test_layout_ble_gap_privacy_params_t() { assert_eq!( ::core::mem::size_of::(), 8usize, concat!("Size of: ", stringify!(ble_gap_privacy_params_t)) ); assert_eq!( ::core::mem::align_of::(), 4usize, concat!("Alignment of ", stringify!(ble_gap_privacy_params_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).privacy_mode as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_privacy_params_t), "::", stringify!(privacy_mode) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).private_addr_type as *const _ as usize }, 1usize, concat!( "Offset of field: ", stringify!(ble_gap_privacy_params_t), "::", stringify!(private_addr_type) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).private_addr_cycle_s as *const _ as usize }, 2usize, concat!( "Offset of field: ", stringify!(ble_gap_privacy_params_t), "::", stringify!(private_addr_cycle_s) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).p_device_irk as *const _ as usize }, 4usize, concat!( "Offset of field: ", stringify!(ble_gap_privacy_params_t), "::", stringify!(p_device_irk) ) ); } #[doc = "@brief PHY preferences for TX and RX"] #[doc = " @note tx_phys and rx_phys are bit fields. Multiple bits can be set in them to indicate multiple preferred PHYs for each direction."] #[doc = " @code"] #[doc = " p_gap_phys->tx_phys = BLE_GAP_PHY_1MBPS | BLE_GAP_PHY_2MBPS;"] #[doc = " p_gap_phys->rx_phys = BLE_GAP_PHY_1MBPS | BLE_GAP_PHY_2MBPS;"] #[doc = " @endcode"] #[doc = ""] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_phys_t { #[doc = "< Preferred transmit PHYs, see @ref BLE_GAP_PHYS."] pub tx_phys: u8, #[doc = "< Preferred receive PHYs, see @ref BLE_GAP_PHYS."] pub rx_phys: u8, } #[test] fn bindgen_test_layout_ble_gap_phys_t() { assert_eq!( ::core::mem::size_of::(), 2usize, concat!("Size of: ", stringify!(ble_gap_phys_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!("Alignment of ", stringify!(ble_gap_phys_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).tx_phys as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_phys_t), "::", stringify!(tx_phys) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).rx_phys as *const _ as usize }, 1usize, concat!( "Offset of field: ", stringify!(ble_gap_phys_t), "::", stringify!(rx_phys) ) ); } #[doc = " @brief Keys that can be exchanged during a bonding procedure."] #[repr(C, packed)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_sec_kdist_t { pub _bitfield_1: __BindgenBitfieldUnit<[u8; 1usize], u8>, } #[test] fn bindgen_test_layout_ble_gap_sec_kdist_t() { assert_eq!( ::core::mem::size_of::(), 1usize, concat!("Size of: ", stringify!(ble_gap_sec_kdist_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!("Alignment of ", stringify!(ble_gap_sec_kdist_t)) ); } impl ble_gap_sec_kdist_t { #[inline] pub fn enc(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(0usize, 1u8) as u8) } } #[inline] pub fn set_enc(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(0usize, 1u8, val as u64) } } #[inline] pub fn id(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(1usize, 1u8) as u8) } } #[inline] pub fn set_id(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(1usize, 1u8, val as u64) } } #[inline] pub fn sign(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(2usize, 1u8) as u8) } } #[inline] pub fn set_sign(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(2usize, 1u8, val as u64) } } #[inline] pub fn link(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(3usize, 1u8) as u8) } } #[inline] pub fn set_link(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(3usize, 1u8, val as u64) } } #[inline] pub fn new_bitfield_1( enc: u8, id: u8, sign: u8, link: u8, ) -> __BindgenBitfieldUnit<[u8; 1usize], u8> { let mut __bindgen_bitfield_unit: __BindgenBitfieldUnit<[u8; 1usize], u8> = Default::default(); __bindgen_bitfield_unit.set(0usize, 1u8, { let enc: u8 = unsafe { ::core::mem::transmute(enc) }; enc as u64 }); __bindgen_bitfield_unit.set(1usize, 1u8, { let id: u8 = unsafe { ::core::mem::transmute(id) }; id as u64 }); __bindgen_bitfield_unit.set(2usize, 1u8, { let sign: u8 = unsafe { ::core::mem::transmute(sign) }; sign as u64 }); __bindgen_bitfield_unit.set(3usize, 1u8, { let link: u8 = unsafe { ::core::mem::transmute(link) }; link as u64 }); __bindgen_bitfield_unit } } #[doc = "@brief GAP security parameters."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_sec_params_t { pub _bitfield_1: __BindgenBitfieldUnit<[u8; 1usize], u8>, #[doc = "< Minimum encryption key size in octets between 7 and 16. If 0 then not applicable in this instance."] pub min_key_size: u8, #[doc = "< Maximum encryption key size in octets between min_key_size and 16."] pub max_key_size: u8, #[doc = "< Key distribution bitmap: keys that the local device will distribute."] pub kdist_own: ble_gap_sec_kdist_t, #[doc = "< Key distribution bitmap: keys that the remote device will distribute."] pub kdist_peer: ble_gap_sec_kdist_t, } #[test] fn bindgen_test_layout_ble_gap_sec_params_t() { assert_eq!( ::core::mem::size_of::(), 5usize, concat!("Size of: ", stringify!(ble_gap_sec_params_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!("Alignment of ", stringify!(ble_gap_sec_params_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).min_key_size as *const _ as usize }, 1usize, concat!( "Offset of field: ", stringify!(ble_gap_sec_params_t), "::", stringify!(min_key_size) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).max_key_size as *const _ as usize }, 2usize, concat!( "Offset of field: ", stringify!(ble_gap_sec_params_t), "::", stringify!(max_key_size) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).kdist_own as *const _ as usize }, 3usize, concat!( "Offset of field: ", stringify!(ble_gap_sec_params_t), "::", stringify!(kdist_own) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).kdist_peer as *const _ as usize }, 4usize, concat!( "Offset of field: ", stringify!(ble_gap_sec_params_t), "::", stringify!(kdist_peer) ) ); } impl ble_gap_sec_params_t { #[inline] pub fn bond(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(0usize, 1u8) as u8) } } #[inline] pub fn set_bond(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(0usize, 1u8, val as u64) } } #[inline] pub fn mitm(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(1usize, 1u8) as u8) } } #[inline] pub fn set_mitm(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(1usize, 1u8, val as u64) } } #[inline] pub fn lesc(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(2usize, 1u8) as u8) } } #[inline] pub fn set_lesc(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(2usize, 1u8, val as u64) } } #[inline] pub fn keypress(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(3usize, 1u8) as u8) } } #[inline] pub fn set_keypress(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(3usize, 1u8, val as u64) } } #[inline] pub fn io_caps(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(4usize, 3u8) as u8) } } #[inline] pub fn set_io_caps(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(4usize, 3u8, val as u64) } } #[inline] pub fn oob(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(7usize, 1u8) as u8) } } #[inline] pub fn set_oob(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(7usize, 1u8, val as u64) } } #[inline] pub fn new_bitfield_1( bond: u8, mitm: u8, lesc: u8, keypress: u8, io_caps: u8, oob: u8, ) -> __BindgenBitfieldUnit<[u8; 1usize], u8> { let mut __bindgen_bitfield_unit: __BindgenBitfieldUnit<[u8; 1usize], u8> = Default::default(); __bindgen_bitfield_unit.set(0usize, 1u8, { let bond: u8 = unsafe { ::core::mem::transmute(bond) }; bond as u64 }); __bindgen_bitfield_unit.set(1usize, 1u8, { let mitm: u8 = unsafe { ::core::mem::transmute(mitm) }; mitm as u64 }); __bindgen_bitfield_unit.set(2usize, 1u8, { let lesc: u8 = unsafe { ::core::mem::transmute(lesc) }; lesc as u64 }); __bindgen_bitfield_unit.set(3usize, 1u8, { let keypress: u8 = unsafe { ::core::mem::transmute(keypress) }; keypress as u64 }); __bindgen_bitfield_unit.set(4usize, 3u8, { let io_caps: u8 = unsafe { ::core::mem::transmute(io_caps) }; io_caps as u64 }); __bindgen_bitfield_unit.set(7usize, 1u8, { let oob: u8 = unsafe { ::core::mem::transmute(oob) }; oob as u64 }); __bindgen_bitfield_unit } } #[doc = "@brief GAP Encryption Information."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_enc_info_t { #[doc = "< Long Term Key."] pub ltk: [u8; 16usize], pub _bitfield_1: __BindgenBitfieldUnit<[u8; 1usize], u8>, } #[test] fn bindgen_test_layout_ble_gap_enc_info_t() { assert_eq!( ::core::mem::size_of::(), 17usize, concat!("Size of: ", stringify!(ble_gap_enc_info_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!("Alignment of ", stringify!(ble_gap_enc_info_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).ltk as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_enc_info_t), "::", stringify!(ltk) ) ); } impl ble_gap_enc_info_t { #[inline] pub fn lesc(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(0usize, 1u8) as u8) } } #[inline] pub fn set_lesc(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(0usize, 1u8, val as u64) } } #[inline] pub fn auth(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(1usize, 1u8) as u8) } } #[inline] pub fn set_auth(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(1usize, 1u8, val as u64) } } #[inline] pub fn ltk_len(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(2usize, 6u8) as u8) } } #[inline] pub fn set_ltk_len(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(2usize, 6u8, val as u64) } } #[inline] pub fn new_bitfield_1( lesc: u8, auth: u8, ltk_len: u8, ) -> __BindgenBitfieldUnit<[u8; 1usize], u8> { let mut __bindgen_bitfield_unit: __BindgenBitfieldUnit<[u8; 1usize], u8> = Default::default(); __bindgen_bitfield_unit.set(0usize, 1u8, { let lesc: u8 = unsafe { ::core::mem::transmute(lesc) }; lesc as u64 }); __bindgen_bitfield_unit.set(1usize, 1u8, { let auth: u8 = unsafe { ::core::mem::transmute(auth) }; auth as u64 }); __bindgen_bitfield_unit.set(2usize, 6u8, { let ltk_len: u8 = unsafe { ::core::mem::transmute(ltk_len) }; ltk_len as u64 }); __bindgen_bitfield_unit } } #[doc = "@brief GAP Master Identification."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_master_id_t { #[doc = "< Encrypted Diversifier."] pub ediv: u16, #[doc = "< Random Number."] pub rand: [u8; 8usize], } #[test] fn bindgen_test_layout_ble_gap_master_id_t() { assert_eq!( ::core::mem::size_of::(), 10usize, concat!("Size of: ", stringify!(ble_gap_master_id_t)) ); assert_eq!( ::core::mem::align_of::(), 2usize, concat!("Alignment of ", stringify!(ble_gap_master_id_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).ediv as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_master_id_t), "::", stringify!(ediv) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).rand as *const _ as usize }, 2usize, concat!( "Offset of field: ", stringify!(ble_gap_master_id_t), "::", stringify!(rand) ) ); } #[doc = "@brief GAP Signing Information."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_sign_info_t { #[doc = "< Connection Signature Resolving Key."] pub csrk: [u8; 16usize], } #[test] fn bindgen_test_layout_ble_gap_sign_info_t() { assert_eq!( ::core::mem::size_of::(), 16usize, concat!("Size of: ", stringify!(ble_gap_sign_info_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!("Alignment of ", stringify!(ble_gap_sign_info_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).csrk as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_sign_info_t), "::", stringify!(csrk) ) ); } #[doc = "@brief GAP LE Secure Connections P-256 Public Key."] #[repr(C)] #[derive(Copy, Clone)] pub struct ble_gap_lesc_p256_pk_t { #[doc = "< LE Secure Connections Elliptic Curve Diffie-Hellman P-256 Public Key. Stored in the standard SMP protocol format: {X,Y} both in little-endian."] pub pk: [u8; 64usize], } #[test] fn bindgen_test_layout_ble_gap_lesc_p256_pk_t() { assert_eq!( ::core::mem::size_of::(), 64usize, concat!("Size of: ", stringify!(ble_gap_lesc_p256_pk_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!("Alignment of ", stringify!(ble_gap_lesc_p256_pk_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).pk as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_lesc_p256_pk_t), "::", stringify!(pk) ) ); } #[doc = "@brief GAP LE Secure Connections DHKey."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_lesc_dhkey_t { #[doc = "< LE Secure Connections Elliptic Curve Diffie-Hellman Key. Stored in little-endian."] pub key: [u8; 32usize], } #[test] fn bindgen_test_layout_ble_gap_lesc_dhkey_t() { assert_eq!( ::core::mem::size_of::(), 32usize, concat!("Size of: ", stringify!(ble_gap_lesc_dhkey_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!("Alignment of ", stringify!(ble_gap_lesc_dhkey_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).key as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_lesc_dhkey_t), "::", stringify!(key) ) ); } #[doc = "@brief GAP LE Secure Connections OOB data."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_lesc_oob_data_t { #[doc = "< Bluetooth address of the device."] pub addr: ble_gap_addr_t, #[doc = "< Random Number."] pub r: [u8; 16usize], #[doc = "< Confirm Value."] pub c: [u8; 16usize], } #[test] fn bindgen_test_layout_ble_gap_lesc_oob_data_t() { assert_eq!( ::core::mem::size_of::(), 39usize, concat!("Size of: ", stringify!(ble_gap_lesc_oob_data_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!("Alignment of ", stringify!(ble_gap_lesc_oob_data_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).addr as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_lesc_oob_data_t), "::", stringify!(addr) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).r as *const _ as usize }, 7usize, concat!( "Offset of field: ", stringify!(ble_gap_lesc_oob_data_t), "::", stringify!(r) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).c as *const _ as usize }, 23usize, concat!( "Offset of field: ", stringify!(ble_gap_lesc_oob_data_t), "::", stringify!(c) ) ); } #[doc = "@brief Event structure for @ref BLE_GAP_EVT_CONNECTED."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_evt_connected_t { #[doc = "< Bluetooth address of the peer device. If the peer_addr resolved: @ref ble_gap_addr_t::addr_id_peer is set to 1"] #[doc = "and the address is the device's identity address."] pub peer_addr: ble_gap_addr_t, #[doc = "< BLE role for this connection, see @ref BLE_GAP_ROLES"] pub role: u8, #[doc = "< GAP Connection Parameters."] pub conn_params: ble_gap_conn_params_t, #[doc = "< Advertising handle in which advertising has ended."] #[doc = "This variable is only set if role is set to @ref BLE_GAP_ROLE_PERIPH."] pub adv_handle: u8, #[doc = "< Advertising buffers corresponding to the terminated"] #[doc = "advertising set. The advertising buffers provided in"] #[doc = "@ref sd_ble_gap_adv_set_configure are now released."] #[doc = "This variable is only set if role is set to @ref BLE_GAP_ROLE_PERIPH."] pub adv_data: ble_gap_adv_data_t, } #[test] fn bindgen_test_layout_ble_gap_evt_connected_t() { assert_eq!( ::core::mem::size_of::(), 36usize, concat!("Size of: ", stringify!(ble_gap_evt_connected_t)) ); assert_eq!( ::core::mem::align_of::(), 4usize, concat!("Alignment of ", stringify!(ble_gap_evt_connected_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).peer_addr as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_connected_t), "::", stringify!(peer_addr) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).role as *const _ as usize }, 7usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_connected_t), "::", stringify!(role) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).conn_params as *const _ as usize }, 8usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_connected_t), "::", stringify!(conn_params) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).adv_handle as *const _ as usize }, 16usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_connected_t), "::", stringify!(adv_handle) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).adv_data as *const _ as usize }, 20usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_connected_t), "::", stringify!(adv_data) ) ); } #[doc = "@brief Event structure for @ref BLE_GAP_EVT_DISCONNECTED."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_evt_disconnected_t { #[doc = "< HCI error code, see @ref BLE_HCI_STATUS_CODES."] pub reason: u8, } #[test] fn bindgen_test_layout_ble_gap_evt_disconnected_t() { assert_eq!( ::core::mem::size_of::(), 1usize, concat!("Size of: ", stringify!(ble_gap_evt_disconnected_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!("Alignment of ", stringify!(ble_gap_evt_disconnected_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).reason as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_disconnected_t), "::", stringify!(reason) ) ); } #[doc = "@brief Event structure for @ref BLE_GAP_EVT_CONN_PARAM_UPDATE."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_evt_conn_param_update_t { #[doc = "< GAP Connection Parameters."] pub conn_params: ble_gap_conn_params_t, } #[test] fn bindgen_test_layout_ble_gap_evt_conn_param_update_t() { assert_eq!( ::core::mem::size_of::(), 8usize, concat!("Size of: ", stringify!(ble_gap_evt_conn_param_update_t)) ); assert_eq!( ::core::mem::align_of::(), 2usize, concat!("Alignment of ", stringify!(ble_gap_evt_conn_param_update_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).conn_params as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_conn_param_update_t), "::", stringify!(conn_params) ) ); } #[doc = "@brief Event structure for @ref BLE_GAP_EVT_PHY_UPDATE_REQUEST."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_evt_phy_update_request_t { #[doc = "< The PHYs the peer prefers to use."] pub peer_preferred_phys: ble_gap_phys_t, } #[test] fn bindgen_test_layout_ble_gap_evt_phy_update_request_t() { assert_eq!( ::core::mem::size_of::(), 2usize, concat!("Size of: ", stringify!(ble_gap_evt_phy_update_request_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!( "Alignment of ", stringify!(ble_gap_evt_phy_update_request_t) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).peer_preferred_phys as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_phy_update_request_t), "::", stringify!(peer_preferred_phys) ) ); } #[doc = "@brief Event Structure for @ref BLE_GAP_EVT_PHY_UPDATE."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_evt_phy_update_t { #[doc = "< Status of the procedure, see @ref BLE_HCI_STATUS_CODES."] pub status: u8, #[doc = "< TX PHY for this connection, see @ref BLE_GAP_PHYS."] pub tx_phy: u8, #[doc = "< RX PHY for this connection, see @ref BLE_GAP_PHYS."] pub rx_phy: u8, } #[test] fn bindgen_test_layout_ble_gap_evt_phy_update_t() { assert_eq!( ::core::mem::size_of::(), 3usize, concat!("Size of: ", stringify!(ble_gap_evt_phy_update_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!("Alignment of ", stringify!(ble_gap_evt_phy_update_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).status as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_phy_update_t), "::", stringify!(status) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).tx_phy as *const _ as usize }, 1usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_phy_update_t), "::", stringify!(tx_phy) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).rx_phy as *const _ as usize }, 2usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_phy_update_t), "::", stringify!(rx_phy) ) ); } #[doc = "@brief Event structure for @ref BLE_GAP_EVT_SEC_PARAMS_REQUEST."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_evt_sec_params_request_t { #[doc = "< Initiator Security Parameters."] pub peer_params: ble_gap_sec_params_t, } #[test] fn bindgen_test_layout_ble_gap_evt_sec_params_request_t() { assert_eq!( ::core::mem::size_of::(), 5usize, concat!("Size of: ", stringify!(ble_gap_evt_sec_params_request_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!( "Alignment of ", stringify!(ble_gap_evt_sec_params_request_t) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).peer_params as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_sec_params_request_t), "::", stringify!(peer_params) ) ); } #[doc = "@brief Event structure for @ref BLE_GAP_EVT_SEC_INFO_REQUEST."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_evt_sec_info_request_t { #[doc = "< Bluetooth address of the peer device."] pub peer_addr: ble_gap_addr_t, #[doc = "< Master Identification for LTK lookup."] pub master_id: ble_gap_master_id_t, pub _bitfield_1: __BindgenBitfieldUnit<[u8; 1usize], u8>, pub __bindgen_padding_0: u8, } #[test] fn bindgen_test_layout_ble_gap_evt_sec_info_request_t() { assert_eq!( ::core::mem::size_of::(), 20usize, concat!("Size of: ", stringify!(ble_gap_evt_sec_info_request_t)) ); assert_eq!( ::core::mem::align_of::(), 2usize, concat!("Alignment of ", stringify!(ble_gap_evt_sec_info_request_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).peer_addr as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_sec_info_request_t), "::", stringify!(peer_addr) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).master_id as *const _ as usize }, 8usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_sec_info_request_t), "::", stringify!(master_id) ) ); } impl ble_gap_evt_sec_info_request_t { #[inline] pub fn enc_info(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(0usize, 1u8) as u8) } } #[inline] pub fn set_enc_info(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(0usize, 1u8, val as u64) } } #[inline] pub fn id_info(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(1usize, 1u8) as u8) } } #[inline] pub fn set_id_info(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(1usize, 1u8, val as u64) } } #[inline] pub fn sign_info(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(2usize, 1u8) as u8) } } #[inline] pub fn set_sign_info(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(2usize, 1u8, val as u64) } } #[inline] pub fn new_bitfield_1( enc_info: u8, id_info: u8, sign_info: u8, ) -> __BindgenBitfieldUnit<[u8; 1usize], u8> { let mut __bindgen_bitfield_unit: __BindgenBitfieldUnit<[u8; 1usize], u8> = Default::default(); __bindgen_bitfield_unit.set(0usize, 1u8, { let enc_info: u8 = unsafe { ::core::mem::transmute(enc_info) }; enc_info as u64 }); __bindgen_bitfield_unit.set(1usize, 1u8, { let id_info: u8 = unsafe { ::core::mem::transmute(id_info) }; id_info as u64 }); __bindgen_bitfield_unit.set(2usize, 1u8, { let sign_info: u8 = unsafe { ::core::mem::transmute(sign_info) }; sign_info as u64 }); __bindgen_bitfield_unit } } #[doc = "@brief Event structure for @ref BLE_GAP_EVT_PASSKEY_DISPLAY."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_evt_passkey_display_t { #[doc = "< 6-digit passkey in ASCII ('0'-'9' digits only)."] pub passkey: [u8; 6usize], pub _bitfield_1: __BindgenBitfieldUnit<[u8; 1usize], u8>, } #[test] fn bindgen_test_layout_ble_gap_evt_passkey_display_t() { assert_eq!( ::core::mem::size_of::(), 7usize, concat!("Size of: ", stringify!(ble_gap_evt_passkey_display_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!("Alignment of ", stringify!(ble_gap_evt_passkey_display_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).passkey as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_passkey_display_t), "::", stringify!(passkey) ) ); } impl ble_gap_evt_passkey_display_t { #[inline] pub fn match_request(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(0usize, 1u8) as u8) } } #[inline] pub fn set_match_request(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(0usize, 1u8, val as u64) } } #[inline] pub fn new_bitfield_1(match_request: u8) -> __BindgenBitfieldUnit<[u8; 1usize], u8> { let mut __bindgen_bitfield_unit: __BindgenBitfieldUnit<[u8; 1usize], u8> = Default::default(); __bindgen_bitfield_unit.set(0usize, 1u8, { let match_request: u8 = unsafe { ::core::mem::transmute(match_request) }; match_request as u64 }); __bindgen_bitfield_unit } } #[doc = "@brief Event structure for @ref BLE_GAP_EVT_KEY_PRESSED."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_evt_key_pressed_t { #[doc = "< Keypress notification type, see @ref BLE_GAP_KP_NOT_TYPES."] pub kp_not: u8, } #[test] fn bindgen_test_layout_ble_gap_evt_key_pressed_t() { assert_eq!( ::core::mem::size_of::(), 1usize, concat!("Size of: ", stringify!(ble_gap_evt_key_pressed_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!("Alignment of ", stringify!(ble_gap_evt_key_pressed_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).kp_not as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_key_pressed_t), "::", stringify!(kp_not) ) ); } #[doc = "@brief Event structure for @ref BLE_GAP_EVT_AUTH_KEY_REQUEST."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_evt_auth_key_request_t { #[doc = "< See @ref BLE_GAP_AUTH_KEY_TYPES."] pub key_type: u8, } #[test] fn bindgen_test_layout_ble_gap_evt_auth_key_request_t() { assert_eq!( ::core::mem::size_of::(), 1usize, concat!("Size of: ", stringify!(ble_gap_evt_auth_key_request_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!("Alignment of ", stringify!(ble_gap_evt_auth_key_request_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).key_type as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_auth_key_request_t), "::", stringify!(key_type) ) ); } #[doc = "@brief Event structure for @ref BLE_GAP_EVT_LESC_DHKEY_REQUEST."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_evt_lesc_dhkey_request_t { #[doc = "< LE Secure Connections remote P-256 Public Key. This will point to the application-supplied memory"] #[doc = "inside the keyset during the call to @ref sd_ble_gap_sec_params_reply."] pub p_pk_peer: *mut ble_gap_lesc_p256_pk_t, pub _bitfield_1: __BindgenBitfieldUnit<[u8; 1usize], u8>, pub __bindgen_padding_0: [u8; 3usize], } #[test] fn bindgen_test_layout_ble_gap_evt_lesc_dhkey_request_t() { assert_eq!( ::core::mem::size_of::(), 8usize, concat!("Size of: ", stringify!(ble_gap_evt_lesc_dhkey_request_t)) ); assert_eq!( ::core::mem::align_of::(), 4usize, concat!( "Alignment of ", stringify!(ble_gap_evt_lesc_dhkey_request_t) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).p_pk_peer as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_lesc_dhkey_request_t), "::", stringify!(p_pk_peer) ) ); } impl ble_gap_evt_lesc_dhkey_request_t { #[inline] pub fn oobd_req(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(0usize, 1u8) as u8) } } #[inline] pub fn set_oobd_req(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(0usize, 1u8, val as u64) } } #[inline] pub fn new_bitfield_1(oobd_req: u8) -> __BindgenBitfieldUnit<[u8; 1usize], u8> { let mut __bindgen_bitfield_unit: __BindgenBitfieldUnit<[u8; 1usize], u8> = Default::default(); __bindgen_bitfield_unit.set(0usize, 1u8, { let oobd_req: u8 = unsafe { ::core::mem::transmute(oobd_req) }; oobd_req as u64 }); __bindgen_bitfield_unit } } #[doc = "@brief Security levels supported."] #[doc = " @note See Bluetooth Specification Version 4.2 Volume 3, Part C, Chapter 10, Section 10.2.1."] #[repr(C, packed)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_sec_levels_t { pub _bitfield_1: __BindgenBitfieldUnit<[u8; 1usize], u8>, } #[test] fn bindgen_test_layout_ble_gap_sec_levels_t() { assert_eq!( ::core::mem::size_of::(), 1usize, concat!("Size of: ", stringify!(ble_gap_sec_levels_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!("Alignment of ", stringify!(ble_gap_sec_levels_t)) ); } impl ble_gap_sec_levels_t { #[inline] pub fn lv1(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(0usize, 1u8) as u8) } } #[inline] pub fn set_lv1(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(0usize, 1u8, val as u64) } } #[inline] pub fn lv2(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(1usize, 1u8) as u8) } } #[inline] pub fn set_lv2(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(1usize, 1u8, val as u64) } } #[inline] pub fn lv3(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(2usize, 1u8) as u8) } } #[inline] pub fn set_lv3(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(2usize, 1u8, val as u64) } } #[inline] pub fn lv4(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(3usize, 1u8) as u8) } } #[inline] pub fn set_lv4(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(3usize, 1u8, val as u64) } } #[inline] pub fn new_bitfield_1( lv1: u8, lv2: u8, lv3: u8, lv4: u8, ) -> __BindgenBitfieldUnit<[u8; 1usize], u8> { let mut __bindgen_bitfield_unit: __BindgenBitfieldUnit<[u8; 1usize], u8> = Default::default(); __bindgen_bitfield_unit.set(0usize, 1u8, { let lv1: u8 = unsafe { ::core::mem::transmute(lv1) }; lv1 as u64 }); __bindgen_bitfield_unit.set(1usize, 1u8, { let lv2: u8 = unsafe { ::core::mem::transmute(lv2) }; lv2 as u64 }); __bindgen_bitfield_unit.set(2usize, 1u8, { let lv3: u8 = unsafe { ::core::mem::transmute(lv3) }; lv3 as u64 }); __bindgen_bitfield_unit.set(3usize, 1u8, { let lv4: u8 = unsafe { ::core::mem::transmute(lv4) }; lv4 as u64 }); __bindgen_bitfield_unit } } #[doc = "@brief Encryption Key."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_enc_key_t { #[doc = "< Encryption Information."] pub enc_info: ble_gap_enc_info_t, #[doc = "< Master Identification."] pub master_id: ble_gap_master_id_t, } #[test] fn bindgen_test_layout_ble_gap_enc_key_t() { assert_eq!( ::core::mem::size_of::(), 28usize, concat!("Size of: ", stringify!(ble_gap_enc_key_t)) ); assert_eq!( ::core::mem::align_of::(), 2usize, concat!("Alignment of ", stringify!(ble_gap_enc_key_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).enc_info as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_enc_key_t), "::", stringify!(enc_info) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).master_id as *const _ as usize }, 18usize, concat!( "Offset of field: ", stringify!(ble_gap_enc_key_t), "::", stringify!(master_id) ) ); } #[doc = "@brief Identity Key."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_id_key_t { #[doc = "< Identity Resolving Key."] pub id_info: ble_gap_irk_t, #[doc = "< Identity Address."] pub id_addr_info: ble_gap_addr_t, } #[test] fn bindgen_test_layout_ble_gap_id_key_t() { assert_eq!( ::core::mem::size_of::(), 23usize, concat!("Size of: ", stringify!(ble_gap_id_key_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!("Alignment of ", stringify!(ble_gap_id_key_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).id_info as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_id_key_t), "::", stringify!(id_info) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).id_addr_info as *const _ as usize }, 16usize, concat!( "Offset of field: ", stringify!(ble_gap_id_key_t), "::", stringify!(id_addr_info) ) ); } #[doc = "@brief Security Keys."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_sec_keys_t { #[doc = "< Encryption Key, or NULL."] pub p_enc_key: *mut ble_gap_enc_key_t, #[doc = "< Identity Key, or NULL."] pub p_id_key: *mut ble_gap_id_key_t, #[doc = "< Signing Key, or NULL."] pub p_sign_key: *mut ble_gap_sign_info_t, #[doc = "< LE Secure Connections P-256 Public Key. When in debug mode the application must use the value defined"] #[doc = "in the Core Bluetooth Specification v4.2 Vol.3, Part H, Section 2.3.5.6.1"] pub p_pk: *mut ble_gap_lesc_p256_pk_t, } #[test] fn bindgen_test_layout_ble_gap_sec_keys_t() { assert_eq!( ::core::mem::size_of::(), 16usize, concat!("Size of: ", stringify!(ble_gap_sec_keys_t)) ); assert_eq!( ::core::mem::align_of::(), 4usize, concat!("Alignment of ", stringify!(ble_gap_sec_keys_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).p_enc_key as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_sec_keys_t), "::", stringify!(p_enc_key) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).p_id_key as *const _ as usize }, 4usize, concat!( "Offset of field: ", stringify!(ble_gap_sec_keys_t), "::", stringify!(p_id_key) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).p_sign_key as *const _ as usize }, 8usize, concat!( "Offset of field: ", stringify!(ble_gap_sec_keys_t), "::", stringify!(p_sign_key) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).p_pk as *const _ as usize }, 12usize, concat!( "Offset of field: ", stringify!(ble_gap_sec_keys_t), "::", stringify!(p_pk) ) ); } #[doc = "@brief Security key set for both local and peer keys."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_sec_keyset_t { #[doc = "< Keys distributed by the local device. For LE Secure Connections the encryption key will be generated locally and will always be stored if bonding."] pub keys_own: ble_gap_sec_keys_t, #[doc = "< Keys distributed by the remote device. For LE Secure Connections, p_enc_key must always be NULL."] pub keys_peer: ble_gap_sec_keys_t, } #[test] fn bindgen_test_layout_ble_gap_sec_keyset_t() { assert_eq!( ::core::mem::size_of::(), 32usize, concat!("Size of: ", stringify!(ble_gap_sec_keyset_t)) ); assert_eq!( ::core::mem::align_of::(), 4usize, concat!("Alignment of ", stringify!(ble_gap_sec_keyset_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).keys_own as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_sec_keyset_t), "::", stringify!(keys_own) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).keys_peer as *const _ as usize }, 16usize, concat!( "Offset of field: ", stringify!(ble_gap_sec_keyset_t), "::", stringify!(keys_peer) ) ); } #[doc = "@brief Data Length Update Procedure parameters."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_data_length_params_t { #[doc = "< Maximum number of payload octets that a Controller supports for transmission of a single Link Layer Data Channel PDU."] pub max_tx_octets: u16, #[doc = "< Maximum number of payload octets that a Controller supports for reception of a single Link Layer Data Channel PDU."] pub max_rx_octets: u16, #[doc = "< Maximum time, in microseconds, that a Controller supports for transmission of a single Link Layer Data Channel PDU."] pub max_tx_time_us: u16, #[doc = "< Maximum time, in microseconds, that a Controller supports for reception of a single Link Layer Data Channel PDU."] pub max_rx_time_us: u16, } #[test] fn bindgen_test_layout_ble_gap_data_length_params_t() { assert_eq!( ::core::mem::size_of::(), 8usize, concat!("Size of: ", stringify!(ble_gap_data_length_params_t)) ); assert_eq!( ::core::mem::align_of::(), 2usize, concat!("Alignment of ", stringify!(ble_gap_data_length_params_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).max_tx_octets as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_data_length_params_t), "::", stringify!(max_tx_octets) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).max_rx_octets as *const _ as usize }, 2usize, concat!( "Offset of field: ", stringify!(ble_gap_data_length_params_t), "::", stringify!(max_rx_octets) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).max_tx_time_us as *const _ as usize }, 4usize, concat!( "Offset of field: ", stringify!(ble_gap_data_length_params_t), "::", stringify!(max_tx_time_us) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).max_rx_time_us as *const _ as usize }, 6usize, concat!( "Offset of field: ", stringify!(ble_gap_data_length_params_t), "::", stringify!(max_rx_time_us) ) ); } #[doc = "@brief Data Length Update Procedure local limitation."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_data_length_limitation_t { #[doc = "< If > 0, the requested TX packet length is too long by this many octets."] pub tx_payload_limited_octets: u16, #[doc = "< If > 0, the requested RX packet length is too long by this many octets."] pub rx_payload_limited_octets: u16, #[doc = "< If > 0, the requested combination of TX and RX packet lengths is too long by this many microseconds."] pub tx_rx_time_limited_us: u16, } #[test] fn bindgen_test_layout_ble_gap_data_length_limitation_t() { assert_eq!( ::core::mem::size_of::(), 6usize, concat!("Size of: ", stringify!(ble_gap_data_length_limitation_t)) ); assert_eq!( ::core::mem::align_of::(), 2usize, concat!( "Alignment of ", stringify!(ble_gap_data_length_limitation_t) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).tx_payload_limited_octets as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_data_length_limitation_t), "::", stringify!(tx_payload_limited_octets) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).rx_payload_limited_octets as *const _ as usize }, 2usize, concat!( "Offset of field: ", stringify!(ble_gap_data_length_limitation_t), "::", stringify!(rx_payload_limited_octets) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).tx_rx_time_limited_us as *const _ as usize }, 4usize, concat!( "Offset of field: ", stringify!(ble_gap_data_length_limitation_t), "::", stringify!(tx_rx_time_limited_us) ) ); } #[doc = "@brief Event structure for @ref BLE_GAP_EVT_AUTH_STATUS."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_evt_auth_status_t { #[doc = "< Authentication status, see @ref BLE_GAP_SEC_STATUS."] pub auth_status: u8, pub _bitfield_1: __BindgenBitfieldUnit<[u8; 1usize], u8>, #[doc = "< Levels supported in Security Mode 1."] pub sm1_levels: ble_gap_sec_levels_t, #[doc = "< Levels supported in Security Mode 2."] pub sm2_levels: ble_gap_sec_levels_t, #[doc = "< Bitmap stating which keys were exchanged (distributed) by the local device. If bonding with LE Secure Connections, the enc bit will be always set."] pub kdist_own: ble_gap_sec_kdist_t, #[doc = "< Bitmap stating which keys were exchanged (distributed) by the remote device. If bonding with LE Secure Connections, the enc bit will never be set."] pub kdist_peer: ble_gap_sec_kdist_t, } #[test] fn bindgen_test_layout_ble_gap_evt_auth_status_t() { assert_eq!( ::core::mem::size_of::(), 6usize, concat!("Size of: ", stringify!(ble_gap_evt_auth_status_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!("Alignment of ", stringify!(ble_gap_evt_auth_status_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).auth_status as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_auth_status_t), "::", stringify!(auth_status) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).sm1_levels as *const _ as usize }, 2usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_auth_status_t), "::", stringify!(sm1_levels) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).sm2_levels as *const _ as usize }, 3usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_auth_status_t), "::", stringify!(sm2_levels) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).kdist_own as *const _ as usize }, 4usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_auth_status_t), "::", stringify!(kdist_own) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).kdist_peer as *const _ as usize }, 5usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_auth_status_t), "::", stringify!(kdist_peer) ) ); } impl ble_gap_evt_auth_status_t { #[inline] pub fn error_src(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(0usize, 2u8) as u8) } } #[inline] pub fn set_error_src(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(0usize, 2u8, val as u64) } } #[inline] pub fn bonded(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(2usize, 1u8) as u8) } } #[inline] pub fn set_bonded(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(2usize, 1u8, val as u64) } } #[inline] pub fn lesc(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(3usize, 1u8) as u8) } } #[inline] pub fn set_lesc(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(3usize, 1u8, val as u64) } } #[inline] pub fn new_bitfield_1( error_src: u8, bonded: u8, lesc: u8, ) -> __BindgenBitfieldUnit<[u8; 1usize], u8> { let mut __bindgen_bitfield_unit: __BindgenBitfieldUnit<[u8; 1usize], u8> = Default::default(); __bindgen_bitfield_unit.set(0usize, 2u8, { let error_src: u8 = unsafe { ::core::mem::transmute(error_src) }; error_src as u64 }); __bindgen_bitfield_unit.set(2usize, 1u8, { let bonded: u8 = unsafe { ::core::mem::transmute(bonded) }; bonded as u64 }); __bindgen_bitfield_unit.set(3usize, 1u8, { let lesc: u8 = unsafe { ::core::mem::transmute(lesc) }; lesc as u64 }); __bindgen_bitfield_unit } } #[doc = "@brief Event structure for @ref BLE_GAP_EVT_CONN_SEC_UPDATE."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_evt_conn_sec_update_t { #[doc = "< Connection security level."] pub conn_sec: ble_gap_conn_sec_t, } #[test] fn bindgen_test_layout_ble_gap_evt_conn_sec_update_t() { assert_eq!( ::core::mem::size_of::(), 2usize, concat!("Size of: ", stringify!(ble_gap_evt_conn_sec_update_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!("Alignment of ", stringify!(ble_gap_evt_conn_sec_update_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).conn_sec as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_conn_sec_update_t), "::", stringify!(conn_sec) ) ); } #[doc = "@brief Event structure for @ref BLE_GAP_EVT_TIMEOUT."] #[repr(C)] #[derive(Copy, Clone)] pub struct ble_gap_evt_timeout_t { #[doc = "< Source of timeout event, see @ref BLE_GAP_TIMEOUT_SOURCES."] pub src: u8, #[doc = "< Event Parameters."] pub params: ble_gap_evt_timeout_t__bindgen_ty_1, } #[repr(C)] #[derive(Copy, Clone)] pub union ble_gap_evt_timeout_t__bindgen_ty_1 { #[doc = "< If source is set to @ref BLE_GAP_TIMEOUT_SRC_SCAN, the released"] #[doc = "scan buffer is contained in this field."] pub adv_report_buffer: ble_data_t, _bindgen_union_align: [u32; 2usize], } #[test] fn bindgen_test_layout_ble_gap_evt_timeout_t__bindgen_ty_1() { assert_eq!( ::core::mem::size_of::(), 8usize, concat!("Size of: ", stringify!(ble_gap_evt_timeout_t__bindgen_ty_1)) ); assert_eq!( ::core::mem::align_of::(), 4usize, concat!( "Alignment of ", stringify!(ble_gap_evt_timeout_t__bindgen_ty_1) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).adv_report_buffer as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_timeout_t__bindgen_ty_1), "::", stringify!(adv_report_buffer) ) ); } #[test] fn bindgen_test_layout_ble_gap_evt_timeout_t() { assert_eq!( ::core::mem::size_of::(), 12usize, concat!("Size of: ", stringify!(ble_gap_evt_timeout_t)) ); assert_eq!( ::core::mem::align_of::(), 4usize, concat!("Alignment of ", stringify!(ble_gap_evt_timeout_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).src as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_timeout_t), "::", stringify!(src) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).params as *const _ as usize }, 4usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_timeout_t), "::", stringify!(params) ) ); } #[doc = "@brief Event structure for @ref BLE_GAP_EVT_RSSI_CHANGED."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_evt_rssi_changed_t { #[doc = "< Received Signal Strength Indication in dBm."] #[doc = "@note ERRATA-153 requires the rssi sample to be compensated based on a temperature measurement."] pub rssi: i8, #[doc = "< Data Channel Index on which the Signal Strength is measured (0-36)."] pub ch_index: u8, } #[test] fn bindgen_test_layout_ble_gap_evt_rssi_changed_t() { assert_eq!( ::core::mem::size_of::(), 2usize, concat!("Size of: ", stringify!(ble_gap_evt_rssi_changed_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!("Alignment of ", stringify!(ble_gap_evt_rssi_changed_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).rssi as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_rssi_changed_t), "::", stringify!(rssi) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).ch_index as *const _ as usize }, 1usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_rssi_changed_t), "::", stringify!(ch_index) ) ); } #[doc = "@brief Event structure for @ref BLE_GAP_EVT_ADV_SET_TERMINATED"] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_evt_adv_set_terminated_t { #[doc = "< Reason for why the advertising set terminated. See"] #[doc = "@ref BLE_GAP_EVT_ADV_SET_TERMINATED_REASON."] pub reason: u8, #[doc = "< Advertising handle in which advertising has ended."] pub adv_handle: u8, #[doc = "< If @ref ble_gap_adv_params_t::max_adv_evts was not set to 0,"] #[doc = "this field indicates the number of completed advertising events."] pub num_completed_adv_events: u8, #[doc = "< Advertising buffers corresponding to the terminated"] #[doc = "advertising set. The advertising buffers provided in"] #[doc = "@ref sd_ble_gap_adv_set_configure are now released."] pub adv_data: ble_gap_adv_data_t, } #[test] fn bindgen_test_layout_ble_gap_evt_adv_set_terminated_t() { assert_eq!( ::core::mem::size_of::(), 20usize, concat!("Size of: ", stringify!(ble_gap_evt_adv_set_terminated_t)) ); assert_eq!( ::core::mem::align_of::(), 4usize, concat!( "Alignment of ", stringify!(ble_gap_evt_adv_set_terminated_t) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).reason as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_adv_set_terminated_t), "::", stringify!(reason) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).adv_handle as *const _ as usize }, 1usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_adv_set_terminated_t), "::", stringify!(adv_handle) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).num_completed_adv_events as *const _ as usize }, 2usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_adv_set_terminated_t), "::", stringify!(num_completed_adv_events) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).adv_data as *const _ as usize }, 4usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_adv_set_terminated_t), "::", stringify!(adv_data) ) ); } #[doc = "@brief Event structure for @ref BLE_GAP_EVT_ADV_REPORT."] #[doc = ""] #[doc = " @note If @ref ble_gap_adv_report_type_t::status is set to @ref BLE_GAP_ADV_DATA_STATUS_INCOMPLETE_MORE_DATA,"] #[doc = " not all fields in the advertising report may be available."] #[doc = ""] #[doc = " @note When ble_gap_adv_report_type_t::status is not set to @ref BLE_GAP_ADV_DATA_STATUS_INCOMPLETE_MORE_DATA,"] #[doc = " scanning will be paused. To continue scanning, call @ref sd_ble_gap_scan_start."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_evt_adv_report_t { #[doc = "< Advertising report type. See @ref ble_gap_adv_report_type_t."] pub type_: ble_gap_adv_report_type_t, #[doc = "< Bluetooth address of the peer device. If the peer_addr is resolved:"] #[doc = "@ref ble_gap_addr_t::addr_id_peer is set to 1 and the address is the"] #[doc = "peer's identity address."] pub peer_addr: ble_gap_addr_t, #[doc = "< Contains the target address of the advertising event if"] #[doc = "@ref ble_gap_adv_report_type_t::directed is set to 1. If the"] #[doc = "SoftDevice was able to resolve the address,"] #[doc = "@ref ble_gap_addr_t::addr_id_peer is set to 1 and the direct_addr"] #[doc = "contains the local identity address. If the target address of the"] #[doc = "advertising event is @ref BLE_GAP_ADDR_TYPE_RANDOM_PRIVATE_RESOLVABLE,"] #[doc = "and the SoftDevice was unable to resolve it, the application may try"] #[doc = "to resolve this address to find out if the advertising event was"] #[doc = "directed to us."] pub direct_addr: ble_gap_addr_t, #[doc = "< Indicates the PHY on which the primary advertising packet was received."] #[doc = "See @ref BLE_GAP_PHYS."] pub primary_phy: u8, #[doc = "< Indicates the PHY on which the secondary advertising packet was received."] #[doc = "See @ref BLE_GAP_PHYS. This field is set to @ref BLE_GAP_PHY_NOT_SET if no packets"] #[doc = "were received on a secondary advertising channel."] pub secondary_phy: u8, #[doc = "< TX Power reported by the advertiser in the last packet header received."] #[doc = "This field is set to @ref BLE_GAP_POWER_LEVEL_INVALID if the"] #[doc = "last received packet did not contain the Tx Power field."] #[doc = "@note TX Power is only included in extended advertising packets."] pub tx_power: i8, #[doc = "< Received Signal Strength Indication in dBm of the last packet received."] #[doc = "@note ERRATA-153 requires the rssi sample to be compensated based on a temperature measurement."] pub rssi: i8, #[doc = "< Channel Index on which the last advertising packet is received (0-39)."] pub ch_index: u8, #[doc = "< Set ID of the received advertising data. Set ID is not present"] #[doc = "if set to @ref BLE_GAP_ADV_REPORT_SET_ID_NOT_AVAILABLE."] pub set_id: u8, pub _bitfield_1: __BindgenBitfieldUnit<[u8; 2usize], u16>, #[doc = "< Received advertising or scan response data. If"] #[doc = "@ref ble_gap_adv_report_type_t::status is not set to"] #[doc = "@ref BLE_GAP_ADV_DATA_STATUS_INCOMPLETE_MORE_DATA, the data buffer provided"] #[doc = "in @ref sd_ble_gap_scan_start is now released."] pub data: ble_data_t, #[doc = "< The offset and PHY of the next advertising packet in this extended advertising"] #[doc = "event. @note This field is only set if @ref ble_gap_adv_report_type_t::status"] #[doc = "is set to @ref BLE_GAP_ADV_DATA_STATUS_INCOMPLETE_MORE_DATA."] pub aux_pointer: ble_gap_aux_pointer_t, } #[test] fn bindgen_test_layout_ble_gap_evt_adv_report_t() { assert_eq!( ::core::mem::size_of::(), 36usize, concat!("Size of: ", stringify!(ble_gap_evt_adv_report_t)) ); assert_eq!( ::core::mem::align_of::(), 4usize, concat!("Alignment of ", stringify!(ble_gap_evt_adv_report_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).type_ as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_adv_report_t), "::", stringify!(type_) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).peer_addr as *const _ as usize }, 2usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_adv_report_t), "::", stringify!(peer_addr) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).direct_addr as *const _ as usize }, 9usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_adv_report_t), "::", stringify!(direct_addr) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).primary_phy as *const _ as usize }, 16usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_adv_report_t), "::", stringify!(primary_phy) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).secondary_phy as *const _ as usize }, 17usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_adv_report_t), "::", stringify!(secondary_phy) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).tx_power as *const _ as usize }, 18usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_adv_report_t), "::", stringify!(tx_power) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).rssi as *const _ as usize }, 19usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_adv_report_t), "::", stringify!(rssi) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).ch_index as *const _ as usize }, 20usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_adv_report_t), "::", stringify!(ch_index) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).set_id as *const _ as usize }, 21usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_adv_report_t), "::", stringify!(set_id) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).data as *const _ as usize }, 24usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_adv_report_t), "::", stringify!(data) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).aux_pointer as *const _ as usize }, 32usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_adv_report_t), "::", stringify!(aux_pointer) ) ); } impl ble_gap_evt_adv_report_t { #[inline] pub fn data_id(&self) -> u16 { unsafe { ::core::mem::transmute(self._bitfield_1.get(0usize, 12u8) as u16) } } #[inline] pub fn set_data_id(&mut self, val: u16) { unsafe { let val: u16 = ::core::mem::transmute(val); self._bitfield_1.set(0usize, 12u8, val as u64) } } #[inline] pub fn new_bitfield_1(data_id: u16) -> __BindgenBitfieldUnit<[u8; 2usize], u16> { let mut __bindgen_bitfield_unit: __BindgenBitfieldUnit<[u8; 2usize], u16> = Default::default(); __bindgen_bitfield_unit.set(0usize, 12u8, { let data_id: u16 = unsafe { ::core::mem::transmute(data_id) }; data_id as u64 }); __bindgen_bitfield_unit } } #[doc = "@brief Event structure for @ref BLE_GAP_EVT_SEC_REQUEST."] #[repr(C, packed)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_evt_sec_request_t { pub _bitfield_1: __BindgenBitfieldUnit<[u8; 1usize], u8>, } #[test] fn bindgen_test_layout_ble_gap_evt_sec_request_t() { assert_eq!( ::core::mem::size_of::(), 1usize, concat!("Size of: ", stringify!(ble_gap_evt_sec_request_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!("Alignment of ", stringify!(ble_gap_evt_sec_request_t)) ); } impl ble_gap_evt_sec_request_t { #[inline] pub fn bond(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(0usize, 1u8) as u8) } } #[inline] pub fn set_bond(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(0usize, 1u8, val as u64) } } #[inline] pub fn mitm(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(1usize, 1u8) as u8) } } #[inline] pub fn set_mitm(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(1usize, 1u8, val as u64) } } #[inline] pub fn lesc(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(2usize, 1u8) as u8) } } #[inline] pub fn set_lesc(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(2usize, 1u8, val as u64) } } #[inline] pub fn keypress(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(3usize, 1u8) as u8) } } #[inline] pub fn set_keypress(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(3usize, 1u8, val as u64) } } #[inline] pub fn new_bitfield_1( bond: u8, mitm: u8, lesc: u8, keypress: u8, ) -> __BindgenBitfieldUnit<[u8; 1usize], u8> { let mut __bindgen_bitfield_unit: __BindgenBitfieldUnit<[u8; 1usize], u8> = Default::default(); __bindgen_bitfield_unit.set(0usize, 1u8, { let bond: u8 = unsafe { ::core::mem::transmute(bond) }; bond as u64 }); __bindgen_bitfield_unit.set(1usize, 1u8, { let mitm: u8 = unsafe { ::core::mem::transmute(mitm) }; mitm as u64 }); __bindgen_bitfield_unit.set(2usize, 1u8, { let lesc: u8 = unsafe { ::core::mem::transmute(lesc) }; lesc as u64 }); __bindgen_bitfield_unit.set(3usize, 1u8, { let keypress: u8 = unsafe { ::core::mem::transmute(keypress) }; keypress as u64 }); __bindgen_bitfield_unit } } #[doc = "@brief Event structure for @ref BLE_GAP_EVT_CONN_PARAM_UPDATE_REQUEST."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_evt_conn_param_update_request_t { #[doc = "< GAP Connection Parameters."] pub conn_params: ble_gap_conn_params_t, } #[test] fn bindgen_test_layout_ble_gap_evt_conn_param_update_request_t() { assert_eq!( ::core::mem::size_of::(), 8usize, concat!( "Size of: ", stringify!(ble_gap_evt_conn_param_update_request_t) ) ); assert_eq!( ::core::mem::align_of::(), 2usize, concat!( "Alignment of ", stringify!(ble_gap_evt_conn_param_update_request_t) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).conn_params as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_conn_param_update_request_t), "::", stringify!(conn_params) ) ); } #[doc = "@brief Event structure for @ref BLE_GAP_EVT_SCAN_REQ_REPORT."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_evt_scan_req_report_t { #[doc = "< Advertising handle for the advertising set which received the Scan Request"] pub adv_handle: u8, #[doc = "< Received Signal Strength Indication in dBm."] #[doc = "@note ERRATA-153 requires the rssi sample to be compensated based on a temperature measurement."] pub rssi: i8, #[doc = "< Bluetooth address of the peer device. If the peer_addr resolved: @ref ble_gap_addr_t::addr_id_peer is set to 1"] #[doc = "and the address is the device's identity address."] pub peer_addr: ble_gap_addr_t, } #[test] fn bindgen_test_layout_ble_gap_evt_scan_req_report_t() { assert_eq!( ::core::mem::size_of::(), 9usize, concat!("Size of: ", stringify!(ble_gap_evt_scan_req_report_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!("Alignment of ", stringify!(ble_gap_evt_scan_req_report_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).adv_handle as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_scan_req_report_t), "::", stringify!(adv_handle) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).rssi as *const _ as usize }, 1usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_scan_req_report_t), "::", stringify!(rssi) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).peer_addr as *const _ as usize }, 2usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_scan_req_report_t), "::", stringify!(peer_addr) ) ); } #[doc = "@brief Event structure for @ref BLE_GAP_EVT_DATA_LENGTH_UPDATE_REQUEST."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_evt_data_length_update_request_t { #[doc = "< Peer data length parameters."] pub peer_params: ble_gap_data_length_params_t, } #[test] fn bindgen_test_layout_ble_gap_evt_data_length_update_request_t() { assert_eq!( ::core::mem::size_of::(), 8usize, concat!( "Size of: ", stringify!(ble_gap_evt_data_length_update_request_t) ) ); assert_eq!( ::core::mem::align_of::(), 2usize, concat!( "Alignment of ", stringify!(ble_gap_evt_data_length_update_request_t) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).peer_params as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_data_length_update_request_t), "::", stringify!(peer_params) ) ); } #[doc = "@brief Event structure for @ref BLE_GAP_EVT_DATA_LENGTH_UPDATE."] #[doc = ""] #[doc = " @note This event may also be raised after a PHY Update procedure."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_evt_data_length_update_t { #[doc = "< The effective data length parameters."] pub effective_params: ble_gap_data_length_params_t, } #[test] fn bindgen_test_layout_ble_gap_evt_data_length_update_t() { assert_eq!( ::core::mem::size_of::(), 8usize, concat!("Size of: ", stringify!(ble_gap_evt_data_length_update_t)) ); assert_eq!( ::core::mem::align_of::(), 2usize, concat!( "Alignment of ", stringify!(ble_gap_evt_data_length_update_t) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).effective_params as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_data_length_update_t), "::", stringify!(effective_params) ) ); } #[doc = "@brief Event structure for @ref BLE_GAP_EVT_QOS_CHANNEL_SURVEY_REPORT."] #[repr(C)] #[derive(Copy, Clone)] pub struct ble_gap_evt_qos_channel_survey_report_t { #[doc = "< The measured energy on the Bluetooth Low Energy"] #[doc = "channels, in dBm, indexed by Channel Index."] #[doc = "If no measurement is available for the given channel, channel_energy is set to"] #[doc = "@ref BLE_GAP_POWER_LEVEL_INVALID."] pub channel_energy: [i8; 40usize], } #[test] fn bindgen_test_layout_ble_gap_evt_qos_channel_survey_report_t() { assert_eq!( ::core::mem::size_of::(), 40usize, concat!( "Size of: ", stringify!(ble_gap_evt_qos_channel_survey_report_t) ) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!( "Alignment of ", stringify!(ble_gap_evt_qos_channel_survey_report_t) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).channel_energy as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_qos_channel_survey_report_t), "::", stringify!(channel_energy) ) ); } #[doc = "@brief GAP event structure."] #[repr(C)] #[derive(Copy, Clone)] pub struct ble_gap_evt_t { #[doc = "< Connection Handle on which event occurred."] pub conn_handle: u16, #[doc = "< Event Parameters."] pub params: ble_gap_evt_t__bindgen_ty_1, } #[repr(C)] #[derive(Copy, Clone)] pub union ble_gap_evt_t__bindgen_ty_1 { #[doc = "< Connected Event Parameters."] pub connected: ble_gap_evt_connected_t, #[doc = "< Disconnected Event Parameters."] pub disconnected: ble_gap_evt_disconnected_t, #[doc = "< Connection Parameter Update Parameters."] pub conn_param_update: ble_gap_evt_conn_param_update_t, #[doc = "< Security Parameters Request Event Parameters."] pub sec_params_request: ble_gap_evt_sec_params_request_t, #[doc = "< Security Information Request Event Parameters."] pub sec_info_request: ble_gap_evt_sec_info_request_t, #[doc = "< Passkey Display Event Parameters."] pub passkey_display: ble_gap_evt_passkey_display_t, #[doc = "< Key Pressed Event Parameters."] pub key_pressed: ble_gap_evt_key_pressed_t, #[doc = "< Authentication Key Request Event Parameters."] pub auth_key_request: ble_gap_evt_auth_key_request_t, #[doc = "< LE Secure Connections DHKey calculation request."] pub lesc_dhkey_request: ble_gap_evt_lesc_dhkey_request_t, #[doc = "< Authentication Status Event Parameters."] pub auth_status: ble_gap_evt_auth_status_t, #[doc = "< Connection Security Update Event Parameters."] pub conn_sec_update: ble_gap_evt_conn_sec_update_t, #[doc = "< Timeout Event Parameters."] pub timeout: ble_gap_evt_timeout_t, #[doc = "< RSSI Event Parameters."] pub rssi_changed: ble_gap_evt_rssi_changed_t, #[doc = "< Advertising Report Event Parameters."] pub adv_report: ble_gap_evt_adv_report_t, #[doc = "< Advertising Set Terminated Event Parameters."] pub adv_set_terminated: ble_gap_evt_adv_set_terminated_t, #[doc = "< Security Request Event Parameters."] pub sec_request: ble_gap_evt_sec_request_t, #[doc = "< Connection Parameter Update Parameters."] pub conn_param_update_request: ble_gap_evt_conn_param_update_request_t, #[doc = "< Scan Request Report Parameters."] pub scan_req_report: ble_gap_evt_scan_req_report_t, #[doc = "< PHY Update Request Event Parameters."] pub phy_update_request: ble_gap_evt_phy_update_request_t, #[doc = "< PHY Update Parameters."] pub phy_update: ble_gap_evt_phy_update_t, #[doc = "< Data Length Update Request Event Parameters."] pub data_length_update_request: ble_gap_evt_data_length_update_request_t, #[doc = "< Data Length Update Event Parameters."] pub data_length_update: ble_gap_evt_data_length_update_t, #[doc = "< Quality of Service (QoS) Channel Survey Report Parameters."] pub qos_channel_survey_report: ble_gap_evt_qos_channel_survey_report_t, _bindgen_union_align: [u32; 10usize], } #[test] fn bindgen_test_layout_ble_gap_evt_t__bindgen_ty_1() { assert_eq!( ::core::mem::size_of::(), 40usize, concat!("Size of: ", stringify!(ble_gap_evt_t__bindgen_ty_1)) ); assert_eq!( ::core::mem::align_of::(), 4usize, concat!("Alignment of ", stringify!(ble_gap_evt_t__bindgen_ty_1)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).connected as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_t__bindgen_ty_1), "::", stringify!(connected) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).disconnected as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_t__bindgen_ty_1), "::", stringify!(disconnected) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).conn_param_update as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_t__bindgen_ty_1), "::", stringify!(conn_param_update) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).sec_params_request as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_t__bindgen_ty_1), "::", stringify!(sec_params_request) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).sec_info_request as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_t__bindgen_ty_1), "::", stringify!(sec_info_request) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).passkey_display as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_t__bindgen_ty_1), "::", stringify!(passkey_display) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).key_pressed as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_t__bindgen_ty_1), "::", stringify!(key_pressed) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).auth_key_request as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_t__bindgen_ty_1), "::", stringify!(auth_key_request) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).lesc_dhkey_request as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_t__bindgen_ty_1), "::", stringify!(lesc_dhkey_request) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).auth_status as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_t__bindgen_ty_1), "::", stringify!(auth_status) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).conn_sec_update as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_t__bindgen_ty_1), "::", stringify!(conn_sec_update) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).timeout as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_t__bindgen_ty_1), "::", stringify!(timeout) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).rssi_changed as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_t__bindgen_ty_1), "::", stringify!(rssi_changed) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).adv_report as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_t__bindgen_ty_1), "::", stringify!(adv_report) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).adv_set_terminated as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_t__bindgen_ty_1), "::", stringify!(adv_set_terminated) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).sec_request as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_t__bindgen_ty_1), "::", stringify!(sec_request) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).conn_param_update_request as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_t__bindgen_ty_1), "::", stringify!(conn_param_update_request) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).scan_req_report as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_t__bindgen_ty_1), "::", stringify!(scan_req_report) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).phy_update_request as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_t__bindgen_ty_1), "::", stringify!(phy_update_request) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).phy_update as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_t__bindgen_ty_1), "::", stringify!(phy_update) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).data_length_update_request as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_t__bindgen_ty_1), "::", stringify!(data_length_update_request) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).data_length_update as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_t__bindgen_ty_1), "::", stringify!(data_length_update) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).qos_channel_survey_report as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_t__bindgen_ty_1), "::", stringify!(qos_channel_survey_report) ) ); } #[test] fn bindgen_test_layout_ble_gap_evt_t() { assert_eq!( ::core::mem::size_of::(), 44usize, concat!("Size of: ", stringify!(ble_gap_evt_t)) ); assert_eq!( ::core::mem::align_of::(), 4usize, concat!("Alignment of ", stringify!(ble_gap_evt_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).conn_handle as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_t), "::", stringify!(conn_handle) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).params as *const _ as usize }, 4usize, concat!( "Offset of field: ", stringify!(ble_gap_evt_t), "::", stringify!(params) ) ); } #[doc = " @brief BLE GAP connection configuration parameters, set with @ref sd_ble_cfg_set."] #[doc = ""] #[doc = " @retval ::NRF_ERROR_CONN_COUNT The connection count for the connection configurations is zero."] #[doc = " @retval ::NRF_ERROR_INVALID_PARAM One or more of the following is true:"] #[doc = " - The sum of conn_count for all connection configurations combined exceeds UINT8_MAX."] #[doc = " - The event length is smaller than @ref BLE_GAP_EVENT_LENGTH_MIN."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_conn_cfg_t { #[doc = "< The number of concurrent connections the application can create with this configuration."] #[doc = "The default and minimum value is @ref BLE_GAP_CONN_COUNT_DEFAULT."] pub conn_count: u8, #[doc = "< The time set aside for this connection on every connection interval in 1.25 ms units."] #[doc = "The default value is @ref BLE_GAP_EVENT_LENGTH_DEFAULT, the minimum value is @ref BLE_GAP_EVENT_LENGTH_MIN."] #[doc = "The event length and the connection interval are the primary parameters"] #[doc = "for setting the throughput of a connection."] #[doc = "See the SoftDevice Specification for details on throughput."] pub event_length: u16, } #[test] fn bindgen_test_layout_ble_gap_conn_cfg_t() { assert_eq!( ::core::mem::size_of::(), 4usize, concat!("Size of: ", stringify!(ble_gap_conn_cfg_t)) ); assert_eq!( ::core::mem::align_of::(), 2usize, concat!("Alignment of ", stringify!(ble_gap_conn_cfg_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).conn_count as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_conn_cfg_t), "::", stringify!(conn_count) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).event_length as *const _ as usize }, 2usize, concat!( "Offset of field: ", stringify!(ble_gap_conn_cfg_t), "::", stringify!(event_length) ) ); } #[doc = " @brief Configuration of maximum concurrent connections in the different connected roles, set with"] #[doc = " @ref sd_ble_cfg_set."] #[doc = ""] #[doc = " @retval ::NRF_ERROR_CONN_COUNT The sum of periph_role_count and central_role_count is too"] #[doc = " large. The maximum supported sum of concurrent connections is"] #[doc = " @ref BLE_GAP_ROLE_COUNT_COMBINED_MAX."] #[doc = " @retval ::NRF_ERROR_INVALID_PARAM central_sec_count is larger than central_role_count."] #[doc = " @retval ::NRF_ERROR_RESOURCES The adv_set_count is too large. The maximum"] #[doc = " supported advertising handles is"] #[doc = " @ref BLE_GAP_ADV_SET_COUNT_MAX."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_cfg_role_count_t { #[doc = "< Maximum number of advertising sets. Default value is @ref BLE_GAP_ADV_SET_COUNT_DEFAULT."] pub adv_set_count: u8, #[doc = "< Maximum number of connections concurrently acting as a peripheral. Default value is @ref BLE_GAP_ROLE_COUNT_PERIPH_DEFAULT."] pub periph_role_count: u8, #[doc = "< Maximum number of connections concurrently acting as a central. Default value is @ref BLE_GAP_ROLE_COUNT_CENTRAL_DEFAULT."] pub central_role_count: u8, #[doc = "< Number of SMP instances shared between all connections acting as a central. Default value is @ref BLE_GAP_ROLE_COUNT_CENTRAL_SEC_DEFAULT."] pub central_sec_count: u8, pub _bitfield_1: __BindgenBitfieldUnit<[u8; 1usize], u8>, } #[test] fn bindgen_test_layout_ble_gap_cfg_role_count_t() { assert_eq!( ::core::mem::size_of::(), 5usize, concat!("Size of: ", stringify!(ble_gap_cfg_role_count_t)) ); assert_eq!( ::core::mem::align_of::(), 1usize, concat!("Alignment of ", stringify!(ble_gap_cfg_role_count_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).adv_set_count as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_cfg_role_count_t), "::", stringify!(adv_set_count) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).periph_role_count as *const _ as usize }, 1usize, concat!( "Offset of field: ", stringify!(ble_gap_cfg_role_count_t), "::", stringify!(periph_role_count) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).central_role_count as *const _ as usize }, 2usize, concat!( "Offset of field: ", stringify!(ble_gap_cfg_role_count_t), "::", stringify!(central_role_count) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).central_sec_count as *const _ as usize }, 3usize, concat!( "Offset of field: ", stringify!(ble_gap_cfg_role_count_t), "::", stringify!(central_sec_count) ) ); } impl ble_gap_cfg_role_count_t { #[inline] pub fn qos_channel_survey_role_available(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(0usize, 1u8) as u8) } } #[inline] pub fn set_qos_channel_survey_role_available(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(0usize, 1u8, val as u64) } } #[inline] pub fn new_bitfield_1( qos_channel_survey_role_available: u8, ) -> __BindgenBitfieldUnit<[u8; 1usize], u8> { let mut __bindgen_bitfield_unit: __BindgenBitfieldUnit<[u8; 1usize], u8> = Default::default(); __bindgen_bitfield_unit.set(0usize, 1u8, { let qos_channel_survey_role_available: u8 = unsafe { ::core::mem::transmute(qos_channel_survey_role_available) }; qos_channel_survey_role_available as u64 }); __bindgen_bitfield_unit } } #[doc = " @brief Device name and its properties, set with @ref sd_ble_cfg_set."] #[doc = ""] #[doc = " @note If the device name is not configured, the default device name will be"] #[doc = " @ref BLE_GAP_DEVNAME_DEFAULT, the maximum device name length will be"] #[doc = " @ref BLE_GAP_DEVNAME_DEFAULT_LEN, vloc will be set to @ref BLE_GATTS_VLOC_STACK and the device name"] #[doc = " will have no write access."] #[doc = ""] #[doc = " @note If @ref max_len is more than @ref BLE_GAP_DEVNAME_DEFAULT_LEN and vloc is set to @ref BLE_GATTS_VLOC_STACK,"] #[doc = " the attribute table size must be increased to have room for the longer device name (see"] #[doc = " @ref sd_ble_cfg_set and @ref ble_gatts_cfg_attr_tab_size_t)."] #[doc = ""] #[doc = " @note If vloc is @ref BLE_GATTS_VLOC_STACK :"] #[doc = " - p_value must point to non-volatile memory (flash) or be NULL."] #[doc = " - If p_value is NULL, the device name will initially be empty."] #[doc = ""] #[doc = " @note If vloc is @ref BLE_GATTS_VLOC_USER :"] #[doc = " - p_value cannot be NULL."] #[doc = " - If the device name is writable, p_value must point to volatile memory (RAM)."] #[doc = ""] #[doc = " @retval ::NRF_ERROR_INVALID_PARAM One or more of the following is true:"] #[doc = " - Invalid device name location (vloc)."] #[doc = " - Invalid device name security mode."] #[doc = " @retval ::NRF_ERROR_INVALID_LENGTH One or more of the following is true:"] #[doc = " - The device name length is invalid (must be between 0 and @ref BLE_GAP_DEVNAME_MAX_LEN)."] #[doc = " - The device name length is too long for the given Attribute Table."] #[doc = " @retval ::NRF_ERROR_NOT_SUPPORTED Device name security mode is not supported."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_cfg_device_name_t { #[doc = "< Write permissions."] pub write_perm: ble_gap_conn_sec_mode_t, pub _bitfield_1: __BindgenBitfieldUnit<[u8; 1usize], u8>, #[doc = "< Pointer to where the value (device name) is stored or will be stored."] pub p_value: *mut u8, #[doc = "< Current length in bytes of the memory pointed to by p_value."] pub current_len: u16, #[doc = "< Maximum length in bytes of the memory pointed to by p_value."] pub max_len: u16, } #[test] fn bindgen_test_layout_ble_gap_cfg_device_name_t() { assert_eq!( ::core::mem::size_of::(), 12usize, concat!("Size of: ", stringify!(ble_gap_cfg_device_name_t)) ); assert_eq!( ::core::mem::align_of::(), 4usize, concat!("Alignment of ", stringify!(ble_gap_cfg_device_name_t)) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).write_perm as *const _ as usize }, 0usize, concat!( "Offset of field: ", stringify!(ble_gap_cfg_device_name_t), "::", stringify!(write_perm) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).p_value as *const _ as usize }, 4usize, concat!( "Offset of field: ", stringify!(ble_gap_cfg_device_name_t), "::", stringify!(p_value) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).current_len as *const _ as usize }, 8usize, concat!( "Offset of field: ", stringify!(ble_gap_cfg_device_name_t), "::", stringify!(current_len) ) ); assert_eq!( unsafe { &(*(::core::ptr::null::())).max_len as *const _ as usize }, 10usize, concat!( "Offset of field: ", stringify!(ble_gap_cfg_device_name_t), "::", stringify!(max_len) ) ); } impl ble_gap_cfg_device_name_t { #[inline] pub fn vloc(&self) -> u8 { unsafe { ::core::mem::transmute(self._bitfield_1.get(0usize, 2u8) as u8) } } #[inline] pub fn set_vloc(&mut self, val: u8) { unsafe { let val: u8 = ::core::mem::transmute(val); self._bitfield_1.set(0usize, 2u8, val as u64) } } #[inline] pub fn new_bitfield_1(vloc: u8) -> __BindgenBitfieldUnit<[u8; 1usize], u8> { let mut __bindgen_bitfield_unit: __BindgenBitfieldUnit<[u8; 1usize], u8> = Default::default(); __bindgen_bitfield_unit.set(0usize, 2u8, { let vloc: u8 = unsafe { ::core::mem::transmute(vloc) }; vloc as u64 }); __bindgen_bitfield_unit } } #[doc = "@brief Peripheral Preferred Connection Parameters include configuration parameters, set with @ref sd_ble_cfg_set."] #[repr(C)] #[derive(Debug, Copy, Clone)] pub struct ble_gap_cfg_ppcp_incl_cfg_t { #[doc = "< Inclusion configuration of the Peripheral Preferred Connection Parameters characteristic."] #[doc = "See @ref BLE_GAP_CHAR_INCL_CONFIG. Default is @ref BLE_GAP_PPCP_INCL_CONFIG_DEFAULT."] pub include_cfg: u8, } #[test] fn bindgen_test_layout_ble_gap_cfg_ppcp_incl_cfg_t() { assert_eq!( ::core::mem::size_of::