nRF51 SDK - S130 SoftDevice
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Functions

uint32_t sd_mutex_new (nrf_mutex_t *p_mutex)
 Initialize a mutex. More...
 
uint32_t sd_mutex_acquire (nrf_mutex_t *p_mutex)
 Attempt to acquire a mutex. More...
 
uint32_t sd_mutex_release (nrf_mutex_t *p_mutex)
 Release a mutex. More...
 
uint32_t sd_nvic_EnableIRQ (IRQn_Type IRQn)
 Enable External Interrupt. More...
 
uint32_t sd_nvic_DisableIRQ (IRQn_Type IRQn)
 Disable External Interrupt. More...
 
uint32_t sd_nvic_GetPendingIRQ (IRQn_Type IRQn, uint32_t *p_pending_irq)
 Get Pending Interrupt. More...
 
uint32_t sd_nvic_SetPendingIRQ (IRQn_Type IRQn)
 Set Pending Interrupt. More...
 
uint32_t sd_nvic_ClearPendingIRQ (IRQn_Type IRQn)
 Clear Pending Interrupt. More...
 
uint32_t sd_nvic_SetPriority (IRQn_Type IRQn, nrf_app_irq_priority_t priority)
 Set Interrupt Priority. More...
 
uint32_t sd_nvic_GetPriority (IRQn_Type IRQn, nrf_app_irq_priority_t *p_priority)
 Get Interrupt Priority. More...
 
uint32_t sd_nvic_SystemReset (void)
 System Reset. More...
 
uint32_t sd_nvic_critical_region_enter (uint8_t *p_is_nested_critical_region)
 Enters critical region. More...
 
uint32_t sd_nvic_critical_region_exit (uint8_t is_nested_critical_region)
 Exit critical region. More...
 
uint32_t sd_rand_application_pool_capacity_get (uint8_t *p_pool_capacity)
 Query the capacity of the application random pool. More...
 
uint32_t sd_rand_application_bytes_available_get (uint8_t *p_bytes_available)
 Get number of random bytes available to the application. More...
 
uint32_t sd_rand_application_vector_get (uint8_t *p_buff, uint8_t length)
 Get random bytes from the application pool. More...
 
uint32_t sd_power_reset_reason_get (uint32_t *p_reset_reason)
 Gets the reset reason register. More...
 
uint32_t sd_power_reset_reason_clr (uint32_t reset_reason_clr_msk)
 Clears the bits of the reset reason register. More...
 
uint32_t sd_power_mode_set (nrf_power_mode_t power_mode)
 Sets the power mode when in CPU sleep. More...
 
uint32_t sd_power_system_off (void)
 Puts the chip in System OFF mode. More...
 
uint32_t sd_power_pof_enable (uint8_t pof_enable)
 Enables or disables the power-fail comparator. More...
 
uint32_t sd_power_pof_threshold_set (nrf_power_failure_threshold_t threshold)
 Sets the power-fail threshold value. More...
 
uint32_t sd_power_ramon_set (uint32_t ramon)
 Sets bits in the NRF_POWER->RAMON register. More...
 
uint32_t sd_power_ramon_clr (uint32_t ramon)
 Clears bits in the NRF_POWER->RAMON register. More...
 
uint32_t sd_power_ramon_get (uint32_t *p_ramon)
 Get contents of NRF_POWER->RAMON register, indicates power status of ram blocks. More...
 
uint32_t sd_power_gpregret_set (uint32_t gpregret_msk)
 Set bits in the NRF_POWER->GPREGRET register. More...
 
uint32_t sd_power_gpregret_clr (uint32_t gpregret_msk)
 Clear bits in the NRF_POWER->GPREGRET register. More...
 
uint32_t sd_power_gpregret_get (uint32_t *p_gpregret)
 Get contents of the NRF_POWER->GPREGRET register. More...
 
uint32_t sd_power_dcdc_mode_set (nrf_power_dcdc_mode_t dcdc_mode)
 Sets the DCDC mode. More...
 
uint32_t sd_clock_hfclk_request (void)
 Request the high frequency crystal oscillator. More...
 
uint32_t sd_clock_hfclk_release (void)
 Releases the high frequency crystal oscillator. More...
 
uint32_t sd_clock_hfclk_is_running (uint32_t *p_is_running)
 Checks if the high frequency crystal oscillator is running. More...
 
uint32_t sd_app_evt_wait (void)
 Waits for an application event. More...
 
uint32_t sd_ppi_channel_enable_get (uint32_t *p_channel_enable)
 Get PPI channel enable register contents. More...
 
uint32_t sd_ppi_channel_enable_set (uint32_t channel_enable_set_msk)
 Set PPI channel enable register. More...
 
uint32_t sd_ppi_channel_enable_clr (uint32_t channel_enable_clr_msk)
 Clear PPI channel enable register. More...
 
uint32_t sd_ppi_channel_assign (uint8_t channel_num, const volatile void *evt_endpoint, const volatile void *task_endpoint)
 Assign endpoints to a PPI channel. More...
 
uint32_t sd_ppi_group_task_enable (uint8_t group_num)
 Task to enable a channel group. More...
 
uint32_t sd_ppi_group_task_disable (uint8_t group_num)
 Task to disable a channel group. More...
 
uint32_t sd_ppi_group_assign (uint8_t group_num, uint32_t channel_msk)
 Assign PPI channels to a channel group. More...
 
uint32_t sd_ppi_group_get (uint8_t group_num, uint32_t *p_channel_msk)
 Gets the PPI channels of a channel group. More...
 
uint32_t sd_radio_notification_cfg_set (nrf_radio_notification_type_t type, nrf_radio_notification_distance_t distance)
 Configures the Radio Notification signal. More...
 
uint32_t sd_ecb_block_encrypt (nrf_ecb_hal_data_t *p_ecb_data)
 Encrypts a block according to the specified parameters. More...
 
uint32_t sd_evt_get (uint32_t *p_evt_id)
 Gets any pending events generated by the SoC API. More...
 
uint32_t sd_temp_get (int32_t *p_temp)
 Get the temperature measured on the chip. More...
 
uint32_t sd_flash_write (uint32_t *const p_dst, uint32_t const *const p_src, uint32_t size)
 Flash Write. More...
 
uint32_t sd_flash_page_erase (uint32_t page_number)
 Flash Erase page. More...
 
uint32_t sd_flash_protect (uint32_t protenset0, uint32_t protenset1)
 Flash Protection set. More...
 
uint32_t sd_radio_session_open (nrf_radio_signal_callback_t p_radio_signal_callback)
 Opens a session for radio requests. More...
 
uint32_t sd_radio_session_close (void)
 Closes a session for radio requests. More...
 
uint32_t sd_radio_request (nrf_radio_request_t *p_request)
 Requests a radio timeslot. More...
 

Detailed Description

Function Documentation

uint32_t sd_app_evt_wait ( void  )

Waits for an application event.

An application event is either an application interrupt or a pended interrupt when the interrupt is disabled. When the interrupt is enabled it will be taken immediately since this function will wait in thread mode, then the execution will return in the application's main thread. When an interrupt is disabled and gets pended it will return to the application's thread main. The application must ensure that the pended flag is cleared using sd_nvic_ClearPendingIRQ in order to sleep using this function. This is only necessary for disabled interrupts, as the interrupt handler will clear the pending flag automatically for enabled interrupts.

In order to wake up from disabled interrupts, the SEVONPEND flag has to be set in the Cortex-M0 System Control Register (SCR).

See Also
CMSIS_SCB
Note
If an application interrupt has happened since the last time sd_app_evt_wait was called this function will return immediately and not go to sleep. This is to avoid race conditions that can occur when a flag is updated in the interrupt handler and processed in the main loop.
Postcondition
An application interrupt has happened or a interrupt pending flag is set.
Return values
NRF_SUCCESS
uint32_t sd_clock_hfclk_is_running ( uint32_t *  p_is_running)

Checks if the high frequency crystal oscillator is running.

See Also
sd_clock_hfclk_request
sd_clock_hfclk_release
Parameters
[out]p_is_running1 if the external crystal oscillator is running, 0 if not.
Return values
NRF_SUCCESS
uint32_t sd_clock_hfclk_release ( void  )

Releases the high frequency crystal oscillator.

Will stop the high frequency crystal oscillator, this happens immediately.

See Also
sd_clock_hfclk_is_running
sd_clock_hfclk_request
Return values
NRF_SUCCESS
uint32_t sd_clock_hfclk_request ( void  )

Request the high frequency crystal oscillator.

Will start the high frequency crystal oscillator, the startup time of the crystal varies and the sd_clock_hfclk_is_running function can be polled to check if it has started.

See Also
sd_clock_hfclk_is_running
sd_clock_hfclk_release
Return values
NRF_SUCCESS
uint32_t sd_ecb_block_encrypt ( nrf_ecb_hal_data_t p_ecb_data)

Encrypts a block according to the specified parameters.

128-bit AES encryption.

Parameters
[in,out]p_ecb_dataPointer to the ECB parameters' struct (two input parameters and one output parameter).
Return values
NRF_SUCCESS
uint32_t sd_evt_get ( uint32_t *  p_evt_id)

Gets any pending events generated by the SoC API.

The application should keep calling this function to get events, until NRF_ERROR_NOT_FOUND is returned.

Parameters
[out]p_evt_idSet to one of the values in NRF_SOC_EVTS, if any events are pending.
Return values
NRF_SUCCESSAn event was pending. The event id is written in the p_evt_id parameter.
NRF_ERROR_NOT_FOUNDNo pending events.
uint32_t sd_flash_page_erase ( uint32_t  page_number)

Flash Erase page.

Commands to erase a flash page If the SoftDevice is enabled: This call initiates the flash access command, and its completion will be communicated to the application with exactly one of the following events:

If the SoftDevice is not enabled no event will be generated, and this call will return NRF_SUCCESS when the erase has been completed

Note
  • This call takes control over the radio and the CPU during flash erase and write to make sure that they will not interfere with the flash access. This means that all interrupts will be blocked for a predictable time (depending on the NVMC specification in nRF51 Series Reference Manual and the command parameters).
Parameters
[in]page_numberPagenumber of the page to erase
Return values
NRF_ERROR_INTERNALIf a new session could not be opened due to an internal error.
NRF_ERROR_INVALID_ADDRTried to erase to a non existing flash page.
NRF_ERROR_BUSYThe previous command has not yet completed.
NRF_ERROR_FORBIDDENTried to erase a protected page.
NRF_SUCCESSThe command was accepted.
uint32_t sd_flash_protect ( uint32_t  protenset0,
uint32_t  protenset1 
)

Flash Protection set.

Commands to set the flash protection registers PROTENSETx

Note
To read the values in PROTENSETx you can read them directly. They are only write-protected.
Parameters
[in]protenset0Value to be written to PROTENSET0.
[in]protenset1Value to be written to PROTENSET1.
Return values
NRF_ERROR_FORBIDDENTried to protect the SoftDevice.
NRF_SUCCESSValues successfully written to PROTENSETx.
uint32_t sd_flash_write ( uint32_t *const  p_dst,
uint32_t const *const  p_src,
uint32_t  size 
)

Flash Write.

Commands to write a buffer to flash

If the SoftDevice is enabled: This call initiates the flash access command, and its completion will be communicated to the application with exactly one of the following events:

If the SoftDevice is not enabled no event will be generated, and this call will return NRF_SUCCESS when the write has been completed

Note
  • This call takes control over the radio and the CPU during flash erase and write to make sure that they will not interfere with the flash access. This means that all interrupts will be blocked for a predictable time (depending on the NVMC specification in nRF51 Series Reference Manual and the command parameters).
Parameters
[in]p_dstPointer to start of flash location to be written.
[in]p_srcPointer to buffer with data to be written.
[in]sizeNumber of 32-bit words to write. Maximum size is 256 32bit words.
Return values
NRF_ERROR_INVALID_ADDRTried to write to a non existing flash address, or p_dst or p_src was unaligned.
NRF_ERROR_BUSYThe previous command has not yet completed.
NRF_ERROR_INVALID_LENGTHSize was 0, or more than 256 words.
NRF_ERROR_FORBIDDENTried to write to or read from protected location.
NRF_SUCCESSThe command was accepted.
uint32_t sd_mutex_acquire ( nrf_mutex_t p_mutex)

Attempt to acquire a mutex.

Parameters
[in]p_mutexPointer to the mutex to acquire.
Return values
NRF_SUCCESSThe mutex was successfully acquired.
NRF_ERROR_SOC_MUTEX_ALREADY_TAKENThe mutex could not be acquired.
uint32_t sd_mutex_new ( nrf_mutex_t p_mutex)

Initialize a mutex.

Parameters
[in]p_mutexPointer to the mutex to initialize.
Return values
NRF_SUCCESS
uint32_t sd_mutex_release ( nrf_mutex_t p_mutex)

Release a mutex.

Parameters
[in]p_mutexPointer to the mutex to release.
Return values
NRF_SUCCESS
uint32_t sd_nvic_ClearPendingIRQ ( IRQn_Type  IRQn)

Clear Pending Interrupt.

Note
Corresponds to NVIC_ClearPendingIRQ in CMSIS.
Precondition
IRQn is valid and not reserved by the stack.
Parameters
[in]IRQnSee the NVIC_ClearPendingIRQ documentation in CMSIS.
Return values
NRF_SUCCESSThe interrupt pending flag is cleared.
NRF_ERROR_SOC_NVIC_INTERRUPT_NOT_AVAILABLEIRQn is not available for the application.
uint32_t sd_nvic_critical_region_enter ( uint8_t *  p_is_nested_critical_region)

Enters critical region.

Postcondition
Application interrupts will be disabled.
See Also
sd_nvic_critical_region_exit
Parameters
[out]p_is_nested_critical_region1: If in a nested critical region. 0: Otherwise.
Return values
NRF_SUCCESS
uint32_t sd_nvic_critical_region_exit ( uint8_t  is_nested_critical_region)

Exit critical region.

Precondition
Application has entered a critical region using sd_nvic_critical_region_enter.
Postcondition
If not in a nested critical region, the application interrupts will restored to the state before sd_nvic_critical_region_enter was called.
Parameters
[in]is_nested_critical_regionIf this is set to 1, the critical region won't be exited.
See Also
sd_nvic_critical_region_enter.
Return values
NRF_SUCCESS
uint32_t sd_nvic_DisableIRQ ( IRQn_Type  IRQn)

Disable External Interrupt.

Note
Corresponds to NVIC_DisableIRQ in CMSIS.
Precondition
IRQn is valid and not reserved by the stack.
Parameters
[in]IRQnSee the NVIC_DisableIRQ documentation in CMSIS.
Return values
NRF_SUCCESSThe interrupt was disabled.
NRF_ERROR_SOC_NVIC_INTERRUPT_NOT_AVAILABLEThe interrupt is not available for the application.
uint32_t sd_nvic_EnableIRQ ( IRQn_Type  IRQn)

Enable External Interrupt.

Note
Corresponds to NVIC_EnableIRQ in CMSIS.
Precondition
IRQn is valid and not reserved by the stack.
Parameters
[in]IRQnSee the NVIC_EnableIRQ documentation in CMSIS.
Return values
NRF_SUCCESSThe interrupt was enabled.
NRF_ERROR_SOC_NVIC_INTERRUPT_NOT_AVAILABLEThe interrupt is not available for the application.
NRF_ERROR_SOC_NVIC_INTERRUPT_PRIORITY_NOT_ALLOWEDThe interrupt has a priority not available for the application.
uint32_t sd_nvic_GetPendingIRQ ( IRQn_Type  IRQn,
uint32_t *  p_pending_irq 
)

Get Pending Interrupt.

Note
Corresponds to NVIC_GetPendingIRQ in CMSIS.
Precondition
IRQn is valid and not reserved by the stack.
Parameters
[in]IRQnSee the NVIC_GetPendingIRQ documentation in CMSIS.
[out]p_pending_irqReturn value from NVIC_GetPendingIRQ.
Return values
NRF_SUCCESSThe interrupt is available for the application.
NRF_ERROR_SOC_NVIC_INTERRUPT_NOT_AVAILABLEIRQn is not available for the application.
uint32_t sd_nvic_GetPriority ( IRQn_Type  IRQn,
nrf_app_irq_priority_t p_priority 
)

Get Interrupt Priority.

Note
Corresponds to NVIC_GetPriority in CMSIS.
Precondition
IRQn is valid and not reserved by the stack.
Parameters
[in]IRQnSee the NVIC_GetPriority documentation in CMSIS.
[out]p_priorityReturn value from NVIC_GetPriority.
Return values
NRF_SUCCESSThe interrupt priority is returned in p_priority.
NRF_ERROR_SOC_NVIC_INTERRUPT_NOT_AVAILABLE- IRQn is not available for the application.
uint32_t sd_nvic_SetPendingIRQ ( IRQn_Type  IRQn)

Set Pending Interrupt.

Note
Corresponds to NVIC_SetPendingIRQ in CMSIS.
Precondition
IRQn is valid and not reserved by the stack.
Parameters
[in]IRQnSee the NVIC_SetPendingIRQ documentation in CMSIS.
Return values
NRF_SUCCESSThe interrupt is set pending.
NRF_ERROR_SOC_NVIC_INTERRUPT_NOT_AVAILABLEIRQn is not available for the application.
uint32_t sd_nvic_SetPriority ( IRQn_Type  IRQn,
nrf_app_irq_priority_t  priority 
)

Set Interrupt Priority.

Note
Corresponds to NVIC_SetPriority in CMSIS.
Precondition
IRQn is valid and not reserved by the stack.
Priority is valid and not reserved by the stack.
Parameters
[in]IRQnSee the NVIC_SetPriority documentation in CMSIS.
[in]priorityA valid IRQ priority for use by the application.
Return values
NRF_SUCCESSThe interrupt and priority level is available for the application.
NRF_ERROR_SOC_NVIC_INTERRUPT_NOT_AVAILABLEIRQn is not available for the application.
NRF_ERROR_SOC_NVIC_INTERRUPT_PRIORITY_NOT_ALLOWEDThe interrupt priority is not available for the application.
uint32_t sd_nvic_SystemReset ( void  )

System Reset.

Note
Corresponds to NVIC_SystemReset in CMSIS.
Return values
NRF_ERROR_SOC_NVIC_SHOULD_NOT_RETURN
uint32_t sd_power_dcdc_mode_set ( nrf_power_dcdc_mode_t  dcdc_mode)

Sets the DCDC mode.

This function is to enable or disable the DCDC periperhal.

Parameters
[in]dcdc_modeThe mode of the DCDC.
Return values
NRF_SUCCESS
NRF_ERROR_INVALID_PARAMThe DCDC mode is invalid.
uint32_t sd_power_gpregret_clr ( uint32_t  gpregret_msk)

Clear bits in the NRF_POWER->GPREGRET register.

Parameters
[in]gpregret_mskBits to be clear in the GPREGRET register.
Return values
NRF_SUCCESS
uint32_t sd_power_gpregret_get ( uint32_t *  p_gpregret)

Get contents of the NRF_POWER->GPREGRET register.

Parameters
[out]p_gpregretContents of the GPREGRET register.
Return values
NRF_SUCCESS
uint32_t sd_power_gpregret_set ( uint32_t  gpregret_msk)

Set bits in the NRF_POWER->GPREGRET register.

Parameters
[in]gpregret_mskBits to be set in the GPREGRET register.
Return values
NRF_SUCCESS
uint32_t sd_power_mode_set ( nrf_power_mode_t  power_mode)

Sets the power mode when in CPU sleep.

Parameters
[in]power_modeThe power mode to use when in CPU sleep.
See Also
sd_app_evt_wait
Return values
NRF_SUCCESSThe power mode was set.
NRF_ERROR_SOC_POWER_MODE_UNKNOWNThe power mode was unknown.
uint32_t sd_power_pof_enable ( uint8_t  pof_enable)

Enables or disables the power-fail comparator.

Enabling this will give a softdevice event (NRF_EVT_POWER_FAILURE_WARNING) when the power failure warning occurs. The event can be retrieved with sd_evt_get();

Parameters
[in]pof_enableTrue if the power-fail comparator should be enabled, false if it should be disabled.
Return values
NRF_SUCCESS
uint32_t sd_power_pof_threshold_set ( nrf_power_failure_threshold_t  threshold)

Sets the power-fail threshold value.

Parameters
[in]thresholdThe power-fail threshold value to use.
Return values
NRF_SUCCESSThe power failure threshold was set.
NRF_ERROR_SOC_POWER_POF_THRESHOLD_UNKNOWNThe power failure threshold is unknown.
uint32_t sd_power_ramon_clr ( uint32_t  ramon)

Clears bits in the NRF_POWER->RAMON register.

Parameters
ramonContains the bits needed to be cleared in the NRF_POWER->RAMON register.
Return values
NRF_SUCCESS
uint32_t sd_power_ramon_get ( uint32_t *  p_ramon)

Get contents of NRF_POWER->RAMON register, indicates power status of ram blocks.

Parameters
[out]p_ramonContent of NRF_POWER->RAMON register.
Return values
NRF_SUCCESS
uint32_t sd_power_ramon_set ( uint32_t  ramon)

Sets bits in the NRF_POWER->RAMON register.

Parameters
[in]ramonContains the bits needed to be set in the NRF_POWER->RAMON register.
Return values
NRF_SUCCESS
uint32_t sd_power_reset_reason_clr ( uint32_t  reset_reason_clr_msk)

Clears the bits of the reset reason register.

Parameters
[in]reset_reason_clr_mskContains the bits to clear from the reset reason register.
Return values
NRF_SUCCESS
uint32_t sd_power_reset_reason_get ( uint32_t *  p_reset_reason)

Gets the reset reason register.

Parameters
[out]p_reset_reasonContents of the NRF_POWER->RESETREAS register.
Return values
NRF_SUCCESS
uint32_t sd_power_system_off ( void  )

Puts the chip in System OFF mode.

Return values
NRF_ERROR_SOC_POWER_OFF_SHOULD_NOT_RETURN
uint32_t sd_ppi_channel_assign ( uint8_t  channel_num,
const volatile void *  evt_endpoint,
const volatile void *  task_endpoint 
)

Assign endpoints to a PPI channel.

Parameters
[in]channel_numNumber of the PPI channel to assign.
[in]evt_endpointEvent endpoint of the PPI channel.
[in]task_endpointTask endpoint of the PPI channel.
Return values
NRF_ERROR_SOC_PPI_INVALID_CHANNELThe channel number is invalid.
NRF_SUCCESS
uint32_t sd_ppi_channel_enable_clr ( uint32_t  channel_enable_clr_msk)

Clear PPI channel enable register.

Parameters
[in]channel_enable_clr_mskMask containing the bits to clear in the PPI CHEN register.
Return values
NRF_SUCCESS
uint32_t sd_ppi_channel_enable_get ( uint32_t *  p_channel_enable)

Get PPI channel enable register contents.

Parameters
[out]p_channel_enableThe contents of the PPI CHEN register.
Return values
NRF_SUCCESS
uint32_t sd_ppi_channel_enable_set ( uint32_t  channel_enable_set_msk)

Set PPI channel enable register.

Parameters
[in]channel_enable_set_mskMask containing the bits to set in the PPI CHEN register.
Return values
NRF_SUCCESS
uint32_t sd_ppi_group_assign ( uint8_t  group_num,
uint32_t  channel_msk 
)

Assign PPI channels to a channel group.

Parameters
[in]group_numNumber of the channel group.
[in]channel_mskMask of the channels to assign to the group.
Return values
NRF_ERROR_SOC_PPI_INVALID_GROUPThe group number is invalid.
NRF_SUCCESS
uint32_t sd_ppi_group_get ( uint8_t  group_num,
uint32_t *  p_channel_msk 
)

Gets the PPI channels of a channel group.

Parameters
[in]group_numNumber of the channel group.
[out]p_channel_mskMask of the channels assigned to the group.
Return values
NRF_ERROR_SOC_PPI_INVALID_GROUPThe group number is invalid.
NRF_SUCCESS
uint32_t sd_ppi_group_task_disable ( uint8_t  group_num)

Task to disable a channel group.

Parameters
[in]group_numNumber of the PPI group.
Return values
NRF_ERROR_SOC_PPI_INVALID_GROUPThe group number is invalid.
NRF_SUCCESS
uint32_t sd_ppi_group_task_enable ( uint8_t  group_num)

Task to enable a channel group.

Parameters
[in]group_numNumber of the channel group.
Return values
NRF_ERROR_SOC_PPI_INVALID_GROUPThe group number is invalid
NRF_SUCCESS
uint32_t sd_radio_notification_cfg_set ( nrf_radio_notification_type_t  type,
nrf_radio_notification_distance_t  distance 
)

Configures the Radio Notification signal.

Note
  • The notification signal latency depends on the interrupt priority settings of SWI used for notification signal.
  • To ensure that the radio notification signal behaves in a consistent way, always configure radio notifications when there is no protocol stack or other SoftDevice activity in progress. It is recommended that the radio notification signal is configured directly after the SoftDevice has been enabled.
  • In the period between the ACTIVE signal and the start of the Radio Event, the SoftDevice will interrupt the application to do Radio Event preparation.
  • Using the Radio Notification feature may limit the bandwidth, as the SoftDevice may have to shorten the connection events to have time for the Radio Notification signals.
Parameters
[in]typeType of notification signal. NRF_RADIO_NOTIFICATION_TYPE_NONE shall be used to turn off radio notification. Using NRF_RADIO_NOTIFICATION_DISTANCE_NONE is recommended (but not required) to be used with NRF_RADIO_NOTIFICATION_TYPE_NONE.
[in]distanceDistance between the notification signal and start of radio activity. This parameter is ignored when NRF_RADIO_NOTIFICATION_TYPE_NONE or NRF_RADIO_NOTIFICATION_TYPE_INT_ON_INACTIVE is used.
Return values
NRF_ERROR_INVALID_PARAMThe group number is invalid.
NRF_SUCCESS
uint32_t sd_radio_request ( nrf_radio_request_t p_request)

Requests a radio timeslot.

Note
The request type is determined by p_request->request_type, and can be one of NRF_RADIO_REQ_TYPE_EARLIEST and NRF_RADIO_REQ_TYPE_NORMAL. The first request in a session must always be of type NRF_RADIO_REQ_TYPE_EARLIEST.
For a normal request (NRF_RADIO_REQ_TYPE_NORMAL), the start time of a radio timeslot is specified by p_request->distance_us and is given relative to the start of the previous timeslot.
A too small p_request->distance_us will lead to a NRF_EVT_RADIO_BLOCKED event.
Timeslots scheduled too close will lead to a NRF_EVT_RADIO_BLOCKED event.
See the SoftDevice Specification for more on radio timeslot scheduling, distances and lengths.
If an opportunity for the first radio timeslot is not found before 100ms after the call to this function, it is not scheduled, and instead a NRF_EVT_RADIO_BLOCKED event is sent. The application may then try to schedule the first radio timeslot again.
Successful requests will result in nrf_radio_signal_callback_t(NRF_RADIO_CALLBACK_SIGNAL_TYPE_START). Unsuccessful requests will result in a NRF_EVT_RADIO_BLOCKED event, see NRF_SOC_EVTS.
The jitter in the start time of the radio timeslots is +/- NRF_RADIO_START_JITTER_US us.
The nrf_radio_signal_callback_t(NRF_RADIO_CALLBACK_SIGNAL_TYPE_START) call has a latency relative to the specified radio timeslot start, but this does not affect the actual start time of the timeslot.
NRF_TIMER0 is reset at the start of the radio timeslot, and is clocked at 1MHz from the high frequency (16 MHz) clock source. If p_request->hfclk_force_xtal is true, the high frequency clock is guaranteed to be clocked from the external crystal.
The SoftDevice will neither access the NRF_RADIO peripheral nor the NRF_TIMER0 peripheral during the radio timeslot.
Parameters
[in]p_requestPointer to the request parameters.
Return values
NRF_ERROR_FORBIDDENIf session not opened or the session is not IDLE.
NRF_ERROR_INVALID_ADDRIf the p_request pointer is invalid.
NRF_ERROR_INVALID_PARAMIf the parameters of p_request are not valid.
NRF_SUCCESSOtherwise.
uint32_t sd_radio_session_close ( void  )

Closes a session for radio requests.

Note
Any current radio timeslot will be finished before the session is closed.
If a radio timeslot is scheduled when the session is closed, it will be canceled.
The application cannot consider the session closed until the NRF_EVT_RADIO_SESSION_CLOSED event is received.
Return values
NRF_ERROR_FORBIDDENIf session not opened.
NRF_ERROR_BUSYIf session is currently being closed.
NRF_SUCCESSOtherwise.
uint32_t sd_radio_session_open ( nrf_radio_signal_callback_t  p_radio_signal_callback)

Opens a session for radio requests.

Note
Only one session can be open at a time.
p_radio_signal_callback(NRF_RADIO_CALLBACK_SIGNAL_TYPE_START) will be called when the radio timeslot starts. From this point the NRF_RADIO and NRF_TIMER0 peripherals can be freely accessed by the application.
p_radio_signal_callback(NRF_RADIO_CALLBACK_SIGNAL_TYPE_TIMER0) is called whenever the NRF_TIMER0 interrupt occurs.
p_radio_signal_callback(NRF_RADIO_CALLBACK_SIGNAL_TYPE_RADIO) is called whenever the NRF_RADIO interrupt occurs.
p_radio_signal_callback() will be called at ARM interrupt priority level 0. This implies that none of the sd_* API calls can be used from p_radio_signal_callback().
Parameters
[in]p_radio_signal_callbackThe signal callback.
Return values
NRF_ERROR_INVALID_ADDRp_radio_signal_callback is an invalid function pointer.
NRF_ERROR_BUSYIf session cannot be opened.
NRF_ERROR_INTERNALIf a new session could not be opened due to an internal error.
NRF_SUCCESSOtherwise.
uint32_t sd_rand_application_bytes_available_get ( uint8_t *  p_bytes_available)

Get number of random bytes available to the application.

Parameters
[out]p_bytes_availableThe number of bytes currently available in the pool.
Return values
NRF_SUCCESS
uint32_t sd_rand_application_pool_capacity_get ( uint8_t *  p_pool_capacity)

Query the capacity of the application random pool.

Parameters
[out]p_pool_capacityThe capacity of the pool.
Return values
NRF_SUCCESS
uint32_t sd_rand_application_vector_get ( uint8_t *  p_buff,
uint8_t  length 
)

Get random bytes from the application pool.

Parameters
[out]p_buffPointer to unit8_t buffer for storing the bytes.
[in]lengthNumber of bytes to take from pool and place in p_buff.
Return values
NRF_SUCCESSThe requested bytes were written to p_buff.
NRF_ERROR_SOC_RAND_NOT_ENOUGH_VALUESNo bytes were written to the buffer, because there were not enough bytes available.
uint32_t sd_temp_get ( int32_t *  p_temp)

Get the temperature measured on the chip.

This function will block until the temperature measurement is done. It takes around 50us from call to return.

Note
Pan #28 in PAN-028 v 1.6 "Negative measured values are not represented correctly" is corrected by this function.
Parameters
[out]p_tempResult of temperature measurement. Die temperature in 0.25 degrees celsius.
Return values
NRF_SUCCESSA temperature measurement was done, and the temperature was written to temp