//***************************************************************************** // // am_hal_ios.h //! @file //! //! @brief Functions for interfacing with the IO Slave module //! //! @addtogroup ios3p IO Slave (SPI/I2C) //! @ingroup apollo3phal //! @{ // //***************************************************************************** //***************************************************************************** // // Copyright (c) 2020, Ambiq Micro // 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 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 the copyright holder nor the names of its // contributors may be used to endorse or promote products derived from this // software without specific prior written permission. // // Third party software included in this distribution is subject to the // additional license terms as defined in the /docs/licenses directory. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" // AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE // IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE // ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER 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. // // This is part of revision 2.4.2 of the AmbiqSuite Development Package. // //***************************************************************************** #ifndef AM_HAL_IOS_H #define AM_HAL_IOS_H #ifdef __cplusplus extern "C" { #endif //***************************************************************************** // // CMSIS-style macro for handling a variable IOS module number. // #define IOSLAVEn(n) ((IOSLAVE_Type*)(IOSLAVE_BASE + (n * (IOSLAVE_BASE - IOSLAVE_BASE)))) //***************************************************************************** //***************************************************************************** // //! @name Interface Configuration //! @brief Macro definitions for configuring the physical interface of the IO //! Slave //! //! These macros may be used with the am_hal_ios_config_t structure to set the //! physical parameters of the SPI/I2C slave module. //! //! @{ // //***************************************************************************** #define AM_HAL_IOS_USE_SPI _VAL2FLD(IOSLAVE_CFG_IFCSEL, IOSLAVE_CFG_IFCSEL_SPI) #define AM_HAL_IOS_SPIMODE_0 _VAL2FLD(IOSLAVE_CFG_SPOL, IOSLAVE_CFG_SPOL_SPI_MODES_0_3) #define AM_HAL_IOS_SPIMODE_1 _VAL2FLD(IOSLAVE_CFG_SPOL, IOSLAVE_CFG_SPOL_SPI_MODES_1_2) #define AM_HAL_IOS_SPIMODE_2 _VAL2FLD(IOSLAVE_CFG_SPOL, IOSLAVE_CFG_SPOL_SPI_MODES_1_2) #define AM_HAL_IOS_SPIMODE_3 _VAL2FLD(IOSLAVE_CFG_SPOL, IOSLAVE_CFG_SPOL_SPI_MODES_0_3) #define AM_HAL_IOS_USE_I2C _VAL2FLD(IOSLAVE_CFG_IFCSEL, IOSLAVE_CFG_IFCSEL_I2C) #define AM_HAL_IOS_I2C_ADDRESS(n) _VAL2FLD(IOSLAVE_CFG_I2CADDR, n) #define AM_HAL_IOS_LSB_FIRST _VAL2FLD(IOSLAVE_CFG_LSB, 1) //! @} //***************************************************************************** // //! @name Register Access Interrupts //! @brief Macro definitions for register access interrupts. //! //! These macros may be used with any of the //! //! @{ // //***************************************************************************** #define AM_HAL_IOS_ACCESS_INT_00 _VAL2FLD(IOSLAVE_REGACCINTEN_REGACC, (uint32_t)1 << 31) #define AM_HAL_IOS_ACCESS_INT_01 _VAL2FLD(IOSLAVE_REGACCINTEN_REGACC, (uint32_t)1 << 30) #define AM_HAL_IOS_ACCESS_INT_02 _VAL2FLD(IOSLAVE_REGACCINTEN_REGACC, (uint32_t)1 << 29) #define AM_HAL_IOS_ACCESS_INT_03 _VAL2FLD(IOSLAVE_REGACCINTEN_REGACC, (uint32_t)1 << 28) #define AM_HAL_IOS_ACCESS_INT_04 _VAL2FLD(IOSLAVE_REGACCINTEN_REGACC, (uint32_t)1 << 27) #define AM_HAL_IOS_ACCESS_INT_05 _VAL2FLD(IOSLAVE_REGACCINTEN_REGACC, (uint32_t)1 << 26) #define AM_HAL_IOS_ACCESS_INT_06 _VAL2FLD(IOSLAVE_REGACCINTEN_REGACC, (uint32_t)1 << 25) #define AM_HAL_IOS_ACCESS_INT_07 _VAL2FLD(IOSLAVE_REGACCINTEN_REGACC, (uint32_t)1 << 24) #define AM_HAL_IOS_ACCESS_INT_08 _VAL2FLD(IOSLAVE_REGACCINTEN_REGACC, (uint32_t)1 << 23) #define AM_HAL_IOS_ACCESS_INT_09 _VAL2FLD(IOSLAVE_REGACCINTEN_REGACC, (uint32_t)1 << 22) #define AM_HAL_IOS_ACCESS_INT_0A _VAL2FLD(IOSLAVE_REGACCINTEN_REGACC, (uint32_t)1 << 21) #define AM_HAL_IOS_ACCESS_INT_0B _VAL2FLD(IOSLAVE_REGACCINTEN_REGACC, (uint32_t)1 << 20) #define AM_HAL_IOS_ACCESS_INT_0C _VAL2FLD(IOSLAVE_REGACCINTEN_REGACC, (uint32_t)1 << 19) #define AM_HAL_IOS_ACCESS_INT_0D _VAL2FLD(IOSLAVE_REGACCINTEN_REGACC, (uint32_t)1 << 18) #define AM_HAL_IOS_ACCESS_INT_0E _VAL2FLD(IOSLAVE_REGACCINTEN_REGACC, (uint32_t)1 << 17) #define AM_HAL_IOS_ACCESS_INT_0F _VAL2FLD(IOSLAVE_REGACCINTEN_REGACC, (uint32_t)1 << 16) #define AM_HAL_IOS_ACCESS_INT_13 _VAL2FLD(IOSLAVE_REGACCINTEN_REGACC, (uint32_t)1 << 15) #define AM_HAL_IOS_ACCESS_INT_17 _VAL2FLD(IOSLAVE_REGACCINTEN_REGACC, (uint32_t)1 << 14) #define AM_HAL_IOS_ACCESS_INT_1B _VAL2FLD(IOSLAVE_REGACCINTEN_REGACC, (uint32_t)1 << 13) #define AM_HAL_IOS_ACCESS_INT_1F _VAL2FLD(IOSLAVE_REGACCINTEN_REGACC, (uint32_t)1 << 12) #define AM_HAL_IOS_ACCESS_INT_23 _VAL2FLD(IOSLAVE_REGACCINTEN_REGACC, (uint32_t)1 << 11) #define AM_HAL_IOS_ACCESS_INT_27 _VAL2FLD(IOSLAVE_REGACCINTEN_REGACC, (uint32_t)1 << 10) #define AM_HAL_IOS_ACCESS_INT_2B _VAL2FLD(IOSLAVE_REGACCINTEN_REGACC, (uint32_t)1 << 9) #define AM_HAL_IOS_ACCESS_INT_2F _VAL2FLD(IOSLAVE_REGACCINTEN_REGACC, (uint32_t)1 << 8) #define AM_HAL_IOS_ACCESS_INT_33 _VAL2FLD(IOSLAVE_REGACCINTEN_REGACC, (uint32_t)1 << 7) #define AM_HAL_IOS_ACCESS_INT_37 _VAL2FLD(IOSLAVE_REGACCINTEN_REGACC, (uint32_t)1 << 6) #define AM_HAL_IOS_ACCESS_INT_3B _VAL2FLD(IOSLAVE_REGACCINTEN_REGACC, (uint32_t)1 << 5) #define AM_HAL_IOS_ACCESS_INT_3F _VAL2FLD(IOSLAVE_REGACCINTEN_REGACC, (uint32_t)1 << 4) #define AM_HAL_IOS_ACCESS_INT_43 _VAL2FLD(IOSLAVE_REGACCINTEN_REGACC, (uint32_t)1 << 3) #define AM_HAL_IOS_ACCESS_INT_47 _VAL2FLD(IOSLAVE_REGACCINTEN_REGACC, (uint32_t)1 << 2) #define AM_HAL_IOS_ACCESS_INT_4B _VAL2FLD(IOSLAVE_REGACCINTEN_REGACC, (uint32_t)1 << 1) #define AM_HAL_IOS_ACCESS_INT_4F _VAL2FLD(IOSLAVE_REGACCINTEN_REGACC, (uint32_t)1 << 0) #define AM_HAL_IOS_ACCESS_INT_ALL 0xFFFFFFFF //! @} //***************************************************************************** // //! @name I/O Slave Interrupts //! @brief Macro definitions for I/O slave (IOS) interrupts. //! //! These macros may be used with any of the //! //! @{ // //***************************************************************************** #define AM_HAL_IOS_INT_FSIZE IOSLAVE_INTEN_FSIZE_Msk #define AM_HAL_IOS_INT_FOVFL IOSLAVE_INTEN_FOVFL_Msk #define AM_HAL_IOS_INT_FUNDFL IOSLAVE_INTEN_FUNDFL_Msk #define AM_HAL_IOS_INT_FRDERR IOSLAVE_INTEN_FRDERR_Msk #define AM_HAL_IOS_INT_GENAD IOSLAVE_INTEN_GENAD_Msk #define AM_HAL_IOS_INT_IOINTW IOSLAVE_INTEN_IOINTW_Msk #define AM_HAL_IOS_INT_XCMPWR IOSLAVE_INTEN_XCMPWR_Msk #define AM_HAL_IOS_INT_XCMPWF IOSLAVE_INTEN_XCMPWF_Msk #define AM_HAL_IOS_INT_XCMPRR IOSLAVE_INTEN_XCMPRR_Msk #define AM_HAL_IOS_INT_XCMPRF IOSLAVE_INTEN_XCMPRF_Msk #define AM_HAL_IOS_INT_ALL 0xFFFFFFFF //! @} //***************************************************************************** // //! @name I/O Slave Interrupts triggers //! @brief Macro definitions for I/O slave (IOS) interrupts. //! //! These macros may be used with am_hal_ios_interrupt_set and am_hal_ios_interrupt_clear //! //! @{ // //***************************************************************************** #define AM_HAL_IOS_IOINTCTL_INT0 (0x01) #define AM_HAL_IOS_IOINTCTL_INT1 (0x02) #define AM_HAL_IOS_IOINTCTL_INT2 (0x04) #define AM_HAL_IOS_IOINTCTL_INT3 (0x08) #define AM_HAL_IOS_IOINTCTL_INT4 (0x10) #define AM_HAL_IOS_IOINTCTL_INT5 (0x20) //! @} //***************************************************************************** // // External variable definitions // //***************************************************************************** //***************************************************************************** // //! @brief LRAM pointer //! //! Pointer to the base of the IO Slave LRAM. // //***************************************************************************** extern volatile uint8_t * const am_hal_ios_pui8LRAM; //***************************************************************************** // //! @brief Configuration structure for the IO slave module. //! //! This structure may be used along with the am_hal_ios_config() function to //! select key parameters of the IO Slave module. See the descriptions of each //! parameter within this structure for more information on what they control. // //***************************************************************************** typedef struct { // //! Interface Selection //! //! This word selects the physical behavior of the IO Slave port. For SPI //! mode, this word should be the logical OR of one or more of the //! following: //! //! AM_HAL_IOS_USE_SPI //! AM_HAL_IOS_SPIMODE_0 //! AM_HAL_IOS_SPIMODE_1 //! AM_HAL_IOS_SPIMODE_2 //! AM_HAL_IOS_SPIMODE_3 //! //! For I2C mode, use the logical OR of one or more of these values instead //! (where n is the 7 or 10-bit I2C address to use): //! //! AM_HAL_IOS_USE_I2C //! AM_HAL_IOS_I2C_ADDRESS(n) //! //! Also, in any mode, you may OR in this value to reverse the order of //! incoming data bits. //! //! AM_HAL_IOS_LSB_FIRST // uint32_t ui32InterfaceSelect; // //! Read-Only section //! //! The IO Slave LRAM is split into three main sections. The first section //! is a "Direct Write" section, which may be accessed for reads or write //! either directly through the Apollo CPU, or over the SPI/I2C bus. The //! "Direct Write" section always begins at LRAM offset 0x0. At the end of //! the normal "Direct Write" space, there is a "Read Only" space, which is //! read/write accessible to the Apollo CPU, but read-only over the I2C/SPI //! Bus. This word selects the base address of this "Read Only" space. //! //! This value may be set to any multiple of 8 between 0x0 and 0x78, //! inclusive. For the configuration to be valid, \e ui32ROBase must also //! be less than or equal to \e ui32FIFOBase //! //! @note The address given here is in units of BYTES. Since the location //! of the "Read Only" space may only be set in 8-byte increments, this //! value must be a multiple of 8. //! //! For the avoidance of doubt this means 0x80 is 128 bytes. These functions //! will shift right by 8 internally. // uint32_t ui32ROBase; // //! FIFO section //! //! After the "Direct Access" and "Read Only" sections is a section of LRAM //! allocated to a FIFO. This section is accessible by the Apollo CPU //! through the FIFO control registers, and accessible on the SPI/I2C bus //! through the 0x7F address. This word selects the base address of the //! FIFO space. The FIFO will extend from the address specified here to the //! address specified in \e ui32RAMBase. //! //! This value may be set to any multiple of 8 between 0x0 and 0x78, //! inclusive. For the configuration to be valid, \e ui32FIFOBase must also //! be greater than or equal to \e ui32ROBase. //! //! @note The address given here is in units of BYTES. Since the location //! of the "FIFO" space may only be set in 8-byte increments, this value //! must be a multiple of 8. //! //! For the avoidance of doubt this means 0x80 is 128 bytes. These functions //! will shift right by 8 internally. // uint32_t ui32FIFOBase; // //! RAM section //! //! At the end of the IOS LRAM, the user may allocate a "RAM" space that //! can only be accessed by the Apollo CPU. This space will not interact //! with the SPI/I2C bus at all, and may be used as general-purpose memory. //! Unlike normal SRAM, this section of LRAM will retain its state through //! Deep Sleep, so it may be used as a data retention space for //! ultra-low-power applications. //! //! This value may be set to any multiple of 8 between 0x0 and 0x100, //! inclusive. For the configuration to be valid, \e ui32RAMBase must also //! be greater than or equal to \e ui32FIFOBase. //! //! @note The address given here is in units of BYTES. Since the location //! of the "FIFO" space may only be set in 8-byte increments, this value //! must be a multiple of 8. //! //! For the avoidance of doubt this means 0x80 is 128 bytes. These functions //! will shift right by 8 internally. // uint32_t ui32RAMBase; // //! FIFO threshold //! //! The IO Slave module will trigger an interrupt when the number of //! entries in the FIFO drops below this number of bytes. // uint32_t ui32FIFOThreshold; // // Pointer to an SRAM // uint8_t *pui8SRAMBuffer; uint32_t ui32SRAMBufferCap; } am_hal_ios_config_t; typedef enum { // Request with arg AM_HAL_IOS_REQ_HOST_INTSET = 0, AM_HAL_IOS_REQ_HOST_INTCLR, AM_HAL_IOS_REQ_HOST_INTGET, AM_HAL_IOS_REQ_HOST_INTEN_GET, AM_HAL_IOS_REQ_READ_GADATA, AM_HAL_IOS_REQ_ARG_MAX, // Request without arg AM_HAL_IOS_REQ_READ_POLL = AM_HAL_IOS_REQ_ARG_MAX, AM_HAL_IOS_REQ_FIFO_UPDATE_CTR, AM_HAL_IOS_REQ_FIFO_BUF_CLR, AM_HAL_IOS_REQ_MAX } am_hal_ios_request_e; typedef struct { uint8_t *pui8Data; volatile uint32_t ui32WriteIndex; volatile uint32_t ui32ReadIndex; volatile uint32_t ui32Length; uint32_t ui32Capacity; }am_hal_ios_buffer_t; //***************************************************************************** // // External function definitions // //***************************************************************************** extern uint32_t am_hal_ios_uninitialize(void *pHandle); extern uint32_t am_hal_ios_initialize(uint32_t ui32Module, void **ppHandle); extern uint32_t am_hal_ios_enable(void *pHandle); extern uint32_t am_hal_ios_disable(void *pHandle); // the following interrupts go back to the NVIC extern uint32_t am_hal_ios_configure(void *pHandle, am_hal_ios_config_t *psConfig); extern uint32_t am_hal_ios_interrupt_enable(void *pHandle, uint32_t ui32IntMask); extern uint32_t am_hal_ios_interrupt_disable(void *pHandle, uint32_t ui32IntMask); extern uint32_t am_hal_ios_interrupt_clear(void *pHandle, uint32_t ui32IntMask); extern uint32_t am_hal_ios_interrupt_status_get(void *pHandle, bool bEnabledOnly, uint32_t *pui32IntStatus); extern uint32_t am_hal_ios_interrupt_service(void *pHandle, uint32_t ui32IntMask); // Returns the number of bytes actually written extern uint32_t am_hal_ios_fifo_write(void *pHandle, uint8_t *pui8Data, uint32_t ui32NumBytes, uint32_t *pui32WrittenBytes); extern uint32_t am_hal_ios_fifo_space_used(void *pHandle, uint32_t *pui32UsedSpace); extern uint32_t am_hal_ios_fifo_space_left(void *pHandle, uint32_t *pui32LeftSpace); extern uint32_t am_hal_ios_power_ctrl(void *pHandle, am_hal_sysctrl_power_state_e ePowerState, bool bRetainState); extern uint32_t am_hal_ios_control(void *pHandle, am_hal_ios_request_e eReq, void *pArgs); #ifdef __cplusplus } #endif #endif // AM_HAL_IOS_H //***************************************************************************** // // End Doxygen group. //! @} // //*****************************************************************************