//***************************************************************************** // // am_hal_ios.c //! @file //! //! @brief Functions for interfacing with the IO Slave module //! //! @addtogroup ios1 IO Slave (SPI/I2C) //! @ingroup apollo1hal //! @{ // //***************************************************************************** //***************************************************************************** // // 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. // //***************************************************************************** #include #include #include "am_mcu_apollo.h" //***************************************************************************** // // SRAM Buffer structure // //***************************************************************************** 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; am_hal_ios_buffer_t g_sSRAMBuffer; //***************************************************************************** // // Forward declarations of static funcitons. // //***************************************************************************** static void am_hal_ios_buffer_init(am_hal_ios_buffer_t *psBuffer, void *pvArray, uint32_t ui32Bytes); static void fifo_write(uint8_t *pui8Data, uint32_t ui32NumBytes); //***************************************************************************** // // Function-like macros. // //***************************************************************************** #define am_hal_ios_buffer_empty(psBuffer) \ ((psBuffer)->ui32Length == 0) #define am_hal_ios_buffer_full(psBuffer) \ ((psBuffer)->ui32Length == (psBuffer)->ui32Capacity) #define am_hal_ios_buffer_data_left(psBuffer) \ ((psBuffer)->ui32Length) //***************************************************************************** // // Global Variables // //***************************************************************************** volatile uint8_t * const am_hal_ios_pui8LRAM = (uint8_t *)REG_IOSLAVE_BASEADDR; uint8_t *g_pui8FIFOBase = (uint8_t *) REG_IOSLAVE_BASEADDR; uint8_t *g_pui8FIFOEnd = (uint8_t *) REG_IOSLAVE_BASEADDR; uint8_t *g_pui8FIFOPtr = (uint8_t *) REG_IOSLAVE_BASEADDR; uint8_t g_ui32HwFifoSize = 0; uint32_t g_ui32FifoBaseOffset = 0; //***************************************************************************** // //! @brief Enables the IOS module //! //! This function enables the IOSLAVE module using the IFCEN bitfield in the //! IOSLAVE_CFG register. //! //! @return None. // //***************************************************************************** void am_hal_ios_enable(uint32_t ui32Module) { AM_REGn(IOSLAVE, ui32Module, CFG) |= AM_REG_IOSLAVE_CFG_IFCEN(1); } //***************************************************************************** // //! @brief Disables the IOSLAVE module. //! //! This function disables the IOSLAVE module using the IFCEN bitfield in the //! IOSLAVE_CFG register. //! //! @return None. // //***************************************************************************** void am_hal_ios_disable(uint32_t ui32Module) { AM_REGn(IOSLAVE, ui32Module, CFG) &= ~(AM_REG_IOSLAVE_CFG_IFCEN(1)); } //***************************************************************************** // //! @brief Configure the IOS module. //! //! This function reads the an \e am_hal_ios_config_t structure and uses it to //! set up the IO Slave module. Please see the information on the configuration //! structure for more information on the parameters that may be set by this //! function. //! //! @return None. // //***************************************************************************** void am_hal_ios_config(am_hal_ios_config_t *psConfig) { uint32_t ui32LRAMConfig; // // Record the FIFO parameters for later use. // g_pui8FIFOBase = (uint8_t *)(REG_IOSLAVE_BASEADDR + psConfig->ui32FIFOBase); g_pui8FIFOEnd = (uint8_t *)(REG_IOSLAVE_BASEADDR + psConfig->ui32RAMBase); g_ui32HwFifoSize = g_pui8FIFOEnd - g_pui8FIFOBase; g_ui32FifoBaseOffset = psConfig->ui32FIFOBase; // // Calculate the value for the IO Slave FIFO configuration register. // ui32LRAMConfig = AM_REG_IOSLAVE_FIFOCFG_ROBASE(psConfig->ui32ROBase >> 3); ui32LRAMConfig |= AM_REG_IOSLAVE_FIFOCFG_FIFOBASE(psConfig->ui32FIFOBase >> 3); ui32LRAMConfig |= AM_REG_IOSLAVE_FIFOCFG_FIFOMAX(psConfig->ui32RAMBase >> 3); // // Just in case, disable the IOS // am_hal_ios_disable(0); // // Write the configuration register with the user's selected interface // characteristics. // AM_REG(IOSLAVE, CFG) = psConfig->ui32InterfaceSelect; // // Write the FIFO configuration register to set the memory map for the LRAM. // AM_REG(IOSLAVE, FIFOCFG) = ui32LRAMConfig; // // Enable the IOS. The following configuration options can't be set while // the IOS is disabled. // am_hal_ios_enable(0); // // Initialize the FIFO pointer to the beginning of the FIFO section. // am_hal_ios_fifo_ptr_set(psConfig->ui32FIFOBase); // // Write the FIFO threshold register. // AM_REG(IOSLAVE, FIFOTHR) = psConfig->ui32FIFOThreshold; } //***************************************************************************** // //! @brief Set bits in the HOST side IOINTCTL register. //! //! This function may be used to set an interrupt bit to the host. //! //! @return None. // //***************************************************************************** void am_hal_ios_host_int_set(uint32_t ui32Interrupt) { // // Set a bit that will cause an interrupt to the host. // AM_REG(IOSLAVE, IOINTCTL) = AM_REG_IOSLAVE_IOINTCTL_IOINTSET(ui32Interrupt); } //***************************************************************************** // //! @brief Clear bits in the HOST side IOINTCTL register. //! //! This function may be used to clear an interrupt bit to the host. //! //! @return None. // //***************************************************************************** void am_hal_ios_host_int_clear(uint32_t ui32Interrupt) { // // Clear bits that will cause an interrupt to the host. // AM_REG(IOSLAVE, IOINTCTL) = AM_REG_IOSLAVE_IOINTCTL_IOINTCLR(ui32Interrupt); } //***************************************************************************** // //! @brief Get the bits in the HOST side IOINTCTL register. //! //! This function may be used to read the host side interrupt bits. //! //! @return None. // //***************************************************************************** uint32_t am_hal_ios_host_int_get(void) { // // return the value of the bits that will cause an interrupt to the host. // return AM_BFR(IOSLAVE, IOINTCTL, IOINT); } //***************************************************************************** // //! @brief Get the enable bits in the HOST side IOINTCTL register. //! //! This function may be used to read the host side interrupt bits. //! //! @return None. // //***************************************************************************** uint32_t am_hal_ios_host_int_enable_get(void) { // // return the value of the bits that will cause an interrupt to the host. // return AM_BFR(IOSLAVE, IOINTCTL, IOINTEN); } //***************************************************************************** // //! @brief Enable an IOS Access Interrupt. //! //! This function may be used to enable an interrupt to the NVIC. //! //! @return None. // //***************************************************************************** void am_hal_ios_access_int_enable(uint32_t ui32Interrupt) { // // OR the desired interrupt into the enable register. // AM_REG(IOSLAVE, REGACCINTEN) |= ui32Interrupt; } //***************************************************************************** // //! @brief Return all enabled IOS Access Interrupts. //! //! This function may be used to return all enabled IOS Access interrupts. //! //! @return the enabled interrrupts. // //***************************************************************************** uint32_t am_hal_ios_access_int_enable_get(void) { // // Return the enabled interrupts. // return AM_REG(IOSLAVE, REGACCINTEN); } //***************************************************************************** // //! @brief Disable an IOS Access Interrupt. //! //! This function may be used to disable an interrupt to the NVIC. //! //! @return None. // //***************************************************************************** void am_hal_ios_access_int_disable(uint32_t ui32Interrupt) { // // Clear the desired bit from the interrupt enable register. // AM_REG(IOSLAVE, REGACCINTEN) &= ~(ui32Interrupt); } //***************************************************************************** // //! @brief Clear an IOS Access Interrupt. //! //! This function may be used to clear an interrupt to the NVIC. //! //! @return None. // //***************************************************************************** void am_hal_ios_access_int_clear(uint32_t ui32Interrupt) { // // Use the interrupt clear register to deactivate the chosen interrupt. // AM_REG(IOSLAVE, REGACCINTCLR) = ui32Interrupt; } //***************************************************************************** // //! @brief Set an IOS Access Interrupt. //! //! This function may be used to set an interrupt to the NVIC. //! //! @return None. // //***************************************************************************** void am_hal_ios_access_int_set(uint32_t ui32Interrupt) { // // Use the interrupt set register to activate the chosen interrupt. // AM_REG(IOSLAVE, REGACCINTSET) = ui32Interrupt; } //***************************************************************************** // //! @brief Check the status of an IOS Access Interrupt. //! //! @param bEnabledOnly - return only the enabled interrupt status. //! //! This function may be used to return the enabled interrupt status. //! //! @return the enabled interrupt status. // //***************************************************************************** uint32_t am_hal_ios_access_int_status_get(bool bEnabledOnly) { if (bEnabledOnly) { uint32_t u32RetVal = AM_REG(IOSLAVE, REGACCINTSTAT); return u32RetVal & AM_REG(IOSLAVE, REGACCINTEN); } else { return AM_REG(IOSLAVE, REGACCINTSTAT); } } //***************************************************************************** // //! @brief Enable an IOS Interrupt. //! //! @param ui32Interrupt - desired interrupts. //! //! This function may be used to enable an interrupt to the NVIC. //! //! @return None. // //***************************************************************************** void am_hal_ios_int_enable(uint32_t ui32Interrupt) { // // OR the desired interrupt into the enable register. // AM_REG(IOSLAVE, INTEN) |= ui32Interrupt; } //***************************************************************************** // //! @brief Return all enabled IOS Interrupts. //! //! This function may be used to return all enabled IOS interrupts. //! //! @return the enabled interrrupts. // //***************************************************************************** uint32_t am_hal_ios_int_enable_get(void) { // // Return the enabled interrupts. // return AM_REG(IOSLAVE, INTEN); } //***************************************************************************** // //! @brief Disable an IOS Interrupt. //! //! @param ui32Interrupt - desired interrupts. //! //! This function may be used to disable an interrupt to the NVIC. //! //! @return None. // //***************************************************************************** void am_hal_ios_int_disable(uint32_t ui32Interrupt) { // // Clear the desired bit from the interrupt enable register. // AM_REG(IOSLAVE, INTEN) &= ~(ui32Interrupt); } //***************************************************************************** // //! @brief Clear an IOS Interrupt. //! //! @param ui32Interrupt - desired interrupts. //! //! This function may be used to clear an interrupt to the NVIC. //! //! @return None. // //***************************************************************************** void am_hal_ios_int_clear(uint32_t ui32Interrupt) { // // Use the interrupt clear register to deactivate the chosen interrupt. // AM_REG(IOSLAVE, INTCLR) = ui32Interrupt; } //***************************************************************************** // //! @brief Set an IOS Interrupt. //! //! @param ui32Interrupt - desired interrupts. //! //! This function may be used to set an interrupt to the NVIC. //! //! @return None. // //***************************************************************************** void am_hal_ios_int_set(uint32_t ui32Interrupt) { // // Use the interrupt clear register to deactivate the chosen interrupt. // AM_REG(IOSLAVE, INTSET) = ui32Interrupt; } //***************************************************************************** // //! @brief Write to the LRAM. //! //! @param ui32Offset - offset into the LRAM to write. //! @param ui8Value - value to be written. //! //! This function writes ui8Value to offset ui32Offset inside the LRAM. //! //! @return None. // //***************************************************************************** void am_hal_ios_lram_write(uint32_t ui32Offset, uint8_t ui8Value) { // // Write the LRAM. // am_hal_ios_pui8LRAM[ui32Offset] = ui8Value; } //***************************************************************************** // //! @brief Read from the LRAM. //! //! @param ui32Offset - offset into the LRAM to read. //! //! This function read from offset ui32Offset inside the LRAM. //! //! @return the value at ui32Offset. // //***************************************************************************** uint8_t am_hal_ios_lram_read(uint32_t ui32Offset) { // // Read the LRAM. // return am_hal_ios_pui8LRAM[ui32Offset]; } //***************************************************************************** // //! @brief Check the status of an IOS Interrupt. //! //! @param bEnabledOnly - return only the enabled interrupt status. //! //! This function may be used to return the enabled interrupt status. //! //! @return the enabled interrupt status. // //***************************************************************************** uint32_t am_hal_ios_int_status_get(bool bEnabledOnly) { if (bEnabledOnly) { uint32_t u32RetVal = AM_REG(IOSLAVE, INTSTAT); return u32RetVal & AM_REG(IOSLAVE, INTEN); } else { return AM_REG(IOSLAVE, INTSTAT); } } //***************************************************************************** // //! @brief Check the amount of space used in the FIFO //! //! This function returns the available data in the overall FIFO yet to be //! read by the host. This takes into account the SRAM buffer and hardware FIFO //! //! @return Bytes used in the Overall FIFO. // //***************************************************************************** uint32_t am_hal_ios_fifo_space_used(void) { uint32_t ui32Val; uint32_t ui32Primask; // // Start a critical section for thread safety. // ui32Primask = am_hal_interrupt_master_disable(); ui32Val = g_sSRAMBuffer.ui32Length; ui32Val += AM_BFR(IOSLAVE, FIFOPTR, FIFOSIZ); // // End the critical section // am_hal_interrupt_master_set(ui32Primask); return ui32Val; } //***************************************************************************** // //! @brief Check the amount of space left in the FIFO //! //! This function returns the available space in the overall FIFO to accept //! new data. This takes into account the SRAM buffer and hardware FIFO //! //! @return Bytes left in the Overall FIFO. // //***************************************************************************** uint32_t am_hal_ios_fifo_space_left(void) { uint32_t ui32Val; uint32_t ui32Primask; // // Start a critical section for thread safety. // ui32Primask = am_hal_interrupt_master_disable(); // // We waste one byte in HW FIFO // ui32Val = g_sSRAMBuffer.ui32Capacity + g_ui32HwFifoSize - 1; ui32Val -= g_sSRAMBuffer.ui32Length; ui32Val -= AM_BFR(IOSLAVE, FIFOPTR, FIFOSIZ); // // End the critical section // am_hal_interrupt_master_set(ui32Primask); return ui32Val; } //***************************************************************************** // //! @brief Check the amount of space left in the hardware FIFO //! //! This function reads the IOSLAVE FIFOPTR register and determines the amount //! of space left in the IOS LRAM FIFO. //! //! @return Bytes left in the IOS FIFO. // //***************************************************************************** static uint32_t fifo_space_left(void) { // // We waste one byte in HW FIFO // return ((uint32_t)g_ui32HwFifoSize- AM_BFR(IOSLAVE, FIFOPTR, FIFOSIZ) - 1); } //***************************************************************************** // // Helper function for managing IOS FIFO writes. // //***************************************************************************** static void fifo_write(uint8_t *pui8Data, uint32_t ui32NumBytes) { while ( ui32NumBytes ) { // // Write the data to the FIFO // *g_pui8FIFOPtr++ = *pui8Data++; ui32NumBytes--; // // Make sure to wrap the FIFO pointer if necessary. // if ( g_pui8FIFOPtr == g_pui8FIFOEnd ) { g_pui8FIFOPtr = g_pui8FIFOBase; } } } // // Assembly code below assumes 8bit FIFOSIZ field aligned at a byte boundary // #if (((AM_REG_IOSLAVE_FIFOPTR_FIFOSIZ_M >> AM_REG_IOSLAVE_FIFOPTR_FIFOSIZ_S) != 0xFF) \ || (AM_REG_IOSLAVE_FIFOPTR_FIFOSIZ_S & 0x3)) #error "FIFOSIZ not 8bit value aligned at byte offset" #endif // // Byte offset of FIFOSIZ field in FIFOPTR register // #define BYTEOFFSET_FIFOSIZE (AM_REG_IOSLAVE_FIFOPTR_FIFOSIZ_S >> 3) //***************************************************************************** // // Helper function in assembly for implementing the ReSync // //***************************************************************************** #if (defined (__ARMCC_VERSION)) && (__ARMCC_VERSION < 6000000) __asm static void internal_resync_fifoSize(uint32_t wrOffset, uint32_t maxFifoSize, uint32_t hwFifoPtrRegAddr) { push {r3, r4} // Save r3, r4 - used by this function internal_resync_fifoSize_loop ldr r4, [r2] // Load FIFOPTR register in r4 ubfx r3, r4, #AM_REG_IOSLAVE_FIFOPTR_FIFOSIZ_S, #8 // Extract hwFifoSize to r3 uxtb r4, r4 // Extract rdOffset in r4 subs r4, r0, r4 // fifoSize in r4 = wrOffset - rdOffset it cc // if (wrOffset < rdOffset), addcc r4, r4, r1 // fifoSize = maxFifoSize - (rdOffset - wrOffset) cmp r3, r4 // (hwFifoSize != fifoSize) beq internal_resync_fifosize_done strb r4, [r2, #1] // Overwrite FIFOSIZ value with fifoSize b internal_resync_fifoSize_loop // Repeat the check internal_resync_fifosize_done pop {r3, r4} // Restore registers bx lr } #elif (defined (__ARMCC_VERSION)) && (__ARMCC_VERSION >= 6000000) #if (AM_REG_IOSLAVE_FIFOPTR_FIFOSIZ_S != 8) #error "AM_REG_IOSLAVE_FIFOPTR_FIFOSIZ_S not 8" #endif __attribute__((naked)) static void internal_resync_fifoSize(uint32_t wrOffset, uint32_t maxFifoSize, uint32_t hwFifoPtrRegAddr) { __asm ( " push {r3,r4}\n\t" // Save r3, r4 - used by this function "__internal_resync_fifoSize_loop:\n\t" " ldr r4, [r2]\n\t" // Load FIFOPTR register in r4 " ubfx r3, r4, #8, #8\n\t" // Extract hwFifoSize to r3 " uxtb r4, r4\n\t" // Extract rdOffset in r4 " subs r4, r0, r4\n\t" // fifoSize in r4 = wrOffset - rdOffset " it cc\n\t" // if (wrOffset < rdOffset) " addcc r4, r4, r1\n\t" // fifoSize = maxFifoSize - (rdOffset - wrOffset) " cmp r3, r4\n\t" // (hwFifoSize != fifoSize) " beq __internal_resync_fifosize_done\n\t" " strb r4, [r2, #1]\n\t" // Overwrite FIFOSIZ value with fifoSize " b __internal_resync_fifoSize_loop\n\t" // Repeat the check "__internal_resync_fifosize_done:\n\t" " pop {r3,r4}\n\t" // Restore registers " bx lr\n\t" ); } #elif defined(__GNUC_STDC_INLINE__) #if (AM_REG_IOSLAVE_FIFOPTR_FIFOSIZ_S != 8) #error "AM_REG_IOSLAVE_FIFOPTR_FIFOSIZ_S not 8" #endif __attribute__((naked)) static void internal_resync_fifoSize(uint32_t wrOffset, uint32_t maxFifoSize, uint32_t hwFifoPtrRegAddr) { __asm ( " push {r3,r4}\n\t" // Save r3, r4 - used by this function "__internal_resync_fifoSize_loop:\n\t" " ldr r4, [r2]\n\t" // Load FIFOPTR register in r4 " ubfx r3, r4, #8, #8\n\t" // Extract hwFifoSize to r3 " uxtb r4, r4\n\t" // Extract rdOffset in r4 " subs r4, r0, r4\n\t" // fifoSize in r4 = wrOffset - rdOffset " it cc\n\t" // if (wrOffset < rdOffset) " addcc r4, r4, r1\n\t" // fifoSize = maxFifoSize - (rdOffset - wrOffset) " cmp r3, r4\n\t" // (hwFifoSize != fifoSize) " beq __internal_resync_fifosize_done\n\t" " strb r4, [r2, #1]\n\t" // Overwrite FIFOSIZ value with fifoSize " b __internal_resync_fifoSize_loop\n\t" // Repeat the check "__internal_resync_fifosize_done:\n\t" " pop {r3,r4}\n\t" // Restore registers " bx lr\n\t" ); } #elif defined(__IAR_SYSTEMS_ICC__) #if (AM_REG_IOSLAVE_FIFOPTR_FIFOSIZ_S != 8) #error "AM_REG_IOSLAVE_FIFOPTR_FIFOSIZ_S not 8" #endif __stackless static void internal_resync_fifoSize(uint32_t wrOffset, uint32_t maxFifoSize, uint32_t hwFifoPtrRegAddr) { __asm volatile ( " push {r3,r4}\n" // Save r3, r4 - used by this function "__internal_resync_fifoSize_loop:\n" " ldr r4, [r2]\n" // Load FIFOPTR register in r4 " ubfx r3, r4, #8, #8\n" // Extract hwFifoSize to r3 " uxtb r4, r4\n" // Extract rdOffset in r4 " subs r4, r0, r4\n" // fifoSize in r4 = wrOffset - rdOffset " it cc\n" " addcc r4, r4, r1\n" // fifoSize = maxFifoSize - (rdOffset - wrOffset) " cmp r3, r4\n" // (fifoSize != hwFifoSize) " beq __internal_resync_fifosize_done\n" " strb r4, [r2, #1]\n" // Overwrite FIFOSIZ value with fifoSize " b __internal_resync_fifoSize_loop\n" // Repeat the check "__internal_resync_fifosize_done:\n" " pop {r3,r4}\n" // Restore registers " bx lr\n" ); } #else static void internal_resync_fifoSize(uint32_t wrOffset, uint32_t maxFifoSize, uint32_t hwFifoPtrRegAddr) { uint32_t fifoSize; uint32_t hwFifoPtrReg; uint32_t rdOffset; uint32_t hwFifoSize; hwFifoPtrReg = AM_REGVAL(hwFifoPtrRegAddr); rdOffset = ((hwFifoPtrReg & AM_REG_IOSLAVE_FIFOPTR_FIFOPTR_M) >> AM_REG_IOSLAVE_FIFOPTR_FIFOPTR_S); hwFifoSize = (hwFifoPtrReg & AM_REG_IOSLAVE_FIFOPTR_FIFOSIZ_M) >> AM_REG_IOSLAVE_FIFOPTR_FIFOSIZ_S; // By wasting one byte in hardware FIFO, we're guaranteed that fifoSize does not need special handling for FULL FIFO case fifoSize = ((wrOffset >= rdOffset) ? (wrOffset - rdOffset) : (maxFifoSize - (rdOffset - wrOffset))); while (fifoSize != hwFifoSize) { // Overwite correct FIFOSIZ // Need to do a Byte Write to make sure the FIFOPTR is not overwritten *((uint8_t *)(hwFifoPtrRegAddr + BYTEOFFSET_FIFOSIZE)) = fifoSize; // Read back the register and check for consistency hwFifoPtrReg = AM_REGVAL(hwFifoPtrRegAddr); rdOffset = ((hwFifoPtrReg & AM_REG_IOSLAVE_FIFOPTR_FIFOPTR_M) >> AM_REG_IOSLAVE_FIFOPTR_FIFOPTR_S); hwFifoSize = (hwFifoPtrReg & AM_REG_IOSLAVE_FIFOPTR_FIFOSIZ_M) >> AM_REG_IOSLAVE_FIFOPTR_FIFOSIZ_S; // By wasting one byte in hardware FIFO, we're guaranteed that fifoSize does not need special handling for FULL FIFO case fifoSize = ((wrOffset >= rdOffset) ? (wrOffset - rdOffset) : (hwFifoSize - (rdOffset - wrOffset))); } } #endif // // Address of the FIFOPTR register // #define AM_REG_IOS_FIFOPTR (REG_IOSLAVE_BASEADDR + AM_REG_IOSLAVE_FIFOPTR_O) // When the FIFO is being replenished by the SW, at the same time as host is // reading from it, there is a possible race condition, where the hardware decrement // of FIFOSIZ as a result of read gets overwritten by hardware increment due to // write. // This function re-sync's the FIFOSIZ to ensure such errors do not accumulate void resync_fifoSize(void) { uint32_t ui32Primask; uint32_t wrOffset = (uint32_t)g_pui8FIFOPtr - (uint32_t)am_hal_ios_pui8LRAM; // // Start a critical section for thread safety. // ui32Primask = am_hal_interrupt_master_disable(); internal_resync_fifoSize(wrOffset, g_ui32HwFifoSize, AM_REG_IOS_FIFOPTR); // Clear interrupts for IOS which could be spuriously triggered AM_REG(IOSLAVE, REGACCINTCLR) = (AM_HAL_IOS_INT_FSIZE | AM_HAL_IOS_INT_FOVFL | AM_HAL_IOS_INT_FUNDFL); // // End the critical section // am_hal_interrupt_master_set(ui32Primask); return; } //***************************************************************************** // //! @brief Transfer any available data from the IOS SRAM buffer to the FIFO. //! //! This function is meant to be called from an interrupt handler for the //! ioslave module. It checks the IOS FIFO interrupt status for a threshold //! event, and transfers data from an SRAM buffer into the IOS FIFO. //! //! @param ui32Status should be set to the ios interrupt status at the time of //! ISR entry. //! //! @return None. // //***************************************************************************** void am_hal_ios_fifo_service(uint32_t ui32Status) { uint32_t thresh; uint32_t freeSpace, usedSpace, chunk1, chunk2, ui32WriteIndex; // // Check for FIFO size interrupts. // if ( ui32Status & AM_HAL_IOS_INT_FSIZE ) { thresh = AM_BFR(IOSLAVE, FIFOTHR, FIFOTHR); // // While the FIFO is at or below threshold Add more data // If Fifo level is above threshold, we're guaranteed an FSIZ interrupt // while (g_sSRAMBuffer.ui32Length && ((usedSpace = AM_BFR(IOSLAVE, FIFOPTR, FIFOSIZ)) <= thresh) ) { // // So, we do have some data in SRAM which needs to be moved to FIFO. // A chunk of data is a continguous set of bytes in SRAM that can be // written to FIFO. Determine the chunks of data from SRAM that can // be written. Up to two chunks possible // ui32WriteIndex = g_sSRAMBuffer.ui32WriteIndex; chunk1 = ((ui32WriteIndex > (uint32_t)g_sSRAMBuffer.ui32ReadIndex) ? \ (ui32WriteIndex - (uint32_t)g_sSRAMBuffer.ui32ReadIndex) : \ (g_sSRAMBuffer.ui32Capacity - (uint32_t)g_sSRAMBuffer.ui32ReadIndex)); chunk2 = g_sSRAMBuffer.ui32Length - chunk1; // We waste one byte in HW FIFO freeSpace = g_ui32HwFifoSize - usedSpace - 1; // Write data in chunks // Determine the chunks of data from SRAM that can be written if (chunk1 > freeSpace) { fifo_write((uint8_t *)(g_sSRAMBuffer.pui8Data + g_sSRAMBuffer.ui32ReadIndex), freeSpace); // // Advance the read index, wrapping if needed. // g_sSRAMBuffer.ui32ReadIndex += freeSpace; // No need to check for wrap as we wrote less than chunk1 // // Adjust the length value to reflect the change. // g_sSRAMBuffer.ui32Length -= freeSpace; } else { fifo_write((uint8_t *)(g_sSRAMBuffer.pui8Data + g_sSRAMBuffer.ui32ReadIndex), chunk1); // // Update the read index - wrapping as needed // g_sSRAMBuffer.ui32ReadIndex += chunk1; g_sSRAMBuffer.ui32ReadIndex %= g_sSRAMBuffer.ui32Capacity; // // Adjust the length value to reflect the change. // g_sSRAMBuffer.ui32Length -= chunk1; freeSpace -= chunk1; if (freeSpace && chunk2) { if (chunk2 > freeSpace) { fifo_write((uint8_t *)(g_sSRAMBuffer.pui8Data + g_sSRAMBuffer.ui32ReadIndex), freeSpace); // // Advance the read index, wrapping if needed. // g_sSRAMBuffer.ui32ReadIndex += freeSpace; // No need to check for wrap in chunk2 // // Adjust the length value to reflect the change. // g_sSRAMBuffer.ui32Length -= freeSpace; } else { fifo_write((uint8_t *)(g_sSRAMBuffer.pui8Data + g_sSRAMBuffer.ui32ReadIndex), chunk2); // // Advance the read index, wrapping if needed. // g_sSRAMBuffer.ui32ReadIndex += chunk2; // No need to check for wrap in chunk2 // // Adjust the length value to reflect the change. // g_sSRAMBuffer.ui32Length -= chunk2; } } } resync_fifoSize(); // // Need to retake the FIFO space, after Threshold interrupt has been reenabled // Clear any spurious FSIZE interrupt that might have got raised // AM_BFW(IOSLAVE, INTCLR, FSIZE, 1); } } } //***************************************************************************** // //! @brief Writes the specified number of bytes to the IOS fifo. //! //! @param pui8Data is a pointer to the data to be written to the fifo. //! @param ui32NumBytes is the number of bytes to send. //! //! This function will write data from the caller-provided array to the IOS //! LRAM FIFO. If there is no space in the LRAM FIFO, the data will be copied //! to a temporary SRAM buffer instead. //! //! The maximum message size for the IO Slave is 1023 bytes. //! //! @note In order for SRAM copy operations in the function to work correctly, //! the \e am_hal_ios_buffer_service() function must be called in the ISR for //! the ioslave module. //! //! @return Number of bytes written (could be less than ui32NumBytes, if not enough space) // //***************************************************************************** uint32_t am_hal_ios_fifo_write(uint8_t *pui8Data, uint32_t ui32NumBytes) { uint32_t ui32FIFOSpace; uint32_t ui32SRAMSpace; uint32_t ui32SRAMLength; uint32_t ui32Primask; uint32_t totalBytes = ui32NumBytes; // // This operation will only work properly if an SRAM buffer has been // allocated. Make sure that am_hal_ios_fifo_buffer_init() has been called, // and the buffer pointer looks valid. // am_hal_debug_assert(g_sSRAMBuffer.pui8Data != 0); if ( ui32NumBytes == 0) { return 0; } // // Start a critical section for thread safety. // ui32Primask = am_hal_interrupt_master_disable(); ui32SRAMLength = g_sSRAMBuffer.ui32Length; // // End the critical section // am_hal_interrupt_master_set(ui32Primask); // // If the SRAM buffer is empty, we should just write directly to the FIFO. // if (ui32SRAMLength == 0) { ui32FIFOSpace = fifo_space_left(); // // If the whole message fits, send it now. // if ( ui32NumBytes <= ui32FIFOSpace ) { fifo_write(pui8Data, ui32NumBytes); ui32NumBytes = 0; } else { fifo_write(pui8Data, ui32FIFOSpace); ui32NumBytes -= ui32FIFOSpace; pui8Data += ui32FIFOSpace; }; resync_fifoSize(); } // // If there's still data, write it to the SRAM buffer. // if ( ui32NumBytes ) { uint32_t idx, writeIdx, capacity, fifoSize; ui32SRAMSpace = g_sSRAMBuffer.ui32Capacity - ui32SRAMLength; writeIdx = g_sSRAMBuffer.ui32WriteIndex; capacity = g_sSRAMBuffer.ui32Capacity; // // Make sure that the data will fit inside the SRAM buffer. // if ( ui32SRAMSpace > ui32NumBytes ) { ui32SRAMSpace = ui32NumBytes; } // // If the data will fit, write it to the SRAM buffer. // for (idx = 0; idx < ui32SRAMSpace; idx++) { g_sSRAMBuffer.pui8Data[(idx + writeIdx) % capacity] = pui8Data[idx]; } ui32NumBytes -= idx; // // Start a critical section for thread safety before updating length & wrIdx. // ui32Primask = am_hal_interrupt_master_disable(); // // Advance the write index, making sure to wrap if necessary. // g_sSRAMBuffer.ui32WriteIndex = (idx + writeIdx) % capacity; // // Update the length value appropriately. // g_sSRAMBuffer.ui32Length += idx; // // End the critical section // am_hal_interrupt_master_set(ui32Primask); // It is possible that there is a race condition that the FIFO level has // gone below the threshold by the time we set the wrIdx above, and hence // we may never get the threshold interrupt to serve the SRAM data we // just wrote // If that is the case, explicitly generate the FSIZE interrupt from here fifoSize = AM_BFR(IOSLAVE, FIFOPTR, FIFOSIZ); if (fifoSize <= AM_BFR(IOSLAVE, FIFOTHR, FIFOTHR)) { AM_BFW(IOSLAVE, INTSET, FSIZE, 1); } } return (totalBytes - ui32NumBytes); } //***************************************************************************** // //! @brief Writes the specified number of bytes to the IOS fifo simply. //! //! @param pui8Data is a pointer to the data to be written to the fifo. //! @param ui32NumBytes is the number of bytes to send. //! //! This function will write data from the caller-provided array to the IOS //! LRAM FIFO. This simple routine does not use SRAM buffering for large //! messages. //! //! The maximum message size for the IO Slave is 128 bytes. //! //! @note Do note call the \e am_hal_ios_buffer_service() function in the ISR for //! the ioslave module. //! //! @return // //***************************************************************************** void am_hal_ios_fifo_write_simple(uint8_t *pui8Data, uint32_t ui32NumBytes) { uint32_t ui32FIFOSpace; // // Check the FIFO and the SRAM buffer to see where we have space. // ui32FIFOSpace = fifo_space_left(); // // If the whole message fits, send it now. // if ( ui32NumBytes <= ui32FIFOSpace ) { fifo_write(pui8Data, ui32NumBytes); } else { // // The message didn't fit. Try using am_hal_ios_fifo_write() instead. // am_hal_debug_assert_msg(0, "The requested IOS transfer didn't fit in" "the LRAM FIFO. Try using am_hal_ios_fifo_write()."); } } //***************************************************************************** // //! @brief Sets the IOS FIFO pointer to the specified LRAM offset. //! //! @param ui32Offset is LRAM offset to set the FIFO pointer to. //! //! @return None. // //***************************************************************************** void am_hal_ios_fifo_ptr_set(uint32_t ui32Offset) { uint32_t ui32Primask; // // Start a critical section for thread safety. // ui32Primask = am_hal_interrupt_master_disable(); // // Set the FIFO Update bit. // AM_REG(IOSLAVE, FUPD) = 0x1; // // Change the FIFO offset. // AM_REG(IOSLAVE, FIFOPTR) = ui32Offset; // // Clear the FIFO update bit. // AM_REG(IOSLAVE, FUPD) = 0x0; // // Set the global FIFO-pointer tracking variable. // g_pui8FIFOPtr = (uint8_t *) (REG_IOSLAVE_BASEADDR + ui32Offset); // // End the critical section. // am_hal_interrupt_master_set(ui32Primask); } //***************************************************************************** // // Initialize an SRAM buffer for use with the IO Slave. // //***************************************************************************** static void am_hal_ios_buffer_init(am_hal_ios_buffer_t *psBuffer, void *pvArray, uint32_t ui32Bytes) { psBuffer->ui32WriteIndex = 0; psBuffer->ui32ReadIndex = 0; psBuffer->ui32Length = 0; psBuffer->ui32Capacity = ui32Bytes; psBuffer->pui8Data = (uint8_t *)pvArray; } //***************************************************************************** // //! @brief Poll for all host side read activity to complete. //! //! Poll for all host side read activity to complete. Use this before //! calling am_hal_ios_fifo_write_simple(). //! //! @return None. // //***************************************************************************** void am_hal_ios_read_poll_complete(void) { while ( AM_REG(IOSLAVE, FUPD) & AM_REG_IOSLAVE_FUPD_IOREAD_M ); } //***************************************************************************** // //! @brief Initializes an SRAM buffer for the IOS FIFO. //! //! @param pui8Buffer is the SRAM buffer that will be used for IOS fifo data. //! @param ui32BufferSize is the size of the SRAM buffer. //! //! This function provides the IOS HAL functions with working memory for //! managing outgoing IOS FIFO transactions. It needs to be called at least //! once before am_hal_ios_fifo_write() may be used. //! //! The recommended buffer size for the IOS FIFO is 1024 bytes. //! //! @return None. // //***************************************************************************** void am_hal_ios_fifo_buffer_init(uint8_t *pui8Buffer, uint32_t ui32NumBytes) { // // Initialize the global SRAM buffer // Total size, which is SRAM Buffer plus the hardware FIFO needs to be // limited to 1023 // if (ui32NumBytes > (1023 - g_ui32HwFifoSize + 1)) { ui32NumBytes = (1023 - g_ui32HwFifoSize + 1); } am_hal_ios_buffer_init(&g_sSRAMBuffer, pui8Buffer, ui32NumBytes); // // Clear the FIFO State // AM_BFW(IOSLAVE, FIFOCTR, FIFOCTR, 0x0); AM_BFW(IOSLAVE, FIFOPTR, FIFOSIZ, 0x0); am_hal_ios_fifo_ptr_set(g_ui32FifoBaseOffset); } //***************************************************************************** // //! @brief Update the FIFOCTR to inform host of available data to read. //! //! This function allows the application to indicate to HAL when it is safe to //! update the FIFOCTR. //! //! Application needs to implement some sort of //! synchronization with the host to make sure host is not reading FIFOCTR while //! it is being updated by the MCU, since the FIFOCTR read over //! IO is not an atomic operation. //! //! //! @return None. // //***************************************************************************** void am_hal_ios_update_fifoctr(void) { uint32_t ui32Val; // Determine the available data ui32Val = am_hal_ios_fifo_space_used(); // Update FIFOCTR AM_BFW(IOSLAVE, FIFOCTR, FIFOCTR, ui32Val); return; } //***************************************************************************** // // End the doxygen group //! @} // //*****************************************************************************