//***************************************************************************** // // am_bsp.c //! @file //! //! @brief Top level functions for performing board initialization. //! //! @addtogroup BSP Board Support Package (BSP) //! @addtogroup apollo3_eb_bsp BSP for the Apollo3 Engineering Board //! @ingroup BSP //! @{ // //***************************************************************************** //***************************************************************************** // // Copyright (c) 2019, 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 v2.0.0 of the AmbiqSuite Development Package. // //***************************************************************************** #include "am_bsp.h" #include "am_util.h" //***************************************************************************** // // Power tracking structures for IOM and UART // //***************************************************************************** am_bsp_uart_pwrsave_t am_bsp_uart_pwrsave[AM_REG_UART_NUM_MODULES]; //***************************************************************************** // // LEDs // //***************************************************************************** #ifdef AM_BSP_NUM_LEDS am_devices_led_t am_bsp_psLEDs[AM_BSP_NUM_LEDS] = {0}; #endif #ifdef AM_BSP_NUM_BUTTONS //***************************************************************************** // // Buttons. // //***************************************************************************** am_devices_button_t am_bsp_psButtons[AM_BSP_NUM_BUTTONS] = { AM_DEVICES_BUTTON(AM_BSP_GPIO_BUTTON0, AM_DEVICES_BUTTON_NORMAL_HIGH) }; #endif //***************************************************************************** // // Print interface tracking variable. // //***************************************************************************** static uint32_t g_ui32PrintInterface = AM_BSP_PRINT_INFC_UART0; //***************************************************************************** // // Default UART configuration settings. // //***************************************************************************** static void *g_sCOMUART; static const am_hal_uart_config_t g_sBspUartConfig = { // // Standard UART settings: 115200-8-N-1 // .ui32BaudRate = 115200, .ui32DataBits = AM_HAL_UART_DATA_BITS_8, .ui32Parity = AM_HAL_UART_PARITY_NONE, .ui32StopBits = AM_HAL_UART_ONE_STOP_BIT, .ui32FlowControl = AM_HAL_UART_FLOW_CTRL_NONE, // // Set TX and RX FIFOs to interrupt at half-full. // .ui32FifoLevels = (AM_HAL_UART_TX_FIFO_1_2 | AM_HAL_UART_RX_FIFO_1_2), // // The default interface will just use polling instead of buffers. // .pui8TxBuffer = 0, .ui32TxBufferSize = 0, .pui8RxBuffer = 0, .ui32RxBufferSize = 0, }; #ifndef AM_BSP_DISABLE_BUFFERED_UART //***************************************************************************** // // Default UART configuration settings if using buffers. // //***************************************************************************** #define AM_BSP_UART_BUFFER_SIZE 1024 static uint8_t pui8UartTxBuffer[AM_BSP_UART_BUFFER_SIZE]; static uint8_t pui8UartRxBuffer[AM_BSP_UART_BUFFER_SIZE]; static am_hal_uart_config_t g_sBspUartBufferedConfig = { // // Standard UART settings: 115200-8-N-1 // .ui32BaudRate = 115200, .ui32DataBits = AM_HAL_UART_DATA_BITS_8, .ui32Parity = AM_HAL_UART_PARITY_NONE, .ui32StopBits = AM_HAL_UART_ONE_STOP_BIT, .ui32FlowControl = AM_HAL_UART_FLOW_CTRL_NONE, // // Set TX and RX FIFOs to interrupt at half-full. // .ui32FifoLevels = (AM_HAL_UART_TX_FIFO_1_2 | AM_HAL_UART_RX_FIFO_1_2), // // The default interface will just use polling instead of buffers. // .pui8TxBuffer = pui8UartTxBuffer, .ui32TxBufferSize = sizeof(pui8UartTxBuffer), .pui8RxBuffer = pui8UartRxBuffer, .ui32RxBufferSize = sizeof(pui8UartRxBuffer), }; #endif // AM_BSP_DISABLE_BUFFERED_UART //***************************************************************************** // //! @brief Prepare the MCU for low power operation. //! //! This function enables several power-saving features of the MCU, and //! disables some of the less-frequently used peripherals. It also sets the //! system clock to 24 MHz. //! //! @return None. // //***************************************************************************** void am_bsp_low_power_init(void) { // // Initialize for low power in the power control block // am_hal_pwrctrl_low_power_init(); // // Disable the RTC. // am_hal_rtc_osc_disable(); // // Stop the XTAL. // am_hal_clkgen_control(AM_HAL_CLKGEN_CONTROL_XTAL_STOP, 0); // // Make sure SWO/ITM/TPIU is disabled. // SBL may not get it completely shut down. // am_bsp_itm_printf_disable(); #ifdef AM_BSP_NUM_LEDS // // Initialize the LEDs. // On the apollo3_evb, when the GPIO outputs are disabled (the default at // power up), the FET gates are floating and partially illuminating the LEDs. // uint32_t ux, ui32GPIONumber; for (ux = 0; ux < AM_BSP_NUM_LEDS; ux++) { ui32GPIONumber = am_bsp_psLEDs[ux].ui32GPIONumber; // // Configure the pin as a push-pull GPIO output // (aka AM_DEVICES_LED_POL_DIRECT_DRIVE_M). // am_hal_gpio_pinconfig(ui32GPIONumber, g_AM_HAL_GPIO_OUTPUT); // // Turn off the LED. // am_hal_gpio_state_write(ui32GPIONumber, AM_HAL_GPIO_OUTPUT_TRISTATE_DISABLE); am_hal_gpio_state_write(ui32GPIONumber, AM_HAL_GPIO_OUTPUT_CLEAR); } #endif // AM_BSP_NUM_LEDS } // am_bsp_low_power_init() //***************************************************************************** // //! @brief Enable the TPIU and ITM for debug printf messages. //! //! This function enables TPIU registers for debug printf messages and enables //! ITM GPIO pin to SWO mode. This function should be called after reset and //! after waking up from deep sleep. //! //! @return None. // //***************************************************************************** void am_bsp_debug_printf_enable(void) { if (g_ui32PrintInterface == AM_BSP_PRINT_INFC_SWO) { #ifdef AM_BSP_GPIO_ITM_SWO am_bsp_itm_printf_enable(); #endif } else if (g_ui32PrintInterface == AM_BSP_PRINT_INFC_UART0) { am_bsp_uart_printf_enable(); } #ifndef AM_BSP_DISABLE_BUFFERED_UART else if (g_ui32PrintInterface == AM_BSP_PRINT_INFC_BUFFERED_UART0) { am_bsp_buffered_uart_printf_enable(); } #endif // AM_BSP_DISABLE_BUFFERED_UART } // am_bsp_debug_printf_enable() //***************************************************************************** // //! @brief Enable the TPIU and ITM for debug printf messages. //! //! This function disables TPIU registers for debug printf messages and //! enables ITM GPIO pin to GPIO mode and prepares the MCU to go to deep sleep. //! //! @return None. // //***************************************************************************** void am_bsp_debug_printf_disable(void) { if (g_ui32PrintInterface == AM_BSP_PRINT_INFC_SWO) { am_bsp_itm_printf_disable(); } else if (g_ui32PrintInterface == AM_BSP_PRINT_INFC_UART0) { am_bsp_uart_printf_disable(); } } // am_bsp_debug_printf_disable() //***************************************************************************** // // @brief Enable printing over ITM. // //***************************************************************************** void #ifdef AM_BSP_GPIO_ITM_SWO am_bsp_itm_printf_enable(void) #else am_bsp_itm_printf_enable(uint32_t ui32Pin, am_hal_gpio_pincfg_t sPincfg) #endif { am_hal_tpiu_config_t TPIUcfg; // // Set the global print interface. // g_ui32PrintInterface = AM_BSP_PRINT_INFC_SWO; // // Enable the ITM interface and the SWO pin. // am_hal_itm_enable(); // // Enable the ITM and TPIU // Set the BAUD clock for 1M // TPIUcfg.ui32SetItmBaud = AM_HAL_TPIU_BAUD_2M; am_hal_tpiu_enable(&TPIUcfg); #ifdef AM_BSP_GPIO_ITM_SWO am_hal_gpio_pinconfig(AM_BSP_GPIO_ITM_SWO, g_AM_BSP_GPIO_ITM_SWO); #else am_hal_gpio_pinconfig(ui32Pin, sPincfg); #endif // // Attach the ITM to the STDIO driver. // am_util_stdio_printf_init(am_hal_itm_print); } // am_bsp_itm_printf_enable() //***************************************************************************** // //! @brief ITM-based string print function. //! //! This function is used for printing a string via the ITM. //! //! @return None. // //***************************************************************************** void am_bsp_itm_string_print(char *pcString) { am_hal_itm_print(pcString); } //***************************************************************************** // // @brief Disable printing over ITM. // //***************************************************************************** void am_bsp_itm_printf_disable(void) { // // Disable the ITM/TPIU // am_hal_itm_disable(); // // Detach the ITM interface from the STDIO driver. // am_util_stdio_printf_init(0); // // // // Disconnect the SWO pin // // // am_hal_gpio_pinconfig(AM_BSP_GPIO_ITM_SWO, g_AM_HAL_GPIO_DISABLE); } // am_bsp_itm_printf_disable() //***************************************************************************** // //! @brief Set up the IOM pins based on mode and module. //! //! This function configures up to 10-pins for MSPI serial, dual, quad, //! dual-quad, and octal operation. //! //! @return None. // //***************************************************************************** void am_bsp_iom_pins_enable(uint32_t ui32Module, am_hal_iom_mode_e eIOMMode) { uint32_t ui32Combined; // // Validate parameters // if ( ui32Module >= AM_REG_IOM_NUM_MODULES ) { // // FPGA supports only IOM0 and 1. // return; } ui32Combined = ((ui32Module << 2) | eIOMMode); switch ( ui32Combined ) { case ((0 << 2) | AM_HAL_IOM_SPI_MODE): am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM0_SCK, g_AM_BSP_GPIO_IOM0_SCK); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM0_MISO, g_AM_BSP_GPIO_IOM0_MISO); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM0_MOSI, g_AM_BSP_GPIO_IOM0_MOSI); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM0_CS, g_AM_BSP_GPIO_IOM0_CS); break; case ((1 << 2) | AM_HAL_IOM_SPI_MODE): am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM1_SCK, g_AM_BSP_GPIO_IOM1_SCK); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM1_MISO, g_AM_BSP_GPIO_IOM1_MISO); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM1_MOSI, g_AM_BSP_GPIO_IOM1_MOSI); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM1_CS, g_AM_BSP_GPIO_IOM1_CS); break; case ((2 << 2) | AM_HAL_IOM_SPI_MODE): am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM2_SCK, g_AM_BSP_GPIO_IOM2_SCK); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM2_MISO, g_AM_BSP_GPIO_IOM2_MISO); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM2_MOSI, g_AM_BSP_GPIO_IOM2_MOSI); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM2_CS, g_AM_BSP_GPIO_IOM2_CS); break; case ((3 << 2) | AM_HAL_IOM_SPI_MODE): am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM3_SCK, g_AM_BSP_GPIO_IOM3_SCK); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM3_MISO, g_AM_BSP_GPIO_IOM3_MISO); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM3_MOSI, g_AM_BSP_GPIO_IOM3_MOSI); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM3_CS, g_AM_BSP_GPIO_IOM3_CS); break; case ((4 << 2) | AM_HAL_IOM_SPI_MODE): am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM4_SCK, g_AM_BSP_GPIO_IOM4_SCK); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM4_MISO, g_AM_BSP_GPIO_IOM4_MISO); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM4_MOSI, g_AM_BSP_GPIO_IOM4_MOSI); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM4_CS, g_AM_BSP_GPIO_IOM4_CS); break; case ((5 << 2) | AM_HAL_IOM_SPI_MODE): am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM5_SCK, g_AM_BSP_GPIO_IOM5_SCK); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM5_MISO, g_AM_BSP_GPIO_IOM5_MISO); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM5_MOSI, g_AM_BSP_GPIO_IOM5_MOSI); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM5_CS, g_AM_BSP_GPIO_IOM5_CS); break; case ((0 << 2) | AM_HAL_IOM_I2C_MODE): am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM0_SCL, g_AM_BSP_GPIO_IOM0_SCL); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM0_SDA, g_AM_BSP_GPIO_IOM0_SDA); break; case ((1 << 2) | AM_HAL_IOM_I2C_MODE): am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM1_SCL, g_AM_BSP_GPIO_IOM1_SCL); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM1_SDA, g_AM_BSP_GPIO_IOM1_SDA); break; case ((2 << 2) | AM_HAL_IOM_I2C_MODE): am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM2_SCL, g_AM_BSP_GPIO_IOM2_SCL); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM2_SDA, g_AM_BSP_GPIO_IOM2_SDA); break; case ((3 << 2) | AM_HAL_IOM_I2C_MODE): am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM3_SCL, g_AM_BSP_GPIO_IOM3_SCL); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM3_SDA, g_AM_BSP_GPIO_IOM3_SDA); break; case ((4 << 2) | AM_HAL_IOM_I2C_MODE): am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM4_SCL, g_AM_BSP_GPIO_IOM4_SCL); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM4_SDA, g_AM_BSP_GPIO_IOM4_SDA); break; case ((5 << 2) | AM_HAL_IOM_I2C_MODE): am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM5_SCL, g_AM_BSP_GPIO_IOM5_SCL); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM5_SDA, g_AM_BSP_GPIO_IOM5_SDA); break; default: break; } } // am_bsp_iom_pins_enable() //***************************************************************************** // //! @brief Disable the IOM pins based on mode and module. //! //! @return None. // //***************************************************************************** void am_bsp_iom_pins_disable(uint32_t ui32Module, am_hal_iom_mode_e eIOMMode) { uint32_t ui32Combined; // // Validate parameters // if ( ui32Module >= AM_REG_IOM_NUM_MODULES ) { // // FPGA supports only IOM0 and 1. // return; } ui32Combined = ((ui32Module << 2) | eIOMMode); switch ( ui32Combined ) { case ((0 << 2) | AM_HAL_IOM_SPI_MODE): am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM0_SCK, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM0_MISO, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM0_MOSI, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM0_CS, g_AM_HAL_GPIO_DISABLE); break; case ((1 << 2) | AM_HAL_IOM_SPI_MODE): am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM1_SCK, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM1_MISO, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM1_MOSI, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM1_CS, g_AM_HAL_GPIO_DISABLE); break; case ((2 << 2) | AM_HAL_IOM_SPI_MODE): am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM2_SCK, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM2_MISO, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM2_MOSI, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM2_CS, g_AM_HAL_GPIO_DISABLE); break; case ((3 << 2) | AM_HAL_IOM_SPI_MODE): am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM3_SCK, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM3_MISO, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM3_MOSI, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM3_CS, g_AM_HAL_GPIO_DISABLE); break; case ((4 << 2) | AM_HAL_IOM_SPI_MODE): am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM4_SCK, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM4_MISO, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM4_MOSI, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM4_CS, g_AM_HAL_GPIO_DISABLE); break; case ((5 << 2) | AM_HAL_IOM_SPI_MODE): am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM5_SCK, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM5_MISO, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM5_MOSI, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM5_CS, g_AM_HAL_GPIO_DISABLE); break; case ((0 << 2) | AM_HAL_IOM_I2C_MODE): am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM0_SCL, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM0_SDA, g_AM_HAL_GPIO_DISABLE); break; case ((1 << 2) | AM_HAL_IOM_I2C_MODE): am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM1_SCL, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM1_SDA, g_AM_HAL_GPIO_DISABLE); break; case ((2 << 2) | AM_HAL_IOM_I2C_MODE): am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM2_SCL, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM2_SDA, g_AM_HAL_GPIO_DISABLE); break; case ((3 << 2) | AM_HAL_IOM_I2C_MODE): am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM3_SCL, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM3_SDA, g_AM_HAL_GPIO_DISABLE); break; case ((4 << 2) | AM_HAL_IOM_I2C_MODE): am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM4_SCL, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM4_SDA, g_AM_HAL_GPIO_DISABLE); break; case ((5 << 2) | AM_HAL_IOM_I2C_MODE): am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM5_SCL, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOM5_SDA, g_AM_HAL_GPIO_DISABLE); break; default: break; } } // am_bsp_iom_pins_disable() //***************************************************************************** // //! @brief Set up the MSPI pins based on the external flash device type. //! //! This function configures up to 10-pins for MSPI serial, dual, quad, //! dual-quad, and octal operation. //! //! @return None. // //***************************************************************************** void am_bsp_mspi_pins_enable(am_hal_mspi_device_e eMSPIDevice) { switch ( eMSPIDevice ) { case AM_HAL_MSPI_FLASH_SERIAL_CE0: am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_CE0, g_AM_BSP_GPIO_MSPI_CE0); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D0, g_AM_BSP_GPIO_MSPI_D0); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D1, g_AM_BSP_GPIO_MSPI_D1); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_SCK, g_AM_BSP_GPIO_MSPI_SCK); break; case AM_HAL_MSPI_FLASH_SERIAL_CE1: am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_CE1, g_AM_BSP_GPIO_MSPI_CE1); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D4, g_AM_BSP_GPIO_MSPI_D4); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D5, g_AM_BSP_GPIO_MSPI_D5); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_SCK, g_AM_BSP_GPIO_MSPI_SCK); break; case AM_HAL_MSPI_FLASH_DUAL_CE0: am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_CE0, g_AM_BSP_GPIO_MSPI_CE0); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D0, g_AM_BSP_GPIO_MSPI_D0); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D1, g_AM_BSP_GPIO_MSPI_D1); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_SCK, g_AM_BSP_GPIO_MSPI_SCK); break; case AM_HAL_MSPI_FLASH_DUAL_CE1: am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_CE1, g_AM_BSP_GPIO_MSPI_CE1); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D4, g_AM_BSP_GPIO_MSPI_D4); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D5, g_AM_BSP_GPIO_MSPI_D5); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_SCK, g_AM_BSP_GPIO_MSPI_SCK); break; case AM_HAL_MSPI_FLASH_QUAD_CE0: am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_CE0, g_AM_BSP_GPIO_MSPI_CE0); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D0, g_AM_BSP_GPIO_MSPI_D0); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D1, g_AM_BSP_GPIO_MSPI_D1); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D2, g_AM_BSP_GPIO_MSPI_D2); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D3, g_AM_BSP_GPIO_MSPI_D3); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_SCK, g_AM_BSP_GPIO_MSPI_SCK); break; case AM_HAL_MSPI_FLASH_QUAD_CE1: am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_CE1, g_AM_BSP_GPIO_MSPI_CE1); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D4, g_AM_BSP_GPIO_MSPI_D4); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D5, g_AM_BSP_GPIO_MSPI_D5); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D6, g_AM_BSP_GPIO_MSPI_D6); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D7, g_AM_BSP_GPIO_MSPI_D7); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_SCK, g_AM_BSP_GPIO_MSPI_SCK); break; case AM_HAL_MSPI_FLASH_OCTAL_CE0: am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_CE0, g_AM_BSP_GPIO_MSPI_CE0); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D0, g_AM_BSP_GPIO_MSPI_D0); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D1, g_AM_BSP_GPIO_MSPI_D1); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D2, g_AM_BSP_GPIO_MSPI_D2); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D3, g_AM_BSP_GPIO_MSPI_D3); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D4, g_AM_BSP_GPIO_MSPI_D4); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D5, g_AM_BSP_GPIO_MSPI_D5); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D6, g_AM_BSP_GPIO_MSPI_D6); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D7, g_AM_BSP_GPIO_MSPI_D7); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_SCK, g_AM_BSP_GPIO_MSPI_SCK); break; case AM_HAL_MSPI_FLASH_OCTAL_CE1: am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_CE1, g_AM_BSP_GPIO_MSPI_CE1); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D0, g_AM_BSP_GPIO_MSPI_D0); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D1, g_AM_BSP_GPIO_MSPI_D1); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D2, g_AM_BSP_GPIO_MSPI_D2); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D3, g_AM_BSP_GPIO_MSPI_D3); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D4, g_AM_BSP_GPIO_MSPI_D4); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D5, g_AM_BSP_GPIO_MSPI_D5); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D6, g_AM_BSP_GPIO_MSPI_D6); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D7, g_AM_BSP_GPIO_MSPI_D7); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_SCK, g_AM_BSP_GPIO_MSPI_SCK); break; case AM_HAL_MSPI_FLASH_QUADPAIRED: case AM_HAL_MSPI_FLASH_QUADPAIRED_SERIAL: am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_CE0, g_AM_BSP_GPIO_MSPI_CE0); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_CE1, g_AM_BSP_GPIO_MSPI_CE1); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D0, g_AM_BSP_GPIO_MSPI_D0); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D1, g_AM_BSP_GPIO_MSPI_D1); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D2, g_AM_BSP_GPIO_MSPI_D2); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D3, g_AM_BSP_GPIO_MSPI_D3); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D4, g_AM_BSP_GPIO_MSPI_D4); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D5, g_AM_BSP_GPIO_MSPI_D5); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D6, g_AM_BSP_GPIO_MSPI_D6); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D7, g_AM_BSP_GPIO_MSPI_D7); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_SCK, g_AM_BSP_GPIO_MSPI_SCK); break; } } // am_bsp_mspi_pins_enable() //***************************************************************************** // //! @brief Disable the MSPI pins based on the external flash device type. //! //! This function configures up to 10-pins for MSPI serial, dual, quad, //! dual-quad, and octal operation. //! //! @return None. // //***************************************************************************** void am_bsp_mspi_pins_disable(am_hal_mspi_device_e eMSPIDevice) { switch ( eMSPIDevice ) { case AM_HAL_MSPI_FLASH_SERIAL_CE0: am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_CE0, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D0, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D1, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_SCK, g_AM_HAL_GPIO_DISABLE); break; case AM_HAL_MSPI_FLASH_SERIAL_CE1: am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_CE1, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D4, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D5, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_SCK, g_AM_HAL_GPIO_DISABLE); break; case AM_HAL_MSPI_FLASH_DUAL_CE0: am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_CE0, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D0, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D1, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_SCK, g_AM_HAL_GPIO_DISABLE); break; case AM_HAL_MSPI_FLASH_DUAL_CE1: am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_CE1, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D4, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D5, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_SCK, g_AM_HAL_GPIO_DISABLE); break; case AM_HAL_MSPI_FLASH_QUAD_CE0: am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_CE0, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D0, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D1, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D2, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D3, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_SCK, g_AM_HAL_GPIO_DISABLE); break; case AM_HAL_MSPI_FLASH_QUAD_CE1: am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_CE1, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D4, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D5, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D6, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D7, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_SCK, g_AM_HAL_GPIO_DISABLE); break; case AM_HAL_MSPI_FLASH_OCTAL_CE0: am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_CE0, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D0, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D1, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D2, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D3, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D4, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D5, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D6, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D7, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_SCK, g_AM_HAL_GPIO_DISABLE); break; case AM_HAL_MSPI_FLASH_OCTAL_CE1: am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_CE1, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D0, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D1, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D2, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D3, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D4, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D5, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D6, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D7, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_SCK, g_AM_HAL_GPIO_DISABLE); break; case AM_HAL_MSPI_FLASH_QUADPAIRED: case AM_HAL_MSPI_FLASH_QUADPAIRED_SERIAL: am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_CE0, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_CE1, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D0, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D1, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D2, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D3, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D4, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D5, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D6, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_D7, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_MSPI_SCK, g_AM_HAL_GPIO_DISABLE); break; } } // am_bsp_mspi_pins_disable() //***************************************************************************** // //! @brief Set up the IOS pins based on mode and module. //! //! @return None. // //***************************************************************************** void am_bsp_ios_pins_enable(uint32_t ui32Module, uint32_t ui32IOSMode) { uint32_t ui32Combined; // // Validate parameters // if ( ui32Module >= AM_REG_IOSLAVE_NUM_MODULES ) { return; } ui32Combined = ((ui32Module << 2) | ui32IOSMode); switch ( ui32Combined ) { case ((0 << 2) | AM_HAL_IOS_USE_SPI): am_hal_gpio_pinconfig(AM_BSP_GPIO_IOS_SCK, g_AM_BSP_GPIO_IOS_SCK); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOS_MISO, g_AM_BSP_GPIO_IOS_MISO); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOS_MOSI, g_AM_BSP_GPIO_IOS_MOSI); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOS_CE, g_AM_BSP_GPIO_IOS_CE); break; case ((0 << 2) | AM_HAL_IOS_USE_I2C): am_hal_gpio_pinconfig(AM_BSP_GPIO_IOS_SCL, g_AM_BSP_GPIO_IOS_SCL); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOS_SDA, g_AM_BSP_GPIO_IOS_SDA); break; default: break; } } // am_bsp_ios_pins_enable() //***************************************************************************** // //! @brief Disable the IOS pins based on mode and module. //! //! @return None. // //***************************************************************************** void am_bsp_ios_pins_disable(uint32_t ui32Module, uint32_t ui32IOSMode) { uint32_t ui32Combined; // // Validate parameters // if ( ui32Module >= AM_REG_IOSLAVE_NUM_MODULES ) { return; } ui32Combined = ((ui32Module << 2) | ui32IOSMode); switch ( ui32Combined ) { case ((0 << 2) | AM_HAL_IOS_USE_SPI): am_hal_gpio_pinconfig(AM_BSP_GPIO_IOS_SCK, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOS_MISO, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOS_MOSI, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOS_CE, g_AM_HAL_GPIO_DISABLE); break; case ((0 << 2) | AM_HAL_IOS_USE_I2C): am_hal_gpio_pinconfig(AM_BSP_GPIO_IOS_SCL, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_IOS_SDA, g_AM_HAL_GPIO_DISABLE); break; default: break; } } // am_bsp_ios_pins_disable() //***************************************************************************** // //! @brief UART-based string print function. //! //! This function is used for printing a string via the UART, which for some //! MCU devices may be multi-module. //! //! @return None. // //***************************************************************************** void am_bsp_uart_string_print(char *pcString) { uint32_t ui32StrLen = 0; uint32_t ui32BytesWritten = 0; // // Measure the length of the string. // while (pcString[ui32StrLen] != 0) { ui32StrLen++; } // // Print the string via the UART. // const am_hal_uart_transfer_t sUartWrite = { .ui32Direction = AM_HAL_UART_WRITE, .pui8Data = (uint8_t *) pcString, .ui32NumBytes = ui32StrLen, .ui32TimeoutMs = AM_HAL_UART_WAIT_FOREVER, .pui32BytesTransferred = &ui32BytesWritten, }; am_hal_uart_transfer(g_sCOMUART, &sUartWrite); if (ui32BytesWritten != ui32StrLen) { // // Couldn't send the whole string!! // while(1); } } // am_bsp_uart_string_print() //***************************************************************************** // // Pass-through function to let applications access the COM UART. // //***************************************************************************** uint32_t am_bsp_com_uart_transfer(const am_hal_uart_transfer_t *psTransfer) { return am_hal_uart_transfer(g_sCOMUART, psTransfer); } // am_bsp_com_uart_transfer() //***************************************************************************** // // Initialize and configure the UART // //***************************************************************************** void am_bsp_uart_printf_enable(void) { // // Save the information that we're using the UART for printing. // g_ui32PrintInterface = AM_BSP_PRINT_INFC_UART0; // // Initialize, power up, and configure the communication UART. Use the // custom configuration if it was provided. Otherwise, just use the default // configuration. // am_hal_uart_initialize(AM_BSP_UART_PRINT_INST, &g_sCOMUART); am_hal_uart_power_control(g_sCOMUART, AM_HAL_SYSCTRL_WAKE, false); am_hal_uart_configure(g_sCOMUART, &g_sBspUartConfig); // // Enable the UART pins. // am_hal_gpio_pinconfig(AM_BSP_GPIO_COM_UART_TX, g_AM_BSP_GPIO_COM_UART_TX); am_hal_gpio_pinconfig(AM_BSP_GPIO_COM_UART_RX, g_AM_BSP_GPIO_COM_UART_RX); // // Register the BSP print function to the STDIO driver. // am_util_stdio_printf_init(am_bsp_uart_string_print); } // am_bsp_uart_printf_enable() //***************************************************************************** // // Initialize and configure the UART with a custom configuration // //***************************************************************************** void am_bsp_uart_printf_enable_custom(const am_hal_uart_config_t* p_config) { // // Save the information that we're using the UART for printing. // g_ui32PrintInterface = AM_BSP_PRINT_INFC_UART0; // // Initialize, power up, and configure the communication UART. Use the // custom configuration if it was provided. Otherwise, just use the default // configuration. // am_hal_uart_initialize(AM_BSP_UART_PRINT_INST, &g_sCOMUART); am_hal_uart_power_control(g_sCOMUART, AM_HAL_SYSCTRL_WAKE, false); am_hal_uart_configure(g_sCOMUART, p_config); // // Enable the UART pins. // am_hal_gpio_pinconfig(AM_BSP_GPIO_COM_UART_TX, g_AM_BSP_GPIO_COM_UART_TX); am_hal_gpio_pinconfig(AM_BSP_GPIO_COM_UART_RX, g_AM_BSP_GPIO_COM_UART_RX); // // Register the BSP print function to the STDIO driver. // am_util_stdio_printf_init(am_bsp_uart_string_print); } // am_bsp_uart_printf_enable() //***************************************************************************** // // Disable the UART // //***************************************************************************** void am_bsp_uart_printf_disable(void) { // // Make sure the UART has finished sending everything it's going to send. // am_hal_uart_tx_flush(g_sCOMUART); // // Detach the UART from the stdio driver. // am_util_stdio_printf_init(0); // // Power down the UART, and surrender the handle. // am_hal_uart_power_control(g_sCOMUART, AM_HAL_SYSCTRL_DEEPSLEEP, false); am_hal_uart_deinitialize(g_sCOMUART); // // Disable the UART pins. // am_hal_gpio_pinconfig(AM_BSP_GPIO_COM_UART_TX, g_AM_HAL_GPIO_DISABLE); am_hal_gpio_pinconfig(AM_BSP_GPIO_COM_UART_RX, g_AM_HAL_GPIO_DISABLE); } // am_bsp_uart_printf_disable() #ifndef AM_BSP_DISABLE_BUFFERED_UART //***************************************************************************** // // Initialize and configure the UART // //***************************************************************************** void am_bsp_buffered_uart_printf_enable(void) { // // Save the information that we're using the UART for printing. // g_ui32PrintInterface = AM_BSP_PRINT_INFC_UART0; // // Initialize, power up, and configure the communication UART. Use the // custom configuration if it was provided. Otherwise, just use the default // configuration. // am_hal_uart_initialize(AM_BSP_UART_PRINT_INST, &g_sCOMUART); am_hal_uart_power_control(g_sCOMUART, AM_HAL_SYSCTRL_WAKE, false); am_hal_uart_configure(g_sCOMUART, &g_sBspUartBufferedConfig); // // Enable the UART pins. // am_hal_gpio_pinconfig(AM_BSP_GPIO_COM_UART_TX, g_AM_BSP_GPIO_COM_UART_TX); am_hal_gpio_pinconfig(AM_BSP_GPIO_COM_UART_RX, g_AM_BSP_GPIO_COM_UART_RX); // // Register the BSP print function to the STDIO driver. // am_util_stdio_printf_init(am_bsp_uart_string_print); // // Enable the interrupts for the UART. // NVIC_EnableIRQ((IRQn_Type)(UART0_IRQn + AM_BSP_UART_PRINT_INST)); } // am_bsp_buffered_uart_printf_enable() //***************************************************************************** // // Interrupt routine for the buffered UART interface. // //***************************************************************************** void am_bsp_buffered_uart_service(void) { uint32_t ui32Status, ui32Idle; am_hal_uart_interrupt_status_get(g_sCOMUART, &ui32Status, true); am_hal_uart_interrupt_clear(g_sCOMUART, ui32Status); am_hal_uart_interrupt_service(g_sCOMUART, ui32Status, &ui32Idle); } // am_bsp_buffered_uart_service() #endif // AM_BSP_DISABLE_BUFFERED_UART //***************************************************************************** // // End Doxygen group. //! @} // //*****************************************************************************