/**************************************************************************//** * @file spi.c * @version V3.00 * @brief M480 series SPI driver source file * * SPDX-License-Identifier: Apache-2.0 * @copyright (C) 2016-2020 Nuvoton Technology Corp. All rights reserved. *****************************************************************************/ #include "NuMicro.h" /** @addtogroup Standard_Driver Standard Driver @{ */ /** @addtogroup SPI_Driver SPI Driver @{ */ /** @addtogroup SPI_EXPORTED_FUNCTIONS SPI Exported Functions @{ */ static uint32_t SPII2S_GetSourceClockFreq(SPI_T *i2s); /** * @brief This function make SPI module be ready to transfer. * @param[in] spi The pointer of the specified SPI module. * @param[in] u32MasterSlave Decides the SPI module is operating in master mode or in slave mode. (SPI_SLAVE, SPI_MASTER) * @param[in] u32SPIMode Decides the transfer timing. (SPI_MODE_0, SPI_MODE_1, SPI_MODE_2, SPI_MODE_3) * @param[in] u32DataWidth Decides the data width of a SPI transaction. * @param[in] u32BusClock The expected frequency of SPI bus clock in Hz. * @return Actual frequency of SPI peripheral clock. * @details By default, the SPI transfer sequence is MSB first, the slave selection signal is active low and the automatic * slave selection function is disabled. * In Slave mode, the u32BusClock shall be NULL and the SPI clock divider setting will be 0. * The actual clock rate may be different from the target SPI clock rate. * For example, if the SPI source clock rate is 12 MHz and the target SPI bus clock rate is 7 MHz, the * actual SPI clock rate will be 6MHz. * @note If u32BusClock = 0, DIVIDER setting will be set to the maximum value. * @note If u32BusClock >= system clock frequency, SPI peripheral clock source will be set to APB clock and DIVIDER will be set to 0. * @note If u32BusClock >= SPI peripheral clock source, DIVIDER will be set to 0. * @note In slave mode, the SPI peripheral clock rate will be equal to APB clock rate. */ uint32_t SPI_Open(SPI_T *spi, uint32_t u32MasterSlave, uint32_t u32SPIMode, uint32_t u32DataWidth, uint32_t u32BusClock) { uint32_t u32ClkSrc = 0U, u32Div, u32HCLKFreq, u32RetValue=0U; /* Disable I2S mode */ spi->I2SCTL &= ~SPI_I2SCTL_I2SEN_Msk; if(u32DataWidth == 32U) { u32DataWidth = 0U; } /* Get system clock frequency */ u32HCLKFreq = CLK_GetHCLKFreq(); if(u32MasterSlave == SPI_MASTER) { /* Default setting: slave selection signal is active low; disable automatic slave selection function. */ spi->SSCTL = SPI_SS_ACTIVE_LOW; /* Default setting: MSB first, disable unit transfer interrupt, SP_CYCLE = 0. */ spi->CTL = u32MasterSlave | (u32DataWidth << SPI_CTL_DWIDTH_Pos) | (u32SPIMode) | SPI_CTL_SPIEN_Msk; if(u32BusClock >= u32HCLKFreq) { /* Select PCLK as the clock source of SPI */ if(spi == SPI0) { CLK->CLKSEL2 = (CLK->CLKSEL2 & (~CLK_CLKSEL2_SPI0SEL_Msk)) | CLK_CLKSEL2_SPI0SEL_PCLK1; } else if(spi == SPI1) { CLK->CLKSEL2 = (CLK->CLKSEL2 & (~CLK_CLKSEL2_SPI1SEL_Msk)) | CLK_CLKSEL2_SPI1SEL_PCLK0; } else if(spi == SPI2) { CLK->CLKSEL2 = (CLK->CLKSEL2 & (~CLK_CLKSEL2_SPI2SEL_Msk)) | CLK_CLKSEL2_SPI2SEL_PCLK1; } else { CLK->CLKSEL2 = (CLK->CLKSEL2 & (~CLK_CLKSEL2_SPI3SEL_Msk)) | CLK_CLKSEL2_SPI3SEL_PCLK0; } } /* Check clock source of SPI */ if(spi == SPI0) { if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI0SEL_Msk) == CLK_CLKSEL2_SPI0SEL_HXT) { u32ClkSrc = __HXT; /* Clock source is HXT */ } else if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI0SEL_Msk) == CLK_CLKSEL2_SPI0SEL_PLL) { u32ClkSrc = CLK_GetPLLClockFreq(); /* Clock source is PLL */ } else if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI0SEL_Msk) == CLK_CLKSEL2_SPI0SEL_PCLK1) { /* Clock source is PCLK1 */ u32ClkSrc = CLK_GetPCLK1Freq(); } else { u32ClkSrc = __HIRC; /* Clock source is HIRC */ } } else if(spi == SPI1) { if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI1SEL_Msk) == CLK_CLKSEL2_SPI1SEL_HXT) { u32ClkSrc = __HXT; /* Clock source is HXT */ } else if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI1SEL_Msk) == CLK_CLKSEL2_SPI1SEL_PLL) { u32ClkSrc = CLK_GetPLLClockFreq(); /* Clock source is PLL */ } else if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI1SEL_Msk) == CLK_CLKSEL2_SPI1SEL_PCLK0) { /* Clock source is PCLK0 */ u32ClkSrc = CLK_GetPCLK0Freq(); } else { u32ClkSrc = __HIRC; /* Clock source is HIRC */ } } else if(spi == SPI2) { if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI2SEL_Msk) == CLK_CLKSEL2_SPI2SEL_HXT) { u32ClkSrc = __HXT; /* Clock source is HXT */ } else if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI2SEL_Msk) == CLK_CLKSEL2_SPI2SEL_PLL) { u32ClkSrc = CLK_GetPLLClockFreq(); /* Clock source is PLL */ } else if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI2SEL_Msk) == CLK_CLKSEL2_SPI2SEL_PCLK1) { u32ClkSrc = CLK_GetPCLK1Freq(); } else { u32ClkSrc = __HIRC; /* Clock source is HIRC */ } } else { if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI3SEL_Msk) == CLK_CLKSEL2_SPI3SEL_HXT) { u32ClkSrc = __HXT; /* Clock source is HXT */ } else if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI3SEL_Msk) == CLK_CLKSEL2_SPI3SEL_PLL) { u32ClkSrc = CLK_GetPLLClockFreq(); /* Clock source is PLL */ } else if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI3SEL_Msk) == CLK_CLKSEL2_SPI3SEL_PCLK0) { /* Clock source is PCLK0 */ u32ClkSrc = CLK_GetPCLK0Freq(); } else { u32ClkSrc = __HIRC; /* Clock source is HIRC */ } } if(u32BusClock >= u32HCLKFreq) { /* Set DIVIDER = 0 */ spi->CLKDIV = 0U; /* Return master peripheral clock rate */ u32RetValue = u32ClkSrc; } else if(u32BusClock >= u32ClkSrc) { /* Set DIVIDER = 0 */ spi->CLKDIV = 0U; /* Return master peripheral clock rate */ u32RetValue = u32ClkSrc; } else if(u32BusClock == 0U) { /* Set DIVIDER to the maximum value 0xFF. f_spi = f_spi_clk_src / (DIVIDER + 1) */ spi->CLKDIV |= SPI_CLKDIV_DIVIDER_Msk; /* Return master peripheral clock rate */ u32RetValue = (u32ClkSrc / (0xFFU + 1U)); } else { u32Div = (((u32ClkSrc * 10U) / u32BusClock + 5U) / 10U) - 1U; /* Round to the nearest integer */ if(u32Div > 0xFFU) { u32Div = 0xFFU; spi->CLKDIV |= SPI_CLKDIV_DIVIDER_Msk; /* Return master peripheral clock rate */ u32RetValue = (u32ClkSrc / (0xFFU + 1U)); } else { spi->CLKDIV = (spi->CLKDIV & (~SPI_CLKDIV_DIVIDER_Msk)) | (u32Div << SPI_CLKDIV_DIVIDER_Pos); /* Return master peripheral clock rate */ u32RetValue = (u32ClkSrc / (u32Div + 1U)); } } } else /* For slave mode, force the SPI peripheral clock rate to equal APB clock rate. */ { /* Default setting: slave selection signal is low level active. */ spi->SSCTL = SPI_SS_ACTIVE_LOW; /* Default setting: MSB first, disable unit transfer interrupt, SP_CYCLE = 0. */ spi->CTL = u32MasterSlave | (u32DataWidth << SPI_CTL_DWIDTH_Pos) | (u32SPIMode) | SPI_CTL_SPIEN_Msk; /* Set DIVIDER = 0 */ spi->CLKDIV = 0U; /* Select PCLK as the clock source of SPI */ if(spi == SPI0) { CLK->CLKSEL2 = (CLK->CLKSEL2 & (~CLK_CLKSEL2_SPI0SEL_Msk)) | CLK_CLKSEL2_SPI0SEL_PCLK1; /* Return slave peripheral clock rate */ u32RetValue = CLK_GetPCLK1Freq(); } else if(spi == SPI1) { CLK->CLKSEL2 = (CLK->CLKSEL2 & (~CLK_CLKSEL2_SPI1SEL_Msk)) | CLK_CLKSEL2_SPI1SEL_PCLK0; /* Return slave peripheral clock rate */ u32RetValue = CLK_GetPCLK0Freq(); } else if(spi == SPI2) { CLK->CLKSEL2 = (CLK->CLKSEL2 & (~CLK_CLKSEL2_SPI2SEL_Msk)) | CLK_CLKSEL2_SPI2SEL_PCLK1; /* Return slave peripheral clock rate */ u32RetValue = CLK_GetPCLK1Freq(); } else { CLK->CLKSEL2 = (CLK->CLKSEL2 & (~CLK_CLKSEL2_SPI3SEL_Msk)) | CLK_CLKSEL2_SPI3SEL_PCLK0; /* Return slave peripheral clock rate */ u32RetValue = CLK_GetPCLK0Freq(); } } return u32RetValue; } /** * @brief Disable SPI controller. * @param[in] spi The pointer of the specified SPI module. * @return None * @details This function will reset SPI controller. */ void SPI_Close(SPI_T *spi) { if(spi == SPI0) { /* Reset SPI */ SYS->IPRST1 |= SYS_IPRST1_SPI0RST_Msk; SYS->IPRST1 &= ~SYS_IPRST1_SPI0RST_Msk; } else if(spi == SPI1) { /* Reset SPI */ SYS->IPRST1 |= SYS_IPRST1_SPI1RST_Msk; SYS->IPRST1 &= ~SYS_IPRST1_SPI1RST_Msk; } else if(spi == SPI2) { /* Reset SPI */ SYS->IPRST1 |= SYS_IPRST1_SPI2RST_Msk; SYS->IPRST1 &= ~SYS_IPRST1_SPI2RST_Msk; } else { /* Reset SPI */ SYS->IPRST2 |= SYS_IPRST2_SPI3RST_Msk; SYS->IPRST2 &= ~SYS_IPRST2_SPI3RST_Msk; } } /** * @brief Clear RX FIFO buffer. * @param[in] spi The pointer of the specified SPI module. * @return None * @details This function will clear SPI RX FIFO buffer. The RXEMPTY (SPI_STATUS[8]) will be set to 1. */ void SPI_ClearRxFIFO(SPI_T *spi) { spi->FIFOCTL |= SPI_FIFOCTL_RXFBCLR_Msk; } /** * @brief Clear TX FIFO buffer. * @param[in] spi The pointer of the specified SPI module. * @return None * @details This function will clear SPI TX FIFO buffer. The TXEMPTY (SPI_STATUS[16]) will be set to 1. * @note The TX shift register will not be cleared. */ void SPI_ClearTxFIFO(SPI_T *spi) { spi->FIFOCTL |= SPI_FIFOCTL_TXFBCLR_Msk; } /** * @brief Disable the automatic slave selection function. * @param[in] spi The pointer of the specified SPI module. * @return None * @details This function will disable the automatic slave selection function and set slave selection signal to inactive state. */ void SPI_DisableAutoSS(SPI_T *spi) { spi->SSCTL &= ~(SPI_SSCTL_AUTOSS_Msk | SPI_SSCTL_SS_Msk); } /** * @brief Enable the automatic slave selection function. * @param[in] spi The pointer of the specified SPI module. * @param[in] u32SSPinMask Specifies slave selection pins. (SPI_SS) * @param[in] u32ActiveLevel Specifies the active level of slave selection signal. (SPI_SS_ACTIVE_HIGH, SPI_SS_ACTIVE_LOW) * @return None * @details This function will enable the automatic slave selection function. Only available in Master mode. * The slave selection pin and the active level will be set in this function. */ void SPI_EnableAutoSS(SPI_T *spi, uint32_t u32SSPinMask, uint32_t u32ActiveLevel) { spi->SSCTL = (spi->SSCTL & (~(SPI_SSCTL_AUTOSS_Msk | SPI_SSCTL_SSACTPOL_Msk | SPI_SSCTL_SS_Msk))) | (u32SSPinMask | u32ActiveLevel | SPI_SSCTL_AUTOSS_Msk); } /** * @brief Set the SPI bus clock. * @param[in] spi The pointer of the specified SPI module. * @param[in] u32BusClock The expected frequency of SPI bus clock in Hz. * @return Actual frequency of SPI bus clock. * @details This function is only available in Master mode. The actual clock rate may be different from the target SPI bus clock rate. * For example, if the SPI source clock rate is 12 MHz and the target SPI bus clock rate is 7 MHz, the actual SPI bus clock * rate will be 6 MHz. * @note If u32BusClock = 0, DIVIDER setting will be set to the maximum value. * @note If u32BusClock >= system clock frequency, SPI peripheral clock source will be set to APB clock and DIVIDER will be set to 0. * @note If u32BusClock >= SPI peripheral clock source, DIVIDER will be set to 0. */ uint32_t SPI_SetBusClock(SPI_T *spi, uint32_t u32BusClock) { uint32_t u32ClkSrc, u32HCLKFreq; uint32_t u32Div, u32RetValue; /* Get system clock frequency */ u32HCLKFreq = CLK_GetHCLKFreq(); if(u32BusClock >= u32HCLKFreq) { /* Select PCLK as the clock source of SPI */ if(spi == SPI0) CLK->CLKSEL2 = (CLK->CLKSEL2 & (~CLK_CLKSEL2_SPI0SEL_Msk)) | CLK_CLKSEL2_SPI0SEL_PCLK1; else if(spi == SPI1) CLK->CLKSEL2 = (CLK->CLKSEL2 & (~CLK_CLKSEL2_SPI1SEL_Msk)) | CLK_CLKSEL2_SPI1SEL_PCLK0; else if(spi == SPI2) CLK->CLKSEL2 = (CLK->CLKSEL2 & (~CLK_CLKSEL2_SPI2SEL_Msk)) | CLK_CLKSEL2_SPI2SEL_PCLK1; else CLK->CLKSEL2 = (CLK->CLKSEL2 & (~CLK_CLKSEL2_SPI3SEL_Msk)) | CLK_CLKSEL2_SPI3SEL_PCLK0; } /* Check clock source of SPI */ if(spi == SPI0) { if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI0SEL_Msk) == CLK_CLKSEL2_SPI0SEL_HXT) { u32ClkSrc = __HXT; /* Clock source is HXT */ } else if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI0SEL_Msk) == CLK_CLKSEL2_SPI0SEL_PLL) { u32ClkSrc = CLK_GetPLLClockFreq(); /* Clock source is PLL */ } else if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI0SEL_Msk) == CLK_CLKSEL2_SPI0SEL_PCLK1) { /* Clock source is PCLK1 */ u32ClkSrc = CLK_GetPCLK1Freq(); } else { u32ClkSrc = __HIRC; /* Clock source is HIRC */ } } else if(spi == SPI1) { if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI1SEL_Msk) == CLK_CLKSEL2_SPI1SEL_HXT) { u32ClkSrc = __HXT; /* Clock source is HXT */ } else if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI1SEL_Msk) == CLK_CLKSEL2_SPI1SEL_PLL) { u32ClkSrc = CLK_GetPLLClockFreq(); /* Clock source is PLL */ } else if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI1SEL_Msk) == CLK_CLKSEL2_SPI1SEL_PCLK0) { /* Clock source is PCLK0 */ u32ClkSrc = CLK_GetPCLK0Freq(); } else { u32ClkSrc = __HIRC; /* Clock source is HIRC */ } } else if(spi == SPI2) { if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI2SEL_Msk) == CLK_CLKSEL2_SPI2SEL_HXT) { u32ClkSrc = __HXT; /* Clock source is HXT */ } else if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI2SEL_Msk) == CLK_CLKSEL2_SPI2SEL_PLL) { u32ClkSrc = CLK_GetPLLClockFreq(); /* Clock source is PLL */ } else if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI2SEL_Msk) == CLK_CLKSEL2_SPI2SEL_PCLK1) { /* Clock source is PCLK1 */ u32ClkSrc = CLK_GetPCLK1Freq(); } else { u32ClkSrc = __HIRC; /* Clock source is HIRC */ } } else { if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI3SEL_Msk) == CLK_CLKSEL2_SPI3SEL_HXT) { u32ClkSrc = __HXT; /* Clock source is HXT */ } else if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI3SEL_Msk) == CLK_CLKSEL2_SPI3SEL_PLL) { u32ClkSrc = CLK_GetPLLClockFreq(); /* Clock source is PLL */ } else if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI3SEL_Msk) == CLK_CLKSEL2_SPI3SEL_PCLK0) { /* Clock source is PCLK0 */ u32ClkSrc = CLK_GetPCLK0Freq(); } else { u32ClkSrc = __HIRC; /* Clock source is HIRC */ } } if(u32BusClock >= u32HCLKFreq) { /* Set DIVIDER = 0 */ spi->CLKDIV = 0U; /* Return master peripheral clock rate */ u32RetValue = u32ClkSrc; } else if(u32BusClock >= u32ClkSrc) { /* Set DIVIDER = 0 */ spi->CLKDIV = 0U; /* Return master peripheral clock rate */ u32RetValue = u32ClkSrc; } else if(u32BusClock == 0U) { /* Set DIVIDER to the maximum value 0xFF. f_spi = f_spi_clk_src / (DIVIDER + 1) */ spi->CLKDIV |= SPI_CLKDIV_DIVIDER_Msk; /* Return master peripheral clock rate */ u32RetValue = (u32ClkSrc / (0xFFU + 1U)); } else { u32Div = (((u32ClkSrc * 10U) / u32BusClock + 5U) / 10U) - 1U; /* Round to the nearest integer */ if(u32Div > 0x1FFU) { u32Div = 0x1FFU; spi->CLKDIV |= SPI_CLKDIV_DIVIDER_Msk; /* Return master peripheral clock rate */ u32RetValue = (u32ClkSrc / (0xFFU + 1U)); } else { spi->CLKDIV = (spi->CLKDIV & (~SPI_CLKDIV_DIVIDER_Msk)) | (u32Div << SPI_CLKDIV_DIVIDER_Pos); /* Return master peripheral clock rate */ u32RetValue = (u32ClkSrc / (u32Div + 1U)); } } return u32RetValue; } /** * @brief Configure FIFO threshold setting. * @param[in] spi The pointer of the specified SPI module. * @param[in] u32TxThreshold Decides the TX FIFO threshold. It could be 0 ~ 3. If data width is 8~16 bits, it could be 0 ~ 7. * @param[in] u32RxThreshold Decides the RX FIFO threshold. It could be 0 ~ 3. If data width is 8~16 bits, it could be 0 ~ 7. * @return None * @details Set TX FIFO threshold and RX FIFO threshold configurations. */ void SPI_SetFIFO(SPI_T *spi, uint32_t u32TxThreshold, uint32_t u32RxThreshold) { spi->FIFOCTL = (spi->FIFOCTL & ~(SPI_FIFOCTL_TXTH_Msk | SPI_FIFOCTL_RXTH_Msk)) | (u32TxThreshold << SPI_FIFOCTL_TXTH_Pos) | (u32RxThreshold << SPI_FIFOCTL_RXTH_Pos); } /** * @brief Get the actual frequency of SPI bus clock. Only available in Master mode. * @param[in] spi The pointer of the specified SPI module. * @return Actual SPI bus clock frequency in Hz. * @details This function will calculate the actual SPI bus clock rate according to the SPInSEL and DIVIDER settings. Only available in Master mode. */ uint32_t SPI_GetBusClock(SPI_T *spi) { uint32_t u32Div; uint32_t u32ClkSrc; /* Get DIVIDER setting */ u32Div = (spi->CLKDIV & SPI_CLKDIV_DIVIDER_Msk) >> SPI_CLKDIV_DIVIDER_Pos; /* Check clock source of SPI */ if(spi == SPI0) { if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI0SEL_Msk) == CLK_CLKSEL2_SPI0SEL_HXT) { u32ClkSrc = __HXT; /* Clock source is HXT */ } else if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI0SEL_Msk) == CLK_CLKSEL2_SPI0SEL_PLL) { u32ClkSrc = CLK_GetPLLClockFreq(); /* Clock source is PLL */ } else if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI0SEL_Msk) == CLK_CLKSEL2_SPI0SEL_PCLK1) { /* Clock source is PCLK1 */ u32ClkSrc = CLK_GetPCLK1Freq(); } else { u32ClkSrc = __HIRC; /* Clock source is HIRC */ } } else if(spi == SPI1) { if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI1SEL_Msk) == CLK_CLKSEL2_SPI1SEL_HXT) { u32ClkSrc = __HXT; /* Clock source is HXT */ } else if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI1SEL_Msk) == CLK_CLKSEL2_SPI1SEL_PLL) { u32ClkSrc = CLK_GetPLLClockFreq(); /* Clock source is PLL */ } else if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI1SEL_Msk) == CLK_CLKSEL2_SPI1SEL_PCLK0) { /* Clock source is PCLK0 */ u32ClkSrc = CLK_GetPCLK0Freq(); } else { u32ClkSrc = __HIRC; /* Clock source is HIRC */ } } else if(spi == SPI2) { if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI2SEL_Msk) == CLK_CLKSEL2_SPI2SEL_HXT) { u32ClkSrc = __HXT; /* Clock source is HXT */ } else if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI2SEL_Msk) == CLK_CLKSEL2_SPI2SEL_PLL) { u32ClkSrc = CLK_GetPLLClockFreq(); /* Clock source is PLL */ } else if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI2SEL_Msk) == CLK_CLKSEL2_SPI2SEL_PCLK1) { /* Clock source is PCLK1 */ u32ClkSrc = CLK_GetPCLK1Freq(); } else { u32ClkSrc = __HIRC; /* Clock source is HIRC */ } } else { if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI3SEL_Msk) == CLK_CLKSEL2_SPI3SEL_HXT) { u32ClkSrc = __HXT; /* Clock source is HXT */ } else if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI3SEL_Msk) == CLK_CLKSEL2_SPI3SEL_PLL) { u32ClkSrc = CLK_GetPLLClockFreq(); /* Clock source is PLL */ } else if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI3SEL_Msk) == CLK_CLKSEL2_SPI3SEL_PCLK0) { /* Clock source is PCLK0 */ u32ClkSrc = CLK_GetPCLK0Freq(); } else { u32ClkSrc = __HIRC; /* Clock source is HIRC */ } } /* Return SPI bus clock rate */ return (u32ClkSrc / (u32Div + 1U)); } /** * @brief Enable interrupt function. * @param[in] spi The pointer of the specified SPI module. * @param[in] u32Mask The combination of all related interrupt enable bits. * Each bit corresponds to a interrupt enable bit. * This parameter decides which interrupts will be enabled. It is combination of: * - \ref SPI_UNIT_INT_MASK * - \ref SPI_SSACT_INT_MASK * - \ref SPI_SSINACT_INT_MASK * - \ref SPI_SLVUR_INT_MASK * - \ref SPI_SLVBE_INT_MASK * - \ref SPI_TXUF_INT_MASK * - \ref SPI_FIFO_TXTH_INT_MASK * - \ref SPI_FIFO_RXTH_INT_MASK * - \ref SPI_FIFO_RXOV_INT_MASK * - \ref SPI_FIFO_RXTO_INT_MASK * * @return None * @details Enable SPI related interrupts specified by u32Mask parameter. */ void SPI_EnableInt(SPI_T *spi, uint32_t u32Mask) { /* Enable unit transfer interrupt flag */ if((u32Mask & SPI_UNIT_INT_MASK) == SPI_UNIT_INT_MASK) { spi->CTL |= SPI_CTL_UNITIEN_Msk; } /* Enable slave selection signal active interrupt flag */ if((u32Mask & SPI_SSACT_INT_MASK) == SPI_SSACT_INT_MASK) { spi->SSCTL |= SPI_SSCTL_SSACTIEN_Msk; } /* Enable slave selection signal inactive interrupt flag */ if((u32Mask & SPI_SSINACT_INT_MASK) == SPI_SSINACT_INT_MASK) { spi->SSCTL |= SPI_SSCTL_SSINAIEN_Msk; } /* Enable slave TX under run interrupt flag */ if((u32Mask & SPI_SLVUR_INT_MASK) == SPI_SLVUR_INT_MASK) { spi->SSCTL |= SPI_SSCTL_SLVURIEN_Msk; } /* Enable slave bit count error interrupt flag */ if((u32Mask & SPI_SLVBE_INT_MASK) == SPI_SLVBE_INT_MASK) { spi->SSCTL |= SPI_SSCTL_SLVBEIEN_Msk; } /* Enable slave TX underflow interrupt flag */ if((u32Mask & SPI_TXUF_INT_MASK) == SPI_TXUF_INT_MASK) { spi->FIFOCTL |= SPI_FIFOCTL_TXUFIEN_Msk; } /* Enable TX threshold interrupt flag */ if((u32Mask & SPI_FIFO_TXTH_INT_MASK) == SPI_FIFO_TXTH_INT_MASK) { spi->FIFOCTL |= SPI_FIFOCTL_TXTHIEN_Msk; } /* Enable RX threshold interrupt flag */ if((u32Mask & SPI_FIFO_RXTH_INT_MASK) == SPI_FIFO_RXTH_INT_MASK) { spi->FIFOCTL |= SPI_FIFOCTL_RXTHIEN_Msk; } /* Enable RX overrun interrupt flag */ if((u32Mask & SPI_FIFO_RXOV_INT_MASK) == SPI_FIFO_RXOV_INT_MASK) { spi->FIFOCTL |= SPI_FIFOCTL_RXOVIEN_Msk; } /* Enable RX time-out interrupt flag */ if((u32Mask & SPI_FIFO_RXTO_INT_MASK) == SPI_FIFO_RXTO_INT_MASK) { spi->FIFOCTL |= SPI_FIFOCTL_RXTOIEN_Msk; } } /** * @brief Disable interrupt function. * @param[in] spi The pointer of the specified SPI module. * @param[in] u32Mask The combination of all related interrupt enable bits. * Each bit corresponds to a interrupt bit. * This parameter decides which interrupts will be disabled. It is combination of: * - \ref SPI_UNIT_INT_MASK * - \ref SPI_SSACT_INT_MASK * - \ref SPI_SSINACT_INT_MASK * - \ref SPI_SLVUR_INT_MASK * - \ref SPI_SLVBE_INT_MASK * - \ref SPI_TXUF_INT_MASK * - \ref SPI_FIFO_TXTH_INT_MASK * - \ref SPI_FIFO_RXTH_INT_MASK * - \ref SPI_FIFO_RXOV_INT_MASK * - \ref SPI_FIFO_RXTO_INT_MASK * * @return None * @details Disable SPI related interrupts specified by u32Mask parameter. */ void SPI_DisableInt(SPI_T *spi, uint32_t u32Mask) { /* Disable unit transfer interrupt flag */ if((u32Mask & SPI_UNIT_INT_MASK) == SPI_UNIT_INT_MASK) { spi->CTL &= ~SPI_CTL_UNITIEN_Msk; } /* Disable slave selection signal active interrupt flag */ if((u32Mask & SPI_SSACT_INT_MASK) == SPI_SSACT_INT_MASK) { spi->SSCTL &= ~SPI_SSCTL_SSACTIEN_Msk; } /* Disable slave selection signal inactive interrupt flag */ if((u32Mask & SPI_SSINACT_INT_MASK) == SPI_SSINACT_INT_MASK) { spi->SSCTL &= ~SPI_SSCTL_SSINAIEN_Msk; } /* Disable slave TX under run interrupt flag */ if((u32Mask & SPI_SLVUR_INT_MASK) == SPI_SLVUR_INT_MASK) { spi->SSCTL &= ~SPI_SSCTL_SLVURIEN_Msk; } /* Disable slave bit count error interrupt flag */ if((u32Mask & SPI_SLVBE_INT_MASK) == SPI_SLVBE_INT_MASK) { spi->SSCTL &= ~SPI_SSCTL_SLVBEIEN_Msk; } /* Disable slave TX underflow interrupt flag */ if((u32Mask & SPI_TXUF_INT_MASK) == SPI_TXUF_INT_MASK) { spi->FIFOCTL &= ~SPI_FIFOCTL_TXUFIEN_Msk; } /* Disable TX threshold interrupt flag */ if((u32Mask & SPI_FIFO_TXTH_INT_MASK) == SPI_FIFO_TXTH_INT_MASK) { spi->FIFOCTL &= ~SPI_FIFOCTL_TXTHIEN_Msk; } /* Disable RX threshold interrupt flag */ if((u32Mask & SPI_FIFO_RXTH_INT_MASK) == SPI_FIFO_RXTH_INT_MASK) { spi->FIFOCTL &= ~SPI_FIFOCTL_RXTHIEN_Msk; } /* Disable RX overrun interrupt flag */ if((u32Mask & SPI_FIFO_RXOV_INT_MASK) == SPI_FIFO_RXOV_INT_MASK) { spi->FIFOCTL &= ~SPI_FIFOCTL_RXOVIEN_Msk; } /* Disable RX time-out interrupt flag */ if((u32Mask & SPI_FIFO_RXTO_INT_MASK) == SPI_FIFO_RXTO_INT_MASK) { spi->FIFOCTL &= ~SPI_FIFOCTL_RXTOIEN_Msk; } } /** * @brief Get interrupt flag. * @param[in] spi The pointer of the specified SPI module. * @param[in] u32Mask The combination of all related interrupt sources. * Each bit corresponds to a interrupt source. * This parameter decides which interrupt flags will be read. It is combination of: * - \ref SPI_UNIT_INT_MASK * - \ref SPI_SSACT_INT_MASK * - \ref SPI_SSINACT_INT_MASK * - \ref SPI_SLVUR_INT_MASK * - \ref SPI_SLVBE_INT_MASK * - \ref SPI_TXUF_INT_MASK * - \ref SPI_FIFO_TXTH_INT_MASK * - \ref SPI_FIFO_RXTH_INT_MASK * - \ref SPI_FIFO_RXOV_INT_MASK * - \ref SPI_FIFO_RXTO_INT_MASK * * @return Interrupt flags of selected sources. * @details Get SPI related interrupt flags specified by u32Mask parameter. */ uint32_t SPI_GetIntFlag(SPI_T *spi, uint32_t u32Mask) { uint32_t u32IntFlag = 0U, u32TmpVal; u32TmpVal = spi->STATUS & SPI_STATUS_UNITIF_Msk; /* Check unit transfer interrupt flag */ if((u32Mask & SPI_UNIT_INT_MASK) && (u32TmpVal)) { u32IntFlag |= SPI_UNIT_INT_MASK; } u32TmpVal = spi->STATUS & SPI_STATUS_SSACTIF_Msk; /* Check slave selection signal active interrupt flag */ if((u32Mask & SPI_SSACT_INT_MASK) && (u32TmpVal)) { u32IntFlag |= SPI_SSACT_INT_MASK; } u32TmpVal = spi->STATUS & SPI_STATUS_SSINAIF_Msk; /* Check slave selection signal inactive interrupt flag */ if((u32Mask & SPI_SSINACT_INT_MASK) && (u32TmpVal)) { u32IntFlag |= SPI_SSINACT_INT_MASK; } u32TmpVal = spi->STATUS & SPI_STATUS_SLVURIF_Msk; /* Check slave TX under run interrupt flag */ if((u32Mask & SPI_SLVUR_INT_MASK) && (u32TmpVal)) { u32IntFlag |= SPI_SLVUR_INT_MASK; } u32TmpVal = spi->STATUS & SPI_STATUS_SLVBEIF_Msk; /* Check slave bit count error interrupt flag */ if((u32Mask & SPI_SLVBE_INT_MASK) && (u32TmpVal)) { u32IntFlag |= SPI_SLVBE_INT_MASK; } u32TmpVal = spi->STATUS & SPI_STATUS_TXUFIF_Msk; /* Check slave TX underflow interrupt flag */ if((u32Mask & SPI_TXUF_INT_MASK) && (u32TmpVal)) { u32IntFlag |= SPI_TXUF_INT_MASK; } u32TmpVal = spi->STATUS & SPI_STATUS_TXTHIF_Msk; /* Check TX threshold interrupt flag */ if((u32Mask & SPI_FIFO_TXTH_INT_MASK) && (u32TmpVal)) { u32IntFlag |= SPI_FIFO_TXTH_INT_MASK; } u32TmpVal = spi->STATUS & SPI_STATUS_RXTHIF_Msk; /* Check RX threshold interrupt flag */ if((u32Mask & SPI_FIFO_RXTH_INT_MASK) && (u32TmpVal)) { u32IntFlag |= SPI_FIFO_RXTH_INT_MASK; } u32TmpVal = spi->STATUS & SPI_STATUS_RXOVIF_Msk; /* Check RX overrun interrupt flag */ if((u32Mask & SPI_FIFO_RXOV_INT_MASK) && (u32TmpVal)) { u32IntFlag |= SPI_FIFO_RXOV_INT_MASK; } u32TmpVal = spi->STATUS & SPI_STATUS_RXTOIF_Msk; /* Check RX time-out interrupt flag */ if((u32Mask & SPI_FIFO_RXTO_INT_MASK) && (u32TmpVal)) { u32IntFlag |= SPI_FIFO_RXTO_INT_MASK; } return u32IntFlag; } /** * @brief Clear interrupt flag. * @param[in] spi The pointer of the specified SPI module. * @param[in] u32Mask The combination of all related interrupt sources. * Each bit corresponds to a interrupt source. * This parameter decides which interrupt flags will be cleared. It could be the combination of: * - \ref SPI_UNIT_INT_MASK * - \ref SPI_SSACT_INT_MASK * - \ref SPI_SSINACT_INT_MASK * - \ref SPI_SLVUR_INT_MASK * - \ref SPI_SLVBE_INT_MASK * - \ref SPI_TXUF_INT_MASK * - \ref SPI_FIFO_RXOV_INT_MASK * - \ref SPI_FIFO_RXTO_INT_MASK * * @return None * @details Clear SPI related interrupt flags specified by u32Mask parameter. */ void SPI_ClearIntFlag(SPI_T *spi, uint32_t u32Mask) { if(u32Mask & SPI_UNIT_INT_MASK) { spi->STATUS = SPI_STATUS_UNITIF_Msk; /* Clear unit transfer interrupt flag */ } if(u32Mask & SPI_SSACT_INT_MASK) { spi->STATUS = SPI_STATUS_SSACTIF_Msk; /* Clear slave selection signal active interrupt flag */ } if(u32Mask & SPI_SSINACT_INT_MASK) { spi->STATUS = SPI_STATUS_SSINAIF_Msk; /* Clear slave selection signal inactive interrupt flag */ } if(u32Mask & SPI_SLVUR_INT_MASK) { spi->STATUS = SPI_STATUS_SLVURIF_Msk; /* Clear slave TX under run interrupt flag */ } if(u32Mask & SPI_SLVBE_INT_MASK) { spi->STATUS = SPI_STATUS_SLVBEIF_Msk; /* Clear slave bit count error interrupt flag */ } if(u32Mask & SPI_TXUF_INT_MASK) { spi->STATUS = SPI_STATUS_TXUFIF_Msk; /* Clear slave TX underflow interrupt flag */ } if(u32Mask & SPI_FIFO_RXOV_INT_MASK) { spi->STATUS = SPI_STATUS_RXOVIF_Msk; /* Clear RX overrun interrupt flag */ } if(u32Mask & SPI_FIFO_RXTO_INT_MASK) { spi->STATUS = SPI_STATUS_RXTOIF_Msk; /* Clear RX time-out interrupt flag */ } } /** * @brief Get SPI status. * @param[in] spi The pointer of the specified SPI module. * @param[in] u32Mask The combination of all related sources. * Each bit corresponds to a source. * This parameter decides which flags will be read. It is combination of: * - \ref SPI_BUSY_MASK * - \ref SPI_RX_EMPTY_MASK * - \ref SPI_RX_FULL_MASK * - \ref SPI_TX_EMPTY_MASK * - \ref SPI_TX_FULL_MASK * - \ref SPI_TXRX_RESET_MASK * - \ref SPI_SPIEN_STS_MASK * - \ref SPI_SSLINE_STS_MASK * * @return Flags of selected sources. * @details Get SPI related status specified by u32Mask parameter. */ uint32_t SPI_GetStatus(SPI_T *spi, uint32_t u32Mask) { uint32_t u32Flag = 0U, u32TmpValue; u32TmpValue = spi->STATUS & SPI_STATUS_BUSY_Msk; /* Check busy status */ if((u32Mask & SPI_BUSY_MASK) && (u32TmpValue)) { u32Flag |= SPI_BUSY_MASK; } u32TmpValue = spi->STATUS & SPI_STATUS_RXEMPTY_Msk; /* Check RX empty flag */ if((u32Mask & SPI_RX_EMPTY_MASK) && (u32TmpValue)) { u32Flag |= SPI_RX_EMPTY_MASK; } u32TmpValue = spi->STATUS & SPI_STATUS_RXFULL_Msk; /* Check RX full flag */ if((u32Mask & SPI_RX_FULL_MASK) && (u32TmpValue)) { u32Flag |= SPI_RX_FULL_MASK; } u32TmpValue = spi->STATUS & SPI_STATUS_TXEMPTY_Msk; /* Check TX empty flag */ if((u32Mask & SPI_TX_EMPTY_MASK) && (u32TmpValue)) { u32Flag |= SPI_TX_EMPTY_MASK; } u32TmpValue = spi->STATUS & SPI_STATUS_TXFULL_Msk; /* Check TX full flag */ if((u32Mask & SPI_TX_FULL_MASK) && (u32TmpValue)) { u32Flag |= SPI_TX_FULL_MASK; } u32TmpValue = spi->STATUS & SPI_STATUS_TXRXRST_Msk; /* Check TX/RX reset flag */ if((u32Mask & SPI_TXRX_RESET_MASK) && (u32TmpValue)) { u32Flag |= SPI_TXRX_RESET_MASK; } u32TmpValue = spi->STATUS & SPI_STATUS_SPIENSTS_Msk; /* Check SPIEN flag */ if((u32Mask & SPI_SPIEN_STS_MASK) && (u32TmpValue)) { u32Flag |= SPI_SPIEN_STS_MASK; } u32TmpValue = spi->STATUS & SPI_STATUS_SSLINE_Msk; /* Check SPIx_SS line status */ if((u32Mask & SPI_SSLINE_STS_MASK) && (u32TmpValue)) { u32Flag |= SPI_SSLINE_STS_MASK; } return u32Flag; } /** * @brief This function is used to get I2S source clock frequency. * @param[in] i2s The pointer of the specified I2S module. * @return I2S source clock frequency (Hz). * @details Return the source clock frequency according to the setting of SPI0SEL (CLKSEL2[27:26]). */ static uint32_t SPII2S_GetSourceClockFreq(SPI_T *i2s) { uint32_t u32Freq; if(i2s == SPI0) { if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI0SEL_Msk) == CLK_CLKSEL2_SPI0SEL_HXT) { u32Freq = __HXT; /* Clock source is HXT */ } else if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI0SEL_Msk) == CLK_CLKSEL2_SPI0SEL_PLL) { u32Freq = CLK_GetPLLClockFreq(); /* Clock source is PLL */ } else if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI0SEL_Msk) == CLK_CLKSEL2_SPI0SEL_PCLK1) { /* Clock source is PCLK1 */ u32Freq = CLK_GetPCLK1Freq(); } else { u32Freq = __HIRC; /* Clock source is HIRC */ } } else if(i2s == SPI1) { if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI1SEL_Msk) == CLK_CLKSEL2_SPI1SEL_HXT) { u32Freq = __HXT; /* Clock source is HXT */ } else if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI1SEL_Msk) == CLK_CLKSEL2_SPI1SEL_PLL) { u32Freq = CLK_GetPLLClockFreq(); /* Clock source is PLL */ } else if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI1SEL_Msk) == CLK_CLKSEL2_SPI1SEL_PCLK0) { /* Clock source is PCLK0 */ u32Freq = CLK_GetPCLK0Freq(); } else { u32Freq = __HIRC; /* Clock source is HIRC */ } } else if(i2s == SPI2) { if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI2SEL_Msk) == CLK_CLKSEL2_SPI2SEL_HXT) { u32Freq = __HXT; /* Clock source is HXT */ } else if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI2SEL_Msk) == CLK_CLKSEL2_SPI2SEL_PLL) { u32Freq = CLK_GetPLLClockFreq(); /* Clock source is PLL */ } else if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI2SEL_Msk) == CLK_CLKSEL2_SPI2SEL_PCLK1) { /* Clock source is PCLK1 */ u32Freq = CLK_GetPCLK1Freq(); } else { u32Freq = __HIRC; /* Clock source is HIRC */ } } else { if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI3SEL_Msk) == CLK_CLKSEL2_SPI3SEL_HXT) { u32Freq = __HXT; /* Clock source is HXT */ } else if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI3SEL_Msk) == CLK_CLKSEL2_SPI3SEL_PLL) { u32Freq = CLK_GetPLLClockFreq(); /* Clock source is PLL */ } else if((CLK->CLKSEL2 & CLK_CLKSEL2_SPI3SEL_Msk) == CLK_CLKSEL2_SPI3SEL_PCLK0) { /* Clock source is PCLK0 */ u32Freq = CLK_GetPCLK0Freq(); } else { u32Freq = __HIRC; /* Clock source is HIRC */ } } return u32Freq; } /** * @brief This function configures some parameters of I2S interface for general purpose use. * @param[in] i2s The pointer of the specified I2S module. * @param[in] u32MasterSlave I2S operation mode. Valid values are listed below. * - \ref SPII2S_MODE_MASTER * - \ref SPII2S_MODE_SLAVE * @param[in] u32SampleRate Sample rate * @param[in] u32WordWidth Data length. Valid values are listed below. * - \ref SPII2S_DATABIT_8 * - \ref SPII2S_DATABIT_16 * - \ref SPII2S_DATABIT_24 * - \ref SPII2S_DATABIT_32 * @param[in] u32Channels Audio format. Valid values are listed below. * - \ref SPII2S_MONO * - \ref SPII2S_STEREO * @param[in] u32DataFormat Data format. Valid values are listed below. * - \ref SPII2S_FORMAT_I2S * - \ref SPII2S_FORMAT_MSB * - \ref SPII2S_FORMAT_PCMA * - \ref SPII2S_FORMAT_PCMB * @return Real sample rate of master mode or peripheral clock rate of slave mode. * @details This function will reset SPI/I2S controller and configure I2S controller according to the input parameters. * Set TX FIFO threshold to 2 and RX FIFO threshold to 1. Both the TX and RX functions will be enabled. * The actual sample rate may be different from the target sample rate. The real sample rate will be returned for reference. * @note In slave mode, the SPI peripheral clock rate will be equal to APB clock rate. */ uint32_t SPII2S_Open(SPI_T *i2s, uint32_t u32MasterSlave, uint32_t u32SampleRate, uint32_t u32WordWidth, uint32_t u32Channels, uint32_t u32DataFormat) { uint32_t u32Divider; uint32_t u32BitRate, u32SrcClk, u32RetValue; /* Reset SPI/I2S */ if(i2s == SPI0) { SYS->IPRST1 |= SYS_IPRST1_SPI0RST_Msk; SYS->IPRST1 &= ~SYS_IPRST1_SPI0RST_Msk; } else if(i2s == SPI1) { SYS->IPRST1 |= SYS_IPRST1_SPI1RST_Msk; SYS->IPRST1 &= ~SYS_IPRST1_SPI1RST_Msk; } else if(i2s == SPI2) { SYS->IPRST1 |= SYS_IPRST1_SPI2RST_Msk; SYS->IPRST1 &= ~SYS_IPRST1_SPI2RST_Msk; } else { SYS->IPRST2 |= SYS_IPRST2_SPI3RST_Msk; SYS->IPRST2 &= ~SYS_IPRST2_SPI3RST_Msk; } /* Configure I2S controller */ i2s->I2SCTL = u32MasterSlave | u32WordWidth | u32Channels | u32DataFormat; /* Set TX FIFO threshold to 2 and RX FIFO threshold to 1 */ SPI_SetFIFO(i2s, 2, 1); if(u32MasterSlave == SPI_MASTER) { /* Get the source clock rate */ u32SrcClk = SPII2S_GetSourceClockFreq(i2s); /* Calculate the bit clock rate */ u32BitRate = u32SampleRate * ((u32WordWidth >> SPI_I2SCTL_WDWIDTH_Pos) + 1U) * 16U; u32Divider = ((u32SrcClk / u32BitRate) >> 1U) - 1U; //u32Divider = ((((u32SrcClk * 10UL / u32BitRate) >> 1U) + 5UL) / 10UL) - 1U; /* Set BCLKDIV setting */ i2s->I2SCLK = (i2s->I2SCLK & ~SPI_I2SCLK_BCLKDIV_Msk) | (u32Divider << SPI_I2SCLK_BCLKDIV_Pos); /* Calculate bit clock rate */ u32BitRate = u32SrcClk / ((u32Divider + 1U) * 2U); /* Calculate real sample rate */ u32SampleRate = u32BitRate / (((u32WordWidth >> SPI_I2SCTL_WDWIDTH_Pos) + 1U) * 16U); /* Enable TX function, RX function and I2S mode. */ i2s->I2SCTL |= (SPI_I2SCTL_RXEN_Msk | SPI_I2SCTL_TXEN_Msk | SPI_I2SCTL_I2SEN_Msk); /* Return the real sample rate */ u32RetValue = u32SampleRate; } else { /* Set BCLKDIV = 0 */ i2s->I2SCLK &= ~SPI_I2SCLK_BCLKDIV_Msk; if(i2s == SPI0) { /* Set the peripheral clock rate to equal APB clock rate */ CLK->CLKSEL2 = (CLK->CLKSEL2 & (~CLK_CLKSEL2_SPI0SEL_Msk)) | CLK_CLKSEL2_SPI0SEL_PCLK1; /* Enable TX function, RX function and I2S mode. */ i2s->I2SCTL |= (SPI_I2SCTL_RXEN_Msk | SPI_I2SCTL_TXEN_Msk | SPI_I2SCTL_I2SEN_Msk); /* Return slave peripheral clock rate */ u32RetValue = CLK_GetPCLK1Freq(); } else if(i2s == SPI1) { /* Set the peripheral clock rate to equal APB clock rate */ CLK->CLKSEL2 = (CLK->CLKSEL2 & (~CLK_CLKSEL2_SPI1SEL_Msk)) | CLK_CLKSEL2_SPI1SEL_PCLK0; /* Enable TX function, RX function and I2S mode. */ i2s->I2SCTL |= (SPI_I2SCTL_RXEN_Msk | SPI_I2SCTL_TXEN_Msk | SPI_I2SCTL_I2SEN_Msk); /* Return slave peripheral clock rate */ u32RetValue = CLK_GetPCLK0Freq(); } else if(i2s == SPI2) { /* Set the peripheral clock rate to equal APB clock rate */ CLK->CLKSEL2 = (CLK->CLKSEL2 & (~CLK_CLKSEL2_SPI2SEL_Msk)) | CLK_CLKSEL2_SPI2SEL_PCLK1; /* Enable TX function, RX function and I2S mode. */ i2s->I2SCTL |= (SPI_I2SCTL_RXEN_Msk | SPI_I2SCTL_TXEN_Msk | SPI_I2SCTL_I2SEN_Msk); /* Return slave peripheral clock rate */ u32RetValue = CLK_GetPCLK1Freq(); } else { /* Set the peripheral clock rate to equal APB clock rate */ CLK->CLKSEL2 = (CLK->CLKSEL2 & (~CLK_CLKSEL2_SPI3SEL_Msk)) | CLK_CLKSEL2_SPI3SEL_PCLK0; /* Enable TX function, RX function and I2S mode. */ i2s->I2SCTL |= (SPI_I2SCTL_RXEN_Msk | SPI_I2SCTL_TXEN_Msk | SPI_I2SCTL_I2SEN_Msk); /* Return slave peripheral clock rate */ u32RetValue = CLK_GetPCLK0Freq(); } } return u32RetValue; } /** * @brief Disable I2S function. * @param[in] i2s The pointer of the specified I2S module. * @return None * @details Disable I2S function. */ void SPII2S_Close(SPI_T *i2s) { i2s->I2SCTL &= ~SPI_I2SCTL_I2SEN_Msk; } /** * @brief Enable interrupt function. * @param[in] i2s The pointer of the specified I2S module. * @param[in] u32Mask The combination of all related interrupt enable bits. * Each bit corresponds to a interrupt source. Valid values are listed below. * - \ref SPII2S_FIFO_TXTH_INT_MASK * - \ref SPII2S_FIFO_RXTH_INT_MASK * - \ref SPII2S_FIFO_RXOV_INT_MASK * - \ref SPII2S_FIFO_RXTO_INT_MASK * - \ref SPII2S_TXUF_INT_MASK * - \ref SPII2S_RIGHT_ZC_INT_MASK * - \ref SPII2S_LEFT_ZC_INT_MASK * @return None * @details This function enables the interrupt according to the u32Mask parameter. */ void SPII2S_EnableInt(SPI_T *i2s, uint32_t u32Mask) { /* Enable TX threshold interrupt flag */ if((u32Mask & SPII2S_FIFO_TXTH_INT_MASK) == SPII2S_FIFO_TXTH_INT_MASK) { i2s->FIFOCTL |= SPI_FIFOCTL_TXTHIEN_Msk; } /* Enable RX threshold interrupt flag */ if((u32Mask & SPII2S_FIFO_RXTH_INT_MASK) == SPII2S_FIFO_RXTH_INT_MASK) { i2s->FIFOCTL |= SPI_FIFOCTL_RXTHIEN_Msk; } /* Enable RX overrun interrupt flag */ if((u32Mask & SPII2S_FIFO_RXOV_INT_MASK) == SPII2S_FIFO_RXOV_INT_MASK) { i2s->FIFOCTL |= SPI_FIFOCTL_RXOVIEN_Msk; } /* Enable RX time-out interrupt flag */ if((u32Mask & SPII2S_FIFO_RXTO_INT_MASK) == SPII2S_FIFO_RXTO_INT_MASK) { i2s->FIFOCTL |= SPI_FIFOCTL_RXTOIEN_Msk; } /* Enable TX underflow interrupt flag */ if((u32Mask & SPII2S_TXUF_INT_MASK) == SPII2S_TXUF_INT_MASK) { i2s->FIFOCTL |= SPI_FIFOCTL_TXUFIEN_Msk; } /* Enable right channel zero cross interrupt flag */ if((u32Mask & SPII2S_RIGHT_ZC_INT_MASK) == SPII2S_RIGHT_ZC_INT_MASK) { i2s->I2SCTL |= SPI_I2SCTL_RZCIEN_Msk; } /* Enable left channel zero cross interrupt flag */ if((u32Mask & SPII2S_LEFT_ZC_INT_MASK) == SPII2S_LEFT_ZC_INT_MASK) { i2s->I2SCTL |= SPI_I2SCTL_LZCIEN_Msk; } } /** * @brief Disable interrupt function. * @param[in] i2s The pointer of the specified I2S module. * @param[in] u32Mask The combination of all related interrupt enable bits. * Each bit corresponds to a interrupt source. Valid values are listed below. * - \ref SPII2S_FIFO_TXTH_INT_MASK * - \ref SPII2S_FIFO_RXTH_INT_MASK * - \ref SPII2S_FIFO_RXOV_INT_MASK * - \ref SPII2S_FIFO_RXTO_INT_MASK * - \ref SPII2S_TXUF_INT_MASK * - \ref SPII2S_RIGHT_ZC_INT_MASK * - \ref SPII2S_LEFT_ZC_INT_MASK * @return None * @details This function disables the interrupt according to the u32Mask parameter. */ void SPII2S_DisableInt(SPI_T *i2s, uint32_t u32Mask) { /* Disable TX threshold interrupt flag */ if((u32Mask & SPII2S_FIFO_TXTH_INT_MASK) == SPII2S_FIFO_TXTH_INT_MASK) { i2s->FIFOCTL &= ~SPI_FIFOCTL_TXTHIEN_Msk; } /* Disable RX threshold interrupt flag */ if((u32Mask & SPII2S_FIFO_RXTH_INT_MASK) == SPII2S_FIFO_RXTH_INT_MASK) { i2s->FIFOCTL &= ~SPI_FIFOCTL_RXTHIEN_Msk; } /* Disable RX overrun interrupt flag */ if((u32Mask & SPII2S_FIFO_RXOV_INT_MASK) == SPII2S_FIFO_RXOV_INT_MASK) { i2s->FIFOCTL &= ~SPI_FIFOCTL_RXOVIEN_Msk; } /* Disable RX time-out interrupt flag */ if((u32Mask & SPII2S_FIFO_RXTO_INT_MASK) == SPII2S_FIFO_RXTO_INT_MASK) { i2s->FIFOCTL &= ~SPI_FIFOCTL_RXTOIEN_Msk; } /* Disable TX underflow interrupt flag */ if((u32Mask & SPII2S_TXUF_INT_MASK) == SPII2S_TXUF_INT_MASK) { i2s->FIFOCTL &= ~SPI_FIFOCTL_TXUFIEN_Msk; } /* Disable right channel zero cross interrupt flag */ if((u32Mask & SPII2S_RIGHT_ZC_INT_MASK) == SPII2S_RIGHT_ZC_INT_MASK) { i2s->I2SCTL &= ~SPI_I2SCTL_RZCIEN_Msk; } /* Disable left channel zero cross interrupt flag */ if((u32Mask & SPII2S_LEFT_ZC_INT_MASK) == SPII2S_LEFT_ZC_INT_MASK) { i2s->I2SCTL &= ~SPI_I2SCTL_LZCIEN_Msk; } } /** * @brief Enable master clock (MCLK). * @param[in] i2s The pointer of the specified I2S module. * @param[in] u32BusClock The target MCLK clock rate. * @return Actual MCLK clock rate * @details Set the master clock rate according to u32BusClock parameter and enable master clock output. * The actual master clock rate may be different from the target master clock rate. The real master clock rate will be returned for reference. */ uint32_t SPII2S_EnableMCLK(SPI_T *i2s, uint32_t u32BusClock) { uint32_t u32Divider; uint32_t u32SrcClk, u32RetValue; u32SrcClk = SPII2S_GetSourceClockFreq(i2s); if(u32BusClock == u32SrcClk) { u32Divider = 0U; } else { u32Divider = (u32SrcClk / u32BusClock) >> 1U; /* MCLKDIV is a 6-bit width configuration. The maximum value is 0x3F. */ if(u32Divider > 0x3FU) { u32Divider = 0x3FU; } } /* Write u32Divider to MCLKDIV (SPI_I2SCLK[5:0]) */ i2s->I2SCLK = (i2s->I2SCLK & ~SPI_I2SCLK_MCLKDIV_Msk) | (u32Divider << SPI_I2SCLK_MCLKDIV_Pos); /* Enable MCLK output */ i2s->I2SCTL |= SPI_I2SCTL_MCLKEN_Msk; if(u32Divider == 0U) { u32RetValue = u32SrcClk; /* If MCLKDIV=0, master clock rate is equal to the source clock rate. */ } else { u32RetValue = ((u32SrcClk >> 1U) / u32Divider); /* If MCLKDIV>0, master clock rate = source clock rate / (MCLKDIV * 2) */ } return u32RetValue; } /** * @brief Disable master clock (MCLK). * @param[in] i2s The pointer of the specified I2S module. * @return None * @details Clear MCLKEN bit of SPI_I2SCTL register to disable master clock output. */ void SPII2S_DisableMCLK(SPI_T *i2s) { i2s->I2SCTL &= ~SPI_I2SCTL_MCLKEN_Msk; } /** * @brief Configure FIFO threshold setting. * @param[in] i2s The pointer of the specified I2S module. * @param[in] u32TxThreshold Decides the TX FIFO threshold. It could be 0 ~ 3. * @param[in] u32RxThreshold Decides the RX FIFO threshold. It could be 0 ~ 3. * @return None * @details Set TX FIFO threshold and RX FIFO threshold configurations. */ void SPII2S_SetFIFO(SPI_T *i2s, uint32_t u32TxThreshold, uint32_t u32RxThreshold) { i2s->FIFOCTL = (i2s->FIFOCTL & ~(SPI_FIFOCTL_TXTH_Msk | SPI_FIFOCTL_RXTH_Msk)) | (u32TxThreshold << SPI_FIFOCTL_TXTH_Pos) | (u32RxThreshold << SPI_FIFOCTL_RXTH_Pos); } /*@}*/ /* end of group SPI_EXPORTED_FUNCTIONS */ /*@}*/ /* end of group SPI_Driver */ /*@}*/ /* end of group Standard_Driver */ /*** (C) COPYRIGHT 2016 Nuvoton Technology Corp. ***/