/**************************************************************************//** * @file clk.c * @version V3.00 * @brief M480 series CLK driver source file * * @copyright (C) 2016 Nuvoton Technology Corp. All rights reserved. *****************************************************************************/ #include "NuMicro.h" /** @addtogroup Standard_Driver Standard Driver @{ */ /** @addtogroup CLK_Driver CLK Driver @{ */ /** @addtogroup CLK_EXPORTED_FUNCTIONS CLK Exported Functions @{ */ /** * @brief Disable clock divider output function * @param None * @return None * @details This function disable clock divider output function. */ void CLK_DisableCKO(void) { /* Disable CKO clock source */ CLK_DisableModuleClock(CLKO_MODULE); } /** * @brief This function enable clock divider output module clock, * enable clock divider output function and set frequency selection. * @param[in] u32ClkSrc is frequency divider function clock source. Including : * - \ref CLK_CLKSEL1_CLKOSEL_HXT * - \ref CLK_CLKSEL1_CLKOSEL_LXT * - \ref CLK_CLKSEL1_CLKOSEL_HCLK * - \ref CLK_CLKSEL1_CLKOSEL_HIRC * @param[in] u32ClkDiv is divider output frequency selection. It could be 0~15. * @param[in] u32ClkDivBy1En is clock divided by one enabled. * @return None * @details Output selected clock to CKO. The output clock frequency is divided by u32ClkDiv. \n * The formula is: \n * CKO frequency = (Clock source frequency) / 2^(u32ClkDiv + 1) \n * This function is just used to set CKO clock. * User must enable I/O for CKO clock output pin by themselves. \n */ void CLK_EnableCKO(uint32_t u32ClkSrc, uint32_t u32ClkDiv, uint32_t u32ClkDivBy1En) { /* CKO = clock source / 2^(u32ClkDiv + 1) */ CLK->CLKOCTL = CLK_CLKOCTL_CLKOEN_Msk | (u32ClkDiv) | (u32ClkDivBy1En << CLK_CLKOCTL_DIV1EN_Pos); /* Enable CKO clock source */ CLK_EnableModuleClock(CLKO_MODULE); /* Select CKO clock source */ CLK_SetModuleClock(CLKO_MODULE, u32ClkSrc, 0UL); } /** * @brief Enter to Power-down mode * @param None * @return None * @details This function is used to let system enter to Power-down mode. \n * The register write-protection function should be disabled before using this function. */ void CLK_PowerDown(void) { /* Set the processor uses deep sleep as its low power mode */ SCB->SCR |= SCB_SCR_SLEEPDEEP_Msk; /* Set system Power-down enabled and Power-down entry condition */ CLK->PWRCTL |= CLK_PWRCTL_PDEN_Msk; /* Chip enter Power-down mode after CPU run WFI instruction */ __WFI(); } /** * @brief Enter to Idle mode * @param None * @return None * @details This function let system enter to Idle mode. \n * The register write-protection function should be disabled before using this function. */ void CLK_Idle(void) { /* Set the processor uses sleep as its low power mode */ SCB->SCR &= ~SCB_SCR_SLEEPDEEP_Msk; /* Set chip in idle mode because of WFI command */ CLK->PWRCTL &= ~CLK_PWRCTL_PDEN_Msk; /* Chip enter idle mode after CPU run WFI instruction */ __WFI(); } /** * @brief Get external high speed crystal clock frequency * @param None * @return External high frequency crystal frequency * @details This function get external high frequency crystal frequency. The frequency unit is Hz. */ uint32_t CLK_GetHXTFreq(void) { uint32_t u32Freq; if((CLK->PWRCTL & CLK_PWRCTL_HXTEN_Msk) == CLK_PWRCTL_HXTEN_Msk) { u32Freq = __HXT; } else { u32Freq = 0UL; } return u32Freq; } /** * @brief Get external low speed crystal clock frequency * @param None * @return External low speed crystal clock frequency * @details This function get external low frequency crystal frequency. The frequency unit is Hz. */ uint32_t CLK_GetLXTFreq(void) { uint32_t u32Freq; if((CLK->PWRCTL & CLK_PWRCTL_LXTEN_Msk) == CLK_PWRCTL_LXTEN_Msk) { u32Freq = __LXT; } else { u32Freq = 0UL; } return u32Freq; } /** * @brief Get PCLK0 frequency * @param None * @return PCLK0 frequency * @details This function get PCLK0 frequency. The frequency unit is Hz. */ uint32_t CLK_GetPCLK0Freq(void) { uint32_t u32Freq; SystemCoreClockUpdate(); #if(1) if((CLK->PCLKDIV & CLK_PCLKDIV_APB0DIV_Msk) == CLK_PCLKDIV_PCLK0DIV1) { u32Freq = SystemCoreClock; } else if((CLK->PCLKDIV & CLK_PCLKDIV_APB0DIV_Msk) == CLK_PCLKDIV_PCLK0DIV2) { u32Freq = SystemCoreClock / 2UL; } else if((CLK->PCLKDIV & CLK_PCLKDIV_APB0DIV_Msk) == CLK_PCLKDIV_PCLK0DIV4) { u32Freq = SystemCoreClock / 4UL; } else if((CLK->PCLKDIV & CLK_PCLKDIV_APB0DIV_Msk) == CLK_PCLKDIV_PCLK0DIV8) { u32Freq = SystemCoreClock / 8UL; } else if((CLK->PCLKDIV & CLK_PCLKDIV_APB0DIV_Msk) == CLK_PCLKDIV_PCLK0DIV16) { u32Freq = SystemCoreClock / 16UL; } else { u32Freq = SystemCoreClock; } #else if((CLK->CLKSEL0 & CLK_CLKSEL0_PCLK0SEL_Msk) == CLK_CLKSEL0_PCLK0DIV1) { u32Freq = SystemCoreClock; } else if((CLK->CLKSEL0 & CLK_CLKSEL0_PCLK0SEL_Msk) == CLK_CLKSEL0_PCLK0DIV2) { u32Freq = SystemCoreClock / 2UL; } else { u32Freq = SystemCoreClock; } #endif return u32Freq; } /** * @brief Get PCLK1 frequency * @param None * @return PCLK1 frequency * @details This function get PCLK1 frequency. The frequency unit is Hz. */ uint32_t CLK_GetPCLK1Freq(void) { uint32_t u32Freq; SystemCoreClockUpdate(); #if(1) if((CLK->PCLKDIV & CLK_PCLKDIV_APB1DIV_Msk) == CLK_PCLKDIV_PCLK1DIV1) { u32Freq = SystemCoreClock; } else if((CLK->PCLKDIV & CLK_PCLKDIV_APB1DIV_Msk) == CLK_PCLKDIV_PCLK1DIV2) { u32Freq = SystemCoreClock / 2UL; } else if((CLK->PCLKDIV & CLK_PCLKDIV_APB1DIV_Msk) == CLK_PCLKDIV_PCLK1DIV4) { u32Freq = SystemCoreClock / 4UL; } else if((CLK->PCLKDIV & CLK_PCLKDIV_APB1DIV_Msk) == CLK_PCLKDIV_PCLK1DIV8) { u32Freq = SystemCoreClock / 8UL; } else if((CLK->PCLKDIV & CLK_PCLKDIV_APB1DIV_Msk) == CLK_PCLKDIV_PCLK1DIV16) { u32Freq = SystemCoreClock / 16UL; } else { u32Freq = SystemCoreClock; } #else if((CLK->CLKSEL0 & CLK_CLKSEL0_PCLK1SEL_Msk) == CLK_CLKSEL0_PCLK1DIV1) { u32Freq = SystemCoreClock; } else if((CLK->CLKSEL0 & CLK_CLKSEL0_PCLK1SEL_Msk) == CLK_CLKSEL0_PCLK1DIV2) { u32Freq = SystemCoreClock / 2UL; } else { u32Freq = SystemCoreClock; } #endif return u32Freq; } /** * @brief Get HCLK frequency * @param None * @return HCLK frequency * @details This function get HCLK frequency. The frequency unit is Hz. */ uint32_t CLK_GetHCLKFreq(void) { SystemCoreClockUpdate(); return SystemCoreClock; } /** * @brief Get CPU frequency * @param None * @return CPU frequency * @details This function get CPU frequency. The frequency unit is Hz. */ uint32_t CLK_GetCPUFreq(void) { SystemCoreClockUpdate(); return SystemCoreClock; } /** * @brief Set HCLK frequency * @param[in] u32Hclk is HCLK frequency. The range of u32Hclk is running up to 192MHz. * @return HCLK frequency * @details This function is used to set HCLK frequency. The frequency unit is Hz. \n * The register write-protection function should be disabled before using this function. */ uint32_t CLK_SetCoreClock(uint32_t u32Hclk) { uint32_t u32HIRCSTB; /* Read HIRC clock source stable flag */ u32HIRCSTB = CLK->STATUS & CLK_STATUS_HIRCSTB_Msk; /* The range of u32Hclk is running up to 192 MHz */ if(u32Hclk > FREQ_192MHZ) { u32Hclk = FREQ_192MHZ; } /* Switch HCLK clock source to HIRC clock for safe */ CLK->PWRCTL |= CLK_PWRCTL_HIRCEN_Msk; CLK_WaitClockReady(CLK_STATUS_HIRCSTB_Msk); CLK->CLKSEL0 |= CLK_CLKSEL0_HCLKSEL_Msk; CLK->CLKDIV0 &= (~CLK_CLKDIV0_HCLKDIV_Msk); /* Configure PLL setting if HXT clock is enabled */ if((CLK->PWRCTL & CLK_PWRCTL_HXTEN_Msk) == CLK_PWRCTL_HXTEN_Msk) { u32Hclk = CLK_EnablePLL(CLK_PLLCTL_PLLSRC_HXT, u32Hclk); } /* Configure PLL setting if HXT clock is not enabled */ else { u32Hclk = CLK_EnablePLL(CLK_PLLCTL_PLLSRC_HIRC, u32Hclk); /* Read HIRC clock source stable flag */ u32HIRCSTB = CLK->STATUS & CLK_STATUS_HIRCSTB_Msk; } /* Select HCLK clock source to PLL, and update system core clock */ CLK_SetHCLK(CLK_CLKSEL0_HCLKSEL_PLL, CLK_CLKDIV0_HCLK(1UL)); /* Disable HIRC if HIRC is disabled before setting core clock */ if(u32HIRCSTB == 0UL) { CLK->PWRCTL &= ~CLK_PWRCTL_HIRCEN_Msk; } /* Return actually HCLK frequency is PLL frequency divide 1 */ return u32Hclk; } /** * @brief This function set HCLK clock source and HCLK clock divider * @param[in] u32ClkSrc is HCLK clock source. Including : * - \ref CLK_CLKSEL0_HCLKSEL_HXT * - \ref CLK_CLKSEL0_HCLKSEL_LXT * - \ref CLK_CLKSEL0_HCLKSEL_PLL * - \ref CLK_CLKSEL0_HCLKSEL_LIRC * - \ref CLK_CLKSEL0_HCLKSEL_HIRC * @param[in] u32ClkDiv is HCLK clock divider. Including : * - \ref CLK_CLKDIV0_HCLK(x) * @return None * @details This function set HCLK clock source and HCLK clock divider. \n * The register write-protection function should be disabled before using this function. */ void CLK_SetHCLK(uint32_t u32ClkSrc, uint32_t u32ClkDiv) { uint32_t u32HIRCSTB; /* Read HIRC clock source stable flag */ u32HIRCSTB = CLK->STATUS & CLK_STATUS_HIRCSTB_Msk; /* Switch to HIRC for Safe. Avoid HCLK too high when applying new divider. */ CLK->PWRCTL |= CLK_PWRCTL_HIRCEN_Msk; CLK_WaitClockReady(CLK_STATUS_HIRCSTB_Msk); CLK->CLKSEL0 = (CLK->CLKSEL0 & (~CLK_CLKSEL0_HCLKSEL_Msk)) | CLK_CLKSEL0_HCLKSEL_HIRC; /* Apply new Divider */ CLK->CLKDIV0 = (CLK->CLKDIV0 & (~CLK_CLKDIV0_HCLKDIV_Msk)) | u32ClkDiv; /* Switch HCLK to new HCLK source */ CLK->CLKSEL0 = (CLK->CLKSEL0 & (~CLK_CLKSEL0_HCLKSEL_Msk)) | u32ClkSrc; /* Update System Core Clock */ SystemCoreClockUpdate(); /* Disable HIRC if HIRC is disabled before switching HCLK source */ if(u32HIRCSTB == 0UL) { CLK->PWRCTL &= ~CLK_PWRCTL_HIRCEN_Msk; } } /** * @brief This function set selected module clock source and module clock divider * @param[in] u32ModuleIdx is module index. * @param[in] u32ClkSrc is module clock source. * @param[in] u32ClkDiv is module clock divider. * @return None * @details Valid parameter combinations listed in following table: * * |Module index |Clock source |Divider | * | :---------------- | :----------------------------------- | :-------------------------- | * |\ref SDH0_MODULE |\ref CLK_CLKSEL0_SDH0SEL_HXT |\ref CLK_CLKDIV0_SDH0(x) | * |\ref SDH0_MODULE |\ref CLK_CLKSEL0_SDH0SEL_PLL |\ref CLK_CLKDIV0_SDH0(x) | * |\ref SDH0_MODULE |\ref CLK_CLKSEL0_SDH0SEL_HIRC |\ref CLK_CLKDIV0_SDH0(x) | * |\ref SDH0_MODULE |\ref CLK_CLKSEL0_SDH0SEL_HCLK |\ref CLK_CLKDIV0_SDH0(x) | * |\ref SDH1_MODULE |\ref CLK_CLKSEL0_SDH1SEL_HXT |\ref CLK_CLKDIV3_SDH1(x) | * |\ref SDH1_MODULE |\ref CLK_CLKSEL0_SDH1SEL_PLL |\ref CLK_CLKDIV3_SDH1(x) | * |\ref SDH1_MODULE |\ref CLK_CLKSEL0_SDH1SEL_HIRC |\ref CLK_CLKDIV3_SDH1(x) | * |\ref SDH1_MODULE |\ref CLK_CLKSEL0_SDH1SEL_HCLK |\ref CLK_CLKDIV3_SDH1(x) | * |\ref WDT_MODULE |\ref CLK_CLKSEL1_WDTSEL_LXT | x | * |\ref WDT_MODULE |\ref CLK_CLKSEL1_WDTSEL_LIRC | x | * |\ref WDT_MODULE |\ref CLK_CLKSEL1_WDTSEL_HCLK_DIV2048 | x | * |\ref TMR0_MODULE |\ref CLK_CLKSEL1_TMR0SEL_HXT | x | * |\ref TMR0_MODULE |\ref CLK_CLKSEL1_TMR0SEL_LXT | x | * |\ref TMR0_MODULE |\ref CLK_CLKSEL1_TMR0SEL_LIRC | x | * |\ref TMR0_MODULE |\ref CLK_CLKSEL1_TMR0SEL_HIRC | x | * |\ref TMR0_MODULE |\ref CLK_CLKSEL1_TMR0SEL_PCLK0 | x | * |\ref TMR0_MODULE |\ref CLK_CLKSEL1_TMR0SEL_EXT | x | * |\ref TMR1_MODULE |\ref CLK_CLKSEL1_TMR1SEL_HXT | x | * |\ref TMR1_MODULE |\ref CLK_CLKSEL1_TMR1SEL_LXT | x | * |\ref TMR1_MODULE |\ref CLK_CLKSEL1_TMR1SEL_LIRC | x | * |\ref TMR1_MODULE |\ref CLK_CLKSEL1_TMR1SEL_HIRC | x | * |\ref TMR1_MODULE |\ref CLK_CLKSEL1_TMR1SEL_PCLK0 | x | * |\ref TMR1_MODULE |\ref CLK_CLKSEL1_TMR1SEL_EXT | x | * |\ref TMR2_MODULE |\ref CLK_CLKSEL1_TMR2SEL_HXT | x | * |\ref TMR2_MODULE |\ref CLK_CLKSEL1_TMR2SEL_LXT | x | * |\ref TMR2_MODULE |\ref CLK_CLKSEL1_TMR2SEL_LIRC | x | * |\ref TMR2_MODULE |\ref CLK_CLKSEL1_TMR2SEL_HIRC | x | * |\ref TMR2_MODULE |\ref CLK_CLKSEL1_TMR2SEL_PCLK1 | x | * |\ref TMR2_MODULE |\ref CLK_CLKSEL1_TMR2SEL_EXT | x | * |\ref TMR3_MODULE |\ref CLK_CLKSEL1_TMR3SEL_HXT | x | * |\ref TMR3_MODULE |\ref CLK_CLKSEL1_TMR3SEL_LXT | x | * |\ref TMR3_MODULE |\ref CLK_CLKSEL1_TMR3SEL_LIRC | x | * |\ref TMR3_MODULE |\ref CLK_CLKSEL1_TMR3SEL_HIRC | x | * |\ref TMR3_MODULE |\ref CLK_CLKSEL1_TMR3SEL_PCLK1 | x | * |\ref TMR3_MODULE |\ref CLK_CLKSEL1_TMR3SEL_EXT | x | * |\ref UART0_MODULE |\ref CLK_CLKSEL1_UART0SEL_HXT |\ref CLK_CLKDIV0_UART0(x) | * |\ref UART0_MODULE |\ref CLK_CLKSEL1_UART0SEL_LXT |\ref CLK_CLKDIV0_UART0(x) | * |\ref UART0_MODULE |\ref CLK_CLKSEL1_UART0SEL_PLL |\ref CLK_CLKDIV0_UART0(x) | * |\ref UART0_MODULE |\ref CLK_CLKSEL1_UART0SEL_HIRC |\ref CLK_CLKDIV0_UART0(x) | * |\ref UART1_MODULE |\ref CLK_CLKSEL1_UART1SEL_HXT |\ref CLK_CLKDIV0_UART1(x) | * |\ref UART1_MODULE |\ref CLK_CLKSEL1_UART1SEL_LXT |\ref CLK_CLKDIV0_UART1(x) | * |\ref UART1_MODULE |\ref CLK_CLKSEL1_UART1SEL_PLL |\ref CLK_CLKDIV0_UART1(x) | * |\ref UART1_MODULE |\ref CLK_CLKSEL1_UART1SEL_HIRC |\ref CLK_CLKDIV0_UART1(x) | * |\ref CLKO_MODULE |\ref CLK_CLKSEL1_CLKOSEL_HXT | x | * |\ref CLKO_MODULE |\ref CLK_CLKSEL1_CLKOSEL_LXT | x | * |\ref CLKO_MODULE |\ref CLK_CLKSEL1_CLKOSEL_HIRC | x | * |\ref CLKO_MODULE |\ref CLK_CLKSEL1_CLKOSEL_HCLK | x | * |\ref WWDT_MODULE |\ref CLK_CLKSEL1_WWDTSEL_LIRC | x | * |\ref WWDT_MODULE |\ref CLK_CLKSEL1_WWDTSEL_HCLK_DIV2048 | x | * |\ref EPWM0_MODULE |\ref CLK_CLKSEL2_EPWM0SEL_PLL | x | * |\ref EPWM0_MODULE |\ref CLK_CLKSEL2_EPWM0SEL_PCLK0 | x | * |\ref EPWM1_MODULE |\ref CLK_CLKSEL2_EPWM1SEL_PLL | x | * |\ref EPWM1_MODULE |\ref CLK_CLKSEL2_EPWM1SEL_PCLK1 | x | * |\ref QSPI0_MODULE |\ref CLK_CLKSEL2_QSPI0SEL_HXT | x | * |\ref QSPI0_MODULE |\ref CLK_CLKSEL2_QSPI0SEL_PLL | x | * |\ref QSPI0_MODULE |\ref CLK_CLKSEL2_QSPI0SEL_HIRC | x | * |\ref QSPI0_MODULE |\ref CLK_CLKSEL2_QSPI0SEL_PCLK0 | x | * |\ref SPI0_MODULE |\ref CLK_CLKSEL2_SPI0SEL_HXT | x | * |\ref SPI0_MODULE |\ref CLK_CLKSEL2_SPI0SEL_PLL | x | * |\ref SPI0_MODULE |\ref CLK_CLKSEL2_SPI0SEL_HIRC | x | * |\ref SPI0_MODULE |\ref CLK_CLKSEL2_SPI0SEL_PCLK1 | x | * |\ref SPI1_MODULE |\ref CLK_CLKSEL2_SPI1SEL_HXT | x | * |\ref SPI1_MODULE |\ref CLK_CLKSEL2_SPI1SEL_PLL | x | * |\ref SPI1_MODULE |\ref CLK_CLKSEL2_SPI1SEL_HIRC | x | * |\ref SPI1_MODULE |\ref CLK_CLKSEL2_SPI1SEL_PCLK0 | x | * |\ref BPWM0_MODULE |\ref CLK_CLKSEL2_BPWM0SEL_PLL | x | * |\ref BPWM0_MODULE |\ref CLK_CLKSEL2_BPWM0SEL_PCLK0 | x | * |\ref BPWM1_MODULE |\ref CLK_CLKSEL2_BPWM1SEL_PLL | x | * |\ref BPWM1_MODULE |\ref CLK_CLKSEL2_BPWM1SEL_PCLK1 | x | * |\ref SPI2_MODULE |\ref CLK_CLKSEL2_SPI2SEL_HXT | x | * |\ref SPI2_MODULE |\ref CLK_CLKSEL2_SPI2SEL_PLL | x | * |\ref SPI2_MODULE |\ref CLK_CLKSEL2_SPI2SEL_HIRC | x | * |\ref SPI2_MODULE |\ref CLK_CLKSEL2_SPI2SEL_PCLK1 | x | * |\ref SPI3_MODULE |\ref CLK_CLKSEL2_SPI3SEL_HXT | x | * |\ref SPI3_MODULE |\ref CLK_CLKSEL2_SPI3SEL_PLL | x | * |\ref SPI3_MODULE |\ref CLK_CLKSEL2_SPI3SEL_HIRC | x | * |\ref SPI3_MODULE |\ref CLK_CLKSEL2_SPI3SEL_PCLK0 | x | * |\ref SC0_MODULE |\ref CLK_CLKSEL3_SC0SEL_HXT |\ref CLK_CLKDIV1_SC0(x) | * |\ref SC0_MODULE |\ref CLK_CLKSEL3_SC0SEL_PLL |\ref CLK_CLKDIV1_SC0(x) | * |\ref SC0_MODULE |\ref CLK_CLKSEL3_SC0SEL_HIRC |\ref CLK_CLKDIV1_SC0(x) | * |\ref SC0_MODULE |\ref CLK_CLKSEL3_SC0SEL_PCLK0 |\ref CLK_CLKDIV1_SC0(x) | * |\ref SC1_MODULE |\ref CLK_CLKSEL3_SC1SEL_HXT |\ref CLK_CLKDIV1_SC1(x) | * |\ref SC1_MODULE |\ref CLK_CLKSEL3_SC1SEL_PLL |\ref CLK_CLKDIV1_SC1(x) | * |\ref SC1_MODULE |\ref CLK_CLKSEL3_SC1SEL_HIRC |\ref CLK_CLKDIV1_SC1(x) | * |\ref SC1_MODULE |\ref CLK_CLKSEL3_SC1SEL_PCLK1 |\ref CLK_CLKDIV1_SC1(x) | * |\ref SC2_MODULE |\ref CLK_CLKSEL3_SC2SEL_HXT |\ref CLK_CLKDIV1_SC2(x) | * |\ref SC2_MODULE |\ref CLK_CLKSEL3_SC2SEL_PLL |\ref CLK_CLKDIV1_SC2(x) | * |\ref SC2_MODULE |\ref CLK_CLKSEL3_SC2SEL_HIRC |\ref CLK_CLKDIV1_SC2(x) | * |\ref SC2_MODULE |\ref CLK_CLKSEL3_SC2SEL_PCLK0 |\ref CLK_CLKDIV1_SC2(x) | * |\ref RTC_MODULE |\ref CLK_CLKSEL3_RTCSEL_LXT | x | * |\ref RTC_MODULE |\ref CLK_CLKSEL3_RTCSEL_LIRC | x | * |\ref I2S0_MODULE |\ref CLK_CLKSEL3_I2S0SEL_HXT | x | * |\ref I2S0_MODULE |\ref CLK_CLKSEL3_I2S0SEL_PLL | x | * |\ref I2S0_MODULE |\ref CLK_CLKSEL3_I2S0SEL_HIRC | x | * |\ref UART2_MODULE |\ref CLK_CLKSEL3_UART2SEL_HXT |\ref CLK_CLKDIV4_UART2(x) | * |\ref UART2_MODULE |\ref CLK_CLKSEL3_UART2SEL_LXT |\ref CLK_CLKDIV4_UART2(x) | * |\ref UART2_MODULE |\ref CLK_CLKSEL3_UART2SEL_PLL |\ref CLK_CLKDIV4_UART2(x) | * |\ref UART2_MODULE |\ref CLK_CLKSEL3_UART2SEL_HIRC |\ref CLK_CLKDIV4_UART2(x) | * |\ref UART3_MODULE |\ref CLK_CLKSEL3_UART3SEL_HXT |\ref CLK_CLKDIV4_UART3(x) | * |\ref UART3_MODULE |\ref CLK_CLKSEL3_UART3SEL_LXT |\ref CLK_CLKDIV4_UART3(x) | * |\ref UART3_MODULE |\ref CLK_CLKSEL3_UART3SEL_PLL |\ref CLK_CLKDIV4_UART3(x) | * |\ref UART3_MODULE |\ref CLK_CLKSEL3_UART3SEL_HIRC |\ref CLK_CLKDIV4_UART3(x) | * |\ref UART4_MODULE |\ref CLK_CLKSEL3_UART4SEL_HXT |\ref CLK_CLKDIV4_UART4(x) | * |\ref UART4_MODULE |\ref CLK_CLKSEL3_UART4SEL_LXT |\ref CLK_CLKDIV4_UART4(x) | * |\ref UART4_MODULE |\ref CLK_CLKSEL3_UART4SEL_PLL |\ref CLK_CLKDIV4_UART4(x) | * |\ref UART4_MODULE |\ref CLK_CLKSEL3_UART4SEL_HIRC |\ref CLK_CLKDIV4_UART4(x) | * |\ref UART5_MODULE |\ref CLK_CLKSEL3_UART5SEL_HXT |\ref CLK_CLKDIV4_UART5(x) | * |\ref UART5_MODULE |\ref CLK_CLKSEL3_UART5SEL_LXT |\ref CLK_CLKDIV4_UART5(x) | * |\ref UART5_MODULE |\ref CLK_CLKSEL3_UART5SEL_PLL |\ref CLK_CLKDIV4_UART5(x) | * |\ref UART5_MODULE |\ref CLK_CLKSEL3_UART5SEL_HIRC |\ref CLK_CLKDIV4_UART5(x) | * |\ref EADC_MODULE | x |\ref CLK_CLKDIV0_EADC(x) | * |\ref EMAC_MODULE | x |\ref CLK_CLKDIV3_EMAC(x) | * */ void CLK_SetModuleClock(uint32_t u32ModuleIdx, uint32_t u32ClkSrc, uint32_t u32ClkDiv) { uint32_t u32sel = 0U, u32div = 0U; if(MODULE_CLKDIV_Msk(u32ModuleIdx) != MODULE_NoMsk) { /* Get clock divider control register address */ if(MODULE_CLKDIV(u32ModuleIdx) == 2U) { u32div = (uint32_t)&CLK->CLKDIV3; } else if (MODULE_CLKDIV(u32ModuleIdx) == 3U) { u32div = (uint32_t)&CLK->CLKDIV4; } else { u32div = (uint32_t)&CLK->CLKDIV0 + ((MODULE_CLKDIV(u32ModuleIdx)) * 4U); } /* Apply new divider */ M32(u32div) = (M32(u32div) & (~(MODULE_CLKDIV_Msk(u32ModuleIdx) << MODULE_CLKDIV_Pos(u32ModuleIdx)))) | u32ClkDiv; } if(MODULE_CLKSEL_Msk(u32ModuleIdx) != MODULE_NoMsk) { /* Get clock select control register address */ u32sel = (uint32_t)&CLK->CLKSEL0 + ((MODULE_CLKSEL(u32ModuleIdx)) * 4U); /* Set new clock selection setting */ M32(u32sel) = (M32(u32sel) & (~(MODULE_CLKSEL_Msk(u32ModuleIdx) << MODULE_CLKSEL_Pos(u32ModuleIdx)))) | u32ClkSrc; } } /** * @brief Set SysTick clock source * @param[in] u32ClkSrc is module clock source. Including: * - \ref CLK_CLKSEL0_STCLKSEL_HXT * - \ref CLK_CLKSEL0_STCLKSEL_LXT * - \ref CLK_CLKSEL0_STCLKSEL_HXT_DIV2 * - \ref CLK_CLKSEL0_STCLKSEL_HCLK_DIV2 * - \ref CLK_CLKSEL0_STCLKSEL_HIRC_DIV2 * @return None * @details This function set SysTick clock source. \n * The register write-protection function should be disabled before using this function. */ void CLK_SetSysTickClockSrc(uint32_t u32ClkSrc) { CLK->CLKSEL0 = (CLK->CLKSEL0 & ~CLK_CLKSEL0_STCLKSEL_Msk) | u32ClkSrc; } /** * @brief Enable clock source * @param[in] u32ClkMask is clock source mask. Including : * - \ref CLK_PWRCTL_HXTEN_Msk * - \ref CLK_PWRCTL_LXTEN_Msk * - \ref CLK_PWRCTL_HIRCEN_Msk * - \ref CLK_PWRCTL_LIRCEN_Msk * @return None * @details This function enable clock source. \n * The register write-protection function should be disabled before using this function. */ void CLK_EnableXtalRC(uint32_t u32ClkMask) { CLK->PWRCTL |= u32ClkMask; } /** * @brief Disable clock source * @param[in] u32ClkMask is clock source mask. Including : * - \ref CLK_PWRCTL_HXTEN_Msk * - \ref CLK_PWRCTL_LXTEN_Msk * - \ref CLK_PWRCTL_HIRCEN_Msk * - \ref CLK_PWRCTL_LIRCEN_Msk * @return None * @details This function disable clock source. \n * The register write-protection function should be disabled before using this function. */ void CLK_DisableXtalRC(uint32_t u32ClkMask) { CLK->PWRCTL &= ~u32ClkMask; } /** * @brief Enable module clock * @param[in] u32ModuleIdx is module index. Including : * - \ref PDMA_MODULE * - \ref ISP_MODULE * - \ref EBI_MODULE * - \ref EMAC_MODULE * - \ref SDH0_MODULE * - \ref CRC_MODULE * - \ref HSUSBD_MODULE * - \ref CRPT_MODULE * - \ref SPIM_MODULE * - \ref USBH_MODULE * - \ref SDH1_MODULE * - \ref WDT_MODULE * - \ref RTC_MODULE * - \ref TMR0_MODULE * - \ref TMR1_MODULE * - \ref TMR2_MODULE * - \ref TMR3_MODULE * - \ref CLKO_MODULE * - \ref WWDT_MODULE * - \ref ACMP01_MODULE * - \ref I2C0_MODULE * - \ref I2C1_MODULE * - \ref I2C2_MODULE * - \ref QSPI0_MODULE * - \ref SPI0_MODULE * - \ref SPI1_MODULE * - \ref SPI2_MODULE * - \ref UART0_MODULE * - \ref UART1_MODULE * - \ref UART2_MODULE * - \ref UART3_MODULE * - \ref UART4_MODULE * - \ref UART5_MODULE * - \ref CAN0_MODULE * - \ref CAN1_MODULE * - \ref OTG_MODULE * - \ref USBD_MODULE * - \ref EADC_MODULE * - \ref I2S0_MODULE * - \ref HSOTG_MODULE * - \ref SC0_MODULE * - \ref SC1_MODULE * - \ref SC2_MODULE * - \ref SPI3_MODULE * - \ref USCI0_MODULE * - \ref USCI1_MODULE * - \ref DAC_MODULE * - \ref EPWM0_MODULE * - \ref EPWM1_MODULE * - \ref BPWM0_MODULE * - \ref BPWM1_MODULE * - \ref QEI0_MODULE * - \ref QEI1_MODULE * - \ref ECAP0_MODULE * - \ref ECAP1_MODULE * - \ref OPA_MODULE * @return None * @details This function is used to enable module clock. */ void CLK_EnableModuleClock(uint32_t u32ModuleIdx) { uint32_t u32tmpVal = 0UL, u32tmpAddr = 0UL; u32tmpVal = (1UL << MODULE_IP_EN_Pos(u32ModuleIdx)); u32tmpAddr = (uint32_t)&CLK->AHBCLK; u32tmpAddr += ((MODULE_APBCLK(u32ModuleIdx) * 4UL)); *(volatile uint32_t *)u32tmpAddr |= u32tmpVal; } /** * @brief Disable module clock * @param[in] u32ModuleIdx is module index. Including : * - \ref PDMA_MODULE * - \ref ISP_MODULE * - \ref EBI_MODULE * - \ref EMAC_MODULE * - \ref SDH0_MODULE * - \ref CRC_MODULE * - \ref HSUSBD_MODULE * - \ref CRPT_MODULE * - \ref SPIM_MODULE * - \ref USBH_MODULE * - \ref SDH1_MODULE * - \ref WDT_MODULE * - \ref RTC_MODULE * - \ref TMR0_MODULE * - \ref TMR1_MODULE * - \ref TMR2_MODULE * - \ref TMR3_MODULE * - \ref CLKO_MODULE * - \ref WWDT_MODULE * - \ref ACMP01_MODULE * - \ref I2C0_MODULE * - \ref I2C1_MODULE * - \ref I2C2_MODULE * - \ref QSPI0_MODULE * - \ref SPI0_MODULE * - \ref SPI1_MODULE * - \ref SPI2_MODULE * - \ref UART0_MODULE * - \ref UART1_MODULE * - \ref UART2_MODULE * - \ref UART3_MODULE * - \ref UART4_MODULE * - \ref UART5_MODULE * - \ref CAN0_MODULE * - \ref CAN1_MODULE * - \ref OTG_MODULE * - \ref USBD_MODULE * - \ref EADC_MODULE * - \ref I2S0_MODULE * - \ref HSOTG_MODULE * - \ref SC0_MODULE * - \ref SC1_MODULE * - \ref SC2_MODULE * - \ref SPI3_MODULE * - \ref USCI0_MODULE * - \ref USCI1_MODULE * - \ref DAC_MODULE * - \ref EPWM0_MODULE * - \ref EPWM1_MODULE * - \ref BPWM0_MODULE * - \ref BPWM1_MODULE * - \ref QEI0_MODULE * - \ref QEI1_MODULE * - \ref ECAP0_MODULE * - \ref ECAP1_MODULE * - \ref OPA_MODULE * @return None * @details This function is used to disable module clock. */ void CLK_DisableModuleClock(uint32_t u32ModuleIdx) { uint32_t u32tmpVal = 0UL, u32tmpAddr = 0UL; u32tmpVal = ~(1UL << MODULE_IP_EN_Pos(u32ModuleIdx)); u32tmpAddr = (uint32_t)&CLK->AHBCLK; u32tmpAddr += ((MODULE_APBCLK(u32ModuleIdx) * 4UL)); *(uint32_t *)u32tmpAddr &= u32tmpVal; } /** * @brief Set PLL frequency * @param[in] u32PllClkSrc is PLL clock source. Including : * - \ref CLK_PLLCTL_PLLSRC_HXT * - \ref CLK_PLLCTL_PLLSRC_HIRC * @param[in] u32PllFreq is PLL frequency. * @return PLL frequency * @details This function is used to configure PLLCTL register to set specified PLL frequency. \n * The register write-protection function should be disabled before using this function. */ uint32_t CLK_EnablePLL(uint32_t u32PllClkSrc, uint32_t u32PllFreq) { uint32_t u32PllSrcClk, u32NR, u32NF, u32NO, u32CLK_SRC, u32PllClk; uint32_t u32Tmp, u32Tmp2, u32Tmp3, u32Min, u32MinNF, u32MinNR, u32MinNO, u32basFreq; /* Disable PLL first to avoid unstable when setting PLL */ CLK_DisablePLL(); /* PLL source clock is from HXT */ if(u32PllClkSrc == CLK_PLLCTL_PLLSRC_HXT) { /* Enable HXT clock */ CLK->PWRCTL |= CLK_PWRCTL_HXTEN_Msk; /* Wait for HXT clock ready */ CLK_WaitClockReady(CLK_STATUS_HXTSTB_Msk); /* Select PLL source clock from HXT */ u32CLK_SRC = CLK_PLLCTL_PLLSRC_HXT; u32PllSrcClk = __HXT; /* u32NR start from 2 */ u32NR = 2UL; } /* PLL source clock is from HIRC */ else { /* Enable HIRC clock */ CLK->PWRCTL |= CLK_PWRCTL_HIRCEN_Msk; /* Wait for HIRC clock ready */ CLK_WaitClockReady(CLK_STATUS_HIRCSTB_Msk); /* Select PLL source clock from HIRC */ u32CLK_SRC = CLK_PLLCTL_PLLSRC_HIRC; u32PllSrcClk = __HIRC; /* u32NR start from 4 when FIN = 22.1184MHz to avoid calculation overflow */ u32NR = 4UL; } if((u32PllFreq <= FREQ_500MHZ) && (u32PllFreq >= FREQ_50MHZ)) { /* Find best solution */ u32Min = (uint32_t) - 1; u32MinNR = 0UL; u32MinNF = 0UL; u32MinNO = 0UL; u32basFreq = u32PllFreq; for(u32NO = 1UL; u32NO <= 4UL; u32NO++) { /* Break when get good results */ if (u32Min == 0UL) { break; } if (u32NO != 3UL) { if(u32NO == 4UL) { u32PllFreq = u32basFreq << 2; } else if(u32NO == 2UL) { u32PllFreq = u32basFreq << 1; } else { } for(u32NR = 2UL; u32NR <= 32UL; u32NR++) { /* Break when get good results */ if (u32Min == 0UL) { break; } u32Tmp = u32PllSrcClk / u32NR; if((u32Tmp >= 4000000UL) && (u32Tmp <= 8000000UL)) { for(u32NF = 2UL; u32NF <= 513UL; u32NF++) { /* u32Tmp2 is shifted 2 bits to avoid overflow */ u32Tmp2 = (((u32Tmp * 2UL) >> 2) * u32NF); if((u32Tmp2 >= FREQ_50MHZ) && (u32Tmp2 <= FREQ_125MHZ)) { u32Tmp3 = (u32Tmp2 > (u32PllFreq>>2)) ? u32Tmp2 - (u32PllFreq>>2) : (u32PllFreq>>2) - u32Tmp2; if(u32Tmp3 < u32Min) { u32Min = u32Tmp3; u32MinNR = u32NR; u32MinNF = u32NF; u32MinNO = u32NO; /* Break when get good results */ if(u32Min == 0UL) { break; } } } } } } } } /* Enable and apply new PLL setting. */ CLK->PLLCTL = u32CLK_SRC | ((u32MinNO - 1UL) << 14) | ((u32MinNR - 1UL) << 9) | (u32MinNF - 2UL); /* Wait for PLL clock stable */ CLK_WaitClockReady(CLK_STATUS_PLLSTB_Msk); /* Actual PLL output clock frequency */ u32PllClk = u32PllSrcClk / (u32MinNO * (u32MinNR)) * (u32MinNF) * 2UL; } else { /* Wrong frequency request. Just return default setting. */ /* Apply default PLL setting and return */ if(u32PllClkSrc == CLK_PLLCTL_PLLSRC_HXT) { CLK->PLLCTL = CLK_PLLCTL_192MHz_HXT; } else { CLK->PLLCTL = CLK_PLLCTL_192MHz_HIRC; } /* Wait for PLL clock stable */ CLK_WaitClockReady(CLK_STATUS_PLLSTB_Msk); /* Actual PLL output clock frequency */ u32PllClk = CLK_GetPLLClockFreq(); } return u32PllClk; } /** * @brief Disable PLL * @param None * @return None * @details This function set PLL in Power-down mode. \n * The register write-protection function should be disabled before using this function. */ void CLK_DisablePLL(void) { CLK->PLLCTL |= CLK_PLLCTL_PD_Msk; } /** * @brief This function check selected clock source status * @param[in] u32ClkMask is selected clock source. Including : * - \ref CLK_STATUS_HXTSTB_Msk * - \ref CLK_STATUS_LXTSTB_Msk * - \ref CLK_STATUS_HIRCSTB_Msk * - \ref CLK_STATUS_LIRCSTB_Msk * - \ref CLK_STATUS_PLLSTB_Msk * @retval 0 clock is not stable * @retval 1 clock is stable * @details To wait for clock ready by specified clock source stable flag or timeout (~300ms) */ uint32_t CLK_WaitClockReady(uint32_t u32ClkMask) { int32_t i32TimeOutCnt = 2160000; uint32_t u32Ret = 1U; while((CLK->STATUS & u32ClkMask) != u32ClkMask) { if(i32TimeOutCnt-- <= 0) { u32Ret = 0U; break; } } return u32Ret; } /** * @brief Enable System Tick counter * @param[in] u32ClkSrc is System Tick clock source. Including: * - \ref CLK_CLKSEL0_STCLKSEL_HXT * - \ref CLK_CLKSEL0_STCLKSEL_LXT * - \ref CLK_CLKSEL0_STCLKSEL_HXT_DIV2 * - \ref CLK_CLKSEL0_STCLKSEL_HCLK_DIV2 * - \ref CLK_CLKSEL0_STCLKSEL_HIRC_DIV2 * - \ref CLK_CLKSEL0_STCLKSEL_HCLK * @param[in] u32Count is System Tick reload value. It could be 0~0xFFFFFF. * @return None * @details This function set System Tick clock source, reload value, enable System Tick counter and interrupt. \n * The register write-protection function should be disabled before using this function. */ void CLK_EnableSysTick(uint32_t u32ClkSrc, uint32_t u32Count) { /* Set System Tick counter disabled */ SysTick->CTRL = 0UL; /* Set System Tick clock source */ if( u32ClkSrc == CLK_CLKSEL0_STCLKSEL_HCLK ) { SysTick->CTRL |= SysTick_CTRL_CLKSOURCE_Msk; } else { CLK->CLKSEL0 = (CLK->CLKSEL0 & ~CLK_CLKSEL0_STCLKSEL_Msk) | u32ClkSrc; } /* Set System Tick reload value */ SysTick->LOAD = u32Count; /* Clear System Tick current value and counter flag */ SysTick->VAL = 0UL; /* Set System Tick interrupt enabled and counter enabled */ SysTick->CTRL |= SysTick_CTRL_TICKINT_Msk | SysTick_CTRL_ENABLE_Msk; } /** * @brief Disable System Tick counter * @param None * @return None * @details This function disable System Tick counter. */ void CLK_DisableSysTick(void) { /* Set System Tick counter disabled */ SysTick->CTRL = 0UL; } /** * @brief Power-down mode selected * @param[in] u32PDMode is power down mode index. Including : * - \ref CLK_PMUCTL_PDMSEL_PD * - \ref CLK_PMUCTL_PDMSEL_LLPD * - \ref CLK_PMUCTL_PDMSEL_FWPD * - \ref CLK_PMUCTL_PDMSEL_SPD0 * - \ref CLK_PMUCTL_PDMSEL_SPD1 * - \ref CLK_PMUCTL_PDMSEL_DPD * @return None * @details This function is used to set power-down mode. * @note Must enable LIRC clock before entering to Standby Power-down Mode */ void CLK_SetPowerDownMode(uint32_t u32PDMode) { /* Enable LIRC clock before entering to Standby Power-down Mode */ if((u32PDMode == CLK_PMUCTL_PDMSEL_SPD0) || (u32PDMode == CLK_PMUCTL_PDMSEL_SPD1)) { /* Enable LIRC clock */ CLK->PWRCTL |= CLK_PWRCTL_LIRCEN_Msk; /* Wait for LIRC clock stable */ CLK_WaitClockReady(CLK_STATUS_LIRCSTB_Msk); } CLK->PMUCTL = (CLK->PMUCTL & ~(CLK_PMUCTL_PDMSEL_Msk)) | u32PDMode; } /** * @brief Set Wake-up pin trigger type at Deep Power down mode * * @param[in] u32TriggerType * - \ref CLK_DPDWKPIN_RISING * - \ref CLK_DPDWKPIN_FALLING * - \ref CLK_DPDWKPIN_BOTHEDGE * @return None * * @details This function is used to enable Wake-up pin trigger type. */ void CLK_EnableDPDWKPin(uint32_t u32TriggerType) { CLK->PMUCTL = (CLK->PMUCTL & ~(CLK_PMUCTL_WKPINEN_Msk)) | u32TriggerType; } /** * @brief Get power manager wake up source * * @param[in] None * @return None * * @details This function get power manager wake up source. */ uint32_t CLK_GetPMUWKSrc(void) { return (CLK->PMUSTS); } /** * @brief Set specified GPIO as wake up source at Stand-by Power down mode * * @param[in] u32Port GPIO port. It could be 0~3. * @param[in] u32Pin The pin of specified GPIO port. It could be 0 ~ 15. * @param[in] u32TriggerType * - \ref CLK_SPDWKPIN_RISING * - \ref CLK_SPDWKPIN_FALLING * @param[in] u32DebounceEn * - \ref CLK_SPDWKPIN_DEBOUNCEEN * - \ref CLK_SPDWKPIN_DEBOUNCEDIS * @return None * * @details This function is used to set specified GPIO as wake up source * at Stand-by Power down mode. */ void CLK_EnableSPDWKPin(uint32_t u32Port, uint32_t u32Pin, uint32_t u32TriggerType, uint32_t u32DebounceEn) { uint32_t u32tmpAddr = 0UL; uint32_t u32tmpVal = 0UL; /* GPx Stand-by Power-down Wake-up Pin Select */ u32tmpAddr = (uint32_t)&CLK->PASWKCTL; u32tmpAddr += (0x4UL * u32Port); u32tmpVal = inpw((uint32_t *)u32tmpAddr); u32tmpVal = (u32tmpVal & ~(CLK_PASWKCTL_WKPSEL_Msk | CLK_PASWKCTL_PRWKEN_Msk | CLK_PASWKCTL_PFWKEN_Msk | CLK_PASWKCTL_DBEN_Msk | CLK_PASWKCTL_WKEN_Msk)) | (u32Pin << CLK_PASWKCTL_WKPSEL_Pos) | u32TriggerType | u32DebounceEn | CLK_SPDWKPIN_ENABLE; outpw((uint32_t *)u32tmpAddr, u32tmpVal); } /** * @brief Get PLL clock frequency * @param None * @return PLL frequency * @details This function get PLL frequency. The frequency unit is Hz. */ uint32_t CLK_GetPLLClockFreq(void) { uint32_t u32PllFreq = 0UL, u32PllReg; uint32_t u32FIN, u32NF, u32NR, u32NO; uint8_t au8NoTbl[4] = {1U, 2U, 2U, 4U}; u32PllReg = CLK->PLLCTL; if(u32PllReg & (CLK_PLLCTL_PD_Msk | CLK_PLLCTL_OE_Msk)) { u32PllFreq = 0UL; /* PLL is in power down mode or fix low */ } else if((u32PllReg & CLK_PLLCTL_BP_Msk) == CLK_PLLCTL_BP_Msk) { if((u32PllReg & CLK_PLLCTL_PLLSRC_HIRC) == CLK_PLLCTL_PLLSRC_HIRC) { u32FIN = __HIRC; /* PLL source clock from HIRC */ } else { u32FIN = __HXT; /* PLL source clock from HXT */ } u32PllFreq = u32FIN; } else { if((u32PllReg & CLK_PLLCTL_PLLSRC_HIRC) == CLK_PLLCTL_PLLSRC_HIRC) { u32FIN = __HIRC; /* PLL source clock from HIRC */ } else { u32FIN = __HXT; /* PLL source clock from HXT */ } /* PLL is output enabled in normal work mode */ u32NO = au8NoTbl[((u32PllReg & CLK_PLLCTL_OUTDIV_Msk) >> CLK_PLLCTL_OUTDIV_Pos)]; u32NF = ((u32PllReg & CLK_PLLCTL_FBDIV_Msk) >> CLK_PLLCTL_FBDIV_Pos) + 2UL; u32NR = ((u32PllReg & CLK_PLLCTL_INDIV_Msk) >> CLK_PLLCTL_INDIV_Pos) + 1UL; /* u32FIN is shifted 2 bits to avoid overflow */ u32PllFreq = (((u32FIN >> 2) * u32NF) / (u32NR * u32NO) << 2) * 2UL; } return u32PllFreq; } /** * @brief Get selected module clock source * @param[in] u32ModuleIdx is module index. * - \ref SDH0_MODULE * - \ref SDH1_MODULE * - \ref WDT_MODULE * - \ref UART0_MODULE * - \ref UART1_MODULE * - \ref CLKO_MODULE * - \ref WWDT_MODULE * - \ref TMR0_MODULE * - \ref TMR1_MODULE * - \ref TMR2_MODULE * - \ref TMR3_MODULE * - \ref EPWM0_MODULE * - \ref EPWM1_MODULE * - \ref BPWM0_MODULE * - \ref BPWM1_MODULE * - \ref QSPI0_MODULE * - \ref SPI0_MODULE * - \ref SPI1_MODULE * - \ref SPI2_MODULE * - \ref SPI3_MODULE * - \ref SC0_MODULE * - \ref SC1_MODULE * - \ref SC2_MODULE * - \ref RTC_MODULE * - \ref I2S0_MODULE * - \ref UART2_MODULE * - \ref UART3_MODULE * - \ref UART4_MODULE * - \ref UART5_MODULE * @return Selected module clock source setting * @details This function get selected module clock source. */ uint32_t CLK_GetModuleClockSource(uint32_t u32ModuleIdx) { uint32_t u32sel = 0; uint32_t u32SelTbl[4] = {0x0, 0x4, 0x8, 0xC}; /* Get clock source selection setting */ if(u32ModuleIdx == EPWM0_MODULE) return ((CLK->CLKSEL2 & CLK_CLKSEL2_EPWM0SEL_Msk) >> CLK_CLKSEL2_EPWM0SEL_Pos); else if(u32ModuleIdx == EPWM1_MODULE) return ((CLK->CLKSEL2 & CLK_CLKSEL2_EPWM1SEL_Msk) >> CLK_CLKSEL2_EPWM1SEL_Pos); else if(u32ModuleIdx == BPWM0_MODULE) return ((CLK->CLKSEL2 & CLK_CLKSEL2_BPWM0SEL_Msk) >> CLK_CLKSEL2_BPWM0SEL_Pos); else if(u32ModuleIdx == BPWM1_MODULE) return ((CLK->CLKSEL2 & CLK_CLKSEL2_BPWM1SEL_Msk) >> CLK_CLKSEL2_BPWM1SEL_Pos); else if(MODULE_CLKSEL_Msk(u32ModuleIdx) != MODULE_NoMsk) { /* Get clock select control register address */ u32sel = (uint32_t)&CLK->CLKSEL0 + (u32SelTbl[MODULE_CLKSEL(u32ModuleIdx)]); /* Get clock source selection setting */ return ((M32(u32sel) & (MODULE_CLKSEL_Msk(u32ModuleIdx) << MODULE_CLKSEL_Pos(u32ModuleIdx))) >> MODULE_CLKSEL_Pos(u32ModuleIdx)); } else return 0; } /** * @brief Get selected module clock divider number * @param[in] u32ModuleIdx is module index. * - \ref UART0_MODULE * - \ref UART1_MODULE * - \ref EADC_MODULE * - \ref SDH0_MODULE * - \ref SC0_MODULE * - \ref SC1_MODULE * - \ref SC2_MODULE * - \ref EMAC_MODULE * - \ref SDH1_MODULE * - \ref UART2_MODULE * - \ref UART3_MODULE * - \ref UART4_MODULE * - \ref UART5_MODULE * @return Selected module clock divider number setting * @details This function get selected module clock divider number. */ uint32_t CLK_GetModuleClockDivider(uint32_t u32ModuleIdx) { uint32_t u32div = 0; uint32_t u32DivTbl[4] = {0x0, 0x4, 0x8, 0x10}; if(MODULE_CLKDIV_Msk(u32ModuleIdx) != MODULE_NoMsk) { /* Get clock divider control register address */ u32div = (uint32_t)&CLK->CLKDIV0 + (u32DivTbl[MODULE_CLKDIV(u32ModuleIdx)]); /* Get clock divider number setting */ return ((M32(u32div) & (MODULE_CLKDIV_Msk(u32ModuleIdx) << MODULE_CLKDIV_Pos(u32ModuleIdx))) >> MODULE_CLKDIV_Pos(u32ModuleIdx)); } else return 0; } /*@}*/ /* end of group CLK_EXPORTED_FUNCTIONS */ /*@}*/ /* end of group CLK_Driver */ /*@}*/ /* end of group Standard_Driver */ /*** (C) COPYRIGHT 2016 Nuvoton Technology Corp. ***/