/* ** ################################################################### ** Compilers: Keil ARM C/C++ Compiler ** Freescale C/C++ for Embedded ARM ** GNU C Compiler ** GNU C Compiler - CodeSourcery Sourcery G++ ** IAR ANSI C/C++ Compiler for ARM ** ** Reference manual: MKW40Z160RM, Rev. 1.1, 4/2015 ** Version: rev. 1.2, 2015-05-07 ** Build: b150513 ** ** Abstract: ** Provides a system configuration function and a global variable that ** contains the system frequency. It configures the device and initializes ** the oscillator (PLL) that is part of the microcontroller device. ** ** Copyright (c) 2015 Freescale Semiconductor, Inc. ** All rights reserved. ** ** Redistribution and use in source and binary forms, with or without modification, ** are permitted provided that the following conditions are met: ** ** o Redistributions of source code must retain the above copyright notice, this list ** of conditions and the following disclaimer. ** ** o 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. ** ** o Neither the name of Freescale Semiconductor, Inc. nor the names of its ** contributors may be used to endorse or promote products derived from this ** software without specific prior written permission. ** ** 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. ** ** http: www.freescale.com ** mail: support@freescale.com ** ** Revisions: ** - rev. 1.0 (2014-08-27) ** Initial version. ** - rev. 1.1 (2015-03-05) ** Update with reference manual rev 1.0 ** - rev. 1.2 (2015-05-07) ** Update with reference manual rev 1.1 ** ** ################################################################### */ /*! * @file MKW30Z4 * @version 1.2 * @date 2015-05-07 * @brief Device specific configuration file for MKW30Z4 (implementation file) * * Provides a system configuration function and a global variable that contains * the system frequency. It configures the device and initializes the oscillator * (PLL) that is part of the microcontroller device. */ #include #include "fsl_device_registers.h" /* ---------------------------------------------------------------------------- -- Core clock ---------------------------------------------------------------------------- */ uint32_t SystemCoreClock = DEFAULT_SYSTEM_CLOCK; /* ---------------------------------------------------------------------------- -- SystemInit() ---------------------------------------------------------------------------- */ void SystemInit (void) { #if (DISABLE_WDOG) /* SIM_COPC: COPT=0,COPCLKS=0,COPW=0 */ SIM->COPC = (uint32_t)0x00u; #endif /* (DISABLE_WDOG) */ #ifdef CLOCK_SETUP if((RCM->SRS0 & RCM_SRS0_WAKEUP_MASK) != 0x00U) { if((PMC->REGSC & PMC_REGSC_ACKISO_MASK) != 0x00U) { PMC->REGSC |= PMC_REGSC_ACKISO_MASK; /* Release hold with ACKISO: Only has an effect if recovering from VLLSx.*/ } } else { #ifdef SYSTEM_RTC_CR_VALUE SIM->SCGC5 |= SIM_SCGC5_PORTB_MASK; SIM_SCGC6 |= SIM_SCGC6_RTC_MASK; /* PORTB_PCR18: ISF=0,MUX=0 */ PORTB->PCR[16] &= (uint32_t)~(uint32_t)((PORT_PCR_ISF_MASK | PORT_PCR_MUX(0x07))); /* PORTA_PCR19: ISF=0,MUX=0 */ PORTB->PCR[17] &= (uint32_t)~(uint32_t)((PORT_PCR_ISF_MASK | PORT_PCR_MUX(0x07))); if ((RTC->CR & RTC_CR_OSCE_MASK) == 0x00U) { /* Only if the OSCILLATOR is not already enabled */ RTC->CR = (uint32_t)((RTC_CR & (uint32_t)~(uint32_t)(RTC_CR_SC2P_MASK | RTC_CR_SC4P_MASK | RTC_CR_SC8P_MASK | RTC_CR_SC16P_MASK)) | (uint32_t)SYSTEM_RTC_CR_VALUE); RTC->CR |= (uint32_t)RTC_CR_OSCE_MASK; RTC->CR &= (uint32_t)~(uint32_t)RTC_CR_CLKO_MASK; } #endif } /* Power mode protection initialization */ #ifdef SYSTEM_SMC_PMPROT_VALUE SMC->PMPROT = SYSTEM_SMC_PMPROT_VALUE; #endif /* RF oscillator setting */ #if defined(SYSTEM_RSIM_CONTROL_VALUE) RSIM->CONTROL = SYSTEM_RSIM_CONTROL_VALUE; #endif /* System clock initialization */ /* Internal reference clock trim initialization */ #if defined(SLOW_TRIM_ADDRESS) if ( *((uint8_t*)SLOW_TRIM_ADDRESS) != 0xFFU) { /* Skip if non-volatile flash memory is erased */ MCG->C3 = *((uint8_t*)SLOW_TRIM_ADDRESS); #endif /* defined(SLOW_TRIM_ADDRESS) */ #if defined(SLOW_FINE_TRIM_ADDRESS) MCG->C4 = (MCG->C4 & ~(MCG_C4_SCFTRIM_MASK)) | ((*((uint8_t*) SLOW_FINE_TRIM_ADDRESS)) & MCG_C4_SCFTRIM_MASK); #endif #if defined(FAST_TRIM_ADDRESS) MCG->C4 = (MCG->C4 & ~(MCG_C4_FCTRIM_MASK)) |((*((uint8_t*) FAST_TRIM_ADDRESS)) & MCG_C4_FCTRIM_MASK); #endif #if defined(FAST_FINE_TRIM_ADDRESS) MCG->C2 = (MCG->C2 & ~(MCG_C2_FCFTRIM_MASK)) | ((*((uint8_t*)FAST_TRIM_ADDRESS)) & MCG_C2_FCFTRIM_MASK); #endif /* defined(FAST_FINE_TRIM_ADDRESS) */ #if defined(SLOW_TRIM_ADDRESS) } #endif /* defined(SLOW_TRIM_ADDRESS) */ /* Set system prescalers and clock sources */ SIM->CLKDIV1 = SYSTEM_SIM_CLKDIV1_VALUE; /* Set system prescalers */ SIM->SOPT1 = ((SIM->SOPT1) & (uint32_t)(~(SIM_SOPT1_OSC32KSEL_MASK))) | ((SYSTEM_SIM_SOPT1_VALUE) & (SIM_SOPT1_OSC32KSEL_MASK)); /* Set 32 kHz clock source (ERCLK32K) */ SIM->SOPT2 = ((SIM->SOPT2) & (uint32_t)(~(SIM_SOPT2_TPMSRC_MASK))) | ((SYSTEM_SIM_SOPT2_VALUE) & (SIM_SOPT2_TPMSRC_MASK)); /* Selects the clock source for the TPM counter clock. */ #if ((MCG_MODE == MCG_MODE_FEI) || (MCG_MODE == MCG_MODE_FBI) || (MCG_MODE == MCG_MODE_BLPI)) /* Set MCG */ MCG->SC = SYSTEM_MCG_SC_VALUE; /* Set SC (fast clock internal reference divider) */ MCG->C1 = SYSTEM_MCG_C1_VALUE; /* Set C1 (clock source selection, FLL ext. reference divider, int. reference enable etc.) */ /* Check that the source of the FLL reference clock is the requested one. */ if (((SYSTEM_MCG_C1_VALUE) & MCG_C1_IREFS_MASK) != 0x00U) { while((MCG->S & MCG_S_IREFST_MASK) == 0x00U) { } } else { while((MCG->S & MCG_S_IREFST_MASK) != 0x00U) { } } MCG->C2 = (MCG->C2 & (uint8_t)(~(MCG_C2_FCFTRIM_MASK))) | (SYSTEM_MCG_C2_VALUE & (uint8_t)(~(MCG_C2_LP_MASK))); /* Set C2 (freq. range, ext. and int. reference selection etc. excluding trim bits; low power bit is set later) */ MCG->C4 = ((SYSTEM_MCG_C4_VALUE) & (uint8_t)(~(MCG_C4_FCTRIM_MASK | MCG_C4_SCFTRIM_MASK))) | (MCG->C4 & (MCG_C4_FCTRIM_MASK | MCG_C4_SCFTRIM_MASK)); /* Set C4 (FLL output; trim values not changed) */ MCG->C7 = SYSTEM_MCG_C7_VALUE; /* Set C7 (OSC Clock Select) */ #if (MCG_MODE == MCG_MODE_BLPI) /* BLPI specific */ MCG->C2 |= (MCG_C2_LP_MASK); /* Disable FLL and PLL in bypass mode */ #endif #else /* MCG_MODE */ /* Set MCG */ MCG->SC = SYSTEM_MCG_SC_VALUE; /* Set SC (fast clock internal reference divider) */ MCG->C2 = (MCG->C2 & (uint8_t)(~(MCG_C2_FCFTRIM_MASK))) | (SYSTEM_MCG_C2_VALUE & (uint8_t)(~(MCG_C2_LP_MASK))); /* Set C2 (freq. range, ext. and int. reference selection etc. excluding trim bits; low power bit is set later) */ MCG->C7 = SYSTEM_MCG_C7_VALUE; /* Set C7 (OSC Clock Select) */ MCG->C1 = SYSTEM_MCG_C1_VALUE; /* Set C1 (clock source selection, FLL ext. reference divider, int. reference enable etc.) */ /* Check that the source of the FLL reference clock is the requested one. */ if (((SYSTEM_MCG_C1_VALUE) & MCG_C1_IREFS_MASK) != 0x00U) { while((MCG->S & MCG_S_IREFST_MASK) == 0x00U) { } } else { while((MCG->S & MCG_S_IREFST_MASK) != 0x00U) { } } MCG->C4 = ((SYSTEM_MCG_C4_VALUE) & (uint8_t)(~(MCG_C4_FCTRIM_MASK | MCG_C4_SCFTRIM_MASK))) | (MCG->C4 & (MCG_C4_FCTRIM_MASK | MCG_C4_SCFTRIM_MASK)); /* Set C4 (FLL output; trim values not changed) */ #endif /* MCG_MODE */ /* Common for all modes */ MCG->C6 = (SYSTEM_MCG_C6_VALUE); /* Set C6 (Clock monitor enable) */ #if ((MCG_MODE == MCG_MODE_BLPI) || (MCG_MODE == MCG_MODE_BLPE)) MCG->C2 |= (MCG_C2_LP_MASK); /* Disable FLL in bypass mode */ #endif #if ((MCG_MODE == MCG_MODE_FEI) || (MCG_MODE == MCG_MODE_FEE)) while((MCG->S & MCG_S_CLKST_MASK) != 0x00U) { /* Wait until output of the FLL is selected */ } #elif ((MCG_MODE == MCG_MODE_FBI) || (MCG_MODE == MCG_MODE_BLPI)) while((MCG->S & MCG_S_CLKST_MASK) != 0x04U) { /* Wait until internal reference clock is selected as MCG output */ } #elif ((MCG_MODE == MCG_MODE_FBE) || (MCG_MODE == MCG_MODE_BLPE)) while((MCG->S & MCG_S_CLKST_MASK) != 0x08U) { /* Wait until external reference clock is selected as MCG output */ } #endif #if (((SYSTEM_SMC_PMCTRL_VALUE) & SMC_PMCTRL_RUNM_MASK) == (0x02U << SMC_PMCTRL_RUNM_SHIFT)) SMC->PMCTRL = (uint8_t)((SYSTEM_SMC_PMCTRL_VALUE) & (SMC_PMCTRL_RUNM_MASK)); /* Enable VLPR mode */ while(SMC->PMSTAT != 0x04U) { /* Wait until the system is in VLPR mode */ } #endif #endif } /* ---------------------------------------------------------------------------- -- SystemCoreClockUpdate() ---------------------------------------------------------------------------- */ void SystemCoreClockUpdate (void) { uint32_t MCGOUTClock; /* Variable to store output clock frequency of the MCG module */ uint16_t Divider; if ((MCG->C1 & MCG_C1_CLKS_MASK) == 0x00U) { /* FLL is selected */ if ((MCG->C1 & MCG_C1_IREFS_MASK) == 0x00U) { /* External reference clock is selected */ if((MCG->C7 & MCG_C7_OSCSEL_MASK) == 0x00U) { MCGOUTClock = CPU_XTAL_CLK_HZ; /* System oscillator drives MCG clock */ } else { MCGOUTClock = CPU_XTAL32k_CLK_HZ; /* RTC 32 kHz oscillator drives MCG clock */ } if (((MCG->C2 & MCG_C2_RANGE_MASK) != 0x00U) && ((MCG->C7 & MCG_C7_OSCSEL_MASK) != 0x01U)) { switch (MCG->C1 & MCG_C1_FRDIV_MASK) { case 0x38U: Divider = 1536U; break; case 0x30U: Divider = 1280U; break; default: Divider = (uint16_t)(32LU << ((MCG->C1 & MCG_C1_FRDIV_MASK) >> MCG_C1_FRDIV_SHIFT)); break; } } else {/* ((MCG->C2 & MCG_C2_RANGE_MASK) != 0x00U) */ Divider = (uint16_t)(1LU << ((MCG->C1 & MCG_C1_FRDIV_MASK) >> MCG_C1_FRDIV_SHIFT)); } MCGOUTClock = (MCGOUTClock / Divider); /* Calculate the divided FLL reference clock */ } else { /* (!((MCG->C1 & MCG_C1_IREFS_MASK) == 0x00U)) */ MCGOUTClock = CPU_INT_SLOW_CLK_HZ; /* The slow internal reference clock is selected */ } /* (!((MCG->C1 & MCG_C1_IREFS_MASK) == 0x00U)) */ /* Select correct multiplier to calculate the MCG output clock */ switch (MCG->C4 & (MCG_C4_DMX32_MASK | MCG_C4_DRST_DRS_MASK)) { case 0x00U: MCGOUTClock *= 640U; break; case 0x20U: MCGOUTClock *= 1280U; break; case 0x40U: MCGOUTClock *= 1920U; break; case 0x60U: MCGOUTClock *= 2560U; break; case 0x80U: MCGOUTClock *= 732U; break; case 0xA0U: MCGOUTClock *= 1464U; break; case 0xC0U: MCGOUTClock *= 2197U; break; case 0xE0U: MCGOUTClock *= 2929U; break; default: break; } } else if ((MCG->C1 & MCG_C1_CLKS_MASK) == 0x40U) { /* Internal reference clock is selected */ if ((MCG->C2 & MCG_C2_IRCS_MASK) == 0x00U) { MCGOUTClock = CPU_INT_SLOW_CLK_HZ; /* Slow internal reference clock selected */ } else { /* (!((MCG->C2 & MCG_C2_IRCS_MASK) == 0x00U)) */ Divider = (uint16_t)(0x01LU << ((MCG->SC & MCG_SC_FCRDIV_MASK) >> MCG_SC_FCRDIV_SHIFT)); MCGOUTClock = (uint32_t) (CPU_INT_FAST_CLK_HZ / Divider); /* Fast internal reference clock selected */ } /* (!((MCG->C2 & MCG_C2_IRCS_MASK) == 0x00U)) */ } else if ((MCG->C1 & MCG_C1_CLKS_MASK) == 0x80U) { /* External reference clock is selected */ if((MCG->C7 & MCG_C7_OSCSEL_MASK) == 0x00U) { MCGOUTClock = CPU_XTAL_CLK_HZ; /* System oscillator drives MCG clock */ } else { MCGOUTClock = CPU_XTAL32k_CLK_HZ; /* RTC 32 kHz oscillator drives MCG clock */ } } else { /* (!((MCG->C1 & MCG_C1_CLKS_MASK) == 0x80U)) */ /* Reserved value */ return; } /* (!((MCG->C1 & MCG_C1_CLKS_MASK) == 0x80U)) */ SystemCoreClock = (MCGOUTClock / (0x01U + ((SIM->CLKDIV1 & SIM_CLKDIV1_OUTDIV1_MASK) >> SIM_CLKDIV1_OUTDIV1_SHIFT))); }