/* ** ################################################################### ** Processor: LPC5502JHI48CPXXXX ** Compilers: GNU C Compiler ** IAR ANSI C/C++ Compiler for ARM ** Keil ARM C/C++ Compiler ** MCUXpresso Compiler ** ** Reference manual: LPC55S0x/LPC550x User manual Rev.0.3 14 August 2020 ** Version: rev. 1.0, 2020-04-09 ** Build: b220117 ** ** 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 2016 Freescale Semiconductor, Inc. ** Copyright 2016-2022 NXP ** All rights reserved. ** ** SPDX-License-Identifier: BSD-3-Clause ** ** http: www.nxp.com ** mail: support@nxp.com ** ** Revisions: ** - rev. 1.0 (2020-04-09) ** Initial version based on Niobe4mini ** ** ################################################################### */ /*! * @file LPC5502CPXXXX * @version 1.0 * @date 2020-04-09 * @brief Device specific configuration file for LPC5502CPXXXX (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" /* PLL0 SSCG control1 */ #define PLL_SSCG_MD_FRACT_P 0U #define PLL_SSCG_MD_INT_P 25U #define PLL_SSCG_MD_FRACT_M (0x1FFFFFFUL << PLL_SSCG_MD_FRACT_P) #define PLL_SSCG_MD_INT_M ((uint64_t)0xFFUL << PLL_SSCG_MD_INT_P) /* Get predivider (N) from PLL0 NDEC setting */ static uint32_t findPll0PreDiv(void) { uint32_t preDiv = 1UL; /* Direct input is not used? */ if ((SYSCON->PLL0CTRL & SYSCON_PLL0CTRL_BYPASSPREDIV_MASK) == 0UL) { preDiv = SYSCON->PLL0NDEC & SYSCON_PLL0NDEC_NDIV_MASK; if (preDiv == 0UL) { preDiv = 1UL; } } return preDiv; } /* Get postdivider (P) from PLL0 PDEC setting */ static uint32_t findPll0PostDiv(void) { uint32_t postDiv = 1; if ((SYSCON->PLL0CTRL & SYSCON_PLL0CTRL_BYPASSPOSTDIV_MASK) == 0UL) { if ((SYSCON->PLL0CTRL & SYSCON_PLL0CTRL_BYPASSPOSTDIV2_MASK) != 0UL) { postDiv = SYSCON->PLL0PDEC & SYSCON_PLL0PDEC_PDIV_MASK; } else { postDiv = 2UL * (SYSCON->PLL0PDEC & SYSCON_PLL0PDEC_PDIV_MASK); } if (postDiv == 0UL) { postDiv = 2UL; } } return postDiv; } /* Get multiplier (M) from PLL0 SSCG and SEL_EXT settings */ static float findPll0MMult(void) { float mMult = 1.0F; float mMult_fract; uint32_t mMult_int; if ((SYSCON->PLL0SSCG1 & SYSCON_PLL0SSCG1_SEL_EXT_MASK) != 0UL) { mMult = (float)(uint32_t)((SYSCON->PLL0SSCG1 & SYSCON_PLL0SSCG1_MDIV_EXT_MASK) >> SYSCON_PLL0SSCG1_MDIV_EXT_SHIFT); } else { mMult_int = ((SYSCON->PLL0SSCG1 & SYSCON_PLL0SSCG1_MD_MBS_MASK) << 7U); mMult_int = mMult_int | ((SYSCON->PLL0SSCG0) >> PLL_SSCG_MD_INT_P); mMult_fract = ((float)(uint32_t)((SYSCON->PLL0SSCG0) & PLL_SSCG_MD_FRACT_M) / (float)(uint32_t)(1UL << PLL_SSCG_MD_INT_P)); mMult = (float)mMult_int + mMult_fract; } if (0ULL == ((uint64_t)mMult)) { mMult = 1.0F; } return mMult; } /* Get predivider (N) from PLL1 NDEC setting */ static uint32_t findPll1PreDiv(void) { uint32_t preDiv = 1UL; /* Direct input is not used? */ if ((SYSCON->PLL1CTRL & SYSCON_PLL1CTRL_BYPASSPREDIV_MASK) == 0UL) { preDiv = SYSCON->PLL1NDEC & SYSCON_PLL1NDEC_NDIV_MASK; if (preDiv == 0UL) { preDiv = 1UL; } } return preDiv; } /* Get postdivider (P) from PLL1 PDEC setting */ static uint32_t findPll1PostDiv(void) { uint32_t postDiv = 1UL; if ((SYSCON->PLL1CTRL & SYSCON_PLL1CTRL_BYPASSPOSTDIV_MASK) == 0UL) { if ((SYSCON->PLL1CTRL & SYSCON_PLL1CTRL_BYPASSPOSTDIV2_MASK) != 0UL) { postDiv = SYSCON->PLL1PDEC & SYSCON_PLL1PDEC_PDIV_MASK; } else { postDiv = 2UL * (SYSCON->PLL1PDEC & SYSCON_PLL1PDEC_PDIV_MASK); } if (postDiv == 0UL) { postDiv = 2UL; } } return postDiv; } /* Get multiplier (M) from PLL1 MDEC settings */ static uint32_t findPll1MMult(void) { uint32_t mMult = 1UL; mMult = SYSCON->PLL1MDEC & SYSCON_PLL1MDEC_MDIV_MASK; if (mMult == 0UL) { mMult = 1UL; } return mMult; } /* Get FRO 12M Clk */ /*! brief Return Frequency of FRO 12MHz * return Frequency of FRO 12MHz */ static uint32_t GetFro12MFreq(void) { return ((ANACTRL->FRO192M_CTRL & ANACTRL_FRO192M_CTRL_ENA_12MHZCLK_MASK) != 0UL) ? 12000000U : 0U; } /* Get FRO 1M Clk */ /*! brief Return Frequency of FRO 1MHz * return Frequency of FRO 1MHz */ static uint32_t GetFro1MFreq(void) { return ((SYSCON->CLOCK_CTRL & SYSCON_CLOCK_CTRL_FRO1MHZ_CLK_ENA_MASK) != 0UL) ? 1000000U : 0U; } /* Get EXT OSC Clk */ /*! brief Return Frequency of External Clock * return Frequency of External Clock. If no external clock is used returns 0. */ static uint32_t GetExtClkFreq(void) { return ((ANACTRL->XO32M_CTRL & ANACTRL_XO32M_CTRL_ENABLE_SYSTEM_CLK_OUT_MASK) != 0UL) ? CLK_CLK_IN : 0U; } /* Get HF FRO Clk */ /*! brief Return Frequency of High-Freq output of FRO * return Frequency of High-Freq output of FRO */ static uint32_t GetFroHfFreq(void) { return ((ANACTRL->FRO192M_CTRL & ANACTRL_FRO192M_CTRL_ENA_96MHZCLK_MASK) != 0UL) ? 96000000U : 0U; } /* Get RTC OSC Clk */ /*! brief Return Frequency of 32kHz osc * return Frequency of 32kHz osc */ static uint32_t GetOsc32KFreq(void) { return ((0UL == (PMC->PDRUNCFG0 & PMC_PDRUNCFG0_PDEN_FRO32K_MASK)) && (0UL == (PMC->RTCOSC32K & PMC_RTCOSC32K_SEL_MASK))) ? CLK_RTC_32K_CLK : ((0UL == (PMC->PDRUNCFG0 & PMC_PDRUNCFG0_PDEN_XTAL32K_MASK)) && ((PMC->RTCOSC32K & PMC_RTCOSC32K_SEL_MASK) != 0UL)) ? CLK_RTC_32K_CLK : 0U; } /* ---------------------------------------------------------------------------- -- Core clock ---------------------------------------------------------------------------- */ uint32_t SystemCoreClock = DEFAULT_SYSTEM_CLOCK; /* ---------------------------------------------------------------------------- -- SystemInit() ---------------------------------------------------------------------------- */ __attribute__ ((weak)) void SystemInit (void) { #if ((__FPU_PRESENT == 1) && (__FPU_USED == 1)) SCB->CPACR |= ((3UL << 10*2) | (3UL << 11*2)); /* set CP10, CP11 Full Access in Secure mode */ #if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) SCB_NS->CPACR |= ((3UL << 10*2) | (3UL << 11*2)); /* set CP10, CP11 Full Access in Non-secure mode */ #endif /* (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) */ #endif /* ((__FPU_PRESENT == 1) && (__FPU_USED == 1)) */ SCB->CPACR |= ((3UL << 0*2) | (3UL << 1*2)); /* set CP0, CP1 Full Access in Secure mode (enable PowerQuad) */ #if defined (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) SCB_NS->CPACR |= ((3UL << 0*2) | (3UL << 1*2)); /* set CP0, CP1 Full Access in Normal mode (enable PowerQuad) */ #endif /* (__ARM_FEATURE_CMSE) && (__ARM_FEATURE_CMSE == 3U) */ SCB->NSACR |= ((3UL << 0) | (3UL << 10)); /* enable CP0, CP1, CP10, CP11 Non-secure Access */ #if defined(__MCUXPRESSO) extern void(*const g_pfnVectors[]) (void); SCB->VTOR = (uint32_t) &g_pfnVectors; #else extern void *__Vectors; SCB->VTOR = (uint32_t) &__Vectors; #endif SYSCON->TRACECLKDIV = 0; /* Optionally enable RAM banks that may be off by default at reset */ #if !defined(DONT_ENABLE_DISABLED_RAMBANKS) SYSCON->AHBCLKCTRLSET[0] = SYSCON_AHBCLKCTRL0_SRAM_CTRL1_MASK | SYSCON_AHBCLKCTRL0_SRAM_CTRL2_MASK; SYSCON->AHBCLKCTRLSET[2] = SYSCON_AHBCLKCTRL2_SRAM_CTRL3_MASK; #endif /* Following code is to reset PUF to remove over consumption */ /* Enable PUF register clock to access register */ SYSCON->AHBCLKCTRLSET[2] = SYSCON_AHBCLKCTRL2_PUF_MASK; /* Release PUF reset */ SYSCON->PRESETCTRLCLR[2] = SYSCON_PRESETCTRL2_PUF_RST_MASK ; /* Enable PUF SRAM */ #define PUF_SRAM_CTRL_CFG (*((volatile uint32_t*)(0x4003B000u + 0x300u))) #define PUF_SRAM_CTRL_INT_STATUS (*((volatile uint32_t*)(0x4003B000u + 0x3E0u))) PUF_SRAM_CTRL_CFG |= 0x01 | 0x04 ; /* Disable PUF register clock. */ // Delaying the line of code below until the PUF State Machine execution is completed: // Shutting down the clock to early will prevent the state machine from reaching the end. // => Wait for status bit in PUF Controller Registers before stop PUF clock. while(!(PUF_SRAM_CTRL_INT_STATUS & 0x1)); SYSCON->AHBCLKCTRLCLR[2] = SYSCON_AHBCLKCTRL2_PUF_MASK ; SystemInitHook(); } /* ---------------------------------------------------------------------------- -- SystemCoreClockUpdate() ---------------------------------------------------------------------------- */ void SystemCoreClockUpdate (void) { uint32_t clkRate = 0; uint32_t prediv, postdiv; uint64_t workRate; uint64_t workRate1; switch (SYSCON->MAINCLKSELB & SYSCON_MAINCLKSELB_SEL_MASK) { case 0x00: /* MAINCLKSELA clock (main_clk_a)*/ switch (SYSCON->MAINCLKSELA & SYSCON_MAINCLKSELA_SEL_MASK) { case 0x00: /* FRO 12 MHz (fro_12m) */ clkRate = GetFro12MFreq(); break; case 0x01: /* CLKIN (clk_in) */ clkRate = GetExtClkFreq(); break; case 0x02: /* Fro 1MHz (fro_1m) */ clkRate = GetFro1MFreq(); break; default: /* = 0x03 = FRO 96 MHz (fro_hf) */ clkRate = GetFroHfFreq(); break; } break; case 0x01: /* PLL0 clock (pll0_clk)*/ switch (SYSCON->PLL0CLKSEL & SYSCON_PLL0CLKSEL_SEL_MASK) { case 0x00: /* FRO 12 MHz (fro_12m) */ clkRate = GetFro12MFreq(); break; case 0x01: /* CLKIN (clk_in) */ clkRate = GetExtClkFreq(); break; case 0x02: /* Fro 1MHz (fro_1m) */ clkRate = GetFro1MFreq(); break; case 0x03: /* RTC oscillator 32 kHz output (32k_clk) */ clkRate = GetOsc32KFreq(); break; default: clkRate = 0UL; break; } if (((SYSCON->PLL0CTRL & SYSCON_PLL0CTRL_BYPASSPLL_MASK) == 0UL) && ((SYSCON->PLL0CTRL & SYSCON_PLL0CTRL_CLKEN_MASK) != 0UL) && ((PMC->PDRUNCFG0 & PMC_PDRUNCFG0_PDEN_PLL0_MASK) == 0UL) && ((PMC->PDRUNCFG0 & PMC_PDRUNCFG0_PDEN_PLL0_SSCG_MASK) == 0UL)) { prediv = findPll0PreDiv(); postdiv = findPll0PostDiv(); /* Adjust input clock */ clkRate = clkRate / prediv; /* MDEC used for rate */ workRate = (uint64_t)clkRate * (uint64_t)findPll0MMult(); clkRate = (uint32_t)(workRate / ((uint64_t)postdiv)); } break; case 0x02: /* PLL1 clock (pll1_clk)*/ switch (SYSCON->PLL1CLKSEL & SYSCON_PLL1CLKSEL_SEL_MASK) { case 0x00: /* FRO 12 MHz (fro_12m) */ clkRate = GetFro12MFreq(); break; case 0x01: /* CLKIN (clk_in) */ clkRate = GetExtClkFreq(); break; case 0x02: /* Fro 1MHz (fro_1m) */ clkRate = GetFro1MFreq(); break; case 0x03: /* RTC oscillator 32 kHz output (32k_clk) */ clkRate = GetOsc32KFreq(); break; default: clkRate = 0UL; break; } if (((SYSCON->PLL1CTRL & SYSCON_PLL1CTRL_BYPASSPLL_MASK) == 0UL) && ((SYSCON->PLL1CTRL & SYSCON_PLL1CTRL_CLKEN_MASK) != 0UL) && ((PMC->PDRUNCFG0 & PMC_PDRUNCFG0_PDEN_PLL1_MASK) == 0UL)) { /* PLL is not in bypass mode, get pre-divider, post-divider, and M divider */ prediv = findPll1PreDiv(); postdiv = findPll1PostDiv(); /* Adjust input clock */ clkRate = clkRate / prediv; /* MDEC used for rate */ workRate1 = (uint64_t)clkRate * (uint64_t)findPll1MMult(); clkRate = (uint32_t)(workRate1 / ((uint64_t)postdiv)); } break; case 0x03: /* RTC oscillator 32 kHz output (32k_clk) */ clkRate = GetOsc32KFreq(); break; default: clkRate = 0UL; break; } SystemCoreClock = clkRate / ((SYSCON->AHBCLKDIV & 0xFFUL) + 1UL); } /* ---------------------------------------------------------------------------- -- SystemInitHook() ---------------------------------------------------------------------------- */ __attribute__ ((weak)) void SystemInitHook (void) { /* Void implementation of the weak function. */ }