Dmitry Kovalev
/
LGstaandart
forkd
Fork of LG2 by
system_LPC17xx.c
- Committer:
- Kovalev_D
- Date:
- 2016-04-13
- Revision:
- 132:2c7bec5cf6fe
- Parent:
- 124:9ae09249f842
- Child:
- 133:90d0bf0e2996
File content as of revision 132:2c7bec5cf6fe:
/**************************************************************************//** * @file system_LPC17xx.c * @brief CMSIS Cortex-M3 Device Peripheral Access Layer Source File * for the NXP LPC17xx Device Series * @version V1.03 * @date 07. October 2009 * * @note * Copyright (C) 2009 ARM Limited. All rights reserved. * * @par * ARM Limited (ARM) is supplying this software for use with Cortex-M * processor based microcontrollers. This file can be freely distributed * within development tools that are supporting such ARM based processors. * * @par * THIS SOFTWARE IS PROVIDED "AS IS". NO WARRANTIES, WHETHER EXPRESS, IMPLIED * OR STATUTORY, INCLUDING, BUT NOT LIMITED TO, IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE APPLY TO THIS SOFTWARE. * ARM SHALL NOT, IN ANY CIRCUMSTANCES, BE LIABLE FOR SPECIAL, INCIDENTAL, OR * CONSEQUENTIAL DAMAGES, FOR ANY REASON WHATSOEVER. * ******************************************************************************/ #include <stdint.h> #include "LPC17xx.h" /* //-------- <<< Use Configuration Wizard in Context Menu >>> ------------------ */ /*--------------------- Clock Configuration ---------------------------------- // // <e> Clock Configuration // <h> System Controls and Status Register (SCS) // <o1.4> OSCRANGE: Main Oscillator Range Select // <0=> 1 MHz to 20 MHz // <1=> 15 MHz to 24 MHz // <e1.5> OSCEN: Main Oscillator Enable // </e> // </h> // // <h> Clock Source Select Register (CLKSRCSEL) // <o2.0..1> CLKSRC: PLL Clock Source Selection // <0=> Internal RC oscillator // <1=> Main oscillator // <2=> RTC oscillator // </h> // // <e3> PLL0 Configuration (Main PLL) // <h> PLL0 Configuration Register (PLL0CFG) // <i> F_cco0 = (2 * M * F_in) / N // <i> F_in must be in the range of 32 kHz to 50 MHz // <i> F_cco0 must be in the range of 275 MHz to 550 MHz // <o4.0..14> MSEL: PLL Multiplier Selection // <6-32768><#-1> // <i> M Value // <o4.16..23> NSEL: PLL Divider Selection // <1-256><#-1> // <i> N Value // </h> // </e> // // <e5> PLL1 Configuration (USB PLL) // <h> PLL1 Configuration Register (PLL1CFG) // <i> F_usb = M * F_osc or F_usb = F_cco1 / (2 * P) // <i> F_cco1 = F_osc * M * 2 * P // <i> F_cco1 must be in the range of 156 MHz to 320 MHz // <o6.0..4> MSEL: PLL Multiplier Selection // <1-32><#-1> // <i> M Value (for USB maximum value is 4) // <o6.5..6> PSEL: PLL Divider Selection // <0=> 1 // <1=> 2 // <2=> 4 // <3=> 8 // <i> P Value // </h> // </e> // // <h> CPU Clock Configuration Register (CCLKCFG) // <o7.0..7> CCLKSEL: Divide Value for CPU Clock from PLL0 // <3-256><#-1> // </h> // // <h> USB Clock Configuration Register (USBCLKCFG) // <o8.0..3> USBSEL: Divide Value for USB Clock from PLL0 // <0-15> // <i> Divide is USBSEL + 1 // </h> // // <h> Peripheral Clock Selection Register 0 (PCLKSEL0) // <o9.0..1> PCLK_WDT: Peripheral Clock Selection for WDT // <0=> Pclk = Cclk / 4 // <1=> Pclk = Cclk // <2=> Pclk = Cclk / 2 // <3=> Pclk = Hclk / 8 // <o9.2..3> PCLK_TIMER0: Peripheral Clock Selection for TIMER0 // <0=> Pclk = Cclk / 4 // <1=> Pclk = Cclk // <2=> Pclk = Cclk / 2 // <3=> Pclk = Hclk / 8 // <o9.4..5> PCLK_TIMER1: Peripheral Clock Selection for TIMER1 // <0=> Pclk = Cclk / 4 // <1=> Pclk = Cclk // <2=> Pclk = Cclk / 2 // <3=> Pclk = Hclk / 8 // <o9.6..7> PCLK_UART0: Peripheral Clock Selection for UART0 // <0=> Pclk = Cclk / 4 // <1=> Pclk = Cclk // <2=> Pclk = Cclk / 2 // <3=> Pclk = Hclk / 8 // <o9.8..9> PCLK_UART1: Peripheral Clock Selection for UART1 // <0=> Pclk = Cclk / 4 // <1=> Pclk = Cclk // <2=> Pclk = Cclk / 2 // <3=> Pclk = Hclk / 8 // <o9.12..13> PCLK_PWM1: Peripheral Clock Selection for PWM1 // <0=> Pclk = Cclk / 4 // <1=> Pclk = Cclk // <2=> Pclk = Cclk / 2 // <3=> Pclk = Hclk / 8 // <o9.14..15> PCLK_I2C0: Peripheral Clock Selection for I2C0 // <0=> Pclk = Cclk / 4 // <1=> Pclk = Cclk // <2=> Pclk = Cclk / 2 // <3=> Pclk = Hclk / 8 // <o9.16..17> PCLK_SPI: Peripheral Clock Selection for SPI // <0=> Pclk = Cclk / 4 // <1=> Pclk = Cclk // <2=> Pclk = Cclk / 2 // <3=> Pclk = Hclk / 8 // <o9.20..21> PCLK_SSP1: Peripheral Clock Selection for SSP1 // <0=> Pclk = Cclk / 4 // <1=> Pclk = Cclk // <2=> Pclk = Cclk / 2 // <3=> Pclk = Hclk / 8 // <o9.22..23> PCLK_DAC: Peripheral Clock Selection for DAC // <0=> Pclk = Cclk / 4 // <1=> Pclk = Cclk // <2=> Pclk = Cclk / 2 // <3=> Pclk = Hclk / 8 // <o9.24..25> PCLK_ADC: Peripheral Clock Selection for ADC // <0=> Pclk = Cclk / 4 // <1=> Pclk = Cclk // <2=> Pclk = Cclk / 2 // <3=> Pclk = Hclk / 8 // <o9.26..27> PCLK_CAN1: Peripheral Clock Selection for CAN1 // <0=> Pclk = Cclk / 4 // <1=> Pclk = Cclk // <2=> Pclk = Cclk / 2 // <3=> Pclk = Hclk / 6 // <o9.28..29> PCLK_CAN2: Peripheral Clock Selection for CAN2 // <0=> Pclk = Cclk / 4 // <1=> Pclk = Cclk // <2=> Pclk = Cclk / 2 // <3=> Pclk = Hclk / 6 // <o9.30..31> PCLK_ACF: Peripheral Clock Selection for ACF // <0=> Pclk = Cclk / 4 // <1=> Pclk = Cclk // <2=> Pclk = Cclk / 2 // <3=> Pclk = Hclk / 6 // </h> // // <h> Peripheral Clock Selection Register 1 (PCLKSEL1) // <o10.0..1> PCLK_QEI: Peripheral Clock Selection for the Quadrature Encoder Interface // <0=> Pclk = Cclk / 4 // <1=> Pclk = Cclk // <2=> Pclk = Cclk / 2 // <3=> Pclk = Hclk / 8 // <o10.2..3> PCLK_GPIO: Peripheral Clock Selection for GPIOs // <0=> Pclk = Cclk / 4 // <1=> Pclk = Cclk // <2=> Pclk = Cclk / 2 // <3=> Pclk = Hclk / 8 // <o10.4..5> PCLK_PCB: Peripheral Clock Selection for the Pin Connect Block // <0=> Pclk = Cclk / 4 // <1=> Pclk = Cclk // <2=> Pclk = Cclk / 2 // <3=> Pclk = Hclk / 8 // <o10.6..7> PCLK_I2C1: Peripheral Clock Selection for I2C1 // <0=> Pclk = Cclk / 4 // <1=> Pclk = Cclk // <2=> Pclk = Cclk / 2 // <3=> Pclk = Hclk / 8 // <o10.10..11> PCLK_SSP0: Peripheral Clock Selection for SSP0 // <0=> Pclk = Cclk / 4 // <1=> Pclk = Cclk // <2=> Pclk = Cclk / 2 // <3=> Pclk = Hclk / 8 // <o10.12..13> PCLK_TIMER2: Peripheral Clock Selection for TIMER2 // <0=> Pclk = Cclk / 4 // <1=> Pclk = Cclk // <2=> Pclk = Cclk / 2 // <3=> Pclk = Hclk / 8 // <o10.14..15> PCLK_TIMER3: Peripheral Clock Selection for TIMER3 // <0=> Pclk = Cclk / 4 // <1=> Pclk = Cclk // <2=> Pclk = Cclk / 2 // <3=> Pclk = Hclk / 8 // <o10.16..17> PCLK_UART2: Peripheral Clock Selection for UART2 // <0=> Pclk = Cclk / 4 // <1=> Pclk = Cclk // <2=> Pclk = Cclk / 2 // <3=> Pclk = Hclk / 8 // <o10.18..19> PCLK_UART3: Peripheral Clock Selection for UART3 // <0=> Pclk = Cclk / 4 // <1=> Pclk = Cclk // <2=> Pclk = Cclk / 2 // <3=> Pclk = Hclk / 8 // <o10.20..21> PCLK_I2C2: Peripheral Clock Selection for I2C2 // <0=> Pclk = Cclk / 4 // <1=> Pclk = Cclk // <2=> Pclk = Cclk / 2 // <3=> Pclk = Hclk / 8 // <o10.22..23> PCLK_I2S: Peripheral Clock Selection for I2S // <0=> Pclk = Cclk / 4 // <1=> Pclk = Cclk // <2=> Pclk = Cclk / 2 // <3=> Pclk = Hclk / 8 // <o10.26..27> PCLK_RIT: Peripheral Clock Selection for the Repetitive Interrupt Timer // <0=> Pclk = Cclk / 4 // <1=> Pclk = Cclk // <2=> Pclk = Cclk / 2 // <3=> Pclk = Hclk / 8 // <o10.28..29> PCLK_SYSCON: Peripheral Clock Selection for the System Control Block // <0=> Pclk = Cclk / 4 // <1=> Pclk = Cclk // <2=> Pclk = Cclk / 2 // <3=> Pclk = Hclk / 8 // <o10.30..31> PCLK_MC: Peripheral Clock Selection for the Motor Control PWM // <0=> Pclk = Cclk / 4 // <1=> Pclk = Cclk // <2=> Pclk = Cclk / 2 // <3=> Pclk = Hclk / 8 // </h> // // <h> Power Control for Peripherals Register (PCONP) // <o11.1> PCTIM0: Timer/Counter 0 power/clock enable // <o11.2> PCTIM1: Timer/Counter 1 power/clock enable // <o11.3> PCUART0: UART 0 power/clock enable // <o11.4> PCUART1: UART 1 power/clock enable // <o11.6> PCPWM1: PWM 1 power/clock enable // <o11.7> PCI2C0: I2C interface 0 power/clock enable // <o11.8> PCSPI: SPI interface power/clock enable // <o11.9> PCRTC: RTC power/clock enable // <o11.10> PCSSP1: SSP interface 1 power/clock enable // <o11.12> PCAD: A/D converter power/clock enable // <o11.13> PCCAN1: CAN controller 1 power/clock enable // <o11.14> PCCAN2: CAN controller 2 power/clock enable // <o11.15> PCGPIO: GPIOs power/clock enable // <o11.16> PCRIT: Repetitive interrupt timer power/clock enable // <o11.17> PCMC: Motor control PWM power/clock enable // <o11.18> PCQEI: Quadrature encoder interface power/clock enable // <o11.19> PCI2C1: I2C interface 1 power/clock enable // <o11.21> PCSSP0: SSP interface 0 power/clock enable // <o11.22> PCTIM2: Timer 2 power/clock enable // <o11.23> PCTIM3: Timer 3 power/clock enable // <o11.24> PCUART2: UART 2 power/clock enable // <o11.25> PCUART3: UART 3 power/clock enable // <o11.26> PCI2C2: I2C interface 2 power/clock enable // <o11.27> PCI2S: I2S interface power/clock enable // <o11.29> PCGPDMA: GP DMA function power/clock enable // <o11.30> PCENET: Ethernet block power/clock enable // <o11.31> PCUSB: USB interface power/clock enable // </h> // // <h> Clock Output Configuration Register (CLKOUTCFG) // <o12.0..3> CLKOUTSEL: Selects clock source for CLKOUT // <0=> CPU clock // <1=> Main oscillator // <2=> Internal RC oscillator // <3=> USB clock // <4=> RTC oscillator // <o12.4..7> CLKOUTDIV: Selects clock divider for CLKOUT // <1-16><#-1> // <o12.8> CLKOUT_EN: CLKOUT enable control // </h> // // </e> */ // сейчас получается частота 100 Mhz //12 * 2 * (99+1) / (5+1) = 400 (должна быть в пределах 275...550) //потом еше делится на 4 = 100 //нам нужно 921600* 16 = 14 745 000, теперб выбираем делитель уартовский 7 = 103 219 200, дибо 8 = 117 964 800 //1 выбираем второе 117 964 800 округляем до 100 000 (для второго таймера) 118 000. таку. частоту нужно на входе УАРТА. //118 * 3 = 354, 118 * 4 = 472. // 354 / "3" = 118 //попробуем с 474 >> умножитель на 59 и делитель на 3 => 12 * 2 * ("58" + 1) / ("2" + 1) = 472. // 472 / "4" = 118 // с другой стороны не рекомендуют частоты выше 100 (120 только для 1769 или чото там еще ) // 103,200 => *3 = 309.6; * 4 = 412,8. // 412,8 умножитель на 86 и делитель на 5 => 12 * 2 * ("85" + 1) / ("4" + 1) = 412,8. !!!!!наверно можно остоновиься и попробовать!!!!!!!! // 412,8 / "4" = 103,2 #define CLOCK_SETUP 1 //System control - system control and status register: // bit 4 - main oscillator range: // 0 - 1...20MHz // 1 - 15...25MHz // bit 5 - main oscillator enable // 0 - disabled // 1 - enabled // bit 6 - main oscillator status // 0 - not ready // 1 - ready #define SCS_Val 0x00000020 //Enable main oscillator,1...20MHz //Clock Source Select register // bits 0-1: // 00 - Selects the Internal RC oscillator as the PLL0 clock source (default) // 01 - Selects the main oscillator as the PLL0 clock source // 10 - Selects the RTC oscillator as the PLL0 clock source // 11 - Reserved, do not use this setting #define CLKSRCSEL_Val 0x00000001//Select the main oscillator as the PLL0 clock source #define PLL0_SETUP 1 //PLL0 Configuration register // bits 0...14 - PLL0 multiplier value minus 1. Supported multiplier M range 6...512 // bits 16...23 - PLL0 Pre-Divider value minus 1. Supported divider N range 1...32 // Fcc0 = (2 * M * Fin) / N #define PLL0CFG_Val 0x00040055//M - 86, N - 5, output = 2 * 86 * 12MHz / 5 = 400MHz #define PLL1_SETUP 1 #define PLL1CFG_Val 0x00000023//M - 36, N - 1, output = 2 * 36 * 12MHz / 1 = 864MHz? //CPU Clock Configure Register #define CCLKCFG_Val 0x00000003 //Divide by 4 //USB Clock Configuration register // bits 0...3 // 5 - PLL0 output is divided by 6. PLL0 output must be 288 MHz // 7 - PLL0 output is divided by 8. PLL0 output must be 384 MHz // 9 - PLL0 output is divided by 10. PLL0 output must be 480 MHz #define USBCLKCFG_Val 0x00000000//default //Peripheral Clock Selection register 0 // 1:0 PCLK_WDT Peripheral clock selection for WDT. 00 // 3:2 PCLK_TIMER0 Peripheral clock selection for TIMER0. 00 // 5:4 PCLK_TIMER1 Peripheral clock selection for TIMER1. 00 // 7:6 PCLK_UART0 Peripheral clock selection for UART0. 00 // 9:8 PCLK_UART1 Peripheral clock selection for UART1. 00 // 11:10 - Reserved. NA // 13:12 PCLK_PWM1 Peripheral clock selection for PWM1. 00 // 15:14 PCLK_I2C0 Peripheral clock selection for I2C0. 00 // 17:16 PCLK_SPI Peripheral clock selection for SPI. 00 // 19:18 - Reserved. NA // 21:20 PCLK_SSP1 Peripheral clock selection for SSP1. 00 // 23:22 PCLK_DAC Peripheral clock selection for DAC. 00 // 25:24 PCLK_ADC Peripheral clock selection for ADC. 00 // 27:26 PCLK_CAN1 Peripheral clock selection for CAN1.[1] 00 // 29:28 PCLK_CAN2 Peripheral clock selection for CAN2.[1] 00 // 31:30 PCLK_ACF Peripheral clock selection for CAN acceptance filtering // bits values: // 00 PCLK_peripheral = CCLK/4 // 01 PCLK_peripheral = CCLK // 10 PCLK_peripheral = CCLK/2 // 11 PCLK_peripheral = CCLK/8, except for CAN1, CAN2, and CAN filtering when “11” selects = CCLK/6. //#define PCLKSEL0_Val 0x00000010//Peripheral clock selection for TIMER1 - CCLK, other peripherals - CCLK/4 #define PCLKSEL0_Val 0x00000150//Peripheral clock selection for TIMER1 - CCLK, other peripherals - CCLK/4 //Peripheral Clock Selection register 1 // 1:0 PCLK_QEI Peripheral clock selection for the Quadrature Encoder Interface.00 // 3:2 PCLK_GPIOINT Peripheral clock selection for GPIO interrupts. 00 // 5:4 PCLK_PCB Peripheral clock selection for the Pin Connect block. 00 // 7:6 PCLK_I2C1 Peripheral clock selection for I2C1. 00 // 9:8 - Reserved. NA // 11:10 PCLK_SSP0 Peripheral clock selection for SSP0. 00 // 13:12 PCLK_TIMER2 Peripheral clock selection for TIMER2. 00 // 15:14 PCLK_TIMER3 Peripheral clock selection for TIMER3. 00 // 17:16 PCLK_UART2 Peripheral clock selection for UART2. 00 // 19:18 PCLK_UART3 Peripheral clock selection for UART3. 00 // 21:20 PCLK_I2C2 Peripheral clock selection for I2C2. 00 // 23:22 PCLK_I2S Peripheral clock selection for I2S. 00 // 25:24 - Reserved. NA // 27:26 PCLK_RIT Peripheral clock selection for Repetitive Interrupt Timer. 00 // 29:28 PCLK_SYSCON Peripheral clock selection for the System Control block. 00 // 31:30 PCLK_MC Peripheral clock selection for the Motor Control PWM #define PCLKSEL1_Val 0x00000000//CCLK/4 //Power Control for Peripherals register //0 - Reserved. NA //1 PCTIM0 Timer/Counter 0 power/clock control bit. 1 //2 PCTIM1 Timer/Counter 1 power/clock control bit. 1 //3 PCUART0 UART0 power/clock control bit. 1 //4 PCUART1 UART1 power/clock control bit. 1 //5 - Reserved. NA //6 PCPWM1 PWM1 power/clock control bit. 1 //7 PCI2C0 The I2C0 interface power/clock control bit. 1 //8 PCSPI The SPI interface power/clock control bit. 1 //9 PCRTC The RTC power/clock control bit. 1 //10 PCSSP1 The SSP 1 interface power/clock control bit. 1 //11 - Reserved. NA //12 PCADC A/D converter (ADC) power/clock control bit. Note: Clear the PDN bit in the AD0CR before clearing this bit, and set this bit before setting PDN. 0 //13 PCCAN1 CAN Controller 1 power/clock control bit. 0 //14 PCCAN2 CAN Controller 2 power/clock control bit. 0 //15 PCGPIO Power/clock control bit for IOCON, GPIO, and GPIO interrupts. 1 //16 PCRIT Repetitive Interrupt Timer power/clock control bit. 0 //17 PCMCPWM Motor Control PWM 0 //18 PCQEI Quadrature Encoder Interface power/clock control bit. 0 //19 PCI2C1 The I2C1 interface power/clock control bit. 1 //20 - Reserved. NA //21 PCSSP0 The SSP0 interface power/clock control bit. 1 //22 PCTIM2 Timer 2 power/clock control bit. 0 //23 PCTIM3 Timer 3 power/clock control bit. 0 //24 PCUART2 UART 2 power/clock control bit. 0 //25 PCUART3 UART 3 power/clock control bit. 0 //26 PCI2C2 I2C interface 2 power/clock control bit. 1 #define PCONP_Val 0x046887DE//ADC,CAN1/2,RIT,Timer3,UART2,UART3 disabled //Clock Output Configuration register // 3:0 CLKOUTSEL Selects the clock source for the CLKOUT function. 0 // 0000 Selects the CPU clock as the CLKOUT source. // 0001 Selects the main oscillator as the CLKOUT source. // 0010 Selects the Internal RC oscillator as the CLKOUT source. // 0011 Selects the USB clock as the CLKOUT source. // 0100 Selects the RTC oscillator as the CLKOUT source. // Others Reserved, do not use these settings. // 7:4 CLKOUTDIV Integer value to divide the output clock by, minus one. 0 // 0000 Clock is divided by 1. // 0001 Clock is divided by 2. // 0010 Clock is divided by 3. // ... ... // 1111 Clock is divided by 16. // 8 CLKOUT_EN CLKOUT enable control, allows switching the CLKOUT source without glitches. Clear to stop CLKOUT on the next falling edge. Set to enable CLKOUT. 0 // 9 CLKOUT_ACT CLKOUT activity indication. Reads as 1 when CLKOUT is enabled. Read as 0 when CLKOUT has been disabled via the CLKOUT_EN bit and the clock has completed being stopped. #define CLKOUTCFG_Val 0x00000000//Host4: CLKOUT pin not used /*--------------------- Flash Accelerator Configuration ---------------------- // // <e> Flash Accelerator Configuration // <o1.0..1> FETCHCFG: Fetch Configuration // <0=> Instruction fetches from flash are not buffered // <1=> One buffer is used for all instruction fetch buffering // <2=> All buffers may be used for instruction fetch buffering // <3=> Reserved (do not use this setting) // <o1.2..3> DATACFG: Data Configuration // <0=> Data accesses from flash are not buffered // <1=> One buffer is used for all data access buffering // <2=> All buffers may be used for data access buffering // <3=> Reserved (do not use this setting) // <o1.4> ACCEL: Acceleration Enable // <o1.5> PREFEN: Prefetch Enable // <o1.6> PREFOVR: Prefetch Override // <o1.12..15> FLASHTIM: Flash Access Time // <0=> 1 CPU clock (for CPU clock up to 20 MHz) // <1=> 2 CPU clocks (for CPU clock up to 40 MHz) // <2=> 3 CPU clocks (for CPU clock up to 60 MHz) // <3=> 4 CPU clocks (for CPU clock up to 80 MHz) // <4=> 5 CPU clocks (for CPU clock up to 100 MHz) // <5=> 6 CPU clocks (for any CPU clock) // </e> */ #define FLASH_SETUP 1 //Flash Accelerator Configuration Register // 11:0 - - Reserved, user software should not change these bits from the reset value. 0x03A // 15:12 FLASHTIM Flash access time. The value of this field plus 1 gives the number of CPU clocks used for a flash access. Warning: improper setting of this value may result in incorrect operation of the device. 0x3 // 0000 Flash accesses use 1 CPU clock. Use for up to 20 MHz CPU clock. // 0001 Flash accesses use 2 CPU clocks. Use for up to 40 MHz CPU clock. // 0010 Flash accesses use 3 CPU clocks. Use for up to 60 MHz CPU clock. // 0011 Flash accesses use 4 CPU clocks. Use for up to 80 MHz CPU clock. // 0100 Flash accesses use 5 CPU clocks. Use for up to 100 MHz CPU clock. Use for up to 120 Mhz for LPC1759 and LPC1769 only. // 0101 Flash accesses use 6 CPU clocks. This “safe” setting will work under any conditions. Other Intended for potential future higher speed devices. // 31:16 - Reserved. The value read from a reserved bit is not defined. NA #define FLASHCFG_Val 0x0000303A//5 CPU clocks required for flash access /* //-------- <<< end of configuration section >>> ------------------------------ */ /*---------------------------------------------------------------------------- Check the register settings *----------------------------------------------------------------------------*/ #define CHECK_RANGE(val, min, max) ((val < min) || (val > max)) #define CHECK_RSVD(val, mask) (val & mask) /* Clock Configuration -------------------------------------------------------*/ #if (CHECK_RSVD((SCS_Val), ~0x00000030)) #error "SCS: Invalid values of reserved bits!" #endif #if (CHECK_RANGE((CLKSRCSEL_Val), 0, 2)) #error "CLKSRCSEL: Value out of range!" #endif #if (CHECK_RSVD((PLL0CFG_Val), ~0x00FF7FFF)) #error "PLL0CFG: Invalid values of reserved bits!" #endif #if (CHECK_RSVD((PLL1CFG_Val), ~0x0000007F)) #error "PLL1CFG: Invalid values of reserved bits!" #endif #if ((CCLKCFG_Val != 0) && (((CCLKCFG_Val - 1) % 2))) #error "CCLKCFG: CCLKSEL field does not contain only odd values or 0!" #endif #if (CHECK_RSVD((USBCLKCFG_Val), ~0x0000000F)) #error "USBCLKCFG: Invalid values of reserved bits!" #endif #if (CHECK_RSVD((PCLKSEL0_Val), 0x000C0C00)) #error "PCLKSEL0: Invalid values of reserved bits!" #endif #if (CHECK_RSVD((PCLKSEL1_Val), 0x03000300)) #error "PCLKSEL1: Invalid values of reserved bits!" #endif #if (CHECK_RSVD((PCONP_Val), 0x10100821)) #error "PCONP: Invalid values of reserved bits!" #endif #if (CHECK_RSVD((CLKOUTCFG_Val), ~0x000001FF)) #error "CLKOUTCFG: Invalid values of reserved bits!" #endif /* Flash Accelerator Configuration -------------------------------------------*/ #if (CHECK_RSVD((FLASHCFG_Val), ~0x0000F07F)) #error "FLASHCFG: Invalid values of reserved bits!" #endif /*---------------------------------------------------------------------------- DEFINES *----------------------------------------------------------------------------*/ /*---------------------------------------------------------------------------- Define clocks *----------------------------------------------------------------------------*/ #define XTAL (12000000UL) /* Oscillator frequency */ #define OSC_CLK ( XTAL) /* Main oscillator frequency */ #define RTC_CLK ( 32000UL) /* RTC oscillator frequency */ #define IRC_OSC ( 4000000UL) /* Internal RC oscillator frequency */ /* F_cco0 = (2 * M * F_in) / N */ #define __M (((PLL0CFG_Val ) & 0x7FFF) + 1) #define __N (((PLL0CFG_Val >> 16) & 0x00FF) + 1) #define __FCCO(__F_IN) ((2 * __M * __F_IN) / __N) #define __CCLK_DIV (((CCLKCFG_Val ) & 0x00FF) + 1) /* Determine core clock frequency according to settings */ #if (PLL0_SETUP) #if ((CLKSRCSEL_Val & 0x03) == 1) #define __CORE_CLK (__FCCO(OSC_CLK) / __CCLK_DIV) #elif ((CLKSRCSEL_Val & 0x03) == 2) #define __CORE_CLK (__FCCO(RTC_CLK) / __CCLK_DIV) #else #define __CORE_CLK (__FCCO(IRC_OSC) / __CCLK_DIV) #endif #else #if ((CLKSRCSEL_Val & 0x03) == 1) #define __CORE_CLK (OSC_CLK / __CCLK_DIV) #elif ((CLKSRCSEL_Val & 0x03) == 2) #define __CORE_CLK (RTC_CLK / __CCLK_DIV) #else #define __CORE_CLK (IRC_OSC / __CCLK_DIV) #endif #endif /*---------------------------------------------------------------------------- Clock Variable definitions *----------------------------------------------------------------------------*/ uint32_t SystemFrequency = IRC_OSC; uint32_t SystemCoreClock1 = __CORE_CLK;/*!< System Clock Frequency (Core Clock)*/ /*---------------------------------------------------------------------------- Clock functions *----------------------------------------------------------------------------*/ void SystemCoreClockUpdate1 (void) /* Get Core Clock Frequency */ { /* Determine clock frequency according to clock register values */ if (((LPC_SC->PLL0STAT >> 24) & 3) == 3) { /* If PLL0 enabled and connected */ switch (LPC_SC->CLKSRCSEL & 0x03) { case 0: /* Int. RC oscillator => PLL0 */ case 3: /* Reserved, default to Int. RC */ SystemCoreClock1 = (IRC_OSC * ((2 * ((LPC_SC->PLL0STAT & 0x7FFF) + 1))) / (((LPC_SC->PLL0STAT >> 16) & 0xFF) + 1) / ((LPC_SC->CCLKCFG & 0xFF)+ 1)); break; case 1: /* Main oscillator => PLL0 */ SystemCoreClock1 = (OSC_CLK * //it is our case osc_clk = 12 MHz ((2 * ((LPC_SC->PLL0STAT & 0x7FFF) + 1))) / //PLL0 multiplier value (((LPC_SC->PLL0STAT >> 16) & 0xFF) + 1) / //PLL0 pre-divider ((LPC_SC->CCLKCFG & 0xFF)+ 1)); //divider for CCLK (SystemCoreClock) break; case 2: /* RTC oscillator => PLL0 */ SystemCoreClock1 = (RTC_CLK * ((2 * ((LPC_SC->PLL0STAT & 0x7FFF) + 1))) / (((LPC_SC->PLL0STAT >> 16) & 0xFF) + 1) / ((LPC_SC->CCLKCFG & 0xFF)+ 1)); break; } } else { switch (LPC_SC->CLKSRCSEL & 0x03) { case 0: /* Int. RC oscillator => PLL0 */ case 3: /* Reserved, default to Int. RC */ SystemCoreClock1 = IRC_OSC / ((LPC_SC->CCLKCFG & 0xFF)+ 1); break; case 1: /* Main oscillator => PLL0 */ SystemCoreClock1 = OSC_CLK / ((LPC_SC->CCLKCFG & 0xFF)+ 1); break; case 2: /* RTC oscillator => PLL0 */ SystemCoreClock1 = RTC_CLK / ((LPC_SC->CCLKCFG & 0xFF)+ 1); break; } } } /** * Initialize the system * * @param none * @return none * * @brief Setup the microcontroller system. * Initialize the System. */ void SystemInit1 (void) { #if (CLOCK_SETUP) /* Clock Setup */ //Init system control and status register LPC_SC->SCS = SCS_Val;//0x20 - enable main oscillator,1...20MHz (12MHz) if (SCS_Val & (1 << 5)) { /* If Main Oscillator is enabled */ while ((LPC_SC->SCS & (1<<6)) == 0);/* Wait for Oscillator to be ready */ } //Init CPU Clock Configure Register - select the divide value for creating the CPU clock (CCLK) from the PLL0 output LPC_SC->CCLKCFG = CCLKCFG_Val; //3 - divide to 4 (3MHz) #if (PLL0_SETUP) //Init Clock Source Select register LPC_SC->CLKSRCSEL = CLKSRCSEL_Val;//1 - Select the main oscillator as the PLL0 clock source //Init PLL0 Configuration register LPC_SC->PLL0CFG = PLL0CFG_Val;//0x00050063: M - 100, N - 6, PLL0output = 2 * 100 * 12MHz / 6 = 400MHz, CPU clock 100MHz //Init PLL0 Feed Register. This register enables loading of the PLL0 control and configuration information from the PLL0CON and PLL0CFG //registers into the shadow registers that actually affect PLL0 operation. //Write 0xAA and 0x55 sequentially to update shadow registers and settings to take effect LPC_SC->PLL0FEED = 0xAA; LPC_SC->PLL0FEED = 0x55; //Init PLL0 Control register // bit 0 - PLL0 Enable // bit 1 - PLL0 connect LPC_SC->PLL0CON = 0x01;//PLL0 Enable //Update shadow registers to settings take effect LPC_SC->PLL0FEED = 0xAA; LPC_SC->PLL0FEED = 0x55; //PLL0 Status register // bits 0...14 - Read-back for the PLL0 Multiplier value // bits 16...23 - Read-back for the PLL0 Pre-Divider value // bit 24 - Read-back for the PLL0 Enable bit // bit 25 - Read-back for the PLL0 Connect bit // bit 26 - Reflects the PLL0 Lock status: 1 - locked while (!(LPC_SC->PLL0STAT & (1<<26)));//Wait while PLL0 locked (PLOCK0) LPC_SC->PLL0CON = 0x03;//PLL0 Enable & Connect LPC_SC->PLL0FEED = 0xAA; LPC_SC->PLL0FEED = 0x55; while (!(LPC_SC->PLL0STAT & ((1<<25) | (1<<24))));//Wait while PLL0 connected (PLLC0_STAT & PLLE0_STAT) #endif #if (PLL1_SETUP) LPC_SC->PLL1CFG = PLL1CFG_Val;//0x23 M - 36, N - 1, output = 2 * 36 * 12MHz / 1 = 864MHz? LPC_SC->PLL1FEED = 0xAA; LPC_SC->PLL1FEED = 0x55; LPC_SC->PLL1CON = 0x01; /* PLL1 Enable */ LPC_SC->PLL1FEED = 0xAA; LPC_SC->PLL1FEED = 0x55; while (!(LPC_SC->PLL1STAT & (1<<10)));/* Wait for PLOCK1 */ LPC_SC->PLL1CON = 0x03; /* PLL1 Enable & Connect */ LPC_SC->PLL1FEED = 0xAA; LPC_SC->PLL1FEED = 0x55; while (!(LPC_SC->PLL1STAT & ((1<< 9) | (1<< 8))));/* Wait for PLLC1_STAT & PLLE1_STAT */ #else LPC_SC->USBCLKCFG = USBCLKCFG_Val; /* Setup USB Clock Divider */ #endif LPC_SC->PCLKSEL0 = PCLKSEL0_Val; /* Peripheral Clock Selection */ LPC_SC->PCLKSEL1 = PCLKSEL1_Val; LPC_SC->PCONP = PCONP_Val; /* Power Control for Peripherals */ LPC_SC->CLKOUTCFG = CLKOUTCFG_Val; /* Clock Output Configuration */ #endif #if (FLASH_SETUP == 1) /* Flash Accelerator Setup */ LPC_SC->FLASHCFG = FLASHCFG_Val; #endif }