yang/uv-k5-firmware-chinese-lts
1
0
Fork 0
mirror of https://github.com/silenty4ng/uv-k5-firmware-chinese-lts synced 2025-01-29 05:33:28 +00:00
Code Issues Projects Releases Packages Wiki Activity
uv-k5-firmware-chinese-lts/external/CMSIS_5/CMSIS/RTOS/Template/system_LPC177x_8x.c
wu58430 26cb842a4f create
2023-11-30 14:38:27 +08:00

455 lines
19 KiB
C
Raw Blame History

/***********************************************************************//**
* @file system_LPC177x_8x.c
* @brief CMSIS Cortex-M3 Device Peripheral Access Layer Source File
* for the NXP LPC177x_8x Device Series
* @version V1.11
* @date 10. November. 2010
* @author NXP MCU SW Application Team
**************************************************************************
* Software that is described herein is for illustrative purposes only
* which provides customers with programming information regarding the
* products. This software is supplied "AS IS" without any warranties.
* NXP Semiconductors assumes no responsibility or liability for the
* use of the software, conveys no license or title under any patent,
* copyright, or mask work right to the product. NXP Semiconductors
* reserves the right to make changes in the software without
* notification. NXP Semiconductors also make no representation or
* warranty that such application will be suitable for the specified
* use without further testing or modification.
**********************************************************************/
#include <stdint.h>
#include "LPC177x_8x.h"
#include "system_LPC177x_8x.h"
/*
//-------- <<< Use Configuration Wizard in Context Menu >>> ------------------
*/
/*--------------------- Clock Configuration ----------------------------------
//
// <e> Clock Configuration
// <h> System Controls and Status Register (SCS)
// <o1.0> EMC_SHIFT: EMC Shift enable
// <0=> Static CS addresses match bus width; AD[1] = 0 for 32 bit, AD[0] = 0 for 16+32 bit
// <1=> Static CS addresses start at LSB 0 regardless of memory width
// <o1.1> EMC_RESET: EMC Reset disable
// <0=> EMC will be reset by any chip reset
// <1=> Portions of EMC will only be reset by POR or BOR
// <o1.2> EMC_BURST: EMC Burst disable
// <o1.3> MCIPWR_LEVEL: SD card interface signal SD_PWR Active Level selection
// <0=> SD_PWR is active low
// <1=> SD_PWR is active high
// <o1.4> OSCRANGE: Main Oscillator Range Select
// <0=> 1 MHz to 20 MHz
// <1=> 15 MHz to 25 MHz
// <o1.5> OSCEN: Main Oscillator enable
// </h>
//
// <h> Clock Source Select Register (CLKSRCSEL)
// <o2.0> CLKSRC: sysclk and PLL0 clock source selection
// <0=> Internal RC oscillator
// <1=> Main oscillator
// </h>
//
// <e3> PLL0 Configuration (Main PLL)
// <h> PLL0 Configuration Register (PLL0CFG)
// <i> PLL out clock = (F_cco / (2 * P))
// <i> F_cco = (F_in * M * 2 * P)
// <i> F_in must be in the range of 1 MHz to 25 MHz
// <i> F_cco must be in the range of 9.75 MHz to 160 MHz
// <o4.0..4> MSEL: PLL Multiplier Selection
// <i> M Value
// <1-32><#-1>
// <o4.5..6> PSEL: PLL Divider Selection
// <i> P Value
// <0=> 1
// <1=> 2
// <2=> 4
// <3=> 8
// </h>
// </e>
//
// <e5> PLL1 Configuration (Alt PLL)
// <h> PLL1 Configuration Register (PLL1CFG)
// <i> PLL out clock = (F_cco / (2 * P))
// <i> F_cco = (F_in * M * 2 * P)
// <i> F_in must be in the range of 1 MHz to 25 MHz
// <i> F_cco must be in the range of 9.75 MHz to 160 MHz
// <o6.0..4> MSEL: PLL Multiplier Selection
// <i> M Value
// <1-32><#-1>
// <o6.5..6> PSEL: PLL Divider Selection
// <i> P Value
// <0=> 1
// <1=> 2
// <2=> 4
// <3=> 8
// </h>
// </e>
//
// <h> CPU Clock Selection Register (CCLKSEL)
// <o7.0..4> CCLKDIV: CPU clock (CCLK) divider
// <i> 0: The divider is turned off. No clock will be provided to the CPU
// <i> n: The input clock is divided by n to produce the CPU clock
// <0-31>
// <o7.8> CCLKSEL: CPU clock divider input clock selection
// <0=> sysclk clock
// <1=> PLL0 clock
// </h>
//
// <h> USB Clock Selection Register (USBCLKSEL)
// <o8.0..4> USBDIV: USB clock (source PLL0) divider selection
// <0=> USB clock off
// <4=> PLL0 / 4 (PLL0 must be 192Mhz)
// <6=> PLL0 / 6 (PLL0 must be 288Mhz)
// <o8.8..9> USBSEL: USB clock divider input clock selection
// <i> When CPU clock is selected, the USB can be accessed
// <i> by software but cannot perform USB functions
// <0=> CPU clock
// <1=> PLL0 clock
// <2=> PLL1 clock
// </h>
//
// <h> EMC Clock Selection Register (EMCCLKSEL)
// <o9.0> EMCDIV: EMC clock selection
// <0=> CPU clock
// <1=> CPU clock / 2
// </h>
//
// <h> Peripheral Clock Selection Register (PCLKSEL)
// <o10.0..4> PCLKDIV: APB Peripheral clock divider
// <i> 0: The divider is turned off. No clock will be provided to APB peripherals
// <i> n: The input clock is divided by n to produce the APB peripheral clock
// <0-31>
// </h>
//
// <h> Power Control for Peripherals Register (PCONP)
// <o11.0> PCLCD: LCD controller power/clock enable
// <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
// <o11.5> PCPWM0: PWM0 power/clock enable
// <o11.6> PCPWM1: PWM1 power/clock enable
// <o11.7> PCI2C0: I2C 0 interface power/clock enable
// <o11.8> PCUART4: UART 4 power/clock enable
// <o11.9> PCRTC: RTC and Event Recorder power/clock enable
// <o11.10> PCSSP1: SSP 1 interface power/clock enable
// <o11.11> PCEMC: External Memory Controller power/clock enable
// <o11.12> PCADC: 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: IOCON, GPIO, and GPIO interrupts power/clock enable
// <o11.17> PCMCPWM: Motor Control PWM power/clock enable
// <o11.18> PCQEI: Quadrature encoder interface power/clock enable
// <o11.19> PCI2C1: I2C 1 interface power/clock enable
// <o11.20> PCSSP2: SSP 2 interface power/clock enable
// <o11.21> PCSSP0: SSP 0 interface 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 2 interface power/clock enable
// <o11.27> PCI2S: I2S interface power/clock enable
// <o11.28> PCSDC: SD Card interface power/clock enable
// <o11.29> PCGPDMA: GPDMA 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: Clock Source for CLKOUT Selection
// <0=> CPU clock
// <1=> Main Oscillator
// <2=> Internal RC Oscillator
// <3=> USB clock
// <4=> RTC Oscillator
// <5=> unused
// <6=> Watchdog Oscillator
// <o12.4..7> CLKOUTDIV: Output Clock Divider
// <1-16><#-1>
// <o12.8> CLKOUT_EN: CLKOUT enable
// </h>
//
// </e>
*/
#define CLOCK_SETUP 1
#define SCS_Val 0x00000021
#define CLKSRCSEL_Val 0x00000001
#define PLL0_SETUP 1
#define PLL0CFG_Val 0x00000009
#define PLL1_SETUP 1
#define PLL1CFG_Val 0x00000023
#define CCLKSEL_Val (0x00000001|(1<<8))
#define USBCLK_SETUP 1
#define USBCLKSEL_Val (0x00000001|(0x02<<8))
#define EMCCLKSEL_Val 0x00000001
#define PCLKSEL_Val 0x00000002
#define PCONP_Val 0x042887DE
#define CLKOUTCFG_Val 0x00000100
/*--------------------- Flash Accelerator Configuration ----------------------
//
// <e> Flash Accelerator Configuration
// <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
#define FLASHCFG_Val 0x00005000
/*----------------------------------------------------------------------------
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), ~0x0000003F))
#error "SCS: Invalid values of reserved bits!"
#endif
#if (CHECK_RANGE((CLKSRCSEL_Val), 0, 1))
#error "CLKSRCSEL: Value out of range!"
#endif
#if (CHECK_RSVD((PLL0CFG_Val), ~0x0000007F))
#error "PLL0CFG: Invalid values of reserved bits!"
#endif
#if (CHECK_RSVD((PLL1CFG_Val), ~0x0000007F))
#error "PLL1CFG: Invalid values of reserved bits!"
#endif
#if (CHECK_RSVD((CCLKSEL_Val), ~0x0000011F))
#error "CCLKSEL: Invalid values of reserved bits!"
#endif
#if (CHECK_RSVD((USBCLKSEL_Val), ~0x0000031F))
#error "USBCLKSEL: Invalid values of reserved bits!"
#endif
#if (CHECK_RSVD((EMCCLKSEL_Val), ~0x00000001))
#error "EMCCLKSEL: Invalid values of reserved bits!"
#endif
#if (CHECK_RSVD((PCLKSEL_Val), ~0x0000001F))
#error "PCLKSEL: Invalid values of reserved bits!"
#endif
#if (CHECK_RSVD((PCONP_Val), ~0xFFFEFFFF))
#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), ~0x0000F000))
#warning "FLASHCFG: Invalid values of reserved bits!"
#endif
/*----------------------------------------------------------------------------
DEFINES
*----------------------------------------------------------------------------*/
/* pll_out_clk = F_cco / (2 <20> P)
F_cco = pll_in_clk <20> M <20> 2 <20> P */
#define __M ((PLL0CFG_Val & 0x1F) + 1)
#define __PLL0_CLK(__F_IN) (__F_IN * __M)
#define __CCLK_DIV (CCLKSEL_Val & 0x1F)
#define __PCLK_DIV (PCLKSEL_Val & 0x1F)
#define __ECLK_DIV ((EMCCLKSEL_Val & 0x01) + 1)
/* Determine core clock frequency according to settings */
#if (CLOCK_SETUP) /* Clock Setup */
#if ((CLKSRCSEL_Val & 0x01) == 1) && ((SCS_Val & 0x20)== 0)
#error "Main Oscillator is selected as clock source but is not enabled!"
#endif
#if ((CCLKSEL_Val & 0x100) == 0x100) && (PLL0_SETUP == 0)
#error "Main PLL is selected as clock source but is not enabled!"
#endif
#if ((CCLKSEL_Val & 0x100) == 0) /* cclk = sysclk */
#if ((CLKSRCSEL_Val & 0x01) == 0) /* sysclk = irc_clk */
#define __CORE_CLK (IRC_OSC / __CCLK_DIV)
#define __PER_CLK (IRC_OSC/ __PCLK_DIV)
#define __EMC_CLK (IRC_OSC/ __ECLK_DIV)
#else /* sysclk = osc_clk */
#define __CORE_CLK (OSC_CLK / __CCLK_DIV)
#define __PER_CLK (OSC_CLK/ __PCLK_DIV)
#define __EMC_CLK (OSC_CLK/ __ECLK_DIV)
#endif
#else /* cclk = pll_clk */
#if ((CLKSRCSEL_Val & 0x01) == 0) /* sysclk = irc_clk */
#define __CORE_CLK (__PLL0_CLK(IRC_OSC) / __CCLK_DIV)
#define __PER_CLK (__PLL0_CLK(IRC_OSC) / __PCLK_DIV)
#define __EMC_CLK (__PLL0_CLK(IRC_OSC) / __ECLK_DIV)
#else /* sysclk = osc_clk */
#define __CORE_CLK (__PLL0_CLK(OSC_CLK) / __CCLK_DIV)
#define __PER_CLK (__PLL0_CLK(OSC_CLK) / __PCLK_DIV)
#define __EMC_CLK (__PLL0_CLK(OSC_CLK) / __ECLK_DIV)
#endif
#endif
#else
#define __CORE_CLK (IRC_OSC)
#define __PER_CLK (IRC_OSC)
#define __EMC_CLK (IRC_OSC)
#endif
/*----------------------------------------------------------------------------
Clock Variable definitions
*----------------------------------------------------------------------------*/
uint32_t SystemCoreClock = __CORE_CLK;/*!< System Clock Frequency (Core Clock)*/
uint32_t PeripheralClock = __PER_CLK; /*!< Peripheral Clock Frequency (Pclk) */
uint32_t EMCClock = __EMC_CLK; /*!< EMC Clock Frequency */
uint32_t USBClock = (48000000UL); /*!< USB Clock Frequency - this value will
be updated after call SystemCoreClockUpdate, should be 48MHz*/
/*----------------------------------------------------------------------------
Clock functions
*----------------------------------------------------------------------------*/
void SystemCoreClockUpdate (void) /* Get Core Clock Frequency */
{
/* Determine clock frequency according to clock register values */
if ((LPC_SC->CCLKSEL &0x100) == 0) { /* cclk = sysclk */
if ((LPC_SC->CLKSRCSEL & 0x01) == 0) { /* sysclk = irc_clk */
SystemCoreClock = (IRC_OSC / (LPC_SC->CCLKSEL & 0x1F));
PeripheralClock = (IRC_OSC / (LPC_SC->PCLKSEL & 0x1F));
EMCClock = (IRC_OSC / ((LPC_SC->EMCCLKSEL & 0x01)+1));
}
else { /* sysclk = osc_clk */
if ((LPC_SC->SCS & 0x40) == 0) {
SystemCoreClock = 0; /* this should never happen! */
PeripheralClock = 0;
EMCClock = 0;
}
else {
SystemCoreClock = (OSC_CLK / (LPC_SC->CCLKSEL & 0x1F));
PeripheralClock = (OSC_CLK / (LPC_SC->PCLKSEL & 0x1F));
EMCClock = (OSC_CLK / ((LPC_SC->EMCCLKSEL & 0x01)+1));
}
}
}
else { /* cclk = pll_clk */
if ((LPC_SC->PLL0STAT & 0x100) == 0) { /* PLL0 not enabled */
SystemCoreClock = 0; /* this should never happen! */
PeripheralClock = 0;
EMCClock = 0;
}
else {
if ((LPC_SC->CLKSRCSEL & 0x01) == 0) { /* sysclk = irc_clk */
SystemCoreClock = (IRC_OSC * ((LPC_SC->PLL0STAT & 0x1F) + 1) / (LPC_SC->CCLKSEL & 0x1F));
PeripheralClock = (IRC_OSC * ((LPC_SC->PLL0STAT & 0x1F) + 1) / (LPC_SC->PCLKSEL & 0x1F));
EMCClock = (IRC_OSC * ((LPC_SC->PLL0STAT & 0x1F) + 1) / ((LPC_SC->EMCCLKSEL & 0x01)+1));
}
else { /* sysclk = osc_clk */
if ((LPC_SC->SCS & 0x40) == 0) {
SystemCoreClock = 0; /* this should never happen! */
PeripheralClock = 0;
EMCClock = 0;
}
else {
SystemCoreClock = (OSC_CLK * ((LPC_SC->PLL0STAT & 0x1F) + 1) / (LPC_SC->CCLKSEL & 0x1F));
PeripheralClock = (OSC_CLK * ((LPC_SC->PLL0STAT & 0x1F) + 1) / (LPC_SC->PCLKSEL & 0x1F));
EMCClock = (OSC_CLK * ((LPC_SC->PLL0STAT & 0x1F) + 1) / ((LPC_SC->EMCCLKSEL & 0x01)+1));
}
}
}
}
/* ---update USBClock------------------*/
if(LPC_SC->USBCLKSEL & (0x01<<8))//Use PLL0 as the input to the USB clock divider
{
switch (LPC_SC->USBCLKSEL & 0x1F)
{
case 0:
USBClock = 0; //no clock will be provided to the USB subsystem
break;
case 4:
case 6:
if(LPC_SC->CLKSRCSEL & 0x01) //pll_clk_in = main_osc
USBClock = (OSC_CLK * ((LPC_SC->PLL0STAT & 0x1F) + 1) / (LPC_SC->USBCLKSEL & 0x1F));
else //pll_clk_in = irc_clk
USBClock = (IRC_OSC * ((LPC_SC->PLL0STAT & 0x1F) + 1) / (LPC_SC->USBCLKSEL & 0x1F));
break;
default:
USBClock = 0; /* this should never happen! */
}
}
else if(LPC_SC->USBCLKSEL & (0x02<<8))//usb_input_clk = alt_pll (pll1)
{
if(LPC_SC->CLKSRCSEL & 0x01) //pll1_clk_in = main_osc
USBClock = (OSC_CLK * ((LPC_SC->PLL1STAT & 0x1F) + 1));
else //pll1_clk_in = irc_clk
USBClock = (IRC_OSC * ((LPC_SC->PLL0STAT & 0x1F) + 1));
}
else
USBClock = 0; /* this should never happen! */
}
/* Determine clock frequency according to clock register values */
/**
* Initialize the system
*
* @param none
* @return none
*
* @brief Setup the microcontroller system.
* Initialize the System.
*/
void SystemInit (void)
{
#if (CLOCK_SETUP) /* Clock Setup */
LPC_SC->SCS = SCS_Val;
if (SCS_Val & (1 << 5)) { /* If Main Oscillator is enabled */
while ((LPC_SC->SCS & (1<<6)) == 0);/* Wait for Oscillator to be ready */
}
LPC_SC->CLKSRCSEL = CLKSRCSEL_Val; /* Select Clock Source for sysclk/PLL0*/
#if (PLL0_SETUP)
LPC_SC->PLL0CFG = PLL0CFG_Val;
LPC_SC->PLL0CON = 0x01; /* PLL0 Enable */
LPC_SC->PLL0FEED = 0xAA;
LPC_SC->PLL0FEED = 0x55;
while (!(LPC_SC->PLL0STAT & (1<<10)));/* Wait for PLOCK0 */
#endif
#if (PLL1_SETUP)
LPC_SC->PLL1CFG = PLL1CFG_Val;
LPC_SC->PLL1CON = 0x01; /* PLL1 Enable */
LPC_SC->PLL1FEED = 0xAA;
LPC_SC->PLL1FEED = 0x55;
while (!(LPC_SC->PLL1STAT & (1<<10)));/* Wait for PLOCK1 */
#endif
LPC_SC->CCLKSEL = CCLKSEL_Val; /* Setup Clock Divider */
LPC_SC->USBCLKSEL = USBCLKSEL_Val; /* Setup USB Clock Divider */
LPC_SC->EMCCLKSEL = EMCCLKSEL_Val; /* EMC Clock Selection */
LPC_SC->PCLKSEL = PCLKSEL_Val; /* Peripheral Clock Selection */
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|0x03A;
#endif
#ifdef __RAM_MODE__
SCB->VTOR = 0x10000000 & 0x3FFFFF80;
#else
SCB->VTOR = 0x00000000 & 0x3FFFFF80;
#endif
}
Reference in a new issue View git blame Copy permalink