experiment_m_2A.c
上传用户:qingfan3
上传日期:2014-10-27
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文件大小:7k
- //###########################################################################
- //
- // FILE: experiment_m_2A.c
- //
- // TITLE: DSP28 GPIO - Port B7..B0 : 8-Bit "Knight - Rider" , software delay
- //
- //
- //###########################################################################
- #include "DSP281x_Device.h"
- // Prototype statements for functions found within this file.
- void delay_loop(long);
- void Gpio_select(void);
- //void SpeedUpRevA(void);
- void InitSystem(void);
- void CfgFlash(void);
- // Global symbols defined in the linker command file
- extern Uint16 RamfuncsLoadStart;
- extern Uint16 RamfuncsLoadEnd;
- extern Uint16 RamfuncsRunStart;
- void main(void)
- {
- unsigned int i;
- unsigned int LED[8]= {0xFF7E,0xFFBD,0xFFDB,0xFFE7};
- InitSystem(); // Initialize the DSP's core Registers
- // SpeedUpRevA(); // Speed_up the silicon A Revision.
- Gpio_select(); // Setup the GPIO Multiplex Registers
- // Copy all FLASH sections that need to run from RAM (use memcpy() from RTS library)
- // Section ramfuncs contains user defined code that runs from CSM secured RAM
- memcpy( &RamfuncsRunStart,
- &RamfuncsLoadStart,
- &RamfuncsLoadEnd - &RamfuncsLoadStart);
- // Initialize the FLASH
- CfgFlash(); // Initialize the FLASH
- while(1)
- {
- for(i=0;i<6;i++)
- {
- if(i<3)
- GpioDataRegs.GPBDAT.all = LED[i];
- else
- GpioDataRegs.GPBDAT.all = LED[6-i];
- delay_loop(500000);
- }
- }
- }
- void delay_loop(long end)
- {
- long i;
- for (i = 0; i < end; i++);
- EALLOW;
- SysCtrlRegs.WDKEY = 0x55;
- SysCtrlRegs.WDKEY = 0xAA;
- EDIS;
- }
- void Gpio_select(void)
- {
- EALLOW;
- GpioMuxRegs.GPAMUX.all = 0x0; // all GPIO port Pin's to I/O
- GpioMuxRegs.GPBMUX.all = 0x0;
- GpioMuxRegs.GPDMUX.all = 0x0;
- GpioMuxRegs.GPFMUX.all = 0x0;
- GpioMuxRegs.GPEMUX.all = 0x0;
- GpioMuxRegs.GPGMUX.all = 0x0;
- GpioMuxRegs.GPADIR.all = 0x0; // GPIO PORT as input
- GpioMuxRegs.GPBDIR.all = 0x00FF;// GPIO Port B15-B8 input , B7-B0 output
- GpioMuxRegs.GPDDIR.all = 0x0; // GPIO PORT as input
- GpioMuxRegs.GPEDIR.all = 0x0; // GPIO PORT as input
- GpioMuxRegs.GPFDIR.all = 0x0; // GPIO PORT as input
- GpioMuxRegs.GPGDIR.all = 0x0; // GPIO PORT as input
- GpioMuxRegs.GPAQUAL.all = 0x0; // Set GPIO input qualifier values to zero
- GpioMuxRegs.GPBQUAL.all = 0x0;
- GpioMuxRegs.GPDQUAL.all = 0x0;
- GpioMuxRegs.GPEQUAL.all = 0x0;
- EDIS;
- }
- /*
- void SpeedUpRevA(void)
- {
- // On TMX samples, to get the best performance of on chip RAM blocks M0/M1/L0/L1/H0 internal
- // control registers bit have to be enabled. The bits are in Device emulation registers.
- EALLOW;
- DevEmuRegs.M0RAMDFT = 0x0300;
- DevEmuRegs.M1RAMDFT = 0x0300;
- DevEmuRegs.L0RAMDFT = 0x0300;
- DevEmuRegs.L1RAMDFT = 0x0300;
- DevEmuRegs.H0RAMDFT = 0x0300;
- EDIS;
- }
- */
- void InitSystem(void)
- {
- volatile int16 dummy; // General purpose volatile int16
- EALLOW; // Enable EALLOW protected register access
- // Memory Protection Configuration
- DevEmuRegs.PROTSTART = 0x0100; // Write default value to protection start register
- DevEmuRegs.PROTRANGE = 0x00FF; // Write default value to protection range register
- // Unlock the Code Security Module if CSM not in use
- /* Unlocking the CSM will allow code running from non-secure memory
- to access code and data in secure memory. One would only want to
- unsecure the CSM if code security were not desired, and therefore
- the CSM is not in use (otherwise, unlocking the CSM will compromise
- the security of user code). If the CSM is not in use, the best
- thing to do is leave the password locations programmed to 0xFFFF,
- which is the flash ERASED state. When all passwords are 0xFFFF,
- all that is required to unlock the CSM are dummy reads of the
- PWL locations.
- */
- dummy = CsmPwl.PSWD0; // Dummy read of PWL locations
- dummy = CsmPwl.PSWD1; // Dummy read of PWL locations
- dummy = CsmPwl.PSWD2; // Dummy read of PWL locations
- dummy = CsmPwl.PSWD3; // Dummy read of PWL locations
- dummy = CsmPwl.PSWD4; // Dummy read of PWL locations
- dummy = CsmPwl.PSWD5; // Dummy read of PWL locations
- dummy = CsmPwl.PSWD6; // Dummy read of PWL locations
- dummy = CsmPwl.PSWD7; // Dummy read of PWL locations
- asm(" RPT #6 || NOP");
-
- SysCtrlRegs.WDCR= 0x00AF; // Setup the watchdog
- // 0x00E8 to disable the Watchdog , Prescaler = 1
- // 0x00AF to NOT disable the Watchdog, Prescaler = 64
- SysCtrlRegs.SCSR = 0; // Watchdog generates a RESET
- SysCtrlRegs.PLLCR.bit.DIV = 10; // Setup the Clock PLL to multiply by 5
- SysCtrlRegs.HISPCP.all = 0x1; // Setup Highspeed Clock Prescaler to divide by 2
- SysCtrlRegs.LOSPCP.all = 0x2; // Setup Lowspeed CLock Prescaler to divide by 4
- // Peripheral clock enables set for the selected peripherals.
- SysCtrlRegs.PCLKCR.bit.EVAENCLK=0;
- SysCtrlRegs.PCLKCR.bit.EVBENCLK=0;
- SysCtrlRegs.PCLKCR.bit.SCIAENCLK=0;
- SysCtrlRegs.PCLKCR.bit.SCIBENCLK=0;
- SysCtrlRegs.PCLKCR.bit.MCBSPENCLK=0;
- SysCtrlRegs.PCLKCR.bit.SPIENCLK=0;
- SysCtrlRegs.PCLKCR.bit.ECANENCLK=0;
- SysCtrlRegs.PCLKCR.bit.ADCENCLK=0;
- EDIS;
- }
- /**********************************************************************
- * Function: CfgFlash()
- * Description: Initializes the F281x flash timing registers.
- * Notes:
- * 1) This function MUST be executed out of RAM. Executing it out of
- * OTP/FLASH will produce unpredictable results.
- * 2) The flash registers are code security module protected. Therefore,
- * you must either run this function from L0/L1 RAM, or you must
- * first unlock the CSM. Note that unlocking the CSM as part of
- * the program flow can compromise the code security.
- * 3) The latest datasheet for the particular device of interest should
- * be consulted to confirm the flash timing specifications.
- **********************************************************************/
- #pragma CODE_SECTION(CfgFlash, "ramfuncs")
- void CfgFlash(void)
- {
- asm(" EALLOW"); // Enable EALLOW protected register access
- FlashRegs.FPWR.bit.PWR = 3; // Pump and bank set to active mode
- FlashRegs.FSTATUS.bit.V3STAT = 1; // Clear the 3VSTAT bit
- FlashRegs.FSTDBYWAIT.bit.STDBYWAIT = 0x01FF; // Sleep to standby transition cycles
- FlashRegs.FACTIVEWAIT.bit.ACTIVEWAIT = 0x01FF; // Standby to active transition cycles
- FlashRegs.FBANKWAIT.bit.RANDWAIT = 5;// Random access waitstates
- FlashRegs.FBANKWAIT.bit.PAGEWAIT = 5;// Paged access waitstates
- FlashRegs.FOTPWAIT.bit.OTPWAIT = 8; // OTP waitstates
- FlashRegs.FOPT.bit.ENPIPE = 1; // Enable the flash pipeline
- asm(" EDIS"); // Disable EALLOW protected register access
- // Force a complete pipeline flush to ensure that the write to the last register
- // configured occurs before returning. Safest thing is to wait 8 full cycles.
- asm(" RPT #6 || NOP");
- } //end of CfgFlash()
- //===========================================================================
- // End
- //===========================================================================