dsp28_cputimers.c

属于麻醉机的一个程序

//
//      TMDX ALPHA RELEASE
//      Intended for product evaluation purposes
//
//###########################################################################
//
// FILE:	DSP28_CpuTimers.c
//
// TITLE:	DSP28 CPU 32-bit Timers Initialization & Support Functions.
//
//###########################################################################
//
//  Ver | dd mmm yyyy | Who  | Description of changes
// =====|=============|======|===============================================
//  0.55| 06 May 2002 | L.H. | EzDSP Alpha Release
//  0.56| 20 May 2002 | L.H. | No change
//  0.57| 27 May 2002 | L.H. | No change
//###########################################################################

#include "DSP28_Device.h"

struct CPUTIMER_VARS CpuTimer0;
struct CPUTIMER_VARS CpuTimer1;
struct CPUTIMER_VARS CpuTimer2;

//---------------------------------------------------------------------------
// InitCpuTimers: 
//---------------------------------------------------------------------------
// This function initializes all three CPU timers to a known state.
//
void InitCpuTimers(void)
{
     unsigned int i;
	// Initialize address pointers to respective timer registers:
	CpuTimer0.RegsAddr = &CpuTimer0Regs;
	CpuTimer1.RegsAddr = &CpuTimer1Regs;
	CpuTimer2.RegsAddr = &CpuTimer2Regs;

	// Initialize timer period to maximum:	
	CpuTimer0Regs.PRD.all  = 0xFFFFFFFF;
	CpuTimer1Regs.PRD.all  = 0xFFFFFFFF;
	CpuTimer2Regs.PRD.all  = 0xFFFFFFFF;

	// Initialize pre-scale counter to divide by 1 (SYSCLKOUT):	
	CpuTimer0Regs.TPR.all  = 0;
	CpuTimer0Regs.TPRH.all = 0;
	
	// Make sure timers are stopped:
	CpuTimer0Regs.TCR.bit.TSS = 1;             
	CpuTimer1Regs.TCR.bit.TSS = 1;             
	CpuTimer2Regs.TCR.bit.TSS = 1;             

	// Reload all counter registers with period values:
	CpuTimer0Regs.TCR.bit.TRB = 1;             
	CpuTimer1Regs.TCR.bit.TRB = 1;             
	CpuTimer2Regs.TCR.bit.TRB = 1;             
	
	// Reset interrupt counters:
	CpuTimer0.InterruptCount = 0;
	CpuTimer1.InterruptCount = 0;
	CpuTimer2.InterruptCount = 0;
	///////////////////////////
	//int i;
	AdcRegs.ADCTRL1.bit.RESET=1;
	NOP;
	AdcRegs.ADCTRL1.bit.RESET=0;
	AdcRegs.ADCTRL1.bit.SUSMOD=3;
	AdcRegs.ADCTRL1.bit.ACQ_PS=0;
	AdcRegs.ADCTRL1.bit.CPS=0;
	AdcRegs.ADCTRL1.bit.CONT_RUN=0;
	AdcRegs.ADCTRL1.bit.SEQ_CASC=1;
	
	AdcRegs.ADCTRL3.bit.ADCBGRFDN=3;
	for(i=0;i<10000;i++)	NOP;
	AdcRegs.ADCTRL3.bit.ADCPWDN=1;
	for(i=0;i<5000;i++)	NOP;
	AdcRegs.ADCTRL3.bit.ADCCLKPS=15;
	AdcRegs.ADCTRL3.bit.SMODE_SEL=1;
	
	AdcRegs.MAX_CONV.bit.MAX_CONV=15;
	
	AdcRegs.CHSELSEQ1.bit.CONV00=0;
	AdcRegs.CHSELSEQ1.bit.CONV01=1;
	AdcRegs.CHSELSEQ1.bit.CONV02=2;
	AdcRegs.CHSELSEQ1.bit.CONV03=3;
	
	AdcRegs.CHSELSEQ2.bit.CONV04=4;
	AdcRegs.CHSELSEQ2.bit.CONV05=5;
	AdcRegs.CHSELSEQ2.bit.CONV06=6;
	AdcRegs.CHSELSEQ2.bit.CONV07=7;
	
	AdcRegs.CHSELSEQ3.bit.CONV08=8;
	AdcRegs.CHSELSEQ3.bit.CONV09=9;
	AdcRegs.CHSELSEQ3.bit.CONV10=10;
	AdcRegs.CHSELSEQ3.bit.CONV11=11;
	
	AdcRegs.CHSELSEQ4.bit.CONV12=12;
	AdcRegs.CHSELSEQ4.bit.CONV13=13;
	AdcRegs.CHSELSEQ4.bit.CONV14=14;
	AdcRegs.CHSELSEQ4.bit.CONV15=15;
	
	AdcRegs.ADC_ST_FLAG.bit.INT_SEQ1_CLR=1;
	AdcRegs.ADC_ST_FLAG.bit.INT_SEQ2_CLR=1;	
	
	AdcRegs.ADCTRL2.bit.EVB_SOC_SEQ=0;
	AdcRegs.ADCTRL2.bit.RST_SEQ1=0;
	AdcRegs.ADCTRL2.bit.INT_ENA_SEQ1=1;
	AdcRegs.ADCTRL2.bit.INT_MOD_SEQ1=0;
	AdcRegs.ADCTRL2.bit.EVA_SOC_SEQ1=0;
	AdcRegs.ADCTRL2.bit.EXT_SOC_SEQ1=0;
	AdcRegs.ADCTRL2.bit.RST_SEQ2=0;
	AdcRegs.ADCTRL2.bit.SOC_SEQ2=0;
	AdcRegs.ADCTRL2.bit.INT_ENA_SEQ2=0;
	AdcRegs.ADCTRL2.bit.INT_MOD_SEQ2=0;
	AdcRegs.ADCTRL2.bit.EVB_SOC_SEQ2=0;
	AdcRegs.ADCTRL2.bit.SOC_SEQ1=1;
}	
	
//---------------------------------------------------------------------------
// ConfigCpuTimer: 
//---------------------------------------------------------------------------
// This function initializes the selected timer to the period specified
// by the "Freq" and "Period" parameters. The "Freq" is entered as "MHz"
// and the period in "uSeconds". The timer is held in the stopped state
// after configuration.
//
void ConfigCpuTimer(struct CPUTIMER_VARS *Timer, float Freq, float Period)
{
	Uint32 	temp;
	
	// Initialize timer period:	
	Timer->CPUFreqInMHz = Freq;
	Timer->PeriodInUSec = Period;
	temp = (long) (Freq * Period);
	Timer->RegsAddr->PRD.all = temp;

	// Set pre-scale counter to divide by 1 (SYSCLKOUT):	
	Timer->RegsAddr->TPR.all  = 0;
	Timer->RegsAddr->TPRH.all  = 0;
	
	// Initialize timer control register:
	Timer->RegsAddr->TCR.bit.POL = 0;      // 0 = Pulse Low
	Timer->RegsAddr->TCR.bit.TOG =	0;     // 0 = No Toggle, POL bit defines action
	Timer->RegsAddr->TCR.bit.TSS = 1;      // 1 = Stop timer, 0 = Start/Restart Timer 
	Timer->RegsAddr->TCR.bit.TRB = 1;      // 1 = reload timer
	Timer->RegsAddr->TCR.bit.FRCEN = 0;    // Force output enable (not used)
	Timer->RegsAddr->TCR.bit.PWIDTH = 7;   // 7+1 = 8 SYSCLKOUT cycle pulse width 
	Timer->RegsAddr->TCR.bit.SOFT = 1;
	Timer->RegsAddr->TCR.bit.FREE = 1;     // Timer Free Run
	Timer->RegsAddr->TCR.bit.TIE = 1;      // 0 = Disable/ 1 = Enable Timer Interrupt
	
	// Reset interrupt counter:
	Timer->InterruptCount = 0;
}

//===========================================================================
// No more.
//===========================================================================