DSP_TMS320F28377D_算法加速方法4_C语言编程优化

前面3篇的优化思路是从硬件本身和函数库这些方向去加速, 本文则仅从代码本身的效率去考虑加速的方法。

1、用全局变量比用局部变量快

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void testfunction1(){  // 局部变量
    int i;
    double s,a,b;
    a = 1.023;
    b = 12.23;
    for(i = 0; i < 1000; i++){
        s = __divf32(a,b);
    }
}

int i1;
double s1,a1,b1;
void testfunction2(){   // 全局变量
    a1 = 1.023;
    b1 = 12.23;
    for(i1 = 0; i1 < 1000; i1++){
        s1 = __divf32(a1,b1);
    }
}

2、用指针增量操作代替数组下标寻址

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double a[10] = {0.1,0.2,0.3,0.4,0.5,0.1,0.2,0.3,0.4,0.5};
double *p = a;
void testfunction1(){  // 数组下标
    int i,j;
    double s;

    for(i = 0; i < 1000; i++){
        for(j = 0; j < 10; j++){
            s = __sqrt(a[j]);
        }
    }
}

void testfunction2(){   // 指针增量
    int i,j;
    double s;

    for(i = 0; i < 1000; i++){
        p = a;
        for(j = 0; j < 10; j++){
            s = __sqrt(*p++);
        }
    }
}

 3、尽量少用函数,用宏函数或者直接实现来替代函数

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double a = 1.0;
double b = 2.0;
double c = 3.0;
double d = 4.0;
double e = 0;

#define TEST(a,b,c,d) (__divf32((__sqrt(a*b)+c),d))

double testfun(double a, double b,double c, double d){
    return __divf32((__sqrt(a*b)+c),d);
}

注:直接实现和用宏定义的函数应该时间是一样或者说是很接近的,没有优劣之分。 18001900的差别应该是测试方法有些不可控因素导致的。如果把直接实现的代码放在第三个部分,它也1800us。
 

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4 多重循环长循环放在层,短循环放在

在系统的多重循环过程中,需要程序员将最长的循环内容设置在系统的最内层,同时需要将最短的循环内容设置在系统的最外层。这样,能够有效提升CPU的运行效率,促进CPU的跨切循环次数。

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5 从算法本身的复杂度去优化

假设我要计算 1+2+…+100

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6 整数的乘除用位移运算替代

DSP的测试结果来看,位移运算和乘法时间一模一样,根本没区别。不推荐使用。

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7 通信优化

DSP经常会用到串口通信,串口发送主要优化思路是去掉多余的赋值语句循环语句。

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float fDrivex = 0.15;
float fDrivey = -0.3;
Uint16 FSM_TxBuffer[9]={0,0,0,0,0,0,0,0,0};

struct _FSM_com_struct_
{
    Uint16  sHeader;
    Uint16  controlmode;
    int     iEddyx;
    int     iEddyy;
    Uint16  Check;
    Uint16  tail;
}FSM_Tx_struct;
void testfunction(){ // 优化前
    int i = 0;
    FSM_Tx_struct.iEddyx = (int16)(fDrivex * 21333.33);
    FSM_Tx_struct.iEddyy = (int16)(fDrivey * 21333.33);

    FSM_TxBuffer[0] = 0x55;
    FSM_TxBuffer[1] = 0xAA;
    FSM_TxBuffer[2] = 0x10;
    FSM_TxBuffer[8] = 0xCC;
    FSM_TxBuffer[3] = ( (Uint16)(FSM_Tx_struct.iEddyx) >> 8);
    FSM_TxBuffer[4] = ( (Uint16)(FSM_Tx_struct.iEddyx) & 0x00FF);
    FSM_TxBuffer[5] = ( (Uint16)(FSM_Tx_struct.iEddyy) >> 8);
    FSM_TxBuffer[6] = ( (Uint16)(FSM_Tx_struct.iEddyy) & 0x00FF);
    FSM_TxBuffer[7] = 0xFF ^ FSM_TxBuffer[2] ^ FSM_TxBuffer[3] ^ FSM_TxBuffer[4] ^ FSM_TxBuffer[5] ^ FSM_TxBuffer[6];

    for(i = 0; i < 9; i++)
    {
        ScicRegs.SCITXBUF.all   = FSM_TxBuffer[i];
        while (ScicRegs.SCICTL2.bit.TXRDY == 0);
    }

}
float fDrivex = 0.15;
float fDrivey = -0.3;
Uint16 FSM_TxBuffer[9]={0,0,0,0,0,0,0,0,0};

struct _SCI_TX_struct_
{
    int     iEddyx;
    int     iEddyy;
};


struct _TxBUF_struct_
{
    Uint16  Low:8;
    Uint16  High:8;
};

union sciTxunion {
    struct  _TxBUF_struct_  TxBUF[2];
    struct  _SCI_TX_struct_ bit;
} FSM_Tx_union;

void testfunction1(){ // 优化后
    FSM_Tx_union.bit.iEddyx = (int16)(fDrivex * 21333.33);
    FSM_Tx_union.bit.iEddyy = (int16)(fDrivey * 21333.33);

    ScicRegs.SCITXBUF.all   = 0x55;
    while (ScicRegs.SCICTL2.bit.TXRDY == 0);

    ScicRegs.SCITXBUF.all   = 0xAA;
    while (ScicRegs.SCICTL2.bit.TXRDY == 0);

    ScicRegs.SCITXBUF.all   = 0x10;
    while (ScicRegs.SCICTL2.bit.TXRDY == 0);

    ScicRegs.SCITXBUF.all   = FSM_Tx_union.TxBUF[0].High;
    while (ScicRegs.SCICTL2.bit.TXRDY == 0);

    ScicRegs.SCITXBUF.all   = FSM_Tx_union.TxBUF[0].Low;
    while (ScicRegs.SCICTL2.bit.TXRDY == 0);

    ScicRegs.SCITXBUF.all   = FSM_Tx_union.TxBUF[1].High;
    while (ScicRegs.SCICTL2.bit.TXRDY == 0);

    ScicRegs.SCITXBUF.all   = FSM_Tx_union.TxBUF[1].Low;
    while (ScicRegs.SCICTL2.bit.TXRDY == 0);

    ScicRegs.SCITXBUF.all   = 0xEF ^ FSM_Tx_union.TxBUF[0].High ^ FSM_Tx_union.TxBUF[0].Low ^ FSM_Tx_union.TxBUF[1].High ^ FSM_Tx_union.TxBUF[1].Low;
    while (ScicRegs.SCICTL2.bit.TXRDY == 0);

    ScicRegs.SCITXBUF.all   = 0xCC;
    while (ScicRegs.SCICTL2.bit.TXRDY == 0);

}

串口接收主要优化思路也是去掉多余的赋值语句,另外,去掉多余的逻辑判断

// 优化前
interrupt void getScic(void){

    int i = 0;
    FSMRxCheck = 0xFF;
    for(i = 0; i < 9; i++)
    {
        FSM_RxBuffer[i]         = ScicRegs.SCIRXBUF.all;
        if(i > 1 && i<7){
            FSMRxCheck ^= FSM_RxBuffer[i];
        }
    }
    FSMRxCheck = FSMRxCheck & 0x00FF;

    FSM_Rx_Cnt  = FSM_Rx_Cnt + 1;

    ScicRegs.SCIFFRX.bit.RXFIFORESET    = 0;    // 0: Write 0 to reset the FIFO pointer to zero, and hold in reset.
    ScicRegs.SCIFFRX.bit.RXFIFORESET    = 1;    // 1: Re-enable receive FIFO operation

    ScicRegs.SCIFFRX.bit.RXFFINTCLR     = 1;    // 1: Write 1 to clear RXFFINT flag in bit 7

    PieCtrlRegs.PIEACK.all  = PIEACK_GROUP8;    // Writing a 1 to the respective interrupt bit clears the bit and enables the PIE block to drive a pulse into
                                                // the CPU interrupt input if an interrupt is pending for that group.
}

void getEddy(void){

    FSM_Rx_struct.sHeader       =   ( FSM_RxBuffer[0] << 8 ) + FSM_RxBuffer[1];
    FSM_Rx_struct.controlmode   =   FSM_RxBuffer[2];
    FSM_Rx_struct.iEddyx        =   (int)( ( FSM_RxBuffer[3] << 8) +  FSM_RxBuffer[4] );
    FSM_Rx_struct.iEddyy        =   (int)( ( FSM_RxBuffer[5] << 8) +  FSM_RxBuffer[6] );
    FSM_Rx_struct.Check         =   FSM_RxBuffer[7];
    FSM_Rx_struct.tail          =   FSM_RxBuffer[8];


    if(FSM_Rx_struct.sHeader == 0x55AA && FSM_Rx_struct.tail == 0xCC && FSMRxCheck == FSM_Rx_struct.Check){
        fEddyx  = (float)FSM_Rx_struct.iEddyx * 0.000046875;
        fEddyy  = (float)FSM_Rx_struct.iEddyy * 0.000046875;

        //asm ("      ESTOP0");
    }


}

// 优化后
Uint16 FSMRxCheck = 0x00FF;
interrupt void getScic(void){

    int i = 0;
    for(i = 0; i < 9; i++)
    {
        FSM_RxBuffer[i]         = ScicRegs.SCIRXBUF.all;
        if(i > 1 && i<7){
            FSMRxCheck ^= FSM_RxBuffer[i];
        }
    }
    DecodeEn = 1;


    ScicRegs.SCIFFRX.bit.RXFIFORESET    = 0;    // 0: Write 0 to reset the FIFO pointer to zero, and hold in reset.
    ScicRegs.SCIFFRX.bit.RXFIFORESET    = 1;    // 1: Re-enable receive FIFO operation
    ScicRegs.SCIFFRX.bit.RXFFINTCLR     = 1;    // 1: Write 1 to clear RXFFINT flag in bit 7
    PieCtrlRegs.PIEACK.all  = PIEACK_GROUP8;    // Writing a 1 to the respective interrupt bit clears the bit and enables the PIE block to drive a pulse into
                                                // the CPU interrupt input if an interrupt is pending for that group.
}

void getEddy(void){

    if( FSMRxCheck==FSM_RxBuffer[7] ){
        fEddyx  = (float)( (FSM_RxBuffer[3]<<8) + FSM_RxBuffer[4] ) * 0.000046875;
        fEddyy  = (float)( (FSM_RxBuffer[5]<<8) + FSM_RxBuffer[6] ) * 0.000046875;

        FSMRxCheck  = 0x00FF;
    }

}

 

 

 后续暂时是不会再写DSP算法加速的方法了。 感谢您的阅读,如果您还有什么优化的方法和思路,欢迎留言分享、收藏点赞

 

 

 

 

 

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