C++静态对象不保存数组属性值

Question

我在 Xilinx 的 Vitis HLS 中使用 C++ 工作。我正在编写一个简单的缓冲区来执行众所周知的重叠和添加算法 (https://www.eetimes.com/fft-convolution-and-the-overlap-add-method/)

我的代码创建了一个静态对象（我的缓冲区），然后使用“sample-wise”方法工作。

我使用的代码如下（header + 待合成函数+ testbench）：

Overlapper_HLS.hpp:

#include "ap_axi_sdata.h"
#include "hls_stream.h"
#include <ap_fixed.h>


#define IFFT_LENGTH 16
#define INPUT_WINDOW_LENGTH 8
#define BUFFER IFFT_LENGTH - INPUT_WINDOW_LENGTH

typedef ap_fixed<16,1> ap_fixed_data_type;

typedef struct {

    ap_fixed_data_type real_part;
    ap_fixed_data_type imaginary_part;

} my_data_struct;

typedef hls::axis<my_data_struct,0,0,0> pkt_t;

typedef hls::axis<my_data_struct,0,0,0> pkt_t_out;

class Overlapper {

private:
    ap_fixed_data_type IFFT_output_real[IFFT_LENGTH];
    ap_fixed_data_type IFFT_output_imaginary[IFFT_LENGTH];

    ap_fixed_data_type output_chunk_real[INPUT_WINDOW_LENGTH];
    ap_fixed_data_type output_chunk_imaginary[INPUT_WINDOW_LENGTH];

    ap_fixed_data_type buffer_real[BUFFER];
    ap_fixed_data_type buffer_imaginary[BUFFER];

    int counter;

public:
    Overlapper() {

        for(int i = 0; i<IFFT_LENGTH; i++){
            IFFT_output_real[i]= 0;
            IFFT_output_imaginary[i] = 0;
        }

        for(int i = 0; i<INPUT_WINDOW_LENGTH; i++){
            output_chunk_real[i]= 0;
            output_chunk_imaginary[i] = 0;
        }

        for(int i = 0; i<BUFFER; i++){
            buffer_real[i]= 0;
            buffer_imaginary[i] = 0;
        }

        counter = 0;
    }

    void top_function(
        hls::stream<pkt_t> &input_signal_stream,
        hls::stream<pkt_t> &output_signal_stream) {
#pragma HLS PIPELINE
        pkt_t pkt_input_signal;
        pkt_t pkt_output_signal;
        float tmp =0;
        int i = 0;

        if(counter < IFFT_LENGTH){
            i = counter;
            input_signal_stream.read(pkt_input_signal);
            
            IFFT_output_real[i] = pkt_input_signal.data.real_part;
            IFFT_output_imaginary[i] = pkt_input_signal.data.imaginary_part;

            counter++;
            printf("printing counter: %d \n", counter);
            printf("printing i: %d \n", i);

            printf("printing input value: %f \n", pkt_input_signal.data.real_part.to_float());
            printf("printing value of IFFT_real: %f \n", IFFT_output_real[i].to_float());


        }
        else{
            //Buffer does not contain the previously stored values anymore, it is always 0.
            for(int i=0; i<BUFFER; i++){
                printf("printing content of buffer: %f \n", buffer_real[i].to_float());
            }

            for(int i=0; i<BUFFER; i++){
                IFFT_output_real[i] += buffer_real[i];
                IFFT_output_imaginary[i] += buffer_imaginary[i];
                printf("checking buffer value before sum: %f \n", buffer_real[i].to_float());
                printf("checking sum result real: %f \n", IFFT_output_real[i].to_float());
                printf("checking sum result imaginary: %f \n", IFFT_output_imaginary[i].to_float());
            }

            for(int k=INPUT_WINDOW_LENGTH; k<IFFT_LENGTH; k++){
                buffer_real[k-BUFFER] = IFFT_output_real[k];
                buffer_imaginary[k-BUFFER] = IFFT_output_imaginary[k];
                printf("Printing value of buffer: %f \n", buffer_real[k-BUFFER].to_float());

            }
            //Here it seems that the values in Buffer are stored correctly
            for(int i=0; i<BUFFER; i++){
                printf("printing content of buffer: %f \n", buffer_real[i].to_float());
            }

            for(int j=0; j<INPUT_WINDOW_LENGTH; j++){
                pkt_output_signal.data.real_part = IFFT_output_real[j];
                pkt_output_signal.data.imaginary_part = IFFT_output_imaginary[j];
                printf("printing output signal: %f \n", pkt_output_signal.data.real_part.to_float());
                output_signal_stream.write(pkt_output_signal);
            }
            counter = 0;

        }

    }

};

void overlapper(hls::stream<pkt_t> &input_signal_stream, hls::stream<pkt_t> &output_signal_stream);

Overlapper_HLS.cpp:

#include <overlapper_HLS.hpp>

void overlapper(hls::stream<pkt_t> &input_signal_stream, hls::stream<pkt_t> &output_signal_stream){
    #pragma HLS INTERFACE axis register port=input_stream
    #pragma HLS INTERFACE axis register port=output_stream
    #pragma HLS INTERFACE ap_ctrl_none port=return
    static Overlapper bb;
    bb.top_function(input_signal_stream, output_signal_stream);
}

testbench.cpp:

#include <overlapper_HLS.hpp>

int main(){

    hls::stream<pkt_t> input_stream;
    hls::stream<pkt_t> output_stream;

    pkt_t input_data;
    pkt_t temp_output;
    float int_output, input_check;
    // pkt_t input_package_check

    input_data.data.real_part = 0.1;
    input_data.data.imaginary_part = 0.1;

    for(int i=0; i<32; i++){
        input_stream.write(input_data);
    }
    for(int i=0; i<34; i++){
        overlapper(input_stream, output_stream);
    }


    for(int i=0; i<16; i++){
        output_stream.read(temp_output);
        //printf("output_value: %f", temp_output.data.real_part.to_float());
        printf("output_value: %f \n", temp_output.data.real_part.to_float());

    }


    return 0;

}

我的代码按预期工作，我遇到的唯一问题是在 Overlapper class 的 top_function()、buffer_real 和 buffer_imaginary 中数组不存储函数的不同调用之间的值。

特别是问题出在以下代码行中：

else{
                //Here unfortunately the stored value is always 0! It seems like the values are "reset" between different calls of the function.
                for(int i=0; i<BUFFER; i++){
                    printf("printing content of buffer: %f \n", buffer_real[i]);
                }
    
                for(int i=0; i<BUFFER; i++){
                    IFFT_output_real[i] += buffer_real[i];
                    IFFT_output_imaginary[i] += buffer_imaginary[i];
                    printf("checking buffer value before sum: %f \n", buffer_real[i].to_float());
                    printf("checking sum result real: %f \n", IFFT_output_real[i].to_float());
                    printf("checking sum result imaginary: %f \n", IFFT_output_imaginary[i].to_float());
                }
    
                for(int k=INPUT_WINDOW_LENGTH; k<IFFT_LENGTH; k++){
                    //Here I am saving the values I need inside my buffer
                    buffer_real[k-BUFFER] = IFFT_output_real[k];
                    buffer_imaginary[k-BUFFER] = IFFT_output_imaginary[k];
                    printf("Printing value of buffer: %f \n", buffer_real[k-BUFFER].to_float());
    
                }
                //Once I assign the values in the previous for cycle, they seem to be stored correctly!
                for(int i=0; i<BUFFER; i++){
                    printf("printing content of buffer: %f \n", buffer_real[i]);
                }
    
                for(int j=0; j<INPUT_WINDOW_LENGTH; j++){
                    pkt_output_signal.data.real_part = IFFT_output_real[j];
                    pkt_output_signal.data.imaginary_part = IFFT_output_imaginary[j];
                    printf("printing output signal: %f \n", pkt_output_signal.data.real_part.to_float());
                    output_signal_stream.write(pkt_output_signal);
                }
                counter = 0;
    
            }

我不明白为什么我的 buffer_real 和 buffer_imaginary 似乎在不同的调用之间被重置，即使我创建的对象是静态的（实际上变量计数器在不同的调用之间被保留我的 top_function())

编辑：我正在添加我的输出日志

#### FIRST ROUND ######
printing counter: 1 
printing i: 0 
printing input value: 0.099976 
printing value of IFFT_real: 0.099976 
printing counter: 2 
printing i: 1 
printing input value: 0.099976 
printing value of IFFT_real: 0.099976 
printing counter: 3 
printing i: 2 
printing input value: 0.099976 
printing value of IFFT_real: 0.099976 
printing counter: 4 
printing i: 3 
printing input value: 0.099976 
printing value of IFFT_real: 0.099976 
printing counter: 5 
printing i: 4 
printing input value: 0.099976 
printing value of IFFT_real: 0.099976 
printing counter: 6 
printing i: 5 
printing input value: 0.099976 
printing value of IFFT_real: 0.099976 
printing counter: 7 
printing i: 6 
printing input value: 0.099976 
printing value of IFFT_real: 0.099976 
printing counter: 8 
printing i: 7 
printing input value: 0.099976 
printing value of IFFT_real: 0.099976 
printing counter: 9 
printing i: 8 
printing input value: 0.099976 
printing value of IFFT_real: 0.099976 
printing counter: 10 
printing i: 9 
printing input value: 0.099976 
printing value of IFFT_real: 0.099976 
printing counter: 11 
printing i: 10 
printing input value: 0.099976 
printing value of IFFT_real: 0.099976 
printing counter: 12 
printing i: 11 
printing input value: 0.099976 
printing value of IFFT_real: 0.099976 
printing counter: 13 
printing i: 12 
printing input value: 0.099976 
printing value of IFFT_real: 0.099976 
printing counter: 14 
printing i: 13 
printing input value: 0.099976 
printing value of IFFT_real: 0.099976 
printing counter: 15 
printing i: 14 
printing input value: 0.099976 
printing value of IFFT_real: 0.099976 
printing counter: 16 
printing i: 15 
printing input value: 0.099976 
printing value of IFFT_real: 0.099976 
printing first content of buffer: 0.000000 
printing first content of buffer: 0.000000 
printing first content of buffer: 0.000000 
printing first content of buffer: 0.000000 
printing first content of buffer: 0.000000 
printing first content of buffer: 0.000000 
printing first content of buffer: 0.000000 
printing first content of buffer: 0.000000 
checking buffer value before sum: 0.000000 
checking sum result real: 0.099976 
checking sum result imaginary: 0.099976 
checking buffer value before sum: 0.000000 
checking sum result real: 0.099976 
checking sum result imaginary: 0.099976 
checking buffer value before sum: 0.000000 
checking sum result real: 0.099976 
checking sum result imaginary: 0.099976 
checking buffer value before sum: 0.000000 
checking sum result real: 0.099976 
checking sum result imaginary: 0.099976 
checking buffer value before sum: 0.000000 
checking sum result real: 0.099976 
checking sum result imaginary: 0.099976 
checking buffer value before sum: 0.000000 
checking sum result real: 0.099976 
checking sum result imaginary: 0.099976 
checking buffer value before sum: 0.000000 
checking sum result real: 0.099976 
checking sum result imaginary: 0.099976 
checking buffer value before sum: 0.000000 
checking sum result real: 0.099976 
checking sum result imaginary: 0.099976 
Printing value of buffer after saving values: 0.099976 
Printing value of buffer after saving values: 0.099976 
Printing value of buffer after saving values: 0.099976 
Printing value of buffer after saving values: 0.099976 
Printing value of buffer after saving values: 0.099976 
Printing value of buffer after saving values: 0.099976 
Printing value of buffer after saving values: 0.099976 
Printing value of buffer after saving values: 0.099976 
printing second content of buffer: 0.000000 
printing second content of buffer: 0.000000 
printing second content of buffer: 0.000000 
printing second content of buffer: 0.000000 
printing second content of buffer: 0.000000 
printing second content of buffer: 0.000000 
printing second content of buffer: 0.000000 
printing second content of buffer: 0.000000 
printing output signal: 0.099976 
printing output signal: 0.099976 
printing output signal: 0.099976 
printing output signal: 0.099976 
printing output signal: 0.099976 
printing output signal: 0.099976 
printing output signal: 0.099976 
printing output signal: 0.099976 

### SECOND ROUND ### 
printing counter: 1 
printing i: 0 
printing input value: 0.099976 
printing value of IFFT_real: 0.099976 
printing counter: 2 
printing i: 1 
printing input value: 0.099976 
printing value of IFFT_real: 0.099976 
printing counter: 3 
printing i: 2 
printing input value: 0.099976 
printing value of IFFT_real: 0.099976 
printing counter: 4 
printing i: 3 
printing input value: 0.099976 
printing value of IFFT_real: 0.099976 
printing counter: 5 
printing i: 4 
printing input value: 0.099976 
printing value of IFFT_real: 0.099976 
printing counter: 6 
printing i: 5 
printing input value: 0.099976 
printing value of IFFT_real: 0.099976 
printing counter: 7 
printing i: 6 
printing input value: 0.099976 
printing value of IFFT_real: 0.099976 
printing counter: 8 
printing i: 7 
printing input value: 0.099976 
printing value of IFFT_real: 0.099976 
printing counter: 9 
printing i: 8 
printing input value: 0.099976 
printing value of IFFT_real: 0.099976 
printing counter: 10 
printing i: 9 
printing input value: 0.099976 
printing value of IFFT_real: 0.099976 
printing counter: 11 
printing i: 10 
printing input value: 0.099976 
printing value of IFFT_real: 0.099976 
printing counter: 12 
printing i: 11 
printing input value: 0.099976 
printing value of IFFT_real: 0.099976 
printing counter: 13 
printing i: 12 
printing input value: 0.099976 
printing value of IFFT_real: 0.099976 
printing counter: 14 
printing i: 13 
printing input value: 0.099976 
printing value of IFFT_real: 0.099976 
printing counter: 15 
printing i: 14 
printing input value: 0.099976 
printing value of IFFT_real: 0.099976 
printing counter: 16 
printing i: 15 
printing input value: 0.099976 
printing value of IFFT_real: 0.099976 
printing first content of buffer: 0.000000 
printing first content of buffer: 0.000000 
printing first content of buffer: 0.000000 
printing first content of buffer: 0.000000 
printing first content of buffer: 0.000000 
printing first content of buffer: 0.000000 
printing first content of buffer: 0.000000 
printing first content of buffer: 0.000000 
checking buffer value before sum: 0.000000 
checking sum result real: 0.099976 
checking sum result imaginary: 0.099976 
checking buffer value before sum: 0.000000 
checking sum result real: 0.099976 
checking sum result imaginary: 0.099976 
checking buffer value before sum: 0.000000 
checking sum result real: 0.099976 
checking sum result imaginary: 0.099976 
checking buffer value before sum: 0.000000 
checking sum result real: 0.099976 
checking sum result imaginary: 0.099976 
checking buffer value before sum: 0.000000 
checking sum result real: 0.099976 
checking sum result imaginary: 0.099976 
checking buffer value before sum: 0.000000 
checking sum result real: 0.099976 
checking sum result imaginary: 0.099976 
checking buffer value before sum: 0.000000 
checking sum result real: 0.099976 
checking sum result imaginary: 0.099976 
checking buffer value before sum: 0.000000 
checking sum result real: 0.099976 
checking sum result imaginary: 0.099976 
Printing value of buffer after saving values: 0.099976 
Printing value of buffer after saving values: 0.099976 
Printing value of buffer after saving values: 0.099976 
Printing value of buffer after saving values: 0.099976 
Printing value of buffer after saving values: 0.099976 
Printing value of buffer after saving values: 0.099976 
Printing value of buffer after saving values: 0.099976 
Printing value of buffer after saving values: 0.099976 
printing second content of buffer: 0.000000 
printing second content of buffer: 0.000000 
printing second content of buffer: 0.000000 
printing second content of buffer: 0.000000 
printing second content of buffer: 0.000000 
printing second content of buffer: 0.000000 
printing second content of buffer: 0.000000 
printing second content of buffer: 0.000000 
printing output signal: 0.099976 
printing output signal: 0.099976 
printing output signal: 0.099976 
printing output signal: 0.099976 
printing output signal: 0.099976 
printing output signal: 0.099976 
printing output signal: 0.099976 
printing output signal: 0.099976 
output_value: 0.099976 
output_value: 0.099976 
output_value: 0.099976 
output_value: 0.099976 
output_value: 0.099976 
output_value: 0.099976 
output_value: 0.099976 
output_value: 0.099976 
output_value: 0.099976 
output_value: 0.099976 
output_value: 0.099976 
output_value: 0.099976 
output_value: 0.099976 
output_value: 0.099976 
output_value: 0.099976 
output_value: 0.099976

您可能会注意到我的缓冲区始终为 0 值 (printing second content of buffer: 0.000000)，但是在我保存值的上一个周期中，它们似乎存储正确 (Printing value of buffer after saving values: 0.099976)。

基本上在打印缓冲区内容的第二“轮”中，它应该是0.099976而不是0

Answer 1

主要问题是我的 #define BUFFER IFFT_LENGTH - INPUT_WINDOW_LENGTH 在以下代码片段的索引中的使用：

 for(int k=INPUT_WINDOW_LENGTH; k<IFFT_LENGTH; k++){
                    //Here I am saving the values I need inside my buffer
                    buffer_real[k-BUFFER] = IFFT_output_real[k];
                    buffer_imaginary[k-BUFFER] = IFFT_output_imaginary[k];
                    printf("Printing value of buffer: %f \n", buffer_real[k-BUFFER].to_float());
    
                }

它打乱了索引，因为它用 16 - 8 代替了 BUFFER，所以我的索引变成了 8 - 16 + 8，它仍然是预期的 0，但可能它创建了一些问题，因为如果按顺序添加，数字会变成负数。

将该行代码更改为 buffer_real[k-(BUFFER)] = IFFT_output_real[k]; 解决了我的问题。

更好的解决方案是使用 constexpr 而不是定义：

#define IFFT_LENGTH 16
#define INPUT_WINDOW_LENGTH 8
constexpr int BUFFER=IFFT_LENGTH - INPUT_WINDOW_LENGTH;

C++静态对象不保存数组属性值

C++ static object does not save array attribute value

c++

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