CubicSDR/src/visual/ScopeCanvas.cpp

#include "ScopeCanvas.h"

#include "wx/wxprec.h"

#ifndef WX_PRECOMP
#include "wx/wx.h"
#endif

#if !wxUSE_GLCANVAS
#error "OpenGL required: set wxUSE_GLCANVAS to 1 and rebuild the library"
#endif

#include "CubicSDR.h"
#include "CubicSDRDefs.h"
#include "AppFrame.h"
#include <algorithm>

wxBEGIN_EVENT_TABLE(ScopeCanvas, wxGLCanvas) EVT_PAINT(ScopeCanvas::OnPaint)
EVT_KEY_DOWN(ScopeCanvas::OnKeyDown)
EVT_IDLE(ScopeCanvas::OnIdle)
wxEND_EVENT_TABLE()

ScopeCanvas::ScopeCanvas(wxWindow *parent, int *attribList) :
        wxGLCanvas(parent, wxID_ANY, attribList, wxDefaultPosition, wxDefaultSize,
        wxFULL_REPAINT_ON_RESIZE), parent(parent) {

    int in_block_size = BUF_SIZE / 2;
    int out_block_size = FFT_SIZE;

    in = (fftw_complex*) fftw_malloc(sizeof(fftw_complex) * in_block_size);
    out[0] = (fftw_complex*) fftw_malloc(sizeof(fftw_complex) * out_block_size);
    out[1] = (fftw_complex*) fftw_malloc(sizeof(fftw_complex) * out_block_size);
    plan[0] = fftw_plan_dft_1d(out_block_size, in, out[0], FFTW_FORWARD, FFTW_MEASURE);
    plan[1] = fftw_plan_dft_1d(out_block_size, out[0], out[1], FFTW_BACKWARD, FFTW_MEASURE);

    fft_ceil_ma = fft_ceil_maa = 100.0;
    fft_floor_ma = fft_floor_maa = 0.0;

    glContext = new ScopeContext(this, &wxGetApp().GetContext(this));
}

ScopeCanvas::~ScopeCanvas() {

}

void ScopeCanvas::OnPaint(wxPaintEvent& WXUNUSED(event)) {
    wxPaintDC dc(this);
    const wxSize ClientSize = GetClientSize();

    glContext->SetCurrent(*this);
    glViewport(0, 0, ClientSize.x, ClientSize.y);

    glContext->Plot(spectrum_points, test_demod.waveform_points);

    SwapBuffers();
}

void ScopeCanvas::OnKeyDown(wxKeyEvent& event) {
    float angle = 5.0;

    unsigned int freq;
    switch (event.GetKeyCode()) {
    case WXK_RIGHT:
        freq = ((AppFrame*) parent)->getFrequency();
        freq += 100000;
        ((AppFrame*) parent)->setFrequency(freq);
        break;
    case WXK_LEFT:
        freq = ((AppFrame*) parent)->getFrequency();
        freq -= 100000;
        ((AppFrame*) parent)->setFrequency(freq);
        break;
    case WXK_DOWN:
        break;
    case WXK_UP:
        break;
    case WXK_SPACE:
        break;
    default:
        event.Skip();
        return;
    }
}

void multiply2(float ar, float aj, float br, float bj, float *cr, float *cj) {
    *cr = ar * br - aj * bj;
    *cj = aj * br + ar * bj;
}
float polar_discriminant2(float ar, float aj, float br, float bj) {
    float cr, cj;
    double angle;
    multiply2(ar, aj, br, -bj, &cr, &cj);
    angle = atan2(cj, cr);
    return (angle / M_PI);
}

void ScopeCanvas::setData(std::vector<signed char> *data) {

    if (data && data->size()) {
        if (spectrum_points.size() < FFT_SIZE * 2) {
            spectrum_points.resize(FFT_SIZE * 2);
        }

        for (int i = 0; i < BUF_SIZE / 2; i++) {
            in[i][0] = (float) (*data)[i * 2] / 127.0f;
            in[i][1] = (float) (*data)[i * 2 + 1] / 127.0f;
        }

        fftw_execute(plan[0]);

        double fft_ceil = 0, fft_floor = 1;

        if (fft_result.size() < FFT_SIZE) {
            fft_result.resize(FFT_SIZE);
            fft_result_ma.resize(FFT_SIZE);
            fft_result_maa.resize(FFT_SIZE);
        }

        for (int j = 0; j < 2; j++) {
            for (int i = 0, iMax = FFT_SIZE / 2; i < iMax; i++) {
                double a = out[0][i][0];
                double b = out[0][i][1];
                double c = sqrt(a * a + b * b);

                double x = out[0][FFT_SIZE / 2 + i][0];
                double y = out[0][FFT_SIZE / 2 + i][1];
                double z = sqrt(x * x + y * y);

                fft_result[i] = (z);
                fft_result[FFT_SIZE / 2 + i] = (c);
            }
        }

        float time_slice = (float) SRATE / (float) (BUF_SIZE / 2);

        for (int i = 0, iMax = FFT_SIZE; i < iMax; i++) {
            fft_result_maa[i] += (fft_result_ma[i] - fft_result_maa[i]) * 0.65;
            fft_result_ma[i] += (fft_result[i] - fft_result_ma[i]) * 0.65;

            if (fft_result_maa[i] > fft_ceil) {
                fft_ceil = fft_result_maa[i];
            }
            if (fft_result_maa[i] < fft_floor) {
                fft_floor = fft_result_maa[i];
            }
        }

        fft_ceil += 1;
        fft_floor -= 1;

        fft_ceil_ma = fft_ceil_ma + (fft_ceil - fft_ceil_ma) * 0.01;
        fft_ceil_maa = fft_ceil_maa + (fft_ceil_ma - fft_ceil_maa) * 0.01;

        fft_floor_ma = fft_floor_ma + (fft_floor - fft_floor_ma) * 0.01;
        fft_floor_maa = fft_floor_maa + (fft_floor_ma - fft_floor_maa) * 0.01;

        // fftw_execute(plan[1]);

        for (int i = 0, iMax = FFT_SIZE; i < iMax; i++) {
            float v = (log10(fft_result_maa[i] - fft_floor_maa) / log10(fft_ceil_maa - fft_floor_maa));
            spectrum_points[i * 2] = ((float) i / (float) iMax);
            spectrum_points[i * 2 + 1] = v;
        }

        test_demod.writeBuffer(data);
    }
}

void ScopeCanvas::OnIdle(wxIdleEvent &event) {
    Refresh(false);
}