#include "PrimaryGLContext.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 #include "Demodulate.h" wxString glGetwxString(GLenum name) { const GLubyte *v = glGetString(name); if (v == 0) { // The error is not important. It is GL_INVALID_ENUM. // We just want to clear the error stack. glGetError(); return wxString(); } return wxString((const char*) v); } static void CheckGLError() { GLenum errLast = GL_NO_ERROR; for (;;) { GLenum err = glGetError(); if (err == GL_NO_ERROR) return; if (err == errLast) { wxLogError (wxT("OpenGL error state couldn't be reset.")); return; } errLast = err; wxLogError (wxT("OpenGL error %d"), err); } } PrimaryGLContext::PrimaryGLContext(wxGLCanvas *canvas) : wxGLContext(canvas) { SetCurrent(*canvas); glEnable(GL_CULL_FACE); glEnable(GL_DEPTH_TEST); glMatrixMode(GL_PROJECTION); glLoadIdentity(); CheckGLError(); } void PrimaryGLContext::Plot(std::vector &points, std::vector &points2) { glClear(GL_COLOR_BUFFER_BIT | GL_DEPTH_BUFFER_BIT); glMatrixMode(GL_MODELVIEW); glLoadIdentity(); // glEnable(GL_LINE_SMOOTH); if (points.size()) { glPushMatrix(); glTranslatef(-1.0f, -0.9f, 0.0f); glScalef(2.0f, 1.0f, 1.0f); glEnableClientState(GL_VERTEX_ARRAY); glVertexPointer(2, GL_FLOAT, 0, &points[0]); glDrawArrays(GL_LINE_STRIP, 0, points.size() / 2); glDisableClientState(GL_VERTEX_ARRAY); glPopMatrix(); } if (points2.size()) { glPushMatrix(); glTranslatef(-1.0f, 0.5f, 0.0f); glScalef(2.0f, 0.5f, 1.0f); glEnableClientState(GL_VERTEX_ARRAY); glVertexPointer(2, GL_FLOAT, 0, &points2[0]); glDrawArrays(GL_LINE_STRIP, 0, points2.size() / 2); glDisableClientState(GL_VERTEX_ARRAY); glPopMatrix(); } glFlush(); CheckGLError(); } wxBEGIN_EVENT_TABLE(TestGLCanvas, wxGLCanvas) EVT_PAINT(TestGLCanvas::OnPaint) EVT_KEY_DOWN(TestGLCanvas::OnKeyDown) EVT_IDLE(TestGLCanvas::OnIdle) wxEND_EVENT_TABLE() TestGLCanvas::TestGLCanvas(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_BACKWARD, FFTW_MEASURE); plan[1] = fftw_plan_dft_1d(out_block_size, in, out[1], FFTW_FORWARD, FFTW_MEASURE); fft_ceil_ma = fft_ceil_maa = 1.0; dev = alcOpenDevice(NULL); if (!dev) { fprintf(stderr, "Oops\n"); } ctx = alcCreateContext(dev, NULL); alcMakeContextCurrent(ctx); if (!ctx) { fprintf(stderr, "Oops2\n"); } alGenBuffers(AL_NUM_BUFFERS, buffers); alGenSources(1, &source); // prime the buffers ALuint buffer_init[AL_BUFFER_SIZE]; for (int i = 0; i < AL_BUFFER_SIZE; i++) { buffer_init[i] = 32767; } format = AL_FORMAT_MONO16; alBufferData(buffers[0], format, buffer_init, AL_BUFFER_SIZE, 32000); alBufferData(buffers[1], format, buffer_init, AL_BUFFER_SIZE, 32000); alBufferData(buffers[2], format, buffer_init, AL_BUFFER_SIZE, 32000); if (alGetError() != AL_NO_ERROR) { std::cout << "Error priming :(\n"; } alSourceQueueBuffers(source, AL_NUM_BUFFERS, buffers); alSourcePlay(source); if (alGetError() != AL_NO_ERROR) { std::cout << "Error starting :(\n"; } } TestGLCanvas::~TestGLCanvas() { alcMakeContextCurrent(NULL); alcDestroyContext(ctx); alcCloseDevice(dev); } void TestGLCanvas::OnPaint(wxPaintEvent& WXUNUSED(event)) { wxPaintDC dc(this); const wxSize ClientSize = GetClientSize(); PrimaryGLContext& canvas = wxGetApp().GetContext(this); glViewport(0, 0, ClientSize.x, ClientSize.y); canvas.Plot(spectrum_points, waveform_points); SwapBuffers(); } void TestGLCanvas::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 TestGLCanvas::setData(std::vector *data) { if (data && data->size()) { std::vector tmp(data->begin(), data->end()); demod.demod(tmp); if (waveform_points.size() < demod.lp_len * 2) { waveform_points.resize(demod.lp_len * 2); } float waveform_ceil = 0; for (int i = 0, iMax = demod.lp_len; i < iMax; i++) { float v = fabs(demod.lowpassed[i]); if (v > waveform_ceil) { waveform_ceil = v; } } for (int i = 0, iMax = demod.lp_len; i < iMax; i++) { waveform_points[i * 2 + 1] = (float) demod.lowpassed[i] / waveform_ceil; waveform_points[i * 2] = ((double) i / (double) iMax); } ALint val; ALuint buffer; frequency = demod.output.rate; alGetSourcei(source, AL_BUFFERS_PROCESSED, &val); if (val > 0) { std::cout << "buffer: " << demod.output_target->len << "@" << frequency << std::endl; // std::vector al_buffer; // al_buffer.resize(demod.lp_len); // for (int i = 0, iMax = demod.lp_len; i < iMax; i++) { // al_buffer[i] = demod.lowpassed[i] + 32767.0; // } alSourceUnqueueBuffers(source, 1, &buffer); alBufferData(buffer, format, demod.output_target->buf, demod.output_target->len*2, frequency); alSourceQueueBuffers(source, 1, &buffer); if (alGetError() != AL_NO_ERROR) { std::cout << "Error buffering :(\n"; } } alGetSourcei(source, AL_SOURCE_STATE, &val); if (val != AL_PLAYING) { alSourcePlay(source); } 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] = (double) (*data)[i * 2] / 127.0f; in[i][1] = (double) (*data)[i * 2 + 1] / 127.0f; } fftw_execute(plan[0]); fftw_execute(plan[1]); double fft_ceil = 0; // fft_floor, 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[j][j ? i : ((iMax - 1) - i)][0]; double b = out[j][j ? i : ((iMax - 1) - i)][1]; double c = sqrt(a * a + b * b); double x = out[j ? 0 : 1][j ? ((FFT_SIZE - 1) - i) : ((FFT_SIZE / 2) + i)][0]; double y = out[j ? 0 : 1][j ? ((FFT_SIZE - 1) - i) : ((FFT_SIZE / 2) + i)][1]; double z = sqrt(x * x + y * y); double r = (c < z) ? c : z; if (!j) { fft_result[i] = r; } else { fft_result[(FFT_SIZE / 2) + i] = r; } } } 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]; } } fft_ceil_ma = fft_ceil_ma + (fft_ceil - fft_ceil_ma) * 0.05; fft_ceil_maa = fft_ceil_maa + (fft_ceil - fft_ceil_maa) * 0.05; for (int i = 0, iMax = FFT_SIZE; i < iMax; i++) { spectrum_points[i * 2 + 1] = fft_result_maa[i] / fft_ceil_maa; spectrum_points[i * 2] = ((double) i / (double) iMax); } } } void TestGLCanvas::OnIdle(wxIdleEvent &event) { Refresh(false); }