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I have been writing a simple GTK+ application and am just getting started with graphical development. I understand that this may not be a good place to start, jumping straight into 3D rendering, but I've done a small amount of it before and with great success using Glade and reading a plethora of docs, I figured it would not be hard to integrate the two - I figured incorrectly. The problem at hand is that glDrawArrays appears to not be working. I looked at this question and unfortunately, it did not help me. I followed some of this tutorial on OpenGL and also this tutorial on GtkGLArea again to no avail.

Can anyone point me in the right direction on this one? I'm not sure where to go from here.

The relevant code is below:

#include "RenderingManager.hpp"

RenderingManager::RenderingManager()  {
  ///GTK+ Setup///
  std::cout << "starting render constructor" << std::endl;
  glArea = GTK_GL_AREA(gtk_gl_area_new());
  std::cout << "got new glarea" << std::endl;
  g_signal_connect(GTK_WIDGET(glArea), "render", G_CALLBACK(signal_render), this);
  g_signal_connect(GTK_WIDGET(glArea), "realize", G_CALLBACK(signal_realize), this);
  g_signal_connect(GTK_WIDGET(glArea), "unrealize", G_CALLBACK(signal_unrealize), this);
  gtk_widget_show(GTK_WIDGET(glArea));
  ///Get Shaders///
  // vshader.open("vertex.shader");
  // fshader.open("fragment.shader");

  std::cout << "finished render constructor" << std::endl;
}

void RenderingManager::onRender() {
    // Dark blue background
    glClearColor(0.1f, 0.0f, 0.1f, 0.0f);
    draw_triangle();
    glFlush();
}
void RenderingManager::initBuffers () {
    glGenVertexArrays(1, &vao);
    glBindVertexArray(vao);

  glGenBuffers(1, &vbo);
    glBindBuffer(GL_ARRAY_BUFFER, vbo);
    glBufferData(GL_ARRAY_BUFFER, sizeof(g_vertex_buffer_data), g_vertex_buffer_data, GL_STATIC_DRAW);

}

void RenderingManager::loadShaders()  {
  // Read the Vertex Shader code from the file
    std::ifstream VertexShaderStream("vertex.shader", std::ios::in);
    if(VertexShaderStream.is_open()){
        std::string Line = "";
        while(getline(VertexShaderStream, Line))
            vshader += "\n" + Line;
        VertexShaderStream.close();
    }

    // Read the Fragment Shader code from the file
    std::ifstream FragmentShaderStream("fragment.shader", std::ios::in);
    if(FragmentShaderStream.is_open()){
        std::string Line = "";
        while(getline(FragmentShaderStream, Line))
            fshader += "\n" + Line;
        FragmentShaderStream.close();
    }

  GLuint vsh, fsh;
  vsh = glCreateShader(GL_VERTEX_SHADER);
  fsh = glCreateShader(GL_FRAGMENT_SHADER);
  vshp = vshader.data();
  fshp = fshader.data();
  // vshp = vshader.get().c_str();
  // fshp = fshader.get().c_str();
  // vshader.get(vshp);
  // fshader.get(fshp);
  printf("%s\n%s\n", vshp, fshp);
  glShaderSource(vsh, 1, &vshp, NULL);
  glShaderSource(fsh, 1, &fshp, NULL);

  glCompileShader(vsh);
  glCompileShader(fsh);

  shaderProgramID = glCreateProgram();
  glAttachShader(shaderProgramID, vsh);
  glAttachShader(shaderProgramID, fsh);
  glLinkProgram(shaderProgramID);

  GLint Result = GL_FALSE;
  int InfoLogLength;
  // Check Vertex Shader
    glGetShaderiv(vsh, GL_COMPILE_STATUS, &Result);
    glGetShaderiv(vsh, GL_INFO_LOG_LENGTH, &InfoLogLength);
    if ( InfoLogLength > 0 ){
        char* VertexShaderErrorMessage = new char[InfoLogLength+1];
        glGetShaderInfoLog(vsh, InfoLogLength, NULL, &VertexShaderErrorMessage[0]);
        printf("%s\n", &VertexShaderErrorMessage[0]);
    }
  // Check Fragment Shader
    glGetShaderiv(fsh, GL_COMPILE_STATUS, &Result);
    glGetShaderiv(fsh, GL_INFO_LOG_LENGTH, &InfoLogLength);
    if ( InfoLogLength > 0 ){
        char* FragmentShaderErrorMessage = new char[InfoLogLength+1];
        glGetShaderInfoLog(fsh, InfoLogLength, NULL, &FragmentShaderErrorMessage[0]);
        printf("%s\n", &FragmentShaderErrorMessage[0]);
    }
}
void RenderingManager::onActivate() {

  // We need to make the context current if we want to
  // call GL API
  gtk_gl_area_make_current (glArea);

  glewExperimental = GL_TRUE;
  glewInit();

  loadShaders();
  initBuffers();

}
void RenderingManager::signal_render(GtkGLArea *a, gpointer *user_data) {
  reinterpret_cast<RenderingManager*>(user_data)->onRender();

}
void RenderingManager::signal_realize(GtkGLArea *a, gpointer *user_data)  {
  reinterpret_cast<RenderingManager*>(user_data)->onActivate();

}
void RenderingManager::signal_unrealize(GtkGLArea *a, gpointer *user_data)  {
    //Don't do this
    //reinterpret_cast<RenderingManager*>(user_data)->~RenderingManager();
}
void RenderingManager::draw_triangle()  {
  // Clear the screen
        glClear( GL_COLOR_BUFFER_BIT );

        // Use our shader
        glUseProgram(shaderProgramID);

        // 1rst attribute buffer : vertices
        glEnableVertexAttribArray(0);
        glBindBuffer(GL_ARRAY_BUFFER, vbo);
        glVertexAttribPointer(
            0,                  // attribute 0. No particular reason for 0, but must match the layout in the shader.
            3,                  // size
            GL_FLOAT,           // type
            GL_FALSE,           // normalized?
            0,                  // stride
            (void*)0            // array buffer offset
        );

        // Draw the triangle !
        glDrawArrays(GL_TRIANGLES, 0, 3); // 3 indices starting at 0 -> 1 triangle

        glDisableVertexAttribArray(0);

}
GtkGLArea *RenderingManager::expose()  {
  //yikes
  return glArea;
}

RenderingManager::~RenderingManager() {
  glDeleteBuffers(1, &vbo);
    glDeleteVertexArrays(1, &vao);
    glDeleteProgram(shaderProgramID);
  std::cout << "GL Resources deleted." << std::endl;
}
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  • For what it's worth the only reinterpret_cast "haxx" there is the one that you didn't label as a "haxx" — directly calling your destructor on yourself. I'm surprised that's even legal in C++. Whatever the case, and even if you make it saner (delete reinterpret_cast<...>(...)), it does mean once you get unrealized, you'll never be safely realized again. Consider restructuring those handlers...
    – andlabs
    Jan 17, 2017 at 7:28
  • @andlabs will do, I didn't know that.
    – PyroAVR
    Jan 17, 2017 at 16:06

1 Answer 1

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Due to the asynchronous nature of X11 (Gtk+ uses it) the gl-context can't be created before the window is realized (a connection to X11 is made).

Create the gl-context in your signal_realize() and make it current before drawing, which should be done handling signal expose_event (gtk+ 2) or draw(gtk+ 3)

3
  • I'm not sure what you mean by this - I think that's already happening. onActivate handles the realize signal, and onRender handles the render signal. How do I create a GL context? I thought the GtkGLArea did that for me, if I read the docs right...
    – PyroAVR
    Jan 16, 2017 at 4:42
  • See the realize example here: developer.gnome.org/gtk3/unstable/…
    – TingPing
    Jan 16, 2017 at 21:56
  • @TingPing I followed that when I got started. My code includes all those elements, and I have filled out loading shaders and buffers and such. Unfortunately, I am still stuck.
    – PyroAVR
    Jan 17, 2017 at 5:42

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