04 Dec

Render a Triangle with OpenGL

This post will discuss how to render a triangle with OpenGL. In the following, renderization of a triangle assumes modern OpenGL, i.e., the old, fixed-function pipeline is of no concern for us in this post, as we’ll be using OpenGL buffer objects and shaders.

A Simple Triangle

By following the tutorials in the previous posts (Setting up Eclipse CDT for OpenGL and the GLFW Example) we were able to create a minimal program displaying an empty window. Now we want to draw something with OpenGL on that window, specifically, a triangle. Why a triangle? Well, the geometric shape more frequently used to approximate surfaces is the triangle. Approximation of 3D surfaces in real-time graphics by means of simpler shapes is known as tessellation. For our tutorial purposes, a single triangle will suffice.

GPU Power

Modern GPUs are quite fast and can also have a considerable amount of dedicated memory. When rendering, we’d like for as much rendering data as possible to be read by the GPU directly from its local memory. In order to render a triangle with OpenGL we’ll need, obviously, to transfer the 3 vertices of the triangle to the GPU’s memory. However, we do NOT want our rendering to go like this:

  • read a vertex from our computer RAM
  • copy it to the GPU memory
  • let the GPU process that single vertex
  • and then repeat this whole process for the next vertex of the triangle.

Ideally, what we want is to transfer a batch of data to the GPU’s memory, copying all the triangle vertices, and then letting the GPU operate with this data directly from its local memory. In OpenGL we have the concept of Vertex Buffer Object (VBO) to represent these data placed on GPU’s memory.

The data to render the triangle in OpenGL

Normally, we think of a vertex as a point, which in 3D space leads to a representation with 3 coordinates, commonly designated by x, y and z. However, in this case I’d like to think of a vertex as a more abstract concept: a minimal data structure required to define a shape. Given a vertex, we can “link” attributes to it to further define our shape. Thereby, one of such attributes of a vertex can be its position (the “x, y, z values”.) Other attribute might be the vertex’s color. And so on. In this tutorial we will “link” two attributes to our vertices: position and color. For position we will have three coordinates, each a floating point value. If a float takes 4 bytes, then our position attribute would require 3 x 4 = 12 bytes. For the color attribute, we’d have 3 extra components, following the RGB model. Each color component would then take 4 bytes, and the color attribute would also require 12 bytes. In total, each vertex would take 24 bytes, 12 for its position attribute, and 12 for its color attribute.

Now we have to specify how to process these vertices.

Read More
03 Dec

GLFW Example

Here I’ll briefly discuss a tiny GLFW example. Previously, I explained how to setup Eclipse CDT to work with OpenGL, using GLFW and GLAD. However, I instructed to copy-paste the example code on GLFW Documentation page, without providing any details. In the following I’ll present some code that you can add to the little project of our setup post, and will include GLAD initialization too.

Read More
27 Nov

Setting up Eclipse CDT for OpenGL with GLFW and GLAD

What’s OpenGL?

OpenGL is an API to render 2D and 3D graphics. Remember that an API (Application Programming Interface) is an interface for interaction between components of a system. Typically, an API defines a set of functions, protocols and/or tools. I’ll skip the details about the client-server model, but OpenGL allows a client program to communicate with GPUs (Graphic Processing Units, e.g., your videocard) to achieve faster, hardware-accelerated rendering. That’s why OpenGL is a common topic in the game development scene.

OpenGL is focused on just rendering. It’s an API to write and read data from a framebuffer, and that’s it. It won’t handle user input, or sound playback, or loading a PNG image. It does not even have functions to create or close a window. We’ll need auxiliar libraries for all of that.

A minimal OpenGL window

So we want to build a minimal OpenGL application on Windows. We’ll create an empty window with an OpenGL context, using the GLFW and GLAD libraries. In the following, I assume we’re using a 64 bits version of Windows. I’ll also be relying on mingw-w64. In summary, these are our assumptions:

  • Windows operating system (64 bits.) Things will be a tad different for macOS and Linux users.
  • Eclipse CDT.
  • mingw-w64 to build GLFW from sources. Besides, our Eclipse CDT project will be compiled with the gcc version of mingw-w64.
  • GLFW and GLAD libraries.

What’s GLFW?

As told, OpenGL does not provide any facility to create a window, retrieve user input, create the OpenGL context, etc. These functionalities depend on the operating system. GLFW is a C library which provides a neat abstraction layer to handle all of this on several platforms. Notice that GLFW is focused on management of windows, OpenGL contexts, user input and time. It will not play sounds, or load images, etc.

Read More