First, OpenGL uses multiple coordinate systems, so there is no "**the** OpenGL coordinate system". What you're referring to are normalized device coordinates (NDCs), where all three coordinates are in the range [-1, 1]. The different coordinate systems and their names are explained here, in the section "9.011 How are coordinates transformed? What are the different coordinate spaces?". 1)

Secondly, to avoid confusion, in OpenGL the term "viewport" refers to the part of the window that you're rendering to, and it's in window coordinates. In your question you used it to describe the portion (l,r,t,b)=(-500, -500, 1200, 1200) of your world that you want to render, which is in world coordinates.

You asked how to "calculate where to draw objects on screen". What you need to do is define a transformation (a 4x4 matrix) that maps from one coordinate system into another. Your 2D world is given in world coordinates, so you need to define a matrix that transforms world coordinates into NDCs, i.e. a projection matrix. In your shaders you then simply multiply your vertices with this projection matrix, and you get NDCs. `glm::ortho`

/`glOrtho`

computes such a projection matrix. As for the perspective projection, it's not clear what you want to do, but you should experiment with the `perspective`

and `lookat`

functions in glm.

To be clear, you define vertices in whatever coordinate system you want (which is called the world coordinate system), and simply draw these vertices. Your vertex shader's job is to apply the transformation you defined.

Also note that you specified a square, and typically that's not what you want. Monitors and most windows are not square, so if you map that square onto a typical viewport, you would get a distorted view of your world. You need to factor in the aspect ratio (width:height) of the viewport. I've tried to explain that here.

1) As a side note, the FAQ is quite old, and refers to ancient versions of OpenGL. Nowadays, programmers are expected and encouraged to manage both the model-view and the projection matrices themselves, since you need them in your shaders. I highly recommend glm, it's header-only thus very easy to integrate, and has nice syntax that mirrors GLSL.