To see an object on screen you need it to fall within the canonical view volume, which is, for OpenGL, [−1, 1] in all three dimensions. To transform an object, you roughly do

P' = Projection × View × Model × P

where `P'`

is the final point which needs to be in the canonical view volume and P is the initial point in model space. P is transformed by the model matrix followed by view and then projection.

The order I've followed is column vector based, where each further transform is pre/left-multiplied. Another way to read the same formula is to read it from left-to-right where instead of transforming the point, the coordinate system is transformed and interpreting `P`

in the transformed system spatially represents `P'`

in the original system. This is just another way to see it, the result is the same in both; both numerically and spatially.

why do we have to do gluPerspective before gluLookAt?

The older, fixed-function pipeline *OpenGL post/right-multiplies* and thus the order needs to be reversed to get the same effect. So when we need *LookAt* first and *Perspective* next, we do the reverse to get the expected result.

Giving the two in right order leads to

P' = View × Projection × Model × P

since matrix multiplication is anti-commutative, you don't get the right `P'`

which falls within the canonical view volume and hence black screen.

See the Chapter 3, Red Book, under the section *General-Purpose Transformation Commands* which explains the order followed by OpenGL. Excerpt:

**Note:** All matrix multiplication with OpenGL occurs as follows: Suppose the current matrix is **C** and the matrix specified with *glMultMatrix*()* or any of the transformation commands is **M**. After multiplication, the final matrix is always **CM**. Since matrix multiplication isn't generally commutative, the order makes a difference.

I want to know why the first case works but the second doesn't.

To know what really happens with the matrix formed of incorrect order, lets do a small workout in 2D. Lets say the canonical view *region* is [−100, 100] in both X and Y; anything outside this is clipped out. The origin of this imaginary square screen is at the centre, X goes right, Y goes up. When no transform is applied calling `DrawImage`

draws the image at the origin. You've an image which is 1 × 1; its model matrix is scaling by `200`

so that it becomes a `200 × 200`

image; one that fills the entire screen. Since origin is at centre of the screen, to draw the image such that it fills the screen, we need a view matrix that translates (moves) the image by (−100, −100). Formulating this

P' = View × Model = Translate_{−100, −100} × Scale_{200, 200}

```
[ 200, 0, −100 ]
[ 0, 200, −100 ]
[ 0, 0, 1 ]
```

However, the result of

Model × View = S_{200, 200} × T_{−100, −100}

```
[ 200, 0, −20000 ]
[ 0, 200, −20000 ]
[ 0, 0, 1 ]
```

Multiplying the former matrix with points (0, 0) and (1, 1) would result in (−100, −100) and (100, 100) as expected. The image corners would be aligned to the screen corners. However, multiplying the latter matrix with them would result in (−20000, −20000) and (−19800, −19800); well outside the viewable region. This is because, geometrically, the latter matrix first translates and then scales as opposed to scaling and then translating. The translated scale leads to a point that is completely off.

`GL_PROJECTION`

should only have projection transforms, both model and view transforms should go in`GL_MODELVIEW`

. Although it'll work, it's the right thing to do, a convention to be followed.