godot-docs/tutorials/mesh_generation_with_heightmap_and_shaders.rst

.. _doc_mesh_generation_with_heightmap_and_shaders:

Mesh generation with heightmap and shaders
==========================================

Introduction
------------

This tutorial will help you to use Godot shaders to deform a plane
mesh so it appears like a basic terrain. Remember that this solution
has pros and cons.

Pros:

-  Pretty easy to do.
-  This approach allows computation of LOD terrains.
-  The heightmap can be used in Godot to create a normal map.

Cons:

-  The Vertex Shader can't re-compute normals of the faces. Thus, if
   your mesh is not static, this method will **not** work with shaded
   materials.
-  This tutorial uses a plane mesh imported from Blender to Godot
   Engine. Godot is able to create meshes as well.

See this tutorial as an introduction, not a method that you should
employ in your games, except if you intend to do LOD. Otherwise, this is
probably not the best way.

However, let's first create a heightmap,or a 2D representation of the terrain.
To do this, I'll use GIMP, but you can use any image editor you like.

The heightmap
-------------

We will use a few functions of GIMP image editor to produce a simple
heightmap. Start GIMP and create a square image of 512x512 pixels.

.. image:: /img/1_GIMP_createImage512.png

You are now in front of a new, blank, square image.

.. image:: /img/2_GIMP.png

Then, use a filter to render some clouds on this new image.

.. image:: /img/3_GIMP_FilterRenderClouds.png

Parameter this filter to whatever you want. A white pixel corresponds
to the highest point of the heightmap, a black pixel corresponds to
the lowest one. So, darker regions are valleys and brighter are
mountains. If you want, you can check "tileable" to render a heightmap
that can be cloned and tiled close together with another one. X and Y
size don't matter a lot as long as they are big enough to provide a
decent ground. A value of 4.0 or 5.0 for both is nice. Click on the
"New Seed" button to roll a dice and GIMP will create a new random
heightmap. Once you are happy with the result, click "OK".

.. image:: /img/4_GIMP_Clouds.png

You can continue to edit your image if you wish. For our example,
let's keep the heightmap as is, and let's export it to a PNG file, say
"heightmap.png". Save it in your Godot project folder.

The plane mesh
--------------

Now, we will need a plane mesh to import in Godot. Let's run Blender.

.. image:: /img/5_Blender.png

Remove the start cube mesh, then add a new plane to the scene.

.. image:: /img/6_Blender_CreatePlane.png

Zoom a bit, then switch to Edit mode (Tab key) and in the Tools
buttongroup at the left, hit "Subdivide" 5 or 6 times.

.. image:: /img/7_Blender_subdivided.png

Your mesh is now subdivided, which means we added vertices to the
plane mesh that we will later be able to move. Job's not finished yet:
in order to texture this mesh a proper UV map is necessary. Currently,
the default UV map contains only the 4 corner vertices we had at the
beginning. However, we now have more, and we want to be able to
texture over the whole mesh correctly.

If all the vertices of your mesh are not selected, select them all
(hit "A"). They must appear orange, not black. Then, in the
Shading/UVs button group to the left, click the "Unwrap" button (or
simply hit "U") and select "Smart UV Project". Keep the default
options and hit "Ok".

.. image:: /img/8_Blender_UVSmart.png

Now, we need to switch our view to "UV/Image editor".

.. image:: /img/9_Blender_UV_editor.png

Select all the vertices again ("A") then in the UV menu, select
"Export UV Layout".

.. image:: /img/10_Blender_exportUV.png

Export the layout as a PNG file. Name it "plane.png" and save it in
your Godot project folder. Now, let's export our mesh as an OBJ file.
Top of the screen, click "File/Export/Wavefront (obj)". Save your
object as "plane.obj" in your Godot project folder.

Shader magic
------------

Let's now open Godot Editor.

Create a new project in the folder you previously created and name it
what you want.

.. image:: /img/11_Godot.png

In our default scene (3D), create a root node "Spatial". Next, import
the mesh OBJ file. Click "Import", choose "3D Mesh" and select your
plane.obj file, set the target path as "/" (or wherever you want in
your project folder).

.. image:: /img/12_Godot_ImportMesh.png

I like to check "Normals" in the import pop-up so the import will also
consider faces normals, which can be useful (even if we don't use them
in this tutorial). Your mesh is now displayed in the FileSystem in
"res://".

.. image:: /img/13_Godot_ImportPopup.png

Create a MeshInstance node. In the Inspector, load the mesh we just
imported. Select "plane.msh" and hit ok.

.. image:: /img/14_Godot_LoadMesh.png

Great! Our plane is now rendered in the 3D view.

.. image:: /img/15_Godot_MeshPlaneRendered.png

It is time to add some shader stuff. In the Inspector, in the
"Material Override" line, add a "New ShaderMaterial". Edit it by
clicking the ">" button just right to it.

.. image:: /img/16_Godot_ShaderMaterial.png

You have two ways to create a shader: by code (MaterialShader), or
using a shader graph (MaterialShaderGraph). The second one is a bit
more visual, but we will not cover it for now. Create a "New
MaterialShader".

.. image:: /img/17_Godot_newMaterialShader.png

Edit it by clicking the ">" button just right to it. The Shaders
editor opens.

.. image:: /img/18_Godot_ShaderEditorOpened.png

The Vertex tab is for the Vertex shader, and the Fragment tab is for
the Fragment shader. No need to explain what both of them do, right?
If so, head to the :ref:`doc_shading_language` page. Else, let's start with the
Fragment shader. This one is used to texture the plane using an image.
For this example, we will texture it with the heightmap image itself,
so we'll actually see mountains as brighter regions and canyons as
darker regions. Use this code:

::

    uniform texture source;
    uniform color col;
    DIFFUSE = col.rgb * tex(source,UV).rgb;

This shader is very simple (it actually comes from the :ref:`doc_shading_language` page).
What it basically does is take 2 parameters that we have to provide from
outside the shader ("uniform"):

-  the texture file
-  a color
   Then, we multiply every pixel of the image given by
   ``tex(source, UV).rgb`` by the color defined ``col`` and we set it to
   DIFFUSE variable, which is the rendered color. Remember that the
   ``UV`` variable is a shader variable that returns the 2D position of
   the pixel in the texture image, according to the vertex we are
   currently dealing with. That is the use of the UV Layout we made
   before. The color ``col`` is actually not necessary to display the
   texture, but it is interesting to play and see how it does, right?

However, the plane is displayed black! This is because we didn't set
the texture file and the color to use.

.. image:: /img/19_Godot_BlackPlane.png

In the Inspector, click the "Previous" button to get back to the
ShaderMaterial. This is where you want to set the texture and the
color. In "Source", click "Load" and select the texture file
"heightmap.png". But the mesh is still black! This is because our
Fragment shader multiplies each pixel value of the texture by the
``col`` parameter. However, this color is currently set to black
(0,0,0), and as you know, 0\*x = 0 ;) . Just change the ``col``
parameter to another color to see your texture appear:

.. image:: /img/20_Godot_TexturedPlane.png

Good. Now, the Vertex Shader.

The Vertex Shader is the first shader to be executed by the pipeline. It
deals with vertices.

Click the "Vertex" tab to switch, and paste this code:

::

    uniform texture source;
    uniform float height_range;
    vec2 xz = SRC_VERTEX.xz;
    float h = tex(source, UV).g * height_range;
    VERTEX = vec3(xz.x, h, xz.y);
    VERTEX = MODELVIEW_MATRIX *  VERTEX;

This shader uses two "uniform" parameters. The ``source`` parameter is
already set for the fragment shader. Thus, the same image will be used
in this shader as the heightmap. The ``height_range`` parameter is a
parameter that we will use to increase the height effect.

At line 3, we save the x and z position of the SRC_VERTEX, because we
do not want them to change : the plane must remain square. Remember
that Y axis corresponds to the "altitude", which is the only one we
want to change with the heightmap.

At line 4, we compute an ``h`` variable by multiplying the pixel value
at the UV position and the ``height_range``. As the heightmap is a
greyscale image, all r, g and b channels contain the same value. I
used ``g``, but any of r, g and b have the same effect.

At line 5, we set the current vertex' position at (xz.x, h, xz.y)
position. Concerning xz.y remember that its type is "vec2". Thus, its
components are x and y. The y component simply contains the z position
we set at line 3.

Finally, at line 6, we multiply the vertex by the model/view matrix in
order to set its position according to camera position. If you try to
comment this line, you'll see that the mesh behaves weird as you move
and rotate the camera.

That's all good, but our plane remains flat. This is because the
``height_range`` value is 0. Increase this value to observe the mesh
distort and take to form of the terrain we set before:

.. image:: /img/21_Godot_Fini.png