OpenGL Visualization with LWJGL
24 Sep 2025Using LWJGL’s OpenGL bindings and Fastmath to render data from NASA’s CGI Moon Kit
(Cross posting article published at Clojure Civitas)
Getting dependencies
First we need to get some libraries and we can use add-libs to fetch them.
(add-libs {'org.lwjgl/lwjgl {:mvn/version "3.3.6"}
'org.lwjgl/lwjgl$natives-linux {:mvn/version "3.3.6"}
'org.lwjgl/lwjgl-opengl {:mvn/version "3.3.6"}
'org.lwjgl/lwjgl-opengl$natives-linux {:mvn/version "3.3.6"}
'org.lwjgl/lwjgl-glfw {:mvn/version "3.3.6"}
'org.lwjgl/lwjgl-glfw$natives-linux {:mvn/version "3.3.6"}
'org.lwjgl/lwjgl-stb {:mvn/version "3.3.6"}
'org.lwjgl/lwjgl-stb$natives-linux {:mvn/version "3.3.6"}
'generateme/fastmath {:mvn/version "3.0.0-alpha3"}})
(require '[clojure.java.io :as io])
(import '[javax.imageio ImageIO]
'[org.lwjgl BufferUtils]
'[org.lwjgl.glfw GLFW]
'[org.lwjgl.opengl GL GL11 GL13 GL15 GL20 GL30]
'[org.lwjgl.stb STBImageWrite])Creating the window
Next we choose the window width and height.
(def window-width 640)
(def window-height 480)(def radius 1737.4)We define a function to get the temporary directory.
(defn tmpdir
[]
(System/getProperty "java.io.tmpdir"))And then a function to get a temporary file name.
(defn tmpname
[]
(str (tmpdir) "/civitas-" (java.util.UUID/randomUUID) ".tmp"))The following function is used to create screenshots for this article. We read the pixels, write them to a temporary file using the STB library and then convert it to an ImageIO object.
(defn screenshot
[]
(let [filename (tmpname)
buffer (java.nio.ByteBuffer/allocateDirect (* 4 window-width window-height))]
(GL11/glReadPixels 0 0 window-width window-height
GL11/GL_RGBA GL11/GL_UNSIGNED_BYTE buffer)
(STBImageWrite/stbi_write_png filename window-width window-height 4
buffer (* 4 window-width))
(-> filename io/file (ImageIO/read))))We need to initialize the GLFW library.
(GLFW/glfwInit)Now we create an invisible window. You can create a visisble window if you want to by not setting the visibility hint to false.
(def window
(do
(GLFW/glfwDefaultWindowHints)
(GLFW/glfwWindowHint GLFW/GLFW_VISIBLE GLFW/GLFW_FALSE)
(GLFW/glfwCreateWindow window-width window-height "Invisible Window" 0 0)))If you have a visible window, you can show it as follows.
(GLFW/glfwShowWindow window)Note that if you are using a visible window, you always need to swap buffers after rendering.
(GLFW/glfwSwapBuffers window)(do
(GLFW/glfwMakeContextCurrent window)
(GL/createCapabilities))Basic rendering
Clearing the window
A simple test is to set a clear color and clear the window.
(do
(GL11/glClearColor 1.0 0.5 0.25 1.0)
(GL11/glClear GL11/GL_COLOR_BUFFER_BIT)
(screenshot))
Creating shader programs
We define a convenience function to compile a shader and handle any errors.
(defn make-shader [source shader-type]
(let [shader (GL20/glCreateShader shader-type)]
(GL20/glShaderSource shader source)
(GL20/glCompileShader shader)
(when (zero? (GL20/glGetShaderi shader GL20/GL_COMPILE_STATUS))
(throw (Exception. (GL20/glGetShaderInfoLog shader 1024))))
shader))We also define a convenience function to link a program and handle any errors.
(defn make-program [& shaders]
(let [program (GL20/glCreateProgram)]
(doseq [shader shaders]
(GL20/glAttachShader program shader)
(GL20/glDeleteShader shader))
(GL20/glLinkProgram program)
(when (zero? (GL20/glGetProgrami program GL20/GL_LINK_STATUS))
(throw (Exception. (GL20/glGetProgramInfoLog program 1024))))
program))The following code shows a simple vertex shader which passes through vertex coordinates.
(def vertex-source "
#version 130
in vec3 point;
void main()
{
gl_Position = vec4(point, 1);
}")In the fragment shader we use the pixel coordinates to output a color ramp. The uniform variable iResolution will later be set to the window resolution.
(def fragment-source "
#version 130
uniform vec2 iResolution;
out vec4 fragColor;
void main()
{
fragColor = vec4(gl_FragCoord.xy / iResolution.xy, 0, 1);
}")Let’s compile the shaders and link the program.
(do
(def vertex-shader (make-shader vertex-source GL20/GL_VERTEX_SHADER))
(def fragment-shader (make-shader fragment-source GL20/GL_FRAGMENT_SHADER))
(def program (make-program vertex-shader fragment-shader)))Note: It is beyond the topic of this talk, but you can set up a Clojure function to test an OpenGL shader function by using a probing fragment shader and rendering to a one pixel texture. Please see my article Test Driven Development with OpenGL for more information!
Creating vertex buffer data
To provide the shader program with vertex data we are going to define just a single quad consisting of four vertices.
First we define a macro and use it to define convenience functions for converting arrays to LWJGL buffer objects.
(defmacro def-make-buffer [method create-buffer]
`(defn ~method [data#]
(let [buffer# (~create-buffer (count data#))]
(.put buffer# data#)
(.flip buffer#)
buffer#)))(do
(def-make-buffer make-float-buffer BufferUtils/createFloatBuffer)
(def-make-buffer make-int-buffer BufferUtils/createIntBuffer)
(def-make-buffer make-byte-buffer BufferUtils/createByteBuffer))We define a simple background quad spanning the entire window. We use normalised device coordinates (NDC) which are between -1 and 1.
(def vertices
(float-array [ 1.0 1.0 0.0
-1.0 1.0 0.0
-1.0 -1.0 0.0
1.0 -1.0 0.0]))The index array defines the order of the vertices.
(def indices
(int-array [0 1 2 3]))Setting up the vertex buffer
We add a convenience function to setup VAO, VBO, and IBO.
- We define a vertex array object (VAO) which acts like a context for the vertex and index buffer.
- We define a vertex buffer object (VBO) which contains the vertex data.
- We also define an index buffer object (IBO) which contains the index data.
(defn setup-vao [vertices indices]
(let [vao (GL30/glGenVertexArrays)
vbo (GL15/glGenBuffers)
ibo (GL15/glGenBuffers)]
(GL30/glBindVertexArray vao)
(GL15/glBindBuffer GL15/GL_ARRAY_BUFFER vbo)
(GL15/glBufferData GL15/GL_ARRAY_BUFFER (make-float-buffer vertices)
GL15/GL_STATIC_DRAW)
(GL15/glBindBuffer GL15/GL_ELEMENT_ARRAY_BUFFER ibo)
(GL15/glBufferData GL15/GL_ELEMENT_ARRAY_BUFFER (make-int-buffer indices)
GL15/GL_STATIC_DRAW)
{:vao vao :vbo vbo :ibo ibo}))Now we use the function to setup the VAO, VBO, and IBO.
(def vao (setup-vao vertices indices))The data of each vertex is defined by 3 floats (x, y, z). We need to specify the layout of the vertex buffer object so that OpenGL knows how to interpret it.
(do
(GL20/glVertexAttribPointer (GL20/glGetAttribLocation program "point") 3
GL11/GL_FLOAT false (* 3 Float/BYTES) (* 0 Float/BYTES))
(GL20/glEnableVertexAttribArray 0))Rendering the quad
We select the program and define the uniform variable iResolution.
(do
(GL20/glUseProgram program)
(GL20/glUniform2f (GL20/glGetUniformLocation program "iResolution")
window-width window-height))Since the correct VAO is already bound from the earlier example, we are now ready to draw the quad.
(GL11/glDrawElements GL11/GL_QUADS (count indices) GL11/GL_UNSIGNED_INT 0)(screenshot)
This time the quad shows a color ramp!
Finishing up
We only delete the program since we are going to reuse the VAO in the next example.
(GL20/glDeleteProgram program)Rendering a Texture
Getting the NASA data
We define a function to download a file from the web.
(defn download [url target]
(with-open [in (io/input-stream url)
out (io/output-stream target)]
(io/copy in out)))If it does not exist, we download the lunar color map from the NASA CGI Moon Kit.
(do
(def moon-tif "src/opengl_visualization/lroc_color_poles_2k.tif")
(when (not (.exists (io/file moon-tif)))
(download
"https://svs.gsfc.nasa.gov/vis/a000000/a004700/a004720/lroc_color_poles_2k.tif"
moon-tif)))Create a texture
Next we load the image using ImageIO.
(do
(def color (ImageIO/read (io/file moon-tif)))
(def color-raster (.getRaster color))
(def color-width (.getWidth color-raster))
(def color-height (.getHeight color-raster))
(def color-channels (.getNumBands color-raster))
(def color-pixels (int-array (* color-width color-height color-channels)))
(.getPixels color-raster 0 0 color-width color-height color-pixels)
[color-width color-height color-channels])
; [2048 1024 3]Then we create an OpenGL texture from the RGB data.
(do
(def texture-color (GL11/glGenTextures))
(GL11/glBindTexture GL11/GL_TEXTURE_2D texture-color)
(GL11/glTexImage2D GL11/GL_TEXTURE_2D 0 GL11/GL_RGBA color-width color-height 0
GL11/GL_RGB GL11/GL_UNSIGNED_BYTE
(make-byte-buffer (byte-array (map unchecked-byte color-pixels))))
(GL11/glTexParameteri GL11/GL_TEXTURE_2D GL11/GL_TEXTURE_MIN_FILTER GL11/GL_LINEAR)
(GL11/glTexParameteri GL11/GL_TEXTURE_2D GL11/GL_TEXTURE_MAG_FILTER GL11/GL_LINEAR)
(GL11/glTexParameteri GL11/GL_TEXTURE_2D GL11/GL_TEXTURE_WRAP_S GL11/GL_REPEAT)
(GL11/glTexParameteri GL11/GL_TEXTURE_2D GL11/GL_TEXTURE_WRAP_T GL11/GL_REPEAT)
(GL11/glBindTexture GL11/GL_TEXTURE_2D 0))Rendering the texture
We are going to use the vertex pass through shader again.
(def vertex-tex "
#version 130
in vec3 point;
void main()
{
gl_Position = vec4(point, 1);
}")The fragment shader now uses the texture function to lookup color values from a texture.
(def fragment-tex "
#version 130
uniform vec2 iResolution;
uniform sampler2D moon;
out vec4 fragColor;
void main()
{
fragColor = texture(moon, gl_FragCoord.xy / iResolution.xy);
}")We compile and link the shaders to create a program.
(do
(def vertex-tex-shader (make-shader vertex-tex GL20/GL_VERTEX_SHADER))
(def fragment-tex-shader (make-shader fragment-tex GL20/GL_FRAGMENT_SHADER))
(def tex-program (make-program vertex-tex-shader fragment-tex-shader)))We need to set up the layout of the vertex data again.
(do
(GL20/glVertexAttribPointer (GL20/glGetAttribLocation tex-program "point") 3
GL11/GL_FLOAT false (* 3 Float/BYTES) (* 0 Float/BYTES))
(GL20/glEnableVertexAttribArray 0))We set the resolution and bind the texture to the texture slot number 0.
(do
(GL20/glUseProgram tex-program)
(GL20/glUniform2f (GL20/glGetUniformLocation tex-program "iResolution")
window-width window-height)
(GL20/glUniform1i (GL20/glGetUniformLocation tex-program "moon") 0)
(GL13/glActiveTexture GL13/GL_TEXTURE0)
(GL11/glBindTexture GL11/GL_TEXTURE_2D texture-color))The quad now is textured!
(do
(GL11/glDrawElements GL11/GL_QUADS (count indices) GL11/GL_UNSIGNED_INT 0)
(screenshot))
Finishing up
We create a convenience function to tear down the VAO, VBO, and IBO.
(defn teardown-vao [{:keys [vao vbo ibo]}]
(GL15/glBindBuffer GL15/GL_ELEMENT_ARRAY_BUFFER 0)
(GL15/glDeleteBuffers ibo)
(GL15/glBindBuffer GL15/GL_ARRAY_BUFFER 0)
(GL15/glDeleteBuffers vbo)
(GL30/glBindVertexArray 0)
(GL15/glDeleteBuffers vao))We tear down the quad.
(teardown-vao vao)We also delete the program.
(GL20/glDeleteProgram tex-program)Render a 3D cube
Create vertex data
If we want to render a cube, we need to define 8 vertices.
(def vertices-cube
(float-array [-1.0 -1.0 -1.0
1.0 -1.0 -1.0
1.0 1.0 -1.0
-1.0 1.0 -1.0
-1.0 -1.0 1.0
1.0 -1.0 1.0
1.0 1.0 1.0
-1.0 1.0 1.0]))The cube is made up of 6 quads, with 4 vertex indices per quad. So we require 6 * 4 = 24 indices.
(def indices-cube
(int-array [0 1 2 3
7 6 5 4
0 3 7 4
5 6 2 1
3 2 6 7
4 5 1 0]))Initialize vertex buffer array
We use the function from earlier to set up the VAO, VBO, and IBO.
(def vao-cube (setup-vao vertices-cube indices-cube))Shader program mapping texture onto cube
We first define a vertex shader, which takes cube coordinates, rotates, translates, and projects them.
(def vertex-moon "
#version 130
uniform float fov;
uniform float alpha;
uniform float beta;
uniform float distance;
uniform vec2 iResolution;
in vec3 point;
out vec3 vpoint;
void main()
{
// Rotate and translate vertex
mat3 rot_y = mat3(vec3(cos(alpha), 0, sin(alpha)),
vec3(0, 1, 0),
vec3(-sin(alpha), 0, cos(alpha)));
mat3 rot_x = mat3(vec3(1, 0, 0),
vec3(0, cos(beta), -sin(beta)),
vec3(0, sin(beta), cos(beta)));
vec3 p = rot_x * rot_y * point + vec3(0, 0, distance);
// Project vertex creating normalized device coordinates
float f = 1.0 / tan(fov / 2.0);
float aspect = iResolution.x / iResolution.y;
float proj_x = p.x / p.z * f;
float proj_y = p.y / p.z * f * aspect;
float proj_z = p.z / (2.0 * distance);
// Output to shader pipeline.
gl_Position = vec4(proj_x, proj_y, proj_z, 1);
vpoint = point;
}")The fragment shader maps the texture onto the cube.
(def fragment-moon "
#version 130
#define PI 3.1415926535897932384626433832795
uniform sampler2D moon;
in vec3 vpoint;
out vec4 fragColor;
vec2 lonlat(vec3 p)
{
float lon = atan(p.x, -p.z) / (2.0 * PI) + 0.5;
float lat = atan(p.y, length(p.xz)) / PI + 0.5;
return vec2(lon, lat);
}
vec3 color(vec2 lonlat)
{
return texture(moon, lonlat).rgb;
}
void main()
{
fragColor = vec4(color(lonlat(vpoint)).rgb, 1);
}")We compile and link the shaders.
(do
(def vertex-shader-moon (make-shader vertex-moon GL30/GL_VERTEX_SHADER))
(def fragment-shader-moon (make-shader fragment-moon GL30/GL_FRAGMENT_SHADER))
(def program-moon (make-program vertex-shader-moon fragment-shader-moon)))We need to set up the memory layout again.
(do
(GL20/glVertexAttribPointer (GL20/glGetAttribLocation program-moon "point") 3
GL11/GL_FLOAT false (* 3 Float/BYTES) (* 0 Float/BYTES))
(GL20/glEnableVertexAttribArray 0))Rendering the cube
This shader program requires setup of several uniforms and a texture.
(do
(GL20/glUseProgram program-moon)
(GL20/glUniform2f (GL20/glGetUniformLocation program-moon "iResolution")
window-width window-height)
(GL20/glUniform1f (GL20/glGetUniformLocation program-moon "fov") (to-radians 25.0))
(GL20/glUniform1f (GL20/glGetUniformLocation program-moon "alpha") (to-radians 30.0))
(GL20/glUniform1f (GL20/glGetUniformLocation program-moon "beta") (to-radians -20.0))
(GL20/glUniform1f (GL20/glGetUniformLocation program-moon "distance") 10.0)
(GL20/glUniform1i (GL20/glGetUniformLocation program-moon "moon") 0)
(GL13/glActiveTexture GL13/GL_TEXTURE0)
(GL11/glBindTexture GL11/GL_TEXTURE_2D texture-color))We enable back face culling to only render the front faces of the cube. Then we clear the window and render the cube.
(do
(GL11/glEnable GL11/GL_CULL_FACE)
(GL11/glCullFace GL11/GL_BACK)
(GL11/glClearColor 0.0 0.0 0.0 1.0)
(GL11/glClear GL11/GL_COLOR_BUFFER_BIT)
(GL11/glDrawElements GL11/GL_QUADS (count indices-cube) GL11/GL_UNSIGNED_INT 0)
(screenshot))
This looks interesting but it is not a good approximation of the moon.
Finishing up
To finish up we delete the vertex data for the cube.
(teardown-vao vao-cube)Approximating a sphere
Creating the vertex data
First we partition the vertex data and convert the triplets to 8 Fastmath vectors.
(def points
(map #(apply vec3 %)
(partition 3 vertices-cube)))points
; ([-1.0 -1.0 -1.0]
; [1.0 -1.0 -1.0]
; [1.0 1.0 -1.0]
; [-1.0 1.0 -1.0]
; [-1.0 -1.0 1.0]
; [1.0 -1.0 1.0]
; [1.0 1.0 1.0]
; [-1.0 1.0 1.0])Then we use the index array to get the coordinates of the first corner of each face resulting in 6 Fastmath vectors.
(def corners
(map (fn [[i _ _ _]] (nth points i))
(partition 4 indices-cube)))corners
; ([-1.0 -1.0 -1.0]
; [-1.0 1.0 1.0]
; [-1.0 -1.0 -1.0]
; [1.0 -1.0 1.0]
; [-1.0 1.0 -1.0]
; [-1.0 -1.0 1.0])We get the first spanning vector of each face by subtracting the second corner from the first.
(def u-vectors
(map (fn [[i j _ _]] (sub (nth points j) (nth points i)))
(partition 4 indices-cube)))u-vectors
; ([2.0 0.0 0.0]
; [2.0 0.0 0.0]
; [0.0 2.0 0.0]
; [0.0 2.0 0.0]
; [2.0 0.0 0.0]
; [2.0 0.0 0.0])We get the second spanning vector of each face by subtracting the fourth corner from the first.
(def v-vectors
(map (fn [[i _ _ l]] (sub (nth points l) (nth points i)))
(partition 4 indices-cube)))v-vectors
; ([0.0 2.0 0.0]
; [0.0 -2.0 0.0]
; [0.0 0.0 2.0]
; [0.0 0.0 -2.0]
; [0.0 0.0 2.0]
; [0.0 0.0 -2.0])We can now use vector math to subsample the faces and project the points onto a sphere by normalizing the vectors and multiplying with the moon radius.
(defn sphere-points [n c u v]
(for [j (range (inc n)) i (range (inc n))]
(mult (normalize (add c (add (mult u (/ i n)) (mult v (/ j n))))) radius)))Subdividing once results in 9 corners for a cube face.
(sphere-points 2 (nth corners 0) (nth u-vectors 0) (nth v-vectors 0))
; ([-1003.088357690056 -1003.088357690056 -1003.088357690056]
; [0.0 -1228.5273216335077 -1228.5273216335077]
; [1003.088357690056 -1003.088357690056 -1003.088357690056]
; [-1228.5273216335077 0.0 -1228.5273216335077]
; [0.0 0.0 -1737.4]
; [1228.5273216335077 0.0 -1228.5273216335077]
; [-1003.088357690056 1003.088357690056 -1003.088357690056]
; [0.0 1228.5273216335077 -1228.5273216335077]
; [1003.088357690056 1003.088357690056 -1003.088357690056])We also need a function to generate the indices for the quads.
(defn sphere-indices [n face]
(for [j (range n) i (range n)]
(let [offset (+ (* face (inc n) (inc n)) (* j (inc n)) i)]
[offset (inc offset) (+ offset n 2) (+ offset n 1)])))Subdividing once results in 4 quads for a cube face.
(sphere-indices 2 0)
; ([0 1 4 3] [1 2 5 4] [3 4 7 6] [4 5 8 7])Rendering a coarse approximation of the sphere.
We subdivide once (n=2) and create a VAO with the data.
(do
(def n 2)
(def vertices-sphere (float-array (flatten (map (partial sphere-points n)
corners u-vectors v-vectors))))
(def indices-sphere (int-array (flatten (map (partial sphere-indices n) (range 6)))))
(def vao-sphere (setup-vao vertices-sphere indices-sphere)))The layout needs to be configured again.
(do
(GL20/glVertexAttribPointer (GL20/glGetAttribLocation program-moon "point") 3
GL11/GL_FLOAT false (* 3 Float/BYTES) (* 0 Float/BYTES))
(GL20/glEnableVertexAttribArray 0))The distance needs to be increased, because the points are on a sphere with the radius of the moon.
(GL20/glUniform1f (GL20/glGetUniformLocation program-moon "distance") (* radius 10.0))Rendering the mesh now results in a better approximation of a sphere.
(do
(GL11/glClear GL11/GL_COLOR_BUFFER_BIT)
(GL11/glDrawElements GL11/GL_QUADS (count indices-sphere) GL11/GL_UNSIGNED_INT 0)
(screenshot))
(teardown-vao vao-sphere)Rendering a fine approximation of the sphere.
To get a high quality approximation we subdivide more and create a VAO with the data. (do
(do
(def n2 16)
(def vertices-sphere-high (float-array (flatten (map (partial sphere-points n2) corners u-vectors v-vectors))))
(def indices-sphere-high (int-array (flatten (map (partial sphere-indices n2) (range 6)))))
(def vao-sphere-high (setup-vao vertices-sphere-high indices-sphere-high)))We set up the vertex layout again.
(do
(GL20/glVertexAttribPointer (GL20/glGetAttribLocation program-moon "point") 3
GL11/GL_FLOAT false (* 3 Float/BYTES) (* 0 Float/BYTES))
(GL20/glEnableVertexAttribArray 0))Rendering the mesh now results in a spherical mesh with a texture.
(do
(GL11/glClear GL11/GL_COLOR_BUFFER_BIT)
(GL11/glDrawElements GL11/GL_QUADS (count indices-sphere-high) GL11/GL_UNSIGNED_INT 0)
(screenshot))
(GL20/glDeleteProgram program-moon)Adding ambient and diffuse reflection
In order to introduce lighting we add ambient and diffuse lighting to the fragment shader. We use the ambient and diffuse lighting from the Phong shading model.
- The ambient light is a constant value.
- The diffuse light is calculated using the dot product of the light vector and the normal vector.
(def fragment-moon-diffuse "
#version 130
#define PI 3.1415926535897932384626433832795
uniform vec3 light;
uniform float ambient;
uniform float diffuse;
uniform sampler2D moon;
in vec3 vpoint;
out vec4 fragColor;
vec2 lonlat(vec3 p)
{
float lon = atan(p.x, -p.z) / (2.0 * PI) + 0.5;
float lat = atan(p.y, length(p.xz)) / PI + 0.5;
return vec2(lon, lat);
}
vec3 color(vec2 lonlat)
{
return texture(moon, lonlat).rgb;
}
void main()
{
float phong = ambient + diffuse * max(0.0, dot(light, normalize(vpoint)));
fragColor = vec4(color(lonlat(vpoint)) * phong, 1);
}")We reuse the vertex shader from the previous example and the new fragment shader.
(do
(def vertex-shader-diffuse (make-shader vertex-moon GL30/GL_VERTEX_SHADER))
(def fragment-shader-diffuse (make-shader fragment-moon-diffuse GL30/GL_FRAGMENT_SHADER))
(def program-diffuse (make-program vertex-shader-diffuse fragment-shader-diffuse)))We set up the vertex data layout again.
(do
(GL20/glVertexAttribPointer (GL20/glGetAttribLocation program-diffuse "point") 3
GL11/GL_FLOAT false (* 3 Float/BYTES) (* 0 Float/BYTES))
(GL20/glEnableVertexAttribArray 0))A normalized light vector is defined.
(def light (normalize (vec3 -1 0 -1)))Before rendering we need to set up the various uniform values.
(do
(GL20/glUseProgram program-diffuse)
(GL20/glUniform2f (GL20/glGetUniformLocation program-diffuse "iResolution")
window-width window-height)
(GL20/glUniform1f (GL20/glGetUniformLocation program-diffuse "fov") (to-radians 20.0))
(GL20/glUniform1f (GL20/glGetUniformLocation program-diffuse "alpha") (to-radians 0.0))
(GL20/glUniform1f (GL20/glGetUniformLocation program-diffuse "beta") (to-radians 0.0))
(GL20/glUniform1f (GL20/glGetUniformLocation program-diffuse "distance") (* radius 10.0))
(GL20/glUniform1f (GL20/glGetUniformLocation program-diffuse "ambient") 0.0)
(GL20/glUniform1f (GL20/glGetUniformLocation program-diffuse "diffuse") 1.6)
(GL20/glUniform3f (GL20/glGetUniformLocation program-diffuse "light")
(light 0) (light 1) (light 2))
(GL20/glUniform1i (GL20/glGetUniformLocation program-diffuse "moon") 0)
(GL13/glActiveTexture GL13/GL_TEXTURE0)
(GL11/glBindTexture GL11/GL_TEXTURE_2D texture-color))Finally we are ready to render the mesh with diffuse shading.
(do
(GL11/glClear GL11/GL_COLOR_BUFFER_BIT)
(GL11/glDrawElements GL11/GL_QUADS (count indices-sphere-high) GL11/GL_UNSIGNED_INT 0)
(screenshot))
Afterwards we delete the shader program.
(GL20/glDeleteProgram program-diffuse)Using normal mapping
Load elevation data into texture
In the final section we also want to add normal mapping in order to get realistic shading of craters.
The lunar elevation data is downloaded from NASA’s website.
(do
(def moon-ldem "src/opengl_visualization/ldem_4.tif")
(when (not (.exists (io/file moon-ldem)))
(download "https://svs.gsfc.nasa.gov/vis/a000000/a004700/a004720/ldem_4.tif"
moon-ldem)))The image is read using ImageIO and the floating point elevation data is extracted.
(do
(def ldem (ImageIO/read (io/file moon-ldem)))
(def ldem-raster (.getRaster ldem))
(def ldem-width (.getWidth ldem))
(def ldem-height (.getHeight ldem))
(def ldem-pixels (float-array (* ldem-width ldem-height)))
(do (.getPixels ldem-raster 0 0 ldem-width ldem-height ldem-pixels) nil)
(def resolution (/ (* 2.0 PI radius) ldem-width))
[ldem-width ldem-height])
; [1440 720]The floating point pixel data is converted into a texture
(do
(def texture-ldem (GL11/glGenTextures))
(GL11/glBindTexture GL11/GL_TEXTURE_2D texture-ldem)
(GL11/glTexParameteri GL11/GL_TEXTURE_2D GL11/GL_TEXTURE_MIN_FILTER GL11/GL_LINEAR)
(GL11/glTexParameteri GL11/GL_TEXTURE_2D GL11/GL_TEXTURE_MAG_FILTER GL11/GL_LINEAR)
(GL11/glTexParameteri GL11/GL_TEXTURE_2D GL11/GL_TEXTURE_WRAP_S GL11/GL_REPEAT)
(GL11/glTexParameteri GL11/GL_TEXTURE_2D GL11/GL_TEXTURE_WRAP_T GL11/GL_REPEAT)
(GL11/glTexImage2D GL11/GL_TEXTURE_2D 0 GL30/GL_R32F ldem-width ldem-height 0
GL11/GL_RED GL11/GL_FLOAT ldem-pixels))Create shader program with normal mapping
We reuse the vertex shader from the previous section.
The fragment shader this time is more involved.
- A horizon matrix with normal, tangent, and bitangent vectors is computed.
- The elevation is sampled in four directions from the current 3D point.
- The elevation values are used to create two surface vectors.
- The cross product of the surface vectors is computed and normalized to get the normal vector.
- This perturbed normal vector is now used to compute diffuse lighting.
(def fragment-normal "
#version 130
#define PI 3.1415926535897932384626433832795
uniform vec3 light;
uniform float ambient;
uniform float diffuse;
uniform float resolution;
uniform sampler2D moon;
uniform sampler2D ldem;
in vec3 vpoint;
in mat3 horizon;
out vec4 fragColor;
vec3 orthogonal_vector(vec3 n)
{
vec3 b;
if (abs(n.x) <= abs(n.y)) {
if (abs(n.x) <= abs(n.z))
b = vec3(1, 0, 0);
else
b = vec3(0, 0, 1);
} else {
if (abs(n.y) <= abs(n.z))
b = vec3(0, 1, 0);
else
b = vec3(0, 0, 1);
};
return normalize(cross(n, b));
}
mat3 oriented_matrix(vec3 n)
{
vec3 o1 = orthogonal_vector(n);
vec3 o2 = cross(n, o1);
return mat3(n, o1, o2);
}
vec2 lonlat(vec3 p)
{
float lon = atan(p.x, -p.z) / (2.0 * PI) + 0.5;
float lat = atan(p.y, length(p.xz)) / PI + 0.5;
return vec2(lon, lat);
}
vec3 color(vec2 lonlat)
{
return texture(moon, lonlat).rgb;
}
float elevation(vec3 p)
{
return texture(ldem, lonlat(p)).r;
}
vec3 normal(mat3 horizon, vec3 p)
{
vec3 pl = p + horizon * vec3(0, -1, 0) * resolution;
vec3 pr = p + horizon * vec3(0, 1, 0) * resolution;
vec3 pu = p + horizon * vec3(0, 0, -1) * resolution;
vec3 pd = p + horizon * vec3(0, 0, 1) * resolution;
vec3 u = horizon * vec3(elevation(pr) - elevation(pl), 2 * resolution, 0);
vec3 v = horizon * vec3(elevation(pd) - elevation(pu), 0, 2 * resolution);
return normalize(cross(u, v));
}
void main()
{
mat3 horizon = oriented_matrix(normalize(vpoint));
float phong = ambient + diffuse * max(0.0, dot(light, normal(horizon, vpoint)));
fragColor = vec4(color(lonlat(vpoint)).rgb * phong, 1);
}")We reuse the vertex shader from the previous example and the new fragment shader.
(do
(def vertex-shader-normal (make-shader vertex-moon GL30/GL_VERTEX_SHADER))
(def fragment-shader-normal (make-shader fragment-normal GL30/GL_FRAGMENT_SHADER))
(def program-normal (make-program vertex-shader-normal fragment-shader-normal)))We set up the vertex data layout again.
(do
(GL20/glVertexAttribPointer (GL20/glGetAttribLocation program-normal "point") 3
GL11/GL_FLOAT false (* 3 Float/BYTES) (* 0 Float/BYTES))
(GL20/glEnableVertexAttribArray 0))Apart from the uniform values we also need to set up two textures this time: the color texture and the elevation texture.
(do
(GL20/glUseProgram program-normal)
(GL20/glUniform2f (GL20/glGetUniformLocation program-normal "iResolution")
window-width window-height)
(GL20/glUniform1f (GL20/glGetUniformLocation program-normal "fov") (to-radians 20.0))
(GL20/glUniform1f (GL20/glGetUniformLocation program-normal "alpha") (to-radians 0.0))
(GL20/glUniform1f (GL20/glGetUniformLocation program-normal "beta") (to-radians 0.0))
(GL20/glUniform1f (GL20/glGetUniformLocation program-normal "distance") (* radius 10.0))
(GL20/glUniform1f (GL20/glGetUniformLocation program-normal "resolution") resolution)
(GL20/glUniform1f (GL20/glGetUniformLocation program-normal "ambient") 0.0)
(GL20/glUniform1f (GL20/glGetUniformLocation program-normal "diffuse") 1.6)
(GL20/glUniform3f (GL20/glGetUniformLocation program-normal "light")
(light 0) (light 1) (light 2))
(GL20/glUniform1i (GL20/glGetUniformLocation program-normal "moon") 0)
(GL20/glUniform1i (GL20/glGetUniformLocation program-normal "ldem") 1)
(GL13/glActiveTexture GL13/GL_TEXTURE0)
(GL11/glBindTexture GL11/GL_TEXTURE_2D texture-color)
(GL13/glActiveTexture GL13/GL_TEXTURE1)
(GL11/glBindTexture GL11/GL_TEXTURE_2D texture-ldem))Finally we are ready to render the mesh with normal mapping.
(do
(GL11/glClear GL11/GL_COLOR_BUFFER_BIT)
(GL11/glDrawElements GL11/GL_QUADS (count indices-sphere-high) GL11/GL_UNSIGNED_INT 0)
(screenshot))
Afterwards we delete the shader program and the vertex data.
(GL20/glDeleteProgram program-normal)(teardown-vao vao-sphere-high)And the textures.
(GL11/glDeleteTextures texture-color)(GL11/glDeleteTextures texture-ldem)Finalizing GLFW
When we are finished, we destroy the window.
(GLFW/glfwDestroyWindow window)Finally we terminate use of the GLFW library.
(GLFW/glfwTerminate)I hope you liked this 3D graphics example.
Note that in practise you will
- use higher resolution data and map the data onto texture tiles
- generate textures containing normal maps offline
- create a multiresolution map
- use tessellation to increase the mesh resolution
- use elevation data to deform the mesh
Thanks to Timothy Pratley for helping getting this post online.
