// Makes the common shared vertex shader
static VertexShader make_vs(void)
{
VertexShader shader;
shader.Source(
"#version 140\n"
"uniform mat4 ProjectionMatrix, CameraMatrix, ModelMatrix;"
"in vec4 Position;"
"in vec3 Normal;"
"in vec2 TexCoord;"
"out vec2 vertTexCoord;"
"out vec3 vertNormal;"
"out vec3 vertLight;"
"uniform vec3 LightPos;"
"void main(void)"
"{"
" vertTexCoord = TexCoord;"
" gl_Position = ModelMatrix * Position;"
" vertNormal = mat3(ModelMatrix)*Normal;"
" vertLight = LightPos - gl_Position.xyz;"
" gl_Position = ProjectionMatrix * CameraMatrix * gl_Position;"
"}"
);
shader.Compile();
return shader;
}
static Program make_prog(void)
{
VertexShader vs;
vs.Source(
"#version 130\n"
"uniform mat4 ProjectionMatrix, ModelMatrix, CameraMatrix;"
"uniform vec4 ClipPlane;"
"attribute vec4 Position;"
"attribute vec2 TexCoord;"
"varying vec2 vertTexCoord;"
"void main(void)"
"{"
" vertTexCoord = TexCoord;"
" gl_Position = "
" ModelMatrix *"
" Position;"
" gl_ClipDistance[0] = dot(ClipPlane, gl_Position);"
" gl_Position = "
" ProjectionMatrix *"
" CameraMatrix *"
" gl_Position;"
"}"
);
vs.Compile();
FragmentShader fs;
fs.Source(
"#version 130\n"
"varying vec2 vertTexCoord;"
"void main(void)"
"{"
" float i = ("
" int(vertTexCoord.x*36) % 2+"
" int(vertTexCoord.y*24) % 2"
" ) % 2;"
" if(gl_FrontFacing)"
" {"
" gl_FragColor = vec4(1-i/2, 1-i/2, 1-i/2, 1.0);"
" }"
" else"
" {"
" gl_FragColor = vec4(0+i/2, 0+i/2, 0+i/2, 1.0);"
" }"
"}"
);
fs.Compile();
Program prog;
prog.AttachShader(vs);
prog.AttachShader(fs);
prog.Link();
prog.Use();
return prog;
}
//==============================================================================
VertexShader * CGraphicsMgr::LoadVertexShader (
const std::wstring & name,
const std::wstring & filepath,
const std::string & entryFunction,
const D3D11_INPUT_ELEMENT_DESC * inputDesc,
unsigned inputElementCount
) {
VertexShader * shader = FindVertexShaderRaii(name);
if (!shader->Compile(name, filepath, entryFunction, inputDesc, inputElementCount))
return nullptr;
return shader;
}
static Program make_prog(void)
{
VertexShader vs;
vs.Source(
"#version 330\n"
"in vec4 Position;"
"in vec3 Normal;"
"out vec3 vertColor;"
"out vec3 vertNormal;"
"out vec3 vertLight;"
"uniform mat4 ProjectionMatrix, CameraMatrix, ModelMatrix;"
"uniform vec3 LightPos;"
"void main(void)"
"{"
" gl_Position = ModelMatrix * Position;"
" vertColor = abs(normalize(Normal+vec3(1, 1, 1)));"
" vertNormal = mat3(ModelMatrix)*Normal;"
" vertLight = LightPos - gl_Position.xyz;"
" gl_Position = ProjectionMatrix * CameraMatrix * gl_Position;"
"}"
);
vs.Compile();
FragmentShader fs;
fs.Source(
"#version 330\n"
"in vec3 vertColor;"
"in vec3 vertNormal;"
"in vec3 vertLight;"
"out vec4 fragColor;"
"void main(void)"
"{"
" float l = dot(vertLight, vertLight);"
" float d = l > 0.0 ? dot(vertNormal, normalize(vertLight)) / l : 0.0;"
" float i = 0.2 + max(d*3.2, 0.0);"
" fragColor = vec4(vertColor*i, 1.0);"
"}"
);
fs.Compile();
Program prog;
prog.AttachShader(vs);
prog.AttachShader(fs);
prog.Link();
return prog;
}
//-----------------------------------------------------------------------------------------------------------------------------------------------------
Ptr<GPUProgram> Context::CreateGPUProgram( LPCTSTR VertexShaderSource, LPCTSTR FragmentShaderSource )
{
VertexShader* pVertexShader = 0;
FragmentShader* pFragmentShader = 0;
if (VertexShaderSource)
{
pVertexShader = new VertexShader(this);
pVertexShader->Compile(VertexShaderSource);
}
if (FragmentShaderSource)
{
pFragmentShader = new FragmentShader(this);
pFragmentShader->Compile(FragmentShaderSource);
}
return CreateGPUProgram( pVertexShader, pFragmentShader );
}
bool ShaderLoader::Load(ShaderResource** resource, Handle handle, const std::string& filename1, const std::string& filename2)
{
*resource = new ShaderResource(handle, filename1);
Program* shader = new Program();
(*resource)->mRaw = shader;
VertexShader vs;
vs.Source(readFile(filename1));
vs.Compile();
FragmentShader fs;
fs.Source(readFile(filename2));
fs.Compile();
shader->AttachShader(vs).AttachShader(fs);
shader->BindAttribute(VertexAttributes::POSITION, "in_Position");
shader->BindAttribute(VertexAttributes::NORMAL, "in_Normal");
shader->BindAttribute(VertexAttributes::TANGENT, "in_Tangent");
shader->BindAttribute(VertexAttributes::TEXCOORD, "in_TexCoords");
shader->Link();
return true;
}
Program * ProgramFromShaderMap(const map<string, string> &mapShdString, const string &root) {
VertexShader vs;
FragmentShader fs;
Program *prog = new Program();
string defS("#version 420\n");
defS.append("#define MAX_BONES "); defS.append(ConvertIntString(G_MAX_BONES_UNIFORM)); defS.append("\n");
defS.append("#define MAX_BONES_INFL "); defS.append(ConvertIntString(G_MAX_BONES_INFLUENCING)); defS.append("\n");
string vsSrc(defS);
vsSrc.append(mapShdString.at(string("vs").append(root)));
string fsSrc(defS);
fsSrc.append(mapShdString.at(string("fs").append(root)));
vs.Source(vsSrc);
fs.Source(fsSrc);
vs.Compile();
fs.Compile();
prog->AttachShader(vs);
prog->AttachShader(fs);
prog->Link();
return prog;
}
GlassExample(void)
: make_plane(Vec3f(2.0f, 0.0f, 0.0f), Vec3f(0.0f, 0.0f, -2.0f))
, plane_instr(make_plane.Instructions())
, plane_indices(make_plane.Indices())
, make_shape()
, shape_instr(make_shape.Instructions())
, shape_indices(make_shape.Indices())
, plane_vs(ObjectDesc("Plane vertex"))
, shape_vs(ObjectDesc("Shape vertex"))
, plane_fs(ObjectDesc("Plane fragment"))
, shape_fs(ObjectDesc("Shape fragment"))
, plane_proj_matrix(plane_prog)
, plane_camera_matrix(plane_prog)
, plane_model_matrix(plane_prog)
, shape_proj_matrix(shape_prog)
, shape_camera_matrix(shape_prog)
, shape_model_matrix(shape_prog)
, shape_clip_plane(shape_prog)
, shape_clip_direction(shape_prog)
, width(512)
, height(512)
, tex_side(512)
{
plane_vs.Source(
"#version 140\n"
"uniform vec3 LightPosition;"
"uniform mat4 ProjectionMatrix, CameraMatrix, ModelMatrix;"
"in vec4 Position;"
"in vec2 TexCoord;"
"out vec3 vertLightDir;"
"out vec2 vertTexCoord;"
"void main(void)"
"{"
" gl_Position = "
" ModelMatrix* "
" Position;"
" vertLightDir = normalize("
" LightPosition - gl_Position.xyz"
" );"
" gl_Position = "
" ProjectionMatrix *"
" CameraMatrix *"
" gl_Position;"
" vertTexCoord = TexCoord;"
"}"
);
plane_vs.Compile();
plane_fs.Source(
"#version 140\n"
"uniform vec3 Normal;"
"in vec3 vertLightDir;"
"in vec2 vertTexCoord;"
"out vec4 fragColor;"
"void main(void)"
"{"
" float checker = ("
" int(vertTexCoord.x*18) % 2+"
" int(vertTexCoord.y*18) % 2"
" ) % 2;"
" vec3 color = mix("
" vec3(0.2, 0.4, 0.9),"
" vec3(0.2, 0.2, 0.7),"
" checker"
" );"
" float d = dot("
" Normal, "
" vertLightDir"
" );"
" float intensity = 0.5 + pow(1.4*d, 2.0);"
" fragColor = vec4(color*intensity, 1.0);"
"}"
);
plane_fs.Compile();
plane_prog.AttachShader(plane_vs);
plane_prog.AttachShader(plane_fs);
plane_prog.Link();
plane_prog.Use();
plane_proj_matrix.BindTo("ProjectionMatrix");
plane_camera_matrix.BindTo("CameraMatrix");
plane_model_matrix.BindTo("ModelMatrix");
Vec3f lightPos(3.0f, 3.0f, 3.0f);
Uniform<Vec3f>(plane_prog, "LightPosition").Set(lightPos);
Uniform<Vec3f>(plane_prog, "Normal").Set(make_plane.Normal());
gl.Bind(plane);
gl.Bind(Buffer::Target::Array, plane_verts);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_plane.Positions(data);
Buffer::Data(Buffer::Target::Array, data);
VertexArrayAttrib attr(plane_prog, "Position");
attr.Setup<GLfloat>(n_per_vertex);
attr.Enable();
}
gl.Bind(Buffer::Target::Array, plane_texcoords);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_plane.TexCoordinates(data);
Buffer::Data(Buffer::Target::Array, data);
VertexArrayAttrib attr(plane_prog, "TexCoord");
attr.Setup<GLfloat>(n_per_vertex);
attr.Enable();
}
shape_vs.Source(
"#version 140\n"
"uniform vec3 LightPosition;"
"uniform mat4 ProjectionMatrix, ModelMatrix, CameraMatrix;"
"uniform vec4 ClipPlane;"
"uniform float ClipDirection;"
"in vec4 Position;"
"in vec3 Normal;"
"out vec3 vertNormal;"
"out vec3 vertLightDir;"
"out vec3 vertLightRefl;"
"out vec3 vertViewDir;"
"out vec2 vertTexCoord;"
"void main(void)"
"{"
" gl_Position = "
" ModelMatrix *"
" Position;"
" gl_ClipDistance[0] = "
" ClipDirection* "
" dot(ClipPlane, gl_Position);"
" vertLightDir = LightPosition - gl_Position.xyz;"
" vertNormal = mat3(ModelMatrix)*Normal;"
" vertLightRefl = reflect("
" -normalize(vertLightDir),"
" normalize(vertNormal)"
" );"
" vertViewDir = (vec4(0.0, 0.0, 1.0, 1.0)*CameraMatrix).xyz;"
" gl_Position = ProjectionMatrix * CameraMatrix * gl_Position;"
" vec3 TexOffs = mat3(CameraMatrix)*vertNormal*0.05;"
" vertTexCoord = "
" vec2(0.5, 0.5) +"
" (gl_Position.xy/gl_Position.w)*0.5 +"
" (TexOffs.z<0.0 ? TexOffs.xy : -TexOffs.xy);"
"}"
);
shape_vs.Compile();
shape_fs.Source(
"#version 140\n"
"uniform sampler2D RefractTex;"
"in vec3 vertNormal;"
"in vec3 vertLightDir;"
"in vec3 vertLightRefl;"
"in vec3 vertViewDir;"
"in vec2 vertTexCoord;"
"out vec4 fragColor;"
"float adj_lt(float i)"
"{"
" return i > 0.0 ? i : -0.7*i;"
"}"
"void main(void)"
"{"
" float l = length(vertLightDir);"
" float d = dot("
" normalize(vertNormal), "
" normalize(vertLightDir)"
" ) / l;"
" float s = dot("
" normalize(vertLightRefl),"
" normalize(vertViewDir)"
" );"
" vec3 lt = vec3(1.0, 1.0, 1.0);"
" vec3 tex = texture(RefractTex, vertTexCoord).rgb;"
" fragColor = vec4("
" tex * 0.5 + "
" (lt + tex) * 1.5 * adj_lt(d) + "
" lt * pow(adj_lt(s), 64), "
" 1.0"
" );"
"}"
);
shape_fs.Compile();
shape_prog.AttachShader(shape_vs);
shape_prog.AttachShader(shape_fs);
shape_prog.Link();
shape_prog.Use();
shape_proj_matrix.BindTo("ProjectionMatrix");
shape_camera_matrix.BindTo("CameraMatrix");
shape_model_matrix.BindTo("ModelMatrix");
shape_clip_plane.BindTo("ClipPlane");
shape_clip_direction.BindTo("ClipDirection");
Uniform<Vec3f>(shape_prog, "LightPosition").Set(lightPos);
gl.Bind(shape);
gl.Bind(Buffer::Target::Array, shape_verts);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_shape.Positions(data);
Buffer::Data(Buffer::Target::Array, data);
VertexArrayAttrib attr(shape_prog, "Position");
attr.Setup<GLfloat>(n_per_vertex);
attr.Enable();
}
gl.Bind(Buffer::Target::Array, shape_normals);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_shape.Normals(data);
Buffer::Data(Buffer::Target::Array, data);
VertexArrayAttrib attr(shape_prog, "Normal");
attr.Setup<GLfloat>(n_per_vertex);
attr.Enable();
}
//
Texture::Active(0);
UniformSampler(shape_prog, "RefractTex").Set(0);
{
gl.Bound(Texture::Target::_2D, refract_tex)
.MinFilter(TextureMinFilter::Linear)
.MagFilter(TextureMagFilter::Linear)
.WrapS(TextureWrap::MirroredRepeat)
.WrapT(TextureWrap::MirroredRepeat)
.Image2D(
0,
PixelDataInternalFormat::RGB,
tex_side, tex_side,
0,
PixelDataFormat::RGB,
PixelDataType::UnsignedByte,
nullptr
);
}
//
gl.ClearColor(0.8f, 0.8f, 0.7f, 0.0f);
gl.ClearDepth(1.0f);
gl.Enable(Capability::DepthTest);
}
LandscapeExample(void)
: grid_side(128)
, make_plane(
Vec3f(0.0f, 0.0f, 0.0f),
Vec3f(9.0f, 0.0f, 0.0f),
Vec3f(0.0f, 0.0f,-9.0f),
grid_side*3, grid_side*3
), plane_instr(make_plane.Instructions())
, plane_indices(make_plane.Indices())
, light_pos(prog, "LightPos")
, projection_matrix(prog, "ProjectionMatrix")
, camera_matrix(prog, "CameraMatrix")
, light_path(
ListOf<Vec3f>
(Vec3f(-3.0f, 2.0f, -3.5f))
(Vec3f( 0.0f, 5.0f, 0.5f))
(Vec3f( 3.0f, 3.0f, 3.0f))
(Vec3f( 3.0f, 3.0f, -3.0f))
(Vec3f( 0.0f, 5.0f, 0.5f))
(Vec3f(-3.2f, 2.0f, 3.0f))
.Get()
)
{
VertexShader vs;
vs.Source(
"#version 330\n"
"uniform mat4 ProjectionMatrix, CameraMatrix;"
"uniform sampler2D TexUnit;"
"in vec4 Position;"
"in vec2 TexCoord;"
"out vec3 vertLight;"
"out vec3 vertNormal;"
"uniform vec3 LightPos;"
"void main(void)"
"{"
" gl_Position = Position;"
" float o = 0.0;"
" float s[9];"
" int k=0;"
" for(int y=-1; y!=2; ++y)"
" for(int x=-1; x!=2; ++x)"
" {"
" s[k] = sqrt(texture("
" TexUnit, "
" TexCoord*3.0+"
" vec2(x, y)/128.0"
" ).r);"
" o += s[k++];"
" }"
" gl_Position.y += o*0.5;"
" vec3 c = vec3( 0.0, s[4], 0.0);"
" float d = 1.0/32.0;"
" vertNormal = normalize("
" cross("
" vec3( 0.0, s[1], -d) - c,"
" vec3( -d, s[3], 0.0) - c"
" )+"
" cross("
" vec3( d, s[5], 0.0) - c,"
" vec3( 0.0, s[1], -d) - c"
" )+"
" cross("
" vec3( 0.0, s[7], d) - c,"
" vec3( d, s[5], 0.0) - c"
" )+"
" cross("
" vec3( -d, s[3], 0.0) - c,"
" vec3( 0.0, s[7], d) - c"
" )"
" );"
" vertLight = LightPos - gl_Position.xyz;"
" gl_Position = "
" ProjectionMatrix *"
" CameraMatrix *"
" gl_Position;"
"}"
);
vs.Compile();
FragmentShader fs;
fs.Source(
"#version 330\n"
"in vec3 vertNormal;"
"in vec3 vertLight;"
"out vec4 fragColor;"
"void main(void)"
"{"
" float l = length(vertLight);"
" float d = l > 0? dot("
" normalize(vertNormal), "
" normalize(vertLight)"
" ) / l : 0.0;"
" float i = 0.1 + 1.2*max(d, 0.0) + 4.2*pow(d, 2.0);"
" fragColor = vec4(i*0.7, i*0.7, i*0.3, 1.0);"
"}"
);
fs.Compile();
// attach the shaders to the program
prog.AttachShader(vs);
prog.AttachShader(fs);
// link and use it
prog.Link();
prog.Use();
// bind the VAO for the plane
plane.Bind();
// bind the VBO for the plane vertices
verts.Bind(Buffer::Target::Array);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_plane.Positions(data);
// upload the data
Buffer::Data(Buffer::Target::Array, data);
// setup the vertex attribs array for the vertices
VertexAttribArray attr(prog, "Position");
attr.Setup<GLfloat>(n_per_vertex);
attr.Enable();
}
// bind the VBO for the plane texture coordinates
texcoords.Bind(Buffer::Target::Array);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_plane.TexCoordinates(data);
// upload the data
Buffer::Data(Buffer::Target::Array, data);
// setup the vertex attribs array for the vertices
VertexAttribArray attr(prog, "TexCoord");
attr.Setup<GLfloat>(n_per_vertex);
attr.Enable();
}
// setup the texture
Texture::Target tex_tgt = Texture::Target::_2D;
tex.Bind(tex_tgt);
{
auto image = images::NewtonFractal(
grid_side, grid_side,
Vec3f(0.0f, 0.1f, 0.2f),
Vec3f(1.0f, 0.8f, 0.9f),
Vec2f(-1.0f, -1.0f),
Vec2f( 1.0f, 1.0f),
images::NewtonFractal::X3Minus1(),
images::NewtonFractal::DefaultMixer()
);
Texture::Image2D(tex_tgt, image);
Texture::MinFilter(tex_tgt, TextureMinFilter::Linear);
Texture::MagFilter(tex_tgt, TextureMagFilter::Linear);
Texture::WrapS(tex_tgt, TextureWrap::MirroredRepeat);
Texture::WrapT(tex_tgt, TextureWrap::MirroredRepeat);
}
//
UniformSampler(prog, "TexUnit").Set(0);
gl.ClearColor(0.8f, 0.8f, 0.7f, 0.0f);
gl.ClearDepth(1.0f);
gl.Enable(Capability::DepthTest);
gl.Enable(Capability::CullFace);
gl.FrontFace(make_plane.FaceWinding());
gl.CullFace(Face::Back);
}
ReflectionExample(void)
: torus_indices(make_torus.Indices())
, torus_instr(make_torus.Instructions())
, vs_norm(ObjectDesc("Vertex-Normal"))
, vs_refl(ObjectDesc("Vertex-Reflection"))
, gs_refl(ObjectDesc("Geometry-Reflection"))
{
namespace se = oglplus::smart_enums;
// Set the normal object vertex shader source
vs_norm.Source(
"#version 330\n"
"in vec4 Position;"
"in vec3 Normal;"
"out vec3 geomColor;"
"out vec3 geomNormal;"
"out vec3 geomLight;"
"uniform mat4 ProjectionMatrix, CameraMatrix, ModelMatrix;"
"uniform vec3 LightPos;"
"void main(void)"
"{"
" gl_Position = ModelMatrix * Position;"
" geomColor = Normal;"
" geomNormal = mat3(ModelMatrix)*Normal;"
" geomLight = LightPos-gl_Position.xyz;"
" gl_Position = ProjectionMatrix * CameraMatrix * gl_Position;"
"}"
);
// compile it
vs_norm.Compile();
// Set the reflected object vertex shader source
// which just passes data to the geometry shader
vs_refl.Source(
"#version 330\n"
"in vec4 Position;"
"in vec3 Normal;"
"out vec3 vertNormal;"
"void main(void)"
"{"
" gl_Position = Position;"
" vertNormal = Normal;"
"}"
);
// compile it
vs_refl.Compile();
// Set the reflected object geometry shader source
// This shader creates a reflection matrix that
// relies on the fact that the reflection is going
// to be done by the y-plane
gs_refl.Source(
"#version 330\n"
"layout(triangles) in;"
"layout(triangle_strip, max_vertices = 6) out;"
"in vec3 vertNormal[];"
"uniform mat4 ProjectionMatrix;"
"uniform mat4 CameraMatrix;"
"uniform mat4 ModelMatrix;"
"out vec3 geomColor;"
"out vec3 geomNormal;"
"out vec3 geomLight;"
"uniform vec3 LightPos;"
"mat4 ReflectionMatrix = mat4("
" 1.0, 0.0, 0.0, 0.0,"
" 0.0,-1.0, 0.0, 0.0,"
" 0.0, 0.0, 1.0, 0.0,"
" 0.0, 0.0, 0.0, 1.0 "
");"
"void main(void)"
"{"
" for(int v=0; v!=gl_in.length(); ++v)"
" {"
" vec4 Position = gl_in[v].gl_Position;"
" gl_Position = ModelMatrix * Position;"
" geomColor = vertNormal[v];"
" geomNormal = mat3(ModelMatrix)*vertNormal[v];"
" geomLight = LightPos - gl_Position.xyz;"
" gl_Position = "
" ProjectionMatrix *"
" CameraMatrix *"
" ReflectionMatrix *"
" gl_Position;"
" EmitVertex();"
" }"
" EndPrimitive();"
"}"
);
// compile it
gs_refl.Compile();
// set the fragment shader source
fs.Source(
"#version 330\n"
"in vec3 geomColor;"
"in vec3 geomNormal;"
"in vec3 geomLight;"
"out vec4 fragColor;"
"void main(void)"
"{"
" float l = length(geomLight);"
" float d = l > 0.0 ? dot("
" geomNormal, "
" normalize(geomLight)"
" ) / l : 0.0;"
" float i = 0.2 + max(d, 0.0) * 2.0;"
" fragColor = vec4(abs(geomNormal)*i, 1.0);"
"}"
);
// compile it
fs.Compile();
// attach the shaders to the normal rendering program
prog_norm.AttachShader(vs_norm);
prog_norm.AttachShader(fs);
// link it
prog_norm.Link();
// attach the shaders to the reflection rendering program
prog_refl.AttachShader(vs_refl);
prog_refl.AttachShader(gs_refl);
prog_refl.AttachShader(fs);
// link it
prog_refl.Link();
// bind the VAO for the torus
torus.Bind();
// bind the VBO for the torus vertices
torus_verts.Bind(se::Array());
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_torus.Positions(data);
// upload the data
Buffer::Data(se::Array(), data);
// setup the vertex attribs array for the vertices
typedef VertexAttribArray VAA;
VertexAttribSlot
loc_norm = VAA::GetLocation(prog_norm, "Position"),
loc_refl = VAA::GetLocation(prog_refl, "Position");
assert(loc_norm == loc_refl);
VertexAttribArray attr(loc_norm);
attr.Setup<GLfloat>(n_per_vertex);
attr.Enable();
}
// bind the VBO for the torus normals
torus_normals.Bind(se::Array());
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_torus.Normals(data);
// upload the data
Buffer::Data(se::Array(), data);
// setup the vertex attribs array for the normals
typedef VertexAttribArray VAA;
VertexAttribSlot
loc_norm = VAA::GetLocation(prog_norm, "Normal"),
loc_refl = VAA::GetLocation(prog_refl, "Normal");
assert(loc_norm == loc_refl);
VertexAttribArray attr(loc_norm);
attr.Setup<GLfloat>(n_per_vertex);
attr.Enable();
}
// bind the VAO for the plane
plane.Bind();
// bind the VBO for the plane vertices
plane_verts.Bind(se::Array());
{
GLfloat data[4*3] = {
-2.0f, 0.0f, 2.0f,
-2.0f, 0.0f, -2.0f,
2.0f, 0.0f, 2.0f,
2.0f, 0.0f, -2.0f
};
// upload the data
Buffer::Data(se::Array(), 4*3, data);
// setup the vertex attribs array for the vertices
prog_norm.Use();
VertexAttribArray attr(prog_norm, "Position");
attr.Setup<Vec3f>();
attr.Enable();
}
// bind the VBO for the torus normals
plane_normals.Bind(se::Array());
{
GLfloat data[4*3] = {
-0.1f, 1.0f, 0.1f,
-0.1f, 1.0f, -0.1f,
0.1f, 1.0f, 0.1f,
0.1f, 1.0f, -0.1f
};
// upload the data
Buffer::Data(se::Array(), 4*3, data);
// setup the vertex attribs array for the normals
prog_norm.Use();
VertexAttribArray attr(prog_norm, "Normal");
attr.Setup<Vec3f>();
attr.Enable();
}
VertexArray::Unbind();
Vec3f lightPos(2.0f, 2.0f, 3.0f);
prog_norm.Use();
SetUniform(prog_norm, "LightPos", lightPos);
prog_refl.Use();
SetUniform(prog_refl, "LightPos", lightPos);
//
gl.ClearColor(0.2f, 0.2f, 0.2f, 0.0f);
gl.ClearDepth(1.0f);
gl.ClearStencil(0);
}
LandscapeExample(void)
: grid_side(8)
, make_plane(
Vec3f(0.0f, 0.0f, 0.0f),
Vec3f(1.0f, 0.0f, 0.0f),
Vec3f(0.0f, 0.0f,-1.0f),
grid_side, grid_side
), plane_instr(make_plane.Instructions())
, plane_indices(make_plane.Indices())
, projection_matrix(prog, "ProjectionMatrix")
, camera_matrix(prog, "CameraMatrix")
, vc_int(prog, "vc_int")
, gc_int(prog, "gc_int")
, fc_int(prog, "fc_int")
{
VertexShader vs;
vs.Source(StrLit(
"#version 420\n"
"uniform mat4 ProjectionMatrix, CameraMatrix;"
"layout(binding = 0, offset = 0) uniform atomic_uint vc;"
"const float mult = 1.0/128.0;"
"uniform float vc_int;"
"in vec4 Position;"
"out vec3 vertColor;"
"void main(void)"
"{"
" gl_Position = "
" ProjectionMatrix *"
" CameraMatrix *"
" Position;"
" vertColor = vec3("
" fract(atomicCounterIncrement(vc)*mult),"
" 0.0,"
" 0.0 "
" )*max(vc_int, 0.0);"
"}"
));
vs.Compile();
prog.AttachShader(vs);
GeometryShader gs;
gs.Source(StrLit(
"#version 420\n"
"layout (triangles) in;"
"layout (triangle_strip, max_vertices = 3) out;"
"layout(binding = 0, offset = 4) uniform atomic_uint gc;"
"const float mult = 1.0/128.0;"
"uniform float gc_int;"
"in vec3 vertColor[3];"
"out vec3 geomColor;"
"void main(void)"
"{"
" vec3 Color = vec3("
" 0.0,"
" fract(atomicCounterIncrement(gc)*mult),"
" 0.0 "
" )*max(gc_int, 0.0);"
" for(int v=0; v!=3; ++v)"
" {"
" gl_Position = gl_in[v].gl_Position;"
" geomColor = vertColor[v] + Color;"
" EmitVertex();"
" }"
" EndPrimitive();"
"}"
));
gs.Compile();
prog.AttachShader(gs);
FragmentShader fs;
fs.Source(StrLit(
"#version 420\n"
"layout(binding = 0, offset = 8) uniform atomic_uint fc;"
"const float mult = 1.0/4096.0;"
"uniform float fc_int;"
"in vec3 geomColor;"
"out vec3 fragColor;"
"void main(void)"
"{"
" vec3 Color = vec3("
" 0.0,"
" 0.0,"
" sqrt(fract(atomicCounterIncrement(fc)*mult))"
" )*max(fc_int, 0.0);"
" fragColor = geomColor + Color;"
"}"
));
fs.Compile();
prog.AttachShader(fs);
prog.Link();
prog.Use();
// bind the VAO for the plane
plane.Bind();
// bind the VBO for the plane vertices
positions.Bind(Buffer::Target::Array);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_plane.Positions(data);
// upload the data
Buffer::Data(Buffer::Target::Array, data);
// setup the vertex attribs array for the vertices
VertexAttribArray attr(prog, "Position");
attr.Setup<GLfloat>(n_per_vertex);
attr.Enable();
}
counters.Bind(Buffer::Target::AtomicCounter);
{
const GLuint tmp[3] = {0u, 0u, 0u};
Buffer::Data(
Buffer::Target::AtomicCounter,
3, tmp,
BufferUsage::DynamicDraw
);
}
counters.BindBase(Buffer::IndexedTarget::AtomicCounter, 0);
gl.ClearColor(0.2f, 0.2f, 0.2f, 0.0f);
gl.ClearDepth(1.0f);
gl.Enable(Capability::DepthTest);
plane.Bind();
}
TessellationExample(void)
: shape_instr(make_shape.Instructions(PrimitiveType::Patches))
, shape_indices(make_shape.Indices())
, vs(ObjectDesc("Vertex"))
, cs(ObjectDesc("Tessellation Control"))
, es(ObjectDesc("Tessellation Evaluation"))
, gs(ObjectDesc("Geometry"))
, fs(ObjectDesc("Fragment"))
, projection_matrix(prog, "ProjectionMatrix")
, camera_matrix(prog, "CameraMatrix")
, model_matrix(prog, "ModelMatrix")
, offset(prog, "Offset")
, view_position(prog, "ViewPosition")
, viewport_dimensions(prog, "ViewportDimensions")
{
vs.Source(
"#version 330\n"
"uniform vec3 ViewPosition;"
"in vec3 Position;"
"out vec3 vertPosition;"
"out float vertDistance;"
"void main(void)"
"{"
" vertPosition = Position;"
" vertDistance = length(ViewPosition - vertPosition);"
"}"
);
vs.Compile();
cs.Source(
"#version 330\n"
"#extension ARB_tessellation_shader : enable\n"
"layout(vertices = 3) out;"
"in vec3 vertPosition[];"
"in float vertDistance[];"
"out vec3 tecoPosition[];"
"int tessLevel(float dist)"
"{"
" return int(9.0 / sqrt(dist+0.1));"
"}"
"void main(void)"
"{"
" tecoPosition[gl_InvocationID] ="
" vertPosition[gl_InvocationID];"
" if(gl_InvocationID == 0)"
" {"
" gl_TessLevelInner[0] = tessLevel(("
" vertDistance[0]+"
" vertDistance[1]+"
" vertDistance[2] "
" )*0.333);"
" gl_TessLevelOuter[0] = tessLevel(("
" vertDistance[1]+"
" vertDistance[2] "
" )*0.5);"
" gl_TessLevelOuter[1] = tessLevel(("
" vertDistance[2]+"
" vertDistance[0] "
" )*0.5);"
" gl_TessLevelOuter[2] = tessLevel(("
" vertDistance[0]+"
" vertDistance[1] "
" )*0.5);"
" }"
"}"
);
cs.Compile();
es.Source(
"#version 330\n"
"#extension ARB_tessellation_shader : enable\n"
"layout(triangles, equal_spacing, ccw) in;"
"const vec3 LightPosition = vec3(12.0, 10.0, 7.0);"
"uniform mat4 ProjectionMatrix, CameraMatrix, ModelMatrix;"
"in vec3 tecoPosition[];"
"out vec3 teevNormal;"
"out vec3 teevLightDir;"
"void main(void)"
"{"
" vec3 p0 = gl_TessCoord.x * tecoPosition[0];"
" vec3 p1 = gl_TessCoord.y * tecoPosition[1];"
" vec3 p2 = gl_TessCoord.z * tecoPosition[2];"
" vec4 tempPosition = vec4(normalize(p0+p1+p2), 0.0);"
" teevNormal = (ModelMatrix * tempPosition).xyz;"
" tempPosition.w = 1.0;"
" tempPosition = ModelMatrix * tempPosition;"
" teevLightDir = LightPosition - tempPosition.xyz;"
" gl_Position = "
" ProjectionMatrix *"
" CameraMatrix *"
" tempPosition;"
"}"
);
es.Compile();
gs.Source(
"#version 330\n"
"layout (triangles) in;"
"layout (triangle_strip, max_vertices = 3) out;"
"uniform vec3 Offset;"
"uniform vec2 ViewportDimensions;"
"in vec3 teevNormal[], teevLightDir[];"
"noperspective out vec3 geomDist;"
"flat out vec3 geomNormal;"
"out vec3 geomColor;"
"out vec3 geomLightDir;"
"void main(void)"
"{"
" geomNormal = normalize("
" teevNormal[0]+"
" teevNormal[1]+"
" teevNormal[2]"
" );"
" vec2 ScreenPos[3];"
" for(int i=0; i!=3; ++i)"
" {"
" ScreenPos[i] = "
" ViewportDimensions*"
" gl_in[i].gl_Position.xy/"
" gl_in[i].gl_Position.w;"
" }"
" vec2 TmpVect[3];"
" for(int i=0; i!=3; ++i)"
" {"
" TmpVect[i] = "
" ScreenPos[(i+2)%3]-"
" ScreenPos[(i+1)%3];"
" }"
" const vec3 EdgeMask[3] = vec3[3]("
" vec3(1.0, 0.0, 0.0),"
" vec3(0.0, 1.0, 0.0),"
" vec3(0.0, 0.0, 1.0) "
" );"
" for(int i=0; i!=3; ++i)"
" {"
" float Dist = abs("
" TmpVect[(i+1)%3].x*TmpVect[(i+2)%3].y-"
" TmpVect[(i+1)%3].y*TmpVect[(i+2)%3].x "
" ) / length(TmpVect[i]);"
" vec3 DistVect = vec3(Dist, Dist, Dist);"
" gl_Position = gl_in[i].gl_Position;"
" geomColor = normalize(abs("
" vec3(2.0, 2.0, 2.0)-"
" teevNormal[i]-"
" Offset"
" ));"
" geomLightDir = teevLightDir[i];"
" geomDist = EdgeMask[i] * DistVect;"
" EmitVertex();"
" }"
" EndPrimitive();"
"}"
);
gs.Compile();
fs.Source(
"#version 330\n"
"noperspective in vec3 geomDist;"
"flat in vec3 geomNormal;"
"in vec3 geomColor;"
"in vec3 geomLightDir;"
"out vec3 fragColor;"
"void main(void)"
"{"
" float MinDist = min(min(geomDist.x,geomDist.y),geomDist.z);"
" float EdgeAlpha = exp2(-pow(MinDist, 2.0));"
" const float Ambient = 0.8;"
" float Diffuse = max(dot("
" normalize(geomNormal),"
" normalize(geomLightDir)"
" ), 0.0);"
" vec3 FaceColor = geomColor * (Diffuse + Ambient);"
" const vec3 EdgeColor = vec3(0.0, 0.0, 0.0);"
" fragColor = mix(FaceColor, EdgeColor, EdgeAlpha);"
"}"
);
fs.Compile();
prog.AttachShader(vs);
prog.AttachShader(cs);
prog.AttachShader(es);
prog.AttachShader(gs);
prog.AttachShader(fs);
prog.Link();
prog.Use();
shape.Bind();
verts.Bind(Buffer::Target::Array);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_shape.Positions(data);
Buffer::Data(Buffer::Target::Array, data);
VertexAttribArray attr(prog, "Position");
attr.Setup<GLfloat>(n_per_vertex);
attr.Enable();
indices.Bind(Buffer::Target::ElementArray);
Buffer::Data(Buffer::Target::ElementArray, shape_indices);
shape_indices.clear();
}
//
gl.ClearColor(0.8f, 0.8f, 0.8f, 0.0f);
gl.ClearDepth(1.0f);
gl.Enable(Capability::DepthTest);
prog.Use();
}
ReflectionExample()
: make_plane(
Vec3f(), Vec3f(3.0f, 0.0f, 0.0f), Vec3f(0.0f, 0.0f, -3.0f), 15, 15)
, plane_instr(make_plane.Instructions())
, plane_indices(make_plane.Indices())
, make_shape()
, shape_instr(make_shape.Instructions())
, shape_indices(make_shape.Indices())
, plane_vs(ObjectDesc("Plane vertex"))
, shape_vs(ObjectDesc("Shape vertex"))
, plane_fs(ObjectDesc("Plane fragment"))
, shape_fs(ObjectDesc("Shape fragment"))
, plane_projection_matrix(plane_prog)
, plane_camera_matrix(plane_prog)
, plane_model_matrix(plane_prog)
, shape_projection_matrix(shape_prog)
, shape_camera_matrix(shape_prog)
, shape_model_matrix(shape_prog)
, width(800)
, height(600)
, tex_size_div(2) {
plane_vs.Source(
"#version 140\n"
"uniform vec3 LightPosition;"
"uniform mat4 ProjectionMatrix, CameraMatrix, ModelMatrix;"
"in vec4 Position;"
"out vec3 vertLightDir;"
"out vec4 vertTexCoord;"
"void main()"
"{"
" gl_Position = ModelMatrix*Position;"
" vertLightDir = LightPosition - gl_Position.xyz;"
" gl_Position = ProjectionMatrix * CameraMatrix * gl_Position;"
" vertTexCoord = gl_Position;"
"}");
plane_vs.Compile();
plane_fs.Source(
"#version 140\n"
"uniform sampler2DRect ReflectTex;"
"uniform vec3 Normal;"
"in vec3 vertLightDir;"
"in vec4 vertTexCoord;"
"out vec3 fragColor;"
"const int n = 5;"
"const int ns = (n*n);"
"const float blur = 0.15/n;"
"void main()"
"{"
" float d = dot(Normal, normalize(vertLightDir));"
" float intensity = 0.5 + pow(1.4*d, 2.0);"
" vec3 color = vec3(0.0, 0.0, 0.0);"
" int n = 2;"
" float pct = 0.5/vertTexCoord.w;"
" for(int y=-n; y!=(n+1); ++y)"
" for(int x=-n; x!=(n+1); ++x)"
" {"
" vec2 coord = vertTexCoord.xy;"
" coord += vec2(blur*x, blur*y);"
" coord *= pct;"
" coord += vec2(0.5, 0.5);"
" coord *= textureSize(ReflectTex);"
" color += texture(ReflectTex, coord).rgb/ns;"
" }"
" fragColor = color*intensity;"
"}");
plane_fs.Compile();
plane_prog.AttachShader(plane_vs);
plane_prog.AttachShader(plane_fs);
plane_prog.Link();
plane_prog.Use();
plane_projection_matrix.BindTo("ProjectionMatrix");
plane_camera_matrix.BindTo("CameraMatrix");
plane_model_matrix.BindTo("ModelMatrix");
Vec3f lightPos(3.0f, 0.5f, 2.0f);
Uniform<Vec3f>(plane_prog, "LightPosition").Set(lightPos);
Uniform<Vec3f>(plane_prog, "Normal").Set(make_plane.Normal());
plane.Bind();
plane_verts.Bind(Buffer::Target::Array);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_plane.Positions(data);
Buffer::Data(Buffer::Target::Array, data);
VertexArrayAttrib attr(plane_prog, "Position");
attr.Setup<GLfloat>(n_per_vertex);
attr.Enable();
}
//
Texture::Active(1);
gl.Bound(Texture::Target::Rectangle, depth_tex)
.MinFilter(TextureMinFilter::Linear)
.MagFilter(TextureMagFilter::Linear)
.WrapS(TextureWrap::ClampToEdge)
.WrapT(TextureWrap::ClampToEdge);
Texture::Active(0);
ProgramUniformSampler(plane_prog, "ReflectTex").Set(0);
gl.Bound(Texture::Target::Rectangle, reflect_tex)
.MinFilter(TextureMinFilter::Linear)
.MagFilter(TextureMagFilter::Linear)
.WrapS(TextureWrap::ClampToEdge)
.WrapT(TextureWrap::ClampToEdge);
gl.Bound(Framebuffer::Target::Draw, fbo)
.AttachTexture(FramebufferAttachment::Color, reflect_tex, 0)
.AttachTexture(FramebufferAttachment::Depth, depth_tex, 0);
shape_vs.Source(
"#version 140\n"
"uniform vec3 LightPosition;"
"uniform mat4 ProjectionMatrix, ModelMatrix, CameraMatrix;"
"in vec4 Position;"
"in vec3 Normal;"
"out vec3 vertNormal;"
"out vec3 vertLightDir;"
"out vec3 vertLightRefl;"
"out vec3 vertViewDir;"
"out vec3 vertColor;"
"void main()"
"{"
" gl_Position = ModelMatrix * Position;"
" vertLightDir = LightPosition - gl_Position.xyz;"
" vertNormal = mat3(ModelMatrix)*Normal;"
" vertLightRefl = reflect("
" -normalize(vertLightDir),"
" normalize(vertNormal)"
" );"
" vertViewDir = (vec4(0.0, 0.0, 1.0, 1.0)*CameraMatrix).xyz;"
" vertColor = vec3(1, 1, 1) - vertNormal;"
" gl_Position = ProjectionMatrix * CameraMatrix * gl_Position;"
"}");
shape_vs.Compile();
shape_fs.Source(
"#version 140\n"
"in vec3 vertNormal;"
"in vec3 vertLightDir;"
"in vec3 vertLightRefl;"
"in vec3 vertViewDir;"
"in vec3 vertColor;"
"out vec3 fragColor;"
"void main()"
"{"
" float l = length(vertLightDir);"
" float d = dot("
" normalize(vertNormal), "
" normalize(vertLightDir)"
" ) / l;"
" float s = dot("
" normalize(vertLightRefl),"
" normalize(vertViewDir)"
" );"
" vec3 lt = vec3(1.0, 1.0, 1.0);"
" fragColor = "
" vertColor * 0.4 + "
" (lt + vertColor)*pow(max(2.5*d, 0.0), 3) + "
" lt * pow(max(s, 0.0), 64);"
"}");
shape_fs.Compile();
shape_prog.AttachShader(shape_vs);
shape_prog.AttachShader(shape_fs);
shape_prog.Link();
shape_prog.Use();
shape_projection_matrix.BindTo("ProjectionMatrix");
shape_camera_matrix.BindTo("CameraMatrix");
shape_model_matrix.BindTo("ModelMatrix");
Uniform<Vec3f>(shape_prog, "LightPosition").Set(lightPos);
shape.Bind();
shape_verts.Bind(Buffer::Target::Array);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_shape.Positions(data);
Buffer::Data(Buffer::Target::Array, data);
VertexArrayAttrib attr(shape_prog, "Position");
attr.Setup<GLfloat>(n_per_vertex);
attr.Enable();
}
shape_normals.Bind(Buffer::Target::Array);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_shape.Normals(data);
Buffer::Data(Buffer::Target::Array, data);
VertexArrayAttrib attr(shape_prog, "Normal");
attr.Setup<GLfloat>(n_per_vertex);
attr.Enable();
}
//
gl.ClearColor(0.5f, 0.5f, 0.4f, 0.0f);
gl.ClearDepth(1.0f);
gl.Enable(Capability::DepthTest);
gl.Enable(Capability::CullFace);
}
MetaballExample(void)
{
for(GLuint i=0; i!=64; ++i)
{
GLuint j = 0, n = 3+std::rand()%3;
std::vector<Vec4f> points(n);
while(j != n)
{
points[j] = Vec4f(
1.4*std::rand()/GLdouble(RAND_MAX) - 0.7,
1.4*std::rand()/GLdouble(RAND_MAX) - 0.7,
0.0,
0.1*std::rand()/GLdouble(RAND_MAX) + 0.1
);
++j;
}
ball_paths.push_back(CubicBezierLoop<Vec4f, double>(points));
++i;
}
// Set the vertex shader source
vs.Source(StrLit(
"#version 330\n"
"in vec2 Position;"
"out vec3 vertPosition;"
"void main(void)"
"{"
" vertPosition = vec3(Position, 0.0);"
" gl_Position = vec4(vertPosition, 1.0);"
"}"
));
// compile it
vs.Compile();
// set the fragment shader source
fs.Source(StrLit(
"#version 330\n"
"uniform sampler1D Metaballs;"
"in vec3 vertPosition;"
"out vec3 fragColor;"
"const vec3 AmbientColor = vec3(0.3, 0.4, 0.9);"
"const vec3 DiffuseColor = vec3(0.5, 0.6, 1.0);"
"const vec3 LightDir = normalize(vec3(1.0, 1.0, 1.0));"
"void main(void)"
"{"
" int i = 0, n = textureSize(Metaballs, 0);"
" float InvN = 1.0/n;"
" float Value = 0.0;"
" vec3 Normal = vec3(0.0, 0.0, 0.0);"
" while(i != n)"
" {"
" vec4 Metaball = texelFetch(Metaballs, i, 0);"
" float Radius = Metaball.w;"
" vec3 Vect = vertPosition - Metaball.xyz;"
" float Tmp = pow(Radius,2.0)/dot(Vect, Vect)-0.25;"
" Value += Tmp;"
" float Mul = max(Tmp, 0.0);"
" Normal += Mul*vec3(Vect.xy, Mul*InvN/Radius);"
" ++i;"
" }"
" if(Value > 0.0)"
" {"
" float Diffuse = 1.4*max(dot("
" LightDir,"
" normalize(Normal)"
" ), 0.0);"
" float Ambient = 0.3;"
" fragColor = "
" Ambient*AmbientColor+"
" Diffuse*DiffuseColor;"
" }"
" else fragColor = vec3(0.4, 0.4, 0.4);"
"}"
));
// compile it
fs.Compile();
// attach the shaders to the program
prog << vs << fs;
// link and use it
prog.Link().Use();
// bind the VAO for the rectangle
rectangle.Bind();
GLfloat rectangle_verts[8] = {
-1.0f, -1.0f,
-1.0f, 1.0f,
1.0f, -1.0f,
1.0f, 1.0f
};
// bind the VBO for the rectangle vertices
verts.Bind(Buffer::Target::Array);
// upload the data
Buffer::Data(Buffer::Target::Array, rectangle_verts);
// setup the vertex attribs array for the vertices
VertexAttribArray vert_attr(prog, "Position");
vert_attr.Setup(2, DataType::Float).Enable();
//
Texture::Active(0);
UniformSampler(prog, "Metaballs").Set(0);
{
auto bound_tex = Bind(metaballs_tex, Texture::Target::_1D);
bound_tex.Image1D(
0,
PixelDataInternalFormat::RGBA32F,
ball_paths.size(),
0,
PixelDataFormat::RGBA,
PixelDataType::Float,
nullptr
);
bound_tex.MinFilter(TextureMinFilter::Nearest);
bound_tex.MagFilter(TextureMagFilter::Nearest);
bound_tex.WrapS(TextureWrap::MirroredRepeat);
}
gl.ClearDepth(1.0f);
}
FBTexExample(void)
: make_cube()
, cube_instr(make_cube.Instructions())
, cube_indices(make_cube.Indices())
, make_torus(1.0, 0.5, 72, 48)
, torus_instr(make_torus.Instructions())
, torus_indices(make_torus.Indices())
, cube_fs(ObjectDesc("Cube fragment"))
, torus_fs(ObjectDesc("Torus fragment"))
, torus_projection_matrix(torus_prog, "ProjectionMatrix")
, torus_camera_matrix(torus_prog, "CameraMatrix")
, torus_model_matrix(torus_prog, "ModelMatrix")
, cube_projection_matrix(cube_prog, "ProjectionMatrix")
, cube_camera_matrix(cube_prog, "CameraMatrix")
, cube_model_matrix(cube_prog, "ModelMatrix")
, tex_side(512)
, width(tex_side)
, height(tex_side)
{
vs.Source(
"#version 330\n"
"uniform mat4 ProjectionMatrix, CameraMatrix, ModelMatrix;"
"in vec4 Position;"
"in vec3 Normal;"
"in vec2 TexCoord;"
"out vec3 vertNormal;"
"out vec3 vertLight;"
"out vec2 vertTexCoord;"
"uniform vec3 LightPos;"
"void main(void)"
"{"
" vertNormal = mat3(ModelMatrix)*Normal;"
" gl_Position = ModelMatrix * Position;"
" vertLight = LightPos-gl_Position.xyz;"
" vertTexCoord = TexCoord;"
" gl_Position = ProjectionMatrix * CameraMatrix * gl_Position;"
"}"
);
vs.Compile();
cube_fs.Source(
"#version 330\n"
"uniform sampler2D TexUnit;"
"in vec3 vertNormal;"
"in vec3 vertLight;"
"in vec2 vertTexCoord;"
"out vec4 fragColor;"
"void main(void)"
"{"
" float l = sqrt(length(vertLight));"
" float d = l > 0? dot(vertNormal, normalize(vertLight)) / l : 0.0;"
" float i = 0.6 + max(d, 0.0);"
" fragColor = texture(TexUnit, vertTexCoord)*i;"
"}"
);
cube_fs.Compile();
cube_prog.AttachShader(vs);
cube_prog.AttachShader(cube_fs);
cube_prog.Link();
cube_prog.Use();
cube.Bind();
cube_verts.Bind(Buffer::Target::Array);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_cube.Positions(data);
Buffer::Data(Buffer::Target::Array, data);
VertexAttribArray attr(cube_prog, "Position");
attr.Setup<GLfloat>(n_per_vertex);
attr.Enable();
}
cube_normals.Bind(Buffer::Target::Array);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_cube.Normals(data);
Buffer::Data(Buffer::Target::Array, data);
VertexAttribArray attr(cube_prog, "Normal");
attr.Setup<GLfloat>(n_per_vertex);
attr.Enable();
}
cube_texcoords.Bind(Buffer::Target::Array);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_cube.TexCoordinates(data);
Buffer::Data(Buffer::Target::Array, data);
VertexAttribArray attr(cube_prog, "TexCoord");
attr.Setup<GLfloat>(n_per_vertex);
attr.Enable();
}
UniformSampler(cube_prog, "TexUnit").Set(0);
Uniform<Vec3f>(cube_prog, "LightPos").Set(4.0f, 4.0f, -8.0f);
torus_fs.Source(
"#version 330\n"
"in vec3 vertNormal;"
"in vec3 vertLight;"
"in vec2 vertTexCoord;"
"out vec4 fragColor;"
"void main(void)"
"{"
" float d = dot("
" vertNormal, "
" normalize(vertLight)"
" );"
" float i = ("
" int(vertTexCoord.x*18) % 2+"
" int(vertTexCoord.y*14) % 2"
" ) % 2;"
" float c = (0.4 + max(d, 0.0))*(1-i/2);"
" fragColor = vec4(c, c, c, 1.0);"
"}"
);
torus_fs.Compile();
torus_prog.AttachShader(vs);
torus_prog.AttachShader(torus_fs);
torus_prog.Link();
torus_prog.Use();
torus.Bind();
torus_verts.Bind(Buffer::Target::Array);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_torus.Positions(data);
Buffer::Data(Buffer::Target::Array, data);
VertexAttribArray attr(torus_prog, "Position");
attr.Setup<GLfloat>(n_per_vertex);
attr.Enable();
}
torus_normals.Bind(Buffer::Target::Array);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_torus.Normals(data);
Buffer::Data(Buffer::Target::Array, data);
VertexAttribArray attr(torus_prog, "Normal");
attr.Setup<GLfloat>(n_per_vertex);
attr.Enable();
}
torus_texcoords.Bind(Buffer::Target::Array);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_torus.TexCoordinates(data);
Buffer::Data(Buffer::Target::Array, data);
VertexAttribArray attr(torus_prog, "TexCoord");
attr.Setup<GLfloat>(n_per_vertex);
attr.Enable();
}
Uniform<Vec3f>(torus_prog, "LightPos").Set(2.0f, 3.0f, 4.0f);
{
auto bound_tex = Bind(tex, Texture::Target::_2D);
bound_tex.Image2D(
0,
PixelDataInternalFormat::RGBA,
tex_side, tex_side,
0,
PixelDataFormat::RGBA,
PixelDataType::UnsignedByte,
nullptr
);
bound_tex.MinFilter(TextureMinFilter::Linear);
bound_tex.MagFilter(TextureMagFilter::Linear);
bound_tex.WrapS(TextureWrap::Repeat);
bound_tex.WrapT(TextureWrap::Repeat);
}
{
auto bound_fbo = Bind(
fbo,
Framebuffer::Target::Draw
);
auto bound_rbo = Bind(
rbo,
Renderbuffer::Target::Renderbuffer
);
bound_rbo.Storage(
PixelDataInternalFormat::DepthComponent,
tex_side,
tex_side
);
bound_fbo.AttachTexture(
FramebufferAttachment::Color,
tex,
0
);
bound_fbo.AttachRenderbuffer(
FramebufferAttachment::Depth,
rbo
);
}
gl.Enable(Capability::DepthTest);
gl.Enable(Capability::CullFace);
gl.CullFace(Face::Back);
}
CubeMapExample(void)
: shape_instr(make_shape.Instructions())
, shape_indices(make_shape.Indices())
, projection_matrix(prog, "ProjectionMatrix")
, camera_matrix(prog, "CameraMatrix")
, model_matrix(prog, "ModelMatrix")
{
// Set the vertex shader source
vs.Source(
"#version 330\n"
"uniform mat4 ProjectionMatrix, CameraMatrix, ModelMatrix;"
"in vec4 Position;"
"in vec3 Normal;"
"in vec2 TexCoord;"
"out vec3 vertNormal;"
"out vec3 vertLightDir;"
"out vec3 vertLightRefl;"
"out vec3 vertViewDir;"
"out vec3 vertViewRefl;"
"uniform vec3 LightPos;"
"void main(void)"
"{"
" gl_Position = ModelMatrix * Position;"
" vertNormal = mat3(ModelMatrix)*Normal;"
" vertLightDir = LightPos - gl_Position.xyz;"
" vertLightRefl = reflect("
" -normalize(vertLightDir),"
" normalize(vertNormal)"
" );"
" vertViewDir = ("
" vec4(0.0, 0.0, 1.0, 1.0)*"
" CameraMatrix"
" ).xyz;"
" vertViewRefl = reflect("
" normalize(vertViewDir),"
" normalize(vertNormal)"
" );"
" gl_Position = ProjectionMatrix * CameraMatrix * gl_Position;"
"}"
);
// compile it
vs.Compile();
// set the fragment shader source
fs.Source(
"#version 330\n"
"uniform samplerCube TexUnit;"
"in vec3 vertNormal;"
"in vec3 vertLightDir;"
"in vec3 vertLightRefl;"
"in vec3 vertViewDir;"
"in vec3 vertViewRefl;"
"out vec4 fragColor;"
"void main(void)"
"{"
" float l = length(vertLightDir);"
" float d = dot("
" normalize(vertNormal), "
" normalize(vertLightDir)"
" ) / l;"
" float s = dot("
" normalize(vertLightRefl),"
" normalize(vertViewDir)"
" );"
" vec3 lt = vec3(1.0, 1.0, 1.0);"
" vec3 env = texture(TexUnit, vertViewRefl).rgb;"
" fragColor = vec4("
" env * 0.4 + "
" (lt + env) * 1.5 * max(d, 0.0) + "
" lt * pow(max(s, 0.0), 64), "
" 1.0"
" );"
"}"
);
// compile it
fs.Compile();
// attach the shaders to the program
prog.AttachShader(vs);
prog.AttachShader(fs);
// link and use it
prog.Link();
prog.Use();
// bind the VAO for the shape
shape.Bind();
verts.Bind(Buffer::Target::Array);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_shape.Positions(data);
Buffer::Data(Buffer::Target::Array, data);
VertexAttribArray attr(prog, "Position");
attr.Setup(n_per_vertex, DataType::Float);
attr.Enable();
}
normals.Bind(Buffer::Target::Array);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_shape.Normals(data);
Buffer::Data(Buffer::Target::Array, data);
VertexAttribArray attr(prog, "Normal");
attr.Setup(n_per_vertex, DataType::Float);
attr.Enable();
}
// setup the texture
{
GLuint tex_side = 256;
auto image = images::NewtonFractal(
tex_side, tex_side,
Vec3f(0.3f, 0.1f, 0.2f),
Vec3f(1.0f, 0.8f, 0.9f),
Vec2f(-1.0f, -1.0f),
Vec2f( 1.0f, 1.0f),
images::NewtonFractal::X4Minus1(),
images::NewtonFractal::DefaultMixer()
);
auto bound_tex = Bind(tex, Texture::Target::CubeMap);
bound_tex.MinFilter(TextureMinFilter::Linear);
bound_tex.MagFilter(TextureMagFilter::Linear);
bound_tex.WrapS(TextureWrap::ClampToEdge);
bound_tex.WrapT(TextureWrap::ClampToEdge);
bound_tex.WrapR(TextureWrap::ClampToEdge);
for(int i=0; i!=6; ++i)
Texture::Image2D(Texture::CubeMapFace(i), image);
}
// typechecked uniform with the exact sampler type
// on compilers supporting strongly typed enums
// you can use:
//Typechecked<Uniform<SLtoCpp<SLDataType::SamplerCube>>>(prog, "TexUnit").Set(0);
// without strongly typed enums you need to do:
typedef SLtoCpp<OGLPLUS_CONST_ENUM_VALUE(SLDataType::SamplerCube)> GLSLsamplerCube;
Typechecked<Uniform<GLSLsamplerCube>>(prog, "TexUnit").Set(0);
//
Uniform<Vec3f>(prog, "LightPos").Set(Vec3f(3.0f, 5.0f, 4.0f));
//
gl.ClearColor(0.2f, 0.05f, 0.1f, 0.0f);
gl.ClearDepth(1.0f);
gl.Enable(Capability::DepthTest);
gl.Enable(Capability::CullFace);
gl.FrontFace(make_shape.FaceWinding());
gl.CullFace(Face::Back);
}
BlenderMeshExample(int argc, const char* argv[])
: prog()
, camera_matrix(prog, "CameraMatrix")
, light_position(prog, "LightPosition")
, camera_position(prog, "CameraPosition")
, face_normals(prog, "FaceNormals")
, element_count(0)
{
using namespace oglplus;
VertexShader vs;
vs.Source(
"#version 330\n"
"uniform mat4 CameraMatrix, ProjectionMatrix;"
"uniform vec3 LightPosition, CameraPosition;"
"mat4 Matrix = ProjectionMatrix * CameraMatrix;"
"in vec3 Position;"
"in vec3 Normal;"
"out vec3 vertNormal;"
"out vec3 vertLightDir;"
"out vec3 vertViewDir;"
"void main(void)"
"{"
" vertNormal = Normal;"
" vertLightDir = LightPosition - Position;"
" vertViewDir = CameraPosition - Position;"
" gl_Position = Matrix * vec4(Position, 1.0);"
"}"
);
vs.Compile();
prog.AttachShader(vs);
GeometryShader gs;
gs.Source(
"#version 330\n"
"layout (triangles) in;"
"layout (triangle_strip, max_vertices=3) out;"
"uniform bool FaceNormals;"
"in vec3 vertNormal[3];"
"in vec3 vertLightDir[3];"
"in vec3 vertViewDir[3];"
"out vec3 geomNormal;"
"out vec3 geomLightDir;"
"out vec3 geomViewDir;"
"void main(void)"
"{"
" vec3 fn;"
" if(FaceNormals)"
" {"
" vec3 p0 = gl_in[0].gl_Position.xyz;"
" vec3 p1 = gl_in[1].gl_Position.xyz;"
" vec3 p2 = gl_in[2].gl_Position.xyz;"
" fn = normalize(cross(p1-p0, p2-p0));"
" }"
" for(int v=0; v!=3; ++v)"
" {"
" gl_Position = gl_in[v].gl_Position;"
" if(FaceNormals) geomNormal = fn;"
" else geomNormal = vertNormal[v];"
" geomLightDir = vertLightDir[v];"
" geomViewDir = vertViewDir[v];"
" EmitVertex();"
" }"
" EndPrimitive();"
"}"
);
gs.Compile();
prog.AttachShader(gs);
FragmentShader fs;
fs.Source(
"#version 330\n"
"in vec3 geomNormal;"
"in vec3 geomLightDir;"
"in vec3 geomViewDir;"
"out vec3 fragColor;"
"void main(void)"
"{"
" vec3 LightColor = vec3(1.0, 1.0, 1.0);"
" vec3 MatColor = vec3(0.5, 0.5, 0.5);"
" vec3 LightRefl = reflect(-geomLightDir, geomNormal);"
" float Ambient = 0.3;"
" float Diffuse = max(dot("
" normalize(geomNormal),"
" normalize(geomLightDir)"
" ), 0.0);"
" float Contour = pow((1.0 - max(dot("
" normalize(geomNormal),"
" normalize(geomViewDir)"
" )-0.1, 0.0))*1.05, 4.0);"
" float Specular = pow(clamp(dot("
" normalize(geomViewDir),"
" normalize(LightRefl)"
" )+0.005, 0.0, 0.98), 64.0);"
" fragColor = MatColor * LightColor * (Contour + Diffuse + Ambient)+"
" LightColor * Specular;"
"}"
);
fs.Compile();
prog.AttachShader(fs);
prog.Link();
prog.Use();
gl.PrimitiveRestartIndex(0);
// vectors with vertex position and normals
// the values at index 0 is unused
// 0 is used as primitive restart index
std::vector<GLfloat> pos_data(3, 0.0);
std::vector<GLfloat> nml_data(3, 0.0);
// index offset starting at 1
GLuint index_offset = 1;
// vectors with vertex indices
std::vector<GLuint> idx_data(1, 0);
// open an input stream
std::ifstream input(argc>1? argv[1]: "./test.blend");
// check if we succeeded
if(!input.good())
throw std::runtime_error("Error opening file for reading");
// parse the input stream
imports::BlendFile blend_file(input);
// get the file's global block
auto glob_block = blend_file.StructuredGlobalBlock();
// get the default scene
auto scene_data = blend_file[glob_block.curscene];
//
// get the pointer to the first object in the scene
auto object_link_ptr = scene_data.Field<void*>("base.first").Get();
// and go through the whole list of objects
while(object_link_ptr)
{
// for each list element open the linked list block
auto object_link_data = blend_file[object_link_ptr];
// get the pointer to its object
auto object_ptr = object_link_data.Field<void*>("object").Get();
// open the object block (if any)
if(object_ptr) try
{
auto object_data = blend_file[object_ptr];
// get the data pointer
auto object_data_ptr = object_data.Field<void*>("data").Get();
// open the data block (if any)
if(object_data_ptr)
{
auto object_data_data = blend_file[object_data_ptr];
// if it is a mesh
if(object_data_data.StructureName() == "Mesh")
{
// get the object matrix field
auto object_obmat_field = object_data.Field<float>("obmat");
// make a transformation matrix
Mat4f obmat(
object_obmat_field.Get(0, 0),
object_obmat_field.Get(0, 4),
object_obmat_field.Get(0, 8),
object_obmat_field.Get(0,12),
object_obmat_field.Get(0, 1),
object_obmat_field.Get(0, 5),
object_obmat_field.Get(0, 9),
object_obmat_field.Get(0,13),
object_obmat_field.Get(0, 2),
object_obmat_field.Get(0, 6),
object_obmat_field.Get(0,10),
object_obmat_field.Get(0,14),
object_obmat_field.Get(0, 3),
object_obmat_field.Get(0, 7),
object_obmat_field.Get(0,11),
object_obmat_field.Get(0,15)
);
// the number of vertices
std::size_t n_verts = 0;
// get the vertex block pointer
auto vertex_ptr = object_data_data.Field<void*>("mvert").Get();
// open the vertex block (if any)
if(vertex_ptr)
{
auto vertex_data = blend_file[vertex_ptr];
// get the number of vertices in the block
n_verts = vertex_data.BlockElementCount();
// get the vertex coordinate and normal fields
auto vertex_co_field = vertex_data.Field<float>("co");
auto vertex_no_field = vertex_data.Field<short>("no");
// make two vectors of position and normal data
std::vector<GLfloat> ps(3 * n_verts);
std::vector<GLfloat> ns(3 * n_verts);
for(std::size_t v=0; v!=n_verts; ++v)
{
// (transpose y and z axes)
// get the positional coordinates
Vec4f position(
vertex_co_field.Get(v, 0),
vertex_co_field.Get(v, 1),
vertex_co_field.Get(v, 2),
1.0f
);
Vec4f newpos = obmat * position;
ps[3*v+0] = newpos.x();
ps[3*v+1] = newpos.z();
ps[3*v+2] =-newpos.y();
// get the normals
Vec4f normal(
vertex_no_field.Get(v, 0),
vertex_no_field.Get(v, 1),
vertex_no_field.Get(v, 2),
0.0f
);
Vec4f newnorm = obmat * normal;
ns[3*v+0] = newnorm.x();
ns[3*v+1] = newnorm.z();
ns[3*v+2] =-newnorm.y();
}
// append the values
pos_data.insert(pos_data.end(), ps.begin(), ps.end());
nml_data.insert(nml_data.end(), ns.begin(), ns.end());
}
// get the face block pointer
auto face_ptr = object_data_data.Field<void*>("mface").Get();
// open the face block (if any)
if(face_ptr)
{
auto face_data = blend_file[face_ptr];
// get the number of faces in the block
std::size_t n_faces = face_data.BlockElementCount();
// get the vertex index fields of the face
auto face_v1_field = face_data.Field<int>("v1");
auto face_v2_field = face_data.Field<int>("v2");
auto face_v3_field = face_data.Field<int>("v3");
auto face_v4_field = face_data.Field<int>("v4");
// make a vector of index data
std::vector<GLuint> is(5 * n_faces);
for(std::size_t f=0; f!=n_faces; ++f)
{
// get face vertex indices
int v1 = face_v1_field.Get(f);
int v2 = face_v2_field.Get(f);
int v3 = face_v3_field.Get(f);
int v4 = face_v4_field.Get(f);
is[5*f+0] = v1+index_offset;
is[5*f+1] = v2+index_offset;
is[5*f+2] = v3+index_offset;
is[5*f+3] = v4?v4+index_offset:0;
is[5*f+4] = 0; // primitive restart index
}
// append the values
idx_data.insert(idx_data.end(), is.begin(), is.end());
}
// get the poly block pointer
auto poly_ptr = object_data_data.TryGet<void*>("mpoly", nullptr);
// and the loop block pointer
auto loop_ptr = object_data_data.TryGet<void*>("mloop", nullptr);
// open the poly and loop blocks (if we have both)
if(poly_ptr && loop_ptr)
{
auto poly_data = blend_file[poly_ptr];
auto loop_data = blend_file[loop_ptr];
// get the number of polys in the block
std::size_t n_polys = poly_data.BlockElementCount();
// get the fields of poly and loop
auto poly_loopstart_field = poly_data.Field<int>("loopstart");
auto poly_totloop_field = poly_data.Field<int>("totloop");
auto loop_v_field = loop_data.Field<int>("v");
// make a vector of index data
std::vector<GLuint> is;
for(std::size_t f=0; f!=n_polys; ++f)
{
int ls = poly_loopstart_field.Get(f);
int tl = poly_totloop_field.Get(f);
for(int l=0; l!=tl; ++l)
{
int v = loop_v_field.Get(ls+l);
is.push_back(v+index_offset);
}
is.push_back(0); // primitive restart index
}
// append the values
idx_data.insert(idx_data.end(), is.begin(), is.end());
}
index_offset += n_verts;
}
}
}
catch(...)
{ }
// and get the pointer to the nex block
object_link_ptr = object_link_data.Field<void*>("next").Get();
}
meshes.Bind();
positions.Bind(Buffer::Target::Array);
{
Buffer::Data(Buffer::Target::Array, pos_data);
VertexAttribArray attr(prog, "Position");
attr.Setup<GLfloat>(3);
attr.Enable();
}
normals.Bind(Buffer::Target::Array);
{
Buffer::Data(Buffer::Target::Array, nml_data);
VertexAttribArray attr(prog, "Normal");
attr.Setup<GLfloat>(3);
attr.Enable();
}
indices.Bind(Buffer::Target::ElementArray);
Buffer::Data(Buffer::Target::ElementArray, idx_data);
element_count = idx_data.size();
// find the extremes of the mesh(es)
GLfloat min_x = pos_data[3], max_x = pos_data[3];
GLfloat min_y = pos_data[4], max_y = pos_data[4];
GLfloat min_z = pos_data[5], max_z = pos_data[5];
for(std::size_t v=1, vn=pos_data.size()/3; v!=vn; ++v)
{
GLfloat x = pos_data[v*3+0];
GLfloat y = pos_data[v*3+1];
GLfloat z = pos_data[v*3+2];
if(min_x > x) min_x = x;
if(min_y > y) min_y = y;
if(min_z > z) min_z = z;
if(max_x < x) max_x = x;
if(max_y < y) max_y = y;
if(max_z < z) max_z = z;
}
// position the camera target
camera_target = Vec3f(
(min_x + max_x) * 0.5,
(min_y + max_y) * 0.5,
(min_z + max_z) * 0.5
);
// and calculate a good value for camera distance
camera_distance = 1.1*Distance(camera_target, Vec3f(min_x, min_y, min_z))+1.0;
gl.ClearColor(0.17f, 0.22f, 0.17f, 0.0f);
gl.ClearDepth(1.0f);
gl.Enable(Capability::DepthTest);
gl.Enable(Capability::PrimitiveRestart);
}
MultiViewportExample(void)
: make_shape(1.0, 0.1, 8, 4, 48)
, shape_instr(make_shape.Instructions())
, shape_indices(make_shape.Indices())
, camera_position_3(prog, "CameraPosition[3]")
, camera_matrix_0(prog, "CameraMatrix[0]")
, camera_matrix_1(prog, "CameraMatrix[1]")
, camera_matrix_2(prog, "CameraMatrix[2]")
, camera_matrix_3(prog, "CameraMatrix[3]")
, model_matrix(prog, "ModelMatrix")
{
VertexShader vs;
// Set the vertex shader source
vs.Source(
"#version 330\n"
"uniform mat4 ModelMatrix;"
"uniform vec3 LightPos;"
"in vec4 Position;"
"in vec3 Normal;"
"out vec3 vertNormal;"
"out vec3 vertTexCoord;"
"out vec3 vertLightDir;"
"out vec3 vertLightRefl;"
"void main(void)"
"{"
" vertNormal = mat3(ModelMatrix)*Normal;"
" vertTexCoord = Normal;"
" gl_Position = ModelMatrix * Position;"
" vertLightDir = LightPos-gl_Position.xyz;"
" vertLightRefl = reflect(-vertLightDir, vertNormal);"
"}"
);
vs.Compile();
GeometryShader gs;
// Set the geometry shader source
gs.Source(
"#version 330\n"
"#extension GL_ARB_viewport_array : enable\n"
"layout(triangles) in;"
"layout(triangle_strip, max_vertices = 12) out;"
"uniform mat4 CameraMatrix[4];"
"uniform vec3 CameraPosition[4];"
"in vec3 vertNormal[];"
"in vec3 vertTexCoord[];"
"in vec3 vertLightDir[];"
"in vec3 vertLightRefl[];"
"out vec3 geomNormal;"
"out vec3 geomTexCoord;"
"out vec3 geomLightDir;"
"out vec3 geomLightRefl;"
"out vec3 geomViewDir;"
"out vec3 geomViewRefl;"
"void main(void)"
"{"
" for(int vp=0; vp!=4; ++vp)"
" {"
" gl_ViewportIndex = vp;"
" for(int v=0; v!=3; ++v)"
" {"
" geomNormal = vertNormal[v];"
" geomTexCoord = vertTexCoord[v];"
" geomLightDir = vertLightDir[v];"
" geomLightRefl = vertLightRefl[v];"
" geomViewDir = "
" CameraPosition[vp] - "
" gl_in[v].gl_Position.xyz;"
" geomViewRefl = reflect("
" -geomViewDir,"
" geomNormal"
" );"
" gl_Position = "
" CameraMatrix[vp] *"
" gl_in[v].gl_Position;"
" EmitVertex();"
" }"
" EndPrimitive();"
" }"
"}"
);
gs.Compile();
FragmentShader fs;
// set the fragment shader source
fs.Source(
"#version 330\n"
"uniform samplerCube TexUnit;"
"in vec3 geomNormal;"
"in vec3 geomTexCoord;"
"in vec3 geomLightDir;"
"in vec3 geomLightRefl;"
"in vec3 geomViewDir;"
"in vec3 geomViewRefl;"
"out vec4 fragColor;"
"void main(void)"
"{"
" float l = length(geomLightDir);"
" float d = dot("
" normalize(geomNormal), "
" normalize(geomLightDir)"
" ) / l;"
" float s = dot("
" normalize(geomLightRefl),"
" normalize(geomViewDir)"
" );"
" vec3 lt = vec3(1.0, 1.0, 1.0);"
" vec3 tex = texture(TexUnit, geomTexCoord).rgb;"
" fragColor = vec4("
" tex * 0.4 + "
" (lt + tex) * 1.5 * max(d, 0.0) + "
" lt * pow(max(s, 0.0), 64), "
" 1.0"
" );"
"}"
);
// compile it
fs.Compile();
// attach the shaders to the program
prog.AttachShader(vs);
prog.AttachShader(gs);
prog.AttachShader(fs);
// link and use it
prog.Link();
prog.Use();
// bind the VAO for the shape
shape.Bind();
verts.Bind(Buffer::Target::Array);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_shape.Positions(data);
Buffer::Data(Buffer::Target::Array, data);
VertexAttribArray attr(prog, "Position");
attr.Setup<GLfloat>(n_per_vertex);
attr.Enable();
}
normals.Bind(Buffer::Target::Array);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_shape.Normals(data);
Buffer::Data(Buffer::Target::Array, data);
VertexAttribArray attr(prog, "Normal");
attr.Setup<GLfloat>(n_per_vertex);
attr.Enable();
}
// setup the texture
{
GLuint tex_side = 512;
auto image = images::NewtonFractal(
tex_side, tex_side,
Vec3f(0.8f, 0.8f, 1.0f),
Vec3f(0.1f, 0.0f, 0.2f),
Vec2f(-0.707f, -0.707f),
Vec2f( 0.707f, 0.707f),
images::NewtonFractal::X4Minus1(),
[](double x) -> double
{
return pow(SineWave(pow(x,0.5)), 4.0);
}
);
auto bound_tex = Bind(tex, Texture::Target::CubeMap);
bound_tex.MinFilter(TextureMinFilter::Linear);
bound_tex.MagFilter(TextureMagFilter::Linear);
bound_tex.WrapS(TextureWrap::ClampToEdge);
bound_tex.WrapT(TextureWrap::ClampToEdge);
bound_tex.WrapR(TextureWrap::ClampToEdge);
for(int i=0; i!=6; ++i)
Texture::Image2D(Texture::CubeMapFace(i), image);
}
//
UniformSampler(prog, "TexUnit").Set(0);
Uniform<Vec3f>(prog, "LightPos").Set(Vec3f(3.0f, 5.0f, 4.0f));
//
gl.ClearColor(0.1f, 0.05f, 0.2f, 0.0f);
gl.ClearDepth(1.0f);
gl.Enable(Capability::DepthTest);
gl.Enable(Capability::CullFace);
gl.FrontFace(make_shape.FaceWinding());
gl.CullFace(Face::Back);
Uniform<Vec3f> camera_position(prog, "CameraPosition");
camera_position[0].Set(Vec3f(2, 0, 0));
camera_position[1].Set(Vec3f(0, 2, 0));
camera_position[2].Set(Vec3f(0, 0, 2));
}
CubeExample(void)
: cube_instr(make_cube.Instructions())
, cube_indices(make_cube.Indices())
, projection_matrix(prog, "ProjectionMatrix")
, camera_matrix(prog, "CameraMatrix")
, model_matrix(prog, "ModelMatrix")
, front_facing(prog, "FrontFacing")
, inst_count(32)
{
// Set the vertex shader source
vs.Source(
"#version 330\n"
"uniform mat4 ProjectionMatrix, CameraMatrix, ModelMatrix;"
"uniform vec3 LightPos;"
"uniform int InstCount;"
"uniform int FrontFacing;"
"in vec4 Position;"
"in vec3 Normal;"
"out float vertMult;"
"out vec3 vertColor;"
"out vec3 vertWrapNormal;"
"out vec3 vertNormal;"
"out vec3 vertLight;"
"void main(void)"
"{"
" int inst = (FrontFacing != 0) ? "
" (InstCount - gl_InstanceID - 1):"
" gl_InstanceID;"
" vertMult = float(inst) / float(InstCount-1);"
" float sca = 1.0 - 0.3 * pow(vertMult, 2);"
" mat4 ScaleMatrix = mat4("
" sca, 0.0, 0.0, 0.0,"
" 0.0, sca, 0.0, 0.0,"
" 0.0, 0.0, sca, 0.0,"
" 0.0, 0.0, 0.0, 1.0 "
" );"
" gl_Position = ModelMatrix * Position;"
" vertColor = Normal;"
" vec3 wrap = Position.xyz - Normal;"
" vertWrapNormal = "
" mat3(ModelMatrix)*"
" normalize(mix("
" Normal,"
" wrap,"
" mix(0.5, 1.0, vertMult)"
" ));"
" vertNormal = mat3(ModelMatrix)*Normal;"
" vertLight = LightPos-gl_Position.xyz;"
" gl_Position = "
" ProjectionMatrix *"
" CameraMatrix *"
" ScaleMatrix *"
" gl_Position;"
"}"
);
// compile it
vs.Compile();
// set the fragment shader source
fs.Source(
"#version 330\n"
"in float vertMult;"
"in vec3 vertColor;"
"in vec3 vertWrapNormal;"
"in vec3 vertNormal;"
"in vec3 vertLight;"
"out vec4 fragColor;"
"uniform int InstCount;"
"void main(void)"
"{"
" float l = dot(vertLight, vertLight);"
" float d = l > 0.0 ? dot("
" vertNormal, "
" normalize(vertLight)"
" ) / l : 0.0;"
" float s = max("
" dot(vertWrapNormal, vertLight)/l,"
" 0.0"
" );"
" float intensity = clamp("
" 0.2 + d * 3.0 + s * 5.5,"
" 0.0,"
" 1.0"
" );"
" fragColor = vec4("
" abs(vertColor) * intensity,"
" (2.5 + 1.5*d + 1.5*s) / InstCount"
" );"
"}"
);
// compile it
fs.Compile();
// attach the shaders to the program
prog.AttachShader(vs);
prog.AttachShader(fs);
// link and use it
prog.Link();
prog.Use();
// bind the VAO for the cube
cube.Bind();
// bind the VBO for the cube vertices
verts.Bind(Buffer::Target::Array);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_cube.Positions(data);
// upload the data
Buffer::Data(Buffer::Target::Array, data);
// setup the vertex attribs array for the vertices
VertexArrayAttrib attr(prog, "Position");
attr.Setup<GLfloat>(n_per_vertex);
attr.Enable();
}
// bind the VBO for the cube normals
normals.Bind(Buffer::Target::Array);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_cube.Normals(data);
// upload the data
Buffer::Data(Buffer::Target::Array, data);
VertexArrayAttrib attr(prog, "Normal");
attr.Setup<GLfloat>(n_per_vertex);
attr.Enable();
}
// the light position
Uniform<Vec3f>(prog, "LightPos").Set(Vec3f(-3.0f, -2.0f, -3.0f));
// and the instance count
Uniform<GLint>(prog, "InstCount").Set(inst_count);
//
gl.ClearColor(0.5f, 0.6f, 0.5f, 0.0f);
gl.ClearDepth(1.0f);
gl.Enable(Capability::DepthTest);
gl.Enable(Capability::CullFace);
gl.FrontFace(make_cube.FaceWinding());
gl.Enable(Capability::Blend);
gl.BlendFunc(BlendFn::SrcAlpha, BlendFn::OneMinusSrcAlpha);
}
CubeExample(void)
: cube_instr(make_cube.Instructions())
, cube_indices(make_cube.Indices())
, projection_matrix(prog, "ProjectionMatrix")
, camera_matrix(prog, "CameraMatrix")
, model_matrix(prog, "ModelMatrix")
{
namespace se = oglplus::smart_enums;
// Set the vertex shader source
vs.Source(
"#version 330\n"
"uniform mat4 ProjectionMatrix, CameraMatrix, ModelMatrix;"
"in vec4 Position;"
"in vec3 Normal;"
"in vec2 TexCoord;"
"out vec3 vertNormal;"
"out vec3 vertLight;"
"out vec2 vertTexCoord;"
"uniform vec3 LightPos;"
"void main(void)"
"{"
" vertNormal = mat3(ModelMatrix)*Normal;"
" gl_Position = ModelMatrix * Position;"
" vertLight = LightPos - gl_Position.xyz;"
" vertTexCoord = TexCoord;"
" gl_Position = ProjectionMatrix * CameraMatrix * gl_Position;"
"}"
);
// compile it
vs.Compile();
// set the fragment shader source
fs.Source(
"#version 330\n"
"uniform sampler2D TexUnit;"
"in vec3 vertNormal;"
"in vec3 vertLight;"
"in vec2 vertTexCoord;"
"out vec4 fragColor;"
"void main(void)"
"{"
" float l = length(vertLight);"
" float d = l > 0 ? dot(vertNormal, normalize(vertLight)) / l : 0.0;"
" float i = 0.3 + 2.0*max(d, 0.0);"
" vec4 t = texture(TexUnit, vertTexCoord);"
" fragColor = vec4(t.rgb*i, 1.0);"
"}"
);
// compile it
fs.Compile();
// attach the shaders to the program
prog.AttachShader(vs);
prog.AttachShader(fs);
// link and use it
prog.Link();
prog.Use();
// bind the VAO for the cube
cube.Bind();
verts.Bind(se::Array());
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_cube.Positions(data);
Buffer::Data(se::Array(), data);
(prog|"Position").Setup(n_per_vertex, se::Float()).Enable();
}
normals.Bind(se::Array());
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_cube.Normals(data);
Buffer::Data(se::Array(), data);
(prog|"Normal").Setup(n_per_vertex, se::Float()).Enable();
}
texcoords.Bind(se::Array());
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_cube.TexCoordinates(data);
Buffer::Data(se::Array(), data);
(prog|"TexCoord").Setup(n_per_vertex, se::Float()).Enable();
}
// setup the texture
{
auto bound_tex = Bind(tex, se::_2D());
bound_tex.Image2D(images::LoadTexture("concrete_block"));
bound_tex.MinFilter(se::Linear());
bound_tex.MagFilter(se::Linear());
bound_tex.WrapS(se::Repeat());
bound_tex.WrapT(se::Repeat());
}
// set the uniform values
(prog/"TexUnit") = 0;
(prog/"LightPos") = Vec3f(1.0f, 2.0f, 3.0f);
//
gl.ClearColor(0.1f, 0.1f, 0.1f, 0.0f);
gl.ClearDepth(1.0f);
gl.Enable(se::DepthTest());
gl.Enable(se::CullFace());
gl.FrontFace(make_cube.FaceWinding());
}
static Program make_transf_prog(void)
{
VertexShader vs;
vs.Source(
"#version 330\n"
"uniform mat4 ModelMatrix;"
"in vec4 Position;"
"in vec3 Normal;"
"in vec2 TexCoord;"
"out gl_PerVertex {"
" vec4 gl_Position;"
"};"
"out vec3 vertNormal;"
"out vec2 vertTexCoord;"
"void main(void)"
"{"
" gl_Position = ModelMatrix * Position;"
" vertNormal = (ModelMatrix*vec4(Normal,0.0)).xyz;"
" vertTexCoord = TexCoord;"
"}"
);
vs.Compile();
GeometryShader gs;
gs.Source(
"#version 330\n"
"layout(triangles) in;"
"layout(triangle_strip, max_vertices = 15) out;"
"uniform mat4 CameraMatrix, ProjectionMatrix;"
"uniform vec3 LightPos;"
"uniform float Time;"
"in gl_PerVertex {"
" vec4 gl_Position;"
"} gl_in[];"
"in vec3 vertNormal[];"
"in vec2 vertTexCoord[];"
"out gl_PerVertex {"
" vec4 gl_Position;"
"};"
"out vec3 geomNormal;"
"out vec3 geomLight;"
"out float geomGlow;"
"flat out int geomTop;"
"void main(void)"
"{"
" vec3 FaceNormal = normalize("
" vertNormal[0]+"
" vertNormal[1]+"
" vertNormal[2] "
" );"
" vec2 FaceCoord = 0.33333 * ("
" vertTexCoord[0]+"
" vertTexCoord[1]+"
" vertTexCoord[2] "
" );"
" float Offs = (sin((FaceCoord.s + Time/10.0)* 3.14 * 2.0 * 10)*0.5 + 0.5)*0.4;"
" Offs *= cos(FaceCoord.t * 3.1415 * 2.0)*0.5 + 0.51;"
" vec3 pos[3], norm[3];"
" for(int i=0; i!=3; ++i)"
" pos[i] = gl_in[i].gl_Position.xyz;"
" for(int i=0; i!=3; ++i)"
" norm[i] = cross("
" FaceNormal, "
" normalize(pos[(i+1)%3] - pos[i])"
" );"
" vec3 pofs = FaceNormal * Offs;"
" geomTop = 0;"
" for(int i=0; i!=3; ++i)"
" {"
" geomNormal = norm[i];"
" for(int j=0; j!=2; ++j)"
" {"
" vec3 tpos = pos[(i+j)%3];"
" geomLight = LightPos-tpos;"
" geomGlow = 1.0;"
" gl_Position = "
" ProjectionMatrix *"
" CameraMatrix *"
" vec4(tpos, 1.0);"
" EmitVertex();"
" geomGlow = 0.7;"
" geomLight = LightPos-tpos+pofs;"
" gl_Position = "
" ProjectionMatrix *"
" CameraMatrix *"
" vec4(tpos + pofs, 1.0);"
" EmitVertex();"
" }"
" EndPrimitive();"
" }"
" geomGlow = 0.0;"
" geomTop = 1;"
" for(int i=0; i!=3; ++i)"
" {"
" geomLight = LightPos - (pos[i]+pofs);"
" geomNormal = vertNormal[i];"
" gl_Position = "
" ProjectionMatrix *"
" CameraMatrix *"
" vec4(pos[i] + pofs, 1.0);"
" EmitVertex();"
" }"
" EndPrimitive();"
"}"
);
gs.Compile();
Program prog;
prog.AttachShader(vs);
prog.AttachShader(gs);
prog.MakeSeparable();
prog.Link();
ProgramUniform<Vec3f>(prog, "LightPos").Set(4, 4, -8);
return prog;
}
ShadowExample()
: make_torus(1.0, 0.7, 72, 48)
, torus_indices(make_torus.Indices())
, torus_instr(make_torus.Instructions())
, object_projection_matrix(object_prog)
, object_camera_matrix(object_prog)
, object_model_matrix(object_prog)
, shadow_projection_matrix(shadow_prog)
, shadow_camera_matrix(shadow_prog)
, shadow_model_matrix(shadow_prog)
, object_color(object_prog)
, object_light_mult(object_prog) {
vs_object.Source(
"#version 140\n"
"in vec4 Position;"
"in vec3 Normal;"
"uniform mat4 ProjectionMatrix, CameraMatrix, ModelMatrix;"
"uniform vec3 LightPos;"
"out vec3 vertNormal;"
"out vec3 vertLight;"
"void main()"
"{"
" gl_Position = ModelMatrix * Position;"
" vertNormal = mat3(ModelMatrix)*Normal;"
" vertLight = LightPos - gl_Position.xyz;"
" gl_Position = ProjectionMatrix * CameraMatrix * gl_Position;"
"}");
vs_object.Compile();
fs_object.Source(
"#version 140\n"
"in vec3 vertNormal;"
"in vec3 vertLight;"
"uniform vec3 Color;"
"uniform float LightMult;"
"out vec4 fragColor;"
"void main()"
"{"
" float l = sqrt(length(vertLight));"
" float d = l > 0.0 ?"
" dot("
" vertNormal,"
" normalize(vertLight)"
" ) / l : 0.0;"
" float i = 0.3 + max(d, 0.0) * LightMult;"
" fragColor = vec4(Color*i, 1.0);"
"}");
fs_object.Compile();
object_prog.AttachShader(vs_object);
object_prog.AttachShader(fs_object);
object_prog.Link().Use();
object_projection_matrix.BindTo("ProjectionMatrix");
object_camera_matrix.BindTo("CameraMatrix");
object_model_matrix.BindTo("ModelMatrix");
object_color.BindTo("Color");
object_light_mult.BindTo("LightMult");
vs_shadow.Source(
"#version 150\n"
"in vec4 Position;"
"in vec3 Normal;"
"uniform mat4 ModelMatrix;"
"uniform vec3 LightPos;"
"out float ld;"
"void main()"
"{"
" gl_Position = ModelMatrix * Position;"
" vec3 geomNormal = mat3(ModelMatrix)*Normal;"
" vec3 lightDir = LightPos - gl_Position.xyz;"
" ld = dot(geomNormal, normalize(lightDir));"
"}");
vs_shadow.Compile();
gs_shadow.Source(
"#version 150\n"
"layout(triangles) in;"
"layout(triangle_strip, max_vertices = 12) out;"
"in float ld[];"
"uniform mat4 CameraMatrix, ProjectionMatrix;"
"uniform vec3 LightPos;"
"void main()"
"{"
" for(int v=0; v!=3; ++v)"
" {"
" int a = v, b = (v+1)%3, c = (v+2)%3;"
" vec4 pa = gl_in[a].gl_Position;"
" vec4 pb = gl_in[b].gl_Position;"
" vec4 pc = gl_in[c].gl_Position;"
" vec4 px, py;"
" if(ld[a] == 0.0 && ld[b] == 0.0)"
" {"
" px = pa;"
" py = pb;"
" }"
" else if(ld[a] > 0.0 && ld[b] < 0.0)"
" {"
" float x = ld[a]/(ld[a]-ld[b]);"
" float y;"
" px = mix(pa, pb, x);"
" if(ld[c] < 0.0)"
" {"
" y = ld[a]/(ld[a]-ld[c]);"
" py = mix(pa, pc, y);"
" }"
" else"
" {"
" y = ld[c]/(ld[c]-ld[b]);"
" py = mix(pc, pb, y);"
" }"
" }"
" else continue;"
" vec3 vx = px.xyz - LightPos;"
" vec3 vy = py.xyz - LightPos;"
" vec4 sx = vec4(px.xyz + vx*10.0, 1.0);"
" vec4 sy = vec4(py.xyz + vy*10.0, 1.0);"
" vec4 cpx = CameraMatrix * px;"
" vec4 cpy = CameraMatrix * py;"
" vec4 csx = CameraMatrix * sx;"
" vec4 csy = CameraMatrix * sy;"
" gl_Position = ProjectionMatrix * cpy;"
" EmitVertex();"
" gl_Position = ProjectionMatrix * cpx;"
" EmitVertex();"
" gl_Position = ProjectionMatrix * csy;"
" EmitVertex();"
" gl_Position = ProjectionMatrix * csx;"
" EmitVertex();"
" EndPrimitive();"
" break;"
" }"
"}");
gs_shadow.Compile();
fs_shadow.Source(
"#version 150\n"
"out vec4 fragColor;"
"void main()"
"{"
" fragColor = vec4(0.0, 0.0, 0.0, 1.0);"
"}");
fs_shadow.Compile();
shadow_prog.AttachShader(vs_shadow);
shadow_prog.AttachShader(gs_shadow);
shadow_prog.AttachShader(fs_shadow);
shadow_prog.Link().Use();
shadow_projection_matrix.BindTo("ProjectionMatrix");
shadow_camera_matrix.BindTo("CameraMatrix");
shadow_model_matrix.BindTo("ModelMatrix");
// bind the VAO for the torus
torus.Bind();
// bind the VBO for the torus vertices
torus_verts.Bind(Buffer::Target::Array);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_torus.Positions(data);
Buffer::Data(Buffer::Target::Array, data);
VertexArrayAttrib attr(VertexArrayAttrib::GetCommonLocation(
MakeGroup(object_prog, shadow_prog), "Position"));
attr.Setup<GLfloat>(n_per_vertex);
attr.Enable();
}
// bind the VBO for the torus normals
torus_normals.Bind(Buffer::Target::Array);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_torus.Normals(data);
Buffer::Data(Buffer::Target::Array, data);
object_prog.Use();
VertexArrayAttrib attr(object_prog, "Normal");
attr.Setup<GLfloat>(n_per_vertex);
attr.Enable();
}
// bind the VAO for the plane
plane.Bind();
// bind the VBO for the plane vertices
plane_verts.Bind(Buffer::Target::Array);
{
GLfloat data[4 * 3] = {-9.0f,
0.0f,
-9.0f,
-9.0f,
0.0f,
9.0f,
9.0f,
0.0f,
-9.0f,
9.0f,
0.0f,
9.0f};
Buffer::Data(Buffer::Target::Array, 4 * 3, data);
object_prog.Use();
VertexArrayAttrib attr(object_prog, "Position");
attr.Setup<GLfloat>(3);
attr.Enable();
}
// bind the VBO for the torus normals
plane_normals.Bind(Buffer::Target::Array);
{
GLfloat data[4 * 3] = {-0.1f,
1.0f,
0.1f,
-0.1f,
1.0f,
-0.1f,
0.1f,
1.0f,
0.1f,
0.1f,
1.0f,
-0.1f};
Buffer::Data(Buffer::Target::Array, 4 * 3, data);
object_prog.Use();
VertexArrayAttrib attr(object_prog, "Normal");
attr.Setup<GLfloat>(3);
attr.Enable();
}
Vec3f lightPos(2.0f, 9.0f, 3.0f);
ProgramUniform<Vec3f>(object_prog, "LightPos").Set(lightPos);
ProgramUniform<Vec3f>(shadow_prog, "LightPos").Set(lightPos);
gl.ClearColor(0.2f, 0.2f, 0.2f, 0.0f);
gl.ClearDepth(1.0f);
gl.ClearStencil(0);
gl.Enable(Capability::DepthTest);
gl.Enable(Capability::CullFace);
gl.FrontFace(make_torus.FaceWinding());
}
CubeMapExample(void)
: make_shape(4)
, shape_instr(make_shape.Instructions())
, shape_indices(make_shape.Indices())
, projection_matrix(prog, "ProjectionMatrix")
, camera_matrix(prog, "CameraMatrix")
, model_matrix(prog, "ModelMatrix")
{
vs.Source(
"#version 330\n"
"uniform mat4 ProjectionMatrix, CameraMatrix, ModelMatrix;"
"in vec4 Position;"
"out vec3 vertNormal;"
"out vec3 vertTexCoord;"
"out vec3 vertLightDir;"
"out vec3 vertViewDir;"
"uniform vec3 LightPos;"
"void main(void)"
"{"
" vec3 Normal = Position.xyz;"
" gl_Position = ModelMatrix * Position;"
" vertNormal = mat3(ModelMatrix)*Normal;"
" vertTexCoord = Normal;"
" vertLightDir = LightPos - gl_Position.xyz;"
" vertViewDir = (vec4(0.0, 0.0, 1.0, 1.0)*CameraMatrix).xyz;"
" gl_Position = ProjectionMatrix * CameraMatrix * gl_Position;"
"}"
);
vs.Compile();
gs.Source(
"#version 330\n"
"layout (triangles) in;"
"layout (triangle_strip, max_vertices = 3) out;"
"in vec3 vertNormal[3];"
"in vec3 vertTexCoord[3];"
"in vec3 vertLightDir[3];"
"in vec3 vertViewDir[3];"
"out vec3 geomNormal;"
"out vec3 geomTexCoord;"
"out vec3 geomLightDir;"
"out vec3 geomLightRefl;"
"out vec3 geomViewDir;"
"void main(void)"
"{"
" vec3 FaceNormal = 0.333333*("
" vertNormal[0]+"
" vertNormal[1]+"
" vertNormal[2] "
" );"
" for(int v=0; v!=3; ++v)"
" {"
" gl_Position = gl_in[v].gl_Position;"
" geomNormal = 0.5*(vertNormal[v]+FaceNormal);"
" geomTexCoord = vertTexCoord[v];"
" geomLightDir = vertLightDir[v];"
" geomLightRefl = reflect("
" -normalize(geomLightDir),"
" normalize(FaceNormal)"
" );"
" geomViewDir = vertViewDir[v];"
" EmitVertex();"
" }"
" EndPrimitive();"
"}"
);
gs.Compile();
fs.Source(
"#version 330\n"
"uniform samplerCube TexUnit;"
"in vec3 geomNormal;"
"in vec3 geomTexCoord;"
"in vec3 geomLightDir;"
"in vec3 geomLightRefl;"
"in vec3 geomViewDir;"
"out vec3 fragColor;"
"void main(void)"
"{"
" vec3 lt = vec3(1.0, 1.0, 1.0);"
" vec3 tex = texture(TexUnit, geomTexCoord).rgb;"
" float d = dot("
" normalize(geomNormal), "
" normalize(geomLightDir)"
" );"
" float s = dot("
" normalize(geomLightRefl),"
" normalize(geomViewDir)"
" );"
" float b = 1.0-sqrt(max(dot("
" normalize(geomNormal),"
" normalize(geomViewDir)"
" ), 0.0));"
" float ea = clamp(tex.b*(-d+0.2), 0.0, 1.0);"
" float sr = 1.0-tex.b*0.8;"
" fragColor = "
" tex * (0.3*ea + 0.6*b + 0.8*max(d, 0.0)) + "
" (tex+lt) * 0.8*sr*pow(clamp(s+0.05, 0.0, 1.0), 32);"
"}"
);
fs.Compile();
// attach the shaders to the program
prog.AttachShader(vs);
prog.AttachShader(gs);
prog.AttachShader(fs);
// link and use it
prog.Link();
prog.Use();
// bind the VAO for the shape
shape.Bind();
positions.Bind(Buffer::Target::Array);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_shape.Positions(data);
Buffer::Data(Buffer::Target::Array, data);
VertexAttribArray attr(prog, "Position");
attr.Setup<GLfloat>(n_per_vertex);
attr.Enable();
}
// setup the texture
{
auto bound_tex = Bind(tex, Texture::Target::CubeMap);
bound_tex.MinFilter(TextureMinFilter::Linear);
bound_tex.MagFilter(TextureMagFilter::Linear);
bound_tex.WrapS(TextureWrap::ClampToEdge);
bound_tex.WrapT(TextureWrap::ClampToEdge);
bound_tex.WrapR(TextureWrap::ClampToEdge);
const char* tex_name[6] = {
"cube_0_right",
"cube_1_left",
"cube_2_top",
"cube_3_bottom",
"cube_4_front",
"cube_5_back"
};
for(GLuint i=0; i!=6; ++i)
{
Texture::Image2D(
Texture::CubeMapFace(i),
images::LoadTexture(tex_name[i], false, true)
);
}
}
UniformSampler(prog, "TexUnit").Set(0);
//
Uniform<Vec3f>(prog, "LightPos").Set(Vec3f(3.0f, 5.0f, 4.0f));
//
gl.ClearColor(0.05f, 0.2f, 0.1f, 0.0f);
gl.ClearDepth(1.0f);
gl.Enable(Capability::DepthTest);
gl.Enable(Capability::CullFace);
gl.FrontFace(make_shape.FaceWinding());
gl.CullFace(Face::Back);
}
TessellationExample(void)
: shape_instr(make_shape.Instructions())
, shape_indices(make_shape.Indices())
, tess_level(prog, "TessLevel")
, viewport_dimensions(prog, "ViewportDimensions")
, projection_matrix(prog, "ProjectionMatrix")
, camera_matrix(prog, "CameraMatrix")
, model_matrix(prog, "ModelMatrix")
{
vs.Source(
"#version 330\n"
"in vec4 Position;"
"void main(void)"
"{"
" gl_Position = Position;"
"}"
);
vs.Compile();
gs.Source(
"#version 330\n"
"layout (triangles) in;"
"layout (triangle_strip, max_vertices = 48) out;"
"const vec3 LightPosition = vec3(12.0, 10.0, 7.0);"
"uniform mat4 ProjectionMatrix, CameraMatrix, ModelMatrix;"
"uniform vec2 ViewportDimensions;"
"uniform int TessLevel;"
"noperspective out vec3 geomDist;"
"flat out vec3 geomNormal;"
"out vec3 geomColor;"
"out vec3 geomLightDir;"
"void make_triangle(vec4 p0, vec4 p1, vec4 p2)"
"{"
" vec3 n0 = (ModelMatrix*vec4(p0.xyz, 0)).xyz;"
" vec3 n1 = (ModelMatrix*vec4(p1.xyz, 0)).xyz;"
" vec3 n2 = (ModelMatrix*vec4(p2.xyz, 0)).xyz;"
" vec4 m0 = ModelMatrix*p0;"
" vec4 m1 = ModelMatrix*p1;"
" vec4 m2 = ModelMatrix*p2;"
" vec4 c0 = ProjectionMatrix*CameraMatrix*m0;"
" vec4 c1 = ProjectionMatrix*CameraMatrix*m1;"
" vec4 c2 = ProjectionMatrix*CameraMatrix*m2;"
" vec2 s0 = ViewportDimensions * c0.xy/c0.w;"
" vec2 s1 = ViewportDimensions * c1.xy/c1.w;"
" vec2 s2 = ViewportDimensions * c2.xy/c2.w;"
" vec2 v0 = s2 - s1;"
" vec2 v1 = s0 - s2;"
" vec2 v2 = s1 - s0;"
" float d0 = abs(v1.x*v2.y-v1.y*v2.x)/length(v0);"
" float d1 = abs(v2.x*v0.y-v2.y*v0.x)/length(v1);"
" float d2 = abs(v0.x*v1.y-v0.y*v1.x)/length(v2);"
" geomNormal = normalize(n0+n1+n2);"
" gl_Position = c0;"
" geomColor = normalize(abs(vec3(1, 1, 1) - n0));"
" geomLightDir = LightPosition - m0.xyz;"
" geomDist = vec3(d0, 0.0, 0.0);"
" EmitVertex();"
" gl_Position = c1;"
" geomColor = normalize(abs(vec3(1, 1, 1) - n1));"
" geomLightDir = LightPosition - m1.xyz;"
" geomDist = vec3(0.0, d1, 0.0);"
" EmitVertex();"
" gl_Position = c2;"
" geomColor = normalize(abs(vec3(1, 1, 1) - n2));"
" geomLightDir = LightPosition - m2.xyz;"
" geomDist = vec3(0.0, 0.0, d2);"
" EmitVertex();"
" EndPrimitive();"
"}"
"void do_tess_1(vec4 p_0, vec4 p_1, vec4 p_2, int l)"
"{"
" if(l == 1) make_triangle(p_0, p_1, p_2);"
" else"
" {"
" vec4 p01 = vec4(normalize(p_0.xyz+p_1.xyz), 1.0);"
" vec4 p12 = vec4(normalize(p_1.xyz+p_2.xyz), 1.0);"
" vec4 p20 = vec4(normalize(p_2.xyz+p_0.xyz), 1.0);"
" make_triangle(p_0, p01, p20);"
" make_triangle(p01, p_1, p12);"
" make_triangle(p20, p12, p_2);"
" make_triangle(p01, p12, p20);"
" }"
"}"
"void do_tess_0(vec4 p_0, vec4 p_1, vec4 p_2, int l)"
"{"
" if(l == 0) make_triangle(p_0, p_1, p_2);"
" else"
" {"
" vec4 p01 = vec4(normalize(p_0.xyz+p_1.xyz), 1.0);"
" vec4 p12 = vec4(normalize(p_1.xyz+p_2.xyz), 1.0);"
" vec4 p20 = vec4(normalize(p_2.xyz+p_0.xyz), 1.0);"
" do_tess_1(p_0, p01, p20, l);"
" do_tess_1(p01, p_1, p12, l);"
" do_tess_1(p20, p12, p_2, l);"
" do_tess_1(p01, p12, p20, l);"
" }"
"}"
"void main(void)"
"{"
" do_tess_0("
" gl_in[0].gl_Position,"
" gl_in[1].gl_Position,"
" gl_in[2].gl_Position,"
" TessLevel"
" );"
"}"
);
gs.Compile();
fs.Source(
"#version 330\n"
"noperspective in vec3 geomDist;"
"flat in vec3 geomNormal;"
"in vec3 geomColor;"
"in vec3 geomLightDir;"
"out vec3 fragColor;"
"void main(void)"
"{"
" float MinDist = min(min(geomDist.x,geomDist.y),geomDist.z);"
" float EdgeAlpha = exp2(-pow(MinDist, 2.0));"
" const float Ambient = 0.7;"
" float Diffuse = max(dot("
" normalize(geomNormal),"
" normalize(geomLightDir)"
" )+0.1, 0.0)*1.4;"
" vec3 FaceColor = geomColor * (Diffuse + Ambient);"
" const vec3 EdgeColor = vec3(0.0, 0.0, 0.0);"
" fragColor = mix(FaceColor, EdgeColor, EdgeAlpha);"
"}"
);
fs.Compile();
prog.AttachShader(vs);
prog.AttachShader(gs);
prog.AttachShader(fs);
prog.Link();
prog.Use();
shape.Bind();
verts.Bind(Buffer::Target::Array);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_shape.Positions(data);
Buffer::Data(Buffer::Target::Array, data);
VertexAttribArray attr(prog, "Position");
attr.Setup<GLfloat>(n_per_vertex);
attr.Enable();
indices.Bind(Buffer::Target::ElementArray);
Buffer::Data(Buffer::Target::ElementArray, shape_indices);
shape_indices.clear();
}
//
gl.ClearColor(0.7f, 0.7f, 0.7f, 0.0f);
gl.ClearDepth(1.0f);
gl.Enable(Capability::DepthTest);
prog.Use();
}
SphereExample(void)
: sphere_instr(make_sphere.Instructions())
, sphere_indices(make_sphere.Indices())
, hole_count(50)
, hole_diameter(0.30f)
{
// This shader will be used in transform fedback mode
// to transform the vertices used to "cut out the holes"
// the same way the sphere is transformed
vs_tfb.Source(
"#version 330\n"
"uniform mat4 CameraMatrix, ModelMatrix;"
"uniform float Diameter;"
"in vec3 Hole;"
"out vec3 vertTransfHole;"
"void main(void)"
"{"
" vertTransfHole = ("
" CameraMatrix *"
" ModelMatrix *"
" vec4(Hole * (1.0 + 0.5 * Diameter), 0.0)"
" ).xyz;"
"}"
);
// compile, setup transform feedback output variables
// link and use the program
vs_tfb.Compile();
prog_tfb.AttachShader(vs_tfb);
const GLchar* var_name = "vertTransfHole";
prog_tfb.TransformFeedbackVaryings(
1, &var_name,
TransformFeedbackMode::InterleavedAttribs
);
prog_tfb.Link();
prog_tfb.Use();
Uniform<GLfloat> diameter(prog_tfb, "Diameter");
diameter.Set(hole_diameter);
// bind the VAO for the holes
holes.Bind();
// bind the VBO for the hole vertices
hole_verts.Bind(Buffer::Target::Array);
// and the VBO for the transformed hole vertices captured by tfb
transf_hole_verts.Bind(Buffer::Target::TransformFeedback);
{
std::vector<GLfloat> data;
make_hole_data(data, hole_count);
Buffer::Data(Buffer::Target::TransformFeedback, data);
Buffer::Data(Buffer::Target::Array, data);
VertexAttribArray attr(prog_tfb, "Hole");
attr.Setup<Vec3f>();
attr.Enable();
}
transf_hole_verts.BindBase(
Buffer::IndexedTarget::TransformFeedback,
0
);
// Set the vertex shader source
vs.Source(
"#version 330\n"
"uniform mat4 ProjectionMatrix, CameraMatrix, ModelMatrix;"
"in vec4 Position;"
"in vec3 Normal;"
"out vec3 vertNormal;"
"out vec3 vertLight;"
"const vec3 LightPos = vec3(2.0, 3.0, 3.0);"
"void main(void)"
"{"
" gl_Position = ModelMatrix * Position;"
" vertNormal = mat3(ModelMatrix)*Normal;"
" vertLight = LightPos-gl_Position.xyz;"
" gl_Position = ProjectionMatrix * CameraMatrix * gl_Position;"
"}"
);
// compile it
vs.Compile();
// set the fragment shader source
fs.Source(
"#version 330\n"
"in vec3 vertNormal;"
"in vec3 vertLight;"
"out vec4 fragColor;"
"const int HoleCount = 50;"
"uniform vec3 TransfHole[50];"
"uniform float Diameter;"
"void main(void)"
"{"
" int imax = 0;"
" float dmax = -1.0;"
" for(int i=0; i!=HoleCount; ++i)"
" {"
" float d = dot(vertNormal, TransfHole[i]);"
" if(dmax < d)"
" {"
" dmax = d;"
" imax = i;"
" }"
" }"
" float l = length(vertLight);"
" vec3 FragDiff = TransfHole[imax] - vertNormal;"
" vec3 FinalNormal = "
" length(FragDiff) > Diameter?"
" vertNormal:"
" normalize(FragDiff+vertNormal*Diameter);"
" float i = (l > 0.0) ? dot("
" FinalNormal, "
" normalize(vertLight)"
" ) / l : 0.0;"
" i = 0.2+max(i*2.5, 0.0);"
" fragColor = vec4(i, i, i, 1.0);"
"}"
);
// compile it
fs.Compile();
// attach the shaders to the program
prog.AttachShader(vs);
prog.AttachShader(fs);
// link and use it
prog.Link();
prog.Use();
diameter.Set(hole_diameter);
// bind the VAO for the sphere
sphere.Bind();
// bind the VBO for the sphere vertices
verts.Bind(Buffer::Target::Array);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_sphere.Positions(data);
// upload the data
Buffer::Data(Buffer::Target::Array, data);
// setup the vertex attribs array for the vertices
VertexAttribArray attr(prog, "Position");
attr.Setup<GLfloat>(n_per_vertex);
attr.Enable();
}
// bind the VBO for the sphere normals
normals.Bind(Buffer::Target::Array);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_sphere.Normals(data);
// upload the data
Buffer::Data(Buffer::Target::Array, data);
// setup the vertex attribs array for the vertices
VertexAttribArray attr(prog, "Normal");
attr.Setup<GLfloat>(n_per_vertex);
attr.Enable();
}
gl.ClearColor(0.8f, 0.8f, 0.7f, 0.0f);
gl.ClearDepth(1.0f);
gl.Enable(Capability::DepthTest);
}
Test01(void)
{
// Set the vertex shader source
vs.Source(
"#version 330\n"
"uniform mat4 projectionMatrix, cameraMatrix, modelMatrix;"
"in vec4 vertex;"
"in vec3 normal;"
"in vec3 tangent;"
"in vec2 texcoord;"
"out vec3 fragLight;"
"out vec2 fragTex;"
"out mat3 normalMatrix;"
"uniform vec3 lightPos;"
"void main(void)"
"{"
" vec3 fragNormal = ("
" modelMatrix *"
" vec4(normal, 0.0)"
" ).xyz;"
" vec3 fragTangent = ("
" modelMatrix *"
" vec4(tangent, 0.0)"
" ).xyz;"
" normalMatrix[0] = fragTangent;"
" normalMatrix[1] = cross(fragNormal, fragTangent);"
" normalMatrix[2] = fragNormal;"
" fragLight = ("
" vec4(lightPos, 0.0)-"
" modelMatrix*vertex"
" ).xyz;"
" fragTex = texcoord;"
" gl_Position = "
" projectionMatrix *"
" cameraMatrix *"
" modelMatrix *"
" vertex;"
"}"
);
// compile it
vs.Compile();
// set the fragment shader source
fs.Source(
"#version 330\n"
"uniform sampler2D colorTex, normalTex;"
"in vec3 fragLight;"
"in vec2 fragTex;"
"in mat3 normalMatrix;"
"out vec4 fragColor;"
"void main(void)"
"{"
" float s = 5.0;"
" float l = length(fragLight);"
" vec3 n = texture2D(normalTex, fragTex*s).xyz;"
" vec3 finalNormal = normalMatrix * n;"
" float d = (l != 0.0)?"
" dot(fragLight, finalNormal)/l:"
" 0.0;"
" float i = 0.1 + 2.5*clamp(d, 0.0, 1.0);"
" vec4 t = texture2D(colorTex, fragTex*s);"
" fragColor = vec4(t.rgb*i, 1.0);"
"}"
);
// compile it
fs.Compile();
// attach the shaders to the program
prog.AttachShader(vs);
prog.AttachShader(fs);
// link and use it
prog.Link();
prog.Use();
// bind the VAO for the shape
vao.Bind();
{
std::vector<GLfloat> data;
GLuint n_per_vertex = shape.Positions(data);
Bind(verts, Buffer::Target::Array).Data(data);
// setup the vertex attribs array for the vertices
VertexAttribArray attr(prog, "vertex");
attr.Setup(n_per_vertex, DataType::Float);
attr.Enable();
}
{
std::vector<GLfloat> data;
GLuint n_per_vertex = shape.Normals(data);
Bind(normals, Buffer::Target::Array).Data(data);
// setup the vertex attribs array for the normals
VertexAttribArray attr(prog, "normal");
attr.Setup(n_per_vertex, DataType::Float);
attr.Enable();
}
{
std::vector<GLfloat> data;
GLuint n_per_vertex = shape.Tangents(data);
Bind(tangents, Buffer::Target::Array).Data(data);
VertexAttribArray attr(prog, "tangent");
attr.Setup(n_per_vertex, DataType::Float);
attr.Enable();
}
// bind the VBO for the shape tex-coords
{
std::vector<GLfloat> data;
GLuint n_per_vertex = shape.TexCoordinates(data);
Bind(texcoords, Buffer::Target::Array).Data(data);
//
VertexAttribArray attr(prog, "texcoord");
attr.Setup(n_per_vertex, DataType::Float);
attr.Enable();
}
// setup the textures
{
Texture::Active(0);
UniformSampler(prog, "colorTex").Set(0);
auto bound_tex = Bind(color_tex, Texture::Target::_2D);
bound_tex.Image2D(images::LoadTexture("stones"));
bound_tex.GenerateMipmap();
bound_tex.MinFilter(TextureMinFilter::LinearMipmapLinear);
bound_tex.MagFilter(TextureMagFilter::Linear);
bound_tex.WrapS(TextureWrap::Repeat);
bound_tex.WrapT(TextureWrap::Repeat);
}
{
Texture::Active(1);
UniformSampler(prog, "normalTex").Set(1);
auto bound_tex = Bind(normal_tex, Texture::Target::_2D);
bound_tex.Image2D(
images::NormalMap(images::LoadTexture("stones-hmap"))
);
bound_tex.GenerateMipmap();
bound_tex.MinFilter(TextureMinFilter::LinearMipmapLinear);
bound_tex.MagFilter(TextureMagFilter::Linear);
bound_tex.WrapS(TextureWrap::Repeat);
bound_tex.WrapT(TextureWrap::Repeat);
}
Uniform<Mat4f>(prog, "projectionMatrix").Set(
CamMatrixf::Perspective(Degrees(24), 1.25, 1, 100)
);
//
VertexArray::Unbind();
gl.ClearColor(0.3f, 0.3f, 0.3f, 0.0f);
gl.ClearDepth(1.0f);
gl.Enable(Capability::DepthTest);
//
gl.FrontFace(shape.FaceWinding());
gl.CullFace(Face::Back);
gl.Enable(Capability::CullFace);
}
CubeExample(void)
: cube_instr(make_cube.Instructions())
, cube_indices(make_cube.Indices())
{
// Set the vertex shader source
vs.Source(
"#version 330\n"
"uniform mat4 ProjectionMatrix, CameraMatrix;"
"in vec4 Position;"
"in vec2 TexCoord;"
"out vec2 vertTexCoord;"
"void main(void)"
"{"
" vertTexCoord = TexCoord;"
" gl_Position = "
" ProjectionMatrix *"
" CameraMatrix *"
" Position;"
"}"
);
// compile it
vs.Compile();
// set the fragment shader source
fs.Source(
"#version 330\n"
"in vec2 vertTexCoord;"
"out vec4 fragColor;"
"void main(void)"
"{"
" float i = ("
" 1 +"
" int(vertTexCoord.x*8) % 2+"
" int(vertTexCoord.y*8) % 2"
" ) % 2;"
" fragColor = vec4(i, i, i, 1.0);"
"}"
);
// compile it
fs.Compile();
// attach the shaders to the program
prog.AttachShader(vs);
prog.AttachShader(fs);
// link and use it
prog.Link();
prog.Use();
// bind the VAO for the cube
cube.Bind();
// bind the VBO for the cube vertices
verts.Bind(Buffer::Target::Array);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_cube.Positions(data);
// upload the data
Buffer::Data(Buffer::Target::Array, data);
// setup the vertex attribs array for the vertices
VertexAttribArray attr(prog, "Position");
attr.Setup(n_per_vertex, DataType::Float);
attr.Enable();
}
// bind the VBO for the cube texture-coordinates
texcoords.Bind(Buffer::Target::Array);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_cube.TexCoordinates(data);
// upload the data
Buffer::Data(Buffer::Target::Array, data);
// setup the vertex attribs array for the vertices
VertexAttribArray attr(prog, "TexCoord");
attr.Setup(n_per_vertex, DataType::Float);
attr.Enable();
}
//
gl.ClearColor(0.8f, 0.8f, 0.7f, 0.0f);
gl.ClearDepth(1.0f);
gl.Enable(Capability::DepthTest);
}
SmokeExample(void)
: emitters()
, projection_matrix(prog, "ProjectionMatrix")
, camera_matrix(prog, "CameraMatrix")
{
emitters.push_back(
ParticleSystem(
ListOf<Vec3f>
(Vec3f(-20.0f, -10.0f, 10.0f))
(Vec3f( 20.0f, 0.0f, -20.0f))
(Vec3f( 20.0f, 10.0f, 20.0f))
(Vec3f(-20.0f, 0.0f, -10.0f))
.As<std::vector<Vec3f>>(), 5.0, 200.0
)
);
emitters.push_back(
ParticleSystem(
ListOf<Vec3f>
(Vec3f( 30.0f, 0.0f, 0.0f))
(Vec3f(-30.0f, 0.0f, 0.0f))
(Vec3f(-20.0f, 20.0f, 0.0f))
(Vec3f( 20.0f, -10.0f, 0.0f))
.As<std::vector<Vec3f>>(), 3.0, 200.0
)
);
emitters.push_back(
ParticleSystem(
ListOf<Vec3f>
(Vec3f( 5.0f, 20.0f, 20.0f))
(Vec3f( -5.0f, 20.0f, -20.0f))
(Vec3f( 5.0f, -20.0f, -20.0f))
(Vec3f( -5.0f, -20.0f, 20.0f))
.As<std::vector<Vec3f>>(), 20.0, 100.0
)
);
// Set the vertex shader source
vs.Source(
"#version 330\n"
"uniform mat4 CameraMatrix;"
"in vec4 Position;"
"in float Age;"
"out float vertAge;"
"void main(void)"
"{"
" gl_Position = CameraMatrix * Position;"
" vertAge = Age;"
"}"
);
// compile it
vs.Compile();
// Set the geometry shader source
gs.Source(
"#version 330\n"
"layout(points) in;"
"layout(triangle_strip, max_vertices = 4) out;"
"uniform mat4 ProjectionMatrix;"
"in float vertAge[];"
"out float geomAge;"
"void main(void)"
"{"
" if(vertAge[0] > 1.0) return;"
" float s = 0.5;"
" float yo[2] = float[2](-1.0, 1.0);"
" float xo[2] = float[2](-1.0, 1.0);"
" for(int j=0;j!=2;++j)"
" for(int i=0;i!=2;++i)"
" {"
" float xoffs = xo[i]*(1.0+vertAge[0])*s;"
" float yoffs = yo[j]*(1.0+vertAge[0])*s;"
" gl_Position = ProjectionMatrix * vec4("
" gl_in[0].gl_Position.x-xoffs,"
" gl_in[0].gl_Position.y-yoffs,"
" gl_in[0].gl_Position.z,"
" 1.0"
" );"
" geomAge = vertAge[0];"
" EmitVertex();"
" }"
" EndPrimitive();"
"}"
);
// compile it
gs.Compile();
// set the fragment shader source
fs.Source(
"#version 330\n"
"in float geomAge;"
"out vec4 fragColor;"
"void main(void)"
"{"
" vec3 Color1 = vec3(1.0, 0.5, 0.5);"
" vec3 Color2 = vec3(0.3, 0.1, 0.1);"
" fragColor = vec4("
" mix(Color1, Color2, geomAge),"
" 1.0 - geomAge"
" );"
"}"
);
// compile it
fs.Compile();
// attach the shaders to the program
prog.AttachShader(vs);
prog.AttachShader(gs);
prog.AttachShader(fs);
// link and use it
prog.Link();
prog.Use();
// bind the VAO for the particles
particles.Bind();
// bind the VBO for the particle positions
pos_buf.Bind(Buffer::Target::Array);
{
Buffer::Data(Buffer::Target::Array, positions, BufferUsage::DynamicDraw);
VertexAttribArray attr(prog, "Position");
attr.Setup(3, DataType::Float);
attr.Enable();
}
// bind the VBO for the particle ages
age_buf.Bind(Buffer::Target::Array);
{
Buffer::Data(Buffer::Target::Array, ages, BufferUsage::DynamicDraw);
VertexAttribArray attr(prog, "Age");
attr.Setup(1, DataType::Float);
attr.Enable();
}
//
gl.ClearColor(0.9f, 0.9f, 0.9f, 0.0f);
gl.ClearDepth(1.0f);
gl.Enable(Capability::DepthTest);
gl.Enable(Capability::Blend);
gl.BlendFunc(BlendFn::SrcAlpha, BlendFn::OneMinusSrcAlpha);
}
HaloExample(void)
: make_shape()
, shape_indices(make_shape.Indices())
, shape_instr(make_shape.Instructions())
, vs_shape(ObjectDesc("Shape VS"))
, vs_plane(ObjectDesc("Plane VS"))
, fs_shape(ObjectDesc("Shape FS"))
, fs_plane(ObjectDesc("Plane FS"))
, vs_halo(ObjectDesc("Halo VS"))
, gs_halo(ObjectDesc("Halo GS"))
, fs_halo(ObjectDesc("Halo FS"))
, shape_projection_matrix(shape_prog, "ProjectionMatrix")
, shape_camera_matrix(shape_prog, "CameraMatrix")
, shape_model_matrix(shape_prog, "ModelMatrix")
, plane_projection_matrix(plane_prog, "ProjectionMatrix")
, plane_camera_matrix(plane_prog, "CameraMatrix")
, halo_projection_matrix(halo_prog, "ProjectionMatrix")
, halo_camera_matrix(halo_prog, "CameraMatrix")
, halo_model_matrix(halo_prog, "ModelMatrix")
{
vs_shape.Source(
"#version 140\n"
"in vec4 Position;"
"in vec3 Normal;"
"uniform mat4 ProjectionMatrix, CameraMatrix, ModelMatrix;"
"uniform vec3 LightPos;"
"out vec3 vertNormal;"
"out vec3 vertViewNormal;"
"out vec3 vertLight;"
"void main(void)"
"{"
" gl_Position = ModelMatrix * Position;"
" vertNormal = mat3(ModelMatrix)*Normal;"
" vertViewNormal = mat3(CameraMatrix)*vertNormal;"
" vertLight = LightPos - gl_Position.xyz;"
" gl_Position = ProjectionMatrix * CameraMatrix * gl_Position;"
"}"
);
vs_shape.Compile();
fs_shape.Source(
"#version 140\n"
"in vec3 vertNormal;"
"in vec3 vertViewNormal;"
"in vec3 vertLight;"
"uniform mat4 CameraMatrix;"
"out vec4 fragColor;"
"void main(void)"
"{"
" float ltlen = sqrt(length(vertLight));"
" float ltexp = dot("
" normalize(vertNormal),"
" normalize(vertLight)"
" );"
" float lview = dot("
" normalize(vertLight),"
" normalize(vec3("
" CameraMatrix[0][2],"
" CameraMatrix[1][2],"
" CameraMatrix[2][2] "
" ))"
" );"
" float depth = normalize(vertViewNormal).z;"
" vec3 ftrefl = vec3(0.9, 0.8, 0.7);"
" vec3 scatter = vec3(0.9, 0.6, 0.1);"
" vec3 bklt = vec3(0.8, 0.6, 0.4);"
" vec3 ambient = vec3(0.5, 0.4, 0.3);"
" fragColor = vec4("
" pow(max(ltexp, 0.0), 8.0)*ftrefl+"
" ( ltexp+1.0)/ltlen*pow(depth,2.0)*scatter+"
" (-ltexp+1.0)/ltlen*(1.0-depth)*scatter+"
" (-lview+1.0)*0.6*(1.0-abs(depth))*bklt+"
" 0.2*ambient,"
" 1.0"
" );"
"}"
);
fs_shape.Compile();
shape_prog.AttachShader(vs_shape);
shape_prog.AttachShader(fs_shape);
shape_prog.Link();
vs_plane.Source(
"#version 140\n"
"in vec4 Position;"
"in vec3 Normal;"
"uniform mat4 ProjectionMatrix, CameraMatrix;"
"uniform vec3 LightPos;"
"out vec3 vertNormal;"
"out vec3 vertLight;"
"void main(void)"
"{"
" gl_Position = "
" ProjectionMatrix *"
" CameraMatrix *"
" Position;"
" vertNormal = Normal;"
" vertLight = LightPos-Position.xyz;"
"}"
);
vs_plane.Compile();
fs_plane.Source(
"#version 140\n"
"in vec3 vertNormal;"
"in vec3 vertLight;"
"out vec4 fragColor;"
"void main(void)"
"{"
" float l = sqrt(length(vertLight));"
" float e = dot("
" vertNormal,"
" normalize(vertLight)"
" );"
" float d = l > 0.0 ? e / l : 0.0;"
" float i = 0.2 + 2.5 * d;"
" fragColor = vec4(0.8*i, 0.7*i, 0.4*i, 1.0);"
"}"
);
fs_plane.Compile();
plane_prog.AttachShader(vs_plane);
plane_prog.AttachShader(fs_plane);
plane_prog.Link();
vs_halo.Source(
"#version 150\n"
"in vec4 Position;"
"in vec3 Normal;"
"uniform mat4 ModelMatrix, CameraMatrix;"
"out vec3 vertNormal;"
"out float vd;"
"void main(void)"
"{"
" gl_Position = "
" CameraMatrix *"
" ModelMatrix *"
" Position;"
" vertNormal = ("
" CameraMatrix *"
" ModelMatrix *"
" vec4(Normal, 0.0)"
" ).xyz;"
" vd = vertNormal.z;"
"}"
);
vs_halo.Compile();
gs_halo.Source(
"#version 150\n"
"layout(triangles) in;"
"layout(triangle_strip, max_vertices = 12) out;"
"in vec3 vertNormal[];"
"in float vd[];"
"uniform mat4 CameraMatrix, ProjectionMatrix;"
"uniform vec3 LightPos;"
"out float geomAlpha;"
"void main(void)"
"{"
" for(int v=0; v!=3; ++v)"
" {"
" int a = v, b = (v+1)%3, c = (v+2)%3;"
" vec4 pa = gl_in[a].gl_Position;"
" vec4 pb = gl_in[b].gl_Position;"
" vec4 pc = gl_in[c].gl_Position;"
" vec4 px, py;"
" vec3 na = vertNormal[a];"
" vec3 nb = vertNormal[b];"
" vec3 nc = vertNormal[c];"
" vec3 nx, ny;"
" if(vd[a] == 0.0 && vd[b] == 0.0)"
" {"
" px = pa;"
" nx = na;"
" py = pb;"
" ny = nb;"
" }"
" else if(vd[a] > 0.0 && vd[b] < 0.0)"
" {"
" float x = vd[a]/(vd[a]-vd[b]);"
" float y;"
" px = mix(pa, pb, x);"
" nx = mix(na, nb, x);"
" if(vd[c] < 0.0)"
" {"
" y = vd[a]/(vd[a]-vd[c]);"
" py = mix(pa, pc, y);"
" ny = mix(na, nc, y);"
" }"
" else"
" {"
" y = vd[c]/(vd[c]-vd[b]);"
" py = mix(pc, pb, y);"
" ny = mix(nc, nb, y);"
" }"
" }"
" else continue;"
" vec4 gx1 = vec4(px.xyz, 1.0);"
" vec4 gy1 = vec4(py.xyz, 1.0);"
" vec4 gx2 = vec4(px.xyz + nx*0.3, 1.0);"
" vec4 gy2 = vec4(py.xyz + ny*0.3, 1.0);"
" gl_Position = ProjectionMatrix * gy1;"
" geomAlpha = 1.0;"
" EmitVertex();"
" gl_Position = ProjectionMatrix * gx1;"
" geomAlpha = 1.0;"
" EmitVertex();"
" gl_Position = ProjectionMatrix * gy2;"
" geomAlpha = 0.0;"
" EmitVertex();"
" gl_Position = ProjectionMatrix * gx2;"
" geomAlpha = 0.0;"
" EmitVertex();"
" EndPrimitive();"
" break;"
" }"
"}"
);
gs_halo.Compile();
fs_halo.Source(
"#version 150\n"
"in float geomAlpha;"
"out vec4 fragColor;"
"void main(void)"
"{"
" fragColor = vec4("
" 0.5, 0.4, 0.3,"
" pow(geomAlpha, 2.0)"
" );"
"}"
);
fs_halo.Compile();
halo_prog.AttachShader(vs_halo);
halo_prog.AttachShader(gs_halo);
halo_prog.AttachShader(fs_halo);
halo_prog.Link();
// bind the VAO for the shape
shape.Bind();
// bind the VBO for the shape vertices
shape_verts.Bind(Buffer::Target::Array);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_shape.Positions(data);
Buffer::Data(Buffer::Target::Array, data);
VertexAttribSlot location;
if(VertexArrayAttrib::QueryCommonLocation(
MakeGroup(shape_prog, halo_prog),
"Position",
location
))
{
VertexArrayAttrib attr(location);
attr.Setup<GLfloat>(n_per_vertex);
attr.Enable();
}
else OGLPLUS_ABORT("Inconsistent 'Position' location");
}
// bind the VBO for the shape normals
shape_normals.Bind(Buffer::Target::Array);
{
std::vector<GLfloat> data;
GLuint n_per_vertex = make_shape.Normals(data);
Buffer::Data(Buffer::Target::Array, data);
shape_prog.Use();
VertexArrayAttrib attr(shape_prog, "Normal");
attr.Setup<GLfloat>(n_per_vertex);
attr.Enable();
}
// bind the VAO for the plane
plane.Bind();
// bind the VBO for the plane vertices
plane_verts.Bind(Buffer::Target::Array);
{
GLfloat data[4*3] = {
-9.0f, 0.0f, 9.0f,
-9.0f, 0.0f, -9.0f,
9.0f, 0.0f, 9.0f,
9.0f, 0.0f, -9.0f
};
Buffer::Data(Buffer::Target::Array, 4*3, data);
plane_prog.Use();
VertexArrayAttrib attr(plane_prog, "Position");
attr.Setup<Vec3f>();
attr.Enable();
}
// bind the VBO for the plane normals
plane_normals.Bind(Buffer::Target::Array);
{
GLfloat data[4*3] = {
-0.1f, 1.0f, 0.1f,
-0.1f, 1.0f, -0.1f,
0.1f, 1.0f, 0.1f,
0.1f, 1.0f, -0.1f
};
Buffer::Data(Buffer::Target::Array, 4*3, data);
plane_prog.Use();
VertexArrayAttrib attr(plane_prog, "Normal");
attr.Setup<Vec3f>();
attr.Enable();
}
Vec3f lightPos(2.0f, 2.5f, 9.0f);
ProgramUniform<Vec3f>(shape_prog, "LightPos").Set(lightPos);
ProgramUniform<Vec3f>(plane_prog, "LightPos").Set(lightPos);
gl.ClearColor(0.2f, 0.2f, 0.2f, 0.0f);
gl.ClearDepth(1.0f);
gl.ClearStencil(0);
gl.Enable(Capability::DepthTest);
gl.BlendFunc(BlendFn::SrcAlpha, BlendFn::One);
}
CloudExample(void)
: projection_matrix(prog, "ProjectionMatrix")
, camera_matrix(prog, "CameraMatrix")
{
// Set the vertex shader source
vs.Source(
"#version 330\n"
"in vec4 Position;"
"uniform mat4 CameraMatrix;"
"void main(void)"
"{"
" gl_Position = "
" CameraMatrix *"
" Position;"
"}"
);
// compile it
vs.Compile();
// Set the geometry shader source
gs.Source(
"#version 330\n"
"layout(points) in;"
"layout(triangle_strip, max_vertices = 100) out;"
"const int p = 25;"
"const float hp = (p-1)*0.5;"
"uniform vec3 LightPos;"
"uniform mat4 CameraMatrix, ProjectionMatrix;"
"out vec3 geomTexCoord;"
"out vec3 geomLightDir;"
"void main(void)"
"{"
" float s = 0.6;"
" float yo[2] = float[2](-1.0, 1.0);"
" float xo[2] = float[2](-1.0, 1.0);"
" vec3 cx = vec3("
" CameraMatrix[0][0],"
" CameraMatrix[1][0],"
" CameraMatrix[2][0] "
" );"
" vec3 cy = vec3("
" CameraMatrix[0][1],"
" CameraMatrix[1][1],"
" CameraMatrix[2][1] "
" );"
" vec3 cz = vec3("
" CameraMatrix[0][2],"
" CameraMatrix[1][2],"
" CameraMatrix[2][2] "
" );"
" for(int k=0;k!=p;++k)"
" {"
" for(int j=0;j!=2;++j)"
" for(int i=0;i!=2;++i)"
" {"
" float zo = ((k - hp) / hp);"
" float xoffs = xo[i]*s;"
" float yoffs = yo[j]*s;"
" float zoffs = zo *s;"
" vec4 v = vec4("
" gl_in[0].gl_Position.x+xoffs,"
" gl_in[0].gl_Position.y+yoffs,"
" gl_in[0].gl_Position.z+zoffs,"
" 1.0"
" );"
" gl_Position = ProjectionMatrix * v;"
" geomLightDir = LightPos - v.xyz;"
" geomTexCoord = "
" vec3(0.5, 0.5, 0.5)+"
" cx*(xo[i])*0.707+"
" cy*(yo[j])*0.707+"
" cz*(zo )*0.707;"
" EmitVertex();"
" }"
" EndPrimitive();"
" }"
"}"
);
// compile it
gs.Compile();
// set the fragment shader source
fs.Source(
"#version 330\n"
"uniform sampler3D cloudTex;"
"in vec3 geomTexCoord;"
"in vec3 geomLightDir;"
"out vec4 fragColor;"
"void main(void)"
"{"
" float d = texture(cloudTex, geomTexCoord).r;"
" float o = 1.0;"
" float s = 2.0/128.0;"
" float r = s * 8.0;"
" vec3 sampleOffs = normalize(geomLightDir) * s;"
" vec3 samplePos = geomTexCoord;"
" if(d > 0.01) while(o > 0.0)"
" {"
" if(samplePos.x<0.0 || samplePos.x>1.0)"
" break;"
" if(samplePos.y<0.0 || samplePos.y>1.0)"
" break;"
" if(samplePos.z<0.0 || samplePos.z>1.0)"
" break;"
" o -= texture(cloudTex, samplePos).r*r;"
" samplePos += sampleOffs;"
" }"
" float a = 0.2 * d;"
" float i = mix(0.4, 1.0, o);"
" fragColor = vec4(i, i, i, a);"
"}"
);
// compile it
fs.Compile();
// attach the shaders to the program
prog.AttachShader(vs);
prog.AttachShader(gs);
prog.AttachShader(fs);
// link and use it
prog.Link();
prog.Use();
// bind the VAO for the clouds
clouds.Bind();
// bind the VBO for the cloud positions
buffer.Bind(Buffer::Target::Array);
{
GLfloat positions[3] = {0.5f, 0.1f, 0.2f};
Buffer::Data(Buffer::Target::Array, 3, positions);
VertexAttribArray attr(prog, "Position");
attr.Setup(3, DataType::Float);
attr.Enable();
}
{
Texture::Active(0);
UniformSampler(prog, "cloudTex").Set(0);
auto bound_tex = Bind(cloud_tex, Texture::Target::_3D);
bound_tex.Image3D(images::Cloud(128, 128, 128));
bound_tex.GenerateMipmap();
bound_tex.MinFilter(TextureMinFilter::LinearMipmapLinear);
bound_tex.MagFilter(TextureMagFilter::Linear);
bound_tex.BorderColor(Vec4f(0.0f, 0.0f, 0.0f, 0.0f));
bound_tex.WrapS(TextureWrap::ClampToBorder);
bound_tex.WrapT(TextureWrap::ClampToBorder);
bound_tex.WrapR(TextureWrap::ClampToBorder);
}
Uniform<Vec3f>(prog, "LightPos").Set(Vec3f(10.0f, 1.0f, 5.0f));
gl.ClearColor(0.2f, 0.3f, 0.4f, 0.0f);
gl.ClearDepth(1.0f);
gl.Enable(Capability::DepthTest);
gl.Enable(Capability::Blend);
gl.BlendFunc(BlendFn::SrcAlpha, BlendFn::OneMinusSrcAlpha);
}
