当使用 OpenGL 固定函数管道进行顶点设置时,片段程序看起来如何与固定函数顶点设置兼容?我想这通常取决于光源和纹理层等的数量。例如,一个简单的非纹理单光源 goraud 着色片段程序看起来如何取代 GL 的固定功能着色器?
3 回答
您可能有兴趣查看ShaderGen。从描述:
ShaderGen 是一个可以自动生成模拟一组固定函数状态结果的着色器的程序。该工具用于验证第 9 章中描述的固定函数着色器代码。
顺便说一句,如果您将固定功能和 GLSL 混合使用,您很可能会遇到细微的驱动程序问题。这不是进行着色的“最常用的方法”,所以它有一个很好的改变有错误(至少在我尝试它的时候是这样)。如果你需要的工作,太好了!否则,在 GLSL 中编写顶点和片段着色器可能会好得多。据我所知,现代 GPU 的驱动程序无论如何都使用引擎盖下的着色器来执行固定功能。
Gouraud 着色计算顶点着色器中的光,而Phong着色计算片段着色器中的光。
标准的 OpenGL 光照模型是Gouraud 着色模型,带有Blinn-Phong 光照模型(不要与Phong 着色混淆)。
标准的 OpenGL Blinn-Phong光照模型计算如下:
Ka ... ambient material
Kd ... difusse material
Ks ... specular material
La ... ambient light
Ld ... diffuse light
Ls ... specular light
sh ... shininess
N ... norlmal vector
L ... light vector (from the vertex postion to the light)
V ... view vector (from the vertex psotion to the eye)
Id = max(dot(N, L), 0.0);
H = normalize(V + L);
NdotH = max(dot(N, H), 0.0);
Is = (sh + 2.0) * pow(NdotH, sh) / (2.0 * 3.14159265);
fs = Ka*La + Id*Kd*Ld + Is*Ks*Ls;
以下函数计算单个定向 Blinn-Phong 光源:
struct TLightSource
{
vec3 lightDir;
vec3 ambient;
vec3 diffuse;
vec3 specular;
float shininess;
};
uniform TLightSource u_lightSource;
vec3 Light( vec3 eyeV, vec3 N )
{
vec3 lightCol = u_lightSource.ambient;
vec3 L = normalize( -u_lightSource.lightDir );
float NdotL = max( 0.0, dot( N, L ) );
lightCol += NdotL * u_lightSource.diffuse;
vec3 H = normalize( eyeV + L );
float NdotH = max( 0.0, dot( N, H ) );
float kSpecular = ( u_lightSource.shininess + 2.0 ) * pow( NdotH, u_lightSource.shininess ) / ( 2.0 * 3.14159265 );
lightCol += kSpecular * u_lightSource.specular;
return lightCol;
}
另请参阅以下问题的答案:
该函数可以应用于顶点着色器,也可以应用于片段着色器。
gouraud 着色器程序和 phong 着色器程序的完整编码可以在以下 WebGL 示例中找到:
(function loadscene() {
var resize, gl, gouraudDraw, phongDraw, vp_size;
var bufCube, bufSphere, bufTorus;
var sliderScale = 100.0;
function render(delteMS){
var ambient_col = hexToRgb( document.getElementById( "ambient_col" ).value );
var diffuse_col = hexToRgb( document.getElementById( "diffuse_col" ).value );
var specular_col = hexToRgb( document.getElementById( "specular_col" ).value );
var ambient = document.getElementById( "ambient" ).value / sliderScale;
var diffuse = document.getElementById( "diffuse" ).value / sliderScale;
var specular = document.getElementById( "specular" ).value / sliderScale;
var shininess = document.getElementById( "shininess" ).value;
var ambientCol = [ambient_col.r*ambient/256.0, ambient_col.g*ambient/256.0, ambient_col.b*ambient/256.0];
var diffuseCol = [diffuse_col.r*diffuse/256.0, diffuse_col.g*diffuse/256.0, diffuse_col.b*diffuse/256.0];
var specularCol = [specular_col.r*ambient/256.0, specular_col.g*ambient/256.0, specular_col.b*ambient/256.0];
var form = document.getElementById( "form" ).value;
var shading = document.getElementById( "shading" ).value;
Camera.create();
Camera.vp = vp_size;
gl.enable( gl.DEPTH_TEST );
gl.clearColor( 0.0, 0.0, 0.0, 1.0 );
gl.clear( gl.COLOR_BUFFER_BIT | gl.DEPTH_BUFFER_BIT );
gl.enable(gl.CULL_FACE);
gl.cullFace(gl.BACK);
//gl.frontFace(gl.CW);
gl.frontFace(gl.CCW);
var progDraw = shading == 0 ? gouraudDraw : phongDraw;;
// set up draw shader
ShaderProgram.Use( progDraw.prog );
ShaderProgram.SetUniformM44( progDraw.prog, "u_projectionMat44", Camera.Perspective() );
ShaderProgram.SetUniformM44( progDraw.prog, "u_viewMat44", Camera.LookAt() );
ShaderProgram.SetUniformF3( progDraw.prog, "u_lightSource.lightDir", [-1.0, -0.5, -2.0] )
ShaderProgram.SetUniformF3( progDraw.prog, "u_lightSource.ambient", ambientCol )
ShaderProgram.SetUniformF3( progDraw.prog, "u_lightSource.diffuse", diffuseCol )
ShaderProgram.SetUniformF3( progDraw.prog, "u_lightSource.specular", specularCol )
ShaderProgram.SetUniformF1( progDraw.prog, "u_lightSource.shininess", shininess )
var modelMat = IdentityMat44()
modelMat = RotateAxis( modelMat, CalcAng( delteMS, 13.0 ), 0 );
modelMat = RotateAxis( modelMat, CalcAng( delteMS, 17.0 ), 1 );
ShaderProgram.SetUniformM44( progDraw.prog, "u_modelMat44", modelMat );
// draw scene
bufObj = form == 0 ? bufCube : form == 1 ? bufSphere : bufTorus;
VertexBuffer.Draw( bufObj );
requestAnimationFrame(render);
}
function resize() {
//vp_size = [gl.drawingBufferWidth, gl.drawingBufferHeight];
vp_size = [window.innerWidth, window.innerHeight]
canvas.width = vp_size[0];
canvas.height = vp_size[1];
gl.viewport( 0, 0, vp_size[0], vp_size[1] );
}
function initScene() {
document.getElementById( "ambient_col" ).value = "#FFFFFF";
document.getElementById( "diffuse_col" ).value = "#FFFFFF";
document.getElementById( "specular_col" ).value = "#FFFFFF";
document.getElementById( "ambient" ).value = 0.2 * sliderScale;
document.getElementById( "diffuse" ).value = 0.6 * sliderScale;
document.getElementById( "specular" ).value = 0.8 * sliderScale;
document.getElementById( "shininess" ).value = 25.0;
document.getElementById( "shading" ).value = 0;
document.getElementById( "form" ).value = 1;
canvas = document.getElementById( "canvas");
gl = canvas.getContext( "experimental-webgl" );
if ( !gl )
return null;
gouraudDraw = {}
gouraudDraw.prog = ShaderProgram.Create(
[ { source : "gouraud-shader-vs", stage : gl.VERTEX_SHADER },
{ source : "gouraud-shader-fs", stage : gl.FRAGMENT_SHADER }
],
[ "u_projectionMat44", "u_viewMat44", "u_modelMat44",
"u_lightSource.lightDir", "u_lightSource.ambient", "u_lightSource.diffuse", "u_lightSource.specular", "u_lightSource.shininess", ] );
if ( gouraudDraw.prog == 0 )
return;
gouraudDraw.inPos = gl.getAttribLocation( gouraudDraw.prog, "inPos" );
gouraudDraw.inNV = gl.getAttribLocation( gouraudDraw.prog, "inNV" );
gouraudDraw.inCol = gl.getAttribLocation( gouraudDraw.prog, "inCol" );
phongDraw = {}
phongDraw.prog = ShaderProgram.Create(
[ { source : "phong-shader-vs", stage : gl.VERTEX_SHADER },
{ source : "phong-shader-fs", stage : gl.FRAGMENT_SHADER }
],
[ "u_projectionMat44", "u_viewMat44", "u_modelMat44",
"u_lightSource.lightDir", "u_lightSource.ambient", "u_lightSource.diffuse", "u_lightSource.specular", "u_lightSource.shininess", ] );
if ( phongDraw.prog == 0 )
return;
phongDraw.inPos = gl.getAttribLocation( phongDraw.prog, "inPos" );
phongDraw.inNV = gl.getAttribLocation( phongDraw.prog, "inNV" );
phongDraw.inCol = gl.getAttribLocation( phongDraw.prog, "inCol" );
// create cube
var cubePos = [
-1.0, -1.0, 1.0, 1.0, -1.0, 1.0, 1.0, 1.0, 1.0, -1.0, 1.0, 1.0,
-1.0, -1.0, -1.0, 1.0, -1.0, -1.0, 1.0, 1.0, -1.0, -1.0, 1.0, -1.0 ];
var cubeCol = [ 1.0, 0.0, 0.0, 1.0, 0.5, 0.0, 1.0, 0.0, 1.0, 1.0, 1.0, 0.0, 0.0, 1.0, 0.0, 0.0, 0.0, 1.0 ];
var cubeHlpInx = [ 0, 1, 2, 3, 1, 5, 6, 2, 5, 4, 7, 6, 4, 0, 3, 7, 3, 2, 6, 7, 1, 0, 4, 5 ];
var cubePosData = [];
for ( var i = 0; i < cubeHlpInx.length; ++ i ) {
cubePosData.push( cubePos[cubeHlpInx[i]*3], cubePos[cubeHlpInx[i]*3+1], cubePos[cubeHlpInx[i]*3+2] );
}
var cubeNVData = [];
for ( var i1 = 0; i1 < cubeHlpInx.length; i1 += 4 ) {
var nv = [0, 0, 0];
for ( i2 = 0; i2 < 4; ++ i2 ) {
var i = i1 + i2;
nv[0] += cubePosData[i*3]; nv[1] += cubePosData[i*3+1]; nv[2] += cubePosData[i*3+2];
}
for ( i2 = 0; i2 < 4; ++ i2 )
cubeNVData.push( nv[0], nv[1], nv[2] );
}
var cubeColData = [];
for ( var is = 0; is < 6; ++ is ) {
for ( var ip = 0; ip < 4; ++ ip ) {
cubeColData.push( cubeCol[is*3], cubeCol[is*3+1], cubeCol[is*3+2] );
}
}
var cubeInxData = [];
for ( var i = 0; i < cubeHlpInx.length; i += 4 ) {
cubeInxData.push( i, i+1, i+2, i, i+2, i+3 );
}
bufCube = VertexBuffer.Create(
[ { data : cubePosData, attrSize : 3, attrLoc : gouraudDraw.inPos },
{ data : cubeNVData, attrSize : 3, attrLoc : gouraudDraw.inNV },
{ data : cubeColData, attrSize : 3, attrLoc : gouraudDraw.inCol } ],
cubeInxData );
// create sphere
var layer_size = 16, circum_size = 32;
var rad_circum = 1.0;
var rad_tube = 0.5;
var sphere_pts = [];
var sphere_nv = [];
var sphere_col = [];
sphere_pts.push( 0.0, 0.0, -2.0 );
sphere_nv.push( 0.0, 0.0, -1.0 );
//sphere_col.push( 0.8, 0.6, 0.3 );
sphere_col.push( 0.75, 0.75, 0.75 );
for ( var i_l = 1; i_l < layer_size; ++ i_l ) {
var angH = (1.0 - i_l / layer_size) * Math.PI;
var h = Math.cos( angH );
var r = Math.sin( angH );
for ( var i_c = 0; i_c < circum_size; ++ i_c ) {
var circumX = Math.cos(2 * Math.PI * i_c / circum_size);
var circumY = Math.sin(2 * Math.PI * i_c / circum_size);
sphere_pts.push( r * circumX * 2.0, r * circumY * 2.0, h * 2.0 );
sphere_nv.push( r * circumX, r * circumY, h );
//sphere_col.push( 0.8, 0.6, 0.3 );
sphere_col.push( 0.75, 0.75, 0.75 );
}
}
sphere_pts.push( 0.0, 0.0, 2.0 );
sphere_nv.push( 0.0, 0.0, 1.0 );
//sphere_col.push( 0.8, 0.6, 0.3 );
sphere_col.push( 0.75, 0.75, 0.75 );
var sphere_inx = [];
for ( var i_c = 0; i_c < circum_size; ++ i_c ) {
sphere_inx.push( i_c+1, 0, (i_c+1) % circum_size + 1 )
}
for ( var i_l = 0; i_l < layer_size-2; ++ i_l ) {
var l1 = i_l * circum_size + 1;
var l2 = (i_l+1) * circum_size + 1
for ( var i_c = 0; i_c < circum_size; ++ i_c ) {
var i_n = (i_c+1) % circum_size;
sphere_inx.push( l1+i_c, l1+i_n, l2+i_c, l1+i_n, l2+i_n, l2+i_c );
}
}
for ( var i_c = 0; i_c < circum_size; ++ i_c ) {
var i_start = 1 + (layer_size-2) * circum_size;
var i_n = (i_c+1) % circum_size;
sphere_inx.push( i_start + i_c, i_start + i_n, sphere_pts.length/3-1 );
}
bufSphere = VertexBuffer.Create(
[ { data : sphere_pts, attrSize : 3, attrLoc : gouraudDraw.inPos },
{ data : sphere_nv, attrSize : 3, attrLoc : gouraudDraw.inNV },
{ data : sphere_col, attrSize : 3, attrLoc : gouraudDraw.inCol } ],
sphere_inx );
// create torus
var circum_size = 32, tube_size = 32;
var rad_circum = 1.4;
var rad_tube = 0.6;
var torus_pts = [];
var torus_nv = [];
var torus_col = [];
var torus_inx = [];
var col = [1, 0.5, 0.0];
for ( var i_c = 0; i_c < circum_size; ++ i_c ) {
var center = [
Math.cos(2 * Math.PI * i_c / circum_size),
Math.sin(2 * Math.PI * i_c / circum_size) ]
for ( var i_t = 0; i_t < tube_size; ++ i_t ) {
var tubeX = Math.cos(2 * Math.PI * i_t / tube_size)
var tubeY = Math.sin(2 * Math.PI * i_t / tube_size)
var pt = [
center[0] * ( rad_circum + tubeX * rad_tube ),
center[1] * ( rad_circum + tubeX * rad_tube ),
tubeY * rad_tube ]
var nv = [ pt[0] - center[0] * rad_tube, pt[1] - center[1] * rad_tube, tubeY * rad_tube ]
torus_pts.push( pt[0], pt[1], pt[2] );
torus_nv.push( nv[0], nv[1], nv[2] );
torus_col.push( col[0], col[1], col[2] );
var i_cn = (i_c+1) % circum_size
var i_tn = (i_t+1) % tube_size
var i_c0 = i_c * tube_size;
var i_c1 = i_cn * tube_size;
torus_inx.push( i_c0+i_t, i_c1+i_t, i_c0+i_tn, i_c0+i_tn, i_c1+i_t, i_c1+i_tn )
}
}
bufTorus = VertexBuffer.Create(
[ { data : torus_pts, attrSize : 3, attrLoc : gouraudDraw.inPos },
{ data : torus_nv, attrSize : 3, attrLoc : gouraudDraw.inNV },
{ data : torus_col, attrSize : 3, attrLoc : gouraudDraw.inCol } ],
torus_inx );
window.onresize = resize;
resize();
requestAnimationFrame(render);
}
function Fract( val ) {
return val - Math.trunc( val );
}
function CalcAng( deltaTime, intervall ) {
return Fract( deltaTime / (1000*intervall) ) * 2.0 * Math.PI;
}
function CalcMove( deltaTime, intervall, range ) {
var pos = self.Fract( deltaTime / (1000*intervall) ) * 2.0
var pos = pos < 1.0 ? pos : (2.0-pos)
return range[0] + (range[1] - range[0]) * pos;
}
function EllipticalPosition( a, b, angRag ) {
var a_b = a * a - b * b
var ea = (a_b <= 0) ? 0 : Math.sqrt( a_b );
var eb = (a_b >= 0) ? 0 : Math.sqrt( -a_b );
return [ a * Math.sin( angRag ) - ea, b * Math.cos( angRag ) - eb, 0 ];
}
glArrayType = typeof Float32Array !="undefined" ? Float32Array : ( typeof WebGLFloatArray != "undefined" ? WebGLFloatArray : Array );
function IdentityMat44() {
var m = new glArrayType(16);
m[0] = 1; m[1] = 0; m[2] = 0; m[3] = 0;
m[4] = 0; m[5] = 1; m[6] = 0; m[7] = 0;
m[8] = 0; m[9] = 0; m[10] = 1; m[11] = 0;
m[12] = 0; m[13] = 0; m[14] = 0; m[15] = 1;
return m;
};
function RotateAxis(matA, angRad, axis) {
var aMap = [ [1, 2], [2, 0], [0, 1] ];
var a0 = aMap[axis][0], a1 = aMap[axis][1];
var sinAng = Math.sin(angRad), cosAng = Math.cos(angRad);
var matB = new glArrayType(16);
for ( var i = 0; i < 16; ++ i ) matB[i] = matA[i];
for ( var i = 0; i < 3; ++ i ) {
matB[a0*4+i] = matA[a0*4+i] * cosAng + matA[a1*4+i] * sinAng;
matB[a1*4+i] = matA[a0*4+i] * -sinAng + matA[a1*4+i] * cosAng;
}
return matB;
}
function Cross( a, b ) { return [ a[1] * b[2] - a[2] * b[1], a[2] * b[0] - a[0] * b[2], a[0] * b[1] - a[1] * b[0], 0.0 ]; }
function Dot( a, b ) { return a[0]*b[0] + a[1]*b[1] + a[2]*b[2]; }
function Normalize( v ) {
var len = Math.sqrt( v[0] * v[0] + v[1] * v[1] + v[2] * v[2] );
return [ v[0] / len, v[1] / len, v[2] / len ];
}
var Camera = {};
Camera.create = function() {
this.pos = [0, 3, 0.0];
this.target = [0, 0, 0];
this.up = [0, 0, 1];
this.fov_y = 90;
this.vp = [800, 600];
this.near = 0.5;
this.far = 100.0;
}
Camera.Perspective = function() {
var fn = this.far + this.near;
var f_n = this.far - this.near;
var r = this.vp[0] / this.vp[1];
var t = 1 / Math.tan( Math.PI * this.fov_y / 360 );
var m = IdentityMat44();
m[0] = t/r; m[1] = 0; m[2] = 0; m[3] = 0;
m[4] = 0; m[5] = t; m[6] = 0; m[7] = 0;
m[8] = 0; m[9] = 0; m[10] = -fn / f_n; m[11] = -1;
m[12] = 0; m[13] = 0; m[14] = -2 * this.far * this.near / f_n; m[15] = 0;
return m;
}
Camera.LookAt = function() {
var mz = Normalize( [ this.pos[0]-this.target[0], this.pos[1]-this.target[1], this.pos[2]-this.target[2] ] );
var mx = Normalize( Cross( this.up, mz ) );
var my = Normalize( Cross( mz, mx ) );
var tx = Dot( mx, this.pos );
var ty = Dot( my, this.pos );
var tz = Dot( [-mz[0], -mz[1], -mz[2]], this.pos );
var m = IdentityMat44();
m[0] = mx[0]; m[1] = my[0]; m[2] = mz[0]; m[3] = 0;
m[4] = mx[1]; m[5] = my[1]; m[6] = mz[1]; m[7] = 0;
m[8] = mx[2]; m[9] = my[2]; m[10] = mz[2]; m[11] = 0;
m[12] = tx; m[13] = ty; m[14] = tz; m[15] = 1;
return m;
}
var ShaderProgram = {};
ShaderProgram.Create = function( shaderList ) {
var shaderObjs = [];
for ( var i_sh = 0; i_sh < shaderList.length; ++ i_sh ) {
var shderObj = this.CompileShader( shaderList[i_sh].source, shaderList[i_sh].stage );
if ( shderObj == 0 )
return 0;
shaderObjs.push( shderObj );
}
var progObj = this.LinkProgram( shaderObjs )
if ( progObj != 0 ) {
progObj.attribIndex = {};
var noOfAttributes = gl.getProgramParameter( progObj, gl.ACTIVE_ATTRIBUTES );
for ( var i_n = 0; i_n < noOfAttributes; ++ i_n ) {
var name = gl.getActiveAttrib( progObj, i_n ).name;
progObj.attribIndex[name] = gl.getAttribLocation( progObj, name );
}
progObj.unifomLocation = {};
var noOfUniforms = gl.getProgramParameter( progObj, gl.ACTIVE_UNIFORMS );
for ( var i_n = 0; i_n < noOfUniforms; ++ i_n ) {
var name = gl.getActiveUniform( progObj, i_n ).name;
progObj.unifomLocation[name] = gl.getUniformLocation( progObj, name );
}
}
return progObj;
}
ShaderProgram.AttributeIndex = function( progObj, name ) { return progObj.attribIndex[name]; }
ShaderProgram.UniformLocation = function( progObj, name ) { return progObj.unifomLocation[name]; }
ShaderProgram.Use = function( progObj ) { gl.useProgram( progObj ); }
ShaderProgram.SetUniformI1 = function( progObj, name, val ) { if(progObj.unifomLocation[name]) gl.uniform1i( progObj.unifomLocation[name], val ); }
ShaderProgram.SetUniformF1 = function( progObj, name, val ) { if(progObj.unifomLocation[name]) gl.uniform1f( progObj.unifomLocation[name], val ); }
ShaderProgram.SetUniformF2 = function( progObj, name, arr ) { if(progObj.unifomLocation[name]) gl.uniform2fv( progObj.unifomLocation[name], arr ); }
ShaderProgram.SetUniformF3 = function( progObj, name, arr ) { if(progObj.unifomLocation[name]) gl.uniform3fv( progObj.unifomLocation[name], arr ); }
ShaderProgram.SetUniformF4 = function( progObj, name, arr ) { if(progObj.unifomLocation[name]) gl.uniform4fv( progObj.unifomLocation[name], arr ); }
ShaderProgram.SetUniformM33 = function( progObj, name, mat ) { if(progObj.unifomLocation[name]) gl.uniformMatrix3fv( progObj.unifomLocation[name], false, mat ); }
ShaderProgram.SetUniformM44 = function( progObj, name, mat ) { if(progObj.unifomLocation[name]) gl.uniformMatrix4fv( progObj.unifomLocation[name], false, mat ); }
ShaderProgram.CompileShader = function( source, shaderStage ) {
var shaderScript = document.getElementById(source);
if (shaderScript)
source = shaderScript.text;
var shaderObj = gl.createShader( shaderStage );
gl.shaderSource( shaderObj, source );
gl.compileShader( shaderObj );
var status = gl.getShaderParameter( shaderObj, gl.COMPILE_STATUS );
if ( !status ) alert(gl.getShaderInfoLog(shaderObj));
return status ? shaderObj : null;
}
ShaderProgram.LinkProgram = function( shaderObjs ) {
var prog = gl.createProgram();
for ( var i_sh = 0; i_sh < shaderObjs.length; ++ i_sh )
gl.attachShader( prog, shaderObjs[i_sh] );
gl.linkProgram( prog );
status = gl.getProgramParameter( prog, gl.LINK_STATUS );
if ( !status ) alert("Could not initialise shaders");
gl.useProgram( null );
return status ? prog : null;
}
var VertexBuffer = {};
VertexBuffer.Create = function( attributes, indices ) {
var buffer = {};
buffer.buf = [];
buffer.attr = []
for ( var i = 0; i < attributes.length; ++ i ) {
buffer.buf.push( gl.createBuffer() );
buffer.attr.push( { size : attributes[i].attrSize, loc : attributes[i].attrLoc } );
gl.bindBuffer( gl.ARRAY_BUFFER, buffer.buf[i] );
gl.bufferData( gl.ARRAY_BUFFER, new Float32Array( attributes[i].data ), gl.STATIC_DRAW );
}
buffer.inx = gl.createBuffer();
gl.bindBuffer( gl.ELEMENT_ARRAY_BUFFER, buffer.inx );
gl.bufferData( gl.ELEMENT_ARRAY_BUFFER, new Uint16Array( indices ), gl.STATIC_DRAW );
buffer.inxLen = indices.length;
gl.bindBuffer( gl.ARRAY_BUFFER, null );
gl.bindBuffer( gl.ELEMENT_ARRAY_BUFFER, null );
return buffer;
}
VertexBuffer.Draw = function( bufObj ) {
for ( var i = 0; i < bufObj.buf.length; ++ i ) {
gl.bindBuffer( gl.ARRAY_BUFFER, bufObj.buf[i] );
gl.vertexAttribPointer( bufObj.attr[i].loc, bufObj.attr[i].size, gl.FLOAT, false, 0, 0 );
gl.enableVertexAttribArray( bufObj.attr[i].loc );
}
gl.bindBuffer( gl.ELEMENT_ARRAY_BUFFER, bufObj.inx );
gl.drawElements( gl.TRIANGLES, bufObj.inxLen, gl.UNSIGNED_SHORT, 0 );
for ( var i = 0; i < bufObj.buf.length; ++ i )
gl.disableVertexAttribArray( bufObj.attr[i].loc );
gl.bindBuffer( gl.ARRAY_BUFFER, null );
gl.bindBuffer( gl.ELEMENT_ARRAY_BUFFER, null );
}
function hexToRgb (hex) {
// Expand shorthand form (e.g. "03F") to full form (e.g. "0033FF")
var shorthandRegex = /^#?([a-f\d])([a-f\d])([a-f\d])$/i;
hex = hex.replace(shorthandRegex, function(m, r, g, b) {
return r + r + g + g + b + b;
});
var result = /^#?([a-f\d]{2})([a-f\d]{2})([a-f\d]{2})$/i.exec(hex);
return result ? {
r: parseInt(result[1], 16),
g: parseInt(result[2], 16),
b: parseInt(result[3], 16)
} : null;
}
initScene();
})();
<style>
html,body { margin: 0; overflow: hidden; }
#gui { position : absolute; top : 0; left : 0; }
</style>
<script id="gouraud-shader-vs" type="x-shader/x-vertex">
precision mediump float;
attribute vec3 inPos;
attribute vec3 inNV;
attribute vec3 inCol;
varying vec3 vertPos;
varying vec3 vertNV;
varying vec3 vertCol;
uniform mat4 u_projectionMat44;
uniform mat4 u_viewMat44;
uniform mat4 u_modelMat44;
struct TLightSource
{
vec3 lightDir;
vec3 ambient;
vec3 diffuse;
vec3 specular;
float shininess;
};
uniform TLightSource u_lightSource;
vec3 Light( vec3 eyeV, vec3 N )
{
vec3 lightCol = u_lightSource.ambient;
vec3 L = normalize( -u_lightSource.lightDir );
float NdotL = max( 0.0, dot( N, L ) );
lightCol += NdotL * u_lightSource.diffuse;
vec3 H = normalize( eyeV + L );
float NdotH = max( 0.0, dot( N, H ) );
float kSpecular = ( u_lightSource.shininess + 2.0 ) * pow( NdotH, u_lightSource.shininess ) / ( 2.0 * 3.14159265 );
lightCol += kSpecular * u_lightSource.specular;
return lightCol;
}
void main()
{
vec3 modelNV = mat3( u_modelMat44 ) * normalize( inNV );
vertNV = mat3( u_viewMat44 ) * modelNV;
vec4 modelPos = u_modelMat44 * vec4( inPos, 1.0 );
vec4 viewPos = u_viewMat44 * modelPos;
vertPos = viewPos.xyz / viewPos.w;
vec3 eyeV = normalize( -vertPos );
vec3 normalV = normalize( vertNV );
vertCol = inCol * Light( eyeV, normalV );
gl_Position = u_projectionMat44 * viewPos;
}
</script>
<script id="gouraud-shader-fs" type="x-shader/x-fragment">
precision mediump float;
varying vec3 vertPos;
varying vec3 vertNV;
varying vec3 vertCol;
void main()
{
gl_FragColor = vec4( vertCol, 1.0 );
}
</script>
<script id="phong-shader-vs" type="x-shader/x-vertex">
precision mediump float;
attribute vec3 inPos;
attribute vec3 inNV;
attribute vec3 inCol;
varying vec3 vertPos;
varying vec3 vertNV;
varying vec3 vertCol;
uniform mat4 u_projectionMat44;
uniform mat4 u_viewMat44;
uniform mat4 u_modelMat44;
void main()
{
vec3 modelNV = mat3( u_modelMat44 ) * normalize( inNV );
vertNV = mat3( u_viewMat44 ) * modelNV;
vertCol = inCol;
vec4 modelPos = u_modelMat44 * vec4( inPos, 1.0 );
vec4 viewPos = u_viewMat44 * modelPos;
vertPos = viewPos.xyz / viewPos.w;
gl_Position = u_projectionMat44 * viewPos;
}
</script>
<script id="phong-shader-fs" type="x-shader/x-fragment">
precision mediump float;
varying vec3 vertPos;
varying vec3 vertNV;
varying vec3 vertCol;
struct TLightSource
{
vec3 lightDir;
vec3 ambient;
vec3 diffuse;
vec3 specular;
float shininess;
};
uniform TLightSource u_lightSource;
vec3 Light( vec3 eyeV, vec3 N )
{
vec3 lightCol = u_lightSource.ambient;
vec3 L = normalize( -u_lightSource.lightDir );
float NdotL = max( 0.0, dot( N, L ) );
lightCol += NdotL * u_lightSource.diffuse;
vec3 H = normalize( eyeV + L );
float NdotH = max( 0.0, dot( N, H ) );
float kSpecular = ( u_lightSource.shininess + 2.0 ) * pow( NdotH, u_lightSource.shininess ) / ( 2.0 * 3.14159265 );
lightCol += kSpecular * u_lightSource.specular;
return lightCol;
}
void main()
{
vec3 eyeV = normalize( -vertPos );
vec3 normalV = normalize( vertNV );
vec3 color = vertCol * Light( eyeV, normalV );
gl_FragColor = vec4( color, 1.0 );
}
</script>
<div>
<form id="gui" name="inputs">
<table>
<tr> <td> <font color= #CCF>ambient</font> </td>
<td> <input type="color" id="ambient_col"></td>
<td> <input type="range" id="ambient" min="0" max="100" value="0"/></td> </tr>
<tr> <td> <font color= #CCF>diffuse</font> </td>
<td> <input type="color" id="diffuse_col"></td>
<td> <input type="range" id="diffuse" min="0" max="100" value="0"/></td> </tr>
<tr> <td> <font color= #CCF>specular</font> </td>
<td> <input type="color" id="specular_col"></td>
<td> <input type="range" id="specular" min="0" max="100" value="0"/></td> </tr>
<tr> <td> <font color= #CCF>shininess</font> </td>
<td> <input type="range" id="shininess" min="0" max="100" value="0"/></td> </tr>
<tr> <td> <font color= #CCF>form</font> </td> <td>
<select id="form">>
<option value="0">cube</option>
<option value="1">sphere</option>
<option value="2">torus</option>
</select>
</td> </tr>
<tr> <td> <font color= #CCF>shading</font> </td> <td>
<select id="shading">>
<option value="0">gouraud</option>
<option value="1">phong</option>
</select>
</td> </tr>
</table>
</form>
</div>
<canvas id="canvas" style="border: none;"></canvas>
好吧,在普通的 GL 固定功能管线中,光照和 goraud 着色完全在管线的顶点阶段完成(在光栅化器的帮助下),所以如果你没有纹理,片段着色器就变成了一个简单的 pass -through ( gl_FragColor = gl_Color;
) 并且实际上并没有做任何事情。
现在你可以通过编写你自己的片段着色器来实现每个片段的光照,如果你想要定向聚光灯或类似的东西,这样做甚至可能是有意义的,但这与固定功能管道无关。