// Upgrade NOTE: replaced 'mul(UNITY_MATRIX_MVP,*)' with 'UnityObjectToClipPos(*)' // Upgrade NOTE: replaced 'glstate_matrix_invtrans_modelview0' with 'UNITY_MATRIX_IT_MV' // Upgrade NOTE: replaced 'glstate_matrix_modelview0' with 'UNITY_MATRIX_MV' // Upgrade NOTE: replaced 'glstate_matrix_mvp' with 'UNITY_MATRIX_MVP' // Example shader for a scriptable render loop that calculates multiple lights // in a single forward-rendered shading pass. Uses same PBR shading model as the // Standard shader. // // The parameters and inspector of the shader are the same as Standard shader, // for easier experimentation. Shader "RenderLoop/Batching/Standard8" { // Properties is just a copy of Standard.shader. Our example shader does not use all of them, // but the inspector UI expects all these to exist. Properties { // _Color("Color", Color) = (1,1,1,1) myColor("Color", Color) = (1,1,1,1) myTexture1("Albedo1", 2D) = "white" {} myTexture2("Albedo2", 2D) = "white" {} myTexture3("Albedo3", 2D) = "white" {} myTexture4("Albedo4", 2D) = "white" {} myTexture5("Albedo5", 2D) = "white" {} myTexture6("Albedo6", 2D) = "white" {} myTexture7("Albedo7", 2D) = "white" {} myTexture8("Albedo8", 2D) = "white" {} // [HideInInspector] _Mode("__mode", Float) = 0.0 // [HideInInspector] _SrcBlend("__src", Float) = 1.0 // [HideInInspector] _DstBlend("__dst", Float) = 0.0 // [HideInInspector] _ZWrite("__zw", Float) = 1.0 } SubShader { Tags { "RenderType" = "Opaque" "PerformanceChecks" = "False" } LOD 300 // Multiple lights at once pass, for our example Basic render loop. Pass { Tags { "LightMode" = "BasicPass" } // Use same blending / depth states as Standard shader Blend One Zero ZWrite On CGPROGRAM #pragma target 3.0 #pragma vertex vert #pragma fragment frag //#pragma shader_feature _METALLICGLOSSMAP //#include "UnityCG.cginc" #include "HLSLSupport.cginc" //float4 _Color; // Global lighting data (setup from C# code once per frame). CBUFFER_START(GlobalLightData) // The variables are very similar to built-in unity_LightColor, unity_LightPosition, // unity_LightAtten, unity_SpotDirection as used by the VertexLit shaders, except here // we use world space positions instead of view space. half4 globalLightColor[8]; float4 globalLightPos[8]; float4 globalLightSpotDir[8]; float4 globalLightAtten[8]; int4 globalLightCount; // Global ambient/SH probe, similar to unity_SH* built-in variables. float4 globalSH[7]; CBUFFER_END CBUFFER_START(simplebufferTest) float4 myColor; CBUFFER_END /* CBUFFER_START(UnityPerDraw) // 352 bytes, uploaded per object (even if just position change position ) float4x4 UNITY_MATRIX_MVP; float4x4 UNITY_MATRIX_MV; float4x4 UNITY_MATRIX_IT_MV; float4x4 unity_ObjectToWorld; float4x4 unity_WorldToObject; float4 unity_LODFade; // x is the fade value ranging within [0,1]. y is x quantized into 16 levels float4 unity_WorldTransformParams; // w is usually 1.0, or -1.0 for odd-negative scale transforms CBUFFER_END */ // Compute attenuation & illumination from one light half3 EvaluateOneLight(int idx, float3 positionWS, half3 normalWS, float3 vAlbedo) { // direction to light float3 dirToLight = globalLightPos[idx].xyz; dirToLight -= positionWS * globalLightPos[idx].w; // distance attenuation float att = 1.0; float distSqr = dot(dirToLight, dirToLight); att /= (1.0 + globalLightAtten[idx].z * distSqr); if (globalLightPos[idx].w != 0 && distSqr > globalLightAtten[idx].w) att = 0.0; // set to 0 if outside of range distSqr = max(distSqr, 0.000001); // don't produce NaNs if some vertex position overlaps with the light dirToLight *= rsqrt(distSqr); // spotlight angular attenuation // Fill in light & indirect structures, and evaluate Standard BRDF half3 light = globalLightColor[idx].rgb * att; half3 c = dot(dirToLight, normalWS) * light * vAlbedo; return c; } sampler2D myTexture1; sampler2D myTexture2; sampler2D myTexture3; sampler2D myTexture4; sampler2D myTexture5; sampler2D myTexture6; sampler2D myTexture7; sampler2D myTexture8; // Vertex shader struct v2f // vertex to fragment { float2 uv : TEXCOORD0; float3 positionWS : TEXCOORD1; float3 normalWS : TEXCOORD2; float4 hpos : SV_POSITION; }; struct s2v // stream to vertex { float4 vertex : POSITION; float3 normal : NORMAL; float4 texcoord : TEXCOORD0; }; v2f vert(s2v v) { v2f o; o.uv = v.texcoord.xy; o.hpos = UnityObjectToClipPos(v.vertex); o.positionWS = mul(unity_ObjectToWorld, v.vertex).xyz; o.normalWS = normalize(mul((float3x3)unity_WorldToObject, v.normal)); return o; } // Fragment shader half4 frag(v2f i) : SV_Target { i.normalWS = normalize(i.normalWS); float4 color; float4 diffuseAlbedo = float4(0, 0, 0, 0); diffuseAlbedo += tex2D(myTexture1, i.uv); diffuseAlbedo += tex2D(myTexture2, i.uv); diffuseAlbedo += tex2D(myTexture3, i.uv); diffuseAlbedo += tex2D(myTexture4, i.uv); diffuseAlbedo += tex2D(myTexture5, i.uv); diffuseAlbedo += tex2D(myTexture6, i.uv); diffuseAlbedo += tex2D(myTexture7, i.uv); diffuseAlbedo += tex2D(myTexture8, i.uv); color = half4(EvaluateOneLight(0, i.positionWS, i.normalWS, diffuseAlbedo.rgb * myColor.rgb),1); return color; } ENDCG } } // CustomEditor "StandardShaderGUI" }