#ifndef SPRITE_LIGHTING_INCLUDED #define SPRITE_LIGHTING_INCLUDED //Check for using mesh normals #if !defined(_FIXED_NORMALS_VIEWSPACE) && !defined(_FIXED_NORMALS_VIEWSPACE_BACKFACE) && !defined(_FIXED_NORMALS_MODELSPACE) && !defined(_FIXED_NORMALS_MODELSPACE_BACKFACE) && !defined(_FIXED_NORMALS_WORLDSPACE) #define MESH_NORMALS #endif //Check for fixing backfacing tangents #if defined(_FIXED_NORMALS_VIEWSPACE_BACKFACE) || defined(_FIXED_NORMALS_MODELSPACE_BACKFACE) #define FIXED_NORMALS_BACKFACE_RENDERING #endif //////////////////////////////////////// // Vertex structs // struct VertexInput { float4 vertex : POSITION; float4 texcoord : TEXCOORD0; float4 color : COLOR; #if defined(MESH_NORMALS) float3 normal : NORMAL; #endif // _FIXED_NORMALS #if defined(_NORMALMAP) float4 tangent : TANGENT; #endif // _NORMALMAP UNITY_VERTEX_INPUT_INSTANCE_ID }; //////////////////////////////////////// // Normal functions // #if !defined(USE_LWRP) && !defined(USE_URP) uniform float4 _FixedNormal = float4(0, 0, 1, 1); #endif inline float3 getFixedNormal() { return _FixedNormal.xyz; } inline float calculateBackfacingSign(float3 worldPos) { //If we're using fixed normals and mesh is facing away from camera, flip tangentSign //Unity uses a left handed coordinate system so camera always looks down the negative z axis float3 cameraForward = float3(0,0,-1); float3 meshWorldForward = mul((float3x3)unity_ObjectToWorld, cameraForward); float3 toCamera = _WorldSpaceCameraPos - worldPos; return sign(dot(toCamera, meshWorldForward)); } inline half3 calculateSpriteWorldNormal(VertexInput vertex, float backFaceSign) { #if defined(MESH_NORMALS) return calculateWorldNormal(vertex.normal); #else // !MESH_NORMALS float3 normal = getFixedNormal(); #if defined(_FIXED_NORMALS_VIEWSPACE) || defined(_FIXED_NORMALS_VIEWSPACE_BACKFACE) //View space fixed normal //Rotate fixed normal by inverse view matrix to convert the fixed normal into world space float3x3 invView = transpose((float3x3)UNITY_MATRIX_V); return normalize(mul(invView, normal)); #elif defined (_FIXED_NORMALS_WORLDSPACE) //World space fixed normal return normal; #else //Model space fixed normal. #if defined(FIXED_NORMALS_BACKFACE_RENDERING) //If back face rendering is enabled and the sprite is facing away from the camera (ie we're rendering the backface) then need to flip the normal normal *= backFaceSign; #endif return calculateWorldNormal(normal); #endif #endif // !MESH_NORMALS } inline half3 calculateSpriteViewNormal(VertexInput vertex, float backFaceSign) { #if defined(MESH_NORMALS) return normalize(mul((float3x3)UNITY_MATRIX_IT_MV, vertex.normal)); #else // !MESH_NORMALS float3 normal = getFixedNormal(); #if defined(_FIXED_NORMALS_VIEWSPACE) || defined(_FIXED_NORMALS_VIEWSPACE_BACKFACE) //View space fixed normal return normal; #elif defined (_FIXED_NORMALS_WORLDSPACE) //World space fixed normal return normalize(mul((float3x3)UNITY_MATRIX_V, normal)); #else //Model space fixed normal #if defined(FIXED_NORMALS_BACKFACE_RENDERING) //If back face rendering is enabled and the sprite is facing away from the camera (ie we're rendering the backface) then need to flip the normal normal *= backFaceSign; #endif return normalize(mul((float3x3)UNITY_MATRIX_IT_MV, normal)); #endif #endif // !MESH_NORMALS } //////////////////////////////////////// // Normal map functions // #if defined(_NORMALMAP) inline half3 calculateSpriteWorldBinormal(VertexInput vertex, half3 normalWorld, half3 tangentWorld, float backFaceSign) { float tangentSign = vertex.tangent.w; #if defined(FIXED_NORMALS_BACKFACE_RENDERING) tangentSign *= backFaceSign; #endif return calculateWorldBinormal(normalWorld, tangentWorld, tangentSign); } #endif // _NORMALMAP #if defined(_DIFFUSE_RAMP) //////////////////////////////////////// // Diffuse ramp functions // uniform sampler2D _DiffuseRamp; inline fixed3 calculateDiffuseRamp(float ramp) { return tex2D(_DiffuseRamp, float2(ramp, ramp)).rgb; } inline fixed3 calculateRampedDiffuse(fixed3 lightColor, float attenuation, float angleDot) { #if defined(_FULLRANGE_HARD_RAMP) float d = angleDot; half3 ramp = calculateDiffuseRamp(d); return lightColor * ramp * attenuation; #elif defined(_FULLRANGE_SOFT_RAMP) float d = angleDot; half3 ramp = calculateDiffuseRamp(d * attenuation); return lightColor * ramp; #elif defined(_OLD_SOFT_RAMP) // for unmodified behaviour with existing projects when // the HARD_DIFFUSE_RAMP define was disabled in this file. // uses only the right half of the ramp texture, as // negative angleDot is clamped to [0,1] before. float d = angleDot * 0.5 + 0.5; half3 ramp = calculateDiffuseRamp(d); return lightColor * ramp * (attenuation * 2); #else // _OLD_HARD_RAMP // old default, for unmodified behaviour with existing projects, // uses only the right half of the ramp texture, as // negative angleDot is clamped to [0,1] before. float d = angleDot * 0.5 + 0.5; half3 ramp = calculateDiffuseRamp(d * attenuation * 2); return lightColor * ramp; #endif } #endif // _DIFFUSE_RAMP //////////////////////////////////////// // Rim Lighting functions // #ifdef _RIM_LIGHTING #if !defined(USE_LWRP) && !defined(USE_URP) uniform float _RimPower; uniform fixed4 _RimColor; #endif inline fixed3 applyRimLighting(fixed3 posWorld, fixed3 normalWorld, fixed4 pixel) : SV_Target { fixed3 viewDir = normalize(_WorldSpaceCameraPos - posWorld); float invDot = 1.0 - saturate(dot(normalWorld, viewDir)); float rimPower = pow(invDot, _RimPower); float rim = saturate(rimPower * _RimColor.a); #if defined(_DIFFUSE_RAMP) rim = calculateDiffuseRamp(rim).r; #endif return lerp(pixel.rgb, _RimColor.xyz * pixel.a, rim); } #endif //_RIM_LIGHTING //////////////////////////////////////// // Emission functions // #ifdef _EMISSION uniform sampler2D _EmissionMap; #if !defined(USE_LWRP) && !defined(USE_URP) uniform fixed4 _EmissionColor; uniform float _EmissionPower; #endif #define APPLY_EMISSION(diffuse, uv) diffuse += tex2D(_EmissionMap, uv).rgb * _EmissionColor.rgb * _EmissionPower; #define APPLY_EMISSION_SPECULAR(pixel, uv) pixel.rgb += (tex2D(_EmissionMap, uv).rgb * _EmissionColor.rgb * _EmissionPower) * pixel.a; #else //!_EMISSION #define APPLY_EMISSION(diffuse, uv) #define APPLY_EMISSION_SPECULAR(pixel, uv) #endif //!_EMISSION #endif // SPRITE_LIGHTING_INCLUDED