path: root/VRCSDK3AvatarsLegacy/Assets/_PoiyomiShaders/Shaders/Patreon/ShatterWave2/ShatterPass.cginc

#if !defined(MY_LIGHTING_INCLUDED)
    #define MY_LIGHTING_INCLUDED
    
    #include "UnityCG.cginc"
    #include "Lighting.cginc"
    #include "UnityPBSLighting.cginc"
    #include "AutoLight.cginc"
    #include "PoiShatterHelpers.cginc"
    
    //Structs
    struct appdata
    {
        float4 vertex: POSITION;
        float3 normal: NORMAL;
        float4 tangent: TANGENT;
        float2 texcoord: TEXCOORD0;
        float2 texcoord1: TEXCOORD1;
    };
    
    struct v2g
    {
        float2 uv: TEXCOORD0;
        float3 normal: TEXCOORD1;
        #if defined(BINORMAL_PER_FRAGMENT)
            float4 tangent: TEXCOORD2;
        #else
            float3 tangent: TEXCOORD2;
            float3 binormal: TEXCOORD3;
        #endif
        float4 pos: SV_POSITION;
        float4 worldPos: TEXCOORD4;
        float4 localPos: TEXCOORD5;
        SHADOW_COORDS(6)
    };
    
    struct g2f
    {
        float2 uv: TEXCOORD0;
        float3 normal: TEXCOORD1;
        #if defined(BINORMAL_PER_FRAGMENT)
            float4 tangent: TEXCOORD2;
        #else
            float3 tangent: TEXCOORD2;
            float3 binormal: TEXCOORD3;
        #endif
        float4 pos: SV_POSITION;
        float4 worldPos: TEXCOORD4;
        float4 localPos: TEXCOORD5;
        float4 waveSettings: TEXCOORD6;
        SHADOW_COORDS(7)
    };
    
    //Properties
    float4 _Color;
    float _Desaturation;
    sampler2D _MainTex; float4 _MainTex_ST;
    sampler2D _BumpMap; float4 _BumpMap_ST;
    sampler2D _DetailNormalMap; float4 _DetailNormalMap_ST;
    float _BumpScale;
    float _DetailNormalMapScale;
    
    sampler2D _WaveTexture; float4 _WaveTexture_ST;
    sampler2D _UnderWaveTexture; float4 _UnderWaveTexture_ST;
    float _ShowUnderWave;
    float4 _WaveSpeed;
    float4 _WaveSlope;
    float4 _WaveDensity;
    
    float _HeightThreshold;
    float4 _WaveColor;
    float _WaveEmission;
    float _UnderWaveEmission;
    float4 _underWaveColor;
    float _WaveHeight;
    
    samplerCUBE _CubeMap;
    float _SampleWorld;
    float _AdditiveClearCoat;
    float _PurelyAdditive;
    sampler2D _MetallicMap; float4 _MetallicMap_ST;
    float _Metallic;
    sampler2D _RoughnessMap; float4 _RoughnessMap_ST;
    float _Roughness;
    
    sampler2D _Matcap;
    sampler2D _MatcapMap; float4 _MatcapMap_ST;
    float4 _MatcapColor;
    float  _MatcapStrength;
    float _ReplaceWithMatcap;
    float _MultiplyMatcap;
    float _AddMatcap;
    
    sampler2D _SpecularMap; float4 _SpecularMap_ST;
    float _Gloss;
    float4 _EmissionColor;
    sampler2D _EmissionMap; float4 _EmissionMap_ST;
    sampler2D _EmissionMask; float4 _EmissionMask_ST;
    float _EmissionStrength;
    
    float4 _EmissiveScroll_Direction;
    float4 _EmissionScrollSpeed;
    float _EmissiveScroll_Width;
    float _EmissiveScroll_Velocity;
    float _EmissiveScroll_Interval;
    float _EmissiveBlink_Min;
    float _EmissiveBlink_Max;
    float _EmissiveBlink_Velocity;
    float _ScrollingEmission;
    
    sampler2D _Ramp;
    float _ForceLightDirection;
    float _ShadowStrength;
    float _ShadowOffset;
    float3 _LightDirection;
    float _ForceShadowStrength;
    float _MinBrightness;
    float _MaxDirectionalIntensity;
    sampler2D _AdditiveRamp;
    float _FlatOrFullAmbientLighting;
    
    float4 _SpecularColor;
    float _SpecularBias;
    float _SpecularStrength;
    float _SpecularSize;
    float _HardSpecular;
    
    float4 _RimLightColor;
    float _RimWidth;
    float _RimStrength;
    float _RimSharpness;
    float _RimLightColorBias;
    float4 _RimTexPanSpeed;
    sampler2D _RimTex; float4 _RimTex_ST;
    
    float _Clip;
    
    float3 getCameraPosition()
    {
        #ifdef USING_STEREO_MATRICES
            return lerp(unity_StereoWorldSpaceCameraPos[0], unity_StereoWorldSpaceCameraPos[1], 0.5);
        #endif
        return _WorldSpaceCameraPos;
    }
    
    float3 getCameraForward()
    {
        #if UNITY_SINGLE_PASS_STEREO
            float3 p1 = mul(unity_StereoCameraToWorld[0], float4(0, 0, 1, 1));
            float3 p2 = mul(unity_StereoCameraToWorld[0], float4(0, 0, 0, 1));
        #else
            float3 p1 = mul(unity_CameraToWorld, float4(0, 0, 1, 1));
            float3 p2 = mul(unity_CameraToWorld, float4(0, 0, 0, 1));
        #endif
        return normalize(p2 - p1);
    }
    
    v2g vert(appdata v)
    {
        v2g o;
        TANGENT_SPACE_ROTATION;
        o.localPos = v.vertex;
        o.pos = UnityObjectToClipPos(v.vertex);
        o.worldPos = mul(unity_ObjectToWorld, v.vertex);
        o.uv = v.texcoord.xy;
        o.normal = UnityObjectToWorldNormal(v.normal);
        
        #if defined(BINORMAL_PER_FRAGMENT)
            o.tangent = float4(UnityObjectToWorldDir(v.tangent.xyz), v.tangent.w);
        #else
            o.tangent = UnityObjectToWorldDir(v.tangent.xyz);
            o.binormal = CreateBinormal(o.normal, o.tangent, v.tangent.w);
        #endif
        
        TRANSFER_SHADOW(i);
        return o;
    }
    
    float3 WaveHeight(float3 position)
    {
        return(sin(
            2 * pow(((sin((position.x + _Time.x * _WaveSpeed.x) * _WaveDensity.x + sin(_Time.y * _WaveSpeed.x)) + 1) / 2), _WaveSlope.x) +
            2 * pow(((sin((position.y + _Time.x * _WaveSpeed.y) * _WaveDensity.y + sin(_Time.y * _WaveSpeed.y)) + 1) / 2), _WaveSlope.y) +
            2 * pow(((sin((position.z + _Time.x * _WaveSpeed.z) * _WaveDensity.z + sin(_Time.y * _WaveSpeed.z)) + 1) / 2), _WaveSlope.z)
        ) + 1) / 2;
    }
    
    [maxvertexcount(6)]
    void geom(triangle v2g IN[3], inout TriangleStream < g2f > tristream)
    {
        float4 mid = (IN[0].localPos + IN[1].localPos + IN[2].localPos) / 3;
        float4 objectPosition = mul(unity_ObjectToWorld, float4(0, 0, 0, 1));
        float4 WavePosition = objectPosition;
        
        float hash = random(mid);
        
        float distanceToWave = clamp(WaveHeight(mid.xyz), 0, 1);
        if (distanceToWave <= _HeightThreshold)
        {
            distanceToWave = 0;
        }
        
        float range = 1 - _HeightThreshold;
        float delta = 1 - distanceToWave;
        float percent = delta / range;
        percent = saturate(percent);
        
        if(percent == 0)
            return;
        
        g2f o;
        g2f milk[3];
        float count = 0;
        
        float3 edgeA = IN[1].localPos - IN[0].localPos;
        float3 edgeB = IN[2].localPos - IN[0].localPos;
        float3 c = cross(edgeA, edgeB);
        float3 outDir = normalize(c);
        float3 normalDir = normalize(c);
        float4 pos = float4(0, 0, 0, 0);
        
        float3 over = cos(IN[1].localPos * 1234.56);
        for (int i = 0; i < 3; i ++)
        {
            if(percent < .5)
            {
                over = normalize(over);
                pos.xyz = (lerp(over, 0, percent * 2) + normalDir) * _WaveHeight;
            }
            else
            {
                pos.xyz = normalDir * _WaveHeight * (1 - percent) * 2 ;
            }
            o.localPos = IN[i].localPos + pos;
            o.worldPos = mul(unity_ObjectToWorld, o.localPos);
            o.pos = UnityObjectToClipPos(IN[i].localPos + pos);
            o.uv = IN[i].uv;
            // r = wave height percentage
            // g = isUnderside?
            o.waveSettings = float4(0, 0, 0, 0);
            
            o.normal = IN[i].normal;
            #if defined(BINORMAL_PER_FRAGMENT)
                o.tangent = IN[i].tangent;
            #else
                o.tangent = IN[i].tangent;
                o.binormal = IN[i].binormal;
            #endif
            
            if (distanceToWave > 0)
            {
                o.waveSettings = float4(1-percent, 0, 0, 0);
                
                milk[i].binormal = IN[i].binormal;
                milk[i].localPos = IN[i].localPos;
                milk[i].normal = IN[i].normal;
                milk[i].pos = IN[i].pos;
                milk[i].tangent = IN[i].tangent;
                milk[i].uv = IN[i].uv;
                if(distanceToWave > 0)
                {
                    milk[i].waveSettings = float4(1-percent, 1, 0, 0);
                }
                milk[i].worldPos = IN[i].worldPos;
                count ++ ;
            }
            tristream.Append(o);
        }
        if(_ShowUnderWave)
        {
            tristream.RestartStrip();
            if(count == 3)
            {
                for (int i = 0; i < 3; i ++)
                {
                    for (int i = 0; i < 3; i ++)
                    {
                        tristream.Append(milk[i]);
                    }
                }
            }
        }
        tristream.RestartStrip();
    }
    
    void InitializeFragmentNormal(inout g2f i)
    {
        float3 mainNormal = UnpackScaleNormal(tex2D(_BumpMap, TRANSFORM_TEX(i.uv, _BumpMap)), _BumpScale);
        float3 detailNormal = UnpackScaleNormal(tex2D(_DetailNormalMap, TRANSFORM_TEX(i.uv, _DetailNormalMap)), _DetailNormalMapScale);
        float3 tangentSpaceNormal = BlendNormals(mainNormal, detailNormal);
        
        #if defined(BINORMAL_PER_FRAGMENT)
            float3 binormal = CreateBinormal(i.normal, i.tangent.xyz, i.tangent.w);
        #else
            float3 binormal = i.binormal;
        #endif
        
        i.normal = normalize(
            tangentSpaceNormal.x * i.tangent +
            tangentSpaceNormal.y * binormal +
            tangentSpaceNormal.z * i.normal
        );
    }
    
    float4 frag(g2f i, float facing: VFACE): SV_Target
    {
        float Pi = 3.141592654;
        #ifdef FORWARD_BASE_PASS
            float3 _light_direction_var = normalize(_LightDirection);
            if(!any(_WorldSpaceLightPos0) == 0 && _ForceLightDirection == 0)
            {
                
                _light_direction_var = _WorldSpaceLightPos0;
            }
        #else
            #if defined(POINT) || defined(SPOT)
                float3 _light_direction_var = normalize(_WorldSpaceLightPos0.xyz - i.worldPos);
            #elif defined(DIRECTIONAL)
                return 0;
                float3 _light_direction_var = _WorldSpaceLightPos0;
            #endif
        #endif
        
        // diffuse
        float4 _main_tex_var = tex2D(_MainTex, TRANSFORM_TEX(i.uv, _MainTex));
        float4 _diffuse_var = float4(lerp(_main_tex_var.rgb, dot(_main_tex_var.rgb, float3(0.3, 0.59, 0.11)), _Desaturation) * _Color.rgb, _main_tex_var.a * _Color.a);
        float4 _underwave_tex_var = tex2D(_UnderWaveTexture, TRANSFORM_TEX(i.uv, _UnderWaveTexture)) * _underWaveColor;
        
        // cutout
        #ifndef TRANSPARENT
            clip(_diffuse_var.a - _Clip);
        #endif
        
        // shatterDiffuse
        float4 _wave_tex_var = tex2D(_WaveTexture, TRANSFORM_TEX(i.uv, _WaveTexture)) * _WaveColor;
        if (i.waveSettings.r > 0)
        {
            _diffuse_var = lerp(_diffuse_var, _wave_tex_var, i.waveSettings.r);
        }
        // math
        InitializeFragmentNormal(i);
        float3 _camera_to_vert_var = normalize(getCameraPosition() - i.worldPos);
        float3 _camera_to_vert_vr_var = normalize(_WorldSpaceCameraPos - i.worldPos);
        float3 _camera_vert_dot_var = abs(dot(_camera_to_vert_var, i.normal));
        
        // metal
        float _metallic_map_var = tex2D(_MetallicMap, TRANSFORM_TEX(i.uv, _MetallicMap));
        float _final_metalic_var = _metallic_map_var * _Metallic;
        float _roughness_map_var = tex2D(_RoughnessMap, TRANSFORM_TEX(i.uv, _RoughnessMap));
        float roughness = (1 - _final_metalic_var * _Roughness * _roughness_map_var);
        roughness *= 1.7 - 0.7 * roughness;
        float3 reflectedDir = reflect(-_camera_to_vert_vr_var, i.normal);
        float3 reflection = float3(0, 0, 0);
        
        float4 envSample = UNITY_SAMPLE_TEXCUBE_LOD(unity_SpecCube0, reflectedDir, roughness * UNITY_SPECCUBE_LOD_STEPS);
        
        float interpolator = unity_SpecCube0_BoxMin.w;
        UNITY_BRANCH
        if (interpolator < 0.99999)
        {
            //Probe 1
            float4 reflectionData0 = UNITY_SAMPLE_TEXCUBE_LOD(unity_SpecCube0, reflectedDir, roughness * UNITY_SPECCUBE_LOD_STEPS);
            float3 reflectionColor0 = DecodeHDR(reflectionData0, unity_SpecCube0_HDR);
            
            //Probe 2
            float4 reflectionData1 = UNITY_SAMPLE_TEXCUBE_SAMPLER_LOD(unity_SpecCube1, unity_SpecCube0, reflectedDir, roughness * UNITY_SPECCUBE_LOD_STEPS);
            float3 reflectionColor1 = DecodeHDR(reflectionData1, unity_SpecCube1_HDR);
            
            reflection = lerp(reflectionColor1, reflectionColor0, interpolator);
        }
        else
        {
            float4 reflectionData = UNITY_SAMPLE_TEXCUBE_LOD(unity_SpecCube0, reflectedDir, roughness * UNITY_SPECCUBE_LOD_STEPS);
            reflection = DecodeHDR(reflectionData, unity_SpecCube0_HDR);
        }
        
        
        bool no_probe = unity_SpecCube0_HDR.a == 0 && envSample.a == 0;
            float lighty_boy_uwu_var = 0;
        if (no_probe || _SampleWorld)
        {
            lighty_boy_uwu_var = 1;
            reflection = texCUBElod(_CubeMap, float4(reflectedDir, roughness * UNITY_SPECCUBE_LOD_STEPS));
        }
        
        // matcap / spehere textures
        half2 matcapUV = getMatcapUV(_camera_to_vert_vr_var, i.normal);
        float _matcapMap_var = tex2D(_MatcapMap, TRANSFORM_TEX(i.uv, _MatcapMap));
        float3 _matcap_var = tex2D(_Matcap, matcapUV) * _MatcapColor * _MatcapStrength;
        
        //rim lighting
        float4 rimColor = tex2D(_RimTex, TRANSFORM_TEX(i.uv, _RimTex) + (_Time.y * _RimTexPanSpeed.xy)) * _RimLightColor;
        float rim = pow((1 - _camera_vert_dot_var), (1 - _RimWidth) * 10);
        _RimSharpness /= 2;
        rim = (smoothstep(_RimSharpness, 1 - _RimSharpness, rim));
        
        // lighting
        UNITY_LIGHT_ATTENUATION(attenuation, i, i.worldPos.xyz);
        float nDotL = dot(i.normal, _light_direction_var);
        float fakeLight = clamp((nDotL + 1) / 2 + _ShadowOffset, 0, 1);
        float4 LightingRamp = tex2D(_Ramp, float2(fakeLight, fakeLight));
        #if defined(FORWARD_BASE_PASS)
            //return float4(ShadeSH9(half4(0.0, 0.0, 0.0, 1.0)),1);
            float3 _flat_lighting_var = 1;
            float3 ambient = ShadeSH9(float4(i.normal * _FlatOrFullAmbientLighting, 1));
            if (any(_LightColor0.rgb))
            {
                float4 lightZero = min(_LightColor0, _MaxDirectionalIntensity);
                
                if(_ForceShadowStrength == 0)
                {
                    _flat_lighting_var = ambient + lightZero.rgb * lerp(1, LightingRamp, _ShadowStrength);
                    _flat_lighting_var = clamp(_flat_lighting_var, _MinBrightness, max(lightZero.a, ambient));
                }
                else
                {
                    _flat_lighting_var = (ambient + lightZero.rgb) * lerp(1, LightingRamp, _ShadowStrength);
                    _flat_lighting_var = clamp(_flat_lighting_var, _MinBrightness, max(lightZero.a, ambient));
                }
            }
            else
            {
                _flat_lighting_var = clamp(ambient + ambient * lerp(1, LightingRamp, _ShadowStrength) - ambient * (_ShadowStrength * lerp(.75, 1, _ForceShadowStrength)), _MinBrightness, ambient);
            }
            //return float4(_flat_lighting_var, 1);
        #else
            float3 _flat_lighting_var = _LightColor0.rgb * attenuation * tex2D(_AdditiveRamp, .5 * nDotL + .5);
        #endif
        
        
        
        // emission
        float4 _Emissive_Tex_var = tex2D(_EmissionMap, TRANSFORM_TEX(i.uv, _EmissionMap) + _Time.y * _EmissionScrollSpeed);
        ///
        float4 _emission_var = _Emissive_Tex_var * _EmissionColor * _EmissionStrength;
        
        // scrolling emission
        if (_ScrollingEmission == 1)
        {
            float phase = dot(i.localPos, _EmissiveScroll_Direction);
            phase -= _Time.y * _EmissiveScroll_Velocity;
            phase /= _EmissiveScroll_Interval;
            phase -= floor(phase);
            float width = _EmissiveScroll_Width;
            phase = (pow(phase, width) + pow(1 - phase, width * 4)) * 0.5;
            _emission_var *= phase;
        }
        
        
        
        // blinking emission
        float amplitude = (_EmissiveBlink_Max - _EmissiveBlink_Min) * 0.5f;
        float base = _EmissiveBlink_Min + amplitude;
        float emissiveBlink = sin(_Time.y * _EmissiveBlink_Velocity) * amplitude + base;
        _emission_var *= emissiveBlink;
        
        float _Emission_mask_var = tex2D(_EmissionMask, TRANSFORM_TEX(i.uv, _EmissionMask));
        _emission_var *= _Emission_mask_var;
        
        // add it all up
        float4 finalColor = _diffuse_var;
        
        float3 _rim_color_var = lerp(finalColor.rgb, rimColor, _RimLightColorBias);
        
        finalColor.rgb = lerp(finalColor.rgb, _rim_color_var, rim * _RimLightColor.a * rimColor.a);
        
        
        finalColor.rgb = lerp(finalColor, _matcap_var, _ReplaceWithMatcap * _matcapMap_var);
        finalColor.rgb *= lerp(1, _matcap_var, _MultiplyMatcap * _matcapMap_var);
        finalColor.rgb += _matcap_var * _AddMatcap * _matcapMap_var;
        float4 finalColorBeforeLighting = finalColor;
        
        finalColor.rgb *= _flat_lighting_var;
        #ifdef FORWARD_BASE_PASS
            float3 finalreflections = reflection.rgb * lerp(finalColorBeforeLighting.rgb, 1, _PurelyAdditive);
            finalColor.rgb = finalColor.rgb * lerp((1 - _final_metalic_var), 1, _AdditiveClearCoat);
            finalColor.rgb += (finalreflections * ((1 - roughness + _final_metalic_var) / 2)) * lerp(1, _flat_lighting_var, lighty_boy_uwu_var);
        #endif
        // specular
        #if (defined(POINT) || defined(SPOT))
            _SpecularColor.rgb = _LightColor0.rgb;
            _SpecularBias = 0;
        #endif
        float specular_map_var = tex2D(_SpecularMap, TRANSFORM_TEX(i.uv, _SpecularMap));
        float3 specularColor = ((finalColor.a * _SpecularStrength) * lerp(finalColor.rgb * _LightColor0.rgb, _SpecularColor.rgb, _SpecularBias));
        float specPow = exp2(_Gloss * 20.0 + 1.0);
        float normTerm = (specPow + 10) / (10 * Pi);
        float3 halfDirection = normalize(_camera_to_vert_vr_var + _light_direction_var);
        float3 _specular_var = float3(0, 0, 0);
        if(_HardSpecular == 1)
        {
            _specular_var = step(1 - (.5 * dot(halfDirection, i.normal) + .5), _SpecularSize) * _SpecularColor * _SpecularBias * specular_map_var;
        }
        else
        {
            _specular_var = pow(max(0, dot(halfDirection, i.normal)), specPow) * normTerm * specularColor * _SpecularStrength * specular_map_var;
        }
        
        #if defined(FORWARD_BASE_PASS)
            finalColor.rgb += _specular_var * _flat_lighting_var;
            finalColor.rgb += lerp(_emission_var, _wave_tex_var * _WaveEmission, i.waveSettings.r) + ((rim * _rim_color_var * _RimStrength) * rimColor.a);
            if(i.waveSettings.g > 0)
            {
                finalColor.rgb = _underwave_tex_var.rgb * _flat_lighting_var;
                finalColor.rgb += _underwave_tex_var.rgb * _UnderWaveEmission;
            }
        #else
            finalColor.rgb += _specular_var;
        #endif
        
        #if(defined(POINT) || defined(SPOT))
            finalColor *= (1 - _final_metalic_var);
        #endif
        
        return finalColor;
    }
#endif