_TheStrongestSnail/TheStrongestSnail/Assets/Spine/Runtime/spine-unity/Shaders/CGIncludes/Spine-Skeleton-Lit-Common.cginc

#ifndef SKELETON_LIT_COMMON_INCLUDED
#define SKELETON_LIT_COMMON_INCLUDED

#include "UnityCG.cginc"
#include "CGIncludes/Spine-Common.cginc"

// ES2.0/WebGL/3DS can not do loops with non-constant-expression iteration counts :(
#if defined(SHADER_API_GLES)
#define LIGHT_LOOP_LIMIT 8
#elif defined(SHADER_API_N3DS)
#define LIGHT_LOOP_LIMIT 4
#else
#define LIGHT_LOOP_LIMIT unity_VertexLightParams.x
#endif


////////////////////////////////////////
// Alpha Clipping
//

#if defined(_ALPHA_CLIP)
	uniform fixed _Cutoff;
	#define ALPHA_CLIP(pixel, color) clip((pixel.a * color.a) - _Cutoff);
#else
	#define ALPHA_CLIP(pixel, color)
#endif

half3 computeLighting (int idx, half3 dirToLight, half3 eyeNormal, half4 diffuseColor, half atten) {
	half NdotL = max(dot(eyeNormal, dirToLight), 0.0);
	// diffuse
	half3 color = NdotL * diffuseColor.rgb * unity_LightColor[idx].rgb;
	return color * atten;
}

half3 computeOneLight (int idx, float3 eyePosition, half3 eyeNormal, half4 diffuseColor) {
	float3 dirToLight = unity_LightPosition[idx].xyz;
	half att = 1.0;

	#if defined(POINT) || defined(SPOT)
	dirToLight -= eyePosition * unity_LightPosition[idx].w;

	// distance attenuation
	float distSqr = dot(dirToLight, dirToLight);
	att /= (1.0 + unity_LightAtten[idx].z * distSqr);
	if (unity_LightPosition[idx].w != 0 && distSqr > unity_LightAtten[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);
	#if defined(SPOT)

	// spot angle attenuation
	half rho = max(dot(dirToLight, unity_SpotDirection[idx].xyz), 0.0);
	half spotAtt = (rho - unity_LightAtten[idx].x) * unity_LightAtten[idx].y;
	att *= saturate(spotAtt);
	#endif
	#endif

	att *= 0.5; // passed in light colors are 2x brighter than what used to be in FFP
	return min (computeLighting (idx, dirToLight, eyeNormal, diffuseColor, att), 1.0);
}

int4 unity_VertexLightParams; // x: light count, y: zero, z: one (y/z needed by d3d9 vs loop instruction)

struct appdata {
	float3 pos : POSITION;
	float3 normal : NORMAL;
	half4 color : COLOR;
	float2 uv0 : TEXCOORD0;
#if defined(_TINT_BLACK_ON)
	float2 tintBlackRG : TEXCOORD1;
	float2 tintBlackB : TEXCOORD2;
#endif
	UNITY_VERTEX_INPUT_INSTANCE_ID
};

struct VertexOutput {
	fixed4 color : COLOR0;
	float2 uv0 : TEXCOORD0;
	float4 pos : SV_POSITION;
	UNITY_VERTEX_OUTPUT_STEREO
};

VertexOutput vert (appdata v) {
	VertexOutput o;
	UNITY_SETUP_INSTANCE_ID(v);
	UNITY_INITIALIZE_VERTEX_OUTPUT_STEREO(o);

	half4 color = PMAGammaToTargetSpace(v.color);
	float3 eyePos = UnityObjectToViewPos(float4(v.pos, 1)).xyz; //mul(UNITY_MATRIX_MV, float4(v.pos,1)).xyz;
	half3 fixedNormal = half3(0,0,-1);
	half3 eyeNormal = normalize(mul((float3x3)UNITY_MATRIX_IT_MV, fixedNormal));
	o.uv0 = v.uv0;
	o.pos = UnityObjectToClipPos(v.pos);

#ifdef _DOUBLE_SIDED_LIGHTING
	// unfortunately we have to compute the sign here in the vertex shader
	// instead of using VFACE in fragment shader stage.
	half faceSign = sign(eyeNormal.z);
	eyeNormal *= faceSign;
#endif

	half3 shadowedColor;
#if !defined(_LIGHT_AFFECTS_ADDITIVE)
	if (color.a == 0) {
		o.color = color;
		return o;
	}
#endif // !defined(_LIGHT_AFFECTS_ADDITIVE)

	// Lights
	half3 lcolor = half4(0,0,0,1).rgb + color.rgb * glstate_lightmodel_ambient.rgb;
	for (int il = 0; il < LIGHT_LOOP_LIMIT; ++il) {
		lcolor += computeOneLight(il, eyePos, eyeNormal, color);
	}

	color.rgb = lcolor.rgb;
	o.color = saturate(color);
	return o;
}

sampler2D _MainTex;

fixed4 frag (VertexOutput i) : SV_Target {
	fixed4 tex = tex2D(_MainTex, i.uv0);
	ALPHA_CLIP(tex, i.color);
#if defined(_STRAIGHT_ALPHA_INPUT)
	tex.rgb *= tex.a;
#endif
	fixed4 col = tex * i.color;
	col.rgb *= 2;
	return col;
}

#endif
add 2024-11-12 14:06:34 +08:00			`#ifndef SKELETON_LIT_COMMON_INCLUDED`
			`#define SKELETON_LIT_COMMON_INCLUDED`

			`#include "UnityCG.cginc"`
			`#include "CGIncludes/Spine-Common.cginc"`

			`// ES2.0/WebGL/3DS can not do loops with non-constant-expression iteration counts :(`
			`#if defined(SHADER_API_GLES)`
			`#define LIGHT_LOOP_LIMIT 8`
			`#elif defined(SHADER_API_N3DS)`
			`#define LIGHT_LOOP_LIMIT 4`
			`#else`
			`#define LIGHT_LOOP_LIMIT unity_VertexLightParams.x`
			`#endif`


			`////////////////////////////////////////`
			`// Alpha Clipping`
			`//`

			`#if defined(_ALPHA_CLIP)`
			`uniform fixed _Cutoff;`
			`#define ALPHA_CLIP(pixel, color) clip((pixel.a * color.a) - _Cutoff);`
			`#else`
			`#define ALPHA_CLIP(pixel, color)`
			`#endif`

			`half3 computeLighting (int idx, half3 dirToLight, half3 eyeNormal, half4 diffuseColor, half atten) {`
			`half NdotL = max(dot(eyeNormal, dirToLight), 0.0);`
			`// diffuse`
			`half3 color = NdotL * diffuseColor.rgb * unity_LightColor[idx].rgb;`
			`return color * atten;`
			`}`

			`half3 computeOneLight (int idx, float3 eyePosition, half3 eyeNormal, half4 diffuseColor) {`
			`float3 dirToLight = unity_LightPosition[idx].xyz;`
			`half att = 1.0;`

			`#if defined(POINT) \|\| defined(SPOT)`
			`dirToLight -= eyePosition * unity_LightPosition[idx].w;`

			`// distance attenuation`
			`float distSqr = dot(dirToLight, dirToLight);`
			`att /= (1.0 + unity_LightAtten[idx].z * distSqr);`
			`if (unity_LightPosition[idx].w != 0 && distSqr > unity_LightAtten[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);`
			`#if defined(SPOT)`

			`// spot angle attenuation`
			`half rho = max(dot(dirToLight, unity_SpotDirection[idx].xyz), 0.0);`
			`half spotAtt = (rho - unity_LightAtten[idx].x) * unity_LightAtten[idx].y;`
			`att *= saturate(spotAtt);`
			`#endif`
			`#endif`

			`att *= 0.5; // passed in light colors are 2x brighter than what used to be in FFP`
			`return min (computeLighting (idx, dirToLight, eyeNormal, diffuseColor, att), 1.0);`
			`}`

			`int4 unity_VertexLightParams; // x: light count, y: zero, z: one (y/z needed by d3d9 vs loop instruction)`

			`struct appdata {`
			`float3 pos : POSITION;`
			`float3 normal : NORMAL;`
			`half4 color : COLOR;`
			`float2 uv0 : TEXCOORD0;`
			`#if defined(_TINT_BLACK_ON)`
			`float2 tintBlackRG : TEXCOORD1;`
			`float2 tintBlackB : TEXCOORD2;`
			`#endif`
			`UNITY_VERTEX_INPUT_INSTANCE_ID`
			`};`

			`struct VertexOutput {`
			`fixed4 color : COLOR0;`
			`float2 uv0 : TEXCOORD0;`
			`float4 pos : SV_POSITION;`
			`UNITY_VERTEX_OUTPUT_STEREO`
			`};`

			`VertexOutput vert (appdata v) {`
			`VertexOutput o;`
			`UNITY_SETUP_INSTANCE_ID(v);`
			`UNITY_INITIALIZE_VERTEX_OUTPUT_STEREO(o);`

			`half4 color = PMAGammaToTargetSpace(v.color);`
			`float3 eyePos = UnityObjectToViewPos(float4(v.pos, 1)).xyz; //mul(UNITY_MATRIX_MV, float4(v.pos,1)).xyz;`
			`half3 fixedNormal = half3(0,0,-1);`
			`half3 eyeNormal = normalize(mul((float3x3)UNITY_MATRIX_IT_MV, fixedNormal));`
			`o.uv0 = v.uv0;`
			`o.pos = UnityObjectToClipPos(v.pos);`

			`#ifdef _DOUBLE_SIDED_LIGHTING`
			`// unfortunately we have to compute the sign here in the vertex shader`
			`// instead of using VFACE in fragment shader stage.`
			`half faceSign = sign(eyeNormal.z);`
			`eyeNormal *= faceSign;`
			`#endif`

			`half3 shadowedColor;`
			`#if !defined(_LIGHT_AFFECTS_ADDITIVE)`
			`if (color.a == 0) {`
			`o.color = color;`
			`return o;`
			`}`
			`#endif // !defined(_LIGHT_AFFECTS_ADDITIVE)`

			`// Lights`
			`half3 lcolor = half4(0,0,0,1).rgb + color.rgb * glstate_lightmodel_ambient.rgb;`
			`for (int il = 0; il < LIGHT_LOOP_LIMIT; ++il) {`
			`lcolor += computeOneLight(il, eyePos, eyeNormal, color);`
			`}`

			`color.rgb = lcolor.rgb;`
			`o.color = saturate(color);`
			`return o;`
			`}`

			`sampler2D _MainTex;`

			`fixed4 frag (VertexOutput i) : SV_Target {`
			`fixed4 tex = tex2D(_MainTex, i.uv0);`
			`ALPHA_CLIP(tex, i.color);`
			`#if defined(_STRAIGHT_ALPHA_INPUT)`
			`tex.rgb *= tex.a;`
			`#endif`
			`fixed4 col = tex * i.color;`
			`col.rgb *= 2;`
			`return col;`
			`}`

			`#endif`