minetest/client/shaders/object_shader/opengl_fragment.glsl

uniform sampler2D baseTexture;

uniform vec4 emissiveColor;
uniform vec4 skyBgColor;
uniform float fogDistance;
uniform vec3 eyePosition;

varying vec3 vNormal;
varying vec3 vPosition;
varying vec3 worldPosition;
varying lowp vec4 varColor;
#ifdef GL_ES
varying mediump vec2 varTexCoord;
#else
centroid varying vec2 varTexCoord;
#endif

varying vec3 eyeVec;
varying float vIDiff;

const float e = 2.718281828459;
const float BS = 10.0;
const float fogStart = FOG_START;
const float fogShadingParameter = 1.0 / (1.0 - fogStart);

#ifdef ENABLE_DYNAMIC_SHADOWS
	// shadow texture
	uniform sampler2D ShadowMapSampler;
	// shadow uniforms
	uniform vec3 v_LightDirection;
	uniform float f_textureresolution;
	uniform mat4 m_ShadowViewProj;
	uniform float f_shadowfar;
	uniform float f_timeofday;
	varying float normalOffsetScale;
	varying float adj_shadow_strength;
	varying float cosLight;
	varying float f_normal_length;
#endif

#if ENABLE_TONE_MAPPING
/* Hable's UC2 Tone mapping parameters
	A = 0.22;
	B = 0.30;
	C = 0.10;
	D = 0.20;
	E = 0.01;
	F = 0.30;
	W = 11.2;
	equation used:  ((x * (A * x + C * B) + D * E) / (x * (A * x + B) + D * F)) - E / F
*/

vec3 uncharted2Tonemap(vec3 x)
{
	return ((x * (0.22 * x + 0.03) + 0.002) / (x * (0.22 * x + 0.3) + 0.06)) - 0.03333;
}

vec4 applyToneMapping(vec4 color)
{
	color = vec4(pow(color.rgb, vec3(2.2)), color.a);
	const float gamma = 1.6;
	const float exposureBias = 5.5;
	color.rgb = uncharted2Tonemap(exposureBias * color.rgb);
	// Precalculated white_scale from
	//vec3 whiteScale = 1.0 / uncharted2Tonemap(vec3(W));
	vec3 whiteScale = vec3(1.036015346);
	color.rgb *= whiteScale;
	return vec4(pow(color.rgb, vec3(1.0 / gamma)), color.a);
}
#endif

#ifdef ENABLE_DYNAMIC_SHADOWS
const float bias0 = 0.9;
const float zPersFactor = 0.5;
const float bias1 = 1.0 - bias0;

vec4 getPerspectiveFactor(in vec4 shadowPosition)
{
	float pDistance = length(shadowPosition.xy);
	float pFactor = pDistance * bias0 + bias1;
	shadowPosition.xyz *= vec3(vec2(1.0 / pFactor), zPersFactor);

	return shadowPosition;
}

// assuming near is always 1.0
float getLinearDepth()
{
	return 2.0 * f_shadowfar / (f_shadowfar + 1.0 - (2.0 * gl_FragCoord.z - 1.0) * (f_shadowfar - 1.0));
}

vec3 getLightSpacePosition()
{
	vec4 pLightSpace;
	float normalBias = 0.0005 * getLinearDepth() * cosLight + normalOffsetScale;
	pLightSpace = m_ShadowViewProj * vec4(worldPosition + normalBias * normalize(vNormal), 1.0);
	pLightSpace = getPerspectiveFactor(pLightSpace);
	return pLightSpace.xyz * 0.5 + 0.5;
}

#ifdef COLORED_SHADOWS

// c_precision of 128 fits within 7 base-10 digits
const float c_precision = 128.0;
const float c_precisionp1 = c_precision + 1.0;

float packColor(vec3 color)
{
	return floor(color.b * c_precision + 0.5)
		+ floor(color.g * c_precision + 0.5) * c_precisionp1
		+ floor(color.r * c_precision + 0.5) * c_precisionp1 * c_precisionp1;
}

vec3 unpackColor(float value)
{
	vec3 color;
	color.b = mod(value, c_precisionp1) / c_precision;
	color.g = mod(floor(value / c_precisionp1), c_precisionp1) / c_precision;
	color.r = floor(value / (c_precisionp1 * c_precisionp1)) / c_precision;
	return color;
}

vec4 getHardShadowColor(sampler2D shadowsampler, vec2 smTexCoord, float realDistance)
{
	vec4 texDepth = texture2D(shadowsampler, smTexCoord.xy).rgba;

	float visibility = step(0.0, (realDistance-2e-5) - texDepth.r);
	vec4 result = vec4(visibility, vec3(0.0,0.0,0.0));//unpackColor(texDepth.g));
	if (visibility < 0.1) {
		visibility = step(0.0, (realDistance-2e-5) - texDepth.r);
		result = vec4(visibility, unpackColor(texDepth.a));
	}
	return result;
}

#else

float getHardShadow(sampler2D shadowsampler, vec2 smTexCoord, float realDistance)
{
	float texDepth = texture2D(shadowsampler, smTexCoord.xy).r;
	float visibility = step(0.0, (realDistance-2e-5) - texDepth);

	return visibility;
}

#endif

#if SHADOW_FILTER == 2
	#define PCFBOUND 3.5
	#define PCFSAMPLES 64.0
#elif SHADOW_FILTER == 1
	#define PCFBOUND 1.5
	#if defined(POISSON_FILTER)
		#define PCFSAMPLES 32.0
	#else
		#define PCFSAMPLES 16.0
	#endif
#else
	#define PCFBOUND 0.0
	#if defined(POISSON_FILTER)
		#define PCFSAMPLES 4.0
	#else
		#define PCFSAMPLES 1.0
	#endif
#endif

#ifdef POISSON_FILTER
const vec2[64] poissonDisk = vec2[64](
	vec2(0.170019, -0.040254),
	vec2(-0.299417, 0.791925),
	vec2(0.645680, 0.493210),
	vec2(-0.651784, 0.717887),
	vec2(0.421003, 0.027070),
	vec2(-0.817194, -0.271096),
	vec2(-0.705374, -0.668203),
	vec2(0.977050, -0.108615),
	vec2(0.063326, 0.142369),
	vec2(0.203528, 0.214331),
	vec2(-0.667531, 0.326090),
	vec2(-0.098422, -0.295755),
	vec2(-0.885922, 0.215369),
	vec2(0.566637, 0.605213),
	vec2(0.039766, -0.396100),
	vec2(0.751946, 0.453352),
	vec2(0.078707, -0.715323),
	vec2(-0.075838, -0.529344),
	vec2(0.724479, -0.580798),
	vec2(0.222999, -0.215125),
	vec2(-0.467574, -0.405438),
	vec2(-0.248268, -0.814753),
	vec2(0.354411, -0.887570),
	vec2(0.175817, 0.382366),
	vec2(0.487472, -0.063082),
	vec2(0.355476, 0.025357),
	vec2(-0.084078, 0.898312),
	vec2(0.488876, -0.783441),
	vec2(0.470016, 0.217933),
	vec2(-0.696890, -0.549791),
	vec2(-0.149693, 0.605762),
	vec2(0.034211, 0.979980),
	vec2(0.503098, -0.308878),
	vec2(-0.016205, -0.872921),
	vec2(0.385784, -0.393902),
	vec2(-0.146886, -0.859249),
	vec2(0.643361, 0.164098),
	vec2(0.634388, -0.049471),
	vec2(-0.688894, 0.007843),
	vec2(0.464034, -0.188818),
	vec2(-0.440840, 0.137486),
	vec2(0.364483, 0.511704),
	vec2(0.034028, 0.325968),
	vec2(0.099094, -0.308023),
	vec2(0.693960, -0.366253),
	vec2(0.678884, -0.204688),
	vec2(0.001801, 0.780328),
	vec2(0.145177, -0.898984),
	vec2(0.062655, -0.611866),
	vec2(0.315226, -0.604297),
	vec2(-0.780145, 0.486251),
	vec2(-0.371868, 0.882138),
	vec2(0.200476, 0.494430),
	vec2(-0.494552, -0.711051),
	vec2(0.612476, 0.705252),
	vec2(-0.578845, -0.768792),
	vec2(-0.772454, -0.090976),
	vec2(0.504440, 0.372295),
	vec2(0.155736, 0.065157),
	vec2(0.391522, 0.849605),
	vec2(-0.620106, -0.328104),
	vec2(0.789239, -0.419965),
	vec2(-0.545396, 0.538133),
	vec2(-0.178564, -0.596057)
);

#ifdef COLORED_SHADOWS

vec4 getShadowColor(sampler2D shadowsampler, vec2 smTexCoord, float realDistance)
{
	vec2 clampedpos;
	vec4 visibility = vec4(0.0);

	float texture_size = 1.0 / (f_textureresolution * 0.5);
	int init_offset = int(floor(mod(((smTexCoord.x * 34.0) + 1.0) * smTexCoord.y, 64.0-PCFSAMPLES)));
	int end_offset = int(PCFSAMPLES) + init_offset;

	for (int x = init_offset; x < end_offset; x++) {
		clampedpos = poissonDisk[x] * texture_size * SOFTSHADOWRADIUS + smTexCoord.xy;
		visibility += getHardShadowColor(shadowsampler, clampedpos.xy, realDistance);
	}

	return visibility / PCFSAMPLES;
}

#else

float getShadow(sampler2D shadowsampler, vec2 smTexCoord, float realDistance)
{
	vec2 clampedpos;
	float visibility = 0.0;

	float texture_size = 1.0 / (f_textureresolution * 0.5);
	int init_offset = int(floor(mod(((smTexCoord.x * 34.0) + 1.0) * smTexCoord.y, 64.0-PCFSAMPLES)));
	int end_offset = int(PCFSAMPLES) + init_offset;

	for (int x = init_offset; x < end_offset; x++) {
		clampedpos = poissonDisk[x] * texture_size * SOFTSHADOWRADIUS + smTexCoord.xy;
		visibility += getHardShadow(shadowsampler, clampedpos.xy, realDistance);
	}

	return visibility / PCFSAMPLES;
}

#endif

#else
/* poisson filter disabled */

#ifdef COLORED_SHADOWS

vec4 getShadowColor(sampler2D shadowsampler, vec2 smTexCoord, float realDistance)
{
	vec2 clampedpos;
	vec4 visibility = vec4(0.0);
	float sradius=0.0;
	if( PCFBOUND>0)
		sradius = SOFTSHADOWRADIUS / PCFBOUND;  
	float texture_size = 1.0 / (f_textureresolution * 0.5);
	float y, x;
	// basic PCF filter
	for (y = -PCFBOUND; y <= PCFBOUND; y += 1.0)
	for (x = -PCFBOUND; x <= PCFBOUND; x += 1.0) {
		clampedpos = vec2(x,y) * texture_size* sradius +  smTexCoord.xy;
		visibility += getHardShadowColor(shadowsampler, clampedpos.xy, realDistance);
	}

	return visibility / PCFSAMPLES;
}

#else
float getShadow(sampler2D shadowsampler, vec2 smTexCoord, float realDistance)
{
	vec2 clampedpos;
	float visibility = 0.0;
	float sradius=0.0;
	if( PCFBOUND>0)
		sradius = SOFTSHADOWRADIUS / PCFBOUND;  
	
	float texture_size = 1.0 / (f_textureresolution * 0.5);
	float y, x;
	// basic PCF filter
	for (y = -PCFBOUND; y <= PCFBOUND; y += 1.0)
	for (x = -PCFBOUND; x <= PCFBOUND; x += 1.0) {
		clampedpos =  vec2(x,y) * texture_size * sradius + smTexCoord.xy;
		visibility += getHardShadow(shadowsampler, clampedpos.xy, realDistance);
	}

	return visibility / PCFSAMPLES;
}

#endif

#endif
#endif

void main(void)
{
	vec3 color;
	vec2 uv = varTexCoord.st;
	vec4 base = texture2D(baseTexture, uv).rgba;

#ifdef USE_DISCARD
	// If alpha is zero, we can just discard the pixel. This fixes transparency
	// on GPUs like GC7000L, where GL_ALPHA_TEST is not implemented in mesa,
	// and also on GLES 2, where GL_ALPHA_TEST is missing entirely.
	if (base.a == 0.0) {
		discard;
	}
#endif

	color = base.rgb;
	vec4 col = vec4(color.rgb, base.a);
	col.rgb *= varColor.rgb;
	col.rgb *= emissiveColor.rgb * vIDiff;

#ifdef ENABLE_DYNAMIC_SHADOWS
	float shadow_int = 0.0;
	vec3 shadow_color = vec3(0.0, 0.0, 0.0);
	vec3 posLightSpace = getLightSpacePosition();

#ifdef COLORED_SHADOWS
	vec4 visibility = getShadowColor(ShadowMapSampler, posLightSpace.xy, posLightSpace.z);
	shadow_int = visibility.r;
	shadow_color = visibility.gba;
#else
	shadow_int = getShadow(ShadowMapSampler, posLightSpace.xy, posLightSpace.z);
#endif

	if (f_normal_length != 0 && cosLight <= 0.001) {
		shadow_int = clamp(shadow_int + 0.5 * abs(cosLight), 0.0, 1.0);
	}

	shadow_int = 1.0 - (shadow_int * adj_shadow_strength);

	col.rgb = mix(shadow_color, col.rgb, shadow_int) * shadow_int;
#endif


#if ENABLE_TONE_MAPPING
	col = applyToneMapping(col);
#endif

	// Due to a bug in some (older ?) graphics stacks (possibly in the glsl compiler ?),
	// the fog will only be rendered correctly if the last operation before the
	// clamp() is an addition. Else, the clamp() seems to be ignored.
	// E.g. the following won't work:
	//      float clarity = clamp(fogShadingParameter
	//		* (fogDistance - length(eyeVec)) / fogDistance), 0.0, 1.0);
	// As additions usually come for free following a multiplication, the new formula
	// should be more efficient as well.
	// Note: clarity = (1 - fogginess)
	float clarity = clamp(fogShadingParameter
		- fogShadingParameter * length(eyeVec) / fogDistance, 0.0, 1.0);
	col = mix(skyBgColor, col, clarity);

	gl_FragColor = vec4(col.rgb, base.a);
}
Basic model shading (#9374) 2020-02-16 20:37:28 +01:00			`uniform sampler2D baseTexture;`

			`uniform vec4 emissiveColor;`
			`uniform vec4 skyBgColor;`
			`uniform float fogDistance;`
			`uniform vec3 eyePosition;`

			`varying vec3 vNormal;`
			`varying vec3 vPosition;`
			`varying vec3 worldPosition;`
Shaders for Android (GLES 2) (#10506) Shader support for OpenGL ES 2 devices (Android) Co-authored-by: sfan5 <sfan5@live.de> 2020-10-25 18:01:03 +01:00			`varying lowp vec4 varColor;`
Fix GLES shader support after #9247 (#10727) 2020-12-22 14:53:52 +01:00			`#ifdef GL_ES`
			`varying mediump vec2 varTexCoord;`
			`#else`
			`centroid varying vec2 varTexCoord;`
			`#endif`
Basic model shading (#9374) 2020-02-16 20:37:28 +01:00
			`varying vec3 eyeVec;`
			`varying float vIDiff;`

			`const float e = 2.718281828459;`
			`const float BS = 10.0;`
			`const float fogStart = FOG_START;`
Shaders for Android (GLES 2) (#10506) Shader support for OpenGL ES 2 devices (Android) Co-authored-by: sfan5 <sfan5@live.de> 2020-10-25 18:01:03 +01:00			`const float fogShadingParameter = 1.0 / (1.0 - fogStart);`
Basic model shading (#9374) 2020-02-16 20:37:28 +01:00
Shadow mapping render pass (#11244) Co-authored-by: x2048 <codeforsmile@gmail.com> 2021-06-06 18:51:21 +02:00			`#ifdef ENABLE_DYNAMIC_SHADOWS`
			`// shadow texture`
			`uniform sampler2D ShadowMapSampler;`
			`// shadow uniforms`
			`uniform vec3 v_LightDirection;`
			`uniform float f_textureresolution;`
			`uniform mat4 m_ShadowViewProj;`
			`uniform float f_shadowfar;`
			`uniform float f_timeofday;`
			`varying float normalOffsetScale;`
			`varying float adj_shadow_strength;`
			`varying float cosLight;`
			`varying float f_normal_length;`
			`#endif`
Add tone mapping for entities (#9521) fixes #9301 2020-04-06 16:06:40 +02:00
Shadow mapping render pass (#11244) Co-authored-by: x2048 <codeforsmile@gmail.com> 2021-06-06 18:51:21 +02:00			`#if ENABLE_TONE_MAPPING`
Add tone mapping for entities (#9521) fixes #9301 2020-04-06 16:06:40 +02:00			`/* Hable's UC2 Tone mapping parameters`
			`A = 0.22;`
			`B = 0.30;`
			`C = 0.10;`
			`D = 0.20;`
			`E = 0.01;`
			`F = 0.30;`
			`W = 11.2;`
			`equation used: ((x * (A * x + C * B) + D * E) / (x * (A * x + B) + D * F)) - E / F`
			`*/`

			`vec3 uncharted2Tonemap(vec3 x)`
			`{`
			`return ((x * (0.22 * x + 0.03) + 0.002) / (x * (0.22 * x + 0.3) + 0.06)) - 0.03333;`
			`}`

			`vec4 applyToneMapping(vec4 color)`
			`{`
			`color = vec4(pow(color.rgb, vec3(2.2)), color.a);`
			`const float gamma = 1.6;`
			`const float exposureBias = 5.5;`
			`color.rgb = uncharted2Tonemap(exposureBias * color.rgb);`
Fix MSAA stripes (#9247) This only works when shaders are enabled. The centroid varying avoids that the textures (which repeat themselves out of bounds) are sampled out of bounds in MSAA. If MSAA (called FSAA in minetest) is disabled, the centroid keyword does nothing. 2020-12-04 20:16:12 +01:00			`// Precalculated white_scale from`
Add tone mapping for entities (#9521) fixes #9301 2020-04-06 16:06:40 +02:00			`//vec3 whiteScale = 1.0 / uncharted2Tonemap(vec3(W));`
			`vec3 whiteScale = vec3(1.036015346);`
			`color.rgb *= whiteScale;`
			`return vec4(pow(color.rgb, vec3(1.0 / gamma)), color.a);`
			`}`
			`#endif`

Shadow mapping render pass (#11244) Co-authored-by: x2048 <codeforsmile@gmail.com> 2021-06-06 18:51:21 +02:00			`#ifdef ENABLE_DYNAMIC_SHADOWS`
			`const float bias0 = 0.9;`
			`const float zPersFactor = 0.5;`
			`const float bias1 = 1.0 - bias0;`

			`vec4 getPerspectiveFactor(in vec4 shadowPosition)`
			`{`
			`float pDistance = length(shadowPosition.xy);`
			`float pFactor = pDistance * bias0 + bias1;`
			`shadowPosition.xyz *= vec3(vec2(1.0 / pFactor), zPersFactor);`

			`return shadowPosition;`
			`}`

			`// assuming near is always 1.0`
			`float getLinearDepth()`
			`{`
			`return 2.0 * f_shadowfar / (f_shadowfar + 1.0 - (2.0 * gl_FragCoord.z - 1.0) * (f_shadowfar - 1.0));`
			`}`

			`vec3 getLightSpacePosition()`
			`{`
			`vec4 pLightSpace;`
			`float normalBias = 0.0005 * getLinearDepth() * cosLight + normalOffsetScale;`
			`pLightSpace = m_ShadowViewProj * vec4(worldPosition + normalBias * normalize(vNormal), 1.0);`
			`pLightSpace = getPerspectiveFactor(pLightSpace);`
			`return pLightSpace.xyz * 0.5 + 0.5;`
			`}`

			`#ifdef COLORED_SHADOWS`

			`// c_precision of 128 fits within 7 base-10 digits`
			`const float c_precision = 128.0;`
			`const float c_precisionp1 = c_precision + 1.0;`

			`float packColor(vec3 color)`
			`{`
			`return floor(color.b * c_precision + 0.5)`
			`+ floor(color.g * c_precision + 0.5) * c_precisionp1`
			`+ floor(color.r * c_precision + 0.5) * c_precisionp1 * c_precisionp1;`
			`}`

			`vec3 unpackColor(float value)`
			`{`
			`vec3 color;`
			`color.b = mod(value, c_precisionp1) / c_precision;`
			`color.g = mod(floor(value / c_precisionp1), c_precisionp1) / c_precision;`
			`color.r = floor(value / (c_precisionp1 * c_precisionp1)) / c_precision;`
			`return color;`
			`}`

			`vec4 getHardShadowColor(sampler2D shadowsampler, vec2 smTexCoord, float realDistance)`
			`{`
			`vec4 texDepth = texture2D(shadowsampler, smTexCoord.xy).rgba;`

			`float visibility = step(0.0, (realDistance-2e-5) - texDepth.r);`
			`vec4 result = vec4(visibility, vec3(0.0,0.0,0.0));//unpackColor(texDepth.g));`
			`if (visibility < 0.1) {`
			`visibility = step(0.0, (realDistance-2e-5) - texDepth.r);`
			`result = vec4(visibility, unpackColor(texDepth.a));`
			`}`
			`return result;`
			`}`

			`#else`

			`float getHardShadow(sampler2D shadowsampler, vec2 smTexCoord, float realDistance)`
			`{`
			`float texDepth = texture2D(shadowsampler, smTexCoord.xy).r;`
			`float visibility = step(0.0, (realDistance-2e-5) - texDepth);`

			`return visibility;`
			`}`

			`#endif`

			`#if SHADOW_FILTER == 2`
			`#define PCFBOUND 3.5`
			`#define PCFSAMPLES 64.0`
			`#elif SHADOW_FILTER == 1`
			`#define PCFBOUND 1.5`
			`#if defined(POISSON_FILTER)`
			`#define PCFSAMPLES 32.0`
			`#else`
			`#define PCFSAMPLES 16.0`
			`#endif`
			`#else`
			`#define PCFBOUND 0.0`
			`#if defined(POISSON_FILTER)`
			`#define PCFSAMPLES 4.0`
			`#else`
			`#define PCFSAMPLES 1.0`
			`#endif`
			`#endif`

			`#ifdef POISSON_FILTER`
			`const vec2[64] poissonDisk = vec2[64](`
			`vec2(0.170019, -0.040254),`
			`vec2(-0.299417, 0.791925),`
			`vec2(0.645680, 0.493210),`
			`vec2(-0.651784, 0.717887),`
			`vec2(0.421003, 0.027070),`
			`vec2(-0.817194, -0.271096),`
			`vec2(-0.705374, -0.668203),`
			`vec2(0.977050, -0.108615),`
			`vec2(0.063326, 0.142369),`
			`vec2(0.203528, 0.214331),`
			`vec2(-0.667531, 0.326090),`
			`vec2(-0.098422, -0.295755),`
			`vec2(-0.885922, 0.215369),`
			`vec2(0.566637, 0.605213),`
			`vec2(0.039766, -0.396100),`
			`vec2(0.751946, 0.453352),`
			`vec2(0.078707, -0.715323),`
			`vec2(-0.075838, -0.529344),`
			`vec2(0.724479, -0.580798),`
			`vec2(0.222999, -0.215125),`
			`vec2(-0.467574, -0.405438),`
			`vec2(-0.248268, -0.814753),`
			`vec2(0.354411, -0.887570),`
			`vec2(0.175817, 0.382366),`
			`vec2(0.487472, -0.063082),`
			`vec2(0.355476, 0.025357),`
			`vec2(-0.084078, 0.898312),`
			`vec2(0.488876, -0.783441),`
			`vec2(0.470016, 0.217933),`
			`vec2(-0.696890, -0.549791),`
			`vec2(-0.149693, 0.605762),`
			`vec2(0.034211, 0.979980),`
			`vec2(0.503098, -0.308878),`
			`vec2(-0.016205, -0.872921),`
			`vec2(0.385784, -0.393902),`
			`vec2(-0.146886, -0.859249),`
			`vec2(0.643361, 0.164098),`
			`vec2(0.634388, -0.049471),`
			`vec2(-0.688894, 0.007843),`
			`vec2(0.464034, -0.188818),`
			`vec2(-0.440840, 0.137486),`
			`vec2(0.364483, 0.511704),`
			`vec2(0.034028, 0.325968),`
			`vec2(0.099094, -0.308023),`
			`vec2(0.693960, -0.366253),`
			`vec2(0.678884, -0.204688),`
			`vec2(0.001801, 0.780328),`
			`vec2(0.145177, -0.898984),`
			`vec2(0.062655, -0.611866),`
			`vec2(0.315226, -0.604297),`
			`vec2(-0.780145, 0.486251),`
			`vec2(-0.371868, 0.882138),`
			`vec2(0.200476, 0.494430),`
			`vec2(-0.494552, -0.711051),`
			`vec2(0.612476, 0.705252),`
			`vec2(-0.578845, -0.768792),`
			`vec2(-0.772454, -0.090976),`
			`vec2(0.504440, 0.372295),`
			`vec2(0.155736, 0.065157),`
			`vec2(0.391522, 0.849605),`
			`vec2(-0.620106, -0.328104),`
			`vec2(0.789239, -0.419965),`
			`vec2(-0.545396, 0.538133),`
			`vec2(-0.178564, -0.596057)`
			`);`

			`#ifdef COLORED_SHADOWS`

			`vec4 getShadowColor(sampler2D shadowsampler, vec2 smTexCoord, float realDistance)`
			`{`
			`vec2 clampedpos;`
			`vec4 visibility = vec4(0.0);`

			`float texture_size = 1.0 / (f_textureresolution * 0.5);`
			`int init_offset = int(floor(mod(((smTexCoord.x * 34.0) + 1.0) * smTexCoord.y, 64.0-PCFSAMPLES)));`
			`int end_offset = int(PCFSAMPLES) + init_offset;`

			`for (int x = init_offset; x < end_offset; x++) {`
			`clampedpos = poissonDisk[x] * texture_size * SOFTSHADOWRADIUS + smTexCoord.xy;`
			`visibility += getHardShadowColor(shadowsampler, clampedpos.xy, realDistance);`
			`}`

			`return visibility / PCFSAMPLES;`
			`}`

			`#else`

			`float getShadow(sampler2D shadowsampler, vec2 smTexCoord, float realDistance)`
			`{`
			`vec2 clampedpos;`
			`float visibility = 0.0;`

			`float texture_size = 1.0 / (f_textureresolution * 0.5);`
			`int init_offset = int(floor(mod(((smTexCoord.x * 34.0) + 1.0) * smTexCoord.y, 64.0-PCFSAMPLES)));`
			`int end_offset = int(PCFSAMPLES) + init_offset;`

			`for (int x = init_offset; x < end_offset; x++) {`
			`clampedpos = poissonDisk[x] * texture_size * SOFTSHADOWRADIUS + smTexCoord.xy;`
			`visibility += getHardShadow(shadowsampler, clampedpos.xy, realDistance);`
			`}`

			`return visibility / PCFSAMPLES;`
			`}`

			`#endif`

			`#else`
			`/* poisson filter disabled */`

			`#ifdef COLORED_SHADOWS`

			`vec4 getShadowColor(sampler2D shadowsampler, vec2 smTexCoord, float realDistance)`
			`{`
			`vec2 clampedpos;`
			`vec4 visibility = vec4(0.0);`
			`float sradius=0.0;`
			`if( PCFBOUND>0)`
			`sradius = SOFTSHADOWRADIUS / PCFBOUND;`
			`float texture_size = 1.0 / (f_textureresolution * 0.5);`
			`float y, x;`
			`// basic PCF filter`
			`for (y = -PCFBOUND; y <= PCFBOUND; y += 1.0)`
			`for (x = -PCFBOUND; x <= PCFBOUND; x += 1.0) {`
			`clampedpos = vec2(x,y) * texture_size* sradius + smTexCoord.xy;`
			`visibility += getHardShadowColor(shadowsampler, clampedpos.xy, realDistance);`
			`}`

			`return visibility / PCFSAMPLES;`
			`}`

			`#else`
			`float getShadow(sampler2D shadowsampler, vec2 smTexCoord, float realDistance)`
			`{`
			`vec2 clampedpos;`
			`float visibility = 0.0;`
			`float sradius=0.0;`
			`if( PCFBOUND>0)`
			`sradius = SOFTSHADOWRADIUS / PCFBOUND;`

			`float texture_size = 1.0 / (f_textureresolution * 0.5);`
			`float y, x;`
			`// basic PCF filter`
			`for (y = -PCFBOUND; y <= PCFBOUND; y += 1.0)`
			`for (x = -PCFBOUND; x <= PCFBOUND; x += 1.0) {`
			`clampedpos = vec2(x,y) * texture_size * sradius + smTexCoord.xy;`
			`visibility += getHardShadow(shadowsampler, clampedpos.xy, realDistance);`
			`}`

			`return visibility / PCFSAMPLES;`
			`}`

			`#endif`

			`#endif`
			`#endif`

Basic model shading (#9374) 2020-02-16 20:37:28 +01:00			`void main(void)`
			`{`
			`vec3 color;`
Shaders for Android (GLES 2) (#10506) Shader support for OpenGL ES 2 devices (Android) Co-authored-by: sfan5 <sfan5@live.de> 2020-10-25 18:01:03 +01:00			`vec2 uv = varTexCoord.st;`
Basic model shading (#9374) 2020-02-16 20:37:28 +01:00			`vec4 base = texture2D(baseTexture, uv).rgba;`

shaders: Fix transparency on GC7000L (#10036) Workaround for the missing GL_ALPHA_TEST implementation in Mesa (etnaviv driver). 2020-08-25 20:49:51 +02:00			`#ifdef USE_DISCARD`
			`// If alpha is zero, we can just discard the pixel. This fixes transparency`
Shaders for Android (GLES 2) (#10506) Shader support for OpenGL ES 2 devices (Android) Co-authored-by: sfan5 <sfan5@live.de> 2020-10-25 18:01:03 +01:00			`// on GPUs like GC7000L, where GL_ALPHA_TEST is not implemented in mesa,`
			`// and also on GLES 2, where GL_ALPHA_TEST is missing entirely.`
shaders: Fix transparency on GC7000L (#10036) Workaround for the missing GL_ALPHA_TEST implementation in Mesa (etnaviv driver). 2020-08-25 20:49:51 +02:00			`if (base.a == 0.0) {`
			`discard;`
			`}`
			`#endif`

Basic model shading (#9374) 2020-02-16 20:37:28 +01:00			`color = base.rgb;`
			`vec4 col = vec4(color.rgb, base.a);`
Shaders for Android (GLES 2) (#10506) Shader support for OpenGL ES 2 devices (Android) Co-authored-by: sfan5 <sfan5@live.de> 2020-10-25 18:01:03 +01:00			`col.rgb *= varColor.rgb;`
Basic model shading (#9374) 2020-02-16 20:37:28 +01:00			`col.rgb = emissiveColor.rgb vIDiff;`
Fix broken coloring of wielditems (#9969) Fixes a regression that appeared in 5.3.0-dev. 2020-06-09 21:38:09 +02:00
Shadow mapping render pass (#11244) Co-authored-by: x2048 <codeforsmile@gmail.com> 2021-06-06 18:51:21 +02:00			`#ifdef ENABLE_DYNAMIC_SHADOWS`
			`float shadow_int = 0.0;`
			`vec3 shadow_color = vec3(0.0, 0.0, 0.0);`
			`vec3 posLightSpace = getLightSpacePosition();`

			`#ifdef COLORED_SHADOWS`
			`vec4 visibility = getShadowColor(ShadowMapSampler, posLightSpace.xy, posLightSpace.z);`
			`shadow_int = visibility.r;`
			`shadow_color = visibility.gba;`
			`#else`
			`shadow_int = getShadow(ShadowMapSampler, posLightSpace.xy, posLightSpace.z);`
			`#endif`

			`if (f_normal_length != 0 && cosLight <= 0.001) {`
			`shadow_int = clamp(shadow_int + 0.5 * abs(cosLight), 0.0, 1.0);`
			`}`

			`shadow_int = 1.0 - (shadow_int * adj_shadow_strength);`

			`col.rgb = mix(shadow_color, col.rgb, shadow_int) * shadow_int;`
			`#endif`



Cleanup shader generation code (#10663) Shader generation is a mess. This commit cleans some parts up, including dropping remains of HLSL support which was never actually implemented. 2020-12-19 20:57:10 +01:00			`#if ENABLE_TONE_MAPPING`
Add tone mapping for entities (#9521) fixes #9301 2020-04-06 16:06:40 +02:00			`col = applyToneMapping(col);`
			`#endif`

Basic model shading (#9374) 2020-02-16 20:37:28 +01:00			`// Due to a bug in some (older ?) graphics stacks (possibly in the glsl compiler ?),`
			`// the fog will only be rendered correctly if the last operation before the`
			`// clamp() is an addition. Else, the clamp() seems to be ignored.`
			`// E.g. the following won't work:`
			`// float clarity = clamp(fogShadingParameter`
			`// * (fogDistance - length(eyeVec)) / fogDistance), 0.0, 1.0);`
			`// As additions usually come for free following a multiplication, the new formula`
			`// should be more efficient as well.`
			`// Note: clarity = (1 - fogginess)`
			`float clarity = clamp(fogShadingParameter`
			`- fogShadingParameter * length(eyeVec) / fogDistance, 0.0, 1.0);`
			`col = mix(skyBgColor, col, clarity);`

			`gl_FragColor = vec4(col.rgb, base.a);`
			`}`