bgfx/examples/21-deferred/fs_deferred_light.sc

$input v_texcoord0

/*
 * Copyright 2011-2015 Branimir Karadzic. All rights reserved.
 * License: http://www.opensource.org/licenses/BSD-2-Clause
 */

#include "../common/common.sh"

SAMPLER2D(s_normal, 0);
SAMPLER2D(s_depth,  1);

uniform vec4 u_lightPosRadius[1];
uniform vec4 u_lightRgbInnerR[1];
uniform mat4 u_mtx;

vec2 blinn(vec3 _lightDir, vec3 _normal, vec3 _viewDir)
{
	float ndotl = dot(_normal, _lightDir);
	vec3 reflected = _lightDir - 2.0*ndotl*_normal; // reflect(_lightDir, _normal);
	float rdotv = dot(reflected, _viewDir);
	return vec2(ndotl, rdotv);
}

float fresnel(float _ndotl, float _bias, float _pow)
{
	float facing = (1.0 - _ndotl);
	return max(_bias + (1.0 - _bias) * pow(facing, _pow), 0.0);
}

vec4 lit(float _ndotl, float _rdotv, float _m)
{
	float diff = max(0.0, _ndotl);
	float spec = step(0.0, _ndotl) * max(0.0, _rdotv * _m);
	return vec4(1.0, diff, spec, 1.0);
}

vec4 powRgba(vec4 _rgba, float _pow)
{
	vec4 result;
	result.xyz = pow(_rgba.xyz, vec3_splat(_pow) );
	result.w = _rgba.w;
	return result;
}

vec3 calcLight(int _idx, vec3 _wpos, vec3 _normal, vec3 _view)
{
	vec3 lp = u_lightPosRadius[_idx].xyz - _wpos;
	float attn = 1.0 - smoothstep(u_lightRgbInnerR[_idx].w, 1.0, length(lp) / u_lightPosRadius[_idx].w);
	vec3 lightDir = normalize(lp);
	vec2 bln = blinn(lightDir, _normal, _view);
	vec4 lc = lit(bln.x, bln.y, 1.0);
	vec3 rgb = u_lightRgbInnerR[_idx].xyz * saturate(lc.y) * attn;
	return rgb;
}

float toClipSpaceDepth(float _depthTextureZ)
{
#if BGFX_SHADER_LANGUAGE_HLSL
	return _depthTextureZ;
#else
	return _depthTextureZ * 2.0 - 1.0;
#endif // BGFX_SHADER_LANGUAGE_HLSL
}

vec3 clipToWorld(mat4 _invViewProj, vec3 _clipPos)
{
	vec4 wpos = mul(_invViewProj, vec4(_clipPos, 1.0) );
	return wpos.xyz / wpos.w;
}

void main()
{
	vec3  normal      = decodeNormalUint(texture2D(s_normal, v_texcoord0).xyz);
	float deviceDepth = texture2D(s_depth,  v_texcoord0).x;
	float depth       = toClipSpaceDepth(deviceDepth);

	vec3 clip = vec3(v_texcoord0 * 2.0 - 1.0, depth);
#if BGFX_SHADER_LANGUAGE_HLSL
	clip.y = -clip.y;
#endif // BGFX_SHADER_LANGUAGE_HLSL
	vec3 wpos = clipToWorld(u_mtx, clip);

	vec3 view = mul(u_view, vec4(wpos, 0.0) ).xyz;
	view = -normalize(view);

	vec3 lightColor;
	lightColor = calcLight(0, wpos, normal, view);
	gl_FragColor.xyz = toGamma(lightColor.xyz);
	gl_FragColor.w = 1.0;
}
Added 21-deferred example. 2014-05-21 23:33:12 -04:00			`$input v_texcoord0`

			`/*`
Updated copyright year. 2015-01-02 17:43:11 -05:00			`* Copyright 2011-2015 Branimir Karadzic. All rights reserved.`
Added 21-deferred example. 2014-05-21 23:33:12 -04:00			`* License: http://www.opensource.org/licenses/BSD-2-Clause`
			`*/`

			`#include "../common/common.sh"`

			`SAMPLER2D(s_normal, 0);`
			`SAMPLER2D(s_depth, 1);`

			`uniform vec4 u_lightPosRadius[1];`
			`uniform vec4 u_lightRgbInnerR[1];`
			`uniform mat4 u_mtx;`

			`vec2 blinn(vec3 _lightDir, vec3 _normal, vec3 _viewDir)`
			`{`
			`float ndotl = dot(_normal, _lightDir);`
			`vec3 reflected = _lightDir - 2.0ndotl_normal; // reflect(_lightDir, _normal);`
			`float rdotv = dot(reflected, _viewDir);`
			`return vec2(ndotl, rdotv);`
			`}`

			`float fresnel(float _ndotl, float _bias, float _pow)`
			`{`
			`float facing = (1.0 - _ndotl);`
			`return max(_bias + (1.0 - _bias) * pow(facing, _pow), 0.0);`
			`}`

			`vec4 lit(float _ndotl, float _rdotv, float _m)`
			`{`
			`float diff = max(0.0, _ndotl);`
			`float spec = step(0.0, _ndotl) * max(0.0, _rdotv * _m);`
			`return vec4(1.0, diff, spec, 1.0);`
			`}`

			`vec4 powRgba(vec4 _rgba, float _pow)`
			`{`
			`vec4 result;`
			`result.xyz = pow(_rgba.xyz, vec3_splat(_pow) );`
			`result.w = _rgba.w;`
			`return result;`
			`}`

			`vec3 calcLight(int _idx, vec3 _wpos, vec3 _normal, vec3 _view)`
			`{`
			`vec3 lp = u_lightPosRadius[_idx].xyz - _wpos;`
			`float attn = 1.0 - smoothstep(u_lightRgbInnerR[_idx].w, 1.0, length(lp) / u_lightPosRadius[_idx].w);`
			`vec3 lightDir = normalize(lp);`
			`vec2 bln = blinn(lightDir, _normal, _view);`
			`vec4 lc = lit(bln.x, bln.y, 1.0);`
			`vec3 rgb = u_lightRgbInnerR[_idx].xyz * saturate(lc.y) * attn;`
			`return rgb;`
			`}`

			`float toClipSpaceDepth(float _depthTextureZ)`
			`{`
			`#if BGFX_SHADER_LANGUAGE_HLSL`
			`return _depthTextureZ;`
			`#else`
			`return _depthTextureZ * 2.0 - 1.0;`
			`#endif // BGFX_SHADER_LANGUAGE_HLSL`
			`}`

			`vec3 clipToWorld(mat4 _invViewProj, vec3 _clipPos)`
			`{`
			`vec4 wpos = mul(_invViewProj, vec4(_clipPos, 1.0) );`
			`return wpos.xyz / wpos.w;`
			`}`

			`void main()`
			`{`
			`vec3 normal = decodeNormalUint(texture2D(s_normal, v_texcoord0).xyz);`
			`float deviceDepth = texture2D(s_depth, v_texcoord0).x;`
			`float depth = toClipSpaceDepth(deviceDepth);`

			`vec3 clip = vec3(v_texcoord0 * 2.0 - 1.0, depth);`
			`#if BGFX_SHADER_LANGUAGE_HLSL`
			`clip.y = -clip.y;`
			`#endif // BGFX_SHADER_LANGUAGE_HLSL`
			`vec3 wpos = clipToWorld(u_mtx, clip);`

			`vec3 view = mul(u_view, vec4(wpos, 0.0) ).xyz;`
			`view = -normalize(view);`

			`vec3 lightColor;`
			`lightColor = calcLight(0, wpos, normal, view);`
			`gl_FragColor.xyz = toGamma(lightColor.xyz);`
			`gl_FragColor.w = 1.0;`
			`}`