#include "gl_common.h" // clang-format off const char dummy_frag[] = GLSL(330, uniform sampler2D tex; in vec2 texcoord; void main() { gl_FragColor = texelFetch(tex, ivec2(texcoord.xy), 0); } ); const char present_frag[] = GLSL(330, uniform sampler2D tex; in vec2 texcoord; vec4 dither(vec4, vec2); void main() { gl_FragColor = dither(texelFetch(tex, ivec2(texcoord.xy), 0), texcoord); } ); const char copy_with_mask_frag[] = GLSL(330, uniform sampler2D tex; in vec2 texcoord; float mask_factor(); void main() { gl_FragColor = texelFetch(tex, ivec2(texcoord.xy), 0) * mask_factor(); } ); const char fill_frag[] = GLSL(330, uniform vec4 color; void main() { gl_FragColor = color; } ); const char fill_vert[] = GLSL(330, layout(location = 0) in vec2 in_coord; uniform mat4 projection; void main() { gl_Position = projection * vec4(in_coord, 0, 1); } ); const char interpolating_frag[] = GLSL(330, uniform sampler2D tex; in vec2 texcoord; void main() { gl_FragColor = vec4(texture2D(tex, vec2(texcoord.xy), 0).rgb, 1); } ); const char interpolating_vert[] = GLSL(330, uniform mat4 projection; uniform vec2 texsize; layout(location = 0) in vec2 in_coord; layout(location = 1) in vec2 in_texcoord; out vec2 texcoord; void main() { gl_Position = projection * vec4(in_coord, 0, 1); texcoord = in_texcoord / texsize; } ); const char masking_glsl[] = GLSL(330, uniform sampler2D mask_tex; uniform vec2 mask_offset; uniform float mask_corner_radius; uniform bool mask_inverted; in vec2 texcoord; float mask_rectangle_sdf(vec2 point, vec2 half_size) { vec2 d = abs(point) - half_size; return length(max(d, 0.0)); } float mask_factor() { vec2 mask_size = textureSize(mask_tex, 0); vec2 maskcoord = texcoord - mask_offset; vec4 mask = texture2D(mask_tex, maskcoord / mask_size); if (mask_corner_radius != 0) { vec2 inner_size = mask_size - vec2(mask_corner_radius) * 2.0f; float dist = mask_rectangle_sdf(maskcoord - mask_size / 2.0f, inner_size / 2.0f) - mask_corner_radius; if (dist > 0.0f) { mask.r *= (1.0f - clamp(dist, 0.0f, 1.0f)); } } if (mask_inverted) { mask.rgb = 1.0 - mask.rgb; } return mask.r; } ); const char win_shader_glsl[] = GLSL(330, uniform float opacity; uniform float dim; uniform float corner_radius; uniform float border_width; uniform bool invert_color; in vec2 texcoord; uniform sampler2D tex; uniform sampler2D brightness; uniform float max_brightness; // Signed distance field for rectangle center at (0, 0), with size of // half_size * 2 float rectangle_sdf(vec2 point, vec2 half_size) { vec2 d = abs(point) - half_size; return length(max(d, 0.0)); } vec4 default_post_processing(vec4 c) { vec4 border_color = texture(tex, vec2(0.0, 0.5)); if (invert_color) { c = vec4(c.aaa - c.rgb, c.a); border_color = vec4(border_color.aaa - border_color.rgb, border_color.a); } c = vec4(c.rgb * (1.0 - dim), c.a) * opacity; border_color = vec4(border_color.rgb * (1.0 - dim), border_color.a) * opacity; vec3 rgb_brightness = texelFetch(brightness, ivec2(0, 0), 0).rgb; // Ref: https://en.wikipedia.org/wiki/Relative_luminance float brightness = rgb_brightness.r * 0.21 + rgb_brightness.g * 0.72 + rgb_brightness.b * 0.07; if (brightness > max_brightness) { c.rgb = c.rgb * (max_brightness / brightness); border_color.rgb = border_color.rgb * (max_brightness / brightness); } // Rim color is the color of the outer rim of the window, if there is no // border, it's the color of the window itself, otherwise it's the border. // Using mix() to avoid a branch here. vec4 rim_color = mix(c, border_color, clamp(border_width, 0.0f, 1.0f)); vec2 outer_size = vec2(textureSize(tex, 0)); vec2 inner_size = outer_size - vec2(corner_radius) * 2.0f; float rect_distance = rectangle_sdf(texcoord - outer_size / 2.0f, inner_size / 2.0f) - corner_radius; if (rect_distance > 0.0f) { c = (1.0f - clamp(rect_distance, 0.0f, 1.0f)) * rim_color; } else { float factor = clamp(rect_distance + border_width, 0.0f, 1.0f); c = (1.0f - factor) * c + factor * border_color; } return c; } vec4 window_shader(); float mask_factor(); void main() { gl_FragColor = window_shader() * mask_factor(); } ); const char win_shader_default[] = GLSL(330, in vec2 texcoord; uniform sampler2D tex; vec4 default_post_processing(vec4 c); vec4 window_shader() { vec4 c = texelFetch(tex, ivec2(texcoord), 0); return default_post_processing(c); } ); const char present_vertex_shader[] = GLSL(330, uniform mat4 projection; layout(location = 0) in vec2 coord; out vec2 texcoord; void main() { gl_Position = projection * vec4(coord, 0, 1); texcoord = coord; } ); const char vertex_shader[] = GLSL(330, uniform mat4 projection; uniform float scale = 1.0; uniform vec2 texorig; layout(location = 0) in vec2 coord; layout(location = 1) in vec2 in_texcoord; out vec2 texcoord; void main() { gl_Position = projection * vec4(coord, 0, scale); texcoord = in_texcoord + texorig; } ); const char dither_glsl[] = GLSL(330, // Stolen from: https://www.shadertoy.com/view/7sfXDn float bayer2(vec2 a) { a = floor(a); return fract(a.x / 2. + a.y * a.y * .75); } // 16 * 16 is 2^8, so in total we have equivalent of 16-bit // color depth, should be enough? float bayer(vec2 a16) { vec2 a8 = a16 * .5; vec2 a4 = a8 * .5; vec2 a2 = a4 * .5; float bayer32 = ((bayer2(a2) * .25 + bayer2( a4)) * .25 + bayer2( a8)) * .25 + bayer2(a16); return bayer32; } vec4 dither(vec4 c, vec2 coord) { return vec4(c + bayer(coord) / 255.0); } ); const char shadow_colorization_frag[] = GLSL(330, uniform vec4 color; uniform sampler2D tex; in vec2 texcoord; out vec4 out_color; void main() { vec4 c = texelFetch(tex, ivec2(texcoord), 0); out_color = c.r * color; } ); // clang-format on