*/}}

la_tns_shaders.cpp 33 KB

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  1. /*
  2. * LaGUI: A graphical application framework.
  3. * Copyright (C) 2022-2023 Wu Yiming
  4. *
  5. * This program is free software: you can redistribute it and/or modify
  6. * it under the terms of the GNU General Public License as published by
  7. * the Free Software Foundation, either version 3 of the License, or
  8. * (at your option) any later version.
  9. *
  10. * This program is distributed in the hope that it will be useful,
  11. * but WITHOUT ANY WARRANTY; without even the implied warranty of
  12. * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
  13. * GNU General Public License for more details.
  14. *
  15. * You should have received a copy of the GNU General Public License
  16. * along with this program. If not, see <http://www.gnu.org/licenses/>.
  17. */
  18. #include "la_5.h"
  19. extern "C" const char* TNS_SHADER_COLOR_COMMON=R"(
  20. #define M_PI 3.1415926535897932384626433832795
  21. float rad(float d){ return d/180.0*M_PI; }
  22. float deg(float r){ return r*180.0/M_PI; }
  23. float cbrt( float x ){
  24. return sign(x)*pow(abs(x),1.0f/3.0f);
  25. }
  26. float srgb_transfer_function(float a){
  27. return .0031308f >= a ? 12.92f * a : 1.055f * pow(a, .4166666666666667f) - .055f;
  28. }
  29. float srgb_transfer_function_inv(float a){
  30. return .04045f < a ? pow((a + .055f) / 1.055f, 2.4f) : a / 12.92f;
  31. }
  32. vec3 to_log_srgb(vec3 color){
  33. return vec3(srgb_transfer_function(color.r),srgb_transfer_function(color.g),srgb_transfer_function(color.b));
  34. }
  35. vec3 to_linear_srgb(vec3 color){
  36. return vec3(srgb_transfer_function_inv(color.r),srgb_transfer_function_inv(color.g),srgb_transfer_function_inv(color.b));
  37. }
  38. vec3 to_linear_clay(vec3 color){
  39. return vec3(pow(color.r,2.19921875),pow(color.g,2.19921875),pow(color.b,2.19921875));
  40. }
  41. vec3 to_log_clay(vec3 color){
  42. return vec3(pow(color.r,1.0/2.19921875),pow(color.g,1.0/2.19921875),pow(color.b,1.0/2.19921875));
  43. }
  44. vec3 linear_srgb_to_oklab(vec3 c){
  45. float l = 0.4122214708f * c.r + 0.5363325363f * c.g + 0.0514459929f * c.b;
  46. float m = 0.2119034982f * c.r + 0.6806995451f * c.g + 0.1073969566f * c.b;
  47. float s = 0.0883024619f * c.r + 0.2817188376f * c.g + 0.6299787005f * c.b;
  48. float l_ = cbrt(l);
  49. float m_ = cbrt(m);
  50. float s_ = cbrt(s);
  51. return vec3(
  52. 0.2104542553f * l_ + 0.7936177850f * m_ - 0.0040720468f * s_,
  53. 1.9779984951f * l_ - 2.4285922050f * m_ + 0.4505937099f * s_,
  54. 0.0259040371f * l_ + 0.7827717662f * m_ - 0.8086757660f * s_
  55. );
  56. }
  57. vec3 oklab_to_linear_srgb(vec3 c){
  58. float l_ = c.x + 0.3963377774f * c.y + 0.2158037573f * c.z;
  59. float m_ = c.x - 0.1055613458f * c.y - 0.0638541728f * c.z;
  60. float s_ = c.x - 0.0894841775f * c.y - 1.2914855480f * c.z;
  61. float l = l_ * l_ * l_;
  62. float m = m_ * m_ * m_;
  63. float s = s_ * s_ * s_;
  64. return vec3(
  65. +4.0767416621f * l - 3.3077115913f * m + 0.2309699292f * s,
  66. -1.2684380046f * l + 2.6097574011f * m - 0.3413193965f * s,
  67. -0.0041960863f * l - 0.7034186147f * m + 1.7076147010f * s
  68. );
  69. }
  70. vec3 oklab_to_xyz(vec3 c){
  71. float l_ = c.x + 0.3963377774f * c.y + 0.2158037573f * c.z;
  72. float m_ = c.x - 0.1055613458f * c.y - 0.0638541728f * c.z;
  73. float s_ = c.x - 0.0894841775f * c.y - 1.2914855480f * c.z;
  74. float l = l_ * l_ * l_;
  75. float m = m_ * m_ * m_;
  76. float s = s_ * s_ * s_;
  77. mat3 mat=inverse(mat3(vec3(+0.8189330101,+0.0329845436,+0.0482003018),
  78. vec3(+0.3618667424,+0.9293118715,+0.2643662691),
  79. vec3(-0.1288597137,+0.0361456387,+0.6338517070)));
  80. return mat*vec3(l,m,s);
  81. }
  82. float compute_max_saturation(float a, float b){ float k0, k1, k2, k3, k4, wl, wm, ws;
  83. if (-1.88170328f * a - 0.80936493f * b > 1.f){ k0 = +1.19086277f; k1 = +1.76576728f; k2 = +0.59662641f; k3 = +0.75515197f; k4 = +0.56771245f;
  84. wl = +4.0767416621f; wm = -3.3077115913f; ws = +0.2309699292f;
  85. }
  86. else if (1.81444104f * a - 1.19445276f * b > 1.f){ k0 = +0.73956515f; k1 = -0.45954404f; k2 = +0.08285427f; k3 = +0.12541070f; k4 = +0.14503204f;
  87. wl = -1.2684380046f; wm = +2.6097574011f; ws = -0.3413193965f;
  88. }
  89. else{ k0 = +1.35733652f; k1 = -0.00915799f; k2 = -1.15130210f; k3 = -0.50559606f; k4 = +0.00692167f;
  90. wl = -0.0041960863f; wm = -0.7034186147f; ws = +1.7076147010f;
  91. } float S = k0 + k1 * a + k2 * b + k3 * a * a + k4 * a * b;
  92. float k_l = +0.3963377774f * a + 0.2158037573f * b;
  93. float k_m = -0.1055613458f * a - 0.0638541728f * b;
  94. float k_s = -0.0894841775f * a - 1.2914855480f * b;{
  95. float l_ = 1.f + S * k_l;
  96. float m_ = 1.f + S * k_m;
  97. float s_ = 1.f + S * k_s;
  98. float l = l_ * l_ * l_;
  99. float m = m_ * m_ * m_;
  100. float s = s_ * s_ * s_;
  101. float l_dS = 3.f * k_l * l_ * l_;
  102. float m_dS = 3.f * k_m * m_ * m_;
  103. float s_dS = 3.f * k_s * s_ * s_;
  104. float l_dS2 = 6.f * k_l * k_l * l_;
  105. float m_dS2 = 6.f * k_m * k_m * m_;
  106. float s_dS2 = 6.f * k_s * k_s * s_;
  107. float f = wl * l + wm * m + ws * s;
  108. float f1 = wl * l_dS + wm * m_dS + ws * s_dS;
  109. float f2 = wl * l_dS2 + wm * m_dS2 + ws * s_dS2;
  110. S = S - f * f1 / (f1 * f1 - 0.5f * f * f2);
  111. }
  112. return S;
  113. }
  114. vec2 find_cusp(float a, float b){ float S_cusp = compute_max_saturation(a, b); vec3 rgb_at_max = oklab_to_linear_srgb(vec3( 1, S_cusp * a, S_cusp * b ));
  115. float L_cusp = cbrt(1.f / max(max(rgb_at_max.r, rgb_at_max.g), rgb_at_max.b));
  116. float C_cusp = L_cusp * S_cusp;
  117. return vec2( L_cusp , C_cusp );
  118. }
  119. float find_gamut_intersection(float a, float b, float L1, float C1, float L0, vec2 cusp){ float t;
  120. if (((L1 - L0) * cusp.y - (cusp.x - L0) * C1) <= 0.f){
  121. t = cusp.y * L0 / (C1 * cusp.x + cusp.y * (L0 - L1));
  122. }
  123. else{ t = cusp.y * (L0 - 1.f) / (C1 * (cusp.x - 1.f) + cusp.y * (L0 - L1)); {
  124. float dL = L1 - L0;
  125. float dC = C1;
  126. float k_l = +0.3963377774f * a + 0.2158037573f * b;
  127. float k_m = -0.1055613458f * a - 0.0638541728f * b;
  128. float k_s = -0.0894841775f * a - 1.2914855480f * b;
  129. float l_dt = dL + dC * k_l;
  130. float m_dt = dL + dC * k_m;
  131. float s_dt = dL + dC * k_s; {
  132. float L = L0 * (1.f - t) + t * L1;
  133. float C = t * C1;
  134. float l_ = L + C * k_l;
  135. float m_ = L + C * k_m;
  136. float s_ = L + C * k_s;
  137. float l = l_ * l_ * l_;
  138. float m = m_ * m_ * m_;
  139. float s = s_ * s_ * s_;
  140. float ldt = 3.f * l_dt * l_ * l_;
  141. float mdt = 3.f * m_dt * m_ * m_;
  142. float sdt = 3.f * s_dt * s_ * s_;
  143. float ldt2 = 6.f * l_dt * l_dt * l_;
  144. float mdt2 = 6.f * m_dt * m_dt * m_;
  145. float sdt2 = 6.f * s_dt * s_dt * s_;
  146. float r = 4.0767416621f * l - 3.3077115913f * m + 0.2309699292f * s - 1.f;
  147. float r1 = 4.0767416621f * ldt - 3.3077115913f * mdt + 0.2309699292f * sdt;
  148. float r2 = 4.0767416621f * ldt2 - 3.3077115913f * mdt2 + 0.2309699292f * sdt2;
  149. float u_r = r1 / (r1 * r1 - 0.5f * r * r2);
  150. float t_r = -r * u_r;
  151. float g = -1.2684380046f * l + 2.6097574011f * m - 0.3413193965f * s - 1.f;
  152. float g1 = -1.2684380046f * ldt + 2.6097574011f * mdt - 0.3413193965f * sdt;
  153. float g2 = -1.2684380046f * ldt2 + 2.6097574011f * mdt2 - 0.3413193965f * sdt2;
  154. float u_g = g1 / (g1 * g1 - 0.5f * g * g2);
  155. float t_g = -g * u_g;
  156. float b = -0.0041960863f * l - 0.7034186147f * m + 1.7076147010f * s - 1.f;
  157. float b1 = -0.0041960863f * ldt - 0.7034186147f * mdt + 1.7076147010f * sdt;
  158. float b2 = -0.0041960863f * ldt2 - 0.7034186147f * mdt2 + 1.7076147010f * sdt2;
  159. float u_b = b1 / (b1 * b1 - 0.5f * b * b2);
  160. float t_b = -b * u_b;
  161. t_r = u_r >= 0.f ? t_r : 10000.f;
  162. t_g = u_g >= 0.f ? t_g : 10000.f;
  163. t_b = u_b >= 0.f ? t_b : 10000.f;
  164. t += min(t_r, min(t_g, t_b));
  165. }
  166. }
  167. }
  168. return t;
  169. }
  170. float find_gamut_intersection(float a, float b, float L1, float C1, float L0){ vec2 cusp = find_cusp(a, b);
  171. return find_gamut_intersection(a, b, L1, C1, L0, cusp);
  172. }
  173. vec3 gamut_clip_preserve_chroma(vec3 rgb){
  174. if (rgb.r < 1.f && rgb.g < 1.f && rgb.b < 1.f && rgb.r > 0.f && rgb.g > 0.f && rgb.b > 0.f)
  175. return rgb;
  176. vec3 lab = linear_srgb_to_oklab(rgb);
  177. float L = lab.x;
  178. float eps = 0.00001f;
  179. float C = max(eps, sqrt(lab.y * lab.y + lab.z * lab.z));
  180. float a_ = lab.y / C;
  181. float b_ = lab.z / C;
  182. float L0 = clamp(L, 0.f, 1.f);
  183. float t = find_gamut_intersection(a_, b_, L, C, L0);
  184. float L_clipped = L0 * (1.f - t) + t * L;
  185. float C_clipped = t * C;
  186. return oklab_to_linear_srgb(vec3( L_clipped, C_clipped * a_, C_clipped * b_ ));
  187. }
  188. vec3 gamut_clip_project_to_0_5(vec3 rgb){
  189. if (rgb.r < 1.f && rgb.g < 1.f && rgb.b < 1.f && rgb.r > 0.f && rgb.g > 0.f && rgb.b > 0.f)
  190. return rgb;
  191. vec3 lab = linear_srgb_to_oklab(rgb);
  192. float L = lab.x;
  193. float eps = 0.00001f;
  194. float C = max(eps, sqrt(lab.y * lab.y + lab.z * lab.z));
  195. float a_ = lab.y / C;
  196. float b_ = lab.z / C;
  197. float L0 = 0.5;
  198. float t = find_gamut_intersection(a_, b_, L, C, L0);
  199. float L_clipped = L0 * (1.f - t) + t * L;
  200. float C_clipped = t * C;
  201. return oklab_to_linear_srgb(vec3( L_clipped, C_clipped * a_, C_clipped * b_ ));
  202. }
  203. vec3 gamut_clip_project_to_L_cusp(vec3 rgb){
  204. if (rgb.r < 1.f && rgb.g < 1.f && rgb.b < 1.f && rgb.r > 0.f && rgb.g > 0.f && rgb.b > 0.f)
  205. return rgb;
  206. vec3 lab = linear_srgb_to_oklab(rgb);
  207. float L = lab.x;
  208. float eps = 0.00001f;
  209. float C = max(eps, sqrt(lab.y * lab.y + lab.z * lab.z));
  210. float a_ = lab.y / C;
  211. float b_ = lab.z / C; vec2 cusp = find_cusp(a_, b_);
  212. float L0 = cusp.x;
  213. float t = find_gamut_intersection(a_, b_, L, C, L0);
  214. float L_clipped = L0 * (1.f - t) + t * L;
  215. float C_clipped = t * C;
  216. return oklab_to_linear_srgb(vec3( L_clipped, C_clipped * a_, C_clipped * b_ ));
  217. }
  218. vec3 gamut_clip_adaptive_L0_0_5(vec3 rgb, float alpha){
  219. if (rgb.r < 1.f && rgb.g < 1.f && rgb.b < 1.f && rgb.r > 0.f && rgb.g > 0.f && rgb.b > 0.f)
  220. return rgb;
  221. vec3 lab = linear_srgb_to_oklab(rgb);
  222. float L = lab.x;
  223. float eps = 0.00001f;
  224. float C = max(eps, sqrt(lab.y * lab.y + lab.z * lab.z));
  225. float a_ = lab.y / C;
  226. float b_ = lab.z / C;
  227. float Ld = L - 0.5f;
  228. float e1 = 0.5f + abs(Ld) + alpha * C;
  229. float L0 = 0.5f * (1.f + sign(Ld) * (e1 - sqrt(e1 * e1 - 2.f * abs(Ld))));
  230. float t = find_gamut_intersection(a_, b_, L, C, L0);
  231. float L_clipped = L0 * (1.f - t) + t * L;
  232. float C_clipped = t * C;
  233. return oklab_to_linear_srgb(vec3( L_clipped, C_clipped * a_, C_clipped * b_ ));
  234. }
  235. vec3 gamut_clip_adaptive_L0_L_cusp(vec3 rgb, float alpha){
  236. if (rgb.r < 1.f && rgb.g < 1.f && rgb.b < 1.f && rgb.r > 0.f && rgb.g > 0.f && rgb.b > 0.f)
  237. return rgb;
  238. vec3 lab = linear_srgb_to_oklab(rgb);
  239. float L = lab.x;
  240. float eps = 0.00001f;
  241. float C = max(eps, sqrt(lab.y * lab.y + lab.z * lab.z));
  242. float a_ = lab.y / C;
  243. float b_ = lab.z / C; vec2 cusp = find_cusp(a_, b_);
  244. float Ld = L - cusp.x;
  245. float k = 2.f * (Ld > 0.f ? 1.f - cusp.x : cusp.x);
  246. float e1 = 0.5f * k + abs(Ld) + alpha * C / k;
  247. float L0 = cusp.x + 0.5f * (sign(Ld) * (e1 - sqrt(e1 * e1 - 2.f * k * abs(Ld))));
  248. float t = find_gamut_intersection(a_, b_, L, C, L0);
  249. float L_clipped = L0 * (1.f - t) + t * L;
  250. float C_clipped = t * C;
  251. return oklab_to_linear_srgb(vec3( L_clipped, C_clipped * a_, C_clipped * b_ ));
  252. }
  253. float toe(float x){
  254. float k_1 = 0.206f;
  255. float k_2 = 0.03f;
  256. float k_3 = (1.f + k_1) / (1.f + k_2);
  257. return 0.5f * (k_3 * x - k_1 + sqrt((k_3 * x - k_1) * (k_3 * x - k_1) + 4.f * k_2 * k_3 * x));
  258. }
  259. float toe_inv(float x){
  260. float k_1 = 0.206f;
  261. float k_2 = 0.03f;
  262. float k_3 = (1.f + k_1) / (1.f + k_2);
  263. return (x * x + k_1 * x) / (k_3 * (x + k_2));
  264. }
  265. vec2 to_ST(vec2 cusp){
  266. float L = cusp.x;
  267. float C = cusp.y;
  268. return vec2( C / L, C / (1.f - L) );
  269. }
  270. vec2 get_ST_mid(float a_, float b_){
  271. float S = 0.11516993f + 1.f / (
  272. +7.44778970f + 4.15901240f * b_
  273. + a_ * (-2.19557347f + 1.75198401f * b_
  274. + a_ * (-2.13704948f - 10.02301043f * b_
  275. + a_ * (-4.24894561f + 5.38770819f * b_ + 4.69891013f * a_
  276. )))
  277. );
  278. float T = 0.11239642f + 1.f / (
  279. +1.61320320f - 0.68124379f * b_
  280. + a_ * (+0.40370612f + 0.90148123f * b_
  281. + a_ * (-0.27087943f + 0.61223990f * b_
  282. + a_ * (+0.00299215f - 0.45399568f * b_ - 0.14661872f * a_
  283. )))
  284. );
  285. return vec2( S, T );
  286. }
  287. vec3 get_Cs(float L, float a_, float b_){
  288. vec2 cusp = find_cusp(a_, b_);
  289. float C_max = find_gamut_intersection(a_, b_, L, 1.f, L, cusp);
  290. vec2 ST_max = to_ST(cusp); float k = C_max / min((L * ST_max.x), (1.f - L) * ST_max.y);
  291. float C_mid;{
  292. vec2 ST_mid = get_ST_mid(a_, b_); float C_a = L * ST_mid.x;
  293. float C_b = (1.f - L) * ST_mid.y;
  294. C_mid = 0.9f * k * sqrt(sqrt(1.f / (1.f / (C_a * C_a * C_a * C_a) + 1.f / (C_b * C_b * C_b * C_b))));
  295. }
  296. float C_0;{ float C_a = L * 0.4f;
  297. float C_b = (1.f - L) * 0.8f; C_0 = sqrt(1.f / (1.f / (C_a * C_a) + 1.f / (C_b * C_b)));
  298. }
  299. return vec3( C_0, C_mid, C_max );
  300. }
  301. vec3 okhsl_to_srgb(vec3 hsl){
  302. float h = hsl.x;
  303. float s = hsl.y;
  304. float l = hsl.z;
  305. if (l == 1.0f){
  306. return vec3( 1.f, 1.f, 1.f );
  307. }
  308. else if (l == 0.f){
  309. return vec3( 0.f, 0.f, 0.f );
  310. }
  311. float a_ = cos(2.f * M_PI * h);
  312. float b_ = sin(2.f * M_PI * h);
  313. float L = toe_inv(l);
  314. vec3 cs = get_Cs(L, a_, b_);
  315. float C_0 = cs.x;
  316. float C_mid = cs.y;
  317. float C_max = cs.z;
  318. float mid = 0.8f;
  319. float mid_inv = 1.25f;
  320. float C, t, k_0, k_1, k_2;
  321. if (s < mid){
  322. t = mid_inv * s;
  323. k_1 = mid * C_0;
  324. k_2 = (1.f - k_1 / C_mid);
  325. C = t * k_1 / (1.f - k_2 * t);
  326. }
  327. else{
  328. t = (s - mid)/ (1.f - mid);
  329. k_0 = C_mid;
  330. k_1 = (1.f - mid) * C_mid * C_mid * mid_inv * mid_inv / C_0;
  331. k_2 = (1.f - (k_1) / (C_max - C_mid));
  332. C = k_0 + t * k_1 / (1.f - k_2 * t);
  333. }
  334. vec3 rgb = oklab_to_linear_srgb(vec3( L, C * a_, C * b_ ));
  335. return vec3(
  336. srgb_transfer_function(rgb.r),
  337. srgb_transfer_function(rgb.g),
  338. srgb_transfer_function(rgb.b)
  339. );
  340. }
  341. vec3 okhsl_to_linear_srgb(vec3 hsl){
  342. float h = hsl.x;
  343. float s = hsl.y;
  344. float l = hsl.z;
  345. if (l == 1.0f){
  346. return vec3( 1.f, 1.f, 1.f );
  347. }
  348. else if (l == 0.f){
  349. return vec3( 0.f, 0.f, 0.f );
  350. }
  351. float a_ = cos(2.f * M_PI * h);
  352. float b_ = sin(2.f * M_PI * h);
  353. float L = toe_inv(l);
  354. vec3 cs = get_Cs(L, a_, b_);
  355. float C_0 = cs.x;
  356. float C_mid = cs.y;
  357. float C_max = cs.z;
  358. float mid = 0.8f;
  359. float mid_inv = 1.25f;
  360. float C, t, k_0, k_1, k_2;
  361. if (s < mid){
  362. t = mid_inv * s;
  363. k_1 = mid * C_0;
  364. k_2 = (1.f - k_1 / C_mid);
  365. C = t * k_1 / (1.f - k_2 * t);
  366. }
  367. else{
  368. t = (s - mid)/ (1.f - mid);
  369. k_0 = C_mid;
  370. k_1 = (1.f - mid) * C_mid * C_mid * mid_inv * mid_inv / C_0;
  371. k_2 = (1.f - (k_1) / (C_max - C_mid));
  372. C = k_0 + t * k_1 / (1.f - k_2 * t);
  373. }
  374. return oklab_to_linear_srgb(vec3( L, C * a_, C * b_ ));
  375. }
  376. vec3 okhsl_to_xyz(vec3 hsl){
  377. float h = hsl.x;
  378. float s = hsl.y;
  379. float l = hsl.z;
  380. if (l == 1.0f){
  381. return vec3( 1.f, 1.f, 1.f );
  382. }
  383. else if (l == 0.f){
  384. return vec3( 0.f, 0.f, 0.f );
  385. }
  386. float a_ = cos(2.f * M_PI * h);
  387. float b_ = sin(2.f * M_PI * h);
  388. float L = toe_inv(l);
  389. vec3 cs = get_Cs(L, a_, b_);
  390. float C_0 = cs.x;
  391. float C_mid = cs.y;
  392. float C_max = cs.z;
  393. float mid = 0.8f;
  394. float mid_inv = 1.25f;
  395. float C, t, k_0, k_1, k_2;
  396. if (s < mid){
  397. t = mid_inv * s;
  398. k_1 = mid * C_0;
  399. k_2 = (1.f - k_1 / C_mid);
  400. C = t * k_1 / (1.f - k_2 * t);
  401. }
  402. else{
  403. t = (s - mid)/ (1.f - mid);
  404. k_0 = C_mid;
  405. k_1 = (1.f - mid) * C_mid * C_mid * mid_inv * mid_inv / C_0;
  406. k_2 = (1.f - (k_1) / (C_max - C_mid));
  407. C = k_0 + t * k_1 / (1.f - k_2 * t);
  408. }
  409. return oklab_to_xyz(vec3( L, C * a_, C * b_ ));
  410. }
  411. vec3 srgb_to_okhsl(vec3 rgb){
  412. vec3 lab = linear_srgb_to_oklab(vec3(
  413. srgb_transfer_function_inv(rgb.r),
  414. srgb_transfer_function_inv(rgb.g),
  415. srgb_transfer_function_inv(rgb.b)
  416. ));
  417. float C = sqrt(lab.y * lab.y + lab.z * lab.z);
  418. float a_ = lab.y / C;
  419. float b_ = lab.z / C;
  420. float L = lab.x;
  421. float h = 0.5f + 0.5f * atan(-lab.z, -lab.y) / M_PI;
  422. vec3 cs = get_Cs(L, a_, b_);
  423. float C_0 = cs.x;
  424. float C_mid = cs.y;
  425. float C_max = cs.z;
  426. float mid = 0.8f;
  427. float mid_inv = 1.25f;
  428. float s;
  429. if (C < C_mid){
  430. float k_1 = mid * C_0;
  431. float k_2 = (1.f - k_1 / C_mid);
  432. float t = C / (k_1 + k_2 * C);
  433. s = t * mid;
  434. }
  435. else{
  436. float k_0 = C_mid;
  437. float k_1 = (1.f - mid) * C_mid * C_mid * mid_inv * mid_inv / C_0;
  438. float k_2 = (1.f - (k_1) / (C_max - C_mid));
  439. float t = (C - k_0) / (k_1 + k_2 * (C - k_0));
  440. s = mid + (1.f - mid) * t;
  441. }
  442. float l = toe(L);
  443. return vec3( h, s, l );
  444. }
  445. vec3 okhsv_to_srgb(vec3 hsv){
  446. float h = hsv.x;
  447. float s = hsv.y;
  448. float v = hsv.z;
  449. float a_ = cos(2.f * M_PI * h);
  450. float b_ = sin(2.f * M_PI * h);
  451. vec2 cusp = find_cusp(a_, b_);
  452. vec2 ST_max = to_ST(cusp);
  453. float S_max = ST_max.x;
  454. float T_max = ST_max.y;
  455. float S_0 = 0.5f;
  456. float k = 1.f- S_0 / S_max; float L_v = 1.f - s * S_0 / (S_0 + T_max - T_max * k * s);
  457. float C_v = s * T_max * S_0 / (S_0 + T_max - T_max * k * s);
  458. float L = v * L_v;
  459. float C = v * C_v; float L_vt = toe_inv(L_v);
  460. float C_vt = C_v * L_vt / L_v;
  461. float L_new = toe_inv(L);
  462. C = C * L_new / L;
  463. L = L_new;
  464. vec3 rgb_scale = oklab_to_linear_srgb(vec3( L_vt, a_ * C_vt, b_ * C_vt ));
  465. float scale_L = cbrt(1.f / max(max(rgb_scale.r, rgb_scale.g), max(rgb_scale.b, 0.f)));
  466. L = L * scale_L;
  467. C = C * scale_L;
  468. vec3 rgb = oklab_to_linear_srgb(vec3( L, C * a_, C * b_ ));
  469. return vec3(
  470. srgb_transfer_function(rgb.r),
  471. srgb_transfer_function(rgb.g),
  472. srgb_transfer_function(rgb.b)
  473. );
  474. })" R"(
  475. vec3 srgb_to_okhsv(vec3 rgb){
  476. vec3 lab = linear_srgb_to_oklab(vec3(
  477. srgb_transfer_function_inv(rgb.r),
  478. srgb_transfer_function_inv(rgb.g),
  479. srgb_transfer_function_inv(rgb.b)
  480. ));
  481. float C = sqrt(lab.y * lab.y + lab.z * lab.z);
  482. float a_ = lab.y / C;
  483. float b_ = lab.z / C;
  484. float L = lab.x;
  485. float h = 0.5f + 0.5f * atan(-lab.z, -lab.y) / M_PI;
  486. vec2 cusp = find_cusp(a_, b_);
  487. vec2 ST_max = to_ST(cusp);
  488. float S_max = ST_max.x;
  489. float T_max = ST_max.y;
  490. float S_0 = 0.5f;
  491. float k = 1.f - S_0 / S_max;
  492. float t = T_max / (C + L * T_max);
  493. float L_v = t * L;
  494. float C_v = t * C;
  495. float L_vt = toe_inv(L_v);
  496. float C_vt = C_v * L_vt / L_v; vec3 rgb_scale = oklab_to_linear_srgb(vec3( L_vt, a_ * C_vt, b_ * C_vt ));
  497. float scale_L = cbrt(1.f / max(max(rgb_scale.r, rgb_scale.g), max(rgb_scale.b, 0.f)));
  498. L = L / scale_L;
  499. C = C / scale_L;
  500. C = C * toe(L) / L;
  501. L = toe(L);
  502. float v = L / L_v;
  503. float s = (S_0 + T_max) * C_v / ((T_max * S_0) + T_max * k * C_v);
  504. return vec3 (h, s, v );
  505. }
  506. vec3 sRGB2XYZ(vec3 color){
  507. mat3 mat=mat3(vec3(0.4124564,0.3575761,0.1804375),
  508. vec3(0.2126729,0.7151522,0.0721750),
  509. vec3(0.0193339,0.1191920,0.9503041));
  510. return color*mat;
  511. }
  512. vec3 Clay2XYZ(vec3 color){
  513. mat3 mat=mat3(vec3(0.5767309,0.1855540,0.1881852),
  514. vec3(0.2973769,0.6273491,0.0752741),
  515. vec3(0.0270343,0.0706872,0.9911085));
  516. return color*mat;
  517. }
  518. vec3 XYZ2sRGB(vec3 xyz){
  519. mat3 mat=mat3(vec3(3.2404542,-1.5371385,-0.4985314),
  520. vec3(-0.9692660,1.8760108,0.0415560),
  521. vec3(0.0556434,-0.2040259,1.0572252));
  522. return xyz*mat;
  523. }
  524. vec3 XYZ2Clay(vec3 xyz){
  525. mat3 mat=mat3(vec3(2.0413690,-0.5649464,-0.3446944),
  526. vec3(-0.9692660,1.8760108,0.0415560),
  527. vec3(0.0134474,-0.1183897,1.0154096));
  528. return xyz*mat;
  529. }
  530. #define htsize HalftoneSize
  531. vec4 rgb2cmyk(vec3 rgb){
  532. vec4 cmyk; cmyk.w=1.-max(max(rgb.r,rgb.g),rgb.b);
  533. float k1=1.-cmyk.w;
  534. cmyk.r=(k1-rgb.r)/k1; cmyk.g=(k1-rgb.g)/k1; cmyk.b=(k1-rgb.b)/k1;
  535. return cmyk;
  536. }
  537. vec3 cmyk2rgb(vec4 cmyk){
  538. vec3 rgb; float k1=1.-cmyk.w;
  539. rgb.r=(1.-cmyk.r)*k1; rgb.g=(1.-cmyk.g)*k1; rgb.b=(1.-cmyk.b)*k1;
  540. return rgb;
  541. }
  542. float rand(vec2 co){
  543. return fract(sin(dot(co, vec2(12.9898, 78.233))) * 43758.5453);
  544. }
  545. float HalftoneSingle(float a,float ps,float theta,float sm){
  546. float psize=ps; vec2 ctr=vec2(psize/2.,psize/2.); vec2 pt=vec2(psize,psize);
  547. vec2 xy=gl_FragCoord.xy; xy=vec2(sin(theta)*xy.x-cos(theta)*xy.y,cos(theta)*xy.x+sin(theta)*xy.y);
  548. xy.x=xy.x+rand(xy)/1.; xy.y=xy.y+rand(xy)/1.; ivec2 xyi=ivec2(int(xy.x/psize),int(xy.y/psize));
  549. vec2 xyf=mod(xy,pt);
  550. float px1=(sm==1.)?(3.0f/psize):(0.000001);
  551. float cmp=(pow(a,1.)*psize/2.*(1.414+px1)); float fac=distance(xyf,ctr)/cmp;
  552. return smoothstep(1.+px1,1.-px1,fac);
  553. }
  554. vec4 halftone(vec4 color){
  555. vec4 cmyk=rgb2cmyk(color.rgb); float a=color.a*(gl_FragCoord.x/400.0f);
  556. cmyk.r=HalftoneSingle(cmyk.r,htsize,rad(15.0),1.);
  557. cmyk.g=HalftoneSingle(cmyk.g,htsize,rad(75.0),1.);
  558. cmyk.b=HalftoneSingle(cmyk.b,htsize,rad(0.),1.);
  559. cmyk.a=HalftoneSingle(cmyk.a,htsize,rad(45.0),1.);
  560. color.rgb=cmyk2rgb(cmyk);
  561. //color.a=HalftoneSingle(a,htsize,rad(30),0);
  562. return color;
  563. }
  564. )";
  565. extern "C" const char* TNS_VERTEX_SIMPLE_MATCAP = R"(#version 310 es
  566. precision highp float;
  567. uniform mat4 mProjection;
  568. uniform mat4 mModel;
  569. uniform mat4 mView;
  570. in vec4 vVertex;
  571. in vec3 vNormal;
  572. smooth out vec3 fNormal;
  573. void main(){
  574. gl_Position = mProjection * mView * mModel * vVertex;
  575. vec3 N = ( mView * mModel * vec4(vNormal,0)).xyz;
  576. fNormal = normalize(N);
  577. })";
  578. extern "C" const char* TNS_FRAGMENT_SIMPLE_MATCAP = R"(#version 310 es
  579. precision highp float;
  580. smooth in vec3 fNormal;
  581. out vec4 outColor;
  582. float Interpolate(float between1,float between2,float value1,float value2,float key){
  583. float i = (key-between1)/(between2-between1);
  584. return value1*(1.-i)+value2*i;
  585. }
  586. void main(){
  587. float value = dot(vec3(0,0,1),fNormal);
  588. if(value<0.65) value=0.15;
  589. else if(value>=0.65 && value<0.85) value=Interpolate(0.65,0.85,0.15,0.75,value);
  590. else if(value>=0.85 && value<0.95) value=0.75;
  591. else if(value>=0.95) value=0.9;
  592. outColor = vec4(vec3(0.84, 0.41, 0.16)*value,1);
  593. })";
  594. extern "C" const char* TNS_VERTEX_GRID = R"(#version 310 es
  595. precision highp float;
  596. uniform mat4 mProjection;
  597. uniform mat4 mModel;
  598. uniform mat4 mView;
  599. in vec4 vVertex;
  600. in vec4 vColor;
  601. in vec2 vUV;
  602. out vec4 fColor;
  603. out vec2 uv;
  604. void main(){
  605. vec4 pos = mProjection * mView * mModel * vVertex;
  606. gl_Position = pos;
  607. fColor = vColor;
  608. uv = vUV;
  609. })";
  610. extern "C" const char* TNS_FRAGMENT_TRANSPARNT_GRID = R"(#version 310 es
  611. precision highp float;
  612. in vec4 fColor;
  613. in vec2 uv;
  614. out vec4 outColor;
  615. void main(){
  616. vec4 c = fColor;
  617. c.a = sin(uv.x)*sin(uv.y)>0.?c.a:0.;
  618. outColor = c;
  619. })";
  620. extern "C" const char* LA_IMM_VERTEX_SHADER = R"(#version 310 es
  621. precision highp float;
  622. uniform mat4 mProjection;
  623. uniform mat4 mModel;
  624. uniform mat4 mView;
  625. uniform int DoOffset;
  626. in vec4 vVertex;
  627. in vec4 vColor;
  628. in vec3 vNormal;
  629. in vec2 vUV;
  630. out vec4 fColor;
  631. out vec2 fUV;
  632. flat out vec3 fNormal;
  633. out vec3 fGPos;
  634. void main(){
  635. vec4 pos=mProjection * mView * mModel * vVertex;
  636. if(DoOffset!=0){ pos.xyw*=1.0+0.00005*float(DoOffset); }
  637. gl_Position = pos;
  638. fColor = vColor;
  639. fUV=vUV;
  640. fGPos=vec3((mModel * vVertex).xyz);
  641. fNormal= normalize((mModel * vec4(vNormal,0.)).xyz);
  642. })";
  643. extern "C" const char* LA_IMM_FRAGMENT_SHADER = R"(#version 310 es
  644. precision highp float;
  645. uniform highp sampler2D TexColor;\
  646. uniform highp sampler2DMS TexColorMS;\
  647. uniform int TextureMode;
  648. uniform int ColorMode;
  649. uniform int MultiplyColor;
  650. uniform int SampleAmount;
  651. uniform int UseNormal;
  652. uniform float UseHalftone;
  653. uniform float HalftoneSize;
  654. uniform int InputColorSpace;
  655. uniform int OutputColorSpace;
  656. uniform int Composing;
  657. uniform float ComposingGamma;
  658. uniform float ComposingBlackpoint;
  659. uniform int ShowStripes;
  660. uniform float HCYGamma;
  661. uniform vec3 uObjectPos;
  662. uniform vec3 uViewPos;
  663. uniform vec3 uViewDir;
  664. in vec4 fColor;
  665. in vec2 fUV;
  666. flat in vec3 fNormal;
  667. in vec3 fGPos;
  668. layout(location = 0) out vec4 outColor;
  669. layout(location = 1) out vec3 outNormal;
  670. layout(location = 2) out vec3 outGPos;
  671. #with TNS_SHADER_COLOR_COMMON
  672. #with TNS_SHADER_LIBRARY
  673. vec3 ConvertColorSpace(vec3 color){
  674. if(InputColorSpace!=OutputColorSpace){
  675. if(ColorMode==0){
  676. if(InputColorSpace==0) color=to_linear_srgb(color);
  677. else if(InputColorSpace==1) color=to_linear_clay(color);
  678. }
  679. vec3 xyz; if(ColorMode==1){ color.y=pow(color.y,max(HCYGamma,1.)); color=okhsl_to_linear_srgb(color); }
  680. if(InputColorSpace==1){ xyz=Clay2XYZ(color); }
  681. if(InputColorSpace==0){ xyz=sRGB2XYZ(color); }
  682. if(OutputColorSpace==0){ color=to_log_srgb(XYZ2sRGB(xyz)); }
  683. if(OutputColorSpace==1){ color=to_log_clay(XYZ2Clay(xyz)); }
  684. }else{
  685. if(ColorMode==1){ color.y=pow(color.y,max(HCYGamma,1.)); color=okhsl_to_srgb(color); }
  686. else if(ColorMode==0){ color=color; }
  687. else{
  688. if(OutputColorSpace==0){ color=to_log_srgb(color); }
  689. if(OutputColorSpace==1){ color=to_log_clay(color); }
  690. }
  691. }
  692. if(ShowStripes!=0){
  693. if(color.r>1.00001||color.g>1.00001||color.b>1.00001||color.r<0.||color.g<0.||color.b<0.){ color=mix(color,vec3(0.5,0.5,0.5),(sin((gl_FragCoord.x+gl_FragCoord.y)/2.)>0.)?1.:0.5); }
  694. }
  695. return color;
  696. }
  697. void main(){
  698. vec4 color=vec4(1,0,1,1);
  699. if(TextureMode==0){ color = fColor; if(UseHalftone>0.) color.a=HalftoneSingle(color.a,htsize,rad(7.),0.); }
  700. else if(TextureMode==1){color = vec4(fColor.rgb,fColor.a*texture(TexColor,fUV.st).r);}
  701. else if(TextureMode==2){
  702. color=texture(TexColor,fUV.st);
  703. if(MultiplyColor!=0){color*=fColor;}
  704. }else if(TextureMode==3){
  705. color=vec4(0,0,0,0);
  706. ivec2 texSize = textureSize(TexColorMS);
  707. for(int i=0;i<SampleAmount;i++){ vec4 res=texelFetch(TexColorMS, ivec2(fUV * vec2(texSize)),i); if(res[0]>-1e19) color+=res; };
  708. color/=float(SampleAmount);
  709. if(MultiplyColor!=0){color*=fColor;}
  710. }
  711. if(UseNormal!=0){
  712. color.a=HalftoneSingle(color.a,htsize,rad(7.),0.);
  713. if(color.a==0.) discard;
  714. float light_factor=dot(fNormal,vec3(0,0,1));
  715. vec3 vd=uViewDir;
  716. if(length(uViewDir)<0.5){ vd=fGPos-uViewPos; }
  717. float view=dot(fNormal,vd);
  718. float factor=abs(light_factor);
  719. if(light_factor*view>0.){ factor=0.; }
  720. color=vec4(color.rgb*mix(0.2,1.,factor),color.a);
  721. vec3 oNormal=fNormal; if(view<0.){ oNormal=-fNormal; }
  722. outNormal = oNormal;
  723. }
  724. color=vec4(ConvertColorSpace(color.rgb),color.a); color.a=clamp(color.a,0.,1.);
  725. if(Composing!=0){
  726. if(color.rgb!=vec3(0,0,0)){
  727. //vec3 cl=srgb_to_okhsl(color.rgb);
  728. //cl.z=cl.z/1.0f*(1.0f-ComposingBlackpoint)+ComposingBlackpoint;
  729. //cl.z=pow(cl.z,ComposingGamma);
  730. //color.rgb=okhsl_to_srgb(cl);
  731. color.rgb=pow(color.rgb,vec3(ComposingGamma,ComposingGamma,ComposingGamma));
  732. color.r=color.r/1.0f*(1.0f-ComposingBlackpoint)+ComposingBlackpoint;
  733. color.g=color.g/1.0f*(1.0f-ComposingBlackpoint)+ComposingBlackpoint;
  734. color.b=color.b/1.0f*(1.0f-ComposingBlackpoint)+ComposingBlackpoint;
  735. }else{
  736. color.rgb=vec3(ComposingBlackpoint,ComposingBlackpoint,ComposingBlackpoint);
  737. }
  738. }
  739. if(UseHalftone>1e-6){ color=mix(color,halftone(color),UseHalftone); }
  740. outColor = color;
  741. outGPos = fGPos;
  742. })";
  743. extern "C" const char* LA_OBJECT_FRAGMENT_SHADER = R"(#version 310 es
  744. precision highp float;
  745. uniform int UseNormal;
  746. uniform float UseHalftone;
  747. uniform float HalftoneSize;
  748. uniform vec3 uObjectPos;
  749. uniform vec3 uViewPos;
  750. uniform vec3 uViewDir;
  751. in vec4 fColor;
  752. in vec2 fUV;
  753. flat in vec3 fNormal;
  754. in vec3 fGPos;
  755. layout(location = 0) out vec4 outColor;
  756. layout(location = 1) out vec3 outNormal;
  757. layout(location = 2) out vec3 outGPos;
  758. #with TNS_SHADER_COLOR_COMMON
  759. #with TNS_SHADER_LIBRARY
  760. void main(){
  761. vec4 color=fColor;
  762. {
  763. #with TNS_SHADER_MATERIAL
  764. }
  765. if(UseNormal!=0){
  766. color.a=HalftoneSingle(color.a,htsize,rad(7),0);
  767. if(color.a==0) discard;
  768. float light_factor=dot(fNormal,vec3(0,0,1));
  769. vec3 vd=uViewDir;
  770. if(len(uViewDir)<0.5){ vd=fGPos-uViewPos; }
  771. float view=dot(fNormal,vd);
  772. float factor=abs(light_factor);
  773. if(light_factor*view>0){ factor=0; }
  774. color=vec4(color.rgb*mix(0.2,1.,factor),color.a);
  775. vec3 oNormal=fNormal; if(view<0){ oNormal=-fNormal; }
  776. outNormal = oNormal;
  777. }
  778. if(UseHalftone>1e-6){ color=mix(color,halftone(color),UseHalftone); }
  779. outColor = color; outGPos = fGPos;
  780. })";
  781. extern "C" const char* LA_FLOOR_VERTEX_SHADER = R"(#version 310 es
  782. precision highp float;
  783. uniform mat4 mProjection;
  784. uniform mat4 mModel;
  785. uniform mat4 mView;
  786. in vec4 vVertex;
  787. in vec4 vColor;
  788. out vec3 fGPos;
  789. out vec4 fColor;
  790. void main(){
  791. gl_Position=mProjection * mView * mModel * vVertex;
  792. fGPos=vec3((mModel * vVertex).xyz);
  793. fColor=vColor;
  794. })";
  795. extern "C" const char* LA_FLOOR_FRAGMENT_SHADER = R"(#version 310 es
  796. precision highp float;
  797. uniform vec3 uViewPos;
  798. uniform float uFar;
  799. in vec4 fColor;
  800. in vec3 fGPos;
  801. layout(location = 0) out vec4 outColor;
  802. void main(){
  803. float fac=1.-pow(clamp(length(uViewPos-fGPos)/uFar,0.,1.),0.4);
  804. outColor=vec4(fColor.rgb,fColor.a*fac);
  805. })";
  806. extern "C" const char* LA_RAY_VERTEX_SHADER = R"(#version 310 es
  807. precision highp float;
  808. in vec3 vUV;
  809. in vec4 vVertex;
  810. out vec3 fViewDir;
  811. void main(){
  812. gl_Position=vVertex;
  813. fViewDir = vUV;
  814. })";
  815. extern "C" const char* LA_SHADER_LIB_FXAA = R"(
  816. #define DIFF_LUM_ABS_HOLD 0.0833
  817. #define DIFF_LUM_RES_HOLD 0.166
  818. float luminance(vec3 col) {
  819. return dot(col, vec3(0.2126729f, 0.7151522f, 0.0721750f));
  820. }
  821. vec4 fxaa(in sampler2D tex, vec2 uv, vec2 texsize) {
  822. vec3 e = vec3(-1., 1., 0.);
  823. vec2 offuv = uv;
  824. vec3 colnw = texture(tex, uv + e.xy / texsize).rgb;
  825. vec3 coln = texture(tex, uv + e.zy / texsize).rgb;
  826. vec3 colne = texture(tex, uv + e.yy / texsize).rgb;
  827. vec3 colw = texture(tex, uv + e.xz / texsize).rgb;
  828. vec4 colm4 = texture(tex, uv + e.zz / texsize);
  829. vec3 colm = colm4.rgb;
  830. vec3 cole = texture(tex, uv + e.yz / texsize).rgb;
  831. vec3 colsw = texture(tex, uv + e.xx / texsize).rgb;
  832. vec3 cols = texture(tex, uv + e.zx / texsize).rgb;
  833. vec3 colse = texture(tex, uv + e.yx / texsize).rgb;
  834. float lnw = luminance(colnw), ln = luminance(coln), lne = luminance(colne),
  835. lw = luminance(colw), lm = luminance(colm), le = luminance(cole),
  836. lsw = luminance(colsw), ls = luminance(cols), lse = luminance(colse);
  837. float maxl = max(ln, max(ls, max(lw, max(le, lm))));
  838. float minl = min(ln, min(ls, min(lw, min(le, lm))));
  839. float diff = maxl - minl;
  840. if (diff < max(DIFF_LUM_ABS_HOLD, DIFF_LUM_RES_HOLD * maxl)) return colm4;
  841. float filterfactor = 0.;
  842. filterfactor += 2. * (ln + lw + ls + le) + lnw + lne + lsw + lse;
  843. filterfactor /= 12.;
  844. filterfactor = abs(filterfactor - lm);
  845. filterfactor = clamp(filterfactor / diff, 0., 1.);
  846. float blend = smoothstep(0., 1., filterfactor);
  847. blend *= blend;
  848. float hedge = 2.*(ln + ls - 2.*lm) + (lne + lse - 2.*le) + (lnw + lsw - 2.*lw);
  849. float vedge = 2.*(le + lw - 2.*lm) + (lne + lnw - 2.*ln) + (lse + lsw - 2.*ls);
  850. float ish = step(vedge, hedge);
  851. float psoff = ish >= 1.0 ? 1./texsize.y : 1./texsize.x;
  852. float pleft = ish >= 1.0 ? ln : le;
  853. float pright = ish >= 1.0 ? ls : lw;
  854. if (abs(pleft - lm) < abs(pright - lm)) psoff = -psoff;
  855. if (ish >= 1.0) { offuv.y += psoff * blend; }else{ offuv.x += psoff * blend; }
  856. return vec4(texture(tex, offuv).rgb,colm4.a);
  857. })";
  858. extern "C" const char* LA_RAY_FRAGMENT_SHADER = R"(#version 310 es
  859. precision highp float;
  860. uniform vec3 uViewDir;
  861. uniform vec3 uViewPos;
  862. uniform float uFOV;
  863. in vec3 fViewDir;
  864. uniform highp sampler2D TexColor;
  865. uniform highp sampler2D TexNormal;
  866. uniform highp sampler2D TexGPos;
  867. #with LA_SHADER_LIB_FXAA
  868. out vec4 outColor;
  869. void main(){
  870. float d=dot(uViewDir,normalize(fViewDir));
  871. float target=cos(uFOV/2.);
  872. vec4 color=vec4(1.,1.,1.,1.); float mul=0.;
  873. //if(d<(target+0.005)&&d>target) mul=1.0;
  874. vec2 uv=gl_FragCoord.xy/vec2(textureSize(TexColor,0));
  875. vec4 buffer_color=fxaa(TexColor,uv,vec2(textureSize(TexColor,0)));
  876. //vec4 buffer_color=texture(TexColor,uv);
  877. outColor = mul*color+buffer_color;
  878. })";
  879. extern "C" const char* LA_SCENE_VERTEX_SHADER = R"(#version 310 es
  880. precision highp float;
  881. uniform mat4 mProjection;
  882. uniform mat4 mModel;
  883. uniform mat4 mView;
  884. uniform mat4 mShadow;
  885. in vec4 vVertex;
  886. in vec4 vColor;
  887. in vec4 vNormal;
  888. in vec2 vUV;
  889. out vec4 fColor;
  890. //out vec4 fNormal;
  891. out vec2 fUV;
  892. out vec4 fGPos;
  893. void main(){
  894. gl_Position= mProjection * mView * mModel * vVertex;
  895. fUV=vUV;
  896. //fNormal=vNormal;
  897. fColor=vColor;
  898. fGPos= mShadow * mModel * vVertex;\
  899. })";
  900. extern "C" const char* LA_SCENE_FRAGMENT_SHADER = R"(#version 310 es
  901. precision highp float;
  902. uniform highp sampler2D TexColor;
  903. uniform highp sampler2DMS TexColorMS;\
  904. uniform int TextureMode;
  905. uniform int SampleAmount;
  906. uniform int MultiplyColor;
  907. in vec4 fColor;
  908. //in vec4 fNormal;
  909. in vec2 fUV;
  910. in vec4 fGPos;
  911. out vec4 outColor;
  912. vec4 GetTexture(vec2 uv){
  913. vec4 color=vec4(1,0,1,1);
  914. if(TextureMode==1 || TextureMode==2){ return texture(TexColor,uv); }
  915. else if(TextureMode==3){
  916. ivec2 texSize = textureSize(TexColorMS);
  917. for(int i=0;i<SampleAmount;i++) color+=texelFetch(TexColorMS, ivec2(fUV * vec2(texSize)),i);
  918. color/=float(SampleAmount);
  919. if(MultiplyColor!=0){color*=fColor;}
  920. return color;
  921. }
  922. else return vec4(1,0,1,1);
  923. }
  924. float GetShadow(vec4 GPos){
  925. vec3 projCoords = GPos.xyz / GPos.w;
  926. projCoords = projCoords * 0.5 + 0.5;
  927. float closestDepth = GetTexture(projCoords.xy).r;
  928. float currentDepth = projCoords.z;
  929. float shadow = currentDepth > (closestDepth+0.001) ? 0.5 : 1.0;
  930. return shadow;
  931. }
  932. void main(){
  933. outColor=GetShadow(fGPos)*fColor;
  934. })";
  935. extern "C" const char* LA_CASCADE_SHADOW_VERTEX_SHADER = R"(#version 310 es
  936. precision highp float;
  937. in vec4 vVertex;
  938. uniform mat4 mModel;
  939. uniform mat4 mShadow;
  940. void main(){
  941. gl_Position=mShadow*mModel*vVertex;
  942. })";
  943. extern "C" const char* LA_CASCADE_SHADOW_FRAGMENT_SHADER = "#version 310 es\n \
  944. precision highp float;\nvoid main(){gl_FragDepth = gl_FragCoord.z;}";
  945. extern "C" const char* LA_SELECTION_VERTEX_SHADER = R"(#version 310 es
  946. precision highp float;
  947. in vec4 vVertex;
  948. in vec3 vColor;
  949. uniform mat4 mProjection;
  950. uniform mat4 mModel;
  951. uniform mat4 mView;
  952. uniform int DoOffset;
  953. flat out vec3 fIdColor;
  954. void main(){
  955. vec4 pos = mProjection * mView * mModel * vVertex;
  956. if(DoOffset!=0){ pos.xyw*=1.00005; }
  957. gl_Position = pos;
  958. fIdColor = vColor;
  959. })";
  960. extern "C" const char* LA_SELECTION_FRAGMENT_SHADER = R"(#version 310 es
  961. precision highp float;
  962. flat in vec3 fIdColor;
  963. out vec4 outColor;
  964. void main(){
  965. outColor=vec4(fIdColor,1.);
  966. })";