erebus: liberebus/src/erebus.cc annotate

erebus

annotate liberebus/src/erebus.cc @ 32:b1fc96c71bcc

- lambert BRDF importance sampling - UI + commandline arguments - font rendering for showing status/progress

author	John Tsiombikas <nuclear@member.fsf.org>
date	Sat, 07 Jun 2014 13:36:36 +0300
parents	53a98c148bf8
children	d15ee526daa6

rev	line source
nuclear@2	1 #include <string.h>
nuclear@2	2 #include <limits.h>
nuclear@27	3 #include <algorithm>
nuclear@2	4 #include <chrono>
nuclear@2	5 #include <random>
nuclear@2	6 #include "erebus.h"
nuclear@17	7 #include "erebus_impl.h"
nuclear@4	8 #include "scene.h"
nuclear@4	9 #include "geomobj.h"
nuclear@5	10 #include "rt.h"
nuclear@2	11
nuclear@8	12 #define INF_SAMPLES (INT_MAX / 2)
nuclear@8	13
nuclear@2	14 using namespace std::chrono;
nuclear@2	15
nuclear@26	16 static void render_block(struct erebus *ctx, Block blk);
nuclear@8	17 static void render_pixel(struct erebus *ctx, int x, int y, int sample);
nuclear@2	18
nuclear@2	19 static std::mt19937 rnd_gen;
nuclear@2	20
nuclear@2	21 extern "C" {
nuclear@2	22
nuclear@2	23 struct erebus *erb_init(void)
nuclear@2	24 {
nuclear@31	25 struct erebus *ctx = 0;
nuclear@2	26 try {
nuclear@2	27 ctx = new struct erebus;
nuclear@2	28 }
nuclear@2	29 catch(...) {
nuclear@2	30 return 0;
nuclear@2	31 }
nuclear@2	32
nuclear@10	33 rnd_gen.seed(time(0));
nuclear@10	34
nuclear@4	35 ctx->scn = 0;
nuclear@2	36 ctx->cur_time = 0;
nuclear@26	37 ctx->cur_frame = 0;
nuclear@32	38 ctx->tpool = 0;
nuclear@8	39
nuclear@17	40 erb_setoptf(ctx, ERB_OPT_GAMMA, 2.2);
nuclear@17	41 erb_setopti(ctx, ERB_OPT_MAX_ITER, 6);
nuclear@17	42 erb_setopti(ctx, ERB_OPT_MAX_SAMPLES, INF_SAMPLES);
nuclear@17	43 erb_setopti(ctx, ERB_OPT_NUM_THREADS, -1);
nuclear@15	44
nuclear@15	45 ctx->dbg_nodesel = -1;
nuclear@2	46 return ctx;
nuclear@2	47 }
nuclear@2	48
nuclear@2	49 void erb_destroy(struct erebus *ctx)
nuclear@2	50 {
nuclear@31	51 if(ctx) {
nuclear@31	52 // make sure the threadpool stops BEFORE destroying the framebuffers etc in ctx
nuclear@31	53 delete ctx->tpool;
nuclear@31	54 delete ctx;
nuclear@31	55 }
nuclear@2	56 }
nuclear@2	57
nuclear@2	58 void erb_setopti(struct erebus *ctx, enum erb_option opt, int val)
nuclear@2	59 {
nuclear@17	60 ctx->options[opt].ival = val;
nuclear@17	61 ctx->options[opt].type = Option::Type::INT;
nuclear@2	62 }
nuclear@17	63
nuclear@2	64 void erb_setoptf(struct erebus *ctx, enum erb_option opt, float val)
nuclear@2	65 {
nuclear@17	66 ctx->options[opt].fval = val;
nuclear@17	67 ctx->options[opt].type = Option::Type::FLOAT;
nuclear@2	68 }
nuclear@17	69
nuclear@2	70 void erb_setoptfv(struct erebus ctx, enum erb_option opt, float vec)
nuclear@2	71 {
nuclear@2	72 for(int i=0; i<4; i++) {
nuclear@17	73 ctx->options[opt].vval[i] = vec[i];
nuclear@2	74 }
nuclear@17	75 ctx->options[opt].type = Option::Type::VEC;
nuclear@2	76 }
nuclear@2	77
nuclear@2	78 int erb_getopti(struct erebus *ctx, enum erb_option opt)
nuclear@2	79 {
nuclear@17	80 switch(ctx->options[opt].type) {
nuclear@17	81 case Option::Type::INT:
nuclear@17	82 return ctx->options[opt].ival;
nuclear@17	83 case Option::Type::FLOAT:
nuclear@17	84 return (int)ctx->options[opt].fval;
nuclear@17	85 case Option::Type::VEC:
nuclear@17	86 return (int)ctx->options[opt].vval.x;
nuclear@17	87 }
nuclear@17	88 return 0; // can't happen
nuclear@2	89 }
nuclear@17	90
nuclear@2	91 float erb_getoptf(struct erebus *ctx, enum erb_option opt)
nuclear@2	92 {
nuclear@17	93 switch(ctx->options[opt].type) {
nuclear@17	94 case Option::Type::INT:
nuclear@17	95 return (float)ctx->options[opt].ival;
nuclear@17	96 case Option::Type::FLOAT:
nuclear@17	97 return ctx->options[opt].fval;
nuclear@17	98 case Option::Type::VEC:
nuclear@17	99 return ctx->options[opt].vval.x;
nuclear@17	100 }
nuclear@17	101 return 0.0f; // can't happen
nuclear@2	102 }
nuclear@17	103
nuclear@2	104 float erb_getoptfv(struct erebus ctx, enum erb_option opt)
nuclear@2	105 {
nuclear@17	106 switch(ctx->options[opt].type) {
nuclear@17	107 case Option::Type::INT:
nuclear@17	108 {
nuclear@17	109 int ival = ctx->options[opt].ival;
nuclear@17	110 ctx->options[opt].vval = Vector4(ival, ival, ival, ival);
nuclear@17	111 }
nuclear@17	112 break;
nuclear@17	113 case Option::Type::FLOAT:
nuclear@17	114 {
nuclear@17	115 float fval = ctx->options[opt].fval;
nuclear@17	116 ctx->options[opt].vval = Vector4(fval, fval, fval, fval);
nuclear@17	117 }
nuclear@17	118 default:
nuclear@17	119 break;
nuclear@17	120 }
nuclear@17	121
nuclear@17	122 return &ctx->options[opt].vval.x;
nuclear@2	123 }
nuclear@2	124
nuclear@2	125 float erb_get_framebuffer(struct erebus ctx)
nuclear@2	126 {
nuclear@2	127 return ctx->fbimg.get_pixels();
nuclear@2	128 }
nuclear@2	129
nuclear@2	130 void erb_begin_frame(struct erebus *ctx, long ms)
nuclear@2	131 {
nuclear@32	132 if(!ctx->tpool) {
nuclear@32	133 int num_threads = erb_getopti(ctx, ERB_OPT_NUM_THREADS);
nuclear@32	134 ctx->tpool = new ThreadPool(num_threads);
nuclear@32	135 }
nuclear@32	136
nuclear@26	137 ++ctx->cur_frame;
nuclear@26	138 ctx->cur_sample = 0;
nuclear@2	139 ctx->cur_time = ms;
nuclear@4	140
nuclear@17	141 int xsz = erb_getopti(ctx, ERB_OPT_WIDTH);
nuclear@17	142 int ysz = erb_getopti(ctx, ERB_OPT_HEIGHT);
nuclear@4	143
nuclear@26	144 if(!ctx->fbimg.get_pixels() \|\| ctx->fbimg.get_width() != xsz \|\| ctx->fbimg.get_height() < ysz) {
nuclear@26	145 ctx->fbimg.create(xsz, ysz);
nuclear@26	146 ctx->accum.create(xsz, ysz);
nuclear@26	147 } else {
nuclear@26	148 ctx->fbimg.clear();
nuclear@26	149 ctx->accum.clear();
nuclear@26	150 }
nuclear@15	151
nuclear@17	152 ctx->inv_gamma = 1.0f / erb_getoptf(ctx, ERB_OPT_GAMMA);
nuclear@26	153
nuclear@26	154 ctx->scn->update(ctx->cur_time);
nuclear@2	155 }
nuclear@2	156
nuclear@2	157 int erb_render(struct erebus *ctx, long timeout)
nuclear@2	158 {
nuclear@2	159 return erb_render_rect(ctx, 0, 0, ctx->fbimg.get_width(), ctx->fbimg.get_height(), timeout);
nuclear@2	160 }
nuclear@2	161
nuclear@26	162 #define BLKSZ 32
nuclear@26	163
nuclear@2	164 int erb_render_rect(struct erebus *ctx, int x, int y, int width, int height, long timeout)
nuclear@2	165 {
nuclear@31	166 while(ctx->tpool->pending()) {
nuclear@26	167 if(timeout > 0) {
nuclear@31	168 long wait_interval = ctx->tpool->wait(timeout);
nuclear@26	169 timeout -= wait_interval;
nuclear@26	170 } else {
nuclear@26	171 return 1;
nuclear@26	172 }
nuclear@26	173 }
nuclear@26	174
nuclear@2	175 if(!width \|\| !height) return -1;
nuclear@2	176
nuclear@26	177 int startx = x;
nuclear@26	178 int endx = x + width;
nuclear@26	179 int endy = y + height;
nuclear@26	180
nuclear@26	181 while(y < endy) {
nuclear@26	182 x = startx;
nuclear@26	183 while(x < endx) {
nuclear@26	184 Block blk;
nuclear@26	185 blk.x = x;
nuclear@26	186 blk.y = y;
nuclear@26	187 blk.width = std::min(BLKSZ, endx - x);
nuclear@26	188 blk.height = std::min(BLKSZ, endy - y);
nuclear@26	189 blk.sample = ctx->cur_sample;
nuclear@26	190 blk.frame = ctx->cur_frame;
nuclear@26	191
nuclear@31	192 ctx->tpool->add_work(std::bind(render_block, ctx, blk));
nuclear@26	193
nuclear@26	194 x += BLKSZ;
nuclear@26	195 }
nuclear@26	196 y += BLKSZ;
nuclear@2	197 }
nuclear@2	198
nuclear@26	199 ++ctx->cur_sample;
nuclear@31	200 ctx->tpool->wait(timeout); // wait for completion
nuclear@26	201 return ctx->cur_sample > erb_getopti(ctx, ERB_OPT_MAX_SAMPLES) ? 0 : 1;
nuclear@26	202 }
nuclear@4	203
nuclear@2	204
nuclear@2	205 int erb_get_progress(struct erebus *ctx)
nuclear@2	206 {
nuclear@32	207 struct erb_render_status st;
nuclear@32	208 if(erb_get_status(ctx, &st) == -1) {
nuclear@32	209 return 0;
nuclear@32	210 }
nuclear@32	211 return st.progress_percent;
nuclear@32	212 }
nuclear@32	213
nuclear@32	214 int erb_get_status(struct erebus ctx, struct erb_render_status stat)
nuclear@32	215 {
nuclear@32	216 long pending = ctx->tpool->pending();
nuclear@32	217 if(!pending) {
nuclear@32	218 return -1;
nuclear@32	219 }
nuclear@32	220 int xsz = ctx->fbimg.get_width();
nuclear@32	221 int ysz = ctx->fbimg.get_height();
nuclear@32	222 int xblocks = (xsz + BLKSZ - 1) / BLKSZ;
nuclear@32	223 int yblocks = (ysz + BLKSZ - 1) / BLKSZ;
nuclear@32	224 long num_blocks = xblocks * yblocks;
nuclear@32	225
nuclear@32	226 stat->frames = stat->max_frames = 0; // TODO
nuclear@32	227
nuclear@32	228 stat->blocks = num_blocks - pending;
nuclear@32	229 stat->max_blocks = num_blocks;
nuclear@32	230
nuclear@32	231 stat->samples = ctx->cur_sample ? ctx->cur_sample - 1 : 0;
nuclear@32	232 if((stat->max_samples = erb_getopti(ctx, ERB_OPT_MAX_SAMPLES)) == INF_SAMPLES) {
nuclear@32	233 stat->max_samples = stat->samples;
nuclear@32	234
nuclear@32	235 stat->progress_percent = 100 * stat->blocks / stat->max_blocks;
nuclear@32	236 } else {
nuclear@32	237 stat->progress_percent = 100 * stat->samples / stat->max_samples;
nuclear@32	238 }
nuclear@32	239 return 0;
nuclear@2	240 }
nuclear@2	241
nuclear@2	242 int erb_load_scene(struct erebus ctx, const char fname)
nuclear@2	243 {
nuclear@4	244 delete ctx->scn;
nuclear@4	245 ctx->scn = new Scene;
nuclear@2	246
nuclear@19	247 if(!ctx->scn->load(fname)) {
nuclear@19	248 return -1;
nuclear@19	249 }
nuclear@4	250 return 0;
nuclear@2	251 }
nuclear@2	252
nuclear@9	253 bool erb_input_keyboard(struct erebus *ctx, int key, bool pressed)
nuclear@9	254 {
nuclear@9	255 if(!ctx) return false;
nuclear@15	256 if((int)ctx->keystate.size() <= key) {
nuclear@15	257 ctx->keystate.resize(key < 256 ? 256 : key + 1);
nuclear@15	258 }
nuclear@9	259
nuclear@9	260 ctx->keystate[key] = pressed;
nuclear@10	261
nuclear@10	262 if(pressed) {
nuclear@10	263 switch(key) {
nuclear@15	264 case '.':
nuclear@15	265 {
nuclear@15	266 int node_count = ctx->scn->get_node_count();
nuclear@15	267 if(node_count && ++ctx->dbg_nodesel >= node_count) {
nuclear@15	268 ctx->dbg_nodesel = 0;
nuclear@15	269 }
nuclear@15	270 printf("selected node: %d\n", ctx->dbg_nodesel);
nuclear@15	271 }
nuclear@15	272 break;
nuclear@15	273
nuclear@15	274 case ',':
nuclear@15	275 {
nuclear@15	276 int node_count = ctx->scn->get_node_count();
nuclear@15	277 if(node_count && --ctx->dbg_nodesel < 0) {
nuclear@15	278 ctx->dbg_nodesel = node_count - 1;
nuclear@15	279 }
nuclear@15	280 printf("selected node: %d\n", ctx->dbg_nodesel);
nuclear@15	281 }
nuclear@15	282 break;
nuclear@15	283
nuclear@10	284 case '=':
nuclear@10	285 case '-':
nuclear@15	286 case '0':
nuclear@15	287 if(ctx->dbg_nodesel != -1) {
nuclear@15	288 SceneNode *node = ctx->scn->get_node(ctx->dbg_nodesel);
nuclear@15	289 Vector3 s = node->get_scaling();
nuclear@15	290 switch(key) {
nuclear@15	291 case '=':
nuclear@15	292 node->set_scaling(s * 1.1);
nuclear@15	293 break;
nuclear@15	294 case '-':
nuclear@15	295 node->set_scaling(s * 0.9);
nuclear@15	296 break;
nuclear@15	297 case '0':
nuclear@15	298 node->set_scaling(Vector3(1, 1, 1));
nuclear@15	299 break;
nuclear@15	300 }
nuclear@15	301 }
nuclear@15	302 erb_begin_frame(ctx, 0);
nuclear@15	303 return true;
nuclear@10	304 }
nuclear@10	305 }
nuclear@9	306 return false;
nuclear@9	307 }
nuclear@9	308
nuclear@9	309 bool erb_input_mouse_button(struct erebus *ctx, int bn, bool pressed, int x, int y)
nuclear@9	310 {
nuclear@9	311 if(!ctx) return false;
nuclear@15	312 if((int)ctx->bnstate.size() <= bn) {
nuclear@15	313 ctx->bnstate.resize(bn < 32 ? 32 : bn + 1);
nuclear@15	314 }
nuclear@9	315
nuclear@9	316 ctx->bnstate[bn] = pressed;
nuclear@9	317 ctx->mouse_pos[0] = x;
nuclear@9	318 ctx->mouse_pos[1] = y;
nuclear@10	319 return false;
nuclear@9	320 }
nuclear@9	321
nuclear@10	322 bool erb_input_mouse_motion(struct erebus *ctx, int x, int y)
nuclear@10	323 {
nuclear@18	324 bool res = false;
nuclear@18	325
nuclear@18	326 if(!ctx) return res;
nuclear@18	327
nuclear@18	328 int dx = x - ctx->mouse_pos[0];
nuclear@18	329 int dy = y - ctx->mouse_pos[1];
nuclear@18	330
nuclear@18	331 if(dx \|\| dy) {
nuclear@18	332 TargetCamera cam = (TargetCamera)ctx->scn->get_active_camera();
nuclear@18	333 if(cam && ctx->bnstate[0]) {
nuclear@18	334 Vector3 cpos = cam->get_position();
nuclear@18	335 float mag = cpos.length();
nuclear@18	336
nuclear@19	337 float theta = atan2(cpos.z / mag, cpos.x / mag) - DEG_TO_RAD(dx * 0.5);
nuclear@19	338 float phi = acos(cpos.y / mag) - DEG_TO_RAD(dy * 0.5);
nuclear@18	339
nuclear@18	340 if(phi < 0) phi = 0;
nuclear@18	341 if(phi > M_PI) phi = M_PI;
nuclear@18	342
nuclear@18	343 cpos.x = cos(theta) * sin(phi) * mag;
nuclear@18	344 cpos.y = cos(phi) * mag;
nuclear@18	345 cpos.z = sin(theta) * sin(phi) * mag;
nuclear@18	346 cam->set_position(cpos);
nuclear@18	347
nuclear@18	348 erb_begin_frame(ctx, 0);
nuclear@18	349 res = true;
nuclear@18	350 }
nuclear@18	351 }
nuclear@10	352
nuclear@10	353 ctx->mouse_pos[0] = x;
nuclear@10	354 ctx->mouse_pos[1] = y;
nuclear@18	355 return res;
nuclear@10	356 }
nuclear@10	357
nuclear@10	358 bool erb_input_6dof_button(struct erebus *ctx, int bn, bool pressed)
nuclear@10	359 {
nuclear@10	360 if(!ctx) return false;
nuclear@10	361 return false;
nuclear@10	362 }
nuclear@10	363
nuclear@10	364 bool erb_input_6dof_motion(struct erebus *ctx, float x, float y, float z)
nuclear@10	365 {
nuclear@10	366 if(!ctx) return false;
nuclear@10	367 return false;
nuclear@10	368 }
nuclear@9	369
nuclear@9	370
nuclear@2	371 } // extern "C"
nuclear@2	372
nuclear@2	373 float randf(float low, float high)
nuclear@2	374 {
nuclear@2	375 std::uniform_real_distribution<float> unirnd(low, high);
nuclear@2	376 return unirnd(rnd_gen);
nuclear@2	377 }
nuclear@2	378
nuclear@26	379 static void render_block(struct erebus *ctx, Block blk)
nuclear@26	380 {
nuclear@26	381 if(blk.frame < ctx->cur_frame) {
nuclear@26	382 return; // skip stale blocks
nuclear@26	383 }
nuclear@26	384
nuclear@26	385 for(int i=0; i<blk.height; i++) {
nuclear@26	386 for(int j=0; j<blk.width; j++) {
nuclear@26	387 render_pixel(ctx, blk.x + j, blk.y + i, blk.sample);
nuclear@26	388 }
nuclear@26	389 }
nuclear@26	390 }
nuclear@26	391
nuclear@8	392 static void render_pixel(struct erebus *ctx, int x, int y, int sample)
nuclear@2	393 {
nuclear@5	394 Camera *cam = ctx->scn->get_active_camera();
nuclear@5	395 if(!cam) return;
nuclear@5	396
nuclear@5	397 int xsz = ctx->fbimg.get_width();
nuclear@5	398 int ysz = ctx->fbimg.get_height();
nuclear@8	399 int offs = (y * xsz + x) * 4;
nuclear@5	400
nuclear@8	401 float *pix = ctx->fbimg.get_pixels() + offs;
nuclear@8	402 float *accum = ctx->accum.get_pixels() + offs;
nuclear@8	403
nuclear@8	404 Ray ray = cam->get_primary_ray(x, y, xsz, ysz, sample);
nuclear@17	405 Color c = ray_trace(ctx, ray, 0);
nuclear@8	406 accum[0] += c.x;
nuclear@8	407 accum[1] += c.y;
nuclear@8	408 accum[2] += c.z;
nuclear@8	409 accum[3] += c.w;
nuclear@8	410
nuclear@8	411 float inv_samples = 1.0f / (float)(sample + 1);
nuclear@17	412 pix[0] = pow(accum[0] * inv_samples, ctx->inv_gamma);
nuclear@17	413 pix[1] = pow(accum[1] * inv_samples, ctx->inv_gamma);
nuclear@17	414 pix[2] = pow(accum[2] * inv_samples, ctx->inv_gamma);
nuclear@8	415 pix[3] = accum[3] * inv_samples;
nuclear@2	416 }