ref: b1335875b19a4db2ae028f8d790784cddcffe8b5
dir: libgraphics/render.c
#include <u.h>
#include <libc.h>
#include <thread.h>
#include <draw.h>
#include <memdraw.h>
#include <geometry.h>
#include "libobj/obj.h"
#include "graphics.h"
#include "internal.h"
Rectangle UR = {0,0,1,1};
static ulong
col2ul(Color c)
{
uchar cbuf[4];
cbuf[0] = fclamp(c.a, 0, 1)*0xFF;
cbuf[1] = fclamp(c.b, 0, 1)*0xFF;
cbuf[2] = fclamp(c.g, 0, 1)*0xFF;
cbuf[3] = fclamp(c.r, 0, 1)*0xFF;
return cbuf[3]<<24 | cbuf[2]<<16 | cbuf[1]<<8 | cbuf[0];
}
static Color
ul2col(ulong l)
{
Color c;
c.a = (l & 0xff)/255.0;
c.b = (l>>8 & 0xff)/255.0;
c.g = (l>>16 & 0xff)/255.0;
c.r = (l>>24 & 0xff)/255.0;
return c;
}
static void
pixel(Framebuf *fb, Point p, Color c)
{
Color dc;
ulong *dst;
dst = fb->cb;
dc = ul2col(dst[Dx(fb->r)*p.y + p.x]);
c = lerp3(dc, c, c.a); /* SoverD */
dst[Dx(fb->r)*p.y + p.x] = col2ul(c);
}
static int
isvisible(Point3 p)
{
if(p.x < -p.w || p.x > p.w ||
p.y < -p.w || p.y > p.w ||
p.z < -p.w || p.z > p.w)
return 0;
return 1;
}
static int
isfacingback(Primitive p)
{
double sa; /* signed area */
sa = p.v[0].p.x * p.v[1].p.y - p.v[0].p.y * p.v[1].p.x +
p.v[1].p.x * p.v[2].p.y - p.v[1].p.y * p.v[2].p.x +
p.v[2].p.x * p.v[0].p.y - p.v[2].p.y * p.v[0].p.x;
return sa <= 0;
}
static void
rasterize(Rastertask *task)
{
SUparams *params;
Primitive prim;
FSparams fsp;
Triangle2 t;
Rectangle bbox;
Point p, dp, Δp, p0, p1;
Point3 bc;
Color c;
double z, dplen, perc;
int steep = 0, Δe, e, Δy;
params = task->params;
prim = task->p;
memmove(prim.v, task->p.v, sizeof prim.v);
fsp.su = params;
memset(&fsp.v, 0, sizeof fsp.v);
switch(prim.type){
case PPoint:
p = Pt(prim.v[0].p.x, prim.v[0].p.y);
z = fclamp(prim.v[0].p.z, 0, 1);
if(z <= params->fb->zb[p.x + p.y*Dx(params->fb->r)])
break;
params->fb->zb[p.x + p.y*Dx(params->fb->r)] = z;
fsp.v = dupvertex(&prim.v[0]);
fsp.p = p;
c = params->fshader(&fsp);
pixel(params->fb, p, c);
delvattrs(&fsp.v);
break;
case PLine:
p0 = Pt(prim.v[0].p.x, prim.v[0].p.y);
p1 = Pt(prim.v[1].p.x, prim.v[1].p.y);
/* clip it against our wr */
if(rectclipline(task->wr, &p0, &p1) < 0)
break;
/* transpose the points */
if(abs(p0.x-p1.x) < abs(p0.y-p1.y)){
steep = 1;
swapi(&p0.x, &p0.y);
swapi(&p1.x, &p1.y);
}
/* make them left-to-right */
if(p0.x > p1.x){
swapi(&p0.x, &p1.x);
swapi(&p0.y, &p1.y);
}
dp = subpt(p1, p0);
Δe = 2*abs(dp.y);
e = 0;
Δy = p1.y > p0.y? 1: -1;
for(p = p0; p.x <= p1.x; p.x++){
Δp = subpt(p, p0);
dplen = hypot(dp.x, dp.y);
perc = dplen == 0? 0: hypot(Δp.x, Δp.y)/dplen;
if(steep) swapi(&p.x, &p.y);
z = flerp(prim.v[0].p.z, prim.v[1].p.z, perc);
/* TODO get rid of the bounds check and make sure the clipping doesn't overflow */
if(!ptinrect(p, params->fb->r) || z <= params->fb->zb[p.x + p.y*Dx(params->fb->r)])
goto discard;
params->fb->zb[p.x + p.y*Dx(params->fb->r)] = z;
/* interpolate z⁻¹ and get actual z */
z = flerp(prim.v[0].p.w, prim.v[1].p.w, perc);
z = 1.0/(z < 1e-5? 1e-5: z);
/* perspective-correct attribute interpolation */
perc *= prim.v[0].p.w * z;
lerpvertex(&fsp.v, &prim.v[0], &prim.v[1], perc);
fsp.p = p;
c = params->fshader(&fsp);
pixel(params->fb, p, c);
delvattrs(&fsp.v);
discard:
if(steep) swapi(&p.x, &p.y);
e += Δe;
if(e > dp.x){
p.y += Δy;
e -= 2*dp.x;
}
}
break;
case PTriangle:
t.p0 = Pt2(prim.v[0].p.x, prim.v[0].p.y, 1);
t.p1 = Pt2(prim.v[1].p.x, prim.v[1].p.y, 1);
t.p2 = Pt2(prim.v[2].p.x, prim.v[2].p.y, 1);
/* find the triangle's bbox and clip it against our wr */
bbox.min.x = min(min(t.p0.x, t.p1.x), t.p2.x);
bbox.min.y = min(min(t.p0.y, t.p1.y), t.p2.y);
bbox.max.x = max(max(t.p0.x, t.p1.x), t.p2.x)+1;
bbox.max.y = max(max(t.p0.y, t.p1.y), t.p2.y)+1;
bbox.min.x = max(bbox.min.x, task->wr.min.x);
bbox.min.y = max(bbox.min.y, task->wr.min.y);
bbox.max.x = min(bbox.max.x, task->wr.max.x);
bbox.max.y = min(bbox.max.y, task->wr.max.y);
for(p.y = bbox.min.y; p.y < bbox.max.y; p.y++)
for(p.x = bbox.min.x; p.x < bbox.max.x; p.x++){
bc = barycoords(t, Pt2(p.x,p.y,1));
if(bc.x < 0 || bc.y < 0 || bc.z < 0)
continue;
z = fberp(prim.v[0].p.z, prim.v[1].p.z, prim.v[2].p.z, bc);
if(z <= params->fb->zb[p.x + p.y*Dx(params->fb->r)])
continue;
params->fb->zb[p.x + p.y*Dx(params->fb->r)] = z;
/* interpolate z⁻¹ and get actual z */
z = fberp(prim.v[0].p.w, prim.v[1].p.w, prim.v[2].p.w, bc);
z = 1.0/(z < 1e-5? 1e-5: z);
/* perspective-correct attribute interpolation */
bc = modulapt3(bc, Vec3(prim.v[0].p.w*z,prim.v[1].p.w*z,prim.v[2].p.w*z));
berpvertex(&fsp.v, &prim.v[0], &prim.v[1], &prim.v[2], bc);
fsp.p = p;
c = params->fshader(&fsp);
pixel(params->fb, p, c);
delvattrs(&fsp.v);
}
break;
}
}
static void
rasterizer(void *arg)
{
Rasterparam *rp;
Rastertask *task;
SUparams *params;
uvlong t0;
int i;
rp = arg;
threadsetname("rasterizer %d", rp->id);
while((task = recvp(rp->taskc)) != nil){
t0 = nanosec();
params = task->params;
/* end of job */
if(params->entity == nil){
if(decref(params->job) < 1){
nbsend(params->job->donec, nil);
free(params);
}
free(task);
continue;
}
if(params->job->times.Rn.t0 == 0)
params->job->times.Rn.t0 = t0;
rasterize(task);
for(i = 0; i < task->p.type+1; i++)
delvattrs(&task->p.v[i]);
params->job->times.Rn.t1 = nanosec();
free(params);
free(task);
}
}
static void
tilerdurden(void *arg)
{
Tilerparam *tp;
SUparams *params, *newparams;
Rastertask *task;
VSparams vsp;
Primitive *ep, *p; /* primitives to raster */
Rectangle *wr, bbox;
Channel **taskchans;
ulong Δy, nproc;
int i, np;
uvlong t0;
tp = arg;
p = emalloc(sizeof(*p)*16);
taskchans = tp->taskchans;
nproc = tp->nproc;
wr = emalloc(nproc*sizeof(Rectangle));
threadsetname("tilerdurden %d", tp->id);
while((params = recvp(tp->paramsc)) != nil){
t0 = nanosec();
if(params->job->times.Tn.t0 == 0)
params->job->times.Tn.t0 = t0;
/* end of job */
if(params->entity == nil){
if(decref(params->job) < 1){
params->job->ref = nproc;
for(i = 0; i < nproc; i++){
task = emalloc(sizeof *task);
memset(task, 0, sizeof *task);
task->params = params;
sendp(taskchans[i], task);
}
}
continue;
}
vsp.su = params;
wr[0] = params->fb->r;
Δy = Dy(wr[0])/nproc;
wr[0].max.y = wr[0].min.y + Δy;
for(i = 1; i < nproc; i++)
wr[i] = rectaddpt(wr[i-1], Pt(0,Δy));
if(wr[nproc-1].max.y < params->fb->r.max.y)
wr[nproc-1].max.y = params->fb->r.max.y;
for(ep = params->eb; ep != params->ee; ep++){
np = 1; /* start with one. after clipping it might change */
memmove(p, ep, sizeof *p);
switch(ep->type){
case PPoint:
p[0].v[0].c = Pt3(1,1,1,1);
p[0].v[0].mtl = ep->mtl;
p[0].v[0].attrs = nil;
p[0].v[0].nattrs = 0;
vsp.v = &p[0].v[0];
vsp.idx = 0;
p[0].v[0].p = params->vshader(&vsp);
if(!isvisible(p[0].v[0].p))
break;
p[0].v[0].p = clip2ndc(p[0].v[0].p);
p[0].v[0].p = ndc2viewport(params->fb, p[0].v[0].p);
bbox.min.x = p[0].v[0].p.x;
bbox.min.y = p[0].v[0].p.y;
bbox.max.x = p[0].v[0].p.x+1;
bbox.max.y = p[0].v[0].p.y+1;
for(i = 0; i < nproc; i++)
if(rectXrect(bbox,wr[i])){
newparams = emalloc(sizeof *newparams);
*newparams = *params;
task = emalloc(sizeof *task);
task->params = newparams;
task->wr = wr[i];
memmove(&task->p, &p[0], sizeof task->p);
task->p.v[0] = dupvertex(&p[0].v[0]);
sendp(taskchans[i], task);
}
delvattrs(&p[0].v[0]);
break;
case PLine:
for(i = 0; i < 2; i++){
p[0].v[i].c = Pt3(1,1,1,1);
p[0].v[i].mtl = ep->mtl;
p[0].v[i].attrs = nil;
p[0].v[i].nattrs = 0;
vsp.v = &p[0].v[i];
vsp.idx = i;
p[0].v[i].p = params->vshader(&vsp);
}
if(!isvisible(p[0].v[0].p) || !isvisible(p[0].v[1].p))
np = clipprimitive(p);
while(np--){
p[np].v[0].p = clip2ndc(p[np].v[0].p);
p[np].v[1].p = clip2ndc(p[np].v[1].p);
p[np].v[0].p = ndc2viewport(params->fb, p[np].v[0].p);
p[np].v[1].p = ndc2viewport(params->fb, p[np].v[1].p);
bbox.min.x = min(p[np].v[0].p.x, p[np].v[1].p.x);
bbox.min.y = min(p[np].v[0].p.y, p[np].v[1].p.y);
bbox.max.x = max(p[np].v[0].p.x, p[np].v[1].p.x)+1;
bbox.max.y = max(p[np].v[0].p.y, p[np].v[1].p.y)+1;
for(i = 0; i < nproc; i++)
if(rectXrect(bbox,wr[i])){
newparams = emalloc(sizeof *newparams);
*newparams = *params;
task = emalloc(sizeof *task);
task->params = newparams;
task->wr = wr[i];
memmove(&task->p, &p[np], sizeof task->p);
task->p.v[0] = dupvertex(&p[np].v[0]);
task->p.v[1] = dupvertex(&p[np].v[1]);
sendp(taskchans[i], task);
}
delvattrs(&p[np].v[0]);
delvattrs(&p[np].v[1]);
}
break;
case PTriangle:
for(i = 0; i < 3; i++){
p[0].v[i].c = Pt3(1,1,1,1);
p[0].v[i].mtl = p->mtl;
p[0].v[i].attrs = nil;
p[0].v[i].nattrs = 0;
p[0].v[i].tangent = p->tangent;
vsp.v = &p[0].v[i];
vsp.idx = i;
p[0].v[i].p = params->vshader(&vsp);
}
if(!isvisible(p[0].v[0].p) || !isvisible(p[0].v[1].p) || !isvisible(p[0].v[2].p))
np = clipprimitive(p);
while(np--){
p[np].v[0].p = clip2ndc(p[np].v[0].p);
p[np].v[1].p = clip2ndc(p[np].v[1].p);
p[np].v[2].p = clip2ndc(p[np].v[2].p);
/* culling */
// if(isfacingback(p[np]))
// goto skiptri;
p[np].v[0].p = ndc2viewport(params->fb, p[np].v[0].p);
p[np].v[1].p = ndc2viewport(params->fb, p[np].v[1].p);
p[np].v[2].p = ndc2viewport(params->fb, p[np].v[2].p);
bbox.min.x = min(min(p[np].v[0].p.x, p[np].v[1].p.x), p[np].v[2].p.x);
bbox.min.y = min(min(p[np].v[0].p.y, p[np].v[1].p.y), p[np].v[2].p.y);
bbox.max.x = max(max(p[np].v[0].p.x, p[np].v[1].p.x), p[np].v[2].p.x)+1;
bbox.max.y = max(max(p[np].v[0].p.y, p[np].v[1].p.y), p[np].v[2].p.y)+1;
for(i = 0; i < nproc; i++)
if(rectXrect(bbox,wr[i])){
newparams = emalloc(sizeof *newparams);
*newparams = *params;
task = emalloc(sizeof *task);
task->params = newparams;
task->wr = wr[i];
memmove(&task->p, &p[np], sizeof task->p);
task->p.v[0] = dupvertex(&p[np].v[0]);
task->p.v[1] = dupvertex(&p[np].v[1]);
task->p.v[2] = dupvertex(&p[np].v[2]);
sendp(taskchans[i], task);
}
//skiptri:
delvattrs(&p[np].v[0]);
delvattrs(&p[np].v[1]);
delvattrs(&p[np].v[2]);
}
break;
}
}
params->job->times.Tn.t1 = nanosec();
free(params);
}
}
static void
entityproc(void *arg)
{
Channel *paramsin, **paramsout, **taskchans;
Tilerparam *tp;
Rasterparam *rp;
SUparams *params, *newparams;
Primitive *eb, *ee;
char *nprocs;
ulong stride, nprims, nproc, nworkers;
int i;
uvlong t0;
threadsetname("entityproc");
paramsin = arg;
nprocs = getenv("NPROC");
if(nprocs == nil || (nproc = strtoul(nprocs, nil, 10)) < 2)
nproc = 1;
else
nproc /= 2;
free(nprocs);
paramsout = emalloc(nproc*sizeof(*paramsout));
taskchans = emalloc(nproc*sizeof(*taskchans));
for(i = 0; i < nproc; i++){
paramsout[i] = chancreate(sizeof(SUparams*), 8);
tp = emalloc(sizeof *tp);
tp->id = i;
tp->paramsc = paramsout[i];
tp->taskchans = taskchans;
tp->nproc = nproc;
proccreate(tilerdurden, tp, mainstacksize);
}
for(i = 0; i < nproc; i++){
rp = emalloc(sizeof *rp);
rp->id = i;
rp->taskc = taskchans[i] = chancreate(sizeof(Rastertask*), 32);
proccreate(rasterizer, rp, mainstacksize);
}
while((params = recvp(paramsin)) != nil){
t0 = nanosec();
if(params->job->times.E.t0 == 0)
params->job->times.E.t0 = t0;
/* end of job */
if(params->entity == nil){
params->job->ref = nproc;
for(i = 0; i < nproc; i++)
sendp(paramsout[i], params);
continue;
}
eb = params->entity->mdl->prims;
nprims = params->entity->mdl->nprims;
ee = eb + nprims;
if(nprims <= nproc){
nworkers = nprims;
stride = 1;
}else{
nworkers = nproc;
stride = nprims/nproc;
}
for(i = 0; i < nworkers; i++){
newparams = emalloc(sizeof *newparams);
*newparams = *params;
newparams->eb = eb + i*stride;
newparams->ee = i == nworkers-1? ee: newparams->eb + stride;
sendp(paramsout[i], newparams);
}
params->job->times.E.t1 = nanosec();
free(params);
}
}
static void
renderer(void *arg)
{
Channel *jobc;
Renderjob *job;
Scene *sc;
Entity *ent;
SUparams *params;
Channel *paramsc;
uvlong time, lastid;
threadsetname("renderer");
jobc = arg;
lastid = 0;
paramsc = chancreate(sizeof(SUparams*), 8);
proccreate(entityproc, paramsc, mainstacksize);
while((job = recvp(jobc)) != nil){
time = nanosec();
job->times.R.t0 = time;
job->id = lastid++;
sc = job->scene;
if(sc->nents < 1){
nbsend(job->donec, nil);
continue;
}
for(ent = sc->ents.next; ent != &sc->ents; ent = ent->next){
params = emalloc(sizeof *params);
memset(params, 0, sizeof *params);
params->fb = job->fb;
params->job = job;
params->camera = job->camera;
params->entity = ent;
params->uni_time = time;
params->vshader = job->shaders->vshader;
params->fshader = job->shaders->fshader;
sendp(paramsc, params);
}
/* mark end of job */
params = emalloc(sizeof *params);
memset(params, 0, sizeof *params);
params->job = job;
sendp(paramsc, params);
job->times.R.t1 = nanosec();
}
}
Renderer *
initgraphics(void)
{
Renderer *r;
r = emalloc(sizeof *r);
r->c = chancreate(sizeof(Renderjob*), 8);
proccreate(renderer, r->c, mainstacksize);
return r;
}