ref: 1a6a53ff7c3964604e2e41c0961aef4736ffb98a
dir: tinyrend/main.c
#include <u.h>
#include <libc.h>
#include <thread.h>
#include <draw.h>
#include <memdraw.h>
#include <mouse.h>
#include <keyboard.h>
#include <geometry.h>
#include "libobj/obj.h"
#include "dat.h"
#include "fns.h"
Stats fps;
Framebufctl *fbctl;
Memimage *screenfb;
Memimage *red, *green, *blue;
OBJ *model;
Memimage *modeltex;
Channel *drawc;
int nprocs;
int showzbuffer;
int shownormals; /* XXX DBG */
char winspec[32];
Point3 light = {0,1,1,1}; /* global directional light */
Point3 camera = {0,0,3,1};
Point3 center = {0,0,0,1};
Point3 up = {0,1,0,0};
Matrix3 view, proj, rota;
double θ, ω;
double scale;
void
updatestats(Stats *s, uvlong v)
{
s->v = v;
s->n++;
s->acc += v;
s->avg = s->acc/s->n;
s->min = v < s->min || s->n == 1? v: s->min;
s->max = v > s->max || s->n == 1? v: s->max;
}
void
pixel(Memimage *dst, Point p, Memimage *src)
{
if(dst == nil || src == nil)
return;
memimagedraw(dst, rectaddpt(Rect(0,0,1,1), p), src, ZP, nil, ZP, SoverD);
}
void
bresenham(Memimage *dst, Point p0, Point p1, Memimage *src)
{
int steep = 0, Δe, e, Δy;
Point p, dp;
/* transpose the points */
if(abs(p0.x-p1.x) < abs(p0.y-p1.y)){
steep = 1;
swap(&p0.x, &p0.y);
swap(&p1.x, &p1.y);
}
/* make them left-to-right */
if(p0.x > p1.x){
swap(&p0.x, &p1.x);
swap(&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++){
if(steep) swap(&p.x, &p.y);
pixel(dst, p, src);
if(steep) swap(&p.x, &p.y);
e += Δe;
if(e > dp.x){
p.y += Δy;
e -= 2*dp.x;
}
}
}
int
ycoordsort(void *a, void *b)
{
return ((Point*)a)->y - ((Point*)b)->y;
}
void
triangle(Memimage *dst, Point p0, Point p1, Point p2, Memimage *src)
{
Triangle t;
t[0] = p0;
t[1] = p1;
t[2] = p2;
qsort(t, nelem(t), sizeof(Point), ycoordsort);
bresenham(dst, t[0], t[1], src);
bresenham(dst, t[1], t[2], src);
bresenham(dst, t[2], t[0], src);
}
void
filltriangle(Memimage *dst, Point p0, Point p1, Point p2, Memimage *src)
{
int y;
double m₀₂, m₀₁, m₁₂;
Point dp₀₂, dp₀₁, dp₁₂;
Triangle t;
t[0] = p0;
t[1] = p1;
t[2] = p2;
qsort(t, nelem(t), sizeof(Point), ycoordsort);
dp₀₂ = subpt(t[2], t[0]);
m₀₂ = dp₀₂.y == 0? 0: (double)dp₀₂.x/dp₀₂.y;
dp₀₁ = subpt(t[1], t[0]);
m₀₁ = dp₀₁.y == 0? 0: (double)dp₀₁.x/dp₀₁.y;
dp₁₂ = subpt(t[2], t[1]);
m₁₂ = dp₁₂.y == 0? 0: (double)dp₁₂.x/dp₁₂.y;
/* first half */
for(y = t[0].y; y <= t[1].y; y++)
bresenham(dst, Pt(t[0].x + (y-t[0].y)*m₀₂,y), Pt(t[0].x + (y-t[0].y)*m₀₁,y), src);
/* second half */
for(; y <= t[2].y; y++)
bresenham(dst, Pt(t[0].x + (y-t[0].y)*m₀₂,y), Pt(t[1].x + (y-t[1].y)*m₁₂,y), src);
}
void
viewport(Rectangle r)
{
identity3(view);
view[0][3] = r.max.x/2.0;
view[1][3] = r.max.y/2.0;
view[2][3] = 1.0/2.0;
view[0][0] = Dx(r)/2.0;
view[1][1] = -Dy(r)/2.0;
view[2][2] = 1.0/2.0;
}
void
projection(double c)
{
identity3(proj);
proj[3][2] = c;
}
void
lookat(Point3 eye, Point3 o, Point3 up)
{
Point3 x, y, z;
z = normvec3(subpt3(eye, o));
x = normvec3(crossvec3(up, z));
y = normvec3(crossvec3(z, x));
identity3(rota);
rota[0][0] = x.x; rota[0][1] = x.y; rota[0][2] = x.z; rota[0][3] = -o.x;
rota[1][0] = y.x; rota[1][1] = y.y; rota[1][2] = y.z; rota[1][3] = -o.y;
rota[2][0] = z.x; rota[2][1] = z.y; rota[2][2] = z.z; rota[2][3] = -o.z;
}
Point3
vertshader(VSparams *sp)
{
Matrix3 S = {
scale, 0, 0, 0,
0, scale, 0, 0,
0, 0, scale, 0,
0, 0, 0, 1,
}, M, V;
identity3(M);
identity3(V);
mulm3(M, rota);
mulm3(M, S);
mulm3(V, view);
mulm3(V, M);
*sp->n = qrotate(*sp->n, Vec3(0,1,0), θ+fmod(ω*sp->su->uni_time/1e9, 2*PI));
sp->su->var_intensity[sp->idx] = fmax(0, dotvec3(*sp->n, light));
*sp->n = xform3(*sp->n, M);
*sp->p = qrotate(*sp->p, Vec3(0,1,0), θ+fmod(ω*sp->su->uni_time/1e9, 2*PI));
*sp->p = xform3(*sp->p, V);
return *sp->p;
}
Memimage *
gouraudshader(FSparams *sp)
{
double intens;
intens = dotvec3(Vec3(sp->su->var_intensity[0], sp->su->var_intensity[1], sp->su->var_intensity[2]), sp->bc);
sp->cbuf[1] *= intens;
sp->cbuf[2] *= intens;
sp->cbuf[3] *= intens;
memfillcolor(sp->frag, *(ulong*)sp->cbuf);
return sp->frag;
}
Memimage *
toonshader(FSparams *sp)
{
double intens;
intens = dotvec3(Vec3(sp->su->var_intensity[0], sp->su->var_intensity[1], sp->su->var_intensity[2]), sp->bc);
intens = intens > 0.85? 1: intens > 0.60? 0.80: intens > 0.45? 0.60: intens > 0.30? 0.45: intens > 0.15? 0.30: 0;
sp->cbuf[1] = 0;
sp->cbuf[2] = 155*intens;
sp->cbuf[3] = 255*intens;
memfillcolor(sp->frag, *(ulong*)sp->cbuf);
return sp->frag;
}
void
rasterize(SUparams *params, Triangle3 st, Triangle2 tt, Memimage *frag)
{
FSparams fsp;
Triangle2 st₂, tt₂;
Rectangle bbox;
Point p, tp;
Point3 bc;
double z, w, depth;
uchar cbuf[4];
st₂.p0 = Pt2(st.p0.x/st.p0.w, st.p0.y/st.p0.w, 1);
st₂.p1 = Pt2(st.p1.x/st.p1.w, st.p1.y/st.p1.w, 1);
st₂.p2 = Pt2(st.p2.x/st.p2.w, st.p2.y/st.p2.w, 1);
/* find the triangle's bbox and clip it against the fb */
bbox = Rect(
min(min(st₂.p0.x, st₂.p1.x), st₂.p2.x), min(min(st₂.p0.y, st₂.p1.y), st₂.p2.y),
max(max(st₂.p0.x, st₂.p1.x), st₂.p2.x)+1, max(max(st₂.p0.y, st₂.p1.y), st₂.p2.y)+1
);
bbox.min.x = max(bbox.min.x, params->fb->r.min.x);
bbox.min.y = max(bbox.min.y, params->fb->r.min.y);
bbox.max.x = min(bbox.max.x, params->fb->r.max.x);
bbox.max.y = min(bbox.max.y, params->fb->r.max.y);
cbuf[0] = 0xFF;
fsp.su = params;
fsp.frag = frag;
fsp.cbuf = cbuf;
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(st₂, Pt2(p.x,p.y,1));
if(bc.x < 0 || bc.y < 0 || bc.z < 0)
continue;
z = st.p0.z*bc.x + st.p1.z*bc.y + st.p2.z*bc.z;
w = st.p0.w*bc.x + st.p1.w*bc.y + st.p2.w*bc.z;
depth = fclamp(z/w, 0, 1);
lock(¶ms->fb->zbuflk);
if(depth <= params->fb->zbuf[p.x + p.y*Dx(params->fb->r)]){
unlock(¶ms->fb->zbuflk);
continue;
}
params->fb->zbuf[p.x + p.y*Dx(params->fb->r)] = depth;
cbuf[1] = 0xFF*depth;
cbuf[2] = 0xFF*depth;
cbuf[3] = 0xFF*depth;
memfillcolor(frag, *(ulong*)cbuf);
pixel(params->fb->zb, p, frag);
unlock(¶ms->fb->zbuflk);
cbuf[0] = 0xFF;
if((tt.p0.w + tt.p1.w + tt.p2.w) != 0){
tt₂.p0 = mulpt2(tt.p0, bc.x);
tt₂.p1 = mulpt2(tt.p1, bc.y);
tt₂.p2 = mulpt2(tt.p2, bc.z);
tp.x = (tt₂.p0.x + tt₂.p1.x + tt₂.p2.x)*Dx(modeltex->r);
tp.y = (1 - (tt₂.p0.y + tt₂.p1.y + tt₂.p2.y))*Dy(modeltex->r);
switch(modeltex->chan){
case RGB24:
unloadmemimage(modeltex, rectaddpt(Rect(0,0,1,1), tp), cbuf+1, sizeof cbuf - 1);
break;
case RGBA32:
unloadmemimage(modeltex, rectaddpt(Rect(0,0,1,1), tp), cbuf, sizeof cbuf);
break;
}
}else
memset(cbuf+1, 0xFF, sizeof cbuf - 1);
fsp.p = p;
fsp.bc = bc;
pixel(params->fb->cb, p, params->fshader(&fsp));
}
}
void
shaderunit(void *arg)
{
SUparams *params;
VSparams vsp;
Memimage *frag;
OBJVertex *verts, *tverts, *nverts; /* geometric, texture and normals vertices */
OBJIndexArray *idxtab;
OBJElem **ep;
Triangle3 t, st, nt; /* world-, screen-space and normals triangles */
Triangle2 tt; /* texture triangle */
Point3 n; /* surface normal */
Point3 np0, np1, bc;
Triangle2 st₂;
params = arg;
vsp.su = params;
frag = rgb(DBlack);
threadsetname("shader unit #%d", params->id);
verts = model->vertdata[OBJVGeometric].verts;
tverts = model->vertdata[OBJVTexture].verts;
nverts = model->vertdata[OBJVNormal].verts;
for(ep = params->b; ep != params->e; ep++){
idxtab = &(*ep)->indextab[OBJVGeometric];
t.p0 = Pt3(verts[idxtab->indices[0]].x,verts[idxtab->indices[0]].y,verts[idxtab->indices[0]].z,verts[idxtab->indices[0]].w);
t.p1 = Pt3(verts[idxtab->indices[1]].x,verts[idxtab->indices[1]].y,verts[idxtab->indices[1]].z,verts[idxtab->indices[1]].w);
t.p2 = Pt3(verts[idxtab->indices[2]].x,verts[idxtab->indices[2]].y,verts[idxtab->indices[2]].z,verts[idxtab->indices[2]].w);
idxtab = &(*ep)->indextab[OBJVNormal];
if(idxtab->nindex == 3){
nt.p0 = Vec3(nverts[idxtab->indices[0]].i, nverts[idxtab->indices[0]].j, nverts[idxtab->indices[0]].k);
nt.p1 = Vec3(nverts[idxtab->indices[1]].i, nverts[idxtab->indices[1]].j, nverts[idxtab->indices[1]].k);
nt.p2 = Vec3(nverts[idxtab->indices[2]].i, nverts[idxtab->indices[2]].j, nverts[idxtab->indices[2]].k);
nt.p0 = normvec3(nt.p0);
nt.p1 = normvec3(nt.p1);
nt.p2 = normvec3(nt.p2);
}else{
n = normvec3(crossvec3(subpt3(t.p2, t.p0), subpt3(t.p1, t.p0)));
nt.p0 = nt.p1 = nt.p2 = mulpt3(n, -1);
}
vsp.p = &t.p0;
vsp.n = &nt.p0;
vsp.idx = 0;
st.p0 = params->vshader(&vsp);
vsp.p = &t.p1;
vsp.n = &nt.p1;
vsp.idx = 1;
st.p1 = params->vshader(&vsp);
vsp.p = &t.p2;
vsp.n = &nt.p2;
vsp.idx = 2;
st.p2 = params->vshader(&vsp);
st₂.p0 = Pt2(st.p0.x/st.p0.w, st.p0.y/st.p0.w, 1);
st₂.p1 = Pt2(st.p1.x/st.p1.w, st.p1.y/st.p1.w, 1);
st₂.p2 = Pt2(st.p2.x/st.p2.w, st.p2.y/st.p2.w, 1);
bc = barycoords(st₂, centroid(st₂));
np0 = centroid3((Triangle3){divpt3(st.p0, st.p0.w),divpt3(st.p1, st.p1.w),divpt3(st.p2, st.p2.w)});
np1 = Vec3(
nt.p0.x*bc.x + nt.p1.x*bc.y + nt.p2.x*bc.z,
nt.p0.y*bc.x + nt.p1.y*bc.y + nt.p2.y*bc.z,
nt.p0.z*bc.x + nt.p1.z*bc.y + nt.p2.z*bc.z);
np1 = addpt3(np0, mulpt3(np1, Dx(params->fb->r)/32));
triangle(params->fb->nb, Pt(st₂.p0.x,st₂.p0.y), Pt(st₂.p1.x,st₂.p1.y), Pt(st₂.p2.x,st₂.p2.y), red);
bresenham(params->fb->nb, Pt(np0.x,np0.y), Pt(np1.x,np1.y), green);
idxtab = &(*ep)->indextab[OBJVTexture];
if(modeltex != nil && idxtab->nindex == 3){
tt.p0 = Pt2(tverts[idxtab->indices[0]].u, tverts[idxtab->indices[0]].v, 1);
tt.p1 = Pt2(tverts[idxtab->indices[1]].u, tverts[idxtab->indices[1]].v, 1);
tt.p2 = Pt2(tverts[idxtab->indices[2]].u, tverts[idxtab->indices[2]].v, 1);
}else
memset(&tt, 0, sizeof tt);
rasterize(params, st, tt, frag);
}
freememimage(frag);
sendp(params->donec, nil);
free(params);
threadexits(nil);
}
/*
* it only processes quads for now.
*/
static int
triangulate(OBJElem **newe, OBJElem *e)
{
OBJIndexArray *newidxtab;
OBJIndexArray *idxtab;
idxtab = &e->indextab[OBJVGeometric];
newe[0] = emalloc(sizeof *newe[0]);
newe[0]->type = OBJEFace;
newidxtab = &newe[0]->indextab[OBJVGeometric];
newidxtab->nindex = 3;
newidxtab->indices = emalloc(newidxtab->nindex*sizeof(*newidxtab->indices));
newidxtab->indices[0] = idxtab->indices[0];
newidxtab->indices[1] = idxtab->indices[1];
newidxtab->indices[2] = idxtab->indices[2];
idxtab = &e->indextab[OBJVTexture];
newidxtab = &newe[0]->indextab[OBJVTexture];
newidxtab->nindex = 3;
newidxtab->indices = emalloc(newidxtab->nindex*sizeof(*newidxtab->indices));
newidxtab->indices[0] = idxtab->indices[0];
newidxtab->indices[1] = idxtab->indices[1];
newidxtab->indices[2] = idxtab->indices[2];
idxtab = &e->indextab[OBJVNormal];
newidxtab = &newe[0]->indextab[OBJVNormal];
newidxtab->nindex = 3;
newidxtab->indices = emalloc(newidxtab->nindex*sizeof(*newidxtab->indices));
newidxtab->indices[0] = idxtab->indices[0];
newidxtab->indices[1] = idxtab->indices[1];
newidxtab->indices[2] = idxtab->indices[2];
idxtab = &e->indextab[OBJVGeometric];
newe[1] = emalloc(sizeof *newe[1]);
newe[1]->type = OBJEFace;
newidxtab = &newe[1]->indextab[OBJVGeometric];
newidxtab->nindex = 3;
newidxtab->indices = emalloc(newidxtab->nindex*sizeof(*newidxtab->indices));
newidxtab->indices[0] = idxtab->indices[0];
newidxtab->indices[1] = idxtab->indices[2];
newidxtab->indices[2] = idxtab->indices[3];
idxtab = &e->indextab[OBJVTexture];
newidxtab = &newe[1]->indextab[OBJVTexture];
newidxtab->nindex = 3;
newidxtab->indices = emalloc(newidxtab->nindex*sizeof(*newidxtab->indices));
newidxtab->indices[0] = idxtab->indices[0];
newidxtab->indices[1] = idxtab->indices[2];
newidxtab->indices[2] = idxtab->indices[3];
idxtab = &e->indextab[OBJVNormal];
newidxtab = &newe[1]->indextab[OBJVNormal];
newidxtab->nindex = 3;
newidxtab->indices = emalloc(newidxtab->nindex*sizeof(*newidxtab->indices));
newidxtab->indices[0] = idxtab->indices[0];
newidxtab->indices[1] = idxtab->indices[2];
newidxtab->indices[2] = idxtab->indices[3];
return 2;
}
void
shade(Framebuf *fb, Shader *s)
{
static int nparts, nworkers;
static OBJElem **elems = nil;
OBJElem *trielems[2];
int i, nelems;
uvlong time;
OBJObject *o;
OBJElem *e;
OBJIndexArray *idxtab;
SUparams *params;
Channel *donec;
if(elems == nil){
nelems = 0;
for(i = 0; i < nelem(model->objtab); i++)
for(o = model->objtab[i]; o != nil; o = o->next)
for(e = o->child; e != nil; e = e->next){
idxtab = &e->indextab[OBJVGeometric];
/* discard non-triangles */
if(e->type != OBJEFace || (idxtab->nindex != 3 && idxtab->nindex != 4))
continue;
if(idxtab->nindex == 4){
triangulate(trielems, e);
nelems += 2;
elems = erealloc(elems, nelems*sizeof(*elems));
elems[nelems-2] = trielems[0];
elems[nelems-1] = trielems[1];
}else{
elems = erealloc(elems, ++nelems*sizeof(*elems));
elems[nelems-1] = e;
}
}
if(nelems < nprocs){
nworkers = nelems;
nparts = 1;
}else{
nworkers = nprocs;
nparts = nelems/nprocs;
}
}
time = nanosec();
donec = chancreate(sizeof(void*), 0);
for(i = 0; i < nworkers; i++){
params = emalloc(sizeof *params);
params->fb = fb;
params->b = &elems[i*nparts];
params->e = params->b + nparts;
params->id = i;
params->donec = donec;
params->uni_time = time;
params->vshader = s->vshader;
params->fshader = s->fshader;
proccreate(shaderunit, params, mainstacksize);
// fprint(2, "spawned su %d for elems [%d, %d)\n", params->id, i*nparts, i*nparts+nparts);
}
while(i--)
recvp(donec);
chanfree(donec);
}
Memimage *
triangleshader(FSparams *sp)
{
Triangle2 t;
Rectangle bbox;
Point3 bc;
uchar cbuf[4];
t.p0 = Pt2(240,200,1);
t.p1 = Pt2(400,40,1);
t.p2 = Pt2(240,40,1);
bbox = Rect(
min(min(t.p0.x, t.p1.x), t.p2.x), min(min(t.p0.y, t.p1.y), t.p2.y),
max(max(t.p0.x, t.p1.x), t.p2.x), max(max(t.p0.y, t.p1.y), t.p2.y)
);
if(!ptinrect(sp->p, bbox))
return nil;
bc = barycoords(t, Pt2(sp->p.x,sp->p.y,1));
if(bc.x < 0 || bc.y < 0 || bc.z < 0)
return nil;
cbuf[0] = 0xFF;
cbuf[1] = 0xFF*bc.z;
cbuf[2] = 0xFF*bc.y;
cbuf[3] = 0xFF*bc.x;
memfillcolor(sp->frag, *(ulong*)cbuf);
return sp->frag;
}
Memimage *
circleshader(FSparams *sp)
{
Point2 uv;
double r, d;
uchar cbuf[4];
uv = Pt2(sp->p.x,sp->p.y,1);
uv.x /= Dx(sp->su->fb->r);
uv.y /= Dy(sp->su->fb->r);
// r = 0.3;
r = 0.3*fabs(sin(sp->su->uni_time/1e9));
d = vec2len(subpt2(uv, Vec2(0.5,0.5)));
if(d > r + r*0.05 || d < r - r*0.05)
return nil;
cbuf[0] = 0xFF;
cbuf[1] = 0;
cbuf[2] = 0xFF*uv.y;
cbuf[3] = 0xFF*uv.x;
memfillcolor(sp->frag, *(ulong*)cbuf);
return sp->frag;
}
/* some shaping functions from The Book of Shaders, Chapter 5 */
Memimage *
sfshader(FSparams *sp)
{
Point2 uv;
double y, pct;
uchar cbuf[4];
uv = Pt2(sp->p.x,sp->p.y,1);
uv.x /= Dx(sp->su->fb->r);
uv.y /= Dy(sp->su->fb->r);
uv.y = 1 - uv.y; /* make [0 0] the bottom-left corner */
// y = step(0.5, uv.x);
// y = pow(uv.x, 5);
// y = sin(uv.x);
y = sin(uv.x*sp->su->uni_time/1e8)/2.0 + 0.5;
// y = smoothstep(0.1, 0.9, uv.x);
pct = smoothstep(y-0.02, y, uv.y) - smoothstep(y, y+0.02, uv.y);
cbuf[0] = 0xFF;
cbuf[1] = 0xFF*flerp(y, 0, pct);
cbuf[2] = 0xFF*flerp(y, 1, pct);
cbuf[3] = 0xFF*flerp(y, 0, pct);
memfillcolor(sp->frag, *(ulong*)cbuf);
return sp->frag;
}
Memimage *
boxshader(FSparams *sp)
{
Point2 uv, p;
Point2 r;
uchar cbuf[4];
uv = Pt2(sp->p.x,sp->p.y,1);
uv.x /= Dx(sp->su->fb->r);
uv.y /= Dy(sp->su->fb->r);
r = Vec2(0.2,0.4);
p = Pt2(fabs(uv.x - 0.5), fabs(uv.y - 0.5), 1);
p = subpt2(p, r);
p.x = fmax(p.x, 0);
p.y = fmax(p.y, 0);
if(vec2len(p) > 0)
return nil;
cbuf[0] = 0xFF;
cbuf[1] = 0xFF*smoothstep(0,1,uv.x+uv.y);
cbuf[2] = 0xFF*uv.y;
cbuf[3] = 0xFF*uv.x;
memfillcolor(sp->frag, *(ulong*)cbuf);
return sp->frag;
}
Point3
ivshader(VSparams *sp)
{
Matrix3 M, V, S = {
scale, 0, 0, 0,
0, scale, 0, 0,
0, 0, scale, 0,
0, 0, 0, 1,
};
identity3(M);
identity3(V);
mulm3(M, rota);
mulm3(M, S);
mulm3(V, view);
mulm3(V, M);
return xform3(*sp->p, V);
}
Memimage *
identshader(FSparams *sp)
{
memfillcolor(sp->frag, *(ulong*)sp->cbuf);
return sp->frag;
}
Shader shadertab[] = {
{ "triangle", ivshader, triangleshader },
{ "circle", ivshader, circleshader },
{ "box", ivshader, boxshader },
{ "sf", ivshader, sfshader },
{ "gouraud", vertshader, gouraudshader },
{ "toon", vertshader, toonshader },
{ "ident", vertshader, identshader },
};
Shader *
getshader(char *name)
{
int i;
for(i = 0; i < nelem(shadertab); i++)
if(strcmp(shadertab[i].name, name) == 0)
return &shadertab[i];
return nil;
}
void
drawstats(void)
{
char buf[128];
/* fps stats hold latency, so max period is min frequency */
snprint(buf, sizeof buf, "FPS %.0f/%.0f/%.0f/%.0f", !fps.max? 0: 1e9/fps.max, !fps.avg? 0: 1e9/fps.avg, !fps.min? 0: 1e9/fps.min, !fps.v? 0: 1e9/fps.v);
stringbg(screen, Pt(screen->r.min.x+10,screen->r.max.y-20), display->black, ZP, font, buf, display->white, ZP);
}
void
redraw(void)
{
memfillcolor(screenfb, 0x888888FF);
fbctl->draw(fbctl, screenfb, showzbuffer);
lockdisplay(display);
loadimage(screen, rectaddpt(screenfb->r, screen->r.min), byteaddr(screenfb, screenfb->r.min), bytesperline(screenfb->r, screenfb->depth)*Dy(screenfb->r));
drawstats();
flushimage(display, 1);
unlockdisplay(display);
}
void
render(Shader *s)
{
uvlong t0, t1;
fbctl->reset(fbctl);
t0 = nanosec();
shade(fbctl->fb[fbctl->idx^1], s); /* address the back buffer */
t1 = nanosec();
updatestats(&fps, t1-t0);
}
void
renderer(void *arg)
{
threadsetname("renderer");
for(;;){
render((Shader*)arg);
fbctl->swap(fbctl);
nbsendp(drawc, nil);
}
}
static char *
genrmbmenuitem(int idx)
{
enum {
TOGGLEZBUF,
TOGGLENORM,
};
switch(idx){
case TOGGLEZBUF:
return showzbuffer? "hide z-buffer": "show z-buffer";
case TOGGLENORM:
return shownormals? "hide normals": "show normals";
}
return nil;
}
void
rmb(Mousectl *mc, Keyboardctl *)
{
enum {
TOGGLEZBUF,
TOGGLENORM,
};
static Menu menu = { .gen = genrmbmenuitem };
switch(menuhit(3, mc, &menu, _screen)){
case TOGGLEZBUF:
showzbuffer ^= 1;
break;
case TOGGLENORM:
shownormals ^= 1;
break;
}
nbsendp(drawc, nil);
}
void
lmb(Mousectl *mc, Keyboardctl *)
{
Point p;
p = subpt(mc->xy, screen->r.min);
fprint(2, "p %P z %g\n", p, fbctl->fb[fbctl->idx]->zbuf[p.x + p.y*Dx(fbctl->fb[fbctl->idx]->r)]);
}
void
mouse(Mousectl *mc, Keyboardctl *kc)
{
if((mc->buttons&1) != 0)
lmb(mc, kc);
if((mc->buttons&4) != 0)
rmb(mc, kc);
if((mc->buttons&8) != 0)
scale += 0.1;
if((mc->buttons&16) != 0)
scale -= 0.1;
}
void
key(Rune r)
{
switch(r){
case Kdel:
case 'q':
threadexitsall(nil);
case 'w':
case 's':
camera.z += r == 'w'? -1: 1;
viewport(screenfb->r);
projection(-1.0/vec3len(subpt3(camera, center)));
lookat(camera, center, up);
mulm3(view, proj);
break;
case 'a':
case 'd':
camera.x += r == 'a'? -1: 1;
viewport(screenfb->r);
projection(-1.0/vec3len(subpt3(camera, center)));
lookat(camera, center, up);
mulm3(view, proj);
break;
case Kdown:
case Kup:
camera.y += r == Kdown? -1: 1;
viewport(screenfb->r);
projection(-1.0/vec3len(subpt3(camera, center)));
lookat(camera, center, up);
mulm3(view, proj);
break;
}
}
void
usage(void)
{
fprint(2, "usage: %s [-n nprocs] [-m objfile] [-t texfile] [-a yrotangle] [-s shader] [-w width] [-h height]\n", argv0);
exits("usage");
}
void
threadmain(int argc, char *argv[])
{
Mousectl *mc;
Keyboardctl *kc;
Rune r;
Shader *s;
char *mdlpath, *texpath, *p;
char *sname;
int fbw, fbh;
GEOMfmtinstall();
mdlpath = "mdl/quad.obj";
texpath = nil;
sname = "gouraud";
fbw = 200;
fbh = 200;
ω = 20*DEG;
scale = 1;
ARGBEGIN{
case 'n':
nprocs = strtoul(EARGF(usage()), nil, 10);
break;
case 'm':
mdlpath = EARGF(usage());
break;
case 't':
texpath = EARGF(usage());
break;
case 'a':
θ = strtod(EARGF(usage()), nil)*DEG;
break;
case 'v':
ω = strtod(EARGF(usage()), nil)*DEG;
break;
case 's':
sname = EARGF(usage());
break;
case 'w':
fbw = strtoul(EARGF(usage()), nil, 10);
break;
case 'h':
fbh = strtoul(EARGF(usage()), nil, 10);
break;
default: usage();
}ARGEND;
if(argc != 0)
usage();
if(nprocs < 1)
nprocs = strtoul(getenv("NPROC"), nil, 10);
if((s = getshader(sname)) == nil)
sysfatal("couldn't find %s shader", sname);
if((model = objparse(mdlpath)) == nil)
sysfatal("objparse: %r");
if(texpath != nil){
if((p = strrchr(texpath, '/')) == nil)
p = texpath;
p = strchr(p, '.');
if(p == nil)
sysfatal("unknown image file");
if(strcmp(++p, "tga") == 0 && (modeltex = readtga(texpath)) == nil)
sysfatal("readtga: %r");
else if(strcmp(p, "png") == 0 && (modeltex = readpng(texpath)) == nil)
sysfatal("readpng: %r");
}
{
int i, nv[OBJNVERT], nf;
OBJObject *o;
OBJElem *e;
nf = 0;
memset(nv, 0, sizeof nv);
for(i = 0; i < OBJNVERT; i++) nv[i] += model->vertdata[i].nvert;
for(i = 0; i < OBJHTSIZE; i++) if((o = model->objtab[i]) != nil)
for(e = o->child; e != nil; e = e->next) if(e->type == OBJEFace) nf++;
fprint(2, "v %d vn %d vt %d f %d\n", nv[OBJVGeometric], nv[OBJVNormal], nv[OBJVTexture], nf);
}
snprint(winspec, sizeof winspec, "-dx %d -dy %d", fbw, fbh);
if(newwindow(winspec) < 0)
sysfatal("newwindow: %r");
if(initdraw(nil, nil, "tinyrend") < 0)
sysfatal("initdraw: %r");
if(memimageinit() != 0)
sysfatal("memimageinit: %r");
if((mc = initmouse(nil, screen)) == nil)
sysfatal("initmouse: %r");
if((kc = initkeyboard(nil)) == nil)
sysfatal("initkeyboard: %r");
screenfb = eallocmemimage(rectsubpt(screen->r, screen->r.min), screen->chan);
fbctl = newfbctl(screenfb->r);
red = rgb(DRed);
green = rgb(DGreen);
blue = rgb(DBlue);
viewport(screenfb->r);
projection(-1.0/vec3len(subpt3(camera, center)));
lookat(camera, center, up);
mulm3(view, proj);
light = normvec3(subpt3(light, center));
drawc = chancreate(sizeof(void*), 1);
display->locking = 1;
unlockdisplay(display);
proccreate(renderer, s, mainstacksize);
for(;;){
enum { MOUSE, RESIZE, KEYBOARD, DRAW };
Alt a[] = {
{mc->c, &mc->Mouse, CHANRCV},
{mc->resizec, nil, CHANRCV},
{kc->c, &r, CHANRCV},
{drawc, nil, CHANRCV},
{nil, nil, CHANEND}
};
switch(alt(a)){
case MOUSE:
mouse(mc, kc);
break;
case RESIZE:
resized();
break;
case KEYBOARD:
key(r);
break;
case DRAW:
redraw();
break;
}
}
}
void
resized(void)
{
lockdisplay(display);
if(getwindow(display, Refnone) < 0)
sysfatal("couldn't resize");
unlockdisplay(display);
nbsend(drawc, nil);
}