#include <u.h>
#include <libc.h>
#include <draw.h>
#include <memdraw.h>
#include <memlayer.h>
enum
{
Arrow1 = 8,
Arrow2 = 10,
Arrow3 = 3,
};
static
int
lmin(int a, int b)
{
if(a < b)
return a;
return b;
}
static
int
lmax(int a, int b)
{
if(a > b)
return a;
return b;
}
#ifdef NOTUSED
/*
* Rather than line clip, we run the Bresenham loop over the full line,
* and clip on each pixel. This is more expensive but means that
* lines look the same regardless of how the windowing has tiled them.
* For speed, we check for clipping outside the loop and make the
* test easy when possible.
*/
static
void
horline1(Memimage *dst, Point p0, Point p1, int srcval, Rectangle clipr)
{
int x, y, dy, deltay, deltax, maxx;
int dd, easy, e, bpp, m, m0;
uchar *d;
deltax = p1.x - p0.x;
deltay = p1.y - p0.y;
dd = dst->width*sizeof(ulong);
dy = 1;
if(deltay < 0){
dd = -dd;
deltay = -deltay;
dy = -1;
}
maxx = lmin(p1.x, clipr.max.x-1);
bpp = dst->depth;
m0 = 0xFF^(0xFF>>bpp);
m = m0 >> (p0.x&(7/dst->depth))*bpp;
easy = ptinrect(p0, clipr) && ptinrect(p1, clipr);
e = 2*deltay - deltax;
y = p0.y;
d = byteaddr(dst, p0);
deltay *= 2;
deltax = deltay - 2*deltax;
for(x=p0.x; x<=maxx; x++){
if(easy || (clipr.min.x<=x && clipr.min.y<=y && y<clipr.max.y))
*d ^= (*d^srcval) & m;
if(e > 0){
y += dy;
d += dd;
e += deltax;
}else
e += deltay;
d++;
m >>= bpp;
if(m == 0)
m = m0;
}
}
static
void
verline1(Memimage *dst, Point p0, Point p1, int srcval, Rectangle clipr)
{
int x, y, deltay, deltax, maxy;
int easy, e, bpp, m, m0, dd;
uchar *d;
deltax = p1.x - p0.x;
deltay = p1.y - p0.y;
dd = 1;
if(deltax < 0){
dd = -1;
deltax = -deltax;
}
maxy = lmin(p1.y, clipr.max.y-1);
bpp = dst->depth;
m0 = 0xFF^(0xFF>>bpp);
m = m0 >> (p0.x&(7/dst->depth))*bpp;
easy = ptinrect(p0, clipr) && ptinrect(p1, clipr);
e = 2*deltax - deltay;
x = p0.x;
d = byteaddr(dst, p0);
deltax *= 2;
deltay = deltax - 2*deltay;
for(y=p0.y; y<=maxy; y++){
if(easy || (clipr.min.y<=y && clipr.min.x<=x && x<clipr.max.x))
*d ^= (*d^srcval) & m;
if(e > 0){
x += dd;
d += dd;
e += deltay;
}else
e += deltax;
d += dst->width*sizeof(ulong);
m >>= bpp;
if(m == 0)
m = m0;
}
}
static
void
horliner(Memimage *dst, Point p0, Point p1, Memimage *src, Point dsrc, Rectangle clipr)
{
int x, y, sx, sy, deltay, deltax, minx, maxx;
int bpp, m, m0;
uchar *d, *s;
deltax = p1.x - p0.x;
deltay = p1.y - p0.y;
sx = drawreplxy(src->r.min.x, src->r.max.x, p0.x+dsrc.x);
minx = lmax(p0.x, clipr.min.x);
maxx = lmin(p1.x, clipr.max.x-1);
bpp = dst->depth;
m0 = 0xFF^(0xFF>>bpp);
m = m0 >> (minx&(7/dst->depth))*bpp;
for(x=minx; x<=maxx; x++){
y = p0.y + (deltay*(x-p0.x)+deltax/2)/deltax;
if(clipr.min.y<=y && y<clipr.max.y){
d = byteaddr(dst, Pt(x, y));
sy = drawreplxy(src->r.min.y, src->r.max.y, y+dsrc.y);
s = byteaddr(src, Pt(sx, sy));
*d ^= (*d^*s) & m;
}
if(++sx >= src->r.max.x)
sx = src->r.min.x;
m >>= bpp;
if(m == 0)
m = m0;
}
}
static
void
verliner(Memimage *dst, Point p0, Point p1, Memimage *src, Point dsrc, Rectangle clipr)
{
int x, y, sx, sy, deltay, deltax, miny, maxy;
int bpp, m, m0;
uchar *d, *s;
deltax = p1.x - p0.x;
deltay = p1.y - p0.y;
sy = drawreplxy(src->r.min.y, src->r.max.y, p0.y+dsrc.y);
miny = lmax(p0.y, clipr.min.y);
maxy = lmin(p1.y, clipr.max.y-1);
bpp = dst->depth;
m0 = 0xFF^(0xFF>>bpp);
for(y=miny; y<=maxy; y++){
if(deltay == 0) /* degenerate line */
x = p0.x;
else
x = p0.x + (deltax*(y-p0.y)+deltay/2)/deltay;
if(clipr.min.x<=x && x<clipr.max.x){
m = m0 >> (x&(7/dst->depth))*bpp;
d = byteaddr(dst, Pt(x, y));
sx = drawreplxy(src->r.min.x, src->r.max.x, x+dsrc.x);
s = byteaddr(src, Pt(sx, sy));
*d ^= (*d^*s) & m;
}
if(++sy >= src->r.max.y)
sy = src->r.min.y;
}
}
static
void
horline(Memimage *dst, Point p0, Point p1, Memimage *src, Point dsrc, Rectangle clipr)
{
int x, y, deltay, deltax, minx, maxx;
int bpp, m, m0;
uchar *d, *s;
deltax = p1.x - p0.x;
deltay = p1.y - p0.y;
minx = lmax(p0.x, clipr.min.x);
maxx = lmin(p1.x, clipr.max.x-1);
bpp = dst->depth;
m0 = 0xFF^(0xFF>>bpp);
m = m0 >> (minx&(7/dst->depth))*bpp;
for(x=minx; x<=maxx; x++){
y = p0.y + (deltay*(x-p0.x)+deltay/2)/deltax;
if(clipr.min.y<=y && y<clipr.max.y){
d = byteaddr(dst, Pt(x, y));
s = byteaddr(src, addpt(dsrc, Pt(x, y)));
*d ^= (*d^*s) & m;
}
m >>= bpp;
if(m == 0)
m = m0;
}
}
static
void
verline(Memimage *dst, Point p0, Point p1, Memimage *src, Point dsrc, Rectangle clipr)
{
int x, y, deltay, deltax, miny, maxy;
int bpp, m, m0;
uchar *d, *s;
deltax = p1.x - p0.x;
deltay = p1.y - p0.y;
miny = lmax(p0.y, clipr.min.y);
maxy = lmin(p1.y, clipr.max.y-1);
bpp = dst->depth;
m0 = 0xFF^(0xFF>>bpp);
for(y=miny; y<=maxy; y++){
if(deltay == 0) /* degenerate line */
x = p0.x;
else
x = p0.x + deltax*(y-p0.y)/deltay;
if(clipr.min.x<=x && x<clipr.max.x){
m = m0 >> (x&(7/dst->depth))*bpp;
d = byteaddr(dst, Pt(x, y));
s = byteaddr(src, addpt(dsrc, Pt(x, y)));
*d ^= (*d^*s) & m;
}
}
}
#endif /* NOTUSED */
static Memimage*
membrush(int radius)
{
static Memimage *brush;
static int brushradius;
if(brush==nil || brushradius!=radius){
freememimage(brush);
brush = allocmemimage(Rect(0, 0, 2*radius+1, 2*radius+1), memopaque->chan);
if(brush != nil){
memfillcolor(brush, DTransparent); /* zeros */
memellipse(brush, Pt(radius, radius), radius, radius, -1, memopaque, Pt(radius, radius), S);
}
brushradius = radius;
}
return brush;
}
static
void
discend(Point p, int radius, Memimage *dst, Memimage *src, Point dsrc, int op)
{
Memimage *disc;
Rectangle r;
disc = membrush(radius);
if(disc != nil){
r.min.x = p.x - radius;
r.min.y = p.y - radius;
r.max.x = p.x + radius+1;
r.max.y = p.y + radius+1;
memdraw(dst, r, src, addpt(r.min, dsrc), disc, Pt(0,0), op);
}
}
static
void
arrowend(Point tip, Point *pp, int end, int sin, int cos, int radius)
{
int x1, x2, x3;
/* before rotation */
if(end == Endarrow){
x1 = Arrow1;
x2 = Arrow2;
x3 = Arrow3;
}else{
x1 = (end>>5) & 0x1FF; /* distance along line from end of line to tip */
x2 = (end>>14) & 0x1FF; /* distance along line from barb to tip */
x3 = (end>>23) & 0x1FF; /* distance perpendicular from edge of line to barb */
}
/* comments follow track of right-facing arrowhead */
pp->x = tip.x+((2*radius+1)*sin/2-x1*cos); /* upper side of shaft */
pp->y = tip.y-((2*radius+1)*cos/2+x1*sin);
pp++;
pp->x = tip.x+((2*radius+2*x3+1)*sin/2-x2*cos); /* upper barb */
pp->y = tip.y-((2*radius+2*x3+1)*cos/2+x2*sin);
pp++;
pp->x = tip.x;
pp->y = tip.y;
pp++;
pp->x = tip.x+(-(2*radius+2*x3+1)*sin/2-x2*cos); /* lower barb */
pp->y = tip.y-(-(2*radius+2*x3+1)*cos/2+x2*sin);
pp++;
pp->x = tip.x+(-(2*radius+1)*sin/2-x1*cos); /* lower side of shaft */
pp->y = tip.y+((2*radius+1)*cos/2-x1*sin);
}
void
_memimageline(Memimage *dst, Point p0, Point p1, int end0, int end1, int radius, Memimage *src, Point sp, Rectangle clipr, int op)
{
/*
* BUG: We should really really pick off purely horizontal and purely
* vertical lines and handle them separately with calls to memimagedraw
* on rectangles.
*/
int hor;
int sin, cos, dx, dy, t;
Rectangle oclipr, r;
Point q, pts[10], *pp, d;
if(radius < 0)
return;
if(rectclip(&clipr, dst->r) == 0)
return;
if(rectclip(&clipr, dst->clipr) == 0)
return;
d = subpt(sp, p0);
if(rectclip(&clipr, rectsubpt(src->clipr, d)) == 0)
return;
if((src->flags&Frepl)==0 && rectclip(&clipr, rectsubpt(src->r, d))==0)
return;
/* this means that only verline() handles degenerate lines (p0==p1) */
hor = (abs(p1.x-p0.x) > abs(p1.y-p0.y));
/*
* Clipping is a little peculiar. We can't use Sutherland-Cohen
* clipping because lines are wide. But this is probably just fine:
* we do all math with the original p0 and p1, but clip when deciding
* what pixels to draw. This means the layer code can call this routine,
* using clipr to define the region being written, and get the same set
* of pixels regardless of the dicing.
*/
if((hor && p0.x>p1.x) || (!hor && p0.y>p1.y)){
q = p0;
p0 = p1;
p1 = q;
t = end0;
end0 = end1;
end1 = t;
}
if((p0.x == p1.x || p0.y == p1.y) && (end0&0x1F) == Endsquare && (end1&0x1F) == Endsquare){
r.min = p0;
r.max = p1;
if(p0.x == p1.x){
r.min.x -= radius;
r.max.x += radius+1;
}
else{
r.min.y -= radius;
r.max.y += radius+1;
}
oclipr = dst->clipr;
sp = addpt(r.min, d);
dst->clipr = clipr;
memimagedraw(dst, r, src, sp, memopaque, sp, op);
dst->clipr = oclipr;
return;
}
/* Hard: */
/* draw thick line using polygon fill */
icossin2(p1.x-p0.x, p1.y-p0.y, &cos, &sin);
dx = (sin*(2*radius+1))/2;
dy = (cos*(2*radius+1))/2;
pp = pts;
oclipr = dst->clipr;
dst->clipr = clipr;
q.x = ICOSSCALE*p0.x+ICOSSCALE/2-cos/2;
q.y = ICOSSCALE*p0.y+ICOSSCALE/2-sin/2;
switch(end0 & 0x1F){
case Enddisc:
discend(p0, radius, dst, src, d, op);
/* fall through */
case Endsquare:
default:
pp->x = q.x-dx;
pp->y = q.y+dy;
pp++;
pp->x = q.x+dx;
pp->y = q.y-dy;
pp++;
break;
case Endarrow:
arrowend(q, pp, end0, -sin, -cos, radius);
_memfillpolysc(dst, pts, 5, ~0, src, addpt(pts[0], mulpt(d, ICOSSCALE)), 1, 10, 1, op);
pp[1] = pp[4];
pp += 2;
}
q.x = ICOSSCALE*p1.x+ICOSSCALE/2+cos/2;
q.y = ICOSSCALE*p1.y+ICOSSCALE/2+sin/2;
switch(end1 & 0x1F){
case Enddisc:
discend(p1, radius, dst, src, d, op);
/* fall through */
case Endsquare:
default:
pp->x = q.x+dx;
pp->y = q.y-dy;
pp++;
pp->x = q.x-dx;
pp->y = q.y+dy;
pp++;
break;
case Endarrow:
arrowend(q, pp, end1, sin, cos, radius);
_memfillpolysc(dst, pp, 5, ~0, src, addpt(pp[0], mulpt(d, ICOSSCALE)), 1, 10, 1, op);
pp[1] = pp[4];
pp += 2;
}
_memfillpolysc(dst, pts, pp-pts, ~0, src, addpt(pts[0], mulpt(d, ICOSSCALE)), 0, 10, 1, op);
dst->clipr = oclipr;
return;
}
void
memimageline(Memimage *dst, Point p0, Point p1, int end0, int end1, int radius, Memimage *src, Point sp, int op)
{
_memimageline(dst, p0, p1, end0, end1, radius, src, sp, dst->clipr, op);
}
/*
* Simple-minded conservative code to compute bounding box of line.
* Result is probably a little larger than it needs to be.
*/
static
void
addbbox(Rectangle *r, Point p)
{
if(r->min.x > p.x)
r->min.x = p.x;
if(r->min.y > p.y)
r->min.y = p.y;
if(r->max.x < p.x+1)
r->max.x = p.x+1;
if(r->max.y < p.y+1)
r->max.y = p.y+1;
}
int
memlineendsize(int end)
{
int x3;
if((end&0x3F) != Endarrow)
return 0;
if(end == Endarrow)
x3 = Arrow3;
else
x3 = (end>>23) & 0x1FF;
return x3;
}
Rectangle
memlinebbox(Point p0, Point p1, int end0, int end1, int radius)
{
Rectangle r, r1;
int extra;
r.min.x = 10000000;
r.min.y = 10000000;
r.max.x = -10000000;
r.max.y = -10000000;
extra = lmax(memlineendsize(end0), memlineendsize(end1));
r1 = insetrect(canonrect(Rpt(p0, p1)), -(radius+extra));
addbbox(&r, r1.min);
addbbox(&r, r1.max);
return r;
}
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