speedwm-personal/layouts.c

/* This C code handles all layouts.
 * You may choose to remove layouts here if you don't find them useful.
 *
 * Luckily for you though, I've added simple options to disable them from getting compiled into the code at all.
 * To change options, edit toggle.h.
 */

#if LAYOUT_TILE
static void
tile(Monitor *m)
{
	unsigned int i, n;
	int oh, ov, ih, iv;
	int mx = 0, my = 0, mh = 0, mw = 0;
	int sx = 0, sy = 0, sh = 0, sw = 0;
	float mfacts, sfacts;
	int mrest, srest;
	Client *c;

	getgaps(m, &oh, &ov, &ih, &iv, &n);
	if (n == 0)
		return;

	sx = mx = m->wx + ov;
	sy = my = m->wy + oh;
	mh = m->wh - 2*oh - ih * (MIN(n, m->nmaster) - 1);
	sh = m->wh - 2*oh - ih * (n - m->nmaster - 1);
	sw = mw = m->ww - 2*ov;

	if (m->nmaster && n > m->nmaster) {
		sw = (mw - iv) * (1 - m->mfact);
		mw = mw - iv - sw;
		sx = mx + mw + iv;
	}

	getfacts(m, mh, sh, &mfacts, &sfacts, &mrest, &srest);

	for (i = 0, c = nexttiled(m->clients); c; c = nexttiled(c->next), i++)
		if (i < m->nmaster) {
			resize(c, mx, my, mw - (2*c->bw), mh * (c->cfact / mfacts) + (i < mrest ? 1 : 0) - (2*c->bw), 0);
			my += HEIGHT(c) + ih;
		} else {
			resize(c, sx, sy, sw - (2*c->bw), sh * (c->cfact / sfacts) + ((i - m->nmaster) < srest ? 1 : 0) - (2*c->bw), 0);
			sy += HEIGHT(c) + ih;
		}
}
#endif

#if LAYOUT_MONOCLE
void
monocle(Monitor *m)
{
    int oh, ov, ih, iv;
	Client *c;

	if (monocleclientcount && !monoclecount) {
		unsigned int n = 0;

		getgaps(m, &oh, &ov, &ih, &iv, &n);

			for (c = m->clients; c; c = c->next)
					if (ISVISIBLE(c))
							n++;
			if (n > 0) /* override layout symbol */
					snprintf(m->ltsymbol, sizeof m->ltsymbol, "[%d]", n);
    }

	for (c = m->stack; c && (!ISVISIBLE(c) || c->isfloating); c = c->snext);
	if (c && !c->isfloating) {
		XMoveWindow(dpy, c->win, m->wx, m->wy);
		resize(c, m->wx, m->wy, m->ww - 2 * c->bw, m->wh - 2 * c->bw, 0);
		c = c->snext;
	}
	for (; c; c = c->snext)
		if (!c->isfloating && ISVISIBLE(c))
			XMoveWindow(dpy, c->win, WIDTH(c) * -2, c->y);
}
#endif

#if LAYOUT_GRID
void
grid(Monitor *m)
{
	unsigned int i, n;
	int cx, cy, cw, ch, cc, cr, chrest, cwrest, cols, rows;
	int oh, ov, ih, iv;
	Client *c;

	getgaps(m, &oh, &ov, &ih, &iv, &n);

	/* grid dimensions */
	for (rows = 0; rows <= n/2; rows++)
		if (rows*rows >= n)
			break;
	cols = (rows && (rows - 1) * rows >= n) ? rows - 1 : rows;

	/* window geoms (cell height/width) */
	ch = (m->wh - 2*oh - ih * (rows - 1)) / (rows ? rows : 1);
	cw = (m->ww - 2*ov - iv * (cols - 1)) / (cols ? cols : 1);
	chrest = (m->wh - 2*oh - ih * (rows - 1)) - ch * rows;
	cwrest = (m->ww - 2*ov - iv * (cols - 1)) - cw * cols;
	for (i = 0, c = nexttiled(m->clients); c; c = nexttiled(c->next), i++) {
		cc = i / rows;
		cr = i % rows;
		cx = m->wx + ov + cc * (cw + iv) + MIN(cc, cwrest);
		cy = m->wy + oh + cr * (ch + ih) + MIN(cr, chrest);
		resize(c, cx, cy, cw + (cc < cwrest ? 1 : 0) - 2*c->bw, ch + (cr < chrest ? 1 : 0) - 2*c->bw, False);
	}
}
#endif

#if LAYOUT_FIBO
void
fibonacci(Monitor *m, int s)
{
	unsigned int i, n;
	int nx, ny, nw, nh;
	int oh, ov, ih, iv;
	int nv, hrest = 0, wrest = 0, r = 1;
	Client *c;

	getgaps(m, &oh, &ov, &ih, &iv, &n);
	if (n == 0)
		return;

	nx = m->wx + ov;
	ny = m->wy + oh;
	nw = m->ww - 2*ov;
	nh = m->wh - 2*oh;

	for (i = 0, c = nexttiled(m->clients); c; c = nexttiled(c->next)) {
		if (r) {
			if ((i % 2 && (nh - ih) / 2 <= (bh + 2*c->bw))
			   || (!(i % 2) && (nw - iv) / 2 <= (bh + 2*c->bw))) {
				r = 0;
			}
			if (r && i < n - 1) {
				if (i % 2) {
					nv = (nh - ih) / 2;
					hrest = nh - 2*nv - ih;
					nh = nv;
				} else {
					nv = (nw - iv) / 2;
					wrest = nw - 2*nv - iv;
					nw = nv;
				}

				if ((i % 4) == 2 && !s)
					nx += nw + iv;
				else if ((i % 4) == 3 && !s)
					ny += nh + ih;
			}

			if ((i % 4) == 0) {
				if (s) {
					ny += nh + ih;
					nh += hrest;
				}
				else {
					nh -= hrest;
					ny -= nh + ih;
				}
			}
			else if ((i % 4) == 1) {
				nx += nw + iv;
				nw += wrest;
			}
			else if ((i % 4) == 2) {
				ny += nh + ih;
				nh += hrest;
				if (i < n - 1)
					nw += wrest;
			}
			else if ((i % 4) == 3) {
				if (s) {
					nx += nw + iv;
					nw -= wrest;
				} else {
					nw -= wrest;
					nx -= nw + iv;
					nh += hrest;
				}
			}
			if (i == 0)	{
				if (n != 1) {
					nw = (m->ww - iv - 2*ov) - (m->ww - iv - 2*ov) * (1 - m->mfact);
					wrest = 0;
				}
				ny = m->wy + oh;
			}
			else if (i == 1)
				nw = m->ww - nw - iv - 2*ov;
			i++;
		}

		resize(c, nx, ny, nw - (2*c->bw), nh - (2*c->bw), False);
	}
}
#endif

#if LAYOUT_DWINDLE
void
dwindle(Monitor *m)
{
	fibonacci(m, 1);
}
#endif

#if LAYOUT_SPIRAL
void
spiral(Monitor *m)
{
	fibonacci(m, 0);
}
#endif

#if LAYOUT_BSTACK
static void
bstack(Monitor *m)
{
	unsigned int i, n;
	int oh, ov, ih, iv;
	int mx = 0, my = 0, mh = 0, mw = 0;
	int sx = 0, sy = 0, sh = 0, sw = 0;
	float mfacts, sfacts;
	int mrest, srest;
	Client *c;

	getgaps(m, &oh, &ov, &ih, &iv, &n);
	if (n == 0)
		return;

	sx = mx = m->wx + ov;
	sy = my = m->wy + oh;
	sh = mh = m->wh - 2*oh;
	mw = m->ww - 2*ov - iv * (MIN(n, m->nmaster) - 1);
	sw = m->ww - 2*ov - iv * (n - m->nmaster - 1);

	if (m->nmaster && n > m->nmaster) {
		sh = (mh - ih) * (1 - m->mfact);
		mh = mh - ih - sh;
		sx = mx;
		sy = my + mh + ih;
	}

	getfacts(m, mw, sw, &mfacts, &sfacts, &mrest, &srest);

	for (i = 0, c = nexttiled(m->clients); c; c = nexttiled(c->next), i++) {
		if (i < m->nmaster) {
			resize(c, mx, my, mw * (c->cfact / mfacts) + (i < mrest ? 1 : 0) - (2*c->bw), mh - (2*c->bw), 0);
			mx += WIDTH(c) + iv;
		} else {
			resize(c, sx, sy, sw * (c->cfact / sfacts) + ((i - m->nmaster) < srest ? 1 : 0) - (2*c->bw), sh - (2*c->bw), 0);
			sx += WIDTH(c) + iv;
		}
	}
}
#endif

#if LAYOUT_BSTACKH
static void
bstackhoriz(Monitor *m)
{
	unsigned int i, n;
	int oh, ov, ih, iv;
	int mx = 0, my = 0, mh = 0, mw = 0;
	int sx = 0, sy = 0, sh = 0, sw = 0;
	float mfacts, sfacts;
	int mrest, srest;
	Client *c;

	getgaps(m, &oh, &ov, &ih, &iv, &n);
	if (n == 0)
		return;

	sx = mx = m->wx + ov;
	sy = my = m->wy + oh;
	mh = m->wh - 2*oh;
	sh = m->wh - 2*oh - ih * (n - m->nmaster - 1);
	mw = m->ww - 2*ov - iv * (MIN(n, m->nmaster) - 1);
	sw = m->ww - 2*ov;

	if (m->nmaster && n > m->nmaster) {
		sh = (mh - ih) * (1 - m->mfact);
		mh = mh - ih - sh;
		sy = my + mh + ih;
		sh = m->wh - mh - 2*oh - ih * (n - m->nmaster);
	}

	getfacts(m, mw, sh, &mfacts, &sfacts, &mrest, &srest);

	for (i = 0, c = nexttiled(m->clients); c; c = nexttiled(c->next), i++) {
		if (i < m->nmaster) {
			resize(c, mx, my, mw * (c->cfact / mfacts) + (i < mrest ? 1 : 0) - (2*c->bw), mh - (2*c->bw), 0);
			mx += WIDTH(c) + iv;
		} else {
			resize(c, sx, sy, sw - (2*c->bw), sh * (c->cfact / sfacts) + ((i - m->nmaster) < srest ? 1 : 0) - (2*c->bw), 0);
			sy += HEIGHT(c) + ih;
		}
	}
}
#endif

#if LAYOUT_HGRID
void
horizgrid(Monitor *m) {
	Client *c;
	unsigned int n, i;
	int oh, ov, ih, iv;
	int mx = 0, my = 0, mh = 0, mw = 0;
	int sx = 0, sy = 0, sh = 0, sw = 0;
	int ntop, nbottom = 1;
	float mfacts = 0, sfacts = 0;
	int mrest, srest, mtotal = 0, stotal = 0;

	/* Count windows */
	getgaps(m, &oh, &ov, &ih, &iv, &n);
	if (n == 0)
		return;

	if (n <= 2)
		ntop = n;
	else {
		ntop = n / 2;
		nbottom = n - ntop;
	}
	sx = mx = m->wx + ov;
	sy = my = m->wy + oh;
	sh = mh = m->wh - 2*oh;
	sw = mw = m->ww - 2*ov;

	if (n > ntop) {
		sh = (mh - ih) / 2;
		mh = mh - ih - sh;
		sy = my + mh + ih;
		mw = m->ww - 2*ov - iv * (ntop - 1);
		sw = m->ww - 2*ov - iv * (nbottom - 1);
	}

	/* calculate facts */
	for (i = 0, c = nexttiled(m->clients); c; c = nexttiled(c->next), i++)
		if (i < ntop)
			mfacts += c->cfact;
		else
			sfacts += c->cfact;

	for (i = 0, c = nexttiled(m->clients); c; c = nexttiled(c->next), i++)
		if (i < ntop)
			mtotal += mh * (c->cfact / mfacts);
		else
			stotal += sw * (c->cfact / sfacts);

	mrest = mh - mtotal;
	srest = sw - stotal;

	for (i = 0, c = nexttiled(m->clients); c; c = nexttiled(c->next), i++)
		if (i < ntop) {
			resize(c, mx, my, mw * (c->cfact / mfacts) + (i < mrest ? 1 : 0) - (2*c->bw), mh - (2*c->bw), 0);
			mx += WIDTH(c) + iv;
		} else {
			resize(c, sx, sy, sw * (c->cfact / sfacts) + ((i - ntop) < srest ? 1 : 0) - (2*c->bw), sh - (2*c->bw), 0);
			sx += WIDTH(c) + iv;
		}
}
#endif

#if LAYOUT_DGRID
void
dynamicgrid(Monitor *m)
{
	unsigned int n;
	int ri = 0, ci = 0;  /* counters */
	int oh, ov, ih, iv;                         /* vanitygap settings */
	unsigned int cx, cy, cw, ch;                /* client geometry */
	unsigned int uw = 0, uh = 0, uc = 0;        /* utilization trackers */
	unsigned int cols, rows = m->nmaster + 1;
	Client *c;

	/* count clients */
	getgaps(m, &oh, &ov, &ih, &iv, &n);

	/* nothing to do here */
	if (n == 0)
		return;

	/* force 2 clients to always split vertically */
	if (FORCE_VSPLIT && n == 2)
		rows = 1;

	/* never allow empty rows */
	if (n < rows)
		rows = n;

	/* define first row */
	cols = n / rows;
	uc = cols;
	cy = m->wy + oh;
	ch = (m->wh - 2*oh - ih*(rows - 1)) / rows;
	uh = ch;

	for (c = nexttiled(m->clients); c; c = nexttiled(c->next), ci++) {
		if (ci == cols) {
			uw = 0;
			ci = 0;
			ri++;

			/* next row */
			cols = (n - uc) / (rows - ri);
			uc += cols;
			cy = m->wy + oh + uh + ih;
			uh += ch + ih;
		}

		cx = m->wx + ov + uw;
		cw = (m->ww - 2*ov - uw) / (cols - ci);
		uw += cw + iv;

		resize(c, cx, cy, cw - (2*c->bw), ch - (2*c->bw), 0);
	}
}
#endif

#if LAYOUT_TATAMI
void 
tatami(Monitor *m) {
	unsigned int i, n, nx, ny, nw, nh,
				 mats, tc,
				 tnx, tny, tnw, tnh;
	Client *c;

	for(n = 0, c = nexttiled(m->clients); c; c = nexttiled(c->next), ++n);
	if(n == 0)
		return;
	
	nx = m->wx;
	ny = 0;
	nw = m->ww;
	nh = m->wh;
	
	c = nexttiled(m->clients);
	
	if(n != 1)  nw = m->ww * m->mfact;
				ny = m->wy;
				
	resize(c, nx, ny, nw - 2 * c->bw, nh - 2 * c->bw, False);
	
	c = nexttiled(c->next);
	
	nx += nw;
	nw = m->ww - nw;
	
	if(n>1)
	{
	
	tc = n-1;
	mats = tc/5;
	
	nh/=(mats + (tc % 5 > 0));
	
	for(i = 0; c && (i < (tc % 5)); c = nexttiled(c->next))
	{
		tnw=nw;
		tnx=nx;
		tnh=nh;
		tny=ny;
		switch(tc - (mats*5))
				{
					case 1://fill
						break;
					case 2://up and down
						if((i % 5) == 0) //up
						tnh/=2;
						else if((i % 5) == 1) //down
						{
							tnh/=2;
							tny += nh/2;
						}
						break;
					case 3://bottom, up-left and up-right
						if((i % 5) == 0) //up-left
						{
						tnw = nw/2;
						tnh = (2*nh)/3;
						}
						else if((i % 5) == 1)//up-right
						{
							tnx += nw/2;
							tnw = nw/2;
							tnh = (2*nh)/3;
						}
						else if((i % 5) == 2)//bottom
						{
							tnh = nh/3;
							tny += (2*nh)/3;	
						}
						break;
					case 4://bottom, left, right and top
						if((i % 5) == 0) //top
						{
							tnh = (nh)/4;
						}
						else if((i % 5) == 1)//left
						{
							tnw = nw/2;
							tny += nh/4;
							tnh = (nh)/2;
						}
						else if((i % 5) == 2)//right
						{
							tnx += nw/2;
							tnw = nw/2;
							tny += nh/4;
							tnh = (nh)/2;
						}
						else if((i % 5) == 3)//bottom
						{
							tny += (3*nh)/4;
							tnh = (nh)/4;
						}
						break;
				}
		++i;
		resize(c, tnx, tny, tnw - 2 * c->bw, tnh - 2 * c->bw, False);
	}
	
	++mats;
	
	for(i = 0; c && (mats>0); c = nexttiled(c->next)) {

			if((i%5)==0)
			{
			--mats;
			if(((tc % 5) > 0)||(i>=5))
			ny+=nh;
			}
			
			tnw=nw;
			tnx=nx;
			tnh=nh;
			tny=ny;
			

			switch(i % 5)
			{
				case 0: //top-left-vert
					tnw = (nw)/3;
					tnh = (nh*2)/3;
					break;
				case 1: //top-right-hor
					tnx += (nw)/3;
					tnw = (nw*2)/3;
					tnh = (nh)/3;
					break;
				case 2: //center
					tnx += (nw)/3;
					tnw = (nw)/3;
					tny += (nh)/3;
					tnh = (nh)/3;
					break;
				case 3: //bottom-right-vert
					tnx += (nw*2)/3;
					tnw = (nw)/3;
					tny += (nh)/3;
					tnh = (nh*2)/3;
					break;
				case 4: //(oldest) bottom-left-hor
					tnw = (2*nw)/3;
					tny += (2*nh)/3;
					tnh = (nh)/3;
					break;
				default:
					break;
			}
			
			++i;
			//i%=5;
		resize(c, tnx, tny, tnw - 2 * c->bw, tnh - 2 * c->bw, False);
		}
	}
}
#endif

#if LAYOUT_CM
void
centeredmaster(Monitor *m)
{
	unsigned int i, n;
	int oh, ov, ih, iv;
	int mx = 0, my = 0, mh = 0, mw = 0;
	int lx = 0, ly = 0, lw = 0, lh = 0;
	int rx = 0, ry = 0, rw = 0, rh = 0;
	float mfacts = 0, lfacts = 0, rfacts = 0;
	int mtotal = 0, ltotal = 0, rtotal = 0;
	int mrest = 0, lrest = 0, rrest = 0;
	Client *c;

	getgaps(m, &oh, &ov, &ih, &iv, &n);
	if (n == 0)
		return;

	/* initialize areas */
	mx = m->wx + ov;
	my = m->wy + oh;
	mh = m->wh - 2*oh - ih * ((!m->nmaster ? n : MIN(n, m->nmaster)) - 1);
	mw = m->ww - 2*ov;
	lh = m->wh - 2*oh - ih * (((n - m->nmaster) / 2) - 1);
	rh = m->wh - 2*oh - ih * (((n - m->nmaster) / 2) - ((n - m->nmaster) % 2 ? 0 : 1));

	if (m->nmaster && n > m->nmaster) {
		/* go mfact box in the center if more than nmaster clients */
		if (n - m->nmaster > 1) {
			/* ||<-S->|<---M--->|<-S->|| */
			mw = (m->ww - 2*ov - 2*iv) * m->mfact;
			lw = (m->ww - mw - 2*ov - 2*iv) / 2;
			rw = (m->ww - mw - 2*ov - 2*iv) - lw;
			mx += lw + iv;
		} else {
			/* ||<---M--->|<-S->|| */
			mw = (mw - iv) * m->mfact;
			lw = 0;
			rw = m->ww - mw - iv - 2*ov;
		}
		lx = m->wx + ov;
		ly = m->wy + oh;
		rx = mx + mw + iv;
		ry = m->wy + oh;
	}

	/* calculate facts */
	for (n = 0, c = nexttiled(m->clients); c; c = nexttiled(c->next), n++) {
		if (!m->nmaster || n < m->nmaster)
			mfacts += c->cfact;
		else if ((n - m->nmaster) % 2)
			lfacts += c->cfact; // total factor of left hand stack area
		else
			rfacts += c->cfact; // total factor of right hand stack area
	}

	for (n = 0, c = nexttiled(m->clients); c; c = nexttiled(c->next), n++)
		if (!m->nmaster || n < m->nmaster)
			mtotal += mh * (c->cfact / mfacts);
		else if ((n - m->nmaster) % 2)
			ltotal += lh * (c->cfact / lfacts);
		else
			rtotal += rh * (c->cfact / rfacts);

	mrest = mh - mtotal;
	lrest = lh - ltotal;
	rrest = rh - rtotal;

	for (i = 0, c = nexttiled(m->clients); c; c = nexttiled(c->next), i++) {
		if (!m->nmaster || i < m->nmaster) {
			/* nmaster clients are stacked vertically, in the center of the screen */
			resize(c, mx, my, mw - (2*c->bw), mh * (c->cfact / mfacts) + (i < mrest ? 1 : 0) - (2*c->bw), 0);
			my += HEIGHT(c) + ih;
		} else {
			/* stack clients are stacked vertically */
			if ((i - m->nmaster) % 2 ) {
				resize(c, lx, ly, lw - (2*c->bw), lh * (c->cfact / lfacts) + ((i - 2*m->nmaster) < 2*lrest ? 1 : 0) - (2*c->bw), 0);
				ly += HEIGHT(c) + ih;
			} else {
				resize(c, rx, ry, rw - (2*c->bw), rh * (c->cfact / rfacts) + ((i - 2*m->nmaster) < 2*rrest ? 1 : 0) - (2*c->bw), 0);
				ry += HEIGHT(c) + ih;
			}
		}
	}
}
#endif

#if LAYOUT_CFM
void
centeredfloatingmaster(Monitor *m)
{
	unsigned int i, n;
	float mfacts, sfacts;
	float mivf = 1.0; // master inner vertical gap factor
	int oh, ov, ih, iv, mrest, srest;
	int mx = 0, my = 0, mh = 0, mw = 0;
	int sx = 0, sy = 0, sh = 0, sw = 0;
	Client *c;

	getgaps(m, &oh, &ov, &ih, &iv, &n);
	if (n == 0)
		return;

	sx = mx = m->wx + ov;
	sy = my = m->wy + oh;
	sh = mh = m->wh - 2*oh;
	mw = m->ww - 2*ov - iv*(n - 1);
	sw = m->ww - 2*ov - iv*(n - m->nmaster - 1);

	if (m->nmaster && n > m->nmaster) {
		mivf = 0.8;
		/* go mfact box in the center if more than nmaster clients */
		if (m->ww > m->wh) {
			mw = m->ww * m->mfact - iv*mivf*(MIN(n, m->nmaster) - 1);
			mh = m->wh * 0.9 - 2 * oh;
		} else {
			mw = m->ww * 0.9 - iv*mivf*(MIN(n, m->nmaster) - 1);
			mh = m->wh * m->mfact;
		}
		mx = m->wx + (m->ww - mw) / 2;
		my = m->wy + (m->wh - mh) / 2;

		sx = m->wx + ov;
		sy = m->wy + oh;
		sh = m->wh - 2*oh;
	}

	getfacts(m, mw, sw, &mfacts, &sfacts, &mrest, &srest);

	for (i = 0, c = nexttiled(m->clients); c; c = nexttiled(c->next), i++)
		if (i < m->nmaster) {
			/* nmaster clients are stacked horizontally, in the center of the screen */
			resize(c, mx, my, mw * (c->cfact / mfacts) + (i < mrest ? 1 : 0) - (2*c->bw), mh - (2*c->bw), 0);
			mx += WIDTH(c) + iv*mivf;
		} else {
			/* stack clients are stacked horizontally */
			resize(c, sx, sy, sw * (c->cfact / sfacts) + ((i - m->nmaster) < srest ? 1 : 0) - (2*c->bw), sh - (2*c->bw), 0);
			sx += WIDTH(c) + iv;
		}
}
#endif

#if LAYOUT_DECK
void
deck(Monitor *m)
{
	unsigned int i, n;
	int oh, ov, ih, iv;
	int mx = 0, my = 0, mh = 0, mw = 0;
	int sx = 0, sy = 0, sh = 0, sw = 0;
	float mfacts, sfacts;
	int mrest, srest;
	Client *c;

	getgaps(m, &oh, &ov, &ih, &iv, &n);
	if (n == 0)
		return;

	sx = mx = m->wx + ov;
	sy = my = m->wy + oh;
	sh = mh = m->wh - 2*oh - ih * (MIN(n, m->nmaster) - 1);
	sw = mw = m->ww - 2*ov;

	if (m->nmaster && n > m->nmaster) {
		sw = (mw - iv) * (1 - m->mfact);
		mw = mw - iv - sw;
		sx = mx + mw + iv;
		sh = m->wh - 2*oh;
	}

	getfacts(m, mh, sh, &mfacts, &sfacts, &mrest, &srest);

	if (n - m->nmaster > 0 && deckcount) /* override layout symbol */
		snprintf(m->ltsymbol, sizeof m->ltsymbol, deckformat, n - m->nmaster);

	for (i = 0, c = nexttiled(m->clients); c; c = nexttiled(c->next), i++)
		if (i < m->nmaster) {
			resize(c, mx, my, mw - (2*c->bw), mh * (c->cfact / mfacts) + (i < mrest ? 1 : 0) - (2*c->bw), 0);
			my += HEIGHT(c) + ih;
		} else {
			resize(c, sx, sy, sw - (2*c->bw), sh - (2*c->bw), 0);
		}
}
#endif

#if LAYOUT_CUSTOM
enum node_type_t
{
   ND_NULL,

   /* Containers */
   ND_MONOCLE,
   ND_HORIZONTAL_LR,
   ND_HORIZONTAL_RL,
   ND_VERTICAL_UD,
   ND_VERTICAL_DU,
   ND_VOID,

   /* Elements */
   ND_CLIENT,
   ND_CLIENT_NUM,
   ND_CLIENT_NTH,
   ND_CLIENT_CLASS,
   ND_CLIENT_FLOAT,
   ND_CLIENT_EMPTY,
   ND_REST,
};

typedef struct node_t node_t;
struct node_t
{
   enum node_type_t type;
   float weight;
   int x, y, w, h;
   int f;
   unsigned n;
   unsigned margin;
   char *s;
   Client *c;

   struct node_t *branch;
   struct node_t *next;
};

struct client_ref_t
{
   Client *c;
   struct client_ref_t *next;
};

static node_t *s_layout_scheme;

node_t* alloc_node(enum node_type_t type)
{
   node_t *node = (node_t*) malloc(sizeof(node_t));
   memset(node, 0, sizeof(node_t));
   node->type = type;
   return node;
}

node_t* clone_node(node_t *n)
{
   if (n == NULL)
      return NULL;

   node_t *node = alloc_node(n->type);
   node->weight = n->weight;
   node->x = n->x;
   node->y = n->y;
   node->w = n->w;
   node->h = n->h;
   node->f = n->f;
   node->n = n->n;
   node->margin = n->margin;
   node->s = n->s;
   node->c = n->c;
   node->next = NULL;
   node->branch = NULL;
   return node;
}

int is_nested(node_t *node)
{
   return node->type == ND_HORIZONTAL_LR
       || node->type == ND_HORIZONTAL_RL
       || node->type == ND_VERTICAL_UD
       || node->type == ND_VERTICAL_DU
       || node->type == ND_MONOCLE;
}

int is_terminal(char c)
{
   return c == ' '
       || c == '\t'
       || c == '('
       || c == ')'
       || c == '\0';
}

void free_node(node_t *node)
{
   for ( node_t *n = node;
         n != NULL; )
   {
      if (is_nested(n))
         free_node(n->branch);

      node_t *ns = n->next;

      if (n->s) free(n->s);
      free(n);
      n = ns;
   }
}

node_t* reverse_node(node_t *node)
{
   node_t *a = node, *b = NULL;

   if (a != NULL) {
      b = a->next;
      a->next = NULL;
   }

   while (b != NULL) {
      node_t *nx = b->next;
      b->next = a;
      a = b;
      b = nx;
   }

   return (b ? b : a);
}

void node_length(node_t *node, unsigned *len, float *weight)
{
   unsigned n = 0;
   float w = 0.0;

   for (; node != NULL; node = node->next) {
      if (!node->f) {
         n ++;
         w += (node->weight == 0 ? 1 : node->weight);
      }
   }

   if (len != NULL)
      *len = n;

   if (weight != NULL)
      *weight = w;
}

struct client_ref_t* copy_clients(Client *clients)
{
   struct client_ref_t head;
   head.next = NULL;
   struct client_ref_t *tail = &head;

   for (Client *c = nexttiled(clients); c != NULL; c = nexttiled(c->next)) {
      tail->next = (struct client_ref_t*) malloc(sizeof(struct client_ref_t));
      tail = tail->next;
      
      tail->next = NULL;
      tail->c = c;
   }

   return head.next;
}

void free_clients(struct client_ref_t *clients)
{
   struct client_ref_t *nxt = NULL;
   while (clients != NULL) {
      nxt = clients->next;
      free(clients);
      clients = nxt;
   }
}

struct s_recur_analyze_ret {
   node_t *head;
   node_t *tail;
}
s_recur_analyze(struct client_ref_t **clients, node_t *node)
{
   struct client_ref_t *c = *clients;
   unsigned i = 0;

   /* a single client, just assign a client. */
   if (node->type == ND_CLIENT) {
      struct s_recur_analyze_ret ret;
      ret.tail = ret.head = clone_node(node);
      *clients = c->next;
      ret.head->c = c->c;
      return ret;
   }

   /* An empty slot. */
   if (node->type == ND_CLIENT_EMPTY) {
      struct s_recur_analyze_ret ret;
      ret.tail = ret.head = clone_node(node);
      ret.tail->c = NULL;
      ret.tail->type = ND_CLIENT;
      return ret;
   }

   /* pick 'n' client from the list top. */
   if (node->type == ND_CLIENT_NTH) {
      struct client_ref_t *prev = NULL;
      struct s_recur_analyze_ret ret;
      ret.head = ret.tail = NULL;

      for ( i = 0, c = *clients;
            i < node->n && c != NULL;
            i ++, c = c->next)
      {
         prev = c;
      }

      if (c != NULL) {
         if (prev == NULL)
            *clients = c->next;
         else
            prev->next = c->next;

         ret.tail = ret.head = clone_node(node);
         ret.head->type = ND_CLIENT;
         ret.head->c = c->c;
      }

      return ret;
   }

   if (node->type == ND_CLIENT_CLASS) {
      struct s_recur_analyze_ret ret;

      return ret;
   }

   /* Fixed number of clients. */
   if (node->type == ND_CLIENT_NUM) {
      struct s_recur_analyze_ret ret;
      node_t head, *p = &head;
      head.next = NULL;
      for ( i = 0, c = *clients;
            i < node->n && c != NULL;
            i ++, c = c->next )
      {
         p->next = clone_node(node);
         p = p->next;
         p->type = ND_CLIENT;
         p->c = c->c;
      }
      *clients = c;
      ret.head = head.next;
      ret.tail = p;
      return ret;
   }

   /* All leftover client. */
   if (node->type == ND_REST) {
      struct s_recur_analyze_ret ret;
      node_t head, *p = &head;
      head.next = NULL;
      for (c = *clients; c != NULL; c = c->next) {
         p->next = clone_node(node);
         p = p->next;
         p->type = ND_CLIENT;
         p->c = c->c;
      }
      *clients = c;
      ret.head = head.next;
      ret.tail = p;
      return ret;
   }

   if (node->type == ND_NULL) {
      struct s_recur_analyze_ret ret;
      ret.head = NULL;
      ret.tail = NULL;
      return ret;
   }

   /* In case the element is a container */
   if (is_nested(node)) {
      struct s_recur_analyze_ret ret;
      ret.head = clone_node(node);
      ret.tail = ret.head;

      struct s_recur_analyze_ret x;
      x.head = ret.head;
      x.tail = x.head;

      node_t branch, *tail = &branch;
      branch.next = NULL;

      node_t *n = NULL;

      /* For reversed containers the order must be reversed */
      if (node->type == ND_HORIZONTAL_RL || node->type == ND_VERTICAL_DU) {
         n = reverse_node(node->branch);
      } else {
         n = node->branch;
      }

      for (; *clients != NULL && n != NULL; n = n->next )
      {
         x = s_recur_analyze(clients, n);
         
         /* Attach the received tree to the tail of the previous element */
         if (x.head != NULL) {
            tail->next = x.head;
            tail = x.tail;
         }
      }

      if (node->type == ND_HORIZONTAL_RL || node->type == ND_VERTICAL_DU) {
         ret.head->branch = reverse_node(branch.next);
      } else {
         ret.head->branch = branch.next;
      }

      return ret;
   }

   struct s_recur_analyze_ret ret;
   ret.head = NULL;
   ret.tail = NULL;
   return ret;
}

struct frame_t
{
   int x, y, w, h;
};

void s_recur_resize(node_t *node, struct frame_t frame)
{
   if (node == NULL) return;

   if (node->type == ND_CLIENT) {
      if (node->c != NULL) {
         if (node->f)
            resize(node->c, node->x, node->y, node->w, node->h, 0);
         else
            resize(node->c,
                  frame.x + node->margin,
                  frame.y + node->margin,
                  frame.w - 2 * node->margin - 2 * node->c->bw,
                  frame.h - 2 * node->margin - 2 * node->c->bw,
                  0);
      }
      return;
   }

   if (node->type == ND_VERTICAL_UD || node->type == ND_VERTICAL_DU) {
      unsigned len = 0;
      float wgt = 0.0;
      int delta = 0;
      float avg_wgt = 1;

      frame.x += node->margin;
      frame.y += node->margin;
      frame.w -= 2 * node->margin;
      frame.h -= 2 * node->margin;
      
      node_length(node->branch, &len, &wgt);
      if (len != 0) {
         delta = frame.h / len;
         avg_wgt = wgt / len;
      }

      for (node_t *n = node->branch; n != NULL; n = n->next) {
         if (!n->f) {
            frame.h = (n->weight == 0 ? 1 : n->weight) / avg_wgt * delta;
            s_recur_resize(n, frame);
            frame.y += frame.h;
         } else {
            s_recur_resize(n, frame);
         }
      }
      return;
   }

   if (node->type == ND_HORIZONTAL_RL || node->type == ND_HORIZONTAL_LR) {
      unsigned len = 0;
      float wgt = 0.0;
      int delta = 0;
      float avg_wgt = 1;

      frame.x += node->margin;
      frame.y += node->margin;
      frame.w -= 2 * node->margin;
      frame.h -= 2 * node->margin;
      
      node_length(node->branch, &len, &wgt);
      if (len != 0) {
         delta = frame.w / len;
         avg_wgt = wgt / len;
      }

      for (node_t *n = node->branch; n != NULL; n = n->next) {
         if (!n->f) {
            frame.w = (n->weight == 0 ? 1 : n->weight) / avg_wgt * delta;
            s_recur_resize(n, frame);
            frame.x += frame.w;
         } else {
            s_recur_resize(n, frame);
         }
      }
      return;
   }

   if (node->type == ND_MONOCLE) {
      frame.x += node->margin;
      frame.y += node->margin;
      frame.w -= 2 * node->margin;
      frame.h -= 2 * node->margin;

      for (node_t *n = node->branch; n != NULL; n = n->next)
         s_recur_resize(n, frame);
   }
}

/* Main layout function. */
void custom(Monitor *m)
{
   /* Need to clone the client stack, as we might need to pull items from it. */
   struct client_ref_t *clients = copy_clients(m->clients),
                       *clients_root = clients;

   if (s_layout_scheme == NULL)
      return;

   struct s_recur_analyze_ret ret = s_recur_analyze(&clients, s_layout_scheme);

   struct frame_t frame;
   frame.x = m->wx;
   frame.y = m->wy;
   frame.w = m->ww;
   frame.h = m->wh;

   s_recur_resize(ret.head, frame);

   /* Free the resources we allocated. */
   free_clients(clients_root);
   free_node(ret.head);
}

/* tokenize string */
typedef struct string_token_t string_token_t;
struct string_token_t {
   char token[32];
   struct string_token_t *next;
};

string_token_t* parse_string(char *str, unsigned *i)
{
   unsigned char escape = 0;
   unsigned j = 0;
   string_token_t *ret = (string_token_t*) malloc(sizeof(string_token_t));
   ret->next = NULL;

   while (str[*i] != '\0' && j < sizeof(ret->token) - 1) {
      if (str[*i] == '\\' && !escape) {
         escape = 1;
         (*i) ++;
         continue;
      }

      if (str[*i] == '"' && !escape) {
         break;
      }

      ret->token[j++] = str[(*i)++];
      escape = 0;
   }
   ret->token[j] = '\0';

   if (str[*i] == '\0')
      (*i) --;
   return ret;
}

struct string_token_t* tokenize_string(char *str)
{
   struct string_token_t head;
   struct string_token_t *node = &head;
   head.next = NULL;
   unsigned word_start = UINT_MAX;
   unsigned len = 0;

   for (unsigned i = 0;; i ++) {
      switch (str[i]) {
         /* end of line */
         case '\0':
            if (word_start != UINT_MAX) {
               node->next = (struct string_token_t*) malloc(sizeof(struct string_token_t));
               node = node->next;
               node->next = NULL;

               len = MIN(i - word_start, sizeof(node->token) - 1);
               strncpy(node->token, &str[word_start], len);
               node->token[len] = '\0';
            }
            return head.next;

         /* comment */
         case ';':
            return head.next;

         /* beginning of a string */
         case '"':
            node->next = parse_string(str, &i);
            if (node->next) node = node->next;

         case ' ':
         case '\t':
         case '(':
         case ')':
            if (word_start != UINT_MAX) {
               node->next = (struct string_token_t*) malloc(sizeof(struct string_token_t));
               node = node->next;
               node->next = NULL;
               len = MIN(i - word_start, sizeof(node->token) - 1);
               strncpy(node->token, &str[word_start], len);
               node->token[len] = '\0';
               word_start = UINT_MAX;
            }
            if (str[i] == '(' || str[i] == ')') {
               node->next = (struct string_token_t*) malloc(sizeof(struct string_token_t));
               node = node->next;
               node->next = NULL;
               node->token[0] = str[i];
               node->token[1] = '\0';
            }
            break;

         // A piece of a word
         default:
            if (word_start == UINT_MAX)
               word_start = i;
      }
   }
   return NULL;
}

/* Parse s-expression to node_t structure */
node_t* parse_sexp(string_token_t **token)
{
   node_t *head = NULL;
   node_t branch, *p = &branch;
   branch.next = NULL;

   string_token_t *t = *token;

   while (t != NULL) {
      if (strcmp(t->token, ")") == 0) {
         t = t->next;
         break;
      }

      if (strcmp(t->token, "(") == 0) {
         t = t->next;
         *token = t;

         if (head == NULL) {
            head = parse_sexp(token);
         } else {
            p->next = parse_sexp(token);
            if (p->next) p = p->next;
         }
         t = *token;
         continue;
      }

      /* client slots
       * single client */
      if (strcmp(t->token, "c") == 0 || strcmp(t->token, "client") == 0) {
         if (head == NULL) {
            head = alloc_node(ND_CLIENT);
         } else {
            p->next = alloc_node(ND_CLIENT);
            p = p->next;
         }
         t = t->next;
         continue;
      }

      /* Empty viewport */
      if (strcmp(t->token, "e") == 0 || strcmp(t->token, "empty") == 0) {
         if (head == NULL) {
            head = alloc_node(ND_CLIENT_EMPTY);
         } else {
            p->next = alloc_node(ND_CLIENT_EMPTY);
            p = p->next;
         }
         t = t->next;
         continue;
      }

      /* the rest of the clients */
      if (strcmp(t->token, "...") == 0 || strcmp(t->token, "rest") == 0) {
         if (head == NULL) {
            head = alloc_node(ND_REST);
         } else {
            p->next = alloc_node(ND_REST);
            p = p->next;
         }
         t = t->next;
         continue;
      }

      /* choose the client by class */
      if (strcmp(t->token, "class") == 0) {
         if (head == NULL) {
            head = alloc_node(ND_CLIENT_CLASS);
            if (t->next) {
               t = t->next;
               head->s = strdup(t->token);
            }
         } else {
            p->next = alloc_node(ND_CLIENT_CLASS);
            p = p->next;
            if (t->next) {
               t = t->next;
               p->s = strdup(t->token);
            }
         }
         t = t->next;
         continue;
      }
      
      /* 'n' client */
      unsigned long n = 0;
      char *endp = NULL;
      n = strtoul(t->token, &endp, 10);
      if (is_terminal(*endp)) {
         if (head == NULL) {
            head = alloc_node(ND_CLIENT_NTH);
            head->n = n;
         } else {
            p->next = alloc_node(ND_CLIENT_NTH);
            p->next->n = n;
            p = p->next;
         }
         t = t->next;
         continue;
      }

      /* max number of clients */
      if (strcmp(t->token, "max") == 0) {
         if (head == NULL) {
            head = alloc_node(ND_CLIENT_NUM);

            t = t->next;
            if (t != NULL) {
               head->n = (unsigned) atoi(t->token);
               t = t->next;
            }
         }
         continue;
      }

      /* parameters
      * weight */
      if ((strcmp(t->token, "w:") == 0 || strcmp(t->token, ":w") == 0
               || strcmp(t->token, "weight:") == 0
               || strcmp(t->token, ":weight") == 0) && head != NULL) {
         t = t->next;

         if (t != NULL) {
            head->weight = (float) atof(t->token);
            t = t->next;
         }
         continue;
      }

      /* margin */
      if (((strcmp(t->token, "m:") == 0) || strcmp(t->token, ":m") == 0 
               || strcmp(t->token, "margin:") == 0
               || strcmp(t->token, ":margin") == 0) && head != NULL) {
         t = t->next;

         if (t != NULL) {
            head->margin = (unsigned) atoi(t->token);
            t = t->next;
         }
         continue;
      }

      /* floating geometry */
      if ((strcmp(t->token, "f:") == 0 || strcmp(t->token, ":f") == 0
               || strcmp(t->token, "float:") == 0
               || strcmp(t->token, ":float") == 0) && head != NULL) {
         head->f = 1;
         t = t->next;

         if (t != NULL) {
            head->x = atoi(t->token);
            t = t->next;
         }
         if (t != NULL) {
            head->y = atoi(t->token);
            t = t->next;
         }
         if (t != NULL) {
            head->w = atoi(t->token);
            t = t->next;
         }
         if (t != NULL) {
            head->h = atoi(t->token);
            t = t->next;
         }
         continue;
      }

      /* containers */
      if ((strcmp(t->token, "h") == 0 || strcmp(t->token, "horizontal") == 0) && head == NULL)
         head = alloc_node(ND_HORIZONTAL_LR);

      if ((strcmp(t->token, "hr") == 0 || strcmp(t->token, "h-reversed") == 0) && head == NULL)
         head = alloc_node(ND_HORIZONTAL_RL);

      if ((strcmp(t->token, "v") == 0 || strcmp(t->token, "vertical") == 0) && head == NULL)
         head = alloc_node(ND_VERTICAL_UD);

      if ((strcmp(t->token, "vr") == 0 || strcmp(t->token, "v-reversed") == 0) && head == NULL)
         head = alloc_node(ND_VERTICAL_UD);

      if ((strcmp(t->token, "m") == 0 || strcmp(t->token, "monocle") == 0) && head == NULL)
         head = alloc_node(ND_MONOCLE);

      t = t->next;
   }

   if (head)
      head->branch = branch.next;

   *token = t;
   return head;
}

void set_s_layout(const Arg *arg)
{
   FILE *pp, *hf;

   char pathbuf[1024];
   char *home = getenv("HOME");
   if (home != NULL) {
      snprintf(pathbuf, 1023, "%s/" CUSTOM_HISTFILE, home);
      pathbuf[1023] = '\0';
      
      /* make sure the history file exists */
      hf = fopen(CUSTOM_HISTFILE, "a"); fclose(hf);
      system("sort " CUSTOM_HISTFILE " | uniq > " CUSTOM_HISTFILE "~");
      system("mv " CUSTOM_HISTFILE "~ " CUSTOM_HISTFILE);

      pp = popen(RUN_CUSTOM_LAYOUT CUSTOM_HISTFILE, "r");
   } else {
      pp = popen(RUN_CUSTOM_LAYOUT, "r");
   }


   if (!pp) 
		return;
   
   char buf[2048];
   buf[2048] = '\0';
   fgets(buf, 1024, pp);
   fclose(pp);
   if (buf[0] == '\0')
		   return;

   hf = fopen(CUSTOM_HISTFILE, "a");
   fprintf(hf, "%s", buf);
   fclose(hf);

   if (s_layout_scheme != NULL) {
      free_node(s_layout_scheme);
      s_layout_scheme = NULL;
   }

   struct string_token_t *token_root = tokenize_string(buf),
                         *token = token_root;

   s_layout_scheme = parse_sexp(&token);

   /* Free the token list */
   while (token_root != NULL) {
      token = token_root->next;
      free(token_root);
      token_root = token;
   }
}
#endif