yigitcolakoglu
/
dotfiles

typedef struct {	void (*arrange)(Monitor *, int, int, int, int, int, int, int);} LayoutArranger;
typedef struct {	void (*arrange)(Monitor *, int, int, int, int, int, int, int, int, int);} TileArranger;
static const LayoutArranger flexlayouts[] = {	{ layout_no_split },	{ layout_split_vertical },	{ layout_split_horizontal },	{ layout_split_centered_vertical },	{ layout_split_centered_horizontal },	{ layout_split_vertical_dual_stack },	{ layout_split_horizontal_dual_stack },	{ layout_floating_master },	{ layout_split_vertical_fixed },	{ layout_split_horizontal_fixed },	{ layout_split_centered_vertical_fixed },	{ layout_split_centered_horizontal_fixed },	{ layout_split_vertical_dual_stack_fixed },	{ layout_split_horizontal_dual_stack_fixed },	{ layout_floating_master_fixed },};
static const TileArranger flextiles[] = {	{ arrange_top_to_bottom },	{ arrange_left_to_right },	{ arrange_monocle },	{ arrange_gapplessgrid },	{ arrange_gapplessgrid_alt1 },	{ arrange_gapplessgrid_alt2 },	{ arrange_gridmode },	{ arrange_horizgrid },	{ arrange_dwindle },	{ arrange_spiral },	{ arrange_tatami },};
static voidgetfactsforrange(Monitor *m, int an, int ai, int size, int *rest, float *fact){	int i;	float facts;	Client *c;	int total = 0;
	facts = 0;	for (i = 0, c = nexttiled(m->clients); c; c = nexttiled(c->next), i++)		if (i >= ai && i < (ai + an))			#if CFACTS_PATCH
			facts += c->cfact;			#else
			facts += 1;			#endif // CFACTS_PATCH

	for (i = 0, c = nexttiled(m->clients); c; c = nexttiled(c->next), i++)		if (i >= ai && i < (ai + an))			#if CFACTS_PATCH
			total += size * (c->cfact / facts);			#else
			total += size / facts;			#endif // CFACTS_PATCH

	*rest = size - total;	*fact = facts;}
#if IPC_PATCH || DWMC_PATCH
static voidsetlayoutaxisex(const Arg *arg){	int axis, arr;
	axis = arg->i & 0x3; // lower two bytes indicates layout, master or stack1-2
	arr = ((arg->i & 0xFC) >> 2); // remaining six upper bytes indicate arrangement

	if ((axis == 0 && abs(arr) > LAYOUT_LAST)			|| (axis > 0 && (arr > AXIS_LAST || arr < 0)))		arr = 0;
	selmon->ltaxis[axis] = arr;	#if PERTAG_PATCH
	selmon->pertag->ltaxis[selmon->pertag->curtag][axis] = selmon->ltaxis[axis];	#endif // PERTAG_PATCH
	arrange(selmon);}#endif // IPC_PATCH | DWMC_PATCH

static voidlayout_no_split(Monitor *m, int x, int y, int h, int w, int ih, int iv, int n){	(&flextiles[m->ltaxis[m->nmaster >= n ? MASTER : STACK]])->arrange(m, x, y, h, w, ih, iv, n, n, 0);}
static voidlayout_split_vertical(Monitor *m, int x, int y, int h, int w, int ih, int iv, int n){	/* Split master into master + stack if we have enough clients */	if (m->nmaster && n > m->nmaster) {		layout_split_vertical_fixed(m, x, y, h, w, ih, iv, n);	} else {		layout_no_split(m, x, y, h, w, ih, iv, n);	}}
static voidlayout_split_vertical_fixed(Monitor *m, int x, int y, int h, int w, int ih, int iv, int n){	int sw, sx;
	sw = (w - iv) * (1 - m->mfact);	w = (w - iv) * m->mfact;	if (m->ltaxis[LAYOUT] < 0) { // mirror
		sx = x;		x += sw + iv;	} else {		sx = x + w + iv;	}
	(&flextiles[m->ltaxis[MASTER]])->arrange(m, x, y, h, w, ih, iv, n, m->nmaster, 0);	(&flextiles[m->ltaxis[STACK]])->arrange(m, sx, y, h, sw, ih, iv, n, n - m->nmaster, m->nmaster);}
static voidlayout_split_vertical_dual_stack(Monitor *m, int x, int y, int h, int w, int ih, int iv, int n){	/* Split master into master + stack if we have enough clients */	if (!m->nmaster || n <= m->nmaster) {		layout_no_split(m, x, y, h, w, ih, iv, n);	} else if (n <= m->nmaster + (m->nstack ? m->nstack : 1)) {		layout_split_vertical(m, x, y, h, w, ih, iv, n);	} else {		layout_split_vertical_dual_stack_fixed(m, x, y, h, w, ih, iv, n);	}}
static voidlayout_split_vertical_dual_stack_fixed(Monitor *m, int x, int y, int h, int w, int ih, int iv, int n){	int sh, sw, sx, oy, sc;
	if (m->nstack)		sc = m->nstack;	else		sc = (n - m->nmaster) / 2 + ((n - m->nmaster) % 2 > 0 ? 1 : 0);
	sw = (w - iv) * (1 - m->mfact);	sh = (h - ih) / 2;	w = (w - iv) * m->mfact;	oy = y + sh + ih;	if (m->ltaxis[LAYOUT] < 0) { // mirror
		sx = x;		x += sw + iv;	} else {		sx = x + w + iv;	}
	(&flextiles[m->ltaxis[MASTER]])->arrange(m, x, y, h, w, ih, iv, n, m->nmaster, 0);	(&flextiles[m->ltaxis[STACK]])->arrange(m, sx, y, sh, sw, ih, iv, n, sc, m->nmaster);	(&flextiles[m->ltaxis[STACK2]])->arrange(m, sx, oy, sh, sw, ih, iv, n, n - m->nmaster - sc, m->nmaster + sc);}
static voidlayout_split_horizontal(Monitor *m, int x, int y, int h, int w, int ih, int iv, int n){	/* Split master into master + stack if we have enough clients */	if (m->nmaster && n > m->nmaster) {		layout_split_horizontal_fixed(m, x, y, h, w, ih, iv, n);	} else {		layout_no_split(m, x, y, h, w, ih, iv, n);	}}
static voidlayout_split_horizontal_fixed(Monitor *m, int x, int y, int h, int w, int ih, int iv, int n){	int sh, sy;
	sh = (h - ih) * (1 - m->mfact);	h = (h - ih) * m->mfact;	if (m->ltaxis[LAYOUT] < 0) { // mirror
		sy = y;		y += sh + ih;	} else {		sy = y + h + ih;	}
	(&flextiles[m->ltaxis[MASTER]])->arrange(m, x, y, h, w, ih, iv, n, m->nmaster, 0);	(&flextiles[m->ltaxis[STACK]])->arrange(m, x, sy, sh, w, ih, iv, n, n - m->nmaster, m->nmaster);}
static voidlayout_split_horizontal_dual_stack(Monitor *m, int x, int y, int h, int w, int ih, int iv, int n){	/* Split master into master + stack if we have enough clients */	if (!m->nmaster || n <= m->nmaster) {		layout_no_split(m, x, y, h, w, ih, iv, n);	} else if (n <= m->nmaster + (m->nstack ? m->nstack : 1)) {		layout_split_horizontal(m, x, y, h, w, ih, iv, n);	} else {		layout_split_horizontal_dual_stack_fixed(m, x, y, h, w, ih, iv, n);	}}
static voidlayout_split_horizontal_dual_stack_fixed(Monitor *m, int x, int y, int h, int w, int ih, int iv, int n){	int sh, sy, ox, sc;
	if (m->nstack)		sc = m->nstack;	else		sc = (n - m->nmaster) / 2 + ((n - m->nmaster) % 2 > 0 ? 1 : 0);
	sh = (h - ih) * (1 - m->mfact);	h = (h - ih) * m->mfact;	sw = (w - iv) / 2;	ox = x + sw + iv;	if (m->ltaxis[LAYOUT] < 0) { // mirror
		sy = y;		y += sh + ih;	} else {		sy = y + h + ih;	}
	(&flextiles[m->ltaxis[MASTER]])->arrange(m, x, y, h, w, ih, iv, n, m->nmaster, 0);	(&flextiles[m->ltaxis[STACK]])->arrange(m, x, sy, sh, sw, ih, iv, n, sc, m->nmaster);	(&flextiles[m->ltaxis[STACK2]])->arrange(m, ox, sy, sh, sw, ih, iv, n, n - m->nmaster - sc, m->nmaster + sc);}
static voidlayout_split_centered_vertical(Monitor *m, int x, int y, int h, int w, int ih, int iv, int n){	/* Split master into master + stack if we have enough clients */	if (!m->nmaster || n <= m->nmaster) {		layout_no_split(m, x, y, h, w, ih, iv, n);	} else if (n <= m->nmaster + (m->nstack ? m->nstack : 1)) {		layout_split_vertical(m, x, y, h, w, ih, iv, n);	} else {		layout_split_centered_vertical_fixed(m, x, y, h, w, ih, iv, n);	}}
static voidlayout_split_centered_vertical_fixed(Monitor *m, int x, int y, int h, int w, int ih, int iv, int n){	int sw, sx, ox, sc;
	if (m->nstack)		sc = m->nstack;	else		sc = (n - m->nmaster) / 2 + ((n - m->nmaster) % 2 > 0 ? 1 : 0);
	sw = (w - 2*iv) * (1 - m->mfact) / 2;	w = (w - 2*iv) * m->mfact;	if (m->ltaxis[LAYOUT] < 0)  { // mirror
		sx = x;		x += sw + iv;		ox = x + w + iv;	} else {		ox = x;		x += sw + iv;		sx = x + w + iv;	}
	(&flextiles[m->ltaxis[MASTER]])->arrange(m, x, y, h, w, ih, iv, n, m->nmaster, 0);	(&flextiles[m->ltaxis[STACK]])->arrange(m, sx, y, h, sw, ih, iv, n, sc, m->nmaster);	(&flextiles[m->ltaxis[STACK2]])->arrange(m, ox, y, h, sw, ih, iv, n, n - m->nmaster - sc, m->nmaster + sc);}
static voidlayout_split_centered_horizontal(Monitor *m, int x, int y, int h, int w, int ih, int iv, int n){	/* Split master into master + stack if we have enough clients */	if (!m->nmaster || n <= m->nmaster) {		layout_no_split(m, x, y, h, w, ih, iv, n);	} else if (n <= m->nmaster + (m->nstack ? m->nstack : 1)) {		layout_split_horizontal(m, x, y, h, w, ih, iv, n);	} else {		layout_split_centered_horizontal_fixed(m, x, y, h, w, ih, iv, n);	}}
static voidlayout_split_centered_horizontal_fixed(Monitor *m, int x, int y, int h, int w, int ih, int iv, int n){	int sh, sy, oy, sc;
	if (m->nstack)		sc = m->nstack;	else		sc = (n - m->nmaster) / 2 + ((n - m->nmaster) % 2 > 0 ? 1 : 0);
	sh = (h - 2*ih) * (1 - m->mfact) / 2;	h = (h - 2*ih) * m->mfact;	if (m->ltaxis[LAYOUT] < 0)  { // mirror
		sy = y;		y += sh + ih;		oy = y + h + ih;	} else {		oy = y;		y += sh + ih;		sy = y + h + ih;	}
	(&flextiles[m->ltaxis[MASTER]])->arrange(m, x, y, h, w, ih, iv, n, m->nmaster, 0);	(&flextiles[m->ltaxis[STACK]])->arrange(m, x, sy, sh, w, ih, iv, n, sc, m->nmaster);	(&flextiles[m->ltaxis[STACK2]])->arrange(m, x, oy, sh, w, ih, iv, n, n - m->nmaster - sc, m->nmaster + sc);}
static voidlayout_floating_master(Monitor *m, int x, int y, int h, int w, int ih, int iv, int n){	/* Split master into master + stack if we have enough clients */	if (!m->nmaster || n <= m->nmaster) {		layout_no_split(m, x, y, h, w, ih, iv, n);	} else {		layout_floating_master_fixed(m, x, y, h, w, ih, iv, n);	}}
static voidlayout_floating_master_fixed(Monitor *m, int x, int y, int h, int w, int ih, int iv, int n){	int mh, mw;
	/* Draw stack area first */	(&flextiles[m->ltaxis[STACK]])->arrange(m, x, y, h, w, ih, iv, n, n - m->nmaster, m->nmaster);
	if (w > h) {		mw = w * m->mfact;		mh = h * 0.9;	} else {		mw = w * 0.9;		mh = h * m->mfact;	}	x = x + (w - mw) / 2;	y = y + (h - mh) / 2;
	(&flextiles[m->ltaxis[MASTER]])->arrange(m, x, y, mh, mw, ih, iv, n, m->nmaster, 0);}
static voidarrange_left_to_right(Monitor *m, int x, int y, int h, int w, int ih, int iv, int n, int an, int ai){	int i, rest;	float facts, fact = 1;	Client *c;
	if (ai + an > n)		an = n - ai;
	w -= iv * (an - 1);	getfactsforrange(m, an, ai, w, &rest, &facts);	for (i = 0, c = nexttiled(m->clients); c; c = nexttiled(c->next), i++) {		if (i >= ai && i < (ai + an)) {			#if CFACTS_PATCH
			fact = c->cfact;			#endif // CFACTS_PATCH
			resize(c, x, y, w * (fact / facts) + ((i - ai) < rest ? 1 : 0) - (2*c->bw), h - (2*c->bw), 0);			x += WIDTH(c) + iv;		}	}}
static voidarrange_top_to_bottom(Monitor *m, int x, int y, int h, int w, int ih, int iv, int n, int an, int ai){	int i, rest;	float facts, fact = 1;	Client *c;
	if (ai + an > n)		an = n - ai;
	h -= ih * (an - 1);	getfactsforrange(m, an, ai, h, &rest, &facts);	for (i = 0, c = nexttiled(m->clients); c; c = nexttiled(c->next), i++) {		if (i >= ai && i < (ai + an)) {			#if CFACTS_PATCH
			fact = c->cfact;			#endif // CFACTS_PATCH
			resize(c, x, y, w - (2*c->bw), h * (fact / facts) + ((i - ai) < rest ? 1 : 0) - (2*c->bw), 0);			y += HEIGHT(c) + ih;		}	}}
static voidarrange_monocle(Monitor *m, int x, int y, int h, int w, int ih, int iv, int n, int an, int ai){	int i;	Client *c;
	for (i = 0, c = nexttiled(m->clients); c; c = nexttiled(c->next), i++)		if (i >= ai && i < (ai + an))			resize(c, x, y, w - (2*c->bw), h - (2*c->bw), 0);}
static voidarrange_gridmode(Monitor *m, int x, int y, int h, int w, int ih, int iv, int n, int an, int ai){	int i, cols, rows, ch, cw, cx, cy, cc, cr, chrest, cwrest; // counters
	Client *c;
	/* grid dimensions */	for (rows = 0; rows <= an/2; rows++)		if (rows*rows >= an)			break;	cols = (rows && (rows - 1) * rows >= an) ? rows - 1 : rows;
	/* window geoms (cell height/width) */	ch = (h - ih * (rows - 1)) / (rows ? rows : 1);	cw = (w - iv * (cols - 1)) / (cols ? cols : 1);	chrest = h - ih * (rows - 1) - ch * rows;	cwrest = w - iv * (cols - 1) - cw * cols;	for (i = 0, c = nexttiled(m->clients); c; c = nexttiled(c->next), i++) {		if (i >= ai && i < (ai + an)) {			cc = ((i - ai) / rows); // client column number
			cr = ((i - ai) % rows); // client row number
			cx = x + cc * (cw + iv) + MIN(cc, cwrest);			cy = y + 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);		}	}}
static voidarrange_horizgrid(Monitor *m, int x, int y, int h, int w, int ih, int iv, int n, int an, int ai){	int ntop, nbottom, rh, rest;
	/* Exception when there is only one client; don't split into two rows */	if (an == 1) {		arrange_monocle(m, x, y, h, w, ih, iv, n, an, ai);		return;	}
	ntop = an / 2;	nbottom = an - ntop;	rh = (h - ih) / 2;	rest = h - ih - rh * 2;	arrange_left_to_right(m, x, y, rh + rest, w, ih, iv, n, ntop, ai);	arrange_left_to_right(m, x, y + rh + ih + rest, rh, w, ih, iv, n, nbottom, ai + ntop);}
static voidarrange_gapplessgrid(Monitor *m, int x, int y, int h, int w, int ih, int iv, int n, int an, int ai){	int i, cols, rows, ch, cw, cn, rn, cc, rrest, crest; // counters
	Client *c;
	/* grid dimensions */	for (cols = 1; cols <= an/2; cols++)		if (cols*cols >= an)			break;	if (an == 5) /* set layout against the general calculation: not 1:2:2, but 2:3 */		cols = 2;	rows = an/cols;	cn = rn = cc = 0; // reset column no, row no, client count

	ch = (h - ih * (rows - 1)) / rows;	rrest = (h - ih * (rows - 1)) - ch * rows;	cw = (w - iv * (cols - 1)) / cols;	crest = (w - iv * (cols - 1)) - cw * cols;
	for (i = 0, c = nexttiled(m->clients); c; c = nexttiled(c->next), i++) {		if (i >= ai && i < (ai + an)) {			if (cc/rows + 1 > cols - an%cols) {				rows = an/cols + 1;				ch = (h - ih * (rows - 1)) / rows;				rrest = (h - ih * (rows - 1)) - ch * rows;			}			resize(c,				x,				y + rn*(ch + ih) + MIN(rn, rrest),				cw + (cn < crest ? 1 : 0) - 2*c->bw,				ch + (rn < rrest ? 1 : 0) - 2*c->bw,				0);			rn++;			cc++;			if (rn >= rows) {				rn = 0;				x += cw + ih + (cn < crest ? 1 : 0);				cn++;			}		}	}}
/* This version of gappless grid fills rows first */static voidarrange_gapplessgrid_alt1(Monitor *m, int x, int y, int h, int w, int ih, int iv, int n, int an, int ai){	int i, cols, rows, rest, ch;
	/* grid dimensions */	for (cols = 1; cols <= an/2; cols++)		if (cols*cols >= an)			break;	rows = (cols && (cols - 1) * cols >= an) ? cols - 1 : cols;	ch = (h - ih * (rows - 1)) / (rows ? rows : 1);	rest = (h - ih * (rows - 1)) - ch * rows;
	for (i = 0; i < rows; i++) {		arrange_left_to_right(m, x, y, ch + (i < rest ? 1 : 0), w, ih, iv, n, MIN(cols, an - i*cols), ai + i*cols);		y += ch + (i < rest ? 1 : 0) + ih;	}}
/* This version of gappless grid fills columns first */static voidarrange_gapplessgrid_alt2(Monitor *m, int x, int y, int h, int w, int ih, int iv, int n, int an, int ai){	int i, cols, rows, rest, cw;
	/* grid dimensions */	for (rows = 0; rows <= an/2; rows++)		if (rows*rows >= an)			break;	cols = (rows && (rows - 1) * rows >= an) ? rows - 1 : rows;	cw = (w - iv * (cols - 1)) / (cols ? cols : 1);	rest = (w - iv * (cols - 1)) - cw * cols;
	for (i = 0; i < cols; i++) {		arrange_top_to_bottom(m, x, y, h, cw + (i < rest ? 1 : 0), ih, iv, n, MIN(rows, an - i*rows), ai + i*rows);		x += cw + (i < rest ? 1 : 0) + iv;	}}
static voidarrange_fibonacci(Monitor *m, int x, int y, int h, int w, int ih, int iv, int n, int an, int ai, int s){	int i, j, nv, hrest = 0, wrest = 0, nx = x, ny = y, nw = w, nh = h, r = 1;	Client *c;
	for (i = 0, j = 0, c = nexttiled(m->clients); c; c = nexttiled(c->next), j++) {		if (j >= ai && j < (ai + an)) {			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 < an - 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 (an != 1) {						nw = (w - iv) - (w - iv) * (1 - m->mfact);						wrest = 0;					}					ny = y;				} else if (i == 1)					nw = w - nw - iv;				i++;			}
			resize(c, nx, ny, nw - 2 * c->bw, nh - 2*c->bw, False);		}	}}
static voidarrange_dwindle(Monitor *m, int x, int y, int h, int w, int ih, int iv, int n, int an, int ai){	arrange_fibonacci(m, x, y, h, w, ih, iv, n, an, ai, 1);}
static voidarrange_spiral(Monitor *m, int x, int y, int h, int w, int ih, int iv, int n, int an, int ai){	arrange_fibonacci(m, x, y, h, w, ih, iv, n, an, ai, 0);}
static voidarrange_tatami(Monitor *m, int x, int y, int h, int w, int ih, int iv, int n, int an, int ai){	unsigned int i, j, nx, ny, nw, nh, tnx, tny, tnw, tnh, nhrest, hrest, wrest, areas, mats, cats;	Client *c;
	nx = x;	ny = y;	nw = w;	nh = h;
	mats = an / 5;	cats = an % 5;	hrest = 0;	wrest = 0;
	areas = mats + (cats > 0);	nh = (h - ih * (areas - 1)) / areas;	nhrest = (h - ih * (areas - 1)) % areas;
	for (i = 0, j = 0, c = nexttiled(m->clients); c; c = nexttiled(c->next), j++) {		if (j >= ai && j < (ai + an)) {
			tnw = nw;			tnx = nx;			tnh = nh;			tny = ny;
			if (j < ai + cats) {				/* Arrange cats (all excess clients that can't be tiled as mats). Cats sleep on mats. */
	 			switch (cats) {				case 1: // fill
					break;				case 2: // up and down
					if ((i % 5) == 0) //up
						tnh = (nh - ih) / 2 + (nh - ih) % 2;					else if ((i % 5) == 1) { //down
						tny += (nh - ih) / 2 + (nh - ih) % 2 + ih;						tnh = (nh - ih) / 2;					}					break;				case 3: //bottom, up-left and up-right
					if ((i % 5) == 0) { // up-left
						tnw = (nw - iv) / 2 + (nw - iv) % 2;						tnh = (nh - ih) * 2 / 3 + (nh - ih) * 2 % 3;					} else if ((i % 5) == 1) { // up-right
						tnx += (nw - iv) / 2 + (nw - iv) % 2 + iv;						tnw = (nw - iv) / 2;						tnh = (nh - ih) * 2 / 3 + (nh - ih) * 2 % 3;					} else if ((i % 5) == 2) { //bottom
						tnh = (nh - ih) / 3;						tny += (nh - ih) * 2 / 3 + (nh - ih) * 2 % 3 + ih;					}					break;				case 4: // bottom, left, right and top
					if ((i % 5) == 0) { //top
						hrest = (nh - 2 * ih) % 4;						tnh = (nh - 2 * ih) / 4 + (hrest ? 1 : 0);					} else if ((i % 5) == 1) { // left
						tnw = (nw - iv) / 2 + (nw - iv) % 2;						tny += (nh - 2 * ih) / 4 + (hrest ? 1 : 0) + ih;						tnh = (nh - 2 * ih) * 2 / 4 + (hrest > 1 ? 1 : 0);					} else if ((i % 5) == 2) { // right
						tnx += (nw - iv) / 2 + (nw - iv) % 2 + iv;						tnw = (nw - iv) / 2;						tny += (nh - 2 * ih) / 4 + (hrest ? 1 : 0) + ih;						tnh = (nh - 2 * ih) * 2 / 4 + (hrest > 1 ? 1 : 0);					} else if ((i % 5) == 3) { // bottom
						tny += (nh - 2 * ih) / 4 + (hrest ? 1 : 0) + (nh - 2 * ih) * 2 / 4 + (hrest > 1 ? 1 : 0) + 2 * ih;						tnh = (nh - 2 * ih) / 4 + (hrest > 2 ? 1 : 0);					}					break;				}
			} else {				/* Arrange mats. One mat is a collection of five clients arranged tatami style */
				if (((i - cats) % 5) == 0) {					if ((cats > 0) || ((i - cats) >= 5)) {						tny = ny = ny + nh + (nhrest > 0 ? 1 : 0) + ih;						--nhrest;					}				}
				switch ((i - cats) % 5) {				case 0: // top-left-vert
					wrest = (nw - 2 * iv) % 3;					hrest = (nh - 2 * ih) % 3;					tnw = (nw - 2 * iv) / 3 + (wrest ? 1 : 0);					tnh = (nh - 2 * ih) * 2 / 3 + hrest + iv;					break;				case 1: // top-right-hor
					tnx += (nw - 2 * iv) / 3 + (wrest ? 1 : 0) + iv;					tnw = (nw - 2 * iv) * 2 / 3 + (wrest > 1 ? 1 : 0) + iv;					tnh = (nh - 2 * ih) / 3 + (hrest ? 1 : 0);					break;				case 2: // center
					tnx += (nw - 2 * iv) / 3 + (wrest ? 1 : 0) + iv;					tnw = (nw - 2 * iv) / 3 + (wrest > 1 ? 1 : 0);					tny += (nh - 2 * ih) / 3 + (hrest ? 1 : 0) + ih;					tnh = (nh - 2 * ih) / 3 + (hrest > 1 ? 1 : 0);					break;				case 3: // bottom-right-vert
					tnx += (nw - 2 * iv) * 2 / 3 + wrest + 2 * iv;					tnw = (nw - 2 * iv) / 3;					tny += (nh - 2 * ih) / 3 + (hrest ? 1 : 0) + ih;					tnh = (nh - 2 * ih) * 2 / 3 + hrest + iv;					break;				case 4: // (oldest) bottom-left-hor
					tnw = (nw - 2 * iv) * 2 / 3 + wrest + iv;					tny += (nh - 2 * ih) * 2 / 3 + hrest + 2 * iv;					tnh = (nh - 2 * ih) / 3;					break;				}
			}
			resize(c, tnx, tny, tnw - 2 * c->bw, tnh - 2 * c->bw, False);			++i;		}	}}
static voidflextile(Monitor *m){	unsigned int n;	int oh = 0, ov = 0, ih = 0, iv = 0; // gaps outer/inner horizontal/vertical

	#if VANITYGAPS_PATCH
	getgaps(m, &oh, &ov, &ih, &iv, &n);	#else
	Client *c;	for (n = 0, c = nexttiled(m->clients); c; c = nexttiled(c->next), n++);	#endif // VANITYGAPS_PATCH

	if (m->lt[m->sellt]->preset.layout != m->ltaxis[LAYOUT] ||			m->lt[m->sellt]->preset.masteraxis != m->ltaxis[MASTER] ||			m->lt[m->sellt]->preset.stack1axis != m->ltaxis[STACK] ||			m->lt[m->sellt]->preset.stack2axis != m->ltaxis[STACK2])		setflexsymbols(m, n);	else if (m->lt[m->sellt]->preset.symbolfunc != NULL)		m->lt[m->sellt]->preset.symbolfunc(m, n);
	if (n == 0)		return;
	#if VANITYGAPS_PATCH && !VANITYGAPS_MONOCLE_PATCH
	/* No outer gap if full screen monocle */	if (abs(m->ltaxis[MASTER]) == MONOCLE && (abs(m->ltaxis[LAYOUT]) == NO_SPLIT || n <= m->nmaster)) {		oh = 0;		ov = 0;	}	#endif // VANITYGAPS_PATCH && !VANITYGAPS_MONOCLE_PATCH

	(&flexlayouts[abs(m->ltaxis[LAYOUT])])->arrange(m, m->wx + ov, m->wy + oh, m->wh - 2*oh, m->ww - 2*ov, ih, iv, n);	return;}
static voidsetflexsymbols(Monitor *m, unsigned int n){	int l;	char sym1, sym2, sym3;	Client *c;
	if (n == 0)		for (c = nexttiled(m->clients); c; c = nexttiled(c->next), n++);
	l = abs(m->ltaxis[LAYOUT]);	if (m->ltaxis[MASTER] == MONOCLE && (l == NO_SPLIT || !m->nmaster || n <= m->nmaster)) {		monoclesymbols(m, n);		return;	}
	if (m->ltaxis[STACK] == MONOCLE && (l == SPLIT_VERTICAL || l == SPLIT_HORIZONTAL_FIXED)) {		decksymbols(m, n);		return;	}
	/* Layout symbols */	if (l == NO_SPLIT || !m->nmaster) {		sym1 = sym2 = sym3 = (int)tilesymb[m->ltaxis[MASTER]];	} else {		sym2 = layoutsymb[l];		if (m->ltaxis[LAYOUT] < 0) {			sym1 = tilesymb[m->ltaxis[STACK]];			sym3 = tilesymb[m->ltaxis[MASTER]];		} else {			sym1 = tilesymb[m->ltaxis[MASTER]];			sym3 = tilesymb[m->ltaxis[STACK]];		}	}
	snprintf(m->ltsymbol, sizeof m->ltsymbol, "%c%c%c", sym1, sym2, sym3);}
static voidmonoclesymbols(Monitor *m, unsigned int n){	if (n > 0)		snprintf(m->ltsymbol, sizeof m->ltsymbol, "[%d]", n);	else		snprintf(m->ltsymbol, sizeof m->ltsymbol, "[M]");}
static voiddecksymbols(Monitor *m, unsigned int n){	if (n > m->nmaster)		snprintf(m->ltsymbol, sizeof m->ltsymbol, "[]%d", n);	else		snprintf(m->ltsymbol, sizeof m->ltsymbol, "[D]");}
/* Mirror layout axis for flextile */voidmirrorlayout(const Arg *arg){	if (!selmon->lt[selmon->sellt]->arrange)		return;	selmon->ltaxis[LAYOUT] *= -1;	#if PERTAG_PATCH
	selmon->pertag->ltaxis[selmon->pertag->curtag][0] = selmon->ltaxis[LAYOUT];	#endif // PERTAG_PATCH
	arrange(selmon);}
/* Rotate layout axis for flextile */voidrotatelayoutaxis(const Arg *arg){	int incr = (arg->i > 0 ? 1 : -1);	int axis = abs(arg->i) - 1;
	if (!selmon->lt[selmon->sellt]->arrange)		return;	if (axis == LAYOUT) {		if (selmon->ltaxis[LAYOUT] >= 0) {			selmon->ltaxis[LAYOUT] += incr;			if (selmon->ltaxis[LAYOUT] >= LAYOUT_LAST)				selmon->ltaxis[LAYOUT] = 0;			else if (selmon->ltaxis[LAYOUT] < 0)				selmon->ltaxis[LAYOUT] = LAYOUT_LAST - 1;		} else {			selmon->ltaxis[LAYOUT] -= incr;			if (selmon->ltaxis[LAYOUT] <= -LAYOUT_LAST)				selmon->ltaxis[LAYOUT] = 0;			else if (selmon->ltaxis[LAYOUT] > 0)				selmon->ltaxis[LAYOUT] = -LAYOUT_LAST + 1;		}	} else {		selmon->ltaxis[axis] += incr;		if (selmon->ltaxis[axis] >= AXIS_LAST)			selmon->ltaxis[axis] = 0;		else if (selmon->ltaxis[axis] < 0)			selmon->ltaxis[axis] = AXIS_LAST - 1;	}	#if PERTAG_PATCH
	selmon->pertag->ltaxis[selmon->pertag->curtag][axis] = selmon->ltaxis[axis];	#endif // PERTAG_PATCH
	arrange(selmon);	setflexsymbols(selmon, 0);}
voidincnstack(const Arg *arg){	#if PERTAG_PATCH
	selmon->nstack = selmon->pertag->nstacks[selmon->pertag->curtag] = MAX(selmon->nstack + arg->i, 0);	#else
	selmon->nstack = MAX(selmon->nstack + arg->i, 0);	#endif // PERTAG_PATCH
	arrange(selmon);}