ref: 670f4e90ee6028ffee399e5a96fb5e4cd72fc7bc
dir: /appl/wm/brutus/table.b/
implement Brutusext;
# <Extension table tablefile>
include "sys.m";
sys: Sys;
include "draw.m";
draw: Draw;
Point, Font, Rect: import draw;
include "tk.m";
tk: Tk;
include "tkclient.m";
tkclient: Tkclient;
include "bufio.m";
include "string.m";
S: String;
include "html.m";
html: HTML;
Lex, Attr, RBRA, Data, Ttable, Tcaption, Tcol, Ttr, Ttd: import html;
include "brutus.m";
Size6, Size8, Size10, Size12, Size16, NSIZE,
Roman, Italic, Bold, Type, NFONT, NFONTTAG,
Example, List, Listelem, Heading, Nofill, Author, Title,
DefFont, DefSize, TitleFont, TitleSize, HeadingFont, HeadingSize: import Brutus;
include "brutusext.m";
Name: con "Table";
# alignment types
Anone, Aleft, Acenter, Aright, Ajustify, Atop, Amiddle, Abottom, Abaseline: con iota;
# A cell has a number of Lines, each of which has a number of Items.
# Each Item is a string in one font.
Item: adt
{
itemid: int; # canvas text item id
s: string;
fontnum: int; # (style*NumSizes + size)
pos: Point; # nw corner of text item, relative to line origin
width: int; # of s, in pixels, when displayed in font
line: cyclic ref Line; # containing line
prev: cyclic ref Item;
next: cyclic ref Item;
};
Line: adt
{
items: cyclic ref Item;
pos: Point; # nw corner of Line relative to containing cell;
height: int;
ascent: int;
width: int;
cell: cyclic ref Tablecell; # containing cell
next: cyclic ref Line;
};
Align: adt
{
halign: int;
valign: int;
};
Tablecell: adt
{
cellid: int;
content: array of ref Lex;
lines: cyclic ref Line;
rowspan: int;
colspan: int;
nowrap: int;
align: Align;
width: int;
height: int;
ascent: int;
row: int;
col: int;
pos: Point; # nw corner of cell, in canvas coords
};
Tablegcell: adt
{
cell: ref Tablecell;
drawnhere: int;
};
Tablerow: adt
{
cells: list of ref Tablecell;
height: int;
ascent: int;
align: Align;
pos: Point;
rule: int; # width of rule below row, if > 0
ruleids: list of int; # canvas ids of lines used to draw rule
};
Tablecol: adt
{
width: int;
align: Align;
pos: Point;
rule: int; # width of rule to right of col, if > 0
ruleids: list of int; # canvas ids of lines used to draw rule
};
Table: adt
{
nrow: int;
ncol: int;
ncell: int;
width: int;
height: int;
capcell: ref Tablecell;
border: int;
brectid: int;
cols: array of ref Tablecol;
rows: array of ref Tablerow;
cells: list of ref Tablecell;
grid: array of array of ref Tablegcell;
colw: array of int;
rowh: array of int;
};
# Font stuff
DefaultFnum: con (DefFont*NSIZE + Size10);
fontnames := array[NFONTTAG] of {
"/fonts/lucidasans/unicode.6.font",
"/fonts/lucidasans/unicode.7.font",
"/fonts/lucidasans/unicode.8.font",
"/fonts/lucidasans/unicode.10.font",
"/fonts/lucidasans/unicode.13.font",
"/fonts/lucidasans/italiclatin1.6.font",
"/fonts/lucidasans/italiclatin1.7.font",
"/fonts/lucidasans/italiclatin1.8.font",
"/fonts/lucidasans/italiclatin1.10.font",
"/fonts/lucidasans/italiclatin1.13.font",
"/fonts/lucidasans/boldlatin1.6.font",
"/fonts/lucidasans/boldlatin1.7.font",
"/fonts/lucidasans/boldlatin1.8.font",
"/fonts/lucidasans/boldlatin1.10.font",
"/fonts/lucidasans/boldlatin1.13.font",
"/fonts/lucidasans/typelatin1.6.font",
"/fonts/lucidasans/typelatin1.7.font",
"/fonts/pelm/latin1.9.font",
"/fonts/pelm/ascii.12.font",
"/fonts/pelm/ascii.16.font"
};
fontrefs := array[NFONTTAG] of ref Font;
fontused := array[NFONTTAG] of { DefaultFnum => 1, * => 0};
# TABHPAD, TABVPAD are extra space between columns, rows
TABHPAD: con 10;
TABVPAD: con 4;
tab: ref Table;
top: ref Tk->Toplevel;
display: ref Draw->Display;
canv: string;
init(asys: Sys, adraw: Draw, nil: Bufio, atk: Tk, aw: Tkclient)
{
sys = asys;
draw = adraw;
tk = atk;
tkclient = aw;
html = load HTML HTML->PATH;
S = load String String->PATH;
}
create(parent: string, t: ref Tk->Toplevel, name, args: string): string
{
if(html == nil)
return "can't load HTML module";
top = t;
display = t.image.display;
canv = name;
err := tk->cmd(t, "canvas " + canv);
if(len err > 0 && err[0] == '!')
return err_ret(err);
spec: array of ref Lex;
(spec, err) = getspec(parent, args);
if(err != "")
return err_ret(err);
err = parsetab(spec);
if(err != "")
return err_ret(err);
err = build();
if(err != "")
return err_ret(err);
return "";
}
err_ret(s: string) : string
{
return Name + ": " + s;
}
getspec(parent, args: string) : (array of ref Lex, string)
{
(n, argl) := sys->tokenize(args, " ");
if(n != 1)
return (nil, "usage: " + Name + " file");
(filebytes, err) := readfile(fullname(parent, hd argl));
if(err != "")
return (nil, err);
return(html->lex(filebytes, HTML->UTF8, 1), "");
}
readfile(path: string): (array of byte, string)
{
fd := sys->open(path, sys->OREAD);
if(fd == nil)
return (nil, sys->sprint("can't open %s, the error was: %r", path));
(ok, d) := sys->fstat(fd);
if(ok < 0)
return (nil, sys->sprint("can't stat %s, the error was: %r", path));
if(d.mode & Sys->DMDIR)
return (nil, sys->sprint("%s is a directory", path));
l := int d.length;
buf := array[l] of byte;
tot := 0;
while(tot < l) {
need := l - tot;
n := sys->read(fd, buf[tot:], need);
if(n <= 0)
return (nil, sys->sprint("error reading %s, the error was: %r", path));
tot += n;
}
return (buf, "");
}
# Use HTML 3.2 table spec as external representation
# (But no th cells, width specs; and extra "rule" attribute
# for col and tr meaning that a rule of given width is to
# follow the given column or row).
# DTD elements:
# table: - O (caption?, col*, tr*)
# caption: - - (%text+)
# col: - O empty
# tr: - O td*
# td: - O (%body.content)
parsetab(toks: array of ref Lex) : string
{
tabletlex := toks[0];
n := len toks;
(tlex, i) := nexttok(toks, n, 0);
# caption
capcell: ref Tablecell = nil;
if(tlex != nil && tlex.tag == Tcaption) {
for(j := i+1; j < n; j++) {
tlex = toks[j];
if(tlex.tag == Tcaption + RBRA)
break;
}
if(j >= n)
return syntax_err(tlex, j);
if(j > i+1) {
captoks := toks[i+1:j];
(caplines, e) := lexes2lines(captoks);
if(e != nil)
return e;
# we ignore caption now
# capcell = ref Tablecell(0, captoks, caplines, 1, 1, 1, Align(Anone, Anone),
# 0, 0, 0, 0, 0, Point(0,0));
}
(tlex, i) = nexttok(toks, n, j);
}
# col*
cols: list of ref Tablecol = nil;
while(tlex != nil && tlex.tag == Tcol) {
col := makecol(tlex);
if(col.align.halign == Anone)
col.align.halign = Aleft;
cols = col :: cols;
(tlex, i) = nexttok(toks, n, i);
}
cols = revcols(cols);
body : list of ref Tablerow = nil;
cells : list of ref Tablecell = nil;
cellid := 0;
rows: list of ref Tablerow = nil;
# tr*
while(tlex != nil && tlex.tag == Ttr) {
currow := ref Tablerow(nil, 0, 0, makealign(tlex), Point(0,0), makelinew(tlex, "rule"), nil);
rows = currow :: rows;
# td*
(tlex, i) = nexttok(toks, n, i);
while(tlex != nil && tlex.tag == Ttd) {
rowspan := 1;
(rsfnd, rs) := html->attrvalue(tlex.attr, "rowspan");
if(rsfnd && rs != "")
rowspan = int rs;
colspan := 1;
(csfnd, cs) := html->attrvalue(tlex.attr, "colspan");
if(csfnd && cs != "")
colspan = int cs;
nowrap := 0;
(nwfnd, nil) := html->attrvalue(tlex.attr, "nowrap");
if(nwfnd)
nowrap = 1;
align := makealign(tlex);
for(j := i+1; j < n; j++) {
tlex = toks[j];
tg := tlex.tag;
if(tg == Ttd + RBRA || tg == Ttd || tg == Ttr + RBRA || tg == Ttr)
break;
}
if(j == n)
tlex = nil;
content: array of ref Lex = nil;
if(j > i+1)
content = toks[i+1:j];
(lines, err) := lexes2lines(content);
if(err != "")
return err;
curcell := ref Tablecell(cellid, content, lines, rowspan, colspan, nowrap, align, 0, 0, 0, 0, 0, Point(0,0));
currow.cells = curcell :: currow.cells;
cells = curcell :: cells;
cellid++;
if(tlex != nil && tlex.tag == Ttd + RBRA)
(tlex, i) = nexttok(toks, n, j);
else
i = j;
}
if(tlex != nil && tlex.tag == Ttr + RBRA)
(tlex, i) = nexttok(toks, n, i);
}
if(tlex == nil || tlex.tag != Ttable + RBRA)
return syntax_err(tlex, i);
# now reverse all the lists that were built in reverse order
# and calculate nrow, ncol
rows = revrowl(rows);
nrow := len rows;
rowa := array[nrow] of ref Tablerow;
ncol := 0;
r := 0;
for(rl := rows; rl != nil; rl = tl rl) {
row := hd rl;
rowa[r++] = row;
rcols := 0;
cl := row.cells;
row.cells = nil;
while(cl != nil) {
c := hd cl;
row.cells = c :: row.cells;
rcols += c.colspan;
cl = tl cl;
}
if(rcols > ncol)
ncol = rcols;
}
cells = revcelll(cells);
cola := array[ncol] of ref Tablecol;
for(c := 0; c < ncol; c++) {
if(cols != nil) {
cola[c] = hd cols;
cols = tl cols;
}
else
cola[c] = ref Tablecol(0, Align(Anone, Anone), Point(0,0), 0, nil);
}
if(tabletlex.tag != Ttable)
return syntax_err(tabletlex, 0);
border := makelinew(tabletlex, "border");
tab = ref Table(nrow, ncol, cellid, 0, 0, capcell, border, 0, cola, rowa, cells, nil, nil, nil);
return "";
}
syntax_err(tlex: ref Lex, i: int) : string
{
if(tlex == nil)
return "syntax error in table: premature end";
else
return "syntax error in table at token " + string i + ": " + html->lex2string(tlex);
}
# next token after toks[i], skipping whitespace
nexttok(toks: array of ref Lex, ntoks, i: int) : (ref Lex, int)
{
i++;
if(i >= ntoks)
return (nil, i);
t := toks[i];
while(t.tag == Data) {
if(S->drop(t.text, " \t\n\r") != "")
break;
i++;
if(i >= ntoks)
return (nil, i);
t = toks[i];
}
# sys->print("nexttok returning (%s,%d)\n", html->lex2string(t), i);
return(t, i);
}
makecol(tlex: ref Lex) : ref Tablecol
{
return ref Tablecol(0, makealign(tlex), Point(0,0), makelinew(tlex, "rule"), nil);
}
makelinew(tlex: ref Lex, aname: string) : int
{
ans := 0;
(fnd, val) := html->attrvalue(tlex.attr, aname);
if(fnd) {
if(val == "")
ans = 1;
else
ans = int val;
}
return ans;
}
makealign(tlex: ref Lex) : Align
{
(nil,h) := html->attrvalue(tlex.attr, "align");
(nil,v) := html->attrvalue(tlex.attr, "valign");
hal := align_val(h, Anone);
val := align_val(v, Anone);
return Align(hal, val);
}
align_val(sal: string, dflt: int) : int
{
ans := dflt;
case sal {
"left" => ans = Aleft;
"center" => ans = Acenter;
"right" => ans = Aright;
"justify" => ans = Ajustify;
"top" => ans = Atop;
"middle" => ans = Amiddle;
"bottom" => ans = Abottom;
"baseline" => ans = Abaseline;
}
return ans;
}
revcols(l : list of ref Tablecol) : list of ref Tablecol
{
ans : list of ref Tablecol = nil;
while(l != nil) {
ans = hd l :: ans;
l = tl l;
}
return ans;
}
revrowl(l : list of ref Tablerow) : list of ref Tablerow
{
ans : list of ref Tablerow = nil;
while(l != nil) {
ans = hd l :: ans;
l = tl l;
}
return ans;
}
revcelll(l : list of ref Tablecell) : list of ref Tablecell
{
ans : list of ref Tablecell = nil;
while(l != nil) {
ans = hd l :: ans;
l = tl l;
}
return ans;
}
revintl(l : list of int) : list of int
{
ans : list of int = nil;
while(l != nil) {
ans = hd l :: ans;
l = tl l;
}
return ans;
}
# toks should contain only Font (i.e., size) and style changes, along with text.
lexes2lines(toks: array of ref Lex) : (ref Line, string)
{
n := len toks;
(tlex, i) := nexttok(toks, n, -1);
ans: ref Line = nil;
if(tlex == nil)
return(ans, "");
curline : ref Line = nil;
curitem : ref Item = nil;
stylestk := DefFont :: nil;
sizestk := DefSize :: nil;
f := DefaultFnum;
fontstk:= f :: nil;
for(;;) {
if(i >= n)
break;
tlex = toks[i++];
case tlex.tag {
Data =>
text := tlex.text;
while(text != "") {
if(curline == nil) {
curline = ref Line(nil, Point(0,0), 0, 0, 0, nil, nil);
ans = curline;
}
s : string;
(s, text) = S->splitl(text, "\n");
if(s != "") {
f = hd fontstk;
it := ref Item(0, s, f, Point(0,0), 0, curline, curitem, nil);
if(curitem == nil)
curline.items = it;
else
curitem.next = it;
curitem = it;
}
if(text != "") {
text = text[1:];
curline.next = ref Line(nil, Point(0,0), 0, 0, 0, nil, nil);
curline = curline.next;
curitem = nil;
}
}
HTML->Tfont =>
(fnd, ssize) := html->attrvalue(tlex.attr, "size");
if(fnd && len ssize > 0) {
# HTML size 3 == our Size10
sz := (int ssize) + (Size10 - 3);
if(sz < 0 || sz >= NSIZE)
return (nil, "bad font size " + ssize);
sizestk = sz :: sizestk;
fontstk = fnum(hd stylestk, sz) :: fontstk;
}
else
return (nil, "bad font command: no size");
HTML->Tfont + RBRA =>
fontstk = tl fontstk;
sizestk = tl sizestk;
if(sizestk == nil)
return (nil, "unmatched </FONT>");
HTML->Tb =>
stylestk = Bold :: stylestk;
fontstk = fnum(Bold, hd sizestk) :: fontstk;
HTML->Ti =>
stylestk = Italic :: stylestk;
fontstk = fnum(Italic, hd sizestk) :: fontstk;
HTML->Ttt =>
stylestk = Type :: stylestk;
fontstk = fnum(Type, hd sizestk) :: fontstk;
HTML->Tb + RBRA or HTML->Ti + RBRA or HTML->Ttt + RBRA =>
fontstk = tl fontstk;
stylestk = tl stylestk;
if(stylestk == nil)
return (nil, "unmatched </B>, </I>, or </TT>");
}
}
return (ans, "");
}
fnum(fstyle, fsize: int) : int
{
ans := fstyle*NSIZE + fsize;
fontused[ans] = 1;
return ans;
}
loadfonts() : string
{
for(i := 0; i < NFONTTAG; i++) {
if(fontused[i] && fontrefs[i] == nil) {
fname := fontnames[i];
f := Font.open(display, fname);
if(f == nil)
return sys->sprint("can't open font %s: %r", fname);
fontrefs[i] = f;
}
}
return "";
}
# Find where each cell goes in nrow x ncol grid
setgrid()
{
gcells := array[tab.nrow] of { * => array[tab.ncol] of { * => ref Tablegcell(nil, 1)} };
# The following arrays keep track of cells that are spanning
# multiple rows; rowspancnt[i] is the number of rows left
# to be spanned in column i.
# When done, cell's (row,col) is upper left grid point.
rowspancnt := array[tab.ncol] of { * => 0};
rowspancell := array[tab.ncol] of ref Tablecell;
ri := 0;
ci := 0;
for(ri = 0; ri < tab.nrow; ri++) {
row := tab.rows[ri];
cl := row.cells;
for(ci = 0; ci < tab.ncol; ) {
if(rowspancnt[ci] > 0) {
gcells[ri][ci].cell = rowspancell[ci];
gcells[ri][ci].drawnhere = 0;
rowspancnt[ci]--;
ci++;
}
else {
if(cl == nil) {
ci++;
continue;
}
c := hd cl;
cl = tl cl;
cspan := c.colspan;
if(cspan == 0) {
cspan = tab.ncol - ci;
c.colspan = cspan;
}
rspan := c.rowspan;
if(rspan == 0) {
rspan = tab.nrow - ri;
c.rowspan = rspan;
}
c.row = ri;
c.col = ci;
for(i := 0; i < cspan && ci < tab.ncol; i++) {
gcells[ri][ci].cell = c;
if(i > 0)
gcells[ri][ci].drawnhere = 0;
if(rspan > 1) {
rowspancnt[ci] = rspan-1;
rowspancell[ci] = c;
}
ci++;
}
}
}
}
tab.grid = gcells;
}
build() : string
{
ri, ci: int;
# sys->print("\n\ninitial table\n"); printtable();
if(tab.ncol == 0 || tab.nrow == 0)
return "";
setgrid();
err := loadfonts();
if(err != "")
return err;
for(cl := tab.cells; cl != nil; cl = tl cl)
cell_geom(hd cl);
for(ci = 0; ci < tab.ncol; ci++)
col_geom(ci);
for(ri = 0; ri < tab.nrow; ri++)
row_geom(ri);
caption_geom();
table_geom();
# sys->print("\n\ntable after geometry set\n"); printtable();
h := tab.height;
w := tab.width;
if(tab.capcell != nil) {
h += tab.capcell.height;
if(tab.capcell.width > w)
w = tab.capcell.width;
}
err = tk->cmd(top, canv + " configure -width " + string w
+ " -height " + string h);
if(len err > 0 && err[0] == '!')
return err;
err = create_cells();
if(err != "")
return err;
err = create_border();
if(err != "")
return err;
err = create_rules();
if(err != "")
return err;
err = create_caption();
if(err != "")
return err;
tk->cmd(top, "update");
return "";
}
create_cells() : string
{
for(cl := tab.cells; cl != nil; cl = tl cl) {
c := hd cl;
cpos := c.pos;
for(l := c.lines; l != nil; l = l.next) {
lpos := l.pos;
for(it := l.items; it != nil; it = it.next) {
ipos := it.pos;
pos := ipos.add(lpos.add(cpos));
fnt := fontrefs[it.fontnum];
v := tk->cmd(top, canv + " create text " + string pos.x + " "
+ string pos.y + " -anchor nw -font " + fnt.name
+ " -text '" + it.s);
if(len v > 0 && v[0] == '!')
return v;
it.itemid = int v;
}
}
}
return "";
}
create_border() : string
{
bd := tab.border;
if(bd > 0) {
x1 := string (bd / 2);
y1 := x1;
x2 := string (tab.width - bd/2 -1);
y2 := string (tab.height - bd/2 -1);
v := tk->cmd(top, canv + " create rectangle "
+ x1 + " " + y1 + " " + x2 + " " + y2 + " -width " + string bd);
if(len v > 0 && v[0] == '!')
return v;
tab.brectid = int v;
}
return "";
}
create_rules() : string
{
ci, ri, i: int;
err : string;
c : ref Tablecell;
for(ci = 0; ci < tab.ncol; ci++) {
col := tab.cols[ci];
rw := col.rule;
if(rw > 0) {
x := col.pos.x + col.width + TABHPAD/2 - rw/2;
ids: list of int = nil;
startri := 0;
for(ri = 0; ri < tab.nrow; ri++) {
c = tab.grid[ri][ci].cell;
if(c.col+c.colspan-1 > ci) {
# rule would cross a spanning cell at this column
if(ri > startri) {
(err, i) = create_col_rule(startri, ri-1, x, rw);
if(err != "")
return err;
ids = i :: ids;
}
startri = ri+1;
}
}
if(ri > startri)
(err, i) = create_col_rule(startri, ri-1, x, rw);
ids = i :: ids;
col.ruleids = revintl(ids);
}
}
for(ri = 0; ri < tab.nrow; ri++) {
row := tab.rows[ri];
rw := row.rule;
if(rw > 0) {
y := row.pos.y + row.height + TABVPAD/2 - rw/2;
ids: list of int = nil;
startci := 0;
for(ci = 0; ci < tab.ncol; ci++) {
c = tab.grid[ri][ci].cell;
if(c.row+c.rowspan-1 > ri) {
# rule would cross a spanning cell at this row
if(ci > startci) {
(err, i) = create_row_rule(startci, ci-1, y, rw);
if(err != "")
return err;
ids = i :: ids;
}
startci = ci+1;
}
}
if(ci > startci)
(err, i) = create_row_rule(startci, ci-1, y, rw);
ids = i :: ids;
row.ruleids = revintl(ids);
}
}
return "";
}
create_col_rule(topri, botri, x, rw: int) : (string, int)
{
y1, y2: int;
if(topri == 0)
y1 = 0;
else
y1 = tab.rows[topri].pos.y - TABVPAD/2;
if(botri == tab.nrow-1)
y2 = tab.height;
else
y2 = tab.rows[botri].pos.y + tab.rows[botri].height + TABVPAD/2;
sx := string x;
v := tk->cmd(top, canv + " create line " + sx + " "
+ string y1 + " " + sx + " " + string y2 + " -width " + string rw);
if(len v > 0 && v[0] == '!')
return (v, 0);
return ("", int v);
}
create_row_rule(leftci, rightci, y, rw: int) : (string, int)
{
x1, x2: int;
if(leftci == 0)
x1 = 0;
else
x1 = tab.cols[leftci].pos.x - TABHPAD/2;
if(rightci == tab.ncol-1)
x2 = tab.width;
else
x2 = tab.cols[rightci].pos.x + tab.cols[rightci].width + TABHPAD/2;
sy := string y;
v := tk->cmd(top, canv + " create line " + string x1 + " "
+ sy + " " + string x2 + " " + sy + " -width " + string rw);
if(len v > 0 && v[0] == '!')
return (v, 0);
return ("", int v);
}
create_caption() : string
{
if(tab.capcell == nil)
return "";
cpos := Point(0, tab.height + 2*TABVPAD);
for(l := tab.capcell.lines; l != nil; l = l.next) {
lpos := l.pos;
for(it := l.items; it != nil; it = it.next) {
ipos := it.pos;
pos := ipos.add(lpos.add(cpos));
fnt := fontrefs[it.fontnum];
v := tk->cmd(top, canv + " create text " + string pos.x + " "
+ string pos.y + " -anchor nw -font " + fnt.name
+ " -text '" + it.s);
if(len v > 0 && v[0] == '!')
return v;
it.itemid = int v;
}
}
return "";
}
# Assuming row and col geoms correct, set row, col, and cell origins
table_geom()
{
row: ref Tablerow;
col: ref Tablecol;
orig := Point(0,0);
bd := tab.border;
if(bd > 0)
orig = orig.add(Point(TABHPAD+bd, TABVPAD+bd));
o := orig;
for(ci := 0; ci < tab.ncol; ci++) {
col = tab.cols[ci];
col.pos = o;
o.x += col.width + col.rule;
if(ci < tab.ncol-1)
o.x += TABHPAD;
}
if(bd > 0)
o.x += TABHPAD + bd;
tab.width = o.x;
o = orig;
for(ri := 0; ri < tab.nrow; ri++) {
row = tab.rows[ri];
row.pos = o;
o.y += row.height + row.rule;
if(ri < tab.nrow-1)
o.y += TABVPAD;
}
if(bd > 0)
o.y += TABVPAD + bd;
tab.height = o.y;
if(tab.capcell != nil) {
tabw := tab.width;
if(tab.capcell.width > tabw)
tabw = tab.capcell.width;
for(l := tab.capcell.lines; l != nil; l = l.next)
l.pos.x += (tabw - l.width)/2;
}
for(cl := tab.cells; cl != nil; cl = tl cl) {
c := hd cl;
row = tab.rows[c.row];
col = tab.cols[c.col];
x := col.pos.x;
y := row.pos.y;
w := spanned_col_width(c.col, c.col+c.colspan-1);
case (cellhalign(c)) {
Aright =>
x += w - c.width;
Acenter =>
x += (w - c.width) / 2;
}
h := spanned_row_height(c.row, c.row+c.rowspan-1);
case (cellvalign(c)) {
Abottom =>
y += h - c.height;
Anone or Amiddle =>
y += (h - c.height) / 2;
Abaseline =>
y += row.ascent - c.ascent;
}
c.pos = Point(x,y);
}
}
spanned_col_width(firstci, lastci: int) : int
{
firstcol := tab.cols[firstci];
if(firstci == lastci)
return firstcol.width;
lastcol := tab.cols[lastci];
return (lastcol.pos.x + lastcol.width - firstcol.pos.x);
}
spanned_row_height(firstri, lastri: int) : int
{
firstrow := tab.rows[firstri];
if(firstri == lastri)
return firstrow.height;
lastrow := tab.rows[lastri];
return (lastrow.pos.y + lastrow.height - firstrow.pos.y);
}
# Assuming cell geoms are correct, set col widths.
# This code is sloppy for spanned columns;
# it will allocate too much space for them because
# inter-column pad is ignored, and it may make
# narrow columns wider than they have to be.
col_geom(ci: int)
{
col := tab.cols[ci];
col.width = 0;
for(ri := 0; ri < tab.nrow; ri++) {
c := tab.grid[ri][ci].cell;
if(c == nil)
continue;
cwd := c.width / c.colspan;
if(cwd > col.width)
col.width = cwd;
}
}
# Assuming cell geoms are correct, set row heights
row_geom(ri: int)
{
row := tab.rows[ri];
# find rows's global height and ascent
h := 0;
a := 0;
n : int;
for(cl := row.cells; cl != nil; cl = tl cl) {
c := hd cl;
al := cellvalign(c);
if(al == Abaseline) {
n = c.ascent;
if(n > a) {
h += (n - a);
a = n;
}
n = c.height - c.ascent;
if(n > h-a)
h = a + n;
}
else {
n = c.height;
if(n > h)
h = n;
}
}
row.height = h;
row.ascent = a;
}
cell_geom(c: ref Tablecell)
{
width := 0;
o := Point(0,0);
for(l := c.lines; l != nil; l = l.next) {
line_geom(l, o);
o.y += l.height;
if(l.width > width)
width = l.width;
}
c.width = width;
c.height = o.y;
if(c.lines != nil)
c.ascent = c.lines.ascent;
else
c.ascent = 0;
al := cellhalign(c);
if(al == Acenter || al == Aright) {
for(l = c.lines; l != nil; l = l.next) {
xdelta := c.width - l.width;
if(al == Acenter)
xdelta /= 2;
l.pos.x += xdelta;
}
}
}
caption_geom()
{
if(tab.capcell != nil) {
o := Point(0,TABVPAD);
width := 0;
for(l := tab.capcell.lines; l != nil; l = l.next) {
line_geom(l, o);
o.y += l.height;
if(l.width > width)
width = l.width;
}
tab.capcell.width = width;
tab.capcell.height = o.y + 4*TABVPAD;
}
}
line_geom(l: ref Line, o: Point)
{
# find line's global height and ascent
h := 0;
a := 0;
for(it := l.items; it != nil; it = it.next) {
fnt := fontrefs[it.fontnum];
n := fnt.ascent;
if(n > a) {
h += (n - a);
a = n;
}
n = fnt.height - fnt.ascent;
if(n > h-a)
h = a + n;
}
l.height = h;
l.ascent = a;
# set positions
l.pos = o;
for(it = l.items; it != nil; it = it.next) {
fnt := fontrefs[it.fontnum];
it.width = fnt.width(it.s);
it.pos.x = o.x;
o.x += it.width;
it.pos.y = a - fnt.ascent;
}
l.width = o.x;
}
cellhalign(c: ref Tablecell) : int
{
a := c.align.halign;
if(a == Anone)
a = tab.cols[c.col].align.halign;
return a;
}
cellvalign(c: ref Tablecell) : int
{
a := c.align.valign;
if(a == Anone)
a = tab.rows[c.row].align.valign;
return a;
}
# table debugging
printtable()
{
if(tab == nil) {
sys->print("no table\n");
return;
}
sys->print("Table %d rows, %d cols width %d height %d\n",
tab.nrow, tab.ncol, tab.width, tab.height);
if(tab.capcell != nil)
sys->print(" caption: "); printlexes(tab.capcell.content, " ");
sys->print(" cols:\n"); printcols(tab.cols);
sys->print(" rows:\n"); printrows(tab.rows);
}
align2string(al: int) : string
{
s := "";
case al {
Anone => s = "none";
Aleft => s = "left";
Acenter => s = "center";
Aright => s = "right";
Ajustify => s = "justify";
Atop => s = "top";
Amiddle => s = "middle";
Abottom => s = "bottom";
Abaseline => s = "baseline";
}
return s;
}
printcols(cols: array of ref Tablecol)
{
n := len cols;
for(i := 0 ; i < n; i++) {
c := cols[i];
sys->print(" width %d align = %s,%s pos (%d,%d) rule %d\n", c.width,
align2string(c.align.halign), align2string(c.align.valign), c.pos.x, c.pos.y, c.rule);
}
}
printrows(rows: array of ref Tablerow)
{
n := len rows;
for(i := 0; i < n; i++) {
tr := rows[i];
sys->print(" row height %d ascent %d align=%s,%s pos (%d,%d) rule %d\n", tr.height, tr.ascent,
align2string(tr.align.halign), align2string(tr.align.valign), tr.pos.x, tr.pos.y, tr.rule);
for(cl := tr.cells; cl != nil; cl = tl cl) {
c := hd cl;
sys->print(" cell %d width %d height %d ascent %d align=%s,%s\n",
c.cellid, c.width, c.height, c.ascent,
align2string(c.align.halign), align2string(c.align.valign));
sys->print(" pos (%d,%d) rowspan=%d colspan=%d nowrap=%d\n",
c.pos.x, c.pos.y, c.rowspan, c.colspan, c.nowrap);
printlexes(c.content, " ");
printlines(c.lines);
}
}
}
printlexes(lexes: array of ref Lex, indent: string)
{
for(i := 0; i < len lexes; i++)
sys->print("%s%s\n", indent, html->lex2string(lexes[i]));
}
printlines(l: ref Line)
{
if(l == nil)
return;
sys->print("lines: \n");
while(l != nil) {
sys->print(" Line: pos (%d,%d), height %d ascent %d\n", l.pos.x, l.pos.y, l.height, l.ascent);
printitems(l.items);
l = l.next;
}
}
printitems(i: ref Item)
{
while(i != nil) {
sys->print(" '%s' id %d fontnum %d w %d, pos (%d,%d)\n", i.s, i.itemid, i.fontnum,
i.width, i.pos.x, i.pos.y);
i = i.next;
}
}
printgrid(g: array of array of ref Tablegcell)
{
nr := len g;
nc := len g[0];
for(r := 0; r < nr; r++) {
for(c := 0; c < nc; c++) {
x := g[r][c];
cell := x.cell;
suf := " ";
if(x.drawnhere == 0)
suf = "*";
if(cell == nil)
sys->print(" %s", suf);
else
sys->print("%5d%s", cell.cellid, suf);
}
sys->print("\n");
}
}
# Return (table in correct format, error string)
cook(parent: string, fmt: int, args: string) : (ref Celem, string)
{
(spec, err) := getspec(parent, args);
if(err != "")
return (nil, err);
if(fmt == FHtml)
return cookhtml(spec);
else
return cooklatex(spec);
}
# Return (table as latex, error string)
# BUG: cells spanning multiple rows not handled correctly
# (all their contents go in the first row of span, though hrules properly broken)
cooklatex(spec: array of ref Lex) : (ref Celem, string)
{
s : string;
ci, ri: int;
err := parsetab(spec);
if(err != "")
return (nil, err_ret(err));
setgrid();
ans := ref Celem(SGML, "", nil, nil, nil, nil);
cur : ref Celem = nil;
cur = add(ans, cur, specialce("\\begin{tabular}[t]{" + lcolspec() + "}\n"));
if(tab.border) {
if(tab.border == 1)
s = "\\hline\n";
else
s = "\\hline\\hline\n";
cur = add(ans, cur, specialce(s));
}
for(ri = 0; ri < tab.nrow; ri++) {
row := tab.rows[ri];
ci = 0;
anyrowspan := 0;
for(cl := row.cells; cl != nil; cl = tl cl) {
c := hd cl;
while(ci < c.col) {
cur = add(ans, cur, specialce("&"));
ci++;
}
mcol := 0;
if(c.colspan > 1) {
cur = add(ans, cur, specialce("\\multicolumn{" + string c.colspan + "}{" +
lnthcolspec(ci, ci+c.colspan-1, c.align.halign) + "}{"));
mcol = 1;
}
else if(c.align.halign != Anone) {
cur = add(ans, cur, specialce("\\multicolumn{1}{" +
lnthcolspec(ci, ci, c.align.halign) + "}{"));
mcol = 1;
}
if(c.rowspan > 1)
anyrowspan = 1;
cur = addlconvlines(ans, cur, c);
if(mcol) {
cur = add(ans, cur, specialce("}"));
ci += c.colspan-1;
}
}
while(ci++ < tab.ncol-1)
cur = add(ans, cur, specialce("&"));
if(ri < tab.nrow-1 || row.rule > 0 || tab.border > 0)
cur = add(ans, cur, specialce("\\\\\n"));
if(row.rule) {
if(anyrowspan) {
startci := 0;
for(ci = 0; ci < tab.ncol; ci++) {
c := tab.grid[ri][ci].cell;
if(c.row+c.rowspan-1 > ri) {
# rule would cross a spanning cell at this row
if(ci > startci)
cur = add(ans, cur, specialce("\\cline{" +
string (startci+1) + "-" + string ci + "}"));
startci = ci+1;
}
}
if(ci > startci)
cur = add(ans, cur, specialce("\\cline{" +
string (startci+1) + "-" + string ci + "}"));
}
else
cur = add(ans, cur, specialce("\\hline\n"));
}
}
if(tab.border) {
if(tab.border == 1)
s = "\\hline\n";
else
s = "\\hline\\hline\n";
cur = add(ans, cur, specialce(s));
}
cur = add(ans, cur, specialce("\\end{tabular}\n"));
if(ans != nil)
ans = ans.contents;
return (ans, "");
}
lcolspec() : string
{
ans := "";
for(ci := 0; ci < tab.ncol; ci++)
ans += lnthcolspec(ci, ci, Anone);
return ans;
}
lnthcolspec(ci, cie, al: int) : string
{
ans := "";
if(ci == 0) {
if(tab.border == 1)
ans = "|";
else if(tab.border > 1)
ans = "||";
}
col := tab.cols[ci];
if(al == Anone)
al = col.align.halign;
case al {
Acenter =>
ans += "c";
Aright =>
ans += "r";
* =>
ans += "l";
}
if(ci == cie) {
if(col.rule == 1)
ans += "|";
else if(col.rule > 1)
ans += "||";
}
if(cie == tab.ncol - 1) {
if(tab.border == 1)
ans += "|";
else if(tab.border > 1)
ans += "||";
}
return ans;
}
addlconvlines(par, tail: ref Celem, c: ref Tablecell) : ref Celem
{
line := c.lines;
if(line == nil)
return tail;
multiline := 0;
if(line.next != nil) {
multiline = 1;
val := "";
case cellvalign(c) {
Abaseline or Atop => val = "[t]";
Abottom => val = "[b]";
}
hal := "l";
case cellhalign(c) {
Aright => hal = "r";
Acenter => hal = "c";
}
# The @{}'s in the colspec eliminate extra space before and after result
tail = add(par, tail, specialce("\\begin{tabular}" + val + "{@{}" + hal + "@{}}\n"));
}
while(line != nil) {
for(it := line.items; it != nil; it = it.next) {
fnum := it.fontnum;
f := fnum / NSIZE;
sz := fnum % NSIZE;
grouped := 0;
if((f != DefFont || sz != DefSize) && (it.prev!=nil || it.next!=nil)) {
tail = add(par, tail, specialce("{"));
grouped = 1;
}
if(f != DefFont) {
fcmd := "";
case f {
Roman => fcmd = "\\rmfamily ";
Italic => fcmd = "\\itshape ";
Bold => fcmd = "\\bfseries ";
Type => fcmd = "\\ttfamily ";
}
tail = add(par, tail, specialce(fcmd));
}
if(sz != DefSize) {
szcmd := "";
case sz {
Size6 => szcmd = "\\footnotesize ";
Size8 => szcmd = "\\small ";
Size10 => szcmd = "\\normalsize ";
Size12 => szcmd = "\\large ";
Size16 => szcmd = "\\Large ";
}
tail = add(par, tail, specialce(szcmd));
}
tail = add(par, tail, textce(it.s));
if(grouped)
tail = add(par, tail, specialce("}"));
}
ln := line.next;
if(multiline && ln != nil)
tail = add(par, tail, specialce("\\\\\n"));
line = line.next;
}
if(multiline)
tail = add(par, tail, specialce("\\end{tabular}\n"));
return tail;
}
# Return (table as html, error string)
cookhtml(spec: array of ref Lex) : (ref Celem, string)
{
n := len spec;
ans := ref Celem(SGML, "", nil, nil, nil, nil);
cur : ref Celem = nil;
for(i := 0; i < n; i++) {
tok := spec[i];
if(tok.tag == Data)
cur = add(ans, cur, textce(tok.text));
else {
s := html->lex2string(spec[i]);
cur = add(ans, cur, specialce(s));
}
}
if(ans != nil)
ans = ans.contents;
return (ans, "");
}
textce(s: string) : ref Celem
{
return ref Celem(Text, s, nil, nil, nil, nil);
}
specialce(s: string) : ref Celem
{
return ref Celem(Special, s, nil, nil, nil, nil);
}
add(par, tail: ref Celem, e: ref Celem) : ref Celem
{
if(tail == nil) {
par.contents = e;
e.parent = par;
}
else
tail.next = e;
e.prev = tail;
return e;
}
fullname(parent, file: string): string
{
if(len parent==0 || (len file>0 && (file[0]=='/' || file[0]=='#')))
return file;
for(i:=len parent-1; i>=0; i--)
if(parent[i] == '/')
return parent[0:i+1] + file;
return file;
}