/usr/src/games/gomoku/pickmove.c

Bug Summary

File:	src/games/gomoku/pickmove.c
Warning:	line 1155, column 21 Array access (via field 'c_framecnt') results in a null pointer dereference
Annotated Source Code

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clang -cc1 -cc1 -triple amd64-unknown-openbsd7.0 -analyze -disable-free -disable-llvm-verifier -discard-value-names -main-file-name pickmove.c -analyzer-store=region -analyzer-opt-analyze-nested-blocks -analyzer-checker=core -analyzer-checker=apiModeling -analyzer-checker=unix -analyzer-checker=deadcode -analyzer-checker=security.insecureAPI.UncheckedReturn -analyzer-checker=security.insecureAPI.getpw -analyzer-checker=security.insecureAPI.gets -analyzer-checker=security.insecureAPI.mktemp -analyzer-checker=security.insecureAPI.mkstemp -analyzer-checker=security.insecureAPI.vfork -analyzer-checker=nullability.NullPassedToNonnull -analyzer-checker=nullability.NullReturnedFromNonnull -analyzer-output plist -w -setup-static-analyzer -mrelocation-model pic -pic-level 1 -pic-is-pie -mframe-pointer=all -relaxed-aliasing -fno-rounding-math -mconstructor-aliases -munwind-tables -target-cpu x86-64 -target-feature +retpoline-indirect-calls -target-feature +retpoline-indirect-branches -tune-cpu generic -debugger-tuning=gdb -fcoverage-compilation-dir=/usr/src/games/gomoku/obj -resource-dir /usr/local/lib/clang/13.0.0 -internal-isystem /usr/local/lib/clang/13.0.0/include -internal-externc-isystem /usr/include -O2 -fdebug-compilation-dir=/usr/src/games/gomoku/obj -ferror-limit 19 -fwrapv -D_RET_PROTECTOR -ret-protector -fgnuc-version=4.2.1 -vectorize-loops -vectorize-slp -fno-builtin-malloc -fno-builtin-calloc -fno-builtin-realloc -fno-builtin-valloc -fno-builtin-free -fno-builtin-strdup -fno-builtin-strndup -analyzer-output=html -faddrsig -D__GCC_HAVE_DWARF2_CFI_ASM=1 -o /home/ben/Projects/vmm/scan-build/2022-01-12-194120-40624-1 -x c /usr/src/games/gomoku/pickmove.c
1/*	$OpenBSD: pickmove.c,v 1.16 2016/01/08 21:38:33 mestre Exp $	*/
2/*
* Copyright (c) 1994
*	The Regents of the University of California.  All rights reserved.
*
* This code is derived from software contributed to Berkeley by
* Ralph Campbell.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
*    notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
*    notice, this list of conditions and the following disclaimer in the
*    documentation and/or other materials provided with the distribution.
* 3. Neither the name of the University nor the names of its contributors
*    may be used to endorse or promote products derived from this software
*    without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED.  IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*/

34#include <curses.h>
35#include <limits.h>
36#include <stdlib.h>
37#include <string.h>

39#include "gomoku.h"

41#define BITS_PER_INT(sizeof(int) * 8)	(sizeof(int) * CHAR_BIT8)
42#define MAPSZ(((19 +2)*(19 +1)+1) / (sizeof(int) * 8))		(BAREA((19 +2)*(19 +1)+1) / BITS_PER_INT(sizeof(int) * 8))

44#define BIT_SET(a, b)((a)[(b)/(sizeof(int) * 8)] |= (1 << ((b) % (sizeof(int
) * 8))))	((a)[(b)/BITS_PER_INT(sizeof(int) * 8)] |= (1 << ((b) % BITS_PER_INT(sizeof(int) * 8))))
45#define BIT_CLR(a, b)((a)[(b)/(sizeof(int) * 8)] &= ~(1 << ((b) % (sizeof
(int) * 8))))	((a)[(b)/BITS_PER_INT(sizeof(int) * 8)] &= ~(1 << ((b) % BITS_PER_INT(sizeof(int) * 8))))
46#define BIT_TEST(a, b)((a)[(b)/(sizeof(int) * 8)] & (1 << ((b) % (sizeof(
int) * 8))))	((a)[(b)/BITS_PER_INT(sizeof(int) * 8)] & (1 << ((b) % BITS_PER_INT(sizeof(int) * 8))))

48struct	combostr *hashcombos[FAREA(19*(19 -4) + (19 -4)*(19 -4) + 19*(19 -4) + (19 -4)*(19 -4))];	/* hash list for finding duplicates */
49struct	combostr *sortcombos;		/* combos at higher levels */
50int	combolen;			/* number of combos in sortcombos */
51int	nextcolor;			/* color of next move */
52int	elistcnt;			/* count of struct elist allocated */
53int	combocnt;			/* count of struct combostr allocated */
54int	forcemap[MAPSZ(((19 +2)*(19 +1)+1) / (sizeof(int) * 8))];		/* map for blocking <1,x> combos */
55int	tmpmap[MAPSZ(((19 +2)*(19 +1)+1) / (sizeof(int) * 8))];			/* map for blocking <1,x> combos */
56int	nforce;				/* count of opponent <1,x> combos */

58int
59pickmove(int us)
60{
struct spotstr *sp, *sp1, *sp2;
union comboval *Ocp, *Tcp;
int m;

/* first move is easy */
if (movenum == 1)
return (PT(K,10)((10) + (19 +1) * (10)));

/* initialize all the board values */
for (sp = &board[PT(T,20)((19) + (19 +1) * (20))]; --sp >= &board[PT(A,1)((1) + (19 +1) * (1))]; ) {
sp->s_combo[BLACK0].s = MAXCOMBO0x600 + 1;
sp->s_combo[WHITE1].s = MAXCOMBO0x600 + 1;
sp->s_level[BLACK0] = 255;
sp->s_level[WHITE1] = 255;
sp->s_nforce[BLACK0] = 0;
sp->s_nforce[WHITE1] = 0;
sp->s_flg &= ~(FFLAGALL0x000F00 | MFLAGALL0x00F000);
}
nforce = 0;
memset(forcemap, 0, sizeof(forcemap));

/* compute new values */
nextcolor = us;
scanframes(BLACK0);
scanframes(WHITE1);

/* find the spot with the highest value */
for (sp = sp1 = sp2 = &board[PT(T,19)((19) + (19 +1) * (19))]; --sp >= &board[PT(A,1)((1) + (19 +1) * (1))]; ) {
if (sp->s_occ != EMPTY2)
	continue;
if (debug && (sp->s_combo[BLACK0].c.a == 1 ||
    sp->s_combo[WHITE1].c.a == 1)) {
	snprintf(fmtbuf, sizeof fmtbuf,
		"- %s %x/%d %d %x/%d %d %d", stoc(sp - board),
		sp->s_combo[BLACK0].s, sp->s_level[BLACK0],
		sp->s_nforce[BLACK0],
		sp->s_combo[WHITE1].s, sp->s_level[WHITE1],
		sp->s_nforce[WHITE1],
		sp->s_wval);
	dlog(fmtbuf);
}
/* pick the best black move */
if (better(sp, sp1, BLACK0))
	sp1 = sp;
/* pick the best white move */
if (better(sp, sp2, WHITE1))
	sp2 = sp;
}

if (debug) {
snprintf(fmtbuf, sizeof fmtbuf,
	"B %s %x/%d %d %x/%d %d %d",
	stoc(sp1 - board),
	sp1->s_combo[BLACK0].s, sp1->s_level[BLACK0],
	sp1->s_nforce[BLACK0],
	sp1->s_combo[WHITE1].s, sp1->s_level[WHITE1],
	sp1->s_nforce[WHITE1], sp1->s_wval);
dlog(fmtbuf);
snprintf(fmtbuf, sizeof fmtbuf,
	"W %s %x/%d %d %x/%d %d %d",
	stoc(sp2 - board),
	sp2->s_combo[WHITE1].s, sp2->s_level[WHITE1],
	sp2->s_nforce[WHITE1],
	sp2->s_combo[BLACK0].s, sp2->s_level[BLACK0],
	sp2->s_nforce[BLACK0], sp2->s_wval);
dlog(fmtbuf);
/*
 * Check for more than one force that can't
 * all be blocked with one move.
 */
sp = (us == BLACK0) ? sp2 : sp1;
m = sp - board;
if (sp->s_combo[!us].c.a == 1 && !BIT_TEST(forcemap, m)((forcemap)[(m)/(sizeof(int) * 8)] & (1 << ((m) % (
sizeof(int) * 8)))))
	dlog("*** Can't be blocked");
}
if (us == BLACK0) {
Ocp = &sp1->s_combo[BLACK0];
Tcp = &sp2->s_combo[WHITE1];
} else {
Tcp = &sp1->s_combo[BLACK0];
Ocp = &sp2->s_combo[WHITE1];
sp = sp1;
sp1 = sp2;
sp2 = sp;
}
/*
* Block their combo only if we have to (i.e., if they are one move
* away from completing a force and we don't have a force that
* we can complete which takes fewer moves to win).
*/
if (Tcp->c.a <= 1 && (Ocp->c.a > 1 ||
   Tcp->c.a + Tcp->c.b < Ocp->c.a + Ocp->c.b))
return (sp2 - board);
return (sp1 - board);
155}

157/*
* Return true if spot 'sp' is better than spot 'sp1' for color 'us'.
*/
160int
161better(struct spotstr *sp, struct spotstr *sp1, int us)
162{
int them, s, s1;

if (sp->s_combo[us].s < sp1->s_combo[us].s)
return (1);
if (sp->s_combo[us].s != sp1->s_combo[us].s)
return (0);
if (sp->s_level[us] < sp1->s_level[us])
return (1);
if (sp->s_level[us] != sp1->s_level[us])
return (0);
if (sp->s_nforce[us] > sp1->s_nforce[us])
return (1);
if (sp->s_nforce[us] != sp1->s_nforce[us])
return (0);

them = !us;
s = sp - board;
s1 = sp1 - board;
if (BIT_TEST(forcemap, s)((forcemap)[(s)/(sizeof(int) * 8)] & (1 << ((s) % (
sizeof(int) * 8)))) && !BIT_TEST(forcemap, s1)((forcemap)[(s1)/(sizeof(int) * 8)] & (1 << ((s1) %
 (sizeof(int) * 8)))))
return (1);
if (!BIT_TEST(forcemap, s)((forcemap)[(s)/(sizeof(int) * 8)] & (1 << ((s) % (
sizeof(int) * 8)))) && BIT_TEST(forcemap, s1)((forcemap)[(s1)/(sizeof(int) * 8)] & (1 << ((s1) %
 (sizeof(int) * 8)))))
return (0);
if (sp->s_combo[them].s < sp1->s_combo[them].s)
return (1);
if (sp->s_combo[them].s != sp1->s_combo[them].s)
return (0);
if (sp->s_level[them] < sp1->s_level[them])
return (1);
if (sp->s_level[them] != sp1->s_level[them])
return (0);
if (sp->s_nforce[them] > sp1->s_nforce[them])
return (1);
if (sp->s_nforce[them] != sp1->s_nforce[them])
return (0);

if (sp->s_wval > sp1->s_wval)
return (1);
if (sp->s_wval != sp1->s_wval)
return (0);

return (arc4random() & 1);
204}

206int	curcolor;	/* implicit parameter to makecombo() */
207int	curlevel;	/* implicit parameter to makecombo() */

209/*
* Scan the sorted list of non-empty frames and
* update the minimum combo values for each empty spot.
* Also, try to combine frames to find more complex (chained) moves.
*/
214void
215scanframes(int color)
216{
struct combostr *cbp, *ecbp;
struct spotstr *sp;
union comboval *cp;
struct elist *ep, *nep;
int i, r, d, n;
union comboval cb;

curcolor = color;

/* check for empty list of frames */
cbp = sortframes[color];
if (cbp == (struct combostr *)0)
return;

/* quick check for four in a row */
sp = &board[cbp->c_vertex];
cb.s = sp->s_fval[color][d = cbp->c_dir].s;
if (cb.s < 0x101) {
d = dd[d];
for (i = 5 + cb.c.b; --i >= 0; sp += d) {
	if (sp->s_occ != EMPTY2)
		continue;
	sp->s_combo[color].s = cb.s;
	sp->s_level[color] = 1;
}
return;
}

/*
* Update the minimum combo value for each spot in the frame
* and try making all combinations of two frames intersecting at
* an empty spot.
*/
n = combolen;
ecbp = cbp;
do {
sp = &board[cbp->c_vertex];
cp = &sp->s_fval[color][r = cbp->c_dir];
d = dd[r];
if (cp->c.b) {
	/*
	 * Since this is the first spot of an open ended
	 * frame, we treat it as a closed frame.
	 */
	cb.c.a = cp->c.a + 1;
	cb.c.b = 0;
	if (cb.s < sp->s_combo[color].s) {
		sp->s_combo[color].s = cb.s;
		sp->s_level[color] = 1;
	}
	/*
	 * Try combining other frames that intersect
	 * at this spot.
	 */
	makecombo2(cbp, sp, 0, cb.s);
	if (cp->s != 0x101)
		cb.s = cp->s;
	else if (color != nextcolor)
		memset(tmpmap, 0, sizeof(tmpmap));
	sp += d;
	i = 1;
} else {
	cb.s = cp->s;
	i = 0;
}
for (; i < 5; i++, sp += d) {	/* for each spot */
	if (sp->s_occ != EMPTY2)
		continue;
	if (cp->s < sp->s_combo[color].s) {
		sp->s_combo[color].s = cp->s;
		sp->s_level[color] = 1;
	}
	if (cp->s == 0x101) {
		sp->s_nforce[color]++;
		if (color != nextcolor) {
			n = sp - board;
			BIT_SET(tmpmap, n)((tmpmap)[(n)/(sizeof(int) * 8)] |= (1 << ((n) % (sizeof
(int) * 8))));
		}
	}
	/*
	 * Try combining other frames that intersect
	 * at this spot.
	 */
	makecombo2(cbp, sp, i, cb.s);
}
if (cp->s == 0x101 && color != nextcolor) {
	if (nforce == 0)
		memcpy(forcemap, tmpmap, sizeof(tmpmap));
	else {
		for (i = 0; i < MAPSZ(((19 +2)*(19 +1)+1) / (sizeof(int) * 8)); i++)
			forcemap[i] &= tmpmap[i];
	}
}
/* mark frame as having been processed */
board[cbp->c_vertex].s_flg |= MFLAG0x001000 << r;
} while ((cbp = cbp->c_next) != ecbp);

/*
* Try to make new 3rd level combos, 4th level, etc.
* Limit the search depth early in the game.
*/
d = 2;
while (d <= ((unsigned)(movenum + 1) >> 1) && combolen > n) {
if (debug) {
	snprintf(fmtbuf, sizeof fmtbuf,
		"%cL%d %d %d %d", "BW"[color],
		d, combolen - n, combocnt, elistcnt);
	dlog(fmtbuf);
	refresh()wrefresh(stdscr);
}
n = combolen;
addframes(d);
d++;
}

/* scan for combos at empty spots */
for (sp = &board[PT(T,20)((19) + (19 +1) * (20))]; --sp >= &board[PT(A,1)((1) + (19 +1) * (1))]; ) {
for (ep = sp->s_empty; ep; ep = nep) {
	cbp = ep->e_combo;
	if (cbp->c_combo.s <= sp->s_combo[color].s) {
		if (cbp->c_combo.s != sp->s_combo[color].s) {
			sp->s_combo[color].s = cbp->c_combo.s;
			sp->s_level[color] = cbp->c_nframes;
		} else if (cbp->c_nframes < sp->s_level[color])
			sp->s_level[color] = cbp->c_nframes;
	}
	nep = ep->e_next;
	free(ep);
	elistcnt--;
}
sp->s_empty = (struct elist *)0;
for (ep = sp->s_nempty; ep; ep = nep) {
	cbp = ep->e_combo;
	if (cbp->c_combo.s <= sp->s_combo[color].s) {
		if (cbp->c_combo.s != sp->s_combo[color].s) {
			sp->s_combo[color].s = cbp->c_combo.s;
			sp->s_level[color] = cbp->c_nframes;
		} else if (cbp->c_nframes < sp->s_level[color])
			sp->s_level[color] = cbp->c_nframes;
	}
	nep = ep->e_next;
	free(ep);
	elistcnt--;
}
sp->s_nempty = (struct elist *)0;
}

/* remove old combos */
if ((cbp = sortcombos) != (struct combostr *)0) {
struct combostr *ncbp;

/* scan the list */
ecbp = cbp;
do {
	ncbp = cbp->c_next;
	free(cbp);
	combocnt--;
} while ((cbp = ncbp) != ecbp);
sortcombos = (struct combostr *)0;
}
combolen = 0;

379#ifdef DEBUG
if (combocnt) {
snprintf(fmtbuf, sizeof fmtbuf,
	"scanframes: %c combocnt %d", "BW"[color],
	combocnt);
dlog(fmtbuf);
whatsup(0);
}
if (elistcnt) {
snprintf(fmtbuf, sizeof fmtbuf,
	"scanframes: %c elistcnt %d", "BW"[color],
	elistcnt);
dlog(fmtbuf);
whatsup(0);
}
394#endif
395}

397/*
* Compute all level 2 combos of frames intersecting spot 'osp'
* within the frame 'ocbp' and combo value 's'.
*/
401void
402makecombo2(struct combostr *ocbp, struct spotstr *osp, int off, int s)
403{
struct spotstr *fsp;
struct combostr *ncbp;
int f, r, d, c;
int baseB, fcnt, emask, bmask, n;
union comboval ocb, fcb;
struct combostr **scbpp, *fcbp;

/* try to combine a new frame with those found so far */
ocb.s = s;
baseB = ocb.c.a + ocb.c.b - 1;
fcnt = ocb.c.a - 2;
emask = fcnt ? ((ocb.c.b ? 0x1E : 0x1F) & ~(1 << off)) : 0;
for (r = 4; --r >= 0; ) {			/* for each direction */
   /* don't include frames that overlap in the same direction */
   if (r == ocbp->c_dir)
continue;
   d = dd[r];
   /*
    * Frame A combined with B is the same value as B combined with A
    * so skip frames that have already been processed (MFLAG).
    * Also skip blocked frames (BFLAG) and frames that are <1,x>
    * since combining another frame with it isn't valid.
    */
   bmask = (BFLAG0x010000 | FFLAG0x000100 | MFLAG0x001000) << r;
   fsp = osp;
   for (f = 0; f < 5; f++, fsp -= d) {		/* for each frame */
if (fsp->s_occ == BORDER3)
    break;
if (fsp->s_flg & bmask)
    continue;

/* don't include frames of the wrong color */
fcb.s = fsp->s_fval[curcolor][r].s;
if (fcb.c.a >= MAXA6)
    continue;

/*
 * Get the combo value for this frame.
 * If this is the end point of the frame,
 * use the closed ended value for the frame.
 */
if (f == 0 && (fcb.c.b || fcb.s == 0x101)) {
    fcb.c.a++;
    fcb.c.b = 0;
}

/* compute combo value */
c = fcb.c.a + ocb.c.a - 3;
if (c > 4)
    continue;
n = fcb.c.a + fcb.c.b - 1;
if (baseB < n)
    n = baseB;

/* make a new combo! */
ncbp = reallocarray(NULL((void *)0), 3, sizeof(struct combostr));
if (ncbp == (struct combostr *)NULL((void *)0))
    qlog("Memory allocation failure.");
scbpp = (struct combostr **)(ncbp + 1);
fcbp = fsp->s_frame[r];
if (ocbp < fcbp) {
    scbpp[0] = ocbp;
    scbpp[1] = fcbp;
} else {
    scbpp[0] = fcbp;
    scbpp[1] = ocbp;
}
ncbp->c_combo.c.a = c;
ncbp->c_combo.c.b = n;
ncbp->c_link[0] = ocbp;
ncbp->c_link[1] = fcbp;
ncbp->c_linkv[0].s = ocb.s;
ncbp->c_linkv[1].s = fcb.s;
ncbp->c_voff[0] = off;
ncbp->c_voff[1] = f;
ncbp->c_vertex = osp - board;
ncbp->c_nframes = 2;
ncbp->c_dir = 0;
ncbp->c_frameindex = 0;
ncbp->c_flg = (ocb.c.b) ? C_OPEN_00x01 : 0;
if (fcb.c.b)
    ncbp->c_flg |= C_OPEN_10x02;
ncbp->c_framecnt[0] = fcnt;
ncbp->c_emask[0] = emask;
ncbp->c_framecnt[1] = fcb.c.a - 2;
ncbp->c_emask[1] = ncbp->c_framecnt[1] ?
    ((fcb.c.b ? 0x1E : 0x1F) & ~(1 << f)) : 0;
combocnt++;

if (c == 1 && debug > 1) {
    snprintf(fmtbuf, sizeof fmtbuf,
	"%c c %d %d m %x %x o %d %d",
	"bw"[curcolor],
	ncbp->c_framecnt[0], ncbp->c_framecnt[1],
	ncbp->c_emask[0], ncbp->c_emask[1],
	ncbp->c_voff[0], ncbp->c_voff[1]);
    dlog(fmtbuf);
    printcombo(ncbp, fmtbuf, sizeof fmtbuf);
    dlog(fmtbuf);
}
if (c > 1) {
    /* record the empty spots that will complete this combo */
    makeempty(ncbp);

    /* add the new combo to the end of the list */
    appendcombo(ncbp);
} else {
    updatecombo(ncbp, curcolor);
    free(ncbp);
    combocnt--;
}
515#ifdef DEBUG
if (c == 1 && debug > 1 || debug > 5) {
    markcombo(ncbp);
    bdisp();
    whatsup(0);
    clearcombo(ncbp, 0);
}
522#endif /* DEBUG */
   }
}
525}

527/*
* Scan the sorted list of frames and try to add a frame to
* combinations of 'level' number of frames.
*/
531void
532addframes(int level)
533{
struct combostr *cbp, *ecbp;
struct spotstr *sp, *fsp;
struct elist *ep, *nep;
int i, r, d;
struct combostr **cbpp, *pcbp;
union comboval fcb, cb;

curlevel = level;

/* scan for combos at empty spots */
i = curcolor;
for (sp = &board[PT(T,20)((19) + (19 +1) * (20))]; --sp >= &board[PT(A,1)((1) + (19 +1) * (1))]; ) {
for (ep = sp->s_empty; ep; ep = nep) {
	cbp = ep->e_combo;
	if (cbp->c_combo.s <= sp->s_combo[i].s) {
		if (cbp->c_combo.s != sp->s_combo[i].s) {
			sp->s_combo[i].s = cbp->c_combo.s;
			sp->s_level[i] = cbp->c_nframes;
		} else if (cbp->c_nframes < sp->s_level[i])
			sp->s_level[i] = cbp->c_nframes;
	}
	nep = ep->e_next;
	free(ep);
	elistcnt--;
}
sp->s_empty = sp->s_nempty;
sp->s_nempty = (struct elist *)0;
}

/* try to add frames to the uncompleted combos at level curlevel */
cbp = ecbp = sortframes[curcolor];
do {
fsp = &board[cbp->c_vertex];
r = cbp->c_dir;
/* skip frames that are part of a <1,x> combo */
if (fsp->s_flg & (FFLAG0x000100 << r))
	continue;

/*
 * Don't include <1,x> combo frames,
 * treat it as a closed three in a row instead.
 */
fcb.s = fsp->s_fval[curcolor][r].s;
if (fcb.s == 0x101)
	fcb.s = 0x200;

/*
 * If this is an open ended frame, use
 * the combo value with the end closed.
 */
if (fsp->s_occ == EMPTY2) {
	if (fcb.c.b) {
		cb.c.a = fcb.c.a + 1;
		cb.c.b = 0;
	} else
		cb.s = fcb.s;
	makecombo(cbp, fsp, 0, cb.s);
}

/*
 * The next four spots are handled the same for both
 * open and closed ended frames.
 */
d = dd[r];
sp = fsp + d;
for (i = 1; i < 5; i++, sp += d) {
	if (sp->s_occ != EMPTY2)
		continue;
	makecombo(cbp, sp, i, fcb.s);
}
} while ((cbp = cbp->c_next) != ecbp);

/* put all the combos in the hash list on the sorted list */
cbpp = &hashcombos[FAREA(19*(19 -4) + (19 -4)*(19 -4) + 19*(19 -4) + (19 -4)*(19 -4))];
do {
cbp = *--cbpp;
if (cbp == (struct combostr *)0)
	continue;
*cbpp = (struct combostr *)0;
ecbp = sortcombos;
if (ecbp == (struct combostr *)0)
	sortcombos = cbp;
else {
	/* append to sort list */
	pcbp = ecbp->c_prev;
	pcbp->c_next = cbp;
	ecbp->c_prev = cbp->c_prev;
	cbp->c_prev->c_next = ecbp;
	cbp->c_prev = pcbp;
}
} while (cbpp != hashcombos);
625}

627/*
* Compute all level N combos of frames intersecting spot 'osp'
* within the frame 'ocbp' and combo value 's'.
*/
631void
632makecombo(struct combostr *ocbp, struct spotstr *osp, int off, int s)
633{
struct combostr *cbp, *ncbp;
struct spotstr *sp;
struct elist *ep;
int n, c;
struct elist *nep;
struct combostr **scbpp;
int baseB, fcnt, emask, verts;
union comboval ocb;
struct ovlp_info vertices[1];

ocb.s = s;
baseB = ocb.c.a + ocb.c.b - 1;
fcnt = ocb.c.a - 2;
emask = fcnt ? ((ocb.c.b ? 0x1E : 0x1F) & ~(1 << off)) : 0;
1
Assuming 'fcnt' is 0→
2
←
'?' condition is false→
for (ep = osp->s_empty; ep; ep = ep->e_next) {
3
←
Loop condition is true.  Entering loop body→
   /* check for various kinds of overlap */
   cbp = ep->e_combo;
   verts = checkframes(cbp, ocbp, osp, s, vertices);
4
←
Calling 'checkframes'→
   if (verts < 0)
continue;

   /* check to see if this frame forms a valid loop */
   if (verts) {
sp = &board[vertices[0].o_intersect];
658#ifdef DEBUG
if (sp->s_occ != EMPTY2) {
    snprintf(fmtbuf, sizeof fmtbuf,
	"loop: %c %s", "BW"[curcolor],
	stoc(sp - board));
    dlog(fmtbuf);
    whatsup(0);
}
666#endif
/*
 * It is a valid loop if the intersection spot
 * of the frame we are trying to attach is one
 * of the completion spots of the combostr
 * we are trying to attach the frame to.
 */
for (nep = sp->s_empty; nep; nep = nep->e_next) {
    if (nep->e_combo == cbp)
	goto fnd;
    if (nep->e_combo->c_nframes < cbp->c_nframes)
	break;
}
/* frame overlaps but not at a valid spot */
continue;
   fnd:
;
   }

   /* compute the first half of the combo value */
   c = cbp->c_combo.c.a + ocb.c.a - verts - 3;
   if (c > 4)
continue;

   /* compute the second half of the combo value */
   n = ep->e_fval.c.a + ep->e_fval.c.b - 1;
   if (baseB < n)
n = baseB;

   /* make a new combo! */
   ncbp = malloc(sizeof(struct combostr) +
(cbp->c_nframes + 1) * sizeof(struct combostr *));
   if (ncbp == (struct combostr *)NULL((void *)0))
qlog("Memory allocation failure.");
   scbpp = (struct combostr **)(ncbp + 1);
   if (sortcombo(scbpp, (struct combostr **)(cbp + 1), ocbp)) {
free(ncbp);
continue;
   }
   combocnt++;

   ncbp->c_combo.c.a = c;
   ncbp->c_combo.c.b = n;
   ncbp->c_link[0] = cbp;
   ncbp->c_link[1] = ocbp;
   ncbp->c_linkv[1].s = ocb.s;
   ncbp->c_voff[1] = off;
   ncbp->c_vertex = osp - board;
   ncbp->c_nframes = cbp->c_nframes + 1;
   ncbp->c_flg = ocb.c.b ? C_OPEN_10x02 : 0;
   ncbp->c_frameindex = ep->e_frameindex;
   /*
    * Update the completion spot mask of the frame we
    * are attaching 'ocbp' to so the intersection isn't
    * listed twice.
    */
   ncbp->c_framecnt[0] = ep->e_framecnt;
   ncbp->c_emask[0] = ep->e_emask;
   if (verts) {
ncbp->c_flg |= C_LOOP0x04;
ncbp->c_dir = vertices[0].o_frameindex;
ncbp->c_framecnt[1] = fcnt - 1;
if (ncbp->c_framecnt[1]) {
    n = (vertices[0].o_intersect - ocbp->c_vertex) /
	dd[ocbp->c_dir];
    ncbp->c_emask[1] = emask & ~(1 << n);
} else
    ncbp->c_emask[1] = 0;
ncbp->c_voff[0] = vertices[0].o_off;
   } else {
ncbp->c_dir = 0;
ncbp->c_framecnt[1] = fcnt;
ncbp->c_emask[1] = emask;
ncbp->c_voff[0] = ep->e_off;
   }

   if (c == 1 && debug > 1) {
snprintf(fmtbuf, sizeof fmtbuf,
    "%c v%d i%d d%d c %d %d m %x %x o %d %d",
    "bw"[curcolor], verts, ncbp->c_frameindex, ncbp->c_dir,
    ncbp->c_framecnt[0], ncbp->c_framecnt[1],
    ncbp->c_emask[0], ncbp->c_emask[1],
    ncbp->c_voff[0], ncbp->c_voff[1]);
dlog(fmtbuf);
printcombo(ncbp, fmtbuf, sizeof fmtbuf);
dlog(fmtbuf);
   }
   if (c > 1) {
/* record the empty spots that will complete this combo */
makeempty(ncbp);
combolen++;
   } else {
/* update board values */
updatecombo(ncbp, curcolor);
   }
761#ifdef DEBUG
   if (c == 1 && debug > 1 || debug > 4) {
markcombo(ncbp);
bdisp();
whatsup(0);
clearcombo(ncbp, 0);
   }
768#endif /* DEBUG */
}
770}

772#define MAXDEPTH100	100
773struct elist	einfo[MAXDEPTH100];
774struct combostr	*ecombo[MAXDEPTH100];	/* separate from elist to save space */

776/*
* Add the combostr 'ocbp' to the empty spots list for each empty spot
* in 'ocbp' that will complete the combo.
*/
780void
781makeempty(struct combostr *ocbp)
782{
struct combostr *cbp, **cbpp;
struct elist *ep, *nep;
struct spotstr *sp;
int s, d, m, emask, i;
int nframes;

if (debug > 2) {
snprintf(fmtbuf, sizeof fmtbuf, "E%c ", "bw"[curcolor]);
printcombo(ocbp, fmtbuf + 3, sizeof fmtbuf - 3);
dlog(fmtbuf);
}

/* should never happen but check anyway */
if ((nframes = ocbp->c_nframes) >= MAXDEPTH100)
return;

/*
* The lower level combo can be pointed to by more than one
* higher level 'struct combostr' so we can't modify the
* lower level. Therefore, higher level combos store the
* real mask of the lower level frame in c_emask[0] and the
* frame number in c_frameindex.
*
* First we traverse the tree from top to bottom and save the
* connection info. Then we traverse the tree from bottom to
* top overwriting lower levels with the newer emask information.
*/
ep = &einfo[nframes];
cbpp = &ecombo[nframes];
for (cbp = ocbp; cbp->c_link[1] != NULL((void *)0); cbp = cbp->c_link[0]) {
ep--;
ep->e_combo = cbp;
*--cbpp = cbp->c_link[1];
ep->e_off = cbp->c_voff[1];
ep->e_frameindex = cbp->c_frameindex;
ep->e_fval.s = cbp->c_linkv[1].s;
ep->e_framecnt = cbp->c_framecnt[1];
ep->e_emask = cbp->c_emask[1];
}
cbp = ep->e_combo;
ep--;
ep->e_combo = cbp;
*--cbpp = cbp->c_link[0];
ep->e_off = cbp->c_voff[0];
ep->e_frameindex = 0;
ep->e_fval.s = cbp->c_linkv[0].s;
ep->e_framecnt = cbp->c_framecnt[0];
ep->e_emask = cbp->c_emask[0];

/* now update the emask info */
s = 0;
for (i = 2, ep += 2; i < nframes; i++, ep++) {
cbp = ep->e_combo;
nep = &einfo[ep->e_frameindex];
nep->e_framecnt = cbp->c_framecnt[0];
nep->e_emask = cbp->c_emask[0];

if (cbp->c_flg & C_LOOP0x04) {
	s++;
	/*
	 * Account for the fact that this frame connects
	 * to a previous one (thus forming a loop).
	 */
	nep = &einfo[cbp->c_dir];
	if (--nep->e_framecnt)
		nep->e_emask &= ~(1 << cbp->c_voff[0]);
	else
		nep->e_emask = 0;
}
}

/*
* We only need to update the emask values of "complete" loops
* to include the intersection spots.
*/
if (s && ocbp->c_combo.c.a == 2) {
/* process loops from the top down */
ep = &einfo[nframes];
do {
	ep--;
	cbp = ep->e_combo;
	if (!(cbp->c_flg & C_LOOP0x04))
		continue;

	/*
	 * Update the emask values to include the
	 * intersection spots.
	 */
	nep = &einfo[cbp->c_dir];
	nep->e_framecnt = 1;
	nep->e_emask = 1 << cbp->c_voff[0];
	ep->e_framecnt = 1;
	ep->e_emask = 1 << ep->e_off;
	ep = &einfo[ep->e_frameindex];
	do {
		ep->e_framecnt = 1;
		ep->e_emask = 1 << ep->e_off;
		ep = &einfo[ep->e_frameindex];
	} while (ep > nep);
} while (ep != einfo);
}

/* check all the frames for completion spots */
for (i = 0, ep = einfo, cbpp = ecombo; i < nframes; i++, ep++, cbpp++) {
/* skip this frame if there are no incomplete spots in it */
if ((emask = ep->e_emask) == 0)
	continue;
cbp = *cbpp;
sp = &board[cbp->c_vertex];
d = dd[cbp->c_dir];
for (s = 0, m = 1; s < 5; s++, sp += d, m <<= 1) {
	if (sp->s_occ != EMPTY2 || !(emask & m))
		continue;

	/* add the combo to the list of empty spots */
	nep = malloc(sizeof(struct elist));
	if (nep == (struct elist *)NULL((void *)0))
		qlog("Memory allocation failure.");
	nep->e_combo = ocbp;
	nep->e_off = s;
	nep->e_frameindex = i;
	if (ep->e_framecnt > 1) {
		nep->e_framecnt = ep->e_framecnt - 1;
		nep->e_emask = emask & ~m;
	} else {
		nep->e_framecnt = 0;
		nep->e_emask = 0;
	}
	nep->e_fval.s = ep->e_fval.s;
	if (debug > 2) {
		snprintf(fmtbuf, sizeof fmtbuf,
			"e %s o%d i%d c%d m%x %x",
			stoc(sp - board),
			nep->e_off,
			nep->e_frameindex,
			nep->e_framecnt,
			nep->e_emask,
			nep->e_fval.s);
		dlog(fmtbuf);
	}

	/* sort by the number of frames in the combo */
	nep->e_next = sp->s_nempty;
	sp->s_nempty = nep;
	elistcnt++;
}
}
930}

932/*
* Update the board value based on the combostr.
* This is called only if 'cbp' is a <1,x> combo.
* We handle things differently depending on whether the next move
* would be trying to "complete" the combo or trying to block it.
*/
938void
939updatecombo(struct combostr *cbp, int color)
940{
struct spotstr *sp;
struct combostr *tcbp;
int i, d;
int nframes, s, flg = 0;
union comboval cb;

/* save the top level value for the whole combo */
cb.c.a = cbp->c_combo.c.a;
nframes = cbp->c_nframes;

if (color != nextcolor)
memset(tmpmap, 0, sizeof(tmpmap));

for (; (tcbp = cbp->c_link[1]) != NULL((void *)0); cbp = cbp->c_link[0]) {
flg = cbp->c_flg;
cb.c.b = cbp->c_combo.c.b;
if (color == nextcolor) {
	/* update the board value for the vertex */
	sp = &board[cbp->c_vertex];
	sp->s_nforce[color]++;
	if (cb.s <= sp->s_combo[color].s) {
		if (cb.s != sp->s_combo[color].s) {
			sp->s_combo[color].s = cb.s;
			sp->s_level[color] = nframes;
		} else if (nframes < sp->s_level[color])
			sp->s_level[color] = nframes;
	}
} else {
	/* update the board values for each spot in frame */
	sp = &board[s = tcbp->c_vertex];
	d = dd[tcbp->c_dir];
	i = (flg & C_OPEN_10x02) ? 6 : 5;
	for (; --i >= 0; sp += d, s += d) {
		if (sp->s_occ != EMPTY2)
			continue;
		sp->s_nforce[color]++;
		if (cb.s <= sp->s_combo[color].s) {
			if (cb.s != sp->s_combo[color].s) {
				sp->s_combo[color].s = cb.s;
				sp->s_level[color] = nframes;
			} else if (nframes < sp->s_level[color])
				sp->s_level[color] = nframes;
		}
		BIT_SET(tmpmap, s)((tmpmap)[(s)/(sizeof(int) * 8)] |= (1 << ((s) % (sizeof
(int) * 8))));
	}
}

/* mark the frame as being part of a <1,x> combo */
board[tcbp->c_vertex].s_flg |= FFLAG0x000100 << tcbp->c_dir;
}

if (color != nextcolor) {
/* update the board values for each spot in frame */
sp = &board[s = cbp->c_vertex];
d = dd[cbp->c_dir];
i = (flg & C_OPEN_00x01) ? 6 : 5;
for (; --i >= 0; sp += d, s += d) {
	if (sp->s_occ != EMPTY2)
		continue;
	sp->s_nforce[color]++;
	if (cb.s <= sp->s_combo[color].s) {
		if (cb.s != sp->s_combo[color].s) {
			sp->s_combo[color].s = cb.s;
			sp->s_level[color] = nframes;
		} else if (nframes < sp->s_level[color])
			sp->s_level[color] = nframes;
	}
	BIT_SET(tmpmap, s)((tmpmap)[(s)/(sizeof(int) * 8)] |= (1 << ((s) % (sizeof
(int) * 8))));
}
if (nforce == 0)
	memcpy(forcemap, tmpmap, sizeof(tmpmap));
else {
	for (i = 0; i < MAPSZ(((19 +2)*(19 +1)+1) / (sizeof(int) * 8)); i++)
		forcemap[i] &= tmpmap[i];
}
nforce++;
}

/* mark the frame as being part of a <1,x> combo */
board[cbp->c_vertex].s_flg |= FFLAG0x000100 << cbp->c_dir;
1021}

1023/*
* Add combo to the end of the list.
*/
1026void
1027appendcombo(struct combostr *cbp)
1028{
struct combostr *pcbp, *ncbp;

combolen++;
ncbp = sortcombos;
if (ncbp == (struct combostr *)0) {
sortcombos = cbp;
cbp->c_next = cbp;
cbp->c_prev = cbp;
return;
}
pcbp = ncbp->c_prev;
cbp->c_next = ncbp;
cbp->c_prev = pcbp;
ncbp->c_prev = cbp;
pcbp->c_next = cbp;
1044}

1046/*
* Return zero if it is valid to combine frame 'fcbp' with the frames
* in 'cbp' and forms a linked chain of frames (i.e., a tree; no loops).
* Return positive if combining frame 'fcbp' to the frames in 'cbp'
* would form some kind of valid loop. Also return the intersection spots
* in 'vertices[]' beside the known intersection at spot 'osp'.
* Return -1 if 'fcbp' should not be combined with 'cbp'.
* 's' is the combo value for frame 'fcpb'.
*/
1055int
1056checkframes(struct combostr *cbp, struct combostr *fcbp, struct spotstr *osp,
  int s, struct ovlp_info *vertices)
1058{
struct combostr *tcbp, *lcbp = NULL((void *)0);
5
←
'lcbp' initialized to a null pointer value→
int i, n, mask, flg, verts, idx, fcnt;
union comboval cb;
u_char *str;
short *ip;

cb.s = s;
fcnt = cb.c.a - 2;
verts = 0;
flg = 0;
idx = cbp->c_nframes;
n = (fcbp - frames) * FAREA(19*(19 -4) + (19 -4)*(19 -4) + 19*(19 -4) + (19 -4)*(19 -4));
str = &overlap[n];
ip = &intersect[n];
/*
* i == which overlap bit to test based on whether 'fcbp' is
* an open or closed frame.
*/
i = cb.c.b ? 2 : 0;
6
←
Assuming field 'b' is not equal to 0→
7
←
'?' condition is true→
for (; (tcbp = cbp->c_link[1]) != NULL((void *)0); lcbp = cbp, cbp = cbp->c_link[0]) {
8
←
Assuming the condition is false→
9
←
Loop condition is false. Execution continues on line 1132→
if (tcbp == fcbp)
	return (-1);	/* fcbp is already included */

/* check for intersection of 'tcbp' with 'fcbp' */
idx--;
mask = str[tcbp - frames];
flg = cbp->c_flg;
n = i + ((flg & C_OPEN_10x02) != 0);
if (mask & (1 << n)) {
	/*
	 * The two frames are not independent if they
	 * both lie in the same line and intersect at
	 * more than one point.
	 */
	if (tcbp->c_dir == fcbp->c_dir && (mask & (0x10 << n)))
		return (-1);
	/*
	 * If this is not the spot we are attaching
	 * 'fcbp' to and it is a reasonable intersection
	 * spot, then there might be a loop.
	 */
	n = ip[tcbp - frames];
	if (osp != &board[n]) {
		/* check to see if this is a valid loop */
		if (verts)
			return (-1);
		if (fcnt == 0 || cbp->c_framecnt[1] == 0)
			return (-1);
		/*
		 * Check to be sure the intersection is not
		 * one of the end points if it is an open
		 * ended frame.
		 */
		if ((flg & C_OPEN_10x02) &&
		    (n == tcbp->c_vertex ||
		     n == tcbp->c_vertex + 5 * dd[tcbp->c_dir]))
			return (-1);	/* invalid overlap */
		if (cb.c.b &&
		    (n == fcbp->c_vertex ||
		     n == fcbp->c_vertex + 5 * dd[fcbp->c_dir]))
			return (-1);	/* invalid overlap */

		vertices->o_intersect = n;
		vertices->o_fcombo = cbp;
		vertices->o_link = 1;
		vertices->o_off = (n - tcbp->c_vertex) /
			dd[tcbp->c_dir];
		vertices->o_frameindex = idx;
		verts++;
	}
}
n = i + ((flg & C_OPEN_00x01) != 0);
}
if (cbp == fcbp)
10
←
Assuming 'cbp' is not equal to 'fcbp'→
11
←
Taking false branch→
return (-1);	/* fcbp is already included */

/* check for intersection of 'cbp' with 'fcbp' */
mask = str[cbp - frames];
if (mask & (1 << n)) {
12
←
Assuming the condition is true→
13
←
Taking true branch→
/*
 * The two frames are not independent if they
 * both lie in the same line and intersect at
 * more than one point.
 */
if (cbp->c_dir == fcbp->c_dir && (mask & (0x10 << n)))
14
←
Assuming 'cbp->c_dir' is not equal to 'fcbp->c_dir'→
	return (-1);
/*
 * If this is not the spot we are attaching
 * 'fcbp' to and it is a reasonable intersection
 * spot, then there might be a loop.
 */
n = ip[cbp - frames];
if (osp != &board[n]) {
15
←
Assuming the condition is true→
16
←
Taking true branch→
	/* check to see if this is a valid loop */
	if (verts16.1
'verts' is 0
)
17
←
Taking false branch→
		return (-1);
	if (fcnt == 0 || lcbp->c_framecnt[0] == 0)
18
←
Assuming 'fcnt' is not equal to 0→
19
←
Array access (via field 'c_framecnt') results in a null pointer dereference
		return (-1);
	/*
	 * Check to be sure the intersection is not
	 * one of the end points if it is an open
	 * ended frame.
	 */
	if ((flg & C_OPEN_00x01) &&
	    (n == cbp->c_vertex ||
	     n == cbp->c_vertex + 5 * dd[cbp->c_dir]))
		return (-1);	/* invalid overlap */
	if (cb.c.b &&
	    (n == fcbp->c_vertex ||
	     n == fcbp->c_vertex + 5 * dd[fcbp->c_dir]))
		return (-1);	/* invalid overlap */

	vertices->o_intersect = n;
	vertices->o_fcombo = lcbp;
	vertices->o_link = 0;
	vertices->o_off = (n - cbp->c_vertex) /
		dd[cbp->c_dir];
	vertices->o_frameindex = 0;
	verts++;
}
}
return (verts);
1181}

1183/*
* Merge sort the frame 'fcbp' and the sorted list of frames 'cbpp' and
* store the result in 'scbpp'. 'curlevel' is the size of the 'cbpp' array.
* Return true if this list of frames is already in the hash list.
* Otherwise, add the new combo to the hash list.
*/
1189int
1190sortcombo(struct combostr **scbpp, struct combostr **cbpp,
  struct combostr *fcbp)
1192{
struct combostr **spp, **cpp;
struct combostr *cbp, *ecbp;
int n, inx;

1197#ifdef DEBUG
if (debug > 3) {
char *str;

snprintf(fmtbuf, sizeof fmtbuf,
	"sortc: %s%c l%d", stoc(fcbp->c_vertex),
	pdir[fcbp->c_dir], curlevel);
dlog(fmtbuf);
str = fmtbuf;
for (cpp = cbpp; cpp < cbpp + curlevel; cpp++) {
	snprintf(str, fmtbuf + sizeof fmtbuf - str,
		" %s%c", stoc((*cpp)->c_vertex),
		pdir[(*cpp)->c_dir]);
	str += strlen(str);
}
dlog(fmtbuf);
}
1214#endif /* DEBUG */

/* first build the new sorted list */
n = curlevel + 1;
spp = scbpp + n;
cpp = cbpp + curlevel;
do {
cpp--;
if (fcbp > *cpp) {
	*--spp = fcbp;
	do
		*--spp = *cpp;
	while (cpp-- != cbpp);
	goto inserted;
}
*--spp = *cpp;
} while (cpp != cbpp);
*--spp = fcbp;
1232inserted:

/* now check to see if this list of frames has already been seen */
cbp = hashcombos[inx = *scbpp - frames];
if (cbp == (struct combostr *)0) {
/*
 * Easy case, this list hasn't been seen.
 * Add it to the hash list.
 */
fcbp = (struct combostr *)
	((char *)scbpp - sizeof(struct combostr));
hashcombos[inx] = fcbp;
fcbp->c_next = fcbp->c_prev = fcbp;
return (0);
}
ecbp = cbp;
do {
cbpp = (struct combostr **)(cbp + 1);
cpp = cbpp + n;
spp = scbpp + n;
cbpp++;	/* first frame is always the same */
do {
	if (*--spp != *--cpp)
		goto next;
} while (cpp != cbpp);
/* we found a match */
1258#ifdef DEBUG
if (debug > 3) {
	char *str;

	snprintf(fmtbuf, sizeof fmtbuf, "sort1: n%d", n);
	dlog(fmtbuf);
	str = fmtbuf;
	for (cpp = scbpp; cpp < scbpp + n; cpp++) {
		snprintf(str, fmtbuf + sizeof fmtbuf - str,
			" %s%c", stoc((*cpp)->c_vertex),
			pdir[(*cpp)->c_dir]);
		str += strlen(str);
	}
	dlog(fmtbuf);
	printcombo(cbp, fmtbuf, sizeof fmtbuf);
	dlog(fmtbuf);
	str = fmtbuf;
	cbpp--;
	for (cpp = cbpp; cpp < cbpp + n; cpp++) {
		snprintf(str, fmtbuf + sizeof fmtbuf - str,
			" %s%c", stoc((*cpp)->c_vertex),
			pdir[(*cpp)->c_dir]);
		str += strlen(str);
	}
	dlog(fmtbuf);
}
1284#endif /* DEBUG */
return (1);
next:
;
} while ((cbp = cbp->c_next) != ecbp);
/*
* This list of frames hasn't been seen.
* Add it to the hash list.
*/
ecbp = cbp->c_prev;
fcbp = (struct combostr *)((char *)scbpp - sizeof(struct combostr));
fcbp->c_next = cbp;
fcbp->c_prev = ecbp;
cbp->c_prev = fcbp;
ecbp->c_next = fcbp;
return (0);
1300}

1302/*
* Print the combo into string 'str'.
*/
1305void
1306printcombo(struct combostr *cbp, char *str, size_t strl)
1307{
char *basestr = str;
struct combostr *tcbp;

snprintf(str, strl, "%x/%d", cbp->c_combo.s, cbp->c_nframes);
str += strlen(str);
for (; (tcbp = cbp->c_link[1]) != NULL((void *)0); cbp = cbp->c_link[0]) {
snprintf(str, basestr + strl - str,
	" %s%c%x", stoc(tcbp->c_vertex), pdir[tcbp->c_dir],
	cbp->c_flg);
str += strlen(str);
}
snprintf(str, basestr + strl - str,
" %s%c", stoc(cbp->c_vertex), pdir[cbp->c_dir]);
1321}

1323#ifdef DEBUG
1324void
1325markcombo(struct combostr *ocbp)
1326{
struct combostr *cbp, *tcbp, **cbpp;
struct elist *ep, *nep, **epp;
struct spotstr *sp;
int s, d, m, i;
int nframes;
int r, n, flg, cmask, omask;

/* should never happen but check anyway */
if ((nframes = ocbp->c_nframes) >= MAXDEPTH100)
return;

/*
* The lower level combo can be pointed to by more than one
* higher level 'struct combostr' so we can't modify the
* lower level. Therefore, higher level combos store the
* real mask of the lower level frame in c_emask[0] and the
* frame number in c_frameindex.
*
* First we traverse the tree from top to bottom and save the
* connection info. Then we traverse the tree from bottom to
* top overwriting lower levels with the newer emask information.
*/
ep = &einfo[nframes];
cbpp = &ecombo[nframes];
for (cbp = ocbp; tcbp = cbp->c_link[1]; cbp = cbp->c_link[0]) {
ep--;
ep->e_combo = cbp;
*--cbpp = cbp->c_link[1];
ep->e_off = cbp->c_voff[1];
ep->e_frameindex = cbp->c_frameindex;
ep->e_fval.s = cbp->c_linkv[1].s;
ep->e_framecnt = cbp->c_framecnt[1];
ep->e_emask = cbp->c_emask[1];
}
cbp = ep->e_combo;
ep--;
ep->e_combo = cbp;
*--cbpp = cbp->c_link[0];
ep->e_off = cbp->c_voff[0];
ep->e_frameindex = 0;
ep->e_fval.s = cbp->c_linkv[0].s;
ep->e_framecnt = cbp->c_framecnt[0];
ep->e_emask = cbp->c_emask[0];

/* now update the emask info */
s = 0;
for (i = 2, ep += 2; i < nframes; i++, ep++) {
cbp = ep->e_combo;
nep = &einfo[ep->e_frameindex];
nep->e_framecnt = cbp->c_framecnt[0];
nep->e_emask = cbp->c_emask[0];

if (cbp->c_flg & C_LOOP0x04) {
	s++;
	/*
	 * Account for the fact that this frame connects
	 * to a previous one (thus forming a loop).
	 */
	nep = &einfo[cbp->c_dir];
	if (--nep->e_framecnt)
		nep->e_emask &= ~(1 << cbp->c_voff[0]);
	else
		nep->e_emask = 0;
}
}

/*
* We only need to update the emask values of "complete" loops
* to include the intersection spots.
*/
if (s && ocbp->c_combo.c.a == 2) {
/* process loops from the top down */
ep = &einfo[nframes];
do {
	ep--;
	cbp = ep->e_combo;
	if (!(cbp->c_flg & C_LOOP0x04))
		continue;

	/*
	 * Update the emask values to include the
	 * intersection spots.
	 */
	nep = &einfo[cbp->c_dir];
	nep->e_framecnt = 1;
	nep->e_emask = 1 << cbp->c_voff[0];
	ep->e_framecnt = 1;
	ep->e_emask = 1 << ep->e_off;
	ep = &einfo[ep->e_frameindex];
	do {
		ep->e_framecnt = 1;
		ep->e_emask = 1 << ep->e_off;
		ep = &einfo[ep->e_frameindex];
	} while (ep > nep);
} while (ep != einfo);
}

/* mark all the frames with the completion spots */
for (i = 0, ep = einfo, cbpp = ecombo; i < nframes; i++, ep++, cbpp++) {
m = ep->e_emask;
cbp = *cbpp;
sp = &board[cbp->c_vertex];
d = dd[s = cbp->c_dir];
cmask = CFLAG0x000001 << s;
omask = (IFLAG0x000010 | CFLAG0x000001) << s;
s = ep->e_fval.c.b ? 6 : 5;
for (; --s >= 0; sp += d, m >>= 1)
	sp->s_flg |= (m & 1) ? omask : cmask;
}
1436}

1438void
1439clearcombo(struct combostr *cbp, int open)
1440{
struct spotstr *sp;
struct combostr *tcbp;
int d, n, mask;

for (; tcbp = cbp->c_link[1]; cbp = cbp->c_link[0]) {
clearcombo(tcbp, cbp->c_flg & C_OPEN_10x02);
open = cbp->c_flg & C_OPEN_00x01;
}
sp = &board[cbp->c_vertex];
d = dd[n = cbp->c_dir];
mask = ~((IFLAG0x000010 | CFLAG0x000001) << n);
n = open ? 6 : 5;
for (; --n >= 0; sp += d)
sp->s_flg &= mask;
1455}

1457int
1458list_eq(struct combostr **scbpp, struct combostr **cbpp, int n)
1459{
struct combostr **spp, **cpp;

spp = scbpp + n;
cpp = cbpp + n;
do {
if (*--spp != *--cpp)
	return (0);
} while (cpp != cbpp);
/* we found a match */
return (1);
1470}
1471#endif /* DEBUG */