void common_init_node(node_t * n)
{
struct fontinfo fi;
char *str;
ND_width(n) =
late_double(n, N_width, DEFAULT_NODEWIDTH, MIN_NODEWIDTH);
ND_height(n) =
late_double(n, N_height, DEFAULT_NODEHEIGHT, MIN_NODEHEIGHT);
ND_shape(n) =
bind_shape(late_nnstring(n, N_shape, DEFAULT_NODESHAPE), n);
str = agxget(n, N_label);
fi.fontsize = late_double(n, N_fontsize, DEFAULT_FONTSIZE, MIN_FONTSIZE);
fi.fontname = late_nnstring(n, N_fontname, DEFAULT_FONTNAME);
fi.fontcolor = late_nnstring(n, N_fontcolor, DEFAULT_COLOR);
ND_label(n) = make_label((void*)n, str,
((aghtmlstr(str) ? LT_HTML : LT_NONE) | ( (shapeOf(n) == SH_RECORD) ? LT_RECD : LT_NONE)),
fi.fontsize, fi.fontname, fi.fontcolor);
if (N_xlabel && (str = agxget(n, N_xlabel)) && (str[0])) {
ND_xlabel(n) = make_label((void*)n, str, (aghtmlstr(str) ? LT_HTML : LT_NONE),
fi.fontsize, fi.fontname, fi.fontcolor);
GD_has_labels(agraphof(n)) |= NODE_XLABEL;
}
ND_showboxes(n) = late_int(n, N_showboxes, 0, 0);
ND_shape(n)->fns->initfn(n);
}
void
dot_sameports (graph_t* g)
/* merge edge ports in G */
{
node_t *n;
edge_t *e;
char *id;
same_t same[MAXSAME];
int i;
E_samehead = agfindattr(g->proto->e,"samehead");
E_sametail = agfindattr(g->proto->e,"sametail");
if (!(E_samehead || E_sametail)) return;
for (n = agfstnode(g); n; n = agnxtnode(g,n)) {
n_same = 0;
for (e = agfstedge(g,n); e; e = agnxtedge(g,e,n)) {
if (e->head==n && E_samehead &&
(id = agxget (e, E_samehead->index))[0])
sameedge (same, n, e, id);
else if (e->tail==n && E_sametail &&
(id = agxget (e, E_sametail->index))[0])
sameedge (same, n, e, id);
}
for (i=0; i<n_same; i++) {
if (same[i].l.size>1) sameport (n, &same[i].l, same[i].arr_len);
free_list(same[i].l);
/* I sure hope I don't need to free the char* id */
}
}
}
static int
late_quadtree_scheme (graph_t* g, Agsym_t* sym, int dflt)
{
char* s;
int v;
int rv;
if (!sym) return dflt;
#ifdef WITH_CGRAPH
s = agxget (g, sym);
#else
s = agxget (g, sym->index);
#endif
if (isdigit(*s)) {
if ((v = atoi (s)) <= QUAD_TREE_FAST && v >= QUAD_TREE_NONE){
rv = v;
} else {
rv = dflt;
}
} else if (isalpha(*s)) {
if (!strcasecmp(s, "none") || !strcasecmp(s, "false") ){
rv = QUAD_TREE_NONE;
} else if (!strcasecmp(s, "normal") || !strcasecmp(s, "true") || !strcasecmp(s, "yes")){
rv = QUAD_TREE_NORMAL;
} else if (!strcasecmp(s, "fast")){
rv = QUAD_TREE_FAST;
} else {
rv = dflt;
}
} else {
rv = dflt;
}
return rv;
}
static void write_diffattr(FILE * fp, int indent, void *obj, void *par,
Agdict_t * dict)
{
Agsym_t *a;
int i;
char *p, *q;
int cnt = 0;
for (i = 0; i < dtsize(dict->dict); i++) {
a = dict->list[i];
if (a->printed == FALSE)
continue;
p = agxget(obj, a->index);
if (par)
q = agxget(par, a->index);
else
q = a->value;
if (strcmp(p, q)) {
if (cnt++ == 0) {
tabover(fp, indent);
agputs(dict->name, fp);
agputs(" [", fp);
} else {
agputs(",\n", fp);
tabover(fp, indent + 1);
}
agputs(agcanonical(a->name), fp);
agputc('=', fp);
agputs(agcanonical(p), fp);
}
}
if (cnt > 0)
agputs("];\n", fp);
}
static void write_diffattr(FILE * fp, int indent, void *obj, void *par,
Agdict_t * dict)
{
Agsym_t *a;
int i;
char *p, *q;
int cnt = 0;
for (i = 0; i < dtsize(dict->dict); i++) {
a = dict->list[i];
if (a->printed == FALSE)
continue;
p = agxget(obj, a->index);
if (par)
q = agxget(par, a->index);
else
q = a->value;
if (strcmp(p, q)) {
if (cnt++ == 0) {
tabover(fp, indent);
fprintf(fp, "%s [", dict->name);
} else {
fprintf(fp, ",\n");
tabover(fp, indent + 1);
}
fprintf(fp, "%s=", agcanonical(a->name));
fprintf(fp, "%s", agcanonical(p));
}
}
if (cnt > 0)
fprintf(fp, "];\n");
}
int user_pos(attrsym_t * posptr, attrsym_t * pinptr, node_t * np, int nG)
{
double *pvec;
char *p, c;
double z;
if (posptr == NULL)
return FALSE;
pvec = ND_pos(np);
p = agxget(np, posptr->index);
if (p[0]) {
c = '\0';
if ((Ndim >= 3) &&
(sscanf(p, "%lf,%lf,%lf%c", pvec, pvec+1, pvec+2, &c) >= 3)){
ND_pinned(np) = P_SET;
if (PSinputscale > 0.0) {
int i;
for (i = 0; i < Ndim; i++)
pvec[i] = pvec[i] / PSinputscale;
}
if (Ndim > 3)
jitter_d(np, nG, 3);
if ((c == '!')
|| (pinptr && mapbool(agxget(np, pinptr->index))))
ND_pinned(np) = P_PIN;
return TRUE;
}
else if (sscanf(p, "%lf,%lf%c", pvec, pvec + 1, &c) >= 2) {
ND_pinned(np) = P_SET;
if (PSinputscale > 0.0) {
int i;
for (i = 0; i < Ndim; i++)
pvec[i] = pvec[i] / PSinputscale;
}
if (Ndim > 2) {
if (N_z && (p = agxget(np, N_z->index)) &&
(sscanf(p,"%lf",&z) == 1)) {
if (PSinputscale > 0.0) {
pvec[2] = z / PSinputscale;
}
else
pvec[2] = z;
jitter_d(np, nG, 3);
}
else
jitter3d(np, nG);
}
if ((c == '!')
|| (pinptr && mapbool(agxget(np, pinptr->index))))
ND_pinned(np) = P_PIN;
return TRUE;
} else
agerr(AGERR, "node %s, position %s, expected two doubles\n",
np->name, p);
}
return FALSE;
}
static void transform(Agraph_t * g)
{
Agnode_t *n;
Agedge_t *e;
char *str;
Agsym_t *m_ix, *s_ix;
int cnt, d;
m_ix = bindedgeattr(g, "minlen");
s_ix = bindedgeattr(g, "style");
for (n = agfstnode(g); n; n = agnxtnode(g, n)) {
d = myindegree(n) + myoutdegree(n);
if (d == 0) {
if (ChainLimit < 1)
continue;
if (ChainNode) {
e = agedge(g, ChainNode, n, "", TRUE);
agxset(e, s_ix, "invis");
ChainSize++;
if (ChainSize < ChainLimit)
ChainNode = n;
else {
ChainNode = NULL;
ChainSize = 0;
}
} else
ChainNode = n;
} else if (d > 1) {
if (MaxMinlen < 1)
continue;
cnt = 0;
for (e = agfstin(g, n); e; e = agnxtin(g, e)) {
if (isleaf(agtail(e))) {
str = agxget(e, m_ix);
if (str[0] == 0) {
adjustlen(e, m_ix, (cnt % MaxMinlen) + 1);
cnt++;
}
}
}
cnt = 0;
for (e = agfstout(g, n); e; e = agnxtout(g, e)) {
if (isleaf(e->node) || (Do_fans && ischainnode(e->node))) {
str = agxget(e, m_ix);
if (str[0] == 0)
adjustlen(e, m_ix, (cnt % MaxMinlen) + 1);
cnt++;
}
}
}
}
}
static void addRevEdge(Agraph_t * g, Agedge_t * e)
{
Agsym_t* sym;
Agedge_t* f = agedge (g, aghead(e), agtail(e), agnameof(e), 1);
agcopyattr (;
sym = agattr (g, AGEDGE, TAILPORT_ID, 0);
if (sym) agsafeset (f, HEADPORT_ID, agxget (e, sym), "");
sym = agattr (g, AGEDGE, HEADPORT_ID, 0);
if (sym) agsafeset (f, TAILPORT_ID, agxget (e, sym), "");
}
static int
late_smooth (graph_t* g, Agsym_t* sym, int dflt)
{
char* s;
int v;
int rv;
if (!sym) return dflt;
#ifdef WITH_CGRAPH
s = agxget (g, sym);
#else
s = agxget (g, sym->index);
#endif
if (isdigit(*s)) {
#if (HAVE_GTS || HAVE_TRIANGLE)
if ((v = atoi (s)) <= SMOOTHING_RNG)
#else
if ((v = atoi (s)) <= SMOOTHING_SPRING)
#endif
rv = v;
else
rv = dflt;
}
else if (isalpha(*s)) {
if (!strcasecmp(s, "avg_dist"))
rv = SMOOTHING_STRESS_MAJORIZATION_AVG_DIST;
else if (!strcasecmp(s, "graph_dist"))
rv = SMOOTHING_STRESS_MAJORIZATION_GRAPH_DIST;
else if (!strcasecmp(s, "none"))
rv = SMOOTHING_NONE;
else if (!strcasecmp(s, "power_dist"))
rv = SMOOTHING_STRESS_MAJORIZATION_POWER_DIST;
#if (HAVE_GTS || HAVE_TRIANGLE)
else if (!strcasecmp(s, "rng"))
rv = SMOOTHING_RNG;
#endif
else if (!strcasecmp(s, "spring"))
rv = SMOOTHING_SPRING;
#if (HAVE_GTS || HAVE_TRIANGLE)
else if (!strcasecmp(s, "triangle"))
rv = SMOOTHING_TRIANGLE;
#endif
else
rv = dflt;
}
else
rv = dflt;
return rv;
}
boolean late_bool(void *obj, attrsym_t * attr, int def)
{
if (attr == NULL)
return def;
return mapbool(agxget(obj, attr));
}
/* mapN:
* Convert cluster nodes back to ordinary nodes
* If n is already ordinary, return it.
* Otherwise, we know node's name is "__i:xxx"
* where i is some number and xxx is the nodes's original name.
* Create new node of name xxx if it doesn't exist and add n to clg
* for later deletion.
*/
static node_t *mapN(node_t * n, graph_t * clg)
{
node_t *nn;
char *name;
graph_t *g = agraphof(n);
Agsym_t *sym;
if (!(IS_CLUST_NODE(n)))
return n;
agsubnode(clg, n, 1);
name = strchr(agnameof(n), ':');
assert(name);
name++;
if ((nn = agfindnode(g, name)))
return nn;
nn = agnode(g, name, 1);
agbindrec(nn, "Agnodeinfo_t", sizeof(Agnodeinfo_t), TRUE);
/* Set all attributes to default */
for (sym = agnxtattr(g, AGNODE, NULL); sym; (sym = agnxtattr(g, AGNODE, sym))) {
if (agxget(nn, sym) != sym->defval)
agxset(nn, sym, sym->defval);
}
return nn;
}
/* copyAttr:
* Copy attributes from src to tgt. Overrides currently
* defined values.
* FIX: we should probably use the default value of the source
* graph when initializing the attribute, rather than "".
* NOTE: We do not assume src and tgt have the same kind.
*/
int copyAttr(Agobj_t * src, Agobj_t * tgt)
{
Agraph_t *srcg;
Agraph_t *tgtg;
Agsym_t *sym = 0;
Agsym_t *tsym = 0;
int skind = AGTYPE(src);
int tkind = AGTYPE(tgt);
char* val;
srcg = agraphof(src);
tgtg = agraphof(tgt);
while ((sym = agnxtattr(srcg, skind, sym))) {
tsym = agattrsym(tgt, sym->name);
if (!tsym)
tsym = agattr(tgtg, tkind, sym->name, sym->defval);
val = agxget(src, sym);
if (aghtmlstr (val)) {
val = agstrdup_html (tgtg, val);
agxset(tgt, tsym, val);
agstrfree (tgtg, val);
}
else
agxset(tgt, tsym, val);
}
return 0;
}
static void ptest_initNode(node_t * n)
{
char *str;
ND_width(n) =
late_double(n, N_width, DEFAULT_NODEWIDTH, MIN_NODEWIDTH);
ND_height(n) =
late_double(n, N_height, DEFAULT_NODEHEIGHT, MIN_NODEWIDTH);
if (N_label == NULL)
str = NODENAME_ESC;
else
str = agxget(n, N_label->index);
str = strdup_and_subst(str, NODENAME_ESC, n->name);
ND_label(n) = make_label(str,
late_double(n, N_fontsize, DEFAULT_FONTSIZE,
MIN_FONTSIZE), late_nnstring(n,
N_fontname,
DEFAULT_FONTNAME),
late_nnstring(n, N_fontcolor, DEFAULT_COLOR),
n->graph);
ND_shape(n) = bind_shape(late_nnstring(n, N_shape, DEFAULT_NODESHAPE));
ND_shape(n)->initfn(n); /* ### need to quantize ? */
ptest_nodesize(n, n->GD_flip(graph));
}
static point *user_spline(attrsym_t * symptr, edge_t * e, int *np)
{
char *pos;
int i, n, nc;
point *ps = 0;
point *pp;
double x, y;
if (symptr == NULL)
return 0;
pos = agxget(e, symptr->index);
if (*pos == '\0')
return 0;
n = numFields(pos);
*np = n;
if (n > 1) {
ps = ALLOC(n, 0, point);
pp = ps;
while (n) {
i = sscanf(pos, "%lf,%lf%n", &x, &y, &nc);
if (i < 2) {
free(ps);
ps = 0;
break;
}
pos = pos + nc;
pp->x = (int) x;
pp->y = (int) y;
pp++;
n--;
}
}
return ps;
}
/* mapN:
* Convert cluster nodes back to ordinary nodes
* If n is already ordinary, return it.
* Otherwise, we know node's name is "__i:xxx"
* where i is some number and xxx is the nodes's original name.
* Create new node of name xxx if it doesn't exist and add n to clg
* for later deletion.
*/
static node_t *mapN(node_t * n, graph_t * clg)
{
extern Agdict_t *agdictof(void *);
node_t *nn;
char *name;
graph_t *g = n->graph;
Agdict_t *d;
Agsym_t **list;
Agsym_t *sym;
if (!(IS_CLUST_NODE(n)))
return n;
aginsert(clg, n);
name = strchr(n->name, ':');
assert(name);
name++;
if ((nn = agfindnode(g, name)))
return nn;
nn = agnode(g, name);
/* Set all attributes to default */
d = agdictof(n);
list = d->list;
while ((sym = *list++)) {
/* Can use pointer comparison because of ref strings. */
if (agxget(nn, sym->index) != sym->value)
agxset(nn, sym->index, sym->value);
}
return nn;
}
void GraphEdge::updateWithEdge(edge_t* edge)
{
kDebug();
DotRenderOpVec ops;
// decrease mem peak
setRenderOperations(ops);
if (agget(edge, (char*)"_draw_") != NULL)
{
parse_renderop(agget(edge, (char*)"_draw_"), ops);
kDebug() << "element renderOperations size is now " << ops.size();
}
if (agget(edge, (char*)"_ldraw_") != NULL)
{
parse_renderop(agget(edge, (char*)"_ldraw_"), ops);
kDebug() << "element renderOperations size is now " << ops.size();
}
if (agget(edge, (char*)"_hdraw_") != NULL)
{
parse_renderop(agget(edge, (char*)"_hdraw_"), ops);
kDebug() << "element renderOperations size is now " << ops.size();
}
if (agget(edge, (char*)"_tdraw_") != NULL)
{
parse_renderop(agget(edge, (char*)"_tdraw_"), ops);
kDebug() << "element renderOperations size is now " << ops.size();
}
if (agget(edge, (char*)"_hldraw_") != NULL)
{
parse_renderop(agget(edge, (char*)"_hldraw_"), ops);
kDebug() << "element renderOperations size is now " << ops.size();
}
if (agget(edge, (char*)"_tldraw_") != NULL)
{
parse_renderop(agget(edge, (char*)"_tldraw_"), ops);
kDebug() << "element renderOperations size is now " << ops.size();
}
setRenderOperations(ops);
Agsym_t *attr = agnxtattr(agraphof(agtail(edge)), AGEDGE, NULL);
while(attr)
{
kDebug() /*<< edge->name*/ << ":" << attr->name << agxget(edge,attr);
m_attributes[attr->name] = agxget(edge,attr);
attr = agnxtattr(agraphof(agtail(edge)), AGEDGE, attr);
}
}
int nonconstraint_edge(edge_t * e)
{
char *constr;
#ifndef WITH_CGRAPH
if (E_constr && (constr = agxget(e, E_constr->index))) {
#else /* WITH_CGRAPH */
if (E_constr && (constr = agxget(e, E_constr))) {
#endif /* WITH_CGRAPH */
if (constr[0] && mapbool(constr) == FALSE)
return TRUE;
}
return FALSE;
}
static void
interclust1(graph_t * g, node_t * t, node_t * h, edge_t * e)
{
node_t *v, *t0, *h0;
int offset, t_len, h_len, t_rank, h_rank;
edge_t *rt, *rh;
if (ND_clust(agtail(e)))
t_rank = ND_rank(agtail(e)) - ND_rank(GD_leader(ND_clust(agtail(e))));
else
t_rank = 0;
if (ND_clust(aghead(e)))
h_rank = ND_rank(aghead(e)) - ND_rank(GD_leader(ND_clust(aghead(e))));
else
h_rank = 0;
offset = ED_minlen(e) + t_rank - h_rank;
if (offset > 0) {
t_len = 0;
h_len = offset;
} else {
t_len = -offset;
h_len = 0;
}
v = virtual_node(g);
ND_node_type(v) = SLACKNODE;
t0 = UF_find(t);
h0 = UF_find(h);
rt = make_aux_edge(v, t0, t_len, CL_BACK * ED_weight(e));
rh = make_aux_edge(v, h0, h_len, ED_weight(e));
ED_to_orig(rt) = ED_to_orig(rh) = e;
}
/* _write_plain:
*/
void write_plain(GVJ_t * job, graph_t * g, FILE * f, boolean extend)
{
int i, j, splinePoints;
char *tport, *hport;
node_t *n;
edge_t *e;
bezier bz;
pointf pt;
char *lbl;
char* fillcolor;
#ifdef WITH_CGRAPH
putstr = g->clos->disc.io->putstr;
#endif
// setup_graph(job, g);
setYInvert(g);
pt = GD_bb(g).UR;
printdouble(f, "graph ", job->zoom);
printdouble(f, " ", PS2INCH(pt.x));
printdouble(f, " ", PS2INCH(pt.y));
agputc('\n', f);
for (n = agfstnode(g); n; n = agnxtnode(g, n)) {
if (IS_CLUST_NODE(n))
continue;
printstring(f, "node ", agcanonStr(agnameof(n)));
printpoint(f, ND_coord(n));
if (ND_label(n)->html) /* if html, get original text */
#ifndef WITH_CGRAPH
lbl = agcanonStr (agxget(n, N_label->index));
#else
lbl = agcanonStr (agxget(n, N_label));
#endif
else
lbl = canon(agraphof(n),ND_label(n)->text);
printdouble(f, " ", ND_width(n));
printdouble(f, " ", ND_height(n));
printstring(f, " ", lbl);
printstring(f, " ", late_nnstring(n, N_style, "solid"));
printstring(f, " ", ND_shape(n)->name);
printstring(f, " ", late_nnstring(n, N_color, DEFAULT_COLOR));
fillcolor = late_nnstring(n, N_fillcolor, "");
if (fillcolor[0] == '\0')
fillcolor = late_nnstring(n, N_color, DEFAULT_FILL);
printstring(f, " ", fillcolor);
agputc('\n', f);
}
int nonconstraint_edge(edge_t* e)
{
char *constr;
if (E_constr && (constr = agxget(e,E_constr->index))) {
if (constr[0] && mapbool(constr) == FALSE) return TRUE;
}
return FALSE;
}
double doubleattr(void *obj, int index, double defval)
{
double val;
if (index < 0)
return defval;
if (sscanf(agxget(obj, index), "%lf", &val) < 1)
return defval;
return val;
}
int
late_int(void *obj, attrsym_t *attr, int def, int low)
{
char *p;
int rv;
if (attr == NULL) return def;
p = agxget(obj,attr->index);
if (p[0] == '\0') return def;
if ((rv = atoi(p)) < low) rv = low;
return rv;
}
static void write_attrs(Agobj_t * obj, GVJ_t * job, state_t* sp)
{
Agraph_t* g = agroot(obj);
int type = AGTYPE(obj);
char* attrval;
Agsym_t* sym = agnxtattr(g, type, NULL);
if (!sym) return;
for (; sym; sym = agnxtattr(g, type, sym)) {
if (!(attrval = agxget(obj, sym))) continue;
if ((*attrval == '\0') && !streq(sym->name, "label")) continue;
gvputs(job, ",\n");
indent(job, sp->Level);
gvprintf(job, "\"%s\": ", stoj(sym->name, sp));
if (sp->doXDot && isXDot(sym->name))
write_xdots(agxget(obj, sym), job, sp);
else
gvprintf(job, "\"%s\"", stoj(agxget(obj, sym), sp));
}
}
double
late_float(void *obj,attrsym_t *attr, double def, double low)
{
char *p;
double rv;
if (attr == NULL) return def;
p = agxget(obj,attr->index);
if (p[0] == '\0') return def;
if ((rv = atof(p)) < low) rv = low;
return rv;
}
static void
emitGraphAttrs (Agraph_t* G, FILE* outFile)
{
Agsym_t* s;
char* v;
for (s = agnxtattr (G, AGRAPH, NULL); s; s = agnxtattr (G, AGRAPH, s)) {
if (*(v = agxget (G, s))) {
emitAttr (s->name, v, outFile, 1);
}
}
}
static double getlength(Agedge_t * e)
{
edgedata_t *data;
data = (edgedata_t *) (e->base.data);
if (data->length == 0) {
if (len_sym)
data->length = atof(agxget(e, len_sym));
if (data->length <= 0)
data->length = 1.0;
}
return data->length;
}
static void post(Agraph_t * g)
{
Agnode_t *v;
Agnode_t *prev;
char buf[256];
char dflt[256];
Agsym_t *sym;
Agsym_t *psym;
double dist, oldmax;
double maxdist = 0.0; /* maximum "finite" distance */
sym = agattr(g, AGNODE, "dist", "");
if (doPath)
psym = agattr(g, AGNODE, "prev", "");
if (setall)
sprintf(dflt, "%.3lf", HUGE);
for (v = agfstnode(g); v; v = agnxtnode(g, v)) {
dist = getdist(v);
if (dist) {
dist--;
sprintf(buf, "%.3lf", dist);
agxset(v, sym, buf);
if (doPath && (prev = getprev(v)))
agxset(v, psym, agnameof(prev));
if (maxdist < dist)
maxdist = dist;
} else if (setall)
agxset(v, sym, dflt);
}
sym = agattrsym(g, "maxdist");
if (sym) {
if (!setall) {
/* if we are preserving distances in other components,
* check previous value of maxdist.
*/
oldmax = atof(agxget(g, sym));
if (oldmax > maxdist)
maxdist = oldmax;
}
sprintf(buf, "%.3lf", maxdist);
agxset(g, sym, buf);
} else {
sprintf(buf, "%.3lf", maxdist);
agattr(g, AGRAPH, "maxdist", buf);
}
agclean(g, AGNODE, "dijkstra");
agclean(g, AGEDGE, "dijkstra");
}
/* noClip:
* Return true if head/tail end of edge should not be clipped
* to node.
*/
static bool
noClip(edge_t *e, attrsym_t* sym)
{
char *str;
bool rv = FALSE;
if (sym) { /* mapbool isn't a good fit, because we want "" to mean TRUE */
str = agxget(e,sym->index);
if (str && str[0]) rv = !mapbool(str);
else rv = FALSE;
}
return rv;
}
static void initPos(Agraph_t * g)
{
Agnode_t *n;
Agedge_t *e;
double *pvec;
char *p;
point *sp;
int pn;
attrsym_t *N_pos = agfindnodeattr(g, "pos");
attrsym_t *E_pos = agfindedgeattr(g, "pos");
assert(N_pos);
if (!E_pos) {
if (doEdges)
fprintf(stderr, "Warning: turning off doEdges, graph %s\n",
g->name);
doEdges = 0;
}
for (n = agfstnode(g); n; n = agnxtnode(g, n)) {
pvec = ND_pos(n);
p = agxget(n, N_pos->index);
if (p[0] && (sscanf(p, "%lf,%lf", pvec, pvec + 1) == 2)) {
int i;
for (i = 0; i < NDIM; i++)
pvec[i] = pvec[i] / PSinputscale;
} else {
fprintf(stderr, "could not find pos for node %s in graph %s\n",
n->name, g->name);
exit(1);
}
ND_coord_i(n).x = POINTS(ND_pos(n)[0]);
ND_coord_i(n).y = POINTS(ND_pos(n)[1]);
}
if (doEdges) {
for (n = agfstnode(g); n; n = agnxtnode(g, n)) {
for (e = agfstout(g, n); e; e = agnxtout(g, e)) {
if ((sp = user_spline(E_pos, e, &pn)) != 0) {
clip_and_install(e, sp, pn);
free(sp);
} else {
fprintf(stderr,
"Missing edge pos for edge %s - %s in graph %s\n",
n->name, e->head->name, g->name);
exit(1);
}
}
}
}
}
static int
late_mode (graph_t* g, Agsym_t* sym, int dflt)
{
char* s;
int v;
int rv;
if (!sym) return dflt;
#ifdef WITH_CGRAPH
s = agxget (g, sym);
#else
s = agxget (g, sym->index);
#endif
if (isdigit(*s)) {
if ((v = atoi (s)) <= METHOD_UNIFORM_STRESS)
rv = v;
else
rv = dflt;
}
else if (isalpha(*s)) {
if (!strcasecmp(s, "spring"))
rv = METHOD_SPRING_ELECTRICAL;
else if (!strcasecmp(s, "maxent"))
rv = METHOD_SPRING_MAXENT;
else if (!strcasecmp(s, "stress"))
rv = METHOD_STRESS;
else if (!strcasecmp(s, "uniform"))
rv = METHOD_UNIFORM_STRESS;
else {
agerr (AGWARN, "Unknown value \"%s\" for mode attribute\n", s);
rv = dflt;
}
}
else
rv = dflt;
return rv;
}
static double getlength(Agedge_t * e)
{
double len;
char* lens;
char* p;
if (len_sym && (*(lens = agxget(e, len_sym)))) {
len = strtod (lens, &p);
if ((len < 0) || (p == lens))
len = 1;
}
else
len = 1;
return len;
}
