-#include "varray.hh"
+/*
+ beam.cc -- implement Beam
+
+ source file of the GNU LilyPond music typesetter
+
+ (c) 1997 Han-Wen Nienhuys <hanwen@stack.nl>
+
+ TODO
+
+ Less hairy code. knee: ([\stem 1; c8 \stem -1; c8]
+
+*/
+#include <math.h>
+
+#include "p-col.hh"
+#include "varray.hh"
#include "proto.hh"
#include "dimen.hh"
#include "beam.hh"
#include "symbol.hh"
#include "molecule.hh"
#include "leastsquares.hh"
-#include "p-col.hh"
#include "stem.hh"
#include "paper-def.hh"
#include "lookup.hh"
struct Stem_info {
Real x;
- Real idealy;
- Real miny;
- int no_beams;
+ int dir_i_;
+ Real idealy_f_;
+ Real miny_f_;
+ int beams_i_;
-
Stem_info(){}
Stem_info(Stem const *);
};
Stem_info::Stem_info(Stem const *s)
{
- x = s->hindex();
- int dir = s->dir;
- idealy = max(dir*s->top, dir*s->bot);
- miny = max(dir*s->minnote, dir*s-> maxnote);
- assert(miny <= idealy);
-
+ x = s->hpos_f();
+ dir_i_ = s->dir_i_;
+ beams_i_ = intlog2( s->flag_i_ ) - 2;
+
+ /*
+ [todo]
+ * get algorithm
+ * runtime
+
+ Breitkopf + H\"artel:
+ miny_f_ = interline + #beams * interbeam
+ ideal8 = 2 * interline + interbeam
+ ideal16,32,64,128 = 1.5 * interline + #beams * interbeam
+
+ * B\"arenreiter:
+ miny_f_ = interline + #beams * interbeam
+ ideal8,16 = 2 interline + #beams * interbeam
+ ideal32,64,128 = 1.5 interline + #beams * interbeam
+
+ */
+
+ Real notehead_y = s->paper()->interline_f();
+ // huh? why do i need the / 2
+// Real interbeam_f = s->paper()->interbeam_f();
+ Real interbeam_f = s->paper()->interbeam_f() / 2;
+
+ /* well eh, huh?
+ idealy_f_ = dir_i_ * s->stem_start_f() + beams_i_ * interbeam_f;
+ if ( beams_i_ < 3 )
+ idealy_f_ += 2 * interline_f;
+ else
+ idealy_f_ += 1.5 * interline_f;
+ */
+
+ idealy_f_ = dir_i_ * s->stem_end_f();
+
+ miny_f_ = dir_i_ * s->stem_start_f() + notehead_y + beams_i_ * interbeam_f;
+
+ idealy_f_ = miny_f_ >? idealy_f_;
+// assert(miny_f_ <= idealy_f_);
}
+
/* *************** */
+
Offset
Beam::center()const
{
- assert(status >= POSTCALCED);
-
Real w=(paper()->note_width() + width().length())/2.0;
- return Offset(w, (left_pos + w* slope)*paper()->internote());
+ return Offset(w, (left_pos + w* slope)*paper()->internote_f());
}
void
Beam::add(Stem*s)
{
- stems.bottom().add(s);
+ stems.push(s);
s->add_dependency(this);
- s->print_flag = false;
+ s->print_flag_b_ = false;
}
void
Beam::set_default_dir()
{
- int dirs[2];
- dirs[0]=0; dirs[1] =0;
- for (iter_top(stems,i); i.ok(); i++) {
- int d = i->get_default_dir();
- dirs[(d+1)/2] ++;
- }
- dir_i_ = (dirs[0] > dirs[1]) ? -1 : 1;
- for (iter_top(stems,i); i.ok(); i++) {
- i->dir = dir_i_;
+ int up = 0, down = 0;
+ int up_count = 0, down_count = 0;
+
+ for (int i=0; i <stems.size(); i++) {
+ Stem *sl = stems[i];
+ int cur_down = sl->get_center_distance_from_top();
+ int cur_up = sl->get_center_distance_from_bottom();
+ if (cur_down) {
+ down += cur_down;
+ down_count++;
+ }
+ if (cur_up) {
+ up += cur_up;
+ up_count++;
+ }
}
+ if (!down)
+ down_count = 1;
+ if (!up)
+ up_count = 1;
+
+ // the following relation is equal to
+ // up / up_count > down / down_count
+ dir_i_ = (up * down_count > down * up_count) ? 1 : -1;
+
+ for (int i=0; i <stems.size(); i++) {
+ Stem *sl = stems[i];
+ sl->dir_i_ = dir_i_;
+ }
}
/*
should use minimum energy formulation (cf linespacing)
- */
+
+ [todo]
+ the y of the (start) of the beam should be quantisized,
+ so that no stafflines appear just in between two beam-flags
+
+*/
void
Beam::solve_slope()
{
Array<Stem_info> sinfo;
- for (iter_top(stems,i); i.ok(); i++) {
+ for (int j=0; j <stems.size(); j++) {
+ Stem *i = stems[j];
+
i->set_default_extents();
+ if (i->invisible_b())
+ continue;
+
Stem_info info(i);
sinfo.push(info);
}
- Real leftx = sinfo[0].x;
- Least_squares l;
- for (int i=0; i < sinfo.size(); i++) {
- sinfo[i].x -= leftx;
- l.input.push(Offset(sinfo[i].x, sinfo[i].idealy));
- }
+ if (! sinfo.size() )
+ slope = left_pos = 0;
+ else if (sinfo.size() == 1) {
+ slope = 0;
+ left_pos = sinfo[0].idealy_f_;
+ } else {
+
+ Real leftx = sinfo[0].x;
+ Least_squares l;
+ for (int i=0; i < sinfo.size(); i++) {
+ sinfo[i].x -= leftx;
+ l.input.push(Offset(sinfo[i].x, sinfo[i].idealy_f_));
+ }
- l.minimise(slope, left_pos);
+ l.minimise(slope, left_pos);
+ }
+
Real dy = 0.0;
for (int i=0; i < sinfo.size(); i++) {
Real y = sinfo[i].x * slope + left_pos;
- Real my = sinfo[i].miny;
+ Real my = sinfo[i].miny_f_;
if (my - y > dy)
dy = my -y;
}
left_pos += dy;
left_pos *= dir_i_;
+
slope *= dir_i_;
- // URG
- Real sl = slope*paper()->internote();
+ /*
+ This neat trick is by Werner Lemberg, damped = tanh(slope) corresponds
+ with some tables in [Wanske]
+ */
+ slope = 0.6 * tanh(slope);
+
+ // ugh
+ Real sl = slope*paper()->internote_f();
paper()->lookup_l()->beam(sl, 20 PT);
- slope = sl /paper()->internote();
+ slope = sl /paper()->internote_f();
}
void
Beam::set_stemlens()
{
- iter_top(stems,s);
- Real x0 = s->hindex();
- for (; s.ok() ; s++) {
- Real x = s->hindex()-x0;
+ Real x0 = stems[0]->hpos_f();
+ for (int j=0; j <stems.size(); j++) {
+ Stem *s = stems[j];
+
+ Real x = s->hpos_f()-x0;
s->set_stemend(left_pos + slope * x);
}
}
void
Beam::do_post_processing()
{
+ if ( stems.size() < 2) {
+ warning("Beam with less than 2 stems");
+ transparent_b_ = true;
+ return ;
+ }
solve_slope();
set_stemlens();
}
Array<int> b;
{
- iter_top(stems,s);
Array<int> flags;
- for (; s.ok(); s++) {
- int f = intlog2(abs(s->flag))-2;
+ for (int j=0; j <stems.size(); j++) {
+ Stem *s = stems[j];
+
+ int f = intlog2(abs(s->flag_i_))-2;
assert(f>0);
flags.push(f);
}
assert(stems.size() == b.size()/2);
}
- iter_top(stems,s);
- for (int i=0; i < b.size() && s.ok(); i+=2, s++) {
- s->beams_left = b[i];
- s->beams_right = b[i+1];
+ for (int j=0, i=0; i < b.size() && j <stems.size(); i+= 2, j++) {
+ Stem *s = stems[j];
+ s->beams_left_i_ = b[i];
+ s->beams_right_i_ = b[i+1];
}
}
-
-// todo.
-Spanner *
-Beam::do_break_at( PCol *, PCol *) const
-{
- Beam *beam_p= new Beam(*this);
-
- return beam_p;
-}
-
void
Beam::do_pre_processing()
{
- left = (*stems.top()) ->pcol_l_;
- right = (*stems.bottom())->pcol_l_;
- assert(stems.size()>1);
if (!dir_i_)
set_default_dir();
Interval
-Beam::width() const
+Beam::do_width() const
{
- Beam * me = (Beam*) this; // ugh
- return Interval( (*me->stems.top()) ->hindex(),
- (*me->stems.bottom()) ->hindex() );
+ return Interval( stems[0]->hpos_f(),
+ stems.top()->hpos_f() );
}
/*
Molecule
Beam::stem_beams(Stem *here, Stem *next, Stem *prev)const
{
- assert( !next || next->hindex() > here->hindex() );
- assert( !prev || prev->hindex() < here->hindex() );
- Real dy=paper()->internote()*2;
+ assert( !next || next->hpos_f() > here->hpos_f() );
+ assert( !prev || prev->hpos_f() < here->hpos_f() );
+// Real dy=paper()->internote_f()*2;
+ Real dy = paper()->interbeam_f();
Real stemdx = paper()->rule_thickness();
- Real sl = slope*paper()->internote();
+ Real sl = slope*paper()->internote_f();
paper()->lookup_l()->beam(sl, 20 PT);
Molecule leftbeams;
/* half beams extending to the left. */
if (prev) {
- int lhalfs= lhalfs = here->beams_left - prev->beams_right ;
- int lwholebeams= here->beams_left <? prev->beams_right ;
- Real w = (here->hindex() - prev->hindex())/4;
+ int lhalfs= lhalfs = here->beams_left_i_ - prev->beams_right_i_ ;
+ int lwholebeams= here->beams_left_i_ <? prev->beams_right_i_ ;
+ Real w = (here->hpos_f() - prev->hpos_f())/4;
Symbol dummy;
Atom a(dummy);
if (lhalfs) // generates warnings if not
a.translate(Offset (-w, -w * sl));
for (int j = 0; j < lhalfs; j++) {
Atom b(a);
- b.translate(Offset(0, -dir_i_ * dy * (lwholebeams+j)));
+ b.translate_y( -dir_i_ * dy * (lwholebeams+j));
leftbeams.add( b );
}
}
if (next){
- int rhalfs = here->beams_right - next->beams_left;
- int rwholebeams = here->beams_right <? next->beams_left;
+ int rhalfs = here->beams_right_i_ - next->beams_left_i_;
+ int rwholebeams = here->beams_right_i_ <? next->beams_left_i_;
- Real w = next->hindex() - here->hindex();
+ Real w = next->hpos_f() - here->hpos_f();
Atom a = paper()->lookup_l()->beam(sl, w + stemdx);
int j = 0;
for (; j < rwholebeams; j++) {
Atom b(a);
- b.translate(Offset(0, -dir_i_ * dy * j));
+ b.translate_y( -dir_i_ * dy * j);
rightbeams.add( b );
}
for (; j < rwholebeams + rhalfs; j++) {
Atom b(a);
- b.translate(Offset(0, -dir_i_ * dy * j));
+ b.translate_y( -dir_i_ * dy * j);
rightbeams.add(b );
}
Molecule*
-Beam::brew_molecule_p() const return out;
+Beam::brew_molecule_p() const
{
- Real inter=paper()->internote();
- out = new Molecule;
- Real x0 = stems.top()->hindex();
-
- for (iter_top(stems,i); i.ok(); i++) {
- PCursor<Stem*> p(i-1);
- PCursor<Stem*> n(i+1);
- Stem * prev = p.ok() ? p.ptr() : 0;
- Stem * next = n.ok() ? n.ptr() : 0;
+
+ Molecule *mol_p = new Molecule;
+ // huh? inter-what
+// Real inter_f = paper()->interbeam_f();
+ Real inter_f = paper()->internote_f();
+ Real x0 = stems[0]->hpos_f();
+ for (int j=0; j <stems.size(); j++) {
+ Stem *i = stems[j];
+ Stem * prev = (j > 0)? stems[j-1] : 0;
+ Stem * next = (j < stems.size()-1) ? stems[j+1] :0;
Molecule sb = stem_beams(i, next, prev);
- Real x = i->hindex()-x0;
- sb.translate(Offset(x, (x * slope + left_pos)* inter));
- out->add(sb);
+ Real x = i->hpos_f()-x0;
+ sb.translate(Offset(x, (x * slope + left_pos)* inter_f));
+ mol_p->add(sb);
}
- out->translate(Offset(x0 - left->hpos,0));
+ mol_p->translate_x(x0 - left_col_l_->hpos);
+ return mol_p;
}
+IMPLEMENT_STATIC_NAME(Beam);
+IMPLEMENT_IS_TYPE_B1(Beam, Spanner);
+
void
Beam::do_print()const
{
Spanner::print();
#endif
}
-
-Beam::~Beam()
+/*
+ duh. The stem is not a dependency but a dependent
+ */
+void
+Beam::do_substitute_dependency(Score_elem*o,Score_elem*n)
{
-
+ if (o->is_type_b( Stem::static_name() )) {
+ stems.substitute( (Stem*)o->item(), n?(Stem*) n->item():0);
+ }
}