(calc_position_and_height): robustness:

[lilypond.git] / lily / tuplet-bracket.cc

/*
  tuplet-bracket.cc -- implement Tuplet_bracket

  source file of the GNU LilyPond music typesetter

  (c) 1997--2006 Jan Nieuwenhuizen <janneke@gnu.org>
  Han-Wen Nienhuys <hanwen@xs4all.nl>
*/

/*
  TODO:

  - tuplet bracket should probably be subject to the same rules as
  beam sloping/quanting.

  - There is no support for kneed brackets, or nested brackets.

  - number placement for parallel beams should be much more advanced:
  for sloped beams some extra horizontal offset must be introduced.

  - number placement is usually done over the center note, not the
  graphical center.
*/

/*
  TODO: quantise, we don't want to collide with staff lines.
  (or should we be above staff?)

  todo: handle breaking elegantly.
*/


#include "tuplet-bracket.hh"
#include "line-interface.hh"
#include "beam.hh"
#include "warn.hh"
#include "output-def.hh"
#include "font-interface.hh"
#include "text-interface.hh"
#include "stem.hh"
#include "note-column.hh"
#include "pointer-group-interface.hh"
#include "directional-element-interface.hh"
#include "spanner.hh"
#include "staff-symbol-referencer.hh"
#include "lookup.hh"
#include "paper-column.hh"
#include "moment.hh"

static Item *
get_x_bound_item (Grob *me_grob, Direction hdir, Direction my_dir)
{
  Spanner *me = dynamic_cast<Spanner *> (me_grob);
  Item *g = me->get_bound (hdir);
  if (Note_column::has_interface (g)
      && Note_column::get_stem (g)
      && Note_column::dir (g) == my_dir)
    g = Note_column::get_stem (g);

  return g;
}


void
flatten_number_pair_property (Grob *me,
                              Direction xdir,  SCM sym)
{
  Drul_array<Real> zero (0, 0);
  Drul_array<Real> pair
    = robust_scm2drul (me->internal_get_property (sym), zero);
  pair[xdir] = 0.0;
  
  me->set_property (sym, ly_interval2scm (pair));
}


/*
  Return beam that encompasses the span of the tuplet bracket.
*/

Grob *
Tuplet_bracket::parallel_beam (Grob *me_grob, vector<Grob*> const &cols,
                               bool *equally_long)
{
  Spanner *me = dynamic_cast<Spanner *> (me_grob);

  if (me->get_bound (LEFT)->break_status_dir ()
      || me->get_bound (RIGHT)->break_status_dir ())
    return 0;

  Drul_array<Grob*> stems (Note_column::get_stem (cols[0]),
                           Note_column::get_stem (cols.back ()));

  if (dynamic_cast<Item*> (stems[RIGHT])->get_column ()
      != me->get_bound (RIGHT)->get_column())
    return 0;

  Drul_array<Grob*> beams;
  Direction d = LEFT;
  do {
    beams[d] = stems[d] ? Stem::get_beam (stems[d]) : 0;
  } while (flip (&d) != LEFT);
  
  *equally_long = false;
  if (! (beams[LEFT] && (beams[LEFT] == beams[RIGHT]) && !me->is_broken ()))
    return 0;

  extract_grob_set (beams[LEFT], "stems", beam_stems);
  if (beam_stems.size () == 0)
    {
      programming_error ("beam under tuplet bracket has no stems");
      *equally_long = 0;
      return 0;
    }

  *equally_long =
    (beam_stems[0] == stems[LEFT]
     && beam_stems.back () == stems[RIGHT]);
  return beams[LEFT];
}


MAKE_SCHEME_CALLBACK(Tuplet_bracket,calc_connect_to_neighbors,1);
SCM
Tuplet_bracket::calc_connect_to_neighbors (SCM smob)
{
  Spanner *me = unsmob_spanner (smob);

  Direction dir = get_grob_direction (me); 
  Drul_array<Item *> bounds (get_x_bound_item (me, LEFT, dir),
                             get_x_bound_item (me, RIGHT, dir));
  
  Drul_array<bool> connect_to_other (false, false);
  Direction d = LEFT;
  do
    {
      Direction break_dir = bounds[d]->break_status_dir ();
      
      Spanner *orig_spanner = dynamic_cast<Spanner*> (me->original ());

      vsize neighbor_idx = me->get_break_index () - break_dir;
      if (break_dir
          && d == RIGHT
          && neighbor_idx < orig_spanner->broken_intos_.size ())
        {
          Grob *neighbor = orig_spanner->broken_intos_[neighbor_idx];

          /* trigger possible suicide*/
          (void) neighbor->get_property ("positions");
        }

      connect_to_other[d]
        = (break_dir
           && neighbor_idx < orig_spanner->broken_intos_.size ()
           && orig_spanner->broken_intos_[neighbor_idx]->is_live ());
    }
  while (flip (&d) != LEFT);


  if (connect_to_other[LEFT] || connect_to_other[RIGHT])
    return scm_cons (scm_from_bool (connect_to_other[LEFT]),
                     scm_from_bool (connect_to_other[RIGHT]));
                     
  return SCM_EOL;
}

Grob* 
Tuplet_bracket::get_common_x (Spanner *me)
{
  extract_grob_set (me, "note-columns", columns);

  Grob * commonx = common_refpoint_of_array (columns, me, X_AXIS);
  commonx = commonx->common_refpoint (me->get_bound (LEFT), X_AXIS);
  commonx = commonx->common_refpoint (me->get_bound (RIGHT), X_AXIS);

  return commonx;
}
  
MAKE_SCHEME_CALLBACK(Tuplet_bracket,calc_control_points,1)
SCM
Tuplet_bracket::calc_control_points (SCM smob)
{
  Spanner *me = unsmob_spanner (smob);

  extract_grob_set (me, "note-columns", columns);

  SCM scm_positions = me->get_property ("positions");
  if (!me->is_live ())
    return SCM_EOL;
  
  if (!scm_is_pair (scm_positions))
    programming_error ("Positions should be number pair");
    
  Drul_array<Real> positions
    = robust_scm2drul (scm_positions, Drul_array<Real> (0,0));

  Grob *commonx = get_common_x (me);
  Direction dir = get_grob_direction (me);

  Drul_array<Item *> bounds;
  bounds[LEFT] = get_x_bound_item (me, LEFT, dir);
  bounds[RIGHT] = get_x_bound_item (me, RIGHT, dir);

  Drul_array<bool> connect_to_other =
    robust_scm2booldrul (me->get_property ("connect-to-neighbor"),
                         Drul_array<bool> (false, false));
  
    
  Interval x_span;
  Direction d = LEFT;
  do
    {
      x_span[d] = robust_relative_extent (bounds[d], commonx, X_AXIS)[d];

      if (connect_to_other[d])
        {
          Interval overshoot (robust_scm2drul (me->get_property ("break-overshoot"),
                                               Interval (-0.5, 0.0)));

          if (d == RIGHT)
            x_span[d] += d * overshoot[d];
          else
            x_span[d] = robust_relative_extent (bounds[d], commonx, X_AXIS)[RIGHT]
              - overshoot[LEFT];
        }
      
      else if (d == RIGHT
               && (columns.empty ()
                   || (bounds[d]->get_column ()
                       != dynamic_cast<Item *> (columns.back ())->get_column ())))
        {
          /*
            We're connecting to a column, for the last bit of a broken
            fullLength bracket.
            
            TODO: make padding tunable?
          */
          Real padding = 1.0;

          if (bounds[d]->break_status_dir ())
            padding = 0.0;
          
          x_span[d]
            = robust_relative_extent (bounds[d], commonx, X_AXIS) [LEFT]
            - padding;
        }
    }
  while (flip (&d) != LEFT);

  
  
  x_span -= me->get_bound (LEFT)->relative_coordinate (commonx, X_AXIS);
  return scm_list_2 (ly_offset2scm (Offset (x_span[LEFT], positions[LEFT])),
                     ly_offset2scm (Offset (x_span[RIGHT], positions[RIGHT])));
}

/*
  TODO:

  in the case that there is no bracket, but there is a (single) beam,
  follow beam precisely for determining tuplet number location.
*/
MAKE_SCHEME_CALLBACK (Tuplet_bracket, print, 1);
SCM
Tuplet_bracket::print (SCM smob)
{
  Spanner *me = unsmob_spanner (smob);
  Stencil mol;

  extract_grob_set (me, "note-columns", columns);
  bool equally_long = false;
  Grob *par_beam = parallel_beam (me, columns, &equally_long);
  
  bool bracket_visibility = !(par_beam && equally_long);
  /*
    Fixme: the type of this prop is sucky.
  */
  SCM bracket = me->get_property ("bracket-visibility");
  if (scm_is_bool (bracket))
    bracket_visibility = ly_scm2bool (bracket);
  else if (bracket == ly_symbol2scm ("if-no-beam"))
    bracket_visibility = !par_beam;

  
  SCM cpoints =  me->get_property ("control-points");
  if (scm_ilength (cpoints) < 2)
    {
      me->suicide ();
      return SCM_EOL;
    }
  
  Drul_array<Offset> points;
  points[LEFT] = ly_scm2offset (scm_car (cpoints));
  points[RIGHT] = ly_scm2offset (scm_cadr (cpoints));
  
  Interval x_span (points[LEFT][X_AXIS], points[RIGHT][X_AXIS]);
  Drul_array<Real> positions (points[LEFT][Y_AXIS], points[RIGHT][Y_AXIS]);



  Output_def *pap = me->layout ();

  Grob *number_grob = unsmob_grob (me->get_object ("tuplet-number"));
  
  /*
    No bracket when it would be smaller than the number.
  */
  Real gap = 0.;
  if (bracket_visibility && number_grob)
    {
      Interval ext = number_grob->extent (number_grob, X_AXIS);
      if (!ext.is_empty ())
        {
          gap = ext.length () + 1.0;
      
          if (0.75 * x_span.length () < gap)
            bracket_visibility = false;
        }
    }

  if (bracket_visibility)
    {
      Drul_array<Real> zero (0, 0);
      Real ss = Staff_symbol_referencer::staff_space (me);
      Drul_array<Real> height
        = robust_scm2drul (me->get_property ("edge-height"), zero);
      Drul_array<Real> flare
        = robust_scm2drul (me->get_property ("bracket-flare"), zero);
      Drul_array<Real> shorten
        = robust_scm2drul (me->get_property ("shorten-pair"), zero);
      Drul_array<Stencil> edge_stencils;

      Direction dir = get_grob_direction (me);
      
      scale_drul (&height, -ss * dir);
      scale_drul (&flare, ss);
      scale_drul (&shorten, ss);

      Drul_array<bool> connect_to_other =
        robust_scm2booldrul (me->get_property ("connect-to-neighbor"),
                             Drul_array<bool> (false, false));

      Direction d = LEFT;
      do
        {
          if (connect_to_other[d])
            {
              height[d] = 0.0;
              flare[d] = 0.0;
              shorten[d] = 0.0;

              SCM edge_text = me->get_property ("edge-text");

              if (scm_is_pair (edge_text))
                {
                  SCM properties = Font_interface::text_font_alist_chain (me);
                  SCM text = index_get_cell (edge_text, d);
                  if (Text_interface::is_markup (text))
                    {
                      SCM t = Text_interface::interpret_markup (pap->self_scm (),
                                                                properties, text);

                      Stencil *edge_text = unsmob_stencil (t);
                      edge_text->translate_axis (x_span[d] - x_span[LEFT], X_AXIS);
                      edge_stencils[d] = *edge_text;
                    }
                }
            }
        }
      while (flip (&d) != LEFT);

      Stencil brack = make_bracket (me, Y_AXIS,
                                    points[RIGHT] - points[LEFT],
                                    height,
                                    /*
                                      0.1 = more space at right due to italics
                                      TODO: use italic correction of font.
                                    */
                                    Interval (-0.5, 0.5) * gap + 0.1,
                                    flare, shorten);

      do
        {
          if (!edge_stencils[d].is_empty ())
            brack.add_stencil (edge_stencils[d]);
        }
      while (flip (&d) != LEFT);

      mol.add_stencil (brack);
    }

  mol.translate (points[LEFT]);
  return mol.smobbed_copy ();
}

/*
  should move to lookup?

  TODO: this will fail for very short (shorter than the flare)
  brackets.
*/
Stencil
Tuplet_bracket::make_bracket (Grob *me, // for line properties.
                              Axis protusion_axis,
                              Offset dz,
                              Drul_array<Real> height,
                              Interval gap,
                              Drul_array<Real> flare,
                              Drul_array<Real> shorten)
{
  Drul_array<Offset> corners (Offset (0, 0), dz);

  Real length = dz.length ();
  Drul_array<Offset> gap_corners;

  Axis bracket_axis = other_axis (protusion_axis);

  Drul_array<Offset> straight_corners = corners;

  Direction d = LEFT;
  do
    straight_corners[d] += -d * shorten[d] / length * dz;
  while (flip (&d) != LEFT);

  if (gap.is_empty ())
    gap = Interval (0, 0);
  do
    gap_corners[d] = (dz * 0.5) + gap[d] / length * dz;
  while (flip (&d) != LEFT)
    ;

  Drul_array<Offset> flare_corners = straight_corners;
  do
    {
      flare_corners[d][bracket_axis] = straight_corners[d][bracket_axis];
      flare_corners[d][protusion_axis] += height[d];
      straight_corners[d][bracket_axis] += -d * flare[d];
    }
  while (flip (&d) != LEFT);

  Stencil m;
  do
    {
      m.add_stencil (Line_interface::line (me, straight_corners[d],
                                           gap_corners[d]));

      m.add_stencil (Line_interface::line (me, straight_corners[d],
                                           flare_corners[d]));
    }
  while (flip (&d) != LEFT);

  return m;
}

void
Tuplet_bracket::get_bounds (Grob *me, Grob **left, Grob **right)
{
  extract_grob_set (me, "note-columns", columns);
  vsize l = 0;
  while (l < columns.size () && Note_column::has_rests (columns[l]))
    l++;

  vsize r = columns.size ();
  while (r > l && Note_column::has_rests (columns[r-1]))
    r--;

  *left = *right = 0;

  if (l < r)
    {
      *left = columns[l];
      *right = columns[r-1];
    }
}

/*
  use first -> last note for slope, and then correct for disturbing
  notes in between.  */
void
Tuplet_bracket::calc_position_and_height (Grob *me_grob, Real *offset, Real *dy)
{
  Spanner *me = dynamic_cast<Spanner *> (me_grob);

  extract_grob_set (me, "note-columns", columns);
  extract_grob_set (me, "tuplets", tuplets);

  Grob *commony = common_refpoint_of_array (columns, me, Y_AXIS);
  commony = common_refpoint_of_array (tuplets, commony, Y_AXIS);
  if (Grob *st = Staff_symbol_referencer::get_staff_symbol (me))
    commony = st->common_refpoint (commony, Y_AXIS);

  Grob *commonx = get_common_x (me);
  commonx = common_refpoint_of_array (tuplets, commonx, Y_AXIS);

  Interval staff;
  if (Grob *st = Staff_symbol_referencer::get_staff_symbol (me))
    {
      Real pad = robust_scm2double (me->get_property ("staff-padding"), -1.0);
      if  (pad >= 0.0)
        {
          staff = st->extent (commony, Y_AXIS);
          staff.widen (pad);
        }
    }
  
  Direction dir = get_grob_direction (me);

  /*
    Use outer non-rest columns to determine slope
  */
  Grob *left_col = 0;
  Grob *right_col = 0;
  get_bounds (me, &left_col, &right_col);
  if (left_col && right_col)
    {
      Interval rv = right_col->extent (commony, Y_AXIS);
      Interval lv = left_col->extent (commony, Y_AXIS);
      rv.unite (staff);
      lv.unite (staff);
      Real graphical_dy = rv[dir] - lv[dir];

      Slice ls = Note_column::head_positions_interval (left_col);
      Slice rs = Note_column::head_positions_interval (right_col);

      Interval musical_dy;
      musical_dy[UP] = rs[UP] - ls[UP];
      musical_dy[DOWN] = rs[DOWN] - ls[DOWN];
      if (sign (musical_dy[UP]) != sign (musical_dy[DOWN]))
        *dy = 0.0;
      else if (sign (graphical_dy) != sign (musical_dy[DOWN]))
        *dy = 0.0;
      else
        *dy = graphical_dy;
    }
  else
    *dy = 0;

  *offset = -dir * infinity_f;

  Item *lgr = get_x_bound_item (me, LEFT, dir);
  Item *rgr = get_x_bound_item (me, RIGHT, dir);
  Real x0 = robust_relative_extent (lgr, commonx, X_AXIS)[LEFT];
  Real x1 = robust_relative_extent (rgr, commonx, X_AXIS)[RIGHT];

  vector<Offset> points;
  points.push_back (Offset (x0 - x0, staff[dir]));
  points.push_back (Offset (x1 - x0, staff[dir]));

  for (vsize i = 0; i < columns.size (); i++)
    {
      Interval note_ext = columns[i]->extent (commony, Y_AXIS);
      Real notey = note_ext[dir] - me->relative_coordinate (commony, Y_AXIS);

      Real x = columns[i]->relative_coordinate (commonx, X_AXIS) - x0;
      points.push_back (Offset (x, notey));
    }

  /*
    This is a slight hack. We compute two encompass points from the
    bbox of the smaller tuplets.

    We assume that the smaller bracket is 1.0 space high.
  */
  Real ss = Staff_symbol_referencer::staff_space (me);
  for (vsize i = 0; i < tuplets.size (); i++)
    {
      Interval tuplet_x (tuplets[i]->extent (commonx, X_AXIS));
      Interval tuplet_y (tuplets[i]->extent (commony, Y_AXIS));

      if (!tuplets[i]->is_live ())
        continue;
      
      Direction d = LEFT;
      Drul_array<Real> positions = robust_scm2interval (tuplets[i]->get_property ("positions"),
                                                        Interval (0,0));

      
      Real other_dy = positions[RIGHT] - positions[LEFT];

      do
        {
          Real y
            = tuplet_y.linear_combination (d * sign (other_dy));

          /*
            We don't take padding into account for nested tuplets.
            the edges can come very close to the stems, likewise for
            nested tuplets?
          */

          points.push_back (Offset (tuplet_x[d] - x0, y));
        }
      while (flip (&d) != LEFT);
    }

  Real factor = (columns.size () > 1) ? 1 / (x1 - x0) : 1.0;
  for (vsize i = 0; i < points.size (); i++)
    {
      Real x = points[i][X_AXIS];
      Real tuplety = (*dy) * x * factor;

      if (points[i][Y_AXIS] * dir > (*offset + tuplety) * dir)
        *offset = points[i][Y_AXIS] - tuplety;
    }

  *offset += scm_to_double (me->get_property ("padding")) * dir;

  /*
    horizontal brackets should not collide with staff lines.

    Kind of pointless since we put them outside the staff anyway, but
    let's leave code for the future when possibly allow them to move
    into the staff once again.
  */
  if (*dy == 0
      && fabs (*offset) < ss * Staff_symbol_referencer::staff_radius (me))
    {
      // quantize, then do collision check.
      *offset *= 2 / ss;

      *offset = rint (*offset);
      if (Staff_symbol_referencer::on_line (me, (int) rint (*offset)))
        *offset += dir;

      *offset *= 0.5 * ss;
    }
}


MAKE_SCHEME_CALLBACK (Tuplet_bracket, calc_direction, 1);
SCM
Tuplet_bracket::calc_direction (SCM smob)
{
  Grob *me = unsmob_grob (smob);
  Direction dir = Tuplet_bracket::get_default_dir (me);
  return scm_from_int (dir);
}

MAKE_SCHEME_CALLBACK (Tuplet_bracket, calc_positions, 1);
SCM
Tuplet_bracket::calc_positions (SCM smob)
{
  Spanner *me = unsmob_spanner (smob);
  extract_grob_set (me, "note-columns", columns);

  /*
    Don't print if it doesn't span time.
   */
  if (robust_scm2moment (me->get_bound (LEFT)->get_column ()->get_property ("when"), Moment (0))
      == robust_scm2moment (me->get_bound (RIGHT)->get_column ()->get_property ("when"), Moment (0)))
    {
      me->suicide ();
      return SCM_EOL;
    }

  
  Direction dir = get_grob_direction (me);
  bool equally_long = false;
  Grob *par_beam = parallel_beam (me, columns, &equally_long);

  /*
    We follow the beam only if there is one, and we are next to it.
  */
  Real dy = 0.0;
  Real offset = 0.0;
  if (!par_beam
      || get_grob_direction (par_beam) != dir)
    calc_position_and_height (me, &offset, &dy);
  else if  (columns.size ()
            && Note_column::get_stem (columns[0])
            && Note_column::get_stem (columns.back ()))
    {
      /*
        trigger set_stem_ends
       */
      (void) par_beam->get_property ("quantized-positions");


      Drul_array<Grob *> stems (Note_column::get_stem (columns[0]),
                                Note_column::get_stem (columns.back ()));

      
      

      Real ss = 0.5 * Staff_symbol_referencer::staff_space (me);
      Real lp = ss * robust_scm2double (stems[LEFT]->get_property ("stem-end-position"), 0.0);
      Real rp = ss * robust_scm2double (stems[RIGHT]->get_property ("stem-end-position"), 0.0);

      
      offset = lp + dir * (0.5 + scm_to_double (me->get_property ("padding")));
      dy = (rp - lp);
    }

  
  SCM x = scm_cons (scm_from_double (offset),
                    scm_from_double (offset + dy));
  
  return x;
}

/*
  similar to beam ?
*/
Direction
Tuplet_bracket::get_default_dir (Grob *me)
{
  Drul_array<int> dirs (0, 0);
  extract_grob_set (me, "note-columns", columns);
  for (vsize i = 0; i < columns.size (); i++)
    {
      Grob *nc = columns[i];
      Direction d = Note_column::dir (nc);
      if (d)
        dirs[d]++;
    }

  return dirs[UP] >= dirs[DOWN] ? UP : DOWN;
}

void
Tuplet_bracket::add_column (Grob *me, Item *n)
{
  Pointer_group_interface::add_grob (me, ly_symbol2scm ("note-columns"), n);
  add_bound_item (dynamic_cast<Spanner *> (me), n);
}

void
Tuplet_bracket::add_tuplet_bracket (Grob *me, Grob *bracket)
{
  Pointer_group_interface::add_grob (me, ly_symbol2scm ("tuplets"), bracket);
}

ADD_INTERFACE (Tuplet_bracket,
               "tuplet-bracket-interface",
               "A bracket with a number in the middle, used for tuplets. "
               "When the bracket spans  a line break, the value of "
               "@code{break-overshoot} determines how far it extends "
               "beyond the staff. "
               "At a line break, the markups in the @code{edge-text} are printed "
               "at the edges. ",


               /* properties */
               "bracket-flare "
               "bracket-visibility "
               "break-overshoot "
               "connect-to-neighbor "
               "control-points "
               "direction "
               "edge-height "
               "edge-text "
               "gap "
               "positions "
               "note-columns "
               "padding "
               "tuplet-number "
               "shorten-pair "
               "staff-padding "
               "thickness "
               "tuplets ");