/* This file is part of LilyPond, the GNU music typesetter. Copyright (C) 1996--2015 Han-Wen Nienhuys Jan Nieuwenhuizen TODO: This is way too hairy TODO: fix naming. Stem-end, chord-start, etc. is all confusing naming. LilyPond is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. LilyPond is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with LilyPond. If not, see . */ /* Note that several internal functions have a calc_beam bool argument. This argument means: "If set, acknowledge the fact that there is a beam and deal with it. If not, give me the measurements as if there is no beam." Most pure functions are called WITHOUT calc_beam, whereas non-pure functions are called WITH calc_beam. The only exception to this is ::pure_height, which calls internal_pure_height with "true" for calc_beam in order to trigger the calculations of other pure heights in case there is a beam. It passes false, however, to internal_height and internal_pure_height for all subsequent iterations. */ #include "stem.hh" #include "spanner.hh" #include // rint using namespace std; #include "beam.hh" #include "directional-element-interface.hh" #include "dot-column.hh" #include "font-interface.hh" #include "international.hh" #include "lookup.hh" #include "misc.hh" #include "note-head.hh" #include "output-def.hh" #include "paper-column.hh" #include "pointer-group-interface.hh" #include "rest.hh" #include "rhythmic-head.hh" #include "side-position-interface.hh" #include "staff-symbol-referencer.hh" #include "stem-tremolo.hh" #include "warn.hh" void Stem::set_beaming (Grob *me, int beam_count, Direction d) { SCM pair = me->get_property ("beaming"); if (!scm_is_pair (pair)) { pair = scm_cons (SCM_EOL, SCM_EOL); me->set_property ("beaming", pair); } SCM lst = index_get_cell (pair, d); if (beam_count) for (int i = 0; i < beam_count; i++) lst = scm_cons (scm_from_int (i), lst); else lst = SCM_BOOL_F; index_set_cell (pair, d, lst); } int Stem::get_beaming (Grob *me, Direction d) { SCM pair = me->get_property ("beaming"); if (!scm_is_pair (pair)) return 0; SCM lst = index_get_cell (pair, d); int len = scm_ilength (lst); return max (len, 0); } Interval Stem::head_positions (Grob *me) { if (head_count (me)) { Drul_array e (extremal_heads (me)); return Interval (Staff_symbol_referencer::get_position (e[DOWN]), Staff_symbol_referencer::get_position (e[UP])); } return Interval (); } Real Stem::chord_start_y (Grob *me) { Interval hp = head_positions (me); if (!hp.is_empty ()) return hp[get_grob_direction (me)] * Staff_symbol_referencer::staff_space (me) * 0.5; return 0; } void Stem::set_stem_positions (Grob *me, Real se) { // todo: margins Direction d = get_grob_direction (me); Grob *beam = Grob::unsmob (me->get_object ("beam")); if (d && d * head_positions (me)[get_grob_direction (me)] >= se * d) me->warning (_ ("weird stem size, check for narrow beams")); // trigger note collision mechanisms Real stem_beg = internal_calc_stem_begin_position (me, false); Real staff_space = Staff_symbol_referencer::staff_space (me); Real half_space = staff_space * 0.5; Interval height; height[-d] = stem_beg * half_space; height[d] = se * half_space + beam_end_corrective (me); Real stemlet_length = robust_scm2double (me->get_property ("stemlet-length"), 0.0); bool stemlet = stemlet_length > 0.0; Grob *lh = get_reference_head (me); if (!lh) { if (stemlet && beam) { Real beam_translation = Beam::get_beam_translation (beam); Real beam_thickness = Beam::get_beam_thickness (beam); int beam_count = beam_multiplicity (me).length () + 1; height[-d] = (height[d] - d * (0.5 * beam_thickness + beam_translation * max (0, (beam_count - 1)) + stemlet_length)); } else if (!stemlet && beam) height[-d] = height[d]; else if (stemlet && !beam) me->programming_error ("Can't have a stemlet without a beam."); } me->set_property ("stem-begin-position", scm_from_double (height[-d] * 2 / staff_space)); me->set_property ("length", scm_from_double (height.length () * 2 / staff_space)); } /* Note head that determines hshift for upstems WARNING: triggers direction */ Grob * Stem::support_head (Grob *me) { extract_grob_set (me, "note-heads", heads); if (heads.size () == 1) return heads[0]; return first_head (me); } int Stem::head_count (Grob *me) { return Pointer_group_interface::count (me, ly_symbol2scm ("note-heads")); } /* The note head which forms one end of the stem. WARNING: triggers direction */ Grob * Stem::first_head (Grob *me) { Direction d = get_grob_direction (me); if (d) return extremal_heads (me)[-d]; return 0; } /* The note head opposite to the first head. */ Grob * Stem::last_head (Grob *me) { Direction d = get_grob_direction (me); if (d) return extremal_heads (me)[d]; return 0; } /* START is part where stem reaches `last' head. This function returns a drul with (bottom-head, top-head). */ Drul_array Stem::extremal_heads (Grob *me) { const int inf = INT_MAX; Drul_array extpos; extpos[DOWN] = inf; extpos[UP] = -inf; Drul_array exthead (0, 0); extract_grob_set (me, "note-heads", heads); for (vsize i = heads.size (); i--;) { Grob *n = heads[i]; int p = Staff_symbol_referencer::get_rounded_position (n); for (LEFT_and_RIGHT (d)) { if (d * p > d * extpos[d]) { exthead[d] = n; extpos[d] = p; } } } return exthead; } /* The staff positions, in ascending order. * If FILTER, include the main column of noteheads only */ vector Stem::note_head_positions (Grob *me, bool filter) { vector ps; extract_grob_set (me, "note-heads", heads); Grob *xref = common_refpoint_of_array (heads, me, X_AXIS); for (vsize i = heads.size (); i--;) { Grob *n = heads[i]; if (filter && n->relative_coordinate (xref, X_AXIS) != 0.0) continue; int p = Staff_symbol_referencer::get_rounded_position (n); ps.push_back (p); } vector_sort (ps, less ()); return ps; } void Stem::add_head (Grob *me, Grob *n) { n->set_object ("stem", me->self_scm ()); if (Note_head::has_interface (n)) Pointer_group_interface::add_grob (me, ly_symbol2scm ("note-heads"), n); else if (Rest::has_interface (n)) Pointer_group_interface::add_grob (me, ly_symbol2scm ("rests"), n); } bool Stem::is_invisible (Grob *me) { if (is_normal_stem (me)) return false; else if (head_count (me)) return true; else // if there are no note-heads, we might want stemlets return 0.0 == robust_scm2double (me->get_property ("stemlet-length"), 0.0); } bool Stem::is_normal_stem (Grob *me) { if (!head_count (me)) return false; return scm_to_int (me->get_property ("duration-log")) >= 1; } MAKE_SCHEME_CALLBACK (Stem, pure_height, 3) SCM Stem::pure_height (SCM smob, SCM /* start */, SCM /* end */) { Grob *me = Grob::unsmob (smob); return ly_interval2scm (internal_pure_height (me, true)); } Interval Stem::internal_pure_height (Grob *me, bool calc_beam) { if (!is_normal_stem (me)) return Interval (0.0, 0.0); Grob *beam = Grob::unsmob (me->get_object ("beam")); Interval iv = internal_height (me, false); if (!beam) return iv; if (calc_beam) { Interval overshoot; Direction dir = get_grob_direction (me); for (DOWN_and_UP (d)) overshoot[d] = d == dir ? dir * infinity_f : iv[d]; vector heights; vector my_stems; extract_grob_set (beam, "normal-stems", normal_stems); for (vsize i = 0; i < normal_stems.size (); i++) if (get_grob_direction (normal_stems[i]) == dir) { if (normal_stems[i] != me) heights.push_back (Stem::internal_pure_height (normal_stems[i], false)); else heights.push_back (iv); my_stems.push_back (normal_stems[i]); } //iv.unite (heights.back ()); // look for cross staff effects vector coords; Grob *common = common_refpoint_of_array (my_stems, me, Y_AXIS); Real min_pos = infinity_f; Real max_pos = -infinity_f; for (vsize i = 0; i < my_stems.size (); i++) { coords.push_back (my_stems[i]->pure_relative_y_coordinate (common, 0, INT_MAX)); min_pos = min (min_pos, coords[i]); max_pos = max (max_pos, coords[i]); } for (vsize i = 0; i < heights.size (); i++) { heights[i][dir] += dir == DOWN ? coords[i] - max_pos : coords[i] - min_pos; } for (vsize i = 0; i < heights.size (); i++) iv.unite (heights[i]); for (vsize i = 0; i < my_stems.size (); i++) cache_pure_height (my_stems[i], iv, heights[i]); iv.intersect (overshoot); } return iv; } void Stem::cache_pure_height (Grob *me, Interval iv, Interval my_iv) { Interval overshoot; Direction dir = get_grob_direction (me); for (DOWN_and_UP (d)) overshoot[d] = d == dir ? dir * infinity_f : my_iv[d]; iv.intersect (overshoot); dynamic_cast (me)->cache_pure_height (iv); } MAKE_SCHEME_CALLBACK (Stem, calc_stem_end_position, 1) SCM Stem::calc_stem_end_position (SCM smob) { Grob *me = Grob::unsmob (smob); return scm_from_double (internal_calc_stem_end_position (me, true)); } MAKE_SCHEME_CALLBACK (Stem, pure_calc_stem_end_position, 3) SCM Stem::pure_calc_stem_end_position (SCM smob, SCM, /* start */ SCM /* end */) { Grob *me = Grob::unsmob (smob); return scm_from_double (internal_calc_stem_end_position (me, false)); } Real Stem::internal_calc_stem_end_position (Grob *me, bool calc_beam) { if (!head_count (me)) return 0.0; Grob *beam = get_beam (me); Real ss = Staff_symbol_referencer::staff_space (me); Direction dir = get_grob_direction (me); if (beam && calc_beam) { (void) beam->get_property ("quantized-positions"); return robust_scm2double (me->get_property ("length"), 0.0) + dir * robust_scm2double (me->get_property ("stem-begin-position"), 0.0); } vector a; /* WARNING: IN HALF SPACES */ SCM details = me->get_property ("details"); int durlog = duration_log (me); Real staff_rad = Staff_symbol_referencer::staff_radius (me); Real length = 7; SCM s = ly_assoc_get (ly_symbol2scm ("lengths"), details, SCM_EOL); if (scm_is_pair (s)) length = 2 * scm_to_double (robust_list_ref (durlog - 2, s)); /* Stems in unnatural (forced) direction should be shortened, according to [Roush & Gourlay] */ Interval hp = head_positions (me); if (dir && dir * hp[dir] >= 0) { SCM sshorten = ly_assoc_get (ly_symbol2scm ("stem-shorten"), details, SCM_EOL); SCM scm_shorten = scm_is_pair (sshorten) ? robust_list_ref (max (duration_log (me) - 2, 0), sshorten) : SCM_EOL; Real shorten_property = 2 * robust_scm2double (scm_shorten, 0); /* change in length between full-size and shortened stems is executed gradually. "transition area" = stems between full-sized and fully-shortened. */ Real quarter_stem_length = 2 * scm_to_double (robust_list_ref (0, s)); /* shortening_step = difference in length between consecutive stem lengths in transition area. The bigger the difference between full-sized and shortened stems, the bigger shortening_step is. (but not greater than 1/2 and not smaller than 1/4). value 6 is heuristic; it determines the suggested transition slope steepnesas. */ Real shortening_step = min (max (0.25, (shorten_property / 6)), 0.5); /* Shortening of unflagged stems should begin on the first stem that sticks more than 1 staffspace (2 units) out of the staff. Shortening of flagged stems begins in the same moment as unflagged ones, but not earlier than on the middle line note. */ Real which_step = (min (1.0, quarter_stem_length - (2 * staff_rad) - 2.0)) + abs (hp[dir]); Real shorten = min (max (0.0, (shortening_step * which_step)), shorten_property); length -= shorten; } length *= robust_scm2double (me->get_property ("length-fraction"), 1.0); /* Tremolo stuff. */ Grob *t_flag = Grob::unsmob (me->get_object ("tremolo-flag")); if (t_flag && (!Grob::is_smob (me->get_object ("beam")) || !calc_beam)) { /* Crude hack: add extra space if tremolo flag is there. We can't do this for the beam, since we get into a loop (Stem_tremolo::raw_stencil () looks at the beam.) --hwn */ Real minlen = 1.0 + 2 * Stem_tremolo::vertical_length (t_flag) / ss; /* We don't want to add the whole extent of the flag because the trem and the flag can overlap partly. beam_translation gives a good approximation */ if (durlog >= 3) { Real beam_trans = Stem_tremolo::get_beam_translation (t_flag); /* the obvious choice is (durlog - 2) here, but we need a bit more space. */ minlen += 2 * (durlog - 1.5) * beam_trans; /* up-stems need even a little more space to avoid collisions. This needs to be in sync with the tremolo positioning code in Stem_tremolo::print */ if (dir == UP) minlen += beam_trans; } length = max (length, minlen + 1.0); } Real stem_end = dir ? hp[dir] + dir * length : 0; /* TODO: change name to extend-stems to staff/center/'() */ bool no_extend = to_boolean (me->get_property ("no-stem-extend")); if (!no_extend && dir * stem_end < 0) stem_end = 0.0; return stem_end; } /* The log of the duration (Number of hooks on the flag minus two) */ int Stem::duration_log (Grob *me) { SCM s = me->get_property ("duration-log"); return (scm_is_number (s)) ? scm_to_int (s) : 2; } MAKE_SCHEME_CALLBACK (Stem, calc_positioning_done, 1); SCM Stem::calc_positioning_done (SCM smob) { Grob *me = Grob::unsmob (smob); if (!head_count (me)) return SCM_BOOL_T; me->set_property ("positioning-done", SCM_BOOL_T); extract_grob_set (me, "note-heads", ro_heads); vector heads (ro_heads); vector_sort (heads, position_less); Direction dir = get_grob_direction (me); if (dir < 0) reverse (heads); Real thick = thickness (me); Grob *hed = support_head (me); if (!dir) { programming_error ("Stem dir must be up or down."); dir = UP; set_grob_direction (me, dir); } bool is_harmonic_centered = false; for (vsize i = 0; i < heads.size (); i++) is_harmonic_centered = is_harmonic_centered || heads[i]->get_property ("style") == ly_symbol2scm ("harmonic"); is_harmonic_centered = is_harmonic_centered && is_invisible (me); Real w = hed->extent (hed, X_AXIS)[dir]; for (vsize i = 0; i < heads.size (); i++) { Real amount = w - heads[i]->extent (heads[i], X_AXIS)[dir]; if (is_harmonic_centered) amount = hed->extent (hed, X_AXIS).linear_combination (CENTER) - heads[i]->extent (heads[i], X_AXIS).linear_combination (CENTER); if (!isnan (amount)) // empty heads can produce NaN heads[i]->translate_axis (amount, X_AXIS); } bool parity = true; Real lastpos = Real (Staff_symbol_referencer::get_position (heads[0])); for (vsize i = 1; i < heads.size (); i++) { Real p = Staff_symbol_referencer::get_position (heads[i]); Real dy = fabs (lastpos - p); /* dy should always be 0.5, 0.0, 1.0, but provide safety margin for rounding errors. */ if (dy < 1.1) { if (parity) { Real ell = heads[i]->extent (heads[i], X_AXIS).length (); Direction d = get_grob_direction (me); /* Reversed head should be shifted ell-thickness, but this looks too crowded, so we only shift ell-0.5*thickness. This leads to assymetry: Normal heads overlap the stem 100% whereas reversed heads only overlaps the stem 50% */ Real reverse_overlap = 0.5; /* However, the first reverse head has to be shifted even more than the full reverse overlap if it is the same height as the first head or there will be a gap because of the head slant (issue 346). */ if (i == 1 && dy < 0.1) reverse_overlap = 1.1; if (is_invisible (me)) { // Semibreves and longer are tucked in considerably // to be recognizable as chorded rather than // parallel voices. During the course of issue 346 // there was a discussion to change this for unisons // (dy < 0.1) to reduce overlap but without reaching // agreement and with Gould being rather on the // overlapping front. reverse_overlap = 2; } heads[i]->translate_axis ((ell - thick * reverse_overlap) * d, X_AXIS); /* TODO: For some cases we should kern some more: when the distance between the next or prev note is too large, we'd get large white gaps, eg. | X| |X <- kern this. | X */ } parity = !parity; } else parity = true; lastpos = int (p); } return SCM_BOOL_T; } MAKE_SCHEME_CALLBACK (Stem, calc_direction, 1); SCM Stem::calc_direction (SCM smob) { Grob *me = Grob::unsmob (smob); Direction dir = CENTER; if (Grob *beam = Grob::unsmob (me->get_object ("beam"))) { SCM ignore_me = beam->get_property ("direction"); (void) ignore_me; dir = get_grob_direction (me); } else { SCM dd = me->get_property ("default-direction"); dir = to_dir (dd); if (!dir) return me->get_property ("neutral-direction"); } return scm_from_int (dir); } MAKE_SCHEME_CALLBACK (Stem, calc_default_direction, 1); SCM Stem::calc_default_direction (SCM smob) { Grob *me = Grob::unsmob (smob); Direction dir = CENTER; int staff_center = 0; Interval hp = head_positions (me); if (!hp.is_empty ()) { int udistance = (int) (UP * hp[UP] - staff_center); int ddistance = (int) (DOWN * hp[DOWN] - staff_center); dir = Direction (sign (ddistance - udistance)); } return scm_from_int (dir); } // note - height property necessary to trigger quantized beam positions // otherwise, we could just use Grob::stencil_height_proc MAKE_SCHEME_CALLBACK (Stem, height, 1); SCM Stem::height (SCM smob) { Grob *me = Grob::unsmob (smob); return ly_interval2scm (internal_height (me, true)); } Grob * Stem::get_reference_head (Grob *me) { return to_boolean (me->get_property ("avoid-note-head")) ? last_head (me) : first_head (me); } Real Stem::beam_end_corrective (Grob *me) { Grob *beam = Grob::unsmob (me->get_object ("beam")); Direction dir = get_grob_direction (me); if (beam) { if (dir == CENTER) { programming_error ("no stem direction"); dir = UP; } return dir * Beam::get_beam_thickness (beam) * 0.5; } return 0.0; } Interval Stem::internal_height (Grob *me, bool calc_beam) { Grob *beam = get_beam (me); if (!is_valid_stem (me) && !beam) return Interval (); Direction dir = get_grob_direction (me); if (beam && calc_beam) { /* trigger set-stem-lengths. */ (void) beam->get_property ("quantized-positions"); } /* If there is a beam but no stem, slope calculations depend on this routine to return where the stem end /would/ be. */ if (calc_beam && !beam && !Stencil::is_smob (me->get_property ("stencil"))) return Interval (); Real y1 = robust_scm2double ((calc_beam ? me->get_property ("stem-begin-position") : me->get_pure_property ("stem-begin-position", 0, INT_MAX)), 0.0); Real y2 = dir * robust_scm2double ((calc_beam ? me->get_property ("length") : me->get_pure_property ("length", 0, INT_MAX)), 0.0) + y1; Real half_space = Staff_symbol_referencer::staff_space (me) * 0.5; Interval stem_y = Interval (min (y1, y2), max (y2, y1)) * half_space; return stem_y; } MAKE_SCHEME_CALLBACK (Stem, width, 1); SCM Stem::width (SCM e) { Grob *me = Grob::unsmob (e); Interval r; if (is_invisible (me)) r.set_empty (); else { r = Interval (-1, 1); r *= thickness (me) / 2; } return ly_interval2scm (r); } Real Stem::thickness (Grob *me) { return scm_to_double (me->get_property ("thickness")) * Staff_symbol_referencer::line_thickness (me); } MAKE_SCHEME_CALLBACK (Stem, calc_stem_begin_position, 1); SCM Stem::calc_stem_begin_position (SCM smob) { Grob *me = Grob::unsmob (smob); return scm_from_double (internal_calc_stem_begin_position (me, true)); } MAKE_SCHEME_CALLBACK (Stem, pure_calc_stem_begin_position, 3); SCM Stem::pure_calc_stem_begin_position (SCM smob, SCM, /* start */ SCM /* end */) { Grob *me = Grob::unsmob (smob); return scm_from_double (internal_calc_stem_begin_position (me, false)); } Real Stem::internal_calc_stem_begin_position (Grob *me, bool calc_beam) { Grob *beam = get_beam (me); Real ss = Staff_symbol_referencer::staff_space (me); if (beam && calc_beam) { (void) beam->get_property ("quantized-positions"); return robust_scm2double (me->get_property ("stem-begin-position"), 0.0); } Direction d = get_grob_direction (me); Grob *lh = get_reference_head (me); if (!lh) return 0.0; Real pos = Staff_symbol_referencer::get_position (lh); if (Grob *head = support_head (me)) { Interval head_height = head->extent (head, Y_AXIS); Real y_attach = Note_head::stem_attachment_coordinate (head, Y_AXIS); y_attach = head_height.linear_combination (y_attach); if (!isinf (y_attach) && !isnan (y_attach)) // empty heads pos += d * y_attach * 2 / ss; } return pos; } MAKE_SCHEME_CALLBACK (Stem, pure_calc_length, 3); SCM Stem::pure_calc_length (SCM smob, SCM /*start*/, SCM /*end*/) { Grob *me = Grob::unsmob (smob); Real beg = robust_scm2double (me->get_pure_property ("stem-begin-position", 0, INT_MAX), 0.0); Real res = fabs (internal_calc_stem_end_position (me, false) - beg); return scm_from_double (res); } MAKE_SCHEME_CALLBACK (Stem, calc_length, 1); SCM Stem::calc_length (SCM smob) { Grob *me = Grob::unsmob (smob); if (Grob::is_smob (me->get_object ("beam"))) { me->programming_error ("ly:stem::calc-length called but will not be used for beamed stem."); return scm_from_double (0.0); } Real beg = robust_scm2double (me->get_property ("stem-begin-position"), 0.0); Real res = fabs (internal_calc_stem_end_position (me, true) - beg); return scm_from_double (res); } bool Stem::is_valid_stem (Grob *me) { /* TODO: make the stem start a direction ? This is required to avoid stems passing in tablature chords. */ if (!me) return false; Grob *lh = get_reference_head (me); Grob *beam = Grob::unsmob (me->get_object ("beam")); if (!lh && !beam) return false; if (is_invisible (me)) return false; return true; } MAKE_SCHEME_CALLBACK (Stem, print, 1); SCM Stem::print (SCM smob) { Grob *me = Grob::unsmob (smob); if (!is_valid_stem (me)) return SCM_EOL; Direction dir = get_grob_direction (me); Real y1 = robust_scm2double (me->get_property ("stem-begin-position"), 0.0); Real y2 = dir * robust_scm2double (me->get_property ("length"), 0.0) + y1; Real half_space = Staff_symbol_referencer::staff_space (me) * 0.5; Interval stem_y = Interval (min (y1, y2), max (y2, y1)) * half_space; stem_y[dir] -= beam_end_corrective (me); // URG Real stem_width = thickness (me); Real blot = me->layout ()->get_dimension (ly_symbol2scm ("blot-diameter")); Box b = Box (Interval (-stem_width / 2, stem_width / 2), stem_y); Stencil mol; Stencil ss = Lookup::round_filled_box (b, blot); mol.add_stencil (ss); return mol.smobbed_copy (); } /* move the stem to right of the notehead if it is up. */ MAKE_SCHEME_CALLBACK (Stem, offset_callback, 1); SCM Stem::offset_callback (SCM smob) { Grob *me = Grob::unsmob (smob); extract_grob_set (me, "rests", rests); if (rests.size ()) { Grob *rest = rests.back (); Real r = rest->extent (rest, X_AXIS).center (); return scm_from_double (r); } if (Grob *f = first_head (me)) { Interval head_wid = f->extent (f, X_AXIS); Real attach = 0.0; if (is_invisible (me)) attach = 0.0; else attach = Note_head::stem_attachment_coordinate (f, X_AXIS); Direction d = get_grob_direction (me); Real real_attach = head_wid.linear_combination (d * attach); Real r = isnan(real_attach)? 0.0: real_attach; /* If not centered: correct for stem thickness. */ string style = robust_symbol2string (f->get_property ("style"), "default"); if (attach && style != "mensural" && style != "neomensural" && style != "petrucci") { Real rule_thick = thickness (me); r += -d * rule_thick * 0.5; } return scm_from_double (r); } programming_error ("Weird stem."); return scm_from_double (0.0); } Spanner * Stem::get_beam (Grob *me) { SCM b = me->get_object ("beam"); return dynamic_cast (Grob::unsmob (b)); } Stem_info Stem::get_stem_info (Grob *me) { Stem_info si; si.dir_ = get_grob_direction (me); SCM scm_info = me->get_property ("stem-info"); si.ideal_y_ = scm_to_double (scm_car (scm_info)); si.shortest_y_ = scm_to_double (scm_cadr (scm_info)); return si; } MAKE_SCHEME_CALLBACK (Stem, calc_stem_info, 1); SCM Stem::calc_stem_info (SCM smob) { Grob *me = Grob::unsmob (smob); Direction my_dir = get_grob_direction (me); if (!my_dir) { programming_error ("no stem dir set"); my_dir = UP; } Real staff_space = Staff_symbol_referencer::staff_space (me); Grob *beam = get_beam (me); if (beam) { (void) beam->get_property ("beaming"); } Real beam_translation = Beam::get_beam_translation (beam); Real beam_thickness = Beam::get_beam_thickness (beam); int beam_count = Beam::get_direction_beam_count (beam, my_dir); Real length_fraction = robust_scm2double (me->get_property ("length-fraction"), 1.0); /* Simple standard stem length */ SCM details = me->get_property ("details"); SCM lengths = ly_assoc_get (ly_symbol2scm ("beamed-lengths"), details, SCM_EOL); Real ideal_length = (scm_is_pair (lengths) ? (scm_to_double (robust_list_ref (beam_count - 1, lengths)) * staff_space * length_fraction /* stem only extends to center of beam */ - 0.5 * beam_thickness) : 0.0); /* Condition: sane minimum free stem length (chord to beams) */ lengths = ly_assoc_get (ly_symbol2scm ("beamed-minimum-free-lengths"), details, SCM_EOL); Real ideal_minimum_free = (scm_is_pair (lengths) ? (scm_to_double (robust_list_ref (beam_count - 1, lengths)) * staff_space * length_fraction) : 0.0); Real height_of_my_trem = 0.0; Grob *trem = Grob::unsmob (me->get_object ("tremolo-flag")); if (trem) { height_of_my_trem = Stem_tremolo::vertical_length (trem) /* hack a bit of space around the trem. */ + beam_translation; } /* UGH It seems that also for ideal minimum length, we must use the maximum beam count (for this direction): \score { \relative c'' { a8[ a32] } } must be horizontal. */ Real height_of_my_beams = beam_thickness + (beam_count - 1) * beam_translation; Real ideal_minimum_length = ideal_minimum_free + height_of_my_beams + height_of_my_trem /* stem only extends to center of beam */ - 0.5 * beam_thickness; ideal_length = max (ideal_length, ideal_minimum_length); /* Convert to Y position, calculate for dir == UP */ Real note_start = /* staff positions */ head_positions (me)[my_dir] * 0.5 * my_dir * staff_space; Real ideal_y = note_start + ideal_length; /* Conditions for Y position */ /* Lowest beam of (UP) beam must never be lower than second staffline Reference? Although this (additional) rule is probably correct, I expect that highest beam (UP) should also never be lower than middle staffline, just as normal stems. Reference? Obviously not for grace beams. Also, not for knees. Seems to be a good thing. */ bool no_extend = to_boolean (me->get_property ("no-stem-extend")); bool is_knee = Beam::is_knee (beam); if (!no_extend && !is_knee) { /* Highest beam of (UP) beam must never be lower than middle staffline */ ideal_y = max (ideal_y, 0.0); /* Lowest beam of (UP) beam must never be lower than second staffline */ ideal_y = max (ideal_y, (-staff_space - beam_thickness + height_of_my_beams)); } ideal_y -= robust_scm2double (beam->get_property ("shorten"), 0); SCM bemfl = ly_assoc_get (ly_symbol2scm ("beamed-extreme-minimum-free-lengths"), details, SCM_EOL); Real minimum_free = (scm_is_pair (bemfl) ? (scm_to_double (robust_list_ref (beam_count - 1, bemfl)) * staff_space * length_fraction) : 0.0); Real minimum_length = max (minimum_free, height_of_my_trem) + height_of_my_beams /* stem only extends to center of beam */ - 0.5 * beam_thickness; ideal_y *= my_dir; Real minimum_y = note_start + minimum_length; Real shortest_y = minimum_y * my_dir; return scm_list_2 (scm_from_double (ideal_y), scm_from_double (shortest_y)); } Slice Stem::beam_multiplicity (Grob *stem) { SCM beaming = stem->get_property ("beaming"); Slice le = int_list_to_slice (scm_car (beaming)); Slice ri = int_list_to_slice (scm_cdr (beaming)); le.unite (ri); return le; } bool Stem::is_cross_staff (Grob *stem) { Grob *beam = Grob::unsmob (stem->get_object ("beam")); return beam && Beam::is_cross_staff (beam); } MAKE_SCHEME_CALLBACK (Stem, calc_cross_staff, 1) SCM Stem::calc_cross_staff (SCM smob) { return scm_from_bool (is_cross_staff (Grob::unsmob (smob))); } Grob * Stem::flag (Grob *me) { return Grob::unsmob (me->get_object ("flag")); } /* FIXME: Too many properties */ ADD_INTERFACE (Stem, "The stem represents the graphical stem. In addition, it" " internally connects note heads, beams, and tremolos. Rests" " and whole notes have invisible stems.\n" "\n" "The following properties may be set in the @code{details}" " list.\n" "\n" "@table @code\n" "@item beamed-lengths\n" "List of stem lengths given beam multiplicity.\n" "@item beamed-minimum-free-lengths\n" "List of normal minimum free stem lengths (chord to beams)" " given beam multiplicity.\n" "@item beamed-extreme-minimum-free-lengths\n" "List of extreme minimum free stem lengths (chord to beams)" " given beam multiplicity.\n" "@item lengths\n" "Default stem lengths. The list gives a length for each" " flag count.\n" "@item stem-shorten\n" "How much a stem in a forced direction should be shortened." " The list gives an amount depending on the number of flags" " and beams.\n" "@end table\n", /* properties */ "avoid-note-head " "beam " "beaming " "beamlet-default-length " "beamlet-max-length-proportion " "default-direction " "details " "direction " "double-stem-separation " "duration-log " "flag " "french-beaming " "length " "length-fraction " "max-beam-connect " "melody-spanner " "neutral-direction " "no-stem-extend " "note-heads " "positioning-done " "rests " "stem-begin-position " "stem-info " "stemlet-length " "thickness " "tremolo-flag " "tuplet-start " ); /****************************************************************/ Stem_info::Stem_info () { ideal_y_ = shortest_y_ = 0; dir_ = CENTER; } void Stem_info::scale (Real x) { ideal_y_ *= x; shortest_y_ *= x; }