#include "constrained-breaking.hh"
-#include "warn.hh"
+#include "international.hh"
#include "main.hh"
+#include "output-def.hh"
#include "paper-column.hh"
#include "paper-score.hh"
-#include "output-def.hh"
#include "simple-spacer.hh"
#include "system.hh"
+#include "warn.hh"
-#include "international.hh"
-
-void
-print_constrained_break_nodes (vector<Constrained_break_node> const &arr)
-{
- for (vsize i = 0; i < arr.size (); i++)
- {
- printf ("node %d: ", (int)i);
- arr[i].print ();
- }
-}
-
-/**
- We use the following optimal substructure. Let W(A) be our weight function.
-
- Let A_{k,n} = (a_{k,n,1}, ... a_{k,n,k}) be the optimal set of line breaks
- for k systems and n potential breakpoints. a_{k,n,k} = n (it is the end of
- the piece)
-
- Then A_{k+1, m} is contructed from
- min_ {k < j < m} ( W(A_{k,j} :: m) )
- where by A::m we denote appending m to the list A
+/*
+ We use the following optimal substructure. Let W(A) be our weight function.
+
+ Let A_{k,n} = (a_{k,n,1}, ... a_{k,n,k}) be the optimal set of line breaks
+ for k systems and n potential breakpoints. a_{k,n,k} = n (it is the end of
+ the piece)
+
+ Then A_{k+1, m} is contructed from
+ min_ {k < j < m} ( W(A_{k,j} :: m) )
+ where by A::m we denote appending m to the list A
+
+ Indices in the code:
+
+ The above algorithm makes it easy to end at a point before the end of the
+ score (just find A_{k,m} for some m < breaks_.size () - 1). However, we must
+ add information for starting at a point after the beginning. One constructor
+ allows the specification of a list of starting columns, start_. We then have
+ start_.size () different solution arrays. state_[i] is the array for the
+ solution starting at column number start_[i].
+
+ The indicies "start" and "end" refer to the index in the start_ array of the
+ desired starting and ending columns.
+
+ each solution array looks like
+ a_{1,1,1} a_{2,1,2} a_{3,1,3} . . .
+ X a_{2,2,2} a_{3,2,3} . . .
+ X X a_{3,3,3} . . .
+ . . . .
+ . . . .
+ where the X's mark invalid solutions (can't have more systems than
+ breakpoints). Note that each value is of the form a_{x,n,x}. This is because
+ a breakpoint of the form a_{x,n,x-1} will also be called a_{x-1,m,x-1} for
+ some m < n. Each cell in the array stores the value of its m (ie. the
+ ending breakpoint of the previous line) as "prev_".
+
+ For finding A_{sys, brk}, let "me" be the (sys_count,brk) cell in our
+ solution array (state_[start][sys * rank + brk]).
+
+ Then A_{sys, brk} = A_{sys - 1, me.prev_} :: me
*/
-/* start and sys here are indexed from 0.
- * max_break is indexed from starting_breakpoints_[start]
- * (for max_break, starting_breakpoints_[start] is the beginning
- * of the piece; the smallest value we should ever see here is
- * starting_breakpoints_[start] + 1) */
+/*
+ start and sys here are indexed from 0.
+ brk is indexed from starting_breakpoints_[start]
+ (for brk, starting_breakpoints_[start] is the beginning
+ of the piece; the smallest value we should ever see here is
+ starting_breakpoints_[start] + 1) */
bool
-Constrained_breaking::calc_subproblem (int start, int sys, int max_break)
+Constrained_breaking::calc_subproblem (vsize start, vsize sys, vsize brk)
{
assert (sys < systems_);
- assert (start < (int)start_.size ());
- assert (max_break < (int)breaks_.size ());
+ assert (start < start_.size ());
+ assert (brk < breaks_.size ());
bool found_something = false;
- int start_col = starting_breakpoints_[start];
+ vsize start_col = starting_breakpoints_[start];
vector<Constrained_break_node> &st = state_[start];
- int rank = breaks_.size () - start_col;
- int max_index = max_break - start_col;
- for (int j=sys; j < max_index; j++)
+ vsize rank = breaks_.size () - start_col;
+ vsize max_index = brk - start_col;
+ for (vsize j=sys; j < max_index; j++)
{
if (0 == sys && j > 0)
break; /* the first line cannot have its first break after the beginning */
- Column_x_positions const &cur = cols_[(j + start_col)*cols_rank_ + max_break];
- Column_x_positions prev;
+ Line_details const &cur = lines_[(j + start_col)*lines_rank_ + brk];
+ Real prev_f = 0;
Real prev_dem = 0;
if (sys > 0)
{
- prev = st[(sys-1) * rank + j].line_config_;
+ prev_f = st[(sys-1) * rank + j].details_.force_;
prev_dem = st[(sys-1) * rank + j].demerits_;
}
if (isinf (prev_dem))
break;
- Real dem, force, pen;
- combine_demerits(prev, cur, &force, &pen, &dem);
- dem += prev_dem;
+ Real dem = combine_demerits (cur.force_, prev_f) + prev_dem + cur.break_penalty_;
if (isinf (dem))
continue;
- if (isinf (st[sys*rank + max_index].demerits_)
- || dem < st[sys*rank + max_index].demerits_)
+ int k = sys*rank + max_index;
+ if (isinf (st[k].demerits_) || dem < st[k].demerits_)
{
found_something = true;
- st[sys*rank + max_index].demerits_ = dem;
- st[sys*rank + max_index].force_ = force;
- st[sys*rank + max_index].penalty_ = pen;
- st[sys*rank + max_index].prev_ = j;
- st[sys*rank + max_index].line_config_ = cur;
+ st[k].demerits_ = dem;
+ st[k].details_ = cur;
+ st[k].prev_ = j;
}
}
return found_something;
}
vector<Column_x_positions>
-Constrained_breaking::do_solve ()
+Constrained_breaking::solve ()
{
if (!systems_)
{
programming_error (_f ("no system number set in constrained-breaking"));
- systems_ = 4;
+ systems_ = breaks_.size () / 4;
}
- resize ();
- return get_solution(0, systems_, -1);
+ resize (systems_);
+ return get_solution(0, VPOS, systems_);
+}
+
+Column_x_positions
+Constrained_breaking::space_line (vsize i, vsize j)
+{
+ bool ragged_right = to_boolean (pscore_->layout ()->c_variable ("ragged-right"));
+ bool ragged_last = to_boolean (pscore_->layout ()->c_variable ("ragged-last"));
+ Column_x_positions col;
+
+ vector<Grob*> line (all_.begin () + breaks_[i],
+ all_.begin() + breaks_[j] + 1);
+ Interval line_dims = line_dimensions_int (pscore_->layout (), i);
+ bool last = j == breaks_.size () - 1;
+ bool ragged = ragged_right || (last && ragged_last);
+
+ return get_line_configuration (line, line_dims[RIGHT] - line_dims[LEFT], line_dims[LEFT], ragged);
}
void
-Constrained_breaking::resize ()
+Constrained_breaking::resize (vsize systems)
{
- if (!breaks_.size ())
+ systems_ = systems;
+
+ if (!breaks_.size () && pscore_)
{
+ Output_def *l = pscore_->layout ();
+ Real extent = scm_to_double (l->c_variable ("system-height"));
+ Real padding = scm_to_double (l->c_variable ("between-system-padding"));
+ Real space = scm_to_double (l->c_variable ("between-system-space"));
bool ragged_right = to_boolean (pscore_->layout ()->c_variable ("ragged-right"));
bool ragged_last = to_boolean (pscore_->layout ()->c_variable ("ragged-last"));
+ Interval first_line = line_dimensions_int (pscore_->layout (), 0);
+ Interval other_lines = line_dimensions_int (pscore_->layout (), 1);
/* do all the rod/spring problems */
- breaks_ = find_break_indices ();
- cols_rank_ = breaks_.size ();
+ breaks_ = pscore_->find_break_indices ();
+ lines_rank_ = breaks_.size ();
all_ = pscore_->root_system ()->columns ();
- cols_.resize (breaks_.size () * breaks_.size ());
+ lines_.resize (breaks_.size () * breaks_.size ());
+ vector<Real> forces = get_line_forces (all_,
+ breaks_,
+ other_lines.length (),
+ other_lines.length () - first_line.length (),
+ ragged_right);
for (vsize i = 0; i < breaks_.size () - 1; i++)
+ {
for (vsize j = i + 1; j < breaks_.size (); j++)
{
- vector<Grob*> line (all_.begin () + breaks_[i],
- all_.begin() + breaks_[j] + 1);
-
- line[0] = dynamic_cast<Item *> (line[0])->find_prebroken_piece (RIGHT);
- line.back () = dynamic_cast<Item *> (line.back ())->find_prebroken_piece (LEFT);
-
- cols_[i*cols_rank_ + j].cols_ = line;
-
- /* we have no idea what line this will be -- only whether it is the first */
- Interval line_dims = line_dimensions_int (pscore_->layout (), i);
- Simple_spacer_wrapper *sp = generate_spacing_problem (line, line_dims);
-
- /* TODO: support raggedness */
- bool last = j == breaks_.size () - 1;
- bool ragged = ragged_right || (last && ragged_last);
- sp->solve (&cols_[i*cols_rank_ + j], ragged);
-
- if (!cols_[i*cols_rank_ + j].satisfies_constraints_)
+ bool last = j == breaks_.size () - 1;
+ bool ragged = ragged_right || (last && ragged_last);
+ int k = i*lines_rank_ + j;
+ SCM pen = all_[breaks_[j]]->get_property ("line-break-penalty");
+ if (scm_is_number (pen))
+ lines_[k].break_penalty_ = scm_to_double (pen);
+
+ lines_[k].force_ = forces[k];
+ lines_[k].extent_ = extent;
+ lines_[k].padding_ = padding;
+ lines_[k].space_ = space;
+ lines_[k].inverse_hooke_ = 3; // FIXME: somewhat arbitrary
+ if (ragged && lines_[k].force_ < 0)
+ lines_[k].force_ = infinity_f;
+ if (isinf (lines_[k].force_))
break;
- delete sp;
}
+ }
/* work out all the starting indices */
for (vsize i = 0; i < start_.size (); i++)
state_.resize (start_.size ());
}
- for (vsize i = 0; i < state_.size (); i++)
- state_[i].resize((breaks_.size () - starting_breakpoints_[i]) * systems_);
-
- /* fill out the matrices */
- for (vsize i = 0; i < state_.size (); i++)
- for (int j = valid_systems_; j < systems_; j++)
- for (vsize k = starting_breakpoints_[i] + j + 1; k < breaks_.size (); k++)
- if (!calc_subproblem (i, j, k))
- break; /* if we couldn't break this, it is too cramped already */
- valid_systems_ = systems_;
+ if (pscore_ && systems_ > valid_systems_)
+ {
+ for (vsize i = 0; i < state_.size (); i++)
+ state_[i].resize((breaks_.size () - starting_breakpoints_[i]) * systems_);
+
+ /* fill out the matrices */
+ for (vsize i = 0; i < state_.size (); i++)
+ for (vsize j = valid_systems_; j < systems_; j++)
+ for (vsize k = starting_breakpoints_[i] + j + 1; k < breaks_.size (); k++)
+ if (!calc_subproblem (i, j, k))
+ break; /* if we couldn't break this, it is too cramped already */
+ valid_systems_ = systems_;
+ }
}
vector<Column_x_positions>
-Constrained_breaking::get_solution (int start, int end, int sys_count)
+Constrained_breaking::get_solution (vsize start, vsize end, vsize sys_count)
{
- int rank, brk;
- prepare_solution (start, end, sys_count, &rank, &brk);
+ vsize rank;
+ vsize end_brk;
+ vsize start_brk = starting_breakpoints_[start];
+ prepare_solution (start, end, sys_count, &rank, &end_brk);
vector<Constrained_break_node> const &st = state_[start];
vector<Column_x_positions> ret;
- for (int sys = sys_count-1; sys >= 0; sys--)
+ /* find the first solution that satisfies constraints */
+ for (vsize sys = sys_count-1; sys != VPOS; sys--)
{
- assert (brk > 0);
- ret.push_back( st[sys*rank + brk].line_config_ );
- brk = st[sys*rank + brk].prev_;
+ for (vsize brk = end_brk; brk != VPOS; brk--)
+ {
+ if (!isinf (st[sys*rank + brk].details_.force_))
+ {
+ if (brk != end_brk)
+ {
+ warning ( _("couldn't find line breaking that satisfies constraints" ));
+ ret.push_back (space_line (brk, end_brk));
+ }
+ /* build up the good solution */
+ for (vsize cur_sys = sys; cur_sys != VPOS; cur_sys--)
+ {
+ vsize prev_brk = st[cur_sys*rank + brk].prev_;
+ assert (brk != VPOS);
+ ret.push_back (space_line (prev_brk + start_brk, brk + start_brk));
+ brk = prev_brk;
+ }
+ reverse (ret);
+ return ret;
+ }
+ }
}
- assert (brk == 0);
- reverse (ret);
+ /* if we get to here, just put everything on one line */
+ warning ( _("couldn't find line breaking that satisfies constraints" ));
+ ret.push_back (space_line (0, end_brk));
return ret;
}
-Real
-Constrained_breaking::get_demerits (int start, int end, int sys_count)
+std::vector<Line_details>
+Constrained_breaking::get_details (vsize start, vsize end, vsize sys_count)
{
- int rank, brk;
- prepare_solution (start, end, sys_count, &rank, &brk);
-
- return state_[start][(sys_count-1)*rank + brk].demerits_;
-}
-
-Real
-Constrained_breaking::get_force (int start, int end, int sys_count)
-{
- int rank, brk;
+ vsize rank;
+ vsize brk;
prepare_solution (start, end, sys_count, &rank, &brk);
vector<Constrained_break_node> const &st = state_[start];
- Real f = 0;
+ vector<Line_details> ret;
- for (int sys = sys_count-1; sys >= 0 && brk >= 0; sys--)
+ for (int sys = sys_count-1; sys >= 0 && brk != VPOS; sys--)
{
- f += fabs (st[sys*rank + brk].force_);
+ ret.push_back (st[sys*rank + brk].details_);
brk = st[sys*rank + brk].prev_;
}
- if (brk < 0)
- f = infinity_f;
-
- return f;
-}
-
-Real
-Constrained_breaking::get_penalty (int start, int end, int sys_count)
-{
- int rank, brk;
- prepare_solution (start, end, sys_count, &rank, &brk);
-
- return state_[start][(sys_count-1)*rank + brk].penalty_;
-}
-
-Real
-Constrained_breaking::get_page_penalty (int start, int end, int sys_count, int sys_num)
-{
- int rank, brk;
- prepare_solution (start, end, sys_count, &rank, &brk);
-
- int sys;
- for (sys = sys_count-1; sys > sys_num; sys--)
- brk = state_[start][sys*rank + brk].prev_;
-
- if (brk < 0) /* we didn't satisfy constraints */
- return 0;
- vector<Grob*> &cols = state_[start][sys*rank + brk].line_config_.cols_;
- if (cols.empty ())
- return 0;
-
- Grob *pc = cols.back ();
- if (pc->original ())
- {
- SCM pen = pc->get_property ("page-penalty");
- if (scm_is_number (pen) && fabs (scm_to_double (pen)) < 10000)
- return scm_to_double (pen);
- }
- return 0;
+ return ret;
}
int
-Constrained_breaking::get_min_systems (int start, int end)
+Constrained_breaking::get_min_systems (vsize start, vsize end)
{
- int rank, brk;
+ vsize rank;
+ vsize brk;
+ vsize sys_count;
+
prepare_solution (start, end, 1, &rank, &brk);
- int sys_count;
vector<Constrained_break_node> const &st = state_[start];
/* sys_count < rank : rank is the # of breakpoints, we can't have more systems */
{
if (sys_count >= valid_systems_)
{
- systems_ = sys_count + 3;
- resize ();
+ resize (sys_count + 3);
}
- if (!isinf (st[sys_count*rank + brk].force_))
+ if (!isinf (st[sys_count*rank + brk].details_.force_))
return sys_count + 1;
}
/* no possible breaks satisfy constraints */
- return 0;
+ return 1;
}
int
-Constrained_breaking::get_max_systems (int start, int end)
+Constrained_breaking::get_max_systems (vsize start, vsize end)
{
- int brk = (end < 0 || end >= (int)start_.size ()) ? breaks_.size () - 1 : start_[end];
+ vsize brk = (end >= start_.size ()) ? breaks_.size () - 1 : starting_breakpoints_[end];
return brk - starting_breakpoints_[start];
}
void
-Constrained_breaking::prepare_solution (int start, int end, int sys_count, int *rank, int *brk)
+Constrained_breaking::prepare_solution (vsize start, vsize end, vsize sys_count, vsize *rank, vsize *brk)
{
- assert (start < (int)start_.size () && end <= (int)start_.size ());
- assert (end < 0 || start < end);
- assert (sys_count > 0);
+ assert (start < start_.size () && (end == VPOS || end <= start_.size ()));
+ assert (start < end);
- if (sys_count >= valid_systems_)
- {
- systems_ = sys_count;
- resize ();
- }
- if (end == (int)start_.size ())
- end = -1;
+ resize (sys_count);
+ if (end == start_.size ())
+ end = VPOS;
*rank = breaks_.size () - starting_breakpoints_[start];
- *brk = end < 0 ? breaks_.size () - 1 : starting_breakpoints_[end];
+ *brk = end == VPOS ? breaks_.size () - 1 : starting_breakpoints_[end];
*brk -= starting_breakpoints_[start];
}
start_.push_back (0);
}
-Constrained_breaking::Constrained_breaking (vector<int> const &start):
- start_ (start)
+Constrained_breaking::Constrained_breaking (vector<vsize> const &start)
+ : start_ (start)
{
valid_systems_ = systems_ = 0;
}
-void
-Constrained_breaking::combine_demerits (Column_x_positions const &prev,
- Column_x_positions const &col,
- Real *force,
- Real *penalty,
- Real *demerits) const
+Real
+Constrained_breaking::combine_demerits (Real force, Real prev_force)
{
- *penalty = 0;
- if (col.cols_.empty () || !col.satisfies_constraints_)
- *force = infinity_f;
- else
- {
- *force = col.force_;
-
- Grob *pc = col.cols_.back ();
- if (pc->original ())
- {
- SCM pen = pc->get_property ("penalty");
- if (scm_is_number (pen) && fabs (scm_to_double (pen)) < 10000)
- *penalty += scm_to_double (pen);
- }
- }
-
- *demerits = (*force) * (*force) + abs (prev.force_ - *force) + *penalty;
+ return force * force + fabs (prev_force - force);
}