lilypond-0.0.31

[lilypond.git] / src / linespace.cc

#include <math.h>
#include "linespace.hh"
#include "pcol.hh"
#include "debug.hh"
#include "qlp.hh"
#include "unionfind.hh"
#include "idealspacing.hh"

const Real COLFUDGE=1e-3;


bool
Spacing_problem::contains(const PCol *w)
{
    for (int i=0; i< cols.size(); i++)
        if (cols[i].pcol_ == w)
            return true;
    return false;
}

int 
Spacing_problem::col_id(const PCol *w)const
{
    for (int i=0; i< cols.size(); i++)
        if (cols[i].pcol_ == w)
            return i;
    assert(false);
    return -1;
}

void
Spacing_problem::OK() const
{
#ifndef NDEBUG
    Union_find connected(cols.size());
    Array<int> fixed;
    for (int i=0; i < ideals.size(); i++) {
        assert(ideals[i]->hooke > 0);
        int l = col_id(ideals[i]->left);
        int r = col_id(ideals[i]->right);
        connected.connect(l,r);         
    }
    for (int i = 0; i < cols.size(); i++)
        if (cols[i].fixed())
            fixed.push(i);
    for (int i = 0; i < cols.size(); i++) {
        bool c=false;
        for (int j =0; j<fixed.size(); j++)
            c |=  connected.equiv(fixed[j],i);
        if (!c)
            WARN << "You have unconnected columns. \n"
                "Check if bars and music fit each other\n"
                "(crashing :-)\n";
        assert(c);
    }
#endif    
}

bool
Spacing_problem::check_constraints(Vector v) const 
{
    int dim=v.dim();
    for (int i=0; i < dim; i++) {

        if (cols[i].fixed()&&
            abs(cols[i].fixed_position() - v(i)) > COLFUDGE) 
            return false;
        
        if (!i) 
            continue;
        
        Real mindist=cols[i-1].minright()
            +cols[i].minleft();

        // ugh... compares
        Real dif =v(i) - v(i-1)- mindist;
        bool b = (dif > - COLFUDGE);
        

        if (!b)
            return false;

    }
    return true;
}

bool
Spacing_problem::check_feasible() const
{
    Vector sol(try_initial_solution());
    return check_constraints(sol);     
}

// generate a solution which obeys the min distances and fixed positions
Vector
Spacing_problem::try_initial_solution() const
{
    int dim=cols.size();
    Vector initsol(dim);
    for (int i=0; i < dim; i++) {
        if (cols[i].fixed()) {
            initsol(i)=cols[i].fixed_position();            
        } else {
            Real mindist=cols[i-1].minright()
                +cols[i].minleft();
            assert(mindist >= 0.0);
            initsol(i)=initsol(i-1)+mindist;

            //nog niet 
            //if (i>0)
            //  assert(initsol(i) > initsol(i-1));
        }       
    }

    return initsol;
}
Vector
Spacing_problem::find_initial_solution() const
{
    Vector v(try_initial_solution());     
    assert(check_constraints(v));
    return v;
}

// generate the matrices
void
Spacing_problem::make_matrices(Matrix &quad, Vector &lin, Real &c) const
{
    quad.fill(0);
    lin.fill(0);
    c = 0;
    for (int j=0; j < ideals.size(); j++){
        Idealspacing const*i=ideals[j];
        int l = col_id(i->left);
        int r = col_id(i->right);

        quad(r,r) += i->hooke;
        quad(r,l) -= i->hooke;
        quad(l,r) -= i->hooke;
        quad(l,l) += i->hooke;

        lin(r) -= i->space*i->hooke;
        lin(l) += i->space*i->hooke;

        c += sqr(i->space);
    }
}

// put the constraints into the LP problem
void
Spacing_problem::make_constraints(Mixed_qp& lp) const
{    
    int dim=cols.size();
    for (int j=0; j < dim; j++) {
        Colinfo *c=&(cols[j]);
        if (c->fixed()) {
            lp.add_fixed_var(j,c->fixed_position());        
        }
        if (j > 0){
            Vector c1(dim);
            
            c1(j)=1.0 ;
            c1(j-1)=-1.0 ;
            lp.add_inequality_cons(c1, cols[j-1].minright() +
                                   cols[j].minleft());
        }
    }
}

Array<Real>
Spacing_problem::solve() const
{
    print();
    OK();
    assert(check_feasible());

    /* optimalisatiefunctie */        
    Mixed_qp lp(cols.size());
    make_matrices(lp.quad,lp.lin, lp.const_term);
    make_constraints(lp);    
    Vector start=find_initial_solution();    
    Vector sol(lp.solve(start));
    if (!check_constraints(sol)) {
        WARN << "solution doesn't satisfy constraints.\n" ;
    }
        

    Array<Real> posns(sol);
    posns.push(lp.eval(sol));
    return posns;
}

/*
    add one column to the problem.
*/    
void
Spacing_problem::add_column(const PCol *col, bool fixed, Real fixpos)
{
    Colinfo c(col,(fixed)? &fixpos :  0);
    cols.push(c);
}

void
Spacing_problem::add_ideal(const Idealspacing *i)
{
    const PCol *l =i->left;
    const PCol *r= i->right;
    
    if (!contains(l) || !contains(r)) {
        return;
    }
    ideals.push(i);
}

void
Spacing_problem::print_ideal(const Idealspacing*id)const
{
#ifndef NPRINT
    int l = col_id(id->left);
    int r = col_id(id->right);

    mtor << "between " << l <<","<<r<<":" ;
    id->print();
#endif
}

void
Spacing_problem::print() const
{
#ifndef NPRINT
    for (int i=0; i < cols.size(); i++) {
        mtor << "col " << i<<' ';
        cols[i].print();
    }
    for (int i=0; i < ideals.size(); i++) {
        print_ideal(ideals[i]);
    }
#endif
    
}

/* **************** */

void
Colinfo::print() const
{
#ifndef NPRINT
    mtor << "column { ";
    if (fixed())
        mtor << "fixed at " << fixed_position()<<", ";
    assert(pcol_);
    mtor << "[" << minleft() << ", " << minright() << "]";
    mtor <<"}\n";
#endif
}

Colinfo::Colinfo(Colinfo const&c)
{
    fixpos = (c.fixpos)?new Real(*c.fixpos):0;
    pcol_ = c.pcol_;
    width = c.width;
}

Colinfo::Colinfo(const PCol*col_p, const Real*fixed_r_p )
{
    fixpos = (fixed_r_p)? new Real(*fixed_r_p) : 0;
    pcol_ = col_p;
    width = pcol_->width();
}

Colinfo::~Colinfo()
{
    delete fixpos;
}

Colinfo::Colinfo()
{
    pcol_=0;
    fixpos = 0;
}
void
Colinfo::operator=(Colinfo const&c )
{
    delete fixpos;
    fixpos = (c.fixpos)?new Real(*c.fixpos):0;
    pcol_ = c.pcol_;
    width = c.width;
}