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[lilypond.git] / lily / moment.cc

/*   
  moment.cc --  implement Moment

  source file of the GNU LilyPond music typesetter

  (c) 1999--2004 Han-Wen Nienhuys <hanwen@cs.uu.nl>
*/

#include "moment.hh"

#include "warn.hh"

Moment::Moment ()
{
}

Moment::Moment (int m)
{
  main_part_ = Rational (m);
  grace_part_ = Rational ( 0);
}

Moment::Moment (Rational m, Rational g)
{
  main_part_ = m;
  grace_part_ = g;
}

Moment::Moment (Rational m)
{
  main_part_ = m;
  grace_part_ = Rational (0);
}

#include "ly-smobs.icc"
IMPLEMENT_SIMPLE_SMOBS (Moment);
IMPLEMENT_TYPE_P (Moment, "ly:moment?");

SCM
Moment::mark_smob (SCM)
{
  return SCM_EOL;
}

int
Moment::print_smob (SCM s, SCM port, scm_print_state *)
{
  Moment  *r = (Moment *) SCM_CELL_WORD_1 (s);
     
  scm_puts ("#<Mom ", port);
  String str = r->to_string ();
  scm_puts ((char *)str.to_str0 (), port);
  scm_puts (">", port);
  
  return 1;
}

SCM
Moment::as_scheme () const
{
  return scm_list_5 (ly_symbol2scm ("ly:make-moment"),
                     scm_from_int (main_part_.num()),
                     scm_from_int (main_part_.den()),
                     scm_from_int (grace_part_.num()),
                     scm_from_int (grace_part_.den()));
}

/* TODO: add optional factor argument. */
LY_DEFINE (ly_make_moment, "ly:make-moment",
           2, 2, 0, (SCM n, SCM d, SCM gn, SCM gd),
           "Create the rational number with main timing @var{n}/@var{d}, "
           "and optional grace timin @var{gn}/@var{gd}.\n"
           "\n"
           "\n"
           "Moment is a point in musical time.  "
           "It is consists of a pair of rationals (@var{m},@var{g}), "
           "where @var{m} is the timing for the main\n"
           "notes, and @var{g} the timing for grace notes.  "
           "In absence of grace notes, @var{g} is zero.\n")
{
  SCM_ASSERT_TYPE (scm_is_integer (n), n, SCM_ARG1, __FUNCTION__, "integer");
  SCM_ASSERT_TYPE (scm_is_integer (d), d, SCM_ARG2, __FUNCTION__, "integer");

  int grace_num = 0;
  if (gn != SCM_UNDEFINED)
    {
      SCM_ASSERT_TYPE (scm_is_integer (gn), gn, SCM_ARG3, __FUNCTION__, "integer");
      grace_num = scm_to_int (gn);
    }

  int grace_den = 1;
  if (gd != SCM_UNDEFINED)
    {
      SCM_ASSERT_TYPE (scm_is_integer (gd), gd, SCM_ARG4, __FUNCTION__, "integer");
      grace_den = scm_to_int (gd);
    }

  return Moment (Rational (scm_to_int (n), scm_to_int (d)),
                 Rational (grace_num, grace_den)).smobbed_copy ();
}

LY_DEFINE (ly_add_moment, "ly:add-moment",
           2, 0, 0, (SCM a, SCM b),
           "Add two moments.")
{
  Moment *ma = unsmob_moment (a);
  Moment *mb = unsmob_moment (b);
  SCM_ASSERT_TYPE (ma, a, SCM_ARG1, __FUNCTION__, "moment");
  SCM_ASSERT_TYPE (mb, b, SCM_ARG2, __FUNCTION__, "moment");
  return (*ma + *mb).smobbed_copy ();
}

LY_DEFINE (ly_mul_moment,"ly:mul-moment",
           2, 0, 0, (SCM a, SCM b),
           "Multiply two moments.")
{
  Moment *ma = unsmob_moment (a);
  Moment *mb = unsmob_moment (b);
  SCM_ASSERT_TYPE (ma, a, SCM_ARG1, __FUNCTION__, "moment");
  SCM_ASSERT_TYPE (mb, b, SCM_ARG2, __FUNCTION__, "moment");
  return (*ma * *mb).smobbed_copy ();
}

LY_DEFINE (ly_div_moment,"ly:div-moment",
           2, 0, 0, (SCM a, SCM b),
           "Divide two moments.")
{
  Moment *ma = unsmob_moment (a);
  Moment *mb = unsmob_moment (b);
  SCM_ASSERT_TYPE (ma, a, SCM_ARG1, __FUNCTION__, "moment");
  SCM_ASSERT_TYPE (mb, b, SCM_ARG2, __FUNCTION__, "moment");
  return (*ma / *mb).smobbed_copy ();
}

LY_DEFINE (ly_moment_main_numerator,"ly:moment-main-numerator",
           1, 0, 0, (SCM mom),
           "Extract numerator from main timing.")
{
  Moment *ma = unsmob_moment (mom);
  SCM_ASSERT_TYPE (ma, mom, SCM_ARG1, __FUNCTION__, "moment");

  return scm_from_int (ma->main_part_.numerator ()); 
}

LY_DEFINE (ly_moment_main_denominator,"ly:moment-main-denominator",
           1, 0, 0, (SCM mom),
           "Extract denominator from main timing.")
{
  Moment *ma = unsmob_moment (mom);
  SCM_ASSERT_TYPE (ma, mom, SCM_ARG1, __FUNCTION__, "moment");

  return scm_from_int (ma->main_part_.denominator ()); 
}

LY_DEFINE (ly_moment_less_p,"ly:moment<?",
           2, 0, 0, (SCM a, SCM b),
           "Compare two moments.")
{
  Moment *ma = unsmob_moment (a);
  Moment *mb = unsmob_moment (b);
  SCM_ASSERT_TYPE (ma, a, SCM_ARG1, __FUNCTION__, "moment");
  SCM_ASSERT_TYPE (mb, b, SCM_ARG2, __FUNCTION__, "moment");
  return ly_bool2scm (*ma <  *mb);
}

SCM
Moment::equal_p (SCM a, SCM b)
{
  Moment *m1 = unsmob_moment (a);
  Moment *m2 = unsmob_moment (b);
      
  return (*m1 == *m2) ? SCM_BOOL_T : SCM_BOOL_F;
}

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

int
compare (Moment const &a, Moment const &b)
{
  return Moment::compare (a,b);
}

int
Moment::compare (Moment const &a, Moment const &b)
{
  int c = Rational::compare (a.main_part_,b.main_part_);
  if (c)
    return c;

  return Rational::compare (a.grace_part_, b.grace_part_);
}

void
Moment::operator += (Moment const &src)
{
  main_part_ += src.main_part_ ;
  grace_part_ += src.grace_part_;
}
void
Moment::operator -= (Moment const &src)
{
  main_part_ -= src.main_part_ ;
  grace_part_ -= src.grace_part_;
}

/*
  only take the main part of SRC for multiplication.
*/
void
Moment::operator *= (Moment const &src)
{
  main_part_ *= src.main_part_ ;
  grace_part_ *= src.main_part_;
}

/*
  only take the main part of SRC for multiplication.
*/
void
Moment::operator /= (Moment const &src)
{
  main_part_ /= src.main_part_ ;
  grace_part_ /= src.main_part_;
}

int
Moment::den () const
{
  return main_part_.den ();
}

int
Moment::num () const
{
  return main_part_.num ();
}

bool
Moment::to_bool () const
{
  return main_part_ || grace_part_;
}

void
Moment::set_infinite (int k)
{
  main_part_.set_infinite (k);
}

String
Moment::to_string () const
{
  String s =  main_part_.to_string ();
  if (grace_part_)
    {
      s += "G" + grace_part_.to_string ();
    }
  return s;
}

Moment
Moment::operator - () const
{
  Moment m;
  m.grace_part_ = - grace_part_;
  m. main_part_ = - main_part_ ;
  return m;
}


#ifdef STREAM_SUPPORT
std::ostream &
operator << (std::ostream &os, Moment const &m)
{
  os << m.to_string ();
  return os;
}
#endif

Moment
robust_scm2moment (SCM m, Moment d)
{
  Moment *p = unsmob_moment (m);
  if (!p)
    return d;
  else
    return *p;
}


bool
moment_less (SCM a, SCM b)
{
  return *unsmob_moment (a) < *unsmob_moment (b);
}