/*
- moment.cc -- implement Moment bindings
+ This file is part of LilyPond, the GNU music typesetter.
- source file of the GNU LilyPond music typesetter
+ Copyright (C) 1999--2011 Han-Wen Nienhuys <hanwen@xs4all.nl>
- (c) 1999--2005 Han-Wen Nienhuys <hanwen@cs.uu.nl>
+ 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 <http://www.gnu.org/licenses/>.
*/
#include "moment.hh"
/* 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"
+ "Create the rational number with main timing @var{n}/@var{d},"
+ " and optional grace timing @var{gn}/@var{gd}.\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")
+ "A @dfn{moment} is a point in musical time. It consists of"
+ " a pair of rationals (@var{m},@tie{}@var{g}), where @var{m} is"
+ " the timing for the main notes, and @var{g} the timing for"
+ " grace notes. In absence of grace notes, @var{g}@tie{}is zero.")
{
- SCM_ASSERT_TYPE (scm_is_integer (n), n, SCM_ARG1, __FUNCTION__, "integer");
- SCM_ASSERT_TYPE (scm_is_integer (d), d, SCM_ARG2, __FUNCTION__, "integer");
+ LY_ASSERT_TYPE (scm_is_integer, n, 1);
+ LY_ASSERT_TYPE (scm_is_integer, d, 2);
int grace_num = 0;
if (gn != SCM_UNDEFINED)
{
- SCM_ASSERT_TYPE (scm_is_integer (gn), gn, SCM_ARG3, __FUNCTION__, "integer");
+ LY_ASSERT_TYPE (scm_is_integer, gn, 3);
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");
+ LY_ASSERT_TYPE (scm_is_integer, gd, 4);
grace_den = scm_to_int (gd);
}
Rational (grace_num, grace_den)).smobbed_copy ();
}
-LY_DEFINE (ly_sub_moment, "ly:moment-sub",
+LY_DEFINE (ly_moment_sub, "ly:moment-sub",
2, 0, 0, (SCM a, SCM b),
"Subtract two moments.")
{
+ LY_ASSERT_SMOB (Moment, a, 1);
+ LY_ASSERT_SMOB (Moment, b, 2);
+
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 ();
}
2, 0, 0, (SCM a, SCM b),
"Add two moments.")
{
+ LY_ASSERT_SMOB (Moment, a, 1);
+ LY_ASSERT_SMOB (Moment, b, 2);
+
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 ();
}
2, 0, 0, (SCM a, SCM b),
"Multiply two moments.")
{
+ LY_ASSERT_SMOB (Moment, a, 1);
+ LY_ASSERT_SMOB (Moment, b, 2);
+
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 ();
}
2, 0, 0, (SCM a, SCM b),
"Divide two moments.")
{
+ LY_ASSERT_SMOB (Moment, a, 1);
+ LY_ASSERT_SMOB (Moment, b, 2);
+
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 ();
}
2, 0, 0, (SCM a, SCM b),
"Modulo of two moments.")
{
+ LY_ASSERT_SMOB (Moment, a, 1);
+ LY_ASSERT_SMOB (Moment, b, 2);
+
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 ();
}
1, 0, 0, (SCM mom),
"Extract numerator from grace timing.")
{
+ LY_ASSERT_SMOB (Moment, mom, 1);
+
Moment *ma = unsmob_moment (mom);
- SCM_ASSERT_TYPE (ma, mom, SCM_ARG1, __FUNCTION__, "moment");
- return scm_from_int (ma->grace_part_.numerator ());
+ return scm_from_int64 (ma->grace_part_.numerator ());
}
LY_DEFINE (ly_moment_grace_denominator, "ly:moment-grace-denominator",
1, 0, 0, (SCM mom),
"Extract denominator from grace timing.")
{
+ LY_ASSERT_SMOB (Moment, mom, 1);
Moment *ma = unsmob_moment (mom);
- SCM_ASSERT_TYPE (ma, mom, SCM_ARG1, __FUNCTION__, "moment");
- return scm_from_int (ma->grace_part_.denominator ());
+ return scm_from_int64 (ma->grace_part_.denominator ());
}
LY_DEFINE (ly_moment_main_numerator, "ly:moment-main-numerator",
1, 0, 0, (SCM mom),
"Extract numerator from main timing.")
{
+ LY_ASSERT_SMOB (Moment, mom, 1);
Moment *ma = unsmob_moment (mom);
- SCM_ASSERT_TYPE (ma, mom, SCM_ARG1, __FUNCTION__, "moment");
- return scm_from_int (ma->main_part_.numerator ());
+ return scm_from_int64 (ma->main_part_.numerator ());
}
LY_DEFINE (ly_moment_main_denominator, "ly:moment-main-denominator",
1, 0, 0, (SCM mom),
"Extract denominator from main timing.")
{
+ LY_ASSERT_SMOB (Moment, mom, 1);
Moment *ma = unsmob_moment (mom);
- SCM_ASSERT_TYPE (ma, mom, SCM_ARG1, __FUNCTION__, "moment");
- return scm_from_int (ma->main_part_.denominator ());
+ return scm_from_int64 (ma->main_part_.denominator ());
}
LY_DEFINE (ly_moment_less_p, "ly:moment<?",
2, 0, 0, (SCM a, SCM b),
"Compare two moments.")
{
+ LY_ASSERT_SMOB (Moment, a, 1);
+ LY_ASSERT_SMOB (Moment, b, 2);
+
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);
}
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