/* This file is part of Evoral.
- * Copyright (C) 2008 Dave Robillard <http://drobilla.net>
+ * Copyright (C) 2008 David Robillard <http://drobilla.net>
* Copyright (C) 2000-2008 Paul Davis
- *
+ *
* Evoral 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 2 of the License, or (at your option) any later
* version.
- *
+ *
* Evoral 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 details.
- *
+ *
* You should have received a copy of the GNU General Public License along
* with this program; if not, write to the Free Software Foundation, Inc.,
* 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
#include <climits>
#include <cfloat>
#include <cmath>
+#include <vector>
-#include <glibmm/thread.h>
+#include <glibmm/threads.h>
#include "evoral/Curve.hpp"
#include "evoral/ControlList.hpp"
if (!_dirty) {
return;
}
-
+
if ((npoints = _list.events().size()) > 2) {
-
+
/* Compute coefficients needed to efficiently compute a constrained spline
curve. See "Constrained Cubic Spline Interpolation" by CJC Kruger
(www.korf.co.uk/spline.pdf) for more details.
*/
- double x[npoints];
- double y[npoints];
+ vector<double> x(npoints);
+ vector<double> y(npoints);
uint32_t i;
ControlList::EventList::const_iterator xx;
double fplast = 0;
for (i = 0, xx = _list.events().begin(); xx != _list.events().end(); ++xx, ++i) {
-
+
double xdelta; /* gcc is wrong about possible uninitialized use */
double xdelta2; /* ditto */
double ydelta; /* ditto */
}
/* compute (constrained) first derivatives */
-
+
if (i == 0) {
/* first segment */
-
+
fplast = ((3 * (y[1] - y[0]) / (2 * (x[1] - x[0]))) - (fpone * 0.5));
/* we don't store coefficients for i = 0 */
/* last segment */
fpi = ((3 * ydelta) / (2 * xdelta)) - (fplast * 0.5);
-
+
} else {
/* all other segments */
} else {
fpi = 2 / (slope_before + slope_after);
}
-
}
/* compute second derivative for either side of control point `i' */
-
+
fppL = (((-2 * (fpi + (2 * fplast))) / (xdelta))) +
((6 * ydelta) / xdelta2);
-
+
fppR = (2 * ((2 * fpi) + fplast) / xdelta) -
((6 * ydelta) / xdelta2);
-
+
/* compute polynomial coefficients */
double b, c, d;
- d = (fppR - fppL) / (6 * xdelta);
+ d = (fppR - fppL) / (6 * xdelta);
c = ((x[i] * fppL) - (x[i-1] * fppR))/(2 * xdelta);
-
+
double xim12, xim13;
double xi2, xi3;
-
+
xim12 = x[i-1] * x[i-1]; /* "x[i-1] squared" */
xim13 = xim12 * x[i-1]; /* "x[i-1] cubed" */
xi2 = x[i] * x[i]; /* "x[i] squared" */
xi3 = xi2 * x[i]; /* "x[i] cubed" */
-
+
b = (ydelta - (c * (xi2 - xim12)) - (d * (xi3 - xim13))) / xdelta;
/* store */
fplast = fpi;
}
-
+
}
_dirty = false;
bool
Curve::rt_safe_get_vector (double x0, double x1, float *vec, int32_t veclen)
{
- Glib::Mutex::Lock lm(_list.lock(), Glib::TRY_LOCK);
+ Glib::Threads::Mutex::Lock lm(_list.lock(), Glib::Threads::TRY_LOCK);
if (!lm.locked()) {
return false;
void
Curve::get_vector (double x0, double x1, float *vec, int32_t veclen)
{
- Glib::Mutex::Lock lm(_list.lock());
+ Glib::Threads::Mutex::Lock lm(_list.lock());
_get_vector (x0, x1, vec, veclen);
}
void
Curve::_get_vector (double x0, double x1, float *vec, int32_t veclen)
{
- double rx, dx, lx, hx, max_x, min_x;
+ double rx, lx, hx, max_x, min_x;
int32_t i;
int32_t original_veclen;
int32_t npoints;
+ if (veclen == 0) {
+ return;
+ }
+
if ((npoints = _list.events().size()) == 0) {
- for (i = 0; i < veclen; ++i) {
+ /* no events in list, so just fill the entire array with the default value */
+ for (int32_t i = 0; i < veclen; ++i) {
vec[i] = _list.default_value();
}
return;
}
+ if (npoints == 1) {
+ for (int32_t i = 0; i < veclen; ++i) {
+ vec[i] = _list.events().front()->value;
+ }
+ return;
+ }
+
/* events is now known not to be empty */
max_x = _list.events().back()->when;
min_x = _list.events().front()->when;
- lx = max (min_x, x0);
-
- if (x1 < 0) {
- x1 = _list.events().back()->when;
+ if (x0 > max_x) {
+ /* totally past the end - just fill the entire array with the final value */
+ for (int32_t i = 0; i < veclen; ++i) {
+ vec[i] = _list.events().back()->value;
+ }
+ return;
}
- hx = min (max_x, x1);
+ if (x1 < min_x) {
+ /* totally before the first event - fill the entire array with
+ * the initial value.
+ */
+ for (int32_t i = 0; i < veclen; ++i) {
+ vec[i] = _list.events().front()->value;
+ }
+ return;
+ }
original_veclen = veclen;
if (x0 < min_x) {
- /* fill some beginning section of the array with the
- initial (used to be default) value
+ /* fill some beginning section of the array with the
+ initial (used to be default) value
*/
double frac = (min_x - x0) / (x1 - x0);
- int32_t subveclen = (int32_t) floor (veclen * frac);
-
- subveclen = min (subveclen, veclen);
+ int64_t fill_len = (int64_t) floor (veclen * frac);
+
+ fill_len = min (fill_len, (int64_t)veclen);
- for (i = 0; i < subveclen; ++i) {
+ for (i = 0; i < fill_len; ++i) {
vec[i] = _list.events().front()->value;
}
- veclen -= subveclen;
- vec += subveclen;
+ veclen -= fill_len;
+ vec += fill_len;
}
if (veclen && x1 > max_x) {
/* fill some end section of the array with the default or final value */
double frac = (x1 - max_x) / (x1 - x0);
-
- int32_t subveclen = (int32_t) floor (original_veclen * frac);
-
+ int64_t fill_len = (int64_t) floor (original_veclen * frac);
float val;
-
- subveclen = min (subveclen, veclen);
+ fill_len = min (fill_len, (int64_t)veclen);
val = _list.events().back()->value;
- i = veclen - subveclen;
-
- for (i = veclen - subveclen; i < veclen; ++i) {
+ for (i = veclen - fill_len; i < veclen; ++i) {
vec[i] = val;
}
- veclen -= subveclen;
+ veclen -= fill_len;
}
- if (veclen == 0) {
+ lx = max (min_x, x0);
+ hx = min (max_x, x1);
+
+ if (npoints == 2) {
+
+ /* linear interpolation between 2 points */
+
+ /* XXX: this numerator / denominator stuff is pretty grim, but it's the only
+ way I could get the maths to be accurate; doing everything with pure doubles
+ gives ~1e-17 errors in the vec[i] computation.
+ */
+
+ /* gradient of the line */
+ double const m_num = _list.events().back()->value - _list.events().front()->value;
+ double const m_den = _list.events().back()->when - _list.events().front()->when;
+
+ /* y intercept of the line */
+ double const c = double (_list.events().back()->value) - (m_num * _list.events().back()->when / m_den);
+
+ /* dx that we are using */
+ double dx_num = 0;
+ double dx_den = 1;
+ if (veclen > 1) {
+ dx_num = hx - lx;
+ dx_den = veclen - 1;
+ for (int i = 0; i < veclen; ++i) {
+ vec[i] = (lx * (m_num / m_den) + m_num * i * dx_num / (m_den * dx_den)) + c;
+ }
+ } else {
+ vec[0] = lx * (m_num / m_den) + c;
+ }
+
return;
}
- if (npoints == 1 ) {
-
- for (i = 0; i < veclen; ++i) {
- vec[i] = _list.events().front()->value;
- }
- return;
- }
-
-
- if (npoints == 2) {
-
- /* linear interpolation between 2 points */
-
- /* XXX I'm not sure that this is the right thing to
- do here. but its not a common case for the envisaged
- uses.
- */
-
- if (veclen > 1) {
- dx = (hx - lx) / (veclen - 1) ;
- } else {
- dx = 0; // not used
- }
-
- double slope = (_list.events().back()->value - _list.events().front()->value)/
- (_list.events().back()->when - _list.events().front()->when);
- double yfrac = dx*slope;
-
- vec[0] = _list.events().front()->value + slope * (lx - _list.events().front()->when);
-
- for (i = 1; i < veclen; ++i) {
- vec[i] = vec[i-1] + yfrac;
- }
-
- return;
- }
-
if (_dirty) {
solve ();
}
rx = lx;
+ double dx = 0;
if (veclen > 1) {
+ dx = (hx - lx) / (veclen - 1);
+ }
- dx = (hx - lx) / (veclen-1);
-
- for (i = 0; i < veclen; ++i, rx += dx) {
- vec[i] = multipoint_eval (rx);
- }
+ for (i = 0; i < veclen; ++i, rx += dx) {
+ vec[i] = multipoint_eval (rx);
}
}
double
Curve::multipoint_eval (double x)
-{
+{
pair<ControlList::EventList::const_iterator,ControlList::EventList::const_iterator> range;
ControlList::LookupCache& lookup_cache = _list.lookup_cache();
if ((lookup_cache.left < 0) ||
- ((lookup_cache.left > x) ||
- (lookup_cache.range.first == _list.events().end()) ||
+ ((lookup_cache.left > x) ||
+ (lookup_cache.range.first == _list.events().end()) ||
((*lookup_cache.range.second)->when < x))) {
-
+
ControlEvent cp (x, 0.0);
lookup_cache.range = equal_range (_list.events().begin(), _list.events().end(), &cp, ControlList::time_comparator);
range = lookup_cache.range;
- /* EITHER
-
+ /* EITHER
+
a) x is an existing control point, so first == existing point, second == next point
OR
b) x is between control points, so range is empty (first == second, points to where
to insert x)
-
+
*/
if (range.first == range.second) {
/* x does not exist within the list as a control point */
-
+
lookup_cache.left = x;
if (range.first == _list.events().begin()) {
/* we're before the first point */
// return default_value;
- _list.events().front()->value;
+ return _list.events().front()->value;
}
-
+
if (range.second == _list.events().end()) {
/* we're after the last point */
return _list.events().back()->value;
}
- double x2 = x * x;
- ControlEvent* ev = *range.second;
+ ControlEvent* after = (*range.second);
+ range.second--;
+ ControlEvent* before = (*range.second);
- return ev->coeff[0] + (ev->coeff[1] * x) + (ev->coeff[2] * x2) + (ev->coeff[3] * x2 * x);
- }
+ double vdelta = after->value - before->value;
+
+ if (vdelta == 0.0) {
+ return before->value;
+ }
+
+ double tdelta = x - before->when;
+ double trange = after->when - before->when;
+
+ if (_list.interpolation() == ControlList::Curved && after->coeff) {
+ ControlEvent* ev = after;
+ double x2 = x * x;
+ return ev->coeff[0] + (ev->coeff[1] * x) + (ev->coeff[2] * x2) + (ev->coeff[3] * x2 * x);
+ } else {
+ return before->value + (vdelta * (tdelta / trange));
+ }
+ }
/* x is a control point in the data */
/* invalidate the cached range because its not usable */
extern "C" {
-void
+void
curve_get_vector_from_c (void *arg, double x0, double x1, float* vec, int32_t vecsize)
{
static_cast<Evoral::Curve*>(arg)->get_vector (x0, x1, vec, vecsize);