PIKApp/app/core/pikacoords-interpolate.c

/* PIKA - Photo and Image Kooker Application
 * a rebranding of The GNU Image Manipulation Program (created with heckimp)
 * A derived work which may be trivial. However, any changes may be (C)2023 by Aldercone Studio
 *
 * Original copyright, applying to most contents (license remains unchanged): 
 * Copyright (C) 1995 Spencer Kimball and Peter Mattis
 *
 * pikacoords-interpolate.c
 *
 * This program 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.
 *
 * This program 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 this program.  If not, see <https://www.gnu.org/licenses/>.
 */

#include "config.h"

#include <glib-object.h>

#include "libpikamath/pikamath.h"

#include "core-types.h"

#include "pikacoords.h"
#include "pikacoords-interpolate.h"


/* Local helper functions declarations*/
static void     pika_coords_interpolate_bezier_internal (const PikaCoords  bezier_pt[4],
                                                         const gdouble     start_t,
                                                         const gdouble     end_t,
                                                         const gdouble     precision,
                                                         GArray           *ret_coords,
                                                         GArray           *ret_params,
                                                         gint              depth);
static gdouble  pika_coords_get_catmull_spline_point    (const gdouble     t,
                                                         const gdouble     p0,
                                                         const gdouble     p1,
                                                         const gdouble     p2,
                                                         const gdouble     p3);

/* Functions for bezier subdivision */

void
pika_coords_interpolate_bezier (const PikaCoords  bezier_pt[4],
                                const gdouble     precision,
                                GArray           *ret_coords,
                                GArray           *ret_params)
{
  g_return_if_fail (bezier_pt != NULL);
  g_return_if_fail (precision >= 0.0);
  g_return_if_fail (ret_coords != NULL);

  pika_coords_interpolate_bezier_internal (bezier_pt,
                                           0.0, 1.0,
                                           precision,
                                           ret_coords, ret_params, 10);
}

/* Recursive subdivision helper function */
static void
pika_coords_interpolate_bezier_internal (const PikaCoords  bezier_pt[4],
                                         const gdouble     start_t,
                                         const gdouble     end_t,
                                         const gdouble     precision,
                                         GArray           *ret_coords,
                                         GArray           *ret_params,
                                         gint              depth)
{
  /*
   * bezier_pt has to contain four PikaCoords with the four control points
   * of the bezier segment. We subdivide it at the parameter 0.5.
   */

  PikaCoords subdivided[8];
  gdouble    middle_t = (start_t + end_t) / 2;

  subdivided[0] = bezier_pt[0];
  subdivided[6] = bezier_pt[3];

  /* if (!depth) g_printerr ("Hit recursion depth limit!\n"); */

  pika_coords_average (&bezier_pt[0],  &bezier_pt[1],  &subdivided[1]);
  pika_coords_average (&bezier_pt[1],  &bezier_pt[2],  &subdivided[7]);
  pika_coords_average (&bezier_pt[2],  &bezier_pt[3],  &subdivided[5]);

  pika_coords_average (&subdivided[1], &subdivided[7], &subdivided[2]);
  pika_coords_average (&subdivided[7], &subdivided[5], &subdivided[4]);
  pika_coords_average (&subdivided[2], &subdivided[4], &subdivided[3]);

  /*
   * We now have the coordinates of the two bezier segments in
   * subdivided [0-3] and subdivided [3-6]
   */

  /*
   * Here we need to check, if we have sufficiently subdivided, i.e.
   * if the stroke is sufficiently close to a straight line.
   */

  if (! depth ||
      pika_coords_bezier_is_straight (subdivided, precision)) /* 1st half */
    {
      g_array_append_vals (ret_coords, subdivided, 3);

      if (ret_params)
        {
          gdouble params[3];

          params[0] = start_t;
          params[1] = (2 * start_t + middle_t) / 3;
          params[2] = (start_t + 2 * middle_t) / 3;

          g_array_append_vals (ret_params, params, 3);
        }
    }
  else
    {
      pika_coords_interpolate_bezier_internal (subdivided,
                                               start_t, (start_t + end_t) / 2,
                                               precision,
                                               ret_coords, ret_params,
                                               depth - 1);
    }

  if (! depth ||
      pika_coords_bezier_is_straight (subdivided + 3, precision)) /* 2nd half */
    {
      g_array_append_vals (ret_coords, subdivided + 3, 3);

      if (ret_params)
        {
          gdouble params[3];

          params[0] = middle_t;
          params[1] = (2 * middle_t + end_t) / 3;
          params[2] = (middle_t + 2 * end_t) / 3;

          g_array_append_vals (ret_params, params, 3);
        }
    }
  else
    {
      pika_coords_interpolate_bezier_internal (subdivided + 3,
                                               (start_t + end_t) / 2, end_t,
                                               precision,
                                               ret_coords, ret_params,
                                               depth - 1);
    }
}


/*
 * Returns the position and/or velocity of a Bezier curve at time 't'.
 */

void
pika_coords_interpolate_bezier_at (const PikaCoords  bezier_pt[4],
                                   gdouble           t,
                                   PikaCoords       *position,
                                   PikaCoords       *velocity)
{
  gdouble u = 1.0 - t;

  g_return_if_fail (bezier_pt != NULL);

  if (position)
    {
      PikaCoords a;
      PikaCoords b;

      pika_coords_mix (      u * u * u, &bezier_pt[0],
                       3.0 * u * u * t, &bezier_pt[1],
                                        &a);
      pika_coords_mix (3.0 * u * t * t, &bezier_pt[2],
                             t * t * t, &bezier_pt[3],
                                        &b);

      pika_coords_add (&a, &b, position);
    }

  if (velocity)
    {
      PikaCoords a;
      PikaCoords b;

      pika_coords_mix (-3.0 * u * u,             &bezier_pt[0],
                        3.0 * (u - 2.0 * t) * u, &bezier_pt[1],
                                                 &a);
      pika_coords_mix (-3.0 * (t - 2.0 * u) * t, &bezier_pt[2],
                        3.0 * t * t,             &bezier_pt[3],
                                                 &b);

      pika_coords_add (&a, &b, velocity);
    }
}

/*
 * a helper function that determines if a bezier segment is "straight
 * enough" to be approximated by a line.
 *
 * To be more exact, it also checks for the control points to be distributed
 * evenly along the line. This makes it easier to reconstruct parameters for
 * a given point along the segment.
 *
 * Needs four PikaCoords in an array.
 */

gboolean
pika_coords_bezier_is_straight (const PikaCoords bezier_pt[4],
                                gdouble          precision)
{
  PikaCoords pt1, pt2;

  g_return_val_if_fail (bezier_pt != NULL, FALSE);
  g_return_val_if_fail (precision >= 0.0, FALSE);

  /* calculate the "ideal" positions for the control points */

  pika_coords_mix (2.0 / 3.0, &bezier_pt[0],
                   1.0 / 3.0, &bezier_pt[3],
                   &pt1);
  pika_coords_mix (1.0 / 3.0, &bezier_pt[0],
                   2.0 / 3.0, &bezier_pt[3],
                   &pt2);

  /* calculate the deviation of the actual control points */

  return (pika_coords_manhattan_dist (&bezier_pt[1], &pt1) < precision &&
          pika_coords_manhattan_dist (&bezier_pt[2], &pt2) < precision);
}


/* Functions for catmull-rom interpolation */

void
pika_coords_interpolate_catmull (const PikaCoords  catmull_pt[4],
                                 gdouble           precision,
                                 GArray           *ret_coords,
                                 GArray           *ret_params)
{
  gdouble    delta_x, delta_y;
  gdouble    distance;
  gdouble    dir_step;
  gdouble    delta_dir;
  gint       num_points;
  gint       n;

  PikaCoords past_coords;
  PikaCoords start_coords;
  PikaCoords end_coords;
  PikaCoords future_coords;

  g_return_if_fail (catmull_pt != NULL);
  g_return_if_fail (precision > 0.0);
  g_return_if_fail (ret_coords != NULL);

  delta_x = catmull_pt[2].x - catmull_pt[1].x;
  delta_y = catmull_pt[2].y - catmull_pt[1].y;

  /* Catmull-Rom interpolation requires 4 points.
   * Two endpoints plus one more at each end.
   */

  past_coords   = catmull_pt[0];
  start_coords  = catmull_pt[1];
  end_coords    = catmull_pt[2];
  future_coords = catmull_pt[3];

  distance  = sqrt (SQR (delta_x) + SQR (delta_y));

  num_points = distance / precision;

  delta_dir = end_coords.direction - start_coords.direction;

  if (delta_dir <= -0.5)
    delta_dir += 1.0;
  else if (delta_dir >= 0.5)
    delta_dir -= 1.0;

  dir_step =  delta_dir / num_points;

  for (n = 1; n <= num_points; n++)
    {
      PikaCoords coords = past_coords; /* Make sure we carry over things
                                        * we do not interpolate */
      gdouble    velocity;
      gdouble    pressure;
      gdouble    p = (gdouble) n / num_points;

      coords.x =
        pika_coords_get_catmull_spline_point (p,
                                              past_coords.x,
                                              start_coords.x,
                                              end_coords.x,
                                              future_coords.x);

      coords.y =
        pika_coords_get_catmull_spline_point (p,
                                              past_coords.y,
                                              start_coords.y,
                                              end_coords.y,
                                              future_coords.y);

      pressure =
        pika_coords_get_catmull_spline_point (p,
                                              past_coords.pressure,
                                              start_coords.pressure,
                                              end_coords.pressure,
                                              future_coords.pressure);
      coords.pressure = CLAMP (pressure, 0.0, 1.0);

      coords.xtilt =
        pika_coords_get_catmull_spline_point (p,
                                              past_coords.xtilt,
                                              start_coords.xtilt,
                                              end_coords.xtilt,
                                              future_coords.xtilt);
      coords.ytilt =
        pika_coords_get_catmull_spline_point (p,
                                              past_coords.ytilt,
                                              start_coords.ytilt,
                                              end_coords.ytilt,
                                              future_coords.ytilt);

      coords.wheel =
        pika_coords_get_catmull_spline_point (p,
                                              past_coords.wheel,
                                              start_coords.wheel,
                                              end_coords.wheel,
                                              future_coords.wheel);

      velocity = pika_coords_get_catmull_spline_point (p,
                                                       past_coords.velocity,
                                                       start_coords.velocity,
                                                       end_coords.velocity,
                                                       future_coords.velocity);
      coords.velocity = CLAMP (velocity, 0.0, 1.0);

      coords.direction = start_coords.direction + dir_step * n;

      coords.direction = coords.direction - floor (coords.direction);

      coords.xscale  = end_coords.xscale;
      coords.yscale  = end_coords.yscale;
      coords.angle   = end_coords.angle;
      coords.reflect = end_coords.reflect;

      g_array_append_val (ret_coords, coords);

      if (ret_params)
        g_array_append_val (ret_params, p);
    }
}

static gdouble
pika_coords_get_catmull_spline_point (const gdouble t,
                                      const gdouble p0,
                                      const gdouble p1,
                                      const gdouble p2,
                                      const gdouble p3)
{
  return ((((-t + 2.0) * t - 1.0) * t / 2.0)        * p0 +
          ((((3.0 * t - 5.0) * t) * t + 2.0) / 2.0) * p1 +
          (((-3.0 * t + 4.0) * t + 1.0) * t / 2.0)  * p2 +
          (((t - 1) * t * t) / 2.0)                 * p3);
}
Initial checkin of Pika from heckimp 2023-09-26 00:35:21 +02:00			`/* PIKA - Photo and Image Kooker Application`
			`* a rebranding of The GNU Image Manipulation Program (created with heckimp)`
			`* A derived work which may be trivial. However, any changes may be (C)2023 by Aldercone Studio`
			`*`
			`* Original copyright, applying to most contents (license remains unchanged):`
			`* Copyright (C) 1995 Spencer Kimball and Peter Mattis`
			`*`
			`* pikacoords-interpolate.c`
			`*`
			`* This program 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.`
			`*`
			`* This program 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 this program. If not, see <https://www.gnu.org/licenses/>.`
			`*/`

			`#include "config.h"`

			`#include <glib-object.h>`

			`#include "libpikamath/pikamath.h"`

			`#include "core-types.h"`

			`#include "pikacoords.h"`
			`#include "pikacoords-interpolate.h"`


			`/* Local helper functions declarations*/`
			`static void pika_coords_interpolate_bezier_internal (const PikaCoords bezier_pt[4],`
			`const gdouble start_t,`
			`const gdouble end_t,`
			`const gdouble precision,`
			`GArray *ret_coords,`
			`GArray *ret_params,`
			`gint depth);`
			`static gdouble pika_coords_get_catmull_spline_point (const gdouble t,`
			`const gdouble p0,`
			`const gdouble p1,`
			`const gdouble p2,`
			`const gdouble p3);`

			`/* Functions for bezier subdivision */`

			`void`
			`pika_coords_interpolate_bezier (const PikaCoords bezier_pt[4],`
			`const gdouble precision,`
			`GArray *ret_coords,`
			`GArray *ret_params)`
			`{`
			`g_return_if_fail (bezier_pt != NULL);`
			`g_return_if_fail (precision >= 0.0);`
			`g_return_if_fail (ret_coords != NULL);`

			`pika_coords_interpolate_bezier_internal (bezier_pt,`
			`0.0, 1.0,`
			`precision,`
			`ret_coords, ret_params, 10);`
			`}`

			`/* Recursive subdivision helper function */`
			`static void`
			`pika_coords_interpolate_bezier_internal (const PikaCoords bezier_pt[4],`
			`const gdouble start_t,`
			`const gdouble end_t,`
			`const gdouble precision,`
			`GArray *ret_coords,`
			`GArray *ret_params,`
			`gint depth)`
			`{`
			`/*`
			`* bezier_pt has to contain four PikaCoords with the four control points`
			`* of the bezier segment. We subdivide it at the parameter 0.5.`
			`*/`

			`PikaCoords subdivided[8];`
			`gdouble middle_t = (start_t + end_t) / 2;`

			`subdivided[0] = bezier_pt[0];`
			`subdivided[6] = bezier_pt[3];`

			`/* if (!depth) g_printerr ("Hit recursion depth limit!\n"); */`

			`pika_coords_average (&bezier_pt[0], &bezier_pt[1], &subdivided[1]);`
			`pika_coords_average (&bezier_pt[1], &bezier_pt[2], &subdivided[7]);`
			`pika_coords_average (&bezier_pt[2], &bezier_pt[3], &subdivided[5]);`

			`pika_coords_average (&subdivided[1], &subdivided[7], &subdivided[2]);`
			`pika_coords_average (&subdivided[7], &subdivided[5], &subdivided[4]);`
			`pika_coords_average (&subdivided[2], &subdivided[4], &subdivided[3]);`

			`/*`
			`* We now have the coordinates of the two bezier segments in`
			`* subdivided [0-3] and subdivided [3-6]`
			`*/`

			`/*`
			`* Here we need to check, if we have sufficiently subdivided, i.e.`
			`* if the stroke is sufficiently close to a straight line.`
			`*/`

			`if (! depth \|\|`
			`pika_coords_bezier_is_straight (subdivided, precision)) /* 1st half */`
			`{`
			`g_array_append_vals (ret_coords, subdivided, 3);`

			`if (ret_params)`
			`{`
			`gdouble params[3];`

			`params[0] = start_t;`
			`params[1] = (2 * start_t + middle_t) / 3;`
			`params[2] = (start_t + 2 * middle_t) / 3;`

			`g_array_append_vals (ret_params, params, 3);`
			`}`
			`}`
			`else`
			`{`
			`pika_coords_interpolate_bezier_internal (subdivided,`
			`start_t, (start_t + end_t) / 2,`
			`precision,`
			`ret_coords, ret_params,`
			`depth - 1);`
			`}`

			`if (! depth \|\|`
			`pika_coords_bezier_is_straight (subdivided + 3, precision)) /* 2nd half */`
			`{`
			`g_array_append_vals (ret_coords, subdivided + 3, 3);`

			`if (ret_params)`
			`{`
			`gdouble params[3];`

			`params[0] = middle_t;`
			`params[1] = (2 * middle_t + end_t) / 3;`
			`params[2] = (middle_t + 2 * end_t) / 3;`

			`g_array_append_vals (ret_params, params, 3);`
			`}`
			`}`
			`else`
			`{`
			`pika_coords_interpolate_bezier_internal (subdivided + 3,`
			`(start_t + end_t) / 2, end_t,`
			`precision,`
			`ret_coords, ret_params,`
			`depth - 1);`
			`}`
			`}`


			`/*`
			`* Returns the position and/or velocity of a Bezier curve at time 't'.`
			`*/`

			`void`
			`pika_coords_interpolate_bezier_at (const PikaCoords bezier_pt[4],`
			`gdouble t,`
			`PikaCoords *position,`
			`PikaCoords *velocity)`
			`{`
			`gdouble u = 1.0 - t;`

			`g_return_if_fail (bezier_pt != NULL);`

			`if (position)`
			`{`
			`PikaCoords a;`
			`PikaCoords b;`

			`pika_coords_mix ( u * u * u, &bezier_pt[0],`
			`3.0 * u * u * t, &bezier_pt[1],`
			`&a);`
			`pika_coords_mix (3.0 * u * t * t, &bezier_pt[2],`
			`t * t * t, &bezier_pt[3],`
			`&b);`

			`pika_coords_add (&a, &b, position);`
			`}`

			`if (velocity)`
			`{`
			`PikaCoords a;`
			`PikaCoords b;`

			`pika_coords_mix (-3.0 * u * u, &bezier_pt[0],`
			`3.0 * (u - 2.0 * t) * u, &bezier_pt[1],`
			`&a);`
			`pika_coords_mix (-3.0 * (t - 2.0 * u) * t, &bezier_pt[2],`
			`3.0 * t * t, &bezier_pt[3],`
			`&b);`

			`pika_coords_add (&a, &b, velocity);`
			`}`
			`}`

			`/*`
			`* a helper function that determines if a bezier segment is "straight`
			`* enough" to be approximated by a line.`
			`*`
			`* To be more exact, it also checks for the control points to be distributed`
			`* evenly along the line. This makes it easier to reconstruct parameters for`
			`* a given point along the segment.`
			`*`
			`* Needs four PikaCoords in an array.`
			`*/`

			`gboolean`
			`pika_coords_bezier_is_straight (const PikaCoords bezier_pt[4],`
			`gdouble precision)`
			`{`
			`PikaCoords pt1, pt2;`

			`g_return_val_if_fail (bezier_pt != NULL, FALSE);`
			`g_return_val_if_fail (precision >= 0.0, FALSE);`

			`/* calculate the "ideal" positions for the control points */`

			`pika_coords_mix (2.0 / 3.0, &bezier_pt[0],`
			`1.0 / 3.0, &bezier_pt[3],`
			`&pt1);`
			`pika_coords_mix (1.0 / 3.0, &bezier_pt[0],`
			`2.0 / 3.0, &bezier_pt[3],`
			`&pt2);`

			`/* calculate the deviation of the actual control points */`

			`return (pika_coords_manhattan_dist (&bezier_pt[1], &pt1) < precision &&`
			`pika_coords_manhattan_dist (&bezier_pt[2], &pt2) < precision);`
			`}`


			`/* Functions for catmull-rom interpolation */`

			`void`
			`pika_coords_interpolate_catmull (const PikaCoords catmull_pt[4],`
			`gdouble precision,`
			`GArray *ret_coords,`
			`GArray *ret_params)`
			`{`
			`gdouble delta_x, delta_y;`
			`gdouble distance;`
			`gdouble dir_step;`
			`gdouble delta_dir;`
			`gint num_points;`
			`gint n;`

			`PikaCoords past_coords;`
			`PikaCoords start_coords;`
			`PikaCoords end_coords;`
			`PikaCoords future_coords;`

			`g_return_if_fail (catmull_pt != NULL);`
			`g_return_if_fail (precision > 0.0);`
			`g_return_if_fail (ret_coords != NULL);`

			`delta_x = catmull_pt[2].x - catmull_pt[1].x;`
			`delta_y = catmull_pt[2].y - catmull_pt[1].y;`

			`/* Catmull-Rom interpolation requires 4 points.`
			`* Two endpoints plus one more at each end.`
			`*/`

			`past_coords = catmull_pt[0];`
			`start_coords = catmull_pt[1];`
			`end_coords = catmull_pt[2];`
			`future_coords = catmull_pt[3];`

			`distance = sqrt (SQR (delta_x) + SQR (delta_y));`

			`num_points = distance / precision;`

			`delta_dir = end_coords.direction - start_coords.direction;`

			`if (delta_dir <= -0.5)`
			`delta_dir += 1.0;`
			`else if (delta_dir >= 0.5)`
			`delta_dir -= 1.0;`

			`dir_step = delta_dir / num_points;`

			`for (n = 1; n <= num_points; n++)`
			`{`
			`PikaCoords coords = past_coords; /* Make sure we carry over things`
			`* we do not interpolate */`
			`gdouble velocity;`
			`gdouble pressure;`
			`gdouble p = (gdouble) n / num_points;`

			`coords.x =`
			`pika_coords_get_catmull_spline_point (p,`
			`past_coords.x,`
			`start_coords.x,`
			`end_coords.x,`
			`future_coords.x);`

			`coords.y =`
			`pika_coords_get_catmull_spline_point (p,`
			`past_coords.y,`
			`start_coords.y,`
			`end_coords.y,`
			`future_coords.y);`

			`pressure =`
			`pika_coords_get_catmull_spline_point (p,`
			`past_coords.pressure,`
			`start_coords.pressure,`
			`end_coords.pressure,`
			`future_coords.pressure);`
			`coords.pressure = CLAMP (pressure, 0.0, 1.0);`

			`coords.xtilt =`
			`pika_coords_get_catmull_spline_point (p,`
			`past_coords.xtilt,`
			`start_coords.xtilt,`
			`end_coords.xtilt,`
			`future_coords.xtilt);`
			`coords.ytilt =`
			`pika_coords_get_catmull_spline_point (p,`
			`past_coords.ytilt,`
			`start_coords.ytilt,`
			`end_coords.ytilt,`
			`future_coords.ytilt);`

			`coords.wheel =`
			`pika_coords_get_catmull_spline_point (p,`
			`past_coords.wheel,`
			`start_coords.wheel,`
			`end_coords.wheel,`
			`future_coords.wheel);`

			`velocity = pika_coords_get_catmull_spline_point (p,`
			`past_coords.velocity,`
			`start_coords.velocity,`
			`end_coords.velocity,`
			`future_coords.velocity);`
			`coords.velocity = CLAMP (velocity, 0.0, 1.0);`

			`coords.direction = start_coords.direction + dir_step * n;`

			`coords.direction = coords.direction - floor (coords.direction);`

			`coords.xscale = end_coords.xscale;`
			`coords.yscale = end_coords.yscale;`
			`coords.angle = end_coords.angle;`
			`coords.reflect = end_coords.reflect;`

			`g_array_append_val (ret_coords, coords);`

			`if (ret_params)`
			`g_array_append_val (ret_params, p);`
			`}`
			`}`

			`static gdouble`
			`pika_coords_get_catmull_spline_point (const gdouble t,`
			`const gdouble p0,`
			`const gdouble p1,`
			`const gdouble p2,`
			`const gdouble p3)`
			`{`
			`return ((((-t + 2.0) * t - 1.0) * t / 2.0) * p0 +`
			`((((3.0 * t - 5.0) * t) * t + 2.0) / 2.0) * p1 +`
			`(((-3.0 * t + 4.0) * t + 1.0) * t / 2.0) * p2 +`
			`(((t - 1) * t * t) / 2.0) * p3);`
			`}`