Adding upstream version 2.10.36.upstream/2.10.36

Signed-off-by: Daniel Baumann <daniel.baumann@progress-linux.org>

1 files changed, 540 insertions, 0 deletions

diff --git a/plug-ins/gfig/gfig-grid.c b/plug-ins/gfig/gfig-grid.c
new file mode 100644
index 0000000..ac81859
--- /dev/null
+++ b/plug-ins/gfig/gfig-grid.c
@@ -0,0 +1,540 @@
+/*
+ * Copyright (C) 1995 Spencer Kimball and Peter Mattis
+ *
+ * This is a plug-in for GIMP.
+ *
+ * Generates images containing vector type drawings.
+ *
+ * Copyright (C) 1997 Andy Thomas  alt@picnic.demon.co.uk
+ *
+ * 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 <math.h>
+#include <stdlib.h>
+
+#include <libgimp/gimp.h>
+#include <libgimp/gimpui.h>
+
+#include "gfig.h"
+#include "gfig-grid.h"
+
+#include "libgimp/stdplugins-intl.h"
+
+
+/* For the isometric grid */
+#define SQRT3 1.73205080756887729353   /* Square root of 3 */
+#define SIN_1o6PI_RAD 0.5              /* Sine    1/6 Pi Radians */
+#define COS_1o6PI_RAD SQRT3 / 2        /* Cosine  1/6 Pi Radians */
+#define TAN_1o6PI_RAD 1 / SQRT3        /* Tangent 1/6 Pi Radians == SIN / COS */
+#define RECIP_TAN_1o6PI_RAD SQRT3      /* Reciprocal of Tangent 1/6 Pi Radians */
+
+gint           grid_gc_type           = GFIG_NORMAL_GC;
+
+static void    draw_grid_polar     (cairo_t  *drawgc);
+static void    draw_grid_sq        (cairo_t  *drawgc);
+static void    draw_grid_iso       (cairo_t  *drawgc);
+
+static cairo_t * gfig_get_grid_gc  (cairo_t   *cr,
+                                    GtkWidget *widget,
+                                    gint       gctype);
+
+static void    find_grid_pos_polar (GdkPoint  *p,
+                                    GdkPoint  *gp);
+
+
+/********** PrimeFactors for Shaneyfelt-style Polar Grid **********
+ * Quickly factor any number up to 17160
+ * Correctly factors numbers up to 131 * 131 - 1
+ */
+typedef struct
+{
+  gint product;
+  gint remaining;
+  gint current;
+  gint next;
+  gint index;
+} PrimeFactors;
+
+static gchar primes[] = { 2,3,5,7,11,13,17,19,23,29,31,37,41,43,47,53,
+                          59,61,67,71,73,79,83,89,97,101,103,107,109,113,127 };
+
+#define PRIMES_MAX_INDEX 30
+
+
+static gint
+prime_factors_get (PrimeFactors *this)
+{
+  this->current = this->next;
+  while (this->index <= PRIMES_MAX_INDEX)
+    {
+      if (this->remaining % primes[this->index] == 0)   /* divisible */
+        {
+          this->remaining /= primes[this->index];
+          this->next = primes[this->index];
+          return this->current;
+        }
+      this->index++;
+    }
+  this->next = this->remaining;
+  this->remaining = 1;
+
+  return this->current;
+}
+
+static gint
+prime_factors_lookahead (PrimeFactors *this)
+{
+  return this->next;
+}
+
+static void
+prime_factors_reset (PrimeFactors *this)
+{
+  this->remaining = this->product;
+  this->index = 0;
+  prime_factors_get (this);
+}
+
+static PrimeFactors *
+prime_factors_new (gint n)
+{
+  PrimeFactors *this = g_new (PrimeFactors, 1);
+
+  this->product = n;
+  prime_factors_reset (this);
+
+  return this;
+}
+
+static void
+prime_factors_delete (PrimeFactors* this)
+{
+  g_free (this);
+}
+
+/********** ********** **********/
+
+static gdouble
+sector_size_at_radius (gdouble inner_radius)
+{
+  PrimeFactors *factors = prime_factors_new (selvals.opts.grid_sectors_desired);
+  gint          current_sectors = 1;
+  gdouble       sector_size     = 2 * G_PI / current_sectors;
+
+  while ((current_sectors < selvals.opts.grid_sectors_desired)
+         && (inner_radius*sector_size
+             > (prime_factors_lookahead (factors) *
+                selvals.opts.grid_granularity)))
+    {
+      current_sectors *= prime_factors_get (factors);
+      sector_size = 2 * G_PI / current_sectors;
+    }
+
+  prime_factors_delete(factors);
+
+  return sector_size;
+}
+
+static void
+find_grid_pos_polar (GdkPoint *p,
+                     GdkPoint *gp)
+{
+  gdouble cx = preview_width / 2.0;
+  gdouble cy = preview_height / 2.0;
+  gdouble px = p->x - cx;
+  gdouble py = p->y - cy;
+  gdouble x  = 0;
+  gdouble y  = 0;
+  gdouble r  = sqrt (SQR (px) + SQR (py));
+
+  if (r >= selvals.opts.grid_radius_min * 0.5)
+    {
+      gdouble t;
+      gdouble sectorSize;
+
+      r = selvals.opts.grid_radius_interval
+        * (gint) (0.5 + ((r - selvals.opts.grid_radius_min) /
+                         selvals.opts.grid_radius_interval))
+        + selvals.opts.grid_radius_min;
+
+      t = atan2 (py, px) + 2 * G_PI;
+      sectorSize = sector_size_at_radius (r);
+      t = selvals.opts.grid_rotation
+        + (gint) (0.5 + ((t - selvals.opts.grid_rotation) / sectorSize))
+        * sectorSize;
+      x = r * cos (t);
+      y = r * sin (t);
+    }
+
+  gp->x = x + cx;
+  gp->y = y + cy;
+}
+
+/* find_grid_pos - Given an x, y point return the grid position of it */
+/* return the new position in the passed point */
+
+void
+gfig_grid_colors (GtkWidget *widget)
+{
+}
+
+void
+find_grid_pos (GdkPoint *p,
+               GdkPoint *gp,
+               guint     is_butt3)
+{
+  gint16          x = p->x;
+  gint16          y = p->y;
+  static GdkPoint cons_pnt;
+
+  if (selvals.opts.gridtype == RECT_GRID)
+    {
+      if (p->x % selvals.opts.gridspacing > selvals.opts.gridspacing/2)
+        x += selvals.opts.gridspacing;
+
+      if (p->y % selvals.opts.gridspacing > selvals.opts.gridspacing/2)
+        y += selvals.opts.gridspacing;
+
+      gp->x = (x/selvals.opts.gridspacing)*selvals.opts.gridspacing;
+      gp->y = (y/selvals.opts.gridspacing)*selvals.opts.gridspacing;
+
+      if (is_butt3)
+        {
+          if (abs (gp->x - cons_pnt.x) < abs (gp->y - cons_pnt.y))
+            gp->x = cons_pnt.x;
+          else
+            gp->y = cons_pnt.y;
+        }
+      else
+        {
+          /* Store the point since might be used later */
+          cons_pnt = *gp; /* Structure copy */
+        }
+    }
+  else if (selvals.opts.gridtype == POLAR_GRID)
+    {
+      find_grid_pos_polar (p,gp);
+    }
+  else if (selvals.opts.gridtype == ISO_GRID)
+    {
+      /*
+       * This really needs a picture to show the math...
+       *
+       * Consider an isometric grid with one of the sets of lines
+       * parallel to the y axis (vertical alignment). Further define
+       * that the origin of a Cartesian grid is at a isometric vertex.
+       * For simplicity consider the first quadrant only.
+       *
+       *  - Let one line segment between vertices be r
+       *  - Define the value of r as the grid spacing
+       *  - Assign an integer n identifier to each vertical grid line
+       *    along the x axis.  with n=0 being the y axis. n can be any
+       *    integer
+       *  - Let m to be any integer
+
+       *  - Let h be the spacing between vertical grid lines measured
+       *    along the x axis.  It follows from the isometric grid that
+       *    h has a value of r * COS(1/6 Pi Rad)
+       *
+       *  Consider a Vertex V at the Cartesian location [Xv, Yv]
+       *
+       *   It follows that vertices belong to the set...
+       *   V[Xv, Yv] = [ [ n * h ] ,
+       *                 [ m * r + ( 0.5 * r (n % 2) ) ] ]
+       *   for all integers n and m
+       *
+       * Who cares? Me. It's useful in solving this problem:
+       * Consider an arbitrary point P[Xp,Yp], find the closest vertex
+       * in the set V.
+       *
+       * Restated this problem is "find values for m and n that are
+       * drive V closest to P"
+       *
+       * A Solution method (there may be a better one?):
+       *
+       * Step 1) bound n to the two closest values for Xp
+       *         n_lo = (int) (Xp / h)
+       *         n_hi = n_lo + 1
+       *
+       * Step 2) Consider the two closes vertices for each n_lo and
+       *         n_hi. The further of the vertices in each pair can
+       *         readily be discarded.
+       *
+       *         m_lo_n_lo = (int) ( (Yp / r) - 0.5 (n_lo % 2) )
+       *         m_hi_n_lo = m_lo_n_lo + 1
+       *
+       *         m_lo_n_hi = (int) ( (Yp / r) - 0.5 (n_hi % 2) )
+       *         m_hi_n_hi = m_hi_n_hi
+       *
+       * Step 3) compute the distance from P to V1 and V2. Snap to the
+       *         closer point.
+       */
+
+      gint n_lo;
+      gint n_hi;
+      gint m_lo_n_lo;
+      gint m_hi_n_lo;
+      gint m_lo_n_hi;
+      gint m_hi_n_hi;
+      gint m_n_lo;
+      gint m_n_hi;
+      gdouble r;
+      gdouble h;
+      gint x1;
+      gint x2;
+      gint y1;
+      gint y2;
+
+      r = selvals.opts.gridspacing;
+      h = COS_1o6PI_RAD * r;
+
+      n_lo = (gint) x / h;
+      n_hi = n_lo + 1;
+
+      /* evaluate m candidates for n_lo */
+      m_lo_n_lo = (gint) ((y / r) - 0.5 * (n_lo % 2));
+      m_hi_n_lo = m_lo_n_lo + 1;
+
+     /* figure out which is the better candidate */
+      if (fabs ((m_lo_n_lo * r + (0.5 * r * (n_lo % 2))) - y) <
+          fabs ((m_hi_n_lo * r + (0.5 * r * (n_lo % 2))) - y))
+        {
+          m_n_lo = m_lo_n_lo;
+        }
+      else
+        {
+          m_n_lo = m_hi_n_lo;
+        }
+
+      /* evaluate m candidates for n_hi */
+      m_lo_n_hi = (gint) ( (y / r) - 0.5 * (n_hi % 2) );
+      m_hi_n_hi = m_lo_n_hi + 1;
+
+      /* figure out which is the better candidate */
+      if (fabs((m_lo_n_hi * r + (0.5 * r * (n_hi % 2))) - y) <
+          fabs((m_hi_n_hi * r + (0.5 * r * (n_hi % 2))) - y))
+        {
+          m_n_hi = m_lo_n_hi;
+        }
+      else
+        {
+          m_n_hi = m_hi_n_hi;
+        }
+
+      /* Now, which is closer to [x,y]? we can use a somewhat
+       * abbreviated form of the distance formula since we only care
+       * about relative values.
+       */
+
+      x1 = (gint) (n_lo * h);
+      y1 = (gint) (m_n_lo * r + (0.5 * r * (n_lo % 2)));
+      x2 = (gint) (n_hi * h);
+      y2 = (gint) (m_n_hi * r + (0.5 * r * (n_hi % 2)));
+
+      if (((x - x1) * (x - x1) + (y - y1) * (y - y1)) <
+          ((x - x2) * (x - x2) + (y - y2) * (y - y2)))
+        {
+          gp->x =  x1;
+          gp->y =  y1;
+        }
+      else
+        {
+          gp->x =  x2;
+          gp->y =  y2;
+        }
+    }
+}
+
+static void
+draw_grid_polar (cairo_t *cr)
+{
+    gdouble       inner_radius;
+    gdouble       outer_radius;
+    gdouble       max_radius = sqrt (SQR (preview_width) + SQR (preview_height));
+    gint          current_sectors = 1;
+    PrimeFactors *factors = prime_factors_new (selvals.opts.grid_sectors_desired);
+    for (inner_radius = 0, outer_radius = selvals.opts.grid_radius_min;
+         outer_radius <= max_radius;
+         inner_radius = outer_radius, outer_radius += selvals.opts.grid_radius_interval)
+      {
+        gdouble t;
+        gdouble sector_size = 2 * G_PI / current_sectors;
+        cairo_arc (cr,
+                   0.5 + preview_width / 2.0,
+                   0.5 + preview_height / 2.0,
+                   outer_radius, 0, 2 * G_PI);
+        cairo_stroke (cr);
+
+        while ((current_sectors < selvals.opts.grid_sectors_desired)
+               && (inner_radius * sector_size
+                   > prime_factors_lookahead (factors) * selvals.opts.grid_granularity ))
+          {
+            current_sectors *= prime_factors_get (factors);
+            sector_size = 2 * G_PI / current_sectors;
+          }
+
+        for (t = 0 ; t < 2 * G_PI ; t += sector_size)
+          {
+            gdouble normal_x = cos (selvals.opts.grid_rotation+t);
+            gdouble normal_y = sin (selvals.opts.grid_rotation+t);
+            cairo_move_to (cr,
+                           0.5 + (preview_width / 2.0 + inner_radius * normal_x),
+                           0.5 + (preview_height / 2.0 - inner_radius * normal_y));
+            cairo_line_to (cr,
+                           0.5 + (preview_width / 2.0 + outer_radius * normal_x),
+                           0.5 + (preview_height / 2.0 - outer_radius * normal_y));
+            cairo_stroke (cr);
+          }
+      }
+
+    prime_factors_delete (factors);
+}
+
+
+static void
+draw_grid_sq (cairo_t *cr)
+{
+  gint step;
+  gint loop;
+
+  /* Draw the horizontal lines */
+  step = selvals.opts.gridspacing;
+
+  for (loop = 0 ; loop < preview_height ; loop += step)
+    {
+      cairo_move_to (cr, 0 + .5, loop + .5);
+      cairo_line_to (cr, preview_width + .5, loop + .5);
+    }
+
+  /* Draw the vertical lines */
+
+  for (loop = 0 ; loop < preview_width ; loop += step)
+    {
+      cairo_move_to (cr, loop + .5, 0 + .5);
+      cairo_line_to (cr, loop + .5, preview_height + .5);
+    }
+  cairo_stroke (cr);
+}
+
+static void
+draw_grid_iso (cairo_t *cr)
+{
+  /* vstep is an int since it's defined from grid size */
+  gint    vstep;
+  gdouble loop;
+  gdouble hstep;
+
+  gdouble diagonal_start;
+  gdouble diagonal_end;
+  gdouble diagonal_width;
+  gdouble diagonal_height;
+
+  vstep = selvals.opts.gridspacing;
+  hstep = selvals.opts.gridspacing * COS_1o6PI_RAD;
+
+  /* Draw the vertical lines - These are easy */
+  for (loop = 0 ; loop < preview_width ; loop += hstep)
+    {
+      cairo_move_to (cr, loop, 0);
+      cairo_line_to (cr, loop, preview_height);
+    }
+  cairo_stroke (cr);
+
+  /* draw diag lines at a Theta of +/- 1/6 Pi Rad */
+
+  diagonal_start = -(((int)preview_width * TAN_1o6PI_RAD) - (((int)(preview_width * TAN_1o6PI_RAD)) % vstep));
+
+  diagonal_end = preview_height + (preview_width * TAN_1o6PI_RAD);
+  diagonal_end -= ((int)diagonal_end) % vstep;
+
+  diagonal_width = preview_width;
+  diagonal_height = preview_width * TAN_1o6PI_RAD;
+
+  /* Draw diag lines */
+  for (loop = diagonal_start ; loop < diagonal_end ; loop += vstep)
+    {
+      cairo_move_to (cr, 0, loop);
+      cairo_line_to (cr, diagonal_width, loop + diagonal_height);
+
+      cairo_move_to (cr, 0, loop);
+      cairo_line_to (cr, diagonal_width, loop - diagonal_height);
+    }
+  cairo_stroke (cr);
+}
+
+static cairo_t *
+gfig_get_grid_gc (cairo_t *cr, GtkWidget *w, gint gctype)
+{
+  switch (gctype)
+    {
+    default:
+    case GFIG_NORMAL_GC:
+      cairo_set_source_rgb (cr, .92, .92, .92);
+      break;
+    case GFIG_BLACK_GC:
+      cairo_set_source_rgb (cr, 0., 0., 0.);
+      break;
+    case GFIG_WHITE_GC:
+      cairo_set_source_rgb (cr, 1., 1., 1.);
+      break;
+    case GFIG_GREY_GC:
+      cairo_set_source_rgb (cr, .5, .5, .5);
+      break;
+    case GFIG_DARKER_GC:
+      cairo_set_source_rgb (cr, .25, .25, .25);
+      break;
+    case GFIG_LIGHTER_GC:
+      cairo_set_source_rgb (cr, .75, .75, .75);
+      break;
+    case GFIG_VERY_DARK_GC:
+      cairo_set_source_rgb (cr, .125, .125, .125);
+      break;
+    }
+
+  return cr;
+}
+
+void
+draw_grid (cairo_t *cr)
+{
+  /* Get the size of the preview and calc where the lines go */
+  /* Draw in prelight to start with... */
+  /* Always start in the upper left corner for rect.
+   */
+
+  if ((preview_width < selvals.opts.gridspacing &&
+       preview_height < selvals.opts.gridspacing))
+    {
+      /* Don't draw if they don't fit */
+      return;
+    }
+
+  if (selvals.opts.drawgrid)
+    gfig_get_grid_gc (cr, gfig_context->preview, grid_gc_type);
+  else
+    return;
+
+  cairo_set_line_width (cr, 1.);
+  if (selvals.opts.gridtype == RECT_GRID)
+    draw_grid_sq (cr);
+  else if (selvals.opts.gridtype == POLAR_GRID)
+    draw_grid_polar (cr);
+  else if (selvals.opts.gridtype == ISO_GRID)
+    draw_grid_iso (cr);
+}
+
+