index 09086f1b203695cea731e8581ded3e9e22fc9f9a..64583b9f2acc0befc36b10dff2feb9f85e44464b 100644 (file)
static NR::Matrix
clonetiler_get_transform (
+
// symmetry group
int type,
+
// row, column
- int x, int y,
+ int i, int j,
+
// center, width, height of the tile
double cx, double cy,
- double w, double h,
+ double w, double h,
// values from the dialog:
- double d_x_per_x, double d_y_per_x, double d_x_per_y, double d_y_per_y,
- int alternate_x, int alternate_y, double rand_x, double rand_y,
- double d_per_x_exp, double d_per_y_exp,
- double d_rot_per_x, double d_rot_per_y, int alternate_rotx, int alternate_roty, double rand_rot,
- double d_scalex_per_x, double d_scaley_per_x, double d_scalex_per_y, double d_scaley_per_y,
- int alternate_scalex, int alternate_scaley, double rand_scalex, double rand_scaley
+ // Shift
+ double shiftx_per_i, double shifty_per_i,
+ double shiftx_per_j, double shifty_per_j,
+ double shiftx_rand, double shifty_rand,
+ double shiftx_exp, double shifty_exp,
+ int shiftx_alternate, int shifty_alternate,
+ int shiftx_cumulate, int shifty_cumulate,
+ int shiftx_excludew, int shifty_excludeh,
+
+ // Scale
+ double scalex_per_i, double scaley_per_i,
+ double scalex_per_j, double scaley_per_j,
+ double scalex_rand, double scaley_rand,
+ double scalex_exp, double scaley_exp,
+ double scalex_log, double scaley_log,
+ int scalex_alternate, int scaley_alternate,
+ int scalex_cumulate, int scaley_cumulate,
+
+ // Rotation
+ double rotate_per_i, double rotate_per_j,
+ double rotate_rand,
+ int rotate_alternatei, int rotate_alternatej,
+ int rotate_cumulatei, int rotate_cumulatej
)
{
- // in abs units
- double eff_x = (alternate_x? (x%2) : pow ((double) x, d_per_x_exp));
- double eff_y = (alternate_y? (y%2) : pow ((double) y, d_per_y_exp));
- double dx = d_x_per_x * w * eff_x + d_x_per_y * w * eff_y + rand_x * w * g_random_double_range (-1, 1);
- double dy = d_y_per_x * h * eff_x + d_y_per_y * h * eff_y + rand_y * h * g_random_double_range (-1, 1);
-
- NR::Matrix rect_translate (NR::translate (w * pow ((double) x, d_per_x_exp) + dx, h * pow ((double) y, d_per_y_exp) + dy));
-
- // in deg
- double eff_x_rot = (alternate_rotx? (x%2) : (x));
- double eff_y_rot = (alternate_roty? (y%2) : (y));
- double drot = d_rot_per_x * eff_x_rot + d_rot_per_y * eff_y_rot + rand_rot * 180 * g_random_double_range (-1, 1);
-
- // times the original
- double eff_x_s = (alternate_scalex? (x%2) : (x));
- double eff_y_s = (alternate_scaley? (y%2) : (y));
- double rand_scale_x, rand_scale_y;
- if (rand_scaley == rand_scalex) {
- // if rands are equal, scale proportionally
- rand_scale_x = rand_scale_y = rand_scalex * 1 * g_random_double_range (-1, 1);
+
+ // Shift (in units of tile width or height) -------------
+ double delta_shifti = 0.0;
+ double delta_shiftj = 0.0;
+
+ if( shiftx_alternate ) {
+ delta_shifti = (double)(i%2);
+ } else {
+ if( shiftx_cumulate ) { // Should the delta shifts be cumulative (i.e. 1, 1+2, 1+2+3, ...)
+ delta_shifti = (double)(i*i);
+ } else {
+ delta_shifti = (double)i;
+ }
+ }
+
+ if( shifty_alternate ) {
+ delta_shiftj = (double)(j%2);
+ } else {
+ if( shifty_cumulate ) {
+ delta_shiftj = (double)(j*j);
+ } else {
+ delta_shiftj = (double)j;
+ }
+ }
+
+ // Random shift, only calculate if non-zero.
+ double delta_shiftx_rand = 0.0;
+ double delta_shifty_rand = 0.0;
+ if( shiftx_rand != 0.0 ) delta_shiftx_rand = shiftx_rand * g_random_double_range (-1, 1);
+ if( shifty_rand != 0.0 ) delta_shifty_rand = shifty_rand * g_random_double_range (-1, 1);
+
+
+ // Delta shift (units of tile width/height)
+ double di = shiftx_per_i * delta_shifti + shiftx_per_j * delta_shiftj + delta_shiftx_rand;
+ double dj = shifty_per_i * delta_shifti + shifty_per_j * delta_shiftj + delta_shifty_rand;
+
+ // Shift in actual x and y, used below
+ double dx = w * di;
+ double dy = h * dj;
+
+ double shifti = di;
+ double shiftj = dj;
+
+ // Include tile width and height in shift if required
+ if( !shiftx_excludew ) shifti += i;
+ if( !shifty_excludeh ) shiftj += j;
+
+ // Add exponential shift if necessary
+ if ( shiftx_exp != 1.0 ) shifti = pow( shifti, shiftx_exp );
+ if ( shifty_exp != 1.0 ) shiftj = pow( shiftj, shifty_exp );
+
+ // Final shift
+ NR::Matrix rect_translate (NR::translate (w * shifti, h * shiftj));
+
+ // Rotation (in degrees) ------------
+ double delta_rotationi = 0.0;
+ double delta_rotationj = 0.0;
+
+ if( rotate_alternatei ) {
+ delta_rotationi = (double)(i%2);
+ } else {
+ if( rotate_cumulatei ) {
+ delta_rotationi = (double)(i*i + i)/2.0;
+ } else {
+ delta_rotationi = (double)i;
+ }
+ }
+
+ if( rotate_alternatej ) {
+ delta_rotationj = (double)(j%2);
+ } else {
+ if( rotate_cumulatej ) {
+ delta_rotationj = (double)(j*j + j)/2.0;
+ } else {
+ delta_rotationj = (double)j;
+ }
+ }
+
+ double delta_rotate_rand = 0.0;
+ if( rotate_rand != 0.0 ) delta_rotate_rand = rotate_rand * 180.0 * g_random_double_range (-1, 1);
+
+ double dr = rotate_per_i * delta_rotationi + rotate_per_j * delta_rotationj + delta_rotate_rand;
+
+ // Scale (times the original) -----------
+ double delta_scalei = 0.0;
+ double delta_scalej = 0.0;
+
+ if( scalex_alternate ) {
+ delta_scalei = (double)(i%2);
} else {
- rand_scale_x = rand_scalex * 1 * g_random_double_range (-1, 1);
- rand_scale_y = rand_scaley * 1 * g_random_double_range (-1, 1);
+ if( scalex_cumulate ) { // Should the delta scales be cumulative (i.e. 1, 1+2, 1+2+3, ...)
+ delta_scalei = (double)(i*i + i)/2.0;
+ } else {
+ delta_scalei = (double)i;
+ }
}
- double dscalex = 1 + d_scalex_per_x * eff_x_s + d_scalex_per_y * eff_y_s + rand_scale_x;
- if (dscalex < 0) dscalex = 0;
- double dscaley = 1 + d_scaley_per_x * eff_x_s + d_scaley_per_y * eff_y_s + rand_scale_y;
- if (dscaley < 0) dscaley = 0;
- NR::Matrix drot_c = NR::translate(-cx, -cy) * NR::rotate (M_PI*drot/180) * NR::translate(cx, cy);
+ if( scaley_alternate ) {
+ delta_scalej = (double)(j%2);
+ } else {
+ if( scaley_cumulate ) {
+ delta_scalej = (double)(j*j + j)/2.0;
+ } else {
+ delta_scalej = (double)j;
+ }
+ }
- NR::Matrix dscale_c = NR::translate(-cx, -cy) * NR::scale (dscalex, dscaley) * NR::translate(cx, cy);
+ // Random scale, only calculate if non-zero.
+ double delta_scalex_rand = 0.0;
+ double delta_scaley_rand = 0.0;
+ if( scalex_rand != 0.0 ) delta_scalex_rand = scalex_rand * g_random_double_range (-1, 1);
+ if( scaley_rand != 0.0 ) delta_scaley_rand = scaley_rand * g_random_double_range (-1, 1);
+ // But if random factors are same, scale x and y proportionally
+ if( scalex_rand == scaley_rand ) delta_scalex_rand = delta_scaley_rand;
+
+ // Total delta scale
+ double scalex = 1.0 + scalex_per_i * delta_scalei + scalex_per_j * delta_scalej + delta_scalex_rand;
+ double scaley = 1.0 + scaley_per_i * delta_scalei + scaley_per_j * delta_scalej + delta_scaley_rand;
+
+ if( scalex < 0.0 ) scalex = 0.0;
+ if( scaley < 0.0 ) scaley = 0.0;
+
+ // Add exponential scale if necessary
+ if ( scalex_exp != 1.0 ) scalex = pow( scalex, scalex_exp );
+ if ( scaley_exp != 1.0 ) scaley = pow( scaley, scaley_exp );
+
+ // Add logarithmic factor if necessary
+ if ( scalex_log > 0.0 ) scalex = pow( scalex_log, scalex - 1.0 );
+ if ( scaley_log > 0.0 ) scaley = pow( scaley_log, scaley - 1.0 );
+ // Alternative using rotation angle
+ //if ( scalex_log != 1.0 ) scalex *= pow( scalex_log, M_PI*dr/180 );
+ //if ( scaley_log != 1.0 ) scaley *= pow( scaley_log, M_PI*dr/180 );
+
+
+ // Calculate transformation matrices, translating back to "center of tile" (rotation center) before transforming
+ NR::Matrix drot_c = NR::translate(-cx, -cy) * NR::rotate (M_PI*dr/180) * NR::translate(cx, cy);
+
+ NR::Matrix dscale_c = NR::translate(-cx, -cy) * NR::scale (scalex, scaley) * NR::translate(cx, cy);
NR::Matrix d_s_r = dscale_c * drot_c;
- NR::Matrix rotate_180_c = NR::translate(-cx, -cy) * NR::rotate (M_PI) * NR::translate(cx, cy);
+ NR::Matrix rotate_180_c = NR::translate(-cx, -cy) * NR::rotate (M_PI) * NR::translate(cx, cy);
+
+ NR::Matrix rotate_90_c = NR::translate(-cx, -cy) * NR::rotate (-M_PI/2) * NR::translate(cx, cy);
+ NR::Matrix rotate_m90_c = NR::translate(-cx, -cy) * NR::rotate ( M_PI/2) * NR::translate(cx, cy);
- NR::Matrix rotate_90_c = NR::translate(-cx, -cy) * NR::rotate (-M_PI/2) * NR::translate(cx, cy);
- NR::Matrix rotate_m90_c = NR::translate(-cx, -cy) * NR::rotate (M_PI/2) * NR::translate(cx, cy);
+ NR::Matrix rotate_120_c = NR::translate(-cx, -cy) * NR::rotate (-2*M_PI/3) * NR::translate(cx, cy);
+ NR::Matrix rotate_m120_c = NR::translate(-cx, -cy) * NR::rotate ( 2*M_PI/3) * NR::translate(cx, cy);
- NR::Matrix rotate_120_c = NR::translate(-cx, -cy) * NR::rotate (-2*M_PI/3) * NR::translate(cx, cy);
- NR::Matrix rotate_m120_c = NR::translate(-cx, -cy) * NR::rotate (2*M_PI/3) * NR::translate(cx, cy);
+ NR::Matrix rotate_60_c = NR::translate(-cx, -cy) * NR::rotate (-M_PI/3) * NR::translate(cx, cy);
+ NR::Matrix rotate_m60_c = NR::translate(-cx, -cy) * NR::rotate ( M_PI/3) * NR::translate(cx, cy);
- NR::Matrix rotate_60_c = NR::translate(-cx, -cy) * NR::rotate (-M_PI/3) * NR::translate(cx, cy);
- NR::Matrix rotate_m60_c = NR::translate(-cx, -cy) * NR::rotate (M_PI/3) * NR::translate(cx, cy);
+ NR::Matrix flip_x = NR::translate(-cx, -cy) * NR::scale (-1, 1) * NR::translate(cx, cy);
+ NR::Matrix flip_y = NR::translate(-cx, -cy) * NR::scale (1, -1) * NR::translate(cx, cy);
- double cos60 = cos(M_PI/3);
- double sin60 = sin(M_PI/3);
- double cos30 = cos(M_PI/6);
- double sin30 = sin(M_PI/6);
- NR::Matrix flip_x = NR::translate(-cx, -cy) * NR::scale (-1, 1) * NR::translate(cx, cy);
- NR::Matrix flip_y = NR::translate(-cx, -cy) * NR::scale (1, -1) * NR::translate(cx, cy);
+ // Create tile with required symmetry
+ const double cos60 = cos(M_PI/3);
+ const double sin60 = sin(M_PI/3);
+ const double cos30 = cos(M_PI/6);
+ const double sin30 = sin(M_PI/6);
switch (type) {
break;
case TILE_P2:
- if (x % 2 == 0) {
+ if (i % 2 == 0) {
return d_s_r * rect_translate;
} else {
return d_s_r * rotate_180_c * rect_translate;
break;
case TILE_PM:
- if (x % 2 == 0) {
+ if (i % 2 == 0) {
return d_s_r * rect_translate;
} else {
return d_s_r * flip_x * rect_translate;
break;
case TILE_PG:
- if (y % 2 == 0) {
+ if (j % 2 == 0) {
return d_s_r * rect_translate;
} else {
return d_s_r * flip_x * rect_translate;
break;
case TILE_CM:
- if ((x + y) % 2 == 0) {
+ if ((i + j) % 2 == 0) {
return d_s_r * rect_translate;
} else {
return d_s_r * flip_x * rect_translate;
break;
case TILE_PMM:
- if (y % 2 == 0) {
- if (x % 2 == 0) {
+ if (j % 2 == 0) {
+ if (i % 2 == 0) {
return d_s_r * rect_translate;
} else {
return d_s_r * flip_x * rect_translate;
}
} else {
- if (x % 2 == 0) {
+ if (i % 2 == 0) {
return d_s_r * flip_y * rect_translate;
} else {
return d_s_r * flip_x * flip_y * rect_translate;
break;
case TILE_PMG:
- if (y % 2 == 0) {
- if (x % 2 == 0) {
+ if (j % 2 == 0) {
+ if (i % 2 == 0) {
return d_s_r * rect_translate;
} else {
return d_s_r * rotate_180_c * rect_translate;
}
} else {
- if (x % 2 == 0) {
+ if (i % 2 == 0) {
return d_s_r * flip_y * rect_translate;
} else {
return d_s_r * rotate_180_c * flip_y * rect_translate;
break;
case TILE_PGG:
- if (y % 2 == 0) {
- if (x % 2 == 0) {
+ if (j % 2 == 0) {
+ if (i % 2 == 0) {
return d_s_r * rect_translate;
} else {
return d_s_r * flip_y * rect_translate;
}
} else {
- if (x % 2 == 0) {
+ if (i % 2 == 0) {
return d_s_r * rotate_180_c * rect_translate;
} else {
return d_s_r * rotate_180_c * flip_y * rect_translate;
break;
case TILE_CMM:
- if (y % 4 == 0) {
- if (x % 2 == 0) {
+ if (j % 4 == 0) {
+ if (i % 2 == 0) {
return d_s_r * rect_translate;
} else {
return d_s_r * flip_x * rect_translate;
}
- } else if (y % 4 == 1) {
- if (x % 2 == 0) {
+ } else if (j % 4 == 1) {
+ if (i % 2 == 0) {
return d_s_r * flip_y * rect_translate;
} else {
return d_s_r * flip_x * flip_y * rect_translate;
}
- } else if (y % 4 == 2) {
- if (x % 2 == 1) {
+ } else if (j % 4 == 2) {
+ if (i % 2 == 1) {
return d_s_r * rect_translate;
} else {
return d_s_r * flip_x * rect_translate;
}
} else {
- if (x % 2 == 1) {
+ if (i % 2 == 1) {
return d_s_r * flip_y * rect_translate;
} else {
return d_s_r * flip_x * flip_y * rect_translate;
case TILE_P4:
{
- NR::Matrix ori (NR::translate ((w + h) * pow((x/2), d_per_x_exp) + dx, (h + w) * pow((y/2), d_per_y_exp) + dy));
+ NR::Matrix ori (NR::translate ((w + h) * pow((i/2), shiftx_exp) + dx, (h + w) * pow((j/2), shifty_exp) + dy));
NR::Matrix dia1 (NR::translate (w/2 + h/2, -h/2 + w/2));
NR::Matrix dia2 (NR::translate (-w/2 + h/2, h/2 + w/2));
- if (y % 2 == 0) {
- if (x % 2 == 0) {
+ if (j % 2 == 0) {
+ if (i % 2 == 0) {
return d_s_r * ori;
} else {
return d_s_r * rotate_m90_c * dia1 * ori;
}
} else {
- if (x % 2 == 0) {
+ if (i % 2 == 0) {
return d_s_r * rotate_90_c * dia2 * ori;
} else {
return d_s_r * rotate_180_c * dia1 * dia2 * ori;
case TILE_P4M:
{
double max = MAX(w, h);
- NR::Matrix ori (NR::translate ((max + max) * pow((x/4), d_per_x_exp) + dx, (max + max) * pow((y/2), d_per_y_exp) + dy));
- NR::Matrix dia1 (NR::translate (w/2 - h/2, h/2 - w/2));
+ NR::Matrix ori (NR::translate ((max + max) * pow((i/4), shiftx_exp) + dx, (max + max) * pow((j/2), shifty_exp) + dy));
+ NR::Matrix dia1 (NR::translate ( w/2 - h/2, h/2 - w/2));
NR::Matrix dia2 (NR::translate (-h/2 + w/2, w/2 - h/2));
- if (y % 2 == 0) {
- if (x % 4 == 0) {
+ if (j % 2 == 0) {
+ if (i % 4 == 0) {
return d_s_r * ori;
- } else if (x % 4 == 1) {
+ } else if (i % 4 == 1) {
return d_s_r * flip_y * rotate_m90_c * dia1 * ori;
- } else if (x % 4 == 2) {
+ } else if (i % 4 == 2) {
return d_s_r * rotate_m90_c * dia1 * NR::translate (h, 0) * ori;
- } else if (x % 4 == 3) {
+ } else if (i % 4 == 3) {
return d_s_r * flip_x * NR::translate (w, 0) * ori;
}
} else {
- if (x % 4 == 0) {
+ if (i % 4 == 0) {
return d_s_r * flip_y * NR::translate(0, h) * ori;
- } else if (x % 4 == 1) {
+ } else if (i % 4 == 1) {
return d_s_r * rotate_90_c * dia2 * NR::translate(0, h) * ori;
- } else if (x % 4 == 2) {
+ } else if (i % 4 == 2) {
return d_s_r * flip_y * rotate_90_c * dia2 * NR::translate(h, 0) * NR::translate(0, h) * ori;
- } else if (x % 4 == 3) {
+ } else if (i % 4 == 3) {
return d_s_r * flip_y * flip_x * NR::translate(w, 0) * NR::translate(0, h) * ori;
}
}
case TILE_P4G:
{
double max = MAX(w, h);
- NR::Matrix ori (NR::translate ((max + max) * pow((x/4), d_per_x_exp) + dx, (max + max) * pow(y, d_per_y_exp) + dy));
- NR::Matrix dia1 (NR::translate (w/2 + h/2, h/2 - w/2));
+ NR::Matrix ori (NR::translate ((max + max) * pow((i/4), shiftx_exp) + dx, (max + max) * pow(j, shifty_exp) + dy));
+ NR::Matrix dia1 (NR::translate ( w/2 + h/2, h/2 - w/2));
NR::Matrix dia2 (NR::translate (-h/2 + w/2, w/2 + h/2));
- if (((x/4) + y) % 2 == 0) {
- if (x % 4 == 0) {
+ if (((i/4) + j) % 2 == 0) {
+ if (i % 4 == 0) {
return d_s_r * ori;
- } else if (x % 4 == 1) {
+ } else if (i % 4 == 1) {
return d_s_r * rotate_m90_c * dia1 * ori;
- } else if (x % 4 == 2) {
+ } else if (i % 4 == 2) {
return d_s_r * rotate_90_c * dia2 * ori;
- } else if (x % 4 == 3) {
+ } else if (i % 4 == 3) {
return d_s_r * rotate_180_c * dia1 * dia2 * ori;
}
} else {
- if (x % 4 == 0) {
+ if (i % 4 == 0) {
return d_s_r * flip_y * NR::translate (0, h) * ori;
- } else if (x % 4 == 1) {
+ } else if (i % 4 == 1) {
return d_s_r * flip_y * rotate_m90_c * dia1 * NR::translate (-h, 0) * ori;
- } else if (x % 4 == 2) {
+ } else if (i % 4 == 2) {
return d_s_r * flip_y * rotate_90_c * dia2 * NR::translate (h, 0) * ori;
- } else if (x % 4 == 3) {
+ } else if (i % 4 == 3) {
return d_s_r * flip_x * NR::translate (w, 0) * ori;
}
}
NR::Matrix dia1;
NR::Matrix dia2;
if (w > h) {
- width = w + w * cos60;
+ width = w + w * cos60;
height = 2 * w * sin60;
dia1 = NR::Matrix (NR::translate (w/2 + w/2 * cos60, -(w/2 * sin60)));
dia2 = dia1 * NR::Matrix (NR::translate (0, 2 * (w/2 * sin60)));
dia1 = NR::Matrix (NR::translate (h/2 * cos30, -(h/2 * sin30)));
dia2 = dia1 * NR::Matrix (NR::translate (0, h/2));
}
- NR::Matrix ori (NR::translate (width * pow((2*(x/3) + y%2), d_per_x_exp) + dx, (height/2) * pow(y, d_per_y_exp) + dy));
- if (x % 3 == 0) {
+ NR::Matrix ori (NR::translate (width * pow((2*(i/3) + j%2), shiftx_exp) + dx, (height/2) * pow(j, shifty_exp) + dy));
+ if (i % 3 == 0) {
return d_s_r * ori;
- } else if (x % 3 == 1) {
+ } else if (i % 3 == 1) {
return d_s_r * rotate_m120_c * dia1 * ori;
- } else if (x % 3 == 2) {
+ } else if (i % 3 == 2) {
return d_s_r * rotate_120_c * dia2 * ori;
}
}
NR::Matrix dia3;
NR::Matrix dia4;
if (w > h) {
- ori = NR::Matrix(NR::translate (w * pow((x/6) + 1/2 * (y%2), d_per_x_exp) + dx, (w * cos30) * pow(y, d_per_y_exp) + dy));
+ ori = NR::Matrix(NR::translate (w * pow((i/6) + 0.5*(j%2), shiftx_exp) + dx, (w * cos30) * pow(j, shifty_exp) + dy));
dia1 = NR::Matrix (NR::translate (0, h/2) * NR::translate (w/2, 0) * NR::translate (w/2 * cos60, -w/2 * sin60) * NR::translate (-h/2 * cos30, -h/2 * sin30) );
dia2 = dia1 * NR::Matrix (NR::translate (h * cos30, h * sin30));
dia3 = dia2 * NR::Matrix (NR::translate (0, 2 * (w/2 * sin60 - h/2 * sin30)));
dia4 = dia3 * NR::Matrix (NR::translate (-h * cos30, h * sin30));
} else {
- ori = NR::Matrix (NR::translate (2*h * cos30 * pow((x/6 + 0.5*(y%2)), d_per_x_exp) + dx, (2*h - h * sin30) * pow(y, d_per_y_exp) + dy));
+ ori = NR::Matrix (NR::translate (2*h * cos30 * pow((i/6 + 0.5*(j%2)), shiftx_exp) + dx, (2*h - h * sin30) * pow(j, shifty_exp) + dy));
dia1 = NR::Matrix (NR::translate (0, -h/2) * NR::translate (h/2 * cos30, h/2 * sin30));
dia2 = dia1 * NR::Matrix (NR::translate (h * cos30, h * sin30));
dia3 = dia2 * NR::Matrix (NR::translate (0, h/2));
dia4 = dia3 * NR::Matrix (NR::translate (-h * cos30, h * sin30));
}
- if (x % 6 == 0) {
+ if (i % 6 == 0) {
return d_s_r * ori;
- } else if (x % 6 == 1) {
+ } else if (i % 6 == 1) {
return d_s_r * flip_y * rotate_m120_c * dia1 * ori;
- } else if (x % 6 == 2) {
+ } else if (i % 6 == 2) {
return d_s_r * rotate_m120_c * dia2 * ori;
- } else if (x % 6 == 3) {
+ } else if (i % 6 == 3) {
return d_s_r * flip_y * rotate_120_c * dia3 * ori;
- } else if (x % 6 == 4) {
+ } else if (i % 6 == 4) {
return d_s_r * rotate_120_c * dia4 * ori;
- } else if (x % 6 == 5) {
+ } else if (i % 6 == 5) {
return d_s_r * flip_y * NR::translate(0, h) * ori;
}
}
dia3 = dia2 * NR::Matrix (NR::translate (0, h/2));
dia4 = dia3 * NR::Matrix (NR::translate (-h * cos30, h * sin30));
}
- NR::Matrix ori (NR::translate (width * pow((2*(x/6) + y%2), d_per_x_exp) + dx, (height/2) * pow(y, d_per_y_exp) + dy));
- if (x % 6 == 0) {
+ NR::Matrix ori (NR::translate (width * pow((2*(i/6) + j%2), shiftx_exp) + dx, (height/2) * pow(j, shifty_exp) + dy));
+ if (i % 6 == 0) {
return d_s_r * ori;
- } else if (x % 6 == 1) {
+ } else if (i % 6 == 1) {
return d_s_r * flip_y * rotate_m120_c * dia1 * ori;
- } else if (x % 6 == 2) {
+ } else if (i % 6 == 2) {
return d_s_r * rotate_m120_c * dia2 * ori;
- } else if (x % 6 == 3) {
+ } else if (i % 6 == 3) {
return d_s_r * flip_y * rotate_120_c * dia3 * ori;
- } else if (x % 6 == 4) {
+ } else if (i % 6 == 4) {
return d_s_r * rotate_120_c * dia4 * ori;
- } else if (x % 6 == 5) {
+ } else if (i % 6 == 5) {
return d_s_r * flip_y * NR::translate(0, h) * ori;
}
}
NR::Matrix dia4;
NR::Matrix dia5;
if (w > h) {
- ori = NR::Matrix(NR::translate (w * pow((2*(x/6) + (y%2)), d_per_x_exp) + dx, (2*w * sin60) * pow(y, d_per_y_exp) + dy));
+ ori = NR::Matrix(NR::translate (w * pow((2*(i/6) + (j%2)), shiftx_exp) + dx, (2*w * sin60) * pow(j, shifty_exp) + dy));
dia1 = NR::Matrix (NR::translate (w/2 * cos60, -w/2 * sin60));
dia2 = dia1 * NR::Matrix (NR::translate (w/2, 0));
dia3 = dia2 * NR::Matrix (NR::translate (w/2 * cos60, w/2 * sin60));
dia4 = dia3 * NR::Matrix (NR::translate (-w/2 * cos60, w/2 * sin60));
dia5 = dia4 * NR::Matrix (NR::translate (-w/2, 0));
} else {
- ori = NR::Matrix(NR::translate (2*h * cos30 * pow((x/6 + 0.5*(y%2)), d_per_x_exp) + dx, (h + h * sin30) * pow(y, d_per_y_exp) + dy));
+ ori = NR::Matrix(NR::translate (2*h * cos30 * pow((i/6 + 0.5*(j%2)), shiftx_exp) + dx, (h + h * sin30) * pow(j, shifty_exp) + dy));
dia1 = NR::Matrix (NR::translate (-w/2, -h/2) * NR::translate (h/2 * cos30, -h/2 * sin30) * NR::translate (w/2 * cos60, w/2 * sin60));
dia2 = dia1 * NR::Matrix (NR::translate (-w/2 * cos60, -w/2 * sin60) * NR::translate (h/2 * cos30, -h/2 * sin30) * NR::translate (h/2 * cos30, h/2 * sin30) * NR::translate (-w/2 * cos60, w/2 * sin60));
dia3 = dia2 * NR::Matrix (NR::translate (w/2 * cos60, -w/2 * sin60) * NR::translate (h/2 * cos30, h/2 * sin30) * NR::translate (-w/2, h/2));
dia4 = dia3 * dia1.inverse();
dia5 = dia3 * dia2.inverse();
}
- if (x % 6 == 0) {
+ if (i % 6 == 0) {
return d_s_r * ori;
- } else if (x % 6 == 1) {
+ } else if (i % 6 == 1) {
return d_s_r * rotate_m60_c * dia1 * ori;
- } else if (x % 6 == 2) {
+ } else if (i % 6 == 2) {
return d_s_r * rotate_m120_c * dia2 * ori;
- } else if (x % 6 == 3) {
+ } else if (i % 6 == 3) {
return d_s_r * rotate_180_c * dia3 * ori;
- } else if (x % 6 == 4) {
+ } else if (i % 6 == 4) {
return d_s_r * rotate_120_c * dia4 * ori;
- } else if (x % 6 == 5) {
+ } else if (i % 6 == 5) {
return d_s_r * rotate_60_c * dia5 * ori;
}
}
NR::Matrix ori;
NR::Matrix dia1, dia2, dia3, dia4, dia5, dia6, dia7, dia8, dia9, dia10;
if (w > h) {
- ori = NR::Matrix(NR::translate (w * pow((2*(x/12) + (y%2)), d_per_x_exp) + dx, (2*w * sin60) * pow(y, d_per_y_exp) + dy));
+ ori = NR::Matrix(NR::translate (w * pow((2*(i/12) + (j%2)), shiftx_exp) + dx, (2*w * sin60) * pow(j, shifty_exp) + dy));
dia1 = NR::Matrix (NR::translate (w/2, h/2) * NR::translate (-w/2 * cos60, -w/2 * sin60) * NR::translate (-h/2 * cos30, h/2 * sin30));
dia2 = dia1 * NR::Matrix (NR::translate (h * cos30, -h * sin30));
dia3 = dia2 * NR::Matrix (NR::translate (-h/2 * cos30, h/2 * sin30) * NR::translate (w * cos60, 0) * NR::translate (-h/2 * cos30, -h/2 * sin30));
dia9 = dia6 * dia3.inverse();
dia10 = dia6 * dia4.inverse();
} else {
- ori = NR::Matrix(NR::translate (4*h * cos30 * pow((x/12 + 0.5*(y%2)), d_per_x_exp) + dx, (2*h + 2*h * sin30) * pow(y, d_per_y_exp) + dy));
+ ori = NR::Matrix(NR::translate (4*h * cos30 * pow((i/12 + 0.5*(j%2)), shiftx_exp) + dx, (2*h + 2*h * sin30) * pow(j, shifty_exp) + dy));
dia1 = NR::Matrix (NR::translate (-w/2, -h/2) * NR::translate (h/2 * cos30, -h/2 * sin30) * NR::translate (w/2 * cos60, w/2 * sin60));
dia2 = dia1 * NR::Matrix (NR::translate (h * cos30, -h * sin30));
dia3 = dia2 * NR::Matrix (NR::translate (-w/2 * cos60, -w/2 * sin60) * NR::translate (h * cos30, 0) * NR::translate (-w/2 * cos60, w/2 * sin60));
dia9 = dia6 * dia3.inverse();
dia10 = dia6 * dia4.inverse();
}
- if (x % 12 == 0) {
+ if (i % 12 == 0) {
return d_s_r * ori;
- } else if (x % 12 == 1) {
+ } else if (i % 12 == 1) {
return d_s_r * flip_y * rotate_m60_c * dia1 * ori;
- } else if (x % 12 == 2) {
+ } else if (i % 12 == 2) {
return d_s_r * rotate_m60_c * dia2 * ori;
- } else if (x % 12 == 3) {
+ } else if (i % 12 == 3) {
return d_s_r * flip_y * rotate_m120_c * dia3 * ori;
- } else if (x % 12 == 4) {
+ } else if (i % 12 == 4) {
return d_s_r * rotate_m120_c * dia4 * ori;
- } else if (x % 12 == 5) {
+ } else if (i % 12 == 5) {
return d_s_r * flip_x * dia5 * ori;
- } else if (x % 12 == 6) {
+ } else if (i % 12 == 6) {
return d_s_r * flip_x * flip_y * dia6 * ori;
- } else if (x % 12 == 7) {
+ } else if (i % 12 == 7) {
return d_s_r * flip_y * rotate_120_c * dia7 * ori;
- } else if (x % 12 == 8) {
+ } else if (i % 12 == 8) {
return d_s_r * rotate_120_c * dia8 * ori;
- } else if (x % 12 == 9) {
+ } else if (i % 12 == 9) {
return d_s_r * flip_y * rotate_60_c * dia9 * ori;
- } else if (x % 12 == 10) {
+ } else if (i % 12 == 10) {
return d_s_r * rotate_60_c * dia10 * ori;
- } else if (x % 12 == 11) {
+ } else if (i % 12 == 11) {
return d_s_r * flip_y * NR::translate (0, h) * ori;
}
}
if (!trace_arena)
return 0;
- NRMatrix t;
- nr_matrix_set_scale(&t, trace_zoom, trace_zoom);
+ NR::Matrix t(NR::scale(trace_zoom, trace_zoom));
nr_arena_item_set_transform(trace_root, &t);
NRGC gc(NULL);
- nr_matrix_set_identity(&gc.transform);
+ gc.transform.set_identity();
nr_arena_item_invoke_update( trace_root, NULL, &gc,
NR_ARENA_ITEM_STATE_ALL,
NR_ARENA_ITEM_STATE_NONE );
clonetiler_remove (NULL, NULL, false);
- double d_x_per_x = 0.01 * prefs_get_double_attribute_limited (prefs_path, "d_x_per_x", 0, -100, 1000);
- double d_y_per_x = 0.01 * prefs_get_double_attribute_limited (prefs_path, "d_y_per_x", 0, -100, 1000);
- double d_per_x_exp = prefs_get_double_attribute_limited (prefs_path, "d_per_x_exp", 1, 0, 10);
- double d_x_per_y = 0.01 * prefs_get_double_attribute_limited (prefs_path, "d_x_per_y", 0, -100, 1000);
- double d_y_per_y = 0.01 * prefs_get_double_attribute_limited (prefs_path, "d_y_per_y", 0, -100, 1000);
- double d_per_y_exp = prefs_get_double_attribute_limited (prefs_path, "d_per_y_exp", 1, 0, 10);
- int alternate_x = prefs_get_int_attribute (prefs_path, "alternate_x", 0);
- int alternate_y = prefs_get_int_attribute (prefs_path, "alternate_y", 0);
- double rand_x = 0.01 * prefs_get_double_attribute_limited (prefs_path, "rand_x", 0, 0, 1000);
- double rand_y = 0.01 * prefs_get_double_attribute_limited (prefs_path, "rand_y", 0, 0, 1000);
-
- double d_scalex_per_x = 0.01 * prefs_get_double_attribute_limited (prefs_path, "d_scalex_per_x", 0, -100, 1000);
- double d_scaley_per_x = 0.01 * prefs_get_double_attribute_limited (prefs_path, "d_scaley_per_x", 0, -100, 1000);
- double d_scalex_per_y = 0.01 * prefs_get_double_attribute_limited (prefs_path, "d_scalex_per_y", 0, -100, 1000);
- double d_scaley_per_y = 0.01 * prefs_get_double_attribute_limited (prefs_path, "d_scaley_per_y", 0, -100, 1000);
- int alternate_scalex = prefs_get_int_attribute (prefs_path, "alternate_scalex", 0);
- int alternate_scaley = prefs_get_int_attribute (prefs_path, "alternate_scaley", 0);
- double rand_scalex = 0.01 * prefs_get_double_attribute_limited (prefs_path, "rand_scalex", 0, 0, 1000);
- double rand_scaley = 0.01 * prefs_get_double_attribute_limited (prefs_path, "rand_scaley", 0, 0, 1000);
-
- double d_rot_per_x = prefs_get_double_attribute_limited (prefs_path, "d_rot_per_x", 0, -180, 180);
- double d_rot_per_y = prefs_get_double_attribute_limited (prefs_path, "d_rot_per_y", 0, -180, 180);
- int alternate_rotx = prefs_get_int_attribute (prefs_path, "alternate_rotx", 0);
- int alternate_roty = prefs_get_int_attribute (prefs_path, "alternate_roty", 0);
- double rand_rot = 0.01 * prefs_get_double_attribute_limited (prefs_path, "rand_rot", 0, 0, 100);
-
- double d_blur_per_y = 0.01 * prefs_get_double_attribute_limited (prefs_path, "d_blur_per_y", 0, 0, 100);
- double d_blur_per_x = 0.01 * prefs_get_double_attribute_limited (prefs_path, "d_blur_per_x", 0, 0, 100);
- int alternate_blury = prefs_get_int_attribute (prefs_path, "alternate_blury", 0);
- int alternate_blurx = prefs_get_int_attribute (prefs_path, "alternate_blurx", 0);
- double rand_blur = 0.01 * prefs_get_double_attribute_limited (prefs_path, "rand_blur", 0, 0, 100);
-
- double d_opacity_per_y = 0.01 * prefs_get_double_attribute_limited (prefs_path, "d_opacity_per_y", 0, 0, 100);
- double d_opacity_per_x = 0.01 * prefs_get_double_attribute_limited (prefs_path, "d_opacity_per_x", 0, 0, 100);
- int alternate_opacityy = prefs_get_int_attribute (prefs_path, "alternate_opacityy", 0);
- int alternate_opacityx = prefs_get_int_attribute (prefs_path, "alternate_opacityx", 0);
- double rand_opacity = 0.01 * prefs_get_double_attribute_limited (prefs_path, "rand_opacity", 0, 0, 100);
-
- const gchar *initial_color = prefs_get_string_attribute (prefs_path, "initial_color");
- double d_hue_per_y = 0.01 * prefs_get_double_attribute_limited (prefs_path, "d_hue_per_y", 0, -100, 100);
- double d_hue_per_x = 0.01 * prefs_get_double_attribute_limited (prefs_path, "d_hue_per_x", 0, -100, 100);
- double rand_hue = 0.01 * prefs_get_double_attribute_limited (prefs_path, "rand_hue", 0, 0, 100);
- double d_saturation_per_y = 0.01 * prefs_get_double_attribute_limited (prefs_path, "d_saturation_per_y", 0, -100, 100);
- double d_saturation_per_x = 0.01 * prefs_get_double_attribute_limited (prefs_path, "d_saturation_per_x", 0, -100, 100);
- double rand_saturation = 0.01 * prefs_get_double_attribute_limited (prefs_path, "rand_saturation", 0, 0, 100);
- double d_lightness_per_y = 0.01 * prefs_get_double_attribute_limited (prefs_path, "d_lightness_per_y", 0, -100, 100);
- double d_lightness_per_x = 0.01 * prefs_get_double_attribute_limited (prefs_path, "d_lightness_per_x", 0, -100, 100);
- double rand_lightness = 0.01 * prefs_get_double_attribute_limited (prefs_path, "rand_lightness", 0, 0, 100);
- int alternate_color_y = prefs_get_int_attribute (prefs_path, "alternate_color_y", 0);
- int alternate_color_x = prefs_get_int_attribute (prefs_path, "alternate_color_x", 0);
+ double shiftx_per_i = 0.01 * prefs_get_double_attribute_limited (prefs_path, "shiftx_per_i", 0, -100, 1000);
+ double shifty_per_i = 0.01 * prefs_get_double_attribute_limited (prefs_path, "shifty_per_i", 0, -100, 1000);
+ double shiftx_per_j = 0.01 * prefs_get_double_attribute_limited (prefs_path, "shiftx_per_j", 0, -100, 1000);
+ double shifty_per_j = 0.01 * prefs_get_double_attribute_limited (prefs_path, "shifty_per_j", 0, -100, 1000);
+ double shiftx_rand = 0.01 * prefs_get_double_attribute_limited (prefs_path, "shiftx_rand", 0, 0, 1000);
+ double shifty_rand = 0.01 * prefs_get_double_attribute_limited (prefs_path, "shifty_rand", 0, 0, 1000);
+ double shiftx_exp = prefs_get_double_attribute_limited (prefs_path, "shiftx_exp", 1, 0, 10);
+ double shifty_exp = prefs_get_double_attribute_limited (prefs_path, "shifty_exp", 1, 0, 10);
+ int shiftx_alternate = prefs_get_int_attribute (prefs_path, "shiftx_alternate", 0);
+ int shifty_alternate = prefs_get_int_attribute (prefs_path, "shifty_alternate", 0);
+ int shiftx_cumulate = prefs_get_int_attribute (prefs_path, "shiftx_cumulate", 0);
+ int shifty_cumulate = prefs_get_int_attribute (prefs_path, "shifty_cumulate", 0);
+ int shiftx_excludew = prefs_get_int_attribute (prefs_path, "shiftx_excludew", 0);
+ int shifty_excludeh = prefs_get_int_attribute (prefs_path, "shifty_excludeh", 0);
+
+ double scalex_per_i = 0.01 * prefs_get_double_attribute_limited (prefs_path, "scalex_per_i", 0, -100, 1000);
+ double scaley_per_i = 0.01 * prefs_get_double_attribute_limited (prefs_path, "scaley_per_i", 0, -100, 1000);
+ double scalex_per_j = 0.01 * prefs_get_double_attribute_limited (prefs_path, "scalex_per_j", 0, -100, 1000);
+ double scaley_per_j = 0.01 * prefs_get_double_attribute_limited (prefs_path, "scaley_per_j", 0, -100, 1000);
+ double scalex_rand = 0.01 * prefs_get_double_attribute_limited (prefs_path, "scalex_rand", 0, 0, 1000);
+ double scaley_rand = 0.01 * prefs_get_double_attribute_limited (prefs_path, "scaley_rand", 0, 0, 1000);
+ double scalex_exp = prefs_get_double_attribute_limited (prefs_path, "scalex_exp", 1, 0, 10);
+ double scaley_exp = prefs_get_double_attribute_limited (prefs_path, "scaley_exp", 1, 0, 10);
+ double scalex_log = prefs_get_double_attribute_limited (prefs_path, "scalex_log", 0, 0, 10);
+ double scaley_log = prefs_get_double_attribute_limited (prefs_path, "scaley_log", 0, 0, 10);
+ int scalex_alternate = prefs_get_int_attribute (prefs_path, "scalex_alternate", 0);
+ int scaley_alternate = prefs_get_int_attribute (prefs_path, "scaley_alternate", 0);
+ int scalex_cumulate = prefs_get_int_attribute (prefs_path, "scalex_cumulate", 0);
+ int scaley_cumulate = prefs_get_int_attribute (prefs_path, "scaley_cumulate", 0);
+
+ double rotate_per_i = prefs_get_double_attribute_limited (prefs_path, "rotate_per_i", 0, -180, 180);
+ double rotate_per_j = prefs_get_double_attribute_limited (prefs_path, "rotate_per_j", 0, -180, 180);
+ double rotate_rand = 0.01 * prefs_get_double_attribute_limited (prefs_path, "rotate_rand", 0, 0, 100);
+ int rotate_alternatei = prefs_get_int_attribute (prefs_path, "rotate_alternatei", 0);
+ int rotate_alternatej = prefs_get_int_attribute (prefs_path, "rotate_alternatej", 0);
+ int rotate_cumulatei = prefs_get_int_attribute (prefs_path, "rotate_cumulatei", 0);
+ int rotate_cumulatej = prefs_get_int_attribute (prefs_path, "rotate_cumulatej", 0);
+
+ double blur_per_i = 0.01 * prefs_get_double_attribute_limited (prefs_path, "blur_per_i", 0, 0, 100);
+ double blur_per_j = 0.01 * prefs_get_double_attribute_limited (prefs_path, "blur_per_j", 0, 0, 100);
+ int blur_alternatei = prefs_get_int_attribute (prefs_path, "blur_alternatei", 0);
+ int blur_alternatej = prefs_get_int_attribute (prefs_path, "blur_alternatej", 0);
+ double blur_rand = 0.01 * prefs_get_double_attribute_limited (prefs_path, "blur_rand", 0, 0, 100);
+
+ double opacity_per_i = 0.01 * prefs_get_double_attribute_limited (prefs_path, "opacity_per_i", 0, 0, 100);
+ double opacity_per_j = 0.01 * prefs_get_double_attribute_limited (prefs_path, "opacity_per_j", 0, 0, 100);
+ int opacity_alternatei = prefs_get_int_attribute (prefs_path, "opacity_alternatei", 0);
+ int opacity_alternatej = prefs_get_int_attribute (prefs_path, "opacity_alternatej", 0);
+ double opacity_rand = 0.01 * prefs_get_double_attribute_limited (prefs_path, "opacity_rand", 0, 0, 100);
+
+ const gchar *initial_color = prefs_get_string_attribute (prefs_path, "initial_color");
+ double hue_per_j = 0.01 * prefs_get_double_attribute_limited (prefs_path, "hue_per_j", 0, -100, 100);
+ double hue_per_i = 0.01 * prefs_get_double_attribute_limited (prefs_path, "hue_per_i", 0, -100, 100);
+ double hue_rand = 0.01 * prefs_get_double_attribute_limited (prefs_path, "hue_rand", 0, 0, 100);
+ double saturation_per_j = 0.01 * prefs_get_double_attribute_limited (prefs_path, "saturation_per_j", 0, -100, 100);
+ double saturation_per_i = 0.01 * prefs_get_double_attribute_limited (prefs_path, "saturation_per_i", 0, -100, 100);
+ double saturation_rand = 0.01 * prefs_get_double_attribute_limited (prefs_path, "saturation_rand", 0, 0, 100);
+ double lightness_per_j = 0.01 * prefs_get_double_attribute_limited (prefs_path, "lightness_per_j", 0, -100, 100);
+ double lightness_per_i = 0.01 * prefs_get_double_attribute_limited (prefs_path, "lightness_per_i", 0, -100, 100);
+ double lightness_rand = 0.01 * prefs_get_double_attribute_limited (prefs_path, "lightness_rand", 0, 0, 100);
+ int color_alternatej = prefs_get_int_attribute (prefs_path, "color_alternatej", 0);
+ int color_alternatei = prefs_get_int_attribute (prefs_path, "color_alternatei", 0);
int type = prefs_get_int_attribute (prefs_path, "symmetrygroup", 0);
int keepbbox = prefs_get_int_attribute (prefs_path, "keepbbox", 1);
- int xmax = prefs_get_int_attribute (prefs_path, "xmax", 2);
- int ymax = prefs_get_int_attribute (prefs_path, "ymax", 2);
+ int imax = prefs_get_int_attribute (prefs_path, "imax", 2);
+ int jmax = prefs_get_int_attribute (prefs_path, "jmax", 2);
int fillrect = prefs_get_int_attribute (prefs_path, "fillrect", 0);
double fillwidth = prefs_get_double_attribute_limited (prefs_path, "fillwidth", 50, 0, 1e6);
NR::Rect bbox_original = NR::Rect (NR::Point (x0, y0), NR::Point (x0 + w, y0 + h));
double perimeter_original = (w + h)/4;
- for (int x = 0;
+ // The integers i and j are reserved for tile column and row.
+ // The doubles x and y are used for coordinates
+ for (int i = 0;
fillrect?
- (fabs(cur[NR::X]) < fillwidth && x < 200) // prevent "freezing" with too large fillrect, arbitrarily limit rows
- : (x < xmax);
- x ++) {
- for (int y = 0;
+ (fabs(cur[NR::X]) < fillwidth && i < 200) // prevent "freezing" with too large fillrect, arbitrarily limit rows
+ : (i < imax);
+ i ++) {
+ for (int j = 0;
fillrect?
- (fabs(cur[NR::Y]) < fillheight && y < 200) // prevent "freezing" with too large fillrect, arbitrarily limit cols
- : (y < ymax);
- y ++) {
+ (fabs(cur[NR::Y]) < fillheight && j < 200) // prevent "freezing" with too large fillrect, arbitrarily limit cols
+ : (j < jmax);
+ j ++) {
// Note: We create a clone at 0,0 too, right over the original, in case our clones are colored
// Get transform from symmetry, shift, scale, rotation
- NR::Matrix t = clonetiler_get_transform (type, x, y, center[NR::X], center[NR::Y], w, h,
- d_x_per_x, d_y_per_x, d_x_per_y, d_y_per_y, alternate_x, alternate_y, rand_x, rand_y,
- d_per_x_exp, d_per_y_exp,
- d_rot_per_x, d_rot_per_y, alternate_rotx, alternate_roty, rand_rot,
- d_scalex_per_x, d_scaley_per_x, d_scalex_per_y, d_scaley_per_y,
- alternate_scalex, alternate_scaley, rand_scalex, rand_scaley);
+ NR::Matrix t = clonetiler_get_transform (type, i, j, center[NR::X], center[NR::Y], w, h,
+ shiftx_per_i, shifty_per_i,
+ shiftx_per_j, shifty_per_j,
+ shiftx_rand, shifty_rand,
+ shiftx_exp, shifty_exp,
+ shiftx_alternate, shifty_alternate,
+ shiftx_cumulate, shifty_cumulate,
+ shiftx_excludew, shifty_excludeh,
+ scalex_per_i, scaley_per_i,
+ scalex_per_j, scaley_per_j,
+ scalex_rand, scaley_rand,
+ scalex_exp, scaley_exp,
+ scalex_log, scaley_log,
+ scalex_alternate, scaley_alternate,
+ scalex_cumulate, scaley_cumulate,
+ rotate_per_i, rotate_per_j,
+ rotate_rand,
+ rotate_alternatei, rotate_alternatej,
+ rotate_cumulatei, rotate_cumulatej );
cur = center * t - center;
if (fillrect) {
float hsl[3];
sp_color_rgb_to_hsl_floatv (hsl, SP_RGBA32_R_F(rgba), SP_RGBA32_G_F(rgba), SP_RGBA32_B_F(rgba));
- double eff_x = (alternate_color_x? (x%2) : (x));
- double eff_y = (alternate_color_y? (y%2) : (y));
+ double eff_i = (color_alternatei? (i%2) : (i));
+ double eff_j = (color_alternatej? (j%2) : (j));
- hsl[0] += d_hue_per_x * eff_x + d_hue_per_y * eff_y + rand_hue * g_random_double_range (-1, 1);
- if (hsl[0] < 0) hsl[0] += 1;
- if (hsl[0] > 1) hsl[0] -= 1;
- hsl[1] += d_saturation_per_x * eff_x + d_saturation_per_y * eff_y + rand_saturation * g_random_double_range (-1, 1);
+ hsl[0] += hue_per_i * eff_i + hue_per_j * eff_j + hue_rand * g_random_double_range (-1, 1);
+ double notused;
+ hsl[0] = modf( hsl[0], ¬used ); // Restrict to 0-1
+ hsl[1] += saturation_per_i * eff_i + saturation_per_j * eff_j + saturation_rand * g_random_double_range (-1, 1);
hsl[1] = CLAMP (hsl[1], 0, 1);
- hsl[2] += d_lightness_per_x * eff_x + d_lightness_per_y * eff_y + rand_lightness * g_random_double_range (-1, 1);
+ hsl[2] += lightness_per_i * eff_i + lightness_per_j * eff_j + lightness_rand * g_random_double_range (-1, 1);
hsl[2] = CLAMP (hsl[2], 0, 1);
float rgb[3];
// Blur
double blur = 0.0;
{
- int eff_x = (alternate_blurx? (x%2) : (x));
- int eff_y = (alternate_blury? (y%2) : (y));
- blur = (d_blur_per_x * eff_x + d_blur_per_y * eff_y + rand_blur * g_random_double_range (-1, 1));
+ int eff_i = (blur_alternatei? (i%2) : (i));
+ int eff_j = (blur_alternatej? (j%2) : (j));
+ blur = (blur_per_i * eff_i + blur_per_j * eff_j + blur_rand * g_random_double_range (-1, 1));
blur = CLAMP (blur, 0, 1);
}
// Opacity
double opacity = 1.0;
{
- int eff_x = (alternate_opacityx? (x%2) : (x));
- int eff_y = (alternate_opacityy? (y%2) : (y));
- opacity = 1 - (d_opacity_per_x * eff_x + d_opacity_per_y * eff_y + rand_opacity * g_random_double_range (-1, 1));
+ int eff_i = (opacity_alternatei? (i%2) : (i));
+ int eff_j = (opacity_alternatej? (j%2) : (j));
+ opacity = 1 - (opacity_per_i * eff_i + opacity_per_j * eff_j + opacity_rand * g_random_double_range (-1, 1));
opacity = CLAMP (opacity, 0, 1);
}
if (blur > 0.0) {
SPObject *clone_object = sp_desktop_document(desktop)->getObjectByRepr(clone);
- double perimeter = perimeter_original * t.expansion();
+ double perimeter = perimeter_original * NR::expansion(t);
double radius = blur * perimeter;
+ // this is necessary for all newly added clones to have correct bboxes,
+ // otherwise filters won't work:
+ sp_document_ensure_up_to_date(sp_desktop_document(desktop));
// it's hard to figure out exact width/height of the tile without having an object
// that we can take bbox of; however here we only need a lower bound so that blur
// margins are not too small, and the perimeter should work
- SPFilter *constructed = new_filter_gaussian_blur(sp_desktop_document(desktop), radius, t.expansion(), t.expansionX(), t.expansionY(), perimeter, perimeter);
+ SPFilter *constructed = new_filter_gaussian_blur(sp_desktop_document(desktop), radius, NR::expansion(t), NR::expansionX(t), NR::expansionY(t), perimeter, perimeter);
sp_style_set_property_url (clone_object, "filter", SP_OBJECT(constructed), false);
}
{
GtkWidget *l = clonetiler_spinbox (tt,
// xgettext:no-c-format
- _("Horizontal shift per row (in % of tile width)"), "d_x_per_y",
+ _("Horizontal shift per row (in % of tile width)"), "shiftx_per_j",
-100, 1000, "%");
clonetiler_table_attach (table, l, 0, 2, 2);
}
{
GtkWidget *l = clonetiler_spinbox (tt,
// xgettext:no-c-format
- _("Horizontal shift per column (in % of tile width)"), "d_x_per_x",
+ _("Horizontal shift per column (in % of tile width)"), "shiftx_per_i",
-100, 1000, "%");
clonetiler_table_attach (table, l, 0, 2, 3);
}
{
GtkWidget *l = clonetiler_spinbox (tt,
- _("Randomize the horizontal shift by this percentage"), "rand_x",
+ _("Randomize the horizontal shift by this percentage"), "shiftx_rand",
0, 1000, "%");
clonetiler_table_attach (table, l, 0, 2, 4);
}
{
GtkWidget *l = clonetiler_spinbox (tt,
// xgettext:no-c-format
- _("Vertical shift per row (in % of tile height)"), "d_y_per_y",
+ _("Vertical shift per row (in % of tile height)"), "shifty_per_j",
-100, 1000, "%");
clonetiler_table_attach (table, l, 0, 3, 2);
}
{
GtkWidget *l = clonetiler_spinbox (tt,
// xgettext:no-c-format
- _("Vertical shift per column (in % of tile height)"), "d_y_per_x",
+ _("Vertical shift per column (in % of tile height)"), "shifty_per_i",
-100, 1000, "%");
clonetiler_table_attach (table, l, 0, 3, 3);
}
{
GtkWidget *l = clonetiler_spinbox (tt,
- _("Randomize the vertical shift by this percentage"), "rand_y",
+ _("Randomize the vertical shift by this percentage"), "shifty_rand",
0, 1000, "%");
clonetiler_table_attach (table, l, 0, 3, 4);
}
{
GtkWidget *l = clonetiler_spinbox (tt,
- _("Whether rows are spaced evenly (1), converge (<1) or diverge (>1)"), "d_per_y_exp",
+ _("Whether rows are spaced evenly (1), converge (<1) or diverge (>1)"), "shifty_exp",
0, 10, "", true);
clonetiler_table_attach (table, l, 0, 4, 2);
}
{
GtkWidget *l = clonetiler_spinbox (tt,
- _("Whether columns are spaced evenly (1), converge (<1) or diverge (>1)"), "d_per_x_exp",
+ _("Whether columns are spaced evenly (1), converge (<1) or diverge (>1)"), "shiftx_exp",
0, 10, "", true);
clonetiler_table_attach (table, l, 0, 4, 3);
}
}
{
- GtkWidget *l = clonetiler_checkbox (tt, _("Alternate the sign of shifts for each row"), "alternate_y");
+ GtkWidget *l = clonetiler_checkbox (tt, _("Alternate the sign of shifts for each row"), "shifty_alternate");
clonetiler_table_attach (table, l, 0, 5, 2);
}
{
- GtkWidget *l = clonetiler_checkbox (tt, _("Alternate the sign of shifts for each column"), "alternate_x");
+ GtkWidget *l = clonetiler_checkbox (tt, _("Alternate the sign of shifts for each column"), "shiftx_alternate");
clonetiler_table_attach (table, l, 0, 5, 3);
}
+ { // Cumulate
+ GtkWidget *l = gtk_label_new ("");
+ // TRANSLATORS: "Cumulate" is a verb here
+ gtk_label_set_markup (GTK_LABEL(l), _("<small>Cumulate:</small>"));
+ gtk_size_group_add_widget(table_row_labels, l);
+ clonetiler_table_attach (table, l, 1, 6, 1);
+ }
+
+ {
+ GtkWidget *l = clonetiler_checkbox (tt, _("Cumulate the shifts for each row"), "shifty_cumulate");
+ clonetiler_table_attach (table, l, 0, 6, 2);
+ }
+
+ {
+ GtkWidget *l = clonetiler_checkbox (tt, _("Cumulate the shifts for each column"), "shiftx_cumulate");
+ clonetiler_table_attach (table, l, 0, 6, 3);
+ }
+
+ { // Exclude tile width and height in shift
+ GtkWidget *l = gtk_label_new ("");
+ // TRANSLATORS: "Cumulate" is a verb here
+ gtk_label_set_markup (GTK_LABEL(l), _("<small>Exclude tile:</small>"));
+ gtk_size_group_add_widget(table_row_labels, l);
+ clonetiler_table_attach (table, l, 1, 7, 1);
+ }
+
+ {
+ GtkWidget *l = clonetiler_checkbox (tt, _("Exclude tile height in shift"), "shifty_excludeh");
+ clonetiler_table_attach (table, l, 0, 7, 2);
+ }
+
+ {
+ GtkWidget *l = clonetiler_checkbox (tt, _("Exclude tile width in shift"), "shiftx_excludew");
+ clonetiler_table_attach (table, l, 0, 7, 3);
+ }
+
}
{
GtkWidget *l = clonetiler_spinbox (tt,
// xgettext:no-c-format
- _("Horizontal scale per row (in % of tile width)"), "d_scalex_per_y",
+ _("Horizontal scale per row (in % of tile width)"), "scalex_per_j",
-100, 1000, "%");
clonetiler_table_attach (table, l, 0, 2, 2);
}
{
GtkWidget *l = clonetiler_spinbox (tt,
// xgettext:no-c-format
- _("Horizontal scale per column (in % of tile width)"), "d_scalex_per_x",
+ _("Horizontal scale per column (in % of tile width)"), "scalex_per_i",
-100, 1000, "%");
clonetiler_table_attach (table, l, 0, 2, 3);
}
{
GtkWidget *l = clonetiler_spinbox (tt,
- _("Randomize the horizontal scale by this percentage"), "rand_scalex",
+ _("Randomize the horizontal scale by this percentage"), "scalex_rand",
0, 1000, "%");
clonetiler_table_attach (table, l, 0, 2, 4);
}
{
GtkWidget *l = clonetiler_spinbox (tt,
// xgettext:no-c-format
- _("Vertical scale per row (in % of tile height)"), "d_scaley_per_y",
+ _("Vertical scale per row (in % of tile height)"), "scaley_per_j",
-100, 1000, "%");
clonetiler_table_attach (table, l, 0, 3, 2);
}
{
GtkWidget *l = clonetiler_spinbox (tt,
// xgettext:no-c-format
- _("Vertical scale per column (in % of tile height)"), "d_scaley_per_x",
+ _("Vertical scale per column (in % of tile height)"), "scaley_per_i",
-100, 1000, "%");
clonetiler_table_attach (table, l, 0, 3, 3);
}
{
GtkWidget *l = clonetiler_spinbox (tt,
- _("Randomize the vertical scale by this percentage"), "rand_scaley",
+ _("Randomize the vertical scale by this percentage"), "scaley_rand",
0, 1000, "%");
clonetiler_table_attach (table, l, 0, 3, 4);
}
- { // alternates
+ // Exponent
+ {
GtkWidget *l = gtk_label_new ("");
- // TRANSLATORS: "Alternate" is a verb here
- gtk_label_set_markup (GTK_LABEL(l), _("<small>Alternate:</small>"));
+ gtk_label_set_markup (GTK_LABEL(l), _("<b>Exponent:</b>"));
gtk_size_group_add_widget(table_row_labels, l);
clonetiler_table_attach (table, l, 1, 4, 1);
}
{
- GtkWidget *l = clonetiler_checkbox (tt, _("Alternate the sign of scales for each row"), "alternate_scaley");
+ GtkWidget *l = clonetiler_spinbox (tt,
+ _("Whether row scaling is uniform (1), converge (<1) or diverge (>1)"), "scaley_exp",
+ 0, 10, "", true);
clonetiler_table_attach (table, l, 0, 4, 2);
}
{
- GtkWidget *l = clonetiler_checkbox (tt, _("Alternate the sign of scales for each column"), "alternate_scalex");
+ GtkWidget *l = clonetiler_spinbox (tt,
+ _("Whether column scaling is uniform (1), converge (<1) or diverge (>1)"), "scalex_exp",
+ 0, 10, "", true);
clonetiler_table_attach (table, l, 0, 4, 3);
}
+ // Logarithmic (as in logarithmic spiral)
+ {
+ GtkWidget *l = gtk_label_new ("");
+ gtk_label_set_markup (GTK_LABEL(l), _("<b>Base:</b>"));
+ gtk_size_group_add_widget(table_row_labels, l);
+ clonetiler_table_attach (table, l, 1, 5, 1);
+ }
+
+ {
+ GtkWidget *l = clonetiler_spinbox (tt,
+ _("Base for a logarithmic spiral: not used (0), converge (<1), or diverge (>1)"), "scaley_log",
+ 0, 10, "", false);
+ clonetiler_table_attach (table, l, 0, 5, 2);
+ }
+
+ {
+ GtkWidget *l = clonetiler_spinbox (tt,
+ _("Base for a logarithmic spiral: not used (0), converge (<1), or diverge (>1)"), "scalex_log",
+ 0, 10, "", false);
+ clonetiler_table_attach (table, l, 0, 5, 3);
+ }
+
+ { // alternates
+ GtkWidget *l = gtk_label_new ("");
+ // TRANSLATORS: "Alternate" is a verb here
+ gtk_label_set_markup (GTK_LABEL(l), _("<small>Alternate:</small>"));
+ gtk_size_group_add_widget(table_row_labels, l);
+ clonetiler_table_attach (table, l, 1, 6, 1);
+ }
+
+ {
+ GtkWidget *l = clonetiler_checkbox (tt, _("Alternate the sign of scales for each row"), "scaley_alternate");
+ clonetiler_table_attach (table, l, 0, 6, 2);
+ }
+
+ {
+ GtkWidget *l = clonetiler_checkbox (tt, _("Alternate the sign of scales for each column"), "scalex_alternate");
+ clonetiler_table_attach (table, l, 0, 6, 3);
+ }
+
+ { // Cumulate
+ GtkWidget *l = gtk_label_new ("");
+ // TRANSLATORS: "Cumulate" is a verb here
+ gtk_label_set_markup (GTK_LABEL(l), _("<small>Cumulate:</small>"));
+ gtk_size_group_add_widget(table_row_labels, l);
+ clonetiler_table_attach (table, l, 1, 7, 1);
+ }
+
+ {
+ GtkWidget *l = clonetiler_checkbox (tt, _("Cumulate the scales for each row"), "scaley_cumulate");
+ clonetiler_table_attach (table, l, 0, 7, 2);
+ }
+
+ {
+ GtkWidget *l = clonetiler_checkbox (tt, _("Cumulate the scales for each column"), "scalex_cumulate");
+ clonetiler_table_attach (table, l, 0, 7, 3);
+ }
+
}
{
GtkWidget *l = clonetiler_spinbox (tt,
// xgettext:no-c-format
- _("Rotate tiles by this angle for each row"), "d_rot_per_y",
+ _("Rotate tiles by this angle for each row"), "rotate_per_j",
-180, 180, "°");
clonetiler_table_attach (table, l, 0, 2, 2);
}
{
GtkWidget *l = clonetiler_spinbox (tt,
// xgettext:no-c-format
- _("Rotate tiles by this angle for each column"), "d_rot_per_x",
+ _("Rotate tiles by this angle for each column"), "rotate_per_i",
-180, 180, "°");
clonetiler_table_attach (table, l, 0, 2, 3);
}
{
GtkWidget *l = clonetiler_spinbox (tt,
- _("Randomize the rotation angle by this percentage"), "rand_rot",
+ _("Randomize the rotation angle by this percentage"), "rotate_rand",
0, 100, "%");
clonetiler_table_attach (table, l, 0, 2, 4);
}
}
{
- GtkWidget *l = clonetiler_checkbox (tt, _("Alternate the rotation direction for each row"), "alternate_roty");
+ GtkWidget *l = clonetiler_checkbox (tt, _("Alternate the rotation direction for each row"), "rotate_alternatej");
clonetiler_table_attach (table, l, 0, 3, 2);
}
{
- GtkWidget *l = clonetiler_checkbox (tt, _("Alternate the rotation direction for each column"), "alternate_rotx");
+ GtkWidget *l = clonetiler_checkbox (tt, _("Alternate the rotation direction for each column"), "rotate_alternatei");
clonetiler_table_attach (table, l, 0, 3, 3);
}
+
+ { // Cumulate
+ GtkWidget *l = gtk_label_new ("");
+ // TRANSLATORS: "Cumulate" is a verb here
+ gtk_label_set_markup (GTK_LABEL(l), _("<small>Cumulate:</small>"));
+ gtk_size_group_add_widget(table_row_labels, l);
+ clonetiler_table_attach (table, l, 1, 4, 1);
+ }
+
+ {
+ GtkWidget *l = clonetiler_checkbox (tt, _("Cumulate the rotation for each row"), "rotate_cumulatej");
+ clonetiler_table_attach (table, l, 0, 4, 2);
+ }
+
+ {
+ GtkWidget *l = clonetiler_checkbox (tt, _("Cumulate the rotation for each column"), "rotate_cumulatei");
+ clonetiler_table_attach (table, l, 0, 4, 3);
+ }
+
}
{
GtkWidget *l = clonetiler_spinbox (tt,
- _("Blur tiles by this percentage for each row"), "d_blur_per_y",
+ _("Blur tiles by this percentage for each row"), "blur_per_j",
0, 100, "%");
clonetiler_table_attach (table, l, 0, 2, 2);
}
{
GtkWidget *l = clonetiler_spinbox (tt,
- _("Blur tiles by this percentage for each column"), "d_blur_per_x",
+ _("Blur tiles by this percentage for each column"), "blur_per_i",
0, 100, "%");
clonetiler_table_attach (table, l, 0, 2, 3);
}
{
GtkWidget *l = clonetiler_spinbox (tt,
- _("Randomize the tile blur by this percentage"), "rand_blur",
+ _("Randomize the tile blur by this percentage"), "blur_rand",
0, 100, "%");
clonetiler_table_attach (table, l, 0, 2, 4);
}
}
{
- GtkWidget *l = clonetiler_checkbox (tt, _("Alternate the sign of blur change for each row"), "alternate_blury");
+ GtkWidget *l = clonetiler_checkbox (tt, _("Alternate the sign of blur change for each row"), "blur_alternatej");
clonetiler_table_attach (table, l, 0, 3, 2);
}
{
- GtkWidget *l = clonetiler_checkbox (tt, _("Alternate the sign of blur change for each column"), "alternate_blurx");
+ GtkWidget *l = clonetiler_checkbox (tt, _("Alternate the sign of blur change for each column"), "blur_alternatei");
clonetiler_table_attach (table, l, 0, 3, 3);
}
{
GtkWidget *l = clonetiler_spinbox (tt,
- _("Decrease tile opacity by this percentage for each row"), "d_opacity_per_y",
+ _("Decrease tile opacity by this percentage for each row"), "opacity_per_j",
0, 100, "%");
clonetiler_table_attach (table, l, 0, 4, 2);
}
{
GtkWidget *l = clonetiler_spinbox (tt,
- _("Decrease tile opacity by this percentage for each column"), "d_opacity_per_x",
+ _("Decrease tile opacity by this percentage for each column"), "opacity_per_i",
0, 100, "%");
clonetiler_table_attach (table, l, 0, 4, 3);
}
{
GtkWidget *l = clonetiler_spinbox (tt,
- _("Randomize the tile opacity by this percentage"), "rand_opacity",
+ _("Randomize the tile opacity by this percentage"), "opacity_rand",
0, 100, "%");
clonetiler_table_attach (table, l, 0, 4, 4);
}
}
{
- GtkWidget *l = clonetiler_checkbox (tt, _("Alternate the sign of opacity change for each row"), "alternate_opacityy");
+ GtkWidget *l = clonetiler_checkbox (tt, _("Alternate the sign of opacity change for each row"), "opacity_alternatej");
clonetiler_table_attach (table, l, 0, 5, 2);
}
{
- GtkWidget *l = clonetiler_checkbox (tt, _("Alternate the sign of opacity change for each column"), "alternate_opacityx");
+ GtkWidget *l = clonetiler_checkbox (tt, _("Alternate the sign of opacity change for each column"), "opacity_alternatei");
clonetiler_table_attach (table, l, 0, 5, 3);
}
}
{
GtkWidget *l = clonetiler_spinbox (tt,
- _("Change the tile hue by this percentage for each row"), "d_hue_per_y",
+ _("Change the tile hue by this percentage for each row"), "hue_per_j",
-100, 100, "%");
clonetiler_table_attach (table, l, 0, 2, 2);
}
{
GtkWidget *l = clonetiler_spinbox (tt,
- _("Change the tile hue by this percentage for each column"), "d_hue_per_x",
+ _("Change the tile hue by this percentage for each column"), "hue_per_i",
-100, 100, "%");
clonetiler_table_attach (table, l, 0, 2, 3);
}
{
GtkWidget *l = clonetiler_spinbox (tt,
- _("Randomize the tile hue by this percentage"), "rand_hue",
+ _("Randomize the tile hue by this percentage"), "hue_rand",
0, 100, "%");
clonetiler_table_attach (table, l, 0, 2, 4);
}
{
GtkWidget *l = clonetiler_spinbox (tt,
- _("Change the color saturation by this percentage for each row"), "d_saturation_per_y",
+ _("Change the color saturation by this percentage for each row"), "saturation_per_j",
-100, 100, "%");
clonetiler_table_attach (table, l, 0, 3, 2);
}
{
GtkWidget *l = clonetiler_spinbox (tt,
- _("Change the color saturation by this percentage for each column"), "d_saturation_per_x",
+ _("Change the color saturation by this percentage for each column"), "saturation_per_i",
-100, 100, "%");
clonetiler_table_attach (table, l, 0, 3, 3);
}
{
GtkWidget *l = clonetiler_spinbox (tt,
- _("Randomize the color saturation by this percentage"), "rand_saturation",
+ _("Randomize the color saturation by this percentage"), "saturation_rand",
0, 100, "%");
clonetiler_table_attach (table, l, 0, 3, 4);
}
{
GtkWidget *l = clonetiler_spinbox (tt,
- _("Change the color lightness by this percentage for each row"), "d_lightness_per_y",
+ _("Change the color lightness by this percentage for each row"), "lightness_per_j",
-100, 100, "%");
clonetiler_table_attach (table, l, 0, 4, 2);
}
{
GtkWidget *l = clonetiler_spinbox (tt,
- _("Change the color lightness by this percentage for each column"), "d_lightness_per_x",
+ _("Change the color lightness by this percentage for each column"), "lightness_per_i",
-100, 100, "%");
clonetiler_table_attach (table, l, 0, 4, 3);
}
{
GtkWidget *l = clonetiler_spinbox (tt,
- _("Randomize the color lightness by this percentage"), "rand_lightness",
+ _("Randomize the color lightness by this percentage"), "lightness_rand",
0, 100, "%");
clonetiler_table_attach (table, l, 0, 4, 4);
}
}
{
- GtkWidget *l = clonetiler_checkbox (tt, _("Alternate the sign of color changes for each row"), "alternate_color_y");
+ GtkWidget *l = clonetiler_checkbox (tt, _("Alternate the sign of color changes for each row"), "color_alternatej");
clonetiler_table_attach (table, l, 0, 5, 2);
}
{
- GtkWidget *l = clonetiler_checkbox (tt, _("Alternate the sign of color changes for each column"), "alternate_color_x");
+ GtkWidget *l = clonetiler_checkbox (tt, _("Alternate the sign of color changes for each column"), "color_alternatei");
clonetiler_table_attach (table, l, 0, 5, 3);
}
{
GtkObject *a = gtk_adjustment_new(0.0, 1, 500, 1, 10, 10);
- int value = prefs_get_int_attribute (prefs_path, "ymax", 2);
+ int value = prefs_get_int_attribute (prefs_path, "jmax", 2);
gtk_adjustment_set_value (GTK_ADJUSTMENT (a), value);
GtkWidget *sb = gtk_spin_button_new (GTK_ADJUSTMENT (a), 1.0, 0);
gtk_tooltips_set_tip (GTK_TOOLTIPS (tt), sb, _("How many rows in the tiling"), NULL);
gtk_box_pack_start (GTK_BOX (hb), sb, TRUE, TRUE, 0);
gtk_signal_connect(GTK_OBJECT(a), "value_changed",
- GTK_SIGNAL_FUNC(clonetiler_xy_changed), (gpointer) "ymax");
+ GTK_SIGNAL_FUNC(clonetiler_xy_changed), (gpointer) "jmax");
}
{
{
GtkObject *a = gtk_adjustment_new(0.0, 1, 500, 1, 10, 10);
- int value = prefs_get_int_attribute (prefs_path, "xmax", 2);
+ int value = prefs_get_int_attribute (prefs_path, "imax", 2);
gtk_adjustment_set_value (GTK_ADJUSTMENT (a), value);
GtkWidget *sb = gtk_spin_button_new (GTK_ADJUSTMENT (a), 1.0, 0);
gtk_tooltips_set_tip (GTK_TOOLTIPS (tt), sb, _("How many columns in the tiling"), NULL);
gtk_box_pack_start (GTK_BOX (hb), sb, TRUE, TRUE, 0);
gtk_signal_connect(GTK_OBJECT(a), "value_changed",
- GTK_SIGNAL_FUNC(clonetiler_xy_changed), (gpointer) "xmax");
+ GTK_SIGNAL_FUNC(clonetiler_xy_changed), (gpointer) "imax");
}
clonetiler_table_attach (table, hb, 0.0, 1, 2);