/* Libart_LGPL - library of basic graphic primitives * Copyright (C) 1998 Raph Levien * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Library General Public * License as published by the Free Software Foundation; either * version 2 of the License, or (at your option) any later version. * * This library 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 * Library General Public License for more details. * * You should have received a copy of the GNU Library General Public * License along with this library; if not, write to the * Free Software Foundation, Inc., 59 Temple Place - Suite 330, * Boston, MA 02111-1307, USA. */ #include "config.h" #include "art_rect.h" #include #ifndef MAX #define MAX(a, b) (((a) > (b)) ? (a) : (b)) #endif /* MAX */ #ifndef MIN #define MIN(a, b) (((a) < (b)) ? (a) : (b)) #endif /* MIN */ /* rectangle primitives stolen from gzilla */ /** * art_irect_copy: Make a copy of an integer rectangle. * @dest: Where the copy is stored. * @src: The source rectangle. * * Copies the rectangle. **/ void art_irect_copy (ArtIRect *dest, const ArtIRect *src) { dest->x0 = src->x0; dest->y0 = src->y0; dest->x1 = src->x1; dest->y1 = src->y1; } /** * art_irect_union: Find union of two integer rectangles. * @dest: Where the result is stored. * @src1: A source rectangle. * @src2: Another source rectangle. * * Finds the smallest rectangle that includes @src1 and @src2. **/ void art_irect_union (ArtIRect *dest, const ArtIRect *src1, const ArtIRect *src2) { if (art_irect_empty (src1)) { art_irect_copy (dest, src2); } else if (art_irect_empty (src2)) { art_irect_copy (dest, src1); } else { dest->x0 = MIN (src1->x0, src2->x0); dest->y0 = MIN (src1->y0, src2->y0); dest->x1 = MAX (src1->x1, src2->x1); dest->y1 = MAX (src1->y1, src2->y1); } } /** * art_irect_intersection: Find intersection of two integer rectangles. * @dest: Where the result is stored. * @src1: A source rectangle. * @src2: Another source rectangle. * * Finds the intersection of @src1 and @src2. **/ void art_irect_intersect (ArtIRect *dest, const ArtIRect *src1, const ArtIRect *src2) { dest->x0 = MAX (src1->x0, src2->x0); dest->y0 = MAX (src1->y0, src2->y0); dest->x1 = MIN (src1->x1, src2->x1); dest->y1 = MIN (src1->y1, src2->y1); } /** * art_irect_empty: Determine whether integer rectangle is empty. * @src: The source rectangle. * * Return value: TRUE if @src is an empty rectangle, FALSE otherwise. **/ int art_irect_empty (const ArtIRect *src) { return (src->x1 <= src->x0 || src->y1 <= src->y0); } #if 0 gboolean irect_point_inside (ArtIRect *rect, GzwPoint *point) { return (point->x >= rect->x0 && point->y >= rect->y0 && point->x < rect->x1 && point->y < rect->y1); } #endif /** * art_drect_copy: Make a copy of a rectangle. * @dest: Where the copy is stored. * @src: The source rectangle. * * Copies the rectangle. **/ void art_drect_copy (ArtDRect *dest, const ArtDRect *src) { dest->x0 = src->x0; dest->y0 = src->y0; dest->x1 = src->x1; dest->y1 = src->y1; } /** * art_drect_union: Find union of two rectangles. * @dest: Where the result is stored. * @src1: A source rectangle. * @src2: Another source rectangle. * * Finds the smallest rectangle that includes @src1 and @src2. **/ void art_drect_union (ArtDRect *dest, const ArtDRect *src1, const ArtDRect *src2) { if (art_drect_empty (src1)) { art_drect_copy (dest, src2); } else if (art_drect_empty (src2)) { art_drect_copy (dest, src1); } else { dest->x0 = MIN (src1->x0, src2->x0); dest->y0 = MIN (src1->y0, src2->y0); dest->x1 = MAX (src1->x1, src2->x1); dest->y1 = MAX (src1->y1, src2->y1); } } /** * art_drect_intersection: Find intersection of two rectangles. * @dest: Where the result is stored. * @src1: A source rectangle. * @src2: Another source rectangle. * * Finds the intersection of @src1 and @src2. **/ void art_drect_intersect (ArtDRect *dest, const ArtDRect *src1, const ArtDRect *src2) { dest->x0 = MAX (src1->x0, src2->x0); dest->y0 = MAX (src1->y0, src2->y0); dest->x1 = MIN (src1->x1, src2->x1); dest->y1 = MIN (src1->y1, src2->y1); } /** * art_irect_empty: Determine whether rectangle is empty. * @src: The source rectangle. * * Return value: TRUE if @src is an empty rectangle, FALSE otherwise. **/ int art_drect_empty (const ArtDRect *src) { return (src->x1 <= src->x0 || src->y1 <= src->y0); } /** * art_drect_affine_transform: Affine transform rectangle. * @dst: Where to store the result. * @src: The source rectangle. * @matrix: The affine transformation. * * Find the smallest rectangle enclosing the affine transformed @src. * The result is exactly the affine transformation of @src when * @matrix specifies a rectilinear affine transformation, otherwise it * is a conservative approximation. **/ void art_drect_affine_transform (ArtDRect *dst, const ArtDRect *src, const double matrix[6]) { double x00, y00, x10, y10; double x01, y01, x11, y11; x00 = src->x0 * matrix[0] + src->y0 * matrix[2] + matrix[4]; y00 = src->x0 * matrix[1] + src->y0 * matrix[3] + matrix[5]; x10 = src->x1 * matrix[0] + src->y0 * matrix[2] + matrix[4]; y10 = src->x1 * matrix[1] + src->y0 * matrix[3] + matrix[5]; x01 = src->x0 * matrix[0] + src->y1 * matrix[2] + matrix[4]; y01 = src->x0 * matrix[1] + src->y1 * matrix[3] + matrix[5]; x11 = src->x1 * matrix[0] + src->y1 * matrix[2] + matrix[4]; y11 = src->x1 * matrix[1] + src->y1 * matrix[3] + matrix[5]; dst->x0 = MIN (MIN (x00, x10), MIN (x01, x11)); dst->y0 = MIN (MIN (y00, y10), MIN (y01, y11)); dst->x1 = MAX (MAX (x00, x10), MAX (x01, x11)); dst->y1 = MAX (MAX (y00, y10), MAX (y01, y11)); } /** * art_drect_to_irect: Convert rectangle to integer rectangle. * @dst: Where to store resulting integer rectangle. * @src: The source rectangle. * * Find the smallest integer rectangle that encloses @src. **/ void art_drect_to_irect (ArtIRect *dst, ArtDRect *src) { dst->x0 = floor (src->x0); dst->y0 = floor (src->y0); dst->x1 = ceil (src->x1); dst->y1 = ceil (src->y1); }