/* GSK - The GTK Scene Kit * * Copyright 2016 Endless * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser 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 * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library. If not, see . */ /** * GskRoundedRect: * @bounds: the bounds of the rectangle * @corner: the size of the 4 rounded corners * * A rectangular region with rounded corners. * * Application code should normalize rectangles using * [method@Gsk.RoundedRect.normalize]; this function will ensure that * the bounds of the rectangle are normalized and ensure that the corner * values are positive and the corners do not overlap. * * All functions taking a `GskRoundedRect` as an argument will internally * operate on a normalized copy; all functions returning a `GskRoundedRect` * will always return a normalized one. * * The algorithm used for normalizing corner sizes is described in * [the CSS specification](https://drafts.csswg.org/css-backgrounds-3/#border-radius). */ #include "config.h" #include "gskroundedrect.h" #include "gskroundedrectprivate.h" #include "gskdebugprivate.h" #include "gskrectprivate.h" #include static void gsk_rounded_rect_normalize_in_place (GskRoundedRect *self) { float factor = 1.0; float corners; guint i; graphene_rect_normalize (&self->bounds); for (i = 0; i < 4; i++) { self->corner[i].width = MAX (self->corner[i].width, 0); self->corner[i].height = MAX (self->corner[i].height, 0); } /* clamp border radius, following CSS specs */ corners = self->corner[GSK_CORNER_TOP_LEFT].width + self->corner[GSK_CORNER_TOP_RIGHT].width; if (corners > self->bounds.size.width) factor = MIN (factor, self->bounds.size.width / corners); corners = self->corner[GSK_CORNER_TOP_RIGHT].height + self->corner[GSK_CORNER_BOTTOM_RIGHT].height; if (corners > self->bounds.size.height) factor = MIN (factor, self->bounds.size.height / corners); corners = self->corner[GSK_CORNER_BOTTOM_RIGHT].width + self->corner[GSK_CORNER_BOTTOM_LEFT].width; if (corners > self->bounds.size.width) factor = MIN (factor, self->bounds.size.width / corners); corners = self->corner[GSK_CORNER_TOP_LEFT].height + self->corner[GSK_CORNER_BOTTOM_LEFT].height; if (corners > self->bounds.size.height) factor = MIN (factor, self->bounds.size.height / corners); for (i = 0; i < 4; i++) graphene_size_scale (&self->corner[i], factor, &self->corner[i]); } /** * gsk_rounded_rect_init: * @self: The `GskRoundedRect` to initialize * @bounds: a `graphene_rect_t` describing the bounds * @top_left: the rounding radius of the top left corner * @top_right: the rounding radius of the top right corner * @bottom_right: the rounding radius of the bottom right corner * @bottom_left: the rounding radius of the bottom left corner * * Initializes the given `GskRoundedRect` with the given values. * * This function will implicitly normalize the `GskRoundedRect` * before returning. * * Returns: (transfer none): the initialized rectangle */ GskRoundedRect * gsk_rounded_rect_init (GskRoundedRect *self, const graphene_rect_t *bounds, const graphene_size_t *top_left, const graphene_size_t *top_right, const graphene_size_t *bottom_right, const graphene_size_t *bottom_left) { graphene_rect_init_from_rect (&self->bounds, bounds); graphene_size_init_from_size (&self->corner[GSK_CORNER_TOP_LEFT], top_left); graphene_size_init_from_size (&self->corner[GSK_CORNER_TOP_RIGHT], top_right); graphene_size_init_from_size (&self->corner[GSK_CORNER_BOTTOM_RIGHT], bottom_right); graphene_size_init_from_size (&self->corner[GSK_CORNER_BOTTOM_LEFT], bottom_left); gsk_rounded_rect_normalize_in_place (self); return self; } /** * gsk_rounded_rect_init_copy: * @self: a `GskRoundedRect` * @src: a `GskRoundedRect` * * Initializes @self using the given @src rectangle. * * This function will not normalize the `GskRoundedRect`, * so make sure the source is normalized. * * Returns: (transfer none): the initialized rectangle */ GskRoundedRect * gsk_rounded_rect_init_copy (GskRoundedRect *self, const GskRoundedRect *src) { *self = *src; return self; } /** * gsk_rounded_rect_init_from_rect: * @self: a `GskRoundedRect` * @bounds: a `graphene_rect_t` * @radius: the border radius * * Initializes @self to the given @bounds and sets the radius * of all four corners to @radius. * * Returns: (transfer none): the initialized rectangle **/ GskRoundedRect * gsk_rounded_rect_init_from_rect (GskRoundedRect *self, const graphene_rect_t *bounds, float radius) { graphene_size_t corner = GRAPHENE_SIZE_INIT(radius, radius); return gsk_rounded_rect_init (self, bounds, &corner, &corner, &corner, &corner); } /** * gsk_rounded_rect_normalize: * @self: a `GskRoundedRect` * * Normalizes the passed rectangle. * * This function will ensure that the bounds of the rectangle * are normalized and ensure that the corner values are positive * and the corners do not overlap. * * Returns: (transfer none): the normalized rectangle */ GskRoundedRect * gsk_rounded_rect_normalize (GskRoundedRect *self) { gsk_rounded_rect_normalize_in_place (self); return self; } /** * gsk_rounded_rect_offset: * @self: a `GskRoundedRect` * @dx: the horizontal offset * @dy: the vertical offset * * Offsets the bound's origin by @dx and @dy. * * The size and corners of the rectangle are unchanged. * * Returns: (transfer none): the offset rectangle */ GskRoundedRect * gsk_rounded_rect_offset (GskRoundedRect *self, float dx, float dy) { gsk_rounded_rect_normalize (self); self->bounds.origin.x += dx; self->bounds.origin.y += dy; return self; } static inline void border_radius_shrink (graphene_size_t *corner, double width, double height, const graphene_size_t *max) { if (corner->width > 0) corner->width -= width; if (corner->height > 0) corner->height -= height; if (corner->width <= 0 || corner->height <= 0) { corner->width = 0; corner->height = 0; } else { corner->width = MIN (corner->width, max->width); corner->height = MIN (corner->height, max->height); } } /** * gsk_rounded_rect_shrink: * @self: The `GskRoundedRect` to shrink or grow * @top: How far to move the top side downwards * @right: How far to move the right side to the left * @bottom: How far to move the bottom side upwards * @left: How far to move the left side to the right * * Shrinks (or grows) the given rectangle by moving the 4 sides * according to the offsets given. * * The corner radii will be changed in a way that tries to keep * the center of the corner circle intact. This emulates CSS behavior. * * This function also works for growing rectangles if you pass * negative values for the @top, @right, @bottom or @left. * * Returns: (transfer none): the resized `GskRoundedRect` **/ GskRoundedRect * gsk_rounded_rect_shrink (GskRoundedRect *self, float top, float right, float bottom, float left) { float width = left + right; float height = top + bottom; if (self->bounds.size.width - width < 0) { self->bounds.origin.x += left * self->bounds.size.width / width; self->bounds.size.width = 0; } else { self->bounds.origin.x += left; self->bounds.size.width -= width; } if (self->bounds.size.height - height < 0) { self->bounds.origin.y += top * self->bounds.size.height / height; self->bounds.size.height = 0; } else { self->bounds.origin.y += top; self->bounds.size.height -= height; } border_radius_shrink (&self->corner[GSK_CORNER_TOP_LEFT], left, top, &self->bounds.size); border_radius_shrink (&self->corner[GSK_CORNER_TOP_RIGHT], right, top, &self->bounds.size); border_radius_shrink (&self->corner[GSK_CORNER_BOTTOM_RIGHT], right, bottom, &self->bounds.size); border_radius_shrink (&self->corner[GSK_CORNER_BOTTOM_LEFT], left, bottom, &self->bounds.size); return self; } void gsk_rounded_rect_scale_affine (GskRoundedRect *dest, const GskRoundedRect *src, float scale_x, float scale_y, float dx, float dy) { guint flip = ((scale_x < 0) ? 1 : 0) + (scale_y < 0 ? 2 : 0); g_assert (dest != src); graphene_rect_scale (&src->bounds, scale_x, scale_y, &dest->bounds); graphene_rect_offset (&dest->bounds, dx, dy); scale_x = fabs (scale_x); scale_y = fabs (scale_y); for (guint i = 0; i < 4; i++) { dest->corner[i].width = src->corner[i ^ flip].width * scale_x; dest->corner[i].height = src->corner[i ^ flip].height * scale_y; } } /* * gsk_rounded_rect_is_circular: * @self: the `GskRoundedRect` to check * * Checks if all corners of @self are quarter-circles (as * opposed to quarter-ellipses). * * Note that different corners can still have different radii. * * Returns: %TRUE if the rectangle is circular. */ gboolean gsk_rounded_rect_is_circular (const GskRoundedRect *self) { for (guint i = 0; i < 4; i++) { if (self->corner[i].width != self->corner[i].height) return FALSE; } return TRUE; } /** * gsk_rounded_rect_is_rectilinear: * @self: the `GskRoundedRect` to check * * Checks if all corners of @self are right angles and the * rectangle covers all of its bounds. * * This information can be used to decide if [ctor@Gsk.ClipNode.new] * or [ctor@Gsk.RoundedClipNode.new] should be called. * * Returns: %TRUE if the rectangle is rectilinear **/ gboolean gsk_rounded_rect_is_rectilinear (const GskRoundedRect *self) { for (guint i = 0; i < 4; i++) { if (self->corner[i].width > 0 || self->corner[i].height > 0) return FALSE; } return TRUE; } static inline gboolean ellipsis_contains_point (const graphene_size_t *ellipsis, const graphene_point_t *point) { return (point->x * point->x) / (ellipsis->width * ellipsis->width) + (point->y * point->y) / (ellipsis->height * ellipsis->height) <= 1; } typedef enum { INSIDE, OUTSIDE_TOP_LEFT, OUTSIDE_TOP_RIGHT, OUTSIDE_BOTTOM_LEFT, OUTSIDE_BOTTOM_RIGHT, OUTSIDE } Location; static Location gsk_rounded_rect_locate_point (const GskRoundedRect *self, const graphene_point_t *point) { float px, py; float ox, oy; ox = self->bounds.origin.x + self->bounds.size.width; oy = self->bounds.origin.y + self->bounds.size.height; if (point->x < self->bounds.origin.x || point->y < self->bounds.origin.y || point->x > ox || point->y > oy) return OUTSIDE; px = self->bounds.origin.x + self->corner[GSK_CORNER_TOP_LEFT].width - point->x; py = self->bounds.origin.y + self->corner[GSK_CORNER_TOP_LEFT].height - point->y; if (px > 0 && py > 0 && !ellipsis_contains_point (&self->corner[GSK_CORNER_TOP_LEFT], &GRAPHENE_POINT_INIT (px, py))) return OUTSIDE_TOP_LEFT; px = ox - self->corner[GSK_CORNER_TOP_RIGHT].width - point->x; py = self->bounds.origin.y + self->corner[GSK_CORNER_TOP_RIGHT].height - point->y; if (px < 0 && py > 0 && !ellipsis_contains_point (&self->corner[GSK_CORNER_TOP_RIGHT], &GRAPHENE_POINT_INIT (px, py))) return OUTSIDE_TOP_RIGHT; px = self->bounds.origin.x + self->corner[GSK_CORNER_BOTTOM_LEFT].width - point->x; py = oy - self->corner[GSK_CORNER_BOTTOM_LEFT].height - point->y; if (px > 0 && py < 0 && !ellipsis_contains_point (&self->corner[GSK_CORNER_BOTTOM_LEFT], &GRAPHENE_POINT_INIT (px, py))) return OUTSIDE_BOTTOM_LEFT; px = ox - self->corner[GSK_CORNER_BOTTOM_RIGHT].width - point->x; py = oy - self->corner[GSK_CORNER_BOTTOM_RIGHT].height - point->y; if (px < 0 && py < 0 && !ellipsis_contains_point (&self->corner[GSK_CORNER_BOTTOM_RIGHT], &GRAPHENE_POINT_INIT (px, py))) return OUTSIDE_BOTTOM_RIGHT; return INSIDE; } /** * gsk_rounded_rect_contains_point: * @self: a `GskRoundedRect` * @point: the point to check * * Checks if the given @point is inside the rounded rectangle. * * Returns: %TRUE if the @point is inside the rounded rectangle **/ gboolean gsk_rounded_rect_contains_point (const GskRoundedRect *self, const graphene_point_t *point) { return gsk_rounded_rect_locate_point (self, point) == INSIDE; } /** * gsk_rounded_rect_contains_rect: * @self: a `GskRoundedRect` * @rect: the rectangle to check * * Checks if the given @rect is contained inside the rounded rectangle. * * Returns: %TRUE if the @rect is fully contained inside the rounded rectangle **/ gboolean gsk_rounded_rect_contains_rect (const GskRoundedRect *self, const graphene_rect_t *rect) { float tx, ty; float px, py; float ox, oy; tx = rect->origin.x + rect->size.width; ty = rect->origin.y + rect->size.height; ox = self->bounds.origin.x + self->bounds.size.width; oy = self->bounds.origin.y + self->bounds.size.height; if (rect->origin.x < self->bounds.origin.x || rect->origin.y < self->bounds.origin.y || tx > ox || ty > oy) return FALSE; px = self->bounds.origin.x + self->corner[GSK_CORNER_TOP_LEFT].width - rect->origin.x; py = self->bounds.origin.y + self->corner[GSK_CORNER_TOP_LEFT].height - rect->origin.y; if (px > 0 && py > 0 && !ellipsis_contains_point (&self->corner[GSK_CORNER_TOP_LEFT], &GRAPHENE_POINT_INIT (px, py))) return FALSE; px = ox - self->corner[GSK_CORNER_TOP_RIGHT].width - tx; py = self->bounds.origin.y + self->corner[GSK_CORNER_TOP_RIGHT].height - rect->origin.y; if (px < 0 && py > 0 && !ellipsis_contains_point (&self->corner[GSK_CORNER_TOP_RIGHT], &GRAPHENE_POINT_INIT (px, py))) return FALSE; px = self->bounds.origin.x + self->corner[GSK_CORNER_BOTTOM_LEFT].width - rect->origin.x; py = oy - self->corner[GSK_CORNER_BOTTOM_LEFT].height - ty; if (px > 0 && py < 0 && !ellipsis_contains_point (&self->corner[GSK_CORNER_BOTTOM_LEFT], &GRAPHENE_POINT_INIT (px, py))) return FALSE; px = ox - self->corner[GSK_CORNER_BOTTOM_RIGHT].width - tx; py = oy - self->corner[GSK_CORNER_BOTTOM_RIGHT].height - ty; if (px < 0 && py < 0 && !ellipsis_contains_point (&self->corner[GSK_CORNER_BOTTOM_RIGHT], &GRAPHENE_POINT_INIT (px, py))) return FALSE; return TRUE; } /** * gsk_rounded_rect_intersects_rect: * @self: a `GskRoundedRect` * @rect: the rectangle to check * * Checks if part of the given @rect is contained inside the rounded rectangle. * * Returns: %TRUE if the @rect intersects with the rounded rectangle */ gboolean gsk_rounded_rect_intersects_rect (const GskRoundedRect *self, const graphene_rect_t *rect) { if (!gsk_rect_intersects (&self->bounds, rect)) return FALSE; /* If the bounding boxes intersect but the rectangles don't, * one of the rect's corners must be in the opposite corner's * outside region */ if (gsk_rounded_rect_locate_point (self, &rect->origin) == OUTSIDE_BOTTOM_RIGHT || gsk_rounded_rect_locate_point (self, &GRAPHENE_POINT_INIT (rect->origin.x + rect->size.width, rect->origin.y)) == OUTSIDE_BOTTOM_LEFT || gsk_rounded_rect_locate_point (self, &GRAPHENE_POINT_INIT (rect->origin.x, rect->origin.y + rect->size.height)) == OUTSIDE_TOP_RIGHT || gsk_rounded_rect_locate_point (self, &GRAPHENE_POINT_INIT (rect->origin.x + rect->size.width, rect->origin.y + rect->size.height)) == OUTSIDE_TOP_LEFT) return FALSE; return TRUE; } #define rect_point0(r) ((r)->origin) #define rect_point1(r) (GRAPHENE_POINT_INIT ((r)->origin.x + (r)->size.width, (r)->origin.y)) #define rect_point2(r) (GRAPHENE_POINT_INIT ((r)->origin.x + (r)->size.width, (r)->origin.y + (r)->size.height)) #define rect_point3(r) (GRAPHENE_POINT_INIT ((r)->origin.x, (r)->origin.y + (r)->size.height)) #define rounded_rect_corner0(r) \ (GRAPHENE_RECT_INIT((r)->bounds.origin.x, \ (r)->bounds.origin.y, \ (r)->corner[0].width, (r)->corner[0].height)) #define rounded_rect_corner1(r) \ (GRAPHENE_RECT_INIT((r)->bounds.origin.x + (r)->bounds.size.width - (r)->corner[1].width, \ (r)->bounds.origin.y, \ (r)->corner[1].width, (r)->corner[1].height)) #define rounded_rect_corner2(r) \ (GRAPHENE_RECT_INIT((r)->bounds.origin.x + (r)->bounds.size.width - (r)->corner[2].width, \ (r)->bounds.origin.y + (r)->bounds.size.height - (r)->corner[2].height, \ (r)->corner[2].width, (r)->corner[2].height)) #define rounded_rect_corner3(r) \ (GRAPHENE_RECT_INIT((r)->bounds.origin.x, \ (r)->bounds.origin.y + (r)->bounds.size.height - (r)->corner[3].height, \ (r)->corner[3].width, (r)->corner[3].height)) enum { BELOW, INNER, ABOVE }; static inline void classify_point (const graphene_point_t *p, const graphene_rect_t *rect, int *px, int *py) { if (p->x <= rect->origin.x) *px = BELOW; else if (p->x >= rect->origin.x + rect->size.width) *px = ABOVE; else *px = INNER; if (p->y <= rect->origin.y) *py = BELOW; else if (p->y >= rect->origin.y + rect->size.height) *py = ABOVE; else *py = INNER; } GskRoundedRectIntersection gsk_rounded_rect_intersect_with_rect (const GskRoundedRect *self, const graphene_rect_t *rect, GskRoundedRect *result) { int px, py, qx, qy; if (!graphene_rect_intersection (&self->bounds, rect, &result->bounds)) return GSK_INTERSECTION_EMPTY; classify_point (&rect_point0 (rect), &rounded_rect_corner0 (self), &px, &py); if (px == BELOW && py == BELOW) { classify_point (&rect_point2 (rect), &rounded_rect_corner0 (self), &qx, &qy); if (qx == BELOW || qy == BELOW) return GSK_INTERSECTION_EMPTY; else if (qx == INNER && qy == INNER && gsk_rounded_rect_locate_point (self, &rect_point2 (rect)) != INSIDE) return GSK_INTERSECTION_EMPTY; else if (qx == ABOVE && qy == ABOVE) result->corner[0] = self->corner[0]; else return GSK_INTERSECTION_NOT_REPRESENTABLE; } else if ((px == INNER || py == INNER) && gsk_rounded_rect_locate_point (self, &rect_point0 (rect)) != INSIDE) { if (gsk_rounded_rect_locate_point (self, &rect_point2 (rect)) == OUTSIDE_TOP_LEFT) return GSK_INTERSECTION_EMPTY; else return GSK_INTERSECTION_NOT_REPRESENTABLE; } else result->corner[0].width = result->corner[0].height = 0; classify_point (&rect_point1 (rect), &rounded_rect_corner1 (self), &px, &py); if (px == ABOVE && py == BELOW) { classify_point (&rect_point3 (rect), &rounded_rect_corner1 (self), &qx, &qy); if (qx == ABOVE || qy == BELOW) return GSK_INTERSECTION_EMPTY; else if (qx == INNER && qy == INNER && gsk_rounded_rect_locate_point (self, &rect_point3 (rect)) != INSIDE) return GSK_INTERSECTION_EMPTY; else if (qx == BELOW && qy == ABOVE) result->corner[1] = self->corner[1]; else return GSK_INTERSECTION_NOT_REPRESENTABLE; } else if ((px == INNER || py == INNER) && gsk_rounded_rect_locate_point (self, &rect_point1 (rect)) != INSIDE) { if (gsk_rounded_rect_locate_point (self, &rect_point3 (rect)) == OUTSIDE_TOP_RIGHT) return GSK_INTERSECTION_EMPTY; else return GSK_INTERSECTION_NOT_REPRESENTABLE; } else result->corner[1].width = result->corner[1].height = 0; classify_point (&rect_point2 (rect), &rounded_rect_corner2 (self), &px, &py); if (px == ABOVE && py == ABOVE) { classify_point (&rect_point0 (rect), &rounded_rect_corner2 (self), &qx, &qy); if (qx == ABOVE || qy == ABOVE) return GSK_INTERSECTION_EMPTY; else if (qx == INNER && qy == INNER && gsk_rounded_rect_locate_point (self, &rect_point0 (rect)) != INSIDE) return GSK_INTERSECTION_EMPTY; else if (qx == BELOW && qy == BELOW) result->corner[2] = self->corner[2]; else return GSK_INTERSECTION_NOT_REPRESENTABLE; } else if ((px == INNER || py == INNER) && gsk_rounded_rect_locate_point (self, &rect_point2 (rect)) != INSIDE) { if (gsk_rounded_rect_locate_point (self, &rect_point0 (rect)) == OUTSIDE_BOTTOM_RIGHT) return GSK_INTERSECTION_EMPTY; else return GSK_INTERSECTION_NOT_REPRESENTABLE; } else result->corner[2].width = result->corner[2].height = 0; classify_point (&rect_point3 (rect), &rounded_rect_corner3 (self), &px, &py); if (px == BELOW && py == ABOVE) { classify_point (&rect_point1 (rect), &rounded_rect_corner3 (self), &qx, &qy); if (qx == BELOW || qy == ABOVE) return GSK_INTERSECTION_EMPTY; else if (qx == INNER && qy == INNER && gsk_rounded_rect_locate_point (self, &rect_point1 (rect)) != INSIDE) return GSK_INTERSECTION_EMPTY; else if (qx == ABOVE && qy == BELOW) result->corner[3] = self->corner[3]; else return GSK_INTERSECTION_NOT_REPRESENTABLE; } else if ((px == INNER || py == INNER) && gsk_rounded_rect_locate_point (self, &rect_point3 (rect)) != INSIDE) { if (gsk_rounded_rect_locate_point (self, &rect_point1 (rect)) == OUTSIDE_BOTTOM_LEFT) return GSK_INTERSECTION_EMPTY; else return GSK_INTERSECTION_NOT_REPRESENTABLE; } else result->corner[3].width = result->corner[3].height = 0; return GSK_INTERSECTION_NONEMPTY; } static gboolean check_nonintersecting_corner (const GskRoundedRect *out, const GskRoundedRect *in, GskCorner corner, float diff_x, float diff_y, GskRoundedRect *result) { g_assert (diff_x >= 0); g_assert (diff_y >= 0); if (out->corner[corner].width < diff_x || out->corner[corner].height < diff_y || (out->corner[corner].width <= in->corner[corner].width + diff_x && out->corner[corner].height <= in->corner[corner].height + diff_y)) { result->corner[corner] = in->corner[corner]; return TRUE; } if (diff_x > 0 || diff_y > 0) return FALSE; if (out->corner[corner].width > in->corner[corner].width && out->corner[corner].height > in->corner[corner].height) { result->corner[corner] = out->corner[corner]; return TRUE; } return FALSE; } /* a is outside in x direction, b is outside in y direction */ static gboolean check_intersecting_corner (const GskRoundedRect *a, const GskRoundedRect *b, GskCorner corner, float diff_x, float diff_y, GskRoundedRect *result) { g_assert (diff_x > 0); g_assert (diff_y > 0); if (diff_x < a->corner[corner].width || diff_x > a->bounds.size.width - a->corner[corner].width - a->corner[OPPOSITE_CORNER_X (corner)].width || diff_y < b->corner[corner].height || diff_y > b->bounds.size.height - b->corner[corner].height - b->corner[OPPOSITE_CORNER_Y (corner)].height) return FALSE; result->corner[corner] = GRAPHENE_SIZE_INIT (0, 0); return TRUE; } static gboolean check_corner (const GskRoundedRect *a, const GskRoundedRect *b, GskCorner corner, float diff_x, float diff_y, GskRoundedRect *result) { if (diff_x >= 0) { if (diff_y >= 0) { return check_nonintersecting_corner (a, b, corner, diff_x, diff_y, result); } else if (diff_x == 0) { return check_nonintersecting_corner (b, a, corner, 0, - diff_y, result); } else { return check_intersecting_corner (a, b, corner, diff_x, - diff_y, result); } } else { if (diff_y <= 0) { return check_nonintersecting_corner (b, a, corner, - diff_x, - diff_y, result); } else { return check_intersecting_corner (b, a, corner, - diff_x, diff_y, result); } } } GskRoundedRectIntersection gsk_rounded_rect_intersection (const GskRoundedRect *a, const GskRoundedRect *b, GskRoundedRect *result) { float top, left, bottom, right; if (!graphene_rect_intersection (&a->bounds, &b->bounds, &result->bounds)) return GSK_INTERSECTION_EMPTY; left = b->bounds.origin.x - a->bounds.origin.x; top = b->bounds.origin.y - a->bounds.origin.y; right = a->bounds.origin.x + a->bounds.size.width - b->bounds.origin.x - b->bounds.size.width; bottom = a->bounds.origin.y + a->bounds.size.height - b->bounds.origin.y - b->bounds.size.height; if (check_corner (a, b, GSK_CORNER_TOP_LEFT, left, top, result) && check_corner (a, b, GSK_CORNER_TOP_RIGHT, right, top, result) && check_corner (a, b, GSK_CORNER_BOTTOM_LEFT, left, bottom, result) && check_corner (a, b, GSK_CORNER_BOTTOM_RIGHT, right, bottom, result)) return GSK_INTERSECTION_NONEMPTY; return GSK_INTERSECTION_NOT_REPRESENTABLE; } static void append_arc (cairo_t *cr, double angle1, double angle2, gboolean negative) { if (negative) cairo_arc_negative (cr, 0.0, 0.0, 1.0, angle1, angle2); else cairo_arc (cr, 0.0, 0.0, 1.0, angle1, angle2); } static void _cairo_ellipsis (cairo_t *cr, double xc, double yc, double xradius, double yradius, double angle1, double angle2) { cairo_matrix_t save; if (xradius <= 0.0 || yradius <= 0.0) { cairo_line_to (cr, xc, yc); return; } cairo_get_matrix (cr, &save); cairo_translate (cr, xc, yc); cairo_scale (cr, xradius, yradius); append_arc (cr, angle1, angle2, FALSE); cairo_set_matrix (cr, &save); } void gsk_rounded_rect_path (const GskRoundedRect *self, cairo_t *cr) { cairo_new_sub_path (cr); _cairo_ellipsis (cr, self->bounds.origin.x + self->corner[GSK_CORNER_TOP_LEFT].width, self->bounds.origin.y + self->corner[GSK_CORNER_TOP_LEFT].height, self->corner[GSK_CORNER_TOP_LEFT].width, self->corner[GSK_CORNER_TOP_LEFT].height, G_PI, 3 * G_PI_2); _cairo_ellipsis (cr, self->bounds.origin.x + self->bounds.size.width - self->corner[GSK_CORNER_TOP_RIGHT].width, self->bounds.origin.y + self->corner[GSK_CORNER_TOP_RIGHT].height, self->corner[GSK_CORNER_TOP_RIGHT].width, self->corner[GSK_CORNER_TOP_RIGHT].height, - G_PI_2, 0); _cairo_ellipsis (cr, self->bounds.origin.x + self->bounds.size.width - self->corner[GSK_CORNER_BOTTOM_RIGHT].width, self->bounds.origin.y + self->bounds.size.height - self->corner[GSK_CORNER_BOTTOM_RIGHT].height, self->corner[GSK_CORNER_BOTTOM_RIGHT].width, self->corner[GSK_CORNER_BOTTOM_RIGHT].height, 0, G_PI_2); _cairo_ellipsis (cr, self->bounds.origin.x + self->corner[GSK_CORNER_BOTTOM_LEFT].width, self->bounds.origin.y + self->bounds.size.height - self->corner[GSK_CORNER_BOTTOM_LEFT].height, self->corner[GSK_CORNER_BOTTOM_LEFT].width, self->corner[GSK_CORNER_BOTTOM_LEFT].height, G_PI_2, G_PI); cairo_close_path (cr); } /*< private > * Converts to the format we use in our shaders: * vec4 rect; * vec4 corner_widths; * vec4 corner_heights; * rect is (x, y, width, height), the corners are the same * order as in the rounded rect. * * This is so that shaders can use just the first vec4 for * rectilinear rects, the 2nd vec4 for circular rects and * only look at the last vec4 if they have to. */ void gsk_rounded_rect_to_float (const GskRoundedRect *self, const graphene_point_t *offset, float rect[12]) { guint i; rect[0] = self->bounds.origin.x + offset->x; rect[1] = self->bounds.origin.y + offset->y; rect[2] = self->bounds.size.width; rect[3] = self->bounds.size.height; for (i = 0; i < 4; i++) { rect[4 + i] = self->corner[i].width; rect[8 + i] = self->corner[i].height; } } gboolean gsk_rounded_rect_equal (gconstpointer rect1, gconstpointer rect2) { const GskRoundedRect *self1 = rect1; const GskRoundedRect *self2 = rect2; return graphene_rect_equal (&self1->bounds, &self2->bounds) && graphene_size_equal (&self1->corner[0], &self2->corner[0]) && graphene_size_equal (&self1->corner[1], &self2->corner[1]) && graphene_size_equal (&self1->corner[2], &self2->corner[2]) && graphene_size_equal (&self1->corner[3], &self2->corner[3]); } char * gsk_rounded_rect_to_string (const GskRoundedRect *self) { return g_strdup_printf ("GskRoundedRect %p: Bounds: (%f, %f, %f, %f)" " Corners: (%f, %f) (%f, %f) (%f, %f) (%f, %f)", self, self->bounds.origin.x, self->bounds.origin.y, self->bounds.size.width, self->bounds.size.height, self->corner[0].width, self->corner[0].height, self->corner[1].width, self->corner[1].height, self->corner[2].width, self->corner[2].height, self->corner[3].width, self->corner[3].height); } /* * gsk_rounded_rect_get_largest_cover: * @self: the rounded rect to intersect with * @rect: the rectangle to intersect * @result: (out caller-allocates): The resulting rectangle * * Computes the largest rectangle that is fully covered by both * the given rect and the rounded rect. * In particular, this function respects corners, so * gsk_rounded_rect_get_largest_cover(self, &self->bounds, &rect) * can be used to compute a decomposition for a rounded rect itself. **/ void gsk_rounded_rect_get_largest_cover (const GskRoundedRect *self, const graphene_rect_t *rect, graphene_rect_t *result) { graphene_rect_t wide, high; double start, end; wide = self->bounds; start = MAX(self->corner[GSK_CORNER_TOP_LEFT].height, self->corner[GSK_CORNER_TOP_RIGHT].height); end = MAX(self->corner[GSK_CORNER_BOTTOM_LEFT].height, self->corner[GSK_CORNER_BOTTOM_RIGHT].height); wide.size.height -= MIN (wide.size.height, start + end); wide.origin.y += start; graphene_rect_intersection (&wide, rect, &wide); high = self->bounds; start = MAX(self->corner[GSK_CORNER_TOP_LEFT].width, self->corner[GSK_CORNER_BOTTOM_LEFT].width); end = MAX(self->corner[GSK_CORNER_TOP_RIGHT].width, self->corner[GSK_CORNER_BOTTOM_RIGHT].width); high.size.width -= MIN (high.size.width, start + end); high.origin.x += start; graphene_rect_intersection (&high, rect, &high); if (wide.size.width * wide.size.height > high.size.width * high.size.height) *result = wide; else *result = high; }