/* * Copyright © 2020 Benjamin Otte * * 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 2.1 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 . * * Authors: Benjamin Otte */ #include "config.h" #include "gskcontourprivate.h" #include "gskcurveprivate.h" #include "gskpathbuilder.h" #include "gskpathprivate.h" #include "gskpathpoint.h" #include "gskstrokeprivate.h" #include /* This is C11 */ #ifndef FLT_DECIMAL_DIG #define FLT_DECIMAL_DIG 9 #endif typedef struct _GskContourClass GskContourClass; struct _GskContour { const GskContourClass *klass; }; struct _GskContourClass { gsize struct_size; const char *type_name; void (* copy) (const GskContour *contour, GskContour *dest); gsize (* get_size) (const GskContour *contour); GskPathFlags (* get_flags) (const GskContour *contour); void (* print) (const GskContour *contour, GString *string); gboolean (* get_bounds) (const GskContour *contour, GskBoundingBox *bounds); gboolean (* get_stroke_bounds) (const GskContour *contour, const GskStroke *stroke, GskBoundingBox *bounds); gboolean (* foreach) (const GskContour *contour, GskPathForeachFunc func, gpointer user_data); GskContour * (* reverse) (const GskContour *contour); int (* get_winding) (const GskContour *contour, const graphene_point_t *point); gsize (* get_n_ops) (const GskContour *contour); gboolean (* get_closest_point) (const GskContour *contour, const graphene_point_t *point, float threshold, GskPathPoint *result, float *out_dist); void (* get_position) (const GskContour *contour, const GskPathPoint *point, graphene_point_t *position); void (* get_tangent) (const GskContour *contour, const GskPathPoint *point, GskPathDirection direction, graphene_vec2_t *tangent); float (* get_curvature) (const GskContour *contour, const GskPathPoint *point, GskPathDirection direction, graphene_point_t *center); void (* add_segment) (const GskContour *contour, GskPathBuilder *builder, gboolean emit_move_to, const GskPathPoint *start, const GskPathPoint *end); gpointer (* init_measure) (const GskContour *contour, float tolerance, float *out_length); void (* free_measure) (const GskContour *contour, gpointer measure_data); void (* get_point) (const GskContour *contour, gpointer measure_data, float distance, GskPathPoint *result); float (* get_distance) (const GskContour *contour, const GskPathPoint *point, gpointer measure_data); }; /* {{{ Utilities */ #define DEG_TO_RAD(x) ((x) * (G_PI / 180.f)) #define RAD_TO_DEG(x) ((x) / (G_PI / 180.f)) static inline void _sincosf (float angle, float *out_s, float *out_c) { #ifdef HAVE_SINCOSF sincosf (angle, out_s, out_c); #else *out_s = sinf (angle); *out_c = cosf (angle); #endif } static void _g_string_append_float (GString *string, const char *prefix, float f) { g_string_append (string, prefix); g_string_append_printf (string, "%.*g", FLT_DECIMAL_DIG, f); } static void _g_string_append_point (GString *string, const char *prefix, const graphene_point_t *pt) { _g_string_append_float (string, prefix, pt->x); _g_string_append_float (string, " ", pt->y); } static gboolean add_segment (GskPathOperation op, const graphene_point_t *pts, gsize n_pts, float weight, gpointer user_data) { GskPathBuilder *builder = user_data; switch (op) { case GSK_PATH_MOVE: gsk_path_builder_move_to (builder, pts[0].x, pts[0].y); break; case GSK_PATH_LINE: gsk_path_builder_line_to (builder, pts[1].x, pts[1].y); break; case GSK_PATH_QUAD: gsk_path_builder_quad_to (builder, pts[1].x, pts[1].y, pts[2].x, pts[2].y); break; case GSK_PATH_CUBIC: gsk_path_builder_cubic_to (builder, pts[1].x, pts[1].y, pts[2].x, pts[2].y, pts[3].x, pts[3].y); break; case GSK_PATH_CONIC: gsk_path_builder_conic_to (builder, pts[1].x, pts[1].y, pts[2].x, pts[2].y, weight); break; case GSK_PATH_CLOSE: gsk_path_builder_close (builder); break; default: g_assert_not_reached (); } return TRUE; } static GskPath * convert_to_standard_contour (const GskContour *contour) { GskPathBuilder *builder; builder = gsk_path_builder_new (); gsk_contour_foreach (contour, add_segment, builder); return gsk_path_builder_free_to_path (builder); } typedef struct { GskCurve *curve; unsigned int idx; unsigned int count; } InitCurveData; static gboolean init_curve_cb (GskPathOperation op, const graphene_point_t *pts, gsize n_pts, float weight, gpointer user_data) { InitCurveData *data = user_data; if (data->idx == data->count) { gsk_curve_init_foreach (data->curve, op, pts, n_pts, weight); return FALSE; } data->count++; return TRUE; } static void contour_init_curve (const GskContour *contour, unsigned int idx, GskCurve *curve) { InitCurveData data; data.curve = curve; data.idx = idx; data.count = 0; gsk_contour_foreach (contour, init_curve_cb, &data); } typedef struct { graphene_point_t point; float threshold; gsize idx; gsize best_idx; gsize best_t; } ClosestPointData; static gboolean get_closest_point_cb (GskPathOperation op, const graphene_point_t *pts, gsize n_pts, float weight, gpointer data) { GskCurve curve; ClosestPointData *pd = data; float distance, t; if (op == GSK_PATH_MOVE) return TRUE; pd->idx++; gsk_curve_init_foreach (&curve, op, pts, n_pts, weight); if (gsk_curve_get_closest_point (&curve, &pd->point, pd->threshold, &distance, &t) && distance < pd->threshold) { pd->best_idx = pd->idx; pd->best_t = t; pd->threshold = distance; } return TRUE; } static gboolean contour_get_closest_point (const GskContour *contour, const graphene_point_t *point, float threshold, GskPathPoint *result, float *out_dist) { ClosestPointData pd; pd.point = *point; pd.threshold = threshold; pd.idx = 0; pd.best_idx = G_MAXUINT; gsk_contour_foreach (contour, get_closest_point_cb, &pd); if (pd.best_idx != G_MAXUINT) { result->idx = pd.best_idx; result->t = pd.best_t; *out_dist = pd.threshold; return TRUE; } return FALSE; } static void add_curve (GskCurve *curve, GskPathBuilder *builder, gboolean *emit_move_to) { if (*emit_move_to) { const graphene_point_t *s; s = gsk_curve_get_start_point (curve); gsk_path_builder_move_to (builder, s->x, s->y); *emit_move_to = FALSE; } gsk_curve_builder_to (curve, builder); } typedef struct { GskPathBuilder *builder; gboolean emit_move_to; GskPathPoint start; GskPathPoint end; gsize idx; } AddSegmentData; static gboolean add_segment_cb (GskPathOperation op, const graphene_point_t *pts, gsize n_pts, float weight, gpointer data) { AddSegmentData *sd = data; GskCurve c, c1, c2; if (op == GSK_PATH_MOVE) return TRUE; sd->idx++; if (sd->start.idx > sd->idx) return TRUE; if (sd->end.idx < sd->idx) return FALSE; if (op == GSK_PATH_CLOSE) op = GSK_PATH_LINE; gsk_curve_init_foreach (&c, op, pts, n_pts, weight); if (sd->start.idx == sd->idx) { if (sd->end.idx == sd->idx) { gsk_curve_segment (&c, sd->start.t, sd->end.t, &c1); add_curve (&c1, sd->builder, &sd->emit_move_to); return FALSE; } else { gsk_curve_split (&c, sd->start.t, &c1, &c2); add_curve (&c2, sd->builder, &sd->emit_move_to); return TRUE; } } else { if (sd->end.idx == sd->idx) { gsk_curve_split (&c, sd->end.t, &c1, &c2); add_curve (&c1, sd->builder, &sd->emit_move_to); return FALSE; } else { add_curve (&c, sd->builder, &sd->emit_move_to); return TRUE; } } } static void contour_add_segment (const GskContour *contour, GskPathBuilder *builder, gboolean emit_move_to, const GskPathPoint *start, const GskPathPoint *end) { AddSegmentData sd; sd.builder = builder; sd.emit_move_to = emit_move_to; sd.start = *start; sd.end = *end; sd.idx = 0; gsk_contour_foreach (contour, add_segment_cb, &sd); } static inline gboolean maybe_emit_line (const graphene_point_t pts[2], GskPathForeachFunc func, gpointer user_data) { if (graphene_point_equal (&pts[0], &pts[1])) return TRUE; return func (GSK_PATH_LINE, pts, 2, 0.f, user_data); } static inline gboolean maybe_emit_conic (const graphene_point_t pts[3], float weight, GskPathForeachFunc func, gpointer user_data) { if (graphene_point_equal (&pts[0], &pts[1])) { if (graphene_point_equal (&pts[1], &pts[2])) return TRUE; else return func (GSK_PATH_LINE, &pts[1], 2, 0.f, user_data); } else if (graphene_point_equal (&pts[1], &pts[2])) return func (GSK_PATH_LINE, &pts[0], 2, 0.f, user_data); return func (GSK_PATH_CONIC, pts, 3, weight, user_data); } /* Assumes a closed contour */ static void apply_corner_direction (GskPathDirection direction, gsize *idx, float *t, gsize n_ops) { if (*t == 0 && (direction == GSK_PATH_FROM_START || direction == GSK_PATH_TO_START)) { if (*idx > 1) *idx = *idx - 1; else *idx = n_ops - 1; *t = 1; } else if (*t == 1 && (direction == GSK_PATH_FROM_END || direction == GSK_PATH_TO_END)) { if (*idx < n_ops - 1) *idx = *idx + 1; else *idx = 1; *t = 0; } } /* }}} */ /* {{{ Default implementations */ static gsize gsk_contour_get_size_default (const GskContour *contour) { return contour->klass->struct_size; } static gboolean foreach_print (GskPathOperation op, const graphene_point_t *pts, gsize n_pts, float weight, gpointer data) { GString *string = data; switch (op) { case GSK_PATH_MOVE: _g_string_append_point (string, "M ", &pts[0]); break; case GSK_PATH_CLOSE: g_string_append (string, " Z"); break; case GSK_PATH_LINE: _g_string_append_point (string, " L ", &pts[1]); break; case GSK_PATH_QUAD: _g_string_append_point (string, " Q ", &pts[1]); _g_string_append_point (string, ", ", &pts[2]); break; case GSK_PATH_CUBIC: _g_string_append_point (string, " C ", &pts[1]); _g_string_append_point (string, ", ", &pts[2]); _g_string_append_point (string, ", ", &pts[3]); break; case GSK_PATH_CONIC: _g_string_append_point (string, " O ", &pts[1]); _g_string_append_point (string, ", ", &pts[2]); _g_string_append_float (string, ", ", weight); break; default: g_assert_not_reached (); } return TRUE; } static void gsk_contour_print_default (const GskContour *contour, GString *string) { gsk_contour_foreach (contour, foreach_print, string); } /* }}} */ /* {{{ Standard */ typedef struct _GskStandardContour GskStandardContour; struct _GskStandardContour { GskContour contour; GskPathFlags flags; GskBoundingBox bounds; gsize n_ops; gsize n_points; graphene_point_t *points; gskpathop ops[]; }; static gsize gsk_standard_contour_compute_size (gsize n_ops, gsize n_points) { gsize align = MAX (G_ALIGNOF (graphene_point_t), MAX (G_ALIGNOF (gpointer), G_ALIGNOF (GskStandardContour))); gsize s = sizeof (GskStandardContour) + sizeof (gskpathop) * n_ops + sizeof (graphene_point_t) * n_points; return s + (align - (s % align)); } static void gsk_standard_contour_init (GskContour *contour, GskPathFlags flags, const graphene_point_t *points, gsize n_points, const gskpathop *ops, gsize n_ops, ptrdiff_t offset); static void gsk_standard_contour_copy (const GskContour *contour, GskContour *dest) { const GskStandardContour *self = (const GskStandardContour *) contour; gsk_standard_contour_init (dest, self->flags, self->points, self->n_points, self->ops, self->n_ops, 0); } static gsize gsk_standard_contour_get_size (const GskContour *contour) { const GskStandardContour *self = (const GskStandardContour *) contour; return gsk_standard_contour_compute_size (self->n_ops, self->n_points); } static gboolean gsk_standard_contour_foreach (const GskContour *contour, GskPathForeachFunc func, gpointer user_data) { const GskStandardContour *self = (const GskStandardContour *) contour; gsize i; for (i = 0; i < self->n_ops; i ++) { if (!gsk_pathop_foreach (self->ops[i], func, user_data)) return FALSE; } return TRUE; } static gboolean add_reverse (GskPathOperation op, const graphene_point_t *pts, gsize n_pts, float weight, gpointer user_data) { GskPathBuilder *builder = user_data; GskCurve c, r; if (op == GSK_PATH_MOVE) return TRUE; if (op == GSK_PATH_CLOSE) op = GSK_PATH_LINE; gsk_curve_init_foreach (&c, op, pts, n_pts, weight); gsk_curve_reverse (&c, &r); gsk_curve_builder_to (&r, builder); return TRUE; } static GskContour * gsk_standard_contour_reverse (const GskContour *contour) { const GskStandardContour *self = (const GskStandardContour *) contour; GskPathBuilder *builder; GskPath *path; GskContour *res; builder = gsk_path_builder_new (); gsk_path_builder_move_to (builder, self->points[self->n_points - 1].x, self->points[self->n_points - 1].y); for (int i = self->n_ops - 1; i >= 0; i--) gsk_pathop_foreach (self->ops[i], add_reverse, builder); if (self->flags & GSK_PATH_CLOSED) gsk_path_builder_close (builder); path = gsk_path_builder_free_to_path (builder); g_assert (gsk_path_get_n_contours (path) == 1); res = gsk_contour_dup (gsk_path_get_contour (path, 0)); gsk_path_unref (path); return res; } static GskPathFlags gsk_standard_contour_get_flags (const GskContour *contour) { const GskStandardContour *self = (const GskStandardContour *) contour; return self->flags; } static gboolean gsk_standard_contour_get_bounds (const GskContour *contour, GskBoundingBox *bounds) { const GskStandardContour *self = (const GskStandardContour *) contour; if (self->n_points == 0) return FALSE; *bounds = self->bounds; return bounds->max.x > bounds->min.x && bounds->max.y > bounds->min.y; } static gboolean gsk_standard_contour_get_stroke_bounds (const GskContour *contour, const GskStroke *stroke, GskBoundingBox *bounds) { GskStandardContour *self = (GskStandardContour *) contour; float extra; if (self->n_points == 0) return FALSE; extra = MAX (stroke->line_width, gsk_stroke_get_join_width (stroke)); gsk_bounding_box_init (bounds, &GRAPHENE_POINT_INIT (self->bounds.min.x - extra, self->bounds.min.y - extra), &GRAPHENE_POINT_INIT (self->bounds.max.x + extra, self->bounds.max.y + extra)); return TRUE; } static int gsk_standard_contour_get_winding (const GskContour *contour, const graphene_point_t *point) { GskStandardContour *self = (GskStandardContour *) contour; int winding = 0; if (!gsk_bounding_box_contains_point (&self->bounds, point)) return 0; for (gsize i = 0; i < self->n_ops; i ++) { GskCurve c; if (gsk_pathop_op (self->ops[i]) == GSK_PATH_MOVE) continue; gsk_curve_init (&c, self->ops[i]); winding += gsk_curve_get_crossing (&c, point); } if ((self->flags & GSK_PATH_CLOSED) == 0) { GskCurve c; gsk_curve_init (&c, gsk_pathop_encode (GSK_PATH_CLOSE, (const graphene_point_t[]) { self->points[self->n_points - 1], self->points[0] })); winding += gsk_curve_get_crossing (&c, point); } return winding; } static gsize gsk_standard_contour_get_n_ops (const GskContour *contour) { GskStandardContour *self = (GskStandardContour *) contour; return self->n_ops; } static gboolean gsk_standard_contour_get_closest_point (const GskContour *contour, const graphene_point_t *point, float threshold, GskPathPoint *result, float *out_dist) { GskStandardContour *self = (GskStandardContour *) contour; unsigned int best_idx = G_MAXUINT; float best_t = 0; g_assert (gsk_pathop_op (self->ops[0]) == GSK_PATH_MOVE); if (self->n_ops == 1) { float dist; dist = graphene_point_distance (point, &self->points[0], NULL, NULL); if (dist <= threshold) { *out_dist = dist; result->idx = 0; result->t = 1; return TRUE; } return FALSE; } for (gsize i = 0; i < self->n_ops; i ++) { GskCurve c; float distance, t; if (gsk_pathop_op (self->ops[i]) == GSK_PATH_MOVE) continue; gsk_curve_init (&c, self->ops[i]); if (gsk_curve_get_closest_point (&c, point, threshold, &distance, &t) && distance < threshold) { best_idx = i; best_t = t; threshold = distance; } } if (best_idx != G_MAXUINT) { *out_dist = threshold; result->idx = best_idx; result->t = best_t; return TRUE; } return FALSE; } static void gsk_standard_contour_get_position (const GskContour *contour, const GskPathPoint *point, graphene_point_t *position) { GskStandardContour *self = (GskStandardContour *) contour; GskCurve curve; if (G_UNLIKELY (point->idx == 0)) { *position = self->points[0]; return; } gsk_curve_init (&curve, self->ops[point->idx]); gsk_curve_get_point (&curve, point->t, position); } static void gsk_standard_contour_get_tangent (const GskContour *contour, const GskPathPoint *point, GskPathDirection direction, graphene_vec2_t *tangent) { GskStandardContour *self = (GskStandardContour *) contour; GskCurve curve; gsize idx; float t; if (G_UNLIKELY (point->idx == 0)) { graphene_vec2_init (tangent, 0, 0); return; } idx = point->idx; t = point->t; if (t == 0 && (direction == GSK_PATH_FROM_START || direction == GSK_PATH_TO_START)) { /* Look at the previous segment */ if (idx > 1) { idx--; t = 1; } else if (self->flags & GSK_PATH_CLOSED) { idx = self->n_ops - 1; t = 1; } } else if (t == 1 && (direction == GSK_PATH_TO_END || direction == GSK_PATH_FROM_END)) { /* Look at the next segment */ if (idx < self->n_ops - 1) { idx++; t = 0; } else if (self->flags & GSK_PATH_CLOSED) { idx = 1; t = 0; } } gsk_curve_init (&curve, self->ops[idx]); gsk_curve_get_tangent (&curve, t, tangent); if (direction == GSK_PATH_TO_START || direction == GSK_PATH_FROM_END) graphene_vec2_negate (tangent, tangent); } static float gsk_standard_contour_get_curvature (const GskContour *contour, const GskPathPoint *point, GskPathDirection direction, graphene_point_t *center) { GskStandardContour *self = (GskStandardContour *) contour; GskCurve curve; gsize idx; float t; if (G_UNLIKELY (point->idx == 0)) return 0; idx = point->idx; t = point->t; if (t == 0 && idx > 1 && (direction == GSK_PATH_FROM_START || direction == GSK_PATH_TO_START)) { idx--; t = 1; } else if (t == 1 && idx + 1 < self->n_ops && (direction == GSK_PATH_FROM_END || direction == GSK_PATH_TO_END)) { idx++; t = 0; } gsk_curve_init (&curve, self->ops[idx]); return gsk_curve_get_curvature (&curve, t, center); } static void gsk_standard_contour_add_segment (const GskContour *contour, GskPathBuilder *builder, gboolean emit_move_to, const GskPathPoint *start, const GskPathPoint *end) { GskStandardContour *self = (GskStandardContour *) contour; GskCurve c, c1, c2; g_assert (start->idx < self->n_ops); g_assert (end->idx < self->n_ops); gsk_curve_init (&c, self->ops[start->idx]); if (start->idx == end->idx) { gsk_curve_segment (&c, start->t, end->t, &c1); add_curve (&c1, builder, &emit_move_to); return; } if (start->t == 0) { add_curve (&c, builder, &emit_move_to); } else if (start->t < 1) { gsk_curve_split (&c, start->t, &c1, &c2); add_curve (&c2, builder, &emit_move_to); } for (gsize i = start->idx + 1; i < end->idx; i++) { gsk_curve_init (&c, self->ops[i]); add_curve (&c, builder, &emit_move_to); } gsk_curve_init (&c, self->ops[end->idx]); if (c.op == GSK_PATH_CLOSE) c.op = GSK_PATH_LINE; if (end->t == 1) { add_curve (&c, builder, &emit_move_to); } else if (end->t > 0) { gsk_curve_split (&c, end->t, &c1, &c2); add_curve (&c1, builder, &emit_move_to); } } typedef struct { gsize idx; float length0; float length1; gsize n_samples; gsize first; } CurveMeasure; typedef struct { float t; float length; } CurvePoint; typedef struct { GArray *curves; GArray *points; float tolerance; } GskStandardContourMeasure; static void add_measure (const GskCurve *curve, gsize idx, float length, float tolerance, float t1, float l1, GArray *array) { GskCurve c; float ll, l0; float t0; CurvePoint *p; /* Check if we can add (t1, length + l1) without further * splitting. We check two things: * - Is the curve close to a straight line (length-wise) ? * - Does the roundtrip length<>t not deviate too much ? */ if (curve->op == GSK_PATH_LINE || curve->op == GSK_PATH_CLOSE) goto done; p = &g_array_index (array, CurvePoint, array->len - 1); t0 = (p->t + t1) / 2; if (t0 == p->t || t0 == t1) goto done; gsk_curve_split (curve, t0, &c, NULL); l0 = gsk_curve_get_length (&c); ll = (p->length + length + l1) / 2; if (fabsf (length + l0 - ll) < tolerance) { done: g_array_append_val (array, ((CurvePoint) { t1, length + l1 })); } else { add_measure (curve, idx, length, tolerance, t0, l0, array); add_measure (curve, idx, length, tolerance, t1, l1, array); } } static int cmpfloat (const void *p1, const void *p2) { const float *f1 = p1; const float *f2 = p2; return *f1 < *f2 ? -1 : (*f1 > *f2 ? 1 : 0); } static void add_samples (const GskStandardContour *self, GskStandardContourMeasure *measure, CurveMeasure *curve_measure) { gsize first; GskCurve curve; float l0, l1; float t[3]; int n; g_assert (curve_measure->n_samples == 0); g_assert (0 < curve_measure->idx && curve_measure->idx < self->n_ops); first = measure->points->len; l0 = curve_measure->length0; l1 = curve_measure->length1; g_array_append_val (measure->points, ((CurvePoint) { 0, l0 } )); gsk_curve_init (&curve, self->ops[curve_measure->idx]); n = gsk_curve_get_curvature_points (&curve, t); qsort (t, n, sizeof (float), cmpfloat); for (int j = 0; j < n; j++) { float l = gsk_curve_get_length_to (&curve, t[j]); add_measure (&curve, curve_measure->idx, l0, measure->tolerance, t[j], l, measure->points); } add_measure (&curve, curve_measure->idx, l0, measure->tolerance, 1, l1 - l0, measure->points); curve_measure->first = first; curve_measure->n_samples = measure->points->len - first; } static void ensure_samples (const GskStandardContour *self, GskStandardContourMeasure *measure, CurveMeasure *curve_measure) { if (curve_measure->n_samples == 0) add_samples (self, measure, curve_measure); } static gpointer gsk_standard_contour_init_measure (const GskContour *contour, float tolerance, float *out_length) { const GskStandardContour *self = (const GskStandardContour *) contour; GskStandardContourMeasure *measure; float length; measure = g_new (GskStandardContourMeasure, 1); measure->curves = g_array_new (FALSE, FALSE, sizeof (CurveMeasure)); measure->points = g_array_new (FALSE, FALSE, sizeof (CurvePoint)); measure->tolerance = tolerance; /* Add a placeholder for the move, so indexes match up */ g_array_append_val (measure->curves, ((CurveMeasure) { 0, -1, -1, 0, 0 } )); length = 0; for (gsize i = 1; i < self->n_ops; i++) { GskCurve curve; float l; gsk_curve_init (&curve, self->ops[i]); l = gsk_curve_get_length (&curve); g_array_append_val (measure->curves, ((CurveMeasure) { i, length, length + l, 0, 0 } )); length += l; } *out_length = length; return measure; } static void gsk_standard_contour_free_measure (const GskContour *contour, gpointer data) { GskStandardContourMeasure *measure = data; g_array_free (measure->curves, TRUE); g_array_free (measure->points, TRUE); g_free (measure); } static int find_curve (gconstpointer a, gconstpointer b) { const CurveMeasure *m = a; const float distance = *(const float *) b; if (distance < m->length0) return 1; else if (distance > m->length1) return -1; else return 0; } static void gsk_standard_contour_get_point (const GskContour *contour, gpointer measure_data, float distance, GskPathPoint *result) { const GskStandardContour *self = (const GskStandardContour *) contour; GskStandardContourMeasure *measure = measure_data; CurveMeasure *curve_measure; gboolean found G_GNUC_UNUSED; guint idx; gsize i0, i1; CurvePoint *p0, *p1; if (self->n_ops == 1) { result->idx = 0; result->t = 1; return; } found = g_array_binary_search (measure->curves, &distance, find_curve, &idx); g_assert (found); curve_measure = &g_array_index (measure->curves, CurveMeasure, idx); ensure_samples (self, measure, curve_measure); i0 = curve_measure->first; i1 = curve_measure->first + curve_measure->n_samples - 1; while (i0 + 1 < i1) { gsize i = (i0 + i1) / 2; CurvePoint *p = &g_array_index (measure->points, CurvePoint, i); if (p->length < distance) i0 = i; else if (p->length > distance) i1 = i; else { result->idx = curve_measure->idx; result->t = p->t; g_assert (0 <= result->t && result->t <= 1); return; } } p0 = &g_array_index (measure->points, CurvePoint, i0); p1 = &g_array_index (measure->points, CurvePoint, i1); if (distance >= p1->length) { if (curve_measure->idx == self->n_ops - 1) { result->idx = curve_measure->idx; result->t = 1; } else { result->idx = curve_measure->idx + 1; result->t = 0; } } else { float fraction; result->idx = curve_measure->idx; fraction = (distance - p0->length) / (p1->length - p0->length); g_assert (fraction >= 0 && fraction <= 1); result->t = p0->t * (1 - fraction) + p1->t * fraction; g_assert (result->t >= 0 && result->t <= 1); } } static float gsk_standard_contour_get_distance (const GskContour *contour, const GskPathPoint *point, gpointer measure_data) { const GskStandardContour *self = (const GskStandardContour *) contour; GskStandardContourMeasure *measure = measure_data; CurveMeasure *curve_measure; gsize i0, i1; CurvePoint *p0, *p1; float fraction; if (G_UNLIKELY (point->idx == 0)) return 0; curve_measure = &g_array_index (measure->curves, CurveMeasure, point->idx); ensure_samples (self, measure, curve_measure); i0 = curve_measure->first; i1 = curve_measure->first + curve_measure->n_samples - 1; while (i0 + 1 < i1) { gsize i = (i0 + i1) / 2; CurvePoint *p = &g_array_index (measure->points, CurvePoint, i); if (p->t > point->t) i1 = i; else if (p->t < point->t) i0 = i; else return p->length; } p0 = &g_array_index (measure->points, CurvePoint, i0); p1 = &g_array_index (measure->points, CurvePoint, i1); g_assert (p0->t <= point->t && point->t <= p1->t); fraction = (point->t - p0->t) / (p1->t - p0->t); g_assert (fraction >= 0 && fraction <= 1); return p0->length * (1 - fraction) + p1->length * fraction; } static const GskContourClass GSK_STANDARD_CONTOUR_CLASS = { sizeof (GskStandardContour), "GskStandardContour", gsk_standard_contour_copy, gsk_standard_contour_get_size, gsk_standard_contour_get_flags, gsk_contour_print_default, gsk_standard_contour_get_bounds, gsk_standard_contour_get_stroke_bounds, gsk_standard_contour_foreach, gsk_standard_contour_reverse, gsk_standard_contour_get_winding, gsk_standard_contour_get_n_ops, gsk_standard_contour_get_closest_point, gsk_standard_contour_get_position, gsk_standard_contour_get_tangent, gsk_standard_contour_get_curvature, gsk_standard_contour_add_segment, gsk_standard_contour_init_measure, gsk_standard_contour_free_measure, gsk_standard_contour_get_point, gsk_standard_contour_get_distance, }; /* You must ensure the contour has enough size allocated, * see gsk_standard_contour_compute_size() */ static void gsk_standard_contour_init (GskContour *contour, GskPathFlags flags, const graphene_point_t *points, gsize n_points, const gskpathop *ops, gsize n_ops, gssize offset) { GskStandardContour *self = (GskStandardContour *) contour; self->contour.klass = &GSK_STANDARD_CONTOUR_CLASS; self->flags = flags; self->n_ops = n_ops; self->n_points = n_points; self->points = (graphene_point_t *) &self->ops[n_ops]; memcpy (self->points, points, sizeof (graphene_point_t) * n_points); offset += self->points - points; for (gsize i = 0; i < n_ops; i++) self->ops[i] = gsk_pathop_encode (gsk_pathop_op (ops[i]), gsk_pathop_points (ops[i]) + offset); gsk_bounding_box_init (&self->bounds, &self->points[0], &self->points[0]); for (gsize i = 1; i < self->n_points; i ++) gsk_bounding_box_expand (&self->bounds, &self->points[i]); } GskContour * gsk_standard_contour_new (GskPathFlags flags, const graphene_point_t *points, gsize n_points, const gskpathop *ops, gsize n_ops, gssize offset) { GskContour *contour; contour = g_malloc0 (gsk_standard_contour_compute_size (n_ops, n_points)); gsk_standard_contour_init (contour, flags, points, n_points, ops, n_ops, offset); return contour; } /* }}} */ /* {{{ Circle */ typedef struct _GskCircleContour GskCircleContour; struct _GskCircleContour { GskContour contour; graphene_point_t center; float radius; gboolean ccw; }; static void gsk_circle_contour_copy (const GskContour *contour, GskContour *dest) { const GskCircleContour *self = (const GskCircleContour *) contour; GskCircleContour *target = (GskCircleContour *) dest; *target = *self; } static GskPathFlags gsk_circle_contour_get_flags (const GskContour *contour) { return GSK_PATH_CLOSED; } static void gsk_circle_contour_print (const GskContour *contour, GString *string) { const GskCircleContour *self = (const GskCircleContour *) contour; float radius, radius_neg; if (self->radius > 0) { radius = self->radius; radius_neg = - self->radius; } else { radius = 0.f; radius_neg = 0.f; } _g_string_append_point (string, "M ", &GRAPHENE_POINT_INIT (self->center.x + radius, self->center.y)); _g_string_append_point (string, " o ", &GRAPHENE_POINT_INIT (0, radius)); _g_string_append_point (string, ", ", &GRAPHENE_POINT_INIT (radius_neg, radius)); _g_string_append_float (string, ", ", M_SQRT1_2); _g_string_append_point (string, " o ", &GRAPHENE_POINT_INIT (radius_neg, 0)); _g_string_append_point (string, ", ", &GRAPHENE_POINT_INIT (radius_neg, radius_neg)); _g_string_append_float (string, ", ", M_SQRT1_2); _g_string_append_point (string, " o ", &GRAPHENE_POINT_INIT (0, radius_neg)); _g_string_append_point (string, ", ", &GRAPHENE_POINT_INIT (radius, radius_neg)); _g_string_append_float (string, ", ", M_SQRT1_2); _g_string_append_point (string, " o ", &GRAPHENE_POINT_INIT (radius, 0)); _g_string_append_point (string, ", ", &GRAPHENE_POINT_INIT (radius, radius)); _g_string_append_float (string, ", ", M_SQRT1_2); g_string_append (string, " z"); } static gboolean gsk_circle_contour_get_bounds (const GskContour *contour, GskBoundingBox *bounds) { const GskCircleContour *self = (const GskCircleContour *) contour; gsk_bounding_box_init (bounds, &GRAPHENE_POINT_INIT (self->center.x - self->radius, self->center.y - self->radius), &GRAPHENE_POINT_INIT (self->center.x + self->radius, self->center.y + self->radius)); return TRUE; } static gboolean gsk_circle_contour_get_stroke_bounds (const GskContour *contour, const GskStroke *stroke, GskBoundingBox *bounds) { const GskCircleContour *self = (const GskCircleContour *) contour; gsk_bounding_box_init (bounds, &GRAPHENE_POINT_INIT (self->center.x - self->radius - stroke->line_width, self->center.y - self->radius - stroke->line_width), &GRAPHENE_POINT_INIT (self->center.x + self->radius + stroke->line_width/2, self->center.y + self->radius + stroke->line_width)); return TRUE; } static gboolean gsk_circle_contour_foreach (const GskContour *contour, GskPathForeachFunc func, gpointer user_data) { const GskCircleContour *self = (const GskCircleContour *) contour; float rx, ry; graphene_point_t pts[10]; rx = ry = self->radius; if (self->ccw) ry = - self->radius; pts[0] = GRAPHENE_POINT_INIT (self->center.x + rx, self->center.y); pts[1] = GRAPHENE_POINT_INIT (self->center.x + rx, self->center.y + ry); pts[2] = GRAPHENE_POINT_INIT (self->center.x, self->center.y + ry); pts[3] = GRAPHENE_POINT_INIT (self->center.x - rx, self->center.y + ry); pts[4] = GRAPHENE_POINT_INIT (self->center.x - rx, self->center.y); pts[5] = GRAPHENE_POINT_INIT (self->center.x - rx, self->center.y - ry); pts[6] = GRAPHENE_POINT_INIT (self->center.x, self->center.y - ry); pts[7] = GRAPHENE_POINT_INIT (self->center.x + rx, self->center.y - ry); pts[8] = GRAPHENE_POINT_INIT (self->center.x + rx, self->center.y); pts[9] = GRAPHENE_POINT_INIT (self->center.x + rx, self->center.y); return func (GSK_PATH_MOVE, &pts[0], 1, 0.f, user_data) && maybe_emit_conic (&pts[0], M_SQRT1_2, func, user_data) && maybe_emit_conic (&pts[2], M_SQRT1_2, func, user_data) && maybe_emit_conic (&pts[4], M_SQRT1_2, func, user_data) && maybe_emit_conic (&pts[6], M_SQRT1_2, func, user_data) && func (GSK_PATH_CLOSE, &pts[8], 2, 0.f, user_data); } static GskContour * gsk_circle_contour_reverse (const GskContour *contour) { const GskCircleContour *self = (const GskCircleContour *) contour; GskCircleContour *copy; copy = g_new0 (GskCircleContour, 1); gsk_circle_contour_copy (contour, (GskContour *)copy); copy->ccw = !self->ccw; return (GskContour *)copy; } static int gsk_circle_contour_get_winding (const GskContour *contour, const graphene_point_t *point) { const GskCircleContour *self = (const GskCircleContour *) contour; if (graphene_point_distance (point, &self->center, NULL, NULL) <= self->radius) return self->ccw ? -1 : 1; return 0; } static gsize gsk_circle_contour_get_n_ops (const GskContour *contour) { const GskCircleContour *self = (const GskCircleContour *) contour; /* idx == 0 is the move (which does not really exist here, * but gskpath.c assumes there is one). */ return self->radius > 0 ? 6 : 2; } static gboolean gsk_circle_contour_get_closest_point (const GskContour *contour, const graphene_point_t *point, float threshold, GskPathPoint *result, float *out_dist) { const GskCircleContour *self = (const GskCircleContour *) contour; float dist, angle, t; gsize idx; dist = fabsf (graphene_point_distance (&self->center, point, NULL, NULL) - self->radius); if (dist > threshold) return FALSE; angle = atan2f (point->y - self->center.y, point->x - self->center.x); if (angle < 0) angle = 2 * M_PI + angle; t = CLAMP (angle / (2 * M_PI), 0, 1); if (self->ccw) t = 1 - t; t = t * 4; idx = 1; do { if (t < 1) break; t = t - 1; idx = idx + 1; } while (t != 0); result->idx = idx; result->t = t; return TRUE; } static void gsk_circle_contour_get_position (const GskContour *contour, const GskPathPoint *point, graphene_point_t *position) { const GskCircleContour *self = (const GskCircleContour *) contour; gsize idx = point->idx; float t = point->t; if (self->radius == 0) { *position = self->center; return; } /* avoid the z */ if (idx == 5) { idx = 4; t = 1; } if (self->ccw) { idx = 5 - idx; t = 1 - t; } if ((idx == 1 && t == 0) || (idx == 4 && t == 1)) { *position = GRAPHENE_POINT_INIT (self->center.x + self->radius, self->center.y); } else { float s, c; _sincosf (M_PI_2 * ((idx - 1) + t), &s, &c); *position = GRAPHENE_POINT_INIT (self->center.x + c * self->radius, self->center.y + s * self->radius); } } static void gsk_circle_contour_get_tangent (const GskContour *contour, const GskPathPoint *point, GskPathDirection direction, graphene_vec2_t *tangent) { const GskCircleContour *self = (const GskCircleContour *) contour; graphene_point_t p; gsk_circle_contour_get_position (contour, point, &p); graphene_vec2_init (tangent, - p.y + self->center.y, p.x - self->center.x); graphene_vec2_normalize (tangent, tangent); } static float gsk_circle_contour_get_curvature (const GskContour *contour, const GskPathPoint *point, GskPathDirection direction, graphene_point_t *center) { const GskCircleContour *self = (const GskCircleContour *) contour; if (center) *center = self->center; if (self->radius == 0) return INFINITY; return 1.f / self->radius; } static void gsk_circle_contour_add_segment (const GskContour *contour, GskPathBuilder *builder, gboolean emit_move_to, const GskPathPoint *start, const GskPathPoint *end) { GskPath *path; const GskContour *std; path = convert_to_standard_contour (contour); std = gsk_path_get_contour (path, 0); gsk_standard_contour_add_segment (std, builder, emit_move_to, start, end); gsk_path_unref (path); } static gpointer gsk_circle_contour_init_measure (const GskContour *contour, float tolerance, float *out_length) { const GskCircleContour *self = (const GskCircleContour *) contour; *out_length = 2 * M_PI * self->radius; return NULL; } static void gsk_circle_contour_free_measure (const GskContour *contour, gpointer data) { } static void gsk_circle_contour_get_point (const GskContour *contour, gpointer measure_data, float distance, GskPathPoint *result) { const GskCircleContour *self = (const GskCircleContour *) contour; float t; gsize idx; if (self->radius == 0) { result->idx = 1; result->t = 0; return; } t = distance / (M_PI_2 * self->radius); idx = 1; do { if (t < 1) break; t = t - 1; idx = idx + 1; } while (t > 0); if (self->ccw) { idx = 5 - idx; t = 1 - t; } result->idx = idx; result->t = t; } static float gsk_circle_contour_get_distance (const GskContour *contour, const GskPathPoint *point, gpointer measure_data) { const GskCircleContour *self = (const GskCircleContour *) contour; float t; gsize idx; if (self->radius == 0) return 0; idx = point->idx; t = point->t; if (self->ccw) { idx = 5 - idx; t = 1 - t; } return M_PI_2 * self->radius * (idx - 1 + t); } static const GskContourClass GSK_CIRCLE_CONTOUR_CLASS = { sizeof (GskCircleContour), "GskCircleContour", gsk_circle_contour_copy, gsk_contour_get_size_default, gsk_circle_contour_get_flags, gsk_circle_contour_print, gsk_circle_contour_get_bounds, gsk_circle_contour_get_stroke_bounds, gsk_circle_contour_foreach, gsk_circle_contour_reverse, gsk_circle_contour_get_winding, gsk_circle_contour_get_n_ops, gsk_circle_contour_get_closest_point, gsk_circle_contour_get_position, gsk_circle_contour_get_tangent, gsk_circle_contour_get_curvature, gsk_circle_contour_add_segment, gsk_circle_contour_init_measure, gsk_circle_contour_free_measure, gsk_circle_contour_get_point, gsk_circle_contour_get_distance, }; GskContour * gsk_circle_contour_new (const graphene_point_t *center, float radius) { GskCircleContour *self; g_assert (radius >= 0); self = g_new0 (GskCircleContour, 1); self->contour.klass = &GSK_CIRCLE_CONTOUR_CLASS; self->contour.klass = &GSK_CIRCLE_CONTOUR_CLASS; self->center = *center; self->radius = radius; self->ccw = FALSE; return (GskContour *) self; } /* }}} */ /* {{{ Rectangle */ typedef struct _GskRectContour GskRectContour; struct _GskRectContour { GskContour contour; float x; float y; float width; float height; gsize n_ops; }; static void gsk_rect_contour_copy (const GskContour *contour, GskContour *dest) { const GskRectContour *self = (const GskRectContour *) contour; GskRectContour *target = (GskRectContour *) dest; *target = *self; } static GskPathFlags gsk_rect_contour_get_flags (const GskContour *contour) { return GSK_PATH_FLAT | GSK_PATH_CLOSED; } static void gsk_rect_contour_print (const GskContour *contour, GString *string) { const GskRectContour *self = (const GskRectContour *) contour; _g_string_append_point (string, "M ", &GRAPHENE_POINT_INIT (self->x, self->y)); _g_string_append_float (string, " h ", self->width); _g_string_append_float (string, " v ", self->height); _g_string_append_float (string, " h ", - self->width); g_string_append (string, " z"); } static gboolean gsk_rect_contour_get_bounds (const GskContour *contour, GskBoundingBox *bounds) { const GskRectContour *self = (const GskRectContour *) contour; gsk_bounding_box_init (bounds, &GRAPHENE_POINT_INIT (self->x, self->y), &GRAPHENE_POINT_INIT (self->x + self->width, self->y + self->height)); return TRUE; } static gboolean gsk_rect_contour_get_stroke_bounds (const GskContour *contour, const GskStroke *stroke, GskBoundingBox *bounds) { const GskRectContour *self = (const GskRectContour *) contour; graphene_rect_t rect; graphene_rect_init (&rect, self->x, self->y, self->width, self->height); graphene_rect_inset (&rect, - stroke->line_width, - stroke->line_width); gsk_bounding_box_init_from_rect (bounds, &rect); return TRUE; } static gboolean gsk_rect_contour_foreach (const GskContour *contour, GskPathForeachFunc func, gpointer user_data) { const GskRectContour *self = (const GskRectContour *) contour; graphene_point_t pts[] = { GRAPHENE_POINT_INIT (self->x, self->y), GRAPHENE_POINT_INIT (self->x + self->width, self->y), GRAPHENE_POINT_INIT (self->x + self->width, self->y + self->height), GRAPHENE_POINT_INIT (self->x, self->y + self->height), GRAPHENE_POINT_INIT (self->x, self->y) }; return func (GSK_PATH_MOVE, &pts[0], 1, 0.f, user_data) && maybe_emit_line (&pts[0], func, user_data) && maybe_emit_line (&pts[1], func, user_data) && maybe_emit_line (&pts[2], func, user_data) && func (GSK_PATH_CLOSE, &pts[3], 2, 0.f, user_data); } static GskContour * gsk_rect_contour_reverse (const GskContour *contour) { const GskRectContour *self = (const GskRectContour *) contour; return gsk_rect_contour_new (&GRAPHENE_RECT_INIT (self->x + self->width, self->y, - self->width, self->height)); } static int gsk_rect_contour_get_winding (const GskContour *contour, const graphene_point_t *point) { const GskRectContour *self = (const GskRectContour *) contour; graphene_rect_t rect; graphene_rect_init (&rect, self->x, self->y, self->width, self->height); if (graphene_rect_contains_point (&rect, point)) { if ((self->width < 0) != (self->height < 0)) return -1; else return 1; } return 0; } static gsize gsk_rect_contour_get_n_ops (const GskContour *contour) { const GskRectContour *self = (const GskRectContour *) contour; return self->n_ops; } static gboolean gsk_rect_contour_get_closest_point (const GskContour *contour, const graphene_point_t *point, float threshold, GskPathPoint *result, float *out_dist) { return contour_get_closest_point (contour, point, threshold, result, out_dist); } static void gsk_rect_contour_get_position (const GskContour *contour, const GskPathPoint *point, graphene_point_t *position) { GskCurve curve; contour_init_curve (contour, point->idx, &curve); gsk_curve_get_point (&curve, point->t, position); } static void gsk_rect_contour_get_tangent (const GskContour *contour, const GskPathPoint *point, GskPathDirection direction, graphene_vec2_t *tangent) { const GskRectContour *self = (const GskRectContour *) contour; gsize idx = point->idx; float t = point->t; GskCurve curve; apply_corner_direction (direction, &idx, &t, self->n_ops); contour_init_curve (contour, idx, &curve); gsk_curve_get_tangent (&curve, t, tangent); if (direction == GSK_PATH_TO_START || direction == GSK_PATH_FROM_END) graphene_vec2_negate (tangent, tangent); } static float gsk_rect_contour_get_curvature (const GskContour *contour, const GskPathPoint *point, GskPathDirection direction, graphene_point_t *center) { return 0; } static void gsk_rect_contour_add_segment (const GskContour *contour, GskPathBuilder *builder, gboolean emit_move_to, const GskPathPoint *start, const GskPathPoint *end) { contour_add_segment (contour, builder, emit_move_to, start, end); } static gpointer gsk_rect_contour_init_measure (const GskContour *contour, float tolerance, float *out_length) { const GskRectContour *self = (const GskRectContour *) contour; *out_length = 2 * (fabsf (self->width) + fabsf (self->height)); return NULL; } static void gsk_rect_contour_free_measure (const GskContour *contour, gpointer data) { } static inline int rect_contour_get_sides (const GskRectContour *self, float sides[5]) { int n_sides = 0; sides[n_sides++] = 0; if (self->width != 0) sides[n_sides++] = fabsf (self->width); if (self->height != 0) sides[n_sides++] = fabsf (self->height); if (self->width != 0) sides[n_sides++] = fabsf (self->width); sides[n_sides++] = fabsf (self->height); return n_sides; } static void gsk_rect_contour_get_point (const GskContour *contour, gpointer measure_data, float distance, GskPathPoint *result) { const GskRectContour *self = (const GskRectContour *) contour; float sides[5]; int n_sides = 0; if (distance == 0) { result->idx = 1; result->t = 0; return; } n_sides = rect_contour_get_sides (self, sides); for (int i = 0; i < n_sides; i++) { if (distance <= sides[i]) { result->idx = i; result->t = distance / sides[i]; return; } distance -= sides[i]; } result->idx = n_sides - 1; result->t = 1; } static float gsk_rect_contour_get_distance (const GskContour *contour, const GskPathPoint *point, gpointer measure_data) { const GskRectContour *self = (const GskRectContour *) contour; float sides[5]; int n_sides G_GNUC_UNUSED; float distance; n_sides = rect_contour_get_sides (self, sides); g_assert (point->idx < n_sides); distance = 0; for (int i = 0; i < point->idx; i++) distance += sides[i]; distance += point->t * sides[point->idx]; return distance; } static const GskContourClass GSK_RECT_CONTOUR_CLASS = { sizeof (GskRectContour), "GskRectContour", gsk_rect_contour_copy, gsk_contour_get_size_default, gsk_rect_contour_get_flags, gsk_rect_contour_print, gsk_rect_contour_get_bounds, gsk_rect_contour_get_stroke_bounds, gsk_rect_contour_foreach, gsk_rect_contour_reverse, gsk_rect_contour_get_winding, gsk_rect_contour_get_n_ops, gsk_rect_contour_get_closest_point, gsk_rect_contour_get_position, gsk_rect_contour_get_tangent, gsk_rect_contour_get_curvature, gsk_rect_contour_add_segment, gsk_rect_contour_init_measure, gsk_rect_contour_free_measure, gsk_rect_contour_get_point, gsk_rect_contour_get_distance, }; GskContour * gsk_rect_contour_new (const graphene_rect_t *rect) { GskRectContour *self; gsize n_ops[] = { 2, 3, 5 }; self = g_new0 (GskRectContour, 1); self->contour.klass = &GSK_RECT_CONTOUR_CLASS; self->x = rect->origin.x; self->y = rect->origin.y; self->width = rect->size.width; self->height = rect->size.height; self->n_ops = n_ops[(self->width != 0) + (self->height != 0)]; return (GskContour *) self; } /* }}} */ /* {{{ Rounded Rectangle */ typedef struct _GskRoundedRectContour GskRoundedRectContour; struct _GskRoundedRectContour { GskContour contour; GskRoundedRect rect; gboolean ccw; gsize n_ops; }; static void gsk_rounded_rect_contour_copy (const GskContour *contour, GskContour *dest) { const GskRoundedRectContour *self = (const GskRoundedRectContour *) contour; GskRoundedRectContour *target = (GskRoundedRectContour *) dest; *target = *self; } static GskPathFlags gsk_rounded_rect_contour_get_flags (const GskContour *contour) { return GSK_PATH_CLOSED; } static gboolean gsk_rounded_rect_contour_get_bounds (const GskContour *contour, GskBoundingBox *bounds) { const GskRoundedRectContour *self = (const GskRoundedRectContour *) contour; gsk_bounding_box_init_from_rect (bounds, &self->rect.bounds); return TRUE; } static gboolean gsk_rounded_rect_contour_get_stroke_bounds (const GskContour *contour, const GskStroke *stroke, GskBoundingBox *bounds) { const GskRoundedRectContour *self = (const GskRoundedRectContour *) contour; GskBoundingBox b; gsk_bounding_box_init_from_rect (&b, &self->rect.bounds); gsk_bounding_box_init (bounds, &GRAPHENE_POINT_INIT (b.min.x - stroke->line_width, b.min.y - stroke->line_width), &GRAPHENE_POINT_INIT (b.max.x + stroke->line_width, b.max.y + stroke->line_width)); return TRUE; } static void get_rounded_rect_points (const GskRoundedRect *rect, graphene_point_t *pts) { pts[0] = GRAPHENE_POINT_INIT (rect->bounds.origin.x + rect->corner[GSK_CORNER_TOP_LEFT].width, rect->bounds.origin.y); pts[1] = GRAPHENE_POINT_INIT (rect->bounds.origin.x + rect->bounds.size.width - rect->corner[GSK_CORNER_TOP_RIGHT].width, rect->bounds.origin.y); pts[2] = GRAPHENE_POINT_INIT (rect->bounds.origin.x + rect->bounds.size.width, rect->bounds.origin.y); pts[3] = GRAPHENE_POINT_INIT (rect->bounds.origin.x + rect->bounds.size.width, rect->bounds.origin.y + rect->corner[GSK_CORNER_TOP_RIGHT].height); pts[4] = GRAPHENE_POINT_INIT (rect->bounds.origin.x + rect->bounds.size.width, rect->bounds.origin.y + rect->bounds.size.height - rect->corner[GSK_CORNER_BOTTOM_RIGHT].height); pts[5] = GRAPHENE_POINT_INIT (rect->bounds.origin.x + rect->bounds.size.width, rect->bounds.origin.y + rect->bounds.size.height); pts[6] = GRAPHENE_POINT_INIT (rect->bounds.origin.x + rect->bounds.size.width - rect->corner[GSK_CORNER_BOTTOM_RIGHT].width, rect->bounds.origin.y + rect->bounds.size.height); pts[7] = GRAPHENE_POINT_INIT (rect->bounds.origin.x + rect->corner[GSK_CORNER_BOTTOM_LEFT].width, rect->bounds.origin.y + rect->bounds.size.height); pts[8] = GRAPHENE_POINT_INIT (rect->bounds.origin.x, rect->bounds.origin.y + rect->bounds.size.height); pts[9] = GRAPHENE_POINT_INIT (rect->bounds.origin.x, rect->bounds.origin.y + rect->bounds.size.height - rect->corner[GSK_CORNER_BOTTOM_LEFT].height); pts[10] = GRAPHENE_POINT_INIT (rect->bounds.origin.x, rect->bounds.origin.y + rect->corner[GSK_CORNER_TOP_LEFT].height); pts[11] = GRAPHENE_POINT_INIT (rect->bounds.origin.x, rect->bounds.origin.y); pts[12] = GRAPHENE_POINT_INIT (rect->bounds.origin.x + rect->corner[GSK_CORNER_TOP_LEFT].width, rect->bounds.origin.y); pts[13] = GRAPHENE_POINT_INIT (rect->bounds.origin.x + rect->corner[GSK_CORNER_TOP_LEFT].width, rect->bounds.origin.y); } static gboolean gsk_rounded_rect_contour_foreach (const GskContour *contour, GskPathForeachFunc func, gpointer user_data) { const GskRoundedRectContour *self = (const GskRoundedRectContour *) contour; graphene_point_t pts[14]; get_rounded_rect_points (&self->rect, pts); if (self->ccw) { graphene_point_t p; #define SWAP(a,b,c) a = b; b = c; c = a; SWAP (p, pts[1], pts[11]); SWAP (p, pts[2], pts[10]); SWAP (p, pts[3], pts[9]); SWAP (p, pts[4], pts[8]); SWAP (p, pts[5], pts[7]); #undef SWAP return func (GSK_PATH_MOVE, &pts[0], 1, 0.f, user_data) && maybe_emit_conic (&pts[0], M_SQRT1_2, func, user_data) && maybe_emit_line (&pts[2], func, user_data) && maybe_emit_conic (&pts[3], M_SQRT1_2, func, user_data) && maybe_emit_line (&pts[5], func, user_data) && maybe_emit_conic (&pts[6], M_SQRT1_2, func, user_data) && maybe_emit_line (&pts[8], func, user_data) && maybe_emit_conic (&pts[9], M_SQRT1_2, func, user_data) && maybe_emit_line (&pts[11], func, user_data) && func (GSK_PATH_CLOSE, &pts[12], 2, 0.f, user_data); } else { return func (GSK_PATH_MOVE, &pts[0], 1, 0.f, user_data) && maybe_emit_line (&pts[0], func, user_data) && maybe_emit_conic (&pts[1], M_SQRT1_2, func, user_data) && maybe_emit_line (&pts[3], func, user_data) && maybe_emit_conic (&pts[4], M_SQRT1_2, func, user_data) && maybe_emit_line (&pts[6], func, user_data) && maybe_emit_conic (&pts[7], M_SQRT1_2, func, user_data) && maybe_emit_line (&pts[9], func, user_data) && maybe_emit_conic (&pts[10], M_SQRT1_2, func, user_data) && func (GSK_PATH_CLOSE, &pts[12], 2, 0.f, user_data); } } static GskContour * gsk_rounded_rect_contour_reverse (const GskContour *contour) { const GskRoundedRectContour *self = (const GskRoundedRectContour *) contour; GskRoundedRectContour *copy; copy = g_new0 (GskRoundedRectContour, 1); gsk_rounded_rect_contour_copy (contour, (GskContour *)copy); copy->ccw = !self->ccw; return (GskContour *)copy; } static int gsk_rounded_rect_contour_get_winding (const GskContour *contour, const graphene_point_t *point) { const GskRoundedRectContour *self = (const GskRoundedRectContour *) contour; if (gsk_rounded_rect_contains_point (&self->rect, point)) return self->ccw ? -1 : 1; return 0; } static gsize gsk_rounded_rect_contour_get_n_ops (const GskContour *contour) { const GskRoundedRectContour *self = (const GskRoundedRectContour *) contour; return self->n_ops; } static gboolean gsk_rounded_rect_contour_get_closest_point (const GskContour *contour, const graphene_point_t *point, float threshold, GskPathPoint *result, float *out_dist) { return contour_get_closest_point (contour, point, threshold, result, out_dist); } static void gsk_rounded_rect_contour_get_position (const GskContour *contour, const GskPathPoint *point, graphene_point_t *position) { GskCurve curve; contour_init_curve (contour, point->idx, &curve); gsk_curve_get_point (&curve, point->t, position); } static void gsk_rounded_rect_contour_get_tangent (const GskContour *contour, const GskPathPoint *point, GskPathDirection direction, graphene_vec2_t *tangent) { const GskRoundedRectContour *self = (const GskRoundedRectContour *) contour; gsize idx = point->idx; float t = point->t; GskCurve curve; /* Avoid the z, since it has length 0 and won't give us a tangent */ if (idx == self->n_ops - 1) { idx = self->n_ops - 2; t = 1; } apply_corner_direction (direction, &idx, &t, self->n_ops - 1); contour_init_curve (contour, idx, &curve); gsk_curve_get_tangent (&curve, t, tangent); if (direction == GSK_PATH_TO_START || direction == GSK_PATH_FROM_END) graphene_vec2_negate (tangent, tangent); } static float gsk_rounded_rect_contour_get_curvature (const GskContour *contour, const GskPathPoint *point, GskPathDirection direction, graphene_point_t *center) { const GskRoundedRectContour *self = (const GskRoundedRectContour *) contour; GskCurve curve; gsize idx = point->idx; float t = point->t; /* Avoid the z, since it has length 0 and won't give us curvature */ if (idx == self->n_ops - 1) { idx = self->n_ops - 2; t = 1; } apply_corner_direction (direction, &idx, &t, self->n_ops - 1); contour_init_curve (contour, idx, &curve); return gsk_curve_get_curvature (&curve, t, center); } static void gsk_rounded_rect_contour_add_segment (const GskContour *contour, GskPathBuilder *builder, gboolean emit_move_to, const GskPathPoint *start, const GskPathPoint *end) { contour_add_segment (contour, builder, emit_move_to, start, end); } typedef struct { const GskContour *contour; gpointer measure_data; } RoundedRectMeasureData; static gpointer gsk_rounded_rect_contour_init_measure (const GskContour *contour, float tolerance, float *out_length) { RoundedRectMeasureData *data; GskPath *path; path = convert_to_standard_contour (contour); data = g_new (RoundedRectMeasureData, 1); data->contour = gsk_contour_dup (gsk_path_get_contour (path, 0)); data->measure_data = gsk_standard_contour_init_measure (data->contour, tolerance, out_length); gsk_path_unref (path); return data; } static void gsk_rounded_rect_contour_free_measure (const GskContour *contour, gpointer measure_data) { RoundedRectMeasureData *data = measure_data; gsk_standard_contour_free_measure (data->contour, data->measure_data); g_free (data); } static void gsk_rounded_rect_contour_get_point (const GskContour *contour, gpointer measure_data, float distance, GskPathPoint *result) { RoundedRectMeasureData *data = measure_data; gsk_standard_contour_get_point (data->contour, data->measure_data, distance, result); } static float gsk_rounded_rect_contour_get_distance (const GskContour *contour, const GskPathPoint *point, gpointer measure_data) { RoundedRectMeasureData *data = measure_data; return gsk_standard_contour_get_distance (data->contour, point, data->measure_data); } static const GskContourClass GSK_ROUNDED_RECT_CONTOUR_CLASS = { sizeof (GskRoundedRectContour), "GskRoundedRectContour", gsk_rounded_rect_contour_copy, gsk_contour_get_size_default, gsk_rounded_rect_contour_get_flags, gsk_contour_print_default, gsk_rounded_rect_contour_get_bounds, gsk_rounded_rect_contour_get_stroke_bounds, gsk_rounded_rect_contour_foreach, gsk_rounded_rect_contour_reverse, gsk_rounded_rect_contour_get_winding, gsk_rounded_rect_contour_get_n_ops, gsk_rounded_rect_contour_get_closest_point, gsk_rounded_rect_contour_get_position, gsk_rounded_rect_contour_get_tangent, gsk_rounded_rect_contour_get_curvature, gsk_rounded_rect_contour_add_segment, gsk_rounded_rect_contour_init_measure, gsk_rounded_rect_contour_free_measure, gsk_rounded_rect_contour_get_point, gsk_rounded_rect_contour_get_distance, }; static gsize rounded_rect_compute_n_ops (const GskRoundedRect *rect) { graphene_point_t pts[14]; gsize n_ops; get_rounded_rect_points (rect, pts); n_ops = 2; if (!graphene_point_equal (&pts[0], &pts[1])) n_ops++; if (!graphene_point_equal (&pts[1], &pts[2]) || !graphene_point_equal (&pts[2], &pts[3])) n_ops++; if (!graphene_point_equal (&pts[3], &pts[4])) n_ops++; if (!graphene_point_equal (&pts[4], &pts[5]) || !graphene_point_equal (&pts[5], &pts[6])) n_ops++; if (!graphene_point_equal (&pts[6], &pts[7])) n_ops++; if (!graphene_point_equal (&pts[7], &pts[8]) || !graphene_point_equal (&pts[8], &pts[9])) n_ops++; if (!graphene_point_equal (&pts[9], &pts[10])) n_ops++; if (!graphene_point_equal (&pts[10], &pts[11]) || !graphene_point_equal (&pts[11], &pts[12])) n_ops++; return n_ops; } GskContour * gsk_rounded_rect_contour_new (const GskRoundedRect *rect) { GskRoundedRectContour *self; self = g_new0 (GskRoundedRectContour, 1); self->contour.klass = &GSK_ROUNDED_RECT_CONTOUR_CLASS; self->rect = *rect; gsk_rounded_rect_normalize (&self->rect); self->n_ops = rounded_rect_compute_n_ops (&self->rect); return (GskContour *) self; } /* }}} */ /* {{{ API */ const char * gsk_contour_get_type_name (const GskContour *self) { return self->klass->type_name; } gsize gsk_contour_get_size (const GskContour *self) { return self->klass->get_size (self); } void gsk_contour_copy (GskContour *dest, const GskContour *src) { src->klass->copy (src, dest); } GskContour * gsk_contour_dup (const GskContour *src) { GskContour *copy; copy = g_malloc0 (gsk_contour_get_size (src)); gsk_contour_copy (copy, src); return copy; } GskContour * gsk_contour_reverse (const GskContour *src) { return src->klass->reverse (src); } GskPathFlags gsk_contour_get_flags (const GskContour *self) { return self->klass->get_flags (self); } void gsk_contour_print (const GskContour *self, GString *string) { self->klass->print (self, string); } gboolean gsk_contour_get_bounds (const GskContour *self, GskBoundingBox *bounds) { return self->klass->get_bounds (self, bounds); } gboolean gsk_contour_get_stroke_bounds (const GskContour *self, const GskStroke *stroke, GskBoundingBox *bounds) { return self->klass->get_stroke_bounds (self, stroke, bounds); } gboolean gsk_contour_foreach (const GskContour *self, GskPathForeachFunc func, gpointer user_data) { return self->klass->foreach (self, func, user_data); } int gsk_contour_get_winding (const GskContour *self, const graphene_point_t *point) { return self->klass->get_winding (self, point); } gboolean gsk_contour_get_closest_point (const GskContour *self, const graphene_point_t *point, float threshold, GskPathPoint *result, float *out_dist) { return self->klass->get_closest_point (self, point, threshold, result, out_dist); } /* Not related to how many curves foreach produces. * * GskPath assumes that the start- and endpoints * of a contour are { x, 1, 0 } and { x, n_ops - 1, 1 }. * * While the standard and rounded rect contours use * one point per op, the circle contour uses a single * 'segment' in path points, with a t that ranges * from 0 to 1 to cover the angles from 0 to 360 (or * 360 to 0 in the ccw case). */ gsize gsk_contour_get_n_ops (const GskContour *self) { return self->klass->get_n_ops (self); } void gsk_contour_get_position (const GskContour *self, const GskPathPoint *point, graphene_point_t *pos) { self->klass->get_position (self, point, pos); } void gsk_contour_get_tangent (const GskContour *self, const GskPathPoint *point, GskPathDirection direction, graphene_vec2_t *tangent) { self->klass->get_tangent (self, point, direction, tangent); } float gsk_contour_get_curvature (const GskContour *self, const GskPathPoint *point, GskPathDirection direction, graphene_point_t *center) { return self->klass->get_curvature (self, point, direction, center); } void gsk_contour_add_segment (const GskContour *self, GskPathBuilder *builder, gboolean emit_move_to, const GskPathPoint *start, const GskPathPoint *end) { self->klass->add_segment (self, builder, emit_move_to, start, end); } gpointer gsk_contour_init_measure (const GskContour *self, float tolerance, float *out_length) { return self->klass->init_measure (self, tolerance, out_length); } void gsk_contour_free_measure (const GskContour *self, gpointer data) { self->klass->free_measure (self, data); } void gsk_contour_get_point (const GskContour *self, gpointer measure_data, float distance, GskPathPoint *result) { self->klass->get_point (self, measure_data, distance, result); } float gsk_contour_get_distance (const GskContour *self, const GskPathPoint *point, gpointer measure_data) { return self->klass->get_distance (self, point, measure_data); } /* }}} */ /* vim:set foldmethod=marker expandtab: */