/*
* 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 "gskpathprivate.h"
#include "gskcurveprivate.h"
#include "gskpathbuilder.h"
#include "gskpathpoint.h"
#include "gskcontourprivate.h"
/**
* GskPath:
*
* A `GskPath` describes lines and curves that are more complex
* than simple rectangles.
*
* Paths can used for rendering (filling or stroking) and for animations
* (e.g. as trajectories).
*
* `GskPath` is an immutable, opaque, reference-counted struct.
* After creation, you cannot change the types it represents. Instead,
* new `GskPath` objects have to be created. The [struct@Gsk.PathBuilder]
* structure is meant to help in this endeavor.
*
* Conceptually, a path consists of zero or more contours (continuous, connected
* curves), each of which may or may not be closed. Contours are typically
* constructed from Bézier segments.
*
*
*
* Since: 4.14
*/
struct _GskPath
{
/*< private >*/
guint ref_count;
GskPathFlags flags;
gsize n_contours;
GskContour *contours[];
/* followed by the contours data */
};
G_DEFINE_BOXED_TYPE (GskPath, gsk_path, gsk_path_ref, gsk_path_unref)
/* {{{ Private API */
GskPath *
gsk_path_new_from_contours (const GSList *contours)
{
GskPath *path;
const GSList *l;
gsize size;
gsize n_contours;
guint8 *contour_data;
GskPathFlags flags;
flags = GSK_PATH_CLOSED | GSK_PATH_FLAT;
size = 0;
n_contours = 0;
for (l = contours; l; l = l->next)
{
GskContour *contour = l->data;
n_contours++;
size += sizeof (GskContour *);
size += gsk_contour_get_size (contour);
flags &= gsk_contour_get_flags (contour);
}
path = g_malloc0 (sizeof (GskPath) + size);
path->ref_count = 1;
path->flags = flags;
path->n_contours = n_contours;
contour_data = (guint8 *) &path->contours[n_contours];
n_contours = 0;
for (l = contours; l; l = l->next)
{
GskContour *contour = l->data;
path->contours[n_contours] = (GskContour *) contour_data;
gsk_contour_copy ((GskContour *) contour_data, contour);
size = gsk_contour_get_size (contour);
contour_data += size;
n_contours++;
}
return path;
}
const GskContour *
gsk_path_get_contour (const GskPath *self,
gsize i)
{
if (i < self->n_contours)
return self->contours[i];
else
return NULL;
}
GskPathFlags
gsk_path_get_flags (const GskPath *self)
{
return self->flags;
}
gsize
gsk_path_get_n_contours (const GskPath *self)
{
return self->n_contours;
}
/* }}} */
/* {{{ Public API */
/**
* gsk_path_ref:
* @self: a `GskPath`
*
* Increases the reference count of a `GskPath` by one.
*
* Returns: the passed in `GskPath`.
*
* Since: 4.14
*/
GskPath *
gsk_path_ref (GskPath *self)
{
g_return_val_if_fail (self != NULL, NULL);
self->ref_count++;
return self;
}
/**
* gsk_path_unref:
* @self: a `GskPath`
*
* Decreases the reference count of a `GskPath` by one.
*
* If the resulting reference count is zero, frees the path.
*
* Since: 4.14
*/
void
gsk_path_unref (GskPath *self)
{
g_return_if_fail (self != NULL);
g_return_if_fail (self->ref_count > 0);
self->ref_count--;
if (self->ref_count > 0)
return;
g_free (self);
}
/**
* gsk_path_print:
* @self: a `GskPath`
* @string: The string to print into
*
* Converts @self into a human-readable string representation suitable
* for printing.
*
* The string is compatible with (a superset of)
* [SVG path syntax](https://www.w3.org/TR/SVG11/paths.html#PathData),
* see [func@Gsk.Path.parse] for a summary of the syntax.
*
* Since: 4.14
*/
void
gsk_path_print (GskPath *self,
GString *string)
{
gsize i;
g_return_if_fail (self != NULL);
g_return_if_fail (string != NULL);
for (i = 0; i < self->n_contours; i++)
{
if (i > 0)
g_string_append_c (string, ' ');
gsk_contour_print (self->contours[i], string);
}
}
/**
* gsk_path_to_string:
* @self: a `GskPath`
*
* Converts the path into a string that is suitable for printing.
*
* You can use this function in a debugger to get a quick overview
* of the path.
*
* This is a wrapper around [method@Gsk.Path.print], see that function
* for details.
*
* Returns: A new string for @self
*
* Since: 4.14
*/
char *
gsk_path_to_string (GskPath *self)
{
GString *string;
g_return_val_if_fail (self != NULL, NULL);
string = g_string_new ("");
gsk_path_print (self, string);
return g_string_free (string, FALSE);
}
static gboolean
gsk_path_to_cairo_add_op (GskPathOperation op,
const graphene_point_t *pts,
gsize n_pts,
float weight,
gpointer cr)
{
switch (op)
{
case GSK_PATH_MOVE:
cairo_move_to (cr, pts[0].x, pts[0].y);
break;
case GSK_PATH_CLOSE:
cairo_close_path (cr);
break;
case GSK_PATH_LINE:
cairo_line_to (cr, pts[1].x, pts[1].y);
break;
case GSK_PATH_CUBIC:
cairo_curve_to (cr, pts[1].x, pts[1].y, pts[2].x, pts[2].y, pts[3].x, pts[3].y);
break;
case GSK_PATH_QUAD:
case GSK_PATH_CONIC:
default:
g_assert_not_reached ();
return FALSE;
}
return TRUE;
}
/**
* gsk_path_to_cairo:
* @self: a `GskPath`
* @cr: a cairo context
*
* Appends the given @path to the given cairo context for drawing
* with Cairo.
*
* This may cause some suboptimal conversions to be performed as
* Cairo does not support all features of `GskPath`.
*
* This function does not clear the existing Cairo path. Call
* cairo_new_path() if you want this.
*
* Since: 4.14
*/
void
gsk_path_to_cairo (GskPath *self,
cairo_t *cr)
{
g_return_if_fail (self != NULL);
g_return_if_fail (cr != NULL);
gsk_path_foreach_with_tolerance (self,
GSK_PATH_FOREACH_ALLOW_CUBIC,
cairo_get_tolerance (cr),
gsk_path_to_cairo_add_op,
cr);
}
/**
* gsk_path_is_empty:
* @self: a `GskPath`
*
* Checks if the path is empty, i.e. contains no lines or curves.
*
* Returns: `TRUE` if the path is empty
*
* Since: 4.14
*/
gboolean
gsk_path_is_empty (GskPath *self)
{
g_return_val_if_fail (self != NULL, FALSE);
return self->n_contours == 0;
}
/**
* gsk_path_is_closed:
* @self: a `GskPath`
*
* Returns if the path represents a single closed
* contour.
*
* Returns: `TRUE` if the path is closed
*
* Since: 4.14
*/
gboolean
gsk_path_is_closed (GskPath *self)
{
g_return_val_if_fail (self != NULL, FALSE);
/* XXX: is the empty path closed? Currently it's not */
if (self->n_contours != 1)
return FALSE;
return gsk_contour_get_flags (self->contours[0]) & GSK_PATH_CLOSED ? TRUE : FALSE;
}
/**
* gsk_path_get_bounds:
* @self: a `GskPath`
* @bounds: (out caller-allocates): the bounds of the given path
*
* Computes the bounds of the given path.
*
* The returned bounds may be larger than necessary, because this
* function aims to be fast, not accurate. The bounds are guaranteed
* to contain the path.
*
* It is possible that the returned rectangle has 0 width and/or height.
* This can happen when the path only describes a point or an
* axis-aligned line.
*
* If the path is empty, `FALSE` is returned and @bounds are set to
* graphene_rect_zero(). This is different from the case where the path
* is a single point at the origin, where the @bounds will also be set to
* the zero rectangle but `TRUE` will be returned.
*
* Returns: `TRUE` if the path has bounds, `FALSE` if the path is known
* to be empty and have no bounds.
*
* Since: 4.14
*/
gboolean
gsk_path_get_bounds (GskPath *self,
graphene_rect_t *bounds)
{
GskBoundingBox b;
g_return_val_if_fail (self != NULL, FALSE);
g_return_val_if_fail (bounds != NULL, FALSE);
if (self->n_contours == 0)
{
graphene_rect_init_from_rect (bounds, graphene_rect_zero ());
return FALSE;
}
gsk_contour_get_bounds (self->contours[0], &b);
for (gsize i = 1; i < self->n_contours; i++)
{
GskBoundingBox tmp;
gsk_contour_get_bounds (self->contours[i], &tmp);
gsk_bounding_box_union (&b, &tmp, &b);
}
gsk_bounding_box_to_rect (&b, bounds);
return TRUE;
}
/**
* gsk_path_get_stroke_bounds:
* @self: a #GtkPath
* @stroke: stroke parameters
* @bounds: (out caller-allocates): the bounds to fill in
*
* Computes the bounds for stroking the given path with the
* parameters in @stroke.
*
* The returned bounds may be larger than necessary, because this
* function aims to be fast, not accurate. The bounds are guaranteed
* to contain the area affected by the stroke, including protrusions
* like miters.
*
* Returns: `TRUE` if the path has bounds, `FALSE` if the path is known
* to be empty and have no bounds.
*
* Since: 4.14
*/
gboolean
gsk_path_get_stroke_bounds (GskPath *self,
const GskStroke *stroke,
graphene_rect_t *bounds)
{
GskBoundingBox b;
g_return_val_if_fail (self != NULL, FALSE);
g_return_val_if_fail (bounds != NULL, FALSE);
if (self->n_contours == 0)
{
graphene_rect_init_from_rect (bounds, graphene_rect_zero ());
return FALSE;
}
gsk_contour_get_stroke_bounds (self->contours[0], stroke, &b);
for (gsize i = 1; i < self->n_contours; i++)
{
GskBoundingBox tmp;
if (gsk_contour_get_stroke_bounds (self->contours[i], stroke, &tmp))
gsk_bounding_box_union (&b, &tmp, &b);
}
gsk_bounding_box_to_rect (&b, bounds);
return TRUE;
}
/**
* gsk_path_in_fill:
* @self: a `GskPath`
* @point: the point to test
* @fill_rule: the fill rule to follow
*
* Returns whether the given point is inside the area
* that would be affected if the path was filled according
* to @fill_rule.
*
* Note that this function assumes that filling a contour
* implicitly closes it.
*
* Returns: `TRUE` if @point is inside
*
* Since: 4.14
*/
gboolean
gsk_path_in_fill (GskPath *self,
const graphene_point_t *point,
GskFillRule fill_rule)
{
int winding = 0;
for (int i = 0; i < self->n_contours; i++)
winding += gsk_contour_get_winding (self->contours[i], point);
switch (fill_rule)
{
case GSK_FILL_RULE_EVEN_ODD:
return winding & 1;
case GSK_FILL_RULE_WINDING:
return winding != 0;
default:
g_assert_not_reached ();
}
}
/**
* gsk_path_get_start_point:
* @self: a `GskPath`
* @result: (out caller-allocates): return location for point
*
* Gets the start point of the path.
*
* An empty path has no points, so `FALSE`
* is returned in this case.
*
* Returns: `TRUE` if @result was filled
*
* Since: 4.14
*/
gboolean
gsk_path_get_start_point (GskPath *self,
GskPathPoint *result)
{
g_return_val_if_fail (self != NULL, FALSE);
g_return_val_if_fail (result != NULL, FALSE);
if (self->n_contours == 0)
return FALSE;
/* Conceptually, there is always a move at the
* beginning, which jumps from where to the start
* point of the contour, so we use idx == 1 here.
*/
result->contour = 0;
result->idx = 1;
result->t = 0;
return TRUE;
}
/**
* gsk_path_get_end_point:
* @self: a `GskPath`
* @result: (out caller-allocates): return location for point
*
* Gets the end point of the path.
*
* An empty path has no points, so `FALSE`
* is returned in this case.
*
* Returns: `TRUE` if @result was filled
*
* Since: 4.14
*/
gboolean
gsk_path_get_end_point (GskPath *self,
GskPathPoint *result)
{
g_return_val_if_fail (self != NULL, FALSE);
g_return_val_if_fail (result != NULL, FALSE);
if (self->n_contours == 0)
return FALSE;
result->contour = self->n_contours - 1;
result->idx = gsk_contour_get_n_ops (self->contours[self->n_contours - 1]) - 1;
result->t = 1;
return TRUE;
}
/**
* gsk_path_get_closest_point:
* @self: a `GskPath`
* @point: the point
* @threshold: maximum allowed distance
* @result: (out caller-allocates): return location for the closest point
* @distance: (out) (optional): return location for the distance
*
* Computes the closest point on the path to the given point
* and sets the @result to it.
*
* If there is no point closer than the given threshold,
* `FALSE` is returned.
*
* Returns: `TRUE` if @point was set to the closest point
* on @self, `FALSE` if no point is closer than @threshold
*
* Since: 4.14
*/
gboolean
gsk_path_get_closest_point (GskPath *self,
const graphene_point_t *point,
float threshold,
GskPathPoint *result,
float *distance)
{
gboolean found;
g_return_val_if_fail (self != NULL, FALSE);
g_return_val_if_fail (point != NULL, FALSE);
g_return_val_if_fail (threshold >= 0, FALSE);
g_return_val_if_fail (result != NULL, FALSE);
found = FALSE;
for (int i = 0; i < self->n_contours; i++)
{
float dist;
if (gsk_contour_get_closest_point (self->contours[i], point, threshold, result, &dist))
{
found = TRUE;
g_assert (0 <= result->t && result->t <= 1);
result->contour = i;
threshold = dist;
if (distance)
*distance = dist;
}
}
return found;
}
/* }}} */
/* {{{ Foreach and decomposition */
/**
* gsk_path_foreach:
* @self: a `GskPath`
* @flags: flags to pass to the foreach function. See [flags@Gsk.PathForeachFlags]
* for details about flags
* @func: (scope call) (closure user_data): the function to call for operations
* @user_data: (nullable): user data passed to @func
*
* Calls @func for every operation of the path.
*
* Note that this may only approximate @self, because paths can contain
* optimizations for various specialized contours, and depending on the
* @flags, the path may be decomposed into simpler curves than the ones
* that it contained originally.
*
* This function serves two purposes:
*
* - When the @flags allow everything, it provides access to the raw,
* unmodified data of the path.
* - When the @flags disallow certain operations, it provides
* an approximation of the path using just the allowed operations.
*
* Returns: `FALSE` if @func returned FALSE`, `TRUE` otherwise.
*
* Since: 4.14
*/
gboolean
gsk_path_foreach (GskPath *self,
GskPathForeachFlags flags,
GskPathForeachFunc func,
gpointer user_data)
{
g_return_val_if_fail (self != NULL, FALSE);
g_return_val_if_fail (func, FALSE);
return gsk_path_foreach_with_tolerance (self,
flags,
GSK_PATH_TOLERANCE_DEFAULT,
func,
user_data);
}
typedef struct _GskPathForeachTrampoline GskPathForeachTrampoline;
struct _GskPathForeachTrampoline
{
GskPathForeachFlags flags;
double tolerance;
GskPathForeachFunc func;
gpointer user_data;
};
static gboolean
gsk_path_foreach_trampoline_add_line (const graphene_point_t *from,
const graphene_point_t *to,
float from_progress,
float to_progress,
GskCurveLineReason reason,
gpointer data)
{
GskPathForeachTrampoline *trampoline = data;
return trampoline->func (GSK_PATH_LINE,
(graphene_point_t[2]) { *from, *to },
2,
0.f,
trampoline->user_data);
}
static gboolean
gsk_path_foreach_trampoline_add_curve (GskPathOperation op,
const graphene_point_t *pts,
gsize n_pts,
float weight,
gpointer data)
{
GskPathForeachTrampoline *trampoline = data;
return trampoline->func (op, pts, n_pts, weight, trampoline->user_data);
}
static gboolean
gsk_path_foreach_trampoline (GskPathOperation op,
const graphene_point_t *pts,
gsize n_pts,
float weight,
gpointer data)
{
GskPathForeachTrampoline *trampoline = data;
switch (op)
{
case GSK_PATH_MOVE:
case GSK_PATH_CLOSE:
case GSK_PATH_LINE:
return trampoline->func (op, pts, n_pts, weight, trampoline->user_data);
case GSK_PATH_QUAD:
{
GskCurve curve;
if (trampoline->flags & GSK_PATH_FOREACH_ALLOW_QUAD)
return trampoline->func (op, pts, n_pts, weight, trampoline->user_data);
else if (trampoline->flags & GSK_PATH_FOREACH_ALLOW_CUBIC)
{
return trampoline->func (GSK_PATH_CUBIC,
(graphene_point_t[4]) {
pts[0],
GRAPHENE_POINT_INIT ((pts[0].x + 2 * pts[1].x) / 3,
(pts[0].y + 2 * pts[1].y) / 3),
GRAPHENE_POINT_INIT ((pts[2].x + 2 * pts[1].x) / 3,
(pts[2].y + 2 * pts[1].y) / 3),
pts[2],
},
4,
weight,
trampoline->user_data);
}
gsk_curve_init (&curve, gsk_pathop_encode (GSK_PATH_QUAD, pts));
return gsk_curve_decompose (&curve,
trampoline->tolerance,
gsk_path_foreach_trampoline_add_line,
trampoline);
}
case GSK_PATH_CUBIC:
{
GskCurve curve;
if (trampoline->flags & GSK_PATH_FOREACH_ALLOW_CUBIC)
return trampoline->func (op, pts, n_pts, weight, trampoline->user_data);
gsk_curve_init (&curve, gsk_pathop_encode (GSK_PATH_CUBIC, pts));
if (trampoline->flags & (GSK_PATH_FOREACH_ALLOW_QUAD|GSK_PATH_FOREACH_ALLOW_CONIC))
return gsk_curve_decompose_curve (&curve,
trampoline->flags,
trampoline->tolerance,
gsk_path_foreach_trampoline_add_curve,
trampoline);
return gsk_curve_decompose (&curve,
trampoline->tolerance,
gsk_path_foreach_trampoline_add_line,
trampoline);
}
case GSK_PATH_CONIC:
{
GskCurve curve;
if (trampoline->flags & GSK_PATH_FOREACH_ALLOW_CONIC)
return trampoline->func (op, pts, n_pts, weight, trampoline->user_data);
gsk_curve_init (&curve, gsk_pathop_encode (GSK_PATH_CONIC, (graphene_point_t[4]) { pts[0], pts[1], { weight, 0.f }, pts[2] } ));
if (trampoline->flags & (GSK_PATH_FOREACH_ALLOW_QUAD|GSK_PATH_FOREACH_ALLOW_CUBIC))
return gsk_curve_decompose_curve (&curve,
trampoline->flags,
trampoline->tolerance,
gsk_path_foreach_trampoline_add_curve,
trampoline);
return gsk_curve_decompose (&curve,
trampoline->tolerance,
gsk_path_foreach_trampoline_add_line,
trampoline);
}
default:
g_assert_not_reached ();
return FALSE;
}
}
#define ALLOW_ANY (GSK_PATH_FOREACH_ALLOW_QUAD | \
GSK_PATH_FOREACH_ALLOW_CUBIC | \
GSK_PATH_FOREACH_ALLOW_CONIC)
gboolean
gsk_path_foreach_with_tolerance (GskPath *self,
GskPathForeachFlags flags,
double tolerance,
GskPathForeachFunc func,
gpointer user_data)
{
GskPathForeachTrampoline trampoline;
gsize i;
/* If we need to massage the data, set up a trampoline here */
if ((flags & ALLOW_ANY) != ALLOW_ANY)
{
trampoline = (GskPathForeachTrampoline) { flags, tolerance, func, user_data };
func = gsk_path_foreach_trampoline;
user_data = &trampoline;
}
for (i = 0; i < self->n_contours; i++)
{
if (!gsk_contour_foreach (self->contours[i], func, user_data))
return FALSE;
}
return TRUE;
}
/* }}} */
/* vim:set foldmethod=marker expandtab: */