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rsvg-marker.c
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rsvg-marker.c
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/* -*- Mode: C; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */
/* vim: set sw=4 sts=4 ts=4 expandtab: */
/*
rsvg-marker.c: Marker loading and rendering
Copyright (C) 2004, 2005 Caleb Moore <c.moore@student.unsw.edu.au>
This program is free software; you can redistribute it and/or
modify it under the terms of the GNU Library General Public License as
published by the Free Software Foundation; either version 2 of the
License, or (at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Library General Public License for more details.
You should have received a copy of the GNU Library General Public
License along with this program; if not, write to the
Free Software Foundation, Inc., 59 Temple Place - Suite 330,
Boston, MA 02111-1307, USA.
Authors: Caleb Moore <c.moore@student.unsw.edu.au>
*/
#include "config.h"
#include "rsvg-marker.h"
#include "rsvg-private.h"
#include "rsvg-styles.h"
#include "rsvg-shapes.h"
#include "rsvg-css.h"
#include "rsvg-defs.h"
#include "rsvg-filter.h"
#include "rsvg-mask.h"
#include "rsvg-image.h"
#include "rsvg-path.h"
#include <string.h>
#include <math.h>
#include <errno.h>
static void
rsvg_node_marker_set_atts (RsvgNode * self, RsvgHandle * ctx, RsvgPropertyBag * atts)
{
const char *klazz = NULL, *id = NULL, *value;
RsvgMarker *marker;
marker = (RsvgMarker *) self;
if (rsvg_property_bag_size (atts)) {
if ((value = rsvg_property_bag_lookup (atts, "id"))) {
id = value;
rsvg_defs_register_name (ctx->priv->defs, id, &marker->super);
}
if ((value = rsvg_property_bag_lookup (atts, "class")))
klazz = value;
if ((value = rsvg_property_bag_lookup (atts, "viewBox")))
marker->vbox = rsvg_css_parse_vbox (value);
if ((value = rsvg_property_bag_lookup (atts, "refX")))
marker->refX = _rsvg_css_parse_length (value);
if ((value = rsvg_property_bag_lookup (atts, "refY")))
marker->refY = _rsvg_css_parse_length (value);
if ((value = rsvg_property_bag_lookup (atts, "markerWidth")))
marker->width = _rsvg_css_parse_length (value);
if ((value = rsvg_property_bag_lookup (atts, "markerHeight")))
marker->height = _rsvg_css_parse_length (value);
if ((value = rsvg_property_bag_lookup (atts, "orient"))) {
if (!strcmp (value, "auto"))
marker->orientAuto = TRUE;
else
marker->orient = rsvg_css_parse_angle (value);
}
if ((value = rsvg_property_bag_lookup (atts, "markerUnits"))) {
if (!strcmp (value, "userSpaceOnUse"))
marker->bbox = FALSE;
if (!strcmp (value, "strokeWidth"))
marker->bbox = TRUE;
}
if ((value = rsvg_property_bag_lookup (atts, "preserveAspectRatio")))
marker->preserve_aspect_ratio = rsvg_css_parse_aspect_ratio (value);
rsvg_parse_style_attrs (ctx, self->state, "marker", klazz, id, atts);
}
}
RsvgNode *
rsvg_new_marker (void)
{
RsvgMarker *marker;
marker = g_new (RsvgMarker, 1);
_rsvg_node_init (&marker->super, RSVG_NODE_TYPE_MARKER);
marker->orient = 0;
marker->orientAuto = FALSE;
marker->preserve_aspect_ratio = RSVG_ASPECT_RATIO_XMID_YMID;
marker->refX = marker->refY = _rsvg_css_parse_length ("0");
marker->width = marker->height = _rsvg_css_parse_length ("3");
marker->bbox = TRUE;
marker->vbox.active = FALSE;
marker->super.set_atts = rsvg_node_marker_set_atts;
return &marker->super;
}
static void
rsvg_marker_render (const char * marker_name, gdouble xpos, gdouble ypos, gdouble orient, gdouble linewidth,
RsvgDrawingCtx * ctx)
{
RsvgMarker *self;
cairo_matrix_t affine, taffine;
unsigned int i;
gdouble rotation;
RsvgState *state = rsvg_current_state (ctx);
if (marker_name == NULL)
return; /* to avoid the caller having to check for nonexistent markers on every call */
self = (RsvgMarker *) rsvg_acquire_node (ctx, marker_name);
if (self == NULL || RSVG_NODE_TYPE (&self->super) != RSVG_NODE_TYPE_MARKER)
{
rsvg_release_node (ctx, &self->super);
return;
}
cairo_matrix_init_translate (&taffine, xpos, ypos);
cairo_matrix_multiply (&affine, &taffine, &state->affine);
if (self->orientAuto)
rotation = orient;
else
rotation = self->orient * M_PI / 180.;
cairo_matrix_init_rotate (&taffine, rotation);
cairo_matrix_multiply (&affine, &taffine, &affine);
if (self->bbox) {
cairo_matrix_init_scale (&taffine, linewidth, linewidth);
cairo_matrix_multiply (&affine, &taffine, &affine);
}
if (self->vbox.active) {
double w, h, x, y;
w = _rsvg_css_normalize_length (&self->width, ctx, 'h');
h = _rsvg_css_normalize_length (&self->height, ctx, 'v');
x = 0;
y = 0;
rsvg_preserve_aspect_ratio (self->preserve_aspect_ratio,
self->vbox.rect.width,
self->vbox.rect.height,
&w, &h, &x, &y);
cairo_matrix_init_scale (&taffine, w / self->vbox.rect.width, h / self->vbox.rect.height);
cairo_matrix_multiply (&affine, &taffine, &affine);
_rsvg_push_view_box (ctx, self->vbox.rect.width, self->vbox.rect.height);
}
cairo_matrix_init_translate (&taffine,
-_rsvg_css_normalize_length (&self->refX, ctx, 'h'),
-_rsvg_css_normalize_length (&self->refY, ctx, 'v'));
cairo_matrix_multiply (&affine, &taffine, &affine);
rsvg_state_push (ctx);
state = rsvg_current_state (ctx);
rsvg_state_reinit (state);
rsvg_state_reconstruct (state, &self->super);
state->affine = affine;
rsvg_push_discrete_layer (ctx);
state = rsvg_current_state (ctx);
if (!state->overflow) {
if (self->vbox.active)
rsvg_add_clipping_rect (ctx, self->vbox.rect.x, self->vbox.rect.y,
self->vbox.rect.width, self->vbox.rect.height);
else
rsvg_add_clipping_rect (ctx, 0, 0,
_rsvg_css_normalize_length (&self->width, ctx, 'h'),
_rsvg_css_normalize_length (&self->height, ctx, 'v'));
}
for (i = 0; i < self->super.children->len; i++) {
rsvg_state_push (ctx);
rsvg_node_draw (g_ptr_array_index (self->super.children, i), ctx, 0);
rsvg_state_pop (ctx);
}
rsvg_pop_discrete_layer (ctx);
rsvg_state_pop (ctx);
if (self->vbox.active)
_rsvg_pop_view_box (ctx);
rsvg_release_node (ctx, (RsvgNode *) self);
}
typedef struct {
gboolean is_degenerate; /* If true, only (p1x, p1y) are valid. If false, all are valid */
double p1x, p1y;
double p2x, p2y;
double p3x, p3y;
double p4x, p4y;
} Segment;
typedef enum {
SEGMENT_START,
SEGMENT_END,
} SegmentState;
/* This converts a cairo_path_t into a list of curveto-like segments. Each segment can be:
*
* 1. segment->is_degenerate = TRUE => the segment is actually a single point (segment->p1x, segment->p1y)
*
* 2. segment->is_degenerate = FALSE => either a lineto or a curveto (or the effective lineto that results from a closepath).
* We have the following points:
* P1 = (p1x, p1y)
* P2 = (p2x, p2y)
* P3 = (p3x, p3y)
* P4 = (p4x, p4y)
*
* The start and end points are P1 and P4, respectively.
* The tangent at the start point is given by the vector (P2 - P1).
* The tangent at the end point is given by the vector (P4 - P3).
* The tangents also work if the segment refers to a lineto (they will both just point in the same direction).
*/
#define EPSILON 1e-10
#define DOUBLE_EQUALS(a, b) (fabs ((a) - (b)) < EPSILON)
static void
path_to_segments (const cairo_path_t *path,
Segment **out_segments,
int *num_segments)
{
int i;
double last_x, last_y;
double cur_x, cur_y;
double subpath_start_x, subpath_start_y;
int max_segments;
int segment_num;
Segment *segments;
SegmentState state;
max_segments = path->num_data; /* We'll generate maximum this many segments */
segments = g_new (Segment, max_segments);
*out_segments = segments;
last_x = last_y = cur_x = cur_y = subpath_start_x = subpath_start_y = 0.0;
segment_num = -1;
state = SEGMENT_END;
for (i = 0; i < path->num_data; i += path->data[i].header.length) {
last_x = cur_x;
last_y = cur_y;
switch (path->data[i].header.type) {
case CAIRO_PATH_MOVE_TO:
segment_num++;
g_assert (segment_num < max_segments);
g_assert (i + 1 < path->num_data);
cur_x = path->data[i + 1].point.x;
cur_y = path->data[i + 1].point.y;
subpath_start_x = cur_x;
subpath_start_y = cur_y;
segments[segment_num].is_degenerate = TRUE;
segments[segment_num].p1x = cur_x;
segments[segment_num].p1y = cur_y;
state = SEGMENT_START;
break;
case CAIRO_PATH_LINE_TO:
g_assert (i + 1 < path->num_data);
cur_x = path->data[i + 1].point.x;
cur_y = path->data[i + 1].point.y;
if (state == SEGMENT_START) {
segments[segment_num].is_degenerate = FALSE;
state = SEGMENT_END;
} else {
segment_num++;
g_assert (segment_num < max_segments);
segments[segment_num].is_degenerate = FALSE;
segments[segment_num].p1x = last_x;
segments[segment_num].p1y = last_y;
}
segments[segment_num].p2x = cur_x;
segments[segment_num].p2y = cur_y;
segments[segment_num].p3x = last_x;
segments[segment_num].p3y = last_y;
segments[segment_num].p4x = cur_x;
segments[segment_num].p4y = cur_y;
break;
case CAIRO_PATH_CURVE_TO:
g_assert (i + 3 < path->num_data);
cur_x = path->data[i + 3].point.x;
cur_y = path->data[i + 3].point.y;
if (state == SEGMENT_START) {
segments[segment_num].is_degenerate = FALSE;
state = SEGMENT_END;
} else {
segment_num++;
g_assert (segment_num < max_segments);
segments[segment_num].is_degenerate = FALSE;
segments[segment_num].p1x = last_x;
segments[segment_num].p1y = last_y;
}
segments[segment_num].p2x = path->data[i + 1].point.x;
segments[segment_num].p2y = path->data[i + 1].point.y;
segments[segment_num].p3x = path->data[i + 2].point.x;
segments[segment_num].p3y = path->data[i + 2].point.y;
segments[segment_num].p4x = cur_x;
segments[segment_num].p4y = cur_y;
/* Fix the tangents for when the middle control points coincide with their respective endpoints */
if (DOUBLE_EQUALS (segments[segment_num].p2x, segments[segment_num].p1x)
&& DOUBLE_EQUALS (segments[segment_num].p2y, segments[segment_num].p1y)) {
segments[segment_num].p2x = segments[segment_num].p3x;
segments[segment_num].p2y = segments[segment_num].p3y;
}
if (DOUBLE_EQUALS (segments[segment_num].p3x, segments[segment_num].p4x)
&& DOUBLE_EQUALS (segments[segment_num].p3y, segments[segment_num].p4y)) {
segments[segment_num].p3x = segments[segment_num].p2x;
segments[segment_num].p3y = segments[segment_num].p2y;
}
break;
case CAIRO_PATH_CLOSE_PATH:
cur_x = subpath_start_x;
cur_y = subpath_start_y;
if (state == SEGMENT_START) {
segments[segment_num].is_degenerate = FALSE;
segments[segment_num].p2x = cur_x;
segments[segment_num].p2y = cur_y;
segments[segment_num].p3x = last_x;
segments[segment_num].p3y = last_y;
segments[segment_num].p4x = cur_x;
segments[segment_num].p4y = cur_y;
state = SEGMENT_END;
} else {
/* nothing; closepath after moveto (or a single lone closepath) does nothing */
}
break;
default:
g_assert_not_reached ();
}
}
*num_segments = segment_num + 1;
g_assert (*num_segments <= max_segments);
}
static gboolean
points_equal (double x1, double y1, double x2, double y2)
{
return DOUBLE_EQUALS (x1, x2) && DOUBLE_EQUALS (y1, y2);
}
/* A segment is zero length if it is degenerate, or if all four control points
* coincide (the first and last control points may coincide, but the others may
* define a loop - thus nonzero length)
*/
static gboolean
is_zero_length_segment (Segment *segment)
{
double p1x, p1y;
double p2x, p2y;
double p3x, p3y;
double p4x, p4y;
if (segment->is_degenerate)
return TRUE;
p1x = segment->p1x;
p1y = segment->p1y;
p2x = segment->p2x;
p2y = segment->p2y;
p3x = segment->p3x;
p3y = segment->p3y;
p4x = segment->p4x;
p4y = segment->p4y;
return (points_equal (p1x, p1y, p2x, p2y)
&& points_equal (p1x, p1y, p3x, p3y)
&& points_equal (p1x, p1y, p4x, p4y));
}
/* The SVG spec 1.1 says http://www.w3.org/TR/SVG/implnote.html#PathElementImplementationNotes
*
* Certain line-capping and line-joining situations and markers
* require that a path segment have directionality at its start and
* end points. Zero-length path segments have no directionality. In
* these cases, the following algorithm is used to establish
* directionality: to determine the directionality of the start
* point of a zero-length path segment, go backwards in the path
* data specification within the current subpath until you find a
* segment which has directionality at its end point (e.g., a path
* segment with non-zero length) and use its ending direction;
* otherwise, temporarily consider the start point to lack
* directionality. Similarly, to determine the directionality of the
* end point of a zero-length path segment, go forwards in the path
* data specification within the current subpath until you find a
* segment which has directionality at its start point (e.g., a path
* segment with non-zero length) and use its starting direction;
* otherwise, temporarily consider the end point to lack
* directionality. If the start point has directionality but the end
* point doesn't, then the end point uses the start point's
* directionality. If the end point has directionality but the start
* point doesn't, then the start point uses the end point's
* directionality. Otherwise, set the directionality for the path
* segment's start and end points to align with the positive x-axis
* in user space.
*/
static gboolean
find_incoming_directionality_backwards (Segment *segments, int num_segments, int start_index, double *vx, double *vy)
{
int j;
gboolean found;
/* "go backwards ... within the current subpath until ... segment which has directionality at its end point" */
found = FALSE;
for (j = start_index; j >= 0; j--) {
if (segments[j].is_degenerate)
break; /* reached the beginning of the subpath as we ran into a standalone point */
else {
if (is_zero_length_segment (&segments[j]))
continue;
else {
found = TRUE;
break;
}
}
}
if (found) {
g_assert (j >= 0);
*vx = segments[j].p4x - segments[j].p3x;
*vy = segments[j].p4y - segments[j].p3y;
return TRUE;
} else {
*vx = 0.0;
*vy = 0.0;
return FALSE;
}
}
static gboolean
find_outgoing_directionality_forwards (Segment *segments, int num_segments, int start_index, double *vx, double *vy)
{
int j;
gboolean found;
/* "go forwards ... within the current subpath until ... segment which has directionality at its start point" */
found = FALSE;
for (j = start_index; j < num_segments; j++) {
if (segments[j].is_degenerate)
break; /* reached the end of a subpath as we ran into a standalone point */
else {
if (is_zero_length_segment (&segments[j]))
continue;
else {
found = TRUE;
break;
}
}
}
if (found) {
g_assert (j < num_segments);
*vx = segments[j].p2x - segments[j].p1x;
*vy = segments[j].p2y - segments[j].p1y;
return TRUE;
} else {
*vx = 0.0;
*vy = 0.0;
return FALSE;
}
}
static double
angle_from_vector (double vx, double vy)
{
double angle;
angle = atan2 (vy, vx);
if (isnan (angle))
return 0.0;
else
return angle;
}
typedef enum {
NO_SUBPATH,
IN_SUBPATH,
} SubpathState;
void
rsvg_render_markers (RsvgDrawingCtx * ctx,
const cairo_path_t *path)
{
RsvgState *state;
double linewidth;
const char *startmarker;
const char *middlemarker;
const char *endmarker;
int i;
double incoming_vx, incoming_vy;
double outgoing_vx, outgoing_vy;
Segment *segments;
int num_segments;
SubpathState subpath_state;
state = rsvg_current_state (ctx);
linewidth = _rsvg_css_normalize_length (&state->stroke_width, ctx, 'o');
startmarker = state->startMarker;
middlemarker = state->middleMarker;
endmarker = state->endMarker;
if (linewidth == 0)
return;
if (!startmarker && !middlemarker && !endmarker)
return;
if (path->num_data <= 0)
return;
/* Convert the path to a list of segments and bare points (i.e. degenerate segments) */
path_to_segments (path, &segments, &num_segments);
subpath_state = NO_SUBPATH;
for (i = 0; i < num_segments; i++) {
incoming_vx = incoming_vy = outgoing_vx = outgoing_vy = 0.0;
if (segments[i].is_degenerate) {
if (subpath_state == IN_SUBPATH) {
g_assert (i > 0);
/* Got a lone point after a subpath; render the subpath's end marker first */
find_incoming_directionality_backwards (segments, num_segments, i - 1, &incoming_vx, &incoming_vy);
rsvg_marker_render (endmarker, segments[i - 1].p4x, segments[i - 1].p4y, angle_from_vector (incoming_vx, incoming_vy), linewidth, ctx);
}
/* Render marker for the lone point; no directionality */
rsvg_marker_render (middlemarker, segments[i].p1x, segments[i].p1y, 0.0, linewidth, ctx);
subpath_state = NO_SUBPATH;
} else {
/* Not a degenerate segment */
if (subpath_state == NO_SUBPATH) {
find_outgoing_directionality_forwards (segments, num_segments, i, &outgoing_vx, &outgoing_vy);
rsvg_marker_render (startmarker, segments[i].p1x, segments[i].p1y, angle_from_vector (outgoing_vx, outgoing_vy), linewidth, ctx);
subpath_state = IN_SUBPATH;
} else {
/* subpath_state == IN_SUBPATH */
gboolean has_incoming, has_outgoing;
double incoming, outgoing;
double angle;
g_assert (i > 0);
has_incoming = find_incoming_directionality_backwards (segments, num_segments, i - 1, &incoming_vx, &incoming_vy);
has_outgoing = find_outgoing_directionality_forwards (segments, num_segments, i, &outgoing_vx, &outgoing_vy);
if (has_incoming)
incoming = angle_from_vector (incoming_vx, incoming_vy);
if (has_outgoing)
outgoing = angle_from_vector (outgoing_vx, outgoing_vy);
if (has_incoming && has_outgoing)
angle = (incoming + outgoing) / 2;
else if (has_incoming)
angle = incoming;
else if (has_outgoing)
angle = outgoing;
else
angle = 0.0;
rsvg_marker_render (middlemarker, segments[i].p1x, segments[i].p1y, angle, linewidth, ctx);
}
}
}
/* Finally, render the last point */
if (num_segments > 0) {
if (!segments[num_segments - 1].is_degenerate) {
find_incoming_directionality_backwards (segments, num_segments, num_segments - 1, &incoming_vx, &incoming_vy);
rsvg_marker_render (endmarker, segments[num_segments - 1].p4x, segments[num_segments - 1].p4y, angle_from_vector (incoming_vx, incoming_vy), linewidth, ctx);
}
}
g_free (segments);
}