69 const QList<QgsFeatureId> ids = index.
intersects( rect );
90 static void assignAnchors(
QgsSpatialIndex &index, QVector<AnchorPoint> &pnts,
double thresh )
92 const double thresh2 = thresh * thresh;
93 int nanchors = 0, ntosnap = 0;
94 for (
int point = 0; point < pnts.count(); ++point )
96 if ( pnts[point].anchor >= 0 )
99 pnts[point].anchor = -2;
103 double x = pnts[point].x, y = pnts[point].y;
104 const QgsRectangle rect( x - thresh, y - thresh, x + thresh, y + thresh );
106 const QList<QgsFeatureId> ids = index.
intersects( rect );
109 if ( pointb == point )
112 const double dx = pnts[pointb].x - pnts[point].x;
113 const double dy = pnts[pointb].y - pnts[point].y;
114 const double dist2 = dx * dx + dy * dy;
115 if ( dist2 > thresh2 )
118 if ( pnts[pointb].anchor == -1 )
121 pnts[pointb].anchor = point;
124 else if ( pnts[pointb].anchor >= 0 )
127 const double dx2 = pnts[pnts[pointb].anchor].x - pnts[pointb].x;
128 const double dy2 = pnts[pnts[pointb].anchor].y - pnts[pointb].y;
129 const double dist2_a = dx2 * dx2 + dy2 * dy2;
130 if ( dist2 < dist2_a )
131 pnts[pointb].anchor = point;
142 Q_ASSERT( fids.count() == 1 );
144 const int spoint = fids[0];
145 const int anchor = pnts[spoint].anchor;
150 pt->
setX( pnts[anchor].x );
151 pt->
setY( pnts[anchor].y );
161 QVector<QgsPoint> newPoints;
162 QVector<int> anchors;
163 const double thresh2 = thresh * thresh;
164 double minDistX, minDistY;
165 bool changed =
false;
168 for (
int v = 0; v < linestring->
numPoints(); v++ )
170 const double x = linestring->
xAt( v );
171 const double y = linestring->
yAt( v );
175 QList<QgsFeatureId> fids = index.
intersects( rect );
176 Q_ASSERT( fids.count() == 1 );
178 const int spoint = fids.first();
179 const int anchor = pnts[spoint].anchor;
183 linestring->
setXAt( v, pnts[anchor].x );
184 linestring->
setYAt( v, pnts[anchor].y );
185 anchors.append( anchor );
190 anchors.append( spoint );
195 for (
int v = 0; v < linestring->
numPoints() - 1; v++ )
197 const double x1 = linestring->
xAt( v );
198 const double x2 = linestring->
xAt( v + 1 );
199 const double y1 = linestring->
yAt( v );
200 const double y2 = linestring->
yAt( v + 1 );
202 newPoints << linestring->
pointN( v );
205 double xmin = x1, xmax = x2, ymin = y1, ymax = y2;
207 std::swap( xmin, xmax );
209 std::swap( ymin, ymax );
211 const QgsRectangle rect( xmin - thresh, ymin - thresh, xmax + thresh, ymax + thresh );
214 const QList<QgsFeatureId> fids = index.
intersects( rect );
216 QVector<AnchorAlongSegment> newVerticesAlongSegment;
221 const int spoint = fid;
223 if ( spoint == anchors[v] || spoint == anchors[v + 1] )
225 if ( pnts[spoint].anchor >= 0 )
231 double dx1 = minDistX - x1, dx2 = minDistX - x2;
232 double dy1 = minDistY - y1, dy2 = minDistY - y2;
234 if ( isOnSegment && dist2 <= thresh2 )
240 newVerticesAlongSegment << item;
244 if ( !newVerticesAlongSegment.isEmpty() )
249 return p1.along < p2.along;
253 for (
int i = 0; i < newVerticesAlongSegment.count(); i++ )
255 const int anchor = newVerticesAlongSegment[i].anchor;
256 newPoints <<
QgsPoint( pnts[anchor].x, pnts[anchor].y, 0 );
275 bool changed =
false;
276 if (
QgsLineString *linestring = qgsgeometry_cast<QgsLineString *>( g ) )
278 changed |= snapLineString( linestring, index, pnts, thresh );
280 else if (
QgsPolygon *polygon = qgsgeometry_cast<QgsPolygon *>( g ) )
282 if (
QgsLineString *exteriorRing = qgsgeometry_cast<QgsLineString *>( polygon->exteriorRing() ) )
283 changed |= snapLineString( exteriorRing, index, pnts, thresh );
284 for (
int i = 0; i < polygon->numInteriorRings(); ++i )
286 if (
QgsLineString *interiorRing = qgsgeometry_cast<QgsLineString *>( polygon->interiorRing( i ) ) )
287 changed |= snapLineString( interiorRing, index, pnts, thresh );
292 for (
int i = 0; i < collection->numGeometries(); ++i )
293 changed |= snapGeometry( collection->geometryN( i ), index, pnts, thresh );
295 else if (
QgsPoint *pt = qgsgeometry_cast<QgsPoint *>( g ) )
297 changed |= snapPoint( pt, index, pnts );
315 QVector<AnchorPoint> pnts;
319 buildSnapIndex( fi, index, pnts, feedback, count, totalCount );
327 assignAnchors( index, pnts, thresh );
343 if ( snapGeometry( geom.
get(), index, pnts, thresh ) )
352 feedback->
setProgress( 100. * count / totalCount );
Abstract base class for all geometries.
Wrapper for iterator of features from vector data provider or vector layer.
bool nextFeature(QgsFeature &f)
This class wraps a request for features to a vector layer (or directly its vector data provider).
QgsFeatureRequest & setNoAttributes()
Set that no attributes will be fetched.
An interface for objects which accept features via addFeature(s) methods.
virtual bool addFeature(QgsFeature &feature, QgsFeatureSink::Flags flags=QgsFeatureSink::Flags())
Adds a single feature to the sink.
@ FastInsert
Use faster inserts, at the cost of updating the passed features to reflect changes made at the provid...
An interface for objects which provide features via a getFeatures method.
virtual QgsFeatureIterator getFeatures(const QgsFeatureRequest &request=QgsFeatureRequest()) const =0
Returns an iterator for the features in the source.
virtual long long featureCount() const =0
Returns the number of features contained in the source, or -1 if the feature count is unknown.
The feature class encapsulates a single feature including its unique ID, geometry and a list of field...
void setGeometry(const QgsGeometry &geometry)
Set the feature's geometry.
Base class for feedback objects to be used for cancellation of something running in a worker thread.
bool isCanceled() const SIP_HOLDGIL
Tells whether the operation has been canceled already.
void setProgress(double progress)
Sets the current progress for the feedback object.
static int run(const QgsFeatureSource &source, QgsFeatureSink &sink, double thresh, QgsFeedback *feedback)
Run the algorithm on given source and output results to the sink, using threshold value in the source...
static double sqrDistToLine(double ptX, double ptY, double x1, double y1, double x2, double y2, double &minDistX, double &minDistY, double epsilon) SIP_HOLDGIL
Returns the squared distance between a point and a line.
A geometry is the spatial representation of a feature.
QgsAbstractGeometry * get()
Returns a modifiable (non-const) reference to the underlying abstract geometry primitive.
QgsAbstractGeometry::vertex_iterator vertices_begin() const
Returns STL-style iterator pointing to the first vertex of the geometry.
QgsAbstractGeometry::vertex_iterator vertices_end() const
Returns STL-style iterator pointing to the imaginary vertex after the last vertex of the geometry.
Line string geometry type, with support for z-dimension and m-values.
int numPoints() const override SIP_HOLDGIL
Returns the number of points in the curve.
QgsPoint pointN(int i) const
Returns the specified point from inside the line string.
void setPoints(const QgsPointSequence &points)
Resets the line string to match the specified list of points.
double yAt(int index) const override
Returns the y-coordinate of the specified node in the line string.
void setYAt(int index, double y)
Sets the y-coordinate of the specified node in the line string.
void setXAt(int index, double x)
Sets the x-coordinate of the specified node in the line string.
double xAt(int index) const override
Returns the x-coordinate of the specified node in the line string.
A class to represent a 2D point.
double distance(double x, double y) const SIP_HOLDGIL
Returns the distance between this point and a specified x, y coordinate.
Point geometry type, with support for z-dimension and m-values.
void setX(double x) SIP_HOLDGIL
Sets the point's x-coordinate.
void setY(double y) SIP_HOLDGIL
Sets the point's y-coordinate.
QgsRectangle boundingBox() const override SIP_HOLDGIL
Returns the minimal bounding box for the geometry.
A rectangle specified with double values.
A spatial index for QgsFeature objects.
QList< QgsFeatureId > intersects(const QgsRectangle &rectangle) const
Returns a list of features with a bounding box which intersects the specified rectangle.
bool addFeature(QgsFeature &feature, QgsFeatureSink::Flags flags=QgsFeatureSink::Flags()) override
Adds a feature to the index.
bool qgsDoubleNear(double a, double b, double epsilon=4 *std::numeric_limits< double >::epsilon())
Compare two doubles (but allow some difference)
qint64 QgsFeatureId
64 bit feature ids negative numbers are used for uncommitted/newly added features
record about anchor being along a segment
int anchor
Index of the anchor point.
double along
Distance of the anchor point along the segment.
record about vertex coordinates and index of anchor to which it is snapped
double x
coordinates of the point
int anchor
Anchor information: 0+ - index of anchor to which this point should be snapped -1 - initial value (un...