gotosocial/vendor/github.com/golang/geo/s2/contains_point_query.go

// Copyright 2018 Google Inc. All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
//     http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.

package s2

// VertexModel defines whether shapes are considered to contain their vertices.
// Note that these definitions differ from the ones used by BooleanOperation.
//
// Note that points other than vertices are never contained by polylines.
// If you want need this behavior, use ClosestEdgeQuery's IsDistanceLess
// with a suitable distance threshold instead.
type VertexModel int

const (
	// VertexModelOpen means no shapes contain their vertices (not even
	// points). Therefore Contains(Point) returns true if and only if the
	// point is in the interior of some polygon.
	VertexModelOpen VertexModel = iota

	// VertexModelSemiOpen means that polygon point containment is defined
	// such that if several polygons tile the region around a vertex, then
	// exactly one of those polygons contains that vertex. Points and
	// polylines still do not contain any vertices.
	VertexModelSemiOpen

	// VertexModelClosed means all shapes contain their vertices (including
	// points and polylines).
	VertexModelClosed
)

// ContainsPointQuery determines whether one or more shapes in a ShapeIndex
// contain a given Point. The ShapeIndex may contain any number of points,
// polylines, and/or polygons (possibly overlapping). Shape boundaries may be
// modeled as Open, SemiOpen, or Closed (this affects whether or not shapes are
// considered to contain their vertices).
//
// This type is not safe for concurrent use.
//
// However, note that if you need to do a large number of point containment
// tests, it is more efficient to re-use the query rather than creating a new
// one each time.
type ContainsPointQuery struct {
	model VertexModel
	index *ShapeIndex
	iter  *ShapeIndexIterator
}

// NewContainsPointQuery creates a new instance of the ContainsPointQuery for the index
// and given vertex model choice.
func NewContainsPointQuery(index *ShapeIndex, model VertexModel) *ContainsPointQuery {
	return &ContainsPointQuery{
		index: index,
		model: model,
		iter:  index.Iterator(),
	}
}

// Contains reports whether any shape in the queries index contains the point p
// under the queries vertex model (Open, SemiOpen, or Closed).
func (q *ContainsPointQuery) Contains(p Point) bool {
	if !q.iter.LocatePoint(p) {
		return false
	}

	cell := q.iter.IndexCell()
	for _, clipped := range cell.shapes {
		if q.shapeContains(clipped, q.iter.Center(), p) {
			return true
		}
	}
	return false
}

// shapeContains reports whether the clippedShape from the iterator's center position contains
// the given point.
func (q *ContainsPointQuery) shapeContains(clipped *clippedShape, center, p Point) bool {
	inside := clipped.containsCenter
	numEdges := clipped.numEdges()
	if numEdges <= 0 {
		return inside
	}

	shape := q.index.Shape(clipped.shapeID)
	if shape.Dimension() != 2 {
		// Points and polylines can be ignored unless the vertex model is Closed.
		if q.model != VertexModelClosed {
			return false
		}

		// Otherwise, the point is contained if and only if it matches a vertex.
		for _, edgeID := range clipped.edges {
			edge := shape.Edge(edgeID)
			if edge.V0 == p || edge.V1 == p {
				return true
			}
		}
		return false
	}

	// Test containment by drawing a line segment from the cell center to the
	// given point and counting edge crossings.
	crosser := NewEdgeCrosser(center, p)
	for _, edgeID := range clipped.edges {
		edge := shape.Edge(edgeID)
		sign := crosser.CrossingSign(edge.V0, edge.V1)
		if sign == DoNotCross {
			continue
		}
		if sign == MaybeCross {
			// For the Open and Closed models, check whether p is a vertex.
			if q.model != VertexModelSemiOpen && (edge.V0 == p || edge.V1 == p) {
				return (q.model == VertexModelClosed)
			}
			// C++ plays fast and loose with the int <-> bool conversions here.
			if VertexCrossing(crosser.a, crosser.b, edge.V0, edge.V1) {
				sign = Cross
			} else {
				sign = DoNotCross
			}
		}
		inside = inside != (sign == Cross)
	}

	return inside
}

// ShapeContains reports whether the given shape contains the point under this
// queries vertex model (Open, SemiOpen, or Closed).
//
// This requires the shape belongs to this queries index.
func (q *ContainsPointQuery) ShapeContains(shape Shape, p Point) bool {
	if !q.iter.LocatePoint(p) {
		return false
	}

	clipped := q.iter.IndexCell().findByShapeID(q.index.idForShape(shape))
	if clipped == nil {
		return false
	}
	return q.shapeContains(clipped, q.iter.Center(), p)
}

// shapeVisitorFunc is a type of function that can be called against shaped in an index.
type shapeVisitorFunc func(shape Shape) bool

// visitContainingShapes visits all shapes in the given index that contain the
// given point p, terminating early if the given visitor function returns false,
// in which case visitContainingShapes returns false. Each shape is
// visited at most once.
func (q *ContainsPointQuery) visitContainingShapes(p Point, f shapeVisitorFunc) bool {
	// This function returns false only if the algorithm terminates early
	// because the visitor function returned false.
	if !q.iter.LocatePoint(p) {
		return true
	}

	cell := q.iter.IndexCell()
	for _, clipped := range cell.shapes {
		if q.shapeContains(clipped, q.iter.Center(), p) &&
			!f(q.index.Shape(clipped.shapeID)) {
			return false
		}
	}
	return true
}

// ContainingShapes returns a slice of all shapes that contain the given point.
func (q *ContainsPointQuery) ContainingShapes(p Point) []Shape {
	var shapes []Shape
	q.visitContainingShapes(p, func(shape Shape) bool {
		shapes = append(shapes, shape)
		return true
	})
	return shapes
}

// TODO(roberts): Remaining methods from C++
// type edgeVisitorFunc func(shape ShapeEdge) bool
// func (q *ContainsPointQuery) visitIncidentEdges(p Point, v edgeVisitorFunc) bool
Grand test fixup (#138) * start fixing up tests * fix up tests + automate with drone * fiddle with linting * messing about with drone.yml * some more fiddling * hmmm * add cache * add vendor directory * verbose * ci updates * update some little things * update sig 2021-08-12 19:03:24 +00:00			`// Copyright 2018 Google Inc. All rights reserved.`
			`//`
			`// Licensed under the Apache License, Version 2.0 (the "License");`
			`// you may not use this file except in compliance with the License.`
			`// You may obtain a copy of the License at`
			`//`
			`// http://www.apache.org/licenses/LICENSE-2.0`
			`//`
			`// Unless required by applicable law or agreed to in writing, software`
			`// distributed under the License is distributed on an "AS IS" BASIS,`
			`// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.`
			`// See the License for the specific language governing permissions and`
			`// limitations under the License.`

			`package s2`

			`// VertexModel defines whether shapes are considered to contain their vertices.`
			`// Note that these definitions differ from the ones used by BooleanOperation.`
			`//`
			`// Note that points other than vertices are never contained by polylines.`
			`// If you want need this behavior, use ClosestEdgeQuery's IsDistanceLess`
			`// with a suitable distance threshold instead.`
			`type VertexModel int`

			`const (`
			`// VertexModelOpen means no shapes contain their vertices (not even`
			`// points). Therefore Contains(Point) returns true if and only if the`
			`// point is in the interior of some polygon.`
			`VertexModelOpen VertexModel = iota`

			`// VertexModelSemiOpen means that polygon point containment is defined`
			`// such that if several polygons tile the region around a vertex, then`
			`// exactly one of those polygons contains that vertex. Points and`
			`// polylines still do not contain any vertices.`
			`VertexModelSemiOpen`

			`// VertexModelClosed means all shapes contain their vertices (including`
			`// points and polylines).`
			`VertexModelClosed`
			`)`

			`// ContainsPointQuery determines whether one or more shapes in a ShapeIndex`
			`// contain a given Point. The ShapeIndex may contain any number of points,`
			`// polylines, and/or polygons (possibly overlapping). Shape boundaries may be`
			`// modeled as Open, SemiOpen, or Closed (this affects whether or not shapes are`
			`// considered to contain their vertices).`
			`//`
			`// This type is not safe for concurrent use.`
			`//`
			`// However, note that if you need to do a large number of point containment`
			`// tests, it is more efficient to re-use the query rather than creating a new`
			`// one each time.`
			`type ContainsPointQuery struct {`
			`model VertexModel`
			`index *ShapeIndex`
			`iter *ShapeIndexIterator`
			`}`

			`// NewContainsPointQuery creates a new instance of the ContainsPointQuery for the index`
			`// and given vertex model choice.`
			`func NewContainsPointQuery(index ShapeIndex, model VertexModel) ContainsPointQuery {`
			`return &ContainsPointQuery{`
			`index: index,`
			`model: model,`
			`iter: index.Iterator(),`
			`}`
			`}`

			`// Contains reports whether any shape in the queries index contains the point p`
			`// under the queries vertex model (Open, SemiOpen, or Closed).`
			`func (q *ContainsPointQuery) Contains(p Point) bool {`
			`if !q.iter.LocatePoint(p) {`
			`return false`
			`}`

			`cell := q.iter.IndexCell()`
			`for _, clipped := range cell.shapes {`
			`if q.shapeContains(clipped, q.iter.Center(), p) {`
			`return true`
			`}`
			`}`
			`return false`
			`}`

			`// shapeContains reports whether the clippedShape from the iterator's center position contains`
			`// the given point.`
			`func (q ContainsPointQuery) shapeContains(clipped clippedShape, center, p Point) bool {`
			`inside := clipped.containsCenter`
			`numEdges := clipped.numEdges()`
			`if numEdges <= 0 {`
			`return inside`
			`}`

			`shape := q.index.Shape(clipped.shapeID)`
			`if shape.Dimension() != 2 {`
			`// Points and polylines can be ignored unless the vertex model is Closed.`
			`if q.model != VertexModelClosed {`
			`return false`
			`}`

			`// Otherwise, the point is contained if and only if it matches a vertex.`
			`for _, edgeID := range clipped.edges {`
			`edge := shape.Edge(edgeID)`
			`if edge.V0 == p \|\| edge.V1 == p {`
			`return true`
			`}`
			`}`
			`return false`
			`}`

			`// Test containment by drawing a line segment from the cell center to the`
			`// given point and counting edge crossings.`
			`crosser := NewEdgeCrosser(center, p)`
			`for _, edgeID := range clipped.edges {`
			`edge := shape.Edge(edgeID)`
			`sign := crosser.CrossingSign(edge.V0, edge.V1)`
			`if sign == DoNotCross {`
			`continue`
			`}`
			`if sign == MaybeCross {`
			`// For the Open and Closed models, check whether p is a vertex.`
			`if q.model != VertexModelSemiOpen && (edge.V0 == p \|\| edge.V1 == p) {`
			`return (q.model == VertexModelClosed)`
			`}`
			`// C++ plays fast and loose with the int <-> bool conversions here.`
			`if VertexCrossing(crosser.a, crosser.b, edge.V0, edge.V1) {`
			`sign = Cross`
			`} else {`
			`sign = DoNotCross`
			`}`
			`}`
			`inside = inside != (sign == Cross)`
			`}`

			`return inside`
			`}`

			`// ShapeContains reports whether the given shape contains the point under this`
			`// queries vertex model (Open, SemiOpen, or Closed).`
			`//`
			`// This requires the shape belongs to this queries index.`
			`func (q *ContainsPointQuery) ShapeContains(shape Shape, p Point) bool {`
			`if !q.iter.LocatePoint(p) {`
			`return false`
			`}`

			`clipped := q.iter.IndexCell().findByShapeID(q.index.idForShape(shape))`
			`if clipped == nil {`
			`return false`
			`}`
			`return q.shapeContains(clipped, q.iter.Center(), p)`
			`}`

			`// shapeVisitorFunc is a type of function that can be called against shaped in an index.`
			`type shapeVisitorFunc func(shape Shape) bool`

			`// visitContainingShapes visits all shapes in the given index that contain the`
			`// given point p, terminating early if the given visitor function returns false,`
			`// in which case visitContainingShapes returns false. Each shape is`
			`// visited at most once.`
			`func (q *ContainsPointQuery) visitContainingShapes(p Point, f shapeVisitorFunc) bool {`
			`// This function returns false only if the algorithm terminates early`
			`// because the visitor function returned false.`
			`if !q.iter.LocatePoint(p) {`
			`return true`
			`}`

			`cell := q.iter.IndexCell()`
			`for _, clipped := range cell.shapes {`
			`if q.shapeContains(clipped, q.iter.Center(), p) &&`
			`!f(q.index.Shape(clipped.shapeID)) {`
			`return false`
			`}`
			`}`
			`return true`
			`}`

			`// ContainingShapes returns a slice of all shapes that contain the given point.`
			`func (q *ContainsPointQuery) ContainingShapes(p Point) []Shape {`
			`var shapes []Shape`
			`q.visitContainingShapes(p, func(shape Shape) bool {`
			`shapes = append(shapes, shape)`
			`return true`
			`})`
			`return shapes`
			`}`

			`// TODO(roberts): Remaining methods from C++`
			`// type edgeVisitorFunc func(shape ShapeEdge) bool`
			`// func (q *ContainsPointQuery) visitIncidentEdges(p Point, v edgeVisitorFunc) bool`