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

// Copyright 2017 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

// CrossingType defines different ways of reporting edge intersections.
type CrossingType int

const (
	// CrossingTypeInterior reports intersections that occur at a point
	// interior to both edges (i.e., not at a vertex).
	CrossingTypeInterior CrossingType = iota

	// CrossingTypeAll reports all intersections, even those where two edges
	// intersect only because they share a common vertex.
	CrossingTypeAll

	// CrossingTypeNonAdjacent reports all intersections except for pairs of
	// the form (AB, BC) where both edges are from the same ShapeIndex.
	CrossingTypeNonAdjacent
)

// rangeIterator is a wrapper over ShapeIndexIterator with extra methods
// that are useful for merging the contents of two or more ShapeIndexes.
type rangeIterator struct {
	it *ShapeIndexIterator
	// The min and max leaf cell ids covered by the current cell. If done() is
	// true, these methods return a value larger than any valid cell id.
	rangeMin CellID
	rangeMax CellID
}

// newRangeIterator creates a new rangeIterator positioned at the first cell of the given index.
func newRangeIterator(index *ShapeIndex) *rangeIterator {
	r := &rangeIterator{
		it: index.Iterator(),
	}
	r.refresh()
	return r
}

func (r *rangeIterator) cellID() CellID             { return r.it.CellID() }
func (r *rangeIterator) indexCell() *ShapeIndexCell { return r.it.IndexCell() }
func (r *rangeIterator) next()                      { r.it.Next(); r.refresh() }
func (r *rangeIterator) done() bool                 { return r.it.Done() }

// seekTo positions the iterator at the first cell that overlaps or follows
// the current range minimum of the target iterator, i.e. such that its
// rangeMax >= target.rangeMin.
func (r *rangeIterator) seekTo(target *rangeIterator) {
	r.it.seek(target.rangeMin)
	// If the current cell does not overlap target, it is possible that the
	// previous cell is the one we are looking for. This can only happen when
	// the previous cell contains target but has a smaller CellID.
	if r.it.Done() || r.it.CellID().RangeMin() > target.rangeMax {
		if r.it.Prev() && r.it.CellID().RangeMax() < target.cellID() {
			r.it.Next()
		}
	}
	r.refresh()
}

// seekBeyond positions the iterator at the first cell that follows the current
// range minimum of the target iterator. i.e. the first cell such that its
// rangeMin > target.rangeMax.
func (r *rangeIterator) seekBeyond(target *rangeIterator) {
	r.it.seek(target.rangeMax.Next())
	if !r.it.Done() && r.it.CellID().RangeMin() <= target.rangeMax {
		r.it.Next()
	}
	r.refresh()
}

// refresh updates the iterators min and max values.
func (r *rangeIterator) refresh() {
	r.rangeMin = r.cellID().RangeMin()
	r.rangeMax = r.cellID().RangeMax()
}

// referencePointForShape is a helper function for implementing various Shapes
// ReferencePoint functions.
//
// Given a shape consisting of closed polygonal loops, the interior of the
// shape is defined as the region to the left of all edges (which must be
// oriented consistently). This function then chooses an arbitrary point and
// returns true if that point is contained by the shape.
//
// Unlike Loop and Polygon, this method allows duplicate vertices and
// edges, which requires some extra care with definitions. The rule that we
// apply is that an edge and its reverse edge cancel each other: the result
// is the same as if that edge pair were not present. Therefore shapes that
// consist only of degenerate loop(s) are either empty or full; by convention,
// the shape is considered full if and only if it contains an empty loop (see
// laxPolygon for details).
//
// Determining whether a loop on the sphere contains a point is harder than
// the corresponding problem in 2D plane geometry. It cannot be implemented
// just by counting edge crossings because there is no such thing as a point
// at infinity that is guaranteed to be outside the loop.
//
// This function requires that the given Shape have an interior.
func referencePointForShape(shape Shape) ReferencePoint {
	if shape.NumEdges() == 0 {
		// A shape with no edges is defined to be full if and only if it
		// contains at least one chain.
		return OriginReferencePoint(shape.NumChains() > 0)
	}
	// Define a "matched" edge as one that can be paired with a corresponding
	// reversed edge. Define a vertex as "balanced" if all of its edges are
	// matched. In order to determine containment, we must find an unbalanced
	// vertex. Often every vertex is unbalanced, so we start by trying an
	// arbitrary vertex.
	edge := shape.Edge(0)

	if ref, ok := referencePointAtVertex(shape, edge.V0); ok {
		return ref
	}

	// That didn't work, so now we do some extra work to find an unbalanced
	// vertex (if any). Essentially we gather a list of edges and a list of
	// reversed edges, and then sort them. The first edge that appears in one
	// list but not the other is guaranteed to be unmatched.
	n := shape.NumEdges()
	var edges = make([]Edge, n)
	var revEdges = make([]Edge, n)
	for i := 0; i < n; i++ {
		edge := shape.Edge(i)
		edges[i] = edge
		revEdges[i] = Edge{V0: edge.V1, V1: edge.V0}
	}

	sortEdges(edges)
	sortEdges(revEdges)

	for i := 0; i < n; i++ {
		if edges[i].Cmp(revEdges[i]) == -1 { // edges[i] is unmatched
			if ref, ok := referencePointAtVertex(shape, edges[i].V0); ok {
				return ref
			}
		}
		if revEdges[i].Cmp(edges[i]) == -1 { // revEdges[i] is unmatched
			if ref, ok := referencePointAtVertex(shape, revEdges[i].V0); ok {
				return ref
			}
		}
	}

	// All vertices are balanced, so this polygon is either empty or full except
	// for degeneracies. By convention it is defined to be full if it contains
	// any chain with no edges.
	for i := 0; i < shape.NumChains(); i++ {
		if shape.Chain(i).Length == 0 {
			return OriginReferencePoint(true)
		}
	}

	return OriginReferencePoint(false)
}

// referencePointAtVertex reports whether the given vertex is unbalanced, and
// returns a ReferencePoint indicating if the point is contained.
// Otherwise returns false.
func referencePointAtVertex(shape Shape, vTest Point) (ReferencePoint, bool) {
	var ref ReferencePoint

	// Let P be an unbalanced vertex. Vertex P is defined to be inside the
	// region if the region contains a particular direction vector starting from
	// P, namely the direction p.Ortho(). This can be calculated using
	// ContainsVertexQuery.

	containsQuery := NewContainsVertexQuery(vTest)
	n := shape.NumEdges()
	for e := 0; e < n; e++ {
		edge := shape.Edge(e)
		if edge.V0 == vTest {
			containsQuery.AddEdge(edge.V1, 1)
		}
		if edge.V1 == vTest {
			containsQuery.AddEdge(edge.V0, -1)
		}
	}
	containsSign := containsQuery.ContainsVertex()
	if containsSign == 0 {
		return ref, false // There are no unmatched edges incident to this vertex.
	}
	ref.Point = vTest
	ref.Contained = containsSign > 0

	return ref, true
}

// containsBruteForce reports whether the given shape contains the given point.
// Most clients should not use this method, since its running time is linear in
// the number of shape edges. Instead clients should create a ShapeIndex and use
// ContainsPointQuery, since this strategy is much more efficient when many
// points need to be tested.
//
// Polygon boundaries are treated as being semi-open (see ContainsPointQuery
// and VertexModel for other options).
func containsBruteForce(shape Shape, point Point) bool {
	if shape.Dimension() != 2 {
		return false
	}

	refPoint := shape.ReferencePoint()
	if refPoint.Point == point {
		return refPoint.Contained
	}

	crosser := NewEdgeCrosser(refPoint.Point, point)
	inside := refPoint.Contained
	for e := 0; e < shape.NumEdges(); e++ {
		edge := shape.Edge(e)
		inside = inside != crosser.EdgeOrVertexCrossing(edge.V0, edge.V1)
	}
	return inside
}
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 20:03:24 +01:00			`// Copyright 2017 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`

			`// CrossingType defines different ways of reporting edge intersections.`
			`type CrossingType int`

			`const (`
			`// CrossingTypeInterior reports intersections that occur at a point`
			`// interior to both edges (i.e., not at a vertex).`
			`CrossingTypeInterior CrossingType = iota`

			`// CrossingTypeAll reports all intersections, even those where two edges`
			`// intersect only because they share a common vertex.`
			`CrossingTypeAll`

			`// CrossingTypeNonAdjacent reports all intersections except for pairs of`
			`// the form (AB, BC) where both edges are from the same ShapeIndex.`
			`CrossingTypeNonAdjacent`
			`)`

			`// rangeIterator is a wrapper over ShapeIndexIterator with extra methods`
			`// that are useful for merging the contents of two or more ShapeIndexes.`
			`type rangeIterator struct {`
			`it *ShapeIndexIterator`
			`// The min and max leaf cell ids covered by the current cell. If done() is`
			`// true, these methods return a value larger than any valid cell id.`
			`rangeMin CellID`
			`rangeMax CellID`
			`}`

			`// newRangeIterator creates a new rangeIterator positioned at the first cell of the given index.`
			`func newRangeIterator(index ShapeIndex) rangeIterator {`
			`r := &rangeIterator{`
			`it: index.Iterator(),`
			`}`
			`r.refresh()`
			`return r`
			`}`

			`func (r *rangeIterator) cellID() CellID { return r.it.CellID() }`
			`func (r rangeIterator) indexCell() ShapeIndexCell { return r.it.IndexCell() }`
			`func (r *rangeIterator) next() { r.it.Next(); r.refresh() }`
			`func (r *rangeIterator) done() bool { return r.it.Done() }`

			`// seekTo positions the iterator at the first cell that overlaps or follows`
			`// the current range minimum of the target iterator, i.e. such that its`
			`// rangeMax >= target.rangeMin.`
			`func (r rangeIterator) seekTo(target rangeIterator) {`
			`r.it.seek(target.rangeMin)`
			`// If the current cell does not overlap target, it is possible that the`
			`// previous cell is the one we are looking for. This can only happen when`
			`// the previous cell contains target but has a smaller CellID.`
			`if r.it.Done() \|\| r.it.CellID().RangeMin() > target.rangeMax {`
			`if r.it.Prev() && r.it.CellID().RangeMax() < target.cellID() {`
			`r.it.Next()`
			`}`
			`}`
			`r.refresh()`
			`}`

			`// seekBeyond positions the iterator at the first cell that follows the current`
			`// range minimum of the target iterator. i.e. the first cell such that its`
			`// rangeMin > target.rangeMax.`
			`func (r rangeIterator) seekBeyond(target rangeIterator) {`
			`r.it.seek(target.rangeMax.Next())`
			`if !r.it.Done() && r.it.CellID().RangeMin() <= target.rangeMax {`
			`r.it.Next()`
			`}`
			`r.refresh()`
			`}`

			`// refresh updates the iterators min and max values.`
			`func (r *rangeIterator) refresh() {`
			`r.rangeMin = r.cellID().RangeMin()`
			`r.rangeMax = r.cellID().RangeMax()`
			`}`

			`// referencePointForShape is a helper function for implementing various Shapes`
			`// ReferencePoint functions.`
			`//`
			`// Given a shape consisting of closed polygonal loops, the interior of the`
			`// shape is defined as the region to the left of all edges (which must be`
			`// oriented consistently). This function then chooses an arbitrary point and`
			`// returns true if that point is contained by the shape.`
			`//`
			`// Unlike Loop and Polygon, this method allows duplicate vertices and`
			`// edges, which requires some extra care with definitions. The rule that we`
			`// apply is that an edge and its reverse edge cancel each other: the result`
			`// is the same as if that edge pair were not present. Therefore shapes that`
			`// consist only of degenerate loop(s) are either empty or full; by convention,`
			`// the shape is considered full if and only if it contains an empty loop (see`
			`// laxPolygon for details).`
			`//`
			`// Determining whether a loop on the sphere contains a point is harder than`
			`// the corresponding problem in 2D plane geometry. It cannot be implemented`
			`// just by counting edge crossings because there is no such thing as a point`
			`// at infinity that is guaranteed to be outside the loop.`
			`//`
			`// This function requires that the given Shape have an interior.`
			`func referencePointForShape(shape Shape) ReferencePoint {`
			`if shape.NumEdges() == 0 {`
			`// A shape with no edges is defined to be full if and only if it`
			`// contains at least one chain.`
			`return OriginReferencePoint(shape.NumChains() > 0)`
			`}`
			`// Define a "matched" edge as one that can be paired with a corresponding`
			`// reversed edge. Define a vertex as "balanced" if all of its edges are`
			`// matched. In order to determine containment, we must find an unbalanced`
			`// vertex. Often every vertex is unbalanced, so we start by trying an`
			`// arbitrary vertex.`
			`edge := shape.Edge(0)`

			`if ref, ok := referencePointAtVertex(shape, edge.V0); ok {`
			`return ref`
			`}`

			`// That didn't work, so now we do some extra work to find an unbalanced`
			`// vertex (if any). Essentially we gather a list of edges and a list of`
			`// reversed edges, and then sort them. The first edge that appears in one`
			`// list but not the other is guaranteed to be unmatched.`
			`n := shape.NumEdges()`
			`var edges = make([]Edge, n)`
			`var revEdges = make([]Edge, n)`
			`for i := 0; i < n; i++ {`
			`edge := shape.Edge(i)`
			`edges[i] = edge`
			`revEdges[i] = Edge{V0: edge.V1, V1: edge.V0}`
			`}`

			`sortEdges(edges)`
			`sortEdges(revEdges)`

			`for i := 0; i < n; i++ {`
			`if edges[i].Cmp(revEdges[i]) == -1 { // edges[i] is unmatched`
			`if ref, ok := referencePointAtVertex(shape, edges[i].V0); ok {`
			`return ref`
			`}`
			`}`
			`if revEdges[i].Cmp(edges[i]) == -1 { // revEdges[i] is unmatched`
			`if ref, ok := referencePointAtVertex(shape, revEdges[i].V0); ok {`
			`return ref`
			`}`
			`}`
			`}`

			`// All vertices are balanced, so this polygon is either empty or full except`
			`// for degeneracies. By convention it is defined to be full if it contains`
			`// any chain with no edges.`
			`for i := 0; i < shape.NumChains(); i++ {`
			`if shape.Chain(i).Length == 0 {`
			`return OriginReferencePoint(true)`
			`}`
			`}`

			`return OriginReferencePoint(false)`
			`}`

			`// referencePointAtVertex reports whether the given vertex is unbalanced, and`
			`// returns a ReferencePoint indicating if the point is contained.`
			`// Otherwise returns false.`
			`func referencePointAtVertex(shape Shape, vTest Point) (ReferencePoint, bool) {`
			`var ref ReferencePoint`

			`// Let P be an unbalanced vertex. Vertex P is defined to be inside the`
			`// region if the region contains a particular direction vector starting from`
			`// P, namely the direction p.Ortho(). This can be calculated using`
			`// ContainsVertexQuery.`

			`containsQuery := NewContainsVertexQuery(vTest)`
			`n := shape.NumEdges()`
			`for e := 0; e < n; e++ {`
			`edge := shape.Edge(e)`
			`if edge.V0 == vTest {`
			`containsQuery.AddEdge(edge.V1, 1)`
			`}`
			`if edge.V1 == vTest {`
			`containsQuery.AddEdge(edge.V0, -1)`
			`}`
			`}`
			`containsSign := containsQuery.ContainsVertex()`
			`if containsSign == 0 {`
			`return ref, false // There are no unmatched edges incident to this vertex.`
			`}`
			`ref.Point = vTest`
			`ref.Contained = containsSign > 0`

			`return ref, true`
			`}`

			`// containsBruteForce reports whether the given shape contains the given point.`
			`// Most clients should not use this method, since its running time is linear in`
			`// the number of shape edges. Instead clients should create a ShapeIndex and use`
			`// ContainsPointQuery, since this strategy is much more efficient when many`
			`// points need to be tested.`
			`//`
			`// Polygon boundaries are treated as being semi-open (see ContainsPointQuery`
			`// and VertexModel for other options).`
			`func containsBruteForce(shape Shape, point Point) bool {`
			`if shape.Dimension() != 2 {`
			`return false`
			`}`

			`refPoint := shape.ReferencePoint()`
			`if refPoint.Point == point {`
			`return refPoint.Contained`
			`}`

			`crosser := NewEdgeCrosser(refPoint.Point, point)`
			`inside := refPoint.Contained`
			`for e := 0; e < shape.NumEdges(); e++ {`
			`edge := shape.Edge(e)`
			`inside = inside != crosser.EdgeOrVertexCrossing(edge.V0, edge.V1)`
			`}`
			`return inside`
			`}`