GoToSocial/vendor/github.com/golang/geo/s2/distance_target.go

150 lines
6.6 KiB
Go
Raw Normal View History

// Copyright 2019 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
import (
"github.com/golang/geo/s1"
)
// The distance interface represents a set of common methods used by algorithms
// that compute distances between various S2 types.
type distance interface {
// chordAngle returns this type as a ChordAngle.
chordAngle() s1.ChordAngle
// fromChordAngle is used to type convert a ChordAngle to this type.
// This is to work around needing to be clever in parts of the code
// where a distanceTarget interface method expects distances, but the
// user only supplies a ChordAngle, and we need to dynamically cast it
// to an appropriate distance interface types.
fromChordAngle(o s1.ChordAngle) distance
// zero returns a zero distance.
zero() distance
// negative returns a value smaller than any valid value.
negative() distance
// infinity returns a value larger than any valid value.
infinity() distance
// less is similar to the Less method in Sort. To get minimum values,
// this would be a less than type operation. For maximum, this would
// be a greater than type operation.
less(other distance) bool
// sub subtracts the other value from this one and returns the new value.
// This is done as a method and not simple mathematical operation to
// allow closest and furthest to implement this in opposite ways.
sub(other distance) distance
// chordAngleBound reports the upper bound on a ChordAngle corresponding
// to this distance. For example, if distance measures WGS84 ellipsoid
// distance then the corresponding angle needs to be 0.56% larger.
chordAngleBound() s1.ChordAngle
// updateDistance may update the value this distance represents
// based on the given input. The updated value and a boolean reporting
// if the value was changed are returned.
updateDistance(other distance) (distance, bool)
}
// distanceTarget is an interface that represents a geometric type to which distances
// are measured.
//
// For example, there are implementations that measure distances to a Point,
// an Edge, a Cell, a CellUnion, and even to an arbitrary collection of geometry
// stored in ShapeIndex.
//
// The distanceTarget types are provided for the benefit of types that measure
// distances and/or find nearby geometry, such as ClosestEdgeQuery, FurthestEdgeQuery,
// ClosestPointQuery, and ClosestCellQuery, etc.
type distanceTarget interface {
// capBound returns a Cap that bounds the set of points whose distance to the
// target is distance.zero().
capBound() Cap
// updateDistanceToPoint updates the distance if the distance to
// the point P is within than the given dist.
// The boolean reports if the value was updated.
updateDistanceToPoint(p Point, dist distance) (distance, bool)
// updateDistanceToEdge updates the distance if the distance to
// the edge E is within than the given dist.
// The boolean reports if the value was updated.
updateDistanceToEdge(e Edge, dist distance) (distance, bool)
// updateDistanceToCell updates the distance if the distance to the cell C
// (including its interior) is within than the given dist.
// The boolean reports if the value was updated.
updateDistanceToCell(c Cell, dist distance) (distance, bool)
// setMaxError potentially updates the value of MaxError, and reports if
// the specific type supports altering it. Whenever one of the
// updateDistanceTo... methods above returns true, the returned distance
// is allowed to be up to maxError larger than the true minimum distance.
// In other words, it gives this target object permission to terminate its
// distance calculation as soon as it has determined that (1) the minimum
// distance is less than minDist and (2) the best possible further
// improvement is less than maxError.
//
// If the target takes advantage of maxError to optimize its distance
// calculation, this method must return true. (Most target types will
// default to return false.)
setMaxError(maxErr s1.ChordAngle) bool
// maxBruteForceIndexSize reports the maximum number of indexed objects for
// which it is faster to compute the distance by brute force (e.g., by testing
// every edge) rather than by using an index.
//
// The following method is provided as a convenience for types that compute
// distances to a collection of indexed geometry, such as ClosestEdgeQuery
// and ClosestPointQuery.
//
// Types that do not support this should return a -1.
maxBruteForceIndexSize() int
// distance returns an instance of the underlying distance type this
// target uses. This is to work around the use of Templates in the C++.
distance() distance
// visitContainingShapes finds all polygons in the given index that
// completely contain a connected component of the target geometry. (For
// example, if the target consists of 10 points, this method finds
// polygons that contain any of those 10 points.) For each such polygon,
// the visit function is called with the Shape of the polygon along with
// a point of the target geometry that is contained by that polygon.
//
// Optionally, any polygon that intersects the target geometry may also be
// returned. In other words, this method returns all polygons that
// contain any connected component of the target, along with an arbitrary
// subset of the polygons that intersect the target.
//
// For example, suppose that the index contains two abutting polygons
// A and B. If the target consists of two points "a" contained by A and
// "b" contained by B, then both A and B are returned. But if the target
// consists of the edge "ab", then any subset of {A, B} could be returned
// (because both polygons intersect the target but neither one contains
// the edge "ab").
//
// If the visit function returns false, this method terminates early and
// returns false as well. Otherwise returns true.
//
// NOTE(roberts): This method exists only for the purpose of implementing
// edgeQuery IncludeInteriors efficiently.
visitContainingShapes(index *ShapeIndex, v shapePointVisitorFunc) bool
}
// shapePointVisitorFunc defines a type of function the visitContainingShapes can call.
type shapePointVisitorFunc func(containingShape Shape, targetPoint Point) bool