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204 lines
8 KiB
Go
204 lines
8 KiB
Go
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// Copyright 2018 Google Inc. All rights reserved.
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//
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// Licensed under the Apache License, Version 2.0 (the "License");
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// you may not use this file except in compliance with the License.
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// You may obtain a copy of the License at
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//
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// http://www.apache.org/licenses/LICENSE-2.0
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//
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// Unless required by applicable law or agreed to in writing, software
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// distributed under the License is distributed on an "AS IS" BASIS,
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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// See the License for the specific language governing permissions and
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// limitations under the License.
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package s2
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import (
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"math"
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"github.com/golang/geo/r2"
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"github.com/golang/geo/s1"
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)
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// Projection defines an interface for different ways of mapping between s2 and r2 Points.
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// It can also define the coordinate wrapping behavior along each axis.
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type Projection interface {
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// Project converts a point on the sphere to a projected 2D point.
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Project(p Point) r2.Point
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// Unproject converts a projected 2D point to a point on the sphere.
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//
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// If wrapping is defined for a given axis (see below), then this method
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// should accept any real number for the corresponding coordinate.
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Unproject(p r2.Point) Point
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// FromLatLng is a convenience function equivalent to Project(LatLngToPoint(ll)),
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// but the implementation is more efficient.
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FromLatLng(ll LatLng) r2.Point
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// ToLatLng is a convenience function equivalent to LatLngFromPoint(Unproject(p)),
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// but the implementation is more efficient.
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ToLatLng(p r2.Point) LatLng
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// Interpolate returns the point obtained by interpolating the given
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// fraction of the distance along the line from A to B.
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// Fractions < 0 or > 1 result in extrapolation instead.
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Interpolate(f float64, a, b r2.Point) r2.Point
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// WrapDistance reports the coordinate wrapping distance along each axis.
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// If this value is non-zero for a given axis, the coordinates are assumed
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// to "wrap" with the given period. For example, if WrapDistance.Y == 360
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// then (x, y) and (x, y + 360) should map to the same Point.
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//
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// This information is used to ensure that edges takes the shortest path
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// between two given points. For example, if coordinates represent
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// (latitude, longitude) pairs in degrees and WrapDistance().Y == 360,
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// then the edge (5:179, 5:-179) would be interpreted as spanning 2 degrees
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// of longitude rather than 358 degrees.
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//
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// If a given axis does not wrap, its WrapDistance should be set to zero.
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WrapDistance() r2.Point
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}
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// PlateCarreeProjection defines the "plate carree" (square plate) projection,
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// which converts points on the sphere to (longitude, latitude) pairs.
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// Coordinates can be scaled so that they represent radians, degrees, etc, but
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// the projection is always centered around (latitude=0, longitude=0).
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//
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// Note that (x, y) coordinates are backwards compared to the usual (latitude,
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// longitude) ordering, in order to match the usual convention for graphs in
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// which "x" is horizontal and "y" is vertical.
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type PlateCarreeProjection struct {
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xWrap float64
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toRadians float64 // Multiplier to convert coordinates to radians.
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fromRadians float64 // Multiplier to convert coordinates from radians.
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}
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// NewPlateCarreeProjection constructs a plate carree projection where the
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// x-coordinates (lng) span [-xScale, xScale] and the y coordinates (lat)
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// span [-xScale/2, xScale/2]. For example if xScale==180 then the x
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// range is [-180, 180] and the y range is [-90, 90].
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//
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// By default coordinates are expressed in radians, i.e. the x range is
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// [-Pi, Pi] and the y range is [-Pi/2, Pi/2].
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func NewPlateCarreeProjection(xScale float64) Projection {
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return &PlateCarreeProjection{
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xWrap: 2 * xScale,
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toRadians: math.Pi / xScale,
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fromRadians: xScale / math.Pi,
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}
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}
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// Project converts a point on the sphere to a projected 2D point.
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func (p *PlateCarreeProjection) Project(pt Point) r2.Point {
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return p.FromLatLng(LatLngFromPoint(pt))
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}
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// Unproject converts a projected 2D point to a point on the sphere.
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func (p *PlateCarreeProjection) Unproject(pt r2.Point) Point {
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return PointFromLatLng(p.ToLatLng(pt))
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}
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// FromLatLng returns the LatLng projected into an R2 Point.
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func (p *PlateCarreeProjection) FromLatLng(ll LatLng) r2.Point {
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return r2.Point{
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X: p.fromRadians * ll.Lng.Radians(),
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Y: p.fromRadians * ll.Lat.Radians(),
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}
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}
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// ToLatLng returns the LatLng projected from the given R2 Point.
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func (p *PlateCarreeProjection) ToLatLng(pt r2.Point) LatLng {
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return LatLng{
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Lat: s1.Angle(p.toRadians * pt.Y),
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Lng: s1.Angle(p.toRadians * math.Remainder(pt.X, p.xWrap)),
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}
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}
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// Interpolate returns the point obtained by interpolating the given
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// fraction of the distance along the line from A to B.
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func (p *PlateCarreeProjection) Interpolate(f float64, a, b r2.Point) r2.Point {
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return a.Mul(1 - f).Add(b.Mul(f))
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}
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// WrapDistance reports the coordinate wrapping distance along each axis.
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func (p *PlateCarreeProjection) WrapDistance() r2.Point {
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return r2.Point{p.xWrap, 0}
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}
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// MercatorProjection defines the spherical Mercator projection. Google Maps
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// uses this projection together with WGS84 coordinates, in which case it is
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// known as the "Web Mercator" projection (see Wikipedia). This class makes
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// no assumptions regarding the coordinate system of its input points, but
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// simply applies the spherical Mercator projection to them.
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//
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// The Mercator projection is finite in width (x) but infinite in height (y).
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// "x" corresponds to longitude, and spans a finite range such as [-180, 180]
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// (with coordinate wrapping), while "y" is a function of latitude and spans
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// an infinite range. (As "y" coordinates get larger, points get closer to
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// the north pole but never quite reach it.) The north and south poles have
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// infinite "y" values. (Note that this will cause problems if you tessellate
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// a Mercator edge where one endpoint is a pole. If you need to do this, clip
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// the edge first so that the "y" coordinate is no more than about 5 * maxX.)
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type MercatorProjection struct {
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xWrap float64
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toRadians float64 // Multiplier to convert coordinates to radians.
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fromRadians float64 // Multiplier to convert coordinates from radians.
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}
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// NewMercatorProjection constructs a Mercator projection with the given maximum
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// longitude axis value corresponding to a range of [-maxLng, maxLng].
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// The horizontal and vertical axes are scaled equally.
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func NewMercatorProjection(maxLng float64) Projection {
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return &MercatorProjection{
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xWrap: 2 * maxLng,
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toRadians: math.Pi / maxLng,
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fromRadians: maxLng / math.Pi,
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}
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}
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// Project converts a point on the sphere to a projected 2D point.
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func (p *MercatorProjection) Project(pt Point) r2.Point {
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return p.FromLatLng(LatLngFromPoint(pt))
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}
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// Unproject converts a projected 2D point to a point on the sphere.
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func (p *MercatorProjection) Unproject(pt r2.Point) Point {
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return PointFromLatLng(p.ToLatLng(pt))
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}
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// FromLatLng returns the LatLng projected into an R2 Point.
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func (p *MercatorProjection) FromLatLng(ll LatLng) r2.Point {
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// This formula is more accurate near zero than the log(tan()) version.
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// Note that latitudes of +/- 90 degrees yield "y" values of +/- infinity.
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sinPhi := math.Sin(float64(ll.Lat))
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y := 0.5 * math.Log((1+sinPhi)/(1-sinPhi))
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return r2.Point{p.fromRadians * float64(ll.Lng), p.fromRadians * y}
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}
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// ToLatLng returns the LatLng projected from the given R2 Point.
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func (p *MercatorProjection) ToLatLng(pt r2.Point) LatLng {
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// This formula is more accurate near zero than the atan(exp()) version.
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x := p.toRadians * math.Remainder(pt.X, p.xWrap)
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k := math.Exp(2 * p.toRadians * pt.Y)
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var y float64
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if math.IsInf(k, 0) {
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y = math.Pi / 2
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} else {
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y = math.Asin((k - 1) / (k + 1))
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}
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return LatLng{s1.Angle(y), s1.Angle(x)}
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}
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// Interpolate returns the point obtained by interpolating the given
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// fraction of the distance along the line from A to B.
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func (p *MercatorProjection) Interpolate(f float64, a, b r2.Point) r2.Point {
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return a.Mul(1 - f).Add(b.Mul(f))
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}
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// WrapDistance reports the coordinate wrapping distance along each axis.
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func (p *MercatorProjection) WrapDistance() r2.Point {
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return r2.Point{p.xWrap, 0}
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}
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