gotosocial/vendor/github.com/golang/geo/r1/interval.go
kim 94e87610c4
[chore] add back exif-terminator and use only for jpeg,png,webp (#3161)
* add back exif-terminator and use only for jpeg,png,webp

* fix arguments passed to terminateExif()

* pull in latest exif-terminator

* fix test

* update processed img

---------

Co-authored-by: tobi <tobi.smethurst@protonmail.com>
2024-08-02 12:46:41 +01:00

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// Copyright 2014 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 r1
import (
"fmt"
"math"
)
// Interval represents a closed interval on .
// Zero-length intervals (where Lo == Hi) represent single points.
// If Lo > Hi then the interval is empty.
type Interval struct {
Lo, Hi float64
}
// EmptyInterval returns an empty interval.
func EmptyInterval() Interval { return Interval{1, 0} }
// IntervalFromPoint returns an interval representing a single point.
func IntervalFromPoint(p float64) Interval { return Interval{p, p} }
// IsEmpty reports whether the interval is empty.
func (i Interval) IsEmpty() bool { return i.Lo > i.Hi }
// Equal returns true iff the interval contains the same points as oi.
func (i Interval) Equal(oi Interval) bool {
return i == oi || i.IsEmpty() && oi.IsEmpty()
}
// Center returns the midpoint of the interval.
// It is undefined for empty intervals.
func (i Interval) Center() float64 { return 0.5 * (i.Lo + i.Hi) }
// Length returns the length of the interval.
// The length of an empty interval is negative.
func (i Interval) Length() float64 { return i.Hi - i.Lo }
// Contains returns true iff the interval contains p.
func (i Interval) Contains(p float64) bool { return i.Lo <= p && p <= i.Hi }
// ContainsInterval returns true iff the interval contains oi.
func (i Interval) ContainsInterval(oi Interval) bool {
if oi.IsEmpty() {
return true
}
return i.Lo <= oi.Lo && oi.Hi <= i.Hi
}
// InteriorContains returns true iff the interval strictly contains p.
func (i Interval) InteriorContains(p float64) bool {
return i.Lo < p && p < i.Hi
}
// InteriorContainsInterval returns true iff the interval strictly contains oi.
func (i Interval) InteriorContainsInterval(oi Interval) bool {
if oi.IsEmpty() {
return true
}
return i.Lo < oi.Lo && oi.Hi < i.Hi
}
// Intersects returns true iff the interval contains any points in common with oi.
func (i Interval) Intersects(oi Interval) bool {
if i.Lo <= oi.Lo {
return oi.Lo <= i.Hi && oi.Lo <= oi.Hi // oi.Lo ∈ i and oi is not empty
}
return i.Lo <= oi.Hi && i.Lo <= i.Hi // i.Lo ∈ oi and i is not empty
}
// InteriorIntersects returns true iff the interior of the interval contains any points in common with oi, including the latter's boundary.
func (i Interval) InteriorIntersects(oi Interval) bool {
return oi.Lo < i.Hi && i.Lo < oi.Hi && i.Lo < i.Hi && oi.Lo <= oi.Hi
}
// Intersection returns the interval containing all points common to i and j.
func (i Interval) Intersection(j Interval) Interval {
// Empty intervals do not need to be special-cased.
return Interval{
Lo: math.Max(i.Lo, j.Lo),
Hi: math.Min(i.Hi, j.Hi),
}
}
// AddPoint returns the interval expanded so that it contains the given point.
func (i Interval) AddPoint(p float64) Interval {
if i.IsEmpty() {
return Interval{p, p}
}
if p < i.Lo {
return Interval{p, i.Hi}
}
if p > i.Hi {
return Interval{i.Lo, p}
}
return i
}
// ClampPoint returns the closest point in the interval to the given point "p".
// The interval must be non-empty.
func (i Interval) ClampPoint(p float64) float64 {
return math.Max(i.Lo, math.Min(i.Hi, p))
}
// Expanded returns an interval that has been expanded on each side by margin.
// If margin is negative, then the function shrinks the interval on
// each side by margin instead. The resulting interval may be empty. Any
// expansion of an empty interval remains empty.
func (i Interval) Expanded(margin float64) Interval {
if i.IsEmpty() {
return i
}
return Interval{i.Lo - margin, i.Hi + margin}
}
// Union returns the smallest interval that contains this interval and the given interval.
func (i Interval) Union(other Interval) Interval {
if i.IsEmpty() {
return other
}
if other.IsEmpty() {
return i
}
return Interval{math.Min(i.Lo, other.Lo), math.Max(i.Hi, other.Hi)}
}
func (i Interval) String() string { return fmt.Sprintf("[%.7f, %.7f]", i.Lo, i.Hi) }
const (
// epsilon is a small number that represents a reasonable level of noise between two
// values that can be considered to be equal.
epsilon = 1e-15
// dblEpsilon is a smaller number for values that require more precision.
// This is the C++ DBL_EPSILON equivalent.
dblEpsilon = 2.220446049250313e-16
)
// ApproxEqual reports whether the interval can be transformed into the
// given interval by moving each endpoint a small distance.
// The empty interval is considered to be positioned arbitrarily on the
// real line, so any interval with a small enough length will match
// the empty interval.
func (i Interval) ApproxEqual(other Interval) bool {
if i.IsEmpty() {
return other.Length() <= 2*epsilon
}
if other.IsEmpty() {
return i.Length() <= 2*epsilon
}
return math.Abs(other.Lo-i.Lo) <= epsilon &&
math.Abs(other.Hi-i.Hi) <= epsilon
}
// DirectedHausdorffDistance returns the Hausdorff distance to the given interval. For two
// intervals x and y, this distance is defined as
// h(x, y) = max_{p in x} min_{q in y} d(p, q).
func (i Interval) DirectedHausdorffDistance(other Interval) float64 {
if i.IsEmpty() {
return 0
}
if other.IsEmpty() {
return math.Inf(1)
}
return math.Max(0, math.Max(i.Hi-other.Hi, other.Lo-i.Lo))
}