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package dnmshared
import (
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. "dnmshared/sharedprotos"
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"fmt"
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"github.com/kvartborg/vector"
"github.com/solarlune/resolv"
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"math"
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"strings"
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)
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func ConvexPolygonStr ( body * resolv . ConvexPolygon ) string {
var s [ ] string = make ( [ ] string , len ( body . Points ) )
for i , p := range body . Points {
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s [ i ] = fmt . Sprintf ( "[%.2f, %.2f]" , p [ 0 ] + body . X , p [ 1 ] + body . Y )
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}
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return fmt . Sprintf ( "{\n%s\n}" , strings . Join ( s , ",\n" ) )
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}
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func RectCenterStr ( body * resolv . Object , halfBoundingW , halfBoundingH , topPadding , bottomPadding , leftPadding , rightPadding , spaceOffsetX , spaceOffsetY float64 ) string {
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return fmt . Sprintf ( "{%.2f, %.2f}" , body . X + leftPadding + halfBoundingW - spaceOffsetX , body . Y + bottomPadding + halfBoundingH - spaceOffsetY )
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}
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func GenerateRectCollider ( wx , wy , w , h , topPadding , bottomPadding , leftPadding , rightPadding , spaceOffsetX , spaceOffsetY float64 , data interface { } , tag string ) * resolv . Object {
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blX , blY := WorldToPolygonColliderBLPos ( wx , wy , w * 0.5 , h * 0.5 , topPadding , bottomPadding , leftPadding , rightPadding , spaceOffsetX , spaceOffsetY )
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return generateRectColliderInCollisionSpace ( blX , blY , leftPadding + w + rightPadding , bottomPadding + h + topPadding , data , tag )
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}
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func generateRectColliderInCollisionSpace ( blX , blY , w , h float64 , data interface { } , tag string ) * resolv . Object {
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collider := resolv . NewObject ( blX , blY , w , h , tag ) // Unlike its frontend counter part, the position of a "resolv.Object" must be specified by "bottom-left point" because "w" and "h" must be positive, see "resolv.Object.BoundsToSpace" for details
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shape := resolv . NewRectangle ( 0 , 0 , w , h )
collider . SetShape ( shape )
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collider . Data = data
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return collider
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}
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func GenerateConvexPolygonCollider ( unalignedSrc * Polygon2D , spaceOffsetX , spaceOffsetY float64 , data interface { } , tag string ) * resolv . Object {
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aligned := AlignPolygon2DToBoundingBox ( unalignedSrc )
var w , h float64 = 0 , 0
shape := resolv . NewConvexPolygon ( )
for i , pi := range aligned . Points {
for j , pj := range aligned . Points {
if i == j {
continue
}
if math . Abs ( pj . X - pi . X ) > w {
w = math . Abs ( pj . X - pi . X )
}
if math . Abs ( pj . Y - pi . Y ) > h {
h = math . Abs ( pj . Y - pi . Y )
}
}
}
for i := 0 ; i < len ( aligned . Points ) ; i ++ {
p := aligned . Points [ i ]
shape . AddPoints ( p . X , p . Y )
}
collider := resolv . NewObject ( aligned . Anchor . X + spaceOffsetX , aligned . Anchor . Y + spaceOffsetY , w , h , tag )
collider . SetShape ( shape )
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collider . Data = data
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return collider
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}
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func CalcPushbacks ( oldDx , oldDy float64 , playerShape , barrierShape * resolv . ConvexPolygon ) ( bool , float64 , float64 , * SatResult ) {
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origX , origY := playerShape . Position ( )
defer func ( ) {
playerShape . SetPosition ( origX , origY )
} ( )
playerShape . SetPosition ( origX + oldDx , origY + oldDy )
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overlapResult := & SatResult {
Overlap : 0 ,
OverlapX : 0 ,
OverlapY : 0 ,
AContainedInB : true ,
BContainedInA : true ,
Axis : vector . Vector { 0 , 0 } ,
}
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if overlapped := isPolygonPairOverlapped ( playerShape , barrierShape , overlapResult ) ; overlapped {
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pushbackX , pushbackY := overlapResult . Overlap * overlapResult . OverlapX , overlapResult . Overlap * overlapResult . OverlapY
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return true , pushbackX , pushbackY , overlapResult
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} else {
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return false , 0 , 0 , overlapResult
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}
}
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type SatResult struct {
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Overlap float64
OverlapX float64
OverlapY float64
AContainedInB bool
BContainedInA bool
Axis vector . Vector
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}
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func isPolygonPairOverlapped ( a , b * resolv . ConvexPolygon , result * SatResult ) bool {
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aCnt , bCnt := len ( a . Points ) , len ( b . Points )
// Single point case
if 1 == aCnt && 1 == bCnt {
if nil != result {
result . Overlap = 0
}
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return a . Points [ 0 ] [ 0 ] == b . Points [ 0 ] [ 0 ] && a . Points [ 0 ] [ 1 ] == b . Points [ 0 ] [ 1 ]
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}
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//Logger.Info(fmt.Sprintf("Checking collision between a=%v, b=%v", ConvexPolygonStr(a), ConvexPolygonStr(b)))
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if 1 < aCnt {
for _ , axis := range a . SATAxes ( ) {
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if isPolygonPairSeparatedByDir ( a , b , axis . Unit ( ) , result ) {
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return false
}
}
}
if 1 < bCnt {
for _ , axis := range b . SATAxes ( ) {
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if isPolygonPairSeparatedByDir ( a , b , axis . Unit ( ) , result ) {
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return false
}
}
}
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//Logger.Info(fmt.Sprintf("a=%v and b=%v are overlapped", ConvexPolygonStr(a), ConvexPolygonStr(b)))
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return true
}
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func isPolygonPairSeparatedByDir ( a , b * resolv . ConvexPolygon , e vector . Vector , result * SatResult ) bool {
/ *
[ WARNING ] This function is deliberately made private , it shouldn ' t be used alone ( i . e . not along the norms of a polygon ) , otherwise the pushbacks calculated would be meaningless .
Consider the following example
a : {
anchor : [ 1337.19 1696.74 ]
points : [ [ 0 0 ] [ 24 0 ] [ 24 24 ] [ 0 24 ] ]
} ,
b : {
anchor : [ 1277.72 1570.56 ]
points : [ [ 642.57 319.16 ] [ 0 319.16 ] [ 5.73 0 ] [ 643.75 0.90 ] ]
}
e = ( - 2.98 , 1.49 ) . Unit ( )
* /
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//Logger.Info(fmt.Sprintf("Checking separation between a=%v, b=%v along axis e={%.3f, %.3f}#1", ConvexPolygonStr(a), ConvexPolygonStr(b), e[0], e[1]))
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var aStart , aEnd , bStart , bEnd float64 = math . MaxFloat64 , - math . MaxFloat64 , math . MaxFloat64 , - math . MaxFloat64
for _ , p := range a . Points {
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dot := ( p [ 0 ] + a . X ) * e [ 0 ] + ( p [ 1 ] + a . Y ) * e [ 1 ]
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if aStart > dot {
aStart = dot
}
if aEnd < dot {
aEnd = dot
}
}
for _ , p := range b . Points {
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dot := ( p [ 0 ] + b . X ) * e [ 0 ] + ( p [ 1 ] + b . Y ) * e [ 1 ]
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if bStart > dot {
bStart = dot
}
if bEnd < dot {
bEnd = dot
}
}
if aStart > bEnd || aEnd < bStart {
// Separated by unit vector "e"
return true
}
if nil != result {
overlap := float64 ( 0 )
if aStart < bStart {
result . AContainedInB = false
if aEnd < bEnd {
overlap = aEnd - bStart
result . BContainedInA = false
} else {
option1 := aEnd - bStart
option2 := bEnd - aStart
if option1 < option2 {
overlap = option1
} else {
overlap = - option2
}
}
} else {
result . BContainedInA = false
if aEnd > bEnd {
overlap = aStart - bEnd
result . AContainedInB = false
} else {
option1 := aEnd - bStart
option2 := bEnd - aStart
if option1 < option2 {
overlap = option1
} else {
overlap = - option2
}
}
}
currentOverlap := result . Overlap
absoluteOverlap := overlap
if overlap < 0 {
absoluteOverlap = - overlap
}
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if ( 0 == result . Axis [ 0 ] && 0 == result . Axis [ 1 ] ) || currentOverlap > absoluteOverlap {
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var sign float64 = 1
if overlap < 0 {
sign = - 1
}
result . Overlap = absoluteOverlap
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result . OverlapX = e [ 0 ] * sign
result . OverlapY = e [ 1 ] * sign
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}
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result . Axis = e
//Logger.Info(fmt.Sprintf("Checking separation between a=%v, b=%v along axis e={%.3f, %.3f}#2: aStart=%.3f, aEnd=%.3f, bStart=%.3f, bEnd=%.3f, overlap=%.3f, currentOverlap=%.3f, absoluteOverlap=%.3f, result=%v", ConvexPolygonStr(a), ConvexPolygonStr(b), e[0], e[1], aStart, aEnd, bStart, bEnd, overlap, currentOverlap, absoluteOverlap, result))
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}
// the specified unit vector "e" doesn't separate "a" and "b", overlap result is generated
return false
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}
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func WorldToVirtualGridPos ( wx , wy , worldToVirtualGridRatio float64 ) ( int32 , int32 ) {
// [WARNING] Introduces loss of precision!
// In JavaScript floating numbers suffer from seemingly non-deterministic arithmetics, and even if certain libs solved this issue by approaches such as fixed-point-number, they might not be used in other libs -- e.g. the "collision libs" we're interested in -- thus couldn't kill all pains.
var virtualGridX int32 = int32 ( math . Round ( wx * worldToVirtualGridRatio ) )
var virtualGridY int32 = int32 ( math . Round ( wy * worldToVirtualGridRatio ) )
return virtualGridX , virtualGridY
}
func VirtualGridToWorldPos ( vx , vy int32 , virtualGridToWorldRatio float64 ) ( float64 , float64 ) {
// No loss of precision
var wx float64 = float64 ( vx ) * virtualGridToWorldRatio
var wy float64 = float64 ( vy ) * virtualGridToWorldRatio
return wx , wy
}
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func WorldToPolygonColliderBLPos ( wx , wy , halfBoundingW , halfBoundingH , topPadding , bottomPadding , leftPadding , rightPadding , collisionSpaceOffsetX , collisionSpaceOffsetY float64 ) ( float64 , float64 ) {
return wx - halfBoundingW - leftPadding + collisionSpaceOffsetX , wy - halfBoundingH - bottomPadding + collisionSpaceOffsetY
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}
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func PolygonColliderBLToWorldPos ( cx , cy , halfBoundingW , halfBoundingH , topPadding , bottomPadding , leftPadding , rightPadding , collisionSpaceOffsetX , collisionSpaceOffsetY float64 ) ( float64 , float64 ) {
return cx + halfBoundingW + leftPadding - collisionSpaceOffsetX , cy + halfBoundingH + bottomPadding - collisionSpaceOffsetY
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}
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func PolygonColliderBLToVirtualGridPos ( cx , cy , halfBoundingW , halfBoundingH , topPadding , bottomPadding , leftPadding , rightPadding , collisionSpaceOffsetX , collisionSpaceOffsetY float64 , worldToVirtualGridRatio float64 ) ( int32 , int32 ) {
wx , wy := PolygonColliderBLToWorldPos ( cx , cy , halfBoundingW , halfBoundingH , topPadding , bottomPadding , leftPadding , rightPadding , collisionSpaceOffsetX , collisionSpaceOffsetY )
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return WorldToVirtualGridPos ( wx , wy , worldToVirtualGridRatio )
}
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func VirtualGridToPolygonColliderBLPos ( vx , vy int32 , halfBoundingW , halfBoundingH , topPadding , bottomPadding , leftPadding , rightPadding , collisionSpaceOffsetX , collisionSpaceOffsetY float64 , virtualGridToWorldRatio float64 ) ( float64 , float64 ) {
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wx , wy := VirtualGridToWorldPos ( vx , vy , virtualGridToWorldRatio )
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return WorldToPolygonColliderBLPos ( wx , wy , halfBoundingW , halfBoundingH , topPadding , bottomPadding , leftPadding , rightPadding , collisionSpaceOffsetX , collisionSpaceOffsetY )
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}