DelayNoMore/jsexport/battle/battle.go

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package battle
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import (
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"math"
"resolv"
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)
const (
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MAX_FLOAT64 = 1.7e+308
MAX_INT32 = int32(999999999)
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COLLISION_PLAYER_INDEX_PREFIX = (1 << 17)
COLLISION_BARRIER_INDEX_PREFIX = (1 << 16)
COLLISION_BULLET_INDEX_PREFIX = (1 << 15)
PATTERN_ID_UNABLE_TO_OP = -2
PATTERN_ID_NO_OP = -1
WORLD_TO_VIRTUAL_GRID_RATIO = float64(100)
VIRTUAL_GRID_TO_WORLD_RATIO = float64(1.0) / WORLD_TO_VIRTUAL_GRID_RATIO
GRAVITY_X = int32(0)
GRAVITY_Y = -int32(float64(0.5) * WORLD_TO_VIRTUAL_GRID_RATIO) // makes all "playerCollider.Y" a multiple of 0.5 in all cases
INPUT_DELAY_FRAMES = int32(8) // in the count of render frames
INPUT_SCALE_FRAMES = uint32(2) // inputDelayedAndScaledFrameId = ((originalFrameId - InputDelayFrames) >> InputScaleFrames)
NST_DELAY_FRAMES = int32(16) // network-single-trip delay in the count of render frames, proposed to be (InputDelayFrames >> 1) because we expect a round-trip delay to be exactly "InputDelayFrames"
SP_ATK_LOOKUP_FRAMES = int32(5)
SNAP_INTO_PLATFORM_OVERLAP = float64(0.1)
SNAP_INTO_PLATFORM_THRESHOLD = float64(0.5)
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NO_SKILL = -1
NO_SKILL_HIT = -1
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NO_LOCK_VEL = int32(-1)
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)
// These directions are chosen such that when speed is changed to "(speedX+delta, speedY+delta)" for any of them, the direction is unchanged.
var DIRECTION_DECODER = [][]int32{
{0, 0},
{0, +2},
{0, -2},
{+2, 0},
{-2, 0},
{+1, +1},
{-1, -1},
{+1, -1},
{-1, +1},
}
const (
ATK_CHARACTER_STATE_IDLE1 = int32(0)
ATK_CHARACTER_STATE_WALKING = int32(1)
ATK_CHARACTER_STATE_ATK1 = int32(2)
ATK_CHARACTER_STATE_ATKED1 = int32(3)
ATK_CHARACTER_STATE_INAIR_IDLE1_NO_JUMP = int32(4)
ATK_CHARACTER_STATE_INAIR_IDLE1_BY_JUMP = int32(5)
ATK_CHARACTER_STATE_INAIR_ATK1 = int32(6)
ATK_CHARACTER_STATE_INAIR_ATKED1 = int32(7)
ATK_CHARACTER_STATE_BLOWN_UP1 = int32(8)
ATK_CHARACTER_STATE_LAY_DOWN1 = int32(9)
ATK_CHARACTER_STATE_GET_UP1 = int32(10)
ATK_CHARACTER_STATE_ATK2 = int32(11)
ATK_CHARACTER_STATE_ATK3 = int32(12)
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ATK_CHARACTER_STATE_ATK4 = int32(13)
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)
var inAirSet = map[int32]bool{
ATK_CHARACTER_STATE_INAIR_IDLE1_NO_JUMP: true,
ATK_CHARACTER_STATE_INAIR_IDLE1_BY_JUMP: true,
ATK_CHARACTER_STATE_INAIR_ATK1: true,
ATK_CHARACTER_STATE_INAIR_ATKED1: true,
ATK_CHARACTER_STATE_BLOWN_UP1: true,
}
var noOpSet = map[int32]bool{
ATK_CHARACTER_STATE_ATKED1: true,
ATK_CHARACTER_STATE_INAIR_ATKED1: true,
ATK_CHARACTER_STATE_BLOWN_UP1: true,
ATK_CHARACTER_STATE_LAY_DOWN1: true,
// During the invinsible frames of GET_UP1, the player is allowed to take any action
}
var invinsibleSet = map[int32]bool{
ATK_CHARACTER_STATE_BLOWN_UP1: true,
ATK_CHARACTER_STATE_LAY_DOWN1: true,
ATK_CHARACTER_STATE_GET_UP1: true,
}
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var nonAttackingSet = map[int32]bool{
ATK_CHARACTER_STATE_IDLE1: true,
ATK_CHARACTER_STATE_WALKING: true,
ATK_CHARACTER_STATE_INAIR_IDLE1_NO_JUMP: true,
ATK_CHARACTER_STATE_INAIR_IDLE1_BY_JUMP: true,
ATK_CHARACTER_STATE_ATKED1: true,
ATK_CHARACTER_STATE_INAIR_ATKED1: true,
ATK_CHARACTER_STATE_BLOWN_UP1: true,
ATK_CHARACTER_STATE_LAY_DOWN1: true,
ATK_CHARACTER_STATE_GET_UP1: true,
}
func ShouldPrefabInputFrameDownsync(prevRenderFrameId int32, renderFrameId int32) (bool, int32) {
for i := prevRenderFrameId + 1; i <= renderFrameId; i++ {
if (0 <= i) && (0 == (i & ((1 << INPUT_SCALE_FRAMES) - 1))) {
return true, i
}
}
return false, -1
}
func ShouldGenerateInputFrameUpsync(renderFrameId int32) bool {
return ((renderFrameId & ((1 << INPUT_SCALE_FRAMES) - 1)) == 0)
}
func ConvertToDelayedInputFrameId(renderFrameId int32) int32 {
if renderFrameId < INPUT_DELAY_FRAMES {
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return 0
}
return ((renderFrameId - INPUT_DELAY_FRAMES) >> INPUT_SCALE_FRAMES)
}
func ConvertToNoDelayInputFrameId(renderFrameId int32) int32 {
return (renderFrameId >> INPUT_SCALE_FRAMES)
}
func ConvertToFirstUsedRenderFrameId(inputFrameId int32) int32 {
return ((inputFrameId << INPUT_SCALE_FRAMES) + INPUT_DELAY_FRAMES)
}
func ConvertToLastUsedRenderFrameId(inputFrameId int32) int32 {
return ((inputFrameId << INPUT_SCALE_FRAMES) + INPUT_DELAY_FRAMES + (1 << INPUT_SCALE_FRAMES) - 1)
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}
func decodeInput(encodedInput uint64) *InputFrameDecoded {
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encodedDirection := (encodedInput & uint64(15))
btnALevel := int32((encodedInput >> 4) & 1)
btnBLevel := int32((encodedInput >> 5) & 1)
return &InputFrameDecoded{
Dx: DIRECTION_DECODER[encodedDirection][0],
Dy: DIRECTION_DECODER[encodedDirection][1],
BtnALevel: btnALevel,
BtnBLevel: btnBLevel,
}
}
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type SatResult struct {
Overlap float64
OverlapX float64
OverlapY float64
AContainedInB bool
BContainedInA bool
Axis resolv.Vector
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}
func CalcPushbacks(oldDx, oldDy float64, playerShape, barrierShape *resolv.ConvexPolygon) (bool, float64, float64, *SatResult) {
origX, origY := playerShape.Position()
defer func() {
playerShape.SetPosition(origX, origY)
}()
playerShape.SetPosition(origX+oldDx, origY+oldDy)
overlapResult := &SatResult{
Overlap: 0,
OverlapX: 0,
OverlapY: 0,
AContainedInB: true,
BContainedInA: true,
Axis: resolv.Vector{0, 0},
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}
if overlapped := isPolygonPairOverlapped(playerShape, barrierShape, overlapResult); overlapped {
pushbackX, pushbackY := overlapResult.Overlap*overlapResult.OverlapX, overlapResult.Overlap*overlapResult.OverlapY
return true, pushbackX, pushbackY, overlapResult
} else {
return false, 0, 0, overlapResult
}
}
func isPolygonPairOverlapped(a, b *resolv.ConvexPolygon, result *SatResult) bool {
aCnt, bCnt := len(a.Points), len(b.Points)
// Single point case
if 1 == aCnt && 1 == bCnt {
if nil != result {
result.Overlap = 0
}
return a.Points[0][0] == b.Points[0][0] && a.Points[0][1] == b.Points[0][1]
}
if 1 < aCnt {
for _, axis := range a.SATAxes() {
if isPolygonPairSeparatedByDir(a, b, axis.Unit(), result) {
return false
}
}
}
if 1 < bCnt {
for _, axis := range b.SATAxes() {
if isPolygonPairSeparatedByDir(a, b, axis.Unit(), result) {
return false
}
}
}
return true
}
func isPolygonPairSeparatedByDir(a, b *resolv.ConvexPolygon, e resolv.Vector, result *SatResult) bool {
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/*
[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()
*/
var aStart, aEnd, bStart, bEnd float64 = MAX_FLOAT64, -MAX_FLOAT64, MAX_FLOAT64, -MAX_FLOAT64
for _, p := range a.Points {
dot := (p[0]+a.X)*e[0] + (p[1]+a.Y)*e[1]
if aStart > dot {
aStart = dot
}
if aEnd < dot {
aEnd = dot
}
}
for _, p := range b.Points {
dot := (p[0]+b.X)*e[0] + (p[1]+b.Y)*e[1]
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
}
if (0 == result.Axis[0] && 0 == result.Axis[1]) || currentOverlap > absoluteOverlap {
var sign float64 = 1
if overlap < 0 {
sign = -1
}
result.Overlap = absoluteOverlap
result.OverlapX = e[0] * sign
result.OverlapY = e[1] * sign
}
result.Axis = e
}
// the specified unit vector "e" doesn't separate "a" and "b", overlap result is generated
return false
}
func WorldToVirtualGridPos(wx, wy float64) (int32, int32) {
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// [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.Floor(wx * WORLD_TO_VIRTUAL_GRID_RATIO))
var virtualGridY int32 = int32(math.Floor(wy * WORLD_TO_VIRTUAL_GRID_RATIO))
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return virtualGridX, virtualGridY
}
func VirtualGridToWorldPos(vx, vy int32) (float64, float64) {
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// No loss of precision
var wx float64 = float64(vx) * VIRTUAL_GRID_TO_WORLD_RATIO
var wy float64 = float64(vy) * VIRTUAL_GRID_TO_WORLD_RATIO
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return wx, wy
}
func WorldToPolygonColliderBLPos(wx, wy, halfBoundingW, halfBoundingH, topPadding, bottomPadding, leftPadding, rightPadding, collisionSpaceOffsetX, collisionSpaceOffsetY float64) (float64, float64) {
return wx - halfBoundingW - leftPadding + collisionSpaceOffsetX, wy - halfBoundingH - bottomPadding + collisionSpaceOffsetY
}
func PolygonColliderBLToWorldPos(cx, cy, halfBoundingW, halfBoundingH, topPadding, bottomPadding, leftPadding, rightPadding, collisionSpaceOffsetX, collisionSpaceOffsetY float64) (float64, float64) {
return cx + halfBoundingW + leftPadding - collisionSpaceOffsetX, cy + halfBoundingH + bottomPadding - collisionSpaceOffsetY
}
func PolygonColliderBLToVirtualGridPos(cx, cy, halfBoundingW, halfBoundingH, topPadding, bottomPadding, leftPadding, rightPadding, collisionSpaceOffsetX, collisionSpaceOffsetY float64) (int32, int32) {
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wx, wy := PolygonColliderBLToWorldPos(cx, cy, halfBoundingW, halfBoundingH, topPadding, bottomPadding, leftPadding, rightPadding, collisionSpaceOffsetX, collisionSpaceOffsetY)
return WorldToVirtualGridPos(wx, wy)
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}
func VirtualGridToPolygonColliderBLPos(vx, vy int32, halfBoundingW, halfBoundingH, topPadding, bottomPadding, leftPadding, rightPadding, collisionSpaceOffsetX, collisionSpaceOffsetY float64) (float64, float64) {
wx, wy := VirtualGridToWorldPos(vx, vy)
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return WorldToPolygonColliderBLPos(wx, wy, halfBoundingW, halfBoundingH, topPadding, bottomPadding, leftPadding, rightPadding, collisionSpaceOffsetX, collisionSpaceOffsetY)
}
func calcHardPushbacksNorms(joinIndex int32, playerCollider *resolv.Object, playerShape *resolv.ConvexPolygon, snapIntoPlatformOverlap float64, pEffPushback *Vec2D) *[]Vec2D {
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ret := make([]Vec2D, 0, 10) // no one would simultaneously have more than 5 hardPushbacks
collision := playerCollider.Check(0, 0)
if nil == collision {
return &ret
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}
//playerColliderCenterX, playerColliderCenterY := playerCollider.Center()
//fmt.Printf("joinIndex=%d calcHardPushbacksNorms has non-empty collision;playerColliderPos=(%.2f,%.2f)\n", joinIndex, playerColliderCenterX, playerColliderCenterY)
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for _, obj := range collision.Objects {
isBarrier := false
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switch obj.Data.(type) {
case *PlayerDownsync:
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case *MeleeBullet, *FireballBullet:
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default:
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// By default it's a regular barrier, even if data is nil, note that Golang syntax of switch-case is kind of confusing, this "default" condition is met only if "!*PlayerDownsync && !*MeleeBullet && !*FireballBullet".
isBarrier = true
}
if !isBarrier {
continue
}
barrierShape := obj.Shape.(*resolv.ConvexPolygon)
overlapped, pushbackX, pushbackY, overlapResult := CalcPushbacks(0, 0, playerShape, barrierShape)
if !overlapped {
continue
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}
// ALWAY snap into hardPushbacks!
// [OverlapX, OverlapY] is the unit vector that points into the platform
pushbackX, pushbackY = (overlapResult.Overlap-snapIntoPlatformOverlap)*overlapResult.OverlapX, (overlapResult.Overlap-snapIntoPlatformOverlap)*overlapResult.OverlapY
ret = append(ret, Vec2D{X: overlapResult.OverlapX, Y: overlapResult.OverlapY})
pEffPushback.X += pushbackX
pEffPushback.Y += pushbackY
//fmt.Printf("joinIndex=%d calcHardPushbacksNorms found one hardpushback; immediatePushback=(%.2f,%.2f)\n", joinIndex, pushbackX, pushbackY)
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}
return &ret
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}
func deriveOpPattern(currPlayerDownsync, thatPlayerInNextFrame *PlayerDownsync, currRenderFrame *RoomDownsyncFrame, inputsBuffer *RingBuffer) (int, bool, int32, int32) {
// returns (patternId, jumpedOrNot, effectiveDx, effectiveDy)
delayedInputFrameId := ConvertToDelayedInputFrameId(currRenderFrame.Id)
delayedInputFrameIdForPrevRdf := ConvertToDelayedInputFrameId(currRenderFrame.Id - 1)
if 0 >= delayedInputFrameId {
return PATTERN_ID_UNABLE_TO_OP, false, 0, 0
}
if _, existent := noOpSet[currPlayerDownsync.CharacterState]; existent {
return PATTERN_ID_UNABLE_TO_OP, false, 0, 0
}
delayedInputList := inputsBuffer.GetByFrameId(delayedInputFrameId).(*InputFrameDownsync).InputList
var delayedInputListForPrevRdf []uint64 = nil
if 0 < delayedInputFrameIdForPrevRdf {
delayedInputListForPrevRdf = inputsBuffer.GetByFrameId(delayedInputFrameIdForPrevRdf).(*InputFrameDownsync).InputList
}
jumpedOrNot := false
joinIndex := currPlayerDownsync.JoinIndex
decodedInput := decodeInput(delayedInputList[joinIndex-1])
effDx, effDy := int32(0), int32(0)
prevBtnALevel, prevBtnBLevel := int32(0), int32(0)
if nil != delayedInputListForPrevRdf {
prevDecodedInput := decodeInput(delayedInputListForPrevRdf[joinIndex-1])
prevBtnALevel = prevDecodedInput.BtnALevel
prevBtnBLevel = prevDecodedInput.BtnBLevel
}
if 0 == currPlayerDownsync.FramesToRecover {
// Jumping and moving are only allowed here
effDx, effDy = decodedInput.Dx, decodedInput.Dy
if decodedInput.BtnBLevel > prevBtnBLevel {
if _, existent := inAirSet[currPlayerDownsync.CharacterState]; !existent {
jumpedOrNot = true
}
}
}
patternId := PATTERN_ID_NO_OP
if decodedInput.BtnALevel > prevBtnALevel {
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patternId = 1
}
return patternId, jumpedOrNot, effDx, effDy
}
// [WARNING] The params of this method is carefully tuned such that only "battle.RoomDownsyncFrame" is a necessary custom struct.
func ApplyInputFrameDownsyncDynamicsOnSingleRenderFrame(inputsBuffer *RingBuffer, currRenderFrame *RoomDownsyncFrame, collisionSys *resolv.Space, collisionSysMap map[int32]*resolv.Object, collisionSpaceOffsetX, collisionSpaceOffsetY float64, chConfigsOrderedByJoinIndex []*CharacterConfig) *RoomDownsyncFrame {
// [WARNING] On backend this function MUST BE called while "InputsBufferLock" is locked!
roomCapacity := len(currRenderFrame.PlayersArr)
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nextRenderFramePlayers := make([]*PlayerDownsync, roomCapacity)
// Make a copy first
for i, currPlayerDownsync := range currRenderFrame.PlayersArr {
nextRenderFramePlayers[i] = &PlayerDownsync{
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Id: currPlayerDownsync.Id,
VirtualGridX: currPlayerDownsync.VirtualGridX,
VirtualGridY: currPlayerDownsync.VirtualGridY,
DirX: currPlayerDownsync.DirX,
DirY: currPlayerDownsync.DirY,
VelX: currPlayerDownsync.VelX,
VelY: currPlayerDownsync.VelY,
CharacterState: currPlayerDownsync.CharacterState,
InAir: true,
Speed: currPlayerDownsync.Speed,
BattleState: currPlayerDownsync.BattleState,
Score: currPlayerDownsync.Score,
Removed: currPlayerDownsync.Removed,
JoinIndex: currPlayerDownsync.JoinIndex,
Hp: currPlayerDownsync.Hp,
MaxHp: currPlayerDownsync.MaxHp,
FramesToRecover: currPlayerDownsync.FramesToRecover - 1,
FramesInChState: currPlayerDownsync.FramesInChState + 1,
ActiveSkillId: currPlayerDownsync.ActiveSkillId,
ActiveSkillHit: currPlayerDownsync.ActiveSkillHit,
FramesInvinsible: currPlayerDownsync.FramesInvinsible - 1,
ColliderRadius: currPlayerDownsync.ColliderRadius,
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}
if nextRenderFramePlayers[i].FramesToRecover < 0 {
nextRenderFramePlayers[i].FramesToRecover = 0
}
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if nextRenderFramePlayers[i].FramesInvinsible < 0 {
nextRenderFramePlayers[i].FramesInvinsible = 0
}
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}
nextRenderFrameMeleeBullets := make([]*MeleeBullet, 0, len(currRenderFrame.MeleeBullets)) // Is there any better way to reduce malloc/free impact, e.g. smart prediction for fixed memory allocation?
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nextRenderFrameFireballBullets := make([]*FireballBullet, 0, len(currRenderFrame.FireballBullets))
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effPushbacks := make([]Vec2D, roomCapacity)
hardPushbackNorms := make([]*[]Vec2D, roomCapacity)
jumpedOrNotList := make([]bool, roomCapacity)
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bulletLocalId := currRenderFrame.BulletLocalIdCounter
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// 1. Process player inputs
for i, currPlayerDownsync := range currRenderFrame.PlayersArr {
jumpedOrNotList[i] = false
chConfig := chConfigsOrderedByJoinIndex[i]
thatPlayerInNextFrame := nextRenderFramePlayers[i]
patternId, jumpedOrNot, effDx, effDy := deriveOpPattern(currPlayerDownsync, thatPlayerInNextFrame, currRenderFrame, inputsBuffer)
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if jumpedOrNot {
thatPlayerInNextFrame.VelY = int32(chConfig.JumpingInitVelY)
jumpedOrNotList[i] = true
}
joinIndex := currPlayerDownsync.JoinIndex
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skillId := chConfig.SkillMapper(patternId, currPlayerDownsync)
if skillConfig, existent := skills[skillId]; existent {
thatPlayerInNextFrame.ActiveSkillId = int32(skillId)
thatPlayerInNextFrame.ActiveSkillHit = 0
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thatPlayerInNextFrame.FramesToRecover = skillConfig.RecoveryFrames
xfac := int32(1)
if 0 > thatPlayerInNextFrame.DirX {
xfac = -xfac
}
hasLockVel := false
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// Hardcoded to use only the first hit for now
switch v := skillConfig.Hits[thatPlayerInNextFrame.ActiveSkillHit].(type) {
case *MeleeBullet:
var newBullet MeleeBullet = *v // Copied primitive fields into an onstack variable
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newBullet.BulletLocalId = bulletLocalId
bulletLocalId++
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newBullet.OriginatedRenderFrameId = currRenderFrame.Id
newBullet.OffenderJoinIndex = joinIndex
nextRenderFrameMeleeBullets = append(nextRenderFrameMeleeBullets, &newBullet)
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if NO_LOCK_VEL != v.SelfLockVelX {
hasLockVel = true
thatPlayerInNextFrame.VelX = xfac * v.SelfLockVelX
}
if NO_LOCK_VEL != v.SelfLockVelY {
hasLockVel = true
thatPlayerInNextFrame.VelY = v.SelfLockVelY
}
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case *FireballBullet:
var newBullet FireballBullet = *v // Copied primitive fields into an onstack variable
newBullet.BulletLocalId = bulletLocalId
bulletLocalId++
xfac := int32(1)
if 0 > thatPlayerInNextFrame.DirX {
xfac = -xfac
}
newBullet.VirtualGridX, newBullet.VirtualGridY = currPlayerDownsync.VirtualGridX+xfac*newBullet.HitboxOffsetX, currPlayerDownsync.VirtualGridY
newBullet.OriginatedRenderFrameId = currRenderFrame.Id
newBullet.OffenderJoinIndex = joinIndex
newBullet.VelX = newBullet.Speed * xfac
newBullet.VelY = 0
nextRenderFrameFireballBullets = append(nextRenderFrameFireballBullets, &newBullet)
if NO_LOCK_VEL != v.SelfLockVelX {
hasLockVel = true
thatPlayerInNextFrame.VelX = xfac * v.SelfLockVelX
}
if NO_LOCK_VEL != v.SelfLockVelY {
hasLockVel = true
thatPlayerInNextFrame.VelY = v.SelfLockVelY
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}
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}
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if false == hasLockVel && false == currPlayerDownsync.InAir {
thatPlayerInNextFrame.VelX = 0
}
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thatPlayerInNextFrame.CharacterState = skillConfig.BoundChState
continue // Don't allow movement if skill is used
}
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if 0 == currPlayerDownsync.FramesToRecover {
if 0 != effDx || 0 != effDy {
thatPlayerInNextFrame.DirX, thatPlayerInNextFrame.DirY = effDx, effDy
thatPlayerInNextFrame.VelX = effDx * currPlayerDownsync.Speed
thatPlayerInNextFrame.CharacterState = ATK_CHARACTER_STATE_WALKING
} else {
thatPlayerInNextFrame.CharacterState = ATK_CHARACTER_STATE_IDLE1
thatPlayerInNextFrame.VelX = 0
}
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}
}
// 2. Process player movement
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playerColliders := make([]*resolv.Object, len(currRenderFrame.PlayersArr), len(currRenderFrame.PlayersArr)) // Will all be removed at the end of this function due to the need for being rollback-compatible
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for i, currPlayerDownsync := range currRenderFrame.PlayersArr {
joinIndex := currPlayerDownsync.JoinIndex
effPushbacks[joinIndex-1].X, effPushbacks[joinIndex-1].Y = float64(0), float64(0)
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chConfig := chConfigsOrderedByJoinIndex[i]
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// Reset playerCollider position from the "virtual grid position"
newVx, newVy := currPlayerDownsync.VirtualGridX+currPlayerDownsync.VelX, currPlayerDownsync.VirtualGridY+currPlayerDownsync.VelY
if jumpedOrNotList[i] {
newVy += chConfig.JumpingInitVelY // Immediately gets out of any snapping
}
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wx, wy := VirtualGridToWorldPos(newVx, newVy)
colliderWidth, colliderHeight := currPlayerDownsync.ColliderRadius*2, currPlayerDownsync.ColliderRadius*4
switch currPlayerDownsync.CharacterState {
case ATK_CHARACTER_STATE_LAY_DOWN1:
colliderWidth, colliderHeight = currPlayerDownsync.ColliderRadius*4, currPlayerDownsync.ColliderRadius*2
case ATK_CHARACTER_STATE_BLOWN_UP1, ATK_CHARACTER_STATE_INAIR_IDLE1_NO_JUMP, ATK_CHARACTER_STATE_INAIR_IDLE1_BY_JUMP:
colliderWidth, colliderHeight = currPlayerDownsync.ColliderRadius*2, currPlayerDownsync.ColliderRadius*2
}
colliderWorldWidth, colliderWorldHeight := VirtualGridToWorldPos(colliderWidth, colliderHeight)
playerCollider := GenerateRectCollider(wx, wy, colliderWorldWidth, colliderWorldHeight, SNAP_INTO_PLATFORM_OVERLAP, SNAP_INTO_PLATFORM_OVERLAP, SNAP_INTO_PLATFORM_OVERLAP, SNAP_INTO_PLATFORM_OVERLAP, collisionSpaceOffsetX, collisionSpaceOffsetY, currPlayerDownsync, "Player") // the coords of all barrier boundaries are multiples of tileWidth(i.e. 16), by adding snapping y-padding when "landedOnGravityPushback" all "playerCollider.Y" would be a multiple of 1.0
playerColliders[i] = playerCollider
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// Add to collision system
collisionSys.Add(playerCollider)
thatPlayerInNextFrame := nextRenderFramePlayers[i]
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if currPlayerDownsync.InAir {
thatPlayerInNextFrame.VelX += GRAVITY_X
thatPlayerInNextFrame.VelY += GRAVITY_Y
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}
}
// 3. Add bullet colliders into collision system
bulletColliders := make([]*resolv.Object, 0, len(currRenderFrame.MeleeBullets)) // Will all be removed at the end of this function due to the need for being rollback-compatible
for _, meleeBullet := range currRenderFrame.MeleeBullets {
if (meleeBullet.OriginatedRenderFrameId+meleeBullet.StartupFrames <= currRenderFrame.Id) && (meleeBullet.OriginatedRenderFrameId+meleeBullet.StartupFrames+meleeBullet.ActiveFrames > currRenderFrame.Id) {
offender := currRenderFrame.PlayersArr[meleeBullet.OffenderJoinIndex-1]
xfac := int32(1) // By now, straight Punch offset doesn't respect "y-axis"
if 0 > offender.DirX {
xfac = -xfac
}
bulletWx, bulletWy := VirtualGridToWorldPos(offender.VirtualGridX+xfac*meleeBullet.HitboxOffsetX, offender.VirtualGridY)
hitboxSizeWx, hitboxSizeWy := VirtualGridToWorldPos(meleeBullet.HitboxSizeX, meleeBullet.HitboxSizeY)
newBulletCollider := GenerateRectCollider(bulletWx, bulletWy, hitboxSizeWx, hitboxSizeWy, SNAP_INTO_PLATFORM_OVERLAP, SNAP_INTO_PLATFORM_OVERLAP, SNAP_INTO_PLATFORM_OVERLAP, SNAP_INTO_PLATFORM_OVERLAP, collisionSpaceOffsetX, collisionSpaceOffsetY, meleeBullet, "MeleeBullet")
collisionSys.Add(newBulletCollider)
bulletColliders = append(bulletColliders, newBulletCollider)
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} else if meleeBullet.OriginatedRenderFrameId+meleeBullet.StartupFrames+meleeBullet.ActiveFrames > currRenderFrame.Id {
nextRenderFrameMeleeBullets = append(nextRenderFrameMeleeBullets, meleeBullet)
}
}
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for _, fireballBullet := range currRenderFrame.FireballBullets {
if (fireballBullet.OriginatedRenderFrameId+fireballBullet.StartupFrames < currRenderFrame.Id) && (fireballBullet.OriginatedRenderFrameId+fireballBullet.StartupFrames+fireballBullet.ActiveFrames > currRenderFrame.Id) {
bulletWx, bulletWy := VirtualGridToWorldPos(fireballBullet.VirtualGridX, fireballBullet.VirtualGridY)
hitboxSizeWx, hitboxSizeWy := VirtualGridToWorldPos(fireballBullet.HitboxSizeX, fireballBullet.HitboxSizeY)
newBulletCollider := GenerateRectCollider(bulletWx, bulletWy, hitboxSizeWx, hitboxSizeWy, SNAP_INTO_PLATFORM_OVERLAP, SNAP_INTO_PLATFORM_OVERLAP, SNAP_INTO_PLATFORM_OVERLAP, SNAP_INTO_PLATFORM_OVERLAP, collisionSpaceOffsetX, collisionSpaceOffsetY, fireballBullet, "FireballBullet")
collisionSys.Add(newBulletCollider)
bulletColliders = append(bulletColliders, newBulletCollider)
} else if fireballBullet.OriginatedRenderFrameId+fireballBullet.StartupFrames+fireballBullet.ActiveFrames > currRenderFrame.Id {
nextRenderFrameFireballBullets = append(nextRenderFrameFireballBullets, fireballBullet)
}
}
// 4. Calc pushbacks for each player (after its movement) w/o bullets
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for i, currPlayerDownsync := range currRenderFrame.PlayersArr {
joinIndex := currPlayerDownsync.JoinIndex
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playerCollider := playerColliders[i]
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playerShape := playerCollider.Shape.(*resolv.ConvexPolygon)
hardPushbackNorms[joinIndex-1] = calcHardPushbacksNorms(joinIndex, playerCollider, playerShape, SNAP_INTO_PLATFORM_OVERLAP, &(effPushbacks[joinIndex-1]))
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thatPlayerInNextFrame := nextRenderFramePlayers[i]
chConfig := chConfigsOrderedByJoinIndex[i]
landedOnGravityPushback := false
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if collision := playerCollider.Check(0, 0); nil != collision {
for _, obj := range collision.Objects {
isBarrier, isAnotherPlayer, isBullet := false, false, false
switch obj.Data.(type) {
case *PlayerDownsync:
isAnotherPlayer = true
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case *MeleeBullet, *FireballBullet:
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isBullet = true
default:
// By default it's a regular barrier, even if data is nil
isBarrier = true
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}
if isBullet {
// ignore bullets for this step
continue
}
bShape := obj.Shape.(*resolv.ConvexPolygon)
overlapped, pushbackX, pushbackY, overlapResult := CalcPushbacks(0, 0, playerShape, bShape)
if !overlapped {
continue
}
normAlignmentWithGravity := (overlapResult.OverlapX*float64(0) + overlapResult.OverlapY*float64(-1.0))
if isAnotherPlayer {
// [WARNING] The "zero overlap collision" might be randomly detected/missed on either frontend or backend, to have deterministic result we added paddings to all sides of a playerCollider. As each velocity component of (velX, velY) being a multiple of 0.5 at any renderFrame, each position component of (x, y) can only be a multiple of 0.5 too, thus whenever a 1-dimensional collision happens between players from [player#1: i*0.5, player#2: j*0.5, not collided yet] to [player#1: (i+k)*0.5, player#2: j*0.5, collided], the overlap becomes (i+k-j)*0.5+2*s, and after snapping subtraction the effPushback magnitude for each player is (i+k-j)*0.5, resulting in 0.5-multiples-position for the next renderFrame.
pushbackX, pushbackY = (overlapResult.Overlap-SNAP_INTO_PLATFORM_OVERLAP*2)*overlapResult.OverlapX, (overlapResult.Overlap-SNAP_INTO_PLATFORM_OVERLAP*2)*overlapResult.OverlapY
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}
for _, hardPushbackNorm := range *hardPushbackNorms[joinIndex-1] {
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projectedMagnitude := pushbackX*hardPushbackNorm.X + pushbackY*hardPushbackNorm.Y
if isBarrier || (isAnotherPlayer && 0 > projectedMagnitude) {
pushbackX -= projectedMagnitude * hardPushbackNorm.X
pushbackY -= projectedMagnitude * hardPushbackNorm.Y
}
}
effPushbacks[joinIndex-1].X += pushbackX
effPushbacks[joinIndex-1].Y += pushbackY
if SNAP_INTO_PLATFORM_THRESHOLD < normAlignmentWithGravity {
landedOnGravityPushback = true
//playerColliderCenterX, playerColliderCenterY := playerCollider.Center()
//fmt.Printf("joinIndex=%d landedOnGravityPushback\n{renderFrame.id: %d, isBarrier: %v, isAnotherPlayer: %v}\nhardPushbackNormsOfThisPlayer=%v, playerColliderPos=(%.2f,%.2f), immediatePushback={%.3f, %.3f}, effPushback={%.3f, %.3f}, overlapMag=%.4f\n", joinIndex, currRenderFrame.Id, isBarrier, isAnotherPlayer, *hardPushbackNorms[joinIndex-1], playerColliderCenterX, playerColliderCenterY, pushbackX, pushbackY, effPushbacks[joinIndex-1].X, effPushbacks[joinIndex-1].Y, overlapResult.Overlap)
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}
}
}
if landedOnGravityPushback {
thatPlayerInNextFrame.InAir = false
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if currPlayerDownsync.InAir && 0 >= currPlayerDownsync.VelY {
// fallStopping
thatPlayerInNextFrame.VelY = 0
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thatPlayerInNextFrame.VelX = 0
if _, existent := nonAttackingSet[thatPlayerInNextFrame.CharacterState]; existent {
if ATK_CHARACTER_STATE_BLOWN_UP1 == thatPlayerInNextFrame.CharacterState {
thatPlayerInNextFrame.CharacterState = ATK_CHARACTER_STATE_LAY_DOWN1
thatPlayerInNextFrame.FramesToRecover = chConfig.LayDownFramesToRecover
} else {
halfColliderWidthDiff, halfColliderHeightDiff := int32(0), currPlayerDownsync.ColliderRadius
_, halfColliderWorldHeightDiff := VirtualGridToWorldPos(halfColliderWidthDiff, halfColliderHeightDiff)
effPushbacks[joinIndex-1].Y -= halfColliderWorldHeightDiff // To prevent bouncing due to abrupt change of collider shape
thatPlayerInNextFrame.CharacterState = ATK_CHARACTER_STATE_IDLE1
}
}
} else {
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if _, existent := nonAttackingSet[thatPlayerInNextFrame.CharacterState]; existent {
// not fallStopping, could be in LayDown or GetUp
if ATK_CHARACTER_STATE_LAY_DOWN1 == thatPlayerInNextFrame.CharacterState {
if 0 == thatPlayerInNextFrame.FramesToRecover {
thatPlayerInNextFrame.CharacterState = ATK_CHARACTER_STATE_GET_UP1
thatPlayerInNextFrame.FramesToRecover = chConfig.GetUpFramesToRecover
}
} else if ATK_CHARACTER_STATE_GET_UP1 == thatPlayerInNextFrame.CharacterState {
if 0 == thatPlayerInNextFrame.FramesToRecover {
thatPlayerInNextFrame.CharacterState = ATK_CHARACTER_STATE_IDLE1
thatPlayerInNextFrame.FramesInvinsible = chConfig.GetUpInvinsibleFrames
}
}
}
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}
}
}
// 5. Check bullet-anything collisions
for _, bulletCollider := range bulletColliders {
collision := bulletCollider.Check(0, 0)
bulletCollider.Space.Remove(bulletCollider) // Make sure that the bulletCollider is always removed for each renderFrame
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addToNextRenderFrame := true
if nil != collision {
switch v := bulletCollider.Data.(type) {
case *MeleeBullet:
bulletShape := bulletCollider.Shape.(*resolv.ConvexPolygon)
offender := currRenderFrame.PlayersArr[v.OffenderJoinIndex-1]
for _, obj := range collision.Objects {
defenderShape := obj.Shape.(*resolv.ConvexPolygon)
switch t := obj.Data.(type) {
case *PlayerDownsync:
if v.OffenderJoinIndex == t.JoinIndex {
continue
}
overlapped, _, _, _ := CalcPushbacks(0, 0, bulletShape, defenderShape)
if !overlapped {
continue
}
addToNextRenderFrame = false
if _, existent := invinsibleSet[t.CharacterState]; existent {
continue
}
if 0 < t.FramesInvinsible {
continue
}
xfac := int32(1) // By now, straight Punch offset doesn't respect "y-axis"
if 0 > offender.DirX {
xfac = -xfac
}
pushbackVelX, pushbackVelY := xfac*v.PushbackVelX, v.PushbackVelY
atkedPlayerInNextFrame := nextRenderFramePlayers[t.JoinIndex-1]
atkedPlayerInNextFrame.VelX = pushbackVelX
atkedPlayerInNextFrame.VelY = pushbackVelY
if v.BlowUp {
atkedPlayerInNextFrame.CharacterState = ATK_CHARACTER_STATE_BLOWN_UP1
} else {
atkedPlayerInNextFrame.CharacterState = ATK_CHARACTER_STATE_ATKED1
}
oldFramesToRecover := nextRenderFramePlayers[t.JoinIndex-1].FramesToRecover
if v.HitStunFrames > oldFramesToRecover {
atkedPlayerInNextFrame.FramesToRecover = v.HitStunFrames
}
default:
addToNextRenderFrame = false
}
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}
case *FireballBullet:
bulletShape := bulletCollider.Shape.(*resolv.ConvexPolygon)
offender := currRenderFrame.PlayersArr[v.OffenderJoinIndex-1]
for _, obj := range collision.Objects {
defenderShape := obj.Shape.(*resolv.ConvexPolygon)
switch t := obj.Data.(type) {
case *PlayerDownsync:
if v.OffenderJoinIndex == t.JoinIndex {
continue
}
overlapped, _, _, _ := CalcPushbacks(0, 0, bulletShape, defenderShape)
if !overlapped {
continue
}
addToNextRenderFrame = false
if _, existent := invinsibleSet[t.CharacterState]; existent {
continue
}
if 0 < t.FramesInvinsible {
continue
}
xfac := int32(1) // By now, straight Punch offset doesn't respect "y-axis"
if 0 > offender.DirX {
xfac = -xfac
}
pushbackVelX, pushbackVelY := xfac*v.PushbackVelX, v.PushbackVelY
atkedPlayerInNextFrame := nextRenderFramePlayers[t.JoinIndex-1]
atkedPlayerInNextFrame.VelX = pushbackVelX
atkedPlayerInNextFrame.VelY = pushbackVelY
if v.BlowUp {
atkedPlayerInNextFrame.CharacterState = ATK_CHARACTER_STATE_BLOWN_UP1
} else {
atkedPlayerInNextFrame.CharacterState = ATK_CHARACTER_STATE_ATKED1
}
oldFramesToRecover := nextRenderFramePlayers[t.JoinIndex-1].FramesToRecover
if v.HitStunFrames > oldFramesToRecover {
atkedPlayerInNextFrame.FramesToRecover = v.HitStunFrames
}
default:
addToNextRenderFrame = false
}
}
}
}
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if addToNextRenderFrame {
switch v := bulletCollider.Data.(type) {
case *MeleeBullet:
nextRenderFrameMeleeBullets = append(nextRenderFrameMeleeBullets, v)
case *FireballBullet:
v.VirtualGridX, v.VirtualGridY = v.VirtualGridX+v.VelX, v.VirtualGridY+v.VelY
nextRenderFrameFireballBullets = append(nextRenderFrameFireballBullets, v)
}
}
}
// 6. Get players out of stuck barriers if there's any
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for i, currPlayerDownsync := range currRenderFrame.PlayersArr {
joinIndex := currPlayerDownsync.JoinIndex
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playerCollider := playerColliders[i]
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// Update "virtual grid position"
thatPlayerInNextFrame := nextRenderFramePlayers[i]
thatPlayerInNextFrame.VirtualGridX, thatPlayerInNextFrame.VirtualGridY = PolygonColliderBLToVirtualGridPos(playerCollider.X-effPushbacks[joinIndex-1].X, playerCollider.Y-effPushbacks[joinIndex-1].Y, playerCollider.W*0.5, playerCollider.H*0.5, 0, 0, 0, 0, collisionSpaceOffsetX, collisionSpaceOffsetY)
// Update "CharacterState"
if thatPlayerInNextFrame.InAir {
oldNextCharacterState := thatPlayerInNextFrame.CharacterState
switch oldNextCharacterState {
case ATK_CHARACTER_STATE_IDLE1, ATK_CHARACTER_STATE_WALKING:
if jumpedOrNotList[i] || ATK_CHARACTER_STATE_INAIR_IDLE1_BY_JUMP == currPlayerDownsync.CharacterState {
thatPlayerInNextFrame.CharacterState = ATK_CHARACTER_STATE_INAIR_IDLE1_BY_JUMP
} else {
thatPlayerInNextFrame.CharacterState = ATK_CHARACTER_STATE_INAIR_IDLE1_NO_JUMP
}
case ATK_CHARACTER_STATE_ATK1:
thatPlayerInNextFrame.CharacterState = ATK_CHARACTER_STATE_INAIR_ATK1
// No inAir transition for ATK2/ATK3 for now
case ATK_CHARACTER_STATE_ATKED1:
thatPlayerInNextFrame.CharacterState = ATK_CHARACTER_STATE_INAIR_ATKED1
}
}
// Reset "FramesInChState" if "CharacterState" is changed
if thatPlayerInNextFrame.CharacterState != currPlayerDownsync.CharacterState {
thatPlayerInNextFrame.FramesInChState = 0
}
// Remove any active skill if not attacking
if _, existent := nonAttackingSet[thatPlayerInNextFrame.CharacterState]; existent {
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thatPlayerInNextFrame.ActiveSkillId = int32(NO_SKILL)
thatPlayerInNextFrame.ActiveSkillHit = int32(NO_SKILL_HIT)
}
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}
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for _, playerCollider := range playerColliders {
playerCollider.Space.Remove(playerCollider)
}
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return &RoomDownsyncFrame{
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Id: currRenderFrame.Id + 1,
PlayersArr: nextRenderFramePlayers,
BulletLocalIdCounter: bulletLocalId,
MeleeBullets: nextRenderFrameMeleeBullets,
FireballBullets: nextRenderFrameFireballBullets,
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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 {
blX, blY := WorldToPolygonColliderBLPos(wx, wy, w*0.5, h*0.5, topPadding, bottomPadding, leftPadding, rightPadding, spaceOffsetX, spaceOffsetY)
return generateRectColliderInCollisionSpace(blX, blY, leftPadding+w+rightPadding, bottomPadding+h+topPadding, data, tag)
}
func generateRectColliderInCollisionSpace(blX, blY, w, h float64, data interface{}, tag string) *resolv.Object {
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
shape := resolv.NewRectangle(0, 0, w, h)
collider.SetShape(shape)
collider.Data = data
return collider
}
func GenerateConvexPolygonCollider(unalignedSrc *Polygon2D, spaceOffsetX, spaceOffsetY float64, data interface{}, tag string) *resolv.Object {
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)
collider.Data = data
return collider
}
func AlignPolygon2DToBoundingBox(input *Polygon2D) *Polygon2D {
// Transform again to put "anchor" at the "bottom-left point (w.r.t. world space)" of the bounding box for "resolv"
boundingBoxBL := &Vec2D{
X: MAX_FLOAT64,
Y: MAX_FLOAT64,
}
for _, p := range input.Points {
if p.X < boundingBoxBL.X {
boundingBoxBL.X = p.X
}
if p.Y < boundingBoxBL.Y {
boundingBoxBL.Y = p.Y
}
}
// Now "input.Anchor" should move to "input.Anchor+boundingBoxBL", thus "boundingBoxBL" is also the value of the negative diff for all "input.Points"
output := &Polygon2D{
Anchor: &Vec2D{
X: input.Anchor.X + boundingBoxBL.X,
Y: input.Anchor.Y + boundingBoxBL.Y,
},
Points: make([]*Vec2D, len(input.Points)),
}
for i, p := range input.Points {
output.Points[i] = &Vec2D{
X: p.X - boundingBoxBL.X,
Y: p.Y - boundingBoxBL.Y,
}
}
return output
}