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- loadstring(game:HttpGet("https://pastebin.com/raw/v1MvZeBv",true))()
- Player = game.Players.LocalPlayer
- Character = Player.Character
- Humanoid = Character.Humanoid
- RootPart = Character["HumanoidRootPart"]
- Torso = Character["Torso"]
- Head = Character["Head"]
- RightArm = Character["Right Arm"]
- LeftArm = Character["Left Arm"]
- RightLeg = Character["Right Leg"]
- LeftLeg = Character["Left Leg"]
- RootJoint = RootPart["RootJoint"]
- Neck = Torso["Neck"]
- RightShoulder = Torso["Right Shoulder"]
- LeftShoulder = Torso["Left Shoulder"]
- RightHip = Torso["Right Hip"]
- LeftHip = Torso["Left Hip"]
- local NB = Neck.C0
- local RSB = RightShoulder.C0
- local LSB = LeftShoulder.C0
- local RHB = RightHip.C0
- local LHB = LeftHip.C0
- local RJB = RootJoint.C0
- function swait(num)
- if num == 0 or num == nil then
- game:service("RunService").Stepped:wait(0)
- else
- for i = 0, num do
- game:service("RunService").Stepped:wait(0)
- end
- end
- end
- function thread(f)
- coroutine.resume(coroutine.create(f))
- end
- function clerp(a, b, t)
- local qa = {
- QuaternionFromCFrame(a)
- }
- local qb = {
- QuaternionFromCFrame(b)
- }
- local ax, ay, az = a.x, a.y, a.z
- local bx, by, bz = b.x, b.y, b.z
- local _t = 1 - t
- return QuaternionToCFrame(_t * ax + t * bx, _t * ay + t * by, _t * az + t * bz, QuaternionSlerp(qa, qb, t))
- end
- function QuaternionFromCFrame(cf)
- local mx, my, mz, m00, m01, m02, m10, m11, m12, m20, m21, m22 = cf:components()
- local trace = m00 + m11 + m22
- if trace > 0 then
- local s = math.sqrt(1 + trace)
- local recip = 0.5 / s
- return (m21 - m12) * recip, (m02 - m20) * recip, (m10 - m01) * recip, s * 0.5
- else
- local i = 0
- if m00 < m11 then
- i = 1
- end
- if m22 > (i == 0 and m00 or m11) then
- i = 2
- end
- if i == 0 then
- local s = math.sqrt(m00 - m11 - m22 + 1)
- local recip = 0.5 / s
- return 0.5 * s, (m10 + m01) * recip, (m20 + m02) * recip, (m21 - m12) * recip
- elseif i == 1 then
- local s = math.sqrt(m11 - m22 - m00 + 1)
- local recip = 0.5 / s
- return (m01 + m10) * recip, 0.5 * s, (m21 + m12) * recip, (m02 - m20) * recip
- elseif i == 2 then
- local s = math.sqrt(m22 - m00 - m11 + 1)
- local recip = 0.5 / s
- return (m02 + m20) * recip, (m12 + m21) * recip, 0.5 * s, (m10 - m01) * recip
- end
- end
- end
- function QuaternionToCFrame(px, py, pz, x, y, z, w)
- local xs, ys, zs = x + x, y + y, z + z
- local wx, wy, wz = w * xs, w * ys, w * zs
- local xx = x * xs
- local xy = x * ys
- local xz = x * zs
- local yy = y * ys
- local yz = y * zs
- local zz = z * zs
- return CFrame.new(px, py, pz, 1 - (yy + zz), xy - wz, xz + wy, xy + wz, 1 - (xx + zz), yz - wx, xz - wy, yz + wx, 1 - (xx + yy))
- end
- function QuaternionSlerp(a, b, t)
- local cosTheta = a[1] * b[1] + a[2] * b[2] + a[3] * b[3] + a[4] * b[4]
- local startInterp, finishInterp
- if cosTheta >= 1.0E-4 then
- if 1 - cosTheta > 1.0E-4 then
- local theta = math.acos(cosTheta)
- local invSinTheta = 1 / Sin(theta)
- startInterp = Sin((1 - t) * theta) * invSinTheta
- finishInterp = Sin(t * theta) * invSinTheta
- else
- startInterp = 1 - t
- finishInterp = t
- end
- elseif 1 + cosTheta > 1.0E-4 then
- local theta = math.acos(-cosTheta)
- local invSinTheta = 1 / Sin(theta)
- startInterp = Sin((t - 1) * theta) * invSinTheta
- finishInterp = Sin(t * theta) * invSinTheta
- else
- startInterp = t - 1
- finishInterp = t
- end
- return a[1] * startInterp + b[1] * finishInterp, a[2] * startInterp + b[2] * finishInterp, a[3] * startInterp + b[3] * finishInterp, a[4] * startInterp + b[4] * finishInterp
- end
- plr = game.Players.LocalPlayer
- chara = plr.Character
- Create = Instance.new
- Huge = math.huge
- Player = game.Players.LocalPlayer
- PlayerGui = Player.PlayerGui
- Cam = workspace.CurrentCamera
- Backpack = Player.Backpack
- Character = Player.Character
- char = Player.Character
- Humanoid = Character.Humanoid
- RootPart = Character["HumanoidRootPart"]
- Torso = Character["Torso"]
- Head = Character["Head"]
- RightArm = Character["Right Arm"]
- LeftArm = Character["Left Arm"]
- RightLeg = Character["Right Leg"]
- LeftLeg = Character["Left Leg"]
- RootJoint = RootPart["RootJoint"]
- Neck = Torso["Neck"]
- RightShoulder = Torso["Right Shoulder"]
- LeftShoulder = Torso["Left Shoulder"]
- RightHip = Torso["Right Hip"]
- LeftHip = Torso["Left Hip"]
- function weld(a, b, acf)
- local w = Instance.new("Weld", a)
- w.Part0 = a
- w.Part1 = b
- w.C0 = acf
- end
- --------------------------------
- local plr = game.Players.LocalPlayer
- local char = plr.Character
- local hum = char.Humanoid
- local hed = char.Head
- local root = char.HumanoidRootPart
- local rootj1 = root.RootJoint
- local tors = char.Torso
- local ra = char["Right Arm"]
- local la = char["Left Arm"]
- local rl = char["Right Leg"]
- local ll = char["Left Leg"]
- local neck1 = tors["Neck"]
- local RootCF = CFrame.fromEulerAnglesXYZ(-1.57, 0, 3.14)
- local RHCF = CFrame.fromEulerAnglesXYZ(0, 1.6, 0)
- local LHCF = CFrame.fromEulerAnglesXYZ(0, -1.6, 0)
- local maincolor = BrickColor.new("Maroon")
- -------------------------------------------------------
- --Start Good Stuff--
- -------------------------------------------------------
- cam = game.Workspace.CurrentCamera
- CF = CFrame.new
- angles = CFrame.Angles
- attack = false
- Euler = CFrame.fromEulerAnglesXYZ
- Rad = math.rad
- IT = Instance.new
- BrickC = BrickColor.new
- Cos = math.cos
- Acos = math.acos
- Sin = math.sin
- Asin = math.asin
- Abs = math.abs
- Mrandom = math.random
- Floor = math.floor
- -------------------------------------------------------
- --End Good Stuff--
- -------------------------------------------------------
- necko = CF(0, 1, 0, -1, -0, -0, 0, 0, 1, 0, 1, 0)
- RSH, LSH = nil, nil
- RHI, LHI = nil, nil
- RJO, NEC = nil, nil
- RW = Instance.new("Weld")
- LW = Instance.new("Weld")
- RH = Instance.new("Weld")
- LH = Instance.new("Weld")
- rootj = Instance.new("Weld")
- neck = Instance.new("Weld")
- RSH = tors["Right Shoulder"]
- LSH = tors["Left Shoulder"]
- RHI = tors["Right Hip"]
- LHI = tors["Left Hip"]
- RJO = root["RootJoint"]
- NEC = tors["Neck"]
- RSH.Parent = nil
- LSH.Parent = nil
- RHI.Parent = nil
- LHI.Parent = nil
- RW.Name = "Right Shoulder"
- RW.Part0 = tors
- RW.C0 = CF(1.5, 0.5, 0)
- RW.C1 = CF(0, 0.5, 0)
- RW.Part1 = ra
- RW.Parent = tors
- LW.Name = "Left Shoulder"
- LW.Part0 = tors
- LW.C0 = CF(-1.5, 0.5, 0)
- LW.C1 = CF(0, 0.5, 0)
- LW.Part1 = la
- LW.Parent = tors
- RH.Name = "Right Hip"
- RH.Part0 = tors
- RH.C0 = CF(0.5, -1, 0)
- RH.C1 = CF(0, 1, 0)
- RH.Part1 = rl
- RH.Parent = tors
- LH.Name = "Left Hip"
- LH.Part0 = tors
- LH.C0 = CF(-0.5, -1, 0)
- LH.C1 = CF(0, 1, 0)
- LH.Part1 = ll
- LH.Parent = tors
- neck.Name = "Neck"
- neck.Part0 = tors
- neck.C0 = CF(0, 1, 0)
- neck.C1 = CF(0, -1/2, 0)
- neck.Part1 = hed
- neck.Parent = tors
- rootj.Name = "RootJoint"
- rootj.Part0 = root
- rootj.C0 = CF(0, 0, 0)
- rootj.C1 = CF(0, 0, 0)
- rootj.Part1 = tors
- rootj.Parent = root
- ArtificialHB = Instance.new("BindableEvent", script)
- ArtificialHB.Name = "Heartbeat"
- script:WaitForChild("Heartbeat")
- RSH.Parent = tors
- LSH.Parent = tors
- RHI.Parent = tors
- LHI.Parent = tors
- RJO.Parent = root
- NEC.Parent = tors
- frame = 1 / 60
- tf = 0
- allowframeloss = false
- tossremainder = false
- lastframe = tick()
- script.Heartbeat:Fire()
- game:GetService("RunService").Heartbeat:connect(function(s, p)
- tf = tf + s
- if tf >= frame then
- if allowframeloss then
- script.Heartbeat:Fire()
- lastframe = tick()
- else
- for i = 1, math.floor(tf / frame) do
- script.Heartbeat:Fire()
- end
- lastframe = tick()
- end
- if tossremainder then
- tf = 0
- else
- tf = tf - frame * math.floor(tf / frame)
- end
- end
- end)
- rootj.Parent = nil
- neck.Parent = nil
- RW.Parent = nil
- LW.Parent = nil
- RH.Parent = nil
- LH.Parent = nil
- ----------------------------------------------------------------------------------
- ----------------------------------------------------------------------------------
- local equipped = false
- local idle = 0
- local change = 1
- local val = 0
- local toim = 0
- local idleanim = 0.4
- local sine = tick()
- local Sit = 1
- asd = [[tors.Neck.C0 = clerp(tors.Neck.C0, necko * angles(Rad(-7.5 * Sin(sine / 20)), Rad(0), Rad(0)), 0.3)
- RH.C0 = clerp(RH.C0, CF(1, -0.9 + -0.2 * Cos(sine / 20), -0.2) * RHCF * angles(Rad(-2.25), Rad(0), Rad(0)), 0.15)
- LH.C0 = clerp(LH.C0, CF(-1, -0.9 + -0.2 * Cos(sine / 20), 0.075) * LHCF * angles(Rad(-6.5), Rad(0), Rad(0)), 0.15)
- RW.C0 = clerp(RW.C0, CF(0.75, 0.5 + 0.1 * Sin(sine / 20), 0.25) * angles(Rad(0), Rad(0), Rad(0)), 0.1)
- LW.C0 = clerp(LW.C0, CF(-0.75, 0.5 + 0.1 * Sin(sine / 20), 0.25) * angles(Rad(0), Rad(0), Rad(0)), 0.12)]]
- ----------------------------------------------------------------------------------
- hum.WalkSpeed = 16
- hum.JumpPower = 45
- animat = hum.Animator
- ----------------------------------------------------------------------------------
- player = game.Players.LocalPlayer
- torso = player.Character:WaitForChild("Torso")
- local dancing = false
- function kolorskiddance()
- dancing = true
- rootj.Parent = root
- neck.Parent = tors
- RW.Parent = tors
- LW.Parent = tors
- RH.Parent = tors
- LH.Parent = tors
- for i = 0,2.5,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, 0) * angles(Rad(90), Rad(180), Rad(0)), 0.15)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90), Rad(180), Rad(0)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.75, -1, 0) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- LH.C0 = clerp(LH.C0, CF(-0.75, -1, 0) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0.25) * RHCF * angles(Rad(-45 * Sin(sine / 1)), Rad(20), Rad(25)), 0.15)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0.25) * LHCF * angles(Rad(-45 * Sin(sine / 1)), Rad(-20), Rad(-25)), 0.15)
- RW.C0 = clerp(RW.C0, CF(1.5, 0.75, 0) * angles(Rad(2.5 * Sin(sine / 20)), Rad(0), Rad(45 + 2.5 * Sin(sine / 30))), 0.12)
- LW.C0 = clerp(LW.C0, CF(-1.5, 0.75, 0) * angles(Rad(2.5 * Sin(sine / 30)), Rad(0), Rad(-45 + 2.5 * Sin(sine / 20))), 0.12)
- swait()
- end
- for i = 0,1.5,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, 0) * angles(Rad(90), Rad(180), Rad(0)), 0.15)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90), Rad(180), Rad(35)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.75, -1, 0) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- LH.C0 = clerp(LH.C0, CF(-0.75, -1, 0) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0.25) * RHCF * angles(Rad(11.25), Rad(20), Rad(25)), 0.15)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0.25) * LHCF * angles(Rad(11.25), Rad(-20), Rad(-25)), 0.15)
- RW.C0 = clerp(RW.C0, CF(1.5, 0.75, 0) * angles(Rad(2.5 * Sin(sine / 20)), Rad(0), Rad(40 + 2.5 * Sin(sine / 30))), 0.12)
- LW.C0 = clerp(LW.C0, CF(-1.5, 0.25, -0.35) * angles(Rad(25), Rad(122.25), Rad(65)), 0.12)
- swait()
- end
- for i = 0,2.5,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, 0) * angles(Rad(90), Rad(180), Rad(0)), 0.15)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90), Rad(180), Rad(-5)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.75, -1, 0) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- LH.C0 = clerp(LH.C0, CF(-0.75, -1, 0) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0.25) * RHCF * angles(Rad(-11.25), Rad(20), Rad(25)), 0.15)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0.25) * LHCF * angles(Rad(-11.25), Rad(-20), Rad(-25)), 0.15)
- RW.C0 = clerp(RW.C0, CF(1.5, 0.75, 0) * angles(Rad(2.5 * Sin(sine / 20)), Rad(0), Rad(35 + 2.5 * Sin(sine / 30))), 0.12)
- LW.C0 = clerp(LW.C0, CF(-1, 0.5, -1) * angles(Rad(25), Rad(0), Rad(95)), 0.12)
- swait()
- end
- for i = 0,1.5,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, 0) * angles(Rad(90), Rad(180), Rad(0)), 0.15)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90), Rad(180), Rad(-5)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.75, -1, 0) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- LH.C0 = clerp(LH.C0, CF(-0.75, -1, 0) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0.25) * RHCF * angles(Rad(11.25), Rad(20), Rad(25)), 0.15)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0.25) * LHCF * angles(Rad(11.25), Rad(-20), Rad(-25)), 0.15)
- RW.C0 = clerp(RW.C0, CF(1.5, 0.75, 0) * angles(Rad(-15), Rad(-122.25), Rad(-75)), 0.12)
- LW.C0 = clerp(LW.C0, CF(-0.75, 0.5, -1) * angles(Rad(25), Rad(0), Rad(92.5)), 0.12)
- swait()
- end
- for i = 0,2.5,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, 0) * angles(Rad(90), Rad(180), Rad(0)), 0.15)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90), Rad(180), Rad(2.5)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.75, -1, 0) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- LH.C0 = clerp(LH.C0, CF(-0.75, -1, 0) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0.25) * RHCF * angles(Rad(-11.25), Rad(20), Rad(25)), 0.15)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0.25) * LHCF * angles(Rad(-11.25), Rad(-20), Rad(-25)), 0.15)
- RW.C0 = clerp(RW.C0, CF(0.5, 0.25, -1.1) * angles(Rad(30), Rad(0), Rad(-65.5)), 0.12)
- LW.C0 = clerp(LW.C0, CF(-0.5, 0.5, -1) * angles(Rad(25), Rad(0), Rad(95)), 0.12)
- swait()
- end
- for i = 0,0.5,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, 0) * angles(Rad(90), Rad(180), Rad(0)), 0.15)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90), Rad(180), Rad(0)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.5, -1, 0) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- LH.C0 = clerp(LH.C0, CF(-0.5, -1, 0) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0.25) * RHCF * angles(Rad(11.25), Rad(0), Rad(0)), 0.15)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0.25) * LHCF * angles(Rad(11.25), Rad(0), Rad(0)), 0.15)
- RW.C0 = clerp(RW.C0, CF(0.5, 0.05, -1.1) * angles(Rad(25), Rad(0), Rad(-25.5)), 0.12)
- LW.C0 = clerp(LW.C0, CF(-0.5, 0.35, -1) * angles(Rad(20), Rad(0), Rad(28.5)), 0.12)
- swait()
- end
- for i = 0,1,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, 0) * angles(Rad(90), Rad(180 + 12.5), Rad(0)), 0.15)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90), Rad(180 + -12.5), Rad(0)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.5, -1, 0) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- LH.C0 = clerp(LH.C0, CF(-0.5, -1.1, 0) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0.25) * RHCF * angles(Rad(11.25), Rad(10), Rad(0)), 0.15)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0.25) * LHCF * angles(Rad(-11.25), Rad(-25), Rad(0)), 0.15)
- RW.C0 = clerp(RW.C0, CF(0.25, 0.6, -1.1) * angles(Rad(142.5), Rad(0), Rad(-55)), 0.12)
- LW.C0 = clerp(LW.C0, CF(-0.75, 0.8, -1) * angles(Rad(132.5), Rad(0), Rad(5)), 0.12)
- swait()
- end
- for i = 0,0.5,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, 0) * angles(Rad(90), Rad(180), Rad(0)), 0.15)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90), Rad(180), Rad(0)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.5, -1, 0) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- LH.C0 = clerp(LH.C0, CF(-0.5, -1, 0) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0.25) * RHCF * angles(Rad(11.25), Rad(0), Rad(0)), 0.15)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0.25) * LHCF * angles(Rad(11.25), Rad(0), Rad(0)), 0.15)
- RW.C0 = clerp(RW.C0, CF(0.5, 0.35, -1.1) * angles(Rad(25), Rad(0), Rad(-28.5)), 0.12)
- LW.C0 = clerp(LW.C0, CF(-0.5, 0.05, -1) * angles(Rad(20), Rad(0), Rad(25.5)), 0.12)
- swait()
- end
- for i = 0,1,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, 0) * angles(Rad(90), Rad(180 + -12.5), Rad(0)), 0.15)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90), Rad(180 + 12.5), Rad(0)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.5, -1.1, 0) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- LH.C0 = clerp(LH.C0, CF(-0.5, -1, 0) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0.25) * RHCF * angles(Rad(-11.25), Rad(10), Rad(0)), 0.15)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0.25) * LHCF * angles(Rad(11.25), Rad(-25), Rad(0)), 0.15)
- RW.C0 = clerp(RW.C0, CF(0.75, 0.5, -1.1) * angles(Rad(122.5), Rad(0), Rad(-5)), 0.12)
- LW.C0 = clerp(LW.C0, CF(-0.25, 0.7, -1) * angles(Rad(112.5), Rad(0), Rad(45)), 0.12)
- swait()
- end
- for i = 0,0.5,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, 0) * angles(Rad(90), Rad(180), Rad(0)), 0.15)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90), Rad(180), Rad(0)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.5, -1, 0) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- LH.C0 = clerp(LH.C0, CF(-0.5, -1, 0) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0.25) * RHCF * angles(Rad(11.25), Rad(0), Rad(0)), 0.15)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0.25) * LHCF * angles(Rad(11.25), Rad(0), Rad(0)), 0.15)
- RW.C0 = clerp(RW.C0, CF(0.5, 0.05, -1.1) * angles(Rad(25), Rad(0), Rad(-25.5)), 0.12)
- LW.C0 = clerp(LW.C0, CF(-0.5, 0.35, -1) * angles(Rad(20), Rad(0), Rad(28.5)), 0.12)
- swait()
- end
- for i = 0,1,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, 0) * angles(Rad(90), Rad(180 + 12.5), Rad(0)), 0.15)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90), Rad(180 + -12.5), Rad(0)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.5, -1, 0) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- LH.C0 = clerp(LH.C0, CF(-0.5, -1.1, 0) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0.25) * RHCF * angles(Rad(11.25), Rad(10), Rad(0)), 0.15)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0.25) * LHCF * angles(Rad(-11.25), Rad(-25), Rad(0)), 0.15)
- RW.C0 = clerp(RW.C0, CF(0.25, 0.6, -1.1) * angles(Rad(142.5), Rad(0), Rad(-55)), 0.12)
- LW.C0 = clerp(LW.C0, CF(-0.75, 0.8, -1) * angles(Rad(132.5), Rad(0), Rad(5)), 0.12)
- swait()
- end
- for i = 0,3.625,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, 0) * angles(Rad(90), Rad(180 + 12.5 * Sin(sine / 10)), Rad(0)), 0.15)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90), Rad(180 + -12.5 * Sin(sine / 10)), Rad(0)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.5, -1, 0) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- LH.C0 = clerp(LH.C0, CF(-0.5, -1.1, 0) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0.25) * RHCF * angles(Rad(11.25 * Sin(sine / 10)), Rad(10), Rad(0)), 0.15)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0.25) * LHCF * angles(Rad(-11.25 * Sin(sine / 10)), Rad(-25), Rad(0)), 0.15)
- RW.C0 = clerp(RW.C0, CF(0.25 + 0.75 * Cos(sine / 5), 0.6 + -0.75 * Sin(sine / 5), -1.1) * angles(Rad(142.5), Rad(0), Rad(-55)), 0.12)
- LW.C0 = clerp(LW.C0, CF(-0.75 + 0.75 * Cos(sine / 5), 0.8 + -0.75 * Sin(sine / 5), -1) * angles(Rad(132.5), Rad(0), Rad(5)), 0.12)
- swait()
- end
- for i = 0,0.5,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, 0) * angles(Rad(90), Rad(180), Rad(0)), 0.15)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90), Rad(180), Rad(0)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.5, -1, 0) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- LH.C0 = clerp(LH.C0, CF(-0.5, -1.1, 0) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0.25) * RHCF * angles(Rad(5.625), Rad(0), Rad(0)), 0.15)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0.25) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- RW.C0 = clerp(RW.C0, CF(0.5, 0.05, -1.1) * angles(Rad(25), Rad(0), Rad(-25.5)), 0.12)
- LW.C0 = clerp(LW.C0, CF(-0.5, 0.05, -1) * angles(Rad(20), Rad(0), Rad(25.5)), 0.12)
- swait()
- end
- for i = 0,2,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, 0) * angles(Rad(90), Rad(180), Rad(0)), 0.15)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90), Rad(180), Rad(0)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.5, -1, 0) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- LH.C0 = clerp(LH.C0, CF(-0.5, -1.1, 0) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0.5) * RHCF * angles(Rad(11.25), Rad(20), Rad(25)), 0.15)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0.5) * LHCF * angles(Rad(11.25), Rad(-20), Rad(-25)), 0.15)
- RW.C0 = clerp(RW.C0, CF(0.5, 0.65, -1.1) * angles(Rad(125), Rad(0), Rad(-25.5)), 0.12)
- LW.C0 = clerp(LW.C0, CF(-0.5, 0.65, -1) * angles(Rad(120), Rad(0), Rad(25.5)), 0.12)
- swait()
- end
- for i = 0,1,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, 0) * angles(Rad(90+25), Rad(180+35), Rad(0)), 0.15)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90+-25), Rad(180+55), Rad(0)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.5, -1, 0) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- LH.C0 = clerp(LH.C0, CF(-0.5, -1.3, 0) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0.5) * RHCF * angles(Rad(20), Rad(30), Rad(-25)), 0.15)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0.5) * LHCF * angles(Rad(-20), Rad(-30), Rad(25)), 0.15)
- RW.C0 = clerp(RW.C0, CF(1.5, 0.5, 0) * angles(Rad(0), Rad(0), Rad(65)), 0.12)
- LW.C0 = clerp(LW.C0, CF(-1.5, 1, 0) * angles(Rad(120), Rad(0), Rad(25)), 0.12)
- swait()
- end
- for i = 0,1,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, 0) * angles(Rad(90+15), Rad(180+-25), Rad(0)), 0.15)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90+-15), Rad(180+25), Rad(0)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.5, -1.2, 0) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- LH.C0 = clerp(LH.C0, CF(-0.75, -1, 0) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0.5) * RHCF * angles(Rad(15), Rad(25), Rad(-15)), 0.15)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0) * LHCF * angles(Rad(15), Rad(-50), Rad(15)), 0.15)
- RW.C0 = clerp(RW.C0, CF(1.5, 0.5, 0) * angles(Rad(120), Rad(0), Rad(0)), 0.12)
- LW.C0 = clerp(LW.C0, CF(-1.5, 0.5, 0) * angles(Rad(0), Rad(180), Rad(55)), 0.12)
- swait()
- end
- for i = 0,1,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, 0) * angles(Rad(90), Rad(180), Rad(0)), 0.15)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90), Rad(180), Rad(0)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.5, -1, 0) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- LH.C0 = clerp(LH.C0, CF(-0.5, -1, 0) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0.75) * RHCF * angles(Rad(15), Rad(10), Rad(10)), 0.15)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0.75) * LHCF * angles(Rad(10), Rad(-15), Rad(-10)), 0.15)
- RW.C0 = clerp(RW.C0, CF(1.5, 0.25, 0) * angles(Rad(110), Rad(-25), Rad(-40)), 0.12)
- LW.C0 = clerp(LW.C0, CF(-1.5, 0.25, 0) * angles(Rad(105), Rad(20), Rad(45)), 0.12)
- swait()
- end
- for i = 0,1,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, -0.5 + 0.5 * Cos(sine / 5)) * angles(Rad(90), Rad(180), Rad(0)), 0.15)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90), Rad(180), Rad(0)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.5, -0.6 - 0.5 * Cos(sine / 5), 0) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- LH.C0 = clerp(LH.C0, CF(-0.5, -0.6 - 0.5 * Cos(sine / 5), 0) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0.5) * RHCF * angles(Rad(11.25), Rad(25), Rad(25)), 0.15)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0.5) * LHCF * angles(Rad(11.25), Rad(-25), Rad(-20)), 0.15)
- RW.C0 = clerp(RW.C0, CF(1.5, 0.5, 0) * angles(Rad(0), Rad(0), Rad(90 - 30 * Cos(sine / 5))), 0.12)
- LW.C0 = clerp(LW.C0, CF(-1, 0.5, -0.5) * angles(Rad(0), Rad(0), Rad(85 - 30 * Cos(sine / 5))), 0.12)
- swait()
- end
- for i = 0,2.5,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, -0.5) * angles(Rad(90+25), Rad(180), Rad(0)), 0.15)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90+-25), Rad(180), Rad(0)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.75, -0.5, 0) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- LH.C0 = clerp(LH.C0, CF(-0.75, -0.5, 0) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0.5) * RHCF * angles(Rad(0), Rad(25), Rad(-25)), 0.15)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0.5) * LHCF * angles(Rad(0), Rad(-25), Rad(25)), 0.15)
- RW.C0 = clerp(RW.C0, CF(0.75, 0.5, -1) * angles(Rad(170), Rad(35), Rad(-90)), 0.12)
- LW.C0 = clerp(LW.C0, CF(-1, 0.5, -0.5) * angles(Rad(40), Rad(15), Rad(25)), 0.12)
- swait()
- end
- for i = 0,2.5,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, -0.5 + 0.5 * Cos(sine / 5.5)) * angles(Rad(90), Rad(180), Rad(0)), 0.15)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90), Rad(180), Rad(0)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.5, -0.5 - 0.5 * Cos(sine / 5.5), 0) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- LH.C0 = clerp(LH.C0, CF(-0.5, -0.5 - 0.5 * Cos(sine / 5.5), 0) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0.5) * RHCF * angles(Rad(0), Rad(0), Rad(11.25 + -11.25 * Cos(sine / 5.5))), 0.15)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0.5) * LHCF * angles(Rad(0), Rad(0), Rad(-11.25 + 11.25 * Cos(sine / 5.5))), 0.15)
- RW.C0 = clerp(RW.C0, CF(0.75, 0.5, -1) * angles(Rad(0), Rad(60 * Cos(sine / 2.5)), Rad(-90 + 60 * Sin(sine / 2.5))), 0.12)
- LW.C0 = clerp(LW.C0, CF(-0.75, 0.5, -1) * angles(Rad(0), Rad(60 * Cos(sine / 2.5)), Rad(85 + 60 * Sin(sine / 2.5))), 0.12)
- swait()
- end
- for i = 0,1,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, 0) * angles(Rad(90), Rad(180), Rad(0)), 0.15)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90+-10), Rad(180), Rad(0)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.5, -1, 0) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- LH.C0 = clerp(LH.C0, CF(-0.5, -1, 0) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0.5) * RHCF * angles(Rad(0), Rad(20), Rad(0)), 0.15)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0.5) * LHCF * angles(Rad(0), Rad(-20), Rad(0)), 0.15)
- RW.C0 = clerp(RW.C0, CF(0.75, 0.25, -1) * angles(Rad(30), Rad(-90), Rad(0)), 0.12)
- LW.C0 = clerp(LW.C0, CF(-1.5, 0.5, 0) * angles(Rad(205), Rad(0), Rad(-25)), 0.12)
- swait()
- end
- for i = 0,1,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, 0) * angles(Rad(90), Rad(180), Rad(0)), 0.3)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90), Rad(180), Rad(0)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.5, -1, 0) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.3)
- LH.C0 = clerp(LH.C0, CF(-0.5, -1, 0) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.3)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0.5) * RHCF * angles(Rad(0), Rad(20), Rad(0)), 0.3)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0.5) * LHCF * angles(Rad(0), Rad(-20), Rad(0)), 0.3)
- RW.C0 = clerp(RW.C0, CF(0.75, 0.15, -0.75) * angles(Rad(70), Rad(-55), Rad(-25)), 0.24)
- LW.C0 = clerp(LW.C0, CF(-0.75, 0.35, -0.75) * angles(Rad(45), Rad(-125), Rad(-45)), 0.24)
- swait()
- end
- for i = 0,1,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, 0) * angles(Rad(90), Rad(180), Rad(-15)), 0.3)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90), Rad(180), Rad(15)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.5, -0.85, 0) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.3)
- LH.C0 = clerp(LH.C0, CF(-0.5, -1.25, 0) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.3)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0.5) * RHCF * angles(Rad(15), Rad(25), Rad(0)), 0.3)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0.5) * LHCF * angles(Rad(-15), Rad(-25), Rad(0)), 0.3)
- RW.C0 = clerp(RW.C0, CF(1.5, 0.5, 0) * angles(Rad(0), Rad(0), Rad(75)), 0.24)
- LW.C0 = clerp(LW.C0, CF(-1.25, 0.5, -0.5) * angles(Rad(175), Rad(-90), Rad(25)), 0.24)
- swait()
- end
- for i = 0,1.5,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, 0) * angles(Rad(90), Rad(180+-15), Rad(-15)), 0.15)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90), Rad(180+15), Rad(15)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.5, -0.85, 0) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- LH.C0 = clerp(LH.C0, CF(-0.5, -1.25, 0) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0.5) * RHCF * angles(Rad(15), Rad(40), Rad(0)), 0.15)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0.5) * LHCF * angles(Rad(-15), Rad(-40), Rad(0)), 0.15)
- RW.C0 = clerp(RW.C0, CF(1.5, 0.6, 0) * angles(Rad(0), Rad(0), Rad(100)), 0.12)
- LW.C0 = clerp(LW.C0, CF(-0.75, 0.15, -0.5) * angles(Rad(0), Rad(0), Rad(35)), 0.12)
- swait()
- end
- for i = 0,4,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, -0.35) * angles(Rad(90+15), Rad(180), Rad(0)), 0.075)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90+-5), Rad(180+15), Rad(25)), 0.15)
- RH.C0 = clerp(RH.C0, CF(0.65, -0.65, 0) * RHCF * angles(Rad(2.5), Rad(0), Rad(0)), 0.075)
- LH.C0 = clerp(LH.C0, CF(-0.65, -0.65, 0) * LHCF * angles(Rad(2.5), Rad(0), Rad(0)), 0.075)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0.5) * RHCF * angles(Rad(0), Rad(25), Rad(-15)), 0.075)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0.5) * LHCF * angles(Rad(0), Rad(-25), Rad(15)), 0.075)
- RW.C0 = clerp(RW.C0, CF(1.5, 1, -0.5) * angles(Rad(250), Rad(-55), Rad(110)), 0.06)
- LW.C0 = clerp(LW.C0, CF(-1.5, 0.5, 0) * angles(Rad(0), Rad(167.5), Rad(60)), 0.06)
- swait()
- end
- for i = 0,1,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, -0.7) * angles(Rad(90+55), Rad(180+5), Rad(15)), 0.3)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90), Rad(180+-5), Rad(15)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.5, -1, 0) * RHCF * angles(Rad(0), Rad(0), Rad(55)), 0.3)
- LH.C0 = clerp(LH.C0, CF(-0.5, -1, 0) * LHCF * angles(Rad(0), Rad(0), Rad(-55)), 0.3)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0.5) * RHCF * angles(Rad(-5), Rad(40), Rad(0)), 0.3)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0.5) * LHCF * angles(Rad(5), Rad(-40), Rad(0)), 0.3)
- RW.C0 = clerp(RW.C0, CF(1.5, 0.5, 0) * angles(Rad(55+75), Rad(10), Rad(-65)), 0.24)
- LW.C0 = clerp(LW.C0, CF(-1.5, 0.5, 0) * angles(Rad(55+25), Rad(-35), Rad(-25)), 0.24)
- swait()
- end
- for i = 0,0.5,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, -0.55) * angles(Rad(90+45), Rad(180+5), Rad(7.5)), 0.15)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90+-45), Rad(180+-5), Rad(7.5)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.5, -1, 0) * RHCF * angles(Rad(0), Rad(0), Rad(55)), 0.15)
- LH.C0 = clerp(LH.C0, CF(-0.5, -1, 0) * LHCF * angles(Rad(0), Rad(0), Rad(-55)), 0.15)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0.5) * RHCF * angles(Rad(-5), Rad(40), Rad(0)), 0.15)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0.5) * LHCF * angles(Rad(5), Rad(-40), Rad(0)), 0.15)
- RW.C0 = clerp(RW.C0, CF(0.5, 0.15, -0.75) * angles(Rad(45), Rad(0), Rad(-82.5)), 0.12)
- LW.C0 = clerp(LW.C0, CF(-1.5, 0.5, 0) * angles(Rad(45), Rad(0), Rad(-75)), 0.12)
- swait()
- end
- for i = 0,1,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, -0.55) * angles(Rad(90+50), Rad(180+5), Rad(7.5)), 0.45)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90+-35), Rad(180+-5), Rad(7.5)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.5, -1, 0) * RHCF * angles(Rad(0), Rad(0), Rad(50)), 0.45)
- LH.C0 = clerp(LH.C0, CF(-0.5, -1, 0) * LHCF * angles(Rad(0), Rad(0), Rad(-50)), 0.45)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0.5) * RHCF * angles(Rad(-5), Rad(40), Rad(0)), 0.45)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0.5) * LHCF * angles(Rad(5), Rad(-40), Rad(0)), 0.45)
- RW.C0 = clerp(RW.C0, CF(0.75, 0.35, -0.5) * angles(Rad(50), Rad(0), Rad(-47.5)), 0.36)
- LW.C0 = clerp(LW.C0, CF(-1.5, 0.5, 0) * angles(Rad(50), Rad(0), Rad(-65)), 0.36)
- swait()
- end
- for i = 0,0.5,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, -0.55) * angles(Rad(90+45), Rad(180+5), Rad(7.5)), 0.45)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90+-45), Rad(180+-5), Rad(7.5)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.5, -1, 0) * RHCF * angles(Rad(0), Rad(0), Rad(55)), 0.45)
- LH.C0 = clerp(LH.C0, CF(-0.5, -1, 0) * LHCF * angles(Rad(0), Rad(0), Rad(-55)), 0.45)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0.5) * RHCF * angles(Rad(-5), Rad(40), Rad(0)), 0.45)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0.5) * LHCF * angles(Rad(5), Rad(-40), Rad(0)), 0.45)
- RW.C0 = clerp(RW.C0, CF(0.5, 0.15, -0.75) * angles(Rad(45), Rad(0), Rad(-82.5)), 0.36)
- LW.C0 = clerp(LW.C0, CF(-1.5, 0.5, 0) * angles(Rad(45), Rad(0), Rad(-75)), 0.36)
- swait()
- end
- for i = 0,2.5,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, 0) * angles(Rad(90+15), Rad(180+-5), Rad(-7.5)), 0.15)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90), Rad(180+5), Rad(7.5)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.5, -1, 0) * RHCF * angles(Rad(0), Rad(0), Rad(15)), 0.15)
- LH.C0 = clerp(LH.C0, CF(-0.5, -1.1, 0) * LHCF * angles(Rad(0), Rad(0), Rad(-15)), 0.15)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0.5) * RHCF * angles(Rad(5+10), Rad(0), Rad(0)), 0.15)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0.5) * LHCF * angles(Rad(-5+-5), Rad(-15), Rad(0)), 0.15)
- RW.C0 = clerp(RW.C0, CF(1.5, 0.85, 0) * angles(Rad(15), Rad(0), Rad(55)), 0.12)
- LW.C0 = clerp(LW.C0, CF(-1.5, 0.6, 0) * angles(Rad(15), Rad(0), Rad(-110)), 0.12)
- swait()
- end
- for i = 0,4.5,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, -0.5 + 0.5 * Cos(sine / 2.5)) * angles(Rad(90), Rad(180), Rad(0)), 0.15)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90), Rad(180), Rad(0)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.75, -0.5 - 0.5 * Cos(sine / 2.5), 0) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- LH.C0 = clerp(LH.C0, CF(-0.75, -0.5 - 0.5 * Cos(sine / 2.5), 0) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0) * RHCF * angles(Rad(-7.5 + 15 * Cos(sine / 2.5)), Rad(25), Rad(0)), 0.15)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0) * LHCF * angles(Rad(-7.5 + 15 * Cos(sine / 2.5)), Rad(-25), Rad(0)), 0.15)
- RW.C0 = clerp(RW.C0, CF(0.75, 0.25, -1) * angles(Rad(0), Rad(15 * Cos(sine / 2.5)), Rad(-105 + 70 * -Sin(sine / 2.5))), 0.12)
- LW.C0 = clerp(LW.C0, CF(-0.75, 0.25, -1) * angles(Rad(0), Rad(22.5 * Sin(sine / 2.5)), Rad(105 + 70 * Sin(sine / 2.5))), 0.12)
- swait()
- end
- for i = 0,4,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0.5 * Cos(sine / 2.5), 0, 0.5 * Sin(sine / 2.5)) * angles(Rad(90), Rad(180), Rad(0)), 0.15)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90), Rad(180), Rad(0)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.75 - -0.5 * Cos(sine / 2.5), -1 + -0.5 * Sin(sine / 2.5), 0) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- LH.C0 = clerp(LH.C0, CF(-0.75 - -0.5 * Cos(sine / 2.5), -1 + -0.5 * Sin(sine / 2.5), 0) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0) * RHCF * angles(Rad(15 * Cos(sine / 2.5)), Rad(25), Rad(15 * Sin(sine / 2.5))), 0.15)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0) * LHCF * angles(Rad(-15 * Cos(sine / 2.5)), Rad(-25), Rad(-15 * Sin(sine / 2.5))), 0.15)
- RW.C0 = clerp(RW.C0, CF(1.5, 0.5, 0) * angles(Rad(175), Rad(-5), Rad(0)), 0.12)
- LW.C0 = clerp(LW.C0, CF(-1.5, 0.5, 0) * angles(Rad(175), Rad(2.5), Rad(0)), 0.12)
- swait()
- end
- for i = 0,4,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0.5 * Cos(sine / 2.5), 0, 0.5 * Sin(sine / 2.5)) * angles(Rad(90), Rad(180), Rad(0)), 0.15)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90), Rad(180), Rad(0)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.75 + 0.5 * Cos(sine / 2.5), -1 + -0.5 * Sin(sine / 2.5), 0) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- LH.C0 = clerp(LH.C0, CF(-0.75 + 0.5 * Cos(sine / 2.5), -1 + -0.5 * Sin(sine / 2.5), 0) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0) * RHCF * angles(Rad(0), Rad(25), Rad(0)), 0.15)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0) * LHCF * angles(Rad(0), Rad(-25), Rad(0)), 0.15)
- RW.C0 = clerp(RW.C0, CF(0.5 + 0.5 * Cos(sine / 2.5), 0.25 + 0.75 * Sin(sine / 2.5), -1 + 0.5 * Sin(sine / 2.5)) * angles(Rad(0), Rad(0), Rad(-45 + -45 * Sin(sine / 2.5))), 0.12)
- LW.C0 = clerp(LW.C0, CF(-0.5 + 0.5 * Cos(sine / 2.5), 0.25 + 0.75 * Sin(sine / 2.5), -1 + 0.5 * Sin(sine / 2.5)) * angles(Rad(0), Rad(0), Rad(45 + 45 * Sin(sine / 2.5))), 0.12)
- swait()
- end
- for i = 0,0.5,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, -0.25) * angles(Rad(90+10), Rad(180+40), Rad(0)), 0.3)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90), Rad(180), Rad(0)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.65, -0.75, -0.5) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.3)
- LH.C0 = clerp(LH.C0, CF(-0.65, -0.85, -0.5) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.3)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0) * RHCF * angles(Rad(10), Rad(25), Rad(-10+12.5)), 0.3)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0) * LHCF * angles(Rad(-10), Rad(-25), Rad(10+-12.5)), 0.3)
- RW.C0 = clerp(RW.C0, CF(1, 0.5, -0.5) * angles(Rad(15), Rad(-35), Rad(-25)), 0.24)
- LW.C0 = clerp(LW.C0, CF(-1, 0.5, -0.5) * angles(Rad(15), Rad(35), Rad(25)), 0.24)
- swait()
- end
- for i = 0,2,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, 0.15) * angles(Rad(90+5), Rad(180+35), Rad(0)), 0.15)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90), Rad(180), Rad(0)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.65, -1.15, -0.5) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- LH.C0 = clerp(LH.C0, CF(-0.65, -1.25, -0.5) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0) * RHCF * angles(Rad(5), Rad(25), Rad(-5+35)), 0.15)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0) * LHCF * angles(Rad(-5), Rad(-25), Rad(5+-35)), 0.15)
- RW.C0 = clerp(RW.C0, CF(1.5, 0.85, -0.5) * angles(Rad(135), Rad(35), Rad(25)), 0.12)
- LW.C0 = clerp(LW.C0, CF(-1.5, 0.85, -0.5) * angles(Rad(135), Rad(-35), Rad(-25)), 0.12)
- swait()
- end
- for i = 0,0.5,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, 0) * angles(Rad(90+2.5), Rad(180+20), Rad(0)), 0.3)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90), Rad(180), Rad(0)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.65, -1, -0.5) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.3)
- LH.C0 = clerp(LH.C0, CF(-0.65, -1.1, -0.5) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.3)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0) * RHCF * angles(Rad(2.5), Rad(25), Rad(-2.5+20)), 0.3)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0) * LHCF * angles(Rad(-2.5), Rad(-25), Rad(2.5+-20)), 0.3)
- RW.C0 = clerp(RW.C0, CF(1.5, 0.75, -0.25) * angles(Rad(0), Rad(-25), Rad(60)), 0.24)
- LW.C0 = clerp(LW.C0, CF(-1.5, 0.75, -0.25) * angles(Rad(0), Rad(20), Rad(-55)), 0.24)
- swait()
- end
- for i = 0,2,0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, 0) * angles(Rad(90), Rad(180), Rad(0)), 0.15)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90), Rad(180), Rad(-7.5)), 0.3)
- RH.C0 = clerp(RH.C0, CF(0.5, -1, 0) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- LH.C0 = clerp(LH.C0, CF(-0.5, -1, 0) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.15)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0) * RHCF * angles(Rad(7.5), Rad(0), Rad(0)), 0.15)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0) * LHCF * angles(Rad(7.5), Rad(0), Rad(0)), 0.15)
- RW.C0 = clerp(RW.C0, CF(1.5, 0.5, 0) * angles(Rad(0), Rad(-145), Rad(-20)), 0.12)
- LW.C0 = clerp(LW.C0, CF(-1.5, 0.5, 0) * angles(Rad(0), Rad(135), Rad(35)), 0.12)
- swait()
- end
- for i = 0, 1, 0.4 do
- rootj.C0 = clerp(rootj.C0, RootCF * CF(0, 0, 0) * angles(Rad(90), Rad(180), Rad(0)), 0.3)
- neck.C0 = clerp(neck.C0, necko * angles(Rad(90), Rad(180), Rad(0)), 0.6)
- RH.C0 = clerp(RH.C0, CF(0.5, -1, 0) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.3)
- LH.C0 = clerp(LH.C0, CF(-0.5, -1, 0) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.3)
- RH.C1 = clerp(RH.C1, CF(0, 1, 0) * RHCF * angles(Rad(0), Rad(0), Rad(0)), 0.3)
- LH.C1 = clerp(LH.C1, CF(0, 1, 0) * LHCF * angles(Rad(0), Rad(0), Rad(0)), 0.3)
- RW.C0 = clerp(RW.C0, CF(1.5, 0.5, 0) * angles(Rad(0), Rad(0), Rad(0)), 0.24)
- LW.C0 = clerp(LW.C0, CF(-1.5, 0.5, 0) * angles(Rad(0), Rad(0), Rad(0)), 0.24)
- swait()
- end
- rootj.Parent = nil
- neck.Parent = nil
- RW.Parent = nil
- LW.Parent = nil
- RH.Parent = nil
- LH.Parent = nil
- dancing = false
- end
- kolors = Instance.new('Sound',torso)
- kolors.SoundId = "rbxassetid://586968170"
- kolors.Looped = true
- kolors.Playing = true
- spawn(function()
- while true do
- swait()
- if not dancing then
- kolorskiddance()
- end
- end
- end)
- spawn(function()
- while true do
- swait()
- sine = sine+change
- change = 1
- end
- end) -- https://glot.io/snippets/foykvbv04m/raws
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