Poodletooth-iLand/dependencies/panda/direct/controls/BattleWalker.py

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Python
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2015-03-03 16:10:12 -06:00
from direct.showbase.InputStateGlobal import inputState
from direct.task.Task import Task
from pandac.PandaModules import *
import GravityWalker
BattleStrafe = 0
def ToggleStrafe():
global BattleStrafe
BattleStrafe = not BattleStrafe
def SetStrafe(status):
global BattleStrafe
BattleStrafe = status
class BattleWalker(GravityWalker.GravityWalker):
def __init__(self):
GravityWalker.GravityWalker.__init__(self)
self.slideSpeed = 0
self.advanceSpeed = 0
def getSpeeds(self):
return (self.speed, self.rotationSpeed, self.slideSpeed, self.advanceSpeed)
def handleAvatarControls(self, task):
"""
Check on the arrow keys and update the avatar.
"""
# get the button states:
run = inputState.isSet("run")
forward = inputState.isSet("forward")
reverse = inputState.isSet("reverse")
turnLeft = inputState.isSet("turnLeft")
turnRight = inputState.isSet("turnRight")
slideLeft = inputState.isSet("slideLeft")
slideRight = inputState.isSet("slideRight")
jump = inputState.isSet("jump")
# Check for Auto-Run
if base.localAvatar.getAutoRun():
forward = 1
reverse = 0
# Determine what the speeds are based on the buttons:
self.speed=(forward and self.avatarControlForwardSpeed or
reverse and -self.avatarControlReverseSpeed)
# Slide speed is a scaled down version of forward speed
self.slideSpeed=(slideLeft and -self.avatarControlForwardSpeed or
slideRight and self.avatarControlForwardSpeed) * 0.5
self.rotationSpeed=not (slideLeft or slideRight) and (
(turnLeft and self.avatarControlRotateSpeed) or
(turnRight and -self.avatarControlRotateSpeed))
debugRunning = inputState.isSet("debugRunning")
if(debugRunning):
self.speed*=base.debugRunningMultiplier
self.slideSpeed*=base.debugRunningMultiplier
self.rotationSpeed*=1.25
if self.needToDeltaPos:
self.setPriorParentVector()
self.needToDeltaPos = 0
if self.wantDebugIndicator:
self.displayDebugInfo()
if self.lifter.isOnGround():
if self.isAirborne:
self.isAirborne = 0
assert self.debugPrint("isAirborne 0 due to isOnGround() true")
impact = self.lifter.getImpactVelocity()
if impact < -30.0:
messenger.send("jumpHardLand")
self.startJumpDelay(0.3)
else:
messenger.send("jumpLand")
if impact < -5.0:
self.startJumpDelay(0.2)
# else, ignore the little potholes.
assert self.isAirborne == 0
self.priorParent = Vec3.zero()
if jump and self.mayJump:
# The jump button is down and we're close
# enough to the ground to jump.
self.lifter.addVelocity(self.avatarControlJumpForce)
messenger.send("jumpStart")
self.isAirborne = 1
assert self.debugPrint("isAirborne 1 due to jump")
else:
if self.isAirborne == 0:
assert self.debugPrint("isAirborne 1 due to isOnGround() false")
self.isAirborne = 1
self.__oldPosDelta = self.avatarNodePath.getPosDelta(render)
# How far did we move based on the amount of time elapsed?
self.__oldDt = ClockObject.getGlobalClock().getDt()
dt=self.__oldDt
# Check to see if we're moving at all:
self.moving = self.speed or self.slideSpeed or self.rotationSpeed or (self.priorParent!=Vec3.zero())
if self.moving:
distance = dt * self.speed
slideDistance = dt * self.slideSpeed
rotation = dt * self.rotationSpeed
# Take a step in the direction of our previous heading.
if distance or slideDistance or self.priorParent != Vec3.zero():
# rotMat is the rotation matrix corresponding to
# our previous heading.
rotMat=Mat3.rotateMatNormaxis(self.avatarNodePath.getH(), Vec3.up())
if self.isAirborne:
forward = Vec3.forward()
else:
contact = self.lifter.getContactNormal()
forward = contact.cross(Vec3.right())
# Consider commenting out this normalize. If you do so
# then going up and down slops is a touch slower and
# steeper terrain can cut the movement in half. Without
# the normalize the movement is slowed by the cosine of
# the slope (i.e. it is multiplied by the sign as a
# side effect of the cross product above).
forward.normalize()
self.vel=Vec3(forward * distance)
if slideDistance:
if self.isAirborne:
right = Vec3.right()
else:
right = forward.cross(contact)
# See note above for forward.normalize()
right.normalize()
self.vel=Vec3(self.vel + (right * slideDistance))
self.vel=Vec3(rotMat.xform(self.vel))
step=self.vel + (self.priorParent * dt)
self.avatarNodePath.setFluidPos(Point3(
self.avatarNodePath.getPos()+step))
self.avatarNodePath.setH(self.avatarNodePath.getH()+rotation)
else:
self.vel.set(0.0, 0.0, 0.0)
if self.moving or jump:
messenger.send("avatarMoving")
return Task.cont
if 0:
def handleAvatarControls(self, task):
# If targetNp is not available, revert back to GravityWalker.handleAvatarControls.
# This situation occurs when the target dies, but we aren't switched out of
# battle walker control mode.
targetNp = self.avatarNodePath.currentTarget
if not BattleStrafe or targetNp == None or targetNp.isEmpty():
return GravityWalker.GravityWalker.handleAvatarControls(self, task)
# get the button states:
run = inputState.isSet("run")
forward = inputState.isSet("forward")
reverse = inputState.isSet("reverse")
turnLeft = inputState.isSet("turnLeft")
turnRight = inputState.isSet("turnRight")
slide = inputState.isSet("slide")
jump = inputState.isSet("jump")
# Determine what the speeds are based on the buttons:
self.advanceSpeed=(forward and self.avatarControlForwardSpeed or
reverse and -self.avatarControlReverseSpeed)
if run and self.advanceSpeed>0.0:
self.advanceSpeed*=2.0 #*#
# Should fSlide be renamed slideButton?
self.slideSpeed=.15*(turnLeft and -self.avatarControlForwardSpeed or
turnRight and self.avatarControlForwardSpeed)
print 'slideSpeed: ', self.slideSpeed
self.rotationSpeed=0
self.speed=0
debugRunning = inputState.isSet("debugRunning")
if debugRunning:
self.advanceSpeed*=4.0
self.slideSpeed*=4.0
self.rotationSpeed*=1.25
if self.needToDeltaPos:
self.setPriorParentVector()
self.needToDeltaPos = 0
if self.wantDebugIndicator:
self.displayDebugInfo()
if self.lifter.isOnGround():
if self.isAirborne:
self.isAirborne = 0
assert self.debugPrint("isAirborne 0 due to isOnGround() true")
impact = self.lifter.getImpactVelocity()
if impact < -30.0:
messenger.send("jumpHardLand")
self.startJumpDelay(0.3)
else:
messenger.send("jumpLand")
if impact < -5.0:
self.startJumpDelay(0.2)
# else, ignore the little potholes.
assert self.isAirborne == 0
self.priorParent = Vec3.zero()
if jump and self.mayJump:
# The jump button is down and we're close
# enough to the ground to jump.
self.lifter.addVelocity(self.avatarControlJumpForce)
messenger.send("jumpStart")
self.isAirborne = 1
assert self.debugPrint("isAirborne 1 due to jump")
else:
if self.isAirborne == 0:
assert self.debugPrint("isAirborne 1 due to isOnGround() false")
self.isAirborne = 1
self.__oldPosDelta = self.avatarNodePath.getPosDelta(render)
# How far did we move based on the amount of time elapsed?
self.__oldDt = ClockObject.getGlobalClock().getDt()
dt=self.__oldDt
# Before we do anything with position or orientation, make the avatar
# face it's target. Only allow rMax degrees rotation per frame, so
# we don't get an unnatural spinning effect
curH = self.avatarNodePath.getH()
self.avatarNodePath.headsUp(targetNp)
newH = self.avatarNodePath.getH()
delH = reduceAngle(newH-curH)
rMax = 10
if delH < -rMax:
self.avatarNodePath.setH(curH-rMax)
self.rotationSpeed=-self.avatarControlRotateSpeed
elif delH > rMax:
self.avatarNodePath.setH(curH+rMax)
self.rotationSpeed=self.avatarControlRotateSpeed
# Check to see if we're moving at all:
self.moving = self.speed or self.slideSpeed or self.rotationSpeed or (self.priorParent!=Vec3.zero())
if self.moving:
distance = dt * self.speed
slideDistance = dt * self.slideSpeed
print 'slideDistance: ', slideDistance
rotation = dt * self.rotationSpeed
# Take a step in the direction of our previous heading.
self.vel=Vec3(Vec3.forward() * distance +
Vec3.right() * slideDistance)
if self.vel != Vec3.zero() or self.priorParent != Vec3.zero():
if 1:
# rotMat is the rotation matrix corresponding to
# our previous heading.
rotMat=Mat3.rotateMatNormaxis(self.avatarNodePath.getH(), Vec3.up())
step=(self.priorParent * dt) + rotMat.xform(self.vel)
self.avatarNodePath.setFluidPos(Point3(
self.avatarNodePath.getPos()+step))
self.avatarNodePath.setH(self.avatarNodePath.getH()+rotation)
else:
self.vel.set(0.0, 0.0, 0.0)
"""
# Check to see if we're moving at all:
self.moving = self.advanceSpeed or self.slideSpeed or self.rotationSpeed or (self.priorParent!=Vec3.zero())
if self.moving:
distance = dt * self.advanceSpeed
slideDistance = dt * self.slideSpeed
rotation = dt * self.rotationSpeed
# Prevent avatar from getting too close to target
d = self.avatarNodePath.getPos(targetNp)
# TODO: make min distance adjust for current weapon
if (d[0]*d[0]+d[1]*d[1] < 6.0 and distance > 0):
# move the avatar sideways instead of forward
slideDistance += .2
distance = 0
# Take a step in the direction of our previous heading.
self.vel=Vec3(Vec3.forward() * distance +
Vec3.right() * slideDistance)
if self.vel != Vec3.zero() or self.priorParent != Vec3.zero():
# rotMat is the rotation matrix corresponding to
# our previous heading.
rotMat=Mat3.rotateMatNormaxis(self.avatarNodePath.getH(), Vec3.up())
step=rotMat.xform(self.vel) + (self.priorParent * dt)
self.avatarNodePath.setFluidPos(Point3(
self.avatarNodePath.getPos()+step))
self.avatarNodePath.setH(self.avatarNodePath.getH()+rotation)
else:
self.vel.set(0.0, 0.0, 0.0)
"""
if self.moving or jump:
messenger.send("avatarMoving")
return Task.cont