Poodletooth-iLand/panda/direct/showutil/Effects.py

""" Showutil Effects module: contains code for useful showcode effects. """

from pandac.PandaModules import *
from direct.interval.IntervalGlobal import *

# bounce types
SX_BOUNCE = 0
SY_BOUNCE = 1
SZ_BOUNCE = 2
TX_BOUNCE = 3
TY_BOUNCE = 4
TZ_BOUNCE = 5
H_BOUNCE = 6
P_BOUNCE = 7
R_BOUNCE = 8


# convenience funcs
#
def createScaleXBounce(nodeObj, numBounces, startValues, totalTime, amplitude):
    return createBounce(nodeObj, numBounces, startValues, totalTime,
                        amplitude, SX_BOUNCE)

def createScaleYBounce(nodeObj, numBounces, startValues, totalTime, amplitude):
    return createBounce(nodeObj, numBounces, startValues, totalTime,
                        amplitude, SY_BOUNCE)

def createScaleZBounce(nodeObj, numBounces, startValue, totalTime, amplitude):
    return createBounce(nodeObj, numBounces, startValue, totalTime,
                        amplitude, SZ_BOUNCE)

def createXBounce(nodeObj, numBounces, startValues, totalTime, amplitude):
    return createBounce(nodeObj, numBounces, startValues, totalTime,
                        amplitude, TX_BOUNCE)

def createYBounce(nodeObj, numBounces, startValues, totalTime, amplitude):
    return createBounce(nodeObj, numBounces, startValues, totalTime,
                        amplitude, TY_BOUNCE)

def createZBounce(nodeObj, numBounces, startValues, totalTime, amplitude):
    return createBounce(nodeObj, numBounces, startValues, totalTime,
                        amplitude, TZ_BOUNCE)

def createHBounce(nodeObj, numBounces, startValues, totalTime, amplitude):
    return createBounce(nodeObj, numBounces, startValues, totalTime,
                        amplitude, H_BOUNCE)

def createPBounce(nodeObj, numBounces, startValues, totalTime, amplitude):
    return createBounce(nodeObj, numBounces, startValues, totalTime,
                        amplitude, P_BOUNCE)

def createRBounce(nodeObj, numBounces, startValues, totalTime, amplitude):
    return createBounce(nodeObj, numBounces, startValues, totalTime,
                        amplitude, R_BOUNCE)

def createBounce(nodeObj, numBounces, startValues, totalTime, amplitude,
                 bounceType=SZ_BOUNCE):
    """
    createBounce: create and return a list of intervals to make a
    given nodePath bounce a given number of times over a give total time.
    """
    if not nodeObj or numBounces < 1 or totalTime == 0:
        self.notify.warning(
            "createBounceIvals called with invalid parameter")
        return
    
    result = Sequence()
        
    # calculate how long, in seconds, each bounce should last
    bounceTime = totalTime/float(numBounces)
    currTime = bounceTime
    currAmplitude = amplitude
    
    # determine the how much of a change in value the first bounce
    # will produce based on the given start value and amplitude 
    #
    if ((bounceType == SX_BOUNCE) or (bounceType == TX_BOUNCE) or
        (bounceType == H_BOUNCE)):
        index = 0        
    elif ((bounceType == SY_BOUNCE) or (bounceType == TY_BOUNCE) or
          (bounceType == P_BOUNCE)):
        index = 1        
    elif ((bounceType == SZ_BOUNCE) or (bounceType == TZ_BOUNCE) or
          (bounceType == R_BOUNCE)):
        index = 2        
    currBounceVal = startValues[index]

    # create a lerp interval for each bounce, making sure to
    # figure out the new value, which progressively gets closer
    # to our start value
    #
    for bounceNum in range(numBounces*2):
        # determine the direction that this value should go,
        # alternating for each lerp interval to simulate
        # a spring effect
        #
        if bounceNum % 2:
            # bounce down
            currBounceVal = startValues[index]
            blend = 'easeIn'
        else:
            # bounce up
            currBounceVal = startValues[index] + currAmplitude
            blend = 'easeOut'

        newVec3 = Vec3(startValues)
        newVec3.setCell(index, currBounceVal)
        print "### newVec3 = ", newVec3
        
        # create the right type of lerp
        if ((bounceType == SX_BOUNCE) or (bounceType == SY_BOUNCE) or
            (bounceType == SZ_BOUNCE)):
            result.append(LerpScaleInterval(
                nodeObj, currTime, newVec3, blendType=blend))
        elif ((bounceType == TX_BOUNCE) or (bounceType == TY_BOUNCE) or
              (bounceType == TZ_BOUNCE)):
            result.append(LerpPosInterval(
                nodeObj, currTime, newVec3, blendType=blend))
        elif ((bounceType == H_BOUNCE) or (bounceType == P_BOUNCE) or
              (bounceType == R_BOUNCE)):
            result.append(LerpHprInterval(
                nodeObj, currTime, newVec3, blendType=blend))

        # the value diff from the base gets smaller for each
        # consecutive bounce, and make sure to update for
        # possibly a new amount of time the next bounce will
        # take
        #
        currAmplitude *= 0.5
        currTime = bounceTime

    return result
Initial commit 2015-03-03 16:10:12 -06:00			`""" Showutil Effects module: contains code for useful showcode effects. """`

			`from pandac.PandaModules import *`
			`from direct.interval.IntervalGlobal import *`

			`# bounce types`
			`SX_BOUNCE = 0`
			`SY_BOUNCE = 1`
			`SZ_BOUNCE = 2`
			`TX_BOUNCE = 3`
			`TY_BOUNCE = 4`
			`TZ_BOUNCE = 5`
			`H_BOUNCE = 6`
			`P_BOUNCE = 7`
			`R_BOUNCE = 8`


			`# convenience funcs`
			`#`
			`def createScaleXBounce(nodeObj, numBounces, startValues, totalTime, amplitude):`
			`return createBounce(nodeObj, numBounces, startValues, totalTime,`
			`amplitude, SX_BOUNCE)`

			`def createScaleYBounce(nodeObj, numBounces, startValues, totalTime, amplitude):`
			`return createBounce(nodeObj, numBounces, startValues, totalTime,`
			`amplitude, SY_BOUNCE)`

			`def createScaleZBounce(nodeObj, numBounces, startValue, totalTime, amplitude):`
			`return createBounce(nodeObj, numBounces, startValue, totalTime,`
			`amplitude, SZ_BOUNCE)`

			`def createXBounce(nodeObj, numBounces, startValues, totalTime, amplitude):`
			`return createBounce(nodeObj, numBounces, startValues, totalTime,`
			`amplitude, TX_BOUNCE)`

			`def createYBounce(nodeObj, numBounces, startValues, totalTime, amplitude):`
			`return createBounce(nodeObj, numBounces, startValues, totalTime,`
			`amplitude, TY_BOUNCE)`

			`def createZBounce(nodeObj, numBounces, startValues, totalTime, amplitude):`
			`return createBounce(nodeObj, numBounces, startValues, totalTime,`
			`amplitude, TZ_BOUNCE)`

			`def createHBounce(nodeObj, numBounces, startValues, totalTime, amplitude):`
			`return createBounce(nodeObj, numBounces, startValues, totalTime,`
			`amplitude, H_BOUNCE)`

			`def createPBounce(nodeObj, numBounces, startValues, totalTime, amplitude):`
			`return createBounce(nodeObj, numBounces, startValues, totalTime,`
			`amplitude, P_BOUNCE)`

			`def createRBounce(nodeObj, numBounces, startValues, totalTime, amplitude):`
			`return createBounce(nodeObj, numBounces, startValues, totalTime,`
			`amplitude, R_BOUNCE)`

			`def createBounce(nodeObj, numBounces, startValues, totalTime, amplitude,`
			`bounceType=SZ_BOUNCE):`
			`"""`
			`createBounce: create and return a list of intervals to make a`
			`given nodePath bounce a given number of times over a give total time.`
			`"""`
			`if not nodeObj or numBounces < 1 or totalTime == 0:`
			`self.notify.warning(`
			`"createBounceIvals called with invalid parameter")`
			`return`

			`result = Sequence()`

			`# calculate how long, in seconds, each bounce should last`
			`bounceTime = totalTime/float(numBounces)`
			`currTime = bounceTime`
			`currAmplitude = amplitude`

			`# determine the how much of a change in value the first bounce`
			`# will produce based on the given start value and amplitude`
			`#`
			`if ((bounceType == SX_BOUNCE) or (bounceType == TX_BOUNCE) or`
			`(bounceType == H_BOUNCE)):`
			`index = 0`
			`elif ((bounceType == SY_BOUNCE) or (bounceType == TY_BOUNCE) or`
			`(bounceType == P_BOUNCE)):`
			`index = 1`
			`elif ((bounceType == SZ_BOUNCE) or (bounceType == TZ_BOUNCE) or`
			`(bounceType == R_BOUNCE)):`
			`index = 2`
			`currBounceVal = startValues[index]`

			`# create a lerp interval for each bounce, making sure to`
			`# figure out the new value, which progressively gets closer`
			`# to our start value`
			`#`
			`for bounceNum in range(numBounces*2):`
			`# determine the direction that this value should go,`
			`# alternating for each lerp interval to simulate`
			`# a spring effect`
			`#`
			`if bounceNum % 2:`
			`# bounce down`
			`currBounceVal = startValues[index]`
			`blend = 'easeIn'`
			`else:`
			`# bounce up`
			`currBounceVal = startValues[index] + currAmplitude`
			`blend = 'easeOut'`

			`newVec3 = Vec3(startValues)`
			`newVec3.setCell(index, currBounceVal)`
			`print "### newVec3 = ", newVec3`

			`# create the right type of lerp`
			`if ((bounceType == SX_BOUNCE) or (bounceType == SY_BOUNCE) or`
			`(bounceType == SZ_BOUNCE)):`
			`result.append(LerpScaleInterval(`
			`nodeObj, currTime, newVec3, blendType=blend))`
			`elif ((bounceType == TX_BOUNCE) or (bounceType == TY_BOUNCE) or`
			`(bounceType == TZ_BOUNCE)):`
			`result.append(LerpPosInterval(`
			`nodeObj, currTime, newVec3, blendType=blend))`
			`elif ((bounceType == H_BOUNCE) or (bounceType == P_BOUNCE) or`
			`(bounceType == R_BOUNCE)):`
			`result.append(LerpHprInterval(`
			`nodeObj, currTime, newVec3, blendType=blend))`

			`# the value diff from the base gets smaller for each`
			`# consecutive bounce, and make sure to update for`
			`# possibly a new amount of time the next bounce will`
			`# take`
			`#`
			`currAmplitude *= 0.5`
			`currTime = bounceTime`

			`return result`