Poodletooth-iLand/dependencies/panda/direct/interval/LerpInterval.py

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2015-03-03 16:10:12 -06:00
"""LerpInterval module: contains the LerpInterval class"""
__all__ = [
'LerpNodePathInterval', 'LerpPosInterval', 'LerpHprInterval',
'LerpQuatInterval', 'LerpScaleInterval', 'LerpShearInterval',
'LerpPosHprInterval', 'LerpPosQuatInterval',
'LerpHprScaleInterval', 'LerpQuatScaleInterval',
'LerpPosHprScaleInterval', 'LerpPosQuatScaleInterval',
'LerpPosHprScaleShearInterval', 'LerpPosQuatScaleShearInterval',
'LerpColorInterval', 'LerpColorScaleInterval',
'LerpTexOffsetInterval', 'LerpTexRotateInterval', 'LerpTexScaleInterval',
'LerpFunctionInterval', 'LerpFunc','LerpFunctionNoStateInterval','LerpFuncNS'
]
from pandac.PandaModules import *
from direct.directnotify.DirectNotifyGlobal import *
import Interval
import LerpBlendHelpers
#
# Most of the intervals defined in this module--the group up here at
# the front of the file--are now derived from a CInterval instead of
# an Interval, so they can run in the low-level C++ code at high
# performance.
#
class LerpNodePathInterval(CLerpNodePathInterval):
# This is the base class for all of the lerps, defined below, that
# affect a property on a NodePath, like pos or hpr.
lerpNodePathNum = 1
def __init__(self, name, duration, blendType, bakeInStart, fluid,
nodePath, other):
if name == None:
name = '%s-%d' % (self.__class__.__name__, self.lerpNodePathNum)
LerpNodePathInterval.lerpNodePathNum += 1
else:
# Allow the user to pass in a %d in the name and we'll go ahead
# and uniquify the name for them.
if "%d" in name:
name = name % LerpNodePathInterval.lerpNodePathNum
LerpNodePathInterval.lerpNodePathNum += 1
blendType = self.stringBlendType(blendType)
assert blendType != self.BTInvalid
if other == None:
other = NodePath()
CLerpNodePathInterval.__init__(self, name, duration, blendType,
bakeInStart, fluid, nodePath, other)
def anyCallable(self, *params):
# Returns true if any of the parameters listed is a callable
# functor, false if none of them are. This is used by derived
# classes to determine if a functor was passed in for a
# parameter.
for param in params:
if callable(param):
return 1
return 0
def setupParam(self, func, param):
# Stores the indicated parameter by passing it to the given
# function (probably a C++ setter function). If the param is
# a callable functor, calls it; otherwise, uses the param
# directly.
if param != None:
if callable(param):
func(param())
else:
func(param)
#####################################################################
##
## It is legal to pass in a functor (a callable Python function that
## returns an appropriate value) for the any of the pos, hpr, scale,
## or shear parameters in the intervals below. These will be
## evaluated at the time the interval starts in order to determine
## the actual final (or initial) position. However, doing so forces
## the entire LerpInterval to be executed up in Python, instead of
## down in the low-level C++ code, at some performance cost.
##
## If bakeInStart is true, the starting values (if unspecified) are
## computed at the time the interval runs for the first time, and
## then stored. If bakeInStart is false, the starting values are
## recomputed each frame based on the current value and the time
## delta since the last time the interval ran, which allows show code
## to manipulate the node even while it is being lerped.
##
## If fluid is true for a LerpPos-style interval, then the pos is set
## via NodePath.setFluidPos() instead of NodePath.setPos(), causing
## the collision system to treat the motion as continuous and test
## for collisions against the entire motion path, instead of as
## discrete position updates. This has no meaning for Lerp intervals
## that do not adjust pos.
##
#####################################################################
class LerpPosInterval(LerpNodePathInterval):
def __init__(self, nodePath, duration, pos, startPos = None,
other = None, blendType = 'noBlend',
bakeInStart = 1, fluid = 0, name = None):
LerpNodePathInterval.__init__(self, name, duration, blendType,
bakeInStart, fluid, nodePath, other)
# Check for functors in the input parameters.
self.paramSetup = self.anyCallable(pos, startPos)
if self.paramSetup:
self.endPos = pos
self.startPos = startPos
self.inPython = 1
else:
self.setEndPos(pos)
if startPos != None:
self.setStartPos(startPos)
def privDoEvent(self, t, event):
# This function is only used if Python functors were passed in
# for some of the input parameters.
if self.paramSetup and event == CInterval.ETInitialize:
self.setupParam(self.setEndPos, self.endPos)
self.setupParam(self.setStartPos, self.startPos)
LerpNodePathInterval.privDoEvent(self, t, event)
class LerpHprInterval(LerpNodePathInterval):
def __init__(self, nodePath, duration, hpr,
startHpr = None, startQuat = None,
other = None, blendType = 'noBlend',
bakeInStart = 1, fluid = 0, name = None):
LerpNodePathInterval.__init__(self, name, duration, blendType,
bakeInStart, fluid, nodePath, other)
# Check for functors in the input parameters.
self.paramSetup = self.anyCallable(hpr, startHpr, startQuat)
if self.paramSetup:
self.endHpr = hpr
self.startHpr = startHpr
self.startQuat = startQuat
self.inPython = 1
else:
self.setEndHpr(hpr)
if startHpr != None:
self.setStartHpr(startHpr)
if startQuat != None:
self.setStartQuat(startQuat)
def privDoEvent(self, t, event):
# This function is only used if Python functors were passed in
# for some of the input parameters.
if self.paramSetup and event == CInterval.ETInitialize:
self.setupParam(self.setEndHpr, self.endHpr)
self.setupParam(self.setStartHpr, self.startHpr)
self.setupParam(self.setStartQuat, self.startQuat)
LerpNodePathInterval.privDoEvent(self, t, event)
class LerpQuatInterval(LerpNodePathInterval):
def __init__(self, nodePath, duration, quat = None,
startHpr = None, startQuat = None,
other = None, blendType = 'noBlend',
bakeInStart = 1, fluid = 0, name = None, hpr = None):
LerpNodePathInterval.__init__(self, name, duration, blendType,
bakeInStart, fluid, nodePath, other)
if not quat:
# If we didn't specify a quat, we're allowed to specify a
# hpr instead, which is converted to the equivalent quat.
assert hpr
quat = LOrientationf()
quat.setHpr(hpr)
# Check for functors in the input parameters.
self.paramSetup = self.anyCallable(quat, startHpr, startQuat)
if self.paramSetup:
self.endQuat = quat
self.startHpr = startHpr
self.startQuat = startQuat
self.inPython = 1
else:
self.setEndQuat(quat)
if startHpr != None:
self.setStartHpr(startHpr)
if startQuat != None:
self.setStartQuat(startQuat)
def privDoEvent(self, t, event):
# This function is only used if Python functors were passed in
# for some of the input parameters.
if self.paramSetup and event == CInterval.ETInitialize:
self.setupParam(self.setEndQuat, self.endQuat)
self.setupParam(self.setStartHpr, self.startHpr)
self.setupParam(self.setStartQuat, self.startQuat)
LerpNodePathInterval.privDoEvent(self, t, event)
class LerpScaleInterval(LerpNodePathInterval):
def __init__(self, nodePath, duration, scale, startScale = None,
other = None, blendType = 'noBlend',
bakeInStart = 1, fluid = 0, name = None):
LerpNodePathInterval.__init__(self, name, duration, blendType,
bakeInStart, fluid, nodePath, other)
# Check for functors in the input parameters.
self.paramSetup = self.anyCallable(scale, startScale)
if self.paramSetup:
self.endScale = scale
self.startScale = startScale
self.inPython = 1
else:
self.setEndScale(scale)
if startScale != None:
self.setStartScale(startScale)
def privDoEvent(self, t, event):
# This function is only used if Python functors were passed in
# for some of the input parameters.
if self.paramSetup and event == CInterval.ETInitialize:
self.setupParam(self.setEndScale, self.endScale)
self.setupParam(self.setStartScale, self.startScale)
LerpNodePathInterval.privDoEvent(self, t, event)
class LerpShearInterval(LerpNodePathInterval):
def __init__(self, nodePath, duration, shear, startShear = None,
other = None, blendType = 'noBlend',
bakeInStart = 1, fluid = 0, name = None):
LerpNodePathInterval.__init__(self, name, duration, blendType,
bakeInStart, fluid, nodePath, other)
# Check for functors in the input parameters.
self.paramSetup = self.anyCallable(shear, startShear)
if self.paramSetup:
self.endShear = shear
self.startShear = startShear
self.inPython = 1
else:
self.setEndShear(shear)
if startShear != None:
self.setStartShear(startShear)
def privDoEvent(self, t, event):
# This function is only used if Python functors were passed in
# for some of the input parameters.
if self.paramSetup and event == CInterval.ETInitialize:
self.setupParam(self.setEndShear, self.endShear)
self.setupParam(self.setStartShear, self.startShear)
LerpNodePathInterval.privDoEvent(self, t, event)
class LerpPosHprInterval(LerpNodePathInterval):
def __init__(self, nodePath, duration, pos, hpr,
startPos = None, startHpr = None, startQuat = None,
other = None, blendType = 'noBlend',
bakeInStart = 1, fluid = 0, name = None):
LerpNodePathInterval.__init__(self, name, duration, blendType,
bakeInStart, fluid, nodePath, other)
# Check for functors in the input parameters.
self.paramSetup = self.anyCallable(pos, startPos, hpr, startHpr, startQuat)
if self.paramSetup:
self.endPos = pos
self.startPos = startPos
self.endHpr = hpr
self.startHpr = startHpr
self.startQuat = startQuat
self.inPython = 1
else:
self.setEndPos(pos)
if startPos != None:
self.setStartPos(startPos)
self.setEndHpr(hpr)
if startHpr != None:
self.setStartHpr(startHpr)
if startQuat != None:
self.setStartQuat(startQuat)
def privDoEvent(self, t, event):
# This function is only used if Python functors were passed in
# for some of the input parameters.
if self.paramSetup and event == CInterval.ETInitialize:
self.setupParam(self.setEndPos, self.endPos)
self.setupParam(self.setStartPos, self.startPos)
self.setupParam(self.setEndHpr, self.endHpr)
self.setupParam(self.setStartHpr, self.startHpr)
self.setupParam(self.setStartQuat, self.startQuat)
LerpNodePathInterval.privDoEvent(self, t, event)
class LerpPosQuatInterval(LerpNodePathInterval):
def __init__(self, nodePath, duration, pos, quat = None,
startPos = None, startHpr = None, startQuat = None,
other = None, blendType = 'noBlend',
bakeInStart = 1, fluid = 0, name = None, hpr = None):
LerpNodePathInterval.__init__(self, name, duration, blendType,
bakeInStart, fluid, nodePath, other)
if not quat:
# If we didn't specify a quat, we're allowed to specify a
# hpr instead, which is converted to the equivalent quat.
assert hpr
quat = LOrientationf()
quat.setHpr(hpr)
# Check for functors in the input parameters.
self.paramSetup = self.anyCallable(pos, startPos, quat, startHpr, startQuat)
if self.paramSetup:
self.endPos = pos
self.startPos = startPos
self.endQuat = quat
self.startHpr = startHpr
self.startQuat = startQuat
self.inPython = 1
else:
self.setEndPos(pos)
if startPos != None:
self.setStartPos(startPos)
self.setEndQuat(quat)
if startHpr != None:
self.setStartHpr(startHpr)
if startQuat != None:
self.setStartQuat(startQuat)
def privDoEvent(self, t, event):
# This function is only used if Python functors were passed in
# for some of the input parameters.
if self.paramSetup and event == CInterval.ETInitialize:
self.setupParam(self.setEndPos, self.endPos)
self.setupParam(self.setStartPos, self.startPos)
self.setupParam(self.setEndQuat, self.endQuat)
self.setupParam(self.setStartHpr, self.startHpr)
self.setupParam(self.setStartQuat, self.startQuat)
LerpNodePathInterval.privDoEvent(self, t, event)
class LerpHprScaleInterval(LerpNodePathInterval):
def __init__(self, nodePath, duration, hpr, scale,
startHpr = None, startQuat = None, startScale = None,
other = None, blendType = 'noBlend',
bakeInStart = 1, fluid = 0, name = None):
LerpNodePathInterval.__init__(self, name, duration, blendType,
bakeInStart, fluid, nodePath, other)
# Check for functors in the input parameters.
self.paramSetup = self.anyCallable(hpr, startHpr, startQuat, scale, startScale)
if self.paramSetup:
self.endHpr = hpr
self.startHpr = startHpr
self.startQuat = startQuat
self.endScale = scale
self.startScale = startScale
self.inPython = 1
else:
self.setEndHpr(hpr)
if startHpr != None:
self.setStartHpr(startHpr)
if startQuat != None:
self.setStartQuat(startQuat)
self.setEndScale(scale)
if startScale != None:
self.setStartScale(startScale)
def privDoEvent(self, t, event):
# This function is only used if Python functors were passed in
# for some of the input parameters.
if self.paramSetup and event == CInterval.ETInitialize:
self.setupParam(self.setEndHpr, self.endHpr)
self.setupParam(self.setStartHpr, self.startHpr)
self.setupParam(self.setStartQuat, self.startQuat)
self.setupParam(self.setEndScale, self.endScale)
self.setupParam(self.setStartScale, self.startScale)
LerpNodePathInterval.privDoEvent(self, t, event)
class LerpQuatScaleInterval(LerpNodePathInterval):
def __init__(self, nodePath, duration, quat = None, scale = None,
hpr = None,
startHpr = None, startQuat = None, startScale = None,
other = None, blendType = 'noBlend',
bakeInStart = 1, fluid = 0, name = None):
LerpNodePathInterval.__init__(self, name, duration, blendType,
bakeInStart, fluid, nodePath, other)
if not quat:
# If we didn't specify a quat, we're allowed to specify a
# hpr instead, which is converted to the equivalent quat.
assert hpr
quat = LOrientationf()
quat.setHpr(hpr)
assert scale
# Check for functors in the input parameters.
self.paramSetup = self.anyCallable(quat, startHpr, startQuat, scale, startScale)
if self.paramSetup:
self.endQuat = quat
self.startHpr = startHpr
self.startQuat = startQuat
self.endScale = scale
self.startScale = startScale
self.inPython = 1
else:
self.setEndQuat(quat)
if startHpr != None:
self.setStartHpr(startHpr)
if startQuat != None:
self.setStartQuat(startQuat)
self.setEndScale(scale)
if startScale != None:
self.setStartScale(startScale)
def privDoEvent(self, t, event):
# This function is only used if Python functors were passed in
# for some of the input parameters.
if self.paramSetup and event == CInterval.ETInitialize:
self.setupParam(self.setEndQuat, self.endQuat)
self.setupParam(self.setStartHpr, self.startHpr)
self.setupParam(self.setStartQuat, self.startQuat)
self.setupParam(self.setEndScale, self.endScale)
self.setupParam(self.setStartScale, self.startScale)
LerpNodePathInterval.privDoEvent(self, t, event)
class LerpPosHprScaleInterval(LerpNodePathInterval):
def __init__(self, nodePath, duration, pos, hpr, scale,
startPos = None, startHpr = None, startQuat = None,
startScale = None,
other = None, blendType = 'noBlend',
bakeInStart = 1, fluid = 0, name = None):
LerpNodePathInterval.__init__(self, name, duration, blendType,
bakeInStart, fluid, nodePath, other)
# Check for functors in the input parameters.
self.paramSetup = self.anyCallable(pos, startPos, hpr, startHpr,
startQuat, scale, startScale)
if self.paramSetup:
self.endPos = pos
self.startPos = startPos
self.endHpr = hpr
self.startHpr = startHpr
self.startQuat = startQuat
self.endScale = scale
self.startScale = startScale
self.inPython = 1
else:
self.setEndPos(pos)
if startPos != None:
self.setStartPos(startPos)
self.setEndHpr(hpr)
if startHpr != None:
self.setStartHpr(startHpr)
if startQuat != None:
self.setStartQuat(startQuat)
self.setEndScale(scale)
if startScale != None:
self.setStartScale(startScale)
def privDoEvent(self, t, event):
# This function is only used if Python functors were passed in
# for some of the input parameters.
if self.paramSetup and event == CInterval.ETInitialize:
self.setupParam(self.setEndPos, self.endPos)
self.setupParam(self.setStartPos, self.startPos)
self.setupParam(self.setEndHpr, self.endHpr)
self.setupParam(self.setStartHpr, self.startHpr)
self.setupParam(self.setStartQuat, self.startQuat)
self.setupParam(self.setEndScale, self.endScale)
self.setupParam(self.setStartScale, self.startScale)
LerpNodePathInterval.privDoEvent(self, t, event)
class LerpPosQuatScaleInterval(LerpNodePathInterval):
def __init__(self, nodePath, duration, pos, quat = None, scale = None,
startPos = None, startHpr = None, startQuat = None,
startScale = None,
other = None, blendType = 'noBlend',
bakeInStart = 1, fluid = 0, name = None, hpr = None):
LerpNodePathInterval.__init__(self, name, duration, blendType,
bakeInStart, fluid, nodePath, other)
if not quat:
# If we didn't specify a quat, we're allowed to specify a
# hpr instead, which is converted to the equivalent quat.
assert hpr
quat = LOrientationf()
quat.setHpr(hpr)
assert scale
# Check for functors in the input parameters.
self.paramSetup = self.anyCallable(pos, startPos, quat, startHpr,
startQuat, scale, startScale)
if self.paramSetup:
self.endPos = pos
self.startPos = startPos
self.endQuat = quat
self.startHpr = startHpr
self.startQuat = startQuat
self.endScale = scale
self.startScale = startScale
self.inPython = 1
else:
self.setEndPos(pos)
if startPos != None:
self.setStartPos(startPos)
self.setEndQuat(quat)
if startHpr != None:
self.setStartHpr(startHpr)
if startQuat != None:
self.setStartQuat(startQuat)
self.setEndScale(scale)
if startScale != None:
self.setStartScale(startScale)
def privDoEvent(self, t, event):
# This function is only used if Python functors were passed in
# for some of the input parameters.
if self.paramSetup and event == CInterval.ETInitialize:
self.setupParam(self.setEndPos, self.endPos)
self.setupParam(self.setStartPos, self.startPos)
self.setupParam(self.setEndQuat, self.endQuat)
self.setupParam(self.setStartHpr, self.startHpr)
self.setupParam(self.setStartQuat, self.startQuat)
self.setupParam(self.setEndScale, self.endScale)
self.setupParam(self.setStartScale, self.startScale)
LerpNodePathInterval.privDoEvent(self, t, event)
class LerpPosHprScaleShearInterval(LerpNodePathInterval):
def __init__(self, nodePath, duration, pos, hpr, scale, shear,
startPos = None, startHpr = None, startQuat = None,
startScale = None, startShear = None,
other = None, blendType = 'noBlend',
bakeInStart = 1, fluid = 0, name = None):
LerpNodePathInterval.__init__(self, name, duration, blendType,
bakeInStart, fluid, nodePath, other)
# Check for functors in the input parameters.
self.paramSetup = self.anyCallable(pos, startPos, hpr, startHpr,
startQuat, scale, startScale,
shear, startShear)
if self.paramSetup:
self.endPos = pos
self.startPos = startPos
self.endHpr = hpr
self.startHpr = startHpr
self.startQuat = startQuat
self.endScale = scale
self.startScale = startScale
self.endShear = shear
self.startShear = startShear
self.inPython = 1
else:
self.setEndPos(pos)
if startPos != None:
self.setStartPos(startPos)
self.setEndHpr(hpr)
if startHpr != None:
self.setStartHpr(startHpr)
if startQuat != None:
self.setStartQuat(startQuat)
self.setEndScale(scale)
if startScale != None:
self.setStartScale(startScale)
self.setEndShear(shear)
if startShear != None:
self.setStartShear(startShear)
def privDoEvent(self, t, event):
# This function is only used if Python functors were passed in
# for some of the input parameters.
if self.paramSetup and event == CInterval.ETInitialize:
self.setupParam(self.setEndPos, self.endPos)
self.setupParam(self.setStartPos, self.startPos)
self.setupParam(self.setEndHpr, self.endHpr)
self.setupParam(self.setStartHpr, self.startHpr)
self.setupParam(self.setStartQuat, self.startQuat)
self.setupParam(self.setEndScale, self.endScale)
self.setupParam(self.setStartScale, self.startScale)
self.setupParam(self.setEndShear, self.endShear)
self.setupParam(self.setStartShear, self.startShear)
LerpNodePathInterval.privDoEvent(self, t, event)
class LerpPosQuatScaleShearInterval(LerpNodePathInterval):
def __init__(self, nodePath, duration, pos, quat = None, scale = None,
shear = None,
startPos = None, startHpr = None, startQuat = None,
startScale = None, startShear = None,
other = None, blendType = 'noBlend',
bakeInStart = 1, fluid = 0, name = None, hpr = None):
LerpNodePathInterval.__init__(self, name, duration, blendType,
bakeInStart, fluid, nodePath, other)
if not quat:
# If we didn't specify a quat, we're allowed to specify a
# hpr instead, which is converted to the equivalent quat.
assert hpr
quat = LOrientationf()
quat.setHpr(hpr)
assert scale
assert shear
# Check for functors in the input parameters.
self.paramSetup = self.anyCallable(pos, startPos, quat, startHpr,
startQuat, scale, startScale,
shear, startShear)
if self.paramSetup:
self.endPos = pos
self.startPos = startPos
self.endQuat = quat
self.startHpr = startHpr
self.startQuat = startQuat
self.endScale = scale
self.startScale = startScale
self.endShear = shear
self.startShear = startShear
self.inPython = 1
else:
self.setEndPos(pos)
if startPos != None:
self.setStartPos(startPos)
self.setEndQuat(quat)
if startHpr != None:
self.setStartHpr(startHpr)
if startQuat != None:
self.setStartQuat(startQuat)
self.setEndScale(scale)
if startScale != None:
self.setStartScale(startScale)
self.setEndShear(shear)
if startShear != None:
self.setStartShear(startShear)
def privDoEvent(self, t, event):
# This function is only used if Python functors were passed in
# for some of the input parameters.
if self.paramSetup and event == CInterval.ETInitialize:
self.setupParam(self.setEndPos, self.endPos)
self.setupParam(self.setStartPos, self.startPos)
self.setupParam(self.setEndQuat, self.endQuat)
self.setupParam(self.setStartHpr, self.startHpr)
self.setupParam(self.setStartQuat, self.startQuat)
self.setupParam(self.setEndScale, self.endScale)
self.setupParam(self.setStartScale, self.startScale)
self.setupParam(self.setEndShear, self.endShear)
self.setupParam(self.setStartShear, self.startShear)
LerpNodePathInterval.privDoEvent(self, t, event)
class LerpColorInterval(LerpNodePathInterval):
def __init__(self, nodePath, duration, color, startColor = None,
other = None, blendType = 'noBlend',
bakeInStart = 1, name = None, override = None):
LerpNodePathInterval.__init__(self, name, duration, blendType,
bakeInStart, 0, nodePath, other)
self.setEndColor(color)
if startColor != None:
self.setStartColor(startColor)
if override != None:
self.setOverride(override)
class LerpColorScaleInterval(LerpNodePathInterval):
def __init__(self, nodePath, duration, colorScale, startColorScale = None,
other = None, blendType = 'noBlend',
bakeInStart = 1, name = None, override = None):
LerpNodePathInterval.__init__(self, name, duration, blendType,
bakeInStart, 0, nodePath, other)
self.setEndColorScale(colorScale)
if startColorScale != None:
self.setStartColorScale(startColorScale)
if override != None:
self.setOverride(override)
class LerpTexOffsetInterval(LerpNodePathInterval):
def __init__(self, nodePath, duration, texOffset, startTexOffset = None,
other = None, blendType = 'noBlend',
textureStage = None,
bakeInStart = 1, name = None, override = None):
LerpNodePathInterval.__init__(self, name, duration, blendType,
bakeInStart, 0, nodePath, other)
self.setEndTexOffset(texOffset)
if startTexOffset != None:
self.setStartTexOffset(startTexOffset)
if textureStage != None:
self.setTextureStage(textureStage)
if override != None:
self.setOverride(override)
class LerpTexRotateInterval(LerpNodePathInterval):
def __init__(self, nodePath, duration, texRotate, startTexRotate = None,
other = None, blendType = 'noBlend',
textureStage = None,
bakeInStart = 1, name = None, override = None):
LerpNodePathInterval.__init__(self, name, duration, blendType,
bakeInStart, 0, nodePath, other)
self.setEndTexRotate(texRotate)
if startTexRotate != None:
self.setStartTexRotate(startTexRotate)
if textureStage != None:
self.setTextureStage(textureStage)
if override != None:
self.setOverride(override)
class LerpTexScaleInterval(LerpNodePathInterval):
def __init__(self, nodePath, duration, texScale, startTexScale = None,
other = None, blendType = 'noBlend',
textureStage = None,
bakeInStart = 1, name = None, override = None):
LerpNodePathInterval.__init__(self, name, duration, blendType,
bakeInStart, 0, nodePath, other)
self.setEndTexScale(texScale)
if startTexScale != None:
self.setStartTexScale(startTexScale)
if textureStage != None:
self.setTextureStage(textureStage)
if override != None:
self.setOverride(override)
#
# The remaining intervals defined in this module are the old-school
# Python-based intervals.
#
class LerpFunctionNoStateInterval(Interval.Interval):
"""
Class used to execute a function over time. Function can access fromData
and toData to perform blend. If fromData and toData not specified, will
execute the given function passing in values ranging from 0 to 1
This is different from a standard LerpFunction, in that it assumes
the function is not modifying any state that needs to be kept; so
that it will only call the function while the lerp is actually
running, and will not be guaranteed to call the function with its
final value of the lerp. In particular, if the lerp interval
happens to get skipped over completely, it will not bother to call
the function at all.
"""
# Interval counter
lerpFunctionIntervalNum = 1
# create LerpFunctionInterval DirectNotify category
notify = directNotify.newCategory('LerpFunctionNoStateInterval')
# Class methods
def __init__(self, function, duration = 0.0, fromData = 0, toData = 1,
blendType = 'noBlend', extraArgs = [], name = None):
"""__init__(function, duration, fromData, toData, name)
"""
# Record instance variables
self.function = function
self.fromData = fromData
self.toData = toData
self.blendType = LerpBlendHelpers.getBlend(blendType)
self.extraArgs = extraArgs
# Generate unique name if necessary
if (name == None):
name = ('LerpFunctionInterval-%d' %
LerpFunctionNoStateInterval.lerpFunctionIntervalNum)
LerpFunctionNoStateInterval.lerpFunctionIntervalNum += 1
else:
# Allow the user to pass in a %d in the name and we'll go ahead
# and uniquify the name for them.
if "%d" in name:
name = name % LerpFunctionNoStateInterval.lerpFunctionIntervalNum
LerpFunctionNoStateInterval.lerpFunctionIntervalNum += 1
# Initialize superclass
Interval.Interval.__init__(self, name, duration)
#def privDoEvent(self,t,event):
#print "doing event",t,event
#bt = self.blendType(t/self.duration)
#data = (self.fromData * (1 - bt)) + (self.toData * bt)
## Evaluate function
#apply(self.function, [data] + self.extraArgs)
#self.state = CInterval.SStarted
#self.currT = t
def privStep(self, t):
# Evaluate the function
#print "doing priv step",t
if (t >= self.duration):
# Set to end value
if (t > self.duration):
print "after end"
#apply(self.function, [self.toData] + self.extraArgs)
elif self.duration == 0.0:
# Zero duration, just use endpoint
apply(self.function, [self.toData] + self.extraArgs)
else:
# In the middle of the lerp, compute appropriate blended value
bt = self.blendType(t/self.duration)
data = (self.fromData * (1 - bt)) + (self.toData * bt)
# Evaluate function
apply(self.function, [data] + self.extraArgs)
# Print debug information
# assert self.notify.debug('updateFunc() - %s: t = %f' % (self.name, t))
self.state = CInterval.SStarted
self.currT = t
# New interface
class LerpFuncNS(LerpFunctionNoStateInterval):
def __init__(self, *args, **kw):
LerpFunctionNoStateInterval.__init__(self, *args, **kw)
class LerpFunctionInterval(Interval.Interval):
"""
Class used to execute a function over time. Function can access fromData
and toData to perform blend. If fromData and toData not specified, will
execute the given function passing in values ranging from 0 to 1
"""
# Interval counter
lerpFunctionIntervalNum = 1
# create LerpFunctionInterval DirectNotify category
notify = directNotify.newCategory('LerpFunctionInterval')
# Class methods
def __init__(self, function, duration = 0.0, fromData = 0, toData = 1,
blendType = 'noBlend', extraArgs = [], name = None):
"""__init__(function, duration, fromData, toData, name)
"""
# Record instance variables
self.function = function
self.fromData = fromData
self.toData = toData
self.blendType = LerpBlendHelpers.getBlend(blendType)
self.extraArgs = extraArgs
# Generate unique name if necessary
if (name == None):
name = ('LerpFunctionInterval-%s-%d' %
(function.__name__,
LerpFunctionInterval.lerpFunctionIntervalNum))
LerpFunctionInterval.lerpFunctionIntervalNum += 1
else:
# Allow the user to pass in a %d in the name and we'll go ahead
# and uniquify the name for them.
if "%d" in name:
name = name % LerpFunctionInterval.lerpFunctionIntervalNum
LerpFunctionInterval.lerpFunctionIntervalNum += 1
# Initialize superclass
Interval.Interval.__init__(self, name, duration)
def privStep(self, t):
# Evaluate the function
#print "doing priv step",t
if (t >= self.duration):
# Set to end value
apply(self.function, [self.toData] + self.extraArgs)
elif self.duration == 0.0:
# Zero duration, just use endpoint
apply(self.function, [self.toData] + self.extraArgs)
else:
# In the middle of the lerp, compute appropriate blended value
bt = self.blendType(t/self.duration)
data = (self.fromData * (1 - bt)) + (self.toData * bt)
# Evaluate function
apply(self.function, [data] + self.extraArgs)
# Print debug information
# assert self.notify.debug('updateFunc() - %s: t = %f' % (self.name, t))
self.state = CInterval.SStarted
self.currT = t
# New interface
class LerpFunc(LerpFunctionInterval):
def __init__(self, *args, **kw):
LerpFunctionInterval.__init__(self, *args, **kw)