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Mark Mine 2000-11-14 23:35:13 +00:00
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direct/src/directutil/DirectManipulation.py Normal file
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from PandaObject import *
from DirectGeometry import *
MANIPULATION_MOVE_DELAY = 0.65
VISIBLE_DISCS = ['x-disc-visible', 'y-disc-visible', 'z-disc-visible']
class DirectManipulationControl(PandaObject):
def __init__(self, direct):
# Create the grid
self.direct = direct
self.chan = direct.chan
self.camera = self.chan.camera
self.objectHandles = ObjectHandles(direct)
self.hitPt = Point3(0)
self.prevHit = Vec3(0)
self.rotationCenter = Point3(0)
self.initScaleMag = 1
self.refNodePath = render.attachNewNode(NamedNode('refNodePath'))
self.hitPtDist = 0
self.constraint = None
self.rotateAxis = 'x'
self.lastCrankAngle = 0
self.fSetCoa = 0
self.fHitInit = 1
self.fWidgetTop = 0
self.fFreeManip = 1
self.fScaling = 1
def manipulationStart(self, chan):
# Start out in select mode
self.mode = 'select'
# Check for a widget hit point
numEntries = self.direct.iRay.pickWidget(
render,chan.mouseX,chan.mouseY)
# Did we hit a widget?
if(numEntries):
# Yes!
# Find the closest hit point if multiple hits
# Start off with first point
minPt = 0
# Find hit point in camera's space
self.hitPt = self.direct.iRay.camToHitPt(minPt)
self.hitPtDist = Vec3(self.hitPt - ZERO_POINT).length()
# Check other intersection points, sorting them
# TBD: Use TBS C++ function to do this
if numEntries > 1:
for i in range(1,numEntries):
hitPt = self.direct.iRay.camToHitPt(i)
dist = Vec3(hitPt - ZERO_POINT).length()
if (dist < self.hitPtDist):
self.hitPtDist = dist
self.hitPt = hitPt
minPt = i
# Get the associated collision queue object
entry = self.direct.iRay.cq.getEntry(minPt)
# Extract the node
node = entry.getIntoNode()
# Constraint determined by nodes name
self.constraint = node.getName()
else:
# Nope, off the widget, no constraint
self.constraint = None
# Check to see if we are moving the object
# We are moving the object if we either wait long enough
"""
taskMgr.spawnTaskNamed(
Task.doLater(MANIPULATION_MOVE_DELAY,
Task.Task(self.switchToMoveMode),
'manip-switch-to-move'),
'manip-move-wait')
"""
# Or if we move far enough
self.moveDir = None
watchMouseTask = Task.Task(self.watchMouseTask)
watchMouseTask.initX = self.chan.mouseX
watchMouseTask.initY = self.chan.mouseY
taskMgr.spawnTaskNamed(watchMouseTask, 'manip-watch-mouse')
def switchToMoveMode(self, state):
taskMgr.removeTasksNamed('manip-watch-mouse')
self.mode = 'move'
self.manipulateObject()
return Task.done
def watchMouseTask(self, state):
if (((abs (state.initX - self.chan.mouseX)) > 0.01) |
((abs (state.initY - self.chan.mouseY)) > 0.01)):
taskMgr.removeTasksNamed('manip-move-wait')
taskMgr.removeTasksNamed('manip-switch-to-move')
self.mode = 'move'
self.manipulateObject()
return Task.done
else:
return Task.cont
def manipulationStop(self):
taskMgr.removeTasksNamed('manipulateObject')
taskMgr.removeTasksNamed('manip-move-wait')
taskMgr.removeTasksNamed('manip-switch-to-move')
taskMgr.removeTasksNamed('manip-watch-mouse')
# depending on flag.....
if self.mode == 'select':
# Check for object under mouse
numEntries = self.direct.iRay.pickGeom(
render,self.chan.mouseX,self.chan.mouseY)
# Filter out widgets from entry list
indexList = []
for i in range(0,numEntries):
entry = self.direct.iRay.cq.getEntry(i)
node = entry.getIntoNode()
# Is it a named node?, If so, see if it has a name
if issubclass(node.__class__, NamedNode):
name = node.getName()
if name not in VISIBLE_DISCS:
indexList.append(i)
else:
# Not one of the widgets, use it
indexList.append(i)
# Did we hit an object?
if(indexList):
# Yes!
# Find the closest hit point if multiple hits
# Start off with first point
minPt = indexList[0]
# Find hit point in camera's space
self.hitPt = self.direct.iRay.camToHitPt(minPt)
self.hitPtDist = Vec3(self.hitPt - ZERO_POINT).length()
# Check other intersection points, sorting them
# TBD: Use TBS C++ function to do this
if len(indexList) > 1:
for i in range(1,len(indexList)):
entryNum = indexList[i]
hitPt = self.direct.iRay.camToHitPt(entryNum)
dist = Vec3(hitPt - ZERO_POINT).length()
if (dist < self.hitPtDist):
self.hitPtDist = dist
self.hitPt = hitPt
minPt = entryNum
# Get the associated collision queue object
entry = self.direct.iRay.cq.getEntry(minPt)
# Extract the node
node = entry.getIntoNode()
nodePath = render.findPathDownTo(node)
# Select it
self.direct.select(nodePath)
else:
self.direct.deselectAll()
else:
self.manipulateObjectCleanup()
def manipulateObjectCleanup(self):
if self.fScaling:
# We had been scaling, need to reset object handles
self.objectHandles.transferObjectHandlesScale()
self.fScaling = 0
if self.fSetCoa:
self.objectHandles.manipModeColor()
self.direct.selected.highlightAll()
self.objectHandles.showAllHandles()
self.objectHandles.hideGuides()
# Restart followSelectedNodePath task
if self.direct.selected.last:
self.spawnFollowSelectedNodePathTask()
messenger.send('manipulateObjectCleanup')
def spawnFollowSelectedNodePathTask(self):
# Where are the object handles relative to the selected object
pos = VBase3(0)
hpr = VBase3(0)
decomposeMatrix(self.direct.selected.last.mCoa2Dnp,
VBase3(0), hpr, pos, getDefaultCoordinateSystem())
# Create the task
t = Task.Task(self.followSelectedNodePathTask)
# Update state variables
t.pos = pos
t.hpr = hpr
t.base = self.direct.selected.last
# Spawn the task
taskMgr.spawnTaskNamed(t, 'followSelectedNodePath')
def followSelectedNodePathTask(self, state):
self.direct.widget.setPosHpr(state.base, state.pos, state.hpr)
return Task.cont
def enableManipulation(self):
# Accept mouse events
self.accept('handleMouse1', self.manipulationStart, [self.chan])
self.accept('handleMouse1Up', self.manipulationStop)
self.enableHotKeys()
def enableHotKeys(self):
self.accept(
'.', self.objectHandles.multiplyScalingFactorBy, [2.0])
self.accept(
',', self.objectHandles.multiplyScalingFactorBy, [0.5])
self.accept('F', self.objectHandles.growToFit)
def disableManipulation(self):
# Ignore middle mouse events
self.ignore('handleMouse1')
self.ignore('handleMouse1Up')
self.disableHotKeys()
def disableHotKeys(self):
self.ignore('.')
self.ignore(',')
self.ignore('F')
def removeManipulateObjectTask(self):
taskMgr.removeTasksNamed('manipulateObject')
def manipulateObject(self):
# Only do this if something is selected
if self.direct.selected:
# Remove the task to keep the widget attached to the object
taskMgr.removeTasksNamed('followSelectedNodePath')
# and the task to highlight the widget
taskMgr.removeTasksNamed('highlightWidgetTask')
# Set manipulation flag
self.fManip = 1
# Update object handles visibility
self.objectHandles.showGuides()
self.objectHandles.hideAllHandles()
self.objectHandles.showHandle(self.constraint)
if self.fSetCoa:
self.objectHandles.coaModeColor()
# Record relationship between selected nodes and widget
self.direct.selected.getWrtAll()
# hide the bbox of the selected objects during interaction
self.direct.selected.dehighlightAll()
"""
# Push the undo dcs for the selected objects
self.direct.undo.push(
(self.direct.selected, 'dcs'))
"""
# Manipulate the real object with the constraint
# The constraint is passed as the name of the node
self.spawnManipulateObjectTask()
def spawnManipulateObjectTask(self):
# reset hit-pt flag
self.fHitInit = 1
# record initial offset between widget and camera
t = Task.Task(self.manipulateObjectTask)
taskMgr.spawnTaskNamed(t, 'manipulateObject')
def manipulateObjectTask(self, state):
if self.constraint:
type = self.constraint[2:]
if type == 'post':
self.xlate1D()
elif type == 'disc':
self.xlate2D()
elif type == 'ring':
self.rotate1D()
elif self.fFreeManip:
if self.fScaling & (not self.direct.fAlt):
# We had been scaling and changed modes,
# reset object handles
self.objectHandles.transferObjectHandlesScale()
self.fScaling = 0
if self.direct.fControl:
self.rotate2D()
elif self.direct.fAlt:
self.fScaling = 1
self.scale3D()
elif self.direct.fShift:
self.xlateCamXY()
else:
self.xlateCamXZ()
else:
# MRM: Needed, more elegant fallback
return Task.cont
if self.fSetCoa:
# Update coa based on current widget position
self.direct.selected.last.mCoa2Dnp.assign(
self.direct.widget.getMat(self.direct.selected.last)
)
else:
# Move the objects with the widget
self.direct.selected.moveWrtWidgetAll()
# Continue
return Task.cont
def xlate1D(self):
# Constrained 1D Translation along widget axis
# Compute nearest hit point along axis and try to keep
# that point as close to the current mouse position as possible
# what point on the axis is the mouse pointing at?
self.hitPt.assign(self.objectHandles.getAxisIntersectPt(
self.constraint[:1]))
# use it to see how far to move the widget
if self.fHitInit:
# First time through, just record that point
self.fHitInit = 0
self.prevHit.assign(self.hitPt)
else:
# Move widget to keep hit point as close to mouse as possible
offset = self.hitPt - self.prevHit
self.direct.widget.setPos(self.direct.widget, offset)
def xlate2D(self):
# Constrained 2D (planar) translation
# Compute point of intersection of ray from eyepoint through cursor
# to one of the three orthogonal planes on the widget.
# This point tracks all subsequent mouse movements
self.hitPt.assign(self.objectHandles.getWidgetIntersectPt(
self.direct.widget, self.constraint[:1]))
# use it to see how far to move the widget
if self.fHitInit:
# First time through just record hit point
self.fHitInit = 0
self.prevHit.assign(self.hitPt)
else:
offset = self.hitPt - self.prevHit
self.direct.widget.setPos(self.direct.widget, offset)
def xlateCamXZ(self):
"""Constrained 2D motion parallel to the camera's image plane
This moves the object in the camera's XZ plane"""
# reset fHitInit
# (in case we later switch to another manipulation mode)
#self.fHitInit = 1
# Where is the widget relative to current camera view
vWidget2Camera = self.direct.widget.getPos(self.camera)
x = vWidget2Camera[0]
y = vWidget2Camera[1]
z = vWidget2Camera[2]
# Move widget (and objects) based upon mouse motion
# Scaled up accordingly based upon widget distance
chan = self.chan
self.direct.widget.setX(
self.camera,
x + 0.5 * chan.mouseDeltaX * chan.nearWidth * (y/chan.near))
self.direct.widget.setZ(
self.camera,
z + 0.5 * chan.mouseDeltaY * chan.nearHeight * (y/chan.near))
def xlateCamXY(self):
"""Constrained 2D motion perpendicular to camera's image plane
This moves the object in the camera's XY plane"""
# Now, where is the widget relative to current camera view
vWidget2Camera = self.direct.widget.getPos(self.camera)
# If this is first time around, record initial y distance
if self.fHitInit:
self.fHitInit = 0
# Record widget offset along y
self.initY = vWidget2Camera[1]
# Extract current values
x = vWidget2Camera[0]
y = vWidget2Camera[1]
z = vWidget2Camera[2]
# Move widget (and objects) based upon mouse motion
# Scaled up accordingly based upon widget distance
chan = self.chan
self.direct.widget.setPos(
self.camera,
x + 0.5 * chan.mouseDeltaX * chan.nearWidth * (y/chan.near),
y + self.initY * chan.mouseDeltaY,
z)
def getCrankAngle(self):
# Used to compute current angle of mouse (relative to the widget's
# origin) in screen space
x = self.chan.mouseX - self.rotationCenter[0]
y = self.chan.mouseY - self.rotationCenter[2]
return (180 + rad2Deg(math.atan2(y,x)))
def widgetCheck(self,type):
# Utility to see if we are looking at the top or bottom of
# a 2D planar widget or if we are looking at a 2D planar widget
# edge on
# Based upon angle between view vector from eye through the
# widget's origin and one of the three principle axes
axis = self.constraint[:1]
# First compute vector from eye through widget origin
mWidget2Cam = self.direct.widget.getMat(self.camera)
# And determine where the viewpoint is relative to widget
pos = VBase3(0)
decomposeMatrix(mWidget2Cam, VBase3(0), VBase3(0), pos,
getDefaultCoordinateSystem())
widgetDir = Vec3(pos)
widgetDir.normalize()
# Convert specified widget axis to view space
if axis == 'x':
widgetAxis = Vec3(mWidget2Cam.xformVec(X_AXIS))
elif axis == 'y':
widgetAxis = Vec3(mWidget2Cam.xformVec(Y_AXIS))
elif axis == 'z':
widgetAxis = Vec3(mWidget2Cam.xformVec(Z_AXIS))
widgetAxis.normalize()
if type == 'top?':
# Check sign of angle between two vectors
return (widgetDir.dot(widgetAxis) < 0.)
elif type == 'edge?':
# Checking to see if we are viewing edge-on
# Check angle between two vectors
return(abs(widgetDir.dot(widgetAxis)) < .2)
def getWidgetsNearProjectionPoint(self):
# Find the position of the projection of the specified node path
# on the near plane
widgetOrigin = self.direct.widget.getPos(self.camera)
# project this onto near plane
return widgetOrigin * (self.chan.near / widgetOrigin[1])
def getScreenXY(self):
# Where does the widget's projection fall on the near plane
nearVec = self.getWidgetsNearProjectionPoint()
# Clamp these coordinates to visible screen
nearX = self.clamp(nearVec[0], self.chan.left, self.chan.right)
nearY = self.clamp(nearVec[2], self.chan.bottom, self.chan.top)
# What percentage of the distance across the screen is this?
percentX = (nearX - self.chan.left)/self.chan.nearWidth
percentY = (nearY - self.chan.bottom)/self.chan.nearHeight
# Map this percentage to the same -1 to 1 space as the mouse
screenXY = Vec3((2 * percentX) - 1.0,nearVec[1],(2 * percentY) - 1.0)
# Return the resulting value
return screenXY
def rotate1D(self):
# Constrained 1D rotation about the widget's main axis (X,Y, or Z)
# Rotation depends upon circular motion of the mouse about the
# projection of the widget's origin on the image plane
# A complete circle about the widget results in a change in
# orientation of 360 degrees.
# First initialize hit point/rotation angle
if self.fHitInit:
self.fHitInit = 0
self.rotateAxis = self.constraint[:1]
self.fWidgetTop = self.widgetCheck('top?')
self.rotationCenter = self.getScreenXY()
self.lastCrankAngle = self.getCrankAngle()
# Rotate widget based on how far cursor has swung around origin
newAngle = self.getCrankAngle()
deltaAngle = self.lastCrankAngle - newAngle
if self.fWidgetTop:
deltaAngle = -1 * deltaAngle
if self.rotateAxis == 'x':
self.direct.widget.setP(self.direct.widget, deltaAngle)
elif self.rotateAxis == 'y':
self.direct.widget.setR(self.direct.widget, -deltaAngle)
elif self.rotateAxis == 'z':
self.direct.widget.setH(self.direct.widget, deltaAngle)
# Record crank angle for next time around
self.lastCrankAngle = newAngle
def relHpr(self, base, h, p, r):
# Compute widget2newWidget relative to base coordinate system
mWidget2Base = self.direct.widget.getMat(base)
mBase2NewBase = Mat4()
mBase2NewBase.composeMatrix(
UNIT_VEC, VBase3(h,p,r), ZERO_VEC,
getDefaultCoordinateSystem())
mBase2Widget = base.getMat(self.direct.widget)
mWidget2Parent = self.direct.widget.getMat()
# Compose the result
resultMat = mWidget2Base * mBase2NewBase
resultMat = resultMat * mBase2Widget
resultMat = resultMat * mWidget2Parent
# Extract and apply the hpr
hpr = Vec3(0)
decomposeMatrix(resultMat, VBase3(), hpr, VBase3(),
getDefaultCoordinateSystem())
self.direct.widget.setHpr(hpr)
def rotate2D(self):
# Virtual trackball or arcball rotation of widget
# Rotation method depends upon variable dd-want-arcball
# Default is virtual trackball (handles 1D rotations better)
self.fHitInit = 1
tumbleRate = 360
# Mouse motion edge to edge of channel results in one full turn
self.relHpr(self.camera,
self.chan.mouseDeltaX * tumbleRate,
-self.chan.mouseDeltaY * tumbleRate,
0)
def scale3D(self):
# Scale the selected node based upon up down mouse motion
# Mouse motion from edge to edge results in a factor of 4 scaling
# From midpoint to edge doubles or halves objects scale
if self.fHitInit:
self.fHitInit = 0
self.refNodePath.setPos(self.direct.widget, 0, 0, 0)
self.refNodePath.setHpr(self.camera, 0, 0, 0)
self.initScaleMag = Vec3(
self.objectHandles.getWidgetIntersectPt(
self.refNodePath, 'y')).length()
# record initial scale
self.initScale = self.direct.widget.getScale()
# Begin
# Scale factor is ratio current mag with init mag
currScale = (
self.initScale *
(self.objectHandles.getWidgetIntersectPt(
self.refNodePath, 'y').length() /
self.initScaleMag)
)
self.direct.widget.setScale(currScale)
def clamp(self, val, min, max):
if val < min:
return min
elif val > max:
return max
else:
return val
class ObjectHandles(NodePath,PandaObject):
def __init__(self,direct):
# Record pointer to direct object
self.direct = direct
# Initialize the superclass
NodePath.__init__(self)
# Load up object handles model and assign it to self
self.assign(loader.loadModel('misc/objectHandles'))
self.node().setName('objectHandles')
self.scalingNode = self.getChild(0)
self.scalingNode.node().setName('ohScalingNode')
self.ohScalingFactor = 1.0
# To avoid recreating a vec every frame
self.hitPt = Vec3(0)
# Get a handle on the components
self.xHandles = self.find('**/X')
self.xPostGroup = self.xHandles.find('**/x-post-group')
self.xPostCollision = self.xHandles.find('**/x-post')
self.xRingGroup = self.xHandles.find('**/x-ring-group')
self.xRingCollision = self.xHandles.find('**/x-ring')
self.xDiscGroup = self.xHandles.find('**/x-disc-group')
self.xDisc = self.xHandles.find('**/x-disc-visible')
self.xDiscCollision = self.xHandles.find('**/x-disc')
self.yHandles = self.find('**/Y')
self.yPostGroup = self.yHandles.find('**/y-post-group')
self.yPostCollision = self.yHandles.find('**/y-post')
self.yRingGroup = self.yHandles.find('**/y-ring-group')
self.yRingCollision = self.yHandles.find('**/y-ring')
self.yDiscGroup = self.yHandles.find('**/y-disc-group')
self.yDisc = self.yHandles.find('**/y-disc-visible')
self.yDiscCollision = self.yHandles.find('**/y-disc')
self.zHandles = self.find('**/Z')
self.zPostGroup = self.zHandles.find('**/z-post-group')
self.zPostCollision = self.zHandles.find('**/z-post')
self.zRingGroup = self.zHandles.find('**/z-ring-group')
self.zRingCollision = self.zHandles.find('**/z-ring')
self.zDiscGroup = self.zHandles.find('**/z-disc-group')
self.zDisc = self.zHandles.find('**/z-disc-visible')
self.zDiscCollision = self.zHandles.find('**/z-disc')
# Adjust visiblity, colors, and transparency
self.xPostCollision.hide()
self.xRingCollision.hide()
self.xDisc.setColor(1,0,0,.2)
self.yPostCollision.hide()
self.yRingCollision.hide()
self.yDisc.setColor(0,1,0,.2)
self.zPostCollision.hide()
self.zRingCollision.hide()
self.zDisc.setColor(0,0,1,.2)
# Augment geometry with lines
self.createObjectHandleLines()
# Create long markers to help line up in world
self.createGuideLines()
self.hideGuides()
def coaModeColor(self):
self.setColor(.5,.5,.5,1)
def manipModeColor(self):
self.clearColor()
def enableHandles(self, handles):
if type(handles) == types.ListType:
for handle in handles:
self.enableHandle(handle)
elif handles == 'x':
self.enableHandles(['x-post','x-ring','x-disc'])
elif handles == 'y':
self.enableHandles(['y-post','y-ring','y-disc'])
elif handles == 'z':
self.enableHandles(['z-post','z-ring','z-disc'])
elif handles == 'post':
self.enableHandles(['x-post','y-post','z-post'])
elif handles == 'ring':
self.enableHandles(['x-ring','y-ring','z-ring'])
elif handles == 'disc':
self.enableHandles(['x-disc','y-disc','z-disc'])
elif handles == 'all':
self.enableHandles(['x-post','x-ring','x-disc',
'y-post','y-ring','y-disc',
'z-post','z-ring','z-disc'])
def enableHandle(self, handle):
if handle == 'x-post':
self.xPostGroup.reparentTo(self.xHandles)
elif handle == 'x-ring':
self.xRingGroup.reparentTo(self.xHandles)
elif handle == 'x-disc':
self.xDiscGroup.reparentTo(self.xHandles)
if handle == 'y-post':
self.yPostGroup.reparentTo(self.yHandles)
elif handle == 'y-ring':
self.yRingGroup.reparentTo(self.yHandles)
elif handle == 'y-disc':
self.yDiscGroup.reparentTo(self.yHandles)
if handle == 'z-post':
self.zPostGroup.reparentTo(self.zHandles)
elif handle == 'z-ring':
self.zRingGroup.reparentTo(self.zHandles)
elif handle == 'z-disc':
self.zDiscGroup.reparentTo(self.zHandles)
def disableHandles(self, handles):
if type(handles) == types.ListType:
for handle in handles:
self.disableHandle(handle)
elif handles == 'x':
self.disableHandles(['x-post','x-ring','x-disc'])
elif handles == 'y':
self.disableHandles(['y-post','y-ring','y-disc'])
elif handles == 'z':
self.disableHandles(['z-post','z-ring','z-disc'])
elif handles == 'post':
self.disableHandles(['x-post','y-post','z-post'])
elif handles == 'ring':
self.disableHandles(['x-ring','y-ring','z-ring'])
elif handles == 'disc':
self.disableHandles(['x-disc','y-disc','z-disc'])
elif handles == 'all':
self.disableHandles(['x-post','x-ring','x-disc',
'y-post','y-ring','y-disc',
'z-post','z-ring','z-disc'])
def disableHandle(self, handle):
if handle == 'x-post':
self.xPostGroup.reparentTo(hidden)
elif handle == 'x-ring':
self.xRingGroup.reparentTo(hidden)
elif handle == 'x-disc':
self.xDiscGroup.reparentTo(hidden)
if handle == 'y-post':
self.yPostGroup.reparentTo(hidden)
elif handle == 'y-ring':
self.yRingGroup.reparentTo(hidden)
elif handle == 'y-disc':
self.yDiscGroup.reparentTo(hidden)
if handle == 'z-post':
self.zPostGroup.reparentTo(hidden)
elif handle == 'z-ring':
self.zRingGroup.reparentTo(hidden)
elif handle == 'z-disc':
self.zDiscGroup.reparentTo(hidden)
def showAllHandles(self):
self.xPost.show()
self.xRing.show()
self.xDisc.show()
self.yPost.show()
self.yRing.show()
self.yDisc.show()
self.zPost.show()
self.zRing.show()
self.zDisc.show()
def hideAllHandles(self):
self.xPost.hide()
self.xRing.hide()
self.xDisc.hide()
self.yPost.hide()
self.yRing.hide()
self.yDisc.hide()
self.zPost.hide()
self.zRing.hide()
self.zDisc.hide()
def showHandle(self, handle):
if handle == 'x-post':
self.xPost.show()
elif handle == 'x-ring':
self.xRing.show()
elif handle == 'x-disc':
self.xDisc.show()
elif handle == 'y-post':
self.yPost.show()
elif handle == 'y-ring':
self.yRing.show()
elif handle == 'y-disc':
self.yDisc.show()
elif handle == 'z-post':
self.zPost.show()
elif handle == 'z-ring':
self.zRing.show()
elif handle == 'z-disc':
self.zDisc.show()
def showGuides(self):
self.guideLines.show()
def hideGuides(self):
self.guideLines.hide()
def setScalingFactor(self, scaleFactor):
self.ohScalingFactor = scaleFactor
self.scalingNode.setScale(self.ohScalingFactor)
def getScalingFactor(self):
return self.scalingNode.getScale()
def transferObjectHandlesScale(self):
# see how much object handles have been scaled
ohs = self.getScale()
sns = self.scalingNode.getScale()
# Transfer this to the scaling node
self.scalingNode.setScale(
ohs[0] * sns[0],
ohs[1] * sns[1],
ohs[2] * sns[2])
self.setScale(1)
def multiplyScalingFactorBy(self, factor):
taskMgr.removeTasksNamed('resizeObjectHandles')
sf = self.ohScalingFactor = self.ohScalingFactor * factor
self.scalingNode.lerpScale(sf,sf,sf, 0.5,
blendType = 'easeInOut',
task = 'resizeObjectHandles')
def growToFit(self):
taskMgr.removeTasksNamed('resizeObjectHandles')
# Increase handles scale until they cover 30% of the min dimension
pos = self.direct.widget.getPos(self.direct.camera)
minDim = min(self.direct.chan.nearWidth, self.direct.chan.nearHeight)
sf = 0.15 * minDim * (pos[1]/self.direct.chan.near)
self.ohScalingFactor = sf
self.scalingNode.lerpScale(sf,sf,sf, 0.5,
blendType = 'easeInOut',
task = 'resizeObjectHandles')
def createObjectHandleLines(self):
# X post
self.xPost = self.xPostGroup.attachNewNode(NamedNode('x-post-visible'))
lines = LineNodePath(self.xPost)
lines.setColor(VBase4(1,0,0,1))
lines.setThickness(5)
lines.moveTo(0,0,0)
lines.drawTo(1.5,0,0)
lines.create()
lines = LineNodePath(self.xPost)
lines.setColor(VBase4(1,0,0,1))
lines.setThickness(1.5)
lines.moveTo(0,0,0)
lines.drawTo(-1.5,0,0)
lines.create()
# X ring
self.xRing = self.xRingGroup.attachNewNode(NamedNode('x-ring-visible'))
lines = LineNodePath(self.xRing)
lines.setColor(VBase4(1,0,0,1))
lines.setThickness(3)
lines.moveTo(0,1,0)
for ang in range(15, 370, 15):
lines.drawTo(0,
math.cos(deg2Rad(ang)),
math.sin(deg2Rad(ang)))
lines.create()
# Y post
self.yPost = self.yPostGroup.attachNewNode(NamedNode('y-post-visible'))
lines = LineNodePath(self.yPost)
lines.setColor(VBase4(0,1,0,1))
lines.setThickness(5)
lines.moveTo(0,0,0)
lines.drawTo(0,1.5,0)
lines.create()
lines = LineNodePath(self.yPost)
lines.setColor(VBase4(0,1,0,1))
lines.setThickness(1.5)
lines.moveTo(0,0,0)
lines.drawTo(0,-1.5,0)
lines.create()
# Y ring
self.yRing = self.yRingGroup.attachNewNode(NamedNode('y-ring-visible'))
lines = LineNodePath(self.yRing)
lines.setColor(VBase4(0,1,0,1))
lines.setThickness(3)
lines.moveTo(1,0,0)
for ang in range(15, 370, 15):
lines.drawTo(math.cos(deg2Rad(ang)),
0,
math.sin(deg2Rad(ang)))
lines.create()
# Z post
self.zPost = self.zPostGroup.attachNewNode(NamedNode('z-post-visible'))
lines = LineNodePath(self.zPost)
lines.setColor(VBase4(0,0,1,1))
lines.setThickness(5)
lines.moveTo(0,0,0)
lines.drawTo(0,0,1.5)
lines.create()
lines = LineNodePath(self.zPost)
lines.setColor(VBase4(0,0,1,1))
lines.setThickness(1.5)
lines.moveTo(0,0,0)
lines.drawTo(0,0,-1.5)
lines.create()
# Z ring
self.zRing = self.zRingGroup.attachNewNode(NamedNode('z-ring-visible'))
lines = LineNodePath(self.zRing)
lines.setColor(VBase4(0,0,1,1))
lines.setThickness(3)
lines.moveTo(1,0,0)
for ang in range(15, 370, 15):
lines.drawTo(math.cos(deg2Rad(ang)),
math.sin(deg2Rad(ang)),
0)
lines.create()
def createGuideLines(self):
self.guideLines = self.attachNewNode(NamedNode('guideLines'))
# X guide lines
lines = LineNodePath(self.guideLines)
lines.setColor(VBase4(1,0,0,1))
lines.setThickness(0.5)
lines.moveTo(-500,0,0)
lines.drawTo(500,0,0)
lines.create()
lines.node().setName('x-guide')
# Y guide lines
lines = LineNodePath(self.guideLines)
lines.setColor(VBase4(0,1,0,1))
lines.setThickness(0.5)
lines.moveTo(0,-500,0)
lines.drawTo(0,500,0)
lines.create()
lines.node().setName('y-guide')
# Z guide lines
lines = LineNodePath(self.guideLines)
lines.setColor(VBase4(0,0,1,1))
lines.setThickness(0.5)
lines.moveTo(0,0,-500)
lines.drawTo(0,0,500)
lines.create()
lines.node().setName('z-guide')
def getAxisIntersectPt(self, axis):
# Calc the xfrom from camera to widget
mCam2Widget = self.direct.camera.getMat(self.direct.widget)
lineDir = Vec3(mCam2Widget.xformVec(self.direct.chan.nearVec))
lineDir.normalize()
# And determine where the viewpoint is relative to widget
lineOrigin = VBase3(0)
decomposeMatrix(mCam2Widget, VBase3(0), VBase3(0), lineOrigin,
getDefaultCoordinateSystem())
# Now see where this hits the plane containing the 1D motion axis.
# Pick the intersection plane most normal to the intersection ray
# by comparing lineDir with plane normals. The plane with the
# largest dotProduct is most "normal"
if axis == 'x':
if (abs(lineDir.dot(Y_AXIS)) > abs(lineDir.dot(Z_AXIS))):
self.hitPt.assign(
planeIntersect(lineOrigin, lineDir, ORIGIN, Y_AXIS))
else:
self.hitPt.assign(
planeIntersect(lineOrigin, lineDir, ORIGIN, Z_AXIS))
# We really only care about the nearest point on the axis
self.hitPt.setY(0)
self.hitPt.setZ(0)
elif axis == 'y':
if (abs(lineDir.dot(X_AXIS)) > abs(lineDir.dot(Z_AXIS))):
self.hitPt.assign(
planeIntersect(lineOrigin, lineDir, ORIGIN, X_AXIS))
else:
self.hitPt.assign(
planeIntersect(lineOrigin, lineDir, ORIGIN, Z_AXIS))
# We really only care about the nearest point on the axis
self.hitPt.setX(0)
self.hitPt.setZ(0)
elif axis == 'z':
if (abs(lineDir.dot(X_AXIS)) > abs(lineDir.dot(Y_AXIS))):
self.hitPt.assign(
planeIntersect(lineOrigin, lineDir, ORIGIN, X_AXIS))
else:
self.hitPt.assign(
planeIntersect(lineOrigin, lineDir, ORIGIN, Y_AXIS))
# We really only care about the nearest point on the axis
self.hitPt.setX(0)
self.hitPt.setY(0)
return self.hitPt
def getWidgetIntersectPt(self, nodePath, plane):
# Find out the point of interection of the ray passing though the mouse
# with the plane containing the 2D xlation or 1D rotation widgets
# Calc the xfrom from camera to the nodePath
mCam2NodePath = self.direct.camera.getMat(nodePath)
# And determine where the viewpoint is relative to widget
lineOrigin = VBase3(0)
decomposeMatrix(mCam2NodePath, VBase3(0), VBase3(0), lineOrigin,
getDefaultCoordinateSystem())
# Next we find the vector from viewpoint to the widget through
# the mouse's position on near plane.
# This defines the intersection ray
lineDir = Vec3(mCam2NodePath.xformVec(self.direct.chan.nearVec))
lineDir.normalize()
# Find the hit point
if plane == 'x':
self.hitPt.assign(planeIntersect(
lineOrigin, lineDir, ORIGIN, X_AXIS))
elif plane == 'y':
self.hitPt.assign(planeIntersect(
lineOrigin, lineDir, ORIGIN, Y_AXIS))
elif plane == 'z':
self.hitPt.assign(planeIntersect(
lineOrigin, lineDir, ORIGIN, Z_AXIS))
return self.hitPt