def __init__(self, name, format = GeomVertexFormat.getV3()):
self.views = []
self.vertexBuffer = GeomVertexData(name + "-vdata", format, GeomEnums.UHDynamic)
self.np = NodePath(name)
self.np.node().setBounds(OmniBoundingVolume())
self.np.node().setFinal(1)
def _CreateOneSynapse(self, presynCell, synapsesType):
presynCell.setPresynapticFocus() # highlight presynaptic cells
form = GeomVertexFormat.getV3()
vdata = GeomVertexData("SynapseLine", form, Geom.UHStatic)
vdata.setNumRows(1)
vertex = GeomVertexWriter(vdata, "vertex")
vertex.addData3f(presynCell.getNode().getPos(self._node))
vertex.addData3f(0, 0, 0)
prim = GeomLines(Geom.UHStatic)
prim.addVertices(0, 1)
geom = Geom(vdata)
geom.addPrimitive(prim)
node = GeomNode("Synapse_" + str(synapsesType))
node.addGeom(geom)
nodePath = self._node.attachNewNode(node)
nodePath.setRenderModeThickness(2)
# color of the line
if presynCell.active:
nodePath.setColor(COL_DISTAL_SYNAPSES_ACTIVE)
else:
nodePath.setColor(COL_DISTAL_SYNAPSES_INACTIVE)
def makeRotationGeomNode():
vdata = GeomVertexData('rotHandleData', GeomVertexFormat.getV3(),
Geom.UHStatic)
v = GeomVertexWriter(vdata, 'vertex')
radius = 0.7
width = 0.08
res = 30
innerRad = radius - width
for i in xrange(res):
theta = i*(2*pi/res)
v.addData3f(innerRad*sin(theta), innerRad*cos(theta), width/2.0)
v.addData3f(innerRad*sin(theta), innerRad*cos(theta), -width/2.0)
v.addData3f(radius*sin(theta), radius*cos(theta), width/2.0)
v.addData3f(radius*sin(theta), radius*cos(theta), -width/2.0)
circle = Geom(vdata)
# Make prims for the faces of the torus
faces = [GeomTristrips(Geom.UHStatic) for i in xrange(4)]
for i in xrange(res):
i = i*4
faces[0].addVertices(i + 1, i)
faces[1].addVertices(i + 2, i + 1)
faces[2].addVertices(i + 3, i + 2)
faces[3].addVertices(i, i + 3)
for i in xrange(4):
faces[i].addVertices((i + 1) % 4, i)
faces[i].closePrimitive()
circle.addPrimitive(faces[i])
node = GeomNode('geomnode')
node.addGeom(circle)
return node
def _CreateOneSynapse(self, presynCell, synapsesType):
form = GeomVertexFormat.getV3()
vdata = GeomVertexData("SynapseLine", form, Geom.UHStatic)
vdata.setNumRows(1)
vertex = GeomVertexWriter(vdata, "vertex")
vertex.addData3f(presynCell.getNode().getPos(self.__node))
vertex.addData3f(0, 0, 0)
# vertex.addData3f(self.__node.getPos())
# printLog("inputObj:"+str(i)+"bits:"+str(y))
# printLog(inputObj[i].inputBits[y].getNode().getPos(self.__node))
prim = GeomLines(Geom.UHStatic)
prim.addVertices(0, 1)
geom = Geom(vdata)
geom.addPrimitive(prim)
node = GeomNode("Synapse_" + str(synapsesType))
node.addGeom(geom)
nodePath = self.__cellsNodePath.attachNewNode(node)
nodePath.setRenderModeThickness(2)
# color of the line
if presynCell.active:
nodePath.setColor(COL_PROXIMAL_SYNAPSES_ACTIVE)
else:
nodePath.setColor(COL_PROXIMAL_SYNAPSES_INACTIVE)
def addMeshConvexRB(self,vertices, faces,ghost=False,**kw):
#step 1) create GeomVertexData and add vertex information
format=GeomVertexFormat.getV3()
vdata=GeomVertexData("vertices", format, Geom.UHStatic)
vertexWriter=GeomVertexWriter(vdata, "vertex")
[vertexWriter.addData3f(v[0],v[1],v[2]) for v in vertices]
#step 2) make primitives and assign vertices to them
tris=GeomTriangles(Geom.UHStatic)
[self.setGeomFaces(tris,face) for face in faces]
#step 3) make a Geom object to hold the primitives
geom=Geom(vdata)
geom.addPrimitive(tris)
#step 4) create the bullet mesh and node
mesh = BulletTriangleMesh()
mesh.addGeom(geom)
shape = BulletConvexHullShape(mesh, dynamic=not ghost)#
if ghost :
inodenp = self.worldNP.attachNewNode(BulletGhostNode('Mesh'))
else :
inodenp = self.worldNP.attachNewNode(BulletRigidBodyNode('Mesh'))
inodenp.node().addShape(shape)
# inodenp.setPos(0, 0, 0.1)
self.setRB(inodenp,**kw)
inodenp.setCollideMask(BitMask32.allOn())
self.world.attachRigidBody(inodenp.node())
return inodenp
def __init__(self, whl_pos, whl_radius, car_h):
GameObject.__init__(self)
self.radius = whl_radius
v_f = GeomVertexFormat.getV3()
vdata = GeomVertexData('skid', v_f, Geom.UHDynamic)
prim = GeomTriangles(Geom.UHStatic)
self.vtx_cnt = 1
self.last_pos = whl_pos
geom = Geom(vdata)
geom.add_primitive(prim)
self.node = GeomNode('gnode')
self.node.add_geom(geom)
nodepath = self.eng.gfx.root.attach_node(self.node)
nodepath.set_transparency(True)
nodepath.set_depth_offset(1)
nodepath.node.set_two_sided(True) # for self-shadowing issues
self.__set_material(nodepath)
nodepath.p3dnode.set_bounds(OmniBoundingVolume())
self.add_vertices(whl_radius, car_h)
self.add_vertices(whl_radius, car_h)
def alpha(time, n_p):
if not n_p.is_empty:
n_p.node.set_shader_input('alpha', time)
# this if seems necessary since, if there are skidmarks and you
# exit from the race (e.g. back to the menu), then alpha is being
# called from the interval manager even if the interval manager
# correctly says that there are 0 intervals.
self.remove_seq = Sequence(
Wait(8), LerpFunc(alpha, 8, .5, 0, 'easeInOut', [nodepath]),
Func(nodepath.remove_node))
self.remove_seq.start()
def makeRotationGeomNode():
vdata = GeomVertexData('rotHandleData', GeomVertexFormat.getV3(),
Geom.UHStatic)
v = GeomVertexWriter(vdata, 'vertex')
radius = 0.7
width = 0.08
res = 30
innerRad = radius - width
for i in xrange(res):
theta = i * (2 * pi / res)
v.addData3f(innerRad * sin(theta), innerRad * cos(theta), width / 2.0)
v.addData3f(innerRad * sin(theta), innerRad * cos(theta), -width / 2.0)
v.addData3f(radius * sin(theta), radius * cos(theta), width / 2.0)
v.addData3f(radius * sin(theta), radius * cos(theta), -width / 2.0)
circle = Geom(vdata)
# Make prims for the faces of the torus
faces = [GeomTristrips(Geom.UHStatic) for i in xrange(4)]
for i in xrange(res):
i = i * 4
faces[0].addVertices(i + 1, i)
faces[1].addVertices(i + 2, i + 1)
faces[2].addVertices(i + 3, i + 2)
faces[3].addVertices(i, i + 3)
for i in xrange(4):
faces[i].addVertices((i + 1) % 4, i)
faces[i].closePrimitive()
circle.addPrimitive(faces[i])
node = GeomNode('geomnode')
node.addGeom(circle)
return node
def create_instance(self):
self.vertexData = GeomVertexData('vertexData',
GeomVertexFormat.getV3(),
Geom.UHStatic)
self.vertexWriter = GeomVertexWriter(self.vertexData, 'vertex')
radius = 1.0
top = LPoint3d(0, 0, radius * 1.25)
north_pole = LPoint3d(0, 0, radius)
south_pole = LPoint3d(0, 0, -radius)
bottom = LPoint3d(0, 0, -radius * 1.25)
self.vertexWriter.addData3f(*top)
self.vertexWriter.addData3f(*north_pole)
self.vertexWriter.addData3f(*south_pole)
self.vertexWriter.addData3f(*bottom)
self.lines = GeomLines(Geom.UHStatic)
self.lines.addVertex(0)
self.lines.addVertex(1)
self.lines.addVertex(2)
self.lines.addVertex(3)
self.lines.closePrimitive()
self.geom = Geom(self.vertexData)
self.geom.addPrimitive(self.lines)
self.node = GeomNode(self.body.get_ascii_name() + '-axis')
self.node.addGeom(self.geom)
self.instance = NodePath(self.node)
self.instance.setRenderModeThickness(settings.axis_thickness)
self.instance.setColor(self.parent.get_orbit_color())
self.instance.setAntialias(AntialiasAttrib.MMultisample)
self.instance.reparentTo(self.context.annotation)
def makeSprite(name, texture, scale, add = False):
from panda3d.core import (GeomVertexFormat, GeomVertexData, GeomEnums,
InternalName, GeomVertexWriter, GeomPoints,
Geom, GeomNode, NodePath, TextureStage,
TexGenAttrib, BoundingSphere)
format = GeomVertexFormat.getV3()
data = GeomVertexData(name + "_data", format, GeomEnums.UHStatic)
writer = GeomVertexWriter(data, InternalName.getVertex())
writer.addData3f((0, 0, 0))
primitive = GeomPoints(GeomEnums.UHStatic)
primitive.addVertex(0)
primitive.closePrimitive()
geom = Geom(data)
geom.addPrimitive(primitive)
geomNode = GeomNode(name)
geomNode.addGeom(geom)
np = NodePath(geomNode)
np.setLightOff(1)
np.setMaterialOff(1)
np.setRenderModePerspective(True)
ts = TextureStage('sprite')
if add:
ts.setMode(TextureStage.MAdd)
np.setTexture(ts, texture)
np.setTexGen(ts, TexGenAttrib.MPointSprite)
np.setDepthWrite(False)
np.setDepthOffset(1)
np.setTransparency(True)
np.node().setBounds(BoundingSphere((0, 0, 0), 1))
np.node().setFinal(True)
np.flattenStrong()
np.setScale(scale)
return np
def __init__(self, wheel_pos, radius, heading):
self.radius = radius
v_f = GeomVertexFormat.getV3()
self.vdata = GeomVertexData('skid', v_f, Geom.UHDynamic)
self.vdata.setNumRows(1)
self.vertex = GeomVertexWriter(self.vdata, 'vertex')
self.prim = GeomTriangles(Geom.UHStatic)
self.cnt = 1
self.last_pos = wheel_pos
geom = Geom(self.vdata)
geom.addPrimitive(self.prim)
node = GeomNode('gnode')
node.addGeom(geom)
nodePath = render.attachNewNode(node)
nodePath.setTransparency(True)
nodePath.setDepthOffset(1)
self.__set_material(nodePath)
nodePath.node().setBounds(OmniBoundingVolume())
self.add_vertices(radius, heading)
self.add_vertices(radius, heading)
self.remove_seq = Sequence(
Wait(8),
LerpFunc(nodePath.setAlphaScale, 8, 1, 0, 'easeInOut'),
Func(nodePath.remove_node))
self.remove_seq.start()
def Cube(size=1.0,
geom_name="CubeMaker",
gvd_name="Data",
gvw_name="vertex"):
from panda3d.core import (
Vec3,
GeomVertexFormat,
GeomVertexData,
GeomVertexWriter,
GeomTriangles,
Geom,
GeomNode,
NodePath,
GeomPoints,
loadPrcFileData,
)
format = GeomVertexFormat.getV3()
data = GeomVertexData(gvd_name, format, Geom.UHStatic)
vertices = GeomVertexWriter(data, gvw_name)
size = float(size) / 2.0
vertices.addData3f(-size, -size, -size)
vertices.addData3f(+size, -size, -size)
vertices.addData3f(-size, +size, -size)
vertices.addData3f(+size, +size, -size)
vertices.addData3f(-size, -size, +size)
vertices.addData3f(+size, -size, +size)
vertices.addData3f(-size, +size, +size)
vertices.addData3f(+size, +size, +size)
triangles = GeomTriangles(Geom.UHStatic)
def addQuad(v0, v1, v2, v3):
triangles.addVertices(v0, v1, v2)
triangles.addVertices(v0, v2, v3)
triangles.closePrimitive()
addQuad(4, 5, 7, 6) # Z+
addQuad(0, 2, 3, 1) # Z-
addQuad(3, 7, 5, 1) # X+
addQuad(4, 6, 2, 0) # X-
addQuad(2, 6, 7, 3) # Y+
addQuad(0, 1, 5, 4) # Y+
geom = Geom(data)
geom.addPrimitive(triangles)
node = GeomNode(geom_name)
node.addGeom(geom)
return NodePath(node)
def __init__(self, name='ConstrainedDelaunayTriangles', geomVertexDataObj=None,
format=GeomVertexFormat.getV3(), usage=Geom.UHDynamic,
onVertexCreationCallback=None, universalZ=0):
if geomVertexDataObj is None:
geomVertexDataObj = GeomVertexData(name, format, usage)
self.vertexData = geomVertexDataObj
# self.vertexRewriter = GeomVertexRewriter(self.vertexData, 'vertex')
if onVertexCreationCallback is None:
onVertexCreationCallback = lambda vdata: None
self._onVertexCreationCallback = onVertexCreationCallback
self.universalZ = universalZ
def makeGeomNode():
vdata = GeomVertexData('handleData', GeomVertexFormat.getV3(),
Geom.UHStatic)
v = GeomVertexWriter(vdata, 'vertex')
length = 1.0
gapLen = 0.2
coneLen = 0.18
coneRad = 0.06
circRes = 10
v.addData3f(0, 0, -length/2.0) # back cone butt
v.addData3f(0, 0, -length/2.0 + coneLen) # back cone point
v.addData3f(0, 0, -gapLen/2.0)
v.addData3f(0, 0, gapLen/2.0)
v.addData3f(0, 0, length/2.0 - coneLen) # front cone butt
v.addData3f(0, 0, length/2.0) # font cone point
# Add vertices for the cone's circles.
for z in [-length/2.0, length/2.0 - coneLen]:
for i in xrange(circRes):
theta = i*(2*pi/circRes)
v.addData3f(coneRad*sin(theta), coneRad*cos(theta), z)
lines = Geom(vdata)
# Make prims for the two lines.
for vertices in [(0, 2), (3, 5)]:
line = GeomLines(Geom.UHStatic)
line.addVertices(*vertices)
line.closePrimitive()
lines.addPrimitive(line)
cones = Geom(vdata)
# Make prims for the cones.
for back, circ in [(0, 6), (4, 6 + circRes)]:
point = back + 1
cone = GeomTriangles(Geom.UHStatic)
for i in xrange(circRes):
if i + 1 == circRes:
cone.addVertices(back, circ, circ + i)
cone.addVertices(point, circ + i, circ)
else:
cone.addVertices(back, circ + i + 1, circ + i)
cone.addVertices(point, circ + i, circ + i + 1)
cone.closePrimitive()
cones.addPrimitive(cone)
node = GeomNode('geomnode')
node.addGeom(lines)
node.addGeom(cones)
return node
def makeGeomNode():
vdata = GeomVertexData('handleData', GeomVertexFormat.getV3(),
Geom.UHStatic)
v = GeomVertexWriter(vdata, 'vertex')
length = 1.0
gapLen = 0.2
coneLen = 0.18
coneRad = 0.06
circRes = 10
v.addData3f(0, 0, -length / 2.0) # back cone butt
v.addData3f(0, 0, -length / 2.0 + coneLen) # back cone point
v.addData3f(0, 0, -gapLen / 2.0)
v.addData3f(0, 0, gapLen / 2.0)
v.addData3f(0, 0, length / 2.0 - coneLen) # front cone butt
v.addData3f(0, 0, length / 2.0) # font cone point
# Add vertices for the cone's circles.
for z in [-length / 2.0, length / 2.0 - coneLen]:
for i in xrange(circRes):
theta = i * (2 * pi / circRes)
v.addData3f(coneRad * sin(theta), coneRad * cos(theta), z)
lines = Geom(vdata)
# Make prims for the two lines.
for vertices in [(0, 2), (3, 5)]:
line = GeomLines(Geom.UHStatic)
line.addVertices(*vertices)
line.closePrimitive()
lines.addPrimitive(line)
cones = Geom(vdata)
# Make prims for the cones.
for back, circ in [(0, 6), (4, 6 + circRes)]:
point = back + 1
cone = GeomTriangles(Geom.UHStatic)
for i in xrange(circRes):
if i + 1 == circRes:
cone.addVertices(back, circ, circ + i)
cone.addVertices(point, circ + i, circ)
else:
cone.addVertices(back, circ + i + 1, circ + i)
cone.addVertices(point, circ + i, circ + i + 1)
cone.closePrimitive()
cones.addPrimitive(cone)
node = GeomNode('geomnode')
node.addGeom(lines)
node.addGeom(cones)
return node
def create_instance(self):
if not self.orbit:
return
self.vertexData = GeomVertexData('vertexData',
GeomVertexFormat.getV3(),
Geom.UHStatic)
self.vertexWriter = GeomVertexWriter(self.vertexData, 'vertex')
delta = self.body.parent.get_local_position()
for i in range(self.nbOfPoints):
time = self.orbit.period / self.nbOfPoints * i
pos = self.orbit.get_position_at(time)
rot = self.orbit.get_rotation_at(time)
pos = self.orbit.frame.get_local_position(rot.xform(pos)) - delta
self.vertexWriter.addData3f(*pos)
self.lines = GeomLines(Geom.UHStatic)
for i in range(self.nbOfPoints - 1):
self.lines.addVertex(i)
self.lines.addVertex(i + 1)
self.lines.closePrimitive()
self.lines.addVertex(self.nbOfPoints - 1)
self.lines.addVertex(0)
self.lines.closePrimitive()
self.geom = Geom(self.vertexData)
self.geom.addPrimitive(self.lines)
self.node = GeomNode(self.body.get_ascii_name() + '-orbit')
self.node.addGeom(self.geom)
self.instance = NodePath(self.node)
self.instance.setRenderModeThickness(settings.orbit_thickness)
self.instance.setCollideMask(GeomNode.getDefaultCollideMask())
self.instance.node().setPythonTag('owner', self)
self.instance.reparentTo(self.context.annotation_shader)
if self.color is None:
self.color = self.parent.get_orbit_color()
self.instance.setColor(self.color * self.fade)
self.instance.setAntialias(AntialiasAttrib.MMultisample)
self.appearance = ModelAppearance(attribute_color=True)
if settings.use_inv_scaling:
vertex_control = LargeObjectVertexControl()
else:
vertex_control = None
self.instance_ready = True
self.shader = BasicShader(lighting_model=FlatLightingModel(),
vertex_control=vertex_control)
self.shader.apply(self, self.appearance)
self.shader.update(self, self.appearance)
def makeNode(self, pointmap=(lambda x, y: (x, y, 0))):
vt = tuple(self.vertices)
t = Triangulator()
fmt = GeomVertexFormat.getV3()
vdata = GeomVertexData('name', fmt, Geom.UHStatic)
vertex = GeomVertexWriter(vdata, 'vertex')
for x, y in vt:
t.addPolygonVertex(t.addVertex(x, y))
vertex.addData3f(pointmap(x, y))
t.triangulate()
prim = GeomTriangles(Geom.UHStatic)
for n in xrange(t.getNumTriangles()):
prim.addVertices(t.getTriangleV0(n),t.getTriangleV1(n),t.getTriangleV2(n))
prim.closePrimitive()
geom = Geom(vdata)
geom.addPrimitive(prim)
node = GeomNode('gnode')
node.addGeom(geom)
return node
def __init__(self):
ShowBase.__init__(self) # 初期化
vs = open('vs_water.glsl', "r", encoding="UTF-8").read()
fs = open('fs_water.glsl', "r", encoding="UTF-8").read()
props = WindowProperties()
props.setTitle('Fragment')
Win_size = (1920, 1080) # ウィンドウサイズ
props.setSize(Win_size) # ウィンドウのサイズを設定
props.setCursorHidden(True) # マウスカーソルを隠す
base.win.requestProperties(props)
self.AspectRaito = float(Win_size[0] / Win_size[1]) # アスペクト比を計算
self.accept("escape", sys.exit) # 終了
self.disableMouse() # マウスカーソルを非表示
self.setFrameRateMeter(True) # FPSを表示
camera.setPos(0, -2, 0) # カメラを配置
format = GeomVertexFormat.getV3()
mesh = GeomVertexData('', format, Geom.UHDynamic) # メッシュを用意
vertex = GeomVertexWriter(mesh, 'vertex') # 頂点オブジェクト
vertex.addData3(-1, 0, -1) # 頂点を追加
vertex.addData3(-1, 0, 1)
vertex.addData3(1, 0, 1)
vertex.addData3(1, 0, -1)
tri = GeomTriangles(Geom.UHDynamic) # 面オブジェクト
tri.addVertices(0, 2, 1) # 面のインデックスを追加
tri.addVertices(0, 3, 2)
node = GeomNode('')
geo = Geom(mesh) # ジオメトリオブジェクト
geo.addPrimitive(tri) # プリミティブにする
node.addGeom(geo)
self.panel = render.attachNewNode(node) # レンダーオブジェクトとして追加
shader = Shader.make(Shader.SL_GLSL, vs, fs)
self.panel.setShader(shader)
resolution = self.win.getXSize(), self.win.getYSize()
self.panel.setShaderInput('resolution', resolution)
taskMgr.add(self.Loop, 'update') # メインループ
def Patch(size=1.0):
(path, node) = empty_node('patch')
form = GeomVertexFormat.getV3()
vdata = GeomVertexData("vertices", form, Geom.UHStatic)
vertexWriter = GeomVertexWriter(vdata, b"vertex")
vertexWriter.addData3f(-size, -size, 0)
vertexWriter.addData3f(size, -size, 0)
vertexWriter.addData3f(size, size, 0)
vertexWriter.addData3f(-size, size, 0)
patches = GeomPatches(4, Geom.UHStatic)
patches.addConsecutiveVertices(0, 4) #South, west, north, east
patches.closePrimitive()
gm = Geom(vdata)
gm.addPrimitive(patches)
node.addGeom(gm)
return path
def CreateTestScene(self):
form = GeomVertexFormat.getV3()
vdata = GeomVertexData("myLine", form, Geom.UHStatic)
vdata.setNumRows(1)
vertex = GeomVertexWriter(vdata, "vertex")
vertex.addData3f(0, 0, 0)
vertex.addData3f(60, 0, 50)
prim = GeomLines(Geom.UHStatic)
prim.addVertices(0, 1)
geom = Geom(vdata)
geom.addPrimitive(prim)
node = GeomNode("gnode")
node.addGeom(geom)
nodePath = self.render.attachNewNode(node)
def addLine(self, points):
"""
Adds a line to class GeomNode from a pair of points
"""
#Creates objects needed to draw a geometry on the HUD
#The vertex data which will define the rendered geometry
vertex_data = GeomVertexData("graph", GeomVertexFormat.getV3(),
Geom.UHStatic)
#The object that writes vertexes the vertex data
writer = GeomVertexWriter(vertex_data, "vertex")
for point in points:
writer.add_data3f(point[0], 0, point[1])
#Defines that this geometry represents a polyline
primitive = GeomLinestrips(Geom.UHStatic)
#Tells geometry how many verticies will be added(?)
primitive.add_consecutive_vertices(0, 2)
primitive.close_primitive()
geometry = Geom(vertex_data)
geometry.add_primitive(primitive)
#Draws a graph on the HUD
self.geom_node.add_geom(geometry)
def makeClickableGeom():
vdata = GeomVertexData('handleData', GeomVertexFormat.getV3(),
Geom.UHStatic)
v = GeomVertexWriter(vdata, 'vertex')
length = 1.0
cylRad = 0.10
circRes = 8
# Add vertices cylinder.
for z in [length / 2.0, -length / 2.0]:
for i in xrange(circRes):
theta = i * (2 * pi / circRes)
v.addData3f(cylRad * sin(theta), cylRad * cos(theta), z)
geom = Geom(vdata)
# Make polys for the circles
CCW = 1
CW = 0
for i, wind in ((0, CCW), (circRes, CW)):
circle = GeomTristrips(Geom.UHStatic)
l = range(i, i + circRes)
for i in xrange(1 - wind, (len(l) - wind) / 2):
l.insert(2 * i + wind, l.pop())
for v in l:
circle.addVertex(v)
circle.closePrimitive()
geom.addPrimitive(circle)
# Make polys for the cylinder.
cyl = GeomTristrips(Geom.UHStatic)
for i in xrange(circRes):
cyl.addVertex(i + circRes)
cyl.addVertex(i)
cyl.addVertex(circRes)
cyl.addVertex(0)
cyl.closePrimitive()
geom.addPrimitive(cyl)
node = GeomNode('geomnode')
node.addGeom(geom)
return node
def createPlane(width,height):
format=GeomVertexFormat.getV3()
vdata=GeomVertexData("vertices", format, Geom.UHStatic)
vertexWriter=GeomVertexWriter(vdata, "vertex")
vertexWriter.addData3f(0,0,0)
vertexWriter.addData3f(width,0,0)
vertexWriter.addData3f(width,height,0)
vertexWriter.addData3f(0,height,0)
#step 2) make primitives and assign vertices to them
tris=GeomTriangles(Geom.UHStatic)
#have to add vertices one by one since they are not in order
tris.addVertex(0)
tris.addVertex(1)
tris.addVertex(3)
#indicates that we have finished adding vertices for the first triangle.
tris.closePrimitive()
#since the coordinates are in order we can use this convenience function.
tris.addConsecutiveVertices(1,3) #add vertex 1, 2 and 3
tris.closePrimitive()
#step 3) make a Geom object to hold the primitives
squareGeom=Geom(vdata)
squareGeom.addPrimitive(tris)
#now put squareGeom in a GeomNode. You can now position your geometry in the scene graph.
squareGN=GeomNode("square")
squareGN.addGeom(squareGeom)
terrainNode = NodePath("terrNode")
terrainNode.reparentTo(render)
terrainNode.attachNewNode(squareGN)
terrainNode.setX(-width/2)
texGrass = loader.loadTexture("textures/envir-ground.jpg")
terrainNode.setTexture(texGrass)
def makeClickableGeom():
vdata = GeomVertexData('handleData', GeomVertexFormat.getV3(),
Geom.UHStatic)
v = GeomVertexWriter(vdata, 'vertex')
length = 1.0
cylRad = 0.10
circRes = 8
# Add vertices cylinder.
for z in [length/2.0, -length/2.0]:
for i in xrange(circRes):
theta = i*(2*pi/circRes)
v.addData3f(cylRad*sin(theta), cylRad*cos(theta), z)
geom = Geom(vdata)
# Make polys for the circles
CCW = 1
CW = 0
for i, wind in ((0, CCW), (circRes, CW)):
circle = GeomTristrips(Geom.UHStatic)
l = range(i, i+circRes)
for i in xrange(1-wind, (len(l)-wind)/2):
l.insert(2*i+wind, l.pop())
for v in l:
circle.addVertex(v)
circle.closePrimitive()
geom.addPrimitive(circle)
# Make polys for the cylinder.
cyl = GeomTristrips(Geom.UHStatic)
for i in xrange(circRes):
cyl.addVertex(i + circRes)
cyl.addVertex(i)
cyl.addVertex(circRes)
cyl.addVertex(0)
cyl.closePrimitive()
geom.addPrimitive(cyl)
node = GeomNode('geomnode')
node.addGeom(geom)
return node
def create_instance(self):
self.vertexData = GeomVertexData('vertexData', GeomVertexFormat.getV3(), Geom.UHStatic)
self.vertexWriter = GeomVertexWriter(self.vertexData, 'vertex')
delta = self.body.parent.get_local_position()
if self.orbit.is_periodic():
epoch = self.context.time.time_full - self.orbit.period / 2
step = self.orbit.period / (self.nbOfPoints - 1)
else:
#TODO: Properly calculate orbit start and end time
epoch = self.orbit.get_time_of_perihelion() - self.orbit.period * 5.0
step = self.orbit.period * 10.0 / (self.nbOfPoints - 1)
for i in range(self.nbOfPoints):
time = epoch + step * i
pos = self.orbit.get_position_at(time) - delta
self.vertexWriter.addData3f(*pos)
self.lines = GeomLines(Geom.UHStatic)
for i in range(self.nbOfPoints-1):
self.lines.addVertex(i)
self.lines.addVertex(i+1)
if self.orbit.is_periodic() and self.orbit.is_closed():
self.lines.addVertex(self.nbOfPoints-1)
self.lines.addVertex(0)
self.geom = Geom(self.vertexData)
self.geom.addPrimitive(self.lines)
self.node = GeomNode(self.body.get_ascii_name() + '-orbit')
self.node.addGeom(self.geom)
self.instance = NodePath(self.node)
self.instance.setRenderModeThickness(settings.orbit_thickness)
self.instance.setCollideMask(GeomNode.getDefaultCollideMask())
self.instance.node().setPythonTag('owner', self)
self.instance.reparentTo(self.context.annotation)
if self.color is None:
self.color = self.parent.get_orbit_color()
self.instance.setColor(srgb_to_linear(self.color * self.fade))
self.instance_ready = True
if self.shader is None:
self.create_shader()
self.shader.apply(self, self.appearance)
self.shader.update(self, self.appearance)
def QuadPatch(x0,
y0,
x1,
y1,
x_inverted=False,
y_inverted=False,
xy_swap=False,
offset=None):
(x0, y0, x1, y1, dx, dy) = convert_xy(x0, y0, x1, y1, x_inverted,
y_inverted, xy_swap)
if offset is None:
offset = 1.0
(path, node) = empty_node('patch')
form = GeomVertexFormat.getV3()
vdata = GeomVertexData("vertices", form, Geom.UHStatic)
vertexWriter = GeomVertexWriter(vdata, b"vertex")
x0 = 2.0 * x0 - 1.0
x1 = 2.0 * x1 - 1.0
y0 = 2.0 * y0 - 1.0
y1 = 2.0 * y1 - 1.0
vertexWriter.addData3f(x0, y0, offset)
vertexWriter.addData3f(x1, y0, offset)
vertexWriter.addData3f(x1, y1, offset)
vertexWriter.addData3f(x0, y1, offset)
patches = GeomPatches(4, Geom.UHStatic)
patches.addConsecutiveVertices(0, 4) #South, west, north, east
patches.closePrimitive()
gm = Geom(vdata)
gm.addPrimitive(patches)
node.addGeom(gm)
return path
def __init__(self, vertexName='ConstrainedDelaunayTriangles', vertexFormat=GeomVertexFormat.getV3(),
usage = Geom.UHDynamic, onVertexCreationCallback = None, universalZ = 0.0):
self._vertexData = GeomVertexData(vertexName, vertexFormat, Geom.UHDynamic)
self._geomTriangles = GeomTriangles(usage)
self._geomTrianglesHoles = GeomTriangles(usage)
self._vertexRewriter = GeomVertexRewriter(self._vertexData, 'vertex') # user cannot have control of a writer
if onVertexCreationCallback is None:
onVertexCreationCallback = lambda x, y, z: None # something to call without checking existence later
self._vertexCallback = onVertexCreationCallback
self._universalZ = universalZ
self.__holes = [[]]
self.__polygon = []
inf = float('inf')
negInf = float('-inf')
self.bounds = {
'minX': inf,
'maxX': negInf,
'minY': inf,
'maxY': negInf,
}
self.lastStaticVertexIndex = -1
def line (self, start, end):
# since we're doing line segments, just vertices in our geom
format = GeomVertexFormat.getV3()
# build our data structure and get a handle to the vertex column
vdata = GeomVertexData ('', format, Geom.UHStatic)
vertices = GeomVertexWriter (vdata, 'vertex')
# build a linestrip vertex buffer
lines = GeomLinestrips (Geom.UHStatic)
vertices.addData3f (start[0], start[1], start[2])
vertices.addData3f (end[0], end[1], end[2])
lines.addVertices (0, 1)
lines.closePrimitive()
geom = Geom (vdata)
geom.addPrimitive (lines)
# Add our primitive to the geomnode
#self.gnode.addGeom (geom)
return geom
def generate(self):
format = GeomVertexFormat.getV3()
data = GeomVertexData("Data", format, Geom.UHStatic)
vertices = GeomVertexWriter(data, "vertex")
size = self.size
vertices.addData3f(-size, -size, -size)
vertices.addData3f(+size, -size, -size)
vertices.addData3f(-size, +size, -size)
vertices.addData3f(+size, +size, -size)
vertices.addData3f(-size, -size, +size)
vertices.addData3f(+size, -size, +size)
vertices.addData3f(-size, +size, +size)
vertices.addData3f(+size, +size, +size)
triangles = GeomTriangles(Geom.UHStatic)
def addQuad(v0, v1, v2, v3):
triangles.addVertices(v0, v1, v2)
triangles.addVertices(v0, v2, v3)
triangles.closePrimitive()
addQuad(4, 5, 7, 6) # Z+
addQuad(0, 2, 3, 1) # Z-
addQuad(3, 7, 5, 1) # X+
addQuad(4, 6, 2, 0) # X-
addQuad(2, 6, 7, 3) # Y+
addQuad(0, 1, 5, 4) # Y+
geom = Geom(data)
geom.addPrimitive(triangles)
node = GeomNode("CubeMaker")
node.addGeom(geom)
cube = NodePath(node)
cube.setColor(0.0, 1.0, 1.0)
return cube
def line(self):
# Create and populate the Moon orbit model using Vertices and Lines
self.planetOrbitVertexData = GeomVertexData(self.description+'OrbitVertexData', GeomVertexFormat.getV3(), Geom.UHDynamic)
self.planetOrbitVertexWriter = GeomVertexWriter(self.planetOrbitVertexData, 'vertex')
self.planetOrbitNumberPoints = 360
for i in range(self.planetOrbitNumberPoints):
angleDegrees = i * 360 / self.planetOrbitNumberPoints
angleRadians = angleDegrees * (pi / 180.0)
x = -self.distance * sin(angleRadians)
y = self.distance * cos(angleRadians)
self.planetOrbitVertexWriter.addData3f(x, y, 0.0)
self.planetOrbitLines = GeomLines(Geom.UHStatic)
for i in range(self.planetOrbitNumberPoints-1):
self.planetOrbitLines.addVertex(i)
self.planetOrbitLines.addVertex(i+1)
self.planetOrbitLines.closePrimitive()
self.planetOrbitLines.addVertex(self.planetOrbitNumberPoints-1)
self.planetOrbitLines.addVertex(0)
self.planetOrbitLines.closePrimitive()
self.planetOrbitGeom = Geom(self.planetOrbitVertexData)
self.planetOrbitGeom.addPrimitive(self.planetOrbitLines)
self.planetOrbitNode = GeomNode(self.description+'OrbitNode')
self.planetOrbitNode.addGeom(self.planetOrbitGeom)
self.planetOrbitNnodePath = render.attachNewNode(self.planetOrbitNode)
self.planetOrbitNnodePath.reparentTo(self.worldOrigin)
return self.planetOrbitVertexWriter
def CreateProximalSynapses(self, inputNames, inputObj, permanences, thresholdConnected, createOnlyActive=False):
self.DestroyProximalSynapses()
printLog("Creating proximal permanences", verbosityMedium)
printLog("To inputObj called:" + str(inputNames), verbosityMedium)
printLog("permanences count:" + str(len(permanences)), verbosityMedium)
printLog("active:" + str(sum([i for i in permanences])), verbosityHigh)
# inputObj are divided into separate items in list - [input1,input2,input3]
# permanences are one united array [1,0,0,1,0,1,0...]
# length is the same
# synapses can be connected to one input or to several inputObj
# if to more than one - split synapses array
synapsesDiv = []
offset = 0
for inputName in inputNames:
synapsesDiv.append(permanences[offset : offset + inputObj[inputName].count])
offset += inputObj[inputName].count
for i in range(len(synapsesDiv)): # for each input object
inputObj[inputNames[i]].resetProximalFocus() # clear color highlight
for y in range(
len(synapsesDiv[i])
): # go through every synapse and check if its connected (we are comparing permanences)
if synapsesDiv[i][y] >= thresholdConnected:
if createOnlyActive and not inputObj[inputNames[i]].inputBits[y].active:# we want to show only active synapses
continue
form = GeomVertexFormat.getV3()
vdata = GeomVertexData("ProximalSynapseLine", form, Geom.UHStatic)
vdata.setNumRows(1)
vertex = GeomVertexWriter(vdata, "vertex")
vertex.addData3f(
inputObj[inputNames[i]]
.inputBits[y]
.getNode()
.getPos(self.__node)
)
vertex.addData3f(0, 0, 0)
# vertex.addData3f(self.__node.getPos())
# printLog("inputObj:"+str(i)+"bits:"+str(y))
# printLog(inputObj[i].inputBits[y].getNode().getPos(self.__node))
# highlight
inputObj[inputNames[i]].inputBits[
y
].setProximalFocus() # highlight connected bits
prim = GeomLines(Geom.UHStatic)
prim.addVertices(0, 1)
geom = Geom(vdata)
geom.addPrimitive(prim)
node = GeomNode("ProximalSynapse")
node.addGeom(geom)
nodePath = self.__cellsNodePath.attachNewNode(node)
nodePath.setRenderModeThickness(2)
# color of the line
if inputObj[inputNames[i]].inputBits[y].active:
nodePath.setColor(COL_PROXIMAL_SYNAPSES_ACTIVE)
else:
nodePath.setColor(COL_PROXIMAL_SYNAPSES_INACTIVE)
def generate(
self
): # call this after setting some of the variables to update it
if not self.vertices:
return
if hasattr(self, 'geomNode'):
self.geomNode.removeAllGeoms()
static_mode = Geom.UHStatic if self.static else Geom.UHDynamic
formats = {
(0, 0, 0): GeomVertexFormat.getV3(),
(1, 0, 0): GeomVertexFormat.getV3c4(),
(0, 1, 0): GeomVertexFormat.getV3t2(),
(0, 0, 1): GeomVertexFormat.getV3n3(),
(1, 0, 1): GeomVertexFormat.getV3n3c4(),
(1, 1, 0): GeomVertexFormat.getV3c4t2(),
(0, 1, 1): GeomVertexFormat.getV3n3t2(),
(1, 1, 1): GeomVertexFormat.getV3n3c4t2(),
}
vertex_format = formats[(bool(self.colors), bool(self.uvs),
bool(self.normals))]
vdata = GeomVertexData('name', vertex_format, static_mode)
vdata.setNumRows(len(self.vertices)) # for speed
vertexwriter = GeomVertexWriter(vdata, 'vertex')
for v in self.vertices:
vertexwriter.addData3f((v[0], v[2], v[1])) # swap y and z
if self.colors:
colorwriter = GeomVertexWriter(vdata, 'color')
for c in self.colors:
colorwriter.addData4f(c)
if self.uvs:
uvwriter = GeomVertexWriter(vdata, 'texcoord')
for uv in self.uvs:
uvwriter.addData2f(uv[0], uv[1])
if self.normals != None:
normalwriter = GeomVertexWriter(vdata, 'normal')
for norm in self.normals:
normalwriter.addData3f((norm[0], norm[2], norm[1]))
modes = {
'triangle': GeomTriangles(static_mode),
'tristrip': GeomTristrips(static_mode),
'ngon': GeomTrifans(static_mode),
'line': GeomLines(static_mode),
'lines': GeomLinestrips(static_mode),
'point': GeomPoints(static_mode),
}
if self.mode == 'line' and len(self.vertices) % 2 > 0:
if len(self.vertices) == 1:
self.mode = point
print(
'warning: number of vertices must be even for line mode, ignoring last vert'
)
self.vertices = self.vertices[:len(self.vertices) - 1]
prim = modes[self.mode]
if self._triangles:
if isinstance(self._triangles[0], int):
for t in self._triangles:
prim.addVertex(t)
elif len(
self._triangles[0]
) >= 3: # if tris are tuples like this: ((0,1,2), (1,2,3))
for t in self._triangles:
if len(t) == 3:
for e in t:
prim.addVertex(e)
elif len(t) == 4: # turn quad into tris
prim.addVertex(t[0])
prim.addVertex(t[1])
prim.addVertex(t[2])
prim.addVertex(t[2])
prim.addVertex(t[3])
prim.addVertex(t[0])
else:
prim.addConsecutiveVertices(0, len(self.vertices))
prim.close_primitive()
geom = Geom(vdata)
geom.addPrimitive(prim)
self.geomNode = GeomNode('mesh')
self.geomNode.addGeom(geom)
self.attachNewNode(self.geomNode)
# print('finished')
self.recipe = f'''Mesh(
def draw_shape(angles, width, radius):
res = 10
if radius == 0:
point = GeomNode('gnode')
vdata = GeomVertexData('occ', GeomVertexFormat.getV3(), Geom.UHStatic)
vdata.setNumRows(1)
vertex = GeomVertexWriter(vdata, 'vertex')
vertex.addData3f(0, 0, 0)
geom = Geom(vdata)
g = GeomPoints(Geom.UHStatic)
g.addVertex(0)
geom.addPrimitive(g)
point.addGeom(geom)
return point, point
#first, sort angles in ascending order
#if negative is given, translate to range of 2pi
for i in range(len(angles)):
if angles[i] < 0: angles[i] = 360 + angles[i]
angles.sort()
angles = [math.radians(a) for a in angles]
angles.append(angles[0]) #read first angle to account for wrapping around
#function = 'w/sin(theta)'
vdata = GeomVertexData('occ', GeomVertexFormat.getV3(), Geom.UHStatic)
vdata.setNumRows(1)
vertex = GeomVertexWriter(vdata, 'vertex')
numverts = [3] * (len(angles) - 1
) #center, and two points on function lines
for i in range(len(angles) - 1):
#find center point
#L = [None,None]
#sign = [-1,1]
#for p in range(2):
# theta1 = angles[i+p] - sign[p]*math.pi/2
# theta2 = angles[i+p] + sign[p]*math.pi/4
# x1 = width*math.cos(theta1)
# y1 = width*math.sin(theta1)
# r = math.sqrt(2*width**2)
# x2 = r*math.cos(theta2)
# y2 = r*math.sin(theta2)
# L[p] = line([x1,y1], [x2,y2])
#R = intersection(L[0],L[1])
#if R is False:
# R = [x1,y1] #if parallel, shift both lines down by y_width
#vertex.addData3f(R[0],R[1],1)
difang = (angles[i + 1] - angles[i]) / 2
l = width / math.sin(difang)
avgang = (angles[i] + angles[i + 1]) / 2
x0 = l * math.cos(avgang)
y0 = l * math.sin(avgang)
vertex.addData3f(x0, y0, 1)
newang1 = angles[i] + (math.pi / 2 - math.acos(width / radius))
x = radius * math.cos(newang1)
y = radius * math.sin(newang1)
vertex.addData3f(x, y, 1)
newang2 = angles[i + 1] - (math.pi / 2 - math.acos(width / radius))
for angle in arc(newang1, newang2, res):
vertex.addData3f(radius * math.cos(math.radians(angle)),
radius * math.sin(math.radians(angle)), 1)
numverts[i] = numverts[i] + 1
x = radius * math.cos(newang2)
y = radius * math.sin(newang2)
vertex.addData3f(x, y, 1)
#copy all data to the bottom, moving it down to z = -1
vertread = GeomVertexReader(vdata, 'vertex')
while not vertread.isAtEnd():
v = vertread.getData3f()
vertex.addData3f(v[0], v[1], -1)
#draw
geom = Geom(vdata)
#draw top
for i in range(len(angles) - 1):
for j in range(numverts[i] - 2):
ind = sum(numverts[0:i]) + j
g = GeomTriangles(Geom.UHStatic)
g.add_vertices(ind - j, ind + 1, ind + 2)
geom.addPrimitive(g)
#draw bottom
for i in range(len(angles) - 1):
for j in range(numverts[i] - 2):
ind = sum(numverts) + sum(numverts[0:i]) + j
g = GeomTriangles(Geom.UHStatic)
g.add_vertices(ind - j, ind + 2, ind + 1)
geom.addPrimitive(g)
#draw edges
for i in range(len(angles) - 1):
for j in range(numverts[i] - 1):
ind = sum(numverts[0:i]) + j
g = GeomTriangles(Geom.UHStatic)
g.add_vertices(ind, ind + sum(numverts), ind + 1)
g.add_vertices(ind + sum(numverts), ind + 1 + sum(numverts),
ind + 1)
geom.addPrimitive(g)
g = GeomTriangles(Geom.UHStatic)
ind = sum(numverts[0:i])
indx = sum(numverts[0:i + 1])
g.add_vertices(indx - 1, indx + sum(numverts) - 1, ind)
g.add_vertices(indx + sum(numverts) - 1, sum(numverts) + ind, ind)
geom.addPrimitive(g)
#outline object
lines = Geom(vdata)
l = GeomLines(Geom.UHStatic)
for i in range(len(angles) - 1):
for j in range(numverts[i] - 1):
ind = sum(numverts[0:i]) + j
l.add_vertices(ind, ind + 1)
l.add_vertices(sum(numverts) + ind, sum(numverts) + ind + 1)
ind = sum(numverts[0:i])
indx = sum(numverts[0:i + 1])
l.add_vertices(ind, indx - 1)
l.add_vertices(sum(numverts) + ind, sum(numverts) + indx - 1)
l.add_vertices(ind + 1, sum(numverts) + ind + 1)
l.add_vertices(indx - 1, sum(numverts) + indx - 1)
lines.addPrimitive(l)
node = GeomNode('gnode')
node.addGeom(geom)
nodeL = GeomNode('gnode')
nodeL.addGeom(lines)
return node, nodeL
def CreateProximalSynapses(self, inputObjects, inputs, synapses):
for child in self.__cellsNodePath.getChildren():
if child.getName() == "ProximalSynapseLine":
child.removeNode()
printLog("Creating proximal synapses", verbosityMedium)
printLog("To inputs called:" + str(inputObjects), verbosityMedium)
printLog("Synapses count:" + str(len(synapses)), verbosityMedium)
printLog("active:" + str(sum([i for i in synapses])), verbosityHigh)
# inputs are divided into separate items in list - [input1,input2,input3]
# synapses are one united array [1,0,0,1,0,1,0...]
# length is the same
# synapses can be connected to one input or to several inputs
# if to more than one - split synapses array
synapsesDiv = []
offset = 0
for inputObj in inputObjects:
synapsesDiv.append(synapses[offset:offset +
inputs[inputObj].count])
offset += inputs[inputObj].count
for i in range(len(synapsesDiv)): # for each input object
inputs[
inputObjects[i]].resetProximalFocus() # clear color highlight
for y in range(len(synapsesDiv[i])
): # go through every synapse and check activity
if synapsesDiv[i][y] == 1:
form = GeomVertexFormat.getV3()
vdata = GeomVertexData("ProximalSynapseLine", form,
Geom.UHStatic)
vdata.setNumRows(1)
vertex = GeomVertexWriter(vdata, "vertex")
vertex.addData3f(
inputs[inputObjects[i]].inputBits[y].getNode().getPos(
self.__node))
vertex.addData3f(0, 0, 0)
# vertex.addData3f(self.__node.getPos())
# printLog("Inputs:"+str(i)+"bits:"+str(y))
# printLog(inputs[i].inputBits[y].getNode().getPos(self.__node))
# highlight
inputs[inputObjects[i]].inputBits[y].setProximalFocus(
) # highlight connected bits
prim = GeomLines(Geom.UHStatic)
prim.addVertices(0, 1)
geom = Geom(vdata)
geom.addPrimitive(prim)
node = GeomNode("ProximalSynapse")
node.addGeom(geom)
nodePath = self.__cellsNodePath.attachNewNode(node)
nodePath.setRenderModeThickness(2)
# color of the line
if inputs[inputObjects[i]].inputBits[y].active:
nodePath.setColor(COL_PROXIMAL_SYNAPSES_ACTIVE)
else:
nodePath.setColor(COL_PROXIMAL_SYNAPSES_INACTIVE)
class Mesh(NodePath):
_formats = {
(0, 0, 0): GeomVertexFormat.getV3(),
(1, 0, 0): GeomVertexFormat.getV3c4(),
(0, 1, 0): GeomVertexFormat.getV3t2(),
(0, 0, 1): GeomVertexFormat.getV3n3(),
(1, 0, 1): GeomVertexFormat.getV3n3c4(),
(1, 1, 0): GeomVertexFormat.getV3c4t2(),
(0, 1, 1): GeomVertexFormat.getV3n3t2(),
(1, 1, 1): GeomVertexFormat.getV3n3c4t2(),
}
_modes = {
'triangle': GeomTriangles,
'tristrip': GeomTristrips,
'ngon': GeomTrifans,
'line': GeomLinestrips,
'point': GeomPoints,
}
def __init__(self,
vertices=None,
triangles=None,
colors=None,
uvs=None,
normals=None,
static=True,
mode='triangle',
thickness=1):
super().__init__('mesh')
self.vertices = vertices
self.triangles = triangles
self.colors = colors
self.uvs = uvs
self.normals = normals
self.static = static
self.mode = mode
self.thickness = thickness
for var in (('vertices', vertices), ('triangles', triangles),
('colors', colors), ('uvs', uvs), ('normals', normals)):
name, value = var
if value is None:
setattr(self, name, list())
if self.vertices:
self.generate()
def generate(
self
): # call this after setting some of the variables to update it
if hasattr(self, 'geomNode'):
self.geomNode.removeAllGeoms()
static_mode = Geom.UHStatic if self.static else Geom.UHDynamic
vertex_format = Mesh._formats[(bool(self.colors), bool(self.uvs),
bool(self.normals))]
vdata = GeomVertexData('name', vertex_format, static_mode)
vdata.setNumRows(len(self.vertices)) # for speed
if not hasattr(self, 'geomNode'):
self.geomNode = GeomNode('mesh')
self.attachNewNode(self.geomNode)
vertexwriter = GeomVertexWriter(vdata, 'vertex')
for v in self.vertices:
vertexwriter.addData3f(*v)
if self.colors:
colorwriter = GeomVertexWriter(vdata, 'color')
for c in self.colors:
colorwriter.addData4f(c)
if self.uvs:
uvwriter = GeomVertexWriter(vdata, 'texcoord')
for uv in self.uvs:
uvwriter.addData2f(uv[0], uv[1])
if self.normals != None:
normalwriter = GeomVertexWriter(vdata, 'normal')
for norm in self.normals:
normalwriter.addData3f(*norm)
if self.mode != 'line' or not self._triangles:
self.indices = list()
if self._triangles:
if isinstance(self._triangles[0], int):
for t in self._triangles:
self.indices.append(t)
elif len(
self._triangles[0]
) >= 3: # if tris are tuples like this: ((0,1,2), (1,2,3))
for t in self._triangles:
if len(t) == 3:
self.indices.extend(t)
elif len(t) == 4: # turn quad into tris
self.indices.extend(
[t[i] for i in (0, 1, 2, 2, 3, 0)])
else:
self.indices = [i for i in range(len(self.vertices))]
prim = Mesh._modes[self.mode](static_mode)
self.generated_vertices = [self.vertices[i] for i in self.indices]
for v in self.indices:
prim.addVertex(v)
prim.close_primitive()
geom = Geom(vdata)
geom.addPrimitive(prim)
self.geomNode.addGeom(geom)
else: # line with segments defined in triangles
for line in self._triangles:
prim = Mesh._modes[self.mode](static_mode)
for e in line:
prim.addVertex(e)
prim.close_primitive()
geom = Geom(vdata)
geom.addPrimitive(prim)
self.geomNode.addGeom(geom)
if self.mode == 'point':
self.setTexGen(TextureStage.getDefault(),
TexGenAttrib.MPointSprite)
# self.set_render_mode_perspective(True)
# print('finished')
@property
def recipe(self):
if hasattr(self, '_recipe'):
return self._recipe
return dedent(f'''
Mesh(
vertices={[tuple(e) for e in self.vertices]},
triangles={self._triangles},
colors={[tuple(e) for e in self.colors]},
uvs={self.uvs},
normals={[tuple(e) for e in self.normals]},
static={self.static},
mode="{self.mode}",
thickness={self.thickness}
)
''')
@recipe.setter
def recipe(self, value):
self._recipe = value
def __add__(self, other):
self.vertices += other.vertices
self.triangles += other.triangles
if other.colors:
self.colors += other.colors
else:
self.colors += (color.white, ) * len(other.vertices)
self.normals += other.normals
self.uvs += other.uvs
def __deepcopy__(self, memo):
m = Mesh(self.vertices, self.triangles, self.colors, self.uvs,
self.normals, self.static, self.mode, self.thickness)
m.name = self.name
return m
@property
def thickness(self):
return self.getRenderModeThickness()
@thickness.setter
def thickness(self, value):
self.setRenderModeThickness(value)
@property
def triangles(self):
if self._triangles == None:
self._triangles = [(i, i + 1, i + 2)
for i in range(0, len(self.vertices), 3)]
return self._triangles
@triangles.setter
def triangles(self, value):
self._triangles = value
def generate_normals(self, smooth=True):
self.normals = list(
generate_normals(self.vertices, self.triangles, smooth))
self.generate()
return self.normals
def colorize(self,
left=color.white,
right=color.blue,
down=color.red,
up=color.green,
back=color.white,
forward=color.white,
smooth=True,
world_space=True):
colorize(self, left, right, down, up, back, forward, smooth,
world_space)
def project_uvs(self, aspect_ratio=1, direction='forward'):
project_uvs(self, aspect_ratio)
def clear(self, regenerate=True):
self.vertices, self.triangles, self.colors, self.uvs, self.normals = list(
), list(), list(), list(), list()
if regenerate:
self.generate()
def save(self, name='', path=application.compressed_models_folder):
if not application.compressed_models_folder.exists():
application.compressed_models_folder.mkdir()
if not name and hasattr(self, 'path'):
name = self.path.stem
if not '.' in name:
name += '.ursinamesh'
if name.endswith('ursinamesh'):
with open(path / name, 'w') as f:
# recipe = self.recipe.replace('LVector3f', '')
f.write(self.recipe)
print('saved .ursinamesh to:', path / name)
elif name.endswith('.obj'):
from ursina.mesh_importer import ursina_mesh_to_obj
ursina_mesh_to_obj(self, name, path)
elif name.endswith('.bam'):
success = self.writeBamFile(path / name)
print('saved .bam to:', path / name)
def createModelClone(self, modelFilename):
newVisualCar = loader.loadModel(modelFilename)
geomNodeCollection = newVisualCar.findAllMatches('**/+GeomNode')
simpleTris = []
self.unmodifiedVertexData = []
for nodePath in geomNodeCollection:
geomNode = nodePath.node()
for i in range(geomNode.getNumGeoms()):
geom = geomNode.getGeom(i)
vdata = geom.getVertexData()
vertex = GeomVertexReader(vdata, 'vertex')
while not vertex.isAtEnd():
v = vertex.getData3f()
vertexModelX, vertexModelY, vertexModelZ = v
self.unmodifiedVertexData.append(
[vertexModelX, vertexModelY, vertexModelZ])
for primitiveIndex in range(geom.getNumPrimitives()):
prim = geom.getPrimitive(primitiveIndex)
prim = prim.decompose()
for p in range(prim.getNumPrimitives()):
s = prim.getPrimitiveStart(p)
e = prim.getPrimitiveEnd(p)
singleTriData = []
for i in range(s, e):
vertex.setRow(prim.getVertex(s))
vi = prim.getVertex(i)
singleTriData.append(vi)
simpleTris.append(singleTriData)
simpleVertices = self.unmodifiedVertexData
format = GeomVertexFormat.getV3()
vdata = GeomVertexData('shadow', format, Geom.UHDynamic)
self.pandaVertexData = vdata
vertex = GeomVertexWriter(vdata, 'vertex')
for vertexIndex in range(len(simpleVertices)):
simpleVertex = simpleVertices[vertexIndex]
vertex.addData3f(0, 0, 0)
tris = GeomTriangles(Geom.UHStatic)
for index in range(len(simpleTris)):
simpleTri = simpleTris[index]
tris.addVertex(simpleTri[0])
tris.addVertex(simpleTri[1])
tris.addVertex(simpleTri[2])
tris.closePrimitive()
shadow = Geom(vdata)
shadow.addPrimitive(tris)
snode = GeomNode('shadow')
snode.addGeom(shadow)
self.snode = snode
class Mesh(NodePath):
_formats = {
(0, 0, 0): GeomVertexFormat.getV3(),
(1, 0, 0): GeomVertexFormat.getV3c4(),
(0, 1, 0): GeomVertexFormat.getV3t2(),
(0, 0, 1): GeomVertexFormat.getV3n3(),
(1, 0, 1): GeomVertexFormat.getV3n3c4(),
(1, 1, 0): GeomVertexFormat.getV3c4t2(),
(0, 1, 1): GeomVertexFormat.getV3n3t2(),
(1, 1, 1): GeomVertexFormat.getV3n3c4t2(),
}
_modes = {
'triangle': GeomTriangles,
'tristrip': GeomTristrips,
'ngon': GeomTrifans,
'line': GeomLinestrips,
'point': GeomPoints,
}
def __init__(self,
vertices=None,
triangles=None,
colors=None,
uvs=None,
normals=None,
static=True,
mode='triangle',
thickness=1):
super().__init__('mesh')
self.vertices = vertices
self.triangles = triangles
self.colors = colors
self.uvs = uvs
self.normals = normals
self.static = static
self.mode = mode
self.thickness = thickness
for var in (('vertices', vertices), ('triangles', triangles),
('colors', colors), ('uvs', uvs), ('normals', normals)):
name, value = var
if value is None:
setattr(self, name, list())
if self.vertices:
self.vertices = [tuple(v) for v in self.vertices]
self.generate()
def generate(
self
): # call this after setting some of the variables to update it
if hasattr(self, 'geomNode'):
self.geomNode.removeAllGeoms()
static_mode = Geom.UHStatic if self.static else Geom.UHDynamic
vertex_format = Mesh._formats[(bool(self.colors), bool(self.uvs),
bool(self.normals))]
vdata = GeomVertexData('name', vertex_format, static_mode)
vdata.setNumRows(len(self.vertices)) # for speed
vertexwriter = GeomVertexWriter(vdata, 'vertex')
for v in self.vertices:
vertexwriter.addData3f((v[0], v[2], v[1])) # swap y and z
if self.colors:
colorwriter = GeomVertexWriter(vdata, 'color')
for c in self.colors:
colorwriter.addData4f(c)
if self.uvs:
uvwriter = GeomVertexWriter(vdata, 'texcoord')
for uv in self.uvs:
uvwriter.addData2f(uv[0], uv[1])
if self.normals != None:
normalwriter = GeomVertexWriter(vdata, 'normal')
for norm in self.normals:
normalwriter.addData3f((norm[0], norm[2], norm[1]))
if self.mode != 'line' or not self._triangles:
prim = Mesh._modes[self.mode](static_mode)
if self._triangles:
if isinstance(self._triangles[0], int):
for t in self._triangles:
prim.addVertex(t)
elif len(
self._triangles[0]
) >= 3: # if tris are tuples like this: ((0,1,2), (1,2,3))
for t in self._triangles:
if len(t) == 3:
for e in t:
prim.addVertex(e)
elif len(t) == 4: # turn quad into tris
prim.addVertex(t[0])
prim.addVertex(t[1])
prim.addVertex(t[2])
prim.addVertex(t[2])
prim.addVertex(t[3])
prim.addVertex(t[0])
else:
prim.addConsecutiveVertices(0, len(self.vertices))
prim.close_primitive()
geom = Geom(vdata)
geom.addPrimitive(prim)
else: # line with segments defined in triangles
for line in self._triangles:
prim = Mesh._modes[self.mode](static_mode)
for e in line:
prim.addVertex(e)
prim.close_primitive()
geom = Geom(vdata)
geom.addPrimitive(prim)
self.geomNode = GeomNode('mesh')
self.geomNode.addGeom(geom)
self.attachNewNode(self.geomNode)
# if self.normals:
# self.normals = [tuple(e) for e in self.normals]
self.recipe = dedent(f'''
Mesh(
vertices={[tuple(e) for e in self.vertices]},
triangles={self._triangles},
colors={[tuple(e) for e in self.colors]},
uvs={self.uvs},
normals={[tuple(e) for e in self.normals]},
static={self.static},
mode="{self.mode}",
thickness={self.thickness}
)
''')
# print('finished')
def __add__(self, other):
self.vertices += other.vertices
self.triangles += other.triangles
if other.colors:
self.colors += other.colors
else:
self.colors += (color.white, ) * len(other.vertices)
self.normals += other.normals
self.uvs += other.uvs
@property
def thickness(self):
return self.getRenderModeThickness()
@thickness.setter
def thickness(self, value):
self.setRenderModeThickness(value)
@property
def triangles(self):
if self._triangles == None:
self._triangles = [(i, i + 1, i + 2)
for i in range(0, len(self.vertices), 3)]
return self._triangles
@triangles.setter
def triangles(self, value):
self._triangles = value
def generate_normals(self, smooth=True):
self.normals = list(
generate_normals(self.vertices, self.triangles, smooth))
self.generate()
return self.normals
def colorize(self,
left=color.white,
right=color.blue,
down=color.red,
up=color.green,
back=color.white,
forward=color.white,
smooth=True,
world_space=True):
colorize(self, left, right, down, up, back, forward, smooth,
world_space)
def project_uvs(self, aspect_ratio=1, direction='forward'):
project_uvs(self, aspect_ratio)
def clear(self, regenerate=True):
self.vertices, self.triangles, self.colors, self.uvs, self.normals = list(
), list(), list(), list(), list()
if regenerate:
self.generate()
def save(self, name, path=application.asset_folder, filetype='ursinamesh'):
if filetype == 'ursinamesh':
if not '.' in name:
name += '.ursinamesh'
with open(path / name, 'w') as f:
recipe = self.recipe.replace('LVector3f', '')
f.write(recipe)
elif filetype == 'obj':
from ursina.mesh_importer import ursina_mesh_to_obj
ursina_mesh_to_obj(self, name, path)
def createModelClone(self,modelFilename):
newVisualCar = loader.loadModel(modelFilename)
geomNodeCollection = newVisualCar.findAllMatches('**/+GeomNode')
simpleTris=[]
self.unmodifiedVertexData=[]
for nodePath in geomNodeCollection:
geomNode = nodePath.node()
for i in range(geomNode.getNumGeoms()):
geom = geomNode.getGeom(i)
vdata = geom.getVertexData()
vertex = GeomVertexReader(vdata, 'vertex')
while not vertex.isAtEnd():
v=vertex.getData3f()
vertexModelX,vertexModelY,vertexModelZ=v
self.unmodifiedVertexData.append([vertexModelX,vertexModelY,vertexModelZ])
for primitiveIndex in range(geom.getNumPrimitives()):
prim=geom.getPrimitive(primitiveIndex)
prim=prim.decompose()
for p in range(prim.getNumPrimitives()):
s = prim.getPrimitiveStart(p)
e = prim.getPrimitiveEnd(p)
singleTriData=[]
for i in range(s, e):
vertex.setRow(prim.getVertex(s))
vi = prim.getVertex(i)
singleTriData.append(vi)
simpleTris.append(singleTriData)
simpleVertices=self.unmodifiedVertexData
format=GeomVertexFormat.getV3()
vdata=GeomVertexData('shadow', format, Geom.UHDynamic)
self.pandaVertexData=vdata
vertex=GeomVertexWriter(vdata, 'vertex')
for vertexIndex in range(len(simpleVertices)):
simpleVertex=simpleVertices[vertexIndex]
vertex.addData3f(0,0,0)
tris=GeomTriangles(Geom.UHStatic)
for index in range(len(simpleTris)):
simpleTri=simpleTris[index]
tris.addVertex(simpleTri[0])
tris.addVertex(simpleTri[1])
tris.addVertex(simpleTri[2])
tris.closePrimitive()
shadow=Geom(vdata)
shadow.addPrimitive(tris)
snode=GeomNode('shadow')
snode.addGeom(shadow)
self.snode=snode
