def link(self, param, val):
if self.is_valid():
arnold.AiNodeLink(self.data, param, val.data)
def _worker(data, new_data, redraw_event, mmap_size, mmap_name, state):
print("+++ _worker: started")
import os
import ctypes
dir = os.path.dirname(__file__)
if dir not in sys.path:
sys.path.append(dir)
import arnold
nodes = {}
lights = {}
nptrs = [] # nodes linked by AiNodeSetPtr
links = [] # nodes linked by AiNodeLink
def _AiNodeSetArray(node, param, value):
t, a = value
_len = len(a)
if t == arnold.AI_TYPE_VECTOR:
_len //= 3
elif t == arnold.AI_TYPE_UINT:
pass
_a = arnold.AiArrayConvert(_len, 1, t, ctypes.c_void_p(a.ctypes.data))
arnold.AiNodeSetArray(node, param, _a)
_AiNodeSet = {
'NodeSocketShader': lambda n, i, v: True,
'NodeSocketBool': lambda n, i, v: arnold.AiNodeSetBool(n, i, v),
'NodeSocketInt': lambda n, i, v: arnold.AiNodeSetInt(n, i, v),
'NodeSocketFloat': lambda n, i, v: arnold.AiNodeSetFlt(n, i, v),
'NodeSocketColor': lambda n, i, v: arnold.AiNodeSetRGBA(n, i, *v),
'NodeSocketVector': lambda n, i, v: arnold.AiNodeSetVec(n, i, *v),
'NodeSocketVectorXYZ':
lambda n, i, v: arnold.AiNodeSetVector(n, i, *v),
'NodeSocketString': lambda n, i, v: arnold.AiNodeSetStr(n, i, v),
'ArnoldNodeSocketColor': lambda n, i, v: arnold.AiNodeSetRGB(n, i, *v),
'ArnoldNodeSocketByte': lambda n, i, v: arnold.AiNodeSetByte(n, i, v),
'ArnoldNodeSocketProperty': lambda n, i, v: True,
'BOOL': lambda n, p, v: arnold.AiNodeSetBool(n, p, v),
'BYTE': lambda n, p, v: arnold.AiNodeSetByte(n, p, v),
'INT': lambda n, p, v: arnold.AiNodeSetInt(n, p, v),
'FLOAT': lambda n, p, v: arnold.AiNodeSetFlt(n, p, v),
'VECTOR2': lambda n, p, v: arnold.AiNodeSetVec2(n, p, *v),
'RGB': lambda n, p, v: arnold.AiNodeSetRGB(n, p, *v),
'RGBA': lambda n, p, v: arnold.AiNodeSetRGBA(n, p, *v),
'VECTOR': lambda n, p, v: arnold.AiNodeSetVec(n, p, *v),
'STRING': lambda n, p, v: arnold.AiNodeSetStr(n, p, v),
'MATRIX':
lambda n, p, v: arnold.AiNodeSetMatrix(n, p, arnold.AtMatrix(*v)),
'ARRAY': _AiNodeSetArray,
'LINK': lambda n, p, v: links.append((n, p, v)),
'NODE': lambda n, p, v: nptrs.append((n, p, v)),
}
arnold.AiBegin()
try:
# arnold.AiMsgSetConsoleFlags(arnold.AI_LOG_ALL)
# arnold.AiMsgSetConsoleFlags(0x000E)
#
# from pprint import pprint as pp
# pp(data)
## Nodes
for node in data['nodes']:
nt, np = node
anode = arnold.AiNode(nt)
for n, (t, v) in np.items():
_AiNodeSet[t](anode, n, v)
nodes[id(node)] = anode
for light in data['lights']:
nt, np = light
anode = arnold.AiNode(nt)
for n, (t, v) in np.items():
_AiNodeSet[t](anode, n, v)
lights[id(light)] = anode
options = arnold.AiUniverseGetOptions()
for n, (t, v) in data['options'].items():
_AiNodeSet[t](options, n, v)
for n, p, v in nptrs:
arnold.AiNodeSetPtr(n, p, nodes[id(v)])
for n, p, v in links:
arnold.AiNodeLink(nodes[id(v)], p, n)
## Outputs
filter = arnold.AiNode("gaussian_filter")
arnold.AiNodeSetStr(filter, "name", "__filter")
driver = arnold.AiNode("driver_display_callback")
arnold.AiNodeSetStr(driver, "name", "__driver")
#arnold.AiNodeSetBool(driver, "rgba_packing", False)
outputs_aovs = (b"RGBA RGBA __filter __driver", )
outputs = arnold.AiArray(len(outputs_aovs), 1, arnold.AI_TYPE_STRING,
*outputs_aovs)
arnold.AiNodeSetArray(options, "outputs", outputs)
sl = data['sl']
del nodes, nptrs, links, data
if platform.system() == "Darwin" or "Linux":
_rect = lambda w, h: numpy.frombuffer(mmap.mmap(-1, w * h * 4 * 4),
dtype=numpy.float32).reshape(
[h, w, 4])
rect = _rect(*mmap_size)
if platform.system() == "Windows":
_rect = lambda n, w, h: numpy.frombuffer(
mmap.mmap(-1, w * h * 4 * 4, n), dtype=numpy.float32).reshape(
[h, w, 4])
rect = _rect(mmap_name, *mmap_size)
def _callback(x, y, width, height, buffer, data):
#print("+++ _callback:", x, y, width, height, ctypes.cast(buffer, ctypes.c_void_p))
if buffer:
try:
if new_data.poll():
arnold.AiRenderInterrupt()
else:
#print("+++ _callback: tile", x, y, width, height)
_buffer = ctypes.cast(buffer,
ctypes.POINTER(ctypes.c_uint16))
a = numpy.ctypeslib.as_array(_buffer,
shape=(height, width, 4))
rect[y:y + height, x:x + width] = a
redraw_event.set()
return
finally:
arnold.AiFree(buffer)
elif not new_data.poll():
return
arnold.AiRenderAbort()
print("+++ _callback: abort")
cb = arnold.AtDisplayCallBack(_callback)
arnold.AiNodeSetPtr(driver, "callback", cb)
class _Dict(dict):
def update(self, u):
for k, v in u.items():
if isinstance(v, dict):
self[k] = _Dict.update(self.get(k, {}), v)
else:
self[k] = u[k]
return self
while state.value != ABORT:
for _sl in range(*sl):
arnold.AiNodeSetInt(options, "AA_samples", _sl)
res = arnold.AiRender(arnold.AI_RENDER_MODE_CAMERA)
if res == arnold.AI_SUCCESS:
break
if state.value == ABORT:
#print("+++ _worker: abort")
break
data = _Dict()
_data = new_data.recv()
print(_data)
while _data is not None:
# from pprint import pprint as pp
# print("+++ _worker: data")
# pp(_data)
data.update(_data)
if not new_data.poll():
_nodes = data.get('nodes')
if _nodes is not None:
for name, params in _nodes.items():
node = arnold.AiNodeLookUpByName(name)
for n, (t, v) in params.items():
_AiNodeSet[t](node, n, v)
opts = data.get('options')
if opts is not None:
for n, (t, v) in opts.items():
_AiNodeSet[t](options, n, v)
size = data.get('mmap_size')
if size is not None:
rect = _rect(mmap_name, *size)
break
_data = new_data.recv()
finally:
arnold.AiEnd()
print("+++ _worker: finished")
def renderGeo(self):
arnold.AiBegin()
arnold.AiMsgSetLogFileName(self._logFile)
arnold.AiMsgSetConsoleFlags(arnold.AI_LOG_ALL)
# create a sphere geometric primitive
sph = arnold.AiNode("sphere")
arnold.AiNodeSetStr(sph, "name", "mysphere")
arnold.AiNodeSetVec(sph, "center", 0.0, 4.0, 0.0)
arnold.AiNodeSetFlt(sph, "radius", 4.0)
# create a red standard shader
shader1 = arnold.AiNode("standard")
arnold.AiNodeSetStr(shader1, "name", "myshader1")
arnold.AiNodeSetRGB(shader1, "Kd_color", self._color[0],
self._color[1], self._color[2])
arnold.AiNodeSetFlt(shader1, "Ks", 0.05)
# assign the shaders to the geometric objects
arnold.AiNodeSetPtr(sph, "shader", shader1)
# create a polymesh, with UV coordinates
mesh = arnold.AiNode("polymesh")
arnold.AiNodeSetStr(mesh, "name", "mymesh")
nsides_array = arnold.AiArray(1, 1, arnold.AI_TYPE_UINT, 4)
arnold.AiNodeSetArray(mesh, "nsides", nsides_array)
vlist_array = arnold.AiArray(12, 1, arnold.AI_TYPE_FLOAT, -10.0, 0.0,
10.0, 10.0, 0.0, 10.0, -10.0, 0.0, -10.0,
10.0, 0.0, -10.0)
arnold.AiNodeSetArray(mesh, "vlist", vlist_array)
vidxs_array = arnold.AiArray(4, 1, arnold.AI_TYPE_UINT, 0, 1, 3, 2)
arnold.AiNodeSetArray(mesh, "vidxs", vidxs_array)
uvlist_array = arnold.AiArray(8, 1, arnold.AI_TYPE_FLOAT, 0.0, 0.0,
1.0, 0.0, 1.0, 1.0, 0.0, 1.0)
arnold.AiNodeSetArray(mesh, "uvlist", uvlist_array)
uvidxs_array = arnold.AiArray(4, 1, arnold.AI_TYPE_UINT, 0, 1, 2, 3)
arnold.AiNodeSetArray(mesh, "uvidxs", uvidxs_array)
# create a textured standard shader
shader2 = arnold.AiNode("standard")
arnold.AiNodeSetStr(shader2, "name", "myshader2")
arnold.AiNodeSetRGB(shader2, "Kd_color", 1.0, 0.0, 0.0)
# create an image shader for texture mapping
image = arnold.AiNode("image")
arnold.AiNodeSetStr(image, "name", "myimage")
arnold.AiNodeSetStr(image, "filename", "scene1.jpg")
arnold.AiNodeSetFlt(image, "sscale", 4.0)
arnold.AiNodeSetFlt(image, "tscale", 4.0)
# link the output of the image shader to the color input of the standard shader
arnold.AiNodeLink(image, "Kd_color", shader2)
# create a perspective camera
camera = arnold.AiNode("persp_camera")
arnold.AiNodeSetStr(camera, "name", "mycamera")
# position the camera (alternatively you can set 'matrix')
arnold.AiNodeSetVec(camera, "position", 0.0, 10.0, 35.0)
arnold.AiNodeSetVec(camera, "look_at", 0.0, 3.0, 0.0)
arnold.AiNodeSetFlt(camera, "fov", 45.0)
# create a point light source
light = arnold.AiNode("point_light")
arnold.AiNodeSetStr(light, "name", "mylight")
# // position the light (alternatively use 'matrix')
arnold.AiNodeSetVec(light, "position", 15.0, 30.0, 15.0)
arnold.AiNodeSetFlt(light, "intensity", 4500.0)
# alternatively, use 'exposure'
arnold.AiNodeSetFlt(light, "radius", 4.0)
# for soft shadows
# // get the global options node and set some options
options = arnold.AiUniverseGetOptions()
arnold.AiNodeSetInt(options, "AA_samples", 8)
arnold.AiNodeSetInt(options, "xres", 480)
arnold.AiNodeSetInt(options, "yres", 360)
arnold.AiNodeSetInt(options, "GI_diffuse_depth", 4)
# // set the active camera (optional, since there is only one camera)
arnold.AiNodeSetPtr(options, "camera", camera)
# create an output driver node
driver = arnold.AiNode("driver_jpeg")
arnold.AiNodeSetStr(driver, "name", "mydriver")
arnold.AiNodeSetStr(driver, "filename", self._sceneName)
arnold.AiNodeSetFlt(driver, "gamma", 2.2)
# create a gaussian filter node
filter = arnold.AiNode("gaussian_filter")
arnold.AiNodeSetStr(filter, "name", "myfilter")
# assign the driver and filter to the main (beauty) AOV,
# which is called "RGBA" and is of type RGBA
outputs_array = arnold.AiArrayAllocate(1, 1, arnold.AI_TYPE_STRING)
arnold.AiArraySetStr(outputs_array, 0, "RGBA RGBA myfilter mydriver")
arnold.AiNodeSetArray(options, "outputs", outputs_array)
# finally, render the image!
arnold.AiRender(arnold.AI_RENDER_MODE_CAMERA)
# // Arnold session shutdown
arnold.AiEnd()
