def __init__(self):
"""Constructs global for PIP.
"""
Node.reset_counter()
Curve.reset_counter()
Sign.reset_counter()
SpawnPoint.reset_counter()
Semaphore.reset_counter()
MapPoint.reset_counter()
TriggerPoint.reset_counter()
Intersection.reset_counter()
def __init__(self):
"""Constructs global for PIP.
"""
Node.reset_counter()
Curve.reset_counter()
Sign.reset_counter()
SpawnPoint.reset_counter()
Semaphore.reset_counter()
MapPoint.reset_counter()
TriggerPoint.reset_counter()
Intersection.reset_counter()
def get_as_section():
"""Gets global prefab information represented with SectionData structure class.
:return: packed globals as section data
:rtype: io_scs_tools.internals.structure.SectionData
"""
section = _SectionData("Global")
section.props.append(("NodeCount", Node.get_global_node_count()))
section.props.append(("TerrainPointCount", Node.get_global_tp_count()))
section.props.append(
("TerrainPointVariantCount", Node.get_global_tp_variant_count()))
section.props.append(("NavCurveCount", Curve.get_global_curve_count()))
section.props.append(("SignCount", Sign.get_global_sign_count()))
section.props.append(
("SpawnPointCount", SpawnPoint.get_global_spawn_point_count()))
section.props.append(
("SemaphoreCount", Semaphore.get_global_semaphore_count()))
section.props.append(
("MapPointCount", MapPoint.get_global_map_point_count()))
section.props.append(("TriggerPointCount",
TriggerPoint.get_global_trigger_point_count()))
section.props.append(("IntersectionCount",
Intersection.get_global_intersection_count()))
return section
def get_as_section():
"""Gets global prefab information represented with SectionData structure class.
:return: packed globals as section data
:rtype: io_scs_tools.internals.structure.SectionData
"""
section = _SectionData("Global")
section.props.append(("NodeCount", Node.get_global_node_count()))
section.props.append(("TerrainPointCount", Node.get_global_tp_count()))
section.props.append(("TerrainPointVariantCount", Node.get_global_tp_variant_count()))
section.props.append(("NavCurveCount", Curve.get_global_curve_count()))
section.props.append(("SignCount", Sign.get_global_sign_count()))
section.props.append(("SpawnPointCount", SpawnPoint.get_global_spawn_point_count()))
section.props.append(("SemaphoreCount", Semaphore.get_global_semaphore_count()))
section.props.append(("MapPointCount", MapPoint.get_global_map_point_count()))
section.props.append(("TriggerPointCount", TriggerPoint.get_global_trigger_point_count()))
section.props.append(("IntersectionCount", Intersection.get_global_intersection_count()))
return section
def execute(dirpath, filename, name_suffix, prefab_locator_list, offset_matrix, used_parts, used_terrain_points):
"""Exports PIP file from given locator list.
:param prefab_locator_list:
:type prefab_locator_list: list of bpy.types.Object
:param dirpath: directory export path
:type dirpath: str
:param filename: name of PIP file
:type filename: str
:param name_suffix: file name suffix
:type name_suffix: str
:param offset_matrix: offset matrix for locators
:type offset_matrix: mathutils.Matrix
:param used_parts: parts transitional structure for storing used parts inside this PIP export
:type used_parts: io_scs_tools.exp.transition_structs.parts.PartsTrans
:param used_terrain_points: terrain points transitional structure for accessing terrain points stored during PIM export
:type used_terrain_points: io_scs_tools.exp.transition_structs.terrain_points.TerrainPntsTrans
:return: True if successfull; otherwise False
:rtype: bool
"""
# CLEANUP CONNECTIONS DATA
_connections_group_wrapper.cleanup_on_export()
print("\n************************************")
print("** SCS PIP Exporter **")
print("** (c)2015 SCS Software **")
print("************************************\n")
(control_node_locs,
nav_point_locs,
sign_locs,
spawn_point_locs,
semaphore_locs,
map_point_locs,
trigger_point_locs) = __sort_locators_by_type__(prefab_locator_list)
pip_header = Header(2, filename)
pip_global = Globall()
pip_nodes = OrderedDict()
""":type: dict[int,Node]"""
pip_curves = OrderedDict()
""":type: dict[int, Curve]"""
pip_signs = []
""":type: list[Sign]"""
pip_spawn_points = []
""":type: list[SpawnPoint]"""
pip_semaphores = []
""":type: list[Semaphore]"""
pip_map_points = OrderedDict()
""":type: dict[str, MapPoint]"""
pip_trigger_points = OrderedDict()
""":type: dict[str, TriggerPoint]"""
pip_intersections = [OrderedDict(), OrderedDict(), OrderedDict()]
""":type: list[dict[str, list[Intersection]]]"""
# nodes creation
for locator in control_node_locs.values():
locator_scs_props = locator.scs_props
""":type: io_scs_tools.properties.object.ObjectSCSTools"""
curr_node_i = int(locator_scs_props.locator_prefab_con_node_index)
if curr_node_i not in pip_nodes:
pos, rot, scale = _get_scs_transformation_components(offset_matrix.inverted() * locator.matrix_world)
rot = Quaternion(rot) * Vector((0, 0, -1))
# create node with position and direction
cn = Node(curr_node_i, pos, rot)
# add terrain points
terrain_points = used_terrain_points.get(curr_node_i)
for variant_i in terrain_points:
# ensure variant entry for no terrain points case
cn.ensure_variant(variant_i)
for tp_entry in terrain_points[variant_i]:
cn.add_terrain_point(tp_entry.position, tp_entry.normal, variant_i)
pip_nodes[curr_node_i] = cn
else:
lprint("W Multiple Control Nodes with same index detected, only one per index will be exported!\n\t "
"Check Control Nodes in SCS Game Object with Root: %r", (filename,))
# curves creation
curves_dict = _connections_group_wrapper.get_curves(nav_point_locs.values())
for key, curve_entry in curves_dict.items():
loc0 = nav_point_locs[curves_dict[key].start]
loc0_scs_props = loc0.scs_props
""":type: io_scs_tools.properties.object.ObjectSCSTools"""
loc1 = nav_point_locs[curves_dict[key].end]
loc1_scs_props = loc1.scs_props
""":type: io_scs_tools.properties.object.ObjectSCSTools"""
# create curve and set properties
curve = __get_curve__(pip_curves, curve_entry.index, loc0.name)
pos, rot, scale = _get_scs_transformation_components(offset_matrix.inverted() * loc0.matrix_world)
curve.set_start(pos, rot)
pos, rot, scale = _get_scs_transformation_components(offset_matrix.inverted() * loc1.matrix_world)
curve.set_end(pos, rot)
curve.set_input_boundaries(loc0_scs_props)
curve.set_output_boundaries(loc1_scs_props)
curve.set_flags(loc0.scs_props, True)
curve.set_flags(loc1.scs_props, False)
curve.set_semaphore_id(int(loc0_scs_props.locator_prefab_np_traffic_semaphore))
curve.set_traffic_rule(loc0_scs_props.locator_prefab_np_traffic_rule)
# set next/prev curves
for next_key in curve_entry.next_curves:
next_curve = __get_curve__(pip_curves, curves_dict[next_key].index, curves_dict[next_key].start)
assert curve.add_next_curve(next_curve)
for prev_key in curve_entry.prev_curves:
prev_curve = __get_curve__(pip_curves, curves_dict[prev_key].index, curves_dict[prev_key].start)
assert curve.add_prev_curve(prev_curve)
# sync nodes input lanes
boundary_node_i = curve.get_input_node_index()
if 0 <= boundary_node_i < _PL_consts.PREFAB_NODE_COUNT_MAX:
if boundary_node_i in pip_nodes:
assert pip_nodes[boundary_node_i].set_input_lane(curve.get_input_lane_index(), curve.get_index())
else:
lprint("E None existing Boundary Node with index: %s used in Navigation Point: %r",
(boundary_node_i, loc0.name,))
# sync nodes output lanes
boundary_node_i = curve.get_output_node_index()
if 0 <= boundary_node_i < _PL_consts.PREFAB_NODE_COUNT_MAX:
if boundary_node_i in pip_nodes:
assert pip_nodes[boundary_node_i].set_output_lane(curve.get_output_lane_index(), curve.get_index())
else:
lprint("E None existing Boundary Node with index: %s used in Navigation Point: %r",
(boundary_node_i, loc1.name,))
Curve.prepare_curves(pip_curves.values())
# signs creation
for locator in sign_locs.values():
locator_scs_props = locator.scs_props
""":type: io_scs_tools.properties.object.ObjectSCSTools"""
# create sign and set properties
sign = Sign(locator.name, used_parts.ensure_part(locator))
pos, rot, scale = _get_scs_transformation_components(offset_matrix.inverted() * locator.matrix_world)
sign.set_position(pos)
sign.set_rotation(rot)
if ":" in locator_scs_props.locator_prefab_sign_model:
sign.set_model(locator_scs_props.locator_prefab_sign_model.split(":")[1].strip())
else:
lprint("W Invalid Sign Model: %r on locator: %r",
(locator_scs_props.locator_prefab_sign_model, locator.name))
pip_signs.append(sign)
# spawn points creation
for locator in spawn_point_locs.values():
locator_scs_props = locator.scs_props
""":type: io_scs_tools.properties.object.ObjectSCSTools"""
# create spawn point and set properties
spawn_point = SpawnPoint(locator.name)
pos, rot, scale = _get_scs_transformation_components(offset_matrix.inverted() * locator.matrix_world)
spawn_point.set_position(pos)
spawn_point.set_rotation(rot)
spawn_point.set_type(int(locator_scs_props.locator_prefab_spawn_type))
pip_spawn_points.append(spawn_point)
# semaphores creation
for locator in semaphore_locs.values():
locator_scs_props = locator.scs_props
""":type: io_scs_tools.properties.object.ObjectSCSTools"""
# create semaphore and set properties
semaphore = Semaphore(int(locator_scs_props.locator_prefab_tsem_type))
pos, rot, scale = _get_scs_transformation_components(offset_matrix.inverted() * locator.matrix_world)
semaphore.set_position(pos)
semaphore.set_rotation(rot)
semaphore.set_semaphore_id(int(locator_scs_props.locator_prefab_tsem_id))
if ":" in locator_scs_props.locator_prefab_tsem_profile:
semaphore.set_profile(locator_scs_props.locator_prefab_tsem_profile.split(":")[1].strip())
else:
lprint("W Invalid Profile: %r on Traffic Semaphore locator: %r",
(locator_scs_props.locator_prefab_tsem_profile, locator.name))
semaphore.set_intervals((locator_scs_props.locator_prefab_tsem_gs,
locator_scs_props.locator_prefab_tsem_os1,
locator_scs_props.locator_prefab_tsem_rs,
locator_scs_props.locator_prefab_tsem_os2))
semaphore.set_cycle(locator_scs_props.locator_prefab_tsem_cyc_delay)
pip_semaphores.append(semaphore)
# map points creation
for locator in map_point_locs.values():
locator_scs_props = locator.scs_props
""":type: io_scs_tools.properties.object.ObjectSCSTools"""
# create map point and set properties
map_point = __get_map_point__(pip_map_points, locator.name)
pos, rot, scale = _get_scs_transformation_components(offset_matrix.inverted() * locator.matrix_world)
map_point.set_position(pos)
map_point.set_flags(locator_scs_props)
for neighbour_name in _connections_group_wrapper.get_neighbours(locator):
assert map_point.add_neighbour(__get_map_point__(pip_map_points, neighbour_name))
MapPoint.calc_segment_extensions(pip_map_points.values())
MapPoint.test_map_points(pip_map_points.values())
MapPoint.auto_generate_map_points(pip_map_points, pip_nodes)
# trigger points creation
for locator in trigger_point_locs.values():
locator_scs_props = locator.scs_props
""":type: io_scs_tools.properties.object.ObjectSCSTools"""
# create trigger point and set properties
trigger_point = __get_trigger_point__(pip_trigger_points, locator.name)
pos, rot, scale = _get_scs_transformation_components(offset_matrix.inverted() * locator.matrix_world)
trigger_point.set_position(pos)
if ":" in locator_scs_props.locator_prefab_tp_action:
trigger_point.set_action(locator_scs_props.locator_prefab_tp_action.split(":")[1].strip())
else:
lprint("W Invalid Action: %r on Trigger Point locator: %r",
(locator_scs_props.locator_prefab_tp_action, locator.name))
trigger_point.set_trigger_range(locator_scs_props.locator_prefab_tp_range)
trigger_point.set_reset_delay(locator_scs_props.locator_prefab_tp_reset_delay)
trigger_point.set_flags(locator_scs_props)
for neighbour_name in _connections_group_wrapper.get_neighbours(locator):
assert trigger_point.add_neighbour(__get_trigger_point__(pip_trigger_points, neighbour_name))
TriggerPoint.prepare_trigger_points(pip_trigger_points.values())
# intersections creation
for c0_i, c0 in enumerate(sorted(pip_curves.values())):
for c1_i, c1 in enumerate(sorted(pip_curves.values())):
if c1_i <= c0_i: # only search each pair of curves once
continue
# get the intersection point and curves coefficient positions
intersect_p, c0_pos, c1_pos = Intersection.get_intersection(c0, c1)
if intersect_p:
intersect_p_str = str(intersect_p) # Format: '<Vector (0.0000, 0.0000, 0.0000)>'
is_start = c0_pos == 0 and c0_pos == c1_pos
is_end = c1_pos == 1 and c0_pos == c1_pos
is_split_sharp = False
if is_start:
inter_type = 0 # fork
elif is_end:
inter_type = 1 # joint
else:
inter_type = 2 # cross
# if there is indication of cross intersection filter out intersections with common fork and joint
# NOTE: this condition might not be sufficient, so if anyone will have problems,
# this is the point that has to be improved
if Intersection.have_common_fork(c0, c1) or Intersection.have_common_joint(c0, c1):
continue
# calculate radius for the same directions on curves
forward_radius = Intersection.get_intersection_radius(c0, c1, c0_pos, c1_pos, 1, 1)
backward_radius = Intersection.get_intersection_radius(c0, c1, c0_pos, c1_pos, -1, -1)
final_radius = max(forward_radius, backward_radius)
# special calculations only for cross intersections
if inter_type == 2:
# calculate radius also for opposite directions
final_radius = max(final_radius, Intersection.get_intersection_radius(c0, c1, c0_pos, c1_pos, 1, -1))
final_radius = max(final_radius, Intersection.get_intersection_radius(c0, c1, c0_pos, c1_pos, -1, 1))
# calculate position of intersection point on curves with better precision
c0_pos = c0.get_closest_point(intersect_p)
c1_pos = c1.get_closest_point(intersect_p)
# calculate if split cross intersection is too sharp for allowing of smother traffic flow
c0_dir = c0.get_curve_tangent_at_position(c0_pos)
c1_dir = c1.get_curve_tangent_at_position(c1_pos)
is_split_sharp = c0_dir.dot(c1_dir) >= _PL_consts.CURVE_SPLIT_CROSS_DOT
lprint("D Found cross intersection point: %r", (intersect_p,))
# creating intersection class instances
intersection = Intersection(c0.get_index(), c0.get_ui_name(), c0_pos * c0.get_length())
intersection1 = Intersection(c1.get_index(), c1.get_ui_name(), c1_pos * c1.get_length())
# init list of intersections for current intersecting point
if intersect_p_str not in pip_intersections[inter_type]:
pip_intersections[inter_type][intersect_p_str] = []
# append intersections to list and calculate new siblings
new_siblings = 2
if intersection not in pip_intersections[inter_type][intersect_p_str]:
pip_intersections[inter_type][intersect_p_str].append(intersection)
else:
del intersection
new_siblings -= 1
if intersection1 not in pip_intersections[inter_type][intersect_p_str]:
pip_intersections[inter_type][intersect_p_str].append(intersection1)
else:
del intersection1
new_siblings -= 1
# always set flags on first entry in current intersection point list
# this way siblings count is getting updated properly
pip_intersections[inter_type][intersect_p_str][0].set_flags(is_start, is_end, is_split_sharp, new_siblings)
# update radius on all of intersection in the same intersecting point
for inter in pip_intersections[inter_type][intersect_p_str]:
inter.set_radius(pip_intersections[inter_type][intersect_p_str][0].get_radius())
inter.set_radius(final_radius)
# create container
pip_container = [pip_header.get_as_section(), pip_global.get_as_section()]
for node in pip_nodes.values():
pip_container.append(node.get_as_section())
for curve_key in sorted(pip_curves):
pip_container.append(pip_curves[curve_key].get_as_section())
for sign in pip_signs:
pip_container.append(sign.get_as_section())
for spawn_point in pip_spawn_points:
pip_container.append(spawn_point.get_as_section())
for semaphore in pip_semaphores:
pip_container.append(semaphore.get_as_section())
for map_point in pip_map_points.values():
pip_container.append(map_point.get_as_section())
for trigger_point in pip_trigger_points.values():
pip_container.append(trigger_point.get_as_section())
for inter_type in range(3):
for intersect_p_str in pip_intersections[inter_type]:
for intersection in pip_intersections[inter_type][intersect_p_str]:
pip_container.append(intersection.get_as_section())
# write to file
ind = " "
pip_filepath = path.join(dirpath, str(filename + ".pip" + name_suffix))
result = _pix_container.write_data_to_file(pip_container, pip_filepath, ind)
return result
def execute(dirpath, filename, prefab_locator_list, offset_matrix, used_terrain_points):
"""Exports PIP file from given locator list.
:param prefab_locator_list:
:type prefab_locator_list: list of bpy.types.Object
:param dirpath: directory export path
:type dirpath: str
:param filename: name of PIP file
:type filename: str
:param offset_matrix: offset matrix for locators
:type offset_matrix: mathutils.Matrix
:param used_terrain_points: terrain points transitional structure for accessing terrain points stored during PIM export
:type used_terrain_points: io_scs_tools.exp.transition_structs.terrain_points.TerrainPntsTrans
:return: True if successfull; otherwise False
:rtype: bool
"""
# CLEANUP CONNECTIONS DATA
_connections_group_wrapper.cleanup_on_export()
print("\n************************************")
print("** SCS PIP Exporter **")
print("** (c)2015 SCS Software **")
print("************************************\n")
(control_node_locs,
nav_point_locs,
sign_locs,
spawn_point_locs,
semaphore_locs,
map_point_locs,
trigger_point_locs) = __sort_locators_by_type__(prefab_locator_list)
pip_header = Header(2, filename)
pip_global = Globall()
pip_nodes = OrderedDict()
""":type: dict[int,Node]"""
pip_curves = OrderedDict()
""":type: dict[int, Curve]"""
pip_signs = []
""":type: list[Sign]"""
pip_spawn_points = []
""":type: list[SpawnPoint]"""
pip_semaphores = []
""":type: list[Semaphore]"""
pip_map_points = OrderedDict()
""":type: dict[str, MapPoint]"""
pip_trigger_points = OrderedDict()
""":type: dict[str, TriggerPoint]"""
pip_intersections = [OrderedDict(), OrderedDict(), OrderedDict()]
""":type: list[dict[str, list[Intersection]]]"""
# nodes creation
for locator in control_node_locs.values():
locator_scs_props = locator.scs_props
""":type: io_scs_tools.properties.object.ObjectSCSTools"""
curr_node_i = int(locator_scs_props.locator_prefab_con_node_index)
if curr_node_i not in pip_nodes:
pos, rot, scale = _get_scs_transformation_components(offset_matrix.inverted() * locator.matrix_world)
rot = Quaternion(rot) * Vector((0, 0, -1))
# create node with position and direction
cn = Node(curr_node_i, pos, rot)
# add terrain points
terrain_points = used_terrain_points.get(curr_node_i)
for variant_i in terrain_points:
# ensure variant entry for no terrain points case
cn.ensure_variant(variant_i)
for tp_entry in terrain_points[variant_i]:
cn.add_terrain_point(tp_entry.position, tp_entry.normal, variant_i)
pip_nodes[curr_node_i] = cn
else:
lprint("W Multiple Control Nodes with same index detected, only one per index will be exported!\n\t "
"Check Control Nodes in SCS Game Object with Root: %r", (filename,))
# curves creation
curves_dict = _connections_group_wrapper.get_curves(nav_point_locs.values())
for key, curve_entry in curves_dict.items():
loc0 = nav_point_locs[curves_dict[key].start]
loc0_scs_props = loc0.scs_props
""":type: io_scs_tools.properties.object.ObjectSCSTools"""
loc1 = nav_point_locs[curves_dict[key].end]
loc1_scs_props = loc1.scs_props
""":type: io_scs_tools.properties.object.ObjectSCSTools"""
# create curve and set properties
curve = __get_curve__(pip_curves, curve_entry.index, loc0.name)
pos, rot, scale = _get_scs_transformation_components(offset_matrix.inverted() * loc0.matrix_world)
curve.set_start(pos, rot)
pos, rot, scale = _get_scs_transformation_components(offset_matrix.inverted() * loc1.matrix_world)
curve.set_end(pos, rot)
curve.set_input_boundaries(loc0_scs_props)
curve.set_output_boundaries(loc1_scs_props)
curve.set_flags(loc0.scs_props, True)
curve.set_flags(loc1.scs_props, False)
curve.set_semaphore_id(int(loc0_scs_props.locator_prefab_np_traffic_semaphore))
curve.set_traffic_rule(loc1_scs_props.locator_prefab_np_traffic_rule)
# set next/prev curves
for next_key in curve_entry.next_curves:
next_curve = __get_curve__(pip_curves, curves_dict[next_key].index, curves_dict[next_key].start)
assert curve.add_next_curve(next_curve)
for prev_key in curve_entry.prev_curves:
prev_curve = __get_curve__(pip_curves, curves_dict[prev_key].index, curves_dict[prev_key].start)
assert curve.add_prev_curve(prev_curve)
# sync nodes input lanes
boundary_node_i = curve.get_input_node_index()
if 0 <= boundary_node_i < _PL_consts.PREFAB_NODE_COUNT_MAX:
if boundary_node_i in pip_nodes:
assert pip_nodes[boundary_node_i].set_input_lane(curve.get_input_lane_index(), curve.get_index())
else:
lprint("E None existing Boundary Node with index: %s used in Navigation Point: %r",
(boundary_node_i, loc0.name,))
# sync nodes output lanes
boundary_node_i = curve.get_output_node_index()
if 0 <= boundary_node_i < _PL_consts.PREFAB_NODE_COUNT_MAX:
if boundary_node_i in pip_nodes:
assert pip_nodes[boundary_node_i].set_output_lane(curve.get_output_lane_index(), curve.get_index())
else:
lprint("E None existing Boundary Node with index: %s used in Navigation Point: %r",
(boundary_node_i, loc1.name,))
Curve.prepare_curves(pip_curves.values())
# signs creation
for locator in sign_locs.values():
locator_scs_props = locator.scs_props
""":type: io_scs_tools.properties.object.ObjectSCSTools"""
# create sign and set properties
sign = Sign(locator.name, locator_scs_props.scs_part)
pos, rot, scale = _get_scs_transformation_components(offset_matrix.inverted() * locator.matrix_world)
sign.set_position(pos)
sign.set_rotation(rot)
if ":" in locator_scs_props.locator_prefab_sign_model:
sign.set_model(locator_scs_props.locator_prefab_sign_model.split(":")[1].strip())
else:
lprint("W Invalid Sign Model: %r on locator: %r",
(locator_scs_props.locator_prefab_sign_model, locator.name))
pip_signs.append(sign)
# spawn points creation
for locator in spawn_point_locs.values():
locator_scs_props = locator.scs_props
""":type: io_scs_tools.properties.object.ObjectSCSTools"""
# create spawn point and set properties
spawn_point = SpawnPoint(locator.name)
pos, rot, scale = _get_scs_transformation_components(offset_matrix.inverted() * locator.matrix_world)
spawn_point.set_position(pos)
spawn_point.set_rotation(rot)
spawn_point.set_type(int(locator_scs_props.locator_prefab_spawn_type))
pip_spawn_points.append(spawn_point)
# semaphores creation
for locator in semaphore_locs.values():
locator_scs_props = locator.scs_props
""":type: io_scs_tools.properties.object.ObjectSCSTools"""
# create semaphore and set properties
semaphore = Semaphore(int(locator_scs_props.locator_prefab_tsem_type))
pos, rot, scale = _get_scs_transformation_components(offset_matrix.inverted() * locator.matrix_world)
semaphore.set_position(pos)
semaphore.set_rotation(rot)
semaphore.set_semaphore_id(int(locator_scs_props.locator_prefab_tsem_id))
if ":" in locator_scs_props.locator_prefab_tsem_profile:
semaphore.set_profile(locator_scs_props.locator_prefab_tsem_profile.split(":")[1].strip())
else:
lprint("W Invalid Profile: %r on Traffic Semaphore locator: %r",
(locator_scs_props.locator_prefab_tsem_profile, locator.name))
semaphore.set_intervals((locator_scs_props.locator_prefab_tsem_gs,
locator_scs_props.locator_prefab_tsem_os1,
locator_scs_props.locator_prefab_tsem_rs,
locator_scs_props.locator_prefab_tsem_os2))
semaphore.set_cycle(locator_scs_props.locator_prefab_tsem_cyc_delay)
pip_semaphores.append(semaphore)
# map points creation
for locator in map_point_locs.values():
locator_scs_props = locator.scs_props
""":type: io_scs_tools.properties.object.ObjectSCSTools"""
# create map point and set properties
map_point = __get_map_point__(pip_map_points, locator.name)
pos, rot, scale = _get_scs_transformation_components(offset_matrix.inverted() * locator.matrix_world)
map_point.set_position(pos)
map_point.set_flags(locator_scs_props)
for neighbour_name in _connections_group_wrapper.get_neighbours(locator):
assert map_point.add_neighbour(__get_map_point__(pip_map_points, neighbour_name))
MapPoint.test_map_points(pip_map_points.values())
MapPoint.auto_generate_map_points(pip_map_points, pip_nodes)
# trigger points creation
for locator in trigger_point_locs.values():
locator_scs_props = locator.scs_props
""":type: io_scs_tools.properties.object.ObjectSCSTools"""
# create trigger point and set properties
trigger_point = __get_trigger_point__(pip_trigger_points, locator.name)
pos, rot, scale = _get_scs_transformation_components(offset_matrix.inverted() * locator.matrix_world)
trigger_point.set_position(pos)
if ":" in locator_scs_props.locator_prefab_tp_action:
trigger_point.set_action(locator_scs_props.locator_prefab_tp_action.split(":")[1].strip())
else:
lprint("W Invalid Action: %r on Trigger Point locator: %r",
(locator_scs_props.locator_prefab_tp_action, locator.name))
trigger_point.set_trigger_range(locator_scs_props.locator_prefab_tp_range)
trigger_point.set_reset_delay(locator_scs_props.locator_prefab_tp_reset_delay)
trigger_point.set_flags(locator_scs_props)
for neighbour_name in _connections_group_wrapper.get_neighbours(locator):
assert trigger_point.add_neighbour(__get_trigger_point__(pip_trigger_points, neighbour_name))
TriggerPoint.prepare_trigger_points(pip_trigger_points.values())
# intersections creation
for c0_i, c0 in enumerate(sorted(pip_curves.values())):
for c1_i, c1 in enumerate(sorted(pip_curves.values())):
if c1_i <= c0_i: # only search each pair of curves once
continue
# get the intersection point and curves coefficient positions
intersect_p, c0_pos, c1_pos = Intersection.get_intersection(c0, c1)
if intersect_p:
intersect_p_str = str(intersect_p) # Format: '<Vector (0.0000, 0.0000, 0.0000)>'
is_start = c0_pos == 0 and c0_pos == c1_pos
is_end = c1_pos == 1 and c0_pos == c1_pos
if is_start:
inter_type = 0 # fork
elif is_end:
inter_type = 1 # joint
else:
inter_type = 2 # cross
# if there is indication of cross intersection filter out intersections with common fork and joint
# NOTE: this condition might not be sufficient, so if anyone will have problems,
# this is the point that has to be improved
if Intersection.have_common_fork(c0, c1) or Intersection.have_common_joint(c0, c1):
continue
# calculate radius for the same directions on curves
forward_radius = Intersection.get_intersection_radius(c0, c1, c0_pos, c1_pos, 1, 1)
backward_radius = Intersection.get_intersection_radius(c0, c1, c0_pos, c1_pos, -1, -1)
final_radius = max(forward_radius, backward_radius)
# special calculations only for cross intersections
if inter_type == 2:
# calculate radius also for opposite directions
final_radius = max(final_radius, Intersection.get_intersection_radius(c0, c1, c0_pos, c1_pos, 1, -1))
final_radius = max(final_radius, Intersection.get_intersection_radius(c0, c1, c0_pos, c1_pos, -1, 1))
# calculate position of intersection point on curves with better precision
c0_pos = c0.get_closest_point(intersect_p)
c1_pos = c1.get_closest_point(intersect_p)
lprint("D Found cross intersection point: %r", (intersect_p,))
# creating intersection class instances
intersection = Intersection(c0.get_index(), c0.get_ui_name(), c0_pos * c0.get_length())
intersection1 = Intersection(c1.get_index(), c1.get_ui_name(), c1_pos * c1.get_length())
# init list of intersections for current intersecting point
if intersect_p_str not in pip_intersections[inter_type]:
pip_intersections[inter_type][intersect_p_str] = []
# append intersections to list and calculate new siblings
new_siblings = 2
if intersection not in pip_intersections[inter_type][intersect_p_str]:
pip_intersections[inter_type][intersect_p_str].append(intersection)
else:
del intersection
new_siblings -= 1
if intersection1 not in pip_intersections[inter_type][intersect_p_str]:
pip_intersections[inter_type][intersect_p_str].append(intersection1)
else:
del intersection1
new_siblings -= 1
# always set flags on first entry in current intersection point list
# this way siblings count is getting updated properly
pip_intersections[inter_type][intersect_p_str][0].set_flags(is_start, is_end, new_siblings)
# update radius on all of intersection in the same intersecting point
for inter in pip_intersections[inter_type][intersect_p_str]:
inter.set_radius(pip_intersections[inter_type][intersect_p_str][0].get_radius())
inter.set_radius(final_radius)
# create container
pip_container = [pip_header.get_as_section(), pip_global.get_as_section()]
for node in pip_nodes.values():
pip_container.append(node.get_as_section())
for curve_key in sorted(pip_curves):
pip_container.append(pip_curves[curve_key].get_as_section())
for sign in pip_signs:
pip_container.append(sign.get_as_section())
for spawn_point in pip_spawn_points:
pip_container.append(spawn_point.get_as_section())
for semaphore in pip_semaphores:
pip_container.append(semaphore.get_as_section())
for map_point in pip_map_points.values():
pip_container.append(map_point.get_as_section())
for trigger_point in pip_trigger_points.values():
pip_container.append(trigger_point.get_as_section())
for inter_type in range(3):
for intersect_p_str in pip_intersections[inter_type]:
for intersection in pip_intersections[inter_type][intersect_p_str]:
pip_container.append(intersection.get_as_section())
# write to file
ind = " "
pip_filepath = path.join(dirpath, str(filename + ".pip"))
result = _pix_container.write_data_to_file(pip_container, pip_filepath, ind)
return result
