def gen_rotated_squarebeams(p1: Vec, p2: Vec, skin, max_rot: int):
"""Generate broken/rotated squarebeams in a region.
They will be rotated around their centers, not the model origin.
"""
z = min(p1.z, p2.z) + 3 # The center of the beams
for x, y in utils.iter_grid(min_x=int(p1.x),
min_y=int(p1.y),
max_x=int(p2.x),
max_y=int(p2.y),
stride=64):
rand_x = random.randint(-max_rot, max_rot) / BEAM_ROT_PRECISION
rand_z = random.randint(-max_rot, max_rot) / BEAM_ROT_PRECISION
# Don't rotate around yaw - the vertical axis.
# Squarebeams are offset 5 units from their real center
offset = Vec(0, 0, 5).rotate(rand_x, 0, rand_z)
prop = _make_squarebeam(Vec(x + 32, y + 32, z) + offset, skin=skin)
prop['angles'] = '{} 0 {}'.format(rand_x, rand_z)
def gen_rotated_squarebeams(vmf: VMF, p1: Vec, p2: Vec, skin, max_rot: int):
"""Generate broken/rotated squarebeams in a region.
They will be rotated around their centers, not the model origin.
"""
z = min(p1.z, p2.z) + 3 # The center of the beams
for x, y in utils.iter_grid(
min_x=int(p1.x),
min_y=int(p1.y),
max_x=int(p2.x),
max_y=int(p2.y),
stride=64):
rand_x = random.randint(-max_rot, max_rot) / BEAM_ROT_PRECISION
rand_z = random.randint(-max_rot, max_rot) / BEAM_ROT_PRECISION
# Don't rotate around yaw - the vertical axis.
# Squarebeams are offset 5 units from their real center
offset = Vec(0, 0, 5).rotate(rand_x, 0, rand_z)
prop = _make_squarebeam(vmf, Vec(x + 32, y + 32, z) + offset, skin=skin)
prop['angles'] = '{} 0 {}'.format(rand_x, rand_z)
def res_cutout_tile(vmf: srctools.VMF, res: Property):
"""Generate random quarter tiles, like in Destroyed or Retro maps.
- `MarkerItem` is the instance file to look for (`<ITEM_BEE2_CUTOUT_TILE>`)
- `floor_chance`: The percentage change for a segment in the middle of the floor to be a normal tile.
- `floor_glue_chance`: The chance for any tile to be glue - this should be higher than the regular chance, as that overrides this.
- `rotateMax` is the maximum angle to rotate squarebeam models.
- `squarebeamsSkin` sets the skin to use for the squarebeams floor frame.
- `dispBase`, if true makes the floor a displacement with random alpha.
- `Materials` blocks specify the possible materials to use:
- `squarebeams` is the squarebeams variant to use.
- `ceilingwalls` are the sides of the ceiling section.
- `floorbase` is the texture under floor sections.
If `dispBase` is True this is a displacement material.
- `tile_glue` is used on top of a thinner tile segment.
- `clip` is the player_clip texture used over floor segments.
(This allows customising the surfaceprop.)
"""
marker_filenames = instanceLocs.resolve(res['markeritem'])
# TODO: Reimplement cutout tiles.
for inst in vmf.by_class['func_instance']:
if inst['file'].casefold() in marker_filenames:
inst.remove()
return
x: float
y: float
max_x: float
max_y: float
INST_LOCS = {} # Map targetnames -> surface loc
CEIL_IO = [] # Pairs of ceil inst corners to cut out.
FLOOR_IO = [] # Pairs of floor inst corners to cut out.
overlay_ids = {} # When we replace brushes, we need to fix any overlays
# on that surface.
MATS.clear()
floor_edges = [] # Values to pass to add_floor_sides() at the end
sign_locs = set()
# If any signage is present in the map, we need to force tiles to
# appear at that location!
for over in vmf.by_class['info_overlay']:
if (over['material'].casefold() in FORCE_TILE_MATS and
# Only check floor/ceiling overlays
over['basisnormal'] in ('0 0 1', '0 0 -1')):
add_signage_loc(sign_locs, Vec.from_str(over['origin']))
for item in connections.ITEMS.values():
for ind_pan in item.ind_panels:
loc = Vec(0, 0, -64)
loc.localise(
Vec.from_str(ind_pan['origin']),
Vec.from_str(ind_pan['angles']),
)
add_signage_loc(sign_locs, loc)
SETTINGS = {
'floor_chance':
srctools.conv_int(res['floorChance', '100'], 100),
'ceil_chance':
srctools.conv_int(res['ceilingChance', '100'], 100),
'floor_glue_chance':
srctools.conv_int(res['floorGlueChance', '0']),
'ceil_glue_chance':
srctools.conv_int(res['ceilingGlueChance', '0']),
'rotate_beams':
int(srctools.conv_float(res['rotateMax', '0']) * BEAM_ROT_PRECISION),
'beam_skin':
res['squarebeamsSkin', '0'],
'base_is_disp':
srctools.conv_bool(res['dispBase', '0']),
'quad_floor':
res['FloorSize', '4x4'].casefold() == '2x2',
'quad_ceil':
res['CeilingSize', '4x4'].casefold() == '2x2',
}
random.seed(vbsp.MAP_RAND_SEED + '_CUTOUT_TILE_NOISE')
noise = SimplexNoise(period=4 * 40) # 4 tiles/block, 50 blocks max
# We want to know the number of neighbouring tile cutouts before
# placing tiles - blocks away from the sides generate fewer tiles.
# all_floors[z][x,y] = count
floor_neighbours = defaultdict(
dict) # type: Dict[float, Dict[Tuple[float, float], int]]
for mat_prop in res.find_key('Materials', []):
MATS[mat_prop.name].append(mat_prop.value)
if SETTINGS['base_is_disp']:
# We want the normal brushes to become nodraw.
MATS['floorbase_disp'] = MATS['floorbase']
MATS['floorbase'] = ['tools/toolsnodraw']
# Since this uses random data for initialisation, the alpha and
# regular will use slightly different patterns.
alpha_noise = SimplexNoise(period=4 * 50)
else:
alpha_noise = None
for key, default in TEX_DEFAULT:
if key not in MATS:
MATS[key] = [default]
# Find our marker ents
for inst in vmf.by_class['func_instance']:
if inst['file'].casefold() not in marker_filenames:
continue
targ = inst['targetname']
normal = Vec(0, 0, 1).rotate_by_str(inst['angles', '0 0 0'])
# Check the orientation of the marker to figure out what to generate
if normal == (0, 0, 1):
io_list = FLOOR_IO
else:
io_list = CEIL_IO
# Reuse orient to calculate where the solid face will be.
loc = Vec.from_str(inst['origin']) - 64 * normal
INST_LOCS[targ] = loc
item = connections.ITEMS[targ]
item.delete_antlines()
if item.outputs:
for conn in list(item.outputs):
if conn.to_item.inst['file'].casefold() in marker_filenames:
io_list.append((targ, conn.to_item.name))
else:
LOGGER.warning('Cutout tile connected to non-cutout!')
conn.remove() # Delete the connection.
else:
# If the item doesn't have any connections, 'connect'
# it to itself so we'll generate a 128x128 tile segment.
io_list.append((targ, targ))
# Remove all traces of this item (other than in connections lists).
inst.remove()
del connections.ITEMS[targ]
for start_floor, end_floor in FLOOR_IO:
box_min = Vec(INST_LOCS[start_floor])
box_min.min(INST_LOCS[end_floor])
box_max = Vec(INST_LOCS[start_floor])
box_max.max(INST_LOCS[end_floor])
if box_min.z != box_max.z:
continue # They're not in the same level!
z = box_min.z
if SETTINGS['rotate_beams']:
# We have to generate 1 model per 64x64 block to do rotation...
gen_rotated_squarebeams(
vmf,
box_min - (64, 64, 0),
box_max + (64, 64, -8),
skin=SETTINGS['beam_skin'],
max_rot=SETTINGS['rotate_beams'],
)
else:
# Make the squarebeams props, using big models if possible
gen_squarebeams(vmf,
box_min + (-64, -64, 0),
box_max + (64, 64, -8),
skin=SETTINGS['beam_skin'])
# Add a player_clip brush across the whole area
vmf.add_brush(
vmf.make_prism(
p1=box_min - (64, 64, FLOOR_DEPTH),
p2=box_max + (64, 64, 0),
mat=MATS['clip'][0],
).solid)
# Add a noportal_volume covering the surface, in case there's
# room for a portal.
noportal_solid = vmf.make_prism(
# Don't go all the way to the sides, so it doesn't affect wall
# brushes.
p1=box_min - (63, 63, 9),
p2=box_max + (63, 63, 0),
mat='tools/toolsinvisible',
).solid
noportal_ent = vmf.create_ent(
classname='func_noportal_volume',
origin=box_min.join(' '),
)
noportal_ent.solids.append(noportal_solid)
if SETTINGS['base_is_disp']:
# Use displacements for the base instead.
make_alpha_base(
vmf,
box_min + (-64, -64, 0),
box_max + (64, 64, 0),
noise=alpha_noise,
)
for x, y in utils.iter_grid(
min_x=int(box_min.x),
max_x=int(box_max.x) + 1,
min_y=int(box_min.y),
max_y=int(box_max.y) + 1,
stride=128,
):
# Build the set of all positions..
floor_neighbours[z][x, y] = -1
# Mark borders we need to fill in, and the angle (for func_instance)
# The wall is the face pointing inwards towards the bottom brush,
# and the ceil is the ceiling of the block above the bordering grid
# points.
for x in range(int(box_min.x), int(box_max.x) + 1, 128):
# North
floor_edges.append(
BorderPoints(
wall=Vec(x, box_max.y + 64, z - 64),
ceil=Vec_tuple(x, box_max.y + 128, z),
rot=270,
))
# South
floor_edges.append(
BorderPoints(
wall=Vec(x, box_min.y - 64, z - 64),
ceil=Vec_tuple(x, box_min.y - 128, z),
rot=90,
))
for y in range(int(box_min.y), int(box_max.y) + 1, 128):
# East
floor_edges.append(
BorderPoints(
wall=Vec(box_max.x + 64, y, z - 64),
ceil=Vec_tuple(box_max.x + 128, y, z),
rot=180,
))
# West
floor_edges.append(
BorderPoints(
wall=Vec(box_min.x - 64, y, z - 64),
ceil=Vec_tuple(box_min.x - 128, y, z),
rot=0,
))
# Now count boundaries near tiles, then generate them.
# Do it separately for each z-level:
for z, xy_dict in floor_neighbours.items():
for x, y in xy_dict:
# We want to count where there aren't any tiles
xy_dict[x, y] = (((x - 128, y - 128) not in xy_dict) +
((x - 128, y + 128) not in xy_dict) +
((x + 128, y - 128) not in xy_dict) +
((x + 128, y + 128) not in xy_dict) +
((x - 128, y) not in xy_dict) +
((x + 128, y) not in xy_dict) +
((x, y - 128) not in xy_dict) +
((x, y + 128) not in xy_dict))
max_x = max_y = 0
weights = {}
# Now the counts are all correct, compute the weight to apply
# for tiles.
# Adding the neighbouring counts will make a 5x5 area needed to set
# the center to 0.
for (x, y), cur_count in xy_dict.items():
max_x = max(x, max_x)
max_y = max(y, max_y)
# Orthrogonal is worth 0.2, diagonal is worth 0.1.
# Not-present tiles would be 8 - the maximum
tile_count = (0.8 * cur_count + 0.1 * xy_dict.get(
(x - 128, y - 128), 8) + 0.1 * xy_dict.get(
(x - 128, y + 128), 8) + 0.1 * xy_dict.get(
(x + 128, y - 128), 8) + 0.1 * xy_dict.get(
(x + 128, y + 128), 8) + 0.2 * xy_dict.get(
(x - 128, y), 8) + 0.2 * xy_dict.get(
(x, y - 128), 8) + 0.2 * xy_dict.get(
(x, y + 128), 8) + 0.2 * xy_dict.get(
(x + 128, y), 8))
# The number ranges from 0 (all tiles) to 12.8 (no tiles).
# All tiles should still have a small chance to generate tiles.
weights[x, y] = min((tile_count + 0.5) / 8, 1)
# Share the detail entity among same-height tiles..
detail_ent = vmf.create_ent(classname='func_detail', )
for x, y in xy_dict:
convert_floor(
vmf,
Vec(x, y, z),
overlay_ids,
MATS,
SETTINGS,
sign_locs,
detail_ent,
noise_weight=weights[x, y],
noise_func=noise,
)
add_floor_sides(vmf, floor_edges)
return conditions.RES_EXHAUSTED
def gen_squarebeams(vmf: VMF, p1: Vec, p2: Vec, skin, gen_collision=True):
"""Generate squarebeams props to fill the space given.
The space should be in multiples of 64. The squarebeams brush will
be aligned to the lowest point in the space.
"""
z = min(p1.z, p2.z) + 8
min_x = min(p1.x, p2.x)
min_y = min(p1.y, p2.y)
max_x = max(p1.x, p2.x)
max_y = max(p1.y, p2.y)
dist_x = max_x - min_x
dist_y = max_y - min_y
# After this x or y dist, move to the next grid size.
cutoff_512_x = dist_x // 512 * 512
cutoff_256_x = dist_x // 256 * 256
cutoff_128_x = dist_x // 128 * 128
cutoff_512_y = dist_y // 512 * 512
cutoff_256_y = dist_y // 256 * 256
cutoff_128_y = dist_y // 128 * 128
for x, y in utils.iter_grid(
max_x=int(dist_x),
max_y=int(dist_y),
stride=64,
):
if x < cutoff_512_x and y < cutoff_512_y:
# Make 1 prop every 512 units, at the center
if x % 512 == 0 and y % 512 == 0:
_make_squarebeam(
vmf,
Vec(min_x + x + 256, min_y + y + 256, z),
skin,
'_8x8',
)
elif x < cutoff_256_x and y < cutoff_256_y:
if x % 256 == 0 and y % 256 == 0:
_make_squarebeam(
vmf,
Vec(min_x + x + 128, min_y + y + 128, z),
skin,
'_4x4',
)
elif x < cutoff_128_x and y < cutoff_128_y:
if x % 128 == 0 and y % 128 == 0:
_make_squarebeam(
vmf,
Vec(min_x + x + 64, min_y + y + 64, z),
skin,
'_2x2',
)
else:
# Make squarebeams for every point!
_make_squarebeam(
vmf,
Vec(min_x + x + 32, min_y + y + 32, z),
skin,
)
if gen_collision:
collision = vmf.create_ent(
classname='func_brush',
disableshadows='1',
disableflashlight='1',
disablereceiveshadows='1',
shadowdepthnocache='1',
solidity='2', # Always Solid
solidbsp='1',
)
for x in range(int(min_x) + 64, int(max_x), 64):
collision.solids.append(
vmf.make_prism(
p1=Vec(x - 2, min_y + 2, z - 2),
p2=Vec(x + 2, max_y - 2, z - 8),
mat='tools/toolsnodraw',
).solid)
for y in range(int(min_y) + 64, int(max_y), 64):
collision.solids.append(
vmf.make_prism(
p1=Vec(min_x + 2, y - 2, z - 2),
p2=Vec(max_x - 2, y + 2, z - 8),
mat='tools/toolsnodraw',
).solid)
for x1, y1, x2, y2 in [
(min_x, min_y, max_x, min_y + 2),
(min_x, max_y, max_x, max_y - 2),
(min_x, min_y, min_x + 2, max_y),
(max_x, min_y, max_x - 2, max_y),
]:
collision.solids.append(
vmf.make_prism(
p1=Vec(x1, y1, z - 2),
p2=Vec(x2, y2, z - 8),
mat='tools/toolsnodraw',
).solid)
def convert_floor(
vmf: VMF,
loc: Vec,
overlay_ids,
mats,
settings,
signage_loc,
detail,
noise_weight,
noise_func: SimplexNoise,
):
"""Cut out tiles at the specified location."""
# We pop it, so the face isn't detected by other logic - otherwise it'll
# be retextured and whatnot, which we don't want.
try:
brush = conditions.SOLIDS.pop(loc.as_tuple())
except KeyError:
return False # No tile here!
if brush.normal == (0, 0, 1):
# This is a pillar block - there isn't actually tiles here!
# We need to generate a squarebeams brush to fill this gap.
brush.face.mat = 'tools/toolsnodraw' # It won't be visible
temp_data = template_brush.import_template(
vmf,
temp_name=FLOOR_TEMP_PILLAR,
origin=loc,
)
template_brush.retexture_template(
temp_data,
loc,
# Switch to use the configured squarebeams texture
replace_tex={
consts.Special.SQUAREBEAMS: random.choice(MATS['squarebeams']),
})
return False
# The new brush IDs overlays need to use
# NOTE: strings, not ints!
ant_locs = overlay_ids[str(brush.face.id)] = []
# Move the floor brush down and switch to the floorbase texture.
for plane in brush.face.planes:
plane.z -= FLOOR_DEPTH
brush.face.mat = random.choice(mats['floorbase'])
loc.x -= 64
loc.y -= 64
for x, y in utils.iter_grid(max_x=4, max_y=4):
tile_loc = loc + (x * 32 + 16, y * 32 + 16, 0)
if tile_loc.as_tuple() in signage_loc:
# Force the tile to be present under signage..
should_make_tile = True
rand = 100
# We don't need to check this again in future!
signage_loc.remove(tile_loc.as_tuple())
else:
# Create a number between 0-100
rand = 100 * get_noise(tile_loc // 32, noise_func) + 10
# Adjust based on the noise_weight value, so boundries have more tiles
rand *= 0.1 + 0.9 * (1 - noise_weight)
should_make_tile = rand < settings['floor_chance']
if random.randint(0, 7) == 0:
# Sometimes there'll be random holes/extra tiles
should_make_tile = not should_make_tile
if should_make_tile:
# Full tile
tile = make_tile(
vmf,
p1=tile_loc - (16, 16, 0),
p2=tile_loc + (16, 16, -2),
top_mat=vbsp.get_tex(str(brush.color) + '.floor'),
bottom_mat='tools/toolsnodraw',
beam_mat=random.choice(mats['squarebeams']),
)
detail.solids.append(tile.solid)
ant_locs.append(str(tile.top.id))
elif rand < settings['floor_glue_chance']:
# 'Glue' tile - this chance should be higher, making these appear
# bordering the full tiles.
tile = make_tile(
vmf,
p1=tile_loc - (16, 16, 1),
p2=tile_loc + (16, 16, -2),
top_mat=random.choice(mats['tile_glue']),
bottom_mat='tools/toolsnodraw',
beam_mat=random.choice(mats['squarebeams']),
)
detail.solids.append(tile.solid)
else:
# No tile at this loc!
pass
return True
def res_goo_debris(res: Property):
"""Add random instances to goo squares.
Options:
- file: The filename for the instance. The variant files should be
suffixed with '_1.vmf', '_2.vmf', etc.
- space: the number of border squares which must be filled with goo
for a square to be eligible - defaults to 1.
- weight, number: see the 'Variant' result, a set of weights for the
options
- chance: The percentage chance a square will have a debris item
- offset: A random xy offset applied to the instances.
"""
import brushLoc
space = res.int('spacing', 1)
rand_count = res.int('number', None)
if rand_count:
rand_list = weighted_random(
rand_count,
res['weights', ''],
)
else:
rand_list = None
chance = res.int('chance', 30) / 100
file = res['file']
offset = res.int('offset', 0)
if file.endswith('.vmf'):
file = file[:-4]
goo_top_locs = {
pos.as_tuple()
for pos, block in brushLoc.POS.items() if block.is_goo and block.is_top
}
if space == 0:
# No spacing needed, just copy
possible_locs = [Vec(loc) for loc in goo_top_locs]
else:
possible_locs = []
for x, y, z in goo_top_locs:
# Check to ensure the neighbouring blocks are also
# goo brushes (depending on spacing).
for x_off, y_off in utils.iter_grid(
min_x=-space,
max_x=space + 1,
min_y=-space,
max_y=space + 1,
stride=1,
):
if x_off == y_off == 0:
continue # We already know this is a goo location
if (x + x_off, y + y_off, z) not in goo_top_locs:
break # This doesn't qualify
else:
possible_locs.append(brushLoc.grid_to_world(Vec(x, y, z)))
LOGGER.info(
'GooDebris: {}/{} locations',
len(possible_locs),
len(goo_top_locs),
)
suff = ''
for loc in possible_locs:
random.seed('goo_debris_{}_{}_{}'.format(loc.x, loc.y, loc.z))
if random.random() > chance:
continue
if rand_list is not None:
suff = '_' + str(random.choice(rand_list) + 1)
if offset > 0:
loc.x += random.randint(-offset, offset)
loc.y += random.randint(-offset, offset)
loc.z -= 32 # Position the instances in the center of the 128 grid.
VMF.create_ent(classname='func_instance',
file=file + suff + '.vmf',
origin=loc.join(' '),
angles='0 {} 0'.format(random.randrange(0, 3600) / 10))
return RES_EXHAUSTED
def res_cutout_tile(res: Property):
"""Generate random quarter tiles, like in Destroyed or Retro maps.
- "MarkerItem" is the instance to look for.
- "TileSize" can be "2x2" or "4x4".
- rotateMax is the amount of degrees to rotate squarebeam models.
Materials:
- "squarebeams" is the squarebeams variant to use.
- "ceilingwalls" are the sides of the ceiling section.
- "floorbase" is the texture under floor sections.
- "tile_glue" is used on top of a thinner tile segment.
- "clip" is the player_clip texture used over floor segments.
(This allows customising the surfaceprop.)
- "Floor4x4Black", "Ceil2x2White" and other combinations can be used to
override the textures used.
"""
item = instanceLocs.resolve(res['markeritem'])
INST_LOCS = {} # Map targetnames -> surface loc
CEIL_IO = [] # Pairs of ceil inst corners to cut out.
FLOOR_IO = [] # Pairs of floor inst corners to cut out.
overlay_ids = {} # When we replace brushes, we need to fix any overlays
# on that surface.
MATS.clear()
floor_edges = [] # Values to pass to add_floor_sides() at the end
sign_loc = set(FORCE_LOCATIONS)
# If any signage is present in the map, we need to force tiles to
# appear at that location!
for over in conditions.VMF.by_class['info_overlay']:
if (over['material'].casefold() in FORCE_TILE_MATS and
# Only check floor/ceiling overlays
over['basisnormal'] in ('0 0 1', '0 0 -1')):
loc = Vec.from_str(over['origin'])
# Sometimes (light bridges etc) a sign will be halfway between
# tiles, so in that case we need to force 2 tiles.
loc_min = (loc - (15, 15, 0)) // 32 * 32 # type: Vec
loc_max = (loc + (15, 15, 0)) // 32 * 32 # type: Vec
loc_min += (16, 16, 0)
loc_max += (16, 16, 0)
FORCE_LOCATIONS.add(loc_min.as_tuple())
FORCE_LOCATIONS.add(loc_max.as_tuple())
SETTINGS = {
'floor_chance':
srctools.conv_int(res['floorChance', '100'], 100),
'ceil_chance':
srctools.conv_int(res['ceilingChance', '100'], 100),
'floor_glue_chance':
srctools.conv_int(res['floorGlueChance', '0']),
'ceil_glue_chance':
srctools.conv_int(res['ceilingGlueChance', '0']),
'rotate_beams':
int(srctools.conv_float(res['rotateMax', '0']) * BEAM_ROT_PRECISION),
'beam_skin':
res['squarebeamsSkin', '0'],
'base_is_disp':
srctools.conv_bool(res['dispBase', '0']),
'quad_floor':
res['FloorSize', '4x4'].casefold() == '2x2',
'quad_ceil':
res['CeilingSize', '4x4'].casefold() == '2x2',
}
random.seed(vbsp.MAP_RAND_SEED + '_CUTOUT_TILE_NOISE')
noise = SimplexNoise(period=4 * 40) # 4 tiles/block, 50 blocks max
# We want to know the number of neighbouring tile cutouts before
# placing tiles - blocks away from the sides generate fewer tiles.
floor_neighbours = defaultdict(dict) # all_floors[z][x,y] = count
for mat_prop in res['Materials', []]:
MATS[mat_prop.name].append(mat_prop.value)
if SETTINGS['base_is_disp']:
# We want the normal brushes to become nodraw.
MATS['floorbase_disp'] = MATS['floorbase']
MATS['floorbase'] = ['tools/toolsnodraw']
# Since this uses random data for initialisation, the alpha and
# regular will use slightly different patterns.
alpha_noise = SimplexNoise(period=4 * 50)
else:
alpha_noise = None
for key, default in TEX_DEFAULT:
if key not in MATS:
MATS[key] = [default]
# Find our marker ents
for inst in conditions.VMF.by_class['func_instance']: # type: VLib.Entity
if inst['file'].casefold() not in item:
continue
targ = inst['targetname']
orient = Vec(0, 0, 1).rotate_by_str(inst['angles', '0 0 0'])
# Check the orientation of the marker to figure out what to generate
if orient == (0, 0, 1):
io_list = FLOOR_IO
else:
io_list = CEIL_IO
# Reuse orient to calculate where the solid face will be.
loc = (orient * -64) + Vec.from_str(inst['origin'])
INST_LOCS[targ] = loc
for out in inst.output_targets():
io_list.append((targ, out))
if not inst.outputs and inst.fixup['$connectioncount'] == '0':
# If the item doesn't have any connections, 'connect'
# it to itself so we'll generate a 128x128 tile segment.
io_list.append((targ, targ))
inst.remove() # Remove the instance itself from the map.
for start_floor, end_floor in FLOOR_IO:
if end_floor not in INST_LOCS:
# Not a marker - remove this and the antline.
for toggle in conditions.VMF.by_target[end_floor]:
conditions.remove_ant_toggle(toggle)
continue
box_min = Vec(INST_LOCS[start_floor])
box_min.min(INST_LOCS[end_floor])
box_max = Vec(INST_LOCS[start_floor])
box_max.max(INST_LOCS[end_floor])
if box_min.z != box_max.z:
continue # They're not in the same level!
z = box_min.z
if SETTINGS['rotate_beams']:
# We have to generate 1 model per 64x64 block to do rotation...
gen_rotated_squarebeams(
box_min - (64, 64, 0),
box_max + (64, 64, -8),
skin=SETTINGS['beam_skin'],
max_rot=SETTINGS['rotate_beams'],
)
else:
# Make the squarebeams props, using big models if possible
gen_squarebeams(box_min + (-64, -64, 0),
box_max + (64, 64, -8),
skin=SETTINGS['beam_skin'])
# Add a player_clip brush across the whole area
conditions.VMF.add_brush(
conditions.VMF.make_prism(
p1=box_min - (64, 64, FLOOR_DEPTH),
p2=box_max + (64, 64, 0),
mat=MATS['clip'][0],
).solid)
# Add a noportal_volume covering the surface, in case there's
# room for a portal.
noportal_solid = conditions.VMF.make_prism(
# Don't go all the way to the sides, so it doesn't affect wall
# brushes.
p1=box_min - (63, 63, 9),
p2=box_max + (63, 63, 0),
mat='tools/toolsinvisible',
).solid
noportal_ent = conditions.VMF.create_ent(
classname='func_noportal_volume',
origin=box_min.join(' '),
)
noportal_ent.solids.append(noportal_solid)
if SETTINGS['base_is_disp']:
# Use displacements for the base instead.
make_alpha_base(
box_min + (-64, -64, 0),
box_max + (64, 64, 0),
noise=alpha_noise,
)
for x, y in utils.iter_grid(
min_x=int(box_min.x),
max_x=int(box_max.x) + 1,
min_y=int(box_min.y),
max_y=int(box_max.y) + 1,
stride=128,
):
# Build the set of all positions..
floor_neighbours[z][x, y] = -1
# Mark borders we need to fill in, and the angle (for func_instance)
# The wall is the face pointing inwards towards the bottom brush,
# and the ceil is the ceiling of the block above the bordering grid
# points.
for x in range(int(box_min.x), int(box_max.x) + 1, 128):
# North
floor_edges.append(
BorderPoints(
wall=Vec(x, box_max.y + 64, z - 64),
ceil=Vec_tuple(x, box_max.y + 128, z),
rot=270,
))
# South
floor_edges.append(
BorderPoints(
wall=Vec(x, box_min.y - 64, z - 64),
ceil=Vec_tuple(x, box_min.y - 128, z),
rot=90,
))
for y in range(int(box_min.y), int(box_max.y) + 1, 128):
# East
floor_edges.append(
BorderPoints(
wall=Vec(box_max.x + 64, y, z - 64),
ceil=Vec_tuple(box_max.x + 128, y, z),
rot=180,
))
# West
floor_edges.append(
BorderPoints(
wall=Vec(box_min.x - 64, y, z - 64),
ceil=Vec_tuple(box_min.x - 128, y, z),
rot=0,
))
# Now count boundries near tiles, then generate them.
# Do it seperately for each z-level:
for z, xy_dict in floor_neighbours.items(): # type: float, dict
for x, y in xy_dict: # type: float, float
# We want to count where there aren't any tiles
xy_dict[x, y] = (((x - 128, y - 128) not in xy_dict) +
((x - 128, y + 128) not in xy_dict) +
((x + 128, y - 128) not in xy_dict) +
((x + 128, y + 128) not in xy_dict) +
((x - 128, y) not in xy_dict) +
((x + 128, y) not in xy_dict) +
((x, y - 128) not in xy_dict) +
((x, y + 128) not in xy_dict))
max_x = max_y = 0
weights = {}
# Now the counts are all correct, compute the weight to apply
# for tiles.
# Adding the neighbouring counts will make a 5x5 area needed to set
# the center to 0.
for (x, y), cur_count in xy_dict.items():
max_x = max(x, max_x)
max_y = max(y, max_y)
# Orthrogonal is worth 0.2, diagonal is worth 0.1.
# Not-present tiles would be 8 - the maximum
tile_count = (0.8 * cur_count + 0.1 * xy_dict.get(
(x - 128, y - 128), 8) + 0.1 * xy_dict.get(
(x - 128, y + 128), 8) + 0.1 * xy_dict.get(
(x + 128, y - 128), 8) + 0.1 * xy_dict.get(
(x + 128, y + 128), 8) + 0.2 * xy_dict.get(
(x - 128, y), 8) + 0.2 * xy_dict.get(
(x, y - 128), 8) + 0.2 * xy_dict.get(
(x, y + 128), 8) + 0.2 * xy_dict.get(
(x + 128, y), 8))
# The number ranges from 0 (all tiles) to 12.8 (no tiles).
# All tiles should still have a small chance to generate tiles.
weights[x, y] = min((tile_count + 0.5) / 8, 1)
# Share the detail entity among same-height tiles..
detail_ent = conditions.VMF.create_ent(classname='func_detail', )
for x, y in xy_dict:
convert_floor(
Vec(x, y, z),
overlay_ids,
MATS,
SETTINGS,
sign_loc,
detail_ent,
noise_weight=weights[x, y],
noise_func=noise,
)
add_floor_sides(floor_edges)
conditions.reallocate_overlays(overlay_ids)
return conditions.RES_EXHAUSTED
def res_cutout_tile(vmf: srctools.VMF, res: Property):
"""Generate random quarter tiles, like in Destroyed or Retro maps.
- "MarkerItem" is the instance to look for.
- "TileSize" can be "2x2" or "4x4".
- rotateMax is the amount of degrees to rotate squarebeam models.
Materials:
- "squarebeams" is the squarebeams variant to use.
- "ceilingwalls" are the sides of the ceiling section.
- "floorbase" is the texture under floor sections.
- "tile_glue" is used on top of a thinner tile segment.
- "clip" is the player_clip texture used over floor segments.
(This allows customising the surfaceprop.)
- "Floor4x4Black", "Ceil2x2White" and other combinations can be used to
override the textures used.
"""
marker_filenames = instanceLocs.resolve(res['markeritem'])
INST_LOCS = {} # Map targetnames -> surface loc
CEIL_IO = [] # Pairs of ceil inst corners to cut out.
FLOOR_IO = [] # Pairs of floor inst corners to cut out.
overlay_ids = {} # When we replace brushes, we need to fix any overlays
# on that surface.
MATS.clear()
floor_edges = [] # Values to pass to add_floor_sides() at the end
sign_locs = set()
# If any signage is present in the map, we need to force tiles to
# appear at that location!
for over in vmf.by_class['info_overlay']:
if (
over['material'].casefold() in FORCE_TILE_MATS and
# Only check floor/ceiling overlays
over['basisnormal'] in ('0 0 1', '0 0 -1')
):
add_signage_loc(sign_locs, Vec.from_str(over['origin']))
for item in connections.ITEMS.values():
for ind_pan in item.ind_panels:
loc = Vec(0, 0, -64)
loc.localise(
Vec.from_str(ind_pan['origin']),
Vec.from_str(ind_pan['angles']),
)
add_signage_loc(sign_locs, loc)
SETTINGS = {
'floor_chance': srctools.conv_int(
res['floorChance', '100'], 100),
'ceil_chance': srctools.conv_int(
res['ceilingChance', '100'], 100),
'floor_glue_chance': srctools.conv_int(
res['floorGlueChance', '0']),
'ceil_glue_chance': srctools.conv_int(
res['ceilingGlueChance', '0']),
'rotate_beams': int(srctools.conv_float(
res['rotateMax', '0']) * BEAM_ROT_PRECISION),
'beam_skin': res['squarebeamsSkin', '0'],
'base_is_disp': srctools.conv_bool(res['dispBase', '0']),
'quad_floor': res['FloorSize', '4x4'].casefold() == '2x2',
'quad_ceil': res['CeilingSize', '4x4'].casefold() == '2x2',
}
random.seed(vbsp.MAP_RAND_SEED + '_CUTOUT_TILE_NOISE')
noise = SimplexNoise(period=4 * 40) # 4 tiles/block, 50 blocks max
# We want to know the number of neighbouring tile cutouts before
# placing tiles - blocks away from the sides generate fewer tiles.
floor_neighbours = defaultdict(dict) # all_floors[z][x,y] = count
for mat_prop in res.find_key('Materials', []):
MATS[mat_prop.name].append(mat_prop.value)
if SETTINGS['base_is_disp']:
# We want the normal brushes to become nodraw.
MATS['floorbase_disp'] = MATS['floorbase']
MATS['floorbase'] = ['tools/toolsnodraw']
# Since this uses random data for initialisation, the alpha and
# regular will use slightly different patterns.
alpha_noise = SimplexNoise(period=4 * 50)
else:
alpha_noise = None
for key, default in TEX_DEFAULT:
if key not in MATS:
MATS[key] = [default]
# Find our marker ents
for inst in vmf.by_class['func_instance']:
if inst['file'].casefold() not in marker_filenames:
continue
targ = inst['targetname']
normal = Vec(0, 0, 1).rotate_by_str(inst['angles', '0 0 0'])
# Check the orientation of the marker to figure out what to generate
if normal == (0, 0, 1):
io_list = FLOOR_IO
else:
io_list = CEIL_IO
# Reuse orient to calculate where the solid face will be.
loc = Vec.from_str(inst['origin']) - 64 * normal
INST_LOCS[targ] = loc
item = connections.ITEMS[targ]
item.delete_antlines()
if item.outputs:
for conn in list(item.outputs):
if conn.to_item.inst['file'].casefold() in marker_filenames:
io_list.append((targ, conn.to_item.name))
else:
LOGGER.warning('Cutout tile connected to non-cutout!')
conn.remove() # Delete the connection.
else:
# If the item doesn't have any connections, 'connect'
# it to itself so we'll generate a 128x128 tile segment.
io_list.append((targ, targ))
# Remove all traces of this item (other than in connections lists).
inst.remove()
del connections.ITEMS[targ]
for start_floor, end_floor in FLOOR_IO:
box_min = Vec(INST_LOCS[start_floor])
box_min.min(INST_LOCS[end_floor])
box_max = Vec(INST_LOCS[start_floor])
box_max.max(INST_LOCS[end_floor])
if box_min.z != box_max.z:
continue # They're not in the same level!
z = box_min.z
if SETTINGS['rotate_beams']:
# We have to generate 1 model per 64x64 block to do rotation...
gen_rotated_squarebeams(
vmf,
box_min - (64, 64, 0),
box_max + (64, 64, -8),
skin=SETTINGS['beam_skin'],
max_rot=SETTINGS['rotate_beams'],
)
else:
# Make the squarebeams props, using big models if possible
gen_squarebeams(
vmf,
box_min + (-64, -64, 0),
box_max + (64, 64, -8),
skin=SETTINGS['beam_skin']
)
# Add a player_clip brush across the whole area
vmf.add_brush(vmf.make_prism(
p1=box_min - (64, 64, FLOOR_DEPTH),
p2=box_max + (64, 64, 0),
mat=MATS['clip'][0],
).solid)
# Add a noportal_volume covering the surface, in case there's
# room for a portal.
noportal_solid = vmf.make_prism(
# Don't go all the way to the sides, so it doesn't affect wall
# brushes.
p1=box_min - (63, 63, 9),
p2=box_max + (63, 63, 0),
mat='tools/toolsinvisible',
).solid
noportal_ent = vmf.create_ent(
classname='func_noportal_volume',
origin=box_min.join(' '),
)
noportal_ent.solids.append(noportal_solid)
if SETTINGS['base_is_disp']:
# Use displacements for the base instead.
make_alpha_base(
vmf,
box_min + (-64, -64, 0),
box_max + (64, 64, 0),
noise=alpha_noise,
)
for x, y in utils.iter_grid(
min_x=int(box_min.x),
max_x=int(box_max.x) + 1,
min_y=int(box_min.y),
max_y=int(box_max.y) + 1,
stride=128,
):
# Build the set of all positions..
floor_neighbours[z][x, y] = -1
# Mark borders we need to fill in, and the angle (for func_instance)
# The wall is the face pointing inwards towards the bottom brush,
# and the ceil is the ceiling of the block above the bordering grid
# points.
for x in range(int(box_min.x), int(box_max.x) + 1, 128):
# North
floor_edges.append(BorderPoints(
wall=Vec(x, box_max.y + 64, z - 64),
ceil=Vec_tuple(x, box_max.y + 128, z),
rot=270,
))
# South
floor_edges.append(BorderPoints(
wall=Vec(x, box_min.y - 64, z - 64),
ceil=Vec_tuple(x, box_min.y - 128, z),
rot=90,
))
for y in range(int(box_min.y), int(box_max.y) + 1, 128):
# East
floor_edges.append(BorderPoints(
wall=Vec(box_max.x + 64, y, z - 64),
ceil=Vec_tuple(box_max.x + 128, y, z),
rot=180,
))
# West
floor_edges.append(BorderPoints(
wall=Vec(box_min.x - 64, y, z - 64),
ceil=Vec_tuple(box_min.x - 128, y, z),
rot=0,
))
# Now count boundaries near tiles, then generate them.
# Do it separately for each z-level:
for z, xy_dict in floor_neighbours.items(): # type: float, dict
for x, y in xy_dict: # type: float, float
# We want to count where there aren't any tiles
xy_dict[x, y] = (
((x - 128, y - 128) not in xy_dict) +
((x - 128, y + 128) not in xy_dict) +
((x + 128, y - 128) not in xy_dict) +
((x + 128, y + 128) not in xy_dict) +
((x - 128, y) not in xy_dict) +
((x + 128, y) not in xy_dict) +
((x, y - 128) not in xy_dict) +
((x, y + 128) not in xy_dict)
)
max_x = max_y = 0
weights = {}
# Now the counts are all correct, compute the weight to apply
# for tiles.
# Adding the neighbouring counts will make a 5x5 area needed to set
# the center to 0.
for (x, y), cur_count in xy_dict.items():
max_x = max(x, max_x)
max_y = max(y, max_y)
# Orthrogonal is worth 0.2, diagonal is worth 0.1.
# Not-present tiles would be 8 - the maximum
tile_count = (
0.8 * cur_count +
0.1 * xy_dict.get((x - 128, y - 128), 8) +
0.1 * xy_dict.get((x - 128, y + 128), 8) +
0.1 * xy_dict.get((x + 128, y - 128), 8) +
0.1 * xy_dict.get((x + 128, y + 128), 8) +
0.2 * xy_dict.get((x - 128, y), 8) +
0.2 * xy_dict.get((x, y - 128), 8) +
0.2 * xy_dict.get((x, y + 128), 8) +
0.2 * xy_dict.get((x + 128, y), 8)
)
# The number ranges from 0 (all tiles) to 12.8 (no tiles).
# All tiles should still have a small chance to generate tiles.
weights[x, y] = min((tile_count + 0.5) / 8, 1)
# Share the detail entity among same-height tiles..
detail_ent = vmf.create_ent(
classname='func_detail',
)
for x, y in xy_dict:
convert_floor(
vmf,
Vec(x, y, z),
overlay_ids,
MATS,
SETTINGS,
sign_locs,
detail_ent,
noise_weight=weights[x, y],
noise_func=noise,
)
add_floor_sides(vmf, floor_edges)
conditions.reallocate_overlays(overlay_ids)
return conditions.RES_EXHAUSTED
def gen_squarebeams(vmf: VMF, p1: Vec, p2: Vec, skin, gen_collision=True):
"""Generate squarebeams props to fill the space given.
The space should be in multiples of 64. The squarebeams brush will
be aligned to the lowest point in the space.
"""
z = min(p1.z, p2.z) + 8
min_x = min(p1.x, p2.x)
min_y = min(p1.y, p2.y)
max_x = max(p1.x, p2.x)
max_y = max(p1.y, p2.y)
dist_x = max_x - min_x
dist_y = max_y - min_y
# After this x or y dist, move to the next grid size.
cutoff_512_x = dist_x // 512 * 512
cutoff_256_x = dist_x // 256 * 256
cutoff_128_x = dist_x // 128 * 128
cutoff_512_y = dist_y // 512 * 512
cutoff_256_y = dist_y // 256 * 256
cutoff_128_y = dist_y // 128 * 128
for x, y in utils.iter_grid(
max_x=int(dist_x),
max_y=int(dist_y),
stride=64,
):
if x < cutoff_512_x and y < cutoff_512_y:
# Make 1 prop every 512 units, at the center
if x % 512 == 0 and y % 512 == 0:
_make_squarebeam(
vmf,
Vec(min_x + x + 256, min_y + y + 256, z),
skin, '_8x8',
)
elif x < cutoff_256_x and y < cutoff_256_y:
if x % 256 == 0 and y % 256 == 0:
_make_squarebeam(
vmf,
Vec(min_x + x + 128, min_y + y + 128, z),
skin, '_4x4',
)
elif x < cutoff_128_x and y < cutoff_128_y:
if x % 128 == 0 and y % 128 == 0:
_make_squarebeam(
vmf,
Vec(min_x + x + 64, min_y + y + 64, z),
skin, '_2x2',
)
else:
# Make squarebeams for every point!
_make_squarebeam(
vmf,
Vec(min_x + x + 32, min_y + y + 32, z),
skin,
)
if gen_collision:
collision = vmf.create_ent(
classname='func_brush',
disableshadows='1',
disableflashlight='1',
disablereceiveshadows='1',
shadowdepthnocache='1',
solidity='2', # Always Solid
solidbsp='1',
)
for x in range(int(min_x)+64, int(max_x), 64):
collision.solids.append(
vmf.make_prism(
p1=Vec(x-2, min_y+2, z-2),
p2=Vec(x+2, max_y-2, z-8),
mat='tools/toolsnodraw',
).solid
)
for y in range(int(min_y)+64, int(max_y), 64):
collision.solids.append(
vmf.make_prism(
p1=Vec(min_x+2, y-2, z-2),
p2=Vec(max_x-2, y+2, z-8),
mat='tools/toolsnodraw',
).solid
)
for x1, y1, x2, y2 in [
(min_x, min_y, max_x, min_y+2),
(min_x, max_y, max_x, max_y-2),
(min_x, min_y, min_x+2, max_y),
(max_x, min_y, max_x-2, max_y),
]:
collision.solids.append(
vmf.make_prism(
p1=Vec(x1, y1, z-2),
p2=Vec(x2, y2, z-8),
mat='tools/toolsnodraw',
).solid
)
def convert_floor(
vmf: VMF,
loc: Vec,
overlay_ids,
mats,
settings,
signage_loc,
detail,
noise_weight,
noise_func: SimplexNoise,
):
"""Cut out tiles at the specified location."""
# We pop it, so the face isn't detected by other logic - otherwise it'll
# be retextured and whatnot, which we don't want.
try:
brush = conditions.SOLIDS.pop(loc.as_tuple())
except KeyError:
return False # No tile here!
if brush.normal == (0, 0, 1):
# This is a pillar block - there isn't actually tiles here!
# We need to generate a squarebeams brush to fill this gap.
brush.face.mat = 'tools/toolsnodraw' # It won't be visible
temp_data = template_brush.import_template(
temp_name=FLOOR_TEMP_PILLAR,
origin=loc,
)
template_brush.retexture_template(
temp_data,
loc,
# Switch to use the configured squarebeams texture
replace_tex={
consts.Special.SQUAREBEAMS: random.choice(
MATS['squarebeams']
),
}
)
return False
# The new brush IDs overlays need to use
# NOTE: strings, not ints!
ant_locs = overlay_ids[str(brush.face.id)] = []
# Move the floor brush down and switch to the floorbase texture.
for plane in brush.face.planes:
plane.z -= FLOOR_DEPTH
brush.face.mat = random.choice(mats['floorbase'])
loc.x -= 64
loc.y -= 64
for x, y in utils.iter_grid(max_x=4, max_y=4):
tile_loc = loc + (x * 32 + 16, y * 32 + 16, 0)
if tile_loc.as_tuple() in signage_loc:
# Force the tile to be present under signage..
should_make_tile = True
rand = 100
# We don't need to check this again in future!
signage_loc.remove(tile_loc.as_tuple())
else:
# Create a number between 0-100
rand = 100 * get_noise(tile_loc // 32, noise_func) + 10
# Adjust based on the noise_weight value, so boundries have more tiles
rand *= 0.1 + 0.9 * (1 - noise_weight)
should_make_tile = rand < settings['floor_chance']
if random.randint(0, 7) == 0:
# Sometimes there'll be random holes/extra tiles
should_make_tile = not should_make_tile
if should_make_tile:
# Full tile
tile = make_tile(
vmf,
p1=tile_loc - (16, 16, 0),
p2=tile_loc + (16, 16, -2),
top_mat=vbsp.get_tex(str(brush.color) + '.floor'),
bottom_mat='tools/toolsnodraw',
beam_mat=random.choice(mats['squarebeams']),
)
detail.solids.append(tile.solid)
ant_locs.append(str(tile.top.id))
elif rand < settings['floor_glue_chance']:
# 'Glue' tile - this chance should be higher, making these appear
# bordering the full tiles.
tile = make_tile(
vmf,
p1=tile_loc - (16, 16, 1),
p2=tile_loc + (16, 16, -2),
top_mat=random.choice(mats['tile_glue']),
bottom_mat='tools/toolsnodraw',
beam_mat=random.choice(mats['squarebeams']),
)
detail.solids.append(tile.solid)
else:
# No tile at this loc!
pass
return True
def res_goo_debris(res: Property):
"""Add random instances to goo squares.
Options:
- file: The filename for the instance. The variant files should be
suffixed with `_1.vmf`, `_2.vmf`, etc.
- space: the number of border squares which must be filled with goo
for a square to be eligible - defaults to 1.
- weight, number: see the `Variant` result, a set of weights for the
options
- chance: The percentage chance a square will have a debris item
- offset: A random xy offset applied to the instances.
"""
import brushLoc
space = res.int('spacing', 1)
rand_count = res.int('number', None)
if rand_count:
rand_list = weighted_random(
rand_count,
res['weights', ''],
)
else:
rand_list = None # type: Optional[List[int]]
chance = res.int('chance', 30) / 100
file = res['file']
offset = res.int('offset', 0)
if file.endswith('.vmf'):
file = file[:-4]
goo_top_locs = {
pos.as_tuple()
for pos, block in
brushLoc.POS.items()
if block.is_goo and block.is_top
}
if space == 0:
# No spacing needed, just copy
possible_locs = [Vec(loc) for loc in goo_top_locs]
else:
possible_locs = []
for x, y, z in goo_top_locs:
# Check to ensure the neighbouring blocks are also
# goo brushes (depending on spacing).
for x_off, y_off in utils.iter_grid(
min_x=-space,
max_x=space + 1,
min_y=-space,
max_y=space + 1,
stride=1,
):
if x_off == y_off == 0:
continue # We already know this is a goo location
if (x + x_off, y + y_off, z) not in goo_top_locs:
break # This doesn't qualify
else:
possible_locs.append(brushLoc.grid_to_world(Vec(x,y,z)))
LOGGER.info(
'GooDebris: {}/{} locations',
len(possible_locs),
len(goo_top_locs),
)
suff = ''
for loc in possible_locs:
random.seed('goo_debris_{}_{}_{}'.format(loc.x, loc.y, loc.z))
if random.random() > chance:
continue
if rand_list is not None:
suff = '_' + str(random.choice(rand_list) + 1)
if offset > 0:
loc.x += random.randint(-offset, offset)
loc.y += random.randint(-offset, offset)
loc.z -= 32 # Position the instances in the center of the 128 grid.
VMF.create_ent(
classname='func_instance',
file=file + suff + '.vmf',
origin=loc.join(' '),
angles='0 {} 0'.format(random.randrange(0, 3600)/10)
)
return RES_EXHAUSTED
def res_cutout_tile(inst, res):
"""Generate random quarter tiles, like in Destroyed or Retro maps.
- "MarkerItem" is the instance to look for.
- "TileSize" can be "2x2" or "4x4".
- rotateMax is the amount of degrees to rotate squarebeam models.
Materials:
- "squarebeams" is the squarebeams variant to use.
- "ceilingwalls" are the sides of the ceiling section.
- "floorbase" is the texture under floor sections.
- "tile_glue" is used on top of a thinner tile segment.
- "clip" is the player_clip texture used over floor segments.
(This allows customising the surfaceprop.)
- "Floor4x4Black", "Ceil2x2White" and other combinations can be used to
override the textures used.
"""
item = resolve_inst(res['markeritem'])
INST_LOCS = {} # Map targetnames -> surface loc
CEIL_IO = [] # Pairs of ceil inst corners to cut out.
FLOOR_IO = [] # Pairs of floor inst corners to cut out.
overlay_ids = {} # When we replace brushes, we need to fix any overlays
# on that surface.
MATS.clear()
floor_edges = [] # Values to pass to add_floor_sides() at the end
sign_loc = set(FORCE_LOCATIONS)
# If any signage is present in the map, we need to force tiles to
# appear at that location!
for over in conditions.VMF.by_class['info_overlay']:
if (
over['material'].casefold() in FORCE_TILE_MATS and
# Only check floor/ceiling overlays
over['basisnormal'] in ('0 0 1', '0 0 -1')
):
loc = Vec.from_str(over['origin'])
# Sometimes (light bridges etc) a sign will be halfway between
# tiles, so in that case we need to force 2 tiles.
loc_min = (loc - (15, 15, 0)) // 32 * 32 + (16, 16, 0)
loc_max = (loc + (15, 15, 0)) // 32 * 32 + (16, 16, 0)
sign_loc.add(loc_min.as_tuple())
sign_loc.add(loc_max.as_tuple())
SETTINGS = {
'floor_chance': utils.conv_int(
res['floorChance', '100'], 100),
'ceil_chance': utils.conv_int(
res['ceilingChance', '100'], 100),
'floor_glue_chance': utils.conv_int(
res['floorGlueChance', '0']),
'ceil_glue_chance': utils.conv_int(
res['ceilingGlueChance', '0']),
'rotate_beams': int(utils.conv_float(
res['rotateMax', '0']) * BEAM_ROT_PRECISION),
'beam_skin': res['squarebeamsSkin', '0'],
'base_is_disp': utils.conv_bool(res['dispBase', '0']),
'quad_floor': res['FloorSize', '4x4'].casefold() == '2x2',
'quad_ceil': res['CeilingSize', '4x4'].casefold() == '2x2',
}
for mat_prop in res['Materials', []]:
MATS[mat_prop.name].append(mat_prop.value)
if SETTINGS['base_is_disp']:
# We want the normal brushes to become nodraw.
MATS['floorbase_disp'] = MATS['floorbase']
MATS['floorbase'] = ['tools/toolsnodraw']
for key, default in TEX_DEFAULT:
if key not in MATS:
MATS[key] = [default]
# Find our marker ents
for inst in conditions.VMF.by_class['func_instance']: # type: VLib.Entity
if inst['file'].casefold() not in item:
continue
targ = inst['targetname']
orient = Vec(0, 0, 1).rotate_by_str(inst['angles', '0 0 0'])
# Check the orientation of the marker to figure out what to generate
if orient == (0, 0, 1):
io_list = FLOOR_IO
else:
io_list = CEIL_IO
# Reuse orient to calculate where the solid face will be.
loc = (orient * -64) + Vec.from_str(inst['origin'])
INST_LOCS[targ] = loc
for out in inst.output_targets():
io_list.append((targ, out))
if not inst.outputs and inst.fixup['$connectioncount'] == '0':
# If the item doesn't have any connections, 'connect'
# it to itself so we'll generate a 128x128 tile segment.
io_list.append((targ, targ))
inst.remove() # Remove the instance itself from the map.
for start_floor, end_floor in FLOOR_IO:
if end_floor not in INST_LOCS:
# Not a marker - remove this and the antline.
for toggle in conditions.VMF.by_target[end_floor]:
conditions.remove_ant_toggle(toggle)
continue
detail_ent = conditions.VMF.create_ent(
classname='func_detail'
)
box_min = Vec(INST_LOCS[start_floor])
box_min.min(INST_LOCS[end_floor])
box_max = Vec(INST_LOCS[start_floor])
box_max.max(INST_LOCS[end_floor])
if box_min.z != box_max.z:
continue # They're not in the same level!
z = box_min.z
if SETTINGS['rotate_beams']:
# We have to generate 1 model per 64x64 block to do rotation...
gen_rotated_squarebeams(
box_min - (64, 64, 0),
box_max + (64, 64, -8),
skin=SETTINGS['beam_skin'],
max_rot=SETTINGS['rotate_beams'],
)
else:
# Make the squarebeams props, using big models if possible
gen_squarebeams(
box_min + (-64, -64, 0),
box_max + (64, 64, -8),
skin=SETTINGS['beam_skin']
)
# Add a player_clip brush across the whole area
conditions.VMF.add_brush(conditions.VMF.make_prism(
p1=box_min - (64, 64, FLOOR_DEPTH),
p2=box_max + (64, 64, 0),
mat=MATS['clip'][0],
).solid)
# Add a noportal_volume covering the surface, in case there's
# room for a portal.
noportal_solid = conditions.VMF.make_prism(
# Don't go all the way to the sides, so it doesn't affect wall
# brushes.
p1=box_min - (63, 63, 9),
p2=box_max + (63, 63, 0),
mat='tools/toolsinvisible',
).solid
noportal_ent = conditions.VMF.create_ent(
classname='func_noportal_volume',
origin=box_min.join(' '),
)
noportal_ent.solids.append(noportal_solid)
if SETTINGS['base_is_disp']:
# Use displacements for the base instead.
make_alpha_base(
box_min + (-64, -64, 0),
box_max + (64, 64, 0),
)
for x, y in utils.iter_grid(
min_x=int(box_min.x),
max_x=int(box_max.x)+1,
min_y=int(box_min.y),
max_y=int(box_max.y)+1,
stride=128,
):
convert_floor(
Vec(x, y, z),
overlay_ids,
MATS,
SETTINGS,
sign_loc,
detail_ent,
)
# Mark borders we need to fill in, and the angle (for func_instance)
# The wall is the face pointing inwards towards the bottom brush,
# and the ceil is the ceiling of the block above the bordering grid
# points.
for x in range(int(box_min.x), int(box_max.x) + 1, 128):
# North
floor_edges.append(BorderPoints(
wall=Vec(x, box_max.y + 64, z - 64),
ceil=Vec_tuple(x, box_max.y + 128, z),
rot=270,
))
# South
floor_edges.append(BorderPoints(
wall=Vec(x, box_min.y - 64, z - 64),
ceil=Vec_tuple(x, box_min.y - 128, z),
rot=90,
))
for y in range(int(box_min.y), int(box_max.y) + 1, 128):
# East
floor_edges.append(BorderPoints(
wall=Vec(box_max.x + 64, y, z - 64),
ceil=Vec_tuple(box_max.x + 128, y, z),
rot=180,
))
# West
floor_edges.append(BorderPoints(
wall=Vec(box_min.x - 64, y, z - 64),
ceil=Vec_tuple(box_min.x - 128, y, z),
rot=0,
))
add_floor_sides(floor_edges)
conditions.reallocate_overlays(overlay_ids)
return True
def convert_floor(
loc,
overlay_ids,
mats,
settings,
signage_loc,
detail,
):
"""Cut out tiles at the specified location."""
try:
brush = conditions.SOLIDS[loc.as_tuple()]
except KeyError:
return False # No tile here!
if brush.normal == (0, 0, 1):
# This is a pillar block - there isn't actually tiles here!
# We need to generate a squarebeams brush to fill this gap.
brush.face.mat = 'tools/toolsnodraw' # It won't be visible
temp_data = conditions.import_template(
temp_name=FLOOR_TEMP_PILLAR,
origin=loc,
)
conditions.retexture_template(
temp_data,
loc,
# Switch to use the configured squarebeams texture
replace_tex={
'anim_wp/framework/squarebeams': random.choice(
MATS['squarebeams']
),
}
)
return False
# The new brush IDs overlays need to use
# NOTE: strings, not ints!
ant_locs = overlay_ids[str(brush.face.id)] = []
# Move the floor brush down and switch to the floorbase texture.
for plane in brush.face.planes:
plane.z -= FLOOR_DEPTH
brush.face.mat = random.choice(mats['floorbase'])
loc.x -= 64
loc.y -= 64
random.seed('cutout_tile' + loc.join(' '))
tile_map = [
(random.randint(0, 100) < settings['floor_chance'])
for _ in range(16)
]
for x, y in utils.iter_grid(max_x=4, max_y=4):
tile_loc = loc + (x*32 + 16, y*32 + 16, 0)
if tile_loc.as_tuple() in signage_loc:
should_make_tile = True
# We don't need to check this again in future!
signage_loc.remove(tile_loc.as_tuple())
else:
should_make_tile = tile_map[x*4 + y]
if should_make_tile:
# Full tile
tile = make_tile(
p1=tile_loc - (16, 16, 0),
p2=tile_loc + (16, 16, -2),
top_mat=vbsp.get_tex(str(brush.color) + '.floor'),
bottom_mat='tools/toolsnodraw',
beam_mat=random.choice(mats['squarebeams']),
)
detail.solids.append(tile.solid)
ant_locs.append(str(tile.top.id))
elif random.randint(0, 100) < settings['floor_glue_chance']:
# 'Glue' tile
tile = make_tile(
p1=tile_loc - (16, 16, 1),
p2=tile_loc + (16, 16, -2),
top_mat=random.choice(mats['tile_glue']),
bottom_mat='tools/toolsnodraw',
beam_mat=random.choice(mats['squarebeams']),
)
detail.solids.append(tile.solid)
else:
# No tile at this loc!
pass
return True
