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import io
import json
import urllib.parse
import urllib.request
from math import pi
import comfy.model_management as model_management
import comfy.utils
import numpy as np
import torch
from PIL import Image
from ..log import log
from ..utils import (
EASINGS,
apply_easing,
get_server_info,
numpy_NFOV,
pil2tensor,
tensor2np,
)
def get_image(filename, subfolder, folder_type):
log.debug(
f"Getting image {filename} from foldertype {folder_type} {f'in subfolder: {subfolder}' if subfolder else ''}"
)
data = {"filename": filename, "subfolder": subfolder, "type": folder_type}
base_url, port = get_server_info()
url_values = urllib.parse.urlencode(data)
url = f"http://{base_url}:{port}/view?{url_values}"
log.debug(f"Fetching image from {url}")
with urllib.request.urlopen(url) as response:
return io.BytesIO(response.read())
class MTB_ToDevice:
"""Send a image or mask tensor to the given device."""
@classmethod
def INPUT_TYPES(cls):
devices = ["cpu"]
if torch.backends.mps.is_available():
devices.append("mps")
if torch.cuda.is_available():
devices.append("cuda")
for i in range(torch.cuda.device_count()):
devices.append(f"cuda{i}")
return {
"required": {
"ignore_errors": ("BOOLEAN", {"default": False}),
"device": (devices, {"default": "cpu"}),
},
"optional": {
"image": ("IMAGE",),
"mask": ("MASK",),
},
}
RETURN_TYPES = ("IMAGE", "MASK")
RETURN_NAMES = ("images", "masks")
CATEGORY = "mtb/utils"
FUNCTION = "to_device"
def to_device(
self,
*,
ignore_errors=False,
device="cuda",
image: torch.Tensor | None = None,
mask: torch.Tensor | None = None,
):
if not ignore_errors and image is None and mask is None:
raise ValueError(
"You must either provide an image or a mask,"
" use ignore_error to passthrough"
)
if image is not None:
image = image.to(device)
if mask is not None:
mask = mask.to(device)
return (image, mask)
# class MTB_ApplyTextTemplate:
class MTB_ApplyTextTemplate:
"""
Experimental node to interpolate strings from inputs.
Interpolation just requires {}, for instance:
Some string {var_1} and {var_2}
"""
@classmethod
def INPUT_TYPES(cls):
return {
"required": {
"template": ("STRING", {"default": "", "multiline": True}),
},
}
RETURN_TYPES = ("STRING",)
RETURN_NAMES = ("string",)
CATEGORY = "mtb/utils"
FUNCTION = "execute"
def execute(self, *, template: str, **kwargs):
res = f"{template}"
for k, v in kwargs.items():
res = res.replace(f"{{{k}}}", f"{v}")
return (res,)
class MTB_MatchDimensions:
"""Match images dimensions along the given dimension, preserving aspect ratio."""
@classmethod
def INPUT_TYPES(cls):
return {
"required": {
"source": ("IMAGE",),
"reference": ("IMAGE",),
"match": (["height", "width"], {"default": "height"}),
},
}
RETURN_TYPES = ("IMAGE", "INT", "INT")
RETURN_NAMES = ("image", "new_width", "new_height")
CATEGORY = "mtb/utils"
FUNCTION = "execute"
def execute(
self, source: torch.Tensor, reference: torch.Tensor, match: str
):
import torchvision.transforms.functional as VF
_batch_size, height, width, _channels = source.shape
_rbatch_size, rheight, rwidth, _rchannels = reference.shape
source_aspect_ratio = width / height
# reference_aspect_ratio = rwidth / rheight
source = source.permute(0, 3, 1, 2)
reference = reference.permute(0, 3, 1, 2)
if match == "height":
new_height = rheight
new_width = int(rheight * source_aspect_ratio)
else:
new_width = rwidth
new_height = int(rwidth / source_aspect_ratio)
resized_images = [
VF.resize(
source[i],
(new_height, new_width),
antialias=True,
interpolation=Image.BICUBIC,
)
for i in range(_batch_size)
]
resized_source = torch.stack(resized_images, dim=0)
resized_source = resized_source.permute(0, 2, 3, 1)
return (resized_source, new_width, new_height)
class MTB_FloatToFloats:
"""Conversion utility for compatibility with other extensions (AD, IPA, Fitz are using FLOAT to represent list of floats.)"""
@classmethod
def INPUT_TYPES(cls):
return {
"required": {
"float": ("FLOAT", {"default": 0.0, "forceInput": True}),
}
}
RETURN_TYPES = ("FLOATS",)
RETURN_NAMES = ("floats",)
CATEGORY = "mtb/utils"
FUNCTION = "convert"
def convert(self, float: float):
return (float,)
class MTB_FloatsToInts:
"""Conversion utility for compatibility with frame interpolation."""
@classmethod
def INPUT_TYPES(cls):
return {
"required": {
"floats": ("FLOATS", {"forceInput": True}),
}
}
RETURN_TYPES = ("INTS", "INT")
CATEGORY = "mtb/utils"
FUNCTION = "convert"
def convert(self, floats: list[float]):
vals = [int(x) for x in floats]
return (vals, vals)
class MTB_FloatsToFloat:
"""Conversion utility for compatibility with other extensions (AD, IPA, Fitz are using FLOAT to represent list of floats.)"""
@classmethod
def INPUT_TYPES(cls):
return {
"required": {
"floats": ("FLOATS",),
}
}
RETURN_TYPES = ("FLOAT",)
RETURN_NAMES = ("float",)
CATEGORY = "mtb/utils"
FUNCTION = "convert"
def convert(self, floats):
return (floats,)
class MTB_AutoPanEquilateral:
"""Generate a 360 panning video from an equilateral image."""
@classmethod
def INPUT_TYPES(cls):
return {
"required": {
"equilateral_image": ("IMAGE",),
"fovX": ("FLOAT", {"default": 45.0}),
"fovY": ("FLOAT", {"default": 45.0}),
"elevation": ("FLOAT", {"default": 0.5}),
"frame_count": ("INT", {"default": 100}),
"width": ("INT", {"default": 768}),
"height": ("INT", {"default": 512}),
},
"optional": {
"floats_fovX": ("FLOATS",),
"floats_fovY": ("FLOATS",),
"floats_elevation": ("FLOATS",),
},
}
RETURN_TYPES = ("IMAGE",)
RETURN_NAMES = ("image",)
CATEGORY = "mtb/utils"
FUNCTION = "generate_frames"
def check_floats(self, f: list[float] | None, expected_count: int):
if f:
if len(f) == expected_count:
return True
return False
return True
def generate_frames(
self,
equilateral_image: torch.Tensor,
fovX: float,
fovY: float,
elevation: float,
frame_count: int,
width: int,
height: int,
floats_fovX: list[float] | None = None,
floats_fovY: list[float] | None = None,
floats_elevation: list[float] | None = None,
):
source = tensor2np(equilateral_image)
if len(source) > 1:
log.warn(
"You provided more than one image in the equilateral_image input, only the first will be used."
)
if not all(
[
self.check_floats(x, frame_count)
for x in [floats_fovX, floats_fovY, floats_elevation]
]
):
raise ValueError(
"You provided less than the expected number of fovX, fovY, or elevation values."
)
source = source[0]
frames = []
pbar = comfy.utils.ProgressBar(frame_count)
for i in range(frame_count):
rotation_angle = (i / frame_count) * 2 * pi
if floats_elevation:
elevation = floats_elevation[i]
if floats_fovX:
fovX = floats_fovX[i]
if floats_fovY:
fovY = floats_fovY[i]
fov = [fovX / 100, fovY / 100]
center_point = [rotation_angle / (2 * pi), elevation]
nfov = numpy_NFOV(fov, height, width)
frame = nfov.to_nfov(source, center_point=center_point)
frames.append(frame)
model_management.throw_exception_if_processing_interrupted()
pbar.update(1)
return (pil2tensor(frames),)
class MTB_GetBatchFromHistory:
"""Very experimental node to load images from the history of the server.
Queue items without output are ignored in the count.
"""
@classmethod
def INPUT_TYPES(cls):
return {
"required": {
"enable": ("BOOLEAN", {"default": True}),
"count": ("INT", {"default": 1, "min": 0}),
"offset": ("INT", {"default": 0, "min": -1e9, "max": 1e9}),
"internal_count": ("INT", {"default": 0}),
},
"optional": {
"passthrough_image": ("IMAGE",),
},
}
RETURN_TYPES = ("IMAGE",)
RETURN_NAMES = ("images",)
CATEGORY = "mtb/animation"
FUNCTION = "load_from_history"
def load_from_history(
self,
*,
enable=True,
count=0,
offset=0,
internal_count=0, # hacky way to invalidate the node
passthrough_image=None,
):
if not enable or count == 0:
if passthrough_image is not None:
log.debug("Using passthrough image")
return (passthrough_image,)
log.debug("Load from history is disabled for this iteration")
return (torch.zeros(0),)
frames = []
base_url, port = get_server_info()
history_url = f"http://{base_url}:{port}/history"
log.debug(f"Fetching history from {history_url}")
output = torch.zeros(0)
with urllib.request.urlopen(history_url) as response:
output = self.load_batch_frames(response, offset, count, frames)
if output.size(0) == 0:
log.warn("No output found in history")
return (output,)
def load_batch_frames(self, response, offset, count, frames):
history = json.loads(response.read())
output_images = []
for run in history.values():
for node_output in run["outputs"].values():
if "images" in node_output:
for image in node_output["images"]:
image_data = get_image(
image["filename"],
image["subfolder"],
image["type"],
)
output_images.append(image_data)
if not output_images:
return torch.zeros(0)
# Directly get desired range of images
start_index = max(len(output_images) - offset - count, 0)
end_index = len(output_images) - offset
selected_images = output_images[start_index:end_index]
frames = [Image.open(image) for image in selected_images]
if not frames:
return torch.zeros(0)
elif len(frames) != count:
log.warning(f"Expected {count} images, got {len(frames)} instead")
return pil2tensor(frames)
class MTB_AnyToString:
"""Tries to take any input and convert it to a string."""
@classmethod
def INPUT_TYPES(cls):
return {
"required": {"input": ("*",)},
}
RETURN_TYPES = ("STRING",)
FUNCTION = "do_str"
CATEGORY = "mtb/converters"
def do_str(self, input):
if isinstance(input, str):
return (input,)
elif isinstance(input, torch.Tensor):
return (f"Tensor of shape {input.shape} and dtype {input.dtype}",)
elif isinstance(input, Image.Image):
return (f"PIL Image of size {input.size} and mode {input.mode}",)
elif isinstance(input, np.ndarray):
return (
f"Numpy array of shape {input.shape} and dtype {input.dtype}",
)
elif isinstance(input, dict):
return (
f"Dictionary of {len(input)} items, with keys {input.keys()}",
)
else:
log.debug(f"Falling back to string conversion of {input}")
return (str(input),)
class MTB_StringReplace:
"""Basic string replacement."""
@classmethod
def INPUT_TYPES(cls):
return {
"required": {
"string": ("STRING", {"forceInput": True}),
"old": ("STRING", {"default": ""}),
"new": ("STRING", {"default": ""}),
}
}
FUNCTION = "replace_str"
RETURN_TYPES = ("STRING",)
CATEGORY = "mtb/string"
def replace_str(self, string: str, old: str, new: str):
log.debug(f"Current string: {string}")
log.debug(f"Find string: {old}")
log.debug(f"Replace string: {new}")
string = string.replace(old, new)
log.debug(f"New string: {string}")
return (string,)
class MTB_MathExpression:
"""Node to evaluate a simple math expression string"""
@classmethod
def INPUT_TYPES(cls):
return {
"required": {
"expression": ("STRING", {"default": "", "multiline": True}),
}
}
FUNCTION = "eval_expression"
RETURN_TYPES = ("FLOAT", "INT")
RETURN_NAMES = ("result (float)", "result (int)")
CATEGORY = "mtb/math"
DESCRIPTION = (
"evaluate a simple math expression string, only supports literal_eval"
)
def eval_expression(self, expression: str, **kwargs):
from ast import literal_eval
for key, value in kwargs.items():
log.debug(f"Replacing placeholder <{key}> with value {value}")
expression = expression.replace(f"<{key}>", str(value))
result = -1
try:
result = literal_eval(expression)
except SyntaxError as e:
raise ValueError(
f"The expression syntax is wrong '{expression}': {e}"
) from e
except Exception as e:
raise ValueError(
f"Math expression only support literal_eval now: {e}"
)
return (result, int(result))
class MTB_FitNumber:
"""Fit the input float using a source and target range"""
@classmethod
def INPUT_TYPES(cls):
return {
"required": {
"value": ("FLOAT", {"default": 0, "forceInput": True}),
"clamp": ("BOOLEAN", {"default": False}),
"source_min": (
"FLOAT",
{"default": 0.0, "step": 0.01, "min": -1e5},
),
"source_max": (
"FLOAT",
{"default": 1.0, "step": 0.01, "min": -1e5},
),
"target_min": (
"FLOAT",
{"default": 0.0, "step": 0.01, "min": -1e5},
),
"target_max": (
"FLOAT",
{"default": 1.0, "step": 0.01, "min": -1e5},
),
"easing": (
EASINGS,
{"default": "Linear"},
),
}
}
FUNCTION = "set_range"
RETURN_TYPES = ("FLOAT",)
CATEGORY = "mtb/math"
DESCRIPTION = "Fit the input float using a source and target range"
def set_range(
self,
value: float,
clamp: bool,
source_min: float,
source_max: float,
target_min: float,
target_max: float,
easing: str,
):
if source_min == source_max:
normalized_value = 0
else:
normalized_value = (value - source_min) / (source_max - source_min)
if clamp:
normalized_value = max(min(normalized_value, 1), 0)
eased_value = apply_easing(normalized_value, easing)
# - Convert the eased value to the target range
res = target_min + (target_max - target_min) * eased_value
return (res,)
class MTB_ConcatImages:
"""Add images to batch."""
RETURN_TYPES = ("IMAGE",)
FUNCTION = "concatenate_tensors"
CATEGORY = "mtb/image"
@classmethod
def INPUT_TYPES(cls):
return {
"required": {"reverse": ("BOOLEAN", {"default": False})},
"optional": {
"on_mismatch": (
["Error", "Smallest", "Largest"],
{"default": "Smallest"},
)
},
}
def concatenate_tensors(
self,
reverse: bool,
on_mismatch: str = "Smallest",
**kwargs: torch.Tensor,
) -> tuple[torch.Tensor]:
tensors = list(kwargs.values())
if on_mismatch == "Error":
shapes = [tensor.shape for tensor in tensors]
if not all(shape == shapes[0] for shape in shapes):
raise ValueError(
"All input tensors must have the same shape when on_mismatch is 'Error'."
)
else:
import torch.nn.functional as F
if on_mismatch == "Smallest":
target_shape = min(
(tensor.shape for tensor in tensors),
key=lambda s: (s[1], s[2]),
)
else: # on_mismatch == "Largest"
target_shape = max(
(tensor.shape for tensor in tensors),
key=lambda s: (s[1], s[2]),
)
target_height, target_width = target_shape[1], target_shape[2]
resized_tensors = []
for tensor in tensors:
if (
tensor.shape[1] != target_height
or tensor.shape[2] != target_width
):
resized_tensor = F.interpolate(
tensor.permute(0, 3, 1, 2),
size=(target_height, target_width),
mode="bilinear",
align_corners=False,
)
resized_tensor = resized_tensor.permute(0, 2, 3, 1)
resized_tensors.append(resized_tensor)
else:
resized_tensors.append(tensor)
tensors = resized_tensors
concatenated = torch.cat(tensors, dim=0)
return (concatenated,)
__nodes__ = [
MTB_StringReplace,
MTB_FitNumber,
MTB_GetBatchFromHistory,
MTB_AnyToString,
MTB_ConcatImages,
MTB_MathExpression,
MTB_ToDevice,
MTB_ApplyTextTemplate,
MTB_MatchDimensions,
MTB_AutoPanEquilateral,
MTB_FloatsToFloat,
MTB_FloatToFloats,
MTB_FloatsToInts,
]
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