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import gradio as gr
from matplotlib import gridspec
import matplotlib.pyplot as plt
import numpy as np
from PIL import Image
import tensorflow as tf
from transformers import SegformerFeatureExtractor, TFSegformerForSemanticSegmentation
feature_extractor = SegformerFeatureExtractor.from_pretrained(
"nvidia/segformer-b1-finetuned-cityscapes-1024-1024"
)
model = TFSegformerForSemanticSegmentation.from_pretrained(
"nvidia/segformer-b1-finetuned-cityscapes-1024-1024"
)
def ade_palette():
"""ADE20K palette that maps each class to RGB values."""
return [
[255, 0, 0], # Class 0
[0, 255, 0], # Class 1
[0, 0, 255], # Class 2
[255, 255, 0], # Class 3
[255, 0, 255], # Class 4
[0, 255, 255], # Class 5
[128, 0, 0], # Class 6
[0, 128, 0], # Class 7
[0, 0, 128], # Class 8
[128, 128, 0], # Class 9
[128, 0, 128], # Class 10
[0, 128, 128], # Class 11
[64, 0, 0], # Class 12
[0, 64, 0], # Class 13
[0, 0, 64], # Class 14
[64, 64, 0], # Class 15
[64, 0, 64], # Class 16
[0, 64, 64], # Class 17
[64, 64, 64],
]
labels_list = []
with open(r'labels.txt', 'r') as fp:
for line in fp:
labels_list.append(line[:-1])
colormap = np.asarray(ade_palette())
def label_to_color_image(label):
if label.ndim != 2:
raise ValueError("Expect 2-D input label")
if np.max(label) >= len(colormap):
raise ValueError("label value too large.")
return colormap[label]
def draw_plot(pred_img, seg):
fig = plt.figure(figsize=(20, 15))
grid_spec = gridspec.GridSpec(1, 2, width_ratios=[6, 1])
plt.subplot(grid_spec[0])
plt.imshow(pred_img)
plt.axis('off')
LABEL_NAMES = np.asarray(labels_list)
FULL_LABEL_MAP = np.arange(len(LABEL_NAMES)).reshape(len(LABEL_NAMES), 1)
FULL_COLOR_MAP = label_to_color_image(FULL_LABEL_MAP)
unique_labels = np.unique(seg.numpy().astype("uint8"))
ax = plt.subplot(grid_spec[1])
plt.imshow(FULL_COLOR_MAP[unique_labels].astype(np.uint8), interpolation="nearest")
ax.yaxis.tick_right()
plt.yticks(range(len(unique_labels)), LABEL_NAMES[unique_labels])
plt.xticks([], [])
ax.tick_params(width=0.0, labelsize=25)
return fig
def sepia(input_img):
input_img = Image.fromarray(input_img)
inputs = feature_extractor(images=input_img, return_tensors="tf")
outputs = model(**inputs)
logits = outputs.logits
logits = tf.transpose(logits, [0, 2, 3, 1])
logits = tf.image.resize(
logits, input_img.size[::-1]
) # We reverse the shape of `image` because `image.size` returns width and height.
seg = tf.math.argmax(logits, axis=-1)[0]
color_seg = np.zeros(
(seg.shape[0], seg.shape[1], 3), dtype=np.uint8
) # height, width, 3
for label, color in enumerate(colormap):
color_seg[seg.numpy() == label, :] = color
# Show image + mask
pred_img = np.array(input_img) * 0.5 + color_seg * 0.5
pred_img = pred_img.astype(np.uint8)
fig = draw_plot(pred_img, seg)
return fig
# demo = gr.Interface(fn=sepia,
# inputs=gr.Image(shape=(400, 600)),
# outputs=['plot'],
# examples=["22.jpg", "33.jpg"],
# allow_flagging='never')
demo = gr.Interface(
fn=sepia,
inputs=gr.Image(shape=(400, 600)),
outputs='plot',
examples=["22.jpg", "33.jpg"],
allow_flagging='never',
title="201912064 Park MinGyu",
description="sample image - city road",
theme="huggingface",
live=True,
interpretation="default",
layout="horizontal",
)
demo.launch()
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