latent-space-theories / pages /2_Network_comparison.py
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import streamlit as st
import streamlit.components.v1 as components
import dnnlib
import legacy
import pickle
import pandas as pd
import numpy as np
from pyvis.network import Network
import random
from sklearn.metrics.pairwise import cosine_similarity
from matplotlib.backends.backend_agg import RendererAgg
from backend.disentangle_concepts import *
_lock = RendererAgg.lock
HIGHTLIGHT_COLOR = '#e7bcc5'
st.set_page_config(layout='wide')
st.title('Comparison among color directions')
st.write('> **How do the color directions relate to each other?**')
st.write("""
This page provides a simple network-based framework to inspect the vector similarity (cosine similarity) among the found color vectors.
The nodes are the colors chosen for comparison and the strength of the edge represents the similarity.
""")
annotations_file = './data/textile_annotated_files/seeds0000-100000_S.pkl'
with open(annotations_file, 'rb') as f:
annotations = pickle.load(f)
concept_vectors = pd.read_csv('./data/stored_vectors/scores_colors_hsv.csv')
concept_vectors['vector'] = [np.array([float(xx) for xx in x]) for x in concept_vectors['vector'].str.split(', ')]
concept_vectors['score'] = concept_vectors['score'].astype(float)
concept_vectors['sign'] = [True if 'sign:True' in val else False for val in concept_vectors['kwargs']]
concept_vectors['extremes'] = [True if 'extremes method:True' in val else False for val in concept_vectors['kwargs']]
concept_vectors['regularization'] = [float(val.split(',')[1].strip('regularization: ')) if 'regularization:' in val else False for val in concept_vectors['kwargs']]
concept_vectors['cl_method'] = [val.split(',')[0].strip('classification method:') if 'classification method:' in val else False for val in concept_vectors['kwargs']]
concept_vectors['num_factors'] = [int(val.split(',')[1].strip('number of factors:')) if 'number of factors:' in val else False for val in concept_vectors['kwargs']]
concept_vectors = concept_vectors.sort_values('score', ascending=False).reset_index()
with dnnlib.util.open_url('./data/textile_model_files/network-snapshot-005000.pkl') as f:
model = legacy.load_network_pkl(f)['G_ema'].to('cpu') # type: ignore
COLORS_LIST = ['Gray', 'Red Orange', 'Yellow', 'Green', 'Light Blue', 'Blue', 'Purple', 'Pink', 'Saturation', 'Value']
if 'concept_ids' not in st.session_state:
st.session_state.concept_ids = COLORS_LIST
if 'sign' not in st.session_state:
st.session_state.sign = False
if 'extremes' not in st.session_state:
st.session_state.extremes = False
if 'regularization' not in st.session_state:
st.session_state.regularization = False
if 'cl_method' not in st.session_state:
st.session_state.cl_method = False
if 'num_factors' not in st.session_state:
st.session_state.num_factors = False
if 'best' not in st.session_state:
st.session_state.best = True
# ----------------------------- INPUT ----------------------------------
st.header('Input')
input_col_1, input_col_2 = st.columns([1,1])
# --------------------------- INPUT column 1 ---------------------------
with input_col_1:
with st.form('text_form'):
# image_id = st.number_input('Image ID: ', format='%d', step=1)
st.write('**Choose a series of colors to compare**')
# chosen_text_id_input = st.empty()
# concept_id = chosen_text_id_input.text_input('Concept:', value=st.session_state.concept_id)
concept_ids = st.multiselect('Color (including Saturation and Value):', tuple(COLORS_LIST), default=COLORS_LIST)
choose_text_button = st.form_submit_button('Choose the defined colors')
if choose_text_button:
st.session_state.concept_ids = list(concept_ids)
with input_col_2:
with st.form('text_form_1'):
st.write('Use the best vectors (after hyperparameter tuning)')
best = st.selectbox('Option:', tuple([True, False]), index=0)
sign = True
num_factors=10
cl_method='LR'
regularization=0.1
extremes=True
if st.session_state.best is False:
st.write('Options for StyleSpace (not available for Saturation and Value)')
sign = st.selectbox('Sign option:', tuple([True, False]), index=1)
num_factors = st.selectbox('Number of factors option:', tuple([1, 5, 10, 20, False]), index=4)
st.write('Options for InterFaceGAN (not available for Saturation and Value)')
cl_method = st.selectbox('Classification method option:', tuple(['LR', 'SVM', False]), index=2)
regularization = st.selectbox('Regularization option:', tuple([0.1, 1.0, False]), index=2)
st.write('Options for InterFaceGAN (only for Saturation and Value)')
extremes = st.selectbox('Extremes option:', tuple([True, False]), index=1)
choose_options_button = st.form_submit_button('Choose the defined options')
if choose_options_button:
st.session_state.best = best
if st.session_state.best is False:
st.session_state.sign = sign
st.session_state.num_factors = num_factors
st.session_state.cl_method = cl_method
st.session_state.regularization = regularization
st.session_state.extremes = extremes
# ---------------------------- SET UP OUTPUT ------------------------------
epsilon_container = st.empty()
st.header('Comparison')
st.subheader('Color vectors')
header_col_1, header_col_2 = st.columns([3,1])
output_col_1, output_col_2 = st.columns([3,1])
# ---------------------------- DISPLAY COL 1 ROW 1 ------------------------------
if st.session_state.best:
tmp = concept_vectors[concept_vectors['color'].isin(st.session_state.concept_ids)].groupby('color').first().reset_index()
else:
tmp = concept_vectors[concept_vectors['color'].isin(st.session_state.concept_ids)]
tmp = tmp[tmp['sign'] == st.session_state.sign][tmp['extremes'] == st.session_state.extremes][tmp['num_factors'] == st.session_state.num_factors][tmp['cl_method'] == st.session_state.cl_method][tmp['regularization'] == st.session_state.regularization]
info = tmp.loc[:, ['vector', 'score', 'color', 'kwargs']].values
concept_ids = [i[2] for i in info] #+ ' ' + i[3]
with header_col_1:
st.write('### Similarity graph')
with header_col_2:
st.write('### Information')
with output_col_2:
for i,concept_id in enumerate(concept_ids):
st.write(f'''Color: {info[i][2]}.\
Settings: {info[i][3]}\
''')
with output_col_1:
edges = []
for i in range(len(concept_ids)):
for j in range(len(concept_ids)):
if i != j and info[i][2] != info[j][2]:
print(f'Similarity between {concept_ids[i]} and {concept_ids[j]}')
similarity = cosine_similarity(info[i][0].reshape(1, -1), info[j][0].reshape(1, -1))
print(np.round(similarity[0][0], 3))
edges.append((concept_ids[i], concept_ids[j], np.round(similarity[0][0] + 0.001, 3)))
net = Network(height="750px", width="100%",)
for e in edges:
src = e[0]
dst = e[1]
w = e[2]
net.add_node(src, src, title=src)
net.add_node(dst, dst, title=dst)
net.add_edge(src, dst, value=w, title=src + ' to ' + dst + ' similarity ' +str(w))
# Generate network with specific layout settings
net.repulsion(
node_distance=420,
central_gravity=0.33,
spring_length=110,
spring_strength=0.10,
damping=0.95
)
# Save and read graph as HTML file (on Streamlit Sharing)
try:
path = '/tmp'
net.save_graph(f'{path}/pyvis_graph.html')
HtmlFile = open(f'{path}/pyvis_graph.html', 'r', encoding='utf-8')
# Save and read graph as HTML file (locally)
except:
path = '/html_files'
net.save_graph(f'{path}/pyvis_graph.html')
HtmlFile = open(f'{path}/pyvis_graph.html', 'r', encoding='utf-8')
# Load HTML file in HTML component for display on Streamlit page
components.html(HtmlFile.read(), height=435)