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| import streamlit as st | |
| import pandas as pd | |
| import numpy as np | |
| from bokeh.plotting import figure | |
| from bokeh.models import ColumnDataSource, DataTable, TableColumn, CustomJS, Select, Button, HoverTool, LinearColorMapper, ColorBar, FuncTickFormatter, FixedTicker | |
| from bokeh.layouts import column | |
| from bokeh.palettes import Reds9, Blues9, Oranges9, Purples9, Greys9, BuGn9, Greens9, RdYlGn11, linear_palette | |
| from sklearn.decomposition import PCA | |
| from sklearn.manifold import TSNE, trustworthiness | |
| from sklearn.metrics import pairwise_distances | |
| from sklearn.preprocessing import MinMaxScaler | |
| from sklearn.pipeline import Pipeline | |
| from sklearn.base import BaseEstimator, TransformerMixin | |
| import io | |
| import ot | |
| from sklearn.linear_model import LinearRegression | |
| from scipy.stats import binned_statistic_2d | |
| import json | |
| import itertools | |
| import matplotlib.pyplot as plt | |
| import matplotlib.colors as mcolors | |
| import zipfile | |
| import tempfile | |
| class RelativeScaler(BaseEstimator, TransformerMixin): | |
| """ | |
| Escala la primera columna al rango [-1, 1] y ajusta las siguientes columnas | |
| manteniendo la proporción relativa respecto a la primera. | |
| """ | |
| def fit(self, X, y=None): | |
| X = np.asarray(X) | |
| self.pc1_min_ = X[:, 0].min() | |
| self.pc1_max_ = X[:, 0].max() | |
| self.scaling_factor_ = (self.pc1_max_ - self.pc1_min_) / 2 | |
| return self | |
| def transform(self, X): | |
| X = np.asarray(X) | |
| pc1 = X[:, 0] | |
| pc1_scaled = 2 * (pc1 - self.pc1_min_) / (self.pc1_max_ - self.pc1_min_) - 1 | |
| transformed = [pc1_scaled.reshape(-1, 1)] | |
| for i in range(1, X.shape[1]): | |
| scaled_i = X[:, i] / self.scaling_factor_ | |
| transformed.append(scaled_i.reshape(-1, 1)) | |
| return np.hstack(transformed) | |
| N_COMPONENTS = 3 | |
| TSNE_NEIGHBOURS = 150 | |
| # WEIGHT_FACTOR = 0.05 | |
| TOOLTIPS = """ | |
| <div> | |
| <div> | |
| <img src="@img{safe}" style="width:128px; height:auto; float: left; margin: 0px 15px 15px 0px;" alt="@img" border="2"></img> | |
| </div> | |
| <div> | |
| <span style="font-size: 17px; font-weight: bold;">@label</span> | |
| </div> | |
| <div> | |
| <span style="font-size: 14px;">X: @x, Y: @y</span> | |
| </div> | |
| </div> | |
| """ | |
| def config_style(): | |
| # st.set_page_config(layout="wide") | |
| st.markdown(""" | |
| <style> | |
| .main-title { font-size: 50px; color: #4CAF50; text-align: center; } | |
| .sub-title { font-size: 30px; color: #555; } | |
| .custom-text { font-size: 18px; line-height: 1.5; } | |
| .bk-legend { | |
| max-height: 200px; | |
| overflow-y: auto; | |
| } | |
| </style> | |
| """, unsafe_allow_html=True) | |
| st.markdown('<h1 class="main-title">Merit Embeddings 🎒📃🏆</h1>', unsafe_allow_html=True) | |
| def load_embeddings(model, version, embedding_prefix, weight_factor): | |
| if model == "Donut": | |
| df_real = pd.read_csv(f"data/donut/{version}/{embedding_prefix}/de_Rodrigo_merit_secret_all_{weight_factor}embeddings.csv") | |
| df_par = pd.read_csv(f"data/donut/{version}/{embedding_prefix}/de_Rodrigo_merit_es-digital-paragraph-degradation-seq_{weight_factor}embeddings.csv") | |
| df_line = pd.read_csv(f"data/donut/{version}/{embedding_prefix}/de_Rodrigo_merit_es-digital-line-degradation-seq_{weight_factor}embeddings.csv") | |
| df_seq = pd.read_csv(f"data/donut/{version}/{embedding_prefix}/de_Rodrigo_merit_es-digital-seq_{weight_factor}embeddings.csv") | |
| df_rot = pd.read_csv(f"data/donut/{version}/{embedding_prefix}/de_Rodrigo_merit_es-digital-rotation-degradation-seq_{weight_factor}embeddings.csv") | |
| df_zoom = pd.read_csv(f"data/donut/{version}/{embedding_prefix}/de_Rodrigo_merit_es-digital-zoom-degradation-seq_{weight_factor}embeddings.csv") | |
| df_render = pd.read_csv(f"data/donut/{version}/{embedding_prefix}/de_Rodrigo_merit_es-render-seq_{weight_factor}embeddings.csv") | |
| df_pretratrained = pd.read_csv(f"data/donut/{version}/{embedding_prefix}/de_Rodrigo_merit_aux_IIT-CDIP_{weight_factor}embeddings.csv") | |
| # Asignar etiquetas de versión | |
| df_real["version"] = "real" | |
| df_par["version"] = "synthetic" | |
| df_line["version"] = "synthetic" | |
| df_seq["version"] = "synthetic" | |
| df_rot["version"] = "synthetic" | |
| df_zoom["version"] = "synthetic" | |
| df_render["version"] = "synthetic" | |
| df_pretratrained["version"] = "pretrained" | |
| # Asignar fuente (source) | |
| df_par["source"] = "es-digital-paragraph-degradation-seq" | |
| df_line["source"] = "es-digital-line-degradation-seq" | |
| df_seq["source"] = "es-digital-seq" | |
| df_rot["source"] = "es-digital-rotation-degradation-seq" | |
| df_zoom["source"] = "es-digital-zoom-degradation-seq" | |
| df_render["source"] = "es-render-seq" | |
| df_pretratrained["source"] = "pretrained" | |
| return {"real": df_real, | |
| "synthetic": pd.concat([df_seq, df_line, df_par, df_rot, df_zoom, df_render], ignore_index=True), | |
| "pretrained": df_pretratrained} | |
| elif model == "Idefics2": | |
| df_real = pd.read_csv(f"data/idefics2/{version}/{embedding_prefix}/de_Rodrigo_merit_secret_britanico_{weight_factor}embeddings.csv") | |
| df_par = pd.read_csv(f"data/idefics2/{version}/{embedding_prefix}/de_Rodrigo_merit_es-digital-paragraph-degradation-seq_{weight_factor}embeddings.csv") | |
| df_line = pd.read_csv(f"data/idefics2/{version}/{embedding_prefix}/de_Rodrigo_merit_es-digital-line-degradation-seq_{weight_factor}embeddings.csv") | |
| df_seq = pd.read_csv(f"data/idefics2/{version}/{embedding_prefix}/de_Rodrigo_merit_es-digital-seq_{weight_factor}embeddings.csv") | |
| df_rot = pd.read_csv(f"data/idefics2/{version}/{embedding_prefix}/de_Rodrigo_merit_es-digital-rotation-degradation-seq_{weight_factor}embeddings.csv") | |
| df_zoom = pd.read_csv(f"data/idefics2/{version}/{embedding_prefix}/de_Rodrigo_merit_es-digital-zoom-degradation-seq_{weight_factor}embeddings.csv") | |
| df_render = pd.read_csv(f"data/idefics2/{version}/{embedding_prefix}/de_Rodrigo_merit_es-render-seq_{weight_factor}embeddings.csv") | |
| # Cargar ambos subconjuntos pretrained y combinarlos | |
| df_pretratrained_PDFA = pd.read_csv(f"data/idefics2/{version}/{embedding_prefix}/de_Rodrigo_merit_aux_PDFA_{weight_factor}embeddings.csv") | |
| df_pretratrained_IDL = pd.read_csv(f"data/idefics2/{version}/{embedding_prefix}/de_Rodrigo_merit_aux_IDL_{weight_factor}embeddings.csv") | |
| df_pretratrained = pd.concat([df_pretratrained_PDFA, df_pretratrained_IDL], ignore_index=True) | |
| # Asignar etiquetas de versión | |
| df_real["version"] = "real" | |
| df_par["version"] = "synthetic" | |
| df_line["version"] = "synthetic" | |
| df_seq["version"] = "synthetic" | |
| df_rot["version"] = "synthetic" | |
| df_zoom["version"] = "synthetic" | |
| df_render["version"] = "synthetic" | |
| df_pretratrained["version"] = "pretrained" | |
| # Asignar fuente (source) | |
| df_par["source"] = "es-digital-paragraph-degradation-seq" | |
| df_line["source"] = "es-digital-line-degradation-seq" | |
| df_seq["source"] = "es-digital-seq" | |
| df_rot["source"] = "es-digital-rotation-degradation-seq" | |
| df_zoom["source"] = "es-digital-zoom-degradation-seq" | |
| df_render["source"] = "es-render-seq" | |
| df_pretratrained["source"] = "pretrained" | |
| return {"real": df_real, | |
| "synthetic": pd.concat([df_seq, df_line, df_par, df_rot, df_zoom, df_render], ignore_index=True), | |
| "pretrained": df_pretratrained} | |
| elif model == "Idefics2-patient": | |
| df_real = pd.read_csv(f"data/idefics2/{version}/{embedding_prefix}/de_Rodrigo_merit_secret_britanico_{weight_factor}embeddings.csv") | |
| df_par = pd.read_csv(f"data/idefics2/{version}/{embedding_prefix}/de_Rodrigo_merit_es-digital-paragraph-degradation-seq_{weight_factor}embeddings.csv") | |
| df_line = pd.read_csv(f"data/idefics2/{version}/{embedding_prefix}/de_Rodrigo_merit_es-digital-line-degradation-seq_{weight_factor}embeddings.csv") | |
| df_seq = pd.read_csv(f"data/idefics2/{version}/{embedding_prefix}/de_Rodrigo_merit_es-digital-seq_{weight_factor}embeddings.csv") | |
| df_rot = pd.read_csv(f"data/idefics2/{version}/{embedding_prefix}/de_Rodrigo_merit_es-digital-rotation-degradation-seq_{weight_factor}embeddings.csv") | |
| df_zoom = pd.read_csv(f"data/idefics2/{version}/{embedding_prefix}/de_Rodrigo_merit_es-digital-zoom-degradation-seq_{weight_factor}embeddings.csv") | |
| df_render = pd.read_csv(f"data/idefics2/{version}/{embedding_prefix}/de_Rodrigo_merit_es-render-seq_{weight_factor}embeddings.csv") | |
| # Cargar ambos subconjuntos pretrained y combinarlos | |
| df_pretratrained_PDFA = pd.read_csv(f"data/idefics2/{version}/{embedding_prefix}/de_Rodrigo_merit_aux_PDFA_{weight_factor}embeddings.csv") | |
| df_pretratrained_IDL = pd.read_csv(f"data/idefics2/{version}/{embedding_prefix}/de_Rodrigo_merit_aux_IDL_{weight_factor}embeddings.csv") | |
| df_pretratrained = pd.concat([df_pretratrained_PDFA, df_pretratrained_IDL], ignore_index=True) | |
| # Asignar etiquetas de versión | |
| df_real["version"] = "real" | |
| df_par["version"] = "synthetic" | |
| df_line["version"] = "synthetic" | |
| df_seq["version"] = "synthetic" | |
| df_rot["version"] = "synthetic" | |
| df_zoom["version"] = "synthetic" | |
| df_render["version"] = "synthetic" | |
| df_pretratrained["version"] = "pretrained" | |
| # Asignar fuente (source) | |
| df_par["source"] = "es-digital-paragraph-degradation-seq" | |
| df_line["source"] = "es-digital-line-degradation-seq" | |
| df_seq["source"] = "es-digital-seq" | |
| df_rot["source"] = "es-digital-rotation-degradation-seq" | |
| df_zoom["source"] = "es-digital-zoom-degradation-seq" | |
| df_render["source"] = "es-render-seq" | |
| df_pretratrained["source"] = "pretrained" | |
| return {"real": df_real, | |
| "synthetic": pd.concat([df_seq, df_line, df_par, df_rot, df_zoom, df_render], ignore_index=True), | |
| "pretrained": df_pretratrained} | |
| elif model == "Paligemma": | |
| df_real = pd.read_csv(f"data/paligemma/{version}/{embedding_prefix}/de_Rodrigo_merit_secret_all_{weight_factor}embeddings.csv") | |
| df_par = pd.read_csv(f"data/paligemma/{version}/{embedding_prefix}/de_Rodrigo_merit_es-digital-paragraph-degradation-seq_{weight_factor}embeddings.csv") | |
| df_line = pd.read_csv(f"data/paligemma/{version}/{embedding_prefix}/de_Rodrigo_merit_es-digital-line-degradation-seq_{weight_factor}embeddings.csv") | |
| df_seq = pd.read_csv(f"data/paligemma/{version}/{embedding_prefix}/de_Rodrigo_merit_es-digital-seq_{weight_factor}embeddings.csv") | |
| df_rot = pd.read_csv(f"data/paligemma/{version}/{embedding_prefix}/de_Rodrigo_merit_es-digital-rotation-degradation-seq_{weight_factor}embeddings.csv") | |
| df_zoom = pd.read_csv(f"data/paligemma/{version}/{embedding_prefix}/de_Rodrigo_merit_es-digital-zoom-degradation-seq_{weight_factor}embeddings.csv") | |
| df_render = pd.read_csv(f"data/paligemma/{version}/{embedding_prefix}/de_Rodrigo_merit_es-render-seq_{weight_factor}embeddings.csv") | |
| # Cargar ambos subconjuntos pretrained y combinarlos | |
| # TODO Pretrained de idefics2, se mantienen para evitar error, pero se debe meter los de paligemma | |
| df_pretratrained_PDFA = pd.read_csv(f"data/idefics2/{version}/{embedding_prefix}/de_Rodrigo_merit_aux_PDFA_{weight_factor}embeddings.csv") | |
| df_pretratrained_IDL = pd.read_csv(f"data/idefics2/{version}/{embedding_prefix}/de_Rodrigo_merit_aux_IDL_{weight_factor}embeddings.csv") | |
| df_pretratrained = pd.concat([df_pretratrained_PDFA, df_pretratrained_IDL], ignore_index=True) | |
| # Asignar etiquetas de versión | |
| df_real["version"] = "real" | |
| df_par["version"] = "synthetic" | |
| df_line["version"] = "synthetic" | |
| df_seq["version"] = "synthetic" | |
| df_rot["version"] = "synthetic" | |
| df_zoom["version"] = "synthetic" | |
| df_render["version"] = "synthetic" | |
| df_pretratrained["version"] = "pretrained" | |
| # Asignar fuente (source) | |
| df_par["source"] = "es-digital-paragraph-degradation-seq" | |
| df_line["source"] = "es-digital-line-degradation-seq" | |
| df_seq["source"] = "es-digital-seq" | |
| df_rot["source"] = "es-digital-rotation-degradation-seq" | |
| df_zoom["source"] = "es-digital-zoom-degradation-seq" | |
| df_render["source"] = "es-render-seq" | |
| df_pretratrained["source"] = "pretrained" | |
| return {"real": df_real, | |
| "synthetic": pd.concat([df_seq, df_line, df_par, df_rot, df_zoom, df_render], ignore_index=True), | |
| "pretrained": df_pretratrained} | |
| elif model == "Llava": | |
| df_real = pd.read_csv(f"data/llava/{version}/{embedding_prefix}/de_Rodrigo_merit_secret_all_{weight_factor}embeddings.csv") | |
| #TODO Embeddings de Paligemma se mantienen para evitar error | |
| df_par = pd.read_csv(f"data/paligemma/{version}/{embedding_prefix}/de_Rodrigo_merit_es-digital-paragraph-degradation-seq_{weight_factor}embeddings.csv") | |
| df_line = pd.read_csv(f"data/paligemma/{version}/{embedding_prefix}/de_Rodrigo_merit_es-digital-line-degradation-seq_{weight_factor}embeddings.csv") | |
| df_seq = pd.read_csv(f"data/paligemma/{version}/{embedding_prefix}/de_Rodrigo_merit_es-digital-seq_{weight_factor}embeddings.csv") | |
| df_rot = pd.read_csv(f"data/paligemma/{version}/{embedding_prefix}/de_Rodrigo_merit_es-digital-rotation-degradation-seq_{weight_factor}embeddings.csv") | |
| df_zoom = pd.read_csv(f"data/paligemma/{version}/{embedding_prefix}/de_Rodrigo_merit_es-digital-zoom-degradation-seq_{weight_factor}embeddings.csv") | |
| df_render = pd.read_csv(f"data/paligemma/{version}/{embedding_prefix}/de_Rodrigo_merit_es-render-seq_{weight_factor}embeddings.csv") | |
| # Cargar ambos subconjuntos pretrained y combinarlos | |
| # TODO Pretrained de idefics2, se mantienen para evitar error, pero se debe meter los de paligemma | |
| df_pretratrained_PDFA = pd.read_csv(f"data/idefics2/{version}/{embedding_prefix}/de_Rodrigo_merit_aux_PDFA_{weight_factor}embeddings.csv") | |
| df_pretratrained_IDL = pd.read_csv(f"data/idefics2/{version}/{embedding_prefix}/de_Rodrigo_merit_aux_IDL_{weight_factor}embeddings.csv") | |
| df_pretratrained = pd.concat([df_pretratrained_PDFA, df_pretratrained_IDL], ignore_index=True) | |
| # Asignar etiquetas de versión | |
| df_real["version"] = "real" | |
| df_par["version"] = "synthetic" | |
| df_line["version"] = "synthetic" | |
| df_seq["version"] = "synthetic" | |
| df_rot["version"] = "synthetic" | |
| df_zoom["version"] = "synthetic" | |
| df_render["version"] = "synthetic" | |
| df_pretratrained["version"] = "pretrained" | |
| # Asignar fuente (source) | |
| df_par["source"] = "es-digital-paragraph-degradation-seq" | |
| df_line["source"] = "es-digital-line-degradation-seq" | |
| df_seq["source"] = "es-digital-seq" | |
| df_rot["source"] = "es-digital-rotation-degradation-seq" | |
| df_zoom["source"] = "es-digital-zoom-degradation-seq" | |
| df_render["source"] = "es-render-seq" | |
| df_pretratrained["source"] = "pretrained" | |
| return {"real": df_real, | |
| "synthetic": pd.concat([df_seq, df_line, df_par, df_rot, df_zoom, df_render], ignore_index=True), | |
| "pretrained": df_pretratrained} | |
| else: | |
| st.error("Modelo no reconocido") | |
| return None | |
| def split_versions(df_combined, reduced): | |
| # Asignar las coordenadas si la reducción es 2D | |
| if reduced.shape[1] == 2: | |
| df_combined['x'] = reduced[:, 0] | |
| df_combined['y'] = reduced[:, 1] | |
| df_real = df_combined[df_combined["version"] == "real"].copy() | |
| df_synth = df_combined[df_combined["version"] == "synthetic"].copy() | |
| df_pretrained = df_combined[df_combined["version"] == "pretrained"].copy() | |
| unique_real = sorted(df_real['label'].unique().tolist()) | |
| unique_synth = {} | |
| for source in df_synth["source"].unique(): | |
| unique_synth[source] = sorted(df_synth[df_synth["source"] == source]['label'].unique().tolist()) | |
| unique_pretrained = sorted(df_pretrained['label'].unique().tolist()) | |
| df_dict = {"real": df_real, "synthetic": df_synth, "pretrained": df_pretrained} | |
| unique_subsets = {"real": unique_real, "synthetic": unique_synth, "pretrained": unique_pretrained} | |
| return df_dict, unique_subsets | |
| def get_embedding_from_df(df): | |
| # Retorna el embedding completo (4 dimensiones en este caso) guardado en la columna 'embedding' | |
| if 'embedding' in df.columns: | |
| return np.stack(df['embedding'].to_numpy()) | |
| elif 'x' in df.columns and 'y' in df.columns: | |
| return df[['x', 'y']].values | |
| else: | |
| raise ValueError("No se encontró embedding o coordenadas x,y en el DataFrame.") | |
| def compute_cluster_distance(synthetic_points, real_points, metric="wasserstein", bins=20): | |
| if metric.lower() == "wasserstein": | |
| n = synthetic_points.shape[0] | |
| m = real_points.shape[0] | |
| weights = np.ones(n) / n | |
| weights_real = np.ones(m) / m | |
| M = ot.dist(synthetic_points, real_points, metric='euclidean') | |
| return ot.emd2(weights, weights_real, M) | |
| elif metric.lower() == "euclidean": | |
| center_syn = np.mean(synthetic_points, axis=0) | |
| center_real = np.mean(real_points, axis=0) | |
| return np.linalg.norm(center_syn - center_real) | |
| elif metric.lower() == "kl": | |
| # Para KL usamos histogramas multidimensionales con límites globales en cada dimensión | |
| all_points = np.vstack([synthetic_points, real_points]) | |
| edges = [ | |
| np.linspace(np.min(all_points[:, i]), np.max(all_points[:, i]), bins+1) | |
| for i in range(all_points.shape[1]) | |
| ] | |
| H_syn, _ = np.histogramdd(synthetic_points, bins=edges) | |
| H_real, _ = np.histogramdd(real_points, bins=edges) | |
| eps = 1e-10 | |
| P = H_syn + eps | |
| Q = H_real + eps | |
| P = P / P.sum() | |
| Q = Q / Q.sum() | |
| kl = np.sum(P * np.log(P / Q)) | |
| return kl | |
| else: | |
| raise ValueError("Métrica desconocida. Usa 'wasserstein', 'euclidean' o 'kl'.") | |
| def compute_cluster_distances_synthetic_individual(synthetic_df: pd.DataFrame, df_real: pd.DataFrame, real_labels: list, metric="wasserstein", bins=20) -> pd.DataFrame: | |
| distances = {} | |
| groups = synthetic_df.groupby(['source', 'label']) | |
| for (source, label), group in groups: | |
| key = f"{label} ({source})" | |
| data = get_embedding_from_df(group) | |
| distances[key] = {} | |
| for real_label in real_labels: | |
| real_data = get_embedding_from_df(df_real[df_real['label'] == real_label]) | |
| d = compute_cluster_distance(data, real_data, metric=metric, bins=bins) | |
| distances[key][real_label] = d | |
| for source, group in synthetic_df.groupby('source'): | |
| key = f"Global ({source})" | |
| data = get_embedding_from_df(group) | |
| distances[key] = {} | |
| for real_label in real_labels: | |
| real_data = get_embedding_from_df(df_real[df_real['label'] == real_label]) | |
| d = compute_cluster_distance(data, real_data, metric=metric, bins=bins) | |
| distances[key][real_label] = d | |
| return pd.DataFrame(distances).T | |
| def compute_continuity(X, X_embedded, n_neighbors=5): | |
| n = X.shape[0] | |
| D_high = pairwise_distances(X, metric='euclidean') | |
| D_low = pairwise_distances(X_embedded, metric='euclidean') | |
| indices_high = np.argsort(D_high, axis=1) | |
| indices_low = np.argsort(D_low, axis=1) | |
| k_high = indices_high[:, 1:n_neighbors+1] | |
| k_low = indices_low[:, 1:n_neighbors+1] | |
| total = 0.0 | |
| for i in range(n): | |
| set_high = set(k_high[i]) | |
| set_low = set(k_low[i]) | |
| missing = set_high - set_low | |
| for j in missing: | |
| rank = np.where(indices_low[i] == j)[0][0] | |
| total += (rank - n_neighbors) | |
| norm = 2.0 / (n * n_neighbors * (2*n - 3*n_neighbors - 1)) | |
| continuity_value = 1 - norm * total | |
| return continuity_value | |
| def create_table(df_distances): | |
| df_table = df_distances.copy() | |
| df_table.reset_index(inplace=True) | |
| df_table.rename(columns={'index': 'Synthetic'}, inplace=True) | |
| min_row = {"Synthetic": "Min."} | |
| mean_row = {"Synthetic": "Mean"} | |
| max_row = {"Synthetic": "Max."} | |
| for col in df_table.columns: | |
| if col != "Synthetic": | |
| min_row[col] = df_table[col].min() | |
| mean_row[col] = df_table[col].mean() | |
| max_row[col] = df_table[col].max() | |
| df_table = pd.concat([df_table, pd.DataFrame([min_row, mean_row, max_row])], ignore_index=True) | |
| source_table = ColumnDataSource(df_table) | |
| columns = [TableColumn(field='Synthetic', title='Synthetic')] | |
| for col in df_table.columns: | |
| if col != 'Synthetic': | |
| columns.append(TableColumn(field=col, title=col)) | |
| total_height = 30 + len(df_table)*28 | |
| data_table = DataTable(source=source_table, columns=columns, sizing_mode='stretch_width', height=total_height) | |
| return data_table, df_table, source_table | |
| def create_figure(dfs, unique_subsets, color_maps, model_name): | |
| # Se crea el plot para el embedding reducido (asumiendo que es 2D) | |
| fig = figure(width=600, height=600, tools="wheel_zoom,pan,reset,save", active_scroll="wheel_zoom", tooltips=TOOLTIPS, title="") | |
| fig.match_aspect = True | |
| # Renderizar datos reales | |
| real_renderers = add_dataset_to_fig(fig, dfs["real"], unique_subsets["real"], | |
| marker="circle", color_mapping=color_maps["real"], | |
| group_label="Real") | |
| # Renderizar datos sintéticos (por fuente) | |
| marker_mapping = { | |
| "es-digital-paragraph-degradation-seq": "x", | |
| "es-digital-line-degradation-seq": "cross", | |
| "es-digital-seq": "triangle", | |
| "es-digital-rotation-degradation-seq": "diamond", | |
| "es-digital-zoom-degradation-seq": "asterisk", | |
| "es-render-seq": "inverted_triangle" | |
| } | |
| synthetic_renderers = {} | |
| synth_df = dfs["synthetic"] | |
| for source in unique_subsets["synthetic"]: | |
| df_source = synth_df[synth_df["source"] == source] | |
| marker = marker_mapping.get(source, "square") | |
| renderers = add_synthetic_dataset_to_fig(fig, df_source, unique_subsets["synthetic"][source], | |
| marker=marker, | |
| color_mapping=color_maps["synthetic"][source], | |
| group_label=source) | |
| synthetic_renderers.update(renderers) | |
| # Agregar el subset pretrained (se puede usar un marcador distinto, por ejemplo, "triangle") | |
| pretrained_renderers = add_dataset_to_fig(fig, dfs["pretrained"], unique_subsets["pretrained"], | |
| marker="triangle", color_mapping=color_maps["pretrained"], | |
| group_label="Pretrained") | |
| fig.legend.location = "top_right" | |
| fig.legend.click_policy = "hide" | |
| show_legend = st.checkbox("Show Legend", value=False, key=f"legend_{model_name}") | |
| fig.legend.visible = show_legend | |
| return fig, real_renderers, synthetic_renderers, pretrained_renderers | |
| def add_dataset_to_fig(fig, df, selected_labels, marker, color_mapping, group_label): | |
| renderers = {} | |
| for label in selected_labels: | |
| subset = df[df['label'] == label] | |
| if subset.empty: | |
| continue | |
| source = ColumnDataSource(data=dict( | |
| x=subset['x'], | |
| y=subset['y'], | |
| label=subset['label'], | |
| img=subset.get('img', "") | |
| )) | |
| color = color_mapping[label] | |
| legend_label = f"{label} ({group_label})" | |
| if marker == "circle": | |
| r = fig.circle('x', 'y', size=10, source=source, | |
| fill_color=color, line_color=color, | |
| legend_label=legend_label) | |
| elif marker == "square": | |
| r = fig.square('x', 'y', size=10, source=source, | |
| fill_color=color, line_color=color, | |
| legend_label=legend_label) | |
| elif marker == "triangle": | |
| r = fig.triangle('x', 'y', size=12, source=source, | |
| fill_color=color, line_color=color, | |
| legend_label=legend_label) | |
| renderers[label + f" ({group_label})"] = r | |
| return renderers | |
| def add_synthetic_dataset_to_fig(fig, df, labels, marker, color_mapping, group_label): | |
| renderers = {} | |
| for label in labels: | |
| subset = df[df['label'] == label] | |
| if subset.empty: | |
| continue | |
| source_obj = ColumnDataSource(data=dict( | |
| x=subset['x'], | |
| y=subset['y'], | |
| label=subset['label'], | |
| img=subset.get('img', "") | |
| )) | |
| color = color_mapping[label] | |
| legend_label = group_label | |
| if marker == "square": | |
| r = fig.square('x', 'y', size=10, source=source_obj, | |
| fill_color=color, line_color=color, | |
| legend_label=legend_label) | |
| elif marker == "triangle": | |
| r = fig.triangle('x', 'y', size=12, source=source_obj, | |
| fill_color=color, line_color=color, | |
| legend_label=legend_label) | |
| elif marker == "inverted_triangle": | |
| r = fig.inverted_triangle('x', 'y', size=12, source=source_obj, | |
| fill_color=color, line_color=color, | |
| legend_label=legend_label) | |
| elif marker == "diamond": | |
| r = fig.diamond('x', 'y', size=10, source=source_obj, | |
| fill_color=color, line_color=color, | |
| legend_label=legend_label) | |
| elif marker == "cross": | |
| r = fig.cross('x', 'y', size=12, source=source_obj, | |
| fill_color=color, line_color=color, | |
| legend_label=legend_label) | |
| elif marker == "x": | |
| r = fig.x('x', 'y', size=12, source=source_obj, | |
| fill_color=color, line_color=color, | |
| legend_label=legend_label) | |
| elif marker == "asterisk": | |
| r = fig.asterisk('x', 'y', size=12, source=source_obj, | |
| fill_color=color, line_color=color, | |
| legend_label=legend_label) | |
| else: | |
| r = fig.circle('x', 'y', size=10, source=source_obj, | |
| fill_color=color, line_color=color, | |
| legend_label=legend_label) | |
| renderers[label + f" ({group_label})"] = r | |
| return renderers | |
| def get_color_maps(unique_subsets): | |
| color_map = {} | |
| num_real = len(unique_subsets["real"]) | |
| red_palette = Reds9[:num_real] if num_real <= 9 else (Reds9 * ((num_real // 9) + 1))[:num_real] | |
| color_map["real"] = {label: red_palette[i] for i, label in enumerate(sorted(unique_subsets["real"]))} | |
| color_map["synthetic"] = {} | |
| for source, labels in unique_subsets["synthetic"].items(): | |
| if source == "es-digital-seq": | |
| palette = Blues9[:len(labels)] if len(labels) <= 9 else (Blues9 * ((len(labels)//9)+1))[:len(labels)] | |
| elif source == "es-digital-line-degradation-seq": | |
| palette = Purples9[:len(labels)] if len(labels) <= 9 else (Purples9 * ((len(labels)//9)+1))[:len(labels)] | |
| elif source == "es-digital-paragraph-degradation-seq": | |
| palette = BuGn9[:len(labels)] if len(labels) <= 9 else (BuGn9 * ((len(labels)//9)+1))[:len(labels)] | |
| elif source == "es-digital-rotation-degradation-seq": | |
| palette = Greys9[:len(labels)] if len(labels) <= 9 else (Greys9 * ((len(labels)//9)+1))[:len(labels)] | |
| elif source == "es-digital-zoom-degradation-seq": | |
| palette = Oranges9[:len(labels)] if len(labels) <= 9 else (Oranges9 * ((len(labels)//9)+1))[:len(labels)] | |
| elif source == "es-render-seq": | |
| palette = Greens9[:len(labels)] if len(labels) <= 9 else (Greens9 * ((len(labels)//9)+1))[:len(labels)] | |
| else: | |
| palette = Blues9[:len(labels)] if len(labels) <= 9 else (Blues9 * ((len(labels)//9)+1))[:len(labels)] | |
| color_map["synthetic"][source] = {label: palette[i] for i, label in enumerate(sorted(labels))} | |
| # Asignar colores al subset pretrained usando, por ejemplo, la paleta Purples9 | |
| num_pretrained = len(unique_subsets["pretrained"]) | |
| purple_palette = Purples9[:num_pretrained] if num_pretrained <= 9 else (Purples9 * ((num_pretrained // 9) + 1))[:num_pretrained] | |
| color_map["pretrained"] = {label: purple_palette[i] for i, label in enumerate(sorted(unique_subsets["pretrained"]))} | |
| return color_map | |
| def calculate_cluster_centers(df, labels): | |
| centers = {} | |
| for label in labels: | |
| subset = df[df['label'] == label] | |
| if not subset.empty and 'x' in subset.columns and 'y' in subset.columns: | |
| centers[label] = (subset['x'].mean(), subset['y'].mean()) | |
| return centers | |
| def compute_global_regression(df_combined, embedding_cols, tsne_params, df_f1, reduction_method="t-SNE", distance_metric="wasserstein"): | |
| if reduction_method == "PCA": | |
| reducer = Pipeline([ | |
| ("pca", PCA(n_components=N_COMPONENTS)), | |
| ("rel_scaler", RelativeScaler()) | |
| ]) | |
| else: | |
| reducer = TSNE(n_components=2, random_state=42, | |
| perplexity=tsne_params["perplexity"], | |
| learning_rate=tsne_params["learning_rate"]) | |
| reduced = reducer.fit_transform(df_combined[embedding_cols].values) | |
| # Guardamos el embedding completo (por ejemplo, 4 dimensiones en PCA) | |
| df_combined['embedding'] = list(reduced) | |
| # Si el embedding es 2D, asignamos x e y para visualización | |
| if reduced.shape[1] == 2: | |
| df_combined['x'] = reduced[:, 0] | |
| df_combined['y'] = reduced[:, 1] | |
| explained_variance = None | |
| if reduction_method == "PCA": | |
| explained_variance = reducer.named_steps["pca"].explained_variance_ratio_ | |
| trust = None | |
| cont = None | |
| if reduction_method == "t-SNE": | |
| X = df_combined[embedding_cols].values | |
| trust = trustworthiness(X, reduced, n_neighbors=TSNE_NEIGHBOURS) | |
| cont = compute_continuity(X, reduced, n_neighbors=TSNE_NEIGHBOURS) | |
| dfs_reduced, unique_subsets = split_versions(df_combined, reduced) | |
| df_distances = compute_cluster_distances_synthetic_individual( | |
| dfs_reduced["synthetic"], | |
| dfs_reduced["real"], | |
| unique_subsets["real"], | |
| metric=distance_metric | |
| ) | |
| global_distances = {} | |
| for idx in df_distances.index: | |
| if idx.startswith("Global"): | |
| source = idx.split("(")[1].rstrip(")") | |
| global_distances[source] = df_distances.loc[idx].values | |
| all_x = [] | |
| all_y = [] | |
| for source in df_f1.columns: | |
| if source in global_distances: | |
| x_vals = global_distances[source] | |
| y_vals = df_f1[source].values | |
| all_x.extend(x_vals) | |
| all_y.extend(y_vals) | |
| all_x_arr = np.array(all_x).reshape(-1, 1) | |
| all_y_arr = np.array(all_y) | |
| model_global = LinearRegression().fit(all_x_arr, all_y_arr) | |
| r2 = model_global.score(all_x_arr, all_y_arr) | |
| slope = model_global.coef_[0] | |
| intercept = model_global.intercept_ | |
| scatter_fig = figure(width=600, height=600, tools="pan,wheel_zoom,reset,save", y_range=(0, 1), | |
| title="Scatter Plot: Distance vs F1") | |
| source_colors = { | |
| "es-digital-paragraph-degradation-seq": "blue", | |
| "es-digital-line-degradation-seq": "green", | |
| "es-digital-seq": "red", | |
| "es-digital-zoom-degradation-seq": "orange", | |
| "es-digital-rotation-degradation-seq": "purple", | |
| "es-digital-rotation-zoom-degradation-seq": "brown", | |
| "es-render-seq": "cyan" | |
| } | |
| for source in df_f1.columns: | |
| if source in global_distances: | |
| x_vals = global_distances[source] | |
| y_vals = df_f1[source].values | |
| data = {"x": x_vals, "y": y_vals, "Fuente": [source]*len(x_vals)} | |
| cds = ColumnDataSource(data=data) | |
| scatter_fig.circle('x', 'y', size=8, alpha=0.7, source=cds, | |
| fill_color=source_colors.get(source, "gray"), | |
| line_color=source_colors.get(source, "gray"), | |
| legend_label=source) | |
| scatter_fig.xaxis.axis_label = "Distance (Global, por Colegio)" | |
| scatter_fig.yaxis.axis_label = "F1 Score" | |
| scatter_fig.legend.location = "top_right" | |
| hover_tool = HoverTool(tooltips=[("Distance", "@x"), ("F1", "@y"), ("Subset", "@Fuente")]) | |
| scatter_fig.add_tools(hover_tool) | |
| # scatter_fig.match_aspect = True | |
| x_line = np.linspace(all_x_arr.min(), all_x_arr.max(), 100) | |
| y_line = model_global.predict(x_line.reshape(-1, 1)) | |
| scatter_fig.line(x_line, y_line, line_width=2, line_color="black", legend_label="Global Regression") | |
| results = { | |
| "R2": r2, | |
| "slope": slope, | |
| "intercept": intercept, | |
| "scatter_fig": scatter_fig, | |
| "dfs_reduced": dfs_reduced, | |
| "unique_subsets": unique_subsets, | |
| "df_distances": df_distances, | |
| "explained_variance": explained_variance, | |
| "trustworthiness": trust, | |
| "continuity": cont | |
| } | |
| if reduction_method == "PCA": | |
| results["pca_model"] = reducer # Agregamos el objeto PCA para usarlo luego en los plots | |
| return results | |
| # def get_color(color_entry): | |
| # if isinstance(color_entry, dict): | |
| # # Extrae el primer valor (o ajusta según convenga) | |
| # return list(color_entry.values())[0] | |
| # return color_entry | |
| def optimize_tsne_params(df_combined, embedding_cols, df_f1, distance_metric): | |
| perplexity_range = np.linspace(30, 50, 10) | |
| learning_rate_range = np.linspace(200, 1000, 20) | |
| best_R2 = -np.inf | |
| best_params = None | |
| total_steps = len(perplexity_range) * len(learning_rate_range) | |
| step = 0 | |
| progress_text = st.empty() | |
| for p in perplexity_range: | |
| for lr in learning_rate_range: | |
| step += 1 | |
| progress_text.text(f"Evaluating: Perplexity={p:.2f}, Learning Rate={lr:.2f} (Step {step}/{total_steps})") | |
| tsne_params = {"perplexity": p, "learning_rate": lr} | |
| result = compute_global_regression(df_combined, embedding_cols, tsne_params, df_f1, reduction_method="t-SNE", distance_metric=distance_metric) | |
| r2_temp = result["R2"] | |
| st.write(f"Parameters: Perplexity={p:.2f}, Learning Rate={lr:.2f} -> R²={r2_temp:.4f}") | |
| if r2_temp > best_R2: | |
| best_R2 = r2_temp | |
| best_params = (p, lr) | |
| progress_text.text("Optimization completed!") | |
| return best_params, best_R2 | |
| def run_model(model_name): | |
| version = st.selectbox("Select Model Version:", options=["vanilla", "finetuned_real"], key=f"version_{model_name}") | |
| # Selector para el método de cómputo del embedding | |
| embedding_computation = st.selectbox("¿Cómo se computa el embedding?", options=["averaged", "weighted"], key=f"embedding_method_{model_name}") | |
| # Se asigna el prefijo correspondiente | |
| if embedding_computation == "weighted": | |
| selected_weight_factor = st.selectbox( | |
| "Seleccione el Weight Factor", | |
| options=[0.05, 0.1, 0.25, 0.5], | |
| index=0, # índice 1 para que por defecto sea 0.05 | |
| key=f"weight_factor_{model_name}" | |
| ) | |
| weight_factor = f"{selected_weight_factor}_" | |
| else: | |
| weight_factor = "" | |
| embeddings = load_embeddings(model_name, version, embedding_computation, weight_factor) | |
| if embeddings is None: | |
| return | |
| # Nuevo selector para incluir o excluir el dataset pretrained | |
| include_pretrained = st.checkbox("Incluir dataset pretrained", value=False, key=f"legend_{model_name}_pretrained") | |
| if not include_pretrained: | |
| # Removemos la entrada pretrained del diccionario, si existe. | |
| embeddings.pop("pretrained", None) | |
| # Extraer columnas de embedding de los datos "real" | |
| embedding_cols = [col for col in embeddings["real"].columns if col.startswith("dim_")] | |
| # Concatenamos los datasets disponibles (ahora, sin pretrained si se deseleccionó) | |
| df_combined = pd.concat(list(embeddings.values()), ignore_index=True) | |
| try: | |
| df_f1 = pd.read_csv("data/f1-donut.csv", sep=';', index_col=0) | |
| except Exception as e: | |
| st.error(f"Error loading f1-donut.csv: {e}") | |
| return | |
| st.markdown('<h6 class="sub-title">Select Dimensionality Reduction Method</h6>', unsafe_allow_html=True) | |
| reduction_method = st.selectbox("", options=["PCA", "t-SNE"], key=f"reduction_{model_name}") | |
| distance_metric = st.selectbox("Select Distance Metric:", | |
| options=["Euclidean", "Wasserstein", "KL"], | |
| key=f"distance_metric_{model_name}") | |
| tsne_params = {} | |
| if reduction_method == "t-SNE": | |
| if st.button("Optimize TSNE parameters", key=f"optimize_tsne_{model_name}"): | |
| st.info("Running optimization, this can take a while...") | |
| best_params, best_R2 = optimize_tsne_params(df_combined, embedding_cols, df_f1, distance_metric.lower()) | |
| st.success(f"Best parameters: Perplexity = {best_params[0]:.2f}, Learning Rate = {best_params[1]:.2f} with R² = {best_R2:.4f}") | |
| tsne_params = {"perplexity": best_params[0], "learning_rate": best_params[1]} | |
| else: | |
| perplexity_val = st.number_input( | |
| "Perplexity", | |
| min_value=5.0, | |
| max_value=50.0, | |
| value=30.0, | |
| step=1.0, | |
| format="%.2f", | |
| key=f"perplexity_{model_name}" | |
| ) | |
| learning_rate_val = st.number_input( | |
| "Learning Rate", | |
| min_value=10.0, | |
| max_value=1000.0, | |
| value=200.0, | |
| step=10.0, | |
| format="%.2f", | |
| key=f"learning_rate_{model_name}" | |
| ) | |
| tsne_params = {"perplexity": perplexity_val, "learning_rate": learning_rate_val} | |
| result = compute_global_regression(df_combined, embedding_cols, tsne_params, df_f1, reduction_method=reduction_method, distance_metric=distance_metric.lower()) | |
| reg_metrics = pd.DataFrame({ | |
| "Slope": [result["slope"]], | |
| "Intercept": [result["intercept"]], | |
| "R2": [result["R2"]] | |
| }) | |
| st.table(reg_metrics) | |
| if reduction_method == "PCA" and result["explained_variance"] is not None: | |
| st.subheader("Explained Variance Ratio") | |
| component_names = [f"PC{i+1}" for i in range(len(result["explained_variance"]))] | |
| variance_df = pd.DataFrame({ | |
| "Component": component_names, | |
| "Explained Variance": result["explained_variance"] | |
| }) | |
| st.table(variance_df) | |
| elif reduction_method == "t-SNE": | |
| st.subheader("t-SNE Quality Metrics") | |
| st.write(f"Trustworthiness: {result['trustworthiness']:.4f}") | |
| st.write(f"Continuity: {result['continuity']:.4f}") | |
| # # Mostrar los plots de loadings si se usó PCA (para el conjunto combinado) | |
| # if reduction_method == "PCA" and result.get("pca_model") is not None: | |
| # # pca_model = result["pca_model"] | |
| # pca_model = result["pca_model"].named_steps["pca"] | |
| # components = pca_model.components_ # Shape: (n_components, n_features) | |
| # st.subheader("Pesos de las Componentes Principales (Loadings) - Conjunto Combinado") | |
| # for i, comp in enumerate(components): | |
| # source = ColumnDataSource(data=dict( | |
| # dimensions=embedding_cols, | |
| # weight=comp | |
| # )) | |
| # p = figure(x_range=embedding_cols, title=f"Componente Principal {i+1}", | |
| # plot_height=400, plot_width=600, | |
| # toolbar_location="above", | |
| # tools="pan,wheel_zoom,reset,save,hover", | |
| # active_scroll="wheel_zoom") | |
| # # Establecer fondo blanco | |
| # p.background_fill_color = "white" | |
| # # Mostrar solo grilla horizontal | |
| # p.xgrid.grid_line_color = None | |
| # p.ygrid.grid_line_color = "gray" | |
| # p.vbar(x='dimensions', top='weight', width=0.8, source=source) | |
| # p.xaxis.major_label_text_font_size = '0pt' | |
| # hover = HoverTool(tooltips=[("Dimensión", "@dimensions"), ("Peso", "@weight")]) | |
| # p.add_tools(hover) | |
| # p.xaxis.axis_label = "Dimensiones originales" | |
| # p.yaxis.axis_label = "Peso" | |
| # st.bokeh_chart(p) | |
| data_table, df_table, source_table = create_table(result["df_distances"]) | |
| real_subset_names = list(df_table.columns[1:]) | |
| real_select = Select(title="", value=real_subset_names[0], options=real_subset_names) | |
| reset_button = Button(label="Reset Colors", button_type="primary") | |
| line_source = ColumnDataSource(data={'x': [], 'y': []}) | |
| # if (reduction_method == "t-SNE" and N_COMPONENTS == 2) or (reduction_method == "PCA" and N_COMPONENTS == 2): | |
| # fig, real_renderers, synthetic_renderers, pretrained_renderers = create_figure( | |
| # result["dfs_reduced"], | |
| # result["unique_subsets"], | |
| # get_color_maps(result["unique_subsets"]), | |
| # model_name | |
| # ) | |
| # fig.line('x', 'y', source=line_source, line_width=2, line_color='black') | |
| # centers_real = calculate_cluster_centers(result["dfs_reduced"]["real"], result["unique_subsets"]["real"]) | |
| # real_centers_js = {k: [v[0], v[1]] for k, v in centers_real.items()} | |
| # synthetic_centers = {} | |
| # synth_labels = sorted(result["dfs_reduced"]["synthetic"]['label'].unique().tolist()) | |
| # for label in synth_labels: | |
| # subset = result["dfs_reduced"]["synthetic"][result["dfs_reduced"]["synthetic"]['label'] == label] | |
| # if 'x' in subset.columns and 'y' in subset.columns: | |
| # synthetic_centers[label] = [subset['x'].mean(), subset['y'].mean()] | |
| # callback = CustomJS(args=dict(source=source_table, line_source=line_source, | |
| # synthetic_centers=synthetic_centers, | |
| # real_centers=real_centers_js, | |
| # real_select=real_select), | |
| # code=""" | |
| # var selected = source.selected.indices; | |
| # if (selected.length > 0) { | |
| # var idx = selected[0]; | |
| # var data = source.data; | |
| # var synth_label = data['Synthetic'][idx]; | |
| # var real_label = real_select.value; | |
| # var syn_coords = synthetic_centers[synth_label]; | |
| # var real_coords = real_centers[real_label]; | |
| # line_source.data = {'x': [syn_coords[0], real_coords[0]], 'y': [syn_coords[1], real_coords[1]]}; | |
| # line_source.change.emit(); | |
| # } else { | |
| # line_source.data = {'x': [], 'y': []}; | |
| # line_source.change.emit(); | |
| # } | |
| # """) | |
| # source_table.selected.js_on_change('indices', callback) | |
| # real_select.js_on_change('value', callback) | |
| # reset_callback = CustomJS(args=dict(line_source=line_source), | |
| # code=""" | |
| # line_source.data = {'x': [], 'y': []}; | |
| # line_source.change.emit(); | |
| # """) | |
| # reset_button.js_on_event("button_click", reset_callback) | |
| # layout = column(fig, result["scatter_fig"], column(real_select, reset_button, data_table)) | |
| # else: | |
| # layout = column(result["scatter_fig"], column(real_select, reset_button, data_table)) | |
| # st.bokeh_chart(layout, use_container_width=True) | |
| buffer = io.BytesIO() | |
| df_table.to_excel(buffer, index=False) | |
| buffer.seek(0) | |
| st.download_button( | |
| label="Export Table", | |
| data=buffer, | |
| file_name=f"cluster_distances_{model_name}.xlsx", | |
| mime="application/vnd.openxmlformats-officedocument.spreadsheetml.sheet", | |
| key=f"download_button_excel_{model_name}" | |
| ) | |
| if reduction_method == "PCA": | |
| st.markdown("## PCA - Solo Muestras Reales") | |
| # ------------------------------------------------------------------------- | |
| # 1. PCA sobre las muestras reales | |
| df_real_only = embeddings["real"].copy() | |
| reducer_real = Pipeline([ | |
| ("pca", PCA(n_components=N_COMPONENTS)), | |
| ("rel_scaler", RelativeScaler()) | |
| ]) | |
| reduced_real = reducer_real.fit_transform(df_real_only[embedding_cols].values) | |
| # Agregar columnas PC1, PC2, … a df_real_only | |
| for i in range(reduced_real.shape[1]): | |
| df_real_only[f'PC{i+1}'] = reduced_real[:, i] | |
| explained_variance_real = reducer_real.named_steps["pca"].explained_variance_ratio_ | |
| unique_labels_real = sorted(df_real_only['label'].unique().tolist()) | |
| # Mapeo de colores para las muestras reales usando la paleta Reds9 | |
| num_labels = len(unique_labels_real) | |
| if num_labels <= 9: | |
| red_palette = Reds9[:num_labels] | |
| else: | |
| red_palette = (Reds9 * ((num_labels // 9) + 1))[:num_labels] | |
| real_color_mapping = {label: red_palette[i] for i, label in enumerate(unique_labels_real)} | |
| # Mostrar tabla de Explained Variance Ratio | |
| st.subheader("PCA - Real: Explained Variance Ratio") | |
| component_names_real = [f"PC{i+1}" for i in range(len(explained_variance_real))] | |
| variance_df_real = pd.DataFrame({ | |
| "Component": component_names_real, | |
| "Explained Variance": explained_variance_real | |
| }) | |
| st.table(variance_df_real) | |
| # Mostrar los plots de loadings para cada componente | |
| # st.subheader("PCA - Real: Component Loadings") | |
| # st.markdown("### Pesos de las Componentes Principales (Loadings) - Conjunto Combinado") | |
| # for i, comp in enumerate(reducer_real.named_steps["pca"].components_): | |
| # source = ColumnDataSource(data=dict( | |
| # dimensions=embedding_cols, | |
| # weight=comp | |
| # )) | |
| # p = figure( | |
| # x_range=embedding_cols, | |
| # title=f"Componente Principal {i+1}", | |
| # plot_height=400, | |
| # plot_width=600, | |
| # toolbar_location="above", | |
| # tools="pan,wheel_zoom,reset,save,hover", | |
| # active_scroll="wheel_zoom" | |
| # ) | |
| # p.background_fill_color = "white" | |
| # p.xgrid.grid_line_color = None | |
| # p.ygrid.grid_line_color = "gray" | |
| # p.vbar(x='dimensions', top='weight', width=0.8, source=source, | |
| # fill_color="#2b83ba", line_color="#2b83ba") | |
| # p.xaxis.axis_label = "Dimensiones Originales" | |
| # p.xaxis.major_label_text_font_size = '0pt' | |
| # hover = p.select_one(HoverTool) | |
| # hover.tooltips = [("Dimensión", "@dimensions"), ("Peso", "@weight")] | |
| # st.bokeh_chart(p) | |
| # ------------------------------------------------------------------------- | |
| # 2. Proyección de todos los subconjuntos usando los loadings de df_real (para PC completos) | |
| # Se proyectan real, synthetic y pretrained (si existen) y se agregan todas las PC's. | |
| df_all = {} | |
| # Real | |
| df_real_proj = embeddings["real"].copy() | |
| # proj_real = reducer_real.named_steps["pca"].transform(df_real_proj[embedding_cols].values) | |
| proj_real = reducer_real.transform(df_real_proj[embedding_cols].values) | |
| for i in range(proj_real.shape[1]): | |
| df_real_proj[f'PC{i+1}'] = proj_real[:, i] | |
| df_all["real"] = df_real_proj | |
| # Synthetic | |
| if "synthetic" in embeddings: | |
| df_synth_proj = embeddings["synthetic"].copy() | |
| proj_synth = reducer_real.transform(df_synth_proj[embedding_cols].values) | |
| for i in range(proj_synth.shape[1]): | |
| df_synth_proj[f'PC{i+1}'] = proj_synth[:, i] | |
| df_all["synthetic"] = df_synth_proj | |
| # Pretrained | |
| if "pretrained" in embeddings: | |
| df_pretr_proj = embeddings["pretrained"].copy() | |
| proj_pretr = reducer_real.transform(df_pretr_proj[embedding_cols].values) | |
| for i in range(proj_pretr.shape[1]): | |
| df_pretr_proj[f'PC{i+1}'] = proj_pretr[:, i] | |
| df_all["pretrained"] = df_pretr_proj | |
| # Para el plot global usaremos PC1 y PC2 (se asignan a 'x' y 'y') | |
| for key in df_all: | |
| df_all[key]["x"] = df_all[key]["PC1"] | |
| df_all[key]["y"] = df_all[key]["PC2"] | |
| # Construir los subconjuntos únicos para agrupar: | |
| unique_subsets = {} | |
| unique_subsets["real"] = sorted(df_all["real"]['label'].unique().tolist()) | |
| if "synthetic" in df_all: | |
| unique_synth = {} | |
| for source in df_all["synthetic"]["source"].unique(): | |
| unique_synth[source] = sorted(df_all["synthetic"][df_all["synthetic"]["source"] == source]['label'].unique().tolist()) | |
| unique_subsets["synthetic"] = unique_synth | |
| else: | |
| unique_subsets["synthetic"] = {} | |
| if "pretrained" in df_all: | |
| unique_subsets["pretrained"] = sorted(df_all["pretrained"]['label'].unique().tolist()) | |
| else: | |
| unique_subsets["pretrained"] = [] | |
| # Obtener mapeo de colores para cada subconjunto (función definida externamente) | |
| color_maps = get_color_maps(unique_subsets) | |
| # Mapeo de marcadores para synthetic (por source) | |
| marker_mapping = { | |
| "es-digital-paragraph-degradation-seq": "x", | |
| "es-digital-line-degradation-seq": "cross", | |
| "es-digital-seq": "triangle", | |
| "es-digital-rotation-degradation-seq": "diamond", | |
| "es-digital-zoom-degradation-seq": "asterisk", | |
| "es-render-seq": "inverted_triangle" | |
| } | |
| # Plot global: se muestran real, synthetic y pretrained (según checkbox) | |
| st.subheader("PCA - Todos los subconjuntos proyectados (PC1 vs PC2)") | |
| fig_all = figure( | |
| title="PCA - Todos los subconjuntos proyectados", | |
| plot_width=600, | |
| plot_height=600, | |
| tools="pan,wheel_zoom,reset,save", | |
| active_scroll="wheel_zoom", | |
| background_fill_color="white", | |
| tooltips=TOOLTIPS | |
| ) | |
| fig_all.xgrid.grid_line_color = None | |
| fig_all.ygrid.grid_line_color = "gray" | |
| # Plotear las muestras reales, agrupadas por label | |
| for label in unique_subsets["real"]: | |
| subset = df_all["real"][df_all["real"]['label'] == label] | |
| source = ColumnDataSource(data={ | |
| 'x': subset['x'], | |
| 'y': subset['y'], | |
| 'label': subset['label'], | |
| 'img': subset['img'] | |
| }) | |
| fig_all.circle('x', 'y', size=10, | |
| fill_color=color_maps["real"][label], | |
| line_color=color_maps["real"][label], | |
| legend_label=f"Real: {label}", | |
| source=source) | |
| show_real_only = st.checkbox("Show only real samples", value=True, key=f"show_real_only_{model_name}") | |
| if not show_real_only: | |
| # Agregar synthetic | |
| if unique_subsets["synthetic"]: | |
| for source_name, labels in unique_subsets["synthetic"].items(): | |
| df_source = df_all["synthetic"][df_all["synthetic"]["source"] == source_name] | |
| marker = marker_mapping.get(source_name, "square") | |
| # Se usa el mapeo de colores para synthetic | |
| color_val = color_maps["synthetic"][source_name] | |
| renderers = add_synthetic_dataset_to_fig( | |
| fig_all, df_source, labels, | |
| marker=marker, | |
| color_mapping=color_val, | |
| group_label=source_name | |
| ) | |
| # Agregar pretrained | |
| if unique_subsets["pretrained"]: | |
| for label in unique_subsets["pretrained"]: | |
| subset = df_all["pretrained"][df_all["pretrained"]['label'] == label] | |
| source = ColumnDataSource(data={ | |
| 'x': subset['x'], | |
| 'y': subset['y'], | |
| 'label': subset['label'], | |
| 'img': subset['img'] | |
| }) | |
| fig_all.triangle('x', 'y', size=10, | |
| fill_color=color_maps["pretrained"][label], | |
| line_color=color_maps["pretrained"][label], | |
| legend_label=f"Pretrained: {label}", | |
| source=source) | |
| show_legend_global = st.checkbox("Show Legend", value=False, key=f"legend_global_{model_name}") | |
| fig_all.legend.visible = show_legend_global | |
| fig_all.legend.location = "top_right" | |
| fig_all.match_aspect = True | |
| st.bokeh_chart(fig_all) | |
| # Calcular centroide y radio (usando solo las muestras reales) | |
| center_x = df_all["real"]['x'].mean() | |
| center_y = df_all["real"]['y'].mean() | |
| distances = np.sqrt((df_all["real"]['x'] - center_x)**2 + (df_all["real"]['y'] - center_y)**2) | |
| radius = distances.max() | |
| # Dibujar el centroide y la circunferencia | |
| centroid_glyph = fig_all.circle( | |
| x=center_x, y=center_y, size=15, | |
| fill_color="white", line_color="black", | |
| legend_label="Centroide", | |
| name="centroid" | |
| ) | |
| circumference_glyph = fig_all.circle( | |
| x=center_x, y=center_y, radius=radius, | |
| fill_color=None, line_color="black", | |
| line_dash="dashed", | |
| legend_label="Circunferencia", | |
| name="circumference" | |
| ) | |
| # Ajustar ejes y tooltips | |
| fig_all.xaxis.axis_label = "PC1" | |
| fig_all.yaxis.axis_label = "PC2" | |
| hover_all = fig_all.select_one(HoverTool) | |
| hover_all.renderers = [r for r in fig_all.renderers if r.name not in ["centroid", "circumference"]] | |
| st.write(f"El radio de la circunferencia (calculado a partir de las muestras reales) es: {radius:.4f}") | |
| # ------------------------------------------------------------------------- | |
| # Calcular el rango global: recorrer todas las proyecciones de todos los subconjuntos | |
| all_vals = [] | |
| for key in df_all: | |
| for comp in [f'PC{i+1}' for i in range(N_COMPONENTS)]: | |
| all_vals.append(df_all[key][comp]) | |
| all_vals = pd.concat(all_vals) | |
| # Tomar el máximo valor absoluto de todas las proyecciones | |
| max_val = all_vals.abs().max() | |
| global_range = (-max_val, max_val) | |
| # 3. Scatter plots para cada combinación (vistas planta, alzado y perfil) | |
| st.subheader("Scatter Plots: Vistas de Componentes (Combinaciones)") | |
| pairs = list(itertools.combinations(range(N_COMPONENTS), 2)) | |
| for (i, j) in pairs: | |
| x_comp = f'PC{i+1}' | |
| y_comp = f'PC{j+1}' | |
| st.markdown(f"### Scatter Plot: {x_comp} vs {y_comp}") | |
| # Usar el rango global para ambos ejes | |
| p = figure( | |
| title=f"{x_comp} vs {y_comp}", | |
| plot_width=700, | |
| plot_height=700, | |
| x_range=global_range, | |
| y_range=global_range, | |
| tools="pan,wheel_zoom,reset,save,hover", | |
| active_scroll="wheel_zoom", | |
| background_fill_color="white", | |
| tooltips=TOOLTIPS | |
| ) | |
| # Etiquetas de ejes | |
| p.xaxis.axis_label = x_comp | |
| p.yaxis.axis_label = y_comp | |
| # Muestras reales: se usan directamente los valores de PC{i+1} y PC{j+1} | |
| for label in unique_subsets["real"]: | |
| subset = df_all["real"][df_all["real"]['label'] == label] | |
| source = ColumnDataSource(data={ | |
| 'x': subset[x_comp], | |
| 'y': subset[y_comp], | |
| 'label': subset['label'], | |
| 'img': subset['img'] | |
| }) | |
| p.circle('x', 'y', size=10, | |
| fill_color=color_maps["real"][label], | |
| line_color=color_maps["real"][label], | |
| legend_label=f"Real: {label}", | |
| source=source) | |
| # Selector para incluir o no synthetic y pretrained en este gráfico | |
| show_pair_only_real = st.checkbox("Show only real samples", value=True, key=f"pair_show_real_{i}_{j}_{model_name}") | |
| if not show_pair_only_real: | |
| # Synthetic | |
| if "synthetic" in df_all: | |
| for source_name, labels in unique_subsets["synthetic"].items(): | |
| # Obtener las filas de synthetic para ese source y asignar el rango adecuado | |
| df_source = df_all["synthetic"][df_all["synthetic"]["source"] == source_name].copy() | |
| df_source["x"] = df_source[x_comp] | |
| df_source["y"] = df_source[y_comp] | |
| marker = marker_mapping.get(source_name, "square") | |
| renderers = add_synthetic_dataset_to_fig( | |
| p, df_source, labels, | |
| marker=marker, | |
| color_mapping=color_maps["synthetic"][source_name], | |
| group_label=source_name | |
| ) | |
| # Pretrained | |
| if "pretrained" in df_all: | |
| for label in unique_subsets["pretrained"]: | |
| subset = df_all["pretrained"][df_all["pretrained"]['label'] == label] | |
| source = ColumnDataSource(data={ | |
| 'x': subset[x_comp], | |
| 'y': subset[y_comp], | |
| 'label': subset['label'], | |
| 'img': subset['img'] | |
| }) | |
| p.triangle('x', 'y', size=10, | |
| fill_color=color_maps["pretrained"][label], | |
| line_color=color_maps["pretrained"][label], | |
| legend_label=f"Pretrained: {label}", | |
| source=source) | |
| show_legend_pair = st.checkbox("Show Legend", value=False, key=f"legend_pair_{i}_{j}_{model_name}") | |
| p.legend.visible = show_legend_pair | |
| st.bokeh_chart(p) | |
| # ------------------------------------------------------------------------- | |
| # 4. Cálculo de distancias y scatter plot: Distance vs F1 (usando PC1 y PC2 globales) | |
| # Genera una paleta de 256 colores basada en RdYlGn11 | |
| cmap = plt.get_cmap("RdYlGn") | |
| red_green_palette = [mcolors.rgb2hex(cmap(i)) for i in np.linspace(0, 1, 256)] | |
| # real_labels_new = sorted(df_all["real"]['label'].unique().tolist()) | |
| # df_distances_new = compute_cluster_distances_synthetic_individual( | |
| # df_all["synthetic"], | |
| # df_all["real"], | |
| # real_labels_new, | |
| # metric="wasserstein", # O la métrica que prefieras | |
| # bins=20 | |
| # ) | |
| # global_distances_new = {} | |
| # for idx in df_distances_new.index: | |
| # if idx.startswith("Global"): | |
| # source_name = idx.split("(")[1].rstrip(")") | |
| # global_distances_new[source_name] = df_distances_new.loc[idx].values | |
| # all_x_new = [] | |
| # all_y_new = [] | |
| # for source in df_f1.columns: | |
| # if source in global_distances_new: | |
| # x_vals = global_distances_new[source] | |
| # y_vals = df_f1[source].values | |
| # all_x_new.extend(x_vals) | |
| # all_y_new.extend(y_vals) | |
| # all_x_arr_new = np.array(all_x_new).reshape(-1, 1) | |
| # all_y_arr_new = np.array(all_y_new) | |
| # model_global_new = LinearRegression().fit(all_x_arr_new, all_y_arr_new) | |
| # r2_new = model_global_new.score(all_x_arr_new, all_y_arr_new) | |
| # slope_new = model_global_new.coef_[0] | |
| # intercept_new = model_global_new.intercept_ | |
| # scatter_fig_new = figure( | |
| # width=600, | |
| # height=600, | |
| # tools="pan,wheel_zoom,reset,save,hover", | |
| # active_scroll="wheel_zoom", | |
| # title="Scatter Plot: Distance vs F1 (Nueva PCA)", | |
| # background_fill_color="white", | |
| # y_range=(0, 1) | |
| # ) | |
| # scatter_fig_new.xgrid.grid_line_color = None | |
| # scatter_fig_new.ygrid.grid_line_color = "gray" | |
| # scatter_fig_new.match_aspect = True | |
| # source_colors = { | |
| # "es-digital-paragraph-degradation-seq": "blue", | |
| # "es-digital-line-degradation-seq": "green", | |
| # "es-digital-seq": "red", | |
| # "es-digital-zoom-degradation-seq": "orange", | |
| # "es-digital-rotation-degradation-seq": "purple", | |
| # "es-digital-rotation-zoom-degradation-seq": "brown", | |
| # "es-render-seq": "cyan" | |
| # } | |
| # for source in df_f1.columns: | |
| # if source in global_distances_new: | |
| # x_vals = global_distances_new[source] | |
| # y_vals = df_f1[source].values | |
| # data = {"x": x_vals, "y": y_vals, "Fuente": [source]*len(x_vals)} | |
| # cds = ColumnDataSource(data=data) | |
| # scatter_fig_new.circle( | |
| # 'x', 'y', size=8, alpha=0.7, source=cds, | |
| # fill_color=source_colors.get(source, "gray"), | |
| # line_color=source_colors.get(source, "gray"), | |
| # legend_label=source | |
| # ) | |
| # scatter_fig_new.xaxis.axis_label = "Distance (Global, por Colegio) - Nueva PCA" | |
| # scatter_fig_new.yaxis.axis_label = "F1 Score" | |
| # scatter_fig_new.legend.location = "top_right" | |
| # hover_tool_new = scatter_fig_new.select_one(HoverTool) | |
| # hover_tool_new.tooltips = [("Distance", "@x"), ("F1", "@y"), ("Subset", "@Fuente")] | |
| # x_line_new = np.linspace(all_x_arr_new.min(), all_x_arr_new.max(), 100) | |
| # y_line_new = model_global_new.predict(x_line_new.reshape(-1,1)) | |
| # scatter_fig_new.line(x_line_new, y_line_new, line_width=2, line_color="black", legend_label="Global Regression") | |
| # st.bokeh_chart(scatter_fig_new) | |
| # st.write(f"Regresión global (Nueva PCA): R² = {r2_new:.4f}, Slope = {slope_new:.4f}, Intercept = {intercept_new:.4f}") | |
| # ------------------------------------------------------------------------- | |
| # 5. BLOQUE: Heatmap de Características | |
| st.markdown("## Heatmap de Características") | |
| try: | |
| df_heat = pd.read_csv(f"data/heatmaps_{model_name.lower()}.csv") | |
| except Exception as e: | |
| st.error(f"Error al cargar heatmaps.csv: {e}") | |
| df_heat = None | |
| if df_heat is not None: | |
| if 'img' not in df_all["real"].columns: | |
| st.error("La columna 'img' no se encuentra en las muestras reales para hacer el merge con heatmaps.csv.") | |
| else: | |
| # Crear columna 'name' en las muestras reales (si aún no existe) | |
| df_all["real"]["name"] = df_all["real"]["img"].apply( | |
| lambda x: x.split("/")[-1].replace(".png", "") if isinstance(x, str) else x | |
| ) | |
| # Merge de las posiciones reales con el CSV de heatmaps (se usa el merge base) | |
| df_heatmap_base = pd.merge(df_all["real"], df_heat, on="name", how="inner") | |
| # Extraer opciones de feature (excluyendo 'name') | |
| feature_options = [col for col in df_heat.columns if col != "name"] | |
| selected_feature = st.selectbox("Select heatmap feature:", | |
| options=feature_options, key=f"heatmap_{model_name}") | |
| select_extra_dataset_hm = st.selectbox("Select a dataset:", | |
| options=model_options_with_default, key=f"heatmap_extra_dataset_{model_name}") | |
| # Definir un rango fijo para los ejes (por ejemplo, de -1 a 1) y rejilla | |
| x_min, x_max = -1, 1 | |
| y_min, y_max = -1, 1 | |
| grid_size = 50 | |
| x_bins = np.linspace(x_min, x_max, grid_size + 1) | |
| y_bins = np.linspace(y_min, y_max, grid_size + 1) | |
| # Listas para almacenar las figuras de heatmap y sus nombres | |
| heatmap_figures = [] | |
| heatmap_names = [] | |
| # Generar heatmaps para cada combinación de componentes | |
| pairs = list(itertools.combinations(range(N_COMPONENTS), 2)) | |
| for (i, j) in pairs: | |
| x_comp = f'PC{i+1}' | |
| y_comp = f'PC{j+1}' | |
| st.markdown(f"### Heatmap: {x_comp} vs {y_comp}") | |
| # Crear un DataFrame de heatmap para la combinación actual a partir del merge base | |
| df_heatmap = df_heatmap_base.copy() | |
| df_heatmap["x"] = df_heatmap[x_comp] | |
| df_heatmap["y"] = df_heatmap[y_comp] | |
| # Si la feature seleccionada no es numérica, convertir a códigos y guardar la correspondencia | |
| cat_mapping = None | |
| if df_heatmap[selected_feature].dtype == bool or not pd.api.types.is_numeric_dtype(df_heatmap[selected_feature]): | |
| cat = df_heatmap[selected_feature].astype('category') | |
| cat_mapping = list(cat.cat.categories) | |
| df_heatmap[selected_feature] = cat.cat.codes | |
| # Calcular la estadística binned (por ejemplo, la media) en la rejilla | |
| try: | |
| heat_stat, x_edges, y_edges, binnumber = binned_statistic_2d( | |
| df_heatmap['x'], df_heatmap['y'], df_heatmap[selected_feature], | |
| statistic='mean', bins=[x_bins, y_bins] | |
| ) | |
| except TypeError: | |
| cat = df_heatmap[selected_feature].astype('category') | |
| cat_mapping = list(cat.cat.categories) | |
| df_heatmap[selected_feature] = cat.cat.codes | |
| heat_stat, x_edges, y_edges, binnumber = binned_statistic_2d( | |
| df_heatmap['x'], df_heatmap['y'], df_heatmap[selected_feature], | |
| statistic='mean', bins=[x_bins, y_bins] | |
| ) | |
| # Transponer la matriz para alinear correctamente los ejes | |
| # Transponer y limpiar valores inválidos (NaN, inf, -inf) | |
| heatmap_data = heat_stat.T | |
| # heatmap_data = np.nan_to_num(heat_stat.T, nan=0.0, posinf=0.0, neginf=0.0) | |
| # Definir el color mapper | |
| if selected_feature in model_options: | |
| color_mapper = LinearColorMapper( | |
| palette=red_green_palette, | |
| low=0, | |
| high=1, | |
| nan_color='rgba(0, 0, 0, 0)' | |
| ) | |
| else: | |
| color_mapper = LinearColorMapper( | |
| palette="Viridis256", | |
| low=np.nanmin(heatmap_data), | |
| high=np.nanmax(heatmap_data), | |
| nan_color='rgba(0, 0, 0, 0)' | |
| ) | |
| # Crear la figura para el heatmap con la misma escala para x e y | |
| heatmap_fig = figure(title=f"Heatmap de '{selected_feature}' ({x_comp} vs {y_comp})", | |
| x_range=(x_min, x_max), y_range=(y_min, y_max), | |
| width=600, height=600, | |
| tools="pan,wheel_zoom,reset,save", active_scroll="wheel_zoom", tooltips=TOOLTIPS, | |
| sizing_mode="fixed") | |
| heatmap_fig.match_aspect = True | |
| # Asignar etiquetas a los ejes | |
| heatmap_fig.xaxis.axis_label = x_comp | |
| heatmap_fig.yaxis.axis_label = y_comp | |
| heatmap_fig.background_fill_color = "white" | |
| heatmap_fig.border_fill_color = "white" | |
| # Dibujar la imagen del heatmap | |
| heatmap_fig.image(image=[heatmap_data], x=x_min, y=y_min, | |
| dw=x_max - x_min, dh=y_max - y_min, | |
| color_mapper=color_mapper) | |
| # Agregar la barra de color | |
| color_bar = ColorBar(color_mapper=color_mapper, location=(0, 0)) | |
| if cat_mapping is not None: | |
| ticks = list(range(len(cat_mapping))) | |
| color_bar.ticker = FixedTicker(ticks=ticks) | |
| categories_json = json.dumps(cat_mapping) | |
| color_bar.formatter = FuncTickFormatter(code=f""" | |
| var categories = {categories_json}; | |
| var index = Math.round(tick); | |
| if(index >= 0 && index < categories.length) {{ | |
| return categories[index]; | |
| }} else {{ | |
| return ""; | |
| }} | |
| """) | |
| heatmap_fig.add_layout(color_bar, 'right') | |
| # Agregar renderer invisible para tooltips | |
| source_points = ColumnDataSource(data={ | |
| 'x': df_heatmap['x'], | |
| 'y': df_heatmap['y'], | |
| 'img': df_heatmap['img'], | |
| 'label': df_heatmap['name'] | |
| }) | |
| invisible_renderer = heatmap_fig.circle('x', 'y', size=10, source=source_points, fill_alpha=0, line_alpha=0.5) | |
| # school = "patria" | |
| if select_extra_dataset_hm != "-": | |
| df_extra = df_all["synthetic"][df_all["synthetic"]["source"] == select_extra_dataset_hm].copy() | |
| df_extra["x"] = df_extra[x_comp] | |
| df_extra["y"] = df_extra[y_comp] | |
| if 'name' not in df_extra.columns: | |
| df_extra["name"] = df_extra["img"].apply(lambda x: x.split("/")[-1].replace(".png", "") if isinstance(x, str) else x) | |
| # mask = df_extra["name"].str.contains(school, case=False, na=False) | |
| # df_extra = df_extra[mask].copy() | |
| source_extra_points = ColumnDataSource(data={ | |
| 'x': df_extra['x'], | |
| 'y': df_extra['y'], | |
| 'img': df_extra['img'], | |
| 'label': df_extra['name'] | |
| }) | |
| extra_renderer = heatmap_fig.circle('x', 'y', size=5, source=source_extra_points, fill_alpha=0, line_alpha=0.5, color="purple") | |
| hover_tool_points = HoverTool(renderers=[invisible_renderer], tooltips=TOOLTIPS) | |
| heatmap_fig.add_tools(hover_tool_points) | |
| # Mostrar el heatmap en la app | |
| st.bokeh_chart(heatmap_fig) | |
| # Botón para descargar df_all (Embeddings in PCA Space) | |
| if st.button("Download Embeddings in PCA Space", key=f"click_download_pca_coordinates_{model_name}"): | |
| # Crear un nuevo diccionario para almacenar solo las columnas que comienzan con "PC" o "name" | |
| df_all_pca = {} | |
| for key, df in df_all.items(): | |
| # Si es el conjunto sintético, separamos cada subset según la columna "source" | |
| if key == "synthetic": | |
| for source in df["source"].unique(): | |
| df_subset = df[df["source"] == source].copy() | |
| # Asegurarse de que exista la columna "name" (como se hace en el snippet de heatmaps) | |
| if "img" in df_subset.columns and "name" not in df_subset.columns: | |
| df_subset["name"] = df_subset["img"].apply(lambda x: x.split("/")[-1].replace(".png", "") if isinstance(x, str) else x) | |
| pca_cols = [col for col in df_subset.columns if col.startswith("PC") or col == "name"] | |
| # Usar un nombre de hoja que identifique que es sintético y el source correspondiente | |
| sheet_name = f"synthetic_{source}" | |
| df_all_pca[sheet_name] = df_subset[pca_cols].copy() | |
| else: | |
| # Para "real" y otros (como "pretrained"), se guardan en una sola hoja | |
| pca_cols = [col for col in df.columns if col.startswith("PC") or col == "name"] | |
| df_all_pca[key] = df[pca_cols].copy() | |
| # Crear un buffer en memoria para el archivo Excel | |
| excel_buffer = io.BytesIO() | |
| # Escribir cada DataFrame en una hoja separada usando ExcelWriter | |
| with pd.ExcelWriter(excel_buffer, engine='openpyxl') as writer: | |
| for key_name, df in df_all_pca.items(): | |
| df.to_excel(writer, sheet_name=key_name, index=False) | |
| excel_buffer.seek(0) | |
| st.download_button( | |
| label="Download Embeddings in PCA Space", | |
| data=excel_buffer, | |
| file_name=f"df_all_pca_{model_name.lower()}.xlsx", | |
| mime="application/vnd.openxmlformats-officedocument.spreadsheetml.sheet", | |
| key=f"download_pca_coordinates_{model_name}" | |
| ) | |
| elif reduction_method == "t-SNE": | |
| st.markdown("## t-SNE - Solo Muestras Reales") | |
| # ------------------------------------------------------------------------- | |
| # 1. t-SNE sobre las muestras reales | |
| df_real_only = embeddings["real"].copy() | |
| reducer_real = TSNE(n_components=2, perplexity=30, random_state=42) | |
| reduced_real = reducer_real.fit_transform(df_real_only[embedding_cols].values) | |
| # Agregar columnas TSNE1, TSNE2 | |
| df_real_only['TSNE1'] = reduced_real[:, 0] | |
| df_real_only['TSNE2'] = reduced_real[:, 1] | |
| # Construir df_all de forma consistente con PCA | |
| df_all = {} | |
| df_all["real"] = df_real_only.copy() | |
| if "synthetic" in embeddings: | |
| df_all["synthetic"] = embeddings["synthetic"].copy() | |
| if "pretrained" in embeddings: | |
| df_all["pretrained"] = embeddings["pretrained"].copy() | |
| unique_labels_real = sorted(df_real_only['label'].unique().tolist()) | |
| # Mapeo de colores para las muestras reales usando la paleta Reds9 | |
| num_labels = len(unique_labels_real) | |
| if num_labels <= 9: | |
| red_palette = Reds9[:num_labels] | |
| else: | |
| red_palette = (Reds9 * ((num_labels // 9) + 1))[:num_labels] | |
| real_color_mapping = {label: red_palette[i] for i, label in enumerate(unique_labels_real)} | |
| # ------------------------------------------------------------------------- | |
| # Crear plot interactivo con Bokeh | |
| st.subheader("t-SNE - Real: Visualización Interactiva") | |
| source = ColumnDataSource(df_real_only) | |
| hover = HoverTool(tooltips=[ | |
| ("Index", "$index"), | |
| ("Label", "@label"), | |
| ("TSNE1", "@TSNE1"), | |
| ("TSNE2", "@TSNE2") | |
| ]) | |
| p = figure( | |
| width=800, | |
| height=600, | |
| title="t-SNE sobre muestras reales", | |
| tools=["pan", "wheel_zoom", "box_zoom", "reset", hover] | |
| ) | |
| for label in unique_labels_real: | |
| subset = df_real_only[df_real_only['label'] == label] | |
| p.scatter( | |
| x=subset["TSNE1"], | |
| y=subset["TSNE2"], | |
| size=8, | |
| color=real_color_mapping[label], | |
| alpha=0.7, | |
| legend_label=str(label) | |
| ) | |
| p.legend.title = "Label" | |
| p.legend.location = "top_right" | |
| p.xaxis.axis_label = "t-SNE 1" | |
| p.yaxis.axis_label = "t-SNE 2" | |
| st.bokeh_chart(p, use_container_width=True) | |
| # ------------------------------------------------------------------------- | |
| # BLOQUE: Heatmap de Características (adaptado a TSNE1 y TSNE2) | |
| st.markdown("## Heatmap de Características") | |
| try: | |
| df_heat = pd.read_csv(f"data/heatmaps_{model_name.lower()}.csv") | |
| except Exception as e: | |
| st.error(f"Error al cargar heatmaps.csv: {e}") | |
| df_heat = None | |
| if df_heat is not None: | |
| if 'img' not in df_all["real"].columns: | |
| st.error("La columna 'img' no se encuentra en las muestras reales para hacer el merge con heatmaps.csv.") | |
| else: | |
| # Crear columna 'name' en las muestras reales (si aún no existe) | |
| df_all["real"]["name"] = df_all["real"]["img"].apply( | |
| lambda x: x.split("/")[-1].replace(".png", "") if isinstance(x, str) else x | |
| ) | |
| # Merge con heatmaps.csv | |
| df_heatmap_base = pd.merge(df_all["real"], df_heat, on="name", how="inner") | |
| # Opciones de features | |
| feature_options = [col for col in df_heat.columns if col != "name"] | |
| selected_feature = st.selectbox("Select heatmap feature:", | |
| options=feature_options, key=f"heatmap_{model_name}") | |
| select_extra_dataset_hm = st.selectbox("Select a dataset:", | |
| options=model_options_with_default, key=f"heatmap_extra_dataset_{model_name}") | |
| # Solo una combinación: TSNE1 vs TSNE2 | |
| x_comp, y_comp = "TSNE1", "TSNE2" | |
| st.markdown(f"### Heatmap: {x_comp} vs {y_comp}") | |
| # Rango real de los datos | |
| df_heatmap = df_heatmap_base.copy() | |
| # Rango real de los datos | |
| x_min, x_max = df_heatmap[x_comp].min(), df_heatmap[x_comp].max() | |
| y_min, y_max = df_heatmap[y_comp].min(), df_heatmap[y_comp].max() | |
| # Opcional: ampliar un poco | |
| padding = 0.05 | |
| x_min, x_max = x_min - padding, x_max + padding | |
| y_min, y_max = y_min - padding, y_max + padding | |
| # Definir rejilla | |
| grid_size = st.slider("Grid size (resolución del heatmap)", min_value=10, max_value=100, value=40, step=5, key=f"grid_size_{model_name}") | |
| x_bins = np.linspace(x_min, x_max, grid_size + 1) | |
| y_bins = np.linspace(y_min, y_max, grid_size + 1) | |
| # Usar los mismos valores para figure y image | |
| x_range, y_range = (x_min, x_max), (y_min, y_max) | |
| df_heatmap["x"] = df_heatmap[x_comp] | |
| df_heatmap["y"] = df_heatmap[y_comp] | |
| df_heatmap['x'] = np.nan_to_num(df_heatmap['x'], nan=0.0, posinf=0.0, neginf=0.0) | |
| df_heatmap['y'] = np.nan_to_num(df_heatmap['y'], nan=0.0, posinf=0.0, neginf=0.0) | |
| # Si la feature seleccionada no es numérica, convertir | |
| cat_mapping = None | |
| if df_heatmap[selected_feature].dtype == bool or not pd.api.types.is_numeric_dtype(df_heatmap[selected_feature]): | |
| cat = df_heatmap[selected_feature].astype('category') | |
| cat_mapping = list(cat.cat.categories) | |
| df_heatmap[selected_feature] = cat.cat.codes | |
| # Calcular estadística binned | |
| heat_stat, x_edges, y_edges, binnumber = binned_statistic_2d( | |
| df_heatmap['x'], df_heatmap['y'], df_heatmap[selected_feature], | |
| statistic='mean', bins=[x_bins, y_bins] | |
| ) | |
| # Mantener NaN para celdas vacías | |
| heatmap_data = heat_stat.T | |
| cmap = plt.get_cmap("RdYlGn") | |
| red_green_palette = [mcolors.rgb2hex(cmap(i)) for i in np.linspace(0, 1, 256)] | |
| # Color mapper | |
| if selected_feature in model_options: | |
| color_mapper = LinearColorMapper( | |
| palette=red_green_palette, | |
| low=0, | |
| high=1, | |
| nan_color="white" | |
| ) | |
| else: | |
| color_mapper = LinearColorMapper( | |
| palette="Viridis256", | |
| low=np.nanmin(heatmap_data), | |
| high=np.nanmax(heatmap_data), | |
| nan_color="white" | |
| ) | |
| # Figura heatmap | |
| heatmap_fig = figure(title=f"Heatmap de '{selected_feature}' ({x_comp} vs {y_comp})", | |
| x_range=x_range, y_range=y_range, | |
| width=600, height=600, | |
| tools="pan,wheel_zoom,reset,save", active_scroll="wheel_zoom", tooltips=TOOLTIPS, | |
| sizing_mode="fixed") | |
| heatmap_fig.match_aspect = True | |
| heatmap_fig.xaxis.axis_label = x_comp | |
| heatmap_fig.yaxis.axis_label = y_comp | |
| heatmap_fig.image(image=[heatmap_data], x=x_min, y=y_min, | |
| dw=x_max - x_min, dh=y_max - y_min, | |
| color_mapper=color_mapper) | |
| # Barra de color | |
| color_bar = ColorBar(color_mapper=color_mapper, location=(0, 0)) | |
| if cat_mapping is not None: | |
| ticks = list(range(len(cat_mapping))) | |
| color_bar.ticker = FixedTicker(ticks=ticks) | |
| categories_json = json.dumps(cat_mapping) | |
| color_bar.formatter = FuncTickFormatter(code=f""" | |
| var categories = {categories_json}; | |
| var index = Math.round(tick); | |
| if(index >= 0 && index < categories.length) {{ | |
| return categories[index]; | |
| }} else {{ | |
| return ""; | |
| }} | |
| """) | |
| heatmap_fig.add_layout(color_bar, 'right') | |
| heatmap_fig.background_fill_color = "white" | |
| heatmap_fig.border_fill_color = "white" | |
| # Tooltips | |
| source_points = ColumnDataSource(data={ | |
| 'x': df_heatmap['x'], | |
| 'y': df_heatmap['y'], | |
| 'img': df_heatmap['img'], | |
| 'label': df_heatmap['name'] | |
| }) | |
| invisible_renderer = heatmap_fig.circle('x', 'y', size=10, source=source_points, fill_alpha=0, line_alpha=0.5) | |
| # if select_extra_dataset_hm != "-": | |
| # df_extra = df_all["synthetic"][df_all["synthetic"]["source"] == select_extra_dataset_hm].copy() | |
| # df_extra["x"] = df_extra[x_comp] | |
| # df_extra["y"] = df_extra[y_comp] | |
| # if 'name' not in df_extra.columns: | |
| # df_extra["name"] = df_extra["img"].apply(lambda x: x.split("/")[-1].replace(".png", "") if isinstance(x, str) else x) | |
| # source_extra_points = ColumnDataSource(data={ | |
| # 'x': df_extra['x'], | |
| # 'y': df_extra['y'], | |
| # 'img': df_extra['img'], | |
| # 'label': df_extra['name'] | |
| # }) | |
| # heatmap_fig.circle('x', 'y', size=5, source=source_extra_points, fill_alpha=0, line_alpha=0.5, color="purple") | |
| hover_tool_points = HoverTool(renderers=[invisible_renderer], tooltips=TOOLTIPS) | |
| heatmap_fig.add_tools(hover_tool_points) | |
| st.bokeh_chart(heatmap_fig) | |
| # ------------------------------------------------------------------------- | |
| # Botón para descargar df_all (Embeddings en t-SNE Space) | |
| if st.button("Download Embeddings in t-SNE Space", key=f"click_download_tsne_coordinates_{model_name}"): | |
| df_all_tsne = {} | |
| for key, df in df_all.items(): | |
| if key == "synthetic": | |
| for source in df["source"].unique(): | |
| df_subset = df[df["source"] == source].copy() | |
| if "img" in df_subset.columns and "name" not in df_subset.columns: | |
| df_subset["name"] = df_subset["img"].apply(lambda x: x.split("/")[-1].replace(".png", "") if isinstance(x, str) else x) | |
| tsne_cols = [col for col in df_subset.columns if col.startswith("TSNE") or col == "name"] | |
| sheet_name = f"synthetic_{source}" | |
| df_all_tsne[sheet_name] = df_subset[tsne_cols].copy() | |
| else: | |
| tsne_cols = [col for col in df.columns if col.startswith("TSNE") or col == "name"] | |
| df_all_tsne[key] = df[tsne_cols].copy() | |
| excel_buffer = io.BytesIO() | |
| with pd.ExcelWriter(excel_buffer, engine='openpyxl') as writer: | |
| for key_name, df in df_all_tsne.items(): | |
| df.to_excel(writer, sheet_name=key_name, index=False) | |
| excel_buffer.seek(0) | |
| st.download_button( | |
| label="Download Embeddings in t-SNE Space", | |
| data=excel_buffer, | |
| file_name=f"df_all_tsne_{model_name.lower()}.xlsx", | |
| mime="application/vnd.openxmlformats-officedocument.spreadsheetml.sheet", | |
| key=f"download_tsne_coordinates_{model_name}" | |
| ) | |
| def main(): | |
| config_style() | |
| tabs = st.tabs(["Donut", "Idefics2", "Idefics2-patient", "Paligemma", "Llava"]) | |
| with tabs[0]: | |
| st.markdown('<h2 class="sub-title">Donut 🤗</h2>', unsafe_allow_html=True) | |
| run_model("Donut") | |
| with tabs[1]: | |
| st.markdown('<h2 class="sub-title">Idefics2 🤗</h2>', unsafe_allow_html=True) | |
| run_model("Idefics2") | |
| with tabs[2]: | |
| st.markdown('<h2 class="sub-title">Idefics2-patient 🤗</h2>', unsafe_allow_html=True) | |
| run_model("Idefics2-patient") | |
| with tabs[3]: | |
| st.markdown('<h2 class="sub-title">Paligemma 🤗</h2>', unsafe_allow_html=True) | |
| run_model("Paligemma") | |
| with tabs[4]: | |
| st.markdown('<h2 class="sub-title">Llava 🤗</h2>', unsafe_allow_html=True) | |
| run_model("Llava") | |
| if __name__ == "__main__": | |
| model_options = [ | |
| "es-digital-paragraph-degradation-seq", | |
| "es-digital-line-degradation-seq", | |
| "es-digital-seq", | |
| "es-digital-noisy-degradation-seq", | |
| "es-digital-seq_es-digital-seq_britanico", | |
| "es-digital-seq_retamar_train-asc-synth", | |
| "es-digital-seq_britanico_es-digital-seq_aletamar", | |
| "es-digital-seq_retamar_train-asc-synth_es-digital-seq_britanico", | |
| "es-digital-seq_retamar_train-asc-synth_es-digital-seq_britanico_v2", | |
| "es-digital-seq_es-digital-seq_aletamar", | |
| "retamar_train-asc-synth_es-digital-seq_britanico", | |
| "es-digital-rotation-degradation-seq", | |
| "es-digital-zoom-degradation-seq", | |
| "es-render-seq", | |
| "es-digital-seq_filtered_deus", | |
| "es-digital-seq_filtered_liceo", | |
| "es-digital-seq_filtered_lusitano", | |
| "es-digital-seq_filtered_monterraso", | |
| "es-digital-seq_filtered_patria", | |
| "es-digital-zoom-0.25-degradation-seq_filtered_deus-liceo-lusitano-monterraso-patria-frozen-encoder", | |
| "es-digital-zoom-0.5-degradation-seq_filtered_deus-liceo-lusitano-monterraso-patria-frozen-encoder", | |
| "es-digital-zoom-0.625-degradation-seq_filtered_deus-liceo-lusitano-monterraso-patria-frozen-encoder", | |
| "es-digital-zoom-0.75-degradation-seq_filtered_deus-liceo-lusitano-monterraso-patria-frozen-encoder", | |
| "es-digital-seq_filtered_deus-liceo-lusitano-monterraso-patria-frozen-encoder", | |
| "es-digital-zoom-degradation-seq_filtered_deus-liceo-lusitano-monterraso-patria-frozen-encoder", | |
| "es-render-seq_filtered_deus-liceo-lusitano-monterraso-patria-frozen-encoder-017", | |
| "es-render-seq_filtered_deus-liceo-lusitano-monterraso-patria-frozen-encoder-016", | |
| "es-digital-rotation-degradation-seq_filtered_deus-liceo-lusitano-monterraso-patria-frozen-encoder", | |
| "retamar_train-asc-synth_filtered_retamar_train-frozen-encoder", | |
| "britanico-retamar_train-asc-synth_filtered_retamar_train-frozen-encoder", | |
| "combination-es-digital-seq", | |
| "combination-es-render-seq", | |
| "retamar_train-asc-synth_es-digital-seq_britanico", | |
| ] | |
| model_options_with_default = [""] | |
| model_options_with_default.extend(model_options) | |
| main() | |