| |
| |
| |
| |
| |
| |
| |
| |
| |
| |
| |
| |
|
|
| import os, json, warnings |
| import pandas as pd |
| import numpy as np |
| import matplotlib |
| matplotlib.use("Agg") |
| import matplotlib.pyplot as plt |
| import matplotlib.patches as mpatches |
| import matplotlib.cm as cm |
| import seaborn as sns |
| import squarify |
|
|
| warnings.filterwarnings("ignore") |
|
|
| RESULTS_DIR = "./results" |
| PLOT_DIR = f"{RESULTS_DIR}/analysis_plots" |
| os.makedirs(PLOT_DIR, exist_ok=True) |
|
|
| plt.rcParams.update({ |
| "figure.dpi": 150, |
| "savefig.bbox": "tight", |
| "savefig.pad_inches": 0.25, |
| "font.size": 11, |
| "axes.titlesize": 13, |
| "axes.titleweight": "bold", |
| "axes.spines.top": False, |
| "axes.spines.right": False, |
| }) |
| PALETTE = sns.color_palette("tab10") |
|
|
| |
| df_all = pd.read_csv(f"{RESULTS_DIR}/all_features.csv") |
| df_sel = pd.read_csv(f"{RESULTS_DIR}/selectivity_live.csv") |
| df_hc = pd.read_csv(f"{RESULTS_DIR}/high_confidence_features.csv") |
| df_neg = pd.read_csv(f"{RESULTS_DIR}/negative_bias_features.csv") |
| df_sum = pd.read_csv(f"{RESULTS_DIR}/concept_summary.csv") |
| df_cf = pd.read_csv(f"{RESULTS_DIR}/counterfactual_delta.csv") |
|
|
| |
| for df in [df_all, df_sel, df_hc, df_neg, df_sum, df_cf]: |
| df.columns = df.columns.str.strip() |
|
|
| for col in ["bias_direction", "inferred_axis", "demographic_group", "axis"]: |
| for df in [df_all, df_sel, df_hc, df_neg]: |
| if col in df.columns: |
| df[col] = df[col].str.strip().str.lower() |
|
|
| print(f"all={len(df_all)} sel={len(df_sel)} hc={len(df_hc)}" |
| f" neg={len(df_neg)} cf={len(df_cf)}") |
|
|
|
|
| |
| |
| |
| |
| df_dir = (df_hc[df_hc["inferred_axis"] != "none"] |
| .groupby(["inferred_axis", "bias_direction"]) |
| .size().reset_index(name="count")) |
| df_dir["pct"] = df_dir.groupby("inferred_axis")["count"] \ |
| .transform(lambda x: x / x.sum() * 100) |
|
|
| pivot_dir = (df_dir.pivot_table(index="inferred_axis", columns="bias_direction", |
| values="pct", aggfunc="sum") |
| .reindex(columns=["positive", "neutral", "negative"], fill_value=0)) |
|
|
| fig, ax = plt.subplots(figsize=(9, 5)) |
| bar_colors = {"positive": "#2ecc71", "neutral": "#95a5a6", "negative": "#e74c3c"} |
| bottom = np.zeros(len(pivot_dir)) |
| for direction in ["positive", "neutral", "negative"]: |
| vals = pivot_dir.get(direction, pd.Series(0, index=pivot_dir.index)).values |
| bars = ax.bar(pivot_dir.index, vals, bottom=bottom, |
| label=direction, color=bar_colors[direction]) |
| for bar, v in zip(bars, vals): |
| if v > 5: |
| ax.text(bar.get_x() + bar.get_width() / 2, |
| bar.get_y() + bar.get_height() / 2, |
| f"{v:.1f}%", ha="center", va="center", |
| fontsize=9, color="white", fontweight="bold") |
| bottom += vals |
|
|
| ax.set_xlabel("Bias Axis"); ax.set_ylabel("% of Features") |
| ax.set_title("Bias Direction Distribution per Axis\n" |
| "% of high-confidence features labelled by VLM") |
| ax.legend(loc="upper right", frameon=False) |
| plt.tight_layout() |
| plt.savefig(f"{PLOT_DIR}/01_bias_direction_by_axis.png") |
| plt.close(); print("Plot 1 saved") |
|
|
|
|
| |
| |
| |
| |
| df_ads = df_sel[df_sel["axis"] != "counterfactual"].copy() |
| axes_sorted = (df_ads.groupby("axis")["ADS"].median() |
| .sort_values(ascending=False).index.tolist()) |
| data_boxes = [df_ads[df_ads["axis"] == a]["ADS"].dropna().values |
| for a in axes_sorted] |
|
|
| fig, ax = plt.subplots(figsize=(10, 5)) |
| bp = ax.boxplot(data_boxes, patch_artist=True, |
| flierprops=dict(marker="o", markersize=3, alpha=0.4), |
| medianprops=dict(color="black", linewidth=2)) |
| for patch, color in zip(bp["boxes"], PALETTE): |
| patch.set_facecolor(color); patch.set_alpha(0.75) |
| ax.set_xticks(range(1, len(axes_sorted) + 1)) |
| ax.set_xticklabels(axes_sorted, rotation=20, ha="right") |
| ax.set_xlabel("Bias Axis"); ax.set_ylabel("ADS") |
| ax.set_title("ADS Distribution per Bias Axis\n" |
| "Activation Discriminativity Score (activator vs control)") |
| ax.axhline(0.05, color="grey", linestyle="--", linewidth=1, label="threshold 0.05") |
| ax.legend(frameon=False) |
| plt.tight_layout() |
| plt.savefig(f"{PLOT_DIR}/02_ADS_distribution_per_axis.png") |
| plt.close(); print("Plot 2 saved") |
|
|
|
|
| |
| |
| |
| |
| top20 = df_hc.nlargest(20, "ADS").copy() |
| top20["label"] = (top20["final_concept"].str[:36] |
| + " [" + top20["group_label"].str[:14] + "]") |
| axis_color_map = { |
| "gender": "#3498db", "caste_class": "#e74c3c", |
| "religion": "#9b59b6", "region": "#f39c12", |
| "skin_tone": "#1abc9c", "occupation": "#e67e22", |
| "counterfactual": "#95a5a6" |
| } |
| bar_c = [axis_color_map.get(a, "#7f8c8d") for a in top20["inferred_axis"]] |
|
|
| fig, ax = plt.subplots(figsize=(12, 9)) |
| y_pos = list(range(len(top20))) |
| ax.barh(y_pos, top20["ADS"].values, color=bar_c, alpha=0.85) |
| ax.set_yticks(y_pos) |
| ax.set_yticklabels(top20["label"].values, fontsize=9) |
| ax.invert_yaxis() |
| ax.set_xlabel("ADS Score"); ax.set_ylabel("Feature Concept") |
| ax.set_title("Top-20 High-Confidence Bias Features by ADS\n" |
| "ADS β₯ 0.05 & selectivity_ratio β₯ 1.3") |
| for v, pos in zip(top20["ADS"].values, y_pos): |
| ax.text(v + 0.001, pos, f"{v:.3f}", va="center", fontsize=8) |
| legend_patches = [mpatches.Patch(color=c, label=a) |
| for a, c in axis_color_map.items() |
| if a in top20["inferred_axis"].values] |
| ax.legend(handles=legend_patches, loc="lower right", frameon=False, fontsize=9) |
| plt.tight_layout() |
| plt.savefig(f"{PLOT_DIR}/03_top20_hc_features.png") |
| plt.close(); print("Plot 3 saved") |
|
|
|
|
| |
| |
| |
| |
| total_per_axis = (df_hc[df_hc["inferred_axis"] != "none"] |
| .groupby("inferred_axis").size()) |
| neg_per_axis = df_neg.groupby("inferred_axis").size() |
| neg_rate = (neg_per_axis / total_per_axis * 100).dropna().reset_index() |
| neg_rate.columns = ["axis", "neg_rate"] |
| neg_rate = neg_rate.sort_values("neg_rate", ascending=False) |
|
|
| norm = plt.Normalize(neg_rate["neg_rate"].min(), neg_rate["neg_rate"].max()) |
| bar_c4 = [cm.Reds(norm(v)) for v in neg_rate["neg_rate"]] |
|
|
| fig, ax = plt.subplots(figsize=(9, 5)) |
| bars = ax.bar(neg_rate["axis"], neg_rate["neg_rate"], color=bar_c4) |
| for bar, v in zip(bars, neg_rate["neg_rate"]): |
| ax.text(bar.get_x() + bar.get_width() / 2, |
| bar.get_height() + 0.4, f"{v:.1f}%", |
| ha="center", va="bottom", fontsize=10) |
| ax.set_xlabel("Bias Axis"); ax.set_ylabel("Negative Rate (%)") |
| ax.set_title("Negative Stereotype Rate per Bias Axis\n" |
| "% of features labelled 'negative' by VLM") |
| plt.tight_layout() |
| plt.savefig(f"{PLOT_DIR}/04_negative_rate_per_axis.png") |
| plt.close(); print("Plot 4 saved") |
|
|
|
|
| |
| |
| |
| |
| df_cf_ads = df_sel[df_sel["axis"] == "counterfactual"].copy() |
| if not df_cf_ads.empty: |
| top_feats = (df_cf_ads.groupby("feature")["ADS"].max() |
| .nlargest(15).index.tolist()) |
| pivot = (df_cf_ads[df_cf_ads["feature"].isin(top_feats)] |
| .pivot_table(index="group_label", columns="feature", |
| values="ADS", aggfunc="mean").fillna(0)) |
| pivot.columns = [f"F{c}" for c in pivot.columns] |
|
|
| fig, ax = plt.subplots(figsize=(12, max(4, len(pivot) * 0.55))) |
| sns.heatmap(pivot, ax=ax, cmap="RdBu_r", center=0, |
| vmin=-0.2, vmax=0.2, annot=True, fmt=".2f", |
| linewidths=0.4, cbar_kws={"label": "ADS"}) |
| ax.set_xlabel("Feature Index"); ax.set_ylabel("Counterfactual Pair") |
| ax.set_title("Counterfactual ADS Heatmap\n" |
| "Red = group A fires more | Blue = group B fires more") |
| plt.tight_layout() |
| plt.savefig(f"{PLOT_DIR}/05_counterfactual_heatmap.png") |
| plt.close(); print("Plot 5 saved") |
| else: |
| print("Plot 5 skipped β no counterfactual rows in df_sel") |
|
|
|
|
| |
| |
| |
| |
| code_col = "code" if "code" in df_all.columns else "split" |
| df_act = (df_all[df_all["source"] == "activator"] |
| .groupby(["split", code_col])["mean_activation"] |
| .mean().reset_index()) |
| df_act["split_short"] = (df_act["split"] |
| .str.replace("_activator", "", regex=False) |
| .str.replace("_", " ")) |
|
|
| codes = df_act[code_col].unique() |
| groups = df_act["split_short"].unique() |
| x = np.arange(len(groups)) |
| width = 0.8 / max(len(codes), 1) |
|
|
| fig, ax = plt.subplots(figsize=(13, 5)) |
| for i, code in enumerate(codes): |
| sub = df_act[df_act[code_col] == code].set_index("split_short") |
| vals = [float(sub.loc[g, "mean_activation"]) |
| if g in sub.index else 0.0 for g in groups] |
| offset = (i - len(codes) / 2 + 0.5) * width |
| ax.bar(x + offset, vals, width=width * 0.9, label=str(code), alpha=0.85) |
|
|
| ax.set_xticks(x) |
| ax.set_xticklabels(groups, rotation=35, ha="right", fontsize=9) |
| ax.set_xlabel("Social Group"); ax.set_ylabel("Mean Activation") |
| ax.set_title("Mean SAE Activation per Group per Block\n" |
| "Activator prompts β down.2.1 vs up.0.1") |
| ax.legend(frameon=False, title="Block") |
| plt.tight_layout() |
| plt.savefig(f"{PLOT_DIR}/06_mean_activation_per_group.png") |
| plt.close(); print("Plot 6 saved") |
|
|
|
|
| |
| |
| |
| |
| df_demo = (df_hc.groupby(["inferred_axis", "group_label"]) |
| .size().reset_index(name="count") |
| .sort_values(["inferred_axis", "count"], ascending=[True, False])) |
| axes_uniq = df_demo["inferred_axis"].unique() |
|
|
| fig, axes_arr = plt.subplots(1, len(axes_uniq), |
| figsize=(4.5 * len(axes_uniq), 5), sharey=False) |
| if len(axes_uniq) == 1: |
| axes_arr = [axes_arr] |
|
|
| for i, (axis_name, grp) in enumerate(df_demo.groupby("inferred_axis")): |
| ax = axes_arr[i] |
| ax.barh(grp["group_label"], grp["count"], |
| color=PALETTE[i % len(PALETTE)], alpha=0.82) |
| ax.invert_yaxis() |
| ax.set_title(axis_name, fontsize=10, fontweight="bold") |
| ax.set_xlabel("Feature Count") |
| ax.tick_params(axis="y", labelsize=8) |
|
|
| fig.suptitle("High-Confidence Features per Demographic Group", |
| fontsize=13, fontweight="bold") |
| plt.tight_layout() |
| plt.savefig(f"{PLOT_DIR}/07_features_per_demo_group.png") |
| plt.close(); print("Plot 7 saved") |
|
|
|
|
| |
| |
| |
| |
| df_scat = df_sel[(df_sel["axis"] != "counterfactual") |
| & (df_sel["ADS"] > 0)].copy() |
| df_scat = df_scat.sample(min(2000, len(df_scat)), random_state=42) |
| axes_u = df_scat["axis"].unique() |
| cmap_s = {a: PALETTE[i % len(PALETTE)] for i, a in enumerate(axes_u)} |
|
|
| fig, ax = plt.subplots(figsize=(9, 6)) |
| for axis_name, grp in df_scat.groupby("axis"): |
| ax.scatter(grp["ADS"], grp["selectivity_ratio"], |
| color=cmap_s[axis_name], alpha=0.4, s=20, label=axis_name) |
| ax.axhline(1.3, color="grey", linestyle="--", linewidth=1) |
| ax.axvline(0.05, color="grey", linestyle="--", linewidth=1) |
| ax.text(0.052, ax.get_ylim()[1] * 0.97, "ADS=0.05", fontsize=8, color="grey") |
| ax.text(df_scat["ADS"].min(), 1.32, "ratio=1.3", fontsize=8, color="grey") |
| ax.set_xlabel("ADS"); ax.set_ylabel("Selectivity Ratio") |
| ax.set_title("ADS vs Selectivity Ratio per Feature\n" |
| "Top-right = most discriminative bias features") |
| ax.legend(frameon=False, markerscale=2, fontsize=9) |
| plt.tight_layout() |
| plt.savefig(f"{PLOT_DIR}/08_scatter_ADS_vs_selectivity.png") |
| plt.close(); print("Plot 8 saved") |
|
|
|
|
| |
| |
| |
| |
| if "A" in df_cf.columns and "B" in df_cf.columns: |
| df_cf["delta_AB"] = pd.to_numeric(df_cf["A"], errors="coerce") \ |
| - pd.to_numeric(df_cf["B"], errors="coerce") |
| top_cf = df_cf.reindex( |
| df_cf["delta_AB"].abs().nlargest(20).index).copy() |
| top_cf["label"] = ("F" + top_cf["feature"].astype(str) |
| + " | " + top_cf["split"].str[:22]) |
| bar_c9 = ["#3498db" if v > 0 else "#e74c3c" |
| for v in top_cf["delta_AB"]] |
|
|
| fig, ax = plt.subplots(figsize=(11, 8)) |
| y_pos = list(range(len(top_cf))) |
| ax.barh(y_pos, top_cf["delta_AB"].values, color=bar_c9, alpha=0.85) |
| ax.set_yticks(y_pos) |
| ax.set_yticklabels(top_cf["label"].values, fontsize=9) |
| ax.invert_yaxis() |
| ax.axvline(0, color="black", linewidth=1) |
| ax.set_xlabel("Delta (AβB)") |
| ax.set_title("Counterfactual Delta (AβB) per Feature\n" |
| "Blue = group A fires more | Red = group B fires more") |
| ax.legend(handles=[ |
| mpatches.Patch(color="#3498db", label="Group A > Group B"), |
| mpatches.Patch(color="#e74c3c", label="Group B > Group A") |
| ], frameon=False) |
| plt.tight_layout() |
| plt.savefig(f"{PLOT_DIR}/09_counterfactual_delta_bar.png") |
| plt.close(); print("Plot 9 saved") |
| else: |
| print("Plot 9 skipped β A/B columns not found in counterfactual_delta.csv") |
|
|
|
|
| |
| |
| |
| |
| df_tree = df_sum.copy() |
| df_tree["count"] = pd.to_numeric(df_tree["count"], errors="coerce").fillna(1) |
| df_tree["mean_act"] = pd.to_numeric(df_tree["mean_act"], errors="coerce").fillna(0) |
| df_tree = df_tree.nlargest(40, "mean_act") |
| df_tree["label"] = df_tree["final_concept"].str[:28] |
|
|
| norm10 = plt.Normalize(df_tree["mean_act"].min(), df_tree["mean_act"].max()) |
| t_colors = [cm.Oranges(norm10(v)) for v in df_tree["mean_act"]] |
|
|
| fig, ax = plt.subplots(figsize=(14, 8)) |
| squarify.plot(sizes=df_tree["count"].values, |
| label=df_tree["label"].values, |
| color=t_colors, alpha=0.85, ax=ax, |
| text_kwargs={"fontsize": 7}) |
| ax.axis("off") |
| ax.set_title("Top Feature Concepts by Bias Direction\n" |
| "Size = frequency | Color = mean activation (darker = higher)", |
| fontsize=12, fontweight="bold") |
| sm = cm.ScalarMappable(cmap="Oranges", norm=norm10) |
| sm.set_array([]) |
| plt.colorbar(sm, ax=ax, shrink=0.6, label="Mean Activation") |
| plt.tight_layout() |
| plt.savefig(f"{PLOT_DIR}/10_concept_treemap.png") |
| plt.close(); print("Plot 10 saved") |
|
|
| print(f"\nβ All 10 plots saved β {PLOT_DIR}") |