| """ |
| pca_all_layers.py β Generate 2D and 3D PCA plots for ALL layers from existing NPZ files. |
| |
| For each results/{model}/npz/vectors_{scale}.npz, produces: |
| results/{model}/plots/all/pca/pca_{scale}_L{layer}.png (2D, 3-panel) |
| results/{model}/plots/all/pca_3d/pca_{scale}_L{layer}.png (3D, 3-panel) |
| |
| for every layer stored in the NPZ. |
| |
| NOTE: NPZ files must have all layers saved. If you only see 5 representative layers in |
| existing results, re-run the main pipeline β save_vectors_npz() now saves all layers. |
| |
| Usage: |
| python pca_all_layers.py # all models, all scales |
| python pca_all_layers.py --model qwen # one model, all scales |
| python pca_all_layers.py --model qwen --scale vanilla # one model, one scale |
| python pca_all_layers.py --overwrite # regenerate existing plots |
| """ |
|
|
| import argparse |
| import os |
| import re |
|
|
| import matplotlib |
| matplotlib.use('Agg') |
| import matplotlib.pyplot as plt |
| from mpl_toolkits.mplot3d import Axes3D |
| import numpy as np |
| from sklearn.decomposition import PCA |
|
|
| |
| |
| |
|
|
| RESULTS_DIR = os.path.join(os.path.dirname(__file__), 'results') |
|
|
| CATEGORY_ORDER = ['left', 'right', 'above', 'under', 'far', 'close'] |
| GROUP_ORDER = ['horizontal', 'vertical', 'distance'] |
|
|
| CAT_COLORS = { |
| 'left': '#ff7f0e', 'right': '#ffbb78', |
| 'above': '#2ca02c', 'under': '#98df8a', |
| 'far': '#9467bd', 'close': '#c5b0d5', |
| } |
| GROUP_COLORS = { |
| 'horizontal': '#ff7f0e', |
| 'vertical': '#2ca02c', |
| 'distance': '#9467bd', |
| } |
|
|
|
|
| |
| |
| |
|
|
| def _plot_2d(data, layer, scale, model, save_path): |
| orig = data.get(f'orig_L{layer}') |
| swap = data.get(f'swap_L{layer}') |
| labels = data.get(f'labels_L{layer}') |
| deltas = data.get(f'delta_L{layer}') |
| cats = data.get(f'categories_L{layer}') |
| groups = data.get(f'groups_L{layer}') |
|
|
| if orig is None or swap is None: |
| return False |
|
|
| fig, axes = plt.subplots(1, 3, figsize=(24, 7)) |
|
|
| |
| pca_emb = PCA(n_components=2) |
| all_proj = pca_emb.fit_transform(np.vstack([orig, swap])) |
| orig_proj = all_proj[:len(orig)] |
| swap_proj = all_proj[len(orig):] |
| ev = pca_emb.explained_variance_ratio_ |
|
|
| ax = axes[0] |
| for cat in CATEGORY_ORDER: |
| mask = np.array([str(l) == cat for l in labels]) |
| if mask.any(): |
| ax.scatter(orig_proj[mask, 0], orig_proj[mask, 1], |
| c=CAT_COLORS.get(cat, 'gray'), label=f'{cat} (orig)', |
| alpha=0.5, s=15, marker='o') |
| ax.scatter(swap_proj[mask, 0], swap_proj[mask, 1], |
| c=CAT_COLORS.get(cat, 'gray'), |
| alpha=0.5, s=15, marker='x') |
| ax.set_title('Embeddings by Category\n(o=orig, x=swap)', fontsize=11) |
| ax.set_xlabel(f'PC1 ({ev[0]:.1%})', fontsize=9) |
| ax.set_ylabel(f'PC2 ({ev[1]:.1%})', fontsize=9) |
| ax.legend(fontsize=7, ncol=2) |
| ax.grid(True, alpha=0.2) |
|
|
| |
| has_delta = deltas is not None and cats is not None and len(deltas) >= 2 |
| if has_delta: |
| pca_d = PCA(n_components=2) |
| delta_proj = pca_d.fit_transform(deltas) |
| ev_d = pca_d.explained_variance_ratio_ |
|
|
| ax = axes[1] |
| if has_delta and groups is not None: |
| for group in GROUP_ORDER: |
| mask = np.array([str(g) == group for g in groups]) |
| if mask.any(): |
| ax.scatter(delta_proj[mask, 0], delta_proj[mask, 1], |
| c=GROUP_COLORS.get(group, 'gray'), label=group, |
| alpha=0.5, s=15) |
| ax.set_title('Delta Vectors by Group', fontsize=11) |
| ax.set_xlabel(f'PC1 ({ev_d[0]:.1%})', fontsize=9) |
| ax.set_ylabel(f'PC2 ({ev_d[1]:.1%})', fontsize=9) |
| ax.legend(fontsize=9) |
| ax.grid(True, alpha=0.2) |
| else: |
| ax.set_title('Delta Vectors by Group\n(no data)', fontsize=11) |
|
|
| ax = axes[2] |
| if has_delta and cats is not None: |
| for cat in CATEGORY_ORDER: |
| mask = np.array([str(c) == cat for c in cats]) |
| if mask.any(): |
| ax.scatter(delta_proj[mask, 0], delta_proj[mask, 1], |
| c=CAT_COLORS.get(cat, 'gray'), label=cat, |
| alpha=0.5, s=15) |
| ax.set_title('Delta Vectors by Category', fontsize=11) |
| ax.set_xlabel(f'PC1 ({ev_d[0]:.1%})', fontsize=9) |
| ax.set_ylabel(f'PC2 ({ev_d[1]:.1%})', fontsize=9) |
| ax.legend(fontsize=8, ncol=2) |
| ax.grid(True, alpha=0.2) |
| else: |
| ax.set_title('Delta Vectors by Category\n(no data)', fontsize=11) |
|
|
| fig.suptitle(f'{model.upper()} ({scale}) β Layer {layer} β 2D PCA', fontweight='bold') |
| plt.tight_layout() |
| plt.savefig(save_path, dpi=200, bbox_inches='tight') |
| plt.close() |
| return True |
|
|
|
|
| |
| |
| |
|
|
| def _plot_3d(data, layer, scale, model, save_path): |
| orig = data.get(f'orig_L{layer}') |
| swap = data.get(f'swap_L{layer}') |
| labels = data.get(f'labels_L{layer}') |
| deltas = data.get(f'delta_L{layer}') |
| cats = data.get(f'categories_L{layer}') |
| groups = data.get(f'groups_L{layer}') |
|
|
| if orig is None or swap is None: |
| return False |
|
|
| fig = plt.figure(figsize=(30, 8)) |
|
|
| |
| pca_emb = PCA(n_components=3) |
| all_proj = pca_emb.fit_transform(np.vstack([orig, swap])) |
| orig_proj = all_proj[:len(orig)] |
| swap_proj = all_proj[len(orig):] |
| ev1 = pca_emb.explained_variance_ratio_ |
|
|
| ax1 = fig.add_subplot(131, projection='3d') |
| for cat in CATEGORY_ORDER: |
| mask = np.array([str(l) == cat for l in labels]) |
| if mask.any(): |
| ax1.scatter(orig_proj[mask, 0], orig_proj[mask, 1], orig_proj[mask, 2], |
| c=CAT_COLORS.get(cat, 'gray'), label=f'{cat} (orig)', |
| alpha=0.45, s=12, marker='o') |
| ax1.scatter(swap_proj[mask, 0], swap_proj[mask, 1], swap_proj[mask, 2], |
| c=CAT_COLORS.get(cat, 'gray'), label=f'{cat} (swap)', |
| alpha=0.45, s=12, marker='^') |
| ax1.set_title('Embeddings by Category\n(o=orig, ^=swap)', fontsize=10) |
| ax1.set_xlabel(f'PC1 ({ev1[0]:.1%})', fontsize=8) |
| ax1.set_ylabel(f'PC2 ({ev1[1]:.1%})', fontsize=8) |
| ax1.set_zlabel(f'PC3 ({ev1[2]:.1%})', fontsize=8) |
| ax1.legend(fontsize=6, ncol=2, loc='upper left') |
|
|
| |
| has_delta = deltas is not None and len(deltas) >= 3 |
| if has_delta: |
| pca_d = PCA(n_components=3) |
| delta_proj = pca_d.fit_transform(deltas) |
| ev2 = pca_d.explained_variance_ratio_ |
| else: |
| delta_proj = None |
| ev2 = None |
|
|
| ax2 = fig.add_subplot(132, projection='3d') |
| if has_delta and groups is not None: |
| for group in GROUP_ORDER: |
| mask = np.array([str(g) == group for g in groups]) |
| if mask.any(): |
| ax2.scatter(delta_proj[mask, 0], delta_proj[mask, 1], delta_proj[mask, 2], |
| c=GROUP_COLORS.get(group, 'gray'), label=group, |
| alpha=0.45, s=12) |
| ax2.set_title('Delta Vectors by Group', fontsize=10) |
| ax2.set_xlabel(f'PC1 ({ev2[0]:.1%})', fontsize=8) |
| ax2.set_ylabel(f'PC2 ({ev2[1]:.1%})', fontsize=8) |
| ax2.set_zlabel(f'PC3 ({ev2[2]:.1%})', fontsize=8) |
| ax2.legend(fontsize=8) |
| else: |
| ax2.set_title('Delta Vectors by Group\n(no data)', fontsize=10) |
|
|
| ax3 = fig.add_subplot(133, projection='3d') |
| if has_delta and cats is not None: |
| for cat in CATEGORY_ORDER: |
| mask = np.array([str(c) == cat for c in cats]) |
| if mask.any(): |
| ax3.scatter(delta_proj[mask, 0], delta_proj[mask, 1], delta_proj[mask, 2], |
| c=CAT_COLORS.get(cat, 'gray'), label=cat, |
| alpha=0.45, s=12) |
| ax3.set_title('Delta Vectors by Category', fontsize=10) |
| ax3.set_xlabel(f'PC1 ({ev2[0]:.1%})', fontsize=8) |
| ax3.set_ylabel(f'PC2 ({ev2[1]:.1%})', fontsize=8) |
| ax3.set_zlabel(f'PC3 ({ev2[2]:.1%})', fontsize=8) |
| ax3.legend(fontsize=7, ncol=2) |
| else: |
| ax3.set_title('Delta Vectors by Category\n(no data)', fontsize=10) |
|
|
| fig.suptitle(f'{model.upper()} ({scale}) β Layer {layer} β 3D PCA', fontweight='bold') |
| plt.tight_layout() |
| plt.savefig(save_path, dpi=200, bbox_inches='tight', pad_inches=0.4) |
| plt.close() |
| return True |
|
|
|
|
| |
| |
| |
|
|
| def process_npz(npz_path, scale, model, plots_all_dir, overwrite=False): |
| data = np.load(npz_path, allow_pickle=True) |
| layer_keys = [k for k in data.files if k.startswith('orig_L')] |
| layers = sorted([int(k.replace('orig_L', '')) for k in layer_keys]) |
|
|
| if not layers: |
| print(f' [skip] No orig_L* keys in {npz_path}') |
| return 0 |
|
|
| print(f' [{model}] {scale}: {len(layers)} layers (L{layers[0]}βL{layers[-1]})') |
|
|
| pca_2d_dir = os.path.join(plots_all_dir, 'pca') |
| pca_3d_dir = os.path.join(plots_all_dir, 'pca_3d') |
| os.makedirs(pca_2d_dir, exist_ok=True) |
| os.makedirs(pca_3d_dir, exist_ok=True) |
|
|
| saved = 0 |
| for i, layer in enumerate(layers): |
| path_2d = os.path.join(pca_2d_dir, f'pca_{scale}_L{layer}.png') |
| path_3d = os.path.join(pca_3d_dir, f'pca_{scale}_L{layer}.png') |
|
|
| skip_2d = not overwrite and os.path.exists(path_2d) |
| skip_3d = not overwrite and os.path.exists(path_3d) |
|
|
| if skip_2d and skip_3d: |
| continue |
|
|
| print(f' L{layer:>3} ({i+1}/{len(layers)})', end='\r', flush=True) |
|
|
| if not skip_2d: |
| if _plot_2d(data, layer, scale, model, path_2d): |
| saved += 1 |
|
|
| if not skip_3d: |
| if _plot_3d(data, layer, scale, model, path_3d): |
| saved += 1 |
|
|
| print() |
| return saved |
|
|
|
|
| |
| |
| |
|
|
| def scale_from_name(filename): |
| m = re.match(r'vectors_(.+)\.npz$', filename) |
| return m.group(1) if m else None |
|
|
|
|
| def main(): |
| parser = argparse.ArgumentParser( |
| description='Generate 2D+3D PCA plots for all layers from NPZ files') |
| parser.add_argument('--model', |
| help='Restrict to this model directory (e.g. qwen)') |
| parser.add_argument('--scale', |
| help='Restrict to this scale (e.g. vanilla, 80k)') |
| parser.add_argument('--overwrite', action='store_true', |
| help='Regenerate plots even if they already exist') |
| parser.add_argument('--results-dir', default=RESULTS_DIR, |
| help='Path to results/ directory') |
| args = parser.parse_args() |
|
|
| results_dir = args.results_dir |
| if not os.path.isdir(results_dir): |
| print(f'Results directory not found: {results_dir}') |
| return |
|
|
| model_dirs = sorted( |
| m for m in os.listdir(results_dir) |
| if os.path.isdir(os.path.join(results_dir, m)) |
| ) |
| if args.model: |
| model_dirs = [m for m in model_dirs if m == args.model] |
| if not model_dirs: |
| print(f"Model '{args.model}' not found in {results_dir}") |
| return |
|
|
| total_saved = 0 |
| total_npz = 0 |
|
|
| for model in model_dirs: |
| model_dir = os.path.join(results_dir, model) |
| npz_dir = os.path.join(model_dir, 'npz') |
| plots_all_dir = os.path.join(model_dir, 'plots', 'all') |
|
|
| if not os.path.isdir(npz_dir): |
| print(f'[{model}] no npz/ directory, skipping') |
| continue |
|
|
| npz_files = sorted( |
| f for f in os.listdir(npz_dir) |
| if f.startswith('vectors_') and f.endswith('.npz') |
| ) |
| if args.scale: |
| npz_files = [f for f in npz_files if scale_from_name(f) == args.scale] |
| if not npz_files: |
| print(f'[{model}] no matching NPZ files, skipping') |
| continue |
|
|
| for npz_file in npz_files: |
| scale = scale_from_name(npz_file) |
| if scale is None: |
| continue |
| npz_path = os.path.join(npz_dir, npz_file) |
| os.makedirs(plots_all_dir, exist_ok=True) |
| n = process_npz(npz_path, scale, model, plots_all_dir, overwrite=args.overwrite) |
| total_saved += n |
| total_npz += 1 |
|
|
| print(f'\nDone. Processed {total_npz} NPZ file(s), saved {total_saved} plots.') |
|
|
|
|
| if __name__ == '__main__': |
| main() |
|
|
