| """ |
| New mapping methods on top of the existing 25-anchor experiment data: |
| |
| (f) procrustes Per-tensor orthogonal Procrustes alignment between |
| X-anchor and Y-anchor matrices in tensor-flat space. |
| Respects the LoRA gauge ambiguity better than ridge. |
| (g) topk_global_ridge Pick top-K anchors by X-side cosine similarity to X_target, |
| then run global anchor-basis ridge on that subset. |
| (h) topk_pertensor_ridge Same, but per-tensor ridge. |
| (i) topk_pertensor_mlp Top-K + per-tensor PCA-MLP hypernet (re-trained per task). |
| |
| Reuses all training artifacts from /app/scaled/X and /app/scaled/Y. |
| """ |
| import os, json, gc, shutil, re, collections, math |
| from pathlib import Path |
| import numpy as np |
| import torch |
| import torch.nn.functional as F |
| from datasets import load_dataset |
| from transformers import AutoTokenizer, AutoModelForCausalLM, set_seed |
| from peft import PeftModel |
| from safetensors.torch import load_file, save_file |
|
|
| |
| import sys; sys.path.insert(0, "/app") |
| import scaled_pipeline as sp |
|
|
| set_seed(42) |
|
|
| OUT = sp.OUT |
| ANCHOR_NAMES = sp.ANCHOR_NAMES |
| HELDOUT_NAMES = sp.HELDOUT_NAMES |
| MODEL_Y = sp.MODEL_Y |
| EVAL_PER_TASK = sp.EVAL_PER_TASK |
|
|
| def load_sd(p): return {k: v.float().cpu() for k,v in load_file(str(p/"adapter_model.safetensors")).items()} |
|
|
| def parse_key(k): |
| m = re.search(r'layers\.(\d+)\.self_attn\.(\w+)_proj\.lora_(A|B)', k) |
| return int(m.group(1)), m.group(2), m.group(3) |
|
|
| def group_by_layer(sd): |
| g = collections.defaultdict(dict) |
| for k, v in sd.items(): |
| L, mod, AB = parse_key(k) |
| g[(mod, AB)][L] = (k, v) |
| return g |
|
|
| def align_X_to_Y(X_anchors_list, X_target, Y_template_sd): |
| Y_g = group_by_layer(Y_template_sd) |
| X_gs = [group_by_layer(s) for s in X_anchors_list] |
| X_t = group_by_layer(X_target) |
| nLY = max(Y_g[("q","A")].keys()) + 1 |
| nLX = max(X_gs[0][("q","A")].keys()) + 1 |
| out = {} |
| for (mod, AB), layers in Y_g.items(): |
| for L_y, (yk, _) in layers.items(): |
| L_x = round(L_y * (nLX-1) / max(1, nLY-1)) |
| x_anchors = [X_gs[i][(mod,AB)][L_x][1] for i in range(len(X_gs))] |
| x_target = X_t[(mod,AB)][L_x][1] |
| out[yk] = (x_anchors, x_target) |
| return out |
|
|
| |
| def procrustes_pred(X_anchors, Y_anchors, X_target): |
| """Per-tensor orthogonal Procrustes (rectangular), avoiding dx*dy materialization. |
| Cross-covariance M = Xc^T Yc has rank ≤ N. Compute its SVD efficiently: |
| Xc = U_x S_x V_x^T (compact, V_x^T is (N, dx), V_x is (dx, N)) |
| Yc = U_y S_y V_y^T |
| Then SVD(M) <- via N-by-N inner SVD; never materialize dx-by-dy. |
| """ |
| align = align_X_to_Y(X_anchors, X_target, Y_anchors[0]) |
| out = {} |
| for yk, (x_anchors, x_target) in align.items(): |
| Y_mat = torch.stack([s[yk].reshape(-1) for s in Y_anchors]) |
| X_mat = torch.stack([t.reshape(-1) for t in x_anchors]) |
| Ym, Xm = Y_mat.mean(0), X_mat.mean(0) |
| Yc, Xc = Y_mat - Ym, X_mat - Xm |
| Ux_, Sx_, Vxh = torch.linalg.svd(Xc, full_matrices=False) |
| Uy_, Sy_, Vyh = torch.linalg.svd(Yc, full_matrices=False) |
| C = (Sx_.unsqueeze(1) * Ux_.T) @ (Uy_ * Sy_.unsqueeze(0)) |
| Uz, Sz, Vzh = torch.linalg.svd(C, full_matrices=False) |
| scale = (Sz.sum() / (Sx_.pow(2).sum() + 1e-8)).item() |
| xt_c = x_target.reshape(-1) - Xm |
| a = Vxh @ xt_c |
| b = (Uz @ Vzh) @ a |
| delta = b @ Vyh |
| out[yk] = (Ym + scale * delta).reshape(Y_anchors[0][yk].shape) |
| return out |
|
|
| |
| def topk_anchor_idx(X_anchors, X_target, k=8): |
| """Return indices of top-K anchors by cosine similarity to X_target.""" |
| keys = sorted(X_anchors[0].keys()) |
| Xa = torch.stack([torch.cat([s[kk].flatten() for kk in keys]) for s in X_anchors]) |
| xt = torch.cat([X_target[kk].flatten() for kk in keys]) |
| sims = F.cosine_similarity(Xa, xt.unsqueeze(0), dim=1) |
| idx = torch.topk(sims, k=min(k, len(X_anchors))).indices.tolist() |
| return idx, sims.tolist() |
|
|
| def topk_global_ridge(X_anchors, Y_anchors, X_target, k=8, ridge=1e-3): |
| idx, sims = topk_anchor_idx(X_anchors, X_target, k=k) |
| Xa = [X_anchors[i] for i in idx] |
| Ya = [Y_anchors[i] for i in idx] |
| pred, alpha = sp.global_ridge_pred(Xa, Ya, X_target, ridge=ridge) |
| return pred, idx, sims |
|
|
| def topk_pertensor_ridge(X_anchors, Y_anchors, X_target, k=8, ridge=1e-3): |
| idx, sims = topk_anchor_idx(X_anchors, X_target, k=k) |
| Xa = [X_anchors[i] for i in idx] |
| Ya = [Y_anchors[i] for i in idx] |
| pred = sp.pertensor_ridge_pred(Xa, Ya, X_target, ridge=ridge) |
| return pred, idx, sims |
|
|
| def topk_pertensor_mlp(X_anchors, Y_anchors, X_target, k=12, k_lat=6, epochs=300, lr=1e-3): |
| idx, sims = topk_anchor_idx(X_anchors, X_target, k=k) |
| Xa = [X_anchors[i] for i in idx] |
| Ya = [Y_anchors[i] for i in idx] |
| pred, _ = sp.pertensor_pca_mlp_pred(Xa, Ya, X_target, k_lat=k_lat, epochs=epochs, lr=lr) |
| return pred, idx, sims |
|
|
| |
| def save_adapter(sd, dirname, src_template): |
| d = OUT/"Y_pred"/dirname |
| d.mkdir(parents=True, exist_ok=True) |
| shutil.copy(src_template/"adapter_config.json", d/"adapter_config.json") |
| save_file({k: v.to(torch.bfloat16) for k,v in sd.items()}, str(d/"adapter_model.safetensors")) |
| return d |
|
|
| @torch.no_grad() |
| def eval_adapter(adapter_dir, eval_ds, labels, tok, max_n=300): |
| base = AutoModelForCausalLM.from_pretrained(MODEL_Y, torch_dtype=torch.bfloat16, attn_implementation="eager").cuda() |
| if adapter_dir is None: |
| m = base |
| else: |
| m = PeftModel.from_pretrained(base, str(adapter_dir)) |
| acc = sp.eval_classification(m, tok, eval_ds, labels, max_n=max_n) |
| del m, base |
| if adapter_dir is None: pass |
| gc.collect(); torch.cuda.empty_cache() |
| return acc |
|
|
| def cos_sd(sd1, sd2): |
| keys = sorted(sd1.keys()) |
| a = torch.cat([sd1[k].float().flatten() for k in keys]) |
| b = torch.cat([sd2[k].float().flatten() for k in keys]) |
| return F.cosine_similarity(a.unsqueeze(0), b.unsqueeze(0)).item() |
|
|
| |
| def main(): |
| print("Loading anchors...") |
| X_anchors = [load_sd(OUT/"X"/n) for n in ANCHOR_NAMES] |
| Y_anchors = [load_sd(OUT/"Y"/n) for n in ANCHOR_NAMES] |
| print(f" N={len(X_anchors)} anchors") |
|
|
| tokY = AutoTokenizer.from_pretrained(MODEL_Y) |
| if tokY.pad_token is None: tokY.pad_token = tokY.eos_token |
| tokY.padding_side = "left" |
|
|
| out_results = {} |
| template = OUT/"Y"/ANCHOR_NAMES[0] |
|
|
| for t_name in HELDOUT_NAMES: |
| print(f"\n=== Held-out task: {t_name} ===") |
| X_target = load_sd(OUT/"X"/t_name) |
| Y_oracle = load_sd(OUT/"Y"/t_name) |
|
|
| results = {"cosines": {}, "acc": {}, "selected_anchors": {}} |
|
|
| |
| preds = {} |
| print(" procrustes ...") |
| preds["procrustes"] = procrustes_pred(X_anchors, Y_anchors, X_target) |
|
|
| for k_top in [5, 8, 12]: |
| print(f" topk_global_ridge k={k_top} ...") |
| p, idx, sims = topk_global_ridge(X_anchors, Y_anchors, X_target, k=k_top) |
| preds[f"topk{k_top}_global_ridge"] = p |
| results["selected_anchors"][f"topk{k_top}"] = [ANCHOR_NAMES[i] for i in idx] |
| print(f" selected: {[ANCHOR_NAMES[i] for i in idx]}") |
|
|
| print(f" topk_pertensor_ridge k={k_top} ...") |
| p, _, _ = topk_pertensor_ridge(X_anchors, Y_anchors, X_target, k=k_top) |
| preds[f"topk{k_top}_pertensor_ridge"] = p |
|
|
| print(" topk12_pertensor_mlp ...") |
| p, _, _ = topk_pertensor_mlp(X_anchors, Y_anchors, X_target, k=12, k_lat=6, epochs=300) |
| preds["topk12_pertensor_mlp"] = p |
|
|
| |
| _, eval_ds, labels = sp.build_task(t_name, n_train=10, n_eval=EVAL_PER_TASK) |
|
|
| |
| for n, sd in preds.items(): |
| results["cosines"][n] = cos_sd(sd, Y_oracle) |
|
|
| |
| results["acc"]["base_Y"] = eval_adapter(None, eval_ds, labels, tokY) |
| print(f" base_Y={results['acc']['base_Y']:.4f}") |
| for n, sd in preds.items(): |
| d = save_adapter(sd, f"{t_name}_{n}", template) |
| acc = eval_adapter(d, eval_ds, labels, tokY) |
| results["acc"][n] = acc |
| print(f" {n:32s} cos={results['cosines'][n]:.4f} acc={acc:.4f}") |
|
|
| results["acc"]["oracle_Y"] = eval_adapter(OUT/"Y"/t_name, eval_ds, labels, tokY) |
| print(f" oracle_Y={results['acc']['oracle_Y']:.4f}") |
|
|
| out_results[t_name] = results |
|
|
| |
| methods = ["base_Y","procrustes","topk5_global_ridge","topk5_pertensor_ridge", |
| "topk8_global_ridge","topk8_pertensor_ridge", |
| "topk12_global_ridge","topk12_pertensor_ridge","topk12_pertensor_mlp","oracle_Y"] |
| avg = {m: float(np.mean([out_results[t]["acc"][m] for t in HELDOUT_NAMES])) for m in methods} |
| print("\n=== AVG (new methods) ===") |
| for m in methods: print(f" {m:32s} {avg[m]:.4f}") |
| out_results["avg"] = avg |
| (OUT/"results_phaseA.json").write_text(json.dumps(out_results, indent=2, default=float)) |
|
|
| if __name__ == "__main__": |
| main() |
|
|
