"""Decisive test for the Anderson idea: at LOW damping (expressive attention), can a fixed-point SOLVER (Anderson acceleration, DEQ-style) converge the free phase where plain fixed-step relaxation cannot? If yes -> we get convergence from the solver, not from suppressing attention with damping.""" import math, torch from lt_ep_train import EQBlock, get_batch dev = 'cuda' if torch.cuda.is_available() else 'cpu' torch.manual_seed(0) B, T, C, H = 16, 64, 128, 4 blk = EQBlock(C, H, 256, T, attn_mode='real') idx, y = get_batch('train', B, T) xin = blk.embed(idx).detach() eps = 0.05 def gmap(z): # relaxation map; its fixed point = the equilibrium with torch.no_grad(): return z + eps * blk.force(z, xin).detach() def plain(z0, steps=200): z = z0.clone() for _ in range(steps): z = gmap(z) return ((gmap(z) - z).norm() / (z.norm() + 1e-9)).item() def anderson(z0, m=6, max_iter=120, tol=1e-6, lam=1e-4): Bs, d = z0.shape[0], z0[0].numel() X = torch.zeros(Bs, m, d, device=dev); Fb = torch.zeros(Bs, m, d, device=dev) X[:, 0] = z0.reshape(Bs, d); Fb[:, 0] = gmap(z0).reshape(Bs, d) X[:, 1] = Fb[:, 0]; Fb[:, 1] = gmap(X[:, 1].view_as(z0)).reshape(Bs, d) Hm = torch.zeros(Bs, m + 1, m + 1, device=dev); Hm[:, 0, 1:] = 1; Hm[:, 1:, 0] = 1 yv = torch.zeros(Bs, m + 1, 1, device=dev); yv[:, 0] = 1 r, k = 1.0, 2 for k in range(2, max_iter): n = min(k, m) Gm = Fb[:, :n] - X[:, :n] Hm[:, 1:n + 1, 1:n + 1] = torch.bmm(Gm, Gm.transpose(1, 2)) + lam * torch.eye(n, device=dev)[None] alpha = torch.linalg.solve(Hm[:, :n + 1, :n + 1], yv[:, :n + 1])[:, 1:n + 1, 0] X[:, k % m] = torch.bmm(alpha[:, None], Fb[:, :n])[:, 0] Fb[:, k % m] = gmap(X[:, k % m].view_as(z0)).reshape(Bs, d) r = ((Fb[:, k % m] - X[:, k % m]).norm() / (Fb[:, k % m].norm() + 1e-9)).item() if r < tol or not math.isfinite(r): break return r, k + 1 print("free-phase convergence: plain relax (200 steps) vs Anderson — real attention, eps=0.05") print(f"{'damp c':>7} {'plain_res':>11} {'anderson_res':>13} {'and_iters':>10}") for c in [0.0, 0.25, 0.5, 1.0, 2.0, 4.0]: blk.c = c pr = plain(xin.clone()) ar, ak = anderson(xin.clone()) print(f"{c:>7.2f} {pr:>11.2e} {ar:>13.2e} {ak:>10d}")