def solve(psi_fns, omega_fns, lmb=1.0, mu=None, quad_funcs=None, max_iters=1000, eps_abs=1e-3, eps_rel=1e-3, lin_solver="cg", lin_solver_options=None, try_diagonalize=True, try_fast_norm=True, scaled=False, metric=None, convlog=None, verbose=0): # Can only have one omega function. assert len(omega_fns) <= 1 prox_fns = psi_fns + omega_fns stacked_ops = vstack([fn.lin_op for fn in psi_fns]) K = CompGraph(stacked_ops) # Select optimal parameters if wanted if lmb is None or mu is None: lmb, mu = est_params_lin_admm(K, lmb, verbose, scaled, try_fast_norm) # Initialize everything to zero. v = np.zeros(K.input_size) z = np.zeros(K.output_size) u = np.zeros(K.output_size) # Buffers. Kv = np.zeros(K.output_size) KTu = np.zeros(K.input_size) s = np.zeros(K.input_size) Kvzu = np.zeros(K.output_size) v_prev = np.zeros(K.input_size) z_prev = np.zeros(K.output_size) # Log for prox ops. prox_log = TimingsLog(prox_fns) # Time iterations. iter_timing = TimingsEntry("LIN-ADMM iteration") # Convergence log for initial iterate if convlog is not None: K.update_vars(v) objval = sum([fn.value for fn in prox_fns]) convlog.record_objective(objval) convlog.record_timing(0.0) for i in range(max_iters): iter_timing.tic() if convlog is not None: convlog.tic() v_prev[:] = v z_prev[:] = z # Update v K.forward(v, Kv) Kvzu[:] = Kv - z + u K.adjoint(Kvzu, v) v[:] = v_prev - (mu / lmb) * v if len(omega_fns) > 0: v[:] = omega_fns[0].prox(1.0 / mu, v, x_init=v_prev.copy(), lin_solver=lin_solver, options=lin_solver_options) # Update z. K.forward(v, Kv) Kv_u = Kv + u offset = 0 for fn in psi_fns: slc = slice(offset, offset + fn.lin_op.size, None) Kv_u_slc = np.reshape(Kv_u[slc], fn.lin_op.shape) # Apply and time prox. prox_log[fn].tic() z[slc] = fn.prox(1.0 / lmb, Kv_u_slc, i).flatten() prox_log[fn].toc() offset += fn.lin_op.size # Update u. u += Kv - z K.adjoint(u, KTu) # Check convergence. r = Kv - z K.adjoint((1.0 / lmb) * (z - z_prev), s) eps_pri = np.sqrt(K.output_size) * eps_abs + eps_rel * \ max([np.linalg.norm(Kv), np.linalg.norm(z)]) eps_dual = np.sqrt(K.input_size) * eps_abs + eps_rel * np.linalg.norm(KTu) / (1.0 / lmb) # Convergence log if convlog is not None: convlog.toc() K.update_vars(v) objval = sum([fn.value for fn in prox_fns]) convlog.record_objective(objval) # Show progess if verbose > 0: # Evaluate objective only if required (expensive !) objstr = '' if verbose == 2: K.update_vars(v) objstr = ", obj_val = %02.03e" % sum([fn.value for fn in prox_fns]) # Evaluate metric potentially metstr = '' if metric is None else ", {}".format(metric.message(v)) print "iter %d: ||r||_2 = %.3f, eps_pri = %.3f, ||s||_2 = %.3f, eps_dual = %.3f%s%s" % ( i, np.linalg.norm(r), eps_pri, np.linalg.norm(s), eps_dual, objstr, metstr) iter_timing.toc() if np.linalg.norm(r) <= eps_pri and np.linalg.norm(s) <= eps_dual: break # Print out timings info. if verbose > 0: print iter_timing print "prox funcs:" print prox_log print "K forward ops:" print K.forward_log print "K adjoint ops:" print K.adjoint_log # Assign values to variables. K.update_vars(v) # Return optimal value. return sum([fn.value for fn in prox_fns])
def solve(psi_fns, omega_fns, lmb=1.0, mu=None, quad_funcs=None, max_iters=1000, eps_abs=1e-3, eps_rel=1e-3, lin_solver="cg", lin_solver_options=None, try_diagonalize=True, try_fast_norm=True, scaled=False, metric=None, convlog=None, verbose=0): # Can only have one omega function. assert len(omega_fns) <= 1 prox_fns = psi_fns + omega_fns stacked_ops = vstack([fn.lin_op for fn in psi_fns]) K = CompGraph(stacked_ops) # Select optimal parameters if wanted if lmb is None or mu is None: lmb, mu = est_params_lin_admm(K, lmb, verbose, scaled, try_fast_norm) # Initialize everything to zero. v = np.zeros(K.input_size) z = np.zeros(K.output_size) u = np.zeros(K.output_size) # Buffers. Kv = np.zeros(K.output_size) KTu = np.zeros(K.input_size) s = np.zeros(K.input_size) Kvzu = np.zeros(K.output_size) v_prev = np.zeros(K.input_size) z_prev = np.zeros(K.output_size) # Log for prox ops. prox_log = TimingsLog(prox_fns) # Time iterations. iter_timing = TimingsEntry("LIN-ADMM iteration") # Convergence log for initial iterate if convlog is not None: K.update_vars(v) objval = sum([fn.value for fn in prox_fns]) convlog.record_objective(objval) convlog.record_timing(0.0) for i in range(max_iters): iter_timing.tic() if convlog is not None: convlog.tic() v_prev[:] = v z_prev[:] = z # Update v K.forward(v, Kv) Kvzu[:] = Kv - z + u K.adjoint(Kvzu, v) v[:] = v_prev - (mu / lmb) * v if len(omega_fns) > 0: v[:] = omega_fns[0].prox(1.0 / mu, v, x_init=v_prev.copy(), lin_solver=lin_solver, options=lin_solver_options) # Update z. K.forward(v, Kv) Kv_u = Kv + u offset = 0 for fn in psi_fns: slc = slice(offset, offset + fn.lin_op.size, None) Kv_u_slc = np.reshape(Kv_u[slc], fn.lin_op.shape) # Apply and time prox. prox_log[fn].tic() z[slc] = fn.prox(1.0 / lmb, Kv_u_slc, i).flatten() prox_log[fn].toc() offset += fn.lin_op.size # Update u. u += Kv - z K.adjoint(u, KTu) # Check convergence. r = Kv - z K.adjoint((1.0 / lmb) * (z - z_prev), s) eps_pri = np.sqrt(K.output_size) * eps_abs + eps_rel * \ max([np.linalg.norm(Kv), np.linalg.norm(z)]) eps_dual = np.sqrt(K.input_size) * eps_abs + eps_rel * np.linalg.norm( KTu) / (1.0 / lmb) # Convergence log if convlog is not None: convlog.toc() K.update_vars(v) objval = sum([fn.value for fn in prox_fns]) convlog.record_objective(objval) # Show progess if verbose > 0: # Evaluate objective only if required (expensive !) objstr = '' if verbose == 2: K.update_vars(v) objstr = ", obj_val = %02.03e" % sum( [fn.value for fn in prox_fns]) # Evaluate metric potentially metstr = '' if metric is None else ", {}".format(metric.message(v)) print( "iter %d: ||r||_2 = %.3f, eps_pri = %.3f, ||s||_2 = %.3f, eps_dual = %.3f%s%s" % (i, np.linalg.norm(r), eps_pri, np.linalg.norm(s), eps_dual, objstr, metstr)) iter_timing.toc() if np.linalg.norm(r) <= eps_pri and np.linalg.norm(s) <= eps_dual: break # Print out timings info. if verbose > 0: print(iter_timing) print("prox funcs:") print(prox_log) print("K forward ops:") print(K.forward_log) print("K adjoint ops:") print(K.adjoint_log) # Assign values to variables. K.update_vars(v) # Return optimal value. return sum([fn.value for fn in prox_fns])
def solve(psi_fns, omega_fns, rho_0=1.0, rho_scale=math.sqrt(2.0) * 2.0, rho_max=2**8, max_iters=-1, max_inner_iters=100, x0=None, eps_rel=1e-3, eps_abs=1e-3, lin_solver="cg", lin_solver_options=None, try_diagonalize=True, scaled=False, try_fast_norm=False, metric=None, convlog=None, verbose=0): prox_fns = psi_fns + omega_fns stacked_ops = vstack([fn.lin_op for fn in psi_fns]) K = CompGraph(stacked_ops) # Rescale so (1/2)||x - b||^2_2 rescaling = np.sqrt(2.) quad_ops = [] quad_weights = [] const_terms = [] for fn in omega_fns: fn = fn.absorb_params() quad_ops.append(scale(rescaling * fn.beta, fn.lin_op)) quad_weights.append(rescaling * fn.beta) const_terms.append(fn.b.flatten() * rescaling) # Get optimize inverse (tries spatial and frequency diagonalization) op_list = [func.lin_op for func in psi_fns] + quad_ops stacked_ops = vstack(op_list) x_update = get_least_squares_inverse(op_list, None, try_diagonalize, verbose) # Initialize if x0 is not None: x = np.reshape(x0, K.input_size) else: x = np.zeros(K.input_size) Kx = np.zeros(K.output_size) w = Kx.copy() # Temporary iteration counts x_prev = x.copy() # Log for prox ops. prox_log = TimingsLog(prox_fns) # Time iterations. iter_timing = TimingsEntry("HQS iteration") inner_iter_timing = TimingsEntry("HQS inner iteration") # Convergence log for initial iterate if convlog is not None: K.update_vars(x) objval = sum([func.value for func in prox_fns]) convlog.record_objective(objval) convlog.record_timing(0.0) # Rho scedule rho = rho_0 i = 0 while rho < rho_max and i < max_iters: iter_timing.tic() if convlog is not None: convlog.tic() # Update rho for quadratics for idx, op in enumerate(quad_ops): op.scalar = quad_weights[idx] / np.sqrt(rho) x_update = get_least_squares_inverse(op_list, CompGraph(stacked_ops), try_diagonalize, verbose) for ii in range(max_inner_iters): inner_iter_timing.tic() # Update Kx. K.forward(x, Kx) # Prox update to get w. offset = 0 w_prev = w.copy() for fn in psi_fns: slc = slice(offset, offset + fn.lin_op.size, None) # Apply and time prox. prox_log[fn].tic() w[slc] = fn.prox(rho, np.reshape(Kx[slc], fn.lin_op.shape), ii).flatten() prox_log[fn].toc() offset += fn.lin_op.size # Update x. x_prev[:] = x tmp = np.hstack([w] + [cterm / np.sqrt(rho) for cterm in const_terms]) x = x_update.solve(tmp, x_init=x, lin_solver=lin_solver, options=lin_solver_options) # Very basic convergence check. r_x = np.linalg.norm(x_prev - x) eps_x = eps_rel * np.prod(K.input_size) r_w = np.linalg.norm(w_prev - w) eps_w = eps_rel * np.prod(K.output_size) # Convergence log if convlog is not None: convlog.toc() K.update_vars(x) objval = sum([fn.value for fn in prox_fns]) convlog.record_objective(objval) # Show progess if verbose > 0: # Evaluate objective only if required (expensive !) objstr = '' if verbose == 2: K.update_vars(x) objstr = ", obj_val = %02.03e" % sum([fn.value for fn in prox_fns]) # Evaluate metric potentially metstr = '' if metric is None else ", {}".format(metric.message(x)) print("iter [%02d (rho=%2.1e) || %02d]:" "||w - w_prev||_2 = %02.02e (eps=%02.03e)" "||x - x_prev||_2 = %02.02e (eps=%02.03e)%s%s" % (i, rho, ii, r_x, eps_x, r_w, eps_w, objstr, metstr)) inner_iter_timing.toc() if r_x < eps_x and r_w < eps_w: break # Update rho rho = np.minimum(rho * rho_scale, rho_max) i += 1 iter_timing.toc() # Print out timings info. if verbose > 0: print(iter_timing) print(inner_iter_timing) print("prox funcs:") print(prox_log) print("K forward ops:") print(K.forward_log) print("K adjoint ops:") print(K.adjoint_log) # Assign values to variables. K.update_vars(x) # Return optimal value. return sum([fn.value for fn in prox_fns])
def solve(psi_fns, omega_fns, tau=None, sigma=None, theta=None, max_iters=1000, eps_abs=1e-3, eps_rel=1e-3, x0=None, lin_solver="cg", lin_solver_options=None, try_diagonalize=True, try_fast_norm=False, scaled=True, metric=None, convlog=None, verbose=0): # Can only have one omega function. assert len(omega_fns) <= 1 prox_fns = psi_fns + omega_fns stacked_ops = vstack([fn.lin_op for fn in psi_fns]) K = CompGraph(stacked_ops) v = np.zeros(K.input_size) # Select optimal parameters if wanted if tau is None or sigma is None or theta is None: tau, sigma, theta = est_params_pc(K, tau, sigma, verbose, scaled, try_fast_norm) # Initialize x = np.zeros(K.input_size) y = np.zeros(K.output_size) xbar = np.zeros(K.input_size) u = np.zeros(K.output_size) z = np.zeros(K.output_size) if x0 is not None: x[:] = np.reshape(x0, K.input_size) K.forward(x, y) xbar[:] = x # Buffers. Kxbar = np.zeros(K.output_size) Kx = np.zeros(K.output_size) KTy = np.zeros(K.input_size) KTu = np.zeros(K.input_size) s = np.zeros(K.input_size) prev_x = x.copy() prev_Kx = Kx.copy() prev_z = z.copy() prev_u = u.copy() # Log for prox ops. prox_log = TimingsLog(prox_fns) # Time iterations. iter_timing = TimingsEntry("PC iteration") # Convergence log for initial iterate if convlog is not None: K.update_vars(x) objval = sum([fn.value for fn in prox_fns]) convlog.record_objective(objval) convlog.record_timing(0.0) for i in range(max_iters): iter_timing.tic() if convlog is not None: convlog.tic() # Keep track of previous iterates np.copyto(prev_x, x) np.copyto(prev_z, z) np.copyto(prev_u, u) np.copyto(prev_Kx, Kx) # Compute z K.forward(xbar, Kxbar) z = y + sigma * Kxbar # Update y. offset = 0 for fn in psi_fns: slc = slice(offset, offset + fn.lin_op.size, None) z_slc = np.reshape(z[slc], fn.lin_op.shape) # Moreau identity: apply and time prox. prox_log[fn].tic() y[slc] = (z_slc - sigma * fn.prox(sigma, z_slc / sigma, i)).flatten() prox_log[fn].toc() offset += fn.lin_op.size y[offset:] = 0 # Update x K.adjoint(y, KTy) x -= tau * KTy if len(omega_fns) > 0: xtmp = np.reshape(x, omega_fns[0].lin_op.shape) x[:] = omega_fns[0].prox(1.0 / tau, xtmp, x_init=prev_x, lin_solver=lin_solver, options=lin_solver_options).flatten() # Update xbar np.copyto(xbar, x) xbar += theta * (x - prev_x) # Convergence log if convlog is not None: convlog.toc() K.update_vars(x) objval = sum([fn.value for fn in prox_fns]) convlog.record_objective(objval) """ Old convergence check #Very basic convergence check. r_x = np.linalg.norm(x - prev_x) r_xbar = np.linalg.norm(xbar - prev_xbar) r_ybar = np.linalg.norm(y - prev_y) error = r_x + r_xbar + r_ybar """ # Residual based convergence check K.forward(x, Kx) u = 1.0 / sigma * y + theta * (Kx - prev_Kx) z = prev_u + prev_Kx - 1.0 / sigma * y # Iteration order is different than # lin-admm (--> start checking at iteration 1) if i > 0: # Check convergence r = prev_Kx - z K.adjoint(sigma * (z - prev_z), s) eps_pri = np.sqrt(K.output_size) * eps_abs + eps_rel * \ max([np.linalg.norm(prev_Kx), np.linalg.norm(z)]) K.adjoint(u, KTu) eps_dual = np.sqrt(K.input_size) * eps_abs + eps_rel * np.linalg.norm(KTu) / sigma # Progress if verbose > 0: # Evaluate objective only if required (expensive !) objstr = '' if verbose == 2: K.update_vars(x) objstr = ", obj_val = %02.03e" % sum([fn.value for fn in prox_fns]) """ Old convergence check #Evaluate metric potentially metstr = '' if metric is None else ", {}".format( metric.message(x.copy()) ) print "iter [%04d]:" \ "||x - x_prev||_2 = %02.02e " \ "||xbar - xbar_prev||_2 = %02.02e " \ "||y - y_prev||_2 = %02.02e " \ "SUM = %02.02e (eps=%02.03e)%s%s" \ % (i, r_x, r_xbar, r_ybar, error, eps, objstr, metstr) """ # Evaluate metric potentially metstr = '' if metric is None else ", {}".format(metric.message(v)) print( "iter %d: ||r||_2 = %.3f, eps_pri = %.3f, ||s||_2 = %.3f, eps_dual = %.3f%s%s" % (i, np.linalg.norm(r), eps_pri, np.linalg.norm(s), eps_dual, objstr, metstr) ) iter_timing.toc() if np.linalg.norm(r) <= eps_pri and np.linalg.norm(s) <= eps_dual: break else: iter_timing.toc() """ Old convergence check if error <= eps: break """ # Print out timings info. if verbose > 0: print iter_timing print "prox funcs:" print prox_log print "K forward ops:" print K.forward_log print "K adjoint ops:" print K.adjoint_log # Assign values to variables. K.update_vars(x) # Return optimal value. return sum([fn.value for fn in prox_fns])
def solve(psi_fns, omega_fns, rho=1.0, max_iters=1000, eps_abs=1e-10, eps_rel=1e-3, x0=None, lin_solver="cg", lin_solver_options=None, try_diagonalize=True, try_fast_norm=False, scaled=True, metric=None, convlog=None, verbose=0): # C=np.array([[1,0],[0,0]]); # b=np.array([2,0]); # print(np.linalg.lstsq(C,b,rcond=None)[0]) prox_fns = psi_fns + omega_fns stacked_ops = vstack([fn.lin_op for fn in psi_fns]) K = CompGraph(stacked_ops) # Rescale so (rho/2)||x - b||^2_2 rescaling = np.sqrt(2. / rho) quad_ops = [] const_terms = [] for fn in omega_fns: fn = fn.absorb_params() quad_ops.append(scale(rescaling * fn.beta, fn.lin_op)) const_terms.append(fn.b.flatten() * rescaling) # Check for fast inverse. op_list = [func.lin_op for func in psi_fns] + quad_ops stacked_ops = vstack(op_list) # Get optimize inverse (tries spatial and frequency diagonalization) v_update = get_least_squares_inverse(op_list, None, try_diagonalize, verbose) # Initialize everything to zero. input_size = K.input_size output_size = K.output_size v = np.zeros(input_size) z = np.zeros(output_size) u = np.zeros(output_size) print(output_size) # Initialize if x0 is not None: v[:] = np.reshape(x0, input_size) K.forward(v, z) # Buffers. v0 = v.copy() z0 = z.copy() u0 = u.copy() N_z = len(z[:]) Kv = np.zeros(output_size) KTu = np.zeros(input_size) s = np.zeros(input_size) Kv_pre = Kv.copy() # Log for prox ops. prox_log = TimingsLog(prox_fns) # Time iterations. iter_timing = TimingsEntry("ADMM iteration") # Convergence log for initial iterate if convlog is not None: K.update_vars(v) objval = sum([func.value for func in prox_fns]) convlog.record_objective(objval) convlog.record_timing(0.0) # -------------------------------------------------------------------------------------------------- print("Anderson Acceleration:") for andersonmk in range(6, 7): v = v0.copy() u = u0.copy() v_d = v.copy() u_d = u.copy() res_pre = 9e20 total_energy = [] total_time = [] Combine_res = [] reset = False sca_z = 1 size = v.flatten().shape[0] total_size = (u.flatten()).shape[0] + size print(size) sign = 0 curr_time = 0 AA_compute_time = 0 acc1 = Anderson( np.concatenate((v.flatten(), sca_z * u.flatten()), axis=0), total_size, andersonmk) for i in range(max_iters): t1 = time.time() if convlog is not None: convlog.tic() K.forward(v, Kv) # Update z. Kv_pre = Kv.copy() K.forward(v, Kv) Kv_u = Kv + u offset = 0 for fn in psi_fns: tmp = np.hstack([z - u] + const_terms) v = v_update.solve(tmp, x_init=v, lin_solver=lin_solver, options=lin_solver_options) K.forward(v, Kv) Kv_u = Kv + u slc = slice(offset, offset + fn.lin_op.size, None) Kv_u_slc = np.reshape(Kv_u[slc], fn.lin_op.shape) # Apply and time prox. z_pre = z.copy() prox_log[fn].tic() z[slc] = fn.prox(rho, Kv_u_slc, i).flatten() prox_log[fn].toc() offset += fn.lin_op.size # Update u. r = Kv - z u += r K.adjoint(u, KTu) # print(np.linalg.norm(u)) # Check convergence. # K.adjoint(rho * (z - z_prev), s) s = z - z_pre res = np.linalg.norm(r)**2 + np.linalg.norm(s)**2 # K.adjoint((z-z_prev),s) # eps_pri = np.sqrt(output_size) * eps_abs + eps_rel * \ # max([np.linalg.norm(Kv), np.linalg.norm(z)]) # eps_dual = np.sqrt(input_size) * eps_abs + eps_rel * np.linalg.norm(KTu) / rho t3 = time.time() if res < res_pre or reset == True: v_d = v.copy() u_d = u.copy() res_pre = res reset = False tt = acc1.compute( np.concatenate((v.flatten(), sca_z * u.flatten()), axis=0)) v = tt[0:size].reshape(v.shape) u = tt[size:].reshape(u.shape) / sca_z else: sign = sign + 1 v = v_d.copy() u = u_d.copy() reset = True acc1.reset( np.concatenate((v.flatten(), sca_z * u.flatten()), axis=0)) t4 = time.time() AA_compute_time += t4 - t3 t2 = time.time() curr_time += t2 - t1 # Convergence log if convlog is not None: convlog.toc() K.update_vars(v) objval = sum([fn.value for fn in prox_fns]) convlog.record_objective(objval) # Show progess if verbose > 0: # Evaluate objective only if required (expensive !) objstr = '' if verbose == 2: K.update_vars(v) objstr = ", obj_val = %02.03e" % sum( [fn.value for fn in prox_fns]) # Evaluate metric potentially metstr = '' if metric is None else ", {}".format( metric.message(v)) # print("iter %d: ||r||_2 = %.3f, eps_pri = %.3f, ||s||_2 = %.3f, eps_dual = %.3f%s%s" % ( # i, np.linalg.norm(r), eps_pri, np.linalg.norm(s), eps_dual, objstr, metstr)) print("iter %d: combine residual = %.8f" % (i, res)) Combine_res.append(np.sqrt(rho * res_pre / N_z)) total_time.append(curr_time) # Exit if converged. if (res) < eps_abs: break print("current time: %.6f, AA compute: %.6f, sign: %d" % (curr_time, AA_compute_time, sign)) hm_src_path = 'residual-' + str(andersonmk) + '.txt' iter_num = [] iter_num.append(len(total_time)) iter_num.append(len(Combine_res)) with open(hm_src_path, 'w') as f: for i in range(0, min(iter_num)): f.write('%f\t%.20f\n' % (total_time[i], Combine_res[i])) f.close() print("Anderson Acceleration with Douglas-Rachford splitting:") for andersonmk in range(6, 7): v = v0.copy() u = u0.copy() K.forward(v, Kv) v_d = v.copy() u_d = u.copy() d_s = z0.copy() d_u = d_s.copy() d_s_d = d_s.copy() d_v = d_s.copy() d_unew = d_u.copy() res_pre = 9e20 r_com = 0 r_com_pre = r_com total_energy = [] total_time = [] Combine_res = [] reset = False size = v.flatten().shape[0] sign = 0 curr_time = 0 acc1 = Anderson(d_s.flatten(), size, andersonmk) for i in range(max_iters): t1 = time.time() if convlog is not None: convlog.tic() # K.forward(v, Kv) # Update v. Kv_u = d_s.copy() offset = 0 for fn in psi_fns: slc = slice(offset, offset + fn.lin_op.size, None) Kv_u_slc = np.reshape(Kv_u[slc], fn.lin_op.shape) # Apply and time prox. prox_log[fn].tic() z[slc] = fn.prox(rho, Kv_u_slc, i).flatten() prox_log[fn].toc() offset += fn.lin_op.size d_u = z.copy() temp = 2 * d_u - d_s tmp = np.hstack([temp] + const_terms) v = v_update.solve(tmp, x_init=v, lin_solver=lin_solver, options=lin_solver_options) K.forward(v, d_v) # z_prev = z.copy() # Update z. # Update d_s r = d_v - d_u d_s += r res = np.linalg.norm(r)**2 t2 = time.time() curr_time += t2 - t1 # print(np.linalg.norm(u)) Kv_u = d_s.copy() offset = 0 for fn in psi_fns: slc = slice(offset, offset + fn.lin_op.size, None) Kv_u_slc = np.reshape(Kv_u[slc], fn.lin_op.shape) # Apply and time prox. prox_log[fn].tic() z[slc] = fn.prox(rho, Kv_u_slc, i).flatten() prox_log[fn].toc() offset += fn.lin_op.size d_unew = z.copy() # Check convergence. # K.adjoint(rho * (z - z_prev), r_com = np.linalg.norm(d_unew - d_v)**2 + np.linalg.norm(d_unew - d_u)**2 # K.adjoint((z-z_prev),s) # eps_pri = np.sqrt(output_size) * eps_abs + eps_rel * \ # max([np.linalg.norm(Kv), np.linalg.norm(z)]) # eps_dual = np.sqrt(input_size) * eps_abs + eps_rel * np.linalg.norm(KTu) / rho # Convergence log if convlog is not None: convlog.toc() K.update_vars(v) objval = sum([fn.value for fn in prox_fns]) convlog.record_objective(objval) t1 = time.time() if res < res_pre or reset == True: d_s_d = d_s.copy() res_pre = res r_com_pre = r_com reset = False tt = acc1.compute(d_s.flatten()) d_s = tt.reshape(d_s.shape) else: sign = sign + 1 d_s = d_s_d.copy() reset = True acc1.reset(d_s.flatten()) # Show progess if verbose > 0: # Evaluate objective only if required (expensive !) objstr = '' if verbose == 2: K.update_vars(v) objstr = ", obj_val = %02.03e" % sum( [fn.value for fn in prox_fns]) # Evaluate metric potentially metstr = '' if metric is None else ", {}".format( metric.message(v)) # print("iter %d: ||r||_2 = %.3f, eps_pri = %.3f, ||s||_2 = %.3f, eps_dual = %.3f%s%s" % ( # i, np.linalg.norm(r), eps_pri, np.linalg.norm(s), eps_dual, objstr, metstr)) print("iter %d: combine residual = %.8f" % (i, r_com)) t2 = time.time() curr_time += t2 - t1 Combine_res.append(np.sqrt(rho * r_com_pre / N_z)) total_time.append(curr_time) # Exit if converged. # if (res) < eps_abs: # break hm_src_path = 'dr-' + str(andersonmk) + '.txt' iter_num = [] iter_num.append(len(total_time)) iter_num.append(len(Combine_res)) with open(hm_src_path, 'w') as f: for i in range(0, min(iter_num)): f.write('%f\t%.20f\n' % (total_time[i], Combine_res[i])) f.close() # Print out timings info. if verbose > 0: print(iter_timing) print("prox funcs:") print(prox_log) print("K forward ops:") print(K.forward_log) print("K adjoint ops:") print(K.adjoint_log) # Assign values to variables. K.update_vars(v) # Return optimal value. # return sum([fn.value for fn in prox_fns]) return total_time, Combine_res
def solve(psi_fns, omega_fns, tau=None, sigma=None, theta=None, max_iters=1000, eps_abs=1e-3, eps_rel=1e-3, x0=None, lin_solver="cg", lin_solver_options=None, conv_check=100, try_diagonalize=True, try_fast_norm=False, scaled=True, metric=None, convlog=None, verbose=0): # Can only have one omega function. assert len(omega_fns) <= 1 prox_fns = psi_fns + omega_fns stacked_ops = vstack([fn.lin_op for fn in psi_fns]) K = CompGraph(stacked_ops) v = np.zeros(K.input_size) # Select optimal parameters if wanted if tau is None or sigma is None or theta is None: tau, sigma, theta = est_params_pc(K, tau, sigma, verbose, scaled, try_fast_norm) # Initialize x = np.zeros(K.input_size) y = np.zeros(K.output_size) xbar = np.zeros(K.input_size) u = np.zeros(K.output_size) z = np.zeros(K.output_size) if x0 is not None: x[:] = np.reshape(x0, K.input_size) K.forward(x, y) xbar[:] = x # Buffers. Kxbar = np.zeros(K.output_size) Kx = np.zeros(K.output_size) KTy = np.zeros(K.input_size) KTu = np.zeros(K.input_size) s = np.zeros(K.input_size) prev_x = x.copy() prev_Kx = Kx.copy() prev_z = z.copy() prev_u = u.copy() # Log for prox ops. prox_log = TimingsLog(prox_fns) # Time iterations. iter_timing = TimingsEntry("PC iteration") # Convergence log for initial iterate if convlog is not None: K.update_vars(x) objval = sum([fn.value for fn in prox_fns]) convlog.record_objective(objval) convlog.record_timing(0.0) for i in range(max_iters): iter_timing.tic() if convlog is not None: convlog.tic() # Keep track of previous iterates np.copyto(prev_x, x) np.copyto(prev_z, z) np.copyto(prev_u, u) np.copyto(prev_Kx, Kx) # Compute z K.forward(xbar, Kxbar) z = y + sigma * Kxbar # Update y. offset = 0 for fn in psi_fns: slc = slice(offset, offset + fn.lin_op.size, None) z_slc = np.reshape(z[slc], fn.lin_op.shape) # Moreau identity: apply and time prox. prox_log[fn].tic() y[slc] = (z_slc - sigma * fn.prox(sigma, z_slc / sigma, i)).flatten() prox_log[fn].toc() offset += fn.lin_op.size y[offset:] = 0 # Update x K.adjoint(y, KTy) x -= tau * KTy if len(omega_fns) > 0: xtmp = np.reshape(x, omega_fns[0].lin_op.shape) x[:] = omega_fns[0].prox(1.0 / tau, xtmp, x_init=prev_x, lin_solver=lin_solver, options=lin_solver_options).flatten() # Update xbar np.copyto(xbar, x) xbar += theta * (x - prev_x) # Convergence log if convlog is not None: convlog.toc() K.update_vars(x) objval = sum([fn.value for fn in prox_fns]) convlog.record_objective(objval) """ Old convergence check #Very basic convergence check. r_x = np.linalg.norm(x - prev_x) r_xbar = np.linalg.norm(xbar - prev_xbar) r_ybar = np.linalg.norm(y - prev_y) error = r_x + r_xbar + r_ybar """ # Residual based convergence check K.forward(x, Kx) u = 1.0 / sigma * y + theta * (Kx - prev_Kx) z = prev_u + prev_Kx - 1.0 / sigma * y # Iteration order is different than # lin-admm (--> start checking at iteration 1) if i > 0 and i % conv_check == 0: # Check convergence r = prev_Kx - z K.adjoint(sigma * (z - prev_z), s) eps_pri = np.sqrt(K.output_size) * eps_abs + eps_rel * \ max([np.linalg.norm(prev_Kx), np.linalg.norm(z)]) K.adjoint(u, KTu) eps_dual = np.sqrt( K.input_size) * eps_abs + eps_rel * np.linalg.norm(KTu) / sigma # Progress if verbose > 0: # Evaluate objective only if required (expensive !) objstr = '' if verbose == 2: K.update_vars(x) objstr = ", obj_val = %02.03e" % sum( [fn.value for fn in prox_fns]) """ Old convergence check #Evaluate metric potentially metstr = '' if metric is None else ", {}".format( metric.message(x.copy()) ) print "iter [%04d]:" \ "||x - x_prev||_2 = %02.02e " \ "||xbar - xbar_prev||_2 = %02.02e " \ "||y - y_prev||_2 = %02.02e " \ "SUM = %02.02e (eps=%02.03e)%s%s" \ % (i, r_x, r_xbar, r_ybar, error, eps, objstr, metstr) """ # Evaluate metric potentially metstr = '' if metric is None else ", {}".format( metric.message(v)) print( "iter %d: ||r||_2 = %.3f, eps_pri = %.3f, ||s||_2 = %.3f, eps_dual = %.3f%s%s" % (i, np.linalg.norm(r), eps_pri, np.linalg.norm(s), eps_dual, objstr, metstr)) iter_timing.toc() if np.linalg.norm(r) <= eps_pri and np.linalg.norm(s) <= eps_dual: break else: iter_timing.toc() """ Old convergence check if error <= eps: break """ # Print out timings info. if verbose > 0: print(iter_timing) print("prox funcs:") print(prox_log) print("K forward ops:") print(K.forward_log) print("K adjoint ops:") print(K.adjoint_log) # Assign values to variables. K.update_vars(x) # Return optimal value. return sum([fn.value for fn in prox_fns])
def solve(psi_fns, omega_fns, rho=1.0, max_iters=1000, eps_abs=1e-1, eps_rel=1e-3, x0=None, lin_solver="cg", lin_solver_options=None, try_diagonalize=True, try_fast_norm=False, scaled=True, metric=None, convlog=None, verbose=0): prox_fns = psi_fns + omega_fns stacked_ops = vstack([fn.lin_op for fn in psi_fns]) K = CompGraph(stacked_ops) # Rescale so (rho/2)||x - b||^2_2 rescaling = np.sqrt(2. / rho) quad_ops = [] const_terms = [] for fn in omega_fns: fn = fn.absorb_params() quad_ops.append(scale(rescaling * fn.beta, fn.lin_op)) const_terms.append(fn.b.flatten() * rescaling) # Check for fast inverse. op_list = [func.lin_op for func in psi_fns] + quad_ops stacked_ops = vstack(op_list) # Get optimize inverse (tries spatial and frequency diagonalization) v_update = get_least_squares_inverse(op_list, None, try_diagonalize, verbose) # Initialize everything to zero. input_size = K.input_size output_size = K.output_size v = np.zeros(input_size) z = np.zeros(output_size) u = np.zeros(output_size) N_z = len(z[:]) print(input_size) print(output_size) # Initialize if x0 is not None: v[:] = np.reshape(x0, input_size) K.forward(v, z) # Buffers. Kv = np.zeros(output_size) KTu = np.zeros(input_size) s = np.zeros(input_size) Kv_pre = Kv.copy() # Log for prox ops. prox_log = TimingsLog(prox_fns) # Time iterations. iter_timing = TimingsEntry("ADMM iteration") # Convergence log for initial iterate if convlog is not None: K.update_vars(v) objval = sum([func.value for func in prox_fns]) convlog.record_objective(objval) convlog.record_timing(0.0) res_pre = 9e20 res = 0 curr_time = 0 total_time = [] Combine_res = [] # ------------------------------------------------------------------------------------ for i in range(max_iters): # iter_timing.tic() t1 = time.time() if convlog is not None: convlog.tic() K.forward(v, Kv) Kv_pre = Kv.copy() # z_prev = z.copy() # Update z. K.forward(v, Kv) Kv_u = Kv + u offset = 0 for fn in psi_fns: tmp = np.hstack([z - u] + const_terms) v = v_update.solve(tmp, x_init=v, lin_solver=lin_solver, options=lin_solver_options) K.forward(v, Kv) Kv_u = Kv + u slc = slice(offset, offset + fn.lin_op.size, None) Kv_u_slc = np.reshape(Kv_u[slc], fn.lin_op.shape) # Apply and time prox. z_pre = z.copy() prox_log[fn].tic() z[slc] = fn.prox(rho, Kv_u_slc, i).flatten() prox_log[fn].toc() offset += fn.lin_op.size # Update v. # Check convergence. r = Kv - z # Update u. u += r K.adjoint(u, KTu) # K.adjoint(rho * (z - z_prev), s) s = z - z_pre t2 = time.time() curr_time += t2 - t1 res = np.linalg.norm(r)**2 + np.linalg.norm(s)**2 # K.adjoint((z-z_prev),s) # eps_pri = np.sqrt(output_size) * eps_abs + eps_rel * \ # max([np.linalg.norm(Kv), np.linalg.norm(z)]) # eps_dual = np.sqrt(input_size) * eps_abs + eps_rel * np.linalg.norm(KTu) / rho # Convergence log if convlog is not None: convlog.toc() K.update_vars(v) objval = sum([fn.value for fn in prox_fns]) convlog.record_objective(objval) # Show progess if verbose > 0: # Evaluate objective only if required (expensive !) objstr = '' if verbose == 2: K.update_vars(v) objstr = ", obj_val = %02.03e" % sum( [fn.value for fn in prox_fns]) # Evaluate metric potentially metstr = '' if metric is None else ", {}".format(metric.message(v)) # print("iter %d: ||r||_2 = %.3f, eps_pri = %.3f, ||s||_2 = %.3f, eps_dual = %.3f%s%s" % ( # i, np.linalg.norm(r), eps_pri, np.linalg.norm(s), eps_dual, objstr, metstr)) print("iter %d: combine residual = %.8f" % (i, res)) #curr_time = curr_time + iter_timing.toc() Combine_res.append(np.sqrt(rho * res / N_z)) total_time.append(curr_time) # Exit if converged. if (res) < eps_abs: break # Print out timings info. if verbose > 0: print(iter_timing) print("prox funcs:") print(prox_log) print("K forward ops:") print(K.forward_log) print("K adjoint ops:") print(K.adjoint_log) # Assign values to variables. K.update_vars(v) # Return optimal value. # return sum([fn.value for fn in prox_fns]) return total_time, Combine_res
def solve(psi_fns, omega_fns, rho_0=1.0, rho_scale=math.sqrt(2.0) * 2.0, rho_max=2**8, max_iters=-1, max_inner_iters=100, x0=None, eps_rel=1e-3, eps_abs=1e-3, lin_solver="cg", lin_solver_options=None, try_diagonalize=True, scaled=False, try_fast_norm=False, metric=None, convlog=None, verbose=0): prox_fns = psi_fns + omega_fns stacked_ops = vstack([fn.lin_op for fn in psi_fns]) K = CompGraph(stacked_ops) # Rescale so (1/2)||x - b||^2_2 rescaling = np.sqrt(2.) quad_ops = [] quad_weights = [] const_terms = [] for fn in omega_fns: fn = fn.absorb_params() quad_ops.append(scale(rescaling * fn.beta, fn.lin_op)) quad_weights.append(rescaling * fn.beta) const_terms.append(fn.b.flatten() * rescaling) # Get optimize inverse (tries spatial and frequency diagonalization) op_list = [func.lin_op for func in psi_fns] + quad_ops stacked_ops = vstack(op_list) x_update = get_least_squares_inverse(op_list, None, try_diagonalize, verbose) # Initialize if x0 is not None: x = np.reshape(x0, K.input_size) else: x = np.zeros(K.input_size) Kx = np.zeros(K.output_size) w = Kx.copy() # Temporary iteration counts x_prev = x.copy() # Log for prox ops. prox_log = TimingsLog(prox_fns) # Time iterations. iter_timing = TimingsEntry("HQS iteration") inner_iter_timing = TimingsEntry("HQS inner iteration") # Convergence log for initial iterate if convlog is not None: K.update_vars(x) objval = sum([func.value for func in prox_fns]) convlog.record_objective(objval) convlog.record_timing(0.0) # Rho scedule rho = rho_0 i = 0 while rho < rho_max and i < max_iters: iter_timing.tic() if convlog is not None: convlog.tic() # Update rho for quadratics for idx, op in enumerate(quad_ops): op.scalar = quad_weights[idx] / np.sqrt(rho) x_update = get_least_squares_inverse(op_list, CompGraph(stacked_ops), try_diagonalize, verbose) for ii in range(max_inner_iters): inner_iter_timing.tic() # Update Kx. K.forward(x, Kx) # Prox update to get w. offset = 0 w_prev = w.copy() for fn in psi_fns: slc = slice(offset, offset + fn.lin_op.size, None) # Apply and time prox. prox_log[fn].tic() w[slc] = fn.prox(rho, np.reshape(Kx[slc], fn.lin_op.shape), ii).flatten() prox_log[fn].toc() offset += fn.lin_op.size # Update x. x_prev[:] = x tmp = np.hstack([w] + [cterm / np.sqrt(rho) for cterm in const_terms]) x = x_update.solve(tmp, x_init=x, lin_solver=lin_solver, options=lin_solver_options) # Very basic convergence check. r_x = np.linalg.norm(x_prev - x) eps_x = eps_rel * np.prod(K.input_size) r_w = np.linalg.norm(w_prev - w) eps_w = eps_rel * np.prod(K.output_size) # Convergence log if convlog is not None: convlog.toc() K.update_vars(x) objval = sum([fn.value for fn in prox_fns]) convlog.record_objective(objval) # Show progess if verbose > 0: # Evaluate objective only if required (expensive !) objstr = '' if verbose == 2: K.update_vars(x) objstr = ", obj_val = %02.03e" % sum( [fn.value for fn in prox_fns]) # Evaluate metric potentially metstr = '' if metric is None else ", {}".format( metric.message(x)) print("iter [%02d (rho=%2.1e) || %02d]:" "||w - w_prev||_2 = %02.02e (eps=%02.03e)" "||x - x_prev||_2 = %02.02e (eps=%02.03e)%s%s" % (i, rho, ii, r_x, eps_x, r_w, eps_w, objstr, metstr)) inner_iter_timing.toc() if r_x < eps_x and r_w < eps_w: break # Update rho rho = np.minimum(rho * rho_scale, rho_max) i += 1 iter_timing.toc() # Print out timings info. if verbose > 0: print(iter_timing) print(inner_iter_timing) print("prox funcs:") print(prox_log) print("K forward ops:") print(K.forward_log) print("K adjoint ops:") print(K.adjoint_log) # Assign values to variables. K.update_vars(x) # Return optimal value. return sum([fn.value for fn in prox_fns])
def solve(psi_fns, omega_fns, tau=None, sigma=None, theta=None, max_iters=1000, eps_abs=1e-3, eps_rel=1e-3, x0=None, lin_solver="cg", lin_solver_options=None, conv_check=100, try_diagonalize=True, try_fast_norm=False, scaled=True, implem=None, metric=None, convlog=None, verbose=0, callback=None, adapter=NumpyAdapter()): # Can only have one omega function. assert len(omega_fns) <= 1 prox_fns = psi_fns + omega_fns stacked_ops = vstack([fn.lin_op for fn in psi_fns]) K = CompGraph(stacked_ops, implem=implem) #graph_visualize(prox_fns) if adapter.implem() == 'numpy': K_forward = K.forward K_adjoint = K.adjoint prox_off_and_fac = lambda offset, factor, fn, *args, **kw: ne.evaluate( 'x*a+b', { 'x': fn.prox(*args, **kw), 'a': factor, 'b': offset }) prox = lambda fn, *args, **kw: fn.prox(*args, **kw) elif adapter.implem() == 'pycuda': K_forward = K.forward_cuda K_adjoint = K.adjoint_cuda prox_off_and_fac = lambda offset, factor, fn, *args, **kw: fn.prox_cuda( *args, offset=offset, factor=factor, **kw) prox = lambda fn, *args, **kw: fn.prox_cuda(*args, **kw) else: raise RuntimeError("Implementation %s unknown" % adapter.implem()) # Select optimal parameters if wanted if tau is None or sigma is None or theta is None: tau, sigma, theta = est_params_pc(K, tau, sigma, verbose, scaled, try_fast_norm) elif callable(tau) or callable(sigma) or callable(theta): if scaled: L = 1 else: L = est_CompGraph_norm(K, try_fast_norm) # Initialize x = adapter.zeros(K.input_size) y = adapter.zeros(K.output_size) xbar = adapter.zeros(K.input_size) u = adapter.zeros(K.output_size) z = adapter.zeros(K.output_size) if x0 is not None: x[:] = adapter.reshape(adapter.from_np(x0), K.input_size) else: x[:] = adapter.from_np(K.x0()) K_forward(x, y) xbar[:] = x # Buffers. Kxbar = adapter.zeros(K.output_size) Kx = adapter.zeros(K.output_size) KTy = adapter.zeros(K.input_size) KTu = adapter.zeros(K.input_size) s = adapter.zeros(K.input_size) prev_x = x.copy() prev_Kx = Kx.copy() prev_z = z.copy() prev_u = u.copy() # Log for prox ops. prox_log = TimingsLog(prox_fns) prox_log_tot = TimingsLog(prox_fns) # Time iterations. iter_timing = TimingsLog([ "pc_iteration_tot", "copyprev", "calcz", "calcx", "omega_fn", "xbar", "conv_check" ]) # Convergence log for initial iterate if convlog is not None: K.update_vars(adapter.to_np(x)) objval = 0.0 for f in prox_fns: evp = f.value #print(str(f), '->', f.value) objval += evp convlog.record_objective(objval) convlog.record_timing(0.0) for i in range(max_iters): iter_timing["pc_iteration_tot"].tic() if convlog is not None: convlog.tic() if callable(sigma): csigma = sigma(i, L) else: csigma = sigma if callable(tau): ctau = tau(i, L) else: ctau = tau if callable(theta): ctheta = theta(i, L) else: ctheta = theta csigma = adapter.scalar(csigma) ctau = adapter.scalar(ctau) ctheta = adapter.scalar(ctheta) # Keep track of previous iterates iter_timing["copyprev"].tic() adapter.copyto(prev_x, x) adapter.copyto(prev_z, z) adapter.copyto(prev_u, u) adapter.copyto(prev_Kx, Kx) iter_timing["copyprev"].toc() # Compute z iter_timing["calcz"].tic() K_forward(xbar, Kxbar) ne.evaluate('y + csigma * Kxbar', out=z) iter_timing["calcz"].toc() # Update y. offset = 0 for fn in psi_fns: prox_log_tot[fn].tic() slc = slice(offset, offset + fn.lin_op.size, None) z_slc = adapter.reshape(z[slc], fn.lin_op.shape) # Moreau identity: apply and time prox. prox_log[fn].tic() y[slc] = adapter.flatten( prox_off_and_fac(z_slc, -csigma, fn, csigma, z_slc / csigma, i)) prox_log[fn].toc() offset += fn.lin_op.size prox_log_tot[fn].toc() iter_timing["calcx"].tic() if offset < y.shape[0]: y[offset:] = 0 # Update x K_adjoint(y, KTy) ne.evaluate('x - ctau * KTy', out=x) iter_timing["calcx"].toc() iter_timing["omega_fn"].tic() if len(omega_fns) > 0: fn = omega_fns[0] prox_log_tot[fn].tic() xtmp = adapter.reshape(x, fn.lin_op.shape) prox_log[fn].tic() if adapter.implem() == 'numpy': # ravel() avoids a redundant memcpy x[:] = prox(fn, 1.0 / ctau, xtmp, x_init=prev_x, lin_solver=lin_solver, options=lin_solver_options).ravel() else: x[:] = adapter.flatten( prox(fn, 1.0 / ctau, xtmp, x_init=prev_x, lin_solver=lin_solver, options=lin_solver_options)) prox_log[fn].toc() prox_log_tot[fn].toc() iter_timing["omega_fn"].toc() iter_timing["xbar"].tic() # Update xbar ne.evaluate('x + ctheta * (x - prev_x)', out=xbar) iter_timing["xbar"].toc() # Convergence log if convlog is not None: convlog.toc() K.update_vars(adapter.to_np(x)) objval = list([fn.value for fn in prox_fns]) objval = sum(objval) convlog.record_objective(objval) # Residual based convergence check if i % conv_check in [0, conv_check - 1]: iter_timing["conv_check"].tic() K_forward(x, Kx) ne.evaluate('y / csigma + ctheta * (Kx - prev_Kx)', out=u, casting='unsafe') ne.evaluate('prev_u + prev_Kx - y / csigma', out=z, casting='unsafe') iter_timing["conv_check"].toc() # Iteration order is different than # lin-admm (--> start checking at iteration 1) if i > 0 and i % conv_check == 0: # Check convergence r = ne.evaluate('prev_Kx - z') dz = ne.evaluate('csigma * (z - prev_z)') K_adjoint(dz, s) eps_pri = np.sqrt(K.output_size) * eps_abs + eps_rel * \ max([np.linalg.norm(prev_Kx), np.linalg.norm(z)]) K_adjoint(u, KTu) eps_dual = np.sqrt( K.input_size) * eps_abs + eps_rel * np.linalg.norm( KTu) / csigma if not callback is None or verbose == 2: K.update_vars(adapter.to_np(x)) if not callback is None: callback(adapter.to_np(x)) # Progress if verbose > 0: # Evaluate objective only if required (expensive !) objstr = '' if verbose == 2: ov = list([fn.value for fn in prox_fns]) objval = sum(ov) objstr = ", obj_val = %02.03e [%s] " % (objval, ", ".join( "%02.03e" % x for x in ov)) # Evaluate metric potentially metstr = '' if metric is None else ", {}".format( metric.message(v)) print( "iter %d: ||r||_2 = %.3f, eps_pri = %.3f, ||s||_2 = %.3f, eps_dual = %.3f%s%s" % (i, np.linalg.norm(adapter.to_np(r)), eps_pri, np.linalg.norm( adapter.to_np(s)), eps_dual, objstr, metstr)) iter_timing["pc_iteration_tot"].toc() if np.linalg.norm(adapter.to_np(r)) <= eps_pri and np.linalg.norm( adapter.to_np(s)) <= eps_dual: break else: iter_timing["pc_iteration_tot"].toc() # Print out timings info. if verbose > 0: print(iter_timing) print("prox funcs total:") print(prox_log_tot) print("prox funcs inner:") print(prox_log) print("K forward ops:") print(K.forward_log) print("K adjoint ops:") print(K.adjoint_log) # Assign values to variables. K.update_vars(adapter.to_np(x)) if not callback is None: callback(adapter.to_np(x)) # Return optimal value. return sum([fn.value for fn in prox_fns])
def solve(psi_fns, omega_fns, tau=None, sigma=None, theta=None, max_iters=1000, eps_abs=1e-3, eps_rel=1e-3, x0=None, lin_solver="cg", lin_solver_options=None, conv_check=100, try_diagonalize=True, try_fast_norm=False, scaled=True, metric=None, convlog=None, verbose=0, callback=None, adapter = NumpyAdapter()): # Can only have one omega function. assert len(omega_fns) <= 1 prox_fns = psi_fns + omega_fns stacked_ops = vstack([fn.lin_op for fn in psi_fns]) K = CompGraph(stacked_ops) #graph_visualize(prox_fns) if adapter.implem() == 'numpy': K_forward = K.forward K_adjoint = K.adjoint prox_off_and_fac = lambda offset, factor, fn, *args, **kw: offset + factor*fn.prox(*args, **kw) prox = lambda fn, *args, **kw: fn.prox(*args, **kw) elif adapter.implem() == 'pycuda': K_forward = K.forward_cuda K_adjoint = K.adjoint_cuda prox_off_and_fac = lambda offset, factor, fn, *args, **kw: fn.prox_cuda(*args, offset=offset, factor=factor, **kw) prox = lambda fn, *args, **kw: fn.prox_cuda(*args, **kw) else: raise RuntimeError("Implementation %s unknown" % adapter.implem()) # Select optimal parameters if wanted if tau is None or sigma is None or theta is None: tau, sigma, theta = est_params_pc(K, tau, sigma, verbose, scaled, try_fast_norm) elif callable(tau) or callable(sigma) or callable(theta): if scaled: L = 1 else: L = est_CompGraph_norm(K, try_fast_norm) # Initialize x = adapter.zeros(K.input_size) y = adapter.zeros(K.output_size) xbar = adapter.zeros(K.input_size) u = adapter.zeros(K.output_size) z = adapter.zeros(K.output_size) if x0 is not None: x[:] = adapter.reshape(adapter.from_np(x0), K.input_size) else: x[:] = adapter.from_np(K.x0()) K_forward(x, y) xbar[:] = x # Buffers. Kxbar = adapter.zeros(K.output_size) Kx = adapter.zeros(K.output_size) KTy = adapter.zeros(K.input_size) KTu = adapter.zeros(K.input_size) s = adapter.zeros(K.input_size) prev_x = x.copy() prev_Kx = Kx.copy() prev_z = z.copy() prev_u = u.copy() # Log for prox ops. prox_log = TimingsLog(prox_fns) prox_log_tot = TimingsLog(prox_fns) # Time iterations. iter_timing = TimingsLog(["pc_iteration_tot", "copyprev", "calcz", "calcx", "omega_fn", "xbar", "conv_check"]) # Convergence log for initial iterate if convlog is not None: K.update_vars(adapter.to_np(x)) objval = 0.0 for f in prox_fns: evp = f.value #print(str(f), '->', f.value) objval += evp convlog.record_objective(objval) convlog.record_timing(0.0) for i in range(max_iters): iter_timing["pc_iteration_tot"].tic() if convlog is not None: convlog.tic() if callable(sigma): csigma = sigma(i, L) else: csigma = sigma if callable(tau): ctau = tau(i, L) else: ctau = tau if callable(theta): ctheta = theta(i, L) else: ctheta = theta csigma = adapter.scalar(csigma) ctau = adapter.scalar(ctau) ctheta = adapter.scalar(ctheta) # Keep track of previous iterates iter_timing["copyprev"].tic() adapter.copyto(prev_x, x) adapter.copyto(prev_z, z) adapter.copyto(prev_u, u) adapter.copyto(prev_Kx, Kx) iter_timing["copyprev"].toc() # Compute z iter_timing["calcz"].tic() K_forward(xbar, Kxbar) z = y + csigma * Kxbar iter_timing["calcz"].toc() # Update y. offset = 0 for fn in psi_fns: prox_log_tot[fn].tic() slc = slice(offset, offset + fn.lin_op.size, None) z_slc = adapter.reshape(z[slc], fn.lin_op.shape) # Moreau identity: apply and time prox. prox_log[fn].tic() y[slc] = adapter.flatten( prox_off_and_fac(z_slc, -csigma, fn, csigma, z_slc / csigma, i) ) prox_log[fn].toc() offset += fn.lin_op.size prox_log_tot[fn].toc() iter_timing["calcx"].tic() if offset < y.shape[0]: y[offset:] = 0 # Update x K_adjoint(y, KTy) x -= ctau * KTy iter_timing["calcx"].toc() iter_timing["omega_fn"].tic() if len(omega_fns) > 0: fn = omega_fns[0] prox_log_tot[fn].tic() xtmp = adapter.reshape(x, fn.lin_op.shape) prox_log[fn].tic() x[:] = adapter.flatten( prox(fn, adapter.scalar(1.0) / ctau, xtmp, x_init=prev_x, lin_solver=lin_solver, options=lin_solver_options) ) prox_log[fn].toc() prox_log_tot[fn].toc() iter_timing["omega_fn"].toc() iter_timing["xbar"].tic() # Update xbar adapter.copyto(xbar, x) xbar += ctheta * (x - prev_x) iter_timing["xbar"].toc() # Convergence log if convlog is not None: convlog.toc() K.update_vars(adapter.to_np(x)) objval = list([fn.value for fn in prox_fns]) objval = sum(objval) convlog.record_objective(objval) """ Old convergence check #Very basic convergence check. r_x = np.linalg.norm(x - prev_x) r_xbar = np.linalg.norm(xbar - prev_xbar) r_ybar = np.linalg.norm(y - prev_y) error = r_x + r_xbar + r_ybar """ # Residual based convergence check if i % conv_check in [0, conv_check-1]: iter_timing["conv_check"].tic() K_forward(x, Kx) u = adapter.scalar(1.0) / csigma * y + ctheta * (Kx - prev_Kx) z = prev_u + prev_Kx - adapter.scalar(1.0) / csigma * y iter_timing["conv_check"].toc() # Iteration order is different than # lin-admm (--> start checking at iteration 1) if i > 0 and i % conv_check == 0: # Check convergence r = prev_Kx - z K_adjoint(csigma * (z - prev_z), s) eps_pri = np.sqrt(K.output_size) * eps_abs + eps_rel * \ max([np.linalg.norm(adapter.to_np(prev_Kx)), np.linalg.norm(adapter.to_np(z))]) K_adjoint(u, KTu) eps_dual = np.sqrt(K.input_size) * eps_abs + eps_rel * np.linalg.norm(adapter.to_np(KTu)) / csigma if not callback is None or verbose == 2: K.update_vars(adapter.to_np(x)) if not callback is None: callback(adapter.to_np(x)) # Progress if verbose > 0: # Evaluate objective only if required (expensive !) objstr = '' if verbose == 2: ov = list([fn.value for fn in prox_fns]) objval = sum(ov) objstr = ", obj_val = %02.03e [%s] " % (objval, ", ".join("%02.03e" % x for x in ov)) """ Old convergence check #Evaluate metric potentially metstr = '' if metric is None else ", {}".format( metric.message(x.copy()) ) print "iter [%04d]:" \ "||x - x_prev||_2 = %02.02e " \ "||xbar - xbar_prev||_2 = %02.02e " \ "||y - y_prev||_2 = %02.02e " \ "SUM = %02.02e (eps=%02.03e)%s%s" \ % (i, r_x, r_xbar, r_ybar, error, eps, objstr, metstr) """ # Evaluate metric potentially metstr = '' if metric is None else ", {}".format(metric.message(v)) print( "iter %d: ||r||_2 = %.3f, eps_pri = %.3f, ||s||_2 = %.3f, eps_dual = %.3f%s%s" % (i, np.linalg.norm(adapter.to_np(r)), eps_pri, np.linalg.norm(adapter.to_np(s)), eps_dual, objstr, metstr) ) iter_timing["pc_iteration_tot"].toc() if np.linalg.norm(adapter.to_np(r)) <= eps_pri and np.linalg.norm(adapter.to_np(s)) <= eps_dual: break else: iter_timing["pc_iteration_tot"].toc() """ Old convergence check if error <= eps: break """ # Print out timings info. if verbose > 0: print(iter_timing) print("prox funcs total:") print(prox_log_tot) print("prox funcs inner:") print(prox_log) print("K forward ops:") print(K.forward_log) print("K adjoint ops:") print(K.adjoint_log) # Assign values to variables. K.update_vars(adapter.to_np(x)) if not callback is None: callback(adapter.to_np(x)) # Return optimal value. return sum([fn.value for fn in prox_fns])
def solve(psi_fns, omega_fns, rho=1.0, max_iters=1000, eps_abs=1e-3, eps_rel=1e-3, x0=None, lin_solver="cg", lin_solver_options=None, try_diagonalize=True, try_fast_norm=False, scaled=True, conv_check=100, metric=None, convlog=None, verbose=0): prox_fns = psi_fns + omega_fns stacked_ops = vstack([fn.lin_op for fn in psi_fns]) K = CompGraph(stacked_ops) # Rescale so (rho/2)||x - b||^2_2 rescaling = np.sqrt(2. / rho) quad_ops = [] const_terms = [] for fn in omega_fns: fn = fn.absorb_params() quad_ops.append(scale(rescaling * fn.beta, fn.lin_op)) const_terms.append(fn.b.flatten() * rescaling) # Check for fast inverse. op_list = [func.lin_op for func in psi_fns] + quad_ops stacked_ops = vstack(op_list) # Get optimize inverse (tries spatial and frequency diagonalization) v_update = get_least_squares_inverse(op_list, None, try_diagonalize, verbose) # Initialize everything to zero. v = np.zeros(K.input_size) z = np.zeros(K.output_size) u = np.zeros(K.output_size) # Initialize if x0 is not None: v[:] = np.reshape(x0, K.input_size) K.forward(v, z) # Buffers. Kv = np.zeros(K.output_size) KTu = np.zeros(K.input_size) s = np.zeros(K.input_size) # Log for prox ops. prox_log = TimingsLog(prox_fns) # Time iterations. iter_timing = TimingsEntry("ADMM iteration") # Convergence log for initial iterate if convlog is not None: K.update_vars(v) objval = sum([func.value for func in prox_fns]) convlog.record_objective(objval) convlog.record_timing(0.0) for i in range(max_iters): iter_timing.tic() if convlog is not None: convlog.tic() z_prev = z.copy() # Update v. tmp = np.hstack([z - u] + const_terms) v = v_update.solve(tmp, x_init=v, lin_solver=lin_solver, options=lin_solver_options) # Update z. K.forward(v, Kv) Kv_u = Kv + u offset = 0 for fn in psi_fns: slc = slice(offset, offset + fn.lin_op.size, None) Kv_u_slc = np.reshape(Kv_u[slc], fn.lin_op.shape) # Apply and time prox. prox_log[fn].tic() z[slc] = fn.prox(rho, Kv_u_slc, i).flatten() prox_log[fn].toc() offset += fn.lin_op.size # Update u. u += Kv - z # Check convergence. if i % conv_check == 0: r = Kv - z K.adjoint(u, KTu) K.adjoint(rho * (z - z_prev), s) eps_pri = np.sqrt(K.output_size) * eps_abs + eps_rel * \ max([np.linalg.norm(Kv), np.linalg.norm(z)]) eps_dual = np.sqrt(K.input_size) * eps_abs + eps_rel * np.linalg.norm(KTu) * rho # Convergence log if convlog is not None: convlog.toc() K.update_vars(v) objval = sum([fn.value for fn in prox_fns]) convlog.record_objective(objval) # Show progess if verbose > 0 and i % conv_check == 0: # Evaluate objective only if required (expensive !) objstr = '' if verbose == 2: K.update_vars(v) objstr = ", obj_val = %02.03e" % sum([fn.value for fn in prox_fns]) # Evaluate metric potentially metstr = '' if metric is None else ", {}".format(metric.message(v)) print("iter %d: ||r||_2 = %.3f, eps_pri = %.3f, ||s||_2 = %.3f, eps_dual = %.3f%s%s" % ( i, np.linalg.norm(r), eps_pri, np.linalg.norm(s), eps_dual, objstr, metstr)) iter_timing.toc() # Exit if converged. if np.linalg.norm(r) <= eps_pri and np.linalg.norm(s) <= eps_dual: break # Print out timings info. if verbose > 0: print(iter_timing) print("prox funcs:") print(prox_log) print("K forward ops:") print(K.forward_log) print("K adjoint ops:") print(K.adjoint_log) # Assign values to variables. K.update_vars(v) # Return optimal value. return sum([fn.value for fn in prox_fns])