1use crate::estimate::EstimationError;
2use crate::estimate::{FitGeometry, UnifiedFitResult};
3use crate::pirls;
4use faer::Mat as FaerMat;
5use faer::linalg::matmul::matmul;
6use faer::prelude::ReborrowMut;
7use faer::{Accum, Par};
8use gam_linalg::faer_ndarray::{FaerArrayView, FaerCholesky};
9use gam_linalg::matrix::{PsdWeightsView, SignedWeightsView};
10use gam_linalg::utils::StableSolver;
11use gam_problem::LinkFunction;
12use ndarray::{Array1, Array2, ArrayView1, ShapeBuilder, s};
13use std::fmt;
14
15#[derive(Debug, Clone)]
24pub enum AloError {
25 InvalidInput { reason: String },
29 WeightInvalid { reason: String },
32 DesignDegenerate { reason: String },
35 InfluenceMatrixFailed { condition_number: f64 },
38 LooComputationFailed { reason: String },
41}
42
43impl fmt::Display for AloError {
44 fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
45 match self {
46 AloError::InvalidInput { reason }
47 | AloError::WeightInvalid { reason }
48 | AloError::DesignDegenerate { reason }
49 | AloError::LooComputationFailed { reason } => f.write_str(reason),
50 AloError::InfluenceMatrixFailed { condition_number } => {
51 write!(
52 f,
53 "ALO influence matrix failed (condition number {condition_number:.3e})"
54 )
55 }
56 }
57 }
58}
59
60impl std::error::Error for AloError {}
61
62impl From<AloError> for EstimationError {
63 fn from(err: AloError) -> EstimationError {
64 match err {
65 AloError::InvalidInput { reason }
66 | AloError::WeightInvalid { reason }
67 | AloError::DesignDegenerate { reason }
68 | AloError::LooComputationFailed { reason } => EstimationError::InvalidInput(reason),
69 AloError::InfluenceMatrixFailed { condition_number } => {
70 EstimationError::ModelIsIllConditioned { condition_number }
71 }
72 }
73 }
74}
75
76impl From<AloError> for String {
77 fn from(err: AloError) -> String {
78 err.to_string()
79 }
80}
81
82#[derive(Debug, Clone)]
84pub struct AloDiagnostics {
85 pub eta_tilde: Array1<f64>,
86 pub se_bayes: Array1<f64>,
89 pub se_sandwich: Array1<f64>,
92 pub pred_identity: Array1<f64>,
93 pub leverage: Array1<f64>,
94 pub fisherweights: Array1<f64>,
95}
96
97#[inline]
98fn alo_eta_updatewith_offset(
99 eta_hat: f64,
100 z: f64,
101 offset: f64,
102 x_hinv_x: f64,
103 score_weight: f64,
104 denom: f64,
105) -> f64 {
106 let eta_centered = eta_hat - offset;
109 let z_centered = z - offset;
110 let score = score_weight * (eta_centered - z_centered);
111 offset + eta_centered + x_hinv_x * score / denom
112}
113
114pub type AloScalarScoreCurvature<'a> = dyn Fn(usize, f64) -> (f64, f64) + Sync + 'a;
124
125const ALO_EXACT_SCALAR_MAX_ITERS: usize = 64;
131
132const ALO_EXACT_SCALAR_TOL: f64 = 1e-12;
136
137#[derive(Debug, Clone, Copy, PartialEq)]
158enum AloExactScalarError {
159 NonFiniteScoreCurvature {
160 eta: f64,
161 ell_prime: f64,
162 ell_double: f64,
163 },
164 DegenerateJacobian {
165 eta: f64,
166 jacobian: f64,
167 },
168 NonFiniteStep {
169 eta: f64,
170 residual: f64,
171 jacobian: f64,
172 next: f64,
173 },
174 MaxIterations {
175 iterations: usize,
176 residual: f64,
177 eta: f64,
178 },
179}
180
181impl fmt::Display for AloExactScalarError {
182 fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
183 match *self {
184 AloExactScalarError::NonFiniteScoreCurvature {
185 eta,
186 ell_prime,
187 ell_double,
188 } => write!(
189 f,
190 "non-finite score/curvature at eta={eta:.6e}: ell_prime={ell_prime:.6e}, ell_double={ell_double:.6e}"
191 ),
192 AloExactScalarError::DegenerateJacobian { eta, jacobian } => write!(
193 f,
194 "degenerate Newton Jacobian at eta={eta:.6e}: jacobian={jacobian:.6e}, min={ALO_DENOMINATOR_MIN:.1e}"
195 ),
196 AloExactScalarError::NonFiniteStep {
197 eta,
198 residual,
199 jacobian,
200 next,
201 } => write!(
202 f,
203 "non-finite Newton step from eta={eta:.6e}: residual={residual:.6e}, jacobian={jacobian:.6e}, next={next:.6e}"
204 ),
205 AloExactScalarError::MaxIterations {
206 iterations,
207 residual,
208 eta,
209 } => write!(
210 f,
211 "did not converge within {iterations} iterations: residual={residual:.6e}, eta={eta:.6e}, tol={ALO_EXACT_SCALAR_TOL:.1e}"
212 ),
213 }
214 }
215}
216
217const ALO_EXACT_SCALAR_BACKTRACKS: usize = 40;
223
224#[inline]
225fn alo_eta_exact_frozen_curvature(
226 eta_hat: f64,
227 a_ii: f64,
228 score_curvature: &dyn Fn(f64) -> (f64, f64),
229) -> Result<f64, AloExactScalarError> {
230 let residual_and_jac = |eta: f64| -> Result<(f64, f64), AloExactScalarError> {
254 let (ell_prime, ell_double) = score_curvature(eta);
255 if !ell_prime.is_finite() || !ell_double.is_finite() {
256 return Err(AloExactScalarError::NonFiniteScoreCurvature {
257 eta,
258 ell_prime,
259 ell_double,
260 });
261 }
262 Ok((eta - eta_hat - a_ii * ell_prime, 1.0 - a_ii * ell_double))
263 };
264
265 let mut eta = eta_hat;
266 let (mut residual, mut jac) = residual_and_jac(eta)?;
267 for _ in 0..ALO_EXACT_SCALAR_MAX_ITERS {
268 if residual.abs() <= ALO_EXACT_SCALAR_TOL {
269 return Ok(eta);
270 }
271 if jac.abs() <= ALO_DENOMINATOR_MIN || !jac.is_finite() {
272 return Err(AloExactScalarError::DegenerateJacobian { eta, jacobian: jac });
273 }
274 let step = residual / jac;
275 if !step.is_finite() {
276 return Err(AloExactScalarError::NonFiniteStep {
277 eta,
278 residual,
279 jacobian: jac,
280 next: eta - step,
281 });
282 }
283 let mut t = 1.0;
288 let mut advanced = false;
289 for _ in 0..ALO_EXACT_SCALAR_BACKTRACKS {
290 let trial = eta - t * step;
291 if let Ok((r_trial, j_trial)) = residual_and_jac(trial) {
292 if r_trial.abs() < residual.abs() {
293 eta = trial;
294 residual = r_trial;
295 jac = j_trial;
296 advanced = true;
297 break;
298 }
299 }
300 t *= 0.5;
301 }
302 if !advanced {
303 break;
304 }
305 }
306 Err(AloExactScalarError::MaxIterations {
307 iterations: ALO_EXACT_SCALAR_MAX_ITERS,
308 residual,
309 eta,
310 })
311}
312
313#[inline]
314fn bayesvar_eta(phi: f64, x_hinv_x: f64) -> f64 {
315 phi * x_hinv_x
316}
317
318#[inline]
319fn sandwichvar_eta_from_meat(phi: f64, meat_quad: f64) -> f64 {
320 phi * meat_quad
321}
322
323#[inline]
324fn variance_negative_tolerance(scale: f64) -> f64 {
325 1e-12 * scale.abs().max(1.0)
327}
328
329const LEVERAGE_HIGH_THRESHOLD: f64 = 0.99;
330const LEVERAGE_VERY_HIGH_THRESHOLD: f64 = 0.999;
331const LEVERAGE_RATE_THRESHOLDS: [f64; 3] = [0.90, 0.95, 0.99];
332const LEVERAGE_PERCENTILES: [f64; 3] = [0.50, 0.95, 0.99];
333const ALO_DENOMINATOR_MIN: f64 = 1e-12;
334const MULTIBLOCK_ALO_MEMORY_BUDGET_BYTES: usize = 256 * 1024 * 1024;
335
336const ALO_RHS_BLOCK_COLS: usize = 8192;
341
342const HESSIAN_SYMMETRY_REL_TOL: f64 = 1e-8;
348
349const ALO_LOCAL_BLOCK_RIDGE: f64 = 1e-6;
355
356const LU_PIVOT_SINGULAR_TOL: f64 = 1e-12;
361
362#[inline]
363fn percentile_index(sample_size: usize, quantile: f64) -> usize {
364 if sample_size <= 1 {
365 return 0;
366 }
367 let max_index = sample_size - 1;
368 ((quantile * max_index as f64).round() as usize).min(max_index)
369}
370
371#[inline]
372fn percentile_from_sorted(sorted: &[f64], quantile: f64) -> f64 {
373 if sorted.is_empty() {
374 0.0
375 } else {
376 sorted[percentile_index(sorted.len(), quantile)]
377 }
378}
379
380#[inline]
381fn multiblock_col_offsets(block_designs: &[Array2<f64>]) -> Vec<usize> {
382 let mut offsets = Vec::with_capacity(block_designs.len());
383 let mut off = 0usize;
384 for design in block_designs {
385 offsets.push(off);
386 off += design.ncols();
387 }
388 offsets
389}
390
391#[inline]
392fn multiblock_alo_parallel_leverage_chunk_size(
393 p_tot: usize,
394 n_blocks: usize,
395 n_obs: usize,
396 max_workers: usize,
397) -> usize {
398 if p_tot == 0 || n_blocks == 0 || n_obs == 0 {
399 return 1;
400 }
401
402 let workers = max_workers.max(1);
408 let per_worker_budget = (MULTIBLOCK_ALO_MEMORY_BUDGET_BYTES / workers).max(1);
409 let elem_count_per_obs = p_tot.saturating_mul(n_blocks.saturating_add(1)).max(1);
410 let bytes_per_obs = elem_count_per_obs
411 .saturating_mul(std::mem::size_of::<f64>())
412 .max(1);
413 let budget_obs = (per_worker_budget / bytes_per_obs).max(1);
414 budget_obs.min(n_obs)
415}
416
417fn compute_alo_diagnostics_from_pirls_impl(
418 base: &pirls::PirlsResult,
419 y: ArrayView1<f64>,
420 link: LinkFunction,
421) -> Result<AloDiagnostics, EstimationError> {
422 compute_alo_diagnostics_from_pirls_inner(base, y, link).map_err(EstimationError::from)
423}
424
425fn alo_link_needs_exact_curvature_refinement(likelihood: &gam_problem::GlmLikelihoodSpec) -> bool {
438 use gam_problem::ResponseFamily;
439 matches!(
440 (&likelihood.spec.response, likelihood.link_function()),
441 (ResponseFamily::Binomial, LinkFunction::Logit)
442 | (ResponseFamily::Poisson, LinkFunction::Log)
443 )
444}
445
446fn compute_alo_diagnostics_from_pirls_inner(
447 base: &pirls::PirlsResult,
448 y: ArrayView1<f64>,
449 link: LinkFunction,
450) -> Result<AloDiagnostics, AloError> {
451 let x_dense_arc = base
452 .x_transformed
453 .try_to_dense_arc("ALO diagnostics require dense transformed design")
454 .map_err(|reason| AloError::DesignDegenerate { reason })?;
455 let x_dense = x_dense_arc.as_ref();
456 let n = x_dense.nrows();
457
458 let phi = match link {
460 LinkFunction::Log => 1.0,
461 LinkFunction::Logit
462 | LinkFunction::Probit
463 | LinkFunction::CLogLog
464 | LinkFunction::Sas
465 | LinkFunction::BetaLogistic => 1.0,
466 LinkFunction::Identity => {
467 use rayon::iter::{IntoParallelIterator, ParallelIterator};
468 let rss: f64 = (0..n)
469 .into_par_iter()
470 .map(|i| {
471 let r = y[i] - base.finalmu[i];
472 base.finalweights[i] * r * r
473 })
474 .sum();
475 let n_pos = (0..n).filter(|&i| base.finalweights[i] > 0.0).count();
482 let dof = (n_pos as f64) - base.edf;
483 let denom = dof.max(1.0);
484 rss / denom
485 }
486 };
487
488 let e = &base.reparam_result.e_transformed;
489 let ridge = base.ridge_passport.laplacehessianridge().max(0.0);
490
491 let h_dense_for_alo = base
495 .dense_stabilizedhessian_transformed(
496 "ALO diagnostics require exact dense stabilized penalized Hessian",
497 )
498 .map_err(|e| match e {
499 EstimationError::InvalidInput(reason) => AloError::InvalidInput { reason },
500 other => AloError::InvalidInput {
501 reason: format!("{other:?}"),
502 },
503 })?;
504
505 let canonical_scale: Option<Array1<f64>> =
524 if alo_link_needs_exact_curvature_refinement(&base.likelihood) {
525 let mut c = Array1::<f64>::zeros(n);
526 for i in 0..n {
527 let dmu = base.solve_dmu_deta[i];
528 let w_h = base.finalweights[i];
529 c[i] = if dmu.abs() <= ALO_DENOMINATOR_MIN || !dmu.is_finite() || !w_h.is_finite() {
530 f64::NAN
531 } else {
532 w_h / dmu
533 };
534 }
535 Some(c)
536 } else {
537 None
538 };
539
540 let inv_link_for_closure = base.likelihood.spec.link.clone();
541 let score_curvature_closure = canonical_scale.as_ref().map(|scale| {
542 move |i: usize, eta: f64| -> (f64, f64) {
543 let (mu, dmu) = crate::mixture_link::inverse_link_mu_d1_for_inverse_link(
544 &inv_link_for_closure,
545 eta,
546 )
547 .unwrap_or((f64::NAN, f64::NAN));
548 let c_i = scale[i];
549 (c_i * (mu - y[i]), c_i * dmu)
550 }
551 });
552 let score_curvature_ref: Option<&AloScalarScoreCurvature> = score_curvature_closure
553 .as_ref()
554 .map(|f| f as &AloScalarScoreCurvature);
555
556 let input = AloInput {
558 design: x_dense,
559 penalized_hessian: &h_dense_for_alo,
560 hessian_weights: base.final_weights_signed(),
561 score_weights: base.solve_weights_psd(),
562 working_response: &base.solveworking_response,
563 eta: &base.final_eta,
564 offset: &base.final_offset,
565 link,
566 phi,
567 penalty_root: if e.nrows() > 0 { Some(e) } else { None },
568 ridge,
569 score_curvature: score_curvature_ref,
570 };
571
572 let result = compute_alo_from_input_inner(&input)?;
573
574 log_leverage_diagnostics(&result.leverage, phi);
576
577 let has_nan_pred = result.eta_tilde.iter().any(|&x| x.is_nan());
579 let has_nan_se_bayes = result.se_bayes.iter().any(|&x| x.is_nan());
580 let has_nan_se_sandwich = result.se_sandwich.iter().any(|&x| x.is_nan());
581 let has_nan_leverage = result.leverage.iter().any(|&x| x.is_nan());
582
583 if has_nan_pred || has_nan_se_bayes || has_nan_se_sandwich || has_nan_leverage {
584 log::error!("[GAM ALO] NaN values found in ALO diagnostics:");
585 log::error!(
586 "[GAM ALO] eta_tilde: {} NaN values",
587 result.eta_tilde.iter().filter(|&&x| x.is_nan()).count()
588 );
589 log::error!(
590 "[GAM ALO] se_bayes: {} NaN values",
591 result.se_bayes.iter().filter(|&&x| x.is_nan()).count()
592 );
593 log::error!(
594 "[GAM ALO] se_sandwich: {} NaN values",
595 result.se_sandwich.iter().filter(|&&x| x.is_nan()).count()
596 );
597 log::error!(
598 "[GAM ALO] leverage: {} NaN values",
599 result.leverage.iter().filter(|&&x| x.is_nan()).count()
600 );
601 return Err(AloError::InfluenceMatrixFailed {
602 condition_number: f64::INFINITY,
603 });
604 }
605
606 Ok(result)
607}
608
609fn log_leverage_diagnostics(leverage: &Array1<f64>, phi: f64) {
611 let n = leverage.len();
612 if n == 0 {
613 return;
614 }
615
616 let mut invalid_count = 0usize;
617 let mut high_leverage_count = 0usize;
618 let mut threshold_counts = [0usize; LEVERAGE_RATE_THRESHOLDS.len()];
619 let mut finite_leverage = Vec::with_capacity(n);
620
621 for (obs, &ai) in leverage.iter().enumerate() {
622 if ai.is_finite() {
623 finite_leverage.push(ai);
624 }
625
626 if !(0.0..=1.0).contains(&ai) || !ai.is_finite() {
627 invalid_count += 1;
628 log::warn!("[GAM ALO] invalid leverage at i={}, a_ii={:.6e}", obs, ai);
629 } else if ai > LEVERAGE_HIGH_THRESHOLD {
630 high_leverage_count += 1;
631 if ai > LEVERAGE_VERY_HIGH_THRESHOLD {
632 log::warn!("[GAM ALO] very high leverage at i={}, a_ii={:.6e}", obs, ai);
633 }
634 }
635
636 for (idx, threshold) in LEVERAGE_RATE_THRESHOLDS.iter().enumerate() {
637 if ai > *threshold {
638 threshold_counts[idx] += 1;
639 }
640 }
641 }
642
643 if invalid_count > 0 || high_leverage_count > 0 {
644 log::warn!(
645 "[GAM ALO] leverage diagnostics: {} invalid values, {} high values (>0.99)",
646 invalid_count,
647 high_leverage_count
648 );
649 }
650
651 finite_leverage.sort_by(f64::total_cmp);
652
653 let finite_n = finite_leverage.len();
654 let a_mean = if finite_n > 0 {
655 finite_leverage.iter().copied().sum::<f64>() / finite_n as f64
656 } else {
657 0.0
658 };
659 let a_median = percentile_from_sorted(&finite_leverage, LEVERAGE_PERCENTILES[0]);
660 let a_p95 = percentile_from_sorted(&finite_leverage, LEVERAGE_PERCENTILES[1]);
661 let a_p99 = percentile_from_sorted(&finite_leverage, LEVERAGE_PERCENTILES[2]);
662 let a_max = finite_leverage.last().copied().unwrap_or(0.0);
663
664 log::info!(
673 "[GAM ALO] leverage: n={}, mean={:.3e}, median={:.3e}, p95={:.3e}, p99={:.3e}, max={:.3e}",
674 n,
675 a_mean,
676 a_median,
677 a_p95,
678 a_p99,
679 a_max
680 );
681 log::info!(
682 "[GAM ALO] high-leverage: a>0.90: {:.2}%, a>0.95: {:.2}%, a>0.99: {:.2}%, dispersion phi={:.3e}",
683 100.0 * (threshold_counts[0] as f64) / n as f64,
684 100.0 * (threshold_counts[1] as f64) / n as f64,
685 100.0 * (threshold_counts[2] as f64) / n as f64,
686 phi
687 );
688}
689
690pub struct AloInput<'a> {
697 pub design: &'a Array2<f64>,
699 pub penalized_hessian: &'a Array2<f64>,
701 pub hessian_weights: SignedWeightsView<'a>,
708 pub score_weights: PsdWeightsView<'a>,
711 pub working_response: &'a Array1<f64>,
713 pub eta: &'a Array1<f64>,
715 pub offset: &'a Array1<f64>,
717 pub link: LinkFunction,
719 pub phi: f64,
721 pub penalty_root: Option<&'a Array2<f64>>,
724 pub ridge: f64,
726 pub score_curvature: Option<&'a AloScalarScoreCurvature<'a>>,
739}
740
741impl<'a> AloInput<'a> {
742 pub fn from_geometry(
744 geom: &'a FitGeometry,
745 design: &'a Array2<f64>,
746 eta: &'a Array1<f64>,
747 offset: &'a Array1<f64>,
748 link: LinkFunction,
749 phi: f64,
750 ) -> Self {
751 let psd_w = PsdWeightsView::from_view_unchecked(geom.working_weights.view());
758 Self {
759 design,
760 penalized_hessian: &geom.penalized_hessian,
761 hessian_weights: psd_w.as_signed(),
762 score_weights: psd_w,
763 working_response: &geom.working_response,
764 eta,
765 offset,
766 link,
767 phi,
768 penalty_root: None,
769 ridge: 0.0,
770 score_curvature: None,
771 }
772 }
773
774 pub fn from_geometry_with_working_state(
794 geom: &'a FitGeometry,
795 design: &'a Array2<f64>,
796 eta: &'a Array1<f64>,
797 offset: &'a Array1<f64>,
798 link: LinkFunction,
799 phi: f64,
800 working_weights: &'a Array1<f64>,
801 working_response: &'a Array1<f64>,
802 ) -> Self {
803 let psd_w = PsdWeightsView::from_view_unchecked(working_weights.view());
804 Self {
805 design,
806 penalized_hessian: &geom.penalized_hessian,
807 hessian_weights: psd_w.as_signed(),
808 score_weights: psd_w,
809 working_response,
810 eta,
811 offset,
812 link,
813 phi,
814 penalty_root: None,
815 ridge: 0.0,
816 score_curvature: None,
817 }
818 }
819}
820
821pub fn compute_alo_from_input(input: &AloInput) -> Result<AloDiagnostics, EstimationError> {
827 compute_alo_from_input_inner(input).map_err(EstimationError::from)
828}
829
830fn compute_alo_from_input_inner(input: &AloInput) -> Result<AloDiagnostics, AloError> {
831 let x_dense = input.design;
832 let n = x_dense.nrows();
833 let p = x_dense.ncols();
834 let w_h = input.hessian_weights.view();
838 let w_s = input.score_weights.view();
839
840 validate_alo_solve_setup(input, n, p)?;
841
842 let factor = StableSolver::new("alo penalized hessian")
843 .factorize(input.penalized_hessian)
844 .map_err(|_| AloError::InfluenceMatrixFailed {
845 condition_number: f64::INFINITY,
846 })?;
847
848 let xt = x_dense.t();
849 let phi = input.phi;
850
851 let mut aii = Array1::<f64>::zeros(n);
852 let mut x_hinv_x_diag = Array1::<f64>::zeros(n);
853 let mut se_bayes = Array1::<f64>::zeros(n);
854 let mut se_sandwich = Array1::<f64>::zeros(n);
855
856 let block_cols = ALO_RHS_BLOCK_COLS;
857 let mut rhs_chunk_buf = Array2::<f64>::zeros((p, block_cols).f());
862 let mut xs_chunk_storage = FaerMat::<f64>::zeros(n, block_cols);
869 let x_dense_view = FaerArrayView::new(x_dense);
870
871 for chunk_start in (0..n).step_by(block_cols) {
872 let chunk_end = (chunk_start + block_cols).min(n);
873 let width = chunk_end - chunk_start;
874
875 rhs_chunk_buf
876 .slice_mut(s![.., ..width])
877 .assign(&xt.slice(s![.., chunk_start..chunk_end]));
878
879 let rhs_chunkview = rhs_chunk_buf.slice(s![.., ..width]);
880 let rhs_chunk = FaerArrayView::new(&rhs_chunkview);
881 let s_chunk = factor.solve(rhs_chunk.as_ref());
885
886 let mut xs_target = xs_chunk_storage.as_mut().subcols_mut(0, width);
887 matmul(
888 xs_target.rb_mut(),
889 Accum::Replace,
890 x_dense_view.as_ref(),
891 s_chunk.as_ref(),
892 1.0,
893 Par::Seq,
894 );
895
896 let rhs_view = rhs_chunk_buf.slice(s![.., ..width]);
897
898 for local_col in 0..width {
899 let obs = chunk_start + local_col;
900 let rhs_col = rhs_view.column(local_col);
904 let rhs_slice = rhs_col.as_slice().expect("column-major col contiguous");
905 let s_slice = s_chunk.col_as_slice(local_col);
906
907 let mut x_hinv_x = 0.0f64;
908 for k in 0..p {
910 let sval = s_slice[k];
911 let xval = rhs_slice[k];
912 x_hinv_x = sval.mul_add(xval, x_hinv_x);
913 }
914 let ai = w_h[obs].max(0.0) * x_hinv_x;
915 aii[obs] = ai;
916 x_hinv_x_diag[obs] = x_hinv_x;
917
918 let var_bayes = bayesvar_eta(phi, x_hinv_x);
919 let xs_slice = xs_chunk_storage.col_as_slice(local_col);
920 let mut meat_quad = 0.0f64;
921 for row in 0..n {
922 let xs = xs_slice[row];
923 meat_quad += w_s[row] * xs * xs;
930 }
931 let var_sandwich = sandwichvar_eta_from_meat(phi, meat_quad);
932
933 if !var_bayes.is_finite() || !var_sandwich.is_finite() {
934 return Err(AloError::LooComputationFailed {
935 reason: format!(
936 "ALO variance is not finite at row {obs}: bayes={var_bayes:.6e}, sandwich={var_sandwich:.6e}"
937 ),
938 });
939 }
940 let bayes_tol = variance_negative_tolerance(phi * x_hinv_x.abs());
941 if var_bayes < -bayes_tol {
942 return Err(AloError::LooComputationFailed {
943 reason: format!(
944 "ALO Bayesian variance is materially negative at row {obs}: var={var_bayes:.6e}, tol={bayes_tol:.6e}"
945 ),
946 });
947 }
948 let sandwich_scale = phi * meat_quad.abs().max(x_hinv_x.abs());
949 let sandwich_tol = variance_negative_tolerance(sandwich_scale);
950 if var_sandwich < -sandwich_tol {
951 return Err(AloError::LooComputationFailed {
952 reason: format!(
953 "ALO sandwich variance is materially negative at row {obs}: var={var_sandwich:.6e}, tol={sandwich_tol:.6e}"
954 ),
955 });
956 }
957
958 se_bayes[obs] = var_bayes.max(0.0).sqrt();
959 se_sandwich[obs] = var_sandwich.max(0.0).sqrt();
960 }
961 }
962
963 let eta_hat = input.eta;
964 let z = input.working_response;
965 let offset = input.offset;
966
967 use rayon::prelude::*;
968 let eta_tilde_vec: Vec<f64> = (0..n)
969 .into_par_iter()
970 .map(|i| {
971 let denom_raw = 1.0 - aii[i];
972 if denom_raw <= ALO_DENOMINATOR_MIN || !denom_raw.is_finite() {
973 return Err(AloError::LooComputationFailed {
974 reason: format!(
975 "ALO denominator is too small at row {i}: a_ii={:.6e}, 1-a_ii={:.6e}, min={:.1e}",
976 aii[i], denom_raw, ALO_DENOMINATOR_MIN
977 ),
978 });
979 }
980 let one_step = alo_eta_updatewith_offset(
981 eta_hat[i],
982 z[i],
983 offset[i],
984 x_hinv_x_diag[i],
985 w_s[i],
986 denom_raw,
987 );
988 let v = if let Some(score_curvature) = input.score_curvature {
996 alo_eta_exact_frozen_curvature(
997 eta_hat[i],
998 x_hinv_x_diag[i],
999 &|eta| score_curvature(i, eta),
1000 )
1001 .map_err(|err| AloError::LooComputationFailed {
1002 reason: format!(
1003 "ALO exact frozen-curvature solve failed at row {i}: {err}"
1004 ),
1005 })?
1006 } else {
1007 one_step
1008 };
1009 if !v.is_finite() {
1010 return Err(AloError::LooComputationFailed {
1011 reason: format!("ALO eta_tilde is not finite at row {i}: eta_tilde={v}"),
1012 });
1013 }
1014 Ok(v)
1015 })
1016 .collect::<Result<_, _>>()?;
1017 let eta_tilde = Array1::from(eta_tilde_vec);
1018
1019 Ok(AloDiagnostics {
1020 eta_tilde,
1021 se_bayes,
1022 se_sandwich,
1023 pred_identity: eta_hat.clone(),
1024 leverage: aii,
1025 fisherweights: w_h.to_owned(),
1026 })
1027}
1028
1029fn validate_alo_solve_setup(input: &AloInput, n: usize, p: usize) -> Result<(), AloError> {
1030 let h = input.penalized_hessian;
1031 if h.nrows() != p || h.ncols() != p {
1032 return Err(AloError::InvalidInput {
1033 reason: format!(
1034 "ALO diagnostics require a dense exact penalized Hessian with shape {p}x{p}; got {}x{}",
1035 h.nrows(),
1036 h.ncols()
1037 ),
1038 });
1039 }
1040 if h.iter().any(|v| !v.is_finite()) {
1041 return Err(AloError::InvalidInput {
1042 reason: "ALO diagnostics require a finite dense exact penalized Hessian".to_string(),
1043 });
1044 }
1045 for i in 0..p {
1046 for j in 0..i {
1047 let a = h[[i, j]];
1048 let b = h[[j, i]];
1049 let scale = a.abs().max(b.abs()).max(1.0);
1050 if (a - b).abs() > HESSIAN_SYMMETRY_REL_TOL * scale {
1051 return Err(AloError::InvalidInput {
1052 reason: format!(
1053 "ALO diagnostics require a symmetric dense exact penalized Hessian; entries ({i},{j}) and ({j},{i}) differ by {:.3e}",
1054 (a - b).abs()
1055 ),
1056 });
1057 }
1058 }
1059 }
1060
1061 let vector_lengths = [
1062 ("hessian_weights", input.hessian_weights.len()),
1063 ("score_weights", input.score_weights.len()),
1064 ("working_response", input.working_response.len()),
1065 ("eta", input.eta.len()),
1066 ("offset", input.offset.len()),
1067 ];
1068 for (name, len) in vector_lengths {
1069 if len != n {
1070 return Err(AloError::InvalidInput {
1071 reason: format!("ALO diagnostics require {name} length {n}; got {len}"),
1072 });
1073 }
1074 }
1075 if input.hessian_weights.view().iter().any(|v| !v.is_finite()) {
1076 return Err(AloError::WeightInvalid {
1077 reason: "ALO diagnostics require finite Hessian-side weights".to_string(),
1078 });
1079 }
1080 if input.score_weights.view().iter().any(|v| !v.is_finite()) {
1081 return Err(AloError::WeightInvalid {
1082 reason: "ALO diagnostics require finite score-side weights".to_string(),
1083 });
1084 }
1085 if input.working_response.iter().any(|v| !v.is_finite()) {
1086 return Err(AloError::WeightInvalid {
1087 reason: "ALO diagnostics require finite working responses".to_string(),
1088 });
1089 }
1090 if input.eta.iter().any(|v| !v.is_finite()) || input.offset.iter().any(|v| !v.is_finite()) {
1091 return Err(AloError::InvalidInput {
1092 reason: "ALO diagnostics require finite linear predictors and offsets".to_string(),
1093 });
1094 }
1095 if !input.phi.is_finite() || input.phi <= 0.0 {
1096 return Err(AloError::InvalidInput {
1097 reason: format!(
1098 "ALO diagnostics require positive finite dispersion phi; got {}",
1099 input.phi
1100 ),
1101 });
1102 }
1103 if !input.ridge.is_finite() || input.ridge < 0.0 {
1104 return Err(AloError::InvalidInput {
1105 reason: format!(
1106 "ALO diagnostics require a finite non-negative Hessian ridge; got {}",
1107 input.ridge
1108 ),
1109 });
1110 }
1111 if let Some(e) = input.penalty_root {
1112 if e.ncols() != p {
1113 return Err(AloError::InvalidInput {
1114 reason: format!(
1115 "ALO diagnostics require penalty root to have {p} columns; got {}",
1116 e.ncols()
1117 ),
1118 });
1119 }
1120 if e.iter().any(|v| !v.is_finite()) {
1121 return Err(AloError::InvalidInput {
1122 reason: "ALO diagnostics require finite penalty-root entries".to_string(),
1123 });
1124 }
1125 }
1126 Ok(())
1127}
1128
1129pub fn compute_alo_diagnostics_from_fit(
1131 fit: &UnifiedFitResult,
1132 y: ArrayView1<f64>,
1133 link: LinkFunction,
1134) -> Result<AloDiagnostics, EstimationError> {
1135 let pirls = fit
1136 .artifacts
1137 .pirls
1138 .as_ref()
1139 .ok_or_else(|| AloError::InvalidInput {
1140 reason:
1141 "ALO diagnostics require a PIRLS-backed fit; this fit does not expose PIRLS geometry"
1142 .to_string(),
1143 })
1144 .map_err(EstimationError::from)?;
1145 compute_alo_diagnostics_from_pirls_impl(pirls, y, link)
1146}
1147
1148pub fn compute_alo_diagnostics_from_unified(
1154 unified: &UnifiedFitResult,
1155 design: &Array2<f64>,
1156 eta: &Array1<f64>,
1157 offset: &Array1<f64>,
1158 link: LinkFunction,
1159 phi: f64,
1160) -> Result<AloDiagnostics, EstimationError> {
1161 let geom = unified
1162 .geometry
1163 .as_ref()
1164 .ok_or_else(|| AloError::InvalidInput {
1165 reason: "UnifiedFitResult does not contain working-set geometry; \
1166 ALO diagnostics require geometry at convergence"
1167 .to_string(),
1168 })
1169 .map_err(EstimationError::from)?;
1170 let input = AloInput::from_geometry(geom, design, eta, offset, link, phi);
1171 compute_alo_from_input(&input)
1172}
1173
1174pub fn compute_alo_diagnostics_from_pirls(
1176 base: &pirls::PirlsResult,
1177 y: ArrayView1<f64>,
1178 link: LinkFunction,
1179) -> Result<AloDiagnostics, EstimationError> {
1180 compute_alo_diagnostics_from_pirls_impl(base, y, link)
1181}
1182
1183pub fn compute_case_deletion_from_pirls(
1202 base: &pirls::PirlsResult,
1203 y: ArrayView1<f64>,
1204 link: LinkFunction,
1205) -> Result<Option<crate::sensitivity::CaseDeletionInfluence>, EstimationError> {
1206 let x_dense_arc = base
1207 .x_transformed
1208 .try_to_dense_arc("case-deletion diagnostics require dense transformed design")
1209 .map_err(|reason| EstimationError::InvalidInput(reason))?;
1210 let x_dense = x_dense_arc.as_ref();
1211 let n = x_dense.nrows();
1212 let p = x_dense.ncols();
1213 if n == 0 || p == 0 {
1214 return Ok(None);
1215 }
1216
1217 let phi = match link {
1220 LinkFunction::Identity => {
1221 use rayon::iter::{IntoParallelIterator, ParallelIterator};
1222 let rss: f64 = (0..n)
1223 .into_par_iter()
1224 .map(|i| {
1225 let r = y[i] - base.finalmu[i];
1226 base.finalweights[i] * r * r
1227 })
1228 .sum();
1229 let dof = (n as f64) - base.edf;
1230 rss / dof.max(1.0)
1231 }
1232 _ => 1.0,
1233 };
1234 if !(phi.is_finite() && phi > 0.0) {
1235 return Ok(None);
1236 }
1237
1238 let h_dense = base
1241 .dense_stabilizedhessian_transformed(
1242 "case-deletion diagnostics require exact dense stabilized penalized Hessian",
1243 )
1244 .map_err(|e| match e {
1245 EstimationError::InvalidInput(reason) => EstimationError::InvalidInput(reason),
1246 other => EstimationError::InvalidInput(format!("{other:?}")),
1247 })?;
1248
1249 let factor = match h_dense.cholesky(faer::Side::Lower) {
1250 Ok(f) => f,
1251 Err(_) => return Ok(None),
1255 };
1256
1257 let working_weights = base.finalweights.clone();
1261 let working_residual = &base.solveworking_response - &base.final_eta;
1262
1263 let sensitivity = crate::sensitivity::FitSensitivity::from_faer_cholesky(&factor, p);
1264 Ok(sensitivity.case_deletion(
1265 x_dense,
1266 working_weights.view(),
1267 working_residual.view(),
1268 phi,
1269 ))
1270}
1271
1272#[derive(Debug, Clone)]
1276pub struct MultiBlockAloDiagnostics {
1277 pub eta_tilde: Vec<Array1<f64>>,
1280 pub leverage: Array1<f64>,
1282 pub alo_variance: Vec<Array1<f64>>,
1287 pub cook_distance: Array1<f64>,
1290}
1291
1292pub struct MultiBlockAloInput<'a> {
1322 pub n_obs: usize,
1324 pub n_blocks: usize,
1326 pub block_designs: &'a [Array2<f64>],
1329 pub penalized_hessian_inv: &'a Array2<f64>,
1331 pub block_weights: Vec<Array2<f64>>,
1333 pub scores: Vec<Array1<f64>>,
1336 pub eta_hat: Vec<Array1<f64>>,
1339}
1340
1341pub fn compute_multiblock_alo(
1360 input: &MultiBlockAloInput,
1361) -> Result<MultiBlockAloDiagnostics, EstimationError> {
1362 compute_multiblock_alo_inner(input).map_err(EstimationError::from)
1363}
1364
1365fn compute_multiblock_alo_inner(
1366 input: &MultiBlockAloInput,
1367) -> Result<MultiBlockAloDiagnostics, AloError> {
1368 use rayon::prelude::*;
1369
1370 let n = input.n_obs;
1371 let b = input.n_blocks;
1372 let p_tot = input.penalized_hessian_inv.nrows();
1373
1374 if input.block_designs.len() != b {
1376 return Err(AloError::InvalidInput {
1377 reason: format!(
1378 "MultiBlockAloInput: expected {} block designs, got {}",
1379 b,
1380 input.block_designs.len()
1381 ),
1382 });
1383 }
1384
1385 let col_sum: usize = input.block_designs.iter().map(|d| d.ncols()).sum();
1387 if col_sum != p_tot {
1388 return Err(AloError::InvalidInput {
1389 reason: format!(
1390 "MultiBlockAloInput: total design columns ({}) != penalized_hessian_inv size ({})",
1391 col_sum, p_tot
1392 ),
1393 });
1394 }
1395
1396 let col_offsets = multiblock_col_offsets(input.block_designs);
1397 let (chunk_size, max_concurrent_chunks) = multiblock_alo_parallel_plan(p_tot, b, n);
1398 let chunk_starts: Vec<usize> = (0..n).step_by(chunk_size).collect();
1399
1400 let mut chunk_results: Vec<Result<MultiBlockAloChunkDiagnostics, AloError>> =
1406 Vec::with_capacity(chunk_starts.len());
1407 for chunk_wave in chunk_starts.chunks(max_concurrent_chunks) {
1408 let mut wave_results: Vec<Result<MultiBlockAloChunkDiagnostics, AloError>> = chunk_wave
1409 .par_iter()
1410 .map_init(
1411 || MultiBlockAloScratch::new(b),
1412 |scratch, &chunk_start| {
1413 let chunk_end = (chunk_start + chunk_size).min(n);
1414 compute_multiblock_alo_chunk(
1415 input,
1416 &col_offsets,
1417 chunk_start,
1418 chunk_end,
1419 scratch,
1420 )
1421 },
1422 )
1423 .collect();
1424 chunk_results.append(&mut wave_results);
1425 }
1426
1427 let mut eta_tilde = Vec::with_capacity(n);
1428 let mut leverage = Array1::<f64>::zeros(n);
1429 let mut alo_variance = Vec::with_capacity(n);
1430 let mut cook_distance = Array1::<f64>::zeros(n);
1431
1432 let mut chunks = Vec::with_capacity(chunk_results.len());
1433 for result in chunk_results {
1434 chunks.push(result?);
1435 }
1436 chunks.sort_unstable_by_key(|chunk| chunk.chunk_start);
1437
1438 for chunk in chunks {
1439 let chunk_start = chunk.chunk_start;
1440 eta_tilde.extend(chunk.eta_tilde);
1441 alo_variance.extend(chunk.alo_variance);
1442 for (local_i, lev) in chunk.leverage.into_iter().enumerate() {
1443 leverage[chunk_start + local_i] = lev;
1444 }
1445 for (local_i, cook) in chunk.cook_distance.into_iter().enumerate() {
1446 cook_distance[chunk_start + local_i] = cook;
1447 }
1448 }
1449
1450 Ok(MultiBlockAloDiagnostics {
1451 eta_tilde,
1452 leverage,
1453 alo_variance,
1454 cook_distance,
1455 })
1456}
1457
1458#[inline]
1459fn multiblock_alo_parallel_plan(p_tot: usize, n_blocks: usize, n_obs: usize) -> (usize, usize) {
1460 if p_tot == 0 || n_blocks == 0 || n_obs == 0 {
1461 return (1, 1);
1462 }
1463 let bytes_per_obs = (p_tot * n_blocks * std::mem::size_of::<f64>()).max(1);
1464 let workers = rayon::current_num_threads().max(1);
1465 let max_concurrent_chunks = (MULTIBLOCK_ALO_MEMORY_BUDGET_BYTES / bytes_per_obs)
1466 .max(1)
1467 .min(workers);
1468 let per_worker_budget =
1469 (MULTIBLOCK_ALO_MEMORY_BUDGET_BYTES / max_concurrent_chunks).max(bytes_per_obs);
1470 let budget_obs = (per_worker_budget / bytes_per_obs).max(1);
1471 (budget_obs.min(n_obs), max_concurrent_chunks)
1472}
1473
1474struct MultiBlockAloScratch {
1475 a_i: Vec<f64>,
1476 wa: Vec<f64>,
1477 aw: Vec<f64>,
1478 imwa: Vec<f64>,
1479 imaw: Vec<f64>,
1480 perm_imwa: Vec<usize>,
1481 perm_imaw: Vec<usize>,
1482 delta_eta: Vec<f64>,
1483 rhs_buf: Vec<f64>,
1484 w_u: Vec<f64>,
1485 var_diag_buf: Vec<f64>,
1486 w_flat: Vec<f64>,
1487 lu_scratch: Vec<f64>,
1488}
1489
1490impl MultiBlockAloScratch {
1491 fn new(b: usize) -> Self {
1492 let bb_sz = b * b;
1493 Self {
1494 a_i: vec![0.0f64; bb_sz],
1495 wa: vec![0.0f64; bb_sz],
1496 aw: vec![0.0f64; bb_sz],
1497 imwa: vec![0.0f64; bb_sz],
1498 imaw: vec![0.0f64; bb_sz],
1499 perm_imwa: vec![0usize; b],
1500 perm_imaw: vec![0usize; b],
1501 delta_eta: vec![0.0f64; b],
1502 rhs_buf: vec![0.0f64; b],
1503 w_u: vec![0.0f64; b],
1504 var_diag_buf: vec![0.0f64; b],
1505 w_flat: vec![0.0f64; bb_sz],
1506 lu_scratch: vec![0.0f64; b],
1507 }
1508 }
1509}
1510
1511struct MultiBlockAloChunkDiagnostics {
1512 chunk_start: usize,
1513 eta_tilde: Vec<Array1<f64>>,
1514 leverage: Vec<f64>,
1515 alo_variance: Vec<Array1<f64>>,
1516 cook_distance: Vec<f64>,
1517}
1518
1519fn compute_multiblock_alo_chunk(
1520 input: &MultiBlockAloInput,
1521 col_offsets: &[usize],
1522 chunk_start: usize,
1523 chunk_end: usize,
1524 scratch: &mut MultiBlockAloScratch,
1525) -> Result<MultiBlockAloChunkDiagnostics, AloError> {
1526 let b = input.n_blocks;
1527 let chunk_len = chunk_end - chunk_start;
1528
1529 let mut q_blocks = Vec::with_capacity(b);
1530 for blk in 0..b {
1531 let x_chunk_t = input.block_designs[blk]
1532 .slice(s![chunk_start..chunk_end, ..])
1533 .t()
1534 .to_owned();
1535 let off_b = col_offsets[blk];
1536 let h_slice = input
1537 .penalized_hessian_inv
1538 .slice(s![.., off_b..off_b + x_chunk_t.nrows()])
1539 .to_owned();
1540 q_blocks.push(h_slice.dot(&x_chunk_t));
1541 }
1542
1543 let mut eta_tilde = Vec::with_capacity(chunk_len);
1544 let mut leverage = vec![0.0f64; chunk_len];
1545 let mut alo_variance = Vec::with_capacity(chunk_len);
1546 let mut cook_distance = vec![0.0f64; chunk_len];
1547
1548 for local_i in 0..chunk_len {
1549 let i = chunk_start + local_i;
1550 let w_i = &input.block_weights[i];
1551
1552 for r in 0..b {
1554 for c in 0..b {
1555 scratch.w_flat[r * b + c] = w_i[(r, c)];
1556 }
1557 }
1558
1559 for a in 0..b {
1561 let x_a = &input.block_designs[a];
1562 let p_a = x_a.ncols();
1563 let off_a = col_offsets[a];
1564 let xa_row = x_a.row(i);
1565 for bb in 0..b {
1566 let q_bb = &q_blocks[bb];
1567 let mut dot = 0.0f64;
1568 for k in 0..p_a {
1569 dot += xa_row[k] * q_bb[(off_a + k, local_i)];
1570 }
1571 scratch.a_i[a * b + bb] = dot;
1572 }
1573 }
1574
1575 mat_mul_flat(&scratch.w_flat, &scratch.a_i, &mut scratch.wa, b);
1577 mat_mul_flat(&scratch.a_i, &scratch.w_flat, &mut scratch.aw, b);
1579
1580 let mut tr = 0.0f64;
1583 for d in 0..b {
1584 tr += scratch.aw[d * b + d];
1585 }
1586 leverage[local_i] = tr;
1587
1588 for r in 0..b {
1590 for c in 0..b {
1591 let idx = r * b + c;
1592 let id = if r == c { 1.0 } else { 0.0 };
1593 scratch.imwa[idx] = id - scratch.wa[idx];
1594 scratch.imaw[idx] = id - scratch.aw[idx];
1595 }
1596 }
1597
1598 if !lu_factor_in_place(&mut scratch.imwa, &mut scratch.perm_imwa, b) {
1604 for r in 0..b {
1605 for c in 0..b {
1606 let idx = r * b + c;
1607 let id = if r == c { 1.0 } else { 0.0 };
1608 scratch.imwa[idx] = id - scratch.wa[idx];
1609 }
1610 }
1611 for d in 0..b {
1612 scratch.imwa[d * b + d] += ALO_LOCAL_BLOCK_RIDGE;
1613 }
1614 let refactored = lu_factor_in_place(&mut scratch.imwa, &mut scratch.perm_imwa, b);
1615 assert!(
1616 refactored,
1617 "ALO local block remained singular after ridge regularization"
1618 );
1619 }
1620 if !lu_factor_in_place(&mut scratch.imaw, &mut scratch.perm_imaw, b) {
1621 for r in 0..b {
1622 for c in 0..b {
1623 let idx = r * b + c;
1624 let id = if r == c { 1.0 } else { 0.0 };
1625 scratch.imaw[idx] = id - scratch.aw[idx];
1626 }
1627 }
1628 for d in 0..b {
1629 scratch.imaw[d * b + d] += ALO_LOCAL_BLOCK_RIDGE;
1630 }
1631 let refactored = lu_factor_in_place(&mut scratch.imaw, &mut scratch.perm_imaw, b);
1632 assert!(
1633 refactored,
1634 "ALO local variance block remained singular after ridge regularization"
1635 );
1636 }
1637
1638 let s_i = &input.scores[i];
1640 for k in 0..b {
1641 scratch.rhs_buf[k] = s_i[k];
1642 }
1643 lu_solve_in_place(
1644 &scratch.imwa,
1645 &scratch.perm_imwa,
1646 &mut scratch.rhs_buf,
1647 &mut scratch.lu_scratch,
1648 b,
1649 );
1650 for r in 0..b {
1652 let mut acc = 0.0f64;
1653 let row_off = r * b;
1654 for k in 0..b {
1655 acc += scratch.a_i[row_off + k] * scratch.rhs_buf[k];
1656 }
1657 scratch.delta_eta[r] = acc;
1658 }
1659
1660 let eta_i = &input.eta_hat[i];
1661 let mut corrected = Array1::<f64>::zeros(b);
1662 for d in 0..b {
1663 corrected[d] = eta_i[d] + scratch.delta_eta[d];
1664 }
1665 eta_tilde.push(corrected);
1666
1667 let mut cook = 0.0f64;
1669 for r in 0..b {
1670 let mut w_delta_r = 0.0f64;
1671 let row_off = r * b;
1672 for k in 0..b {
1673 w_delta_r += scratch.w_flat[row_off + k] * scratch.delta_eta[k];
1674 }
1675 cook += scratch.delta_eta[r] * w_delta_r;
1676 }
1677 cook_distance[local_i] = cook;
1678
1679 for d in 0..b {
1685 let row_off = d * b;
1686 for k in 0..b {
1688 scratch.rhs_buf[k] = scratch.a_i[row_off + k];
1689 }
1690 lu_solve_in_place(
1691 &scratch.imaw,
1692 &scratch.perm_imaw,
1693 &mut scratch.rhs_buf,
1694 &mut scratch.lu_scratch,
1695 b,
1696 );
1697 for r in 0..b {
1699 let mut acc = 0.0f64;
1700 let wr = r * b;
1701 for k in 0..b {
1702 acc += scratch.w_flat[wr + k] * scratch.rhs_buf[k];
1703 }
1704 scratch.w_u[r] = acc;
1705 }
1706 lu_solve_in_place(
1708 &scratch.imwa,
1709 &scratch.perm_imwa,
1710 &mut scratch.w_u,
1711 &mut scratch.lu_scratch,
1712 b,
1713 );
1714 let mut v_dd = 0.0f64;
1716 for k in 0..b {
1717 v_dd += scratch.a_i[row_off + k] * scratch.w_u[k];
1718 }
1719 scratch.var_diag_buf[d] = v_dd.max(0.0);
1720 }
1721 let mut var_diag = Array1::<f64>::zeros(b);
1722 for d in 0..b {
1723 var_diag[d] = scratch.var_diag_buf[d];
1724 }
1725 alo_variance.push(var_diag);
1726 }
1727
1728 Ok(MultiBlockAloChunkDiagnostics {
1729 chunk_start,
1730 eta_tilde,
1731 leverage,
1732 alo_variance,
1733 cook_distance,
1734 })
1735}
1736
1737#[inline]
1739fn mat_mul_flat(a: &[f64], b_mat: &[f64], out: &mut [f64], b: usize) {
1740 for r in 0..b {
1741 let ar = r * b;
1742 let or = r * b;
1743 for c in 0..b {
1744 let mut acc = 0.0f64;
1745 for k in 0..b {
1746 acc += a[ar + k] * b_mat[k * b + c];
1747 }
1748 out[or + c] = acc;
1749 }
1750 }
1751}
1752
1753fn lu_factor_in_place(m: &mut [f64], perm: &mut [usize], b: usize) -> bool {
1760 for i in 0..b {
1761 perm[i] = i;
1762 }
1763 for col in 0..b {
1764 let mut max_val = m[col * b + col].abs();
1766 let mut max_idx = col;
1767 for row in (col + 1)..b {
1768 let v = m[row * b + col].abs();
1769 if v > max_val {
1770 max_val = v;
1771 max_idx = row;
1772 }
1773 }
1774 if max_val < LU_PIVOT_SINGULAR_TOL {
1775 return false;
1776 }
1777 if max_idx != col {
1778 for k in 0..b {
1780 m.swap(col * b + k, max_idx * b + k);
1781 }
1782 perm.swap(col, max_idx);
1783 }
1784 let pivot = m[col * b + col];
1785 for row in (col + 1)..b {
1786 let factor = m[row * b + col] / pivot;
1787 m[row * b + col] = factor; for k in (col + 1)..b {
1789 let upd = factor * m[col * b + k];
1790 m[row * b + k] -= upd;
1791 }
1792 }
1793 }
1794 true
1795}
1796
1797fn lu_solve_in_place(m: &[f64], perm: &[usize], rhs: &mut [f64], scratch: &mut [f64], b: usize) {
1800 let y = &mut scratch[..b];
1802 for row in 0..b {
1803 let mut s = rhs[perm[row]];
1804 for k in 0..row {
1805 s -= m[row * b + k] * y[k];
1806 }
1807 y[row] = s;
1808 }
1809 for row in (0..b).rev() {
1811 let mut s = y[row];
1812 for k in (row + 1)..b {
1813 s -= m[row * b + k] * rhs[k];
1814 }
1815 rhs[row] = s / m[row * b + row];
1816 }
1817}
1818
1819pub fn compute_multiblock_alo_leverages(
1827 n_obs: usize,
1828 n_blocks: usize,
1829 block_designs: &[Array2<f64>],
1830 penalized_hessian_inv: &Array2<f64>,
1831 block_weights: &[Array2<f64>],
1832) -> Result<Array1<f64>, EstimationError> {
1833 use rayon::prelude::*;
1834
1835 let n = n_obs;
1836 let b = n_blocks;
1837 let p_tot = penalized_hessian_inv.nrows();
1838
1839 let col_offsets = multiblock_col_offsets(block_designs);
1840 let max_workers = rayon::current_num_threads();
1841 let chunk_size = multiblock_alo_parallel_leverage_chunk_size(p_tot, b, n, max_workers);
1842
1843 let mut leverage = Array1::<f64>::zeros(n);
1844
1845 let block_widths: Vec<usize> = block_designs.iter().map(|d| d.ncols()).collect();
1849 let mut h_stripes: Vec<FaerMat<f64>> = block_widths
1850 .iter()
1851 .map(|&p_blk| FaerMat::<f64>::zeros(p_tot, p_blk))
1852 .collect();
1853 for blk in 0..b {
1856 let off_b = col_offsets[blk];
1857 let p_blk = block_widths[blk];
1858 let stripe = &mut h_stripes[blk];
1859 for c in 0..p_blk {
1860 for r in 0..p_tot {
1861 stripe[(r, c)] = penalized_hessian_inv[(r, off_b + c)];
1862 }
1863 }
1864 }
1865
1866 leverage
1867 .as_slice_mut()
1868 .expect("newly allocated Array1 is contiguous")
1869 .par_chunks_mut(chunk_size)
1870 .enumerate()
1871 .for_each(|(chunk_idx, leverage_chunk)| {
1872 let chunk_start = chunk_idx * chunk_size;
1873 let chunk_len = leverage_chunk.len();
1874 let chunk_end = chunk_start + chunk_len;
1875
1876 let bb_sz = b * b;
1880 let mut a_i = vec![0.0f64; bb_sz];
1881 let mut aw = vec![0.0f64; bb_sz];
1882 let mut w_flat = vec![0.0f64; bb_sz];
1883
1884 let mut q_storage: Vec<FaerMat<f64>> = block_widths
1888 .iter()
1889 .map(|_| FaerMat::<f64>::zeros(p_tot, chunk_len))
1890 .collect();
1891
1892 let mut xt_storage: Vec<FaerMat<f64>> = block_widths
1896 .iter()
1897 .map(|&p_blk| FaerMat::<f64>::zeros(p_blk, chunk_len))
1898 .collect();
1899
1900 for blk in 0..b {
1905 let p_blk = block_widths[blk];
1906
1907 let x_chunk = block_designs[blk].slice(s![chunk_start..chunk_end, ..]);
1908 let xt = &mut xt_storage[blk];
1909 for local_i in 0..chunk_len {
1910 let row = x_chunk.row(local_i);
1911 for j in 0..p_blk {
1912 xt[(j, local_i)] = row[j];
1913 }
1914 }
1915
1916 matmul(
1917 q_storage[blk].as_mut(),
1918 Accum::Replace,
1919 h_stripes[blk].as_ref(),
1920 xt_storage[blk].as_ref(),
1921 1.0,
1922 Par::Seq,
1923 );
1924 }
1925
1926 for local_i in 0..chunk_len {
1927 let i = chunk_start + local_i;
1928 let w_i = &block_weights[i];
1929
1930 for r in 0..b {
1932 for c in 0..b {
1933 w_flat[r * b + c] = w_i[(r, c)];
1934 }
1935 }
1936
1937 for r in 0..bb_sz {
1941 a_i[r] = 0.0;
1942 }
1943 for k in 0..b {
1944 let q_k = &q_storage[k];
1945 let q_col = q_k.col_as_slice(local_i);
1946 for a in 0..b {
1947 let p_a = block_widths[a];
1948 let off_a = col_offsets[a];
1949 let xa_row = block_designs[a].row(i);
1950 let mut dot = 0.0f64;
1951 for j in 0..p_a {
1952 dot = xa_row[j].mul_add(q_col[off_a + j], dot);
1953 }
1954 a_i[a * b + k] = dot;
1955 }
1956 }
1957
1958 mat_mul_flat(&a_i, &w_flat, &mut aw, b);
1960 let mut tr = 0.0f64;
1961 for d in 0..b {
1962 tr += aw[d * b + d];
1963 }
1964 leverage_chunk[local_i] = tr;
1965 }
1966 });
1967
1968 Ok(leverage)
1969}
1970
1971#[cfg(test)]
1975mod tests {
1976 use super::{
1977 ALO_EXACT_SCALAR_MAX_ITERS, AloExactScalarError, AloInput, alo_eta_exact_frozen_curvature,
1978 alo_eta_updatewith_offset, bayesvar_eta, compute_alo_from_input_inner,
1979 percentile_from_sorted, percentile_index, sandwichvar_eta_from_meat,
1980 };
1981 use gam_linalg::matrix::{PsdWeightsView, SignedWeightsView};
1982 use gam_problem::LinkFunction;
1983
1984 #[test]
1985 fn alo_offset_update_matches_centered_algebra() {
1986 let eta_hat = 11.0;
1987 let z = 13.0;
1988 let offset = 10.0;
1989 let x_hinv_x = 0.2;
1990 let hessian_weight = 1.0;
1991 let score_weight = 1.0;
1992 let leverage = hessian_weight * x_hinv_x;
1994 let expected = offset + ((eta_hat - offset) - leverage * (z - offset)) / (1.0 - leverage);
1995 let got =
1996 alo_eta_updatewith_offset(eta_hat, z, offset, x_hinv_x, score_weight, 1.0 - leverage);
1997 assert!((got - expected).abs() < 1e-12);
1998 }
1999
2000 #[test]
2001 fn alo_offset_update_reduces_to_classicwhen_offsetzero() {
2002 let eta_hat = 1.25;
2003 let z = -0.5;
2004 let x_hinv_x = 0.35;
2005 let hessian_weight = 1.0;
2006 let score_weight = 1.0;
2007 let leverage = hessian_weight * x_hinv_x;
2008 let expected = (eta_hat - leverage * z) / (1.0 - leverage);
2009 let got =
2010 alo_eta_updatewith_offset(eta_hat, z, 0.0, x_hinv_x, score_weight, 1.0 - leverage);
2011 assert!((got - expected).abs() < 1e-12);
2012 }
2013
2014 #[test]
2015 fn alo_offset_update_uses_distinct_score_and_hessian_weights() {
2016 let eta_hat = 1.7;
2017 let z = 0.4;
2018 let offset = -0.2;
2019 let x_hinv_x = 0.15;
2020 let hessian_weight = 3.0;
2021 let score_weight = 5.0;
2022 let expected = offset
2023 + (eta_hat - offset)
2024 + x_hinv_x * score_weight * ((eta_hat - offset) - (z - offset))
2025 / (1.0 - hessian_weight * x_hinv_x);
2026 let got = alo_eta_updatewith_offset(
2027 eta_hat,
2028 z,
2029 offset,
2030 x_hinv_x,
2031 score_weight,
2032 1.0 - hessian_weight * x_hinv_x,
2033 );
2034 assert!((got - expected).abs() < 1e-12);
2035 }
2036
2037 #[test]
2038 fn alo_offset_update_handles_zero_hessian_weight() {
2039 let eta_hat = 0.8;
2040 let z = -0.3;
2041 let offset = 0.1;
2042 let x_hinv_x = 0.4;
2043 let hessian_weight = 0.0;
2044 let score_weight = 2.5;
2045 let expected = offset
2046 + (eta_hat - offset)
2047 + x_hinv_x * score_weight * ((eta_hat - offset) - (z - offset));
2048 let got = alo_eta_updatewith_offset(
2049 eta_hat,
2050 z,
2051 offset,
2052 x_hinv_x,
2053 score_weight,
2054 1.0 - hessian_weight * x_hinv_x,
2055 );
2056 assert!((got - expected).abs() < 1e-12);
2057 }
2058
2059 #[test]
2060 fn alo_exact_frozen_curvature_converges_to_fixed_point() {
2061 let eta_hat = 1.0;
2062 let a_ii = 0.4;
2063 let got = alo_eta_exact_frozen_curvature(eta_hat, a_ii, &|eta| (0.5 * (eta - 2.0), 0.5))
2064 .expect("linear scalar fixed point should converge in one Newton step");
2065 assert!((got - 0.75).abs() < 1e-12);
2066 }
2067
2068 #[test]
2069 fn alo_exact_frozen_curvature_reports_nonconvergence() {
2070 let err = alo_eta_exact_frozen_curvature(0.0, 1.0, &|eta| (eta + 1.0, 0.0))
2071 .expect_err("constant residual should exhaust the scalar iteration budget");
2072 let AloExactScalarError::MaxIterations { iterations, .. } = err else {
2073 panic!("constant residual must report MaxIterations, got {err:?}");
2074 };
2075 assert_eq!(
2076 iterations, ALO_EXACT_SCALAR_MAX_ITERS,
2077 "non-convergence must report the full scalar iteration budget"
2078 );
2079 }
2080
2081 #[test]
2082 fn alo_input_reports_exact_scalar_nonconvergence_with_row_context() {
2083 let design = Array2::from_elem((1, 1), 1.0);
2084 let penalized_hessian = Array2::from_elem((1, 1), 1.0);
2085 let hessian_weights = Array1::from_vec(vec![0.0]);
2086 let score_weights = Array1::from_vec(vec![0.0]);
2087 let working_response = Array1::from_vec(vec![0.0]);
2088 let eta = Array1::from_vec(vec![0.0]);
2089 let offset = Array1::from_vec(vec![0.0]);
2090 let score_curvature = |_: usize, eta: f64| (eta + 1.0, 0.0);
2091 let input = AloInput {
2092 design: &design,
2093 penalized_hessian: &penalized_hessian,
2094 hessian_weights: SignedWeightsView::from_array(&hessian_weights),
2095 score_weights: PsdWeightsView::try_from_array(&score_weights).expect("psd weights"),
2096 working_response: &working_response,
2097 eta: &eta,
2098 offset: &offset,
2099 link: LinkFunction::Logit,
2100 phi: 1.0,
2101 penalty_root: None,
2102 ridge: 0.0,
2103 score_curvature: Some(&score_curvature),
2104 };
2105
2106 let err =
2107 compute_alo_from_input_inner(&input).expect_err("non-converged exact ALO must error");
2108 let msg = err.to_string();
2109 assert!(
2110 msg.contains("ALO exact frozen-curvature solve failed at row 0"),
2111 "missing row context in exact ALO error: {msg}"
2112 );
2113 assert!(
2114 msg.contains("did not converge within"),
2115 "missing non-convergence cause in exact ALO error: {msg}"
2116 );
2117 }
2118
2119 #[test]
2120 fn gaussian_unpenalized_direct_sandwich_equals_bayes() {
2121 let phi = 2.5;
2124 let x_hinv_x = 0.3;
2125 let vb = bayesvar_eta(phi, x_hinv_x);
2126 let vs = sandwichvar_eta_from_meat(phi, x_hinv_x);
2127 assert!((vb - vs).abs() < 1e-12);
2128 }
2129
2130 #[test]
2131 fn sandwich_from_direct_meat_scales_by_phi() {
2132 let phi = 1.7;
2133 let meat_quad = 0.358;
2134 let got = sandwichvar_eta_from_meat(phi, meat_quad);
2135 let expected = phi * meat_quad;
2136 assert!((got - expected).abs() < 1e-12);
2137 }
2138
2139 #[test]
2140 fn sandwich_meat_uses_score_weights_not_hessian_weights_noncanonical() {
2141 let x = Array2::from_shape_vec((5, 1), vec![1.0, 2.0, 1.0, 2.0, 1.0]).unwrap();
2150 let w_h_vec = Array1::from_vec(vec![1.0, -1.0, 1.0, -1.0, 0.5]);
2153 let w_s_vec = Array1::from_vec(vec![1.0, 0.8, 1.2, 0.6, 0.9]);
2155 let phi = 1.3;
2156
2157 let n = x.nrows();
2158 let sum_wh_x2: f64 = (0..n).map(|i| w_h_vec[i] * x[[i, 0]] * x[[i, 0]]).sum();
2159 let sum_ws_x2: f64 = (0..n).map(|i| w_s_vec[i] * x[[i, 0]] * x[[i, 0]]).sum();
2160 assert!(sum_wh_x2 < 0.0, "fixture must exercise a negative W_H meat");
2164 assert!(sum_ws_x2 > 0.0);
2165
2166 let s0 = 8.0_f64;
2168 let h = s0 + sum_wh_x2; assert!(h > 0.0, "penalized Hessian must stay PD");
2170 let penalized_hessian = Array2::from_elem((1, 1), h);
2171
2172 let old_meat_obs1 = x[[1, 0]] * x[[1, 0]] / (h * h) * sum_wh_x2;
2175 assert!(
2176 phi * old_meat_obs1 < -super::variance_negative_tolerance(phi * old_meat_obs1.abs()),
2177 "the pre-fix W_H meat must be materially negative (guard would trip)"
2178 );
2179
2180 let working_response = Array1::from_vec(vec![0.3, -0.2, 0.5, 0.1, -0.4]);
2181 let eta = Array1::from_vec(vec![0.2, 0.1, 0.4, -0.1, 0.05]);
2182 let offset = Array1::zeros(n);
2183 let input = AloInput {
2184 design: &x,
2185 penalized_hessian: &penalized_hessian,
2186 hessian_weights: SignedWeightsView::from_array(&w_h_vec),
2187 score_weights: PsdWeightsView::try_from_array(&w_s_vec).expect("psd weights"),
2188 working_response: &working_response,
2189 eta: &eta,
2190 offset: &offset,
2191 link: LinkFunction::Probit,
2192 phi,
2193 penalty_root: None,
2194 ridge: 0.0,
2195 score_curvature: None,
2196 };
2197
2198 let diag = compute_alo_from_input_inner(&input)
2200 .expect("fixed sandwich meat (W_S) must not trip the negative-variance guard");
2201
2202 for obs in 0..n {
2204 let expected =
2205 (phi * x[[obs, 0]] * x[[obs, 0]] / (h * h) * sum_ws_x2).sqrt();
2206 assert!(
2207 (diag.se_sandwich[obs] - expected).abs() <= 1e-10 * expected.max(1.0),
2208 "row {obs}: se_sandwich={} expected={expected}",
2209 diag.se_sandwich[obs]
2210 );
2211 }
2212 }
2213
2214 #[test]
2215 fn percentile_index_matches_expected_rounding() {
2216 assert_eq!(percentile_index(0, 0.95), 0);
2217 assert_eq!(percentile_index(1, 0.95), 0);
2218 assert_eq!(percentile_index(10, 0.50), 5);
2219 assert_eq!(percentile_index(10, 0.95), 9);
2220 }
2221
2222 #[test]
2223 fn percentile_from_sorted_returns_order_statistic() {
2224 let values = [1.0, 2.0, 3.0, 4.0, 5.0];
2225 assert_eq!(percentile_from_sorted(&values, 0.50), 3.0);
2226 assert_eq!(percentile_from_sorted(&values, 0.95), 5.0);
2227 assert_eq!(percentile_from_sorted(&[], 0.95), 0.0);
2228 }
2229
2230 use super::{MultiBlockAloInput, compute_multiblock_alo, compute_multiblock_alo_leverages};
2233 use ndarray::{Array1, Array2};
2234
2235 #[test]
2236 fn multiblock_b1_matches_scalar_leverage() {
2237 let n = 3;
2240 let p = 2;
2241 let x = Array2::from_shape_vec((n, p), vec![1.0, 0.5, 0.8, -0.3, 0.2, 1.1]).unwrap();
2242 let w = [1.0, 2.0, 0.5];
2244 let mut h = Array2::<f64>::eye(p);
2245 for i in 0..n {
2246 for r in 0..p {
2247 for c in 0..p {
2248 h[(r, c)] += w[i] * x[(i, r)] * x[(i, c)];
2249 }
2250 }
2251 }
2252 let det = h[(0, 0)] * h[(1, 1)] - h[(0, 1)] * h[(1, 0)];
2254 let mut h_inv = Array2::<f64>::zeros((p, p));
2255 h_inv[(0, 0)] = h[(1, 1)] / det;
2256 h_inv[(1, 1)] = h[(0, 0)] / det;
2257 h_inv[(0, 1)] = -h[(0, 1)] / det;
2258 h_inv[(1, 0)] = -h[(1, 0)] / det;
2259
2260 let mut scalar_lev = vec![0.0f64; n];
2262 for i in 0..n {
2263 let mut xhx = 0.0;
2264 for r in 0..p {
2265 for c in 0..p {
2266 xhx += x[(i, r)] * h_inv[(r, c)] * x[(i, c)];
2267 }
2268 }
2269 scalar_lev[i] = w[i] * xhx;
2270 }
2271
2272 let block_designs = vec![x.clone()];
2274 let block_weights: Vec<Array2<f64>> =
2275 w.iter().map(|&wi| Array2::from_elem((1, 1), wi)).collect();
2276 let scores: Vec<Array1<f64>> = (0..n).map(|_| Array1::from_vec(vec![0.1])).collect();
2277 let eta_hat: Vec<Array1<f64>> = (0..n).map(|i| Array1::from_vec(vec![i as f64])).collect();
2278
2279 let input = MultiBlockAloInput {
2280 n_obs: n,
2281 n_blocks: 1,
2282 block_designs: &block_designs,
2283 penalized_hessian_inv: &h_inv,
2284 block_weights,
2285 scores,
2286 eta_hat,
2287 };
2288
2289 let result = compute_multiblock_alo(&input).unwrap();
2290 for i in 0..n {
2291 assert!(
2292 (result.leverage[i] - scalar_lev[i]).abs() < 1e-10,
2293 "leverage mismatch at i={}: got {}, expected {}",
2294 i,
2295 result.leverage[i],
2296 scalar_lev[i]
2297 );
2298 }
2299 }
2300
2301 #[test]
2302 fn multiblock_leverage_only_matches_full() {
2303 let n = 4;
2306 let p1 = 2;
2307 let p2 = 3;
2308 let x1 = Array2::from_shape_fn((n, p1), |(i, j)| (i + j + 1) as f64 * 0.3);
2309 let x2 = Array2::from_shape_fn((n, p2), |(i, j)| (i * 2 + j) as f64 * 0.2 - 0.1);
2310 let p_tot = p1 + p2;
2311 let h_inv = Array2::<f64>::eye(p_tot); let block_weights: Vec<Array2<f64>> = (0..n)
2313 .map(|i| {
2314 let v = (i + 1) as f64;
2315 Array2::from_shape_vec((2, 2), vec![v, 0.1, 0.1, v * 0.5]).unwrap()
2316 })
2317 .collect();
2318 let scores: Vec<Array1<f64>> = (0..n).map(|_| Array1::from_vec(vec![0.0, 0.0])).collect();
2319 let eta_hat: Vec<Array1<f64>> = (0..n).map(|_| Array1::from_vec(vec![0.0, 0.0])).collect();
2320 let block_designs = vec![x1.clone(), x2.clone()];
2321
2322 let input = MultiBlockAloInput {
2323 n_obs: n,
2324 n_blocks: 2,
2325 block_designs: &block_designs,
2326 penalized_hessian_inv: &h_inv,
2327 block_weights: block_weights.clone(),
2328 scores,
2329 eta_hat,
2330 };
2331 let full = compute_multiblock_alo(&input).unwrap();
2332 let lev_only =
2333 compute_multiblock_alo_leverages(n, 2, &block_designs, &h_inv, &block_weights).unwrap();
2334
2335 for i in 0..n {
2336 assert!(
2337 (full.leverage[i] - lev_only[i]).abs() < 1e-12,
2338 "leverage mismatch at i={}: full={}, lev_only={}",
2339 i,
2340 full.leverage[i],
2341 lev_only[i]
2342 );
2343 }
2344 }
2345
2346 #[test]
2347 fn multiblock_singular_weight_still_corrects() {
2348 let n = 1;
2352 let p = 2;
2353 let x = Array2::from_shape_vec((1, p), vec![1.0, 0.5]).unwrap();
2354 let h_inv = Array2::eye(p);
2355 let block_designs = vec![x.clone()];
2356 let block_weights = vec![Array2::from_elem((1, 1), 0.0)]; let scores = vec![Array1::from_vec(vec![1.0])];
2358 let eta_hat = vec![Array1::from_vec(vec![std::f64::consts::PI])];
2359
2360 let input = MultiBlockAloInput {
2361 n_obs: n,
2362 n_blocks: 1,
2363 block_designs: &block_designs,
2364 penalized_hessian_inv: &h_inv,
2365 block_weights,
2366 scores,
2367 eta_hat,
2368 };
2369 let result = compute_multiblock_alo(&input).unwrap();
2370 let expected = std::f64::consts::PI + 1.25;
2372 assert!(
2373 (result.eta_tilde[0][0] - expected).abs() < 1e-12,
2374 "expected {}, got {}",
2375 expected,
2376 result.eta_tilde[0][0]
2377 );
2378 assert!(result.cook_distance[0].abs() < 1e-14);
2380 assert!(result.alo_variance[0][0].abs() < 1e-14);
2382 }
2383
2384 #[test]
2385 fn multiblock_cook_and_variance_basic() {
2386 let n = 1;
2388 let x = Array2::from_elem((1, 1), 1.0);
2389 let h_inv = Array2::from_elem((1, 1), 0.5);
2391 let block_designs = vec![x.clone()];
2392 let w_val = 2.0;
2393 let s_val = 0.4;
2394 let block_weights = vec![Array2::from_elem((1, 1), w_val)];
2395 let scores = vec![Array1::from_vec(vec![s_val])];
2396 let eta_hat = vec![Array1::from_vec(vec![1.0])];
2397
2398 let input = MultiBlockAloInput {
2399 n_obs: n,
2400 n_blocks: 1,
2401 block_designs: &block_designs,
2402 penalized_hessian_inv: &h_inv,
2403 block_weights,
2404 scores,
2405 eta_hat,
2406 };
2407 let result = compute_multiblock_alo(&input).unwrap();
2408
2409 assert!(result.eta_tilde[0][0].is_finite());
2416 assert!(result.cook_distance[0].is_finite());
2417 assert!(result.alo_variance[0][0].is_finite());
2418 }
2419}