"""RV11 alignment structure analysis. Compares gap structure and alignment geometry between kalign, reference, and external tools (mafft, muscle, clustalo) to understand HOW alignments differ structurally — not just score differences. Usage: # Locally (kalign only, external tools skipped if not installed): uv run python -m benchmarks.analysis # Inside container (has mafft/muscle/clustalo): python -m benchmarks.analysis # Specific dataset: python -m benchmarks.analysis --dataset balibase_RV11 # Write CSV: python -m benchmarks.analysis --csv benchmarks/results/gap_analysis.csv """ import argparse import csv import json import re import statistics import sys import tempfile from dataclasses import dataclass, fields from pathlib import Path from typing import Dict, List, Optional, Tuple from .datasets import balibase_cases, balibase_is_available RESULTS_DIR = Path(__file__).parent / "results" # --------------------------------------------------------------------------- # MSF parser (reference alignments are in GCG MSF format) # --------------------------------------------------------------------------- def parse_msf(path: Path) -> Dict[str, str]: """Parse a GCG MSF file into {name: aligned_sequence}.""" text = path.read_text() # Split at "//" separator parts = text.split("//") if len(parts) < 2: raise ValueError(f"No // separator found in {path}") body = parts[1] seqs: Dict[str, List[str]] = {} for line in body.splitlines(): line = line.strip() if not line: continue tokens = line.split() if len(tokens) < 2: continue name = tokens[0] # Sequence characters (may contain dots for gaps) seq_parts = "".join(tokens[1:]) seqs.setdefault(name, []).append(seq_parts) # Join blocks and normalise: dots → dashes, remove whitespace result = {} for name, blocks in seqs.items(): seq = "".join(blocks).replace(".", "-").upper() result[name] = seq return result # --------------------------------------------------------------------------- # FASTA parser (kalign/tool outputs) # --------------------------------------------------------------------------- def parse_fasta(path: Path) -> Dict[str, str]: """Parse a FASTA file into {name: sequence}.""" seqs: Dict[str, str] = {} current = None parts: List[str] = [] for line in path.read_text().splitlines(): line = line.strip() if line.startswith(">"): if current is not None: seqs[current] = "".join(parts).upper() current = line[1:].split()[0] parts = [] elif current is not None: parts.append(line) if current is not None: seqs[current] = "".join(parts).upper() return seqs # --------------------------------------------------------------------------- # Gap structure metrics # --------------------------------------------------------------------------- @dataclass class GapStats: """Gap structure metrics for one alignment.""" n_seqs: int alignment_length: int mean_seq_length: float # unaligned (non-gap chars) expansion_factor: float # alignment_length / mean_seq_length total_gaps: int gap_fraction: float # total_gaps / (n_seqs * alignment_length) n_gap_blocks: int mean_gap_block_len: float mean_terminal_gap: float # average leading+trailing gap per sequence mean_internal_gap: float # average total internal gap chars per sequence n_gappy_columns: int # columns where >50% of sequences have a gap gappy_column_fraction: float def compute_gap_stats(seqs: Dict[str, str]) -> GapStats: """Compute gap structure metrics from aligned sequences.""" sequences = list(seqs.values()) n_seqs = len(sequences) if n_seqs == 0: return GapStats(0, 0, 0.0, 0.0, 0, 0.0, 0, 0.0, 0.0, 0.0, 0, 0.0) aln_len = len(sequences[0]) # Unaligned lengths (non-gap characters) ungapped_lens = [len(s.replace("-", "")) for s in sequences] mean_seq_len = statistics.mean(ungapped_lens) expansion = aln_len / mean_seq_len if mean_seq_len > 0 else 0.0 total_gaps = sum(s.count("-") for s in sequences) total_chars = n_seqs * aln_len gap_frac = total_gaps / total_chars if total_chars > 0 else 0.0 # Gap blocks and lengths all_block_lens: List[int] = [] terminal_gaps: List[int] = [] internal_gaps: List[int] = [] for seq in sequences: # Find all gap blocks blocks = [(m.start(), m.end()) for m in re.finditer(r"-+", seq)] all_block_lens.extend(m.end() - m.start() for m in re.finditer(r"-+", seq)) # Terminal: leading and trailing leading = len(seq) - len(seq.lstrip("-")) trailing = len(seq) - len(seq.rstrip("-")) terminal_gaps.append(leading + trailing) # Internal: everything that's not leading/trailing internal = sum(e - s for s, e in blocks) internal -= leading + trailing internal_gaps.append(max(0, internal)) n_gap_blocks = len(all_block_lens) mean_block_len = statistics.mean(all_block_lens) if all_block_lens else 0.0 mean_terminal = statistics.mean(terminal_gaps) mean_internal = statistics.mean(internal_gaps) # Gappy columns (>50% gaps) n_gappy = 0 for col in range(aln_len): gaps_in_col = sum(1 for s in sequences if s[col] == "-") if gaps_in_col > n_seqs / 2: n_gappy += 1 return GapStats( n_seqs=n_seqs, alignment_length=aln_len, mean_seq_length=mean_seq_len, expansion_factor=expansion, total_gaps=total_gaps, gap_fraction=gap_frac, n_gap_blocks=n_gap_blocks, mean_gap_block_len=mean_block_len, mean_terminal_gap=mean_terminal, mean_internal_gap=mean_internal, n_gappy_columns=n_gappy, gappy_column_fraction=n_gappy / aln_len if aln_len > 0 else 0.0, ) # --------------------------------------------------------------------------- # Alignment generation helpers # --------------------------------------------------------------------------- def _align_kalign(unaligned: Path, output: Path, seq_type: str) -> None: """Run kalign via Python API.""" import kalign kalign.align_file_to_file( str(unaligned), str(output), format="fasta", seq_type=seq_type, ) def _align_external(unaligned: Path, output: Path, tool: str) -> bool: """Run an external tool. Returns True if successful.""" import shutil import subprocess if shutil.which(tool) is None: return False try: if tool == "mafft": with open(output, "w") as f: subprocess.run( ["mafft", "--auto", str(unaligned)], stdout=f, stderr=subprocess.PIPE, check=True, ) elif tool == "clustalo": subprocess.run( ["clustalo", "-i", str(unaligned), "-o", str(output), "--outfmt=fasta", "--force"], capture_output=True, check=True, ) elif tool == "muscle": subprocess.run( ["muscle", "-align", str(unaligned), "-output", str(output)], capture_output=True, check=True, ) return True except (subprocess.CalledProcessError, FileNotFoundError): return False # --------------------------------------------------------------------------- # Per-case analysis row # --------------------------------------------------------------------------- @dataclass class CaseRow: family: str method: str # Scores from results JSON (NaN if not available) recall: float precision: float f1: float tc: float # Gap stats alignment_length: int expansion_factor: float gap_fraction: float n_gap_blocks: int mean_gap_block_len: float mean_terminal_gap: float mean_internal_gap: float n_gappy_columns: int gappy_column_fraction: float # --------------------------------------------------------------------------- # Load frozen scores from full_comparison.json # --------------------------------------------------------------------------- def load_scores(json_path: Path, dataset_filter: str = "balibase_RV11") -> Dict[Tuple[str, str], dict]: """Load {(family, method_key): scores} from results JSON. method_key is 'kalign' for python_api/refine=none, or the external tool name. """ with open(json_path) as f: data = json.load(f) scores: Dict[Tuple[str, str], dict] = {} for r in data["results"]: if dataset_filter and r["dataset"] != dataset_filter: continue if r["method"] == "python_api" and r["refine"] == "none": key = (r["family"], "kalign") elif r["method"] in ("clustalo", "mafft", "muscle"): key = (r["family"], r["method"]) else: continue scores[key] = { "recall": r.get("recall", float("nan")), "precision": r.get("precision", float("nan")), "f1": r.get("f1", float("nan")), "tc": r.get("tc", float("nan")), } return scores # --------------------------------------------------------------------------- # Main analysis # --------------------------------------------------------------------------- def analyse_rv11( dataset_filter: str = "balibase_RV11", external_tools: Optional[List[str]] = None, ) -> List[CaseRow]: """Run gap analysis on all RV11 cases. Returns list of CaseRow.""" if external_tools is None: external_tools = ["mafft", "muscle", "clustalo"] if not balibase_is_available(): print("BAliBASE not downloaded. Run: uv run python -m benchmarks --download-only") return [] cases = [c for c in balibase_cases() if c.dataset == dataset_filter] if not cases: print(f"No cases found for {dataset_filter}") return [] # Load frozen scores json_path = RESULTS_DIR / "full_comparison.json" scores = load_scores(json_path, dataset_filter) if json_path.exists() else {} rows: List[CaseRow] = [] for case in cases: print(f" {case.family} ...", end="", flush=True) # --- Reference alignment --- ref_seqs = parse_msf(case.reference) ref_stats = compute_gap_stats(ref_seqs) sc = scores.get((case.family, "reference"), {}) rows.append(CaseRow( family=case.family, method="reference", recall=1.0, precision=1.0, f1=1.0, tc=1.0, alignment_length=ref_stats.alignment_length, expansion_factor=ref_stats.expansion_factor, gap_fraction=ref_stats.gap_fraction, n_gap_blocks=ref_stats.n_gap_blocks, mean_gap_block_len=ref_stats.mean_gap_block_len, mean_terminal_gap=ref_stats.mean_terminal_gap, mean_internal_gap=ref_stats.mean_internal_gap, n_gappy_columns=ref_stats.n_gappy_columns, gappy_column_fraction=ref_stats.gappy_column_fraction, )) # --- Kalign --- with tempfile.TemporaryDirectory() as tmpdir: kalign_out = Path(tmpdir) / f"{case.family}_kalign.fa" _align_kalign(case.unaligned, kalign_out, case.seq_type) kalign_seqs = parse_fasta(kalign_out) kalign_stats = compute_gap_stats(kalign_seqs) sc = scores.get((case.family, "kalign"), {}) rows.append(CaseRow( family=case.family, method="kalign", recall=sc.get("recall", float("nan")), precision=sc.get("precision", float("nan")), f1=sc.get("f1", float("nan")), tc=sc.get("tc", float("nan")), alignment_length=kalign_stats.alignment_length, expansion_factor=kalign_stats.expansion_factor, gap_fraction=kalign_stats.gap_fraction, n_gap_blocks=kalign_stats.n_gap_blocks, mean_gap_block_len=kalign_stats.mean_gap_block_len, mean_terminal_gap=kalign_stats.mean_terminal_gap, mean_internal_gap=kalign_stats.mean_internal_gap, n_gappy_columns=kalign_stats.n_gappy_columns, gappy_column_fraction=kalign_stats.gappy_column_fraction, )) # --- External tools --- for tool in external_tools: with tempfile.TemporaryDirectory() as tmpdir: tool_out = Path(tmpdir) / f"{case.family}_{tool}.fa" ok = _align_external(case.unaligned, tool_out, tool) if not ok: continue tool_seqs = parse_fasta(tool_out) tool_stats = compute_gap_stats(tool_seqs) sc = scores.get((case.family, tool), {}) rows.append(CaseRow( family=case.family, method=tool, recall=sc.get("recall", float("nan")), precision=sc.get("precision", float("nan")), f1=sc.get("f1", float("nan")), tc=sc.get("tc", float("nan")), alignment_length=tool_stats.alignment_length, expansion_factor=tool_stats.expansion_factor, gap_fraction=tool_stats.gap_fraction, n_gap_blocks=tool_stats.n_gap_blocks, mean_gap_block_len=tool_stats.mean_gap_block_len, mean_terminal_gap=tool_stats.mean_terminal_gap, mean_internal_gap=tool_stats.mean_internal_gap, n_gappy_columns=tool_stats.n_gappy_columns, gappy_column_fraction=tool_stats.gappy_column_fraction, )) print(" done") return rows # --------------------------------------------------------------------------- # Output formatting # --------------------------------------------------------------------------- def print_table(rows: List[CaseRow]) -> None: """Print a summary table to stdout, grouped by family.""" if not rows: return families = sorted(set(r.family for r in rows)) methods = sorted(set(r.method for r in rows)) # Per-case comparison table hdr = f"{'Family':<10} {'Method':<10} {'Recall':>7} {'Prec':>7} {'F1':>7} {'AlnLen':>7} {'Expand':>7} {'GapFrac':>7} {'GapBlk':>7} {'MeanBL':>7} {'TermGap':>7} {'IntGap':>7} {'Gappy%':>7}" print("\n" + "=" * len(hdr)) print(hdr) print("-" * len(hdr)) for fam in families: fam_rows = sorted( [r for r in rows if r.family == fam], key=lambda r: (r.method != "reference", r.method != "kalign", r.method), ) for r in fam_rows: rec = f"{r.recall:.3f}" if r.recall == r.recall else " n/a" pre = f"{r.precision:.3f}" if r.precision == r.precision else " n/a" f1 = f"{r.f1:.3f}" if r.f1 == r.f1 else " n/a" print( f"{r.family:<10} {r.method:<10} {rec:>7} {pre:>7} {f1:>7} " f"{r.alignment_length:>7} {r.expansion_factor:>7.2f} " f"{r.gap_fraction:>7.3f} {r.n_gap_blocks:>7} " f"{r.mean_gap_block_len:>7.1f} {r.mean_terminal_gap:>7.1f} " f"{r.mean_internal_gap:>7.1f} {r.gappy_column_fraction:>7.3f}" ) print() # Aggregate summary by method print("=" * 80) print("AGGREGATE SUMMARY (means across all families)") print("-" * 80) fmt = "{:<10} {:>7} {:>7} {:>7} {:>8} {:>7} {:>7} {:>8} {:>8}" print(fmt.format("Method", "Recall", "Prec", "F1", "Expand", "GapFrac", "MeanBL", "TermGap", "IntGap")) print("-" * 80) for method in ["reference", "kalign"] + [m for m in methods if m not in ("reference", "kalign")]: method_rows = [r for r in rows if r.method == method] if not method_rows: continue def safe_mean(vals): clean = [v for v in vals if v == v] # filter NaN return statistics.mean(clean) if clean else float("nan") rec = safe_mean([r.recall for r in method_rows]) pre = safe_mean([r.precision for r in method_rows]) f1 = safe_mean([r.f1 for r in method_rows]) exp = statistics.mean([r.expansion_factor for r in method_rows]) gf = statistics.mean([r.gap_fraction for r in method_rows]) mbl = statistics.mean([r.mean_gap_block_len for r in method_rows]) tg = statistics.mean([r.mean_terminal_gap for r in method_rows]) ig = statistics.mean([r.mean_internal_gap for r in method_rows]) rec_s = f"{rec:.3f}" if rec == rec else " n/a" pre_s = f"{pre:.3f}" if pre == pre else " n/a" f1_s = f"{f1:.3f}" if f1 == f1 else " n/a" print(fmt.format(method, rec_s, pre_s, f1_s, f"{exp:.2f}", f"{gf:.3f}", f"{mbl:.1f}", f"{tg:.1f}", f"{ig:.1f}")) # Correlation analysis: precision vs expansion factor for kalign kalign_rows = [r for r in rows if r.method == "kalign" and r.precision == r.precision] if len(kalign_rows) >= 5: print("\n" + "=" * 80) print("CORRELATION: kalign precision vs gap metrics") print("-" * 80) # Simple Pearson correlation def pearson(xs, ys): n = len(xs) if n < 3: return float("nan") mx, my = statistics.mean(xs), statistics.mean(ys) num = sum((x - mx) * (y - my) for x, y in zip(xs, ys)) dx = sum((x - mx) ** 2 for x in xs) ** 0.5 dy = sum((y - my) ** 2 for y in ys) ** 0.5 return num / (dx * dy) if dx > 0 and dy > 0 else float("nan") prec = [r.precision for r in kalign_rows] metrics = [ ("expansion_factor", [r.expansion_factor for r in kalign_rows]), ("gap_fraction", [r.gap_fraction for r in kalign_rows]), ("mean_gap_block_len", [r.mean_gap_block_len for r in kalign_rows]), ("mean_terminal_gap", [r.mean_terminal_gap for r in kalign_rows]), ("mean_internal_gap", [r.mean_internal_gap for r in kalign_rows]), ("gappy_column_fraction", [r.gappy_column_fraction for r in kalign_rows]), ] for name, vals in metrics: r = pearson(prec, vals) print(f" precision vs {name:<25}: r = {r:+.3f}") # Also: kalign expansion vs reference expansion ref_rows = {r.family: r for r in rows if r.method == "reference"} kalign_dict = {r.family: r for r in kalign_rows} common = sorted(set(ref_rows) & set(kalign_dict)) if common: print(f"\n Expansion factor comparison (kalign vs reference, n={len(common)}):") over = [f for f in common if kalign_dict[f].expansion_factor > ref_rows[f].expansion_factor * 1.05] under = [f for f in common if kalign_dict[f].expansion_factor < ref_rows[f].expansion_factor * 0.95] same = [f for f in common if f not in over and f not in under] print(f" Over-expanded (>5%): {len(over)}") print(f" Under-expanded: {len(under)}") print(f" Similar (+/-5%): {len(same)}") # Relative expansion ratio correlated with precision ratios = [kalign_dict[f].expansion_factor / max(ref_rows[f].expansion_factor, 0.01) for f in common] precs = [kalign_dict[f].precision for f in common] r_ratio = pearson(ratios, precs) print(f" Correlation (expand_ratio vs precision): r = {r_ratio:+.3f}") if over: print(f"\n Worst over-expanded cases (kalign expand / ref expand):") ranked = sorted(over, key=lambda f: kalign_dict[f].expansion_factor / max(ref_rows[f].expansion_factor, 0.01), reverse=True) for f in ranked[:10]: ke = kalign_dict[f].expansion_factor re = ref_rows[f].expansion_factor kp = kalign_dict[f].precision print(f" {f}: kalign={ke:.2f} ref={re:.2f} ratio={ke/re:.2f} precision={kp:.3f}") if under: print(f"\n Worst under-expanded cases (kalign expand / ref expand):") ranked = sorted(under, key=lambda f: kalign_dict[f].expansion_factor / max(ref_rows[f].expansion_factor, 0.01)) for f in ranked[:10]: ke = kalign_dict[f].expansion_factor re = ref_rows[f].expansion_factor kp = kalign_dict[f].precision print(f" {f}: kalign={ke:.2f} ref={re:.2f} ratio={ke/re:.2f} precision={kp:.3f}") def write_csv(rows: List[CaseRow], path: str) -> None: """Write analysis results to CSV.""" fieldnames = [f.name for f in fields(CaseRow)] Path(path).parent.mkdir(parents=True, exist_ok=True) with open(path, "w", newline="") as f: writer = csv.DictWriter(f, fieldnames=fieldnames) writer.writeheader() for row in rows: d = {fn: getattr(row, fn) for fn in fieldnames} writer.writerow(d) print(f"\nCSV written to {path}") # --------------------------------------------------------------------------- # CLI entry point # --------------------------------------------------------------------------- def main() -> None: parser = argparse.ArgumentParser( description="RV11 alignment structure analysis", prog="python -m benchmarks.analysis", ) parser.add_argument( "--dataset", default="balibase_RV11", help="Dataset filter (default: balibase_RV11)", ) parser.add_argument( "--csv", default="", help="Write results to CSV file", ) parser.add_argument( "--no-external", action="store_true", help="Skip external tools (mafft, muscle, clustalo)", ) args = parser.parse_args() external = [] if args.no_external else ["mafft", "muscle", "clustalo"] print(f"Analysing {args.dataset} alignment structure...") rows = analyse_rv11(dataset_filter=args.dataset, external_tools=external) if not rows: sys.exit(1) print_table(rows) if args.csv: write_csv(rows, args.csv) if __name__ == "__main__": main()