Hugging Face's logo

Datasets:
gregb
/
sudoku-padic-regression-experiments

Tasks:
Tabular Regression
Modalities:
Document
Text
Formats:
text
Size:
< 1K
Tags:
sudoku
p-adic
local-search
reproducibility
Libraries:
Datasets
License:
Dataset card Data Studio Files
xet
 Community
1
sudoku-padic-regression-experiments / code /run_experiments.py
gregb's picture
gregb
Add Sudoku p-adic regression experiment bundle
94ec51c verified
raw
history blame contribute delete
8.66 kB
#!/usr/bin/env python3
"""
run_experiments.py
Reproducible experiments for the "Sudoku the Hard Way" p-adic regression solver.
Default behaviour is *fast*: puzzles are produced by carving random solved grids down to a
given clue count (no uniqueness guarantee). This keeps runtimes sane.
Use --unique to enforce unique solutions (slower, but closer to "real" Sudoku).
"""
from __future__ import annotations
import argparse
import csv
import time
from pathlib import Path
import random
import statistics
try:
 import matplotlib.pyplot as plt # type: ignore
except ImportError: # pragma: no cover
 plt = None
from padic_sudoku_regression import (
 generate_unique_puzzle,
 random_solved_grid,
 grid_to_string,
 parse_puzzle,
 solve_stepwise_swap,
 solve_greedy_descent_swap,
 solve_greedy_local_edit_best,
 solve_greedy_local_edit_first,
 solve_zubarev_local_edit,
 solve_zubarev_walk,
 pretty,
)
def carve_fast(solved, clues: int, rng: random.Random):
 puzzle = solved[:]
 positions = list(range(81))
 rng.shuffle(positions)
 to_remove = 81 - clues
 for pos in positions[:to_remove]:
 puzzle[pos] = 0
 return puzzle
def main() -> None:
 ap = argparse.ArgumentParser()
 ap.add_argument("--outdir", type=str, default=str(Path(__file__).resolve().parent.parent / "outputs"))
 ap.add_argument("--seed", type=int, default=0)
 ap.add_argument("--n", type=int, default=12, help="puzzles per clue count")
 ap.add_argument("--clues", type=str, default="36,30,26", help="comma-separated clue counts")
 ap.add_argument("--max-steps", type=int, default=200000)
 ap.add_argument("--restarts", type=int, default=30)
 ap.add_argument(
 "--method",
 type=str,
 default="stepwise",
 choices=["stepwise", "greedy", "zubarev", "local-best", "local-first", "local-zubarev"],
 )
 ap.add_argument("--beta0", type=float, default=0.5, help="Zubarev walk: initial beta (inverse temperature).")
 ap.add_argument("--beta1", type=float, default=6.0, help="Zubarev walk: final beta (ignored if schedule=constant).")
 ap.add_argument("--beta-schedule", type=str, default="linear", choices=["constant", "linear", "exp"])
 ap.add_argument("--unique", action="store_true", help="enforce uniqueness (slower)")
 args = ap.parse_args()
outdir = Path(args.outdir)
 outdir.mkdir(parents=True, exist_ok=True)
clue_counts = [int(x.strip()) for x in args.clues.split(",") if x.strip()]
 rng = random.Random(args.seed)
results_rows = []
# We'll capture a trace for the first puzzle in the middle clue count (if available).
 trace_target = clue_counts[len(clue_counts)//2]
 trace_saved = False
t0 = time.time()
for clues in clue_counts:
 for j in range(args.n):
 seed = rng.randrange(1_000_000_000)
if args.unique:
 puzzle = generate_unique_puzzle(clues=clues, seed=seed)
 else:
 solved = random_solved_grid(random.Random(seed))
 puzzle = carve_fast(solved, clues=clues, rng=random.Random(seed ^ 0xDEADBEEF))
puzzle_str = grid_to_string(puzzle)
record_trace = (not trace_saved) and (clues == trace_target) and (j == 0)
 if args.method == "stepwise":
 res = solve_stepwise_swap(
 puzzle,
 seed=seed ^ 0xA5A5A5A5,
 max_steps=args.max_steps,
 restarts=args.restarts,
 record_trace=record_trace,
 trace_every=200,
 )
 elif args.method == "greedy":
 res = solve_greedy_descent_swap(
 puzzle,
 seed=seed ^ 0xA5A5A5A5,
 max_steps=args.max_steps,
 restarts=args.restarts,
 record_trace=record_trace,
 trace_every=200,
 )
 elif args.method == "local-best":
 res = solve_greedy_local_edit_best(
 puzzle,
 seed=seed ^ 0xA5A5A5A5,
 max_steps=args.max_steps,
 restarts=args.restarts,
 record_trace=record_trace,
 trace_every=200,
 )
 elif args.method == "local-first":
 res = solve_greedy_local_edit_first(
 puzzle,
 seed=seed ^ 0xA5A5A5A5,
 max_steps=args.max_steps,
 restarts=args.restarts,
 record_trace=record_trace,
 trace_every=200,
 )
 elif args.method == "local-zubarev":
 res = solve_zubarev_local_edit(
 puzzle,
 seed=seed ^ 0xA5A5A5A5,
 max_steps=args.max_steps,
 restarts=args.restarts,
 beta0=args.beta0,
 beta1=args.beta1,
 beta_schedule=args.beta_schedule,
 record_trace=record_trace,
 trace_every=200,
 )
 else:
 res = solve_zubarev_walk(
 puzzle,
 seed=seed ^ 0xA5A5A5A5,
 max_steps=args.max_steps,
 restarts=args.restarts,
 beta0=args.beta0,
 beta1=args.beta1,
 beta_schedule=args.beta_schedule,
 record_trace=record_trace,
 trace_every=200,
 )
results_rows.append({
 "clues": clues,
 "puzzle_seed": seed,
 "solve_seed": seed ^ 0xA5A5A5A5,
 "unique_enforced": int(args.unique),
 "method": args.method,
 "objective": res.objective_label,
 "puzzle": puzzle_str,
 "solved": int(res.solved),
 "steps": res.steps,
 "restarts_used": res.restarts,
 "seconds": res.seconds,
 "final_conflicts": res.final_conflicts,
 })
if record_trace and res.trace is not None:
 # Save trace plot
 if plt is None:
 print("Note: matplotlib not installed; skipping loss_curve plot.")
 else:
 fig = plt.figure()
 x_values = res.trace_steps if res.trace_steps is not None else [200 * k for k in range(len(res.trace))]
 plt.plot(x_values, res.trace)
 plt.xlabel("Iteration (approx.)")
 plt.ylabel(f"{res.objective_label} conflict pairs")
 plt.title(f"Loss trajectory (clues={clues}, seed={seed})")
 fig.tight_layout()
 png_path = outdir / "loss_curve.png"
 pdf_path = outdir / "loss_curve.pdf"
 fig.savefig(png_path, dpi=200)
 fig.savefig(pdf_path)
 plt.close(fig)
# also save the puzzle and (if solved) its solution
 (outdir / "trace_puzzle.txt").write_text(pretty(parse_puzzle(puzzle_str)))
 if res.solved:
 (outdir / "trace_solution.txt").write_text(pretty(res.grid))
 trace_saved = True
# Write CSV
 csv_path = outdir / "experiment_results.csv"
 with csv_path.open("w", newline="") as f:
 w = csv.DictWriter(f, fieldnames=list(results_rows[0].keys()))
 w.writeheader()
 for row in results_rows:
 w.writerow(row)
# Summaries
 summary_lines = []
 summary_lines.append(f"Total runs: {len(results_rows)}")
 summary_lines.append(f"Unique enforced: {args.unique}")
 for clues in clue_counts:
 subset = [r for r in results_rows if r["clues"] == clues]
 solved = [r for r in subset if r["solved"] == 1]
 summary_lines.append(f"\nClues={clues}: solved {len(solved)}/{len(subset)}")
 if solved:
 steps = [r["steps"] for r in solved]
 secs = [r["seconds"] for r in solved]
 summary_lines.append(f" median steps: {int(statistics.median(steps))}")
 summary_lines.append(f" median seconds: {statistics.median(secs):.3f}")
 (outdir / "summary.txt").write_text("\n".join(summary_lines))
dt = time.time() - t0
 print("Wrote", csv_path)
 print("Wall time:", f"{dt:.2f}s")
 print((outdir / "summary.txt").read_text())
if __name__ == "__main__":
 main()