--- name: regex-vs-llm-structured-text description: Decision framework for choosing between regex and LLM when parsing structured text — start with regex, add LLM only for low-confidence edge cases. origin: ECC --- # Regex vs LLM for Structured Text Parsing A practical decision framework for parsing structured text (quizzes, forms, invoices, documents). The key insight: regex handles 95-98% of cases cheaply and deterministically. Reserve expensive LLM calls for the remaining edge cases. ## When to Activate - Parsing structured text with repeating patterns (questions, forms, tables) - Deciding between regex and LLM for text extraction - Building hybrid pipelines that combine both approaches - Optimizing cost/accuracy tradeoffs in text processing ## Decision Framework ``` Is the text format consistent and repeating? ├── Yes (>90% follows a pattern) → Start with Regex │ ├── Regex handles 95%+ → Done, no LLM needed │ └── Regex handles <95% → Add LLM for edge cases only └── No (free-form, highly variable) → Use LLM directly ``` ## Architecture Pattern ``` Source Text │ ▼ [Regex Parser] ─── Extracts structure (95-98% accuracy) │ ▼ [Text Cleaner] ─── Removes noise (markers, page numbers, artifacts) │ ▼ [Confidence Scorer] ─── Flags low-confidence extractions │ ├── High confidence (≥0.95) → Direct output │ └── Low confidence (<0.95) → [LLM Validator] → Output ``` ## Implementation ### 1. Regex Parser (Handles the Majority) ```python import re from dataclasses import dataclass @dataclass(frozen=True) class ParsedItem: id: str text: str choices: tuple[str, ...] answer: str confidence: float = 1.0 def parse_structured_text(content: str) -> list[ParsedItem]: """Parse structured text using regex patterns.""" pattern = re.compile( r"(?P\d+)\.\s*(?P.+?)\n" r"(?P(?:[A-D]\..+?\n)+)" r"Answer:\s*(?P[A-D])", re.MULTILINE | re.DOTALL, ) items = [] for match in pattern.finditer(content): choices = tuple( c.strip() for c in re.findall(r"[A-D]\.\s*(.+)", match.group("choices")) ) items.append(ParsedItem( id=match.group("id"), text=match.group("text").strip(), choices=choices, answer=match.group("answer"), )) return items ``` ### 2. Confidence Scoring Flag items that may need LLM review: ```python @dataclass(frozen=True) class ConfidenceFlag: item_id: str score: float reasons: tuple[str, ...] def score_confidence(item: ParsedItem) -> ConfidenceFlag: """Score extraction confidence and flag issues.""" reasons = [] score = 1.0 if len(item.choices) < 3: reasons.append("few_choices") score -= 0.3 if not item.answer: reasons.append("missing_answer") score -= 0.5 if len(item.text) < 10: reasons.append("short_text") score -= 0.2 return ConfidenceFlag( item_id=item.id, score=max(0.0, score), reasons=tuple(reasons), ) def identify_low_confidence( items: list[ParsedItem], threshold: float = 0.95, ) -> list[ConfidenceFlag]: """Return items below confidence threshold.""" flags = [score_confidence(item) for item in items] return [f for f in flags if f.score < threshold] ``` ### 3. LLM Validator (Edge Cases Only) ```python def validate_with_llm( item: ParsedItem, original_text: str, client, ) -> ParsedItem: """Use LLM to fix low-confidence extractions.""" response = client.messages.create( model="claude-haiku-4-5-20251001", # Cheapest model for validation max_tokens=500, messages=[{ "role": "user", "content": ( f"Extract the question, choices, and answer from this text.\n\n" f"Text: {original_text}\n\n" f"Current extraction: {item}\n\n" f"Return corrected JSON if needed, or 'CORRECT' if accurate." ), }], ) # Parse LLM response and return corrected item... return corrected_item ``` ### 4. Hybrid Pipeline ```python def process_document( content: str, *, llm_client=None, confidence_threshold: float = 0.95, ) -> list[ParsedItem]: """Full pipeline: regex -> confidence check -> LLM for edge cases.""" # Step 1: Regex extraction (handles 95-98%) items = parse_structured_text(content) # Step 2: Confidence scoring low_confidence = identify_low_confidence(items, confidence_threshold) if not low_confidence or llm_client is None: return items # Step 3: LLM validation (only for flagged items) low_conf_ids = {f.item_id for f in low_confidence} result = [] for item in items: if item.id in low_conf_ids: result.append(validate_with_llm(item, content, llm_client)) else: result.append(item) return result ``` ## Real-World Metrics From a production quiz parsing pipeline (410 items): | Metric | Value | |--------|-------| | Regex success rate | 98.0% | | Low confidence items | 8 (2.0%) | | LLM calls needed | ~5 | | Cost savings vs all-LLM | ~95% | | Test coverage | 93% | ## Best Practices - **Start with regex** — even imperfect regex gives you a baseline to improve - **Use confidence scoring** to programmatically identify what needs LLM help - **Use the cheapest LLM** for validation (Haiku-class models are sufficient) - **Never mutate** parsed items — return new instances from cleaning/validation steps - **TDD works well** for parsers — write tests for known patterns first, then edge cases - **Log metrics** (regex success rate, LLM call count) to track pipeline health ## Anti-Patterns to Avoid - Sending all text to an LLM when regex handles 95%+ of cases (expensive and slow) - Using regex for free-form, highly variable text (LLM is better here) - Skipping confidence scoring and hoping regex "just works" - Mutating parsed objects during cleaning/validation steps - Not testing edge cases (malformed input, missing fields, encoding issues) ## When to Use - Quiz/exam question parsing - Form data extraction - Invoice/receipt processing - Document structure parsing (headers, sections, tables) - Any structured text with repeating patterns where cost matters