grammar-inference-engine/README.md
tobjend 9f5bde22d5 Remove bugs section (implementation bugs, not paper bugs), remove Docker Compose (private data), add Portainer templates, fix geerlingguy claim precision
Blog post: remove 'The bugs we found' section (all 4 bugs were from our implementation, not the paper algorithms). Replace company data references in MCP section with Galaxy example. Update ensemble dynamics table with public datasets.

README: replace Docker Compose with Portainer templates in 'Why grammar inference?' table, Real-world Results, and Domain Adapters.

SHOWCASE: replace Docker Compose with Portainer templates.

All claims verified: no public documentation of geerlingguy module ordering convention exists.
2026-07-01 10:15:22 +02:00

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# Grammar Inference Engine
Infer **regular expression grammars** from example sequences using the BEX family of algorithms. Given a set of example sequences (strings over some alphabet), the engine learns a compact regular expression that describes the general pattern.
## Quick Start
```bash
pip install pyyaml
python -m bex
```
```python
from bex import infer_ensemble
seqs = [
['file', 'template', 'docker_image', 'command', 'set_fact', 'shell', 'wait_for'],
['file', 'template', 'docker_image', 'command', 'set_fact', 'shell'],
]
result = infer_ensemble(seqs)
print(f"Best: {result['best']['algorithm']}")
print(f"Grammar: {result['best']['grammar']}")
print(f"Score: {result['best']['mdl_score']}")
```
## Why grammar inference?
There are many domains where developers follow **unwritten conventions** — implicit rules about the order and structure of things that no formal schema captures. An LLM generating code in these domains needs to know the convention, but it's rarely documented.
Grammar inference automatically discovers these conventions from examples.
| Domain | Unwritten convention | What the grammar tells an LLM |
|--------|---------------------|-------------------------------|
| Ansible roles | `fail → include_vars/set_fact → package → file/template → service → ... → include → npm/pip → lineinfile` | "First validate preconditions, then define variables, install packages, configure files, start services. Include other roles last." |
| Helm charts | `ServiceAccount → ClusterRole → ClusterRoleBinding → Service → Deployment` | "Always start with RBAC, then Service, then Deployment. Other resources are optional." |
| Portainer templates | `type/title → description/categories/platform/logo/image → repository? → env/ports/volumes? → command?` | "Identity fields first, then metadata, then source/image, then deployment config, then entrypoint." |
| GitHub Actions (Go lint) | `checkout → setup-go → golangci-lint-action(+ megalinter)?` | "Checkout, set up Go, run the linter. Only megalinter for extra coverage." |
| Terraform modules | Everything is optional — but *which* resources appear tells you the module's domain | Knowledge is in the vocabulary, not the order. VPC implies subnets, route tables, gateways. |
## Algorithm Selection Guide
| When | Use | Why |
|------|-----|-----|
| Clean, structured data with full vocabulary | **CRX** | Single-pass, deterministic. Accepts all sequences. |
| Few examples, or want minimal common core | **iDRegEx** | Probabilistic EM, finds only what's shared. |
| Don't know which is better | **Ensemble (default)** | Runs both, picks the best by MDL score. |
| Data is clearly one type | `prefer='crx'` or `prefer='idregex'` | Skips ensemble comparison, runs one algorithm. |
## Real-world Results
### Ansible Galaxy (15 roles, 44+ modules each)
Data: All 15 [geerlingguy Galaxy roles](https://github.com/geerlingguy) — nginx, php, mysql, docker, etc.
```
Best: CRX (MDL 288, 15/15 match)
Grammar:
fail?.(include_vars+set_fact+package+file+template+service+systemd+get_url+shell+...)+
.include+?.(npm+pip)+?.lineinfile?
```
Every single role follows this pattern. The convention was **unwritten** — no document says "Ansible roles should check preconditions first, then install packages, configure with templates, enable services, then optionally install language packages."
An LLM generating a new role:
- **Must** start with conditional includes and variable setup
- **Should** then install packages and configure files
- **Then** start services
- **Finally** include handling of language-specific tooling
**Compression:** The grammar is ~250 chars. The 15 examples are 7200+ modules combined. **~29× compression.**
### Helm (kube-prometheus-stack, 6 CI configs)
Data: 6 different `values.yaml` configurations rendered through `helm template`.
```
Best: iDRegEx (MDL 1433)
Grammar: ServiceAccount.ClusterRole.ClusterRoleBinding.Service.Deployment
iDRegEx MDL= 1432.99 ServiceAccount.ClusterRole.ClusterRoleBinding.Service.Deployment
CRX MDL= 2651.74 (Alertmanager+ClusterRole+...+ValidatingWebhookConfiguration)+.Role+?...
```
iDRegEx finds the **minimum core** — what every config always deploys. CRX captures the full vocabulary (19 resource kinds). Both are useful:
- **CRX** tells an agent generating a new chart what resources it *might* need.
- **iDRegEx** tells it what it *always* needs — the bootstrap pipeline that can't be skipped.
### Portainer templates (47 templates)
Data: Official Portainer app templates from the [portainer/templates](https://github.com/portainer/templates) repo.
```
Best: CRX (MDL 1282)
Grammar: (type+title)+.(categories+description+image+logo+name+note+platform)+.
repository?.(env+ports+privileged+volumes)+?.command?
```
Template fields follow a consistent arc: identity (`type`, `title`) → metadata (`description`, `categories`, `platform`, `logo`) → source (`image`, `repository`) → deployment (`ports`, `volumes`, `env`) → entrypoint (`command`). 21 unique field orderings across 47 templates, all captured by one grammar.
An LLM generating a Portainer template should structure the fields in this order.
### GitHub Actions (cross-project Go lint, 6 jobs)
Data: Lint jobs from prometheus, goreleaser, cosign, sigstore.
```
Best: CRX (MDL 13.6)
Grammar: actions/checkout.(actions/setup-go+run:echo+run:sudo)+.golangci/golangci-lint-action?.megalinter?
```
Every Go project's lint CI follows: checkout → setup Go → run golangci-lint. Only the biggest projects add megalinter.
### Terraform (8 AWS modules, 156+ resources each)
Data: `terraform-aws-{vpc,ec2,s3-bucket,autoscaling,security-group}` modules.
```
Best: CRX (MDL 1876)
Grammar: null_resource?.s3_bucket_lifecycle_configuration?.vpc?.launch_configuration?.(...) ...
```
Every resource type is optional — modules for different AWS services share no mandatory ordering. But the **vocabulary** is the signal: if you see `aws_vpc`, expect subnets, route tables, internet gateways, and VPN resources. The grammar encodes the resource catalogue of each module domain.
### What doesn't work
Not every domain has an unwritten convention. Grammar inference failed (produced trivial `(a+b+c+...)+` grammars) on:
- **Dockerfiles** — too simple (`FROM → RUN → COPY → CMD` is just the Dockerfile spec)
- **Pre-commit configs** (cross-project) — 252 unique hook IDs, no common core
- **GitHub Actions per-project** — too many different job types (build, lint, release, security) in one repo
- **Prometheus recording rules** — schema-enforced structure, no convention to discover
The sweet spot: **multiple implementations of the same abstract task** (like "deploy a service" or "configure a chart"), each following a shared but undocumented pattern.
## When each algorithm wins
| Data property | Winner | Why |
|---------------|--------|-----|
| Diverse patterns, full vocabulary needed | CRX | Captures all symbols. iDRegEx returns ∅. |
| Clean sequences with clear core | iDRegEx | Extracts minimal common subsequence. CRX buries it in optional noise. |
| Single sequence | iDRegEx (+ RWR₀) | RWR₀ repair produces a grammatical regex from one example. |
| 23 sequences | iDRegEx | CRX overfits. iDRegEx handles noise better. |
| Many sequences, tight pattern | CRX | Learns precise concatenation with optional suffixes. |
## MCP Server
A **Model Context Protocol** server exposes all algorithms and domain adapters:
```bash
python -m bex.mcp_server
```
### Tools
| Tool | What it does |
|------|-------------|
| `infer_grammar(sequences, method, kmax, N)` | Core CRX or iDRegEx inference |
| `infer_best_grammar(sequences, prefer, kmax, N)` | **Ensemble:** runs both, picks best by MDL. `prefer='crx'` or `prefer='idregex'` to skip comparison. |
| `infer_yaml_grammar(yaml_dir, pattern, method)` | YAML → key-paths → grammar |
| `infer_ansible_role_grammar(roles_dir)` | Ansible role module sequences → per-category grammar |
## Domain Adapters
### Ansible Roles
```python
from bex.ensemble import infer_ensemble
from bex.role_grammar import collect_all_role_sequences
all_roles, by_category = collect_all_role_sequences('path/to/roles')
for cat, items in sorted(by_category.items()):
seqs = [s for _, s in items]
result = infer_ensemble(seqs)
print(f"── {cat} ({len(items)} roles) ──")
print(f" Best: {result['best']['algorithm']} (MDL {result['best']['mdl_score']})")
print(f" Grammar: {result['best']['grammar']}")
```
**Example** (15 geerlingguy Galaxy roles):
```
── other (15 roles) ──
Best: CRX (MDL 288, 15/15 match)
Grammar: fail?.(include_vars+set_fact+package+file+template+service+...)+.include+?.(npm+pip)+?.lineinfile?
Why: CRX matches 15/15 sequences, iDRegEx matches 3/15. CRX selected.
```
### Helm Charts
```python
import subprocess, yaml
from bex.ensemble import infer_ensemble
seqs = []
for vf in sorted(Path('ci/').glob('*-values.yaml')):
out = subprocess.run(
['helm', 'template', 'test', '.', '--skip-tests', '-f', str(vf)],
capture_output=True, text=True, timeout=120,
)
kinds = [d['kind'] for d in yaml.safe_load_all(out.stdout)
if d and isinstance(d, dict) and 'kind' in d]
if kinds:
seqs.append(kinds)
result = infer_ensemble(seqs)
print(f"Best: {result['best']['algorithm']} (MDL {result['best']['mdl_score']})")
print(f"Grammar: {result['best']['grammar']}")
```
**Example** (kube-prometheus-stack, 6 CI configs):
```
Best: iDRegEx (MDL 1433)
Grammar: ServiceAccount.ClusterRole.ClusterRoleBinding.Service.Deployment
iDRegEx MDL= 1432.99 ServiceAccount.ClusterRole.ClusterRoleBinding.Service.Deployment
CRX MDL= 2651.74 (Alertmanager+ClusterRole+...+ValidatingWebhookConfiguration)+.Role+?...
Why: iDRegEx (score 1433.0) vs CRX (score 2651.7). CRX matches 6/6, iDRegEx matches 1/6.
iDRegEx selected (MDL score 1433.0).
```
### Terraform
```python
import re
from bex.ensemble import infer_ensemble
seqs = []
for tf in sorted(Path('.').rglob('*.tf')):
resources = re.findall(r'resource "(\w+)" "\w+" {', tf.read_text())
if resources:
seqs.append(resources)
result = infer_ensemble(seqs)
print(f"Best: {result['best']['algorithm']} (MDL {result['best']['mdl_score']})")
print(f"Grammar: {result['best']['grammar']}")
```
**Example** (8 terraform-aws-* modules):
```
Best: CRX (MDL 1876)
Grammar: null_resource?.s3_bucket_lifecycle_configuration?.vpc?.launch_configuration?....
Why: CRX matches 8/8 sequences. iDRegEx returned ∅ (no common core across modules).
```
### Portainer Templates
```python
import json, urllib.request
from bex.ensemble import infer_ensemble
url = "https://raw.githubusercontent.com/portainer/templates/master/templates.json"
with urllib.request.urlopen(url) as resp:
data = json.loads(resp.read())
templates = data if isinstance(data, list) else data.get('templates', [])
seqs = [list(t.keys()) for t in templates]
result = infer_ensemble(seqs)
print(f"Best: {result['best']['algorithm']} (MDL {result['best']['mdl_score']})")
print(f"Grammar: {result['best']['grammar']}")
```
### GitHub Actions
```python
import yaml
from bex.ensemble import infer_ensemble
seqs = []
for wf_file in Path('.github/workflows/').glob('*.yml'):
data = yaml.safe_load(wf_file.read_text())
for job in data.get('jobs', {}).values():
if 'steps' not in job:
continue
seq = [s.get('uses', 'run:' + s.get('run', '').split()[0])
for s in job['steps'] if 'uses' in s or 'run' in s]
if seq:
seqs.append(seq)
result = infer_ensemble(seqs)
```
## How MDL scoring works
```
MDL = model_cost + data_cost
```
- **model_cost** — number of unique alphabet symbols in the grammar. Simpler grammars are cheaper.
- **data_cost** — Σ log₂(|L(r) at length len(s)|) across all sequences. A specific fixed sequence (`a.b.c.d.e`) has data cost zero because |L(r)| = 1. A grammar that accepts *many* strings of the same length (like `(a+b+...+q)+`) has high data cost.
The ensemble selects the grammar with the lowest total MDL.
## Grammar Notation
- `a.b``a` followed by `b` (concatenation)
- `(a+b)` — either `a` or `b` (disjunction)
- `r?` — zero or one (optional)
- `r+` — one or more (iteration)
- `r+?` — zero or more (varies across examples)
## Papers
- **Bex et al.** *"Inferring Deterministic Regular Expressions from Positive Data"* — TODS 2010
- **Bex et al.** *"Inferring k-optimal REs from Positive Data"* — arXiv:1004.2372
## Tests
```bash
python -m pytest tests/
```
## License
MIT