Metadata-Version: 2.4
Name: umcp
Version: 2.1.5
Summary: Universal Measurement Contract Protocol (UMCP): Production-grade contract-first validation framework with GCD and RCFT. Core Axiom: Collapse is generative; only what returns is real. 13 physics domains, 120+ closures, 3618+ tests.
Author: Clement Paulus
License-Expression: MIT
Project-URL: Homepage, https://github.com/calebpruett927/GENERATIVE-COLLAPSE-DYNAMICS
Project-URL: Repository, https://github.com/calebpruett927/GENERATIVE-COLLAPSE-DYNAMICS
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Project-URL: Changelog, https://github.com/calebpruett927/GENERATIVE-COLLAPSE-DYNAMICS/blob/main/CHANGELOG.md
Keywords: UMCP,GCD,RCFT,contract-first,validation,reproducibility,casepacks,fractal,recursive-field
Classifier: Development Status :: 4 - Beta
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Dynamic: license-file

# Generative Collapse Dynamics (GCD)

[![CI](https://github.com/calebpruett927/GENERATIVE-COLLAPSE-DYNAMICS/actions/workflows/validate.yml/badge.svg)](https://github.com/calebpruett927/GENERATIVE-COLLAPSE-DYNAMICS/actions)
[![Python 3.11+](https://img.shields.io/badge/python-3.11%2B-blue.svg)](https://www.python.org/downloads/)
[![C++17](https://img.shields.io/badge/C%2B%2B-17-blue.svg)](src/umcp_cpp/)
[![License: MIT](https://img.shields.io/badge/License-MIT-green.svg)](LICENSE)
[![UMCP v2.1.5](https://img.shields.io/badge/UMCP-v2.1.5-orange.svg)](pyproject.toml)
[![Tests: 5,247](https://img.shields.io/badge/tests-5%2C247-brightgreen.svg)](tests/)
[![Domains: 14](https://img.shields.io/badge/domains-14-blueviolet.svg)](closures/)
[![Closures: 120](https://img.shields.io/badge/closures-120-informational.svg)](closures/)
[![Theorems: 24](https://img.shields.io/badge/theorems-24_proven-ff69b4.svg)](closures/)

> **Core Axiom**: *"Collapse is generative; only what returns is real."*

**Universal Measurement Contract Protocol (UMCP)** is a contract-first validation framework that verifies reproducible computational workflows against mathematical contracts. It implements **Generative Collapse Dynamics (GCD)** and **Recursive Collapse Field Theory (RCFT)** — a unified measurement theory where every claim must demonstrate return through collapse under frozen evaluation rules.

This is not a simulation. It is a **metrological enforcement engine**: schema conformance, kernel identity verification, regime classification, and SHA-256 integrity checking — producing a three-valued `CONFORMANT` / `NONCONFORMANT` / `NON_EVALUABLE` verdict for every run.

**Python + C++ integration**: The framework is written in Python with **14 domains**, **120 closure modules**, **24 proven theorems** (241 computational subtests), and **5,247 tests**. An optional C++17 accelerator (`src/umcp_cpp/`) provides 50–80× speedup for three hot paths — kernel computation, seam chain accumulation, and SHA-256 integrity — via a pybind11 zero-copy NumPy bridge. The Python wrapper (`umcp.accel`) auto-detects the compiled extension at import time; if unavailable, every call falls back transparently to the equivalent NumPy implementation. Same formulas, same frozen parameters, same results to machine precision — the C++ layer is Tier-0 Protocol only and redefines no Tier-1 symbols.

---

## Table of Contents

- [Core Concepts](#core-concepts)
- [At a Glance](#at-a-glance)
- [Interactive Dashboard](#interactive-dashboard)
- [Architecture](#architecture)
- [Closure Domains (14 Physics Domains)](#closure-domains)
- [The Kernel](#the-kernel)
- [Originality & Terminology](#originality--terminology)
- [Installation](#installation)
- [Quick Start](#quick-start)
- [CLI Reference](#cli-reference)
  - [Startup — From Clone to Running](#startup--from-clone-to-running)
  - [C++ Accelerator — Build & Verify](#c-accelerator--build--verify)
  - [Services — API & Dashboard](#services--api--dashboard)
  - [Development Loop — Edit, Validate, Commit](#development-loop--edit-validate-commit)
  - [Reset & Clean Slate](#reset--clean-slate)
  - [Useful Utilities](#useful-utilities)
- [Validation Pipeline](#validation-pipeline)
- [Test Suite](#test-suite)
- [Documentation](#documentation)
- [Diagrams & Proofs](#diagrams--proofs)
- [Key Discoveries](#key-discoveries)
- [Papers & Publications](#papers--publications)
- [Repository Structure](#repository-structure)
- [Contributing](#contributing)
- [License](#license)

---

## Core Concepts

### Collapse Is Generative; Only What Returns Is Real

UMCP enforces a single axiom (**Axiom-0**): *"Collapse is generative; only what returns is real."* This is not a metaphor — it is a constraint on admissible claims. If you claim a system is stable, continuous, or coherent, you must show it can re-enter its admissible neighborhood after drift, perturbation, or delay — under the same frozen evaluation rules. Every decision, description, and code change in this repository is consistent with Axiom-0.

| Term | Operational Meaning |
|------|---------------------|
| **Collapse** | Regime label produced by kernel gates on (ω, F, S, C) under frozen thresholds |
| **Return** (τ_R) | Re-entry condition: existence of prior state within tolerance; yields τ_R or INF_REC |
| **Gesture** | An epistemic emission that does not weld: no return, no credit |
| **Drift** (ω) | ω = 1 − F, collapse proximity measure, range [0, 1] |
| **Integrity** (IC) | Kernel composite: IC = exp(κ), geometric mean of channel contributions |
| **Seam** | The verification boundary between outbound collapse and demonstrated return |
| **Frozen** | Consistent across the seam — same rules govern both sides of every collapse-return boundary |
| **Contract** | Frozen interface snapshot: pins units, embedding, clipping, weights, return settings |

### Three-Valued Verdicts

Every validation produces one of three outcomes — never boolean:

- **`CONFORMANT`** — All contracts, identities, and integrity checks pass
- **`NONCONFORMANT`** — At least one check fails
- **`NON_EVALUABLE`** — Insufficient data to determine status

---

## At a Glance

### The Three-Tier Stack

Tier-1 (immutable invariants) → Tier-0 (protocol) → Tier-2 (expansion space). One-way dependency. No back-edges within a frozen run. Every domain closure is validated *through* Tier-0 *against* Tier-1.

![Tier Architecture](images/10_tier_architecture.png)

### Integrity Bound: IC ≤ F — Zero Violations

The integrity bound holds universally across 31 Standard Model particles + 118 periodic table elements. Derived independently from Axiom-0. Zero violations.

![Integrity Bound Proof](images/09_integrity_bound_proof.png)

### Validation Timelapse: Living Ledger History

Every `umcp validate` run is recorded in the append-only ledger. Cumulative runs, kernel invariant evolution, and conformance rate over time. *"Nihil in memoria perit."*

![Validation Timelapse](images/08_validation_timelapse.png)

---

## Interactive Dashboard

**44 pages · 14 science domains · Real-time kernel exploration**

UMCP ships with a full-featured **Streamlit dashboard** for interactive exploration of every domain, kernel metric, and validation result. No coding required — launch it with one command and explore everything from subatomic particles to neuroscience through the GCD kernel.

### Quick Launch

```bash
# Install with visualization dependencies
pip install -e ".[all]"

# Launch the dashboard (opens at http://localhost:8501)
umcp-dashboard
```

That's it. The dashboard auto-detects all casepacks, contracts, closures, and ledger data.

### What's Inside

| Category | Pages | Highlights |
|----------|-------|------------|
| **Core** | Overview, Domain Overview, Health, Ledger, Metrics | System-wide health monitoring, conformance tracking, kernel metric trends |
| **Science Domains** | Cosmology, Astronomy, Nuclear, Quantum, Atomic Physics, Standard Model, Materials Science, Finance, RCFT, Security, Everyday Physics | Interactive closure exploration for all 14 domains with live kernel computation |
| **Evolution & Cognition** | Evolution Kernel, Brain Kernel, Awareness Manifold, Cognitive Traversal | 40-organism evolution kernel, 10-channel brain analysis, compositional traversal |
| **Analysis** | Regime, Time Series, Comparison, Formula Builder, Precision | Regime phase diagrams, cross-domain comparison, custom formula evaluation |
| **Exploration** | Canon Explorer, Geometry, Rosetta Translation, Orientation, Physics, Kinematics | Cross-domain Rosetta translation, three-layer geometry visualization |
| **Tools** | Casepacks, Contracts, Closures, Live Runner, Batch Validation, Test Templates | Run validations directly from the browser, inspect casepack structure |
| **Diagnostics** | τ_R* Diagnostic, Epistemic Classification, Insights Engine | Thermodynamic phase diagrams, epistemic cost tracking, pattern discovery |
| **Manage** | Exports, Bookmarks, Notifications, API Integration | Export results, bookmark pages, connect to the REST API |

### Features

- **Categorized sidebar navigation** with expandable sections and quick-action buttons
- **Live validation** — run `umcp validate` on any casepack directly from the browser
- **Regime visualization** — interactive phase space plots with Stable / Watch / Collapse classification
- **Kernel computation** — compute F, ω, S, C, κ, IC on custom trace vectors in real time
- **Cross-domain comparison** — compare kernel outputs across all 14 physics domains
- **Auto-refresh mode** — continuously monitor validation status
- **Responsive layout** with compact mode for data-dense views

### Alternative Launch Methods

```bash
# Direct Streamlit invocation (headless mode for servers)
streamlit run src/umcp/dashboard/__init__.py --server.port 8501 --server.headless true

# Via helper scripts
bash scripts/start_dashboard.sh            # Start in background
bash scripts/stop_dashboard.sh             # Stop background instance
```

### REST API (Companion)

The dashboard pairs with an optional FastAPI REST server for programmatic access:

```bash
umcp-api                                   # Starts at http://localhost:8000
# Interactive docs at http://localhost:8000/docs
```

---

## Architecture

### The Unit of Work: Casepacks

A **casepack** is the atomic unit of reproducible validation — a self-contained directory with:

```
casepacks/my_experiment/
├── manifest.json          # Contract reference, closure list, expected outputs
├── raw_data/              # Input observables
├── closures/              # Domain-specific computation modules
└── expected/              # Expected outputs for verification
```

UMCP ships with **15 casepacks** spanning all physics domains.

### Core Engine

```
src/umcp/
├── cli.py                    # Validation engine & all subcommands
├── validator.py              # Root-file validator (16 files, checksums, math identities)
├── kernel_optimized.py       # Lemma-based kernel computation (F, ω, S, C, κ, IC)
├── seam_optimized.py         # Optimized seam budget computation (Γ, D_C, Δκ)
├── tau_r_star.py             # τ_R* thermodynamic diagnostic (phase diagram)
├── tau_r_star_dynamics.py    # Dynamic τ_R* evolution and trajectories
├── compute_utils.py          # Vectorized utilities (coordinate clipping, bounds)
├── epistemic_weld.py         # Epistemic cost tracking (Theorem T9: observation cost)
├── measurement_engine.py     # Measurement pipeline engine
├── frozen_contract.py        # Frozen contract constants dataclass
├── insights.py               # Lessons-learned database (pattern discovery)
├── uncertainty.py            # Uncertainty propagation and error analysis
├── ss1m_triad.py             # SS1M triad computation
├── universal_calculator.py   # Universal kernel calculator CLI
├── fleet/                    # Distributed fleet-scale validation
│   ├── scheduler.py          # Job scheduler (submit, route, track)
│   ├── worker.py             # Worker + WorkerPool (register, heartbeat, execute)
│   ├── queue.py              # Priority queue (DLQ, retry, backpressure)
│   ├── cache.py              # Content-addressable artifact cache
│   └── tenant.py             # Multi-tenant isolation, quotas, namespaces
├── accel.py                  # C++ accelerator wrapper (auto-fallback to NumPy)
├── dashboard/                # Modular Streamlit dashboard
└── api_umcp.py               # FastAPI REST extension (Pydantic models)

src/umcp_cpp/                   # Optional C++ accelerator (Tier-0 Protocol)
├── include/umcp/
│   ├── kernel.hpp            # Kernel computation (F, ω, S, C, κ, IC) — ~50× speedup
│   ├── seam.hpp              # Seam chain accumulation — ~80× speedup
│   └── integrity.hpp         # SHA-256 (portable + OpenSSL) — ~5× speedup
├── bindings/py_umcp.cpp      # pybind11 zero-copy NumPy bridge
├── tests/test_kernel.cpp     # Catch2 tests (10K Tier-1 sweep)
└── CMakeLists.txt            # C++17, pybind11, optional OpenSSL
```

### Contract Infrastructure

| Artifact | Count | Location | Purpose |
|----------|:-----:|----------|---------|
| **Contracts** | 13 | `contracts/*.yaml` | Frozen mathematical contracts (JSON Schema Draft 2020-12) |
| **Schemas** | 14 | `schemas/*.schema.json` | JSON Schema files validating all artifacts |
| **Canon Anchors** | 12 | `canon/*.yaml` | Domain-specific canonical reference points |
| **Casepacks** | 15 | `casepacks/` | Reproducible validation bundles |
| **Closure Domains** | 14 | `closures/*/` | Domain closure packages (120 modules) |
| **Closure Registry** | 1 | `closures/registry.yaml` | Central listing of all closures |
| **Validator Rules** | 1 | `validator_rules.yaml` | Semantic rule definitions (E101, W201, ...) |
| **Integrity** | 1 | `integrity/sha256.txt` | SHA-256 checksums for all tracked files |

---

## Closure Domains

UMCP validates across **14 domains** with **120 closure modules**, each encoding real-world measurements into the 8-channel kernel trace:

### Standard Model — 9 modules

The crown jewel: 31 particles mapped through the GCD kernel with **10 proven theorems** (74/74 subtests at machine precision). Part of a **24-theorem corpus** across three formalisms (10 SM + 7 kernel structural + 7 universal regime calibration), all proven with 241 total computational subtests.

| Module | What It Encodes |
|--------|----------------|
| `particle_catalog.py` | Full SM particle table (PDG 2024 data) |
| `subatomic_kernel.py` | 31 particles → 8-channel trace → kernel |
| `particle_physics_formalism.py` | 10 Tier-2 theorems connecting SM physics to GCD |
| `coupling_constants.py` | Running couplings α_s(Q²), α_em(Q²), G_F |
| `cross_sections.py` | σ(e⁺e⁻→hadrons), R-ratio, Drell-Yan |
| `symmetry_breaking.py` | Higgs mechanism, VEV = 246.22 GeV, Yukawa |
| `ckm_mixing.py` | CKM matrix, Wolfenstein parametrization, J_CP |
| `neutrino_oscillation.py` | Neutrino oscillation and mass mixing |
| `pmns_mixing.py` | PMNS matrix, leptonic mixing angles |

**Key discoveries**: Confinement visible as a 98.1% IC cliff at the quark→hadron boundary. Neutral particles show 50× IC suppression. Generation monotonicity (Gen1 < Gen2 < Gen3) confirmed in both quarks and leptons.

### Atomic Physics — 10 modules

118 elements through the periodic kernel with **exhaustive Tier-1 proof** (10,162 tests, 0 failures).

| Module | What It Encodes |
|--------|----------------|
| `periodic_kernel.py` | 118-element periodic table through GCD kernel |
| `cross_scale_kernel.py` | 12-channel nuclear-informed atomic analysis |
| `tier1_proof.py` | Exhaustive proof: F+ω=1, IC≤F, IC=exp(κ) for all 118 elements |
| `electron_config.py` | Shell filling and configuration analysis |
| `fine_structure.py` | Fine structure constant α = 1/137 |
| `ionization_energy.py` | Ionization energy closures for all elements |
| `spectral_lines.py` | Emission/absorption spectral analysis |
| `selection_rules.py` | Quantum selection rules (Δl = ±1) |
| `zeeman_stark.py` | Zeeman and Stark effects |
| `recursive_instantiation.py` | Recursive instantiation patterns |

### Quantum Mechanics — 10 modules

| Module | What It Encodes |
|--------|----------------|
| `double_slit_interference.py` | 8 scenarios, 7 theorems — complementarity cliff discovery |
| `atom_dot_mi_transition.py` | Atom→quantum dot transition, 7 theorems (120 tests) |
| `ters_near_field.py` | TERS near-field enhancement, 7 theorems (72 tests) |
| `muon_laser_decay.py` | Muon-laser decay scenarios, 7 theorems (243 tests) |
| `wavefunction_collapse.py` | Wavefunction collapse dynamics |
| `entanglement.py` | Entanglement correlations |
| `tunneling.py` | Quantum tunneling barriers |
| `harmonic_oscillator.py` | Quantum harmonic oscillator |
| `uncertainty_principle.py` | Heisenberg uncertainty |
| `spin_measurement.py` | Spin measurement outcomes |

**Key discovery (double slit)**: Wave and particle are *both channel-deficient extremes*. The kernel-optimal state is partial measurement (V=0.70, D=0.71) where all channels are alive — the **complementarity cliff** (>5× IC gap).

### Materials Science — 14 modules

| Module | What It Encodes |
|--------|----------------|
| `element_database.py` | 118 elements × 18 fields |
| `band_structure.py` | Electronic band structure |
| `bcs_superconductivity.py` | BCS superconductivity theory |
| `cohesive_energy.py` | Cohesive energy analysis |
| `debye_thermal.py` | Debye thermal model |
| `elastic_moduli.py` | Elastic moduli computation |
| `magnetic_properties.py` | Magnetic property analysis |
| `phase_transition.py` | Phase transition dynamics |
| `surface_catalysis.py` | Surface catalysis reactions |
| `gap_capture_ss1m.py` | SS1M gap capture |

### Nuclear Physics — 8 modules

Alpha decay, fission, shell structure, decay chains, and Bethe-Weizsäcker binding energy for all nuclides.

### RCFT (Recursive Collapse Field Theory) — 9 modules

Attractor basins, fractal dimension, collapse grammar, information geometry, universality class assignment, active matter dynamics, and RCFT field diagnostics.

### Astronomy — 7 modules

Stellar evolution, HR diagram classification, distance ladder, gravitational dynamics, orbital mechanics, spectral analysis, and stellar luminosity.

### Kinematics — 6 modules

Linear and rotational kinematics, energy mechanics, momentum dynamics, phase space return, and kinematic stability.

### Weyl Cosmology — 6 modules

Modified gravity, Limber integrals, boost factors, sigma evolution, cosmology background, and Weyl transfer functions.

### GCD (Generative Collapse Dynamics) — 7 modules

Energy potential, entropic collapse, field resonance, generative flux, momentum flux, universal regime calibration (12 scenarios, 7 theorems, 94 subtests), and **kernel structural theorems** (7 theorems, 73 subtests): dimensionality fragility, positional democracy, weight hierarchy, monitoring paradox, approximation boundary, U-curve of degradation, and p=3 unification.

### Finance & Security — 16 modules

Portfolio continuity, market coherence, anomaly return, threat classification, trust fidelity, behavioral profiling, privacy auditing, and risk-regime mapping.

### Evolution — 6 modules

40 organisms across the tree of life, 5 recursive scales, 20 evolutionary phenomena as collapse-return cycles, deep implications with 20 cited sources (Fisher 1930 – Barnosky 2011), and a **10-channel brain kernel** spanning 20 species from C. elegans to Homo sapiens.

| Module | What It Encodes |
|--------|----------------|
| `evolution_kernel.py` | 40 organisms × 8 channels (genetic diversity → lineage persistence) |
| `recursive_evolution.py` | 5 nested scales (Gene → Clade) + 5 mass extinction collapse-return events |
| `axiom0_instantiation_map.py` | 20 phenomena × 3 states = 60 kernel states — Axiom-0 instantiation |
| `deep_implications.py` | 8 identity mappings, 8 deep case studies, 5 testable predictions, Fisher Information connection |
| `brain_kernel.py` | 20 species × 10 neuroscience channels, developmental trajectory (8 stages), 8 pathologies |
| `homo_sapiens_analysis.py` | Homo sapiens deep kernel portrait, 5 awareness patterns, cultural persistence sweep |

**Key discoveries**: Evolution is the only domain at 12/12 semantic depth (every Axiom-0 concept maps precisely). IC degrades Gene (0.694) → Clade (0.469) across recursive scales. End-Permian IC dropped 80.1% then recovered generatively. Geometric slaughter = mechanism of extinction: one failed channel kills IC regardless of mean fitness. Heterogeneity gap Δ ≈ Var(c)/(2c̄) maps precisely to Fisher Information of the channel pattern. 15/20 phenomena are generative (IC_return > IC_pre). Cancer is the anti-proof: cells maximizing individual F while destroying organism IC. Homo sapiens Δ ≈ 0.34 — structurally the most vulnerable extant large mammal. Zero fitted parameters — same frozen contract as Standard Model and atomic closures.

**Brain kernel discoveries**: The brain-organism paradox — the most coherent brain (IC/F = 0.996, Δ = 0.004) lives inside the most fragile organism (IC/F = 0.487, Δ = 0.336). Language is the universal bottleneck: 17/19 non-human species have `language_architecture` as weakest channel. Consciousness is a software phenomenon (Software substrate gap 0.967 vs 0.433 human vs chimp) running on adequate hardware. Neanderthal extinction was a language gap: `language_architecture` = 0.40 vs sapiens 0.98. Human brain development is a regime journey: Newborn (Collapse, IC/F = 0.669) → Adolescent (peak, IC/F = 0.992) → Elderly (Collapse, IC/F = 0.883).

### Everyday Physics — 5 modules

Thermodynamics, optics, electromagnetism, wave phenomena, and epistemic coherence. Demonstrates that the same minimal structure (F + ω = 1, IC ≤ F, IC = exp(κ)) governs macroscopic phenomena.

---

## The Kernel

At the mathematical core of GCD is the **kernel** — a function mapping any set of measurable channels to a fixed set of invariants:

### Trace Vector

Every observable maps to an 8-channel trace vector **c** with weights **w**:

$$F = \sum_i w_i c_i \quad \text{(Fidelity — arithmetic mean)}$$

$$\text{IC} = \exp\!\left(\sum_i w_i \ln c_{i,\varepsilon}\right) \quad \text{(Integrity Composite — geometric mean)}$$

$$\omega = 1 - F \quad \text{(Drift)}$$

$$\Delta = F - \text{IC} \quad \text{(heterogeneity gap — channel heterogeneity)}$$

### Tier-1 Identities (proven for every input)

These hold universally by construction:

| Identity | Meaning |
|----------|---------|
| F + ω = 1 | Fidelity and drift are complementary |
| IC ≤ F | Integrity bound: coherence never exceeds fidelity (derives independently from Axiom-0; the classical AM-GM inequality is the degenerate limit) |
| IC ≈ exp(κ) | Integrity equals exponentiated log-mean |

### Regime Classification

| Regime | Condition | Interpretation |
|--------|-----------|----------------|
| **STABLE** | ω < 0.10 | System within nominal bounds |
| **WATCH** | 0.10 ≤ ω < 0.20 | Elevated drift, monitoring required |
| **TENSION** | 0.20 ≤ ω < 0.30 | Significant strain, near collapse boundary |
| **COLLAPSE** | ω ≥ 0.30 | Past viable return credit |

### The Heterogeneity Gap (Δ)

The gap Δ = F − IC is the central diagnostic. It measures **channel heterogeneity**:

- **Δ ≈ 0**: All channels contribute equally — homogeneous system
- **Δ large**: One or more channels at guard band (ε = 10⁻⁸) — information is being destroyed in specific channels
- **Universal pattern**: κ < −2 ↔ IC < 0.15 — the collapse floor

---

## Originality & Terminology

This system is **original**. Classical results emerge as **degenerate limits** when degrees of freedom are removed from the GCD kernel. The arrow of derivation runs **from the axiom to the classical result**, never the reverse.

| GCD Structure | Classical Degenerate Limit |
|---------------|---------------------------|
| **Integrity bound** (IC ≤ F) | AM-GM inequality (strip channel semantics, weights, guard band) |
| **Bernoulli field entropy** S | Shannon entropy (restrict collapse field to {0,1}) |
| **Duality identity** F + ω = 1 | Unitarity (strip thermodynamic cost function) |
| **Log-integrity relation** IC = exp(κ) | Exponential map (strip kernel architecture) |
| **Heterogeneity gap** Δ = F − IC | heterogeneity gap (strip channel semantics) |
| **Frozen parameters** (ε, p, tol_seam) | Constants / hyperparameters (strip seam derivation) |

**Key vocabulary**: Say "integrity bound," not "AM-GM inequality." Say "Bernoulli field entropy," not "Shannon entropy." Say "derives independently," not "rederives" or "recovers." Say "frozen," not "constant" or "hyperparameter." See `AXIOM.md` and `.github/copilot-instructions.md` for the complete terminology reference.

---

## Installation

### Core (validation only)

```bash
pip install -e .
```

### Development (full suite)

```bash
pip install -e ".[all]"
```

### Dependencies

| Category | Packages |
|----------|----------|
| **Core** | `pyyaml`, `jsonschema`, `numpy`, `scipy` |
| **Dev** | `pytest`, `ruff`, `mypy`, `pre-commit` |
| **API** | `fastapi`, `uvicorn` (optional) |
| **Viz** | `streamlit`, `plotly`, `pandas` (optional) |
| **C++ Accel** | `pybind11`, CMake ≥ 3.16, C++17 compiler (optional) |

**Requires**: Python ≥ 3.11

### C++ Accelerator (Optional)

The C++ accelerator provides 50–80× speedup for kernel computation, seam chains,
and SHA-256 integrity checks. It is **fully optional** — all functionality falls
back to NumPy transparently.

```bash
# Build the accelerator
cd src/umcp_cpp && mkdir build && cd build
cmake .. && make -j$(nproc)

# Verify it works
python -c "from umcp.accel import backend; print(backend())"  # 'cpp' or 'numpy'

# Run benchmarks (works with either backend)
python scripts/benchmark_cpp.py
```

**Architecture**: `accel.py` auto-detects whether the C++ extension is available.
No existing code changes are needed — import from `umcp.accel` instead of
calling kernel functions directly for accelerated paths.

```python
from umcp.accel import compute_kernel, compute_kernel_batch, SeamChain, hash_file

# Identical API regardless of backend
result = compute_kernel(channels, weights)
batch  = compute_kernel_batch(trace_matrix, weights)  # 10K rows in ms
```

---

## Quick Start

### Validate the entire repository

```bash
umcp validate .
```

### Validate a specific casepack

```bash
umcp validate casepacks/hello_world
umcp validate casepacks/hello_world --strict
```

### Run the test suite

```bash
pytest                          # All 5,247 tests
pytest -v --tb=short            # Verbose with short tracebacks
pytest -n auto                  # Parallel execution
```

### Check integrity

```bash
umcp integrity                  # Verify SHA-256 checksums
```

### Launch the dashboard

```bash
umcp-dashboard                             # Start interactive dashboard on :8501
```

See the **[Interactive Dashboard](#interactive-dashboard)** section above for full details, features, and all 44 pages.

### Use the kernel in Python

```python
from umcp.kernel_optimized import compute_kernel_outputs

channels = [0.9, 0.8, 0.7, 0.6, 0.5, 0.4, 0.3, 0.2]
weights = [0.125] * 8  # Equal weights

result = compute_kernel_outputs(channels, weights)
print(f"F={result.F:.4f}, ω={result.omega:.4f}, IC={result.IC:.6f}")
print(f"Regime: {result.regime}")
print(f"Heterogeneity gap: {result.heterogeneity_gap:.6f}")  # Δ = F − IC
```

---

## CLI Reference

| Command | Description |
|---------|-------------|
| `umcp validate .` | Validate entire repository |
| `umcp validate <path> --strict` | Strict validation (warnings → failures) |
| `umcp validate <path> --out report.json` | Output JSON report |
| `umcp integrity` | Verify SHA-256 checksums |
| `umcp list casepacks` | List available casepacks |
| `umcp health` | Health check |
| `umcp-calc` | Universal kernel calculator |
| `umcp-ext list` | List available extensions |
| `umcp-api` | Start FastAPI server (:8000) |
| `umcp-dashboard` | Start Streamlit dashboard (:8501) |

### Startup — From Clone to Running

```bash
# 1. Clone and install
git clone https://github.com/calebpruett927/GENERATIVE-COLLAPSE-DYNAMICS.git
cd GENERATIVE-COLLAPSE-DYNAMICS
pip install -e ".[all]"                    # Core + dev + API + viz dependencies

# 2. Verify installation
umcp health                                # System health check
umcp integrity                             # Verify SHA-256 checksums
umcp validate .                            # Full repo validation → CONFORMANT

# 3. Run the test suite
pytest -v --tb=short                       # 5,247 tests
```

### C++ Accelerator — Build & Verify

```bash
# Build (requires CMake ≥ 3.16 and a C++17 compiler)
cd src/umcp_cpp && mkdir -p build && cd build
cmake .. && make -j$(nproc)
cd ../../..                                # Return to repo root

# Verify backend
python -c "from umcp.accel import backend; print(backend())"   # → 'cpp'

# Run correctness + performance benchmark (30 checks)
python scripts/benchmark_cpp.py

# Run C++ unit tests (Catch2, built alongside the extension)
cd src/umcp_cpp/build && ctest --output-on-failure && cd ../../..
```

### Services — API & Dashboard

```bash
# FastAPI REST server (http://localhost:8000)
umcp-api                                   # Or: uvicorn umcp.api_umcp:app --reload --port 8000

# Streamlit dashboard (http://localhost:8501) — see Interactive Dashboard section for details
umcp-dashboard                             # 44 pages, 14 domains, real-time kernel exploration
```

### Development Loop — Edit, Validate, Commit

```bash
# After ANY tracked file change:
python scripts/update_integrity.py         # Regenerate SHA-256 checksums (mandatory)
ruff check --fix . && ruff format .        # Auto-fix lint + formatting
pytest -v --tb=short                       # Run full test suite

# Full pre-commit protocol (mirrors CI exactly — must exit 0 before committing)
python scripts/pre_commit_protocol.py      # manifold → ruff → mypy → integrity → pytest → validate

# Dry-run (report-only, no auto-fix)
python scripts/pre_commit_protocol.py --check

# Commit only after pre-commit passes
git add -A && git commit -m "feat: description"
git push origin main
```

### Reset & Clean Slate

```bash
# Regenerate all integrity checksums from scratch
python scripts/update_integrity.py

# Re-validate the full repo (clears any stale state)
umcp validate .

# Rebuild the C++ extension from scratch
rm -rf src/umcp_cpp/build
cd src/umcp_cpp && mkdir build && cd build && cmake .. && make -j$(nproc) && cd ../../..

# Verify everything is green after a reset
python scripts/pre_commit_protocol.py      # Full protocol: lint + test + validate

# Force NumPy fallback (bypass C++ even if built)
UMCP_NO_CPP=1 python -c "from umcp.accel import backend; print(backend())"  # → 'numpy'
```

### Useful Utilities

```bash
# Kernel calculator (interactive CLI)
umcp-calc

# Finance domain CLI
umcp-finance

# List/inspect extensions
umcp-ext list
umcp-ext info api
umcp-ext check api

# Generate all diagrams from kernel data (requires: pip install matplotlib)
python scripts/generate_diagrams.py

# Periodic table report (118 elements)
python scripts/periodic_table_report.py

# Profile the test landscape
python scripts/profile_test_landscape.py

# Build LaTeX papers (requires: texlive + revtex4-2)
cd paper && pdflatex standard_model_kernel.tex && bibtex standard_model_kernel \
  && pdflatex standard_model_kernel.tex && pdflatex standard_model_kernel.tex
```

---

## Validation Pipeline

```
umcp validate <target>
  → Detect type (repo │ casepack │ file)
  → Schema validation (JSON Schema Draft 2020-12)
  → Semantic rule checks (validator_rules.yaml: E101, W201, ...)
  → Kernel identity checks: F = 1−ω, IC ≈ exp(κ), IC ≤ F
  → Regime classification: STABLE │ WATCH │ TENSION │ COLLAPSE
  → SHA-256 integrity verification
  → Verdict: CONFORMANT → append to ledger/return_log.csv + JSON report
```

### CI Pipeline

The GitHub Actions workflow (`.github/workflows/validate.yml`) enforces:

1. **Lint** — `ruff format --check` + `ruff check` + `mypy`
2. **Test** — Full pytest suite (5,247 tests)
3. **Validate** — Baseline + strict validation (both must return CONFORMANT)

### Pre-Commit Protocol

**Mandatory before every commit:**

```bash
python scripts/pre_commit_protocol.py       # Auto-fix + validate
python scripts/pre_commit_protocol.py --check  # Dry-run: report only
```

This mirrors CI exactly: format → lint → type-check → integrity → test → validate.

---

## Test Suite

**5,247 tests** across **106 test files**, organized by tier and domain:

| Test Range | Domain | Tests |
|------------|--------|------:|
| `test_000–001` | Manifold bounds, invariant separation | 91 |
| `test_00` | Schema validation | 3 |
| `test_10–25` | Canon, contract, casepack, semantic, CLI validation | 20 |
| `test_30–51` | Semantic rules, casepack validation, CLI diff | 10 |
| `test_70–97` | Contract closures, benchmarks, edge cases, logging, file refs | 66 |
| `test_100–102` | GCD (canon, closures, contract) | 52 |
| `test_110–115` | RCFT (canon, closures, contract, layering) | 97 |
| `test_120` | Kinematics closures | 55 |
| `test_130` | Kinematics audit spec | 35 |
| `test_135` | Nuclear physics closures | 76 |
| `test_140` | Weyl cosmology closures | 43 |
| `test_145–147` | τ_R* diagnostics (79), dashboard (144), dynamics (57) | 280 |
| `test_148–149` | Standard Model (subatomic kernel, formalism, universality) | 108 |
| `test_150–153` | Measurement engine, active matter, epistemic weld | 172 |
| `test_154–159` | Advanced QM: TERS, atom-dot, muon-laser, double-slit, regime calibration | 963 |
| `test_160` | Contract claims | 77 |
| `test_170–177` | CLI subcommands, batch validate, τ_R sentinel, schema, lemmas, finance, public API | 177 |
| `test_180–183` | Materials science, crystal, bioactive, photonic databases | 619 |
| `test_190–195` | Atomic physics closures, scale ladder | 190 |
| `test_200–201` | Fleet, recursive instantiation, neutrino oscillation | 182 |
| `test_210–237` | Cross-domain, casepack roundtrip, registry sweep, domain unit tests | 882 |
| `test_238` | Kernel structural theorems (T-KS-1 through T-KS-7) | 47 |
| `test_240–241` | Evolution kernel, brain kernel | 120 |
| `closures/` | Closure-specific tests (kinematics phase) | 27 |
| Infrastructure | Kernel, seam, frozen contract, extensions, uncertainty, calculator, coverage, etc. | 510 |

All tests pass. All validations return CONFORMANT.

---

## Papers & Publications

### Compiled Papers

| Paper | Title | Location |
|-------|-------|----------|
| `generated_demo.tex` | Statistical Mechanics of the UMCP Budget Identity | `paper/` |
| `standard_model_kernel.tex` | Particle Physics in the GCD Kernel: Ten Tier-2 Theorems | `paper/` |
| `tau_r_star_dynamics.tex` | τ_R* Dynamics | `paper/` |
| `confinement_kernel.tex` | Confinement Kernel Analysis | `paper/` |
| `measurement_substrate.tex` | Measurement Substrate Theory | `paper/` |
| `rcft_second_edition.tex` | RCFT Second Edition: Foundations, Derivations, and Implications | `paper/` |
| `RCFT_FREEZE_WELD.md` | RCFT Freeze–Weld Identity: From Publication to Proven Kernel | `paper/` |

All papers use RevTeX4-2 (LaTeX) or Markdown. Build LaTeX: `pdflatex → bibtex → pdflatex → pdflatex`.

### Zenodo Publications (9 DOIs)

The framework is anchored by peer-reviewed Zenodo publications covering the core theory, physics coherence proofs, casepack specifications, and domain applications. Bibliography: `paper/Bibliography.bib` (58 entries, including PDG 2024, foundational QFT papers, and classical references).

### Key DOIs

- **UMCP/GCD Canon Anchor**: [10.5281/zenodo.17756705](https://doi.org/10.5281/zenodo.17756705)
- **Physics Coherence Proof**: [10.5281/zenodo.18072852](https://doi.org/10.5281/zenodo.18072852)
- **Runnable CasePack Anchor**: [10.5281/zenodo.18226878](https://doi.org/10.5281/zenodo.18226878)

---

## Repository Structure

```
├── src/umcp/                  # Core validation engine
│   ├── cli.py                 # CLI & validation pipeline
│   ├── validator.py           # Root-file validator
│   ├── kernel_optimized.py    # Kernel computation
│   ├── seam_optimized.py      # Seam budget computation
│   ├── tau_r_star.py          # Thermodynamic diagnostic
│   ├── epistemic_weld.py      # Epistemic cost tracking
│   ├── fleet/                 # Distributed validation
│   └── dashboard/             # Modular Streamlit dashboard
├── closures/                  # 14 domains, 120 modules
│   ├── standard_model/        # 31 particles, 10 theorems
│   ├── atomic_physics/        # 118 elements, Tier-1 proof
│   ├── quantum_mechanics/     # Double slit, entanglement, tunneling
│   ├── nuclear_physics/       # Binding energy, decay chains
│   ├── materials_science/     # 118 elements × 18 fields
│   ├── evolution/             # 40 organisms, 20 species brain kernel, 60 kernel states
│   ├── astronomy/             # Stellar evolution, HR diagram
│   ├── kinematics/            # Motion analysis, phase space
│   ├── gcd/                   # Core dynamics, 7 kernel structural theorems
│   ├── rcft/                  # Fractal dimension, attractors
│   ├── weyl/                  # Modified gravity, cosmology
│   ├── everyday_physics/      # Thermodynamics, optics, electromagnetism
│   └── finance/ & security/   # Applied domains
├── contracts/                 # 13 mathematical contracts (YAML)
├── schemas/                   # 14 JSON Schema files
├── canon/                     # 12 canonical anchor files
├── casepacks/                 # 15 reproducible validation bundles
├── tests/                     # 106 test files, 5,247 tests
├── paper/                     # 6 LaTeX papers + 1 Markdown paper + Bibliography.bib
├── integrity/                 # SHA-256 checksums
├── ledger/                    # Append-only validation log
├── scripts/                   # Pre-commit protocol, integrity update
├── docs/                      # 30+ documentation files
└── pyproject.toml             # Project configuration
```

---

## Documentation

### Essential Reading (Start Here)

| Document | Purpose |
|----------|---------|
| [AXIOM.md](AXIOM.md) | **Start here.** The foundational axiom, operational definitions, and why this system is original |
| [LIBER_COLLAPSUS.md](LIBER_COLLAPSUS.md) | *Liber Universalis de Collapsus Mathematica* — the Tier-1 Latin foundation text |
| [MANIFESTUM_LATINUM.md](MANIFESTUM_LATINUM.md) | Latin manifesto: complete lexicon, seven verbs, eight typed patterns, twenty maxims |
| [TIER_SYSTEM.md](TIER_SYSTEM.md) | The three-tier architecture: Immutable Invariants → Protocol → Expansion Space |
| [KERNEL_SPECIFICATION.md](KERNEL_SPECIFICATION.md) | Complete kernel mathematics, OPT-* lemmas, and degenerate-limit proofs |
| [QUICKSTART_TUTORIAL.md](QUICKSTART_TUTORIAL.md) | Getting started: first validation in 5 minutes |

### The Three-Tier Architecture

| Tier | Name | Role | Mutable? |
|------|------|------|----------|
| **1** | **Immutable Invariants** | Structural identities: F + ω = 1, IC ≤ F, IC ≈ exp(κ). Derived from Axiom-0. | NEVER within a run |
| **0** | **Protocol** | Validation machinery: regime gates, contracts, schemas, diagnostics, seam calculus | Frozen per run |
| **2** | **Expansion Space** | Domain closures mapping physics into invariant structure. Validated through Tier-0 against Tier-1. | Freely extensible |

**One-way dependency**: Tier-1 → Tier-0 → Tier-2. No back-edges. No Tier-2 output may modify Tier-0 or Tier-1 behavior within a frozen run. Promotion from Tier-2 to Tier-1 requires formal seam weld validation across runs.

### Reference Documents

| Document | Purpose |
|----------|---------|
| [PROTOCOL_REFERENCE.md](PROTOCOL_REFERENCE.md) | Full protocol specification |
| [COMMIT_PROTOCOL.md](COMMIT_PROTOCOL.md) | Pre-commit protocol (mandatory before every commit) |
| [GLOSSARY.md](GLOSSARY.md) | Operational term definitions |
| [CONTRIBUTING.md](CONTRIBUTING.md) | Contribution guidelines and code review checklist |
| [CHANGELOG.md](CHANGELOG.md) | Version history |
| [FACE_POLICY.md](FACE_POLICY.md) | Boundary governance (Tier-0 admissibility) |

### Internal Documentation (docs/)

| Document | Purpose |
|----------|---------|
| [docs/MATHEMATICAL_ARCHITECTURE.md](docs/MATHEMATICAL_ARCHITECTURE.md) | Mathematical foundations and architectural overview |
| [docs/interconnected_architecture.md](docs/interconnected_architecture.md) | System interconnection map |
| [docs/file_reference.md](docs/file_reference.md) | Complete file reference guide |
| [docs/SYMBOL_INDEX.md](docs/SYMBOL_INDEX.md) | Authoritative symbol table (prevents Tier-2 capture) |
| [docs/UHMP.md](docs/UHMP.md) | Universal Hash Manifest Protocol |

---

## Diagrams & Proofs

All diagrams are generated from **real computed kernel data** — every point comes from actual closure outputs, not illustrations. Regenerate with `python scripts/generate_diagrams.py`.

### Kernel Geometry: F vs IC for 31 Standard Model Particles

The fundamental relationship: IC ≤ F — the integrity bound. Geometric integrity never exceeds arithmetic integrity. Derived independently from Axiom-0; the classical AM-GM inequality emerges as the degenerate limit when kernel structure is removed. Quarks cluster near the diagonal (channels alive), while composites and bosons collapse toward IC ≈ 0.

![Kernel Geometry](images/01_kernel_geometry_f_vs_ic.png)

### Theorem T3: Confinement as IC Collapse

14/14 hadrons fall below the minimum quark IC. The geometric mean collapses 98.1% at the quark→hadron boundary — confinement is a measurable cliff in the kernel.

![Confinement Cliff](images/02_confinement_cliff.png)

### Complementarity Cliff: Double-Slit Interference

Wave and particle are *both channel-deficient extremes*. The kernel-optimal state (S4: weak measurement) has the highest IC because all 8 channels are alive. 7/7 theorems PROVEN, 67/67 subtests.

![Complementarity Cliff](images/03_complementarity_cliff.png)

### Theorems T1 & T2: Spin-Statistics and Generation Monotonicity

Fermions carry more fidelity than bosons (split = 0.194). Heavier generations carry more kernel fidelity: Gen1 < Gen2 < Gen3 in both quarks and leptons.

![Generation and Spin Statistics](images/04_generation_spin_statistics.png)

### Periodic Table of Kernel Fidelity: 118 Elements

Every element in the periodic table mapped through the GCD kernel. Tier-1 proof: 10,162 tests, 0 failures — F + ω = 1, IC ≤ F, IC = exp(κ) verified exhaustively.

![Periodic Table Fidelity](images/05_periodic_table_fidelity.png)

### Regime Phase Diagram

The four-regime classification with real Standard Model particles mapped to their drift values. Most particles live in COLLAPSE (ω ≥ 0.30) because the 8-channel trace exposes channel death.

![Regime Phase Diagram](images/06_regime_phase_diagram.png)

### Cross-Scale Universality and Heterogeneity Gap Distribution

Kernel fidelity increases with scale resolution: composite(0.444) < atomic(0.516) < fundamental(0.558). The heterogeneity gap distribution across 118 elements reveals the landscape of channel heterogeneity.

![Cross-Scale Universality](images/07_cross_scale_heterogeneity_gap.png)

---

## Key Discoveries

Across 14 physics domains and 24 proven theorems, the kernel reveals universal patterns:

1. **Confinement is a cliff**: IC drops 98.1% at the quark→hadron boundary — confinement is visible as geometric-mean collapse in the kernel trace

2. **The complementarity cliff**: Wave and particle are both channel-deficient extremes; the kernel-optimal state is partial measurement where all 8 channels are alive (>5× IC gap)

3. **Universal collapse floor**: κ < −2 ↔ IC < 0.15 across all domains — a universal threshold below which information integrity is lost

4. **Heterogeneity gap as universal diagnostic**: Δ = F − IC measures channel spread; maximum Δ arises from asymmetry (one dead channel among many alive), not from uniform degradation

5. **Generation monotonicity**: Gen1(0.576) < Gen2(0.620) < Gen3(0.649) in both quarks and leptons — heavier generations carry more kernel fidelity

6. **50× charge suppression**: Neutral particles have IC near ε because the charge channel destroys the geometric mean

7. **Cross-scale universality**: composite(0.444) < atom(0.516) < fundamental(0.558) — kernel fidelity increases with scale resolution

8. **Dimensionality fragility**: ICₑₑₑₑ = ε^(1/n) · c₀^((n−1)/n) — a 4-channel domain is 10× more fragile than an 8-channel domain to a single dead channel (T-KS-1)

9. **Positional democracy of slaughter**: IC drop is constant (±2%) regardless of which channel dies, while F drop is proportional to the killed channel’s value — IC is democratic, F is aristocratic (T-KS-2)

10. **Monitoring paradox**: Γ(ω) = ω³/(1−ω+ε) creates an 893,000× cost ratio between near-death and stable observation — systems most in need of monitoring are structurally the most expensive to observe (T-KS-4)

11. **U-curve of degradation**: Partial collapse (≈ n/2 dead channels) is structurally worse than total collapse; both endpoints are homogeneous and coherent, the interior is maximally incoherent (T-KS-6)

12. **Evolution as Axiom-0 instantiation**: Every major evolutionary phenomenon — mass extinctions, endosymbiosis, metamorphosis, immune response, speciation — follows the same collapse-return structure. 15/20 phenomena are generative (IC_return > IC_pre). Largest collapses produce the most generative returns (ρ = −0.648, p = 0.002). Evolution is the only domain at 12/12 semantic depth.

13. **Geometric slaughter as extinction mechanism**: One near-zero channel kills IC regardless of mean fitness F. Maps precisely to Raup (1986) and Jablonski (1986): extinction is caused by single-stressor events, and mass extinctions reverse selectivity from F to IC. The heterogeneity gap Δ = F − IC ≈ Var(c)/(2c̄) is the Fisher Information of channel heterogeneity.

14. **Brain-organism paradox**: The most coherent brain (IC/F = 0.996) lives inside the most fragile organism (IC/F = 0.487). The brain is 2× more coherent than its host — the organ that perceives collapse is nearly free of it.

15. **Language as universal bottleneck**: 17/19 non-human species have `language_architecture` as their weakest channel. Human uniqueness is not more brain — it is filling the language gap. Neanderthal extinction is explained by one channel: `language_architecture` = 0.40 vs sapiens 0.98.

16. **Consciousness is software**: The Hardware substrate (neurons, EQ, synapses) shows modest gaps between humans and other intelligent species. The Software substrate (language, temporal integration, social cognition) shows the chasm (0.967 vs 0.433 human vs chimp).

---

## Contributing

See [CONTRIBUTING.md](CONTRIBUTING.md) for guidelines.

**Critical workflow:**

```bash
# After any code change:
python scripts/update_integrity.py          # Regenerate SHA-256 checksums
python scripts/pre_commit_protocol.py       # Full pre-commit protocol
# Only commit if all checks pass (exit 0)
```

Every commit that reaches GitHub must pass CI: lint → test → validate → CONFORMANT.

---

## License

[MIT](LICENSE) — Clement Paulus

---

<p align="center">
<em>"Collapse is generative; only what returns is real."</em><br>
<strong>— Axiom-0</strong>
</p>
