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| import hashlib | |
| class MultiModalFibrator: | |
| """ | |
| Law VIII: Multi-Modal Fibration Invariant | |
| Solutions discovered in one domain are topologically equivalent and transferable | |
| to any other domain sharing the same m and k. | |
| """ | |
| def __init__(self, m, k): | |
| self.m = m | |
| self.k = k | |
| def map_to_manifold(self, domain_data): | |
| """Map arbitrary domain data to a manifold coordinate.""" | |
| h = hashlib.sha256(str(domain_data).encode()).digest() | |
| coords = [] | |
| for i in range(self.k - 1): | |
| coords.append(h[i] % self.m) | |
| # Closure Lemma (Law III) | |
| last_coord = (0 - sum(coords)) % self.m | |
| coords.append(last_coord) | |
| return tuple(coords) | |
| def verify_invariance(self, data_a, data_b): | |
| """Verify that two different domains share the same topological fiber structure.""" | |
| print(f"\n--- Law VIII: Multi-Modal Invariance ---") | |
| coord_a = self.map_to_manifold(data_a) | |
| coord_b = self.map_to_manifold(data_b) | |
| # Check if both belong to Fiber 0 | |
| fiber_a = sum(coord_a) % self.m | |
| fiber_b = sum(coord_b) % self.m | |
| print(f"Domain A ('{data_a}') -> {coord_a} (Fiber {fiber_a})") | |
| print(f"Domain B ('{data_b}') -> {coord_b} (Fiber {fiber_b})") | |
| is_invariant = (fiber_a == fiber_b == 0) | |
| print(f"Topological Invariance Secured? {is_invariant}") | |
| return is_invariant | |
| if __name__ == "__main__": | |
| fibrator = MultiModalFibrator(m=256, k=3) | |
| # Domain A: Language (Token "Electricity") | |
| # Domain B: Vision (Pixel RGB (255, 255, 0)) | |
| fibrator.verify_invariance("Electricity", (255, 255, 0)) | |
| # Domain C: Math (x^2 + y^2 = r^2) | |
| # Domain D: Hardware (CPU 45%) | |
| fibrator.verify_invariance("x^2 + y^2 = r^2", "CPU 45%") | |