The Continuum Engine is a universal, reversible, identity‑preserving transformation framework that establishes a continuity layer beneath all computational systems. It formalises how stateful systems evolve without violating their axioms, invariants, or identity anchors, providing a mathematically grounded structure for lawful, reversible change. Where traditional engines (state machines, reducers, CRDTs, DOM engines, physics engines, blockchain VMs, simulation engines) operate within a domain, the Continuum Engine operates beneath them — defining the rules by which any domain can evolve coherently. It guarantees: Identity continuity across all transformations Reversibility through formally constructed inverse operations Axiom enforcement before and after every state transition Invariant preservation as a structural constraint Law‑driven evolution that cannot violate system physics This work introduces the Continuum Equation, a unifying expression that captures reversible, axiom‑checked, identity‑preserving evolution. It provides a foundation for building systems that behave like computational physics: lawful, reversible, and structurally continuous. The manifesto and accompanying materials present the theory, architecture, equations, pseudocode, and conceptual lineage of the Continuum Engine, along with historical context tracing its emergence from HTML‑physics experiments and reversible‑system research. This release is intended for researchers in computer science, formal methods, distributed systems, simulation theory, computational physics, and anyone exploring the foundations of reversible or axiom‑driven computation. Keywords: Continuum Engine; Reversible Computation; Identity Continuity; Axiom‑Driven Systems; Invariant Preservation; Transformation Laws; Formal Methods; State Transition Theory; Computational Physics; System Dynamics; Meta‑Engines; Universal Engines; Distributed Systems; CRDT Theory; Simulation Theory; Blockchain VM Theory; DOM Physics; Computational Identity; Axiomatic Computation; Invariant‑Based Design; Reversible Architectures; Lawful Evolution; Continuity Layer Theory; Computational Ontology; System Integrity; Deterministic Systems; Transformation Frameworks; Foundational Computer Science; Generalised State Machines; Computational Continuity; System Evolution Theory; Mathematical Systems; Equation‑Driven Engines; Continuum Equation; Computational Foundations; High‑Integrity Systems
Matthew Arthur Carlo (Tue,) studied this question.