axon-lang 0.15.0

A programming language for AI cognition — compiles to prompts, not machine code.

AXON v0.15.0
A programming language whose primitives are cognitive primitives of AI.

persona · intent · flow · reason · anchor · refine · memory · tool · probe · weave · validate · context
know · believe · speculate · doubt · par · hibernate
dataspace · ingest · focus · associate · aggregate · explore
deliberate · consensus · forge · agent · shield
stream · effects · @contract_tool · @csp_tool
pix · navigate · drill · trail

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What is AXON?

AXON is a compiled language that targets LLMs instead of CPUs. It has a formal EBNF grammar, a lexer, parser, AST, intermediate representation, multiple compiler backends (Anthropic, OpenAI, Gemini, Ollama), and a runtime with semantic type checking, retry engines, and execution tracing.

It is not a Python library, a LangChain wrapper, or a YAML DSL.

persona LegalExpert {
    domain: ["contract law", "IP", "corporate"]
    tone: precise
    confidence_threshold: 0.85
    refuse_if: [speculation, unverifiable_claim]
}

anchor NoHallucination {
    require: source_citation
    confidence_floor: 0.75
    unknown_response: "Insufficient information"
}

flow AnalyzeContract(doc: Document) -> StructuredReport {
    step Extract {
        probe doc for [parties, obligations, dates, penalties]
        output: EntityMap
    }
    step Assess {
        reason {
            chain_of_thought: enabled
            given: Extract.output
            ask: "Are there ambiguous or risky clauses?"
            depth: 3
        }
        output: RiskAnalysis
    }
    step Check {
        validate Assess.output against: ContractSchema
        if confidence < 0.8 -> refine(max_attempts: 2)
        output: ValidatedAnalysis
    }
    step Report {
        weave [Extract.output, Check.output]
        format: StructuredReport
        include: [summary, risks, recommendations]
    }
}

---

Paradigm Shifts

AXON v0.7 introduces three compiler-level paradigm shifts that elevate the language from prompt compilation to a Cognitive Operating System.

I. Formal Model — Epistemic Constraint Calculus

Each program P in AXON operates over a typed epistemic lattice (T, ≤) where the compiler enforces semantic constraints at compile time. The paradigm shifts extend this with three new formal mechanisms:

Epistemic Scoping Function. Given an epistemic mode m ∈ {know, believe, speculate, doubt}, the compiler applies a constraint function C(m) that maps to a tuple of LLM parameters and auto-injected anchors:

C : Mode → (τ, p, A)
where
  τ ∈ [0,1]    — temperature override
  p ∈ [0,1]    — nucleus sampling (top_p)
  A ⊆ Anchors  — auto-injected constraint set

C(know)      = (0.1, 0.3, {RequiresCitation, NoHallucination})
C(believe)   = (0.3, 0.5, {NoHallucination})
C(speculate) = (0.9, 0.95, ∅)
C(doubt)     = (0.2, 0.4, {RequiresCitation, SyllogismChecker})

This is calculated at compile time — the IR carries the resolved constraint set, so the executor applies them as zero-cost runtime overrides.

Parallel DAG Scheduling. A par block B = {b₁, ..., bₙ} where n ≥ 2 is verified at compile time to have no data dependencies between branches:

∀ bᵢ, bⱼ ∈ B, i ≠ j : deps(bᵢ) ∩ outputs(bⱼ) = ∅

At runtime, branches execute via asyncio.gather, achieving O(max(tᵢ)) latency instead of O(Σtᵢ) for sequential chains.

CPS Continuation Points. A hibernate node generates a deterministic continuation ID via SHA-256(flow_name ∥ event_name ∥ source_position). The executor serializes the full ExecutionState (call stack, step results, context variables) and halts. On resume(continuation_id), the state is deserialized and execution continues from the exact IR node — implementing Continuation-Passing Style at the language level.

II. Design Philosophy — Programming Epistemic States

Traditional LLM frameworks treat every model call identically — the same temperature, the same constraints, the same trust level. This is the equivalent of asking a human to treat brainstorming and sworn testimony with the same cognitive rigor.

AXON rejects this flat model. Epistemic Directives make the confidence state of the AI a first-class construct in the language:

know {
    flow ExtractFacts(doc: Document) -> CitedFact {
        step Verify { ask: "Extract only verifiable facts" output: CitedFact }
    }
}

speculate {
    flow Brainstorm(topic: String) -> Opinion {
        step Imagine { ask: "What could be possible?" output: Opinion }
    }
}

The compiler does not merely label these blocks — it structurally transforms them. A know block injects citation anchors and drops temperature to 0.1, making hallucination a compile-time constraint violation. A speculate block removes all constraints and raises temperature to 0.9, liberating the model.

Parallel Cognitive Dispatch mirrors how human organizations work: delegate independent analyses to specialists concurrently, then synthesize.

Dynamic State Yielding transforms agents from expensive while True loops into event-driven processes that can sleep for days, weeks, or months — then resume with full context. The language handles the serialization; the developer writes hibernate until "event_name" and moves on.

III. Real-World Use Cases

Use Case 1: Legal Document Analysis Pipeline

A law firm needs to analyze contracts with maximum factual rigor, while also exploring creative legal strategies. AXON separates these cognitive modes at the language level:

know {
    flow ExtractClauses(contract: Document) -> ClauseMap {
        step Parse { probe contract for [parties, obligations, penalties] output: ClauseMap }
    }
}

flow AnalyzeRisk(contract: Document) -> StructuredReport {
    par {
        step Financial { ask: "Analyze financial exposure" output: RiskScore }
        step Regulatory { ask: "Check regulatory compliance" output: ComplianceReport }
        step Precedent { ask: "Find relevant case law" output: CaseList }
    }
    weave [Financial, Regulatory, Precedent] into Report { format: StructuredReport }
}

speculate {
    flow ExploreStrategies(report: StructuredReport) -> Opinion {
        step Creative { ask: "What unconventional strategies could mitigate these risks?" output: Opinion }
    }
}

• know guarantees citation-backed extraction (temperature 0.1)
• par runs 3 analyses concurrently, reducing latency by ~3x
• speculate explicitly relaxes constraints for creative strategy exploration

Use Case 2: Multi-Agent Research & Intelligence System

A BI platform deploys autonomous research agents that run for weeks, hibernating between data collection phases:

flow MarketIntelligence(sector: String) -> Report {
    know {
        flow GatherData(sector: String) -> DataSet {
            step Collect { ask: "Gather verified market data" output: DataSet }
        }
    }

    par {
        step Trends { ask: "Identify emerging trends" output: TrendAnalysis }
        step Competitors { ask: "Map competitor landscape" output: CompetitorMap }
    }

    hibernate until "quarterly_data_available"

    doubt {
        flow ValidateFindings(data: DataSet) -> ValidatedReport {
            step CrossCheck { ask: "Challenge every assumption with evidence" output: ValidatedReport }
        }
    }

    weave [Trends, Competitors] into Final { format: Report }
}

• Agent hibernates after initial analysis, costing $0 while waiting
• Resumes automatically when quarterly data arrives (webhook/cron)
• doubt mode forces adversarial validation with syllogism checking

Use Case 3: Autonomous Customer Support with Escalation

A SaaS platform handles support tickets with different confidence requirements and automatic escalation via hibernate:

persona SupportAgent {
    domain: ["product knowledge", "troubleshooting"]
    tone: empathetic
    confidence_threshold: 0.8
}

flow HandleTicket(ticket: String) -> Resolution {
    know {
        flow DiagnoseIssue(ticket: String) -> Diagnosis {
            step Classify { ask: "Classify the issue type and severity" output: Diagnosis }
        }
    }

    believe {
        flow SuggestSolution(diagnosis: Diagnosis) -> Solution {
            step Solve { ask: "Propose a solution based on known patterns" output: Solution }
        }
    }

    if confidence < 0.7 -> hibernate until "human_review_complete"

    step Respond { ask: "Draft customer response" output: Resolution }
}

• know classifies with strict accuracy (no guessing on severity)
• believe suggests solutions with moderate confidence
• Low confidence triggers hibernate — agent sleeps until a human reviews
• Zero compute cost during human review; resumes with full context

IV. Directed Creative Synthesis — the forge Primitive

AXON v0.10 introduces a sixth paradigm shift: mathematical formalization of the creative process inside LLMs.

The industry suffers from a structural limitation: LLMs can interpolate, but they struggle to create. forge addresses this by implementing a compiler-level Poincaré pipeline — the same 4-phase process mathematicians and scientists use when producing genuinely novel work.

Poincaré-Hadamard Creative Pipeline. A forge block orchestrates four sequential phases, each mapped to a distinct LLM configuration:

forge(seed, mode, novelty, depth, branches) → result

Phase 1: PREPARATION   — Expand the seed via context probing
Phase 2: INCUBATION    — Speculative exploration (depth iterations)
Phase 3: ILLUMINATION  — Best-of-N consensus crystallization
Phase 4: VERIFICATION  — Adversarial doubt + anchor validation

Boden Creativity Taxonomy. The mode parameter maps Margaret Boden's three creativity types to concrete LLM parameter overrides at compile time:

B : Mode → (τ, freedom, rule_flexibility)

B(combinatory)      = (0.9,  0.8, 0.3)   — novel recombination of known ideas
B(exploratory)      = (0.7,  0.6, 0.5)   — structured navigation of possibility spaces
B(transformational) = (1.2,  1.0, 0.9)   — rule-breaking synthesis, new paradigms

Novelty Operator K(x|K). The novelty parameter (0.0–1.0) controls the Kolmogorov-inspired tradeoff between utility and surprise. It blends into the effective temperature used during incubation:

τ_eff = τ_base × (0.5 + 0.5 × novelty)

novelty = 0.0 → τ_eff = 0.5 × τ_base  (conservative, high utility)
novelty = 1.0 → τ_eff = 1.0 × τ_base  (maximum divergence, high surprise)

Usage example — Directed Creative Synthesis:

anchor GoldenRatio {
    require: aesthetic_harmony
    confidence_floor: 0.70
}

flow CreateVisualConcept(brief: String) -> Visual {
    forge Artwork(seed: "aurora borealis over ancient ruins") -> Visual {
        mode:        transformational
        novelty:     0.85
        constraints: GoldenRatio
        depth:       4
        branches:    7
    }
}

run CreateVisualConcept("Create a visual concept for a film poster")

What the compiler does:

1. Preparation — expands "aurora borealis over ancient ruins" into a rich conceptual foundation via context probing
2. Incubation — runs 4 iterations of speculative exploration at τ_eff = 1.2 × 0.925 = 1.11, pushing beyond obvious associations
3. Illumination — launches 7 parallel branches, each crystallizing the incubated ideas, then selects the most coherent output (Best-of-N)
4. Verification — applies adversarial doubt against the GoldenRatio anchor, validating that the result is genuinely novel (K(x|K) > 0) and aesthetically balanced

This is not a prompt template. The forge primitive compiles to structured IR metadata that the runtime executes as an orchestrated pipeline — the same precision AXON applies to every other cognitive primitive.

V. Autonomous Goal-Seeking — the agent Primitive

AXON v0.12 introduces a seventh paradigm shift: compiler-verified autonomous agents grounded in the Belief-Desire-Intention (BDI) architecture, epistemic logic, and coinductive semantics.

Every existing LLM framework implements agents as Python classes with ad-hoc while-loops, hidden state machines, and zero formal guarantees. LangChain's AgentExecutor is a runtime artifact — it cannot be statically analyzed, type- checked, or budget-bounded at compile time. AXON's agent primitive makes autonomous goal-seeking a first-class compiled construct with mathematical semantics.

BDI Coinductive Semantics. An agent declaration compiles to a coinductive BDI system — a state machine whose behavior is defined by an infinite observation/transition pair over the epistemic lattice:

Agent ≅ ν X. (S × (Action → X))

where
  S        = Beliefs × Goals × Plans    — cognitive state
  Action   = Observe | Deliberate | Act | Reflect
  ν        = greatest fixpoint (coinduction — runs indefinitely)

The ν (nu) operator is the key: unlike inductive data (finite trees), a coinductive agent is a potentially infinite stream of state transitions, terminating only when the goal is achieved or a budget is exhausted. This formalization is not decorative — it determines the compiler's verification strategy and the executor's loop semantics.

Epistemic Lattice Convergence. At each BDI cycle, the agent's epistemic state is projected onto the same lattice (T, ≤) used by epistemic directives. The deliberation phase produces a state σ ∈ {know, believe, speculate, doubt} and a boolean goal_achieved. The convergence criterion is:

Converge(σ, g) = g = true ∧ σ ≥ believe

Diverge(σ, i, n) = σ = doubt ∧ Δσ = 0 ∧ i ≥ n
  where
    Δσ       = σᵢ - σᵢ₋₁   — epistemic progress between cycles
    i        = current iteration
    n        = stuck_window  — consecutive stagnation threshold

When Converge fires, the agent terminates successfully. When Diverge fires, the on_stuck recovery policy activates — escalate raises AgentStuckError, forge triggers creative re-seeding via the Poincaré pipeline, retry resets and re-attempts.

Budget Composition. Budget constraints compose from the IR into the runtime as a 4-tuple verified at compile time:

B(agent) = (max_iter, max_tokens, max_time, max_cost)

Terminate when: ∃ b ∈ B(agent) : consumed(b) ≥ limit(b)

The compiler rejects agents with unbounded budgets (max_iterations = 0 without an explicit on_stuck policy), preventing runaway execution by construction.

Strategy Dispatch. The strategy parameter selects the BDI loop variant at compile time. Each strategy maps to a specific deliberation/action sequence:

Λ : Strategy → CycleShape

Λ(react)            = Deliberate → Act → Observe
Λ(reflexion)        = Deliberate → Act → Observe → Reflect
Λ(plan_and_execute) = Plan → (Act → Observe)* → Verify
Λ(custom)           = user-defined step sequence

Usage example — Autonomous Research Agent:

persona ResearchAnalyst {
    domain: ["market research", "competitive analysis"]
    tone: analytical
    confidence_threshold: 0.85
}

tool WebSearch {
    provider: serper
    timeout: 10s
}

tool DataAnalyzer {
    provider: internal
    timeout: 30s
}

agent MarketResearcher {
    goal: "Produce a comprehensive competitive analysis report
           with verified data from at least 5 sources"
    tools: [WebSearch, DataAnalyzer]
    strategy: react
    max_iterations: 15
    max_tokens: 50000
    max_cost: 2.50
    on_stuck: forge
    return: CompetitiveReport
}

flow CompetitiveIntelligence(sector: String) -> CompetitiveReport {
    step Research {
        MarketResearcher(sector)
        output: CompetitiveReport
    }
}

run CompetitiveIntelligence("electric vehicles")
    with ResearchAnalyst

What the compiler does:

1. IR Generation — the agent block compiles to an IRAgent node containing goal, tools, budget (15 iter / 50k tokens / $2.50), strategy (react), and recovery policy (forge). The IRAgent is embedded as a step inside IRFlow, preserving compositional semantics.
2. Backend Compilation — the backend (Anthropic, Gemini) generates a CompiledStep with step_name: "agent:MarketResearcher" and full agent metadata in its metadata["agent"] dictionary. The system prompt includes persona traits, tool availability, and epistemic constraints.
3. Runtime Execution — the executor detects agent: prefix and dispatches to the BDI loop. Each cycle: deliberate (epistemic assessment via JSON), act (execute step or invoke tool), observe (update beliefs). The loop respects the budget 4-tuple and applies on_stuck when Diverge fires.
4. Trace Events — every BDI cycle emits STEP_START, MODEL_CALL, and STEP_END trace events, giving full observability into the agent's reasoning trajectory.

Why this matters: The agent is not a Python class that wraps while True. It is a compiled cognitive primitive — the compiler verifies its budget boundedness, the type checker validates its return type, the backend generates strategy-specific prompts, and the runtime executes a formally-defined BDI loop with epistemic convergence criteria. This is the difference between duct-taping an LLM into a loop and engineering an autonomous system with mathematical guarantees.

Agent Use Case 1: Autonomous Legal Research Agent

A law firm deploys an agent that autonomously researches case law until it finds sufficient precedent — or exhausts its budget and escalates to a human attorney:

agent CaseLawResearcher {
    goal: "Find 3+ relevant precedents for the contract dispute
           with verified court citations"
    tools: [WebSearch, PDFExtractor]
    strategy: reflexion
    max_iterations: 20
    max_cost: 5.00
    on_stuck: escalate
    return: CaseLawReport
}

• reflexion strategy adds self-critique after each cycle — the agent evaluates whether its found precedents are truly relevant, not just keyword matches
• on_stuck: escalate means if the agent doubts its findings after 20 cycles, it raises AgentStuckError with full context, so the human reviews exactly where the agent got stuck
• Budget cap of $5.00 prevents runaway API costs — the compiler guarantees termination

Agent Use Case 2: Multi-Agent Data Pipeline

A BI platform chains two agents: one gathers data, the other analyzes it. Both execute within the same compiled flow:

agent DataGatherer {
    goal: "Collect quarterly revenue data from public filings"
    tools: [WebSearch, FileReader]
    strategy: react
    max_iterations: 10
    on_stuck: retry
    return: DataSet
}

agent TrendAnalyzer {
    goal: "Identify year-over-year growth patterns and anomalies"
    tools: [Calculator, DataAnalyzer]
    strategy: plan_and_execute
    max_iterations: 8
    on_stuck: forge
    return: TrendReport
}

flow QuarterlyIntelligence(sector: String) -> TrendReport {
    step Gather { DataGatherer(sector) output: DataSet }
    step Analyze { TrendAnalyzer(Gather.output) output: TrendReport }
}

• Two agents, two strategies: react for data gathering (fast, tool-heavy), plan_and_execute for analysis (structured, plan-then-verify)
• Each agent has independent budget tracking — if DataGatherer costs $0.50, TrendAnalyzer still has its full budget
• If TrendAnalyzer gets stuck, forge triggers creative re-seeding via the Poincaré pipeline, generating novel analytical angles

Agent Use Case 3: Customer Onboarding Agent with Dynamic Recovery

A SaaS platform uses an agent to guide new customers through a personalized onboarding flow, adapting when it gets stuck:

persona OnboardingSpecialist {
    domain: ["product knowledge", "user experience"]
    tone: warm
    confidence_threshold: 0.80
}

agent OnboardingGuide {
    goal: "Complete the customer's onboarding checklist with
           personalized recommendations for their industry"
    tools: [APICall, Calculator]
    strategy: custom
    max_iterations: 12
    max_tokens: 30000
    on_stuck: forge
    return: OnboardingReport

    step Greet { ask: "Welcome the user and assess their goals" }
    step Configure { ask: "Recommend workspace configuration" }
    step Train { ask: "Generate personalized tutorial sequence" }
}

• custom strategy: the agent follows a user-defined step sequence (Greet → Configure → Train), not a generic loop
• on_stuck: forge — if the agent can't personalize recommendations (e.g., unknown industry), it triggers creative synthesis to propose novel onboarding paths instead of failing
• The return: OnboardingReport type is validated by the semantic type checker — the agent must produce a structurally valid report, not just free text

VI. Compile-Time Security — the shield Primitive

AXON v0.13 introduces an eighth paradigm shift: Information Flow Control (IFC) as a first-class compiled construct, providing compile-time security guarantees against LLM-specific attack vectors.

Every LLM framework treats security as an afterthought — runtime guardrails bolted on top of applications. AXON's shield primitive makes security a compiler-verified property of your program, grounded in taint analysis and Information Flow Control theory.

Trust Lattice (Denning-style IFC). The shield system operates over a trust lattice where data flows from untrusted sources through shield application points to trusted sinks. The compiler statically verifies that every path from an untrusted source to a trusted sink passes through at least one shield:

U : DataLabel → TrustLevel

TrustLevel = Untrusted < Scanned < Sanitized < Trusted

∀ path(source, sink) ∈ Flow :
  label(source) = Untrusted ∧ label(sink) = Trusted
  → ∃ shield ∈ path : label(shield.output) ≥ Sanitized

Threat Taxonomy. The scan field declares which threats the shield detects, drawn from a formal taxonomy of 11 LLM attack categories:

T = { prompt_injection, jailbreak, data_exfil, pii_leak, toxicity,
      bias, hallucination, code_injection, social_engineering,
      model_theft, training_poisoning }

Detection Strategies. The strategy parameter selects the detection mechanism, each with different cost/accuracy tradeoffs:

Σ : Strategy → (Cost, Accuracy, Latency)

Σ(pattern)     = (low,    medium, fast)     — regex/heuristic scan
Σ(classifier)  = (medium, high,   medium)   — fine-tuned classifier (Llama Guard)
Σ(dual_llm)    = (high,   highest, slow)    — privileged/quarantined model pair
Σ(canary)      = (low,    medium, fast)     — traceable token injection
Σ(perplexity)  = (medium, high,   medium)   — statistical anomaly detection
Σ(ensemble)    = (high,   highest, slow)    — majority voting across multiple strategies

Capability Enforcement. The compiler statically verifies that agent tool access is a subset of the shield's allow list — preventing privilege escalation at compile time:

∀ agent A with shield S :
  tools(A) ⊆ allow_tools(S)    — verified at compile time
  tools(A) ∩ deny_tools(S) = ∅  — also verified

Usage example — LLM Input Shield:

shield InputGuard {
    scan: [prompt_injection, jailbreak, pii_leak]
    strategy: dual_llm
    on_breach: halt
    severity: critical
    allow: [web_search, calculator]
    deny: [code_executor]
    sandbox: true
    redact: [email, phone]
    confidence_threshold: 0.85
}

persona SecureAssistant {
    domain: ["customer support"]
    tone: professional
    confidence_threshold: 0.80
}

agent SecureBot {
    goal: "Answer customer queries safely"
    tools: [web_search, calculator]
    shield: InputGuard
    strategy: react
    max_iterations: 10
    return: SafeResponse
}

flow SecureSupport(query: String) -> SafeResponse {
    shield InputGuard on query -> SanitizedQuery
    step Process {
        SecureBot(SanitizedQuery)
        output: SafeResponse
    }
}

run SecureSupport("Help me with my account")
    with SecureAssistant

What the compiler does:

1. Type Checking — validates all scan categories, strategies, breach policies, severity levels, and confidence thresholds. Detects allow/deny overlaps and invalid configurations at compile time.
2. Capability Enforcement — verifies that SecureBot only uses [web_search, calculator] which are in InputGuard.allow, and that neither appears in deny. If SecureBot tried to use code_executor, the compiler would reject the program.
3. Taint Analysis — verifies that query (untrusted) passes through shield InputGuard on query before reaching the agent's trusted context.
4. Runtime Execution — the shield step emits SHIELD_SCAN_START, scans for prompt injection/jailbreak/PII, and either passes (SHIELD_SCAN_PASS) or raises ShieldBreachError (SHIELD_SCAN_BREACH).

Shield Use Case 1: Financial Data Pipeline with PII Redaction

shield DataShield {
    scan: [pii_leak, data_exfil]
    strategy: classifier
    on_breach: sanitize_and_retry
    max_retries: 3
    severity: high
    redact: [ssn, credit_card, bank_account]
}

flow ProcessFinancialQuery(input: String) -> Report {
    shield DataShield on input -> CleanInput
    step Analyze {
        given: CleanInput
        ask: "Analyze the financial data"
        output: Report
    }
}

• PII fields (SSN, credit card, bank account) are auto-redacted before the LLM sees the data
• sanitize_and_retry means detected threats are cleaned and re-scanned up to 3 times, not just blocked
• The compiler guarantees the LLM never processes raw PII

Shield Use Case 2: Multi-Agent System with Capability Isolation

shield ResearchShield {
    scan: [data_exfil, model_theft]
    strategy: ensemble
    on_breach: quarantine
    allow: [web_search, file_reader]
    deny: [code_executor, api_call]
    sandbox: true
}

agent Researcher {
    goal: "Gather market intelligence from public sources"
    tools: [web_search, file_reader]
    shield: ResearchShield
    strategy: reflexion
    max_iterations: 15
    return: IntelligenceReport
}

• ensemble strategy runs multiple detectors with majority voting — highest accuracy for sensitive operations
• sandbox: true runs tool execution in an isolated environment
• Capability enforcement: the compiler rejects any agent that tries to use code_executor or api_call — preventing privilege escalation by design
• quarantine breach policy isolates suspicious data for human review instead of blocking operations

VII. Epistemic Tool Fortification — Streaming, Effects & Blame Semantics

AXON v0.14 introduces a ninth paradigm shift: formal epistemic control over tool invocations, streaming outputs, and foreign-function interfaces — backed by algebraic effect theory, coinductive stream semantics, and Findler-Felleisen blame calculus.

Every LLM framework treats tool calls as black boxes: a function returns a string, and the framework trusts it unconditionally. Streaming is even worse — partial tokens arrive without any notion of confidence, reliability, or epistemic state. AXON v0.14 solves this by making every interaction with the external world subject to formal epistemic tracking.

Formal Model — Four Convergence Theorems

CT-1: Coinductive Semantic Streaming. A streaming response is a coinductive process — an infinite observation/transition pair that monotonically accumulates epistemic confidence as chunks arrive:

Stream(τ) = νX. (StreamChunk × EpistemicState × X)

where
  StreamChunk    = (content: String, index: ℕ, timestamp: ℝ)
  EpistemicState = (level ∈ {doubt, speculate, believe, know}, confidence ∈ [0,1])
  ν              = greatest fixpoint (coinduction — process unfolds indefinitely)

Monotonicity invariant:
  ∀ i < j : gradient(chunkᵢ) ⊑ gradient(chunkⱼ)
  (epistemic level can only rise, never degrade during streaming)

Streaming in AXON is not "tokens arriving". It is a formal epistemic process: each chunk carries its position on the lattice, and the system guarantees that confidence can only increase monotonically until convergence.

CT-2: Algebraic Effect Rows. Every tool declares its computational effects using Plotkin & Pretnar's algebraic effect theory. The compiler statically verifies effect compatibility:

EffectRow(tool) = ⟨ε₁, ε₂, ..., εₙ, epistemic:level⟩

where
  εᵢ ∈ {pure, io, network, storage, random}
  level ∈ {know, believe, speculate, doubt}

Composition rule:
  EffectRow(A ∘ B) = EffectRow(A) ∪ EffectRow(B)
  epistemic(A ∘ B) = min(epistemic(A), epistemic(B))   — meet on lattice

The composition rule means: if you chain a network + speculate tool with a pure + know tool, the combined effect is network + speculate — the system automatically tracks the least trustworthy component.

CT-3: Blame Semantics for FFI. External tool calls are wrapped in Findler-Felleisen contract monitors that assign blame when pre/postconditions fail:

ContractMonitor(tool) = (Pre, Post, Blame)

where
  Pre  : Input → Bool         — caller's obligation
  Post : Output → Bool        — server's obligation
  Blame : {CALLER, SERVER}    — who violated the contract

Blame assignment:
  ¬Pre(input)   → Blame = CALLER   (you sent bad data)
  ¬Post(output) → Blame = SERVER   (tool returned bad data)

This is not error handling — this is formal accountability. When a tool fails, AXON tells you who broke the contract, not just that it broke.

CT-4: Epistemic Inference via CSP. The @csp_tool decorator automatically infers the epistemic level of any Python function by analyzing its effect footprint using a constraint-satisfaction heuristic:

Infer(f) : Function → EpistemicLevel

  If ∄ io/network/random ∈ effects(f) → know
  If ∃ network ∈ effects(f)           → speculate
  If ∃ random ∈ effects(f)            → doubt
  Otherwise                           → believe

What Makes This Revolutionary

No LLM framework in existence tracks what a tool does to your epistemic state. LangChain, CrewAI, AutoGen — they all treat tool results as trusted strings. This means:

• A web search result (unreliable) gets the same trust as a database query (reliable)
• A streaming response's first token gets the same trust as the final, validated output
• When a tool fails, you don't know if your input was wrong or the tool was broken

AXON solves all three. The compiler guarantees that:

1. Every tool call is tagged with its effect signature and epistemic level
2. Streaming outputs start at doubt and can only ascend monotonically
3. Tool failures carry blame labels that identify the responsible party
4. Data crossing the FFI boundary is automatically tainted — it cannot reach know level without passing through a shield or anchor

Use Case 1: Real-Time Financial Streaming with Epistemic Gradient

A trading desk receives streaming market data and needs to distinguish between real-time quotes (speculative) and confirmed trades (factual):

tool MarketFeed {
    provider: bloomberg
    timeout: 5s
    effects: <io, network, epistemic:speculate>
}

flow MonitorMarket(sector: String) -> MarketReport {
    step Stream {
        stream<QuoteData> {
            on_chunk: {
                probe chunk for [symbol, price, volume]
                output: QuoteSnapshot
            }
            on_complete: {
                validate QuoteSnapshot against: MarketSchema
                output: VerifiedQuote
            }
        }
    }
    step Analyze {
        reason {
            given: Stream.output
            ask: "Identify anomalous price movements"
            depth: 2
        }
        output: MarketReport
    }
}

• Each streaming chunk starts at doubt — the system treats partial data as unreliable by default
• on_complete handler validates and promotes to believe — only complete, schema-validated data upgrades
• The effects: <io, network, epistemic:speculate> declaration means the compiler knows this tool is never factual — preventing accidental know-level assertions from market data

Use Case 2: Multi-Tool Research Agent with Blame Tracking

A research agent uses multiple tools with different reliability levels. When something fails, the system identifies exactly who broke the contract:

tool WebSearch {
    provider: serper
    timeout: 10s
    effects: <network, epistemic:speculate>
}

tool DatabaseQuery {
    provider: internal
    timeout: 30s
    effects: <io, epistemic:believe>
}

tool Calculator {
    provider: stdlib
    effects: <pure, epistemic:know>
}

flow DeepResearch(question: String) -> ResearchReport {
    par {
        step Web {
            use_tool WebSearch with query: question
            output: WebResults
        }
        step DB {
            use_tool DatabaseQuery with query: question
            output: DBResults
        }
    }
    step Synthesize {
        weave [Web.output, DB.output]
        output: ResearchReport
    }
}

• WebSearch is epistemic:speculate — the compiler knows web results are unreliable and automatically taints downstream data
• DatabaseQuery is epistemic:believe — more reliable, but still not know because external I/O is involved
• Calculator is pure + epistemic:know — no side effects, deterministic, fully trustworthy
• When weave combines them, the result's epistemic level is min(speculate, believe) = speculate — the weakest link determines trust
• If WebSearch returns garbage, the ContractMonitor issues Blame = SERVER with full diagnostic context

Use Case 3: Safe External API Integration with @contract_tool

A production system integrates a third-party payment API. The @contract_tool decorator wraps it with pre/postcondition contracts and automatic epistemic downgrade:

from axon.runtime.tools import contract_tool

@contract_tool(
    pre=lambda amount, currency: amount > 0 and currency in ["USD", "EUR"],
    post=lambda result: "transaction_id" in result,
    effect_row=("network", "io"),
    epistemic_level="speculate"
)
async def process_payment(amount: float, currency: str) -> dict:
    return await stripe_api.charge(amount, currency)

flow ProcessOrder(order: Order) -> Receipt {
    step Charge {
        use_tool process_payment with amount: order.total, currency: "USD"
        output: PaymentResult
    }
    step Verify {
        validate Charge.output against: PaymentSchema
        if confidence < 0.9 -> refine(max_attempts: 2)
        output: Receipt
    }
}

• pre contract: AXON validates that amount > 0 and currency is valid before calling Stripe. If violated → Blame = CALLER
• post contract: AXON validates that the response contains a transaction_id. If violated → Blame = SERVER (Stripe returned bad data)
• All payment results are automatically tainted = True — they cannot reach know level without explicit anchor validation
• The effects: <network, io> declaration prevents this tool from being used inside a pure context — a compile-time error

---

VIII. Structured Cognitive Retrieval — the pix Primitive

AXON v0.15 introduces a tenth paradigm shift: intent-driven tree navigation as a formally grounded alternative to vector-similarity retrieval (RAG), built on information foraging theory, bounded rational search, and full explainability via reasoning trails.

Every RAG system in existence makes the same assumption: semantically close embeddings imply relevance. This works for keyword-style queries, but fails catastrophically for structured documents — legal contracts, technical manuals, medical records — where the answer lives at a specific structural location, not in the nearest embedding vector.

AXON's pix primitive rejects the "embed everything, retrieve by cosine" paradigm. Instead, it treats documents as navigable trees and retrieval as a bounded cognitive search — the same process a human expert uses when consulting a complex document: start at the table of contents, follow the most promising branches, prune irrelevant paths, and explain every decision.

Formal Model — Rooted Directed Acyclic Tree (DAG→Tree)

Document Tree. A PIX-indexed document D is a rooted tree:

D = (N, E, n₀)

where
  N  = {n₀, n₁, ..., nₖ}    — nodes (sections, subsections, paragraphs)
  E  ⊆ N × N               — directed edges (parent → child)
  n₀ ∈ N                    — root (document-level summary)

Properties:
  ∀ nᵢ ∈ N \ {n₀} : ∃! nⱼ : (nⱼ, nᵢ) ∈ E    — unique parent
  height(D) = h                                — maximum depth
  |leaves(D)| = content nodes with full text

Each node carries a summary (generated at index time) and optionally the full section content. Internal nodes hold structure; leaf nodes hold answers.

Information Scent Navigation. Navigation follows Pirolli & Card's Information Foraging Theory. At each tree level, a scoring function S evaluates the "information scent" of every child relative to the query:

S : (query, title, summary) → [0, 1]

Navigation rule at depth d:
  children_d = {nᵢ : (current, nᵢ) ∈ E}
  scored     = {(nᵢ, S(q, nᵢ.title, nᵢ.summary)) : nᵢ ∈ children_d}
  selected   = top_k(scored, k=max_branch) ∩ {(n, s) : s ≥ threshold}

Fallback (no child meets threshold):
  selected = {argmax(scored)} if max(scored) > 0 else ∅

The key insight: the scorer replaces embedding similarity. In production it is an LLM call; in tests a keyword-overlap heuristic suffices. Either way, the navigator uses the same bounded-search algorithm.

Bounded Rational Search. Navigation terminates via a budget 4-tuple verified at compile time:

Config(pix) = (max_depth, max_branch, threshold, timeout)

Termination:
  depth ≥ max_depth  ∨  node.is_leaf  ∨  elapsed ≥ timeout
  → append to result leaves

This prevents unbounded traversal — the same principle behind AXON's agent budget enforcement.

Reasoning Trail (Explainability). Every navigation produces a ReasoningPath — an ordered sequence of NavigationStep records documenting why each branch was selected or pruned:

Trail = [Step₁, Step₂, ..., Stepₙ]

Stepᵢ = (node_id, title, score, reasoning, depth)

Properties:
  |Trail| = total nodes evaluated
  depth(Trail) = max(Stepᵢ.depth)

This is not logging — it is formal explainability. The trail is a first-class data structure accessible via the trail keyword.

What Makes PIX Different from RAG

Property	RAG	PIX
Index structure	Flat vector store	Hierarchical tree
Retrieval method	Cosine similarity	Bounded tree navigation
Granularity	Fixed chunks	Structural sections
Explainability	None (black-box)	Full reasoning trail
Query type	Keyword/semantic	Intent-driven
Relevance model	"Closest vector"	"Most scented path"
Compile-time verification	❌	✅ (depth, branching bounds)

PIX principle: "Lo estructuralmente navegado con intención es lo relevante" — what matters is not what is semantically close, but what a rational agent would navigate to when consulting the document with purpose.

Usage Example — PIX-Navigated Legal Analysis

pix ContractIndex {
    source: "contracts/master_agreement.md"
    depth: 4
    branching: 3
    model: "fast"
}

flow AnalyzeContract(question: String) -> LegalAnalysis {
    step Search {
        navigate ContractIndex
            query: question
            trail: enabled
            as: relevant_sections
    }
    step Drill {
        drill ContractIndex
            into "Liabilities"
            query: question
            as: liability_detail
    }
    step Explain {
        trail relevant_sections
    }
    step Synthesize {
        weave [relevant_sections, liability_detail]
        format: LegalAnalysis
        include: [answer, sources, reasoning_trail]
    }
}

What the compiler does:

1. Type Checking — validates pix parameters (depth ≤ 10, branching ≤ 10), verifies that navigate and drill reference a declared pix (not a persona or flow), and guarantees output bindings are unique
2. IR Generation — compiles to IRPixSpec, IRNavigate, IRDrill, and IRTrail nodes carrying the full configuration (source, depth, branching, model, effects)
3. Runtime Execution — the PIX engine indexes the source document into a DocumentTree, then the navigator performs bounded tree search guided by the scoring function, recording every decision in the ReasoningPath
4. Trail Output — the trail step exposes the full reasoning path — every node evaluated, its score, and why it was selected or pruned

PIX Use Case 1: Medical Document Navigation

A hospital system needs to find specific clinical guidelines within a 200-page protocol manual. RAG would chunk the document into 512-token fragments and return the 5 closest embeddings — potentially mixing guidelines from different sections. PIX navigates structurally:

pix ClinicalProtocol {
    source: "protocols/surgical_guidelines_v12.md"
    depth: 5
    branching: 2
    model: "precise"
}

flow FindGuideline(procedure: String) -> ClinicalGuideline {
    step Navigate {
        navigate ClinicalProtocol
            query: procedure
            trail: enabled
            as: guideline
    }
    step Verify {
        validate guideline against: ClinicalSchema
        if confidence < 0.9 -> refine(max_attempts: 2)
        output: ClinicalGuideline
    }
}

• depth: 5 allows reaching deeply nested subsections (Chapter → Section → Subsection → Paragraph → Note)
• branching: 2 limits exploration to the 2 most relevant children per level — fast, focused retrieval
• The trail documents exactly which sections were evaluated and why, which is required for medical audit compliance

PIX Use Case 2: Technical Documentation Q&A

A developer needs to find the exact API method for a specific task in a large SDK documentation. RAG returns 5 chunks that all mention the API but none answer the precise question. PIX drills directly:

pix SDKDocs {
    source: "docs/sdk_reference_v3.md"
    depth: 6
    branching: 3
}

flow AnswerDevQuestion(question: String) -> DevAnswer {
    step Browse {
        navigate SDKDocs query: question as: overview
    }
    step Deep {
        drill SDKDocs into "API Reference" query: question as: api_detail
    }
    step Respond {
        weave [overview, api_detail]
        format: DevAnswer
        include: [answer, code_examples, see_also]
    }
}

• navigate finds the general area; drill goes directly into "API Reference"
• Combined result gives both context (overview) and precision (api_detail)
• No embedding database needed — the document's own structure is the index

PIX Use Case 3: Regulatory Compliance Audit with Full Trail

A compliance team audits whether a company's data practices satisfy GDPR requirements. The trail provides the auditable decision chain:

pix GDPRRegulation {
    source: "regulations/gdpr_full_text.md"
    depth: 4
    branching: 3
    model: "precise"
}

know {
    flow AuditCompliance(practice: String) -> ComplianceReport {
        step Find {
            navigate GDPRRegulation
                query: practice
                trail: enabled
                as: articles
        }
        step ShowTrail {
            trail articles
        }
        step Assess {
            reason {
                given: articles
                ask: "Does the practice comply with these articles?"
                depth: 3
            }
            output: ComplianceReport
        }
    }
}

• know block ensures maximum factual rigor — no speculation about regulations
• The trail provides a complete record of which GDPR articles were considered and why, satisfying regulatory audit requirements
• No vector database, no embedding model, no chunking strategy to tune — the regulation's own hierarchical structure (Part → Chapter → Section → Article) is the retrieval mechanism

---

Architecture

.axon source → Lexer → Tokens → Parser → AST
                                           │
                              Type Checker (semantic validation)
                                           │
                              IR Generator → AXON IR (JSON-serializable)
                                           │
                              Backend (Anthropic │ OpenAI │ Gemini │ Ollama)
                                           │
                              Runtime (Executor + Validators + Tracer)
                                           │
                              Typed Output (validated, traced result)

33 Cognitive Primitives

Primitive	Keyword	What it represents
Persona	persona	Cognitive identity of the model
Context	context	Working memory / session config
Intent	intent	Atomic semantic instruction
Flow	flow	Composable pipeline of cognitive steps
Reason	reason	Explicit chain-of-thought
Anchor	anchor	Hard constraint (never violable)
Validate	validate	Semantic validation gate
Refine	refine	Adaptive retry with failure context
Memory	memory	Persistent semantic storage
Tool	tool	External invocable capability
Probe	probe	Directed information extraction
Weave	weave	Semantic synthesis of multiple outputs
Know	know	Epistemic scope — maximum factual rigor
Believe	believe	Epistemic scope — moderate confidence
Speculate	speculate	Epistemic scope — creative freedom
Doubt	doubt	Epistemic scope — adversarial validation
Par	par	Parallel cognitive dispatch
Hibernate	hibernate	Dynamic state yielding / CPS checkpoint
DataSpace	dataspace	In-memory associative data container
Ingest	ingest	Load external data into a DataSpace
Focus	focus	Select data — propagate associations
Associate	associate	Link tables via shared fields
Aggregate	aggregate	Group-by aggregation on selections
Explore	explore	Snapshot current associative state
Deliberate	deliberate	Compute budget control (tokens/depth/strategy)
Consensus	consensus	Best-of-N parallel evaluation & selection
Forge	forge	Directed creative synthesis (Poincaré pipeline)
Agent	agent	Autonomous goal-seeking BDI cognitive system
Shield	shield	Compile-time IFC security (taint + capability)
Stream	stream	Coinductive semantic streaming with epistemic gradient
Effects	effects	Algebraic effect rows for tool declarations
PIX	pix	Structured document index (navigable tree)
Navigate	navigate	Intent-driven tree retrieval with reasoning trail
Drill	drill	Subtree-scoped navigation for targeted retrieval
Trail	trail	Explainability path — formal reasoning audit

Epistemic Type System (Partial Order Lattice)

Types represent meaning and cognitive state, not just data structures. AXON implements an epistemic type system based on a partial order lattice (T, ≤), representing formal subsumption relationships:

⊤ (Any)
    │
    ├── FactualClaim
    │   └── CitedFact
    │       └── HighConfidenceFact
    │
    ├── Opinion
    ├── Uncertainty   ← propagates upwards (taint)
    └── Speculation
⊥ (Never)

Rule of Subsumption: If T₁ ≤ T₂, then T₁ can be used where T₂ is expected. For instance, a CitedFact can naturally satisfy a FactualClaim dependency, but an Opinion never can. Furthermore, computations involving Uncertainty structurally taint the result, propagating Uncertainty forwards to guarantee epistemic honesty throughout the execution flow.

Content:      Document · Chunk · EntityMap · Summary · Translation
Analysis:     RiskScore(0..1) · ConfidenceScore(0..1) · SentimentScore(-1..1)
Structural:   Party · Obligation · Risk (user-defined)
Compound:     StructuredReport

---

Project Structure

axon-constructor/
├── axon/
│   ├── compiler/
│   │   ├── lexer.py              # Source → Token stream
│   │   ├── tokens.py             # Token type enum (48 keywords)
│   │   ├── parser.py             # Tokens → AST (recursive descent)
│   │   ├── ast_nodes.py          # AST node class hierarchy
│   │   ├── type_checker.py       # Semantic type validation
│   │   ├── ir_generator.py       # AST → AXON IR
│   │   └── ir_nodes.py           # IR node definitions
│   ├── backends/
│   │   ├── base_backend.py       # Abstract backend interface
│   │   ├── anthropic.py          # Claude
│   │   ├── openai.py             # GPT
│   │   ├── gemini.py             # Gemini
│   │   └── ollama.py             # Local models
│   ├── engine/                   # In-memory associative data engine
│   │   ├── symbol_table.py       # Dictionary encoding
│   │   ├── data_column.py        # Columnar storage + inverted index
│   │   ├── association_index.py  # Cross-table link graph
│   │   ├── selection_state.py    # Selection propagation engine
│   │   ├── dataspace.py          # Top-level data container
│   │   └── pix/                  # PIX retrieval engine
│   │       ├── document_tree.py  # PixNode + DocumentTree (navigable tree)
│   │       ├── navigator.py      # PixNavigator (bounded tree search)
│   │       └── indexer.py        # PixIndexer (document → tree)
│   ├── runtime/
│   │   ├── executor.py           # Flow execution engine
│   │   ├── data_dispatcher.py    # Data Science IR → engine bridge
│   │   ├── context_mgr.py        # Mutable state between steps
│   │   ├── semantic_validator.py # Output type validation
│   │   ├── retry_engine.py       # Backoff + failure context
│   │   ├── memory_backend.py     # Abstract + InMemoryBackend
│   │   ├── state_backend.py      # CPS persistence (hibernate/resume)
│   │   ├── tracer.py             # 23 event types, JSON trace
│   │   ├── runtime_errors.py     # 11-level error hierarchy
│   │   └── tools/
│   │       ├── base_tool.py      # BaseTool ABC + ToolResult
│   │       ├── registry.py       # RuntimeToolRegistry (cached)
│   │       ├── dispatcher.py     # IR → runtime tool bridge
│   │       ├── contract_tool.py  # @contract_tool FFI decorator
│   │       ├── csp_tool.py       # @csp_tool auto-inference decorator
│   │       ├── blame.py          # Blame semantics (CT-3)
│   │       ├── epistemic_inference.py  # CSP heuristic engine (CT-4)
│   │       ├── stubs/            # 8 tools (6 stubs + 2 real)
│   │       └── backends/         # 3 production backends
│   ├── runtime/
│   │   └── streaming.py          # Coinductive streaming engine (CT-1)
│   └── stdlib/                   # Built-in personas, flows, anchors
└── tests/                        # 1513 tests

---

Installation

# From PyPI
pip install axon-lang

# With real tool backends (WebSearch, etc.)
pip install axon-lang[tools]

# Verify
axon version

From Source

git clone https://github.com/bemarking/axon-constructor.git
cd axon-constructor
python -m venv .venv
source .venv/bin/activate  # or .venv\Scripts\activate on Windows
pip install -e ".[tools,dev]"  # editable install

Required API Keys

Key	For	Get it at
SERPER_API_KEY	WebSearch backend	serper.dev
ANTHROPIC_API_KEY	Claude backend	console.anthropic.com
OPENAI_API_KEY	GPT backend	platform.openai.com
GEMINI_API_KEY	Gemini backend	aistudio.google.com

None are required for development — stubs work without keys.

---

CLI Usage

# Validate syntax: lex + parse + type-check
axon check program.axon

# Compile to IR JSON
axon compile program.axon                     # → program.ir.json
axon compile program.axon --stdout             # pipe to stdout
axon compile program.axon -b openai            # target backend
axon compile program.axon -o custom.json       # custom output path

# Execute end-to-end (requires API key for chosen backend)
axon run program.axon                          # default: anthropic
axon run program.axon -b gemini                # choose backend
axon run program.axon --trace                  # save execution trace
axon run program.axon --tool-mode hybrid       # stub | real | hybrid

# Pretty-print an execution trace
axon trace program.trace.json

# Version
axon version

# Interactive REPL
axon repl

# Introspect stdlib
axon inspect anchors                       # list all anchors
axon inspect personas                      # list all personas
axon inspect NoHallucination               # detail for a component
axon inspect --all                         # list everything

Python API

from axon import Lexer, Parser, TypeChecker, IRGenerator, get_backend

source = open("program.axon").read()
tokens  = Lexer(source).tokenize()
ast     = Parser(tokens).parse()
errors  = TypeChecker(ast).check()
ir      = IRGenerator().generate(ast)
backend = get_backend("anthropic")
result  = backend.compile(ir)

---

Tests

# Full suite
pytest tests/ -v

# By layer
pytest tests/test_lexer.py tests/test_parser.py         # Phase 1: Language core
pytest tests/test_ir_nodes.py tests/test_backends.py     # Phase 2: Compiler
pytest tests/test_executor.py tests/test_retry.py        # Phase 3: Runtime
pytest tests/test_tool_stubs.py tests/test_tool_backends.py  # Phase 4: Tools

Current Status

1513 passed, 0 failures ✅

Phase	Tests	What's covered
1	83	Lexer, Parser, AST, Type Checker
2	164	IR Generator, Compiler Backends
3	115	Executor, Context, Retry, Tracer, Validator
4	88	Tool infra (53) + Real backends (35)
7	56	Paradigm Shifts (epistemic, par, hibernate)
8	69	Data Science Engine (core)
11	22	Forge (creative synthesis pipeline)
12	28	Agent (BDI pipeline + integration)
13	70	Shield (compiler + runtime + integration)
14	83	Streaming, Effects, Contract, CSP (CT-1–4)
15	124	PIX (engine + compiler + integration)
misc	611	Stdlib, integration, edge cases

---

Tool System

AXON tools bridge compile-time IRUseTool nodes with runtime implementations.

Registry Modes

from axon.runtime.tools import create_default_registry

# Safe for tests — no API calls, no I/O
registry = create_default_registry(mode="stub")

# Real backends where available, stubs elsewhere
registry = create_default_registry(mode="hybrid")

# Only real backends (fails if deps missing)
registry = create_default_registry(mode="real")

Available Backends

Tool	Stub	Real Backend	Requires
WebSearch	✅	Serper.dev (httpx)	SERPER_API_KEY
FileReader	✅	Local filesystem	—
CodeExecutor	✅	subprocess + asyncio	—
Calculator	—	stdlib (real)	—
DateTime	—	stdlib (real)	—
PDFExtractor	✅	—	—
ImageAnalyzer	✅	—	—
APICall	✅	—	—

---

Error Hierarchy

Level  1: ValidationError         — output type mismatch
Level  2: ConfidenceError         — confidence below floor
Level  3: AnchorBreachError       — anchor constraint violated
Level  4: RefineExhausted         — max retry attempts exceeded
Level  5: RuntimeError            — model call failed
Level  6: TimeoutError            — execution time limit exceeded
Level  7: ToolExecutionError      — tool invocation failed
Level  8: AgentStuckError         — agent stagnation detected
Level  9: ShieldBreachError       — shield detected security threat
Level 10: TaintViolationError     — untrusted data reached trusted sink
Level 11: CapabilityViolationError — tool access outside shield allow list

---

Runtime Self-Healing

AXON features a native self-healing mechanism for L3 Semantic Gates. When the LLM output violates a hard constraint (AnchorBreachError) or fails structural semantic validation (ValidationError), the AXON RetryEngine automatically intercepts the failure.

Instead of crashing or silently failing, the engine re-injects the exact failure_context (e.g., "Anchor breach detected: Hedging without citation") back into the LLM's next prompt. This creates a closed feedback loop where the model adaptively corrects its logic and structurally self-heals in real-time.

Production Guarantees:

• Strict Boundaries: The correction loop strictly respects the refine limits explicitly defined in the execution configuration. If the model fails to heal within the permitted attempts, AXON deterministically raises a RefineExhaustedError (containing the last failed state) to escalate the failure, preventing infinite execution loops.
• Anchor Dependency: The healing capability is directly proportional to the precision of the defined Anchors. AXON provides the robust recovery mechanism, but ambiguous or poorly defined constraints may cause the model to optimize for passing validation syntactically while failing semantically. Clear, logical Anchors are required.

Phase 4: Logic & Epistemic Anchors

AXON includes specialized standard library anchors (Phase 4) explicitly designed to work with the Self-Healing engine to enforce logical structures and epistemic honesty:

• SyllogismChecker: Enforces explicit logical formats using Premise: and Conclusion: markers to guarantee structurally parseable arguments.
• ChainOfThoughtValidator: Requires explicit sequence step markers before resolving a prompt.
• RequiresCitation: Deep verification enforcing academic-style inline citations/URLs blocking unverifiable claims.
• AgnosticFallback: Penalizes unwarranted speculation, forcing the model to explicitly state a lack of information when sufficient data is unavailable.

---

Roadmap

Phase	What	Status
0	Spec, grammar, type system	✅ Done
1	Lexer, Parser, AST, Type Checker	✅ Done
2	IR Generator, Compiler Backends	✅ Done
3	Runtime (7 modules)	✅ Done
4	Standard Library	✅ Done
5	CLI, REPL, Inspect	✅ Done
6	Test Suite, Hardening, Docs	✅ Done
7	Paradigm Shifts (epistemic/par/hibernate)	✅ Done
8	Data Science Engine + Runtime Integration	✅ Done
9	Executor integration + production backends	✅ Done
10	Compute Budget & Consensus (deliberate/consensus)	✅ Done
11	Directed Creative Synthesis (forge)	✅ Done
12	Autonomous Agents (agent BDI primitive)	✅ Done
13	Security Shields (shield IFC primitive)	✅ Done
14	Epistemic Tool Fortification (stream/effects/FFI)	✅ Done
15	Structured Cognitive Retrieval (pix)	✅ Done

---

Design Principles

1. Declarative over imperative — describe what, not how
2. Semantic over syntactic — types carry meaning, not layout
3. Composable cognition — blocks compose like neurons
4. Configurable determinism — spectrum from exploration to precision
5. Failure as first-class citizen — retry, refine, fallback are native

---

How it Compares

	LangChain	DSPy	Guidance	AXON
Own language + grammar	❌	❌	❌	✅
Semantic type system	❌	Partial	❌	✅
Formal anchors	❌	❌	❌	✅
Persona as type	❌	❌	❌	✅
Reasoning as primitive	❌	Partial	❌	✅
Native multi-model	Partial	Partial	❌	✅
Epistemic directives	❌	❌	❌	✅
Native parallel dispatch	❌	❌	❌	✅
State yielding / CPS	❌	❌	❌	✅
Compute budget control	❌	❌	❌	✅
Best-of-N consensus	❌	❌	❌	✅
Creative synthesis engine	❌	❌	❌	✅
Compiled autonomous agents	❌	❌	❌	✅
Formal BDI convergence	❌	❌	❌	✅
Budget-bounded agent loops	❌	❌	❌	✅
Compile-time taint analysis	❌	❌	❌	✅
Capability enforcement	❌	❌	❌	✅
LLM attack surface shielding	❌	❌	Partial	✅
Algebraic effect rows	❌	❌	❌	✅
Coinductive streaming	❌	❌	❌	✅
FFI blame semantics	❌	❌	❌	✅
Epistemic tool inference	❌	❌	❌	✅
Structured tree retrieval	❌	❌	❌	✅
Explainable retrieval trail	❌	❌	❌	✅
Compile-time retrieval bounds	❌	❌	❌	✅

---

License

MIT

Authors

Ricardo Velit