# portfolio-optimiser Generic, open framework on **Microsoft Agent Framework (MAF)** for finding cost-savings / efficiency proposals *within* each project of a portfolio of independent projects. Multiple agents collaborate to generate candidate proposals; a mandatory deterministic validator (solver + Monte Carlo) decides the numbers; domain experts review via human-in-the-loop, and the system learns from their verdicts. > **Status:** Early development. The deterministic backbone is solid; the agentic learning loop is being wired one load-bearing seam at a time — **Steps 1, 3/4, 5, 7 and 8 are wired** (OKF-navigated context, checker gate, informed refinement, the async file feedback loop, and gated wiki promotion; see below). Not yet end-to-end usable. > **Disclaimer — technical framework only.** This project is a *technical framework*. Organizations that deploy it are themselves responsible for ensuring a valid processing purpose and for any required assessments (DPIA, risk/ROS, security reviews, etc.). The framework ships technical affordances (local-only mode, provenance/audit logging, no silent data egress) to *enable* compliant use, but makes no compliance guarantees. ## Design philosophy The result will never fit any single customer 100%. The goal is a **~90% genuinely generic core plus clear extension points**, so competent people can configure the last mile per customer. We deliberately do not chase the final 10%. ## Agentic loop — wiring status The mandatory deterministic backbone (validator + budget meter + provenance) is solid and load-bearing. The agentic learning loop (see the [target picture](docs/plan/2026-06-26-maalbilde-agentic-loop.md) §11) is wired one seam at a time: - **Step 1 — OKF context → hypothesis (wired).** `run_project(..., bundle_dir=...)` wires the first agentic seam in two halves: - **Context by navigation, not stuffing.** The agent read-context is built by **navigating** the project's [OKF bundle](shared/examples/bygg-energi-mikro/) (`index.md` + frontmatter + cross-links, progressive disclosure) — never keyword chunk-stuffing (target picture §2/§4). - **Verdict layer gated out of context.** The `type: verdict` layer is excluded from that context; the candidate's prior expert verdicts reach the hypothesis prompt *only* through the gated ExpeL fold (folded in *before* generation), so a prior verdict provably — and exclusively — influences the next hypothesis. - Two load-bearing tests fail when the seam is detached: the realization signal must reach the prompt via the fold (`tests/test_step1_expel_loadbearing.py`), and must never leak via context (`tests/test_okf.py::test_bundle_context_excludes_verdict_layer`). - **Steps 3/4 — checker gates the reasoning (wired).** Two falsifiers now act on the same candidate: the deterministic validator gates the **numbers** (blocking, as before), and the maker-checker's checker gates the **reasoning** (target picture §2/§6). The checker ends its turn with a `VERDICT: APPROVE` / `VERDICT: REJECT — ` line; an explicit reject blocks an otherwise-validated proposal (`run_project` surfaces both debate participants via `output_from=agents` and overrides the outcome to a checker-sourced `Rejection`). The gate is opt-in-reject (fail-open on a missing marker), and `provenance.validator_decision` stays honest — it reflects the validator only, never the checker. Load-bearing: `tests/test_checker_gate_loadbearing.py` goes red on *either* detach (revert `output_from`, or drop the override). - **Step 5 — informed refinement (wired).** The proposer's bounded retry is no longer blind: the validator's *previous* `Rejection.reason` is fed into the next attempt's prompt (`generate.py` `generate_via_llm` → `_build_messages(prior_rejection=...)`), so the model corrects against the falsification instead of re-answering identically (target picture §5/§7). It carries only the most-recent reason (never an accumulated history, never the rejected proposal JSON) and runs under the *existing* `max_attempts` + token-meter cap — no new loop, so "improve until good enough" without a ceiling stays impossible. The only per-attempt falsifier here is the validator; seeding generation with the checker's critique is a run-level, separately-scoped concern and is deliberately not done here. Load-bearing: `tests/test_step5_refine_loadbearing.py` goes red when the reason is detached from the prompt (the outcome never flips *and* the verbatim-reason assertion fails), with a bounded control proving the loop still stops at `max_attempts`. - **Step 7 — async file feedback loop (wired).** `run_project(..., verdict_dir=...)` adds the long feedback timescale (target picture §3/§7): an expert/persona drops a verdict file (plain JSON — the raw output layer, §10 R2) into an inbox folder *after* a run, and a separate, later run ingests it — merged into the store *before* the Step-1 fold — so a verdict that landed out of band reaches the next hypothesis. The loop is fully resumable across runs separated in time; no live session is assumed. The system *reads* the folder, the expert/persona *writes* it (§3 role split), so `run_project` deliberately does **not** persist its own captured verdict back (that is the outbox / Step-8 concern). Ingestion is tolerant (a missing folder, foreign or half-written files are skipped, not raised) and **merges** (never replaces), preserving `run_portfolio`'s cross-project store. Reachable from the CLI via `--bundle-dir --verdict-dir`. Load-bearing: `tests/test_step7_async_loop_loadbearing.py` — a verdict dropped after run A must reach run B's prompt (run B uses a *fresh* store, so the transfer is the file loop, not in-memory carryover), with an empty-inbox control proving causality. - **Step 8 — gated wiki promotion (wired).** When an expert/persona **approves** an outcome, `verdicts.promote_verdict` lifts it from the raw output layer into the context layer (the OKF bundle) as a `type: verdict` concept file, navigable by the next run's `seed_store_from_bundle` (target picture §3/§6/§7). The **gate** is fail-closed: a verdict whose decision is not an approval raises `PromotionRefused` and writes/links nothing — only human/persona-approved knowledge enters the wiki, never raw agent output (self-contamination). The promotion is provenance-stamped (who approved / which experiment / when — `timestamp` is a required keyword, no wall-clock default). The OKF writer lives in `okf.py` and stays pure stdlib (D7-portable, MAF-free). **R4 = optional + gated:** `promote_verdict` is a public opt-in primitive, deliberately **not** wired into `run_project` (mirrors `write_verdict` — the system reads context; the gate/persona promotes). Two honesty limits: the promoted file is *minimal* (it carries the learning signal only as `description`/body prose — it does not reproduce the hand-authored seed's structured `realization_rate` etc.), and because the verdict id is the learning key, two approvals about the same candidate share a filename (last-write-wins, like `write_verdict`) — the wiki grows one curated file per distinct candidate, not per verdict event. Load-bearing trio (`tests/test_step8_promotion_loadbearing.py`): the gate refuses a non-approved verdict (red if the gate is removed), the approved verdict is navigable (red if `link_in_index` is detached), and the promoted signal stays out of `bundle_context` — reaching a prompt only via the gated ExpeL fold (red if a descriptive index label leaks it into the read-context). **Verdict conflict semantics (chosen, minimal).** The in-memory `VerdictStore` is **first-write-wins per verdict id** (a re-ingested duplicate is dropped, so repeated inbox merges are idempotent), while the disk layers — `write_verdict` (inbox authoring) and `promote_verdict` (wiki) — are **last-write-wins per file**. Ids are content-hashes of the candidate *features*, so "same id" means "same candidate measure", not "same verdict event". A full verdict-conflict taxonomy (B10: rejection categories + a rule for conflicting expert verdicts) is deliberately deferred until real domain experts produce conflicting verdicts. ## Offline simulation — the end-to-end proof The loop is proven end to end **offline**, with no real model. `portfolio_optimiser.simulation` drives `run_project` with a **scripted** synthetic chat client (network-free) across two runs separated by a promotion, and shows the learning loop close: Run A produces a validated, persona-approved verdict carrying a realization marker absent from the bundle; `promote_verdict` lifts it into the OKF wiki; a re-seed picks it up; **Run B's hypothesis prompt then carries the marker** (an empty-wiki control on Run A proves causality). Run it: ``` uv run python -m portfolio_optimiser.simulation ``` This is a deliberate, cost-driven substitution for a real-model run (target picture §11 step 8): it proves the plumbing, the deterministic spine, and that the **learning dataflow closes**. It does **not** prove that a live LLM would *produce* the proposal or verdict — those are scripted stand-ins for the swarm and the expert persona (honesty per §1). The scripted client is MAF-side scaffolding, not part of the framework-neutral `shared/` core. Load-bearing: `tests/test_simulation_loadbearing.py` goes red the moment promotion is detached (the marker never crosses into Run B). ## Shared expert-reviewer persona (§8) The expert reviewer is a **framework-neutral Agent Skill** in [`shared/skills/expert-reviewer/`](shared/skills/expert-reviewer/) — a `SKILL.md` persona prompt (the energy-advisor / M&V role, the realization-gap methodology the validator cannot compute) plus a canonical `references/example-verdict.json`. It is the shared artifact both reference implementations consume to instantiate the reviewer; `shared/` stays pure data, so the MAF side reads it via `portfolio_optimiser.persona.load_persona_example` and the Claude-SDK sibling reads the same JSON with its own loader. This **de-stubs the simulation**: its persona judgement (decision + rationale + traced marker) is now sourced from the artifact at call time, not a hardcoded literal — so the shared persona is genuinely consumed and cannot rot silently. The persona's `decision` is binary (`approved` / `rejected`, the feedback contract the run path accepts); the realization correction lives in the rationale prose. Load-bearing trio (`tests/test_persona_skill_loadbearing.py`): structure + framework-neutrality (red on a framework import), the example is valid pipeline input (red on schema/contract drift), and the simulation's marker follows the artifact file (red the moment the persona is re-inlined). ## Docs - [`docs/plan/2026-06-26-maalbilde-agentic-loop.md`](docs/plan/2026-06-26-maalbilde-agentic-loop.md) — target picture: the agentic cost-saving loop + OKF knowledge architecture (north star). - [`docs/research/2026-06-23-prior-art-platform.md`](docs/research/2026-06-23-prior-art-platform.md) — prior-art & platform research (incl. implementation register §15). - [`docs/plan/2026-06-23-incremental-plan.md`](docs/plan/2026-06-23-incremental-plan.md) — incremental delivery plan (deterministic backbone). - [`shared/`](shared/) — framework-neutral shared core (concept + example OKF knowledge bundles + the expert-reviewer persona skill), reused unchanged by both reference implementations. ## Stack Python ≥3.10 · MAF via the split GA packages (`agent-framework-core`, `agent-framework-foundry`, `agent-framework-openai`, `agent-framework-orchestrations` — deliberately **not** the `agent-framework` meta-package; see `pyproject.toml`) · `uv`. Backend profiles: Azure/Foundry (full) + local (fallback). ## Develop ```bash uv sync uv run pytest uv run ruff check . ```