Files

giles 9dd9fb9c37 plans: layered-stack framing + chisel sequence + loop scaffolding

Design + ops scaffolding for the next phase of work, none of it touching
substrate or guest code.

lib-guest.md: rewrites Architectural framing as a 5-layer stack
  (substrate → lib/guest → languages → shared/ → applications),
  recursive dependency-direction rule, scaled two-consumer rule. Adds
  Phase B (long-running stratification) with sub-layer matrix
  (core/typed/relational/effects/layout/lazy/oo), language profiles, and
  the long-running-discipline section. Preserves existing Phase A
  progress log and rules.

ocaml-on-sx.md: scope reduced to substrate validation + HM + reference
  oracle. Phases 1-5 + minimal stdlib slice + vendored testsuite slice.
  Dream carved out into dream-on-sx.md; Phase 8 (ReasonML) deferred.
  Records lib-guest sequencing dependency.

datalog-on-sx.md: adds Phase 4 built-in predicates + body arithmetic,
  Phase 6 magic sets, safety analysis in Phase 3, Non-goals section.

New chisel plans (forward-looking, not yet launchable):
  kernel-on-sx.md       — first-class everything, env-as-value endgame
  idris-on-sx.md        — dependent types, evidence chisel
  probabilistic-on-sx.md — weighted nondeterminism + traces
  maude-on-sx.md        — rewriting as primitive
  linear-on-sx.md       — resource model, artdag-relevant

Loop briefings (4 active, 1 cold):
  minikanren-loop.md, ocaml-loop.md, datalog-loop.md, elm-loop.md, koka-loop.md

Restore scripts mirror the loop pattern:
  restore-{minikanren,ocaml,datalog,jit-perf,lib-guest}.sh
  Each captures worktree state, plan progress, MCP health, tmux status.
  Includes the .mcp.json absolute-path patch instruction (fresh worktrees
  have no _build/, so the relative mcp_tree path fails on first launch).

Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>

2026-05-08 22:27:50 +00:00

7.1 KiB

Raw Blame History

Kernel-on-SX: first-class everything

The natural successor to SX's recently-completed env-as-value work (sx-improvements Phase 4). Kernel — John Shutt's reformulation of Lisp from his 2010 PhD — pushes first-class all the way: environments, evaluators, special forms (operatives), lambda variants are all runtime values, manipulable by programs. SX already has env-as-value; Kernel is what env-as-value looks like all the way.

The chisel: reflection. Every language in the current set treats some part of itself as fixed and ineffable — Common Lisp's special forms, Erlang's process model, OCaml's modules. Kernel reifies more of itself than any other language does. Implementing it stresses the substrate's self-knowledge: which parts of evaluation does SX expose to user programs, and which stay opaque?

What this exposes about the substrate:

Whether eval-expr can be called as a primitive on user-supplied environments without breaking invariants.
Whether CEK frames can be reified as values (they currently aren't).
Whether special-form dispatch can be table-driven and user-extensible at runtime.
Whether the macro hygiene story extends to Shutt's "hygienic operatives" (operatives that don't capture).

End-state goal: Kernel's R-1RK core — $vau/$lambda/wrap/unwrap, first-class environments, the applicative–operative distinction, the standard environment, encapsulations.

Ground rules

Scope: lib/kernel/** and plans/kernel-on-sx.md only. Substrate work belongs to sx-improvements.md — if a feature is missing, file it there, don't fix from this plan.
Consumes from lib/guest/: core/lex.sx, core/pratt.sx (s-expression-shaped, minimal demand), core/ast.sx, core/match.sx.
May propose a new sub-layer lib/guest/reflective/ — environment reification helpers, applicative-vs-operative dispatch, evaluator continuation protocols. A second consumer would be needed; candidates are a hypothetical "MetaScheme" or a Common-Lisp port that exposes its evaluator.
Branch: loops/kernel. Standard worktree pattern.

Architecture sketch

Kernel source text (S-expression syntax)
    │
    ▼
lib/kernel/parser.sx       — bog-standard s-expr reader
    │
    ▼
lib/kernel/eval.sx         — kernel-eval: walks the AST, threads first-class env
    │                        dispatches to operatives via env-bound bindings, not
    │                        a hardcoded switch
    ▼
lib/kernel/runtime.sx      — applicative/operative tagged values, wrap/unwrap,
    │                        standard environment construction, encapsulations
    ▼
SX CEK evaluator

Semantic mappings

Kernel construct	SX mapping
`($lambda (x) body)`	applicative: `(make-applicative (fn (x) body))` — args evaluated
`($vau (x) e body)`	operative: `(make-operative (fn (x e) body))` — args UN-evaluated, dynamic env passed as `e`
`(wrap op)`	applicative wrapping an operative: evaluate args, then call op
`(unwrap app)`	get the underlying operative of an applicative
`($define! x v)`	operative: bind `x` to `v` in dynamic env
`(eval expr env)`	call `kernel-eval` on `expr` in `env` — first-class
`(make-environment)`	fresh empty env
`(get-current-environment)`	reify the calling env (via SX env-as-value)
`($if c t e)`	operative: evaluate `c`, then `t` or `e` in dynamic env

The whole interesting thing: there are no special forms hardcoded in the evaluator. $if, $define!, $lambda are all operatives bound in the standard environment. User code can rebind them. The evaluator is just lookup-and-call.

Roadmap

Phase 1 — Parser

S-expression reader with the standard atoms (number, string, symbol, boolean, nil) and lists.
Reader macros optional; defer to Phase 6.
Tests in lib/kernel/tests/parse.sx.

Phase 2 — Core evaluator with first-class environments

kernel-eval expr env — primary entry, walks AST, threads env as a value.
Symbol lookup → environment value (using SX env-as-value primitives).
List → look up head, dispatch on tag (applicative vs operative).
No hardcoded special forms — even if/define/lambda are env-bound.
Tests in lib/kernel/tests/eval.sx.

Phase 3 — `$vau` / `$lambda` / `wrap` / `unwrap`

Operative tagged value: {:type :operative :params :env-param :body :static-env}.
Applicative tagged value wraps an operative + the "evaluate args first" contract.
$vau builds operatives; $lambda is wrap ∘ $vau.
wrap / unwrap round-trip cleanly.
Tests: define a custom operative, define a custom applicative on top of it.

Phase 4 — Standard environment

Standard env construction: bind $if, $define!, $lambda, $vau, wrap, unwrap, eval, make-environment, get-current-environment, plus arithmetic and list primitives.
Tests: classic Kernel programs (factorial, list operations, environment manipulation).

Phase 5 — Encapsulations

make-encapsulation-type returns three operatives: encapsulator, predicate, decapsulator. Standard Kernel idiom for opaque types.
Tests: implement promises, streams, or simple modules via encapsulations.

Phase 6 — Hygienic operatives (Shutt's later work)

Operatives that don't capture caller bindings — uses scope sets / frame stamps to track provenance.
Bridge to SX's hygienic macro story; possibly extends lib/guest/reflective/ with hygiene primitives.
Tests: write an operative that introduces a binding and verify it doesn't shadow caller's same-named bindings.

Phase 7 — Propose `lib/guest/reflective/`

Once Phase 3 lands and stabilises, identify which env-reification + dispatch primitives are reusable. Candidate API: make-operative, make-applicative, with-current-env, eval-in-env.
Find a second consumer (Common-Lisp's macro-expansion evaluator? a metacircular Scheme variant? a future plan).
Only extract once two consumers exist (per stratification rule).

lib/guest feedback loop

Consumes: core/lex, core/pratt, core/ast, core/match.

Stresses substrate: env-as-value (Phase 4 of sx-improvements) under heavy use; eval as a primitive on user environments; potentially CEK frame reification.

May propose: lib/guest/reflective/ sub-layer — environment manipulation, evaluator-as-value, applicative/operative dispatch protocols.

What it teaches: whether SX's recent env-as-value direction generalises to "evaluator-as-value." If Kernel implements cleanly in <2000 lines, env-as-value is real. If it requires substrate fixes at every turn, env-as-value was incomplete and the substrate is telling us what's missing.

References

Shutt, "Fexprs as the basis of Lisp function application" (PhD thesis, 2010).
Kernel Report (R-1RK): https://web.cs.wpi.edu/~jshutt/kernel.html
Klisp implementation (Andres Navarro) — pragmatic reference.

Progress log

(awaiting Phase 1 — depends on stable env-as-value substrate state)

Blockers

(none yet — main risk is substrate gap discovery during Phase 2)

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