The composition DAG is not a content mechanism; render is fold #1. The same structure (content-addressed objects + ordered labelled forks + seq/par/alt/each) is interpreted by a different fold per domain: content=render, behaviour=execute (flow-on-sx), query=eval (Datalog), pipeline=reduce (artdag, literally a content-addressed composition DAG), types=extent (and/or = intersection/union). "Relations just a fork" generalises: relation kind + fold = domain. The X-on-sx loops already ARE these folds — the composition DAG is the fleet convergence point. Payoff: build composition once, reuse per domain via interpreters; the block editor + metamodel UI generalise to every fold (author a workflow like a document). System collapses to four ideas: content-addressed objects + composition algebra + per-domain folds + decidable-core predicates. Roadmap +2: prove universality with a second (execute) fold over the same seq/alt/each; then factor out the shared compose core. Co-Authored-By: Claude Opus 4.8 <noreply@anthropic.com>
8.1 KiB
Composition objects — a content-addressed, data-driven UI model
Everything the system stores is an object: typed, content-addressed (:cid), in one graph.
"Post" was the blog's word; the unit is an object. A document is an object whose body is a
composition over other objects' CIDs. This is the cards-as-objects decision, generalised.
One mechanism: ordered, labelled forks
An object forks into children via labelled, ordered edges (the relations engine + order on
the edge value + an optional when). There is no separate "composition system" — relations are
the forks. The label says what a fork means:
- structural (
contains) → ordered, part of identity, rendered; - cross-cutting (
tagged,related,author) → loose links, not structural.
Multiple relations from an object are its fork. No "multiple DAGs per object" — fork immediately;
differently-labelled forks (body vs aside) give named slots. Join = a child CID referenced
by two forks — free, because content-addressed. The whole structure is a Merkle DAG (git trees
/ IPFS / artdag): :cid = hash over fields + contains-forks (child-CID + order + when).
The body is a tiny UI language (the render-fold is its interpreter)
A body is a composition node. Four combinators + leaves + references:
| node | meaning | strategy |
|---|---|---|
(seq …) |
sequence | render all (block), in order |
(row …) / (grid …) |
layout (par) | render all, side-by-side |
(alt (when P n) … (else n)) |
conditional (or) | render the FIRST child whose when holds |
(each src tmpl) |
iteration (loop) | eval src → items; render tmpl per item (item bound) |
(ref CID) |
transclude | fetch object by CID, render its body |
(card TYPE fields) |
leaf | render via the card-type's :template (host/blog--instantiate) |
(tmpl NAME) |
recursion | a named template, may reference itself |
seq/row = render-all passing children; alt = render-first passing child. So and/or/choice
all come from one axis (when on forks) × the container's all/first strategy — Alt isn't a new
node kind, it's "first" instead of "all".
The two fundamentals we designed IN
- Recursion —
(tmpl NAME)may reference itself;(each (children) (tmpl NAME))renders trees (comment threads, nested nav, the/metatype hierarchy itself). Terminates naturally when a query runs dry; a depth guard in the context backstops it. - The context is an environment, not a flat dict.
whenreads it;eachextends it (:item). Make it extensible + reactive-ready and the two non-composition axes plug in with NO new combinators:- Behaviour / interactivity (Slice 9 lifecycles/effects) — a button references a behaviour;
- Reactivity / local state (the reactive runtime) —
alt(when local-state=active-tab)is a tabset,alt(when accordion-open)an accordion; a liveeachre-renders on data change. The static render-fold becomes a live, interactive UI purely by making the context live.
The unifying property
The object's CID is its definition (the query, the template, every when-variant). The
rendering is the execution (which items, which branch, which context). The object is the
program; the render is the run. One immutable content-addressed object encodes its whole
responsive/personalised/variant space; rendering picks the path. Render-fold and the Slice-9
behaviour interpreter are the same shape — interpreters over content-addressed objects + the
decidable-core predicate set + the graph. The system converges on: objects + small interpreters.
Beyond content — composition is universal; a fold per domain
The render-fold isn't "the content renderer" — it's fold #1. The composition DAG is a
universal algebra (seq/par/alt/each over content-addressed objects); content is just one
interpretation. Same structure, a different fold per domain — what changes is what the
combinators and leaves mean:
| domain | the fold | seq |
par |
alt+when |
each |
substrate |
|---|---|---|---|---|---|---|
| content | render → HTML | block order | layout/columns | choose variant | map items | compose.sx (done) |
| behaviour | execute → effects | steps in order | concurrent | branch (if/cond) | for-each | [[project_flow_on_sx]] |
| query | eval → results | join/chain | union | conditional | iterate/quantify | [[project_relations_on_sx]] (Datalog) |
| pipeline | reduce → data | dataflow stages | parallel ops | choose path | fan-out | [[project_artdag_on_sx]] (content-addressed DAG) |
| types | extent → set | — | ∧ intersection | — | ∨ union | the type algebra (make-and!/make-or!) |
So "relations just a fork" generalises: a contains fork folded by render is a document; a
then fork folded by execute is a workflow step; a depends-on fork folded by eval is a
dependency graph. The relation kind + the fold = the domain. This isn't aspirational — the
repo's X-on-sx loops ALREADY ARE these folds (flow = execute, Datalog = eval, artdag = a
content-addressed composition DAG); we just hadn't seen them as one shape. The composition DAG is
the convergence point the whole fleet has been circling.
The payoff is concrete: build the composition machinery ONCE (forks + ordered edges + the four
combinators + a fold framework) → reuse for every domain by writing one interpreter. The block
editor edits any composition — author a workflow like a document, same structure, one editor.
The whole system collapses to four ideas: content-addressed objects + a composition algebra +
per-domain folds + the decidable-core predicates (when). The render-fold's shape (walk the
composition, dispatch combinators, recurse, read the context) is the template for every other fold.
What lives elsewhere (not composition primitives)
Transclusion = a ref leaf. Sort/filter/limit/group = the source query language (Datalog).
each reconciliation keys = the item's CID (free). Empty / missing-CID = render-fold robustness
(the per-block guard). Async/streaming, events, local state = the behaviour + reactive axes.
Build roadmap
- Keystone (this):
lib/host/compose.sx— the render-fold interpreter over seq/row/alt/each/ ref/card/tmpl, with the context-as-environment,whenpredicates, and recursion + depth guard. Self-contained proof: render one composed object two ways (auth on/off) + a recursive tree. - Wire it to objects: a document's
:bodyis a composition node;containsforks carry order;host/blog-renderdispatches to the render-fold when:bodyis present (else the legacysx_contentpath). Card leaves render via the existing card-type:template. eachsource = a graph query ((query is-a Event)→host/blog-instances-of) — data-driven.- Live context: route auth/device/locale into the context; reactive values later.
- The typed importer decomposes Ghost Lexical into card objects + a
containsbody (cards-as- objects), instead of onesx_contentstring. - The block editor edits the body (insert/reorder/
alt/each) — the metamodel editor for content. - Prove universality with a second fold. Write a tiny
execute-fold over the sameseq/alt/eachstructure that runs a workflow (leaves = effects;seq= steps in order,alt= branch,each= for-each) — the way the recursive tree proved recursion, this proves the composition algebra is domain-agnostic. Then the behaviour model (Slice 9) is "anexecute-fold over a composition object", not a separate system. - Factor out the shared machinery once two folds exist: the fork model (ordered, labelled,
when), the combinator dispatch, the context-environment, and recursion become a reusablecomposecore; each domain (render,execute,eval, …) supplies only its leaf + combinator semantics. The block editor + the metamodel UI then generalise to every fold — one composition editor authors documents, workflows, queries, and pipelines alike.