the emperor wears no contacts

it is the future. 

the year 2026. 

so far in the future that 90% of sci fi paperback stories had dates set before now. 

and yet.

and yet every ui related to Contacts on iOS and Android is literally a train wreck. it has been thus since day one of those systems, and they only get worse. 

cps ftw

license: public domain CC0

attn: improved version https://docs.google.com/document/d/19w_P7hPIawRBzRXpBlyuFaFTogdtlFT6ZnqRRJv9vhQ/edit?usp=drivesdk

Project document: Stackless CPS engine for Haskell

1. Vision and goals

Vision:
Build a stackless CPS engine written in Haskell that:

• Executes Haskell programs via a Core→CPS IR pipeline.
• Has no semantic call–return: only one active frame; all “future” is heap data.
• Treats control flow as data: continuations are first-class, mutable, cloneable, serializable.
• Enables:
  • hot-swap and version routing,
  • shadow execution (fork futures),
  • replay / time travel,
  • semantic drift governance,
  • rich introspection and lore.

Key separation:

• Host Haskell (GHC): stackful, classic call–return, used to implement the engine and tooling.
• Guest Haskell: compiled to a Core-like IR, executed by the CPS engine with stackless semantics.

---

2. Architecture overview

2.1 High-level pipeline

1. Haskell source (guest)
2. GHC front-end
   • parse, rename, typecheck
   • desugar to GHC Core
   • run Core-to-Core optimizations
3. Core extraction (plugin/backend)
   • capture Core AST
   • translate to EngineCore (our IR)
4. CPS engine (host Haskell)
   • interpret EngineCore using heap-resident continuations
   • manage scheduling, effects, hot-swap, shadow execution, replay

2.2 Components

• GHC plugin / custom backend

  • Intercepts Core.
  • Serializes or passes it directly to the engine.

• EngineCore IR

  • Small, typed lambda calculus with ADTs and case.
  • Designed for CPS interpretation.

• CPS runtime

  • Machine state (expr, env, cont, meta).
  • Step function (small-step interpreter).
  • Engine loop (schedule–resume, no semantic stack).

• Meta layer

  • Versioning, tracing, effect routing, shadow execution hooks.

---

3. Front-end: GHC integration

3.1 Core interception via plugin

A GHC plugin that captures Core after optimization:

module Plugin (plugin) where

import GhcPlugins

plugin :: Plugin
plugin = defaultPlugin { installCoreToDos = install }

install :: [CommandLineOption] -> [CoreToDo] -> CoreM [CoreToDo]
install _ todos = do
  modGuts <- getModGuts
  let binds = mg_binds modGuts
  liftIO $ writeFile "program.core" (show binds)
  -- Option A: stop compilation here
  pure []

Later iteration: instead of writing to a file, directly call into the engine or serialize a structured format.

3.2 Core → EngineCore translation

Define a Core-like IR:

type Name = String

data EngineExpr
  = EVar Name
  | ELam Name EngineExpr
  | EApp EngineExpr EngineExpr
  | ELet Name EngineExpr EngineExpr
  | EInt Int
  | ECase EngineExpr [Alt]
  | EConstr Name [EngineExpr]
  deriving (Show)

data Alt = Alt ConName [Name] EngineExpr
type ConName = String

Translator skeleton:

ghcCoreToEngine :: GHC.CoreExpr -> EngineExpr
ghcCoreToEngine = go
  where
    go (Var v)      = EVar (occNameString (getOccName v))
    go (Lit (MachInt n)) = EInt (fromIntegral n)
    go (Lam b e)    = ELam (occNameString (getOccName b)) (go e)
    go (App f a)    = EApp (go f) (go a)
    go (Let (NonRec b rhs) body) =
      ELet (occNameString (getOccName b)) (go rhs) (go body)
    go (Case scrut b _ alts) =
      ECase (go scrut) (map goAlt alts)
    go _ = error "unsupported Core form (first pass)"

    goAlt (DataAlt dc, bs, rhs) =
      Alt (occNameString (getOccName dc))
          (map (occNameString . getOccName) bs)
          (go rhs)
    goAlt _ = error "unsupported alt"

---

4. CPS engine: core runtime model

4.1 Values, environments, continuations

data Value
  = VInt Int
  | VClosure Name EngineExpr Env
  | VConstr ConName [Value]
  deriving (Show)

type Env = [(Name, Value)]

data Frame
  = FAppFun EngineExpr Env
  | FAppArg Value
  | FLet Name EngineExpr Env
  | FCase [Alt] Env
  deriving (Show)

type Cont = [Frame]  -- head = next frame

4.2 Meta state

data VersionId = VersionId String
data TraceId   = TraceId String

data MetaState = MetaState
  { msVersion :: VersionId
  , msTrace   :: TraceId
  -- hooks for logging, lore, etc.
  }

4.3 Machine state

data MachineState = MachineState
  { msExpr :: EngineExpr
  , msEnv  :: Env
  , msCont :: Cont
  , msMeta :: MetaState
  }

Exactly one semantic frame is active: (msExpr, msEnv).
All other “future work” is in msCont on the heap.

---

5. CPS interpreter loop

5.1 Engine monad

newtype Engine a = Engine { runEngine :: IO a }
  deriving (Functor, Applicative, Monad, MonadIO)

5.2 Step function

step :: MachineState -> Engine MachineState
step st@MachineState{ msExpr = expr, msEnv = env, msCont = cont } =
  case expr of
    EVar x ->
      case lookup x env of
        Just v  -> continueValue v cont (msMeta st)
        Nothing -> error ("unbound variable: " ++ x)

    ELam x body ->
      continueValue (VClosure x body env) cont (msMeta st)

    EApp f a ->
      pure st { msExpr = f
              , msCont = FAppFun a env : cont
              }

    ELet x e body ->
      pure st { msExpr = e
              , msCont = FLet x body env : cont
              }

    EInt n ->
      continueValue (VInt n) cont (msMeta st)

    EConstr c es ->
      -- naive: evaluate args left-to-right
      case es of
        [] -> continueValue (VConstr c []) cont (msMeta st)
        (e0:rest) ->
          pure st { msExpr = e0
                  , msCont = FAppFun (EConstr c rest) env : cont
                  }

    ECase scrut alts ->
      pure st { msExpr = scrut
              , msCont = FCase alts env : cont
              }

5.3 Continuation handling

continueValue :: Value -> Cont -> MetaState -> Engine MachineState
continueValue v [] meta =
  pure $ MachineState (EInt 0) [] [] meta  -- “done” marker

continueValue v (frame:rest) meta =
  case frame of
    FAppFun arg env ->
      pure $ MachineState arg env (FAppArg v : rest) meta

    FAppArg funVal ->
      case funVal of
        VClosure x body cloEnv ->
          let env' = (x, v) : cloEnv
          in pure $ MachineState body env' rest meta
        _ ->
          error "attempt to call non-function"

    FLet x body env ->
      let env' = (x, v) : env
      in pure $ MachineState body env' rest meta

    FCase alts env ->
      matchCase v alts env rest meta

5.4 Case matching

matchCase :: Value -> [Alt] -> Env -> Cont -> MetaState -> Engine MachineState
matchCase v alts env cont meta =
  case v of
    VConstr c vs ->
      case findAlt c alts of
        Just (Alt _ names body) ->
          let env' = zip names vs ++ env
          in pure $ MachineState body env' cont meta
        Nothing ->
          error "no matching constructor"
    _ ->
      error "case on non-constructor"

findAlt :: ConName -> [Alt] -> Maybe Alt
findAlt c = find (\(Alt c' _ _) -> c' == c)

5.5 Run loop

runMachine :: MachineState -> Engine Value
runMachine st0 = loop st0
  where
    loop st = do
      st' <- step st
      case msCont st' of
        [] -> extractResult st'
        _  -> loop st'

extractResult :: MachineState -> Engine Value
extractResult MachineState{ msExpr = expr, msEnv = env } =
  case expr of
    EInt n -> pure (VInt n)
    _      -> error "non-value at termination"

---

6. Advanced features: where the CPS model shines

Because continuations and machine states are heap data, we can:

6.1 Hot-swap / version routing

• Store VersionId in MetaState.
• At each step, consult a version router to decide:
  • which implementation of primitives to use,
  • which function body to dispatch to (e.g., by name + version).

Hook point: inside step or continueValue, before executing a function body.

6.2 Shadow execution

• Clone MachineState (deep copy of msExpr, msEnv, msCont, msMeta).
• Run:
  • stA under version A,
  • stB under version B.
• Compare results, logs, or effects.

Shadow execution is “fork the future,” not “clone a stack.”

6.3 Replay / time travel

• Periodically snapshot MachineState (or log deltas).
• To replay:
  • restore a snapshot,
  • run forward under new code or different version.

6.4 Semantic drift governance

• When semantics change, traverse msCont and:
  • rewrite frames (e.g., rename functions, adjust environments),
  • migrate data representations,
  • annotate frames with drift metadata.

Because frames are just data, you can patch history.

---

7. Implementation roadmap

1. Phase 1: Minimal engine

   • Implement EngineExpr, Value, Env, Frame, Cont, MachineState.
   • Implement step, continueValue, runMachine.
   • Hand-construct small EngineExpr programs and run them.

2. Phase 2: GHC integration

   • Write a GHC plugin that dumps Core.
   • Implement ghcCoreToEngine for a small subset (ints, lambdas, apps, lets).
   • Run simple Haskell programs on the engine.

3. Phase 3: Extend Core coverage

   • Add ADTs, pattern matching, recursion, basic primitives.
   • Support more Core constructs (case, letrec, etc.).

4. Phase 4: Meta and effects

   • Add MetaState with versioning and tracing.
   • Introduce an Effect layer (IO-like operations via explicit effect nodes).
   • Implement effect routing in the engine.

5. Phase 5: Advanced semantics

   • Hot-swap: version routing for functions and primitives.
   • Shadow execution: state cloning and dual runs.
   • Replay: checkpoints and re-runs.
   • Drift governance: continuation rewriting tools.

6. Phase 6: Tooling and ergonomics

   • CLI or library to compile Haskell → EngineCore → run.
   • Debug views: pretty-print continuations, traces, versions.
   • Optional: GHC plugin that directly invokes the engine for main.

---

This gives you a full, end-to-end story:

• Haskell in → GHC front-end → Core → EngineCore → CPS engine → stackless, mutable-history execution.

---

ADDENDUM

🌟 The “Big Five” features your runtime truly depends on

These are the features that make your hot‑swap / replay / shadow‑execution / version‑routing runtime easy instead of a nightmare of hacks.

1. Semantic closures

Not just syntactic closures — but closures that:

• capture lexical environments predictably
• can be reified or at least reasoned about
• behave deterministically
• don’t hide mutable references in surprising ways

This is the foundation of your entire model.

---

2. Purity (or at least effect isolation)

You don’t need religious purity.
You need semantic purity:

• deterministic functions
• explicit effects
• replayable computations
• serializable state transitions
• no hidden side effects

This is what makes:

• shadow execution
• hot‑swap
• drift detection
• replay
• time travel
• version routing

…possible without black magic.

---

3. First‑class continuations (or CPS‑friendly semantics)

Your runtime is fundamentally:

• continuation‑driven
• checkpoint‑driven
• resumable
• hot‑swappable
• replayable

You don’t need full call/cc, but you do need:

• the ability to reify the “rest of the computation”
• or to structure the runtime so that the stack is already in the heap

This is why your “no real stack, only semantic frames” idea is so powerful.

---

4. Structured concurrency / actor‑style isolation

Your runtime wants:

• tasks as independent semantic units
• message passing
• supervision trees
• restartability
• deterministic scheduling (or at least observable scheduling)

This is what makes:

• shadow execution of tasks
• version‑routed execution
• hot‑swap of individual tasks
• replay of task histories

…tractable.

---

5. A type system that can express effects, capabilities, or at least “what this function touches”

This doesn’t have to be Haskell‑level purity.
It can be:

• algebraic effects
• effect rows
• capabilities
• linear types
• region types
• ownership types
• or even a disciplined annotation system

But you need some way to know:

• what a function reads
• what it writes
• what it depends on
• what it captures
• what it can be safely swapped with

This is essential for:

• drift detection
• safe hot‑swap
• shadow execution
• replay correctness
• version routing

---

🌱 Secondary but still important features

These aren’t strictly required, but they make your life dramatically easier.

6. Immutable data structures as the default

Because:

• snapshots become trivial
• diffs become trivial
• replay becomes trivial
• shadow execution becomes trivial

7. Pattern matching / algebraic data types

Because your runtime manipulates:

• semantic frames
• effect logs
• versioned closures
• task states

…and ADTs make this clean.

8. Tail‑call friendliness

Not for performance —
but because your runtime is fundamentally CPS‑shaped.

9. A runtime that doesn’t hide too much

Languages like Java, Go, and Python hide:

• stack frames
• scheduling
• GC timing
• object layout
• closure representation

This makes your runtime harder to implement.

Languages like:

• Haskell
• OCaml
• Scheme
• Racket
• Clojure
• Rust (with some work)

…give you more control.

---

🎯 The crisp answer to your question

If closures were the only requirement, you could port the runtime anywhere.
But closures are only 1 of the 5 essential features.

The full set is:

1. Semantic closures
2. Purity / effect isolation
3. Continuation‑friendly semantics
4. Structured concurrency
5. Effect‑expressive type system

These five together make your runtime natural instead of forced.

---

haskell ftw

license: public domain CC0

i have long dreamed of what purity could bring to versioning of software. 

attn: the details below were handwaving. here are some refinements to be slightly less wrong: https://claude.ai/public/artifacts/0f516820-88f3-4ade-a7c4-6c8b34e41bdd

________________________________

📘 A Runtime Where CPS, Erlang, Haskell, and Shared Memory Had a Baby

Design Memo: Motivation → Problem Space → Ideal Model → Reality →
Lessons → Architecture → Game Plan → Example

________________________________

1. Motivation

Modern systems must evolve continuously:

deploy new code without restarting the world
run old and new versions side‑by‑side
shadow‑test new logic
replay tasks to debug hard‑to‑reproduce bugs
inspect state and control flow
isolate failures
maintain performance

Existing languages give you fragments of this vision:

Haskell gives purity, replayability, and typed effects
Erlang gives supervision, isolation, and hot‑swap
CPS gives explicit, inspectable control flow
Shared memory gives performance

But no single runtime gives you all of these together.

We want a system where:

writing version 1 feels like normal programming
version 2 can be shadow‑tested without code changes
debugging is “replay + swap,” not “sprinkle logs + redeploy”
the engine stays out of your way until you need it
the engine becomes powerful and interactive when you do

________________________________

2. Problem Space

2.1 Hidden state

Most languages hide state in:

closures
stacks
mutable objects
runtime internals

Hidden state breaks:

replay
hot‑swap
debugging
determinism

2.2 Unstructured concurrency

Async/await, threads, callbacks → tasks that cannot be:

paused
serialized
inspected
replayed

2.3 Tight coupling between code and runtime

Most languages assume:

one version of code
one global heap
no routing
no versioning

2.4 Library ecosystems

Real apps need:

HTTP
DB
crypto
cloud SDKs

These are impure and not replayable.

2.5 Serialization boundaries

Crossing process/FFI/microservice boundaries means:

schemas
serialization
versioning
impedance mismatch

This is the tax you pay for isolation.

________________________________

3. Abstract Goals

3.1 Explicit, serializable state

All meaningful state is:

pure
versioned
serializable
replayable

3.2 Reified tasks

All work is:

first‑class
inspectable
resumable
replayable
routable

3.3 Typed effects

Effects are:

explicit
typed
isolated
mockable
replay‑aware

3.4 Hot‑swap as a primitive

The runtime supports:

multiple versions of code
routing policies
draining
shadow execution
replay into new versions

3.5 Supervision and isolation

Processes are:

isolated
supervised
restartable

3.6 Shared memory where safe

Shared memory is:

explicit
capability‑based
optionally linear
STM‑backed

3.7 A principled core SDK

The language provides:

strings
collections
time
serialization
concurrency primitives
effect types

________________________________

4. High‑Level Design in an Ideal World

4.1 Pure state + event sourcing

State is:

State = fold(Event)

Events are:

append‑only
versioned
typed

4.2 Reified CPS‑style tasks

A task is:

data Task = Task
  { taskId       :: TaskId
  , continuation :: Continuation
  , mailbox      :: [Message]
  , history      :: [Event]
  }

The runtime can:

pause
serialize
resume
replay
shadow
migrate tasks

4.3 Erlang‑style processes

Each task runs in a supervised process with:

mailbox
restart strategy
versioned code
routing rules

4.4 STM‑style shared memory

Global or sharded state lives in:

TVar WorldState

4.5 Typed effects

Effects are declared like:

effect HttpGet :: Url -> HttpResponse
effect Now     :: Time
effect Random  :: Int -> Int

4.6 Multi‑process hot‑swap

When new code arrives:

Spin up a new process tree
Replay state/events into it
Route new tasks to it
Drain old tasks
Kill old version

________________________________

5. Reality: Nothing Is Ideal

5.1 Library ecosystems

You can’t rewrite DB drivers or cloud SDKs.

5.2 Serialization tax

Crossing process boundaries is unavoidable.

5.3 Hot‑swap complexity

You must handle:

in‑flight tasks
schema evolution
draining
replay failures

5.4 Debugging distributed processes

You need:

tracing
unified logs
task histories

5.5 Performance tradeoffs

Reified tasks and event logs cost memory and CPU.

________________________________

6. Which Approach Is Least Wrong?

Option A — Build on a dynamic language

❌ Hidden state, no replay, no typed effects.

Option B — Build a new language + runtime

❌ Impossible library ecosystem.

Option C — Build an EDSL inside Haskell

✅ Purity
✅ STM
✅ Typed effects
✅ Replayability
✅ Strong compiler
❌ Hot‑swap requires multi‑process orchestration
❌ FFI still needed

This is the least wrong option.

________________________________

7. Lessons From Other Systems

Erlang/Elixir

supervision
hot code upgrades
message passing

Haskell

purity
STM
typed effects

CPS languages

explicit continuations

Unison

code as data
versioned definitions

Cloud Haskell

distributed processes

Akka

actor supervision

________________________________

8. Putting It All Together: The Layered Model

Layer 1 — App Code (developer writes this)

Feels like normal Haskell:

handleRequest :: Request -> AppM Response
lookupUser    :: UserId -> AppM User
listItems     :: UserId -> AppM [Item]

Layer 2 — Router (developer registers functions)

routes :: Router AppM
routes =
  register "handleRequest" handleRequest
    <> register "lookupUser" lookupUser
    <> register "listItems"  listItems

Layer 3 — Engine Runtime (framework provides this)

task manager
process registry
supervision
version routing
event log
replay
hot‑swap

Layer 4 — Multi‑Process Orchestrator

runs version N and version N+1
routes traffic
drains old version
replays tasks
kills old version

________________________________

9. Concrete Haskell Types

9.1 App Monad

newtype AppM a = AppM
  { unAppM :: ReaderT Env (TaskM) a
  } deriving (Functor, Applicative, Monad)

9.2 Task Monad (reified CPS)

data TaskF next
  = Log Text next
  | Send ProcessId Message next
  | Receive (Message -> next)
  | GetTime (Time -> next)
  | ReadState (State -> next)
  | WriteState State next
  deriving Functor

type TaskM = Free TaskF

9.3 Router

data Version = Version Text  -- e.g. "v1", "v2"

data RoutingPolicy
  = Primary Version
  | Shadow Version Version
  | Percent Version Version Int  -- percent for candidate

data Router m = Router
  { routes :: Map Text (Map Version (DynamicFunction m))
  , policies :: Map Text RoutingPolicy
  }

9.4 Engine Entry Point

runEngine :: EngineConfig -> Router AppM -> IO ()

________________________________

10. End‑to‑End Example

Step 1 — Developer writes v1 code

handleRequest :: Request -> AppM Response
handleRequest req = do
  user  <- lookupUser (reqUserId req)
  items <- listItems (userId user)
  pure (renderPage user items)

Step 2 — Register v1 routes

routesV1 :: Router AppM
routesV1 =
  register "handleRequest" handleRequest
    <> register "lookupUser" lookupUser
    <> register "listItems"  listItems

Step 3 — Deploy v1

main = runEngine defaultConfig routesV1

Everything feels like normal Haskell.

________________________________

Step 4 — Developer writes v2 of one function

lookupUserV2 :: UserId -> AppM User
lookupUserV2 uid = do
  logInfo ("lookupUserV2 called with " <> show uid)
  lookupUser uid  -- call v1 internally

Step 5 — Register v2

routesV2 =
  register "lookupUser" lookupUserV2

Step 6 — Shadow test v2

Config:

functions:
  lookupUser:
    routing:
      mode: shadow
      primary: v1
      shadow: v2

Engine behavior:

v1 handles the real request
v2 runs in parallel
engine compares outputs
engine logs divergences

Developer writes no new code.

________________________________

Step 7 — Debug a hard‑to‑reproduce bug

Capture failing task abc123

Replay it:

engine task replay abc123

Switch only lookupUser to debug version:

engine route set lookupUser --task abc123 --version debug

Replay again and inspect logs.

No redeploy.
No code changes.
No global logging.

________________________________

11. The Game Plan

Phase 1 — Core EDSL

TaskF, TaskM, typed effects
CPS‑friendly continuation model

Phase 2 — Runtime

process registry
mailboxes
STM‑backed world state
supervision

Phase 3 — Router + Versioning

versioned functions
routing policies
shadow execution

Phase 4 — Event Log + Replay

append‑only log
replay engine
divergence detection

Phase 5 — Multi‑Process Hot‑Swap

orchestrator
drain protocol
replay protocol
version migration

Phase 6 — Core SDK

strings, collections, time
serialization
effect wrappers

Phase 7 — Tooling

task inspector UI
event log viewer
routing dashboard
replay debugger