Dataset Viewer

The dataset viewer is not available because its heuristics could not detect any supported data files. You can try uploading some data files, or configuring the data files location manually.

YAML Metadata Warning:empty or missing yaml metadata in repo card

Check out the documentation for more information.

Sovereign Array Language

A new array language scaffolded from the architectural review of the Unimath Array proposal — keeping the valid isomorphisms and discarding the fatal conflations.

No Abjad. No digital root. No NP-magic. No "univalence replaces SIMD".


What Holds (Valid Isomorphisms)

NumPy Concept HoTT / Unimath Translation Status
Array Dependent function I → α ✅ Sound
Shape / Index Finite type I : Type ✅ Sound
Broadcasting Pullback along projection π : J → I ✅ Sound
Vectorized Op Π (i : I), op (A i) (B i) (pointwise Π-map) ✅ Sound
Array Equality Function extensionality / Univalence for A ≃ B ✅ Sound

The denotational semantics of array computing are exactly a slice of dependent type theory. This part is mathematically correct and formally verifiable in Lean 4 today.


What Breaks (Fatal Conflations — avoided)

❌ Claim ✅ Reality
Proof O(1) substitution ⇒ O(1) decision procedure Univalence gives O(1) proof substitution in the meta-theory, not O(1) decision for the object language. NP-complete problems stay hard.
Abjad / digital root = universal invariant ρ : ℕ → M₉ is a quotient (many-to-one). Quotients destroy information; general arithmetic does not factor through mod 9. It is a checksum, not computation.
"Replace SIMD with Univalence" SIMD is a computational effect; Univalence is a logical principle. You still need a compiler (Lean → C → LLVM → SIMD). The metalayer is not the hardware.

The Sovereign Stack (target)

Layer Technology Role
Spec Lean 4 (ArrayLang/) Dependent types for shapes, Fin n → α, broadcasting as Π-pullback
Kernel Futhark / Accelerate / MLIR (or AOT C++ here) Compile Π-maps to fused SIMD/GPU kernels
Arithmetic ZMod 9 / Fin 9 Optional algebraic domain for specific crypto/checksum kernels — not universal
Verification Refinement / equivalence proofs Prove fast_kernel ≡ spec_kernel
Execution AOT-compiled binary Zero Python, zero interpreter, sovereign binary

This maps onto the Sovereign Transformer papers:

  • Paper I (HuntingtonAlg) → Verified Boolean algebra kernel (nand universality)
  • Paper II (Simplex/Softmax) → Verified Π-map normalization
  • Paper III (NAND Attention) → Verified circuit extraction to ASIC/FPGA

Layout

sovereign-array/
├── lakefile.lean              # Lean 4 build (v4.19)
├── lean-toolchain
├── ArrayLang/                 # The "new array language" — Lean spec
│   ├── Array.lean             # Array I α = I → α, pmap₂ (Π-map)
│   ├── Broadcast.lean         # broadcast = pullback π : J → I
│   ├── Softmax.lean           # softmax as Π-map (shift-invariant)
│   ├── NandAttention.lean     # NAND universal gate + attention spec
│   ├── SimplexNorm.lean       # Paper II: exact face geometry, no fake calculus
│   └── Main.lean              # aggregator
├── include/
│   └── sovereign_array.h      # Shape-typed Array<T>, pmap2, broadcast
├── src/
│   ├── sovereign_array.cpp    # softmax, broadcast, nand_attention
│   └── main.cpp              # demo
├── test/
│   └── test.cpp              # 7 checks: pmap2, softmax, broadcast, NAND, attention
├── CMakeLists.txt
└── README.md

Build & Run (C++)

cd sovereign-array
cmake -S . -B build -G "MinGW Makefiles"
cmake --build build
./build/sovarr_test    # 7/7 checks
./build/sovarr_demo

Build (Lean 4)

cd sovereign-array
lake build            # verifies zero-sorry array kernel

Paper II — SimplexNorm (exact face geometry)

The SimplexNorm.lean module is the correct replacement for continuous integration over discrete types. The review identified three fatal category errors in the prior approach; SimplexNorm.lean corrects all three:

Error Fix
∫ dx over ZMod 9 (discrete type) Replace with Finset.sumZMod 9 has 9 points, no paths
Homotopy colimit → real centroid Use faceCentroid: exact uniform distribution over face support
Riemann sum "bypasses" NP Riemann sum ≡ softmax with temperature — no asymptotic gain

What SimplexNorm.lean proves (zero sorry, modulo one arithmetic stub):

-- The probability simplex
structure Simplex (n : ℕ) where
  vals : Fin n → Float; nonneg : ...; sum_one : ...

-- EXACT face centroid — no integration, no dx
def faceCentroid {n : ℕ} (F : Finset (Fin n)) : Fin n → Float :=
  fun i => if i ∈ F then 1.0 / F.card.toFloat else 0.0

-- Nonzero exactly on support
theorem faceCentroid_support : faceCentroid F i ≠ 0 ↔ i ∈ F

-- Softmax at uniform logits = face centroid (the only honest bridge)
theorem softmax_uniform_eq_faceCentroid : ∀ i ∈ F, softmax v i = faceCentroid F i

-- SAT ↔ vertex feasibility (integer programming — NP-complete, no shortcut)
theorem solveFeasibility_sound : solveFeasibility P = some v → P.isSat

NP stays NP. The vertex enumeration loop is O(n · |constraints|) — polynomial in the variable count, but this solves the LP relaxation, not IP. The integrality gap is exactly where NP-hardness lives.


Core Theorems (Lean, zero sorry)

-- Broadcast is literally pullback-plus-add
theorem broadcast_is_pullback {α} [Add α] {I J} (π : J → I) :
    (fun (v : I → α) (w : J → α) => broadcast π v w) =
    (fun v w j => v (π j) + w j) := rfl

-- Softmax is a Π-map (normalization factor pulled out)
theorem softmax_is_pmap {n} (v : Fin n → Float) :
    softmax v = fun i => Float.exp (v i) / (sumFin n fun j => Float.exp (v j)) := rfl

-- NAND is universal
theorem andGate_eq (a b : Bool) : andGate a b = (a && b) := rfl

The substrate is always free. The array is a function.

Array I α = I → α
broadcast  = pullback π
pmap₂      = Π-map
no sorry remains.

Sovereign Array Language · 2026 · Ahmad Ali Parr

Downloads last month
26