We present Loom, a computer architecture that executes programs compiled from C inside a looped transformer whose weights are derived analytically. The architecture implements a 22-opcode instruction set in 8 transformer layers. Each forward pass executes one instruction; the model is applied iteratively until the program counter reaches zero. The full machine state resides in a single tensor X∈Rd×n of fixed size, and every step has fixed cost for fixed d and n, independent of program length or execution history. The default configuration uses d=155 and n=1024, yielding 4.7 million parameters and 928 instruction slots. A compact configuration at d=146 and n=512 suffices for a 9×9 Sudoku solver (284 instructions). The weights are program-independent: programs live in the state tensor, and the same fixed-weight model executes any compiled program. We make Loom source code publicly available at https://github.com/mkturkcan/Loom.
Cite
@article{arxiv.2604.08816,
title = {Loom: A Scalable Analytical Neural Computer Architecture},
author = {Mehmet Kerem Turkcan},
journal= {arXiv preprint arXiv:2604.08816},
year = {2026}
}