From ai-and-reasoning
Executes programs on a compiled transformer stack machine where attention heads implement instruction fetch and memory read. Use for running/tracing programs on the transformer executor or discussing LLM-as-computer concepts.
How this skill is triggered — by the user, by Claude, or both
Slash command
/ai-and-reasoning:llm-as-computerThe summary Claude sees in its skill listing — used to decide when to auto-load this skill
A working computer built from transformer primitives. Every instruction fetch and stack read
A working computer built from transformer primitives. Every instruction fetch and stack read is a parabolic attention head (dot-product → argmax → value extraction). The transformer's weights ARE the interpreter — compiled analytically, not trained.
Attention is lookup; feed-forward is routing. A vanilla transformer with compiled weights can execute arbitrary programs: loops, recursion, arithmetic, memory access. 55 opcodes covering WASM i32 semantics. 21M+ steps/second via the Mojo executor.
cd /mnt/skills/user/llm-as-computer/src && bash setup.sh
This installs Mojo (~20s) and compiles the executor binary (~6s). If Mojo is unavailable, the skill falls back to a pure-Python executor (slower but functional).
import sys
sys.path.insert(0, '/mnt/skills/user/llm-as-computer/src')
from programs import make_fibonacci, make_factorial, make_gcd, make_multiply
from runner import run, setup
# Ensure Mojo is compiled (idempotent)
setup()
# Run a program — shows instructions, trace, result
prog, expected = make_fibonacci(10)
print(run(prog))
# Benchmark mode — measures throughput
print(run(prog, benchmark=True, repeat=200))
From programs.py — all return (program, expected_result):
| Generator | Description | Example |
|---|---|---|
make_fibonacci(n) | Iterative fib via SWAP+OVER+ADD+ROT | fib(10)=55, 111 steps |
make_multiply(a, b) | Repeated addition | mul(7,8)=56 |
make_factorial(n) | Loop with MUL | fact(8)=40320 |
make_gcd(a, b) | Euclidean algorithm | gcd(48,18)=6 |
make_power_of_2(n) | Repeated doubling | 2^7=128 |
make_sum_1_to_n(n) | Accumulation loop | sum(15)=120 |
make_is_even(n) | Parity check | is_even(7)=0 |
make_native_multiply(a,b) | Single MUL opcode | |
make_native_divmod(a,b) | DIV_S + REM_S | |
make_compare_binary(op,a,b) | eq/ne/lt_s/gt_s/le_s/ge_s | |
make_bitwise_binary(op,a,b) | and/or/xor/shl/shr_u/rotl/rotr | |
make_select(a,b,c) | Conditional select |
from isa_lite import program
# Assembly tuples
prog = program(
('PUSH', 10),
('PUSH', 20),
('ADD',),
('DUP',),
('ADD',), # (10+20)*2 = 60
('HALT',),
)
print(run(prog))
# Loops: countdown from 5
prog = program(
('PUSH', 5), # 0: counter
('PUSH', 1), # 1: decrement
('SUB',), # 2: counter - 1
('DUP',), # 3: copy for JNZ test
('JNZ', 1), # 4: loop if non-zero
('HALT',), # 5: done, top = 0
)
print(run(prog))
Stack: PUSH n, POP, DUP, SWAP, OVER, ROT Arithmetic: ADD, SUB, MUL, DIV_S, DIV_U, REM_S, REM_U Comparison: EQZ, EQ, NE, LT_S/U, GT_S/U, LE_S/U, GE_S/U Bitwise: AND, OR, XOR, SHL, SHR_S/U, ROTL, ROTR Unary: CLZ, CTZ, POPCNT, ABS, NEG, SELECT Control: JZ addr, JNZ addr, CALL addr, RETURN, HALT, NOP Locals: LOCAL.GET idx, LOCAL.SET idx, LOCAL.TEE idx Memory: I32.LOAD, I32.STORE, I32.LOAD8_U/S, I32.LOAD16_U/S, I32.STORE8, I32.STORE16
All arithmetic is 32-bit signed with WASM i32 semantics (wrap on overflow).
The key insight: parabolic encoding k = (2j, -j²) makes dot-product attention peak
sharply at a target position. Same encoding addresses program memory, stack, locals,
and heap without interference. Each attention head is a compiled W_Q @ state → query,
W_K @ memory → keys, scores = K @ q, output = V[argmax(scores)].
To pull latest source from the repository:
cd /mnt/skills/user/llm-as-computer/src
GH_TOKEN=$(grep GH_TOKEN /mnt/project/GitHub.env 2>/dev/null | cut -d= -f2)
for f in executor.mojo; do
curl -sL -H "Authorization: token $GH_TOKEN" -H "Accept: application/vnd.github.v3.raw" \
"https://api.github.com/repos/oaustegard/llm-as-computer/contents/src/$f?ref=main" > $f
done
for f in isa_lite.py programs.py runner.py; do
curl -sL -H "Authorization: token $GH_TOKEN" -H "Accept: application/vnd.github.v3.raw" \
"https://api.github.com/repos/oaustegard/llm-as-computer/contents/skill/src/$f?ref=main" > $f
done
rm -f percepta_exec # force recompile
bash setup.sh
npx claudepluginhub oaustegard/claude-skills --plugin ai-and-reasoningCovers self-attention, multi-head attention, RoPE, ALiBi, and transformer architecture variants for implementation and inference optimization.
Skill for understanding and implementing LLM internals concepts from tokenization to attention mechanisms to inference optimization.
Runs LLMs on Apple Silicon with MLX/mlx_lm: unified memory, 4-bit quantization, streaming generation, prompt caching. For M-series chips.