2578bfee61
- Renamed ideas/stoa/ → ideas/passepartout/, all stage files prefixed passepartout- - Renamed triad-index/overview/systemic-effects → passepartout-* under passepartout/ - Renamed ideas/agora/ → ideas/passepartout-social-protocol/, stripped agora- prefixes - Merged overview and environment pages into architecture; deleted 3 redundant files - Renamed growth-strategy → enterprise-growth-strategy - Renamed alternative-growth-social-first → social-growth-strategy - Removed all Greek names: Stoa, Logos, Agora as product names - Updated 50+ files of cross-references to new naming - Kept org-id UUIDs intact throughout
17 lines
2.1 KiB
Org Mode
17 lines
2.1 KiB
Org Mode
:PROPERTIES:
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:CREATED: [2026-05-24 Sun]
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:ID: 13e6ae54-2d24-5aa0-b1cd-a7e8e749aa70
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:END:
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#+title: The Self-Driving Lisp Machine
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#+filetags: :passepartout:lisp-machine:hardware:riscv:tenstorrent:
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A Tenstorrent P150 (~72 RISC-V Tensix cores) running Passepartout: 72 RISC-V cores running Lisp microcode, one core dedicated to ACL2, one to Screamer, the rest to gate verification and fact store operations.
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The self-driving threshold: the system can synthesize and load its own FPGA microcode or Tensix dispatch programs from within the running Lisp image. The system profiles its own gate verification latency, proposes a new microcoded instruction for the hot path, compiles RISC-V assembly from ACL2-verified specifications, loads it via PCIe DMA from within SBCL, benchmarks it — and rolls back if slower.
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Every subdomain involved is software — the most codifiable domain. RISC-V ISA, SBCL internals, ACL2 metafunctions, CIC type theory, compiler optimization — all can [[id:efc76898-03f7-57ba-923d-35d65da88bb7][flip to symbolic sufficiency]] within days to weeks of ingestion.
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**Timeline:** ~6,000 lines of new code (microcode, PCIe DMA, Tensix management, benchmark harness). ~60 cycles at current velocity. 2-4 weeks. Total from today: 6-10 weeks. See [[id:dc2e4f22-1c4c-5d4a-a151-f96e5d3b0d70][time estimates]] for the velocity model behind these numbers.
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The Tenstorrent approach is dramatically simpler than FPGA because the microcode is RISC-V assembly (software), not FPGA bitstream (hardware with minutes-per-iteration synthesis). The [[id:1c95ce7d-a2db-506a-9608-df68f9ae211b][Lisp Machine security model]] — unified memory, tagged architecture, no MMU — applies directly because the Tensix cores share the same address space. [[id:84a537b4-4256-50c8-91f5-dd5b4538418f][Verification appliance]] economics apply: a certified Lisp Machine at scale replaces compliance hardware. See [[id:9af13fff-9725-542b-93b1-a555bc74ad72][why Lisp is economically viable now]] and [[id:29e4dbf3-cf19-589c-8b14-389e8a39d564][upgrade lifecycle]] for the economic and deployment foundations.
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