Building autonomous AI infrastructure, high-performance DeFi,
and privacy-first blockchain protocols from the ground up.
Solidus Network is a high-performance perpetuals exchange built on a multi-algorithm, multi-chain DAGKNIGHT architecture. Forked from Quai Network and re-engineered with 4 zones per region, each running a different mining algorithm for a different hardware class — ASIC, GPU, CPU, and Mobile miners all participate without competing against each other. Built-in perps core with on-chain order matching. Research benchmarks are matching Hyperliquid-class speeds and TPS.
DAGKNIGHT consensus runs at the zone level where transaction throughput matters. Region and Prime chains use entropic block ordering
Each region contains 4 parallel zones, each running a distinct consensus algorithm. Miners of different hardware classes never compete against each other — each class has its own dedicated zone with balanced difficulty, ensuring fair participation from enterprise ASICs down to mobile devices.
| Zone | Algorithm | Hardware Class | Design Goal |
|---|---|---|---|
| Zone 1 | SHA-256 | ASIC miners | Maximum hashrate throughput |
| Zone 2 | ProgPoW | GPU miners (NVIDIA/AMD) | Memory-hard, ASIC-resistant |
| Zone 3 | RandomX-S | CPU miners | Modified RandomX — breaks Antminer RandomX ASICs |
| Zone 4 | Panthera | Mobile devices | Lightweight mobile-optimized algorithm |
| Metric | Target |
|---|---|
| Throughput | Hyperliquid-competitive TPS (200,000+ ops/sec) |
| Zone Consensus | DAGKNIGHT — completed from Kaspa research |
| Region/Prime | Entropic block ordering (no DAG overhead) |
| Order Matching | Sub-second on-chain execution |
| Finality | Instant at zone level, cross-region within epoch |
| Architecture | Quai fork — hierarchical, sharded, merged-mined |
| Feature | Description |
|---|---|
| On-Chain Order Book | Fully on-chain limit/market order matching — no off-chain sequencer |
| Cross-Margin | Unified margin across positions with portfolio-level risk |
| Liquidation Engine | MEV-resistant liquidation with keeper incentives |
| Funding Rates | Decentralized oracle-fed funding rate mechanism |
| Multi-Collateral | Multiple collateral types with real-time mark pricing |
Innova is a hybrid PoW/PoS privacy blockchain with 1,500+ commits, built on the Tribus hashing algorithm (three NIST5 algorithms), ~15s block times, and a hardcapped 18M supply. Five-layer privacy architecture, decentralized services layer, and a Collateral Node network.
¹ Layer 4 Silent Shielding: RPC commands registered (sp_send, sp_getnewaddress);
|
Privacy & Staking
|
Decentralized Services
|
Nyx Encryption Stack (Detail)
Live now:
Proposed upgrade (IIP):
Innova Improvement Proposals (IIPs)
Network Specifications
| Parameter | Value |
|---|---|
| Algorithm | Tribus PoW (3x NIST5) + PoS (6% annual) |
| Block Time | ~15 seconds |
| Total Supply | 18,000,000 INN |
| Collateral Nodes | 25,000 INN collateral, 65% block reward |
| Confirmations | 10 required, 75 block maturity |
| Stake Age | 10-hour minimum |
| BIP39 Coin Type | 116 |
| Ports | P2P 14530, RPC 14531, CN 14539 |
| Atomic Swaps | BIP65 CLTV |
| Multi-Sig | Native support |
The first block DAG with DAGKNIGHT adaptive ordering, PoS finality, and full zero-knowledge privacy.
IDAG is Innova's next-generation consensus — a four-phase migration from linear blockchain to a high-throughput block DAG. First to implement epoch-anchored FCMP++ membership proofs in a DAG and adaptive DAGKNIGHT k inference.
| Parameter | Value |
|---|---|
| Block Interval | ~1 second (post-DAG fork at block 7,450,000) |
| Block Size | 300 KB floor – 8 MB ceiling (adaptive median over 1000-block window) |
| Finality | TENTATIVE (⅓ stake) → SOFT (½ stake) → HARD (⅔ stake, 3 consecutive epochs) |
| GHOSTDAG | Fixed k=18, pre-DAGKNIGHT ordering |
| DAGKNIGHT | Adaptive k=3..32 (EMA-inferred, activates at block 7,500,000) |
| Fork Resolution | POEM — GetBlockEntropy() computes entropy from inverted block hash (staged) |
| Epoch | 300 blocks (~5 min), min 2 unique voters for finality |
| Privacy | Epoch-anchored FCMP++ membership proofs via dual curve tree (secp256k1 + Ed25519) with deterministic DAG-ordered commits |
INVS is the shielded asset layer within the Innova ecosystem — fully private value transfer with ZK-proof verification, leveraging all five privacy layers and IDAG's throughput for high-frequency confidential transactions.
Project Lavalamp is a hardware-software security product that masks the AMD Zen 5 SMT port contention timing side-channel — a 27.6% signal leakage vulnerability that AMD, Google, Microsoft, and NVIDIA all declined to fix. At its core is a proprietary entropy engine that generates high-quality dither patterns to bury timing signals below the detection floor. Validated on live FPGA hardware — 8/8 NIST-class statistical quality tests pass, 98.4% Shannon entropy efficiency, with integrity sealing across every released bitstream.
- Hardware validation complete on the Artix-7 reference platform — full end-to-end signal-masking loop running on live silicon.
- Shield (software) tier daemon feature-complete on x86 and ARM Neoverse with 93% leak reduction at ~6% CPU overhead.
- Lite (USB-FPGA) tier shipping across 7 Artix-7 boards with 99%+ leak reduction at <1% host overhead.
- Pro (PCIe) tier in active development — kernel driver and TLP-inference pipeline under bring-up.
- Phase 2 porting effort underway — extending the FPGA build system to 17 boards across 6 vendors.
| Tier | Form Factor | Leak Reduction | CPU Overhead |
|---|---|---|---|
| Shield | CPU-only software daemon (x86 / ARM Neoverse) | 93% | 6% |
| Lite | USB FPGA bitstream + host daemon — 7+ Artix-7 boards | 99%+ | <1% |
| Pro (in dev) | PCIe FPGA card + kernel driver + TLP inference | 99%+ | ~0% |
One command per supported board — vivado -mode batch -source build_board.tcl -tclargs <board>. Currently shipping on the Artix-7 family; Phase 2 validates across 17 FPGA boards spanning 6 vendors (AMD/Xilinx, Intel/Altera, Lattice, Gowin, Microchip).
| Vendor | Families | Status |
|---|---|---|
| AMD / Xilinx | Artix-7, Kintex-7, Virtex UltraScale+ | 7 boards shipping · Kintex/UltraScale validation in progress |
| Intel / Altera | Cyclone V SoC | Planned (Phase 2) |
| Lattice | ECP5 | Planned (Phase 2) |
| Gowin | GW2A | Planned (Phase 2) |
| Microchip | PolarFire SoC | Planned (Phase 2) |
| Vendor | Tracking ID | Response |
|---|---|---|
| AMD | AMD-NSACNT3N |
"Expected Behavior" |
| Google / Chromium | Issue 475937586 |
"Won't Fix" |
| Microsoft MSRC | VULN-171518 |
"Does not meet criteria" |
| NVIDIA PSIRT | Tracking 5775002 |
"Expected behavior" |
Disabling SMT mitigates the leak but costs ~50% of compute capacity. Lavalamp recovers 97% of that capacity while reducing leakage by 93–99% depending on tier. No other product targets this specific vulnerability at the hardware level.
Git for agent runs. Fork, replay, resume any execution.
~250 lines of core · Any model · Zero lock-in · Public beta v0.1.x on PyPI
A tine is the prong of a fork. opentine literally forks your agent runs.
Every agent execution becomes a run tree — content-addressed, serializable, forkable. Pause on your laptop, resume on a server. Branch from step 7 with a different prompt. Diff two runs side by side.
pip install opentinefrom opentine import Agent
from opentine.models.anthropic import Anthropic
agent = Agent(model=Anthropic("claude-sonnet-4-20250514"))
run = agent.run_sync("What is opentine?")
run.save("result.tine")tine show result.tineMatches current PyPI releases in the 0.1.x line — lightweight agent SDK, stable .tine serialization, full CLI (run, ls, show, replay, fork, diff, resume). Native adapters for Anthropic, OpenAI, Google, Ollama; OpenAI-compatible wrappers for Kimi, DeepSeek, Qwen, GLM, Groq, Together, Mistral.
Your agent fails after many steps — fork before the bad tool call instead of burning tokens from step zero:
tine show failed_run.tine
tine fork failed_run.tine --from-step 3 --save fixed_run.tine
tine diff failed_run.tine fixed_run.tine| Install size | Forkable runs | Any model | Core LOC | |
|---|---|---|---|---|
| LangChain | 166 MB | No | Partial | ~200k |
| LangGraph | 51 MB | Checkpoints only | Partial | ~50k |
| CrewAI | 173 MB | No | Partial | ~30k |
| smolagents | 198 MB | No | Partial | ~15k |
| opentine | <5 MB | Yes | Yes | ~250 |
tine run <script.py> Execute agent, stream steps, save run tree
tine ls List recent runs (status, cost, model)
tine show <run_id> Pretty-print the tree (like git log --graph)
tine replay <id> [--from N] Replay from a step
tine fork <id> --from-step N Branch a new run
tine diff <run_a> <run_b> Side-by-side comparison
tine resume <run_id> Resume a paused run
Tools are plain Python callables — opentine introspects type hints. Common symbols from opentine.tools:
| Module | Callables |
|---|---|
web |
web.fetch |
search |
search.search |
fs |
fs.read, fs.write |
shell |
shell.run |
Optional extras (e.g. python) live in the same package when you want sandboxed scripting steps — see upstream docs.
from opentine import Agent
from opentine.models.anthropic import Anthropic
from opentine.tools import web, search, fs, shell
agent = Agent(
model=Anthropic("claude-sonnet-4-20250514"),
tools=[web.fetch, search.search, fs.read, fs.write, shell.run],
)Native backends (opentine.models)
| Backend | Wrapper | Example model ID |
|---|---|---|
| Anthropic | Anthropic |
claude-sonnet-4-20250514 |
| OpenAI | OpenAI |
gpt-4o |
Google |
gemini-2.0-flash |
|
| Local / Ollama | Ollama |
llama3.1 |
OpenAI-compatible (opentine.models.compat — one shared SDK surface)
| Provider | Wrapper | Example model ID |
|---|---|---|
| Kimi (Moonshot) | Kimi |
moonshot-v1-8k |
| DeepSeek | DeepSeek |
deepseek-chat |
| Qwen | Qwen |
qwen-plus |
| Zhipu (GLM) | GLM |
glm-4-flash |
| Groq | Groq |
llama-3.1-70b-versatile |
| Together | Together |
meta-llama/Meta-Llama-3.1-70B-Instruct-Turbo |
| Mistral | Mistral |
mistral-large-latest |
Wire-up is always Agent(model=…(...)) after the matching from opentine.models… import (see Quickstart for a full runnable Anthropic snippet).
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MEV & Ethereum Infrastructure — Block builder tooling (Rust), P2P mempool crawlers, EVM benchmarking, and DeFi protocol analysis.
Cryptanalysis & Bitcoin Research — UTXO analysis, chainstate parsing, vanity address generation, and parallel cryptanalysis tooling.
Priscus Research — Applied AI systems research under private development. Public releases will focus on verifiable claims, reproducible evaluation summaries, and externally reviewable findings while keeping proprietary code, architecture details, model weights, datasets, and internal design materials confidential.
AI/ML — Autonomous agent architectures, multimodal models, and research aligned with agent-first design philosophy.
Building autonomous AI infrastructure, high-performance DeFi, and privacy-first blockchain protocols.