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Comprehensive Artificial Life skill combining ALIFE2025 proceedings, classic texts (Axelrod, Epstein-Axtell), ALIEN simulation, Lenia, NCA, swarm intelligence, and evolutionary computation. 337 pages extracted, 80+ papers, 153 figures.
SOC 직업 분류 기준
Query and explore the 2600: The Hacker Quarterly magazine archive (1984-present) via DuckDB. Provides structured access to 168+ issues covering hacker culture, security, privacy, telephony, and digital rights without loading full content into context.
ACSets (Attributed C-Sets): Algebraic databases with Specter-style bidirectional navigation. Category-theoretic formalism for relational databases.
Attributed C-Sets as algebraic databases. Category-theoretic data structures generalizing graphs and dataframes with Gay.jl color integration.
ACSets (Attributed C-Sets): Algebraic databases with Specter-style bidirectional
Bridge active inference theory with robot control using K-Scale's JAX/MuJoCo stack. Use when connecting predictive coding to locomotion policies, mapping KL divergence minimization to RL training, applying mean field approximation to robotics state estimation, or implementing sim2real as inference about future observations.
Implement affective valence as directional derivative of interoceptive energy landscapes for AI alignment. Use when building alignment-aware RL agents, validating GF(3) conservation in reward signals, training Langevin-based policies, or analyzing fold-change detection signals in POMDP environments.
| name | alife |
| description | Comprehensive Artificial Life skill combining ALIFE2025 proceedings, classic texts (Axelrod, Epstein-Axtell), ALIEN simulation, Lenia, NCA, swarm intelligence, and evolutionary computation. 337 pages extracted, 80+ papers, 153 figures. |
Status: ✅ Production Ready Trit: +1 (PLUS - generative/creative) Sources: ALIFE2025 Proceedings + Classic Texts + Code Repos
| Resource | Content |
|---|---|
| ALIFE2025 | 337 pages, 80+ papers, 153 figures, 100+ equations |
| Axelrod | Evolution of Cooperation, TIT-FOR-TAT, Prisoner's Dilemma |
| Epstein-Axtell | Sugarscape, Growing Artificial Societies |
| ALIEN | CUDA 2D particle engine (ALIFE 2024 winner) |
| Lenia | Continuous cellular automata |
| Concordia | DeepMind generative agent-based models |
% Fitness-proportionate selection
P(i) = \frac{f_i}{\sum_{j=1}^{N} f_j}
% Replicator dynamics
\dot{x}_i = x_i \left[ f_i(x) - \bar{f}(x) \right]
Cooperate Defect
Cooperate R,R S,T
Defect T,S P,P
where T > R > P > S (temptation > reward > punishment > sucker)
TIT-FOR-TAT Strategy (Axelrod):
Properties: Nice (never defects first), Retaliatory, Forgiving, Clear
Elementary CA (Wolfram):
Rule 110: [111→0] [110→1] [101→1] [100→0] [011→1] [010→1] [001→1] [000→0]
Lenia (Continuous CA):
A^{t+\Delta t} = \left[ A^t + \Delta t \cdot G(K * A^t) \right]_0^1
G_{\mu,\sigma}(x) = 2e^{-\frac{(x-\mu)^2}{2\sigma^2}} - 1
Flow-Lenia (Mass-conserving, arXiv:2506.08569):
% Velocity field from kernel convolution
\vec{v}(x) = \nabla G(K * A^t)
% Mass-conserving update via continuity equation
A^{t+1} = A^t - \nabla \cdot (A^t \cdot \vec{v})
% With multispecies extension
A_i^{t+1} = A_i^t - \nabla \cdot \left(A_i^t \cdot \sum_j w_{ij} \vec{v}_j\right)
H-Lenia (Hierarchical):
\left[\left[A_i^t + \Delta t G(K * A_i^t)\right]_0^1 + \sum_{j \in N(i)} k_{ji} \cdot E_{ji}^t\right]_0^1
def nca_step(grid, model):
# Perceive: Sobel filters for gradients
perception = perceive(grid) # [identity, sobel_x, sobel_y, ...]
# Update: Neural network
delta = model(perception)
# Apply with stochastic mask
mask = torch.rand_like(delta) < 0.5
return grid + delta * mask
Sugarscape (Epstein-Axtell):
class Agent:
def __init__(self):
self.sugar = initial_sugar
self.metabolism = random.randint(1, 4)
self.vision = random.randint(1, 6)
def move(self, landscape):
# Look in cardinal directions up to vision
best = max(visible_sites, key=lambda s: s.sugar)
self.position = best
self.sugar += best.sugar - self.metabolism
Boid Rules (Reynolds):
\vec{v}_{new} = w_s \cdot \text{separation} + w_a \cdot \text{alignment} + w_c \cdot \text{cohesion}
BZ Oscillator (Belousov-Zhabotinsky):
\mathcal{F} = \underbrace{D_{KL}[q(\theta)||p(\theta)]}_{\text{complexity}} + \underbrace{\mathbb{E}_q[-\log p(y|\theta)]}_{\text{accuracy}}
| Page | Title | Equations |
|---|---|---|
| 1 | Chemical Computer | BZ reservoir |
| 49 | Hummingbird Kernel | Chaotic LV |
| 73 | Neural Cellular Automata | NCA rules |
| 99 | Language Cellular Automata | NLP + CA |
| 103 | Lenia Parameter Space | Growth functions |
| 107 | Evolvable Chemotons | Autopoiesis |
| 111 | Category Theory for Life | CT formalization |
| 127 | Swarm2Algo | Swarm → Algorithms |
| 135 | Open-Ended Evolution in Binary CA | Emergence |
| 173 | H-Lenia | Hierarchical CA |
| 195 | Neural Particle Automata | Particles |
| 251 | Autotelic RL for CA | RL + CA |
| 301 | Gridarians: LLM-Driven ALife | LLM + ALife |
Key Results:
Tournament Lessons:
Sugarscape Phenomena:
Emergent Properties:
/Users/bob/ies/hatchery_repos/bmorphism__alien/
├── source/ # CUDA kernels
├── resources/ # Simulation configs
└── GAY.md # Gay.jl integration
Winner: ALIFE 2024 Virtual Creatures Competition
github.com/Chakazul/Leniagithub.com/riveSunder/Lenia.jlchakazul.github.io/Lenia# Full import paths for Concordia generative ABM
from concordia.agents import entity_agent
from concordia.agents.components.v2 import memory_component
from concordia.agents.components.v2 import observation
from concordia.agents.components.v2 import action_spec_ignored
from concordia.associative_memory import associative_memory
from concordia.associative_memory import importance_function
from concordia.clocks import game_clock
from concordia.environment import game_master
from concordia.language_model import gpt_model # or gemini_model
# Initialize clock and memory
clock = game_clock.MultiIntervalClock(
start=datetime.datetime(2024, 1, 1),
step_sizes=[datetime.timedelta(hours=1)]
)
# Associative memory with embeddings
mem = associative_memory.AssociativeMemory(
embedder=embedder, # sentence-transformers or similar
importance=importance_function.ConstantImportanceFunction()
)
# Create LLM-driven agent with components
agent = entity_agent.EntityAgent(
model=language_model,
memory=mem,
clock=clock,
components=[
observation.Observation(clock=clock, memory=mem),
memory_component.MemoryComponent(memory=mem),
]
)
# Game master orchestrates environment
gm = game_master.GameMaster(
model=language_model,
players=[agent],
clock=clock,
memory=mem
)
% Mutation-selection balance
\hat{p} = \frac{\mu}{s}
% Wright-Fisher drift
\text{Var}(\Delta p) = \frac{p(1-p)}{2N}
% Gray-Scott
\frac{\partial u}{\partial t} = D_u \nabla^2 u - uv^2 + f(1-u)
\frac{\partial v}{\partial t} = D_v \nabla^2 v + uv^2 - (f+k)v
% Information synergy
I_{\text{syn}}(X \rightarrow Y) = I_{\text{tot}} - \sum_{i=1}^{n} I_{\text{ind}}(X_i)
\frac{dx_i}{dt} = x_i\left(r_i + \sum_{j=1}^{n} A_{ij} x_j\right)
/Users/bob/ies/paper_extracts/alife2025/
├── ALIFE2025_full.md # 925KB markdown
├── ALIFE2025_tex.zip # 11MB LaTeX
├── tex_extracted/
│ └── fed660c6-.../
│ ├── *.tex # 7283 lines
│ └── images/ # 153 figures
└── conversion_status.json
/Users/bob/ies/
├── axelrod-evolution-of-cooperation.md
├── epstein-axtell-growing-artificial-societies.txt
├── wooldridge-multiagent-systems.txt
└── hatchery_repos/bmorphism__alien/
using Gay
# Theme colors for ALife domains
ALIFE_THEMES = Dict(
:evolution => Gay.color_at(0xEV0L, 1), # Warm
:emergence => Gay.color_at(0xEMRG, 1), # Neutral
:cellular => Gay.color_at(0xCA11, 1), # Cool
:swarm => Gay.color_at(0x5ARM, 1), # Dynamic
:chemical => Gay.color_at(0xCHEM, 1), # Reactive
)
# GF(3) classification
# -1: Structure (CA rules, genomes)
# 0: Process (dynamics, transitions)
# +1: Emergence (patterns, behaviors)
just alife-toc # Full table of contents
just alife-paper 42 # Get paper at page 42
just alife-equation "lenia" # Find Lenia equations
just alife-axelrod # Axelrod summary
just alife-sugarscape # Sugarscape patterns
just alife-alien # ALIEN simulation info
just alife-lenia "orbium" # Lenia creature lookup
# Run Lenia simulation (via leniax)
python -c "
import jax.numpy as jnp
from leniax import Lenia
lenia = Lenia.from_name('orbium')
state = lenia.init_state(jax.random.PRNGKey(42))
for _ in range(100): state = lenia.step(state)
print(f'Final mass: {state.sum():.2f}')
"
# Run NCA step (via cax)
python -c "
from cax import NCA
import jax
nca = NCA(hidden_channels=12)
params = nca.init(jax.random.PRNGKey(0), jnp.zeros((64, 64, 16)))
grid = jax.random.uniform(jax.random.PRNGKey(1), (64, 64, 16))
new_grid = nca.apply(params, grid)
print(f'Grid shape: {new_grid.shape}')
"
# TIT-FOR-TAT simulation
python -c "
import axelrod as axl
players = [axl.TitForTat(), axl.Defector(), axl.Cooperator(), axl.Random()]
tournament = axl.Tournament(players, turns=200, repetitions=10)
results = tournament.play()
print(results.ranked_names[:3])
"
# Sugarscape-style agent (simplified)
python -c "
import numpy as np
class Agent:
def __init__(self): self.x, self.y, self.sugar = 0, 0, 10
def move(self, grid):
neighbors = [(self.x+dx, self.y+dy) for dx,dy in [(-1,0),(1,0),(0,-1),(0,1)]]
best = max(neighbors, key=lambda p: grid[p[0]%50, p[1]%50])
self.x, self.y = best[0]%50, best[1]%50
self.sugar += grid[self.x, self.y]
grid = np.random.rand(50, 50) * 4
agent = Agent(); [agent.move(grid) for _ in range(100)]
print(f'Final sugar: {agent.sugar:.1f}')
"
| Library | Purpose | Install |
|---|---|---|
| Leniax | Lenia simulation (JAX, differentiable) | pip install leniax |
| CAX | Cellular Automata Accelerated (ICLR 2025) | pip install cax |
| Leniabreeder | Quality-Diversity for Lenia | GitHub |
| ALIEN | CUDA particle engine (5.2k⭐) | alien-project.org |
| EvoTorch | Evolutionary algorithms (PyTorch+Ray) | pip install evotorch |
| neat-python | NEAT neuroevolution | pip install neat-python |
| JaxLife | Open-ended agentic simulator | GitHub |
See: LIBRARIES.md for full documentation and code examples
graph TB
subgraph Evolution
GA[Genetic Algorithms]
OEE[Open-Ended Evolution]
NS[Natural Selection]
end
subgraph Emergence
CA[Cellular Automata]
NCA[Neural CA]
Lenia[Lenia]
end
subgraph Agents
ABM[Agent-Based Models]
Swarm[Swarm Intelligence]
GABM[Generative ABM]
end
subgraph Chemistry
BZ[BZ Reaction]
Auto[Autopoiesis]
Chem[Artificial Chemistry]
end
GA --> OEE
CA --> NCA --> Lenia
ABM --> Swarm --> GABM
BZ --> Auto --> Chem
OEE --> Emergence
Lenia --> Agents
GABM --> Chemistry
Primary Interop Skills (load together for full capability):
| Skill | Interop | Command |
|---|---|---|
gay-mcp | Deterministic coloring of all ALife entities | mcp gay palette 12 seed=0x4C454E49 |
acsets-algebraic-databases | Lenia/NCA as C-Set schemas | @acset_type LeniaGrid(SchLenia) |
glass-bead-game | Cross-domain morphisms (CA↔music↔philosophy) | Morphism.new(:lenia, :timbre) |
self-validation-loop | Prediction/observation for CA dynamics | validate_ca_step(grid, kernel, seed) |
algorithmic-art | p5.js visualization with Gay.jl palettes | just art-lenia seed=0x4C454E49 |
world-hopping | Badiou triangle for parameter space | LeniaWorld.hop_to(target) |
Secondary Skills:
epistemic-arbitrage - Knowledge transfer across ALife domainshatchery-papers - Academic paper patterns (ALIEN, Lenia papers)bmorphism-stars - Related repositoriestriad-interleave - Three-stream parallel CA updatesbisimulation-game - Skill dispersal with GF(3) conservationSee: INTEROP.md for full integration patterns
@proceedings{alife2025,
title = {ALIFE 25: Ciphers of Life},
editor = {Witkowski, O. and Adams, A.M. and Sinapayen, L.},
year = {2025},
pages = {337}
}
@book{axelrod1984,
title = {The Evolution of Cooperation},
author = {Axelrod, Robert},
year = {1984},
publisher = {Basic Books}
}
@book{epstein1996,
title = {Growing Artificial Societies},
author = {Epstein, Joshua M. and Axtell, Robert},
year = {1996},
publisher = {MIT Press}
}
Skill Name: alife
Type: Research Reference / Algorithm Library / Simulation Toolkit
Trit: +1 (PLUS - generative)
Mathpix: PDF ID fed660c6-4d3d-4bb6-bb3c-f9b039187660
| Theme | Paper | arXiv | Key Innovation |
|---|---|---|---|
| Flow-Lenia | Emergent evolutionary dynamics | 2506.08569 | Mass conservation + multispecies |
| Leniabreeder | Quality-Diversity for Lenia | 2406.04235 | MAP-Elites + AURORA |
| ARC-NCA | Developmental Solutions | 2505.08778 | EngramNCA matches GPT-4.5 |
| DiffLogic CA | Differentiable Logic Gates | 2506.04912 | Discrete learnable CA |
| Active Inference | Missing Reward | 2508.05619 | FEP for autonomous agents |
| CT Autopoiesis | Autonomy as Closure | 2305.15279 | Monoid = operational closure |
% Flow-Lenia mass conservation
A^{t+1} = A^t + \nabla \cdot (A^t \cdot \vec{v}(K * A^t))
% EngramNCA hidden memory
h^{t+1} = \sigma(W_h \cdot [v^t, h^t] + b_h)
% DiffLogic gate probability
p(g) = \text{softmax}(\theta_g) \quad g \in \{\text{AND}, \text{OR}, \text{XOR}, ...\}
% Monoid operational closure
\text{Aut}(S) \cong \text{Mon}(\mathcal{C}), \quad |\text{Ob}| = 1
| System | Task | Score | vs GPT-4.5 |
|---|---|---|---|
| ARC-NCA | ARC public | 17.6% | comparable |
| EngramNCA v3 | ARC public | 27% | 1000x less compute |
| Leniabreeder | OEE metrics | unbounded | N/A |
Exa Index: /Users/bob/ies/ALIFE_EXA_REFINED_INDEX.md
Part of: alife-commons. Family: open-ended-evolution. Canonical: alife.