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Executable Genome Framework (EGF)
Formalizing Genome-as-Program Modeling
This module implements a novel computational paradigm where biological systems
are represented as executable, modular, memory-preserving programs.
"""
import hashlib
import json
import time
import random
import copy
import uuid
from dataclasses import dataclass, field
from typing import Dict, List, Optional, Any, Tuple, Set
from pathlib import Path
from ..core.adapter_engine import Adapter, AdapterEngine, QuantumArtifact
@dataclass
class BiologicalArtifact:
"""Stores a complete 'biological execution episode'"""
artifact_id: str
raw_context: Dict[str, Any]
processed_context: Dict[str, Any]
context_hash: str
gate_state_hash: str
gate_states: Dict[str, float]
regulatory_paths: List[Tuple[str, str, float]]
expression_results: Dict[str, float]
outcome_scores: Dict[str, float]
timestamp: float = field(default_factory=time.time)
def to_dict(self) -> Dict[str, Any]:
return {
"artifact_id": self.artifact_id,
"raw_context": self.raw_context,
"processed_context": self.processed_context,
"context_hash": self.context_hash,
"gate_state_hash": self.gate_state_hash,
"gate_states": self.gate_states,
"regulatory_paths": self.regulatory_paths,
"expression_results": self.expression_results,
"outcome_scores": self.outcome_scores,
"timestamp": self.timestamp
}
class GenomeCoreAdapter:
"""
Stores DNA sequences, variants, and isoforms.
Acts as the immutable biological source code.
"""
def __init__(self, sequence_data: Dict[str, str]):
self.sequence_data = sequence_data
self.version = "1.0.0"
self.memory: List[Any] = []
def get_sequence(self, gene_id: str) -> Optional[str]:
return self.sequence_data.get(gene_id)
class EpigeneticGateAdapter:
"""
Stateful gates controlling regulatory edges.
Context-dependent, persistent, history-aware.
Mimics methylation / chromatin accessibility behavior.
"""
def __init__(self):
self.gate_states: Dict[str, float] = {} # 0.0 (closed) to 1.0 (open)
self.memory: List[Dict[str, float]] = []
def update_gates(self, context: Dict[str, Any]):
"""Update gates based on tissue, signals, and past history"""
# Logic to mimic chromatin accessibility
for gate_id, current_state in self.gate_states.items():
# Example: persistent state with context influence
stress = context.get("stress", 0.0)
tissue_bias = context.get("tissue_gates", {}).get(gate_id, 0.5)
# Non-linear update
new_state = (current_state * 0.8) + (tissue_bias * 0.1) - (stress * 0.05)
self.gate_states[gate_id] = max(0.0, min(1.0, new_state))
self.memory.append(self.gate_states.copy())
def get_gate_multiplier(self, edge_id: str) -> float:
return self.gate_states.get(edge_id, 1.0)
class RegulomeAdapter:
"""
Represents promoters, enhancers, silencers, transcription factors.
Implemented as an executable graph.
"""
def __init__(self):
self.nodes: Set[str] = set()
self.edges: Dict[str, List[Tuple[str, float]]] = {} # src -> [(dest, weight)]
self.memory: List[Any] = []
def add_regulatory_link(self, source: str, target: str, influence: float):
self.nodes.add(source)
self.nodes.add(target)
if source not in self.edges:
self.edges[source] = []
self.edges[source].append((target, influence))
def execute_logic(self, active_tfs: Dict[str, float], gates: EpigeneticGateAdapter) -> Tuple[Dict[str, float], List[Tuple[str, str, float]]]:
"""Runs the regulatory logic to determine activation levels"""
activations = active_tfs.copy()
execution_trace: List[Tuple[str, str, float]] = []
# Simple iterative activation spread (mimics regulatory cascade)
for _ in range(3): # Depth of cascade
new_activations = activations.copy()
for src, targets in self.edges.items():
if src in activations:
src_level = activations[src]
for dest, weight in targets:
gate_mult = gates.get_gate_multiplier(f"{src}->{dest}")
effective_influence = src_level * weight * gate_mult
new_activations[dest] = new_activations.get(dest, 0.0) + effective_influence
if effective_influence != 0:
execution_trace.append((src, dest, effective_influence))
activations = new_activations
return activations, execution_trace
class ContextAdapter:
"""
Inputs: tissue identity, stress, signals, nutrients, conditions.
Activates transcription factors and regulatory pathways.
"""
def __init__(self):
self.current_context: Dict[str, Any] = {}
self.memory: List[Dict[str, Any]] = []
def process_environment(self, raw_inputs: Dict[str, Any]) -> Dict[str, Any]:
self.current_context = copy.deepcopy(raw_inputs)
# Logic to activate initial TFs based on environment
signals = raw_inputs.get("initial_signals", {}).copy()
# Example: high glucose in environment activates TF_Glucose
if raw_inputs.get("glucose_level", 0) > 0.5:
signals["TF_Glucose"] = signals.get("TF_Glucose", 0.0) + 0.5
self.current_context["processed_signals"] = signals
self.memory.append(self.current_context.copy())
return self.current_context
class ExpressionDynamicsAdapter:
"""
Executes the regulatory graph over time.
Produces continuous gene expression trajectories.
"""
def __init__(self, regulome: RegulomeAdapter):
self.regulome = regulome
self.trajectories: List[Dict[str, float]] = []
self.execution_traces: List[List[Tuple[str, str, float]]] = []
self.memory: List[Any] = []
def run_trajectory(self, initial_state: Dict[str, float], gates: EpigeneticGateAdapter, steps: int = 10) -> Tuple[List[Dict[str, float]], List[Tuple[str, str, float]]]:
current_state = initial_state
self.trajectories = [current_state]
combined_trace: List[Tuple[str, str, float]] = []
for _ in range(steps):
current_state, step_trace = self.regulome.execute_logic(current_state, gates)
# Apply decay/homeostasis
current_state = {k: v * 0.9 for k, v in current_state.items()}
self.trajectories.append(current_state)
combined_trace.extend(step_trace)
self.execution_traces.append(combined_trace)
self.memory.append((self.trajectories, combined_trace))
return self.trajectories, combined_trace
class ProteomeAdapter:
"""
Translates expression into protein abundance and functional embeddings.
"""
def __init__(self):
self.protein_abundance: Dict[str, float] = {}
self.memory: List[Dict[str, float]] = []
def translate(self, expression: Dict[str, float]):
# Translation efficiency and half-life simulation
self.protein_abundance = {gene: val * 1.2 for gene, val in expression.items()}
self.memory.append(self.protein_abundance.copy())
return self.protein_abundance
class PhenotypeAdapter:
"""
Scores biological outcomes (stability, efficiency, viability proxies).
"""
def __init__(self):
self.memory: List[Dict[str, float]] = []
def score_outcome(self, protein_levels: Dict[str, float], context: Dict[str, Any]) -> Dict[str, float]:
# Example: scoring based on required proteins for a tissue
target_proteins = context.get("required_proteins", {})
stability = 1.0
efficiency = 0.0
for p, target in target_proteins.items():
actual = protein_levels.get(p, 0.0)
diff = abs(actual - target)
stability -= (diff * 0.1)
efficiency += actual
score = {
"stability": max(0.0, stability),
"efficiency": efficiency,
"viability": 1.0 if stability > 0.5 else 0.0
}
self.memory.append(score)
return score
class ExecutableGenomeFramework:
"""
The master framework that orchestrates biological execution and learning.
"""
def __init__(self, storage_path: str):
self.storage_path = Path(storage_path)
self.storage_path.mkdir(parents=True, exist_ok=True)
# Initialize Adapters
self.genome = GenomeCoreAdapter({})
self.regulome = RegulomeAdapter()
self.epigenetics = EpigeneticGateAdapter()
self.context_engine = ContextAdapter()
self.expression_engine = ExpressionDynamicsAdapter(self.regulome)
self.proteome = ProteomeAdapter()
self.phenotype = PhenotypeAdapter()
# Artifact Memory
self.memory: List[BiologicalArtifact] = []
self.memory_index: Dict[str, BiologicalArtifact] = {}
self._load_memory()
def _load_memory(self):
memory_file = self.storage_path / "biological_memory.json"
if memory_file.exists():
with open(memory_file, "r") as f:
data = json.load(f)
self.memory = []
self.memory_index = {}
for a in data:
# Migration/Compatibility
if "context" in a and "raw_context" not in a:
a["raw_context"] = a.pop("context")
a["processed_context"] = a["raw_context"]
if "context_hash" not in a:
a["context_hash"] = self._compute_context_hash(a["raw_context"])
if "gate_state_hash" not in a:
a["gate_state_hash"] = self._compute_gate_hash(a.get("gate_states", {}))
# Ensure all fields are present for dataclass unpacking
try:
artifact = BiologicalArtifact(**a)
self.memory.append(artifact)
# Replay key includes state
replay_key = f"{artifact.context_hash}:{artifact.gate_state_hash}"
self.memory_index[replay_key] = artifact
except TypeError:
# Skip corrupted or incompatible entries
continue
def _compute_gate_hash(self, gate_states: Dict[str, float]) -> str:
"""Compute a stable hash of the epigenetic gate states."""
gates_json = json.dumps(gate_states, sort_keys=True)
return hashlib.sha256(gates_json.encode()).hexdigest()
def _compute_context_hash(self, context: Dict[str, Any]) -> str:
"""
Compute a stable hash of the context, ignoring transient fields.
"""
# Create a copy to avoid mutating the original
clean_ctx = copy.deepcopy(context)
# Fields to ignore
ignore_fields = ["timestamp", "processed_signals", "artifact_id", "runtime_ms", "name"]
for field in ignore_fields:
if field in clean_ctx:
del clean_ctx[field]
# Stable sort for consistent hashing
ctx_json = json.dumps(clean_ctx, sort_keys=True)
return hashlib.sha256(ctx_json.encode()).hexdigest()
def _save_memory(self):
memory_file = self.storage_path / "biological_memory.json"
with open(memory_file, "w") as f:
json.dump([a.to_dict() for a in self.memory], f, indent=2)
def execute(self, raw_context: Dict[str, Any], allow_replay: bool = True) -> BiologicalArtifact:
"""
Runs a biological execution episode.
Genome -> Program -> Execution -> Memory
"""
start_time = time.time()
# 0. Replay Lookup
context_hash = self._compute_context_hash(raw_context)
gate_state_hash = self._compute_gate_hash(self.epigenetics.gate_states)
replay_key = f"{context_hash}:{gate_state_hash}"
if allow_replay:
cached_artifact = self.memory_index.get(replay_key)
if cached_artifact:
# Restore state for consistency in stateful systems
self.epigenetics.gate_states = cached_artifact.gate_states.copy()
duration_ms = (time.time() - start_time) * 1000
print(f"โ
REPLAY_HIT: {cached_artifact.artifact_id} (hash: {context_hash[:8]}:{gate_state_hash[:8]}) [{duration_ms:.2f}ms]")
return cached_artifact
print(f"๐ REPLAY_MISS: Executing biological program... (hash: {context_hash[:8]}:{gate_state_hash[:8]})")
# 1. Process environment/context (work on a deep copy)
processed_context = self.context_engine.process_environment(copy.deepcopy(raw_context))
# 2. Update epigenetic state based on context
self.epigenetics.update_gates(processed_context)
# 3. Get initial signals from context (Transcription Factors)
initial_signals = processed_context.get("processed_signals", {})
# 4. Run expression dynamics
trajectory, execution_trace = self.expression_engine.run_trajectory(initial_signals, self.epigenetics)
final_expression = trajectory[-1]
# 5. Translate to proteome
protein_levels = self.proteome.translate(final_expression)
# 6. Score phenotype
scores = self.phenotype.score_outcome(protein_levels, processed_context)
# 7. Create Artifact
artifact_id = f"episode_{uuid.uuid4().hex[:8]}"
artifact = BiologicalArtifact(
artifact_id=artifact_id,
raw_context=raw_context,
processed_context=processed_context,
context_hash=context_hash,
gate_state_hash=gate_state_hash,
gate_states=self.epigenetics.gate_states.copy(),
regulatory_paths=execution_trace,
expression_results=final_expression,
outcome_scores=scores
)
# 8. Learn: Store execution (unconditional storage for experiments)
self.memory.append(artifact)
self.memory_index[replay_key] = artifact
self._save_memory()
duration_ms = (time.time() - start_time) * 1000
print(f"๐ฌ Execution complete in {duration_ms:.2f}ms. Artifact: {artifact_id}")
return artifact
def replay_experience(self, artifact_id: str):
"""Replays a previous biological episode to reinforce or adapt"""
artifact = next((a for a in self.memory if a.artifact_id == artifact_id), None)
if not artifact:
return None
# Set state from artifact
self.epigenetics.gate_states = artifact.gate_states.copy()
# Re-execute with same context, forcing recompute for "rehearsal"
return self.execute(artifact.raw_context, allow_replay=False)
if __name__ == "__main__":
# Example setup
egf = ExecutableGenomeFramework("./egf_data")
# Configure some regulatory links
egf.regulome.add_regulatory_link("TF_A", "GENE_X", 1.5)
egf.regulome.add_regulatory_link("GENE_X", "GENE_Y", 0.8)
egf.epigenetics.gate_states["TF_A->GENE_X"] = 1.0
egf.epigenetics.gate_states["GENE_X->GENE_Y"] = 0.5
# Run an execution
context = {
"tissue": "liver",
"stress": 0.1,
"initial_signals": {"TF_A": 1.0},
"required_proteins": {"GENE_Y": 1.0}
}
result = egf.execute(context)
print(f"Executed Episode: {result.artifact_id}")
print(f"Outcome Scores: {result.outcome_scores}")
print(f"Final Expression: {result.expression_results}")
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