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Atomizer/tests/test_phase_2_5_intelligent_gap_detection.py
Anto01 eabcc4c3ca refactor: Major reorganization of optimization_engine module structure 
BREAKING CHANGE: Module paths have been reorganized for better maintainability.
Backwards compatibility aliases with deprecation warnings are provided.

New Structure:
- core/           - Optimization runners (runner, intelligent_optimizer, etc.)
- processors/     - Data processing
  - surrogates/   - Neural network surrogates
- nx/             - NX/Nastran integration (solver, updater, session_manager)
- study/          - Study management (creator, wizard, state, reset)
- reporting/      - Reports and analysis (visualizer, report_generator)
- config/         - Configuration management (manager, builder)
- utils/          - Utilities (logger, auto_doc, etc.)
- future/         - Research/experimental code

Migration:
- ~200 import changes across 125 files
- All __init__.py files use lazy loading to avoid circular imports
- Backwards compatibility layer supports old import paths with warnings
- All existing functionality preserved

To migrate existing code:
  OLD: from optimization_engine.nx_solver import NXSolver
  NEW: from optimization_engine.nx.solver import NXSolver

  OLD: from optimization_engine.runner import OptimizationRunner
  NEW: from optimization_engine.core.runner import OptimizationRunner

🤖 Generated with [Claude Code](https://claude.com/claude-code)

Co-Authored-By: Claude Opus 4.5 <noreply@anthropic.com>
2025-12-29 12:30:59 -05:00

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"""
Test Phase 2.5: Intelligent Codebase-Aware Gap Detection
This test demonstrates the complete Phase 2.5 system that intelligently
identifies what's missing vs what's already implemented in the codebase.
Author: Atomizer Development Team
Version: 0.1.0 (Phase 2.5)
Last Updated: 2025-01-16
"""
import sys
from pathlib import Path
# Set UTF-8 encoding for Windows console
if sys.platform == 'win32':
import codecs
if not isinstance(sys.stdout, codecs.StreamWriter):
if hasattr(sys.stdout, 'buffer'):
sys.stdout = codecs.getwriter('utf-8')(sys.stdout.buffer, errors='replace')
sys.stderr = codecs.getwriter('utf-8')(sys.stderr.buffer, errors='replace')
# Add project root to path
project_root = Path(__file__).parent.parent
sys.path.insert(0, str(project_root))
from optimization_engine.utils.codebase_analyzer import CodebaseCapabilityAnalyzer
from optimization_engine.future.workflow_decomposer import WorkflowDecomposer
from optimization_engine.config.capability_matcher import CapabilityMatcher
from optimization_engine.future.targeted_research_planner import TargetedResearchPlanner
def print_header(text: str, char: str = "="):
"""Print formatted header."""
print(f"\n{char * 80}")
print(text)
print(f"{char * 80}\n")
def print_section(text: str):
"""Print section divider."""
print(f"\n{'-' * 80}")
print(text)
print(f"{'-' * 80}\n")
def test_phase_2_5():
"""Test the complete Phase 2.5 intelligent gap detection system."""
print_header("PHASE 2.5: Intelligent Codebase-Aware Gap Detection Test")
print("This test demonstrates how the Research Agent now understands")
print("the existing Atomizer codebase before asking for examples.\n")
# Test request (the problematic one from before)
test_request = (
"I want to evaluate strain on a part with sol101 and optimize this "
"(minimize) using iterations and optuna to lower it varying all my "
"geometry parameters that contains v_ in its expression"
)
print("User Request:")
print(f' "{test_request}"')
print()
# Initialize Phase 2.5 components
print_section("[1] Initializing Phase 2.5 Components")
analyzer = CodebaseCapabilityAnalyzer()
print(" CodebaseCapabilityAnalyzer initialized")
decomposer = WorkflowDecomposer()
print(" WorkflowDecomposer initialized")
matcher = CapabilityMatcher(analyzer)
print(" CapabilityMatcher initialized")
planner = TargetedResearchPlanner()
print(" TargetedResearchPlanner initialized")
# Step 1: Analyze codebase capabilities
print_section("[2] Analyzing Atomizer Codebase Capabilities")
capabilities = analyzer.analyze_codebase()
print(" Scanning optimization_engine directory...")
print(" Analyzing Python files for capabilities...\n")
print(" Found Capabilities:")
print(f" Optimization: {sum(capabilities['optimization'].values())} implemented")
print(f" Simulation: {sum(capabilities['simulation'].values())} implemented")
print(f" Result Extraction: {sum(capabilities['result_extraction'].values())} implemented")
print(f" Geometry: {sum(capabilities['geometry'].values())} implemented")
print()
print(" Result Extraction Detail:")
for cap_name, exists in capabilities['result_extraction'].items():
status = "FOUND" if exists else "MISSING"
print(f" {cap_name:15s} : {status}")
# Step 2: Decompose workflow
print_section("[3] Decomposing User Request into Workflow Steps")
workflow_steps = decomposer.decompose(test_request)
print(f" Identified {len(workflow_steps)} atomic workflow steps:\n")
for i, step in enumerate(workflow_steps, 1):
print(f" {i}. {step.action.replace('_', ' ').title()}")
print(f" Domain: {step.domain}")
if step.params:
print(f" Params: {step.params}")
print()
# Step 3: Match to capabilities
print_section("[4] Matching Workflow to Existing Capabilities")
match = matcher.match(workflow_steps)
print(f" Coverage: {match.coverage:.0%} ({len(match.known_steps)}/{len(workflow_steps)} steps)")
print(f" Confidence: {match.overall_confidence:.0%}\n")
print(" KNOWN Steps (Already Implemented):")
for i, known in enumerate(match.known_steps, 1):
print(f" {i}. {known.step.action.replace('_', ' ').title()}")
if known.implementation:
impl_file = Path(known.implementation).name if known.implementation != 'unknown' else 'multiple files'
print(f" Implementation: {impl_file}")
print()
print(" MISSING Steps (Need Research):")
for i, unknown in enumerate(match.unknown_steps, 1):
print(f" {i}. {unknown.step.action.replace('_', ' ').title()}")
print(f" Required: {unknown.step.params}")
if unknown.similar_capabilities:
print(f" Can adapt from: {', '.join(unknown.similar_capabilities)}")
print(f" Confidence: {unknown.confidence:.0%} (pattern reuse)")
else:
print(f" Confidence: {unknown.confidence:.0%} (needs research)")
# Step 4: Create targeted research plan
print_section("[5] Creating Targeted Research Plan")
research_plan = planner.plan(match)
print(f" Generated {len(research_plan)} research steps\n")
if research_plan:
print(" Research Plan:")
for i, step in enumerate(research_plan, 1):
print(f"\n Step {i}: {step['description']}")
print(f" Action: {step['action']}")
if 'details' in step:
if 'capability' in step['details']:
print(f" Study: {step['details']['capability']}")
if 'query' in step['details']:
print(f" Query: \"{step['details']['query']}\"")
print(f" Expected confidence: {step['expected_confidence']:.0%}")
# Summary
print_section("[6] Summary - Expected vs Actual Behavior")
print(" OLD Behavior (Phase 2):")
print(" - Detected keyword 'geometry'")
print(" - Asked user for geometry examples")
print(" - Completely missed the actual request")
print(" - Wasted time on known capabilities\n")
print(" NEW Behavior (Phase 2.5):")
print(f" - Analyzed full workflow: {len(workflow_steps)} steps")
print(f" - Identified {len(match.known_steps)} steps already implemented:")
for known in match.known_steps:
print(f" {known.step.action}")
print(f" - Identified {len(match.unknown_steps)} missing capability:")
for unknown in match.unknown_steps:
print(f" {unknown.step.action} (can adapt from {unknown.similar_capabilities[0] if unknown.similar_capabilities else 'scratch'})")
print(f" - Focused research: ONLY {len(research_plan)} steps needed")
print(f" - Strategy: Adapt from existing OP2 extraction pattern\n")
# Validation
print_section("[7] Validation")
success = True
# Check 1: Should identify strain as missing
has_strain_gap = any(
'strain' in str(step.step.params)
for step in match.unknown_steps
)
print(f" Correctly identified strain extraction as missing: {has_strain_gap}")
if not has_strain_gap:
print(" FAILED: Should have identified strain as the gap")
success = False
# Check 2: Should NOT research known capabilities
researching_known = any(
step['action'] in ['identify_parameters', 'update_parameters', 'run_analysis', 'optimize']
for step in research_plan
)
print(f" Does NOT research known capabilities: {not researching_known}")
if researching_known:
print(" FAILED: Should not research already-known capabilities")
success = False
# Check 3: Should identify similar capabilities
has_similar = any(
len(step.similar_capabilities) > 0
for step in match.unknown_steps
)
print(f" Found similar capabilities (displacement, stress): {has_similar}")
if not has_similar:
print(" FAILED: Should have found displacement/stress as similar")
success = False
# Check 4: Should have high overall confidence
high_confidence = match.overall_confidence >= 0.80
print(f" High overall confidence (>= 80%): {high_confidence} ({match.overall_confidence:.0%})")
if not high_confidence:
print(" WARNING: Confidence should be high since only 1/5 steps is missing")
print_header("TEST RESULT: " + ("SUCCESS" if success else "FAILED"), "=")
if success:
print("Phase 2.5 is working correctly!")
print()
print("Key Achievements:")
print(" - Understands existing codebase before asking for help")
print(" - Identifies ONLY actual gaps (strain extraction)")
print(" - Leverages similar code patterns (displacement, stress)")
print(" - Focused research (4 steps instead of asking about everything)")
print(" - High confidence due to pattern reuse (90%)")
print()
return success
def main():
"""Main entry point."""
try:
success = test_phase_2_5()
sys.exit(0 if success else 1)
except Exception as e:
print(f"\nERROR: {e}")
import traceback
traceback.print_exc()
sys.exit(1)
if __name__ == '__main__':
main()
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